pax_global_header00006660000000000000000000000064130072712140014507gustar00rootroot0000000000000052 comment=1426e334e1d20542400d77c72c132b04c6d17ddb pyqtgraph-pyqtgraph-0.10.0/000077500000000000000000000000001300727121400156215ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/.coveragerc000066400000000000000000000005131300727121400177410ustar00rootroot00000000000000[run] source = pyqtgraph branch = True [report] omit = */python?.?/* */site-packages/nose/* *test* */__pycache__/* *.pyc exclude_lines = pragma: no cover def __repr__ if self\.debug raise AssertionError raise NotImplementedError if 0: if __name__ == .__main__.: ignore_errors = True pyqtgraph-pyqtgraph-0.10.0/.gitignore000066400000000000000000000021431300727121400176110ustar00rootroot00000000000000# Byte-compiled / optimized / DLL files __pycache__/ *.py[cod] # C extensions *.so # Distribution / packaging .Python env/ bin/ build/ develop-eggs/ dist/ eggs/ lib/ lib64/ parts/ sdist/ var/ *.egg-info/ .installed.cfg *.egg doc/_build # PyInstaller # Usually these files are written by a python script from a template # before PyInstaller builds the exe, so as to inject date/other infos into it. *.manifest *.spec # Installer logs pip-log.txt pip-delete-this-directory.txt # Unit test / coverage reports htmlcov/ .tox/ cover/ .coverage .cache nosetests.xml coverage.xml .coverage.* # Translations *.mo *.pot # Mr Developer .mr.developer.cfg .project .pydevproject # Rope .ropeproject # Django stuff: *.log *.pot # Sphinx documentation docs/_build/ #mac .DS_Store *~ #vim *.swp #pycharm .idea/* #Dolphin browser files .directory/ .directory #Binary data files *.volume *.am *.tiff *.tif *.dat *.DAT #generated documntation files doc/resource/api/generated/ # Enaml __enamlcache__/ # PyBuilder target/ # sphinx docs generated/ MANIFEST deb_build rtr.cvs # pytest parallel .coverage # ctags .tags* pyqtgraph-pyqtgraph-0.10.0/.mailmap000066400000000000000000000015711300727121400172460ustar00rootroot00000000000000Luke Campagnola Luke Campagnola <> Luke Campagnola Luke Campagnola Megan Kratz meganbkratz@gmail.com <> Megan Kratz Megan Kratz Megan Kratz Megan Kratz Megan Kratz Megan Kratz Megan Kratz Megan Kratz Megan Kratz Megan Kratz Megan Kratz Megan Kratz Ingo Breßler Ingo Breßler Ingo Breßler Ingo B. pyqtgraph-pyqtgraph-0.10.0/.travis.yml000066400000000000000000000145021300727121400177340ustar00rootroot00000000000000language: python sudo: false # Credit: Original .travis.yml lifted from VisPy # Here we use anaconda for 2.6 and 3.3, since it provides the simplest # interface for running different versions of Python. We could also use # it for 2.7, but the Ubuntu system has installable 2.7 Qt4-GL, which # allows for more complete testing. notifications: email: false virtualenv: system_site_packages: true env: # Enable python 2 and python 3 builds # Note that the 2.6 build doesn't get flake8, and runs old versions of # Pyglet and GLFW to make sure we deal with those correctly - PYTHON=2.6 QT=pyqt4 TEST=standard - PYTHON=2.7 QT=pyqt4 TEST=extra - PYTHON=2.7 QT=pyside TEST=standard - PYTHON=3.4 QT=pyqt5 TEST=standard # - PYTHON=3.4 QT=pyside TEST=standard # pyside isn't available for 3.4 with conda #- PYTHON=3.2 QT=pyqt5 TEST=standard before_install: - if [ ${TRAVIS_PYTHON_VERSION:0:1} == "2" ]; then wget http://repo.continuum.io/miniconda/Miniconda-3.5.5-Linux-x86_64.sh -O miniconda.sh; else wget http://repo.continuum.io/miniconda/Miniconda3-3.5.5-Linux-x86_64.sh -O miniconda.sh; fi - chmod +x miniconda.sh - ./miniconda.sh -b -p /home/travis/mc - export PATH=/home/travis/mc/bin:$PATH # not sure what is if block is for - if [ "${TRAVIS_PULL_REQUEST}" != "false" ]; then GIT_TARGET_EXTRA="+refs/heads/${TRAVIS_BRANCH}"; GIT_SOURCE_EXTRA="+refs/pull/${TRAVIS_PULL_REQUEST}/merge"; else GIT_TARGET_EXTRA=""; GIT_SOURCE_EXTRA=""; fi; # to aid in debugging - echo ${TRAVIS_BRANCH} - echo ${TRAVIS_REPO_SLUG} - echo ${GIT_TARGET_EXTRA} - echo ${GIT_SOURCE_EXTRA} install: - export GIT_FULL_HASH=`git rev-parse HEAD` - conda update conda --yes - conda create -n test_env python=${PYTHON} --yes - source activate test_env - conda install numpy pyopengl pytest flake8 six coverage --yes - echo ${QT} - echo ${TEST} - echo ${PYTHON} - if [ "${QT}" == "pyqt5" ]; then conda install pyqt --yes; fi; - if [ "${QT}" == "pyqt4" ]; then conda install pyqt=4 --yes; fi; - if [ "${QT}" == "pyside" ]; then conda install pyside --yes; fi; - pip install pytest-xdist # multi-thread py.test - pip install pytest-cov # add coverage stats # required for example testing on python 2.6 - if [ "${PYTHON}" == "2.6" ]; then pip install importlib; fi; # Debugging helpers - uname -a - cat /etc/issue - if [ "${PYTHON}" == "2.7" ]; then python --version; else python3 --version; fi; before_script: # We need to create a (fake) display on Travis, let's use a funny resolution - export DISPLAY=:99.0 - "sh -e /etc/init.d/xvfb start" - /sbin/start-stop-daemon --start --quiet --pidfile /tmp/custom_xvfb_99.pid --make-pidfile --background --exec /usr/bin/Xvfb -- :99 -screen 0 1400x900x24 -ac +extension GLX +render # Make sure everyone uses the correct python (this is handled by conda) - which python - python --version - pwd - ls # Help color output from each test - RESET='\033[0m'; RED='\033[00;31m'; GREEN='\033[00;32m'; YELLOW='\033[00;33m'; BLUE='\033[00;34m'; PURPLE='\033[00;35m'; CYAN='\033[00;36m'; WHITE='\033[00;37m'; start_test() { echo -e "${BLUE}======== Starting $1 ========${RESET}"; }; check_output() { ret=$?; if [ $ret == 0 ]; then echo -e "${GREEN}>>>>>> $1 passed <<<<<<${RESET}"; else echo -e "${RED}>>>>>> $1 FAILED <<<<<<${RESET}"; fi; return $ret; }; - if [ "${TEST}" == "extra" ]; then start_test "repo size check"; mkdir ~/repo-clone && cd ~/repo-clone && git init && git remote add -t ${TRAVIS_BRANCH} origin git://github.com/${TRAVIS_REPO_SLUG}.git && git fetch origin ${GIT_TARGET_EXTRA} && git checkout -qf FETCH_HEAD && git tag travis-merge-target && git gc --aggressive && TARGET_SIZE=`du -s . | sed -e "s/\t.*//"` && git pull origin ${GIT_SOURCE_EXTRA} && git gc --aggressive && MERGE_SIZE=`du -s . | sed -e "s/\t.*//"` && if [ "${MERGE_SIZE}" != "${TARGET_SIZE}" ]; then SIZE_DIFF=`expr \( ${MERGE_SIZE} - ${TARGET_SIZE} \)`; else SIZE_DIFF=0; fi; fi; script: - source activate test_env # Check system info - python -c "import pyqtgraph as pg; pg.systemInfo()" # Run unit tests - start_test "unit tests"; PYTHONPATH=. py.test --cov pyqtgraph -sv; check_output "unit tests"; - echo "test script finished. Current directory:" - pwd # check line endings - if [ "${TEST}" == "extra" ]; then start_test "line ending check"; ! find ./ -name "*.py" | xargs file | grep CRLF && ! find ./ -name "*.rst" | xargs file | grep CRLF; check_output "line ending check"; fi; # Check repo size does not expand too much - if [ "${TEST}" == "extra" ]; then start_test "repo size check"; echo -e "Estimated content size difference = ${SIZE_DIFF} kB" && test ${SIZE_DIFF} -lt 100; check_output "repo size check"; fi; # Check for style issues - if [ "${TEST}" == "extra" ]; then start_test "style check"; cd ~/repo-clone && git reset -q travis-merge-target && python setup.py style && check_output "style check"; fi; # Check install works - start_test "install test"; python setup.py --quiet install; check_output "install test"; # Check double-install fails # Note the bash -c is because travis strips off the ! otherwise. - start_test "double install test"; bash -c "! python setup.py --quiet install"; check_output "double install test"; # Check we can import pg - start_test "import test"; echo "import sys; print(sys.path)" | python && cd /; echo "import pyqtgraph.examples" | python; check_output "import test"; after_success: - cd /home/travis/build/pyqtgraph/pyqtgraph - pip install codecov --upgrade # add coverage integration service - codecov - pip install coveralls --upgrade # add another coverage integration service - coveralls pyqtgraph-pyqtgraph-0.10.0/CHANGELOG000066400000000000000000000504211300727121400170350ustar00rootroot00000000000000pyqtgraph-0.10.0 New Features: - PyQt5 support - Options for interpreting image data as either row-major or col-major - InfiniteLine and LinearRegionItem can have attached labels - DockArea: - Dock titles can be changed after creation - Added Dock.sigClosed - Added TextItem.setColor() - FillBetweenItem supports finite-connected curves (those that exclude nan/inf) API / behavior changes: - Improved ImageItem performance for some data types by scaling LUT instead of image - Change the defaut color kwarg to None in TextItem.setText() to avoid changing the color every time the text is changed. - FFT plots skip first sample if x-axis uses log scaling - Multiprocessing system adds bytes and unicode to the default list of no-proxy data types - Version number scheme changed to be PEP440-compliant (only affects installations from non- release git commits) Bugfixes: - Fix for numpy API change that caused casting errors for inplace operations - Fixed git version string generation on python3 - Fixed setting default values for out-of-bound points in pg.interpolateArray - Fixed plot downsampling bug on python 3 - Fixed invalid slice in ImageItem.getHistogram - DockArea: - Fixed adding Docks to DockArea after all Docks have been removed - Fixed DockArea save/restoreState when area is empty - Properly remove select box when export dialog is closed using window decorations - Remove all modifications to python builtins - Better Python 2.6 compatibility - Fix SpinBox decimals - Fixed numerous issues with ImageItem automatic downsampling - Fixed PlotItem average curves using incorrect stepMode - Fixed TableWidget eating key events - Prevent redundant updating of flowchart nodes with multiple inputs - Ignore wheel events in GraphicsView if mouse interaction is disabled - Correctly pass calls to QWidget.close() up the inheritance chain - ColorMap forces color inputs to be sorted - Fixed memory mapping for RemoteGraphicsView in OSX - Fixed QPropertyAnimation str/bytes handling - Fixed __version__ string update when using `setup.py install` with newer setuptools Maintenance: - Image comparison system for unit testing plus tests for several graphics items - Travis CI and coveralls/codecov support - Add examples to unit tests pyqtgraph-0.9.10 Fixed installation issues with more recent pip versions. pyqtgraph-0.9.9 API / behavior changes: - Dynamic import system abandoned; pg now uses static imports throughout. - Flowcharts and exporters have new pluggin systems - Version strings: - __init__.py in git repo now contains latest release version string (previously, only packaged releases had version strings). - installing from git checkout that does not correspond to a release commit will result in a more descriptive version string. - Speed improvements in functions.makeARGB - ImageItem is faster by avoiding makeQImage(transpose=True) - ComboBox will raise error when adding multiple items of the same name - ArrowItem.setStyle now updates style options rather than replacing them - Renamed GraphicsView signals to avoid collision with ViewBox signals that are wrapped in PlotWidget: sigRangeChanged => sigDeviceRangeChanged and sigTransformChanged => sigDeviceTransformChanged. - GLViewWidget.itemsAt() now measures y from top of widget to match mouse event position. - Made setPen() methods consistent throughout the package - Fix in GLScatterPlotItem requires that points will appear slightly more opaque (so you may need to adjust to lower alpha to achieve the same results) New Features: - Added ViewBox.setLimits() method - Adde ImageItem downsampling - New HDF5 example for working with very large datasets - Removed all dependency on scipy - Added Qt.loadUiType function for PySide - Simplified Profilers; can be activated with environmental variables - Added Dock.raiseDock() method - ComboBox updates: - Essentially a graphical interface to dict; all items have text and value - Assigns previously-selected text after list is cleared and repopulated - Get, set current value - Flowchart updates - Added Flowchart.sigChartChanged - Custom nodes may now be registered in sub-menu trees - ImageItem.getHistogram is more clever about constructing histograms - Added FillBetweenItem.setCurves() - MultiPlotWidget now has setMinimumPlotHeight method and displays scroll bar when plots do not fit inside the widget. - Added BarGraphItem.shape() to allow better mouse interaction - Added MeshData.cylinder - Added ViewBox.setBackgroundColor() and GLViewWidget.setBackgroundColor() - Utilities / debugging tools - Mutex used for tracing deadlocks - Color output on terminal - Multiprocess debugging colors messages by process - Stdout filter that colors text by thread - PeriodicTrace used to report deadlocks - Added AxisItem.setStyle() - Added configurable formatting for TableWidget - Added 'stepMode' argument to PlotDataItem() - Added ViewBox.invertX() - Docks now have optional close button - Added InfiniteLine.setHoverPen - Added GLVolumeItem.setData - Added PolyLineROI.setPoints, clearPoints, saveState, setState - Added ErrorBarItem.setData Bugfixes: - PlotCurveItem now has correct clicking behavior--clicks within a few px of the line will trigger a signal. - Fixes related to CSV exporter: - CSV headers include data names, if available - Exporter correctly handles items with no data - pg.plot() avoids creating empty data item - removed call to reduce() from exporter; not available in python 3 - Gave .name() methods to PlotDataItem, PlotCurveItem, and ScatterPlotItem - fixed ImageItem handling of rgb images - fixed makeARGB re-ordering of color channels - fixed unicode usage in AxisItem tick strings - fixed PlotCurveItem generating exceptions when data has length=0 - fixed ImageView.setImage only working once - PolyLineROI.setPen() now changes the pen of its segments as well - Prevent divide-by-zero in AxisItem - Major speedup when using ScatterPlotItem in pxMode - PlotCurveItem ignores clip-to-view when auto range is enabled - FillBetweenItem now forces PlotCurveItem to generate path - Fixed import errors and py3 issues in MultiPlotWidget - Isosurface works for arrays with shapes > 255 - Fixed ImageItem exception building histogram when image has only one value - Fixed MeshData exception caused when vertexes have no matching faces - Fixed GLViewWidget exception handler - Fixed unicode support in Dock - Fixed PySide crash caused by emitting signal from GraphicsObject.itemChange - Fixed possible infinite loop from FiniteCache - Allow images with NaN in ImageView - MeshData can generate edges from face-indexed vertexes - Fixed multiprocess deadlocks on windows - Fixed GLGridItem.setSize - Fixed parametertree.Parameter.sigValueChanging - Fixed AxisItem.__init__(showValues=False) - Fixed TableWidget append / sort issues - Fixed AxisItem not resizing text area when setTicks() is used - Removed a few cyclic references - Fixed Parameter 'readonly' option for bool, color, and text parameter types - Fixed alpha on GLScatterPlotItem spots (formerly maxed out at alpha=200) - Fixed a few bugs causing exit crashes pyqtgraph-0.9.8 2013-11-24 API / behavior changes: - ViewBox will auto-range when ImageItem changes shape - AxisItem: - Smarter about deciding which ticks get text - AxisItem.setScale(float) has the usual behavior, but .setScale(None) is deprecated. Instead use: AxisItem.enableAutoSIPrefix(bool) to enable/disable SI prefix scaling - Removed inf/nan checking from PlotDataItem and PlotCurveItem; improved performance New Features: - Support for dynamic downsampling and view clipping in PlotDataItem and PlotItem - Added 'connect' option to PlotDataItem and PlotCurveItem to affect which line segments are drawn - Support for FFT with non-uniform time sampling - Added BarGraphItem - OpenGL: - Added export methods to GLViewWidget - Wireframe meshes - GLLinePLotItem gets antialiasing, accepts array of colors - GLMeshItem accepts ShaderProgram or name of predefined program - Added GLBarGraphItem - LegendItem: - User-draggable - Allow custom ItemSamples - Symbol support - Support for removing items - ScatterPlotWidget, ColorMapWidget, and DataFilterWidget are stable - TableWidget: - Made numerically sortable - Added setEditable method - AxisItem ability to truncate axis lines at the last tick - arrayToQPath() added 'finite' connection mode which omits non-finite values from connections - pg.plot() and pg.PlotWidget() now accept background argument - Allow QtProcess without local QApplication - Support for dashing in mkPen() - Added Dock.close() - Added style options to flowchart connection lines - Added parentChanged and viewChanged hooks to GraphicsItem - Bidirectional pseudoScatter for beeswarm plots - Added exit() function for working around PyQt exit crashes - Added PolylineROI.getArrayRegion() Bugfixes: - Many Python 3 compatibility fixes - AxisItem: - Correctly handles scaling with values that are not power of 10 - Did not update grid line length when plot stretches - Fixed unicode handling in AxisItem label - ViewBox: - Overhauled to fix issues with aspect locking - ViewBox context menu elements are no longer deleted when using flowchart with pyside - Fixed view linking with inverted y axis - Prevent auto-range disabling when dragging with one mouse axis diabled - Ignore inf and nan when auto-ranging - ParameterTree: - fixed TextParameter editor disappearing after focus lost - ListParameter: allow unhashable types as parameter values. - Exporting: - ImageExporter correctly handles QBrush with style=NoBrush - SVGExporter text, gradients working correctly - SVGExporter correctly handles coordinate corrections for groups with mixed elements - ImageView: - Fixed auto-levelling when normalization options change - Added autoHistogramRange argument to setImage - ScatterPlotItem: - Fixed crashes caused by ScatterPlotItem - Fixed antialiasing - arrayToQPath performance improved for python 3 - Fixed makeQImage on many platforms (notably, on newer PyQt APIs) - Removed unnecessary scipy imports for faster import - GraphItem reports pixel margins to improve auto-range - Add backport ordereddict to repository; old OrderedDict class is removed - Corrected behavior of GraphicsView.setBackground - Fixed PySide bug listing image formats - Fixed QString -> str conversions in flowchart - Unicode file name support when exporting - Fixed MatplotlibWidget + PySide - Fixed 3D view updating after every scene change - Fixed handling of non-native dtypes when optimizing with weave - RemoteGraphicsView fixed for PyQt 4.10, Python 3 - Fixed GLLinePlotItem line width option - HistogramLUTWidget obeys default background color - ScaleBar complete rewrite - GraphItem obeys antialiasing flag - Workaround for PySide/QByteArray memory leak - Fixed example --test on windows, python3 - Luke finished dissertation pyqtgraph-0.9.7 2013-02-25 Bugfixes: - ArrowItem auto range now works correctly - Dock drag/drop fixed on PySide - Made padding behavior consistent across ViewBox methods - Fixed MeshData / python2.6 incompatibility - Fixed ScatterPlotItem.setSize and .setPointData - Workaround for PySide bug; GradientEditor fixed - Prefer initially selecting PlotItem rather then ViewBox when exporting - Fixed python3 import error with flowcharts Cleaned up examples, made code editable from example loader Minor documentation updates Features: - Added GraphItem class for displaying networks/trees - Added ColorMap class for mapping linear gradients and generating lookup tables (Provides gradient editor functionality without the GUI) - Added ColorMapWidget for complex user-defined color mapping - Added ScatterPlotWidget for exploring relationships in multi-column tables - Added ErrorBarItem - SVG and image exporters can now copy to clipboard - PlotItem gets new methods: addLine, setLabels, and listDataItems - AxisItem gets setTickFont method - Added functions.arrayToQPath, shared between GraphItem and PlotCurveItem - Added gradient editors to parametertree - Expanded documentation, added beginning of Qt crash course Bugfixes: - Fixed auto-ranging bugs: ViewBox now properly handles pixel-padding around data items - ViewBox ignores bounds of zoom-rect when auto ranging - Fixed AxisItem artifacts - Fixed GraphicsItem.pixelVector caching bugs and simplified workaround for fp-precision errors - LinearRegionItem.hoverEvent obeys 'movable' flag - Fixed PlotDataItem nan masking bugs - Workaround for segmentation fault in QPainter.drawPixmapFragments - multiprocess and RemoteGraphicsView work correctly in Windows. - Expanded python 3 support - Silenced weave errors by default - Fixed " 'win' in sys.platform " occurrences matching 'darwin' (duh) - Workaround for change in QImage API (PyQt 4.9.6) - Fixed axis ordering bug in GLScatterPlotItem pyqtgraph-0.9.6 2013-02-14 Features: - Added GraphItem class for displaying networks/trees - Added ColorMap class for mapping linear gradients and generating lookup tables (Provides gradient editor functionality without the GUI) - Added ColorMapWidget for complex user-defined color mapping - Added ScatterPlotWidget for exploring relationships in multi-column tables - Added ErrorBarItem - SVG and image exporters can now copy to clipboard - PlotItem gets new methods: addLine, setLabels, and listDataItems - AxisItem gets setTickFont method - Added functions.arrayToQPath, shared between GraphItem and PlotCurveItem - Added gradient editors to parametertree - Expanded documentation, added beginning of Qt crash course Bugfixes: - Fixed auto-ranging bugs: ViewBox now properly handles pixel-padding around data items - ViewBox ignores bounds of zoom-rect when auto ranging - Fixed AxisItem artifacts - Fixed GraphicsItem.pixelVector caching bugs and simplified workaround for fp-precision errors - LinearRegionItem.hoverEvent obeys 'movable' flag - Fixed PlotDataItem nan masking bugs - Workaround for segmentation fault in QPainter.drawPixmapFragments - multiprocess and RemoteGraphicsView work correctly in Windows. - Expanded python 3 support - Silenced weave errors by default - Fixed " 'win' in sys.platform " occurrences matching 'darwin' (duh) - Workaround for change in QImage API (PyQt 4.9.6) - Fixed axis ordering bug in GLScatterPlotItem Plotting performance improvements: - AxisItem shows fewer tick levels in some cases. - Lots of boundingRect and dataBounds caching (improves ViewBox auto-range performance, especially with multiple plots) - GraphicsScene avoids testing for hover intersections with non-hoverable items (much less slowdown when moving mouse over plots) Improved performance for remote plotting: - reduced cost of transferring arrays between processes (pickle is too slow) - avoid unnecessary synchronous calls Added RemoteSpeedTest example pyqtgraph-0.9.5 2013-01-11 Plotting performance improvements: - AxisItem shows fewer tick levels in some cases. - Lots of boundingRect and dataBounds caching (improves ViewBox auto-range performance, especially with multiple plots) - GraphicsScene avoids testing for hover intersections with non-hoverable items (much less slowdown when moving mouse over plots) Improved performance for remote plotting: - reduced cost of transferring arrays between processes (pickle is too slow) - avoid unnecessary synchronous calls Added RemoteSpeedTest example Documentation: - Added documentation on export system - Added flowchart documentation and custom node example Bugfixes: - prevent PlotCurveItem drawing shadow when unnecessary - deprecated flowchart.Node.__getattr__ -- causes too many problems. pyqtgraph-0.9.4 2013-01-07 Documentation: - Added documentation on export system - Added flowchart documentation and custom node example Bugfixes: - prevent PlotCurveItem drawing shadow when unnecessary - deprecated flowchart.Node.__getattr__ -- causes too many problems. Bugfix: prevent adding invalid entry to sys.path when running examples pyqtgraph-0.9.3 2012-12-29 Bugfix: prevent adding invalid entry to sys.path when running examples Bugfixes: - SVG export text elements use generic font-family as backup, corrected item transformation issues - Fixed RuntimeError caused when clearing item hierarchies from ViewBox - Fixed example execution bug Packaging maintenance: - Added missing files to MANIFEST.in, fixed setup.py package detection - Added debian control files for building source packages - Fixed version numbering in doc, __init__.py pyqtgraph-0.9.2 2012-12-29 Bugfixes: - SVG export text elements use generic font-family as backup, corrected item transformation issues - Fixed RuntimeError caused when clearing item hierarchies from ViewBox - Fixed example execution bug Packaging maintenance: - Added missing files to MANIFEST.in, fixed setup.py package detection - Added debian control files for building source packages - Fixed version numbering in doc, __init__.py pyqtgraph-0.9.1 2012-12-27 Removed incorrect version numbers Correction to setup.py - use install_requires to inform pip of dependencies. Fixed doc version (again) Added debian control files bugfixes for new package structure pyqtgraph-0.9.0 2012-12-27 * Initial release. pyqtgraph-pyqtgraph-0.10.0/CONTRIBUTING.txt000066400000000000000000000046141300727121400202760ustar00rootroot00000000000000Contributions to pyqtgraph are welcome! Please use the following guidelines when preparing changes: * The preferred method for submitting changes is by github pull request against the "develop" branch. If this is inconvenient, don't hesitate to submit by other means. * Pull requests should include only a focused and related set of changes. Mixed features and unrelated changes (such as .gitignore) will usually be rejected. * For major changes, it is recommended to discuss your plans on the mailing list or in a github issue before putting in too much effort. * Along these lines, please note that pyqtgraph.opengl will be deprecated soon and replaced with VisPy. * Writing proper documentation and unit tests is highly encouraged. PyQtGraph uses nose / py.test style testing, so tests should usually be included in a tests/ directory adjacent to the relevant code. * Documentation is generated with sphinx; please check that docstring changes compile correctly. * Style guidelines: * PyQtGraph prefers PEP8 for most style issues, but this is not enforced rigorously as long as the code is clean and readable. * Use `python setup.py style` to see whether your code follows the mandatory style guidelines checked by flake8. * Exception 1: All variable names should use camelCase rather than underscore_separation. This is done for consistency with Qt * Exception 2: Function docstrings use ReStructuredText tables for describing arguments: ``` ============== ======================================================== **Arguments:** argName1 (type) Description of argument argName2 (type) Description of argument. Longer descriptions must be wrapped within the column guidelines defined by the "====" header and footer. ============== ======================================================== ``` QObject subclasses that implement new signals should also describe these in a similar table. * Setting up a test environment. Tests for a module should ideally cover all code in that module, i.e., statement coverage should be at 100%. To measure the test coverage, install py.test, pytest-cov and pytest-xdist. Then run 'py.test --cov -n 4' to run the test suite with coverage on 4 cores. pyqtgraph-pyqtgraph-0.10.0/LICENSE.txt000066400000000000000000000022111300727121400174400ustar00rootroot00000000000000Copyright (c) 2012 University of North Carolina at Chapel Hill Luke Campagnola ('luke.campagnola@%s.com' % 'gmail') The MIT License Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. pyqtgraph-pyqtgraph-0.10.0/MANIFEST.in000066400000000000000000000004531300727121400173610ustar00rootroot00000000000000recursive-include pyqtgraph *.py *.ui *.m README.* *.txt recursive-include examples *.py *.ui *.gz *.cfg recursive-include doc *.rst *.py *.svg *.png recursive-include doc/build/html * recursive-include tools * include doc/Makefile doc/make.bat README.md LICENSE.txt CHANGELOG global-exclude *.pyc pyqtgraph-pyqtgraph-0.10.0/README.md000066400000000000000000000047331300727121400171070ustar00rootroot00000000000000[![Build Status](https://travis-ci.org/pyqtgraph/pyqtgraph.svg?branch=develop)](https://travis-ci.org/pyqtgraph/pyqtgraph) [![codecov.io](http://codecov.io/github/pyqtgraph/pyqtgraph/coverage.svg?branch=develop)](http://codecov.io/github/pyqtgraph/pyqtgraph?branch=develop) PyQtGraph ========= A pure-Python graphics library for PyQt/PySide Copyright 2012 Luke Campagnola, University of North Carolina at Chapel Hill Maintainer ---------- * Luke Campagnola Contributors ------------ * Megan Kratz * Paul Manis * Ingo Breßler * Christian Gavin * Michael Cristopher Hogg * Ulrich Leutner * Felix Schill * Guillaume Poulin * Antony Lee * Mattias Põldaru * Thomas S. * Fabio Zadrozny * Mikhail Terekhov * Pietro Zambelli * Stefan Holzmann * Nicholas TJ * John David Reaver * David Kaplan * Martin Fitzpatrick * Daniel Lidstrom * Eric Dill * Vincent LeSaux Requirements ------------ * PyQt 4.7+, PySide, or PyQt5 * python 2.6, 2.7, or 3.x * NumPy * For 3D graphics: pyopengl and qt-opengl * Known to run on Windows, Linux, and Mac. Support ------- Post at the [mailing list / forum](https://groups.google.com/forum/?fromgroups#!forum/pyqtgraph) Installation Methods -------------------- * To use with a specific project, simply copy the pyqtgraph subdirectory anywhere that is importable from your project. PyQtGraph may also be used as a git subtree by cloning the git-core repository from github. * To install system-wide from source distribution: `$ python setup.py install` * For installation packages, see the website (pyqtgraph.org) * On debian-like systems, pyqtgraph requires the following packages: python-numpy, python-qt4 | python-pyside For 3D support: python-opengl, python-qt4-gl | python-pyside.qtopengl Documentation ------------- There are many examples; run `python -m pyqtgraph.examples` for a menu. Some (incomplete) documentation exists at this time. * Easiest place to get documentation is at * If you acquired this code as a .tar.gz file from the website, then you can also look in doc/html. * If you acquired this code via GitHub, then you can build the documentation using sphinx. From the documentation directory, run: `$ make html` Please feel free to pester Luke or post to the forum if you need a specific section of documentation to be expanded. pyqtgraph-pyqtgraph-0.10.0/doc/000077500000000000000000000000001300727121400163665ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/doc/Makefile000066400000000000000000000107761300727121400200410ustar00rootroot00000000000000# Makefile for Sphinx documentation # # You can set these variables from the command line. SPHINXOPTS = SPHINXBUILD = sphinx-build PAPER = BUILDDIR = build # Internal variables. PAPEROPT_a4 = -D latex_paper_size=a4 PAPEROPT_letter = -D latex_paper_size=letter ALLSPHINXOPTS = -d $(BUILDDIR)/doctrees $(PAPEROPT_$(PAPER)) $(SPHINXOPTS) source .PHONY: help clean html dirhtml singlehtml pickle json htmlhelp qthelp devhelp epub latex latexpdf text man changes linkcheck doctest help: @echo "Please use \`make ' where is one of" @echo " html to make standalone HTML files" @echo " dirhtml to make HTML files named index.html in directories" @echo " singlehtml to make a single large HTML file" @echo " pickle to make pickle files" @echo " json to make JSON files" @echo " htmlhelp to make HTML files and a HTML help project" @echo " qthelp to make HTML files and a qthelp project" @echo " devhelp to make HTML files and a Devhelp project" @echo " epub to make an epub" @echo " latex to make LaTeX files, you can set PAPER=a4 or PAPER=letter" @echo " latexpdf to make LaTeX files and run them through pdflatex" @echo " text to make text files" @echo " man to make manual pages" @echo " changes to make an overview of all changed/added/deprecated items" @echo " linkcheck to check all external links for integrity" @echo " doctest to run all doctests embedded in the documentation (if enabled)" clean: -rm -rf $(BUILDDIR)/* html: $(SPHINXBUILD) -b html $(ALLSPHINXOPTS) $(BUILDDIR)/html @echo @echo "Build finished. The HTML pages are in $(BUILDDIR)/html." dirhtml: $(SPHINXBUILD) -b dirhtml $(ALLSPHINXOPTS) $(BUILDDIR)/dirhtml @echo @echo "Build finished. The HTML pages are in $(BUILDDIR)/dirhtml." singlehtml: $(SPHINXBUILD) -b singlehtml $(ALLSPHINXOPTS) $(BUILDDIR)/singlehtml @echo @echo "Build finished. The HTML page is in $(BUILDDIR)/singlehtml." pickle: $(SPHINXBUILD) -b pickle $(ALLSPHINXOPTS) $(BUILDDIR)/pickle @echo @echo "Build finished; now you can process the pickle files." json: $(SPHINXBUILD) -b json $(ALLSPHINXOPTS) $(BUILDDIR)/json @echo @echo "Build finished; now you can process the JSON files." htmlhelp: $(SPHINXBUILD) -b htmlhelp $(ALLSPHINXOPTS) $(BUILDDIR)/htmlhelp @echo @echo "Build finished; now you can run HTML Help Workshop with the" \ ".hhp project file in $(BUILDDIR)/htmlhelp." qthelp: $(SPHINXBUILD) -b qthelp $(ALLSPHINXOPTS) $(BUILDDIR)/qthelp @echo @echo "Build finished; now you can run "qcollectiongenerator" with the" \ ".qhcp project file in $(BUILDDIR)/qthelp, like this:" @echo "# qcollectiongenerator $(BUILDDIR)/qthelp/pyqtgraph.qhcp" @echo "To view the help file:" @echo "# assistant -collectionFile $(BUILDDIR)/qthelp/pyqtgraph.qhc" devhelp: $(SPHINXBUILD) -b devhelp $(ALLSPHINXOPTS) $(BUILDDIR)/devhelp @echo @echo "Build finished." @echo "To view the help file:" @echo "# mkdir -p $$HOME/.local/share/devhelp/pyqtgraph" @echo "# ln -s $(BUILDDIR)/devhelp $$HOME/.local/share/devhelp/pyqtgraph" @echo "# devhelp" epub: $(SPHINXBUILD) -b epub $(ALLSPHINXOPTS) $(BUILDDIR)/epub @echo @echo "Build finished. The epub file is in $(BUILDDIR)/epub." latex: $(SPHINXBUILD) -b latex $(ALLSPHINXOPTS) $(BUILDDIR)/latex @echo @echo "Build finished; the LaTeX files are in $(BUILDDIR)/latex." @echo "Run \`make' in that directory to run these through (pdf)latex" \ "(use \`make latexpdf' here to do that automatically)." latexpdf: $(SPHINXBUILD) -b latex $(ALLSPHINXOPTS) $(BUILDDIR)/latex @echo "Running LaTeX files through pdflatex..." make -C $(BUILDDIR)/latex all-pdf @echo "pdflatex finished; the PDF files are in $(BUILDDIR)/latex." text: $(SPHINXBUILD) -b text $(ALLSPHINXOPTS) $(BUILDDIR)/text @echo @echo "Build finished. The text files are in $(BUILDDIR)/text." man: $(SPHINXBUILD) -b man $(ALLSPHINXOPTS) $(BUILDDIR)/man @echo @echo "Build finished. The manual pages are in $(BUILDDIR)/man." changes: $(SPHINXBUILD) -b changes $(ALLSPHINXOPTS) $(BUILDDIR)/changes @echo @echo "The overview file is in $(BUILDDIR)/changes." linkcheck: $(SPHINXBUILD) -b linkcheck $(ALLSPHINXOPTS) $(BUILDDIR)/linkcheck @echo @echo "Link check complete; look for any errors in the above output " \ "or in $(BUILDDIR)/linkcheck/output.txt." doctest: $(SPHINXBUILD) -b doctest $(ALLSPHINXOPTS) $(BUILDDIR)/doctest @echo "Testing of doctests in the sources finished, look at the " \ "results in $(BUILDDIR)/doctest/output.txt." pyqtgraph-pyqtgraph-0.10.0/doc/extensions/000077500000000000000000000000001300727121400205655ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/doc/extensions/qt_doc.py000066400000000000000000000112671300727121400224170ustar00rootroot00000000000000""" Extension for building Qt-like documentation. - Method lists preceding the actual method documentation - Inherited members documented separately - Members inherited from Qt have links to qt-project documentation - Signal documentation """ def setup(app): # probably we will be making a wrapper around autodoc app.setup_extension('sphinx.ext.autodoc') # would it be useful to define a new domain? #app.add_domain(QtDomain) ## Add new configuration options app.add_config_value('todo_include_todos', False, False) ## Nodes are the basic objects representing documentation directives ## and roles app.add_node(Todolist) app.add_node(Todo, html=(visit_todo_node, depart_todo_node), latex=(visit_todo_node, depart_todo_node), text=(visit_todo_node, depart_todo_node)) ## New directives like ".. todo:" app.add_directive('todo', TodoDirective) app.add_directive('todolist', TodolistDirective) ## Connect callbacks to specific hooks in the build process app.connect('doctree-resolved', process_todo_nodes) app.connect('env-purge-doc', purge_todos) from docutils import nodes from sphinx.util.compat import Directive from sphinx.util.compat import make_admonition # Just a general node class Todolist(nodes.General, nodes.Element): pass # .. and its directive class TodolistDirective(Directive): # all directives have 'run' method that returns a list of nodes def run(self): return [Todolist('')] # Admonition classes are like notes or warnings class Todo(nodes.Admonition, nodes.Element): pass def visit_todo_node(self, node): self.visit_admonition(node) def depart_todo_node(self, node): self.depart_admonition(node) class TodoDirective(Directive): # this enables content in the directive has_content = True def run(self): env = self.state.document.settings.env # create a new target node for linking to targetid = "todo-%d" % env.new_serialno('todo') targetnode = nodes.target('', '', ids=[targetid]) # make the admonition node ad = make_admonition(Todo, self.name, [('Todo')], self.options, self.content, self.lineno, self.content_offset, self.block_text, self.state, self.state_machine) # store a handle in a global list of all todos if not hasattr(env, 'todo_all_todos'): env.todo_all_todos = [] env.todo_all_todos.append({ 'docname': env.docname, 'lineno': self.lineno, 'todo': ad[0].deepcopy(), 'target': targetnode, }) # return both the linking target and the node itself return [targetnode] + ad # env data is persistent across source files so we purge whenever the source file has changed. def purge_todos(app, env, docname): if not hasattr(env, 'todo_all_todos'): return env.todo_all_todos = [todo for todo in env.todo_all_todos if todo['docname'] != docname] # called at the end of resolving phase; we will convert temporary nodes # into finalized nodes def process_todo_nodes(app, doctree, fromdocname): if not app.config.todo_include_todos: for node in doctree.traverse(Todo): node.parent.remove(node) # Replace all todolist nodes with a list of the collected todos. # Augment each todo with a backlink to the original location. env = app.builder.env for node in doctree.traverse(Todolist): if not app.config.todo_include_todos: node.replace_self([]) continue content = [] for todo_info in env.todo_all_todos: para = nodes.paragraph() filename = env.doc2path(todo_info['docname'], base=None) description = ( ('(The original entry is located in %s, line %d and can be found ') % (filename, todo_info['lineno'])) para += nodes.Text(description, description) # Create a reference newnode = nodes.reference('', '') innernode = nodes.emphasis(('here'), ('here')) newnode['refdocname'] = todo_info['docname'] newnode['refuri'] = app.builder.get_relative_uri( fromdocname, todo_info['docname']) newnode['refuri'] += '#' + todo_info['target']['refid'] newnode.append(innernode) para += newnode para += nodes.Text('.)', '.)') # Insert into the todolist content.append(todo_info['todo']) content.append(para) node.replace_self(content) pyqtgraph-pyqtgraph-0.10.0/doc/listmissing.py000066400000000000000000000007431300727121400213110ustar00rootroot00000000000000import os dirs = [ ('graphicsItems', 'graphicsItems'), ('3dgraphics', 'opengl/items'), ('widgets', 'widgets'), ] path = os.path.join(os.path.dirname(os.path.abspath(__file__)), '..') for a, b in dirs: rst = [os.path.splitext(x)[0].lower() for x in os.listdir(os.path.join(path, 'documentation', 'source', a))] py = [os.path.splitext(x)[0].lower() for x in os.listdir(os.path.join(path, b))] print(a) for x in set(py) - set(rst): print( " ", x) pyqtgraph-pyqtgraph-0.10.0/doc/make.bat000066400000000000000000000100241300727121400177700ustar00rootroot00000000000000@ECHO OFF REM Command file for Sphinx documentation if "%SPHINXBUILD%" == "" ( set SPHINXBUILD=sphinx-build ) set BUILDDIR=build set ALLSPHINXOPTS=-d %BUILDDIR%/doctrees %SPHINXOPTS% source if NOT "%PAPER%" == "" ( set ALLSPHINXOPTS=-D latex_paper_size=%PAPER% %ALLSPHINXOPTS% ) if "%1" == "" goto help if "%1" == "help" ( :help echo.Please use `make ^` where ^ is one of echo. html to make standalone HTML files echo. dirhtml to make HTML files named index.html in directories echo. singlehtml to make a single large HTML file echo. pickle to make pickle files echo. json to make JSON files echo. htmlhelp to make HTML files and a HTML help project echo. qthelp to make HTML files and a qthelp project echo. devhelp to make HTML files and a Devhelp project echo. epub to make an epub echo. latex to make LaTeX files, you can set PAPER=a4 or PAPER=letter echo. text to make text files echo. man to make manual pages echo. changes to make an overview over all changed/added/deprecated items echo. linkcheck to check all external links for integrity echo. doctest to run all doctests embedded in the documentation if enabled goto end ) if "%1" == "clean" ( for /d %%i in (%BUILDDIR%\*) do rmdir /q /s %%i del /q /s %BUILDDIR%\* goto end ) if "%1" == "html" ( %SPHINXBUILD% -b html %ALLSPHINXOPTS% %BUILDDIR%/html echo. echo.Build finished. The HTML pages are in %BUILDDIR%/html. goto end ) if "%1" == "dirhtml" ( %SPHINXBUILD% -b dirhtml %ALLSPHINXOPTS% %BUILDDIR%/dirhtml echo. echo.Build finished. The HTML pages are in %BUILDDIR%/dirhtml. goto end ) if "%1" == "singlehtml" ( %SPHINXBUILD% -b singlehtml %ALLSPHINXOPTS% %BUILDDIR%/singlehtml echo. echo.Build finished. The HTML pages are in %BUILDDIR%/singlehtml. goto end ) if "%1" == "pickle" ( %SPHINXBUILD% -b pickle %ALLSPHINXOPTS% %BUILDDIR%/pickle echo. echo.Build finished; now you can process the pickle files. goto end ) if "%1" == "json" ( %SPHINXBUILD% -b json %ALLSPHINXOPTS% %BUILDDIR%/json echo. echo.Build finished; now you can process the JSON files. goto end ) if "%1" == "htmlhelp" ( %SPHINXBUILD% -b htmlhelp %ALLSPHINXOPTS% %BUILDDIR%/htmlhelp echo. echo.Build finished; now you can run HTML Help Workshop with the ^ .hhp project file in %BUILDDIR%/htmlhelp. goto end ) if "%1" == "qthelp" ( %SPHINXBUILD% -b qthelp %ALLSPHINXOPTS% %BUILDDIR%/qthelp echo. echo.Build finished; now you can run "qcollectiongenerator" with the ^ .qhcp project file in %BUILDDIR%/qthelp, like this: echo.^> qcollectiongenerator %BUILDDIR%\qthelp\pyqtgraph.qhcp echo.To view the help file: echo.^> assistant -collectionFile %BUILDDIR%\qthelp\pyqtgraph.ghc goto end ) if "%1" == "devhelp" ( %SPHINXBUILD% -b devhelp %ALLSPHINXOPTS% %BUILDDIR%/devhelp echo. echo.Build finished. goto end ) if "%1" == "epub" ( %SPHINXBUILD% -b epub %ALLSPHINXOPTS% %BUILDDIR%/epub echo. echo.Build finished. The epub file is in %BUILDDIR%/epub. goto end ) if "%1" == "latex" ( %SPHINXBUILD% -b latex %ALLSPHINXOPTS% %BUILDDIR%/latex echo. echo.Build finished; the LaTeX files are in %BUILDDIR%/latex. goto end ) if "%1" == "text" ( %SPHINXBUILD% -b text %ALLSPHINXOPTS% %BUILDDIR%/text echo. echo.Build finished. The text files are in %BUILDDIR%/text. goto end ) if "%1" == "man" ( %SPHINXBUILD% -b man %ALLSPHINXOPTS% %BUILDDIR%/man echo. echo.Build finished. The manual pages are in %BUILDDIR%/man. goto end ) if "%1" == "changes" ( %SPHINXBUILD% -b changes %ALLSPHINXOPTS% %BUILDDIR%/changes echo. echo.The overview file is in %BUILDDIR%/changes. goto end ) if "%1" == "linkcheck" ( %SPHINXBUILD% -b linkcheck %ALLSPHINXOPTS% %BUILDDIR%/linkcheck echo. echo.Link check complete; look for any errors in the above output ^ or in %BUILDDIR%/linkcheck/output.txt. goto end ) if "%1" == "doctest" ( %SPHINXBUILD% -b doctest %ALLSPHINXOPTS% %BUILDDIR%/doctest echo. echo.Testing of doctests in the sources finished, look at the ^ results in %BUILDDIR%/doctest/output.txt. goto end ) :end pyqtgraph-pyqtgraph-0.10.0/doc/source/000077500000000000000000000000001300727121400176665ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/doc/source/3dgraphics.rst000066400000000000000000000025211300727121400224470ustar00rootroot000000000000003D Graphics =========== PyQtGraph uses OpenGL to provide a 3D scenegraph system. This system is functional but still early in development. Current capabilities include: * 3D view widget with zoom/rotate controls (mouse drag and wheel) * Scenegraph allowing items to be added/removed from scene with per-item transformations and parent/child relationships. * Triangular meshes * Basic mesh computation functions: isosurfaces, per-vertex normals * Volumetric rendering item * Grid/axis items See the :doc:`API Reference ` and the Volumetric (GLVolumeItem.py) and Isosurface (GLMeshItem.py) examples for more information. Basic usage example:: ## build a QApplication before building other widgets import pyqtgraph as pg pg.mkQApp() ## make a widget for displaying 3D objects import pyqtgraph.opengl as gl view = gl.GLViewWidget() view.show() ## create three grids, add each to the view xgrid = gl.GLGridItem() ygrid = gl.GLGridItem() zgrid = gl.GLGridItem() view.addItem(xgrid) view.addItem(ygrid) view.addItem(zgrid) ## rotate x and y grids to face the correct direction xgrid.rotate(90, 0, 1, 0) ygrid.rotate(90, 1, 0, 0) ## scale each grid differently xgrid.scale(0.2, 0.1, 0.1) ygrid.scale(0.2, 0.1, 0.1) zgrid.scale(0.1, 0.2, 0.1) pyqtgraph-pyqtgraph-0.10.0/doc/source/3dgraphics/000077500000000000000000000000001300727121400217155ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/doc/source/3dgraphics/glaxisitem.rst000066400000000000000000000002131300727121400246110ustar00rootroot00000000000000GLAxisItem ========== .. autoclass:: pyqtgraph.opengl.GLAxisItem :members: .. automethod:: pyqtgraph.opengl.GLAxisItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/3dgraphics/glgraphicsitem.rst000066400000000000000000000002711300727121400254510ustar00rootroot00000000000000GLGraphicsItem ============== .. autoclass:: pyqtgraph.opengl.GLGraphicsItem.GLGraphicsItem :members: .. automethod:: pyqtgraph.opengl.GLGraphicsItem.GLGraphicsItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/3dgraphics/glgriditem.rst000066400000000000000000000002131300727121400245720ustar00rootroot00000000000000GLGridItem ========== .. autoclass:: pyqtgraph.opengl.GLGridItem :members: .. automethod:: pyqtgraph.opengl.GLGridItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/3dgraphics/glimageitem.rst000066400000000000000000000002171300727121400247330ustar00rootroot00000000000000GLImageItem =========== .. autoclass:: pyqtgraph.opengl.GLImageItem :members: .. automethod:: pyqtgraph.opengl.GLImageItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/3dgraphics/gllineplotitem.rst000066400000000000000000000002331300727121400254750ustar00rootroot00000000000000GLLinePlotItem ============== .. autoclass:: pyqtgraph.opengl.GLLinePlotItem :members: .. automethod:: pyqtgraph.opengl.GLLinePlotItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/3dgraphics/glmeshitem.rst000066400000000000000000000002131300727121400246010ustar00rootroot00000000000000GLMeshItem ========== .. autoclass:: pyqtgraph.opengl.GLMeshItem :members: .. automethod:: pyqtgraph.opengl.GLMeshItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/3dgraphics/glscatterplotitem.rst000066400000000000000000000002471300727121400262200ustar00rootroot00000000000000GLScatterPlotItem ================= .. autoclass:: pyqtgraph.opengl.GLScatterPlotItem :members: .. automethod:: pyqtgraph.opengl.GLScatterPlotItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/3dgraphics/glsurfaceplotitem.rst000066400000000000000000000002471300727121400262030ustar00rootroot00000000000000GLSurfacePlotItem ================= .. autoclass:: pyqtgraph.opengl.GLSurfacePlotItem :members: .. automethod:: pyqtgraph.opengl.GLSurfacePlotItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/3dgraphics/glviewwidget.rst000066400000000000000000000002231300727121400251450ustar00rootroot00000000000000GLViewWidget ============ .. autoclass:: pyqtgraph.opengl.GLViewWidget :members: .. automethod:: pyqtgraph.opengl.GLViewWidget.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/3dgraphics/glvolumeitem.rst000066400000000000000000000002231300727121400251550ustar00rootroot00000000000000GLVolumeItem ============ .. autoclass:: pyqtgraph.opengl.GLVolumeItem :members: .. automethod:: pyqtgraph.opengl.GLVolumeItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/3dgraphics/index.rst000066400000000000000000000017221300727121400235600ustar00rootroot00000000000000PyQtGraph's 3D Graphics System ============================== The 3D graphics system in pyqtgraph is composed of a :class:`view widget ` and several graphics items (all subclasses of :class:`GLGraphicsItem `) which can be added to a view widget. **Note 1:** pyqtgraph.opengl is based on the deprecated OpenGL fixed-function pipeline. Although it is currently a functioning system, it is likely to be superceded in the future by `VisPy `_. **Note 2:** use of this system requires python-opengl bindings. Linux users should install the python-opengl packages from their distribution. Windows/OSX users can download from ``_. Contents: .. toctree:: :maxdepth: 2 glviewwidget glgriditem glsurfaceplotitem glvolumeitem glimageitem glmeshitem gllineplotitem glaxisitem glgraphicsitem glscatterplotitem meshdata pyqtgraph-pyqtgraph-0.10.0/doc/source/3dgraphics/meshdata.rst000066400000000000000000000002031300727121400242300ustar00rootroot00000000000000MeshData ======== .. autoclass:: pyqtgraph.opengl.MeshData :members: .. automethod:: pyqtgraph.opengl.MeshData.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/apireference.rst000066400000000000000000000003701300727121400230500ustar00rootroot00000000000000API Reference ============= Contents: .. toctree:: :maxdepth: 2 config_options functions graphicsItems/index widgets/index 3dgraphics/index colormap parametertree/index graphicsscene/index flowchart/index pyqtgraph-pyqtgraph-0.10.0/doc/source/colormap.rst000066400000000000000000000001651300727121400222360ustar00rootroot00000000000000ColorMap ======== .. autoclass:: pyqtgraph.ColorMap :members: .. automethod:: pyqtgraph.ColorMap.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/conf.py000066400000000000000000000157561300727121400212030ustar00rootroot00000000000000# -*- coding: utf-8 -*- # # pyqtgraph documentation build configuration file, created by # sphinx-quickstart on Fri Nov 18 19:33:12 2011. # # This file is execfile()d with the current directory set to its containing dir. # # Note that not all possible configuration values are present in this # autogenerated file. # # All configuration values have a default; values that are commented out # serve to show the default. import sys, os # If extensions (or modules to document with autodoc) are in another directory, # add these directories to sys.path here. If the directory is relative to the # documentation root, use os.path.abspath to make it absolute, like shown here. path = os.path.dirname(os.path.abspath(__file__)) sys.path.insert(0, os.path.join(path, '..', '..')) sys.path.insert(0, os.path.join(path, '..', 'extensions')) # -- General configuration ----------------------------------------------------- # If your documentation needs a minimal Sphinx version, state it here. #needs_sphinx = '1.0' # Add any Sphinx extension module names here, as strings. They can be extensions # coming with Sphinx (named 'sphinx.ext.*') or your custom ones. extensions = ['sphinx.ext.autodoc', 'sphinx.ext.viewcode'] # Add any paths that contain templates here, relative to this directory. templates_path = ['_templates'] # The suffix of source filenames. source_suffix = '.rst' # The encoding of source files. #source_encoding = 'utf-8-sig' # The master toctree document. master_doc = 'index' # General information about the project. project = 'pyqtgraph' copyright = '2011, Luke Campagnola' # The version info for the project you're documenting, acts as replacement for # |version| and |release|, also used in various other places throughout the # built documents. # # The short X.Y version. version = '0.10.0' # The full version, including alpha/beta/rc tags. release = '0.10.0' # The language for content autogenerated by Sphinx. Refer to documentation # for a list of supported languages. #language = None # There are two options for replacing |today|: either, you set today to some # non-false value, then it is used: #today = '' # Else, today_fmt is used as the format for a strftime call. #today_fmt = '%B %d, %Y' # List of patterns, relative to source directory, that match files and # directories to ignore when looking for source files. exclude_patterns = [] # The reST default role (used for this markup: `text`) to use for all documents. #default_role = None # If true, '()' will be appended to :func: etc. cross-reference text. #add_function_parentheses = True # If true, the current module name will be prepended to all description # unit titles (such as .. function::). #add_module_names = True # If true, sectionauthor and moduleauthor directives will be shown in the # output. They are ignored by default. #show_authors = False # The name of the Pygments (syntax highlighting) style to use. pygments_style = 'sphinx' # A list of ignored prefixes for module index sorting. #modindex_common_prefix = [] # -- Options for HTML output --------------------------------------------------- # The theme to use for HTML and HTML Help pages. See the documentation for # a list of builtin themes. html_theme = 'default' # Theme options are theme-specific and customize the look and feel of a theme # further. For a list of options available for each theme, see the # documentation. #html_theme_options = {} # Add any paths that contain custom themes here, relative to this directory. #html_theme_path = [] # The name for this set of Sphinx documents. If None, it defaults to # " v documentation". #html_title = None # A shorter title for the navigation bar. Default is the same as html_title. #html_short_title = None # The name of an image file (relative to this directory) to place at the top # of the sidebar. #html_logo = None # The name of an image file (within the static path) to use as favicon of the # docs. This file should be a Windows icon file (.ico) being 16x16 or 32x32 # pixels large. #html_favicon = None # Add any paths that contain custom static files (such as style sheets) here, # relative to this directory. They are copied after the builtin static files, # so a file named "default.css" will overwrite the builtin "default.css". html_static_path = ['_static'] # If not '', a 'Last updated on:' timestamp is inserted at every page bottom, # using the given strftime format. #html_last_updated_fmt = '%b %d, %Y' # If true, SmartyPants will be used to convert quotes and dashes to # typographically correct entities. #html_use_smartypants = True # Custom sidebar templates, maps document names to template names. #html_sidebars = {} # Additional templates that should be rendered to pages, maps page names to # template names. #html_additional_pages = {} # If false, no module index is generated. #html_domain_indices = True # If false, no index is generated. #html_use_index = True # If true, the index is split into individual pages for each letter. #html_split_index = False # If true, links to the reST sources are added to the pages. #html_show_sourcelink = True # If true, "Created using Sphinx" is shown in the HTML footer. Default is True. #html_show_sphinx = True # If true, "(C) Copyright ..." is shown in the HTML footer. Default is True. #html_show_copyright = True # If true, an OpenSearch description file will be output, and all pages will # contain a tag referring to it. The value of this option must be the # base URL from which the finished HTML is served. #html_use_opensearch = '' # This is the file name suffix for HTML files (e.g. ".xhtml"). #html_file_suffix = None # Output file base name for HTML help builder. htmlhelp_basename = 'pyqtgraphdoc' # -- Options for LaTeX output -------------------------------------------------- # The paper size ('letter' or 'a4'). #latex_paper_size = 'letter' # The font size ('10pt', '11pt' or '12pt'). #latex_font_size = '10pt' # Grouping the document tree into LaTeX files. List of tuples # (source start file, target name, title, author, documentclass [howto/manual]). latex_documents = [ ('index', 'pyqtgraph.tex', 'pyqtgraph Documentation', 'Luke Campagnola', 'manual'), ] # The name of an image file (relative to this directory) to place at the top of # the title page. #latex_logo = None # For "manual" documents, if this is true, then toplevel headings are parts, # not chapters. #latex_use_parts = False # If true, show page references after internal links. #latex_show_pagerefs = False # If true, show URL addresses after external links. #latex_show_urls = False # Additional stuff for the LaTeX preamble. #latex_preamble = '' # Documents to append as an appendix to all manuals. #latex_appendices = [] # If false, no module index is generated. #latex_domain_indices = True # -- Options for manual page output -------------------------------------------- # One entry per manual page. List of tuples # (source start file, name, description, authors, manual section). man_pages = [ ('index', 'pyqtgraph', 'pyqtgraph Documentation', ['Luke Campagnola'], 1) ] pyqtgraph-pyqtgraph-0.10.0/doc/source/config_options.rst000066400000000000000000000057661300727121400234560ustar00rootroot00000000000000.. currentmodule:: pyqtgraph .. _apiref_config: Global Configuration Options ============================ PyQtGraph has several global configuration options that allow you to change its default behavior. These can be accessed using the :func:`setConfigOptions` and :func:`getConfigOption` functions: ================== =================== ================== ================================================================================ **Option** **Type** **Default** leftButtonPan bool True If True, dragging the left mouse button over a ViewBox causes the view to be panned. If False, then dragging the left mouse button draws a rectangle that the ViewBox will zoom to. foreground See :func:`mkColor` 'd' Default foreground color for text, lines, axes, etc. background See :func:`mkColor` 'k' Default background for :class:`GraphicsView`. antialias bool False Enabling antialiasing causes lines to be drawn with smooth edges at the cost of reduced performance. imageAxisOrder str 'col-major' For 'row-major', image data is expected in the standard row-major (row, col) order. For 'col-major', image data is expected in reversed column-major (col, row) order. The default is 'col-major' for backward compatibility, but this may change in the future. editorCommand str or None None Command used to invoke code editor from ConsoleWidget. exitCleanup bool True Attempt to work around some exit crash bugs in PyQt and PySide. useWeave bool False Use weave to speed up some operations, if it is available. weaveDebug bool False Print full error message if weave compile fails. useOpenGL bool False Enable OpenGL in GraphicsView. This can have unpredictable effects on stability and performance. enableExperimental bool False Enable experimental features (the curious can search for this key in the code). crashWarning bool False If True, print warnings about situations that may result in a crash. ================== =================== ================== ================================================================================ .. autofunction:: pyqtgraph.setConfigOptions .. autofunction:: pyqtgraph.getConfigOption pyqtgraph-pyqtgraph-0.10.0/doc/source/exporting.rst000066400000000000000000000051741300727121400224460ustar00rootroot00000000000000Exporting ========= PyQtGraph provides a variety of export formats for all 2D graphics. For 3D graphics, see `Exporting 3D Graphics`_ below. Exporting from the GUI ---------------------- Any 2D graphics can be exported by right-clicking on the graphic, then selecting 'export' from the context menu. This will display the export dialog in which the user must: #. Select an item (or the entire scene) to export. Selecting an item will cause the item to be hilighted in the original graphic window (but this hilight will not be displayed in the exported file). #. Select an export format. #. Change any desired export options. #. Click the 'export' button. Export Formats -------------- * Image - PNG is the default format. The exact set of image formats supported will depend on your Qt libraries. However, common formats such as PNG, JPG, and TIFF are almost always available. * SVG - Graphics exported as SVG are targeted to work as well as possible with both Inkscape and Adobe Illustrator. For high quality SVG export, please use PyQtGraph version 0.9.3 or later. This is the preferred method for generating publication graphics from PyQtGraph. * CSV - Exports plotted data as CSV. This exporter _only_ works if a PlotItem is selected for export. * Matplotlib - This exporter opens a new window and attempts to re-plot the data using matplotlib (if available). Note that some graphic features are either not implemented for this exporter or not available in matplotlib. This exporter _only_ works if a PlotItem is selected for export. * Printer - Exports to the operating system's printing service. This exporter is provided for completeness, but is not well supported due to problems with Qt's printing system. Exporting from the API ---------------------- To export a file programatically, follow this example:: import pyqtgraph as pg import pyqtgraph.exporters # generate something to export plt = pg.plot([1,5,2,4,3]) # create an exporter instance, as an argument give it # the item you wish to export exporter = pg.exporters.ImageExporter(plt.plotItem) # set export parameters if needed exporter.parameters()['width'] = 100 # (note this also affects height parameter) # save to file exporter.export('fileName.png') Exporting 3D Graphics --------------------- The exporting functionality described above is not yet available for 3D graphics. However, it is possible to generate an image from a GLViewWidget by using QGLWidget.grabFrameBuffer or QGLWidget.renderPixmap:: glview.grabFrameBuffer().save('fileName.png') See the Qt documentation for more information. pyqtgraph-pyqtgraph-0.10.0/doc/source/flowchart/000077500000000000000000000000001300727121400216575ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/doc/source/flowchart/flowchart.rst000066400000000000000000000002411300727121400243770ustar00rootroot00000000000000flowchart.Flowchart =================== .. autoclass:: pyqtgraph.flowchart.Flowchart :members: .. automethod:: pyqtgraph.flowchart.Flowchart.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/flowchart/index.rst000066400000000000000000000241211300727121400235200ustar00rootroot00000000000000Visual Programming with Flowcharts ================================== PyQtGraph's flowcharts provide a visual programming environment similar in concept to LabView--functional modules are added to a flowchart and connected by wires to define a more complex and arbitrarily configurable algorithm. A small number of predefined modules (called Nodes) are included with pyqtgraph, but most flowchart developers will want to define their own library of Nodes. At their core, the Nodes are little more than 1) a python function 2) a list of input/output terminals, and 3) an optional widget providing a control panel for the Node. Nodes may transmit/receive any type of Python object via their terminals. One major limitation of flowcharts is that there is no mechanism for looping within a flowchart. (however individual Nodes may contain loops (they may contain any Python code at all), and an entire flowchart may be executed from within a loop). There are two distinct modes of executing the code in a flowchart: 1. Provide data to the input terminals of the flowchart. This method is slower and will provide a graphical representation of the data as it passes through the flowchart. This is useful for debugging as it allows the user to inspect the data at each terminal and see where exceptions occurred within the flowchart. 2. Call :func:`Flowchart.process() `. This method does not update the displayed state of the flowchart and only retains the state of each terminal as long as it is needed. Additionally, Nodes which do not contribute to the output values of the flowchart (such as plotting nodes) are ignored. This mode allows for faster processing of large data sets and avoids memory issues which can occur if too much data is present in the flowchart at once (e.g., when processing image data through several stages). See the flowchart example for more information. API Reference: .. toctree:: :maxdepth: 2 flowchart node terminal Basic Use --------- Flowcharts are most useful in situations where you have a processing stage in your application that you would like to be arbitrarily configurable by the user. Rather than giving a pre-defined algorithm with parameters for the user to tweak, you supply a set of pre-defined functions and allow the user to arrange and connect these functions how they like. A very common example is the use of filter networks in audio / video processing applications. To begin, you must decide what the input and output variables will be for your flowchart. Create a flowchart with one terminal defined for each variable:: ## This example creates just a single input and a single output. ## Flowcharts may define any number of terminals, though. from pyqtgraph.flowchart import Flowchart fc = Flowchart(terminals={ 'nameOfInputTerminal': {'io': 'in'}, 'nameOfOutputTerminal': {'io': 'out'} }) In the example above, each terminal is defined by a dictionary of options which define the behavior of that terminal (see :func:`Terminal.__init__() ` for more information and options). Note that Terminals are not typed; any python object may be passed from one Terminal to another. Once the flowchart is created, add its control widget to your application:: ctrl = fc.ctrlWidget() myLayout.addWidget(ctrl) ## read Qt docs on QWidget and layouts for more information The control widget provides several features: * Displays a list of all nodes in the flowchart containing the control widget for each node. * Provides access to the flowchart design window via the 'flowchart' button * Interface for saving / restoring flowcharts to disk. At this point your user has the ability to generate flowcharts based on the built-in node library. It is recommended to provide a default set of flowcharts for your users to build from. All that remains is to process data through the flowchart. As noted above, there are two ways to do this: .. _processing methods: 1. Set the values of input terminals with :func:`Flowchart.setInput() `, then read the values of output terminals with :func:`Flowchart.output() `:: fc.setInput(nameOfInputTerminal=newValue) output = fc.output() # returns {terminalName:value} This method updates all of the values displayed in the flowchart design window, allowing the user to inspect values at all terminals in the flowchart and indicating the location of errors that occurred during processing. 2. Call :func:`Flowchart.process() `:: output = fc.process(nameOfInputTerminal=newValue) This method processes data without updating any of the displayed terminal values. Additionally, all :func:`Node.process() ` methods are called with display=False to request that they not invoke any custom display code. This allows data to be processed both more quickly and with a smaller memory footprint, but errors that occur during Flowchart.process() will be more difficult for the user to diagnose. It is thus recommended to use this method for batch processing through flowcharts that have already been tested and debugged with method 1. Implementing Custom Nodes ------------------------- PyQtGraph includes a small library of built-in flowchart nodes. This library is intended to cover some of the most commonly-used functions as well as provide examples for some more exotic Node types. Most applications that use the flowchart system will find the built-in library insufficient and will thus need to implement custom Node classes. A node subclass implements at least: 1) A list of input / output terminals and their properties 2) A :func:`process() ` function which takes the names of input terminals as keyword arguments and returns a dict with the names of output terminals as keys. Optionally, a Node subclass can implement the :func:`ctrlWidget() ` method, which must return a QWidget (usually containing other widgets) that will be displayed in the flowchart control panel. A minimal Node subclass looks like:: class SpecialFunctionNode(Node): """SpecialFunction: short description This description will appear in the flowchart design window when the user selects a node of this type. """ nodeName = 'SpecialFunction' # Node type name that will appear to the user. def __init__(self, name): # all Nodes are provided a unique name when they # are created. Node.__init__(self, name, terminals={ # Initialize with a dict # describing the I/O terminals # on this Node. 'inputTerminalName': {'io': 'in'}, 'anotherInputTerminal': {'io': 'in'}, 'outputTerminalName': {'io': 'out'}, }) def process(self, **kwds): # kwds will have one keyword argument per input terminal. return {'outputTerminalName': result} def ctrlWidget(self): # this method is optional return someQWidget Some nodes implement fairly complex control widgets, but most nodes follow a simple form-like pattern: a list of parameter names and a single value (represented as spin box, check box, etc..) for each parameter. To make this easier, the :class:`~pyqtgraph.flowchart.library.common.CtrlNode` subclass allows you to instead define a simple data structure that CtrlNode will use to automatically generate the control widget. This is used in many of the built-in library nodes (especially the filters). There are many other optional parameters for nodes and terminals -- whether the user is allowed to add/remove/rename terminals, whether one terminal may be connected to many others or just one, etc. See the documentation on the :class:`~pyqtgraph.flowchart.Node` and :class:`~pyqtgraph.flowchart.Terminal` classes for more details. After implementing a new Node subclass, you will most likely want to register the class so that it appears in the menu of Nodes the user can select from:: import pyqtgraph.flowchart.library as fclib fclib.registerNodeType(SpecialFunctionNode, [('Category', 'Sub-Category')]) The second argument to registerNodeType is a list of tuples, with each tuple describing a menu location in which SpecialFunctionNode should appear. See the FlowchartCustomNode example for more information. Debugging Custom Nodes ^^^^^^^^^^^^^^^^^^^^^^ When designing flowcharts or custom Nodes, it is important to set the input of the flowchart with data that at least has the same types and structure as the data you intend to process (see `processing methods`_ #1 above). When you use :func:`Flowchart.setInput() `, the flowchart displays visual feedback in its design window that can tell you what data is present at any terminal and whether there were errors in processing. Nodes that generated errors are displayed with a red border. If you select a Node, its input and output values will be displayed as well as the exception that occurred while the node was processing, if any. Using Nodes Without Flowcharts ------------------------------ Flowchart Nodes implement a very useful generalization in data processing by combining a function with a GUI for configuring that function. This generalization is useful even outside the context of a flowchart. For example:: ## We defined a useful filter Node for use in flowcharts, but would like to ## re-use its processing code and GUI without having a flowchart present. filterNode = MyFilterNode("filterNodeName") ## get the Node's control widget and place it inside the main window filterCtrl = filterNode.ctrlWidget() someLayout.addWidget(filterCtrl) ## later on, process data through the node filteredData = filterNode.process(inputTerminal=rawData) pyqtgraph-pyqtgraph-0.10.0/doc/source/flowchart/node.rst000066400000000000000000000002151300727121400233340ustar00rootroot00000000000000flowchart.Node ============== .. autoclass:: pyqtgraph.flowchart.Node :members: .. automethod:: pyqtgraph.flowchart.Node.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/flowchart/terminal.rst000066400000000000000000000002351300727121400242240ustar00rootroot00000000000000flowchart.Terminal ================== .. autoclass:: pyqtgraph.flowchart.Terminal :members: .. automethod:: pyqtgraph.flowchart.Terminal.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/functions.rst000066400000000000000000000045771300727121400224450ustar00rootroot00000000000000PyQtGraph's Helper Functions ============================ Simple Data Display Functions ----------------------------- .. autofunction:: pyqtgraph.plot .. autofunction:: pyqtgraph.image .. autofunction:: pyqtgraph.dbg Color, Pen, and Brush Functions ------------------------------- Qt uses the classes QColor, QPen, and QBrush to determine how to draw lines and fill shapes. These classes are highly capable but somewhat awkward to use. PyQtGraph offers the functions :func:`~pyqtgraph.mkColor`, :func:`~pyqtgraph.mkPen`, and :func:`~pyqtgraph.mkBrush` to simplify the process of creating these classes. In most cases, however, it will be unnecessary to call these functions directly--any function or method that accepts *pen* or *brush* arguments will make use of these functions for you. For example, the following three lines all have the same effect:: pg.plot(xdata, ydata, pen='r') pg.plot(xdata, ydata, pen=pg.mkPen('r')) pg.plot(xdata, ydata, pen=QPen(QColor(255, 0, 0))) .. autofunction:: pyqtgraph.mkColor .. autofunction:: pyqtgraph.mkPen .. autofunction:: pyqtgraph.mkBrush .. autofunction:: pyqtgraph.hsvColor .. autofunction:: pyqtgraph.intColor .. autofunction:: pyqtgraph.colorTuple .. autofunction:: pyqtgraph.colorStr .. autofunction:: pyqtgraph.glColor Data Slicing ------------ .. autofunction:: pyqtgraph.affineSlice Coordinate Transformation ------------------------- .. autofunction:: pyqtgraph.transformToArray .. autofunction:: pyqtgraph.transformCoordinates .. autofunction:: pyqtgraph.solve3DTransform .. autofunction:: pyqtgraph.solveBilinearTransform SI Unit Conversion Functions ---------------------------- .. autofunction:: pyqtgraph.siFormat .. autofunction:: pyqtgraph.siScale .. autofunction:: pyqtgraph.siEval Image Preparation Functions --------------------------- .. autofunction:: pyqtgraph.makeARGB .. autofunction:: pyqtgraph.makeQImage .. autofunction:: pyqtgraph.applyLookupTable .. autofunction:: pyqtgraph.rescaleData .. autofunction:: pyqtgraph.imageToArray Mesh Generation Functions ------------------------- .. autofunction:: pyqtgraph.isocurve .. autofunction:: pyqtgraph.isosurface Miscellaneous Functions ----------------------- .. autofunction:: pyqtgraph.eq .. autofunction:: pyqtgraph.arrayToQPath .. autofunction:: pyqtgraph.pseudoScatter .. autofunction:: pyqtgraph.systemInfo .. autofunction:: pyqtgraph.exit pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/000077500000000000000000000000001300727121400224705ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/arrowitem.rst000066400000000000000000000001711300727121400252320ustar00rootroot00000000000000ArrowItem ========= .. autoclass:: pyqtgraph.ArrowItem :members: .. automethod:: pyqtgraph.ArrowItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/axisitem.rst000066400000000000000000000001651300727121400250470ustar00rootroot00000000000000AxisItem ======== .. autoclass:: pyqtgraph.AxisItem :members: .. automethod:: pyqtgraph.AxisItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/buttonitem.rst000066400000000000000000000001751300727121400254170ustar00rootroot00000000000000ButtonItem ========== .. autoclass:: pyqtgraph.ButtonItem :members: .. automethod:: pyqtgraph.ButtonItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/curvearrow.rst000066400000000000000000000001751300727121400254240ustar00rootroot00000000000000CurveArrow ========== .. autoclass:: pyqtgraph.CurveArrow :members: .. automethod:: pyqtgraph.CurveArrow.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/curvepoint.rst000066400000000000000000000001751300727121400254230ustar00rootroot00000000000000CurvePoint ========== .. autoclass:: pyqtgraph.CurvePoint :members: .. automethod:: pyqtgraph.CurvePoint.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/errorbaritem.rst000066400000000000000000000002051300727121400257140ustar00rootroot00000000000000ErrorBarItem ============ .. autoclass:: pyqtgraph.ErrorBarItem :members: .. automethod:: pyqtgraph.ErrorBarItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/fillbetweenitem.rst000066400000000000000000000002211300727121400263740ustar00rootroot00000000000000FillBetweenItem =============== .. autoclass:: pyqtgraph.FillBetweenItem :members: .. automethod:: pyqtgraph.FillBetweenItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/gradienteditoritem.rst000066400000000000000000000004751300727121400271130ustar00rootroot00000000000000GradientEditorItem ================== .. autoclass:: pyqtgraph.GradientEditorItem :members: .. automethod:: pyqtgraph.GradientEditorItem.__init__ TickSliderItem ================== .. autoclass:: pyqtgraph.TickSliderItem :members: .. automethod:: pyqtgraph.TickSliderItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/gradientlegend.rst000066400000000000000000000002151300727121400261740ustar00rootroot00000000000000GradientLegend ============== .. autoclass:: pyqtgraph.GradientLegend :members: .. automethod:: pyqtgraph.GradientLegend.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/graphicsitem.rst000066400000000000000000000001201300727121400256720ustar00rootroot00000000000000GraphicsItem ============ .. autoclass:: pyqtgraph.GraphicsItem :members: pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/graphicslayout.rst000066400000000000000000000002151300727121400262560ustar00rootroot00000000000000GraphicsLayout ============== .. autoclass:: pyqtgraph.GraphicsLayout :members: .. automethod:: pyqtgraph.GraphicsLayout.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/graphicsobject.rst000066400000000000000000000002151300727121400262070ustar00rootroot00000000000000GraphicsObject ============== .. autoclass:: pyqtgraph.GraphicsObject :members: .. automethod:: pyqtgraph.GraphicsObject.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/graphicswidget.rst000066400000000000000000000002151300727121400262240ustar00rootroot00000000000000GraphicsWidget ============== .. autoclass:: pyqtgraph.GraphicsWidget :members: .. automethod:: pyqtgraph.GraphicsWidget.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/graphicswidgetanchor.rst000066400000000000000000000002451300727121400274220ustar00rootroot00000000000000GraphicsWidgetAnchor ==================== .. autoclass:: pyqtgraph.GraphicsWidgetAnchor :members: .. automethod:: pyqtgraph.GraphicsWidgetAnchor.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/graphitem.rst000066400000000000000000000001711300727121400252010ustar00rootroot00000000000000GraphItem ========= .. autoclass:: pyqtgraph.GraphItem :members: .. automethod:: pyqtgraph.GraphItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/griditem.rst000066400000000000000000000001651300727121400250300ustar00rootroot00000000000000GridItem ======== .. autoclass:: pyqtgraph.GridItem :members: .. automethod:: pyqtgraph.GridItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/histogramlutitem.rst000066400000000000000000000002251300727121400266220ustar00rootroot00000000000000HistogramLUTItem ================ .. autoclass:: pyqtgraph.HistogramLUTItem :members: .. automethod:: pyqtgraph.HistogramLUTItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/imageitem.rst000066400000000000000000000001711300727121400251620ustar00rootroot00000000000000ImageItem ========= .. autoclass:: pyqtgraph.ImageItem :members: .. automethod:: pyqtgraph.ImageItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/index.rst000066400000000000000000000017571300727121400243430ustar00rootroot00000000000000PyQtGraph's Graphics Items ========================== Since pyqtgraph relies on Qt's GraphicsView framework, most of its graphics functionality is implemented as QGraphicsItem subclasses. This has two important consequences: 1) virtually anything you want to draw can be easily accomplished using the functionality provided by Qt. 2) Many of pyqtgraph's GraphicsItem classes can be used in any normal QGraphicsScene. Contents: .. toctree:: :maxdepth: 2 plotdataitem plotitem imageitem graphitem viewbox linearregionitem infiniteline roi graphicslayout plotcurveitem scatterplotitem isocurveitem axisitem textitem errorbaritem arrowitem fillbetweenitem curvepoint curvearrow griditem scalebar labelitem vtickgroup legenditem gradienteditoritem histogramlutitem gradientlegend buttonitem graphicsobject graphicswidget graphicsitem uigraphicsitem graphicswidgetanchor pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/infiniteline.rst000066400000000000000000000002051300727121400256740ustar00rootroot00000000000000InfiniteLine ============ .. autoclass:: pyqtgraph.InfiniteLine :members: .. automethod:: pyqtgraph.InfiniteLine.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/isocurveitem.rst000066400000000000000000000002041300727121400257340ustar00rootroot00000000000000IsocurveItem ============ .. autoclass:: pyqtgraph.IsocurveItem :members: .. automethod:: pyqtgraph.IsocurveItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/labelitem.rst000066400000000000000000000001711300727121400251570ustar00rootroot00000000000000LabelItem ========= .. autoclass:: pyqtgraph.LabelItem :members: .. automethod:: pyqtgraph.LabelItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/legenditem.rst000066400000000000000000000001751300727121400253420ustar00rootroot00000000000000LegendItem ========== .. autoclass:: pyqtgraph.LegendItem :members: .. automethod:: pyqtgraph.LegendItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/linearregionitem.rst000066400000000000000000000002251300727121400265560ustar00rootroot00000000000000LinearRegionItem ================ .. autoclass:: pyqtgraph.LinearRegionItem :members: .. automethod:: pyqtgraph.LinearRegionItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/make000066400000000000000000000010061300727121400233250ustar00rootroot00000000000000files = """ArrowItem AxisItem ButtonItem CurvePoint GradientEditorItem GradientLegend GraphicsLayout GraphicsObject GraphicsWidget GridItem HistogramLUTItem ImageItem InfiniteLine LabelItem LinearRegionItem PlotCurveItem PlotDataItem ROI ScaleBar ScatterPlotItem UIGraphicsItem ViewBox VTickGroup""".split('\n') for f in files: print(f) fh = open(f.lower()+'.rst', 'w') fh.write( """%s %s .. autoclass:: pyqtgraph.%s :members: .. automethod:: pyqtgraph.%s.__init__ """ % (f, '='*len(f), f, f)) pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/plotcurveitem.rst000066400000000000000000000002111300727121400261160ustar00rootroot00000000000000PlotCurveItem ============= .. autoclass:: pyqtgraph.PlotCurveItem :members: .. automethod:: pyqtgraph.PlotCurveItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/plotdataitem.rst000066400000000000000000000002051300727121400257060ustar00rootroot00000000000000PlotDataItem ============ .. autoclass:: pyqtgraph.PlotDataItem :members: .. automethod:: pyqtgraph.PlotDataItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/plotitem.rst000066400000000000000000000001721300727121400250570ustar00rootroot00000000000000PlotItem ======== .. autoclass:: pyqtgraph.PlotItem() :members: .. automethod:: pyqtgraph.PlotItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/roi.rst000066400000000000000000000006331300727121400240150ustar00rootroot00000000000000ROI === .. autoclass:: pyqtgraph.ROI :members: .. autoclass:: pyqtgraph.RectROI :members: .. autoclass:: pyqtgraph.EllipseROI :members: .. autoclass:: pyqtgraph.CircleROI :members: .. autoclass:: pyqtgraph.LineSegmentROI :members: .. autoclass:: pyqtgraph.PolyLineROI :members: .. autoclass:: pyqtgraph.LineROI :members: .. autoclass:: pyqtgraph.MultiRectROI :members: pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/scalebar.rst000066400000000000000000000001651300727121400250000ustar00rootroot00000000000000ScaleBar ======== .. autoclass:: pyqtgraph.ScaleBar :members: .. automethod:: pyqtgraph.ScaleBar.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/scatterplotitem.rst000066400000000000000000000002211300727121400264400ustar00rootroot00000000000000ScatterPlotItem =============== .. autoclass:: pyqtgraph.ScatterPlotItem :members: .. automethod:: pyqtgraph.ScatterPlotItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/textitem.rst000066400000000000000000000001651300727121400250670ustar00rootroot00000000000000TextItem ======== .. autoclass:: pyqtgraph.TextItem :members: .. automethod:: pyqtgraph.TextItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/uigraphicsitem.rst000066400000000000000000000002151300727121400262350ustar00rootroot00000000000000UIGraphicsItem ============== .. autoclass:: pyqtgraph.UIGraphicsItem :members: .. automethod:: pyqtgraph.UIGraphicsItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/viewbox.rst000066400000000000000000000001611300727121400247030ustar00rootroot00000000000000ViewBox ======= .. autoclass:: pyqtgraph.ViewBox :members: .. automethod:: pyqtgraph.ViewBox.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsItems/vtickgroup.rst000066400000000000000000000001751300727121400254220ustar00rootroot00000000000000VTickGroup ========== .. autoclass:: pyqtgraph.VTickGroup :members: .. automethod:: pyqtgraph.VTickGroup.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsscene/000077500000000000000000000000001300727121400225045ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsscene/graphicsscene.rst000066400000000000000000000002111300727121400260460ustar00rootroot00000000000000GraphicsScene ============= .. autoclass:: pyqtgraph.GraphicsScene :members: .. automethod:: pyqtgraph.GraphicsScene.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsscene/hoverevent.rst000066400000000000000000000001431300727121400254210ustar00rootroot00000000000000HoverEvent ========== .. autoclass:: pyqtgraph.GraphicsScene.mouseEvents.HoverEvent :members: pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsscene/index.rst000066400000000000000000000002611300727121400243440ustar00rootroot00000000000000GraphicsScene and Mouse Events ============================== Contents: .. toctree:: :maxdepth: 2 graphicsscene hoverevent mouseclickevent mousedragevent pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsscene/mouseclickevent.rst000066400000000000000000000001621300727121400264350ustar00rootroot00000000000000MouseClickEvent =============== .. autoclass:: pyqtgraph.GraphicsScene.mouseEvents.MouseClickEvent :members: pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicsscene/mousedragevent.rst000066400000000000000000000001571300727121400262710ustar00rootroot00000000000000MouseDragEvent ============== .. autoclass:: pyqtgraph.GraphicsScene.mouseEvents.MouseDragEvent :members: pyqtgraph-pyqtgraph-0.10.0/doc/source/graphicswindow.rst000066400000000000000000000001611300727121400234460ustar00rootroot00000000000000Basic display widgets ===================== - GraphicsWindow - GraphicsView - GraphicsLayoutItem - ViewBox pyqtgraph-pyqtgraph-0.10.0/doc/source/how_to_use.rst000066400000000000000000000200321300727121400225700ustar00rootroot00000000000000How to use pyqtgraph ==================== There are a few suggested ways to use pyqtgraph: * From the interactive shell (python -i, ipython, etc) * Displaying pop-up windows from an application * Embedding widgets in a PyQt application Command-line use ---------------- PyQtGraph makes it very easy to visualize data from the command line. Observe:: import pyqtgraph as pg pg.plot(data) # data can be a list of values or a numpy array The example above would open a window displaying a line plot of the data given. The call to :func:`pg.plot ` returns a handle to the :class:`plot widget ` that is created, allowing more data to be added to the same window. **Note:** interactive plotting from the python prompt is only available with PyQt; PySide does not run the Qt event loop while the interactive prompt is running. If you wish to use pyqtgraph interactively with PySide, see the 'console' :ref:`example `. Further examples:: pw = pg.plot(xVals, yVals, pen='r') # plot x vs y in red pw.plot(xVals, yVals2, pen='b') win = pg.GraphicsWindow() # Automatically generates grids with multiple items win.addPlot(data1, row=0, col=0) win.addPlot(data2, row=0, col=1) win.addPlot(data3, row=1, col=0, colspan=2) pg.show(imageData) # imageData must be a numpy array with 2 to 4 dimensions We're only scratching the surface here--these functions accept many different data formats and options for customizing the appearance of your data. Displaying windows from within an application --------------------------------------------- While I consider this approach somewhat lazy, it is often the case that 'lazy' is indistinguishable from 'highly efficient'. The approach here is simply to use the very same functions that would be used on the command line, but from within an existing application. I often use this when I simply want to get a immediate feedback about the state of data in my application without taking the time to build a user interface for it. Embedding widgets inside PyQt applications ------------------------------------------ For the serious application developer, all of the functionality in pyqtgraph is available via :ref:`widgets ` that can be embedded just like any other Qt widgets. Most importantly, see: :class:`PlotWidget `, :class:`ImageView `, :class:`GraphicsLayoutWidget `, and :class:`GraphicsView `. PyQtGraph's widgets can be included in Designer's ui files via the "Promote To..." functionality: #. In Designer, create a QGraphicsView widget ("Graphics View" under the "Display Widgets" category). #. Right-click on the QGraphicsView and select "Promote To...". #. Under "Promoted class name", enter the class name you wish to use ("PlotWidget", "GraphicsLayoutWidget", etc). #. Under "Header file", enter "pyqtgraph". #. Click "Add", then click "Promote". See the designer documentation for more information on promoting widgets. The "VideoSpeedTest" and "ScatterPlotSpeedTest" examples both demonstrate the use of .ui files that are compiled to .py modules using pyuic4 or pyside-uic. The "designerExample" example demonstrates dynamically generating python classes from .ui files (no pyuic4 / pyside-uic needed). PyQt and PySide --------------- PyQtGraph supports two popular python wrappers for the Qt library: PyQt and PySide. Both packages provide nearly identical APIs and functionality, but for various reasons (discussed elsewhere) you may prefer to use one package or the other. When pyqtgraph is first imported, it automatically determines which library to use by making the fillowing checks: #. If PyQt4 is already imported, use that #. Else, if PySide is already imported, use that #. Else, attempt to import PyQt4 #. If that import fails, attempt to import PySide. If you have both libraries installed on your system and you wish to force pyqtgraph to use one or the other, simply make sure it is imported before pyqtgraph:: import PySide ## this will force pyqtgraph to use PySide instead of PyQt4 import pyqtgraph as pg Embedding PyQtGraph as a sub-package of a larger project -------------------------------------------------------- When writing applications or python packages that make use of pyqtgraph, it is most common to install pyqtgraph system-wide (or within a virtualenv) and simply call `import pyqtgraph` from within your application. The main benefit to this is that pyqtgraph is configured independently of your application and thus you (or your users) are free to install newer versions of pyqtgraph without changing anything in your application. This is standard practice when developing with python. However, it is also often the case, especially for scientific applications, that software is written for a very specific purpose and then archived. If we want to ensure that the software will still work ten years later, then it is preferrable to tie the application to a very specific version of pyqtgraph and *avoid* importing the system-installed version of pyqtgraph, which may be much newer (and potentially incompatible). This is especially the case when the application requires site-specific modifications to the pyqtgraph package which may not be present in the main releases. PyQtGraph facilitates this usage through two mechanisms. First, all internal import statements in pyqtgraph are relative, which allows the package to be renamed or used as a sub-package without any naming conflicts with other versions of pyqtgraph on the system (that is, pyqtgraph never refers to itself internally as 'pyqtgraph'). Second, a git subtree repository is available at https://github.com/pyqtgraph/pyqtgraph-core.git that contains only the 'pyqtgraph/' subtree, allowing the code to be cloned directly as a subtree of the application which uses it. The basic approach is to clone the repository into the appropriate location in your package. When you import pyqtgraph from within your package, be sure to use the full name to avoid importing any system-installed pyqtgraph packages. For example, imagine a simple project has the following structure:: my_project/ __init__.py plotting.py """Plotting functions used by this package""" import pyqtgraph as pg def my_plot_function(*data): pg.plot(*data) To embed a specific version of pyqtgraph, we would clone the pyqtgraph-core repository inside the project:: my_project$ git clone https://github.com/pyqtgraph/pyqtgraph-core.git Then adjust the import statements accordingly:: my_project/ __init__.py pyqtgraph/ plotting.py """Plotting functions used by this package""" import my_project.pyqtgraph as pg # be sure to use the local subpackage # rather than any globally-installed # versions. def my_plot_function(*data): pg.plot(*data) Use ``git checkout pyqtgraph-core-x.x.x`` to select a specific version of the repository, or use ``git pull`` to pull pyqtgraph updates from upstream (see the git documentation for more information). For projects that already use git for code control, it is also possible to include pyqtgraph as a git subtree within your own repository. The major advantage to this approach is that, in addition to being able to pull pyqtgraph updates from the upstream repository, it is also possible to commit your local pyqtgraph changes into the project repository and push those changes upstream:: my_project$ git remote add pyqtgraph-core https://github.com/pyqtgraph/pyqtgraph-core.git my_project$ git fetch pyqtgraph-core my_project$ git merge -s ours --no-commit pyqtgraph-core/core my_project$ mkdir pyqtgraph my_project$ git read-tree -u --prefix=pyqtgraph/ pyqtgraph-core/core my_project$ git commit -m "Added pyqtgraph to project repository" See the ``git subtree`` documentation for more information. pyqtgraph-pyqtgraph-0.10.0/doc/source/images.rst000066400000000000000000000042371300727121400216730ustar00rootroot00000000000000Displaying images and video =========================== PyQtGraph displays 2D numpy arrays as images and provides tools for determining how to translate between the numpy data type and RGB values on the screen. If you want to display data from common image and video file formats, you will need to load the data first using another library (PIL works well for images and built-in numpy conversion). The easiest way to display 2D or 3D data is using the :func:`pyqtgraph.image` function:: import pyqtgraph as pg pg.image(imageData) This function will accept any floating-point or integer data types and displays a single :class:`~pyqtgraph.ImageView` widget containing your data. This widget includes controls for determining how the image data will be converted to 32-bit RGBa values. Conversion happens in two steps (both are optional): 1. Scale and offset the data (by selecting the dark/light levels on the displayed histogram) 2. Convert the data to color using a lookup table (determined by the colors shown in the gradient editor) If the data is 3D (time, x, y), then a time axis will be shown with a slider that can set the currently displayed frame. (if the axes in your data are ordered differently, use numpy.transpose to rearrange them) There are a few other methods for displaying images as well: * The :class:`~pyqtgraph.ImageView` class can also be instantiated directly and embedded in Qt applications. * Instances of :class:`~pyqtgraph.ImageItem` can be used inside a :class:`ViewBox ` or :class:`GraphicsView `. * For higher performance, use :class:`~pyqtgraph.RawImageWidget`. Any of these classes are acceptable for displaying video by calling setImage() to display a new frame. To increase performance, the image processing system uses scipy.weave to produce compiled libraries. If your computer has a compiler available, weave will automatically attempt to build the libraries it needs on demand. If this fails, then the slower pure-python methods will be used instead. For more information, see the classes listed above and the 'VideoSpeedTest', 'ImageItem', 'ImageView', and 'HistogramLUT' :ref:`examples`.pyqtgraph-pyqtgraph-0.10.0/doc/source/images/000077500000000000000000000000001300727121400211335ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/doc/source/images/plottingClasses.png000066400000000000000000001264321300727121400250270ustar00rootroot00000000000000PNG  IHDR ܔLsBIT|d pHYs B(xtEXtSoftwarewww.inkscape.org< IDATxwXT׀ߥ*MbCQ7wwckb」{E wX?Vl Fbwه[Μ=šB$Ӈ"EDDD[PPT~B"E/α@ƧcAVJ H$~DDDD @>R ȱbH$_LBcqQЇJTgEDDD@9>E>|^*UQwPDDD@2jw ?RDBAAARae? 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You can adapt this file completely to your liking, but it should at least contain the root `toctree` directive. Welcome to the documentation for pyqtgraph ========================================== Contents: .. toctree:: :maxdepth: 2 introduction mouse_interaction how_to_use installation qtcrashcourse plotting images 3dgraphics style region_of_interest exporting prototyping parametertree/index flowchart/index internals apireference Indices and tables ================== * :ref:`genindex` * :ref:`modindex` * :ref:`search` pyqtgraph-pyqtgraph-0.10.0/doc/source/installation.rst000066400000000000000000000020411300727121400231160ustar00rootroot00000000000000Installation ============ PyQtGraph does not really require any installation scripts. All that is needed is for the pyqtgraph folder to be placed someplace importable. Most people will prefer to simply place this folder within a larger project folder. If you want to make pyqtgraph available system-wide, use one of the methods listed below: * **Debian, Ubuntu, and similar Linux:** Download the .deb file linked at the top of the pyqtgraph web page or install using apt by putting "deb http://luke.campagnola.me/debian dev/" in your /etc/apt/sources.list file and install the python-pyqtgraph package. * **Arch Linux:** Looks like someone has posted unofficial packages for Arch (thanks windel). (https://aur.archlinux.org/packages.php?ID=62577) * **Windows:** Download and run the .exe installer file linked at the top of the pyqtgraph web page. * **Everybody (including OSX):** Download the .tar.gz source package linked at the top of the pyqtgraph web page, extract its contents, and run "python setup.py install" from within the extracted directory. pyqtgraph-pyqtgraph-0.10.0/doc/source/internals.rst000066400000000000000000000002641300727121400224210ustar00rootroot00000000000000Internals - Extensions to Qt's GraphicsView =========================================== * GraphicsView * GraphicsScene (mouse events) * GraphicsObject * GraphicsWidget * ViewBox pyqtgraph-pyqtgraph-0.10.0/doc/source/introduction.rst000066400000000000000000000066451300727121400231540ustar00rootroot00000000000000Introduction ============ What is pyqtgraph? ------------------ PyQtGraph is a graphics and user interface library for Python that provides functionality commonly required in engineering and science applications. Its primary goals are 1) to provide fast, interactive graphics for displaying data (plots, video, etc.) and 2) to provide tools to aid in rapid application development (for example, property trees such as used in Qt Designer). PyQtGraph makes heavy use of the Qt GUI platform (via PyQt or PySide) for its high-performance graphics and numpy for heavy number crunching. In particular, pyqtgraph uses Qt's GraphicsView framework which is a highly capable graphics system on its own; we bring optimized and simplified primitives to this framework to allow data visualization with minimal effort. It is known to run on Linux, Windows, and OSX What can it do? --------------- Amongst the core features of pyqtgraph are: * Basic data visualization primitives: Images, line and scatter plots * Fast enough for realtime update of video/plot data * Interactive scaling/panning, averaging, FFTs, SVG/PNG export * Widgets for marking/selecting plot regions * Widgets for marking/selecting image region-of-interest and automatically slicing multi-dimensional image data * Framework for building customized image region-of-interest widgets * Docking system that replaces/complements Qt's dock system to allow more complex (and more predictable) docking arrangements * ParameterTree widget for rapid prototyping of dynamic interfaces (Similar to the property trees in Qt Designer and many other applications) .. _examples: Examples -------- PyQtGraph includes an extensive set of examples that can be accessed by running:: import pyqtgraph.examples pyqtgraph.examples.run() Or by running ``python examples/`` from the source root. This will start a launcher with a list of available examples. Select an item from the list to view its source code and double-click an item to run the example. Note If you have installed pyqtgraph with ``python setup.py develop`` then the examples are incorrectly exposed as a top-level module. In this case, use ``import examples; examples.run()``. How does it compare to... ------------------------- * matplotlib: For plotting, pyqtgraph is not nearly as complete/mature as matplotlib, but runs much faster. Matplotlib is more aimed toward making publication-quality graphics, whereas pyqtgraph is intended for use in data acquisition and analysis applications. Matplotlib is more intuitive for matlab programmers; pyqtgraph is more intuitive for python/qt programmers. Matplotlib (to my knowledge) does not include many of pyqtgraph's features such as image interaction, volumetric rendering, parameter trees, flowcharts, etc. * pyqwt5: About as fast as pyqwt5, but not quite as complete for plotting functionality. Image handling in pyqtgraph is much more complete (again, no ROI widgets in qwt). Also, pyqtgraph is written in pure python, so it is more portable than pyqwt, which often lags behind pyqt in development (I originally used pyqwt, but decided it was too much trouble to rely on it as a dependency in my projects). Like matplotlib, pyqwt (to my knowledge) does not include many of pyqtgraph's features such as image interaction, volumetric rendering, parameter trees, flowcharts, etc. (My experience with these libraries is somewhat outdated; please correct me if I am wrong here) pyqtgraph-pyqtgraph-0.10.0/doc/source/mouse_interaction.rst000066400000000000000000000052421300727121400241520ustar00rootroot00000000000000Mouse Interaction ================= Most applications that use pyqtgraph's data visualization will generate widgets that can be interactively scaled, panned, and otherwise configured using the mouse. This section describes mouse interaction with these widgets. 2D Graphics ----------- In pyqtgraph, most 2D visualizations follow the following mouse interaction: * Left button: Interacts with items in the scene (select/move objects, etc). If there are no movable objects under the mouse cursor, then dragging with the left button will pan the scene instead. * Right button drag: Scales the scene. Dragging left/right scales horizontally; dragging up/down scales vertically (although some scenes will have their x/y scales locked together). If there are x/y axes fisible in the scene, then right-dragging over the axis will _only_ affect that axis. * Right button click: Clicking the right button in most cases will show a context menu with a variety of options depending on the object(s) under the mouse cursor. * Middle button (or wheel) drag: Dragging the mouse with the wheel pressed down will always pan the scene (this is useful in instances where panning with the left button is prevented by other objects in the scene). * Wheel spin: Zooms the scene in and out. For machines where dragging with the right or middle buttons is difficult (usually Mac), another mouse interaction mode exists. In this mode, dragging with the left mouse button draws a box over a region of the scene. After the button is released, the scene is scaled and panned to fit the box. This mode can be accessed in the context menu or by calling:: pyqtgraph.setConfigOption('leftButtonPan', False) Context Menu ------------ Right-clicking on most scenes will show a context menu with various options for changing the behavior of the scene. Some of the options available in this menu are: * Enable/disable automatic scaling when the data range changes * Link the axes of multiple views together * Enable disable mouse interaction per axis * Explicitly set the visible range values The exact set of items available in the menu depends on the contents of the scene and the object clicked on. 3D Graphics ----------- 3D visualizations use the following mouse interaction: * Left button drag: Rotates the scene around a central point * Middle button drag: Pan the scene by moving the central "look-at" point within the x-y plane * Middle button drag + CTRL: Pan the scene by moving the central "look-at" point along the z axis * Wheel spin: zoom in/out * Wheel + CTRL: change field-of-view angle And keyboard controls: * Arrow keys rotate around central point, just like dragging the left mouse button pyqtgraph-pyqtgraph-0.10.0/doc/source/parametertree/000077500000000000000000000000001300727121400225265ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/doc/source/parametertree/apiref.rst000066400000000000000000000003471300727121400245320ustar00rootroot00000000000000ParameterTree API Reference =========================== Also see the 'parametertree' example included with pyqtgraph Contents: .. toctree:: :maxdepth: 2 parameter parametertree parametertypes parameteritem pyqtgraph-pyqtgraph-0.10.0/doc/source/parametertree/index.rst000066400000000000000000000024371300727121400243750ustar00rootroot00000000000000.. _parametertree: Parameter Trees =============== Parameter trees are a system for handling hierarchies of parameters while automatically generating one or more GUIs to display and interact with the parameters. This feature is commonly seen, for example, in user interface design applications which display a list of editable properties for each widget. Parameters generally have a name, a data type (int, float, string, color, etc), and a value matching the data type. Parameters may be grouped and nested to form hierarchies and may be subclassed to provide custom behavior and display widgets. PyQtGraph's parameter tree system works similarly to the model-view architecture used by some components of Qt: Parameters are purely data-handling classes that exist independent of any graphical interface. A ParameterTree is a widget that automatically generates a graphical interface which represents the state of a haierarchy of Parameter objects and allows the user to edit the values within that hierarchy. This separation of data (model) and graphical interface (view) allows the same data to be represented multiple times and in a variety of different ways. For more information, see the 'parametertree' example included with pyqtgraph and the API reference .. toctree:: :maxdepth: 2 apiref pyqtgraph-pyqtgraph-0.10.0/doc/source/parametertree/parameter.rst000066400000000000000000000002251300727121400252370ustar00rootroot00000000000000Parameter ========= .. autoclass:: pyqtgraph.parametertree.Parameter :members: .. automethod:: pyqtgraph.parametertree.Parameter.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/parametertree/parameteritem.rst000066400000000000000000000002451300727121400261200ustar00rootroot00000000000000ParameterItem ============= .. autoclass:: pyqtgraph.parametertree.ParameterItem :members: .. automethod:: pyqtgraph.parametertree.ParameterItem.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/parametertree/parametertree.rst000066400000000000000000000002451300727121400261210ustar00rootroot00000000000000ParameterTree ============= .. autoclass:: pyqtgraph.parametertree.ParameterTree :members: .. automethod:: pyqtgraph.parametertree.ParameterTree.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/parametertree/parametertypes.rst000066400000000000000000000001711300727121400263240ustar00rootroot00000000000000Built-in Parameter Types ======================== .. automodule:: pyqtgraph.parametertree.parameterTypes :members: pyqtgraph-pyqtgraph-0.10.0/doc/source/plotting.rst000066400000000000000000000116441300727121400222660ustar00rootroot00000000000000Plotting in pyqtgraph ===================== There are a few basic ways to plot data in pyqtgraph: =================================================================== ================================================== :func:`pyqtgraph.plot` Create a new plot window showing your data :func:`PlotWidget.plot() ` Add a new set of data to an existing plot widget :func:`PlotItem.plot() ` Add a new set of data to an existing plot widget :func:`GraphicsLayout.addPlot() ` Add a new plot to a grid of plots =================================================================== ================================================== All of these will accept the same basic arguments which control how the plot data is interpreted and displayed: * x - Optional X data; if not specified, then a range of integers will be generated automatically. * y - Y data. * pen - The pen to use when drawing plot lines, or None to disable lines. * symbol - A string describing the shape of symbols to use for each point. Optionally, this may also be a sequence of strings with a different symbol for each point. * symbolPen - The pen (or sequence of pens) to use when drawing the symbol outline. * symbolBrush - The brush (or sequence of brushes) to use when filling the symbol. * fillLevel - Fills the area under the plot curve to this Y-value. * brush - The brush to use when filling under the curve. See the 'plotting' :ref:`example ` for a demonstration of these arguments. All of the above functions also return handles to the objects that are created, allowing the plots and data to be further modified. Organization of Plotting Classes -------------------------------- There are several classes invloved in displaying plot data. Most of these classes are instantiated automatically, but it is useful to understand how they are organized and relate to each other. PyQtGraph is based heavily on Qt's GraphicsView framework--if you are not already familiar with this, it's worth reading about (but not essential). Most importantly: 1) Qt GUIs are composed of QWidgets, 2) A special widget called QGraphicsView is used for displaying complex graphics, and 3) QGraphicsItems define the objects that are displayed within a QGraphicsView. * Data Classes (all subclasses of QGraphicsItem) * :class:`PlotCurveItem ` - Displays a plot line given x,y data * :class:`ScatterPlotItem ` - Displays points given x,y data * :class:`PlotDataItem ` - Combines PlotCurveItem and ScatterPlotItem. The plotting functions discussed above create objects of this type. * Container Classes (subclasses of QGraphicsItem; contain other QGraphicsItem objects and must be viewed from within a GraphicsView) * :class:`PlotItem ` - Contains a ViewBox for displaying data as well as AxisItems and labels for displaying the axes and title. This is a QGraphicsItem subclass and thus may only be used from within a GraphicsView * :class:`GraphicsLayout ` - QGraphicsItem subclass which displays a grid of items. This is used to display multiple PlotItems together. * :class:`ViewBox ` - A QGraphicsItem subclass for displaying data. The user may scale/pan the contents of a ViewBox using the mouse. Typically all PlotData/PlotCurve/ScatterPlotItems are displayed from within a ViewBox. * :class:`AxisItem ` - Displays axis values, ticks, and labels. Most commonly used with PlotItem. * Container Classes (subclasses of QWidget; may be embedded in PyQt GUIs) * :class:`PlotWidget ` - A subclass of GraphicsView with a single PlotItem displayed. Most of the methods provided by PlotItem are also available through PlotWidget. * :class:`GraphicsLayoutWidget ` - QWidget subclass displaying a single GraphicsLayoutItem. Most of the methods provided by GraphicsLayoutItem are also available through GraphicsLayoutWidget. .. image:: images/plottingClasses.png Examples -------- See the 'plotting' and 'PlotWidget' :ref:`examples included with pyqtgraph ` for more information. Show x,y data as scatter plot:: import pyqtgraph as pg import numpy as np x = np.random.normal(size=1000) y = np.random.normal(size=1000) pg.plot(x, y, pen=None, symbol='o') ## setting pen=None disables line drawing Create/show a plot widget, display three data curves:: import pyqtgraph as pg import numpy as np x = np.arange(1000) y = np.random.normal(size=(3, 1000)) plotWidget = pg.plot(title="Three plot curves") for i in range(3): plotWidget.plot(x, y[i], pen=(i,3)) ## setting pen=(i,3) automaticaly creates three different-colored pens pyqtgraph-pyqtgraph-0.10.0/doc/source/prototyping.rst000066400000000000000000000047621300727121400230270ustar00rootroot00000000000000Rapid GUI prototyping ===================== [Just an overview; documentation is not complete yet] PyQtGraph offers several powerful features which are commonly used in engineering and scientific applications. Parameter Trees --------------- The parameter tree system provides a widget displaying a tree of modifiable values similar to those used in most GUI editor applications. This allows a large number of variables to be controlled by the user with relatively little programming effort. The system also provides separation between the data being controlled and the user interface controlling it (model/view architecture). Parameters may be grouped/nested to any depth and custom parameter types can be built by subclassing from Parameter and ParameterItem. See the `parametertree documentation `_ for more information. Visual Programming Flowcharts ----------------------------- PyQtGraph's flowcharts provide a visual programming environment similar in concept to LabView--functional modules are added to a flowchart and connected by wires to define a more complex and arbitrarily configurable algorithm. A small number of predefined modules (called Nodes) are included with pyqtgraph, but most flowchart developers will want to define their own library of Nodes. At their core, the Nodes are little more than 1) a Python function 2) a list of input/output terminals, and 3) an optional widget providing a control panel for the Node. Nodes may transmit/receive any type of Python object via their terminals. See the `flowchart documentation `_ and the flowchart examples for more information. Graphical Canvas ---------------- The Canvas is a system designed to allow the user to add/remove items to a 2D canvas similar to most vector graphics applications. Items can be translated/scaled/rotated and each item may define its own custom control interface. Dockable Widgets ---------------- The dockarea system allows the design of user interfaces which can be rearranged by the user at runtime. Docks can be moved, resized, stacked, and torn out of the main window. This is similar in principle to the docking system built into Qt, but offers a more deterministic dock placement API (in Qt it is very difficult to programatically generate complex dock arrangements). Additionally, Qt's docks are designed to be used as small panels around the outer edge of a window. PyQtGraph's docks were created with the notion that the entire window (or any portion of it) would consist of dockable components. pyqtgraph-pyqtgraph-0.10.0/doc/source/qtcrashcourse.rst000066400000000000000000000101141300727121400233030ustar00rootroot00000000000000Qt Crash Course =============== PyQtGraph makes extensive use of Qt for generating nearly all of its visual output and interfaces. Qt's documentation is very well written and we encourage all pyqtgraph developers to familiarize themselves with it. The purpose of this section is to provide an introduction to programming with Qt (using either PyQt or PySide) for the pyqtgraph developer. QWidgets and Layouts -------------------- A Qt GUI is almost always composed of a few basic components: * A window. This is often provided by QMainWindow, but note that all QWidgets can be displayed in their window by simply calling widget.show() if the widget does not have a parent. * Multiple QWidget instances such as QPushButton, QLabel, QComboBox, etc. * QLayout instances (optional, but strongly encouraged) which automatically manage the positioning of widgets to allow the GUI to resize in a usable way. PyQtGraph fits into this scheme by providing its own QWidget subclasses to be inserted into your GUI. Example:: from PyQt4 import QtGui # (the example applies equally well to PySide) import pyqtgraph as pg ## Always start by initializing Qt (only once per application) app = QtGui.QApplication([]) ## Define a top-level widget to hold everything w = QtGui.QWidget() ## Create some widgets to be placed inside btn = QtGui.QPushButton('press me') text = QtGui.QLineEdit('enter text') listw = QtGui.QListWidget() plot = pg.PlotWidget() ## Create a grid layout to manage the widgets size and position layout = QtGui.QGridLayout() w.setLayout(layout) ## Add widgets to the layout in their proper positions layout.addWidget(btn, 0, 0) # button goes in upper-left layout.addWidget(text, 1, 0) # text edit goes in middle-left layout.addWidget(listw, 2, 0) # list widget goes in bottom-left layout.addWidget(plot, 0, 1, 3, 1) # plot goes on right side, spanning 3 rows ## Display the widget as a new window w.show() ## Start the Qt event loop app.exec_() More complex interfaces may be designed graphically using Qt Designer, which allows you to simply drag widgets into your window to define its appearance. Naming Conventions ------------------ Virtually every class in pyqtgraph is an extension of base classes provided by Qt. When reading the documentation, remember that all of Qt's classes start with the letter 'Q', whereas pyqtgraph's classes do not. When reading through the methods for any class, it is often helpful to see which Qt base classes are used and look through the Qt documentation as well. Most of Qt's classes define signals which can be difficult to tell apart from regular methods. Almost all signals explicity defined by pyqtgraph are named beginning with 'sig' to indicate that these signals are not defined at the Qt level. In most cases, classes which end in 'Widget' are subclassed from QWidget and can therefore be used as a GUI element in a Qt window. Classes which end in 'Item' are subclasses of QGraphicsItem and can only be displayed within a QGraphicsView instance (such as GraphicsLayoutWidget or PlotWidget). Signals, Slots, and Events -------------------------- [ to be continued.. please post a request on the pyqtgraph forum if you'd like to read more ] Qt detects and reacts to user interaction by executing its *event loop*. - what happens in the event loop? - when do I need to use QApplication.exec_() ? - what control do I have over event loop execution? (QApplication.processEvents) GraphicsView and GraphicsItems ------------------------------ More information about the architecture of Qt GraphicsView: http://qt-project.org/doc/qt-4.8/graphicsview.html Coordinate Systems and Transformations -------------------------------------- More information about the coordinate systems in Qt GraphicsView: http://qt-project.org/doc/qt-4.8/graphicsview.html#the-graphics-view-coordinate-system Mouse and Keyboard Input ------------------------ QTimer, Multi-Threading ----------------------- Multi-threading vs Multi-processing in Qt ----------------------------------------- pyqtgraph-pyqtgraph-0.10.0/doc/source/region_of_interest.rst000066400000000000000000000040001300727121400242760ustar00rootroot00000000000000Interactive Data Selection Controls =================================== PyQtGraph includes graphics items which allow the user to select and mark regions of data. Linear Selection and Marking ---------------------------- Two classes allow marking and selecting 1-dimensional data: :class:`LinearRegionItem ` and :class:`InfiniteLine `. The first class, :class:`LinearRegionItem `, may be added to any ViewBox or PlotItem to mark either a horizontal or vertical region. The region can be dragged and its bounding edges can be moved independently. The second class, :class:`InfiniteLine `, is usually used to mark a specific position along the x or y axis. These may be dragged by the user. 2D Selection and Marking ------------------------ To select a 2D region from an image, pyqtgraph uses the :class:`ROI ` class or any of its subclasses. By default, :class:`ROI ` simply displays a rectangle which can be moved by the user to mark a specific region (most often this will be a region of an image, but this is not required). To allow the ROI to be resized or rotated, there are several methods for adding handles (:func:`addScaleHandle `, :func:`addRotateHandle `, etc.) which can be dragged by the user. These handles may be placed at any location relative to the ROI and may scale/rotate the ROI around any arbitrary center point. There are several ROI subclasses with a variety of shapes and modes of interaction. To automatically extract a region of image data using an ROI and an ImageItem, use :func:`ROI.getArrayRegion `. ROI classes use the :func:`affineSlice ` function to perform this extraction. ROI can also be used as a control for moving/rotating/scaling items in a scene similar to most vetctor graphics editing applications. See the ROITypes example for more information. pyqtgraph-pyqtgraph-0.10.0/doc/source/style.rst000066400000000000000000000040571300727121400215660ustar00rootroot00000000000000Line, Fill, and Color ===================== Qt relies on its QColor, QPen and QBrush classes for specifying line and fill styles for all of its drawing. Internally, pyqtgraph uses the same system but also allows many shorthand methods of specifying the same style options. Many functions and methods in pyqtgraph accept arguments specifying the line style (pen), fill style (brush), or color. For most of these function arguments, the following values may be used: * single-character string representing color (b, g, r, c, m, y, k, w) * (r, g, b) or (r, g, b, a) tuple * single greyscale value (0.0 - 1.0) * (index, maximum) tuple for automatically iterating through colors (see :func:`intColor `) * QColor * QPen / QBrush where appropriate Notably, more complex pens and brushes can be easily built using the :func:`mkPen() ` / :func:`mkBrush() ` functions or with Qt's QPen and QBrush classes:: mkPen('y', width=3, style=QtCore.Qt.DashLine) ## Make a dashed yellow line 2px wide mkPen(0.5) ## solid grey line 1px wide mkPen(color=(200, 200, 255), style=QtCore.Qt.DotLine) ## Dotted pale-blue line See the Qt documentation for 'QPen' and 'PenStyle' for more line-style options and 'QBrush' for more fill options. Colors can also be built using :func:`mkColor() `, :func:`intColor() `, :func:`hsvColor() `, or Qt's QColor class. Default Background and Foreground Colors ---------------------------------------- By default, pyqtgraph uses a black background for its plots and grey for axes, text, and plot lines. These defaults can be changed using pyqtgraph.setConfigOption():: import pyqtgraph as pg ## Switch to using white background and black foreground pg.setConfigOption('background', 'w') pg.setConfigOption('foreground', 'k') ## The following plot has inverted colors pg.plot([1,4,2,3,5]) (Note that this must be set *before* creating any widgets) pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/000077500000000000000000000000001300727121400213345ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/busycursor.rst000066400000000000000000000001751300727121400243110ustar00rootroot00000000000000BusyCursor ========== .. autoclass:: pyqtgraph.BusyCursor :members: .. automethod:: pyqtgraph.BusyCursor.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/checktable.rst000066400000000000000000000001751300727121400241560ustar00rootroot00000000000000CheckTable ========== .. autoclass:: pyqtgraph.CheckTable :members: .. automethod:: pyqtgraph.CheckTable.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/colorbutton.rst000066400000000000000000000002011300727121400244310ustar00rootroot00000000000000ColorButton =========== .. autoclass:: pyqtgraph.ColorButton :members: .. automethod:: pyqtgraph.ColorButton.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/colormapwidget.rst000066400000000000000000000004561300727121400251130ustar00rootroot00000000000000ColorMapWidget ============== .. autoclass:: pyqtgraph.ColorMapWidget :members: .. automethod:: pyqtgraph.ColorMapWidget.__init__ .. automethod:: pyqtgraph.widgets.ColorMapWidget.ColorMapParameter.setFields .. automethod:: pyqtgraph.widgets.ColorMapWidget.ColorMapParameter.map pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/combobox.rst000066400000000000000000000001651300727121400237000ustar00rootroot00000000000000ComboBox ======== .. autoclass:: pyqtgraph.ComboBox :members: .. automethod:: pyqtgraph.ComboBox.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/consolewidget.rst000066400000000000000000000001361300727121400247340ustar00rootroot00000000000000ConsoleWidget ============= .. autoclass:: pyqtgraph.console.ConsoleWidget :members: pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/datatreewidget.rst000066400000000000000000000002151300727121400250610ustar00rootroot00000000000000DataTreeWidget ============== .. autoclass:: pyqtgraph.DataTreeWidget :members: .. automethod:: pyqtgraph.DataTreeWidget.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/dockarea.rst000066400000000000000000000001221300727121400236320ustar00rootroot00000000000000dockarea module =============== .. automodule:: pyqtgraph.dockarea :members: pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/feedbackbutton.rst000066400000000000000000000002151300727121400250440ustar00rootroot00000000000000FeedbackButton ============== .. autoclass:: pyqtgraph.FeedbackButton :members: .. automethod:: pyqtgraph.FeedbackButton.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/filedialog.rst000066400000000000000000000001751300727121400241700ustar00rootroot00000000000000FileDialog ========== .. autoclass:: pyqtgraph.FileDialog :members: .. automethod:: pyqtgraph.FileDialog.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/gradientwidget.rst000066400000000000000000000002151300727121400250650ustar00rootroot00000000000000GradientWidget ============== .. autoclass:: pyqtgraph.GradientWidget :members: .. automethod:: pyqtgraph.GradientWidget.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/graphicslayoutwidget.rst000066400000000000000000000002451300727121400263310ustar00rootroot00000000000000GraphicsLayoutWidget ==================== .. autoclass:: pyqtgraph.GraphicsLayoutWidget :members: .. automethod:: pyqtgraph.GraphicsLayoutWidget.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/graphicsview.rst000066400000000000000000000002051300727121400245560ustar00rootroot00000000000000GraphicsView ============ .. autoclass:: pyqtgraph.GraphicsView :members: .. automethod:: pyqtgraph.GraphicsView.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/histogramlutwidget.rst000066400000000000000000000002351300727121400260140ustar00rootroot00000000000000HistogramLUTWidget ================== .. autoclass:: pyqtgraph.HistogramLUTWidget :members: .. automethod:: pyqtgraph.HistogramLUTWidget.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/imageview.rst000066400000000000000000000001711300727121400240420ustar00rootroot00000000000000ImageView ========= .. autoclass:: pyqtgraph.ImageView :members: .. automethod:: pyqtgraph.ImageView.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/index.rst000066400000000000000000000015471300727121400232040ustar00rootroot00000000000000.. _api_widgets: PyQtGraph's Widgets =================== PyQtGraph provides several QWidget subclasses which are useful for building user interfaces. These widgets can generally be used in any Qt application and provide functionality that is frequently useful in science and engineering applications. Contents: .. toctree:: :maxdepth: 2 plotwidget imageview dockarea spinbox gradientwidget histogramlutwidget parametertree consolewidget colormapwidget scatterplotwidget graphicsview datatreewidget tablewidget treewidget checktable colorbutton graphicslayoutwidget progressdialog filedialog joystickbutton multiplotwidget verticallabel remotegraphicsview matplotlibwidget feedbackbutton combobox layoutwidget pathbutton valuelabel busycursor pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/joystickbutton.rst000066400000000000000000000002151300727121400251570ustar00rootroot00000000000000JoystickButton ============== .. autoclass:: pyqtgraph.JoystickButton :members: .. automethod:: pyqtgraph.JoystickButton.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/layoutwidget.rst000066400000000000000000000002051300727121400246040ustar00rootroot00000000000000LayoutWidget ============ .. autoclass:: pyqtgraph.LayoutWidget :members: .. automethod:: pyqtgraph.LayoutWidget.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/make000066400000000000000000000007221300727121400221750ustar00rootroot00000000000000files = """CheckTable ColorButton DataTreeWidget FileDialog GradientWidget GraphicsLayoutWidget GraphicsView HistogramLUTWidget JoystickButton MultiPlotWidget PlotWidget ProgressDialog RawImageWidget SpinBox TableWidget TreeWidget VerticalLabel""".split('\n') for f in files: print(f) fh = open(f.lower()+'.rst', 'w') fh.write( """%s %s .. autoclass:: pyqtgraph.%s :members: .. automethod:: pyqtgraph.%s.__init__ """ % (f, '='*len(f), f, f)) pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/matplotlibwidget.rst000066400000000000000000000003071300727121400254410ustar00rootroot00000000000000MatplotlibWidget ================ .. autoclass:: pyqtgraph.widgets.MatplotlibWidget.MatplotlibWidget :members: .. automethod:: pyqtgraph.widgets.MatplotlibWidget.MatplotlibWidget.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/multiplotwidget.rst000066400000000000000000000002211300727121400253160ustar00rootroot00000000000000MultiPlotWidget =============== .. autoclass:: pyqtgraph.MultiPlotWidget :members: .. automethod:: pyqtgraph.MultiPlotWidget.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/parametertree.rst000066400000000000000000000001411300727121400247220ustar00rootroot00000000000000parametertree module ==================== .. automodule:: pyqtgraph.parametertree :members: pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/pathbutton.rst000066400000000000000000000001751300727121400242610ustar00rootroot00000000000000PathButton ========== .. autoclass:: pyqtgraph.PathButton :members: .. automethod:: pyqtgraph.PathButton.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/plotwidget.rst000066400000000000000000000001751300727121400242530ustar00rootroot00000000000000PlotWidget ========== .. autoclass:: pyqtgraph.PlotWidget :members: .. automethod:: pyqtgraph.PlotWidget.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/progressdialog.rst000066400000000000000000000002151300727121400251100ustar00rootroot00000000000000ProgressDialog ============== .. autoclass:: pyqtgraph.ProgressDialog :members: .. automethod:: pyqtgraph.ProgressDialog.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/remotegraphicsview.rst000066400000000000000000000003231300727121400257730ustar00rootroot00000000000000RemoteGraphicsView ================== .. autoclass:: pyqtgraph.widgets.RemoteGraphicsView.RemoteGraphicsView :members: .. automethod:: pyqtgraph.widgets.RemoteGraphicsView.RemoteGraphicsView.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/scatterplotwidget.rst000066400000000000000000000002311300727121400256320ustar00rootroot00000000000000ScatterPlotWidget ================= .. autoclass:: pyqtgraph.ScatterPlotWidget :members: .. automethod:: pyqtgraph.ScatterPlotWidget.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/spinbox.rst000066400000000000000000000001611300727121400235460ustar00rootroot00000000000000SpinBox ======= .. autoclass:: pyqtgraph.SpinBox :members: .. automethod:: pyqtgraph.SpinBox.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/tablewidget.rst000066400000000000000000000002011300727121400243520ustar00rootroot00000000000000TableWidget =========== .. autoclass:: pyqtgraph.TableWidget :members: .. automethod:: pyqtgraph.TableWidget.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/treewidget.rst000066400000000000000000000001751300727121400242340ustar00rootroot00000000000000TreeWidget ========== .. autoclass:: pyqtgraph.TreeWidget :members: .. automethod:: pyqtgraph.TreeWidget.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/valuelabel.rst000066400000000000000000000001751300727121400242050ustar00rootroot00000000000000ValueLabel ========== .. autoclass:: pyqtgraph.ValueLabel :members: .. automethod:: pyqtgraph.ValueLabel.__init__ pyqtgraph-pyqtgraph-0.10.0/doc/source/widgets/verticallabel.rst000066400000000000000000000002111300727121400246710ustar00rootroot00000000000000VerticalLabel ============= .. autoclass:: pyqtgraph.VerticalLabel :members: .. automethod:: pyqtgraph.VerticalLabel.__init__ pyqtgraph-pyqtgraph-0.10.0/examples/000077500000000000000000000000001300727121400174375ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/examples/Arrow.py000066400000000000000000000033331300727121400211050ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Display an animated arrowhead following a curve. This example uses the CurveArrow class, which is a combination of ArrowItem and CurvePoint. To place a static arrow anywhere in a scene, use ArrowItem. To attach other types of item to a curve, use CurvePoint. """ import initExample ## Add path to library (just for examples; you do not need this) import numpy as np from pyqtgraph.Qt import QtGui, QtCore import pyqtgraph as pg app = QtGui.QApplication([]) w = QtGui.QMainWindow() cw = pg.GraphicsLayoutWidget() w.show() w.resize(400,600) w.setCentralWidget(cw) w.setWindowTitle('pyqtgraph example: Arrow') p = cw.addPlot(row=0, col=0) p2 = cw.addPlot(row=1, col=0) ## variety of arrow shapes a1 = pg.ArrowItem(angle=-160, tipAngle=60, headLen=40, tailLen=40, tailWidth=20, pen={'color': 'w', 'width': 3}) a2 = pg.ArrowItem(angle=-120, tipAngle=30, baseAngle=20, headLen=40, tailLen=40, tailWidth=8, pen=None, brush='y') a3 = pg.ArrowItem(angle=-60, tipAngle=30, baseAngle=20, headLen=40, tailLen=None, brush=None) a4 = pg.ArrowItem(angle=-20, tipAngle=30, baseAngle=-30, headLen=40, tailLen=None) a2.setPos(10,0) a3.setPos(20,0) a4.setPos(30,0) p.addItem(a1) p.addItem(a2) p.addItem(a3) p.addItem(a4) p.setRange(QtCore.QRectF(-20, -10, 60, 20)) ## Animated arrow following curve c = p2.plot(x=np.sin(np.linspace(0, 2*np.pi, 1000)), y=np.cos(np.linspace(0, 6*np.pi, 1000))) a = pg.CurveArrow(c) a.setStyle(headLen=40) p2.addItem(a) anim = a.makeAnimation(loop=-1) anim.start() ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/BarGraphItem.py000066400000000000000000000021051300727121400223140ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Simple example using BarGraphItem """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np win = pg.plot() win.setWindowTitle('pyqtgraph example: BarGraphItem') x = np.arange(10) y1 = np.sin(x) y2 = 1.1 * np.sin(x+1) y3 = 1.2 * np.sin(x+2) bg1 = pg.BarGraphItem(x=x, height=y1, width=0.3, brush='r') bg2 = pg.BarGraphItem(x=x+0.33, height=y2, width=0.3, brush='g') bg3 = pg.BarGraphItem(x=x+0.66, height=y3, width=0.3, brush='b') win.addItem(bg1) win.addItem(bg2) win.addItem(bg3) # Final example shows how to handle mouse clicks: class BarGraph(pg.BarGraphItem): def mouseClickEvent(self, event): print("clicked") bg = BarGraph(x=x, y=y1*0.3+2, height=0.4+y1*0.2, width=0.8) win.addItem(bg) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/CLIexample.py000066400000000000000000000016161300727121400220000ustar00rootroot00000000000000""" Display a plot and an image with minimal setup. pg.plot() and pg.image() are indended to be used from an interactive prompt to allow easy data inspection (but note that PySide unfortunately does not call the Qt event loop while the interactive prompt is running, in this case it is necessary to call QApplication.exec_() to make the windows appear). """ import initExample ## Add path to library (just for examples; you do not need this) import numpy as np import pyqtgraph as pg data = np.random.normal(size=1000) pg.plot(data, title="Simplest possible plotting example") data = np.random.normal(size=(500,500)) pg.image(data, title="Simplest possible image example") ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if sys.flags.interactive != 1 or not hasattr(QtCore, 'PYQT_VERSION'): pg.QtGui.QApplication.exec_() pyqtgraph-pyqtgraph-0.10.0/examples/ColorButton.py000066400000000000000000000016301300727121400222630ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Simple example demonstrating a button which displays a colored rectangle and allows the user to select a new color by clicking on the button. """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np app = QtGui.QApplication([]) win = QtGui.QMainWindow() btn = pg.ColorButton() win.setCentralWidget(btn) win.show() win.setWindowTitle('pyqtgraph example: ColorButton') def change(btn): print("change", btn.color()) def done(btn): print("done", btn.color()) btn.sigColorChanging.connect(change) btn.sigColorChanged.connect(done) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/ConsoleWidget.py000066400000000000000000000022141300727121400225560ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ ConsoleWidget is used to allow execution of user-supplied python commands in an application. It also includes a command history and functionality for trapping and inspecting stack traces. """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np import pyqtgraph.console app = pg.mkQApp() ## build an initial namespace for console commands to be executed in (this is optional; ## the user can always import these modules manually) namespace = {'pg': pg, 'np': np} ## initial text to display in the console text = """ This is an interactive python console. The numpy and pyqtgraph modules have already been imported as 'np' and 'pg'. Go, play. """ c = pyqtgraph.console.ConsoleWidget(namespace=namespace, text=text) c.show() c.setWindowTitle('pyqtgraph example: ConsoleWidget') ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/CustomGraphItem.py000066400000000000000000000071561300727121400230750ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Simple example of subclassing GraphItem. """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np # Enable antialiasing for prettier plots pg.setConfigOptions(antialias=True) w = pg.GraphicsWindow() w.setWindowTitle('pyqtgraph example: CustomGraphItem') v = w.addViewBox() v.setAspectLocked() class Graph(pg.GraphItem): def __init__(self): self.dragPoint = None self.dragOffset = None self.textItems = [] pg.GraphItem.__init__(self) self.scatter.sigClicked.connect(self.clicked) def setData(self, **kwds): self.text = kwds.pop('text', []) self.data = kwds if 'pos' in self.data: npts = self.data['pos'].shape[0] self.data['data'] = np.empty(npts, dtype=[('index', int)]) self.data['data']['index'] = np.arange(npts) self.setTexts(self.text) self.updateGraph() def setTexts(self, text): for i in self.textItems: i.scene().removeItem(i) self.textItems = [] for t in text: item = pg.TextItem(t) self.textItems.append(item) item.setParentItem(self) def updateGraph(self): pg.GraphItem.setData(self, **self.data) for i,item in enumerate(self.textItems): item.setPos(*self.data['pos'][i]) def mouseDragEvent(self, ev): if ev.button() != QtCore.Qt.LeftButton: ev.ignore() return if ev.isStart(): # We are already one step into the drag. # Find the point(s) at the mouse cursor when the button was first # pressed: pos = ev.buttonDownPos() pts = self.scatter.pointsAt(pos) if len(pts) == 0: ev.ignore() return self.dragPoint = pts[0] ind = pts[0].data()[0] self.dragOffset = self.data['pos'][ind] - pos elif ev.isFinish(): self.dragPoint = None return else: if self.dragPoint is None: ev.ignore() return ind = self.dragPoint.data()[0] self.data['pos'][ind] = ev.pos() + self.dragOffset self.updateGraph() ev.accept() def clicked(self, pts): print("clicked: %s" % pts) g = Graph() v.addItem(g) ## Define positions of nodes pos = np.array([ [0,0], [10,0], [0,10], [10,10], [5,5], [15,5] ], dtype=float) ## Define the set of connections in the graph adj = np.array([ [0,1], [1,3], [3,2], [2,0], [1,5], [3,5], ]) ## Define the symbol to use for each node (this is optional) symbols = ['o','o','o','o','t','+'] ## Define the line style for each connection (this is optional) lines = np.array([ (255,0,0,255,1), (255,0,255,255,2), (255,0,255,255,3), (255,255,0,255,2), (255,0,0,255,1), (255,255,255,255,4), ], dtype=[('red',np.ubyte),('green',np.ubyte),('blue',np.ubyte),('alpha',np.ubyte),('width',float)]) ## Define text to show next to each symbol texts = ["Point %d" % i for i in range(6)] ## Update the graph g.setData(pos=pos, adj=adj, pen=lines, size=1, symbol=symbols, pxMode=False, text=texts) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/DataSlicing.py000066400000000000000000000033341300727121400221760ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Demonstrate a simple data-slicing task: given 3D data (displayed at top), select a 2D plane and interpolate data along that plane to generate a slice image (displayed at bottom). """ ## Add path to library (just for examples; you do not need this) import initExample import numpy as np from pyqtgraph.Qt import QtCore, QtGui import pyqtgraph as pg app = QtGui.QApplication([]) ## Create window with two ImageView widgets win = QtGui.QMainWindow() win.resize(800,800) win.setWindowTitle('pyqtgraph example: DataSlicing') cw = QtGui.QWidget() win.setCentralWidget(cw) l = QtGui.QGridLayout() cw.setLayout(l) imv1 = pg.ImageView() imv2 = pg.ImageView() l.addWidget(imv1, 0, 0) l.addWidget(imv2, 1, 0) win.show() roi = pg.LineSegmentROI([[10, 64], [120,64]], pen='r') imv1.addItem(roi) x1 = np.linspace(-30, 10, 128)[:, np.newaxis, np.newaxis] x2 = np.linspace(-20, 20, 128)[:, np.newaxis, np.newaxis] y = np.linspace(-30, 10, 128)[np.newaxis, :, np.newaxis] z = np.linspace(-20, 20, 128)[np.newaxis, np.newaxis, :] d1 = np.sqrt(x1**2 + y**2 + z**2) d2 = 2*np.sqrt(x1[::-1]**2 + y**2 + z**2) d3 = 4*np.sqrt(x2**2 + y[:,::-1]**2 + z**2) data = (np.sin(d1) / d1**2) + (np.sin(d2) / d2**2) + (np.sin(d3) / d3**2) def update(): global data, imv1, imv2 d2 = roi.getArrayRegion(data, imv1.imageItem, axes=(1,2)) imv2.setImage(d2) roi.sigRegionChanged.connect(update) ## Display the data imv1.setImage(data) imv1.setHistogramRange(-0.01, 0.01) imv1.setLevels(-0.003, 0.003) update() ## Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/DataTreeWidget.py000066400000000000000000000015631300727121400226530ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Simple use of DataTreeWidget to display a structure of nested dicts, lists, and arrays """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np app = QtGui.QApplication([]) d = { 'list1': [1,2,3,4,5,6, {'nested1': 'aaaaa', 'nested2': 'bbbbb'}, "seven"], 'dict1': { 'x': 1, 'y': 2, 'z': 'three' }, 'array1 (20x20)': np.ones((10,10)) } tree = pg.DataTreeWidget(data=d) tree.show() tree.setWindowTitle('pyqtgraph example: DataTreeWidget') tree.resize(600,600) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_()pyqtgraph-pyqtgraph-0.10.0/examples/Draw.py000066400000000000000000000021661300727121400207130ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Demonstrate ability of ImageItem to be used as a canvas for painting with the mouse. """ import initExample ## Add path to library (just for examples; you do not need this) from pyqtgraph.Qt import QtCore, QtGui import numpy as np import pyqtgraph as pg app = QtGui.QApplication([]) ## Create window with GraphicsView widget w = pg.GraphicsView() w.show() w.resize(800,800) w.setWindowTitle('pyqtgraph example: Draw') view = pg.ViewBox() w.setCentralItem(view) ## lock the aspect ratio view.setAspectLocked(True) ## Create image item img = pg.ImageItem(np.zeros((200,200))) view.addItem(img) ## Set initial view bounds view.setRange(QtCore.QRectF(0, 0, 200, 200)) ## start drawing with 3x3 brush kern = np.array([ [0.0, 0.5, 0.0], [0.5, 1.0, 0.5], [0.0, 0.5, 0.0] ]) img.setDrawKernel(kern, mask=kern, center=(1,1), mode='add') img.setLevels([0, 10]) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/ErrorBarItem.py000066400000000000000000000015551300727121400223540ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Demonstrates basic use of ErrorBarItem """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtGui, QtCore import numpy as np import pyqtgraph as pg import numpy as np pg.setConfigOptions(antialias=True) x = np.arange(10) y = np.arange(10) %3 top = np.linspace(1.0, 3.0, 10) bottom = np.linspace(2, 0.5, 10) plt = pg.plot() plt.setWindowTitle('pyqtgraph example: ErrorBarItem') err = pg.ErrorBarItem(x=x, y=y, top=top, bottom=bottom, beam=0.5) plt.addItem(err) plt.plot(x, y, symbol='o', pen={'color': 0.8, 'width': 2}) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/FillBetweenItem.py000066400000000000000000000030061300727121400230270ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Demonstrates use of FillBetweenItem to fill the space between two plot curves. """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtGui, QtCore import numpy as np #FIXME: When running on Qt5, not as perfect as on Qt4 win = pg.plot() win.setWindowTitle('pyqtgraph example: FillBetweenItem') win.setXRange(-10, 10) win.setYRange(-10, 10) N = 200 x = np.linspace(-10, 10, N) gauss = np.exp(-x**2 / 20.) mn = mx = np.zeros(len(x)) curves = [win.plot(x=x, y=np.zeros(len(x)), pen='k') for i in range(4)] brushes = [0.5, (100, 100, 255), 0.5] fills = [pg.FillBetweenItem(curves[i], curves[i+1], brushes[i]) for i in range(3)] for f in fills: win.addItem(f) def update(): global mx, mn, curves, gauss, x a = 5 / abs(np.random.normal(loc=1, scale=0.2)) y1 = -np.abs(a*gauss + np.random.normal(size=len(x))) y2 = np.abs(a*gauss + np.random.normal(size=len(x))) s = 0.01 mn = np.where(y1mx, y2, mx) * (1-s) + y2 * s curves[0].setData(x, mn) curves[1].setData(x, y1) curves[2].setData(x, y2) curves[3].setData(x, mx) timer = QtCore.QTimer() timer.timeout.connect(update) timer.start(30) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/Flowchart.py000066400000000000000000000050021300727121400217370ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ This example demonstrates a very basic use of flowcharts: filter data, displaying both the input and output of the filter. The behavior of the filter can be reprogrammed by the user. Basic steps are: - create a flowchart and two plots - input noisy data to the flowchart - flowchart connects data to the first plot, where it is displayed - add a gaussian filter to lowpass the data, then display it in the second plot. """ import initExample ## Add path to library (just for examples; you do not need this) from pyqtgraph.flowchart import Flowchart from pyqtgraph.Qt import QtGui, QtCore import pyqtgraph as pg import numpy as np import pyqtgraph.metaarray as metaarray app = QtGui.QApplication([]) ## Create main window with grid layout win = QtGui.QMainWindow() win.setWindowTitle('pyqtgraph example: Flowchart') cw = QtGui.QWidget() win.setCentralWidget(cw) layout = QtGui.QGridLayout() cw.setLayout(layout) ## Create flowchart, define input/output terminals fc = Flowchart(terminals={ 'dataIn': {'io': 'in'}, 'dataOut': {'io': 'out'} }) w = fc.widget() ## Add flowchart control panel to the main window layout.addWidget(fc.widget(), 0, 0, 2, 1) ## Add two plot widgets pw1 = pg.PlotWidget() pw2 = pg.PlotWidget() layout.addWidget(pw1, 0, 1) layout.addWidget(pw2, 1, 1) win.show() ## generate signal data to pass through the flowchart data = np.random.normal(size=1000) data[200:300] += 1 data += np.sin(np.linspace(0, 100, 1000)) data = metaarray.MetaArray(data, info=[{'name': 'Time', 'values': np.linspace(0, 1.0, len(data))}, {}]) ## Feed data into the input terminal of the flowchart fc.setInput(dataIn=data) ## populate the flowchart with a basic set of processing nodes. ## (usually we let the user do this) plotList = {'Top Plot': pw1, 'Bottom Plot': pw2} pw1Node = fc.createNode('PlotWidget', pos=(0, -150)) pw1Node.setPlotList(plotList) pw1Node.setPlot(pw1) pw2Node = fc.createNode('PlotWidget', pos=(150, -150)) pw2Node.setPlot(pw2) pw2Node.setPlotList(plotList) fNode = fc.createNode('GaussianFilter', pos=(0, 0)) fNode.ctrls['sigma'].setValue(5) fc.connectTerminals(fc['dataIn'], fNode['In']) fc.connectTerminals(fc['dataIn'], pw1Node['In']) fc.connectTerminals(fNode['Out'], pw2Node['In']) fc.connectTerminals(fNode['Out'], fc['dataOut']) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/FlowchartCustomNode.py000066400000000000000000000135041300727121400237460ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ This example demonstrates writing a custom Node subclass for use with flowcharts. We implement a couple of simple image processing nodes. """ import initExample ## Add path to library (just for examples; you do not need this) from pyqtgraph.flowchart import Flowchart, Node import pyqtgraph.flowchart.library as fclib from pyqtgraph.flowchart.library.common import CtrlNode from pyqtgraph.Qt import QtGui, QtCore import pyqtgraph as pg import numpy as np app = QtGui.QApplication([]) ## Create main window with a grid layout inside win = QtGui.QMainWindow() win.setWindowTitle('pyqtgraph example: FlowchartCustomNode') cw = QtGui.QWidget() win.setCentralWidget(cw) layout = QtGui.QGridLayout() cw.setLayout(layout) ## Create an empty flowchart with a single input and output fc = Flowchart(terminals={ 'dataIn': {'io': 'in'}, 'dataOut': {'io': 'out'} }) w = fc.widget() layout.addWidget(fc.widget(), 0, 0, 2, 1) ## Create two ImageView widgets to display the raw and processed data with contrast ## and color control. v1 = pg.ImageView() v2 = pg.ImageView() layout.addWidget(v1, 0, 1) layout.addWidget(v2, 1, 1) win.show() ## generate random input data data = np.random.normal(size=(100,100)) data = 25 * pg.gaussianFilter(data, (5,5)) data += np.random.normal(size=(100,100)) data[40:60, 40:60] += 15.0 data[30:50, 30:50] += 15.0 #data += np.sin(np.linspace(0, 100, 1000)) #data = metaarray.MetaArray(data, info=[{'name': 'Time', 'values': np.linspace(0, 1.0, len(data))}, {}]) ## Set the raw data as the input value to the flowchart fc.setInput(dataIn=data) ## At this point, we need some custom Node classes since those provided in the library ## are not sufficient. Each node will define a set of input/output terminals, a ## processing function, and optionally a control widget (to be displayed in the ## flowchart control panel) class ImageViewNode(Node): """Node that displays image data in an ImageView widget""" nodeName = 'ImageView' def __init__(self, name): self.view = None ## Initialize node with only a single input terminal Node.__init__(self, name, terminals={'data': {'io':'in'}}) def setView(self, view): ## setView must be called by the program self.view = view def process(self, data, display=True): ## if process is called with display=False, then the flowchart is being operated ## in batch processing mode, so we should skip displaying to improve performance. if display and self.view is not None: ## the 'data' argument is the value given to the 'data' terminal if data is None: self.view.setImage(np.zeros((1,1))) # give a blank array to clear the view else: self.view.setImage(data) ## We will define an unsharp masking filter node as a subclass of CtrlNode. ## CtrlNode is just a convenience class that automatically creates its ## control widget based on a simple data structure. class UnsharpMaskNode(CtrlNode): """Return the input data passed through an unsharp mask.""" nodeName = "UnsharpMask" uiTemplate = [ ('sigma', 'spin', {'value': 1.0, 'step': 1.0, 'bounds': [0.0, None]}), ('strength', 'spin', {'value': 1.0, 'dec': True, 'step': 0.5, 'minStep': 0.01, 'bounds': [0.0, None]}), ] def __init__(self, name): ## Define the input / output terminals available on this node terminals = { 'dataIn': dict(io='in'), # each terminal needs at least a name and 'dataOut': dict(io='out'), # to specify whether it is input or output } # other more advanced options are available # as well.. CtrlNode.__init__(self, name, terminals=terminals) def process(self, dataIn, display=True): # CtrlNode has created self.ctrls, which is a dict containing {ctrlName: widget} sigma = self.ctrls['sigma'].value() strength = self.ctrls['strength'].value() output = dataIn - (strength * pg.gaussianFilter(dataIn, (sigma,sigma))) return {'dataOut': output} ## To make our custom node classes available in the flowchart context menu, ## we can either register them with the default node library or make a ## new library. ## Method 1: Register to global default library: #fclib.registerNodeType(ImageViewNode, [('Display',)]) #fclib.registerNodeType(UnsharpMaskNode, [('Image',)]) ## Method 2: If we want to make our custom node available only to this flowchart, ## then instead of registering the node type globally, we can create a new ## NodeLibrary: library = fclib.LIBRARY.copy() # start with the default node set library.addNodeType(ImageViewNode, [('Display',)]) # Add the unsharp mask node to two locations in the menu to demonstrate # that we can create arbitrary menu structures library.addNodeType(UnsharpMaskNode, [('Image',), ('Submenu_test','submenu2','submenu3')]) fc.setLibrary(library) ## Now we will programmatically add nodes to define the function of the flowchart. ## Normally, the user will do this manually or by loading a pre-generated ## flowchart file. v1Node = fc.createNode('ImageView', pos=(0, -150)) v1Node.setView(v1) v2Node = fc.createNode('ImageView', pos=(150, -150)) v2Node.setView(v2) fNode = fc.createNode('UnsharpMask', pos=(0, 0)) fc.connectTerminals(fc['dataIn'], fNode['dataIn']) fc.connectTerminals(fc['dataIn'], v1Node['data']) fc.connectTerminals(fNode['dataOut'], v2Node['data']) fc.connectTerminals(fNode['dataOut'], fc['dataOut']) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/GLBarGraphItem.py000066400000000000000000000022141300727121400225400ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Demonstrate use of GLLinePlotItem to draw cross-sections of a surface. """ ## Add path to library (just for examples; you do not need this) import initExample from pyqtgraph.Qt import QtCore, QtGui import pyqtgraph.opengl as gl import pyqtgraph as pg import numpy as np app = QtGui.QApplication([]) w = gl.GLViewWidget() w.opts['distance'] = 40 w.show() w.setWindowTitle('pyqtgraph example: GLBarGraphItem') gx = gl.GLGridItem() gx.rotate(90, 0, 1, 0) gx.translate(-10, 0, 10) w.addItem(gx) gy = gl.GLGridItem() gy.rotate(90, 1, 0, 0) gy.translate(0, -10, 10) w.addItem(gy) gz = gl.GLGridItem() gz.translate(0, 0, 0) w.addItem(gz) # regular grid of starting positions pos = np.mgrid[0:10, 0:10, 0:1].reshape(3,10,10).transpose(1,2,0) # fixed widths, random heights size = np.empty((10,10,3)) size[...,0:2] = 0.4 size[...,2] = np.random.normal(size=(10,10)) bg = gl.GLBarGraphItem(pos, size) w.addItem(bg) ## Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/GLImageItem.py000066400000000000000000000033221300727121400220750ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Use GLImageItem to display image data on rectangular planes. In this example, the image data is sampled from a volume and the image planes placed as if they slice through the volume. """ ## Add path to library (just for examples; you do not need this) import initExample from pyqtgraph.Qt import QtCore, QtGui import pyqtgraph.opengl as gl import pyqtgraph as pg import numpy as np app = QtGui.QApplication([]) w = gl.GLViewWidget() w.opts['distance'] = 200 w.show() w.setWindowTitle('pyqtgraph example: GLImageItem') ## create volume data set to slice three images from shape = (100,100,70) data = pg.gaussianFilter(np.random.normal(size=shape), (4,4,4)) data += pg.gaussianFilter(np.random.normal(size=shape), (15,15,15))*15 ## slice out three planes, convert to RGBA for OpenGL texture levels = (-0.08, 0.08) tex1 = pg.makeRGBA(data[shape[0]/2], levels=levels)[0] # yz plane tex2 = pg.makeRGBA(data[:,shape[1]/2], levels=levels)[0] # xz plane tex3 = pg.makeRGBA(data[:,:,shape[2]/2], levels=levels)[0] # xy plane #tex1[:,:,3] = 128 #tex2[:,:,3] = 128 #tex3[:,:,3] = 128 ## Create three image items from textures, add to view v1 = gl.GLImageItem(tex1) v1.translate(-shape[1]/2, -shape[2]/2, 0) v1.rotate(90, 0,0,1) v1.rotate(-90, 0,1,0) w.addItem(v1) v2 = gl.GLImageItem(tex2) v2.translate(-shape[0]/2, -shape[2]/2, 0) v2.rotate(-90, 1,0,0) w.addItem(v2) v3 = gl.GLImageItem(tex3) v3.translate(-shape[0]/2, -shape[1]/2, 0) w.addItem(v3) ax = gl.GLAxisItem() w.addItem(ax) ## Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/GLIsosurface.py000066400000000000000000000040461300727121400223430ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ This example uses the isosurface function to convert a scalar field (a hydrogen orbital) into a mesh for 3D display. """ ## Add path to library (just for examples; you do not need this) import initExample from pyqtgraph.Qt import QtCore, QtGui import pyqtgraph as pg import pyqtgraph.opengl as gl app = QtGui.QApplication([]) w = gl.GLViewWidget() w.show() w.setWindowTitle('pyqtgraph example: GLIsosurface') w.setCameraPosition(distance=40) g = gl.GLGridItem() g.scale(2,2,1) w.addItem(g) import numpy as np ## Define a scalar field from which we will generate an isosurface def psi(i, j, k, offset=(25, 25, 50)): x = i-offset[0] y = j-offset[1] z = k-offset[2] th = np.arctan2(z, (x**2+y**2)**0.5) phi = np.arctan2(y, x) r = (x**2 + y**2 + z **2)**0.5 a0 = 1 #ps = (1./81.) * (2./np.pi)**0.5 * (1./a0)**(3/2) * (6 - r/a0) * (r/a0) * np.exp(-r/(3*a0)) * np.cos(th) ps = (1./81.) * 1./(6.*np.pi)**0.5 * (1./a0)**(3/2) * (r/a0)**2 * np.exp(-r/(3*a0)) * (3 * np.cos(th)**2 - 1) return ps #return ((1./81.) * (1./np.pi)**0.5 * (1./a0)**(3/2) * (r/a0)**2 * (r/a0) * np.exp(-r/(3*a0)) * np.sin(th) * np.cos(th) * np.exp(2 * 1j * phi))**2 print("Generating scalar field..") data = np.abs(np.fromfunction(psi, (50,50,100))) print("Generating isosurface..") verts, faces = pg.isosurface(data, data.max()/4.) md = gl.MeshData(vertexes=verts, faces=faces) colors = np.ones((md.faceCount(), 4), dtype=float) colors[:,3] = 0.2 colors[:,2] = np.linspace(0, 1, colors.shape[0]) md.setFaceColors(colors) m1 = gl.GLMeshItem(meshdata=md, smooth=False, shader='balloon') m1.setGLOptions('additive') #w.addItem(m1) m1.translate(-25, -25, -20) m2 = gl.GLMeshItem(meshdata=md, smooth=True, shader='balloon') m2.setGLOptions('additive') w.addItem(m2) m2.translate(-25, -25, -50) ## Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/GLLinePlotItem.py000066400000000000000000000023741300727121400226070ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Demonstrate use of GLLinePlotItem to draw cross-sections of a surface. """ ## Add path to library (just for examples; you do not need this) import initExample from pyqtgraph.Qt import QtCore, QtGui import pyqtgraph.opengl as gl import pyqtgraph as pg import numpy as np app = QtGui.QApplication([]) w = gl.GLViewWidget() w.opts['distance'] = 40 w.show() w.setWindowTitle('pyqtgraph example: GLLinePlotItem') gx = gl.GLGridItem() gx.rotate(90, 0, 1, 0) gx.translate(-10, 0, 0) w.addItem(gx) gy = gl.GLGridItem() gy.rotate(90, 1, 0, 0) gy.translate(0, -10, 0) w.addItem(gy) gz = gl.GLGridItem() gz.translate(0, 0, -10) w.addItem(gz) def fn(x, y): return np.cos((x**2 + y**2)**0.5) n = 51 y = np.linspace(-10,10,n) x = np.linspace(-10,10,100) for i in range(n): yi = np.array([y[i]]*100) d = (x**2 + yi**2)**0.5 z = 10 * np.cos(d) / (d+1) pts = np.vstack([x,yi,z]).transpose() plt = gl.GLLinePlotItem(pos=pts, color=pg.glColor((i,n*1.3)), width=(i+1)/10., antialias=True) w.addItem(plt) ## Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/GLMeshItem.py000066400000000000000000000063431300727121400217550ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Simple examples demonstrating the use of GLMeshItem. """ ## Add path to library (just for examples; you do not need this) import initExample from pyqtgraph.Qt import QtCore, QtGui import pyqtgraph as pg import pyqtgraph.opengl as gl app = QtGui.QApplication([]) w = gl.GLViewWidget() w.show() w.setWindowTitle('pyqtgraph example: GLMeshItem') w.setCameraPosition(distance=40) g = gl.GLGridItem() g.scale(2,2,1) w.addItem(g) import numpy as np ## Example 1: ## Array of vertex positions and array of vertex indexes defining faces ## Colors are specified per-face verts = np.array([ [0, 0, 0], [2, 0, 0], [1, 2, 0], [1, 1, 1], ]) faces = np.array([ [0, 1, 2], [0, 1, 3], [0, 2, 3], [1, 2, 3] ]) colors = np.array([ [1, 0, 0, 0.3], [0, 1, 0, 0.3], [0, 0, 1, 0.3], [1, 1, 0, 0.3] ]) ## Mesh item will automatically compute face normals. m1 = gl.GLMeshItem(vertexes=verts, faces=faces, faceColors=colors, smooth=False) m1.translate(5, 5, 0) m1.setGLOptions('additive') w.addItem(m1) ## Example 2: ## Array of vertex positions, three per face verts = np.empty((36, 3, 3), dtype=np.float32) theta = np.linspace(0, 2*np.pi, 37)[:-1] verts[:,0] = np.vstack([2*np.cos(theta), 2*np.sin(theta), [0]*36]).T verts[:,1] = np.vstack([4*np.cos(theta+0.2), 4*np.sin(theta+0.2), [-1]*36]).T verts[:,2] = np.vstack([4*np.cos(theta-0.2), 4*np.sin(theta-0.2), [1]*36]).T ## Colors are specified per-vertex colors = np.random.random(size=(verts.shape[0], 3, 4)) m2 = gl.GLMeshItem(vertexes=verts, vertexColors=colors, smooth=False, shader='balloon', drawEdges=True, edgeColor=(1, 1, 0, 1)) m2.translate(-5, 5, 0) w.addItem(m2) ## Example 3: ## sphere md = gl.MeshData.sphere(rows=10, cols=20) #colors = np.random.random(size=(md.faceCount(), 4)) #colors[:,3] = 0.3 #colors[100:] = 0.0 colors = np.ones((md.faceCount(), 4), dtype=float) colors[::2,0] = 0 colors[:,1] = np.linspace(0, 1, colors.shape[0]) md.setFaceColors(colors) m3 = gl.GLMeshItem(meshdata=md, smooth=False)#, shader='balloon') m3.translate(5, -5, 0) w.addItem(m3) # Example 4: # wireframe md = gl.MeshData.sphere(rows=4, cols=8) m4 = gl.GLMeshItem(meshdata=md, smooth=False, drawFaces=False, drawEdges=True, edgeColor=(1,1,1,1)) m4.translate(0,10,0) w.addItem(m4) # Example 5: # cylinder md = gl.MeshData.cylinder(rows=10, cols=20, radius=[1., 2.0], length=5.) md2 = gl.MeshData.cylinder(rows=10, cols=20, radius=[2., 0.5], length=10.) colors = np.ones((md.faceCount(), 4), dtype=float) colors[::2,0] = 0 colors[:,1] = np.linspace(0, 1, colors.shape[0]) md.setFaceColors(colors) m5 = gl.GLMeshItem(meshdata=md, smooth=True, drawEdges=True, edgeColor=(1,0,0,1), shader='balloon') colors = np.ones((md.faceCount(), 4), dtype=float) colors[::2,0] = 0 colors[:,1] = np.linspace(0, 1, colors.shape[0]) md2.setFaceColors(colors) m6 = gl.GLMeshItem(meshdata=md2, smooth=True, drawEdges=False, shader='balloon') m6.translate(0,0,7.5) m6.rotate(0., 0, 1, 1) #m5.translate(-3,3,0) w.addItem(m5) w.addItem(m6) ## Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/GLScatterPlotItem.py000066400000000000000000000054601300727121400233240ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Demonstrates use of GLScatterPlotItem with rapidly-updating plots. """ ## Add path to library (just for examples; you do not need this) import initExample from pyqtgraph.Qt import QtCore, QtGui import pyqtgraph.opengl as gl import numpy as np app = QtGui.QApplication([]) w = gl.GLViewWidget() w.opts['distance'] = 20 w.show() w.setWindowTitle('pyqtgraph example: GLScatterPlotItem') g = gl.GLGridItem() w.addItem(g) ## ## First example is a set of points with pxMode=False ## These demonstrate the ability to have points with real size down to a very small scale ## pos = np.empty((53, 3)) size = np.empty((53)) color = np.empty((53, 4)) pos[0] = (1,0,0); size[0] = 0.5; color[0] = (1.0, 0.0, 0.0, 0.5) pos[1] = (0,1,0); size[1] = 0.2; color[1] = (0.0, 0.0, 1.0, 0.5) pos[2] = (0,0,1); size[2] = 2./3.; color[2] = (0.0, 1.0, 0.0, 0.5) z = 0.5 d = 6.0 for i in range(3,53): pos[i] = (0,0,z) size[i] = 2./d color[i] = (0.0, 1.0, 0.0, 0.5) z *= 0.5 d *= 2.0 sp1 = gl.GLScatterPlotItem(pos=pos, size=size, color=color, pxMode=False) sp1.translate(5,5,0) w.addItem(sp1) ## ## Second example shows a volume of points with rapidly updating color ## and pxMode=True ## pos = np.random.random(size=(100000,3)) pos *= [10,-10,10] pos[0] = (0,0,0) color = np.ones((pos.shape[0], 4)) d2 = (pos**2).sum(axis=1)**0.5 size = np.random.random(size=pos.shape[0])*10 sp2 = gl.GLScatterPlotItem(pos=pos, color=(1,1,1,1), size=size) phase = 0. w.addItem(sp2) ## ## Third example shows a grid of points with rapidly updating position ## and pxMode = False ## pos3 = np.zeros((100,100,3)) pos3[:,:,:2] = np.mgrid[:100, :100].transpose(1,2,0) * [-0.1,0.1] pos3 = pos3.reshape(10000,3) d3 = (pos3**2).sum(axis=1)**0.5 sp3 = gl.GLScatterPlotItem(pos=pos3, color=(1,1,1,.3), size=0.1, pxMode=False) w.addItem(sp3) def update(): ## update volume colors global phase, sp2, d2 s = -np.cos(d2*2+phase) color = np.empty((len(d2),4), dtype=np.float32) color[:,3] = np.clip(s * 0.1, 0, 1) color[:,0] = np.clip(s * 3.0, 0, 1) color[:,1] = np.clip(s * 1.0, 0, 1) color[:,2] = np.clip(s ** 3, 0, 1) sp2.setData(color=color) phase -= 0.1 ## update surface positions and colors global sp3, d3, pos3 z = -np.cos(d3*2+phase) pos3[:,2] = z color = np.empty((len(d3),4), dtype=np.float32) color[:,3] = 0.3 color[:,0] = np.clip(z * 3.0, 0, 1) color[:,1] = np.clip(z * 1.0, 0, 1) color[:,2] = np.clip(z ** 3, 0, 1) sp3.setData(pos=pos3, color=color) t = QtCore.QTimer() t.timeout.connect(update) t.start(50) ## Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/GLSurfacePlot.py000066400000000000000000000054621300727121400224720ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ This example demonstrates the use of GLSurfacePlotItem. """ ## Add path to library (just for examples; you do not need this) import initExample from pyqtgraph.Qt import QtCore, QtGui import pyqtgraph as pg import pyqtgraph.opengl as gl import numpy as np ## Create a GL View widget to display data app = QtGui.QApplication([]) w = gl.GLViewWidget() w.show() w.setWindowTitle('pyqtgraph example: GLSurfacePlot') w.setCameraPosition(distance=50) ## Add a grid to the view g = gl.GLGridItem() g.scale(2,2,1) g.setDepthValue(10) # draw grid after surfaces since they may be translucent w.addItem(g) ## Simple surface plot example ## x, y values are not specified, so assumed to be 0:50 z = pg.gaussianFilter(np.random.normal(size=(50,50)), (1,1)) p1 = gl.GLSurfacePlotItem(z=z, shader='shaded', color=(0.5, 0.5, 1, 1)) p1.scale(16./49., 16./49., 1.0) p1.translate(-18, 2, 0) w.addItem(p1) ## Saddle example with x and y specified x = np.linspace(-8, 8, 50) y = np.linspace(-8, 8, 50) z = 0.1 * ((x.reshape(50,1) ** 2) - (y.reshape(1,50) ** 2)) p2 = gl.GLSurfacePlotItem(x=x, y=y, z=z, shader='normalColor') p2.translate(-10,-10,0) w.addItem(p2) ## Manually specified colors z = pg.gaussianFilter(np.random.normal(size=(50,50)), (1,1)) x = np.linspace(-12, 12, 50) y = np.linspace(-12, 12, 50) colors = np.ones((50,50,4), dtype=float) colors[...,0] = np.clip(np.cos(((x.reshape(50,1) ** 2) + (y.reshape(1,50) ** 2)) ** 0.5), 0, 1) colors[...,1] = colors[...,0] p3 = gl.GLSurfacePlotItem(z=z, colors=colors.reshape(50*50,4), shader='shaded', smooth=False) p3.scale(16./49., 16./49., 1.0) p3.translate(2, -18, 0) w.addItem(p3) ## Animated example ## compute surface vertex data cols = 90 rows = 100 x = np.linspace(-8, 8, cols+1).reshape(cols+1,1) y = np.linspace(-8, 8, rows+1).reshape(1,rows+1) d = (x**2 + y**2) * 0.1 d2 = d ** 0.5 + 0.1 ## precompute height values for all frames phi = np.arange(0, np.pi*2, np.pi/20.) z = np.sin(d[np.newaxis,...] + phi.reshape(phi.shape[0], 1, 1)) / d2[np.newaxis,...] ## create a surface plot, tell it to use the 'heightColor' shader ## since this does not require normal vectors to render (thus we ## can set computeNormals=False to save time when the mesh updates) p4 = gl.GLSurfacePlotItem(x=x[:,0], y = y[0,:], shader='heightColor', computeNormals=False, smooth=False) p4.shader()['colorMap'] = np.array([0.2, 2, 0.5, 0.2, 1, 1, 0.2, 0, 2]) p4.translate(10, 10, 0) w.addItem(p4) index = 0 def update(): global p4, z, index index -= 1 p4.setData(z=z[index%z.shape[0]]) timer = QtCore.QTimer() timer.timeout.connect(update) timer.start(30) ## Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/GLViewWidget.py000066400000000000000000000014051300727121400223120ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Very basic 3D graphics example; create a view widget and add a few items. """ ## Add path to library (just for examples; you do not need this) import initExample from pyqtgraph.Qt import QtCore, QtGui import pyqtgraph.opengl as gl app = QtGui.QApplication([]) w = gl.GLViewWidget() w.opts['distance'] = 20 w.show() w.setWindowTitle('pyqtgraph example: GLViewWidget') ax = gl.GLAxisItem() ax.setSize(5,5,5) w.addItem(ax) b = gl.GLBoxItem() w.addItem(b) ax2 = gl.GLAxisItem() ax2.setParentItem(b) b.translate(1,1,1) ## Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/GLVolumeItem.py000066400000000000000000000036601300727121400223270ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Demonstrates GLVolumeItem for displaying volumetric data. """ ## Add path to library (just for examples; you do not need this) import initExample from pyqtgraph.Qt import QtCore, QtGui import pyqtgraph.opengl as gl app = QtGui.QApplication([]) w = gl.GLViewWidget() w.opts['distance'] = 200 w.show() w.setWindowTitle('pyqtgraph example: GLVolumeItem') #b = gl.GLBoxItem() #w.addItem(b) g = gl.GLGridItem() g.scale(10, 10, 1) w.addItem(g) import numpy as np ## Hydrogen electron probability density def psi(i, j, k, offset=(50,50,100)): x = i-offset[0] y = j-offset[1] z = k-offset[2] th = np.arctan2(z, (x**2+y**2)**0.5) phi = np.arctan2(y, x) r = (x**2 + y**2 + z **2)**0.5 a0 = 2 #ps = (1./81.) * (2./np.pi)**0.5 * (1./a0)**(3/2) * (6 - r/a0) * (r/a0) * np.exp(-r/(3*a0)) * np.cos(th) ps = (1./81.) * 1./(6.*np.pi)**0.5 * (1./a0)**(3/2) * (r/a0)**2 * np.exp(-r/(3*a0)) * (3 * np.cos(th)**2 - 1) return ps #return ((1./81.) * (1./np.pi)**0.5 * (1./a0)**(3/2) * (r/a0)**2 * (r/a0) * np.exp(-r/(3*a0)) * np.sin(th) * np.cos(th) * np.exp(2 * 1j * phi))**2 data = np.fromfunction(psi, (100,100,200)) positive = np.log(np.clip(data, 0, data.max())**2) negative = np.log(np.clip(-data, 0, -data.min())**2) d2 = np.empty(data.shape + (4,), dtype=np.ubyte) d2[..., 0] = positive * (255./positive.max()) d2[..., 1] = negative * (255./negative.max()) d2[..., 2] = d2[...,1] d2[..., 3] = d2[..., 0]*0.3 + d2[..., 1]*0.3 d2[..., 3] = (d2[..., 3].astype(float) / 255.) **2 * 255 d2[:, 0, 0] = [255,0,0,100] d2[0, :, 0] = [0,255,0,100] d2[0, 0, :] = [0,0,255,100] v = gl.GLVolumeItem(d2) v.translate(-50,-50,-100) w.addItem(v) ax = gl.GLAxisItem() w.addItem(ax) ## Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/GLshaders.py000066400000000000000000000060231300727121400216660ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Demonstration of some of the shader programs included with pyqtgraph that can be used to affect the appearance of a surface. """ ## Add path to library (just for examples; you do not need this) import initExample from pyqtgraph.Qt import QtCore, QtGui import pyqtgraph as pg import pyqtgraph.opengl as gl app = QtGui.QApplication([]) w = gl.GLViewWidget() w.show() w.setWindowTitle('pyqtgraph example: GL Shaders') w.setCameraPosition(distance=15, azimuth=-90) g = gl.GLGridItem() g.scale(2,2,1) w.addItem(g) import numpy as np md = gl.MeshData.sphere(rows=10, cols=20) x = np.linspace(-8, 8, 6) m1 = gl.GLMeshItem(meshdata=md, smooth=True, color=(1, 0, 0, 0.2), shader='balloon', glOptions='additive') m1.translate(x[0], 0, 0) m1.scale(1, 1, 2) w.addItem(m1) m2 = gl.GLMeshItem(meshdata=md, smooth=True, shader='normalColor', glOptions='opaque') m2.translate(x[1], 0, 0) m2.scale(1, 1, 2) w.addItem(m2) m3 = gl.GLMeshItem(meshdata=md, smooth=True, shader='viewNormalColor', glOptions='opaque') m3.translate(x[2], 0, 0) m3.scale(1, 1, 2) w.addItem(m3) m4 = gl.GLMeshItem(meshdata=md, smooth=True, shader='shaded', glOptions='opaque') m4.translate(x[3], 0, 0) m4.scale(1, 1, 2) w.addItem(m4) m5 = gl.GLMeshItem(meshdata=md, smooth=True, color=(1, 0, 0, 1), shader='edgeHilight', glOptions='opaque') m5.translate(x[4], 0, 0) m5.scale(1, 1, 2) w.addItem(m5) m6 = gl.GLMeshItem(meshdata=md, smooth=True, color=(1, 0, 0, 1), shader='heightColor', glOptions='opaque') m6.translate(x[5], 0, 0) m6.scale(1, 1, 2) w.addItem(m6) #def psi(i, j, k, offset=(25, 25, 50)): #x = i-offset[0] #y = j-offset[1] #z = k-offset[2] #th = np.arctan2(z, (x**2+y**2)**0.5) #phi = np.arctan2(y, x) #r = (x**2 + y**2 + z **2)**0.5 #a0 = 1 ##ps = (1./81.) * (2./np.pi)**0.5 * (1./a0)**(3/2) * (6 - r/a0) * (r/a0) * np.exp(-r/(3*a0)) * np.cos(th) #ps = (1./81.) * 1./(6.*np.pi)**0.5 * (1./a0)**(3/2) * (r/a0)**2 * np.exp(-r/(3*a0)) * (3 * np.cos(th)**2 - 1) #return ps ##return ((1./81.) * (1./np.pi)**0.5 * (1./a0)**(3/2) * (r/a0)**2 * (r/a0) * np.exp(-r/(3*a0)) * np.sin(th) * np.cos(th) * np.exp(2 * 1j * phi))**2 #print("Generating scalar field..") #data = np.abs(np.fromfunction(psi, (50,50,100))) ##data = np.fromfunction(lambda i,j,k: np.sin(0.2*((i-25)**2+(j-15)**2+k**2)**0.5), (50,50,50)); #print("Generating isosurface..") #verts = pg.isosurface(data, data.max()/4.) #md = gl.MeshData.MeshData(vertexes=verts) #colors = np.ones((md.vertexes(indexed='faces').shape[0], 4), dtype=float) #colors[:,3] = 0.3 #colors[:,2] = np.linspace(0, 1, colors.shape[0]) #m1 = gl.GLMeshItem(meshdata=md, color=colors, smooth=False) #w.addItem(m1) #m1.translate(-25, -25, -20) #m2 = gl.GLMeshItem(vertexes=verts, color=colors, smooth=True) #w.addItem(m2) #m2.translate(-25, -25, -50) ## Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/GradientEditor.py000066400000000000000000000013171300727121400227170ustar00rootroot00000000000000# -*- coding: utf-8 -*- ## Add path to library (just for examples; you do not need this) import initExample import numpy as np from pyqtgraph.Qt import QtGui, QtCore import pyqtgraph as pg app = QtGui.QApplication([]) mw = pg.GraphicsView() mw.resize(800,800) mw.show() #ts = pg.TickSliderItem() #mw.setCentralItem(ts) #ts.addTick(0.5, 'r') #ts.addTick(0.9, 'b') ge = pg.GradientEditorItem() mw.setCentralItem(ge) ## Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/GradientWidget.py000066400000000000000000000026001300727121400227100ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Demonstrates the appearance / interactivity of GradientWidget (without actually doing anything useful with it) """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np app = QtGui.QApplication([]) w = QtGui.QMainWindow() w.show() w.setWindowTitle('pyqtgraph example: GradientWidget') w.setGeometry(10, 50, 400, 400) cw = QtGui.QWidget() w.setCentralWidget(cw) l = QtGui.QGridLayout() l.setSpacing(0) cw.setLayout(l) w1 = pg.GradientWidget(orientation='top') w2 = pg.GradientWidget(orientation='right', allowAdd=False) #w2.setTickColor(1, QtGui.QColor(255,255,255)) w3 = pg.GradientWidget(orientation='bottom') w4 = pg.GradientWidget(orientation='left') w4.loadPreset('spectrum') label = QtGui.QLabel(""" - Click a triangle to change its color - Drag triangles to move - Click in an empty area to add a new color (adding is disabled for the right-side widget) - Right click a triangle to remove """) l.addWidget(w1, 0, 1) l.addWidget(w2, 1, 2) l.addWidget(w3, 2, 1) l.addWidget(w4, 1, 0) l.addWidget(label, 1, 1) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/GraphItem.py000066400000000000000000000027221300727121400216740ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Simple example of GraphItem use. """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np # Enable antialiasing for prettier plots pg.setConfigOptions(antialias=True) w = pg.GraphicsWindow() w.setWindowTitle('pyqtgraph example: GraphItem') v = w.addViewBox() v.setAspectLocked() g = pg.GraphItem() v.addItem(g) ## Define positions of nodes pos = np.array([ [0,0], [10,0], [0,10], [10,10], [5,5], [15,5] ]) ## Define the set of connections in the graph adj = np.array([ [0,1], [1,3], [3,2], [2,0], [1,5], [3,5], ]) ## Define the symbol to use for each node (this is optional) symbols = ['o','o','o','o','t','+'] ## Define the line style for each connection (this is optional) lines = np.array([ (255,0,0,255,1), (255,0,255,255,2), (255,0,255,255,3), (255,255,0,255,2), (255,0,0,255,1), (255,255,255,255,4), ], dtype=[('red',np.ubyte),('green',np.ubyte),('blue',np.ubyte),('alpha',np.ubyte),('width',float)]) ## Update the graph g.setData(pos=pos, adj=adj, pen=lines, size=1, symbol=symbols, pxMode=False) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/GraphicsLayout.py000066400000000000000000000044441300727121400227550ustar00rootroot00000000000000""" Demonstrate the use of layouts to control placement of multiple plots / views / labels """ ## Add path to library (just for examples; you do not need this) import initExample from pyqtgraph.Qt import QtGui, QtCore import pyqtgraph as pg import numpy as np app = QtGui.QApplication([]) view = pg.GraphicsView() l = pg.GraphicsLayout(border=(100,100,100)) view.setCentralItem(l) view.show() view.setWindowTitle('pyqtgraph example: GraphicsLayout') view.resize(800,600) ## Title at top text = """ This example demonstrates the use of GraphicsLayout to arrange items in a grid.
The items added to the layout must be subclasses of QGraphicsWidget (this includes
PlotItem, ViewBox, LabelItem, and GrphicsLayout itself). """ l.addLabel(text, col=1, colspan=4) l.nextRow() ## Put vertical label on left side l.addLabel('Long Vertical Label', angle=-90, rowspan=3) ## Add 3 plots into the first row (automatic position) p1 = l.addPlot(title="Plot 1") p2 = l.addPlot(title="Plot 2") vb = l.addViewBox(lockAspect=True) img = pg.ImageItem(np.random.normal(size=(100,100))) vb.addItem(img) vb.autoRange() ## Add a sub-layout into the second row (automatic position) ## The added item should avoid the first column, which is already filled l.nextRow() l2 = l.addLayout(colspan=3, border=(50,0,0)) l2.setContentsMargins(10, 10, 10, 10) l2.addLabel("Sub-layout: this layout demonstrates the use of shared axes and axis labels", colspan=3) l2.nextRow() l2.addLabel('Vertical Axis Label', angle=-90, rowspan=2) p21 = l2.addPlot() p22 = l2.addPlot() l2.nextRow() p23 = l2.addPlot() p24 = l2.addPlot() l2.nextRow() l2.addLabel("HorizontalAxisLabel", col=1, colspan=2) ## hide axes on some plots p21.hideAxis('bottom') p22.hideAxis('bottom') p22.hideAxis('left') p24.hideAxis('left') p21.hideButtons() p22.hideButtons() p23.hideButtons() p24.hideButtons() ## Add 2 more plots into the third row (manual position) p4 = l.addPlot(row=3, col=1) p5 = l.addPlot(row=3, col=2, colspan=2) ## show some content in the plots p1.plot([1,3,2,4,3,5]) p2.plot([1,3,2,4,3,5]) p4.plot([1,3,2,4,3,5]) p5.plot([1,3,2,4,3,5]) ## Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/GraphicsScene.py000066400000000000000000000027521300727121400225350ustar00rootroot00000000000000# -*- coding: utf-8 -*- ## Add path to library (just for examples; you do not need this) import initExample from pyqtgraph.Qt import QtCore, QtGui import pyqtgraph as pg from pyqtgraph.GraphicsScene import GraphicsScene app = QtGui.QApplication([]) win = pg.GraphicsView() win.show() class Obj(QtGui.QGraphicsObject): def __init__(self): QtGui.QGraphicsObject.__init__(self) GraphicsScene.registerObject(self) def paint(self, p, *args): p.setPen(pg.mkPen(200,200,200)) p.drawRect(self.boundingRect()) def boundingRect(self): return QtCore.QRectF(0, 0, 20, 20) def mouseClickEvent(self, ev): if ev.double(): print("double click") else: print("click") ev.accept() #def mouseDragEvent(self, ev): #print "drag" #ev.accept() #self.setPos(self.pos() + ev.pos()-ev.lastPos()) vb = pg.ViewBox() win.setCentralItem(vb) obj = Obj() vb.addItem(obj) obj2 = Obj() win.addItem(obj2) def clicked(): print("button click") btn = QtGui.QPushButton("BTN") btn.clicked.connect(clicked) prox = QtGui.QGraphicsProxyWidget() prox.setWidget(btn) prox.setPos(100,0) vb.addItem(prox) g = pg.GridItem() vb.addItem(g) ## Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/HistogramLUT.py000066400000000000000000000025061300727121400223360ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Use a HistogramLUTWidget to control the contrast / coloration of an image. """ ## Add path to library (just for examples; you do not need this) import initExample import numpy as np from pyqtgraph.Qt import QtGui, QtCore import pyqtgraph as pg app = QtGui.QApplication([]) win = QtGui.QMainWindow() win.resize(800,600) win.show() win.setWindowTitle('pyqtgraph example: Histogram LUT') cw = QtGui.QWidget() win.setCentralWidget(cw) l = QtGui.QGridLayout() cw.setLayout(l) l.setSpacing(0) v = pg.GraphicsView() vb = pg.ViewBox() vb.setAspectLocked() v.setCentralItem(vb) l.addWidget(v, 0, 0) w = pg.HistogramLUTWidget() l.addWidget(w, 0, 1) data = pg.gaussianFilter(np.random.normal(size=(256, 256)), (20, 20)) for i in range(32): for j in range(32): data[i*8, j*8] += .1 img = pg.ImageItem(data) #data2 = np.zeros((2,) + data.shape + (2,)) #data2[0,:,:,0] = data ## make non-contiguous array for testing purposes #img = pg.ImageItem(data2[0,:,:,0]) vb.addItem(img) vb.autoRange() w.setImageItem(img) ## Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/ImageItem.py000066400000000000000000000027221300727121400216550ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Demonstrates very basic use of ImageItem to display image data inside a ViewBox. """ ## Add path to library (just for examples; you do not need this) import initExample from pyqtgraph.Qt import QtCore, QtGui import numpy as np import pyqtgraph as pg import pyqtgraph.ptime as ptime app = QtGui.QApplication([]) ## Create window with GraphicsView widget win = pg.GraphicsLayoutWidget() win.show() ## show widget alone in its own window win.setWindowTitle('pyqtgraph example: ImageItem') view = win.addViewBox() ## lock the aspect ratio so pixels are always square view.setAspectLocked(True) ## Create image item img = pg.ImageItem(border='w') view.addItem(img) ## Set initial view bounds view.setRange(QtCore.QRectF(0, 0, 600, 600)) ## Create random image data = np.random.normal(size=(15, 600, 600), loc=1024, scale=64).astype(np.uint16) i = 0 updateTime = ptime.time() fps = 0 def updateData(): global img, data, i, updateTime, fps ## Display the data img.setImage(data[i]) i = (i+1) % data.shape[0] QtCore.QTimer.singleShot(1, updateData) now = ptime.time() fps2 = 1.0 / (now-updateTime) updateTime = now fps = fps * 0.9 + fps2 * 0.1 #print "%0.1f fps" % fps updateData() ## Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/ImageView.py000066400000000000000000000041511300727121400216670ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ This example demonstrates the use of ImageView, which is a high-level widget for displaying and analyzing 2D and 3D data. ImageView provides: 1. A zoomable region (ViewBox) for displaying the image 2. A combination histogram and gradient editor (HistogramLUTItem) for controlling the visual appearance of the image 3. A timeline for selecting the currently displayed frame (for 3D data only). 4. Tools for very basic analysis of image data (see ROI and Norm buttons) """ ## Add path to library (just for examples; you do not need this) import initExample import numpy as np from pyqtgraph.Qt import QtCore, QtGui import pyqtgraph as pg # Interpret image data as row-major instead of col-major pg.setConfigOptions(imageAxisOrder='row-major') app = QtGui.QApplication([]) ## Create window with ImageView widget win = QtGui.QMainWindow() win.resize(800,800) imv = pg.ImageView() win.setCentralWidget(imv) win.show() win.setWindowTitle('pyqtgraph example: ImageView') ## Create random 3D data set with noisy signals img = pg.gaussianFilter(np.random.normal(size=(200, 200)), (5, 5)) * 20 + 100 img = img[np.newaxis,:,:] decay = np.exp(-np.linspace(0,0.3,100))[:,np.newaxis,np.newaxis] data = np.random.normal(size=(100, 200, 200)) data += img * decay data += 2 ## Add time-varying signal sig = np.zeros(data.shape[0]) sig[30:] += np.exp(-np.linspace(1,10, 70)) sig[40:] += np.exp(-np.linspace(1,10, 60)) sig[70:] += np.exp(-np.linspace(1,10, 30)) sig = sig[:,np.newaxis,np.newaxis] * 3 data[:,50:60,30:40] += sig ## Display the data and assign each frame a time value from 1.0 to 3.0 imv.setImage(data, xvals=np.linspace(1., 3., data.shape[0])) ## Set a custom color map colors = [ (0, 0, 0), (45, 5, 61), (84, 42, 55), (150, 87, 60), (208, 171, 141), (255, 255, 255) ] cmap = pg.ColorMap(pos=np.linspace(0.0, 1.0, 6), color=colors) imv.setColorMap(cmap) ## Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/InfiniteLine.py000066400000000000000000000033261300727121400223720ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ This example demonstrates some of the plotting items available in pyqtgraph. """ import initExample ## Add path to library (just for examples; you do not need this) from pyqtgraph.Qt import QtGui, QtCore import numpy as np import pyqtgraph as pg app = QtGui.QApplication([]) win = pg.GraphicsWindow(title="Plotting items examples") win.resize(1000,600) # Enable antialiasing for prettier plots pg.setConfigOptions(antialias=True) # Create a plot with some random data p1 = win.addPlot(title="Plot Items example", y=np.random.normal(size=100, scale=10), pen=0.5) p1.setYRange(-40, 40) # Add three infinite lines with labels inf1 = pg.InfiniteLine(movable=True, angle=90, label='x={value:0.2f}', labelOpts={'position':0.1, 'color': (200,200,100), 'fill': (200,200,200,50), 'movable': True}) inf2 = pg.InfiniteLine(movable=True, angle=0, pen=(0, 0, 200), bounds = [-20, 20], hoverPen=(0,200,0), label='y={value:0.2f}mm', labelOpts={'color': (200,0,0), 'movable': True, 'fill': (0, 0, 200, 100)}) inf3 = pg.InfiniteLine(movable=True, angle=45, pen='g', label='diagonal', labelOpts={'rotateAxis': [1, 0], 'fill': (0, 200, 0, 100), 'movable': True}) inf1.setPos([2,2]) p1.addItem(inf1) p1.addItem(inf2) p1.addItem(inf3) # Add a linear region with a label lr = pg.LinearRegionItem(values=[70, 80]) p1.addItem(lr) label = pg.InfLineLabel(lr.lines[1], "region 1", position=0.95, rotateAxis=(1,0), anchor=(1, 1)) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/JoystickButton.py000066400000000000000000000025471300727121400230140ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ JoystickButton is a button with x/y values. When the button is depressed and the mouse dragged, the x/y values change to follow the mouse. When the mouse button is released, the x/y values change to 0,0 (rather like letting go of the joystick). """ import initExample ## Add path to library (just for examples; you do not need this) from pyqtgraph.Qt import QtGui, QtCore import pyqtgraph as pg app = QtGui.QApplication([]) mw = QtGui.QMainWindow() mw.resize(300,50) mw.setWindowTitle('pyqtgraph example: JoystickButton') cw = QtGui.QWidget() mw.setCentralWidget(cw) layout = QtGui.QGridLayout() cw.setLayout(layout) mw.show() l1 = pg.ValueLabel(siPrefix=True, suffix='m') l2 = pg.ValueLabel(siPrefix=True, suffix='m') jb = pg.JoystickButton() jb.setFixedWidth(30) jb.setFixedHeight(30) layout.addWidget(l1, 0, 0) layout.addWidget(l2, 0, 1) layout.addWidget(jb, 0, 2) x = 0 y = 0 def update(): global x, y, l1, l2, jb dx, dy = jb.getState() x += dx * 1e-3 y += dy * 1e-3 l1.setValue(x) l2.setValue(y) timer = QtCore.QTimer() timer.timeout.connect(update) timer.start(30) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/Legend.py000066400000000000000000000016571300727121400212200ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Demonstrates basic use of LegendItem """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui plt = pg.plot() plt.setWindowTitle('pyqtgraph example: Legend') plt.addLegend() #l = pg.LegendItem((100,60), offset=(70,30)) # args are (size, offset) #l.setParentItem(plt.graphicsItem()) # Note we do NOT call plt.addItem in this case c1 = plt.plot([1,3,2,4], pen='r', symbol='o', symbolPen='r', symbolBrush=0.5, name='red plot') c2 = plt.plot([2,1,4,3], pen='g', fillLevel=0, fillBrush=(255,255,255,30), name='green plot') #l.addItem(c1, 'red plot') #l.addItem(c2, 'green plot') ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/LogPlotTest.py000066400000000000000000000020461300727121400222330ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Simple logarithmic plotting test """ import initExample ## Add path to library (just for examples; you do not need this) from pyqtgraph.Qt import QtGui, QtCore import numpy as np import pyqtgraph as pg app = QtGui.QApplication([]) win = pg.GraphicsWindow(title="Basic plotting examples") win.resize(1000,600) win.setWindowTitle('pyqtgraph example: LogPlotTest') p5 = win.addPlot(title="Scatter plot, axis labels, log scale") x = np.random.normal(size=1000) * 1e-5 y = x*1000 + 0.005 * np.random.normal(size=1000) y -= y.min()-1.0 mask = x > 1e-15 x = x[mask] y = y[mask] p5.plot(x, y, pen=None, symbol='t', symbolPen=None, symbolSize=10, symbolBrush=(100, 100, 255, 50)) p5.setLabel('left', "Y Axis", units='A') p5.setLabel('bottom', "Y Axis", units='s') p5.setLogMode(x=True, y=False) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/MouseSelection.py000066400000000000000000000021551300727121400227520ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Demonstrates selecting plot curves by mouse click """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np win = pg.plot() win.setWindowTitle('pyqtgraph example: Plot data selection') curves = [ pg.PlotCurveItem(y=np.sin(np.linspace(0, 20, 1000)), pen='r', clickable=True), pg.PlotCurveItem(y=np.sin(np.linspace(1, 21, 1000)), pen='g', clickable=True), pg.PlotCurveItem(y=np.sin(np.linspace(2, 22, 1000)), pen='b', clickable=True), ] def plotClicked(curve): global curves for i,c in enumerate(curves): if c is curve: c.setPen('rgb'[i], width=3) else: c.setPen('rgb'[i], width=1) for c in curves: win.addItem(c) c.sigClicked.connect(plotClicked) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/MultiPlotSpeedTest.py000066400000000000000000000035561300727121400235740ustar00rootroot00000000000000#!/usr/bin/python # -*- coding: utf-8 -*- """ Test the speed of rapidly updating multiple plot curves """ ## Add path to library (just for examples; you do not need this) import initExample from pyqtgraph.Qt import QtGui, QtCore import numpy as np import pyqtgraph as pg from pyqtgraph.ptime import time #QtGui.QApplication.setGraphicsSystem('raster') app = QtGui.QApplication([]) #mw = QtGui.QMainWindow() #mw.resize(800,800) p = pg.plot() p.setWindowTitle('pyqtgraph example: MultiPlotSpeedTest') #p.setRange(QtCore.QRectF(0, -10, 5000, 20)) p.setLabel('bottom', 'Index', units='B') nPlots = 100 nSamples = 500 #curves = [p.plot(pen=(i,nPlots*1.3)) for i in range(nPlots)] curves = [] for i in range(nPlots): c = pg.PlotCurveItem(pen=(i,nPlots*1.3)) p.addItem(c) c.setPos(0,i*6) curves.append(c) p.setYRange(0, nPlots*6) p.setXRange(0, nSamples) p.resize(600,900) rgn = pg.LinearRegionItem([nSamples/5.,nSamples/3.]) p.addItem(rgn) data = np.random.normal(size=(nPlots*23,nSamples)) ptr = 0 lastTime = time() fps = None count = 0 def update(): global curve, data, ptr, p, lastTime, fps, nPlots, count count += 1 #print "---------", count for i in range(nPlots): curves[i].setData(data[(ptr+i)%data.shape[0]]) #print " setData done." ptr += nPlots now = time() dt = now - lastTime lastTime = now if fps is None: fps = 1.0/dt else: s = np.clip(dt*3., 0, 1) fps = fps * (1-s) + (1.0/dt) * s p.setTitle('%0.2f fps' % fps) #app.processEvents() ## force complete redraw for every plot timer = QtCore.QTimer() timer.timeout.connect(update) timer.start(0) ## Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/MultiPlotWidget.py000066400000000000000000000021661300727121400231130ustar00rootroot00000000000000#!/usr/bin/python # -*- coding: utf-8 -*- ## Add path to library (just for examples; you do not need this) import initExample from scipy import random from numpy import linspace from pyqtgraph.Qt import QtGui, QtCore import pyqtgraph as pg from pyqtgraph import MultiPlotWidget try: from pyqtgraph.metaarray import * except: print("MultiPlot is only used with MetaArray for now (and you do not have the metaarray package)") exit() app = QtGui.QApplication([]) mw = QtGui.QMainWindow() mw.resize(800,800) pw = MultiPlotWidget() mw.setCentralWidget(pw) mw.show() data = random.normal(size=(3, 1000)) * np.array([[0.1], [1e-5], [1]]) ma = MetaArray(data, info=[ {'name': 'Signal', 'cols': [ {'name': 'Col1', 'units': 'V'}, {'name': 'Col2', 'units': 'A'}, {'name': 'Col3'}, ]}, {'name': 'Time', 'values': linspace(0., 1., 1000), 'units': 's'} ]) pw.plot(ma) ## Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/MultiplePlotAxes.py000066400000000000000000000035661300727121400232760ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Demonstrates a way to put multiple axes around a single plot. (This will eventually become a built-in feature of PlotItem) """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np pg.mkQApp() pw = pg.PlotWidget() pw.show() pw.setWindowTitle('pyqtgraph example: MultiplePlotAxes') p1 = pw.plotItem p1.setLabels(left='axis 1') ## create a new ViewBox, link the right axis to its coordinate system p2 = pg.ViewBox() p1.showAxis('right') p1.scene().addItem(p2) p1.getAxis('right').linkToView(p2) p2.setXLink(p1) p1.getAxis('right').setLabel('axis2', color='#0000ff') ## create third ViewBox. ## this time we need to create a new axis as well. p3 = pg.ViewBox() ax3 = pg.AxisItem('right') p1.layout.addItem(ax3, 2, 3) p1.scene().addItem(p3) ax3.linkToView(p3) p3.setXLink(p1) ax3.setZValue(-10000) ax3.setLabel('axis 3', color='#ff0000') ## Handle view resizing def updateViews(): ## view has resized; update auxiliary views to match global p1, p2, p3 p2.setGeometry(p1.vb.sceneBoundingRect()) p3.setGeometry(p1.vb.sceneBoundingRect()) ## need to re-update linked axes since this was called ## incorrectly while views had different shapes. ## (probably this should be handled in ViewBox.resizeEvent) p2.linkedViewChanged(p1.vb, p2.XAxis) p3.linkedViewChanged(p1.vb, p3.XAxis) updateViews() p1.vb.sigResized.connect(updateViews) p1.plot([1,2,4,8,16,32]) p2.addItem(pg.PlotCurveItem([10,20,40,80,40,20], pen='b')) p3.addItem(pg.PlotCurveItem([3200,1600,800,400,200,100], pen='r')) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/PanningPlot.py000066400000000000000000000016521300727121400222460ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Shows use of PlotWidget to display panning data """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np win = pg.GraphicsWindow() win.setWindowTitle('pyqtgraph example: PanningPlot') plt = win.addPlot() #plt.setAutoVisibleOnly(y=True) curve = plt.plot() data = [] count = 0 def update(): global data, curve, count data.append(np.random.normal(size=10) + np.sin(count * 0.1) * 5) if len(data) > 100: data.pop(0) curve.setData(np.hstack(data)) count += 1 timer = QtCore.QTimer() timer.timeout.connect(update) timer.start(50) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/PlotAutoRange.py000066400000000000000000000022721300727121400225400ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ This example demonstrates the different auto-ranging capabilities of ViewBoxes """ import initExample ## Add path to library (just for examples; you do not need this) from pyqtgraph.Qt import QtGui, QtCore import numpy as np import pyqtgraph as pg #QtGui.QApplication.setGraphicsSystem('raster') app = QtGui.QApplication([]) #mw = QtGui.QMainWindow() #mw.resize(800,800) win = pg.GraphicsWindow(title="Plot auto-range examples") win.resize(800,600) win.setWindowTitle('pyqtgraph example: PlotAutoRange') d = np.random.normal(size=100) d[50:54] += 10 p1 = win.addPlot(title="95th percentile range", y=d) p1.enableAutoRange('y', 0.95) p2 = win.addPlot(title="Auto Pan Only") p2.setAutoPan(y=True) curve = p2.plot() def update(): t = pg.time() data = np.ones(100) * np.sin(t) data[50:60] += np.sin(t) global curve curve.setData(data) timer = QtCore.QTimer() timer.timeout.connect(update) timer.start(50) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/PlotSpeedTest.py000066400000000000000000000025641300727121400225570ustar00rootroot00000000000000#!/usr/bin/python # -*- coding: utf-8 -*- """ Update a simple plot as rapidly as possible to measure speed. """ ## Add path to library (just for examples; you do not need this) import initExample from pyqtgraph.Qt import QtGui, QtCore import numpy as np import pyqtgraph as pg from pyqtgraph.ptime import time app = QtGui.QApplication([]) p = pg.plot() p.setWindowTitle('pyqtgraph example: PlotSpeedTest') p.setRange(QtCore.QRectF(0, -10, 5000, 20)) p.setLabel('bottom', 'Index', units='B') curve = p.plot() #curve.setFillBrush((0, 0, 100, 100)) #curve.setFillLevel(0) #lr = pg.LinearRegionItem([100, 4900]) #p.addItem(lr) data = np.random.normal(size=(50,5000)) ptr = 0 lastTime = time() fps = None def update(): global curve, data, ptr, p, lastTime, fps curve.setData(data[ptr%10]) ptr += 1 now = time() dt = now - lastTime lastTime = now if fps is None: fps = 1.0/dt else: s = np.clip(dt*3., 0, 1) fps = fps * (1-s) + (1.0/dt) * s p.setTitle('%0.2f fps' % fps) app.processEvents() ## force complete redraw for every plot timer = QtCore.QTimer() timer.timeout.connect(update) timer.start(0) ## Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/PlotWidget.py000066400000000000000000000047511300727121400221020ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Demonstrates use of PlotWidget class. This is little more than a GraphicsView with a PlotItem placed in its center. """ import initExample ## Add path to library (just for examples; you do not need this) from pyqtgraph.Qt import QtGui, QtCore import numpy as np import pyqtgraph as pg #QtGui.QApplication.setGraphicsSystem('raster') app = QtGui.QApplication([]) mw = QtGui.QMainWindow() mw.setWindowTitle('pyqtgraph example: PlotWidget') mw.resize(800,800) cw = QtGui.QWidget() mw.setCentralWidget(cw) l = QtGui.QVBoxLayout() cw.setLayout(l) pw = pg.PlotWidget(name='Plot1') ## giving the plots names allows us to link their axes together l.addWidget(pw) pw2 = pg.PlotWidget(name='Plot2') l.addWidget(pw2) pw3 = pg.PlotWidget() l.addWidget(pw3) mw.show() ## Create an empty plot curve to be filled later, set its pen p1 = pw.plot() p1.setPen((200,200,100)) ## Add in some extra graphics rect = QtGui.QGraphicsRectItem(QtCore.QRectF(0, 0, 1, 5e-11)) rect.setPen(pg.mkPen(100, 200, 100)) pw.addItem(rect) pw.setLabel('left', 'Value', units='V') pw.setLabel('bottom', 'Time', units='s') pw.setXRange(0, 2) pw.setYRange(0, 1e-10) def rand(n): data = np.random.random(n) data[int(n*0.1):int(n*0.13)] += .5 data[int(n*0.18)] += 2 data[int(n*0.1):int(n*0.13)] *= 5 data[int(n*0.18)] *= 20 data *= 1e-12 return data, np.arange(n, n+len(data)) / float(n) def updateData(): yd, xd = rand(10000) p1.setData(y=yd, x=xd) ## Start a timer to rapidly update the plot in pw t = QtCore.QTimer() t.timeout.connect(updateData) t.start(50) #updateData() ## Multiple parameterized plots--we can autogenerate averages for these. for i in range(0, 5): for j in range(0, 3): yd, xd = rand(10000) pw2.plot(y=yd*(j+1), x=xd, params={'iter': i, 'val': j}) ## Test large numbers curve = pw3.plot(np.random.normal(size=100)*1e0, clickable=True) curve.curve.setClickable(True) curve.setPen('w') ## white pen curve.setShadowPen(pg.mkPen((70,70,30), width=6, cosmetic=True)) def clicked(): print("curve clicked") curve.sigClicked.connect(clicked) lr = pg.LinearRegionItem([1, 30], bounds=[0,100], movable=True) pw3.addItem(lr) line = pg.InfiniteLine(angle=90, movable=True) pw3.addItem(line) line.setBounds([0,200]) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/Plotting.py000066400000000000000000000061751300727121400216220ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ This example demonstrates many of the 2D plotting capabilities in pyqtgraph. All of the plots may be panned/scaled by dragging with the left/right mouse buttons. Right click on any plot to show a context menu. """ import initExample ## Add path to library (just for examples; you do not need this) from pyqtgraph.Qt import QtGui, QtCore import numpy as np import pyqtgraph as pg #QtGui.QApplication.setGraphicsSystem('raster') app = QtGui.QApplication([]) #mw = QtGui.QMainWindow() #mw.resize(800,800) win = pg.GraphicsWindow(title="Basic plotting examples") win.resize(1000,600) win.setWindowTitle('pyqtgraph example: Plotting') # Enable antialiasing for prettier plots pg.setConfigOptions(antialias=True) p1 = win.addPlot(title="Basic array plotting", y=np.random.normal(size=100)) p2 = win.addPlot(title="Multiple curves") p2.plot(np.random.normal(size=100), pen=(255,0,0), name="Red curve") p2.plot(np.random.normal(size=110)+5, pen=(0,255,0), name="Green curve") p2.plot(np.random.normal(size=120)+10, pen=(0,0,255), name="Blue curve") p3 = win.addPlot(title="Drawing with points") p3.plot(np.random.normal(size=100), pen=(200,200,200), symbolBrush=(255,0,0), symbolPen='w') win.nextRow() p4 = win.addPlot(title="Parametric, grid enabled") x = np.cos(np.linspace(0, 2*np.pi, 1000)) y = np.sin(np.linspace(0, 4*np.pi, 1000)) p4.plot(x, y) p4.showGrid(x=True, y=True) p5 = win.addPlot(title="Scatter plot, axis labels, log scale") x = np.random.normal(size=1000) * 1e-5 y = x*1000 + 0.005 * np.random.normal(size=1000) y -= y.min()-1.0 mask = x > 1e-15 x = x[mask] y = y[mask] p5.plot(x, y, pen=None, symbol='t', symbolPen=None, symbolSize=10, symbolBrush=(100, 100, 255, 50)) p5.setLabel('left', "Y Axis", units='A') p5.setLabel('bottom', "Y Axis", units='s') p5.setLogMode(x=True, y=False) p6 = win.addPlot(title="Updating plot") curve = p6.plot(pen='y') data = np.random.normal(size=(10,1000)) ptr = 0 def update(): global curve, data, ptr, p6 curve.setData(data[ptr%10]) if ptr == 0: p6.enableAutoRange('xy', False) ## stop auto-scaling after the first data set is plotted ptr += 1 timer = QtCore.QTimer() timer.timeout.connect(update) timer.start(50) win.nextRow() p7 = win.addPlot(title="Filled plot, axis disabled") y = np.sin(np.linspace(0, 10, 1000)) + np.random.normal(size=1000, scale=0.1) p7.plot(y, fillLevel=-0.3, brush=(50,50,200,100)) p7.showAxis('bottom', False) x2 = np.linspace(-100, 100, 1000) data2 = np.sin(x2) / x2 p8 = win.addPlot(title="Region Selection") p8.plot(data2, pen=(255,255,255,200)) lr = pg.LinearRegionItem([400,700]) lr.setZValue(-10) p8.addItem(lr) p9 = win.addPlot(title="Zoom on selected region") p9.plot(data2) def updatePlot(): p9.setXRange(*lr.getRegion(), padding=0) def updateRegion(): lr.setRegion(p9.getViewBox().viewRange()[0]) lr.sigRegionChanged.connect(updatePlot) p9.sigXRangeChanged.connect(updateRegion) updatePlot() ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/ROIExamples.py000066400000000000000000000112711300727121400221430ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Demonstrates a variety of uses for ROI. This class provides a user-adjustable region of interest marker. It is possible to customize the layout and function of the scale/rotate handles in very flexible ways. """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np pg.setConfigOptions(imageAxisOrder='row-major') ## Create image to display arr = np.ones((100, 100), dtype=float) arr[45:55, 45:55] = 0 arr[25, :] = 5 arr[:, 25] = 5 arr[75, :] = 5 arr[:, 75] = 5 arr[50, :] = 10 arr[:, 50] = 10 arr += np.sin(np.linspace(0, 20, 100)).reshape(1, 100) arr += np.random.normal(size=(100,100)) # add an arrow for asymmetry arr[10, :50] = 10 arr[9:12, 44:48] = 10 arr[8:13, 44:46] = 10 ## create GUI app = QtGui.QApplication([]) w = pg.GraphicsWindow(size=(1000,800), border=True) w.setWindowTitle('pyqtgraph example: ROI Examples') text = """Data Selection From Image.
\n Drag an ROI or its handles to update the selected image.
Hold CTRL while dragging to snap to pixel boundaries
and 15-degree rotation angles. """ w1 = w.addLayout(row=0, col=0) label1 = w1.addLabel(text, row=0, col=0) v1a = w1.addViewBox(row=1, col=0, lockAspect=True) v1b = w1.addViewBox(row=2, col=0, lockAspect=True) img1a = pg.ImageItem(arr) v1a.addItem(img1a) img1b = pg.ImageItem() v1b.addItem(img1b) v1a.disableAutoRange('xy') v1b.disableAutoRange('xy') v1a.autoRange() v1b.autoRange() rois = [] rois.append(pg.RectROI([20, 20], [20, 20], pen=(0,9))) rois[-1].addRotateHandle([1,0], [0.5, 0.5]) rois.append(pg.LineROI([0, 60], [20, 80], width=5, pen=(1,9))) rois.append(pg.MultiRectROI([[20, 90], [50, 60], [60, 90]], width=5, pen=(2,9))) rois.append(pg.EllipseROI([60, 10], [30, 20], pen=(3,9))) rois.append(pg.CircleROI([80, 50], [20, 20], pen=(4,9))) #rois.append(pg.LineSegmentROI([[110, 50], [20, 20]], pen=(5,9))) rois.append(pg.PolyLineROI([[80, 60], [90, 30], [60, 40]], pen=(6,9), closed=True)) def update(roi): img1b.setImage(roi.getArrayRegion(arr, img1a), levels=(0, arr.max())) v1b.autoRange() for roi in rois: roi.sigRegionChanged.connect(update) v1a.addItem(roi) update(rois[-1]) text = """User-Modifiable ROIs
Click on a line segment to add a new handle. Right click on a handle to remove. """ w2 = w.addLayout(row=0, col=1) label2 = w2.addLabel(text, row=0, col=0) v2a = w2.addViewBox(row=1, col=0, lockAspect=True) r2a = pg.PolyLineROI([[0,0], [10,10], [10,30], [30,10]], closed=True) v2a.addItem(r2a) r2b = pg.PolyLineROI([[0,-20], [10,-10], [10,-30]], closed=False) v2a.addItem(r2b) v2a.disableAutoRange('xy') #v2b.disableAutoRange('xy') v2a.autoRange() #v2b.autoRange() text = """Building custom ROI types
ROIs can be built with a variety of different handle types
that scale and rotate the roi around an arbitrary center location """ w3 = w.addLayout(row=1, col=0) label3 = w3.addLabel(text, row=0, col=0) v3 = w3.addViewBox(row=1, col=0, lockAspect=True) r3a = pg.ROI([0,0], [10,10]) v3.addItem(r3a) ## handles scaling horizontally around center r3a.addScaleHandle([1, 0.5], [0.5, 0.5]) r3a.addScaleHandle([0, 0.5], [0.5, 0.5]) ## handles scaling vertically from opposite edge r3a.addScaleHandle([0.5, 0], [0.5, 1]) r3a.addScaleHandle([0.5, 1], [0.5, 0]) ## handles scaling both vertically and horizontally r3a.addScaleHandle([1, 1], [0, 0]) r3a.addScaleHandle([0, 0], [1, 1]) r3b = pg.ROI([20,0], [10,10]) v3.addItem(r3b) ## handles rotating around center r3b.addRotateHandle([1, 1], [0.5, 0.5]) r3b.addRotateHandle([0, 0], [0.5, 0.5]) ## handles rotating around opposite corner r3b.addRotateHandle([1, 0], [0, 1]) r3b.addRotateHandle([0, 1], [1, 0]) ## handles rotating/scaling around center r3b.addScaleRotateHandle([0, 0.5], [0.5, 0.5]) r3b.addScaleRotateHandle([1, 0.5], [0.5, 0.5]) v3.disableAutoRange('xy') v3.autoRange() text = """Transforming objects with ROI""" w4 = w.addLayout(row=1, col=1) label4 = w4.addLabel(text, row=0, col=0) v4 = w4.addViewBox(row=1, col=0, lockAspect=True) g = pg.GridItem() v4.addItem(g) r4 = pg.ROI([0,0], [100,100], removable=True) r4.addRotateHandle([1,0], [0.5, 0.5]) r4.addRotateHandle([0,1], [0.5, 0.5]) img4 = pg.ImageItem(arr) v4.addItem(r4) img4.setParentItem(r4) v4.disableAutoRange('xy') v4.autoRange() # Provide a callback to remove the ROI (and its children) when # "remove" is selected from the context menu. def remove(): v4.removeItem(r4) r4.sigRemoveRequested.connect(remove) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/ROItypes.py000066400000000000000000000063331300727121400215340ustar00rootroot00000000000000#!/usr/bin/python -i # -*- coding: utf-8 -*- ## Add path to library (just for examples; you do not need this) import initExample from pyqtgraph.Qt import QtCore, QtGui import numpy as np import pyqtgraph as pg pg.setConfigOptions(imageAxisOrder='row-major') ## create GUI app = QtGui.QApplication([]) w = pg.GraphicsWindow(size=(800,800), border=True) v = w.addViewBox(colspan=2) v.invertY(True) ## Images usually have their Y-axis pointing downward v.setAspectLocked(True) ## Create image to display arr = np.ones((100, 100), dtype=float) arr[45:55, 45:55] = 0 arr[25, :] = 5 arr[:, 25] = 5 arr[75, :] = 5 arr[:, 75] = 5 arr[50, :] = 10 arr[:, 50] = 10 # add an arrow for asymmetry arr[10, :50] = 10 arr[9:12, 44:48] = 10 arr[8:13, 44:46] = 10 ## Create image items, add to scene and set position im1 = pg.ImageItem(arr) im2 = pg.ImageItem(arr) v.addItem(im1) v.addItem(im2) im2.moveBy(110, 20) v.setRange(QtCore.QRectF(0, 0, 200, 120)) im1.scale(0.8, 0.5) im3 = pg.ImageItem() v2 = w.addViewBox(1,0) v2.addItem(im3) v2.setRange(QtCore.QRectF(0, 0, 60, 60)) v2.invertY(True) v2.setAspectLocked(True) #im3.moveBy(0, 130) im3.setZValue(10) im4 = pg.ImageItem() v3 = w.addViewBox(1,1) v3.addItem(im4) v3.setRange(QtCore.QRectF(0, 0, 60, 60)) v3.invertY(True) v3.setAspectLocked(True) #im4.moveBy(110, 130) im4.setZValue(10) ## create the plot pi1 = w.addPlot(2,0, colspan=2) #pi1 = pg.PlotItem() #s.addItem(pi1) #pi1.scale(0.5, 0.5) #pi1.setGeometry(0, 170, 300, 100) lastRoi = None def updateRoi(roi): global im1, im2, im3, im4, arr, lastRoi if roi is None: return lastRoi = roi arr1 = roi.getArrayRegion(im1.image, img=im1) im3.setImage(arr1) arr2 = roi.getArrayRegion(im2.image, img=im2) im4.setImage(arr2) updateRoiPlot(roi, arr1) def updateRoiPlot(roi, data=None): if data is None: data = roi.getArrayRegion(im1.image, img=im1) if data is not None: roi.curve.setData(data.mean(axis=1)) ## Create a variety of different ROI types rois = [] rois.append(pg.TestROI([0, 0], [20, 20], maxBounds=QtCore.QRectF(-10, -10, 230, 140), pen=(0,9))) rois.append(pg.LineROI([0, 0], [20, 20], width=5, pen=(1,9))) rois.append(pg.MultiLineROI([[0, 50], [50, 60], [60, 30]], width=5, pen=(2,9))) rois.append(pg.EllipseROI([110, 10], [30, 20], pen=(3,9))) rois.append(pg.CircleROI([110, 50], [20, 20], pen=(4,9))) rois.append(pg.PolygonROI([[2,0], [2.1,0], [2,.1]], pen=(5,9))) #rois.append(SpiralROI([20,30], [1,1], pen=mkPen(0))) ## Add each ROI to the scene and link its data to a plot curve with the same color for r in rois: v.addItem(r) c = pi1.plot(pen=r.pen) r.curve = c r.sigRegionChanged.connect(updateRoi) def updateImage(): global im1, arr, lastRoi r = abs(np.random.normal(loc=0, scale=(arr.max()-arr.min())*0.1, size=arr.shape)) im1.updateImage(arr + r) updateRoi(lastRoi) for r in rois: updateRoiPlot(r) ## Rapidly update one of the images with random noise t = QtCore.QTimer() t.timeout.connect(updateImage) t.start(50) ## Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/RemoteGraphicsView.py000066400000000000000000000024211300727121400235570ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Very simple example demonstrating RemoteGraphicsView. This allows graphics to be rendered in a child process and displayed in the parent, which can improve CPU usage on multi-core processors. """ import initExample ## Add path to library (just for examples; you do not need this) from pyqtgraph.Qt import QtGui, QtCore import pyqtgraph as pg from pyqtgraph.widgets.RemoteGraphicsView import RemoteGraphicsView app = pg.mkQApp() ## Create the widget v = RemoteGraphicsView(debug=False) # setting debug=True causes both processes to print information # about interprocess communication v.show() v.setWindowTitle('pyqtgraph example: RemoteGraphicsView') ## v.pg is a proxy to the remote process' pyqtgraph module. All attribute ## requests and function calls made with this object are forwarded to the ## remote process and executed there. See pyqtgraph.multiprocess.remoteproxy ## for more inormation. plt = v.pg.PlotItem() v.setCentralItem(plt) plt.plot([1,4,2,3,6,2,3,4,2,3], pen='g') ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/RemoteSpeedTest.py000066400000000000000000000056601300727121400230740ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ This example demonstrates the use of RemoteGraphicsView to improve performance in applications with heavy load. It works by starting a second process to handle all graphics rendering, thus freeing up the main process to do its work. In this example, the update() function is very expensive and is called frequently. After update() generates a new set of data, it can either plot directly to a local plot (bottom) or remotely via a RemoteGraphicsView (top), allowing speed comparison between the two cases. IF you have a multi-core CPU, it should be obvious that the remote case is much faster. """ import initExample ## Add path to library (just for examples; you do not need this) from pyqtgraph.Qt import QtGui, QtCore import pyqtgraph as pg import pyqtgraph.widgets.RemoteGraphicsView import numpy as np app = pg.mkQApp() view = pg.widgets.RemoteGraphicsView.RemoteGraphicsView() pg.setConfigOptions(antialias=True) ## this will be expensive for the local plot view.pg.setConfigOptions(antialias=True) ## prettier plots at no cost to the main process! view.setWindowTitle('pyqtgraph example: RemoteSpeedTest') label = QtGui.QLabel() rcheck = QtGui.QCheckBox('plot remote') rcheck.setChecked(True) lcheck = QtGui.QCheckBox('plot local') lplt = pg.PlotWidget() layout = pg.LayoutWidget() layout.addWidget(rcheck) layout.addWidget(lcheck) layout.addWidget(label) layout.addWidget(view, row=1, col=0, colspan=3) layout.addWidget(lplt, row=2, col=0, colspan=3) layout.resize(800,800) layout.show() ## Create a PlotItem in the remote process that will be displayed locally rplt = view.pg.PlotItem() rplt._setProxyOptions(deferGetattr=True) ## speeds up access to rplt.plot view.setCentralItem(rplt) lastUpdate = pg.ptime.time() avgFps = 0.0 def update(): global check, label, plt, lastUpdate, avgFps, rpltfunc data = np.random.normal(size=(10000,50)).sum(axis=1) data += 5 * np.sin(np.linspace(0, 10, data.shape[0])) if rcheck.isChecked(): rplt.plot(data, clear=True, _callSync='off') ## We do not expect a return value. ## By turning off callSync, we tell ## the proxy that it does not need to ## wait for a reply from the remote ## process. if lcheck.isChecked(): lplt.plot(data, clear=True) now = pg.ptime.time() fps = 1.0 / (now - lastUpdate) lastUpdate = now avgFps = avgFps * 0.8 + fps * 0.2 label.setText("Generating %0.2f fps" % avgFps) timer = QtCore.QTimer() timer.timeout.connect(update) timer.start(0) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/ScaleBar.py000066400000000000000000000014431300727121400214670ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Demonstrates ScaleBar """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np pg.mkQApp() win = pg.GraphicsWindow() win.setWindowTitle('pyqtgraph example: ScaleBar') vb = win.addViewBox() vb.setAspectLocked() img = pg.ImageItem() img.setImage(np.random.normal(size=(100,100))) img.scale(0.01, 0.01) vb.addItem(img) scale = pg.ScaleBar(size=0.1) scale.setParentItem(vb) scale.anchor((1, 1), (1, 1), offset=(-20, -20)) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/ScatterPlot.py000066400000000000000000000061651300727121400222650ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Example demonstrating a variety of scatter plot features. """ ## Add path to library (just for examples; you do not need this) import initExample from pyqtgraph.Qt import QtGui, QtCore import pyqtgraph as pg import numpy as np app = QtGui.QApplication([]) mw = QtGui.QMainWindow() mw.resize(800,800) view = pg.GraphicsLayoutWidget() ## GraphicsView with GraphicsLayout inserted by default mw.setCentralWidget(view) mw.show() mw.setWindowTitle('pyqtgraph example: ScatterPlot') ## create four areas to add plots w1 = view.addPlot() w2 = view.addViewBox() w2.setAspectLocked(True) view.nextRow() w3 = view.addPlot() w4 = view.addPlot() print("Generating data, this takes a few seconds...") ## There are a few different ways we can draw scatter plots; each is optimized for different types of data: ## 1) All spots identical and transform-invariant (top-left plot). ## In this case we can get a huge performance boost by pre-rendering the spot ## image and just drawing that image repeatedly. n = 300 s1 = pg.ScatterPlotItem(size=10, pen=pg.mkPen(None), brush=pg.mkBrush(255, 255, 255, 120)) pos = np.random.normal(size=(2,n), scale=1e-5) spots = [{'pos': pos[:,i], 'data': 1} for i in range(n)] + [{'pos': [0,0], 'data': 1}] s1.addPoints(spots) w1.addItem(s1) ## Make all plots clickable lastClicked = [] def clicked(plot, points): global lastClicked for p in lastClicked: p.resetPen() print("clicked points", points) for p in points: p.setPen('b', width=2) lastClicked = points s1.sigClicked.connect(clicked) ## 2) Spots are transform-invariant, but not identical (top-right plot). ## In this case, drawing is almsot as fast as 1), but there is more startup ## overhead and memory usage since each spot generates its own pre-rendered ## image. s2 = pg.ScatterPlotItem(size=10, pen=pg.mkPen('w'), pxMode=True) pos = np.random.normal(size=(2,n), scale=1e-5) spots = [{'pos': pos[:,i], 'data': 1, 'brush':pg.intColor(i, n), 'symbol': i%5, 'size': 5+i/10.} for i in range(n)] s2.addPoints(spots) w2.addItem(s2) s2.sigClicked.connect(clicked) ## 3) Spots are not transform-invariant, not identical (bottom-left). ## This is the slowest case, since all spots must be completely re-drawn ## every time because their apparent transformation may have changed. s3 = pg.ScatterPlotItem(pxMode=False) ## Set pxMode=False to allow spots to transform with the view spots3 = [] for i in range(10): for j in range(10): spots3.append({'pos': (1e-6*i, 1e-6*j), 'size': 1e-6, 'pen': {'color': 'w', 'width': 2}, 'brush':pg.intColor(i*10+j, 100)}) s3.addPoints(spots3) w3.addItem(s3) s3.sigClicked.connect(clicked) ## Test performance of large scatterplots s4 = pg.ScatterPlotItem(size=10, pen=pg.mkPen(None), brush=pg.mkBrush(255, 255, 255, 20)) pos = np.random.normal(size=(2,10000), scale=1e-9) s4.addPoints(x=pos[0], y=pos[1]) w4.addItem(s4) s4.sigClicked.connect(clicked) ## Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/ScatterPlotSpeedTest.py000066400000000000000000000040571300727121400241040ustar00rootroot00000000000000#!/usr/bin/python # -*- coding: utf-8 -*- """ For testing rapid updates of ScatterPlotItem under various conditions. (Scatter plots are still rather slow to draw; expect about 20fps) """ ## Add path to library (just for examples; you do not need this) import initExample from pyqtgraph.Qt import QtGui, QtCore, USE_PYSIDE, USE_PYQT5 import numpy as np import pyqtgraph as pg from pyqtgraph.ptime import time #QtGui.QApplication.setGraphicsSystem('raster') app = QtGui.QApplication([]) #mw = QtGui.QMainWindow() #mw.resize(800,800) if USE_PYSIDE: from ScatterPlotSpeedTestTemplate_pyside import Ui_Form elif USE_PYQT5: from ScatterPlotSpeedTestTemplate_pyqt5 import Ui_Form else: from ScatterPlotSpeedTestTemplate_pyqt import Ui_Form win = QtGui.QWidget() win.setWindowTitle('pyqtgraph example: ScatterPlotSpeedTest') ui = Ui_Form() ui.setupUi(win) win.show() p = ui.plot p.setRange(xRange=[-500, 500], yRange=[-500, 500]) data = np.random.normal(size=(50,500), scale=100) sizeArray = (np.random.random(500) * 20.).astype(int) ptr = 0 lastTime = time() fps = None def update(): global curve, data, ptr, p, lastTime, fps p.clear() if ui.randCheck.isChecked(): size = sizeArray else: size = ui.sizeSpin.value() curve = pg.ScatterPlotItem(x=data[ptr%50], y=data[(ptr+1)%50], pen='w', brush='b', size=size, pxMode=ui.pixelModeCheck.isChecked()) p.addItem(curve) ptr += 1 now = time() dt = now - lastTime lastTime = now if fps is None: fps = 1.0/dt else: s = np.clip(dt*3., 0, 1) fps = fps * (1-s) + (1.0/dt) * s p.setTitle('%0.2f fps' % fps) p.repaint() #app.processEvents() ## force complete redraw for every plot timer = QtCore.QTimer() timer.timeout.connect(update) timer.start(0) ## Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/ScatterPlotSpeedTestTemplate.ui000066400000000000000000000025721300727121400255650ustar00rootroot00000000000000 Form 0 0 400 300 Form 10 pixel mode Size Randomize PlotWidget QGraphicsView
pyqtgraph
 pyqtgraph-pyqtgraph-0.10.0/examples/ScatterPlotSpeedTestTemplate_pyqt.py000066400000000000000000000041141300727121400266470ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './examples/ScatterPlotSpeedTestTemplate.ui' # # Created: Fri Sep 21 15:39:09 2012 # by: PyQt4 UI code generator 4.9.1 # # WARNING! All changes made in this file will be lost! from PyQt4 import QtCore, QtGui try: _fromUtf8 = QtCore.QString.fromUtf8 except AttributeError: _fromUtf8 = lambda s: s class Ui_Form(object): def setupUi(self, Form): Form.setObjectName(_fromUtf8("Form")) Form.resize(400, 300) self.gridLayout = QtGui.QGridLayout(Form) self.gridLayout.setObjectName(_fromUtf8("gridLayout")) self.sizeSpin = QtGui.QSpinBox(Form) self.sizeSpin.setProperty("value", 10) self.sizeSpin.setObjectName(_fromUtf8("sizeSpin")) self.gridLayout.addWidget(self.sizeSpin, 1, 1, 1, 1) self.pixelModeCheck = QtGui.QCheckBox(Form) self.pixelModeCheck.setObjectName(_fromUtf8("pixelModeCheck")) self.gridLayout.addWidget(self.pixelModeCheck, 1, 3, 1, 1) self.label = QtGui.QLabel(Form) self.label.setObjectName(_fromUtf8("label")) self.gridLayout.addWidget(self.label, 1, 0, 1, 1) self.plot = PlotWidget(Form) self.plot.setObjectName(_fromUtf8("plot")) self.gridLayout.addWidget(self.plot, 0, 0, 1, 4) self.randCheck = QtGui.QCheckBox(Form) self.randCheck.setObjectName(_fromUtf8("randCheck")) self.gridLayout.addWidget(self.randCheck, 1, 2, 1, 1) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): Form.setWindowTitle(QtGui.QApplication.translate("Form", "Form", None, QtGui.QApplication.UnicodeUTF8)) self.pixelModeCheck.setText(QtGui.QApplication.translate("Form", "pixel mode", None, QtGui.QApplication.UnicodeUTF8)) self.label.setText(QtGui.QApplication.translate("Form", "Size", None, QtGui.QApplication.UnicodeUTF8)) self.randCheck.setText(QtGui.QApplication.translate("Form", "Randomize", None, QtGui.QApplication.UnicodeUTF8)) from pyqtgraph import PlotWidget pyqtgraph-pyqtgraph-0.10.0/examples/ScatterPlotSpeedTestTemplate_pyside.py000066400000000000000000000036531300727121400271560ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './examples/ScatterPlotSpeedTestTemplate.ui' # # Created: Fri Sep 21 15:39:09 2012 # by: pyside-uic 0.2.13 running on PySide 1.1.0 # # WARNING! All changes made in this file will be lost! from PySide import QtCore, QtGui class Ui_Form(object): def setupUi(self, Form): Form.setObjectName("Form") Form.resize(400, 300) self.gridLayout = QtGui.QGridLayout(Form) self.gridLayout.setObjectName("gridLayout") self.sizeSpin = QtGui.QSpinBox(Form) self.sizeSpin.setProperty("value", 10) self.sizeSpin.setObjectName("sizeSpin") self.gridLayout.addWidget(self.sizeSpin, 1, 1, 1, 1) self.pixelModeCheck = QtGui.QCheckBox(Form) self.pixelModeCheck.setObjectName("pixelModeCheck") self.gridLayout.addWidget(self.pixelModeCheck, 1, 3, 1, 1) self.label = QtGui.QLabel(Form) self.label.setObjectName("label") self.gridLayout.addWidget(self.label, 1, 0, 1, 1) self.plot = PlotWidget(Form) self.plot.setObjectName("plot") self.gridLayout.addWidget(self.plot, 0, 0, 1, 4) self.randCheck = QtGui.QCheckBox(Form) self.randCheck.setObjectName("randCheck") self.gridLayout.addWidget(self.randCheck, 1, 2, 1, 1) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): Form.setWindowTitle(QtGui.QApplication.translate("Form", "Form", None, QtGui.QApplication.UnicodeUTF8)) self.pixelModeCheck.setText(QtGui.QApplication.translate("Form", "pixel mode", None, QtGui.QApplication.UnicodeUTF8)) self.label.setText(QtGui.QApplication.translate("Form", "Size", None, QtGui.QApplication.UnicodeUTF8)) self.randCheck.setText(QtGui.QApplication.translate("Form", "Randomize", None, QtGui.QApplication.UnicodeUTF8)) from pyqtgraph import PlotWidget pyqtgraph-pyqtgraph-0.10.0/examples/ScatterPlotWidget.py000066400000000000000000000052431300727121400234250ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Demonstration of ScatterPlotWidget for exploring structure in tabular data. The widget consists of four components: 1) A list of column names from which the user may select 1 or 2 columns to plot. If one column is selected, the data for that column will be plotted in a histogram-like manner by using pg.pseudoScatter(). If two columns are selected, then the scatter plot will be generated with x determined by the first column that was selected and y by the second. 2) A DataFilter that allows the user to select a subset of the data by specifying multiple selection criteria. 3) A ColorMap that allows the user to determine how points are colored by specifying multiple criteria. 4) A PlotWidget for displaying the data. """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np pg.mkQApp() # Make up some tabular data with structure data = np.empty(1000, dtype=[('x_pos', float), ('y_pos', float), ('count', int), ('amplitude', float), ('decay', float), ('type', 'S10')]) strings = ['Type-A', 'Type-B', 'Type-C', 'Type-D', 'Type-E'] typeInds = np.random.randint(5, size=1000) data['type'] = np.array(strings)[typeInds] data['x_pos'] = np.random.normal(size=1000) data['x_pos'][data['type'] == 'Type-A'] -= 1 data['x_pos'][data['type'] == 'Type-B'] -= 1 data['x_pos'][data['type'] == 'Type-C'] += 2 data['x_pos'][data['type'] == 'Type-D'] += 2 data['x_pos'][data['type'] == 'Type-E'] += 2 data['y_pos'] = np.random.normal(size=1000) + data['x_pos']*0.1 data['y_pos'][data['type'] == 'Type-A'] += 3 data['y_pos'][data['type'] == 'Type-B'] += 3 data['amplitude'] = data['x_pos'] * 1.4 + data['y_pos'] + np.random.normal(size=1000, scale=0.4) data['count'] = (np.random.exponential(size=1000, scale=100) * data['x_pos']).astype(int) data['decay'] = np.random.normal(size=1000, scale=1e-3) + data['amplitude'] * 1e-4 data['decay'][data['type'] == 'Type-A'] /= 2 data['decay'][data['type'] == 'Type-E'] *= 3 # Create ScatterPlotWidget and configure its fields spw = pg.ScatterPlotWidget() spw.setFields([ ('x_pos', {'units': 'm'}), ('y_pos', {'units': 'm'}), ('count', {}), ('amplitude', {'units': 'V'}), ('decay', {'units': 's'}), ('type', {'mode': 'enum', 'values': strings}), ]) spw.setData(data) spw.show() ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/SimplePlot.py000066400000000000000000000007311300727121400221020ustar00rootroot00000000000000import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg import pyqtgraph.exporters import numpy as np plt = pg.plot(np.random.normal(size=100), title="Simplest possible plotting example") ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if sys.flags.interactive != 1 or not hasattr(pg.QtCore, 'PYQT_VERSION'): pg.QtGui.QApplication.exec_() pyqtgraph-pyqtgraph-0.10.0/examples/SpinBox.py000066400000000000000000000100121300727121400213650ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ This example demonstrates the SpinBox widget, which is an extension of QDoubleSpinBox providing some advanced features: * SI-prefixed units * Non-linear stepping modes * Bounded/unbounded values """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np app = QtGui.QApplication([]) spins = [ ("Floating-point spin box, min=0, no maximum.", pg.SpinBox(value=5.0, bounds=[0, None])), ("Integer spin box, dec stepping
(1-9, 10-90, 100-900, etc), decimals=4", pg.SpinBox(value=10, int=True, dec=True, minStep=1, step=1, decimals=4)), ("Float with SI-prefixed units
(n, u, m, k, M, etc)", pg.SpinBox(value=0.9, suffix='V', siPrefix=True)), ("Float with SI-prefixed units,
dec step=0.1, minStep=0.1", pg.SpinBox(value=1.0, suffix='V', siPrefix=True, dec=True, step=0.1, minStep=0.1)), ("Float with SI-prefixed units,
dec step=0.5, minStep=0.01", pg.SpinBox(value=1.0, suffix='V', siPrefix=True, dec=True, step=0.5, minStep=0.01)), ("Float with SI-prefixed units,
dec step=1.0, minStep=0.001", pg.SpinBox(value=1.0, suffix='V', siPrefix=True, dec=True, step=1.0, minStep=0.001)), ] win = QtGui.QMainWindow() win.setWindowTitle('pyqtgraph example: SpinBox') cw = QtGui.QWidget() layout = QtGui.QGridLayout() cw.setLayout(layout) win.setCentralWidget(cw) win.show() #win.resize(300, 600) changingLabel = QtGui.QLabel() ## updated immediately changedLabel = QtGui.QLabel() ## updated only when editing is finished or mouse wheel has stopped for 0.3sec changingLabel.setMinimumWidth(200) font = changingLabel.font() font.setBold(True) font.setPointSize(14) changingLabel.setFont(font) changedLabel.setFont(font) labels = [] def valueChanged(sb): changedLabel.setText("Final value: %s" % str(sb.value())) def valueChanging(sb, value): changingLabel.setText("Value changing: %s" % str(sb.value())) for text, spin in spins: label = QtGui.QLabel(text) labels.append(label) layout.addWidget(label) layout.addWidget(spin) spin.sigValueChanged.connect(valueChanged) spin.sigValueChanging.connect(valueChanging) layout.addWidget(changingLabel, 0, 1) layout.addWidget(changedLabel, 2, 1) #def mkWin(): #win = QtGui.QMainWindow() #g = QtGui.QFormLayout() #w = QtGui.QWidget() #w.setLayout(g) #win.setCentralWidget(w) #s1 = SpinBox(value=5, step=0.1, bounds=[-1.5, None], suffix='units') #t1 = QtGui.QLineEdit() #g.addRow(s1, t1) #s2 = SpinBox(value=10e-6, dec=True, step=0.1, minStep=1e-6, suffix='A', siPrefix=True) #t2 = QtGui.QLineEdit() #g.addRow(s2, t2) #s3 = SpinBox(value=1000, dec=True, step=0.5, minStep=1e-6, bounds=[1, 1e9], suffix='Hz', siPrefix=True) #t3 = QtGui.QLineEdit() #g.addRow(s3, t3) #s4 = SpinBox(int=True, dec=True, step=1, minStep=1, bounds=[-10, 1000]) #t4 = QtGui.QLineEdit() #g.addRow(s4, t4) #win.show() #import sys #for sb in [s1, s2, s3,s4]: ##QtCore.QObject.connect(sb, QtCore.SIGNAL('valueChanged(double)'), lambda v: sys.stdout.write(str(sb) + " valueChanged\n")) ##QtCore.QObject.connect(sb, QtCore.SIGNAL('editingFinished()'), lambda: sys.stdout.write(str(sb) + " editingFinished\n")) #sb.sigValueChanged.connect(valueChanged) #sb.sigValueChanging.connect(valueChanging) #sb.editingFinished.connect(lambda: sys.stdout.write(str(sb) + " editingFinished\n")) #return win, w, [s1, s2, s3, s4] #a = mkWin() #def test(n=100): #for i in range(n): #win, w, sb = mkWin() #for s in sb: #w.setParent(None) #s.setParent(None) #s.valueChanged.disconnect() #s.editingFinished.disconnect() ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/Symbols.py000077500000000000000000000044111300727121400214440ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ This example shows all the scatter plot symbols available in pyqtgraph. These symbols are used to mark point locations for scatter plots and some line plots, similar to "markers" in matplotlib and vispy. """ import initExample ## Add path to library (just for examples; you do not need this) from pyqtgraph.Qt import QtGui, QtCore import pyqtgraph as pg app = QtGui.QApplication([]) win = pg.GraphicsWindow(title="Scatter Plot Symbols") win.resize(1000,600) pg.setConfigOptions(antialias=True) plot = win.addPlot(title="Plotting with symbols") plot.addLegend() plot.plot([0, 1, 2, 3, 4], pen=(0,0,200), symbolBrush=(0,0,200), symbolPen='w', symbol='o', symbolSize=14, name="symbol='o'") plot.plot([1, 2, 3, 4, 5], pen=(0,128,0), symbolBrush=(0,128,0), symbolPen='w', symbol='t', symbolSize=14, name="symbol='t'") plot.plot([2, 3, 4, 5, 6], pen=(19,234,201), symbolBrush=(19,234,201), symbolPen='w', symbol='t1', symbolSize=14, name="symbol='t1'") plot.plot([3, 4, 5, 6, 7], pen=(195,46,212), symbolBrush=(195,46,212), symbolPen='w', symbol='t2', symbolSize=14, name="symbol='t2'") plot.plot([4, 5, 6, 7, 8], pen=(250,194,5), symbolBrush=(250,194,5), symbolPen='w', symbol='t3', symbolSize=14, name="symbol='t3'") plot.plot([5, 6, 7, 8, 9], pen=(54,55,55), symbolBrush=(55,55,55), symbolPen='w', symbol='s', symbolSize=14, name="symbol='s'") plot.plot([6, 7, 8, 9, 10], pen=(0,114,189), symbolBrush=(0,114,189), symbolPen='w', symbol='p', symbolSize=14, name="symbol='p'") plot.plot([7, 8, 9, 10, 11], pen=(217,83,25), symbolBrush=(217,83,25), symbolPen='w', symbol='h', symbolSize=14, name="symbol='h'") plot.plot([8, 9, 10, 11, 12], pen=(237,177,32), symbolBrush=(237,177,32), symbolPen='w', symbol='star', symbolSize=14, name="symbol='star'") plot.plot([9, 10, 11, 12, 13], pen=(126,47,142), symbolBrush=(126,47,142), symbolPen='w', symbol='+', symbolSize=14, name="symbol='+'") plot.plot([10, 11, 12, 13, 14], pen=(119,172,48), symbolBrush=(119,172,48), symbolPen='w', symbol='d', symbolSize=14, name="symbol='d'") plot.setXRange(-2, 4) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/TableWidget.py000066400000000000000000000016311300727121400222050ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Simple demonstration of TableWidget, which is an extension of QTableWidget that automatically displays a variety of tabluar data formats. """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np app = QtGui.QApplication([]) w = pg.TableWidget() w.show() w.resize(500,500) w.setWindowTitle('pyqtgraph example: TableWidget') data = np.array([ (1, 1.6, 'x'), (3, 5.4, 'y'), (8, 12.5, 'z'), (443, 1e-12, 'w'), ], dtype=[('Column 1', int), ('Column 2', float), ('Column 3', object)]) w.setData(data) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/TreeWidget.py000066400000000000000000000027211300727121400220560ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Simple demonstration of TreeWidget, which is an extension of QTreeWidget that allows widgets to be added and dragged within the tree more easily. """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np app = QtGui.QApplication([]) w = pg.TreeWidget() w.setColumnCount(2) w.show() w.setWindowTitle('pyqtgraph example: TreeWidget') i1 = QtGui.QTreeWidgetItem(["Item 1"]) i11 = QtGui.QTreeWidgetItem(["Item 1.1"]) i12 = QtGui.QTreeWidgetItem(["Item 1.2"]) i2 = QtGui.QTreeWidgetItem(["Item 2"]) i21 = QtGui.QTreeWidgetItem(["Item 2.1"]) i211 = pg.TreeWidgetItem(["Item 2.1.1"]) i212 = pg.TreeWidgetItem(["Item 2.1.2"]) i22 = pg.TreeWidgetItem(["Item 2.2"]) i3 = pg.TreeWidgetItem(["Item 3"]) i4 = pg.TreeWidgetItem(["Item 4"]) i5 = pg.TreeWidgetItem(["Item 5"]) b5 = QtGui.QPushButton('Button') i5.setWidget(1, b5) w.addTopLevelItem(i1) w.addTopLevelItem(i2) w.addTopLevelItem(i3) w.addTopLevelItem(i4) w.addTopLevelItem(i5) i1.addChild(i11) i1.addChild(i12) i2.addChild(i21) i21.addChild(i211) i21.addChild(i212) i2.addChild(i22) b1 = QtGui.QPushButton("Button") w.setItemWidget(i1, 1, b1) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/VideoSpeedTest.py000066400000000000000000000141311300727121400227000ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Tests the speed of image updates for an ImageItem and RawImageWidget. The speed will generally depend on the type of data being shown, whether it is being scaled and/or converted by lookup table, and whether OpenGL is used by the view widget """ import initExample ## Add path to library (just for examples; you do not need this) from pyqtgraph.Qt import QtGui, QtCore, USE_PYSIDE, USE_PYQT5 import numpy as np import pyqtgraph as pg import pyqtgraph.ptime as ptime if USE_PYSIDE: import VideoTemplate_pyside as VideoTemplate elif USE_PYQT5: import VideoTemplate_pyqt5 as VideoTemplate else: import VideoTemplate_pyqt as VideoTemplate #QtGui.QApplication.setGraphicsSystem('raster') app = QtGui.QApplication([]) win = QtGui.QMainWindow() win.setWindowTitle('pyqtgraph example: VideoSpeedTest') ui = VideoTemplate.Ui_MainWindow() ui.setupUi(win) win.show() try: from pyqtgraph.widgets.RawImageWidget import RawImageGLWidget except ImportError: ui.rawGLRadio.setEnabled(False) ui.rawGLRadio.setText(ui.rawGLRadio.text() + " (OpenGL not available)") else: ui.rawGLImg = RawImageGLWidget() ui.stack.addWidget(ui.rawGLImg) ui.maxSpin1.setOpts(value=255, step=1) ui.minSpin1.setOpts(value=0, step=1) #ui.graphicsView.useOpenGL() ## buggy, but you can try it if you need extra speed. vb = pg.ViewBox() ui.graphicsView.setCentralItem(vb) vb.setAspectLocked() img = pg.ImageItem() vb.addItem(img) vb.setRange(QtCore.QRectF(0, 0, 512, 512)) LUT = None def updateLUT(): global LUT, ui dtype = ui.dtypeCombo.currentText() if dtype == 'uint8': n = 256 else: n = 4096 LUT = ui.gradient.getLookupTable(n, alpha=ui.alphaCheck.isChecked()) ui.gradient.sigGradientChanged.connect(updateLUT) updateLUT() ui.alphaCheck.toggled.connect(updateLUT) def updateScale(): global ui spins = [ui.minSpin1, ui.maxSpin1, ui.minSpin2, ui.maxSpin2, ui.minSpin3, ui.maxSpin3] if ui.rgbLevelsCheck.isChecked(): for s in spins[2:]: s.setEnabled(True) else: for s in spins[2:]: s.setEnabled(False) ui.rgbLevelsCheck.toggled.connect(updateScale) cache = {} def mkData(): with pg.BusyCursor(): global data, cache, ui frames = ui.framesSpin.value() width = ui.widthSpin.value() height = ui.heightSpin.value() dtype = (ui.dtypeCombo.currentText(), ui.rgbCheck.isChecked(), frames, width, height) if dtype not in cache: if dtype[0] == 'uint8': dt = np.uint8 loc = 128 scale = 64 mx = 255 elif dtype[0] == 'uint16': dt = np.uint16 loc = 4096 scale = 1024 mx = 2**16 elif dtype[0] == 'float': dt = np.float loc = 1.0 scale = 0.1 if ui.rgbCheck.isChecked(): data = np.random.normal(size=(frames,width,height,3), loc=loc, scale=scale) data = pg.gaussianFilter(data, (0, 6, 6, 0)) else: data = np.random.normal(size=(frames,width,height), loc=loc, scale=scale) data = pg.gaussianFilter(data, (0, 6, 6)) if dtype[0] != 'float': data = np.clip(data, 0, mx) data = data.astype(dt) data[:, 10, 10:50] = mx data[:, 9:12, 48] = mx data[:, 8:13, 47] = mx cache = {dtype: data} # clear to save memory (but keep one to prevent unnecessary regeneration) data = cache[dtype] updateLUT() updateSize() def updateSize(): global ui frames = ui.framesSpin.value() width = ui.widthSpin.value() height = ui.heightSpin.value() dtype = np.dtype(str(ui.dtypeCombo.currentText())) rgb = 3 if ui.rgbCheck.isChecked() else 1 ui.sizeLabel.setText('%d MB' % (frames * width * height * rgb * dtype.itemsize / 1e6)) mkData() ui.dtypeCombo.currentIndexChanged.connect(mkData) ui.rgbCheck.toggled.connect(mkData) ui.widthSpin.editingFinished.connect(mkData) ui.heightSpin.editingFinished.connect(mkData) ui.framesSpin.editingFinished.connect(mkData) ui.widthSpin.valueChanged.connect(updateSize) ui.heightSpin.valueChanged.connect(updateSize) ui.framesSpin.valueChanged.connect(updateSize) ptr = 0 lastTime = ptime.time() fps = None def update(): global ui, ptr, lastTime, fps, LUT, img if ui.lutCheck.isChecked(): useLut = LUT else: useLut = None downsample = ui.downsampleCheck.isChecked() if ui.scaleCheck.isChecked(): if ui.rgbLevelsCheck.isChecked(): useScale = [ [ui.minSpin1.value(), ui.maxSpin1.value()], [ui.minSpin2.value(), ui.maxSpin2.value()], [ui.minSpin3.value(), ui.maxSpin3.value()]] else: useScale = [ui.minSpin1.value(), ui.maxSpin1.value()] else: useScale = None if ui.rawRadio.isChecked(): ui.rawImg.setImage(data[ptr%data.shape[0]], lut=useLut, levels=useScale) ui.stack.setCurrentIndex(1) elif ui.rawGLRadio.isChecked(): ui.rawGLImg.setImage(data[ptr%data.shape[0]], lut=useLut, levels=useScale) ui.stack.setCurrentIndex(2) else: img.setImage(data[ptr%data.shape[0]], autoLevels=False, levels=useScale, lut=useLut, autoDownsample=downsample) ui.stack.setCurrentIndex(0) #img.setImage(data[ptr%data.shape[0]], autoRange=False) ptr += 1 now = ptime.time() dt = now - lastTime lastTime = now if fps is None: fps = 1.0/dt else: s = np.clip(dt*3., 0, 1) fps = fps * (1-s) + (1.0/dt) * s ui.fpsLabel.setText('%0.2f fps' % fps) app.processEvents() ## force complete redraw for every plot timer = QtCore.QTimer() timer.timeout.connect(update) timer.start(0) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/VideoTemplate.ui000066400000000000000000000221371300727121400225450ustar00rootroot00000000000000 MainWindow 0 0 695 798 MainWindow Auto downsample Scale Data RawImageWidget GraphicsView + ImageItem true 1 0 0 RawGLImageWidget uint8 uint16 float Data type RGB false <---> Qt::AlignCenter false <---> Qt::AlignCenter false <---> Qt::AlignCenter false Use Lookup Table alpha 0 0 Qt::Horizontal 40 20 12 FPS Qt::AlignCenter RGB Image size QAbstractSpinBox::NoButtons 10 QAbstractSpinBox::PlusMinus 10000 512 QAbstractSpinBox::NoButtons 10000 512 GraphicsView QGraphicsView
pyqtgraph
 RawImageWidget QWidget
pyqtgraph.widgets.RawImageWidget
1 GradientWidget QWidget
pyqtgraph
1 SpinBox QDoubleSpinBox
pyqtgraph
 pyqtgraph-pyqtgraph-0.10.0/examples/VideoTemplate_pyqt.py000066400000000000000000000267171300727121400236450ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file 'examples/VideoTemplate.ui' # # Created by: PyQt4 UI code generator 4.11.4 # # WARNING! All changes made in this file will be lost! from PyQt4 import QtCore, QtGui try: _fromUtf8 = QtCore.QString.fromUtf8 except AttributeError: def _fromUtf8(s): return s try: _encoding = QtGui.QApplication.UnicodeUTF8 def _translate(context, text, disambig): return QtGui.QApplication.translate(context, text, disambig, _encoding) except AttributeError: def _translate(context, text, disambig): return QtGui.QApplication.translate(context, text, disambig) class Ui_MainWindow(object): def setupUi(self, MainWindow): MainWindow.setObjectName(_fromUtf8("MainWindow")) MainWindow.resize(695, 798) self.centralwidget = QtGui.QWidget(MainWindow) self.centralwidget.setObjectName(_fromUtf8("centralwidget")) self.gridLayout_2 = QtGui.QGridLayout(self.centralwidget) self.gridLayout_2.setObjectName(_fromUtf8("gridLayout_2")) self.downsampleCheck = QtGui.QCheckBox(self.centralwidget) self.downsampleCheck.setObjectName(_fromUtf8("downsampleCheck")) self.gridLayout_2.addWidget(self.downsampleCheck, 8, 0, 1, 2) self.scaleCheck = QtGui.QCheckBox(self.centralwidget) self.scaleCheck.setObjectName(_fromUtf8("scaleCheck")) self.gridLayout_2.addWidget(self.scaleCheck, 4, 0, 1, 1) self.gridLayout = QtGui.QGridLayout() self.gridLayout.setObjectName(_fromUtf8("gridLayout")) self.rawRadio = QtGui.QRadioButton(self.centralwidget) self.rawRadio.setObjectName(_fromUtf8("rawRadio")) self.gridLayout.addWidget(self.rawRadio, 3, 0, 1, 1) self.gfxRadio = QtGui.QRadioButton(self.centralwidget) self.gfxRadio.setChecked(True) self.gfxRadio.setObjectName(_fromUtf8("gfxRadio")) self.gridLayout.addWidget(self.gfxRadio, 2, 0, 1, 1) self.stack = QtGui.QStackedWidget(self.centralwidget) self.stack.setObjectName(_fromUtf8("stack")) self.page = QtGui.QWidget() self.page.setObjectName(_fromUtf8("page")) self.gridLayout_3 = QtGui.QGridLayout(self.page) self.gridLayout_3.setObjectName(_fromUtf8("gridLayout_3")) self.graphicsView = GraphicsView(self.page) self.graphicsView.setObjectName(_fromUtf8("graphicsView")) self.gridLayout_3.addWidget(self.graphicsView, 0, 0, 1, 1) self.stack.addWidget(self.page) self.page_2 = QtGui.QWidget() self.page_2.setObjectName(_fromUtf8("page_2")) self.gridLayout_4 = QtGui.QGridLayout(self.page_2) self.gridLayout_4.setObjectName(_fromUtf8("gridLayout_4")) self.rawImg = RawImageWidget(self.page_2) sizePolicy = QtGui.QSizePolicy(QtGui.QSizePolicy.Expanding, QtGui.QSizePolicy.Preferred) sizePolicy.setHorizontalStretch(0) sizePolicy.setVerticalStretch(0) sizePolicy.setHeightForWidth(self.rawImg.sizePolicy().hasHeightForWidth()) self.rawImg.setSizePolicy(sizePolicy) self.rawImg.setObjectName(_fromUtf8("rawImg")) self.gridLayout_4.addWidget(self.rawImg, 0, 0, 1, 1) self.stack.addWidget(self.page_2) self.gridLayout.addWidget(self.stack, 0, 0, 1, 1) self.rawGLRadio = QtGui.QRadioButton(self.centralwidget) self.rawGLRadio.setObjectName(_fromUtf8("rawGLRadio")) self.gridLayout.addWidget(self.rawGLRadio, 4, 0, 1, 1) self.gridLayout_2.addLayout(self.gridLayout, 1, 0, 1, 4) self.dtypeCombo = QtGui.QComboBox(self.centralwidget) self.dtypeCombo.setObjectName(_fromUtf8("dtypeCombo")) self.dtypeCombo.addItem(_fromUtf8("")) self.dtypeCombo.addItem(_fromUtf8("")) self.dtypeCombo.addItem(_fromUtf8("")) self.gridLayout_2.addWidget(self.dtypeCombo, 3, 2, 1, 1) self.label = QtGui.QLabel(self.centralwidget) self.label.setObjectName(_fromUtf8("label")) self.gridLayout_2.addWidget(self.label, 3, 0, 1, 1) self.rgbLevelsCheck = QtGui.QCheckBox(self.centralwidget) self.rgbLevelsCheck.setObjectName(_fromUtf8("rgbLevelsCheck")) self.gridLayout_2.addWidget(self.rgbLevelsCheck, 4, 1, 1, 1) self.horizontalLayout_2 = QtGui.QHBoxLayout() self.horizontalLayout_2.setObjectName(_fromUtf8("horizontalLayout_2")) self.minSpin2 = SpinBox(self.centralwidget) self.minSpin2.setEnabled(False) self.minSpin2.setObjectName(_fromUtf8("minSpin2")) self.horizontalLayout_2.addWidget(self.minSpin2) self.label_3 = QtGui.QLabel(self.centralwidget) self.label_3.setAlignment(QtCore.Qt.AlignCenter) self.label_3.setObjectName(_fromUtf8("label_3")) self.horizontalLayout_2.addWidget(self.label_3) self.maxSpin2 = SpinBox(self.centralwidget) self.maxSpin2.setEnabled(False) self.maxSpin2.setObjectName(_fromUtf8("maxSpin2")) self.horizontalLayout_2.addWidget(self.maxSpin2) self.gridLayout_2.addLayout(self.horizontalLayout_2, 5, 2, 1, 1) self.horizontalLayout = QtGui.QHBoxLayout() self.horizontalLayout.setObjectName(_fromUtf8("horizontalLayout")) self.minSpin1 = SpinBox(self.centralwidget) self.minSpin1.setObjectName(_fromUtf8("minSpin1")) self.horizontalLayout.addWidget(self.minSpin1) self.label_2 = QtGui.QLabel(self.centralwidget) self.label_2.setAlignment(QtCore.Qt.AlignCenter) self.label_2.setObjectName(_fromUtf8("label_2")) self.horizontalLayout.addWidget(self.label_2) self.maxSpin1 = SpinBox(self.centralwidget) self.maxSpin1.setObjectName(_fromUtf8("maxSpin1")) self.horizontalLayout.addWidget(self.maxSpin1) self.gridLayout_2.addLayout(self.horizontalLayout, 4, 2, 1, 1) self.horizontalLayout_3 = QtGui.QHBoxLayout() self.horizontalLayout_3.setObjectName(_fromUtf8("horizontalLayout_3")) self.minSpin3 = SpinBox(self.centralwidget) self.minSpin3.setEnabled(False) self.minSpin3.setObjectName(_fromUtf8("minSpin3")) self.horizontalLayout_3.addWidget(self.minSpin3) self.label_4 = QtGui.QLabel(self.centralwidget) self.label_4.setAlignment(QtCore.Qt.AlignCenter) self.label_4.setObjectName(_fromUtf8("label_4")) self.horizontalLayout_3.addWidget(self.label_4) self.maxSpin3 = SpinBox(self.centralwidget) self.maxSpin3.setEnabled(False) self.maxSpin3.setObjectName(_fromUtf8("maxSpin3")) self.horizontalLayout_3.addWidget(self.maxSpin3) self.gridLayout_2.addLayout(self.horizontalLayout_3, 6, 2, 1, 1) self.lutCheck = QtGui.QCheckBox(self.centralwidget) self.lutCheck.setObjectName(_fromUtf8("lutCheck")) self.gridLayout_2.addWidget(self.lutCheck, 7, 0, 1, 1) self.alphaCheck = QtGui.QCheckBox(self.centralwidget) self.alphaCheck.setObjectName(_fromUtf8("alphaCheck")) self.gridLayout_2.addWidget(self.alphaCheck, 7, 1, 1, 1) self.gradient = GradientWidget(self.centralwidget) sizePolicy = QtGui.QSizePolicy(QtGui.QSizePolicy.Expanding, QtGui.QSizePolicy.Preferred) sizePolicy.setHorizontalStretch(0) sizePolicy.setVerticalStretch(0) sizePolicy.setHeightForWidth(self.gradient.sizePolicy().hasHeightForWidth()) self.gradient.setSizePolicy(sizePolicy) self.gradient.setObjectName(_fromUtf8("gradient")) self.gridLayout_2.addWidget(self.gradient, 7, 2, 1, 2) spacerItem = QtGui.QSpacerItem(40, 20, QtGui.QSizePolicy.Expanding, QtGui.QSizePolicy.Minimum) self.gridLayout_2.addItem(spacerItem, 3, 3, 1, 1) self.fpsLabel = QtGui.QLabel(self.centralwidget) font = QtGui.QFont() font.setPointSize(12) self.fpsLabel.setFont(font) self.fpsLabel.setAlignment(QtCore.Qt.AlignCenter) self.fpsLabel.setObjectName(_fromUtf8("fpsLabel")) self.gridLayout_2.addWidget(self.fpsLabel, 0, 0, 1, 4) self.rgbCheck = QtGui.QCheckBox(self.centralwidget) self.rgbCheck.setObjectName(_fromUtf8("rgbCheck")) self.gridLayout_2.addWidget(self.rgbCheck, 3, 1, 1, 1) self.label_5 = QtGui.QLabel(self.centralwidget) self.label_5.setObjectName(_fromUtf8("label_5")) self.gridLayout_2.addWidget(self.label_5, 2, 0, 1, 1) self.horizontalLayout_4 = QtGui.QHBoxLayout() self.horizontalLayout_4.setObjectName(_fromUtf8("horizontalLayout_4")) self.framesSpin = QtGui.QSpinBox(self.centralwidget) self.framesSpin.setButtonSymbols(QtGui.QAbstractSpinBox.NoButtons) self.framesSpin.setProperty("value", 10) self.framesSpin.setObjectName(_fromUtf8("framesSpin")) self.horizontalLayout_4.addWidget(self.framesSpin) self.widthSpin = QtGui.QSpinBox(self.centralwidget) self.widthSpin.setButtonSymbols(QtGui.QAbstractSpinBox.PlusMinus) self.widthSpin.setMaximum(10000) self.widthSpin.setProperty("value", 512) self.widthSpin.setObjectName(_fromUtf8("widthSpin")) self.horizontalLayout_4.addWidget(self.widthSpin) self.heightSpin = QtGui.QSpinBox(self.centralwidget) self.heightSpin.setButtonSymbols(QtGui.QAbstractSpinBox.NoButtons) self.heightSpin.setMaximum(10000) self.heightSpin.setProperty("value", 512) self.heightSpin.setObjectName(_fromUtf8("heightSpin")) self.horizontalLayout_4.addWidget(self.heightSpin) self.gridLayout_2.addLayout(self.horizontalLayout_4, 2, 1, 1, 2) self.sizeLabel = QtGui.QLabel(self.centralwidget) self.sizeLabel.setText(_fromUtf8("")) self.sizeLabel.setObjectName(_fromUtf8("sizeLabel")) self.gridLayout_2.addWidget(self.sizeLabel, 2, 3, 1, 1) MainWindow.setCentralWidget(self.centralwidget) self.retranslateUi(MainWindow) self.stack.setCurrentIndex(1) QtCore.QMetaObject.connectSlotsByName(MainWindow) def retranslateUi(self, MainWindow): MainWindow.setWindowTitle(_translate("MainWindow", "MainWindow", None)) self.downsampleCheck.setText(_translate("MainWindow", "Auto downsample", None)) self.scaleCheck.setText(_translate("MainWindow", "Scale Data", None)) self.rawRadio.setText(_translate("MainWindow", "RawImageWidget", None)) self.gfxRadio.setText(_translate("MainWindow", "GraphicsView + ImageItem", None)) self.rawGLRadio.setText(_translate("MainWindow", "RawGLImageWidget", None)) self.dtypeCombo.setItemText(0, _translate("MainWindow", "uint8", None)) self.dtypeCombo.setItemText(1, _translate("MainWindow", "uint16", None)) self.dtypeCombo.setItemText(2, _translate("MainWindow", "float", None)) self.label.setText(_translate("MainWindow", "Data type", None)) self.rgbLevelsCheck.setText(_translate("MainWindow", "RGB", None)) self.label_3.setText(_translate("MainWindow", "<--->", None)) self.label_2.setText(_translate("MainWindow", "<--->", None)) self.label_4.setText(_translate("MainWindow", "<--->", None)) self.lutCheck.setText(_translate("MainWindow", "Use Lookup Table", None)) self.alphaCheck.setText(_translate("MainWindow", "alpha", None)) self.fpsLabel.setText(_translate("MainWindow", "FPS", None)) self.rgbCheck.setText(_translate("MainWindow", "RGB", None)) self.label_5.setText(_translate("MainWindow", "Image size", None)) from pyqtgraph import GradientWidget, GraphicsView, SpinBox from pyqtgraph.widgets.RawImageWidget import RawImageWidget pyqtgraph-pyqtgraph-0.10.0/examples/VideoTemplate_pyqt5.py000066400000000000000000000252551300727121400237260ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file 'examples/VideoTemplate.ui' # # Created by: PyQt5 UI code generator 5.5.1 # # WARNING! All changes made in this file will be lost! from PyQt5 import QtCore, QtGui, QtWidgets class Ui_MainWindow(object): def setupUi(self, MainWindow): MainWindow.setObjectName("MainWindow") MainWindow.resize(695, 798) self.centralwidget = QtWidgets.QWidget(MainWindow) self.centralwidget.setObjectName("centralwidget") self.gridLayout_2 = QtWidgets.QGridLayout(self.centralwidget) self.gridLayout_2.setObjectName("gridLayout_2") self.downsampleCheck = QtWidgets.QCheckBox(self.centralwidget) self.downsampleCheck.setObjectName("downsampleCheck") self.gridLayout_2.addWidget(self.downsampleCheck, 8, 0, 1, 2) self.scaleCheck = QtWidgets.QCheckBox(self.centralwidget) self.scaleCheck.setObjectName("scaleCheck") self.gridLayout_2.addWidget(self.scaleCheck, 4, 0, 1, 1) self.gridLayout = QtWidgets.QGridLayout() self.gridLayout.setObjectName("gridLayout") self.rawRadio = QtWidgets.QRadioButton(self.centralwidget) self.rawRadio.setObjectName("rawRadio") self.gridLayout.addWidget(self.rawRadio, 3, 0, 1, 1) self.gfxRadio = QtWidgets.QRadioButton(self.centralwidget) self.gfxRadio.setChecked(True) self.gfxRadio.setObjectName("gfxRadio") self.gridLayout.addWidget(self.gfxRadio, 2, 0, 1, 1) self.stack = QtWidgets.QStackedWidget(self.centralwidget) self.stack.setObjectName("stack") self.page = QtWidgets.QWidget() self.page.setObjectName("page") self.gridLayout_3 = QtWidgets.QGridLayout(self.page) self.gridLayout_3.setObjectName("gridLayout_3") self.graphicsView = GraphicsView(self.page) self.graphicsView.setObjectName("graphicsView") self.gridLayout_3.addWidget(self.graphicsView, 0, 0, 1, 1) self.stack.addWidget(self.page) self.page_2 = QtWidgets.QWidget() self.page_2.setObjectName("page_2") self.gridLayout_4 = QtWidgets.QGridLayout(self.page_2) self.gridLayout_4.setObjectName("gridLayout_4") self.rawImg = RawImageWidget(self.page_2) sizePolicy = QtWidgets.QSizePolicy(QtWidgets.QSizePolicy.Expanding, QtWidgets.QSizePolicy.Preferred) sizePolicy.setHorizontalStretch(0) sizePolicy.setVerticalStretch(0) sizePolicy.setHeightForWidth(self.rawImg.sizePolicy().hasHeightForWidth()) self.rawImg.setSizePolicy(sizePolicy) self.rawImg.setObjectName("rawImg") self.gridLayout_4.addWidget(self.rawImg, 0, 0, 1, 1) self.stack.addWidget(self.page_2) self.gridLayout.addWidget(self.stack, 0, 0, 1, 1) self.rawGLRadio = QtWidgets.QRadioButton(self.centralwidget) self.rawGLRadio.setObjectName("rawGLRadio") self.gridLayout.addWidget(self.rawGLRadio, 4, 0, 1, 1) self.gridLayout_2.addLayout(self.gridLayout, 1, 0, 1, 4) self.dtypeCombo = QtWidgets.QComboBox(self.centralwidget) self.dtypeCombo.setObjectName("dtypeCombo") self.dtypeCombo.addItem("") self.dtypeCombo.addItem("") self.dtypeCombo.addItem("") self.gridLayout_2.addWidget(self.dtypeCombo, 3, 2, 1, 1) self.label = QtWidgets.QLabel(self.centralwidget) self.label.setObjectName("label") self.gridLayout_2.addWidget(self.label, 3, 0, 1, 1) self.rgbLevelsCheck = QtWidgets.QCheckBox(self.centralwidget) self.rgbLevelsCheck.setObjectName("rgbLevelsCheck") self.gridLayout_2.addWidget(self.rgbLevelsCheck, 4, 1, 1, 1) self.horizontalLayout_2 = QtWidgets.QHBoxLayout() self.horizontalLayout_2.setObjectName("horizontalLayout_2") self.minSpin2 = SpinBox(self.centralwidget) self.minSpin2.setEnabled(False) self.minSpin2.setObjectName("minSpin2") self.horizontalLayout_2.addWidget(self.minSpin2) self.label_3 = QtWidgets.QLabel(self.centralwidget) self.label_3.setAlignment(QtCore.Qt.AlignCenter) self.label_3.setObjectName("label_3") self.horizontalLayout_2.addWidget(self.label_3) self.maxSpin2 = SpinBox(self.centralwidget) self.maxSpin2.setEnabled(False) self.maxSpin2.setObjectName("maxSpin2") self.horizontalLayout_2.addWidget(self.maxSpin2) self.gridLayout_2.addLayout(self.horizontalLayout_2, 5, 2, 1, 1) self.horizontalLayout = QtWidgets.QHBoxLayout() self.horizontalLayout.setObjectName("horizontalLayout") self.minSpin1 = SpinBox(self.centralwidget) self.minSpin1.setObjectName("minSpin1") self.horizontalLayout.addWidget(self.minSpin1) self.label_2 = QtWidgets.QLabel(self.centralwidget) self.label_2.setAlignment(QtCore.Qt.AlignCenter) self.label_2.setObjectName("label_2") self.horizontalLayout.addWidget(self.label_2) self.maxSpin1 = SpinBox(self.centralwidget) self.maxSpin1.setObjectName("maxSpin1") self.horizontalLayout.addWidget(self.maxSpin1) self.gridLayout_2.addLayout(self.horizontalLayout, 4, 2, 1, 1) self.horizontalLayout_3 = QtWidgets.QHBoxLayout() self.horizontalLayout_3.setObjectName("horizontalLayout_3") self.minSpin3 = SpinBox(self.centralwidget) self.minSpin3.setEnabled(False) self.minSpin3.setObjectName("minSpin3") self.horizontalLayout_3.addWidget(self.minSpin3) self.label_4 = QtWidgets.QLabel(self.centralwidget) self.label_4.setAlignment(QtCore.Qt.AlignCenter) self.label_4.setObjectName("label_4") self.horizontalLayout_3.addWidget(self.label_4) self.maxSpin3 = SpinBox(self.centralwidget) self.maxSpin3.setEnabled(False) self.maxSpin3.setObjectName("maxSpin3") self.horizontalLayout_3.addWidget(self.maxSpin3) self.gridLayout_2.addLayout(self.horizontalLayout_3, 6, 2, 1, 1) self.lutCheck = QtWidgets.QCheckBox(self.centralwidget) self.lutCheck.setObjectName("lutCheck") self.gridLayout_2.addWidget(self.lutCheck, 7, 0, 1, 1) self.alphaCheck = QtWidgets.QCheckBox(self.centralwidget) self.alphaCheck.setObjectName("alphaCheck") self.gridLayout_2.addWidget(self.alphaCheck, 7, 1, 1, 1) self.gradient = GradientWidget(self.centralwidget) sizePolicy = QtWidgets.QSizePolicy(QtWidgets.QSizePolicy.Expanding, QtWidgets.QSizePolicy.Preferred) sizePolicy.setHorizontalStretch(0) sizePolicy.setVerticalStretch(0) sizePolicy.setHeightForWidth(self.gradient.sizePolicy().hasHeightForWidth()) self.gradient.setSizePolicy(sizePolicy) self.gradient.setObjectName("gradient") self.gridLayout_2.addWidget(self.gradient, 7, 2, 1, 2) spacerItem = QtWidgets.QSpacerItem(40, 20, QtWidgets.QSizePolicy.Expanding, QtWidgets.QSizePolicy.Minimum) self.gridLayout_2.addItem(spacerItem, 3, 3, 1, 1) self.fpsLabel = QtWidgets.QLabel(self.centralwidget) font = QtGui.QFont() font.setPointSize(12) self.fpsLabel.setFont(font) self.fpsLabel.setAlignment(QtCore.Qt.AlignCenter) self.fpsLabel.setObjectName("fpsLabel") self.gridLayout_2.addWidget(self.fpsLabel, 0, 0, 1, 4) self.rgbCheck = QtWidgets.QCheckBox(self.centralwidget) self.rgbCheck.setObjectName("rgbCheck") self.gridLayout_2.addWidget(self.rgbCheck, 3, 1, 1, 1) self.label_5 = QtWidgets.QLabel(self.centralwidget) self.label_5.setObjectName("label_5") self.gridLayout_2.addWidget(self.label_5, 2, 0, 1, 1) self.horizontalLayout_4 = QtWidgets.QHBoxLayout() self.horizontalLayout_4.setObjectName("horizontalLayout_4") self.framesSpin = QtWidgets.QSpinBox(self.centralwidget) self.framesSpin.setButtonSymbols(QtWidgets.QAbstractSpinBox.NoButtons) self.framesSpin.setProperty("value", 10) self.framesSpin.setObjectName("framesSpin") self.horizontalLayout_4.addWidget(self.framesSpin) self.widthSpin = QtWidgets.QSpinBox(self.centralwidget) self.widthSpin.setButtonSymbols(QtWidgets.QAbstractSpinBox.PlusMinus) self.widthSpin.setMaximum(10000) self.widthSpin.setProperty("value", 512) self.widthSpin.setObjectName("widthSpin") self.horizontalLayout_4.addWidget(self.widthSpin) self.heightSpin = QtWidgets.QSpinBox(self.centralwidget) self.heightSpin.setButtonSymbols(QtWidgets.QAbstractSpinBox.NoButtons) self.heightSpin.setMaximum(10000) self.heightSpin.setProperty("value", 512) self.heightSpin.setObjectName("heightSpin") self.horizontalLayout_4.addWidget(self.heightSpin) self.gridLayout_2.addLayout(self.horizontalLayout_4, 2, 1, 1, 2) self.sizeLabel = QtWidgets.QLabel(self.centralwidget) self.sizeLabel.setText("") self.sizeLabel.setObjectName("sizeLabel") self.gridLayout_2.addWidget(self.sizeLabel, 2, 3, 1, 1) MainWindow.setCentralWidget(self.centralwidget) self.retranslateUi(MainWindow) self.stack.setCurrentIndex(1) QtCore.QMetaObject.connectSlotsByName(MainWindow) def retranslateUi(self, MainWindow): _translate = QtCore.QCoreApplication.translate MainWindow.setWindowTitle(_translate("MainWindow", "MainWindow")) self.downsampleCheck.setText(_translate("MainWindow", "Auto downsample")) self.scaleCheck.setText(_translate("MainWindow", "Scale Data")) self.rawRadio.setText(_translate("MainWindow", "RawImageWidget")) self.gfxRadio.setText(_translate("MainWindow", "GraphicsView + ImageItem")) self.rawGLRadio.setText(_translate("MainWindow", "RawGLImageWidget")) self.dtypeCombo.setItemText(0, _translate("MainWindow", "uint8")) self.dtypeCombo.setItemText(1, _translate("MainWindow", "uint16")) self.dtypeCombo.setItemText(2, _translate("MainWindow", "float")) self.label.setText(_translate("MainWindow", "Data type")) self.rgbLevelsCheck.setText(_translate("MainWindow", "RGB")) self.label_3.setText(_translate("MainWindow", "<--->")) self.label_2.setText(_translate("MainWindow", "<--->")) self.label_4.setText(_translate("MainWindow", "<--->")) self.lutCheck.setText(_translate("MainWindow", "Use Lookup Table")) self.alphaCheck.setText(_translate("MainWindow", "alpha")) self.fpsLabel.setText(_translate("MainWindow", "FPS")) self.rgbCheck.setText(_translate("MainWindow", "RGB")) self.label_5.setText(_translate("MainWindow", "Image size")) from pyqtgraph import GradientWidget, GraphicsView, SpinBox from pyqtgraph.widgets.RawImageWidget import RawImageWidget pyqtgraph-pyqtgraph-0.10.0/examples/VideoTemplate_pyside.py000066400000000000000000000270211300727121400241320ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file 'examples/VideoTemplate.ui' # # Created: Wed Oct 26 09:21:01 2016 # by: pyside-uic 0.2.15 running on PySide 1.2.2 # # WARNING! All changes made in this file will be lost! from PySide import QtCore, QtGui class Ui_MainWindow(object): def setupUi(self, MainWindow): MainWindow.setObjectName("MainWindow") MainWindow.resize(695, 798) self.centralwidget = QtGui.QWidget(MainWindow) self.centralwidget.setObjectName("centralwidget") self.gridLayout_2 = QtGui.QGridLayout(self.centralwidget) self.gridLayout_2.setObjectName("gridLayout_2") self.downsampleCheck = QtGui.QCheckBox(self.centralwidget) self.downsampleCheck.setObjectName("downsampleCheck") self.gridLayout_2.addWidget(self.downsampleCheck, 8, 0, 1, 2) self.scaleCheck = QtGui.QCheckBox(self.centralwidget) self.scaleCheck.setObjectName("scaleCheck") self.gridLayout_2.addWidget(self.scaleCheck, 4, 0, 1, 1) self.gridLayout = QtGui.QGridLayout() self.gridLayout.setObjectName("gridLayout") self.rawRadio = QtGui.QRadioButton(self.centralwidget) self.rawRadio.setObjectName("rawRadio") self.gridLayout.addWidget(self.rawRadio, 3, 0, 1, 1) self.gfxRadio = QtGui.QRadioButton(self.centralwidget) self.gfxRadio.setChecked(True) self.gfxRadio.setObjectName("gfxRadio") self.gridLayout.addWidget(self.gfxRadio, 2, 0, 1, 1) self.stack = QtGui.QStackedWidget(self.centralwidget) self.stack.setObjectName("stack") self.page = QtGui.QWidget() self.page.setObjectName("page") self.gridLayout_3 = QtGui.QGridLayout(self.page) self.gridLayout_3.setObjectName("gridLayout_3") self.graphicsView = GraphicsView(self.page) self.graphicsView.setObjectName("graphicsView") self.gridLayout_3.addWidget(self.graphicsView, 0, 0, 1, 1) self.stack.addWidget(self.page) self.page_2 = QtGui.QWidget() self.page_2.setObjectName("page_2") self.gridLayout_4 = QtGui.QGridLayout(self.page_2) self.gridLayout_4.setObjectName("gridLayout_4") self.rawImg = RawImageWidget(self.page_2) sizePolicy = QtGui.QSizePolicy(QtGui.QSizePolicy.Expanding, QtGui.QSizePolicy.Preferred) sizePolicy.setHorizontalStretch(0) sizePolicy.setVerticalStretch(0) sizePolicy.setHeightForWidth(self.rawImg.sizePolicy().hasHeightForWidth()) self.rawImg.setSizePolicy(sizePolicy) self.rawImg.setObjectName("rawImg") self.gridLayout_4.addWidget(self.rawImg, 0, 0, 1, 1) self.stack.addWidget(self.page_2) self.gridLayout.addWidget(self.stack, 0, 0, 1, 1) self.rawGLRadio = QtGui.QRadioButton(self.centralwidget) self.rawGLRadio.setObjectName("rawGLRadio") self.gridLayout.addWidget(self.rawGLRadio, 4, 0, 1, 1) self.gridLayout_2.addLayout(self.gridLayout, 1, 0, 1, 4) self.dtypeCombo = QtGui.QComboBox(self.centralwidget) self.dtypeCombo.setObjectName("dtypeCombo") self.dtypeCombo.addItem("") self.dtypeCombo.addItem("") self.dtypeCombo.addItem("") self.gridLayout_2.addWidget(self.dtypeCombo, 3, 2, 1, 1) self.label = QtGui.QLabel(self.centralwidget) self.label.setObjectName("label") self.gridLayout_2.addWidget(self.label, 3, 0, 1, 1) self.rgbLevelsCheck = QtGui.QCheckBox(self.centralwidget) self.rgbLevelsCheck.setObjectName("rgbLevelsCheck") self.gridLayout_2.addWidget(self.rgbLevelsCheck, 4, 1, 1, 1) self.horizontalLayout_2 = QtGui.QHBoxLayout() self.horizontalLayout_2.setObjectName("horizontalLayout_2") self.minSpin2 = SpinBox(self.centralwidget) self.minSpin2.setEnabled(False) self.minSpin2.setObjectName("minSpin2") self.horizontalLayout_2.addWidget(self.minSpin2) self.label_3 = QtGui.QLabel(self.centralwidget) self.label_3.setAlignment(QtCore.Qt.AlignCenter) self.label_3.setObjectName("label_3") self.horizontalLayout_2.addWidget(self.label_3) self.maxSpin2 = SpinBox(self.centralwidget) self.maxSpin2.setEnabled(False) self.maxSpin2.setObjectName("maxSpin2") self.horizontalLayout_2.addWidget(self.maxSpin2) self.gridLayout_2.addLayout(self.horizontalLayout_2, 5, 2, 1, 1) self.horizontalLayout = QtGui.QHBoxLayout() self.horizontalLayout.setObjectName("horizontalLayout") self.minSpin1 = SpinBox(self.centralwidget) self.minSpin1.setObjectName("minSpin1") self.horizontalLayout.addWidget(self.minSpin1) self.label_2 = QtGui.QLabel(self.centralwidget) self.label_2.setAlignment(QtCore.Qt.AlignCenter) self.label_2.setObjectName("label_2") self.horizontalLayout.addWidget(self.label_2) self.maxSpin1 = SpinBox(self.centralwidget) self.maxSpin1.setObjectName("maxSpin1") self.horizontalLayout.addWidget(self.maxSpin1) self.gridLayout_2.addLayout(self.horizontalLayout, 4, 2, 1, 1) self.horizontalLayout_3 = QtGui.QHBoxLayout() self.horizontalLayout_3.setObjectName("horizontalLayout_3") self.minSpin3 = SpinBox(self.centralwidget) self.minSpin3.setEnabled(False) self.minSpin3.setObjectName("minSpin3") self.horizontalLayout_3.addWidget(self.minSpin3) self.label_4 = QtGui.QLabel(self.centralwidget) self.label_4.setAlignment(QtCore.Qt.AlignCenter) self.label_4.setObjectName("label_4") self.horizontalLayout_3.addWidget(self.label_4) self.maxSpin3 = SpinBox(self.centralwidget) self.maxSpin3.setEnabled(False) self.maxSpin3.setObjectName("maxSpin3") self.horizontalLayout_3.addWidget(self.maxSpin3) self.gridLayout_2.addLayout(self.horizontalLayout_3, 6, 2, 1, 1) self.lutCheck = QtGui.QCheckBox(self.centralwidget) self.lutCheck.setObjectName("lutCheck") self.gridLayout_2.addWidget(self.lutCheck, 7, 0, 1, 1) self.alphaCheck = QtGui.QCheckBox(self.centralwidget) self.alphaCheck.setObjectName("alphaCheck") self.gridLayout_2.addWidget(self.alphaCheck, 7, 1, 1, 1) self.gradient = GradientWidget(self.centralwidget) sizePolicy = QtGui.QSizePolicy(QtGui.QSizePolicy.Expanding, QtGui.QSizePolicy.Preferred) sizePolicy.setHorizontalStretch(0) sizePolicy.setVerticalStretch(0) sizePolicy.setHeightForWidth(self.gradient.sizePolicy().hasHeightForWidth()) self.gradient.setSizePolicy(sizePolicy) self.gradient.setObjectName("gradient") self.gridLayout_2.addWidget(self.gradient, 7, 2, 1, 2) spacerItem = QtGui.QSpacerItem(40, 20, QtGui.QSizePolicy.Expanding, QtGui.QSizePolicy.Minimum) self.gridLayout_2.addItem(spacerItem, 3, 3, 1, 1) self.fpsLabel = QtGui.QLabel(self.centralwidget) font = QtGui.QFont() font.setPointSize(12) self.fpsLabel.setFont(font) self.fpsLabel.setAlignment(QtCore.Qt.AlignCenter) self.fpsLabel.setObjectName("fpsLabel") self.gridLayout_2.addWidget(self.fpsLabel, 0, 0, 1, 4) self.rgbCheck = QtGui.QCheckBox(self.centralwidget) self.rgbCheck.setObjectName("rgbCheck") self.gridLayout_2.addWidget(self.rgbCheck, 3, 1, 1, 1) self.label_5 = QtGui.QLabel(self.centralwidget) self.label_5.setObjectName("label_5") self.gridLayout_2.addWidget(self.label_5, 2, 0, 1, 1) self.horizontalLayout_4 = QtGui.QHBoxLayout() self.horizontalLayout_4.setObjectName("horizontalLayout_4") self.framesSpin = QtGui.QSpinBox(self.centralwidget) self.framesSpin.setButtonSymbols(QtGui.QAbstractSpinBox.NoButtons) self.framesSpin.setProperty("value", 10) self.framesSpin.setObjectName("framesSpin") self.horizontalLayout_4.addWidget(self.framesSpin) self.widthSpin = QtGui.QSpinBox(self.centralwidget) self.widthSpin.setButtonSymbols(QtGui.QAbstractSpinBox.PlusMinus) self.widthSpin.setMaximum(10000) self.widthSpin.setProperty("value", 512) self.widthSpin.setObjectName("widthSpin") self.horizontalLayout_4.addWidget(self.widthSpin) self.heightSpin = QtGui.QSpinBox(self.centralwidget) self.heightSpin.setButtonSymbols(QtGui.QAbstractSpinBox.NoButtons) self.heightSpin.setMaximum(10000) self.heightSpin.setProperty("value", 512) self.heightSpin.setObjectName("heightSpin") self.horizontalLayout_4.addWidget(self.heightSpin) self.gridLayout_2.addLayout(self.horizontalLayout_4, 2, 1, 1, 2) self.sizeLabel = QtGui.QLabel(self.centralwidget) self.sizeLabel.setText("") self.sizeLabel.setObjectName("sizeLabel") self.gridLayout_2.addWidget(self.sizeLabel, 2, 3, 1, 1) MainWindow.setCentralWidget(self.centralwidget) self.retranslateUi(MainWindow) self.stack.setCurrentIndex(1) QtCore.QMetaObject.connectSlotsByName(MainWindow) def retranslateUi(self, MainWindow): MainWindow.setWindowTitle(QtGui.QApplication.translate("MainWindow", "MainWindow", None, QtGui.QApplication.UnicodeUTF8)) self.downsampleCheck.setText(QtGui.QApplication.translate("MainWindow", "Auto downsample", None, QtGui.QApplication.UnicodeUTF8)) self.scaleCheck.setText(QtGui.QApplication.translate("MainWindow", "Scale Data", None, QtGui.QApplication.UnicodeUTF8)) self.rawRadio.setText(QtGui.QApplication.translate("MainWindow", "RawImageWidget", None, QtGui.QApplication.UnicodeUTF8)) self.gfxRadio.setText(QtGui.QApplication.translate("MainWindow", "GraphicsView + ImageItem", None, QtGui.QApplication.UnicodeUTF8)) self.rawGLRadio.setText(QtGui.QApplication.translate("MainWindow", "RawGLImageWidget", None, QtGui.QApplication.UnicodeUTF8)) self.dtypeCombo.setItemText(0, QtGui.QApplication.translate("MainWindow", "uint8", None, QtGui.QApplication.UnicodeUTF8)) self.dtypeCombo.setItemText(1, QtGui.QApplication.translate("MainWindow", "uint16", None, QtGui.QApplication.UnicodeUTF8)) self.dtypeCombo.setItemText(2, QtGui.QApplication.translate("MainWindow", "float", None, QtGui.QApplication.UnicodeUTF8)) self.label.setText(QtGui.QApplication.translate("MainWindow", "Data type", None, QtGui.QApplication.UnicodeUTF8)) self.rgbLevelsCheck.setText(QtGui.QApplication.translate("MainWindow", "RGB", None, QtGui.QApplication.UnicodeUTF8)) self.label_3.setText(QtGui.QApplication.translate("MainWindow", "<--->", None, QtGui.QApplication.UnicodeUTF8)) self.label_2.setText(QtGui.QApplication.translate("MainWindow", "<--->", None, QtGui.QApplication.UnicodeUTF8)) self.label_4.setText(QtGui.QApplication.translate("MainWindow", "<--->", None, QtGui.QApplication.UnicodeUTF8)) self.lutCheck.setText(QtGui.QApplication.translate("MainWindow", "Use Lookup Table", None, QtGui.QApplication.UnicodeUTF8)) self.alphaCheck.setText(QtGui.QApplication.translate("MainWindow", "alpha", None, QtGui.QApplication.UnicodeUTF8)) self.fpsLabel.setText(QtGui.QApplication.translate("MainWindow", "FPS", None, QtGui.QApplication.UnicodeUTF8)) self.rgbCheck.setText(QtGui.QApplication.translate("MainWindow", "RGB", None, QtGui.QApplication.UnicodeUTF8)) self.label_5.setText(QtGui.QApplication.translate("MainWindow", "Image size", None, QtGui.QApplication.UnicodeUTF8)) from pyqtgraph.widgets.RawImageWidget import RawImageWidget from pyqtgraph import SpinBox, GradientWidget, GraphicsView pyqtgraph-pyqtgraph-0.10.0/examples/ViewBox.py000066400000000000000000000053031300727121400213750ustar00rootroot00000000000000#!/usr/bin/python # -*- coding: utf-8 -*- """ ViewBox is the general-purpose graphical container that allows the user to zoom / pan to inspect any area of a 2D coordinate system. This unimaginative example demonstrates the constrution of a ViewBox-based plot area with axes, very similar to the way PlotItem is built. """ ## Add path to library (just for examples; you do not need this) import initExample ## This example uses a ViewBox to create a PlotWidget-like interface import numpy as np from pyqtgraph.Qt import QtGui, QtCore import pyqtgraph as pg app = QtGui.QApplication([]) mw = QtGui.QMainWindow() mw.setWindowTitle('pyqtgraph example: ViewBox') mw.show() mw.resize(800, 600) gv = pg.GraphicsView() mw.setCentralWidget(gv) l = QtGui.QGraphicsGridLayout() l.setHorizontalSpacing(0) l.setVerticalSpacing(0) vb = pg.ViewBox() p1 = pg.PlotDataItem() vb.addItem(p1) ## Just something to play with inside the ViewBox class movableRect(QtGui.QGraphicsRectItem): def __init__(self, *args): QtGui.QGraphicsRectItem.__init__(self, *args) self.setAcceptHoverEvents(True) def hoverEnterEvent(self, ev): self.savedPen = self.pen() self.setPen(pg.mkPen(255, 255, 255)) ev.ignore() def hoverLeaveEvent(self, ev): self.setPen(self.savedPen) ev.ignore() def mousePressEvent(self, ev): if ev.button() == QtCore.Qt.LeftButton: ev.accept() self.pressDelta = self.mapToParent(ev.pos()) - self.pos() else: ev.ignore() def mouseMoveEvent(self, ev): self.setPos(self.mapToParent(ev.pos()) - self.pressDelta) rect = movableRect(QtCore.QRectF(0, 0, 1, 1)) rect.setPen(pg.mkPen(100, 200, 100)) vb.addItem(rect) l.addItem(vb, 0, 1) gv.centralWidget.setLayout(l) xScale = pg.AxisItem(orientation='bottom', linkView=vb) l.addItem(xScale, 1, 1) yScale = pg.AxisItem(orientation='left', linkView=vb) l.addItem(yScale, 0, 0) xScale.setLabel(text="X Axis", units="s") yScale.setLabel('Y Axis', units='V') def rand(n): data = np.random.random(n) data[int(n*0.1):int(n*0.13)] += .5 data[int(n*0.18)] += 2 data[int(n*0.1):int(n*0.13)] *= 5 data[int(n*0.18)] *= 20 return data, np.arange(n, n+len(data)) / float(n) def updateData(): yd, xd = rand(10000) p1.setData(y=yd, x=xd) yd, xd = rand(10000) updateData() vb.autoRange() t = QtCore.QTimer() t.timeout.connect(updateData) t.start(50) ## Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/ViewBoxFeatures.py000066400000000000000000000046651300727121400231060ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ ViewBox is the general-purpose graphical container that allows the user to zoom / pan to inspect any area of a 2D coordinate system. This example demonstrates many of the features ViewBox provides. """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np x = np.arange(1000, dtype=float) y = np.random.normal(size=1000) y += 5 * np.sin(x/100) win = pg.GraphicsWindow() win.setWindowTitle('pyqtgraph example: ____') win.resize(1000, 800) win.ci.setBorder((50, 50, 100)) sub1 = win.addLayout() sub1.addLabel("Standard mouse interaction:
left-drag to pan, right-drag to zoom.") sub1.nextRow() v1 = sub1.addViewBox() l1 = pg.PlotDataItem(y) v1.addItem(l1) sub2 = win.addLayout() sub2.addLabel("One-button mouse interaction:
left-drag zoom to box, wheel to zoom out.") sub2.nextRow() v2 = sub2.addViewBox() v2.setMouseMode(v2.RectMode) l2 = pg.PlotDataItem(y) v2.addItem(l2) win.nextRow() sub3 = win.addLayout() sub3.addLabel("Locked aspect ratio when zooming.") sub3.nextRow() v3 = sub3.addViewBox() v3.setAspectLocked(1.0) l3 = pg.PlotDataItem(y) v3.addItem(l3) sub4 = win.addLayout() sub4.addLabel("View limits:
prevent panning or zooming past limits.") sub4.nextRow() v4 = sub4.addViewBox() v4.setLimits(xMin=-100, xMax=1100, minXRange=20, maxXRange=500, yMin=-10, yMax=10, minYRange=1, maxYRange=10) l4 = pg.PlotDataItem(y) v4.addItem(l4) win.nextRow() sub5 = win.addLayout() sub5.addLabel("Linked axes: Data in this plot is always X-aligned to
the plot above.") sub5.nextRow() v5 = sub5.addViewBox() v5.setXLink(v3) l5 = pg.PlotDataItem(y) v5.addItem(l5) sub6 = win.addLayout() sub6.addLabel("Disable mouse: Per-axis control over mouse input.
" "Auto-scale-visible: Automatically fit *visible* data within view
" "(try panning left-right).") sub6.nextRow() v6 = sub6.addViewBox() v6.setMouseEnabled(x=True, y=False) v6.enableAutoRange(x=False, y=True) v6.setXRange(300, 450) v6.setAutoVisible(x=False, y=True) l6 = pg.PlotDataItem(y) v6.addItem(l6) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/ViewLimits.py000066400000000000000000000010431300727121400221030ustar00rootroot00000000000000import initExample ## Add path to library (just for examples; you do not need this) from pyqtgraph.Qt import QtGui, QtCore import pyqtgraph as pg import numpy as np plt = pg.plot(np.random.normal(size=100), title="View limit example") plt.centralWidget.vb.setLimits(xMin=-20, xMax=120, minXRange=5, maxXRange=100) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if sys.flags.interactive != 1 or not hasattr(QtCore, 'PYQT_VERSION'): pg.QtGui.QApplication.exec_() pyqtgraph-pyqtgraph-0.10.0/examples/__init__.py000066400000000000000000000000321300727121400215430ustar00rootroot00000000000000from .__main__ import run pyqtgraph-pyqtgraph-0.10.0/examples/__main__.py000066400000000000000000000112661300727121400215370ustar00rootroot00000000000000import sys, os if __name__ == "__main__" and (__package__ is None or __package__==''): parent_dir = os.path.dirname(os.path.dirname(os.path.abspath(__file__))) sys.path.insert(0, parent_dir) import examples __package__ = "examples" import pyqtgraph as pg import subprocess from pyqtgraph.python2_3 import basestring from pyqtgraph.Qt import QtGui, USE_PYSIDE, USE_PYQT5 from .utils import buildFileList, testFile, path, examples if USE_PYSIDE: from .exampleLoaderTemplate_pyside import Ui_Form elif USE_PYQT5: from .exampleLoaderTemplate_pyqt5 import Ui_Form else: from .exampleLoaderTemplate_pyqt import Ui_Form class ExampleLoader(QtGui.QMainWindow): def __init__(self): QtGui.QMainWindow.__init__(self) self.ui = Ui_Form() self.cw = QtGui.QWidget() self.setCentralWidget(self.cw) self.ui.setupUi(self.cw) self.codeBtn = QtGui.QPushButton('Run Edited Code') self.codeLayout = QtGui.QGridLayout() self.ui.codeView.setLayout(self.codeLayout) self.codeLayout.addItem(QtGui.QSpacerItem(100,100,QtGui.QSizePolicy.Expanding,QtGui.QSizePolicy.Expanding), 0, 0) self.codeLayout.addWidget(self.codeBtn, 1, 1) self.codeBtn.hide() global examples self.itemCache = [] self.populateTree(self.ui.exampleTree.invisibleRootItem(), examples) self.ui.exampleTree.expandAll() self.resize(1000,500) self.show() self.ui.splitter.setSizes([250,750]) self.ui.loadBtn.clicked.connect(self.loadFile) self.ui.exampleTree.currentItemChanged.connect(self.showFile) self.ui.exampleTree.itemDoubleClicked.connect(self.loadFile) self.ui.codeView.textChanged.connect(self.codeEdited) self.codeBtn.clicked.connect(self.runEditedCode) def populateTree(self, root, examples): for key, val in examples.items(): item = QtGui.QTreeWidgetItem([key]) self.itemCache.append(item) # PyQt 4.9.6 no longer keeps references to these wrappers, # so we need to make an explicit reference or else the .file # attribute will disappear. if isinstance(val, basestring): item.file = val else: self.populateTree(item, val) root.addChild(item) def currentFile(self): item = self.ui.exampleTree.currentItem() if hasattr(item, 'file'): global path return os.path.join(path, item.file) return None def loadFile(self, edited=False): extra = [] qtLib = str(self.ui.qtLibCombo.currentText()) gfxSys = str(self.ui.graphicsSystemCombo.currentText()) if qtLib != 'default': extra.append(qtLib.lower()) elif gfxSys != 'default': extra.append(gfxSys) if edited: path = os.path.abspath(os.path.dirname(__file__)) proc = subprocess.Popen([sys.executable, '-'] + extra, stdin=subprocess.PIPE, cwd=path) code = str(self.ui.codeView.toPlainText()).encode('UTF-8') proc.stdin.write(code) proc.stdin.close() else: fn = self.currentFile() if fn is None: return if sys.platform.startswith('win'): os.spawnl(os.P_NOWAIT, sys.executable, '"'+sys.executable+'"', '"' + fn + '"', *extra) else: os.spawnl(os.P_NOWAIT, sys.executable, sys.executable, fn, *extra) def showFile(self): fn = self.currentFile() if fn is None: self.ui.codeView.clear() return if os.path.isdir(fn): fn = os.path.join(fn, '__main__.py') text = open(fn).read() self.ui.codeView.setPlainText(text) self.ui.loadedFileLabel.setText(fn) self.codeBtn.hide() def codeEdited(self): self.codeBtn.show() def runEditedCode(self): self.loadFile(edited=True) def run(): app = QtGui.QApplication([]) loader = ExampleLoader() app.exec_() if __name__ == '__main__': args = sys.argv[1:] if '--test' in args: # get rid of orphaned cache files first pg.renamePyc(path) files = buildFileList(examples) if '--pyside' in args: lib = 'PySide' elif '--pyqt' in args or '--pyqt4' in args: lib = 'PyQt4' elif '--pyqt5' in args: lib = 'PyQt5' else: lib = '' exe = sys.executable print("Running tests:", lib, sys.executable) for f in files: testFile(f[0], f[1], exe, lib) else: run() pyqtgraph-pyqtgraph-0.10.0/examples/beeswarm.py000066400000000000000000000021611300727121400216160ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Example beeswarm / bar chart """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np win = pg.plot() win.setWindowTitle('pyqtgraph example: beeswarm') data = np.random.normal(size=(4,20)) data[0] += 5 data[1] += 7 data[2] += 5 data[3] = 10 + data[3] * 2 ## Make bar graph #bar = pg.BarGraphItem(x=range(4), height=data.mean(axis=1), width=0.5, brush=0.4) #win.addItem(bar) ## add scatter plots on top for i in range(4): xvals = pg.pseudoScatter(data[i], spacing=0.4, bidir=True) * 0.2 win.plot(x=xvals+i, y=data[i], pen=None, symbol='o', symbolBrush=pg.intColor(i,6,maxValue=128)) ## Make error bars err = pg.ErrorBarItem(x=np.arange(4), y=data.mean(axis=1), height=data.std(axis=1), beam=0.5, pen={'color':'w', 'width':2}) win.addItem(err) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/contextMenu.py000066400000000000000000000106211300727121400223220ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Demonstrates adding a custom context menu to a GraphicsItem and extending the context menu of a ViewBox. PyQtGraph implements a system that allows each item in a scene to implement its own context menu, and for the menus of its parent items to be automatically displayed as well. """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np win = pg.GraphicsWindow() win.setWindowTitle('pyqtgraph example: context menu') view = win.addViewBox() # add two new actions to the ViewBox context menu: zoom1 = view.menu.addAction('Zoom to box 1') zoom2 = view.menu.addAction('Zoom to box 2') # define callbacks for these actions def zoomTo1(): # note that box1 is defined below view.autoRange(items=[box1]) zoom1.triggered.connect(zoomTo1) def zoomTo2(): # note that box1 is defined below view.autoRange(items=[box2]) zoom2.triggered.connect(zoomTo2) class MenuBox(pg.GraphicsObject): """ This class draws a rectangular area. Right-clicking inside the area will raise a custom context menu which also includes the context menus of its parents. """ def __init__(self, name): self.name = name self.pen = pg.mkPen('r') # menu creation is deferred because it is expensive and often # the user will never see the menu anyway. self.menu = None # note that the use of super() is often avoided because Qt does not # allow to inherit from multiple QObject subclasses. pg.GraphicsObject.__init__(self) # All graphics items must have paint() and boundingRect() defined. def boundingRect(self): return QtCore.QRectF(0, 0, 10, 10) def paint(self, p, *args): p.setPen(self.pen) p.drawRect(self.boundingRect()) # On right-click, raise the context menu def mouseClickEvent(self, ev): if ev.button() == QtCore.Qt.RightButton: if self.raiseContextMenu(ev): ev.accept() def raiseContextMenu(self, ev): menu = self.getContextMenus() # Let the scene add on to the end of our context menu # (this is optional) menu = self.scene().addParentContextMenus(self, menu, ev) pos = ev.screenPos() menu.popup(QtCore.QPoint(pos.x(), pos.y())) return True # This method will be called when this item's _children_ want to raise # a context menu that includes their parents' menus. def getContextMenus(self, event=None): if self.menu is None: self.menu = QtGui.QMenu() self.menu.setTitle(self.name+ " options..") green = QtGui.QAction("Turn green", self.menu) green.triggered.connect(self.setGreen) self.menu.addAction(green) self.menu.green = green blue = QtGui.QAction("Turn blue", self.menu) blue.triggered.connect(self.setBlue) self.menu.addAction(blue) self.menu.green = blue alpha = QtGui.QWidgetAction(self.menu) alphaSlider = QtGui.QSlider() alphaSlider.setOrientation(QtCore.Qt.Horizontal) alphaSlider.setMaximum(255) alphaSlider.setValue(255) alphaSlider.valueChanged.connect(self.setAlpha) alpha.setDefaultWidget(alphaSlider) self.menu.addAction(alpha) self.menu.alpha = alpha self.menu.alphaSlider = alphaSlider return self.menu # Define context menu callbacks def setGreen(self): self.pen = pg.mkPen('g') # inform Qt that this item must be redrawn. self.update() def setBlue(self): self.pen = pg.mkPen('b') self.update() def setAlpha(self, a): self.setOpacity(a/255.) # This box's context menu will include the ViewBox's menu box1 = MenuBox("Menu Box #1") view.addItem(box1) # This box's context menu will include both the ViewBox's menu and box1's menu box2 = MenuBox("Menu Box #2") box2.setParentItem(box1) box2.setPos(5, 5) box2.scale(0.2, 0.2) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/crosshair.py000066400000000000000000000051311300727121400220060ustar00rootroot00000000000000""" Demonstrates some customized mouse interaction by drawing a crosshair that follows the mouse. """ import initExample ## Add path to library (just for examples; you do not need this) import numpy as np import pyqtgraph as pg from pyqtgraph.Qt import QtGui, QtCore from pyqtgraph.Point import Point #generate layout app = QtGui.QApplication([]) win = pg.GraphicsWindow() win.setWindowTitle('pyqtgraph example: crosshair') label = pg.LabelItem(justify='right') win.addItem(label) p1 = win.addPlot(row=1, col=0) p2 = win.addPlot(row=2, col=0) region = pg.LinearRegionItem() region.setZValue(10) # Add the LinearRegionItem to the ViewBox, but tell the ViewBox to exclude this # item when doing auto-range calculations. p2.addItem(region, ignoreBounds=True) #pg.dbg() p1.setAutoVisible(y=True) #create numpy arrays #make the numbers large to show that the xrange shows data from 10000 to all the way 0 data1 = 10000 + 15000 * pg.gaussianFilter(np.random.random(size=10000), 10) + 3000 * np.random.random(size=10000) data2 = 15000 + 15000 * pg.gaussianFilter(np.random.random(size=10000), 10) + 3000 * np.random.random(size=10000) p1.plot(data1, pen="r") p1.plot(data2, pen="g") p2.plot(data1, pen="w") def update(): region.setZValue(10) minX, maxX = region.getRegion() p1.setXRange(minX, maxX, padding=0) region.sigRegionChanged.connect(update) def updateRegion(window, viewRange): rgn = viewRange[0] region.setRegion(rgn) p1.sigRangeChanged.connect(updateRegion) region.setRegion([1000, 2000]) #cross hair vLine = pg.InfiniteLine(angle=90, movable=False) hLine = pg.InfiniteLine(angle=0, movable=False) p1.addItem(vLine, ignoreBounds=True) p1.addItem(hLine, ignoreBounds=True) vb = p1.vb def mouseMoved(evt): pos = evt[0] ## using signal proxy turns original arguments into a tuple if p1.sceneBoundingRect().contains(pos): mousePoint = vb.mapSceneToView(pos) index = int(mousePoint.x()) if index > 0 and index < len(data1): label.setText("x=%0.1f, y1=%0.1f, y2=%0.1f" % (mousePoint.x(), data1[index], data2[index])) vLine.setPos(mousePoint.x()) hLine.setPos(mousePoint.y()) proxy = pg.SignalProxy(p1.scene().sigMouseMoved, rateLimit=60, slot=mouseMoved) #p1.scene().sigMouseMoved.connect(mouseMoved) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/customGraphicsItem.py000066400000000000000000000042731300727121400236310ustar00rootroot00000000000000""" Demonstrate creation of a custom graphic (a candlestick plot) """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph import QtCore, QtGui ## Create a subclass of GraphicsObject. ## The only required methods are paint() and boundingRect() ## (see QGraphicsItem documentation) class CandlestickItem(pg.GraphicsObject): def __init__(self, data): pg.GraphicsObject.__init__(self) self.data = data ## data must have fields: time, open, close, min, max self.generatePicture() def generatePicture(self): ## pre-computing a QPicture object allows paint() to run much more quickly, ## rather than re-drawing the shapes every time. self.picture = QtGui.QPicture() p = QtGui.QPainter(self.picture) p.setPen(pg.mkPen('w')) w = (self.data[1][0] - self.data[0][0]) / 3. for (t, open, close, min, max) in self.data: p.drawLine(QtCore.QPointF(t, min), QtCore.QPointF(t, max)) if open > close: p.setBrush(pg.mkBrush('r')) else: p.setBrush(pg.mkBrush('g')) p.drawRect(QtCore.QRectF(t-w, open, w*2, close-open)) p.end() def paint(self, p, *args): p.drawPicture(0, 0, self.picture) def boundingRect(self): ## boundingRect _must_ indicate the entire area that will be drawn on ## or else we will get artifacts and possibly crashing. ## (in this case, QPicture does all the work of computing the bouning rect for us) return QtCore.QRectF(self.picture.boundingRect()) data = [ ## fields are (time, open, close, min, max). (1., 10, 13, 5, 15), (2., 13, 17, 9, 20), (3., 17, 14, 11, 23), (4., 14, 15, 5, 19), (5., 15, 9, 8, 22), (6., 9, 15, 8, 16), ] item = CandlestickItem(data) plt = pg.plot() plt.addItem(item) plt.setWindowTitle('pyqtgraph example: customGraphicsItem') ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/customPlot.py000066400000000000000000000052701300727121400221660ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ This example demonstrates the creation of a plot with a customized AxisItem and ViewBox. """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np import time class DateAxis(pg.AxisItem): def tickStrings(self, values, scale, spacing): strns = [] rng = max(values)-min(values) #if rng < 120: # return pg.AxisItem.tickStrings(self, values, scale, spacing) if rng < 3600*24: string = '%H:%M:%S' label1 = '%b %d -' label2 = ' %b %d, %Y' elif rng >= 3600*24 and rng < 3600*24*30: string = '%d' label1 = '%b - ' label2 = '%b, %Y' elif rng >= 3600*24*30 and rng < 3600*24*30*24: string = '%b' label1 = '%Y -' label2 = ' %Y' elif rng >=3600*24*30*24: string = '%Y' label1 = '' label2 = '' for x in values: try: strns.append(time.strftime(string, time.localtime(x))) except ValueError: ## Windows can't handle dates before 1970 strns.append('') try: label = time.strftime(label1, time.localtime(min(values)))+time.strftime(label2, time.localtime(max(values))) except ValueError: label = '' #self.setLabel(text=label) return strns class CustomViewBox(pg.ViewBox): def __init__(self, *args, **kwds): pg.ViewBox.__init__(self, *args, **kwds) self.setMouseMode(self.RectMode) ## reimplement right-click to zoom out def mouseClickEvent(self, ev): if ev.button() == QtCore.Qt.RightButton: self.autoRange() def mouseDragEvent(self, ev): if ev.button() == QtCore.Qt.RightButton: ev.ignore() else: pg.ViewBox.mouseDragEvent(self, ev) app = pg.mkQApp() axis = DateAxis(orientation='bottom') vb = CustomViewBox() pw = pg.PlotWidget(viewBox=vb, axisItems={'bottom': axis}, enableMenu=False, title="PlotItem with custom axis and ViewBox
Menu disabled, mouse behavior changed: left-drag to zoom, right-click to reset zoom") dates = np.arange(8) * (3600*24*356) pw.plot(x=dates, y=[1,6,2,4,3,5,6,8], symbol='o') pw.show() pw.setWindowTitle('pyqtgraph example: customPlot') r = pg.PolyLineROI([(0,0), (10, 10)]) pw.addItem(r) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/cx_freeze/000077500000000000000000000000001300727121400214115ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/examples/cx_freeze/plotTest.py000066400000000000000000000012471300727121400236050ustar00rootroot00000000000000import sys from PyQt4 import QtGui import pyqtgraph as pg from pyqtgraph.graphicsItems import TextItem # For packages that require scipy, these may be needed: # from scipy.stats import futil # from scipy.sparse.csgraph import _validation from pyqtgraph import setConfigOption pg.setConfigOption('background','w') pg.setConfigOption('foreground','k') app = QtGui.QApplication(sys.argv) pw = pg.plot(x = [0, 1, 2, 4], y = [4, 5, 9, 6]) pw.showGrid(x=True,y=True) text = pg.TextItem(html='
%s
' % "here",anchor=(0.0, 0.0)) text.setPos(1.0, 5.0) pw.addItem(text) status = app.exec_() sys.exit(status) pyqtgraph-pyqtgraph-0.10.0/examples/cx_freeze/setup.py000066400000000000000000000022261300727121400231250ustar00rootroot00000000000000# Build with `python setup.py build_exe` from cx_Freeze import setup, Executable import shutil from glob import glob # Remove the build folder shutil.rmtree("build", ignore_errors=True) shutil.rmtree("dist", ignore_errors=True) import sys includes = ['PyQt4.QtCore', 'PyQt4.QtGui', 'sip', 'pyqtgraph.graphicsItems', 'numpy', 'atexit'] excludes = ['cvxopt','_gtkagg', '_tkagg', 'bsddb', 'curses', 'email', 'pywin.debugger', 'pywin.debugger.dbgcon', 'pywin.dialogs', 'tcl','tables', 'Tkconstants', 'Tkinter', 'zmq','PySide','pysideuic','scipy','matplotlib'] if sys.version[0] == '2': # causes syntax error on py2 excludes.append('PyQt4.uic.port_v3') base = None if sys.platform == "win32": base = "Win32GUI" build_exe_options = {'excludes': excludes, 'includes':includes, 'include_msvcr':True, 'compressed':True, 'copy_dependent_files':True, 'create_shared_zip':True, 'include_in_shared_zip':True, 'optimize':2} setup(name = "cx_freeze plot test", version = "0.1", description = "cx_freeze plot test", options = {"build_exe": build_exe_options}, executables = [Executable("plotTest.py", base=base)]) pyqtgraph-pyqtgraph-0.10.0/examples/designerExample.py000066400000000000000000000026721300727121400231340ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Simple example of loading UI template created with Qt Designer. This example uses uic.loadUiType to parse and load the ui at runtime. It is also possible to pre-compile the .ui file using pyuic (see VideoSpeedTest and ScatterPlotSpeedTest examples; these .ui files have been compiled with the tools/rebuildUi.py script). """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np import os pg.mkQApp() ## Define main window class from template path = os.path.dirname(os.path.abspath(__file__)) uiFile = os.path.join(path, 'designerExample.ui') WindowTemplate, TemplateBaseClass = pg.Qt.loadUiType(uiFile) class MainWindow(TemplateBaseClass): def __init__(self): TemplateBaseClass.__init__(self) self.setWindowTitle('pyqtgraph example: Qt Designer') # Create the main window self.ui = WindowTemplate() self.ui.setupUi(self) self.ui.plotBtn.clicked.connect(self.plot) self.show() def plot(self): self.ui.plot.plot(np.random.normal(size=100), clear=True) win = MainWindow() ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/designerExample.ui000066400000000000000000000015341300727121400231150ustar00rootroot00000000000000 Form 0 0 400 300 Form Plot! PlotWidget QGraphicsView
pyqtgraph
 pyqtgraph-pyqtgraph-0.10.0/examples/dockarea.py000066400000000000000000000100311300727121400215550ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ This example demonstrates the use of pyqtgraph's dock widget system. The dockarea system allows the design of user interfaces which can be rearranged by the user at runtime. Docks can be moved, resized, stacked, and torn out of the main window. This is similar in principle to the docking system built into Qt, but offers a more deterministic dock placement API (in Qt it is very difficult to programatically generate complex dock arrangements). Additionally, Qt's docks are designed to be used as small panels around the outer edge of a window. Pyqtgraph's docks were created with the notion that the entire window (or any portion of it) would consist of dockable components. """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import pyqtgraph.console import numpy as np from pyqtgraph.dockarea import * app = QtGui.QApplication([]) win = QtGui.QMainWindow() area = DockArea() win.setCentralWidget(area) win.resize(1000,500) win.setWindowTitle('pyqtgraph example: dockarea') ## Create docks, place them into the window one at a time. ## Note that size arguments are only a suggestion; docks will still have to ## fill the entire dock area and obey the limits of their internal widgets. d1 = Dock("Dock1", size=(1, 1)) ## give this dock the minimum possible size d2 = Dock("Dock2 - Console", size=(500,300), closable=True) d3 = Dock("Dock3", size=(500,400)) d4 = Dock("Dock4 (tabbed) - Plot", size=(500,200)) d5 = Dock("Dock5 - Image", size=(500,200)) d6 = Dock("Dock6 (tabbed) - Plot", size=(500,200)) area.addDock(d1, 'left') ## place d1 at left edge of dock area (it will fill the whole space since there are no other docks yet) area.addDock(d2, 'right') ## place d2 at right edge of dock area area.addDock(d3, 'bottom', d1)## place d3 at bottom edge of d1 area.addDock(d4, 'right') ## place d4 at right edge of dock area area.addDock(d5, 'left', d1) ## place d5 at left edge of d1 area.addDock(d6, 'top', d4) ## place d5 at top edge of d4 ## Test ability to move docks programatically after they have been placed area.moveDock(d4, 'top', d2) ## move d4 to top edge of d2 area.moveDock(d6, 'above', d4) ## move d6 to stack on top of d4 area.moveDock(d5, 'top', d2) ## move d5 to top edge of d2 ## Add widgets into each dock ## first dock gets save/restore buttons w1 = pg.LayoutWidget() label = QtGui.QLabel(""" -- DockArea Example -- This window has 6 Dock widgets in it. Each dock can be dragged by its title bar to occupy a different space within the window but note that one dock has its title bar hidden). Additionally, the borders between docks may be dragged to resize. Docks that are dragged on top of one another are stacked in a tabbed layout. Double-click a dock title bar to place it in its own window. """) saveBtn = QtGui.QPushButton('Save dock state') restoreBtn = QtGui.QPushButton('Restore dock state') restoreBtn.setEnabled(False) w1.addWidget(label, row=0, col=0) w1.addWidget(saveBtn, row=1, col=0) w1.addWidget(restoreBtn, row=2, col=0) d1.addWidget(w1) state = None def save(): global state state = area.saveState() restoreBtn.setEnabled(True) def load(): global state area.restoreState(state) saveBtn.clicked.connect(save) restoreBtn.clicked.connect(load) w2 = pg.console.ConsoleWidget() d2.addWidget(w2) ## Hide title bar on dock 3 d3.hideTitleBar() w3 = pg.PlotWidget(title="Plot inside dock with no title bar") w3.plot(np.random.normal(size=100)) d3.addWidget(w3) w4 = pg.PlotWidget(title="Dock 4 plot") w4.plot(np.random.normal(size=100)) d4.addWidget(w4) w5 = pg.ImageView() w5.setImage(np.random.normal(size=(100,100))) d5.addWidget(w5) w6 = pg.PlotWidget(title="Dock 6 plot") w6.plot(np.random.normal(size=100)) d6.addWidget(w6) win.show() ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/exampleLoaderTemplate.ui000066400000000000000000000072241300727121400242610ustar00rootroot00000000000000 Form 0 0 846 552 Form Qt::Horizontal false 1 default native raster opengl default PyQt4 PySide PyQt5 Graphics System: Qt Library: Run Example 75 true Qt::AlignCenter FreeMono pyqtgraph-pyqtgraph-0.10.0/examples/exampleLoaderTemplate_pyqt.py000066400000000000000000000117261300727121400253530ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file 'exampleLoaderTemplate.ui' # # Created: Sat Feb 28 10:30:29 2015 # by: PyQt4 UI code generator 4.10.4 # # WARNING! All changes made in this file will be lost! from PyQt4 import QtCore, QtGui try: _fromUtf8 = QtCore.QString.fromUtf8 except AttributeError: def _fromUtf8(s): return s try: _encoding = QtGui.QApplication.UnicodeUTF8 def _translate(context, text, disambig): return QtGui.QApplication.translate(context, text, disambig, _encoding) except AttributeError: def _translate(context, text, disambig): return QtGui.QApplication.translate(context, text, disambig) class Ui_Form(object): def setupUi(self, Form): Form.setObjectName(_fromUtf8("Form")) Form.resize(846, 552) self.gridLayout_2 = QtGui.QGridLayout(Form) self.gridLayout_2.setObjectName(_fromUtf8("gridLayout_2")) self.splitter = QtGui.QSplitter(Form) self.splitter.setOrientation(QtCore.Qt.Horizontal) self.splitter.setObjectName(_fromUtf8("splitter")) self.widget = QtGui.QWidget(self.splitter) self.widget.setObjectName(_fromUtf8("widget")) self.gridLayout = QtGui.QGridLayout(self.widget) self.gridLayout.setMargin(0) self.gridLayout.setObjectName(_fromUtf8("gridLayout")) self.exampleTree = QtGui.QTreeWidget(self.widget) self.exampleTree.setObjectName(_fromUtf8("exampleTree")) self.exampleTree.headerItem().setText(0, _fromUtf8("1")) self.exampleTree.header().setVisible(False) self.gridLayout.addWidget(self.exampleTree, 0, 0, 1, 2) self.graphicsSystemCombo = QtGui.QComboBox(self.widget) self.graphicsSystemCombo.setObjectName(_fromUtf8("graphicsSystemCombo")) self.graphicsSystemCombo.addItem(_fromUtf8("")) self.graphicsSystemCombo.addItem(_fromUtf8("")) self.graphicsSystemCombo.addItem(_fromUtf8("")) self.graphicsSystemCombo.addItem(_fromUtf8("")) self.gridLayout.addWidget(self.graphicsSystemCombo, 2, 1, 1, 1) self.qtLibCombo = QtGui.QComboBox(self.widget) self.qtLibCombo.setObjectName(_fromUtf8("qtLibCombo")) self.qtLibCombo.addItem(_fromUtf8("")) self.qtLibCombo.addItem(_fromUtf8("")) self.qtLibCombo.addItem(_fromUtf8("")) self.qtLibCombo.addItem(_fromUtf8("")) self.gridLayout.addWidget(self.qtLibCombo, 1, 1, 1, 1) self.label_2 = QtGui.QLabel(self.widget) self.label_2.setObjectName(_fromUtf8("label_2")) self.gridLayout.addWidget(self.label_2, 2, 0, 1, 1) self.label = QtGui.QLabel(self.widget) self.label.setObjectName(_fromUtf8("label")) self.gridLayout.addWidget(self.label, 1, 0, 1, 1) self.loadBtn = QtGui.QPushButton(self.widget) self.loadBtn.setObjectName(_fromUtf8("loadBtn")) self.gridLayout.addWidget(self.loadBtn, 3, 1, 1, 1) self.widget1 = QtGui.QWidget(self.splitter) self.widget1.setObjectName(_fromUtf8("widget1")) self.verticalLayout = QtGui.QVBoxLayout(self.widget1) self.verticalLayout.setMargin(0) self.verticalLayout.setObjectName(_fromUtf8("verticalLayout")) self.loadedFileLabel = QtGui.QLabel(self.widget1) font = QtGui.QFont() font.setBold(True) font.setWeight(75) self.loadedFileLabel.setFont(font) self.loadedFileLabel.setText(_fromUtf8("")) self.loadedFileLabel.setAlignment(QtCore.Qt.AlignCenter) self.loadedFileLabel.setObjectName(_fromUtf8("loadedFileLabel")) self.verticalLayout.addWidget(self.loadedFileLabel) self.codeView = QtGui.QPlainTextEdit(self.widget1) font = QtGui.QFont() font.setFamily(_fromUtf8("FreeMono")) self.codeView.setFont(font) self.codeView.setObjectName(_fromUtf8("codeView")) self.verticalLayout.addWidget(self.codeView) self.gridLayout_2.addWidget(self.splitter, 0, 0, 1, 1) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): Form.setWindowTitle(_translate("Form", "Form", None)) self.graphicsSystemCombo.setItemText(0, _translate("Form", "default", None)) self.graphicsSystemCombo.setItemText(1, _translate("Form", "native", None)) self.graphicsSystemCombo.setItemText(2, _translate("Form", "raster", None)) self.graphicsSystemCombo.setItemText(3, _translate("Form", "opengl", None)) self.qtLibCombo.setItemText(0, _translate("Form", "default", None)) self.qtLibCombo.setItemText(1, _translate("Form", "PyQt4", None)) self.qtLibCombo.setItemText(2, _translate("Form", "PySide", None)) self.qtLibCombo.setItemText(3, _translate("Form", "PyQt5", None)) self.label_2.setText(_translate("Form", "Graphics System:", None)) self.label.setText(_translate("Form", "Qt Library:", None)) self.loadBtn.setText(_translate("Form", "Run Example", None)) pyqtgraph-pyqtgraph-0.10.0/examples/exampleLoaderTemplate_pyqt5.py000066400000000000000000000105461300727121400254370ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file 'exampleLoaderTemplate.ui' # # Created: Sat Feb 28 10:28:50 2015 # by: PyQt5 UI code generator 5.2.1 # # WARNING! All changes made in this file will be lost! from PyQt5 import QtCore, QtGui, QtWidgets class Ui_Form(object): def setupUi(self, Form): Form.setObjectName("Form") Form.resize(846, 552) self.gridLayout_2 = QtWidgets.QGridLayout(Form) self.gridLayout_2.setObjectName("gridLayout_2") self.splitter = QtWidgets.QSplitter(Form) self.splitter.setOrientation(QtCore.Qt.Horizontal) self.splitter.setObjectName("splitter") self.widget = QtWidgets.QWidget(self.splitter) self.widget.setObjectName("widget") self.gridLayout = QtWidgets.QGridLayout(self.widget) self.gridLayout.setContentsMargins(0, 0, 0, 0) self.gridLayout.setObjectName("gridLayout") self.exampleTree = QtWidgets.QTreeWidget(self.widget) self.exampleTree.setObjectName("exampleTree") self.exampleTree.headerItem().setText(0, "1") self.exampleTree.header().setVisible(False) self.gridLayout.addWidget(self.exampleTree, 0, 0, 1, 2) self.graphicsSystemCombo = QtWidgets.QComboBox(self.widget) self.graphicsSystemCombo.setObjectName("graphicsSystemCombo") self.graphicsSystemCombo.addItem("") self.graphicsSystemCombo.addItem("") self.graphicsSystemCombo.addItem("") self.graphicsSystemCombo.addItem("") self.gridLayout.addWidget(self.graphicsSystemCombo, 2, 1, 1, 1) self.qtLibCombo = QtWidgets.QComboBox(self.widget) self.qtLibCombo.setObjectName("qtLibCombo") self.qtLibCombo.addItem("") self.qtLibCombo.addItem("") self.qtLibCombo.addItem("") self.qtLibCombo.addItem("") self.gridLayout.addWidget(self.qtLibCombo, 1, 1, 1, 1) self.label_2 = QtWidgets.QLabel(self.widget) self.label_2.setObjectName("label_2") self.gridLayout.addWidget(self.label_2, 2, 0, 1, 1) self.label = QtWidgets.QLabel(self.widget) self.label.setObjectName("label") self.gridLayout.addWidget(self.label, 1, 0, 1, 1) self.loadBtn = QtWidgets.QPushButton(self.widget) self.loadBtn.setObjectName("loadBtn") self.gridLayout.addWidget(self.loadBtn, 3, 1, 1, 1) self.widget1 = QtWidgets.QWidget(self.splitter) self.widget1.setObjectName("widget1") self.verticalLayout = QtWidgets.QVBoxLayout(self.widget1) self.verticalLayout.setContentsMargins(0, 0, 0, 0) self.verticalLayout.setObjectName("verticalLayout") self.loadedFileLabel = QtWidgets.QLabel(self.widget1) font = QtGui.QFont() font.setBold(True) font.setWeight(75) self.loadedFileLabel.setFont(font) self.loadedFileLabel.setText("") self.loadedFileLabel.setAlignment(QtCore.Qt.AlignCenter) self.loadedFileLabel.setObjectName("loadedFileLabel") self.verticalLayout.addWidget(self.loadedFileLabel) self.codeView = QtWidgets.QPlainTextEdit(self.widget1) font = QtGui.QFont() font.setFamily("FreeMono") self.codeView.setFont(font) self.codeView.setObjectName("codeView") self.verticalLayout.addWidget(self.codeView) self.gridLayout_2.addWidget(self.splitter, 0, 0, 1, 1) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): _translate = QtCore.QCoreApplication.translate Form.setWindowTitle(_translate("Form", "Form")) self.graphicsSystemCombo.setItemText(0, _translate("Form", "default")) self.graphicsSystemCombo.setItemText(1, _translate("Form", "native")) self.graphicsSystemCombo.setItemText(2, _translate("Form", "raster")) self.graphicsSystemCombo.setItemText(3, _translate("Form", "opengl")) self.qtLibCombo.setItemText(0, _translate("Form", "default")) self.qtLibCombo.setItemText(1, _translate("Form", "PyQt4")) self.qtLibCombo.setItemText(2, _translate("Form", "PySide")) self.qtLibCombo.setItemText(3, _translate("Form", "PyQt5")) self.label_2.setText(_translate("Form", "Graphics System:")) self.label.setText(_translate("Form", "Qt Library:")) self.loadBtn.setText(_translate("Form", "Run Example")) pyqtgraph-pyqtgraph-0.10.0/examples/exampleLoaderTemplate_pyside.py000066400000000000000000000116311300727121400256460ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file 'exampleLoaderTemplate.ui' # # Created: Sat Feb 28 10:31:57 2015 # by: pyside-uic 0.2.15 running on PySide 1.2.1 # # WARNING! All changes made in this file will be lost! from PySide import QtCore, QtGui class Ui_Form(object): def setupUi(self, Form): Form.setObjectName("Form") Form.resize(846, 552) self.gridLayout_2 = QtGui.QGridLayout(Form) self.gridLayout_2.setObjectName("gridLayout_2") self.splitter = QtGui.QSplitter(Form) self.splitter.setOrientation(QtCore.Qt.Horizontal) self.splitter.setObjectName("splitter") self.widget = QtGui.QWidget(self.splitter) self.widget.setObjectName("widget") self.gridLayout = QtGui.QGridLayout(self.widget) self.gridLayout.setContentsMargins(0, 0, 0, 0) self.gridLayout.setObjectName("gridLayout") self.exampleTree = QtGui.QTreeWidget(self.widget) self.exampleTree.setObjectName("exampleTree") self.exampleTree.headerItem().setText(0, "1") self.exampleTree.header().setVisible(False) self.gridLayout.addWidget(self.exampleTree, 0, 0, 1, 2) self.graphicsSystemCombo = QtGui.QComboBox(self.widget) self.graphicsSystemCombo.setObjectName("graphicsSystemCombo") self.graphicsSystemCombo.addItem("") self.graphicsSystemCombo.addItem("") self.graphicsSystemCombo.addItem("") self.graphicsSystemCombo.addItem("") self.gridLayout.addWidget(self.graphicsSystemCombo, 2, 1, 1, 1) self.qtLibCombo = QtGui.QComboBox(self.widget) self.qtLibCombo.setObjectName("qtLibCombo") self.qtLibCombo.addItem("") self.qtLibCombo.addItem("") self.qtLibCombo.addItem("") self.qtLibCombo.addItem("") self.gridLayout.addWidget(self.qtLibCombo, 1, 1, 1, 1) self.label_2 = QtGui.QLabel(self.widget) self.label_2.setObjectName("label_2") self.gridLayout.addWidget(self.label_2, 2, 0, 1, 1) self.label = QtGui.QLabel(self.widget) self.label.setObjectName("label") self.gridLayout.addWidget(self.label, 1, 0, 1, 1) self.loadBtn = QtGui.QPushButton(self.widget) self.loadBtn.setObjectName("loadBtn") self.gridLayout.addWidget(self.loadBtn, 3, 1, 1, 1) self.widget1 = QtGui.QWidget(self.splitter) self.widget1.setObjectName("widget1") self.verticalLayout = QtGui.QVBoxLayout(self.widget1) self.verticalLayout.setContentsMargins(0, 0, 0, 0) self.verticalLayout.setObjectName("verticalLayout") self.loadedFileLabel = QtGui.QLabel(self.widget1) font = QtGui.QFont() font.setWeight(75) font.setBold(True) self.loadedFileLabel.setFont(font) self.loadedFileLabel.setText("") self.loadedFileLabel.setAlignment(QtCore.Qt.AlignCenter) self.loadedFileLabel.setObjectName("loadedFileLabel") self.verticalLayout.addWidget(self.loadedFileLabel) self.codeView = QtGui.QPlainTextEdit(self.widget1) font = QtGui.QFont() font.setFamily("FreeMono") self.codeView.setFont(font) self.codeView.setObjectName("codeView") self.verticalLayout.addWidget(self.codeView) self.gridLayout_2.addWidget(self.splitter, 0, 0, 1, 1) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): Form.setWindowTitle(QtGui.QApplication.translate("Form", "Form", None, QtGui.QApplication.UnicodeUTF8)) self.graphicsSystemCombo.setItemText(0, QtGui.QApplication.translate("Form", "default", None, QtGui.QApplication.UnicodeUTF8)) self.graphicsSystemCombo.setItemText(1, QtGui.QApplication.translate("Form", "native", None, QtGui.QApplication.UnicodeUTF8)) self.graphicsSystemCombo.setItemText(2, QtGui.QApplication.translate("Form", "raster", None, QtGui.QApplication.UnicodeUTF8)) self.graphicsSystemCombo.setItemText(3, QtGui.QApplication.translate("Form", "opengl", None, QtGui.QApplication.UnicodeUTF8)) self.qtLibCombo.setItemText(0, QtGui.QApplication.translate("Form", "default", None, QtGui.QApplication.UnicodeUTF8)) self.qtLibCombo.setItemText(1, QtGui.QApplication.translate("Form", "PyQt4", None, QtGui.QApplication.UnicodeUTF8)) self.qtLibCombo.setItemText(2, QtGui.QApplication.translate("Form", "PySide", None, QtGui.QApplication.UnicodeUTF8)) self.qtLibCombo.setItemText(3, QtGui.QApplication.translate("Form", "PyQt5", None, QtGui.QApplication.UnicodeUTF8)) self.label_2.setText(QtGui.QApplication.translate("Form", "Graphics System:", None, QtGui.QApplication.UnicodeUTF8)) self.label.setText(QtGui.QApplication.translate("Form", "Qt Library:", None, QtGui.QApplication.UnicodeUTF8)) self.loadBtn.setText(QtGui.QApplication.translate("Form", "Run Example", None, QtGui.QApplication.UnicodeUTF8)) pyqtgraph-pyqtgraph-0.10.0/examples/hdf5.py000066400000000000000000000121041300727121400206350ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ In this example we create a subclass of PlotCurveItem for displaying a very large data set from an HDF5 file that does not fit in memory. The basic approach is to override PlotCurveItem.viewRangeChanged such that it reads only the portion of the HDF5 data that is necessary to display the visible portion of the data. This is further downsampled to reduce the number of samples being displayed. A more clever implementation of this class would employ some kind of caching to avoid re-reading the entire visible waveform at every update. """ import initExample ## Add path to library (just for examples; you do not need this) import sys, os import numpy as np import h5py import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui pg.mkQApp() plt = pg.plot() plt.setWindowTitle('pyqtgraph example: HDF5 big data') plt.enableAutoRange(False, False) plt.setXRange(0, 500) class HDF5Plot(pg.PlotCurveItem): def __init__(self, *args, **kwds): self.hdf5 = None self.limit = 10000 # maximum number of samples to be plotted pg.PlotCurveItem.__init__(self, *args, **kwds) def setHDF5(self, data): self.hdf5 = data self.updateHDF5Plot() def viewRangeChanged(self): self.updateHDF5Plot() def updateHDF5Plot(self): if self.hdf5 is None: self.setData([]) return vb = self.getViewBox() if vb is None: return # no ViewBox yet # Determine what data range must be read from HDF5 xrange = vb.viewRange()[0] start = max(0,int(xrange[0])-1) stop = min(len(self.hdf5), int(xrange[1]+2)) # Decide by how much we should downsample ds = int((stop-start) / self.limit) + 1 if ds == 1: # Small enough to display with no intervention. visible = self.hdf5[start:stop] scale = 1 else: # Here convert data into a down-sampled array suitable for visualizing. # Must do this piecewise to limit memory usage. samples = 1 + ((stop-start) // ds) visible = np.zeros(samples*2, dtype=self.hdf5.dtype) sourcePtr = start targetPtr = 0 # read data in chunks of ~1M samples chunkSize = (1000000//ds) * ds while sourcePtr < stop-1: chunk = self.hdf5[sourcePtr:min(stop,sourcePtr+chunkSize)] sourcePtr += len(chunk) # reshape chunk to be integral multiple of ds chunk = chunk[:(len(chunk)//ds) * ds].reshape(len(chunk)//ds, ds) # compute max and min chunkMax = chunk.max(axis=1) chunkMin = chunk.min(axis=1) # interleave min and max into plot data to preserve envelope shape visible[targetPtr:targetPtr+chunk.shape[0]*2:2] = chunkMin visible[1+targetPtr:1+targetPtr+chunk.shape[0]*2:2] = chunkMax targetPtr += chunk.shape[0]*2 visible = visible[:targetPtr] scale = ds * 0.5 self.setData(visible) # update the plot self.setPos(start, 0) # shift to match starting index self.resetTransform() self.scale(scale, 1) # scale to match downsampling def createFile(finalSize=2000000000): """Create a large HDF5 data file for testing. Data consists of 1M random samples tiled through the end of the array. """ chunk = np.random.normal(size=1000000).astype(np.float32) f = h5py.File('test.hdf5', 'w') f.create_dataset('data', data=chunk, chunks=True, maxshape=(None,)) data = f['data'] nChunks = finalSize // (chunk.size * chunk.itemsize) with pg.ProgressDialog("Generating test.hdf5...", 0, nChunks) as dlg: for i in range(nChunks): newshape = [data.shape[0] + chunk.shape[0]] data.resize(newshape) data[-chunk.shape[0]:] = chunk dlg += 1 if dlg.wasCanceled(): f.close() os.remove('test.hdf5') sys.exit() dlg += 1 f.close() if len(sys.argv) > 1: fileName = sys.argv[1] else: fileName = 'test.hdf5' if not os.path.isfile(fileName): size, ok = QtGui.QInputDialog.getDouble(None, "Create HDF5 Dataset?", "This demo requires a large HDF5 array. To generate a file, enter the array size (in GB) and press OK.", 2.0) if not ok: sys.exit(0) else: createFile(int(size*1e9)) #raise Exception("No suitable HDF5 file found. Use createFile() to generate an example file.") f = h5py.File(fileName, 'r') curve = HDF5Plot() curve.setHDF5(f['data']) plt.addItem(curve) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/histogram.py000066400000000000000000000024051300727121400220070ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ In this example we draw two different kinds of histogram. """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np win = pg.GraphicsWindow() win.resize(800,350) win.setWindowTitle('pyqtgraph example: Histogram') plt1 = win.addPlot() plt2 = win.addPlot() ## make interesting distribution of values vals = np.hstack([np.random.normal(size=500), np.random.normal(size=260, loc=4)]) ## compute standard histogram y,x = np.histogram(vals, bins=np.linspace(-3, 8, 40)) ## Using stepMode=True causes the plot to draw two lines for each sample. ## notice that len(x) == len(y)+1 plt1.plot(x, y, stepMode=True, fillLevel=0, brush=(0,0,255,150)) ## Now draw all points as a nicely-spaced scatter plot y = pg.pseudoScatter(vals, spacing=0.15) #plt2.plot(vals, y, pen=None, symbol='o', symbolSize=5) plt2.plot(vals, y, pen=None, symbol='o', symbolSize=5, symbolPen=(255,255,255,200), symbolBrush=(0,0,255,150)) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/imageAnalysis.py000066400000000000000000000051641300727121400226050ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Demonstrates common image analysis tools. Many of the features demonstrated here are already provided by the ImageView widget, but here we present a lower-level approach that provides finer control over the user interface. """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np # Interpret image data as row-major instead of col-major pg.setConfigOptions(imageAxisOrder='row-major') pg.mkQApp() win = pg.GraphicsLayoutWidget() win.setWindowTitle('pyqtgraph example: Image Analysis') # A plot area (ViewBox + axes) for displaying the image p1 = win.addPlot() # Item for displaying image data img = pg.ImageItem() p1.addItem(img) # Custom ROI for selecting an image region roi = pg.ROI([-8, 14], [6, 5]) roi.addScaleHandle([0.5, 1], [0.5, 0.5]) roi.addScaleHandle([0, 0.5], [0.5, 0.5]) p1.addItem(roi) roi.setZValue(10) # make sure ROI is drawn above image # Isocurve drawing iso = pg.IsocurveItem(level=0.8, pen='g') iso.setParentItem(img) iso.setZValue(5) # Contrast/color control hist = pg.HistogramLUTItem() hist.setImageItem(img) win.addItem(hist) # Draggable line for setting isocurve level isoLine = pg.InfiniteLine(angle=0, movable=True, pen='g') hist.vb.addItem(isoLine) hist.vb.setMouseEnabled(y=False) # makes user interaction a little easier isoLine.setValue(0.8) isoLine.setZValue(1000) # bring iso line above contrast controls # Another plot area for displaying ROI data win.nextRow() p2 = win.addPlot(colspan=2) p2.setMaximumHeight(250) win.resize(800, 800) win.show() # Generate image data data = np.random.normal(size=(200, 100)) data[20:80, 20:80] += 2. data = pg.gaussianFilter(data, (3, 3)) data += np.random.normal(size=(200, 100)) * 0.1 img.setImage(data) hist.setLevels(data.min(), data.max()) # build isocurves from smoothed data iso.setData(pg.gaussianFilter(data, (2, 2))) # set position and scale of image img.scale(0.2, 0.2) img.translate(-50, 0) # zoom to fit imageo p1.autoRange() # Callbacks for handling user interaction def updatePlot(): global img, roi, data, p2 selected = roi.getArrayRegion(data, img) p2.plot(selected.mean(axis=0), clear=True) roi.sigRegionChanged.connect(updatePlot) updatePlot() def updateIsocurve(): global isoLine, iso iso.setLevel(isoLine.value()) isoLine.sigDragged.connect(updateIsocurve) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/infiniteline_performance.py000066400000000000000000000025101300727121400250450ustar00rootroot00000000000000#!/usr/bin/python import initExample ## Add path to library (just for examples; you do not need this) from pyqtgraph.Qt import QtGui, QtCore import numpy as np import pyqtgraph as pg from pyqtgraph.ptime import time app = QtGui.QApplication([]) p = pg.plot() p.setWindowTitle('pyqtgraph performance: InfiniteLine') p.setRange(QtCore.QRectF(0, -10, 5000, 20)) p.setLabel('bottom', 'Index', units='B') curve = p.plot() # Add a large number of horizontal InfiniteLine to plot for i in range(100): line = pg.InfiniteLine(pos=np.random.randint(5000), movable=True) p.addItem(line) data = np.random.normal(size=(50, 5000)) ptr = 0 lastTime = time() fps = None def update(): global curve, data, ptr, p, lastTime, fps curve.setData(data[ptr % 10]) ptr += 1 now = time() dt = now - lastTime lastTime = now if fps is None: fps = 1.0/dt else: s = np.clip(dt*3., 0, 1) fps = fps * (1-s) + (1.0/dt) * s p.setTitle('%0.2f fps' % fps) app.processEvents() # force complete redraw for every plot timer = QtCore.QTimer() timer.timeout.connect(update) timer.start(0) # Start Qt event loop unless running in interactive mode. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_()pyqtgraph-pyqtgraph-0.10.0/examples/initExample.py000066400000000000000000000030621300727121400222710ustar00rootroot00000000000000## make this version of pyqtgraph importable before any others ## we do this to make sure that, when running examples, the correct library ## version is imported (if there are multiple versions present). import sys, os if not hasattr(sys, 'frozen'): if __file__ == '': path = os.getcwd() else: path = os.path.abspath(os.path.join(os.path.dirname(__file__), '..')) path.rstrip(os.path.sep) if 'pyqtgraph' in os.listdir(path): sys.path.insert(0, path) ## examples adjacent to pyqtgraph (as in source tree) else: for p in sys.path: if len(p) < 3: continue if path.startswith(p): ## If the example is already in an importable location, promote that location sys.path.remove(p) sys.path.insert(0, p) ## should force example to use PySide instead of PyQt if 'pyside' in sys.argv: from PySide import QtGui elif 'pyqt' in sys.argv: from PyQt4 import QtGui elif 'pyqt5' in sys.argv: from PyQt5 import QtGui else: from pyqtgraph.Qt import QtGui import pyqtgraph as pg ## Force use of a specific graphics system use_gs = 'default' for gs in ['raster', 'native', 'opengl']: if gs in sys.argv: use_gs = gs QtGui.QApplication.setGraphicsSystem(gs) break print("Using %s (%s graphics system)" % (pg.Qt.QT_LIB, use_gs)) ## Enable fault handling to give more helpful error messages on crash. ## Only available in python 3.3+ try: import faulthandler faulthandler.enable() except ImportError: passpyqtgraph-pyqtgraph-0.10.0/examples/isocurve.py000066400000000000000000000031651300727121400216550ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Tests use of IsoCurve item displayed with image """ import initExample ## Add path to library (just for examples; you do not need this) from pyqtgraph.Qt import QtGui, QtCore import numpy as np import pyqtgraph as pg app = QtGui.QApplication([]) ## make pretty looping data frames = 200 data = np.random.normal(size=(frames,30,30), loc=0, scale=100) data = np.concatenate([data, data], axis=0) data = pg.gaussianFilter(data, (10, 10, 10))[frames/2:frames + frames/2] data[:, 15:16, 15:17] += 1 win = pg.GraphicsWindow() win.setWindowTitle('pyqtgraph example: Isocurve') vb = win.addViewBox() img = pg.ImageItem(data[0]) vb.addItem(img) vb.setAspectLocked() ## generate empty curves curves = [] levels = np.linspace(data.min(), data.max(), 10) for i in range(len(levels)): v = levels[i] ## generate isocurve with automatic color selection c = pg.IsocurveItem(level=v, pen=(i, len(levels)*1.5)) c.setParentItem(img) ## make sure isocurve is always correctly displayed over image c.setZValue(10) curves.append(c) ## animate! ptr = 0 imgLevels = (data.min(), data.max() * 2) def update(): global data, curves, img, ptr, imgLevels ptr = (ptr + 1) % data.shape[0] data[ptr] img.setImage(data[ptr], levels=imgLevels) for c in curves: c.setData(data[ptr]) timer = QtCore.QTimer() timer.timeout.connect(update) timer.start(50) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/linkedViews.py000066400000000000000000000030571300727121400223020ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ This example demonstrates the ability to link the axes of views together Views can be linked manually using the context menu, but only if they are given names. """ import initExample ## Add path to library (just for examples; you do not need this) from pyqtgraph.Qt import QtGui, QtCore import numpy as np import pyqtgraph as pg #QtGui.QApplication.setGraphicsSystem('raster') app = QtGui.QApplication([]) #mw = QtGui.QMainWindow() #mw.resize(800,800) x = np.linspace(-50, 50, 1000) y = np.sin(x) / x win = pg.GraphicsWindow(title="pyqtgraph example: Linked Views") win.resize(800,600) win.addLabel("Linked Views", colspan=2) win.nextRow() p1 = win.addPlot(x=x, y=y, name="Plot1", title="Plot1") p2 = win.addPlot(x=x, y=y, name="Plot2", title="Plot2: Y linked with Plot1") p2.setLabel('bottom', "Label to test offset") p2.setYLink('Plot1') ## test linking by name ## create plots 3 and 4 out of order p4 = win.addPlot(x=x, y=y, name="Plot4", title="Plot4: X -> Plot3 (deferred), Y -> Plot1", row=2, col=1) p4.setXLink('Plot3') ## Plot3 has not been created yet, but this should still work anyway. p4.setYLink(p1) p3 = win.addPlot(x=x, y=y, name="Plot3", title="Plot3: X linked with Plot1", row=2, col=0) p3.setXLink(p1) p3.setLabel('left', "Label to test offset") #QtGui.QApplication.processEvents() ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/logAxis.py000066400000000000000000000017711300727121400214250ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Test programmatically setting log transformation modes. """ import initExample ## Add path to library (just for examples; you do not need this) import numpy as np from pyqtgraph.Qt import QtGui, QtCore import pyqtgraph as pg app = QtGui.QApplication([]) w = pg.GraphicsWindow() w.setWindowTitle('pyqtgraph example: logAxis') p1 = w.addPlot(0,0, title="X Semilog") p2 = w.addPlot(1,0, title="Y Semilog") p3 = w.addPlot(2,0, title="XY Log") p1.showGrid(True, True) p2.showGrid(True, True) p3.showGrid(True, True) p1.setLogMode(True, False) p2.setLogMode(False, True) p3.setLogMode(True, True) w.show() y = np.random.normal(size=1000) x = np.linspace(0, 1, 1000) p1.plot(x, y) p2.plot(x, y) p3.plot(x, y) #p.getAxis('bottom').setLogMode(True) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/multiplePlotSpeedTest.py000066400000000000000000000052731300727121400243330ustar00rootroot00000000000000# -*- coding: utf-8 -*- import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np app = pg.mkQApp() plt = pg.PlotWidget() app.processEvents() ## Putting this at the beginning or end does not have much effect plt.show() ## The auto-range is recomputed after each item is added, ## so disabling it before plotting helps plt.enableAutoRange(False, False) def plot(): start = pg.ptime.time() n = 15 pts = 100 x = np.linspace(0, 0.8, pts) y = np.random.random(size=pts)*0.8 for i in range(n): for j in range(n): ## calling PlotWidget.plot() generates a PlotDataItem, which ## has a bit more overhead than PlotCurveItem, which is all ## we need here. This overhead adds up quickly and makes a big ## difference in speed. #plt.plot(x=x+i, y=y+j) plt.addItem(pg.PlotCurveItem(x=x+i, y=y+j)) #path = pg.arrayToQPath(x+i, y+j) #item = QtGui.QGraphicsPathItem(path) #item.setPen(pg.mkPen('w')) #plt.addItem(item) dt = pg.ptime.time() - start print("Create plots took: %0.3fms" % (dt*1000)) ## Plot and clear 5 times, printing the time it took for i in range(5): plt.clear() plot() app.processEvents() plt.autoRange() def fastPlot(): ## Different approach: generate a single item with all data points. ## This runs about 20x faster. start = pg.ptime.time() n = 15 pts = 100 x = np.linspace(0, 0.8, pts) y = np.random.random(size=pts)*0.8 xdata = np.empty((n, n, pts)) xdata[:] = x.reshape(1,1,pts) + np.arange(n).reshape(n,1,1) ydata = np.empty((n, n, pts)) ydata[:] = y.reshape(1,1,pts) + np.arange(n).reshape(1,n,1) conn = np.ones((n*n,pts)) conn[:,-1] = False # make sure plots are disconnected path = pg.arrayToQPath(xdata.flatten(), ydata.flatten(), conn.flatten()) item = QtGui.QGraphicsPathItem(path) item.setPen(pg.mkPen('w')) plt.addItem(item) dt = pg.ptime.time() - start print("Create plots took: %0.3fms" % (dt*1000)) ## Plot and clear 5 times, printing the time it took if hasattr(pg, 'arrayToQPath'): for i in range(5): plt.clear() fastPlot() app.processEvents() else: print("Skipping fast tests--arrayToQPath function is missing.") plt.autoRange() ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/multiprocess.py000066400000000000000000000027731300727121400225530ustar00rootroot00000000000000# -*- coding: utf-8 -*- import initExample ## Add path to library (just for examples; you do not need this) import numpy as np import pyqtgraph.multiprocess as mp import pyqtgraph as pg import time print("\n=================\nStart Process") proc = mp.Process() import os print("parent:", os.getpid(), "child:", proc.proc.pid) print("started") rnp = proc._import('numpy') arr = rnp.array([1,2,3,4]) print(repr(arr)) print(str(arr)) print("return value:", repr(arr.mean(_returnType='value'))) print( "return proxy:", repr(arr.mean(_returnType='proxy'))) print( "return auto: ", repr(arr.mean(_returnType='auto'))) proc.join() print( "process finished") print( "\n=================\nStart ForkedProcess") proc = mp.ForkedProcess() rnp = proc._import('numpy') arr = rnp.array([1,2,3,4]) print( repr(arr)) print( str(arr)) print( repr(arr.mean())) proc.join() print( "process finished") import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui app = pg.QtGui.QApplication([]) print( "\n=================\nStart QtProcess") import sys if (sys.flags.interactive != 1): print( " (not interactive; remote process will exit immediately.)") proc = mp.QtProcess() d1 = proc.transfer(np.random.normal(size=1000)) d2 = proc.transfer(np.random.normal(size=1000)) rpg = proc._import('pyqtgraph') plt = rpg.plot(d1+d2) ## Start Qt event loop unless running in interactive mode or using pyside. #import sys #if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): #QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/optics/000077500000000000000000000000001300727121400207405ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/examples/optics/__init__.py000066400000000000000000000000261300727121400230470ustar00rootroot00000000000000from .pyoptic import *pyqtgraph-pyqtgraph-0.10.0/examples/optics/pyoptic.py000066400000000000000000000442461300727121400230130ustar00rootroot00000000000000# -*- coding: utf-8 -*- import pyqtgraph as pg from pyqtgraph.Qt import QtGui, QtCore import numpy as np import csv, gzip, os from pyqtgraph import Point class GlassDB: """ Database of dispersion coefficients for Schott glasses + Corning 7980 """ def __init__(self, fileName='schott_glasses.csv'): path = os.path.dirname(__file__) fh = gzip.open(os.path.join(path, 'schott_glasses.csv.gz'), 'rb') r = csv.reader(map(str, fh.readlines())) lines = [x for x in r] self.data = {} header = lines[0] for l in lines[1:]: info = {} for i in range(1, len(l)): info[header[i]] = l[i] self.data[l[0]] = info self.data['Corning7980'] = { ## Thorlabs UV fused silica--not in schott catalog. 'B1': 0.68374049400, 'B2': 0.42032361300, 'B3': 0.58502748000, 'C1': 0.00460352869, 'C2': 0.01339688560, 'C3': 64.49327320000, 'TAUI25/250': 0.95, ## transmission data is fabricated, but close. 'TAUI25/1400': 0.98, } for k in self.data: self.data[k]['ior_cache'] = {} def ior(self, glass, wl): """ Return the index of refraction for *glass* at wavelength *wl*. The *glass* argument must be a key in self.data. """ info = self.data[glass] cache = info['ior_cache'] if wl not in cache: B = list(map(float, [info['B1'], info['B2'], info['B3']])) C = list(map(float, [info['C1'], info['C2'], info['C3']])) w2 = (wl/1000.)**2 n = np.sqrt(1.0 + (B[0]*w2 / (w2-C[0])) + (B[1]*w2 / (w2-C[1])) + (B[2]*w2 / (w2-C[2]))) cache[wl] = n return cache[wl] def transmissionCurve(self, glass): data = self.data[glass] keys = [int(x[7:]) for x in data.keys() if 'TAUI25' in x] keys.sort() curve = np.empty((2,len(keys))) for i in range(len(keys)): curve[0][i] = keys[i] key = 'TAUI25/%d' % keys[i] val = data[key] if val == '': val = 0 else: val = float(val) curve[1][i] = val return curve GLASSDB = GlassDB() def wlPen(wl): """Return a pen representing the given wavelength""" l1 = 400 l2 = 700 hue = np.clip(((l2-l1) - (wl-l1)) * 0.8 / (l2-l1), 0, 0.8) val = 1.0 if wl > 700: val = 1.0 * (((700-wl)/700.) + 1) elif wl < 400: val = wl * 1.0/400. #print hue, val color = pg.hsvColor(hue, 1.0, val) pen = pg.mkPen(color) return pen class ParamObj(object): # Just a helper for tracking parameters and responding to changes def __init__(self): self.__params = {} def __setitem__(self, item, val): self.setParam(item, val) def setParam(self, param, val): self.setParams(**{param:val}) def setParams(self, **params): """Set parameters for this optic. This is a good function to override for subclasses.""" self.__params.update(params) self.paramStateChanged() def paramStateChanged(self): pass def __getitem__(self, item): # bug in pyside 1.2.2 causes getitem to be called inside QGraphicsObject.parentItem: return self.getParam(item) # PySide bug: https://bugreports.qt.io/browse/PYSIDE-441 def getParam(self, param): return self.__params[param] class Optic(pg.GraphicsObject, ParamObj): sigStateChanged = QtCore.Signal() def __init__(self, gitem, **params): ParamObj.__init__(self) pg.GraphicsObject.__init__(self) #, [0,0], [1,1]) self.gitem = gitem self.surfaces = gitem.surfaces gitem.setParentItem(self) self.roi = pg.ROI([0,0], [1,1]) self.roi.addRotateHandle([1, 1], [0.5, 0.5]) self.roi.setParentItem(self) defaults = { 'pos': Point(0,0), 'angle': 0, } defaults.update(params) self._ior_cache = {} self.roi.sigRegionChanged.connect(self.roiChanged) self.setParams(**defaults) def updateTransform(self): self.resetTransform() self.setPos(0, 0) self.translate(Point(self['pos'])) self.rotate(self['angle']) def setParam(self, param, val): ParamObj.setParam(self, param, val) def paramStateChanged(self): """Some parameters of the optic have changed.""" # Move graphics item self.gitem.setPos(Point(self['pos'])) self.gitem.resetTransform() self.gitem.rotate(self['angle']) # Move ROI to match try: self.roi.sigRegionChanged.disconnect(self.roiChanged) br = self.gitem.boundingRect() o = self.gitem.mapToParent(br.topLeft()) self.roi.setAngle(self['angle']) self.roi.setPos(o) self.roi.setSize([br.width(), br.height()]) finally: self.roi.sigRegionChanged.connect(self.roiChanged) self.sigStateChanged.emit() def roiChanged(self, *args): pos = self.roi.pos() # rotate gitem temporarily so we can decide where it will need to move self.gitem.resetTransform() self.gitem.rotate(self.roi.angle()) br = self.gitem.boundingRect() o1 = self.gitem.mapToParent(br.topLeft()) self.setParams(angle=self.roi.angle(), pos=pos + (self.gitem.pos() - o1)) def boundingRect(self): return QtCore.QRectF() def paint(self, p, *args): pass def ior(self, wavelength): return GLASSDB.ior(self['glass'], wavelength) class Lens(Optic): def __init__(self, **params): defaults = { 'dia': 25.4, ## diameter of lens 'r1': 50., ## positive means convex, use 0 for planar 'r2': 0, ## negative means convex 'd': 4.0, 'glass': 'N-BK7', 'reflect': False, } defaults.update(params) d = defaults.pop('d') defaults['x1'] = -d/2. defaults['x2'] = d/2. gitem = CircularSolid(brush=(100, 100, 130, 100), **defaults) Optic.__init__(self, gitem, **defaults) def propagateRay(self, ray): """Refract, reflect, absorb, and/or scatter ray. This function may create and return new rays""" """ NOTE:: We can probably use this to compute refractions faster: (from GLSL 120 docs) For the incident vector I and surface normal N, and the ratio of indices of refraction eta, return the refraction vector. The result is computed by k = 1.0 - eta * eta * (1.0 - dot(N, I) * dot(N, I)) if (k < 0.0) return genType(0.0) else return eta * I - (eta * dot(N, I) + sqrt(k)) * N The input parameters for the incident vector I and the surface normal N must already be normalized to get the desired results. eta == ratio of IORs For reflection: For the incident vector I and surface orientation N, returns the reflection direction: I – 2 ∗ dot(N, I) ∗ N N must already be normalized in order to achieve the desired result. """ iors = [self.ior(ray['wl']), 1.0] for i in [0,1]: surface = self.surfaces[i] ior = iors[i] p1, ai = surface.intersectRay(ray) #print "surface intersection:", p1, ai*180/3.14159 #trans = self.sceneTransform().inverted()[0] * surface.sceneTransform() #p1 = trans.map(p1) if p1 is None: ray.setEnd(None) break p1 = surface.mapToItem(ray, p1) #print "adjusted position:", p1 #ior = self.ior(ray['wl']) rd = ray['dir'] a1 = np.arctan2(rd[1], rd[0]) ar = a1 - ai + np.arcsin((np.sin(ai) * ray['ior'] / ior)) #print [x for x in [a1, ai, (np.sin(ai) * ray['ior'] / ior), ar]] #print ai, np.sin(ai), ray['ior'], ior ray.setEnd(p1) dp = Point(np.cos(ar), np.sin(ar)) #p2 = p1+dp #p1p = self.mapToScene(p1) #p2p = self.mapToScene(p2) #dpp = Point(p2p-p1p) ray = Ray(parent=ray, ior=ior, dir=dp) return [ray] class Mirror(Optic): def __init__(self, **params): defaults = { 'r1': 0, 'r2': 0, 'd': 0.01, } defaults.update(params) d = defaults.pop('d') defaults['x1'] = -d/2. defaults['x2'] = d/2. gitem = CircularSolid(brush=(100,100,100,255), **defaults) Optic.__init__(self, gitem, **defaults) def propagateRay(self, ray): """Refract, reflect, absorb, and/or scatter ray. This function may create and return new rays""" surface = self.surfaces[0] p1, ai = surface.intersectRay(ray) if p1 is not None: p1 = surface.mapToItem(ray, p1) rd = ray['dir'] a1 = np.arctan2(rd[1], rd[0]) ar = a1 + np.pi - 2*ai ray.setEnd(p1) dp = Point(np.cos(ar), np.sin(ar)) ray = Ray(parent=ray, dir=dp) else: ray.setEnd(None) return [ray] class CircularSolid(pg.GraphicsObject, ParamObj): """GraphicsObject with two circular or flat surfaces.""" def __init__(self, pen=None, brush=None, **opts): """ Arguments for each surface are: x1,x2 - position of center of _physical surface_ r1,r2 - radius of curvature d1,d2 - diameter of optic """ defaults = dict(x1=-2, r1=100, d1=25.4, x2=2, r2=100, d2=25.4) defaults.update(opts) ParamObj.__init__(self) self.surfaces = [CircleSurface(defaults['r1'], defaults['d1']), CircleSurface(-defaults['r2'], defaults['d2'])] pg.GraphicsObject.__init__(self) for s in self.surfaces: s.setParentItem(self) if pen is None: self.pen = pg.mkPen((220,220,255,200), width=1, cosmetic=True) else: self.pen = pg.mkPen(pen) if brush is None: self.brush = pg.mkBrush((230, 230, 255, 30)) else: self.brush = pg.mkBrush(brush) self.setParams(**defaults) def paramStateChanged(self): self.updateSurfaces() def updateSurfaces(self): self.surfaces[0].setParams(self['r1'], self['d1']) self.surfaces[1].setParams(-self['r2'], self['d2']) self.surfaces[0].setPos(self['x1'], 0) self.surfaces[1].setPos(self['x2'], 0) self.path = QtGui.QPainterPath() self.path.connectPath(self.surfaces[0].path.translated(self.surfaces[0].pos())) self.path.connectPath(self.surfaces[1].path.translated(self.surfaces[1].pos()).toReversed()) self.path.closeSubpath() def boundingRect(self): return self.path.boundingRect() def shape(self): return self.path def paint(self, p, *args): p.setRenderHints(p.renderHints() | p.Antialiasing) p.setPen(self.pen) p.fillPath(self.path, self.brush) p.drawPath(self.path) class CircleSurface(pg.GraphicsObject): def __init__(self, radius=None, diameter=None): """center of physical surface is at 0,0 radius is the radius of the surface. If radius is None, the surface is flat. diameter is of the optic's edge.""" pg.GraphicsObject.__init__(self) self.r = radius self.d = diameter self.mkPath() def setParams(self, r, d): self.r = r self.d = d self.mkPath() def mkPath(self): self.prepareGeometryChange() r = self.r d = self.d h2 = d/2. self.path = QtGui.QPainterPath() if r == 0: ## flat surface self.path.moveTo(0, h2) self.path.lineTo(0, -h2) else: ## half-height of surface can't be larger than radius h2 = min(h2, abs(r)) #dx = abs(r) - (abs(r)**2 - abs(h2)**2)**0.5 #p.moveTo(-d*w/2.+ d*dx, d*h2) arc = QtCore.QRectF(0, -r, r*2, r*2) #self.surfaces.append((arc.center(), r, h2)) a1 = np.arcsin(h2/r) * 180. / np.pi a2 = -2*a1 a1 += 180. self.path.arcMoveTo(arc, a1) self.path.arcTo(arc, a1, a2) #if d == -1: #p1 = QtGui.QPainterPath() #p1.addRect(arc) #self.paths.append(p1) self.h2 = h2 def boundingRect(self): return self.path.boundingRect() def paint(self, p, *args): return ## usually we let the optic draw. #p.setPen(pg.mkPen('r')) #p.drawPath(self.path) def intersectRay(self, ray): ## return the point of intersection and the angle of incidence #print "intersect ray" h = self.h2 r = self.r p, dir = ray.currentState(relativeTo=self) # position and angle of ray in local coords. #print " ray: ", p, dir p = p - Point(r, 0) ## move position so center of circle is at 0,0 #print " adj: ", p, r if r == 0: #print " flat" if dir[0] == 0: y = 0 else: y = p[1] - p[0] * dir[1]/dir[0] if abs(y) > h: return None, None else: return (Point(0, y), np.arctan2(dir[1], dir[0])) else: #print " curve" ## find intersection of circle and line (quadratic formula) dx = dir[0] dy = dir[1] dr = (dx**2 + dy**2) ** 0.5 D = p[0] * (p[1]+dy) - (p[0]+dx) * p[1] idr2 = 1.0 / dr**2 disc = r**2 * dr**2 - D**2 if disc < 0: return None, None disc2 = disc**0.5 if dy < 0: sgn = -1 else: sgn = 1 br = self.path.boundingRect() x1 = (D*dy + sgn*dx*disc2) * idr2 y1 = (-D*dx + abs(dy)*disc2) * idr2 if br.contains(x1+r, y1): pt = Point(x1, y1) else: x2 = (D*dy - sgn*dx*disc2) * idr2 y2 = (-D*dx - abs(dy)*disc2) * idr2 pt = Point(x2, y2) if not br.contains(x2+r, y2): return None, None raise Exception("No intersection!") norm = np.arctan2(pt[1], pt[0]) if r < 0: norm += np.pi #print " norm:", norm*180/3.1415 dp = p - pt #print " dp:", dp ang = np.arctan2(dp[1], dp[0]) #print " ang:", ang*180/3.1415 #print " ai:", (ang-norm)*180/3.1415 #print " intersection:", pt return pt + Point(r, 0), ang-norm class Ray(pg.GraphicsObject, ParamObj): """Represents a single straight segment of a ray""" sigStateChanged = QtCore.Signal() def __init__(self, **params): ParamObj.__init__(self) defaults = { 'ior': 1.0, 'wl': 500, 'end': None, 'dir': Point(1,0), } self.params = {} pg.GraphicsObject.__init__(self) self.children = [] parent = params.get('parent', None) if parent is not None: defaults['start'] = parent['end'] defaults['wl'] = parent['wl'] self['ior'] = parent['ior'] self['dir'] = parent['dir'] parent.addChild(self) defaults.update(params) defaults['dir'] = Point(defaults['dir']) self.setParams(**defaults) self.mkPath() def clearChildren(self): for c in self.children: c.clearChildren() c.setParentItem(None) self.scene().removeItem(c) self.children = [] def paramStateChanged(self): pass def addChild(self, ch): self.children.append(ch) ch.setParentItem(self) def currentState(self, relativeTo=None): pos = self['start'] dir = self['dir'] if relativeTo is None: return pos, dir else: trans = self.itemTransform(relativeTo)[0] p1 = trans.map(pos) p2 = trans.map(pos + dir) return Point(p1), Point(p2-p1) def setEnd(self, end): self['end'] = end self.mkPath() def boundingRect(self): return self.path.boundingRect() def paint(self, p, *args): #p.setPen(pg.mkPen((255,0,0, 150))) p.setRenderHints(p.renderHints() | p.Antialiasing) p.setCompositionMode(p.CompositionMode_Plus) p.setPen(wlPen(self['wl'])) p.drawPath(self.path) def mkPath(self): self.prepareGeometryChange() self.path = QtGui.QPainterPath() self.path.moveTo(self['start']) if self['end'] is not None: self.path.lineTo(self['end']) else: self.path.lineTo(self['start']+500*self['dir']) def trace(rays, optics): if len(optics) < 1 or len(rays) < 1: return for r in rays: r.clearChildren() o = optics[0] r2 = o.propagateRay(r) trace(r2, optics[1:]) class Tracer(QtCore.QObject): """ Simple ray tracer. Initialize with a list of rays and optics; calling trace() will cause rays to be extended by propagating them through each optic in sequence. 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timer.timeout.connect(update) timer.start(40) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/parallelize.py000066400000000000000000000041061300727121400223160ustar00rootroot00000000000000# -*- coding: utf-8 -*- import initExample ## Add path to library (just for examples; you do not need this) import time import numpy as np import pyqtgraph.multiprocess as mp import pyqtgraph as pg from pyqtgraph.python2_3 import xrange print( "\n=================\nParallelize") ## Do a simple task: ## for x in range(N): ## sum([x*i for i in range(M)]) ## ## We'll do this three times ## - once without Parallelize ## - once with Parallelize, but forced to use a single worker ## - once with Parallelize automatically determining how many workers to use ## tasks = range(10) results = [None] * len(tasks) results2 = results[:] results3 = results[:] size = 2000000 pg.mkQApp() ### Purely serial processing start = time.time() with pg.ProgressDialog('processing serially..', maximum=len(tasks)) as dlg: for i, x in enumerate(tasks): tot = 0 for j in xrange(size): tot += j * x results[i] = tot dlg += 1 if dlg.wasCanceled(): raise Exception('processing canceled') print( "Serial time: %0.2f" % (time.time() - start)) ### Use parallelize, but force a single worker ### (this simulates the behavior seen on windows, which lacks os.fork) start = time.time() with mp.Parallelize(enumerate(tasks), results=results2, workers=1, progressDialog='processing serially (using Parallelizer)..') as tasker: for i, x in tasker: tot = 0 for j in xrange(size): tot += j * x tasker.results[i] = tot print( "\nParallel time, 1 worker: %0.2f" % (time.time() - start)) print( "Results match serial: %s" % str(results2 == results)) ### Use parallelize with multiple workers start = time.time() with mp.Parallelize(enumerate(tasks), results=results3, progressDialog='processing in parallel..') as tasker: for i, x in tasker: tot = 0 for j in xrange(size): tot += j * x tasker.results[i] = tot print( "\nParallel time, %d workers: %0.2f" % (mp.Parallelize.suggestedWorkerCount(), time.time() - start)) print( "Results match serial: %s" % str(results3 == results)) pyqtgraph-pyqtgraph-0.10.0/examples/parametertree.py000066400000000000000000000155611300727121400226610ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ This example demonstrates the use of pyqtgraph's parametertree system. This provides a simple way to generate user interfaces that control sets of parameters. The example demonstrates a variety of different parameter types (int, float, list, etc.) as well as some customized parameter types """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui app = QtGui.QApplication([]) import pyqtgraph.parametertree.parameterTypes as pTypes from pyqtgraph.parametertree import Parameter, ParameterTree, ParameterItem, registerParameterType ## test subclassing parameters ## This parameter automatically generates two child parameters which are always reciprocals of each other class ComplexParameter(pTypes.GroupParameter): def __init__(self, **opts): opts['type'] = 'bool' opts['value'] = True pTypes.GroupParameter.__init__(self, **opts) self.addChild({'name': 'A = 1/B', 'type': 'float', 'value': 7, 'suffix': 'Hz', 'siPrefix': True}) self.addChild({'name': 'B = 1/A', 'type': 'float', 'value': 1/7., 'suffix': 's', 'siPrefix': True}) self.a = self.param('A = 1/B') self.b = self.param('B = 1/A') self.a.sigValueChanged.connect(self.aChanged) self.b.sigValueChanged.connect(self.bChanged) def aChanged(self): self.b.setValue(1.0 / self.a.value(), blockSignal=self.bChanged) def bChanged(self): self.a.setValue(1.0 / self.b.value(), blockSignal=self.aChanged) ## test add/remove ## this group includes a menu allowing the user to add new parameters into its child list class ScalableGroup(pTypes.GroupParameter): def __init__(self, **opts): opts['type'] = 'group' opts['addText'] = "Add" opts['addList'] = ['str', 'float', 'int'] pTypes.GroupParameter.__init__(self, **opts) def addNew(self, typ): val = { 'str': '', 'float': 0.0, 'int': 0 }[typ] self.addChild(dict(name="ScalableParam %d" % (len(self.childs)+1), type=typ, value=val, removable=True, renamable=True)) params = [ {'name': 'Basic parameter data types', 'type': 'group', 'children': [ {'name': 'Integer', 'type': 'int', 'value': 10}, {'name': 'Float', 'type': 'float', 'value': 10.5, 'step': 0.1}, {'name': 'String', 'type': 'str', 'value': "hi"}, {'name': 'List', 'type': 'list', 'values': [1,2,3], 'value': 2}, {'name': 'Named List', 'type': 'list', 'values': {"one": 1, "two": "twosies", "three": [3,3,3]}, 'value': 2}, {'name': 'Boolean', 'type': 'bool', 'value': True, 'tip': "This is a checkbox"}, {'name': 'Color', 'type': 'color', 'value': "FF0", 'tip': "This is a color button"}, {'name': 'Gradient', 'type': 'colormap'}, {'name': 'Subgroup', 'type': 'group', 'children': [ {'name': 'Sub-param 1', 'type': 'int', 'value': 10}, {'name': 'Sub-param 2', 'type': 'float', 'value': 1.2e6}, ]}, {'name': 'Text Parameter', 'type': 'text', 'value': 'Some text...'}, {'name': 'Action Parameter', 'type': 'action'}, ]}, {'name': 'Numerical Parameter Options', 'type': 'group', 'children': [ {'name': 'Units + SI prefix', 'type': 'float', 'value': 1.2e-6, 'step': 1e-6, 'siPrefix': True, 'suffix': 'V'}, {'name': 'Limits (min=7;max=15)', 'type': 'int', 'value': 11, 'limits': (7, 15), 'default': -6}, {'name': 'DEC stepping', 'type': 'float', 'value': 1.2e6, 'dec': True, 'step': 1, 'siPrefix': True, 'suffix': 'Hz'}, ]}, {'name': 'Save/Restore functionality', 'type': 'group', 'children': [ {'name': 'Save State', 'type': 'action'}, {'name': 'Restore State', 'type': 'action', 'children': [ {'name': 'Add missing items', 'type': 'bool', 'value': True}, {'name': 'Remove extra items', 'type': 'bool', 'value': True}, ]}, ]}, {'name': 'Extra Parameter Options', 'type': 'group', 'children': [ {'name': 'Read-only', 'type': 'float', 'value': 1.2e6, 'siPrefix': True, 'suffix': 'Hz', 'readonly': True}, {'name': 'Renamable', 'type': 'float', 'value': 1.2e6, 'siPrefix': True, 'suffix': 'Hz', 'renamable': True}, {'name': 'Removable', 'type': 'float', 'value': 1.2e6, 'siPrefix': True, 'suffix': 'Hz', 'removable': True}, ]}, ComplexParameter(name='Custom parameter group (reciprocal values)'), ScalableGroup(name="Expandable Parameter Group", children=[ {'name': 'ScalableParam 1', 'type': 'str', 'value': "default param 1"}, {'name': 'ScalableParam 2', 'type': 'str', 'value': "default param 2"}, ]), ] ## Create tree of Parameter objects p = Parameter.create(name='params', type='group', children=params) ## If anything changes in the tree, print a message def change(param, changes): print("tree changes:") for param, change, data in changes: path = p.childPath(param) if path is not None: childName = '.'.join(path) else: childName = param.name() print(' parameter: %s'% childName) print(' change: %s'% change) print(' data: %s'% str(data)) print(' ----------') p.sigTreeStateChanged.connect(change) def valueChanging(param, value): print("Value changing (not finalized): %s %s" % (param, value)) # Too lazy for recursion: for child in p.children(): child.sigValueChanging.connect(valueChanging) for ch2 in child.children(): ch2.sigValueChanging.connect(valueChanging) def save(): global state state = p.saveState() def restore(): global state add = p['Save/Restore functionality', 'Restore State', 'Add missing items'] rem = p['Save/Restore functionality', 'Restore State', 'Remove extra items'] p.restoreState(state, addChildren=add, removeChildren=rem) p.param('Save/Restore functionality', 'Save State').sigActivated.connect(save) p.param('Save/Restore functionality', 'Restore State').sigActivated.connect(restore) ## Create two ParameterTree widgets, both accessing the same data t = ParameterTree() t.setParameters(p, showTop=False) t.setWindowTitle('pyqtgraph example: Parameter Tree') t2 = ParameterTree() t2.setParameters(p, showTop=False) win = QtGui.QWidget() layout = QtGui.QGridLayout() win.setLayout(layout) layout.addWidget(QtGui.QLabel("These are two views of the same data. They should always display the same values."), 0, 0, 1, 2) layout.addWidget(t, 1, 0, 1, 1) layout.addWidget(t2, 1, 1, 1, 1) win.show() win.resize(800,800) ## test save/restore s = p.saveState() p.restoreState(s) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/py2exe/000077500000000000000000000000001300727121400206535ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/examples/py2exe/plotTest.py000066400000000000000000000012471300727121400230470ustar00rootroot00000000000000import sys from PyQt4 import QtGui import pyqtgraph as pg from pyqtgraph.graphicsItems import TextItem # For packages that require scipy, these may be needed: # from scipy.stats import futil # from scipy.sparse.csgraph import _validation from pyqtgraph import setConfigOption pg.setConfigOption('background','w') pg.setConfigOption('foreground','k') app = QtGui.QApplication(sys.argv) pw = pg.plot(x = [0, 1, 2, 4], y = [4, 5, 9, 6]) pw.showGrid(x=True,y=True) text = pg.TextItem(html='
%s
' % "here",anchor=(0.0, 0.0)) text.setPos(1.0, 5.0) pw.addItem(text) status = app.exec_() sys.exit(status) pyqtgraph-pyqtgraph-0.10.0/examples/py2exe/setup.py000066400000000000000000000021531300727121400223660ustar00rootroot00000000000000from distutils.core import setup import shutil from glob import glob # Remove the build folder shutil.rmtree("build", ignore_errors=True) shutil.rmtree("dist", ignore_errors=True) import py2exe import sys includes = ['PyQt4', 'PyQt4.QtGui', 'PyQt4.QtSvg', 'sip', 'pyqtgraph.graphicsItems'] excludes = ['_gtkagg', '_tkagg', 'bsddb', 'curses', 'email', 'pywin.debugger', 'pywin.debugger.dbgcon', 'pywin.dialogs', 'tcl', 'Tkconstants', 'Tkinter', 'zmq'] if sys.version[0] == '2': # causes syntax error on py2 excludes.append('PyQt4.uic.port_v3') packages = [] dll_excludes = ['libgdk-win32-2.0-0.dll', 'libgobject-2.0-0.dll', 'tcl84.dll', 'tk84.dll', 'MSVCP90.dll'] icon_resources = [] bitmap_resources = [] other_resources = [] data_files = [] setup( data_files=data_files, console=['plotTest.py'] , options={"py2exe": {"excludes": excludes, "includes": includes, "dll_excludes": dll_excludes, "optimize": 0, "compressed": 2, "bundle_files": 1}}, zipfile=None, ) pyqtgraph-pyqtgraph-0.10.0/examples/relativity/000077500000000000000000000000001300727121400216335ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/examples/relativity/__init__.py000066400000000000000000000000321300727121400237370ustar00rootroot00000000000000from .relativity import * pyqtgraph-pyqtgraph-0.10.0/examples/relativity/presets/000077500000000000000000000000001300727121400233205ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/examples/relativity/presets/Grid Expansion.cfg000066400000000000000000000422711300727121400266210ustar00rootroot00000000000000name: 'params' strictNaming: False default: None renamable: False enabled: True value: None visible: True readonly: False removable: False type: 'group' children: Load Preset..: name: 'Load Preset..' limits: ['', 'Twin Paradox (grid)', 'Twin Paradox'] strictNaming: False default: None renamable: False enabled: True value: 'Twin Paradox (grid)' visible: True readonly: False values: [] removable: False type: 'list' children: Duration: name: 'Duration' limits: [0.1, None] strictNaming: False default: 10.0 renamable: False enabled: True readonly: False value: 20.0 visible: True step: 0.1 removable: False type: 'float' children: Reference Frame: name: 'Reference Frame' limits: ['Grid00', 'Grid01', 'Grid02', 'Grid03', 'Grid04'] strictNaming: False default: None renamable: False enabled: True value: 'Grid02' visible: True readonly: False values: [] removable: False type: 'list' children: Animate: name: 'Animate' strictNaming: False default: True renamable: False enabled: True value: True visible: True readonly: False removable: False type: 'bool' children: Animation Speed: name: 'Animation Speed' limits: [0.0001, None] strictNaming: False default: 1.0 renamable: False enabled: True readonly: False value: 1.0 visible: True step: 0.1 removable: False dec: True type: 'float' children: Recalculate Worldlines: name: 'Recalculate Worldlines' strictNaming: False default: None renamable: False enabled: True value: None visible: True readonly: False removable: False type: 'action' children: Save: name: 'Save' strictNaming: False default: None renamable: False enabled: True value: None visible: True readonly: False removable: False type: 'action' children: Load: name: 'Load' strictNaming: False default: None renamable: False enabled: True value: None visible: True readonly: False removable: False type: 'action' children: Objects: name: 'Objects' strictNaming: False default: None renamable: False addText: 'Add New..' enabled: True value: None visible: True readonly: False removable: False type: None children: Grid: name: 'Grid' strictNaming: False default: None renamable: True enabled: True value: None visible: True readonly: False removable: True type: 'Grid' autoIncrementName: True children: Number of Clocks: name: 'Number of Clocks' limits: [1, None] strictNaming: False default: 5 renamable: False enabled: True value: 5 visible: True readonly: False removable: False type: 'int' children: Spacing: name: 'Spacing' strictNaming: False default: 1.0 renamable: False enabled: True readonly: False value: 1.0 visible: True step: 0.1 removable: False type: 'float' children: ClockTemplate: name: 'ClockTemplate' strictNaming: False default: None renamable: True enabled: True value: None visible: True readonly: False removable: True type: 'Clock' autoIncrementName: True children: Initial Position: name: 'Initial Position' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: -2.0 visible: True step: 0.1 removable: False type: 'float' children: Acceleration: name: 'Acceleration' strictNaming: False default: None renamable: False addText: 'Add Command..' enabled: True value: None visible: True readonly: False removable: False type: 'AccelerationGroup' children: Command: name: 'Command' strictNaming: False default: None renamable: True enabled: True value: None visible: True readonly: False removable: True type: None autoIncrementName: True children: Proper Time: name: 'Proper Time' strictNaming: False default: 0.0 renamable: False enabled: True value: 1.0 visible: True readonly: False removable: False type: 'float' children: Acceleration: name: 'Acceleration' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: 0.5 visible: True step: 0.1 removable: False type: 'float' children: Command2: name: 'Command2' strictNaming: False default: None renamable: True enabled: True value: None visible: True readonly: False removable: True type: None autoIncrementName: True children: Proper Time: name: 'Proper Time' strictNaming: False default: 2.0 renamable: False enabled: True value: 3.0 visible: True readonly: False removable: False type: 'float' children: Acceleration: name: 'Acceleration' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: 0.0 visible: True step: 0.1 removable: False type: 'float' children: Command3: name: 'Command3' strictNaming: False default: None renamable: True enabled: True value: None visible: True readonly: False removable: True type: None autoIncrementName: True children: Proper Time: name: 'Proper Time' strictNaming: False default: 4.0 renamable: False enabled: True value: 11.0 visible: True readonly: False removable: False type: 'float' children: Acceleration: name: 'Acceleration' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: -0.5 visible: True step: 0.1 removable: False type: 'float' children: Command4: name: 'Command4' strictNaming: False default: None renamable: True enabled: True value: None visible: True readonly: False removable: True type: None autoIncrementName: True children: Proper Time: name: 'Proper Time' strictNaming: False default: 8.0 renamable: False enabled: True value: 13.0 visible: True readonly: False removable: False type: 'float' children: Acceleration: name: 'Acceleration' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: 0.0 visible: True step: 0.1 removable: False type: 'float' children: Rest Mass: name: 'Rest Mass' limits: [1e-09, None] strictNaming: False default: 1.0 renamable: False enabled: True readonly: False value: 1.0 visible: True step: 0.1 removable: False type: 'float' children: Color: name: 'Color' strictNaming: False default: (100, 100, 150) renamable: False enabled: True value: (100, 100, 150, 255) visible: True readonly: False removable: False type: 'color' children: Size: name: 'Size' strictNaming: False default: 0.5 renamable: False enabled: True value: 0.5 visible: True readonly: False removable: False type: 'float' children: Vertical Position: name: 'Vertical Position' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: 0.0 visible: True step: 0.1 removable: False type: 'float' children: addList: ['Clock', 'Grid'] pyqtgraph-pyqtgraph-0.10.0/examples/relativity/presets/Twin Paradox (grid).cfg000066400000000000000000000650731300727121400273430ustar00rootroot00000000000000name: 'params' strictNaming: False default: None renamable: False enabled: True value: None visible: True readonly: False removable: False type: 'group' children: Load Preset..: name: 'Load Preset..' limits: ['', 'Twin Paradox (grid)', 'Twin Paradox'] strictNaming: False default: None renamable: False enabled: True value: 'Twin Paradox (grid)' visible: True readonly: False values: [] removable: False type: 'list' children: Duration: name: 'Duration' limits: [0.1, None] strictNaming: False default: 10.0 renamable: False enabled: True readonly: False value: 27.0 visible: True step: 0.1 removable: False type: 'float' children: Reference Frame: name: 'Reference Frame' limits: ['Grid00', 'Grid01', 'Grid02', 'Grid03', 'Grid04', 'Grid05', 'Grid06', 'Grid07', 'Grid08', 'Grid09', 'Grid10', 'Alice', 'Bob'] strictNaming: False default: None renamable: False enabled: True value: 'Alice' visible: True readonly: False values: [] removable: False type: 'list' children: Animate: name: 'Animate' strictNaming: False default: True renamable: False enabled: True value: True visible: True readonly: False removable: False type: 'bool' children: Animation Speed: name: 'Animation Speed' limits: [0.0001, None] strictNaming: False default: 1.0 renamable: False enabled: True readonly: False value: 1.0 visible: True step: 0.1 removable: False dec: True type: 'float' children: Recalculate Worldlines: name: 'Recalculate Worldlines' strictNaming: False default: None renamable: False enabled: True value: None visible: True readonly: False removable: False type: 'action' children: Save: name: 'Save' strictNaming: False default: None renamable: False enabled: True value: None visible: True readonly: False removable: False type: 'action' children: Load: name: 'Load' strictNaming: False default: None renamable: False enabled: True value: None visible: True readonly: False removable: False type: 'action' children: Objects: name: 'Objects' strictNaming: False default: None renamable: False addText: 'Add New..' enabled: True value: None visible: True readonly: False removable: False type: None children: Grid: name: 'Grid' strictNaming: False default: None renamable: True enabled: True value: None visible: True readonly: False removable: True type: 'Grid' autoIncrementName: True children: Number of Clocks: name: 'Number of Clocks' limits: [1, None] strictNaming: False default: 5 renamable: False enabled: True value: 11 visible: True readonly: False removable: False type: 'int' children: Spacing: name: 'Spacing' strictNaming: False default: 1.0 renamable: False enabled: True readonly: False value: 2.0 visible: True step: 0.1 removable: False type: 'float' children: ClockTemplate: name: 'ClockTemplate' strictNaming: False default: None renamable: True enabled: True value: None visible: True readonly: False removable: True type: 'Clock' autoIncrementName: True children: Initial Position: name: 'Initial Position' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: -10.0 visible: True step: 0.1 removable: False type: 'float' children: Acceleration: name: 'Acceleration' strictNaming: False default: None renamable: False addText: 'Add Command..' enabled: True value: None visible: True readonly: False removable: False type: 'AccelerationGroup' children: Rest Mass: name: 'Rest Mass' limits: [1e-09, None] strictNaming: False default: 1.0 renamable: False enabled: True readonly: False value: 1.0 visible: True step: 0.1 removable: False type: 'float' children: Color: name: 'Color' strictNaming: False default: (100, 100, 150) renamable: False enabled: True value: (77, 77, 77, 255) visible: True readonly: False removable: False type: 'color' children: Size: name: 'Size' strictNaming: False default: 0.5 renamable: False enabled: True value: 1.0 visible: True readonly: False removable: False type: 'float' children: Vertical Position: name: 'Vertical Position' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: -2.0 visible: True step: 0.1 removable: False type: 'float' children: Alice: name: 'Alice' strictNaming: False default: None renamable: True enabled: True value: None visible: True readonly: False removable: True type: 'Clock' autoIncrementName: True children: Initial Position: name: 'Initial Position' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: 0.0 visible: True step: 0.1 removable: False type: 'float' children: Acceleration: name: 'Acceleration' strictNaming: False default: None renamable: False addText: 'Add Command..' enabled: True value: None visible: True readonly: False removable: False type: 'AccelerationGroup' children: Command: name: 'Command' strictNaming: False default: None renamable: True enabled: True value: None visible: True readonly: False removable: True type: None autoIncrementName: True children: Proper Time: name: 'Proper Time' strictNaming: False default: 0.0 renamable: False enabled: True value: 1.0 visible: True readonly: False removable: False type: 'float' children: Acceleration: name: 'Acceleration' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: 0.5 visible: True step: 0.1 removable: False type: 'float' children: Command2: name: 'Command2' strictNaming: False default: None renamable: True enabled: True value: None visible: True readonly: False removable: True type: None autoIncrementName: True children: Proper Time: name: 'Proper Time' strictNaming: False default: 2.0 renamable: False enabled: True value: 3.0 visible: True readonly: False removable: False type: 'float' children: Acceleration: name: 'Acceleration' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: 0.0 visible: True step: 0.1 removable: False type: 'float' children: Command3: name: 'Command3' strictNaming: False default: None renamable: True enabled: True value: None visible: True readonly: False removable: True type: None autoIncrementName: True children: Proper Time: name: 'Proper Time' strictNaming: False default: 3.0 renamable: False enabled: True value: 8.0 visible: True readonly: False removable: False type: 'float' children: Acceleration: name: 'Acceleration' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: -0.5 visible: True step: 0.1 removable: False type: 'float' children: Command4: name: 'Command4' strictNaming: False default: None renamable: True enabled: True value: None visible: True readonly: False removable: True type: None autoIncrementName: True children: Proper Time: name: 'Proper Time' strictNaming: False default: 4.0 renamable: False enabled: True value: 12.0 visible: True readonly: False removable: False type: 'float' children: Acceleration: name: 'Acceleration' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: 0.0 visible: True step: 0.1 removable: False type: 'float' children: Command5: name: 'Command5' strictNaming: False default: None renamable: True enabled: True value: None visible: True readonly: False removable: True type: None autoIncrementName: True children: Proper Time: name: 'Proper Time' strictNaming: False default: 6.0 renamable: False enabled: True value: 17.0 visible: True readonly: False removable: False type: 'float' children: Acceleration: name: 'Acceleration' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: 0.5 visible: True step: 0.1 removable: False type: 'float' children: Command6: name: 'Command6' strictNaming: False default: None renamable: True enabled: True value: None visible: True readonly: False removable: True type: None autoIncrementName: True children: Proper Time: name: 'Proper Time' strictNaming: False default: 7.0 renamable: False enabled: True value: 19.0 visible: True readonly: False removable: False type: 'float' children: Acceleration: name: 'Acceleration' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: 0.0 visible: True step: 0.1 removable: False type: 'float' children: Rest Mass: name: 'Rest Mass' limits: [1e-09, None] strictNaming: False default: 1.0 renamable: False enabled: True readonly: False value: 1.0 visible: True step: 0.1 removable: False type: 'float' children: Color: name: 'Color' strictNaming: False default: (100, 100, 150) renamable: False enabled: True value: (82, 123, 44, 255) visible: True readonly: False removable: False type: 'color' children: Size: name: 'Size' strictNaming: False default: 0.5 renamable: False enabled: True value: 1.5 visible: True readonly: False removable: False type: 'float' children: Vertical Position: name: 'Vertical Position' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: 3.0 visible: True step: 0.1 removable: False type: 'float' children: Bob: name: 'Bob' strictNaming: False default: None renamable: True enabled: True value: None visible: True readonly: False removable: True type: 'Clock' autoIncrementName: True children: Initial Position: name: 'Initial Position' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: 0.0 visible: True step: 0.1 removable: False type: 'float' children: Acceleration: name: 'Acceleration' strictNaming: False default: None renamable: False addText: 'Add Command..' enabled: True value: None visible: True readonly: False removable: False type: 'AccelerationGroup' children: Rest Mass: name: 'Rest Mass' limits: [1e-09, None] strictNaming: False default: 1.0 renamable: False enabled: True readonly: False value: 1.0 visible: True step: 0.1 removable: False type: 'float' children: Color: name: 'Color' strictNaming: False default: (100, 100, 150) renamable: False enabled: True value: (69, 69, 126, 255) visible: True readonly: False removable: False type: 'color' children: Size: name: 'Size' strictNaming: False default: 0.5 renamable: False enabled: True value: 1.5 visible: True readonly: False removable: False type: 'float' children: Vertical Position: name: 'Vertical Position' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: 0.0 visible: True step: 0.1 removable: False type: 'float' children: addList: ['Clock', 'Grid'] pyqtgraph-pyqtgraph-0.10.0/examples/relativity/presets/Twin Paradox.cfg000066400000000000000000000520311300727121400263020ustar00rootroot00000000000000name: 'params' strictNaming: False default: None renamable: False enabled: True value: None visible: True readonly: False removable: False type: 'group' children: Load Preset..: name: 'Load Preset..' limits: ['', 'Twin Paradox', 'test'] strictNaming: False default: None renamable: False enabled: True value: 'Twin Paradox' visible: True readonly: False values: [] removable: False type: 'list' children: Duration: name: 'Duration' limits: [0.1, None] strictNaming: False default: 10.0 renamable: False enabled: True readonly: False value: 27.0 visible: True step: 0.1 removable: False type: 'float' children: Reference Frame: name: 'Reference Frame' limits: ['Alice', 'Bob'] strictNaming: False default: None renamable: False enabled: True value: 'Alice' visible: True readonly: False values: [] removable: False type: 'list' children: Animate: name: 'Animate' strictNaming: False default: True renamable: False enabled: True value: True visible: True readonly: False removable: False type: 'bool' children: Animation Speed: name: 'Animation Speed' limits: [0.0001, None] strictNaming: False default: 1.0 renamable: False enabled: True readonly: False value: 1.0 visible: True step: 0.1 removable: False dec: True type: 'float' children: Recalculate Worldlines: name: 'Recalculate Worldlines' strictNaming: False default: None renamable: False enabled: True value: None visible: True readonly: False removable: False type: 'action' children: Save: name: 'Save' strictNaming: False default: None renamable: False enabled: True value: None visible: True readonly: False removable: False type: 'action' children: Load: name: 'Load' strictNaming: False default: None renamable: False enabled: True value: None visible: True readonly: False removable: False type: 'action' children: Objects: name: 'Objects' strictNaming: False default: None renamable: False addText: 'Add New..' enabled: True value: None visible: True readonly: False removable: False type: None children: Alice: name: 'Alice' strictNaming: False default: None renamable: True enabled: True value: None visible: True readonly: False removable: True type: 'Clock' autoIncrementName: True children: Initial Position: name: 'Initial Position' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: 0.0 visible: True step: 0.1 removable: False type: 'float' children: Acceleration: name: 'Acceleration' strictNaming: False default: None renamable: False addText: 'Add Command..' enabled: True value: None visible: True readonly: False removable: False type: 'AccelerationGroup' children: Command: name: 'Command' strictNaming: False default: None renamable: True enabled: True value: None visible: True readonly: False removable: True type: None autoIncrementName: True children: Proper Time: name: 'Proper Time' strictNaming: False default: 0.0 renamable: False enabled: True value: 1.0 visible: True readonly: False removable: False type: 'float' children: Acceleration: name: 'Acceleration' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: 0.5 visible: True step: 0.1 removable: False type: 'float' children: Command2: name: 'Command2' strictNaming: False default: None renamable: True enabled: True value: None visible: True readonly: False removable: True type: None autoIncrementName: True children: Proper Time: name: 'Proper Time' strictNaming: False default: 2.0 renamable: False enabled: True value: 3.0 visible: True readonly: False removable: False type: 'float' children: Acceleration: name: 'Acceleration' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: 0.0 visible: True step: 0.1 removable: False type: 'float' children: Command3: name: 'Command3' strictNaming: False default: None renamable: True enabled: True value: None visible: True readonly: False removable: True type: None autoIncrementName: True children: Proper Time: name: 'Proper Time' strictNaming: False default: 3.0 renamable: False enabled: True value: 8.0 visible: True readonly: False removable: False type: 'float' children: Acceleration: name: 'Acceleration' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: -0.5 visible: True step: 0.1 removable: False type: 'float' children: Command4: name: 'Command4' strictNaming: False default: None renamable: True enabled: True value: None visible: True readonly: False removable: True type: None autoIncrementName: True children: Proper Time: name: 'Proper Time' strictNaming: False default: 4.0 renamable: False enabled: True value: 12.0 visible: True readonly: False removable: False type: 'float' children: Acceleration: name: 'Acceleration' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: 0.0 visible: True step: 0.1 removable: False type: 'float' children: Command5: name: 'Command5' strictNaming: False default: None renamable: True enabled: True value: None visible: True readonly: False removable: True type: None autoIncrementName: True children: Proper Time: name: 'Proper Time' strictNaming: False default: 6.0 renamable: False enabled: True value: 17.0 visible: True readonly: False removable: False type: 'float' children: Acceleration: name: 'Acceleration' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: 0.5 visible: True step: 0.1 removable: False type: 'float' children: Command6: name: 'Command6' strictNaming: False default: None renamable: True enabled: True value: None visible: True readonly: False removable: True type: None autoIncrementName: True children: Proper Time: name: 'Proper Time' strictNaming: False default: 7.0 renamable: False enabled: True value: 19.0 visible: True readonly: False removable: False type: 'float' children: Acceleration: name: 'Acceleration' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: 0.0 visible: True step: 0.1 removable: False type: 'float' children: Rest Mass: name: 'Rest Mass' limits: [1e-09, None] strictNaming: False default: 1.0 renamable: False enabled: True readonly: False value: 1.0 visible: True step: 0.1 removable: False type: 'float' children: Color: name: 'Color' strictNaming: False default: (100, 100, 150) renamable: False enabled: True value: (82, 123, 44, 255) visible: True readonly: False removable: False type: 'color' children: Size: name: 'Size' strictNaming: False default: 0.5 renamable: False enabled: True value: 0.5 visible: True readonly: False removable: False type: 'float' children: Vertical Position: name: 'Vertical Position' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: 0.5 visible: True step: 0.1 removable: False type: 'float' children: Bob: name: 'Bob' strictNaming: False default: None renamable: True enabled: True value: None visible: True readonly: False removable: True type: 'Clock' autoIncrementName: True children: Initial Position: name: 'Initial Position' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: 0.0 visible: True step: 0.1 removable: False type: 'float' children: Acceleration: name: 'Acceleration' strictNaming: False default: None renamable: False addText: 'Add Command..' enabled: True value: None visible: True readonly: False removable: False type: 'AccelerationGroup' children: Rest Mass: name: 'Rest Mass' limits: [1e-09, None] strictNaming: False default: 1.0 renamable: False enabled: True readonly: False value: 1.0 visible: True step: 0.1 removable: False type: 'float' children: Color: name: 'Color' strictNaming: False default: (100, 100, 150) renamable: False enabled: True value: (69, 69, 126, 255) visible: True readonly: False removable: False type: 'color' children: Size: name: 'Size' strictNaming: False default: 0.5 renamable: False enabled: True value: 0.5 visible: True readonly: False removable: False type: 'float' children: Vertical Position: name: 'Vertical Position' strictNaming: False default: 0.0 renamable: False enabled: True readonly: False value: 0.0 visible: True step: 0.1 removable: False type: 'float' children: addList: ['Clock', 'Grid'] pyqtgraph-pyqtgraph-0.10.0/examples/relativity/relativity.py000066400000000000000000000672061300727121400244140ustar00rootroot00000000000000import numpy as np import collections import sys, os import pyqtgraph as pg from pyqtgraph.Qt import QtGui, QtCore from pyqtgraph.parametertree import Parameter, ParameterTree from pyqtgraph.parametertree import types as pTypes import pyqtgraph.configfile from pyqtgraph.python2_3 import xrange class RelativityGUI(QtGui.QWidget): def __init__(self): QtGui.QWidget.__init__(self) self.animations = [] self.animTimer = QtCore.QTimer() self.animTimer.timeout.connect(self.stepAnimation) self.animTime = 0 self.animDt = .016 self.lastAnimTime = 0 self.setupGUI() self.objectGroup = ObjectGroupParam() self.params = Parameter.create(name='params', type='group', children=[ dict(name='Load Preset..', type='list', values=[]), #dict(name='Unit System', type='list', values=['', 'MKS']), dict(name='Duration', type='float', value=10.0, step=0.1, limits=[0.1, None]), dict(name='Reference Frame', type='list', values=[]), dict(name='Animate', type='bool', value=True), dict(name='Animation Speed', type='float', value=1.0, dec=True, step=0.1, limits=[0.0001, None]), dict(name='Recalculate Worldlines', type='action'), dict(name='Save', type='action'), dict(name='Load', type='action'), self.objectGroup, ]) self.tree.setParameters(self.params, showTop=False) self.params.param('Recalculate Worldlines').sigActivated.connect(self.recalculate) self.params.param('Save').sigActivated.connect(self.save) self.params.param('Load').sigActivated.connect(self.load) self.params.param('Load Preset..').sigValueChanged.connect(self.loadPreset) self.params.sigTreeStateChanged.connect(self.treeChanged) ## read list of preset configs presetDir = os.path.join(os.path.abspath(os.path.dirname(sys.argv[0])), 'presets') if os.path.exists(presetDir): presets = [os.path.splitext(p)[0] for p in os.listdir(presetDir)] self.params.param('Load Preset..').setLimits(['']+presets) def setupGUI(self): self.layout = QtGui.QVBoxLayout() self.layout.setContentsMargins(0,0,0,0) self.setLayout(self.layout) self.splitter = QtGui.QSplitter() self.splitter.setOrientation(QtCore.Qt.Horizontal) self.layout.addWidget(self.splitter) self.tree = ParameterTree(showHeader=False) self.splitter.addWidget(self.tree) self.splitter2 = QtGui.QSplitter() self.splitter2.setOrientation(QtCore.Qt.Vertical) self.splitter.addWidget(self.splitter2) self.worldlinePlots = pg.GraphicsLayoutWidget() self.splitter2.addWidget(self.worldlinePlots) self.animationPlots = pg.GraphicsLayoutWidget() self.splitter2.addWidget(self.animationPlots) self.splitter2.setSizes([int(self.height()*0.8), int(self.height()*0.2)]) self.inertWorldlinePlot = self.worldlinePlots.addPlot() self.refWorldlinePlot = self.worldlinePlots.addPlot() self.inertAnimationPlot = self.animationPlots.addPlot() self.inertAnimationPlot.setAspectLocked(1) self.refAnimationPlot = self.animationPlots.addPlot() self.refAnimationPlot.setAspectLocked(1) self.inertAnimationPlot.setXLink(self.inertWorldlinePlot) self.refAnimationPlot.setXLink(self.refWorldlinePlot) def recalculate(self): ## build 2 sets of clocks clocks1 = collections.OrderedDict() clocks2 = collections.OrderedDict() for cl in self.params.param('Objects'): clocks1.update(cl.buildClocks()) clocks2.update(cl.buildClocks()) ## Inertial simulation dt = self.animDt * self.params['Animation Speed'] sim1 = Simulation(clocks1, ref=None, duration=self.params['Duration'], dt=dt) sim1.run() sim1.plot(self.inertWorldlinePlot) self.inertWorldlinePlot.autoRange(padding=0.1) ## reference simulation ref = self.params['Reference Frame'] dur = clocks1[ref].refData['pt'][-1] ## decide how long to run the reference simulation sim2 = Simulation(clocks2, ref=clocks2[ref], duration=dur, dt=dt) sim2.run() sim2.plot(self.refWorldlinePlot) self.refWorldlinePlot.autoRange(padding=0.1) ## create animations self.refAnimationPlot.clear() self.inertAnimationPlot.clear() self.animTime = 0 self.animations = [Animation(sim1), Animation(sim2)] self.inertAnimationPlot.addItem(self.animations[0]) self.refAnimationPlot.addItem(self.animations[1]) ## create lines representing all that is visible to a particular reference #self.inertSpaceline = Spaceline(sim1, ref) #self.refSpaceline = Spaceline(sim2) self.inertWorldlinePlot.addItem(self.animations[0].items[ref].spaceline()) self.refWorldlinePlot.addItem(self.animations[1].items[ref].spaceline()) def setAnimation(self, a): if a: self.lastAnimTime = pg.ptime.time() self.animTimer.start(self.animDt*1000) else: self.animTimer.stop() def stepAnimation(self): now = pg.ptime.time() dt = (now-self.lastAnimTime) * self.params['Animation Speed'] self.lastAnimTime = now self.animTime += dt if self.animTime > self.params['Duration']: self.animTime = 0 for a in self.animations: a.restart() for a in self.animations: a.stepTo(self.animTime) def treeChanged(self, *args): clocks = [] for c in self.params.param('Objects'): clocks.extend(c.clockNames()) #for param, change, data in args[1]: #if change == 'childAdded': self.params.param('Reference Frame').setLimits(clocks) self.setAnimation(self.params['Animate']) def save(self): fn = str(pg.QtGui.QFileDialog.getSaveFileName(self, "Save State..", "untitled.cfg", "Config Files (*.cfg)")) if fn == '': return state = self.params.saveState() pg.configfile.writeConfigFile(state, fn) def load(self): fn = str(pg.QtGui.QFileDialog.getOpenFileName(self, "Save State..", "", "Config Files (*.cfg)")) if fn == '': return state = pg.configfile.readConfigFile(fn) self.loadState(state) def loadPreset(self, param, preset): if preset == '': return path = os.path.abspath(os.path.dirname(__file__)) fn = os.path.join(path, 'presets', preset+".cfg") state = pg.configfile.readConfigFile(fn) self.loadState(state) def loadState(self, state): if 'Load Preset..' in state['children']: del state['children']['Load Preset..']['limits'] del state['children']['Load Preset..']['value'] self.params.param('Objects').clearChildren() self.params.restoreState(state, removeChildren=False) self.recalculate() class ObjectGroupParam(pTypes.GroupParameter): def __init__(self): pTypes.GroupParameter.__init__(self, name="Objects", addText="Add New..", addList=['Clock', 'Grid']) def addNew(self, typ): if typ == 'Clock': self.addChild(ClockParam()) elif typ == 'Grid': self.addChild(GridParam()) class ClockParam(pTypes.GroupParameter): def __init__(self, **kwds): defs = dict(name="Clock", autoIncrementName=True, renamable=True, removable=True, children=[ dict(name='Initial Position', type='float', value=0.0, step=0.1), #dict(name='V0', type='float', value=0.0, step=0.1), AccelerationGroup(), dict(name='Rest Mass', type='float', value=1.0, step=0.1, limits=[1e-9, None]), dict(name='Color', type='color', value=(100,100,150)), dict(name='Size', type='float', value=0.5), dict(name='Vertical Position', type='float', value=0.0, step=0.1), ]) #defs.update(kwds) pTypes.GroupParameter.__init__(self, **defs) self.restoreState(kwds, removeChildren=False) def buildClocks(self): x0 = self['Initial Position'] y0 = self['Vertical Position'] color = self['Color'] m = self['Rest Mass'] size = self['Size'] prog = self.param('Acceleration').generate() c = Clock(x0=x0, m0=m, y0=y0, color=color, prog=prog, size=size) return {self.name(): c} def clockNames(self): return [self.name()] pTypes.registerParameterType('Clock', ClockParam) class GridParam(pTypes.GroupParameter): def __init__(self, **kwds): defs = dict(name="Grid", autoIncrementName=True, renamable=True, removable=True, children=[ dict(name='Number of Clocks', type='int', value=5, limits=[1, None]), dict(name='Spacing', type='float', value=1.0, step=0.1), ClockParam(name='ClockTemplate'), ]) #defs.update(kwds) pTypes.GroupParameter.__init__(self, **defs) self.restoreState(kwds, removeChildren=False) def buildClocks(self): clocks = {} template = self.param('ClockTemplate') spacing = self['Spacing'] for i in range(self['Number of Clocks']): c = list(template.buildClocks().values())[0] c.x0 += i * spacing clocks[self.name() + '%02d' % i] = c return clocks def clockNames(self): return [self.name() + '%02d' % i for i in range(self['Number of Clocks'])] pTypes.registerParameterType('Grid', GridParam) class AccelerationGroup(pTypes.GroupParameter): def __init__(self, **kwds): defs = dict(name="Acceleration", addText="Add Command..") pTypes.GroupParameter.__init__(self, **defs) self.restoreState(kwds, removeChildren=False) def addNew(self): nextTime = 0.0 if self.hasChildren(): nextTime = self.children()[-1]['Proper Time'] + 1 self.addChild(Parameter.create(name='Command', autoIncrementName=True, type=None, renamable=True, removable=True, children=[ dict(name='Proper Time', type='float', value=nextTime), dict(name='Acceleration', type='float', value=0.0, step=0.1), ])) def generate(self): prog = [] for cmd in self: prog.append((cmd['Proper Time'], cmd['Acceleration'])) return prog pTypes.registerParameterType('AccelerationGroup', AccelerationGroup) class Clock(object): nClocks = 0 def __init__(self, x0=0.0, y0=0.0, m0=1.0, v0=0.0, t0=0.0, color=None, prog=None, size=0.5): Clock.nClocks += 1 self.pen = pg.mkPen(color) self.brush = pg.mkBrush(color) self.y0 = y0 self.x0 = x0 self.v0 = v0 self.m0 = m0 self.t0 = t0 self.prog = prog self.size = size def init(self, nPts): ## Keep records of object from inertial frame as well as reference frame self.inertData = np.empty(nPts, dtype=[('x', float), ('t', float), ('v', float), ('pt', float), ('m', float), ('f', float)]) self.refData = np.empty(nPts, dtype=[('x', float), ('t', float), ('v', float), ('pt', float), ('m', float), ('f', float)]) ## Inertial frame variables self.x = self.x0 self.v = self.v0 self.m = self.m0 self.t = 0.0 ## reference clock always starts at 0 self.pt = self.t0 ## proper time starts at t0 ## reference frame variables self.refx = None self.refv = None self.refm = None self.reft = None self.recordFrame(0) def recordFrame(self, i): f = self.force() self.inertData[i] = (self.x, self.t, self.v, self.pt, self.m, f) self.refData[i] = (self.refx, self.reft, self.refv, self.pt, self.refm, f) def force(self, t=None): if len(self.prog) == 0: return 0.0 if t is None: t = self.pt ret = 0.0 for t1,f in self.prog: if t >= t1: ret = f return ret def acceleration(self, t=None): return self.force(t) / self.m0 def accelLimits(self): ## return the proper time values which bound the current acceleration command if len(self.prog) == 0: return -np.inf, np.inf t = self.pt ind = -1 for i, v in enumerate(self.prog): t1,f = v if t >= t1: ind = i if ind == -1: return -np.inf, self.prog[0][0] elif ind == len(self.prog)-1: return self.prog[-1][0], np.inf else: return self.prog[ind][0], self.prog[ind+1][0] def getCurve(self, ref=True): if ref is False: data = self.inertData else: data = self.refData[1:] x = data['x'] y = data['t'] curve = pg.PlotCurveItem(x=x, y=y, pen=self.pen) #x = self.data['x'] - ref.data['x'] #y = self.data['t'] step = 1.0 #mod = self.data['pt'] % step #inds = np.argwhere(abs(mod[1:] - mod[:-1]) > step*0.9) inds = [0] pt = data['pt'] for i in range(1,len(pt)): diff = pt[i] - pt[inds[-1]] if abs(diff) >= step: inds.append(i) inds = np.array(inds) #t = self.data['t'][inds] #x = self.data['x'][inds] pts = [] for i in inds: x = data['x'][i] y = data['t'][i] if i+1 < len(data): dpt = data['pt'][i+1]-data['pt'][i] dt = data['t'][i+1]-data['t'][i] else: dpt = 1 if dpt > 0: c = pg.mkBrush((0,0,0)) else: c = pg.mkBrush((200,200,200)) pts.append({'pos': (x, y), 'brush': c}) points = pg.ScatterPlotItem(pts, pen=self.pen, size=7) return curve, points class Simulation: def __init__(self, clocks, ref, duration, dt): self.clocks = clocks self.ref = ref self.duration = duration self.dt = dt @staticmethod def hypTStep(dt, v0, x0, tau0, g): ## Hyperbolic step. ## If an object has proper acceleration g and starts at position x0 with speed v0 and proper time tau0 ## as seen from an inertial frame, then return the new v, x, tau after time dt has elapsed. if g == 0: return v0, x0 + v0*dt, tau0 + dt * (1. - v0**2)**0.5 v02 = v0**2 g2 = g**2 tinit = v0 / (g * (1 - v02)**0.5) B = (1 + (g2 * (dt+tinit)**2))**0.5 v1 = g * (dt+tinit) / B dtau = (np.arcsinh(g * (dt+tinit)) - np.arcsinh(g * tinit)) / g tau1 = tau0 + dtau x1 = x0 + (1.0 / g) * ( B - 1. / (1.-v02)**0.5 ) return v1, x1, tau1 @staticmethod def tStep(dt, v0, x0, tau0, g): ## Linear step. ## Probably not as accurate as hyperbolic step, but certainly much faster. gamma = (1. - v0**2)**-0.5 dtau = dt / gamma return v0 + dtau * g, x0 + v0*dt, tau0 + dtau @staticmethod def tauStep(dtau, v0, x0, t0, g): ## linear step in proper time of clock. ## If an object has proper acceleration g and starts at position x0 with speed v0 at time t0 ## as seen from an inertial frame, then return the new v, x, t after proper time dtau has elapsed. ## Compute how much t will change given a proper-time step of dtau gamma = (1. - v0**2)**-0.5 if g == 0: dt = dtau * gamma else: v0g = v0 * gamma dt = (np.sinh(dtau * g + np.arcsinh(v0g)) - v0g) / g #return v0 + dtau * g, x0 + v0*dt, t0 + dt v1, x1, t1 = Simulation.hypTStep(dt, v0, x0, t0, g) return v1, x1, t0+dt @staticmethod def hypIntersect(x0r, t0r, vr, x0, t0, v0, g): ## given a reference clock (seen from inertial frame) has rx, rt, and rv, ## and another clock starts at x0, t0, and v0, with acceleration g, ## compute the intersection time of the object clock's hyperbolic path with ## the reference plane. ## I'm sure we can simplify this... if g == 0: ## no acceleration, path is linear (and hyperbola is undefined) #(-t0r + t0 v0 vr - vr x0 + vr x0r)/(-1 + v0 vr) t = (-t0r + t0 *v0 *vr - vr *x0 + vr *x0r)/(-1 + v0 *vr) return t gamma = (1.0-v0**2)**-0.5 sel = (1 if g>0 else 0) + (1 if vr<0 else 0) sel = sel%2 if sel == 0: #(1/(g^2 (-1 + vr^2)))(-g^2 t0r + g gamma vr + g^2 t0 vr^2 - #g gamma v0 vr^2 - g^2 vr x0 + #g^2 vr x0r + \[Sqrt](g^2 vr^2 (1 + gamma^2 (v0 - vr)^2 - vr^2 + #2 g gamma (v0 - vr) (-t0 + t0r + vr (x0 - x0r)) + #g^2 (t0 - t0r + vr (-x0 + x0r))^2))) t = (1./(g**2 *(-1. + vr**2)))*(-g**2 *t0r + g *gamma *vr + g**2 *t0 *vr**2 - g *gamma *v0 *vr**2 - g**2 *vr *x0 + g**2 *vr *x0r + np.sqrt(g**2 *vr**2 *(1. + gamma**2 *(v0 - vr)**2 - vr**2 + 2 *g *gamma *(v0 - vr)* (-t0 + t0r + vr *(x0 - x0r)) + g**2 *(t0 - t0r + vr* (-x0 + x0r))**2))) else: #-(1/(g^2 (-1 + vr^2)))(g^2 t0r - g gamma vr - g^2 t0 vr^2 + #g gamma v0 vr^2 + g^2 vr x0 - #g^2 vr x0r + \[Sqrt](g^2 vr^2 (1 + gamma^2 (v0 - vr)^2 - vr^2 + #2 g gamma (v0 - vr) (-t0 + t0r + vr (x0 - x0r)) + #g^2 (t0 - t0r + vr (-x0 + x0r))^2))) t = -(1./(g**2 *(-1. + vr**2)))*(g**2 *t0r - g *gamma* vr - g**2 *t0 *vr**2 + g *gamma *v0 *vr**2 + g**2* vr* x0 - g**2 *vr *x0r + np.sqrt(g**2* vr**2 *(1. + gamma**2 *(v0 - vr)**2 - vr**2 + 2 *g *gamma *(v0 - vr) *(-t0 + t0r + vr *(x0 - x0r)) + g**2 *(t0 - t0r + vr *(-x0 + x0r))**2))) return t def run(self): nPts = int(self.duration/self.dt)+1 for cl in self.clocks.values(): cl.init(nPts) if self.ref is None: self.runInertial(nPts) else: self.runReference(nPts) def runInertial(self, nPts): clocks = self.clocks dt = self.dt tVals = np.linspace(0, dt*(nPts-1), nPts) for cl in self.clocks.values(): for i in xrange(1,nPts): nextT = tVals[i] while True: tau1, tau2 = cl.accelLimits() x = cl.x v = cl.v tau = cl.pt g = cl.acceleration() v1, x1, tau1 = self.hypTStep(dt, v, x, tau, g) if tau1 > tau2: dtau = tau2-tau cl.v, cl.x, cl.t = self.tauStep(dtau, v, x, cl.t, g) cl.pt = tau2 else: cl.v, cl.x, cl.pt = v1, x1, tau1 cl.t += dt if cl.t >= nextT: cl.refx = cl.x cl.refv = cl.v cl.reft = cl.t cl.recordFrame(i) break def runReference(self, nPts): clocks = self.clocks ref = self.ref dt = self.dt dur = self.duration ## make sure reference clock is not present in the list of clocks--this will be handled separately. clocks = clocks.copy() for k,v in clocks.items(): if v is ref: del clocks[k] break ref.refx = 0 ref.refv = 0 ref.refm = ref.m0 ## These are the set of proper times (in the reference frame) that will be simulated ptVals = np.linspace(ref.pt, ref.pt + dt*(nPts-1), nPts) for i in xrange(1,nPts): ## step reference clock ahead one time step in its proper time nextPt = ptVals[i] ## this is where (when) we want to end up while True: tau1, tau2 = ref.accelLimits() dtau = min(nextPt-ref.pt, tau2-ref.pt) ## do not step past the next command boundary g = ref.acceleration() v, x, t = Simulation.tauStep(dtau, ref.v, ref.x, ref.t, g) ref.pt += dtau ref.v = v ref.x = x ref.t = t ref.reft = ref.pt if ref.pt >= nextPt: break #else: #print "Stepped to", tau2, "instead of", nextPt ref.recordFrame(i) ## determine plane visible to reference clock ## this plane goes through the point ref.x, ref.t and has slope = ref.v ## update all other clocks for cl in clocks.values(): while True: g = cl.acceleration() tau1, tau2 = cl.accelLimits() ##Given current position / speed of clock, determine where it will intersect reference plane #t1 = (ref.v * (cl.x - cl.v * cl.t) + (ref.t - ref.v * ref.x)) / (1. - cl.v) t1 = Simulation.hypIntersect(ref.x, ref.t, ref.v, cl.x, cl.t, cl.v, g) dt1 = t1 - cl.t ## advance clock by correct time step v, x, tau = Simulation.hypTStep(dt1, cl.v, cl.x, cl.pt, g) ## check to see whether we have gone past an acceleration command boundary. ## if so, we must instead advance the clock to the boundary and start again if tau < tau1: dtau = tau1 - cl.pt cl.v, cl.x, cl.t = Simulation.tauStep(dtau, cl.v, cl.x, cl.t, g) cl.pt = tau1-0.000001 continue if tau > tau2: dtau = tau2 - cl.pt cl.v, cl.x, cl.t = Simulation.tauStep(dtau, cl.v, cl.x, cl.t, g) cl.pt = tau2 continue ## Otherwise, record the new values and exit the loop cl.v = v cl.x = x cl.pt = tau cl.t = t1 cl.m = None break ## transform position into reference frame x = cl.x - ref.x t = cl.t - ref.t gamma = (1.0 - ref.v**2) ** -0.5 vg = -ref.v * gamma cl.refx = gamma * (x - ref.v * t) cl.reft = ref.pt # + gamma * (t - ref.v * x) # this term belongs here, but it should always be equal to 0. cl.refv = (cl.v - ref.v) / (1.0 - cl.v * ref.v) cl.refm = None cl.recordFrame(i) t += dt def plot(self, plot): plot.clear() for cl in self.clocks.values(): c, p = cl.getCurve() plot.addItem(c) plot.addItem(p) class Animation(pg.ItemGroup): def __init__(self, sim): pg.ItemGroup.__init__(self) self.sim = sim self.clocks = sim.clocks self.items = {} for name, cl in self.clocks.items(): item = ClockItem(cl) self.addItem(item) self.items[name] = item #self.timer = timer #self.timer.timeout.connect(self.step) #def run(self, run): #if not run: #self.timer.stop() #else: #self.timer.start(self.dt) def restart(self): for cl in self.items.values(): cl.reset() def stepTo(self, t): for i in self.items.values(): i.stepTo(t) class ClockItem(pg.ItemGroup): def __init__(self, clock): pg.ItemGroup.__init__(self) self.size = clock.size self.item = QtGui.QGraphicsEllipseItem(QtCore.QRectF(0, 0, self.size, self.size)) self.item.translate(-self.size*0.5, -self.size*0.5) self.item.setPen(pg.mkPen(100,100,100)) self.item.setBrush(clock.brush) self.hand = QtGui.QGraphicsLineItem(0, 0, 0, self.size*0.5) self.hand.setPen(pg.mkPen('w')) self.hand.setZValue(10) self.flare = QtGui.QGraphicsPolygonItem(QtGui.QPolygonF([ QtCore.QPointF(0, -self.size*0.25), QtCore.QPointF(0, self.size*0.25), QtCore.QPointF(self.size*1.5, 0), QtCore.QPointF(0, -self.size*0.25), ])) self.flare.setPen(pg.mkPen('y')) self.flare.setBrush(pg.mkBrush(255,150,0)) self.flare.setZValue(-10) self.addItem(self.hand) self.addItem(self.item) self.addItem(self.flare) self.clock = clock self.i = 1 self._spaceline = None def spaceline(self): if self._spaceline is None: self._spaceline = pg.InfiniteLine() self._spaceline.setPen(self.clock.pen) return self._spaceline def stepTo(self, t): data = self.clock.refData while self.i < len(data)-1 and data['t'][self.i] < t: self.i += 1 while self.i > 1 and data['t'][self.i-1] >= t: self.i -= 1 self.setPos(data['x'][self.i], self.clock.y0) t = data['pt'][self.i] self.hand.setRotation(-0.25 * t * 360.) self.resetTransform() v = data['v'][self.i] gam = (1.0 - v**2)**0.5 self.scale(gam, 1.0) f = data['f'][self.i] self.flare.resetTransform() if f < 0: self.flare.translate(self.size*0.4, 0) else: self.flare.translate(-self.size*0.4, 0) self.flare.scale(-f * (0.5+np.random.random()*0.1), 1.0) if self._spaceline is not None: self._spaceline.setPos(pg.Point(data['x'][self.i], data['t'][self.i])) self._spaceline.setAngle(data['v'][self.i] * 45.) def reset(self): self.i = 1 #class Spaceline(pg.InfiniteLine): #def __init__(self, sim, frame): #self.sim = sim #self.frame = frame #pg.InfiniteLine.__init__(self) #self.setPen(sim.clocks[frame].pen) #def stepTo(self, t): #self.setAngle(0) #pass if __name__ == '__main__': pg.mkQApp() #import pyqtgraph.console #cw = pyqtgraph.console.ConsoleWidget() #cw.show() #cw.catchNextException() win = RelativityGUI() win.setWindowTitle("Relativity!") win.show() win.resize(1100,700) if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() #win.params.param('Objects').restoreState(state, removeChildren=False) pyqtgraph-pyqtgraph-0.10.0/examples/relativity_demo.py000066400000000000000000000011311300727121400232050ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Special relativity simulation """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from relativity import RelativityGUI pg.mkQApp() win = RelativityGUI() win.setWindowTitle("Relativity!") win.resize(1100,700) win.show() win.loadPreset(None, 'Twin Paradox (grid)') ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(pg.QtCore, 'PYQT_VERSION'): pg.QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/scrollingPlots.py000066400000000000000000000056531300727121400230400ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Various methods of drawing scrolling plots. """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np win = pg.GraphicsWindow() win.setWindowTitle('pyqtgraph example: Scrolling Plots') # 1) Simplest approach -- update data in the array such that plot appears to scroll # In these examples, the array size is fixed. p1 = win.addPlot() p2 = win.addPlot() data1 = np.random.normal(size=300) curve1 = p1.plot(data1) curve2 = p2.plot(data1) ptr1 = 0 def update1(): global data1, curve1, ptr1 data1[:-1] = data1[1:] # shift data in the array one sample left # (see also: np.roll) data1[-1] = np.random.normal() curve1.setData(data1) ptr1 += 1 curve2.setData(data1) curve2.setPos(ptr1, 0) # 2) Allow data to accumulate. In these examples, the array doubles in length # whenever it is full. win.nextRow() p3 = win.addPlot() p4 = win.addPlot() # Use automatic downsampling and clipping to reduce the drawing load p3.setDownsampling(mode='peak') p4.setDownsampling(mode='peak') p3.setClipToView(True) p4.setClipToView(True) p3.setRange(xRange=[-100, 0]) p3.setLimits(xMax=0) curve3 = p3.plot() curve4 = p4.plot() data3 = np.empty(100) ptr3 = 0 def update2(): global data3, ptr3 data3[ptr3] = np.random.normal() ptr3 += 1 if ptr3 >= data3.shape[0]: tmp = data3 data3 = np.empty(data3.shape[0] * 2) data3[:tmp.shape[0]] = tmp curve3.setData(data3[:ptr3]) curve3.setPos(-ptr3, 0) curve4.setData(data3[:ptr3]) # 3) Plot in chunks, adding one new plot curve for every 100 samples chunkSize = 100 # Remove chunks after we have 10 maxChunks = 10 startTime = pg.ptime.time() win.nextRow() p5 = win.addPlot(colspan=2) p5.setLabel('bottom', 'Time', 's') p5.setXRange(-10, 0) curves = [] data5 = np.empty((chunkSize+1,2)) ptr5 = 0 def update3(): global p5, data5, ptr5, curves now = pg.ptime.time() for c in curves: c.setPos(-(now-startTime), 0) i = ptr5 % chunkSize if i == 0: curve = p5.plot() curves.append(curve) last = data5[-1] data5 = np.empty((chunkSize+1,2)) data5[0] = last while len(curves) > maxChunks: c = curves.pop(0) p5.removeItem(c) else: curve = curves[-1] data5[i+1,0] = now - startTime data5[i+1,1] = np.random.normal() curve.setData(x=data5[:i+2, 0], y=data5[:i+2, 1]) ptr5 += 1 # update all plots def update(): update1() update2() update3() timer = pg.QtCore.QTimer() timer.timeout.connect(update) timer.start(50) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/template.py000066400000000000000000000010371300727121400216250ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Description of example """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np app = QtGui.QApplication([]) # win.setWindowTitle('pyqtgraph example: ____') ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/test_examples.py000066400000000000000000000022131300727121400226640ustar00rootroot00000000000000from __future__ import print_function, division, absolute_import from pyqtgraph import Qt from . import utils import itertools import pytest # apparently importlib does not exist in python 2.6... try: import importlib except ImportError: # we are on python 2.6 print("If you want to test the examples, please install importlib from " "pypi\n\npip install importlib\n\n") pass files = utils.buildFileList(utils.examples) frontends = {Qt.PYQT4: False, Qt.PYSIDE: False} # sort out which of the front ends are available for frontend in frontends.keys(): try: importlib.import_module(frontend) frontends[frontend] = True except ImportError: pass @pytest.mark.parametrize( "frontend, f", itertools.product(sorted(list(frontends.keys())), files)) def test_examples(frontend, f): # Test the examples with all available front-ends print('frontend = %s. f = %s' % (frontend, f)) if not frontends[frontend]: pytest.skip('%s is not installed. Skipping tests' % frontend) utils.testFile(f[0], f[1], utils.sys.executable, frontend) if __name__ == "__main__": pytest.cmdline.main() pyqtgraph-pyqtgraph-0.10.0/examples/text.py000066400000000000000000000037121300727121400210000ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ This example shows how to insert text into a scene using TextItem. This class is for displaying text that is anchored to a particular location in the data coordinate system, but which is always displayed unscaled. For text that scales with the data, use QTextItem. For text that can be placed in a layout, use LabelItem. """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np x = np.linspace(-20, 20, 1000) y = np.sin(x) / x plot = pg.plot() ## create an empty plot widget plot.setYRange(-1, 2) plot.setWindowTitle('pyqtgraph example: text') curve = plot.plot(x,y) ## add a single curve ## Create text object, use HTML tags to specify color/size text = pg.TextItem(html='
This is the
PEAK
', anchor=(-0.3,0.5), angle=45, border='w', fill=(0, 0, 255, 100)) plot.addItem(text) text.setPos(0, y.max()) ## Draw an arrowhead next to the text box arrow = pg.ArrowItem(pos=(0, y.max()), angle=-45) plot.addItem(arrow) ## Set up an animated arrow and text that track the curve curvePoint = pg.CurvePoint(curve) plot.addItem(curvePoint) text2 = pg.TextItem("test", anchor=(0.5, -1.0)) text2.setParentItem(curvePoint) arrow2 = pg.ArrowItem(angle=90) arrow2.setParentItem(curvePoint) ## update position every 10ms index = 0 def update(): global curvePoint, index index = (index + 1) % len(x) curvePoint.setPos(float(index)/(len(x)-1)) text2.setText('[%0.1f, %0.1f]' % (x[index], y[index])) timer = QtCore.QTimer() timer.timeout.connect(update) timer.start(10) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/examples/utils.py000066400000000000000000000130771300727121400211610ustar00rootroot00000000000000from __future__ import division, print_function, absolute_import import subprocess import time import os import sys from pyqtgraph.pgcollections import OrderedDict from pyqtgraph.python2_3 import basestring path = os.path.abspath(os.path.dirname(__file__)) examples = OrderedDict([ ('Command-line usage', 'CLIexample.py'), ('Basic Plotting', 'Plotting.py'), ('ImageView', 'ImageView.py'), ('ParameterTree', 'parametertree.py'), ('Crosshair / Mouse interaction', 'crosshair.py'), ('Data Slicing', 'DataSlicing.py'), ('Plot Customization', 'customPlot.py'), ('Image Analysis', 'imageAnalysis.py'), ('Dock widgets', 'dockarea.py'), ('Console', 'ConsoleWidget.py'), ('Histograms', 'histogram.py'), ('Beeswarm plot', 'beeswarm.py'), ('Symbols', 'Symbols.py'), ('Auto-range', 'PlotAutoRange.py'), ('Remote Plotting', 'RemoteSpeedTest.py'), ('Scrolling plots', 'scrollingPlots.py'), ('HDF5 big data', 'hdf5.py'), ('Demos', OrderedDict([ ('Optics', 'optics_demos.py'), ('Special relativity', 'relativity_demo.py'), ('Verlet chain', 'verlet_chain_demo.py'), ])), ('GraphicsItems', OrderedDict([ ('Scatter Plot', 'ScatterPlot.py'), #('PlotItem', 'PlotItem.py'), ('IsocurveItem', 'isocurve.py'), ('GraphItem', 'GraphItem.py'), ('ErrorBarItem', 'ErrorBarItem.py'), ('FillBetweenItem', 'FillBetweenItem.py'), ('ImageItem - video', 'ImageItem.py'), ('ImageItem - draw', 'Draw.py'), ('Region-of-Interest', 'ROIExamples.py'), ('Bar Graph', 'BarGraphItem.py'), ('GraphicsLayout', 'GraphicsLayout.py'), ('LegendItem', 'Legend.py'), ('Text Item', 'text.py'), ('Linked Views', 'linkedViews.py'), ('Arrow', 'Arrow.py'), ('ViewBox', 'ViewBox.py'), ('Custom Graphics', 'customGraphicsItem.py'), ('Labeled Graph', 'CustomGraphItem.py'), ])), ('Benchmarks', OrderedDict([ ('Video speed test', 'VideoSpeedTest.py'), ('Line Plot update', 'PlotSpeedTest.py'), ('Scatter Plot update', 'ScatterPlotSpeedTest.py'), ('Multiple plots', 'MultiPlotSpeedTest.py'), ])), ('3D Graphics', OrderedDict([ ('Volumetric', 'GLVolumeItem.py'), ('Isosurface', 'GLIsosurface.py'), ('Surface Plot', 'GLSurfacePlot.py'), ('Scatter Plot', 'GLScatterPlotItem.py'), ('Shaders', 'GLshaders.py'), ('Line Plot', 'GLLinePlotItem.py'), ('Mesh', 'GLMeshItem.py'), ('Image', 'GLImageItem.py'), ])), ('Widgets', OrderedDict([ ('PlotWidget', 'PlotWidget.py'), ('SpinBox', 'SpinBox.py'), ('ConsoleWidget', 'ConsoleWidget.py'), ('Histogram / lookup table', 'HistogramLUT.py'), ('TreeWidget', 'TreeWidget.py'), ('ScatterPlotWidget', 'ScatterPlotWidget.py'), ('DataTreeWidget', 'DataTreeWidget.py'), ('GradientWidget', 'GradientWidget.py'), ('TableWidget', 'TableWidget.py'), ('ColorButton', 'ColorButton.py'), #('CheckTable', '../widgets/CheckTable.py'), #('VerticalLabel', '../widgets/VerticalLabel.py'), ('JoystickButton', 'JoystickButton.py'), ])), ('Flowcharts', 'Flowchart.py'), ('Custom Flowchart Nodes', 'FlowchartCustomNode.py'), ]) def buildFileList(examples, files=None): if files == None: files = [] for key, val in examples.items(): #item = QtGui.QTreeWidgetItem([key]) if isinstance(val, basestring): #item.file = val files.append((key,val)) else: buildFileList(val, files) return files def testFile(name, f, exe, lib, graphicsSystem=None): global path fn = os.path.join(path,f) #print "starting process: ", fn os.chdir(path) sys.stdout.write(name) sys.stdout.flush() import1 = "import %s" % lib if lib != '' else '' import2 = os.path.splitext(os.path.split(fn)[1])[0] graphicsSystem = '' if graphicsSystem is None else "pg.QtGui.QApplication.setGraphicsSystem('%s')" % graphicsSystem code = """ try: %s import initExample import pyqtgraph as pg %s import %s import sys print("test complete") sys.stdout.flush() import time while True: ## run a little event loop pg.QtGui.QApplication.processEvents() time.sleep(0.01) except: print("test failed") raise """ % (import1, graphicsSystem, import2) if sys.platform.startswith('win'): process = subprocess.Popen([exe], stdin=subprocess.PIPE, stderr=subprocess.PIPE, stdout=subprocess.PIPE) process.stdin.write(code.encode('UTF-8')) process.stdin.close() else: process = subprocess.Popen(['exec %s -i' % (exe)], shell=True, stdin=subprocess.PIPE, stderr=subprocess.PIPE, stdout=subprocess.PIPE) process.stdin.write(code.encode('UTF-8')) process.stdin.close() ##? output = '' fail = False while True: c = process.stdout.read(1).decode() output += c #sys.stdout.write(c) #sys.stdout.flush() if output.endswith('test complete'): break if output.endswith('test failed'): fail = True break time.sleep(1) process.kill() #res = process.communicate() res = (process.stdout.read(), process.stderr.read()) if fail or 'exception' in res[1].decode().lower() or 'error' in res[1].decode().lower(): print('.' * (50-len(name)) + 'FAILED') print(res[0].decode()) print(res[1].decode()) else: print('.' * (50-len(name)) + 'passed') pyqtgraph-pyqtgraph-0.10.0/examples/verlet_chain/000077500000000000000000000000001300727121400221025ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/examples/verlet_chain/__init__.py000066400000000000000000000000331300727121400242070ustar00rootroot00000000000000from .chain import ChainSimpyqtgraph-pyqtgraph-0.10.0/examples/verlet_chain/chain.py000066400000000000000000000071221300727121400235400ustar00rootroot00000000000000import pyqtgraph as pg import numpy as np import time from . import relax class ChainSim(pg.QtCore.QObject): stepped = pg.QtCore.Signal() relaxed = pg.QtCore.Signal() def __init__(self): pg.QtCore.QObject.__init__(self) self.damping = 0.1 # 0=full damping, 1=no damping self.relaxPerStep = 10 self.maxTimeStep = 0.01 self.pos = None # (Npts, 2) float self.mass = None # (Npts) float self.fixed = None # (Npts) bool self.links = None # (Nlinks, 2), uint self.lengths = None # (Nlinks), float self.push = None # (Nlinks), bool self.pull = None # (Nlinks), bool self.initialized = False self.lasttime = None self.lastpos = None def init(self): if self.initialized: return assert None not in [self.pos, self.mass, self.links, self.lengths] if self.fixed is None: self.fixed = np.zeros(self.pos.shape[0], dtype=bool) if self.push is None: self.push = np.ones(self.links.shape[0], dtype=bool) if self.pull is None: self.pull = np.ones(self.links.shape[0], dtype=bool) # precompute relative masses across links l1 = self.links[:,0] l2 = self.links[:,1] m1 = self.mass[l1] m2 = self.mass[l2] self.mrel1 = (m1 / (m1+m2))[:,np.newaxis] self.mrel1[self.fixed[l1]] = 1 # fixed point constraint self.mrel1[self.fixed[l2]] = 0 self.mrel2 = 1.0 - self.mrel1 for i in range(10): self.relax(n=10) self.initialized = True def makeGraph(self): #g1 = pg.GraphItem(pos=self.pos, adj=self.links[self.rope], pen=0.2, symbol=None) brushes = np.where(self.fixed, pg.mkBrush(0,0,0,255), pg.mkBrush(50,50,200,255)) g2 = pg.GraphItem(pos=self.pos, adj=self.links[self.push & self.pull], pen=0.5, brush=brushes, symbol='o', size=(self.mass**0.33), pxMode=False) p = pg.ItemGroup() #p.addItem(g1) p.addItem(g2) return p def update(self): # approximate physics with verlet integration now = pg.ptime.time() if self.lasttime is None: dt = 0 else: dt = now - self.lasttime self.lasttime = now # limit amount of work to be done between frames if not relax.COMPILED: dt = self.maxTimeStep if self.lastpos is None: self.lastpos = self.pos # remember fixed positions fixedpos = self.pos[self.fixed] while dt > 0: dt1 = min(self.maxTimeStep, dt) dt -= dt1 # compute motion since last timestep dx = self.pos - self.lastpos self.lastpos = self.pos # update positions for gravity and inertia acc = np.array([[0, -5]]) * dt1 inertia = dx * (self.damping**(dt1/self.mass))[:,np.newaxis] # with mass-dependent damping self.pos = self.pos + inertia + acc self.pos[self.fixed] = fixedpos # fixed point constraint # correct for link constraints self.relax(self.relaxPerStep) self.stepped.emit() def relax(self, n=50): # speed up with C magic if possible relax.relax(self.pos, self.links, self.mrel1, self.mrel2, self.lengths, self.push, self.pull, n) self.relaxed.emit() pyqtgraph-pyqtgraph-0.10.0/examples/verlet_chain/make000077500000000000000000000000661300727121400227470ustar00rootroot00000000000000gcc -fPIC -c relax.c gcc -shared -o maths.so relax.o pyqtgraph-pyqtgraph-0.10.0/examples/verlet_chain/relax.c000066400000000000000000000023111300727121400233560ustar00rootroot00000000000000#include #include void relax( double* pos, long* links, double* mrel1, double* mrel2, double* lengths, char* push, char* pull, int nlinks, int iters) { int i, l, p1, p2; double x1, x2, y1, y2, dx, dy, dist, change; // printf("%d, %d\n", iters, nlinks); for( i=0; i lengths[l] ) dist = lengths[l]; change = (lengths[l]-dist) / dist; dx *= change; dy *= change; pos[p1] -= mrel2[l] * dx; pos[p1+1] -= mrel2[l] * dy; pos[p2] += mrel1[l] * dx; pos[p2+1] += mrel1[l] * dy; } } }pyqtgraph-pyqtgraph-0.10.0/examples/verlet_chain/relax.py000066400000000000000000000041051300727121400235670ustar00rootroot00000000000000import ctypes import os so = os.path.join(os.path.dirname(__file__), 'maths.so') try: lib = ctypes.CDLL(so) COMPILED = True except OSError: COMPILED = False if COMPILED: lib.relax.argtypes = [ ctypes.c_void_p, ctypes.c_void_p, ctypes.c_void_p, ctypes.c_void_p, ctypes.c_void_p, ctypes.c_void_p, ctypes.c_void_p, ctypes.c_int, ctypes.c_int, ] def relax(pos, links, mrel1, mrel2, lengths, push, pull, iters): nlinks = links.shape[0] lib.relax(pos.ctypes, links.ctypes, mrel1.ctypes, mrel2.ctypes, lengths.ctypes, push.ctypes, pull.ctypes, nlinks, iters) else: def relax(pos, links, mrel1, mrel2, lengths, push, pull, iters): lengths2 = lengths**2 for i in range(iters): #p1 = links[:, 0] #p2 = links[:, 1] #x1 = pos[p1] #x2 = pos[p2] #dx = x2 - x1 #dist = (dx**2).sum(axis=1)**0.5 #mask = (npush & (dist < lengths)) | (npull & (dist > lengths)) ##dist[mask] = lengths[mask] #change = (lengths-dist) / dist #change[mask] = 0 #dx *= change[:, np.newaxis] #print dx ##pos[p1] -= mrel2 * dx ##pos[p2] += mrel1 * dx #for j in range(links.shape[0]): #pos[links[j,0]] -= mrel2[j] * dx[j] #pos[links[j,1]] += mrel1[j] * dx[j] for l in range(links.shape[0]): p1, p2 = links[l]; x1 = pos[p1] x2 = pos[p2] dx = x2 - x1 dist2 = (dx**2).sum() if (push[l] and dist2 < lengths2[l]) or (pull[l] and dist2 > lengths2[l]): dist = dist2 ** 0.5 change = (lengths[l]-dist) / dist dx *= change pos[p1] -= mrel2[l] * dx pos[p2] += mrel1[l] * dx pyqtgraph-pyqtgraph-0.10.0/examples/verlet_chain_demo.py000066400000000000000000000062651300727121400234710ustar00rootroot00000000000000""" Mechanical simulation of a chain using verlet integration. Use the mouse to interact with one of the chains. By default, this uses a slow, pure-python integrator to solve the chain link positions. Unix users may compile a small math library to speed this up by running the `examples/verlet_chain/make` script. """ import initExample ## Add path to library (just for examples; you do not need this) import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np import verlet_chain sim = verlet_chain.ChainSim() if verlet_chain.relax.COMPILED: # Use more complex chain if compiled mad library is available. chlen1 = 80 chlen2 = 60 linklen = 1 else: chlen1 = 10 chlen2 = 8 linklen = 8 npts = chlen1 + chlen2 sim.mass = np.ones(npts) sim.mass[int(chlen1 * 0.8)] = 100 sim.mass[chlen1-1] = 500 sim.mass[npts-1] = 200 sim.fixed = np.zeros(npts, dtype=bool) sim.fixed[0] = True sim.fixed[chlen1] = True sim.pos = np.empty((npts, 2)) sim.pos[:chlen1, 0] = 0 sim.pos[chlen1:, 0] = 10 sim.pos[:chlen1, 1] = np.arange(chlen1) * linklen sim.pos[chlen1:, 1] = np.arange(chlen2) * linklen # to prevent miraculous balancing acts: sim.pos += np.random.normal(size=sim.pos.shape, scale=1e-3) links1 = [(j, i+j+1) for i in range(chlen1) for j in range(chlen1-i-1)] links2 = [(j, i+j+1) for i in range(chlen2) for j in range(chlen2-i-1)] sim.links = np.concatenate([np.array(links1), np.array(links2)+chlen1, np.array([[chlen1-1, npts-1]])]) p1 = sim.pos[sim.links[:,0]] p2 = sim.pos[sim.links[:,1]] dif = p2-p1 sim.lengths = (dif**2).sum(axis=1) ** 0.5 sim.lengths[(chlen1-1):len(links1)] *= 1.05 # let auxiliary links stretch a little sim.lengths[(len(links1)+chlen2-1):] *= 1.05 sim.lengths[-1] = 7 push1 = np.ones(len(links1), dtype=bool) push1[chlen1:] = False push2 = np.ones(len(links2), dtype=bool) push2[chlen2:] = False sim.push = np.concatenate([push1, push2, np.array([True], dtype=bool)]) sim.pull = np.ones(sim.links.shape[0], dtype=bool) sim.pull[-1] = False # move chain initially just to generate some motion if the mouse is not over the window mousepos = np.array([30, 20]) def display(): global view, sim view.clear() view.addItem(sim.makeGraph()) def relaxed(): global app display() app.processEvents() def mouse(pos): global mousepos pos = view.mapSceneToView(pos) mousepos = np.array([pos.x(), pos.y()]) def update(): global mousepos #sim.pos[0] = sim.pos[0] * 0.9 + mousepos * 0.1 s = 0.9 sim.pos[0] = sim.pos[0] * s + mousepos * (1.0-s) sim.update() app = pg.mkQApp() win = pg.GraphicsLayoutWidget() win.show() view = win.addViewBox() view.setAspectLocked(True) view.setXRange(-100, 100) #view.autoRange() view.scene().sigMouseMoved.connect(mouse) #display() #app.processEvents() sim.relaxed.connect(relaxed) sim.init() sim.relaxed.disconnect(relaxed) sim.stepped.connect(display) timer = pg.QtCore.QTimer() timer.timeout.connect(update) timer.start(16) ## Start Qt event loop unless running in interactive mode or using pyside. if __name__ == '__main__': import sys if (sys.flags.interactive != 1) or not hasattr(QtCore, 'PYQT_VERSION'): QtGui.QApplication.instance().exec_() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/000077500000000000000000000000001300727121400176405ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/GraphicsScene/000077500000000000000000000000001300727121400223565ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/GraphicsScene/GraphicsScene.py000066400000000000000000000601631300727121400254540ustar00rootroot00000000000000import weakref from ..Qt import QtCore, QtGui from ..python2_3 import sortList, cmp from ..Point import Point from .. import functions as fn from .. import ptime as ptime from .mouseEvents import * from .. import debug as debug if hasattr(QtCore, 'PYQT_VERSION'): try: import sip HAVE_SIP = True except ImportError: HAVE_SIP = False else: HAVE_SIP = False __all__ = ['GraphicsScene'] class GraphicsScene(QtGui.QGraphicsScene): """ Extension of QGraphicsScene that implements a complete, parallel mouse event system. (It would have been preferred to just alter the way QGraphicsScene creates and delivers events, but this turned out to be impossible because the constructor for QGraphicsMouseEvent is private) * Generates MouseClicked events in addition to the usual press/move/release events. (This works around a problem where it is impossible to have one item respond to a drag if another is watching for a click.) * Adjustable radius around click that will catch objects so you don't have to click *exactly* over small/thin objects * Global context menu--if an item implements a context menu, then its parent(s) may also add items to the menu. * Allows items to decide _before_ a mouse click which item will be the recipient of mouse events. This lets us indicate unambiguously to the user which item they are about to click/drag on * Eats mouseMove events that occur too soon after a mouse press. * Reimplements items() and itemAt() to circumvent PyQt bug Mouse interaction is as follows: 1) Every time the mouse moves, the scene delivers both the standard hoverEnter/Move/LeaveEvents as well as custom HoverEvents. 2) Items are sent HoverEvents in Z-order and each item may optionally call event.acceptClicks(button), acceptDrags(button) or both. If this method call returns True, this informs the item that _if_ the user clicks/drags the specified mouse button, the item is guaranteed to be the recipient of click/drag events (the item may wish to change its appearance to indicate this). If the call to acceptClicks/Drags returns False, then the item is guaranteed to *not* receive the requested event (because another item has already accepted it). 3) If the mouse is clicked, a mousePressEvent is generated as usual. If any items accept this press event, then No click/drag events will be generated and mouse interaction proceeds as defined by Qt. This allows items to function properly if they are expecting the usual press/move/release sequence of events. (It is recommended that items do NOT accept press events, and instead use click/drag events) Note: The default implementation of QGraphicsItem.mousePressEvent will *accept* the event if the item is has its Selectable or Movable flags enabled. You may need to override this behavior. 4) If no item accepts the mousePressEvent, then the scene will begin delivering mouseDrag and/or mouseClick events. If the mouse is moved a sufficient distance (or moved slowly enough) before the button is released, then a mouseDragEvent is generated. If no drag events are generated before the button is released, then a mouseClickEvent is generated. 5) Click/drag events are delivered to the item that called acceptClicks/acceptDrags on the HoverEvent in step 1. If no such items exist, then the scene attempts to deliver the events to items near the event. ClickEvents may be delivered in this way even if no item originally claimed it could accept the click. DragEvents may only be delivered this way if it is the initial move in a drag. """ sigMouseHover = QtCore.Signal(object) ## emits a list of objects hovered over sigMouseMoved = QtCore.Signal(object) ## emits position of mouse on every move sigMouseClicked = QtCore.Signal(object) ## emitted when mouse is clicked. Check for event.isAccepted() to see whether the event has already been acted on. sigPrepareForPaint = QtCore.Signal() ## emitted immediately before the scene is about to be rendered _addressCache = weakref.WeakValueDictionary() ExportDirectory = None @classmethod def registerObject(cls, obj): """ Workaround for PyQt bug in qgraphicsscene.items() All subclasses of QGraphicsObject must register themselves with this function. (otherwise, mouse interaction with those objects will likely fail) """ if HAVE_SIP and isinstance(obj, sip.wrapper): cls._addressCache[sip.unwrapinstance(sip.cast(obj, QtGui.QGraphicsItem))] = obj def __init__(self, clickRadius=2, moveDistance=5, parent=None): QtGui.QGraphicsScene.__init__(self, parent) self.setClickRadius(clickRadius) self.setMoveDistance(moveDistance) self.exportDirectory = None self.clickEvents = [] self.dragButtons = [] self.mouseGrabber = None self.dragItem = None self.lastDrag = None self.hoverItems = weakref.WeakKeyDictionary() self.lastHoverEvent = None self.minDragTime = 0.5 # drags shorter than 0.5 sec are interpreted as clicks self.contextMenu = [QtGui.QAction("Export...", self)] self.contextMenu[0].triggered.connect(self.showExportDialog) self.exportDialog = None def render(self, *args): self.prepareForPaint() return QtGui.QGraphicsScene.render(self, *args) def prepareForPaint(self): """Called before every render. This method will inform items that the scene is about to be rendered by emitting sigPrepareForPaint. This allows items to delay expensive processing until they know a paint will be required.""" self.sigPrepareForPaint.emit() def setClickRadius(self, r): """ Set the distance away from mouse clicks to search for interacting items. When clicking, the scene searches first for items that directly intersect the click position followed by any other items that are within a rectangle that extends r pixels away from the click position. """ self._clickRadius = r def setMoveDistance(self, d): """ Set the distance the mouse must move after a press before mouseMoveEvents will be delivered. This ensures that clicks with a small amount of movement are recognized as clicks instead of drags. """ self._moveDistance = d def mousePressEvent(self, ev): QtGui.QGraphicsScene.mousePressEvent(self, ev) if self.mouseGrabberItem() is None: ## nobody claimed press; we are free to generate drag/click events if self.lastHoverEvent is not None: # If the mouse has moved since the last hover event, send a new one. # This can happen if a context menu is open while the mouse is moving. if ev.scenePos() != self.lastHoverEvent.scenePos(): self.sendHoverEvents(ev) self.clickEvents.append(MouseClickEvent(ev)) ## set focus on the topmost focusable item under this click items = self.items(ev.scenePos()) for i in items: if i.isEnabled() and i.isVisible() and int(i.flags() & i.ItemIsFocusable) > 0: i.setFocus(QtCore.Qt.MouseFocusReason) break def mouseMoveEvent(self, ev): self.sigMouseMoved.emit(ev.scenePos()) ## First allow QGraphicsScene to deliver hoverEnter/Move/ExitEvents QtGui.QGraphicsScene.mouseMoveEvent(self, ev) ## Next deliver our own HoverEvents self.sendHoverEvents(ev) if int(ev.buttons()) != 0: ## button is pressed; send mouseMoveEvents and mouseDragEvents QtGui.QGraphicsScene.mouseMoveEvent(self, ev) if self.mouseGrabberItem() is None: now = ptime.time() init = False ## keep track of which buttons are involved in dragging for btn in [QtCore.Qt.LeftButton, QtCore.Qt.MidButton, QtCore.Qt.RightButton]: if int(ev.buttons() & btn) == 0: continue if int(btn) not in self.dragButtons: ## see if we've dragged far enough yet cev = [e for e in self.clickEvents if int(e.button()) == int(btn)][0] dist = Point(ev.scenePos() - cev.scenePos()).length() if dist == 0 or (dist < self._moveDistance and now - cev.time() < self.minDragTime): continue init = init or (len(self.dragButtons) == 0) ## If this is the first button to be dragged, then init=True self.dragButtons.append(int(btn)) ## If we have dragged buttons, deliver a drag event if len(self.dragButtons) > 0: if self.sendDragEvent(ev, init=init): ev.accept() def leaveEvent(self, ev): ## inform items that mouse is gone if len(self.dragButtons) == 0: self.sendHoverEvents(ev, exitOnly=True) def mouseReleaseEvent(self, ev): if self.mouseGrabberItem() is None: if ev.button() in self.dragButtons: if self.sendDragEvent(ev, final=True): #print "sent drag event" ev.accept() self.dragButtons.remove(ev.button()) else: cev = [e for e in self.clickEvents if int(e.button()) == int(ev.button())] if self.sendClickEvent(cev[0]): #print "sent click event" ev.accept() self.clickEvents.remove(cev[0]) if int(ev.buttons()) == 0: self.dragItem = None self.dragButtons = [] self.clickEvents = [] self.lastDrag = None QtGui.QGraphicsScene.mouseReleaseEvent(self, ev) self.sendHoverEvents(ev) ## let items prepare for next click/drag def mouseDoubleClickEvent(self, ev): QtGui.QGraphicsScene.mouseDoubleClickEvent(self, ev) if self.mouseGrabberItem() is None: ## nobody claimed press; we are free to generate drag/click events self.clickEvents.append(MouseClickEvent(ev, double=True)) def sendHoverEvents(self, ev, exitOnly=False): ## if exitOnly, then just inform all previously hovered items that the mouse has left. if exitOnly: acceptable=False items = [] event = HoverEvent(None, acceptable) else: acceptable = int(ev.buttons()) == 0 ## if we are in mid-drag, do not allow items to accept the hover event. event = HoverEvent(ev, acceptable) items = self.itemsNearEvent(event, hoverable=True) self.sigMouseHover.emit(items) prevItems = list(self.hoverItems.keys()) for item in items: if hasattr(item, 'hoverEvent'): event.currentItem = item if item not in self.hoverItems: self.hoverItems[item] = None event.enter = True else: prevItems.remove(item) event.enter = False try: item.hoverEvent(event) except: debug.printExc("Error sending hover event:") event.enter = False event.exit = True #print "hover exit items:", prevItems for item in prevItems: event.currentItem = item try: item.hoverEvent(event) except: debug.printExc("Error sending hover exit event:") finally: del self.hoverItems[item] # Update last hover event unless: # - mouse is dragging (move+buttons); in this case we want the dragged # item to continue receiving events until the drag is over # - event is not a mouse event (QEvent.Leave sometimes appears here) if (ev.type() == ev.GraphicsSceneMousePress or (ev.type() == ev.GraphicsSceneMouseMove and int(ev.buttons()) == 0)): self.lastHoverEvent = event ## save this so we can ask about accepted events later. def sendDragEvent(self, ev, init=False, final=False): ## Send a MouseDragEvent to the current dragItem or to ## items near the beginning of the drag event = MouseDragEvent(ev, self.clickEvents[0], self.lastDrag, start=init, finish=final) #print "dragEvent: init=", init, 'final=', final, 'self.dragItem=', self.dragItem if init and self.dragItem is None: if self.lastHoverEvent is not None: acceptedItem = self.lastHoverEvent.dragItems().get(event.button(), None) else: acceptedItem = None if acceptedItem is not None: #print "Drag -> pre-selected item:", acceptedItem self.dragItem = acceptedItem event.currentItem = self.dragItem try: self.dragItem.mouseDragEvent(event) except: debug.printExc("Error sending drag event:") else: #print "drag -> new item" for item in self.itemsNearEvent(event): #print "check item:", item if not item.isVisible() or not item.isEnabled(): continue if hasattr(item, 'mouseDragEvent'): event.currentItem = item try: item.mouseDragEvent(event) except: debug.printExc("Error sending drag event:") if event.isAccepted(): #print " --> accepted" self.dragItem = item if int(item.flags() & item.ItemIsFocusable) > 0: item.setFocus(QtCore.Qt.MouseFocusReason) break elif self.dragItem is not None: event.currentItem = self.dragItem try: self.dragItem.mouseDragEvent(event) except: debug.printExc("Error sending hover exit event:") self.lastDrag = event return event.isAccepted() def sendClickEvent(self, ev): ## if we are in mid-drag, click events may only go to the dragged item. if self.dragItem is not None and hasattr(self.dragItem, 'mouseClickEvent'): ev.currentItem = self.dragItem self.dragItem.mouseClickEvent(ev) ## otherwise, search near the cursor else: if self.lastHoverEvent is not None: acceptedItem = self.lastHoverEvent.clickItems().get(ev.button(), None) else: acceptedItem = None if acceptedItem is not None: ev.currentItem = acceptedItem try: acceptedItem.mouseClickEvent(ev) except: debug.printExc("Error sending click event:") else: for item in self.itemsNearEvent(ev): if not item.isVisible() or not item.isEnabled(): continue if hasattr(item, 'mouseClickEvent'): ev.currentItem = item try: item.mouseClickEvent(ev) except: debug.printExc("Error sending click event:") if ev.isAccepted(): if int(item.flags() & item.ItemIsFocusable) > 0: item.setFocus(QtCore.Qt.MouseFocusReason) break self.sigMouseClicked.emit(ev) return ev.isAccepted() def items(self, *args): #print 'args:', args items = QtGui.QGraphicsScene.items(self, *args) ## PyQt bug: items() returns a list of QGraphicsItem instances. If the item is subclassed from QGraphicsObject, ## then the object returned will be different than the actual item that was originally added to the scene items2 = list(map(self.translateGraphicsItem, items)) #if HAVE_SIP and isinstance(self, sip.wrapper): #items2 = [] #for i in items: #addr = sip.unwrapinstance(sip.cast(i, QtGui.QGraphicsItem)) #i2 = GraphicsScene._addressCache.get(addr, i) ##print i, "==>", i2 #items2.append(i2) #print 'items:', items return items2 def selectedItems(self, *args): items = QtGui.QGraphicsScene.selectedItems(self, *args) ## PyQt bug: items() returns a list of QGraphicsItem instances. If the item is subclassed from QGraphicsObject, ## then the object returned will be different than the actual item that was originally added to the scene #if HAVE_SIP and isinstance(self, sip.wrapper): #items2 = [] #for i in items: #addr = sip.unwrapinstance(sip.cast(i, QtGui.QGraphicsItem)) #i2 = GraphicsScene._addressCache.get(addr, i) ##print i, "==>", i2 #items2.append(i2) items2 = list(map(self.translateGraphicsItem, items)) #print 'items:', items return items2 def itemAt(self, *args): item = QtGui.QGraphicsScene.itemAt(self, *args) ## PyQt bug: items() returns a list of QGraphicsItem instances. If the item is subclassed from QGraphicsObject, ## then the object returned will be different than the actual item that was originally added to the scene #if HAVE_SIP and isinstance(self, sip.wrapper): #addr = sip.unwrapinstance(sip.cast(item, QtGui.QGraphicsItem)) #item = GraphicsScene._addressCache.get(addr, item) #return item return self.translateGraphicsItem(item) def itemsNearEvent(self, event, selMode=QtCore.Qt.IntersectsItemShape, sortOrder=QtCore.Qt.DescendingOrder, hoverable=False): """ Return an iterator that iterates first through the items that directly intersect point (in Z order) followed by any other items that are within the scene's click radius. """ #tr = self.getViewWidget(event.widget()).transform() view = self.views()[0] tr = view.viewportTransform() r = self._clickRadius rect = view.mapToScene(QtCore.QRect(0, 0, 2*r, 2*r)).boundingRect() seen = set() if hasattr(event, 'buttonDownScenePos'): point = event.buttonDownScenePos() else: point = event.scenePos() w = rect.width() h = rect.height() rgn = QtCore.QRectF(point.x()-w, point.y()-h, 2*w, 2*h) #self.searchRect.setRect(rgn) items = self.items(point, selMode, sortOrder, tr) ## remove items whose shape does not contain point (scene.items() apparently sucks at this) items2 = [] for item in items: if hoverable and not hasattr(item, 'hoverEvent'): continue shape = item.shape() # Note: default shape() returns boundingRect() if shape is None: continue if shape.contains(item.mapFromScene(point)): items2.append(item) ## Sort by descending Z-order (don't trust scene.itms() to do this either) ## use 'absolute' z value, which is the sum of all item/parent ZValues def absZValue(item): if item is None: return 0 return item.zValue() + absZValue(item.parentItem()) sortList(items2, lambda a,b: cmp(absZValue(b), absZValue(a))) return items2 #for item in items: ##seen.add(item) #shape = item.mapToScene(item.shape()) #if not shape.contains(point): #continue #yield item #for item in self.items(rgn, selMode, sortOrder, tr): ##if item not in seen: #yield item def getViewWidget(self): return self.views()[0] #def getViewWidget(self, widget): ### same pyqt bug -- mouseEvent.widget() doesn't give us the original python object. ### [[doesn't seem to work correctly]] #if HAVE_SIP and isinstance(self, sip.wrapper): #addr = sip.unwrapinstance(sip.cast(widget, QtGui.QWidget)) ##print "convert", widget, addr #for v in self.views(): #addr2 = sip.unwrapinstance(sip.cast(v, QtGui.QWidget)) ##print " check:", v, addr2 #if addr2 == addr: #return v #else: #return widget def addParentContextMenus(self, item, menu, event): """ Can be called by any item in the scene to expand its context menu to include parent context menus. Parents may implement getContextMenus to add new menus / actions to the existing menu. getContextMenus must accept 1 argument (the event that generated the original menu) and return a single QMenu or a list of QMenus. The final menu will look like: | Original Item 1 | Original Item 2 | ... | Original Item N | ------------------ | Parent Item 1 | Parent Item 2 | ... | Grandparent Item 1 | ... ============== ================================================== **Arguments:** item The item that initially created the context menu (This is probably the item making the call to this function) menu The context menu being shown by the item event The original event that triggered the menu to appear. ============== ================================================== """ menusToAdd = [] while item is not self: item = item.parentItem() if item is None: item = self if not hasattr(item, "getContextMenus"): continue subMenus = item.getContextMenus(event) or [] if isinstance(subMenus, list): ## so that some items (like FlowchartViewBox) can return multiple menus menusToAdd.extend(subMenus) else: menusToAdd.append(subMenus) if menusToAdd: menu.addSeparator() for m in menusToAdd: if isinstance(m, QtGui.QMenu): menu.addMenu(m) elif isinstance(m, QtGui.QAction): menu.addAction(m) else: raise Exception("Cannot add object %s (type=%s) to QMenu." % (str(m), str(type(m)))) return menu def getContextMenus(self, event): self.contextMenuItem = event.acceptedItem return self.contextMenu def showExportDialog(self): if self.exportDialog is None: from . import exportDialog self.exportDialog = exportDialog.ExportDialog(self) self.exportDialog.show(self.contextMenuItem) @staticmethod def translateGraphicsItem(item): ## for fixing pyqt bugs where the wrong item is returned if HAVE_SIP and isinstance(item, sip.wrapper): addr = sip.unwrapinstance(sip.cast(item, QtGui.QGraphicsItem)) item = GraphicsScene._addressCache.get(addr, item) return item @staticmethod def translateGraphicsItems(items): return list(map(GraphicsScene.translateGraphicsItem, items)) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/GraphicsScene/__init__.py000066400000000000000000000000351300727121400244650ustar00rootroot00000000000000from .GraphicsScene import * pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/GraphicsScene/exportDialog.py000066400000000000000000000123051300727121400253720ustar00rootroot00000000000000from ..Qt import QtCore, QtGui, USE_PYSIDE, USE_PYQT5 from .. import exporters as exporters from .. import functions as fn from ..graphicsItems.ViewBox import ViewBox from ..graphicsItems.PlotItem import PlotItem if USE_PYSIDE: from . import exportDialogTemplate_pyside as exportDialogTemplate elif USE_PYQT5: from . import exportDialogTemplate_pyqt5 as exportDialogTemplate else: from . import exportDialogTemplate_pyqt as exportDialogTemplate class ExportDialog(QtGui.QWidget): def __init__(self, scene): QtGui.QWidget.__init__(self) self.setVisible(False) self.setWindowTitle("Export") self.shown = False self.currentExporter = None self.scene = scene self.selectBox = QtGui.QGraphicsRectItem() self.selectBox.setPen(fn.mkPen('y', width=3, style=QtCore.Qt.DashLine)) self.selectBox.hide() self.scene.addItem(self.selectBox) self.ui = exportDialogTemplate.Ui_Form() self.ui.setupUi(self) self.ui.closeBtn.clicked.connect(self.close) self.ui.exportBtn.clicked.connect(self.exportClicked) self.ui.copyBtn.clicked.connect(self.copyClicked) self.ui.itemTree.currentItemChanged.connect(self.exportItemChanged) self.ui.formatList.currentItemChanged.connect(self.exportFormatChanged) def show(self, item=None): if item is not None: ## Select next exportable parent of the item originally clicked on while not isinstance(item, ViewBox) and not isinstance(item, PlotItem) and item is not None: item = item.parentItem() ## if this is a ViewBox inside a PlotItem, select the parent instead. if isinstance(item, ViewBox) and isinstance(item.parentItem(), PlotItem): item = item.parentItem() self.updateItemList(select=item) self.setVisible(True) self.activateWindow() self.raise_() self.selectBox.setVisible(True) if not self.shown: self.shown = True vcenter = self.scene.getViewWidget().geometry().center() self.setGeometry(vcenter.x()-self.width()/2, vcenter.y()-self.height()/2, self.width(), self.height()) def updateItemList(self, select=None): self.ui.itemTree.clear() si = QtGui.QTreeWidgetItem(["Entire Scene"]) si.gitem = self.scene self.ui.itemTree.addTopLevelItem(si) self.ui.itemTree.setCurrentItem(si) si.setExpanded(True) for child in self.scene.items(): if child.parentItem() is None: self.updateItemTree(child, si, select=select) def updateItemTree(self, item, treeItem, select=None): si = None if isinstance(item, ViewBox): si = QtGui.QTreeWidgetItem(['ViewBox']) elif isinstance(item, PlotItem): si = QtGui.QTreeWidgetItem(['Plot']) if si is not None: si.gitem = item treeItem.addChild(si) treeItem = si if si.gitem is select: self.ui.itemTree.setCurrentItem(si) for ch in item.childItems(): self.updateItemTree(ch, treeItem, select=select) def exportItemChanged(self, item, prev): if item is None: return if item.gitem is self.scene: newBounds = self.scene.views()[0].viewRect() else: newBounds = item.gitem.sceneBoundingRect() self.selectBox.setRect(newBounds) self.selectBox.show() self.updateFormatList() def updateFormatList(self): current = self.ui.formatList.currentItem() if current is not None: current = str(current.text()) self.ui.formatList.clear() self.exporterClasses = {} gotCurrent = False for exp in exporters.listExporters(): self.ui.formatList.addItem(exp.Name) self.exporterClasses[exp.Name] = exp if exp.Name == current: self.ui.formatList.setCurrentRow(self.ui.formatList.count()-1) gotCurrent = True if not gotCurrent: self.ui.formatList.setCurrentRow(0) def exportFormatChanged(self, item, prev): if item is None: self.currentExporter = None self.ui.paramTree.clear() return expClass = self.exporterClasses[str(item.text())] exp = expClass(item=self.ui.itemTree.currentItem().gitem) params = exp.parameters() if params is None: self.ui.paramTree.clear() else: self.ui.paramTree.setParameters(params) self.currentExporter = exp self.ui.copyBtn.setEnabled(exp.allowCopy) def exportClicked(self): self.selectBox.hide() self.currentExporter.export() def copyClicked(self): self.selectBox.hide() self.currentExporter.export(copy=True) def close(self): self.selectBox.setVisible(False) self.setVisible(False) def closeEvent(self, event): self.close() QtGui.QWidget.closeEvent(self, event) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/GraphicsScene/exportDialogTemplate.ui000066400000000000000000000047131300727121400270570ustar00rootroot00000000000000 Form 0 0 241 367 Export 0 Item to export: false 1 Export format Export Close false 1 Export options Copy ParameterTree QTreeWidget
..parametertree
 pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/GraphicsScene/exportDialogTemplate_pyqt.py000066400000000000000000000064271300727121400301530ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './pyqtgraph/GraphicsScene/exportDialogTemplate.ui' # # Created: Mon Dec 23 10:10:52 2013 # by: PyQt4 UI code generator 4.10 # # WARNING! All changes made in this file will be lost! from PyQt4 import QtCore, QtGui try: _fromUtf8 = QtCore.QString.fromUtf8 except AttributeError: def _fromUtf8(s): return s try: _encoding = QtGui.QApplication.UnicodeUTF8 def _translate(context, text, disambig): return QtGui.QApplication.translate(context, text, disambig, _encoding) except AttributeError: def _translate(context, text, disambig): return QtGui.QApplication.translate(context, text, disambig) class Ui_Form(object): def setupUi(self, Form): Form.setObjectName(_fromUtf8("Form")) Form.resize(241, 367) self.gridLayout = QtGui.QGridLayout(Form) self.gridLayout.setSpacing(0) self.gridLayout.setObjectName(_fromUtf8("gridLayout")) self.label = QtGui.QLabel(Form) self.label.setObjectName(_fromUtf8("label")) self.gridLayout.addWidget(self.label, 0, 0, 1, 3) self.itemTree = QtGui.QTreeWidget(Form) self.itemTree.setObjectName(_fromUtf8("itemTree")) self.itemTree.headerItem().setText(0, _fromUtf8("1")) self.itemTree.header().setVisible(False) self.gridLayout.addWidget(self.itemTree, 1, 0, 1, 3) self.label_2 = QtGui.QLabel(Form) self.label_2.setObjectName(_fromUtf8("label_2")) self.gridLayout.addWidget(self.label_2, 2, 0, 1, 3) self.formatList = QtGui.QListWidget(Form) self.formatList.setObjectName(_fromUtf8("formatList")) self.gridLayout.addWidget(self.formatList, 3, 0, 1, 3) self.exportBtn = QtGui.QPushButton(Form) self.exportBtn.setObjectName(_fromUtf8("exportBtn")) self.gridLayout.addWidget(self.exportBtn, 6, 1, 1, 1) self.closeBtn = QtGui.QPushButton(Form) self.closeBtn.setObjectName(_fromUtf8("closeBtn")) self.gridLayout.addWidget(self.closeBtn, 6, 2, 1, 1) self.paramTree = ParameterTree(Form) self.paramTree.setObjectName(_fromUtf8("paramTree")) self.paramTree.headerItem().setText(0, _fromUtf8("1")) self.paramTree.header().setVisible(False) self.gridLayout.addWidget(self.paramTree, 5, 0, 1, 3) self.label_3 = QtGui.QLabel(Form) self.label_3.setObjectName(_fromUtf8("label_3")) self.gridLayout.addWidget(self.label_3, 4, 0, 1, 3) self.copyBtn = QtGui.QPushButton(Form) self.copyBtn.setObjectName(_fromUtf8("copyBtn")) self.gridLayout.addWidget(self.copyBtn, 6, 0, 1, 1) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): Form.setWindowTitle(_translate("Form", "Export", None)) self.label.setText(_translate("Form", "Item to export:", None)) self.label_2.setText(_translate("Form", "Export format", None)) self.exportBtn.setText(_translate("Form", "Export", None)) self.closeBtn.setText(_translate("Form", "Close", None)) self.label_3.setText(_translate("Form", "Export options", None)) self.copyBtn.setText(_translate("Form", "Copy", None)) from ..parametertree import ParameterTree pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/GraphicsScene/exportDialogTemplate_pyqt5.py000066400000000000000000000054361300727121400302370ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './pyqtgraph/GraphicsScene/exportDialogTemplate.ui' # # Created: Wed Mar 26 15:09:29 2014 # by: PyQt5 UI code generator 5.0.1 # # WARNING! All changes made in this file will be lost! from PyQt5 import QtCore, QtGui, QtWidgets class Ui_Form(object): def setupUi(self, Form): Form.setObjectName("Form") Form.resize(241, 367) self.gridLayout = QtWidgets.QGridLayout(Form) self.gridLayout.setSpacing(0) self.gridLayout.setObjectName("gridLayout") self.label = QtWidgets.QLabel(Form) self.label.setObjectName("label") self.gridLayout.addWidget(self.label, 0, 0, 1, 3) self.itemTree = QtWidgets.QTreeWidget(Form) self.itemTree.setObjectName("itemTree") self.itemTree.headerItem().setText(0, "1") self.itemTree.header().setVisible(False) self.gridLayout.addWidget(self.itemTree, 1, 0, 1, 3) self.label_2 = QtWidgets.QLabel(Form) self.label_2.setObjectName("label_2") self.gridLayout.addWidget(self.label_2, 2, 0, 1, 3) self.formatList = QtWidgets.QListWidget(Form) self.formatList.setObjectName("formatList") self.gridLayout.addWidget(self.formatList, 3, 0, 1, 3) self.exportBtn = QtWidgets.QPushButton(Form) self.exportBtn.setObjectName("exportBtn") self.gridLayout.addWidget(self.exportBtn, 6, 1, 1, 1) self.closeBtn = QtWidgets.QPushButton(Form) self.closeBtn.setObjectName("closeBtn") self.gridLayout.addWidget(self.closeBtn, 6, 2, 1, 1) self.paramTree = ParameterTree(Form) self.paramTree.setObjectName("paramTree") self.paramTree.headerItem().setText(0, "1") self.paramTree.header().setVisible(False) self.gridLayout.addWidget(self.paramTree, 5, 0, 1, 3) self.label_3 = QtWidgets.QLabel(Form) self.label_3.setObjectName("label_3") self.gridLayout.addWidget(self.label_3, 4, 0, 1, 3) self.copyBtn = QtWidgets.QPushButton(Form) self.copyBtn.setObjectName("copyBtn") self.gridLayout.addWidget(self.copyBtn, 6, 0, 1, 1) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): _translate = QtCore.QCoreApplication.translate Form.setWindowTitle(_translate("Form", "Export")) self.label.setText(_translate("Form", "Item to export:")) self.label_2.setText(_translate("Form", "Export format")) self.exportBtn.setText(_translate("Form", "Export")) self.closeBtn.setText(_translate("Form", "Close")) self.label_3.setText(_translate("Form", "Export options")) self.copyBtn.setText(_translate("Form", "Copy")) from ..parametertree import ParameterTree pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/GraphicsScene/exportDialogTemplate_pyside.py000066400000000000000000000061151300727121400304450ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './pyqtgraph/GraphicsScene/exportDialogTemplate.ui' # # Created: Mon Dec 23 10:10:53 2013 # by: pyside-uic 0.2.14 running on PySide 1.1.2 # # WARNING! All changes made in this file will be lost! from PySide import QtCore, QtGui class Ui_Form(object): def setupUi(self, Form): Form.setObjectName("Form") Form.resize(241, 367) self.gridLayout = QtGui.QGridLayout(Form) self.gridLayout.setSpacing(0) self.gridLayout.setObjectName("gridLayout") self.label = QtGui.QLabel(Form) self.label.setObjectName("label") self.gridLayout.addWidget(self.label, 0, 0, 1, 3) self.itemTree = QtGui.QTreeWidget(Form) self.itemTree.setObjectName("itemTree") self.itemTree.headerItem().setText(0, "1") self.itemTree.header().setVisible(False) self.gridLayout.addWidget(self.itemTree, 1, 0, 1, 3) self.label_2 = QtGui.QLabel(Form) self.label_2.setObjectName("label_2") self.gridLayout.addWidget(self.label_2, 2, 0, 1, 3) self.formatList = QtGui.QListWidget(Form) self.formatList.setObjectName("formatList") self.gridLayout.addWidget(self.formatList, 3, 0, 1, 3) self.exportBtn = QtGui.QPushButton(Form) self.exportBtn.setObjectName("exportBtn") self.gridLayout.addWidget(self.exportBtn, 6, 1, 1, 1) self.closeBtn = QtGui.QPushButton(Form) self.closeBtn.setObjectName("closeBtn") self.gridLayout.addWidget(self.closeBtn, 6, 2, 1, 1) self.paramTree = ParameterTree(Form) self.paramTree.setObjectName("paramTree") self.paramTree.headerItem().setText(0, "1") self.paramTree.header().setVisible(False) self.gridLayout.addWidget(self.paramTree, 5, 0, 1, 3) self.label_3 = QtGui.QLabel(Form) self.label_3.setObjectName("label_3") self.gridLayout.addWidget(self.label_3, 4, 0, 1, 3) self.copyBtn = QtGui.QPushButton(Form) self.copyBtn.setObjectName("copyBtn") self.gridLayout.addWidget(self.copyBtn, 6, 0, 1, 1) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): Form.setWindowTitle(QtGui.QApplication.translate("Form", "Export", None, QtGui.QApplication.UnicodeUTF8)) self.label.setText(QtGui.QApplication.translate("Form", "Item to export:", None, QtGui.QApplication.UnicodeUTF8)) self.label_2.setText(QtGui.QApplication.translate("Form", "Export format", None, QtGui.QApplication.UnicodeUTF8)) self.exportBtn.setText(QtGui.QApplication.translate("Form", "Export", None, QtGui.QApplication.UnicodeUTF8)) self.closeBtn.setText(QtGui.QApplication.translate("Form", "Close", None, QtGui.QApplication.UnicodeUTF8)) self.label_3.setText(QtGui.QApplication.translate("Form", "Export options", None, QtGui.QApplication.UnicodeUTF8)) self.copyBtn.setText(QtGui.QApplication.translate("Form", "Copy", None, QtGui.QApplication.UnicodeUTF8)) from ..parametertree import ParameterTree pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/GraphicsScene/mouseEvents.py000066400000000000000000000335601300727121400252540ustar00rootroot00000000000000from ..Point import Point from ..Qt import QtCore, QtGui import weakref from .. import ptime as ptime class MouseDragEvent(object): """ Instances of this class are delivered to items in a :class:`GraphicsScene ` via their mouseDragEvent() method when the item is being mouse-dragged. """ def __init__(self, moveEvent, pressEvent, lastEvent, start=False, finish=False): self.start = start self.finish = finish self.accepted = False self.currentItem = None self._buttonDownScenePos = {} self._buttonDownScreenPos = {} for btn in [QtCore.Qt.LeftButton, QtCore.Qt.MidButton, QtCore.Qt.RightButton]: self._buttonDownScenePos[int(btn)] = moveEvent.buttonDownScenePos(btn) self._buttonDownScreenPos[int(btn)] = moveEvent.buttonDownScreenPos(btn) self._scenePos = moveEvent.scenePos() self._screenPos = moveEvent.screenPos() if lastEvent is None: self._lastScenePos = pressEvent.scenePos() self._lastScreenPos = pressEvent.screenPos() else: self._lastScenePos = lastEvent.scenePos() self._lastScreenPos = lastEvent.screenPos() self._buttons = moveEvent.buttons() self._button = pressEvent.button() self._modifiers = moveEvent.modifiers() self.acceptedItem = None def accept(self): """An item should call this method if it can handle the event. This will prevent the event being delivered to any other items.""" self.accepted = True self.acceptedItem = self.currentItem def ignore(self): """An item should call this method if it cannot handle the event. This will allow the event to be delivered to other items.""" self.accepted = False def isAccepted(self): return self.accepted def scenePos(self): """Return the current scene position of the mouse.""" return Point(self._scenePos) def screenPos(self): """Return the current screen position (pixels relative to widget) of the mouse.""" return Point(self._screenPos) def buttonDownScenePos(self, btn=None): """ Return the scene position of the mouse at the time *btn* was pressed. If *btn* is omitted, then the button that initiated the drag is assumed. """ if btn is None: btn = self.button() return Point(self._buttonDownScenePos[int(btn)]) def buttonDownScreenPos(self, btn=None): """ Return the screen position (pixels relative to widget) of the mouse at the time *btn* was pressed. If *btn* is omitted, then the button that initiated the drag is assumed. """ if btn is None: btn = self.button() return Point(self._buttonDownScreenPos[int(btn)]) def lastScenePos(self): """ Return the scene position of the mouse immediately prior to this event. """ return Point(self._lastScenePos) def lastScreenPos(self): """ Return the screen position of the mouse immediately prior to this event. """ return Point(self._lastScreenPos) def buttons(self): """ Return the buttons currently pressed on the mouse. (see QGraphicsSceneMouseEvent::buttons in the Qt documentation) """ return self._buttons def button(self): """Return the button that initiated the drag (may be different from the buttons currently pressed) (see QGraphicsSceneMouseEvent::button in the Qt documentation) """ return self._button def pos(self): """ Return the current position of the mouse in the coordinate system of the item that the event was delivered to. """ return Point(self.currentItem.mapFromScene(self._scenePos)) def lastPos(self): """ Return the previous position of the mouse in the coordinate system of the item that the event was delivered to. """ return Point(self.currentItem.mapFromScene(self._lastScenePos)) def buttonDownPos(self, btn=None): """ Return the position of the mouse at the time the drag was initiated in the coordinate system of the item that the event was delivered to. """ if btn is None: btn = self.button() return Point(self.currentItem.mapFromScene(self._buttonDownScenePos[int(btn)])) def isStart(self): """Returns True if this event is the first since a drag was initiated.""" return self.start def isFinish(self): """Returns False if this is the last event in a drag. Note that this event will have the same position as the previous one.""" return self.finish def __repr__(self): if self.currentItem is None: lp = self._lastScenePos p = self._scenePos else: lp = self.lastPos() p = self.pos() return "(%g,%g) buttons=%d start=%s finish=%s>" % (lp.x(), lp.y(), p.x(), p.y(), int(self.buttons()), str(self.isStart()), str(self.isFinish())) def modifiers(self): """Return any keyboard modifiers currently pressed. (see QGraphicsSceneMouseEvent::modifiers in the Qt documentation) """ return self._modifiers class MouseClickEvent(object): """ Instances of this class are delivered to items in a :class:`GraphicsScene ` via their mouseClickEvent() method when the item is clicked. """ def __init__(self, pressEvent, double=False): self.accepted = False self.currentItem = None self._double = double self._scenePos = pressEvent.scenePos() self._screenPos = pressEvent.screenPos() self._button = pressEvent.button() self._buttons = pressEvent.buttons() self._modifiers = pressEvent.modifiers() self._time = ptime.time() self.acceptedItem = None def accept(self): """An item should call this method if it can handle the event. This will prevent the event being delivered to any other items.""" self.accepted = True self.acceptedItem = self.currentItem def ignore(self): """An item should call this method if it cannot handle the event. This will allow the event to be delivered to other items.""" self.accepted = False def isAccepted(self): return self.accepted def scenePos(self): """Return the current scene position of the mouse.""" return Point(self._scenePos) def screenPos(self): """Return the current screen position (pixels relative to widget) of the mouse.""" return Point(self._screenPos) def buttons(self): """ Return the buttons currently pressed on the mouse. (see QGraphicsSceneMouseEvent::buttons in the Qt documentation) """ return self._buttons def button(self): """Return the mouse button that generated the click event. (see QGraphicsSceneMouseEvent::button in the Qt documentation) """ return self._button def double(self): """Return True if this is a double-click.""" return self._double def pos(self): """ Return the current position of the mouse in the coordinate system of the item that the event was delivered to. """ return Point(self.currentItem.mapFromScene(self._scenePos)) def lastPos(self): """ Return the previous position of the mouse in the coordinate system of the item that the event was delivered to. """ return Point(self.currentItem.mapFromScene(self._lastScenePos)) def modifiers(self): """Return any keyboard modifiers currently pressed. (see QGraphicsSceneMouseEvent::modifiers in the Qt documentation) """ return self._modifiers def __repr__(self): try: if self.currentItem is None: p = self._scenePos else: p = self.pos() return "" % (p.x(), p.y(), int(self.button())) except: return "" % (int(self.button())) def time(self): return self._time class HoverEvent(object): """ Instances of this class are delivered to items in a :class:`GraphicsScene ` via their hoverEvent() method when the mouse is hovering over the item. This event class both informs items that the mouse cursor is nearby and allows items to communicate with one another about whether each item will accept *potential* mouse events. It is common for multiple overlapping items to receive hover events and respond by changing their appearance. This can be misleading to the user since, in general, only one item will respond to mouse events. To avoid this, items make calls to event.acceptClicks(button) and/or acceptDrags(button). Each item may make multiple calls to acceptClicks/Drags, each time for a different button. If the method returns True, then the item is guaranteed to be the recipient of the claimed event IF the user presses the specified mouse button before moving. If claimEvent returns False, then this item is guaranteed NOT to get the specified event (because another has already claimed it) and the item should change its appearance accordingly. event.isEnter() returns True if the mouse has just entered the item's shape; event.isExit() returns True if the mouse has just left. """ def __init__(self, moveEvent, acceptable): self.enter = False self.acceptable = acceptable self.exit = False self.__clickItems = weakref.WeakValueDictionary() self.__dragItems = weakref.WeakValueDictionary() self.currentItem = None if moveEvent is not None: self._scenePos = moveEvent.scenePos() self._screenPos = moveEvent.screenPos() self._lastScenePos = moveEvent.lastScenePos() self._lastScreenPos = moveEvent.lastScreenPos() self._buttons = moveEvent.buttons() self._modifiers = moveEvent.modifiers() else: self.exit = True def isEnter(self): """Returns True if the mouse has just entered the item's shape""" return self.enter def isExit(self): """Returns True if the mouse has just exited the item's shape""" return self.exit def acceptClicks(self, button): """Inform the scene that the item (that the event was delivered to) would accept a mouse click event if the user were to click before moving the mouse again. Returns True if the request is successful, otherwise returns False (indicating that some other item would receive an incoming click). """ if not self.acceptable: return False if button not in self.__clickItems: self.__clickItems[button] = self.currentItem return True return False def acceptDrags(self, button): """Inform the scene that the item (that the event was delivered to) would accept a mouse drag event if the user were to drag before the next hover event. Returns True if the request is successful, otherwise returns False (indicating that some other item would receive an incoming drag event). """ if not self.acceptable: return False if button not in self.__dragItems: self.__dragItems[button] = self.currentItem return True return False def scenePos(self): """Return the current scene position of the mouse.""" return Point(self._scenePos) def screenPos(self): """Return the current screen position of the mouse.""" return Point(self._screenPos) def lastScenePos(self): """Return the previous scene position of the mouse.""" return Point(self._lastScenePos) def lastScreenPos(self): """Return the previous screen position of the mouse.""" return Point(self._lastScreenPos) def buttons(self): """ Return the buttons currently pressed on the mouse. (see QGraphicsSceneMouseEvent::buttons in the Qt documentation) """ return self._buttons def pos(self): """ Return the current position of the mouse in the coordinate system of the item that the event was delivered to. """ return Point(self.currentItem.mapFromScene(self._scenePos)) def lastPos(self): """ Return the previous position of the mouse in the coordinate system of the item that the event was delivered to. """ return Point(self.currentItem.mapFromScene(self._lastScenePos)) def __repr__(self): if self.exit: return "" if self.currentItem is None: lp = self._lastScenePos p = self._scenePos else: lp = self.lastPos() p = self.pos() return "(%g,%g) buttons=%d enter=%s exit=%s>" % (lp.x(), lp.y(), p.x(), p.y(), int(self.buttons()), str(self.isEnter()), str(self.isExit())) def modifiers(self): """Return any keyboard modifiers currently pressed. (see QGraphicsSceneMouseEvent::modifiers in the Qt documentation) """ return self._modifiers def clickItems(self): return self.__clickItems def dragItems(self): return self.__dragItems pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/PlotData.py000066400000000000000000000030441300727121400217230ustar00rootroot00000000000000 class PlotData(object): """ Class used for managing plot data - allows data sharing between multiple graphics items (curve, scatter, graph..) - each item may define the columns it needs - column groupings ('pos' or x, y, z) - efficiently appendable - log, fft transformations - color mode conversion (float/byte/qcolor) - pen/brush conversion - per-field cached masking - allows multiple masking fields (different graphics need to mask on different criteria) - removal of nan/inf values - option for single value shared by entire column - cached downsampling - cached min / max / hasnan / isuniform """ def __init__(self): self.fields = {} self.maxVals = {} ## cache for max/min self.minVals = {} def addFields(self, **fields): for f in fields: if f not in self.fields: self.fields[f] = None def hasField(self, f): return f in self.fields def __getitem__(self, field): return self.fields[field] def __setitem__(self, field, val): self.fields[field] = val def max(self, field): mx = self.maxVals.get(field, None) if mx is None: mx = np.max(self[field]) self.maxVals[field] = mx return mx def min(self, field): mn = self.minVals.get(field, None) if mn is None: mn = np.min(self[field]) self.minVals[field] = mn return mn pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/Point.py000066400000000000000000000105221300727121400213030ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Point.py - Extension of QPointF which adds a few missing methods. Copyright 2010 Luke Campagnola Distributed under MIT/X11 license. See license.txt for more infomation. """ from .Qt import QtCore import numpy as np def clip(x, mn, mx): if x > mx: return mx if x < mn: return mn return x class Point(QtCore.QPointF): """Extension of QPointF which adds a few missing methods.""" def __init__(self, *args): if len(args) == 1: if isinstance(args[0], QtCore.QSizeF): QtCore.QPointF.__init__(self, float(args[0].width()), float(args[0].height())) return elif isinstance(args[0], float) or isinstance(args[0], int): QtCore.QPointF.__init__(self, float(args[0]), float(args[0])) return elif hasattr(args[0], '__getitem__'): QtCore.QPointF.__init__(self, float(args[0][0]), float(args[0][1])) return elif len(args) == 2: QtCore.QPointF.__init__(self, args[0], args[1]) return QtCore.QPointF.__init__(self, *args) def __len__(self): return 2 def __reduce__(self): return (Point, (self.x(), self.y())) def __getitem__(self, i): if i == 0: return self.x() elif i == 1: return self.y() else: raise IndexError("Point has no index %s" % str(i)) def __setitem__(self, i, x): if i == 0: return self.setX(x) elif i == 1: return self.setY(x) else: raise IndexError("Point has no index %s" % str(i)) def __radd__(self, a): return self._math_('__radd__', a) def __add__(self, a): return self._math_('__add__', a) def __rsub__(self, a): return self._math_('__rsub__', a) def __sub__(self, a): return self._math_('__sub__', a) def __rmul__(self, a): return self._math_('__rmul__', a) def __mul__(self, a): return self._math_('__mul__', a) def __rdiv__(self, a): return self._math_('__rdiv__', a) def __div__(self, a): return self._math_('__div__', a) def __truediv__(self, a): return self._math_('__truediv__', a) def __rtruediv__(self, a): return self._math_('__rtruediv__', a) def __rpow__(self, a): return self._math_('__rpow__', a) def __pow__(self, a): return self._math_('__pow__', a) def _math_(self, op, x): #print "point math:", op #try: #fn = getattr(QtCore.QPointF, op) #pt = fn(self, x) #print fn, pt, self, x #return Point(pt) #except AttributeError: x = Point(x) return Point(getattr(self[0], op)(x[0]), getattr(self[1], op)(x[1])) def length(self): """Returns the vector length of this Point.""" return (self[0]**2 + self[1]**2) ** 0.5 def norm(self): """Returns a vector in the same direction with unit length.""" return self / self.length() def angle(self, a): """Returns the angle in degrees between this vector and the vector a.""" n1 = self.length() n2 = a.length() if n1 == 0. or n2 == 0.: return None ## Probably this should be done with arctan2 instead.. ang = np.arccos(clip(self.dot(a) / (n1 * n2), -1.0, 1.0)) ### in radians c = self.cross(a) if c > 0: ang *= -1. return ang * 180. / np.pi def dot(self, a): """Returns the dot product of a and this Point.""" a = Point(a) return self[0]*a[0] + self[1]*a[1] def cross(self, a): a = Point(a) return self[0]*a[1] - self[1]*a[0] def proj(self, b): """Return the projection of this vector onto the vector b""" b1 = b / b.length() return self.dot(b1) * b1 def __repr__(self): return "Point(%f, %f)" % (self[0], self[1]) def min(self): return min(self[0], self[1]) def max(self): return max(self[0], self[1]) def copy(self): return Point(self) def toQPoint(self): return QtCore.QPoint(*self) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/Qt.py000066400000000000000000000161651300727121400206070ustar00rootroot00000000000000""" This module exists to smooth out some of the differences between PySide and PyQt4: * Automatically import either PyQt4 or PySide depending on availability * Allow to import QtCore/QtGui pyqtgraph.Qt without specifying which Qt wrapper you want to use. * Declare QtCore.Signal, .Slot in PyQt4 * Declare loadUiType function for Pyside """ import os, sys, re, time from .python2_3 import asUnicode PYSIDE = 'PySide' PYQT4 = 'PyQt4' PYQT5 = 'PyQt5' QT_LIB = os.getenv('PYQTGRAPH_QT_LIB') ## Automatically determine whether to use PyQt or PySide (unless specified by ## environment variable). ## This is done by first checking to see whether one of the libraries ## is already imported. If not, then attempt to import PyQt4, then PySide. if QT_LIB is None: libOrder = [PYQT4, PYSIDE, PYQT5] for lib in libOrder: if lib in sys.modules: QT_LIB = lib break if QT_LIB is None: for lib in libOrder: try: __import__(lib) QT_LIB = lib break except ImportError: pass if QT_LIB is None: raise Exception("PyQtGraph requires one of PyQt4, PyQt5 or PySide; none of these packages could be imported.") if QT_LIB == PYSIDE: from PySide import QtGui, QtCore, QtOpenGL, QtSvg try: from PySide import QtTest if not hasattr(QtTest.QTest, 'qWait'): @staticmethod def qWait(msec): start = time.time() QtGui.QApplication.processEvents() while time.time() < start + msec * 0.001: QtGui.QApplication.processEvents() QtTest.QTest.qWait = qWait except ImportError: pass import PySide try: from PySide import shiboken isQObjectAlive = shiboken.isValid except ImportError: def isQObjectAlive(obj): try: if hasattr(obj, 'parent'): obj.parent() elif hasattr(obj, 'parentItem'): obj.parentItem() else: raise Exception("Cannot determine whether Qt object %s is still alive." % obj) except RuntimeError: return False else: return True VERSION_INFO = 'PySide ' + PySide.__version__ # Make a loadUiType function like PyQt has # Credit: # http://stackoverflow.com/questions/4442286/python-code-genration-with-pyside-uic/14195313#14195313 class StringIO(object): """Alternative to built-in StringIO needed to circumvent unicode/ascii issues""" def __init__(self): self.data = [] def write(self, data): self.data.append(data) def getvalue(self): return ''.join(map(asUnicode, self.data)).encode('utf8') def loadUiType(uiFile): """ Pyside "loadUiType" command like PyQt4 has one, so we have to convert the ui file to py code in-memory first and then execute it in a special frame to retrieve the form_class. from stackoverflow: http://stackoverflow.com/a/14195313/3781327 seems like this might also be a legitimate solution, but I'm not sure how to make PyQt4 and pyside look the same... http://stackoverflow.com/a/8717832 """ import pysideuic import xml.etree.ElementTree as xml #from io import StringIO parsed = xml.parse(uiFile) widget_class = parsed.find('widget').get('class') form_class = parsed.find('class').text with open(uiFile, 'r') as f: o = StringIO() frame = {} pysideuic.compileUi(f, o, indent=0) pyc = compile(o.getvalue(), '', 'exec') exec(pyc, frame) #Fetch the base_class and form class based on their type in the xml from designer form_class = frame['Ui_%s'%form_class] base_class = eval('QtGui.%s'%widget_class) return form_class, base_class elif QT_LIB == PYQT4: from PyQt4 import QtGui, QtCore, uic try: from PyQt4 import QtSvg except ImportError: pass try: from PyQt4 import QtOpenGL except ImportError: pass try: from PyQt4 import QtTest except ImportError: pass VERSION_INFO = 'PyQt4 ' + QtCore.PYQT_VERSION_STR + ' Qt ' + QtCore.QT_VERSION_STR elif QT_LIB == PYQT5: # We're using PyQt5 which has a different structure so we're going to use a shim to # recreate the Qt4 structure for Qt5 from PyQt5 import QtGui, QtCore, QtWidgets, uic try: from PyQt5 import QtSvg except ImportError: pass try: from PyQt5 import QtOpenGL except ImportError: pass try: from PyQt5 import QtTest QtTest.QTest.qWaitForWindowShown = QtTest.QTest.qWaitForWindowExposed except ImportError: pass # Re-implement deprecated APIs __QGraphicsItem_scale = QtWidgets.QGraphicsItem.scale def scale(self, *args): if args: sx, sy = args tr = self.transform() tr.scale(sx, sy) self.setTransform(tr) else: return __QGraphicsItem_scale(self) QtWidgets.QGraphicsItem.scale = scale def rotate(self, angle): tr = self.transform() tr.rotate(angle) self.setTransform(tr) QtWidgets.QGraphicsItem.rotate = rotate def translate(self, dx, dy): tr = self.transform() tr.translate(dx, dy) self.setTransform(tr) QtWidgets.QGraphicsItem.translate = translate def setMargin(self, i): self.setContentsMargins(i, i, i, i) QtWidgets.QGridLayout.setMargin = setMargin def setResizeMode(self, *args): self.setSectionResizeMode(*args) QtWidgets.QHeaderView.setResizeMode = setResizeMode QtGui.QApplication = QtWidgets.QApplication QtGui.QGraphicsScene = QtWidgets.QGraphicsScene QtGui.QGraphicsObject = QtWidgets.QGraphicsObject QtGui.QGraphicsWidget = QtWidgets.QGraphicsWidget QtGui.QApplication.setGraphicsSystem = None # Import all QtWidgets objects into QtGui for o in dir(QtWidgets): if o.startswith('Q'): setattr(QtGui, o, getattr(QtWidgets,o) ) VERSION_INFO = 'PyQt5 ' + QtCore.PYQT_VERSION_STR + ' Qt ' + QtCore.QT_VERSION_STR else: raise ValueError("Invalid Qt lib '%s'" % QT_LIB) # Common to PyQt4 and 5 if QT_LIB.startswith('PyQt'): import sip def isQObjectAlive(obj): return not sip.isdeleted(obj) loadUiType = uic.loadUiType QtCore.Signal = QtCore.pyqtSignal ## Make sure we have Qt >= 4.7 versionReq = [4, 7] USE_PYSIDE = QT_LIB == PYSIDE USE_PYQT4 = QT_LIB == PYQT4 USE_PYQT5 = QT_LIB == PYQT5 QtVersion = PySide.QtCore.__version__ if QT_LIB == PYSIDE else QtCore.QT_VERSION_STR m = re.match(r'(\d+)\.(\d+).*', QtVersion) if m is not None and list(map(int, m.groups())) < versionReq: print(list(map(int, m.groups()))) raise Exception('pyqtgraph requires Qt version >= %d.%d (your version is %s)' % (versionReq[0], versionReq[1], QtVersion)) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/SRTTransform.py000066400000000000000000000174301300727121400225630ustar00rootroot00000000000000# -*- coding: utf-8 -*- from .Qt import QtCore, QtGui from .Point import Point import numpy as np class SRTTransform(QtGui.QTransform): """Transform that can always be represented as a combination of 3 matrices: scale * rotate * translate This transform has no shear; angles are always preserved. """ def __init__(self, init=None): QtGui.QTransform.__init__(self) self.reset() if init is None: return elif isinstance(init, dict): self.restoreState(init) elif isinstance(init, SRTTransform): self._state = { 'pos': Point(init._state['pos']), 'scale': Point(init._state['scale']), 'angle': init._state['angle'] } self.update() elif isinstance(init, QtGui.QTransform): self.setFromQTransform(init) elif isinstance(init, QtGui.QMatrix4x4): self.setFromMatrix4x4(init) else: raise Exception("Cannot create SRTTransform from input type: %s" % str(type(init))) def getScale(self): return self._state['scale'] def getAngle(self): ## deprecated; for backward compatibility return self.getRotation() def getRotation(self): return self._state['angle'] def getTranslation(self): return self._state['pos'] def reset(self): self._state = { 'pos': Point(0,0), 'scale': Point(1,1), 'angle': 0.0 ## in degrees } self.update() def setFromQTransform(self, tr): p1 = Point(tr.map(0., 0.)) p2 = Point(tr.map(1., 0.)) p3 = Point(tr.map(0., 1.)) dp2 = Point(p2-p1) dp3 = Point(p3-p1) ## detect flipped axes if dp2.angle(dp3) > 0: #da = 180 da = 0 sy = -1.0 else: da = 0 sy = 1.0 self._state = { 'pos': Point(p1), 'scale': Point(dp2.length(), dp3.length() * sy), 'angle': (np.arctan2(dp2[1], dp2[0]) * 180. / np.pi) + da } self.update() def setFromMatrix4x4(self, m): m = SRTTransform3D(m) angle, axis = m.getRotation() if angle != 0 and (axis[0] != 0 or axis[1] != 0 or axis[2] != 1): print("angle: %s axis: %s" % (str(angle), str(axis))) raise Exception("Can only convert 4x4 matrix to 3x3 if rotation is around Z-axis.") self._state = { 'pos': Point(m.getTranslation()), 'scale': Point(m.getScale()), 'angle': angle } self.update() def translate(self, *args): """Acceptable arguments are: x, y [x, y] Point(x,y)""" t = Point(*args) self.setTranslate(self._state['pos']+t) def setTranslate(self, *args): """Acceptable arguments are: x, y [x, y] Point(x,y)""" self._state['pos'] = Point(*args) self.update() def scale(self, *args): """Acceptable arguments are: x, y [x, y] Point(x,y)""" s = Point(*args) self.setScale(self._state['scale'] * s) def setScale(self, *args): """Acceptable arguments are: x, y [x, y] Point(x,y)""" self._state['scale'] = Point(*args) self.update() def rotate(self, angle): """Rotate the transformation by angle (in degrees)""" self.setRotate(self._state['angle'] + angle) def setRotate(self, angle): """Set the transformation rotation to angle (in degrees)""" self._state['angle'] = angle self.update() def __truediv__(self, t): """A / B == B^-1 * A""" dt = t.inverted()[0] * self return SRTTransform(dt) def __div__(self, t): return self.__truediv__(t) def __mul__(self, t): return SRTTransform(QtGui.QTransform.__mul__(self, t)) def saveState(self): p = self._state['pos'] s = self._state['scale'] #if s[0] == 0: #raise Exception('Invalid scale: %s' % str(s)) return {'pos': (p[0], p[1]), 'scale': (s[0], s[1]), 'angle': self._state['angle']} def restoreState(self, state): self._state['pos'] = Point(state.get('pos', (0,0))) self._state['scale'] = Point(state.get('scale', (1.,1.))) self._state['angle'] = state.get('angle', 0) self.update() def update(self): QtGui.QTransform.reset(self) ## modifications to the transform are multiplied on the right, so we need to reverse order here. QtGui.QTransform.translate(self, *self._state['pos']) QtGui.QTransform.rotate(self, self._state['angle']) QtGui.QTransform.scale(self, *self._state['scale']) def __repr__(self): return str(self.saveState()) def matrix(self): return np.array([[self.m11(), self.m12(), self.m13()],[self.m21(), self.m22(), self.m23()],[self.m31(), self.m32(), self.m33()]]) if __name__ == '__main__': from . import widgets import GraphicsView from .functions import * app = QtGui.QApplication([]) win = QtGui.QMainWindow() win.show() cw = GraphicsView.GraphicsView() #cw.enableMouse() win.setCentralWidget(cw) s = QtGui.QGraphicsScene() cw.setScene(s) win.resize(600,600) cw.enableMouse() cw.setRange(QtCore.QRectF(-100., -100., 200., 200.)) class Item(QtGui.QGraphicsItem): def __init__(self): QtGui.QGraphicsItem.__init__(self) self.b = QtGui.QGraphicsRectItem(20, 20, 20, 20, self) self.b.setPen(QtGui.QPen(mkPen('y'))) self.t1 = QtGui.QGraphicsTextItem(self) self.t1.setHtml('R') self.t1.translate(20, 20) self.l1 = QtGui.QGraphicsLineItem(10, 0, -10, 0, self) self.l2 = QtGui.QGraphicsLineItem(0, 10, 0, -10, self) self.l1.setPen(QtGui.QPen(mkPen('y'))) self.l2.setPen(QtGui.QPen(mkPen('y'))) def boundingRect(self): return QtCore.QRectF() def paint(self, *args): pass #s.addItem(b) #s.addItem(t1) item = Item() s.addItem(item) l1 = QtGui.QGraphicsLineItem(10, 0, -10, 0) l2 = QtGui.QGraphicsLineItem(0, 10, 0, -10) l1.setPen(QtGui.QPen(mkPen('r'))) l2.setPen(QtGui.QPen(mkPen('r'))) s.addItem(l1) s.addItem(l2) tr1 = SRTTransform() tr2 = SRTTransform() tr3 = QtGui.QTransform() tr3.translate(20, 0) tr3.rotate(45) print("QTransform -> Transform:", SRTTransform(tr3)) print("tr1:", tr1) tr2.translate(20, 0) tr2.rotate(45) print("tr2:", tr2) dt = tr2/tr1 print("tr2 / tr1 = ", dt) print("tr2 * tr1 = ", tr2*tr1) tr4 = SRTTransform() tr4.scale(-1, 1) tr4.rotate(30) print("tr1 * tr4 = ", tr1*tr4) w1 = widgets.TestROI((19,19), (22, 22), invertible=True) #w2 = widgets.TestROI((0,0), (150, 150)) w1.setZValue(10) s.addItem(w1) #s.addItem(w2) w1Base = w1.getState() #w2Base = w2.getState() def update(): tr1 = w1.getGlobalTransform(w1Base) #tr2 = w2.getGlobalTransform(w2Base) item.setTransform(tr1) #def update2(): #tr1 = w1.getGlobalTransform(w1Base) #tr2 = w2.getGlobalTransform(w2Base) #t1.setTransform(tr1) #w1.setState(w1Base) #w1.applyGlobalTransform(tr2) w1.sigRegionChanged.connect(update) #w2.sigRegionChanged.connect(update2) from .SRTTransform3D import SRTTransform3D pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/SRTTransform3D.py000066400000000000000000000251771300727121400227610ustar00rootroot00000000000000# -*- coding: utf-8 -*- from .Qt import QtCore, QtGui from .Vector import Vector from .Transform3D import Transform3D from .Vector import Vector import numpy as np class SRTTransform3D(Transform3D): """4x4 Transform matrix that can always be represented as a combination of 3 matrices: scale * rotate * translate This transform has no shear; angles are always preserved. """ def __init__(self, init=None): Transform3D.__init__(self) self.reset() if init is None: return if init.__class__ is QtGui.QTransform: init = SRTTransform(init) if isinstance(init, dict): self.restoreState(init) elif isinstance(init, SRTTransform3D): self._state = { 'pos': Vector(init._state['pos']), 'scale': Vector(init._state['scale']), 'angle': init._state['angle'], 'axis': Vector(init._state['axis']), } self.update() elif isinstance(init, SRTTransform): self._state = { 'pos': Vector(init._state['pos']), 'scale': Vector(init._state['scale']), 'angle': init._state['angle'], 'axis': Vector(0, 0, 1), } self._state['scale'][2] = 1.0 self.update() elif isinstance(init, QtGui.QMatrix4x4): self.setFromMatrix(init) else: raise Exception("Cannot build SRTTransform3D from argument type:", type(init)) def getScale(self): return Vector(self._state['scale']) def getRotation(self): """Return (angle, axis) of rotation""" return self._state['angle'], Vector(self._state['axis']) def getTranslation(self): return Vector(self._state['pos']) def reset(self): self._state = { 'pos': Vector(0,0,0), 'scale': Vector(1,1,1), 'angle': 0.0, ## in degrees 'axis': (0, 0, 1) } self.update() def translate(self, *args): """Adjust the translation of this transform""" t = Vector(*args) self.setTranslate(self._state['pos']+t) def setTranslate(self, *args): """Set the translation of this transform""" self._state['pos'] = Vector(*args) self.update() def scale(self, *args): """adjust the scale of this transform""" ## try to prevent accidentally setting 0 scale on z axis if len(args) == 1 and hasattr(args[0], '__len__'): args = args[0] if len(args) == 2: args = args + (1,) s = Vector(*args) self.setScale(self._state['scale'] * s) def setScale(self, *args): """Set the scale of this transform""" if len(args) == 1 and hasattr(args[0], '__len__'): args = args[0] if len(args) == 2: args = args + (1,) self._state['scale'] = Vector(*args) self.update() def rotate(self, angle, axis=(0,0,1)): """Adjust the rotation of this transform""" origAxis = self._state['axis'] if axis[0] == origAxis[0] and axis[1] == origAxis[1] and axis[2] == origAxis[2]: self.setRotate(self._state['angle'] + angle) else: m = QtGui.QMatrix4x4() m.translate(*self._state['pos']) m.rotate(self._state['angle'], *self._state['axis']) m.rotate(angle, *axis) m.scale(*self._state['scale']) self.setFromMatrix(m) def setRotate(self, angle, axis=(0,0,1)): """Set the transformation rotation to angle (in degrees)""" self._state['angle'] = angle self._state['axis'] = Vector(axis) self.update() def setFromMatrix(self, m): """ Set this transform mased on the elements of *m* The input matrix must be affine AND have no shear, otherwise the conversion will most likely fail. """ import numpy.linalg for i in range(4): self.setRow(i, m.row(i)) m = self.matrix().reshape(4,4) ## translation is 4th column self._state['pos'] = m[:3,3] ## scale is vector-length of first three columns scale = (m[:3,:3]**2).sum(axis=0)**0.5 ## see whether there is an inversion z = np.cross(m[0, :3], m[1, :3]) if np.dot(z, m[2, :3]) < 0: scale[1] *= -1 ## doesn't really matter which axis we invert self._state['scale'] = scale ## rotation axis is the eigenvector with eigenvalue=1 r = m[:3, :3] / scale[np.newaxis, :] try: evals, evecs = numpy.linalg.eig(r) except: print("Rotation matrix: %s" % str(r)) print("Scale: %s" % str(scale)) print("Original matrix: %s" % str(m)) raise eigIndex = np.argwhere(np.abs(evals-1) < 1e-6) if len(eigIndex) < 1: print("eigenvalues: %s" % str(evals)) print("eigenvectors: %s" % str(evecs)) print("index: %s, %s" % (str(eigIndex), str(evals-1))) raise Exception("Could not determine rotation axis.") axis = evecs[:,eigIndex[0,0]].real axis /= ((axis**2).sum())**0.5 self._state['axis'] = axis ## trace(r) == 2 cos(angle) + 1, so: cos = (r.trace()-1)*0.5 ## this only gets us abs(angle) ## The off-diagonal values can be used to correct the angle ambiguity, ## but we need to figure out which element to use: axisInd = np.argmax(np.abs(axis)) rInd,sign = [((1,2), -1), ((0,2), 1), ((0,1), -1)][axisInd] ## Then we have r-r.T = sin(angle) * 2 * sign * axis[axisInd]; ## solve for sin(angle) sin = (r-r.T)[rInd] / (2. * sign * axis[axisInd]) ## finally, we get the complete angle from arctan(sin/cos) self._state['angle'] = np.arctan2(sin, cos) * 180 / np.pi if self._state['angle'] == 0: self._state['axis'] = (0,0,1) def as2D(self): """Return a QTransform representing the x,y portion of this transform (if possible)""" return SRTTransform(self) #def __div__(self, t): #"""A / B == B^-1 * A""" #dt = t.inverted()[0] * self #return SRTTransform(dt) #def __mul__(self, t): #return SRTTransform(QtGui.QTransform.__mul__(self, t)) def saveState(self): p = self._state['pos'] s = self._state['scale'] ax = self._state['axis'] #if s[0] == 0: #raise Exception('Invalid scale: %s' % str(s)) return { 'pos': (p[0], p[1], p[2]), 'scale': (s[0], s[1], s[2]), 'angle': self._state['angle'], 'axis': (ax[0], ax[1], ax[2]) } def restoreState(self, state): self._state['pos'] = Vector(state.get('pos', (0.,0.,0.))) scale = state.get('scale', (1.,1.,1.)) scale = tuple(scale) + (1.,) * (3-len(scale)) self._state['scale'] = Vector(scale) self._state['angle'] = state.get('angle', 0.) self._state['axis'] = state.get('axis', (0, 0, 1)) self.update() def update(self): Transform3D.setToIdentity(self) ## modifications to the transform are multiplied on the right, so we need to reverse order here. Transform3D.translate(self, *self._state['pos']) Transform3D.rotate(self, self._state['angle'], *self._state['axis']) Transform3D.scale(self, *self._state['scale']) def __repr__(self): return str(self.saveState()) def matrix(self, nd=3): if nd == 3: return np.array(self.copyDataTo()).reshape(4,4) elif nd == 2: m = np.array(self.copyDataTo()).reshape(4,4) m[2] = m[3] m[:,2] = m[:,3] return m[:3,:3] else: raise Exception("Argument 'nd' must be 2 or 3") if __name__ == '__main__': import widgets import GraphicsView from functions import * app = QtGui.QApplication([]) win = QtGui.QMainWindow() win.show() cw = GraphicsView.GraphicsView() #cw.enableMouse() win.setCentralWidget(cw) s = QtGui.QGraphicsScene() cw.setScene(s) win.resize(600,600) cw.enableMouse() cw.setRange(QtCore.QRectF(-100., -100., 200., 200.)) class Item(QtGui.QGraphicsItem): def __init__(self): QtGui.QGraphicsItem.__init__(self) self.b = QtGui.QGraphicsRectItem(20, 20, 20, 20, self) self.b.setPen(QtGui.QPen(mkPen('y'))) self.t1 = QtGui.QGraphicsTextItem(self) self.t1.setHtml('R') self.t1.translate(20, 20) self.l1 = QtGui.QGraphicsLineItem(10, 0, -10, 0, self) self.l2 = QtGui.QGraphicsLineItem(0, 10, 0, -10, self) self.l1.setPen(QtGui.QPen(mkPen('y'))) self.l2.setPen(QtGui.QPen(mkPen('y'))) def boundingRect(self): return QtCore.QRectF() def paint(self, *args): pass #s.addItem(b) #s.addItem(t1) item = Item() s.addItem(item) l1 = QtGui.QGraphicsLineItem(10, 0, -10, 0) l2 = QtGui.QGraphicsLineItem(0, 10, 0, -10) l1.setPen(QtGui.QPen(mkPen('r'))) l2.setPen(QtGui.QPen(mkPen('r'))) s.addItem(l1) s.addItem(l2) tr1 = SRTTransform() tr2 = SRTTransform() tr3 = QtGui.QTransform() tr3.translate(20, 0) tr3.rotate(45) print("QTransform -> Transform: %s" % str(SRTTransform(tr3))) print("tr1: %s" % str(tr1)) tr2.translate(20, 0) tr2.rotate(45) print("tr2: %s" % str(tr2)) dt = tr2/tr1 print("tr2 / tr1 = %s" % str(dt)) print("tr2 * tr1 = %s" % str(tr2*tr1)) tr4 = SRTTransform() tr4.scale(-1, 1) tr4.rotate(30) print("tr1 * tr4 = %s" % str(tr1*tr4)) w1 = widgets.TestROI((19,19), (22, 22), invertible=True) #w2 = widgets.TestROI((0,0), (150, 150)) w1.setZValue(10) s.addItem(w1) #s.addItem(w2) w1Base = w1.getState() #w2Base = w2.getState() def update(): tr1 = w1.getGlobalTransform(w1Base) #tr2 = w2.getGlobalTransform(w2Base) item.setTransform(tr1) #def update2(): #tr1 = w1.getGlobalTransform(w1Base) #tr2 = w2.getGlobalTransform(w2Base) #t1.setTransform(tr1) #w1.setState(w1Base) #w1.applyGlobalTransform(tr2) w1.sigRegionChanged.connect(update) #w2.sigRegionChanged.connect(update2) from .SRTTransform import SRTTransform pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/SignalProxy.py000066400000000000000000000074041300727121400224760ustar00rootroot00000000000000# -*- coding: utf-8 -*- from .Qt import QtCore from .ptime import time from . import ThreadsafeTimer import weakref __all__ = ['SignalProxy'] class SignalProxy(QtCore.QObject): """Object which collects rapid-fire signals and condenses them into a single signal or a rate-limited stream of signals. Used, for example, to prevent a SpinBox from generating multiple signals when the mouse wheel is rolled over it. Emits sigDelayed after input signals have stopped for a certain period of time. """ sigDelayed = QtCore.Signal(object) def __init__(self, signal, delay=0.3, rateLimit=0, slot=None): """Initialization arguments: signal - a bound Signal or pyqtSignal instance delay - Time (in seconds) to wait for signals to stop before emitting (default 0.3s) slot - Optional function to connect sigDelayed to. rateLimit - (signals/sec) if greater than 0, this allows signals to stream out at a steady rate while they are being received. """ QtCore.QObject.__init__(self) signal.connect(self.signalReceived) self.signal = signal self.delay = delay self.rateLimit = rateLimit self.args = None self.timer = ThreadsafeTimer.ThreadsafeTimer() self.timer.timeout.connect(self.flush) self.block = False self.slot = weakref.ref(slot) self.lastFlushTime = None if slot is not None: self.sigDelayed.connect(slot) def setDelay(self, delay): self.delay = delay def signalReceived(self, *args): """Received signal. Cancel previous timer and store args to be forwarded later.""" if self.block: return self.args = args if self.rateLimit == 0: self.timer.stop() self.timer.start((self.delay*1000)+1) else: now = time() if self.lastFlushTime is None: leakTime = 0 else: lastFlush = self.lastFlushTime leakTime = max(0, (lastFlush + (1.0 / self.rateLimit)) - now) self.timer.stop() self.timer.start((min(leakTime, self.delay)*1000)+1) def flush(self): """If there is a signal queued up, send it now.""" if self.args is None or self.block: return False #self.emit(self.signal, *self.args) self.sigDelayed.emit(self.args) self.args = None self.timer.stop() self.lastFlushTime = time() return True def disconnect(self): self.block = True try: self.signal.disconnect(self.signalReceived) except: pass try: self.sigDelayed.disconnect(self.slot()) except: pass #def proxyConnect(source, signal, slot, delay=0.3): #"""Connect a signal to a slot with delay. Returns the SignalProxy #object that was created. Be sure to store this object so it is not #garbage-collected immediately.""" #sp = SignalProxy(source, signal, delay) #if source is None: #sp.connect(sp, QtCore.SIGNAL('signal'), slot) #else: #sp.connect(sp, signal, slot) #return sp if __name__ == '__main__': from .Qt import QtGui app = QtGui.QApplication([]) win = QtGui.QMainWindow() spin = QtGui.QSpinBox() win.setCentralWidget(spin) win.show() def fn(*args): print("Raw signal:", args) def fn2(*args): print("Delayed signal:", args) spin.valueChanged.connect(fn) #proxy = proxyConnect(spin, QtCore.SIGNAL('valueChanged(int)'), fn) proxy = SignalProxy(spin.valueChanged, delay=0.5, slot=fn2) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/ThreadsafeTimer.py000066400000000000000000000030171300727121400232620ustar00rootroot00000000000000from .Qt import QtCore, QtGui class ThreadsafeTimer(QtCore.QObject): """ Thread-safe replacement for QTimer. """ timeout = QtCore.Signal() sigTimerStopRequested = QtCore.Signal() sigTimerStartRequested = QtCore.Signal(object) def __init__(self): QtCore.QObject.__init__(self) self.timer = QtCore.QTimer() self.timer.timeout.connect(self.timerFinished) self.timer.moveToThread(QtCore.QCoreApplication.instance().thread()) self.moveToThread(QtCore.QCoreApplication.instance().thread()) self.sigTimerStopRequested.connect(self.stop, QtCore.Qt.QueuedConnection) self.sigTimerStartRequested.connect(self.start, QtCore.Qt.QueuedConnection) def start(self, timeout): isGuiThread = QtCore.QThread.currentThread() == QtCore.QCoreApplication.instance().thread() if isGuiThread: #print "start timer", self, "from gui thread" self.timer.start(timeout) else: #print "start timer", self, "from remote thread" self.sigTimerStartRequested.emit(timeout) def stop(self): isGuiThread = QtCore.QThread.currentThread() == QtCore.QCoreApplication.instance().thread() if isGuiThread: #print "stop timer", self, "from gui thread" self.timer.stop() else: #print "stop timer", self, "from remote thread" self.sigTimerStopRequested.emit() def timerFinished(self): self.timeout.emit()pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/Transform3D.py000066400000000000000000000021231300727121400223520ustar00rootroot00000000000000# -*- coding: utf-8 -*- from .Qt import QtCore, QtGui from . import functions as fn import numpy as np class Transform3D(QtGui.QMatrix4x4): """ Extension of QMatrix4x4 with some helpful methods added. """ def __init__(self, *args): QtGui.QMatrix4x4.__init__(self, *args) def matrix(self, nd=3): if nd == 3: return np.array(self.copyDataTo()).reshape(4,4) elif nd == 2: m = np.array(self.copyDataTo()).reshape(4,4) m[2] = m[3] m[:,2] = m[:,3] return m[:3,:3] else: raise Exception("Argument 'nd' must be 2 or 3") def map(self, obj): """ Extends QMatrix4x4.map() to allow mapping (3, ...) arrays of coordinates """ if isinstance(obj, np.ndarray) and obj.ndim >= 2 and obj.shape[0] in (2,3): return fn.transformCoordinates(self, obj) else: return QtGui.QMatrix4x4.map(self, obj) def inverted(self): inv, b = QtGui.QMatrix4x4.inverted(self) return Transform3D(inv), bpyqtgraph-pyqtgraph-0.10.0/pyqtgraph/Vector.py000066400000000000000000000055571300727121400214700ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Vector.py - Extension of QVector3D which adds a few missing methods. Copyright 2010 Luke Campagnola Distributed under MIT/X11 license. See license.txt for more infomation. """ from .Qt import QtGui, QtCore, USE_PYSIDE import numpy as np class Vector(QtGui.QVector3D): """Extension of QVector3D which adds a few helpful methods.""" def __init__(self, *args): if len(args) == 1: if isinstance(args[0], QtCore.QSizeF): QtGui.QVector3D.__init__(self, float(args[0].width()), float(args[0].height()), 0) return elif isinstance(args[0], QtCore.QPoint) or isinstance(args[0], QtCore.QPointF): QtGui.QVector3D.__init__(self, float(args[0].x()), float(args[0].y()), 0) elif hasattr(args[0], '__getitem__'): vals = list(args[0]) if len(vals) == 2: vals.append(0) if len(vals) != 3: raise Exception('Cannot init Vector with sequence of length %d' % len(args[0])) QtGui.QVector3D.__init__(self, *vals) return elif len(args) == 2: QtGui.QVector3D.__init__(self, args[0], args[1], 0) return QtGui.QVector3D.__init__(self, *args) def __len__(self): return 3 def __add__(self, b): # workaround for pyside bug. see https://bugs.launchpad.net/pyqtgraph/+bug/1223173 if USE_PYSIDE and isinstance(b, QtGui.QVector3D): b = Vector(b) return QtGui.QVector3D.__add__(self, b) #def __reduce__(self): #return (Point, (self.x(), self.y())) def __getitem__(self, i): if i == 0: return self.x() elif i == 1: return self.y() elif i == 2: return self.z() else: raise IndexError("Point has no index %s" % str(i)) def __setitem__(self, i, x): if i == 0: return self.setX(x) elif i == 1: return self.setY(x) elif i == 2: return self.setZ(x) else: raise IndexError("Point has no index %s" % str(i)) def __iter__(self): yield(self.x()) yield(self.y()) yield(self.z()) def angle(self, a): """Returns the angle in degrees between this vector and the vector a.""" n1 = self.length() n2 = a.length() if n1 == 0. or n2 == 0.: return None ## Probably this should be done with arctan2 instead.. ang = np.arccos(np.clip(QtGui.QVector3D.dotProduct(self, a) / (n1 * n2), -1.0, 1.0)) ### in radians # c = self.crossProduct(a) # if c > 0: # ang *= -1. return ang * 180. / np.pi def __abs__(self): return Vector(abs(self.x()), abs(self.y()), abs(self.z())) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/WidgetGroup.py000066400000000000000000000234221300727121400224550ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ WidgetGroup.py - WidgetGroup class for easily managing lots of Qt widgets Copyright 2010 Luke Campagnola Distributed under MIT/X11 license. See license.txt for more infomation. This class addresses the problem of having to save and restore the state of a large group of widgets. """ from .Qt import QtCore, QtGui, USE_PYQT5 import weakref, inspect from .python2_3 import asUnicode __all__ = ['WidgetGroup'] def splitterState(w): s = str(w.saveState().toPercentEncoding()) return s def restoreSplitter(w, s): if type(s) is list: w.setSizes(s) elif type(s) is str: w.restoreState(QtCore.QByteArray.fromPercentEncoding(s)) else: print("Can't configure QSplitter using object of type", type(s)) if w.count() > 0: ## make sure at least one item is not collapsed for i in w.sizes(): if i > 0: return w.setSizes([50] * w.count()) def comboState(w): ind = w.currentIndex() data = w.itemData(ind) #if not data.isValid(): if data is not None: try: if not data.isValid(): data = None else: data = data.toInt()[0] except AttributeError: pass if data is None: return asUnicode(w.itemText(ind)) else: return data def setComboState(w, v): if type(v) is int: #ind = w.findData(QtCore.QVariant(v)) ind = w.findData(v) if ind > -1: w.setCurrentIndex(ind) return w.setCurrentIndex(w.findText(str(v))) class WidgetGroup(QtCore.QObject): """This class takes a list of widgets and keeps an internal record of their state that is always up to date. Allows reading and writing from groups of widgets simultaneously. """ ## List of widget types that can be handled by WidgetGroup. ## The value for each type is a tuple (change signal function, get function, set function, [auto-add children]) ## The change signal function that takes an object and returns a signal that is emitted any time the state of the widget changes, not just ## when it is changed by user interaction. (for example, 'clicked' is not a valid signal here) ## If the change signal is None, the value of the widget is not cached. ## Custom widgets not in this list can be made to work with WidgetGroup by giving them a 'widgetGroupInterface' method ## which returns the tuple. classes = { QtGui.QSpinBox: (lambda w: w.valueChanged, QtGui.QSpinBox.value, QtGui.QSpinBox.setValue), QtGui.QDoubleSpinBox: (lambda w: w.valueChanged, QtGui.QDoubleSpinBox.value, QtGui.QDoubleSpinBox.setValue), QtGui.QSplitter: (None, splitterState, restoreSplitter, True), QtGui.QCheckBox: (lambda w: w.stateChanged, QtGui.QCheckBox.isChecked, QtGui.QCheckBox.setChecked), QtGui.QComboBox: (lambda w: w.currentIndexChanged, comboState, setComboState), QtGui.QGroupBox: (lambda w: w.toggled, QtGui.QGroupBox.isChecked, QtGui.QGroupBox.setChecked, True), QtGui.QLineEdit: (lambda w: w.editingFinished, lambda w: str(w.text()), QtGui.QLineEdit.setText), QtGui.QRadioButton: (lambda w: w.toggled, QtGui.QRadioButton.isChecked, QtGui.QRadioButton.setChecked), QtGui.QSlider: (lambda w: w.valueChanged, QtGui.QSlider.value, QtGui.QSlider.setValue), } sigChanged = QtCore.Signal(str, object) def __init__(self, widgetList=None): """Initialize WidgetGroup, adding specified widgets into this group. widgetList can be: - a list of widget specifications (widget, [name], [scale]) - a dict of name: widget pairs - any QObject, and all compatible child widgets will be added recursively. The 'scale' parameter for each widget allows QSpinBox to display a different value than the value recorded in the group state (for example, the program may set a spin box value to 100e-6 and have it displayed as 100 to the user) """ QtCore.QObject.__init__(self) self.widgetList = weakref.WeakKeyDictionary() # Make sure widgets don't stick around just because they are listed here self.scales = weakref.WeakKeyDictionary() self.cache = {} ## name:value pairs self.uncachedWidgets = weakref.WeakKeyDictionary() if isinstance(widgetList, QtCore.QObject): self.autoAdd(widgetList) elif isinstance(widgetList, list): for w in widgetList: self.addWidget(*w) elif isinstance(widgetList, dict): for name, w in widgetList.items(): self.addWidget(w, name) elif widgetList is None: return else: raise Exception("Wrong argument type %s" % type(widgetList)) def addWidget(self, w, name=None, scale=None): if not self.acceptsType(w): raise Exception("Widget type %s not supported by WidgetGroup" % type(w)) if name is None: name = str(w.objectName()) if name == '': raise Exception("Cannot add widget '%s' without a name." % str(w)) self.widgetList[w] = name self.scales[w] = scale self.readWidget(w) if type(w) in WidgetGroup.classes: signal = WidgetGroup.classes[type(w)][0] else: signal = w.widgetGroupInterface()[0] if signal is not None: if inspect.isfunction(signal) or inspect.ismethod(signal): signal = signal(w) signal.connect(self.mkChangeCallback(w)) else: self.uncachedWidgets[w] = None def findWidget(self, name): for w in self.widgetList: if self.widgetList[w] == name: return w return None def interface(self, obj): t = type(obj) if t in WidgetGroup.classes: return WidgetGroup.classes[t] else: return obj.widgetGroupInterface() def checkForChildren(self, obj): """Return true if we should automatically search the children of this object for more.""" iface = self.interface(obj) return (len(iface) > 3 and iface[3]) def autoAdd(self, obj): ## Find all children of this object and add them if possible. accepted = self.acceptsType(obj) if accepted: #print "%s auto add %s" % (self.objectName(), obj.objectName()) self.addWidget(obj) if not accepted or self.checkForChildren(obj): for c in obj.children(): self.autoAdd(c) def acceptsType(self, obj): for c in WidgetGroup.classes: if isinstance(obj, c): return True if hasattr(obj, 'widgetGroupInterface'): return True return False def setScale(self, widget, scale): val = self.readWidget(widget) self.scales[widget] = scale self.setWidget(widget, val) def mkChangeCallback(self, w): return lambda *args: self.widgetChanged(w, *args) def widgetChanged(self, w, *args): n = self.widgetList[w] v1 = self.cache[n] v2 = self.readWidget(w) if v1 != v2: if not USE_PYQT5: # Old signal kept for backward compatibility. self.emit(QtCore.SIGNAL('changed'), self.widgetList[w], v2) self.sigChanged.emit(self.widgetList[w], v2) def state(self): for w in self.uncachedWidgets: self.readWidget(w) return self.cache.copy() def setState(self, s): for w in self.widgetList: n = self.widgetList[w] if n not in s: continue self.setWidget(w, s[n]) def readWidget(self, w): if type(w) in WidgetGroup.classes: getFunc = WidgetGroup.classes[type(w)][1] else: getFunc = w.widgetGroupInterface()[1] if getFunc is None: return None ## if the getter function provided in the interface is a bound method, ## then just call the method directly. Otherwise, pass in the widget as the first arg ## to the function. if inspect.ismethod(getFunc) and getFunc.__self__ is not None: val = getFunc() else: val = getFunc(w) if self.scales[w] is not None: val /= self.scales[w] #if isinstance(val, QtCore.QString): #val = str(val) n = self.widgetList[w] self.cache[n] = val return val def setWidget(self, w, v): v1 = v if self.scales[w] is not None: v *= self.scales[w] if type(w) in WidgetGroup.classes: setFunc = WidgetGroup.classes[type(w)][2] else: setFunc = w.widgetGroupInterface()[2] ## if the setter function provided in the interface is a bound method, ## then just call the method directly. Otherwise, pass in the widget as the first arg ## to the function. if inspect.ismethod(setFunc) and setFunc.__self__ is not None: setFunc(v) else: setFunc(w, v) #name = self.widgetList[w] #if name in self.cache and (self.cache[name] != v1): #print "%s: Cached value %s != set value %s" % (name, str(self.cache[name]), str(v1)) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/__init__.py000066400000000000000000000422211300727121400217520ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ PyQtGraph - Scientific Graphics and GUI Library for Python www.pyqtgraph.org """ __version__ = '0.10.0' ### import all the goodies and add some helper functions for easy CLI use ## 'Qt' is a local module; it is intended mainly to cover up the differences ## between PyQt4 and PySide. from .Qt import QtGui ## not really safe--If we accidentally create another QApplication, the process hangs (and it is very difficult to trace the cause) #if QtGui.QApplication.instance() is None: #app = QtGui.QApplication([]) import numpy ## pyqtgraph requires numpy ## (import here to avoid massive error dump later on if numpy is not available) import os, sys ## check python version ## Allow anything >= 2.7 if sys.version_info[0] < 2 or (sys.version_info[0] == 2 and sys.version_info[1] < 6): raise Exception("Pyqtgraph requires Python version 2.6 or greater (this is %d.%d)" % (sys.version_info[0], sys.version_info[1])) ## helpers for 2/3 compatibility from . import python2_3 ## install workarounds for numpy bugs from . import numpy_fix ## in general openGL is poorly supported with Qt+GraphicsView. ## we only enable it where the performance benefit is critical. ## Note this only applies to 2D graphics; 3D graphics always use OpenGL. if 'linux' in sys.platform: ## linux has numerous bugs in opengl implementation useOpenGL = False elif 'darwin' in sys.platform: ## openGL can have a major impact on mac, but also has serious bugs useOpenGL = False if QtGui.QApplication.instance() is not None: print('Warning: QApplication was created before pyqtgraph was imported; there may be problems (to avoid bugs, call QApplication.setGraphicsSystem("raster") before the QApplication is created).') if QtGui.QApplication.setGraphicsSystem: QtGui.QApplication.setGraphicsSystem('raster') ## work around a variety of bugs in the native graphics system else: useOpenGL = False ## on windows there's a more even performance / bugginess tradeoff. CONFIG_OPTIONS = { 'useOpenGL': useOpenGL, ## by default, this is platform-dependent (see widgets/GraphicsView). Set to True or False to explicitly enable/disable opengl. 'leftButtonPan': True, ## if false, left button drags a rubber band for zooming in viewbox # foreground/background take any arguments to the 'mkColor' in /pyqtgraph/functions.py 'foreground': 'd', ## default foreground color for axes, labels, etc. 'background': 'k', ## default background for GraphicsWidget 'antialias': False, 'editorCommand': None, ## command used to invoke code editor from ConsoleWidgets 'useWeave': False, ## Use weave to speed up some operations, if it is available 'weaveDebug': False, ## Print full error message if weave compile fails 'exitCleanup': True, ## Attempt to work around some exit crash bugs in PyQt and PySide 'enableExperimental': False, ## Enable experimental features (the curious can search for this key in the code) 'crashWarning': False, # If True, print warnings about situations that may result in a crash 'imageAxisOrder': 'col-major', # For 'row-major', image data is expected in the standard (row, col) order. # For 'col-major', image data is expected in reversed (col, row) order. # The default is 'col-major' for backward compatibility, but this may # change in the future. } def setConfigOption(opt, value): global CONFIG_OPTIONS if opt not in CONFIG_OPTIONS: raise KeyError('Unknown configuration option "%s"' % opt) if opt == 'imageAxisOrder' and value not in ('row-major', 'col-major'): raise ValueError('imageAxisOrder must be either "row-major" or "col-major"') CONFIG_OPTIONS[opt] = value def setConfigOptions(**opts): """Set global configuration options. Each keyword argument sets one global option. """ for k,v in opts.items(): setConfigOption(k, v) def getConfigOption(opt): """Return the value of a single global configuration option. """ return CONFIG_OPTIONS[opt] def systemInfo(): print("sys.platform: %s" % sys.platform) print("sys.version: %s" % sys.version) from .Qt import VERSION_INFO print("qt bindings: %s" % VERSION_INFO) global __version__ rev = None if __version__ is None: ## this code was probably checked out from bzr; look up the last-revision file lastRevFile = os.path.join(os.path.dirname(__file__), '..', '.bzr', 'branch', 'last-revision') if os.path.exists(lastRevFile): rev = open(lastRevFile, 'r').read().strip() print("pyqtgraph: %s; %s" % (__version__, rev)) print("config:") import pprint pprint.pprint(CONFIG_OPTIONS) ## Rename orphaned .pyc files. This is *probably* safe :) ## We only do this if __version__ is None, indicating the code was probably pulled ## from the repository. def renamePyc(startDir): ### Used to rename orphaned .pyc files ### When a python file changes its location in the repository, usually the .pyc file ### is left behind, possibly causing mysterious and difficult to track bugs. ### Note that this is no longer necessary for python 3.2; from PEP 3147: ### "If the py source file is missing, the pyc file inside __pycache__ will be ignored. ### This eliminates the problem of accidental stale pyc file imports." printed = False startDir = os.path.abspath(startDir) for path, dirs, files in os.walk(startDir): if '__pycache__' in path: continue for f in files: fileName = os.path.join(path, f) base, ext = os.path.splitext(fileName) py = base + ".py" if ext == '.pyc' and not os.path.isfile(py): if not printed: print("NOTE: Renaming orphaned .pyc files:") printed = True n = 1 while True: name2 = fileName + ".renamed%d" % n if not os.path.exists(name2): break n += 1 print(" " + fileName + " ==>") print(" " + name2) os.rename(fileName, name2) path = os.path.split(__file__)[0] if __version__ is None and not hasattr(sys, 'frozen') and sys.version_info[0] == 2: ## If we are frozen, there's a good chance we don't have the original .py files anymore. renamePyc(path) ## Import almost everything to make it available from a single namespace ## don't import the more complex systems--canvas, parametertree, flowchart, dockarea ## these must be imported separately. #from . import frozenSupport #def importModules(path, globals, locals, excludes=()): #"""Import all modules residing within *path*, return a dict of name: module pairs. #Note that *path* MUST be relative to the module doing the import. #""" #d = os.path.join(os.path.split(globals['__file__'])[0], path) #files = set() #for f in frozenSupport.listdir(d): #if frozenSupport.isdir(os.path.join(d, f)) and f not in ['__pycache__', 'tests']: #files.add(f) #elif f[-3:] == '.py' and f != '__init__.py': #files.add(f[:-3]) #elif f[-4:] == '.pyc' and f != '__init__.pyc': #files.add(f[:-4]) #mods = {} #path = path.replace(os.sep, '.') #for modName in files: #if modName in excludes: #continue #try: #if len(path) > 0: #modName = path + '.' + modName #print( "from .%s import * " % modName) #mod = __import__(modName, globals, locals, ['*'], 1) #mods[modName] = mod #except: #import traceback #traceback.print_stack() #sys.excepthook(*sys.exc_info()) #print("[Error importing module: %s]" % modName) #return mods #def importAll(path, globals, locals, excludes=()): #"""Given a list of modules, import all names from each module into the global namespace.""" #mods = importModules(path, globals, locals, excludes) #for mod in mods.values(): #if hasattr(mod, '__all__'): #names = mod.__all__ #else: #names = [n for n in dir(mod) if n[0] != '_'] #for k in names: #if hasattr(mod, k): #globals[k] = getattr(mod, k) # Dynamic imports are disabled. This causes too many problems. #importAll('graphicsItems', globals(), locals()) #importAll('widgets', globals(), locals(), #excludes=['MatplotlibWidget', 'RawImageWidget', 'RemoteGraphicsView']) from .graphicsItems.VTickGroup import * from .graphicsItems.GraphicsWidget import * from .graphicsItems.ScaleBar import * from .graphicsItems.PlotDataItem import * from .graphicsItems.GraphItem import * from .graphicsItems.TextItem import * from .graphicsItems.GraphicsLayout import * from .graphicsItems.UIGraphicsItem import * from .graphicsItems.GraphicsObject import * from .graphicsItems.PlotItem import * from .graphicsItems.ROI import * from .graphicsItems.InfiniteLine import * from .graphicsItems.HistogramLUTItem import * from .graphicsItems.GridItem import * from .graphicsItems.GradientLegend import * from .graphicsItems.GraphicsItem import * from .graphicsItems.BarGraphItem import * from .graphicsItems.ViewBox import * from .graphicsItems.ArrowItem import * from .graphicsItems.ImageItem import * from .graphicsItems.AxisItem import * from .graphicsItems.LabelItem import * from .graphicsItems.CurvePoint import * from .graphicsItems.GraphicsWidgetAnchor import * from .graphicsItems.PlotCurveItem import * from .graphicsItems.ButtonItem import * from .graphicsItems.GradientEditorItem import * from .graphicsItems.MultiPlotItem import * from .graphicsItems.ErrorBarItem import * from .graphicsItems.IsocurveItem import * from .graphicsItems.LinearRegionItem import * from .graphicsItems.FillBetweenItem import * from .graphicsItems.LegendItem import * from .graphicsItems.ScatterPlotItem import * from .graphicsItems.ItemGroup import * from .widgets.MultiPlotWidget import * from .widgets.ScatterPlotWidget import * from .widgets.ColorMapWidget import * from .widgets.FileDialog import * from .widgets.ValueLabel import * from .widgets.HistogramLUTWidget import * from .widgets.CheckTable import * from .widgets.BusyCursor import * from .widgets.PlotWidget import * from .widgets.ComboBox import * from .widgets.GradientWidget import * from .widgets.DataFilterWidget import * from .widgets.SpinBox import * from .widgets.JoystickButton import * from .widgets.GraphicsLayoutWidget import * from .widgets.TreeWidget import * from .widgets.PathButton import * from .widgets.VerticalLabel import * from .widgets.FeedbackButton import * from .widgets.ColorButton import * from .widgets.DataTreeWidget import * from .widgets.GraphicsView import * from .widgets.LayoutWidget import * from .widgets.TableWidget import * from .widgets.ProgressDialog import * from .imageview import * from .WidgetGroup import * from .Point import Point from .Vector import Vector from .SRTTransform import SRTTransform from .Transform3D import Transform3D from .SRTTransform3D import SRTTransform3D from .functions import * from .graphicsWindows import * from .SignalProxy import * from .colormap import * from .ptime import time from .Qt import isQObjectAlive ############################################################## ## PyQt and PySide both are prone to crashing on exit. ## There are two general approaches to dealing with this: ## 1. Install atexit handlers that assist in tearing down to avoid crashes. ## This helps, but is never perfect. ## 2. Terminate the process before python starts tearing down ## This is potentially dangerous ## Attempts to work around exit crashes: import atexit _cleanupCalled = False def cleanup(): global _cleanupCalled if _cleanupCalled: return if not getConfigOption('exitCleanup'): return ViewBox.quit() ## tell ViewBox that it doesn't need to deregister views anymore. ## Workaround for Qt exit crash: ## ALL QGraphicsItems must have a scene before they are deleted. ## This is potentially very expensive, but preferred over crashing. ## Note: this appears to be fixed in PySide as of 2012.12, but it should be left in for a while longer.. if QtGui.QApplication.instance() is None: return import gc s = QtGui.QGraphicsScene() for o in gc.get_objects(): try: if isinstance(o, QtGui.QGraphicsItem) and isQObjectAlive(o) and o.scene() is None: if getConfigOption('crashWarning'): sys.stderr.write('Error: graphics item without scene. ' 'Make sure ViewBox.close() and GraphicsView.close() ' 'are properly called before app shutdown (%s)\n' % (o,)) s.addItem(o) except RuntimeError: ## occurs if a python wrapper no longer has its underlying C++ object continue _cleanupCalled = True atexit.register(cleanup) # Call cleanup when QApplication quits. This is necessary because sometimes # the QApplication will quit before the atexit callbacks are invoked. # Note: cannot connect this function until QApplication has been created, so # instead we have GraphicsView.__init__ call this for us. _cleanupConnected = False def _connectCleanup(): global _cleanupConnected if _cleanupConnected: return QtGui.QApplication.instance().aboutToQuit.connect(cleanup) _cleanupConnected = True ## Optional function for exiting immediately (with some manual teardown) def exit(): """ Causes python to exit without garbage-collecting any objects, and thus avoids calling object destructor methods. This is a sledgehammer workaround for a variety of bugs in PyQt and Pyside that cause crashes on exit. This function does the following in an attempt to 'safely' terminate the process: * Invoke atexit callbacks * Close all open file handles * os._exit() Note: there is some potential for causing damage with this function if you are using objects that _require_ their destructors to be called (for example, to properly terminate log files, disconnect from devices, etc). Situations like this are probably quite rare, but use at your own risk. """ ## first disable our own cleanup function; won't be needing it. setConfigOptions(exitCleanup=False) ## invoke atexit callbacks atexit._run_exitfuncs() ## close file handles if sys.platform == 'darwin': for fd in range(3, 4096): if fd not in [7]: # trying to close 7 produces an illegal instruction on the Mac. os.close(fd) else: os.closerange(3, 4096) ## just guessing on the maximum descriptor count.. os._exit(0) ## Convenience functions for command-line use plots = [] images = [] QAPP = None def plot(*args, **kargs): """ Create and return a :class:`PlotWindow ` (this is just a window with :class:`PlotWidget ` inside), plot data in it. Accepts a *title* argument to set the title of the window. All other arguments are used to plot data. (see :func:`PlotItem.plot() `) """ mkQApp() #if 'title' in kargs: #w = PlotWindow(title=kargs['title']) #del kargs['title'] #else: #w = PlotWindow() #if len(args)+len(kargs) > 0: #w.plot(*args, **kargs) pwArgList = ['title', 'labels', 'name', 'left', 'right', 'top', 'bottom', 'background'] pwArgs = {} dataArgs = {} for k in kargs: if k in pwArgList: pwArgs[k] = kargs[k] else: dataArgs[k] = kargs[k] w = PlotWindow(**pwArgs) if len(args) > 0 or len(dataArgs) > 0: w.plot(*args, **dataArgs) plots.append(w) w.show() return w def image(*args, **kargs): """ Create and return an :class:`ImageWindow ` (this is just a window with :class:`ImageView ` widget inside), show image data inside. Will show 2D or 3D image data. Accepts a *title* argument to set the title of the window. All other arguments are used to show data. (see :func:`ImageView.setImage() `) """ mkQApp() w = ImageWindow(*args, **kargs) images.append(w) w.show() return w show = image ## for backward compatibility def dbg(*args, **kwds): """ Create a console window and begin watching for exceptions. All arguments are passed to :func:`ConsoleWidget.__init__() `. """ mkQApp() from . import console c = console.ConsoleWidget(*args, **kwds) c.catchAllExceptions() c.show() global consoles try: consoles.append(c) except NameError: consoles = [c] return c def mkQApp(): global QAPP inst = QtGui.QApplication.instance() if inst is None: QAPP = QtGui.QApplication([]) else: QAPP = inst return QAPP pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/canvas/000077500000000000000000000000001300727121400211135ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/canvas/Canvas.py000066400000000000000000000504141300727121400227040ustar00rootroot00000000000000# -*- coding: utf-8 -*- if __name__ == '__main__': import sys, os md = os.path.dirname(os.path.abspath(__file__)) sys.path = [os.path.dirname(md), os.path.join(md, '..', '..', '..')] + sys.path from ..Qt import QtGui, QtCore, USE_PYSIDE from ..graphicsItems.ROI import ROI from ..graphicsItems.ViewBox import ViewBox from ..graphicsItems.GridItem import GridItem if USE_PYSIDE: from .CanvasTemplate_pyside import * else: from .CanvasTemplate_pyqt import * import numpy as np from .. import debug import weakref from .CanvasManager import CanvasManager from .CanvasItem import CanvasItem, GroupCanvasItem class Canvas(QtGui.QWidget): sigSelectionChanged = QtCore.Signal(object, object) sigItemTransformChanged = QtCore.Signal(object, object) sigItemTransformChangeFinished = QtCore.Signal(object, object) def __init__(self, parent=None, allowTransforms=True, hideCtrl=False, name=None): QtGui.QWidget.__init__(self, parent) self.ui = Ui_Form() self.ui.setupUi(self) #self.view = self.ui.view self.view = ViewBox() self.ui.view.setCentralItem(self.view) self.itemList = self.ui.itemList self.itemList.setSelectionMode(self.itemList.ExtendedSelection) self.allowTransforms = allowTransforms self.multiSelectBox = SelectBox() self.view.addItem(self.multiSelectBox) self.multiSelectBox.hide() self.multiSelectBox.setZValue(1e6) self.ui.mirrorSelectionBtn.hide() self.ui.reflectSelectionBtn.hide() self.ui.resetTransformsBtn.hide() self.redirect = None ## which canvas to redirect items to self.items = [] #self.view.enableMouse() self.view.setAspectLocked(True) #self.view.invertY() grid = GridItem() self.grid = CanvasItem(grid, name='Grid', movable=False) self.addItem(self.grid) self.hideBtn = QtGui.QPushButton('>', self) self.hideBtn.setFixedWidth(20) self.hideBtn.setFixedHeight(20) self.ctrlSize = 200 self.sizeApplied = False self.hideBtn.clicked.connect(self.hideBtnClicked) self.ui.splitter.splitterMoved.connect(self.splitterMoved) self.ui.itemList.itemChanged.connect(self.treeItemChanged) self.ui.itemList.sigItemMoved.connect(self.treeItemMoved) self.ui.itemList.itemSelectionChanged.connect(self.treeItemSelected) self.ui.autoRangeBtn.clicked.connect(self.autoRange) #self.ui.storeSvgBtn.clicked.connect(self.storeSvg) #self.ui.storePngBtn.clicked.connect(self.storePng) self.ui.redirectCheck.toggled.connect(self.updateRedirect) self.ui.redirectCombo.currentIndexChanged.connect(self.updateRedirect) self.multiSelectBox.sigRegionChanged.connect(self.multiSelectBoxChanged) self.multiSelectBox.sigRegionChangeFinished.connect(self.multiSelectBoxChangeFinished) self.ui.mirrorSelectionBtn.clicked.connect(self.mirrorSelectionClicked) self.ui.reflectSelectionBtn.clicked.connect(self.reflectSelectionClicked) self.ui.resetTransformsBtn.clicked.connect(self.resetTransformsClicked) self.resizeEvent() if hideCtrl: self.hideBtnClicked() if name is not None: self.registeredName = CanvasManager.instance().registerCanvas(self, name) self.ui.redirectCombo.setHostName(self.registeredName) self.menu = QtGui.QMenu() #self.menu.setTitle("Image") remAct = QtGui.QAction("Remove item", self.menu) remAct.triggered.connect(self.removeClicked) self.menu.addAction(remAct) self.menu.remAct = remAct self.ui.itemList.contextMenuEvent = self.itemListContextMenuEvent #def storeSvg(self): #from pyqtgraph.GraphicsScene.exportDialog import ExportDialog #ex = ExportDialog(self.ui.view) #ex.show() #def storePng(self): #self.ui.view.writeImage() def splitterMoved(self): self.resizeEvent() def hideBtnClicked(self): ctrlSize = self.ui.splitter.sizes()[1] if ctrlSize == 0: cs = self.ctrlSize w = self.ui.splitter.size().width() if cs > w: cs = w - 20 self.ui.splitter.setSizes([w-cs, cs]) self.hideBtn.setText('>') else: self.ctrlSize = ctrlSize self.ui.splitter.setSizes([100, 0]) self.hideBtn.setText('<') self.resizeEvent() def autoRange(self): self.view.autoRange() def resizeEvent(self, ev=None): if ev is not None: QtGui.QWidget.resizeEvent(self, ev) self.hideBtn.move(self.ui.view.size().width() - self.hideBtn.width(), 0) if not self.sizeApplied: self.sizeApplied = True s = min(self.width(), max(100, min(200, self.width()*0.25))) s2 = self.width()-s self.ui.splitter.setSizes([s2, s]) def updateRedirect(self, *args): ### Decide whether/where to redirect items and make it so cname = str(self.ui.redirectCombo.currentText()) man = CanvasManager.instance() if self.ui.redirectCheck.isChecked() and cname != '': redirect = man.getCanvas(cname) else: redirect = None if self.redirect is redirect: return self.redirect = redirect if redirect is None: self.reclaimItems() else: self.redirectItems(redirect) def redirectItems(self, canvas): for i in self.items: if i is self.grid: continue li = i.listItem parent = li.parent() if parent is None: tree = li.treeWidget() if tree is None: print("Skipping item", i, i.name) continue tree.removeTopLevelItem(li) else: parent.removeChild(li) canvas.addItem(i) def reclaimItems(self): items = self.items #self.items = {'Grid': items['Grid']} #del items['Grid'] self.items = [self.grid] items.remove(self.grid) for i in items: i.canvas.removeItem(i) self.addItem(i) def treeItemChanged(self, item, col): #gi = self.items.get(item.name, None) #if gi is None: #return try: citem = item.canvasItem() except AttributeError: return if item.checkState(0) == QtCore.Qt.Checked: for i in range(item.childCount()): item.child(i).setCheckState(0, QtCore.Qt.Checked) citem.show() else: for i in range(item.childCount()): item.child(i).setCheckState(0, QtCore.Qt.Unchecked) citem.hide() def treeItemSelected(self): sel = self.selectedItems() #sel = [] #for listItem in self.itemList.selectedItems(): #if hasattr(listItem, 'canvasItem') and listItem.canvasItem is not None: #sel.append(listItem.canvasItem) #sel = [self.items[item.name] for item in sel] if len(sel) == 0: #self.selectWidget.hide() return multi = len(sel) > 1 for i in self.items: #i.ctrlWidget().hide() ## updated the selected state of every item i.selectionChanged(i in sel, multi) if len(sel)==1: #item = sel[0] #item.ctrlWidget().show() self.multiSelectBox.hide() self.ui.mirrorSelectionBtn.hide() self.ui.reflectSelectionBtn.hide() self.ui.resetTransformsBtn.hide() elif len(sel) > 1: self.showMultiSelectBox() #if item.isMovable(): #self.selectBox.setPos(item.item.pos()) #self.selectBox.setSize(item.item.sceneBoundingRect().size()) #self.selectBox.show() #else: #self.selectBox.hide() #self.emit(QtCore.SIGNAL('itemSelected'), self, item) self.sigSelectionChanged.emit(self, sel) def selectedItems(self): """ Return list of all selected canvasItems """ return [item.canvasItem() for item in self.itemList.selectedItems() if item.canvasItem() is not None] #def selectedItem(self): #sel = self.itemList.selectedItems() #if sel is None or len(sel) < 1: #return #return self.items.get(sel[0].name, None) def selectItem(self, item): li = item.listItem #li = self.getListItem(item.name()) #print "select", li self.itemList.setCurrentItem(li) def showMultiSelectBox(self): ## Get list of selected canvas items items = self.selectedItems() rect = self.view.itemBoundingRect(items[0].graphicsItem()) for i in items: if not i.isMovable(): ## all items in selection must be movable return br = self.view.itemBoundingRect(i.graphicsItem()) rect = rect|br self.multiSelectBox.blockSignals(True) self.multiSelectBox.setPos([rect.x(), rect.y()]) self.multiSelectBox.setSize(rect.size()) self.multiSelectBox.setAngle(0) self.multiSelectBox.blockSignals(False) self.multiSelectBox.show() self.ui.mirrorSelectionBtn.show() self.ui.reflectSelectionBtn.show() self.ui.resetTransformsBtn.show() #self.multiSelectBoxBase = self.multiSelectBox.getState().copy() def mirrorSelectionClicked(self): for ci in self.selectedItems(): ci.mirrorY() self.showMultiSelectBox() def reflectSelectionClicked(self): for ci in self.selectedItems(): ci.mirrorXY() self.showMultiSelectBox() def resetTransformsClicked(self): for i in self.selectedItems(): i.resetTransformClicked() self.showMultiSelectBox() def multiSelectBoxChanged(self): self.multiSelectBoxMoved() def multiSelectBoxChangeFinished(self): for ci in self.selectedItems(): ci.applyTemporaryTransform() ci.sigTransformChangeFinished.emit(ci) def multiSelectBoxMoved(self): transform = self.multiSelectBox.getGlobalTransform() for ci in self.selectedItems(): ci.setTemporaryTransform(transform) ci.sigTransformChanged.emit(ci) def addGraphicsItem(self, item, **opts): """Add a new GraphicsItem to the scene at pos. Common options are name, pos, scale, and z """ citem = CanvasItem(item, **opts) item._canvasItem = citem self.addItem(citem) return citem def addGroup(self, name, **kargs): group = GroupCanvasItem(name=name) self.addItem(group, **kargs) return group def addItem(self, citem): """ Add an item to the canvas. """ ## Check for redirections if self.redirect is not None: name = self.redirect.addItem(citem) self.items.append(citem) return name if not self.allowTransforms: citem.setMovable(False) citem.sigTransformChanged.connect(self.itemTransformChanged) citem.sigTransformChangeFinished.connect(self.itemTransformChangeFinished) citem.sigVisibilityChanged.connect(self.itemVisibilityChanged) ## Determine name to use in the item list name = citem.opts['name'] if name is None: name = 'item' newname = name ## If name already exists, append a number to the end ## NAH. Let items have the same name if they really want. #c=0 #while newname in self.items: #c += 1 #newname = name + '_%03d' %c #name = newname ## find parent and add item to tree #currentNode = self.itemList.invisibleRootItem() insertLocation = 0 #print "Inserting node:", name ## determine parent list item where this item should be inserted parent = citem.parentItem() if parent in (None, self.view.childGroup): parent = self.itemList.invisibleRootItem() else: parent = parent.listItem ## set Z value above all other siblings if none was specified siblings = [parent.child(i).canvasItem() for i in range(parent.childCount())] z = citem.zValue() if z is None: zvals = [i.zValue() for i in siblings] if parent == self.itemList.invisibleRootItem(): if len(zvals) == 0: z = 0 else: z = max(zvals)+10 else: if len(zvals) == 0: z = parent.canvasItem().zValue() else: z = max(zvals)+1 citem.setZValue(z) ## determine location to insert item relative to its siblings for i in range(parent.childCount()): ch = parent.child(i) zval = ch.canvasItem().graphicsItem().zValue() ## should we use CanvasItem.zValue here? if zval < z: insertLocation = i break else: insertLocation = i+1 node = QtGui.QTreeWidgetItem([name]) flags = node.flags() | QtCore.Qt.ItemIsUserCheckable | QtCore.Qt.ItemIsDragEnabled if not isinstance(citem, GroupCanvasItem): flags = flags & ~QtCore.Qt.ItemIsDropEnabled node.setFlags(flags) if citem.opts['visible']: node.setCheckState(0, QtCore.Qt.Checked) else: node.setCheckState(0, QtCore.Qt.Unchecked) node.name = name #if citem.opts['parent'] != None: ## insertLocation is incorrect in this case parent.insertChild(insertLocation, node) #else: #root.insertChild(insertLocation, node) citem.name = name citem.listItem = node node.canvasItem = weakref.ref(citem) self.items.append(citem) ctrl = citem.ctrlWidget() ctrl.hide() self.ui.ctrlLayout.addWidget(ctrl) ## inform the canvasItem that its parent canvas has changed citem.setCanvas(self) ## Autoscale to fit the first item added (not including the grid). if len(self.items) == 2: self.autoRange() #for n in name: #nextnode = None #for x in range(currentNode.childCount()): #ch = currentNode.child(x) #if hasattr(ch, 'name'): ## check Z-value of current item to determine insert location #zval = ch.canvasItem.zValue() #if zval > z: ###print " ->", x #insertLocation = x+1 #if n == ch.text(0): #nextnode = ch #break #if nextnode is None: ## If name doesn't exist, create it #nextnode = QtGui.QTreeWidgetItem([n]) #nextnode.setFlags((nextnode.flags() | QtCore.Qt.ItemIsUserCheckable) & ~QtCore.Qt.ItemIsDropEnabled) #nextnode.setCheckState(0, QtCore.Qt.Checked) ### Add node to correct position in list by Z-value ###print " ==>", insertLocation #currentNode.insertChild(insertLocation, nextnode) #if n == name[-1]: ## This is the leaf; add some extra properties. #nextnode.name = name #if n == name[0]: ## This is the root; make the item movable #nextnode.setFlags(nextnode.flags() | QtCore.Qt.ItemIsDragEnabled) #else: #nextnode.setFlags(nextnode.flags() & ~QtCore.Qt.ItemIsDragEnabled) #currentNode = nextnode return citem def treeItemMoved(self, item, parent, index): ##Item moved in tree; update Z values if parent is self.itemList.invisibleRootItem(): item.canvasItem().setParentItem(self.view.childGroup) else: item.canvasItem().setParentItem(parent.canvasItem()) siblings = [parent.child(i).canvasItem() for i in range(parent.childCount())] zvals = [i.zValue() for i in siblings] zvals.sort(reverse=True) for i in range(len(siblings)): item = siblings[i] item.setZValue(zvals[i]) #item = self.itemList.topLevelItem(i) ##ci = self.items[item.name] #ci = item.canvasItem #if ci is None: #continue #if ci.zValue() != zvals[i]: #ci.setZValue(zvals[i]) #if self.itemList.topLevelItemCount() < 2: #return #name = item.name #gi = self.items[name] #if index == 0: #next = self.itemList.topLevelItem(1) #z = self.items[next.name].zValue()+1 #else: #prev = self.itemList.topLevelItem(index-1) #z = self.items[prev.name].zValue()-1 #gi.setZValue(z) def itemVisibilityChanged(self, item): listItem = item.listItem checked = listItem.checkState(0) == QtCore.Qt.Checked vis = item.isVisible() if vis != checked: if vis: listItem.setCheckState(0, QtCore.Qt.Checked) else: listItem.setCheckState(0, QtCore.Qt.Unchecked) def removeItem(self, item): if isinstance(item, QtGui.QTreeWidgetItem): item = item.canvasItem() if isinstance(item, CanvasItem): item.setCanvas(None) listItem = item.listItem listItem.canvasItem = None item.listItem = None self.itemList.removeTopLevelItem(listItem) self.items.remove(item) ctrl = item.ctrlWidget() ctrl.hide() self.ui.ctrlLayout.removeWidget(ctrl) else: if hasattr(item, '_canvasItem'): self.removeItem(item._canvasItem) else: self.view.removeItem(item) ## disconnect signals, remove from list, etc.. def clear(self): while len(self.items) > 0: self.removeItem(self.items[0]) def addToScene(self, item): self.view.addItem(item) def removeFromScene(self, item): self.view.removeItem(item) def listItems(self): """Return a dictionary of name:item pairs""" return self.items def getListItem(self, name): return self.items[name] #def scene(self): #return self.view.scene() def itemTransformChanged(self, item): #self.emit(QtCore.SIGNAL('itemTransformChanged'), self, item) self.sigItemTransformChanged.emit(self, item) def itemTransformChangeFinished(self, item): #self.emit(QtCore.SIGNAL('itemTransformChangeFinished'), self, item) self.sigItemTransformChangeFinished.emit(self, item) def itemListContextMenuEvent(self, ev): self.menuItem = self.itemList.itemAt(ev.pos()) self.menu.popup(ev.globalPos()) def removeClicked(self): #self.removeItem(self.menuItem) for item in self.selectedItems(): self.removeItem(item) self.menuItem = None import gc gc.collect() class SelectBox(ROI): def __init__(self, scalable=False): #QtGui.QGraphicsRectItem.__init__(self, 0, 0, size[0], size[1]) ROI.__init__(self, [0,0], [1,1]) center = [0.5, 0.5] if scalable: self.addScaleHandle([1, 1], center, lockAspect=True) self.addScaleHandle([0, 0], center, lockAspect=True) self.addRotateHandle([0, 1], center) self.addRotateHandle([1, 0], center) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/canvas/CanvasItem.py000066400000000000000000000455041300727121400235270ustar00rootroot00000000000000# -*- coding: utf-8 -*- from ..Qt import QtGui, QtCore, QtSvg, USE_PYSIDE from ..graphicsItems.ROI import ROI from .. import SRTTransform, ItemGroup if USE_PYSIDE: from . import TransformGuiTemplate_pyside as TransformGuiTemplate else: from . import TransformGuiTemplate_pyqt as TransformGuiTemplate from .. import debug class SelectBox(ROI): def __init__(self, scalable=False, rotatable=True): #QtGui.QGraphicsRectItem.__init__(self, 0, 0, size[0], size[1]) ROI.__init__(self, [0,0], [1,1], invertible=True) center = [0.5, 0.5] if scalable: self.addScaleHandle([1, 1], center, lockAspect=True) self.addScaleHandle([0, 0], center, lockAspect=True) if rotatable: self.addRotateHandle([0, 1], center) self.addRotateHandle([1, 0], center) class CanvasItem(QtCore.QObject): sigResetUserTransform = QtCore.Signal(object) sigTransformChangeFinished = QtCore.Signal(object) sigTransformChanged = QtCore.Signal(object) """CanvasItem takes care of managing an item's state--alpha, visibility, z-value, transformations, etc. and provides a control widget""" sigVisibilityChanged = QtCore.Signal(object) transformCopyBuffer = None def __init__(self, item, **opts): defOpts = {'name': None, 'z': None, 'movable': True, 'scalable': False, 'rotatable': True, 'visible': True, 'parent':None} #'pos': [0,0], 'scale': [1,1], 'angle':0, defOpts.update(opts) self.opts = defOpts self.selectedAlone = False ## whether this item is the only one selected QtCore.QObject.__init__(self) self.canvas = None self._graphicsItem = item parent = self.opts['parent'] if parent is not None: self._graphicsItem.setParentItem(parent.graphicsItem()) self._parentItem = parent else: self._parentItem = None z = self.opts['z'] if z is not None: item.setZValue(z) self.ctrl = QtGui.QWidget() self.layout = QtGui.QGridLayout() self.layout.setSpacing(0) self.layout.setContentsMargins(0,0,0,0) self.ctrl.setLayout(self.layout) self.alphaLabel = QtGui.QLabel("Alpha") self.alphaSlider = QtGui.QSlider() self.alphaSlider.setMaximum(1023) self.alphaSlider.setOrientation(QtCore.Qt.Horizontal) self.alphaSlider.setValue(1023) self.layout.addWidget(self.alphaLabel, 0, 0) self.layout.addWidget(self.alphaSlider, 0, 1) self.resetTransformBtn = QtGui.QPushButton('Reset Transform') self.copyBtn = QtGui.QPushButton('Copy') self.pasteBtn = QtGui.QPushButton('Paste') self.transformWidget = QtGui.QWidget() self.transformGui = TransformGuiTemplate.Ui_Form() self.transformGui.setupUi(self.transformWidget) self.layout.addWidget(self.transformWidget, 3, 0, 1, 2) self.transformGui.mirrorImageBtn.clicked.connect(self.mirrorY) self.transformGui.reflectImageBtn.clicked.connect(self.mirrorXY) self.layout.addWidget(self.resetTransformBtn, 1, 0, 1, 2) self.layout.addWidget(self.copyBtn, 2, 0, 1, 1) self.layout.addWidget(self.pasteBtn, 2, 1, 1, 1) self.alphaSlider.valueChanged.connect(self.alphaChanged) self.alphaSlider.sliderPressed.connect(self.alphaPressed) self.alphaSlider.sliderReleased.connect(self.alphaReleased) #self.canvas.sigSelectionChanged.connect(self.selectionChanged) self.resetTransformBtn.clicked.connect(self.resetTransformClicked) self.copyBtn.clicked.connect(self.copyClicked) self.pasteBtn.clicked.connect(self.pasteClicked) self.setMovable(self.opts['movable']) ## update gui to reflect this option if 'transform' in self.opts: self.baseTransform = self.opts['transform'] else: self.baseTransform = SRTTransform() if 'pos' in self.opts and self.opts['pos'] is not None: self.baseTransform.translate(self.opts['pos']) if 'angle' in self.opts and self.opts['angle'] is not None: self.baseTransform.rotate(self.opts['angle']) if 'scale' in self.opts and self.opts['scale'] is not None: self.baseTransform.scale(self.opts['scale']) ## create selection box (only visible when selected) tr = self.baseTransform.saveState() if 'scalable' not in opts and tr['scale'] == (1,1): self.opts['scalable'] = True ## every CanvasItem implements its own individual selection box ## so that subclasses are free to make their own. self.selectBox = SelectBox(scalable=self.opts['scalable'], rotatable=self.opts['rotatable']) #self.canvas.scene().addItem(self.selectBox) self.selectBox.hide() self.selectBox.setZValue(1e6) self.selectBox.sigRegionChanged.connect(self.selectBoxChanged) ## calls selectBoxMoved self.selectBox.sigRegionChangeFinished.connect(self.selectBoxChangeFinished) ## set up the transformations that will be applied to the item ## (It is not safe to use item.setTransform, since the item might count on that not changing) self.itemRotation = QtGui.QGraphicsRotation() self.itemScale = QtGui.QGraphicsScale() self._graphicsItem.setTransformations([self.itemRotation, self.itemScale]) self.tempTransform = SRTTransform() ## holds the additional transform that happens during a move - gets added to the userTransform when move is done. self.userTransform = SRTTransform() ## stores the total transform of the object self.resetUserTransform() ## now happens inside resetUserTransform -> selectBoxToItem # self.selectBoxBase = self.selectBox.getState().copy() #print "Created canvas item", self #print " base:", self.baseTransform #print " user:", self.userTransform #print " temp:", self.tempTransform #print " bounds:", self.item.sceneBoundingRect() def setMovable(self, m): self.opts['movable'] = m if m: self.resetTransformBtn.show() self.copyBtn.show() self.pasteBtn.show() else: self.resetTransformBtn.hide() self.copyBtn.hide() self.pasteBtn.hide() def setCanvas(self, canvas): ## Called by canvas whenever the item is added. ## It is our responsibility to add all graphicsItems to the canvas's scene ## The canvas will automatically add our graphicsitem, ## so we just need to take care of the selectbox. if canvas is self.canvas: return if canvas is None: self.canvas.removeFromScene(self._graphicsItem) self.canvas.removeFromScene(self.selectBox) else: canvas.addToScene(self._graphicsItem) canvas.addToScene(self.selectBox) self.canvas = canvas def graphicsItem(self): """Return the graphicsItem for this canvasItem.""" return self._graphicsItem def parentItem(self): return self._parentItem def setParentItem(self, parent): self._parentItem = parent if parent is not None: if isinstance(parent, CanvasItem): parent = parent.graphicsItem() self.graphicsItem().setParentItem(parent) #def name(self): #return self.opts['name'] def copyClicked(self): CanvasItem.transformCopyBuffer = self.saveTransform() def pasteClicked(self): t = CanvasItem.transformCopyBuffer if t is None: return else: self.restoreTransform(t) def mirrorY(self): if not self.isMovable(): return #flip = self.transformGui.mirrorImageCheck.isChecked() #tr = self.userTransform.saveState() inv = SRTTransform() inv.scale(-1, 1) self.userTransform = self.userTransform * inv self.updateTransform() self.selectBoxFromUser() self.sigTransformChangeFinished.emit(self) #if flip: #if tr['scale'][0] < 0 xor tr['scale'][1] < 0: #return #else: #self.userTransform.setScale([-tr['scale'][0], tr['scale'][1]]) #self.userTransform.setTranslate([-tr['pos'][0], tr['pos'][1]]) #self.userTransform.setRotate(-tr['angle']) #self.updateTransform() #self.selectBoxFromUser() #return #elif not flip: #if tr['scale'][0] > 0 and tr['scale'][1] > 0: #return #else: #self.userTransform.setScale([-tr['scale'][0], tr['scale'][1]]) #self.userTransform.setTranslate([-tr['pos'][0], tr['pos'][1]]) #self.userTransform.setRotate(-tr['angle']) #self.updateTransform() #self.selectBoxFromUser() #return def mirrorXY(self): if not self.isMovable(): return self.rotate(180.) # inv = SRTTransform() # inv.scale(-1, -1) # self.userTransform = self.userTransform * inv #flip lr/ud # s=self.updateTransform() # self.setTranslate(-2*s['pos'][0], -2*s['pos'][1]) # self.selectBoxFromUser() def hasUserTransform(self): #print self.userRotate, self.userTranslate return not self.userTransform.isIdentity() def ctrlWidget(self): return self.ctrl def alphaChanged(self, val): alpha = val / 1023. self._graphicsItem.setOpacity(alpha) def isMovable(self): return self.opts['movable'] def selectBoxMoved(self): """The selection box has moved; get its transformation information and pass to the graphics item""" self.userTransform = self.selectBox.getGlobalTransform(relativeTo=self.selectBoxBase) self.updateTransform() def scale(self, x, y): self.userTransform.scale(x, y) self.selectBoxFromUser() self.updateTransform() def rotate(self, ang): self.userTransform.rotate(ang) self.selectBoxFromUser() self.updateTransform() def translate(self, x, y): self.userTransform.translate(x, y) self.selectBoxFromUser() self.updateTransform() def setTranslate(self, x, y): self.userTransform.setTranslate(x, y) self.selectBoxFromUser() self.updateTransform() def setRotate(self, angle): self.userTransform.setRotate(angle) self.selectBoxFromUser() self.updateTransform() def setScale(self, x, y): self.userTransform.setScale(x, y) self.selectBoxFromUser() self.updateTransform() def setTemporaryTransform(self, transform): self.tempTransform = transform self.updateTransform() def applyTemporaryTransform(self): """Collapses tempTransform into UserTransform, resets tempTransform""" self.userTransform = self.userTransform * self.tempTransform ## order is important! self.resetTemporaryTransform() self.selectBoxFromUser() ## update the selection box to match the new userTransform #st = self.userTransform.saveState() #self.userTransform = self.userTransform * self.tempTransform ## order is important! #### matrix multiplication affects the scale factors, need to reset #if st['scale'][0] < 0 or st['scale'][1] < 0: #nst = self.userTransform.saveState() #self.userTransform.setScale([-nst['scale'][0], -nst['scale'][1]]) #self.resetTemporaryTransform() #self.selectBoxFromUser() #self.selectBoxChangeFinished() def resetTemporaryTransform(self): self.tempTransform = SRTTransform() ## don't use Transform.reset()--this transform might be used elsewhere. self.updateTransform() def transform(self): return self._graphicsItem.transform() def updateTransform(self): """Regenerate the item position from the base, user, and temp transforms""" transform = self.baseTransform * self.userTransform * self.tempTransform ## order is important s = transform.saveState() self._graphicsItem.setPos(*s['pos']) self.itemRotation.setAngle(s['angle']) self.itemScale.setXScale(s['scale'][0]) self.itemScale.setYScale(s['scale'][1]) self.displayTransform(transform) return(s) # return the transform state def displayTransform(self, transform): """Updates transform numbers in the ctrl widget.""" tr = transform.saveState() self.transformGui.translateLabel.setText("Translate: (%f, %f)" %(tr['pos'][0], tr['pos'][1])) self.transformGui.rotateLabel.setText("Rotate: %f degrees" %tr['angle']) self.transformGui.scaleLabel.setText("Scale: (%f, %f)" %(tr['scale'][0], tr['scale'][1])) #self.transformGui.mirrorImageCheck.setChecked(False) #if tr['scale'][0] < 0: # self.transformGui.mirrorImageCheck.setChecked(True) def resetUserTransform(self): #self.userRotate = 0 #self.userTranslate = pg.Point(0,0) self.userTransform.reset() self.updateTransform() self.selectBox.blockSignals(True) self.selectBoxToItem() self.selectBox.blockSignals(False) self.sigTransformChanged.emit(self) self.sigTransformChangeFinished.emit(self) def resetTransformClicked(self): self.resetUserTransform() self.sigResetUserTransform.emit(self) def restoreTransform(self, tr): try: #self.userTranslate = pg.Point(tr['trans']) #self.userRotate = tr['rot'] self.userTransform = SRTTransform(tr) self.updateTransform() self.selectBoxFromUser() ## move select box to match self.sigTransformChanged.emit(self) self.sigTransformChangeFinished.emit(self) except: #self.userTranslate = pg.Point([0,0]) #self.userRotate = 0 self.userTransform = SRTTransform() debug.printExc("Failed to load transform:") #print "set transform", self, self.userTranslate def saveTransform(self): """Return a dict containing the current user transform""" #print "save transform", self, self.userTranslate #return {'trans': list(self.userTranslate), 'rot': self.userRotate} return self.userTransform.saveState() def selectBoxFromUser(self): """Move the selection box to match the current userTransform""" ## user transform #trans = QtGui.QTransform() #trans.translate(*self.userTranslate) #trans.rotate(-self.userRotate) #x2, y2 = trans.map(*self.selectBoxBase['pos']) self.selectBox.blockSignals(True) self.selectBox.setState(self.selectBoxBase) self.selectBox.applyGlobalTransform(self.userTransform) #self.selectBox.setAngle(self.userRotate) #self.selectBox.setPos([x2, y2]) self.selectBox.blockSignals(False) def selectBoxToItem(self): """Move/scale the selection box so it fits the item's bounding rect. (assumes item is not rotated)""" self.itemRect = self._graphicsItem.boundingRect() rect = self._graphicsItem.mapRectToParent(self.itemRect) self.selectBox.blockSignals(True) self.selectBox.setPos([rect.x(), rect.y()]) self.selectBox.setSize(rect.size()) self.selectBox.setAngle(0) self.selectBoxBase = self.selectBox.getState().copy() self.selectBox.blockSignals(False) def zValue(self): return self.opts['z'] def setZValue(self, z): self.opts['z'] = z if z is not None: self._graphicsItem.setZValue(z) #def selectionChanged(self, canvas, items): #self.selected = len(items) == 1 and (items[0] is self) #self.showSelectBox() def selectionChanged(self, sel, multi): """ Inform the item that its selection state has changed. ============== ========================================================= **Arguments:** sel (bool) whether the item is currently selected multi (bool) whether there are multiple items currently selected ============== ========================================================= """ self.selectedAlone = sel and not multi self.showSelectBox() if self.selectedAlone: self.ctrlWidget().show() else: self.ctrlWidget().hide() def showSelectBox(self): """Display the selection box around this item if it is selected and movable""" if self.selectedAlone and self.isMovable() and self.isVisible(): #and len(self.canvas.itemList.selectedItems())==1: self.selectBox.show() else: self.selectBox.hide() def hideSelectBox(self): self.selectBox.hide() def selectBoxChanged(self): self.selectBoxMoved() #self.updateTransform(self.selectBox) #self.emit(QtCore.SIGNAL('transformChanged'), self) self.sigTransformChanged.emit(self) def selectBoxChangeFinished(self): #self.emit(QtCore.SIGNAL('transformChangeFinished'), self) self.sigTransformChangeFinished.emit(self) def alphaPressed(self): """Hide selection box while slider is moving""" self.hideSelectBox() def alphaReleased(self): self.showSelectBox() def show(self): if self.opts['visible']: return self.opts['visible'] = True self._graphicsItem.show() self.showSelectBox() self.sigVisibilityChanged.emit(self) def hide(self): if not self.opts['visible']: return self.opts['visible'] = False self._graphicsItem.hide() self.hideSelectBox() self.sigVisibilityChanged.emit(self) def setVisible(self, vis): if vis: self.show() else: self.hide() def isVisible(self): return self.opts['visible'] class GroupCanvasItem(CanvasItem): """ Canvas item used for grouping others """ def __init__(self, **opts): defOpts = {'movable': False, 'scalable': False} defOpts.update(opts) item = ItemGroup() CanvasItem.__init__(self, item, **defOpts) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/canvas/CanvasManager.py000066400000000000000000000042361300727121400242000ustar00rootroot00000000000000# -*- coding: utf-8 -*- from ..Qt import QtCore, QtGui if not hasattr(QtCore, 'Signal'): QtCore.Signal = QtCore.pyqtSignal import weakref class CanvasManager(QtCore.QObject): SINGLETON = None sigCanvasListChanged = QtCore.Signal() def __init__(self): if CanvasManager.SINGLETON is not None: raise Exception("Can only create one canvas manager.") CanvasManager.SINGLETON = self QtCore.QObject.__init__(self) self.canvases = weakref.WeakValueDictionary() @classmethod def instance(cls): return CanvasManager.SINGLETON def registerCanvas(self, canvas, name): n2 = name i = 0 while n2 in self.canvases: n2 = "%s_%03d" % (name, i) i += 1 self.canvases[n2] = canvas self.sigCanvasListChanged.emit() return n2 def unregisterCanvas(self, name): c = self.canvases[name] del self.canvases[name] self.sigCanvasListChanged.emit() def listCanvases(self): return list(self.canvases.keys()) def getCanvas(self, name): return self.canvases[name] manager = CanvasManager() class CanvasCombo(QtGui.QComboBox): def __init__(self, parent=None): QtGui.QComboBox.__init__(self, parent) man = CanvasManager.instance() man.sigCanvasListChanged.connect(self.updateCanvasList) self.hostName = None self.updateCanvasList() def updateCanvasList(self): canvases = CanvasManager.instance().listCanvases() canvases.insert(0, "") if self.hostName in canvases: canvases.remove(self.hostName) sel = self.currentText() if sel in canvases: self.blockSignals(True) ## change does not affect current selection; block signals during update self.clear() for i in canvases: self.addItem(i) if i == sel: self.setCurrentIndex(self.count()) self.blockSignals(False) def setHostName(self, name): self.hostName = name self.updateCanvasList() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/canvas/CanvasTemplate.ui000066400000000000000000000076031300727121400243670ustar00rootroot00000000000000 Form 0 0 490 414 Form 0 0 Qt::Horizontal 0 1 Auto Range 0 Check to display all local items in a remote canvas. Redirect 0 100 true 1 0 Reset Transforms Mirror Selection MirrorXY TreeWidget QTreeWidget
..widgets.TreeWidget
 GraphicsView QGraphicsView
..widgets.GraphicsView
 CanvasCombo QComboBox
CanvasManager
 pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/canvas/CanvasTemplate_pyqt.py000066400000000000000000000120061300727121400254500ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file 'acq4/pyqtgraph/canvas/CanvasTemplate.ui' # # Created: Thu Jan 2 11:13:07 2014 # by: PyQt4 UI code generator 4.9 # # WARNING! All changes made in this file will be lost! from PyQt4 import QtCore, QtGui try: _fromUtf8 = QtCore.QString.fromUtf8 except AttributeError: _fromUtf8 = lambda s: s class Ui_Form(object): def setupUi(self, Form): Form.setObjectName(_fromUtf8("Form")) Form.resize(490, 414) self.gridLayout = QtGui.QGridLayout(Form) self.gridLayout.setMargin(0) self.gridLayout.setSpacing(0) self.gridLayout.setObjectName(_fromUtf8("gridLayout")) self.splitter = QtGui.QSplitter(Form) self.splitter.setOrientation(QtCore.Qt.Horizontal) self.splitter.setObjectName(_fromUtf8("splitter")) self.view = GraphicsView(self.splitter) self.view.setObjectName(_fromUtf8("view")) self.layoutWidget = QtGui.QWidget(self.splitter) self.layoutWidget.setObjectName(_fromUtf8("layoutWidget")) self.gridLayout_2 = QtGui.QGridLayout(self.layoutWidget) self.gridLayout_2.setMargin(0) self.gridLayout_2.setObjectName(_fromUtf8("gridLayout_2")) self.autoRangeBtn = QtGui.QPushButton(self.layoutWidget) sizePolicy = QtGui.QSizePolicy(QtGui.QSizePolicy.Minimum, QtGui.QSizePolicy.Fixed) sizePolicy.setHorizontalStretch(0) sizePolicy.setVerticalStretch(1) sizePolicy.setHeightForWidth(self.autoRangeBtn.sizePolicy().hasHeightForWidth()) self.autoRangeBtn.setSizePolicy(sizePolicy) self.autoRangeBtn.setObjectName(_fromUtf8("autoRangeBtn")) self.gridLayout_2.addWidget(self.autoRangeBtn, 2, 0, 1, 2) self.horizontalLayout = QtGui.QHBoxLayout() self.horizontalLayout.setSpacing(0) self.horizontalLayout.setObjectName(_fromUtf8("horizontalLayout")) self.redirectCheck = QtGui.QCheckBox(self.layoutWidget) self.redirectCheck.setObjectName(_fromUtf8("redirectCheck")) self.horizontalLayout.addWidget(self.redirectCheck) self.redirectCombo = CanvasCombo(self.layoutWidget) self.redirectCombo.setObjectName(_fromUtf8("redirectCombo")) self.horizontalLayout.addWidget(self.redirectCombo) self.gridLayout_2.addLayout(self.horizontalLayout, 5, 0, 1, 2) self.itemList = TreeWidget(self.layoutWidget) sizePolicy = QtGui.QSizePolicy(QtGui.QSizePolicy.Expanding, QtGui.QSizePolicy.Expanding) sizePolicy.setHorizontalStretch(0) sizePolicy.setVerticalStretch(100) sizePolicy.setHeightForWidth(self.itemList.sizePolicy().hasHeightForWidth()) self.itemList.setSizePolicy(sizePolicy) self.itemList.setHeaderHidden(True) self.itemList.setObjectName(_fromUtf8("itemList")) self.itemList.headerItem().setText(0, _fromUtf8("1")) self.gridLayout_2.addWidget(self.itemList, 6, 0, 1, 2) self.ctrlLayout = QtGui.QGridLayout() self.ctrlLayout.setSpacing(0) self.ctrlLayout.setObjectName(_fromUtf8("ctrlLayout")) self.gridLayout_2.addLayout(self.ctrlLayout, 10, 0, 1, 2) self.resetTransformsBtn = QtGui.QPushButton(self.layoutWidget) self.resetTransformsBtn.setObjectName(_fromUtf8("resetTransformsBtn")) self.gridLayout_2.addWidget(self.resetTransformsBtn, 7, 0, 1, 1) self.mirrorSelectionBtn = QtGui.QPushButton(self.layoutWidget) self.mirrorSelectionBtn.setObjectName(_fromUtf8("mirrorSelectionBtn")) self.gridLayout_2.addWidget(self.mirrorSelectionBtn, 3, 0, 1, 1) self.reflectSelectionBtn = QtGui.QPushButton(self.layoutWidget) self.reflectSelectionBtn.setObjectName(_fromUtf8("reflectSelectionBtn")) self.gridLayout_2.addWidget(self.reflectSelectionBtn, 3, 1, 1, 1) self.gridLayout.addWidget(self.splitter, 0, 0, 1, 1) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): Form.setWindowTitle(QtGui.QApplication.translate("Form", "Form", None, QtGui.QApplication.UnicodeUTF8)) self.autoRangeBtn.setText(QtGui.QApplication.translate("Form", "Auto Range", None, QtGui.QApplication.UnicodeUTF8)) self.redirectCheck.setToolTip(QtGui.QApplication.translate("Form", "Check to display all local items in a remote canvas.", None, QtGui.QApplication.UnicodeUTF8)) self.redirectCheck.setText(QtGui.QApplication.translate("Form", "Redirect", None, QtGui.QApplication.UnicodeUTF8)) self.resetTransformsBtn.setText(QtGui.QApplication.translate("Form", "Reset Transforms", None, QtGui.QApplication.UnicodeUTF8)) self.mirrorSelectionBtn.setText(QtGui.QApplication.translate("Form", "Mirror Selection", None, QtGui.QApplication.UnicodeUTF8)) self.reflectSelectionBtn.setText(QtGui.QApplication.translate("Form", "MirrorXY", None, QtGui.QApplication.UnicodeUTF8)) from ..widgets.TreeWidget import TreeWidget from CanvasManager import CanvasCombo from ..widgets.GraphicsView import GraphicsView pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/canvas/CanvasTemplate_pyqt5.py000066400000000000000000000120221300727121400255330ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './pyqtgraph/canvas/CanvasTemplate.ui' # # Created: Wed Mar 26 15:09:28 2014 # by: PyQt5 UI code generator 5.0.1 # # WARNING! All changes made in this file will be lost! from PyQt5 import QtCore, QtGui, QtWidgets class Ui_Form(object): def setupUi(self, Form): Form.setObjectName("Form") Form.resize(490, 414) self.gridLayout = QtWidgets.QGridLayout(Form) self.gridLayout.setContentsMargins(0, 0, 0, 0) self.gridLayout.setSpacing(0) self.gridLayout.setObjectName("gridLayout") self.splitter = QtWidgets.QSplitter(Form) self.splitter.setOrientation(QtCore.Qt.Horizontal) self.splitter.setObjectName("splitter") self.view = GraphicsView(self.splitter) self.view.setObjectName("view") self.layoutWidget = QtWidgets.QWidget(self.splitter) self.layoutWidget.setObjectName("layoutWidget") self.gridLayout_2 = QtWidgets.QGridLayout(self.layoutWidget) self.gridLayout_2.setContentsMargins(0, 0, 0, 0) self.gridLayout_2.setObjectName("gridLayout_2") self.storeSvgBtn = QtWidgets.QPushButton(self.layoutWidget) self.storeSvgBtn.setObjectName("storeSvgBtn") self.gridLayout_2.addWidget(self.storeSvgBtn, 1, 0, 1, 1) self.storePngBtn = QtWidgets.QPushButton(self.layoutWidget) self.storePngBtn.setObjectName("storePngBtn") self.gridLayout_2.addWidget(self.storePngBtn, 1, 1, 1, 1) self.autoRangeBtn = QtWidgets.QPushButton(self.layoutWidget) sizePolicy = QtWidgets.QSizePolicy(QtWidgets.QSizePolicy.Minimum, QtWidgets.QSizePolicy.Fixed) sizePolicy.setHorizontalStretch(0) sizePolicy.setVerticalStretch(1) sizePolicy.setHeightForWidth(self.autoRangeBtn.sizePolicy().hasHeightForWidth()) self.autoRangeBtn.setSizePolicy(sizePolicy) self.autoRangeBtn.setObjectName("autoRangeBtn") self.gridLayout_2.addWidget(self.autoRangeBtn, 3, 0, 1, 2) self.horizontalLayout = QtWidgets.QHBoxLayout() self.horizontalLayout.setSpacing(0) self.horizontalLayout.setObjectName("horizontalLayout") self.redirectCheck = QtWidgets.QCheckBox(self.layoutWidget) self.redirectCheck.setObjectName("redirectCheck") self.horizontalLayout.addWidget(self.redirectCheck) self.redirectCombo = CanvasCombo(self.layoutWidget) self.redirectCombo.setObjectName("redirectCombo") self.horizontalLayout.addWidget(self.redirectCombo) self.gridLayout_2.addLayout(self.horizontalLayout, 6, 0, 1, 2) self.itemList = TreeWidget(self.layoutWidget) sizePolicy = QtWidgets.QSizePolicy(QtWidgets.QSizePolicy.Expanding, QtWidgets.QSizePolicy.Expanding) sizePolicy.setHorizontalStretch(0) sizePolicy.setVerticalStretch(100) sizePolicy.setHeightForWidth(self.itemList.sizePolicy().hasHeightForWidth()) self.itemList.setSizePolicy(sizePolicy) self.itemList.setHeaderHidden(True) self.itemList.setObjectName("itemList") self.itemList.headerItem().setText(0, "1") self.gridLayout_2.addWidget(self.itemList, 7, 0, 1, 2) self.ctrlLayout = QtWidgets.QGridLayout() self.ctrlLayout.setSpacing(0) self.ctrlLayout.setObjectName("ctrlLayout") self.gridLayout_2.addLayout(self.ctrlLayout, 11, 0, 1, 2) self.resetTransformsBtn = QtWidgets.QPushButton(self.layoutWidget) self.resetTransformsBtn.setObjectName("resetTransformsBtn") self.gridLayout_2.addWidget(self.resetTransformsBtn, 8, 0, 1, 1) self.mirrorSelectionBtn = QtWidgets.QPushButton(self.layoutWidget) self.mirrorSelectionBtn.setObjectName("mirrorSelectionBtn") self.gridLayout_2.addWidget(self.mirrorSelectionBtn, 4, 0, 1, 1) self.reflectSelectionBtn = QtWidgets.QPushButton(self.layoutWidget) self.reflectSelectionBtn.setObjectName("reflectSelectionBtn") self.gridLayout_2.addWidget(self.reflectSelectionBtn, 4, 1, 1, 1) self.gridLayout.addWidget(self.splitter, 0, 0, 1, 1) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): _translate = QtCore.QCoreApplication.translate Form.setWindowTitle(_translate("Form", "Form")) self.storeSvgBtn.setText(_translate("Form", "Store SVG")) self.storePngBtn.setText(_translate("Form", "Store PNG")) self.autoRangeBtn.setText(_translate("Form", "Auto Range")) self.redirectCheck.setToolTip(_translate("Form", "Check to display all local items in a remote canvas.")) self.redirectCheck.setText(_translate("Form", "Redirect")) self.resetTransformsBtn.setText(_translate("Form", "Reset Transforms")) self.mirrorSelectionBtn.setText(_translate("Form", "Mirror Selection")) self.reflectSelectionBtn.setText(_translate("Form", "MirrorXY")) from ..widgets.GraphicsView import GraphicsView from ..widgets.TreeWidget import TreeWidget from CanvasManager import CanvasCombo pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/canvas/CanvasTemplate_pyside.py000066400000000000000000000126111300727121400257520ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './pyqtgraph/canvas/CanvasTemplate.ui' # # Created: Mon Dec 23 10:10:52 2013 # by: pyside-uic 0.2.14 running on PySide 1.1.2 # # WARNING! All changes made in this file will be lost! from PySide import QtCore, QtGui class Ui_Form(object): def setupUi(self, Form): Form.setObjectName("Form") Form.resize(490, 414) self.gridLayout = QtGui.QGridLayout(Form) self.gridLayout.setContentsMargins(0, 0, 0, 0) self.gridLayout.setSpacing(0) self.gridLayout.setObjectName("gridLayout") self.splitter = QtGui.QSplitter(Form) self.splitter.setOrientation(QtCore.Qt.Horizontal) self.splitter.setObjectName("splitter") self.view = GraphicsView(self.splitter) self.view.setObjectName("view") self.layoutWidget = QtGui.QWidget(self.splitter) self.layoutWidget.setObjectName("layoutWidget") self.gridLayout_2 = QtGui.QGridLayout(self.layoutWidget) self.gridLayout_2.setContentsMargins(0, 0, 0, 0) self.gridLayout_2.setObjectName("gridLayout_2") self.storeSvgBtn = QtGui.QPushButton(self.layoutWidget) self.storeSvgBtn.setObjectName("storeSvgBtn") self.gridLayout_2.addWidget(self.storeSvgBtn, 1, 0, 1, 1) self.storePngBtn = QtGui.QPushButton(self.layoutWidget) self.storePngBtn.setObjectName("storePngBtn") self.gridLayout_2.addWidget(self.storePngBtn, 1, 1, 1, 1) self.autoRangeBtn = QtGui.QPushButton(self.layoutWidget) sizePolicy = QtGui.QSizePolicy(QtGui.QSizePolicy.Minimum, QtGui.QSizePolicy.Fixed) sizePolicy.setHorizontalStretch(0) sizePolicy.setVerticalStretch(1) sizePolicy.setHeightForWidth(self.autoRangeBtn.sizePolicy().hasHeightForWidth()) self.autoRangeBtn.setSizePolicy(sizePolicy) self.autoRangeBtn.setObjectName("autoRangeBtn") self.gridLayout_2.addWidget(self.autoRangeBtn, 3, 0, 1, 2) self.horizontalLayout = QtGui.QHBoxLayout() self.horizontalLayout.setSpacing(0) self.horizontalLayout.setObjectName("horizontalLayout") self.redirectCheck = QtGui.QCheckBox(self.layoutWidget) self.redirectCheck.setObjectName("redirectCheck") self.horizontalLayout.addWidget(self.redirectCheck) self.redirectCombo = CanvasCombo(self.layoutWidget) self.redirectCombo.setObjectName("redirectCombo") self.horizontalLayout.addWidget(self.redirectCombo) self.gridLayout_2.addLayout(self.horizontalLayout, 6, 0, 1, 2) self.itemList = TreeWidget(self.layoutWidget) sizePolicy = QtGui.QSizePolicy(QtGui.QSizePolicy.Expanding, QtGui.QSizePolicy.Expanding) sizePolicy.setHorizontalStretch(0) sizePolicy.setVerticalStretch(100) sizePolicy.setHeightForWidth(self.itemList.sizePolicy().hasHeightForWidth()) self.itemList.setSizePolicy(sizePolicy) self.itemList.setHeaderHidden(True) self.itemList.setObjectName("itemList") self.itemList.headerItem().setText(0, "1") self.gridLayout_2.addWidget(self.itemList, 7, 0, 1, 2) self.ctrlLayout = QtGui.QGridLayout() self.ctrlLayout.setSpacing(0) self.ctrlLayout.setObjectName("ctrlLayout") self.gridLayout_2.addLayout(self.ctrlLayout, 11, 0, 1, 2) self.resetTransformsBtn = QtGui.QPushButton(self.layoutWidget) self.resetTransformsBtn.setObjectName("resetTransformsBtn") self.gridLayout_2.addWidget(self.resetTransformsBtn, 8, 0, 1, 1) self.mirrorSelectionBtn = QtGui.QPushButton(self.layoutWidget) self.mirrorSelectionBtn.setObjectName("mirrorSelectionBtn") self.gridLayout_2.addWidget(self.mirrorSelectionBtn, 4, 0, 1, 1) self.reflectSelectionBtn = QtGui.QPushButton(self.layoutWidget) self.reflectSelectionBtn.setObjectName("reflectSelectionBtn") self.gridLayout_2.addWidget(self.reflectSelectionBtn, 4, 1, 1, 1) self.gridLayout.addWidget(self.splitter, 0, 0, 1, 1) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): Form.setWindowTitle(QtGui.QApplication.translate("Form", "Form", None, QtGui.QApplication.UnicodeUTF8)) self.storeSvgBtn.setText(QtGui.QApplication.translate("Form", "Store SVG", None, QtGui.QApplication.UnicodeUTF8)) self.storePngBtn.setText(QtGui.QApplication.translate("Form", "Store PNG", None, QtGui.QApplication.UnicodeUTF8)) self.autoRangeBtn.setText(QtGui.QApplication.translate("Form", "Auto Range", None, QtGui.QApplication.UnicodeUTF8)) self.redirectCheck.setToolTip(QtGui.QApplication.translate("Form", "Check to display all local items in a remote canvas.", None, QtGui.QApplication.UnicodeUTF8)) self.redirectCheck.setText(QtGui.QApplication.translate("Form", "Redirect", None, QtGui.QApplication.UnicodeUTF8)) self.resetTransformsBtn.setText(QtGui.QApplication.translate("Form", "Reset Transforms", None, QtGui.QApplication.UnicodeUTF8)) self.mirrorSelectionBtn.setText(QtGui.QApplication.translate("Form", "Mirror Selection", None, QtGui.QApplication.UnicodeUTF8)) self.reflectSelectionBtn.setText(QtGui.QApplication.translate("Form", "MirrorXY", None, QtGui.QApplication.UnicodeUTF8)) from ..widgets.TreeWidget import TreeWidget from CanvasManager import CanvasCombo from ..widgets.GraphicsView import GraphicsView pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/canvas/TransformGuiTemplate.ui000066400000000000000000000034231300727121400255700ustar00rootroot00000000000000 Form 0 0 224 117 0 0 Form 1 0 Translate: Rotate: Scale: Mirror Reflect pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/canvas/TransformGuiTemplate_pyqt.py000066400000000000000000000057131300727121400266640ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './pyqtgraph/canvas/TransformGuiTemplate.ui' # # Created: Mon Dec 23 10:10:52 2013 # by: PyQt4 UI code generator 4.10 # # WARNING! All changes made in this file will be lost! from PyQt4 import QtCore, QtGui try: _fromUtf8 = QtCore.QString.fromUtf8 except AttributeError: def _fromUtf8(s): return s try: _encoding = QtGui.QApplication.UnicodeUTF8 def _translate(context, text, disambig): return QtGui.QApplication.translate(context, text, disambig, _encoding) except AttributeError: def _translate(context, text, disambig): return QtGui.QApplication.translate(context, text, disambig) class Ui_Form(object): def setupUi(self, Form): Form.setObjectName(_fromUtf8("Form")) Form.resize(224, 117) sizePolicy = QtGui.QSizePolicy(QtGui.QSizePolicy.Preferred, QtGui.QSizePolicy.Preferred) sizePolicy.setHorizontalStretch(0) sizePolicy.setVerticalStretch(0) sizePolicy.setHeightForWidth(Form.sizePolicy().hasHeightForWidth()) Form.setSizePolicy(sizePolicy) self.verticalLayout = QtGui.QVBoxLayout(Form) self.verticalLayout.setSpacing(1) self.verticalLayout.setMargin(0) self.verticalLayout.setObjectName(_fromUtf8("verticalLayout")) self.translateLabel = QtGui.QLabel(Form) self.translateLabel.setObjectName(_fromUtf8("translateLabel")) self.verticalLayout.addWidget(self.translateLabel) self.rotateLabel = QtGui.QLabel(Form) self.rotateLabel.setObjectName(_fromUtf8("rotateLabel")) self.verticalLayout.addWidget(self.rotateLabel) self.scaleLabel = QtGui.QLabel(Form) self.scaleLabel.setObjectName(_fromUtf8("scaleLabel")) self.verticalLayout.addWidget(self.scaleLabel) self.horizontalLayout = QtGui.QHBoxLayout() self.horizontalLayout.setObjectName(_fromUtf8("horizontalLayout")) self.mirrorImageBtn = QtGui.QPushButton(Form) self.mirrorImageBtn.setToolTip(_fromUtf8("")) self.mirrorImageBtn.setObjectName(_fromUtf8("mirrorImageBtn")) self.horizontalLayout.addWidget(self.mirrorImageBtn) self.reflectImageBtn = QtGui.QPushButton(Form) self.reflectImageBtn.setObjectName(_fromUtf8("reflectImageBtn")) self.horizontalLayout.addWidget(self.reflectImageBtn) self.verticalLayout.addLayout(self.horizontalLayout) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): Form.setWindowTitle(_translate("Form", "Form", None)) self.translateLabel.setText(_translate("Form", "Translate:", None)) self.rotateLabel.setText(_translate("Form", "Rotate:", None)) self.scaleLabel.setText(_translate("Form", "Scale:", None)) self.mirrorImageBtn.setText(_translate("Form", "Mirror", None)) self.reflectImageBtn.setText(_translate("Form", "Reflect", None)) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/canvas/TransformGuiTemplate_pyqt5.py000066400000000000000000000050321300727121400267430ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './pyqtgraph/canvas/TransformGuiTemplate.ui' # # Created: Wed Mar 26 15:09:28 2014 # by: PyQt5 UI code generator 5.0.1 # # WARNING! All changes made in this file will be lost! from PyQt5 import QtCore, QtGui, QtWidgets class Ui_Form(object): def setupUi(self, Form): Form.setObjectName("Form") Form.resize(224, 117) sizePolicy = QtWidgets.QSizePolicy(QtWidgets.QSizePolicy.Preferred, QtWidgets.QSizePolicy.Preferred) sizePolicy.setHorizontalStretch(0) sizePolicy.setVerticalStretch(0) sizePolicy.setHeightForWidth(Form.sizePolicy().hasHeightForWidth()) Form.setSizePolicy(sizePolicy) self.verticalLayout = QtWidgets.QVBoxLayout(Form) self.verticalLayout.setSpacing(1) self.verticalLayout.setContentsMargins(0, 0, 0, 0) self.verticalLayout.setObjectName("verticalLayout") self.translateLabel = QtWidgets.QLabel(Form) self.translateLabel.setObjectName("translateLabel") self.verticalLayout.addWidget(self.translateLabel) self.rotateLabel = QtWidgets.QLabel(Form) self.rotateLabel.setObjectName("rotateLabel") self.verticalLayout.addWidget(self.rotateLabel) self.scaleLabel = QtWidgets.QLabel(Form) self.scaleLabel.setObjectName("scaleLabel") self.verticalLayout.addWidget(self.scaleLabel) self.horizontalLayout = QtWidgets.QHBoxLayout() self.horizontalLayout.setObjectName("horizontalLayout") self.mirrorImageBtn = QtWidgets.QPushButton(Form) self.mirrorImageBtn.setToolTip("") self.mirrorImageBtn.setObjectName("mirrorImageBtn") self.horizontalLayout.addWidget(self.mirrorImageBtn) self.reflectImageBtn = QtWidgets.QPushButton(Form) self.reflectImageBtn.setObjectName("reflectImageBtn") self.horizontalLayout.addWidget(self.reflectImageBtn) self.verticalLayout.addLayout(self.horizontalLayout) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): _translate = QtCore.QCoreApplication.translate Form.setWindowTitle(_translate("Form", "Form")) self.translateLabel.setText(_translate("Form", "Translate:")) self.rotateLabel.setText(_translate("Form", "Rotate:")) self.scaleLabel.setText(_translate("Form", "Scale:")) self.mirrorImageBtn.setText(_translate("Form", "Mirror")) self.reflectImageBtn.setText(_translate("Form", "Reflect")) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/canvas/TransformGuiTemplate_pyside.py000066400000000000000000000054151300727121400271630ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './pyqtgraph/canvas/TransformGuiTemplate.ui' # # Created: Mon Dec 23 10:10:52 2013 # by: pyside-uic 0.2.14 running on PySide 1.1.2 # # WARNING! All changes made in this file will be lost! from PySide import QtCore, QtGui class Ui_Form(object): def setupUi(self, Form): Form.setObjectName("Form") Form.resize(224, 117) sizePolicy = QtGui.QSizePolicy(QtGui.QSizePolicy.Preferred, QtGui.QSizePolicy.Preferred) sizePolicy.setHorizontalStretch(0) sizePolicy.setVerticalStretch(0) sizePolicy.setHeightForWidth(Form.sizePolicy().hasHeightForWidth()) Form.setSizePolicy(sizePolicy) self.verticalLayout = QtGui.QVBoxLayout(Form) self.verticalLayout.setSpacing(1) self.verticalLayout.setContentsMargins(0, 0, 0, 0) self.verticalLayout.setObjectName("verticalLayout") self.translateLabel = QtGui.QLabel(Form) self.translateLabel.setObjectName("translateLabel") self.verticalLayout.addWidget(self.translateLabel) self.rotateLabel = QtGui.QLabel(Form) self.rotateLabel.setObjectName("rotateLabel") self.verticalLayout.addWidget(self.rotateLabel) self.scaleLabel = QtGui.QLabel(Form) self.scaleLabel.setObjectName("scaleLabel") self.verticalLayout.addWidget(self.scaleLabel) self.horizontalLayout = QtGui.QHBoxLayout() self.horizontalLayout.setObjectName("horizontalLayout") self.mirrorImageBtn = QtGui.QPushButton(Form) self.mirrorImageBtn.setToolTip("") self.mirrorImageBtn.setObjectName("mirrorImageBtn") self.horizontalLayout.addWidget(self.mirrorImageBtn) self.reflectImageBtn = QtGui.QPushButton(Form) self.reflectImageBtn.setObjectName("reflectImageBtn") self.horizontalLayout.addWidget(self.reflectImageBtn) self.verticalLayout.addLayout(self.horizontalLayout) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): Form.setWindowTitle(QtGui.QApplication.translate("Form", "Form", None, QtGui.QApplication.UnicodeUTF8)) self.translateLabel.setText(QtGui.QApplication.translate("Form", "Translate:", None, QtGui.QApplication.UnicodeUTF8)) self.rotateLabel.setText(QtGui.QApplication.translate("Form", "Rotate:", None, QtGui.QApplication.UnicodeUTF8)) self.scaleLabel.setText(QtGui.QApplication.translate("Form", "Scale:", None, QtGui.QApplication.UnicodeUTF8)) self.mirrorImageBtn.setText(QtGui.QApplication.translate("Form", "Mirror", None, QtGui.QApplication.UnicodeUTF8)) self.reflectImageBtn.setText(QtGui.QApplication.translate("Form", "Reflect", None, QtGui.QApplication.UnicodeUTF8)) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/canvas/__init__.py000066400000000000000000000001071300727121400232220ustar00rootroot00000000000000# -*- coding: utf-8 -*- from .Canvas import * from .CanvasItem import *pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/colormap.py000066400000000000000000000231601300727121400220300ustar00rootroot00000000000000import numpy as np from .Qt import QtGui, QtCore from .python2_3 import basestring class ColorMap(object): """ A ColorMap defines a relationship between a scalar value and a range of colors. ColorMaps are commonly used for false-coloring monochromatic images, coloring scatter-plot points, and coloring surface plots by height. Each color map is defined by a set of colors, each corresponding to a particular scalar value. For example: | 0.0 -> black | 0.2 -> red | 0.6 -> yellow | 1.0 -> white The colors for intermediate values are determined by interpolating between the two nearest colors in either RGB or HSV color space. To provide user-defined color mappings, see :class:`GradientWidget `. """ ## color interpolation modes RGB = 1 HSV_POS = 2 HSV_NEG = 3 ## boundary modes CLIP = 1 REPEAT = 2 MIRROR = 3 ## return types BYTE = 1 FLOAT = 2 QCOLOR = 3 enumMap = { 'rgb': RGB, 'hsv+': HSV_POS, 'hsv-': HSV_NEG, 'clip': CLIP, 'repeat': REPEAT, 'mirror': MIRROR, 'byte': BYTE, 'float': FLOAT, 'qcolor': QCOLOR, } def __init__(self, pos, color, mode=None): """ =============== ============================================================== **Arguments:** pos Array of positions where each color is defined color Array of RGBA colors. Integer data types are interpreted as 0-255; float data types are interpreted as 0.0-1.0 mode Array of color modes (ColorMap.RGB, HSV_POS, or HSV_NEG) indicating the color space that should be used when interpolating between stops. Note that the last mode value is ignored. By default, the mode is entirely RGB. =============== ============================================================== """ self.pos = np.array(pos) order = np.argsort(self.pos) self.pos = self.pos[order] self.color = np.array(color)[order] if mode is None: mode = np.ones(len(pos)) self.mode = mode self.stopsCache = {} def map(self, data, mode='byte'): """ Return an array of colors corresponding to the values in *data*. Data must be either a scalar position or an array (any shape) of positions. The *mode* argument determines the type of data returned: =========== =============================================================== byte (default) Values are returned as 0-255 unsigned bytes. float Values are returned as 0.0-1.0 floats. qcolor Values are returned as an array of QColor objects. =========== =============================================================== """ if isinstance(mode, basestring): mode = self.enumMap[mode.lower()] if mode == self.QCOLOR: pos, color = self.getStops(self.BYTE) else: pos, color = self.getStops(mode) # don't need this--np.interp takes care of it. #data = np.clip(data, pos.min(), pos.max()) # Interpolate # TODO: is griddata faster? # interp = scipy.interpolate.griddata(pos, color, data) if np.isscalar(data): interp = np.empty((color.shape[1],), dtype=color.dtype) else: if not isinstance(data, np.ndarray): data = np.array(data) interp = np.empty(data.shape + (color.shape[1],), dtype=color.dtype) for i in range(color.shape[1]): interp[...,i] = np.interp(data, pos, color[:,i]) # Convert to QColor if requested if mode == self.QCOLOR: if np.isscalar(data): return QtGui.QColor(*interp) else: return [QtGui.QColor(*x) for x in interp] else: return interp def mapToQColor(self, data): """Convenience function; see :func:`map() `.""" return self.map(data, mode=self.QCOLOR) def mapToByte(self, data): """Convenience function; see :func:`map() `.""" return self.map(data, mode=self.BYTE) def mapToFloat(self, data): """Convenience function; see :func:`map() `.""" return self.map(data, mode=self.FLOAT) def getGradient(self, p1=None, p2=None): """Return a QLinearGradient object spanning from QPoints p1 to p2.""" if p1 == None: p1 = QtCore.QPointF(0,0) if p2 == None: p2 = QtCore.QPointF(self.pos.max()-self.pos.min(),0) g = QtGui.QLinearGradient(p1, p2) pos, color = self.getStops(mode=self.BYTE) color = [QtGui.QColor(*x) for x in color] g.setStops(zip(pos, color)) #if self.colorMode == 'rgb': #ticks = self.listTicks() #g.setStops([(x, QtGui.QColor(t.color)) for t,x in ticks]) #elif self.colorMode == 'hsv': ## HSV mode is approximated for display by interpolating 10 points between each stop #ticks = self.listTicks() #stops = [] #stops.append((ticks[0][1], ticks[0][0].color)) #for i in range(1,len(ticks)): #x1 = ticks[i-1][1] #x2 = ticks[i][1] #dx = (x2-x1) / 10. #for j in range(1,10): #x = x1 + dx*j #stops.append((x, self.getColor(x))) #stops.append((x2, self.getColor(x2))) #g.setStops(stops) return g def getColors(self, mode=None): """Return list of all color stops converted to the specified mode. If mode is None, then no conversion is done.""" if isinstance(mode, basestring): mode = self.enumMap[mode.lower()] color = self.color if mode in [self.BYTE, self.QCOLOR] and color.dtype.kind == 'f': color = (color * 255).astype(np.ubyte) elif mode == self.FLOAT and color.dtype.kind != 'f': color = color.astype(float) / 255. if mode == self.QCOLOR: color = [QtGui.QColor(*x) for x in color] return color def getStops(self, mode): ## Get fully-expanded set of RGBA stops in either float or byte mode. if mode not in self.stopsCache: color = self.color if mode == self.BYTE and color.dtype.kind == 'f': color = (color * 255).astype(np.ubyte) elif mode == self.FLOAT and color.dtype.kind != 'f': color = color.astype(float) / 255. ## to support HSV mode, we need to do a little more work.. #stops = [] #for i in range(len(self.pos)): #pos = self.pos[i] #color = color[i] #imode = self.mode[i] #if imode == self.RGB: #stops.append((x,color)) #else: #ns = self.stopsCache[mode] = (self.pos, color) return self.stopsCache[mode] def getLookupTable(self, start=0.0, stop=1.0, nPts=512, alpha=None, mode='byte'): """ Return an RGB(A) lookup table (ndarray). =============== ============================================================================= **Arguments:** start The starting value in the lookup table (default=0.0) stop The final value in the lookup table (default=1.0) nPts The number of points in the returned lookup table. alpha True, False, or None - Specifies whether or not alpha values are included in the table. If alpha is None, it will be automatically determined. mode Determines return type: 'byte' (0-255), 'float' (0.0-1.0), or 'qcolor'. See :func:`map() `. =============== ============================================================================= """ if isinstance(mode, basestring): mode = self.enumMap[mode.lower()] if alpha is None: alpha = self.usesAlpha() x = np.linspace(start, stop, nPts) table = self.map(x, mode) if not alpha: return table[:,:3] else: return table def usesAlpha(self): """Return True if any stops have an alpha < 255""" max = 1.0 if self.color.dtype.kind == 'f' else 255 return np.any(self.color[:,3] != max) def isMapTrivial(self): """ Return True if the gradient has exactly two stops in it: black at 0.0 and white at 1.0. """ if len(self.pos) != 2: return False if self.pos[0] != 0.0 or self.pos[1] != 1.0: return False if self.color.dtype.kind == 'f': return np.all(self.color == np.array([[0.,0.,0.,1.], [1.,1.,1.,1.]])) else: return np.all(self.color == np.array([[0,0,0,255], [255,255,255,255]])) def __repr__(self): pos = repr(self.pos).replace('\n', '') color = repr(self.color).replace('\n', '') return "ColorMap(%s, %s)" % (pos, color) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/configfile.py000066400000000000000000000151701300727121400223230ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ configfile.py - Human-readable text configuration file library Copyright 2010 Luke Campagnola Distributed under MIT/X11 license. See license.txt for more infomation. Used for reading and writing dictionary objects to a python-like configuration file format. Data structures may be nested and contain any data type as long as it can be converted to/from a string using repr and eval. """ import re, os, sys import numpy from .pgcollections import OrderedDict from . import units from .python2_3 import asUnicode, basestring from .Qt import QtCore from .Point import Point from .colormap import ColorMap GLOBAL_PATH = None # so not thread safe. class ParseError(Exception): def __init__(self, message, lineNum, line, fileName=None): self.lineNum = lineNum self.line = line #self.message = message self.fileName = fileName Exception.__init__(self, message) def __str__(self): if self.fileName is None: msg = "Error parsing string at line %d:\n" % self.lineNum else: msg = "Error parsing config file '%s' at line %d:\n" % (self.fileName, self.lineNum) msg += "%s\n%s" % (self.line, self.message) return msg #raise Exception() def writeConfigFile(data, fname): s = genString(data) fd = open(fname, 'w') fd.write(s) fd.close() def readConfigFile(fname): #cwd = os.getcwd() global GLOBAL_PATH if GLOBAL_PATH is not None: fname2 = os.path.join(GLOBAL_PATH, fname) if os.path.exists(fname2): fname = fname2 GLOBAL_PATH = os.path.dirname(os.path.abspath(fname)) try: #os.chdir(newDir) ## bad. fd = open(fname) s = asUnicode(fd.read()) fd.close() s = s.replace("\r\n", "\n") s = s.replace("\r", "\n") data = parseString(s)[1] except ParseError: sys.exc_info()[1].fileName = fname raise except: print("Error while reading config file %s:"% fname) raise #finally: #os.chdir(cwd) return data def appendConfigFile(data, fname): s = genString(data) fd = open(fname, 'a') fd.write(s) fd.close() def genString(data, indent=''): s = '' for k in data: sk = str(k) if len(sk) == 0: print(data) raise Exception('blank dict keys not allowed (see data above)') if sk[0] == ' ' or ':' in sk: print(data) raise Exception('dict keys must not contain ":" or start with spaces [offending key is "%s"]' % sk) if isinstance(data[k], dict): s += indent + sk + ':\n' s += genString(data[k], indent + ' ') else: s += indent + sk + ': ' + repr(data[k]) + '\n' return s def parseString(lines, start=0): data = OrderedDict() if isinstance(lines, basestring): lines = lines.split('\n') lines = [l for l in lines if re.search(r'\S', l) and not re.match(r'\s*#', l)] ## remove empty lines indent = measureIndent(lines[start]) ln = start - 1 try: while True: ln += 1 #print ln if ln >= len(lines): break l = lines[ln] ## Skip blank lines or lines starting with # if re.match(r'\s*#', l) or not re.search(r'\S', l): continue ## Measure line indentation, make sure it is correct for this level lineInd = measureIndent(l) if lineInd < indent: ln -= 1 break if lineInd > indent: #print lineInd, indent raise ParseError('Indentation is incorrect. Expected %d, got %d' % (indent, lineInd), ln+1, l) if ':' not in l: raise ParseError('Missing colon', ln+1, l) (k, p, v) = l.partition(':') k = k.strip() v = v.strip() ## set up local variables to use for eval local = units.allUnits.copy() local['OrderedDict'] = OrderedDict local['readConfigFile'] = readConfigFile local['Point'] = Point local['QtCore'] = QtCore local['ColorMap'] = ColorMap # Needed for reconstructing numpy arrays local['array'] = numpy.array for dtype in ['int8', 'uint8', 'int16', 'uint16', 'float16', 'int32', 'uint32', 'float32', 'int64', 'uint64', 'float64']: local[dtype] = getattr(numpy, dtype) if len(k) < 1: raise ParseError('Missing name preceding colon', ln+1, l) if k[0] == '(' and k[-1] == ')': ## If the key looks like a tuple, try evaluating it. try: k1 = eval(k, local) if type(k1) is tuple: k = k1 except: pass if re.search(r'\S', v) and v[0] != '#': ## eval the value try: val = eval(v, local) except: ex = sys.exc_info()[1] raise ParseError("Error evaluating expression '%s': [%s: %s]" % (v, ex.__class__.__name__, str(ex)), (ln+1), l) else: if ln+1 >= len(lines) or measureIndent(lines[ln+1]) <= indent: #print "blank dict" val = {} else: #print "Going deeper..", ln+1 (ln, val) = parseString(lines, start=ln+1) data[k] = val #print k, repr(val) except ParseError: raise except: ex = sys.exc_info()[1] raise ParseError("%s: %s" % (ex.__class__.__name__, str(ex)), ln+1, l) #print "Returning shallower..", ln+1 return (ln, data) def measureIndent(s): n = 0 while n < len(s) and s[n] == ' ': n += 1 return n if __name__ == '__main__': import tempfile fn = tempfile.mktemp() tf = open(fn, 'w') cf = """ key: 'value' key2: ##comment ##comment key21: 'value' ## comment ##comment key22: [1,2,3] key23: 234 #comment """ tf.write(cf) tf.close() print("=== Test:===") num = 1 for line in cf.split('\n'): print("%02d %s" % (num, line)) num += 1 print(cf) print("============") data = readConfigFile(fn) print(data) os.remove(fn) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/console/000077500000000000000000000000001300727121400213025ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/console/CmdInput.py000066400000000000000000000037041300727121400234030ustar00rootroot00000000000000from ..Qt import QtCore, QtGui from ..python2_3 import asUnicode class CmdInput(QtGui.QLineEdit): sigExecuteCmd = QtCore.Signal(object) def __init__(self, parent): QtGui.QLineEdit.__init__(self, parent) self.history = [""] self.ptr = 0 #self.lastCmd = None #self.setMultiline(False) def keyPressEvent(self, ev): #print "press:", ev.key(), QtCore.Qt.Key_Up, QtCore.Qt.Key_Down, QtCore.Qt.Key_Enter if ev.key() == QtCore.Qt.Key_Up and self.ptr < len(self.history) - 1: self.setHistory(self.ptr+1) ev.accept() return elif ev.key() == QtCore.Qt.Key_Down and self.ptr > 0: self.setHistory(self.ptr-1) ev.accept() return elif ev.key() == QtCore.Qt.Key_Return: self.execCmd() else: QtGui.QLineEdit.keyPressEvent(self, ev) self.history[0] = asUnicode(self.text()) def execCmd(self): cmd = asUnicode(self.text()) if len(self.history) == 1 or cmd != self.history[1]: self.history.insert(1, cmd) #self.lastCmd = cmd self.history[0] = "" self.setHistory(0) self.sigExecuteCmd.emit(cmd) def setHistory(self, num): self.ptr = num self.setText(self.history[self.ptr]) #def setMultiline(self, m): #height = QtGui.QFontMetrics(self.font()).lineSpacing() #if m: #self.setFixedHeight(height*5) #else: #self.setFixedHeight(height+15) #self.setVerticalScrollBarPolicy(QtCore.Qt.ScrollBarAlwaysOff) #self.setHorizontalScrollBarPolicy(QtCore.Qt.ScrollBarAlwaysOff) #def sizeHint(self): #hint = QtGui.QPlainTextEdit.sizeHint(self) #height = QtGui.QFontMetrics(self.font()).lineSpacing() #hint.setHeight(height) #return hint pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/console/Console.py000066400000000000000000000361111300727121400232600ustar00rootroot00000000000000import sys, re, os, time, traceback, subprocess import pickle from ..Qt import QtCore, QtGui, USE_PYSIDE, USE_PYQT5 from ..python2_3 import basestring from .. import exceptionHandling as exceptionHandling from .. import getConfigOption if USE_PYSIDE: from . import template_pyside as template elif USE_PYQT5: from . import template_pyqt5 as template else: from . import template_pyqt as template class ConsoleWidget(QtGui.QWidget): """ Widget displaying console output and accepting command input. Implements: - eval python expressions / exec python statements - storable history of commands - exception handling allowing commands to be interpreted in the context of any level in the exception stack frame Why not just use python in an interactive shell (or ipython) ? There are a few reasons: - pyside does not yet allow Qt event processing and interactive shell at the same time - on some systems, typing in the console _blocks_ the qt event loop until the user presses enter. This can be baffling and frustrating to users since it would appear the program has frozen. - some terminals (eg windows cmd.exe) have notoriously unfriendly interfaces - ability to add extra features like exception stack introspection - ability to have multiple interactive prompts, including for spawned sub-processes """ def __init__(self, parent=None, namespace=None, historyFile=None, text=None, editor=None): """ ============== ============================================================================ **Arguments:** namespace dictionary containing the initial variables present in the default namespace historyFile optional file for storing command history text initial text to display in the console window editor optional string for invoking code editor (called when stack trace entries are double-clicked). May contain {fileName} and {lineNum} format keys. Example:: editorCommand --loadfile {fileName} --gotoline {lineNum} ============== ============================================================================= """ QtGui.QWidget.__init__(self, parent) if namespace is None: namespace = {} self.localNamespace = namespace self.editor = editor self.multiline = None self.inCmd = False self.ui = template.Ui_Form() self.ui.setupUi(self) self.output = self.ui.output self.input = self.ui.input self.input.setFocus() if text is not None: self.output.setPlainText(text) self.historyFile = historyFile history = self.loadHistory() if history is not None: self.input.history = [""] + history self.ui.historyList.addItems(history[::-1]) self.ui.historyList.hide() self.ui.exceptionGroup.hide() self.input.sigExecuteCmd.connect(self.runCmd) self.ui.historyBtn.toggled.connect(self.ui.historyList.setVisible) self.ui.historyList.itemClicked.connect(self.cmdSelected) self.ui.historyList.itemDoubleClicked.connect(self.cmdDblClicked) self.ui.exceptionBtn.toggled.connect(self.ui.exceptionGroup.setVisible) self.ui.catchAllExceptionsBtn.toggled.connect(self.catchAllExceptions) self.ui.catchNextExceptionBtn.toggled.connect(self.catchNextException) self.ui.clearExceptionBtn.clicked.connect(self.clearExceptionClicked) self.ui.exceptionStackList.itemClicked.connect(self.stackItemClicked) self.ui.exceptionStackList.itemDoubleClicked.connect(self.stackItemDblClicked) self.ui.onlyUncaughtCheck.toggled.connect(self.updateSysTrace) self.currentTraceback = None def loadHistory(self): """Return the list of previously-invoked command strings (or None).""" if self.historyFile is not None: return pickle.load(open(self.historyFile, 'rb')) def saveHistory(self, history): """Store the list of previously-invoked command strings.""" if self.historyFile is not None: pickle.dump(open(self.historyFile, 'wb'), history) def runCmd(self, cmd): #cmd = str(self.input.lastCmd) self.stdout = sys.stdout self.stderr = sys.stderr encCmd = re.sub(r'>', '>', re.sub(r'<', '<', cmd)) encCmd = re.sub(r' ', ' ', encCmd) self.ui.historyList.addItem(cmd) self.saveHistory(self.input.history[1:100]) try: sys.stdout = self sys.stderr = self if self.multiline is not None: self.write("
%s\n"%encCmd, html=True) self.execMulti(cmd) else: self.write("
%s\n"%encCmd, html=True) self.inCmd = True self.execSingle(cmd) if not self.inCmd: self.write("
\n", html=True) finally: sys.stdout = self.stdout sys.stderr = self.stderr sb = self.output.verticalScrollBar() sb.setValue(sb.maximum()) sb = self.ui.historyList.verticalScrollBar() sb.setValue(sb.maximum()) def globals(self): frame = self.currentFrame() if frame is not None and self.ui.runSelectedFrameCheck.isChecked(): return self.currentFrame().tb_frame.f_globals else: return globals() def locals(self): frame = self.currentFrame() if frame is not None and self.ui.runSelectedFrameCheck.isChecked(): return self.currentFrame().tb_frame.f_locals else: return self.localNamespace def currentFrame(self): ## Return the currently selected exception stack frame (or None if there is no exception) if self.currentTraceback is None: return None index = self.ui.exceptionStackList.currentRow() tb = self.currentTraceback for i in range(index): tb = tb.tb_next return tb def execSingle(self, cmd): try: output = eval(cmd, self.globals(), self.locals()) self.write(repr(output) + '\n') except SyntaxError: try: exec(cmd, self.globals(), self.locals()) except SyntaxError as exc: if 'unexpected EOF' in exc.msg: self.multiline = cmd else: self.displayException() except: self.displayException() except: self.displayException() def execMulti(self, nextLine): #self.stdout.write(nextLine+"\n") if nextLine.strip() != '': self.multiline += "\n" + nextLine return else: cmd = self.multiline try: output = eval(cmd, self.globals(), self.locals()) self.write(str(output) + '\n') self.multiline = None except SyntaxError: try: exec(cmd, self.globals(), self.locals()) self.multiline = None except SyntaxError as exc: if 'unexpected EOF' in exc.msg: self.multiline = cmd else: self.displayException() self.multiline = None except: self.displayException() self.multiline = None except: self.displayException() self.multiline = None def write(self, strn, html=False): self.output.moveCursor(QtGui.QTextCursor.End) if html: self.output.textCursor().insertHtml(strn) else: if self.inCmd: self.inCmd = False self.output.textCursor().insertHtml("
") #self.stdout.write("

") self.output.insertPlainText(strn) #self.stdout.write(strn) def displayException(self): """ Display the current exception and stack. """ tb = traceback.format_exc() lines = [] indent = 4 prefix = '' for l in tb.split('\n'): lines.append(" "*indent + prefix + l) self.write('\n'.join(lines)) self.exceptionHandler(*sys.exc_info()) def cmdSelected(self, item): index = -(self.ui.historyList.row(item)+1) self.input.setHistory(index) self.input.setFocus() def cmdDblClicked(self, item): index = -(self.ui.historyList.row(item)+1) self.input.setHistory(index) self.input.execCmd() def flush(self): pass def catchAllExceptions(self, catch=True): """ If True, the console will catch all unhandled exceptions and display the stack trace. Each exception caught clears the last. """ self.ui.catchAllExceptionsBtn.setChecked(catch) if catch: self.ui.catchNextExceptionBtn.setChecked(False) self.enableExceptionHandling() self.ui.exceptionBtn.setChecked(True) else: self.disableExceptionHandling() def catchNextException(self, catch=True): """ If True, the console will catch the next unhandled exception and display the stack trace. """ self.ui.catchNextExceptionBtn.setChecked(catch) if catch: self.ui.catchAllExceptionsBtn.setChecked(False) self.enableExceptionHandling() self.ui.exceptionBtn.setChecked(True) else: self.disableExceptionHandling() def enableExceptionHandling(self): exceptionHandling.register(self.exceptionHandler) self.updateSysTrace() def disableExceptionHandling(self): exceptionHandling.unregister(self.exceptionHandler) self.updateSysTrace() def clearExceptionClicked(self): self.currentTraceback = None self.ui.exceptionInfoLabel.setText("[No current exception]") self.ui.exceptionStackList.clear() self.ui.clearExceptionBtn.setEnabled(False) def stackItemClicked(self, item): pass def stackItemDblClicked(self, item): editor = self.editor if editor is None: editor = getConfigOption('editorCommand') if editor is None: return tb = self.currentFrame() lineNum = tb.tb_lineno fileName = tb.tb_frame.f_code.co_filename subprocess.Popen(self.editor.format(fileName=fileName, lineNum=lineNum), shell=True) #def allExceptionsHandler(self, *args): #self.exceptionHandler(*args) #def nextExceptionHandler(self, *args): #self.ui.catchNextExceptionBtn.setChecked(False) #self.exceptionHandler(*args) def updateSysTrace(self): ## Install or uninstall sys.settrace handler if not self.ui.catchNextExceptionBtn.isChecked() and not self.ui.catchAllExceptionsBtn.isChecked(): if sys.gettrace() == self.systrace: sys.settrace(None) return if self.ui.onlyUncaughtCheck.isChecked(): if sys.gettrace() == self.systrace: sys.settrace(None) else: if sys.gettrace() is not None and sys.gettrace() != self.systrace: self.ui.onlyUncaughtCheck.setChecked(False) raise Exception("sys.settrace is in use; cannot monitor for caught exceptions.") else: sys.settrace(self.systrace) def exceptionHandler(self, excType, exc, tb): if self.ui.catchNextExceptionBtn.isChecked(): self.ui.catchNextExceptionBtn.setChecked(False) elif not self.ui.catchAllExceptionsBtn.isChecked(): return self.ui.clearExceptionBtn.setEnabled(True) self.currentTraceback = tb excMessage = ''.join(traceback.format_exception_only(excType, exc)) self.ui.exceptionInfoLabel.setText(excMessage) self.ui.exceptionStackList.clear() for index, line in enumerate(traceback.extract_tb(tb)): self.ui.exceptionStackList.addItem('File "%s", line %s, in %s()\n %s' % line) def systrace(self, frame, event, arg): if event == 'exception' and self.checkException(*arg): self.exceptionHandler(*arg) return self.systrace def checkException(self, excType, exc, tb): ## Return True if the exception is interesting; False if it should be ignored. filename = tb.tb_frame.f_code.co_filename function = tb.tb_frame.f_code.co_name filterStr = str(self.ui.filterText.text()) if filterStr != '': if isinstance(exc, Exception): msg = exc.message elif isinstance(exc, basestring): msg = exc else: msg = repr(exc) match = re.search(filterStr, "%s:%s:%s" % (filename, function, msg)) return match is not None ## Go through a list of common exception points we like to ignore: if excType is GeneratorExit or excType is StopIteration: return False if excType is KeyError: if filename.endswith('python2.7/weakref.py') and function in ('__contains__', 'get'): return False if filename.endswith('python2.7/copy.py') and function == '_keep_alive': return False if excType is AttributeError: if filename.endswith('python2.7/collections.py') and function == '__init__': return False if filename.endswith('numpy/core/fromnumeric.py') and function in ('all', '_wrapit', 'transpose', 'sum'): return False if filename.endswith('numpy/core/arrayprint.py') and function in ('_array2string'): return False if filename.endswith('MetaArray.py') and function == '__getattr__': for name in ('__array_interface__', '__array_struct__', '__array__'): ## numpy looks for these when converting objects to array if name in exc: return False if filename.endswith('flowchart/eq.py'): return False if filename.endswith('pyqtgraph/functions.py') and function == 'makeQImage': return False if excType is TypeError: if filename.endswith('numpy/lib/function_base.py') and function == 'iterable': return False if excType is ZeroDivisionError: if filename.endswith('python2.7/traceback.py'): return False return True pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/console/__init__.py000066400000000000000000000000421300727121400234070ustar00rootroot00000000000000from .Console import ConsoleWidgetpyqtgraph-pyqtgraph-0.10.0/pyqtgraph/console/template.ui000066400000000000000000000126671300727121400234700ustar00rootroot00000000000000 Form 0 0 694 497 Console 0 0 Qt::Vertical Monospace true History.. true Exceptions.. true Monospace Exception Handling 0 0 0 false Clear Exception Show All Exceptions true Show Next Exception true Only Uncaught Exceptions true true Run commands in selected stack frame true Exception Info Qt::Horizontal 40 20 Filter (regex): CmdInput QLineEdit
.CmdInput
 pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/console/template_pyqt.py000066400000000000000000000151531300727121400245510ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file 'template.ui' # # Created: Fri May 02 18:55:28 2014 # by: PyQt4 UI code generator 4.10.4 # # WARNING! All changes made in this file will be lost! from PyQt4 import QtCore, QtGui try: _fromUtf8 = QtCore.QString.fromUtf8 except AttributeError: def _fromUtf8(s): return s try: _encoding = QtGui.QApplication.UnicodeUTF8 def _translate(context, text, disambig): return QtGui.QApplication.translate(context, text, disambig, _encoding) except AttributeError: def _translate(context, text, disambig): return QtGui.QApplication.translate(context, text, disambig) class Ui_Form(object): def setupUi(self, Form): Form.setObjectName(_fromUtf8("Form")) Form.resize(694, 497) self.gridLayout = QtGui.QGridLayout(Form) self.gridLayout.setMargin(0) self.gridLayout.setSpacing(0) self.gridLayout.setObjectName(_fromUtf8("gridLayout")) self.splitter = QtGui.QSplitter(Form) self.splitter.setOrientation(QtCore.Qt.Vertical) self.splitter.setObjectName(_fromUtf8("splitter")) self.layoutWidget = QtGui.QWidget(self.splitter) self.layoutWidget.setObjectName(_fromUtf8("layoutWidget")) self.verticalLayout = QtGui.QVBoxLayout(self.layoutWidget) self.verticalLayout.setMargin(0) self.verticalLayout.setObjectName(_fromUtf8("verticalLayout")) self.output = QtGui.QPlainTextEdit(self.layoutWidget) font = QtGui.QFont() font.setFamily(_fromUtf8("Monospace")) self.output.setFont(font) self.output.setReadOnly(True) self.output.setObjectName(_fromUtf8("output")) self.verticalLayout.addWidget(self.output) self.horizontalLayout = QtGui.QHBoxLayout() self.horizontalLayout.setObjectName(_fromUtf8("horizontalLayout")) self.input = CmdInput(self.layoutWidget) self.input.setObjectName(_fromUtf8("input")) self.horizontalLayout.addWidget(self.input) self.historyBtn = QtGui.QPushButton(self.layoutWidget) self.historyBtn.setCheckable(True) self.historyBtn.setObjectName(_fromUtf8("historyBtn")) self.horizontalLayout.addWidget(self.historyBtn) self.exceptionBtn = QtGui.QPushButton(self.layoutWidget) self.exceptionBtn.setCheckable(True) self.exceptionBtn.setObjectName(_fromUtf8("exceptionBtn")) self.horizontalLayout.addWidget(self.exceptionBtn) self.verticalLayout.addLayout(self.horizontalLayout) self.historyList = QtGui.QListWidget(self.splitter) font = QtGui.QFont() font.setFamily(_fromUtf8("Monospace")) self.historyList.setFont(font) self.historyList.setObjectName(_fromUtf8("historyList")) self.exceptionGroup = QtGui.QGroupBox(self.splitter) self.exceptionGroup.setObjectName(_fromUtf8("exceptionGroup")) self.gridLayout_2 = QtGui.QGridLayout(self.exceptionGroup) self.gridLayout_2.setSpacing(0) self.gridLayout_2.setContentsMargins(-1, 0, -1, 0) self.gridLayout_2.setObjectName(_fromUtf8("gridLayout_2")) self.clearExceptionBtn = QtGui.QPushButton(self.exceptionGroup) self.clearExceptionBtn.setEnabled(False) self.clearExceptionBtn.setObjectName(_fromUtf8("clearExceptionBtn")) self.gridLayout_2.addWidget(self.clearExceptionBtn, 0, 6, 1, 1) self.catchAllExceptionsBtn = QtGui.QPushButton(self.exceptionGroup) self.catchAllExceptionsBtn.setCheckable(True) self.catchAllExceptionsBtn.setObjectName(_fromUtf8("catchAllExceptionsBtn")) self.gridLayout_2.addWidget(self.catchAllExceptionsBtn, 0, 1, 1, 1) self.catchNextExceptionBtn = QtGui.QPushButton(self.exceptionGroup) self.catchNextExceptionBtn.setCheckable(True) self.catchNextExceptionBtn.setObjectName(_fromUtf8("catchNextExceptionBtn")) self.gridLayout_2.addWidget(self.catchNextExceptionBtn, 0, 0, 1, 1) self.onlyUncaughtCheck = QtGui.QCheckBox(self.exceptionGroup) self.onlyUncaughtCheck.setChecked(True) self.onlyUncaughtCheck.setObjectName(_fromUtf8("onlyUncaughtCheck")) self.gridLayout_2.addWidget(self.onlyUncaughtCheck, 0, 4, 1, 1) self.exceptionStackList = QtGui.QListWidget(self.exceptionGroup) self.exceptionStackList.setAlternatingRowColors(True) self.exceptionStackList.setObjectName(_fromUtf8("exceptionStackList")) self.gridLayout_2.addWidget(self.exceptionStackList, 2, 0, 1, 7) self.runSelectedFrameCheck = QtGui.QCheckBox(self.exceptionGroup) self.runSelectedFrameCheck.setChecked(True) self.runSelectedFrameCheck.setObjectName(_fromUtf8("runSelectedFrameCheck")) self.gridLayout_2.addWidget(self.runSelectedFrameCheck, 3, 0, 1, 7) self.exceptionInfoLabel = QtGui.QLabel(self.exceptionGroup) self.exceptionInfoLabel.setObjectName(_fromUtf8("exceptionInfoLabel")) self.gridLayout_2.addWidget(self.exceptionInfoLabel, 1, 0, 1, 7) spacerItem = QtGui.QSpacerItem(40, 20, QtGui.QSizePolicy.Expanding, QtGui.QSizePolicy.Minimum) self.gridLayout_2.addItem(spacerItem, 0, 5, 1, 1) self.label = QtGui.QLabel(self.exceptionGroup) self.label.setObjectName(_fromUtf8("label")) self.gridLayout_2.addWidget(self.label, 0, 2, 1, 1) self.filterText = QtGui.QLineEdit(self.exceptionGroup) self.filterText.setObjectName(_fromUtf8("filterText")) self.gridLayout_2.addWidget(self.filterText, 0, 3, 1, 1) self.gridLayout.addWidget(self.splitter, 0, 0, 1, 1) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): Form.setWindowTitle(_translate("Form", "Console", None)) self.historyBtn.setText(_translate("Form", "History..", None)) self.exceptionBtn.setText(_translate("Form", "Exceptions..", None)) self.exceptionGroup.setTitle(_translate("Form", "Exception Handling", None)) self.clearExceptionBtn.setText(_translate("Form", "Clear Exception", None)) self.catchAllExceptionsBtn.setText(_translate("Form", "Show All Exceptions", None)) self.catchNextExceptionBtn.setText(_translate("Form", "Show Next Exception", None)) self.onlyUncaughtCheck.setText(_translate("Form", "Only Uncaught Exceptions", None)) self.runSelectedFrameCheck.setText(_translate("Form", "Run commands in selected stack frame", None)) self.exceptionInfoLabel.setText(_translate("Form", "Exception Info", None)) self.label.setText(_translate("Form", "Filter (regex):", None)) from .CmdInput import CmdInput pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/console/template_pyqt5.py000066400000000000000000000132641300727121400246370ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './pyqtgraph/console/template.ui' # # Created: Wed Mar 26 15:09:29 2014 # by: PyQt5 UI code generator 5.0.1 # # WARNING! All changes made in this file will be lost! from PyQt5 import QtCore, QtGui, QtWidgets class Ui_Form(object): def setupUi(self, Form): Form.setObjectName("Form") Form.resize(710, 497) self.gridLayout = QtWidgets.QGridLayout(Form) self.gridLayout.setContentsMargins(0, 0, 0, 0) self.gridLayout.setSpacing(0) self.gridLayout.setObjectName("gridLayout") self.splitter = QtWidgets.QSplitter(Form) self.splitter.setOrientation(QtCore.Qt.Vertical) self.splitter.setObjectName("splitter") self.layoutWidget = QtWidgets.QWidget(self.splitter) self.layoutWidget.setObjectName("layoutWidget") self.verticalLayout = QtWidgets.QVBoxLayout(self.layoutWidget) self.verticalLayout.setContentsMargins(0, 0, 0, 0) self.verticalLayout.setObjectName("verticalLayout") self.output = QtWidgets.QPlainTextEdit(self.layoutWidget) font = QtGui.QFont() font.setFamily("Monospace") self.output.setFont(font) self.output.setReadOnly(True) self.output.setObjectName("output") self.verticalLayout.addWidget(self.output) self.horizontalLayout = QtWidgets.QHBoxLayout() self.horizontalLayout.setObjectName("horizontalLayout") self.input = CmdInput(self.layoutWidget) self.input.setObjectName("input") self.horizontalLayout.addWidget(self.input) self.historyBtn = QtWidgets.QPushButton(self.layoutWidget) self.historyBtn.setCheckable(True) self.historyBtn.setObjectName("historyBtn") self.horizontalLayout.addWidget(self.historyBtn) self.exceptionBtn = QtWidgets.QPushButton(self.layoutWidget) self.exceptionBtn.setCheckable(True) self.exceptionBtn.setObjectName("exceptionBtn") self.horizontalLayout.addWidget(self.exceptionBtn) self.verticalLayout.addLayout(self.horizontalLayout) self.historyList = QtWidgets.QListWidget(self.splitter) font = QtGui.QFont() font.setFamily("Monospace") self.historyList.setFont(font) self.historyList.setObjectName("historyList") self.exceptionGroup = QtWidgets.QGroupBox(self.splitter) self.exceptionGroup.setObjectName("exceptionGroup") self.gridLayout_2 = QtWidgets.QGridLayout(self.exceptionGroup) self.gridLayout_2.setSpacing(0) self.gridLayout_2.setContentsMargins(-1, 0, -1, 0) self.gridLayout_2.setObjectName("gridLayout_2") self.catchAllExceptionsBtn = QtWidgets.QPushButton(self.exceptionGroup) self.catchAllExceptionsBtn.setCheckable(True) self.catchAllExceptionsBtn.setObjectName("catchAllExceptionsBtn") self.gridLayout_2.addWidget(self.catchAllExceptionsBtn, 0, 1, 1, 1) self.catchNextExceptionBtn = QtWidgets.QPushButton(self.exceptionGroup) self.catchNextExceptionBtn.setCheckable(True) self.catchNextExceptionBtn.setObjectName("catchNextExceptionBtn") self.gridLayout_2.addWidget(self.catchNextExceptionBtn, 0, 0, 1, 1) self.onlyUncaughtCheck = QtWidgets.QCheckBox(self.exceptionGroup) self.onlyUncaughtCheck.setChecked(True) self.onlyUncaughtCheck.setObjectName("onlyUncaughtCheck") self.gridLayout_2.addWidget(self.onlyUncaughtCheck, 0, 2, 1, 1) self.exceptionStackList = QtWidgets.QListWidget(self.exceptionGroup) self.exceptionStackList.setAlternatingRowColors(True) self.exceptionStackList.setObjectName("exceptionStackList") self.gridLayout_2.addWidget(self.exceptionStackList, 2, 0, 1, 5) self.runSelectedFrameCheck = QtWidgets.QCheckBox(self.exceptionGroup) self.runSelectedFrameCheck.setChecked(True) self.runSelectedFrameCheck.setObjectName("runSelectedFrameCheck") self.gridLayout_2.addWidget(self.runSelectedFrameCheck, 3, 0, 1, 5) self.exceptionInfoLabel = QtWidgets.QLabel(self.exceptionGroup) self.exceptionInfoLabel.setObjectName("exceptionInfoLabel") self.gridLayout_2.addWidget(self.exceptionInfoLabel, 1, 0, 1, 5) self.clearExceptionBtn = QtWidgets.QPushButton(self.exceptionGroup) self.clearExceptionBtn.setEnabled(False) self.clearExceptionBtn.setObjectName("clearExceptionBtn") self.gridLayout_2.addWidget(self.clearExceptionBtn, 0, 4, 1, 1) spacerItem = QtWidgets.QSpacerItem(40, 20, QtWidgets.QSizePolicy.Expanding, QtWidgets.QSizePolicy.Minimum) self.gridLayout_2.addItem(spacerItem, 0, 3, 1, 1) self.gridLayout.addWidget(self.splitter, 0, 0, 1, 1) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): _translate = QtCore.QCoreApplication.translate Form.setWindowTitle(_translate("Form", "Console")) self.historyBtn.setText(_translate("Form", "History..")) self.exceptionBtn.setText(_translate("Form", "Exceptions..")) self.exceptionGroup.setTitle(_translate("Form", "Exception Handling")) self.catchAllExceptionsBtn.setText(_translate("Form", "Show All Exceptions")) self.catchNextExceptionBtn.setText(_translate("Form", "Show Next Exception")) self.onlyUncaughtCheck.setText(_translate("Form", "Only Uncaught Exceptions")) self.runSelectedFrameCheck.setText(_translate("Form", "Run commands in selected stack frame")) self.exceptionInfoLabel.setText(_translate("Form", "Exception Info")) self.clearExceptionBtn.setText(_translate("Form", "Clear Exception")) from .CmdInput import CmdInput pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/console/template_pyside.py000066400000000000000000000141331300727121400250460ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './pyqtgraph/console/template.ui' # # Created: Mon Dec 23 10:10:53 2013 # by: pyside-uic 0.2.14 running on PySide 1.1.2 # # WARNING! All changes made in this file will be lost! from PySide import QtCore, QtGui class Ui_Form(object): def setupUi(self, Form): Form.setObjectName("Form") Form.resize(710, 497) self.gridLayout = QtGui.QGridLayout(Form) self.gridLayout.setContentsMargins(0, 0, 0, 0) self.gridLayout.setSpacing(0) self.gridLayout.setObjectName("gridLayout") self.splitter = QtGui.QSplitter(Form) self.splitter.setOrientation(QtCore.Qt.Vertical) self.splitter.setObjectName("splitter") self.layoutWidget = QtGui.QWidget(self.splitter) self.layoutWidget.setObjectName("layoutWidget") self.verticalLayout = QtGui.QVBoxLayout(self.layoutWidget) self.verticalLayout.setContentsMargins(0, 0, 0, 0) self.verticalLayout.setObjectName("verticalLayout") self.output = QtGui.QPlainTextEdit(self.layoutWidget) font = QtGui.QFont() font.setFamily("Monospace") self.output.setFont(font) self.output.setReadOnly(True) self.output.setObjectName("output") self.verticalLayout.addWidget(self.output) self.horizontalLayout = QtGui.QHBoxLayout() self.horizontalLayout.setObjectName("horizontalLayout") self.input = CmdInput(self.layoutWidget) self.input.setObjectName("input") self.horizontalLayout.addWidget(self.input) self.historyBtn = QtGui.QPushButton(self.layoutWidget) self.historyBtn.setCheckable(True) self.historyBtn.setObjectName("historyBtn") self.horizontalLayout.addWidget(self.historyBtn) self.exceptionBtn = QtGui.QPushButton(self.layoutWidget) self.exceptionBtn.setCheckable(True) self.exceptionBtn.setObjectName("exceptionBtn") self.horizontalLayout.addWidget(self.exceptionBtn) self.verticalLayout.addLayout(self.horizontalLayout) self.historyList = QtGui.QListWidget(self.splitter) font = QtGui.QFont() font.setFamily("Monospace") self.historyList.setFont(font) self.historyList.setObjectName("historyList") self.exceptionGroup = QtGui.QGroupBox(self.splitter) self.exceptionGroup.setObjectName("exceptionGroup") self.gridLayout_2 = QtGui.QGridLayout(self.exceptionGroup) self.gridLayout_2.setSpacing(0) self.gridLayout_2.setContentsMargins(-1, 0, -1, 0) self.gridLayout_2.setObjectName("gridLayout_2") self.catchAllExceptionsBtn = QtGui.QPushButton(self.exceptionGroup) self.catchAllExceptionsBtn.setCheckable(True) self.catchAllExceptionsBtn.setObjectName("catchAllExceptionsBtn") self.gridLayout_2.addWidget(self.catchAllExceptionsBtn, 0, 1, 1, 1) self.catchNextExceptionBtn = QtGui.QPushButton(self.exceptionGroup) self.catchNextExceptionBtn.setCheckable(True) self.catchNextExceptionBtn.setObjectName("catchNextExceptionBtn") self.gridLayout_2.addWidget(self.catchNextExceptionBtn, 0, 0, 1, 1) self.onlyUncaughtCheck = QtGui.QCheckBox(self.exceptionGroup) self.onlyUncaughtCheck.setChecked(True) self.onlyUncaughtCheck.setObjectName("onlyUncaughtCheck") self.gridLayout_2.addWidget(self.onlyUncaughtCheck, 0, 2, 1, 1) self.exceptionStackList = QtGui.QListWidget(self.exceptionGroup) self.exceptionStackList.setAlternatingRowColors(True) self.exceptionStackList.setObjectName("exceptionStackList") self.gridLayout_2.addWidget(self.exceptionStackList, 2, 0, 1, 5) self.runSelectedFrameCheck = QtGui.QCheckBox(self.exceptionGroup) self.runSelectedFrameCheck.setChecked(True) self.runSelectedFrameCheck.setObjectName("runSelectedFrameCheck") self.gridLayout_2.addWidget(self.runSelectedFrameCheck, 3, 0, 1, 5) self.exceptionInfoLabel = QtGui.QLabel(self.exceptionGroup) self.exceptionInfoLabel.setObjectName("exceptionInfoLabel") self.gridLayout_2.addWidget(self.exceptionInfoLabel, 1, 0, 1, 5) self.clearExceptionBtn = QtGui.QPushButton(self.exceptionGroup) self.clearExceptionBtn.setEnabled(False) self.clearExceptionBtn.setObjectName("clearExceptionBtn") self.gridLayout_2.addWidget(self.clearExceptionBtn, 0, 4, 1, 1) spacerItem = QtGui.QSpacerItem(40, 20, QtGui.QSizePolicy.Expanding, QtGui.QSizePolicy.Minimum) self.gridLayout_2.addItem(spacerItem, 0, 3, 1, 1) self.gridLayout.addWidget(self.splitter, 0, 0, 1, 1) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): Form.setWindowTitle(QtGui.QApplication.translate("Form", "Console", None, QtGui.QApplication.UnicodeUTF8)) self.historyBtn.setText(QtGui.QApplication.translate("Form", "History..", None, QtGui.QApplication.UnicodeUTF8)) self.exceptionBtn.setText(QtGui.QApplication.translate("Form", "Exceptions..", None, QtGui.QApplication.UnicodeUTF8)) self.exceptionGroup.setTitle(QtGui.QApplication.translate("Form", "Exception Handling", None, QtGui.QApplication.UnicodeUTF8)) self.catchAllExceptionsBtn.setText(QtGui.QApplication.translate("Form", "Show All Exceptions", None, QtGui.QApplication.UnicodeUTF8)) self.catchNextExceptionBtn.setText(QtGui.QApplication.translate("Form", "Show Next Exception", None, QtGui.QApplication.UnicodeUTF8)) self.onlyUncaughtCheck.setText(QtGui.QApplication.translate("Form", "Only Uncaught Exceptions", None, QtGui.QApplication.UnicodeUTF8)) self.runSelectedFrameCheck.setText(QtGui.QApplication.translate("Form", "Run commands in selected stack frame", None, QtGui.QApplication.UnicodeUTF8)) self.exceptionInfoLabel.setText(QtGui.QApplication.translate("Form", "Exception Info", None, QtGui.QApplication.UnicodeUTF8)) self.clearExceptionBtn.setText(QtGui.QApplication.translate("Form", "Clear Exception", None, QtGui.QApplication.UnicodeUTF8)) from .CmdInput import CmdInput pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/debug.py000066400000000000000000001162221300727121400213040ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ debug.py - Functions to aid in debugging Copyright 2010 Luke Campagnola Distributed under MIT/X11 license. See license.txt for more infomation. """ from __future__ import print_function import sys, traceback, time, gc, re, types, weakref, inspect, os, cProfile, threading from . import ptime from numpy import ndarray from .Qt import QtCore, QtGui from .util.mutex import Mutex from .util import cprint __ftraceDepth = 0 def ftrace(func): """Decorator used for marking the beginning and end of function calls. Automatically indents nested calls. """ def w(*args, **kargs): global __ftraceDepth pfx = " " * __ftraceDepth print(pfx + func.__name__ + " start") __ftraceDepth += 1 try: rv = func(*args, **kargs) finally: __ftraceDepth -= 1 print(pfx + func.__name__ + " done") return rv return w class Tracer(object): """ Prints every function enter/exit. Useful for debugging crashes / lockups. """ def __init__(self): self.count = 0 self.stack = [] def trace(self, frame, event, arg): self.count += 1 # If it has been a long time since we saw the top of the stack, # print a reminder if self.count % 1000 == 0: print("----- current stack: -----") for line in self.stack: print(line) if event == 'call': line = " " * len(self.stack) + ">> " + self.frameInfo(frame) print(line) self.stack.append(line) elif event == 'return': self.stack.pop() line = " " * len(self.stack) + "<< " + self.frameInfo(frame) print(line) if len(self.stack) == 0: self.count = 0 return self.trace def stop(self): sys.settrace(None) def start(self): sys.settrace(self.trace) def frameInfo(self, fr): filename = fr.f_code.co_filename funcname = fr.f_code.co_name lineno = fr.f_lineno callfr = sys._getframe(3) callline = "%s %d" % (callfr.f_code.co_name, callfr.f_lineno) args, _, _, value_dict = inspect.getargvalues(fr) if len(args) and args[0] == 'self': instance = value_dict.get('self', None) if instance is not None: cls = getattr(instance, '__class__', None) if cls is not None: funcname = cls.__name__ + "." + funcname return "%s: %s %s: %s" % (callline, filename, lineno, funcname) def warnOnException(func): """Decorator that catches/ignores exceptions and prints a stack trace.""" def w(*args, **kwds): try: func(*args, **kwds) except: printExc('Ignored exception:') return w def getExc(indent=4, prefix='| ', skip=1): lines = formatException(*sys.exc_info(), skip=skip) lines2 = [] for l in lines: lines2.extend(l.strip('\n').split('\n')) lines3 = [" "*indent + prefix + l for l in lines2] return '\n'.join(lines3) def printExc(msg='', indent=4, prefix='|'): """Print an error message followed by an indented exception backtrace (This function is intended to be called within except: blocks)""" exc = getExc(indent, prefix + ' ', skip=2) print("[%s] %s\n" % (time.strftime("%H:%M:%S"), msg)) print(" "*indent + prefix + '='*30 + '>>') print(exc) print(" "*indent + prefix + '='*30 + '<<') def printTrace(msg='', indent=4, prefix='|'): """Print an error message followed by an indented stack trace""" trace = backtrace(1) #exc = getExc(indent, prefix + ' ') print("[%s] %s\n" % (time.strftime("%H:%M:%S"), msg)) print(" "*indent + prefix + '='*30 + '>>') for line in trace.split('\n'): print(" "*indent + prefix + " " + line) print(" "*indent + prefix + '='*30 + '<<') def backtrace(skip=0): return ''.join(traceback.format_stack()[:-(skip+1)]) def formatException(exctype, value, tb, skip=0): """Return a list of formatted exception strings. Similar to traceback.format_exception, but displays the entire stack trace rather than just the portion downstream of the point where the exception is caught. In particular, unhandled exceptions that occur during Qt signal handling do not usually show the portion of the stack that emitted the signal. """ lines = traceback.format_exception(exctype, value, tb) lines = [lines[0]] + traceback.format_stack()[:-(skip+1)] + [' --- exception caught here ---\n'] + lines[1:] return lines def printException(exctype, value, traceback): """Print an exception with its full traceback. Set `sys.excepthook = printException` to ensure that exceptions caught inside Qt signal handlers are printed with their full stack trace. """ print(''.join(formatException(exctype, value, traceback, skip=1))) def listObjs(regex='Q', typ=None): """List all objects managed by python gc with class name matching regex. Finds 'Q...' classes by default.""" if typ is not None: return [x for x in gc.get_objects() if isinstance(x, typ)] else: return [x for x in gc.get_objects() if re.match(regex, type(x).__name__)] def findRefPath(startObj, endObj, maxLen=8, restart=True, seen={}, path=None, ignore=None): """Determine all paths of object references from startObj to endObj""" refs = [] if path is None: path = [endObj] if ignore is None: ignore = {} ignore[id(sys._getframe())] = None ignore[id(path)] = None ignore[id(seen)] = None prefix = " "*(8-maxLen) #print prefix + str(map(type, path)) prefix += " " if restart: #gc.collect() seen.clear() gc.collect() newRefs = [r for r in gc.get_referrers(endObj) if id(r) not in ignore] ignore[id(newRefs)] = None #fo = allFrameObjs() #newRefs = [] #for r in gc.get_referrers(endObj): #try: #if r not in fo: #newRefs.append(r) #except: #newRefs.append(r) for r in newRefs: #print prefix+"->"+str(type(r)) if type(r).__name__ in ['frame', 'function', 'listiterator']: #print prefix+" FRAME" continue try: if any([r is x for x in path]): #print prefix+" LOOP", objChainString([r]+path) continue except: print(r) print(path) raise if r is startObj: refs.append([r]) print(refPathString([startObj]+path)) continue if maxLen == 0: #print prefix+" END:", objChainString([r]+path) continue ## See if we have already searched this node. ## If not, recurse. tree = None try: cache = seen[id(r)] if cache[0] >= maxLen: tree = cache[1] for p in tree: print(refPathString(p+path)) except KeyError: pass ignore[id(tree)] = None if tree is None: tree = findRefPath(startObj, r, maxLen-1, restart=False, path=[r]+path, ignore=ignore) seen[id(r)] = [maxLen, tree] ## integrate any returned results if len(tree) == 0: #print prefix+" EMPTY TREE" continue else: for p in tree: refs.append(p+[r]) #seen[id(r)] = [maxLen, refs] return refs def objString(obj): """Return a short but descriptive string for any object""" try: if type(obj) in [int, float]: return str(obj) elif isinstance(obj, dict): if len(obj) > 5: return "" % (",".join(list(obj.keys())[:5])) else: return "" % (",".join(list(obj.keys()))) elif isinstance(obj, str): if len(obj) > 50: return '"%s..."' % obj[:50] else: return obj[:] elif isinstance(obj, ndarray): return "" % (str(obj.dtype), str(obj.shape)) elif hasattr(obj, '__len__'): if len(obj) > 5: return "<%s [%s,...]>" % (type(obj).__name__, ",".join([type(o).__name__ for o in obj[:5]])) else: return "<%s [%s]>" % (type(obj).__name__, ",".join([type(o).__name__ for o in obj])) else: return "<%s %s>" % (type(obj).__name__, obj.__class__.__name__) except: return str(type(obj)) def refPathString(chain): """Given a list of adjacent objects in a reference path, print the 'natural' path names (ie, attribute names, keys, and indexes) that follow from one object to the next .""" s = objString(chain[0]) i = 0 while i < len(chain)-1: #print " -> ", i i += 1 o1 = chain[i-1] o2 = chain[i] cont = False if isinstance(o1, list) or isinstance(o1, tuple): if any([o2 is x for x in o1]): s += "[%d]" % o1.index(o2) continue #print " not list" if isinstance(o2, dict) and hasattr(o1, '__dict__') and o2 == o1.__dict__: i += 1 if i >= len(chain): s += ".__dict__" continue o3 = chain[i] for k in o2: if o2[k] is o3: s += '.%s' % k cont = True continue #print " not __dict__" if isinstance(o1, dict): try: if o2 in o1: s += "[key:%s]" % objString(o2) continue except TypeError: pass for k in o1: if o1[k] is o2: s += "[%s]" % objString(k) cont = True continue #print " not dict" #for k in dir(o1): ## Not safe to request attributes like this. #if getattr(o1, k) is o2: #s += ".%s" % k #cont = True #continue #print " not attr" if cont: continue s += " ? " sys.stdout.flush() return s def objectSize(obj, ignore=None, verbose=False, depth=0, recursive=False): """Guess how much memory an object is using""" ignoreTypes = ['MethodType', 'UnboundMethodType', 'BuiltinMethodType', 'FunctionType', 'BuiltinFunctionType'] ignoreTypes = [getattr(types, key) for key in ignoreTypes if hasattr(types, key)] ignoreRegex = re.compile('(method-wrapper|Flag|ItemChange|Option|Mode)') if ignore is None: ignore = {} indent = ' '*depth try: hash(obj) hsh = obj except: hsh = "%s:%d" % (str(type(obj)), id(obj)) if hsh in ignore: return 0 ignore[hsh] = 1 try: size = sys.getsizeof(obj) except TypeError: size = 0 if isinstance(obj, ndarray): try: size += len(obj.data) except: pass if recursive: if type(obj) in [list, tuple]: if verbose: print(indent+"list:") for o in obj: s = objectSize(o, ignore=ignore, verbose=verbose, depth=depth+1) if verbose: print(indent+' +', s) size += s elif isinstance(obj, dict): if verbose: print(indent+"list:") for k in obj: s = objectSize(obj[k], ignore=ignore, verbose=verbose, depth=depth+1) if verbose: print(indent+' +', k, s) size += s #elif isinstance(obj, QtCore.QObject): #try: #childs = obj.children() #if verbose: #print indent+"Qt children:" #for ch in childs: #s = objectSize(obj, ignore=ignore, verbose=verbose, depth=depth+1) #size += s #if verbose: #print indent + ' +', ch.objectName(), s #except: #pass #if isinstance(obj, types.InstanceType): gc.collect() if verbose: print(indent+'attrs:') for k in dir(obj): if k in ['__dict__']: continue o = getattr(obj, k) if type(o) in ignoreTypes: continue strtyp = str(type(o)) if ignoreRegex.search(strtyp): continue #if isinstance(o, types.ObjectType) and strtyp == "": #continue #if verbose: #print indent, k, '?' refs = [r for r in gc.get_referrers(o) if type(r) != types.FrameType] if len(refs) == 1: s = objectSize(o, ignore=ignore, verbose=verbose, depth=depth+1) size += s if verbose: print(indent + " +", k, s) #else: #if verbose: #print indent + ' -', k, len(refs) return size class GarbageWatcher(object): """ Convenient dictionary for holding weak references to objects. Mainly used to check whether the objects have been collect yet or not. Example: gw = GarbageWatcher() gw['objName'] = obj gw['objName2'] = obj2 gw.check() """ def __init__(self): self.objs = weakref.WeakValueDictionary() self.allNames = [] def add(self, obj, name): self.objs[name] = obj self.allNames.append(name) def __setitem__(self, name, obj): self.add(obj, name) def check(self): """Print a list of all watched objects and whether they have been collected.""" gc.collect() dead = self.allNames[:] alive = [] for k in self.objs: dead.remove(k) alive.append(k) print("Deleted objects:", dead) print("Live objects:", alive) def __getitem__(self, item): return self.objs[item] class Profiler(object): """Simple profiler allowing measurement of multiple time intervals. By default, profilers are disabled. To enable profiling, set the environment variable `PYQTGRAPHPROFILE` to a comma-separated list of fully-qualified names of profiled functions. Calling a profiler registers a message (defaulting to an increasing counter) that contains the time elapsed since the last call. When the profiler is about to be garbage-collected, the messages are passed to the outer profiler if one is running, or printed to stdout otherwise. If `delayed` is set to False, messages are immediately printed instead. Example: def function(...): profiler = Profiler() ... do stuff ... profiler('did stuff') ... do other stuff ... profiler('did other stuff') # profiler is garbage-collected and flushed at function end If this function is a method of class C, setting `PYQTGRAPHPROFILE` to "C.function" (without the module name) will enable this profiler. For regular functions, use the qualified name of the function, stripping only the initial "pyqtgraph." prefix from the module. """ _profilers = os.environ.get("PYQTGRAPHPROFILE", None) _profilers = _profilers.split(",") if _profilers is not None else [] _depth = 0 _msgs = [] disable = False # set this flag to disable all or individual profilers at runtime class DisabledProfiler(object): def __init__(self, *args, **kwds): pass def __call__(self, *args): pass def finish(self): pass def mark(self, msg=None): pass _disabledProfiler = DisabledProfiler() def __new__(cls, msg=None, disabled='env', delayed=True): """Optionally create a new profiler based on caller's qualname. """ if disabled is True or (disabled == 'env' and len(cls._profilers) == 0): return cls._disabledProfiler # determine the qualified name of the caller function caller_frame = sys._getframe(1) try: caller_object_type = type(caller_frame.f_locals["self"]) except KeyError: # we are in a regular function qualifier = caller_frame.f_globals["__name__"].split(".", 1)[1] else: # we are in a method qualifier = caller_object_type.__name__ func_qualname = qualifier + "." + caller_frame.f_code.co_name if disabled == 'env' and func_qualname not in cls._profilers: # don't do anything return cls._disabledProfiler # create an actual profiling object cls._depth += 1 obj = super(Profiler, cls).__new__(cls) obj._name = msg or func_qualname obj._delayed = delayed obj._markCount = 0 obj._finished = False obj._firstTime = obj._lastTime = ptime.time() obj._newMsg("> Entering " + obj._name) return obj def __call__(self, msg=None): """Register or print a new message with timing information. """ if self.disable: return if msg is None: msg = str(self._markCount) self._markCount += 1 newTime = ptime.time() self._newMsg(" %s: %0.4f ms", msg, (newTime - self._lastTime) * 1000) self._lastTime = newTime def mark(self, msg=None): self(msg) def _newMsg(self, msg, *args): msg = " " * (self._depth - 1) + msg if self._delayed: self._msgs.append((msg, args)) else: self.flush() print(msg % args) def __del__(self): self.finish() def finish(self, msg=None): """Add a final message; flush the message list if no parent profiler. """ if self._finished or self.disable: return self._finished = True if msg is not None: self(msg) self._newMsg("< Exiting %s, total time: %0.4f ms", self._name, (ptime.time() - self._firstTime) * 1000) type(self)._depth -= 1 if self._depth < 1: self.flush() def flush(self): if self._msgs: print("\n".join([m[0]%m[1] for m in self._msgs])) type(self)._msgs = [] def profile(code, name='profile_run', sort='cumulative', num=30): """Common-use for cProfile""" cProfile.run(code, name) stats = pstats.Stats(name) stats.sort_stats(sort) stats.print_stats(num) return stats #### Code for listing (nearly) all objects in the known universe #### http://utcc.utoronto.ca/~cks/space/blog/python/GetAllObjects # Recursively expand slist's objects # into olist, using seen to track # already processed objects. def _getr(slist, olist, first=True): i = 0 for e in slist: oid = id(e) typ = type(e) if oid in olist or typ is int: ## or e in olist: ## since we're excluding all ints, there is no longer a need to check for olist keys continue olist[oid] = e if first and (i%1000) == 0: gc.collect() tl = gc.get_referents(e) if tl: _getr(tl, olist, first=False) i += 1 # The public function. def get_all_objects(): """Return a list of all live Python objects (excluding int and long), not including the list itself.""" gc.collect() gcl = gc.get_objects() olist = {} _getr(gcl, olist) del olist[id(olist)] del olist[id(gcl)] del olist[id(sys._getframe())] return olist def lookup(oid, objects=None): """Return an object given its ID, if it exists.""" if objects is None: objects = get_all_objects() return objects[oid] class ObjTracker(object): """ Tracks all objects under the sun, reporting the changes between snapshots: what objects are created, deleted, and persistent. This class is very useful for tracking memory leaks. The class goes to great (but not heroic) lengths to avoid tracking its own internal objects. Example: ot = ObjTracker() # takes snapshot of currently existing objects ... do stuff ... ot.diff() # prints lists of objects created and deleted since ot was initialized ... do stuff ... ot.diff() # prints lists of objects created and deleted since last call to ot.diff() # also prints list of items that were created since initialization AND have not been deleted yet # (if done correctly, this list can tell you about objects that were leaked) arrays = ot.findPersistent('ndarray') ## returns all objects matching 'ndarray' (string match, not instance checking) ## that were considered persistent when the last diff() was run describeObj(arrays[0]) ## See if we can determine who has references to this array """ allObjs = {} ## keep track of all objects created and stored within class instances allObjs[id(allObjs)] = None def __init__(self): self.startRefs = {} ## list of objects that exist when the tracker is initialized {oid: weakref} ## (If it is not possible to weakref the object, then the value is None) self.startCount = {} self.newRefs = {} ## list of objects that have been created since initialization self.persistentRefs = {} ## list of objects considered 'persistent' when the last diff() was called self.objTypes = {} ObjTracker.allObjs[id(self)] = None self.objs = [self.__dict__, self.startRefs, self.startCount, self.newRefs, self.persistentRefs, self.objTypes] self.objs.append(self.objs) for v in self.objs: ObjTracker.allObjs[id(v)] = None self.start() def findNew(self, regex): """Return all objects matching regex that were considered 'new' when the last diff() was run.""" return self.findTypes(self.newRefs, regex) def findPersistent(self, regex): """Return all objects matching regex that were considered 'persistent' when the last diff() was run.""" return self.findTypes(self.persistentRefs, regex) def start(self): """ Remember the current set of objects as the comparison for all future calls to diff() Called automatically on init, but can be called manually as well. """ refs, count, objs = self.collect() for r in self.startRefs: self.forgetRef(self.startRefs[r]) self.startRefs.clear() self.startRefs.update(refs) for r in refs: self.rememberRef(r) self.startCount.clear() self.startCount.update(count) #self.newRefs.clear() #self.newRefs.update(refs) def diff(self, **kargs): """ Compute all differences between the current object set and the reference set. Print a set of reports for created, deleted, and persistent objects """ refs, count, objs = self.collect() ## refs contains the list of ALL objects ## Which refs have disappeared since call to start() (these are only displayed once, then forgotten.) delRefs = {} for i in list(self.startRefs.keys()): if i not in refs: delRefs[i] = self.startRefs[i] del self.startRefs[i] self.forgetRef(delRefs[i]) for i in list(self.newRefs.keys()): if i not in refs: delRefs[i] = self.newRefs[i] del self.newRefs[i] self.forgetRef(delRefs[i]) #print "deleted:", len(delRefs) ## Which refs have appeared since call to start() or diff() persistentRefs = {} ## created since start(), but before last diff() createRefs = {} ## created since last diff() for o in refs: if o not in self.startRefs: if o not in self.newRefs: createRefs[o] = refs[o] ## object has been created since last diff() else: persistentRefs[o] = refs[o] ## object has been created since start(), but before last diff() (persistent) #print "new:", len(newRefs) ## self.newRefs holds the entire set of objects created since start() for r in self.newRefs: self.forgetRef(self.newRefs[r]) self.newRefs.clear() self.newRefs.update(persistentRefs) self.newRefs.update(createRefs) for r in self.newRefs: self.rememberRef(self.newRefs[r]) #print "created:", len(createRefs) ## self.persistentRefs holds all objects considered persistent. self.persistentRefs.clear() self.persistentRefs.update(persistentRefs) print("----------- Count changes since start: ----------") c1 = count.copy() for k in self.startCount: c1[k] = c1.get(k, 0) - self.startCount[k] typs = list(c1.keys()) typs.sort(key=lambda a: c1[a]) for t in typs: if c1[t] == 0: continue num = "%d" % c1[t] print(" " + num + " "*(10-len(num)) + str(t)) print("----------- %d Deleted since last diff: ------------" % len(delRefs)) self.report(delRefs, objs, **kargs) print("----------- %d Created since last diff: ------------" % len(createRefs)) self.report(createRefs, objs, **kargs) print("----------- %d Created since start (persistent): ------------" % len(persistentRefs)) self.report(persistentRefs, objs, **kargs) def __del__(self): self.startRefs.clear() self.startCount.clear() self.newRefs.clear() self.persistentRefs.clear() del ObjTracker.allObjs[id(self)] for v in self.objs: del ObjTracker.allObjs[id(v)] @classmethod def isObjVar(cls, o): return type(o) is cls or id(o) in cls.allObjs def collect(self): print("Collecting list of all objects...") gc.collect() objs = get_all_objects() frame = sys._getframe() del objs[id(frame)] ## ignore the current frame del objs[id(frame.f_code)] ignoreTypes = [int] refs = {} count = {} for k in objs: o = objs[k] typ = type(o) oid = id(o) if ObjTracker.isObjVar(o) or typ in ignoreTypes: continue try: ref = weakref.ref(obj) except: ref = None refs[oid] = ref typ = type(o) typStr = typeStr(o) self.objTypes[oid] = typStr ObjTracker.allObjs[id(typStr)] = None count[typ] = count.get(typ, 0) + 1 print("All objects: %d Tracked objects: %d" % (len(objs), len(refs))) return refs, count, objs def forgetRef(self, ref): if ref is not None: del ObjTracker.allObjs[id(ref)] def rememberRef(self, ref): ## Record the address of the weakref object so it is not included in future object counts. if ref is not None: ObjTracker.allObjs[id(ref)] = None def lookup(self, oid, ref, objs=None): if ref is None or ref() is None: try: obj = lookup(oid, objects=objs) except: obj = None else: obj = ref() return obj def report(self, refs, allobjs=None, showIDs=False): if allobjs is None: allobjs = get_all_objects() count = {} rev = {} for oid in refs: obj = self.lookup(oid, refs[oid], allobjs) if obj is None: typ = "[del] " + self.objTypes[oid] else: typ = typeStr(obj) if typ not in rev: rev[typ] = [] rev[typ].append(oid) c = count.get(typ, [0,0]) count[typ] = [c[0]+1, c[1]+objectSize(obj)] typs = list(count.keys()) typs.sort(key=lambda a: count[a][1]) for t in typs: line = " %d\t%d\t%s" % (count[t][0], count[t][1], t) if showIDs: line += "\t"+",".join(map(str,rev[t])) print(line) def findTypes(self, refs, regex): allObjs = get_all_objects() ids = {} objs = [] r = re.compile(regex) for k in refs: if r.search(self.objTypes[k]): objs.append(self.lookup(k, refs[k], allObjs)) return objs def describeObj(obj, depth=4, path=None, ignore=None): """ Trace all reference paths backward, printing a list of different ways this object can be accessed. Attempts to answer the question "who has a reference to this object" """ if path is None: path = [obj] if ignore is None: ignore = {} ## holds IDs of objects used within the function. ignore[id(sys._getframe())] = None ignore[id(path)] = None gc.collect() refs = gc.get_referrers(obj) ignore[id(refs)] = None printed=False for ref in refs: if id(ref) in ignore: continue if id(ref) in list(map(id, path)): print("Cyclic reference: " + refPathString([ref]+path)) printed = True continue newPath = [ref]+path if len(newPath) >= depth: refStr = refPathString(newPath) if '[_]' not in refStr: ## ignore '_' references generated by the interactive shell print(refStr) printed = True else: describeObj(ref, depth, newPath, ignore) printed = True if not printed: print("Dead end: " + refPathString(path)) def typeStr(obj): """Create a more useful type string by making types report their class.""" typ = type(obj) if typ == getattr(types, 'InstanceType', None): return "" % obj.__class__.__name__ else: return str(typ) def searchRefs(obj, *args): """Pseudo-interactive function for tracing references backward. **Arguments:** obj: The initial object from which to start searching args: A set of string or int arguments. each integer selects one of obj's referrers to be the new 'obj' each string indicates an action to take on the current 'obj': t: print the types of obj's referrers l: print the lengths of obj's referrers (if they have __len__) i: print the IDs of obj's referrers o: print obj ro: return obj rr: return list of obj's referrers Examples:: searchRefs(obj, 't') ## Print types of all objects referring to obj searchRefs(obj, 't', 0, 't') ## ..then select the first referrer and print the types of its referrers searchRefs(obj, 't', 0, 't', 'l') ## ..also print lengths of the last set of referrers searchRefs(obj, 0, 1, 'ro') ## Select index 0 from obj's referrer, then select index 1 from the next set of referrers, then return that object """ ignore = {id(sys._getframe()): None} gc.collect() refs = gc.get_referrers(obj) ignore[id(refs)] = None refs = [r for r in refs if id(r) not in ignore] for a in args: #fo = allFrameObjs() #refs = [r for r in refs if r not in fo] if type(a) is int: obj = refs[a] gc.collect() refs = gc.get_referrers(obj) ignore[id(refs)] = None refs = [r for r in refs if id(r) not in ignore] elif a == 't': print(list(map(typeStr, refs))) elif a == 'i': print(list(map(id, refs))) elif a == 'l': def slen(o): if hasattr(o, '__len__'): return len(o) else: return None print(list(map(slen, refs))) elif a == 'o': print(obj) elif a == 'ro': return obj elif a == 'rr': return refs def allFrameObjs(): """Return list of frame objects in current stack. Useful if you want to ignore these objects in refernece searches""" f = sys._getframe() objs = [] while f is not None: objs.append(f) objs.append(f.f_code) #objs.append(f.f_locals) #objs.append(f.f_globals) #objs.append(f.f_builtins) f = f.f_back return objs def findObj(regex): """Return a list of objects whose typeStr matches regex""" allObjs = get_all_objects() objs = [] r = re.compile(regex) for i in allObjs: obj = allObjs[i] if r.search(typeStr(obj)): objs.append(obj) return objs def listRedundantModules(): """List modules that have been imported more than once via different paths.""" mods = {} for name, mod in sys.modules.items(): if not hasattr(mod, '__file__'): continue mfile = os.path.abspath(mod.__file__) if mfile[-1] == 'c': mfile = mfile[:-1] if mfile in mods: print("module at %s has 2 names: %s, %s" % (mfile, name, mods[mfile])) else: mods[mfile] = name def walkQObjectTree(obj, counts=None, verbose=False, depth=0): """ Walk through a tree of QObjects, doing nothing to them. The purpose of this function is to find dead objects and generate a crash immediately rather than stumbling upon them later. Prints a count of the objects encountered, for fun. (or is it?) """ if verbose: print(" "*depth + typeStr(obj)) report = False if counts is None: counts = {} report = True typ = str(type(obj)) try: counts[typ] += 1 except KeyError: counts[typ] = 1 for child in obj.children(): walkQObjectTree(child, counts, verbose, depth+1) return counts QObjCache = {} def qObjectReport(verbose=False): """Generate a report counting all QObjects and their types""" global qObjCache count = {} for obj in findObj('PyQt'): if isinstance(obj, QtCore.QObject): oid = id(obj) if oid not in QObjCache: QObjCache[oid] = typeStr(obj) + " " + obj.objectName() try: QObjCache[oid] += " " + obj.parent().objectName() QObjCache[oid] += " " + obj.text() except: pass print("check obj", oid, str(QObjCache[oid])) if obj.parent() is None: walkQObjectTree(obj, count, verbose) typs = list(count.keys()) typs.sort() for t in typs: print(count[t], "\t", t) class PrintDetector(object): """Find code locations that print to stdout.""" def __init__(self): self.stdout = sys.stdout sys.stdout = self def remove(self): sys.stdout = self.stdout def __del__(self): self.remove() def write(self, x): self.stdout.write(x) traceback.print_stack() def flush(self): self.stdout.flush() def listQThreads(): """Prints Thread IDs (Qt's, not OS's) for all QThreads.""" thr = findObj('[Tt]hread') thr = [t for t in thr if isinstance(t, QtCore.QThread)] import sip for t in thr: print("--> ", t) print(" Qt ID: 0x%x" % sip.unwrapinstance(t)) def pretty(data, indent=''): """Format nested dict/list/tuple structures into a more human-readable string This function is a bit better than pprint for displaying OrderedDicts. """ ret = "" ind2 = indent + " " if isinstance(data, dict): ret = indent+"{\n" for k, v in data.iteritems(): ret += ind2 + repr(k) + ": " + pretty(v, ind2).strip() + "\n" ret += indent+"}\n" elif isinstance(data, list) or isinstance(data, tuple): s = repr(data) if len(s) < 40: ret += indent + s else: if isinstance(data, list): d = '[]' else: d = '()' ret = indent+d[0]+"\n" for i, v in enumerate(data): ret += ind2 + str(i) + ": " + pretty(v, ind2).strip() + "\n" ret += indent+d[1]+"\n" else: ret += indent + repr(data) return ret class ThreadTrace(object): """ Used to debug freezing by starting a new thread that reports on the location of other threads periodically. """ def __init__(self, interval=10.0): self.interval = interval self.lock = Mutex() self._stop = False self.start() def stop(self): with self.lock: self._stop = True def start(self, interval=None): if interval is not None: self.interval = interval self._stop = False self.thread = threading.Thread(target=self.run) self.thread.daemon = True self.thread.start() def run(self): while True: with self.lock: if self._stop is True: return print("\n============= THREAD FRAMES: ================") for id, frame in sys._current_frames().items(): if id == threading.current_thread().ident: continue print("<< thread %d >>" % id) traceback.print_stack(frame) print("===============================================\n") time.sleep(self.interval) class ThreadColor(object): """ Wrapper on stdout/stderr that colors text by the current thread ID. *stream* must be 'stdout' or 'stderr'. """ colors = {} lock = Mutex() def __init__(self, stream): self.stream = getattr(sys, stream) self.err = stream == 'stderr' setattr(sys, stream, self) def write(self, msg): with self.lock: cprint.cprint(self.stream, self.color(), msg, -1, stderr=self.err) def flush(self): with self.lock: self.stream.flush() def color(self): tid = threading.current_thread() if tid not in self.colors: c = (len(self.colors) % 15) + 1 self.colors[tid] = c return self.colors[tid] pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/dockarea/000077500000000000000000000000001300727121400214115ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/dockarea/Container.py000066400000000000000000000206721300727121400237140ustar00rootroot00000000000000# -*- coding: utf-8 -*- from ..Qt import QtCore, QtGui import weakref class Container(object): #sigStretchChanged = QtCore.Signal() ## can't do this here; not a QObject. def __init__(self, area): object.__init__(self) self.area = area self._container = None self._stretch = (10, 10) self.stretches = weakref.WeakKeyDictionary() def container(self): return self._container def containerChanged(self, c): self._container = c def type(self): return None def insert(self, new, pos=None, neighbor=None): # remove from existing parent first new.setParent(None) if not isinstance(new, list): new = [new] if neighbor is None: if pos == 'before': index = 0 else: index = self.count() else: index = self.indexOf(neighbor) if index == -1: index = 0 if pos == 'after': index += 1 for n in new: #print "change container", n, " -> ", self n.containerChanged(self) #print "insert", n, " -> ", self, index self._insertItem(n, index) index += 1 n.sigStretchChanged.connect(self.childStretchChanged) #print "child added", self self.updateStretch() def apoptose(self, propagate=True): ##if there is only one (or zero) item in this container, disappear. cont = self._container c = self.count() if c > 1: return if self.count() == 1: ## if there is one item, give it to the parent container (unless this is the top) if self is self.area.topContainer: return self.container().insert(self.widget(0), 'before', self) #print "apoptose:", self self.close() if propagate and cont is not None: cont.apoptose() def close(self): self.area = None self._container = None self.setParent(None) def childEvent(self, ev): ch = ev.child() if ev.removed() and hasattr(ch, 'sigStretchChanged'): #print "Child", ev.child(), "removed, updating", self try: ch.sigStretchChanged.disconnect(self.childStretchChanged) except: pass self.updateStretch() def childStretchChanged(self): #print "child", QtCore.QObject.sender(self), "changed shape, updating", self self.updateStretch() def setStretch(self, x=None, y=None): #print "setStretch", self, x, y self._stretch = (x, y) self.sigStretchChanged.emit() def updateStretch(self): ###Set the stretch values for this container to reflect its contents pass def stretch(self): """Return the stretch factors for this container""" return self._stretch class SplitContainer(Container, QtGui.QSplitter): """Horizontal or vertical splitter with some changes: - save/restore works correctly """ sigStretchChanged = QtCore.Signal() def __init__(self, area, orientation): QtGui.QSplitter.__init__(self) self.setOrientation(orientation) Container.__init__(self, area) #self.splitterMoved.connect(self.restretchChildren) def _insertItem(self, item, index): self.insertWidget(index, item) item.show() ## need to show since it may have been previously hidden by tab def saveState(self): sizes = self.sizes() if all([x == 0 for x in sizes]): sizes = [10] * len(sizes) return {'sizes': sizes} def restoreState(self, state): sizes = state['sizes'] self.setSizes(sizes) for i in range(len(sizes)): self.setStretchFactor(i, sizes[i]) def childEvent(self, ev): QtGui.QSplitter.childEvent(self, ev) Container.childEvent(self, ev) #def restretchChildren(self): #sizes = self.sizes() #tot = sum(sizes) class HContainer(SplitContainer): def __init__(self, area): SplitContainer.__init__(self, area, QtCore.Qt.Horizontal) def type(self): return 'horizontal' def updateStretch(self): ##Set the stretch values for this container to reflect its contents #print "updateStretch", self x = 0 y = 0 sizes = [] for i in range(self.count()): wx, wy = self.widget(i).stretch() x += wx y = max(y, wy) sizes.append(wx) #print " child", self.widget(i), wx, wy self.setStretch(x, y) #print sizes tot = float(sum(sizes)) if tot == 0: scale = 1.0 else: scale = self.width() / tot self.setSizes([int(s*scale) for s in sizes]) class VContainer(SplitContainer): def __init__(self, area): SplitContainer.__init__(self, area, QtCore.Qt.Vertical) def type(self): return 'vertical' def updateStretch(self): ##Set the stretch values for this container to reflect its contents #print "updateStretch", self x = 0 y = 0 sizes = [] for i in range(self.count()): wx, wy = self.widget(i).stretch() y += wy x = max(x, wx) sizes.append(wy) #print " child", self.widget(i), wx, wy self.setStretch(x, y) #print sizes tot = float(sum(sizes)) if tot == 0: scale = 1.0 else: scale = self.height() / tot self.setSizes([int(s*scale) for s in sizes]) class TContainer(Container, QtGui.QWidget): sigStretchChanged = QtCore.Signal() def __init__(self, area): QtGui.QWidget.__init__(self) Container.__init__(self, area) self.layout = QtGui.QGridLayout() self.layout.setSpacing(0) self.layout.setContentsMargins(0,0,0,0) self.setLayout(self.layout) self.hTabLayout = QtGui.QHBoxLayout() self.hTabBox = QtGui.QWidget() self.hTabBox.setLayout(self.hTabLayout) self.hTabLayout.setSpacing(2) self.hTabLayout.setContentsMargins(0,0,0,0) self.layout.addWidget(self.hTabBox, 0, 1) self.stack = QtGui.QStackedWidget() self.layout.addWidget(self.stack, 1, 1) self.stack.childEvent = self.stackChildEvent self.setLayout(self.layout) for n in ['count', 'widget', 'indexOf']: setattr(self, n, getattr(self.stack, n)) def _insertItem(self, item, index): if not isinstance(item, Dock.Dock): raise Exception("Tab containers may hold only docks, not other containers.") self.stack.insertWidget(index, item) self.hTabLayout.insertWidget(index, item.label) #QtCore.QObject.connect(item.label, QtCore.SIGNAL('clicked'), self.tabClicked) item.label.sigClicked.connect(self.tabClicked) self.tabClicked(item.label) def tabClicked(self, tab, ev=None): if ev is None or ev.button() == QtCore.Qt.LeftButton: for i in range(self.count()): w = self.widget(i) if w is tab.dock: w.label.setDim(False) self.stack.setCurrentIndex(i) else: w.label.setDim(True) def raiseDock(self, dock): """Move *dock* to the top of the stack""" self.stack.currentWidget().label.setDim(True) self.stack.setCurrentWidget(dock) dock.label.setDim(False) def type(self): return 'tab' def saveState(self): return {'index': self.stack.currentIndex()} def restoreState(self, state): self.stack.setCurrentIndex(state['index']) def updateStretch(self): ##Set the stretch values for this container to reflect its contents x = 0 y = 0 for i in range(self.count()): wx, wy = self.widget(i).stretch() x = max(x, wx) y = max(y, wy) self.setStretch(x, y) def stackChildEvent(self, ev): QtGui.QStackedWidget.childEvent(self.stack, ev) Container.childEvent(self, ev) from . import Dock pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/dockarea/Dock.py000066400000000000000000000274551300727121400226600ustar00rootroot00000000000000from ..Qt import QtCore, QtGui from .DockDrop import * from ..widgets.VerticalLabel import VerticalLabel from ..python2_3 import asUnicode class Dock(QtGui.QWidget, DockDrop): sigStretchChanged = QtCore.Signal() sigClosed = QtCore.Signal(object) def __init__(self, name, area=None, size=(10, 10), widget=None, hideTitle=False, autoOrientation=True, closable=False): QtGui.QWidget.__init__(self) DockDrop.__init__(self) self._container = None self._name = name self.area = area self.label = DockLabel(name, self, closable) if closable: self.label.sigCloseClicked.connect(self.close) self.labelHidden = False self.moveLabel = True ## If false, the dock is no longer allowed to move the label. self.autoOrient = autoOrientation self.orientation = 'horizontal' #self.label.setAlignment(QtCore.Qt.AlignHCenter) self.topLayout = QtGui.QGridLayout() self.topLayout.setContentsMargins(0, 0, 0, 0) self.topLayout.setSpacing(0) self.setLayout(self.topLayout) self.topLayout.addWidget(self.label, 0, 1) self.widgetArea = QtGui.QWidget() self.topLayout.addWidget(self.widgetArea, 1, 1) self.layout = QtGui.QGridLayout() self.layout.setContentsMargins(0, 0, 0, 0) self.layout.setSpacing(0) self.widgetArea.setLayout(self.layout) self.widgetArea.setSizePolicy(QtGui.QSizePolicy.Expanding, QtGui.QSizePolicy.Expanding) self.widgets = [] self.currentRow = 0 #self.titlePos = 'top' self.raiseOverlay() self.hStyle = """ Dock > QWidget { border: 1px solid #000; border-radius: 5px; border-top-left-radius: 0px; border-top-right-radius: 0px; border-top-width: 0px; }""" self.vStyle = """ Dock > QWidget { border: 1px solid #000; border-radius: 5px; border-top-left-radius: 0px; border-bottom-left-radius: 0px; border-left-width: 0px; }""" self.nStyle = """ Dock > QWidget { border: 1px solid #000; border-radius: 5px; }""" self.dragStyle = """ Dock > QWidget { border: 4px solid #00F; border-radius: 5px; }""" self.setAutoFillBackground(False) self.widgetArea.setStyleSheet(self.hStyle) self.setStretch(*size) if widget is not None: self.addWidget(widget) if hideTitle: self.hideTitleBar() def implements(self, name=None): if name is None: return ['dock'] else: return name == 'dock' def setStretch(self, x=None, y=None): """ Set the 'target' size for this Dock. The actual size will be determined by comparing this Dock's stretch value to the rest of the docks it shares space with. """ #print "setStretch", self, x, y #self._stretch = (x, y) if x is None: x = 0 if y is None: y = 0 #policy = self.sizePolicy() #policy.setHorizontalStretch(x) #policy.setVerticalStretch(y) #self.setSizePolicy(policy) self._stretch = (x, y) self.sigStretchChanged.emit() #print "setStretch", self, x, y, self.stretch() def stretch(self): #policy = self.sizePolicy() #return policy.horizontalStretch(), policy.verticalStretch() return self._stretch #def stretch(self): #return self._stretch def hideTitleBar(self): """ Hide the title bar for this Dock. This will prevent the Dock being moved by the user. """ self.label.hide() self.labelHidden = True if 'center' in self.allowedAreas: self.allowedAreas.remove('center') self.updateStyle() def showTitleBar(self): """ Show the title bar for this Dock. """ self.label.show() self.labelHidden = False self.allowedAreas.add('center') self.updateStyle() def title(self): """ Gets the text displayed in the title bar for this dock. """ return asUnicode(self.label.text()) def setTitle(self, text): """ Sets the text displayed in title bar for this Dock. """ self.label.setText(text) def setOrientation(self, o='auto', force=False): """ Sets the orientation of the title bar for this Dock. Must be one of 'auto', 'horizontal', or 'vertical'. By default ('auto'), the orientation is determined based on the aspect ratio of the Dock. """ #print self.name(), "setOrientation", o, force if o == 'auto' and self.autoOrient: if self.container().type() == 'tab': o = 'horizontal' elif self.width() > self.height()*1.5: o = 'vertical' else: o = 'horizontal' if force or self.orientation != o: self.orientation = o self.label.setOrientation(o) self.updateStyle() def updateStyle(self): ## updates orientation and appearance of title bar #print self.name(), "update style:", self.orientation, self.moveLabel, self.label.isVisible() if self.labelHidden: self.widgetArea.setStyleSheet(self.nStyle) elif self.orientation == 'vertical': self.label.setOrientation('vertical') if self.moveLabel: #print self.name(), "reclaim label" self.topLayout.addWidget(self.label, 1, 0) self.widgetArea.setStyleSheet(self.vStyle) else: self.label.setOrientation('horizontal') if self.moveLabel: #print self.name(), "reclaim label" self.topLayout.addWidget(self.label, 0, 1) self.widgetArea.setStyleSheet(self.hStyle) def resizeEvent(self, ev): self.setOrientation() self.resizeOverlay(self.size()) def name(self): return self._name def container(self): return self._container def addWidget(self, widget, row=None, col=0, rowspan=1, colspan=1): """ Add a new widget to the interior of this Dock. Each Dock uses a QGridLayout to arrange widgets within. """ if row is None: row = self.currentRow self.currentRow = max(row+1, self.currentRow) self.widgets.append(widget) self.layout.addWidget(widget, row, col, rowspan, colspan) self.raiseOverlay() def startDrag(self): self.drag = QtGui.QDrag(self) mime = QtCore.QMimeData() #mime.setPlainText("asd") self.drag.setMimeData(mime) self.widgetArea.setStyleSheet(self.dragStyle) self.update() action = self.drag.exec_() self.updateStyle() def float(self): self.area.floatDock(self) def containerChanged(self, c): #print self.name(), "container changed" self._container = c if c.type() != 'tab': self.moveLabel = True self.label.setDim(False) else: self.moveLabel = False self.setOrientation(force=True) def raiseDock(self): """If this Dock is stacked underneath others, raise it to the top.""" self.container().raiseDock(self) def close(self): """Remove this dock from the DockArea it lives inside.""" self.setParent(None) self.label.setParent(None) self._container.apoptose() self._container = None self.sigClosed.emit(self) def __repr__(self): return "" % (self.name(), self.stretch()) ## PySide bug: We need to explicitly redefine these methods ## or else drag/drop events will not be delivered. def dragEnterEvent(self, *args): DockDrop.dragEnterEvent(self, *args) def dragMoveEvent(self, *args): DockDrop.dragMoveEvent(self, *args) def dragLeaveEvent(self, *args): DockDrop.dragLeaveEvent(self, *args) def dropEvent(self, *args): DockDrop.dropEvent(self, *args) class DockLabel(VerticalLabel): sigClicked = QtCore.Signal(object, object) sigCloseClicked = QtCore.Signal() def __init__(self, text, dock, showCloseButton): self.dim = False self.fixedWidth = False VerticalLabel.__init__(self, text, orientation='horizontal', forceWidth=False) self.setAlignment(QtCore.Qt.AlignTop|QtCore.Qt.AlignHCenter) self.dock = dock self.updateStyle() self.setAutoFillBackground(False) self.startedDrag = False self.closeButton = None if showCloseButton: self.closeButton = QtGui.QToolButton(self) self.closeButton.clicked.connect(self.sigCloseClicked) self.closeButton.setIcon(QtGui.QApplication.style().standardIcon(QtGui.QStyle.SP_TitleBarCloseButton)) def updateStyle(self): r = '3px' if self.dim: fg = '#aaa' bg = '#44a' border = '#339' else: fg = '#fff' bg = '#66c' border = '#55B' if self.orientation == 'vertical': self.vStyle = """DockLabel { background-color : %s; color : %s; border-top-right-radius: 0px; border-top-left-radius: %s; border-bottom-right-radius: 0px; border-bottom-left-radius: %s; border-width: 0px; border-right: 2px solid %s; padding-top: 3px; padding-bottom: 3px; }""" % (bg, fg, r, r, border) self.setStyleSheet(self.vStyle) else: self.hStyle = """DockLabel { background-color : %s; color : %s; border-top-right-radius: %s; border-top-left-radius: %s; border-bottom-right-radius: 0px; border-bottom-left-radius: 0px; border-width: 0px; border-bottom: 2px solid %s; padding-left: 3px; padding-right: 3px; }""" % (bg, fg, r, r, border) self.setStyleSheet(self.hStyle) def setDim(self, d): if self.dim != d: self.dim = d self.updateStyle() def setOrientation(self, o): VerticalLabel.setOrientation(self, o) self.updateStyle() def mousePressEvent(self, ev): if ev.button() == QtCore.Qt.LeftButton: self.pressPos = ev.pos() self.startedDrag = False ev.accept() def mouseMoveEvent(self, ev): if not self.startedDrag and (ev.pos() - self.pressPos).manhattanLength() > QtGui.QApplication.startDragDistance(): self.dock.startDrag() ev.accept() def mouseReleaseEvent(self, ev): if not self.startedDrag: self.sigClicked.emit(self, ev) ev.accept() def mouseDoubleClickEvent(self, ev): if ev.button() == QtCore.Qt.LeftButton: self.dock.float() def resizeEvent (self, ev): if self.closeButton: if self.orientation == 'vertical': size = ev.size().width() pos = QtCore.QPoint(0, 0) else: size = ev.size().height() pos = QtCore.QPoint(ev.size().width() - size, 0) self.closeButton.setFixedSize(QtCore.QSize(size, size)) self.closeButton.move(pos) super(DockLabel,self).resizeEvent(ev) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/dockarea/DockArea.py000066400000000000000000000260551300727121400234440ustar00rootroot00000000000000# -*- coding: utf-8 -*- import weakref from ..Qt import QtCore, QtGui from .Container import * from .DockDrop import * from .Dock import Dock from .. import debug as debug from ..python2_3 import basestring class DockArea(Container, QtGui.QWidget, DockDrop): def __init__(self, temporary=False, home=None): Container.__init__(self, self) QtGui.QWidget.__init__(self) DockDrop.__init__(self, allowedAreas=['left', 'right', 'top', 'bottom']) self.layout = QtGui.QVBoxLayout() self.layout.setContentsMargins(0,0,0,0) self.layout.setSpacing(0) self.setLayout(self.layout) self.docks = weakref.WeakValueDictionary() self.topContainer = None self.raiseOverlay() self.temporary = temporary self.tempAreas = [] self.home = home def type(self): return "top" def addDock(self, dock=None, position='bottom', relativeTo=None, **kwds): """Adds a dock to this area. ============== ================================================================= **Arguments:** dock The new Dock object to add. If None, then a new Dock will be created. position 'bottom', 'top', 'left', 'right', 'above', or 'below' relativeTo If relativeTo is None, then the new Dock is added to fill an entire edge of the window. If relativeTo is another Dock, then the new Dock is placed adjacent to it (or in a tabbed configuration for 'above' and 'below'). ============== ================================================================= All extra keyword arguments are passed to Dock.__init__() if *dock* is None. """ if dock is None: dock = Dock(**kwds) ## Determine the container to insert this dock into. ## If there is no neighbor, then the container is the top. if relativeTo is None or relativeTo is self: if self.topContainer is None: container = self neighbor = None else: container = self.topContainer neighbor = None else: if isinstance(relativeTo, basestring): relativeTo = self.docks[relativeTo] container = self.getContainer(relativeTo) neighbor = relativeTo ## what container type do we need? neededContainer = { 'bottom': 'vertical', 'top': 'vertical', 'left': 'horizontal', 'right': 'horizontal', 'above': 'tab', 'below': 'tab' }[position] ## Can't insert new containers into a tab container; insert outside instead. if neededContainer != container.type() and container.type() == 'tab': neighbor = container container = container.container() ## Decide if the container we have is suitable. ## If not, insert a new container inside. if neededContainer != container.type(): if neighbor is None: container = self.addContainer(neededContainer, self.topContainer) else: container = self.addContainer(neededContainer, neighbor) ## Insert the new dock before/after its neighbor insertPos = { 'bottom': 'after', 'top': 'before', 'left': 'before', 'right': 'after', 'above': 'before', 'below': 'after' }[position] #print "request insert", dock, insertPos, neighbor old = dock.container() container.insert(dock, insertPos, neighbor) dock.area = self self.docks[dock.name()] = dock if old is not None: old.apoptose() return dock def moveDock(self, dock, position, neighbor): """ Move an existing Dock to a new location. """ ## Moving to the edge of a tabbed dock causes a drop outside the tab box if position in ['left', 'right', 'top', 'bottom'] and neighbor is not None and neighbor.container() is not None and neighbor.container().type() == 'tab': neighbor = neighbor.container() self.addDock(dock, position, neighbor) def getContainer(self, obj): if obj is None: return self return obj.container() def makeContainer(self, typ): if typ == 'vertical': new = VContainer(self) elif typ == 'horizontal': new = HContainer(self) elif typ == 'tab': new = TContainer(self) return new def addContainer(self, typ, obj): """Add a new container around obj""" new = self.makeContainer(typ) container = self.getContainer(obj) container.insert(new, 'before', obj) #print "Add container:", new, " -> ", container if obj is not None: new.insert(obj) self.raiseOverlay() return new def insert(self, new, pos=None, neighbor=None): if self.topContainer is not None: self.topContainer.containerChanged(None) self.layout.addWidget(new) self.topContainer = new #print self, "set top:", new new._container = self self.raiseOverlay() #print "Insert top:", new def count(self): if self.topContainer is None: return 0 return 1 #def paintEvent(self, ev): #self.drawDockOverlay() def resizeEvent(self, ev): self.resizeOverlay(self.size()) def addTempArea(self): if self.home is None: area = DockArea(temporary=True, home=self) self.tempAreas.append(area) win = TempAreaWindow(area) area.win = win win.show() else: area = self.home.addTempArea() #print "added temp area", area, area.window() return area def floatDock(self, dock): """Removes *dock* from this DockArea and places it in a new window.""" area = self.addTempArea() area.win.resize(dock.size()) area.moveDock(dock, 'top', None) def removeTempArea(self, area): self.tempAreas.remove(area) #print "close window", area.window() area.window().close() def saveState(self): """ Return a serialized (storable) representation of the state of all Docks in this DockArea.""" if self.topContainer is None: main = None else: main = self.childState(self.topContainer) state = {'main': main, 'float': []} for a in self.tempAreas: geo = a.win.geometry() geo = (geo.x(), geo.y(), geo.width(), geo.height()) state['float'].append((a.saveState(), geo)) return state def childState(self, obj): if isinstance(obj, Dock): return ('dock', obj.name(), {}) else: childs = [] for i in range(obj.count()): childs.append(self.childState(obj.widget(i))) return (obj.type(), childs, obj.saveState()) def restoreState(self, state): """ Restore Dock configuration as generated by saveState. Note that this function does not create any Docks--it will only restore the arrangement of an existing set of Docks. """ ## 1) make dict of all docks and list of existing containers containers, docks = self.findAll() oldTemps = self.tempAreas[:] #print "found docks:", docks ## 2) create container structure, move docks into new containers if state['main'] is not None: self.buildFromState(state['main'], docks, self) ## 3) create floating areas, populate for s in state['float']: a = self.addTempArea() a.buildFromState(s[0]['main'], docks, a) a.win.setGeometry(*s[1]) ## 4) Add any remaining docks to the bottom for d in docks.values(): self.moveDock(d, 'below', None) #print "\nKill old containers:" ## 5) kill old containers for c in containers: c.close() for a in oldTemps: a.apoptose() def buildFromState(self, state, docks, root, depth=0): typ, contents, state = state pfx = " " * depth if typ == 'dock': try: obj = docks[contents] del docks[contents] except KeyError: raise Exception('Cannot restore dock state; no dock with name "%s"' % contents) else: obj = self.makeContainer(typ) root.insert(obj, 'after') #print pfx+"Add:", obj, " -> ", root if typ != 'dock': for o in contents: self.buildFromState(o, docks, obj, depth+1) obj.apoptose(propagate=False) obj.restoreState(state) ## this has to be done later? def findAll(self, obj=None, c=None, d=None): if obj is None: obj = self.topContainer ## check all temp areas first if c is None: c = [] d = {} for a in self.tempAreas: c1, d1 = a.findAll() c.extend(c1) d.update(d1) if isinstance(obj, Dock): d[obj.name()] = obj elif obj is not None: c.append(obj) for i in range(obj.count()): o2 = obj.widget(i) c2, d2 = self.findAll(o2) c.extend(c2) d.update(d2) return (c, d) def apoptose(self): #print "apoptose area:", self.temporary, self.topContainer, self.topContainer.count() if self.topContainer.count() == 0: self.topContainer = None if self.temporary: self.home.removeTempArea(self) #self.close() def clear(self): docks = self.findAll()[1] for dock in docks.values(): dock.close() ## PySide bug: We need to explicitly redefine these methods ## or else drag/drop events will not be delivered. def dragEnterEvent(self, *args): DockDrop.dragEnterEvent(self, *args) def dragMoveEvent(self, *args): DockDrop.dragMoveEvent(self, *args) def dragLeaveEvent(self, *args): DockDrop.dragLeaveEvent(self, *args) def dropEvent(self, *args): DockDrop.dropEvent(self, *args) class TempAreaWindow(QtGui.QMainWindow): def __init__(self, area, **kwargs): QtGui.QMainWindow.__init__(self, **kwargs) self.setCentralWidget(area) def closeEvent(self, *args, **kwargs): self.centralWidget().clear() QtGui.QMainWindow.closeEvent(self, *args, **kwargs) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/dockarea/DockDrop.py000066400000000000000000000077671300727121400235110ustar00rootroot00000000000000# -*- coding: utf-8 -*- from ..Qt import QtCore, QtGui class DockDrop(object): """Provides dock-dropping methods""" def __init__(self, allowedAreas=None): object.__init__(self) if allowedAreas is None: allowedAreas = ['center', 'right', 'left', 'top', 'bottom'] self.allowedAreas = set(allowedAreas) self.setAcceptDrops(True) self.dropArea = None self.overlay = DropAreaOverlay(self) self.overlay.raise_() def resizeOverlay(self, size): self.overlay.resize(size) def raiseOverlay(self): self.overlay.raise_() def dragEnterEvent(self, ev): src = ev.source() if hasattr(src, 'implements') and src.implements('dock'): #print "drag enter accept" ev.accept() else: #print "drag enter ignore" ev.ignore() def dragMoveEvent(self, ev): #print "drag move" ld = ev.pos().x() rd = self.width() - ld td = ev.pos().y() bd = self.height() - td mn = min(ld, rd, td, bd) if mn > 30: self.dropArea = "center" elif (ld == mn or td == mn) and mn > self.height()/3.: self.dropArea = "center" elif (rd == mn or ld == mn) and mn > self.width()/3.: self.dropArea = "center" elif rd == mn: self.dropArea = "right" elif ld == mn: self.dropArea = "left" elif td == mn: self.dropArea = "top" elif bd == mn: self.dropArea = "bottom" if ev.source() is self and self.dropArea == 'center': #print " no self-center" self.dropArea = None ev.ignore() elif self.dropArea not in self.allowedAreas: #print " not allowed" self.dropArea = None ev.ignore() else: #print " ok" ev.accept() self.overlay.setDropArea(self.dropArea) def dragLeaveEvent(self, ev): self.dropArea = None self.overlay.setDropArea(self.dropArea) def dropEvent(self, ev): area = self.dropArea if area is None: return if area == 'center': area = 'above' self.area.moveDock(ev.source(), area, self) self.dropArea = None self.overlay.setDropArea(self.dropArea) class DropAreaOverlay(QtGui.QWidget): """Overlay widget that draws drop areas during a drag-drop operation""" def __init__(self, parent): QtGui.QWidget.__init__(self, parent) self.dropArea = None self.hide() self.setAttribute(QtCore.Qt.WA_TransparentForMouseEvents) def setDropArea(self, area): self.dropArea = area if area is None: self.hide() else: ## Resize overlay to just the region where drop area should be displayed. ## This works around a Qt bug--can't display transparent widgets over QGLWidget prgn = self.parent().rect() rgn = QtCore.QRect(prgn) w = min(30, prgn.width()/3.) h = min(30, prgn.height()/3.) if self.dropArea == 'left': rgn.setWidth(w) elif self.dropArea == 'right': rgn.setLeft(rgn.left() + prgn.width() - w) elif self.dropArea == 'top': rgn.setHeight(h) elif self.dropArea == 'bottom': rgn.setTop(rgn.top() + prgn.height() - h) elif self.dropArea == 'center': rgn.adjust(w, h, -w, -h) self.setGeometry(rgn) self.show() self.update() def paintEvent(self, ev): if self.dropArea is None: return p = QtGui.QPainter(self) rgn = self.rect() p.setBrush(QtGui.QBrush(QtGui.QColor(100, 100, 255, 50))) p.setPen(QtGui.QPen(QtGui.QColor(50, 50, 150), 3)) p.drawRect(rgn) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/dockarea/__init__.py000066400000000000000000000000651300727121400235230ustar00rootroot00000000000000from .DockArea import DockArea from .Dock import Dockpyqtgraph-pyqtgraph-0.10.0/pyqtgraph/dockarea/tests/000077500000000000000000000000001300727121400225535ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/dockarea/tests/test_dock.py000066400000000000000000000005731300727121400251110ustar00rootroot00000000000000# -*- coding: utf-8 -*- #import sip #sip.setapi('QString', 1) import pyqtgraph as pg pg.mkQApp() import pyqtgraph.dockarea as da def test_dock(): name = pg.asUnicode("évènts_zàhéér") dock = da.Dock(name=name) # make sure unicode names work correctly assert dock.name() == name # no surprises in return type. assert type(dock.name()) == type(name) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/exceptionHandling.py000066400000000000000000000100651300727121400236570ustar00rootroot00000000000000# -*- coding: utf-8 -*- """This module installs a wrapper around sys.excepthook which allows multiple new exception handlers to be registered. Optionally, the wrapper also stops exceptions from causing long-term storage of local stack frames. This has two major effects: - Unhandled exceptions will no longer cause memory leaks (If an exception occurs while a lot of data is present on the stack, such as when loading large files, the data would ordinarily be kept until the next exception occurs. We would rather release this memory as soon as possible.) - Some debuggers may have a hard time handling uncaught exceptions The module also provides a callback mechanism allowing others to respond to exceptions. """ import sys, time #from lib.Manager import logMsg import traceback #from log import * #logging = False callbacks = [] clear_tracebacks = False def register(fn): """ Register a callable to be invoked when there is an unhandled exception. The callback will be passed the output of sys.exc_info(): (exception type, exception, traceback) Multiple callbacks will be invoked in the order they were registered. """ callbacks.append(fn) def unregister(fn): """Unregister a previously registered callback.""" callbacks.remove(fn) def setTracebackClearing(clear=True): """ Enable or disable traceback clearing. By default, clearing is disabled and Python will indefinitely store unhandled exception stack traces. This function is provided since Python's default behavior can cause unexpected retention of large memory-consuming objects. """ global clear_tracebacks clear_tracebacks = clear class ExceptionHandler(object): def __call__(self, *args): ## Start by extending recursion depth just a bit. ## If the error we are catching is due to recursion, we don't want to generate another one here. recursionLimit = sys.getrecursionlimit() try: sys.setrecursionlimit(recursionLimit+100) ## call original exception handler first (prints exception) global original_excepthook, callbacks, clear_tracebacks try: print("===== %s =====" % str(time.strftime("%Y.%m.%d %H:%m:%S", time.localtime(time.time())))) except Exception: sys.stderr.write("Warning: stdout is broken! Falling back to stderr.\n") sys.stdout = sys.stderr ret = original_excepthook(*args) for cb in callbacks: try: cb(*args) except Exception: print(" --------------------------------------------------------------") print(" Error occurred during exception callback %s" % str(cb)) print(" --------------------------------------------------------------") traceback.print_exception(*sys.exc_info()) ## Clear long-term storage of last traceback to prevent memory-hogging. ## (If an exception occurs while a lot of data is present on the stack, ## such as when loading large files, the data would ordinarily be kept ## until the next exception occurs. We would rather release this memory ## as soon as possible.) if clear_tracebacks is True: sys.last_traceback = None finally: sys.setrecursionlimit(recursionLimit) def implements(self, interface=None): ## this just makes it easy for us to detect whether an ExceptionHook is already installed. if interface is None: return ['ExceptionHandler'] else: return interface == 'ExceptionHandler' ## replace built-in excepthook only if this has not already been done if not (hasattr(sys.excepthook, 'implements') and sys.excepthook.implements('ExceptionHandler')): original_excepthook = sys.excepthook sys.excepthook = ExceptionHandler() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/exporters/000077500000000000000000000000001300727121400216735ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/exporters/CSVExporter.py000066400000000000000000000053561300727121400244420ustar00rootroot00000000000000from ..Qt import QtGui, QtCore from .Exporter import Exporter from ..parametertree import Parameter from .. import PlotItem __all__ = ['CSVExporter'] class CSVExporter(Exporter): Name = "CSV from plot data" windows = [] def __init__(self, item): Exporter.__init__(self, item) self.params = Parameter(name='params', type='group', children=[ {'name': 'separator', 'type': 'list', 'value': 'comma', 'values': ['comma', 'tab']}, {'name': 'precision', 'type': 'int', 'value': 10, 'limits': [0, None]}, {'name': 'columnMode', 'type': 'list', 'values': ['(x,y) per plot', '(x,y,y,y) for all plots']} ]) def parameters(self): return self.params def export(self, fileName=None): if not isinstance(self.item, PlotItem): raise Exception("Must have a PlotItem selected for CSV export.") if fileName is None: self.fileSaveDialog(filter=["*.csv", "*.tsv"]) return fd = open(fileName, 'w') data = [] header = [] appendAllX = self.params['columnMode'] == '(x,y) per plot' for i, c in enumerate(self.item.curves): cd = c.getData() if cd[0] is None: continue data.append(cd) if hasattr(c, 'implements') and c.implements('plotData') and c.name() is not None: name = c.name().replace('"', '""') + '_' xName, yName = '"'+name+'x"', '"'+name+'y"' else: xName = 'x%04d' % i yName = 'y%04d' % i if appendAllX or i == 0: header.extend([xName, yName]) else: header.extend([yName]) if self.params['separator'] == 'comma': sep = ',' else: sep = '\t' fd.write(sep.join(header) + '\n') i = 0 numFormat = '%%0.%dg' % self.params['precision'] numRows = max([len(d[0]) for d in data]) for i in range(numRows): for j, d in enumerate(data): # write x value if this is the first column, or if we want x # for all rows if appendAllX or j == 0: if d is not None and i < len(d[0]): fd.write(numFormat % d[0][i] + sep) else: fd.write(' %s' % sep) # write y value if d is not None and i < len(d[1]): fd.write(numFormat % d[1][i] + sep) else: fd.write(' %s' % sep) fd.write('\n') fd.close() CSVExporter.register() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/exporters/Exporter.py000066400000000000000000000124211300727121400240550ustar00rootroot00000000000000from ..widgets.FileDialog import FileDialog from ..Qt import QtGui, QtCore, QtSvg from ..python2_3 import asUnicode, basestring from ..GraphicsScene import GraphicsScene import os, re LastExportDirectory = None class Exporter(object): """ Abstract class used for exporting graphics to file / printer / whatever. """ allowCopy = False # subclasses set this to True if they can use the copy buffer Exporters = [] @classmethod def register(cls): """ Used to register Exporter classes to appear in the export dialog. """ Exporter.Exporters.append(cls) def __init__(self, item): """ Initialize with the item to be exported. Can be an individual graphics item or a scene. """ object.__init__(self) self.item = item def parameters(self): """Return the parameters used to configure this exporter.""" raise Exception("Abstract method must be overridden in subclass.") def export(self, fileName=None, toBytes=False, copy=False): """ If *fileName* is None, pop-up a file dialog. If *toBytes* is True, return a bytes object rather than writing to file. If *copy* is True, export to the copy buffer rather than writing to file. """ raise Exception("Abstract method must be overridden in subclass.") def fileSaveDialog(self, filter=None, opts=None): ## Show a file dialog, call self.export(fileName) when finished. if opts is None: opts = {} self.fileDialog = FileDialog() self.fileDialog.setFileMode(QtGui.QFileDialog.AnyFile) self.fileDialog.setAcceptMode(QtGui.QFileDialog.AcceptSave) if filter is not None: if isinstance(filter, basestring): self.fileDialog.setNameFilter(filter) elif isinstance(filter, list): self.fileDialog.setNameFilters(filter) global LastExportDirectory exportDir = LastExportDirectory if exportDir is not None: self.fileDialog.setDirectory(exportDir) self.fileDialog.show() self.fileDialog.opts = opts self.fileDialog.fileSelected.connect(self.fileSaveFinished) return def fileSaveFinished(self, fileName): fileName = asUnicode(fileName) global LastExportDirectory LastExportDirectory = os.path.split(fileName)[0] ## If file name does not match selected extension, append it now ext = os.path.splitext(fileName)[1].lower().lstrip('.') selectedExt = re.search(r'\*\.(\w+)\b', asUnicode(self.fileDialog.selectedNameFilter())) if selectedExt is not None: selectedExt = selectedExt.groups()[0].lower() if ext != selectedExt: fileName = fileName + '.' + selectedExt.lstrip('.') self.export(fileName=fileName, **self.fileDialog.opts) def getScene(self): if isinstance(self.item, GraphicsScene): return self.item else: return self.item.scene() def getSourceRect(self): if isinstance(self.item, GraphicsScene): w = self.item.getViewWidget() return w.viewportTransform().inverted()[0].mapRect(w.rect()) else: return self.item.sceneBoundingRect() def getTargetRect(self): if isinstance(self.item, GraphicsScene): return self.item.getViewWidget().rect() else: return self.item.mapRectToDevice(self.item.boundingRect()) def setExportMode(self, export, opts=None): """ Call setExportMode(export, opts) on all items that will be painted during the export. This informs the item that it is about to be painted for export, allowing it to alter its appearance temporarily *export* - bool; must be True before exporting and False afterward *opts* - dict; common parameters are 'antialias' and 'background' """ if opts is None: opts = {} for item in self.getPaintItems(): if hasattr(item, 'setExportMode'): item.setExportMode(export, opts) def getPaintItems(self, root=None): """Return a list of all items that should be painted in the correct order.""" if root is None: root = self.item preItems = [] postItems = [] if isinstance(root, QtGui.QGraphicsScene): childs = [i for i in root.items() if i.parentItem() is None] rootItem = [] else: childs = root.childItems() rootItem = [root] childs.sort(key=lambda a: a.zValue()) while len(childs) > 0: ch = childs.pop(0) tree = self.getPaintItems(ch) if int(ch.flags() & ch.ItemStacksBehindParent) > 0 or (ch.zValue() < 0 and int(ch.flags() & ch.ItemNegativeZStacksBehindParent) > 0): preItems.extend(tree) else: postItems.extend(tree) return preItems + rootItem + postItems def render(self, painter, targetRect, sourceRect, item=None): self.getScene().render(painter, QtCore.QRectF(targetRect), QtCore.QRectF(sourceRect)) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/exporters/HDF5Exporter.py000066400000000000000000000034251300727121400244700ustar00rootroot00000000000000from ..Qt import QtGui, QtCore from .Exporter import Exporter from ..parametertree import Parameter from .. import PlotItem import numpy try: import h5py HAVE_HDF5 = True except ImportError: HAVE_HDF5 = False __all__ = ['HDF5Exporter'] class HDF5Exporter(Exporter): Name = "HDF5 Export: plot (x,y)" windows = [] allowCopy = False def __init__(self, item): Exporter.__init__(self, item) self.params = Parameter(name='params', type='group', children=[ {'name': 'Name', 'type': 'str', 'value': 'Export',}, {'name': 'columnMode', 'type': 'list', 'values': ['(x,y) per plot', '(x,y,y,y) for all plots']}, ]) def parameters(self): return self.params def export(self, fileName=None): if not HAVE_HDF5: raise RuntimeError("This exporter requires the h5py package, " "but it was not importable.") if not isinstance(self.item, PlotItem): raise Exception("Must have a PlotItem selected for HDF5 export.") if fileName is None: self.fileSaveDialog(filter=["*.h5", "*.hdf", "*.hd5"]) return dsname = self.params['Name'] fd = h5py.File(fileName, 'a') # forces append to file... 'w' doesn't seem to "delete/overwrite" data = [] appendAllX = self.params['columnMode'] == '(x,y) per plot' for i,c in enumerate(self.item.curves): d = c.getData() if appendAllX or i == 0: data.append(d[0]) data.append(d[1]) fdata = numpy.array(data).astype('double') dset = fd.create_dataset(dsname, data=fdata) fd.close() if HAVE_HDF5: HDF5Exporter.register() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/exporters/ImageExporter.py000066400000000000000000000103141300727121400250170ustar00rootroot00000000000000from .Exporter import Exporter from ..parametertree import Parameter from ..Qt import QtGui, QtCore, QtSvg, USE_PYSIDE from .. import functions as fn import numpy as np __all__ = ['ImageExporter'] class ImageExporter(Exporter): Name = "Image File (PNG, TIF, JPG, ...)" allowCopy = True def __init__(self, item): Exporter.__init__(self, item) tr = self.getTargetRect() if isinstance(item, QtGui.QGraphicsItem): scene = item.scene() else: scene = item bgbrush = scene.views()[0].backgroundBrush() bg = bgbrush.color() if bgbrush.style() == QtCore.Qt.NoBrush: bg.setAlpha(0) self.params = Parameter(name='params', type='group', children=[ {'name': 'width', 'type': 'int', 'value': tr.width(), 'limits': (0, None)}, {'name': 'height', 'type': 'int', 'value': tr.height(), 'limits': (0, None)}, {'name': 'antialias', 'type': 'bool', 'value': True}, {'name': 'background', 'type': 'color', 'value': bg}, ]) self.params.param('width').sigValueChanged.connect(self.widthChanged) self.params.param('height').sigValueChanged.connect(self.heightChanged) def widthChanged(self): sr = self.getSourceRect() ar = float(sr.height()) / sr.width() self.params.param('height').setValue(self.params['width'] * ar, blockSignal=self.heightChanged) def heightChanged(self): sr = self.getSourceRect() ar = float(sr.width()) / sr.height() self.params.param('width').setValue(self.params['height'] * ar, blockSignal=self.widthChanged) def parameters(self): return self.params def export(self, fileName=None, toBytes=False, copy=False): if fileName is None and not toBytes and not copy: if USE_PYSIDE: filter = ["*."+str(f) for f in QtGui.QImageWriter.supportedImageFormats()] else: filter = ["*."+bytes(f).decode('utf-8') for f in QtGui.QImageWriter.supportedImageFormats()] preferred = ['*.png', '*.tif', '*.jpg'] for p in preferred[::-1]: if p in filter: filter.remove(p) filter.insert(0, p) self.fileSaveDialog(filter=filter) return targetRect = QtCore.QRect(0, 0, self.params['width'], self.params['height']) sourceRect = self.getSourceRect() #self.png = QtGui.QImage(targetRect.size(), QtGui.QImage.Format_ARGB32) #self.png.fill(pyqtgraph.mkColor(self.params['background'])) w, h = self.params['width'], self.params['height'] if w == 0 or h == 0: raise Exception("Cannot export image with size=0 (requested export size is %dx%d)" % (w,h)) bg = np.empty((self.params['width'], self.params['height'], 4), dtype=np.ubyte) color = self.params['background'] bg[:,:,0] = color.blue() bg[:,:,1] = color.green() bg[:,:,2] = color.red() bg[:,:,3] = color.alpha() self.png = fn.makeQImage(bg, alpha=True) ## set resolution of image: origTargetRect = self.getTargetRect() resolutionScale = targetRect.width() / origTargetRect.width() #self.png.setDotsPerMeterX(self.png.dotsPerMeterX() * resolutionScale) #self.png.setDotsPerMeterY(self.png.dotsPerMeterY() * resolutionScale) painter = QtGui.QPainter(self.png) #dtr = painter.deviceTransform() try: self.setExportMode(True, {'antialias': self.params['antialias'], 'background': self.params['background'], 'painter': painter, 'resolutionScale': resolutionScale}) painter.setRenderHint(QtGui.QPainter.Antialiasing, self.params['antialias']) self.getScene().render(painter, QtCore.QRectF(targetRect), QtCore.QRectF(sourceRect)) finally: self.setExportMode(False) painter.end() if copy: QtGui.QApplication.clipboard().setImage(self.png) elif toBytes: return self.png else: self.png.save(fileName) ImageExporter.register() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/exporters/Matplotlib.py000066400000000000000000000113251300727121400243560ustar00rootroot00000000000000from ..Qt import QtGui, QtCore from .Exporter import Exporter from .. import PlotItem from .. import functions as fn __all__ = ['MatplotlibExporter'] """ It is helpful when using the matplotlib Exporter if your .matplotlib/matplotlibrc file is configured appropriately. The following are suggested for getting usable PDF output that can be edited in Illustrator, etc. backend : Qt4Agg text.usetex : True # Assumes you have a findable LaTeX installation interactive : False font.family : sans-serif font.sans-serif : 'Arial' # (make first in list) mathtext.default : sf figure.facecolor : white # personal preference # next setting allows pdf font to be readable in Adobe Illustrator pdf.fonttype : 42 # set fonts to TrueType (otherwise it will be 3 # and the text will be vectorized. text.dvipnghack : True # primarily to clean up font appearance on Mac The advantage is that there is less to do to get an exported file cleaned and ready for publication. Fonts are not vectorized (outlined), and window colors are white. """ class MatplotlibExporter(Exporter): Name = "Matplotlib Window" windows = [] def __init__(self, item): Exporter.__init__(self, item) def parameters(self): return None def cleanAxes(self, axl): if type(axl) is not list: axl = [axl] for ax in axl: if ax is None: continue for loc, spine in ax.spines.iteritems(): if loc in ['left', 'bottom']: pass elif loc in ['right', 'top']: spine.set_color('none') # do not draw the spine else: raise ValueError('Unknown spine location: %s' % loc) # turn off ticks when there is no spine ax.xaxis.set_ticks_position('bottom') def export(self, fileName=None): if isinstance(self.item, PlotItem): mpw = MatplotlibWindow() MatplotlibExporter.windows.append(mpw) stdFont = 'Arial' fig = mpw.getFigure() # get labels from the graphic item xlabel = self.item.axes['bottom']['item'].label.toPlainText() ylabel = self.item.axes['left']['item'].label.toPlainText() title = self.item.titleLabel.text ax = fig.add_subplot(111, title=title) ax.clear() self.cleanAxes(ax) #ax.grid(True) for item in self.item.curves: x, y = item.getData() opts = item.opts pen = fn.mkPen(opts['pen']) if pen.style() == QtCore.Qt.NoPen: linestyle = '' else: linestyle = '-' color = tuple([c/255. for c in fn.colorTuple(pen.color())]) symbol = opts['symbol'] if symbol == 't': symbol = '^' symbolPen = fn.mkPen(opts['symbolPen']) symbolBrush = fn.mkBrush(opts['symbolBrush']) markeredgecolor = tuple([c/255. for c in fn.colorTuple(symbolPen.color())]) markerfacecolor = tuple([c/255. for c in fn.colorTuple(symbolBrush.color())]) markersize = opts['symbolSize'] if opts['fillLevel'] is not None and opts['fillBrush'] is not None: fillBrush = fn.mkBrush(opts['fillBrush']) fillcolor = tuple([c/255. for c in fn.colorTuple(fillBrush.color())]) ax.fill_between(x=x, y1=y, y2=opts['fillLevel'], facecolor=fillcolor) pl = ax.plot(x, y, marker=symbol, color=color, linewidth=pen.width(), linestyle=linestyle, markeredgecolor=markeredgecolor, markerfacecolor=markerfacecolor, markersize=markersize) xr, yr = self.item.viewRange() ax.set_xbound(*xr) ax.set_ybound(*yr) ax.set_xlabel(xlabel) # place the labels. ax.set_ylabel(ylabel) mpw.draw() else: raise Exception("Matplotlib export currently only works with plot items") MatplotlibExporter.register() class MatplotlibWindow(QtGui.QMainWindow): def __init__(self): from ..widgets import MatplotlibWidget QtGui.QMainWindow.__init__(self) self.mpl = MatplotlibWidget.MatplotlibWidget() self.setCentralWidget(self.mpl) self.show() def __getattr__(self, attr): return getattr(self.mpl, attr) def closeEvent(self, ev): MatplotlibExporter.windows.remove(self) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/exporters/PrintExporter.py000066400000000000000000000051571300727121400251020ustar00rootroot00000000000000from .Exporter import Exporter from ..parametertree import Parameter from ..Qt import QtGui, QtCore, QtSvg import re __all__ = ['PrintExporter'] #__all__ = [] ## Printer is disabled for now--does not work very well. class PrintExporter(Exporter): Name = "Printer" def __init__(self, item): Exporter.__init__(self, item) tr = self.getTargetRect() self.params = Parameter(name='params', type='group', children=[ {'name': 'width', 'type': 'float', 'value': 0.1, 'limits': (0, None), 'suffix': 'm', 'siPrefix': True}, {'name': 'height', 'type': 'float', 'value': (0.1 * tr.height()) / tr.width(), 'limits': (0, None), 'suffix': 'm', 'siPrefix': True}, ]) self.params.param('width').sigValueChanged.connect(self.widthChanged) self.params.param('height').sigValueChanged.connect(self.heightChanged) def widthChanged(self): sr = self.getSourceRect() ar = sr.height() / sr.width() self.params.param('height').setValue(self.params['width'] * ar, blockSignal=self.heightChanged) def heightChanged(self): sr = self.getSourceRect() ar = sr.width() / sr.height() self.params.param('width').setValue(self.params['height'] * ar, blockSignal=self.widthChanged) def parameters(self): return self.params def export(self, fileName=None): printer = QtGui.QPrinter(QtGui.QPrinter.HighResolution) dialog = QtGui.QPrintDialog(printer) dialog.setWindowTitle("Print Document") if dialog.exec_() != QtGui.QDialog.Accepted: return #dpi = QtGui.QDesktopWidget().physicalDpiX() #self.svg.setSize(QtCore.QSize(100,100)) #self.svg.setResolution(600) #res = printer.resolution() sr = self.getSourceRect() #res = sr.width() * .4 / (self.params['width'] * 100 / 2.54) res = QtGui.QDesktopWidget().physicalDpiX() printer.setResolution(res) rect = printer.pageRect() center = rect.center() h = self.params['height'] * res * 100. / 2.54 w = self.params['width'] * res * 100. / 2.54 x = center.x() - w/2. y = center.y() - h/2. targetRect = QtCore.QRect(x, y, w, h) sourceRect = self.getSourceRect() painter = QtGui.QPainter(printer) try: self.setExportMode(True, {'painter': painter}) self.getScene().render(painter, QtCore.QRectF(targetRect), QtCore.QRectF(sourceRect)) finally: self.setExportMode(False) painter.end() #PrintExporter.register() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/exporters/SVGExporter.py000066400000000000000000000415311300727121400244410ustar00rootroot00000000000000from .Exporter import Exporter from ..python2_3 import asUnicode from ..parametertree import Parameter from ..Qt import QtGui, QtCore, QtSvg, USE_PYSIDE from .. import debug from .. import functions as fn import re import xml.dom.minidom as xml import numpy as np __all__ = ['SVGExporter'] class SVGExporter(Exporter): Name = "Scalable Vector Graphics (SVG)" allowCopy=True def __init__(self, item): Exporter.__init__(self, item) #tr = self.getTargetRect() self.params = Parameter(name='params', type='group', children=[ #{'name': 'width', 'type': 'float', 'value': tr.width(), 'limits': (0, None)}, #{'name': 'height', 'type': 'float', 'value': tr.height(), 'limits': (0, None)}, #{'name': 'viewbox clipping', 'type': 'bool', 'value': True}, #{'name': 'normalize coordinates', 'type': 'bool', 'value': True}, #{'name': 'normalize line width', 'type': 'bool', 'value': True}, ]) #self.params.param('width').sigValueChanged.connect(self.widthChanged) #self.params.param('height').sigValueChanged.connect(self.heightChanged) def widthChanged(self): sr = self.getSourceRect() ar = sr.height() / sr.width() self.params.param('height').setValue(self.params['width'] * ar, blockSignal=self.heightChanged) def heightChanged(self): sr = self.getSourceRect() ar = sr.width() / sr.height() self.params.param('width').setValue(self.params['height'] * ar, blockSignal=self.widthChanged) def parameters(self): return self.params def export(self, fileName=None, toBytes=False, copy=False): if toBytes is False and copy is False and fileName is None: self.fileSaveDialog(filter="Scalable Vector Graphics (*.svg)") return ## Qt's SVG generator is not complete. (notably, it lacks clipping) ## Instead, we will use Qt to generate SVG for each item independently, ## then manually reconstruct the entire document. xml = generateSvg(self.item) if toBytes: return xml.encode('UTF-8') elif copy: md = QtCore.QMimeData() md.setData('image/svg+xml', QtCore.QByteArray(xml.encode('UTF-8'))) QtGui.QApplication.clipboard().setMimeData(md) else: with open(fileName, 'wb') as fh: fh.write(asUnicode(xml).encode('utf-8')) xmlHeader = """\ pyqtgraph SVG export Generated with Qt and pyqtgraph """ def generateSvg(item): global xmlHeader try: node, defs = _generateItemSvg(item) finally: ## reset export mode for all items in the tree if isinstance(item, QtGui.QGraphicsScene): items = item.items() else: items = [item] for i in items: items.extend(i.childItems()) for i in items: if hasattr(i, 'setExportMode'): i.setExportMode(False) cleanXml(node) defsXml = "\n" for d in defs: defsXml += d.toprettyxml(indent=' ') defsXml += "\n" return xmlHeader + defsXml + node.toprettyxml(indent=' ') + "\n\n" def _generateItemSvg(item, nodes=None, root=None): ## This function is intended to work around some issues with Qt's SVG generator ## and SVG in general. ## 1) Qt SVG does not implement clipping paths. This is absurd. ## The solution is to let Qt generate SVG for each item independently, ## then glue them together manually with clipping. ## ## The format Qt generates for all items looks like this: ## ## ## ## one or more of: or or ## ## ## one or more of: or or ## ## . . . ## ## ## 2) There seems to be wide disagreement over whether path strokes ## should be scaled anisotropically. ## see: http://web.mit.edu/jonas/www/anisotropy/ ## Given that both inkscape and illustrator seem to prefer isotropic ## scaling, we will optimize for those cases. ## ## 3) Qt generates paths using non-scaling-stroke from SVG 1.2, but ## inkscape only supports 1.1. ## ## Both 2 and 3 can be addressed by drawing all items in world coordinates. profiler = debug.Profiler() if nodes is None: ## nodes maps all node IDs to their XML element. ## this allows us to ensure all elements receive unique names. nodes = {} if root is None: root = item ## Skip hidden items if hasattr(item, 'isVisible') and not item.isVisible(): return None ## If this item defines its own SVG generator, use that. if hasattr(item, 'generateSvg'): return item.generateSvg(nodes) ## Generate SVG text for just this item (exclude its children; we'll handle them later) tr = QtGui.QTransform() if isinstance(item, QtGui.QGraphicsScene): xmlStr = "\n\n" doc = xml.parseString(xmlStr) childs = [i for i in item.items() if i.parentItem() is None] elif item.__class__.paint == QtGui.QGraphicsItem.paint: xmlStr = "\n\n" doc = xml.parseString(xmlStr) childs = item.childItems() else: childs = item.childItems() tr = itemTransform(item, item.scene()) ## offset to corner of root item if isinstance(root, QtGui.QGraphicsScene): rootPos = QtCore.QPoint(0,0) else: rootPos = root.scenePos() tr2 = QtGui.QTransform() tr2.translate(-rootPos.x(), -rootPos.y()) tr = tr * tr2 arr = QtCore.QByteArray() buf = QtCore.QBuffer(arr) svg = QtSvg.QSvgGenerator() svg.setOutputDevice(buf) dpi = QtGui.QDesktopWidget().physicalDpiX() svg.setResolution(dpi) p = QtGui.QPainter() p.begin(svg) if hasattr(item, 'setExportMode'): item.setExportMode(True, {'painter': p}) try: p.setTransform(tr) item.paint(p, QtGui.QStyleOptionGraphicsItem(), None) finally: p.end() ## Can't do this here--we need to wait until all children have painted as well. ## this is taken care of in generateSvg instead. #if hasattr(item, 'setExportMode'): #item.setExportMode(False) if USE_PYSIDE: xmlStr = str(arr) else: xmlStr = bytes(arr).decode('utf-8') doc = xml.parseString(xmlStr) try: ## Get top-level group for this item g1 = doc.getElementsByTagName('g')[0] ## get list of sub-groups g2 = [n for n in g1.childNodes if isinstance(n, xml.Element) and n.tagName == 'g'] defs = doc.getElementsByTagName('defs') if len(defs) > 0: defs = [n for n in defs[0].childNodes if isinstance(n, xml.Element)] except: print(doc.toxml()) raise profiler('render') ## Get rid of group transformation matrices by applying ## transformation to inner coordinates correctCoordinates(g1, defs, item) profiler('correct') ## make sure g1 has the transformation matrix #m = (tr.m11(), tr.m12(), tr.m21(), tr.m22(), tr.m31(), tr.m32()) #g1.setAttribute('transform', "matrix(%f,%f,%f,%f,%f,%f)" % m) #print "=================",item,"=====================" #print g1.toprettyxml(indent=" ", newl='') ## Inkscape does not support non-scaling-stroke (this is SVG 1.2, inkscape supports 1.1) ## So we need to correct anything attempting to use this. #correctStroke(g1, item, root) ## decide on a name for this item baseName = item.__class__.__name__ i = 1 while True: name = baseName + "_%d" % i if name not in nodes: break i += 1 nodes[name] = g1 g1.setAttribute('id', name) ## If this item clips its children, we need to take care of that. childGroup = g1 ## add children directly to this node unless we are clipping if not isinstance(item, QtGui.QGraphicsScene): ## See if this item clips its children if int(item.flags() & item.ItemClipsChildrenToShape) > 0: ## Generate svg for just the path #if isinstance(root, QtGui.QGraphicsScene): #path = QtGui.QGraphicsPathItem(item.mapToScene(item.shape())) #else: #path = QtGui.QGraphicsPathItem(root.mapToParent(item.mapToItem(root, item.shape()))) path = QtGui.QGraphicsPathItem(item.mapToScene(item.shape())) item.scene().addItem(path) try: #pathNode = _generateItemSvg(path, root=root).getElementsByTagName('path')[0] pathNode = _generateItemSvg(path, root=root)[0].getElementsByTagName('path')[0] # assume for this path is empty.. possibly problematic. finally: item.scene().removeItem(path) ## and for the clipPath element clip = name + '_clip' clipNode = g1.ownerDocument.createElement('clipPath') clipNode.setAttribute('id', clip) clipNode.appendChild(pathNode) g1.appendChild(clipNode) childGroup = g1.ownerDocument.createElement('g') childGroup.setAttribute('clip-path', 'url(#%s)' % clip) g1.appendChild(childGroup) profiler('clipping') ## Add all child items as sub-elements. childs.sort(key=lambda c: c.zValue()) for ch in childs: csvg = _generateItemSvg(ch, nodes, root) if csvg is None: continue cg, cdefs = csvg childGroup.appendChild(cg) ### this isn't quite right--some items draw below their parent (good enough for now) defs.extend(cdefs) profiler('children') return g1, defs def correctCoordinates(node, defs, item): # TODO: correct gradient coordinates inside defs ## Remove transformation matrices from tags by applying matrix to coordinates inside. ## Each item is represented by a single top-level group with one or more groups inside. ## Each inner group contains one or more drawing primitives, possibly of different types. groups = node.getElementsByTagName('g') ## Since we leave text unchanged, groups which combine text and non-text primitives must be split apart. ## (if at some point we start correcting text transforms as well, then it should be safe to remove this) groups2 = [] for grp in groups: subGroups = [grp.cloneNode(deep=False)] textGroup = None for ch in grp.childNodes[:]: if isinstance(ch, xml.Element): if textGroup is None: textGroup = ch.tagName == 'text' if ch.tagName == 'text': if textGroup is False: subGroups.append(grp.cloneNode(deep=False)) textGroup = True else: if textGroup is True: subGroups.append(grp.cloneNode(deep=False)) textGroup = False subGroups[-1].appendChild(ch) groups2.extend(subGroups) for sg in subGroups: node.insertBefore(sg, grp) node.removeChild(grp) groups = groups2 for grp in groups: matrix = grp.getAttribute('transform') match = re.match(r'matrix\((.*)\)', matrix) if match is None: vals = [1,0,0,1,0,0] else: vals = [float(a) for a in match.groups()[0].split(',')] tr = np.array([[vals[0], vals[2], vals[4]], [vals[1], vals[3], vals[5]]]) removeTransform = False for ch in grp.childNodes: if not isinstance(ch, xml.Element): continue if ch.tagName == 'polyline': removeTransform = True coords = np.array([[float(a) for a in c.split(',')] for c in ch.getAttribute('points').strip().split(' ')]) coords = fn.transformCoordinates(tr, coords, transpose=True) ch.setAttribute('points', ' '.join([','.join([str(a) for a in c]) for c in coords])) elif ch.tagName == 'path': removeTransform = True newCoords = '' oldCoords = ch.getAttribute('d').strip() if oldCoords == '': continue for c in oldCoords.split(' '): x,y = c.split(',') if x[0].isalpha(): t = x[0] x = x[1:] else: t = '' nc = fn.transformCoordinates(tr, np.array([[float(x),float(y)]]), transpose=True) newCoords += t+str(nc[0,0])+','+str(nc[0,1])+' ' ch.setAttribute('d', newCoords) elif ch.tagName == 'text': removeTransform = False ## leave text alone for now. Might need this later to correctly render text with outline. #c = np.array([ #[float(ch.getAttribute('x')), float(ch.getAttribute('y'))], #[float(ch.getAttribute('font-size')), 0], #[0,0]]) #c = fn.transformCoordinates(tr, c, transpose=True) #ch.setAttribute('x', str(c[0,0])) #ch.setAttribute('y', str(c[0,1])) #fs = c[1]-c[2] #fs = (fs**2).sum()**0.5 #ch.setAttribute('font-size', str(fs)) ## Correct some font information families = ch.getAttribute('font-family').split(',') if len(families) == 1: font = QtGui.QFont(families[0].strip('" ')) if font.style() == font.SansSerif: families.append('sans-serif') elif font.style() == font.Serif: families.append('serif') elif font.style() == font.Courier: families.append('monospace') ch.setAttribute('font-family', ', '.join([f if ' ' not in f else '"%s"'%f for f in families])) ## correct line widths if needed if removeTransform and ch.getAttribute('vector-effect') != 'non-scaling-stroke': w = float(grp.getAttribute('stroke-width')) s = fn.transformCoordinates(tr, np.array([[w,0], [0,0]]), transpose=True) w = ((s[0]-s[1])**2).sum()**0.5 ch.setAttribute('stroke-width', str(w)) if removeTransform: grp.removeAttribute('transform') SVGExporter.register() def itemTransform(item, root): ## Return the transformation mapping item to root ## (actually to parent coordinate system of root) if item is root: tr = QtGui.QTransform() tr.translate(*item.pos()) tr = tr * item.transform() return tr if int(item.flags() & item.ItemIgnoresTransformations) > 0: pos = item.pos() parent = item.parentItem() if parent is not None: pos = itemTransform(parent, root).map(pos) tr = QtGui.QTransform() tr.translate(pos.x(), pos.y()) tr = item.transform() * tr else: ## find next parent that is either the root item or ## an item that ignores its transformation nextRoot = item while True: nextRoot = nextRoot.parentItem() if nextRoot is None: nextRoot = root break if nextRoot is root or int(nextRoot.flags() & nextRoot.ItemIgnoresTransformations) > 0: break if isinstance(nextRoot, QtGui.QGraphicsScene): tr = item.sceneTransform() else: tr = itemTransform(nextRoot, root) * item.itemTransform(nextRoot)[0] return tr def cleanXml(node): ## remove extraneous text; let the xml library do the formatting. hasElement = False nonElement = [] for ch in node.childNodes: if isinstance(ch, xml.Element): hasElement = True cleanXml(ch) else: nonElement.append(ch) if hasElement: for ch in nonElement: node.removeChild(ch) elif node.tagName == 'g': ## remove childless groups node.parentNode.removeChild(node) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/exporters/__init__.py000066400000000000000000000003751300727121400240110ustar00rootroot00000000000000from .Exporter import Exporter from .ImageExporter import * from .SVGExporter import * from .Matplotlib import * from .CSVExporter import * from .PrintExporter import * from .HDF5Exporter import * def listExporters(): return Exporter.Exporters[:] pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/exporters/tests/000077500000000000000000000000001300727121400230355ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/exporters/tests/__init__.py000066400000000000000000000000001300727121400251340ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/exporters/tests/test_csv.py000066400000000000000000000032011300727121400252350ustar00rootroot00000000000000""" SVG export test """ from __future__ import division, print_function, absolute_import import pyqtgraph as pg import csv import os import tempfile app = pg.mkQApp() def approxeq(a, b): return (a-b) <= ((a + b) * 1e-6) def test_CSVExporter(): tempfilename = tempfile.NamedTemporaryFile(suffix='.csv').name print("using %s as a temporary file" % tempfilename) plt = pg.plot() y1 = [1,3,2,3,1,6,9,8,4,2] plt.plot(y=y1, name='myPlot') y2 = [3,4,6,1,2,4,2,3,5,3,5,1,3] x2 = pg.np.linspace(0, 1.0, len(y2)) plt.plot(x=x2, y=y2) y3 = [1,5,2,3,4,6,1,2,4,2,3,5,3] x3 = pg.np.linspace(0, 1.0, len(y3)+1) plt.plot(x=x3, y=y3, stepMode=True) ex = pg.exporters.CSVExporter(plt.plotItem) ex.export(fileName=tempfilename) r = csv.reader(open(tempfilename, 'r')) lines = [line for line in r] header = lines.pop(0) assert header == ['myPlot_x', 'myPlot_y', 'x0001', 'y0001', 'x0002', 'y0002'] i = 0 for vals in lines: vals = list(map(str.strip, vals)) assert (i >= len(y1) and vals[0] == '') or approxeq(float(vals[0]), i) assert (i >= len(y1) and vals[1] == '') or approxeq(float(vals[1]), y1[i]) assert (i >= len(x2) and vals[2] == '') or approxeq(float(vals[2]), x2[i]) assert (i >= len(y2) and vals[3] == '') or approxeq(float(vals[3]), y2[i]) assert (i >= len(x3) and vals[4] == '') or approxeq(float(vals[4]), x3[i]) assert (i >= len(y3) and vals[5] == '') or approxeq(float(vals[5]), y3[i]) i += 1 os.unlink(tempfilename) if __name__ == '__main__': test_CSVExporter() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/exporters/tests/test_svg.py000066400000000000000000000042201300727121400252430ustar00rootroot00000000000000""" SVG export test """ from __future__ import division, print_function, absolute_import import pyqtgraph as pg import tempfile import os app = pg.mkQApp() def test_plotscene(): tempfilename = tempfile.NamedTemporaryFile(suffix='.svg').name print("using %s as a temporary file" % tempfilename) pg.setConfigOption('foreground', (0,0,0)) w = pg.GraphicsWindow() w.show() p1 = w.addPlot() p2 = w.addPlot() p1.plot([1,3,2,3,1,6,9,8,4,2,3,5,3], pen={'color':'k'}) p1.setXRange(0,5) p2.plot([1,5,2,3,4,6,1,2,4,2,3,5,3], pen={'color':'k', 'cosmetic':False, 'width': 0.3}) app.processEvents() app.processEvents() ex = pg.exporters.SVGExporter(w.scene()) ex.export(fileName=tempfilename) # clean up after the test is done os.unlink(tempfilename) def test_simple(): tempfilename = tempfile.NamedTemporaryFile(suffix='.svg').name print("using %s as a temporary file" % tempfilename) scene = pg.QtGui.QGraphicsScene() #rect = pg.QtGui.QGraphicsRectItem(0, 0, 100, 100) #scene.addItem(rect) #rect.setPos(20,20) #rect.translate(50, 50) #rect.rotate(30) #rect.scale(0.5, 0.5) #rect1 = pg.QtGui.QGraphicsRectItem(0, 0, 100, 100) #rect1.setParentItem(rect) #rect1.setFlag(rect1.ItemIgnoresTransformations) #rect1.setPos(20, 20) #rect1.scale(2,2) #el1 = pg.QtGui.QGraphicsEllipseItem(0, 0, 100, 100) #el1.setParentItem(rect1) ##grp = pg.ItemGroup() #grp.setParentItem(rect) #grp.translate(200,0) ##grp.rotate(30) #rect2 = pg.QtGui.QGraphicsRectItem(0, 0, 100, 25) #rect2.setFlag(rect2.ItemClipsChildrenToShape) #rect2.setParentItem(grp) #rect2.setPos(0,25) #rect2.rotate(30) #el = pg.QtGui.QGraphicsEllipseItem(0, 0, 100, 50) #el.translate(10,-5) #el.scale(0.5,2) #el.setParentItem(rect2) grp2 = pg.ItemGroup() scene.addItem(grp2) grp2.scale(100,100) rect3 = pg.QtGui.QGraphicsRectItem(0,0,2,2) rect3.setPen(pg.mkPen(width=1, cosmetic=False)) grp2.addItem(rect3) ex = pg.exporters.SVGExporter(scene) ex.export(fileName=tempfilename) os.unlink(tempfilename) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/flowchart/000077500000000000000000000000001300727121400216315ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/flowchart/Flowchart.py000066400000000000000000001056611300727121400241450ustar00rootroot00000000000000# -*- coding: utf-8 -*- from ..Qt import QtCore, QtGui, USE_PYSIDE, USE_PYQT5 from .Node import * from ..pgcollections import OrderedDict from ..widgets.TreeWidget import * from .. import FileDialog, DataTreeWidget ## pyside and pyqt use incompatible ui files. if USE_PYSIDE: from . import FlowchartTemplate_pyside as FlowchartTemplate from . import FlowchartCtrlTemplate_pyside as FlowchartCtrlTemplate elif USE_PYQT5: from . import FlowchartTemplate_pyqt5 as FlowchartTemplate from . import FlowchartCtrlTemplate_pyqt5 as FlowchartCtrlTemplate else: from . import FlowchartTemplate_pyqt as FlowchartTemplate from . import FlowchartCtrlTemplate_pyqt as FlowchartCtrlTemplate from .Terminal import Terminal from numpy import ndarray from .library import LIBRARY from ..debug import printExc from .. import configfile as configfile from .. import dockarea as dockarea from . import FlowchartGraphicsView from .. import functions as fn def strDict(d): return dict([(str(k), v) for k, v in d.items()]) class Flowchart(Node): sigFileLoaded = QtCore.Signal(object) sigFileSaved = QtCore.Signal(object) #sigOutputChanged = QtCore.Signal() ## inherited from Node sigChartLoaded = QtCore.Signal() sigStateChanged = QtCore.Signal() # called when output is expected to have changed sigChartChanged = QtCore.Signal(object, object, object) # called when nodes are added, removed, or renamed. # (self, action, node) def __init__(self, terminals=None, name=None, filePath=None, library=None): self.library = library or LIBRARY if name is None: name = "Flowchart" if terminals is None: terminals = {} self.filePath = filePath Node.__init__(self, name, allowAddInput=True, allowAddOutput=True) ## create node without terminals; we'll add these later self.inputWasSet = False ## flag allows detection of changes in the absence of input change. self._nodes = {} self.nextZVal = 10 #self.connects = [] #self._chartGraphicsItem = FlowchartGraphicsItem(self) self._widget = None self._scene = None self.processing = False ## flag that prevents recursive node updates self.widget() self.inputNode = Node('Input', allowRemove=False, allowAddOutput=True) self.outputNode = Node('Output', allowRemove=False, allowAddInput=True) self.addNode(self.inputNode, 'Input', [-150, 0]) self.addNode(self.outputNode, 'Output', [300, 0]) self.outputNode.sigOutputChanged.connect(self.outputChanged) self.outputNode.sigTerminalRenamed.connect(self.internalTerminalRenamed) self.inputNode.sigTerminalRenamed.connect(self.internalTerminalRenamed) self.outputNode.sigTerminalRemoved.connect(self.internalTerminalRemoved) self.inputNode.sigTerminalRemoved.connect(self.internalTerminalRemoved) self.outputNode.sigTerminalAdded.connect(self.internalTerminalAdded) self.inputNode.sigTerminalAdded.connect(self.internalTerminalAdded) self.viewBox.autoRange(padding = 0.04) for name, opts in terminals.items(): self.addTerminal(name, **opts) def setLibrary(self, lib): self.library = lib self.widget().chartWidget.buildMenu() def setInput(self, **args): """Set the input values of the flowchart. This will automatically propagate the new values throughout the flowchart, (possibly) causing the output to change. """ #print "setInput", args #Node.setInput(self, **args) #print " ....." self.inputWasSet = True self.inputNode.setOutput(**args) def outputChanged(self): ## called when output of internal node has changed vals = self.outputNode.inputValues() self.widget().outputChanged(vals) self.setOutput(**vals) #self.sigOutputChanged.emit(self) def output(self): """Return a dict of the values on the Flowchart's output terminals. """ return self.outputNode.inputValues() def nodes(self): return self._nodes def addTerminal(self, name, **opts): term = Node.addTerminal(self, name, **opts) name = term.name() if opts['io'] == 'in': ## inputs to the flowchart become outputs on the input node opts['io'] = 'out' opts['multi'] = False self.inputNode.sigTerminalAdded.disconnect(self.internalTerminalAdded) try: term2 = self.inputNode.addTerminal(name, **opts) finally: self.inputNode.sigTerminalAdded.connect(self.internalTerminalAdded) else: opts['io'] = 'in' #opts['multi'] = False self.outputNode.sigTerminalAdded.disconnect(self.internalTerminalAdded) try: term2 = self.outputNode.addTerminal(name, **opts) finally: self.outputNode.sigTerminalAdded.connect(self.internalTerminalAdded) return term def removeTerminal(self, name): #print "remove:", name term = self[name] inTerm = self.internalTerminal(term) Node.removeTerminal(self, name) inTerm.node().removeTerminal(inTerm.name()) def internalTerminalRenamed(self, term, oldName): self[oldName].rename(term.name()) def internalTerminalAdded(self, node, term): if term._io == 'in': io = 'out' else: io = 'in' Node.addTerminal(self, term.name(), io=io, renamable=term.isRenamable(), removable=term.isRemovable(), multiable=term.isMultiable()) def internalTerminalRemoved(self, node, term): try: Node.removeTerminal(self, term.name()) except KeyError: pass def terminalRenamed(self, term, oldName): newName = term.name() #print "flowchart rename", newName, oldName #print self.terminals Node.terminalRenamed(self, self[oldName], oldName) #print self.terminals for n in [self.inputNode, self.outputNode]: if oldName in n.terminals: n[oldName].rename(newName) def createNode(self, nodeType, name=None, pos=None): if name is None: n = 0 while True: name = "%s.%d" % (nodeType, n) if name not in self._nodes: break n += 1 node = self.library.getNodeType(nodeType)(name) self.addNode(node, name, pos) return node def addNode(self, node, name, pos=None): if pos is None: pos = [0, 0] if type(pos) in [QtCore.QPoint, QtCore.QPointF]: pos = [pos.x(), pos.y()] item = node.graphicsItem() item.setZValue(self.nextZVal*2) self.nextZVal += 1 self.viewBox.addItem(item) item.moveBy(*pos) self._nodes[name] = node self.widget().addNode(node) node.sigClosed.connect(self.nodeClosed) node.sigRenamed.connect(self.nodeRenamed) node.sigOutputChanged.connect(self.nodeOutputChanged) self.sigChartChanged.emit(self, 'add', node) def removeNode(self, node): node.close() def nodeClosed(self, node): del self._nodes[node.name()] self.widget().removeNode(node) for signal in ['sigClosed', 'sigRenamed', 'sigOutputChanged']: try: getattr(node, signal).disconnect(self.nodeClosed) except (TypeError, RuntimeError): pass self.sigChartChanged.emit(self, 'remove', node) def nodeRenamed(self, node, oldName): del self._nodes[oldName] self._nodes[node.name()] = node self.widget().nodeRenamed(node, oldName) self.sigChartChanged.emit(self, 'rename', node) def arrangeNodes(self): pass def internalTerminal(self, term): """If the terminal belongs to the external Node, return the corresponding internal terminal""" if term.node() is self: if term.isInput(): return self.inputNode[term.name()] else: return self.outputNode[term.name()] else: return term def connectTerminals(self, term1, term2): """Connect two terminals together within this flowchart.""" term1 = self.internalTerminal(term1) term2 = self.internalTerminal(term2) term1.connectTo(term2) def process(self, **args): """ Process data through the flowchart, returning the output. Keyword arguments must be the names of input terminals. The return value is a dict with one key per output terminal. """ data = {} ## Stores terminal:value pairs ## determine order of operations ## order should look like [('p', node1), ('p', node2), ('d', terminal1), ...] ## Each tuple specifies either (p)rocess this node or (d)elete the result from this terminal order = self.processOrder() #print "ORDER:", order ## Record inputs given to process() for n, t in self.inputNode.outputs().items(): # if n not in args: # raise Exception("Parameter %s required to process this chart." % n) if n in args: data[t] = args[n] ret = {} ## process all in order for c, arg in order: if c == 'p': ## Process a single node #print "===> process:", arg node = arg if node is self.inputNode: continue ## input node has already been processed. ## get input and output terminals for this node outs = list(node.outputs().values()) ins = list(node.inputs().values()) ## construct input value dictionary args = {} for inp in ins: inputs = inp.inputTerminals() if len(inputs) == 0: continue if inp.isMultiValue(): ## multi-input terminals require a dict of all inputs args[inp.name()] = dict([(i, data[i]) for i in inputs if i in data]) else: ## single-inputs terminals only need the single input value available args[inp.name()] = data[inputs[0]] if node is self.outputNode: ret = args ## we now have the return value, but must keep processing in case there are other endpoint nodes in the chart else: try: if node.isBypassed(): result = node.processBypassed(args) else: result = node.process(display=False, **args) except: print("Error processing node %s. Args are: %s" % (str(node), str(args))) raise for out in outs: #print " Output:", out, out.name() #print out.name() try: data[out] = result[out.name()] except KeyError: pass elif c == 'd': ## delete a terminal result (no longer needed; may be holding a lot of memory) #print "===> delete", arg if arg in data: del data[arg] return ret def processOrder(self): """Return the order of operations required to process this chart. The order returned should look like [('p', node1), ('p', node2), ('d', terminal1), ...] where each tuple specifies either (p)rocess this node or (d)elete the result from this terminal """ ## first collect list of nodes/terminals and their dependencies deps = {} tdeps = {} ## {terminal: [nodes that depend on terminal]} for name, node in self._nodes.items(): deps[node] = node.dependentNodes() for t in node.outputs().values(): tdeps[t] = t.dependentNodes() #print "DEPS:", deps ## determine correct node-processing order #deps[self] = [] order = fn.toposort(deps) #print "ORDER1:", order ## construct list of operations ops = [('p', n) for n in order] ## determine when it is safe to delete terminal values dels = [] for t, nodes in tdeps.items(): lastInd = 0 lastNode = None for n in nodes: ## determine which node is the last to be processed according to order if n is self: lastInd = None break else: try: ind = order.index(n) except ValueError: continue if lastNode is None or ind > lastInd: lastNode = n lastInd = ind #tdeps[t] = lastNode if lastInd is not None: dels.append((lastInd+1, t)) dels.sort(key=lambda a: a[0], reverse=True) for i, t in dels: ops.insert(i, ('d', t)) return ops def nodeOutputChanged(self, startNode): """Triggered when a node's output values have changed. (NOT called during process()) Propagates new data forward through network.""" ## first collect list of nodes/terminals and their dependencies if self.processing: return self.processing = True try: deps = {} for name, node in self._nodes.items(): deps[node] = [] for t in node.outputs().values(): deps[node].extend(t.dependentNodes()) ## determine order of updates order = fn.toposort(deps, nodes=[startNode]) order.reverse() ## keep track of terminals that have been updated terms = set(startNode.outputs().values()) #print "======= Updating", startNode # print("Order:", order) for node in order[1:]: # print("Processing node", node) update = False for term in list(node.inputs().values()): # print(" checking terminal", term) deps = list(term.connections().keys()) for d in deps: if d in terms: # print(" ..input", d, "changed") update |= True term.inputChanged(d, process=False) if update: # print(" processing..") node.update() terms |= set(node.outputs().values()) finally: self.processing = False if self.inputWasSet: self.inputWasSet = False else: self.sigStateChanged.emit() def chartGraphicsItem(self): """Return the graphicsItem which displays the internals of this flowchart. (graphicsItem() still returns the external-view item)""" #return self._chartGraphicsItem return self.viewBox def widget(self): if self._widget is None: self._widget = FlowchartCtrlWidget(self) self.scene = self._widget.scene() self.viewBox = self._widget.viewBox() #self._scene = QtGui.QGraphicsScene() #self._widget.setScene(self._scene) #self.scene.addItem(self.chartGraphicsItem()) #ci = self.chartGraphicsItem() #self.viewBox.addItem(ci) #self.viewBox.autoRange() return self._widget def listConnections(self): conn = set() for n in self._nodes.values(): terms = n.outputs() for n, t in terms.items(): for c in t.connections(): conn.add((t, c)) return conn def saveState(self): state = Node.saveState(self) state['nodes'] = [] state['connects'] = [] #state['terminals'] = self.saveTerminals() for name, node in self._nodes.items(): cls = type(node) if hasattr(cls, 'nodeName'): clsName = cls.nodeName pos = node.graphicsItem().pos() ns = {'class': clsName, 'name': name, 'pos': (pos.x(), pos.y()), 'state': node.saveState()} state['nodes'].append(ns) conn = self.listConnections() for a, b in conn: state['connects'].append((a.node().name(), a.name(), b.node().name(), b.name())) state['inputNode'] = self.inputNode.saveState() state['outputNode'] = self.outputNode.saveState() return state def restoreState(self, state, clear=False): self.blockSignals(True) try: if clear: self.clear() Node.restoreState(self, state) nodes = state['nodes'] nodes.sort(key=lambda a: a['pos'][0]) for n in nodes: if n['name'] in self._nodes: #self._nodes[n['name']].graphicsItem().moveBy(*n['pos']) self._nodes[n['name']].restoreState(n['state']) continue try: node = self.createNode(n['class'], name=n['name']) node.restoreState(n['state']) except: printExc("Error creating node %s: (continuing anyway)" % n['name']) #node.graphicsItem().moveBy(*n['pos']) self.inputNode.restoreState(state.get('inputNode', {})) self.outputNode.restoreState(state.get('outputNode', {})) #self.restoreTerminals(state['terminals']) for n1, t1, n2, t2 in state['connects']: try: self.connectTerminals(self._nodes[n1][t1], self._nodes[n2][t2]) except: print(self._nodes[n1].terminals) print(self._nodes[n2].terminals) printExc("Error connecting terminals %s.%s - %s.%s:" % (n1, t1, n2, t2)) finally: self.blockSignals(False) self.sigChartLoaded.emit() self.outputChanged() self.sigStateChanged.emit() #self.sigOutputChanged.emit() def loadFile(self, fileName=None, startDir=None): if fileName is None: if startDir is None: startDir = self.filePath if startDir is None: startDir = '.' self.fileDialog = FileDialog(None, "Load Flowchart..", startDir, "Flowchart (*.fc)") #self.fileDialog.setFileMode(QtGui.QFileDialog.AnyFile) #self.fileDialog.setAcceptMode(QtGui.QFileDialog.AcceptSave) self.fileDialog.show() self.fileDialog.fileSelected.connect(self.loadFile) return ## NOTE: was previously using a real widget for the file dialog's parent, but this caused weird mouse event bugs.. #fileName = QtGui.QFileDialog.getOpenFileName(None, "Load Flowchart..", startDir, "Flowchart (*.fc)") fileName = unicode(fileName) state = configfile.readConfigFile(fileName) self.restoreState(state, clear=True) self.viewBox.autoRange() #self.emit(QtCore.SIGNAL('fileLoaded'), fileName) self.sigFileLoaded.emit(fileName) def saveFile(self, fileName=None, startDir=None, suggestedFileName='flowchart.fc'): if fileName is None: if startDir is None: startDir = self.filePath if startDir is None: startDir = '.' self.fileDialog = FileDialog(None, "Save Flowchart..", startDir, "Flowchart (*.fc)") #self.fileDialog.setFileMode(QtGui.QFileDialog.AnyFile) self.fileDialog.setAcceptMode(QtGui.QFileDialog.AcceptSave) #self.fileDialog.setDirectory(startDir) self.fileDialog.show() self.fileDialog.fileSelected.connect(self.saveFile) return #fileName = QtGui.QFileDialog.getSaveFileName(None, "Save Flowchart..", startDir, "Flowchart (*.fc)") fileName = unicode(fileName) configfile.writeConfigFile(self.saveState(), fileName) self.sigFileSaved.emit(fileName) def clear(self): for n in list(self._nodes.values()): if n is self.inputNode or n is self.outputNode: continue n.close() ## calls self.nodeClosed(n) by signal #self.clearTerminals() self.widget().clear() def clearTerminals(self): Node.clearTerminals(self) self.inputNode.clearTerminals() self.outputNode.clearTerminals() #class FlowchartGraphicsItem(QtGui.QGraphicsItem): class FlowchartGraphicsItem(GraphicsObject): def __init__(self, chart): #print "FlowchartGraphicsItem.__init__" #QtGui.QGraphicsItem.__init__(self) GraphicsObject.__init__(self) self.chart = chart ## chart is an instance of Flowchart() self.updateTerminals() def updateTerminals(self): #print "FlowchartGraphicsItem.updateTerminals" self.terminals = {} bounds = self.boundingRect() inp = self.chart.inputs() dy = bounds.height() / (len(inp)+1) y = dy for n, t in inp.items(): item = t.graphicsItem() self.terminals[n] = item item.setParentItem(self) item.setAnchor(bounds.width(), y) y += dy out = self.chart.outputs() dy = bounds.height() / (len(out)+1) y = dy for n, t in out.items(): item = t.graphicsItem() self.terminals[n] = item item.setParentItem(self) item.setAnchor(0, y) y += dy def boundingRect(self): #print "FlowchartGraphicsItem.boundingRect" return QtCore.QRectF() def paint(self, p, *args): #print "FlowchartGraphicsItem.paint" pass #p.drawRect(self.boundingRect()) class FlowchartCtrlWidget(QtGui.QWidget): """The widget that contains the list of all the nodes in a flowchart and their controls, as well as buttons for loading/saving flowcharts.""" def __init__(self, chart): self.items = {} #self.loadDir = loadDir ## where to look initially for chart files self.currentFileName = None QtGui.QWidget.__init__(self) self.chart = chart self.ui = FlowchartCtrlTemplate.Ui_Form() self.ui.setupUi(self) self.ui.ctrlList.setColumnCount(2) #self.ui.ctrlList.setColumnWidth(0, 200) self.ui.ctrlList.setColumnWidth(1, 20) self.ui.ctrlList.setVerticalScrollMode(self.ui.ctrlList.ScrollPerPixel) self.ui.ctrlList.setHorizontalScrollBarPolicy(QtCore.Qt.ScrollBarAlwaysOff) self.chartWidget = FlowchartWidget(chart, self) #self.chartWidget.viewBox().autoRange() self.cwWin = QtGui.QMainWindow() self.cwWin.setWindowTitle('Flowchart') self.cwWin.setCentralWidget(self.chartWidget) self.cwWin.resize(1000,800) h = self.ui.ctrlList.header() if not USE_PYQT5: h.setResizeMode(0, h.Stretch) else: h.setSectionResizeMode(0, h.Stretch) self.ui.ctrlList.itemChanged.connect(self.itemChanged) self.ui.loadBtn.clicked.connect(self.loadClicked) self.ui.saveBtn.clicked.connect(self.saveClicked) self.ui.saveAsBtn.clicked.connect(self.saveAsClicked) self.ui.showChartBtn.toggled.connect(self.chartToggled) self.chart.sigFileLoaded.connect(self.setCurrentFile) self.ui.reloadBtn.clicked.connect(self.reloadClicked) self.chart.sigFileSaved.connect(self.fileSaved) #def resizeEvent(self, ev): #QtGui.QWidget.resizeEvent(self, ev) #self.ui.ctrlList.setColumnWidth(0, self.ui.ctrlList.viewport().width()-20) def chartToggled(self, b): if b: self.cwWin.show() else: self.cwWin.hide() def reloadClicked(self): try: self.chartWidget.reloadLibrary() self.ui.reloadBtn.success("Reloaded.") except: self.ui.reloadBtn.success("Error.") raise def loadClicked(self): newFile = self.chart.loadFile() #self.setCurrentFile(newFile) def fileSaved(self, fileName): self.setCurrentFile(unicode(fileName)) self.ui.saveBtn.success("Saved.") def saveClicked(self): if self.currentFileName is None: self.saveAsClicked() else: try: self.chart.saveFile(self.currentFileName) #self.ui.saveBtn.success("Saved.") except: self.ui.saveBtn.failure("Error") raise def saveAsClicked(self): try: if self.currentFileName is None: newFile = self.chart.saveFile() else: newFile = self.chart.saveFile(suggestedFileName=self.currentFileName) #self.ui.saveAsBtn.success("Saved.") #print "Back to saveAsClicked." except: self.ui.saveBtn.failure("Error") raise #self.setCurrentFile(newFile) def setCurrentFile(self, fileName): self.currentFileName = unicode(fileName) if fileName is None: self.ui.fileNameLabel.setText("[ new ]") else: self.ui.fileNameLabel.setText("%s" % os.path.split(self.currentFileName)[1]) self.resizeEvent(None) def itemChanged(self, *args): pass def scene(self): return self.chartWidget.scene() ## returns the GraphicsScene object def viewBox(self): return self.chartWidget.viewBox() def nodeRenamed(self, node, oldName): self.items[node].setText(0, node.name()) def addNode(self, node): ctrl = node.ctrlWidget() #if ctrl is None: #return item = QtGui.QTreeWidgetItem([node.name(), '', '']) self.ui.ctrlList.addTopLevelItem(item) byp = QtGui.QPushButton('X') byp.setCheckable(True) byp.setFixedWidth(20) item.bypassBtn = byp self.ui.ctrlList.setItemWidget(item, 1, byp) byp.node = node node.bypassButton = byp byp.setChecked(node.isBypassed()) byp.clicked.connect(self.bypassClicked) if ctrl is not None: item2 = QtGui.QTreeWidgetItem() item.addChild(item2) self.ui.ctrlList.setItemWidget(item2, 0, ctrl) self.items[node] = item def removeNode(self, node): if node in self.items: item = self.items[node] #self.disconnect(item.bypassBtn, QtCore.SIGNAL('clicked()'), self.bypassClicked) try: item.bypassBtn.clicked.disconnect(self.bypassClicked) except (TypeError, RuntimeError): pass self.ui.ctrlList.removeTopLevelItem(item) def bypassClicked(self): btn = QtCore.QObject.sender(self) btn.node.bypass(btn.isChecked()) def chartWidget(self): return self.chartWidget def outputChanged(self, data): pass #self.ui.outputTree.setData(data, hideRoot=True) def clear(self): self.chartWidget.clear() def select(self, node): item = self.items[node] self.ui.ctrlList.setCurrentItem(item) class FlowchartWidget(dockarea.DockArea): """Includes the actual graphical flowchart and debugging interface""" def __init__(self, chart, ctrl): #QtGui.QWidget.__init__(self) dockarea.DockArea.__init__(self) self.chart = chart self.ctrl = ctrl self.hoverItem = None #self.setMinimumWidth(250) #self.setSizePolicy(QtGui.QSizePolicy(QtGui.QSizePolicy.Preferred, QtGui.QSizePolicy.Expanding)) #self.ui = FlowchartTemplate.Ui_Form() #self.ui.setupUi(self) ## build user interface (it was easier to do it here than via developer) self.view = FlowchartGraphicsView.FlowchartGraphicsView(self) self.viewDock = dockarea.Dock('view', size=(1000,600)) self.viewDock.addWidget(self.view) self.viewDock.hideTitleBar() self.addDock(self.viewDock) self.hoverText = QtGui.QTextEdit() self.hoverText.setReadOnly(True) self.hoverDock = dockarea.Dock('Hover Info', size=(1000,20)) self.hoverDock.addWidget(self.hoverText) self.addDock(self.hoverDock, 'bottom') self.selInfo = QtGui.QWidget() self.selInfoLayout = QtGui.QGridLayout() self.selInfo.setLayout(self.selInfoLayout) self.selDescLabel = QtGui.QLabel() self.selNameLabel = QtGui.QLabel() self.selDescLabel.setWordWrap(True) self.selectedTree = DataTreeWidget() #self.selectedTree.setHorizontalScrollBarPolicy(QtCore.Qt.ScrollBarAsNeeded) #self.selInfoLayout.addWidget(self.selNameLabel) self.selInfoLayout.addWidget(self.selDescLabel) self.selInfoLayout.addWidget(self.selectedTree) self.selDock = dockarea.Dock('Selected Node', size=(1000,200)) self.selDock.addWidget(self.selInfo) self.addDock(self.selDock, 'bottom') self._scene = self.view.scene() self._viewBox = self.view.viewBox() #self._scene = QtGui.QGraphicsScene() #self._scene = FlowchartGraphicsView.FlowchartGraphicsScene() #self.view.setScene(self._scene) self.buildMenu() #self.ui.addNodeBtn.mouseReleaseEvent = self.addNodeBtnReleased self._scene.selectionChanged.connect(self.selectionChanged) self._scene.sigMouseHover.connect(self.hoverOver) #self.view.sigClicked.connect(self.showViewMenu) #self._scene.sigSceneContextMenu.connect(self.showViewMenu) #self._viewBox.sigActionPositionChanged.connect(self.menuPosChanged) def reloadLibrary(self): #QtCore.QObject.disconnect(self.nodeMenu, QtCore.SIGNAL('triggered(QAction*)'), self.nodeMenuTriggered) self.nodeMenu.triggered.disconnect(self.nodeMenuTriggered) self.nodeMenu = None self.subMenus = [] self.chart.library.reload() self.buildMenu() def buildMenu(self, pos=None): def buildSubMenu(node, rootMenu, subMenus, pos=None): for section, node in node.items(): menu = QtGui.QMenu(section) rootMenu.addMenu(menu) if isinstance(node, OrderedDict): buildSubMenu(node, menu, subMenus, pos=pos) subMenus.append(menu) else: act = rootMenu.addAction(section) act.nodeType = section act.pos = pos self.nodeMenu = QtGui.QMenu() self.subMenus = [] buildSubMenu(self.chart.library.getNodeTree(), self.nodeMenu, self.subMenus, pos=pos) self.nodeMenu.triggered.connect(self.nodeMenuTriggered) return self.nodeMenu def menuPosChanged(self, pos): self.menuPos = pos def showViewMenu(self, ev): #QtGui.QPushButton.mouseReleaseEvent(self.ui.addNodeBtn, ev) #if ev.button() == QtCore.Qt.RightButton: #self.menuPos = self.view.mapToScene(ev.pos()) #self.nodeMenu.popup(ev.globalPos()) #print "Flowchart.showViewMenu called" #self.menuPos = ev.scenePos() self.buildMenu(ev.scenePos()) self.nodeMenu.popup(ev.screenPos()) def scene(self): return self._scene ## the GraphicsScene item def viewBox(self): return self._viewBox ## the viewBox that items should be added to def nodeMenuTriggered(self, action): nodeType = action.nodeType if action.pos is not None: pos = action.pos else: pos = self.menuPos pos = self.viewBox().mapSceneToView(pos) self.chart.createNode(nodeType, pos=pos) def selectionChanged(self): #print "FlowchartWidget.selectionChanged called." items = self._scene.selectedItems() #print " scene.selectedItems: ", items if len(items) == 0: data = None else: item = items[0] if hasattr(item, 'node') and isinstance(item.node, Node): n = item.node self.ctrl.select(n) data = {'outputs': n.outputValues(), 'inputs': n.inputValues()} self.selNameLabel.setText(n.name()) if hasattr(n, 'nodeName'): self.selDescLabel.setText("%s: %s" % (n.nodeName, n.__class__.__doc__)) else: self.selDescLabel.setText("") if n.exception is not None: data['exception'] = n.exception else: data = None self.selectedTree.setData(data, hideRoot=True) def hoverOver(self, items): #print "FlowchartWidget.hoverOver called." term = None for item in items: if item is self.hoverItem: return self.hoverItem = item if hasattr(item, 'term') and isinstance(item.term, Terminal): term = item.term break if term is None: self.hoverText.setPlainText("") else: val = term.value() if isinstance(val, ndarray): val = "%s %s %s" % (type(val).__name__, str(val.shape), str(val.dtype)) else: val = str(val) if len(val) > 400: val = val[:400] + "..." self.hoverText.setPlainText("%s.%s = %s" % (term.node().name(), term.name(), val)) #self.hoverLabel.setCursorPosition(0) def clear(self): #self.outputTree.setData(None) self.selectedTree.setData(None) self.hoverText.setPlainText('') self.selNameLabel.setText('') self.selDescLabel.setText('') class FlowchartNode(Node): pass pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/flowchart/FlowchartCtrlTemplate.ui000066400000000000000000000056731300727121400264550ustar00rootroot00000000000000 Form 0 0 217 499 Form 0 0 Load.. Flowchart true false false false false 1 75 true Qt::AlignCenter TreeWidget QTreeWidget
..widgets.TreeWidget
 FeedbackButton QPushButton
..widgets.FeedbackButton
 pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/flowchart/FlowchartCtrlTemplate_pyqt.py000066400000000000000000000064731300727121400275440ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './pyqtgraph/flowchart/FlowchartCtrlTemplate.ui' # # Created: Mon Dec 23 10:10:50 2013 # by: PyQt4 UI code generator 4.10 # # WARNING! All changes made in this file will be lost! from PyQt4 import QtCore, QtGui try: _fromUtf8 = QtCore.QString.fromUtf8 except AttributeError: def _fromUtf8(s): return s try: _encoding = QtGui.QApplication.UnicodeUTF8 def _translate(context, text, disambig): return QtGui.QApplication.translate(context, text, disambig, _encoding) except AttributeError: def _translate(context, text, disambig): return QtGui.QApplication.translate(context, text, disambig) class Ui_Form(object): def setupUi(self, Form): Form.setObjectName(_fromUtf8("Form")) Form.resize(217, 499) self.gridLayout = QtGui.QGridLayout(Form) self.gridLayout.setMargin(0) self.gridLayout.setVerticalSpacing(0) self.gridLayout.setObjectName(_fromUtf8("gridLayout")) self.loadBtn = QtGui.QPushButton(Form) self.loadBtn.setObjectName(_fromUtf8("loadBtn")) self.gridLayout.addWidget(self.loadBtn, 1, 0, 1, 1) self.saveBtn = FeedbackButton(Form) self.saveBtn.setObjectName(_fromUtf8("saveBtn")) self.gridLayout.addWidget(self.saveBtn, 1, 1, 1, 2) self.saveAsBtn = FeedbackButton(Form) self.saveAsBtn.setObjectName(_fromUtf8("saveAsBtn")) self.gridLayout.addWidget(self.saveAsBtn, 1, 3, 1, 1) self.reloadBtn = FeedbackButton(Form) self.reloadBtn.setCheckable(False) self.reloadBtn.setFlat(False) self.reloadBtn.setObjectName(_fromUtf8("reloadBtn")) self.gridLayout.addWidget(self.reloadBtn, 4, 0, 1, 2) self.showChartBtn = QtGui.QPushButton(Form) self.showChartBtn.setCheckable(True) self.showChartBtn.setObjectName(_fromUtf8("showChartBtn")) self.gridLayout.addWidget(self.showChartBtn, 4, 2, 1, 2) self.ctrlList = TreeWidget(Form) self.ctrlList.setObjectName(_fromUtf8("ctrlList")) self.ctrlList.headerItem().setText(0, _fromUtf8("1")) self.ctrlList.header().setVisible(False) self.ctrlList.header().setStretchLastSection(False) self.gridLayout.addWidget(self.ctrlList, 3, 0, 1, 4) self.fileNameLabel = QtGui.QLabel(Form) font = QtGui.QFont() font.setBold(True) font.setWeight(75) self.fileNameLabel.setFont(font) self.fileNameLabel.setText(_fromUtf8("")) self.fileNameLabel.setAlignment(QtCore.Qt.AlignCenter) self.fileNameLabel.setObjectName(_fromUtf8("fileNameLabel")) self.gridLayout.addWidget(self.fileNameLabel, 0, 1, 1, 1) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): Form.setWindowTitle(_translate("Form", "Form", None)) self.loadBtn.setText(_translate("Form", "Load..", None)) self.saveBtn.setText(_translate("Form", "Save", None)) self.saveAsBtn.setText(_translate("Form", "As..", None)) self.reloadBtn.setText(_translate("Form", "Reload Libs", None)) self.showChartBtn.setText(_translate("Form", "Flowchart", None)) from ..widgets.TreeWidget import TreeWidget from ..widgets.FeedbackButton import FeedbackButton pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/flowchart/FlowchartCtrlTemplate_pyqt5.py000066400000000000000000000055341300727121400276260ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './pyqtgraph/flowchart/FlowchartCtrlTemplate.ui' # # Created: Wed Mar 26 15:09:28 2014 # by: PyQt5 UI code generator 5.0.1 # # WARNING! All changes made in this file will be lost! from PyQt5 import QtCore, QtGui, QtWidgets class Ui_Form(object): def setupUi(self, Form): Form.setObjectName("Form") Form.resize(217, 499) self.gridLayout = QtWidgets.QGridLayout(Form) self.gridLayout.setContentsMargins(0, 0, 0, 0) self.gridLayout.setVerticalSpacing(0) self.gridLayout.setObjectName("gridLayout") self.loadBtn = QtWidgets.QPushButton(Form) self.loadBtn.setObjectName("loadBtn") self.gridLayout.addWidget(self.loadBtn, 1, 0, 1, 1) self.saveBtn = FeedbackButton(Form) self.saveBtn.setObjectName("saveBtn") self.gridLayout.addWidget(self.saveBtn, 1, 1, 1, 2) self.saveAsBtn = FeedbackButton(Form) self.saveAsBtn.setObjectName("saveAsBtn") self.gridLayout.addWidget(self.saveAsBtn, 1, 3, 1, 1) self.reloadBtn = FeedbackButton(Form) self.reloadBtn.setCheckable(False) self.reloadBtn.setFlat(False) self.reloadBtn.setObjectName("reloadBtn") self.gridLayout.addWidget(self.reloadBtn, 4, 0, 1, 2) self.showChartBtn = QtWidgets.QPushButton(Form) self.showChartBtn.setCheckable(True) self.showChartBtn.setObjectName("showChartBtn") self.gridLayout.addWidget(self.showChartBtn, 4, 2, 1, 2) self.ctrlList = TreeWidget(Form) self.ctrlList.setObjectName("ctrlList") self.ctrlList.headerItem().setText(0, "1") self.ctrlList.header().setVisible(False) self.ctrlList.header().setStretchLastSection(False) self.gridLayout.addWidget(self.ctrlList, 3, 0, 1, 4) self.fileNameLabel = QtWidgets.QLabel(Form) font = QtGui.QFont() font.setBold(True) font.setWeight(75) self.fileNameLabel.setFont(font) self.fileNameLabel.setText("") self.fileNameLabel.setAlignment(QtCore.Qt.AlignCenter) self.fileNameLabel.setObjectName("fileNameLabel") self.gridLayout.addWidget(self.fileNameLabel, 0, 1, 1, 1) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): _translate = QtCore.QCoreApplication.translate Form.setWindowTitle(_translate("Form", "Form")) self.loadBtn.setText(_translate("Form", "Load..")) self.saveBtn.setText(_translate("Form", "Save")) self.saveAsBtn.setText(_translate("Form", "As..")) self.reloadBtn.setText(_translate("Form", "Reload Libs")) self.showChartBtn.setText(_translate("Form", "Flowchart")) from ..widgets.FeedbackButton import FeedbackButton from ..widgets.TreeWidget import TreeWidget pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/flowchart/FlowchartCtrlTemplate_pyside.py000066400000000000000000000061471300727121400300420ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './pyqtgraph/flowchart/FlowchartCtrlTemplate.ui' # # Created: Mon Dec 23 10:10:51 2013 # by: pyside-uic 0.2.14 running on PySide 1.1.2 # # WARNING! All changes made in this file will be lost! from PySide import QtCore, QtGui class Ui_Form(object): def setupUi(self, Form): Form.setObjectName("Form") Form.resize(217, 499) self.gridLayout = QtGui.QGridLayout(Form) self.gridLayout.setContentsMargins(0, 0, 0, 0) self.gridLayout.setVerticalSpacing(0) self.gridLayout.setObjectName("gridLayout") self.loadBtn = QtGui.QPushButton(Form) self.loadBtn.setObjectName("loadBtn") self.gridLayout.addWidget(self.loadBtn, 1, 0, 1, 1) self.saveBtn = FeedbackButton(Form) self.saveBtn.setObjectName("saveBtn") self.gridLayout.addWidget(self.saveBtn, 1, 1, 1, 2) self.saveAsBtn = FeedbackButton(Form) self.saveAsBtn.setObjectName("saveAsBtn") self.gridLayout.addWidget(self.saveAsBtn, 1, 3, 1, 1) self.reloadBtn = FeedbackButton(Form) self.reloadBtn.setCheckable(False) self.reloadBtn.setFlat(False) self.reloadBtn.setObjectName("reloadBtn") self.gridLayout.addWidget(self.reloadBtn, 4, 0, 1, 2) self.showChartBtn = QtGui.QPushButton(Form) self.showChartBtn.setCheckable(True) self.showChartBtn.setObjectName("showChartBtn") self.gridLayout.addWidget(self.showChartBtn, 4, 2, 1, 2) self.ctrlList = TreeWidget(Form) self.ctrlList.setObjectName("ctrlList") self.ctrlList.headerItem().setText(0, "1") self.ctrlList.header().setVisible(False) self.ctrlList.header().setStretchLastSection(False) self.gridLayout.addWidget(self.ctrlList, 3, 0, 1, 4) self.fileNameLabel = QtGui.QLabel(Form) font = QtGui.QFont() font.setWeight(75) font.setBold(True) self.fileNameLabel.setFont(font) self.fileNameLabel.setText("") self.fileNameLabel.setAlignment(QtCore.Qt.AlignCenter) self.fileNameLabel.setObjectName("fileNameLabel") self.gridLayout.addWidget(self.fileNameLabel, 0, 1, 1, 1) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): Form.setWindowTitle(QtGui.QApplication.translate("Form", "Form", None, QtGui.QApplication.UnicodeUTF8)) self.loadBtn.setText(QtGui.QApplication.translate("Form", "Load..", None, QtGui.QApplication.UnicodeUTF8)) self.saveBtn.setText(QtGui.QApplication.translate("Form", "Save", None, QtGui.QApplication.UnicodeUTF8)) self.saveAsBtn.setText(QtGui.QApplication.translate("Form", "As..", None, QtGui.QApplication.UnicodeUTF8)) self.reloadBtn.setText(QtGui.QApplication.translate("Form", "Reload Libs", None, QtGui.QApplication.UnicodeUTF8)) self.showChartBtn.setText(QtGui.QApplication.translate("Form", "Flowchart", None, QtGui.QApplication.UnicodeUTF8)) from ..widgets.TreeWidget import TreeWidget from ..widgets.FeedbackButton import FeedbackButton pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/flowchart/FlowchartGraphicsView.py000066400000000000000000000025241300727121400264530ustar00rootroot00000000000000# -*- coding: utf-8 -*- from ..Qt import QtGui, QtCore from ..widgets.GraphicsView import GraphicsView from ..GraphicsScene import GraphicsScene from ..graphicsItems.ViewBox import ViewBox class FlowchartGraphicsView(GraphicsView): sigHoverOver = QtCore.Signal(object) sigClicked = QtCore.Signal(object) def __init__(self, widget, *args): GraphicsView.__init__(self, *args, useOpenGL=False) self._vb = FlowchartViewBox(widget, lockAspect=True, invertY=True) self.setCentralItem(self._vb) self.setRenderHint(QtGui.QPainter.Antialiasing, True) def viewBox(self): return self._vb class FlowchartViewBox(ViewBox): def __init__(self, widget, *args, **kwargs): ViewBox.__init__(self, *args, **kwargs) self.widget = widget def getMenu(self, ev): ## called by ViewBox to create a new context menu self._fc_menu = QtGui.QMenu() self._subMenus = self.getContextMenus(ev) for menu in self._subMenus: self._fc_menu.addMenu(menu) return self._fc_menu def getContextMenus(self, ev): ## called by scene to add menus on to someone else's context menu menu = self.widget.buildMenu(ev.scenePos()) menu.setTitle("Add node") return [menu, ViewBox.getMenu(self, ev)] pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/flowchart/FlowchartTemplate.ui000066400000000000000000000044271300727121400256240ustar00rootroot00000000000000 Form 0 0 529 329 Form 260 10 264 222 Qt::AlignLeading|Qt::AlignLeft|Qt::AlignTop true 75 true 1 0 240 521 81 0 0 256 192 DataTreeWidget QTreeWidget
..widgets.DataTreeWidget
 FlowchartGraphicsView QGraphicsView
..flowchart.FlowchartGraphicsView
 pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/flowchart/FlowchartTemplate_pyqt.py000066400000000000000000000054411300727121400267110ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './pyqtgraph/flowchart/FlowchartTemplate.ui' # # Created: Mon Dec 23 10:10:51 2013 # by: PyQt4 UI code generator 4.10 # # WARNING! All changes made in this file will be lost! from PyQt4 import QtCore, QtGui try: _fromUtf8 = QtCore.QString.fromUtf8 except AttributeError: def _fromUtf8(s): return s try: _encoding = QtGui.QApplication.UnicodeUTF8 def _translate(context, text, disambig): return QtGui.QApplication.translate(context, text, disambig, _encoding) except AttributeError: def _translate(context, text, disambig): return QtGui.QApplication.translate(context, text, disambig) class Ui_Form(object): def setupUi(self, Form): Form.setObjectName(_fromUtf8("Form")) Form.resize(529, 329) self.selInfoWidget = QtGui.QWidget(Form) self.selInfoWidget.setGeometry(QtCore.QRect(260, 10, 264, 222)) self.selInfoWidget.setObjectName(_fromUtf8("selInfoWidget")) self.gridLayout = QtGui.QGridLayout(self.selInfoWidget) self.gridLayout.setMargin(0) self.gridLayout.setObjectName(_fromUtf8("gridLayout")) self.selDescLabel = QtGui.QLabel(self.selInfoWidget) self.selDescLabel.setText(_fromUtf8("")) self.selDescLabel.setAlignment(QtCore.Qt.AlignLeading|QtCore.Qt.AlignLeft|QtCore.Qt.AlignTop) self.selDescLabel.setWordWrap(True) self.selDescLabel.setObjectName(_fromUtf8("selDescLabel")) self.gridLayout.addWidget(self.selDescLabel, 0, 0, 1, 1) self.selNameLabel = QtGui.QLabel(self.selInfoWidget) font = QtGui.QFont() font.setBold(True) font.setWeight(75) self.selNameLabel.setFont(font) self.selNameLabel.setText(_fromUtf8("")) self.selNameLabel.setObjectName(_fromUtf8("selNameLabel")) self.gridLayout.addWidget(self.selNameLabel, 0, 1, 1, 1) self.selectedTree = DataTreeWidget(self.selInfoWidget) self.selectedTree.setObjectName(_fromUtf8("selectedTree")) self.selectedTree.headerItem().setText(0, _fromUtf8("1")) self.gridLayout.addWidget(self.selectedTree, 1, 0, 1, 2) self.hoverText = QtGui.QTextEdit(Form) self.hoverText.setGeometry(QtCore.QRect(0, 240, 521, 81)) self.hoverText.setObjectName(_fromUtf8("hoverText")) self.view = FlowchartGraphicsView(Form) self.view.setGeometry(QtCore.QRect(0, 0, 256, 192)) self.view.setObjectName(_fromUtf8("view")) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): Form.setWindowTitle(_translate("Form", "Form", None)) from ..flowchart.FlowchartGraphicsView import FlowchartGraphicsView from ..widgets.DataTreeWidget import DataTreeWidget pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/flowchart/FlowchartTemplate_pyqt5.py000066400000000000000000000045441300727121400270010ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './pyqtgraph/flowchart/FlowchartTemplate.ui' # # Created: Wed Mar 26 15:09:28 2014 # by: PyQt5 UI code generator 5.0.1 # # WARNING! All changes made in this file will be lost! from PyQt5 import QtCore, QtGui, QtWidgets class Ui_Form(object): def setupUi(self, Form): Form.setObjectName("Form") Form.resize(529, 329) self.selInfoWidget = QtWidgets.QWidget(Form) self.selInfoWidget.setGeometry(QtCore.QRect(260, 10, 264, 222)) self.selInfoWidget.setObjectName("selInfoWidget") self.gridLayout = QtWidgets.QGridLayout(self.selInfoWidget) self.gridLayout.setContentsMargins(0, 0, 0, 0) self.gridLayout.setObjectName("gridLayout") self.selDescLabel = QtWidgets.QLabel(self.selInfoWidget) self.selDescLabel.setText("") self.selDescLabel.setAlignment(QtCore.Qt.AlignLeading|QtCore.Qt.AlignLeft|QtCore.Qt.AlignTop) self.selDescLabel.setWordWrap(True) self.selDescLabel.setObjectName("selDescLabel") self.gridLayout.addWidget(self.selDescLabel, 0, 0, 1, 1) self.selNameLabel = QtWidgets.QLabel(self.selInfoWidget) font = QtGui.QFont() font.setBold(True) font.setWeight(75) self.selNameLabel.setFont(font) self.selNameLabel.setText("") self.selNameLabel.setObjectName("selNameLabel") self.gridLayout.addWidget(self.selNameLabel, 0, 1, 1, 1) self.selectedTree = DataTreeWidget(self.selInfoWidget) self.selectedTree.setObjectName("selectedTree") self.selectedTree.headerItem().setText(0, "1") self.gridLayout.addWidget(self.selectedTree, 1, 0, 1, 2) self.hoverText = QtWidgets.QTextEdit(Form) self.hoverText.setGeometry(QtCore.QRect(0, 240, 521, 81)) self.hoverText.setObjectName("hoverText") self.view = FlowchartGraphicsView(Form) self.view.setGeometry(QtCore.QRect(0, 0, 256, 192)) self.view.setObjectName("view") self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): _translate = QtCore.QCoreApplication.translate Form.setWindowTitle(_translate("Form", "Form")) from ..widgets.DataTreeWidget import DataTreeWidget from ..flowchart.FlowchartGraphicsView import FlowchartGraphicsView pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/flowchart/FlowchartTemplate_pyside.py000066400000000000000000000045231300727121400272110ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './pyqtgraph/flowchart/FlowchartTemplate.ui' # # Created: Mon Dec 23 10:10:51 2013 # by: pyside-uic 0.2.14 running on PySide 1.1.2 # # WARNING! All changes made in this file will be lost! from PySide import QtCore, QtGui class Ui_Form(object): def setupUi(self, Form): Form.setObjectName("Form") Form.resize(529, 329) self.selInfoWidget = QtGui.QWidget(Form) self.selInfoWidget.setGeometry(QtCore.QRect(260, 10, 264, 222)) self.selInfoWidget.setObjectName("selInfoWidget") self.gridLayout = QtGui.QGridLayout(self.selInfoWidget) self.gridLayout.setContentsMargins(0, 0, 0, 0) self.gridLayout.setObjectName("gridLayout") self.selDescLabel = QtGui.QLabel(self.selInfoWidget) self.selDescLabel.setText("") self.selDescLabel.setAlignment(QtCore.Qt.AlignLeading|QtCore.Qt.AlignLeft|QtCore.Qt.AlignTop) self.selDescLabel.setWordWrap(True) self.selDescLabel.setObjectName("selDescLabel") self.gridLayout.addWidget(self.selDescLabel, 0, 0, 1, 1) self.selNameLabel = QtGui.QLabel(self.selInfoWidget) font = QtGui.QFont() font.setWeight(75) font.setBold(True) self.selNameLabel.setFont(font) self.selNameLabel.setText("") self.selNameLabel.setObjectName("selNameLabel") self.gridLayout.addWidget(self.selNameLabel, 0, 1, 1, 1) self.selectedTree = DataTreeWidget(self.selInfoWidget) self.selectedTree.setObjectName("selectedTree") self.selectedTree.headerItem().setText(0, "1") self.gridLayout.addWidget(self.selectedTree, 1, 0, 1, 2) self.hoverText = QtGui.QTextEdit(Form) self.hoverText.setGeometry(QtCore.QRect(0, 240, 521, 81)) self.hoverText.setObjectName("hoverText") self.view = FlowchartGraphicsView(Form) self.view.setGeometry(QtCore.QRect(0, 0, 256, 192)) self.view.setObjectName("view") self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): Form.setWindowTitle(QtGui.QApplication.translate("Form", "Form", None, QtGui.QApplication.UnicodeUTF8)) from ..flowchart.FlowchartGraphicsView import FlowchartGraphicsView from ..widgets.DataTreeWidget import DataTreeWidget pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/flowchart/Node.py000066400000000000000000000613151300727121400230760ustar00rootroot00000000000000# -*- coding: utf-8 -*- from ..Qt import QtCore, QtGui from ..graphicsItems.GraphicsObject import GraphicsObject from .. import functions as fn from .Terminal import * from ..pgcollections import OrderedDict from ..debug import * import numpy as np def strDict(d): return dict([(str(k), v) for k, v in d.items()]) class Node(QtCore.QObject): """ Node represents the basic processing unit of a flowchart. A Node subclass implements at least: 1) A list of input / ouptut terminals and their properties 2) a process() function which takes the names of input terminals as keyword arguments and returns a dict with the names of output terminals as keys. A flowchart thus consists of multiple instances of Node subclasses, each of which is connected to other by wires between their terminals. A flowchart is, itself, also a special subclass of Node. This allows Nodes within the flowchart to connect to the input/output nodes of the flowchart itself. Optionally, a node class can implement the ctrlWidget() method, which must return a QWidget (usually containing other widgets) that will be displayed in the flowchart control panel. Some nodes implement fairly complex control widgets, but most nodes follow a simple form-like pattern: a list of parameter names and a single value (represented as spin box, check box, etc..) for each parameter. To make this easier, the CtrlNode subclass allows you to instead define a simple data structure that CtrlNode will use to automatically generate the control widget. """ sigOutputChanged = QtCore.Signal(object) # self sigClosed = QtCore.Signal(object) sigRenamed = QtCore.Signal(object, object) sigTerminalRenamed = QtCore.Signal(object, object) # term, oldName sigTerminalAdded = QtCore.Signal(object, object) # self, term sigTerminalRemoved = QtCore.Signal(object, object) # self, term def __init__(self, name, terminals=None, allowAddInput=False, allowAddOutput=False, allowRemove=True): """ ============== ============================================================ **Arguments:** name The name of this specific node instance. It can be any string, but must be unique within a flowchart. Usually, we simply let the flowchart decide on a name when calling Flowchart.addNode(...) terminals Dict-of-dicts specifying the terminals present on this Node. Terminal specifications look like:: 'inputTerminalName': {'io': 'in'} 'outputTerminalName': {'io': 'out'} There are a number of optional parameters for terminals: multi, pos, renamable, removable, multiable, bypass. See the Terminal class for more information. allowAddInput bool; whether the user is allowed to add inputs by the context menu. allowAddOutput bool; whether the user is allowed to add outputs by the context menu. allowRemove bool; whether the user is allowed to remove this node by the context menu. ============== ============================================================ """ QtCore.QObject.__init__(self) self._name = name self._bypass = False self.bypassButton = None ## this will be set by the flowchart ctrl widget.. self._graphicsItem = None self.terminals = OrderedDict() self._inputs = OrderedDict() self._outputs = OrderedDict() self._allowAddInput = allowAddInput ## flags to allow the user to add/remove terminals self._allowAddOutput = allowAddOutput self._allowRemove = allowRemove self.exception = None if terminals is None: return for name, opts in terminals.items(): self.addTerminal(name, **opts) def nextTerminalName(self, name): """Return an unused terminal name""" name2 = name i = 1 while name2 in self.terminals: name2 = "%s.%d" % (name, i) i += 1 return name2 def addInput(self, name="Input", **args): """Add a new input terminal to this Node with the given name. Extra keyword arguments are passed to Terminal.__init__. This is a convenience function that just calls addTerminal(io='in', ...)""" #print "Node.addInput called." return self.addTerminal(name, io='in', **args) def addOutput(self, name="Output", **args): """Add a new output terminal to this Node with the given name. Extra keyword arguments are passed to Terminal.__init__. This is a convenience function that just calls addTerminal(io='out', ...)""" return self.addTerminal(name, io='out', **args) def removeTerminal(self, term): """Remove the specified terminal from this Node. May specify either the terminal's name or the terminal itself. Causes sigTerminalRemoved to be emitted.""" if isinstance(term, Terminal): name = term.name() else: name = term term = self.terminals[name] #print "remove", name #term.disconnectAll() term.close() del self.terminals[name] if name in self._inputs: del self._inputs[name] if name in self._outputs: del self._outputs[name] self.graphicsItem().updateTerminals() self.sigTerminalRemoved.emit(self, term) def terminalRenamed(self, term, oldName): """Called after a terminal has been renamed Causes sigTerminalRenamed to be emitted.""" newName = term.name() for d in [self.terminals, self._inputs, self._outputs]: if oldName not in d: continue d[newName] = d[oldName] del d[oldName] self.graphicsItem().updateTerminals() self.sigTerminalRenamed.emit(term, oldName) def addTerminal(self, name, **opts): """Add a new terminal to this Node with the given name. Extra keyword arguments are passed to Terminal.__init__. Causes sigTerminalAdded to be emitted.""" name = self.nextTerminalName(name) term = Terminal(self, name, **opts) self.terminals[name] = term if term.isInput(): self._inputs[name] = term elif term.isOutput(): self._outputs[name] = term self.graphicsItem().updateTerminals() self.sigTerminalAdded.emit(self, term) return term def inputs(self): """Return dict of all input terminals. Warning: do not modify.""" return self._inputs def outputs(self): """Return dict of all output terminals. Warning: do not modify.""" return self._outputs def process(self, **kargs): """Process data through this node. This method is called any time the flowchart wants the node to process data. It will be called with one keyword argument corresponding to each input terminal, and must return a dict mapping the name of each output terminal to its new value. This method is also called with a 'display' keyword argument, which indicates whether the node should update its display (if it implements any) while processing this data. This is primarily used to disable expensive display operations during batch processing. """ return {} def graphicsItem(self): """Return the GraphicsItem for this node. Subclasses may re-implement this method to customize their appearance in the flowchart.""" if self._graphicsItem is None: self._graphicsItem = NodeGraphicsItem(self) return self._graphicsItem ## this is just bad planning. Causes too many bugs. def __getattr__(self, attr): """Return the terminal with the given name""" if attr not in self.terminals: raise AttributeError(attr) else: import traceback traceback.print_stack() print("Warning: use of node.terminalName is deprecated; use node['terminalName'] instead.") return self.terminals[attr] def __getitem__(self, item): #return getattr(self, item) """Return the terminal with the given name""" if item not in self.terminals: raise KeyError(item) else: return self.terminals[item] def name(self): """Return the name of this node.""" return self._name def rename(self, name): """Rename this node. This will cause sigRenamed to be emitted.""" oldName = self._name self._name = name #self.emit(QtCore.SIGNAL('renamed'), self, oldName) self.sigRenamed.emit(self, oldName) def dependentNodes(self): """Return the list of nodes which provide direct input to this node""" nodes = set() for t in self.inputs().values(): nodes |= set([i.node() for i in t.inputTerminals()]) return nodes #return set([t.inputTerminals().node() for t in self.listInputs().itervalues()]) def __repr__(self): return "" % (self.name(), id(self)) def ctrlWidget(self): """Return this Node's control widget. By default, Nodes have no control widget. Subclasses may reimplement this method to provide a custom widget. This method is called by Flowcharts when they are constructing their Node list.""" return None def bypass(self, byp): """Set whether this node should be bypassed. When bypassed, a Node's process() method is never called. In some cases, data is automatically copied directly from specific input nodes to output nodes instead (see the bypass argument to Terminal.__init__). This is usually called when the user disables a node from the flowchart control panel. """ self._bypass = byp if self.bypassButton is not None: self.bypassButton.setChecked(byp) self.update() def isBypassed(self): """Return True if this Node is currently bypassed.""" return self._bypass def setInput(self, **args): """Set the values on input terminals. For most nodes, this will happen automatically through Terminal.inputChanged. This is normally only used for nodes with no connected inputs.""" changed = False for k, v in args.items(): term = self._inputs[k] oldVal = term.value() if not fn.eq(oldVal, v): changed = True term.setValue(v, process=False) if changed and '_updatesHandled_' not in args: self.update() def inputValues(self): """Return a dict of all input values currently assigned to this node.""" vals = {} for n, t in self.inputs().items(): vals[n] = t.value() return vals def outputValues(self): """Return a dict of all output values currently generated by this node.""" vals = {} for n, t in self.outputs().items(): vals[n] = t.value() return vals def connected(self, localTerm, remoteTerm): """Called whenever one of this node's terminals is connected elsewhere.""" pass def disconnected(self, localTerm, remoteTerm): """Called whenever one of this node's terminals is disconnected from another.""" pass def update(self, signal=True): """Collect all input values, attempt to process new output values, and propagate downstream. Subclasses should call update() whenever thir internal state has changed (such as when the user interacts with the Node's control widget). Update is automatically called when the inputs to the node are changed. """ vals = self.inputValues() #print " inputs:", vals try: if self.isBypassed(): out = self.processBypassed(vals) else: out = self.process(**strDict(vals)) #print " output:", out if out is not None: if signal: self.setOutput(**out) else: self.setOutputNoSignal(**out) for n,t in self.inputs().items(): t.setValueAcceptable(True) self.clearException() except: #printExc( "Exception while processing %s:" % self.name()) for n,t in self.outputs().items(): t.setValue(None) self.setException(sys.exc_info()) if signal: #self.emit(QtCore.SIGNAL('outputChanged'), self) ## triggers flowchart to propagate new data self.sigOutputChanged.emit(self) ## triggers flowchart to propagate new data def processBypassed(self, args): """Called when the flowchart would normally call Node.process, but this node is currently bypassed. The default implementation looks for output terminals with a bypass connection and returns the corresponding values. Most Node subclasses will _not_ need to reimplement this method.""" result = {} for term in list(self.outputs().values()): byp = term.bypassValue() if byp is None: result[term.name()] = None else: result[term.name()] = args.get(byp, None) return result def setOutput(self, **vals): self.setOutputNoSignal(**vals) #self.emit(QtCore.SIGNAL('outputChanged'), self) ## triggers flowchart to propagate new data self.sigOutputChanged.emit(self) ## triggers flowchart to propagate new data def setOutputNoSignal(self, **vals): for k, v in vals.items(): term = self.outputs()[k] term.setValue(v) #targets = term.connections() #for t in targets: ## propagate downstream #if t is term: #continue #t.inputChanged(term) term.setValueAcceptable(True) def setException(self, exc): self.exception = exc self.recolor() def clearException(self): self.setException(None) def recolor(self): if self.exception is None: self.graphicsItem().setPen(QtGui.QPen(QtGui.QColor(0, 0, 0))) else: self.graphicsItem().setPen(QtGui.QPen(QtGui.QColor(150, 0, 0), 3)) def saveState(self): """Return a dictionary representing the current state of this node (excluding input / output values). This is used for saving/reloading flowcharts. The default implementation returns this Node's position, bypass state, and information about each of its terminals. Subclasses may want to extend this method, adding extra keys to the returned dict.""" pos = self.graphicsItem().pos() state = {'pos': (pos.x(), pos.y()), 'bypass': self.isBypassed()} termsEditable = self._allowAddInput | self._allowAddOutput for term in self._inputs.values() + self._outputs.values(): termsEditable |= term._renamable | term._removable | term._multiable if termsEditable: state['terminals'] = self.saveTerminals() return state def restoreState(self, state): """Restore the state of this node from a structure previously generated by saveState(). """ pos = state.get('pos', (0,0)) self.graphicsItem().setPos(*pos) self.bypass(state.get('bypass', False)) if 'terminals' in state: self.restoreTerminals(state['terminals']) def saveTerminals(self): terms = OrderedDict() for n, t in self.terminals.items(): terms[n] = (t.saveState()) return terms def restoreTerminals(self, state): for name in list(self.terminals.keys()): if name not in state: self.removeTerminal(name) for name, opts in state.items(): if name in self.terminals: term = self[name] term.setOpts(**opts) continue try: opts = strDict(opts) self.addTerminal(name, **opts) except: printExc("Error restoring terminal %s (%s):" % (str(name), str(opts))) def clearTerminals(self): for t in self.terminals.values(): t.close() self.terminals = OrderedDict() self._inputs = OrderedDict() self._outputs = OrderedDict() def close(self): """Cleans up after the node--removes terminals, graphicsItem, widget""" self.disconnectAll() self.clearTerminals() item = self.graphicsItem() if item.scene() is not None: item.scene().removeItem(item) self._graphicsItem = None w = self.ctrlWidget() if w is not None: w.setParent(None) #self.emit(QtCore.SIGNAL('closed'), self) self.sigClosed.emit(self) def disconnectAll(self): for t in self.terminals.values(): t.disconnectAll() #class NodeGraphicsItem(QtGui.QGraphicsItem): class NodeGraphicsItem(GraphicsObject): def __init__(self, node): #QtGui.QGraphicsItem.__init__(self) GraphicsObject.__init__(self) #QObjectWorkaround.__init__(self) #self.shadow = QtGui.QGraphicsDropShadowEffect() #self.shadow.setOffset(5,5) #self.shadow.setBlurRadius(10) #self.setGraphicsEffect(self.shadow) self.pen = fn.mkPen(0,0,0) self.selectPen = fn.mkPen(200,200,200,width=2) self.brush = fn.mkBrush(200, 200, 200, 150) self.hoverBrush = fn.mkBrush(200, 200, 200, 200) self.selectBrush = fn.mkBrush(200, 200, 255, 200) self.hovered = False self.node = node flags = self.ItemIsMovable | self.ItemIsSelectable | self.ItemIsFocusable |self.ItemSendsGeometryChanges #flags = self.ItemIsFocusable |self.ItemSendsGeometryChanges self.setFlags(flags) self.bounds = QtCore.QRectF(0, 0, 100, 100) self.nameItem = QtGui.QGraphicsTextItem(self.node.name(), self) self.nameItem.setDefaultTextColor(QtGui.QColor(50, 50, 50)) self.nameItem.moveBy(self.bounds.width()/2. - self.nameItem.boundingRect().width()/2., 0) self.nameItem.setTextInteractionFlags(QtCore.Qt.TextEditorInteraction) self.updateTerminals() #self.setZValue(10) self.nameItem.focusOutEvent = self.labelFocusOut self.nameItem.keyPressEvent = self.labelKeyPress self.menu = None self.buildMenu() #self.node.sigTerminalRenamed.connect(self.updateActionMenu) #def setZValue(self, z): #for t, item in self.terminals.itervalues(): #item.setZValue(z+1) #GraphicsObject.setZValue(self, z) def labelFocusOut(self, ev): QtGui.QGraphicsTextItem.focusOutEvent(self.nameItem, ev) self.labelChanged() def labelKeyPress(self, ev): if ev.key() == QtCore.Qt.Key_Enter or ev.key() == QtCore.Qt.Key_Return: self.labelChanged() else: QtGui.QGraphicsTextItem.keyPressEvent(self.nameItem, ev) def labelChanged(self): newName = str(self.nameItem.toPlainText()) if newName != self.node.name(): self.node.rename(newName) ### re-center the label bounds = self.boundingRect() self.nameItem.setPos(bounds.width()/2. - self.nameItem.boundingRect().width()/2., 0) def setPen(self, *args, **kwargs): self.pen = fn.mkPen(*args, **kwargs) self.update() def setBrush(self, brush): self.brush = brush self.update() def updateTerminals(self): bounds = self.bounds self.terminals = {} inp = self.node.inputs() dy = bounds.height() / (len(inp)+1) y = dy for i, t in inp.items(): item = t.graphicsItem() item.setParentItem(self) #item.setZValue(self.zValue()+1) br = self.bounds item.setAnchor(0, y) self.terminals[i] = (t, item) y += dy out = self.node.outputs() dy = bounds.height() / (len(out)+1) y = dy for i, t in out.items(): item = t.graphicsItem() item.setParentItem(self) item.setZValue(self.zValue()) br = self.bounds item.setAnchor(bounds.width(), y) self.terminals[i] = (t, item) y += dy #self.buildMenu() def boundingRect(self): return self.bounds.adjusted(-5, -5, 5, 5) def paint(self, p, *args): p.setPen(self.pen) if self.isSelected(): p.setPen(self.selectPen) p.setBrush(self.selectBrush) else: p.setPen(self.pen) if self.hovered: p.setBrush(self.hoverBrush) else: p.setBrush(self.brush) p.drawRect(self.bounds) def mousePressEvent(self, ev): ev.ignore() def mouseClickEvent(self, ev): #print "Node.mouseClickEvent called." if int(ev.button()) == int(QtCore.Qt.LeftButton): ev.accept() #print " ev.button: left" sel = self.isSelected() #ret = QtGui.QGraphicsItem.mousePressEvent(self, ev) self.setSelected(True) if not sel and self.isSelected(): #self.setBrush(QtGui.QBrush(QtGui.QColor(200, 200, 255))) #self.emit(QtCore.SIGNAL('selected')) #self.scene().selectionChanged.emit() ## for some reason this doesn't seem to be happening automatically self.update() #return ret elif int(ev.button()) == int(QtCore.Qt.RightButton): #print " ev.button: right" ev.accept() #pos = ev.screenPos() self.raiseContextMenu(ev) #self.menu.popup(QtCore.QPoint(pos.x(), pos.y())) def mouseDragEvent(self, ev): #print "Node.mouseDrag" if ev.button() == QtCore.Qt.LeftButton: ev.accept() self.setPos(self.pos()+self.mapToParent(ev.pos())-self.mapToParent(ev.lastPos())) def hoverEvent(self, ev): if not ev.isExit() and ev.acceptClicks(QtCore.Qt.LeftButton): ev.acceptDrags(QtCore.Qt.LeftButton) self.hovered = True else: self.hovered = False self.update() def keyPressEvent(self, ev): if ev.key() == QtCore.Qt.Key_Delete or ev.key() == QtCore.Qt.Key_Backspace: ev.accept() if not self.node._allowRemove: return self.node.close() else: ev.ignore() def itemChange(self, change, val): if change == self.ItemPositionHasChanged: for k, t in self.terminals.items(): t[1].nodeMoved() return GraphicsObject.itemChange(self, change, val) def getMenu(self): return self.menu def raiseContextMenu(self, ev): menu = self.scene().addParentContextMenus(self, self.getMenu(), ev) pos = ev.screenPos() menu.popup(QtCore.QPoint(pos.x(), pos.y())) def buildMenu(self): self.menu = QtGui.QMenu() self.menu.setTitle("Node") a = self.menu.addAction("Add input", self.addInputFromMenu) if not self.node._allowAddInput: a.setEnabled(False) a = self.menu.addAction("Add output", self.addOutputFromMenu) if not self.node._allowAddOutput: a.setEnabled(False) a = self.menu.addAction("Remove node", self.node.close) if not self.node._allowRemove: a.setEnabled(False) def addInputFromMenu(self): ## called when add input is clicked in context menu self.node.addInput(renamable=True, removable=True, multiable=True) def addOutputFromMenu(self): ## called when add output is clicked in context menu self.node.addOutput(renamable=True, removable=True, multiable=False) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/flowchart/NodeLibrary.py000066400000000000000000000050771300727121400244260ustar00rootroot00000000000000from ..pgcollections import OrderedDict from .Node import Node def isNodeClass(cls): try: if not issubclass(cls, Node): return False except: return False return hasattr(cls, 'nodeName') class NodeLibrary: """ A library of flowchart Node types. Custom libraries may be built to provide each flowchart with a specific set of allowed Node types. """ def __init__(self): self.nodeList = OrderedDict() self.nodeTree = OrderedDict() def addNodeType(self, nodeClass, paths, override=False): """ Register a new node type. If the type's name is already in use, an exception will be raised (unless override=True). ============== ========================================================= **Arguments:** nodeClass a subclass of Node (must have typ.nodeName) paths list of tuples specifying the location(s) this type will appear in the library tree. override if True, overwrite any class having the same name ============== ========================================================= """ if not isNodeClass(nodeClass): raise Exception("Object %s is not a Node subclass" % str(nodeClass)) name = nodeClass.nodeName if not override and name in self.nodeList: raise Exception("Node type name '%s' is already registered." % name) self.nodeList[name] = nodeClass for path in paths: root = self.nodeTree for n in path: if n not in root: root[n] = OrderedDict() root = root[n] root[name] = nodeClass def getNodeType(self, name): try: return self.nodeList[name] except KeyError: raise Exception("No node type called '%s'" % name) def getNodeTree(self): return self.nodeTree def copy(self): """ Return a copy of this library. """ lib = NodeLibrary() lib.nodeList = self.nodeList.copy() lib.nodeTree = self.treeCopy(self.nodeTree) return lib @staticmethod def treeCopy(tree): copy = OrderedDict() for k,v in tree.items(): if isNodeClass(v): copy[k] = v else: copy[k] = NodeLibrary.treeCopy(v) return copy def reload(self): """ Reload Node classes in this library. """ raise NotImplementedError() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/flowchart/Terminal.py000066400000000000000000000504621300727121400237650ustar00rootroot00000000000000# -*- coding: utf-8 -*- from ..Qt import QtCore, QtGui import weakref from ..graphicsItems.GraphicsObject import GraphicsObject from .. import functions as fn from ..Point import Point class Terminal(object): def __init__(self, node, name, io, optional=False, multi=False, pos=None, renamable=False, removable=False, multiable=False, bypass=None): """ Construct a new terminal. ============== ================================================================================= **Arguments:** node the node to which this terminal belongs name string, the name of the terminal io 'in' or 'out' optional bool, whether the node may process without connection to this terminal multi bool, for inputs: whether this terminal may make multiple connections for outputs: whether this terminal creates a different value for each connection pos [x, y], the position of the terminal within its node's boundaries renamable (bool) Whether the terminal can be renamed by the user removable (bool) Whether the terminal can be removed by the user multiable (bool) Whether the user may toggle the *multi* option for this terminal bypass (str) Name of the terminal from which this terminal's value is derived when the Node is in bypass mode. ============== ================================================================================= """ self._io = io self._optional = optional self._multi = multi self._node = weakref.ref(node) self._name = name self._renamable = renamable self._removable = removable self._multiable = multiable self._connections = {} self._graphicsItem = TerminalGraphicsItem(self, parent=self._node().graphicsItem()) self._bypass = bypass if multi: self._value = {} ## dictionary of terminal:value pairs. else: self._value = None self.valueOk = None self.recolor() def value(self, term=None): """Return the value this terminal provides for the connected terminal""" if term is None: return self._value if self.isMultiValue(): return self._value.get(term, None) else: return self._value def bypassValue(self): return self._bypass def setValue(self, val, process=True): """If this is a single-value terminal, val should be a single value. If this is a multi-value terminal, val should be a dict of terminal:value pairs""" if not self.isMultiValue(): if fn.eq(val, self._value): return self._value = val else: if not isinstance(self._value, dict): self._value = {} if val is not None: self._value.update(val) self.setValueAcceptable(None) ## by default, input values are 'unchecked' until Node.update(). if self.isInput() and process: self.node().update() self.recolor() def setOpts(self, **opts): self._renamable = opts.get('renamable', self._renamable) self._removable = opts.get('removable', self._removable) self._multiable = opts.get('multiable', self._multiable) if 'multi' in opts: self.setMultiValue(opts['multi']) def connected(self, term): """Called whenever this terminal has been connected to another. (note--this function is called on both terminals)""" if self.isInput() and term.isOutput(): self.inputChanged(term) if self.isOutput() and self.isMultiValue(): self.node().update() self.node().connected(self, term) def disconnected(self, term): """Called whenever this terminal has been disconnected from another. (note--this function is called on both terminals)""" if self.isMultiValue() and term in self._value: del self._value[term] self.node().update() else: if self.isInput(): self.setValue(None) self.node().disconnected(self, term) def inputChanged(self, term, process=True): """Called whenever there is a change to the input value to this terminal. It may often be useful to override this function.""" if self.isMultiValue(): self.setValue({term: term.value(self)}, process=process) else: self.setValue(term.value(self), process=process) def valueIsAcceptable(self): """Returns True->acceptable None->unknown False->Unacceptable""" return self.valueOk def setValueAcceptable(self, v=True): self.valueOk = v self.recolor() def connections(self): return self._connections def node(self): return self._node() def isInput(self): return self._io == 'in' def isMultiValue(self): return self._multi def setMultiValue(self, multi): """Set whether this is a multi-value terminal.""" self._multi = multi if not multi and len(self.inputTerminals()) > 1: self.disconnectAll() for term in self.inputTerminals(): self.inputChanged(term) def isOutput(self): return self._io == 'out' def isRenamable(self): return self._renamable def isRemovable(self): return self._removable def isMultiable(self): return self._multiable def name(self): return self._name def graphicsItem(self): return self._graphicsItem def isConnected(self): return len(self.connections()) > 0 def connectedTo(self, term): return term in self.connections() def hasInput(self): for t in self.connections(): if t.isOutput(): return True return False def inputTerminals(self): """Return the terminal(s) that give input to this one.""" return [t for t in self.connections() if t.isOutput()] def dependentNodes(self): """Return the list of nodes which receive input from this terminal.""" return set([t.node() for t in self.connections() if t.isInput()]) def connectTo(self, term, connectionItem=None): try: if self.connectedTo(term): raise Exception('Already connected') if term is self: raise Exception('Not connecting terminal to self') if term.node() is self.node(): raise Exception("Can't connect to terminal on same node.") for t in [self, term]: if t.isInput() and not t._multi and len(t.connections()) > 0: raise Exception("Cannot connect %s <-> %s: Terminal %s is already connected to %s (and does not allow multiple connections)" % (self, term, t, list(t.connections().keys()))) except: if connectionItem is not None: connectionItem.close() raise if connectionItem is None: connectionItem = ConnectionItem(self.graphicsItem(), term.graphicsItem()) self.graphicsItem().getViewBox().addItem(connectionItem) self._connections[term] = connectionItem term._connections[self] = connectionItem self.recolor() self.connected(term) term.connected(self) return connectionItem def disconnectFrom(self, term): if not self.connectedTo(term): return item = self._connections[term] item.close() del self._connections[term] del term._connections[self] self.recolor() term.recolor() self.disconnected(term) term.disconnected(self) def disconnectAll(self): for t in list(self._connections.keys()): self.disconnectFrom(t) def recolor(self, color=None, recurse=True): if color is None: if not self.isConnected(): ## disconnected terminals are black color = QtGui.QColor(0,0,0) elif self.isInput() and not self.hasInput(): ## input terminal with no connected output terminals color = QtGui.QColor(200,200,0) elif self._value is None or fn.eq(self._value, {}): ## terminal is connected but has no data (possibly due to processing error) color = QtGui.QColor(255,255,255) elif self.valueIsAcceptable() is None: ## terminal has data, but it is unknown if the data is ok color = QtGui.QColor(200, 200, 0) elif self.valueIsAcceptable() is True: ## terminal has good input, all ok color = QtGui.QColor(0, 200, 0) else: ## terminal has bad input color = QtGui.QColor(200, 0, 0) self.graphicsItem().setBrush(QtGui.QBrush(color)) if recurse: for t in self.connections(): t.recolor(color, recurse=False) def rename(self, name): oldName = self._name self._name = name self.node().terminalRenamed(self, oldName) self.graphicsItem().termRenamed(name) def __repr__(self): return "" % (str(self.node().name()), str(self.name())) def __hash__(self): return id(self) def close(self): self.disconnectAll() item = self.graphicsItem() if item.scene() is not None: item.scene().removeItem(item) def saveState(self): return {'io': self._io, 'multi': self._multi, 'optional': self._optional, 'renamable': self._renamable, 'removable': self._removable, 'multiable': self._multiable} class TerminalGraphicsItem(GraphicsObject): def __init__(self, term, parent=None): self.term = term GraphicsObject.__init__(self, parent) self.brush = fn.mkBrush(0,0,0) self.box = QtGui.QGraphicsRectItem(0, 0, 10, 10, self) self.label = QtGui.QGraphicsTextItem(self.term.name(), self) self.label.scale(0.7, 0.7) self.newConnection = None self.setFiltersChildEvents(True) ## to pick up mouse events on the rectitem if self.term.isRenamable(): self.label.setTextInteractionFlags(QtCore.Qt.TextEditorInteraction) self.label.focusOutEvent = self.labelFocusOut self.label.keyPressEvent = self.labelKeyPress self.setZValue(1) self.menu = None def labelFocusOut(self, ev): QtGui.QGraphicsTextItem.focusOutEvent(self.label, ev) self.labelChanged() def labelKeyPress(self, ev): if ev.key() == QtCore.Qt.Key_Enter or ev.key() == QtCore.Qt.Key_Return: self.labelChanged() else: QtGui.QGraphicsTextItem.keyPressEvent(self.label, ev) def labelChanged(self): newName = str(self.label.toPlainText()) if newName != self.term.name(): self.term.rename(newName) def termRenamed(self, name): self.label.setPlainText(name) def setBrush(self, brush): self.brush = brush self.box.setBrush(brush) def disconnect(self, target): self.term.disconnectFrom(target.term) def boundingRect(self): br = self.box.mapRectToParent(self.box.boundingRect()) lr = self.label.mapRectToParent(self.label.boundingRect()) return br | lr def paint(self, p, *args): pass def setAnchor(self, x, y): pos = QtCore.QPointF(x, y) self.anchorPos = pos br = self.box.mapRectToParent(self.box.boundingRect()) lr = self.label.mapRectToParent(self.label.boundingRect()) if self.term.isInput(): self.box.setPos(pos.x(), pos.y()-br.height()/2.) self.label.setPos(pos.x() + br.width(), pos.y() - lr.height()/2.) else: self.box.setPos(pos.x()-br.width(), pos.y()-br.height()/2.) self.label.setPos(pos.x()-br.width()-lr.width(), pos.y()-lr.height()/2.) self.updateConnections() def updateConnections(self): for t, c in self.term.connections().items(): c.updateLine() def mousePressEvent(self, ev): #ev.accept() ev.ignore() ## necessary to allow click/drag events to process correctly def mouseClickEvent(self, ev): if ev.button() == QtCore.Qt.LeftButton: ev.accept() self.label.setFocus(QtCore.Qt.MouseFocusReason) elif ev.button() == QtCore.Qt.RightButton: ev.accept() self.raiseContextMenu(ev) def raiseContextMenu(self, ev): ## only raise menu if this terminal is removable menu = self.getMenu() menu = self.scene().addParentContextMenus(self, menu, ev) pos = ev.screenPos() menu.popup(QtCore.QPoint(pos.x(), pos.y())) def getMenu(self): if self.menu is None: self.menu = QtGui.QMenu() self.menu.setTitle("Terminal") remAct = QtGui.QAction("Remove terminal", self.menu) remAct.triggered.connect(self.removeSelf) self.menu.addAction(remAct) self.menu.remAct = remAct if not self.term.isRemovable(): remAct.setEnabled(False) multiAct = QtGui.QAction("Multi-value", self.menu) multiAct.setCheckable(True) multiAct.setChecked(self.term.isMultiValue()) multiAct.setEnabled(self.term.isMultiable()) multiAct.triggered.connect(self.toggleMulti) self.menu.addAction(multiAct) self.menu.multiAct = multiAct if self.term.isMultiable(): multiAct.setEnabled = False return self.menu def toggleMulti(self): multi = self.menu.multiAct.isChecked() self.term.setMultiValue(multi) def removeSelf(self): self.term.node().removeTerminal(self.term) def mouseDragEvent(self, ev): if ev.button() != QtCore.Qt.LeftButton: ev.ignore() return ev.accept() if ev.isStart(): if self.newConnection is None: self.newConnection = ConnectionItem(self) #self.scene().addItem(self.newConnection) self.getViewBox().addItem(self.newConnection) #self.newConnection.setParentItem(self.parent().parent()) self.newConnection.setTarget(self.mapToView(ev.pos())) elif ev.isFinish(): if self.newConnection is not None: items = self.scene().items(ev.scenePos()) gotTarget = False for i in items: if isinstance(i, TerminalGraphicsItem): self.newConnection.setTarget(i) try: self.term.connectTo(i.term, self.newConnection) gotTarget = True except: self.scene().removeItem(self.newConnection) self.newConnection = None raise break if not gotTarget: self.newConnection.close() self.newConnection = None else: if self.newConnection is not None: self.newConnection.setTarget(self.mapToView(ev.pos())) def hoverEvent(self, ev): if not ev.isExit() and ev.acceptDrags(QtCore.Qt.LeftButton): ev.acceptClicks(QtCore.Qt.LeftButton) ## we don't use the click, but we also don't want anyone else to use it. ev.acceptClicks(QtCore.Qt.RightButton) self.box.setBrush(fn.mkBrush('w')) else: self.box.setBrush(self.brush) self.update() def connectPoint(self): ## return the connect position of this terminal in view coords return self.mapToView(self.mapFromItem(self.box, self.box.boundingRect().center())) def nodeMoved(self): for t, item in self.term.connections().items(): item.updateLine() class ConnectionItem(GraphicsObject): def __init__(self, source, target=None): GraphicsObject.__init__(self) self.setFlags( self.ItemIsSelectable | self.ItemIsFocusable ) self.source = source self.target = target self.length = 0 self.hovered = False self.path = None self.shapePath = None self.style = { 'shape': 'line', 'color': (100, 100, 250), 'width': 1.0, 'hoverColor': (150, 150, 250), 'hoverWidth': 1.0, 'selectedColor': (200, 200, 0), 'selectedWidth': 3.0, } self.source.getViewBox().addItem(self) self.updateLine() self.setZValue(0) def close(self): if self.scene() is not None: self.scene().removeItem(self) def setTarget(self, target): self.target = target self.updateLine() def setStyle(self, **kwds): self.style.update(kwds) if 'shape' in kwds: self.updateLine() else: self.update() def updateLine(self): start = Point(self.source.connectPoint()) if isinstance(self.target, TerminalGraphicsItem): stop = Point(self.target.connectPoint()) elif isinstance(self.target, QtCore.QPointF): stop = Point(self.target) else: return self.prepareGeometryChange() self.path = self.generatePath(start, stop) self.shapePath = None self.update() def generatePath(self, start, stop): path = QtGui.QPainterPath() path.moveTo(start) if self.style['shape'] == 'line': path.lineTo(stop) elif self.style['shape'] == 'cubic': path.cubicTo(Point(stop.x(), start.y()), Point(start.x(), stop.y()), Point(stop.x(), stop.y())) else: raise Exception('Invalid shape "%s"; options are "line" or "cubic"' % self.style['shape']) return path def keyPressEvent(self, ev): if not self.isSelected(): ev.ignore() return if ev.key() == QtCore.Qt.Key_Delete or ev.key() == QtCore.Qt.Key_Backspace: self.source.disconnect(self.target) ev.accept() else: ev.ignore() def mousePressEvent(self, ev): ev.ignore() def mouseClickEvent(self, ev): if ev.button() == QtCore.Qt.LeftButton: ev.accept() sel = self.isSelected() self.setSelected(True) self.setFocus() if not sel and self.isSelected(): self.update() def hoverEvent(self, ev): if (not ev.isExit()) and ev.acceptClicks(QtCore.Qt.LeftButton): self.hovered = True else: self.hovered = False self.update() def boundingRect(self): return self.shape().boundingRect() def viewRangeChanged(self): self.shapePath = None self.prepareGeometryChange() def shape(self): if self.shapePath is None: if self.path is None: return QtGui.QPainterPath() stroker = QtGui.QPainterPathStroker() px = self.pixelWidth() stroker.setWidth(px*8) self.shapePath = stroker.createStroke(self.path) return self.shapePath def paint(self, p, *args): if self.isSelected(): p.setPen(fn.mkPen(self.style['selectedColor'], width=self.style['selectedWidth'])) else: if self.hovered: p.setPen(fn.mkPen(self.style['hoverColor'], width=self.style['hoverWidth'])) else: p.setPen(fn.mkPen(self.style['color'], width=self.style['width'])) p.drawPath(self.path) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/flowchart/__init__.py000066400000000000000000000001611300727121400237400ustar00rootroot00000000000000# -*- coding: utf-8 -*- from .Flowchart import * from .library import getNodeType, registerNodeType, getNodeTreepyqtgraph-pyqtgraph-0.10.0/pyqtgraph/flowchart/library/000077500000000000000000000000001300727121400232755ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/flowchart/library/Data.py000066400000000000000000000307121300727121400245230ustar00rootroot00000000000000# -*- coding: utf-8 -*- from ..Node import Node from ...Qt import QtGui, QtCore import numpy as np from .common import * from ...SRTTransform import SRTTransform from ...Point import Point from ...widgets.TreeWidget import TreeWidget from ...graphicsItems.LinearRegionItem import LinearRegionItem from . import functions class ColumnSelectNode(Node): """Select named columns from a record array or MetaArray.""" nodeName = "ColumnSelect" def __init__(self, name): Node.__init__(self, name, terminals={'In': {'io': 'in'}}) self.columns = set() self.columnList = QtGui.QListWidget() self.axis = 0 self.columnList.itemChanged.connect(self.itemChanged) def process(self, In, display=True): if display: self.updateList(In) out = {} if hasattr(In, 'implements') and In.implements('MetaArray'): for c in self.columns: out[c] = In[self.axis:c] elif isinstance(In, np.ndarray) and In.dtype.fields is not None: for c in self.columns: out[c] = In[c] else: self.In.setValueAcceptable(False) raise Exception("Input must be MetaArray or ndarray with named fields") return out def ctrlWidget(self): return self.columnList def updateList(self, data): if hasattr(data, 'implements') and data.implements('MetaArray'): cols = data.listColumns() for ax in cols: ## find first axis with columns if len(cols[ax]) > 0: self.axis = ax cols = set(cols[ax]) break else: cols = list(data.dtype.fields.keys()) rem = set() for c in self.columns: if c not in cols: self.removeTerminal(c) rem.add(c) self.columns -= rem self.columnList.blockSignals(True) self.columnList.clear() for c in cols: item = QtGui.QListWidgetItem(c) item.setFlags(QtCore.Qt.ItemIsEnabled|QtCore.Qt.ItemIsUserCheckable) if c in self.columns: item.setCheckState(QtCore.Qt.Checked) else: item.setCheckState(QtCore.Qt.Unchecked) self.columnList.addItem(item) self.columnList.blockSignals(False) def itemChanged(self, item): col = str(item.text()) if item.checkState() == QtCore.Qt.Checked: if col not in self.columns: self.columns.add(col) self.addOutput(col) else: if col in self.columns: self.columns.remove(col) self.removeTerminal(col) self.update() def saveState(self): state = Node.saveState(self) state['columns'] = list(self.columns) return state def restoreState(self, state): Node.restoreState(self, state) self.columns = set(state.get('columns', [])) for c in self.columns: self.addOutput(c) class RegionSelectNode(CtrlNode): """Returns a slice from a 1-D array. Connect the 'widget' output to a plot to display a region-selection widget.""" nodeName = "RegionSelect" uiTemplate = [ ('start', 'spin', {'value': 0, 'step': 0.1}), ('stop', 'spin', {'value': 0.1, 'step': 0.1}), ('display', 'check', {'value': True}), ('movable', 'check', {'value': True}), ] def __init__(self, name): self.items = {} CtrlNode.__init__(self, name, terminals={ 'data': {'io': 'in'}, 'selected': {'io': 'out'}, 'region': {'io': 'out'}, 'widget': {'io': 'out', 'multi': True} }) self.ctrls['display'].toggled.connect(self.displayToggled) self.ctrls['movable'].toggled.connect(self.movableToggled) def displayToggled(self, b): for item in self.items.values(): item.setVisible(b) def movableToggled(self, b): for item in self.items.values(): item.setMovable(b) def process(self, data=None, display=True): #print "process.." s = self.stateGroup.state() region = [s['start'], s['stop']] if display: conn = self['widget'].connections() for c in conn: plot = c.node().getPlot() if plot is None: continue if c in self.items: item = self.items[c] item.setRegion(region) #print " set rgn:", c, region #item.setXVals(events) else: item = LinearRegionItem(values=region) self.items[c] = item #item.connect(item, QtCore.SIGNAL('regionChanged'), self.rgnChanged) item.sigRegionChanged.connect(self.rgnChanged) item.setVisible(s['display']) item.setMovable(s['movable']) #print " new rgn:", c, region #self.items[c].setYRange([0., 0.2], relative=True) if self['selected'].isConnected(): if data is None: sliced = None elif (hasattr(data, 'implements') and data.implements('MetaArray')): sliced = data[0:s['start']:s['stop']] else: mask = (data['time'] >= s['start']) * (data['time'] < s['stop']) sliced = data[mask] else: sliced = None return {'selected': sliced, 'widget': self.items, 'region': region} def rgnChanged(self, item): region = item.getRegion() self.stateGroup.setState({'start': region[0], 'stop': region[1]}) self.update() class EvalNode(Node): """Return the output of a string evaluated/executed by the python interpreter. The string may be either an expression or a python script, and inputs are accessed as the name of the terminal. For expressions, a single value may be evaluated for a single output, or a dict for multiple outputs. For a script, the text will be executed as the body of a function.""" nodeName = 'PythonEval' def __init__(self, name): Node.__init__(self, name, terminals = { 'input': {'io': 'in', 'renamable': True, 'multiable': True}, 'output': {'io': 'out', 'renamable': True, 'multiable': True}, }, allowAddInput=True, allowAddOutput=True) self.ui = QtGui.QWidget() self.layout = QtGui.QGridLayout() #self.addInBtn = QtGui.QPushButton('+Input') #self.addOutBtn = QtGui.QPushButton('+Output') self.text = QtGui.QTextEdit() self.text.setTabStopWidth(30) self.text.setPlainText("# Access inputs as args['input_name']\nreturn {'output': None} ## one key per output terminal") #self.layout.addWidget(self.addInBtn, 0, 0) #self.layout.addWidget(self.addOutBtn, 0, 1) self.layout.addWidget(self.text, 1, 0, 1, 2) self.ui.setLayout(self.layout) #QtCore.QObject.connect(self.addInBtn, QtCore.SIGNAL('clicked()'), self.addInput) #self.addInBtn.clicked.connect(self.addInput) #QtCore.QObject.connect(self.addOutBtn, QtCore.SIGNAL('clicked()'), self.addOutput) #self.addOutBtn.clicked.connect(self.addOutput) self.text.focusOutEvent = self.focusOutEvent self.lastText = None def ctrlWidget(self): return self.ui #def addInput(self): #Node.addInput(self, 'input', renamable=True) #def addOutput(self): #Node.addOutput(self, 'output', renamable=True) def focusOutEvent(self, ev): text = str(self.text.toPlainText()) if text != self.lastText: self.lastText = text self.update() return QtGui.QTextEdit.focusOutEvent(self.text, ev) def process(self, display=True, **args): l = locals() l.update(args) ## try eval first, then exec try: text = str(self.text.toPlainText()).replace('\n', ' ') output = eval(text, globals(), l) except SyntaxError: fn = "def fn(**args):\n" run = "\noutput=fn(**args)\n" text = fn + "\n".join([" "+l for l in str(self.text.toPlainText()).split('\n')]) + run exec(text) except: print("Error processing node: %s" % self.name()) raise return output def saveState(self): state = Node.saveState(self) state['text'] = str(self.text.toPlainText()) #state['terminals'] = self.saveTerminals() return state def restoreState(self, state): Node.restoreState(self, state) self.text.clear() self.text.insertPlainText(state['text']) self.restoreTerminals(state['terminals']) self.update() class ColumnJoinNode(Node): """Concatenates record arrays and/or adds new columns""" nodeName = 'ColumnJoin' def __init__(self, name): Node.__init__(self, name, terminals = { 'output': {'io': 'out'}, }) #self.items = [] self.ui = QtGui.QWidget() self.layout = QtGui.QGridLayout() self.ui.setLayout(self.layout) self.tree = TreeWidget() self.addInBtn = QtGui.QPushButton('+ Input') self.remInBtn = QtGui.QPushButton('- Input') self.layout.addWidget(self.tree, 0, 0, 1, 2) self.layout.addWidget(self.addInBtn, 1, 0) self.layout.addWidget(self.remInBtn, 1, 1) self.addInBtn.clicked.connect(self.addInput) self.remInBtn.clicked.connect(self.remInput) self.tree.sigItemMoved.connect(self.update) def ctrlWidget(self): return self.ui def addInput(self): #print "ColumnJoinNode.addInput called." term = Node.addInput(self, 'input', renamable=True, removable=True, multiable=True) #print "Node.addInput returned. term:", term item = QtGui.QTreeWidgetItem([term.name()]) item.term = term term.joinItem = item #self.items.append((term, item)) self.tree.addTopLevelItem(item) def remInput(self): sel = self.tree.currentItem() term = sel.term term.joinItem = None sel.term = None self.tree.removeTopLevelItem(sel) self.removeTerminal(term) self.update() def process(self, display=True, **args): order = self.order() vals = [] for name in order: if name not in args: continue val = args[name] if isinstance(val, np.ndarray) and len(val.dtype) > 0: vals.append(val) else: vals.append((name, None, val)) return {'output': functions.concatenateColumns(vals)} def order(self): return [str(self.tree.topLevelItem(i).text(0)) for i in range(self.tree.topLevelItemCount())] def saveState(self): state = Node.saveState(self) state['order'] = self.order() return state def restoreState(self, state): Node.restoreState(self, state) inputs = self.inputs() ## Node.restoreState should have created all of the terminals we need ## However: to maintain support for some older flowchart files, we need ## to manually add any terminals that were not taken care of. for name in [n for n in state['order'] if n not in inputs]: Node.addInput(self, name, renamable=True, removable=True, multiable=True) inputs = self.inputs() order = [name for name in state['order'] if name in inputs] for name in inputs: if name not in order: order.append(name) self.tree.clear() for name in order: term = self[name] item = QtGui.QTreeWidgetItem([name]) item.term = term term.joinItem = item #self.items.append((term, item)) self.tree.addTopLevelItem(item) def terminalRenamed(self, term, oldName): Node.terminalRenamed(self, term, oldName) item = term.joinItem item.setText(0, term.name()) self.update() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/flowchart/library/Display.py000066400000000000000000000241471300727121400252640ustar00rootroot00000000000000# -*- coding: utf-8 -*- from ..Node import Node import weakref from ...Qt import QtCore, QtGui from ...graphicsItems.ScatterPlotItem import ScatterPlotItem from ...graphicsItems.PlotCurveItem import PlotCurveItem from ... import PlotDataItem, ComboBox from .common import * import numpy as np class PlotWidgetNode(Node): """Connection to PlotWidget. Will plot arrays, metaarrays, and display event lists.""" nodeName = 'PlotWidget' sigPlotChanged = QtCore.Signal(object) def __init__(self, name): Node.__init__(self, name, terminals={'In': {'io': 'in', 'multi': True}}) self.plot = None # currently selected plot self.plots = {} # list of available plots user may select from self.ui = None self.items = {} def disconnected(self, localTerm, remoteTerm): if localTerm is self['In'] and remoteTerm in self.items: self.plot.removeItem(self.items[remoteTerm]) del self.items[remoteTerm] def setPlot(self, plot): #print "======set plot" if plot == self.plot: return # clear data from previous plot if self.plot is not None: for vid in list(self.items.keys()): self.plot.removeItem(self.items[vid]) del self.items[vid] self.plot = plot self.updateUi() self.update() self.sigPlotChanged.emit(self) def getPlot(self): return self.plot def process(self, In, display=True): if display and self.plot is not None: items = set() # Add all new input items to selected plot for name, vals in In.items(): if vals is None: continue if type(vals) is not list: vals = [vals] for val in vals: vid = id(val) if vid in self.items and self.items[vid].scene() is self.plot.scene(): # Item is already added to the correct scene # possible bug: what if two plots occupy the same scene? (should # rarely be a problem because items are removed from a plot before # switching). items.add(vid) else: # Add the item to the plot, or generate a new item if needed. if isinstance(val, QtGui.QGraphicsItem): self.plot.addItem(val) item = val else: item = self.plot.plot(val) self.items[vid] = item items.add(vid) # Any left-over items that did not appear in the input must be removed for vid in list(self.items.keys()): if vid not in items: self.plot.removeItem(self.items[vid]) del self.items[vid] def processBypassed(self, args): if self.plot is None: return for item in list(self.items.values()): self.plot.removeItem(item) self.items = {} def ctrlWidget(self): if self.ui is None: self.ui = ComboBox() self.ui.currentIndexChanged.connect(self.plotSelected) self.updateUi() return self.ui def plotSelected(self, index): self.setPlot(self.ui.value()) def setPlotList(self, plots): """ Specify the set of plots (PlotWidget or PlotItem) that the user may select from. *plots* must be a dictionary of {name: plot} pairs. """ self.plots = plots self.updateUi() def updateUi(self): # sets list and automatically preserves previous selection self.ui.setItems(self.plots) try: self.ui.setValue(self.plot) except ValueError: pass class CanvasNode(Node): """Connection to a Canvas widget.""" nodeName = 'CanvasWidget' def __init__(self, name): Node.__init__(self, name, terminals={'In': {'io': 'in', 'multi': True}}) self.canvas = None self.items = {} def disconnected(self, localTerm, remoteTerm): if localTerm is self.In and remoteTerm in self.items: self.canvas.removeItem(self.items[remoteTerm]) del self.items[remoteTerm] def setCanvas(self, canvas): self.canvas = canvas def getCanvas(self): return self.canvas def process(self, In, display=True): if display: items = set() for name, vals in In.items(): if vals is None: continue if type(vals) is not list: vals = [vals] for val in vals: vid = id(val) if vid in self.items: items.add(vid) else: self.canvas.addItem(val) item = val self.items[vid] = item items.add(vid) for vid in list(self.items.keys()): if vid not in items: #print "remove", self.items[vid] self.canvas.removeItem(self.items[vid]) del self.items[vid] class PlotCurve(CtrlNode): """Generates a plot curve from x/y data""" nodeName = 'PlotCurve' uiTemplate = [ ('color', 'color'), ] def __init__(self, name): CtrlNode.__init__(self, name, terminals={ 'x': {'io': 'in'}, 'y': {'io': 'in'}, 'plot': {'io': 'out'} }) self.item = PlotDataItem() def process(self, x, y, display=True): #print "scatterplot process" if not display: return {'plot': None} self.item.setData(x, y, pen=self.ctrls['color'].color()) return {'plot': self.item} class ScatterPlot(CtrlNode): """Generates a scatter plot from a record array or nested dicts""" nodeName = 'ScatterPlot' uiTemplate = [ ('x', 'combo', {'values': [], 'index': 0}), ('y', 'combo', {'values': [], 'index': 0}), ('sizeEnabled', 'check', {'value': False}), ('size', 'combo', {'values': [], 'index': 0}), ('absoluteSize', 'check', {'value': False}), ('colorEnabled', 'check', {'value': False}), ('color', 'colormap', {}), ('borderEnabled', 'check', {'value': False}), ('border', 'colormap', {}), ] def __init__(self, name): CtrlNode.__init__(self, name, terminals={ 'input': {'io': 'in'}, 'plot': {'io': 'out'} }) self.item = ScatterPlotItem() self.keys = [] #self.ui = QtGui.QWidget() #self.layout = QtGui.QGridLayout() #self.ui.setLayout(self.layout) #self.xCombo = QtGui.QComboBox() #self.yCombo = QtGui.QComboBox() def process(self, input, display=True): #print "scatterplot process" if not display: return {'plot': None} self.updateKeys(input[0]) x = str(self.ctrls['x'].currentText()) y = str(self.ctrls['y'].currentText()) size = str(self.ctrls['size'].currentText()) pen = QtGui.QPen(QtGui.QColor(0,0,0,0)) points = [] for i in input: pt = {'pos': (i[x], i[y])} if self.ctrls['sizeEnabled'].isChecked(): pt['size'] = i[size] if self.ctrls['borderEnabled'].isChecked(): pt['pen'] = QtGui.QPen(self.ctrls['border'].getColor(i)) else: pt['pen'] = pen if self.ctrls['colorEnabled'].isChecked(): pt['brush'] = QtGui.QBrush(self.ctrls['color'].getColor(i)) points.append(pt) self.item.setPxMode(not self.ctrls['absoluteSize'].isChecked()) self.item.setPoints(points) return {'plot': self.item} def updateKeys(self, data): if isinstance(data, dict): keys = list(data.keys()) elif isinstance(data, list) or isinstance(data, tuple): keys = data elif isinstance(data, np.ndarray) or isinstance(data, np.void): keys = data.dtype.names else: print("Unknown data type:", type(data), data) return for c in self.ctrls.values(): c.blockSignals(True) for c in [self.ctrls['x'], self.ctrls['y'], self.ctrls['size']]: cur = str(c.currentText()) c.clear() for k in keys: c.addItem(k) if k == cur: c.setCurrentIndex(c.count()-1) for c in [self.ctrls['color'], self.ctrls['border']]: c.setArgList(keys) for c in self.ctrls.values(): c.blockSignals(False) self.keys = keys def saveState(self): state = CtrlNode.saveState(self) return {'keys': self.keys, 'ctrls': state} def restoreState(self, state): self.updateKeys(state['keys']) CtrlNode.restoreState(self, state['ctrls']) #class ImageItem(Node): #"""Creates an ImageItem for display in a canvas from a file handle.""" #nodeName = 'Image' #def __init__(self, name): #Node.__init__(self, name, terminals={ #'file': {'io': 'in'}, #'image': {'io': 'out'} #}) #self.imageItem = graphicsItems.ImageItem() #self.handle = None #def process(self, file, display=True): #if not display: #return {'image': None} #if file != self.handle: #self.handle = file #data = file.read() #self.imageItem.updateImage(data) #pos = file. pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/flowchart/library/Filters.py000066400000000000000000000324071300727121400252650ustar00rootroot00000000000000# -*- coding: utf-8 -*- import numpy as np from ...Qt import QtCore, QtGui from ..Node import Node from . import functions from ... import functions as pgfn from .common import * from ...python2_3 import xrange from ... import PolyLineROI from ... import Point from ... import metaarray as metaarray class Downsample(CtrlNode): """Downsample by averaging samples together.""" nodeName = 'Downsample' uiTemplate = [ ('n', 'intSpin', {'min': 1, 'max': 1000000}) ] def processData(self, data): return functions.downsample(data, self.ctrls['n'].value(), axis=0) class Subsample(CtrlNode): """Downsample by selecting every Nth sample.""" nodeName = 'Subsample' uiTemplate = [ ('n', 'intSpin', {'min': 1, 'max': 1000000}) ] def processData(self, data): return data[::self.ctrls['n'].value()] class Bessel(CtrlNode): """Bessel filter. Input data must have time values.""" nodeName = 'BesselFilter' uiTemplate = [ ('band', 'combo', {'values': ['lowpass', 'highpass'], 'index': 0}), ('cutoff', 'spin', {'value': 1000., 'step': 1, 'dec': True, 'range': [0.0, None], 'suffix': 'Hz', 'siPrefix': True}), ('order', 'intSpin', {'value': 4, 'min': 1, 'max': 16}), ('bidir', 'check', {'checked': True}) ] def processData(self, data): s = self.stateGroup.state() if s['band'] == 'lowpass': mode = 'low' else: mode = 'high' return functions.besselFilter(data, bidir=s['bidir'], btype=mode, cutoff=s['cutoff'], order=s['order']) class Butterworth(CtrlNode): """Butterworth filter""" nodeName = 'ButterworthFilter' uiTemplate = [ ('band', 'combo', {'values': ['lowpass', 'highpass'], 'index': 0}), ('wPass', 'spin', {'value': 1000., 'step': 1, 'dec': True, 'range': [0.0, None], 'suffix': 'Hz', 'siPrefix': True}), ('wStop', 'spin', {'value': 2000., 'step': 1, 'dec': True, 'range': [0.0, None], 'suffix': 'Hz', 'siPrefix': True}), ('gPass', 'spin', {'value': 2.0, 'step': 1, 'dec': True, 'range': [0.0, None], 'suffix': 'dB', 'siPrefix': True}), ('gStop', 'spin', {'value': 20.0, 'step': 1, 'dec': True, 'range': [0.0, None], 'suffix': 'dB', 'siPrefix': True}), ('bidir', 'check', {'checked': True}) ] def processData(self, data): s = self.stateGroup.state() if s['band'] == 'lowpass': mode = 'low' else: mode = 'high' ret = functions.butterworthFilter(data, bidir=s['bidir'], btype=mode, wPass=s['wPass'], wStop=s['wStop'], gPass=s['gPass'], gStop=s['gStop']) return ret class ButterworthNotch(CtrlNode): """Butterworth notch filter""" nodeName = 'ButterworthNotchFilter' uiTemplate = [ ('low_wPass', 'spin', {'value': 1000., 'step': 1, 'dec': True, 'range': [0.0, None], 'suffix': 'Hz', 'siPrefix': True}), ('low_wStop', 'spin', {'value': 2000., 'step': 1, 'dec': True, 'range': [0.0, None], 'suffix': 'Hz', 'siPrefix': True}), ('low_gPass', 'spin', {'value': 2.0, 'step': 1, 'dec': True, 'range': [0.0, None], 'suffix': 'dB', 'siPrefix': True}), ('low_gStop', 'spin', {'value': 20.0, 'step': 1, 'dec': True, 'range': [0.0, None], 'suffix': 'dB', 'siPrefix': True}), ('high_wPass', 'spin', {'value': 3000., 'step': 1, 'dec': True, 'range': [0.0, None], 'suffix': 'Hz', 'siPrefix': True}), ('high_wStop', 'spin', {'value': 4000., 'step': 1, 'dec': True, 'range': [0.0, None], 'suffix': 'Hz', 'siPrefix': True}), ('high_gPass', 'spin', {'value': 2.0, 'step': 1, 'dec': True, 'range': [0.0, None], 'suffix': 'dB', 'siPrefix': True}), ('high_gStop', 'spin', {'value': 20.0, 'step': 1, 'dec': True, 'range': [0.0, None], 'suffix': 'dB', 'siPrefix': True}), ('bidir', 'check', {'checked': True}) ] def processData(self, data): s = self.stateGroup.state() low = functions.butterworthFilter(data, bidir=s['bidir'], btype='low', wPass=s['low_wPass'], wStop=s['low_wStop'], gPass=s['low_gPass'], gStop=s['low_gStop']) high = functions.butterworthFilter(data, bidir=s['bidir'], btype='high', wPass=s['high_wPass'], wStop=s['high_wStop'], gPass=s['high_gPass'], gStop=s['high_gStop']) return low + high class Mean(CtrlNode): """Filters data by taking the mean of a sliding window""" nodeName = 'MeanFilter' uiTemplate = [ ('n', 'intSpin', {'min': 1, 'max': 1000000}) ] @metaArrayWrapper def processData(self, data): n = self.ctrls['n'].value() return functions.rollingSum(data, n) / n class Median(CtrlNode): """Filters data by taking the median of a sliding window""" nodeName = 'MedianFilter' uiTemplate = [ ('n', 'intSpin', {'min': 1, 'max': 1000000}) ] @metaArrayWrapper def processData(self, data): try: import scipy.ndimage except ImportError: raise Exception("MedianFilter node requires the package scipy.ndimage.") return scipy.ndimage.median_filter(data, self.ctrls['n'].value()) class Mode(CtrlNode): """Filters data by taking the mode (histogram-based) of a sliding window""" nodeName = 'ModeFilter' uiTemplate = [ ('window', 'intSpin', {'value': 500, 'min': 1, 'max': 1000000}), ] @metaArrayWrapper def processData(self, data): return functions.modeFilter(data, self.ctrls['window'].value()) class Denoise(CtrlNode): """Removes anomalous spikes from data, replacing with nearby values""" nodeName = 'DenoiseFilter' uiTemplate = [ ('radius', 'intSpin', {'value': 2, 'min': 0, 'max': 1000000}), ('threshold', 'doubleSpin', {'value': 4.0, 'min': 0, 'max': 1000}) ] def processData(self, data): #print "DENOISE" s = self.stateGroup.state() return functions.denoise(data, **s) class Gaussian(CtrlNode): """Gaussian smoothing filter.""" nodeName = 'GaussianFilter' uiTemplate = [ ('sigma', 'doubleSpin', {'min': 0, 'max': 1000000}) ] @metaArrayWrapper def processData(self, data): try: import scipy.ndimage except ImportError: raise Exception("GaussianFilter node requires the package scipy.ndimage.") if hasattr(data, 'implements') and data.implements('MetaArray'): info = data.infoCopy() filt = pgfn.gaussianFilter(data.asarray(), self.ctrls['sigma'].value()) if 'values' in info[0]: info[0]['values'] = info[0]['values'][:filt.shape[0]] return metaarray.MetaArray(filt, info=info) else: return pgfn.gaussianFilter(data, self.ctrls['sigma'].value()) class Derivative(CtrlNode): """Returns the pointwise derivative of the input""" nodeName = 'DerivativeFilter' def processData(self, data): if hasattr(data, 'implements') and data.implements('MetaArray'): info = data.infoCopy() if 'values' in info[0]: info[0]['values'] = info[0]['values'][:-1] return metaarray.MetaArray(data[1:] - data[:-1], info=info) else: return data[1:] - data[:-1] class Integral(CtrlNode): """Returns the pointwise integral of the input""" nodeName = 'IntegralFilter' @metaArrayWrapper def processData(self, data): data[1:] += data[:-1] return data class Detrend(CtrlNode): """Removes linear trend from the data""" nodeName = 'DetrendFilter' @metaArrayWrapper def processData(self, data): try: from scipy.signal import detrend except ImportError: raise Exception("DetrendFilter node requires the package scipy.signal.") return detrend(data) class RemoveBaseline(PlottingCtrlNode): """Remove an arbitrary, graphically defined baseline from the data.""" nodeName = 'RemoveBaseline' def __init__(self, name): ## define inputs and outputs (one output needs to be a plot) PlottingCtrlNode.__init__(self, name) self.line = PolyLineROI([[0,0],[1,0]]) self.line.sigRegionChanged.connect(self.changed) ## create a PolyLineROI, add it to a plot -- actually, I think we want to do this after the node is connected to a plot (look at EventDetection.ThresholdEvents node for ideas), and possible after there is data. We will need to update the end positions of the line each time the input data changes #self.line = None ## will become a PolyLineROI def connectToPlot(self, node): """Define what happens when the node is connected to a plot""" if node.plot is None: return node.getPlot().addItem(self.line) def disconnectFromPlot(self, plot): """Define what happens when the node is disconnected from a plot""" plot.removeItem(self.line) def processData(self, data): ## get array of baseline (from PolyLineROI) h0 = self.line.getHandles()[0] h1 = self.line.getHandles()[-1] timeVals = data.xvals(0) h0.setPos(timeVals[0], h0.pos()[1]) h1.setPos(timeVals[-1], h1.pos()[1]) pts = self.line.listPoints() ## lists line handles in same coordinates as data pts, indices = self.adjustXPositions(pts, timeVals) ## maxe sure x positions match x positions of data points ## construct an array that represents the baseline arr = np.zeros(len(data), dtype=float) n = 1 arr[0] = pts[0].y() for i in range(len(pts)-1): x1 = pts[i].x() x2 = pts[i+1].x() y1 = pts[i].y() y2 = pts[i+1].y() m = (y2-y1)/(x2-x1) b = y1 times = timeVals[(timeVals > x1)*(timeVals <= x2)] arr[n:n+len(times)] = (m*(times-times[0]))+b n += len(times) return data - arr ## subract baseline from data def adjustXPositions(self, pts, data): """Return a list of Point() where the x position is set to the nearest x value in *data* for each point in *pts*.""" points = [] timeIndices = [] for p in pts: x = np.argwhere(abs(data - p.x()) == abs(data - p.x()).min()) points.append(Point(data[x], p.y())) timeIndices.append(x) return points, timeIndices class AdaptiveDetrend(CtrlNode): """Removes baseline from data, ignoring anomalous events""" nodeName = 'AdaptiveDetrend' uiTemplate = [ ('threshold', 'doubleSpin', {'value': 3.0, 'min': 0, 'max': 1000000}) ] def processData(self, data): return functions.adaptiveDetrend(data, threshold=self.ctrls['threshold'].value()) class HistogramDetrend(CtrlNode): """Removes baseline from data by computing mode (from histogram) of beginning and end of data.""" nodeName = 'HistogramDetrend' uiTemplate = [ ('windowSize', 'intSpin', {'value': 500, 'min': 10, 'max': 1000000, 'suffix': 'pts'}), ('numBins', 'intSpin', {'value': 50, 'min': 3, 'max': 1000000}), ('offsetOnly', 'check', {'checked': False}), ] def processData(self, data): s = self.stateGroup.state() #ws = self.ctrls['windowSize'].value() #bn = self.ctrls['numBins'].value() #offset = self.ctrls['offsetOnly'].checked() return functions.histogramDetrend(data, window=s['windowSize'], bins=s['numBins'], offsetOnly=s['offsetOnly']) class RemovePeriodic(CtrlNode): nodeName = 'RemovePeriodic' uiTemplate = [ #('windowSize', 'intSpin', {'value': 500, 'min': 10, 'max': 1000000, 'suffix': 'pts'}), #('numBins', 'intSpin', {'value': 50, 'min': 3, 'max': 1000000}) ('f0', 'spin', {'value': 60, 'suffix': 'Hz', 'siPrefix': True, 'min': 0, 'max': None}), ('harmonics', 'intSpin', {'value': 30, 'min': 0}), ('samples', 'intSpin', {'value': 1, 'min': 1}), ] def processData(self, data): times = data.xvals('Time') dt = times[1]-times[0] data1 = data.asarray() ft = np.fft.fft(data1) ## determine frequencies in fft data df = 1.0 / (len(data1) * dt) freqs = np.linspace(0.0, (len(ft)-1) * df, len(ft)) ## flatten spikes at f0 and harmonics f0 = self.ctrls['f0'].value() for i in xrange(1, self.ctrls['harmonics'].value()+2): f = f0 * i # target frequency ## determine index range to check for this frequency ind1 = int(np.floor(f / df)) ind2 = int(np.ceil(f / df)) + (self.ctrls['samples'].value()-1) if ind1 > len(ft)/2.: break mag = (abs(ft[ind1-1]) + abs(ft[ind2+1])) * 0.5 for j in range(ind1, ind2+1): phase = np.angle(ft[j]) ## Must preserve the phase of each point, otherwise any transients in the trace might lead to large artifacts. re = mag * np.cos(phase) im = mag * np.sin(phase) ft[j] = re + im*1j ft[len(ft)-j] = re - im*1j data2 = np.fft.ifft(ft).real ma = metaarray.MetaArray(data2, info=data.infoCopy()) return ma pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/flowchart/library/Operators.py000066400000000000000000000044341300727121400256320ustar00rootroot00000000000000# -*- coding: utf-8 -*- from ..Node import Node class UniOpNode(Node): """Generic node for performing any operation like Out = In.fn()""" def __init__(self, name, fn): self.fn = fn Node.__init__(self, name, terminals={ 'In': {'io': 'in'}, 'Out': {'io': 'out', 'bypass': 'In'} }) def process(self, **args): return {'Out': getattr(args['In'], self.fn)()} class BinOpNode(Node): """Generic node for performing any operation like A.fn(B)""" def __init__(self, name, fn): self.fn = fn Node.__init__(self, name, terminals={ 'A': {'io': 'in'}, 'B': {'io': 'in'}, 'Out': {'io': 'out', 'bypass': 'A'} }) def process(self, **args): if isinstance(self.fn, tuple): for name in self.fn: try: fn = getattr(args['A'], name) break except AttributeError: pass else: fn = getattr(args['A'], self.fn) out = fn(args['B']) if out is NotImplemented: raise Exception("Operation %s not implemented between %s and %s" % (fn, str(type(args['A'])), str(type(args['B'])))) #print " ", fn, out return {'Out': out} class AbsNode(UniOpNode): """Returns abs(Inp). Does not check input types.""" nodeName = 'Abs' def __init__(self, name): UniOpNode.__init__(self, name, '__abs__') class AddNode(BinOpNode): """Returns A + B. Does not check input types.""" nodeName = 'Add' def __init__(self, name): BinOpNode.__init__(self, name, '__add__') class SubtractNode(BinOpNode): """Returns A - B. Does not check input types.""" nodeName = 'Subtract' def __init__(self, name): BinOpNode.__init__(self, name, '__sub__') class MultiplyNode(BinOpNode): """Returns A * B. Does not check input types.""" nodeName = 'Multiply' def __init__(self, name): BinOpNode.__init__(self, name, '__mul__') class DivideNode(BinOpNode): """Returns A / B. Does not check input types.""" nodeName = 'Divide' def __init__(self, name): # try truediv first, followed by div BinOpNode.__init__(self, name, ('__truediv__', '__div__')) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/flowchart/library/__init__.py000066400000000000000000000014541300727121400254120ustar00rootroot00000000000000# -*- coding: utf-8 -*- from ...pgcollections import OrderedDict import os, types from ...debug import printExc from ..NodeLibrary import NodeLibrary, isNodeClass from ... import reload as reload # Build default library LIBRARY = NodeLibrary() # For backward compatibility, expose the default library's properties here: NODE_LIST = LIBRARY.nodeList NODE_TREE = LIBRARY.nodeTree registerNodeType = LIBRARY.addNodeType getNodeTree = LIBRARY.getNodeTree getNodeType = LIBRARY.getNodeType # Add all nodes to the default library from . import Data, Display, Filters, Operators for mod in [Data, Display, Filters, Operators]: nodes = [getattr(mod, name) for name in dir(mod) if isNodeClass(getattr(mod, name))] for node in nodes: LIBRARY.addNodeType(node, [(mod.__name__.split('.')[-1],)]) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/flowchart/library/common.py000066400000000000000000000133101300727121400251350ustar00rootroot00000000000000# -*- coding: utf-8 -*- from ...Qt import QtCore, QtGui from ...widgets.SpinBox import SpinBox #from ...SignalProxy import SignalProxy from ...WidgetGroup import WidgetGroup #from ColorMapper import ColorMapper from ..Node import Node import numpy as np from ...widgets.ColorButton import ColorButton try: import metaarray HAVE_METAARRAY = True except: HAVE_METAARRAY = False def generateUi(opts): """Convenience function for generating common UI types""" widget = QtGui.QWidget() l = QtGui.QFormLayout() l.setSpacing(0) widget.setLayout(l) ctrls = {} row = 0 for opt in opts: if len(opt) == 2: k, t = opt o = {} elif len(opt) == 3: k, t, o = opt else: raise Exception("Widget specification must be (name, type) or (name, type, {opts})") if t == 'intSpin': w = QtGui.QSpinBox() if 'max' in o: w.setMaximum(o['max']) if 'min' in o: w.setMinimum(o['min']) if 'value' in o: w.setValue(o['value']) elif t == 'doubleSpin': w = QtGui.QDoubleSpinBox() if 'max' in o: w.setMaximum(o['max']) if 'min' in o: w.setMinimum(o['min']) if 'value' in o: w.setValue(o['value']) elif t == 'spin': w = SpinBox() w.setOpts(**o) elif t == 'check': w = QtGui.QCheckBox() if 'checked' in o: w.setChecked(o['checked']) elif t == 'combo': w = QtGui.QComboBox() for i in o['values']: w.addItem(i) #elif t == 'colormap': #w = ColorMapper() elif t == 'color': w = ColorButton() else: raise Exception("Unknown widget type '%s'" % str(t)) if 'tip' in o: w.setToolTip(o['tip']) w.setObjectName(k) l.addRow(k, w) if o.get('hidden', False): w.hide() label = l.labelForField(w) label.hide() ctrls[k] = w w.rowNum = row row += 1 group = WidgetGroup(widget) return widget, group, ctrls class CtrlNode(Node): """Abstract class for nodes with auto-generated control UI""" sigStateChanged = QtCore.Signal(object) def __init__(self, name, ui=None, terminals=None): if ui is None: if hasattr(self, 'uiTemplate'): ui = self.uiTemplate else: ui = [] if terminals is None: terminals = {'In': {'io': 'in'}, 'Out': {'io': 'out', 'bypass': 'In'}} Node.__init__(self, name=name, terminals=terminals) self.ui, self.stateGroup, self.ctrls = generateUi(ui) self.stateGroup.sigChanged.connect(self.changed) def ctrlWidget(self): return self.ui def changed(self): self.update() self.sigStateChanged.emit(self) def process(self, In, display=True): out = self.processData(In) return {'Out': out} def saveState(self): state = Node.saveState(self) state['ctrl'] = self.stateGroup.state() return state def restoreState(self, state): Node.restoreState(self, state) if self.stateGroup is not None: self.stateGroup.setState(state.get('ctrl', {})) def hideRow(self, name): w = self.ctrls[name] l = self.ui.layout().labelForField(w) w.hide() l.hide() def showRow(self, name): w = self.ctrls[name] l = self.ui.layout().labelForField(w) w.show() l.show() class PlottingCtrlNode(CtrlNode): """Abstract class for CtrlNodes that can connect to plots.""" def __init__(self, name, ui=None, terminals=None): #print "PlottingCtrlNode.__init__ called." CtrlNode.__init__(self, name, ui=ui, terminals=terminals) self.plotTerminal = self.addOutput('plot', optional=True) def connected(self, term, remote): CtrlNode.connected(self, term, remote) if term is not self.plotTerminal: return node = remote.node() node.sigPlotChanged.connect(self.connectToPlot) self.connectToPlot(node) def disconnected(self, term, remote): CtrlNode.disconnected(self, term, remote) if term is not self.plotTerminal: return remote.node().sigPlotChanged.disconnect(self.connectToPlot) self.disconnectFromPlot(remote.node().getPlot()) def connectToPlot(self, node): """Define what happens when the node is connected to a plot""" raise Exception("Must be re-implemented in subclass") def disconnectFromPlot(self, plot): """Define what happens when the node is disconnected from a plot""" raise Exception("Must be re-implemented in subclass") def process(self, In, display=True): out = CtrlNode.process(self, In, display) out['plot'] = None return out def metaArrayWrapper(fn): def newFn(self, data, *args, **kargs): if HAVE_METAARRAY and (hasattr(data, 'implements') and data.implements('MetaArray')): d1 = fn(self, data.view(np.ndarray), *args, **kargs) info = data.infoCopy() if d1.shape != data.shape: for i in range(data.ndim): if 'values' in info[i]: info[i]['values'] = info[i]['values'][:d1.shape[i]] return metaarray.MetaArray(d1, info=info) else: return fn(self, data, *args, **kargs) return newFn pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/flowchart/library/functions.py000066400000000000000000000267661300727121400257000ustar00rootroot00000000000000import numpy as np from ...metaarray import MetaArray from ...python2_3 import basestring, xrange def downsample(data, n, axis=0, xvals='subsample'): """Downsample by averaging points together across axis. If multiple axes are specified, runs once per axis. If a metaArray is given, then the axis values can be either subsampled or downsampled to match. """ ma = None if (hasattr(data, 'implements') and data.implements('MetaArray')): ma = data data = data.view(np.ndarray) if hasattr(axis, '__len__'): if not hasattr(n, '__len__'): n = [n]*len(axis) for i in range(len(axis)): data = downsample(data, n[i], axis[i]) return data nPts = int(data.shape[axis] / n) s = list(data.shape) s[axis] = nPts s.insert(axis+1, n) sl = [slice(None)] * data.ndim sl[axis] = slice(0, nPts*n) d1 = data[tuple(sl)] #print d1.shape, s d1.shape = tuple(s) d2 = d1.mean(axis+1) if ma is None: return d2 else: info = ma.infoCopy() if 'values' in info[axis]: if xvals == 'subsample': info[axis]['values'] = info[axis]['values'][::n][:nPts] elif xvals == 'downsample': info[axis]['values'] = downsample(info[axis]['values'], n) return MetaArray(d2, info=info) def applyFilter(data, b, a, padding=100, bidir=True): """Apply a linear filter with coefficients a, b. Optionally pad the data before filtering and/or run the filter in both directions.""" try: import scipy.signal except ImportError: raise Exception("applyFilter() requires the package scipy.signal.") d1 = data.view(np.ndarray) if padding > 0: d1 = np.hstack([d1[:padding], d1, d1[-padding:]]) if bidir: d1 = scipy.signal.lfilter(b, a, scipy.signal.lfilter(b, a, d1)[::-1])[::-1] else: d1 = scipy.signal.lfilter(b, a, d1) if padding > 0: d1 = d1[padding:-padding] if (hasattr(data, 'implements') and data.implements('MetaArray')): return MetaArray(d1, info=data.infoCopy()) else: return d1 def besselFilter(data, cutoff, order=1, dt=None, btype='low', bidir=True): """return data passed through bessel filter""" try: import scipy.signal except ImportError: raise Exception("besselFilter() requires the package scipy.signal.") if dt is None: try: tvals = data.xvals('Time') dt = (tvals[-1]-tvals[0]) / (len(tvals)-1) except: dt = 1.0 b,a = scipy.signal.bessel(order, cutoff * dt, btype=btype) return applyFilter(data, b, a, bidir=bidir) #base = data.mean() #d1 = scipy.signal.lfilter(b, a, data.view(ndarray)-base) + base #if (hasattr(data, 'implements') and data.implements('MetaArray')): #return MetaArray(d1, info=data.infoCopy()) #return d1 def butterworthFilter(data, wPass, wStop=None, gPass=2.0, gStop=20.0, order=1, dt=None, btype='low', bidir=True): """return data passed through bessel filter""" try: import scipy.signal except ImportError: raise Exception("butterworthFilter() requires the package scipy.signal.") if dt is None: try: tvals = data.xvals('Time') dt = (tvals[-1]-tvals[0]) / (len(tvals)-1) except: dt = 1.0 if wStop is None: wStop = wPass * 2.0 ord, Wn = scipy.signal.buttord(wPass*dt*2., wStop*dt*2., gPass, gStop) #print "butterworth ord %f Wn %f c %f sc %f" % (ord, Wn, cutoff, stopCutoff) b,a = scipy.signal.butter(ord, Wn, btype=btype) return applyFilter(data, b, a, bidir=bidir) def rollingSum(data, n): d1 = data.copy() d1[1:] += d1[:-1] # integrate d2 = np.empty(len(d1) - n + 1, dtype=data.dtype) d2[0] = d1[n-1] # copy first point d2[1:] = d1[n:] - d1[:-n] # subtract return d2 def mode(data, bins=None): """Returns location max value from histogram.""" if bins is None: bins = int(len(data)/10.) if bins < 2: bins = 2 y, x = np.histogram(data, bins=bins) ind = np.argmax(y) mode = 0.5 * (x[ind] + x[ind+1]) return mode def modeFilter(data, window=500, step=None, bins=None): """Filter based on histogram-based mode function""" d1 = data.view(np.ndarray) vals = [] l2 = int(window/2.) if step is None: step = l2 i = 0 while True: if i > len(data)-step: break vals.append(mode(d1[i:i+window], bins)) i += step chunks = [np.linspace(vals[0], vals[0], l2)] for i in range(len(vals)-1): chunks.append(np.linspace(vals[i], vals[i+1], step)) remain = len(data) - step*(len(vals)-1) - l2 chunks.append(np.linspace(vals[-1], vals[-1], remain)) d2 = np.hstack(chunks) if (hasattr(data, 'implements') and data.implements('MetaArray')): return MetaArray(d2, info=data.infoCopy()) return d2 def denoise(data, radius=2, threshold=4): """Very simple noise removal function. Compares a point to surrounding points, replaces with nearby values if the difference is too large.""" r2 = radius * 2 d1 = data.view(np.ndarray) d2 = d1[radius:] - d1[:-radius] #a derivative #d3 = data[r2:] - data[:-r2] #d4 = d2 - d3 stdev = d2.std() #print "denoise: stdev of derivative:", stdev mask1 = d2 > stdev*threshold #where derivative is large and positive mask2 = d2 < -stdev*threshold #where derivative is large and negative maskpos = mask1[:-radius] * mask2[radius:] #both need to be true maskneg = mask1[radius:] * mask2[:-radius] mask = maskpos + maskneg d5 = np.where(mask, d1[:-r2], d1[radius:-radius]) #where both are true replace the value with the value from 2 points before d6 = np.empty(d1.shape, dtype=d1.dtype) #add points back to the ends d6[radius:-radius] = d5 d6[:radius] = d1[:radius] d6[-radius:] = d1[-radius:] if (hasattr(data, 'implements') and data.implements('MetaArray')): return MetaArray(d6, info=data.infoCopy()) return d6 def adaptiveDetrend(data, x=None, threshold=3.0): """Return the signal with baseline removed. Discards outliers from baseline measurement.""" try: import scipy.signal except ImportError: raise Exception("adaptiveDetrend() requires the package scipy.signal.") if x is None: x = data.xvals(0) d = data.view(np.ndarray) d2 = scipy.signal.detrend(d) stdev = d2.std() mask = abs(d2) < stdev*threshold #d3 = where(mask, 0, d2) #d4 = d2 - lowPass(d3, cutoffs[1], dt=dt) lr = scipy.stats.linregress(x[mask], d[mask]) base = lr[1] + lr[0]*x d4 = d - base if (hasattr(data, 'implements') and data.implements('MetaArray')): return MetaArray(d4, info=data.infoCopy()) return d4 def histogramDetrend(data, window=500, bins=50, threshold=3.0, offsetOnly=False): """Linear detrend. Works by finding the most common value at the beginning and end of a trace, excluding outliers. If offsetOnly is True, then only the offset from the beginning of the trace is subtracted. """ d1 = data.view(np.ndarray) d2 = [d1[:window], d1[-window:]] v = [0, 0] for i in [0, 1]: d3 = d2[i] stdev = d3.std() mask = abs(d3-np.median(d3)) < stdev*threshold d4 = d3[mask] y, x = np.histogram(d4, bins=bins) ind = np.argmax(y) v[i] = 0.5 * (x[ind] + x[ind+1]) if offsetOnly: d3 = data.view(np.ndarray) - v[0] else: base = np.linspace(v[0], v[1], len(data)) d3 = data.view(np.ndarray) - base if (hasattr(data, 'implements') and data.implements('MetaArray')): return MetaArray(d3, info=data.infoCopy()) return d3 def concatenateColumns(data): """Returns a single record array with columns taken from the elements in data. data should be a list of elements, which can be either record arrays or tuples (name, type, data) """ ## first determine dtype dtype = [] names = set() maxLen = 0 for element in data: if isinstance(element, np.ndarray): ## use existing columns for i in range(len(element.dtype)): name = element.dtype.names[i] dtype.append((name, element.dtype[i])) maxLen = max(maxLen, len(element)) else: name, type, d = element if type is None: type = suggestDType(d) dtype.append((name, type)) if isinstance(d, list) or isinstance(d, np.ndarray): maxLen = max(maxLen, len(d)) if name in names: raise Exception('Name "%s" repeated' % name) names.add(name) ## create empty array out = np.empty(maxLen, dtype) ## fill columns for element in data: if isinstance(element, np.ndarray): for i in range(len(element.dtype)): name = element.dtype.names[i] try: out[name] = element[name] except: print("Column:", name) print("Input shape:", element.shape, element.dtype) print("Output shape:", out.shape, out.dtype) raise else: name, type, d = element out[name] = d return out def suggestDType(x): """Return a suitable dtype for x""" if isinstance(x, list) or isinstance(x, tuple): if len(x) == 0: raise Exception('can not determine dtype for empty list') x = x[0] if hasattr(x, 'dtype'): return x.dtype elif isinstance(x, float): return float elif isinstance(x, int): return int #elif isinstance(x, basestring): ## don't try to guess correct string length; use object instead. #return ' len(ft)/2.: break mag = (abs(ft[ind1-1]) + abs(ft[ind2+1])) * 0.5 for j in range(ind1, ind2+1): phase = np.angle(ft[j]) ## Must preserve the phase of each point, otherwise any transients in the trace might lead to large artifacts. re = mag * np.cos(phase) im = mag * np.sin(phase) ft[j] = re + im*1j ft[len(ft)-j] = re - im*1j data2 = np.fft.ifft(ft).real if (hasattr(data, 'implements') and data.implements('MetaArray')): return metaarray.MetaArray(data2, info=data.infoCopy()) else: return data2 pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/frozenSupport.py000066400000000000000000000034461300727121400231210ustar00rootroot00000000000000## Definitions helpful in frozen environments (eg py2exe) import os, sys, zipfile def listdir(path): """Replacement for os.listdir that works in frozen environments.""" if not hasattr(sys, 'frozen'): return os.listdir(path) (zipPath, archivePath) = splitZip(path) if archivePath is None: return os.listdir(path) with zipfile.ZipFile(zipPath, "r") as zipobj: contents = zipobj.namelist() results = set() for name in contents: # components in zip archive paths are always separated by forward slash if name.startswith(archivePath) and len(name) > len(archivePath): name = name[len(archivePath):].split('/')[0] results.add(name) return list(results) def isdir(path): """Replacement for os.path.isdir that works in frozen environments.""" if not hasattr(sys, 'frozen'): return os.path.isdir(path) (zipPath, archivePath) = splitZip(path) if archivePath is None: return os.path.isdir(path) with zipfile.ZipFile(zipPath, "r") as zipobj: contents = zipobj.namelist() archivePath = archivePath.rstrip('/') + '/' ## make sure there's exactly one '/' at the end for c in contents: if c.startswith(archivePath): return True return False def splitZip(path): """Splits a path containing a zip file into (zipfile, subpath). If there is no zip file, returns (path, None)""" components = os.path.normpath(path).split(os.sep) for index, component in enumerate(components): if component.endswith('.zip'): zipPath = os.sep.join(components[0:index+1]) archivePath = ''.join([x+'/' for x in components[index+1:]]) return (zipPath, archivePath) else: return (path, None) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/functions.py000066400000000000000000002544721300727121400222400ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ functions.py - Miscellaneous functions with no other home Copyright 2010 Luke Campagnola Distributed under MIT/X11 license. See license.txt for more infomation. """ from __future__ import division import warnings import numpy as np import decimal, re import ctypes import sys, struct from .python2_3 import asUnicode, basestring from .Qt import QtGui, QtCore, USE_PYSIDE from . import getConfigOption, setConfigOptions from . import debug Colors = { 'b': QtGui.QColor(0,0,255,255), 'g': QtGui.QColor(0,255,0,255), 'r': QtGui.QColor(255,0,0,255), 'c': QtGui.QColor(0,255,255,255), 'm': QtGui.QColor(255,0,255,255), 'y': QtGui.QColor(255,255,0,255), 'k': QtGui.QColor(0,0,0,255), 'w': QtGui.QColor(255,255,255,255), 'd': QtGui.QColor(150,150,150,255), 'l': QtGui.QColor(200,200,200,255), 's': QtGui.QColor(100,100,150,255), } SI_PREFIXES = asUnicode('yzafpnµm kMGTPEZY') SI_PREFIXES_ASCII = 'yzafpnum kMGTPEZY' def siScale(x, minVal=1e-25, allowUnicode=True): """ Return the recommended scale factor and SI prefix string for x. Example:: siScale(0.0001) # returns (1e6, 'μ') # This indicates that the number 0.0001 is best represented as 0.0001 * 1e6 = 100 μUnits """ if isinstance(x, decimal.Decimal): x = float(x) try: if np.isnan(x) or np.isinf(x): return(1, '') except: print(x, type(x)) raise if abs(x) < minVal: m = 0 x = 0 else: m = int(np.clip(np.floor(np.log(abs(x))/np.log(1000)), -9.0, 9.0)) if m == 0: pref = '' elif m < -8 or m > 8: pref = 'e%d' % (m*3) else: if allowUnicode: pref = SI_PREFIXES[m+8] else: pref = SI_PREFIXES_ASCII[m+8] p = .001**m return (p, pref) def siFormat(x, precision=3, suffix='', space=True, error=None, minVal=1e-25, allowUnicode=True): """ Return the number x formatted in engineering notation with SI prefix. Example:: siFormat(0.0001, suffix='V') # returns "100 μV" """ if space is True: space = ' ' if space is False: space = '' (p, pref) = siScale(x, minVal, allowUnicode) if not (len(pref) > 0 and pref[0] == 'e'): pref = space + pref if error is None: fmt = "%." + str(precision) + "g%s%s" return fmt % (x*p, pref, suffix) else: if allowUnicode: plusminus = space + asUnicode("±") + space else: plusminus = " +/- " fmt = "%." + str(precision) + "g%s%s%s%s" return fmt % (x*p, pref, suffix, plusminus, siFormat(error, precision=precision, suffix=suffix, space=space, minVal=minVal)) def siEval(s): """ Convert a value written in SI notation to its equivalent prefixless value Example:: siEval("100 μV") # returns 0.0001 """ s = asUnicode(s) m = re.match(r'(-?((\d+(\.\d*)?)|(\.\d+))([eE]-?\d+)?)\s*([u' + SI_PREFIXES + r']?).*$', s) if m is None: raise Exception("Can't convert string '%s' to number." % s) v = float(m.groups()[0]) p = m.groups()[6] #if p not in SI_PREFIXES: #raise Exception("Can't convert string '%s' to number--unknown prefix." % s) if p == '': n = 0 elif p == 'u': n = -2 else: n = SI_PREFIXES.index(p) - 8 return v * 1000**n class Color(QtGui.QColor): def __init__(self, *args): QtGui.QColor.__init__(self, mkColor(*args)) def glColor(self): """Return (r,g,b,a) normalized for use in opengl""" return (self.red()/255., self.green()/255., self.blue()/255., self.alpha()/255.) def __getitem__(self, ind): return (self.red, self.green, self.blue, self.alpha)[ind]() def mkColor(*args): """ Convenience function for constructing QColor from a variety of argument types. Accepted arguments are: ================ ================================================ 'c' one of: r, g, b, c, m, y, k, w R, G, B, [A] integers 0-255 (R, G, B, [A]) tuple of integers 0-255 float greyscale, 0.0-1.0 int see :func:`intColor() ` (int, hues) see :func:`intColor() ` "RGB" hexadecimal strings; may begin with '#' "RGBA" "RRGGBB" "RRGGBBAA" QColor QColor instance; makes a copy. ================ ================================================ """ err = 'Not sure how to make a color from "%s"' % str(args) if len(args) == 1: if isinstance(args[0], basestring): c = args[0] if c[0] == '#': c = c[1:] if len(c) == 1: try: return Colors[c] except KeyError: raise Exception('No color named "%s"' % c) if len(c) == 3: r = int(c[0]*2, 16) g = int(c[1]*2, 16) b = int(c[2]*2, 16) a = 255 elif len(c) == 4: r = int(c[0]*2, 16) g = int(c[1]*2, 16) b = int(c[2]*2, 16) a = int(c[3]*2, 16) elif len(c) == 6: r = int(c[0:2], 16) g = int(c[2:4], 16) b = int(c[4:6], 16) a = 255 elif len(c) == 8: r = int(c[0:2], 16) g = int(c[2:4], 16) b = int(c[4:6], 16) a = int(c[6:8], 16) elif isinstance(args[0], QtGui.QColor): return QtGui.QColor(args[0]) elif isinstance(args[0], float): r = g = b = int(args[0] * 255) a = 255 elif hasattr(args[0], '__len__'): if len(args[0]) == 3: (r, g, b) = args[0] a = 255 elif len(args[0]) == 4: (r, g, b, a) = args[0] elif len(args[0]) == 2: return intColor(*args[0]) else: raise Exception(err) elif type(args[0]) == int: return intColor(args[0]) else: raise Exception(err) elif len(args) == 3: (r, g, b) = args a = 255 elif len(args) == 4: (r, g, b, a) = args else: raise Exception(err) args = [r,g,b,a] args = [0 if np.isnan(a) or np.isinf(a) else a for a in args] args = list(map(int, args)) return QtGui.QColor(*args) def mkBrush(*args, **kwds): """ | Convenience function for constructing Brush. | This function always constructs a solid brush and accepts the same arguments as :func:`mkColor() ` | Calling mkBrush(None) returns an invisible brush. """ if 'color' in kwds: color = kwds['color'] elif len(args) == 1: arg = args[0] if arg is None: return QtGui.QBrush(QtCore.Qt.NoBrush) elif isinstance(arg, QtGui.QBrush): return QtGui.QBrush(arg) else: color = arg elif len(args) > 1: color = args return QtGui.QBrush(mkColor(color)) def mkPen(*args, **kargs): """ Convenience function for constructing QPen. Examples:: mkPen(color) mkPen(color, width=2) mkPen(cosmetic=False, width=4.5, color='r') mkPen({'color': "FF0", width: 2}) mkPen(None) # (no pen) In these examples, *color* may be replaced with any arguments accepted by :func:`mkColor() ` """ color = kargs.get('color', None) width = kargs.get('width', 1) style = kargs.get('style', None) dash = kargs.get('dash', None) cosmetic = kargs.get('cosmetic', True) hsv = kargs.get('hsv', None) if len(args) == 1: arg = args[0] if isinstance(arg, dict): return mkPen(**arg) if isinstance(arg, QtGui.QPen): return QtGui.QPen(arg) ## return a copy of this pen elif arg is None: style = QtCore.Qt.NoPen else: color = arg if len(args) > 1: color = args if color is None: color = mkColor('l') if hsv is not None: color = hsvColor(*hsv) else: color = mkColor(color) pen = QtGui.QPen(QtGui.QBrush(color), width) pen.setCosmetic(cosmetic) if style is not None: pen.setStyle(style) if dash is not None: pen.setDashPattern(dash) return pen def hsvColor(hue, sat=1.0, val=1.0, alpha=1.0): """Generate a QColor from HSVa values. (all arguments are float 0.0-1.0)""" c = QtGui.QColor() c.setHsvF(hue, sat, val, alpha) return c def colorTuple(c): """Return a tuple (R,G,B,A) from a QColor""" return (c.red(), c.green(), c.blue(), c.alpha()) def colorStr(c): """Generate a hex string code from a QColor""" return ('%02x'*4) % colorTuple(c) def intColor(index, hues=9, values=1, maxValue=255, minValue=150, maxHue=360, minHue=0, sat=255, alpha=255, **kargs): """ Creates a QColor from a single index. Useful for stepping through a predefined list of colors. The argument *index* determines which color from the set will be returned. All other arguments determine what the set of predefined colors will be Colors are chosen by cycling across hues while varying the value (brightness). By default, this selects from a list of 9 hues.""" hues = int(hues) values = int(values) ind = int(index) % (hues * values) indh = ind % hues indv = ind / hues if values > 1: v = minValue + indv * ((maxValue-minValue) / (values-1)) else: v = maxValue h = minHue + (indh * (maxHue-minHue)) / hues c = QtGui.QColor() c.setHsv(h, sat, v) c.setAlpha(alpha) return c def glColor(*args, **kargs): """ Convert a color to OpenGL color format (r,g,b,a) floats 0.0-1.0 Accepts same arguments as :func:`mkColor `. """ c = mkColor(*args, **kargs) return (c.red()/255., c.green()/255., c.blue()/255., c.alpha()/255.) def makeArrowPath(headLen=20, tipAngle=20, tailLen=20, tailWidth=3, baseAngle=0): """ Construct a path outlining an arrow with the given dimensions. The arrow points in the -x direction with tip positioned at 0,0. If *tipAngle* is supplied (in degrees), it overrides *headWidth*. If *tailLen* is None, no tail will be drawn. """ headWidth = headLen * np.tan(tipAngle * 0.5 * np.pi/180.) path = QtGui.QPainterPath() path.moveTo(0,0) path.lineTo(headLen, -headWidth) if tailLen is None: innerY = headLen - headWidth * np.tan(baseAngle*np.pi/180.) path.lineTo(innerY, 0) else: tailWidth *= 0.5 innerY = headLen - (headWidth-tailWidth) * np.tan(baseAngle*np.pi/180.) path.lineTo(innerY, -tailWidth) path.lineTo(headLen + tailLen, -tailWidth) path.lineTo(headLen + tailLen, tailWidth) path.lineTo(innerY, tailWidth) path.lineTo(headLen, headWidth) path.lineTo(0,0) return path def eq(a, b): """The great missing equivalence function: Guaranteed evaluation to a single bool value.""" if a is b: return True try: with warnings.catch_warnings(module=np): # ignore numpy futurewarning (numpy v. 1.10) e = a==b except ValueError: return False except AttributeError: return False except: print('failed to evaluate equivalence for:') print(" a:", str(type(a)), str(a)) print(" b:", str(type(b)), str(b)) raise t = type(e) if t is bool: return e elif t is np.bool_: return bool(e) elif isinstance(e, np.ndarray) or (hasattr(e, 'implements') and e.implements('MetaArray')): try: ## disaster: if a is an empty array and b is not, then e.all() is True if a.shape != b.shape: return False except: return False if (hasattr(e, 'implements') and e.implements('MetaArray')): return e.asarray().all() else: return e.all() else: raise Exception("== operator returned type %s" % str(type(e))) def affineSlice(data, shape, origin, vectors, axes, order=1, returnCoords=False, **kargs): """ Take a slice of any orientation through an array. This is useful for extracting sections of multi-dimensional arrays such as MRI images for viewing as 1D or 2D data. The slicing axes are aribtrary; they do not need to be orthogonal to the original data or even to each other. It is possible to use this function to extract arbitrary linear, rectangular, or parallelepiped shapes from within larger datasets. The original data is interpolated onto a new array of coordinates using scipy.ndimage.map_coordinates if it is available (see the scipy documentation for more information about this). If scipy is not available, then a slower implementation of map_coordinates is used. For a graphical interface to this function, see :func:`ROI.getArrayRegion ` ============== ==================================================================================================== **Arguments:** *data* (ndarray) the original dataset *shape* the shape of the slice to take (Note the return value may have more dimensions than len(shape)) *origin* the location in the original dataset that will become the origin of the sliced data. *vectors* list of unit vectors which point in the direction of the slice axes. Each vector must have the same length as *axes*. If the vectors are not unit length, the result will be scaled relative to the original data. If the vectors are not orthogonal, the result will be sheared relative to the original data. *axes* The axes in the original dataset which correspond to the slice *vectors* *order* The order of spline interpolation. Default is 1 (linear). See scipy.ndimage.map_coordinates for more information. *returnCoords* If True, return a tuple (result, coords) where coords is the array of coordinates used to select values from the original dataset. *All extra keyword arguments are passed to scipy.ndimage.map_coordinates.* -------------------------------------------------------------------------------------------------------------------- ============== ==================================================================================================== Note the following must be true: | len(shape) == len(vectors) | len(origin) == len(axes) == len(vectors[i]) Example: start with a 4D fMRI data set, take a diagonal-planar slice out of the last 3 axes * data = array with dims (time, x, y, z) = (100, 40, 40, 40) * The plane to pull out is perpendicular to the vector (x,y,z) = (1,1,1) * The origin of the slice will be at (x,y,z) = (40, 0, 0) * We will slice a 20x20 plane from each timepoint, giving a final shape (100, 20, 20) The call for this example would look like:: affineSlice(data, shape=(20,20), origin=(40,0,0), vectors=((-1, 1, 0), (-1, 0, 1)), axes=(1,2,3)) """ try: import scipy.ndimage have_scipy = True except ImportError: have_scipy = False have_scipy = False # sanity check if len(shape) != len(vectors): raise Exception("shape and vectors must have same length.") if len(origin) != len(axes): raise Exception("origin and axes must have same length.") for v in vectors: if len(v) != len(axes): raise Exception("each vector must be same length as axes.") shape = list(map(np.ceil, shape)) ## transpose data so slice axes come first trAx = list(range(data.ndim)) for x in axes: trAx.remove(x) tr1 = tuple(axes) + tuple(trAx) data = data.transpose(tr1) #print "tr1:", tr1 ## dims are now [(slice axes), (other axes)] ## make sure vectors are arrays if not isinstance(vectors, np.ndarray): vectors = np.array(vectors) if not isinstance(origin, np.ndarray): origin = np.array(origin) origin.shape = (len(axes),) + (1,)*len(shape) ## Build array of sample locations. grid = np.mgrid[tuple([slice(0,x) for x in shape])] ## mesh grid of indexes x = (grid[np.newaxis,...] * vectors.transpose()[(Ellipsis,) + (np.newaxis,)*len(shape)]).sum(axis=1) ## magic x += origin ## iterate manually over unused axes since map_coordinates won't do it for us if have_scipy: extraShape = data.shape[len(axes):] output = np.empty(tuple(shape) + extraShape, dtype=data.dtype) for inds in np.ndindex(*extraShape): ind = (Ellipsis,) + inds output[ind] = scipy.ndimage.map_coordinates(data[ind], x, order=order, **kargs) else: # map_coordinates expects the indexes as the first axis, whereas # interpolateArray expects indexes at the last axis. tr = tuple(range(1,x.ndim)) + (0,) output = interpolateArray(data, x.transpose(tr)) tr = list(range(output.ndim)) trb = [] for i in range(min(axes)): ind = tr1.index(i) + (len(shape)-len(axes)) tr.remove(ind) trb.append(ind) tr2 = tuple(trb+tr) ## Untranspose array before returning output = output.transpose(tr2) if returnCoords: return (output, x) else: return output def interpolateArray(data, x, default=0.0): """ N-dimensional interpolation similar to scipy.ndimage.map_coordinates. This function returns linearly-interpolated values sampled from a regular grid of data. *data* is an array of any shape containing the values to be interpolated. *x* is an array with (shape[-1] <= data.ndim) containing the locations within *data* to interpolate. Returns array of shape (x.shape[:-1] + data.shape[x.shape[-1]:]) For example, assume we have the following 2D image data:: >>> data = np.array([[1, 2, 4 ], [10, 20, 40 ], [100, 200, 400]]) To compute a single interpolated point from this data:: >>> x = np.array([(0.5, 0.5)]) >>> interpolateArray(data, x) array([ 8.25]) To compute a 1D list of interpolated locations:: >>> x = np.array([(0.5, 0.5), (1.0, 1.0), (1.0, 2.0), (1.5, 0.0)]) >>> interpolateArray(data, x) array([ 8.25, 20. , 40. , 55. ]) To compute a 2D array of interpolated locations:: >>> x = np.array([[(0.5, 0.5), (1.0, 2.0)], [(1.0, 1.0), (1.5, 0.0)]]) >>> interpolateArray(data, x) array([[ 8.25, 40. ], [ 20. , 55. ]]) ..and so on. The *x* argument may have any shape as long as ```x.shape[-1] <= data.ndim```. In the case that ```x.shape[-1] < data.ndim```, then the remaining axes are simply broadcasted as usual. For example, we can interpolate one location from an entire row of the data:: >>> x = np.array([[0.5]]) >>> interpolateArray(data, x) array([[ 5.5, 11. , 22. ]]) This is useful for interpolating from arrays of colors, vertexes, etc. """ prof = debug.Profiler() nd = data.ndim md = x.shape[-1] if md > nd: raise TypeError("x.shape[-1] must be less than or equal to data.ndim") # First we generate arrays of indexes that are needed to # extract the data surrounding each point fields = np.mgrid[(slice(0,2),) * md] xmin = np.floor(x).astype(int) xmax = xmin + 1 indexes = np.concatenate([xmin[np.newaxis, ...], xmax[np.newaxis, ...]]) fieldInds = [] totalMask = np.ones(x.shape[:-1], dtype=bool) # keep track of out-of-bound indexes for ax in range(md): mask = (xmin[...,ax] >= 0) & (x[...,ax] <= data.shape[ax]-1) # keep track of points that need to be set to default totalMask &= mask # ..and keep track of indexes that are out of bounds # (note that when x[...,ax] == data.shape[ax], then xmax[...,ax] will be out # of bounds, but the interpolation will work anyway) mask &= (xmax[...,ax] < data.shape[ax]) axisIndex = indexes[...,ax][fields[ax]] axisIndex[axisIndex < 0] = 0 axisIndex[axisIndex >= data.shape[ax]] = 0 fieldInds.append(axisIndex) prof() # Get data values surrounding each requested point fieldData = data[tuple(fieldInds)] prof() ## Interpolate s = np.empty((md,) + fieldData.shape, dtype=float) dx = x - xmin # reshape fields for arithmetic against dx for ax in range(md): f1 = fields[ax].reshape(fields[ax].shape + (1,)*(dx.ndim-1)) sax = f1 * dx[...,ax] + (1-f1) * (1-dx[...,ax]) sax = sax.reshape(sax.shape + (1,) * (s.ndim-1-sax.ndim)) s[ax] = sax s = np.product(s, axis=0) result = fieldData * s for i in range(md): result = result.sum(axis=0) prof() if totalMask.ndim > 0: result[~totalMask] = default else: if totalMask is False: result[:] = default prof() return result def subArray(data, offset, shape, stride): """ Unpack a sub-array from *data* using the specified offset, shape, and stride. Note that *stride* is specified in array elements, not bytes. For example, we have a 2x3 array packed in a 1D array as follows:: data = [_, _, 00, 01, 02, _, 10, 11, 12, _] Then we can unpack the sub-array with this call:: subArray(data, offset=2, shape=(2, 3), stride=(4, 1)) ..which returns:: [[00, 01, 02], [10, 11, 12]] This function operates only on the first axis of *data*. So changing the input in the example above to have shape (10, 7) would cause the output to have shape (2, 3, 7). """ #data = data.flatten() data = data[offset:] shape = tuple(shape) stride = tuple(stride) extraShape = data.shape[1:] #print data.shape, offset, shape, stride for i in range(len(shape)): mask = (slice(None),) * i + (slice(None, shape[i] * stride[i]),) newShape = shape[:i+1] if i < len(shape)-1: newShape += (stride[i],) newShape += extraShape #print i, mask, newShape #print "start:\n", data.shape, data data = data[mask] #print "mask:\n", data.shape, data data = data.reshape(newShape) #print "reshape:\n", data.shape, data return data def transformToArray(tr): """ Given a QTransform, return a 3x3 numpy array. Given a QMatrix4x4, return a 4x4 numpy array. Example: map an array of x,y coordinates through a transform:: ## coordinates to map are (1,5), (2,6), (3,7), and (4,8) coords = np.array([[1,2,3,4], [5,6,7,8], [1,1,1,1]]) # the extra '1' coordinate is needed for translation to work ## Make an example transform tr = QtGui.QTransform() tr.translate(3,4) tr.scale(2, 0.1) ## convert to array m = pg.transformToArray()[:2] # ignore the perspective portion of the transformation ## map coordinates through transform mapped = np.dot(m, coords) """ #return np.array([[tr.m11(), tr.m12(), tr.m13()],[tr.m21(), tr.m22(), tr.m23()],[tr.m31(), tr.m32(), tr.m33()]]) ## The order of elements given by the method names m11..m33 is misleading-- ## It is most common for x,y translation to occupy the positions 1,3 and 2,3 in ## a transformation matrix. However, with QTransform these values appear at m31 and m32. ## So the correct interpretation is transposed: if isinstance(tr, QtGui.QTransform): return np.array([[tr.m11(), tr.m21(), tr.m31()], [tr.m12(), tr.m22(), tr.m32()], [tr.m13(), tr.m23(), tr.m33()]]) elif isinstance(tr, QtGui.QMatrix4x4): return np.array(tr.copyDataTo()).reshape(4,4) else: raise Exception("Transform argument must be either QTransform or QMatrix4x4.") def transformCoordinates(tr, coords, transpose=False): """ Map a set of 2D or 3D coordinates through a QTransform or QMatrix4x4. The shape of coords must be (2,...) or (3,...) The mapping will _ignore_ any perspective transformations. For coordinate arrays with ndim=2, this is basically equivalent to matrix multiplication. Most arrays, however, prefer to put the coordinate axis at the end (eg. shape=(...,3)). To allow this, use transpose=True. """ if transpose: ## move last axis to beginning. This transposition will be reversed before returning the mapped coordinates. coords = coords.transpose((coords.ndim-1,) + tuple(range(0,coords.ndim-1))) nd = coords.shape[0] if isinstance(tr, np.ndarray): m = tr else: m = transformToArray(tr) m = m[:m.shape[0]-1] # remove perspective ## If coords are 3D and tr is 2D, assume no change for Z axis if m.shape == (2,3) and nd == 3: m2 = np.zeros((3,4)) m2[:2, :2] = m[:2,:2] m2[:2, 3] = m[:2,2] m2[2,2] = 1 m = m2 ## if coords are 2D and tr is 3D, ignore Z axis if m.shape == (3,4) and nd == 2: m2 = np.empty((2,3)) m2[:,:2] = m[:2,:2] m2[:,2] = m[:2,3] m = m2 ## reshape tr and coords to prepare for multiplication m = m.reshape(m.shape + (1,)*(coords.ndim-1)) coords = coords[np.newaxis, ...] # separate scale/rotate and translation translate = m[:,-1] m = m[:, :-1] ## map coordinates and return mapped = (m*coords).sum(axis=1) ## apply scale/rotate mapped += translate if transpose: ## move first axis to end. mapped = mapped.transpose(tuple(range(1,mapped.ndim)) + (0,)) return mapped def solve3DTransform(points1, points2): """ Find a 3D transformation matrix that maps points1 onto points2. Points must be specified as either lists of 4 Vectors or (4, 3) arrays. """ import numpy.linalg pts = [] for inp in (points1, points2): if isinstance(inp, np.ndarray): A = np.empty((4,4), dtype=float) A[:,:3] = inp[:,:3] A[:,3] = 1.0 else: A = np.array([[inp[i].x(), inp[i].y(), inp[i].z(), 1] for i in range(4)]) pts.append(A) ## solve 3 sets of linear equations to determine transformation matrix elements matrix = np.zeros((4,4)) for i in range(3): ## solve Ax = B; x is one row of the desired transformation matrix matrix[i] = numpy.linalg.solve(pts[0], pts[1][:,i]) return matrix def solveBilinearTransform(points1, points2): """ Find a bilinear transformation matrix (2x4) that maps points1 onto points2. Points must be specified as a list of 4 Vector, Point, QPointF, etc. To use this matrix to map a point [x,y]:: mapped = np.dot(matrix, [x*y, x, y, 1]) """ import numpy.linalg ## A is 4 rows (points) x 4 columns (xy, x, y, 1) ## B is 4 rows (points) x 2 columns (x, y) A = np.array([[points1[i].x()*points1[i].y(), points1[i].x(), points1[i].y(), 1] for i in range(4)]) B = np.array([[points2[i].x(), points2[i].y()] for i in range(4)]) ## solve 2 sets of linear equations to determine transformation matrix elements matrix = np.zeros((2,4)) for i in range(2): matrix[i] = numpy.linalg.solve(A, B[:,i]) ## solve Ax = B; x is one row of the desired transformation matrix return matrix def rescaleData(data, scale, offset, dtype=None, clip=None): """Return data rescaled and optionally cast to a new dtype:: data => (data-offset) * scale """ if dtype is None: dtype = data.dtype else: dtype = np.dtype(dtype) try: if not getConfigOption('useWeave'): raise Exception('Weave is disabled; falling back to slower version.') try: import scipy.weave except ImportError: raise Exception('scipy.weave is not importable; falling back to slower version.') ## require native dtype when using weave if not data.dtype.isnative: data = data.astype(data.dtype.newbyteorder('=')) if not dtype.isnative: weaveDtype = dtype.newbyteorder('=') else: weaveDtype = dtype newData = np.empty((data.size,), dtype=weaveDtype) flat = np.ascontiguousarray(data).reshape(data.size) size = data.size code = """ double sc = (double)scale; double off = (double)offset; for( int i=0; i0 and max->*scale*:: rescaled = (clip(data, min, max) - min) * (*scale* / (max - min)) It is also possible to use a 2D (N,2) array of values for levels. In this case, it is assumed that each pair of min,max values in the levels array should be applied to a different subset of the input data (for example, the input data may already have RGB values and the levels are used to independently scale each channel). The use of this feature requires that levels.shape[0] == data.shape[-1]. scale The maximum value to which data will be rescaled before being passed through the lookup table (or returned if there is no lookup table). By default this will be set to the length of the lookup table, or 255 if no lookup table is provided. lut Optional lookup table (array with dtype=ubyte). Values in data will be converted to color by indexing directly from lut. The output data shape will be input.shape + lut.shape[1:]. Lookup tables can be built using ColorMap or GradientWidget. useRGBA If True, the data is returned in RGBA order (useful for building OpenGL textures). The default is False, which returns in ARGB order for use with QImage (Note that 'ARGB' is a term used by the Qt documentation; the *actual* order is BGRA). ============== ================================================================================== """ profile = debug.Profiler() if data.ndim not in (2, 3): raise TypeError("data must be 2D or 3D") if data.ndim == 3 and data.shape[2] > 4: raise TypeError("data.shape[2] must be <= 4") if lut is not None and not isinstance(lut, np.ndarray): lut = np.array(lut) if levels is None: # automatically decide levels based on data dtype if data.dtype.kind == 'u': levels = np.array([0, 2**(data.itemsize*8)-1]) elif data.dtype.kind == 'i': s = 2**(data.itemsize*8 - 1) levels = np.array([-s, s-1]) elif data.dtype.kind == 'b': levels = np.array([0,1]) else: raise Exception('levels argument is required for float input types') if not isinstance(levels, np.ndarray): levels = np.array(levels) if levels.ndim == 1: if levels.shape[0] != 2: raise Exception('levels argument must have length 2') elif levels.ndim == 2: if lut is not None and lut.ndim > 1: raise Exception('Cannot make ARGB data when both levels and lut have ndim > 2') if levels.shape != (data.shape[-1], 2): raise Exception('levels must have shape (data.shape[-1], 2)') else: raise Exception("levels argument must be 1D or 2D (got shape=%s)." % repr(levels.shape)) profile() # Decide on maximum scaled value if scale is None: if lut is not None: scale = lut.shape[0] - 1 else: scale = 255. # Decide on the dtype we want after scaling if lut is None: dtype = np.ubyte else: dtype = np.min_scalar_type(lut.shape[0]-1) # Apply levels if given if levels is not None: if isinstance(levels, np.ndarray) and levels.ndim == 2: # we are going to rescale each channel independently if levels.shape[0] != data.shape[-1]: raise Exception("When rescaling multi-channel data, there must be the same number of levels as channels (data.shape[-1] == levels.shape[0])") newData = np.empty(data.shape, dtype=int) for i in range(data.shape[-1]): minVal, maxVal = levels[i] if minVal == maxVal: maxVal += 1e-16 newData[...,i] = rescaleData(data[...,i], scale/(maxVal-minVal), minVal, dtype=dtype) data = newData else: # Apply level scaling unless it would have no effect on the data minVal, maxVal = levels if minVal != 0 or maxVal != scale: if minVal == maxVal: maxVal += 1e-16 data = rescaleData(data, scale/(maxVal-minVal), minVal, dtype=dtype) profile() # apply LUT if given if lut is not None: data = applyLookupTable(data, lut) else: if data.dtype is not np.ubyte: data = np.clip(data, 0, 255).astype(np.ubyte) profile() # this will be the final image array imgData = np.empty(data.shape[:2]+(4,), dtype=np.ubyte) profile() # decide channel order if useRGBA: order = [0,1,2,3] # array comes out RGBA else: order = [2,1,0,3] # for some reason, the colors line up as BGR in the final image. # copy data into image array if data.ndim == 2: # This is tempting: # imgData[..., :3] = data[..., np.newaxis] # ..but it turns out this is faster: for i in range(3): imgData[..., i] = data elif data.shape[2] == 1: for i in range(3): imgData[..., i] = data[..., 0] else: for i in range(0, data.shape[2]): imgData[..., i] = data[..., order[i]] profile() # add opaque alpha channel if needed if data.ndim == 2 or data.shape[2] == 3: alpha = False imgData[..., 3] = 255 else: alpha = True profile() return imgData, alpha def makeQImage(imgData, alpha=None, copy=True, transpose=True): """ Turn an ARGB array into QImage. By default, the data is copied; changes to the array will not be reflected in the image. The image will be given a 'data' attribute pointing to the array which shares its data to prevent python freeing that memory while the image is in use. ============== =================================================================== **Arguments:** imgData Array of data to convert. Must have shape (width, height, 3 or 4) and dtype=ubyte. The order of values in the 3rd axis must be (b, g, r, a). alpha If True, the QImage returned will have format ARGB32. If False, the format will be RGB32. By default, _alpha_ is True if array.shape[2] == 4. copy If True, the data is copied before converting to QImage. If False, the new QImage points directly to the data in the array. Note that the array must be contiguous for this to work (see numpy.ascontiguousarray). transpose If True (the default), the array x/y axes are transposed before creating the image. Note that Qt expects the axes to be in (height, width) order whereas pyqtgraph usually prefers the opposite. ============== =================================================================== """ ## create QImage from buffer profile = debug.Profiler() ## If we didn't explicitly specify alpha, check the array shape. if alpha is None: alpha = (imgData.shape[2] == 4) copied = False if imgData.shape[2] == 3: ## need to make alpha channel (even if alpha==False; QImage requires 32 bpp) if copy is True: d2 = np.empty(imgData.shape[:2] + (4,), dtype=imgData.dtype) d2[:,:,:3] = imgData d2[:,:,3] = 255 imgData = d2 copied = True else: raise Exception('Array has only 3 channels; cannot make QImage without copying.') if alpha: imgFormat = QtGui.QImage.Format_ARGB32 else: imgFormat = QtGui.QImage.Format_RGB32 if transpose: imgData = imgData.transpose((1, 0, 2)) ## QImage expects the row/column order to be opposite profile() if not imgData.flags['C_CONTIGUOUS']: if copy is False: extra = ' (try setting transpose=False)' if transpose else '' raise Exception('Array is not contiguous; cannot make QImage without copying.'+extra) imgData = np.ascontiguousarray(imgData) copied = True if copy is True and copied is False: imgData = imgData.copy() if USE_PYSIDE: ch = ctypes.c_char.from_buffer(imgData, 0) img = QtGui.QImage(ch, imgData.shape[1], imgData.shape[0], imgFormat) else: #addr = ctypes.addressof(ctypes.c_char.from_buffer(imgData, 0)) ## PyQt API for QImage changed between 4.9.3 and 4.9.6 (I don't know exactly which version it was) ## So we first attempt the 4.9.6 API, then fall back to 4.9.3 #addr = ctypes.c_char.from_buffer(imgData, 0) #try: #img = QtGui.QImage(addr, imgData.shape[1], imgData.shape[0], imgFormat) #except TypeError: #addr = ctypes.addressof(addr) #img = QtGui.QImage(addr, imgData.shape[1], imgData.shape[0], imgFormat) try: img = QtGui.QImage(imgData.ctypes.data, imgData.shape[1], imgData.shape[0], imgFormat) except: if copy: # does not leak memory, is not mutable img = QtGui.QImage(buffer(imgData), imgData.shape[1], imgData.shape[0], imgFormat) else: # mutable, but leaks memory img = QtGui.QImage(memoryview(imgData), imgData.shape[1], imgData.shape[0], imgFormat) img.data = imgData return img #try: #buf = imgData.data #except AttributeError: ## happens when image data is non-contiguous #buf = imgData.data #profiler() #qimage = QtGui.QImage(buf, imgData.shape[1], imgData.shape[0], imgFormat) #profiler() #qimage.data = imgData #return qimage def imageToArray(img, copy=False, transpose=True): """ Convert a QImage into numpy array. The image must have format RGB32, ARGB32, or ARGB32_Premultiplied. By default, the image is not copied; changes made to the array will appear in the QImage as well (beware: if the QImage is collected before the array, there may be trouble). The array will have shape (width, height, (b,g,r,a)). """ fmt = img.format() ptr = img.bits() if USE_PYSIDE: arr = np.frombuffer(ptr, dtype=np.ubyte) else: ptr.setsize(img.byteCount()) arr = np.asarray(ptr) if img.byteCount() != arr.size * arr.itemsize: # Required for Python 2.6, PyQt 4.10 # If this works on all platforms, then there is no need to use np.asarray.. arr = np.frombuffer(ptr, np.ubyte, img.byteCount()) arr = arr.reshape(img.height(), img.width(), 4) if fmt == img.Format_RGB32: arr[...,3] = 255 if copy: arr = arr.copy() if transpose: return arr.transpose((1,0,2)) else: return arr def colorToAlpha(data, color): """ Given an RGBA image in *data*, convert *color* to be transparent. *data* must be an array (w, h, 3 or 4) of ubyte values and *color* must be an array (3) of ubyte values. This is particularly useful for use with images that have a black or white background. Algorithm is taken from Gimp's color-to-alpha function in plug-ins/common/colortoalpha.c Credit: /* * Color To Alpha plug-in v1.0 by Seth Burgess, sjburges@gimp.org 1999/05/14 * with algorithm by clahey */ """ data = data.astype(float) if data.shape[-1] == 3: ## add alpha channel if needed d2 = np.empty(data.shape[:2]+(4,), dtype=data.dtype) d2[...,:3] = data d2[...,3] = 255 data = d2 color = color.astype(float) alpha = np.zeros(data.shape[:2]+(3,), dtype=float) output = data.copy() for i in [0,1,2]: d = data[...,i] c = color[i] mask = d > c alpha[...,i][mask] = (d[mask] - c) / (255. - c) imask = d < c alpha[...,i][imask] = (c - d[imask]) / c output[...,3] = alpha.max(axis=2) * 255. mask = output[...,3] >= 1.0 ## avoid zero division while processing alpha channel correction = 255. / output[...,3][mask] ## increase value to compensate for decreased alpha for i in [0,1,2]: output[...,i][mask] = ((output[...,i][mask]-color[i]) * correction) + color[i] output[...,3][mask] *= data[...,3][mask] / 255. ## combine computed and previous alpha values #raise Exception() return np.clip(output, 0, 255).astype(np.ubyte) def gaussianFilter(data, sigma): """ Drop-in replacement for scipy.ndimage.gaussian_filter. (note: results are only approximately equal to the output of gaussian_filter) """ if np.isscalar(sigma): sigma = (sigma,) * data.ndim baseline = data.mean() filtered = data - baseline for ax in range(data.ndim): s = sigma[ax] if s == 0: continue # generate 1D gaussian kernel ksize = int(s * 6) x = np.arange(-ksize, ksize) kernel = np.exp(-x**2 / (2*s**2)) kshape = [1,] * data.ndim kshape[ax] = len(kernel) kernel = kernel.reshape(kshape) # convolve as product of FFTs shape = data.shape[ax] + ksize scale = 1.0 / (abs(s) * (2*np.pi)**0.5) filtered = scale * np.fft.irfft(np.fft.rfft(filtered, shape, axis=ax) * np.fft.rfft(kernel, shape, axis=ax), axis=ax) # clip off extra data sl = [slice(None)] * data.ndim sl[ax] = slice(filtered.shape[ax]-data.shape[ax],None,None) filtered = filtered[sl] return filtered + baseline def downsample(data, n, axis=0, xvals='subsample'): """Downsample by averaging points together across axis. If multiple axes are specified, runs once per axis. If a metaArray is given, then the axis values can be either subsampled or downsampled to match. """ ma = None if (hasattr(data, 'implements') and data.implements('MetaArray')): ma = data data = data.view(np.ndarray) if hasattr(axis, '__len__'): if not hasattr(n, '__len__'): n = [n]*len(axis) for i in range(len(axis)): data = downsample(data, n[i], axis[i]) return data if n <= 1: return data nPts = int(data.shape[axis] / n) s = list(data.shape) s[axis] = nPts s.insert(axis+1, n) sl = [slice(None)] * data.ndim sl[axis] = slice(0, nPts*n) d1 = data[tuple(sl)] #print d1.shape, s d1.shape = tuple(s) d2 = d1.mean(axis+1) if ma is None: return d2 else: info = ma.infoCopy() if 'values' in info[axis]: if xvals == 'subsample': info[axis]['values'] = info[axis]['values'][::n][:nPts] elif xvals == 'downsample': info[axis]['values'] = downsample(info[axis]['values'], n) return MetaArray(d2, info=info) def arrayToQPath(x, y, connect='all'): """Convert an array of x,y coordinats to QPainterPath as efficiently as possible. The *connect* argument may be 'all', indicating that each point should be connected to the next; 'pairs', indicating that each pair of points should be connected, or an array of int32 values (0 or 1) indicating connections. """ ## Create all vertices in path. The method used below creates a binary format so that all ## vertices can be read in at once. This binary format may change in future versions of Qt, ## so the original (slower) method is left here for emergencies: #path.moveTo(x[0], y[0]) #if connect == 'all': #for i in range(1, y.shape[0]): #path.lineTo(x[i], y[i]) #elif connect == 'pairs': #for i in range(1, y.shape[0]): #if i%2 == 0: #path.lineTo(x[i], y[i]) #else: #path.moveTo(x[i], y[i]) #elif isinstance(connect, np.ndarray): #for i in range(1, y.shape[0]): #if connect[i] == 1: #path.lineTo(x[i], y[i]) #else: #path.moveTo(x[i], y[i]) #else: #raise Exception('connect argument must be "all", "pairs", or array') ## Speed this up using >> operator ## Format is: ## numVerts(i4) 0(i4) ## x(f8) y(f8) 0(i4) <-- 0 means this vertex does not connect ## x(f8) y(f8) 1(i4) <-- 1 means this vertex connects to the previous vertex ## ... ## 0(i4) ## ## All values are big endian--pack using struct.pack('>d') or struct.pack('>i') path = QtGui.QPainterPath() #profiler = debug.Profiler() n = x.shape[0] # create empty array, pad with extra space on either end arr = np.empty(n+2, dtype=[('x', '>f8'), ('y', '>f8'), ('c', '>i4')]) # write first two integers #profiler('allocate empty') byteview = arr.view(dtype=np.ubyte) byteview[:12] = 0 byteview.data[12:20] = struct.pack('>ii', n, 0) #profiler('pack header') # Fill array with vertex values arr[1:-1]['x'] = x arr[1:-1]['y'] = y # decide which points are connected by lines if eq(connect, 'all'): arr[1:-1]['c'] = 1 elif eq(connect, 'pairs'): arr[1:-1]['c'][::2] = 1 arr[1:-1]['c'][1::2] = 0 elif eq(connect, 'finite'): arr[1:-1]['c'] = np.isfinite(x) & np.isfinite(y) elif isinstance(connect, np.ndarray): arr[1:-1]['c'] = connect else: raise Exception('connect argument must be "all", "pairs", "finite", or array') #profiler('fill array') # write last 0 lastInd = 20*(n+1) byteview.data[lastInd:lastInd+4] = struct.pack('>i', 0) #profiler('footer') # create datastream object and stream into path ## Avoiding this method because QByteArray(str) leaks memory in PySide #buf = QtCore.QByteArray(arr.data[12:lastInd+4]) # I think one unnecessary copy happens here path.strn = byteview.data[12:lastInd+4] # make sure data doesn't run away try: buf = QtCore.QByteArray.fromRawData(path.strn) except TypeError: buf = QtCore.QByteArray(bytes(path.strn)) #profiler('create buffer') ds = QtCore.QDataStream(buf) ds >> path #profiler('load') return path #def isosurface(data, level): #""" #Generate isosurface from volumetric data using marching tetrahedra algorithm. #See Paul Bourke, "Polygonising a Scalar Field Using Tetrahedrons" (http://local.wasp.uwa.edu.au/~pbourke/geometry/polygonise/) #*data* 3D numpy array of scalar values #*level* The level at which to generate an isosurface #""" #facets = [] ### mark everything below the isosurface level #mask = data < level #### make eight sub-fields #fields = np.empty((2,2,2), dtype=object) #slices = [slice(0,-1), slice(1,None)] #for i in [0,1]: #for j in [0,1]: #for k in [0,1]: #fields[i,j,k] = mask[slices[i], slices[j], slices[k]] ### split each cell into 6 tetrahedra ### these all have the same 'orienation'; points 1,2,3 circle ### clockwise around point 0 #tetrahedra = [ #[(0,1,0), (1,1,1), (0,1,1), (1,0,1)], #[(0,1,0), (0,1,1), (0,0,1), (1,0,1)], #[(0,1,0), (0,0,1), (0,0,0), (1,0,1)], #[(0,1,0), (0,0,0), (1,0,0), (1,0,1)], #[(0,1,0), (1,0,0), (1,1,0), (1,0,1)], #[(0,1,0), (1,1,0), (1,1,1), (1,0,1)] #] ### each tetrahedron will be assigned an index ### which determines how to generate its facets. ### this structure is: ### facets[index][facet1, facet2, ...] ### where each facet is triangular and its points are each ### interpolated between two points on the tetrahedron ### facet = [(p1a, p1b), (p2a, p2b), (p3a, p3b)] ### facet points always circle clockwise if you are looking ### at them from below the isosurface. #indexFacets = [ #[], ## all above #[[(0,1), (0,2), (0,3)]], # 0 below #[[(1,0), (1,3), (1,2)]], # 1 below #[[(0,2), (1,3), (1,2)], [(0,2), (0,3), (1,3)]], # 0,1 below #[[(2,0), (2,1), (2,3)]], # 2 below #[[(0,3), (1,2), (2,3)], [(0,3), (0,1), (1,2)]], # 0,2 below #[[(1,0), (2,3), (2,0)], [(1,0), (1,3), (2,3)]], # 1,2 below #[[(3,0), (3,1), (3,2)]], # 3 above #[[(3,0), (3,2), (3,1)]], # 3 below #[[(1,0), (2,0), (2,3)], [(1,0), (2,3), (1,3)]], # 0,3 below #[[(0,3), (2,3), (1,2)], [(0,3), (1,2), (0,1)]], # 1,3 below #[[(2,0), (2,3), (2,1)]], # 0,1,3 below #[[(0,2), (1,2), (1,3)], [(0,2), (1,3), (0,3)]], # 2,3 below #[[(1,0), (1,2), (1,3)]], # 0,2,3 below #[[(0,1), (0,3), (0,2)]], # 1,2,3 below #[] ## all below #] #for tet in tetrahedra: ### get the 4 fields for this tetrahedron #tetFields = [fields[c] for c in tet] ### generate an index for each grid cell #index = tetFields[0] + tetFields[1]*2 + tetFields[2]*4 + tetFields[3]*8 ### add facets #for i in xrange(index.shape[0]): # data x-axis #for j in xrange(index.shape[1]): # data y-axis #for k in xrange(index.shape[2]): # data z-axis #for f in indexFacets[index[i,j,k]]: # faces to generate for this tet #pts = [] #for l in [0,1,2]: # points in this face #p1 = tet[f[l][0]] # tet corner 1 #p2 = tet[f[l][1]] # tet corner 2 #pts.append([(p1[x]+p2[x])*0.5+[i,j,k][x]+0.5 for x in [0,1,2]]) ## interpolate between tet corners #facets.append(pts) #return facets def isocurve(data, level, connected=False, extendToEdge=False, path=False): """ Generate isocurve from 2D data using marching squares algorithm. ============== ========================================================= **Arguments:** data 2D numpy array of scalar values level The level at which to generate an isosurface connected If False, return a single long list of point pairs If True, return multiple long lists of connected point locations. (This is slower but better for drawing continuous lines) extendToEdge If True, extend the curves to reach the exact edges of the data. path if True, return a QPainterPath rather than a list of vertex coordinates. This forces connected=True. ============== ========================================================= This function is SLOW; plenty of room for optimization here. """ if path is True: connected = True if extendToEdge: d2 = np.empty((data.shape[0]+2, data.shape[1]+2), dtype=data.dtype) d2[1:-1, 1:-1] = data d2[0, 1:-1] = data[0] d2[-1, 1:-1] = data[-1] d2[1:-1, 0] = data[:, 0] d2[1:-1, -1] = data[:, -1] d2[0,0] = d2[0,1] d2[0,-1] = d2[1,-1] d2[-1,0] = d2[-1,1] d2[-1,-1] = d2[-1,-2] data = d2 sideTable = [ [], [0,1], [1,2], [0,2], [0,3], [1,3], [0,1,2,3], [2,3], [2,3], [0,1,2,3], [1,3], [0,3], [0,2], [1,2], [0,1], [] ] edgeKey=[ [(0,1), (0,0)], [(0,0), (1,0)], [(1,0), (1,1)], [(1,1), (0,1)] ] lines = [] ## mark everything below the isosurface level mask = data < level ### make four sub-fields and compute indexes for grid cells index = np.zeros([x-1 for x in data.shape], dtype=np.ubyte) fields = np.empty((2,2), dtype=object) slices = [slice(0,-1), slice(1,None)] for i in [0,1]: for j in [0,1]: fields[i,j] = mask[slices[i], slices[j]] #vertIndex = i - 2*j*i + 3*j + 4*k ## this is just to match Bourk's vertex numbering scheme vertIndex = i+2*j #print i,j,k," : ", fields[i,j,k], 2**vertIndex np.add(index, fields[i,j] * 2**vertIndex, out=index, casting='unsafe') #print index #print index ## add lines for i in range(index.shape[0]): # data x-axis for j in range(index.shape[1]): # data y-axis sides = sideTable[index[i,j]] for l in range(0, len(sides), 2): ## faces for this grid cell edges = sides[l:l+2] pts = [] for m in [0,1]: # points in this face p1 = edgeKey[edges[m]][0] # p1, p2 are points at either side of an edge p2 = edgeKey[edges[m]][1] v1 = data[i+p1[0], j+p1[1]] # v1 and v2 are the values at p1 and p2 v2 = data[i+p2[0], j+p2[1]] f = (level-v1) / (v2-v1) fi = 1.0 - f p = ( ## interpolate between corners p1[0]*fi + p2[0]*f + i + 0.5, p1[1]*fi + p2[1]*f + j + 0.5 ) if extendToEdge: ## check bounds p = ( min(data.shape[0]-2, max(0, p[0]-1)), min(data.shape[1]-2, max(0, p[1]-1)), ) if connected: gridKey = i + (1 if edges[m]==2 else 0), j + (1 if edges[m]==3 else 0), edges[m]%2 pts.append((p, gridKey)) ## give the actual position and a key identifying the grid location (for connecting segments) else: pts.append(p) lines.append(pts) if not connected: return lines ## turn disjoint list of segments into continuous lines #lines = [[2,5], [5,4], [3,4], [1,3], [6,7], [7,8], [8,6], [11,12], [12,15], [11,13], [13,14]] #lines = [[(float(a), a), (float(b), b)] for a,b in lines] points = {} ## maps each point to its connections for a,b in lines: if a[1] not in points: points[a[1]] = [] points[a[1]].append([a,b]) if b[1] not in points: points[b[1]] = [] points[b[1]].append([b,a]) ## rearrange into chains for k in list(points.keys()): try: chains = points[k] except KeyError: ## already used this point elsewhere continue #print "===========", k for chain in chains: #print " chain:", chain x = None while True: if x == chain[-1][1]: break ## nothing left to do on this chain x = chain[-1][1] if x == k: break ## chain has looped; we're done and can ignore the opposite chain y = chain[-2][1] connects = points[x] for conn in connects[:]: if conn[1][1] != y: #print " ext:", conn chain.extend(conn[1:]) #print " del:", x del points[x] if chain[0][1] == chain[-1][1]: # looped chain; no need to continue the other direction chains.pop() break ## extract point locations lines = [] for chain in points.values(): if len(chain) == 2: chain = chain[1][1:][::-1] + chain[0] # join together ends of chain else: chain = chain[0] lines.append([p[0] for p in chain]) if not path: return lines ## a list of pairs of points path = QtGui.QPainterPath() for line in lines: path.moveTo(*line[0]) for p in line[1:]: path.lineTo(*p) return path def traceImage(image, values, smooth=0.5): """ Convert an image to a set of QPainterPath curves. One curve will be generated for each item in *values*; each curve outlines the area of the image that is closer to its value than to any others. If image is RGB or RGBA, then the shape of values should be (nvals, 3/4) The parameter *smooth* is expressed in pixels. """ try: import scipy.ndimage as ndi except ImportError: raise Exception("traceImage() requires the package scipy.ndimage, but it is not importable.") if values.ndim == 2: values = values.T values = values[np.newaxis, np.newaxis, ...].astype(float) image = image[..., np.newaxis].astype(float) diff = np.abs(image-values) if values.ndim == 4: diff = diff.sum(axis=2) labels = np.argmin(diff, axis=2) paths = [] for i in range(diff.shape[-1]): d = (labels==i).astype(float) d = gaussianFilter(d, (smooth, smooth)) lines = isocurve(d, 0.5, connected=True, extendToEdge=True) path = QtGui.QPainterPath() for line in lines: path.moveTo(*line[0]) for p in line[1:]: path.lineTo(*p) paths.append(path) return paths IsosurfaceDataCache = None def isosurface(data, level): """ Generate isosurface from volumetric data using marching cubes algorithm. See Paul Bourke, "Polygonising a Scalar Field" (http://paulbourke.net/geometry/polygonise/) *data* 3D numpy array of scalar values. Must be contiguous. *level* The level at which to generate an isosurface Returns an array of vertex coordinates (Nv, 3) and an array of per-face vertex indexes (Nf, 3) """ ## For improvement, see: ## ## Efficient implementation of Marching Cubes' cases with topological guarantees. ## Thomas Lewiner, Helio Lopes, Antonio Wilson Vieira and Geovan Tavares. ## Journal of Graphics Tools 8(2): pp. 1-15 (december 2003) ## Precompute lookup tables on the first run global IsosurfaceDataCache if IsosurfaceDataCache is None: ## map from grid cell index to edge index. ## grid cell index tells us which corners are below the isosurface, ## edge index tells us which edges are cut by the isosurface. ## (Data stolen from Bourk; see above.) edgeTable = np.array([ 0x0 , 0x109, 0x203, 0x30a, 0x406, 0x50f, 0x605, 0x70c, 0x80c, 0x905, 0xa0f, 0xb06, 0xc0a, 0xd03, 0xe09, 0xf00, 0x190, 0x99 , 0x393, 0x29a, 0x596, 0x49f, 0x795, 0x69c, 0x99c, 0x895, 0xb9f, 0xa96, 0xd9a, 0xc93, 0xf99, 0xe90, 0x230, 0x339, 0x33 , 0x13a, 0x636, 0x73f, 0x435, 0x53c, 0xa3c, 0xb35, 0x83f, 0x936, 0xe3a, 0xf33, 0xc39, 0xd30, 0x3a0, 0x2a9, 0x1a3, 0xaa , 0x7a6, 0x6af, 0x5a5, 0x4ac, 0xbac, 0xaa5, 0x9af, 0x8a6, 0xfaa, 0xea3, 0xda9, 0xca0, 0x460, 0x569, 0x663, 0x76a, 0x66 , 0x16f, 0x265, 0x36c, 0xc6c, 0xd65, 0xe6f, 0xf66, 0x86a, 0x963, 0xa69, 0xb60, 0x5f0, 0x4f9, 0x7f3, 0x6fa, 0x1f6, 0xff , 0x3f5, 0x2fc, 0xdfc, 0xcf5, 0xfff, 0xef6, 0x9fa, 0x8f3, 0xbf9, 0xaf0, 0x650, 0x759, 0x453, 0x55a, 0x256, 0x35f, 0x55 , 0x15c, 0xe5c, 0xf55, 0xc5f, 0xd56, 0xa5a, 0xb53, 0x859, 0x950, 0x7c0, 0x6c9, 0x5c3, 0x4ca, 0x3c6, 0x2cf, 0x1c5, 0xcc , 0xfcc, 0xec5, 0xdcf, 0xcc6, 0xbca, 0xac3, 0x9c9, 0x8c0, 0x8c0, 0x9c9, 0xac3, 0xbca, 0xcc6, 0xdcf, 0xec5, 0xfcc, 0xcc , 0x1c5, 0x2cf, 0x3c6, 0x4ca, 0x5c3, 0x6c9, 0x7c0, 0x950, 0x859, 0xb53, 0xa5a, 0xd56, 0xc5f, 0xf55, 0xe5c, 0x15c, 0x55 , 0x35f, 0x256, 0x55a, 0x453, 0x759, 0x650, 0xaf0, 0xbf9, 0x8f3, 0x9fa, 0xef6, 0xfff, 0xcf5, 0xdfc, 0x2fc, 0x3f5, 0xff , 0x1f6, 0x6fa, 0x7f3, 0x4f9, 0x5f0, 0xb60, 0xa69, 0x963, 0x86a, 0xf66, 0xe6f, 0xd65, 0xc6c, 0x36c, 0x265, 0x16f, 0x66 , 0x76a, 0x663, 0x569, 0x460, 0xca0, 0xda9, 0xea3, 0xfaa, 0x8a6, 0x9af, 0xaa5, 0xbac, 0x4ac, 0x5a5, 0x6af, 0x7a6, 0xaa , 0x1a3, 0x2a9, 0x3a0, 0xd30, 0xc39, 0xf33, 0xe3a, 0x936, 0x83f, 0xb35, 0xa3c, 0x53c, 0x435, 0x73f, 0x636, 0x13a, 0x33 , 0x339, 0x230, 0xe90, 0xf99, 0xc93, 0xd9a, 0xa96, 0xb9f, 0x895, 0x99c, 0x69c, 0x795, 0x49f, 0x596, 0x29a, 0x393, 0x99 , 0x190, 0xf00, 0xe09, 0xd03, 0xc0a, 0xb06, 0xa0f, 0x905, 0x80c, 0x70c, 0x605, 0x50f, 0x406, 0x30a, 0x203, 0x109, 0x0 ], dtype=np.uint16) ## Table of triangles to use for filling each grid cell. ## Each set of three integers tells us which three edges to ## draw a triangle between. ## (Data stolen from Bourk; see above.) triTable = [ [], [0, 8, 3], [0, 1, 9], [1, 8, 3, 9, 8, 1], [1, 2, 10], [0, 8, 3, 1, 2, 10], [9, 2, 10, 0, 2, 9], [2, 8, 3, 2, 10, 8, 10, 9, 8], [3, 11, 2], [0, 11, 2, 8, 11, 0], [1, 9, 0, 2, 3, 11], [1, 11, 2, 1, 9, 11, 9, 8, 11], [3, 10, 1, 11, 10, 3], [0, 10, 1, 0, 8, 10, 8, 11, 10], [3, 9, 0, 3, 11, 9, 11, 10, 9], [9, 8, 10, 10, 8, 11], [4, 7, 8], [4, 3, 0, 7, 3, 4], [0, 1, 9, 8, 4, 7], [4, 1, 9, 4, 7, 1, 7, 3, 1], [1, 2, 10, 8, 4, 7], [3, 4, 7, 3, 0, 4, 1, 2, 10], [9, 2, 10, 9, 0, 2, 8, 4, 7], [2, 10, 9, 2, 9, 7, 2, 7, 3, 7, 9, 4], [8, 4, 7, 3, 11, 2], [11, 4, 7, 11, 2, 4, 2, 0, 4], [9, 0, 1, 8, 4, 7, 2, 3, 11], [4, 7, 11, 9, 4, 11, 9, 11, 2, 9, 2, 1], [3, 10, 1, 3, 11, 10, 7, 8, 4], [1, 11, 10, 1, 4, 11, 1, 0, 4, 7, 11, 4], [4, 7, 8, 9, 0, 11, 9, 11, 10, 11, 0, 3], [4, 7, 11, 4, 11, 9, 9, 11, 10], [9, 5, 4], [9, 5, 4, 0, 8, 3], [0, 5, 4, 1, 5, 0], [8, 5, 4, 8, 3, 5, 3, 1, 5], [1, 2, 10, 9, 5, 4], [3, 0, 8, 1, 2, 10, 4, 9, 5], [5, 2, 10, 5, 4, 2, 4, 0, 2], [2, 10, 5, 3, 2, 5, 3, 5, 4, 3, 4, 8], [9, 5, 4, 2, 3, 11], [0, 11, 2, 0, 8, 11, 4, 9, 5], [0, 5, 4, 0, 1, 5, 2, 3, 11], [2, 1, 5, 2, 5, 8, 2, 8, 11, 4, 8, 5], [10, 3, 11, 10, 1, 3, 9, 5, 4], [4, 9, 5, 0, 8, 1, 8, 10, 1, 8, 11, 10], [5, 4, 0, 5, 0, 11, 5, 11, 10, 11, 0, 3], [5, 4, 8, 5, 8, 10, 10, 8, 11], [9, 7, 8, 5, 7, 9], [9, 3, 0, 9, 5, 3, 5, 7, 3], [0, 7, 8, 0, 1, 7, 1, 5, 7], [1, 5, 3, 3, 5, 7], [9, 7, 8, 9, 5, 7, 10, 1, 2], [10, 1, 2, 9, 5, 0, 5, 3, 0, 5, 7, 3], [8, 0, 2, 8, 2, 5, 8, 5, 7, 10, 5, 2], [2, 10, 5, 2, 5, 3, 3, 5, 7], [7, 9, 5, 7, 8, 9, 3, 11, 2], [9, 5, 7, 9, 7, 2, 9, 2, 0, 2, 7, 11], [2, 3, 11, 0, 1, 8, 1, 7, 8, 1, 5, 7], [11, 2, 1, 11, 1, 7, 7, 1, 5], [9, 5, 8, 8, 5, 7, 10, 1, 3, 10, 3, 11], [5, 7, 0, 5, 0, 9, 7, 11, 0, 1, 0, 10, 11, 10, 0], [11, 10, 0, 11, 0, 3, 10, 5, 0, 8, 0, 7, 5, 7, 0], [11, 10, 5, 7, 11, 5], [10, 6, 5], [0, 8, 3, 5, 10, 6], [9, 0, 1, 5, 10, 6], [1, 8, 3, 1, 9, 8, 5, 10, 6], [1, 6, 5, 2, 6, 1], [1, 6, 5, 1, 2, 6, 3, 0, 8], [9, 6, 5, 9, 0, 6, 0, 2, 6], [5, 9, 8, 5, 8, 2, 5, 2, 6, 3, 2, 8], [2, 3, 11, 10, 6, 5], [11, 0, 8, 11, 2, 0, 10, 6, 5], [0, 1, 9, 2, 3, 11, 5, 10, 6], [5, 10, 6, 1, 9, 2, 9, 11, 2, 9, 8, 11], [6, 3, 11, 6, 5, 3, 5, 1, 3], [0, 8, 11, 0, 11, 5, 0, 5, 1, 5, 11, 6], [3, 11, 6, 0, 3, 6, 0, 6, 5, 0, 5, 9], [6, 5, 9, 6, 9, 11, 11, 9, 8], [5, 10, 6, 4, 7, 8], [4, 3, 0, 4, 7, 3, 6, 5, 10], [1, 9, 0, 5, 10, 6, 8, 4, 7], [10, 6, 5, 1, 9, 7, 1, 7, 3, 7, 9, 4], [6, 1, 2, 6, 5, 1, 4, 7, 8], [1, 2, 5, 5, 2, 6, 3, 0, 4, 3, 4, 7], [8, 4, 7, 9, 0, 5, 0, 6, 5, 0, 2, 6], [7, 3, 9, 7, 9, 4, 3, 2, 9, 5, 9, 6, 2, 6, 9], [3, 11, 2, 7, 8, 4, 10, 6, 5], [5, 10, 6, 4, 7, 2, 4, 2, 0, 2, 7, 11], [0, 1, 9, 4, 7, 8, 2, 3, 11, 5, 10, 6], [9, 2, 1, 9, 11, 2, 9, 4, 11, 7, 11, 4, 5, 10, 6], [8, 4, 7, 3, 11, 5, 3, 5, 1, 5, 11, 6], [5, 1, 11, 5, 11, 6, 1, 0, 11, 7, 11, 4, 0, 4, 11], [0, 5, 9, 0, 6, 5, 0, 3, 6, 11, 6, 3, 8, 4, 7], [6, 5, 9, 6, 9, 11, 4, 7, 9, 7, 11, 9], [10, 4, 9, 6, 4, 10], [4, 10, 6, 4, 9, 10, 0, 8, 3], [10, 0, 1, 10, 6, 0, 6, 4, 0], [8, 3, 1, 8, 1, 6, 8, 6, 4, 6, 1, 10], [1, 4, 9, 1, 2, 4, 2, 6, 4], [3, 0, 8, 1, 2, 9, 2, 4, 9, 2, 6, 4], [0, 2, 4, 4, 2, 6], [8, 3, 2, 8, 2, 4, 4, 2, 6], [10, 4, 9, 10, 6, 4, 11, 2, 3], [0, 8, 2, 2, 8, 11, 4, 9, 10, 4, 10, 6], [3, 11, 2, 0, 1, 6, 0, 6, 4, 6, 1, 10], [6, 4, 1, 6, 1, 10, 4, 8, 1, 2, 1, 11, 8, 11, 1], [9, 6, 4, 9, 3, 6, 9, 1, 3, 11, 6, 3], [8, 11, 1, 8, 1, 0, 11, 6, 1, 9, 1, 4, 6, 4, 1], [3, 11, 6, 3, 6, 0, 0, 6, 4], [6, 4, 8, 11, 6, 8], [7, 10, 6, 7, 8, 10, 8, 9, 10], [0, 7, 3, 0, 10, 7, 0, 9, 10, 6, 7, 10], [10, 6, 7, 1, 10, 7, 1, 7, 8, 1, 8, 0], [10, 6, 7, 10, 7, 1, 1, 7, 3], [1, 2, 6, 1, 6, 8, 1, 8, 9, 8, 6, 7], [2, 6, 9, 2, 9, 1, 6, 7, 9, 0, 9, 3, 7, 3, 9], [7, 8, 0, 7, 0, 6, 6, 0, 2], [7, 3, 2, 6, 7, 2], [2, 3, 11, 10, 6, 8, 10, 8, 9, 8, 6, 7], [2, 0, 7, 2, 7, 11, 0, 9, 7, 6, 7, 10, 9, 10, 7], [1, 8, 0, 1, 7, 8, 1, 10, 7, 6, 7, 10, 2, 3, 11], [11, 2, 1, 11, 1, 7, 10, 6, 1, 6, 7, 1], [8, 9, 6, 8, 6, 7, 9, 1, 6, 11, 6, 3, 1, 3, 6], [0, 9, 1, 11, 6, 7], [7, 8, 0, 7, 0, 6, 3, 11, 0, 11, 6, 0], [7, 11, 6], [7, 6, 11], [3, 0, 8, 11, 7, 6], [0, 1, 9, 11, 7, 6], [8, 1, 9, 8, 3, 1, 11, 7, 6], [10, 1, 2, 6, 11, 7], [1, 2, 10, 3, 0, 8, 6, 11, 7], [2, 9, 0, 2, 10, 9, 6, 11, 7], [6, 11, 7, 2, 10, 3, 10, 8, 3, 10, 9, 8], [7, 2, 3, 6, 2, 7], [7, 0, 8, 7, 6, 0, 6, 2, 0], [2, 7, 6, 2, 3, 7, 0, 1, 9], [1, 6, 2, 1, 8, 6, 1, 9, 8, 8, 7, 6], [10, 7, 6, 10, 1, 7, 1, 3, 7], [10, 7, 6, 1, 7, 10, 1, 8, 7, 1, 0, 8], [0, 3, 7, 0, 7, 10, 0, 10, 9, 6, 10, 7], [7, 6, 10, 7, 10, 8, 8, 10, 9], [6, 8, 4, 11, 8, 6], [3, 6, 11, 3, 0, 6, 0, 4, 6], [8, 6, 11, 8, 4, 6, 9, 0, 1], [9, 4, 6, 9, 6, 3, 9, 3, 1, 11, 3, 6], [6, 8, 4, 6, 11, 8, 2, 10, 1], [1, 2, 10, 3, 0, 11, 0, 6, 11, 0, 4, 6], [4, 11, 8, 4, 6, 11, 0, 2, 9, 2, 10, 9], [10, 9, 3, 10, 3, 2, 9, 4, 3, 11, 3, 6, 4, 6, 3], [8, 2, 3, 8, 4, 2, 4, 6, 2], [0, 4, 2, 4, 6, 2], [1, 9, 0, 2, 3, 4, 2, 4, 6, 4, 3, 8], [1, 9, 4, 1, 4, 2, 2, 4, 6], [8, 1, 3, 8, 6, 1, 8, 4, 6, 6, 10, 1], [10, 1, 0, 10, 0, 6, 6, 0, 4], [4, 6, 3, 4, 3, 8, 6, 10, 3, 0, 3, 9, 10, 9, 3], [10, 9, 4, 6, 10, 4], [4, 9, 5, 7, 6, 11], [0, 8, 3, 4, 9, 5, 11, 7, 6], [5, 0, 1, 5, 4, 0, 7, 6, 11], [11, 7, 6, 8, 3, 4, 3, 5, 4, 3, 1, 5], [9, 5, 4, 10, 1, 2, 7, 6, 11], [6, 11, 7, 1, 2, 10, 0, 8, 3, 4, 9, 5], [7, 6, 11, 5, 4, 10, 4, 2, 10, 4, 0, 2], [3, 4, 8, 3, 5, 4, 3, 2, 5, 10, 5, 2, 11, 7, 6], [7, 2, 3, 7, 6, 2, 5, 4, 9], [9, 5, 4, 0, 8, 6, 0, 6, 2, 6, 8, 7], [3, 6, 2, 3, 7, 6, 1, 5, 0, 5, 4, 0], [6, 2, 8, 6, 8, 7, 2, 1, 8, 4, 8, 5, 1, 5, 8], [9, 5, 4, 10, 1, 6, 1, 7, 6, 1, 3, 7], [1, 6, 10, 1, 7, 6, 1, 0, 7, 8, 7, 0, 9, 5, 4], [4, 0, 10, 4, 10, 5, 0, 3, 10, 6, 10, 7, 3, 7, 10], [7, 6, 10, 7, 10, 8, 5, 4, 10, 4, 8, 10], [6, 9, 5, 6, 11, 9, 11, 8, 9], [3, 6, 11, 0, 6, 3, 0, 5, 6, 0, 9, 5], [0, 11, 8, 0, 5, 11, 0, 1, 5, 5, 6, 11], [6, 11, 3, 6, 3, 5, 5, 3, 1], [1, 2, 10, 9, 5, 11, 9, 11, 8, 11, 5, 6], [0, 11, 3, 0, 6, 11, 0, 9, 6, 5, 6, 9, 1, 2, 10], [11, 8, 5, 11, 5, 6, 8, 0, 5, 10, 5, 2, 0, 2, 5], [6, 11, 3, 6, 3, 5, 2, 10, 3, 10, 5, 3], [5, 8, 9, 5, 2, 8, 5, 6, 2, 3, 8, 2], [9, 5, 6, 9, 6, 0, 0, 6, 2], [1, 5, 8, 1, 8, 0, 5, 6, 8, 3, 8, 2, 6, 2, 8], [1, 5, 6, 2, 1, 6], [1, 3, 6, 1, 6, 10, 3, 8, 6, 5, 6, 9, 8, 9, 6], [10, 1, 0, 10, 0, 6, 9, 5, 0, 5, 6, 0], [0, 3, 8, 5, 6, 10], [10, 5, 6], [11, 5, 10, 7, 5, 11], [11, 5, 10, 11, 7, 5, 8, 3, 0], [5, 11, 7, 5, 10, 11, 1, 9, 0], [10, 7, 5, 10, 11, 7, 9, 8, 1, 8, 3, 1], [11, 1, 2, 11, 7, 1, 7, 5, 1], [0, 8, 3, 1, 2, 7, 1, 7, 5, 7, 2, 11], [9, 7, 5, 9, 2, 7, 9, 0, 2, 2, 11, 7], [7, 5, 2, 7, 2, 11, 5, 9, 2, 3, 2, 8, 9, 8, 2], [2, 5, 10, 2, 3, 5, 3, 7, 5], [8, 2, 0, 8, 5, 2, 8, 7, 5, 10, 2, 5], [9, 0, 1, 5, 10, 3, 5, 3, 7, 3, 10, 2], [9, 8, 2, 9, 2, 1, 8, 7, 2, 10, 2, 5, 7, 5, 2], [1, 3, 5, 3, 7, 5], [0, 8, 7, 0, 7, 1, 1, 7, 5], [9, 0, 3, 9, 3, 5, 5, 3, 7], [9, 8, 7, 5, 9, 7], [5, 8, 4, 5, 10, 8, 10, 11, 8], [5, 0, 4, 5, 11, 0, 5, 10, 11, 11, 3, 0], [0, 1, 9, 8, 4, 10, 8, 10, 11, 10, 4, 5], [10, 11, 4, 10, 4, 5, 11, 3, 4, 9, 4, 1, 3, 1, 4], [2, 5, 1, 2, 8, 5, 2, 11, 8, 4, 5, 8], [0, 4, 11, 0, 11, 3, 4, 5, 11, 2, 11, 1, 5, 1, 11], [0, 2, 5, 0, 5, 9, 2, 11, 5, 4, 5, 8, 11, 8, 5], [9, 4, 5, 2, 11, 3], [2, 5, 10, 3, 5, 2, 3, 4, 5, 3, 8, 4], [5, 10, 2, 5, 2, 4, 4, 2, 0], [3, 10, 2, 3, 5, 10, 3, 8, 5, 4, 5, 8, 0, 1, 9], [5, 10, 2, 5, 2, 4, 1, 9, 2, 9, 4, 2], [8, 4, 5, 8, 5, 3, 3, 5, 1], [0, 4, 5, 1, 0, 5], [8, 4, 5, 8, 5, 3, 9, 0, 5, 0, 3, 5], [9, 4, 5], [4, 11, 7, 4, 9, 11, 9, 10, 11], [0, 8, 3, 4, 9, 7, 9, 11, 7, 9, 10, 11], [1, 10, 11, 1, 11, 4, 1, 4, 0, 7, 4, 11], [3, 1, 4, 3, 4, 8, 1, 10, 4, 7, 4, 11, 10, 11, 4], [4, 11, 7, 9, 11, 4, 9, 2, 11, 9, 1, 2], [9, 7, 4, 9, 11, 7, 9, 1, 11, 2, 11, 1, 0, 8, 3], [11, 7, 4, 11, 4, 2, 2, 4, 0], [11, 7, 4, 11, 4, 2, 8, 3, 4, 3, 2, 4], [2, 9, 10, 2, 7, 9, 2, 3, 7, 7, 4, 9], [9, 10, 7, 9, 7, 4, 10, 2, 7, 8, 7, 0, 2, 0, 7], [3, 7, 10, 3, 10, 2, 7, 4, 10, 1, 10, 0, 4, 0, 10], [1, 10, 2, 8, 7, 4], [4, 9, 1, 4, 1, 7, 7, 1, 3], [4, 9, 1, 4, 1, 7, 0, 8, 1, 8, 7, 1], [4, 0, 3, 7, 4, 3], [4, 8, 7], [9, 10, 8, 10, 11, 8], [3, 0, 9, 3, 9, 11, 11, 9, 10], [0, 1, 10, 0, 10, 8, 8, 10, 11], [3, 1, 10, 11, 3, 10], [1, 2, 11, 1, 11, 9, 9, 11, 8], [3, 0, 9, 3, 9, 11, 1, 2, 9, 2, 11, 9], [0, 2, 11, 8, 0, 11], [3, 2, 11], [2, 3, 8, 2, 8, 10, 10, 8, 9], [9, 10, 2, 0, 9, 2], [2, 3, 8, 2, 8, 10, 0, 1, 8, 1, 10, 8], [1, 10, 2], [1, 3, 8, 9, 1, 8], [0, 9, 1], [0, 3, 8], [] ] edgeShifts = np.array([ ## maps edge ID (0-11) to (x,y,z) cell offset and edge ID (0-2) [0, 0, 0, 0], [1, 0, 0, 1], [0, 1, 0, 0], [0, 0, 0, 1], [0, 0, 1, 0], [1, 0, 1, 1], [0, 1, 1, 0], [0, 0, 1, 1], [0, 0, 0, 2], [1, 0, 0, 2], [1, 1, 0, 2], [0, 1, 0, 2], #[9, 9, 9, 9] ## fake ], dtype=np.uint16) # don't use ubyte here! This value gets added to cell index later; will need the extra precision. nTableFaces = np.array([len(f)/3 for f in triTable], dtype=np.ubyte) faceShiftTables = [None] for i in range(1,6): ## compute lookup table of index: vertexes mapping faceTableI = np.zeros((len(triTable), i*3), dtype=np.ubyte) faceTableInds = np.argwhere(nTableFaces == i) faceTableI[faceTableInds[:,0]] = np.array([triTable[j] for j in faceTableInds]) faceTableI = faceTableI.reshape((len(triTable), i, 3)) faceShiftTables.append(edgeShifts[faceTableI]) ## Let's try something different: #faceTable = np.empty((256, 5, 3, 4), dtype=np.ubyte) # (grid cell index, faces, vertexes, edge lookup) #for i,f in enumerate(triTable): #f = np.array(f + [12] * (15-len(f))).reshape(5,3) #faceTable[i] = edgeShifts[f] IsosurfaceDataCache = (faceShiftTables, edgeShifts, edgeTable, nTableFaces) else: faceShiftTables, edgeShifts, edgeTable, nTableFaces = IsosurfaceDataCache # We use strides below, which means we need contiguous array input. # Ideally we can fix this just by removing the dependency on strides. if not data.flags['C_CONTIGUOUS']: raise TypeError("isosurface input data must be c-contiguous.") ## mark everything below the isosurface level mask = data < level ### make eight sub-fields and compute indexes for grid cells index = np.zeros([x-1 for x in data.shape], dtype=np.ubyte) fields = np.empty((2,2,2), dtype=object) slices = [slice(0,-1), slice(1,None)] for i in [0,1]: for j in [0,1]: for k in [0,1]: fields[i,j,k] = mask[slices[i], slices[j], slices[k]] vertIndex = i - 2*j*i + 3*j + 4*k ## this is just to match Bourk's vertex numbering scheme np.add(index, fields[i,j,k] * 2**vertIndex, out=index, casting='unsafe') ### Generate table of edges that have been cut cutEdges = np.zeros([x+1 for x in index.shape]+[3], dtype=np.uint32) edges = edgeTable[index] for i, shift in enumerate(edgeShifts[:12]): slices = [slice(shift[j],cutEdges.shape[j]+(shift[j]-1)) for j in range(3)] cutEdges[slices[0], slices[1], slices[2], shift[3]] += edges & 2**i ## for each cut edge, interpolate to see where exactly the edge is cut and generate vertex positions m = cutEdges > 0 vertexInds = np.argwhere(m) ## argwhere is slow! vertexes = vertexInds[:,:3].astype(np.float32) dataFlat = data.reshape(data.shape[0]*data.shape[1]*data.shape[2]) ## re-use the cutEdges array as a lookup table for vertex IDs cutEdges[vertexInds[:,0], vertexInds[:,1], vertexInds[:,2], vertexInds[:,3]] = np.arange(vertexInds.shape[0]) for i in [0,1,2]: vim = vertexInds[:,3] == i vi = vertexInds[vim, :3] viFlat = (vi * (np.array(data.strides[:3]) // data.itemsize)[np.newaxis,:]).sum(axis=1) v1 = dataFlat[viFlat] v2 = dataFlat[viFlat + data.strides[i]//data.itemsize] vertexes[vim,i] += (level-v1) / (v2-v1) ### compute the set of vertex indexes for each face. ## This works, but runs a bit slower. #cells = np.argwhere((index != 0) & (index != 255)) ## all cells with at least one face #cellInds = index[cells[:,0], cells[:,1], cells[:,2]] #verts = faceTable[cellInds] #mask = verts[...,0,0] != 9 #verts[...,:3] += cells[:,np.newaxis,np.newaxis,:] ## we now have indexes into cutEdges #verts = verts[mask] #faces = cutEdges[verts[...,0], verts[...,1], verts[...,2], verts[...,3]] ## and these are the vertex indexes we want. ## To allow this to be vectorized efficiently, we count the number of faces in each ## grid cell and handle each group of cells with the same number together. ## determine how many faces to assign to each grid cell nFaces = nTableFaces[index] totFaces = nFaces.sum() faces = np.empty((totFaces, 3), dtype=np.uint32) ptr = 0 #import debug #p = debug.Profiler() ## this helps speed up an indexing operation later on cs = np.array(cutEdges.strides)//cutEdges.itemsize cutEdges = cutEdges.flatten() ## this, strangely, does not seem to help. #ins = np.array(index.strides)/index.itemsize #index = index.flatten() for i in range(1,6): ### expensive: #profiler() cells = np.argwhere(nFaces == i) ## all cells which require i faces (argwhere is expensive) #profiler() if cells.shape[0] == 0: continue cellInds = index[cells[:,0], cells[:,1], cells[:,2]] ## index values of cells to process for this round #profiler() ### expensive: verts = faceShiftTables[i][cellInds] #profiler() np.add(verts[...,:3], cells[:,np.newaxis,np.newaxis,:], out=verts[...,:3], casting='unsafe') ## we now have indexes into cutEdges verts = verts.reshape((verts.shape[0]*i,)+verts.shape[2:]) #profiler() ### expensive: verts = (verts * cs[np.newaxis, np.newaxis, :]).sum(axis=2) vertInds = cutEdges[verts] #profiler() nv = vertInds.shape[0] #profiler() faces[ptr:ptr+nv] = vertInds #.reshape((nv, 3)) #profiler() ptr += nv return vertexes, faces def invertQTransform(tr): """Return a QTransform that is the inverse of *tr*. Rasises an exception if tr is not invertible. Note that this function is preferred over QTransform.inverted() due to bugs in that method. (specifically, Qt has floating-point precision issues when determining whether a matrix is invertible) """ try: import numpy.linalg arr = np.array([[tr.m11(), tr.m12(), tr.m13()], [tr.m21(), tr.m22(), tr.m23()], [tr.m31(), tr.m32(), tr.m33()]]) inv = numpy.linalg.inv(arr) return QtGui.QTransform(inv[0,0], inv[0,1], inv[0,2], inv[1,0], inv[1,1], inv[1,2], inv[2,0], inv[2,1]) except ImportError: inv = tr.inverted() if inv[1] is False: raise Exception("Transform is not invertible.") return inv[0] def pseudoScatter(data, spacing=None, shuffle=True, bidir=False): """ Used for examining the distribution of values in a set. Produces scattering as in beeswarm or column scatter plots. Given a list of x-values, construct a set of y-values such that an x,y scatter-plot will not have overlapping points (it will look similar to a histogram). """ inds = np.arange(len(data)) if shuffle: np.random.shuffle(inds) data = data[inds] if spacing is None: spacing = 2.*np.std(data)/len(data)**0.5 s2 = spacing**2 yvals = np.empty(len(data)) if len(data) == 0: return yvals yvals[0] = 0 for i in range(1,len(data)): x = data[i] # current x value to be placed x0 = data[:i] # all x values already placed y0 = yvals[:i] # all y values already placed y = 0 dx = (x0-x)**2 # x-distance to each previous point xmask = dx < s2 # exclude anything too far away if xmask.sum() > 0: if bidir: dirs = [-1, 1] else: dirs = [1] yopts = [] for direction in dirs: y = 0 dx2 = dx[xmask] dy = (s2 - dx2)**0.5 limits = np.empty((2,len(dy))) # ranges of y-values to exclude limits[0] = y0[xmask] - dy limits[1] = y0[xmask] + dy while True: # ignore anything below this y-value if direction > 0: mask = limits[1] >= y else: mask = limits[0] <= y limits2 = limits[:,mask] # are we inside an excluded region? mask = (limits2[0] < y) & (limits2[1] > y) if mask.sum() == 0: break if direction > 0: y = limits2[:,mask].max() else: y = limits2[:,mask].min() yopts.append(y) if bidir: y = yopts[0] if -yopts[0] < yopts[1] else yopts[1] else: y = yopts[0] yvals[i] = y return yvals[np.argsort(inds)] ## un-shuffle values before returning def toposort(deps, nodes=None, seen=None, stack=None, depth=0): """Topological sort. Arguments are: deps dictionary describing dependencies where a:[b,c] means "a depends on b and c" nodes optional, specifies list of starting nodes (these should be the nodes which are not depended on by any other nodes). Other candidate starting nodes will be ignored. Example:: # Sort the following graph: # # B ──┬─────> C <── D # │ │ # E <─┴─> A <─┘ # deps = {'a': ['b', 'c'], 'c': ['b', 'd'], 'e': ['b']} toposort(deps) => ['b', 'd', 'c', 'a', 'e'] """ # fill in empty dep lists deps = deps.copy() for k,v in list(deps.items()): for k in v: if k not in deps: deps[k] = [] if nodes is None: ## run through deps to find nodes that are not depended upon rem = set() for dep in deps.values(): rem |= set(dep) nodes = set(deps.keys()) - rem if seen is None: seen = set() stack = [] sorted = [] for n in nodes: if n in stack: raise Exception("Cyclic dependency detected", stack + [n]) if n in seen: continue seen.add(n) sorted.extend( toposort(deps, deps[n], seen, stack+[n], depth=depth+1)) sorted.append(n) return sorted pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/000077500000000000000000000000001300727121400224425ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/ArrowItem.py000066400000000000000000000110571300727121400247310ustar00rootroot00000000000000from ..Qt import QtGui, QtCore from .. import functions as fn import numpy as np __all__ = ['ArrowItem'] class ArrowItem(QtGui.QGraphicsPathItem): """ For displaying scale-invariant arrows. For arrows pointing to a location on a curve, see CurveArrow """ def __init__(self, **opts): """ Arrows can be initialized with any keyword arguments accepted by the setStyle() method. """ self.opts = {} QtGui.QGraphicsPathItem.__init__(self, opts.get('parent', None)) if 'size' in opts: opts['headLen'] = opts['size'] if 'width' in opts: opts['headWidth'] = opts['width'] defaultOpts = { 'pxMode': True, 'angle': -150, ## If the angle is 0, the arrow points left 'pos': (0,0), 'headLen': 20, 'tipAngle': 25, 'baseAngle': 0, 'tailLen': None, 'tailWidth': 3, 'pen': (200,200,200), 'brush': (50,50,200), } defaultOpts.update(opts) self.setStyle(**defaultOpts) self.rotate(self.opts['angle']) self.moveBy(*self.opts['pos']) def setStyle(self, **opts): """ Changes the appearance of the arrow. All arguments are optional: ====================== ================================================= **Keyword Arguments:** angle Orientation of the arrow in degrees. Default is 0; arrow pointing to the left. headLen Length of the arrow head, from tip to base. default=20 headWidth Width of the arrow head at its base. tipAngle Angle of the tip of the arrow in degrees. Smaller values make a 'sharper' arrow. If tipAngle is specified, ot overrides headWidth. default=25 baseAngle Angle of the base of the arrow head. Default is 0, which means that the base of the arrow head is perpendicular to the arrow tail. tailLen Length of the arrow tail, measured from the base of the arrow head to the end of the tail. If this value is None, no tail will be drawn. default=None tailWidth Width of the tail. default=3 pen The pen used to draw the outline of the arrow. brush The brush used to fill the arrow. ====================== ================================================= """ self.opts.update(opts) opt = dict([(k,self.opts[k]) for k in ['headLen', 'tipAngle', 'baseAngle', 'tailLen', 'tailWidth']]) self.path = fn.makeArrowPath(**opt) self.setPath(self.path) self.setPen(fn.mkPen(self.opts['pen'])) self.setBrush(fn.mkBrush(self.opts['brush'])) if self.opts['pxMode']: self.setFlags(self.flags() | self.ItemIgnoresTransformations) else: self.setFlags(self.flags() & ~self.ItemIgnoresTransformations) def paint(self, p, *args): p.setRenderHint(QtGui.QPainter.Antialiasing) QtGui.QGraphicsPathItem.paint(self, p, *args) #p.setPen(fn.mkPen('r')) #p.setBrush(fn.mkBrush(None)) #p.drawRect(self.boundingRect()) def shape(self): #if not self.opts['pxMode']: #return QtGui.QGraphicsPathItem.shape(self) return self.path ## dataBounds and pixelPadding methods are provided to ensure ViewBox can ## properly auto-range def dataBounds(self, ax, frac, orthoRange=None): pw = 0 pen = self.pen() if not pen.isCosmetic(): pw = pen.width() * 0.7072 if self.opts['pxMode']: return [0,0] else: br = self.boundingRect() if ax == 0: return [br.left()-pw, br.right()+pw] else: return [br.top()-pw, br.bottom()+pw] def pixelPadding(self): pad = 0 if self.opts['pxMode']: br = self.boundingRect() pad += (br.width()**2 + br.height()**2) ** 0.5 pen = self.pen() if pen.isCosmetic(): pad += max(1, pen.width()) * 0.7072 return pad pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/AxisItem.py000066400000000000000000001253411300727121400245450ustar00rootroot00000000000000from ..Qt import QtGui, QtCore from ..python2_3 import asUnicode import numpy as np from ..Point import Point from .. import debug as debug import weakref from .. import functions as fn from .. import getConfigOption from .GraphicsWidget import GraphicsWidget __all__ = ['AxisItem'] class AxisItem(GraphicsWidget): """ GraphicsItem showing a single plot axis with ticks, values, and label. Can be configured to fit on any side of a plot, and can automatically synchronize its displayed scale with ViewBox items. Ticks can be extended to draw a grid. If maxTickLength is negative, ticks point into the plot. """ def __init__(self, orientation, pen=None, linkView=None, parent=None, maxTickLength=-5, showValues=True): """ ============== =============================================================== **Arguments:** orientation one of 'left', 'right', 'top', or 'bottom' maxTickLength (px) maximum length of ticks to draw. Negative values draw into the plot, positive values draw outward. linkView (ViewBox) causes the range of values displayed in the axis to be linked to the visible range of a ViewBox. showValues (bool) Whether to display values adjacent to ticks pen (QPen) Pen used when drawing ticks. ============== =============================================================== """ GraphicsWidget.__init__(self, parent) self.label = QtGui.QGraphicsTextItem(self) self.picture = None self.orientation = orientation if orientation not in ['left', 'right', 'top', 'bottom']: raise Exception("Orientation argument must be one of 'left', 'right', 'top', or 'bottom'.") if orientation in ['left', 'right']: self.label.rotate(-90) self.style = { 'tickTextOffset': [5, 2], ## (horizontal, vertical) spacing between text and axis 'tickTextWidth': 30, ## space reserved for tick text 'tickTextHeight': 18, 'autoExpandTextSpace': True, ## automatically expand text space if needed 'tickFont': None, 'stopAxisAtTick': (False, False), ## whether axis is drawn to edge of box or to last tick 'textFillLimits': [ ## how much of the axis to fill up with tick text, maximally. (0, 0.8), ## never fill more than 80% of the axis (2, 0.6), ## If we already have 2 ticks with text, fill no more than 60% of the axis (4, 0.4), ## If we already have 4 ticks with text, fill no more than 40% of the axis (6, 0.2), ## If we already have 6 ticks with text, fill no more than 20% of the axis ], 'showValues': showValues, 'tickLength': maxTickLength, 'maxTickLevel': 2, 'maxTextLevel': 2, } self.textWidth = 30 ## Keeps track of maximum width / height of tick text self.textHeight = 18 # If the user specifies a width / height, remember that setting # indefinitely. self.fixedWidth = None self.fixedHeight = None self.labelText = '' self.labelUnits = '' self.labelUnitPrefix='' self.labelStyle = {} self.logMode = False self.tickFont = None self._tickLevels = None ## used to override the automatic ticking system with explicit ticks self._tickSpacing = None # used to override default tickSpacing method self.scale = 1.0 self.autoSIPrefix = True self.autoSIPrefixScale = 1.0 self.setRange(0, 1) if pen is None: self.setPen() else: self.setPen(pen) self._linkedView = None if linkView is not None: self.linkToView(linkView) self.showLabel(False) self.grid = False #self.setCacheMode(self.DeviceCoordinateCache) def setStyle(self, **kwds): """ Set various style options. =================== ======================================================= Keyword Arguments: tickLength (int) The maximum length of ticks in pixels. Positive values point toward the text; negative values point away. tickTextOffset (int) reserved spacing between text and axis in px tickTextWidth (int) Horizontal space reserved for tick text in px tickTextHeight (int) Vertical space reserved for tick text in px autoExpandTextSpace (bool) Automatically expand text space if the tick strings become too long. tickFont (QFont or None) Determines the font used for tick values. Use None for the default font. stopAxisAtTick (tuple: (bool min, bool max)) If True, the axis line is drawn only as far as the last tick. Otherwise, the line is drawn to the edge of the AxisItem boundary. textFillLimits (list of (tick #, % fill) tuples). This structure determines how the AxisItem decides how many ticks should have text appear next to them. Each tuple in the list specifies what fraction of the axis length may be occupied by text, given the number of ticks that already have text displayed. For example:: [(0, 0.8), # Never fill more than 80% of the axis (2, 0.6), # If we already have 2 ticks with text, # fill no more than 60% of the axis (4, 0.4), # If we already have 4 ticks with text, # fill no more than 40% of the axis (6, 0.2)] # If we already have 6 ticks with text, # fill no more than 20% of the axis showValues (bool) indicates whether text is displayed adjacent to ticks. =================== ======================================================= Added in version 0.9.9 """ for kwd,value in kwds.items(): if kwd not in self.style: raise NameError("%s is not a valid style argument." % kwd) if kwd in ('tickLength', 'tickTextOffset', 'tickTextWidth', 'tickTextHeight'): if not isinstance(value, int): raise ValueError("Argument '%s' must be int" % kwd) if kwd == 'tickTextOffset': if self.orientation in ('left', 'right'): self.style['tickTextOffset'][0] = value else: self.style['tickTextOffset'][1] = value elif kwd == 'stopAxisAtTick': try: assert len(value) == 2 and isinstance(value[0], bool) and isinstance(value[1], bool) except: raise ValueError("Argument 'stopAxisAtTick' must have type (bool, bool)") self.style[kwd] = value else: self.style[kwd] = value self.picture = None self._adjustSize() self.update() def close(self): self.scene().removeItem(self.label) self.label = None self.scene().removeItem(self) def setGrid(self, grid): """Set the alpha value (0-255) for the grid, or False to disable. When grid lines are enabled, the axis tick lines are extended to cover the extent of the linked ViewBox, if any. """ self.grid = grid self.picture = None self.prepareGeometryChange() self.update() def setLogMode(self, log): """ If *log* is True, then ticks are displayed on a logarithmic scale and values are adjusted accordingly. (This is usually accessed by changing the log mode of a :func:`PlotItem `) """ self.logMode = log self.picture = None self.update() def setTickFont(self, font): self.tickFont = font self.picture = None self.prepareGeometryChange() ## Need to re-allocate space depending on font size? self.update() def resizeEvent(self, ev=None): #s = self.size() ## Set the position of the label nudge = 5 br = self.label.boundingRect() p = QtCore.QPointF(0, 0) if self.orientation == 'left': p.setY(int(self.size().height()/2 + br.width()/2)) p.setX(-nudge) elif self.orientation == 'right': p.setY(int(self.size().height()/2 + br.width()/2)) p.setX(int(self.size().width()-br.height()+nudge)) elif self.orientation == 'top': p.setY(-nudge) p.setX(int(self.size().width()/2. - br.width()/2.)) elif self.orientation == 'bottom': p.setX(int(self.size().width()/2. - br.width()/2.)) p.setY(int(self.size().height()-br.height()+nudge)) self.label.setPos(p) self.picture = None def showLabel(self, show=True): """Show/hide the label text for this axis.""" #self.drawLabel = show self.label.setVisible(show) if self.orientation in ['left', 'right']: self._updateWidth() else: self._updateHeight() if self.autoSIPrefix: self.updateAutoSIPrefix() def setLabel(self, text=None, units=None, unitPrefix=None, **args): """Set the text displayed adjacent to the axis. ============== ============================================================= **Arguments:** text The text (excluding units) to display on the label for this axis. units The units for this axis. Units should generally be given without any scaling prefix (eg, 'V' instead of 'mV'). The scaling prefix will be automatically prepended based on the range of data displayed. **args All extra keyword arguments become CSS style options for the tag which will surround the axis label and units. ============== ============================================================= The final text generated for the label will look like:: {text} (prefix{units}) Each extra keyword argument will become a CSS option in the above template. For example, you can set the font size and color of the label:: labelStyle = {'color': '#FFF', 'font-size': '14pt'} axis.setLabel('label text', units='V', **labelStyle) """ if text is not None: self.labelText = text self.showLabel() if units is not None: self.labelUnits = units self.showLabel() if unitPrefix is not None: self.labelUnitPrefix = unitPrefix if len(args) > 0: self.labelStyle = args self.label.setHtml(self.labelString()) self._adjustSize() self.picture = None self.update() def labelString(self): if self.labelUnits == '': if not self.autoSIPrefix or self.autoSIPrefixScale == 1.0: units = '' else: units = asUnicode('(x%g)') % (1.0/self.autoSIPrefixScale) else: #print repr(self.labelUnitPrefix), repr(self.labelUnits) units = asUnicode('(%s%s)') % (asUnicode(self.labelUnitPrefix), asUnicode(self.labelUnits)) s = asUnicode('%s %s') % (asUnicode(self.labelText), asUnicode(units)) style = ';'.join(['%s: %s' % (k, self.labelStyle[k]) for k in self.labelStyle]) return asUnicode("%s") % (style, asUnicode(s)) def _updateMaxTextSize(self, x): ## Informs that the maximum tick size orthogonal to the axis has ## changed; we use this to decide whether the item needs to be resized ## to accomodate. if self.orientation in ['left', 'right']: mx = max(self.textWidth, x) if mx > self.textWidth or mx < self.textWidth-10: self.textWidth = mx if self.style['autoExpandTextSpace'] is True: self._updateWidth() #return True ## size has changed else: mx = max(self.textHeight, x) if mx > self.textHeight or mx < self.textHeight-10: self.textHeight = mx if self.style['autoExpandTextSpace'] is True: self._updateHeight() #return True ## size has changed def _adjustSize(self): if self.orientation in ['left', 'right']: self._updateWidth() else: self._updateHeight() def setHeight(self, h=None): """Set the height of this axis reserved for ticks and tick labels. The height of the axis label is automatically added. If *height* is None, then the value will be determined automatically based on the size of the tick text.""" self.fixedHeight = h self._updateHeight() def _updateHeight(self): if not self.isVisible(): h = 0 else: if self.fixedHeight is None: if not self.style['showValues']: h = 0 elif self.style['autoExpandTextSpace'] is True: h = self.textHeight else: h = self.style['tickTextHeight'] h += self.style['tickTextOffset'][1] if self.style['showValues'] else 0 h += max(0, self.style['tickLength']) if self.label.isVisible(): h += self.label.boundingRect().height() * 0.8 else: h = self.fixedHeight self.setMaximumHeight(h) self.setMinimumHeight(h) self.picture = None def setWidth(self, w=None): """Set the width of this axis reserved for ticks and tick labels. The width of the axis label is automatically added. If *width* is None, then the value will be determined automatically based on the size of the tick text.""" self.fixedWidth = w self._updateWidth() def _updateWidth(self): if not self.isVisible(): w = 0 else: if self.fixedWidth is None: if not self.style['showValues']: w = 0 elif self.style['autoExpandTextSpace'] is True: w = self.textWidth else: w = self.style['tickTextWidth'] w += self.style['tickTextOffset'][0] if self.style['showValues'] else 0 w += max(0, self.style['tickLength']) if self.label.isVisible(): w += self.label.boundingRect().height() * 0.8 ## bounding rect is usually an overestimate else: w = self.fixedWidth self.setMaximumWidth(w) self.setMinimumWidth(w) self.picture = None def pen(self): if self._pen is None: return fn.mkPen(getConfigOption('foreground')) return fn.mkPen(self._pen) def setPen(self, *args, **kwargs): """ Set the pen used for drawing text, axes, ticks, and grid lines. If no arguments are given, the default foreground color will be used (see :func:`setConfigOption `). """ self.picture = None if args or kwargs: self._pen = fn.mkPen(*args, **kwargs) else: self._pen = fn.mkPen(getConfigOption('foreground')) self.labelStyle['color'] = '#' + fn.colorStr(self._pen.color())[:6] self.setLabel() self.update() def setScale(self, scale=None): """ Set the value scaling for this axis. Setting this value causes the axis to draw ticks and tick labels as if the view coordinate system were scaled. By default, the axis scaling is 1.0. """ # Deprecated usage, kept for backward compatibility if scale is None: scale = 1.0 self.enableAutoSIPrefix(True) if scale != self.scale: self.scale = scale self.setLabel() self.picture = None self.update() def enableAutoSIPrefix(self, enable=True): """ Enable (or disable) automatic SI prefix scaling on this axis. When enabled, this feature automatically determines the best SI prefix to prepend to the label units, while ensuring that axis values are scaled accordingly. For example, if the axis spans values from -0.1 to 0.1 and has units set to 'V' then the axis would display values -100 to 100 and the units would appear as 'mV' This feature is enabled by default, and is only available when a suffix (unit string) is provided to display on the label. """ self.autoSIPrefix = enable self.updateAutoSIPrefix() def updateAutoSIPrefix(self): if self.label.isVisible(): (scale, prefix) = fn.siScale(max(abs(self.range[0]*self.scale), abs(self.range[1]*self.scale))) if self.labelUnits == '' and prefix in ['k', 'm']: ## If we are not showing units, wait until 1e6 before scaling. scale = 1.0 prefix = '' self.setLabel(unitPrefix=prefix) else: scale = 1.0 self.autoSIPrefixScale = scale self.picture = None self.update() def setRange(self, mn, mx): """Set the range of values displayed by the axis. Usually this is handled automatically by linking the axis to a ViewBox with :func:`linkToView `""" if any(np.isinf((mn, mx))) or any(np.isnan((mn, mx))): raise Exception("Not setting range to [%s, %s]" % (str(mn), str(mx))) self.range = [mn, mx] if self.autoSIPrefix: self.updateAutoSIPrefix() self.picture = None self.update() def linkedView(self): """Return the ViewBox this axis is linked to""" if self._linkedView is None: return None else: return self._linkedView() def linkToView(self, view): """Link this axis to a ViewBox, causing its displayed range to match the visible range of the view.""" oldView = self.linkedView() self._linkedView = weakref.ref(view) if self.orientation in ['right', 'left']: if oldView is not None: oldView.sigYRangeChanged.disconnect(self.linkedViewChanged) view.sigYRangeChanged.connect(self.linkedViewChanged) else: if oldView is not None: oldView.sigXRangeChanged.disconnect(self.linkedViewChanged) view.sigXRangeChanged.connect(self.linkedViewChanged) if oldView is not None: oldView.sigResized.disconnect(self.linkedViewChanged) view.sigResized.connect(self.linkedViewChanged) def linkedViewChanged(self, view, newRange=None): if self.orientation in ['right', 'left']: if newRange is None: newRange = view.viewRange()[1] if view.yInverted(): self.setRange(*newRange[::-1]) else: self.setRange(*newRange) else: if newRange is None: newRange = view.viewRange()[0] if view.xInverted(): self.setRange(*newRange[::-1]) else: self.setRange(*newRange) def boundingRect(self): linkedView = self.linkedView() if linkedView is None or self.grid is False: rect = self.mapRectFromParent(self.geometry()) ## extend rect if ticks go in negative direction ## also extend to account for text that flows past the edges tl = self.style['tickLength'] if self.orientation == 'left': rect = rect.adjusted(0, -15, -min(0,tl), 15) elif self.orientation == 'right': rect = rect.adjusted(min(0,tl), -15, 0, 15) elif self.orientation == 'top': rect = rect.adjusted(-15, 0, 15, -min(0,tl)) elif self.orientation == 'bottom': rect = rect.adjusted(-15, min(0,tl), 15, 0) return rect else: return self.mapRectFromParent(self.geometry()) | linkedView.mapRectToItem(self, linkedView.boundingRect()) def paint(self, p, opt, widget): profiler = debug.Profiler() if self.picture is None: try: picture = QtGui.QPicture() painter = QtGui.QPainter(picture) specs = self.generateDrawSpecs(painter) profiler('generate specs') if specs is not None: self.drawPicture(painter, *specs) profiler('draw picture') finally: painter.end() self.picture = picture #p.setRenderHint(p.Antialiasing, False) ## Sometimes we get a segfault here ??? #p.setRenderHint(p.TextAntialiasing, True) self.picture.play(p) def setTicks(self, ticks): """Explicitly determine which ticks to display. This overrides the behavior specified by tickSpacing(), tickValues(), and tickStrings() The format for *ticks* looks like:: [ [ (majorTickValue1, majorTickString1), (majorTickValue2, majorTickString2), ... ], [ (minorTickValue1, minorTickString1), (minorTickValue2, minorTickString2), ... ], ... ] If *ticks* is None, then the default tick system will be used instead. """ self._tickLevels = ticks self.picture = None self.update() def setTickSpacing(self, major=None, minor=None, levels=None): """ Explicitly determine the spacing of major and minor ticks. This overrides the default behavior of the tickSpacing method, and disables the effect of setTicks(). Arguments may be either *major* and *minor*, or *levels* which is a list of (spacing, offset) tuples for each tick level desired. If no arguments are given, then the default behavior of tickSpacing is enabled. Examples:: # two levels, all offsets = 0 axis.setTickSpacing(5, 1) # three levels, all offsets = 0 axis.setTickSpacing([(3, 0), (1, 0), (0.25, 0)]) # reset to default axis.setTickSpacing() """ if levels is None: if major is None: levels = None else: levels = [(major, 0), (minor, 0)] self._tickSpacing = levels self.picture = None self.update() def tickSpacing(self, minVal, maxVal, size): """Return values describing the desired spacing and offset of ticks. This method is called whenever the axis needs to be redrawn and is a good method to override in subclasses that require control over tick locations. The return value must be a list of tuples, one for each set of ticks:: [ (major tick spacing, offset), (minor tick spacing, offset), (sub-minor tick spacing, offset), ... ] """ # First check for override tick spacing if self._tickSpacing is not None: return self._tickSpacing dif = abs(maxVal - minVal) if dif == 0: return [] ## decide optimal minor tick spacing in pixels (this is just aesthetics) optimalTickCount = max(2., np.log(size)) ## optimal minor tick spacing optimalSpacing = dif / optimalTickCount ## the largest power-of-10 spacing which is smaller than optimal p10unit = 10 ** np.floor(np.log10(optimalSpacing)) ## Determine major/minor tick spacings which flank the optimal spacing. intervals = np.array([1., 2., 10., 20., 100.]) * p10unit minorIndex = 0 while intervals[minorIndex+1] <= optimalSpacing: minorIndex += 1 levels = [ (intervals[minorIndex+2], 0), (intervals[minorIndex+1], 0), #(intervals[minorIndex], 0) ## Pretty, but eats up CPU ] if self.style['maxTickLevel'] >= 2: ## decide whether to include the last level of ticks minSpacing = min(size / 20., 30.) maxTickCount = size / minSpacing if dif / intervals[minorIndex] <= maxTickCount: levels.append((intervals[minorIndex], 0)) return levels ##### This does not work -- switching between 2/5 confuses the automatic text-level-selection ### Determine major/minor tick spacings which flank the optimal spacing. #intervals = np.array([1., 2., 5., 10., 20., 50., 100.]) * p10unit #minorIndex = 0 #while intervals[minorIndex+1] <= optimalSpacing: #minorIndex += 1 ### make sure we never see 5 and 2 at the same time #intIndexes = [ #[0,1,3], #[0,2,3], #[2,3,4], #[3,4,6], #[3,5,6], #][minorIndex] #return [ #(intervals[intIndexes[2]], 0), #(intervals[intIndexes[1]], 0), #(intervals[intIndexes[0]], 0) #] def tickValues(self, minVal, maxVal, size): """ Return the values and spacing of ticks to draw:: [ (spacing, [major ticks]), (spacing, [minor ticks]), ... ] By default, this method calls tickSpacing to determine the correct tick locations. This is a good method to override in subclasses. """ minVal, maxVal = sorted((minVal, maxVal)) minVal *= self.scale maxVal *= self.scale #size *= self.scale ticks = [] tickLevels = self.tickSpacing(minVal, maxVal, size) allValues = np.array([]) for i in range(len(tickLevels)): spacing, offset = tickLevels[i] ## determine starting tick start = (np.ceil((minVal-offset) / spacing) * spacing) + offset ## determine number of ticks num = int((maxVal-start) / spacing) + 1 values = (np.arange(num) * spacing + start) / self.scale ## remove any ticks that were present in higher levels ## we assume here that if the difference between a tick value and a previously seen tick value ## is less than spacing/100, then they are 'equal' and we can ignore the new tick. values = list(filter(lambda x: all(np.abs(allValues-x) > spacing*0.01), values) ) allValues = np.concatenate([allValues, values]) ticks.append((spacing/self.scale, values)) if self.logMode: return self.logTickValues(minVal, maxVal, size, ticks) #nticks = [] #for t in ticks: #nvals = [] #for v in t[1]: #nvals.append(v/self.scale) #nticks.append((t[0]/self.scale,nvals)) #ticks = nticks return ticks def logTickValues(self, minVal, maxVal, size, stdTicks): ## start with the tick spacing given by tickValues(). ## Any level whose spacing is < 1 needs to be converted to log scale ticks = [] for (spacing, t) in stdTicks: if spacing >= 1.0: ticks.append((spacing, t)) if len(ticks) < 3: v1 = int(np.floor(minVal)) v2 = int(np.ceil(maxVal)) #major = list(range(v1+1, v2)) minor = [] for v in range(v1, v2): minor.extend(v + np.log10(np.arange(1, 10))) minor = [x for x in minor if x>minVal and x= 10000: vstr = "%g" % vs else: vstr = ("%%0.%df" % places) % vs strings.append(vstr) return strings def logTickStrings(self, values, scale, spacing): return ["%0.1g"%x for x in 10 ** np.array(values).astype(float)] def generateDrawSpecs(self, p): """ Calls tickValues() and tickStrings() to determine where and how ticks should be drawn, then generates from this a set of drawing commands to be interpreted by drawPicture(). """ profiler = debug.Profiler() #bounds = self.boundingRect() bounds = self.mapRectFromParent(self.geometry()) linkedView = self.linkedView() if linkedView is None or self.grid is False: tickBounds = bounds else: tickBounds = linkedView.mapRectToItem(self, linkedView.boundingRect()) if self.orientation == 'left': span = (bounds.topRight(), bounds.bottomRight()) tickStart = tickBounds.right() tickStop = bounds.right() tickDir = -1 axis = 0 elif self.orientation == 'right': span = (bounds.topLeft(), bounds.bottomLeft()) tickStart = tickBounds.left() tickStop = bounds.left() tickDir = 1 axis = 0 elif self.orientation == 'top': span = (bounds.bottomLeft(), bounds.bottomRight()) tickStart = tickBounds.bottom() tickStop = bounds.bottom() tickDir = -1 axis = 1 elif self.orientation == 'bottom': span = (bounds.topLeft(), bounds.topRight()) tickStart = tickBounds.top() tickStop = bounds.top() tickDir = 1 axis = 1 #print tickStart, tickStop, span ## determine size of this item in pixels points = list(map(self.mapToDevice, span)) if None in points: return lengthInPixels = Point(points[1] - points[0]).length() if lengthInPixels == 0: return # Determine major / minor / subminor axis ticks if self._tickLevels is None: tickLevels = self.tickValues(self.range[0], self.range[1], lengthInPixels) tickStrings = None else: ## parse self.tickLevels into the formats returned by tickLevels() and tickStrings() tickLevels = [] tickStrings = [] for level in self._tickLevels: values = [] strings = [] tickLevels.append((None, values)) tickStrings.append(strings) for val, strn in level: values.append(val) strings.append(strn) ## determine mapping between tick values and local coordinates dif = self.range[1] - self.range[0] if dif == 0: xScale = 1 offset = 0 else: if axis == 0: xScale = -bounds.height() / dif offset = self.range[0] * xScale - bounds.height() else: xScale = bounds.width() / dif offset = self.range[0] * xScale xRange = [x * xScale - offset for x in self.range] xMin = min(xRange) xMax = max(xRange) profiler('init') tickPositions = [] # remembers positions of previously drawn ticks ## compute coordinates to draw ticks ## draw three different intervals, long ticks first tickSpecs = [] for i in range(len(tickLevels)): tickPositions.append([]) ticks = tickLevels[i][1] ## length of tick tickLength = self.style['tickLength'] / ((i*0.5)+1.0) lineAlpha = 255 / (i+1) if self.grid is not False: lineAlpha *= self.grid/255. * np.clip((0.05 * lengthInPixels / (len(ticks)+1)), 0., 1.) for v in ticks: ## determine actual position to draw this tick x = (v * xScale) - offset if x < xMin or x > xMax: ## last check to make sure no out-of-bounds ticks are drawn tickPositions[i].append(None) continue tickPositions[i].append(x) p1 = [x, x] p2 = [x, x] p1[axis] = tickStart p2[axis] = tickStop if self.grid is False: p2[axis] += tickLength*tickDir tickPen = self.pen() color = tickPen.color() color.setAlpha(lineAlpha) tickPen.setColor(color) tickSpecs.append((tickPen, Point(p1), Point(p2))) profiler('compute ticks') if self.style['stopAxisAtTick'][0] is True: stop = max(span[0].y(), min(map(min, tickPositions))) if axis == 0: span[0].setY(stop) else: span[0].setX(stop) if self.style['stopAxisAtTick'][1] is True: stop = min(span[1].y(), max(map(max, tickPositions))) if axis == 0: span[1].setY(stop) else: span[1].setX(stop) axisSpec = (self.pen(), span[0], span[1]) textOffset = self.style['tickTextOffset'][axis] ## spacing between axis and text #if self.style['autoExpandTextSpace'] is True: #textWidth = self.textWidth #textHeight = self.textHeight #else: #textWidth = self.style['tickTextWidth'] ## space allocated for horizontal text #textHeight = self.style['tickTextHeight'] ## space allocated for horizontal text textSize2 = 0 textRects = [] textSpecs = [] ## list of draw # If values are hidden, return early if not self.style['showValues']: return (axisSpec, tickSpecs, textSpecs) for i in range(min(len(tickLevels), self.style['maxTextLevel']+1)): ## Get the list of strings to display for this level if tickStrings is None: spacing, values = tickLevels[i] strings = self.tickStrings(values, self.autoSIPrefixScale * self.scale, spacing) else: strings = tickStrings[i] if len(strings) == 0: continue ## ignore strings belonging to ticks that were previously ignored for j in range(len(strings)): if tickPositions[i][j] is None: strings[j] = None ## Measure density of text; decide whether to draw this level rects = [] for s in strings: if s is None: rects.append(None) else: br = p.boundingRect(QtCore.QRectF(0, 0, 100, 100), QtCore.Qt.AlignCenter, asUnicode(s)) ## boundingRect is usually just a bit too large ## (but this probably depends on per-font metrics?) br.setHeight(br.height() * 0.8) rects.append(br) textRects.append(rects[-1]) if len(textRects) > 0: ## measure all text, make sure there's enough room if axis == 0: textSize = np.sum([r.height() for r in textRects]) textSize2 = np.max([r.width() for r in textRects]) else: textSize = np.sum([r.width() for r in textRects]) textSize2 = np.max([r.height() for r in textRects]) else: textSize = 0 textSize2 = 0 if i > 0: ## always draw top level ## If the strings are too crowded, stop drawing text now. ## We use three different crowding limits based on the number ## of texts drawn so far. textFillRatio = float(textSize) / lengthInPixels finished = False for nTexts, limit in self.style['textFillLimits']: if len(textSpecs) >= nTexts and textFillRatio >= limit: finished = True break if finished: break #spacing, values = tickLevels[best] #strings = self.tickStrings(values, self.scale, spacing) # Determine exactly where tick text should be drawn for j in range(len(strings)): vstr = strings[j] if vstr is None: ## this tick was ignored because it is out of bounds continue vstr = asUnicode(vstr) x = tickPositions[i][j] #textRect = p.boundingRect(QtCore.QRectF(0, 0, 100, 100), QtCore.Qt.AlignCenter, vstr) textRect = rects[j] height = textRect.height() width = textRect.width() #self.textHeight = height offset = max(0,self.style['tickLength']) + textOffset if self.orientation == 'left': textFlags = QtCore.Qt.TextDontClip|QtCore.Qt.AlignRight|QtCore.Qt.AlignVCenter rect = QtCore.QRectF(tickStop-offset-width, x-(height/2), width, height) elif self.orientation == 'right': textFlags = QtCore.Qt.TextDontClip|QtCore.Qt.AlignLeft|QtCore.Qt.AlignVCenter rect = QtCore.QRectF(tickStop+offset, x-(height/2), width, height) elif self.orientation == 'top': textFlags = QtCore.Qt.TextDontClip|QtCore.Qt.AlignCenter|QtCore.Qt.AlignBottom rect = QtCore.QRectF(x-width/2., tickStop-offset-height, width, height) elif self.orientation == 'bottom': textFlags = QtCore.Qt.TextDontClip|QtCore.Qt.AlignCenter|QtCore.Qt.AlignTop rect = QtCore.QRectF(x-width/2., tickStop+offset, width, height) #p.setPen(self.pen()) #p.drawText(rect, textFlags, vstr) textSpecs.append((rect, textFlags, vstr)) profiler('compute text') ## update max text size if needed. self._updateMaxTextSize(textSize2) return (axisSpec, tickSpecs, textSpecs) def drawPicture(self, p, axisSpec, tickSpecs, textSpecs): profiler = debug.Profiler() p.setRenderHint(p.Antialiasing, False) p.setRenderHint(p.TextAntialiasing, True) ## draw long line along axis pen, p1, p2 = axisSpec p.setPen(pen) p.drawLine(p1, p2) p.translate(0.5,0) ## resolves some damn pixel ambiguity ## draw ticks for pen, p1, p2 in tickSpecs: p.setPen(pen) p.drawLine(p1, p2) profiler('draw ticks') ## Draw all text if self.tickFont is not None: p.setFont(self.tickFont) p.setPen(self.pen()) for rect, flags, text in textSpecs: p.drawText(rect, flags, text) #p.drawRect(rect) profiler('draw text') def show(self): GraphicsWidget.show(self) if self.orientation in ['left', 'right']: self._updateWidth() else: self._updateHeight() def hide(self): GraphicsWidget.hide(self) if self.orientation in ['left', 'right']: self._updateWidth() else: self._updateHeight() def wheelEvent(self, ev): if self.linkedView() is None: return if self.orientation in ['left', 'right']: self.linkedView().wheelEvent(ev, axis=1) else: self.linkedView().wheelEvent(ev, axis=0) ev.accept() def mouseDragEvent(self, event): if self.linkedView() is None: return if self.orientation in ['left', 'right']: return self.linkedView().mouseDragEvent(event, axis=1) else: return self.linkedView().mouseDragEvent(event, axis=0) def mouseClickEvent(self, event): if self.linkedView() is None: return return self.linkedView().mouseClickEvent(event) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/BarGraphItem.py000066400000000000000000000113341300727121400253230ustar00rootroot00000000000000from ..Qt import QtGui, QtCore from .GraphicsObject import GraphicsObject from .. import getConfigOption from .. import functions as fn import numpy as np __all__ = ['BarGraphItem'] class BarGraphItem(GraphicsObject): def __init__(self, **opts): """ Valid keyword options are: x, x0, x1, y, y0, y1, width, height, pen, brush x specifies the x-position of the center of the bar. x0, x1 specify left and right edges of the bar, respectively. width specifies distance from x0 to x1. You may specify any combination: x, width x0, width x1, width x0, x1 Likewise y, y0, y1, and height. If only height is specified, then y0 will be set to 0 Example uses: BarGraphItem(x=range(5), height=[1,5,2,4,3], width=0.5) """ GraphicsObject.__init__(self) self.opts = dict( x=None, y=None, x0=None, y0=None, x1=None, y1=None, height=None, width=None, pen=None, brush=None, pens=None, brushes=None, ) self._shape = None self.picture = None self.setOpts(**opts) def setOpts(self, **opts): self.opts.update(opts) self.picture = None self._shape = None self.update() self.informViewBoundsChanged() def drawPicture(self): self.picture = QtGui.QPicture() self._shape = QtGui.QPainterPath() p = QtGui.QPainter(self.picture) pen = self.opts['pen'] pens = self.opts['pens'] if pen is None and pens is None: pen = getConfigOption('foreground') brush = self.opts['brush'] brushes = self.opts['brushes'] if brush is None and brushes is None: brush = (128, 128, 128) def asarray(x): if x is None or np.isscalar(x) or isinstance(x, np.ndarray): return x return np.array(x) x = asarray(self.opts.get('x')) x0 = asarray(self.opts.get('x0')) x1 = asarray(self.opts.get('x1')) width = asarray(self.opts.get('width')) if x0 is None: if width is None: raise Exception('must specify either x0 or width') if x1 is not None: x0 = x1 - width elif x is not None: x0 = x - width/2. else: raise Exception('must specify at least one of x, x0, or x1') if width is None: if x1 is None: raise Exception('must specify either x1 or width') width = x1 - x0 y = asarray(self.opts.get('y')) y0 = asarray(self.opts.get('y0')) y1 = asarray(self.opts.get('y1')) height = asarray(self.opts.get('height')) if y0 is None: if height is None: y0 = 0 elif y1 is not None: y0 = y1 - height elif y is not None: y0 = y - height/2. else: y0 = 0 if height is None: if y1 is None: raise Exception('must specify either y1 or height') height = y1 - y0 p.setPen(fn.mkPen(pen)) p.setBrush(fn.mkBrush(brush)) for i in range(len(x0)): if pens is not None: p.setPen(fn.mkPen(pens[i])) if brushes is not None: p.setBrush(fn.mkBrush(brushes[i])) if np.isscalar(x0): x = x0 else: x = x0[i] if np.isscalar(y0): y = y0 else: y = y0[i] if np.isscalar(width): w = width else: w = width[i] if np.isscalar(height): h = height else: h = height[i] rect = QtCore.QRectF(x, y, w, h) p.drawRect(rect) self._shape.addRect(rect) p.end() self.prepareGeometryChange() def paint(self, p, *args): if self.picture is None: self.drawPicture() self.picture.play(p) def boundingRect(self): if self.picture is None: self.drawPicture() return QtCore.QRectF(self.picture.boundingRect()) def shape(self): if self.picture is None: self.drawPicture() return self._shape pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/ButtonItem.py000066400000000000000000000031451300727121400251110ustar00rootroot00000000000000from ..Qt import QtGui, QtCore from .GraphicsObject import GraphicsObject __all__ = ['ButtonItem'] class ButtonItem(GraphicsObject): """Button graphicsItem displaying an image.""" clicked = QtCore.Signal(object) def __init__(self, imageFile=None, width=None, parentItem=None, pixmap=None): self.enabled = True GraphicsObject.__init__(self) if imageFile is not None: self.setImageFile(imageFile) elif pixmap is not None: self.setPixmap(pixmap) if width is not None: s = float(width) / self.pixmap.width() self.scale(s, s) if parentItem is not None: self.setParentItem(parentItem) self.setOpacity(0.7) def setImageFile(self, imageFile): self.setPixmap(QtGui.QPixmap(imageFile)) def setPixmap(self, pixmap): self.pixmap = pixmap self.update() def mouseClickEvent(self, ev): if self.enabled: self.clicked.emit(self) def mouseHoverEvent(self, ev): if not self.enabled: return if ev.isEnter(): self.setOpacity(1.0) else: self.setOpacity(0.7) def disable(self): self.enabled = False self.setOpacity(0.4) def enable(self): self.enabled = True self.setOpacity(0.7) def paint(self, p, *args): p.setRenderHint(p.Antialiasing) p.drawPixmap(0, 0, self.pixmap) def boundingRect(self): return QtCore.QRectF(self.pixmap.rect()) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/CurvePoint.py000066400000000000000000000111051300727121400251100ustar00rootroot00000000000000from ..Qt import QtGui, QtCore from . import ArrowItem import numpy as np from ..Point import Point import weakref from .GraphicsObject import GraphicsObject __all__ = ['CurvePoint', 'CurveArrow'] class CurvePoint(GraphicsObject): """A GraphicsItem that sets its location to a point on a PlotCurveItem. Also rotates to be tangent to the curve. The position along the curve is a Qt property, and thus can be easily animated. Note: This class does not display anything; see CurveArrow for an applied example """ def __init__(self, curve, index=0, pos=None, rotate=True): """Position can be set either as an index referring to the sample number or the position 0.0 - 1.0 If *rotate* is True, then the item rotates to match the tangent of the curve. """ GraphicsObject.__init__(self) #QObjectWorkaround.__init__(self) self._rotate = rotate self.curve = weakref.ref(curve) self.setParentItem(curve) self.setProperty('position', 0.0) self.setProperty('index', 0) if hasattr(self, 'ItemHasNoContents'): self.setFlags(self.flags() | self.ItemHasNoContents) if pos is not None: self.setPos(pos) else: self.setIndex(index) def setPos(self, pos): self.setProperty('position', float(pos))## cannot use numpy types here, MUST be python float. def setIndex(self, index): self.setProperty('index', int(index)) ## cannot use numpy types here, MUST be python int. def event(self, ev): if not isinstance(ev, QtCore.QDynamicPropertyChangeEvent) or self.curve() is None: return False if ev.propertyName() == 'index': index = self.property('index') if 'QVariant' in repr(index): index = index.toInt()[0] elif ev.propertyName() == 'position': index = None else: return False (x, y) = self.curve().getData() if index is None: #print ev.propertyName(), self.property('position').toDouble()[0], self.property('position').typeName() pos = self.property('position') if 'QVariant' in repr(pos): ## need to support 2 APIs :( pos = pos.toDouble()[0] index = (len(x)-1) * np.clip(pos, 0.0, 1.0) if index != int(index): ## interpolate floating-point values i1 = int(index) i2 = np.clip(i1+1, 0, len(x)-1) s2 = index-i1 s1 = 1.0-s2 newPos = (x[i1]*s1+x[i2]*s2, y[i1]*s1+y[i2]*s2) else: index = int(index) i1 = np.clip(index-1, 0, len(x)-1) i2 = np.clip(index+1, 0, len(x)-1) newPos = (x[index], y[index]) p1 = self.parentItem().mapToScene(QtCore.QPointF(x[i1], y[i1])) p2 = self.parentItem().mapToScene(QtCore.QPointF(x[i2], y[i2])) ang = np.arctan2(p2.y()-p1.y(), p2.x()-p1.x()) ## returns radians self.resetTransform() if self._rotate: self.rotate(180+ ang * 180 / np.pi) ## takes degrees QtGui.QGraphicsItem.setPos(self, *newPos) return True def boundingRect(self): return QtCore.QRectF() def paint(self, *args): pass def makeAnimation(self, prop='position', start=0.0, end=1.0, duration=10000, loop=1): # In Python 3, a bytes object needs to be used as a property name in # QPropertyAnimation. PyQt stopped automatically encoding a str when a # QByteArray was expected in v5.5 (see qbytearray.sip). if not isinstance(prop, bytes): prop = prop.encode('latin-1') anim = QtCore.QPropertyAnimation(self, prop) anim.setDuration(duration) anim.setStartValue(start) anim.setEndValue(end) anim.setLoopCount(loop) return anim class CurveArrow(CurvePoint): """Provides an arrow that points to any specific sample on a PlotCurveItem. Provides properties that can be animated.""" def __init__(self, curve, index=0, pos=None, **opts): CurvePoint.__init__(self, curve, index=index, pos=pos) if opts.get('pxMode', True): opts['pxMode'] = False self.setFlags(self.flags() | self.ItemIgnoresTransformations) opts['angle'] = 0 self.arrow = ArrowItem.ArrowItem(**opts) self.arrow.setParentItem(self) def setStyle(self, **opts): return self.arrow.setStyle(**opts) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/ErrorBarItem.py000066400000000000000000000115771300727121400253640ustar00rootroot00000000000000from ..Qt import QtGui, QtCore from .GraphicsObject import GraphicsObject from .. import getConfigOption from .. import functions as fn __all__ = ['ErrorBarItem'] class ErrorBarItem(GraphicsObject): def __init__(self, **opts): """ All keyword arguments are passed to setData(). """ GraphicsObject.__init__(self) self.opts = dict( x=None, y=None, height=None, width=None, top=None, bottom=None, left=None, right=None, beam=None, pen=None ) self.setData(**opts) def setData(self, **opts): """ Update the data in the item. All arguments are optional. Valid keyword options are: x, y, height, width, top, bottom, left, right, beam, pen * x and y must be numpy arrays specifying the coordinates of data points. * height, width, top, bottom, left, right, and beam may be numpy arrays, single values, or None to disable. All values should be positive. * top, bottom, left, and right specify the lengths of bars extending in each direction. * If height is specified, it overrides top and bottom. * If width is specified, it overrides left and right. * beam specifies the width of the beam at the end of each bar. * pen may be any single argument accepted by pg.mkPen(). This method was added in version 0.9.9. For prior versions, use setOpts. """ self.opts.update(opts) self.path = None self.update() self.prepareGeometryChange() self.informViewBoundsChanged() def setOpts(self, **opts): # for backward compatibility self.setData(**opts) def drawPath(self): p = QtGui.QPainterPath() x, y = self.opts['x'], self.opts['y'] if x is None or y is None: return beam = self.opts['beam'] height, top, bottom = self.opts['height'], self.opts['top'], self.opts['bottom'] if height is not None or top is not None or bottom is not None: ## draw vertical error bars if height is not None: y1 = y - height/2. y2 = y + height/2. else: if bottom is None: y1 = y else: y1 = y - bottom if top is None: y2 = y else: y2 = y + top for i in range(len(x)): p.moveTo(x[i], y1[i]) p.lineTo(x[i], y2[i]) if beam is not None and beam > 0: x1 = x - beam/2. x2 = x + beam/2. if height is not None or top is not None: for i in range(len(x)): p.moveTo(x1[i], y2[i]) p.lineTo(x2[i], y2[i]) if height is not None or bottom is not None: for i in range(len(x)): p.moveTo(x1[i], y1[i]) p.lineTo(x2[i], y1[i]) width, right, left = self.opts['width'], self.opts['right'], self.opts['left'] if width is not None or right is not None or left is not None: ## draw vertical error bars if width is not None: x1 = x - width/2. x2 = x + width/2. else: if left is None: x1 = x else: x1 = x - left if right is None: x2 = x else: x2 = x + right for i in range(len(x)): p.moveTo(x1[i], y[i]) p.lineTo(x2[i], y[i]) if beam is not None and beam > 0: y1 = y - beam/2. y2 = y + beam/2. if width is not None or right is not None: for i in range(len(x)): p.moveTo(x2[i], y1[i]) p.lineTo(x2[i], y2[i]) if width is not None or left is not None: for i in range(len(x)): p.moveTo(x1[i], y1[i]) p.lineTo(x1[i], y2[i]) self.path = p self.prepareGeometryChange() def paint(self, p, *args): if self.path is None: self.drawPath() pen = self.opts['pen'] if pen is None: pen = getConfigOption('foreground') p.setPen(fn.mkPen(pen)) p.drawPath(self.path) def boundingRect(self): if self.path is None: self.drawPath() return self.path.boundingRect() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/FillBetweenItem.py000066400000000000000000000056421300727121400260420ustar00rootroot00000000000000from ..Qt import QtGui, USE_PYQT5, USE_PYQT4, USE_PYSIDE from .. import functions as fn from .PlotDataItem import PlotDataItem from .PlotCurveItem import PlotCurveItem class FillBetweenItem(QtGui.QGraphicsPathItem): """ GraphicsItem filling the space between two PlotDataItems. """ def __init__(self, curve1=None, curve2=None, brush=None, pen=None): QtGui.QGraphicsPathItem.__init__(self) self.curves = None if curve1 is not None and curve2 is not None: self.setCurves(curve1, curve2) elif curve1 is not None or curve2 is not None: raise Exception("Must specify two curves to fill between.") if brush is not None: self.setBrush(brush) self.setPen(pen) self.updatePath() def setBrush(self, *args, **kwds): QtGui.QGraphicsPathItem.setBrush(self, fn.mkBrush(*args, **kwds)) def setPen(self, *args, **kwds): QtGui.QGraphicsPathItem.setPen(self, fn.mkPen(*args, **kwds)) def setCurves(self, curve1, curve2): """Set the curves to fill between. Arguments must be instances of PlotDataItem or PlotCurveItem. Added in version 0.9.9 """ if self.curves is not None: for c in self.curves: try: c.sigPlotChanged.disconnect(self.curveChanged) except (TypeError, RuntimeError): pass curves = [curve1, curve2] for c in curves: if not isinstance(c, PlotDataItem) and not isinstance(c, PlotCurveItem): raise TypeError("Curves must be PlotDataItem or PlotCurveItem.") self.curves = curves curve1.sigPlotChanged.connect(self.curveChanged) curve2.sigPlotChanged.connect(self.curveChanged) self.setZValue(min(curve1.zValue(), curve2.zValue())-1) self.curveChanged() def setBrush(self, *args, **kwds): """Change the fill brush. Acceps the same arguments as pg.mkBrush()""" QtGui.QGraphicsPathItem.setBrush(self, fn.mkBrush(*args, **kwds)) def curveChanged(self): self.updatePath() def updatePath(self): if self.curves is None: self.setPath(QtGui.QPainterPath()) return paths = [] for c in self.curves: if isinstance(c, PlotDataItem): paths.append(c.curve.getPath()) elif isinstance(c, PlotCurveItem): paths.append(c.getPath()) path = QtGui.QPainterPath() transform = QtGui.QTransform() ps1 = paths[0].toSubpathPolygons(transform) ps2 = paths[1].toReversed().toSubpathPolygons(transform) ps2.reverse() if len(ps1) == 0 or len(ps2) == 0: self.setPath(QtGui.QPainterPath()) return for p1, p2 in zip(ps1, ps2): path.addPolygon(p1 + p2) self.setPath(path) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/GradientEditorItem.py000066400000000000000000001102271300727121400265420ustar00rootroot00000000000000import weakref import numpy as np from ..Qt import QtGui, QtCore from ..python2_3 import sortList from .. import functions as fn from .GraphicsObject import GraphicsObject from .GraphicsWidget import GraphicsWidget from ..widgets.SpinBox import SpinBox from ..pgcollections import OrderedDict from ..colormap import ColorMap from ..python2_3 import cmp __all__ = ['TickSliderItem', 'GradientEditorItem'] Gradients = OrderedDict([ ('thermal', {'ticks': [(0.3333, (185, 0, 0, 255)), (0.6666, (255, 220, 0, 255)), (1, (255, 255, 255, 255)), (0, (0, 0, 0, 255))], 'mode': 'rgb'}), ('flame', {'ticks': [(0.2, (7, 0, 220, 255)), (0.5, (236, 0, 134, 255)), (0.8, (246, 246, 0, 255)), (1.0, (255, 255, 255, 255)), (0.0, (0, 0, 0, 255))], 'mode': 'rgb'}), ('yellowy', {'ticks': [(0.0, (0, 0, 0, 255)), (0.2328863796753704, (32, 0, 129, 255)), (0.8362738179251941, (255, 255, 0, 255)), (0.5257586450247, (115, 15, 255, 255)), (1.0, (255, 255, 255, 255))], 'mode': 'rgb'} ), ('bipolar', {'ticks': [(0.0, (0, 255, 255, 255)), (1.0, (255, 255, 0, 255)), (0.5, (0, 0, 0, 255)), (0.25, (0, 0, 255, 255)), (0.75, (255, 0, 0, 255))], 'mode': 'rgb'}), ('spectrum', {'ticks': [(1.0, (255, 0, 255, 255)), (0.0, (255, 0, 0, 255))], 'mode': 'hsv'}), ('cyclic', {'ticks': [(0.0, (255, 0, 4, 255)), (1.0, (255, 0, 0, 255))], 'mode': 'hsv'}), ('greyclip', {'ticks': [(0.0, (0, 0, 0, 255)), (0.99, (255, 255, 255, 255)), (1.0, (255, 0, 0, 255))], 'mode': 'rgb'}), ('grey', {'ticks': [(0.0, (0, 0, 0, 255)), (1.0, (255, 255, 255, 255))], 'mode': 'rgb'}), ]) def addGradientListToDocstring(): """Decorator to add list of current pre-defined gradients to the end of a function docstring.""" def dec(fn): fn.__doc__ = fn.__doc__ + str(Gradients.keys()).strip('[').strip(']') return fn return dec class TickSliderItem(GraphicsWidget): ## public class """**Bases:** :class:`GraphicsWidget ` A rectangular item with tick marks along its length that can (optionally) be moved by the user.""" def __init__(self, orientation='bottom', allowAdd=True, **kargs): """ ============== ================================================================================= **Arguments:** orientation Set the orientation of the gradient. Options are: 'left', 'right' 'top', and 'bottom'. allowAdd Specifies whether ticks can be added to the item by the user. tickPen Default is white. Specifies the color of the outline of the ticks. Can be any of the valid arguments for :func:`mkPen ` ============== ================================================================================= """ ## public GraphicsWidget.__init__(self) self.orientation = orientation self.length = 100 self.tickSize = 15 self.ticks = {} self.maxDim = 20 self.allowAdd = allowAdd if 'tickPen' in kargs: self.tickPen = fn.mkPen(kargs['tickPen']) else: self.tickPen = fn.mkPen('w') self.orientations = { 'left': (90, 1, 1), 'right': (90, 1, 1), 'top': (0, 1, -1), 'bottom': (0, 1, 1) } self.setOrientation(orientation) #self.setFrameStyle(QtGui.QFrame.NoFrame | QtGui.QFrame.Plain) #self.setBackgroundRole(QtGui.QPalette.NoRole) #self.setMouseTracking(True) #def boundingRect(self): #return self.mapRectFromParent(self.geometry()).normalized() #def shape(self): ## No idea why this is necessary, but rotated items do not receive clicks otherwise. #p = QtGui.QPainterPath() #p.addRect(self.boundingRect()) #return p def paint(self, p, opt, widget): #p.setPen(fn.mkPen('g', width=3)) #p.drawRect(self.boundingRect()) return def keyPressEvent(self, ev): ev.ignore() def setMaxDim(self, mx=None): if mx is None: mx = self.maxDim else: self.maxDim = mx if self.orientation in ['bottom', 'top']: self.setFixedHeight(mx) self.setMaximumWidth(16777215) else: self.setFixedWidth(mx) self.setMaximumHeight(16777215) def setOrientation(self, orientation): ## public """Set the orientation of the TickSliderItem. ============== =================================================================== **Arguments:** orientation Options are: 'left', 'right', 'top', 'bottom' The orientation option specifies which side of the slider the ticks are on, as well as whether the slider is vertical ('right' and 'left') or horizontal ('top' and 'bottom'). ============== =================================================================== """ self.orientation = orientation self.setMaxDim() self.resetTransform() ort = orientation if ort == 'top': transform = QtGui.QTransform.fromScale(1, -1) transform.translate(0, -self.height()) self.setTransform(transform) elif ort == 'left': transform = QtGui.QTransform() transform.rotate(270) transform.scale(1, -1) transform.translate(-self.height(), -self.maxDim) self.setTransform(transform) elif ort == 'right': transform = QtGui.QTransform() transform.rotate(270) transform.translate(-self.height(), 0) self.setTransform(transform) elif ort != 'bottom': raise Exception("%s is not a valid orientation. Options are 'left', 'right', 'top', and 'bottom'" %str(ort)) self.translate(self.tickSize/2., 0) def addTick(self, x, color=None, movable=True): ## public """ Add a tick to the item. ============== ================================================================== **Arguments:** x Position where tick should be added. color Color of added tick. If color is not specified, the color will be white. movable Specifies whether the tick is movable with the mouse. ============== ================================================================== """ if color is None: color = QtGui.QColor(255,255,255) tick = Tick(self, [x*self.length, 0], color, movable, self.tickSize, pen=self.tickPen) self.ticks[tick] = x tick.setParentItem(self) return tick def removeTick(self, tick): ## public """ Removes the specified tick. """ del self.ticks[tick] tick.setParentItem(None) if self.scene() is not None: self.scene().removeItem(tick) def tickMoved(self, tick, pos): #print "tick changed" ## Correct position of tick if it has left bounds. newX = min(max(0, pos.x()), self.length) pos.setX(newX) tick.setPos(pos) self.ticks[tick] = float(newX) / self.length def tickMoveFinished(self, tick): pass def tickClicked(self, tick, ev): if ev.button() == QtCore.Qt.RightButton: self.removeTick(tick) def widgetLength(self): if self.orientation in ['bottom', 'top']: return self.width() else: return self.height() def resizeEvent(self, ev): wlen = max(40, self.widgetLength()) self.setLength(wlen-self.tickSize-2) self.setOrientation(self.orientation) #bounds = self.scene().itemsBoundingRect() #bounds.setLeft(min(-self.tickSize*0.5, bounds.left())) #bounds.setRight(max(self.length + self.tickSize, bounds.right())) #self.setSceneRect(bounds) #self.fitInView(bounds, QtCore.Qt.KeepAspectRatio) def setLength(self, newLen): #private for t, x in list(self.ticks.items()): t.setPos(x * newLen + 1, t.pos().y()) self.length = float(newLen) #def mousePressEvent(self, ev): #QtGui.QGraphicsView.mousePressEvent(self, ev) #self.ignoreRelease = False #for i in self.items(ev.pos()): #if isinstance(i, Tick): #self.ignoreRelease = True #break ##if len(self.items(ev.pos())) > 0: ## Let items handle their own clicks ##self.ignoreRelease = True #def mouseReleaseEvent(self, ev): #QtGui.QGraphicsView.mouseReleaseEvent(self, ev) #if self.ignoreRelease: #return #pos = self.mapToScene(ev.pos()) #if ev.button() == QtCore.Qt.LeftButton and self.allowAdd: #if pos.x() < 0 or pos.x() > self.length: #return #if pos.y() < 0 or pos.y() > self.tickSize: #return #pos.setX(min(max(pos.x(), 0), self.length)) #self.addTick(pos.x()/self.length) #elif ev.button() == QtCore.Qt.RightButton: #self.showMenu(ev) def mouseClickEvent(self, ev): if ev.button() == QtCore.Qt.LeftButton and self.allowAdd: pos = ev.pos() if pos.x() < 0 or pos.x() > self.length: return if pos.y() < 0 or pos.y() > self.tickSize: return pos.setX(min(max(pos.x(), 0), self.length)) self.addTick(pos.x()/self.length) elif ev.button() == QtCore.Qt.RightButton: self.showMenu(ev) #if ev.button() == QtCore.Qt.RightButton: #if self.moving: #ev.accept() #self.setPos(self.startPosition) #self.moving = False #self.sigMoving.emit(self) #self.sigMoved.emit(self) #else: #pass #self.view().tickClicked(self, ev) ###remove def hoverEvent(self, ev): if (not ev.isExit()) and ev.acceptClicks(QtCore.Qt.LeftButton): ev.acceptClicks(QtCore.Qt.RightButton) ## show ghost tick #self.currentPen = fn.mkPen(255, 0,0) #else: #self.currentPen = self.pen #self.update() def showMenu(self, ev): pass def setTickColor(self, tick, color): """Set the color of the specified tick. ============== ================================================================== **Arguments:** tick Can be either an integer corresponding to the index of the tick or a Tick object. Ex: if you had a slider with 3 ticks and you wanted to change the middle tick, the index would be 1. color The color to make the tick. Can be any argument that is valid for :func:`mkBrush ` ============== ================================================================== """ tick = self.getTick(tick) tick.color = color tick.update() #tick.setBrush(QtGui.QBrush(QtGui.QColor(tick.color))) def setTickValue(self, tick, val): ## public """ Set the position (along the slider) of the tick. ============== ================================================================== **Arguments:** tick Can be either an integer corresponding to the index of the tick or a Tick object. Ex: if you had a slider with 3 ticks and you wanted to change the middle tick, the index would be 1. val The desired position of the tick. If val is < 0, position will be set to 0. If val is > 1, position will be set to 1. ============== ================================================================== """ tick = self.getTick(tick) val = min(max(0.0, val), 1.0) x = val * self.length pos = tick.pos() pos.setX(x) tick.setPos(pos) self.ticks[tick] = val self.updateGradient() def tickValue(self, tick): ## public """Return the value (from 0.0 to 1.0) of the specified tick. ============== ================================================================== **Arguments:** tick Can be either an integer corresponding to the index of the tick or a Tick object. Ex: if you had a slider with 3 ticks and you wanted the value of the middle tick, the index would be 1. ============== ================================================================== """ tick = self.getTick(tick) return self.ticks[tick] def getTick(self, tick): ## public """Return the Tick object at the specified index. ============== ================================================================== **Arguments:** tick An integer corresponding to the index of the desired tick. If the argument is not an integer it will be returned unchanged. ============== ================================================================== """ if type(tick) is int: tick = self.listTicks()[tick][0] return tick #def mouseMoveEvent(self, ev): #QtGui.QGraphicsView.mouseMoveEvent(self, ev) def listTicks(self): """Return a sorted list of all the Tick objects on the slider.""" ## public ticks = list(self.ticks.items()) sortList(ticks, lambda a,b: cmp(a[1], b[1])) ## see pyqtgraph.python2_3.sortList return ticks class GradientEditorItem(TickSliderItem): """ **Bases:** :class:`TickSliderItem ` An item that can be used to define a color gradient. Implements common pre-defined gradients that are customizable by the user. :class: `GradientWidget ` provides a widget with a GradientEditorItem that can be added to a GUI. ================================ =========================================================== **Signals:** sigGradientChanged(self) Signal is emitted anytime the gradient changes. The signal is emitted in real time while ticks are being dragged or colors are being changed. sigGradientChangeFinished(self) Signal is emitted when the gradient is finished changing. ================================ =========================================================== """ sigGradientChanged = QtCore.Signal(object) sigGradientChangeFinished = QtCore.Signal(object) def __init__(self, *args, **kargs): """ Create a new GradientEditorItem. All arguments are passed to :func:`TickSliderItem.__init__ ` =============== ================================================================================= **Arguments:** orientation Set the orientation of the gradient. Options are: 'left', 'right' 'top', and 'bottom'. allowAdd Default is True. Specifies whether ticks can be added to the item. tickPen Default is white. Specifies the color of the outline of the ticks. Can be any of the valid arguments for :func:`mkPen ` =============== ================================================================================= """ self.currentTick = None self.currentTickColor = None self.rectSize = 15 self.gradRect = QtGui.QGraphicsRectItem(QtCore.QRectF(0, self.rectSize, 100, self.rectSize)) self.backgroundRect = QtGui.QGraphicsRectItem(QtCore.QRectF(0, -self.rectSize, 100, self.rectSize)) self.backgroundRect.setBrush(QtGui.QBrush(QtCore.Qt.DiagCrossPattern)) self.colorMode = 'rgb' TickSliderItem.__init__(self, *args, **kargs) self.colorDialog = QtGui.QColorDialog() self.colorDialog.setOption(QtGui.QColorDialog.ShowAlphaChannel, True) self.colorDialog.setOption(QtGui.QColorDialog.DontUseNativeDialog, True) self.colorDialog.currentColorChanged.connect(self.currentColorChanged) self.colorDialog.rejected.connect(self.currentColorRejected) self.colorDialog.accepted.connect(self.currentColorAccepted) self.backgroundRect.setParentItem(self) self.gradRect.setParentItem(self) self.setMaxDim(self.rectSize + self.tickSize) self.rgbAction = QtGui.QAction('RGB', self) self.rgbAction.setCheckable(True) self.rgbAction.triggered.connect(lambda: self.setColorMode('rgb')) self.hsvAction = QtGui.QAction('HSV', self) self.hsvAction.setCheckable(True) self.hsvAction.triggered.connect(lambda: self.setColorMode('hsv')) self.menu = QtGui.QMenu() ## build context menu of gradients l = self.length self.length = 100 global Gradients for g in Gradients: px = QtGui.QPixmap(100, 15) p = QtGui.QPainter(px) self.restoreState(Gradients[g]) grad = self.getGradient() brush = QtGui.QBrush(grad) p.fillRect(QtCore.QRect(0, 0, 100, 15), brush) p.end() label = QtGui.QLabel() label.setPixmap(px) label.setContentsMargins(1, 1, 1, 1) act = QtGui.QWidgetAction(self) act.setDefaultWidget(label) act.triggered.connect(self.contextMenuClicked) act.name = g self.menu.addAction(act) self.length = l self.menu.addSeparator() self.menu.addAction(self.rgbAction) self.menu.addAction(self.hsvAction) for t in list(self.ticks.keys()): self.removeTick(t) self.addTick(0, QtGui.QColor(0,0,0), True) self.addTick(1, QtGui.QColor(255,0,0), True) self.setColorMode('rgb') self.updateGradient() def setOrientation(self, orientation): ## public """ Set the orientation of the GradientEditorItem. ============== =================================================================== **Arguments:** orientation Options are: 'left', 'right', 'top', 'bottom' The orientation option specifies which side of the gradient the ticks are on, as well as whether the gradient is vertical ('right' and 'left') or horizontal ('top' and 'bottom'). ============== =================================================================== """ TickSliderItem.setOrientation(self, orientation) self.translate(0, self.rectSize) def showMenu(self, ev): #private self.menu.popup(ev.screenPos().toQPoint()) def contextMenuClicked(self, b=None): #private #global Gradients act = self.sender() self.loadPreset(act.name) @addGradientListToDocstring() def loadPreset(self, name): """ Load a predefined gradient. Currently defined gradients are: """## TODO: provide image with names of defined gradients #global Gradients self.restoreState(Gradients[name]) def setColorMode(self, cm): """ Set the color mode for the gradient. Options are: 'hsv', 'rgb' """ ## public if cm not in ['rgb', 'hsv']: raise Exception("Unknown color mode %s. Options are 'rgb' and 'hsv'." % str(cm)) try: self.rgbAction.blockSignals(True) self.hsvAction.blockSignals(True) self.rgbAction.setChecked(cm == 'rgb') self.hsvAction.setChecked(cm == 'hsv') finally: self.rgbAction.blockSignals(False) self.hsvAction.blockSignals(False) self.colorMode = cm self.updateGradient() def colorMap(self): """Return a ColorMap object representing the current state of the editor.""" if self.colorMode == 'hsv': raise NotImplementedError('hsv colormaps not yet supported') pos = [] color = [] for t,x in self.listTicks(): pos.append(x) c = t.color color.append([c.red(), c.green(), c.blue(), c.alpha()]) return ColorMap(np.array(pos), np.array(color, dtype=np.ubyte)) def updateGradient(self): #private self.gradient = self.getGradient() self.gradRect.setBrush(QtGui.QBrush(self.gradient)) self.sigGradientChanged.emit(self) def setLength(self, newLen): #private (but maybe public) TickSliderItem.setLength(self, newLen) self.backgroundRect.setRect(1, -self.rectSize, newLen, self.rectSize) self.gradRect.setRect(1, -self.rectSize, newLen, self.rectSize) self.updateGradient() def currentColorChanged(self, color): #private if color.isValid() and self.currentTick is not None: self.setTickColor(self.currentTick, color) self.updateGradient() def currentColorRejected(self): #private self.setTickColor(self.currentTick, self.currentTickColor) self.updateGradient() def currentColorAccepted(self): self.sigGradientChangeFinished.emit(self) def tickClicked(self, tick, ev): #private if ev.button() == QtCore.Qt.LeftButton: self.raiseColorDialog(tick) elif ev.button() == QtCore.Qt.RightButton: self.raiseTickContextMenu(tick, ev) def raiseColorDialog(self, tick): if not tick.colorChangeAllowed: return self.currentTick = tick self.currentTickColor = tick.color self.colorDialog.setCurrentColor(tick.color) self.colorDialog.open() def raiseTickContextMenu(self, tick, ev): self.tickMenu = TickMenu(tick, self) self.tickMenu.popup(ev.screenPos().toQPoint()) def tickMoved(self, tick, pos): #private TickSliderItem.tickMoved(self, tick, pos) self.updateGradient() def tickMoveFinished(self, tick): self.sigGradientChangeFinished.emit(self) def getGradient(self): """Return a QLinearGradient object.""" g = QtGui.QLinearGradient(QtCore.QPointF(0,0), QtCore.QPointF(self.length,0)) if self.colorMode == 'rgb': ticks = self.listTicks() g.setStops([(x, QtGui.QColor(t.color)) for t,x in ticks]) elif self.colorMode == 'hsv': ## HSV mode is approximated for display by interpolating 10 points between each stop ticks = self.listTicks() stops = [] stops.append((ticks[0][1], ticks[0][0].color)) for i in range(1,len(ticks)): x1 = ticks[i-1][1] x2 = ticks[i][1] dx = (x2-x1) / 10. for j in range(1,10): x = x1 + dx*j stops.append((x, self.getColor(x))) stops.append((x2, self.getColor(x2))) g.setStops(stops) return g def getColor(self, x, toQColor=True): """ Return a color for a given value. ============== ================================================================== **Arguments:** x Value (position on gradient) of requested color. toQColor If true, returns a QColor object, else returns a (r,g,b,a) tuple. ============== ================================================================== """ ticks = self.listTicks() if x <= ticks[0][1]: c = ticks[0][0].color if toQColor: return QtGui.QColor(c) # always copy colors before handing them out else: return (c.red(), c.green(), c.blue(), c.alpha()) if x >= ticks[-1][1]: c = ticks[-1][0].color if toQColor: return QtGui.QColor(c) # always copy colors before handing them out else: return (c.red(), c.green(), c.blue(), c.alpha()) x2 = ticks[0][1] for i in range(1,len(ticks)): x1 = x2 x2 = ticks[i][1] if x1 <= x and x2 >= x: break dx = (x2-x1) if dx == 0: f = 0. else: f = (x-x1) / dx c1 = ticks[i-1][0].color c2 = ticks[i][0].color if self.colorMode == 'rgb': r = c1.red() * (1.-f) + c2.red() * f g = c1.green() * (1.-f) + c2.green() * f b = c1.blue() * (1.-f) + c2.blue() * f a = c1.alpha() * (1.-f) + c2.alpha() * f if toQColor: return QtGui.QColor(int(r), int(g), int(b), int(a)) else: return (r,g,b,a) elif self.colorMode == 'hsv': h1,s1,v1,_ = c1.getHsv() h2,s2,v2,_ = c2.getHsv() h = h1 * (1.-f) + h2 * f s = s1 * (1.-f) + s2 * f v = v1 * (1.-f) + v2 * f c = QtGui.QColor() c.setHsv(h,s,v) if toQColor: return c else: return (c.red(), c.green(), c.blue(), c.alpha()) def getLookupTable(self, nPts, alpha=None): """ Return an RGB(A) lookup table (ndarray). ============== ============================================================================ **Arguments:** nPts The number of points in the returned lookup table. alpha True, False, or None - Specifies whether or not alpha values are included in the table.If alpha is None, alpha will be automatically determined. ============== ============================================================================ """ if alpha is None: alpha = self.usesAlpha() if alpha: table = np.empty((nPts,4), dtype=np.ubyte) else: table = np.empty((nPts,3), dtype=np.ubyte) for i in range(nPts): x = float(i)/(nPts-1) color = self.getColor(x, toQColor=False) table[i] = color[:table.shape[1]] return table def usesAlpha(self): """Return True if any ticks have an alpha < 255""" ticks = self.listTicks() for t in ticks: if t[0].color.alpha() < 255: return True return False def isLookupTrivial(self): """Return True if the gradient has exactly two stops in it: black at 0.0 and white at 1.0""" ticks = self.listTicks() if len(ticks) != 2: return False if ticks[0][1] != 0.0 or ticks[1][1] != 1.0: return False c1 = fn.colorTuple(ticks[0][0].color) c2 = fn.colorTuple(ticks[1][0].color) if c1 != (0,0,0,255) or c2 != (255,255,255,255): return False return True def mouseReleaseEvent(self, ev): #private TickSliderItem.mouseReleaseEvent(self, ev) self.updateGradient() def addTick(self, x, color=None, movable=True, finish=True): """ Add a tick to the gradient. Return the tick. ============== ================================================================== **Arguments:** x Position where tick should be added. color Color of added tick. If color is not specified, the color will be the color of the gradient at the specified position. movable Specifies whether the tick is movable with the mouse. ============== ================================================================== """ if color is None: color = self.getColor(x) t = TickSliderItem.addTick(self, x, color=color, movable=movable) t.colorChangeAllowed = True t.removeAllowed = True if finish: self.sigGradientChangeFinished.emit(self) return t def removeTick(self, tick, finish=True): TickSliderItem.removeTick(self, tick) if finish: self.updateGradient() self.sigGradientChangeFinished.emit(self) def saveState(self): """ Return a dictionary with parameters for rebuilding the gradient. Keys will include: - 'mode': hsv or rgb - 'ticks': a list of tuples (pos, (r,g,b,a)) """ ## public ticks = [] for t in self.ticks: c = t.color ticks.append((self.ticks[t], (c.red(), c.green(), c.blue(), c.alpha()))) state = {'mode': self.colorMode, 'ticks': ticks} return state def restoreState(self, state): """ Restore the gradient specified in state. ============== ==================================================================== **Arguments:** state A dictionary with same structure as those returned by :func:`saveState ` Keys must include: - 'mode': hsv or rgb - 'ticks': a list of tuples (pos, (r,g,b,a)) ============== ==================================================================== """ ## public self.setColorMode(state['mode']) for t in list(self.ticks.keys()): self.removeTick(t, finish=False) for t in state['ticks']: c = QtGui.QColor(*t[1]) self.addTick(t[0], c, finish=False) self.updateGradient() self.sigGradientChangeFinished.emit(self) def setColorMap(self, cm): self.setColorMode('rgb') for t in list(self.ticks.keys()): self.removeTick(t, finish=False) colors = cm.getColors(mode='qcolor') for i in range(len(cm.pos)): x = cm.pos[i] c = colors[i] self.addTick(x, c, finish=False) self.updateGradient() self.sigGradientChangeFinished.emit(self) class Tick(QtGui.QGraphicsWidget): ## NOTE: Making this a subclass of GraphicsObject instead results in ## activating this bug: https://bugreports.qt-project.org/browse/PYSIDE-86 ## private class # When making Tick a subclass of QtGui.QGraphicsObject as origin, # ..GraphicsScene.items(self, *args) will get Tick object as a # class of QtGui.QMultimediaWidgets.QGraphicsVideoItem in python2.7-PyQt5(5.4.0) sigMoving = QtCore.Signal(object) sigMoved = QtCore.Signal(object) def __init__(self, view, pos, color, movable=True, scale=10, pen='w'): self.movable = movable self.moving = False self.view = weakref.ref(view) self.scale = scale self.color = color self.pen = fn.mkPen(pen) self.hoverPen = fn.mkPen(255,255,0) self.currentPen = self.pen self.pg = QtGui.QPainterPath(QtCore.QPointF(0,0)) self.pg.lineTo(QtCore.QPointF(-scale/3**0.5, scale)) self.pg.lineTo(QtCore.QPointF(scale/3**0.5, scale)) self.pg.closeSubpath() QtGui.QGraphicsWidget.__init__(self) self.setPos(pos[0], pos[1]) if self.movable: self.setZValue(1) else: self.setZValue(0) def boundingRect(self): return self.pg.boundingRect() def shape(self): return self.pg def paint(self, p, *args): p.setRenderHints(QtGui.QPainter.Antialiasing) p.fillPath(self.pg, fn.mkBrush(self.color)) p.setPen(self.currentPen) p.drawPath(self.pg) def mouseDragEvent(self, ev): if self.movable and ev.button() == QtCore.Qt.LeftButton: if ev.isStart(): self.moving = True self.cursorOffset = self.pos() - self.mapToParent(ev.buttonDownPos()) self.startPosition = self.pos() ev.accept() if not self.moving: return newPos = self.cursorOffset + self.mapToParent(ev.pos()) newPos.setY(self.pos().y()) self.setPos(newPos) self.view().tickMoved(self, newPos) self.sigMoving.emit(self) if ev.isFinish(): self.moving = False self.sigMoved.emit(self) self.view().tickMoveFinished(self) def mouseClickEvent(self, ev): if ev.button() == QtCore.Qt.RightButton and self.moving: ev.accept() self.setPos(self.startPosition) self.view().tickMoved(self, self.startPosition) self.moving = False self.sigMoving.emit(self) self.sigMoved.emit(self) else: self.view().tickClicked(self, ev) ##remove def hoverEvent(self, ev): if (not ev.isExit()) and ev.acceptDrags(QtCore.Qt.LeftButton): ev.acceptClicks(QtCore.Qt.LeftButton) ev.acceptClicks(QtCore.Qt.RightButton) self.currentPen = self.hoverPen else: self.currentPen = self.pen self.update() class TickMenu(QtGui.QMenu): def __init__(self, tick, sliderItem): QtGui.QMenu.__init__(self) self.tick = weakref.ref(tick) self.sliderItem = weakref.ref(sliderItem) self.removeAct = self.addAction("Remove Tick", lambda: self.sliderItem().removeTick(tick)) if (not self.tick().removeAllowed) or len(self.sliderItem().ticks) < 3: self.removeAct.setEnabled(False) positionMenu = self.addMenu("Set Position") w = QtGui.QWidget() l = QtGui.QGridLayout() w.setLayout(l) value = sliderItem.tickValue(tick) self.fracPosSpin = SpinBox() self.fracPosSpin.setOpts(value=value, bounds=(0.0, 1.0), step=0.01, decimals=2) #self.dataPosSpin = SpinBox(value=dataVal) #self.dataPosSpin.setOpts(decimals=3, siPrefix=True) l.addWidget(QtGui.QLabel("Position:"), 0,0) l.addWidget(self.fracPosSpin, 0, 1) #l.addWidget(QtGui.QLabel("Position (data units):"), 1, 0) #l.addWidget(self.dataPosSpin, 1,1) #if self.sliderItem().dataParent is None: # self.dataPosSpin.setEnabled(False) a = QtGui.QWidgetAction(self) a.setDefaultWidget(w) positionMenu.addAction(a) self.fracPosSpin.sigValueChanging.connect(self.fractionalValueChanged) #self.dataPosSpin.valueChanged.connect(self.dataValueChanged) colorAct = self.addAction("Set Color", lambda: self.sliderItem().raiseColorDialog(self.tick())) if not self.tick().colorChangeAllowed: colorAct.setEnabled(False) def fractionalValueChanged(self, x): self.sliderItem().setTickValue(self.tick(), self.fracPosSpin.value()) #if self.sliderItem().dataParent is not None: # self.dataPosSpin.blockSignals(True) # self.dataPosSpin.setValue(self.sliderItem().tickDataValue(self.tick())) # self.dataPosSpin.blockSignals(False) #def dataValueChanged(self, val): # self.sliderItem().setTickValue(self.tick(), val, dataUnits=True) # self.fracPosSpin.blockSignals(True) # self.fracPosSpin.setValue(self.sliderItem().tickValue(self.tick())) # self.fracPosSpin.blockSignals(False) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/GradientLegend.py000066400000000000000000000102661300727121400256750ustar00rootroot00000000000000from ..Qt import QtGui, QtCore from .UIGraphicsItem import * from .. import functions as fn __all__ = ['GradientLegend'] class GradientLegend(UIGraphicsItem): """ Draws a color gradient rectangle along with text labels denoting the value at specific points along the gradient. """ def __init__(self, size, offset): self.size = size self.offset = offset UIGraphicsItem.__init__(self) self.setAcceptedMouseButtons(QtCore.Qt.NoButton) self.brush = QtGui.QBrush(QtGui.QColor(200,0,0)) self.pen = QtGui.QPen(QtGui.QColor(0,0,0)) self.labels = {'max': 1, 'min': 0} self.gradient = QtGui.QLinearGradient() self.gradient.setColorAt(0, QtGui.QColor(0,0,0)) self.gradient.setColorAt(1, QtGui.QColor(255,0,0)) def setGradient(self, g): self.gradient = g self.update() def setIntColorScale(self, minVal, maxVal, *args, **kargs): colors = [fn.intColor(i, maxVal-minVal, *args, **kargs) for i in range(minVal, maxVal)] g = QtGui.QLinearGradient() for i in range(len(colors)): x = float(i)/len(colors) g.setColorAt(x, colors[i]) self.setGradient(g) if 'labels' not in kargs: self.setLabels({str(minVal/10.): 0, str(maxVal): 1}) else: self.setLabels({kargs['labels'][0]:0, kargs['labels'][1]:1}) def setLabels(self, l): """Defines labels to appear next to the color scale. Accepts a dict of {text: value} pairs""" self.labels = l self.update() def paint(self, p, opt, widget): UIGraphicsItem.paint(self, p, opt, widget) rect = self.boundingRect() ## Boundaries of visible area in scene coords. unit = self.pixelSize() ## Size of one view pixel in scene coords. if unit[0] is None: return ## determine max width of all labels labelWidth = 0 labelHeight = 0 for k in self.labels: b = p.boundingRect(QtCore.QRectF(0, 0, 0, 0), QtCore.Qt.AlignLeft | QtCore.Qt.AlignVCenter, str(k)) labelWidth = max(labelWidth, b.width()) labelHeight = max(labelHeight, b.height()) labelWidth *= unit[0] labelHeight *= unit[1] textPadding = 2 # in px if self.offset[0] < 0: x3 = rect.right() + unit[0] * self.offset[0] x2 = x3 - labelWidth - unit[0]*textPadding*2 x1 = x2 - unit[0] * self.size[0] else: x1 = rect.left() + unit[0] * self.offset[0] x2 = x1 + unit[0] * self.size[0] x3 = x2 + labelWidth + unit[0]*textPadding*2 if self.offset[1] < 0: y2 = rect.top() - unit[1] * self.offset[1] y1 = y2 + unit[1] * self.size[1] else: y1 = rect.bottom() - unit[1] * self.offset[1] y2 = y1 - unit[1] * self.size[1] self.b = [x1,x2,x3,y1,y2,labelWidth] ## Draw background p.setPen(self.pen) p.setBrush(QtGui.QBrush(QtGui.QColor(255,255,255,100))) rect = QtCore.QRectF( QtCore.QPointF(x1 - unit[0]*textPadding, y1 + labelHeight/2 + unit[1]*textPadding), QtCore.QPointF(x3, y2 - labelHeight/2 - unit[1]*textPadding) ) p.drawRect(rect) ## Have to scale painter so that text and gradients are correct size. Bleh. p.scale(unit[0], unit[1]) ## Draw color bar self.gradient.setStart(0, y1/unit[1]) self.gradient.setFinalStop(0, y2/unit[1]) p.setBrush(self.gradient) rect = QtCore.QRectF( QtCore.QPointF(x1/unit[0], y1/unit[1]), QtCore.QPointF(x2/unit[0], y2/unit[1]) ) p.drawRect(rect) ## draw labels p.setPen(QtGui.QPen(QtGui.QColor(0,0,0))) tx = x2 + unit[0]*textPadding lh = labelHeight/unit[1] for k in self.labels: y = y1 + self.labels[k] * (y2-y1) p.drawText(QtCore.QRectF(tx/unit[0], y/unit[1] - lh/2.0, 1000, lh), QtCore.Qt.AlignLeft | QtCore.Qt.AlignVCenter, str(k)) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/GraphItem.py000066400000000000000000000127111300727121400246760ustar00rootroot00000000000000from .. import functions as fn from .GraphicsObject import GraphicsObject from .ScatterPlotItem import ScatterPlotItem from ..Qt import QtGui, QtCore import numpy as np from .. import getConfigOption __all__ = ['GraphItem'] class GraphItem(GraphicsObject): """A GraphItem displays graph information as a set of nodes connected by lines (as in 'graph theory', not 'graphics'). Useful for drawing networks, trees, etc. """ def __init__(self, **kwds): GraphicsObject.__init__(self) self.scatter = ScatterPlotItem() self.scatter.setParentItem(self) self.adjacency = None self.pos = None self.picture = None self.pen = 'default' self.setData(**kwds) def setData(self, **kwds): """ Change the data displayed by the graph. ============== ======================================================================= **Arguments:** pos (N,2) array of the positions of each node in the graph. adj (M,2) array of connection data. Each row contains indexes of two nodes that are connected. pen The pen to use when drawing lines between connected nodes. May be one of: * QPen * a single argument to pass to pg.mkPen * a record array of length M with fields (red, green, blue, alpha, width). Note that using this option may have a significant performance cost. * None (to disable connection drawing) * 'default' to use the default foreground color. symbolPen The pen(s) used for drawing nodes. symbolBrush The brush(es) used for drawing nodes. ``**opts`` All other keyword arguments are given to :func:`ScatterPlotItem.setData() ` to affect the appearance of nodes (symbol, size, brush, etc.) ============== ======================================================================= """ if 'adj' in kwds: self.adjacency = kwds.pop('adj') if self.adjacency.dtype.kind not in 'iu': raise Exception("adjacency array must have int or unsigned type.") self._update() if 'pos' in kwds: self.pos = kwds['pos'] self._update() if 'pen' in kwds: self.setPen(kwds.pop('pen')) self._update() if 'symbolPen' in kwds: kwds['pen'] = kwds.pop('symbolPen') if 'symbolBrush' in kwds: kwds['brush'] = kwds.pop('symbolBrush') self.scatter.setData(**kwds) self.informViewBoundsChanged() def _update(self): self.picture = None self.prepareGeometryChange() self.update() def setPen(self, *args, **kwargs): """ Set the pen used to draw graph lines. May be: * None to disable line drawing * Record array with fields (red, green, blue, alpha, width) * Any set of arguments and keyword arguments accepted by :func:`mkPen `. * 'default' to use the default foreground color. """ if len(args) == 1 and len(kwargs) == 0: self.pen = args[0] else: self.pen = fn.mkPen(*args, **kwargs) self.picture = None self.update() def generatePicture(self): self.picture = QtGui.QPicture() if self.pen is None or self.pos is None or self.adjacency is None: return p = QtGui.QPainter(self.picture) try: pts = self.pos[self.adjacency] pen = self.pen if isinstance(pen, np.ndarray): lastPen = None for i in range(pts.shape[0]): pen = self.pen[i] if np.any(pen != lastPen): lastPen = pen if pen.dtype.fields is None: p.setPen(fn.mkPen(color=(pen[0], pen[1], pen[2], pen[3]), width=1)) else: p.setPen(fn.mkPen(color=(pen['red'], pen['green'], pen['blue'], pen['alpha']), width=pen['width'])) p.drawLine(QtCore.QPointF(*pts[i][0]), QtCore.QPointF(*pts[i][1])) else: if pen == 'default': pen = getConfigOption('foreground') p.setPen(fn.mkPen(pen)) pts = pts.reshape((pts.shape[0]*pts.shape[1], pts.shape[2])) path = fn.arrayToQPath(x=pts[:,0], y=pts[:,1], connect='pairs') p.drawPath(path) finally: p.end() def paint(self, p, *args): if self.picture == None: self.generatePicture() if getConfigOption('antialias') is True: p.setRenderHint(p.Antialiasing) self.picture.play(p) def boundingRect(self): return self.scatter.boundingRect() def dataBounds(self, *args, **kwds): return self.scatter.dataBounds(*args, **kwds) def pixelPadding(self): return self.scatter.pixelPadding() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/GraphicsItem.py000066400000000000000000000554571300727121400254130ustar00rootroot00000000000000from ..Qt import QtGui, QtCore, isQObjectAlive from ..GraphicsScene import GraphicsScene from ..Point import Point from .. import functions as fn import weakref import operator from ..util.lru_cache import LRUCache class GraphicsItem(object): """ **Bases:** :class:`object` Abstract class providing useful methods to GraphicsObject and GraphicsWidget. (This is required because we cannot have multiple inheritance with QObject subclasses.) A note about Qt's GraphicsView framework: The GraphicsView system places a lot of emphasis on the notion that the graphics within the scene should be device independent--you should be able to take the same graphics and display them on screens of different resolutions, printers, export to SVG, etc. This is nice in principle, but causes me a lot of headache in practice. It means that I have to circumvent all the device-independent expectations any time I want to operate in pixel coordinates rather than arbitrary scene coordinates. A lot of the code in GraphicsItem is devoted to this task--keeping track of view widgets and device transforms, computing the size and shape of a pixel in local item coordinates, etc. Note that in item coordinates, a pixel does not have to be square or even rectangular, so just asking how to increase a bounding rect by 2px can be a rather complex task. """ _pixelVectorGlobalCache = LRUCache(100, 70) def __init__(self, register=True): if not hasattr(self, '_qtBaseClass'): for b in self.__class__.__bases__: if issubclass(b, QtGui.QGraphicsItem): self.__class__._qtBaseClass = b break if not hasattr(self, '_qtBaseClass'): raise Exception('Could not determine Qt base class for GraphicsItem: %s' % str(self)) self._pixelVectorCache = [None, None] self._viewWidget = None self._viewBox = None self._connectedView = None self._exportOpts = False ## If False, not currently exporting. Otherwise, contains dict of export options. if register: GraphicsScene.registerObject(self) ## workaround for pyqt bug in graphicsscene.items() def getViewWidget(self): """ Return the view widget for this item. If the scene has multiple views, only the first view is returned. The return value is cached; clear the cached value with forgetViewWidget(). If the view has been deleted by Qt, return None. """ if self._viewWidget is None: scene = self.scene() if scene is None: return None views = scene.views() if len(views) < 1: return None self._viewWidget = weakref.ref(self.scene().views()[0]) v = self._viewWidget() if v is not None and not isQObjectAlive(v): return None return v def forgetViewWidget(self): self._viewWidget = None def getViewBox(self): """ Return the first ViewBox or GraphicsView which bounds this item's visible space. If this item is not contained within a ViewBox, then the GraphicsView is returned. If the item is contained inside nested ViewBoxes, then the inner-most ViewBox is returned. The result is cached; clear the cache with forgetViewBox() """ if self._viewBox is None: p = self while True: try: p = p.parentItem() except RuntimeError: ## sometimes happens as items are being removed from a scene and collected. return None if p is None: vb = self.getViewWidget() if vb is None: return None else: self._viewBox = weakref.ref(vb) break if hasattr(p, 'implements') and p.implements('ViewBox'): self._viewBox = weakref.ref(p) break return self._viewBox() ## If we made it this far, _viewBox is definitely not None def forgetViewBox(self): self._viewBox = None def deviceTransform(self, viewportTransform=None): """ Return the transform that converts local item coordinates to device coordinates (usually pixels). Extends deviceTransform to automatically determine the viewportTransform. """ if self._exportOpts is not False and 'painter' in self._exportOpts: ## currently exporting; device transform may be different. return self._exportOpts['painter'].deviceTransform() * self.sceneTransform() if viewportTransform is None: view = self.getViewWidget() if view is None: return None viewportTransform = view.viewportTransform() dt = self._qtBaseClass.deviceTransform(self, viewportTransform) #xmag = abs(dt.m11())+abs(dt.m12()) #ymag = abs(dt.m21())+abs(dt.m22()) #if xmag * ymag == 0: if dt.determinant() == 0: ## occurs when deviceTransform is invalid because widget has not been displayed return None else: return dt def viewTransform(self): """Return the transform that maps from local coordinates to the item's ViewBox coordinates If there is no ViewBox, return the scene transform. Returns None if the item does not have a view.""" view = self.getViewBox() if view is None: return None if hasattr(view, 'implements') and view.implements('ViewBox'): tr = self.itemTransform(view.innerSceneItem()) if isinstance(tr, tuple): tr = tr[0] ## difference between pyside and pyqt return tr else: return self.sceneTransform() #return self.deviceTransform(view.viewportTransform()) def getBoundingParents(self): """Return a list of parents to this item that have child clipping enabled.""" p = self parents = [] while True: p = p.parentItem() if p is None: break if p.flags() & self.ItemClipsChildrenToShape: parents.append(p) return parents def viewRect(self): """Return the bounds (in item coordinates) of this item's ViewBox or GraphicsWidget""" view = self.getViewBox() if view is None: return None bounds = self.mapRectFromView(view.viewRect()) if bounds is None: return None bounds = bounds.normalized() ## nah. #for p in self.getBoundingParents(): #bounds &= self.mapRectFromScene(p.sceneBoundingRect()) return bounds def pixelVectors(self, direction=None): """Return vectors in local coordinates representing the width and height of a view pixel. If direction is specified, then return vectors parallel and orthogonal to it. Return (None, None) if pixel size is not yet defined (usually because the item has not yet been displayed) or if pixel size is below floating-point precision limit. """ ## This is an expensive function that gets called very frequently. ## We have two levels of cache to try speeding things up. dt = self.deviceTransform() if dt is None: return None, None ## Ignore translation. If the translation is much larger than the scale ## (such as when looking at unix timestamps), we can get floating-point errors. dt.setMatrix(dt.m11(), dt.m12(), 0, dt.m21(), dt.m22(), 0, 0, 0, 1) ## check local cache if direction is None and dt == self._pixelVectorCache[0]: return tuple(map(Point, self._pixelVectorCache[1])) ## return a *copy* ## check global cache #key = (dt.m11(), dt.m21(), dt.m31(), dt.m12(), dt.m22(), dt.m32(), dt.m31(), dt.m32()) key = (dt.m11(), dt.m21(), dt.m12(), dt.m22()) pv = self._pixelVectorGlobalCache.get(key, None) if direction is None and pv is not None: self._pixelVectorCache = [dt, pv] return tuple(map(Point,pv)) ## return a *copy* if direction is None: direction = QtCore.QPointF(1, 0) if direction.manhattanLength() == 0: raise Exception("Cannot compute pixel length for 0-length vector.") ## attempt to re-scale direction vector to fit within the precision of the coordinate system ## Here's the problem: we need to map the vector 'direction' from the item to the device, via transform 'dt'. ## In some extreme cases, this mapping can fail unless the length of 'direction' is cleverly chosen. ## Example: ## dt = [ 1, 0, 2 ## 0, 2, 1e20 ## 0, 0, 1 ] ## Then we map the origin (0,0) and direction (0,1) and get: ## o' = 2,1e20 ## d' = 2,1e20 <-- should be 1e20+2, but this can't be represented with a 32-bit float ## ## |o' - d'| == 0 <-- this is the problem. ## Perhaps the easiest solution is to exclude the transformation column from dt. Does this cause any other problems? #if direction.x() == 0: #r = abs(dt.m32())/(abs(dt.m12()) + abs(dt.m22())) ##r = 1.0/(abs(dt.m12()) + abs(dt.m22())) #elif direction.y() == 0: #r = abs(dt.m31())/(abs(dt.m11()) + abs(dt.m21())) ##r = 1.0/(abs(dt.m11()) + abs(dt.m21())) #else: #r = ((abs(dt.m32())/(abs(dt.m12()) + abs(dt.m22()))) * (abs(dt.m31())/(abs(dt.m11()) + abs(dt.m21()))))**0.5 #if r == 0: #r = 1. ## shouldn't need to do this; probably means the math above is wrong? #directionr = direction * r directionr = direction ## map direction vector onto device #viewDir = Point(dt.map(directionr) - dt.map(Point(0,0))) #mdirection = dt.map(directionr) dirLine = QtCore.QLineF(QtCore.QPointF(0,0), directionr) viewDir = dt.map(dirLine) if viewDir.length() == 0: return None, None ## pixel size cannot be represented on this scale ## get unit vector and orthogonal vector (length of pixel) #orthoDir = Point(viewDir[1], -viewDir[0]) ## orthogonal to line in pixel-space try: normView = viewDir.unitVector() #normView = viewDir.norm() ## direction of one pixel orthogonal to line normOrtho = normView.normalVector() #normOrtho = orthoDir.norm() except: raise Exception("Invalid direction %s" %directionr) ## map back to item dti = fn.invertQTransform(dt) #pv = Point(dti.map(normView)-dti.map(Point(0,0))), Point(dti.map(normOrtho)-dti.map(Point(0,0))) pv = Point(dti.map(normView).p2()), Point(dti.map(normOrtho).p2()) self._pixelVectorCache[1] = pv self._pixelVectorCache[0] = dt self._pixelVectorGlobalCache[key] = pv return self._pixelVectorCache[1] def pixelLength(self, direction, ortho=False): """Return the length of one pixel in the direction indicated (in local coordinates) If ortho=True, then return the length of one pixel orthogonal to the direction indicated. Return None if pixel size is not yet defined (usually because the item has not yet been displayed). """ normV, orthoV = self.pixelVectors(direction) if normV == None or orthoV == None: return None if ortho: return orthoV.length() return normV.length() def pixelSize(self): ## deprecated v = self.pixelVectors() if v == (None, None): return None, None return (v[0].x()**2+v[0].y()**2)**0.5, (v[1].x()**2+v[1].y()**2)**0.5 def pixelWidth(self): ## deprecated vt = self.deviceTransform() if vt is None: return 0 vt = fn.invertQTransform(vt) return vt.map(QtCore.QLineF(0, 0, 1, 0)).length() def pixelHeight(self): ## deprecated vt = self.deviceTransform() if vt is None: return 0 vt = fn.invertQTransform(vt) return vt.map(QtCore.QLineF(0, 0, 0, 1)).length() #return Point(vt.map(QtCore.QPointF(0, 1))-vt.map(QtCore.QPointF(0, 0))).length() def mapToDevice(self, obj): """ Return *obj* mapped from local coordinates to device coordinates (pixels). If there is no device mapping available, return None. """ vt = self.deviceTransform() if vt is None: return None return vt.map(obj) def mapFromDevice(self, obj): """ Return *obj* mapped from device coordinates (pixels) to local coordinates. If there is no device mapping available, return None. """ vt = self.deviceTransform() if vt is None: return None if isinstance(obj, QtCore.QPoint): obj = QtCore.QPointF(obj) vt = fn.invertQTransform(vt) return vt.map(obj) def mapRectToDevice(self, rect): """ Return *rect* mapped from local coordinates to device coordinates (pixels). If there is no device mapping available, return None. """ vt = self.deviceTransform() if vt is None: return None return vt.mapRect(rect) def mapRectFromDevice(self, rect): """ Return *rect* mapped from device coordinates (pixels) to local coordinates. If there is no device mapping available, return None. """ vt = self.deviceTransform() if vt is None: return None vt = fn.invertQTransform(vt) return vt.mapRect(rect) def mapToView(self, obj): vt = self.viewTransform() if vt is None: return None return vt.map(obj) def mapRectToView(self, obj): vt = self.viewTransform() if vt is None: return None return vt.mapRect(obj) def mapFromView(self, obj): vt = self.viewTransform() if vt is None: return None vt = fn.invertQTransform(vt) return vt.map(obj) def mapRectFromView(self, obj): vt = self.viewTransform() if vt is None: return None vt = fn.invertQTransform(vt) return vt.mapRect(obj) def pos(self): return Point(self._qtBaseClass.pos(self)) def viewPos(self): return self.mapToView(self.mapFromParent(self.pos())) def parentItem(self): ## PyQt bug -- some items are returned incorrectly. return GraphicsScene.translateGraphicsItem(self._qtBaseClass.parentItem(self)) def setParentItem(self, parent): ## Workaround for Qt bug: https://bugreports.qt-project.org/browse/QTBUG-18616 if parent is not None: pscene = parent.scene() if pscene is not None and self.scene() is not pscene: pscene.addItem(self) return self._qtBaseClass.setParentItem(self, parent) def childItems(self): ## PyQt bug -- some child items are returned incorrectly. return list(map(GraphicsScene.translateGraphicsItem, self._qtBaseClass.childItems(self))) def sceneTransform(self): ## Qt bug: do no allow access to sceneTransform() until ## the item has a scene. if self.scene() is None: return self.transform() else: return self._qtBaseClass.sceneTransform(self) def transformAngle(self, relativeItem=None): """Return the rotation produced by this item's transform (this assumes there is no shear in the transform) If relativeItem is given, then the angle is determined relative to that item. """ if relativeItem is None: relativeItem = self.parentItem() tr = self.itemTransform(relativeItem) if isinstance(tr, tuple): ## difference between pyside and pyqt tr = tr[0] #vec = tr.map(Point(1,0)) - tr.map(Point(0,0)) vec = tr.map(QtCore.QLineF(0,0,1,0)) #return Point(vec).angle(Point(1,0)) return vec.angleTo(QtCore.QLineF(vec.p1(), vec.p1()+QtCore.QPointF(1,0))) #def itemChange(self, change, value): #ret = self._qtBaseClass.itemChange(self, change, value) #if change == self.ItemParentHasChanged or change == self.ItemSceneHasChanged: #print "Item scene changed:", self #self.setChildScene(self) ## This is bizarre. #return ret #def setChildScene(self, ch): #scene = self.scene() #for ch2 in ch.childItems(): #if ch2.scene() is not scene: #print "item", ch2, "has different scene:", ch2.scene(), scene #scene.addItem(ch2) #QtGui.QApplication.processEvents() #print " --> ", ch2.scene() #self.setChildScene(ch2) def parentChanged(self): """Called when the item's parent has changed. This method handles connecting / disconnecting from ViewBox signals to make sure viewRangeChanged works properly. It should generally be extended, not overridden.""" self._updateView() def _updateView(self): ## called to see whether this item has a new view to connect to ## NOTE: This is called from GraphicsObject.itemChange or GraphicsWidget.itemChange. ## It is possible this item has moved to a different ViewBox or widget; ## clear out previously determined references to these. self.forgetViewBox() self.forgetViewWidget() ## check for this item's current viewbox or view widget view = self.getViewBox() #if view is None: ##print " no view" #return oldView = None if self._connectedView is not None: oldView = self._connectedView() if view is oldView: #print " already have view", view return ## disconnect from previous view if oldView is not None: for signal, slot in [('sigRangeChanged', self.viewRangeChanged), ('sigDeviceRangeChanged', self.viewRangeChanged), ('sigTransformChanged', self.viewTransformChanged), ('sigDeviceTransformChanged', self.viewTransformChanged)]: try: getattr(oldView, signal).disconnect(slot) except (TypeError, AttributeError, RuntimeError): # TypeError and RuntimeError are from pyqt and pyside, respectively pass self._connectedView = None ## connect to new view if view is not None: #print "connect:", self, view if hasattr(view, 'sigDeviceRangeChanged'): # connect signals from GraphicsView view.sigDeviceRangeChanged.connect(self.viewRangeChanged) view.sigDeviceTransformChanged.connect(self.viewTransformChanged) else: # connect signals from ViewBox view.sigRangeChanged.connect(self.viewRangeChanged) view.sigTransformChanged.connect(self.viewTransformChanged) self._connectedView = weakref.ref(view) self.viewRangeChanged() self.viewTransformChanged() ## inform children that their view might have changed self._replaceView(oldView) self.viewChanged(view, oldView) def viewChanged(self, view, oldView): """Called when this item's view has changed (ie, the item has been added to or removed from a ViewBox)""" pass def _replaceView(self, oldView, item=None): if item is None: item = self for child in item.childItems(): if isinstance(child, GraphicsItem): if child.getViewBox() is oldView: child._updateView() #self._replaceView(oldView, child) else: self._replaceView(oldView, child) def viewRangeChanged(self): """ Called whenever the view coordinates of the ViewBox containing this item have changed. """ pass def viewTransformChanged(self): """ Called whenever the transformation matrix of the view has changed. (eg, the view range has changed or the view was resized) """ pass #def prepareGeometryChange(self): #self._qtBaseClass.prepareGeometryChange(self) #self.informViewBoundsChanged() def informViewBoundsChanged(self): """ Inform this item's container ViewBox that the bounds of this item have changed. This is used by ViewBox to react if auto-range is enabled. """ view = self.getViewBox() if view is not None and hasattr(view, 'implements') and view.implements('ViewBox'): view.itemBoundsChanged(self) ## inform view so it can update its range if it wants def childrenShape(self): """Return the union of the shapes of all descendants of this item in local coordinates.""" childs = self.allChildItems() shapes = [self.mapFromItem(c, c.shape()) for c in self.allChildItems()] return reduce(operator.add, shapes) def allChildItems(self, root=None): """Return list of the entire item tree descending from this item.""" if root is None: root = self tree = [] for ch in root.childItems(): tree.append(ch) tree.extend(self.allChildItems(ch)) return tree def setExportMode(self, export, opts=None): """ This method is called by exporters to inform items that they are being drawn for export with a specific set of options. Items access these via self._exportOptions. When exporting is complete, _exportOptions is set to False. """ if opts is None: opts = {} if export: self._exportOpts = opts #if 'antialias' not in opts: #self._exportOpts['antialias'] = True else: self._exportOpts = False #def update(self): #self._qtBaseClass.update(self) #print "Update:", self def getContextMenus(self, event): return [self.getMenu()] if hasattr(self, "getMenu") else [] pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/GraphicsLayout.py000066400000000000000000000145371300727121400257640ustar00rootroot00000000000000from ..Qt import QtGui, QtCore from .. import functions as fn from .GraphicsWidget import GraphicsWidget ## Must be imported at the end to avoid cyclic-dependency hell: from .ViewBox import ViewBox from .PlotItem import PlotItem from .LabelItem import LabelItem __all__ = ['GraphicsLayout'] class GraphicsLayout(GraphicsWidget): """ Used for laying out GraphicsWidgets in a grid. This is usually created automatically as part of a :class:`GraphicsWindow ` or :class:`GraphicsLayoutWidget `. """ def __init__(self, parent=None, border=None): GraphicsWidget.__init__(self, parent) if border is True: border = (100,100,100) self.border = border self.layout = QtGui.QGraphicsGridLayout() self.setLayout(self.layout) self.items = {} ## item: [(row, col), (row, col), ...] lists all cells occupied by the item self.rows = {} ## row: {col1: item1, col2: item2, ...} maps cell location to item self.currentRow = 0 self.currentCol = 0 self.setSizePolicy(QtGui.QSizePolicy(QtGui.QSizePolicy.Expanding, QtGui.QSizePolicy.Expanding)) #def resizeEvent(self, ev): #ret = GraphicsWidget.resizeEvent(self, ev) #print self.pos(), self.mapToDevice(self.rect().topLeft()) #return ret def setBorder(self, *args, **kwds): """ Set the pen used to draw border between cells. See :func:`mkPen ` for arguments. """ self.border = fn.mkPen(*args, **kwds) self.update() def nextRow(self): """Advance to next row for automatic item placement""" self.currentRow += 1 self.currentCol = -1 self.nextColumn() def nextColumn(self): """Advance to next available column (generally only for internal use--called by addItem)""" self.currentCol += 1 while self.getItem(self.currentRow, self.currentCol) is not None: self.currentCol += 1 def nextCol(self, *args, **kargs): """Alias of nextColumn""" return self.nextColumn(*args, **kargs) def addPlot(self, row=None, col=None, rowspan=1, colspan=1, **kargs): """ Create a PlotItem and place it in the next available cell (or in the cell specified) All extra keyword arguments are passed to :func:`PlotItem.__init__ ` Returns the created item. """ plot = PlotItem(**kargs) self.addItem(plot, row, col, rowspan, colspan) return plot def addViewBox(self, row=None, col=None, rowspan=1, colspan=1, **kargs): """ Create a ViewBox and place it in the next available cell (or in the cell specified) All extra keyword arguments are passed to :func:`ViewBox.__init__ ` Returns the created item. """ vb = ViewBox(**kargs) self.addItem(vb, row, col, rowspan, colspan) return vb def addLabel(self, text=' ', row=None, col=None, rowspan=1, colspan=1, **kargs): """ Create a LabelItem with *text* and place it in the next available cell (or in the cell specified) All extra keyword arguments are passed to :func:`LabelItem.__init__ ` Returns the created item. To create a vertical label, use *angle* = -90. """ text = LabelItem(text, **kargs) self.addItem(text, row, col, rowspan, colspan) return text def addLayout(self, row=None, col=None, rowspan=1, colspan=1, **kargs): """ Create an empty GraphicsLayout and place it in the next available cell (or in the cell specified) All extra keyword arguments are passed to :func:`GraphicsLayout.__init__ ` Returns the created item. """ layout = GraphicsLayout(**kargs) self.addItem(layout, row, col, rowspan, colspan) return layout def addItem(self, item, row=None, col=None, rowspan=1, colspan=1): """ Add an item to the layout and place it in the next available cell (or in the cell specified). The item must be an instance of a QGraphicsWidget subclass. """ if row is None: row = self.currentRow if col is None: col = self.currentCol self.items[item] = [] for i in range(rowspan): for j in range(colspan): row2 = row + i col2 = col + j if row2 not in self.rows: self.rows[row2] = {} self.rows[row2][col2] = item self.items[item].append((row2, col2)) self.layout.addItem(item, row, col, rowspan, colspan) self.nextColumn() def getItem(self, row, col): """Return the item in (*row*, *col*). If the cell is empty, return None.""" return self.rows.get(row, {}).get(col, None) def boundingRect(self): return self.rect() def paint(self, p, *args): if self.border is None: return p.setPen(fn.mkPen(self.border)) for i in self.items: r = i.mapRectToParent(i.boundingRect()) p.drawRect(r) def itemIndex(self, item): for i in range(self.layout.count()): if self.layout.itemAt(i).graphicsItem() is item: return i raise Exception("Could not determine index of item " + str(item)) def removeItem(self, item): """Remove *item* from the layout.""" ind = self.itemIndex(item) self.layout.removeAt(ind) self.scene().removeItem(item) for r,c in self.items[item]: del self.rows[r][c] del self.items[item] self.update() def clear(self): items = [] for i in list(self.items.keys()): self.removeItem(i) def setContentsMargins(self, *args): # Wrap calls to layout. This should happen automatically, but there # seems to be a Qt bug: # http://stackoverflow.com/questions/27092164/margins-in-pyqtgraphs-graphicslayout self.layout.setContentsMargins(*args) def setSpacing(self, *args): self.layout.setSpacing(*args) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/GraphicsObject.py000066400000000000000000000032701300727121400257050ustar00rootroot00000000000000from ..Qt import QtGui, QtCore, USE_PYSIDE if not USE_PYSIDE: import sip from .GraphicsItem import GraphicsItem __all__ = ['GraphicsObject'] class GraphicsObject(GraphicsItem, QtGui.QGraphicsObject): """ **Bases:** :class:`GraphicsItem `, :class:`QtGui.QGraphicsObject` Extension of QGraphicsObject with some useful methods (provided by :class:`GraphicsItem `) """ _qtBaseClass = QtGui.QGraphicsObject def __init__(self, *args): self.__inform_view_on_changes = True QtGui.QGraphicsObject.__init__(self, *args) self.setFlag(self.ItemSendsGeometryChanges) GraphicsItem.__init__(self) def itemChange(self, change, value): ret = QtGui.QGraphicsObject.itemChange(self, change, value) if change in [self.ItemParentHasChanged, self.ItemSceneHasChanged]: self.parentChanged() try: inform_view_on_change = self.__inform_view_on_changes except AttributeError: # It's possible that the attribute was already collected when the itemChange happened # (if it was triggered during the gc of the object). pass else: if inform_view_on_change and change in [self.ItemPositionHasChanged, self.ItemTransformHasChanged]: self.informViewBoundsChanged() ## workaround for pyqt bug: ## http://www.riverbankcomputing.com/pipermail/pyqt/2012-August/031818.html if not USE_PYSIDE and change == self.ItemParentChange and isinstance(ret, QtGui.QGraphicsItem): ret = sip.cast(ret, QtGui.QGraphicsItem) return ret pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/GraphicsWidget.py000066400000000000000000000041471300727121400257260ustar00rootroot00000000000000from ..Qt import QtGui, QtCore from ..GraphicsScene import GraphicsScene from .GraphicsItem import GraphicsItem __all__ = ['GraphicsWidget'] class GraphicsWidget(GraphicsItem, QtGui.QGraphicsWidget): _qtBaseClass = QtGui.QGraphicsWidget def __init__(self, *args, **kargs): """ **Bases:** :class:`GraphicsItem `, :class:`QtGui.QGraphicsWidget` Extends QGraphicsWidget with several helpful methods and workarounds for PyQt bugs. Most of the extra functionality is inherited from :class:`GraphicsItem `. """ QtGui.QGraphicsWidget.__init__(self, *args, **kargs) GraphicsItem.__init__(self) ## done by GraphicsItem init #GraphicsScene.registerObject(self) ## workaround for pyqt bug in graphicsscene.items() # Removed due to https://bugreports.qt-project.org/browse/PYSIDE-86 #def itemChange(self, change, value): ## BEWARE: Calling QGraphicsWidget.itemChange can lead to crashing! ##ret = QtGui.QGraphicsWidget.itemChange(self, change, value) ## segv occurs here ## The default behavior is just to return the value argument, so we'll do that ## without calling the original method. #ret = value #if change in [self.ItemParentHasChanged, self.ItemSceneHasChanged]: #self._updateView() #return ret def setFixedHeight(self, h): self.setMaximumHeight(h) self.setMinimumHeight(h) def setFixedWidth(self, h): self.setMaximumWidth(h) self.setMinimumWidth(h) def height(self): return self.geometry().height() def width(self): return self.geometry().width() def boundingRect(self): br = self.mapRectFromParent(self.geometry()).normalized() #print "bounds:", br return br def shape(self): ## No idea why this is necessary, but rotated items do not receive clicks otherwise. p = QtGui.QPainterPath() p.addRect(self.boundingRect()) #print "shape:", p.boundingRect() return p pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/GraphicsWidgetAnchor.py000066400000000000000000000077601300727121400270650ustar00rootroot00000000000000from ..Qt import QtGui, QtCore from ..Point import Point class GraphicsWidgetAnchor(object): """ Class used to allow GraphicsWidgets to anchor to a specific position on their parent. The item will be automatically repositioned if the parent is resized. This is used, for example, to anchor a LegendItem to a corner of its parent PlotItem. """ def __init__(self): self.__parent = None self.__parentAnchor = None self.__itemAnchor = None self.__offset = (0,0) if hasattr(self, 'geometryChanged'): self.geometryChanged.connect(self.__geometryChanged) def anchor(self, itemPos, parentPos, offset=(0,0)): """ Anchors the item at its local itemPos to the item's parent at parentPos. Both positions are expressed in values relative to the size of the item or parent; a value of 0 indicates left or top edge, while 1 indicates right or bottom edge. Optionally, offset may be specified to introduce an absolute offset. Example: anchor a box such that its upper-right corner is fixed 10px left and 10px down from its parent's upper-right corner:: box.anchor(itemPos=(1,0), parentPos=(1,0), offset=(-10,10)) """ parent = self.parentItem() if parent is None: raise Exception("Cannot anchor; parent is not set.") if self.__parent is not parent: if self.__parent is not None: self.__parent.geometryChanged.disconnect(self.__geometryChanged) self.__parent = parent parent.geometryChanged.connect(self.__geometryChanged) self.__itemAnchor = itemPos self.__parentAnchor = parentPos self.__offset = offset self.__geometryChanged() def autoAnchor(self, pos, relative=True): """ Set the position of this item relative to its parent by automatically choosing appropriate anchor settings. If relative is True, one corner of the item will be anchored to the appropriate location on the parent with no offset. The anchored corner will be whichever is closest to the parent's boundary. If relative is False, one corner of the item will be anchored to the same corner of the parent, with an absolute offset to achieve the correct position. """ pos = Point(pos) br = self.mapRectToParent(self.boundingRect()).translated(pos - self.pos()) pbr = self.parentItem().boundingRect() anchorPos = [0,0] parentPos = Point() itemPos = Point() if abs(br.left() - pbr.left()) < abs(br.right() - pbr.right()): anchorPos[0] = 0 parentPos[0] = pbr.left() itemPos[0] = br.left() else: anchorPos[0] = 1 parentPos[0] = pbr.right() itemPos[0] = br.right() if abs(br.top() - pbr.top()) < abs(br.bottom() - pbr.bottom()): anchorPos[1] = 0 parentPos[1] = pbr.top() itemPos[1] = br.top() else: anchorPos[1] = 1 parentPos[1] = pbr.bottom() itemPos[1] = br.bottom() if relative: relPos = [(itemPos[0]-pbr.left()) / pbr.width(), (itemPos[1]-pbr.top()) / pbr.height()] self.anchor(anchorPos, relPos) else: offset = itemPos - parentPos self.anchor(anchorPos, anchorPos, offset) def __geometryChanged(self): if self.__parent is None: return if self.__itemAnchor is None: return o = self.mapToParent(Point(0,0)) a = self.boundingRect().bottomRight() * Point(self.__itemAnchor) a = self.mapToParent(a) p = self.__parent.boundingRect().bottomRight() * Point(self.__parentAnchor) off = Point(self.__offset) pos = p + (o-a) + off self.setPos(pos) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/GridItem.py000066400000000000000000000107061300727121400245240ustar00rootroot00000000000000from ..Qt import QtGui, QtCore from .UIGraphicsItem import * import numpy as np from ..Point import Point from .. import functions as fn __all__ = ['GridItem'] class GridItem(UIGraphicsItem): """ **Bases:** :class:`UIGraphicsItem ` Displays a rectangular grid of lines indicating major divisions within a coordinate system. Automatically determines what divisions to use. """ def __init__(self): UIGraphicsItem.__init__(self) #QtGui.QGraphicsItem.__init__(self, *args) #self.setFlag(QtGui.QGraphicsItem.ItemClipsToShape) #self.setCacheMode(QtGui.QGraphicsItem.DeviceCoordinateCache) self.picture = None def viewRangeChanged(self): UIGraphicsItem.viewRangeChanged(self) self.picture = None #UIGraphicsItem.viewRangeChanged(self) #self.update() def paint(self, p, opt, widget): #p.setPen(QtGui.QPen(QtGui.QColor(100, 100, 100))) #p.drawRect(self.boundingRect()) #UIGraphicsItem.paint(self, p, opt, widget) ### draw picture if self.picture is None: #print "no pic, draw.." self.generatePicture() p.drawPicture(QtCore.QPointF(0, 0), self.picture) #p.setPen(QtGui.QPen(QtGui.QColor(255,0,0))) #p.drawLine(0, -100, 0, 100) #p.drawLine(-100, 0, 100, 0) #print "drawing Grid." def generatePicture(self): self.picture = QtGui.QPicture() p = QtGui.QPainter() p.begin(self.picture) dt = fn.invertQTransform(self.viewTransform()) vr = self.getViewWidget().rect() unit = self.pixelWidth(), self.pixelHeight() dim = [vr.width(), vr.height()] lvr = self.boundingRect() ul = np.array([lvr.left(), lvr.top()]) br = np.array([lvr.right(), lvr.bottom()]) texts = [] if ul[1] > br[1]: x = ul[1] ul[1] = br[1] br[1] = x for i in [2,1,0]: ## Draw three different scales of grid dist = br-ul nlTarget = 10.**i d = 10. ** np.floor(np.log10(abs(dist/nlTarget))+0.5) ul1 = np.floor(ul / d) * d br1 = np.ceil(br / d) * d dist = br1-ul1 nl = (dist / d) + 0.5 #print "level", i #print " dim", dim #print " dist", dist #print " d", d #print " nl", nl for ax in range(0,2): ## Draw grid for both axes ppl = dim[ax] / nl[ax] c = np.clip(3.*(ppl-3), 0., 30.) linePen = QtGui.QPen(QtGui.QColor(255, 255, 255, c)) textPen = QtGui.QPen(QtGui.QColor(255, 255, 255, c*2)) #linePen.setCosmetic(True) #linePen.setWidth(1) bx = (ax+1) % 2 for x in range(0, int(nl[ax])): linePen.setCosmetic(False) if ax == 0: linePen.setWidthF(self.pixelWidth()) #print "ax 0 height", self.pixelHeight() else: linePen.setWidthF(self.pixelHeight()) #print "ax 1 width", self.pixelWidth() p.setPen(linePen) p1 = np.array([0.,0.]) p2 = np.array([0.,0.]) p1[ax] = ul1[ax] + x * d[ax] p2[ax] = p1[ax] p1[bx] = ul[bx] p2[bx] = br[bx] ## don't draw lines that are out of bounds. if p1[ax] < min(ul[ax], br[ax]) or p1[ax] > max(ul[ax], br[ax]): continue p.drawLine(QtCore.QPointF(p1[0], p1[1]), QtCore.QPointF(p2[0], p2[1])) if i < 2: p.setPen(textPen) if ax == 0: x = p1[0] + unit[0] y = ul[1] + unit[1] * 8. else: x = ul[0] + unit[0]*3 y = p1[1] + unit[1] texts.append((QtCore.QPointF(x, y), "%g"%p1[ax])) tr = self.deviceTransform() #tr.scale(1.5, 1.5) p.setWorldTransform(fn.invertQTransform(tr)) for t in texts: x = tr.map(t[0]) + Point(0.5, 0.5) p.drawText(x, t[1]) p.end() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/HistogramLUTItem.py000066400000000000000000000172631300727121400261660ustar00rootroot00000000000000""" GraphicsWidget displaying an image histogram along with gradient editor. Can be used to adjust the appearance of images. """ from ..Qt import QtGui, QtCore from .. import functions as fn from .GraphicsWidget import GraphicsWidget from .ViewBox import * from .GradientEditorItem import * from .LinearRegionItem import * from .PlotDataItem import * from .AxisItem import * from .GridItem import * from ..Point import Point from .. import functions as fn import numpy as np from .. import debug as debug import weakref __all__ = ['HistogramLUTItem'] class HistogramLUTItem(GraphicsWidget): """ This is a graphicsWidget which provides controls for adjusting the display of an image. Includes: - Image histogram - Movable region over histogram to select black/white levels - Gradient editor to define color lookup table for single-channel images """ sigLookupTableChanged = QtCore.Signal(object) sigLevelsChanged = QtCore.Signal(object) sigLevelChangeFinished = QtCore.Signal(object) def __init__(self, image=None, fillHistogram=True): """ If *image* (ImageItem) is provided, then the control will be automatically linked to the image and changes to the control will be immediately reflected in the image's appearance. By default, the histogram is rendered with a fill. For performance, set *fillHistogram* = False. """ GraphicsWidget.__init__(self) self.lut = None self.imageItem = lambda: None # fake a dead weakref self.layout = QtGui.QGraphicsGridLayout() self.setLayout(self.layout) self.layout.setContentsMargins(1,1,1,1) self.layout.setSpacing(0) self.vb = ViewBox(parent=self) self.vb.setMaximumWidth(152) self.vb.setMinimumWidth(45) self.vb.setMouseEnabled(x=False, y=True) self.gradient = GradientEditorItem() self.gradient.setOrientation('right') self.gradient.loadPreset('grey') self.region = LinearRegionItem([0, 1], LinearRegionItem.Horizontal) self.region.setZValue(1000) self.vb.addItem(self.region) self.axis = AxisItem('left', linkView=self.vb, maxTickLength=-10, parent=self) self.layout.addItem(self.axis, 0, 0) self.layout.addItem(self.vb, 0, 1) self.layout.addItem(self.gradient, 0, 2) self.range = None self.gradient.setFlag(self.gradient.ItemStacksBehindParent) self.vb.setFlag(self.gradient.ItemStacksBehindParent) #self.grid = GridItem() #self.vb.addItem(self.grid) self.gradient.sigGradientChanged.connect(self.gradientChanged) self.region.sigRegionChanged.connect(self.regionChanging) self.region.sigRegionChangeFinished.connect(self.regionChanged) self.vb.sigRangeChanged.connect(self.viewRangeChanged) self.plot = PlotDataItem() self.plot.rotate(90) self.fillHistogram(fillHistogram) self.vb.addItem(self.plot) self.autoHistogramRange() if image is not None: self.setImageItem(image) #self.setSizePolicy(QtGui.QSizePolicy.Preferred, QtGui.QSizePolicy.Expanding) def fillHistogram(self, fill=True, level=0.0, color=(100, 100, 200)): if fill: self.plot.setFillLevel(level) self.plot.setFillBrush(color) else: self.plot.setFillLevel(None) #def sizeHint(self, *args): #return QtCore.QSizeF(115, 200) def paint(self, p, *args): pen = self.region.lines[0].pen rgn = self.getLevels() p1 = self.vb.mapFromViewToItem(self, Point(self.vb.viewRect().center().x(), rgn[0])) p2 = self.vb.mapFromViewToItem(self, Point(self.vb.viewRect().center().x(), rgn[1])) gradRect = self.gradient.mapRectToParent(self.gradient.gradRect.rect()) for pen in [fn.mkPen('k', width=3), pen]: p.setPen(pen) p.drawLine(p1, gradRect.bottomLeft()) p.drawLine(p2, gradRect.topLeft()) p.drawLine(gradRect.topLeft(), gradRect.topRight()) p.drawLine(gradRect.bottomLeft(), gradRect.bottomRight()) #p.drawRect(self.boundingRect()) def setHistogramRange(self, mn, mx, padding=0.1): """Set the Y range on the histogram plot. This disables auto-scaling.""" self.vb.enableAutoRange(self.vb.YAxis, False) self.vb.setYRange(mn, mx, padding) #d = mx-mn #mn -= d*padding #mx += d*padding #self.range = [mn,mx] #self.updateRange() #self.vb.setMouseEnabled(False, True) #self.region.setBounds([mn,mx]) def autoHistogramRange(self): """Enable auto-scaling on the histogram plot.""" self.vb.enableAutoRange(self.vb.XYAxes) #self.range = None #self.updateRange() #self.vb.setMouseEnabled(False, False) #def updateRange(self): #self.vb.autoRange() #if self.range is not None: #self.vb.setYRange(*self.range) #vr = self.vb.viewRect() #self.region.setBounds([vr.top(), vr.bottom()]) def setImageItem(self, img): """Set an ImageItem to have its levels and LUT automatically controlled by this HistogramLUTItem. """ self.imageItem = weakref.ref(img) img.sigImageChanged.connect(self.imageChanged) img.setLookupTable(self.getLookupTable) ## send function pointer, not the result #self.gradientChanged() self.regionChanged() self.imageChanged(autoLevel=True) #self.vb.autoRange() def viewRangeChanged(self): self.update() def gradientChanged(self): if self.imageItem() is not None: if self.gradient.isLookupTrivial(): self.imageItem().setLookupTable(None) #lambda x: x.astype(np.uint8)) else: self.imageItem().setLookupTable(self.getLookupTable) ## send function pointer, not the result self.lut = None #if self.imageItem is not None: #self.imageItem.setLookupTable(self.gradient.getLookupTable(512)) self.sigLookupTableChanged.emit(self) def getLookupTable(self, img=None, n=None, alpha=None): """Return a lookup table from the color gradient defined by this HistogramLUTItem. """ if n is None: if img.dtype == np.uint8: n = 256 else: n = 512 if self.lut is None: self.lut = self.gradient.getLookupTable(n, alpha=alpha) return self.lut def regionChanged(self): if self.imageItem() is not None: self.imageItem().setLevels(self.region.getRegion()) self.sigLevelChangeFinished.emit(self) #self.update() def regionChanging(self): if self.imageItem() is not None: self.imageItem().setLevels(self.region.getRegion()) self.sigLevelsChanged.emit(self) self.update() def imageChanged(self, autoLevel=False, autoRange=False): profiler = debug.Profiler() h = self.imageItem().getHistogram() profiler('get histogram') if h[0] is None: return self.plot.setData(*h) profiler('set plot') if autoLevel: mn = h[0][0] mx = h[0][-1] self.region.setRegion([mn, mx]) profiler('set region') def getLevels(self): """Return the min and max levels. """ return self.region.getRegion() def setLevels(self, mn, mx): """Set the min and max levels. """ self.region.setRegion([mn, mx]) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/ImageItem.py000066400000000000000000000565431300727121400246720ustar00rootroot00000000000000from __future__ import division from ..Qt import QtGui, QtCore import numpy as np import collections from .. import functions as fn from .. import debug as debug from .GraphicsObject import GraphicsObject from ..Point import Point from .. import getConfigOption __all__ = ['ImageItem'] class ImageItem(GraphicsObject): """ **Bases:** :class:`GraphicsObject ` GraphicsObject displaying an image. Optimized for rapid update (ie video display). This item displays either a 2D numpy array (height, width) or a 3D array (height, width, RGBa). This array is optionally scaled (see :func:`setLevels `) and/or colored with a lookup table (see :func:`setLookupTable `) before being displayed. ImageItem is frequently used in conjunction with :class:`HistogramLUTItem ` or :class:`HistogramLUTWidget ` to provide a GUI for controlling the levels and lookup table used to display the image. """ sigImageChanged = QtCore.Signal() sigRemoveRequested = QtCore.Signal(object) # self; emitted when 'remove' is selected from context menu def __init__(self, image=None, **kargs): """ See :func:`setImage ` for all allowed initialization arguments. """ GraphicsObject.__init__(self) self.menu = None self.image = None ## original image data self.qimage = None ## rendered image for display self.paintMode = None self.levels = None ## [min, max] or [[redMin, redMax], ...] self.lut = None self.autoDownsample = False self.axisOrder = getConfigOption('imageAxisOrder') # In some cases, we use a modified lookup table to handle both rescaling # and LUT more efficiently self._effectiveLut = None self.drawKernel = None self.border = None self.removable = False if image is not None: self.setImage(image, **kargs) else: self.setOpts(**kargs) def setCompositionMode(self, mode): """Change the composition mode of the item (see QPainter::CompositionMode in the Qt documentation). This is useful when overlaying multiple ImageItems. ============================================ ============================================================ **Most common arguments:** QtGui.QPainter.CompositionMode_SourceOver Default; image replaces the background if it is opaque. Otherwise, it uses the alpha channel to blend the image with the background. QtGui.QPainter.CompositionMode_Overlay The image color is mixed with the background color to reflect the lightness or darkness of the background. QtGui.QPainter.CompositionMode_Plus Both the alpha and color of the image and background pixels are added together. QtGui.QPainter.CompositionMode_Multiply The output is the image color multiplied by the background. ============================================ ============================================================ """ self.paintMode = mode self.update() def setBorder(self, b): self.border = fn.mkPen(b) self.update() def width(self): if self.image is None: return None axis = 0 if self.axisOrder == 'col-major' else 1 return self.image.shape[axis] def height(self): if self.image is None: return None axis = 1 if self.axisOrder == 'col-major' else 0 return self.image.shape[axis] def boundingRect(self): if self.image is None: return QtCore.QRectF(0., 0., 0., 0.) return QtCore.QRectF(0., 0., float(self.width()), float(self.height())) def setLevels(self, levels, update=True): """ Set image scaling levels. Can be one of: * [blackLevel, whiteLevel] * [[minRed, maxRed], [minGreen, maxGreen], [minBlue, maxBlue]] Only the first format is compatible with lookup tables. See :func:`makeARGB ` for more details on how levels are applied. """ if levels is not None: levels = np.asarray(levels) if not fn.eq(levels, self.levels): self.levels = levels self._effectiveLut = None if update: self.updateImage() def getLevels(self): return self.levels #return self.whiteLevel, self.blackLevel def setLookupTable(self, lut, update=True): """ Set the lookup table (numpy array) to use for this image. (see :func:`makeARGB ` for more information on how this is used). Optionally, lut can be a callable that accepts the current image as an argument and returns the lookup table to use. Ordinarily, this table is supplied by a :class:`HistogramLUTItem ` or :class:`GradientEditorItem `. """ if lut is not self.lut: self.lut = lut self._effectiveLut = None if update: self.updateImage() def setAutoDownsample(self, ads): """ Set the automatic downsampling mode for this ImageItem. Added in version 0.9.9 """ self.autoDownsample = ads self.qimage = None self.update() def setOpts(self, update=True, **kargs): if 'axisOrder' in kargs: val = kargs['axisOrder'] if val not in ('row-major', 'col-major'): raise ValueError('axisOrder must be either "row-major" or "col-major"') self.axisOrder = val if 'lut' in kargs: self.setLookupTable(kargs['lut'], update=update) if 'levels' in kargs: self.setLevels(kargs['levels'], update=update) #if 'clipLevel' in kargs: #self.setClipLevel(kargs['clipLevel']) if 'opacity' in kargs: self.setOpacity(kargs['opacity']) if 'compositionMode' in kargs: self.setCompositionMode(kargs['compositionMode']) if 'border' in kargs: self.setBorder(kargs['border']) if 'removable' in kargs: self.removable = kargs['removable'] self.menu = None if 'autoDownsample' in kargs: self.setAutoDownsample(kargs['autoDownsample']) if update: self.update() def setRect(self, rect): """Scale and translate the image to fit within rect (must be a QRect or QRectF).""" self.resetTransform() self.translate(rect.left(), rect.top()) self.scale(rect.width() / self.width(), rect.height() / self.height()) def clear(self): self.image = None self.prepareGeometryChange() self.informViewBoundsChanged() self.update() def setImage(self, image=None, autoLevels=None, **kargs): """ Update the image displayed by this item. For more information on how the image is processed before displaying, see :func:`makeARGB ` ================= ========================================================================= **Arguments:** image (numpy array) Specifies the image data. May be 2D (width, height) or 3D (width, height, RGBa). The array dtype must be integer or floating point of any bit depth. For 3D arrays, the third dimension must be of length 3 (RGB) or 4 (RGBA). See *notes* below. autoLevels (bool) If True, this forces the image to automatically select levels based on the maximum and minimum values in the data. By default, this argument is true unless the levels argument is given. lut (numpy array) The color lookup table to use when displaying the image. See :func:`setLookupTable `. levels (min, max) The minimum and maximum values to use when rescaling the image data. By default, this will be set to the minimum and maximum values in the image. If the image array has dtype uint8, no rescaling is necessary. opacity (float 0.0-1.0) compositionMode See :func:`setCompositionMode ` border Sets the pen used when drawing the image border. Default is None. autoDownsample (bool) If True, the image is automatically downsampled to match the screen resolution. This improves performance for large images and reduces aliasing. ================= ========================================================================= **Notes:** For backward compatibility, image data is assumed to be in column-major order (column, row). However, most image data is stored in row-major order (row, column) and will need to be transposed before calling setImage():: imageitem.setImage(imagedata.T) This requirement can be changed by calling ``image.setOpts(axisOrder='row-major')`` or by changing the ``imageAxisOrder`` :ref:`global configuration option `. """ profile = debug.Profiler() gotNewData = False if image is None: if self.image is None: return else: gotNewData = True shapeChanged = (self.image is None or image.shape != self.image.shape) image = image.view(np.ndarray) if self.image is None or image.dtype != self.image.dtype: self._effectiveLut = None self.image = image if self.image.shape[0] > 2**15-1 or self.image.shape[1] > 2**15-1: if 'autoDownsample' not in kargs: kargs['autoDownsample'] = True if shapeChanged: self.prepareGeometryChange() self.informViewBoundsChanged() profile() if autoLevels is None: if 'levels' in kargs: autoLevels = False else: autoLevels = True if autoLevels: img = self.image while img.size > 2**16: img = img[::2, ::2] mn, mx = img.min(), img.max() if mn == mx: mn = 0 mx = 255 kargs['levels'] = [mn,mx] profile() self.setOpts(update=False, **kargs) profile() self.qimage = None self.update() profile() if gotNewData: self.sigImageChanged.emit() def dataTransform(self): """Return the transform that maps from this image's input array to its local coordinate system. This transform corrects for the transposition that occurs when image data is interpreted in row-major order. """ # Might eventually need to account for downsampling / clipping here tr = QtGui.QTransform() if self.axisOrder == 'row-major': # transpose tr.scale(1, -1) tr.rotate(-90) return tr def inverseDataTransform(self): """Return the transform that maps from this image's local coordinate system to its input array. See dataTransform() for more information. """ tr = QtGui.QTransform() if self.axisOrder == 'row-major': # transpose tr.scale(1, -1) tr.rotate(-90) return tr def mapToData(self, obj): tr = self.inverseDataTransform() return tr.map(obj) def mapFromData(self, obj): tr = self.dataTransform() return tr.map(obj) def quickMinMax(self, targetSize=1e6): """ Estimate the min/max values of the image data by subsampling. """ data = self.image while data.size > targetSize: ax = np.argmax(data.shape) sl = [slice(None)] * data.ndim sl[ax] = slice(None, None, 2) data = data[sl] return nanmin(data), nanmax(data) def updateImage(self, *args, **kargs): ## used for re-rendering qimage from self.image. ## can we make any assumptions here that speed things up? ## dtype, range, size are all the same? defaults = { 'autoLevels': False, } defaults.update(kargs) return self.setImage(*args, **defaults) def render(self): # Convert data to QImage for display. profile = debug.Profiler() if self.image is None or self.image.size == 0: return if isinstance(self.lut, collections.Callable): lut = self.lut(self.image) else: lut = self.lut if self.autoDownsample: # reduce dimensions of image based on screen resolution o = self.mapToDevice(QtCore.QPointF(0,0)) x = self.mapToDevice(QtCore.QPointF(1,0)) y = self.mapToDevice(QtCore.QPointF(0,1)) w = Point(x-o).length() h = Point(y-o).length() if w == 0 or h == 0: self.qimage = None return xds = max(1, int(1.0 / w)) yds = max(1, int(1.0 / h)) axes = [1, 0] if self.axisOrder == 'row-major' else [0, 1] image = fn.downsample(self.image, xds, axis=axes[0]) image = fn.downsample(image, yds, axis=axes[1]) self._lastDownsample = (xds, yds) else: image = self.image # if the image data is a small int, then we can combine levels + lut # into a single lut for better performance levels = self.levels if levels is not None and levels.ndim == 1 and image.dtype in (np.ubyte, np.uint16): if self._effectiveLut is None: eflsize = 2**(image.itemsize*8) ind = np.arange(eflsize) minlev, maxlev = levels levdiff = maxlev - minlev levdiff = 1 if levdiff == 0 else levdiff # don't allow division by 0 if lut is None: efflut = fn.rescaleData(ind, scale=255./levdiff, offset=minlev, dtype=np.ubyte) else: lutdtype = np.min_scalar_type(lut.shape[0]-1) efflut = fn.rescaleData(ind, scale=(lut.shape[0]-1)/levdiff, offset=minlev, dtype=lutdtype, clip=(0, lut.shape[0]-1)) efflut = lut[efflut] self._effectiveLut = efflut lut = self._effectiveLut levels = None # Assume images are in column-major order for backward compatibility # (most images are in row-major order) if self.axisOrder == 'col-major': image = image.transpose((1, 0, 2)[:image.ndim]) argb, alpha = fn.makeARGB(image, lut=lut, levels=levels) self.qimage = fn.makeQImage(argb, alpha, transpose=False) def paint(self, p, *args): profile = debug.Profiler() if self.image is None: return if self.qimage is None: self.render() if self.qimage is None: return profile('render QImage') if self.paintMode is not None: p.setCompositionMode(self.paintMode) profile('set comp mode') shape = self.image.shape[:2] if self.axisOrder == 'col-major' else self.image.shape[:2][::-1] p.drawImage(QtCore.QRectF(0,0,*shape), self.qimage) profile('p.drawImage') if self.border is not None: p.setPen(self.border) p.drawRect(self.boundingRect()) def save(self, fileName, *args): """Save this image to file. Note that this saves the visible image (after scale/color changes), not the original data.""" if self.qimage is None: self.render() self.qimage.save(fileName, *args) def getHistogram(self, bins='auto', step='auto', targetImageSize=200, targetHistogramSize=500, **kwds): """Returns x and y arrays containing the histogram values for the current image. For an explanation of the return format, see numpy.histogram(). The *step* argument causes pixels to be skipped when computing the histogram to save time. If *step* is 'auto', then a step is chosen such that the analyzed data has dimensions roughly *targetImageSize* for each axis. The *bins* argument and any extra keyword arguments are passed to np.histogram(). If *bins* is 'auto', then a bin number is automatically chosen based on the image characteristics: * Integer images will have approximately *targetHistogramSize* bins, with each bin having an integer width. * All other types will have *targetHistogramSize* bins. This method is also used when automatically computing levels. """ if self.image is None: return None,None if step == 'auto': step = (int(np.ceil(self.image.shape[0] / targetImageSize)), int(np.ceil(self.image.shape[1] / targetImageSize))) if np.isscalar(step): step = (step, step) stepData = self.image[::step[0], ::step[1]] if bins == 'auto': if stepData.dtype.kind in "ui": mn = stepData.min() mx = stepData.max() step = np.ceil((mx-mn) / 500.) bins = np.arange(mn, mx+1.01*step, step, dtype=np.int) if len(bins) == 0: bins = [mn, mx] else: bins = 500 kwds['bins'] = bins stepData = stepData[np.isfinite(stepData)] hist = np.histogram(stepData, **kwds) return hist[1][:-1], hist[0] def setPxMode(self, b): """ Set whether the item ignores transformations and draws directly to screen pixels. If True, the item will not inherit any scale or rotation transformations from its parent items, but its position will be transformed as usual. (see GraphicsItem::ItemIgnoresTransformations in the Qt documentation) """ self.setFlag(self.ItemIgnoresTransformations, b) def setScaledMode(self): self.setPxMode(False) def getPixmap(self): if self.qimage is None: self.render() if self.qimage is None: return None return QtGui.QPixmap.fromImage(self.qimage) def pixelSize(self): """return scene-size of a single pixel in the image""" br = self.sceneBoundingRect() if self.image is None: return 1,1 return br.width()/self.width(), br.height()/self.height() def viewTransformChanged(self): if self.autoDownsample: self.qimage = None self.update() def mouseDragEvent(self, ev): if ev.button() != QtCore.Qt.LeftButton: ev.ignore() return elif self.drawKernel is not None: ev.accept() self.drawAt(ev.pos(), ev) def mouseClickEvent(self, ev): if ev.button() == QtCore.Qt.RightButton: if self.raiseContextMenu(ev): ev.accept() if self.drawKernel is not None and ev.button() == QtCore.Qt.LeftButton: self.drawAt(ev.pos(), ev) def raiseContextMenu(self, ev): menu = self.getMenu() if menu is None: return False menu = self.scene().addParentContextMenus(self, menu, ev) pos = ev.screenPos() menu.popup(QtCore.QPoint(pos.x(), pos.y())) return True def getMenu(self): if self.menu is None: if not self.removable: return None self.menu = QtGui.QMenu() self.menu.setTitle("Image") remAct = QtGui.QAction("Remove image", self.menu) remAct.triggered.connect(self.removeClicked) self.menu.addAction(remAct) self.menu.remAct = remAct return self.menu def hoverEvent(self, ev): if not ev.isExit() and self.drawKernel is not None and ev.acceptDrags(QtCore.Qt.LeftButton): ev.acceptClicks(QtCore.Qt.LeftButton) ## we don't use the click, but we also don't want anyone else to use it. ev.acceptClicks(QtCore.Qt.RightButton) elif not ev.isExit() and self.removable: ev.acceptClicks(QtCore.Qt.RightButton) ## accept context menu clicks def tabletEvent(self, ev): pass #print(ev.device()) #print(ev.pointerType()) #print(ev.pressure()) def drawAt(self, pos, ev=None): pos = [int(pos.x()), int(pos.y())] dk = self.drawKernel kc = self.drawKernelCenter sx = [0,dk.shape[0]] sy = [0,dk.shape[1]] tx = [pos[0] - kc[0], pos[0] - kc[0]+ dk.shape[0]] ty = [pos[1] - kc[1], pos[1] - kc[1]+ dk.shape[1]] for i in [0,1]: dx1 = -min(0, tx[i]) dx2 = min(0, self.image.shape[0]-tx[i]) tx[i] += dx1+dx2 sx[i] += dx1+dx2 dy1 = -min(0, ty[i]) dy2 = min(0, self.image.shape[1]-ty[i]) ty[i] += dy1+dy2 sy[i] += dy1+dy2 ts = (slice(tx[0],tx[1]), slice(ty[0],ty[1])) ss = (slice(sx[0],sx[1]), slice(sy[0],sy[1])) mask = self.drawMask src = dk if isinstance(self.drawMode, collections.Callable): self.drawMode(dk, self.image, mask, ss, ts, ev) else: src = src[ss] if self.drawMode == 'set': if mask is not None: mask = mask[ss] self.image[ts] = self.image[ts] * (1-mask) + src * mask else: self.image[ts] = src elif self.drawMode == 'add': self.image[ts] += src else: raise Exception("Unknown draw mode '%s'" % self.drawMode) self.updateImage() def setDrawKernel(self, kernel=None, mask=None, center=(0,0), mode='set'): self.drawKernel = kernel self.drawKernelCenter = center self.drawMode = mode self.drawMask = mask def removeClicked(self): ## Send remove event only after we have exited the menu event handler self.removeTimer = QtCore.QTimer() self.removeTimer.timeout.connect(self.emitRemoveRequested) self.removeTimer.start(0) def emitRemoveRequested(self): self.removeTimer.timeout.disconnect(self.emitRemoveRequested) self.sigRemoveRequested.emit(self) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/InfiniteLine.py000066400000000000000000000422631300727121400254000ustar00rootroot00000000000000from ..Qt import QtGui, QtCore from ..Point import Point from .GraphicsObject import GraphicsObject from .TextItem import TextItem from .ViewBox import ViewBox from .. import functions as fn import numpy as np import weakref __all__ = ['InfiniteLine', 'InfLineLabel'] class InfiniteLine(GraphicsObject): """ **Bases:** :class:`GraphicsObject ` Displays a line of infinite length. This line may be dragged to indicate a position in data coordinates. =============================== =================================================== **Signals:** sigDragged(self) sigPositionChangeFinished(self) sigPositionChanged(self) =============================== =================================================== """ sigDragged = QtCore.Signal(object) sigPositionChangeFinished = QtCore.Signal(object) sigPositionChanged = QtCore.Signal(object) def __init__(self, pos=None, angle=90, pen=None, movable=False, bounds=None, hoverPen=None, label=None, labelOpts=None, name=None): """ =============== ================================================================== **Arguments:** pos Position of the line. This can be a QPointF or a single value for vertical/horizontal lines. angle Angle of line in degrees. 0 is horizontal, 90 is vertical. pen Pen to use when drawing line. Can be any arguments that are valid for :func:`mkPen `. Default pen is transparent yellow. movable If True, the line can be dragged to a new position by the user. hoverPen Pen to use when drawing line when hovering over it. Can be any arguments that are valid for :func:`mkPen `. Default pen is red. bounds Optional [min, max] bounding values. Bounds are only valid if the line is vertical or horizontal. label Text to be displayed in a label attached to the line, or None to show no label (default is None). May optionally include formatting strings to display the line value. labelOpts A dict of keyword arguments to use when constructing the text label. See :class:`InfLineLabel`. name Name of the item =============== ================================================================== """ self._boundingRect = None self._line = None self._name = name GraphicsObject.__init__(self) if bounds is None: ## allowed value boundaries for orthogonal lines self.maxRange = [None, None] else: self.maxRange = bounds self.moving = False self.setMovable(movable) self.mouseHovering = False self.p = [0, 0] self.setAngle(angle) if pos is None: pos = Point(0,0) self.setPos(pos) if pen is None: pen = (200, 200, 100) self.setPen(pen) if hoverPen is None: self.setHoverPen(color=(255,0,0), width=self.pen.width()) else: self.setHoverPen(hoverPen) self.currentPen = self.pen if label is not None: labelOpts = {} if labelOpts is None else labelOpts self.label = InfLineLabel(self, text=label, **labelOpts) def setMovable(self, m): """Set whether the line is movable by the user.""" self.movable = m self.setAcceptHoverEvents(m) def setBounds(self, bounds): """Set the (minimum, maximum) allowable values when dragging.""" self.maxRange = bounds self.setValue(self.value()) def setPen(self, *args, **kwargs): """Set the pen for drawing the line. Allowable arguments are any that are valid for :func:`mkPen `.""" self.pen = fn.mkPen(*args, **kwargs) if not self.mouseHovering: self.currentPen = self.pen self.update() def setHoverPen(self, *args, **kwargs): """Set the pen for drawing the line while the mouse hovers over it. Allowable arguments are any that are valid for :func:`mkPen `. If the line is not movable, then hovering is also disabled. Added in version 0.9.9.""" self.hoverPen = fn.mkPen(*args, **kwargs) if self.mouseHovering: self.currentPen = self.hoverPen self.update() def setAngle(self, angle): """ Takes angle argument in degrees. 0 is horizontal; 90 is vertical. Note that the use of value() and setValue() changes if the line is not vertical or horizontal. """ self.angle = ((angle+45) % 180) - 45 ## -45 <= angle < 135 self.resetTransform() self.rotate(self.angle) self.update() def setPos(self, pos): if type(pos) in [list, tuple]: newPos = pos elif isinstance(pos, QtCore.QPointF): newPos = [pos.x(), pos.y()] else: if self.angle == 90: newPos = [pos, 0] elif self.angle == 0: newPos = [0, pos] else: raise Exception("Must specify 2D coordinate for non-orthogonal lines.") ## check bounds (only works for orthogonal lines) if self.angle == 90: if self.maxRange[0] is not None: newPos[0] = max(newPos[0], self.maxRange[0]) if self.maxRange[1] is not None: newPos[0] = min(newPos[0], self.maxRange[1]) elif self.angle == 0: if self.maxRange[0] is not None: newPos[1] = max(newPos[1], self.maxRange[0]) if self.maxRange[1] is not None: newPos[1] = min(newPos[1], self.maxRange[1]) if self.p != newPos: self.p = newPos self._invalidateCache() GraphicsObject.setPos(self, Point(self.p)) self.sigPositionChanged.emit(self) def getXPos(self): return self.p[0] def getYPos(self): return self.p[1] def getPos(self): return self.p def value(self): """Return the value of the line. Will be a single number for horizontal and vertical lines, and a list of [x,y] values for diagonal lines.""" if self.angle%180 == 0: return self.getYPos() elif self.angle%180 == 90: return self.getXPos() else: return self.getPos() def setValue(self, v): """Set the position of the line. If line is horizontal or vertical, v can be a single value. Otherwise, a 2D coordinate must be specified (list, tuple and QPointF are all acceptable).""" self.setPos(v) ## broken in 4.7 #def itemChange(self, change, val): #if change in [self.ItemScenePositionHasChanged, self.ItemSceneHasChanged]: #self.updateLine() #print "update", change #print self.getBoundingParents() #else: #print "ignore", change #return GraphicsObject.itemChange(self, change, val) def _invalidateCache(self): self._line = None self._boundingRect = None def boundingRect(self): if self._boundingRect is None: #br = UIGraphicsItem.boundingRect(self) br = self.viewRect() if br is None: return QtCore.QRectF() ## add a 4-pixel radius around the line for mouse interaction. px = self.pixelLength(direction=Point(1,0), ortho=True) ## get pixel length orthogonal to the line if px is None: px = 0 w = (max(4, self.pen.width()/2, self.hoverPen.width()/2)+1) * px br.setBottom(-w) br.setTop(w) br = br.normalized() self._boundingRect = br self._line = QtCore.QLineF(br.right(), 0.0, br.left(), 0.0) return self._boundingRect def paint(self, p, *args): p.setPen(self.currentPen) p.drawLine(self._line) def dataBounds(self, axis, frac=1.0, orthoRange=None): if axis == 0: return None ## x axis should never be auto-scaled else: return (0,0) def mouseDragEvent(self, ev): if self.movable and ev.button() == QtCore.Qt.LeftButton: if ev.isStart(): self.moving = True self.cursorOffset = self.pos() - self.mapToParent(ev.buttonDownPos()) self.startPosition = self.pos() ev.accept() if not self.moving: return self.setPos(self.cursorOffset + self.mapToParent(ev.pos())) self.sigDragged.emit(self) if ev.isFinish(): self.moving = False self.sigPositionChangeFinished.emit(self) def mouseClickEvent(self, ev): if self.moving and ev.button() == QtCore.Qt.RightButton: ev.accept() self.setPos(self.startPosition) self.moving = False self.sigDragged.emit(self) self.sigPositionChangeFinished.emit(self) def hoverEvent(self, ev): if (not ev.isExit()) and self.movable and ev.acceptDrags(QtCore.Qt.LeftButton): self.setMouseHover(True) else: self.setMouseHover(False) def setMouseHover(self, hover): ## Inform the item that the mouse is (not) hovering over it if self.mouseHovering == hover: return self.mouseHovering = hover if hover: self.currentPen = self.hoverPen else: self.currentPen = self.pen self.update() def viewTransformChanged(self): """ Called whenever the transformation matrix of the view has changed. (eg, the view range has changed or the view was resized) """ self._invalidateCache() def setName(self, name): self._name = name def name(self): return self._name class InfLineLabel(TextItem): """ A TextItem that attaches itself to an InfiniteLine. This class extends TextItem with the following features: * Automatically positions adjacent to the line at a fixed position along the line and within the view box. * Automatically reformats text when the line value has changed. * Can optionally be dragged to change its location along the line. * Optionally aligns to its parent line. =============== ================================================================== **Arguments:** line The InfiniteLine to which this label will be attached. text String to display in the label. May contain a {value} formatting string to display the current value of the line. movable Bool; if True, then the label can be dragged along the line. position Relative position (0.0-1.0) within the view to position the label along the line. anchors List of (x,y) pairs giving the text anchor positions that should be used when the line is moved to one side of the view or the other. This allows text to switch to the opposite side of the line as it approaches the edge of the view. These are automatically selected for some common cases, but may be specified if the default values give unexpected results. =============== ================================================================== All extra keyword arguments are passed to TextItem. A particularly useful option here is to use `rotateAxis=(1, 0)`, which will cause the text to be automatically rotated parallel to the line. """ def __init__(self, line, text="", movable=False, position=0.5, anchors=None, **kwds): self.line = line self.movable = movable self.moving = False self.orthoPos = position # text will always be placed on the line at a position relative to view bounds self.format = text self.line.sigPositionChanged.connect(self.valueChanged) self._endpoints = (None, None) if anchors is None: # automatically pick sensible anchors rax = kwds.get('rotateAxis', None) if rax is not None: if tuple(rax) == (1,0): anchors = [(0.5, 0), (0.5, 1)] else: anchors = [(0, 0.5), (1, 0.5)] else: if line.angle % 180 == 0: anchors = [(0.5, 0), (0.5, 1)] else: anchors = [(0, 0.5), (1, 0.5)] self.anchors = anchors TextItem.__init__(self, **kwds) self.setParentItem(line) self.valueChanged() def valueChanged(self): if not self.isVisible(): return value = self.line.value() self.setText(self.format.format(value=value)) self.updatePosition() def getEndpoints(self): # calculate points where line intersects view box # (in line coordinates) if self._endpoints[0] is None: lr = self.line.boundingRect() pt1 = Point(lr.left(), 0) pt2 = Point(lr.right(), 0) if self.line.angle % 90 != 0: # more expensive to find text position for oblique lines. view = self.getViewBox() if not self.isVisible() or not isinstance(view, ViewBox): # not in a viewbox, skip update return (None, None) p = QtGui.QPainterPath() p.moveTo(pt1) p.lineTo(pt2) p = self.line.itemTransform(view)[0].map(p) vr = QtGui.QPainterPath() vr.addRect(view.boundingRect()) paths = vr.intersected(p).toSubpathPolygons(QtGui.QTransform()) if len(paths) > 0: l = list(paths[0]) pt1 = self.line.mapFromItem(view, l[0]) pt2 = self.line.mapFromItem(view, l[1]) self._endpoints = (pt1, pt2) return self._endpoints def updatePosition(self): # update text position to relative view location along line self._endpoints = (None, None) pt1, pt2 = self.getEndpoints() if pt1 is None: return pt = pt2 * self.orthoPos + pt1 * (1-self.orthoPos) self.setPos(pt) # update anchor to keep text visible as it nears the view box edge vr = self.line.viewRect() if vr is not None: self.setAnchor(self.anchors[0 if vr.center().y() < 0 else 1]) def setVisible(self, v): TextItem.setVisible(self, v) if v: self.updateText() self.updatePosition() def setMovable(self, m): """Set whether this label is movable by dragging along the line. """ self.movable = m self.setAcceptHoverEvents(m) def setPosition(self, p): """Set the relative position (0.0-1.0) of this label within the view box and along the line. For horizontal (angle=0) and vertical (angle=90) lines, a value of 0.0 places the text at the bottom or left of the view, respectively. """ self.orthoPos = p self.updatePosition() def setFormat(self, text): """Set the text format string for this label. May optionally contain "{value}" to include the lines current value (the text will be reformatted whenever the line is moved). """ self.format = text self.valueChanged() def mouseDragEvent(self, ev): if self.movable and ev.button() == QtCore.Qt.LeftButton: if ev.isStart(): self._moving = True self._cursorOffset = self._posToRel(ev.buttonDownPos()) self._startPosition = self.orthoPos ev.accept() if not self._moving: return rel = self._posToRel(ev.pos()) self.orthoPos = np.clip(self._startPosition + rel - self._cursorOffset, 0, 1) self.updatePosition() if ev.isFinish(): self._moving = False def mouseClickEvent(self, ev): if self.moving and ev.button() == QtCore.Qt.RightButton: ev.accept() self.orthoPos = self._startPosition self.moving = False def hoverEvent(self, ev): if not ev.isExit() and self.movable: ev.acceptDrags(QtCore.Qt.LeftButton) def viewTransformChanged(self): self.updatePosition() TextItem.viewTransformChanged(self) def _posToRel(self, pos): # convert local position to relative position along line between view bounds pt1, pt2 = self.getEndpoints() if pt1 is None: return 0 view = self.getViewBox() pos = self.mapToParent(pos) return (pos.x() - pt1.x()) / (pt2.x()-pt1.x()) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/IsocurveItem.py000066400000000000000000000076521300727121400254440ustar00rootroot00000000000000from .. import getConfigOption from .GraphicsObject import * from .. import functions as fn from ..Qt import QtGui, QtCore class IsocurveItem(GraphicsObject): """ **Bases:** :class:`GraphicsObject ` Item displaying an isocurve of a 2D array. To align this item correctly with an ImageItem, call ``isocurve.setParentItem(image)``. """ def __init__(self, data=None, level=0, pen='w', axisOrder=None): """ Create a new isocurve item. ============== =============================================================== **Arguments:** data A 2-dimensional ndarray. Can be initialized as None, and set later using :func:`setData ` level The cutoff value at which to draw the isocurve. pen The color of the curve item. Can be anything valid for :func:`mkPen ` axisOrder May be either 'row-major' or 'col-major'. By default this uses the ``imageAxisOrder`` :ref:`global configuration option `. ============== =============================================================== """ GraphicsObject.__init__(self) self.level = level self.data = None self.path = None self.axisOrder = getConfigOption('imageAxisOrder') if axisOrder is None else axisOrder self.setPen(pen) self.setData(data, level) def setData(self, data, level=None): """ Set the data/image to draw isocurves for. ============== ======================================================================== **Arguments:** data A 2-dimensional ndarray. level The cutoff value at which to draw the curve. If level is not specified, the previously set level is used. ============== ======================================================================== """ if level is None: level = self.level self.level = level self.data = data self.path = None self.prepareGeometryChange() self.update() def setLevel(self, level): """Set the level at which the isocurve is drawn.""" self.level = level self.path = None self.prepareGeometryChange() self.update() def setPen(self, *args, **kwargs): """Set the pen used to draw the isocurve. Arguments can be any that are valid for :func:`mkPen `""" self.pen = fn.mkPen(*args, **kwargs) self.update() def setBrush(self, *args, **kwargs): """Set the brush used to draw the isocurve. Arguments can be any that are valid for :func:`mkBrush `""" self.brush = fn.mkBrush(*args, **kwargs) self.update() def updateLines(self, data, level): self.setData(data, level) def boundingRect(self): if self.data is None: return QtCore.QRectF() if self.path is None: self.generatePath() return self.path.boundingRect() def generatePath(self): if self.data is None: self.path = None return if self.axisOrder == 'row-major': data = self.data.T else: data = self.data lines = fn.isocurve(data, self.level, connected=True, extendToEdge=True) self.path = QtGui.QPainterPath() for line in lines: self.path.moveTo(*line[0]) for p in line[1:]: self.path.lineTo(*p) def paint(self, p, *args): if self.data is None: return if self.path is None: self.generatePath() p.setPen(self.pen) p.drawPath(self.path) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/ItemGroup.py000066400000000000000000000010421300727121400247240ustar00rootroot00000000000000from ..Qt import QtGui, QtCore from .GraphicsObject import GraphicsObject __all__ = ['ItemGroup'] class ItemGroup(GraphicsObject): """ Replacement for QGraphicsItemGroup """ def __init__(self, *args): GraphicsObject.__init__(self, *args) if hasattr(self, "ItemHasNoContents"): self.setFlag(self.ItemHasNoContents) def boundingRect(self): return QtCore.QRectF() def paint(self, *args): pass def addItem(self, item): item.setParentItem(self) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/LabelItem.py000066400000000000000000000120321300727121400246500ustar00rootroot00000000000000from ..Qt import QtGui, QtCore from .. import functions as fn from .GraphicsWidget import GraphicsWidget from .GraphicsWidgetAnchor import GraphicsWidgetAnchor from .. import getConfigOption __all__ = ['LabelItem'] class LabelItem(GraphicsWidget, GraphicsWidgetAnchor): """ GraphicsWidget displaying text. Used mainly as axis labels, titles, etc. Note: To display text inside a scaled view (ViewBox, PlotWidget, etc) use TextItem """ def __init__(self, text=' ', parent=None, angle=0, **args): GraphicsWidget.__init__(self, parent) GraphicsWidgetAnchor.__init__(self) self.item = QtGui.QGraphicsTextItem(self) self.opts = { 'color': None, 'justify': 'center' } self.opts.update(args) self._sizeHint = {} self.setText(text) self.setAngle(angle) def setAttr(self, attr, value): """Set default text properties. See setText() for accepted parameters.""" self.opts[attr] = value def setText(self, text, **args): """Set the text and text properties in the label. Accepts optional arguments for auto-generating a CSS style string: ==================== ============================== **Style Arguments:** color (str) example: 'CCFF00' size (str) example: '8pt' bold (bool) italic (bool) ==================== ============================== """ self.text = text opts = self.opts for k in args: opts[k] = args[k] optlist = [] color = self.opts['color'] if color is None: color = getConfigOption('foreground') color = fn.mkColor(color) optlist.append('color: #' + fn.colorStr(color)[:6]) if 'size' in opts: optlist.append('font-size: ' + opts['size']) if 'bold' in opts and opts['bold'] in [True, False]: optlist.append('font-weight: ' + {True:'bold', False:'normal'}[opts['bold']]) if 'italic' in opts and opts['italic'] in [True, False]: optlist.append('font-style: ' + {True:'italic', False:'normal'}[opts['italic']]) full = "%s" % ('; '.join(optlist), text) #print full self.item.setHtml(full) self.updateMin() self.resizeEvent(None) self.updateGeometry() def resizeEvent(self, ev): #c1 = self.boundingRect().center() #c2 = self.item.mapToParent(self.item.boundingRect().center()) # + self.item.pos() #dif = c1 - c2 #self.item.moveBy(dif.x(), dif.y()) #print c1, c2, dif, self.item.pos() self.item.setPos(0,0) bounds = self.itemRect() left = self.mapFromItem(self.item, QtCore.QPointF(0,0)) - self.mapFromItem(self.item, QtCore.QPointF(1,0)) rect = self.rect() if self.opts['justify'] == 'left': if left.x() != 0: bounds.moveLeft(rect.left()) if left.y() < 0: bounds.moveTop(rect.top()) elif left.y() > 0: bounds.moveBottom(rect.bottom()) elif self.opts['justify'] == 'center': bounds.moveCenter(rect.center()) #bounds = self.itemRect() #self.item.setPos(self.width()/2. - bounds.width()/2., 0) elif self.opts['justify'] == 'right': if left.x() != 0: bounds.moveRight(rect.right()) if left.y() < 0: bounds.moveBottom(rect.bottom()) elif left.y() > 0: bounds.moveTop(rect.top()) #bounds = self.itemRect() #self.item.setPos(self.width() - bounds.width(), 0) self.item.setPos(bounds.topLeft() - self.itemRect().topLeft()) self.updateMin() def setAngle(self, angle): self.angle = angle self.item.resetTransform() self.item.rotate(angle) self.updateMin() def updateMin(self): bounds = self.itemRect() self.setMinimumWidth(bounds.width()) self.setMinimumHeight(bounds.height()) self._sizeHint = { QtCore.Qt.MinimumSize: (bounds.width(), bounds.height()), QtCore.Qt.PreferredSize: (bounds.width(), bounds.height()), QtCore.Qt.MaximumSize: (-1, -1), #bounds.width()*2, bounds.height()*2), QtCore.Qt.MinimumDescent: (0, 0) ##?? what is this? } self.updateGeometry() def sizeHint(self, hint, constraint): if hint not in self._sizeHint: return QtCore.QSizeF(0, 0) return QtCore.QSizeF(*self._sizeHint[hint]) def itemRect(self): return self.item.mapRectToParent(self.item.boundingRect()) #def paint(self, p, *args): #p.setPen(fn.mkPen('r')) #p.drawRect(self.rect()) #p.setPen(fn.mkPen('g')) #p.drawRect(self.itemRect()) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/LegendItem.py000066400000000000000000000151431300727121400250350ustar00rootroot00000000000000from .GraphicsWidget import GraphicsWidget from .LabelItem import LabelItem from ..Qt import QtGui, QtCore from .. import functions as fn from ..Point import Point from .ScatterPlotItem import ScatterPlotItem, drawSymbol from .PlotDataItem import PlotDataItem from .GraphicsWidgetAnchor import GraphicsWidgetAnchor __all__ = ['LegendItem'] class LegendItem(GraphicsWidget, GraphicsWidgetAnchor): """ Displays a legend used for describing the contents of a plot. LegendItems are most commonly created by calling PlotItem.addLegend(). Note that this item should not be added directly to a PlotItem. Instead, Make it a direct descendant of the PlotItem:: legend.setParentItem(plotItem) """ def __init__(self, size=None, offset=None): """ ============== =============================================================== **Arguments:** size Specifies the fixed size (width, height) of the legend. If this argument is omitted, the legend will autimatically resize to fit its contents. offset Specifies the offset position relative to the legend's parent. Positive values offset from the left or top; negative values offset from the right or bottom. If offset is None, the legend must be anchored manually by calling anchor() or positioned by calling setPos(). ============== =============================================================== """ GraphicsWidget.__init__(self) GraphicsWidgetAnchor.__init__(self) self.setFlag(self.ItemIgnoresTransformations) self.layout = QtGui.QGraphicsGridLayout() self.setLayout(self.layout) self.items = [] self.size = size self.offset = offset if size is not None: self.setGeometry(QtCore.QRectF(0, 0, self.size[0], self.size[1])) def setParentItem(self, p): ret = GraphicsWidget.setParentItem(self, p) if self.offset is not None: offset = Point(self.offset) anchorx = 1 if offset[0] <= 0 else 0 anchory = 1 if offset[1] <= 0 else 0 anchor = (anchorx, anchory) self.anchor(itemPos=anchor, parentPos=anchor, offset=offset) return ret def addItem(self, item, name): """ Add a new entry to the legend. ============== ======================================================== **Arguments:** item A PlotDataItem from which the line and point style of the item will be determined or an instance of ItemSample (or a subclass), allowing the item display to be customized. title The title to display for this item. Simple HTML allowed. ============== ======================================================== """ label = LabelItem(name) if isinstance(item, ItemSample): sample = item else: sample = ItemSample(item) row = self.layout.rowCount() self.items.append((sample, label)) self.layout.addItem(sample, row, 0) self.layout.addItem(label, row, 1) self.updateSize() def removeItem(self, name): """ Removes one item from the legend. ============== ======================================================== **Arguments:** title The title displayed for this item. ============== ======================================================== """ # Thanks, Ulrich! # cycle for a match for sample, label in self.items: if label.text == name: # hit self.items.remove( (sample, label) ) # remove from itemlist self.layout.removeItem(sample) # remove from layout sample.close() # remove from drawing self.layout.removeItem(label) label.close() self.updateSize() # redraq box def updateSize(self): if self.size is not None: return height = 0 width = 0 #print("-------") for sample, label in self.items: height += max(sample.height(), label.height()) + 3 width = max(width, sample.width()+label.width()) #print(width, height) #print width, height self.setGeometry(0, 0, width+25, height) def boundingRect(self): return QtCore.QRectF(0, 0, self.width(), self.height()) def paint(self, p, *args): p.setPen(fn.mkPen(255,255,255,100)) p.setBrush(fn.mkBrush(100,100,100,50)) p.drawRect(self.boundingRect()) def hoverEvent(self, ev): ev.acceptDrags(QtCore.Qt.LeftButton) def mouseDragEvent(self, ev): if ev.button() == QtCore.Qt.LeftButton: dpos = ev.pos() - ev.lastPos() self.autoAnchor(self.pos() + dpos) class ItemSample(GraphicsWidget): """ Class responsible for drawing a single item in a LegendItem (sans label). This may be subclassed to draw custom graphics in a Legend. """ ## Todo: make this more generic; let each item decide how it should be represented. def __init__(self, item): GraphicsWidget.__init__(self) self.item = item def boundingRect(self): return QtCore.QRectF(0, 0, 20, 20) def paint(self, p, *args): #p.setRenderHint(p.Antialiasing) # only if the data is antialiased. opts = self.item.opts if opts.get('fillLevel',None) is not None and opts.get('fillBrush',None) is not None: p.setBrush(fn.mkBrush(opts['fillBrush'])) p.setPen(fn.mkPen(None)) p.drawPolygon(QtGui.QPolygonF([QtCore.QPointF(2,18), QtCore.QPointF(18,2), QtCore.QPointF(18,18)])) if not isinstance(self.item, ScatterPlotItem): p.setPen(fn.mkPen(opts['pen'])) p.drawLine(2, 18, 18, 2) symbol = opts.get('symbol', None) if symbol is not None: if isinstance(self.item, PlotDataItem): opts = self.item.scatter.opts pen = fn.mkPen(opts['pen']) brush = fn.mkBrush(opts['brush']) size = opts['size'] p.translate(10,10) path = drawSymbol(p, symbol, size, pen, brush) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/LinearRegionItem.py000066400000000000000000000255121300727121400262160ustar00rootroot00000000000000from ..Qt import QtGui, QtCore from .UIGraphicsItem import UIGraphicsItem from .InfiniteLine import InfiniteLine from .. import functions as fn from .. import debug as debug __all__ = ['LinearRegionItem'] class LinearRegionItem(UIGraphicsItem): """ **Bases:** :class:`UIGraphicsItem ` Used for marking a horizontal or vertical region in plots. The region can be dragged and is bounded by lines which can be dragged individually. =============================== ============================================================================= **Signals:** sigRegionChangeFinished(self) Emitted when the user has finished dragging the region (or one of its lines) and when the region is changed programatically. sigRegionChanged(self) Emitted while the user is dragging the region (or one of its lines) and when the region is changed programatically. =============================== ============================================================================= """ sigRegionChangeFinished = QtCore.Signal(object) sigRegionChanged = QtCore.Signal(object) Vertical = 0 Horizontal = 1 def __init__(self, values=[0,1], orientation=None, brush=None, movable=True, bounds=None): """Create a new LinearRegionItem. ============== ===================================================================== **Arguments:** values A list of the positions of the lines in the region. These are not limits; limits can be set by specifying bounds. orientation Options are LinearRegionItem.Vertical or LinearRegionItem.Horizontal. If not specified it will be vertical. brush Defines the brush that fills the region. Can be any arguments that are valid for :func:`mkBrush `. Default is transparent blue. movable If True, the region and individual lines are movable by the user; if False, they are static. bounds Optional [min, max] bounding values for the region ============== ===================================================================== """ UIGraphicsItem.__init__(self) if orientation is None: orientation = LinearRegionItem.Vertical self.orientation = orientation self.bounds = QtCore.QRectF() self.blockLineSignal = False self.moving = False self.mouseHovering = False if orientation == LinearRegionItem.Horizontal: self.lines = [ InfiniteLine(QtCore.QPointF(0, values[0]), 0, movable=movable, bounds=bounds), InfiniteLine(QtCore.QPointF(0, values[1]), 0, movable=movable, bounds=bounds)] elif orientation == LinearRegionItem.Vertical: self.lines = [ InfiniteLine(QtCore.QPointF(values[1], 0), 90, movable=movable, bounds=bounds), InfiniteLine(QtCore.QPointF(values[0], 0), 90, movable=movable, bounds=bounds)] else: raise Exception('Orientation must be one of LinearRegionItem.Vertical or LinearRegionItem.Horizontal') for l in self.lines: l.setParentItem(self) l.sigPositionChangeFinished.connect(self.lineMoveFinished) l.sigPositionChanged.connect(self.lineMoved) if brush is None: brush = QtGui.QBrush(QtGui.QColor(0, 0, 255, 50)) self.setBrush(brush) self.setMovable(movable) def getRegion(self): """Return the values at the edges of the region.""" #if self.orientation[0] == 'h': #r = (self.bounds.top(), self.bounds.bottom()) #else: #r = (self.bounds.left(), self.bounds.right()) r = [self.lines[0].value(), self.lines[1].value()] return (min(r), max(r)) def setRegion(self, rgn): """Set the values for the edges of the region. ============== ============================================== **Arguments:** rgn A list or tuple of the lower and upper values. ============== ============================================== """ if self.lines[0].value() == rgn[0] and self.lines[1].value() == rgn[1]: return self.blockLineSignal = True self.lines[0].setValue(rgn[0]) self.blockLineSignal = False self.lines[1].setValue(rgn[1]) #self.blockLineSignal = False self.lineMoved() self.lineMoveFinished() def setBrush(self, *br, **kargs): """Set the brush that fills the region. Can have any arguments that are valid for :func:`mkBrush `. """ self.brush = fn.mkBrush(*br, **kargs) self.currentBrush = self.brush def setBounds(self, bounds): """Optional [min, max] bounding values for the region. To have no bounds on the region use [None, None]. Does not affect the current position of the region unless it is outside the new bounds. See :func:`setRegion ` to set the position of the region.""" for l in self.lines: l.setBounds(bounds) def setMovable(self, m): """Set lines to be movable by the user, or not. If lines are movable, they will also accept HoverEvents.""" for l in self.lines: l.setMovable(m) self.movable = m self.setAcceptHoverEvents(m) def boundingRect(self): br = UIGraphicsItem.boundingRect(self) rng = self.getRegion() if self.orientation == LinearRegionItem.Vertical: br.setLeft(rng[0]) br.setRight(rng[1]) else: br.setTop(rng[0]) br.setBottom(rng[1]) return br.normalized() def paint(self, p, *args): profiler = debug.Profiler() UIGraphicsItem.paint(self, p, *args) p.setBrush(self.currentBrush) p.setPen(fn.mkPen(None)) p.drawRect(self.boundingRect()) def dataBounds(self, axis, frac=1.0, orthoRange=None): if axis == self.orientation: return self.getRegion() else: return None def lineMoved(self): if self.blockLineSignal: return self.prepareGeometryChange() #self.emit(QtCore.SIGNAL('regionChanged'), self) self.sigRegionChanged.emit(self) def lineMoveFinished(self): #self.emit(QtCore.SIGNAL('regionChangeFinished'), self) self.sigRegionChangeFinished.emit(self) #def updateBounds(self): #vb = self.view().viewRect() #vals = [self.lines[0].value(), self.lines[1].value()] #if self.orientation[0] == 'h': #vb.setTop(min(vals)) #vb.setBottom(max(vals)) #else: #vb.setLeft(min(vals)) #vb.setRight(max(vals)) #if vb != self.bounds: #self.bounds = vb #self.rect.setRect(vb) #def mousePressEvent(self, ev): #if not self.movable: #ev.ignore() #return #for l in self.lines: #l.mousePressEvent(ev) ## pass event to both lines so they move together ##if self.movable and ev.button() == QtCore.Qt.LeftButton: ##ev.accept() ##self.pressDelta = self.mapToParent(ev.pos()) - QtCore.QPointF(*self.p) ##else: ##ev.ignore() #def mouseReleaseEvent(self, ev): #for l in self.lines: #l.mouseReleaseEvent(ev) #def mouseMoveEvent(self, ev): ##print "move", ev.pos() #if not self.movable: #return #self.lines[0].blockSignals(True) # only want to update once #for l in self.lines: #l.mouseMoveEvent(ev) #self.lines[0].blockSignals(False) ##self.setPos(self.mapToParent(ev.pos()) - self.pressDelta) ##self.emit(QtCore.SIGNAL('dragged'), self) def mouseDragEvent(self, ev): if not self.movable or int(ev.button() & QtCore.Qt.LeftButton) == 0: return ev.accept() if ev.isStart(): bdp = ev.buttonDownPos() self.cursorOffsets = [l.pos() - bdp for l in self.lines] self.startPositions = [l.pos() for l in self.lines] self.moving = True if not self.moving: return #delta = ev.pos() - ev.lastPos() self.lines[0].blockSignals(True) # only want to update once for i, l in enumerate(self.lines): l.setPos(self.cursorOffsets[i] + ev.pos()) #l.setPos(l.pos()+delta) #l.mouseDragEvent(ev) self.lines[0].blockSignals(False) self.prepareGeometryChange() if ev.isFinish(): self.moving = False self.sigRegionChangeFinished.emit(self) else: self.sigRegionChanged.emit(self) def mouseClickEvent(self, ev): if self.moving and ev.button() == QtCore.Qt.RightButton: ev.accept() for i, l in enumerate(self.lines): l.setPos(self.startPositions[i]) self.moving = False self.sigRegionChanged.emit(self) self.sigRegionChangeFinished.emit(self) def hoverEvent(self, ev): if self.movable and (not ev.isExit()) and ev.acceptDrags(QtCore.Qt.LeftButton): self.setMouseHover(True) else: self.setMouseHover(False) def setMouseHover(self, hover): ## Inform the item that the mouse is(not) hovering over it if self.mouseHovering == hover: return self.mouseHovering = hover if hover: c = self.brush.color() c.setAlpha(c.alpha() * 2) self.currentBrush = fn.mkBrush(c) else: self.currentBrush = self.brush self.update() #def hoverEnterEvent(self, ev): #print "rgn hover enter" #ev.ignore() #self.updateHoverBrush() #def hoverMoveEvent(self, ev): #print "rgn hover move" #ev.ignore() #self.updateHoverBrush() #def hoverLeaveEvent(self, ev): #print "rgn hover leave" #ev.ignore() #self.updateHoverBrush(False) #def updateHoverBrush(self, hover=None): #if hover is None: #scene = self.scene() #hover = scene.claimEvent(self, QtCore.Qt.LeftButton, scene.Drag) #if hover: #self.currentBrush = fn.mkBrush(255, 0,0,100) #else: #self.currentBrush = self.brush #self.update() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/MultiPlotItem.py000066400000000000000000000040161300727121400255650ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ MultiPlotItem.py - Graphics item used for displaying an array of PlotItems Copyright 2010 Luke Campagnola Distributed under MIT/X11 license. See license.txt for more infomation. """ from numpy import ndarray from . import GraphicsLayout from ..metaarray import * __all__ = ['MultiPlotItem'] class MultiPlotItem(GraphicsLayout.GraphicsLayout): """ Automatically generates a grid of plots from a multi-dimensional array """ def __init__(self, *args, **kwds): GraphicsLayout.GraphicsLayout.__init__(self, *args, **kwds) self.plots = [] def plot(self, data): #self.layout.clear() if hasattr(data, 'implements') and data.implements('MetaArray'): if data.ndim != 2: raise Exception("MultiPlot currently only accepts 2D MetaArray.") ic = data.infoCopy() ax = 0 for i in [0, 1]: if 'cols' in ic[i]: ax = i break #print "Plotting using axis %d as columns (%d plots)" % (ax, data.shape[ax]) for i in range(data.shape[ax]): pi = self.addPlot() self.nextRow() sl = [slice(None)] * 2 sl[ax] = i pi.plot(data[tuple(sl)]) #self.layout.addItem(pi, i, 0) self.plots.append((pi, i, 0)) info = ic[ax]['cols'][i] title = info.get('title', info.get('name', None)) units = info.get('units', None) pi.setLabel('left', text=title, units=units) info = ic[1-ax] title = info.get('title', info.get('name', None)) units = info.get('units', None) pi.setLabel('bottom', text=title, units=units) else: raise Exception("Data type %s not (yet?) supported for MultiPlot." % type(data)) def close(self): for p in self.plots: p[0].close() self.plots = None self.clear() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/PlotCurveItem.py000066400000000000000000000544301300727121400255640ustar00rootroot00000000000000from ..Qt import QtGui, QtCore try: from ..Qt import QtOpenGL HAVE_OPENGL = True except: HAVE_OPENGL = False import numpy as np from .GraphicsObject import GraphicsObject from .. import functions as fn from ..Point import Point import struct, sys from .. import getConfigOption from .. import debug __all__ = ['PlotCurveItem'] class PlotCurveItem(GraphicsObject): """ Class representing a single plot curve. Instances of this class are created automatically as part of PlotDataItem; these rarely need to be instantiated directly. Features: - Fast data update - Fill under curve - Mouse interaction ==================== =============================================== **Signals:** sigPlotChanged(self) Emitted when the data being plotted has changed sigClicked(self) Emitted when the curve is clicked ==================== =============================================== """ sigPlotChanged = QtCore.Signal(object) sigClicked = QtCore.Signal(object) def __init__(self, *args, **kargs): """ Forwards all arguments to :func:`setData `. Some extra arguments are accepted as well: ============== ======================================================= **Arguments:** parent The parent GraphicsObject (optional) clickable If True, the item will emit sigClicked when it is clicked on. Defaults to False. ============== ======================================================= """ GraphicsObject.__init__(self, kargs.get('parent', None)) self.clear() ## this is disastrous for performance. #self.setCacheMode(QtGui.QGraphicsItem.DeviceCoordinateCache) self.metaData = {} self.opts = { 'pen': fn.mkPen('w'), 'shadowPen': None, 'fillLevel': None, 'brush': None, 'stepMode': False, 'name': None, 'antialias': getConfigOption('antialias'), 'connect': 'all', 'mouseWidth': 8, # width of shape responding to mouse click } self.setClickable(kargs.get('clickable', False)) self.setData(*args, **kargs) def implements(self, interface=None): ints = ['plotData'] if interface is None: return ints return interface in ints def name(self): return self.opts.get('name', None) def setClickable(self, s, width=None): """Sets whether the item responds to mouse clicks. The *width* argument specifies the width in pixels orthogonal to the curve that will respond to a mouse click. """ self.clickable = s if width is not None: self.opts['mouseWidth'] = width self._mouseShape = None self._boundingRect = None def getData(self): return self.xData, self.yData def dataBounds(self, ax, frac=1.0, orthoRange=None): ## Need this to run as fast as possible. ## check cache first: cache = self._boundsCache[ax] if cache is not None and cache[0] == (frac, orthoRange): return cache[1] (x, y) = self.getData() if x is None or len(x) == 0: return (None, None) if ax == 0: d = x d2 = y elif ax == 1: d = y d2 = x ## If an orthogonal range is specified, mask the data now if orthoRange is not None: mask = (d2 >= orthoRange[0]) * (d2 <= orthoRange[1]) d = d[mask] #d2 = d2[mask] if len(d) == 0: return (None, None) ## Get min/max (or percentiles) of the requested data range if frac >= 1.0: # include complete data range # first try faster nanmin/max function, then cut out infs if needed. b = (np.nanmin(d), np.nanmax(d)) if any(np.isinf(b)): mask = np.isfinite(d) d = d[mask] b = (d.min(), d.max()) elif frac <= 0.0: raise Exception("Value for parameter 'frac' must be > 0. (got %s)" % str(frac)) else: # include a percentile of data range mask = np.isfinite(d) d = d[mask] b = np.percentile(d, [50 * (1 - frac), 50 * (1 + frac)]) ## adjust for fill level if ax == 1 and self.opts['fillLevel'] is not None: b = (min(b[0], self.opts['fillLevel']), max(b[1], self.opts['fillLevel'])) ## Add pen width only if it is non-cosmetic. pen = self.opts['pen'] spen = self.opts['shadowPen'] if not pen.isCosmetic(): b = (b[0] - pen.widthF()*0.7072, b[1] + pen.widthF()*0.7072) if spen is not None and not spen.isCosmetic() and spen.style() != QtCore.Qt.NoPen: b = (b[0] - spen.widthF()*0.7072, b[1] + spen.widthF()*0.7072) self._boundsCache[ax] = [(frac, orthoRange), b] return b def pixelPadding(self): pen = self.opts['pen'] spen = self.opts['shadowPen'] w = 0 if pen.isCosmetic(): w += pen.widthF()*0.7072 if spen is not None and spen.isCosmetic() and spen.style() != QtCore.Qt.NoPen: w = max(w, spen.widthF()*0.7072) if self.clickable: w = max(w, self.opts['mouseWidth']//2 + 1) return w def boundingRect(self): if self._boundingRect is None: (xmn, xmx) = self.dataBounds(ax=0) (ymn, ymx) = self.dataBounds(ax=1) if xmn is None: return QtCore.QRectF() px = py = 0.0 pxPad = self.pixelPadding() if pxPad > 0: # determine length of pixel in local x, y directions px, py = self.pixelVectors() try: px = 0 if px is None else px.length() except OverflowError: px = 0 try: py = 0 if py is None else py.length() except OverflowError: py = 0 # return bounds expanded by pixel size px *= pxPad py *= pxPad #px += self._maxSpotWidth * 0.5 #py += self._maxSpotWidth * 0.5 self._boundingRect = QtCore.QRectF(xmn-px, ymn-py, (2*px)+xmx-xmn, (2*py)+ymx-ymn) return self._boundingRect def viewTransformChanged(self): self.invalidateBounds() self.prepareGeometryChange() #def boundingRect(self): #if self._boundingRect is None: #(x, y) = self.getData() #if x is None or y is None or len(x) == 0 or len(y) == 0: #return QtCore.QRectF() #if self.opts['shadowPen'] is not None: #lineWidth = (max(self.opts['pen'].width(), self.opts['shadowPen'].width()) + 1) #else: #lineWidth = (self.opts['pen'].width()+1) #pixels = self.pixelVectors() #if pixels == (None, None): #pixels = [Point(0,0), Point(0,0)] #xmin = x.min() #xmax = x.max() #ymin = y.min() #ymax = y.max() #if self.opts['fillLevel'] is not None: #ymin = min(ymin, self.opts['fillLevel']) #ymax = max(ymax, self.opts['fillLevel']) #xmin -= pixels[0].x() * lineWidth #xmax += pixels[0].x() * lineWidth #ymin -= abs(pixels[1].y()) * lineWidth #ymax += abs(pixels[1].y()) * lineWidth #self._boundingRect = QtCore.QRectF(xmin, ymin, xmax-xmin, ymax-ymin) #return self._boundingRect def invalidateBounds(self): self._boundingRect = None self._boundsCache = [None, None] def setPen(self, *args, **kargs): """Set the pen used to draw the curve.""" self.opts['pen'] = fn.mkPen(*args, **kargs) self.invalidateBounds() self.update() def setShadowPen(self, *args, **kargs): """Set the shadow pen used to draw behind tyhe primary pen. This pen must have a larger width than the primary pen to be visible. """ self.opts['shadowPen'] = fn.mkPen(*args, **kargs) self.invalidateBounds() self.update() def setBrush(self, *args, **kargs): """Set the brush used when filling the area under the curve""" self.opts['brush'] = fn.mkBrush(*args, **kargs) self.invalidateBounds() self.update() def setFillLevel(self, level): """Set the level filled to when filling under the curve""" self.opts['fillLevel'] = level self.fillPath = None self.invalidateBounds() self.update() def setData(self, *args, **kargs): """ ============== ======================================================== **Arguments:** x, y (numpy arrays) Data to show pen Pen to use when drawing. Any single argument accepted by :func:`mkPen ` is allowed. shadowPen Pen for drawing behind the primary pen. Usually this is used to emphasize the curve by providing a high-contrast border. Any single argument accepted by :func:`mkPen ` is allowed. fillLevel (float or None) Fill the area 'under' the curve to *fillLevel* brush QBrush to use when filling. Any single argument accepted by :func:`mkBrush ` is allowed. antialias (bool) Whether to use antialiasing when drawing. This is disabled by default because it decreases performance. stepMode If True, two orthogonal lines are drawn for each sample as steps. This is commonly used when drawing histograms. Note that in this case, len(x) == len(y) + 1 connect Argument specifying how vertexes should be connected by line segments. Default is "all", indicating full connection. "pairs" causes only even-numbered segments to be drawn. "finite" causes segments to be omitted if they are attached to nan or inf values. For any other connectivity, specify an array of boolean values. ============== ======================================================== If non-keyword arguments are used, they will be interpreted as setData(y) for a single argument and setData(x, y) for two arguments. """ self.updateData(*args, **kargs) def updateData(self, *args, **kargs): profiler = debug.Profiler() if len(args) == 1: kargs['y'] = args[0] elif len(args) == 2: kargs['x'] = args[0] kargs['y'] = args[1] if 'y' not in kargs or kargs['y'] is None: kargs['y'] = np.array([]) if 'x' not in kargs or kargs['x'] is None: kargs['x'] = np.arange(len(kargs['y'])) for k in ['x', 'y']: data = kargs[k] if isinstance(data, list): data = np.array(data) kargs[k] = data if not isinstance(data, np.ndarray) or data.ndim > 1: raise Exception("Plot data must be 1D ndarray.") if 'complex' in str(data.dtype): raise Exception("Can not plot complex data types.") profiler("data checks") #self.setCacheMode(QtGui.QGraphicsItem.NoCache) ## Disabling and re-enabling the cache works around a bug in Qt 4.6 causing the cached results to display incorrectly ## Test this bug with test_PlotWidget and zoom in on the animated plot self.invalidateBounds() self.prepareGeometryChange() self.informViewBoundsChanged() self.yData = kargs['y'].view(np.ndarray) self.xData = kargs['x'].view(np.ndarray) profiler('copy') if 'stepMode' in kargs: self.opts['stepMode'] = kargs['stepMode'] if self.opts['stepMode'] is True: if len(self.xData) != len(self.yData)+1: ## allow difference of 1 for step mode plots raise Exception("len(X) must be len(Y)+1 since stepMode=True (got %s and %s)" % (self.xData.shape, self.yData.shape)) else: if self.xData.shape != self.yData.shape: ## allow difference of 1 for step mode plots raise Exception("X and Y arrays must be the same shape--got %s and %s." % (self.xData.shape, self.yData.shape)) self.path = None self.fillPath = None self._mouseShape = None #self.xDisp = self.yDisp = None if 'name' in kargs: self.opts['name'] = kargs['name'] if 'connect' in kargs: self.opts['connect'] = kargs['connect'] if 'pen' in kargs: self.setPen(kargs['pen']) if 'shadowPen' in kargs: self.setShadowPen(kargs['shadowPen']) if 'fillLevel' in kargs: self.setFillLevel(kargs['fillLevel']) if 'brush' in kargs: self.setBrush(kargs['brush']) if 'antialias' in kargs: self.opts['antialias'] = kargs['antialias'] profiler('set') self.update() profiler('update') self.sigPlotChanged.emit(self) profiler('emit') def generatePath(self, x, y): if self.opts['stepMode']: ## each value in the x/y arrays generates 2 points. x2 = np.empty((len(x),2), dtype=x.dtype) x2[:] = x[:,np.newaxis] if self.opts['fillLevel'] is None: x = x2.reshape(x2.size)[1:-1] y2 = np.empty((len(y),2), dtype=y.dtype) y2[:] = y[:,np.newaxis] y = y2.reshape(y2.size) else: ## If we have a fill level, add two extra points at either end x = x2.reshape(x2.size) y2 = np.empty((len(y)+2,2), dtype=y.dtype) y2[1:-1] = y[:,np.newaxis] y = y2.reshape(y2.size)[1:-1] y[0] = self.opts['fillLevel'] y[-1] = self.opts['fillLevel'] path = fn.arrayToQPath(x, y, connect=self.opts['connect']) return path def getPath(self): if self.path is None: x,y = self.getData() if x is None or len(x) == 0 or y is None or len(y) == 0: self.path = QtGui.QPainterPath() else: self.path = self.generatePath(*self.getData()) self.fillPath = None self._mouseShape = None return self.path @debug.warnOnException ## raising an exception here causes crash def paint(self, p, opt, widget): profiler = debug.Profiler() if self.xData is None or len(self.xData) == 0: return if HAVE_OPENGL and getConfigOption('enableExperimental') and isinstance(widget, QtOpenGL.QGLWidget): self.paintGL(p, opt, widget) return x = None y = None path = self.getPath() profiler('generate path') if self._exportOpts is not False: aa = self._exportOpts.get('antialias', True) else: aa = self.opts['antialias'] p.setRenderHint(p.Antialiasing, aa) if self.opts['brush'] is not None and self.opts['fillLevel'] is not None: if self.fillPath is None: if x is None: x,y = self.getData() p2 = QtGui.QPainterPath(self.path) p2.lineTo(x[-1], self.opts['fillLevel']) p2.lineTo(x[0], self.opts['fillLevel']) p2.lineTo(x[0], y[0]) p2.closeSubpath() self.fillPath = p2 profiler('generate fill path') p.fillPath(self.fillPath, self.opts['brush']) profiler('draw fill path') sp = fn.mkPen(self.opts['shadowPen']) cp = fn.mkPen(self.opts['pen']) ## Copy pens and apply alpha adjustment #sp = QtGui.QPen(self.opts['shadowPen']) #cp = QtGui.QPen(self.opts['pen']) #for pen in [sp, cp]: #if pen is None: #continue #c = pen.color() #c.setAlpha(c.alpha() * self.opts['alphaHint']) #pen.setColor(c) ##pen.setCosmetic(True) if sp is not None and sp.style() != QtCore.Qt.NoPen: p.setPen(sp) p.drawPath(path) p.setPen(cp) p.drawPath(path) profiler('drawPath') #print "Render hints:", int(p.renderHints()) #p.setPen(QtGui.QPen(QtGui.QColor(255,0,0))) #p.drawRect(self.boundingRect()) def paintGL(self, p, opt, widget): p.beginNativePainting() import OpenGL.GL as gl ## set clipping viewport view = self.getViewBox() if view is not None: rect = view.mapRectToItem(self, view.boundingRect()) #gl.glViewport(int(rect.x()), int(rect.y()), int(rect.width()), int(rect.height())) #gl.glTranslate(-rect.x(), -rect.y(), 0) gl.glEnable(gl.GL_STENCIL_TEST) gl.glColorMask(gl.GL_FALSE, gl.GL_FALSE, gl.GL_FALSE, gl.GL_FALSE) # disable drawing to frame buffer gl.glDepthMask(gl.GL_FALSE) # disable drawing to depth buffer gl.glStencilFunc(gl.GL_NEVER, 1, 0xFF) gl.glStencilOp(gl.GL_REPLACE, gl.GL_KEEP, gl.GL_KEEP) ## draw stencil pattern gl.glStencilMask(0xFF) gl.glClear(gl.GL_STENCIL_BUFFER_BIT) gl.glBegin(gl.GL_TRIANGLES) gl.glVertex2f(rect.x(), rect.y()) gl.glVertex2f(rect.x()+rect.width(), rect.y()) gl.glVertex2f(rect.x(), rect.y()+rect.height()) gl.glVertex2f(rect.x()+rect.width(), rect.y()+rect.height()) gl.glVertex2f(rect.x()+rect.width(), rect.y()) gl.glVertex2f(rect.x(), rect.y()+rect.height()) gl.glEnd() gl.glColorMask(gl.GL_TRUE, gl.GL_TRUE, gl.GL_TRUE, gl.GL_TRUE) gl.glDepthMask(gl.GL_TRUE) gl.glStencilMask(0x00) gl.glStencilFunc(gl.GL_EQUAL, 1, 0xFF) try: x, y = self.getData() pos = np.empty((len(x), 2)) pos[:,0] = x pos[:,1] = y gl.glEnableClientState(gl.GL_VERTEX_ARRAY) try: gl.glVertexPointerf(pos) pen = fn.mkPen(self.opts['pen']) color = pen.color() gl.glColor4f(color.red()/255., color.green()/255., color.blue()/255., color.alpha()/255.) width = pen.width() if pen.isCosmetic() and width < 1: width = 1 gl.glPointSize(width) gl.glEnable(gl.GL_LINE_SMOOTH) gl.glEnable(gl.GL_BLEND) gl.glBlendFunc(gl.GL_SRC_ALPHA, gl.GL_ONE_MINUS_SRC_ALPHA) gl.glHint(gl.GL_LINE_SMOOTH_HINT, gl.GL_NICEST) gl.glDrawArrays(gl.GL_LINE_STRIP, 0, pos.size / pos.shape[-1]) finally: gl.glDisableClientState(gl.GL_VERTEX_ARRAY) finally: p.endNativePainting() def clear(self): self.xData = None ## raw values self.yData = None self.xDisp = None ## display values (after log / fft) self.yDisp = None self.path = None self.fillPath = None self._mouseShape = None self._mouseBounds = None self._boundsCache = [None, None] #del self.xData, self.yData, self.xDisp, self.yDisp, self.path def mouseShape(self): """ Return a QPainterPath representing the clickable shape of the curve """ if self._mouseShape is None: view = self.getViewBox() if view is None: return QtGui.QPainterPath() stroker = QtGui.QPainterPathStroker() path = self.getPath() path = self.mapToItem(view, path) stroker.setWidth(self.opts['mouseWidth']) mousePath = stroker.createStroke(path) self._mouseShape = self.mapFromItem(view, mousePath) return self._mouseShape def mouseClickEvent(self, ev): if not self.clickable or ev.button() != QtCore.Qt.LeftButton: return if self.mouseShape().contains(ev.pos()): ev.accept() self.sigClicked.emit(self) class ROIPlotItem(PlotCurveItem): """Plot curve that monitors an ROI and image for changes to automatically replot.""" def __init__(self, roi, data, img, axes=(0,1), xVals=None, color=None): self.roi = roi self.roiData = data self.roiImg = img self.axes = axes self.xVals = xVals PlotCurveItem.__init__(self, self.getRoiData(), x=self.xVals, color=color) #roi.connect(roi, QtCore.SIGNAL('regionChanged'), self.roiChangedEvent) roi.sigRegionChanged.connect(self.roiChangedEvent) #self.roiChangedEvent() def getRoiData(self): d = self.roi.getArrayRegion(self.roiData, self.roiImg, axes=self.axes) if d is None: return while d.ndim > 1: d = d.mean(axis=1) return d def roiChangedEvent(self): d = self.getRoiData() self.updateData(d, self.xVals) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/PlotDataItem.py000066400000000000000000001055461300727121400253560ustar00rootroot00000000000000import numpy as np from .. import metaarray as metaarray from ..Qt import QtCore from .GraphicsObject import GraphicsObject from .PlotCurveItem import PlotCurveItem from .ScatterPlotItem import ScatterPlotItem from .. import functions as fn from .. import debug as debug from .. import getConfigOption class PlotDataItem(GraphicsObject): """ **Bases:** :class:`GraphicsObject ` GraphicsItem for displaying plot curves, scatter plots, or both. While it is possible to use :class:`PlotCurveItem ` or :class:`ScatterPlotItem ` individually, this class provides a unified interface to both. Instances of :class:`PlotDataItem` are usually created by plot() methods such as :func:`pyqtgraph.plot` and :func:`PlotItem.plot() `. ============================== ============================================== **Signals:** sigPlotChanged(self) Emitted when the data in this item is updated. sigClicked(self) Emitted when the item is clicked. sigPointsClicked(self, points) Emitted when a plot point is clicked Sends the list of points under the mouse. ============================== ============================================== """ sigPlotChanged = QtCore.Signal(object) sigClicked = QtCore.Signal(object) sigPointsClicked = QtCore.Signal(object, object) def __init__(self, *args, **kargs): """ There are many different ways to create a PlotDataItem: **Data initialization arguments:** (x,y data only) =================================== ====================================== PlotDataItem(xValues, yValues) x and y values may be any sequence (including ndarray) of real numbers PlotDataItem(yValues) y values only -- x will be automatically set to range(len(y)) PlotDataItem(x=xValues, y=yValues) x and y given by keyword arguments PlotDataItem(ndarray(Nx2)) numpy array with shape (N, 2) where x=data[:,0] and y=data[:,1] =================================== ====================================== **Data initialization arguments:** (x,y data AND may include spot style) =========================== ========================================= PlotDataItem(recarray) numpy array with dtype=[('x', float), ('y', float), ...] PlotDataItem(list-of-dicts) [{'x': x, 'y': y, ...}, ...] PlotDataItem(dict-of-lists) {'x': [...], 'y': [...], ...} PlotDataItem(MetaArray) 1D array of Y values with X sepecified as axis values OR 2D array with a column 'y' and extra columns as needed. =========================== ========================================= **Line style keyword arguments:** ========== ============================================================================== connect Specifies how / whether vertexes should be connected. See :func:`arrayToQPath() ` pen Pen to use for drawing line between points. Default is solid grey, 1px width. Use None to disable line drawing. May be any single argument accepted by :func:`mkPen() ` shadowPen Pen for secondary line to draw behind the primary line. disabled by default. May be any single argument accepted by :func:`mkPen() ` fillLevel Fill the area between the curve and fillLevel fillBrush Fill to use when fillLevel is specified. May be any single argument accepted by :func:`mkBrush() ` stepMode If True, two orthogonal lines are drawn for each sample as steps. This is commonly used when drawing histograms. Note that in this case, `len(x) == len(y) + 1` (added in version 0.9.9) ========== ============================================================================== **Point style keyword arguments:** (see :func:`ScatterPlotItem.setData() ` for more information) ============ ===================================================== symbol Symbol to use for drawing points OR list of symbols, one per point. Default is no symbol. Options are o, s, t, d, +, or any QPainterPath symbolPen Outline pen for drawing points OR list of pens, one per point. May be any single argument accepted by :func:`mkPen() ` symbolBrush Brush for filling points OR list of brushes, one per point. May be any single argument accepted by :func:`mkBrush() ` symbolSize Diameter of symbols OR list of diameters. pxMode (bool) If True, then symbolSize is specified in pixels. If False, then symbolSize is specified in data coordinates. ============ ===================================================== **Optimization keyword arguments:** ================ ===================================================================== antialias (bool) By default, antialiasing is disabled to improve performance. Note that in some cases (in particluar, when pxMode=True), points will be rendered antialiased even if this is set to False. decimate deprecated. downsample (int) Reduce the number of samples displayed by this value downsampleMethod 'subsample': Downsample by taking the first of N samples. This method is fastest and least accurate. 'mean': Downsample by taking the mean of N samples. 'peak': Downsample by drawing a saw wave that follows the min and max of the original data. This method produces the best visual representation of the data but is slower. autoDownsample (bool) If True, resample the data before plotting to avoid plotting multiple line segments per pixel. This can improve performance when viewing very high-density data, but increases the initial overhead and memory usage. clipToView (bool) If True, only plot data that is visible within the X range of the containing ViewBox. This can improve performance when plotting very large data sets where only a fraction of the data is visible at any time. identical *deprecated* ================ ===================================================================== **Meta-info keyword arguments:** ========== ================================================ name name of dataset. This would appear in a legend ========== ================================================ """ GraphicsObject.__init__(self) self.setFlag(self.ItemHasNoContents) self.xData = None self.yData = None self.xDisp = None self.yDisp = None #self.dataMask = None #self.curves = [] #self.scatters = [] self.curve = PlotCurveItem() self.scatter = ScatterPlotItem() self.curve.setParentItem(self) self.scatter.setParentItem(self) self.curve.sigClicked.connect(self.curveClicked) self.scatter.sigClicked.connect(self.scatterClicked) #self.clear() self.opts = { 'connect': 'all', 'fftMode': False, 'logMode': [False, False], 'alphaHint': 1.0, 'alphaMode': False, 'pen': (200,200,200), 'shadowPen': None, 'fillLevel': None, 'fillBrush': None, 'stepMode': None, 'symbol': None, 'symbolSize': 10, 'symbolPen': (200,200,200), 'symbolBrush': (50, 50, 150), 'pxMode': True, 'antialias': getConfigOption('antialias'), 'pointMode': None, 'downsample': 1, 'autoDownsample': False, 'downsampleMethod': 'peak', 'autoDownsampleFactor': 5., # draw ~5 samples per pixel 'clipToView': False, 'data': None, } self.setData(*args, **kargs) def implements(self, interface=None): ints = ['plotData'] if interface is None: return ints return interface in ints def name(self): return self.opts.get('name', None) def boundingRect(self): return QtCore.QRectF() ## let child items handle this def setAlpha(self, alpha, auto): if self.opts['alphaHint'] == alpha and self.opts['alphaMode'] == auto: return self.opts['alphaHint'] = alpha self.opts['alphaMode'] = auto self.setOpacity(alpha) #self.update() def setFftMode(self, mode): if self.opts['fftMode'] == mode: return self.opts['fftMode'] = mode self.xDisp = self.yDisp = None self.xClean = self.yClean = None self.updateItems() self.informViewBoundsChanged() def setLogMode(self, xMode, yMode): if self.opts['logMode'] == [xMode, yMode]: return self.opts['logMode'] = [xMode, yMode] self.xDisp = self.yDisp = None self.xClean = self.yClean = None self.updateItems() self.informViewBoundsChanged() def setPointMode(self, mode): if self.opts['pointMode'] == mode: return self.opts['pointMode'] = mode self.update() def setPen(self, *args, **kargs): """ | Sets the pen used to draw lines between points. | *pen* can be a QPen or any argument accepted by :func:`pyqtgraph.mkPen() ` """ pen = fn.mkPen(*args, **kargs) self.opts['pen'] = pen #self.curve.setPen(pen) #for c in self.curves: #c.setPen(pen) #self.update() self.updateItems() def setShadowPen(self, *args, **kargs): """ | Sets the shadow pen used to draw lines between points (this is for enhancing contrast or emphacizing data). | This line is drawn behind the primary pen (see :func:`setPen() `) and should generally be assigned greater width than the primary pen. | *pen* can be a QPen or any argument accepted by :func:`pyqtgraph.mkPen() ` """ pen = fn.mkPen(*args, **kargs) self.opts['shadowPen'] = pen #for c in self.curves: #c.setPen(pen) #self.update() self.updateItems() def setFillBrush(self, *args, **kargs): brush = fn.mkBrush(*args, **kargs) if self.opts['fillBrush'] == brush: return self.opts['fillBrush'] = brush self.updateItems() def setBrush(self, *args, **kargs): return self.setFillBrush(*args, **kargs) def setFillLevel(self, level): if self.opts['fillLevel'] == level: return self.opts['fillLevel'] = level self.updateItems() def setSymbol(self, symbol): if self.opts['symbol'] == symbol: return self.opts['symbol'] = symbol #self.scatter.setSymbol(symbol) self.updateItems() def setSymbolPen(self, *args, **kargs): pen = fn.mkPen(*args, **kargs) if self.opts['symbolPen'] == pen: return self.opts['symbolPen'] = pen #self.scatter.setSymbolPen(pen) self.updateItems() def setSymbolBrush(self, *args, **kargs): brush = fn.mkBrush(*args, **kargs) if self.opts['symbolBrush'] == brush: return self.opts['symbolBrush'] = brush #self.scatter.setSymbolBrush(brush) self.updateItems() def setSymbolSize(self, size): if self.opts['symbolSize'] == size: return self.opts['symbolSize'] = size #self.scatter.setSymbolSize(symbolSize) self.updateItems() def setDownsampling(self, ds=None, auto=None, method=None): """ Set the downsampling mode of this item. Downsampling reduces the number of samples drawn to increase performance. ============== ================================================================= **Arguments:** ds (int) Reduce visible plot samples by this factor. To disable, set ds=1. auto (bool) If True, automatically pick *ds* based on visible range mode 'subsample': Downsample by taking the first of N samples. This method is fastest and least accurate. 'mean': Downsample by taking the mean of N samples. 'peak': Downsample by drawing a saw wave that follows the min and max of the original data. This method produces the best visual representation of the data but is slower. ============== ================================================================= """ changed = False if ds is not None: if self.opts['downsample'] != ds: changed = True self.opts['downsample'] = ds if auto is not None and self.opts['autoDownsample'] != auto: self.opts['autoDownsample'] = auto changed = True if method is not None: if self.opts['downsampleMethod'] != method: changed = True self.opts['downsampleMethod'] = method if changed: self.xDisp = self.yDisp = None self.updateItems() def setClipToView(self, clip): if self.opts['clipToView'] == clip: return self.opts['clipToView'] = clip self.xDisp = self.yDisp = None self.updateItems() def setData(self, *args, **kargs): """ Clear any data displayed by this item and display new data. See :func:`__init__() ` for details; it accepts the same arguments. """ #self.clear() profiler = debug.Profiler() y = None x = None if len(args) == 1: data = args[0] dt = dataType(data) if dt == 'empty': pass elif dt == 'listOfValues': y = np.array(data) elif dt == 'Nx2array': x = data[:,0] y = data[:,1] elif dt == 'recarray' or dt == 'dictOfLists': if 'x' in data: x = np.array(data['x']) if 'y' in data: y = np.array(data['y']) elif dt == 'listOfDicts': if 'x' in data[0]: x = np.array([d.get('x',None) for d in data]) if 'y' in data[0]: y = np.array([d.get('y',None) for d in data]) for k in ['data', 'symbolSize', 'symbolPen', 'symbolBrush', 'symbolShape']: if k in data: kargs[k] = [d.get(k, None) for d in data] elif dt == 'MetaArray': y = data.view(np.ndarray) x = data.xvals(0).view(np.ndarray) else: raise Exception('Invalid data type %s' % type(data)) elif len(args) == 2: seq = ('listOfValues', 'MetaArray', 'empty') dtyp = dataType(args[0]), dataType(args[1]) if dtyp[0] not in seq or dtyp[1] not in seq: raise Exception('When passing two unnamed arguments, both must be a list or array of values. (got %s, %s)' % (str(type(args[0])), str(type(args[1])))) if not isinstance(args[0], np.ndarray): #x = np.array(args[0]) if dtyp[0] == 'MetaArray': x = args[0].asarray() else: x = np.array(args[0]) else: x = args[0].view(np.ndarray) if not isinstance(args[1], np.ndarray): #y = np.array(args[1]) if dtyp[1] == 'MetaArray': y = args[1].asarray() else: y = np.array(args[1]) else: y = args[1].view(np.ndarray) if 'x' in kargs: x = kargs['x'] if 'y' in kargs: y = kargs['y'] profiler('interpret data') ## pull in all style arguments. ## Use self.opts to fill in anything not present in kargs. if 'name' in kargs: self.opts['name'] = kargs['name'] if 'connect' in kargs: self.opts['connect'] = kargs['connect'] ## if symbol pen/brush are given with no symbol, then assume symbol is 'o' if 'symbol' not in kargs and ('symbolPen' in kargs or 'symbolBrush' in kargs or 'symbolSize' in kargs): kargs['symbol'] = 'o' if 'brush' in kargs: kargs['fillBrush'] = kargs['brush'] for k in list(self.opts.keys()): if k in kargs: self.opts[k] = kargs[k] #curveArgs = {} #for k in ['pen', 'shadowPen', 'fillLevel', 'brush']: #if k in kargs: #self.opts[k] = kargs[k] #curveArgs[k] = self.opts[k] #scatterArgs = {} #for k,v in [('symbolPen','pen'), ('symbolBrush','brush'), ('symbol','symbol')]: #if k in kargs: #self.opts[k] = kargs[k] #scatterArgs[v] = self.opts[k] if y is None: return if y is not None and x is None: x = np.arange(len(y)) if isinstance(x, list): x = np.array(x) if isinstance(y, list): y = np.array(y) self.xData = x.view(np.ndarray) ## one last check to make sure there are no MetaArrays getting by self.yData = y.view(np.ndarray) self.xClean = self.yClean = None self.xDisp = None self.yDisp = None profiler('set data') self.updateItems() profiler('update items') self.informViewBoundsChanged() #view = self.getViewBox() #if view is not None: #view.itemBoundsChanged(self) ## inform view so it can update its range if it wants self.sigPlotChanged.emit(self) profiler('emit') def updateItems(self): curveArgs = {} for k,v in [('pen','pen'), ('shadowPen','shadowPen'), ('fillLevel','fillLevel'), ('fillBrush', 'brush'), ('antialias', 'antialias'), ('connect', 'connect'), ('stepMode', 'stepMode')]: curveArgs[v] = self.opts[k] scatterArgs = {} for k,v in [('symbolPen','pen'), ('symbolBrush','brush'), ('symbol','symbol'), ('symbolSize', 'size'), ('data', 'data'), ('pxMode', 'pxMode'), ('antialias', 'antialias')]: if k in self.opts: scatterArgs[v] = self.opts[k] x,y = self.getData() #scatterArgs['mask'] = self.dataMask if curveArgs['pen'] is not None or (curveArgs['brush'] is not None and curveArgs['fillLevel'] is not None): self.curve.setData(x=x, y=y, **curveArgs) self.curve.show() else: self.curve.hide() if scatterArgs['symbol'] is not None: self.scatter.setData(x=x, y=y, **scatterArgs) self.scatter.show() else: self.scatter.hide() def getData(self): if self.xData is None: return (None, None) #if self.xClean is None: #nanMask = np.isnan(self.xData) | np.isnan(self.yData) | np.isinf(self.xData) | np.isinf(self.yData) #if nanMask.any(): #self.dataMask = ~nanMask #self.xClean = self.xData[self.dataMask] #self.yClean = self.yData[self.dataMask] #else: #self.dataMask = None #self.xClean = self.xData #self.yClean = self.yData if self.xDisp is None: x = self.xData y = self.yData #ds = self.opts['downsample'] #if isinstance(ds, int) and ds > 1: #x = x[::ds] ##y = resample(y[:len(x)*ds], len(x)) ## scipy.signal.resample causes nasty ringing #y = y[::ds] if self.opts['fftMode']: x,y = self._fourierTransform(x, y) # Ignore the first bin for fft data if we have a logx scale if self.opts['logMode'][0]: x=x[1:] y=y[1:] if self.opts['logMode'][0]: x = np.log10(x) if self.opts['logMode'][1]: y = np.log10(y) #if any(self.opts['logMode']): ## re-check for NANs after log #nanMask = np.isinf(x) | np.isinf(y) | np.isnan(x) | np.isnan(y) #if any(nanMask): #self.dataMask = ~nanMask #x = x[self.dataMask] #y = y[self.dataMask] #else: #self.dataMask = None ds = self.opts['downsample'] if not isinstance(ds, int): ds = 1 if self.opts['autoDownsample']: # this option presumes that x-values have uniform spacing range = self.viewRect() if range is not None: dx = float(x[-1]-x[0]) / (len(x)-1) x0 = (range.left()-x[0]) / dx x1 = (range.right()-x[0]) / dx width = self.getViewBox().width() if width != 0.0: ds = int(max(1, int((x1-x0) / (width*self.opts['autoDownsampleFactor'])))) ## downsampling is expensive; delay until after clipping. if self.opts['clipToView']: view = self.getViewBox() if view is None or not view.autoRangeEnabled()[0]: # this option presumes that x-values have uniform spacing range = self.viewRect() if range is not None and len(x) > 1: dx = float(x[-1]-x[0]) / (len(x)-1) # clip to visible region extended by downsampling value x0 = np.clip(int((range.left()-x[0])/dx)-1*ds , 0, len(x)-1) x1 = np.clip(int((range.right()-x[0])/dx)+2*ds , 0, len(x)-1) x = x[x0:x1] y = y[x0:x1] if ds > 1: if self.opts['downsampleMethod'] == 'subsample': x = x[::ds] y = y[::ds] elif self.opts['downsampleMethod'] == 'mean': n = len(x) // ds x = x[:n*ds:ds] y = y[:n*ds].reshape(n,ds).mean(axis=1) elif self.opts['downsampleMethod'] == 'peak': n = len(x) // ds x1 = np.empty((n,2)) x1[:] = x[:n*ds:ds,np.newaxis] x = x1.reshape(n*2) y1 = np.empty((n,2)) y2 = y[:n*ds].reshape((n, ds)) y1[:,0] = y2.max(axis=1) y1[:,1] = y2.min(axis=1) y = y1.reshape(n*2) self.xDisp = x self.yDisp = y #print self.yDisp.shape, self.yDisp.min(), self.yDisp.max() #print self.xDisp.shape, self.xDisp.min(), self.xDisp.max() return self.xDisp, self.yDisp def dataBounds(self, ax, frac=1.0, orthoRange=None): """ Returns the range occupied by the data (along a specific axis) in this item. This method is called by ViewBox when auto-scaling. =============== ============================================================= **Arguments:** ax (0 or 1) the axis for which to return this item's data range frac (float 0.0-1.0) Specifies what fraction of the total data range to return. By default, the entire range is returned. This allows the ViewBox to ignore large spikes in the data when auto-scaling. orthoRange ([min,max] or None) Specifies that only the data within the given range (orthogonal to *ax*) should me measured when returning the data range. (For example, a ViewBox might ask what is the y-range of all data with x-values between min and max) =============== ============================================================= """ range = [None, None] if self.curve.isVisible(): range = self.curve.dataBounds(ax, frac, orthoRange) elif self.scatter.isVisible(): r2 = self.scatter.dataBounds(ax, frac, orthoRange) range = [ r2[0] if range[0] is None else (range[0] if r2[0] is None else min(r2[0], range[0])), r2[1] if range[1] is None else (range[1] if r2[1] is None else min(r2[1], range[1])) ] return range def pixelPadding(self): """ Return the size in pixels that this item may draw beyond the values returned by dataBounds(). This method is called by ViewBox when auto-scaling. """ pad = 0 if self.curve.isVisible(): pad = max(pad, self.curve.pixelPadding()) elif self.scatter.isVisible(): pad = max(pad, self.scatter.pixelPadding()) return pad def clear(self): #for i in self.curves+self.scatters: #if i.scene() is not None: #i.scene().removeItem(i) #self.curves = [] #self.scatters = [] self.xData = None self.yData = None #self.xClean = None #self.yClean = None self.xDisp = None self.yDisp = None self.curve.setData([]) self.scatter.setData([]) def appendData(self, *args, **kargs): pass def curveClicked(self): self.sigClicked.emit(self) def scatterClicked(self, plt, points): self.sigClicked.emit(self) self.sigPointsClicked.emit(self, points) def viewRangeChanged(self): # view range has changed; re-plot if needed if self.opts['clipToView'] or self.opts['autoDownsample']: self.xDisp = self.yDisp = None self.updateItems() def _fourierTransform(self, x, y): ## Perform fourier transform. If x values are not sampled uniformly, ## then use np.interp to resample before taking fft. dx = np.diff(x) uniform = not np.any(np.abs(dx-dx[0]) > (abs(dx[0]) / 1000.)) if not uniform: x2 = np.linspace(x[0], x[-1], len(x)) y = np.interp(x2, x, y) x = x2 f = np.fft.fft(y) / len(y) y = abs(f[1:len(f)/2]) dt = x[-1] - x[0] x = np.linspace(0, 0.5*len(x)/dt, len(y)) return x, y def dataType(obj): if hasattr(obj, '__len__') and len(obj) == 0: return 'empty' if isinstance(obj, dict): return 'dictOfLists' elif isSequence(obj): first = obj[0] if (hasattr(obj, 'implements') and obj.implements('MetaArray')): return 'MetaArray' elif isinstance(obj, np.ndarray): if obj.ndim == 1: if obj.dtype.names is None: return 'listOfValues' else: return 'recarray' elif obj.ndim == 2 and obj.dtype.names is None and obj.shape[1] == 2: return 'Nx2array' else: raise Exception('array shape must be (N,) or (N,2); got %s instead' % str(obj.shape)) elif isinstance(first, dict): return 'listOfDicts' else: return 'listOfValues' def isSequence(obj): return hasattr(obj, '__iter__') or isinstance(obj, np.ndarray) or (hasattr(obj, 'implements') and obj.implements('MetaArray')) #class TableData: #""" #Class for presenting multiple forms of tabular data through a consistent interface. #May contain: #- numpy record array #- list-of-dicts (all dicts are _not_ required to have the same keys) #- dict-of-lists #- dict (single record) #Note: if all the values in this record are lists, it will be interpreted as multiple records #Data can be accessed and modified by column, by row, or by value #data[columnName] #data[rowId] #data[columnName, rowId] = value #data[columnName] = [value, value, ...] #data[rowId] = {columnName: value, ...} #""" #def __init__(self, data): #self.data = data #if isinstance(data, np.ndarray): #self.mode = 'array' #elif isinstance(data, list): #self.mode = 'list' #elif isinstance(data, dict): #types = set(map(type, data.values())) ### dict may be a dict-of-lists or a single record #types -= set([list, np.ndarray]) ## if dict contains any non-sequence values, it is probably a single record. #if len(types) != 0: #self.data = [self.data] #self.mode = 'list' #else: #self.mode = 'dict' #elif isinstance(data, TableData): #self.data = data.data #self.mode = data.mode #else: #raise TypeError(type(data)) #for fn in ['__getitem__', '__setitem__']: #setattr(self, fn, getattr(self, '_TableData'+fn+self.mode)) #def originalData(self): #return self.data #def toArray(self): #if self.mode == 'array': #return self.data #if len(self) < 1: ##return np.array([]) ## need to return empty array *with correct columns*, but this is very difficult, so just return None #return None #rec1 = self[0] #dtype = functions.suggestRecordDType(rec1) ##print rec1, dtype #arr = np.empty(len(self), dtype=dtype) #arr[0] = tuple(rec1.values()) #for i in xrange(1, len(self)): #arr[i] = tuple(self[i].values()) #return arr #def __getitem__array(self, arg): #if isinstance(arg, tuple): #return self.data[arg[0]][arg[1]] #else: #return self.data[arg] #def __getitem__list(self, arg): #if isinstance(arg, basestring): #return [d.get(arg, None) for d in self.data] #elif isinstance(arg, int): #return self.data[arg] #elif isinstance(arg, tuple): #arg = self._orderArgs(arg) #return self.data[arg[0]][arg[1]] #else: #raise TypeError(type(arg)) #def __getitem__dict(self, arg): #if isinstance(arg, basestring): #return self.data[arg] #elif isinstance(arg, int): #return dict([(k, v[arg]) for k, v in self.data.iteritems()]) #elif isinstance(arg, tuple): #arg = self._orderArgs(arg) #return self.data[arg[1]][arg[0]] #else: #raise TypeError(type(arg)) #def __setitem__array(self, arg, val): #if isinstance(arg, tuple): #self.data[arg[0]][arg[1]] = val #else: #self.data[arg] = val #def __setitem__list(self, arg, val): #if isinstance(arg, basestring): #if len(val) != len(self.data): #raise Exception("Values (%d) and data set (%d) are not the same length." % (len(val), len(self.data))) #for i, rec in enumerate(self.data): #rec[arg] = val[i] #elif isinstance(arg, int): #self.data[arg] = val #elif isinstance(arg, tuple): #arg = self._orderArgs(arg) #self.data[arg[0]][arg[1]] = val #else: #raise TypeError(type(arg)) #def __setitem__dict(self, arg, val): #if isinstance(arg, basestring): #if len(val) != len(self.data[arg]): #raise Exception("Values (%d) and data set (%d) are not the same length." % (len(val), len(self.data[arg]))) #self.data[arg] = val #elif isinstance(arg, int): #for k in self.data: #self.data[k][arg] = val[k] #elif isinstance(arg, tuple): #arg = self._orderArgs(arg) #self.data[arg[1]][arg[0]] = val #else: #raise TypeError(type(arg)) #def _orderArgs(self, args): ### return args in (int, str) order #if isinstance(args[0], basestring): #return (args[1], args[0]) #else: #return args #def __iter__(self): #for i in xrange(len(self)): #yield self[i] #def __len__(self): #if self.mode == 'array' or self.mode == 'list': #return len(self.data) #else: #return max(map(len, self.data.values())) #def columnNames(self): #"""returns column names in no particular order""" #if self.mode == 'array': #return self.data.dtype.names #elif self.mode == 'list': #names = set() #for row in self.data: #names.update(row.keys()) #return list(names) #elif self.mode == 'dict': #return self.data.keys() #def keys(self): #return self.columnNames() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/PlotItem/000077500000000000000000000000001300727121400241775ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/PlotItem/PlotItem.py000066400000000000000000001341411300727121400263120ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ PlotItem.py - Graphics item implementing a scalable ViewBox with plotting powers. Copyright 2010 Luke Campagnola Distributed under MIT/X11 license. See license.txt for more infomation. This class is one of the workhorses of pyqtgraph. It implements a graphics item with plots, labels, and scales which can be viewed inside a QGraphicsScene. If you want a widget that can be added to your GUI, see PlotWidget instead. This class is very heavily featured: - Automatically creates and manages PlotCurveItems - Fast display and update of plots - Manages zoom/pan ViewBox, scale, and label elements - Automatic scaling when data changes - Control panel with a huge feature set including averaging, decimation, display, power spectrum, svg/png export, plot linking, and more. """ import sys import weakref import numpy as np import os from ...Qt import QtGui, QtCore, QT_LIB from ... import pixmaps from ... import functions as fn from ...widgets.FileDialog import FileDialog from .. PlotDataItem import PlotDataItem from .. ViewBox import ViewBox from .. AxisItem import AxisItem from .. LabelItem import LabelItem from .. LegendItem import LegendItem from .. GraphicsWidget import GraphicsWidget from .. ButtonItem import ButtonItem from .. InfiniteLine import InfiniteLine from ...WidgetGroup import WidgetGroup from ...python2_3 import basestring if QT_LIB == 'PyQt4': from .plotConfigTemplate_pyqt import * elif QT_LIB == 'PySide': from .plotConfigTemplate_pyside import * elif QT_LIB == 'PyQt5': from .plotConfigTemplate_pyqt5 import * __all__ = ['PlotItem'] try: from metaarray import * HAVE_METAARRAY = True except: HAVE_METAARRAY = False class PlotItem(GraphicsWidget): """ **Bases:** :class:`GraphicsWidget ` Plot graphics item that can be added to any graphics scene. Implements axes, titles, and interactive viewbox. PlotItem also provides some basic analysis functionality that may be accessed from the context menu. Use :func:`plot() ` to create a new PlotDataItem and add it to the view. Use :func:`addItem() ` to add any QGraphicsItem to the view. This class wraps several methods from its internal ViewBox: :func:`setXRange `, :func:`setYRange `, :func:`setRange `, :func:`autoRange `, :func:`setXLink `, :func:`setYLink `, :func:`setAutoPan `, :func:`setAutoVisible `, :func:`setLimits `, :func:`viewRect `, :func:`viewRange `, :func:`setMouseEnabled `, :func:`enableAutoRange `, :func:`disableAutoRange `, :func:`setAspectLocked `, :func:`invertY `, :func:`invertX `, :func:`register `, :func:`unregister ` The ViewBox itself can be accessed by calling :func:`getViewBox() ` ==================== ======================================================================= **Signals:** sigYRangeChanged wrapped from :class:`ViewBox ` sigXRangeChanged wrapped from :class:`ViewBox ` sigRangeChanged wrapped from :class:`ViewBox ` ==================== ======================================================================= """ sigRangeChanged = QtCore.Signal(object, object) ## Emitted when the ViewBox range has changed sigYRangeChanged = QtCore.Signal(object, object) ## Emitted when the ViewBox Y range has changed sigXRangeChanged = QtCore.Signal(object, object) ## Emitted when the ViewBox X range has changed lastFileDir = None def __init__(self, parent=None, name=None, labels=None, title=None, viewBox=None, axisItems=None, enableMenu=True, **kargs): """ Create a new PlotItem. All arguments are optional. Any extra keyword arguments are passed to PlotItem.plot(). ============== ========================================================================================== **Arguments:** *title* Title to display at the top of the item. Html is allowed. *labels* A dictionary specifying the axis labels to display:: {'left': (args), 'bottom': (args), ...} The name of each axis and the corresponding arguments are passed to :func:`PlotItem.setLabel() ` Optionally, PlotItem my also be initialized with the keyword arguments left, right, top, or bottom to achieve the same effect. *name* Registers a name for this view so that others may link to it *viewBox* If specified, the PlotItem will be constructed with this as its ViewBox. *axisItems* Optional dictionary instructing the PlotItem to use pre-constructed items for its axes. The dict keys must be axis names ('left', 'bottom', 'right', 'top') and the values must be instances of AxisItem (or at least compatible with AxisItem). ============== ========================================================================================== """ GraphicsWidget.__init__(self, parent) self.setSizePolicy(QtGui.QSizePolicy.Expanding, QtGui.QSizePolicy.Expanding) ## Set up control buttons path = os.path.dirname(__file__) #self.autoImageFile = os.path.join(path, 'auto.png') #self.lockImageFile = os.path.join(path, 'lock.png') self.autoBtn = ButtonItem(pixmaps.getPixmap('auto'), 14, self) self.autoBtn.mode = 'auto' self.autoBtn.clicked.connect(self.autoBtnClicked) #self.autoBtn.hide() self.buttonsHidden = False ## whether the user has requested buttons to be hidden self.mouseHovering = False self.layout = QtGui.QGraphicsGridLayout() self.layout.setContentsMargins(1,1,1,1) self.setLayout(self.layout) self.layout.setHorizontalSpacing(0) self.layout.setVerticalSpacing(0) if viewBox is None: viewBox = ViewBox(parent=self) self.vb = viewBox self.vb.sigStateChanged.connect(self.viewStateChanged) self.setMenuEnabled(enableMenu, enableMenu) ## en/disable plotitem and viewbox menus if name is not None: self.vb.register(name) self.vb.sigRangeChanged.connect(self.sigRangeChanged) self.vb.sigXRangeChanged.connect(self.sigXRangeChanged) self.vb.sigYRangeChanged.connect(self.sigYRangeChanged) self.layout.addItem(self.vb, 2, 1) self.alpha = 1.0 self.autoAlpha = True self.spectrumMode = False self.legend = None ## Create and place axis items if axisItems is None: axisItems = {} self.axes = {} for k, pos in (('top', (1,1)), ('bottom', (3,1)), ('left', (2,0)), ('right', (2,2))): if k in axisItems: axis = axisItems[k] else: axis = AxisItem(orientation=k, parent=self) axis.linkToView(self.vb) self.axes[k] = {'item': axis, 'pos': pos} self.layout.addItem(axis, *pos) axis.setZValue(-1000) axis.setFlag(axis.ItemNegativeZStacksBehindParent) self.titleLabel = LabelItem('', size='11pt', parent=self) self.layout.addItem(self.titleLabel, 0, 1) self.setTitle(None) ## hide for i in range(4): self.layout.setRowPreferredHeight(i, 0) self.layout.setRowMinimumHeight(i, 0) self.layout.setRowSpacing(i, 0) self.layout.setRowStretchFactor(i, 1) for i in range(3): self.layout.setColumnPreferredWidth(i, 0) self.layout.setColumnMinimumWidth(i, 0) self.layout.setColumnSpacing(i, 0) self.layout.setColumnStretchFactor(i, 1) self.layout.setRowStretchFactor(2, 100) self.layout.setColumnStretchFactor(1, 100) self.items = [] self.curves = [] self.itemMeta = weakref.WeakKeyDictionary() self.dataItems = [] self.paramList = {} self.avgCurves = {} ### Set up context menu w = QtGui.QWidget() self.ctrl = c = Ui_Form() c.setupUi(w) dv = QtGui.QDoubleValidator(self) menuItems = [ ('Transforms', c.transformGroup), ('Downsample', c.decimateGroup), ('Average', c.averageGroup), ('Alpha', c.alphaGroup), ('Grid', c.gridGroup), ('Points', c.pointsGroup), ] self.ctrlMenu = QtGui.QMenu() self.ctrlMenu.setTitle('Plot Options') self.subMenus = [] for name, grp in menuItems: sm = QtGui.QMenu(name) act = QtGui.QWidgetAction(self) act.setDefaultWidget(grp) sm.addAction(act) self.subMenus.append(sm) self.ctrlMenu.addMenu(sm) self.stateGroup = WidgetGroup() for name, w in menuItems: self.stateGroup.autoAdd(w) self.fileDialog = None c.alphaGroup.toggled.connect(self.updateAlpha) c.alphaSlider.valueChanged.connect(self.updateAlpha) c.autoAlphaCheck.toggled.connect(self.updateAlpha) c.xGridCheck.toggled.connect(self.updateGrid) c.yGridCheck.toggled.connect(self.updateGrid) c.gridAlphaSlider.valueChanged.connect(self.updateGrid) c.fftCheck.toggled.connect(self.updateSpectrumMode) c.logXCheck.toggled.connect(self.updateLogMode) c.logYCheck.toggled.connect(self.updateLogMode) c.downsampleSpin.valueChanged.connect(self.updateDownsampling) c.downsampleCheck.toggled.connect(self.updateDownsampling) c.autoDownsampleCheck.toggled.connect(self.updateDownsampling) c.subsampleRadio.toggled.connect(self.updateDownsampling) c.meanRadio.toggled.connect(self.updateDownsampling) c.clipToViewCheck.toggled.connect(self.updateDownsampling) self.ctrl.avgParamList.itemClicked.connect(self.avgParamListClicked) self.ctrl.averageGroup.toggled.connect(self.avgToggled) self.ctrl.maxTracesCheck.toggled.connect(self.updateDecimation) self.ctrl.maxTracesSpin.valueChanged.connect(self.updateDecimation) self.hideAxis('right') self.hideAxis('top') self.showAxis('left') self.showAxis('bottom') if labels is None: labels = {} for label in list(self.axes.keys()): if label in kargs: labels[label] = kargs[label] del kargs[label] for k in labels: if isinstance(labels[k], basestring): labels[k] = (labels[k],) self.setLabel(k, *labels[k]) if title is not None: self.setTitle(title) if len(kargs) > 0: self.plot(**kargs) def implements(self, interface=None): return interface in ['ViewBoxWrapper'] def getViewBox(self): """Return the :class:`ViewBox ` contained within.""" return self.vb ## Wrap a few methods from viewBox. #Important: don't use a settattr(m, getattr(self.vb, m)) as we'd be leaving the viebox alive #because we had a reference to an instance method (creating wrapper methods at runtime instead). for m in ['setXRange', 'setYRange', 'setXLink', 'setYLink', 'setAutoPan', # NOTE: 'setAutoVisible', 'setRange', 'autoRange', 'viewRect', 'viewRange', # If you update this list, please 'setMouseEnabled', 'setLimits', 'enableAutoRange', 'disableAutoRange', # update the class docstring 'setAspectLocked', 'invertY', 'invertX', 'register', 'unregister']: # as well. def _create_method(name): def method(self, *args, **kwargs): return getattr(self.vb, name)(*args, **kwargs) method.__name__ = name return method locals()[m] = _create_method(m) del _create_method def setLogMode(self, x=None, y=None): """ Set log scaling for x and/or y axes. This informs PlotDataItems to transform logarithmically and switches the axes to use log ticking. Note that *no other items* in the scene will be affected by this; there is (currently) no generic way to redisplay a GraphicsItem with log coordinates. """ if x is not None: self.ctrl.logXCheck.setChecked(x) if y is not None: self.ctrl.logYCheck.setChecked(y) def showGrid(self, x=None, y=None, alpha=None): """ Show or hide the grid for either axis. ============== ===================================== **Arguments:** x (bool) Whether to show the X grid y (bool) Whether to show the Y grid alpha (0.0-1.0) Opacity of the grid ============== ===================================== """ if x is None and y is None and alpha is None: raise Exception("Must specify at least one of x, y, or alpha.") ## prevent people getting confused if they just call showGrid() if x is not None: self.ctrl.xGridCheck.setChecked(x) if y is not None: self.ctrl.yGridCheck.setChecked(y) if alpha is not None: v = np.clip(alpha, 0, 1)*self.ctrl.gridAlphaSlider.maximum() self.ctrl.gridAlphaSlider.setValue(v) #def paint(self, *args): #prof = debug.Profiler() #QtGui.QGraphicsWidget.paint(self, *args) ## bad idea. #def __getattr__(self, attr): ## wrap ms #return getattr(self.vb, attr) def close(self): #print "delete", self ## Most of this crap is needed to avoid PySide trouble. ## The problem seems to be whenever scene.clear() leads to deletion of widgets (either through proxies or qgraphicswidgets) ## the solution is to manually remove all widgets before scene.clear() is called if self.ctrlMenu is None: ## already shut down return self.ctrlMenu.setParent(None) self.ctrlMenu = None self.autoBtn.setParent(None) self.autoBtn = None for k in self.axes: i = self.axes[k]['item'] i.close() self.axes = None self.scene().removeItem(self.vb) self.vb = None def registerPlot(self, name): ## for backward compatibility self.vb.register(name) def updateGrid(self, *args): alpha = self.ctrl.gridAlphaSlider.value() x = alpha if self.ctrl.xGridCheck.isChecked() else False y = alpha if self.ctrl.yGridCheck.isChecked() else False self.getAxis('top').setGrid(x) self.getAxis('bottom').setGrid(x) self.getAxis('left').setGrid(y) self.getAxis('right').setGrid(y) def viewGeometry(self): """Return the screen geometry of the viewbox""" v = self.scene().views()[0] b = self.vb.mapRectToScene(self.vb.boundingRect()) wr = v.mapFromScene(b).boundingRect() pos = v.mapToGlobal(v.pos()) wr.adjust(pos.x(), pos.y(), pos.x(), pos.y()) return wr def avgToggled(self, b): if b: self.recomputeAverages() for k in self.avgCurves: self.avgCurves[k][1].setVisible(b) def avgParamListClicked(self, item): name = str(item.text()) self.paramList[name] = (item.checkState() == QtCore.Qt.Checked) self.recomputeAverages() def recomputeAverages(self): if not self.ctrl.averageGroup.isChecked(): return for k in self.avgCurves: self.removeItem(self.avgCurves[k][1]) self.avgCurves = {} for c in self.curves: self.addAvgCurve(c) self.replot() def addAvgCurve(self, curve): ## Add a single curve into the pool of curves averaged together ## If there are plot parameters, then we need to determine which to average together. remKeys = [] addKeys = [] if self.ctrl.avgParamList.count() > 0: ### First determine the key of the curve to which this new data should be averaged for i in range(self.ctrl.avgParamList.count()): item = self.ctrl.avgParamList.item(i) if item.checkState() == QtCore.Qt.Checked: remKeys.append(str(item.text())) else: addKeys.append(str(item.text())) if len(remKeys) < 1: ## In this case, there would be 1 average plot for each data plot; not useful. return p = self.itemMeta.get(curve,{}).copy() for k in p: if type(k) is tuple: p['.'.join(k)] = p[k] del p[k] for rk in remKeys: if rk in p: del p[rk] for ak in addKeys: if ak not in p: p[ak] = None key = tuple(p.items()) ### Create a new curve if needed if key not in self.avgCurves: plot = PlotDataItem() plot.setPen(fn.mkPen([0, 200, 0])) plot.setShadowPen(fn.mkPen([0, 0, 0, 100], width=3)) plot.setAlpha(1.0, False) plot.setZValue(100) self.addItem(plot, skipAverage=True) self.avgCurves[key] = [0, plot] self.avgCurves[key][0] += 1 (n, plot) = self.avgCurves[key] ### Average data together (x, y) = curve.getData() stepMode = curve.opts['stepMode'] if plot.yData is not None and y.shape == plot.yData.shape: # note that if shapes do not match, then the average resets. newData = plot.yData * (n-1) / float(n) + y * 1.0 / float(n) plot.setData(plot.xData, newData, stepMode=stepMode) else: plot.setData(x, y, stepMode=stepMode) def autoBtnClicked(self): if self.autoBtn.mode == 'auto': self.enableAutoRange() self.autoBtn.hide() else: self.disableAutoRange() def viewStateChanged(self): self.updateButtons() def enableAutoScale(self): """ Enable auto-scaling. The plot will continuously scale to fit the boundaries of its data. """ print("Warning: enableAutoScale is deprecated. Use enableAutoRange(axis, enable) instead.") self.vb.enableAutoRange(self.vb.XYAxes) def addItem(self, item, *args, **kargs): """ Add a graphics item to the view box. If the item has plot data (PlotDataItem, PlotCurveItem, ScatterPlotItem), it may be included in analysis performed by the PlotItem. """ self.items.append(item) vbargs = {} if 'ignoreBounds' in kargs: vbargs['ignoreBounds'] = kargs['ignoreBounds'] self.vb.addItem(item, *args, **vbargs) name = None if hasattr(item, 'implements') and item.implements('plotData'): name = item.name() self.dataItems.append(item) #self.plotChanged() params = kargs.get('params', {}) self.itemMeta[item] = params #item.setMeta(params) self.curves.append(item) #self.addItem(c) if hasattr(item, 'setLogMode'): item.setLogMode(self.ctrl.logXCheck.isChecked(), self.ctrl.logYCheck.isChecked()) if isinstance(item, PlotDataItem): ## configure curve for this plot (alpha, auto) = self.alphaState() item.setAlpha(alpha, auto) item.setFftMode(self.ctrl.fftCheck.isChecked()) item.setDownsampling(*self.downsampleMode()) item.setClipToView(self.clipToViewMode()) item.setPointMode(self.pointMode()) ## Hide older plots if needed self.updateDecimation() ## Add to average if needed self.updateParamList() if self.ctrl.averageGroup.isChecked() and 'skipAverage' not in kargs: self.addAvgCurve(item) #c.connect(c, QtCore.SIGNAL('plotChanged'), self.plotChanged) #item.sigPlotChanged.connect(self.plotChanged) #self.plotChanged() #name = kargs.get('name', getattr(item, 'opts', {}).get('name', None)) if name is not None and hasattr(self, 'legend') and self.legend is not None: self.legend.addItem(item, name=name) def addDataItem(self, item, *args): print("PlotItem.addDataItem is deprecated. Use addItem instead.") self.addItem(item, *args) def listDataItems(self): """Return a list of all data items (PlotDataItem, PlotCurveItem, ScatterPlotItem, etc) contained in this PlotItem.""" return self.dataItems[:] def addCurve(self, c, params=None): print("PlotItem.addCurve is deprecated. Use addItem instead.") self.addItem(c, params) def addLine(self, x=None, y=None, z=None, **kwds): """ Create an InfiniteLine and add to the plot. If *x* is specified, the line will be vertical. If *y* is specified, the line will be horizontal. All extra keyword arguments are passed to :func:`InfiniteLine.__init__() `. Returns the item created. """ pos = kwds.get('pos', x if x is not None else y) angle = kwds.get('angle', 0 if x is None else 90) line = InfiniteLine(pos, angle, **kwds) self.addItem(line) if z is not None: line.setZValue(z) return line def removeItem(self, item): """ Remove an item from the internal ViewBox. """ if not item in self.items: return self.items.remove(item) if item in self.dataItems: self.dataItems.remove(item) if item.scene() is not None: self.vb.removeItem(item) if item in self.curves: self.curves.remove(item) self.updateDecimation() self.updateParamList() #item.connect(item, QtCore.SIGNAL('plotChanged'), self.plotChanged) #item.sigPlotChanged.connect(self.plotChanged) def clear(self): """ Remove all items from the ViewBox. """ for i in self.items[:]: self.removeItem(i) self.avgCurves = {} def clearPlots(self): for i in self.curves[:]: self.removeItem(i) self.avgCurves = {} def plot(self, *args, **kargs): """ Add and return a new plot. See :func:`PlotDataItem.__init__ ` for data arguments Extra allowed arguments are: clear - clear all plots before displaying new data params - meta-parameters to associate with this data """ clear = kargs.get('clear', False) params = kargs.get('params', None) if clear: self.clear() item = PlotDataItem(*args, **kargs) if params is None: params = {} self.addItem(item, params=params) return item def addLegend(self, size=None, offset=(30, 30)): """ Create a new LegendItem and anchor it over the internal ViewBox. Plots will be automatically displayed in the legend if they are created with the 'name' argument. """ self.legend = LegendItem(size, offset) self.legend.setParentItem(self.vb) return self.legend def scatterPlot(self, *args, **kargs): if 'pen' in kargs: kargs['symbolPen'] = kargs['pen'] kargs['pen'] = None if 'brush' in kargs: kargs['symbolBrush'] = kargs['brush'] del kargs['brush'] if 'size' in kargs: kargs['symbolSize'] = kargs['size'] del kargs['size'] return self.plot(*args, **kargs) def replot(self): self.update() def updateParamList(self): self.ctrl.avgParamList.clear() ## Check to see that each parameter for each curve is present in the list for c in self.curves: for p in list(self.itemMeta.get(c, {}).keys()): if type(p) is tuple: p = '.'.join(p) ## If the parameter is not in the list, add it. matches = self.ctrl.avgParamList.findItems(p, QtCore.Qt.MatchExactly) if len(matches) == 0: i = QtGui.QListWidgetItem(p) if p in self.paramList and self.paramList[p] is True: i.setCheckState(QtCore.Qt.Checked) else: i.setCheckState(QtCore.Qt.Unchecked) self.ctrl.avgParamList.addItem(i) else: i = matches[0] self.paramList[p] = (i.checkState() == QtCore.Qt.Checked) ## Qt's SVG-writing capabilities are pretty terrible. def writeSvgCurves(self, fileName=None): if fileName is None: self.fileDialog = FileDialog() if PlotItem.lastFileDir is not None: self.fileDialog.setDirectory(PlotItem.lastFileDir) self.fileDialog.setFileMode(QtGui.QFileDialog.AnyFile) self.fileDialog.setAcceptMode(QtGui.QFileDialog.AcceptSave) self.fileDialog.show() self.fileDialog.fileSelected.connect(self.writeSvg) return #if fileName is None: #fileName = QtGui.QFileDialog.getSaveFileName() if isinstance(fileName, tuple): raise Exception("Not implemented yet..") fileName = str(fileName) PlotItem.lastFileDir = os.path.dirname(fileName) rect = self.vb.viewRect() xRange = rect.left(), rect.right() svg = "" fh = open(fileName, 'w') dx = max(rect.right(),0) - min(rect.left(),0) ymn = min(rect.top(), rect.bottom()) ymx = max(rect.top(), rect.bottom()) dy = max(ymx,0) - min(ymn,0) sx = 1. sy = 1. while dx*sx < 10: sx *= 1000 while dy*sy < 10: sy *= 1000 sy *= -1 #fh.write('\n' % (rect.left()*sx, rect.top()*sx, rect.width()*sy, rect.height()*sy)) fh.write('\n') fh.write('\n' % (rect.left()*sx, rect.right()*sx)) fh.write('\n' % (rect.top()*sy, rect.bottom()*sy)) for item in self.curves: if isinstance(item, PlotCurveItem): color = fn.colorStr(item.pen.color()) opacity = item.pen.color().alpha() / 255. color = color[:6] x, y = item.getData() mask = (x > xRange[0]) * (x < xRange[1]) mask[:-1] += mask[1:] m2 = mask.copy() mask[1:] += m2[:-1] x = x[mask] y = y[mask] x *= sx y *= sy #fh.write('\n' % color) fh.write('') #fh.write("") for item in self.dataItems: if isinstance(item, ScatterPlotItem): pRect = item.boundingRect() vRect = pRect.intersected(rect) for point in item.points(): pos = point.pos() if not rect.contains(pos): continue color = fn.colorStr(point.brush.color()) opacity = point.brush.color().alpha() / 255. color = color[:6] x = pos.x() * sx y = pos.y() * sy fh.write('\n' % (x, y, color, opacity)) fh.write("\n") def writeSvg(self, fileName=None): if fileName is None: fileName = QtGui.QFileDialog.getSaveFileName() fileName = str(fileName) PlotItem.lastFileDir = os.path.dirname(fileName) from ...exporters import SVGExporter ex = SVGExporter(self) ex.export(fileName) def writeImage(self, fileName=None): if fileName is None: self.fileDialog = FileDialog() if PlotItem.lastFileDir is not None: self.fileDialog.setDirectory(PlotItem.lastFileDir) self.fileDialog.setFileMode(QtGui.QFileDialog.AnyFile) self.fileDialog.setAcceptMode(QtGui.QFileDialog.AcceptSave) self.fileDialog.show() self.fileDialog.fileSelected.connect(self.writeImage) return #if fileName is None: #fileName = QtGui.QFileDialog.getSaveFileName() if isinstance(fileName, tuple): raise Exception("Not implemented yet..") fileName = str(fileName) PlotItem.lastFileDir = os.path.dirname(fileName) self.png = QtGui.QImage(int(self.size().width()), int(self.size().height()), QtGui.QImage.Format_ARGB32) painter = QtGui.QPainter(self.png) painter.setRenderHints(painter.Antialiasing | painter.TextAntialiasing) self.scene().render(painter, QtCore.QRectF(), self.mapRectToScene(self.boundingRect())) painter.end() self.png.save(fileName) def writeCsv(self, fileName=None): if fileName is None: self.fileDialog = FileDialog() if PlotItem.lastFileDir is not None: self.fileDialog.setDirectory(PlotItem.lastFileDir) self.fileDialog.setFileMode(QtGui.QFileDialog.AnyFile) self.fileDialog.setAcceptMode(QtGui.QFileDialog.AcceptSave) self.fileDialog.show() self.fileDialog.fileSelected.connect(self.writeCsv) return #if fileName is None: #fileName = QtGui.QFileDialog.getSaveFileName() fileName = str(fileName) PlotItem.lastFileDir = os.path.dirname(fileName) fd = open(fileName, 'w') data = [c.getData() for c in self.curves] i = 0 while True: done = True for d in data: if i < len(d[0]): fd.write('%g,%g,'%(d[0][i], d[1][i])) done = False else: fd.write(' , ,') fd.write('\n') if done: break i += 1 fd.close() def saveState(self): state = self.stateGroup.state() state['paramList'] = self.paramList.copy() state['view'] = self.vb.getState() return state def restoreState(self, state): if 'paramList' in state: self.paramList = state['paramList'].copy() self.stateGroup.setState(state) self.updateSpectrumMode() self.updateDownsampling() self.updateAlpha() self.updateDecimation() if 'powerSpectrumGroup' in state: state['fftCheck'] = state['powerSpectrumGroup'] if 'gridGroup' in state: state['xGridCheck'] = state['gridGroup'] state['yGridCheck'] = state['gridGroup'] self.stateGroup.setState(state) self.updateParamList() if 'view' not in state: r = [[float(state['xMinText']), float(state['xMaxText'])], [float(state['yMinText']), float(state['yMaxText'])]] state['view'] = { 'autoRange': [state['xAutoRadio'], state['yAutoRadio']], 'linkedViews': [state['xLinkCombo'], state['yLinkCombo']], 'targetRange': r, 'viewRange': r, } self.vb.setState(state['view']) def widgetGroupInterface(self): return (None, PlotItem.saveState, PlotItem.restoreState) def updateSpectrumMode(self, b=None): if b is None: b = self.ctrl.fftCheck.isChecked() for c in self.curves: c.setFftMode(b) self.enableAutoRange() self.recomputeAverages() def updateLogMode(self): x = self.ctrl.logXCheck.isChecked() y = self.ctrl.logYCheck.isChecked() for i in self.items: if hasattr(i, 'setLogMode'): i.setLogMode(x,y) self.getAxis('bottom').setLogMode(x) self.getAxis('top').setLogMode(x) self.getAxis('left').setLogMode(y) self.getAxis('right').setLogMode(y) self.enableAutoRange() self.recomputeAverages() def setDownsampling(self, ds=None, auto=None, mode=None): """Change the default downsampling mode for all PlotDataItems managed by this plot. =============== ================================================================= **Arguments:** ds (int) Reduce visible plot samples by this factor, or (bool) To enable/disable downsampling without changing the value. auto (bool) If True, automatically pick *ds* based on visible range mode 'subsample': Downsample by taking the first of N samples. This method is fastest and least accurate. 'mean': Downsample by taking the mean of N samples. 'peak': Downsample by drawing a saw wave that follows the min and max of the original data. This method produces the best visual representation of the data but is slower. =============== ================================================================= """ if ds is not None: if ds is False: self.ctrl.downsampleCheck.setChecked(False) elif ds is True: self.ctrl.downsampleCheck.setChecked(True) else: self.ctrl.downsampleCheck.setChecked(True) self.ctrl.downsampleSpin.setValue(ds) if auto is not None: if auto and ds is not False: self.ctrl.downsampleCheck.setChecked(True) self.ctrl.autoDownsampleCheck.setChecked(auto) if mode is not None: if mode == 'subsample': self.ctrl.subsampleRadio.setChecked(True) elif mode == 'mean': self.ctrl.meanRadio.setChecked(True) elif mode == 'peak': self.ctrl.peakRadio.setChecked(True) else: raise ValueError("mode argument must be 'subsample', 'mean', or 'peak'.") def updateDownsampling(self): ds, auto, method = self.downsampleMode() clip = self.ctrl.clipToViewCheck.isChecked() for c in self.curves: c.setDownsampling(ds, auto, method) c.setClipToView(clip) self.recomputeAverages() def downsampleMode(self): if self.ctrl.downsampleCheck.isChecked(): ds = self.ctrl.downsampleSpin.value() else: ds = 1 auto = self.ctrl.downsampleCheck.isChecked() and self.ctrl.autoDownsampleCheck.isChecked() if self.ctrl.subsampleRadio.isChecked(): method = 'subsample' elif self.ctrl.meanRadio.isChecked(): method = 'mean' elif self.ctrl.peakRadio.isChecked(): method = 'peak' return ds, auto, method def setClipToView(self, clip): """Set the default clip-to-view mode for all PlotDataItems managed by this plot. If *clip* is True, then PlotDataItems will attempt to draw only points within the visible range of the ViewBox.""" self.ctrl.clipToViewCheck.setChecked(clip) def clipToViewMode(self): return self.ctrl.clipToViewCheck.isChecked() def updateDecimation(self): if self.ctrl.maxTracesCheck.isChecked(): numCurves = self.ctrl.maxTracesSpin.value() else: numCurves = -1 curves = self.curves[:] split = len(curves) - numCurves for i in range(len(curves)): if numCurves == -1 or i >= split: curves[i].show() else: if self.ctrl.forgetTracesCheck.isChecked(): curves[i].clear() self.removeItem(curves[i]) else: curves[i].hide() def updateAlpha(self, *args): (alpha, auto) = self.alphaState() for c in self.curves: c.setAlpha(alpha**2, auto) def alphaState(self): enabled = self.ctrl.alphaGroup.isChecked() auto = self.ctrl.autoAlphaCheck.isChecked() alpha = float(self.ctrl.alphaSlider.value()) / self.ctrl.alphaSlider.maximum() if auto: alpha = 1.0 ## should be 1/number of overlapping plots if not enabled: auto = False alpha = 1.0 return (alpha, auto) def pointMode(self): if self.ctrl.pointsGroup.isChecked(): if self.ctrl.autoPointsCheck.isChecked(): mode = None else: mode = True else: mode = False return mode def resizeEvent(self, ev): if self.autoBtn is None: ## already closed down return btnRect = self.mapRectFromItem(self.autoBtn, self.autoBtn.boundingRect()) y = self.size().height() - btnRect.height() self.autoBtn.setPos(0, y) def getMenu(self): return self.ctrlMenu def getContextMenus(self, event): ## called when another item is displaying its context menu; we get to add extras to the end of the menu. if self.menuEnabled(): return self.ctrlMenu else: return None def setMenuEnabled(self, enableMenu=True, enableViewBoxMenu='same'): """ Enable or disable the context menu for this PlotItem. By default, the ViewBox's context menu will also be affected. (use enableViewBoxMenu=None to leave the ViewBox unchanged) """ self._menuEnabled = enableMenu if enableViewBoxMenu is None: return if enableViewBoxMenu is 'same': enableViewBoxMenu = enableMenu self.vb.setMenuEnabled(enableViewBoxMenu) def menuEnabled(self): return self._menuEnabled def hoverEvent(self, ev): if ev.enter: self.mouseHovering = True if ev.exit: self.mouseHovering = False self.updateButtons() def getLabel(self, key): pass def _checkScaleKey(self, key): if key not in self.axes: raise Exception("Scale '%s' not found. Scales are: %s" % (key, str(list(self.axes.keys())))) def getScale(self, key): return self.getAxis(key) def getAxis(self, name): """Return the specified AxisItem. *name* should be 'left', 'bottom', 'top', or 'right'.""" self._checkScaleKey(name) return self.axes[name]['item'] def setLabel(self, axis, text=None, units=None, unitPrefix=None, **args): """ Set the label for an axis. Basic HTML formatting is allowed. ============== ================================================================= **Arguments:** axis must be one of 'left', 'bottom', 'right', or 'top' text text to display along the axis. HTML allowed. units units to display after the title. If units are given, then an SI prefix will be automatically appended and the axis values will be scaled accordingly. (ie, use 'V' instead of 'mV'; 'm' will be added automatically) ============== ================================================================= """ self.getAxis(axis).setLabel(text=text, units=units, **args) self.showAxis(axis) def setLabels(self, **kwds): """ Convenience function allowing multiple labels and/or title to be set in one call. Keyword arguments can be 'title', 'left', 'bottom', 'right', or 'top'. Values may be strings or a tuple of arguments to pass to setLabel. """ for k,v in kwds.items(): if k == 'title': self.setTitle(v) else: if isinstance(v, basestring): v = (v,) self.setLabel(k, *v) def showLabel(self, axis, show=True): """ Show or hide one of the plot's axis labels (the axis itself will be unaffected). axis must be one of 'left', 'bottom', 'right', or 'top' """ self.getScale(axis).showLabel(show) def setTitle(self, title=None, **args): """ Set the title of the plot. Basic HTML formatting is allowed. If title is None, then the title will be hidden. """ if title is None: self.titleLabel.setVisible(False) self.layout.setRowFixedHeight(0, 0) self.titleLabel.setMaximumHeight(0) else: self.titleLabel.setMaximumHeight(30) self.layout.setRowFixedHeight(0, 30) self.titleLabel.setVisible(True) self.titleLabel.setText(title, **args) def showAxis(self, axis, show=True): """ Show or hide one of the plot's axes. axis must be one of 'left', 'bottom', 'right', or 'top' """ s = self.getScale(axis) p = self.axes[axis]['pos'] if show: s.show() else: s.hide() def hideAxis(self, axis): """Hide one of the PlotItem's axes. ('left', 'bottom', 'right', or 'top')""" self.showAxis(axis, False) def showScale(self, *args, **kargs): print("Deprecated. use showAxis() instead") return self.showAxis(*args, **kargs) def hideButtons(self): """Causes auto-scale button ('A' in lower-left corner) to be hidden for this PlotItem""" #self.ctrlBtn.hide() self.buttonsHidden = True self.updateButtons() def showButtons(self): """Causes auto-scale button ('A' in lower-left corner) to be visible for this PlotItem""" #self.ctrlBtn.hide() self.buttonsHidden = False self.updateButtons() def updateButtons(self): try: if self._exportOpts is False and self.mouseHovering and not self.buttonsHidden and not all(self.vb.autoRangeEnabled()): self.autoBtn.show() else: self.autoBtn.hide() except RuntimeError: pass # this can happen if the plot has been deleted. def _plotArray(self, arr, x=None, **kargs): if arr.ndim != 1: raise Exception("Array must be 1D to plot (shape is %s)" % arr.shape) if x is None: x = np.arange(arr.shape[0]) if x.ndim != 1: raise Exception("X array must be 1D to plot (shape is %s)" % x.shape) c = PlotCurveItem(arr, x=x, **kargs) return c def _plotMetaArray(self, arr, x=None, autoLabel=True, **kargs): inf = arr.infoCopy() if arr.ndim != 1: raise Exception('can only automatically plot 1 dimensional arrays.') ## create curve try: xv = arr.xvals(0) except: if x is None: xv = np.arange(arr.shape[0]) else: xv = x c = PlotCurveItem(**kargs) c.setData(x=xv, y=arr.view(np.ndarray)) if autoLabel: name = arr._info[0].get('name', None) units = arr._info[0].get('units', None) self.setLabel('bottom', text=name, units=units) name = arr._info[1].get('name', None) units = arr._info[1].get('units', None) self.setLabel('left', text=name, units=units) return c def setExportMode(self, export, opts=None): GraphicsWidget.setExportMode(self, export, opts) self.updateButtons() #if export: #self.autoBtn.hide() #else: #self.autoBtn.show() �������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/PlotItem/__init__.py�����������������������������0000664�0000000�0000000�00000000037�13007271214�0026310�0����������������������������������������������������������������������������������������������������ustar�00root����������������������������root����������������������������0000000�0000000������������������������������������������������������������������������������������������������������������������������������������������������������������������������from .PlotItem import PlotItem �������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/PlotItem/plotConfigTemplate.ui�������������������0000664�0000000�0000000�00000022765�13007271214�0030352�0����������������������������������������������������������������������������������������������������ustar�00root����������������������������root����������������������������0000000�0000000������������������������������������������������������������������������������������������������������������������������������������������������������������������������ Form 0 0 481 840 Form 0 640 242 182 Display averages of the curves displayed in this plot. The parameter list allows you to choose parameters to average over (if any are available). Average true false 0 0 10 140 191 171 0 0 Plot only the portion of each curve that is visible. This assumes X values are uniformly spaced. Clip to View If multiple curves are displayed in this plot, check this box to limit the number of traces that are displayed. Max Traces: Downsample Downsample by drawing a saw wave that follows the min and max of the original data. This method produces the best visual representation of the data but is slower. Peak true If multiple curves are displayed in this plot, check "Max Traces" and set this value to limit the number of traces that are displayed. If MaxTraces is checked, remove curves from memory after they are hidden (saves memory, but traces can not be un-hidden). Forget hidden traces Downsample by taking the mean of N samples. Mean Downsample by taking the first of N samples. This method is fastest and least accurate. Subsample Automatically downsample data based on the visible range. This assumes X values are uniformly spaced. Auto true Qt::Horizontal QSizePolicy::Maximum 30 20 Downsample data before plotting. (plot every Nth sample) x 1 100000 1 0 0 154 79 Power Spectrum (FFT) Log X Log Y 10 550 234 58 Points true Auto true 10 460 221 81 Show X Grid Show Y Grid 255 128 Qt::Horizontal Opacity 10 390 234 60 Alpha true Auto false 1000 1000 Qt::Horizontal �����������pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/PlotItem/plotConfigTemplate_pyqt.py��������������0000664�0000000�0000000�00000026212�13007271214�0031431�0����������������������������������������������������������������������������������������������������ustar�00root����������������������������root����������������������������0000000�0000000������������������������������������������������������������������������������������������������������������������������������������������������������������������������# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './pyqtgraph/graphicsItems/PlotItem/plotConfigTemplate.ui' # # Created: Mon Dec 23 10:10:51 2013 # by: PyQt4 UI code generator 4.10 # # WARNING! All changes made in this file will be lost! from PyQt4 import QtCore, QtGui try: _fromUtf8 = QtCore.QString.fromUtf8 except AttributeError: def _fromUtf8(s): return s try: _encoding = QtGui.QApplication.UnicodeUTF8 def _translate(context, text, disambig): return QtGui.QApplication.translate(context, text, disambig, _encoding) except AttributeError: def _translate(context, text, disambig): return QtGui.QApplication.translate(context, text, disambig) class Ui_Form(object): def setupUi(self, Form): Form.setObjectName(_fromUtf8("Form")) Form.resize(481, 840) self.averageGroup = QtGui.QGroupBox(Form) self.averageGroup.setGeometry(QtCore.QRect(0, 640, 242, 182)) self.averageGroup.setCheckable(True) self.averageGroup.setChecked(False) self.averageGroup.setObjectName(_fromUtf8("averageGroup")) self.gridLayout_5 = QtGui.QGridLayout(self.averageGroup) self.gridLayout_5.setMargin(0) self.gridLayout_5.setSpacing(0) self.gridLayout_5.setObjectName(_fromUtf8("gridLayout_5")) self.avgParamList = QtGui.QListWidget(self.averageGroup) self.avgParamList.setObjectName(_fromUtf8("avgParamList")) self.gridLayout_5.addWidget(self.avgParamList, 0, 0, 1, 1) self.decimateGroup = QtGui.QFrame(Form) self.decimateGroup.setGeometry(QtCore.QRect(10, 140, 191, 171)) self.decimateGroup.setObjectName(_fromUtf8("decimateGroup")) self.gridLayout_4 = QtGui.QGridLayout(self.decimateGroup) self.gridLayout_4.setMargin(0) self.gridLayout_4.setSpacing(0) self.gridLayout_4.setObjectName(_fromUtf8("gridLayout_4")) self.clipToViewCheck = QtGui.QCheckBox(self.decimateGroup) self.clipToViewCheck.setObjectName(_fromUtf8("clipToViewCheck")) self.gridLayout_4.addWidget(self.clipToViewCheck, 7, 0, 1, 3) self.maxTracesCheck = QtGui.QCheckBox(self.decimateGroup) self.maxTracesCheck.setObjectName(_fromUtf8("maxTracesCheck")) self.gridLayout_4.addWidget(self.maxTracesCheck, 8, 0, 1, 2) self.downsampleCheck = QtGui.QCheckBox(self.decimateGroup) self.downsampleCheck.setObjectName(_fromUtf8("downsampleCheck")) self.gridLayout_4.addWidget(self.downsampleCheck, 0, 0, 1, 3) self.peakRadio = QtGui.QRadioButton(self.decimateGroup) self.peakRadio.setChecked(True) self.peakRadio.setObjectName(_fromUtf8("peakRadio")) self.gridLayout_4.addWidget(self.peakRadio, 6, 1, 1, 2) self.maxTracesSpin = QtGui.QSpinBox(self.decimateGroup) self.maxTracesSpin.setObjectName(_fromUtf8("maxTracesSpin")) self.gridLayout_4.addWidget(self.maxTracesSpin, 8, 2, 1, 1) self.forgetTracesCheck = QtGui.QCheckBox(self.decimateGroup) self.forgetTracesCheck.setObjectName(_fromUtf8("forgetTracesCheck")) self.gridLayout_4.addWidget(self.forgetTracesCheck, 9, 0, 1, 3) self.meanRadio = QtGui.QRadioButton(self.decimateGroup) self.meanRadio.setObjectName(_fromUtf8("meanRadio")) self.gridLayout_4.addWidget(self.meanRadio, 3, 1, 1, 2) self.subsampleRadio = QtGui.QRadioButton(self.decimateGroup) self.subsampleRadio.setObjectName(_fromUtf8("subsampleRadio")) self.gridLayout_4.addWidget(self.subsampleRadio, 2, 1, 1, 2) self.autoDownsampleCheck = QtGui.QCheckBox(self.decimateGroup) self.autoDownsampleCheck.setChecked(True) self.autoDownsampleCheck.setObjectName(_fromUtf8("autoDownsampleCheck")) self.gridLayout_4.addWidget(self.autoDownsampleCheck, 1, 2, 1, 1) spacerItem = QtGui.QSpacerItem(30, 20, QtGui.QSizePolicy.Maximum, QtGui.QSizePolicy.Minimum) self.gridLayout_4.addItem(spacerItem, 2, 0, 1, 1) self.downsampleSpin = QtGui.QSpinBox(self.decimateGroup) self.downsampleSpin.setMinimum(1) self.downsampleSpin.setMaximum(100000) self.downsampleSpin.setProperty("value", 1) self.downsampleSpin.setObjectName(_fromUtf8("downsampleSpin")) self.gridLayout_4.addWidget(self.downsampleSpin, 1, 1, 1, 1) self.transformGroup = QtGui.QFrame(Form) self.transformGroup.setGeometry(QtCore.QRect(0, 0, 154, 79)) self.transformGroup.setObjectName(_fromUtf8("transformGroup")) self.gridLayout = QtGui.QGridLayout(self.transformGroup) self.gridLayout.setObjectName(_fromUtf8("gridLayout")) self.fftCheck = QtGui.QCheckBox(self.transformGroup) self.fftCheck.setObjectName(_fromUtf8("fftCheck")) self.gridLayout.addWidget(self.fftCheck, 0, 0, 1, 1) self.logXCheck = QtGui.QCheckBox(self.transformGroup) self.logXCheck.setObjectName(_fromUtf8("logXCheck")) self.gridLayout.addWidget(self.logXCheck, 1, 0, 1, 1) self.logYCheck = QtGui.QCheckBox(self.transformGroup) self.logYCheck.setObjectName(_fromUtf8("logYCheck")) self.gridLayout.addWidget(self.logYCheck, 2, 0, 1, 1) self.pointsGroup = QtGui.QGroupBox(Form) self.pointsGroup.setGeometry(QtCore.QRect(10, 550, 234, 58)) self.pointsGroup.setCheckable(True) self.pointsGroup.setObjectName(_fromUtf8("pointsGroup")) self.verticalLayout_5 = QtGui.QVBoxLayout(self.pointsGroup) self.verticalLayout_5.setObjectName(_fromUtf8("verticalLayout_5")) self.autoPointsCheck = QtGui.QCheckBox(self.pointsGroup) self.autoPointsCheck.setChecked(True) self.autoPointsCheck.setObjectName(_fromUtf8("autoPointsCheck")) self.verticalLayout_5.addWidget(self.autoPointsCheck) self.gridGroup = QtGui.QFrame(Form) self.gridGroup.setGeometry(QtCore.QRect(10, 460, 221, 81)) self.gridGroup.setObjectName(_fromUtf8("gridGroup")) self.gridLayout_2 = QtGui.QGridLayout(self.gridGroup) self.gridLayout_2.setObjectName(_fromUtf8("gridLayout_2")) self.xGridCheck = QtGui.QCheckBox(self.gridGroup) self.xGridCheck.setObjectName(_fromUtf8("xGridCheck")) self.gridLayout_2.addWidget(self.xGridCheck, 0, 0, 1, 2) self.yGridCheck = QtGui.QCheckBox(self.gridGroup) self.yGridCheck.setObjectName(_fromUtf8("yGridCheck")) self.gridLayout_2.addWidget(self.yGridCheck, 1, 0, 1, 2) self.gridAlphaSlider = QtGui.QSlider(self.gridGroup) self.gridAlphaSlider.setMaximum(255) self.gridAlphaSlider.setProperty("value", 128) self.gridAlphaSlider.setOrientation(QtCore.Qt.Horizontal) self.gridAlphaSlider.setObjectName(_fromUtf8("gridAlphaSlider")) self.gridLayout_2.addWidget(self.gridAlphaSlider, 2, 1, 1, 1) self.label = QtGui.QLabel(self.gridGroup) self.label.setObjectName(_fromUtf8("label")) self.gridLayout_2.addWidget(self.label, 2, 0, 1, 1) self.alphaGroup = QtGui.QGroupBox(Form) self.alphaGroup.setGeometry(QtCore.QRect(10, 390, 234, 60)) self.alphaGroup.setCheckable(True) self.alphaGroup.setObjectName(_fromUtf8("alphaGroup")) self.horizontalLayout = QtGui.QHBoxLayout(self.alphaGroup) self.horizontalLayout.setObjectName(_fromUtf8("horizontalLayout")) self.autoAlphaCheck = QtGui.QCheckBox(self.alphaGroup) self.autoAlphaCheck.setChecked(False) self.autoAlphaCheck.setObjectName(_fromUtf8("autoAlphaCheck")) self.horizontalLayout.addWidget(self.autoAlphaCheck) self.alphaSlider = QtGui.QSlider(self.alphaGroup) self.alphaSlider.setMaximum(1000) self.alphaSlider.setProperty("value", 1000) self.alphaSlider.setOrientation(QtCore.Qt.Horizontal) self.alphaSlider.setObjectName(_fromUtf8("alphaSlider")) self.horizontalLayout.addWidget(self.alphaSlider) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): Form.setWindowTitle(_translate("Form", "Form", None)) self.averageGroup.setToolTip(_translate("Form", "Display averages of the curves displayed in this plot. The parameter list allows you to choose parameters to average over (if any are available).", None)) self.averageGroup.setTitle(_translate("Form", "Average", None)) self.clipToViewCheck.setToolTip(_translate("Form", "Plot only the portion of each curve that is visible. This assumes X values are uniformly spaced.", None)) self.clipToViewCheck.setText(_translate("Form", "Clip to View", None)) self.maxTracesCheck.setToolTip(_translate("Form", "If multiple curves are displayed in this plot, check this box to limit the number of traces that are displayed.", None)) self.maxTracesCheck.setText(_translate("Form", "Max Traces:", None)) self.downsampleCheck.setText(_translate("Form", "Downsample", None)) self.peakRadio.setToolTip(_translate("Form", "Downsample by drawing a saw wave that follows the min and max of the original data. This method produces the best visual representation of the data but is slower.", None)) self.peakRadio.setText(_translate("Form", "Peak", None)) self.maxTracesSpin.setToolTip(_translate("Form", "If multiple curves are displayed in this plot, check \"Max Traces\" and set this value to limit the number of traces that are displayed.", None)) self.forgetTracesCheck.setToolTip(_translate("Form", "If MaxTraces is checked, remove curves from memory after they are hidden (saves memory, but traces can not be un-hidden).", None)) self.forgetTracesCheck.setText(_translate("Form", "Forget hidden traces", None)) self.meanRadio.setToolTip(_translate("Form", "Downsample by taking the mean of N samples.", None)) self.meanRadio.setText(_translate("Form", "Mean", None)) self.subsampleRadio.setToolTip(_translate("Form", "Downsample by taking the first of N samples. This method is fastest and least accurate.", None)) self.subsampleRadio.setText(_translate("Form", "Subsample", None)) self.autoDownsampleCheck.setToolTip(_translate("Form", "Automatically downsample data based on the visible range. This assumes X values are uniformly spaced.", None)) self.autoDownsampleCheck.setText(_translate("Form", "Auto", None)) self.downsampleSpin.setToolTip(_translate("Form", "Downsample data before plotting. (plot every Nth sample)", None)) self.downsampleSpin.setSuffix(_translate("Form", "x", None)) self.fftCheck.setText(_translate("Form", "Power Spectrum (FFT)", None)) self.logXCheck.setText(_translate("Form", "Log X", None)) self.logYCheck.setText(_translate("Form", "Log Y", None)) self.pointsGroup.setTitle(_translate("Form", "Points", None)) self.autoPointsCheck.setText(_translate("Form", "Auto", None)) self.xGridCheck.setText(_translate("Form", "Show X Grid", None)) self.yGridCheck.setText(_translate("Form", "Show Y Grid", None)) self.label.setText(_translate("Form", "Opacity", None)) self.alphaGroup.setTitle(_translate("Form", "Alpha", None)) self.autoAlphaCheck.setText(_translate("Form", "Auto", None)) ��������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/PlotItem/plotConfigTemplate_pyqt5.py�������������0000664�0000000�0000000�00000024652�13007271214�0031524�0����������������������������������������������������������������������������������������������������ustar�00root����������������������������root����������������������������0000000�0000000������������������������������������������������������������������������������������������������������������������������������������������������������������������������# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './pyqtgraph/graphicsItems/PlotItem/plotConfigTemplate.ui' # # Created: Wed Mar 26 15:09:28 2014 # by: PyQt5 UI code generator 5.0.1 # # WARNING! All changes made in this file will be lost! from PyQt5 import QtCore, QtGui, QtWidgets class Ui_Form(object): def setupUi(self, Form): Form.setObjectName("Form") Form.resize(481, 840) self.averageGroup = QtWidgets.QGroupBox(Form) self.averageGroup.setGeometry(QtCore.QRect(0, 640, 242, 182)) self.averageGroup.setCheckable(True) self.averageGroup.setChecked(False) self.averageGroup.setObjectName("averageGroup") self.gridLayout_5 = QtWidgets.QGridLayout(self.averageGroup) self.gridLayout_5.setContentsMargins(0, 0, 0, 0) self.gridLayout_5.setSpacing(0) self.gridLayout_5.setObjectName("gridLayout_5") self.avgParamList = QtWidgets.QListWidget(self.averageGroup) self.avgParamList.setObjectName("avgParamList") self.gridLayout_5.addWidget(self.avgParamList, 0, 0, 1, 1) self.decimateGroup = QtWidgets.QFrame(Form) self.decimateGroup.setGeometry(QtCore.QRect(10, 140, 191, 171)) self.decimateGroup.setObjectName("decimateGroup") self.gridLayout_4 = QtWidgets.QGridLayout(self.decimateGroup) self.gridLayout_4.setContentsMargins(0, 0, 0, 0) self.gridLayout_4.setSpacing(0) self.gridLayout_4.setObjectName("gridLayout_4") self.clipToViewCheck = QtWidgets.QCheckBox(self.decimateGroup) self.clipToViewCheck.setObjectName("clipToViewCheck") self.gridLayout_4.addWidget(self.clipToViewCheck, 7, 0, 1, 3) self.maxTracesCheck = QtWidgets.QCheckBox(self.decimateGroup) self.maxTracesCheck.setObjectName("maxTracesCheck") self.gridLayout_4.addWidget(self.maxTracesCheck, 8, 0, 1, 2) self.downsampleCheck = QtWidgets.QCheckBox(self.decimateGroup) self.downsampleCheck.setObjectName("downsampleCheck") self.gridLayout_4.addWidget(self.downsampleCheck, 0, 0, 1, 3) self.peakRadio = QtWidgets.QRadioButton(self.decimateGroup) self.peakRadio.setChecked(True) self.peakRadio.setObjectName("peakRadio") self.gridLayout_4.addWidget(self.peakRadio, 6, 1, 1, 2) self.maxTracesSpin = QtWidgets.QSpinBox(self.decimateGroup) self.maxTracesSpin.setObjectName("maxTracesSpin") self.gridLayout_4.addWidget(self.maxTracesSpin, 8, 2, 1, 1) self.forgetTracesCheck = QtWidgets.QCheckBox(self.decimateGroup) self.forgetTracesCheck.setObjectName("forgetTracesCheck") self.gridLayout_4.addWidget(self.forgetTracesCheck, 9, 0, 1, 3) self.meanRadio = QtWidgets.QRadioButton(self.decimateGroup) self.meanRadio.setObjectName("meanRadio") self.gridLayout_4.addWidget(self.meanRadio, 3, 1, 1, 2) self.subsampleRadio = QtWidgets.QRadioButton(self.decimateGroup) self.subsampleRadio.setObjectName("subsampleRadio") self.gridLayout_4.addWidget(self.subsampleRadio, 2, 1, 1, 2) self.autoDownsampleCheck = QtWidgets.QCheckBox(self.decimateGroup) self.autoDownsampleCheck.setChecked(True) self.autoDownsampleCheck.setObjectName("autoDownsampleCheck") self.gridLayout_4.addWidget(self.autoDownsampleCheck, 1, 2, 1, 1) spacerItem = QtWidgets.QSpacerItem(30, 20, QtWidgets.QSizePolicy.Maximum, QtWidgets.QSizePolicy.Minimum) self.gridLayout_4.addItem(spacerItem, 2, 0, 1, 1) self.downsampleSpin = QtWidgets.QSpinBox(self.decimateGroup) self.downsampleSpin.setMinimum(1) self.downsampleSpin.setMaximum(100000) self.downsampleSpin.setProperty("value", 1) self.downsampleSpin.setObjectName("downsampleSpin") self.gridLayout_4.addWidget(self.downsampleSpin, 1, 1, 1, 1) self.transformGroup = QtWidgets.QFrame(Form) self.transformGroup.setGeometry(QtCore.QRect(0, 0, 154, 79)) self.transformGroup.setObjectName("transformGroup") self.gridLayout = QtWidgets.QGridLayout(self.transformGroup) self.gridLayout.setObjectName("gridLayout") self.fftCheck = QtWidgets.QCheckBox(self.transformGroup) self.fftCheck.setObjectName("fftCheck") self.gridLayout.addWidget(self.fftCheck, 0, 0, 1, 1) self.logXCheck = QtWidgets.QCheckBox(self.transformGroup) self.logXCheck.setObjectName("logXCheck") self.gridLayout.addWidget(self.logXCheck, 1, 0, 1, 1) self.logYCheck = QtWidgets.QCheckBox(self.transformGroup) self.logYCheck.setObjectName("logYCheck") self.gridLayout.addWidget(self.logYCheck, 2, 0, 1, 1) self.pointsGroup = QtWidgets.QGroupBox(Form) self.pointsGroup.setGeometry(QtCore.QRect(10, 550, 234, 58)) self.pointsGroup.setCheckable(True) self.pointsGroup.setObjectName("pointsGroup") self.verticalLayout_5 = QtWidgets.QVBoxLayout(self.pointsGroup) self.verticalLayout_5.setObjectName("verticalLayout_5") self.autoPointsCheck = QtWidgets.QCheckBox(self.pointsGroup) self.autoPointsCheck.setChecked(True) self.autoPointsCheck.setObjectName("autoPointsCheck") self.verticalLayout_5.addWidget(self.autoPointsCheck) self.gridGroup = QtWidgets.QFrame(Form) self.gridGroup.setGeometry(QtCore.QRect(10, 460, 221, 81)) self.gridGroup.setObjectName("gridGroup") self.gridLayout_2 = QtWidgets.QGridLayout(self.gridGroup) self.gridLayout_2.setObjectName("gridLayout_2") self.xGridCheck = QtWidgets.QCheckBox(self.gridGroup) self.xGridCheck.setObjectName("xGridCheck") self.gridLayout_2.addWidget(self.xGridCheck, 0, 0, 1, 2) self.yGridCheck = QtWidgets.QCheckBox(self.gridGroup) self.yGridCheck.setObjectName("yGridCheck") self.gridLayout_2.addWidget(self.yGridCheck, 1, 0, 1, 2) self.gridAlphaSlider = QtWidgets.QSlider(self.gridGroup) self.gridAlphaSlider.setMaximum(255) self.gridAlphaSlider.setProperty("value", 128) self.gridAlphaSlider.setOrientation(QtCore.Qt.Horizontal) self.gridAlphaSlider.setObjectName("gridAlphaSlider") self.gridLayout_2.addWidget(self.gridAlphaSlider, 2, 1, 1, 1) self.label = QtWidgets.QLabel(self.gridGroup) self.label.setObjectName("label") self.gridLayout_2.addWidget(self.label, 2, 0, 1, 1) self.alphaGroup = QtWidgets.QGroupBox(Form) self.alphaGroup.setGeometry(QtCore.QRect(10, 390, 234, 60)) self.alphaGroup.setCheckable(True) self.alphaGroup.setObjectName("alphaGroup") self.horizontalLayout = QtWidgets.QHBoxLayout(self.alphaGroup) self.horizontalLayout.setObjectName("horizontalLayout") self.autoAlphaCheck = QtWidgets.QCheckBox(self.alphaGroup) self.autoAlphaCheck.setChecked(False) self.autoAlphaCheck.setObjectName("autoAlphaCheck") self.horizontalLayout.addWidget(self.autoAlphaCheck) self.alphaSlider = QtWidgets.QSlider(self.alphaGroup) self.alphaSlider.setMaximum(1000) self.alphaSlider.setProperty("value", 1000) self.alphaSlider.setOrientation(QtCore.Qt.Horizontal) self.alphaSlider.setObjectName("alphaSlider") self.horizontalLayout.addWidget(self.alphaSlider) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): _translate = QtCore.QCoreApplication.translate Form.setWindowTitle(_translate("Form", "Form")) self.averageGroup.setToolTip(_translate("Form", "Display averages of the curves displayed in this plot. The parameter list allows you to choose parameters to average over (if any are available).")) self.averageGroup.setTitle(_translate("Form", "Average")) self.clipToViewCheck.setToolTip(_translate("Form", "Plot only the portion of each curve that is visible. This assumes X values are uniformly spaced.")) self.clipToViewCheck.setText(_translate("Form", "Clip to View")) self.maxTracesCheck.setToolTip(_translate("Form", "If multiple curves are displayed in this plot, check this box to limit the number of traces that are displayed.")) self.maxTracesCheck.setText(_translate("Form", "Max Traces:")) self.downsampleCheck.setText(_translate("Form", "Downsample")) self.peakRadio.setToolTip(_translate("Form", "Downsample by drawing a saw wave that follows the min and max of the original data. This method produces the best visual representation of the data but is slower.")) self.peakRadio.setText(_translate("Form", "Peak")) self.maxTracesSpin.setToolTip(_translate("Form", "If multiple curves are displayed in this plot, check \"Max Traces\" and set this value to limit the number of traces that are displayed.")) self.forgetTracesCheck.setToolTip(_translate("Form", "If MaxTraces is checked, remove curves from memory after they are hidden (saves memory, but traces can not be un-hidden).")) self.forgetTracesCheck.setText(_translate("Form", "Forget hidden traces")) self.meanRadio.setToolTip(_translate("Form", "Downsample by taking the mean of N samples.")) self.meanRadio.setText(_translate("Form", "Mean")) self.subsampleRadio.setToolTip(_translate("Form", "Downsample by taking the first of N samples. This method is fastest and least accurate.")) self.subsampleRadio.setText(_translate("Form", "Subsample")) self.autoDownsampleCheck.setToolTip(_translate("Form", "Automatically downsample data based on the visible range. This assumes X values are uniformly spaced.")) self.autoDownsampleCheck.setText(_translate("Form", "Auto")) self.downsampleSpin.setToolTip(_translate("Form", "Downsample data before plotting. (plot every Nth sample)")) self.downsampleSpin.setSuffix(_translate("Form", "x")) self.fftCheck.setText(_translate("Form", "Power Spectrum (FFT)")) self.logXCheck.setText(_translate("Form", "Log X")) self.logYCheck.setText(_translate("Form", "Log Y")) self.pointsGroup.setTitle(_translate("Form", "Points")) self.autoPointsCheck.setText(_translate("Form", "Auto")) self.xGridCheck.setText(_translate("Form", "Show X Grid")) self.yGridCheck.setText(_translate("Form", "Show Y Grid")) self.label.setText(_translate("Form", "Opacity")) self.alphaGroup.setTitle(_translate("Form", "Alpha")) self.autoAlphaCheck.setText(_translate("Form", "Auto")) ��������������������������������������������������������������������������������������pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/PlotItem/plotConfigTemplate_pyside.py������������0000664�0000000�0000000�00000027655�13007271214�0031745�0����������������������������������������������������������������������������������������������������ustar�00root����������������������������root����������������������������0000000�0000000������������������������������������������������������������������������������������������������������������������������������������������������������������������������# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './pyqtgraph/graphicsItems/PlotItem/plotConfigTemplate.ui' # # Created: Mon Dec 23 10:10:52 2013 # by: pyside-uic 0.2.14 running on PySide 1.1.2 # # WARNING! All changes made in this file will be lost! from PySide import QtCore, QtGui class Ui_Form(object): def setupUi(self, Form): Form.setObjectName("Form") Form.resize(481, 840) self.averageGroup = QtGui.QGroupBox(Form) self.averageGroup.setGeometry(QtCore.QRect(0, 640, 242, 182)) self.averageGroup.setCheckable(True) self.averageGroup.setChecked(False) self.averageGroup.setObjectName("averageGroup") self.gridLayout_5 = QtGui.QGridLayout(self.averageGroup) self.gridLayout_5.setContentsMargins(0, 0, 0, 0) self.gridLayout_5.setSpacing(0) self.gridLayout_5.setObjectName("gridLayout_5") self.avgParamList = QtGui.QListWidget(self.averageGroup) self.avgParamList.setObjectName("avgParamList") self.gridLayout_5.addWidget(self.avgParamList, 0, 0, 1, 1) self.decimateGroup = QtGui.QFrame(Form) self.decimateGroup.setGeometry(QtCore.QRect(10, 140, 191, 171)) self.decimateGroup.setObjectName("decimateGroup") self.gridLayout_4 = QtGui.QGridLayout(self.decimateGroup) self.gridLayout_4.setContentsMargins(0, 0, 0, 0) self.gridLayout_4.setSpacing(0) self.gridLayout_4.setObjectName("gridLayout_4") self.clipToViewCheck = QtGui.QCheckBox(self.decimateGroup) self.clipToViewCheck.setObjectName("clipToViewCheck") self.gridLayout_4.addWidget(self.clipToViewCheck, 7, 0, 1, 3) self.maxTracesCheck = QtGui.QCheckBox(self.decimateGroup) self.maxTracesCheck.setObjectName("maxTracesCheck") self.gridLayout_4.addWidget(self.maxTracesCheck, 8, 0, 1, 2) self.downsampleCheck = QtGui.QCheckBox(self.decimateGroup) self.downsampleCheck.setObjectName("downsampleCheck") self.gridLayout_4.addWidget(self.downsampleCheck, 0, 0, 1, 3) self.peakRadio = QtGui.QRadioButton(self.decimateGroup) self.peakRadio.setChecked(True) self.peakRadio.setObjectName("peakRadio") self.gridLayout_4.addWidget(self.peakRadio, 6, 1, 1, 2) self.maxTracesSpin = QtGui.QSpinBox(self.decimateGroup) self.maxTracesSpin.setObjectName("maxTracesSpin") self.gridLayout_4.addWidget(self.maxTracesSpin, 8, 2, 1, 1) self.forgetTracesCheck = QtGui.QCheckBox(self.decimateGroup) self.forgetTracesCheck.setObjectName("forgetTracesCheck") self.gridLayout_4.addWidget(self.forgetTracesCheck, 9, 0, 1, 3) self.meanRadio = QtGui.QRadioButton(self.decimateGroup) self.meanRadio.setObjectName("meanRadio") self.gridLayout_4.addWidget(self.meanRadio, 3, 1, 1, 2) self.subsampleRadio = QtGui.QRadioButton(self.decimateGroup) self.subsampleRadio.setObjectName("subsampleRadio") self.gridLayout_4.addWidget(self.subsampleRadio, 2, 1, 1, 2) self.autoDownsampleCheck = QtGui.QCheckBox(self.decimateGroup) self.autoDownsampleCheck.setChecked(True) self.autoDownsampleCheck.setObjectName("autoDownsampleCheck") self.gridLayout_4.addWidget(self.autoDownsampleCheck, 1, 2, 1, 1) spacerItem = QtGui.QSpacerItem(30, 20, QtGui.QSizePolicy.Maximum, QtGui.QSizePolicy.Minimum) self.gridLayout_4.addItem(spacerItem, 2, 0, 1, 1) self.downsampleSpin = QtGui.QSpinBox(self.decimateGroup) self.downsampleSpin.setMinimum(1) self.downsampleSpin.setMaximum(100000) self.downsampleSpin.setProperty("value", 1) self.downsampleSpin.setObjectName("downsampleSpin") self.gridLayout_4.addWidget(self.downsampleSpin, 1, 1, 1, 1) self.transformGroup = QtGui.QFrame(Form) self.transformGroup.setGeometry(QtCore.QRect(0, 0, 154, 79)) self.transformGroup.setObjectName("transformGroup") self.gridLayout = QtGui.QGridLayout(self.transformGroup) self.gridLayout.setObjectName("gridLayout") self.fftCheck = QtGui.QCheckBox(self.transformGroup) self.fftCheck.setObjectName("fftCheck") self.gridLayout.addWidget(self.fftCheck, 0, 0, 1, 1) self.logXCheck = QtGui.QCheckBox(self.transformGroup) self.logXCheck.setObjectName("logXCheck") self.gridLayout.addWidget(self.logXCheck, 1, 0, 1, 1) self.logYCheck = QtGui.QCheckBox(self.transformGroup) self.logYCheck.setObjectName("logYCheck") self.gridLayout.addWidget(self.logYCheck, 2, 0, 1, 1) self.pointsGroup = QtGui.QGroupBox(Form) self.pointsGroup.setGeometry(QtCore.QRect(10, 550, 234, 58)) self.pointsGroup.setCheckable(True) self.pointsGroup.setObjectName("pointsGroup") self.verticalLayout_5 = QtGui.QVBoxLayout(self.pointsGroup) self.verticalLayout_5.setObjectName("verticalLayout_5") self.autoPointsCheck = QtGui.QCheckBox(self.pointsGroup) self.autoPointsCheck.setChecked(True) self.autoPointsCheck.setObjectName("autoPointsCheck") self.verticalLayout_5.addWidget(self.autoPointsCheck) self.gridGroup = QtGui.QFrame(Form) self.gridGroup.setGeometry(QtCore.QRect(10, 460, 221, 81)) self.gridGroup.setObjectName("gridGroup") self.gridLayout_2 = QtGui.QGridLayout(self.gridGroup) self.gridLayout_2.setObjectName("gridLayout_2") self.xGridCheck = QtGui.QCheckBox(self.gridGroup) self.xGridCheck.setObjectName("xGridCheck") self.gridLayout_2.addWidget(self.xGridCheck, 0, 0, 1, 2) self.yGridCheck = QtGui.QCheckBox(self.gridGroup) self.yGridCheck.setObjectName("yGridCheck") self.gridLayout_2.addWidget(self.yGridCheck, 1, 0, 1, 2) self.gridAlphaSlider = QtGui.QSlider(self.gridGroup) self.gridAlphaSlider.setMaximum(255) self.gridAlphaSlider.setProperty("value", 128) self.gridAlphaSlider.setOrientation(QtCore.Qt.Horizontal) self.gridAlphaSlider.setObjectName("gridAlphaSlider") self.gridLayout_2.addWidget(self.gridAlphaSlider, 2, 1, 1, 1) self.label = QtGui.QLabel(self.gridGroup) self.label.setObjectName("label") self.gridLayout_2.addWidget(self.label, 2, 0, 1, 1) self.alphaGroup = QtGui.QGroupBox(Form) self.alphaGroup.setGeometry(QtCore.QRect(10, 390, 234, 60)) self.alphaGroup.setCheckable(True) self.alphaGroup.setObjectName("alphaGroup") self.horizontalLayout = QtGui.QHBoxLayout(self.alphaGroup) self.horizontalLayout.setObjectName("horizontalLayout") self.autoAlphaCheck = QtGui.QCheckBox(self.alphaGroup) self.autoAlphaCheck.setChecked(False) self.autoAlphaCheck.setObjectName("autoAlphaCheck") self.horizontalLayout.addWidget(self.autoAlphaCheck) self.alphaSlider = QtGui.QSlider(self.alphaGroup) self.alphaSlider.setMaximum(1000) self.alphaSlider.setProperty("value", 1000) self.alphaSlider.setOrientation(QtCore.Qt.Horizontal) self.alphaSlider.setObjectName("alphaSlider") self.horizontalLayout.addWidget(self.alphaSlider) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): Form.setWindowTitle(QtGui.QApplication.translate("Form", "Form", None, QtGui.QApplication.UnicodeUTF8)) self.averageGroup.setToolTip(QtGui.QApplication.translate("Form", "Display averages of the curves displayed in this plot. The parameter list allows you to choose parameters to average over (if any are available).", None, QtGui.QApplication.UnicodeUTF8)) self.averageGroup.setTitle(QtGui.QApplication.translate("Form", "Average", None, QtGui.QApplication.UnicodeUTF8)) self.clipToViewCheck.setToolTip(QtGui.QApplication.translate("Form", "Plot only the portion of each curve that is visible. This assumes X values are uniformly spaced.", None, QtGui.QApplication.UnicodeUTF8)) self.clipToViewCheck.setText(QtGui.QApplication.translate("Form", "Clip to View", None, QtGui.QApplication.UnicodeUTF8)) self.maxTracesCheck.setToolTip(QtGui.QApplication.translate("Form", "If multiple curves are displayed in this plot, check this box to limit the number of traces that are displayed.", None, QtGui.QApplication.UnicodeUTF8)) self.maxTracesCheck.setText(QtGui.QApplication.translate("Form", "Max Traces:", None, QtGui.QApplication.UnicodeUTF8)) self.downsampleCheck.setText(QtGui.QApplication.translate("Form", "Downsample", None, QtGui.QApplication.UnicodeUTF8)) self.peakRadio.setToolTip(QtGui.QApplication.translate("Form", "Downsample by drawing a saw wave that follows the min and max of the original data. This method produces the best visual representation of the data but is slower.", None, QtGui.QApplication.UnicodeUTF8)) self.peakRadio.setText(QtGui.QApplication.translate("Form", "Peak", None, QtGui.QApplication.UnicodeUTF8)) self.maxTracesSpin.setToolTip(QtGui.QApplication.translate("Form", "If multiple curves are displayed in this plot, check \"Max Traces\" and set this value to limit the number of traces that are displayed.", None, QtGui.QApplication.UnicodeUTF8)) self.forgetTracesCheck.setToolTip(QtGui.QApplication.translate("Form", "If MaxTraces is checked, remove curves from memory after they are hidden (saves memory, but traces can not be un-hidden).", None, QtGui.QApplication.UnicodeUTF8)) self.forgetTracesCheck.setText(QtGui.QApplication.translate("Form", "Forget hidden traces", None, QtGui.QApplication.UnicodeUTF8)) self.meanRadio.setToolTip(QtGui.QApplication.translate("Form", "Downsample by taking the mean of N samples.", None, QtGui.QApplication.UnicodeUTF8)) self.meanRadio.setText(QtGui.QApplication.translate("Form", "Mean", None, QtGui.QApplication.UnicodeUTF8)) self.subsampleRadio.setToolTip(QtGui.QApplication.translate("Form", "Downsample by taking the first of N samples. This method is fastest and least accurate.", None, QtGui.QApplication.UnicodeUTF8)) self.subsampleRadio.setText(QtGui.QApplication.translate("Form", "Subsample", None, QtGui.QApplication.UnicodeUTF8)) self.autoDownsampleCheck.setToolTip(QtGui.QApplication.translate("Form", "Automatically downsample data based on the visible range. This assumes X values are uniformly spaced.", None, QtGui.QApplication.UnicodeUTF8)) self.autoDownsampleCheck.setText(QtGui.QApplication.translate("Form", "Auto", None, QtGui.QApplication.UnicodeUTF8)) self.downsampleSpin.setToolTip(QtGui.QApplication.translate("Form", "Downsample data before plotting. (plot every Nth sample)", None, QtGui.QApplication.UnicodeUTF8)) self.downsampleSpin.setSuffix(QtGui.QApplication.translate("Form", "x", None, QtGui.QApplication.UnicodeUTF8)) self.fftCheck.setText(QtGui.QApplication.translate("Form", "Power Spectrum (FFT)", None, QtGui.QApplication.UnicodeUTF8)) self.logXCheck.setText(QtGui.QApplication.translate("Form", "Log X", None, QtGui.QApplication.UnicodeUTF8)) self.logYCheck.setText(QtGui.QApplication.translate("Form", "Log Y", None, QtGui.QApplication.UnicodeUTF8)) self.pointsGroup.setTitle(QtGui.QApplication.translate("Form", "Points", None, QtGui.QApplication.UnicodeUTF8)) self.autoPointsCheck.setText(QtGui.QApplication.translate("Form", "Auto", None, QtGui.QApplication.UnicodeUTF8)) self.xGridCheck.setText(QtGui.QApplication.translate("Form", "Show X Grid", None, QtGui.QApplication.UnicodeUTF8)) self.yGridCheck.setText(QtGui.QApplication.translate("Form", "Show Y Grid", None, QtGui.QApplication.UnicodeUTF8)) self.label.setText(QtGui.QApplication.translate("Form", "Opacity", None, QtGui.QApplication.UnicodeUTF8)) self.alphaGroup.setTitle(QtGui.QApplication.translate("Form", "Alpha", None, QtGui.QApplication.UnicodeUTF8)) self.autoAlphaCheck.setText(QtGui.QApplication.translate("Form", "Auto", None, QtGui.QApplication.UnicodeUTF8)) �����������������������������������������������������������������������������������pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/ROI.py�������������������������������������������0000664�0000000�0000000�00000267122�13007271214�0023457�0����������������������������������������������������������������������������������������������������ustar�00root����������������������������root����������������������������0000000�0000000������������������������������������������������������������������������������������������������������������������������������������������������������������������������# -*- coding: utf-8 -*- """ ROI.py - Interactive graphics items for GraphicsView (ROI widgets) Copyright 2010 Luke Campagnola Distributed under MIT/X11 license. See license.txt for more infomation. Implements a series of graphics items which display movable/scalable/rotatable shapes for use as region-of-interest markers. ROI class automatically handles extraction of array data from ImageItems. The ROI class is meant to serve as the base for more specific types; see several examples of how to build an ROI at the bottom of the file. """ from ..Qt import QtCore, QtGui import numpy as np #from numpy.linalg import norm from ..Point import * from ..SRTTransform import SRTTransform from math import cos, sin from .. import functions as fn from .GraphicsObject import GraphicsObject from .UIGraphicsItem import UIGraphicsItem from .. import getConfigOption __all__ = [ 'ROI', 'TestROI', 'RectROI', 'EllipseROI', 'CircleROI', 'PolygonROI', 'LineROI', 'MultiLineROI', 'MultiRectROI', 'LineSegmentROI', 'PolyLineROI', 'SpiralROI', 'CrosshairROI', ] def rectStr(r): return "[%f, %f] + [%f, %f]" % (r.x(), r.y(), r.width(), r.height()) class ROI(GraphicsObject): """ Generic region-of-interest widget. Can be used for implementing many types of selection box with rotate/translate/scale handles. ROIs can be customized to have a variety of shapes (by subclassing or using any of the built-in subclasses) and any combination of draggable handles that allow the user to manipulate the ROI. ================ =========================================================== **Arguments** pos (length-2 sequence) Indicates the position of the ROI's origin. For most ROIs, this is the lower-left corner of its bounding rectangle. size (length-2 sequence) Indicates the width and height of the ROI. angle (float) The rotation of the ROI in degrees. Default is 0. invertible (bool) If True, the user may resize the ROI to have negative width or height (assuming the ROI has scale handles). Default is False. maxBounds (QRect, QRectF, or None) Specifies boundaries that the ROI cannot be dragged outside of by the user. Default is None. snapSize (float) The spacing of snap positions used when *scaleSnap* or *translateSnap* are enabled. Default is 1.0. scaleSnap (bool) If True, the width and height of the ROI are forced to be integer multiples of *snapSize* when being resized by the user. Default is False. translateSnap (bool) If True, the x and y positions of the ROI are forced to be integer multiples of *snapSize* when being resized by the user. Default is False. rotateSnap (bool) If True, the ROI angle is forced to a multiple of 15 degrees when rotated by the user. Default is False. parent (QGraphicsItem) The graphics item parent of this ROI. It is generally not necessary to specify the parent. pen (QPen or argument to pg.mkPen) The pen to use when drawing the shape of the ROI. movable (bool) If True, the ROI can be moved by dragging anywhere inside the ROI. Default is True. removable (bool) If True, the ROI will be given a context menu with an option to remove the ROI. The ROI emits sigRemoveRequested when this menu action is selected. Default is False. ================ =========================================================== ======================= ==================================================== **Signals** sigRegionChangeFinished Emitted when the user stops dragging the ROI (or one of its handles) or if the ROI is changed programatically. sigRegionChangeStarted Emitted when the user starts dragging the ROI (or one of its handles). sigRegionChanged Emitted any time the position of the ROI changes, including while it is being dragged by the user. sigHoverEvent Emitted when the mouse hovers over the ROI. sigClicked Emitted when the user clicks on the ROI. Note that clicking is disabled by default to prevent stealing clicks from objects behind the ROI. To enable clicking, call roi.setAcceptedMouseButtons(QtCore.Qt.LeftButton). See QtGui.QGraphicsItem documentation for more details. sigRemoveRequested Emitted when the user selects 'remove' from the ROI's context menu (if available). ======================= ==================================================== """ sigRegionChangeFinished = QtCore.Signal(object) sigRegionChangeStarted = QtCore.Signal(object) sigRegionChanged = QtCore.Signal(object) sigHoverEvent = QtCore.Signal(object) sigClicked = QtCore.Signal(object, object) sigRemoveRequested = QtCore.Signal(object) def __init__(self, pos, size=Point(1, 1), angle=0.0, invertible=False, maxBounds=None, snapSize=1.0, scaleSnap=False, translateSnap=False, rotateSnap=False, parent=None, pen=None, movable=True, removable=False): #QObjectWorkaround.__init__(self) GraphicsObject.__init__(self, parent) self.setAcceptedMouseButtons(QtCore.Qt.NoButton) pos = Point(pos) size = Point(size) self.aspectLocked = False self.translatable = movable self.rotateAllowed = True self.removable = removable self.menu = None self.freeHandleMoved = False ## keep track of whether free handles have moved since last change signal was emitted. self.mouseHovering = False if pen is None: pen = (255, 255, 255) self.setPen(pen) self.handlePen = QtGui.QPen(QtGui.QColor(150, 255, 255)) self.handles = [] self.state = {'pos': Point(0,0), 'size': Point(1,1), 'angle': 0} ## angle is in degrees for ease of Qt integration self.lastState = None self.setPos(pos) self.setAngle(angle) self.setSize(size) self.setZValue(10) self.isMoving = False self.handleSize = 5 self.invertible = invertible self.maxBounds = maxBounds self.snapSize = snapSize self.translateSnap = translateSnap self.rotateSnap = rotateSnap self.scaleSnap = scaleSnap #self.setFlag(self.ItemIsSelectable, True) def getState(self): return self.stateCopy() def stateCopy(self): sc = {} sc['pos'] = Point(self.state['pos']) sc['size'] = Point(self.state['size']) sc['angle'] = self.state['angle'] return sc def saveState(self): """Return the state of the widget in a format suitable for storing to disk. (Points are converted to tuple) Combined with setState(), this allows ROIs to be easily saved and restored.""" state = {} state['pos'] = tuple(self.state['pos']) state['size'] = tuple(self.state['size']) state['angle'] = self.state['angle'] return state def setState(self, state, update=True): """ Set the state of the ROI from a structure generated by saveState() or getState(). """ self.setPos(state['pos'], update=False) self.setSize(state['size'], update=False) self.setAngle(state['angle'], update=update) def setZValue(self, z): QtGui.QGraphicsItem.setZValue(self, z) for h in self.handles: h['item'].setZValue(z+1) def parentBounds(self): """ Return the bounding rectangle of this ROI in the coordinate system of its parent. """ return self.mapToParent(self.boundingRect()).boundingRect() def setPen(self, *args, **kwargs): """ Set the pen to use when drawing the ROI shape. For arguments, see :func:`mkPen `. """ self.pen = fn.mkPen(*args, **kwargs) self.currentPen = self.pen self.update() def size(self): """Return the size (w,h) of the ROI.""" return self.getState()['size'] def pos(self): """Return the position (x,y) of the ROI's origin. For most ROIs, this will be the lower-left corner.""" return self.getState()['pos'] def angle(self): """Return the angle of the ROI in degrees.""" return self.getState()['angle'] def setPos(self, pos, y=None, update=True, finish=True): """Set the position of the ROI (in the parent's coordinate system). Accepts either separate (x, y) arguments or a single :class:`Point` or ``QPointF`` argument. By default, this method causes both ``sigRegionChanged`` and ``sigRegionChangeFinished`` to be emitted. If *finish* is False, then ``sigRegionChangeFinished`` will not be emitted. You can then use stateChangeFinished() to cause the signal to be emitted after a series of state changes. If *update* is False, the state change will be remembered but not processed and no signals will be emitted. You can then use stateChanged() to complete the state change. This allows multiple change functions to be called sequentially while minimizing processing overhead and repeated signals. Setting ``update=False`` also forces ``finish=False``. """ if y is None: pos = Point(pos) else: # avoid ambiguity where update is provided as a positional argument if isinstance(y, bool): raise TypeError("Positional arguments to setPos() must be numerical.") pos = Point(pos, y) self.state['pos'] = pos QtGui.QGraphicsItem.setPos(self, pos) if update: self.stateChanged(finish=finish) def setSize(self, size, update=True, finish=True): """Set the size of the ROI. May be specified as a QPoint, Point, or list of two values. See setPos() for an explanation of the update and finish arguments. """ size = Point(size) self.prepareGeometryChange() self.state['size'] = size if update: self.stateChanged(finish=finish) def setAngle(self, angle, update=True, finish=True): """Set the angle of rotation (in degrees) for this ROI. See setPos() for an explanation of the update and finish arguments. """ self.state['angle'] = angle tr = QtGui.QTransform() #tr.rotate(-angle * 180 / np.pi) tr.rotate(angle) self.setTransform(tr) if update: self.stateChanged(finish=finish) def scale(self, s, center=[0,0], update=True, finish=True): """ Resize the ROI by scaling relative to *center*. See setPos() for an explanation of the *update* and *finish* arguments. """ c = self.mapToParent(Point(center) * self.state['size']) self.prepareGeometryChange() newSize = self.state['size'] * s c1 = self.mapToParent(Point(center) * newSize) newPos = self.state['pos'] + c - c1 self.setSize(newSize, update=False) self.setPos(newPos, update=update, finish=finish) def translate(self, *args, **kargs): """ Move the ROI to a new position. Accepts either (x, y, snap) or ([x,y], snap) as arguments If the ROI is bounded and the move would exceed boundaries, then the ROI is moved to the nearest acceptable position instead. *snap* can be: =============== ========================================================================== None (default) use self.translateSnap and self.snapSize to determine whether/how to snap False do not snap Point(w,h) snap to rectangular grid with spacing (w,h) True snap using self.snapSize (and ignoring self.translateSnap) =============== ========================================================================== Also accepts *update* and *finish* arguments (see setPos() for a description of these). """ if len(args) == 1: pt = args[0] else: pt = args newState = self.stateCopy() newState['pos'] = newState['pos'] + pt ## snap position #snap = kargs.get('snap', None) #if (snap is not False) and not (snap is None and self.translateSnap is False): snap = kargs.get('snap', None) if snap is None: snap = self.translateSnap if snap is not False: newState['pos'] = self.getSnapPosition(newState['pos'], snap=snap) #d = ev.scenePos() - self.mapToScene(self.pressPos) if self.maxBounds is not None: r = self.stateRect(newState) #r0 = self.sceneTransform().mapRect(self.boundingRect()) d = Point(0,0) if self.maxBounds.left() > r.left(): d[0] = self.maxBounds.left() - r.left() elif self.maxBounds.right() < r.right(): d[0] = self.maxBounds.right() - r.right() if self.maxBounds.top() > r.top(): d[1] = self.maxBounds.top() - r.top() elif self.maxBounds.bottom() < r.bottom(): d[1] = self.maxBounds.bottom() - r.bottom() newState['pos'] += d #self.state['pos'] = newState['pos'] update = kargs.get('update', True) finish = kargs.get('finish', True) self.setPos(newState['pos'], update=update, finish=finish) #if 'update' not in kargs or kargs['update'] is True: #self.stateChanged() def rotate(self, angle, update=True, finish=True): """ Rotate the ROI by *angle* degrees. Also accepts *update* and *finish* arguments (see setPos() for a description of these). """ self.setAngle(self.angle()+angle, update=update, finish=finish) def handleMoveStarted(self): self.preMoveState = self.getState() def addTranslateHandle(self, pos, axes=None, item=None, name=None, index=None): """ Add a new translation handle to the ROI. Dragging the handle will move the entire ROI without changing its angle or shape. Note that, by default, ROIs may be moved by dragging anywhere inside the ROI. However, for larger ROIs it may be desirable to disable this and instead provide one or more translation handles. =================== ==================================================== **Arguments** pos (length-2 sequence) The position of the handle relative to the shape of the ROI. A value of (0,0) indicates the origin, whereas (1, 1) indicates the upper-right corner, regardless of the ROI's size. item The Handle instance to add. If None, a new handle will be created. name The name of this handle (optional). Handles are identified by name when calling getLocalHandlePositions and getSceneHandlePositions. =================== ==================================================== """ pos = Point(pos) return self.addHandle({'name': name, 'type': 't', 'pos': pos, 'item': item}, index=index) def addFreeHandle(self, pos=None, axes=None, item=None, name=None, index=None): """ Add a new free handle to the ROI. Dragging free handles has no effect on the position or shape of the ROI. =================== ==================================================== **Arguments** pos (length-2 sequence) The position of the handle relative to the shape of the ROI. A value of (0,0) indicates the origin, whereas (1, 1) indicates the upper-right corner, regardless of the ROI's size. item The Handle instance to add. If None, a new handle will be created. name The name of this handle (optional). Handles are identified by name when calling getLocalHandlePositions and getSceneHandlePositions. =================== ==================================================== """ if pos is not None: pos = Point(pos) return self.addHandle({'name': name, 'type': 'f', 'pos': pos, 'item': item}, index=index) def addScaleHandle(self, pos, center, axes=None, item=None, name=None, lockAspect=False, index=None): """ Add a new scale handle to the ROI. Dragging a scale handle allows the user to change the height and/or width of the ROI. =================== ==================================================== **Arguments** pos (length-2 sequence) The position of the handle relative to the shape of the ROI. A value of (0,0) indicates the origin, whereas (1, 1) indicates the upper-right corner, regardless of the ROI's size. center (length-2 sequence) The center point around which scaling takes place. If the center point has the same x or y value as the handle position, then scaling will be disabled for that axis. item The Handle instance to add. If None, a new handle will be created. name The name of this handle (optional). Handles are identified by name when calling getLocalHandlePositions and getSceneHandlePositions. =================== ==================================================== """ pos = Point(pos) center = Point(center) info = {'name': name, 'type': 's', 'center': center, 'pos': pos, 'item': item, 'lockAspect': lockAspect} if pos.x() == center.x(): info['xoff'] = True if pos.y() == center.y(): info['yoff'] = True return self.addHandle(info, index=index) def addRotateHandle(self, pos, center, item=None, name=None, index=None): """ Add a new rotation handle to the ROI. Dragging a rotation handle allows the user to change the angle of the ROI. =================== ==================================================== **Arguments** pos (length-2 sequence) The position of the handle relative to the shape of the ROI. A value of (0,0) indicates the origin, whereas (1, 1) indicates the upper-right corner, regardless of the ROI's size. center (length-2 sequence) The center point around which rotation takes place. item The Handle instance to add. If None, a new handle will be created. name The name of this handle (optional). Handles are identified by name when calling getLocalHandlePositions and getSceneHandlePositions. =================== ==================================================== """ pos = Point(pos) center = Point(center) return self.addHandle({'name': name, 'type': 'r', 'center': center, 'pos': pos, 'item': item}, index=index) def addScaleRotateHandle(self, pos, center, item=None, name=None, index=None): """ Add a new scale+rotation handle to the ROI. When dragging a handle of this type, the user can simultaneously rotate the ROI around an arbitrary center point as well as scale the ROI by dragging the handle toward or away from the center point. =================== ==================================================== **Arguments** pos (length-2 sequence) The position of the handle relative to the shape of the ROI. A value of (0,0) indicates the origin, whereas (1, 1) indicates the upper-right corner, regardless of the ROI's size. center (length-2 sequence) The center point around which scaling and rotation take place. item The Handle instance to add. If None, a new handle will be created. name The name of this handle (optional). Handles are identified by name when calling getLocalHandlePositions and getSceneHandlePositions. =================== ==================================================== """ pos = Point(pos) center = Point(center) if pos[0] != center[0] and pos[1] != center[1]: raise Exception("Scale/rotate handles must have either the same x or y coordinate as their center point.") return self.addHandle({'name': name, 'type': 'sr', 'center': center, 'pos': pos, 'item': item}, index=index) def addRotateFreeHandle(self, pos, center, axes=None, item=None, name=None, index=None): """ Add a new rotation+free handle to the ROI. When dragging a handle of this type, the user can rotate the ROI around an arbitrary center point, while moving toward or away from the center point has no effect on the shape of the ROI. =================== ==================================================== **Arguments** pos (length-2 sequence) The position of the handle relative to the shape of the ROI. A value of (0,0) indicates the origin, whereas (1, 1) indicates the upper-right corner, regardless of the ROI's size. center (length-2 sequence) The center point around which rotation takes place. item The Handle instance to add. If None, a new handle will be created. name The name of this handle (optional). Handles are identified by name when calling getLocalHandlePositions and getSceneHandlePositions. =================== ==================================================== """ pos = Point(pos) center = Point(center) return self.addHandle({'name': name, 'type': 'rf', 'center': center, 'pos': pos, 'item': item}, index=index) def addHandle(self, info, index=None): ## If a Handle was not supplied, create it now if 'item' not in info or info['item'] is None: h = Handle(self.handleSize, typ=info['type'], pen=self.handlePen, parent=self) h.setPos(info['pos'] * self.state['size']) info['item'] = h else: h = info['item'] if info['pos'] is None: info['pos'] = h.pos() ## connect the handle to this ROI #iid = len(self.handles) h.connectROI(self) if index is None: self.handles.append(info) else: self.handles.insert(index, info) h.setZValue(self.zValue()+1) self.stateChanged() return h def indexOfHandle(self, handle): """ Return the index of *handle* in the list of this ROI's handles. """ if isinstance(handle, Handle): index = [i for i, info in enumerate(self.handles) if info['item'] is handle] if len(index) == 0: raise Exception("Cannot return handle index; not attached to this ROI") return index[0] else: return handle def removeHandle(self, handle): """Remove a handle from this ROI. Argument may be either a Handle instance or the integer index of the handle.""" index = self.indexOfHandle(handle) handle = self.handles[index]['item'] self.handles.pop(index) handle.disconnectROI(self) if len(handle.rois) == 0: self.scene().removeItem(handle) self.stateChanged() def replaceHandle(self, oldHandle, newHandle): """Replace one handle in the ROI for another. This is useful when connecting multiple ROIs together. *oldHandle* may be a Handle instance or the index of a handle to be replaced.""" index = self.indexOfHandle(oldHandle) info = self.handles[index] self.removeHandle(index) info['item'] = newHandle info['pos'] = newHandle.pos() self.addHandle(info, index=index) def checkRemoveHandle(self, handle): ## This is used when displaying a Handle's context menu to determine ## whether removing is allowed. ## Subclasses may wish to override this to disable the menu entry. ## Note: by default, handles are not user-removable even if this method returns True. return True def getLocalHandlePositions(self, index=None): """Returns the position of handles in the ROI's coordinate system. The format returned is a list of (name, pos) tuples. """ if index == None: positions = [] for h in self.handles: positions.append((h['name'], h['pos'])) return positions else: return (self.handles[index]['name'], self.handles[index]['pos']) def getSceneHandlePositions(self, index=None): """Returns the position of handles in the scene coordinate system. The format returned is a list of (name, pos) tuples. """ if index == None: positions = [] for h in self.handles: positions.append((h['name'], h['item'].scenePos())) return positions else: return (self.handles[index]['name'], self.handles[index]['item'].scenePos()) def getHandles(self): """ Return a list of this ROI's Handles. """ return [h['item'] for h in self.handles] def mapSceneToParent(self, pt): return self.mapToParent(self.mapFromScene(pt)) def setSelected(self, s): QtGui.QGraphicsItem.setSelected(self, s) #print "select", self, s if s: for h in self.handles: h['item'].show() else: for h in self.handles: h['item'].hide() def hoverEvent(self, ev): hover = False if not ev.isExit(): if self.translatable and ev.acceptDrags(QtCore.Qt.LeftButton): hover=True for btn in [QtCore.Qt.LeftButton, QtCore.Qt.RightButton, QtCore.Qt.MidButton]: if int(self.acceptedMouseButtons() & btn) > 0 and ev.acceptClicks(btn): hover=True if self.contextMenuEnabled(): ev.acceptClicks(QtCore.Qt.RightButton) if hover: self.setMouseHover(True) self.sigHoverEvent.emit(self) ev.acceptClicks(QtCore.Qt.LeftButton) ## If the ROI is hilighted, we should accept all clicks to avoid confusion. ev.acceptClicks(QtCore.Qt.RightButton) ev.acceptClicks(QtCore.Qt.MidButton) else: self.setMouseHover(False) def setMouseHover(self, hover): ## Inform the ROI that the mouse is(not) hovering over it if self.mouseHovering == hover: return self.mouseHovering = hover self._updateHoverColor() def _updateHoverColor(self): pen = self._makePen() if self.currentPen != pen: self.currentPen = pen self.update() def _makePen(self): # Generate the pen color for this ROI based on its current state. if self.mouseHovering: return fn.mkPen(255, 255, 0) else: return self.pen def contextMenuEnabled(self): return self.removable def raiseContextMenu(self, ev): if not self.contextMenuEnabled(): return menu = self.getMenu() menu = self.scene().addParentContextMenus(self, menu, ev) pos = ev.screenPos() menu.popup(QtCore.QPoint(pos.x(), pos.y())) def getMenu(self): if self.menu is None: self.menu = QtGui.QMenu() self.menu.setTitle("ROI") remAct = QtGui.QAction("Remove ROI", self.menu) remAct.triggered.connect(self.removeClicked) self.menu.addAction(remAct) self.menu.remAct = remAct return self.menu def removeClicked(self): ## Send remove event only after we have exited the menu event handler QtCore.QTimer.singleShot(0, lambda: self.sigRemoveRequested.emit(self)) def mouseDragEvent(self, ev): if ev.isStart(): #p = ev.pos() #if not self.isMoving and not self.shape().contains(p): #ev.ignore() #return if ev.button() == QtCore.Qt.LeftButton: self.setSelected(True) if self.translatable: self.isMoving = True self.preMoveState = self.getState() self.cursorOffset = self.pos() - self.mapToParent(ev.buttonDownPos()) self.sigRegionChangeStarted.emit(self) ev.accept() else: ev.ignore() elif ev.isFinish(): if self.translatable: if self.isMoving: self.stateChangeFinished() self.isMoving = False return if self.translatable and self.isMoving and ev.buttons() == QtCore.Qt.LeftButton: snap = True if (ev.modifiers() & QtCore.Qt.ControlModifier) else None newPos = self.mapToParent(ev.pos()) + self.cursorOffset self.translate(newPos - self.pos(), snap=snap, finish=False) def mouseClickEvent(self, ev): if ev.button() == QtCore.Qt.RightButton and self.isMoving: ev.accept() self.cancelMove() if ev.button() == QtCore.Qt.RightButton and self.contextMenuEnabled(): self.raiseContextMenu(ev) ev.accept() elif int(ev.button() & self.acceptedMouseButtons()) > 0: ev.accept() self.sigClicked.emit(self, ev) else: ev.ignore() def cancelMove(self): self.isMoving = False self.setState(self.preMoveState) def checkPointMove(self, handle, pos, modifiers): """When handles move, they must ask the ROI if the move is acceptable. By default, this always returns True. Subclasses may wish override. """ return True def movePoint(self, handle, pos, modifiers=QtCore.Qt.KeyboardModifier(), finish=True, coords='parent'): ## called by Handles when they are moved. ## pos is the new position of the handle in scene coords, as requested by the handle. newState = self.stateCopy() index = self.indexOfHandle(handle) h = self.handles[index] p0 = self.mapToParent(h['pos'] * self.state['size']) p1 = Point(pos) if coords == 'parent': pass elif coords == 'scene': p1 = self.mapSceneToParent(p1) else: raise Exception("New point location must be given in either 'parent' or 'scene' coordinates.") ## transform p0 and p1 into parent's coordinates (same as scene coords if there is no parent). I forget why. #p0 = self.mapSceneToParent(p0) #p1 = self.mapSceneToParent(p1) ## Handles with a 'center' need to know their local position relative to the center point (lp0, lp1) if 'center' in h: c = h['center'] cs = c * self.state['size'] lp0 = self.mapFromParent(p0) - cs lp1 = self.mapFromParent(p1) - cs if h['type'] == 't': snap = True if (modifiers & QtCore.Qt.ControlModifier) else None #if self.translateSnap or (): #snap = Point(self.snapSize, self.snapSize) self.translate(p1-p0, snap=snap, update=False) elif h['type'] == 'f': newPos = self.mapFromParent(p1) h['item'].setPos(newPos) h['pos'] = newPos self.freeHandleMoved = True #self.sigRegionChanged.emit(self) ## should be taken care of by call to stateChanged() elif h['type'] == 's': ## If a handle and its center have the same x or y value, we can't scale across that axis. if h['center'][0] == h['pos'][0]: lp1[0] = 0 if h['center'][1] == h['pos'][1]: lp1[1] = 0 ## snap if self.scaleSnap or (modifiers & QtCore.Qt.ControlModifier): lp1[0] = round(lp1[0] / self.snapSize) * self.snapSize lp1[1] = round(lp1[1] / self.snapSize) * self.snapSize ## preserve aspect ratio (this can override snapping) if h['lockAspect'] or (modifiers & QtCore.Qt.AltModifier): #arv = Point(self.preMoveState['size']) - lp1 = lp1.proj(lp0) ## determine scale factors and new size of ROI hs = h['pos'] - c if hs[0] == 0: hs[0] = 1 if hs[1] == 0: hs[1] = 1 newSize = lp1 / hs ## Perform some corrections and limit checks if newSize[0] == 0: newSize[0] = newState['size'][0] if newSize[1] == 0: newSize[1] = newState['size'][1] if not self.invertible: if newSize[0] < 0: newSize[0] = newState['size'][0] if newSize[1] < 0: newSize[1] = newState['size'][1] if self.aspectLocked: newSize[0] = newSize[1] ## Move ROI so the center point occupies the same scene location after the scale s0 = c * self.state['size'] s1 = c * newSize cc = self.mapToParent(s0 - s1) - self.mapToParent(Point(0, 0)) ## update state, do more boundary checks newState['size'] = newSize newState['pos'] = newState['pos'] + cc if self.maxBounds is not None: r = self.stateRect(newState) if not self.maxBounds.contains(r): return self.setPos(newState['pos'], update=False) self.setSize(newState['size'], update=False) elif h['type'] in ['r', 'rf']: if h['type'] == 'rf': self.freeHandleMoved = True if not self.rotateAllowed: return ## If the handle is directly over its center point, we can't compute an angle. try: if lp1.length() == 0 or lp0.length() == 0: return except OverflowError: return ## determine new rotation angle, constrained if necessary ang = newState['angle'] - lp0.angle(lp1) if ang is None: ## this should never happen.. return if self.rotateSnap or (modifiers & QtCore.Qt.ControlModifier): ang = round(ang / 15.) * 15. ## 180/12 = 15 ## create rotation transform tr = QtGui.QTransform() tr.rotate(ang) ## move ROI so that center point remains stationary after rotate cc = self.mapToParent(cs) - (tr.map(cs) + self.state['pos']) newState['angle'] = ang newState['pos'] = newState['pos'] + cc ## check boundaries, update if self.maxBounds is not None: r = self.stateRect(newState) if not self.maxBounds.contains(r): return #self.setTransform(tr) self.setPos(newState['pos'], update=False) self.setAngle(ang, update=False) #self.state = newState ## If this is a free-rotate handle, its distance from the center may change. if h['type'] == 'rf': h['item'].setPos(self.mapFromScene(p1)) ## changes ROI coordinates of handle elif h['type'] == 'sr': if h['center'][0] == h['pos'][0]: scaleAxis = 1 nonScaleAxis=0 else: scaleAxis = 0 nonScaleAxis=1 try: if lp1.length() == 0 or lp0.length() == 0: return except OverflowError: return ang = newState['angle'] - lp0.angle(lp1) if ang is None: return if self.rotateSnap or (modifiers & QtCore.Qt.ControlModifier): #ang = round(ang / (np.pi/12.)) * (np.pi/12.) ang = round(ang / 15.) * 15. hs = abs(h['pos'][scaleAxis] - c[scaleAxis]) newState['size'][scaleAxis] = lp1.length() / hs #if self.scaleSnap or (modifiers & QtCore.Qt.ControlModifier): if self.scaleSnap: ## use CTRL only for angular snap here. newState['size'][scaleAxis] = round(newState['size'][scaleAxis] / self.snapSize) * self.snapSize if newState['size'][scaleAxis] == 0: newState['size'][scaleAxis] = 1 if self.aspectLocked: newState['size'][nonScaleAxis] = newState['size'][scaleAxis] c1 = c * newState['size'] tr = QtGui.QTransform() tr.rotate(ang) cc = self.mapToParent(cs) - (tr.map(c1) + self.state['pos']) newState['angle'] = ang newState['pos'] = newState['pos'] + cc if self.maxBounds is not None: r = self.stateRect(newState) if not self.maxBounds.contains(r): return #self.setTransform(tr) #self.setPos(newState['pos'], update=False) #self.prepareGeometryChange() #self.state = newState self.setState(newState, update=False) self.stateChanged(finish=finish) def stateChanged(self, finish=True): """Process changes to the state of the ROI. If there are any changes, then the positions of handles are updated accordingly and sigRegionChanged is emitted. If finish is True, then sigRegionChangeFinished will also be emitted.""" changed = False if self.lastState is None: changed = True else: state = self.getState() for k in list(state.keys()): if state[k] != self.lastState[k]: changed = True self.prepareGeometryChange() if changed: ## Move all handles to match the current configuration of the ROI for h in self.handles: if h['item'] in self.childItems(): p = h['pos'] h['item'].setPos(h['pos'] * self.state['size']) #else: # trans = self.state['pos']-self.lastState['pos'] # h['item'].setPos(h['pos'] + h['item'].parentItem().mapFromParent(trans)) self.update() self.sigRegionChanged.emit(self) elif self.freeHandleMoved: self.sigRegionChanged.emit(self) self.freeHandleMoved = False self.lastState = self.getState() if finish: self.stateChangeFinished() self.informViewBoundsChanged() def stateChangeFinished(self): self.sigRegionChangeFinished.emit(self) def stateRect(self, state): r = QtCore.QRectF(0, 0, state['size'][0], state['size'][1]) tr = QtGui.QTransform() #tr.rotate(-state['angle'] * 180 / np.pi) tr.rotate(-state['angle']) r = tr.mapRect(r) return r.adjusted(state['pos'][0], state['pos'][1], state['pos'][0], state['pos'][1]) def getSnapPosition(self, pos, snap=None): ## Given that pos has been requested, return the nearest snap-to position ## optionally, snap may be passed in to specify a rectangular snap grid. ## override this function for more interesting snap functionality.. if snap is None or snap is True: if self.snapSize is None: return pos snap = Point(self.snapSize, self.snapSize) return Point( round(pos[0] / snap[0]) * snap[0], round(pos[1] / snap[1]) * snap[1] ) def boundingRect(self): return QtCore.QRectF(0, 0, self.state['size'][0], self.state['size'][1]).normalized() def paint(self, p, opt, widget): # p.save() # Note: don't use self.boundingRect here, because subclasses may need to redefine it. r = QtCore.QRectF(0, 0, self.state['size'][0], self.state['size'][1]).normalized() p.setRenderHint(QtGui.QPainter.Antialiasing) p.setPen(self.currentPen) p.translate(r.left(), r.top()) p.scale(r.width(), r.height()) p.drawRect(0, 0, 1, 1) # p.restore() def getArraySlice(self, data, img, axes=(0,1), returnSlice=True): """Return a tuple of slice objects that can be used to slice the region from *data* that is covered by the bounding rectangle of this ROI. Also returns the transform that maps the ROI into data coordinates. If returnSlice is set to False, the function returns a pair of tuples with the values that would have been used to generate the slice objects. ((ax0Start, ax0Stop), (ax1Start, ax1Stop)) If the slice cannot be computed (usually because the scene/transforms are not properly constructed yet), then the method returns None. """ ## Determine shape of array along ROI axes dShape = (data.shape[axes[0]], data.shape[axes[1]]) ## Determine transform that maps ROI bounding box to image coordinates try: tr = self.sceneTransform() * fn.invertQTransform(img.sceneTransform()) except np.linalg.linalg.LinAlgError: return None ## Modify transform to scale from image coords to data coords axisOrder = img.axisOrder if axisOrder == 'row-major': tr.scale(float(dShape[1]) / img.width(), float(dShape[0]) / img.height()) else: tr.scale(float(dShape[0]) / img.width(), float(dShape[1]) / img.height()) ## Transform ROI bounds into data bounds dataBounds = tr.mapRect(self.boundingRect()) ## Intersect transformed ROI bounds with data bounds if axisOrder == 'row-major': intBounds = dataBounds.intersected(QtCore.QRectF(0, 0, dShape[1], dShape[0])) else: intBounds = dataBounds.intersected(QtCore.QRectF(0, 0, dShape[0], dShape[1])) ## Determine index values to use when referencing the array. bounds = ( (int(min(intBounds.left(), intBounds.right())), int(1+max(intBounds.left(), intBounds.right()))), (int(min(intBounds.bottom(), intBounds.top())), int(1+max(intBounds.bottom(), intBounds.top()))) ) if axisOrder == 'row-major': bounds = bounds[::-1] if returnSlice: ## Create slice objects sl = [slice(None)] * data.ndim sl[axes[0]] = slice(*bounds[0]) sl[axes[1]] = slice(*bounds[1]) return tuple(sl), tr else: return bounds, tr def getArrayRegion(self, data, img, axes=(0,1), returnMappedCoords=False, **kwds): """Use the position and orientation of this ROI relative to an imageItem to pull a slice from an array. =================== ==================================================== **Arguments** data The array to slice from. Note that this array does *not* have to be the same data that is represented in *img*. img (ImageItem or other suitable QGraphicsItem) Used to determine the relationship between the ROI and the boundaries of *data*. axes (length-2 tuple) Specifies the axes in *data* that correspond to the (x, y) axes of *img*. If the image's axis order is set to 'row-major', then the axes are instead specified in (y, x) order. returnMappedCoords (bool) If True, the array slice is returned along with a corresponding array of coordinates that were used to extract data from the original array. \**kwds All keyword arguments are passed to :func:`affineSlice `. =================== ==================================================== This method uses :func:`affineSlice ` to generate the slice from *data* and uses :func:`getAffineSliceParams ` to determine the parameters to pass to :func:`affineSlice `. If *returnMappedCoords* is True, then the method returns a tuple (result, coords) such that coords is the set of coordinates used to interpolate values from the original data, mapped into the parent coordinate system of the image. This is useful, when slicing data from images that have been transformed, for determining the location of each value in the sliced data. All extra keyword arguments are passed to :func:`affineSlice `. """ # this is a hidden argument for internal use fromBR = kwds.pop('fromBoundingRect', False) shape, vectors, origin = self.getAffineSliceParams(data, img, axes, fromBoundingRect=fromBR) if not returnMappedCoords: rgn = fn.affineSlice(data, shape=shape, vectors=vectors, origin=origin, axes=axes, **kwds) return rgn else: kwds['returnCoords'] = True result, coords = fn.affineSlice(data, shape=shape, vectors=vectors, origin=origin, axes=axes, **kwds) ### map coordinates and return mapped = fn.transformCoordinates(img.transform(), coords) return result, mapped def getAffineSliceParams(self, data, img, axes=(0,1), fromBoundingRect=False): """ Returns the parameters needed to use :func:`affineSlice ` (shape, vectors, origin) to extract a subset of *data* using this ROI and *img* to specify the subset. If *fromBoundingRect* is True, then the ROI's bounding rectangle is used rather than the shape of the ROI. See :func:`getArrayRegion ` for more information. """ if self.scene() is not img.scene(): raise Exception("ROI and target item must be members of the same scene.") origin = img.mapToData(self.mapToItem(img, QtCore.QPointF(0, 0))) ## vx and vy point in the directions of the slice axes, but must be scaled properly vx = img.mapToData(self.mapToItem(img, QtCore.QPointF(1, 0))) - origin vy = img.mapToData(self.mapToItem(img, QtCore.QPointF(0, 1))) - origin lvx = np.sqrt(vx.x()**2 + vx.y()**2) lvy = np.sqrt(vy.x()**2 + vy.y()**2) #pxLen = img.width() / float(data.shape[axes[0]]) ##img.width is number of pixels, not width of item. ##need pxWidth and pxHeight instead of pxLen ? #sx = pxLen / lvx #sy = pxLen / lvy sx = 1.0 / lvx sy = 1.0 / lvy vectors = ((vx.x()*sx, vx.y()*sx), (vy.x()*sy, vy.y()*sy)) if fromBoundingRect is True: shape = self.boundingRect().width(), self.boundingRect().height() origin = img.mapToData(self.mapToItem(img, self.boundingRect().topLeft())) origin = (origin.x(), origin.y()) else: shape = self.state['size'] origin = (origin.x(), origin.y()) shape = [abs(shape[0]/sx), abs(shape[1]/sy)] if img.axisOrder == 'row-major': # transpose output vectors = vectors[::-1] shape = shape[::-1] return shape, vectors, origin def renderShapeMask(self, width, height): """Return an array of 0.0-1.0 into which the shape of the item has been drawn. This can be used to mask array selections. """ if width == 0 or height == 0: return np.empty((width, height), dtype=float) # QImage(width, height, format) im = QtGui.QImage(width, height, QtGui.QImage.Format_ARGB32) im.fill(0x0) p = QtGui.QPainter(im) p.setPen(fn.mkPen(None)) p.setBrush(fn.mkBrush('w')) shape = self.shape() bounds = shape.boundingRect() p.scale(im.width() / bounds.width(), im.height() / bounds.height()) p.translate(-bounds.topLeft()) p.drawPath(shape) p.end() mask = fn.imageToArray(im, transpose=True)[:,:,0].astype(float) / 255. return mask def getGlobalTransform(self, relativeTo=None): """Return global transformation (rotation angle+translation) required to move from relative state to current state. If relative state isn't specified, then we use the state of the ROI when mouse is pressed.""" if relativeTo == None: relativeTo = self.preMoveState st = self.getState() ## this is only allowed because we will be comparing the two relativeTo['scale'] = relativeTo['size'] st['scale'] = st['size'] t1 = SRTTransform(relativeTo) t2 = SRTTransform(st) return t2/t1 #st = self.getState() ### rotation #ang = (st['angle']-relativeTo['angle']) * 180. / 3.14159265358 #rot = QtGui.QTransform() #rot.rotate(-ang) ### We need to come up with a universal transformation--one that can be applied to other objects ### such that all maintain alignment. ### More specifically, we need to turn the ROI's position and angle into ### a rotation _around the origin_ and a translation. #p0 = Point(relativeTo['pos']) ### base position, rotated #p1 = rot.map(p0) #trans = Point(st['pos']) - p1 #return trans, ang def applyGlobalTransform(self, tr): st = self.getState() st['scale'] = st['size'] st = SRTTransform(st) st = (st * tr).saveState() st['size'] = st['scale'] self.setState(st) class Handle(UIGraphicsItem): """ Handle represents a single user-interactable point attached to an ROI. They are usually created by a call to one of the ROI.add___Handle() methods. Handles are represented as a square, diamond, or circle, and are drawn with fixed pixel size regardless of the scaling of the view they are displayed in. Handles may be dragged to change the position, size, orientation, or other properties of the ROI they are attached to. """ types = { ## defines number of sides, start angle for each handle type 't': (4, np.pi/4), 'f': (4, np.pi/4), 's': (4, 0), 'r': (12, 0), 'sr': (12, 0), 'rf': (12, 0), } sigClicked = QtCore.Signal(object, object) # self, event sigRemoveRequested = QtCore.Signal(object) # self def __init__(self, radius, typ=None, pen=(200, 200, 220), parent=None, deletable=False): #print " create item with parent", parent #self.bounds = QtCore.QRectF(-1e-10, -1e-10, 2e-10, 2e-10) #self.setFlags(self.ItemIgnoresTransformations | self.ItemSendsScenePositionChanges) self.rois = [] self.radius = radius self.typ = typ self.pen = fn.mkPen(pen) self.currentPen = self.pen self.pen.setWidth(0) self.pen.setCosmetic(True) self.isMoving = False self.sides, self.startAng = self.types[typ] self.buildPath() self._shape = None self.menu = self.buildMenu() UIGraphicsItem.__init__(self, parent=parent) self.setAcceptedMouseButtons(QtCore.Qt.NoButton) self.deletable = deletable if deletable: self.setAcceptedMouseButtons(QtCore.Qt.RightButton) #self.updateShape() self.setZValue(11) def connectROI(self, roi): ### roi is the "parent" roi, i is the index of the handle in roi.handles self.rois.append(roi) def disconnectROI(self, roi): self.rois.remove(roi) #for i, r in enumerate(self.roi): #if r[0] == roi: #self.roi.pop(i) #def close(self): #for r in self.roi: #r.removeHandle(self) def setDeletable(self, b): self.deletable = b if b: self.setAcceptedMouseButtons(self.acceptedMouseButtons() | QtCore.Qt.RightButton) else: self.setAcceptedMouseButtons(self.acceptedMouseButtons() & ~QtCore.Qt.RightButton) def removeClicked(self): self.sigRemoveRequested.emit(self) def hoverEvent(self, ev): hover = False if not ev.isExit(): if ev.acceptDrags(QtCore.Qt.LeftButton): hover=True for btn in [QtCore.Qt.LeftButton, QtCore.Qt.RightButton, QtCore.Qt.MidButton]: if int(self.acceptedMouseButtons() & btn) > 0 and ev.acceptClicks(btn): hover=True if hover: self.currentPen = fn.mkPen(255, 255,0) else: self.currentPen = self.pen self.update() #if (not ev.isExit()) and ev.acceptDrags(QtCore.Qt.LeftButton): #self.currentPen = fn.mkPen(255, 255,0) #else: #self.currentPen = self.pen #self.update() def mouseClickEvent(self, ev): ## right-click cancels drag if ev.button() == QtCore.Qt.RightButton and self.isMoving: self.isMoving = False ## prevents any further motion self.movePoint(self.startPos, finish=True) #for r in self.roi: #r[0].cancelMove() ev.accept() elif int(ev.button() & self.acceptedMouseButtons()) > 0: ev.accept() if ev.button() == QtCore.Qt.RightButton and self.deletable: self.raiseContextMenu(ev) self.sigClicked.emit(self, ev) else: ev.ignore() #elif self.deletable: #ev.accept() #self.raiseContextMenu(ev) #else: #ev.ignore() def buildMenu(self): menu = QtGui.QMenu() menu.setTitle("Handle") self.removeAction = menu.addAction("Remove handle", self.removeClicked) return menu def getMenu(self): return self.menu def raiseContextMenu(self, ev): menu = self.scene().addParentContextMenus(self, self.getMenu(), ev) ## Make sure it is still ok to remove this handle removeAllowed = all([r.checkRemoveHandle(self) for r in self.rois]) self.removeAction.setEnabled(removeAllowed) pos = ev.screenPos() menu.popup(QtCore.QPoint(pos.x(), pos.y())) def mouseDragEvent(self, ev): if ev.button() != QtCore.Qt.LeftButton: return ev.accept() ## Inform ROIs that a drag is happening ## note: the ROI is informed that the handle has moved using ROI.movePoint ## this is for other (more nefarious) purposes. #for r in self.roi: #r[0].pointDragEvent(r[1], ev) if ev.isFinish(): if self.isMoving: for r in self.rois: r.stateChangeFinished() self.isMoving = False elif ev.isStart(): for r in self.rois: r.handleMoveStarted() self.isMoving = True self.startPos = self.scenePos() self.cursorOffset = self.scenePos() - ev.buttonDownScenePos() if self.isMoving: ## note: isMoving may become False in mid-drag due to right-click. pos = ev.scenePos() + self.cursorOffset self.movePoint(pos, ev.modifiers(), finish=False) def movePoint(self, pos, modifiers=QtCore.Qt.KeyboardModifier(), finish=True): for r in self.rois: if not r.checkPointMove(self, pos, modifiers): return #print "point moved; inform %d ROIs" % len(self.roi) # A handle can be used by multiple ROIs; tell each to update its handle position for r in self.rois: r.movePoint(self, pos, modifiers, finish=finish, coords='scene') def buildPath(self): size = self.radius self.path = QtGui.QPainterPath() ang = self.startAng dt = 2*np.pi / self.sides for i in range(0, self.sides+1): x = size * cos(ang) y = size * sin(ang) ang += dt if i == 0: self.path.moveTo(x, y) else: self.path.lineTo(x, y) def paint(self, p, opt, widget): ### determine rotation of transform #m = self.sceneTransform() ##mi = m.inverted()[0] #v = m.map(QtCore.QPointF(1, 0)) - m.map(QtCore.QPointF(0, 0)) #va = np.arctan2(v.y(), v.x()) ### Determine length of unit vector in painter's coords ##size = mi.map(Point(self.radius, self.radius)) - mi.map(Point(0, 0)) ##size = (size.x()*size.x() + size.y() * size.y()) ** 0.5 #size = self.radius #bounds = QtCore.QRectF(-size, -size, size*2, size*2) #if bounds != self.bounds: #self.bounds = bounds #self.prepareGeometryChange() p.setRenderHints(p.Antialiasing, True) p.setPen(self.currentPen) #p.rotate(va * 180. / 3.1415926) #p.drawPath(self.path) p.drawPath(self.shape()) #ang = self.startAng + va #dt = 2*np.pi / self.sides #for i in range(0, self.sides): #x1 = size * cos(ang) #y1 = size * sin(ang) #x2 = size * cos(ang+dt) #y2 = size * sin(ang+dt) #ang += dt #p.drawLine(Point(x1, y1), Point(x2, y2)) def shape(self): if self._shape is None: s = self.generateShape() if s is None: return self.path self._shape = s self.prepareGeometryChange() ## beware--this can cause the view to adjust, which would immediately invalidate the shape. return self._shape def boundingRect(self): #print 'roi:', self.roi s1 = self.shape() #print " s1:", s1 #s2 = self.shape() #print " s2:", s2 return self.shape().boundingRect() def generateShape(self): ## determine rotation of transform #m = self.sceneTransform() ## Qt bug: do not access sceneTransform() until we know this object has a scene. #mi = m.inverted()[0] dt = self.deviceTransform() if dt is None: self._shape = self.path return None v = dt.map(QtCore.QPointF(1, 0)) - dt.map(QtCore.QPointF(0, 0)) va = np.arctan2(v.y(), v.x()) dti = fn.invertQTransform(dt) devPos = dt.map(QtCore.QPointF(0,0)) tr = QtGui.QTransform() tr.translate(devPos.x(), devPos.y()) tr.rotate(va * 180. / 3.1415926) return dti.map(tr.map(self.path)) def viewTransformChanged(self): GraphicsObject.viewTransformChanged(self) self._shape = None ## invalidate shape, recompute later if requested. self.update() #def itemChange(self, change, value): #if change == self.ItemScenePositionHasChanged: #self.updateShape() class TestROI(ROI): def __init__(self, pos, size, **args): #QtGui.QGraphicsRectItem.__init__(self, pos[0], pos[1], size[0], size[1]) ROI.__init__(self, pos, size, **args) #self.addTranslateHandle([0, 0]) self.addTranslateHandle([0.5, 0.5]) self.addScaleHandle([1, 1], [0, 0]) self.addScaleHandle([0, 0], [1, 1]) self.addScaleRotateHandle([1, 0.5], [0.5, 0.5]) self.addScaleHandle([0.5, 1], [0.5, 0.5]) self.addRotateHandle([1, 0], [0, 0]) self.addRotateHandle([0, 1], [1, 1]) class RectROI(ROI): """ Rectangular ROI subclass with a single scale handle at the top-right corner. ============== ============================================================= **Arguments** pos (length-2 sequence) The position of the ROI origin. See ROI(). size (length-2 sequence) The size of the ROI. See ROI(). centered (bool) If True, scale handles affect the ROI relative to its center, rather than its origin. sideScalers (bool) If True, extra scale handles are added at the top and right edges. \**args All extra keyword arguments are passed to ROI() ============== ============================================================= """ def __init__(self, pos, size, centered=False, sideScalers=False, **args): #QtGui.QGraphicsRectItem.__init__(self, 0, 0, size[0], size[1]) ROI.__init__(self, pos, size, **args) if centered: center = [0.5, 0.5] else: center = [0, 0] #self.addTranslateHandle(center) self.addScaleHandle([1, 1], center) if sideScalers: self.addScaleHandle([1, 0.5], [center[0], 0.5]) self.addScaleHandle([0.5, 1], [0.5, center[1]]) class LineROI(ROI): """ Rectangular ROI subclass with scale-rotate handles on either side. This allows the ROI to be positioned as if moving the ends of a line segment. A third handle controls the width of the ROI orthogonal to its "line" axis. ============== ============================================================= **Arguments** pos1 (length-2 sequence) The position of the center of the ROI's left edge. pos2 (length-2 sequence) The position of the center of the ROI's right edge. width (float) The width of the ROI. \**args All extra keyword arguments are passed to ROI() ============== ============================================================= """ def __init__(self, pos1, pos2, width, **args): pos1 = Point(pos1) pos2 = Point(pos2) d = pos2-pos1 l = d.length() ang = Point(1, 0).angle(d) ra = ang * np.pi / 180. c = Point(-width/2. * sin(ra), -width/2. * cos(ra)) pos1 = pos1 + c ROI.__init__(self, pos1, size=Point(l, width), angle=ang, **args) self.addScaleRotateHandle([0, 0.5], [1, 0.5]) self.addScaleRotateHandle([1, 0.5], [0, 0.5]) self.addScaleHandle([0.5, 1], [0.5, 0.5]) class MultiRectROI(QtGui.QGraphicsObject): """ Chain of rectangular ROIs connected by handles. This is generally used to mark a curved path through an image similarly to PolyLineROI. It differs in that each segment of the chain is rectangular instead of linear and thus has width. ============== ============================================================= **Arguments** points (list of length-2 sequences) The list of points in the path. width (float) The width of the ROIs orthogonal to the path. \**args All extra keyword arguments are passed to ROI() ============== ============================================================= """ sigRegionChangeFinished = QtCore.Signal(object) sigRegionChangeStarted = QtCore.Signal(object) sigRegionChanged = QtCore.Signal(object) def __init__(self, points, width, pen=None, **args): QtGui.QGraphicsObject.__init__(self) self.pen = pen self.roiArgs = args self.lines = [] if len(points) < 2: raise Exception("Must start with at least 2 points") ## create first segment self.addSegment(points[1], connectTo=points[0], scaleHandle=True) ## create remaining segments for p in points[2:]: self.addSegment(p) def paint(self, *args): pass def boundingRect(self): return QtCore.QRectF() def roiChangedEvent(self): w = self.lines[0].state['size'][1] for l in self.lines[1:]: w0 = l.state['size'][1] if w == w0: continue l.scale([1.0, w/w0], center=[0.5,0.5]) self.sigRegionChanged.emit(self) def roiChangeStartedEvent(self): self.sigRegionChangeStarted.emit(self) def roiChangeFinishedEvent(self): self.sigRegionChangeFinished.emit(self) def getHandlePositions(self): """Return the positions of all handles in local coordinates.""" pos = [self.mapFromScene(self.lines[0].getHandles()[0].scenePos())] for l in self.lines: pos.append(self.mapFromScene(l.getHandles()[1].scenePos())) return pos def getArrayRegion(self, arr, img=None, axes=(0,1), **kwds): rgns = [] for l in self.lines: rgn = l.getArrayRegion(arr, img, axes=axes, **kwds) if rgn is None: continue #return None rgns.append(rgn) #print l.state['size'] ## make sure orthogonal axis is the same size ## (sometimes fp errors cause differences) if img.axisOrder == 'row-major': axes = axes[::-1] ms = min([r.shape[axes[1]] for r in rgns]) sl = [slice(None)] * rgns[0].ndim sl[axes[1]] = slice(0,ms) rgns = [r[sl] for r in rgns] #print [r.shape for r in rgns], axes return np.concatenate(rgns, axis=axes[0]) def addSegment(self, pos=(0,0), scaleHandle=False, connectTo=None): """ Add a new segment to the ROI connecting from the previous endpoint to *pos*. (pos is specified in the parent coordinate system of the MultiRectROI) """ ## by default, connect to the previous endpoint if connectTo is None: connectTo = self.lines[-1].getHandles()[1] ## create new ROI newRoi = ROI((0,0), [1, 5], parent=self, pen=self.pen, **self.roiArgs) self.lines.append(newRoi) ## Add first SR handle if isinstance(connectTo, Handle): self.lines[-1].addScaleRotateHandle([0, 0.5], [1, 0.5], item=connectTo) newRoi.movePoint(connectTo, connectTo.scenePos(), coords='scene') else: h = self.lines[-1].addScaleRotateHandle([0, 0.5], [1, 0.5]) newRoi.movePoint(h, connectTo, coords='scene') ## add second SR handle h = self.lines[-1].addScaleRotateHandle([1, 0.5], [0, 0.5]) newRoi.movePoint(h, pos) ## optionally add scale handle (this MUST come after the two SR handles) if scaleHandle: newRoi.addScaleHandle([0.5, 1], [0.5, 0.5]) newRoi.translatable = False newRoi.sigRegionChanged.connect(self.roiChangedEvent) newRoi.sigRegionChangeStarted.connect(self.roiChangeStartedEvent) newRoi.sigRegionChangeFinished.connect(self.roiChangeFinishedEvent) self.sigRegionChanged.emit(self) def removeSegment(self, index=-1): """Remove a segment from the ROI.""" roi = self.lines[index] self.lines.pop(index) self.scene().removeItem(roi) roi.sigRegionChanged.disconnect(self.roiChangedEvent) roi.sigRegionChangeStarted.disconnect(self.roiChangeStartedEvent) roi.sigRegionChangeFinished.disconnect(self.roiChangeFinishedEvent) self.sigRegionChanged.emit(self) class MultiLineROI(MultiRectROI): def __init__(self, *args, **kwds): MultiRectROI.__init__(self, *args, **kwds) print("Warning: MultiLineROI has been renamed to MultiRectROI. (and MultiLineROI may be redefined in the future)") class EllipseROI(ROI): """ Elliptical ROI subclass with one scale handle and one rotation handle. ============== ============================================================= **Arguments** pos (length-2 sequence) The position of the ROI's origin. size (length-2 sequence) The size of the ROI's bounding rectangle. \**args All extra keyword arguments are passed to ROI() ============== ============================================================= """ def __init__(self, pos, size, **args): #QtGui.QGraphicsRectItem.__init__(self, 0, 0, size[0], size[1]) ROI.__init__(self, pos, size, **args) self.addRotateHandle([1.0, 0.5], [0.5, 0.5]) self.addScaleHandle([0.5*2.**-0.5 + 0.5, 0.5*2.**-0.5 + 0.5], [0.5, 0.5]) def paint(self, p, opt, widget): r = self.boundingRect() p.setRenderHint(QtGui.QPainter.Antialiasing) p.setPen(self.currentPen) p.scale(r.width(), r.height())## workaround for GL bug r = QtCore.QRectF(r.x()/r.width(), r.y()/r.height(), 1,1) p.drawEllipse(r) def getArrayRegion(self, arr, img=None, axes=(0, 1), **kwds): """ Return the result of ROI.getArrayRegion() masked by the elliptical shape of the ROI. Regions outside the ellipse are set to 0. """ # Note: we could use the same method as used by PolyLineROI, but this # implementation produces a nicer mask. arr = ROI.getArrayRegion(self, arr, img, axes, **kwds) if arr is None or arr.shape[axes[0]] == 0 or arr.shape[axes[1]] == 0: return arr w = arr.shape[axes[0]] h = arr.shape[axes[1]] ## generate an ellipsoidal mask mask = np.fromfunction(lambda x,y: (((x+0.5)/(w/2.)-1)**2+ ((y+0.5)/(h/2.)-1)**2)**0.5 < 1, (w, h)) # reshape to match array axes if axes[0] > axes[1]: mask = mask.T shape = [(n if i in axes else 1) for i,n in enumerate(arr.shape)] mask = mask.reshape(shape) return arr * mask def shape(self): self.path = QtGui.QPainterPath() self.path.addEllipse(self.boundingRect()) return self.path class CircleROI(EllipseROI): """ Circular ROI subclass. Behaves exactly as EllipseROI, but may only be scaled proportionally to maintain its aspect ratio. ============== ============================================================= **Arguments** pos (length-2 sequence) The position of the ROI's origin. size (length-2 sequence) The size of the ROI's bounding rectangle. \**args All extra keyword arguments are passed to ROI() ============== ============================================================= """ def __init__(self, pos, size, **args): ROI.__init__(self, pos, size, **args) self.aspectLocked = True #self.addTranslateHandle([0.5, 0.5]) self.addScaleHandle([0.5*2.**-0.5 + 0.5, 0.5*2.**-0.5 + 0.5], [0.5, 0.5]) class PolygonROI(ROI): ## deprecated. Use PloyLineROI instead. def __init__(self, positions, pos=None, **args): if pos is None: pos = [0,0] ROI.__init__(self, pos, [1,1], **args) #ROI.__init__(self, positions[0]) for p in positions: self.addFreeHandle(p) self.setZValue(1000) print("Warning: PolygonROI is deprecated. Use PolyLineROI instead.") def listPoints(self): return [p['item'].pos() for p in self.handles] #def movePoint(self, *args, **kargs): #ROI.movePoint(self, *args, **kargs) #self.prepareGeometryChange() #for h in self.handles: #h['pos'] = h['item'].pos() def paint(self, p, *args): p.setRenderHint(QtGui.QPainter.Antialiasing) p.setPen(self.currentPen) for i in range(len(self.handles)): h1 = self.handles[i]['item'].pos() h2 = self.handles[i-1]['item'].pos() p.drawLine(h1, h2) def boundingRect(self): r = QtCore.QRectF() for h in self.handles: r |= self.mapFromItem(h['item'], h['item'].boundingRect()).boundingRect() ## |= gives the union of the two QRectFs return r def shape(self): p = QtGui.QPainterPath() p.moveTo(self.handles[0]['item'].pos()) for i in range(len(self.handles)): p.lineTo(self.handles[i]['item'].pos()) return p def stateCopy(self): sc = {} sc['pos'] = Point(self.state['pos']) sc['size'] = Point(self.state['size']) sc['angle'] = self.state['angle'] #sc['handles'] = self.handles return sc class PolyLineROI(ROI): """ Container class for multiple connected LineSegmentROIs. This class allows the user to draw paths of multiple line segments. ============== ============================================================= **Arguments** positions (list of length-2 sequences) The list of points in the path. Note that, unlike the handle positions specified in other ROIs, these positions must be expressed in the normal coordinate system of the ROI, rather than (0 to 1) relative to the size of the ROI. closed (bool) if True, an extra LineSegmentROI is added connecting the beginning and end points. \**args All extra keyword arguments are passed to ROI() ============== ============================================================= """ def __init__(self, positions, closed=False, pos=None, **args): if pos is None: pos = [0,0] self.closed = closed self.segments = [] ROI.__init__(self, pos, size=[1,1], **args) self.setPoints(positions) def setPoints(self, points, closed=None): """ Set the complete sequence of points displayed by this ROI. ============= ========================================================= **Arguments** points List of (x,y) tuples specifying handle locations to set. closed If bool, then this will set whether the ROI is closed (the last point is connected to the first point). If None, then the closed mode is left unchanged. ============= ========================================================= """ if closed is not None: self.closed = closed self.clearPoints() for p in points: self.addFreeHandle(p) start = -1 if self.closed else 0 for i in range(start, len(self.handles)-1): self.addSegment(self.handles[i]['item'], self.handles[i+1]['item']) def clearPoints(self): """ Remove all handles and segments. """ while len(self.handles) > 0: self.removeHandle(self.handles[0]['item']) def getState(self): state = ROI.getState(self) state['closed'] = self.closed state['points'] = [Point(h.pos()) for h in self.getHandles()] return state def saveState(self): state = ROI.saveState(self) state['closed'] = self.closed state['points'] = [tuple(h.pos()) for h in self.getHandles()] return state def setState(self, state): ROI.setState(self, state) self.setPoints(state['points'], closed=state['closed']) def addSegment(self, h1, h2, index=None): seg = _PolyLineSegment(handles=(h1, h2), pen=self.pen, parent=self, movable=False) if index is None: self.segments.append(seg) else: self.segments.insert(index, seg) seg.sigClicked.connect(self.segmentClicked) seg.setAcceptedMouseButtons(QtCore.Qt.LeftButton) seg.setZValue(self.zValue()+1) for h in seg.handles: h['item'].setDeletable(True) h['item'].setAcceptedMouseButtons(h['item'].acceptedMouseButtons() | QtCore.Qt.LeftButton) ## have these handles take left clicks too, so that handles cannot be added on top of other handles def setMouseHover(self, hover): ## Inform all the ROI's segments that the mouse is(not) hovering over it ROI.setMouseHover(self, hover) for s in self.segments: s.setParentHover(hover) def addHandle(self, info, index=None): h = ROI.addHandle(self, info, index=index) h.sigRemoveRequested.connect(self.removeHandle) self.stateChanged(finish=True) return h def segmentClicked(self, segment, ev=None, pos=None): ## pos should be in this item's coordinate system if ev != None: pos = segment.mapToParent(ev.pos()) elif pos != None: pos = pos else: raise Exception("Either an event or a position must be given.") h1 = segment.handles[0]['item'] h2 = segment.handles[1]['item'] i = self.segments.index(segment) h3 = self.addFreeHandle(pos, index=self.indexOfHandle(h2)) self.addSegment(h3, h2, index=i+1) segment.replaceHandle(h2, h3) def removeHandle(self, handle, updateSegments=True): ROI.removeHandle(self, handle) handle.sigRemoveRequested.disconnect(self.removeHandle) if not updateSegments: return segments = handle.rois[:] if len(segments) == 1: self.removeSegment(segments[0]) elif len(segments) > 1: handles = [h['item'] for h in segments[1].handles] handles.remove(handle) segments[0].replaceHandle(handle, handles[0]) self.removeSegment(segments[1]) self.stateChanged(finish=True) def removeSegment(self, seg): for handle in seg.handles[:]: seg.removeHandle(handle['item']) self.segments.remove(seg) seg.sigClicked.disconnect(self.segmentClicked) self.scene().removeItem(seg) def checkRemoveHandle(self, h): ## called when a handle is about to display its context menu if self.closed: return len(self.handles) > 3 else: return len(self.handles) > 2 def paint(self, p, *args): pass def boundingRect(self): return self.shape().boundingRect() def shape(self): p = QtGui.QPainterPath() if len(self.handles) == 0: return p p.moveTo(self.handles[0]['item'].pos()) for i in range(len(self.handles)): p.lineTo(self.handles[i]['item'].pos()) p.lineTo(self.handles[0]['item'].pos()) return p def getArrayRegion(self, data, img, axes=(0,1), **kwds): """ Return the result of ROI.getArrayRegion(), masked by the shape of the ROI. Values outside the ROI shape are set to 0. """ br = self.boundingRect() if br.width() > 1000: raise Exception() sliced = ROI.getArrayRegion(self, data, img, axes=axes, fromBoundingRect=True, **kwds) if img.axisOrder == 'col-major': mask = self.renderShapeMask(sliced.shape[axes[0]], sliced.shape[axes[1]]) else: mask = self.renderShapeMask(sliced.shape[axes[1]], sliced.shape[axes[0]]) mask = mask.T # reshape mask to ensure it is applied to the correct data axes shape = [1] * data.ndim shape[axes[0]] = sliced.shape[axes[0]] shape[axes[1]] = sliced.shape[axes[1]] mask = mask.reshape(shape) return sliced * mask def setPen(self, *args, **kwds): ROI.setPen(self, *args, **kwds) for seg in self.segments: seg.setPen(*args, **kwds) class LineSegmentROI(ROI): """ ROI subclass with two freely-moving handles defining a line. ============== ============================================================= **Arguments** positions (list of two length-2 sequences) The endpoints of the line segment. Note that, unlike the handle positions specified in other ROIs, these positions must be expressed in the normal coordinate system of the ROI, rather than (0 to 1) relative to the size of the ROI. \**args All extra keyword arguments are passed to ROI() ============== ============================================================= """ def __init__(self, positions=(None, None), pos=None, handles=(None,None), **args): if pos is None: pos = [0,0] ROI.__init__(self, pos, [1,1], **args) #ROI.__init__(self, positions[0]) if len(positions) > 2: raise Exception("LineSegmentROI must be defined by exactly 2 positions. For more points, use PolyLineROI.") for i, p in enumerate(positions): self.addFreeHandle(p, item=handles[i]) def listPoints(self): return [p['item'].pos() for p in self.handles] def paint(self, p, *args): p.setRenderHint(QtGui.QPainter.Antialiasing) p.setPen(self.currentPen) h1 = self.handles[0]['item'].pos() h2 = self.handles[1]['item'].pos() p.drawLine(h1, h2) def boundingRect(self): return self.shape().boundingRect() def shape(self): p = QtGui.QPainterPath() h1 = self.handles[0]['item'].pos() h2 = self.handles[1]['item'].pos() dh = h2-h1 if dh.length() == 0: return p pxv = self.pixelVectors(dh)[1] if pxv is None: return p pxv *= 4 p.moveTo(h1+pxv) p.lineTo(h2+pxv) p.lineTo(h2-pxv) p.lineTo(h1-pxv) p.lineTo(h1+pxv) return p def getArrayRegion(self, data, img, axes=(0,1), order=1, **kwds): """ Use the position of this ROI relative to an imageItem to pull a slice from an array. Since this pulls 1D data from a 2D coordinate system, the return value will have ndim = data.ndim-1 See ROI.getArrayRegion() for a description of the arguments. """ imgPts = [self.mapToItem(img, h['item'].pos()) for h in self.handles] rgns = [] for i in range(len(imgPts)-1): d = Point(imgPts[i+1] - imgPts[i]) o = Point(imgPts[i]) r = fn.affineSlice(data, shape=(int(d.length()),), vectors=[Point(d.norm())], origin=o, axes=axes, order=order, **kwds) rgns.append(r) return np.concatenate(rgns, axis=axes[0]) class _PolyLineSegment(LineSegmentROI): # Used internally by PolyLineROI def __init__(self, *args, **kwds): self._parentHovering = False LineSegmentROI.__init__(self, *args, **kwds) def setParentHover(self, hover): # set independently of own hover state if self._parentHovering != hover: self._parentHovering = hover self._updateHoverColor() def _makePen(self): if self.mouseHovering or self._parentHovering: return fn.mkPen(255, 255, 0) else: return self.pen def hoverEvent(self, ev): # accept drags even though we discard them to prevent competition with parent ROI # (unless parent ROI is not movable) if self.parentItem().translatable: ev.acceptDrags(QtCore.Qt.LeftButton) return LineSegmentROI.hoverEvent(self, ev) class SpiralROI(ROI): def __init__(self, pos=None, size=None, **args): if size == None: size = [100e-6,100e-6] if pos == None: pos = [0,0] ROI.__init__(self, pos, size, **args) self.translateSnap = False self.addFreeHandle([0.25,0], name='a') self.addRotateFreeHandle([1,0], [0,0], name='r') #self.getRadius() #QtCore.connect(self, QtCore.SIGNAL('regionChanged'), self. def getRadius(self): radius = Point(self.handles[1]['item'].pos()).length() #r2 = radius[1] #r3 = r2[0] return radius def boundingRect(self): r = self.getRadius() return QtCore.QRectF(-r*1.1, -r*1.1, 2.2*r, 2.2*r) #return self.bounds #def movePoint(self, *args, **kargs): #ROI.movePoint(self, *args, **kargs) #self.prepareGeometryChange() #for h in self.handles: #h['pos'] = h['item'].pos()/self.state['size'][0] def stateChanged(self, finish=True): ROI.stateChanged(self, finish=finish) if len(self.handles) > 1: self.path = QtGui.QPainterPath() h0 = Point(self.handles[0]['item'].pos()).length() a = h0/(2.0*np.pi) theta = 30.0*(2.0*np.pi)/360.0 self.path.moveTo(QtCore.QPointF(a*theta*cos(theta), a*theta*sin(theta))) x0 = a*theta*cos(theta) y0 = a*theta*sin(theta) radius = self.getRadius() theta += 20.0*(2.0*np.pi)/360.0 i = 0 while Point(x0, y0).length() < radius and i < 1000: x1 = a*theta*cos(theta) y1 = a*theta*sin(theta) self.path.lineTo(QtCore.QPointF(x1,y1)) theta += 20.0*(2.0*np.pi)/360.0 x0 = x1 y0 = y1 i += 1 return self.path def shape(self): p = QtGui.QPainterPath() p.addEllipse(self.boundingRect()) return p def paint(self, p, *args): p.setRenderHint(QtGui.QPainter.Antialiasing) #path = self.shape() p.setPen(self.currentPen) p.drawPath(self.path) p.setPen(QtGui.QPen(QtGui.QColor(255,0,0))) p.drawPath(self.shape()) p.setPen(QtGui.QPen(QtGui.QColor(0,0,255))) p.drawRect(self.boundingRect()) class CrosshairROI(ROI): """A crosshair ROI whose position is at the center of the crosshairs. By default, it is scalable, rotatable and translatable.""" def __init__(self, pos=None, size=None, **kargs): if size == None: #size = [100e-6,100e-6] size=[1,1] if pos == None: pos = [0,0] self._shape = None ROI.__init__(self, pos, size, **kargs) self.sigRegionChanged.connect(self.invalidate) self.addScaleRotateHandle(Point(1, 0), Point(0, 0)) self.aspectLocked = True def invalidate(self): self._shape = None self.prepareGeometryChange() def boundingRect(self): #size = self.size() #return QtCore.QRectF(-size[0]/2., -size[1]/2., size[0], size[1]).normalized() return self.shape().boundingRect() #def getRect(self): ### same as boundingRect -- for internal use so that boundingRect can be re-implemented in subclasses #size = self.size() #return QtCore.QRectF(-size[0]/2., -size[1]/2., size[0], size[1]).normalized() def shape(self): if self._shape is None: radius = self.getState()['size'][1] p = QtGui.QPainterPath() p.moveTo(Point(0, -radius)) p.lineTo(Point(0, radius)) p.moveTo(Point(-radius, 0)) p.lineTo(Point(radius, 0)) p = self.mapToDevice(p) stroker = QtGui.QPainterPathStroker() stroker.setWidth(10) outline = stroker.createStroke(p) self._shape = self.mapFromDevice(outline) ##h1 = self.handles[0]['item'].pos() ##h2 = self.handles[1]['item'].pos() #w1 = Point(-0.5, 0)*self.size() #w2 = Point(0.5, 0)*self.size() #h1 = Point(0, -0.5)*self.size() #h2 = Point(0, 0.5)*self.size() #dh = h2-h1 #dw = w2-w1 #if dh.length() == 0 or dw.length() == 0: #return p #pxv = self.pixelVectors(dh)[1] #if pxv is None: #return p #pxv *= 4 #p.moveTo(h1+pxv) #p.lineTo(h2+pxv) #p.lineTo(h2-pxv) #p.lineTo(h1-pxv) #p.lineTo(h1+pxv) #pxv = self.pixelVectors(dw)[1] #if pxv is None: #return p #pxv *= 4 #p.moveTo(w1+pxv) #p.lineTo(w2+pxv) #p.lineTo(w2-pxv) #p.lineTo(w1-pxv) #p.lineTo(w1+pxv) return self._shape def paint(self, p, *args): #p.save() #r = self.getRect() radius = self.getState()['size'][1] p.setRenderHint(QtGui.QPainter.Antialiasing) p.setPen(self.currentPen) #p.translate(r.left(), r.top()) #p.scale(r.width()/10., r.height()/10.) ## need to scale up a little because drawLine has trouble dealing with 0.5 #p.drawLine(0,5, 10,5) #p.drawLine(5,0, 5,10) #p.restore() p.drawLine(Point(0, -radius), Point(0, radius)) p.drawLine(Point(-radius, 0), Point(radius, 0)) ����������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/ScaleBar.py��������������������������������������0000664�0000000�0000000�00000004357�13007271214�0024501�0����������������������������������������������������������������������������������������������������ustar�00root����������������������������root����������������������������0000000�0000000������������������������������������������������������������������������������������������������������������������������������������������������������������������������from ..Qt import QtGui, QtCore from .GraphicsObject import * from .GraphicsWidgetAnchor import * from .TextItem import TextItem import numpy as np from .. import functions as fn from .. import getConfigOption from ..Point import Point __all__ = ['ScaleBar'] class ScaleBar(GraphicsObject, GraphicsWidgetAnchor): """ Displays a rectangular bar to indicate the relative scale of objects on the view. """ def __init__(self, size, width=5, brush=None, pen=None, suffix='m', offset=None): GraphicsObject.__init__(self) GraphicsWidgetAnchor.__init__(self) self.setFlag(self.ItemHasNoContents) self.setAcceptedMouseButtons(QtCore.Qt.NoButton) if brush is None: brush = getConfigOption('foreground') self.brush = fn.mkBrush(brush) self.pen = fn.mkPen(pen) self._width = width self.size = size if offset == None: offset = (0,0) self.offset = offset self.bar = QtGui.QGraphicsRectItem() self.bar.setPen(self.pen) self.bar.setBrush(self.brush) self.bar.setParentItem(self) self.text = TextItem(text=fn.siFormat(size, suffix=suffix), anchor=(0.5,1)) self.text.setParentItem(self) def parentChanged(self): view = self.parentItem() if view is None: return view.sigRangeChanged.connect(self.updateBar) self.updateBar() def updateBar(self): view = self.parentItem() if view is None: return p1 = view.mapFromViewToItem(self, QtCore.QPointF(0,0)) p2 = view.mapFromViewToItem(self, QtCore.QPointF(self.size,0)) w = (p2-p1).x() self.bar.setRect(QtCore.QRectF(-w, 0, w, self._width)) self.text.setPos(-w/2., 0) def boundingRect(self): return QtCore.QRectF() def setParentItem(self, p): ret = GraphicsObject.setParentItem(self, p) if self.offset is not None: offset = Point(self.offset) anchorx = 1 if offset[0] <= 0 else 0 anchory = 1 if offset[1] <= 0 else 0 anchor = (anchorx, anchory) self.anchor(itemPos=anchor, parentPos=anchor, offset=offset) return ret ���������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/ScatterPlotItem.py�������������������������������0000664�0000000�0000000�00000111421�13007271214�0026077�0����������������������������������������������������������������������������������������������������ustar�00root����������������������������root����������������������������0000000�0000000������������������������������������������������������������������������������������������������������������������������������������������������������������������������from itertools import starmap, repeat try: from itertools import imap except ImportError: imap = map import numpy as np import weakref from ..Qt import QtGui, QtCore, USE_PYSIDE, USE_PYQT5 from ..Point import Point from .. import functions as fn from .GraphicsItem import GraphicsItem from .GraphicsObject import GraphicsObject from .. import getConfigOption from ..pgcollections import OrderedDict from .. import debug from ..python2_3 import basestring __all__ = ['ScatterPlotItem', 'SpotItem'] ## Build all symbol paths Symbols = OrderedDict([(name, QtGui.QPainterPath()) for name in ['o', 's', 't', 't1', 't2', 't3','d', '+', 'x', 'p', 'h', 'star']]) Symbols['o'].addEllipse(QtCore.QRectF(-0.5, -0.5, 1, 1)) Symbols['s'].addRect(QtCore.QRectF(-0.5, -0.5, 1, 1)) coords = { 't': [(-0.5, -0.5), (0, 0.5), (0.5, -0.5)], 't1': [(-0.5, 0.5), (0, -0.5), (0.5, 0.5)], 't2': [(-0.5, -0.5), (-0.5, 0.5), (0.5, 0)], 't3': [(0.5, 0.5), (0.5, -0.5), (-0.5, 0)], 'd': [(0., -0.5), (-0.4, 0.), (0, 0.5), (0.4, 0)], '+': [ (-0.5, -0.05), (-0.5, 0.05), (-0.05, 0.05), (-0.05, 0.5), (0.05, 0.5), (0.05, 0.05), (0.5, 0.05), (0.5, -0.05), (0.05, -0.05), (0.05, -0.5), (-0.05, -0.5), (-0.05, -0.05) ], 'p': [(0, -0.5), (-0.4755, -0.1545), (-0.2939, 0.4045), (0.2939, 0.4045), (0.4755, -0.1545)], 'h': [(0.433, 0.25), (0., 0.5), (-0.433, 0.25), (-0.433, -0.25), (0, -0.5), (0.433, -0.25)], 'star': [(0, -0.5), (-0.1123, -0.1545), (-0.4755, -0.1545), (-0.1816, 0.059), (-0.2939, 0.4045), (0, 0.1910), (0.2939, 0.4045), (0.1816, 0.059), (0.4755, -0.1545), (0.1123, -0.1545)] } for k, c in coords.items(): Symbols[k].moveTo(*c[0]) for x,y in c[1:]: Symbols[k].lineTo(x, y) Symbols[k].closeSubpath() tr = QtGui.QTransform() tr.rotate(45) Symbols['x'] = tr.map(Symbols['+']) def drawSymbol(painter, symbol, size, pen, brush): if symbol is None: return painter.scale(size, size) painter.setPen(pen) painter.setBrush(brush) if isinstance(symbol, basestring): symbol = Symbols[symbol] if np.isscalar(symbol): symbol = list(Symbols.values())[symbol % len(Symbols)] painter.drawPath(symbol) def renderSymbol(symbol, size, pen, brush, device=None): """ Render a symbol specification to QImage. Symbol may be either a QPainterPath or one of the keys in the Symbols dict. If *device* is None, a new QPixmap will be returned. Otherwise, the symbol will be rendered into the device specified (See QPainter documentation for more information). """ ## Render a spot with the given parameters to a pixmap penPxWidth = max(np.ceil(pen.widthF()), 1) if device is None: device = QtGui.QImage(int(size+penPxWidth), int(size+penPxWidth), QtGui.QImage.Format_ARGB32) device.fill(0) p = QtGui.QPainter(device) try: p.setRenderHint(p.Antialiasing) p.translate(device.width()*0.5, device.height()*0.5) drawSymbol(p, symbol, size, pen, brush) finally: p.end() return device def makeSymbolPixmap(size, pen, brush, symbol): ## deprecated img = renderSymbol(symbol, size, pen, brush) return QtGui.QPixmap(img) class SymbolAtlas(object): """ Used to efficiently construct a single QPixmap containing all rendered symbols for a ScatterPlotItem. This is required for fragment rendering. Use example: atlas = SymbolAtlas() sc1 = atlas.getSymbolCoords('o', 5, QPen(..), QBrush(..)) sc2 = atlas.getSymbolCoords('t', 10, QPen(..), QBrush(..)) pm = atlas.getAtlas() """ def __init__(self): # symbol key : QRect(...) coordinates where symbol can be found in atlas. # note that the coordinate list will always be the same list object as # long as the symbol is in the atlas, but the coordinates may # change if the atlas is rebuilt. # weak value; if all external refs to this list disappear, # the symbol will be forgotten. self.symbolMap = weakref.WeakValueDictionary() self.atlasData = None # numpy array of atlas image self.atlas = None # atlas as QPixmap self.atlasValid = False self.max_width=0 def getSymbolCoords(self, opts): """ Given a list of spot records, return an object representing the coordinates of that symbol within the atlas """ sourceRect = np.empty(len(opts), dtype=object) keyi = None sourceRecti = None for i, rec in enumerate(opts): key = (rec[3], rec[2], id(rec[4]), id(rec[5])) # TODO: use string indexes? if key == keyi: sourceRect[i] = sourceRecti else: try: sourceRect[i] = self.symbolMap[key] except KeyError: newRectSrc = QtCore.QRectF() newRectSrc.pen = rec['pen'] newRectSrc.brush = rec['brush'] self.symbolMap[key] = newRectSrc self.atlasValid = False sourceRect[i] = newRectSrc keyi = key sourceRecti = newRectSrc return sourceRect def buildAtlas(self): # get rendered array for all symbols, keep track of avg/max width rendered = {} avgWidth = 0.0 maxWidth = 0 images = [] for key, sourceRect in self.symbolMap.items(): if sourceRect.width() == 0: img = renderSymbol(key[0], key[1], sourceRect.pen, sourceRect.brush) images.append(img) ## we only need this to prevent the images being garbage collected immediately arr = fn.imageToArray(img, copy=False, transpose=False) else: (y,x,h,w) = sourceRect.getRect() arr = self.atlasData[int(x):int(x+w), int(y):int(y+w)] rendered[key] = arr w = arr.shape[0] avgWidth += w maxWidth = max(maxWidth, w) nSymbols = len(rendered) if nSymbols > 0: avgWidth /= nSymbols width = max(maxWidth, avgWidth * (nSymbols**0.5)) else: avgWidth = 0 width = 0 # sort symbols by height symbols = sorted(rendered.keys(), key=lambda x: rendered[x].shape[1], reverse=True) self.atlasRows = [] x = width y = 0 rowheight = 0 for key in symbols: arr = rendered[key] w,h = arr.shape[:2] if x+w > width: y += rowheight x = 0 rowheight = h self.atlasRows.append([y, rowheight, 0]) self.symbolMap[key].setRect(y, x, h, w) x += w self.atlasRows[-1][2] = x height = y + rowheight self.atlasData = np.zeros((int(width), int(height), 4), dtype=np.ubyte) for key in symbols: y, x, h, w = self.symbolMap[key].getRect() self.atlasData[int(x):int(x+w), int(y):int(y+h)] = rendered[key] self.atlas = None self.atlasValid = True self.max_width = maxWidth def getAtlas(self): if not self.atlasValid: self.buildAtlas() if self.atlas is None: if len(self.atlasData) == 0: return QtGui.QPixmap(0,0) img = fn.makeQImage(self.atlasData, copy=False, transpose=False) self.atlas = QtGui.QPixmap(img) return self.atlas class ScatterPlotItem(GraphicsObject): """ Displays a set of x/y points. Instances of this class are created automatically as part of PlotDataItem; these rarely need to be instantiated directly. The size, shape, pen, and fill brush may be set for each point individually or for all points. ======================== =============================================== **Signals:** sigPlotChanged(self) Emitted when the data being plotted has changed sigClicked(self, points) Emitted when the curve is clicked. Sends a list of all the points under the mouse pointer. ======================== =============================================== """ #sigPointClicked = QtCore.Signal(object, object) sigClicked = QtCore.Signal(object, object) ## self, points sigPlotChanged = QtCore.Signal(object) def __init__(self, *args, **kargs): """ Accepts the same arguments as setData() """ profiler = debug.Profiler() GraphicsObject.__init__(self) self.picture = None # QPicture used for rendering when pxmode==False self.fragmentAtlas = SymbolAtlas() self.data = np.empty(0, dtype=[('x', float), ('y', float), ('size', float), ('symbol', object), ('pen', object), ('brush', object), ('data', object), ('item', object), ('sourceRect', object), ('targetRect', object), ('width', float)]) self.bounds = [None, None] ## caches data bounds self._maxSpotWidth = 0 ## maximum size of the scale-variant portion of all spots self._maxSpotPxWidth = 0 ## maximum size of the scale-invariant portion of all spots self.opts = { 'pxMode': True, 'useCache': True, ## If useCache is False, symbols are re-drawn on every paint. 'antialias': getConfigOption('antialias'), 'name': None, } self.setPen(fn.mkPen(getConfigOption('foreground')), update=False) self.setBrush(fn.mkBrush(100,100,150), update=False) self.setSymbol('o', update=False) self.setSize(7, update=False) profiler() self.setData(*args, **kargs) profiler('setData') #self.setCacheMode(self.DeviceCoordinateCache) def setData(self, *args, **kargs): """ **Ordered Arguments:** * If there is only one unnamed argument, it will be interpreted like the 'spots' argument. * If there are two unnamed arguments, they will be interpreted as sequences of x and y values. ====================== =============================================================================================== **Keyword Arguments:** *spots* Optional list of dicts. Each dict specifies parameters for a single spot: {'pos': (x,y), 'size', 'pen', 'brush', 'symbol'}. This is just an alternate method of passing in data for the corresponding arguments. *x*,*y* 1D arrays of x,y values. *pos* 2D structure of x,y pairs (such as Nx2 array or list of tuples) *pxMode* If True, spots are always the same size regardless of scaling, and size is given in px. Otherwise, size is in scene coordinates and the spots scale with the view. Default is True *symbol* can be one (or a list) of: * 'o' circle (default) * 's' square * 't' triangle * 'd' diamond * '+' plus * any QPainterPath to specify custom symbol shapes. To properly obey the position and size, custom symbols should be centered at (0,0) and width and height of 1.0. Note that it is also possible to 'install' custom shapes by setting ScatterPlotItem.Symbols[key] = shape. *pen* The pen (or list of pens) to use for drawing spot outlines. *brush* The brush (or list of brushes) to use for filling spots. *size* The size (or list of sizes) of spots. If *pxMode* is True, this value is in pixels. Otherwise, it is in the item's local coordinate system. *data* a list of python objects used to uniquely identify each spot. *identical* *Deprecated*. This functionality is handled automatically now. *antialias* Whether to draw symbols with antialiasing. Note that if pxMode is True, symbols are always rendered with antialiasing (since the rendered symbols can be cached, this incurs very little performance cost) *name* The name of this item. Names are used for automatically generating LegendItem entries and by some exporters. ====================== =============================================================================================== """ oldData = self.data ## this causes cached pixmaps to be preserved while new data is registered. self.clear() ## clear out all old data self.addPoints(*args, **kargs) def addPoints(self, *args, **kargs): """ Add new points to the scatter plot. Arguments are the same as setData() """ ## deal with non-keyword arguments if len(args) == 1: kargs['spots'] = args[0] elif len(args) == 2: kargs['x'] = args[0] kargs['y'] = args[1] elif len(args) > 2: raise Exception('Only accepts up to two non-keyword arguments.') ## convert 'pos' argument to 'x' and 'y' if 'pos' in kargs: pos = kargs['pos'] if isinstance(pos, np.ndarray): kargs['x'] = pos[:,0] kargs['y'] = pos[:,1] else: x = [] y = [] for p in pos: if isinstance(p, QtCore.QPointF): x.append(p.x()) y.append(p.y()) else: x.append(p[0]) y.append(p[1]) kargs['x'] = x kargs['y'] = y ## determine how many spots we have if 'spots' in kargs: numPts = len(kargs['spots']) elif 'y' in kargs and kargs['y'] is not None: numPts = len(kargs['y']) else: kargs['x'] = [] kargs['y'] = [] numPts = 0 ## Extend record array oldData = self.data self.data = np.empty(len(oldData)+numPts, dtype=self.data.dtype) ## note that np.empty initializes object fields to None and string fields to '' self.data[:len(oldData)] = oldData #for i in range(len(oldData)): #oldData[i]['item']._data = self.data[i] ## Make sure items have proper reference to new array newData = self.data[len(oldData):] newData['size'] = -1 ## indicates to use default size if 'spots' in kargs: spots = kargs['spots'] for i in range(len(spots)): spot = spots[i] for k in spot: if k == 'pos': pos = spot[k] if isinstance(pos, QtCore.QPointF): x,y = pos.x(), pos.y() else: x,y = pos[0], pos[1] newData[i]['x'] = x newData[i]['y'] = y elif k == 'pen': newData[i][k] = fn.mkPen(spot[k]) elif k == 'brush': newData[i][k] = fn.mkBrush(spot[k]) elif k in ['x', 'y', 'size', 'symbol', 'brush', 'data']: newData[i][k] = spot[k] else: raise Exception("Unknown spot parameter: %s" % k) elif 'y' in kargs: newData['x'] = kargs['x'] newData['y'] = kargs['y'] if 'pxMode' in kargs: self.setPxMode(kargs['pxMode']) if 'antialias' in kargs: self.opts['antialias'] = kargs['antialias'] ## Set any extra parameters provided in keyword arguments for k in ['pen', 'brush', 'symbol', 'size']: if k in kargs: setMethod = getattr(self, 'set' + k[0].upper() + k[1:]) setMethod(kargs[k], update=False, dataSet=newData, mask=kargs.get('mask', None)) if 'data' in kargs: self.setPointData(kargs['data'], dataSet=newData) self.prepareGeometryChange() self.informViewBoundsChanged() self.bounds = [None, None] self.invalidate() self.updateSpots(newData) self.sigPlotChanged.emit(self) def invalidate(self): ## clear any cached drawing state self.picture = None self.update() def getData(self): return self.data['x'], self.data['y'] def setPoints(self, *args, **kargs): ##Deprecated; use setData return self.setData(*args, **kargs) def implements(self, interface=None): ints = ['plotData'] if interface is None: return ints return interface in ints def name(self): return self.opts.get('name', None) def setPen(self, *args, **kargs): """Set the pen(s) used to draw the outline around each spot. If a list or array is provided, then the pen for each spot will be set separately. Otherwise, the arguments are passed to pg.mkPen and used as the default pen for all spots which do not have a pen explicitly set.""" update = kargs.pop('update', True) dataSet = kargs.pop('dataSet', self.data) if len(args) == 1 and (isinstance(args[0], np.ndarray) or isinstance(args[0], list)): pens = args[0] if 'mask' in kargs and kargs['mask'] is not None: pens = pens[kargs['mask']] if len(pens) != len(dataSet): raise Exception("Number of pens does not match number of points (%d != %d)" % (len(pens), len(dataSet))) dataSet['pen'] = pens else: self.opts['pen'] = fn.mkPen(*args, **kargs) dataSet['sourceRect'] = None if update: self.updateSpots(dataSet) def setBrush(self, *args, **kargs): """Set the brush(es) used to fill the interior of each spot. If a list or array is provided, then the brush for each spot will be set separately. Otherwise, the arguments are passed to pg.mkBrush and used as the default brush for all spots which do not have a brush explicitly set.""" update = kargs.pop('update', True) dataSet = kargs.pop('dataSet', self.data) if len(args) == 1 and (isinstance(args[0], np.ndarray) or isinstance(args[0], list)): brushes = args[0] if 'mask' in kargs and kargs['mask'] is not None: brushes = brushes[kargs['mask']] if len(brushes) != len(dataSet): raise Exception("Number of brushes does not match number of points (%d != %d)" % (len(brushes), len(dataSet))) dataSet['brush'] = brushes else: self.opts['brush'] = fn.mkBrush(*args, **kargs) #self._spotPixmap = None dataSet['sourceRect'] = None if update: self.updateSpots(dataSet) def setSymbol(self, symbol, update=True, dataSet=None, mask=None): """Set the symbol(s) used to draw each spot. If a list or array is provided, then the symbol for each spot will be set separately. Otherwise, the argument will be used as the default symbol for all spots which do not have a symbol explicitly set.""" if dataSet is None: dataSet = self.data if isinstance(symbol, np.ndarray) or isinstance(symbol, list): symbols = symbol if mask is not None: symbols = symbols[mask] if len(symbols) != len(dataSet): raise Exception("Number of symbols does not match number of points (%d != %d)" % (len(symbols), len(dataSet))) dataSet['symbol'] = symbols else: self.opts['symbol'] = symbol self._spotPixmap = None dataSet['sourceRect'] = None if update: self.updateSpots(dataSet) def setSize(self, size, update=True, dataSet=None, mask=None): """Set the size(s) used to draw each spot. If a list or array is provided, then the size for each spot will be set separately. Otherwise, the argument will be used as the default size for all spots which do not have a size explicitly set.""" if dataSet is None: dataSet = self.data if isinstance(size, np.ndarray) or isinstance(size, list): sizes = size if mask is not None: sizes = sizes[mask] if len(sizes) != len(dataSet): raise Exception("Number of sizes does not match number of points (%d != %d)" % (len(sizes), len(dataSet))) dataSet['size'] = sizes else: self.opts['size'] = size self._spotPixmap = None dataSet['sourceRect'] = None if update: self.updateSpots(dataSet) def setPointData(self, data, dataSet=None, mask=None): if dataSet is None: dataSet = self.data if isinstance(data, np.ndarray) or isinstance(data, list): if mask is not None: data = data[mask] if len(data) != len(dataSet): raise Exception("Length of meta data does not match number of points (%d != %d)" % (len(data), len(dataSet))) ## Bug: If data is a numpy record array, then items from that array must be copied to dataSet one at a time. ## (otherwise they are converted to tuples and thus lose their field names. if isinstance(data, np.ndarray) and (data.dtype.fields is not None)and len(data.dtype.fields) > 1: for i, rec in enumerate(data): dataSet['data'][i] = rec else: dataSet['data'] = data def setPxMode(self, mode): if self.opts['pxMode'] == mode: return self.opts['pxMode'] = mode self.invalidate() def updateSpots(self, dataSet=None): if dataSet is None: dataSet = self.data invalidate = False if self.opts['pxMode']: mask = np.equal(dataSet['sourceRect'], None) if np.any(mask): invalidate = True opts = self.getSpotOpts(dataSet[mask]) sourceRect = self.fragmentAtlas.getSymbolCoords(opts) dataSet['sourceRect'][mask] = sourceRect self.fragmentAtlas.getAtlas() # generate atlas so source widths are available. dataSet['width'] = np.array(list(imap(QtCore.QRectF.width, dataSet['sourceRect'])))/2 dataSet['targetRect'] = None self._maxSpotPxWidth = self.fragmentAtlas.max_width else: self._maxSpotWidth = 0 self._maxSpotPxWidth = 0 self.measureSpotSizes(dataSet) if invalidate: self.invalidate() def getSpotOpts(self, recs, scale=1.0): if recs.ndim == 0: rec = recs symbol = rec['symbol'] if symbol is None: symbol = self.opts['symbol'] size = rec['size'] if size < 0: size = self.opts['size'] pen = rec['pen'] if pen is None: pen = self.opts['pen'] brush = rec['brush'] if brush is None: brush = self.opts['brush'] return (symbol, size*scale, fn.mkPen(pen), fn.mkBrush(brush)) else: recs = recs.copy() recs['symbol'][np.equal(recs['symbol'], None)] = self.opts['symbol'] recs['size'][np.equal(recs['size'], -1)] = self.opts['size'] recs['size'] *= scale recs['pen'][np.equal(recs['pen'], None)] = fn.mkPen(self.opts['pen']) recs['brush'][np.equal(recs['brush'], None)] = fn.mkBrush(self.opts['brush']) return recs def measureSpotSizes(self, dataSet): for rec in dataSet: ## keep track of the maximum spot size and pixel size symbol, size, pen, brush = self.getSpotOpts(rec) width = 0 pxWidth = 0 if self.opts['pxMode']: pxWidth = size + pen.widthF() else: width = size if pen.isCosmetic(): pxWidth += pen.widthF() else: width += pen.widthF() self._maxSpotWidth = max(self._maxSpotWidth, width) self._maxSpotPxWidth = max(self._maxSpotPxWidth, pxWidth) self.bounds = [None, None] def clear(self): """Remove all spots from the scatter plot""" #self.clearItems() self.data = np.empty(0, dtype=self.data.dtype) self.bounds = [None, None] self.invalidate() def dataBounds(self, ax, frac=1.0, orthoRange=None): if frac >= 1.0 and orthoRange is None and self.bounds[ax] is not None: return self.bounds[ax] #self.prepareGeometryChange() if self.data is None or len(self.data) == 0: return (None, None) if ax == 0: d = self.data['x'] d2 = self.data['y'] elif ax == 1: d = self.data['y'] d2 = self.data['x'] if orthoRange is not None: mask = (d2 >= orthoRange[0]) * (d2 <= orthoRange[1]) d = d[mask] d2 = d2[mask] if frac >= 1.0: self.bounds[ax] = (np.nanmin(d) - self._maxSpotWidth*0.7072, np.nanmax(d) + self._maxSpotWidth*0.7072) return self.bounds[ax] elif frac <= 0.0: raise Exception("Value for parameter 'frac' must be > 0. (got %s)" % str(frac)) else: mask = np.isfinite(d) d = d[mask] return np.percentile(d, [50 * (1 - frac), 50 * (1 + frac)]) def pixelPadding(self): return self._maxSpotPxWidth*0.7072 def boundingRect(self): (xmn, xmx) = self.dataBounds(ax=0) (ymn, ymx) = self.dataBounds(ax=1) if xmn is None or xmx is None: xmn = 0 xmx = 0 if ymn is None or ymx is None: ymn = 0 ymx = 0 px = py = 0.0 pxPad = self.pixelPadding() if pxPad > 0: # determine length of pixel in local x, y directions px, py = self.pixelVectors() try: px = 0 if px is None else px.length() except OverflowError: px = 0 try: py = 0 if py is None else py.length() except OverflowError: py = 0 # return bounds expanded by pixel size px *= pxPad py *= pxPad return QtCore.QRectF(xmn-px, ymn-py, (2*px)+xmx-xmn, (2*py)+ymx-ymn) def viewTransformChanged(self): self.prepareGeometryChange() GraphicsObject.viewTransformChanged(self) self.bounds = [None, None] self.data['targetRect'] = None def setExportMode(self, *args, **kwds): GraphicsObject.setExportMode(self, *args, **kwds) self.invalidate() def mapPointsToDevice(self, pts): # Map point locations to device tr = self.deviceTransform() if tr is None: return None #pts = np.empty((2,len(self.data['x']))) #pts[0] = self.data['x'] #pts[1] = self.data['y'] pts = fn.transformCoordinates(tr, pts) pts -= self.data['width'] pts = np.clip(pts, -2**30, 2**30) ## prevent Qt segmentation fault. return pts def getViewMask(self, pts): # Return bool mask indicating all points that are within viewbox # pts is expressed in *device coordiantes* vb = self.getViewBox() if vb is None: return None viewBounds = vb.mapRectToDevice(vb.boundingRect()) w = self.data['width'] mask = ((pts[0] + w > viewBounds.left()) & (pts[0] - w < viewBounds.right()) & (pts[1] + w > viewBounds.top()) & (pts[1] - w < viewBounds.bottom())) ## remove out of view points return mask @debug.warnOnException ## raising an exception here causes crash def paint(self, p, *args): #p.setPen(fn.mkPen('r')) #p.drawRect(self.boundingRect()) if self._exportOpts is not False: aa = self._exportOpts.get('antialias', True) scale = self._exportOpts.get('resolutionScale', 1.0) ## exporting to image; pixel resolution may have changed else: aa = self.opts['antialias'] scale = 1.0 if self.opts['pxMode'] is True: p.resetTransform() # Map point coordinates to device pts = np.vstack([self.data['x'], self.data['y']]) pts = self.mapPointsToDevice(pts) if pts is None: return # Cull points that are outside view viewMask = self.getViewMask(pts) #pts = pts[:,mask] #data = self.data[mask] if self.opts['useCache'] and self._exportOpts is False: # Draw symbols from pre-rendered atlas atlas = self.fragmentAtlas.getAtlas() # Update targetRects if necessary updateMask = viewMask & np.equal(self.data['targetRect'], None) if np.any(updateMask): updatePts = pts[:,updateMask] width = self.data[updateMask]['width']*2 self.data['targetRect'][updateMask] = list(imap(QtCore.QRectF, updatePts[0,:], updatePts[1,:], width, width)) data = self.data[viewMask] if USE_PYSIDE or USE_PYQT5: list(imap(p.drawPixmap, data['targetRect'], repeat(atlas), data['sourceRect'])) else: p.drawPixmapFragments(data['targetRect'].tolist(), data['sourceRect'].tolist(), atlas) else: # render each symbol individually p.setRenderHint(p.Antialiasing, aa) data = self.data[viewMask] pts = pts[:,viewMask] for i, rec in enumerate(data): p.resetTransform() p.translate(pts[0,i] + rec['width'], pts[1,i] + rec['width']) drawSymbol(p, *self.getSpotOpts(rec, scale)) else: if self.picture is None: self.picture = QtGui.QPicture() p2 = QtGui.QPainter(self.picture) for rec in self.data: if scale != 1.0: rec = rec.copy() rec['size'] *= scale p2.resetTransform() p2.translate(rec['x'], rec['y']) drawSymbol(p2, *self.getSpotOpts(rec, scale)) p2.end() p.setRenderHint(p.Antialiasing, aa) self.picture.play(p) def points(self): for rec in self.data: if rec['item'] is None: rec['item'] = SpotItem(rec, self) return self.data['item'] def pointsAt(self, pos): x = pos.x() y = pos.y() pw = self.pixelWidth() ph = self.pixelHeight() pts = [] for s in self.points(): sp = s.pos() ss = s.size() sx = sp.x() sy = sp.y() s2x = s2y = ss * 0.5 if self.opts['pxMode']: s2x *= pw s2y *= ph if x > sx-s2x and x < sx+s2x and y > sy-s2y and y < sy+s2y: pts.append(s) #print "HIT:", x, y, sx, sy, s2x, s2y #else: #print "No hit:", (x, y), (sx, sy) #print " ", (sx-s2x, sy-s2y), (sx+s2x, sy+s2y) return pts[::-1] def mouseClickEvent(self, ev): if ev.button() == QtCore.Qt.LeftButton: pts = self.pointsAt(ev.pos()) if len(pts) > 0: self.ptsClicked = pts self.sigClicked.emit(self, self.ptsClicked) ev.accept() else: #print "no spots" ev.ignore() else: ev.ignore() class SpotItem(object): """ Class referring to individual spots in a scatter plot. These can be retrieved by calling ScatterPlotItem.points() or by connecting to the ScatterPlotItem's click signals. """ def __init__(self, data, plot): #GraphicsItem.__init__(self, register=False) self._data = data self._plot = plot #self.setParentItem(plot) #self.setPos(QtCore.QPointF(data['x'], data['y'])) #self.updateItem() def data(self): """Return the user data associated with this spot.""" return self._data['data'] def size(self): """Return the size of this spot. If the spot has no explicit size set, then return the ScatterPlotItem's default size instead.""" if self._data['size'] == -1: return self._plot.opts['size'] else: return self._data['size'] def pos(self): return Point(self._data['x'], self._data['y']) def viewPos(self): return self._plot.mapToView(self.pos()) def setSize(self, size): """Set the size of this spot. If the size is set to -1, then the ScatterPlotItem's default size will be used instead.""" self._data['size'] = size self.updateItem() def symbol(self): """Return the symbol of this spot. If the spot has no explicit symbol set, then return the ScatterPlotItem's default symbol instead. """ symbol = self._data['symbol'] if symbol is None: symbol = self._plot.opts['symbol'] try: n = int(symbol) symbol = list(Symbols.keys())[n % len(Symbols)] except: pass return symbol def setSymbol(self, symbol): """Set the symbol for this spot. If the symbol is set to '', then the ScatterPlotItem's default symbol will be used instead.""" self._data['symbol'] = symbol self.updateItem() def pen(self): pen = self._data['pen'] if pen is None: pen = self._plot.opts['pen'] return fn.mkPen(pen) def setPen(self, *args, **kargs): """Set the outline pen for this spot""" pen = fn.mkPen(*args, **kargs) self._data['pen'] = pen self.updateItem() def resetPen(self): """Remove the pen set for this spot; the scatter plot's default pen will be used instead.""" self._data['pen'] = None ## Note this is NOT the same as calling setPen(None) self.updateItem() def brush(self): brush = self._data['brush'] if brush is None: brush = self._plot.opts['brush'] return fn.mkBrush(brush) def setBrush(self, *args, **kargs): """Set the fill brush for this spot""" brush = fn.mkBrush(*args, **kargs) self._data['brush'] = brush self.updateItem() def resetBrush(self): """Remove the brush set for this spot; the scatter plot's default brush will be used instead.""" self._data['brush'] = None ## Note this is NOT the same as calling setBrush(None) self.updateItem() def setData(self, data): """Set the user-data associated with this spot""" self._data['data'] = data def updateItem(self): self._data['sourceRect'] = None self._plot.updateSpots(self._data.reshape(1)) self._plot.invalidate() #class PixmapSpotItem(SpotItem, QtGui.QGraphicsPixmapItem): #def __init__(self, data, plot): #QtGui.QGraphicsPixmapItem.__init__(self) #self.setFlags(self.flags() | self.ItemIgnoresTransformations) #SpotItem.__init__(self, data, plot) #def setPixmap(self, pixmap): #QtGui.QGraphicsPixmapItem.setPixmap(self, pixmap) #self.setOffset(-pixmap.width()/2.+0.5, -pixmap.height()/2.) #def updateItem(self): #symbolOpts = (self._data['pen'], self._data['brush'], self._data['size'], self._data['symbol']) ### If all symbol options are default, use default pixmap #if symbolOpts == (None, None, -1, ''): #pixmap = self._plot.defaultSpotPixmap() #else: #pixmap = makeSymbolPixmap(size=self.size(), pen=self.pen(), brush=self.brush(), symbol=self.symbol()) #self.setPixmap(pixmap) #class PathSpotItem(SpotItem, QtGui.QGraphicsPathItem): #def __init__(self, data, plot): #QtGui.QGraphicsPathItem.__init__(self) #SpotItem.__init__(self, data, plot) #def updateItem(self): #QtGui.QGraphicsPathItem.setPath(self, Symbols[self.symbol()]) #QtGui.QGraphicsPathItem.setPen(self, self.pen()) #QtGui.QGraphicsPathItem.setBrush(self, self.brush()) #size = self.size() #self.resetTransform() #self.scale(size, size) �����������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/TextItem.py��������������������������������������0000664�0000000�0000000�00000017374�13007271214�0024573�0����������������������������������������������������������������������������������������������������ustar�00root����������������������������root����������������������������0000000�0000000������������������������������������������������������������������������������������������������������������������������������������������������������������������������import numpy as np from ..Qt import QtCore, QtGui from ..Point import Point from .. import functions as fn from .GraphicsObject import GraphicsObject class TextItem(GraphicsObject): """ GraphicsItem displaying unscaled text (the text will always appear normal even inside a scaled ViewBox). """ def __init__(self, text='', color=(200,200,200), html=None, anchor=(0,0), border=None, fill=None, angle=0, rotateAxis=None): """ ============== ================================================================================= **Arguments:** *text* The text to display *color* The color of the text (any format accepted by pg.mkColor) *html* If specified, this overrides both *text* and *color* *anchor* A QPointF or (x,y) sequence indicating what region of the text box will be anchored to the item's position. A value of (0,0) sets the upper-left corner of the text box to be at the position specified by setPos(), while a value of (1,1) sets the lower-right corner. *border* A pen to use when drawing the border *fill* A brush to use when filling within the border *angle* Angle in degrees to rotate text. Default is 0; text will be displayed upright. *rotateAxis* If None, then a text angle of 0 always points along the +x axis of the scene. If a QPointF or (x,y) sequence is given, then it represents a vector direction in the parent's coordinate system that the 0-degree line will be aligned to. This Allows text to follow both the position and orientation of its parent while still discarding any scale and shear factors. ============== ================================================================================= The effects of the `rotateAxis` and `angle` arguments are added independently. So for example: * rotateAxis=None, angle=0 -> normal horizontal text * rotateAxis=None, angle=90 -> normal vertical text * rotateAxis=(1, 0), angle=0 -> text aligned with x axis of its parent * rotateAxis=(0, 1), angle=0 -> text aligned with y axis of its parent * rotateAxis=(1, 0), angle=90 -> text orthogonal to x axis of its parent """ self.anchor = Point(anchor) self.rotateAxis = None if rotateAxis is None else Point(rotateAxis) #self.angle = 0 GraphicsObject.__init__(self) self.textItem = QtGui.QGraphicsTextItem() self.textItem.setParentItem(self) self._lastTransform = None self._lastScene = None self._bounds = QtCore.QRectF() if html is None: self.setColor(color) self.setText(text) else: self.setHtml(html) self.fill = fn.mkBrush(fill) self.border = fn.mkPen(border) self.setAngle(angle) def setText(self, text, color=None): """ Set the text of this item. This method sets the plain text of the item; see also setHtml(). """ if color is not None: self.setColor(color) self.textItem.setPlainText(text) self.updateTextPos() def setPlainText(self, *args): """ Set the plain text to be rendered by this item. See QtGui.QGraphicsTextItem.setPlainText(). """ self.textItem.setPlainText(*args) self.updateTextPos() def setHtml(self, *args): """ Set the HTML code to be rendered by this item. See QtGui.QGraphicsTextItem.setHtml(). """ self.textItem.setHtml(*args) self.updateTextPos() def setTextWidth(self, *args): """ Set the width of the text. If the text requires more space than the width limit, then it will be wrapped into multiple lines. See QtGui.QGraphicsTextItem.setTextWidth(). """ self.textItem.setTextWidth(*args) self.updateTextPos() def setFont(self, *args): """ Set the font for this text. See QtGui.QGraphicsTextItem.setFont(). """ self.textItem.setFont(*args) self.updateTextPos() def setAngle(self, angle): self.angle = angle self.updateTransform() def setAnchor(self, anchor): self.anchor = Point(anchor) self.updateTextPos() def setColor(self, color): """ Set the color for this text. See QtGui.QGraphicsItem.setDefaultTextColor(). """ self.color = fn.mkColor(color) self.textItem.setDefaultTextColor(self.color) def updateTextPos(self): # update text position to obey anchor r = self.textItem.boundingRect() tl = self.textItem.mapToParent(r.topLeft()) br = self.textItem.mapToParent(r.bottomRight()) offset = (br - tl) * self.anchor self.textItem.setPos(-offset) ### Needed to maintain font size when rendering to image with increased resolution #self.textItem.resetTransform() ##self.textItem.rotate(self.angle) #if self._exportOpts is not False and 'resolutionScale' in self._exportOpts: #s = self._exportOpts['resolutionScale'] #self.textItem.scale(s, s) def boundingRect(self): return self.textItem.mapToParent(self.textItem.boundingRect()).boundingRect() def viewTransformChanged(self): # called whenever view transform has changed. # Do this here to avoid double-updates when view changes. self.updateTransform() def paint(self, p, *args): # this is not ideal because it requires the transform to be updated at every draw. # ideally, we would have a sceneTransformChanged event to react to.. s = self.scene() ls = self._lastScene if s is not ls: if ls is not None: ls.sigPrepareForPaint.disconnect(self.updateTransform) self._lastScene = s if s is not None: s.sigPrepareForPaint.connect(self.updateTransform) self.updateTransform() p.setTransform(self.sceneTransform()) if self.border.style() != QtCore.Qt.NoPen or self.fill.style() != QtCore.Qt.NoBrush: p.setPen(self.border) p.setBrush(self.fill) p.setRenderHint(p.Antialiasing, True) p.drawPolygon(self.textItem.mapToParent(self.textItem.boundingRect())) def updateTransform(self): # update transform such that this item has the correct orientation # and scaling relative to the scene, but inherits its position from its # parent. # This is similar to setting ItemIgnoresTransformations = True, but # does not break mouse interaction and collision detection. p = self.parentItem() if p is None: pt = QtGui.QTransform() else: pt = p.sceneTransform() if pt == self._lastTransform: return t = pt.inverted()[0] # reset translation t.setMatrix(t.m11(), t.m12(), t.m13(), t.m21(), t.m22(), t.m23(), 0, 0, t.m33()) # apply rotation angle = -self.angle if self.rotateAxis is not None: d = pt.map(self.rotateAxis) - pt.map(Point(0, 0)) a = np.arctan2(d.y(), d.x()) * 180 / np.pi angle += a t.rotate(angle) self.setTransform(t) self._lastTransform = pt self.updateTextPos() ��������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/UIGraphicsItem.py��������������������������������0000664�0000000�0000000�00000011074�13007271214�0025634�0����������������������������������������������������������������������������������������������������ustar�00root����������������������������root����������������������������0000000�0000000������������������������������������������������������������������������������������������������������������������������������������������������������������������������from ..Qt import QtGui, QtCore, USE_PYSIDE import weakref from .GraphicsObject import GraphicsObject if not USE_PYSIDE: import sip __all__ = ['UIGraphicsItem'] class UIGraphicsItem(GraphicsObject): """ Base class for graphics items with boundaries relative to a GraphicsView or ViewBox. The purpose of this class is to allow the creation of GraphicsItems which live inside a scalable view, but whose boundaries will always stay fixed relative to the view's boundaries. For example: GridItem, InfiniteLine The view can be specified on initialization or it can be automatically detected when the item is painted. NOTE: Only the item's boundingRect is affected; the item is not transformed in any way. Use viewRangeChanged to respond to changes in the view. """ #sigViewChanged = QtCore.Signal(object) ## emitted whenever the viewport coords have changed def __init__(self, bounds=None, parent=None): """ ============== ============================================================================= **Arguments:** bounds QRectF with coordinates relative to view box. The default is QRectF(0,0,1,1), which means the item will have the same bounds as the view. ============== ============================================================================= """ GraphicsObject.__init__(self, parent) self.setFlag(self.ItemSendsScenePositionChanges) if bounds is None: self._bounds = QtCore.QRectF(0, 0, 1, 1) else: self._bounds = bounds self._boundingRect = None self._updateView() def paint(self, *args): ## check for a new view object every time we paint. #self.updateView() pass def itemChange(self, change, value): ret = GraphicsObject.itemChange(self, change, value) ## workaround for pyqt bug: ## http://www.riverbankcomputing.com/pipermail/pyqt/2012-August/031818.html if not USE_PYSIDE and change == self.ItemParentChange and isinstance(ret, QtGui.QGraphicsItem): ret = sip.cast(ret, QtGui.QGraphicsItem) if change == self.ItemScenePositionHasChanged: self.setNewBounds() return ret #def updateView(self): ### called to see whether this item has a new view to connect to ### check for this item's current viewbox or view widget #view = self.getViewBox() #if view is None: ##print " no view" #return #if self._connectedView is not None and view is self._connectedView(): ##print " already have view", view #return ### disconnect from previous view #if self._connectedView is not None: #cv = self._connectedView() #if cv is not None: ##print "disconnect:", self #cv.sigRangeChanged.disconnect(self.viewRangeChanged) ### connect to new view ##print "connect:", self #view.sigRangeChanged.connect(self.viewRangeChanged) #self._connectedView = weakref.ref(view) #self.setNewBounds() def boundingRect(self): if self._boundingRect is None: br = self.viewRect() if br is None: return QtCore.QRectF() else: self._boundingRect = br return QtCore.QRectF(self._boundingRect) def dataBounds(self, axis, frac=1.0, orthoRange=None): """Called by ViewBox for determining the auto-range bounds. By default, UIGraphicsItems are excluded from autoRange.""" return None def viewRangeChanged(self): """Called when the view widget/viewbox is resized/rescaled""" self.setNewBounds() self.update() def setNewBounds(self): """Update the item's bounding rect to match the viewport""" self._boundingRect = None ## invalidate bounding rect, regenerate later if needed. self.prepareGeometryChange() def setPos(self, *args): GraphicsObject.setPos(self, *args) self.setNewBounds() def mouseShape(self): """Return the shape of this item after expanding by 2 pixels""" shape = self.shape() ds = self.mapToDevice(shape) stroker = QtGui.QPainterPathStroker() stroker.setWidh(2) ds2 = stroker.createStroke(ds).united(ds) return self.mapFromDevice(ds2) ��������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/VTickGroup.py������������������������������������0000664�0000000�0000000�00000006664�13007271214�0025065�0����������������������������������������������������������������������������������������������������ustar�00root����������������������������root����������������������������0000000�0000000������������������������������������������������������������������������������������������������������������������������������������������������������������������������if __name__ == '__main__': import os, sys path = os.path.abspath(os.path.dirname(__file__)) sys.path.insert(0, os.path.join(path, '..', '..')) from ..Qt import QtGui, QtCore from .. import functions as fn import weakref from .UIGraphicsItem import UIGraphicsItem __all__ = ['VTickGroup'] class VTickGroup(UIGraphicsItem): """ **Bases:** :class:`UIGraphicsItem ` Draws a set of tick marks which always occupy the same vertical range of the view, but have x coordinates relative to the data within the view. """ def __init__(self, xvals=None, yrange=None, pen=None): """ ============== =================================================================== **Arguments:** xvals A list of x values (in data coordinates) at which to draw ticks. yrange A list of [low, high] limits for the tick. 0 is the bottom of the view, 1 is the top. [0.8, 1] would draw ticks in the top fifth of the view. pen The pen to use for drawing ticks. Default is grey. Can be specified as any argument valid for :func:`mkPen` ============== =================================================================== """ if yrange is None: yrange = [0, 1] if xvals is None: xvals = [] UIGraphicsItem.__init__(self) if pen is None: pen = (200, 200, 200) self.path = QtGui.QGraphicsPathItem() self.ticks = [] self.xvals = [] self.yrange = [0,1] self.setPen(pen) self.setYRange(yrange) self.setXVals(xvals) def setPen(self, *args, **kwargs): """Set the pen to use for drawing ticks. Can be specified as any arguments valid for :func:`mkPen`""" self.pen = fn.mkPen(*args, **kwargs) def setXVals(self, vals): """Set the x values for the ticks. ============== ===================================================================== **Arguments:** vals A list of x values (in data/plot coordinates) at which to draw ticks. ============== ===================================================================== """ self.xvals = vals self.rebuildTicks() #self.valid = False def setYRange(self, vals): """Set the y range [low, high] that the ticks are drawn on. 0 is the bottom of the view, 1 is the top.""" self.yrange = vals self.rebuildTicks() def dataBounds(self, *args, **kargs): return None ## item should never affect view autoscaling def yRange(self): return self.yrange def rebuildTicks(self): self.path = QtGui.QPainterPath() yrange = self.yRange() for x in self.xvals: self.path.moveTo(x, 0.) self.path.lineTo(x, 1.) def paint(self, p, *args): UIGraphicsItem.paint(self, p, *args) br = self.boundingRect() h = br.height() br.setY(br.y() + self.yrange[0] * h) br.setHeight(h - (1.0-self.yrange[1]) * h) p.translate(0, br.y()) p.scale(1.0, br.height()) p.setPen(self.pen) p.drawPath(self.path) ����������������������������������������������������������������������������pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/ViewBox/�����������������������������������������0000775�0000000�0000000�00000000000�13007271214�0024025�5����������������������������������������������������������������������������������������������������ustar�00root����������������������������root����������������������������0000000�0000000������������������������������������������������������������������������������������������������������������������������������������������������������������������������pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/ViewBox/ViewBox.py�������������������������������0000664�0000000�0000000�00000215644�13007271214�0025776�0����������������������������������������������������������������������������������������������������ustar�00root����������������������������root����������������������������0000000�0000000������������������������������������������������������������������������������������������������������������������������������������������������������������������������import weakref import sys from copy import deepcopy import numpy as np from ...Qt import QtGui, QtCore from ...python2_3 import sortList, basestring, cmp from ...Point import Point from ... import functions as fn from .. ItemGroup import ItemGroup from .. GraphicsWidget import GraphicsWidget from ... import debug as debug from ... import getConfigOption from ...Qt import isQObjectAlive __all__ = ['ViewBox'] class WeakList(object): def __init__(self): self._items = [] def append(self, obj): #Add backwards to iterate backwards (to make iterating more efficient on removal). self._items.insert(0, weakref.ref(obj)) def __iter__(self): i = len(self._items)-1 while i >= 0: ref = self._items[i] d = ref() if d is None: del self._items[i] else: yield d i -= 1 class ChildGroup(ItemGroup): def __init__(self, parent): ItemGroup.__init__(self, parent) # Used as callback to inform ViewBox when items are added/removed from # the group. # Note 1: We would prefer to override itemChange directly on the # ViewBox, but this causes crashes on PySide. # Note 2: We might also like to use a signal rather than this callback # mechanism, but this causes a different PySide crash. self.itemsChangedListeners = WeakList() # excempt from telling view when transform changes self._GraphicsObject__inform_view_on_change = False def itemChange(self, change, value): ret = ItemGroup.itemChange(self, change, value) if change == self.ItemChildAddedChange or change == self.ItemChildRemovedChange: try: itemsChangedListeners = self.itemsChangedListeners except AttributeError: # It's possible that the attribute was already collected when the itemChange happened # (if it was triggered during the gc of the object). pass else: for listener in itemsChangedListeners: listener.itemsChanged() return ret class ViewBox(GraphicsWidget): """ **Bases:** :class:`GraphicsWidget ` Box that allows internal scaling/panning of children by mouse drag. This class is usually created automatically as part of a :class:`PlotItem ` or :class:`Canvas ` or with :func:`GraphicsLayout.addViewBox() `. Features: * Scaling contents by mouse or auto-scale when contents change * View linking--multiple views display the same data ranges * Configurable by context menu * Item coordinate mapping methods """ sigYRangeChanged = QtCore.Signal(object, object) sigXRangeChanged = QtCore.Signal(object, object) sigRangeChangedManually = QtCore.Signal(object) sigRangeChanged = QtCore.Signal(object, object) #sigActionPositionChanged = QtCore.Signal(object) sigStateChanged = QtCore.Signal(object) sigTransformChanged = QtCore.Signal(object) sigResized = QtCore.Signal(object) ## mouse modes PanMode = 3 RectMode = 1 ## axes XAxis = 0 YAxis = 1 XYAxes = 2 ## for linking views together NamedViews = weakref.WeakValueDictionary() # name: ViewBox AllViews = weakref.WeakKeyDictionary() # ViewBox: None def __init__(self, parent=None, border=None, lockAspect=False, enableMouse=True, invertY=False, enableMenu=True, name=None, invertX=False): """ ============== ============================================================= **Arguments:** *parent* (QGraphicsWidget) Optional parent widget *border* (QPen) Do draw a border around the view, give any single argument accepted by :func:`mkPen ` *lockAspect* (False or float) The aspect ratio to lock the view coorinates to. (or False to allow the ratio to change) *enableMouse* (bool) Whether mouse can be used to scale/pan the view *invertY* (bool) See :func:`invertY ` *invertX* (bool) See :func:`invertX ` *enableMenu* (bool) Whether to display a context menu when right-clicking on the ViewBox background. *name* (str) Used to register this ViewBox so that it appears in the "Link axis" dropdown inside other ViewBox context menus. This allows the user to manually link the axes of any other view to this one. ============== ============================================================= """ GraphicsWidget.__init__(self, parent) self.name = None self.linksBlocked = False self.addedItems = [] #self.gView = view #self.showGrid = showGrid self._matrixNeedsUpdate = True ## indicates that range has changed, but matrix update was deferred self._autoRangeNeedsUpdate = True ## indicates auto-range needs to be recomputed. self._lastScene = None ## stores reference to the last known scene this view was a part of. self.state = { ## separating targetRange and viewRange allows the view to be resized ## while keeping all previously viewed contents visible 'targetRange': [[0,1], [0,1]], ## child coord. range visible [[xmin, xmax], [ymin, ymax]] 'viewRange': [[0,1], [0,1]], ## actual range viewed 'yInverted': invertY, 'xInverted': invertX, 'aspectLocked': False, ## False if aspect is unlocked, otherwise float specifies the locked ratio. 'autoRange': [True, True], ## False if auto range is disabled, ## otherwise float gives the fraction of data that is visible 'autoPan': [False, False], ## whether to only pan (do not change scaling) when auto-range is enabled 'autoVisibleOnly': [False, False], ## whether to auto-range only to the visible portion of a plot 'linkedViews': [None, None], ## may be None, "viewName", or weakref.ref(view) ## a name string indicates that the view *should* link to another, but no view with that name exists yet. 'mouseEnabled': [enableMouse, enableMouse], 'mouseMode': ViewBox.PanMode if getConfigOption('leftButtonPan') else ViewBox.RectMode, 'enableMenu': enableMenu, 'wheelScaleFactor': -1.0 / 8.0, 'background': None, # Limits 'limits': { 'xLimits': [None, None], # Maximum and minimum visible X values 'yLimits': [None, None], # Maximum and minimum visible Y values 'xRange': [None, None], # Maximum and minimum X range 'yRange': [None, None], # Maximum and minimum Y range } } self._updatingRange = False ## Used to break recursive loops. See updateAutoRange. self._itemBoundsCache = weakref.WeakKeyDictionary() self.locateGroup = None ## items displayed when using ViewBox.locate(item) self.setFlag(self.ItemClipsChildrenToShape) self.setFlag(self.ItemIsFocusable, True) ## so we can receive key presses ## childGroup is required so that ViewBox has local coordinates similar to device coordinates. ## this is a workaround for a Qt + OpenGL bug that causes improper clipping ## https://bugreports.qt.nokia.com/browse/QTBUG-23723 self.childGroup = ChildGroup(self) self.childGroup.itemsChangedListeners.append(self) self.background = QtGui.QGraphicsRectItem(self.rect()) self.background.setParentItem(self) self.background.setZValue(-1e6) self.background.setPen(fn.mkPen(None)) self.updateBackground() #self.useLeftButtonPan = pyqtgraph.getConfigOption('leftButtonPan') # normally use left button to pan # this also enables capture of keyPressEvents. ## Make scale box that is shown when dragging on the view self.rbScaleBox = QtGui.QGraphicsRectItem(0, 0, 1, 1) self.rbScaleBox.setPen(fn.mkPen((255,255,100), width=1)) self.rbScaleBox.setBrush(fn.mkBrush(255,255,0,100)) self.rbScaleBox.setZValue(1e9) self.rbScaleBox.hide() self.addItem(self.rbScaleBox, ignoreBounds=True) ## show target rect for debugging self.target = QtGui.QGraphicsRectItem(0, 0, 1, 1) self.target.setPen(fn.mkPen('r')) self.target.setParentItem(self) self.target.hide() self.axHistory = [] # maintain a history of zoom locations self.axHistoryPointer = -1 # pointer into the history. Allows forward/backward movement, not just "undo" self.setZValue(-100) self.setSizePolicy(QtGui.QSizePolicy(QtGui.QSizePolicy.Expanding, QtGui.QSizePolicy.Expanding)) self.setAspectLocked(lockAspect) self.border = fn.mkPen(border) self.menu = ViewBoxMenu(self) self.register(name) if name is None: self.updateViewLists() def register(self, name): """ Add this ViewBox to the registered list of views. This allows users to manually link the axes of any other ViewBox to this one. The specified *name* will appear in the drop-down lists for axis linking in the context menus of all other views. The same can be accomplished by initializing the ViewBox with the *name* attribute. """ ViewBox.AllViews[self] = None if self.name is not None: del ViewBox.NamedViews[self.name] self.name = name if name is not None: ViewBox.NamedViews[name] = self ViewBox.updateAllViewLists() sid = id(self) self.destroyed.connect(lambda: ViewBox.forgetView(sid, name) if (ViewBox is not None and 'sid' in locals() and 'name' in locals()) else None) #self.destroyed.connect(self.unregister) def unregister(self): """ Remove this ViewBox from the list of linkable views. (see :func:`register() `) """ del ViewBox.AllViews[self] if self.name is not None: del ViewBox.NamedViews[self.name] def close(self): self.clear() self.unregister() def implements(self, interface): return interface == 'ViewBox' # removed due to https://bugreports.qt-project.org/browse/PYSIDE-86 #def itemChange(self, change, value): ## Note: Calling QWidget.itemChange causes segv in python 3 + PyQt ##ret = QtGui.QGraphicsItem.itemChange(self, change, value) #ret = GraphicsWidget.itemChange(self, change, value) #if change == self.ItemSceneChange: #scene = self.scene() #if scene is not None and hasattr(scene, 'sigPrepareForPaint'): #scene.sigPrepareForPaint.disconnect(self.prepareForPaint) #elif change == self.ItemSceneHasChanged: #scene = self.scene() #if scene is not None and hasattr(scene, 'sigPrepareForPaint'): #scene.sigPrepareForPaint.connect(self.prepareForPaint) #return ret def checkSceneChange(self): # ViewBox needs to receive sigPrepareForPaint from its scene before # being painted. However, we have no way of being informed when the # scene has changed in order to make this connection. The usual way # to do this is via itemChange(), but bugs prevent this approach # (see above). Instead, we simply check at every paint to see whether # (the scene has changed. scene = self.scene() if scene == self._lastScene: return if self._lastScene is not None and hasattr(self.lastScene, 'sigPrepareForPaint'): self._lastScene.sigPrepareForPaint.disconnect(self.prepareForPaint) if scene is not None and hasattr(scene, 'sigPrepareForPaint'): scene.sigPrepareForPaint.connect(self.prepareForPaint) self.prepareForPaint() self._lastScene = scene def prepareForPaint(self): #autoRangeEnabled = (self.state['autoRange'][0] is not False) or (self.state['autoRange'][1] is not False) # don't check whether auto range is enabled here--only check when setting dirty flag. if self._autoRangeNeedsUpdate: # and autoRangeEnabled: self.updateAutoRange() if self._matrixNeedsUpdate: self.updateMatrix() def getState(self, copy=True): """Return the current state of the ViewBox. Linked views are always converted to view names in the returned state.""" state = self.state.copy() views = [] for v in state['linkedViews']: if isinstance(v, weakref.ref): v = v() if v is None or isinstance(v, basestring): views.append(v) else: views.append(v.name) state['linkedViews'] = views if copy: return deepcopy(state) else: return state def setState(self, state): """Restore the state of this ViewBox. (see also getState)""" state = state.copy() self.setXLink(state['linkedViews'][0]) self.setYLink(state['linkedViews'][1]) del state['linkedViews'] self.state.update(state) #self.updateMatrix() self.updateViewRange() self.sigStateChanged.emit(self) def setBackgroundColor(self, color): """ Set the background color of the ViewBox. If color is None, then no background will be drawn. Added in version 0.9.9 """ self.background.setVisible(color is not None) self.state['background'] = color self.updateBackground() def setMouseMode(self, mode): """ Set the mouse interaction mode. *mode* must be either ViewBox.PanMode or ViewBox.RectMode. In PanMode, the left mouse button pans the view and the right button scales. In RectMode, the left button draws a rectangle which updates the visible region (this mode is more suitable for single-button mice) """ if mode not in [ViewBox.PanMode, ViewBox.RectMode]: raise Exception("Mode must be ViewBox.PanMode or ViewBox.RectMode") self.state['mouseMode'] = mode self.sigStateChanged.emit(self) #def toggleLeftAction(self, act): ## for backward compatibility #if act.text() is 'pan': #self.setLeftButtonAction('pan') #elif act.text() is 'zoom': #self.setLeftButtonAction('rect') def setLeftButtonAction(self, mode='rect'): ## for backward compatibility if mode.lower() == 'rect': self.setMouseMode(ViewBox.RectMode) elif mode.lower() == 'pan': self.setMouseMode(ViewBox.PanMode) else: raise Exception('graphicsItems:ViewBox:setLeftButtonAction: unknown mode = %s (Options are "pan" and "rect")' % mode) def innerSceneItem(self): return self.childGroup def setMouseEnabled(self, x=None, y=None): """ Set whether each axis is enabled for mouse interaction. *x*, *y* arguments must be True or False. This allows the user to pan/scale one axis of the view while leaving the other axis unchanged. """ if x is not None: self.state['mouseEnabled'][0] = x if y is not None: self.state['mouseEnabled'][1] = y self.sigStateChanged.emit(self) def mouseEnabled(self): return self.state['mouseEnabled'][:] def setMenuEnabled(self, enableMenu=True): self.state['enableMenu'] = enableMenu self.sigStateChanged.emit(self) def menuEnabled(self): return self.state.get('enableMenu', True) def addItem(self, item, ignoreBounds=False): """ Add a QGraphicsItem to this view. The view will include this item when determining how to set its range automatically unless *ignoreBounds* is True. """ if item.zValue() < self.zValue(): item.setZValue(self.zValue()+1) scene = self.scene() if scene is not None and scene is not item.scene(): scene.addItem(item) ## Necessary due to Qt bug: https://bugreports.qt-project.org/browse/QTBUG-18616 item.setParentItem(self.childGroup) if not ignoreBounds: self.addedItems.append(item) self.updateAutoRange() #print "addItem:", item, item.boundingRect() def removeItem(self, item): """Remove an item from this view.""" try: self.addedItems.remove(item) except: pass self.scene().removeItem(item) self.updateAutoRange() def clear(self): for i in self.addedItems[:]: self.removeItem(i) for ch in self.childGroup.childItems(): ch.setParentItem(None) def resizeEvent(self, ev): self.linkedXChanged() self.linkedYChanged() self.updateAutoRange() self.updateViewRange() self._matrixNeedsUpdate = True self.sigStateChanged.emit(self) self.background.setRect(self.rect()) self.sigResized.emit(self) def viewRange(self): """Return a the view's visible range as a list: [[xmin, xmax], [ymin, ymax]]""" return [x[:] for x in self.state['viewRange']] ## return copy def viewRect(self): """Return a QRectF bounding the region visible within the ViewBox""" try: vr0 = self.state['viewRange'][0] vr1 = self.state['viewRange'][1] return QtCore.QRectF(vr0[0], vr1[0], vr0[1]-vr0[0], vr1[1] - vr1[0]) except: print("make qrectf failed:", self.state['viewRange']) raise def targetRange(self): return [x[:] for x in self.state['targetRange']] ## return copy def targetRect(self): """ Return the region which has been requested to be visible. (this is not necessarily the same as the region that is *actually* visible-- resizing and aspect ratio constraints can cause targetRect() and viewRect() to differ) """ try: tr0 = self.state['targetRange'][0] tr1 = self.state['targetRange'][1] return QtCore.QRectF(tr0[0], tr1[0], tr0[1]-tr0[0], tr1[1] - tr1[0]) except: print("make qrectf failed:", self.state['targetRange']) raise def _resetTarget(self): # Reset target range to exactly match current view range. # This is used during mouse interaction to prevent unpredictable # behavior (because the user is unaware of targetRange). if self.state['aspectLocked'] is False: # (interferes with aspect locking) self.state['targetRange'] = [self.state['viewRange'][0][:], self.state['viewRange'][1][:]] def setRange(self, rect=None, xRange=None, yRange=None, padding=None, update=True, disableAutoRange=True): """ Set the visible range of the ViewBox. Must specify at least one of *rect*, *xRange*, or *yRange*. ================== ===================================================================== **Arguments:** *rect* (QRectF) The full range that should be visible in the view box. *xRange* (min,max) The range that should be visible along the x-axis. *yRange* (min,max) The range that should be visible along the y-axis. *padding* (float) Expand the view by a fraction of the requested range. By default, this value is set between 0.02 and 0.1 depending on the size of the ViewBox. *update* (bool) If True, update the range of the ViewBox immediately. Otherwise, the update is deferred until before the next render. *disableAutoRange* (bool) If True, auto-ranging is diabled. Otherwise, it is left unchanged. ================== ===================================================================== """ #print self.name, "ViewBox.setRange", rect, xRange, yRange, padding #import traceback #traceback.print_stack() changes = {} # axes setRequested = [False, False] if rect is not None: changes = {0: [rect.left(), rect.right()], 1: [rect.top(), rect.bottom()]} setRequested = [True, True] if xRange is not None: changes[0] = xRange setRequested[0] = True if yRange is not None: changes[1] = yRange setRequested[1] = True if len(changes) == 0: print(rect) raise Exception("Must specify at least one of rect, xRange, or yRange. (gave rect=%s)" % str(type(rect))) # Update axes one at a time changed = [False, False] for ax, range in changes.items(): mn = min(range) mx = max(range) # If we requested 0 range, try to preserve previous scale. # Otherwise just pick an arbitrary scale. if mn == mx: dy = self.state['viewRange'][ax][1] - self.state['viewRange'][ax][0] if dy == 0: dy = 1 mn -= dy*0.5 mx += dy*0.5 xpad = 0.0 # Make sure no nan/inf get through if not all(np.isfinite([mn, mx])): raise Exception("Cannot set range [%s, %s]" % (str(mn), str(mx))) # Apply padding if padding is None: xpad = self.suggestPadding(ax) else: xpad = padding p = (mx-mn) * xpad mn -= p mx += p # Set target range if self.state['targetRange'][ax] != [mn, mx]: self.state['targetRange'][ax] = [mn, mx] changed[ax] = True # Update viewRange to match targetRange as closely as possible while # accounting for aspect ratio constraint lockX, lockY = setRequested if lockX and lockY: lockX = False lockY = False self.updateViewRange(lockX, lockY) # Disable auto-range for each axis that was requested to be set if disableAutoRange: xOff = False if setRequested[0] else None yOff = False if setRequested[1] else None self.enableAutoRange(x=xOff, y=yOff) changed.append(True) # If nothing has changed, we are done. if any(changed): #if update and self.matrixNeedsUpdate: #self.updateMatrix(changed) #return self.sigStateChanged.emit(self) # Update target rect for debugging if self.target.isVisible(): self.target.setRect(self.mapRectFromItem(self.childGroup, self.targetRect())) # If ortho axes have auto-visible-only, update them now # Note that aspect ratio constraints and auto-visible probably do not work together.. if changed[0] and self.state['autoVisibleOnly'][1] and (self.state['autoRange'][0] is not False): self._autoRangeNeedsUpdate = True #self.updateAutoRange() ## Maybe just indicate that auto range needs to be updated? elif changed[1] and self.state['autoVisibleOnly'][0] and (self.state['autoRange'][1] is not False): self._autoRangeNeedsUpdate = True #self.updateAutoRange() ## Update view matrix only if requested #if update: #self.updateMatrix(changed) ## Otherwise, indicate that the matrix needs to be updated #else: #self.matrixNeedsUpdate = True ## Inform linked views that the range has changed <> #for ax, range in changes.items(): #link = self.linkedView(ax) #if link is not None: #link.linkedViewChanged(self, ax) def setYRange(self, min, max, padding=None, update=True): """ Set the visible Y range of the view to [*min*, *max*]. The *padding* argument causes the range to be set larger by the fraction specified. (by default, this value is between 0.02 and 0.1 depending on the size of the ViewBox) """ self.setRange(yRange=[min, max], update=update, padding=padding) def setXRange(self, min, max, padding=None, update=True): """ Set the visible X range of the view to [*min*, *max*]. The *padding* argument causes the range to be set larger by the fraction specified. (by default, this value is between 0.02 and 0.1 depending on the size of the ViewBox) """ self.setRange(xRange=[min, max], update=update, padding=padding) def autoRange(self, padding=None, items=None, item=None): """ Set the range of the view box to make all children visible. Note that this is not the same as enableAutoRange, which causes the view to automatically auto-range whenever its contents are changed. ============== ============================================================ **Arguments:** padding The fraction of the total data range to add on to the final visible range. By default, this value is set between 0.02 and 0.1 depending on the size of the ViewBox. items If specified, this is a list of items to consider when determining the visible range. ============== ============================================================ """ if item is None: bounds = self.childrenBoundingRect(items=items) else: print("Warning: ViewBox.autoRange(item=__) is deprecated. Use 'items' argument instead.") bounds = self.mapFromItemToView(item, item.boundingRect()).boundingRect() if bounds is not None: self.setRange(bounds, padding=padding) def suggestPadding(self, axis): l = self.width() if axis==0 else self.height() if l > 0: padding = np.clip(1./(l**0.5), 0.02, 0.1) else: padding = 0.02 return padding def setLimits(self, **kwds): """ Set limits that constrain the possible view ranges. **Panning limits**. The following arguments define the region within the viewbox coordinate system that may be accessed by panning the view. =========== ============================================================ xMin Minimum allowed x-axis value xMax Maximum allowed x-axis value yMin Minimum allowed y-axis value yMax Maximum allowed y-axis value =========== ============================================================ **Scaling limits**. These arguments prevent the view being zoomed in or out too far. =========== ============================================================ minXRange Minimum allowed left-to-right span across the view. maxXRange Maximum allowed left-to-right span across the view. minYRange Minimum allowed top-to-bottom span across the view. maxYRange Maximum allowed top-to-bottom span across the view. =========== ============================================================ Added in version 0.9.9 """ update = False allowed = ['xMin', 'xMax', 'yMin', 'yMax', 'minXRange', 'maxXRange', 'minYRange', 'maxYRange'] for kwd in kwds: if kwd not in allowed: raise ValueError("Invalid keyword argument '%s'." % kwd) #for kwd in ['xLimits', 'yLimits', 'minRange', 'maxRange']: #if kwd in kwds and self.state['limits'][kwd] != kwds[kwd]: #self.state['limits'][kwd] = kwds[kwd] #update = True for axis in [0,1]: for mnmx in [0,1]: kwd = [['xMin', 'xMax'], ['yMin', 'yMax']][axis][mnmx] lname = ['xLimits', 'yLimits'][axis] if kwd in kwds and self.state['limits'][lname][mnmx] != kwds[kwd]: self.state['limits'][lname][mnmx] = kwds[kwd] update = True kwd = [['minXRange', 'maxXRange'], ['minYRange', 'maxYRange']][axis][mnmx] lname = ['xRange', 'yRange'][axis] if kwd in kwds and self.state['limits'][lname][mnmx] != kwds[kwd]: self.state['limits'][lname][mnmx] = kwds[kwd] update = True if update: self.updateViewRange() def scaleBy(self, s=None, center=None, x=None, y=None): """ Scale by *s* around given center point (or center of view). *s* may be a Point or tuple (x, y). Optionally, x or y may be specified individually. This allows the other axis to be left unaffected (note that using a scale factor of 1.0 may cause slight changes due to floating-point error). """ if s is not None: scale = Point(s) else: scale = [x, y] affect = [True, True] if scale[0] is None and scale[1] is None: return elif scale[0] is None: affect[0] = False scale[0] = 1.0 elif scale[1] is None: affect[1] = False scale[1] = 1.0 scale = Point(scale) if self.state['aspectLocked'] is not False: scale[0] = scale[1] vr = self.targetRect() if center is None: center = Point(vr.center()) else: center = Point(center) tl = center + (vr.topLeft()-center) * scale br = center + (vr.bottomRight()-center) * scale if not affect[0]: self.setYRange(tl.y(), br.y(), padding=0) elif not affect[1]: self.setXRange(tl.x(), br.x(), padding=0) else: self.setRange(QtCore.QRectF(tl, br), padding=0) def translateBy(self, t=None, x=None, y=None): """ Translate the view by *t*, which may be a Point or tuple (x, y). Alternately, x or y may be specified independently, leaving the other axis unchanged (note that using a translation of 0 may still cause small changes due to floating-point error). """ vr = self.targetRect() if t is not None: t = Point(t) self.setRange(vr.translated(t), padding=0) else: if x is not None: x = vr.left()+x, vr.right()+x if y is not None: y = vr.top()+y, vr.bottom()+y if x is not None or y is not None: self.setRange(xRange=x, yRange=y, padding=0) def enableAutoRange(self, axis=None, enable=True, x=None, y=None): """ Enable (or disable) auto-range for *axis*, which may be ViewBox.XAxis, ViewBox.YAxis, or ViewBox.XYAxes for both (if *axis* is omitted, both axes will be changed). When enabled, the axis will automatically rescale when items are added/removed or change their shape. The argument *enable* may optionally be a float (0.0-1.0) which indicates the fraction of the data that should be visible (this only works with items implementing a dataRange method, such as PlotDataItem). """ #print "autorange:", axis, enable #if not enable: #import traceback #traceback.print_stack() # support simpler interface: if x is not None or y is not None: if x is not None: self.enableAutoRange(ViewBox.XAxis, x) if y is not None: self.enableAutoRange(ViewBox.YAxis, y) return if enable is True: enable = 1.0 if axis is None: axis = ViewBox.XYAxes needAutoRangeUpdate = False if axis == ViewBox.XYAxes or axis == 'xy': axes = [0, 1] elif axis == ViewBox.XAxis or axis == 'x': axes = [0] elif axis == ViewBox.YAxis or axis == 'y': axes = [1] else: raise Exception('axis argument must be ViewBox.XAxis, ViewBox.YAxis, or ViewBox.XYAxes.') for ax in axes: if self.state['autoRange'][ax] != enable: # If we are disabling, do one last auto-range to make sure that # previously scheduled auto-range changes are enacted if enable is False and self._autoRangeNeedsUpdate: self.updateAutoRange() self.state['autoRange'][ax] = enable self._autoRangeNeedsUpdate |= (enable is not False) self.update() #if needAutoRangeUpdate: # self.updateAutoRange() self.sigStateChanged.emit(self) def disableAutoRange(self, axis=None): """Disables auto-range. (See enableAutoRange)""" self.enableAutoRange(axis, enable=False) def autoRangeEnabled(self): return self.state['autoRange'][:] def setAutoPan(self, x=None, y=None): if x is not None: self.state['autoPan'][0] = x if y is not None: self.state['autoPan'][1] = y if None not in [x,y]: self.updateAutoRange() def setAutoVisible(self, x=None, y=None): if x is not None: self.state['autoVisibleOnly'][0] = x if x is True: self.state['autoVisibleOnly'][1] = False if y is not None: self.state['autoVisibleOnly'][1] = y if y is True: self.state['autoVisibleOnly'][0] = False if x is not None or y is not None: self.updateAutoRange() def updateAutoRange(self): ## Break recursive loops when auto-ranging. ## This is needed because some items change their size in response ## to a view change. if self._updatingRange: return self._updatingRange = True try: targetRect = self.viewRange() if not any(self.state['autoRange']): return fractionVisible = self.state['autoRange'][:] for i in [0,1]: if type(fractionVisible[i]) is bool: fractionVisible[i] = 1.0 childRange = None order = [0,1] if self.state['autoVisibleOnly'][0] is True: order = [1,0] args = {} for ax in order: if self.state['autoRange'][ax] is False: continue if self.state['autoVisibleOnly'][ax]: oRange = [None, None] oRange[ax] = targetRect[1-ax] childRange = self.childrenBounds(frac=fractionVisible, orthoRange=oRange) else: if childRange is None: childRange = self.childrenBounds(frac=fractionVisible) ## Make corrections to range xr = childRange[ax] if xr is not None: if self.state['autoPan'][ax]: x = sum(xr) * 0.5 w2 = (targetRect[ax][1]-targetRect[ax][0]) / 2. childRange[ax] = [x-w2, x+w2] else: padding = self.suggestPadding(ax) wp = (xr[1] - xr[0]) * padding childRange[ax][0] -= wp childRange[ax][1] += wp targetRect[ax] = childRange[ax] args['xRange' if ax == 0 else 'yRange'] = targetRect[ax] if len(args) == 0: return args['padding'] = 0 args['disableAutoRange'] = False # check for and ignore bad ranges for k in ['xRange', 'yRange']: if k in args: if not np.all(np.isfinite(args[k])): r = args.pop(k) #print("Warning: %s is invalid: %s" % (k, str(r)) self.setRange(**args) finally: self._autoRangeNeedsUpdate = False self._updatingRange = False def setXLink(self, view): """Link this view's X axis to another view. (see LinkView)""" self.linkView(self.XAxis, view) def setYLink(self, view): """Link this view's Y axis to another view. (see LinkView)""" self.linkView(self.YAxis, view) def linkView(self, axis, view): """ Link X or Y axes of two views and unlink any previously connected axes. *axis* must be ViewBox.XAxis or ViewBox.YAxis. If view is None, the axis is left unlinked. """ if isinstance(view, basestring): if view == '': view = None else: view = ViewBox.NamedViews.get(view, view) ## convert view name to ViewBox if possible if hasattr(view, 'implements') and view.implements('ViewBoxWrapper'): view = view.getViewBox() ## used to connect/disconnect signals between a pair of views if axis == ViewBox.XAxis: signal = 'sigXRangeChanged' slot = self.linkedXChanged else: signal = 'sigYRangeChanged' slot = self.linkedYChanged oldLink = self.linkedView(axis) if oldLink is not None: try: getattr(oldLink, signal).disconnect(slot) oldLink.sigResized.disconnect(slot) except (TypeError, RuntimeError): ## This can occur if the view has been deleted already pass if view is None or isinstance(view, basestring): self.state['linkedViews'][axis] = view else: self.state['linkedViews'][axis] = weakref.ref(view) getattr(view, signal).connect(slot) view.sigResized.connect(slot) if view.autoRangeEnabled()[axis] is not False: self.enableAutoRange(axis, False) slot() else: if self.autoRangeEnabled()[axis] is False: slot() self.sigStateChanged.emit(self) def blockLink(self, b): self.linksBlocked = b ## prevents recursive plot-change propagation def linkedXChanged(self): ## called when x range of linked view has changed view = self.linkedView(0) self.linkedViewChanged(view, ViewBox.XAxis) def linkedYChanged(self): ## called when y range of linked view has changed view = self.linkedView(1) self.linkedViewChanged(view, ViewBox.YAxis) def linkedView(self, ax): ## Return the linked view for axis *ax*. ## this method _always_ returns either a ViewBox or None. v = self.state['linkedViews'][ax] if v is None or isinstance(v, basestring): return None else: return v() ## dereference weakref pointer. If the reference is dead, this returns None def linkedViewChanged(self, view, axis): if self.linksBlocked or view is None: return #print self.name, "ViewBox.linkedViewChanged", axis, view.viewRange()[axis] vr = view.viewRect() vg = view.screenGeometry() sg = self.screenGeometry() if vg is None or sg is None: return view.blockLink(True) try: if axis == ViewBox.XAxis: overlap = min(sg.right(), vg.right()) - max(sg.left(), vg.left()) if overlap < min(vg.width()/3, sg.width()/3): ## if less than 1/3 of views overlap, ## then just replicate the view x1 = vr.left() x2 = vr.right() else: ## views overlap; line them up upp = float(vr.width()) / vg.width() if self.xInverted(): x1 = vr.left() + (sg.right()-vg.right()) * upp else: x1 = vr.left() + (sg.x()-vg.x()) * upp x2 = x1 + sg.width() * upp self.enableAutoRange(ViewBox.XAxis, False) self.setXRange(x1, x2, padding=0) else: overlap = min(sg.bottom(), vg.bottom()) - max(sg.top(), vg.top()) if overlap < min(vg.height()/3, sg.height()/3): ## if less than 1/3 of views overlap, ## then just replicate the view y1 = vr.top() y2 = vr.bottom() else: ## views overlap; line them up upp = float(vr.height()) / vg.height() if self.yInverted(): y2 = vr.bottom() + (sg.bottom()-vg.bottom()) * upp else: y2 = vr.bottom() + (sg.top()-vg.top()) * upp y1 = y2 - sg.height() * upp self.enableAutoRange(ViewBox.YAxis, False) self.setYRange(y1, y2, padding=0) finally: view.blockLink(False) def screenGeometry(self): """return the screen geometry of the viewbox""" v = self.getViewWidget() if v is None: return None b = self.sceneBoundingRect() wr = v.mapFromScene(b).boundingRect() pos = v.mapToGlobal(v.pos()) wr.adjust(pos.x(), pos.y(), pos.x(), pos.y()) return wr def itemsChanged(self): ## called when items are added/removed from self.childGroup self.updateAutoRange() def itemBoundsChanged(self, item): self._itemBoundsCache.pop(item, None) if (self.state['autoRange'][0] is not False) or (self.state['autoRange'][1] is not False): self._autoRangeNeedsUpdate = True self.update() #self.updateAutoRange() def _invertAxis(self, ax, inv): key = 'xy'[ax] + 'Inverted' if self.state[key] == inv: return self.state[key] = inv self._matrixNeedsUpdate = True # updateViewRange won't detect this for us self.updateViewRange() self.update() self.sigStateChanged.emit(self) self.sigYRangeChanged.emit(self, tuple(self.state['viewRange'][ax])) def invertY(self, b=True): """ By default, the positive y-axis points upward on the screen. Use invertY(True) to reverse the y-axis. """ self._invertAxis(1, b) def yInverted(self): return self.state['yInverted'] def invertX(self, b=True): """ By default, the positive x-axis points rightward on the screen. Use invertX(True) to reverse the x-axis. """ self._invertAxis(0, b) def xInverted(self): return self.state['xInverted'] def setAspectLocked(self, lock=True, ratio=1): """ If the aspect ratio is locked, view scaling must always preserve the aspect ratio. By default, the ratio is set to 1; x and y both have the same scaling. This ratio can be overridden (xScale/yScale), or use None to lock in the current ratio. """ if not lock: if self.state['aspectLocked'] == False: return self.state['aspectLocked'] = False else: rect = self.rect() vr = self.viewRect() if rect.height() == 0 or vr.width() == 0 or vr.height() == 0: currentRatio = 1.0 else: currentRatio = (rect.width()/float(rect.height())) / (vr.width()/vr.height()) if ratio is None: ratio = currentRatio if self.state['aspectLocked'] == ratio: # nothing to change return self.state['aspectLocked'] = ratio if ratio != currentRatio: ## If this would change the current range, do that now #self.setRange(0, self.state['viewRange'][0][0], self.state['viewRange'][0][1]) self.updateViewRange() self.updateAutoRange() self.updateViewRange() self.sigStateChanged.emit(self) def childTransform(self): """ Return the transform that maps from child(item in the childGroup) coordinates to local coordinates. (This maps from inside the viewbox to outside) """ if self._matrixNeedsUpdate: self.updateMatrix() m = self.childGroup.transform() #m1 = QtGui.QTransform() #m1.translate(self.childGroup.pos().x(), self.childGroup.pos().y()) return m #*m1 def mapToView(self, obj): """Maps from the local coordinates of the ViewBox to the coordinate system displayed inside the ViewBox""" m = fn.invertQTransform(self.childTransform()) return m.map(obj) def mapFromView(self, obj): """Maps from the coordinate system displayed inside the ViewBox to the local coordinates of the ViewBox""" m = self.childTransform() return m.map(obj) def mapSceneToView(self, obj): """Maps from scene coordinates to the coordinate system displayed inside the ViewBox""" return self.mapToView(self.mapFromScene(obj)) def mapViewToScene(self, obj): """Maps from the coordinate system displayed inside the ViewBox to scene coordinates""" return self.mapToScene(self.mapFromView(obj)) def mapFromItemToView(self, item, obj): """Maps *obj* from the local coordinate system of *item* to the view coordinates""" return self.childGroup.mapFromItem(item, obj) #return self.mapSceneToView(item.mapToScene(obj)) def mapFromViewToItem(self, item, obj): """Maps *obj* from view coordinates to the local coordinate system of *item*.""" return self.childGroup.mapToItem(item, obj) #return item.mapFromScene(self.mapViewToScene(obj)) def mapViewToDevice(self, obj): return self.mapToDevice(self.mapFromView(obj)) def mapDeviceToView(self, obj): return self.mapToView(self.mapFromDevice(obj)) def viewPixelSize(self): """Return the (width, height) of a screen pixel in view coordinates.""" o = self.mapToView(Point(0,0)) px, py = [Point(self.mapToView(v) - o) for v in self.pixelVectors()] return (px.length(), py.length()) def itemBoundingRect(self, item): """Return the bounding rect of the item in view coordinates""" return self.mapSceneToView(item.sceneBoundingRect()).boundingRect() #def viewScale(self): #vr = self.viewRect() ##print "viewScale:", self.range #xd = vr.width() #yd = vr.height() #if xd == 0 or yd == 0: #print "Warning: 0 range in view:", xd, yd #return np.array([1,1]) ##cs = self.canvas().size() #cs = self.boundingRect() #scale = np.array([cs.width() / xd, cs.height() / yd]) ##print "view scale:", scale #return scale def wheelEvent(self, ev, axis=None): mask = np.array(self.state['mouseEnabled'], dtype=np.float) if axis is not None and axis >= 0 and axis < len(mask): mv = mask[axis] mask[:] = 0 mask[axis] = mv s = ((mask * 0.02) + 1) ** (ev.delta() * self.state['wheelScaleFactor']) # actual scaling factor center = Point(fn.invertQTransform(self.childGroup.transform()).map(ev.pos())) #center = ev.pos() self._resetTarget() self.scaleBy(s, center) self.sigRangeChangedManually.emit(self.state['mouseEnabled']) ev.accept() def mouseClickEvent(self, ev): if ev.button() == QtCore.Qt.RightButton and self.menuEnabled(): ev.accept() self.raiseContextMenu(ev) def raiseContextMenu(self, ev): menu = self.getMenu(ev) self.scene().addParentContextMenus(self, menu, ev) menu.popup(ev.screenPos().toPoint()) def getMenu(self, ev): return self.menu def getContextMenus(self, event): return self.menu.actions() if self.menuEnabled() else [] def mouseDragEvent(self, ev, axis=None): ## if axis is specified, event will only affect that axis. ev.accept() ## we accept all buttons pos = ev.pos() lastPos = ev.lastPos() dif = pos - lastPos dif = dif * -1 ## Ignore axes if mouse is disabled mouseEnabled = np.array(self.state['mouseEnabled'], dtype=np.float) mask = mouseEnabled.copy() if axis is not None: mask[1-axis] = 0.0 ## Scale or translate based on mouse button if ev.button() & (QtCore.Qt.LeftButton | QtCore.Qt.MidButton): if self.state['mouseMode'] == ViewBox.RectMode: if ev.isFinish(): ## This is the final move in the drag; change the view scale now #print "finish" self.rbScaleBox.hide() #ax = QtCore.QRectF(Point(self.pressPos), Point(self.mousePos)) ax = QtCore.QRectF(Point(ev.buttonDownPos(ev.button())), Point(pos)) ax = self.childGroup.mapRectFromParent(ax) self.showAxRect(ax) self.axHistoryPointer += 1 self.axHistory = self.axHistory[:self.axHistoryPointer] + [ax] else: ## update shape of scale box self.updateScaleBox(ev.buttonDownPos(), ev.pos()) else: tr = dif*mask tr = self.mapToView(tr) - self.mapToView(Point(0,0)) x = tr.x() if mask[0] == 1 else None y = tr.y() if mask[1] == 1 else None self._resetTarget() if x is not None or y is not None: self.translateBy(x=x, y=y) self.sigRangeChangedManually.emit(self.state['mouseEnabled']) elif ev.button() & QtCore.Qt.RightButton: #print "vb.rightDrag" if self.state['aspectLocked'] is not False: mask[0] = 0 dif = ev.screenPos() - ev.lastScreenPos() dif = np.array([dif.x(), dif.y()]) dif[0] *= -1 s = ((mask * 0.02) + 1) ** dif tr = self.childGroup.transform() tr = fn.invertQTransform(tr) x = s[0] if mouseEnabled[0] == 1 else None y = s[1] if mouseEnabled[1] == 1 else None center = Point(tr.map(ev.buttonDownPos(QtCore.Qt.RightButton))) self._resetTarget() self.scaleBy(x=x, y=y, center=center) self.sigRangeChangedManually.emit(self.state['mouseEnabled']) def keyPressEvent(self, ev): """ This routine should capture key presses in the current view box. Key presses are used only when mouse mode is RectMode The following events are implemented: ctrl-A : zooms out to the default "full" view of the plot ctrl-+ : moves forward in the zooming stack (if it exists) ctrl-- : moves backward in the zooming stack (if it exists) """ #print ev.key() #print 'I intercepted a key press, but did not accept it' ## not implemented yet ? #self.keypress.sigkeyPressEvent.emit() ev.accept() if ev.text() == '-': self.scaleHistory(-1) elif ev.text() in ['+', '=']: self.scaleHistory(1) elif ev.key() == QtCore.Qt.Key_Backspace: self.scaleHistory(len(self.axHistory)) else: ev.ignore() def scaleHistory(self, d): if len(self.axHistory) == 0: return ptr = max(0, min(len(self.axHistory)-1, self.axHistoryPointer+d)) if ptr != self.axHistoryPointer: self.axHistoryPointer = ptr self.showAxRect(self.axHistory[ptr]) def updateScaleBox(self, p1, p2): r = QtCore.QRectF(p1, p2) r = self.childGroup.mapRectFromParent(r) self.rbScaleBox.setPos(r.topLeft()) self.rbScaleBox.resetTransform() self.rbScaleBox.scale(r.width(), r.height()) self.rbScaleBox.show() def showAxRect(self, ax): self.setRange(ax.normalized()) # be sure w, h are correct coordinates self.sigRangeChangedManually.emit(self.state['mouseEnabled']) #def mouseRect(self): #vs = self.viewScale() #vr = self.state['viewRange'] ## Convert positions from screen (view) pixel coordinates to axis coordinates #ax = QtCore.QRectF(self.pressPos[0]/vs[0]+vr[0][0], -(self.pressPos[1]/vs[1]-vr[1][1]), #(self.mousePos[0]-self.pressPos[0])/vs[0], -(self.mousePos[1]-self.pressPos[1])/vs[1]) #return(ax) def allChildren(self, item=None): """Return a list of all children and grandchildren of this ViewBox""" if item is None: item = self.childGroup children = [item] for ch in item.childItems(): children.extend(self.allChildren(ch)) return children def childrenBounds(self, frac=None, orthoRange=(None,None), items=None): """Return the bounding range of all children. [[xmin, xmax], [ymin, ymax]] Values may be None if there are no specific bounds for an axis. """ profiler = debug.Profiler() if items is None: items = self.addedItems ## measure pixel dimensions in view box px, py = [v.length() if v is not None else 0 for v in self.childGroup.pixelVectors()] ## First collect all boundary information itemBounds = [] for item in items: if not item.isVisible(): continue useX = True useY = True if hasattr(item, 'dataBounds'): #bounds = self._itemBoundsCache.get(item, None) #if bounds is None: if frac is None: frac = (1.0, 1.0) xr = item.dataBounds(0, frac=frac[0], orthoRange=orthoRange[0]) yr = item.dataBounds(1, frac=frac[1], orthoRange=orthoRange[1]) pxPad = 0 if not hasattr(item, 'pixelPadding') else item.pixelPadding() if xr is None or (xr[0] is None and xr[1] is None) or np.isnan(xr).any() or np.isinf(xr).any(): useX = False xr = (0,0) if yr is None or (yr[0] is None and yr[1] is None) or np.isnan(yr).any() or np.isinf(yr).any(): useY = False yr = (0,0) bounds = QtCore.QRectF(xr[0], yr[0], xr[1]-xr[0], yr[1]-yr[0]) bounds = self.mapFromItemToView(item, bounds).boundingRect() if not any([useX, useY]): continue ## If we are ignoring only one axis, we need to check for rotations if useX != useY: ## != means xor ang = round(item.transformAngle()) if ang == 0 or ang == 180: pass elif ang == 90 or ang == 270: useX, useY = useY, useX else: ## Item is rotated at non-orthogonal angle, ignore bounds entirely. ## Not really sure what is the expected behavior in this case. continue ## need to check for item rotations and decide how best to apply this boundary. itemBounds.append((bounds, useX, useY, pxPad)) #self._itemBoundsCache[item] = (bounds, useX, useY) #else: #bounds, useX, useY = bounds else: if int(item.flags() & item.ItemHasNoContents) > 0: continue else: bounds = item.boundingRect() bounds = self.mapFromItemToView(item, bounds).boundingRect() itemBounds.append((bounds, True, True, 0)) #print itemBounds ## determine tentative new range range = [None, None] for bounds, useX, useY, px in itemBounds: if useY: if range[1] is not None: range[1] = [min(bounds.top(), range[1][0]), max(bounds.bottom(), range[1][1])] else: range[1] = [bounds.top(), bounds.bottom()] if useX: if range[0] is not None: range[0] = [min(bounds.left(), range[0][0]), max(bounds.right(), range[0][1])] else: range[0] = [bounds.left(), bounds.right()] profiler() #print "range", range ## Now expand any bounds that have a pixel margin ## This must be done _after_ we have a good estimate of the new range ## to ensure that the pixel size is roughly accurate. w = self.width() h = self.height() #print "w:", w, "h:", h if w > 0 and range[0] is not None: pxSize = (range[0][1] - range[0][0]) / w for bounds, useX, useY, px in itemBounds: if px == 0 or not useX: continue range[0][0] = min(range[0][0], bounds.left() - px*pxSize) range[0][1] = max(range[0][1], bounds.right() + px*pxSize) if h > 0 and range[1] is not None: pxSize = (range[1][1] - range[1][0]) / h for bounds, useX, useY, px in itemBounds: if px == 0 or not useY: continue range[1][0] = min(range[1][0], bounds.top() - px*pxSize) range[1][1] = max(range[1][1], bounds.bottom() + px*pxSize) return range def childrenBoundingRect(self, *args, **kwds): range = self.childrenBounds(*args, **kwds) tr = self.targetRange() if range[0] is None: range[0] = tr[0] if range[1] is None: range[1] = tr[1] bounds = QtCore.QRectF(range[0][0], range[1][0], range[0][1]-range[0][0], range[1][1]-range[1][0]) return bounds def updateViewRange(self, forceX=False, forceY=False): ## Update viewRange to match targetRange as closely as possible, given ## aspect ratio constraints. The *force* arguments are used to indicate ## which axis (if any) should be unchanged when applying constraints. viewRange = [self.state['targetRange'][0][:], self.state['targetRange'][1][:]] changed = [False, False] #-------- Make correction for aspect ratio constraint ---------- # aspect is (widget w/h) / (view range w/h) aspect = self.state['aspectLocked'] # size ratio / view ratio tr = self.targetRect() bounds = self.rect() if aspect is not False and 0 not in [aspect, tr.height(), bounds.height(), bounds.width()]: ## This is the view range aspect ratio we have requested targetRatio = tr.width() / tr.height() if tr.height() != 0 else 1 ## This is the view range aspect ratio we need to obey aspect constraint viewRatio = (bounds.width() / bounds.height() if bounds.height() != 0 else 1) / aspect viewRatio = 1 if viewRatio == 0 else viewRatio # Decide which range to keep unchanged #print self.name, "aspect:", aspect, "changed:", changed, "auto:", self.state['autoRange'] if forceX: ax = 0 elif forceY: ax = 1 else: # if we are not required to keep a particular axis unchanged, # then make the entire target range visible ax = 0 if targetRatio > viewRatio else 1 if ax == 0: ## view range needs to be taller than target dy = 0.5 * (tr.width() / viewRatio - tr.height()) if dy != 0: changed[1] = True viewRange[1] = [self.state['targetRange'][1][0] - dy, self.state['targetRange'][1][1] + dy] else: ## view range needs to be wider than target dx = 0.5 * (tr.height() * viewRatio - tr.width()) if dx != 0: changed[0] = True viewRange[0] = [self.state['targetRange'][0][0] - dx, self.state['targetRange'][0][1] + dx] # ----------- Make corrections for view limits ----------- limits = (self.state['limits']['xLimits'], self.state['limits']['yLimits']) minRng = [self.state['limits']['xRange'][0], self.state['limits']['yRange'][0]] maxRng = [self.state['limits']['xRange'][1], self.state['limits']['yRange'][1]] for axis in [0, 1]: if limits[axis][0] is None and limits[axis][1] is None and minRng[axis] is None and maxRng[axis] is None: continue # max range cannot be larger than bounds, if they are given if limits[axis][0] is not None and limits[axis][1] is not None: if maxRng[axis] is not None: maxRng[axis] = min(maxRng[axis], limits[axis][1]-limits[axis][0]) else: maxRng[axis] = limits[axis][1]-limits[axis][0] #print "\nLimits for axis %d: range=%s min=%s max=%s" % (axis, limits[axis], minRng[axis], maxRng[axis]) #print "Starting range:", viewRange[axis] # Apply xRange, yRange diff = viewRange[axis][1] - viewRange[axis][0] if maxRng[axis] is not None and diff > maxRng[axis]: delta = maxRng[axis] - diff changed[axis] = True elif minRng[axis] is not None and diff < minRng[axis]: delta = minRng[axis] - diff changed[axis] = True else: delta = 0 viewRange[axis][0] -= delta/2. viewRange[axis][1] += delta/2. #print "after applying min/max:", viewRange[axis] # Apply xLimits, yLimits mn, mx = limits[axis] if mn is not None and viewRange[axis][0] < mn: delta = mn - viewRange[axis][0] viewRange[axis][0] += delta viewRange[axis][1] += delta changed[axis] = True elif mx is not None and viewRange[axis][1] > mx: delta = mx - viewRange[axis][1] viewRange[axis][0] += delta viewRange[axis][1] += delta changed[axis] = True #print "after applying edge limits:", viewRange[axis] changed = [(viewRange[i][0] != self.state['viewRange'][i][0]) or (viewRange[i][1] != self.state['viewRange'][i][1]) for i in (0,1)] self.state['viewRange'] = viewRange # emit range change signals if changed[0]: self.sigXRangeChanged.emit(self, tuple(self.state['viewRange'][0])) if changed[1]: self.sigYRangeChanged.emit(self, tuple(self.state['viewRange'][1])) if any(changed): self.sigRangeChanged.emit(self, self.state['viewRange']) self.update() self._matrixNeedsUpdate = True # Inform linked views that the range has changed for ax in [0, 1]: if not changed[ax]: continue link = self.linkedView(ax) if link is not None: link.linkedViewChanged(self, ax) def updateMatrix(self, changed=None): ## Make the childGroup's transform match the requested viewRange. bounds = self.rect() vr = self.viewRect() if vr.height() == 0 or vr.width() == 0: return scale = Point(bounds.width()/vr.width(), bounds.height()/vr.height()) if not self.state['yInverted']: scale = scale * Point(1, -1) if self.state['xInverted']: scale = scale * Point(-1, 1) m = QtGui.QTransform() ## First center the viewport at 0 center = bounds.center() m.translate(center.x(), center.y()) ## Now scale and translate properly m.scale(scale[0], scale[1]) st = Point(vr.center()) m.translate(-st[0], -st[1]) self.childGroup.setTransform(m) self.sigTransformChanged.emit(self) ## segfaults here: 1 self._matrixNeedsUpdate = False def paint(self, p, opt, widget): self.checkSceneChange() if self.border is not None: bounds = self.shape() p.setPen(self.border) #p.fillRect(bounds, QtGui.QColor(0, 0, 0)) p.drawPath(bounds) #p.setPen(fn.mkPen('r')) #path = QtGui.QPainterPath() #path.addRect(self.targetRect()) #tr = self.mapFromView(path) #p.drawPath(tr) def updateBackground(self): bg = self.state['background'] if bg is None: self.background.hide() else: self.background.show() self.background.setBrush(fn.mkBrush(bg)) def updateViewLists(self): try: self.window() except RuntimeError: ## this view has already been deleted; it will probably be collected shortly. return def cmpViews(a, b): wins = 100 * cmp(a.window() is self.window(), b.window() is self.window()) alpha = cmp(a.name, b.name) return wins + alpha ## make a sorted list of all named views nv = list(ViewBox.NamedViews.values()) #print "new view list:", nv sortList(nv, cmpViews) ## see pyqtgraph.python2_3.sortList if self in nv: nv.remove(self) self.menu.setViewList(nv) for ax in [0,1]: link = self.state['linkedViews'][ax] if isinstance(link, basestring): ## axis has not been linked yet; see if it's possible now for v in nv: if link == v.name: self.linkView(ax, v) #print "New view list:", nv #print "linked views:", self.state['linkedViews'] @staticmethod def updateAllViewLists(): #print "Update:", ViewBox.AllViews.keys() #print "Update:", ViewBox.NamedViews.keys() for v in ViewBox.AllViews: v.updateViewLists() @staticmethod def forgetView(vid, name): if ViewBox is None: ## can happen as python is shutting down return if QtGui.QApplication.instance() is None: return ## Called with ID and name of view (the view itself is no longer available) for v in list(ViewBox.AllViews.keys()): if id(v) == vid: ViewBox.AllViews.pop(v) break ViewBox.NamedViews.pop(name, None) ViewBox.updateAllViewLists() @staticmethod def quit(): ## called when the application is about to exit. ## this disables all callbacks, which might otherwise generate errors if invoked during exit. for k in ViewBox.AllViews: if isQObjectAlive(k) and getConfigOption('crashWarning'): sys.stderr.write('Warning: ViewBox should be closed before application exit.\n') try: k.destroyed.disconnect() except RuntimeError: ## signal is already disconnected. pass except TypeError: ## view has already been deleted (?) pass except AttributeError: # PySide has deleted signal pass def locate(self, item, timeout=3.0, children=False): """ Temporarily display the bounding rect of an item and lines connecting to the center of the view. This is useful for determining the location of items that may be out of the range of the ViewBox. if allChildren is True, then the bounding rect of all item's children will be shown instead. """ self.clearLocate() if item.scene() is not self.scene(): raise Exception("Item does not share a scene with this ViewBox.") c = self.viewRect().center() if children: br = self.mapFromItemToView(item, item.childrenBoundingRect()).boundingRect() else: br = self.mapFromItemToView(item, item.boundingRect()).boundingRect() g = ItemGroup() g.setParentItem(self.childGroup) self.locateGroup = g g.box = QtGui.QGraphicsRectItem(br) g.box.setParentItem(g) g.lines = [] for p in (br.topLeft(), br.bottomLeft(), br.bottomRight(), br.topRight()): line = QtGui.QGraphicsLineItem(c.x(), c.y(), p.x(), p.y()) line.setParentItem(g) g.lines.append(line) for item in g.childItems(): item.setPen(fn.mkPen(color='y', width=3)) g.setZValue(1000000) if children: g.path = QtGui.QGraphicsPathItem(g.childrenShape()) else: g.path = QtGui.QGraphicsPathItem(g.shape()) g.path.setParentItem(g) g.path.setPen(fn.mkPen('g')) g.path.setZValue(100) QtCore.QTimer.singleShot(timeout*1000, self.clearLocate) def clearLocate(self): if self.locateGroup is None: return self.scene().removeItem(self.locateGroup) self.locateGroup = None from .ViewBoxMenu import ViewBoxMenu ��������������������������������������������������������������������������������������������pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/ViewBox/ViewBoxMenu.py���������������������������0000664�0000000�0000000�00000023274�13007271214�0026617�0����������������������������������������������������������������������������������������������������ustar�00root����������������������������root����������������������������0000000�0000000������������������������������������������������������������������������������������������������������������������������������������������������������������������������from ...Qt import QtCore, QtGui, QT_LIB from ...python2_3 import asUnicode from ...WidgetGroup import WidgetGroup if QT_LIB == 'PyQt4': from .axisCtrlTemplate_pyqt import Ui_Form as AxisCtrlTemplate elif QT_LIB == 'PySide': from .axisCtrlTemplate_pyside import Ui_Form as AxisCtrlTemplate elif QT_LIB == 'PyQt5': from .axisCtrlTemplate_pyqt5 import Ui_Form as AxisCtrlTemplate import weakref class ViewBoxMenu(QtGui.QMenu): def __init__(self, view): QtGui.QMenu.__init__(self) self.view = weakref.ref(view) ## keep weakref to view to avoid circular reference (don't know why, but this prevents the ViewBox from being collected) self.valid = False ## tells us whether the ui needs to be updated self.viewMap = weakref.WeakValueDictionary() ## weakrefs to all views listed in the link combos self.setTitle("ViewBox options") self.viewAll = QtGui.QAction("View All", self) self.viewAll.triggered.connect(self.autoRange) self.addAction(self.viewAll) self.axes = [] self.ctrl = [] self.widgetGroups = [] self.dv = QtGui.QDoubleValidator(self) for axis in 'XY': m = QtGui.QMenu() m.setTitle("%s Axis" % axis) w = QtGui.QWidget() ui = AxisCtrlTemplate() ui.setupUi(w) a = QtGui.QWidgetAction(self) a.setDefaultWidget(w) m.addAction(a) self.addMenu(m) self.axes.append(m) self.ctrl.append(ui) wg = WidgetGroup(w) self.widgetGroups.append(w) connects = [ (ui.mouseCheck.toggled, 'MouseToggled'), (ui.manualRadio.clicked, 'ManualClicked'), (ui.minText.editingFinished, 'MinTextChanged'), (ui.maxText.editingFinished, 'MaxTextChanged'), (ui.autoRadio.clicked, 'AutoClicked'), (ui.autoPercentSpin.valueChanged, 'AutoSpinChanged'), (ui.linkCombo.currentIndexChanged, 'LinkComboChanged'), (ui.autoPanCheck.toggled, 'AutoPanToggled'), (ui.visibleOnlyCheck.toggled, 'VisibleOnlyToggled') ] for sig, fn in connects: sig.connect(getattr(self, axis.lower()+fn)) self.ctrl[0].invertCheck.toggled.connect(self.xInvertToggled) self.ctrl[1].invertCheck.toggled.connect(self.yInvertToggled) ## exporting is handled by GraphicsScene now #self.export = QtGui.QMenu("Export") #self.setExportMethods(view.exportMethods) #self.addMenu(self.export) self.leftMenu = QtGui.QMenu("Mouse Mode") group = QtGui.QActionGroup(self) # This does not work! QAction _must_ be initialized with a permanent # object as the parent or else it may be collected prematurely. #pan = self.leftMenu.addAction("3 button", self.set3ButtonMode) #zoom = self.leftMenu.addAction("1 button", self.set1ButtonMode) pan = QtGui.QAction("3 button", self.leftMenu) zoom = QtGui.QAction("1 button", self.leftMenu) self.leftMenu.addAction(pan) self.leftMenu.addAction(zoom) pan.triggered.connect(self.set3ButtonMode) zoom.triggered.connect(self.set1ButtonMode) pan.setCheckable(True) zoom.setCheckable(True) pan.setActionGroup(group) zoom.setActionGroup(group) self.mouseModes = [pan, zoom] self.addMenu(self.leftMenu) self.view().sigStateChanged.connect(self.viewStateChanged) self.updateState() def setExportMethods(self, methods): self.exportMethods = methods self.export.clear() for opt, fn in methods.items(): self.export.addAction(opt, self.exportMethod) def viewStateChanged(self): self.valid = False if self.ctrl[0].minText.isVisible() or self.ctrl[1].minText.isVisible(): self.updateState() def updateState(self): ## Something about the viewbox has changed; update the menu GUI state = self.view().getState(copy=False) if state['mouseMode'] == ViewBox.PanMode: self.mouseModes[0].setChecked(True) else: self.mouseModes[1].setChecked(True) for i in [0,1]: # x, y tr = state['targetRange'][i] self.ctrl[i].minText.setText("%0.5g" % tr[0]) self.ctrl[i].maxText.setText("%0.5g" % tr[1]) if state['autoRange'][i] is not False: self.ctrl[i].autoRadio.setChecked(True) if state['autoRange'][i] is not True: self.ctrl[i].autoPercentSpin.setValue(state['autoRange'][i]*100) else: self.ctrl[i].manualRadio.setChecked(True) self.ctrl[i].mouseCheck.setChecked(state['mouseEnabled'][i]) ## Update combo to show currently linked view c = self.ctrl[i].linkCombo c.blockSignals(True) try: view = state['linkedViews'][i] ## will always be string or None if view is None: view = '' ind = c.findText(view) if ind == -1: ind = 0 c.setCurrentIndex(ind) finally: c.blockSignals(False) self.ctrl[i].autoPanCheck.setChecked(state['autoPan'][i]) self.ctrl[i].visibleOnlyCheck.setChecked(state['autoVisibleOnly'][i]) xy = ['x', 'y'][i] self.ctrl[i].invertCheck.setChecked(state.get(xy+'Inverted', False)) self.valid = True def popup(self, *args): if not self.valid: self.updateState() QtGui.QMenu.popup(self, *args) def autoRange(self): self.view().autoRange() ## don't let signal call this directly--it'll add an unwanted argument def xMouseToggled(self, b): self.view().setMouseEnabled(x=b) def xManualClicked(self): self.view().enableAutoRange(ViewBox.XAxis, False) def xMinTextChanged(self): self.ctrl[0].manualRadio.setChecked(True) self.view().setXRange(float(self.ctrl[0].minText.text()), float(self.ctrl[0].maxText.text()), padding=0) def xMaxTextChanged(self): self.ctrl[0].manualRadio.setChecked(True) self.view().setXRange(float(self.ctrl[0].minText.text()), float(self.ctrl[0].maxText.text()), padding=0) def xAutoClicked(self): val = self.ctrl[0].autoPercentSpin.value() * 0.01 self.view().enableAutoRange(ViewBox.XAxis, val) def xAutoSpinChanged(self, val): self.ctrl[0].autoRadio.setChecked(True) self.view().enableAutoRange(ViewBox.XAxis, val*0.01) def xLinkComboChanged(self, ind): self.view().setXLink(str(self.ctrl[0].linkCombo.currentText())) def xAutoPanToggled(self, b): self.view().setAutoPan(x=b) def xVisibleOnlyToggled(self, b): self.view().setAutoVisible(x=b) def yMouseToggled(self, b): self.view().setMouseEnabled(y=b) def yManualClicked(self): self.view().enableAutoRange(ViewBox.YAxis, False) def yMinTextChanged(self): self.ctrl[1].manualRadio.setChecked(True) self.view().setYRange(float(self.ctrl[1].minText.text()), float(self.ctrl[1].maxText.text()), padding=0) def yMaxTextChanged(self): self.ctrl[1].manualRadio.setChecked(True) self.view().setYRange(float(self.ctrl[1].minText.text()), float(self.ctrl[1].maxText.text()), padding=0) def yAutoClicked(self): val = self.ctrl[1].autoPercentSpin.value() * 0.01 self.view().enableAutoRange(ViewBox.YAxis, val) def yAutoSpinChanged(self, val): self.ctrl[1].autoRadio.setChecked(True) self.view().enableAutoRange(ViewBox.YAxis, val*0.01) def yLinkComboChanged(self, ind): self.view().setYLink(str(self.ctrl[1].linkCombo.currentText())) def yAutoPanToggled(self, b): self.view().setAutoPan(y=b) def yVisibleOnlyToggled(self, b): self.view().setAutoVisible(y=b) def yInvertToggled(self, b): self.view().invertY(b) def xInvertToggled(self, b): self.view().invertX(b) def exportMethod(self): act = self.sender() self.exportMethods[str(act.text())]() def set3ButtonMode(self): self.view().setLeftButtonAction('pan') def set1ButtonMode(self): self.view().setLeftButtonAction('rect') def setViewList(self, views): names = [''] self.viewMap.clear() ## generate list of views to show in the link combo for v in views: name = v.name if name is None: ## unnamed views do not show up in the view list (although they are linkable) continue names.append(name) self.viewMap[name] = v for i in [0,1]: c = self.ctrl[i].linkCombo current = asUnicode(c.currentText()) c.blockSignals(True) changed = True try: c.clear() for name in names: c.addItem(name) if name == current: changed = False c.setCurrentIndex(c.count()-1) finally: c.blockSignals(False) if changed: c.setCurrentIndex(0) c.currentIndexChanged.emit(c.currentIndex()) from .ViewBox import ViewBox ������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/ViewBox/__init__.py������������������������������0000664�0000000�0000000�00000000035�13007271214�0026134�0����������������������������������������������������������������������������������������������������ustar�00root����������������������������root����������������������������0000000�0000000������������������������������������������������������������������������������������������������������������������������������������������������������������������������from .ViewBox import ViewBox ���������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������������pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/ViewBox/axisCtrlTemplate.ui����������������������0000664�0000000�0000000�00000013000�13007271214�0027643�0����������������������������������������������������������������������������������������������������ustar�00root����������������������������root����������������������������0000000�0000000������������������������������������������������������������������������������������������������������������������������������������������������������������������������ Form 0 0 186 154 200 16777215 Form 0 0 Link Axis: <html><head/><body><p>Links this axis with another view. When linked, both views will display the same data range.</p></body></html> QComboBox::AdjustToContents true <html><head/><body><p>Percent of data to be visible when auto-scaling. It may be useful to decrease this value for data with spiky noise.</p></body></html> % 1 100 1 100 <html><head/><body><p>Automatically resize this axis whenever the displayed data is changed.</p></body></html> Auto true <html><head/><body><p>Set the range for this axis manually. This disables automatic scaling. </p></body></html> Manual <html><head/><body><p>Minimum value to display for this axis.</p></body></html> 0 <html><head/><body><p>Maximum value to display for this axis.</p></body></html> 0 <html><head/><body><p>Inverts the display of this axis. (+y points downward instead of upward)</p></body></html> Invert Axis <html><head/><body><p>Enables mouse interaction (panning, scaling) for this axis.</p></body></html> Mouse Enabled true <html><head/><body><p>When checked, the axis will only auto-scale to data that is visible along the orthogonal axis.</p></body></html> Visible Data Only <html><head/><body><p>When checked, the axis will automatically pan to center on the current data, but the scale along this axis will not change.</p></body></html> Auto Pan Only pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/ViewBox/axisCtrlTemplate_pyqt.py�����������������0000664�0000000�0000000�00000013766�13007271214�0030756�0����������������������������������������������������������������������������������������������������ustar�00root����������������������������root����������������������������0000000�0000000������������������������������������������������������������������������������������������������������������������������������������������������������������������������# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './pyqtgraph/graphicsItems/ViewBox/axisCtrlTemplate.ui' # # Created: Mon Dec 23 10:10:51 2013 # by: PyQt4 UI code generator 4.10 # # WARNING! All changes made in this file will be lost! from ...Qt import QtCore, QtGui try: _fromUtf8 = QtCore.QString.fromUtf8 except AttributeError: def _fromUtf8(s): return s try: _encoding = QtGui.QApplication.UnicodeUTF8 def _translate(context, text, disambig): return QtGui.QApplication.translate(context, text, disambig, _encoding) except AttributeError: def _translate(context, text, disambig): return QtGui.QApplication.translate(context, text, disambig) class Ui_Form(object): def setupUi(self, Form): Form.setObjectName(_fromUtf8("Form")) Form.resize(186, 154) Form.setMaximumSize(QtCore.QSize(200, 16777215)) self.gridLayout = QtGui.QGridLayout(Form) self.gridLayout.setMargin(0) self.gridLayout.setSpacing(0) self.gridLayout.setObjectName(_fromUtf8("gridLayout")) self.label = QtGui.QLabel(Form) self.label.setObjectName(_fromUtf8("label")) self.gridLayout.addWidget(self.label, 7, 0, 1, 2) self.linkCombo = QtGui.QComboBox(Form) self.linkCombo.setSizeAdjustPolicy(QtGui.QComboBox.AdjustToContents) self.linkCombo.setObjectName(_fromUtf8("linkCombo")) self.gridLayout.addWidget(self.linkCombo, 7, 2, 1, 2) self.autoPercentSpin = QtGui.QSpinBox(Form) self.autoPercentSpin.setEnabled(True) self.autoPercentSpin.setMinimum(1) self.autoPercentSpin.setMaximum(100) self.autoPercentSpin.setSingleStep(1) self.autoPercentSpin.setProperty("value", 100) self.autoPercentSpin.setObjectName(_fromUtf8("autoPercentSpin")) self.gridLayout.addWidget(self.autoPercentSpin, 2, 2, 1, 2) self.autoRadio = QtGui.QRadioButton(Form) self.autoRadio.setChecked(True) self.autoRadio.setObjectName(_fromUtf8("autoRadio")) self.gridLayout.addWidget(self.autoRadio, 2, 0, 1, 2) self.manualRadio = QtGui.QRadioButton(Form) self.manualRadio.setObjectName(_fromUtf8("manualRadio")) self.gridLayout.addWidget(self.manualRadio, 1, 0, 1, 2) self.minText = QtGui.QLineEdit(Form) self.minText.setObjectName(_fromUtf8("minText")) self.gridLayout.addWidget(self.minText, 1, 2, 1, 1) self.maxText = QtGui.QLineEdit(Form) self.maxText.setObjectName(_fromUtf8("maxText")) self.gridLayout.addWidget(self.maxText, 1, 3, 1, 1) self.invertCheck = QtGui.QCheckBox(Form) self.invertCheck.setObjectName(_fromUtf8("invertCheck")) self.gridLayout.addWidget(self.invertCheck, 5, 0, 1, 4) self.mouseCheck = QtGui.QCheckBox(Form) self.mouseCheck.setChecked(True) self.mouseCheck.setObjectName(_fromUtf8("mouseCheck")) self.gridLayout.addWidget(self.mouseCheck, 6, 0, 1, 4) self.visibleOnlyCheck = QtGui.QCheckBox(Form) self.visibleOnlyCheck.setObjectName(_fromUtf8("visibleOnlyCheck")) self.gridLayout.addWidget(self.visibleOnlyCheck, 3, 2, 1, 2) self.autoPanCheck = QtGui.QCheckBox(Form) self.autoPanCheck.setObjectName(_fromUtf8("autoPanCheck")) self.gridLayout.addWidget(self.autoPanCheck, 4, 2, 1, 2) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): Form.setWindowTitle(_translate("Form", "Form", None)) self.label.setText(_translate("Form", "Link Axis:", None)) self.linkCombo.setToolTip(_translate("Form", "

Links this axis with another view. When linked, both views will display the same data range.

", None)) self.autoPercentSpin.setToolTip(_translate("Form", "

Percent of data to be visible when auto-scaling. It may be useful to decrease this value for data with spiky noise.

", None)) self.autoPercentSpin.setSuffix(_translate("Form", "%", None)) self.autoRadio.setToolTip(_translate("Form", "

Automatically resize this axis whenever the displayed data is changed.

", None)) self.autoRadio.setText(_translate("Form", "Auto", None)) self.manualRadio.setToolTip(_translate("Form", "

Set the range for this axis manually. This disables automatic scaling.

", None)) self.manualRadio.setText(_translate("Form", "Manual", None)) self.minText.setToolTip(_translate("Form", "

Minimum value to display for this axis.

", None)) self.minText.setText(_translate("Form", "0", None)) self.maxText.setToolTip(_translate("Form", "

Maximum value to display for this axis.

", None)) self.maxText.setText(_translate("Form", "0", None)) self.invertCheck.setToolTip(_translate("Form", "

Inverts the display of this axis. (+y points downward instead of upward)

", None)) self.invertCheck.setText(_translate("Form", "Invert Axis", None)) self.mouseCheck.setToolTip(_translate("Form", "

Enables mouse interaction (panning, scaling) for this axis.

", None)) self.mouseCheck.setText(_translate("Form", "Mouse Enabled", None)) self.visibleOnlyCheck.setToolTip(_translate("Form", "

When checked, the axis will only auto-scale to data that is visible along the orthogonal axis.

", None)) self.visibleOnlyCheck.setText(_translate("Form", "Visible Data Only", None)) self.autoPanCheck.setToolTip(_translate("Form", "

When checked, the axis will automatically pan to center on the current data, but the scale along this axis will not change.

", None)) self.autoPanCheck.setText(_translate("Form", "Auto Pan Only", None)) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/ViewBox/axisCtrlTemplate_pyqt5.py000066400000000000000000000127131300727121400310320ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './pyqtgraph/graphicsItems/ViewBox/axisCtrlTemplate.ui' # # Created: Wed Mar 26 15:09:28 2014 # by: PyQt5 UI code generator 5.0.1 # # WARNING! All changes made in this file will be lost! from PyQt5 import QtCore, QtGui, QtWidgets class Ui_Form(object): def setupUi(self, Form): Form.setObjectName("Form") Form.resize(186, 154) Form.setMaximumSize(QtCore.QSize(200, 16777215)) self.gridLayout = QtWidgets.QGridLayout(Form) self.gridLayout.setContentsMargins(0, 0, 0, 0) self.gridLayout.setSpacing(0) self.gridLayout.setObjectName("gridLayout") self.label = QtWidgets.QLabel(Form) self.label.setObjectName("label") self.gridLayout.addWidget(self.label, 7, 0, 1, 2) self.linkCombo = QtWidgets.QComboBox(Form) self.linkCombo.setSizeAdjustPolicy(QtWidgets.QComboBox.AdjustToContents) self.linkCombo.setObjectName("linkCombo") self.gridLayout.addWidget(self.linkCombo, 7, 2, 1, 2) self.autoPercentSpin = QtWidgets.QSpinBox(Form) self.autoPercentSpin.setEnabled(True) self.autoPercentSpin.setMinimum(1) self.autoPercentSpin.setMaximum(100) self.autoPercentSpin.setSingleStep(1) self.autoPercentSpin.setProperty("value", 100) self.autoPercentSpin.setObjectName("autoPercentSpin") self.gridLayout.addWidget(self.autoPercentSpin, 2, 2, 1, 2) self.autoRadio = QtWidgets.QRadioButton(Form) self.autoRadio.setChecked(True) self.autoRadio.setObjectName("autoRadio") self.gridLayout.addWidget(self.autoRadio, 2, 0, 1, 2) self.manualRadio = QtWidgets.QRadioButton(Form) self.manualRadio.setObjectName("manualRadio") self.gridLayout.addWidget(self.manualRadio, 1, 0, 1, 2) self.minText = QtWidgets.QLineEdit(Form) self.minText.setObjectName("minText") self.gridLayout.addWidget(self.minText, 1, 2, 1, 1) self.maxText = QtWidgets.QLineEdit(Form) self.maxText.setObjectName("maxText") self.gridLayout.addWidget(self.maxText, 1, 3, 1, 1) self.invertCheck = QtWidgets.QCheckBox(Form) self.invertCheck.setObjectName("invertCheck") self.gridLayout.addWidget(self.invertCheck, 5, 0, 1, 4) self.mouseCheck = QtWidgets.QCheckBox(Form) self.mouseCheck.setChecked(True) self.mouseCheck.setObjectName("mouseCheck") self.gridLayout.addWidget(self.mouseCheck, 6, 0, 1, 4) self.visibleOnlyCheck = QtWidgets.QCheckBox(Form) self.visibleOnlyCheck.setObjectName("visibleOnlyCheck") self.gridLayout.addWidget(self.visibleOnlyCheck, 3, 2, 1, 2) self.autoPanCheck = QtWidgets.QCheckBox(Form) self.autoPanCheck.setObjectName("autoPanCheck") self.gridLayout.addWidget(self.autoPanCheck, 4, 2, 1, 2) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): _translate = QtCore.QCoreApplication.translate Form.setWindowTitle(_translate("Form", "Form")) self.label.setText(_translate("Form", "Link Axis:")) self.linkCombo.setToolTip(_translate("Form", "

Links this axis with another view. When linked, both views will display the same data range.

")) self.autoPercentSpin.setToolTip(_translate("Form", "

Percent of data to be visible when auto-scaling. It may be useful to decrease this value for data with spiky noise.

")) self.autoPercentSpin.setSuffix(_translate("Form", "%")) self.autoRadio.setToolTip(_translate("Form", "

Automatically resize this axis whenever the displayed data is changed.

")) self.autoRadio.setText(_translate("Form", "Auto")) self.manualRadio.setToolTip(_translate("Form", "

Set the range for this axis manually. This disables automatic scaling.

")) self.manualRadio.setText(_translate("Form", "Manual")) self.minText.setToolTip(_translate("Form", "

Minimum value to display for this axis.

")) self.minText.setText(_translate("Form", "0")) self.maxText.setToolTip(_translate("Form", "

Maximum value to display for this axis.

")) self.maxText.setText(_translate("Form", "0")) self.invertCheck.setToolTip(_translate("Form", "

Inverts the display of this axis. (+y points downward instead of upward)

")) self.invertCheck.setText(_translate("Form", "Invert Axis")) self.mouseCheck.setToolTip(_translate("Form", "

Enables mouse interaction (panning, scaling) for this axis.

")) self.mouseCheck.setText(_translate("Form", "Mouse Enabled")) self.visibleOnlyCheck.setToolTip(_translate("Form", "

When checked, the axis will only auto-scale to data that is visible along the orthogonal axis.

")) self.visibleOnlyCheck.setText(_translate("Form", "Visible Data Only")) self.autoPanCheck.setToolTip(_translate("Form", "

When checked, the axis will automatically pan to center on the current data, but the scale along this axis will not change.

")) self.autoPanCheck.setText(_translate("Form", "Auto Pan Only")) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/ViewBox/axisCtrlTemplate_pyside.py000066400000000000000000000147721300727121400312540ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './pyqtgraph/graphicsItems/ViewBox/axisCtrlTemplate.ui' # # Created: Mon Dec 23 10:10:51 2013 # by: pyside-uic 0.2.14 running on PySide 1.1.2 # # WARNING! All changes made in this file will be lost! from PySide import QtCore, QtGui class Ui_Form(object): def setupUi(self, Form): Form.setObjectName("Form") Form.resize(186, 154) Form.setMaximumSize(QtCore.QSize(200, 16777215)) self.gridLayout = QtGui.QGridLayout(Form) self.gridLayout.setContentsMargins(0, 0, 0, 0) self.gridLayout.setSpacing(0) self.gridLayout.setObjectName("gridLayout") self.label = QtGui.QLabel(Form) self.label.setObjectName("label") self.gridLayout.addWidget(self.label, 7, 0, 1, 2) self.linkCombo = QtGui.QComboBox(Form) self.linkCombo.setSizeAdjustPolicy(QtGui.QComboBox.AdjustToContents) self.linkCombo.setObjectName("linkCombo") self.gridLayout.addWidget(self.linkCombo, 7, 2, 1, 2) self.autoPercentSpin = QtGui.QSpinBox(Form) self.autoPercentSpin.setEnabled(True) self.autoPercentSpin.setMinimum(1) self.autoPercentSpin.setMaximum(100) self.autoPercentSpin.setSingleStep(1) self.autoPercentSpin.setProperty("value", 100) self.autoPercentSpin.setObjectName("autoPercentSpin") self.gridLayout.addWidget(self.autoPercentSpin, 2, 2, 1, 2) self.autoRadio = QtGui.QRadioButton(Form) self.autoRadio.setChecked(True) self.autoRadio.setObjectName("autoRadio") self.gridLayout.addWidget(self.autoRadio, 2, 0, 1, 2) self.manualRadio = QtGui.QRadioButton(Form) self.manualRadio.setObjectName("manualRadio") self.gridLayout.addWidget(self.manualRadio, 1, 0, 1, 2) self.minText = QtGui.QLineEdit(Form) self.minText.setObjectName("minText") self.gridLayout.addWidget(self.minText, 1, 2, 1, 1) self.maxText = QtGui.QLineEdit(Form) self.maxText.setObjectName("maxText") self.gridLayout.addWidget(self.maxText, 1, 3, 1, 1) self.invertCheck = QtGui.QCheckBox(Form) self.invertCheck.setObjectName("invertCheck") self.gridLayout.addWidget(self.invertCheck, 5, 0, 1, 4) self.mouseCheck = QtGui.QCheckBox(Form) self.mouseCheck.setChecked(True) self.mouseCheck.setObjectName("mouseCheck") self.gridLayout.addWidget(self.mouseCheck, 6, 0, 1, 4) self.visibleOnlyCheck = QtGui.QCheckBox(Form) self.visibleOnlyCheck.setObjectName("visibleOnlyCheck") self.gridLayout.addWidget(self.visibleOnlyCheck, 3, 2, 1, 2) self.autoPanCheck = QtGui.QCheckBox(Form) self.autoPanCheck.setObjectName("autoPanCheck") self.gridLayout.addWidget(self.autoPanCheck, 4, 2, 1, 2) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): Form.setWindowTitle(QtGui.QApplication.translate("Form", "Form", None, QtGui.QApplication.UnicodeUTF8)) self.label.setText(QtGui.QApplication.translate("Form", "Link Axis:", None, QtGui.QApplication.UnicodeUTF8)) self.linkCombo.setToolTip(QtGui.QApplication.translate("Form", "

Links this axis with another view. When linked, both views will display the same data range.

", None, QtGui.QApplication.UnicodeUTF8)) self.autoPercentSpin.setToolTip(QtGui.QApplication.translate("Form", "

Percent of data to be visible when auto-scaling. It may be useful to decrease this value for data with spiky noise.

", None, QtGui.QApplication.UnicodeUTF8)) self.autoPercentSpin.setSuffix(QtGui.QApplication.translate("Form", "%", None, QtGui.QApplication.UnicodeUTF8)) self.autoRadio.setToolTip(QtGui.QApplication.translate("Form", "

Automatically resize this axis whenever the displayed data is changed.

", None, QtGui.QApplication.UnicodeUTF8)) self.autoRadio.setText(QtGui.QApplication.translate("Form", "Auto", None, QtGui.QApplication.UnicodeUTF8)) self.manualRadio.setToolTip(QtGui.QApplication.translate("Form", "

Set the range for this axis manually. This disables automatic scaling.

", None, QtGui.QApplication.UnicodeUTF8)) self.manualRadio.setText(QtGui.QApplication.translate("Form", "Manual", None, QtGui.QApplication.UnicodeUTF8)) self.minText.setToolTip(QtGui.QApplication.translate("Form", "

Minimum value to display for this axis.

", None, QtGui.QApplication.UnicodeUTF8)) self.minText.setText(QtGui.QApplication.translate("Form", "0", None, QtGui.QApplication.UnicodeUTF8)) self.maxText.setToolTip(QtGui.QApplication.translate("Form", "

Maximum value to display for this axis.

", None, QtGui.QApplication.UnicodeUTF8)) self.maxText.setText(QtGui.QApplication.translate("Form", "0", None, QtGui.QApplication.UnicodeUTF8)) self.invertCheck.setToolTip(QtGui.QApplication.translate("Form", "

Inverts the display of this axis. (+y points downward instead of upward)

", None, QtGui.QApplication.UnicodeUTF8)) self.invertCheck.setText(QtGui.QApplication.translate("Form", "Invert Axis", None, QtGui.QApplication.UnicodeUTF8)) self.mouseCheck.setToolTip(QtGui.QApplication.translate("Form", "

Enables mouse interaction (panning, scaling) for this axis.

", None, QtGui.QApplication.UnicodeUTF8)) self.mouseCheck.setText(QtGui.QApplication.translate("Form", "Mouse Enabled", None, QtGui.QApplication.UnicodeUTF8)) self.visibleOnlyCheck.setToolTip(QtGui.QApplication.translate("Form", "

When checked, the axis will only auto-scale to data that is visible along the orthogonal axis.

", None, QtGui.QApplication.UnicodeUTF8)) self.visibleOnlyCheck.setText(QtGui.QApplication.translate("Form", "Visible Data Only", None, QtGui.QApplication.UnicodeUTF8)) self.autoPanCheck.setToolTip(QtGui.QApplication.translate("Form", "

When checked, the axis will automatically pan to center on the current data, but the scale along this axis will not change.

", None, QtGui.QApplication.UnicodeUTF8)) self.autoPanCheck.setText(QtGui.QApplication.translate("Form", "Auto Pan Only", None, QtGui.QApplication.UnicodeUTF8)) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/ViewBox/tests/000077500000000000000000000000001300727121400251675ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/ViewBox/tests/test_ViewBox.py000066400000000000000000000046201300727121400301650ustar00rootroot00000000000000#import PySide import pyqtgraph as pg import pytest app = pg.mkQApp() qtest = pg.Qt.QtTest.QTest QRectF = pg.QtCore.QRectF def assertMapping(vb, r1, r2): assert vb.mapFromView(r1.topLeft()) == r2.topLeft() assert vb.mapFromView(r1.bottomLeft()) == r2.bottomLeft() assert vb.mapFromView(r1.topRight()) == r2.topRight() assert vb.mapFromView(r1.bottomRight()) == r2.bottomRight() def init_viewbox(): """Helper function to init the ViewBox """ global win, vb win = pg.GraphicsWindow() win.ci.layout.setContentsMargins(0,0,0,0) win.resize(200, 200) win.show() vb = win.addViewBox() # set range before viewbox is shown vb.setRange(xRange=[0, 10], yRange=[0, 10], padding=0) # required to make mapFromView work properly. qtest.qWaitForWindowShown(win) g = pg.GridItem() vb.addItem(g) app.processEvents() def test_ViewBox(): init_viewbox() w = vb.geometry().width() h = vb.geometry().height() view1 = QRectF(0, 0, 10, 10) size1 = QRectF(0, h, w, -h) assertMapping(vb, view1, size1) # test resize win.resize(400, 400) app.processEvents() w = vb.geometry().width() h = vb.geometry().height() size1 = QRectF(0, h, w, -h) assertMapping(vb, view1, size1) # now lock aspect vb.setAspectLocked() # test wide resize win.resize(800, 400) app.processEvents() w = vb.geometry().width() h = vb.geometry().height() view1 = QRectF(-5, 0, 20, 10) size1 = QRectF(0, h, w, -h) assertMapping(vb, view1, size1) # test tall resize win.resize(400, 800) app.processEvents() w = vb.geometry().width() h = vb.geometry().height() view1 = QRectF(0, -5, 10, 20) size1 = QRectF(0, h, w, -h) assertMapping(vb, view1, size1) skipreason = "Skipping this test until someone has time to fix it." @pytest.mark.skipif(True, reason=skipreason) def test_limits_and_resize(): init_viewbox() # now lock aspect vb.setAspectLocked() # test limits + resize (aspect ratio constraint has priority over limits win.resize(400, 400) app.processEvents() vb.setLimits(xMin=0, xMax=10, yMin=0, yMax=10) win.resize(800, 400) app.processEvents() w = vb.geometry().width() h = vb.geometry().height() view1 = QRectF(-5, 0, 20, 10) size1 = QRectF(0, h, w, -h) assertMapping(vb, view1, size1) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/__init__.py000066400000000000000000000011111300727121400245450ustar00rootroot00000000000000### just import everything from sub-modules #import os #d = os.path.split(__file__)[0] #files = [] #for f in os.listdir(d): #if os.path.isdir(os.path.join(d, f)): #files.append(f) #elif f[-3:] == '.py' and f != '__init__.py': #files.append(f[:-3]) #for modName in files: #mod = __import__(modName, globals(), locals(), fromlist=['*']) #if hasattr(mod, '__all__'): #names = mod.__all__ #else: #names = [n for n in dir(mod) if n[0] != '_'] #for k in names: ##print modName, k #globals()[k] = getattr(mod, k) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/tests/000077500000000000000000000000001300727121400236045ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/tests/test_GraphicsItem.py000066400000000000000000000017271300727121400276030ustar00rootroot00000000000000import gc import weakref try: import faulthandler faulthandler.enable() except ImportError: pass import pyqtgraph as pg pg.mkQApp() def test_getViewWidget(): view = pg.PlotWidget() vref = weakref.ref(view) item = pg.InfiniteLine() view.addItem(item) assert item.getViewWidget() is view del view gc.collect() assert vref() is None assert item.getViewWidget() is None def test_getViewWidget_deleted(): view = pg.PlotWidget() item = pg.InfiniteLine() view.addItem(item) assert item.getViewWidget() is view # Arrange to have Qt automatically delete the view widget obj = pg.QtGui.QWidget() view.setParent(obj) del obj gc.collect() assert not pg.Qt.isQObjectAlive(view) assert item.getViewWidget() is None #if __name__ == '__main__': #view = pg.PlotItem() #vref = weakref.ref(view) #item = pg.InfiniteLine() #view.addItem(item) #del view #gc.collect() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/tests/test_ImageItem.py000066400000000000000000000126411300727121400270620ustar00rootroot00000000000000import time import pytest from pyqtgraph.Qt import QtCore, QtGui, QtTest import numpy as np import pyqtgraph as pg from pyqtgraph.tests import assertImageApproved, TransposedImageItem app = pg.mkQApp() def test_ImageItem(transpose=False): w = pg.GraphicsWindow() view = pg.ViewBox() w.setCentralWidget(view) w.resize(200, 200) w.show() img = TransposedImageItem(border=0.5, transpose=transpose) view.addItem(img) # test mono float np.random.seed(0) data = np.random.normal(size=(20, 20)) dmax = data.max() data[:10, 1] = dmax + 10 data[1, :10] = dmax + 12 data[3, :10] = dmax + 13 img.setImage(data) QtTest.QTest.qWaitForWindowShown(w) time.sleep(0.1) app.processEvents() assertImageApproved(w, 'imageitem/init', 'Init image item. View is auto-scaled, image axis 0 marked by 1 line, axis 1 is marked by 2 lines. Origin in bottom-left.') # ..with colormap cmap = pg.ColorMap([0, 0.25, 0.75, 1], [[0, 0, 0, 255], [255, 0, 0, 255], [255, 255, 0, 255], [255, 255, 255, 255]]) img.setLookupTable(cmap.getLookupTable()) assertImageApproved(w, 'imageitem/lut', 'Set image LUT.') # ..and different levels img.setLevels([dmax+9, dmax+13]) assertImageApproved(w, 'imageitem/levels1', 'Levels show only axis lines.') img.setLookupTable(None) # test mono int data = np.fromfunction(lambda x,y: x+y*10, (129, 128)).astype(np.int16) img.setImage(data) assertImageApproved(w, 'imageitem/gradient_mono_int', 'Mono int gradient.') img.setLevels([640, 641]) assertImageApproved(w, 'imageitem/gradient_mono_int_levels', 'Mono int gradient w/ levels to isolate diagonal.') # test mono byte data = np.fromfunction(lambda x,y: x+y, (129, 128)).astype(np.ubyte) img.setImage(data) assertImageApproved(w, 'imageitem/gradient_mono_byte', 'Mono byte gradient.') img.setLevels([127, 128]) assertImageApproved(w, 'imageitem/gradient_mono_byte_levels', 'Mono byte gradient w/ levels to isolate diagonal.') # test monochrome image data = np.zeros((10, 10), dtype='uint8') data[:5,:5] = 1 data[5:,5:] = 1 img.setImage(data) assertImageApproved(w, 'imageitem/monochrome', 'Ubyte image with only 0,1 values.') # test bool data = data.astype(bool) img.setImage(data) assertImageApproved(w, 'imageitem/bool', 'Boolean mask.') # test RGBA byte data = np.zeros((100, 100, 4), dtype='ubyte') data[..., 0] = np.linspace(0, 255, 100).reshape(100, 1) data[..., 1] = np.linspace(0, 255, 100).reshape(1, 100) data[..., 3] = 255 img.setImage(data) assertImageApproved(w, 'imageitem/gradient_rgba_byte', 'RGBA byte gradient.') img.setLevels([[128, 129], [128, 255], [0, 1], [0, 255]]) assertImageApproved(w, 'imageitem/gradient_rgba_byte_levels', 'RGBA byte gradient. Levels set to show x=128 and y>128.') # test RGBA float data = data.astype(float) img.setImage(data / 1e9) assertImageApproved(w, 'imageitem/gradient_rgba_float', 'RGBA float gradient.') # checkerboard to test alpha img2 = TransposedImageItem(transpose=transpose) img2.setImage(np.fromfunction(lambda x,y: (x+y)%2, (10, 10)), levels=[-1,2]) view.addItem(img2) img2.scale(10, 10) img2.setZValue(-10) data[..., 0] *= 1e-9 data[..., 1] *= 1e9 data[..., 3] = np.fromfunction(lambda x,y: np.sin(0.1 * (x+y)), (100, 100)) img.setImage(data, levels=[[0, 128e-9],[0, 128e9],[0, 1],[-1, 1]]) assertImageApproved(w, 'imageitem/gradient_rgba_float_alpha', 'RGBA float gradient with alpha.') # test composition mode img.setCompositionMode(QtGui.QPainter.CompositionMode_Plus) assertImageApproved(w, 'imageitem/gradient_rgba_float_additive', 'RGBA float gradient with alpha and additive composition mode.') img2.hide() img.setCompositionMode(QtGui.QPainter.CompositionMode_SourceOver) # test downsampling data = np.fromfunction(lambda x,y: np.cos(0.002 * x**2), (800, 100)) img.setImage(data, levels=[-1, 1]) assertImageApproved(w, 'imageitem/resolution_without_downsampling', 'Resolution test without downsampling.') img.setAutoDownsample(True) assertImageApproved(w, 'imageitem/resolution_with_downsampling_x', 'Resolution test with downsampling axross x axis.') assert img._lastDownsample == (4, 1) img.setImage(data.T, levels=[-1, 1]) assertImageApproved(w, 'imageitem/resolution_with_downsampling_y', 'Resolution test with downsampling across y axis.') assert img._lastDownsample == (1, 4) view.hide() def test_ImageItem_axisorder(): # All image tests pass again using the opposite axis order origMode = pg.getConfigOption('imageAxisOrder') altMode = 'row-major' if origMode == 'col-major' else 'col-major' pg.setConfigOptions(imageAxisOrder=altMode) try: test_ImageItem(transpose=True) finally: pg.setConfigOptions(imageAxisOrder=origMode) @pytest.mark.skipif(pg.Qt.USE_PYSIDE, reason="pyside does not have qWait") def test_dividebyzero(): import pyqtgraph as pg im = pg.image(pg.np.random.normal(size=(100,100))) im.imageItem.setAutoDownsample(True) im.view.setRange(xRange=[-5+25, 5e+25],yRange=[-5e+25, 5e+25]) app.processEvents() QtTest.QTest.qWait(1000) # must manually call im.imageItem.render here or the exception # will only exist on the Qt event loop im.imageItem.render() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/tests/test_InfiniteLine.py000066400000000000000000000065741300727121400276060ustar00rootroot00000000000000import pyqtgraph as pg from pyqtgraph.Qt import QtGui, QtCore, QtTest from pyqtgraph.tests import mouseDrag, mouseMove pg.mkQApp() def test_InfiniteLine(): # Test basic InfiniteLine API plt = pg.plot() plt.setXRange(-10, 10) plt.setYRange(-10, 10) plt.resize(600, 600) # seemingly arbitrary requirements; might need longer wait time for some platforms.. QtTest.QTest.qWaitForWindowShown(plt) QtTest.QTest.qWait(100) vline = plt.addLine(x=1) assert vline.angle == 90 br = vline.mapToView(QtGui.QPolygonF(vline.boundingRect())) assert br.containsPoint(pg.Point(1, 5), QtCore.Qt.OddEvenFill) assert not br.containsPoint(pg.Point(5, 0), QtCore.Qt.OddEvenFill) hline = plt.addLine(y=0) assert hline.angle == 0 assert hline.boundingRect().contains(pg.Point(5, 0)) assert not hline.boundingRect().contains(pg.Point(0, 5)) vline.setValue(2) assert vline.value() == 2 vline.setPos(pg.Point(4, -5)) assert vline.value() == 4 oline = pg.InfiniteLine(angle=30) plt.addItem(oline) oline.setPos(pg.Point(1, -1)) assert oline.angle == 30 assert oline.pos() == pg.Point(1, -1) assert oline.value() == [1, -1] # test bounding rect for oblique line br = oline.mapToScene(oline.boundingRect()) pos = oline.mapToScene(pg.Point(2, 0)) assert br.containsPoint(pos, QtCore.Qt.OddEvenFill) px = pg.Point(-0.5, -1.0 / 3**0.5) assert br.containsPoint(pos + 5 * px, QtCore.Qt.OddEvenFill) assert not br.containsPoint(pos + 7 * px, QtCore.Qt.OddEvenFill) def test_mouseInteraction(): plt = pg.plot() plt.scene().minDragTime = 0 # let us simulate mouse drags very quickly. vline = plt.addLine(x=0, movable=True) plt.addItem(vline) hline = plt.addLine(y=0, movable=True) hline2 = plt.addLine(y=-1, movable=False) plt.setXRange(-10, 10) plt.setYRange(-10, 10) # test horizontal drag pos = plt.plotItem.vb.mapViewToScene(pg.Point(0,5)).toPoint() pos2 = pos - QtCore.QPoint(200, 200) mouseMove(plt, pos) assert vline.mouseHovering is True and hline.mouseHovering is False mouseDrag(plt, pos, pos2, QtCore.Qt.LeftButton) px = vline.pixelLength(pg.Point(1, 0), ortho=True) assert abs(vline.value() - plt.plotItem.vb.mapSceneToView(pos2).x()) <= px # test missed drag pos = plt.plotItem.vb.mapViewToScene(pg.Point(5,0)).toPoint() pos = pos + QtCore.QPoint(0, 6) pos2 = pos + QtCore.QPoint(-20, -20) mouseMove(plt, pos) assert vline.mouseHovering is False and hline.mouseHovering is False mouseDrag(plt, pos, pos2, QtCore.Qt.LeftButton) assert hline.value() == 0 # test vertical drag pos = plt.plotItem.vb.mapViewToScene(pg.Point(5,0)).toPoint() pos2 = pos - QtCore.QPoint(50, 50) mouseMove(plt, pos) assert vline.mouseHovering is False and hline.mouseHovering is True mouseDrag(plt, pos, pos2, QtCore.Qt.LeftButton) px = hline.pixelLength(pg.Point(1, 0), ortho=True) assert abs(hline.value() - plt.plotItem.vb.mapSceneToView(pos2).y()) <= px # test non-interactive line pos = plt.plotItem.vb.mapViewToScene(pg.Point(5,-1)).toPoint() pos2 = pos - QtCore.QPoint(50, 50) mouseMove(plt, pos) assert hline2.mouseHovering == False mouseDrag(plt, pos, pos2, QtCore.Qt.LeftButton) assert hline2.value() == -1 if __name__ == '__main__': test_mouseInteraction() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/tests/test_PlotCurveItem.py000066400000000000000000000023651300727121400277650ustar00rootroot00000000000000import numpy as np import pyqtgraph as pg from pyqtgraph.tests import assertImageApproved def test_PlotCurveItem(): p = pg.GraphicsWindow() p.ci.layout.setContentsMargins(4, 4, 4, 4) # default margins vary by platform v = p.addViewBox() p.resize(200, 150) data = np.array([1,4,2,3,np.inf,5,7,6,-np.inf,8,10,9,np.nan,-1,-2,0]) c = pg.PlotCurveItem(data) v.addItem(c) v.autoRange() # Check auto-range works. Some platform differences may be expected.. checkRange = np.array([[-1.1457564053237301, 16.145756405323731], [-3.076811473165955, 11.076811473165955]]) assert np.allclose(v.viewRange(), checkRange) assertImageApproved(p, 'plotcurveitem/connectall', "Plot curve with all points connected.") c.setData(data, connect='pairs') assertImageApproved(p, 'plotcurveitem/connectpairs', "Plot curve with pairs connected.") c.setData(data, connect='finite') assertImageApproved(p, 'plotcurveitem/connectfinite', "Plot curve with finite points connected.") c.setData(data, connect=np.array([1,1,1,0,1,1,0,0,1,0,0,0,1,1,0,0])) assertImageApproved(p, 'plotcurveitem/connectarray', "Plot curve with connection array.") if __name__ == '__main__': test_PlotCurveItem() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/tests/test_ROI.py000066400000000000000000000173061300727121400256550ustar00rootroot00000000000000import numpy as np import pytest import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtTest from pyqtgraph.tests import assertImageApproved, mouseMove, mouseDrag, mouseClick, TransposedImageItem app = pg.mkQApp() def test_getArrayRegion(transpose=False): pr = pg.PolyLineROI([[0, 0], [27, 0], [0, 28]], closed=True) pr.setPos(1, 1) rois = [ (pg.ROI([1, 1], [27, 28], pen='y'), 'baseroi'), (pg.RectROI([1, 1], [27, 28], pen='y'), 'rectroi'), (pg.EllipseROI([1, 1], [27, 28], pen='y'), 'ellipseroi'), (pr, 'polylineroi'), ] for roi, name in rois: # For some ROIs, resize should not be used. testResize = not isinstance(roi, pg.PolyLineROI) origMode = pg.getConfigOption('imageAxisOrder') try: if transpose: pg.setConfigOptions(imageAxisOrder='row-major') check_getArrayRegion(roi, 'roi/'+name, testResize, transpose=True) else: pg.setConfigOptions(imageAxisOrder='col-major') check_getArrayRegion(roi, 'roi/'+name, testResize) finally: pg.setConfigOptions(imageAxisOrder=origMode) def test_getArrayRegion_axisorder(): test_getArrayRegion(transpose=True) def check_getArrayRegion(roi, name, testResize=True, transpose=False): initState = roi.getState() #win = pg.GraphicsLayoutWidget() win = pg.GraphicsView() win.show() win.resize(200, 400) # Don't use Qt's layouts for testing--these generate unpredictable results. #vb1 = win.addViewBox() #win.nextRow() #vb2 = win.addViewBox() # Instead, place the viewboxes manually vb1 = pg.ViewBox() win.scene().addItem(vb1) vb1.setPos(6, 6) vb1.resize(188, 191) vb2 = pg.ViewBox() win.scene().addItem(vb2) vb2.setPos(6, 203) vb2.resize(188, 191) img1 = pg.ImageItem(border='w') img2 = pg.ImageItem(border='w') vb1.addItem(img1) vb2.addItem(img2) np.random.seed(0) data = np.random.normal(size=(7, 30, 31, 5)) data[0, :, :, :] += 10 data[:, 1, :, :] += 10 data[:, :, 2, :] += 10 data[:, :, :, 3] += 10 if transpose: data = data.transpose(0, 2, 1, 3) img1.setImage(data[0, ..., 0]) vb1.setAspectLocked() vb1.enableAutoRange(True, True) roi.setZValue(10) vb1.addItem(roi) if isinstance(roi, pg.RectROI): if transpose: assert roi.getAffineSliceParams(data, img1, axes=(1, 2)) == ([28.0, 27.0], ((1.0, 0.0), (0.0, 1.0)), (1.0, 1.0)) else: assert roi.getAffineSliceParams(data, img1, axes=(1, 2)) == ([27.0, 28.0], ((1.0, 0.0), (0.0, 1.0)), (1.0, 1.0)) rgn = roi.getArrayRegion(data, img1, axes=(1, 2)) #assert np.all((rgn == data[:, 1:-2, 1:-2, :]) | (rgn == 0)) img2.setImage(rgn[0, ..., 0]) vb2.setAspectLocked() vb2.enableAutoRange(True, True) app.processEvents() assertImageApproved(win, name+'/roi_getarrayregion', 'Simple ROI region selection.') with pytest.raises(TypeError): roi.setPos(0, False) roi.setPos([0.5, 1.5]) rgn = roi.getArrayRegion(data, img1, axes=(1, 2)) img2.setImage(rgn[0, ..., 0]) app.processEvents() assertImageApproved(win, name+'/roi_getarrayregion_halfpx', 'Simple ROI region selection, 0.5 pixel shift.') roi.setAngle(45) roi.setPos([3, 0]) rgn = roi.getArrayRegion(data, img1, axes=(1, 2)) img2.setImage(rgn[0, ..., 0]) app.processEvents() assertImageApproved(win, name+'/roi_getarrayregion_rotate', 'Simple ROI region selection, rotation.') if testResize: roi.setSize([60, 60]) rgn = roi.getArrayRegion(data, img1, axes=(1, 2)) img2.setImage(rgn[0, ..., 0]) app.processEvents() assertImageApproved(win, name+'/roi_getarrayregion_resize', 'Simple ROI region selection, resized.') img1.scale(1, -1) img1.setPos(0, img1.height()) img1.rotate(20) rgn = roi.getArrayRegion(data, img1, axes=(1, 2)) img2.setImage(rgn[0, ..., 0]) app.processEvents() assertImageApproved(win, name+'/roi_getarrayregion_img_trans', 'Simple ROI region selection, image transformed.') vb1.invertY() rgn = roi.getArrayRegion(data, img1, axes=(1, 2)) img2.setImage(rgn[0, ..., 0]) app.processEvents() assertImageApproved(win, name+'/roi_getarrayregion_inverty', 'Simple ROI region selection, view inverted.') roi.setState(initState) img1.resetTransform() img1.setPos(0, 0) img1.scale(1, 0.5) rgn = roi.getArrayRegion(data, img1, axes=(1, 2)) img2.setImage(rgn[0, ..., 0]) app.processEvents() assertImageApproved(win, name+'/roi_getarrayregion_anisotropic', 'Simple ROI region selection, image scaled anisotropically.') # allow the roi to be re-used roi.scene().removeItem(roi) def test_PolyLineROI(): rois = [ (pg.PolyLineROI([[0, 0], [10, 0], [0, 15]], closed=True, pen=0.3), 'closed'), (pg.PolyLineROI([[0, 0], [10, 0], [0, 15]], closed=False, pen=0.3), 'open') ] #plt = pg.plot() plt = pg.GraphicsView() plt.show() plt.resize(200, 200) vb = pg.ViewBox() plt.scene().addItem(vb) vb.resize(200, 200) #plt.plotItem = pg.PlotItem() #plt.scene().addItem(plt.plotItem) #plt.plotItem.resize(200, 200) plt.scene().minDragTime = 0 # let us simulate mouse drags very quickly. # seemingly arbitrary requirements; might need longer wait time for some platforms.. QtTest.QTest.qWaitForWindowShown(plt) QtTest.QTest.qWait(100) for r, name in rois: vb.clear() vb.addItem(r) vb.autoRange() app.processEvents() assertImageApproved(plt, 'roi/polylineroi/'+name+'_init', 'Init %s polyline.' % name) initState = r.getState() assert len(r.getState()['points']) == 3 # hover over center center = r.mapToScene(pg.Point(3, 3)) mouseMove(plt, center) assertImageApproved(plt, 'roi/polylineroi/'+name+'_hover_roi', 'Hover mouse over center of ROI.') # drag ROI mouseDrag(plt, center, center + pg.Point(10, -10), QtCore.Qt.LeftButton) assertImageApproved(plt, 'roi/polylineroi/'+name+'_drag_roi', 'Drag mouse over center of ROI.') # hover over handle pt = r.mapToScene(pg.Point(r.getState()['points'][2])) mouseMove(plt, pt) assertImageApproved(plt, 'roi/polylineroi/'+name+'_hover_handle', 'Hover mouse over handle.') # drag handle mouseDrag(plt, pt, pt + pg.Point(5, 20), QtCore.Qt.LeftButton) assertImageApproved(plt, 'roi/polylineroi/'+name+'_drag_handle', 'Drag mouse over handle.') # hover over segment pt = r.mapToScene((pg.Point(r.getState()['points'][2]) + pg.Point(r.getState()['points'][1])) * 0.5) mouseMove(plt, pt+pg.Point(0, 2)) assertImageApproved(plt, 'roi/polylineroi/'+name+'_hover_segment', 'Hover mouse over diagonal segment.') # click segment mouseClick(plt, pt, QtCore.Qt.LeftButton) assertImageApproved(plt, 'roi/polylineroi/'+name+'_click_segment', 'Click mouse over segment.') r.clearPoints() assertImageApproved(plt, 'roi/polylineroi/'+name+'_clear', 'All points cleared.') assert len(r.getState()['points']) == 0 r.setPoints(initState['points']) assertImageApproved(plt, 'roi/polylineroi/'+name+'_setpoints', 'Reset points to initial state.') assert len(r.getState()['points']) == 3 r.setState(initState) assertImageApproved(plt, 'roi/polylineroi/'+name+'_setstate', 'Reset ROI to initial state.') assert len(r.getState()['points']) == 3 pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsItems/tests/test_ScatterPlotItem.py000066400000000000000000000052701300727121400303040ustar00rootroot00000000000000import pyqtgraph as pg import numpy as np app = pg.mkQApp() app.processEvents() def test_scatterplotitem(): plot = pg.PlotWidget() # set view range equal to its bounding rect. # This causes plots to look the same regardless of pxMode. plot.setRange(rect=plot.boundingRect()) for i, pxMode in enumerate([True, False]): for j, useCache in enumerate([True, False]): s = pg.ScatterPlotItem() s.opts['useCache'] = useCache plot.addItem(s) s.setData(x=np.array([10,40,20,30])+i*100, y=np.array([40,60,10,30])+j*100, pxMode=pxMode) s.addPoints(x=np.array([60, 70])+i*100, y=np.array([60, 70])+j*100, size=[20, 30]) # Test uniform spot updates s.setSize(10) s.setBrush('r') s.setPen('g') s.setSymbol('+') app.processEvents() # Test list spot updates s.setSize([10] * 6) s.setBrush([pg.mkBrush('r')] * 6) s.setPen([pg.mkPen('g')] * 6) s.setSymbol(['+'] * 6) s.setPointData([s] * 6) app.processEvents() # Test array spot updates s.setSize(np.array([10] * 6)) s.setBrush(np.array([pg.mkBrush('r')] * 6)) s.setPen(np.array([pg.mkPen('g')] * 6)) s.setSymbol(np.array(['+'] * 6)) s.setPointData(np.array([s] * 6)) app.processEvents() # Test per-spot updates spot = s.points()[0] spot.setSize(20) spot.setBrush('b') spot.setPen('g') spot.setSymbol('o') spot.setData(None) app.processEvents() plot.clear() def test_init_spots(): plot = pg.PlotWidget() # set view range equal to its bounding rect. # This causes plots to look the same regardless of pxMode. plot.setRange(rect=plot.boundingRect()) spots = [ {'x': 0, 'y': 1}, {'pos': (1, 2), 'pen': None, 'brush': None, 'data': 'zzz'}, ] s = pg.ScatterPlotItem(spots=spots) # Check we can display without errors plot.addItem(s) app.processEvents() plot.clear() # check data is correct spots = s.points() defPen = pg.mkPen(pg.getConfigOption('foreground')) assert spots[0].pos().x() == 0 assert spots[0].pos().y() == 1 assert spots[0].pen() == defPen assert spots[0].data() is None assert spots[1].pos().x() == 1 assert spots[1].pos().y() == 2 assert spots[1].pen() == pg.mkPen(None) assert spots[1].brush() == pg.mkBrush(None) assert spots[1].data() == 'zzz' if __name__ == '__main__': test_scatterplotitem() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/graphicsWindows.py000066400000000000000000000051471300727121400233740ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ graphicsWindows.py - Convenience classes which create a new window with PlotWidget or ImageView. Copyright 2010 Luke Campagnola Distributed under MIT/X11 license. See license.txt for more infomation. """ from .Qt import QtCore, QtGui from .widgets.PlotWidget import * from .imageview import * from .widgets.GraphicsLayoutWidget import GraphicsLayoutWidget from .widgets.GraphicsView import GraphicsView QAPP = None def mkQApp(): if QtGui.QApplication.instance() is None: global QAPP QAPP = QtGui.QApplication([]) class GraphicsWindow(GraphicsLayoutWidget): """ Convenience subclass of :class:`GraphicsLayoutWidget `. This class is intended for use from the interactive python prompt. """ def __init__(self, title=None, size=(800,600), **kargs): mkQApp() GraphicsLayoutWidget.__init__(self, **kargs) self.resize(*size) if title is not None: self.setWindowTitle(title) self.show() class TabWindow(QtGui.QMainWindow): def __init__(self, title=None, size=(800,600)): mkQApp() QtGui.QMainWindow.__init__(self) self.resize(*size) self.cw = QtGui.QTabWidget() self.setCentralWidget(self.cw) if title is not None: self.setWindowTitle(title) self.show() def __getattr__(self, attr): if hasattr(self.cw, attr): return getattr(self.cw, attr) else: raise NameError(attr) class PlotWindow(PlotWidget): def __init__(self, title=None, **kargs): mkQApp() self.win = QtGui.QMainWindow() PlotWidget.__init__(self, **kargs) self.win.setCentralWidget(self) for m in ['resize']: setattr(self, m, getattr(self.win, m)) if title is not None: self.win.setWindowTitle(title) self.win.show() class ImageWindow(ImageView): def __init__(self, *args, **kargs): mkQApp() self.win = QtGui.QMainWindow() self.win.resize(800,600) if 'title' in kargs: self.win.setWindowTitle(kargs['title']) del kargs['title'] ImageView.__init__(self, self.win) if len(args) > 0 or len(kargs) > 0: self.setImage(*args, **kargs) self.win.setCentralWidget(self) for m in ['resize']: setattr(self, m, getattr(self.win, m)) #for m in ['setImage', 'autoRange', 'addItem', 'removeItem', 'blackLevel', 'whiteLevel', 'imageItem']: #setattr(self, m, getattr(self.cw, m)) self.win.show() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/imageview/000077500000000000000000000000001300727121400216155ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/imageview/ImageView.py000066400000000000000000000705451300727121400240570ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ ImageView.py - Widget for basic image dispay and analysis Copyright 2010 Luke Campagnola Distributed under MIT/X11 license. See license.txt for more infomation. Widget used for displaying 2D or 3D data. Features: - float or int (including 16-bit int) image display via ImageItem - zoom/pan via GraphicsView - black/white level controls - time slider for 3D data sets - ROI plotting - Image normalization through a variety of methods """ import os import numpy as np from ..Qt import QtCore, QtGui, USE_PYSIDE if USE_PYSIDE: from .ImageViewTemplate_pyside import * else: from .ImageViewTemplate_pyqt import * from ..graphicsItems.ImageItem import * from ..graphicsItems.ROI import * from ..graphicsItems.LinearRegionItem import * from ..graphicsItems.InfiniteLine import * from ..graphicsItems.ViewBox import * from ..graphicsItems.GradientEditorItem import addGradientListToDocstring from .. import ptime as ptime from .. import debug as debug from ..SignalProxy import SignalProxy from .. import getConfigOption try: from bottleneck import nanmin, nanmax except ImportError: from numpy import nanmin, nanmax class PlotROI(ROI): def __init__(self, size): ROI.__init__(self, pos=[0,0], size=size) #, scaleSnap=True, translateSnap=True) self.addScaleHandle([1, 1], [0, 0]) self.addRotateHandle([0, 0], [0.5, 0.5]) class ImageView(QtGui.QWidget): """ Widget used for display and analysis of image data. Implements many features: * Displays 2D and 3D image data. For 3D data, a z-axis slider is displayed allowing the user to select which frame is displayed. * Displays histogram of image data with movable region defining the dark/light levels * Editable gradient provides a color lookup table * Frame slider may also be moved using left/right arrow keys as well as pgup, pgdn, home, and end. * Basic analysis features including: * ROI and embedded plot for measuring image values across frames * Image normalization / background subtraction Basic Usage:: imv = pg.ImageView() imv.show() imv.setImage(data) **Keyboard interaction** * left/right arrows step forward/backward 1 frame when pressed, seek at 20fps when held. * up/down arrows seek at 100fps * pgup/pgdn seek at 1000fps * home/end seek immediately to the first/last frame * space begins playing frames. If time values (in seconds) are given for each frame, then playback is in realtime. """ sigTimeChanged = QtCore.Signal(object, object) sigProcessingChanged = QtCore.Signal(object) def __init__(self, parent=None, name="ImageView", view=None, imageItem=None, *args): """ By default, this class creates an :class:`ImageItem ` to display image data and a :class:`ViewBox ` to contain the ImageItem. ============= ========================================================= **Arguments** parent (QWidget) Specifies the parent widget to which this ImageView will belong. If None, then the ImageView is created with no parent. name (str) The name used to register both the internal ViewBox and the PlotItem used to display ROI data. See the *name* argument to :func:`ViewBox.__init__() `. view (ViewBox or PlotItem) If specified, this will be used as the display area that contains the displayed image. Any :class:`ViewBox `, :class:`PlotItem `, or other compatible object is acceptable. imageItem (ImageItem) If specified, this object will be used to display the image. Must be an instance of ImageItem or other compatible object. ============= ========================================================= Note: to display axis ticks inside the ImageView, instantiate it with a PlotItem instance as its view:: pg.ImageView(view=pg.PlotItem()) """ QtGui.QWidget.__init__(self, parent, *args) self.levelMax = 4096 self.levelMin = 0 self.name = name self.image = None self.axes = {} self.imageDisp = None self.ui = Ui_Form() self.ui.setupUi(self) self.scene = self.ui.graphicsView.scene() self.ignoreTimeLine = False if view is None: self.view = ViewBox() else: self.view = view self.ui.graphicsView.setCentralItem(self.view) self.view.setAspectLocked(True) self.view.invertY() if imageItem is None: self.imageItem = ImageItem() else: self.imageItem = imageItem self.view.addItem(self.imageItem) self.currentIndex = 0 self.ui.histogram.setImageItem(self.imageItem) self.menu = None self.ui.normGroup.hide() self.roi = PlotROI(10) self.roi.setZValue(20) self.view.addItem(self.roi) self.roi.hide() self.normRoi = PlotROI(10) self.normRoi.setPen('y') self.normRoi.setZValue(20) self.view.addItem(self.normRoi) self.normRoi.hide() self.roiCurve = self.ui.roiPlot.plot() self.timeLine = InfiniteLine(0, movable=True) self.timeLine.setPen((255, 255, 0, 200)) self.timeLine.setZValue(1) self.ui.roiPlot.addItem(self.timeLine) self.ui.splitter.setSizes([self.height()-35, 35]) self.ui.roiPlot.hideAxis('left') self.keysPressed = {} self.playTimer = QtCore.QTimer() self.playRate = 0 self.lastPlayTime = 0 self.normRgn = LinearRegionItem() self.normRgn.setZValue(0) self.ui.roiPlot.addItem(self.normRgn) self.normRgn.hide() ## wrap functions from view box for fn in ['addItem', 'removeItem']: setattr(self, fn, getattr(self.view, fn)) ## wrap functions from histogram for fn in ['setHistogramRange', 'autoHistogramRange', 'getLookupTable', 'getLevels']: setattr(self, fn, getattr(self.ui.histogram, fn)) self.timeLine.sigPositionChanged.connect(self.timeLineChanged) self.ui.roiBtn.clicked.connect(self.roiClicked) self.roi.sigRegionChanged.connect(self.roiChanged) #self.ui.normBtn.toggled.connect(self.normToggled) self.ui.menuBtn.clicked.connect(self.menuClicked) self.ui.normDivideRadio.clicked.connect(self.normRadioChanged) self.ui.normSubtractRadio.clicked.connect(self.normRadioChanged) self.ui.normOffRadio.clicked.connect(self.normRadioChanged) self.ui.normROICheck.clicked.connect(self.updateNorm) self.ui.normFrameCheck.clicked.connect(self.updateNorm) self.ui.normTimeRangeCheck.clicked.connect(self.updateNorm) self.playTimer.timeout.connect(self.timeout) self.normProxy = SignalProxy(self.normRgn.sigRegionChanged, slot=self.updateNorm) self.normRoi.sigRegionChangeFinished.connect(self.updateNorm) self.ui.roiPlot.registerPlot(self.name + '_ROI') self.view.register(self.name) self.noRepeatKeys = [QtCore.Qt.Key_Right, QtCore.Qt.Key_Left, QtCore.Qt.Key_Up, QtCore.Qt.Key_Down, QtCore.Qt.Key_PageUp, QtCore.Qt.Key_PageDown] self.roiClicked() ## initialize roi plot to correct shape / visibility def setImage(self, img, autoRange=True, autoLevels=True, levels=None, axes=None, xvals=None, pos=None, scale=None, transform=None, autoHistogramRange=True): """ Set the image to be displayed in the widget. ================== =========================================================================== **Arguments:** img (numpy array) the image to be displayed. See :func:`ImageItem.setImage` and *notes* below. xvals (numpy array) 1D array of z-axis values corresponding to the third axis in a 3D image. For video, this array should contain the time of each frame. autoRange (bool) whether to scale/pan the view to fit the image. autoLevels (bool) whether to update the white/black levels to fit the image. levels (min, max); the white and black level values to use. axes Dictionary indicating the interpretation for each axis. This is only needed to override the default guess. Format is:: {'t':0, 'x':1, 'y':2, 'c':3}; pos Change the position of the displayed image scale Change the scale of the displayed image transform Set the transform of the displayed image. This option overrides *pos* and *scale*. autoHistogramRange If True, the histogram y-range is automatically scaled to fit the image data. ================== =========================================================================== **Notes:** For backward compatibility, image data is assumed to be in column-major order (column, row). However, most image data is stored in row-major order (row, column) and will need to be transposed before calling setImage():: imageview.setImage(imagedata.T) This requirement can be changed by the ``imageAxisOrder`` :ref:`global configuration option `. """ profiler = debug.Profiler() if hasattr(img, 'implements') and img.implements('MetaArray'): img = img.asarray() if not isinstance(img, np.ndarray): required = ['dtype', 'max', 'min', 'ndim', 'shape', 'size'] if not all([hasattr(img, attr) for attr in required]): raise TypeError("Image must be NumPy array or any object " "that provides compatible attributes/methods:\n" " %s" % str(required)) self.image = img self.imageDisp = None profiler() if axes is None: x,y = (0, 1) if self.imageItem.axisOrder == 'col-major' else (1, 0) if img.ndim == 2: self.axes = {'t': None, 'x': x, 'y': y, 'c': None} elif img.ndim == 3: # Ambiguous case; make a guess if img.shape[2] <= 4: self.axes = {'t': None, 'x': x, 'y': y, 'c': 2} else: self.axes = {'t': 0, 'x': x+1, 'y': y+1, 'c': None} elif img.ndim == 4: # Even more ambiguous; just assume the default self.axes = {'t': 0, 'x': x+1, 'y': y+1, 'c': 3} else: raise Exception("Can not interpret image with dimensions %s" % (str(img.shape))) elif isinstance(axes, dict): self.axes = axes.copy() elif isinstance(axes, list) or isinstance(axes, tuple): self.axes = {} for i in range(len(axes)): self.axes[axes[i]] = i else: raise Exception("Can not interpret axis specification %s. Must be like {'t': 2, 'x': 0, 'y': 1} or ('t', 'x', 'y', 'c')" % (str(axes))) for x in ['t', 'x', 'y', 'c']: self.axes[x] = self.axes.get(x, None) axes = self.axes if xvals is not None: self.tVals = xvals elif axes['t'] is not None: if hasattr(img, 'xvals'): try: self.tVals = img.xvals(axes['t']) except: self.tVals = np.arange(img.shape[axes['t']]) else: self.tVals = np.arange(img.shape[axes['t']]) profiler() self.currentIndex = 0 self.updateImage(autoHistogramRange=autoHistogramRange) if levels is None and autoLevels: self.autoLevels() if levels is not None: ## this does nothing since getProcessedImage sets these values again. self.setLevels(*levels) if self.ui.roiBtn.isChecked(): self.roiChanged() profiler() if self.axes['t'] is not None: #self.ui.roiPlot.show() self.ui.roiPlot.setXRange(self.tVals.min(), self.tVals.max()) self.timeLine.setValue(0) #self.ui.roiPlot.setMouseEnabled(False, False) if len(self.tVals) > 1: start = self.tVals.min() stop = self.tVals.max() + abs(self.tVals[-1] - self.tVals[0]) * 0.02 elif len(self.tVals) == 1: start = self.tVals[0] - 0.5 stop = self.tVals[0] + 0.5 else: start = 0 stop = 1 for s in [self.timeLine, self.normRgn]: s.setBounds([start, stop]) #else: #self.ui.roiPlot.hide() profiler() self.imageItem.resetTransform() if scale is not None: self.imageItem.scale(*scale) if pos is not None: self.imageItem.setPos(*pos) if transform is not None: self.imageItem.setTransform(transform) profiler() if autoRange: self.autoRange() self.roiClicked() profiler() def clear(self): self.image = None self.imageItem.clear() def play(self, rate): """Begin automatically stepping frames forward at the given rate (in fps). This can also be accessed by pressing the spacebar.""" #print "play:", rate self.playRate = rate if rate == 0: self.playTimer.stop() return self.lastPlayTime = ptime.time() if not self.playTimer.isActive(): self.playTimer.start(16) def autoLevels(self): """Set the min/max intensity levels automatically to match the image data.""" self.setLevels(self.levelMin, self.levelMax) def setLevels(self, min, max): """Set the min/max (bright and dark) levels.""" self.ui.histogram.setLevels(min, max) def autoRange(self): """Auto scale and pan the view around the image such that the image fills the view.""" image = self.getProcessedImage() self.view.autoRange() def getProcessedImage(self): """Returns the image data after it has been processed by any normalization options in use. This method also sets the attributes self.levelMin and self.levelMax to indicate the range of data in the image.""" if self.imageDisp is None: image = self.normalize(self.image) self.imageDisp = image self.levelMin, self.levelMax = list(map(float, self.quickMinMax(self.imageDisp))) return self.imageDisp def close(self): """Closes the widget nicely, making sure to clear the graphics scene and release memory.""" self.ui.roiPlot.close() self.ui.graphicsView.close() self.scene.clear() del self.image del self.imageDisp super(ImageView, self).close() self.setParent(None) def keyPressEvent(self, ev): #print ev.key() if ev.key() == QtCore.Qt.Key_Space: if self.playRate == 0: fps = (self.getProcessedImage().shape[0]-1) / (self.tVals[-1] - self.tVals[0]) self.play(fps) #print fps else: self.play(0) ev.accept() elif ev.key() == QtCore.Qt.Key_Home: self.setCurrentIndex(0) self.play(0) ev.accept() elif ev.key() == QtCore.Qt.Key_End: self.setCurrentIndex(self.getProcessedImage().shape[0]-1) self.play(0) ev.accept() elif ev.key() in self.noRepeatKeys: ev.accept() if ev.isAutoRepeat(): return self.keysPressed[ev.key()] = 1 self.evalKeyState() else: QtGui.QWidget.keyPressEvent(self, ev) def keyReleaseEvent(self, ev): if ev.key() in [QtCore.Qt.Key_Space, QtCore.Qt.Key_Home, QtCore.Qt.Key_End]: ev.accept() elif ev.key() in self.noRepeatKeys: ev.accept() if ev.isAutoRepeat(): return try: del self.keysPressed[ev.key()] except: self.keysPressed = {} self.evalKeyState() else: QtGui.QWidget.keyReleaseEvent(self, ev) def evalKeyState(self): if len(self.keysPressed) == 1: key = list(self.keysPressed.keys())[0] if key == QtCore.Qt.Key_Right: self.play(20) self.jumpFrames(1) self.lastPlayTime = ptime.time() + 0.2 ## 2ms wait before start ## This happens *after* jumpFrames, since it might take longer than 2ms elif key == QtCore.Qt.Key_Left: self.play(-20) self.jumpFrames(-1) self.lastPlayTime = ptime.time() + 0.2 elif key == QtCore.Qt.Key_Up: self.play(-100) elif key == QtCore.Qt.Key_Down: self.play(100) elif key == QtCore.Qt.Key_PageUp: self.play(-1000) elif key == QtCore.Qt.Key_PageDown: self.play(1000) else: self.play(0) def timeout(self): now = ptime.time() dt = now - self.lastPlayTime if dt < 0: return n = int(self.playRate * dt) if n != 0: self.lastPlayTime += (float(n)/self.playRate) if self.currentIndex+n > self.image.shape[0]: self.play(0) self.jumpFrames(n) def setCurrentIndex(self, ind): """Set the currently displayed frame index.""" self.currentIndex = np.clip(ind, 0, self.getProcessedImage().shape[self.axes['t']]-1) self.updateImage() self.ignoreTimeLine = True self.timeLine.setValue(self.tVals[self.currentIndex]) self.ignoreTimeLine = False def jumpFrames(self, n): """Move video frame ahead n frames (may be negative)""" if self.axes['t'] is not None: self.setCurrentIndex(self.currentIndex + n) def normRadioChanged(self): self.imageDisp = None self.updateImage() self.autoLevels() self.roiChanged() self.sigProcessingChanged.emit(self) def updateNorm(self): if self.ui.normTimeRangeCheck.isChecked(): self.normRgn.show() else: self.normRgn.hide() if self.ui.normROICheck.isChecked(): self.normRoi.show() else: self.normRoi.hide() if not self.ui.normOffRadio.isChecked(): self.imageDisp = None self.updateImage() self.autoLevels() self.roiChanged() self.sigProcessingChanged.emit(self) def normToggled(self, b): self.ui.normGroup.setVisible(b) self.normRoi.setVisible(b and self.ui.normROICheck.isChecked()) self.normRgn.setVisible(b and self.ui.normTimeRangeCheck.isChecked()) def hasTimeAxis(self): return 't' in self.axes and self.axes['t'] is not None def roiClicked(self): showRoiPlot = False if self.ui.roiBtn.isChecked(): showRoiPlot = True self.roi.show() #self.ui.roiPlot.show() self.ui.roiPlot.setMouseEnabled(True, True) self.ui.splitter.setSizes([self.height()*0.6, self.height()*0.4]) self.roiCurve.show() self.roiChanged() self.ui.roiPlot.showAxis('left') else: self.roi.hide() self.ui.roiPlot.setMouseEnabled(False, False) self.roiCurve.hide() self.ui.roiPlot.hideAxis('left') if self.hasTimeAxis(): showRoiPlot = True mn = self.tVals.min() mx = self.tVals.max() self.ui.roiPlot.setXRange(mn, mx, padding=0.01) self.timeLine.show() self.timeLine.setBounds([mn, mx]) self.ui.roiPlot.show() if not self.ui.roiBtn.isChecked(): self.ui.splitter.setSizes([self.height()-35, 35]) else: self.timeLine.hide() #self.ui.roiPlot.hide() self.ui.roiPlot.setVisible(showRoiPlot) def roiChanged(self): if self.image is None: return image = self.getProcessedImage() if image.ndim == 2: axes = (0, 1) elif image.ndim == 3: axes = (1, 2) else: return data, coords = self.roi.getArrayRegion(image.view(np.ndarray), self.imageItem, axes, returnMappedCoords=True) if data is not None: while data.ndim > 1: data = data.mean(axis=1) if image.ndim == 3: self.roiCurve.setData(y=data, x=self.tVals) else: while coords.ndim > 2: coords = coords[:,:,0] coords = coords - coords[:,0,np.newaxis] xvals = (coords**2).sum(axis=0) ** 0.5 self.roiCurve.setData(y=data, x=xvals) def quickMinMax(self, data): """ Estimate the min/max values of *data* by subsampling. """ while data.size > 1e6: ax = np.argmax(data.shape) sl = [slice(None)] * data.ndim sl[ax] = slice(None, None, 2) data = data[sl] return nanmin(data), nanmax(data) def normalize(self, image): """ Process *image* using the normalization options configured in the control panel. This can be repurposed to process any data through the same filter. """ if self.ui.normOffRadio.isChecked(): return image div = self.ui.normDivideRadio.isChecked() norm = image.view(np.ndarray).copy() #if div: #norm = ones(image.shape) #else: #norm = zeros(image.shape) if div: norm = norm.astype(np.float32) if self.ui.normTimeRangeCheck.isChecked() and image.ndim == 3: (sind, start) = self.timeIndex(self.normRgn.lines[0]) (eind, end) = self.timeIndex(self.normRgn.lines[1]) #print start, end, sind, eind n = image[sind:eind+1].mean(axis=0) n.shape = (1,) + n.shape if div: norm /= n else: norm -= n if self.ui.normFrameCheck.isChecked() and image.ndim == 3: n = image.mean(axis=1).mean(axis=1) n.shape = n.shape + (1, 1) if div: norm /= n else: norm -= n if self.ui.normROICheck.isChecked() and image.ndim == 3: n = self.normRoi.getArrayRegion(norm, self.imageItem, (1, 2)).mean(axis=1).mean(axis=1) n = n[:,np.newaxis,np.newaxis] #print start, end, sind, eind if div: norm /= n else: norm -= n return norm def timeLineChanged(self): #(ind, time) = self.timeIndex(self.ui.timeSlider) if self.ignoreTimeLine: return self.play(0) (ind, time) = self.timeIndex(self.timeLine) if ind != self.currentIndex: self.currentIndex = ind self.updateImage() #self.timeLine.setPos(time) #self.emit(QtCore.SIGNAL('timeChanged'), ind, time) self.sigTimeChanged.emit(ind, time) def updateImage(self, autoHistogramRange=True): ## Redraw image on screen if self.image is None: return image = self.getProcessedImage() if autoHistogramRange: self.ui.histogram.setHistogramRange(self.levelMin, self.levelMax) # Transpose image into order expected by ImageItem if self.imageItem.axisOrder == 'col-major': axorder = ['t', 'x', 'y', 'c'] else: axorder = ['t', 'y', 'x', 'c'] axorder = [self.axes[ax] for ax in axorder if self.axes[ax] is not None] image = image.transpose(axorder) # Select time index if self.axes['t'] is not None: self.ui.roiPlot.show() image = image[self.currentIndex] self.imageItem.updateImage(image) def timeIndex(self, slider): ## Return the time and frame index indicated by a slider if self.image is None: return (0,0) t = slider.value() xv = self.tVals if xv is None: ind = int(t) else: if len(xv) < 2: return (0,0) totTime = xv[-1] + (xv[-1]-xv[-2]) inds = np.argwhere(xv < t) if len(inds) < 1: return (0,t) ind = inds[-1,0] return ind, t def getView(self): """Return the ViewBox (or other compatible object) which displays the ImageItem""" return self.view def getImageItem(self): """Return the ImageItem for this ImageView.""" return self.imageItem def getRoiPlot(self): """Return the ROI PlotWidget for this ImageView""" return self.ui.roiPlot def getHistogramWidget(self): """Return the HistogramLUTWidget for this ImageView""" return self.ui.histogram def export(self, fileName): """ Export data from the ImageView to a file, or to a stack of files if the data is 3D. Saving an image stack will result in index numbers being added to the file name. Images are saved as they would appear onscreen, with levels and lookup table applied. """ img = self.getProcessedImage() if self.hasTimeAxis(): base, ext = os.path.splitext(fileName) fmt = "%%s%%0%dd%%s" % int(np.log10(img.shape[0])+1) for i in range(img.shape[0]): self.imageItem.setImage(img[i], autoLevels=False) self.imageItem.save(fmt % (base, i, ext)) self.updateImage() else: self.imageItem.save(fileName) def exportClicked(self): fileName = QtGui.QFileDialog.getSaveFileName() if fileName == '': return self.export(fileName) def buildMenu(self): self.menu = QtGui.QMenu() self.normAction = QtGui.QAction("Normalization", self.menu) self.normAction.setCheckable(True) self.normAction.toggled.connect(self.normToggled) self.menu.addAction(self.normAction) self.exportAction = QtGui.QAction("Export", self.menu) self.exportAction.triggered.connect(self.exportClicked) self.menu.addAction(self.exportAction) def menuClicked(self): if self.menu is None: self.buildMenu() self.menu.popup(QtGui.QCursor.pos()) def setColorMap(self, colormap): """Set the color map. ============= ========================================================= **Arguments** colormap (A ColorMap() instance) The ColorMap to use for coloring images. ============= ========================================================= """ self.ui.histogram.gradient.setColorMap(colormap) @addGradientListToDocstring() def setPredefinedGradient(self, name): """Set one of the gradients defined in :class:`GradientEditorItem `. Currently available gradients are: """ self.ui.histogram.gradient.loadPreset(name) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/imageview/ImageViewTemplate.ui000066400000000000000000000157301300727121400255330ustar00rootroot00000000000000 Form 0 0 726 588 Form 0 0 Qt::Vertical 0 0 1 ROI true 0 1 Menu 0 0 0 40 Normalization 0 0 Subtract Divide false 75 true Operation: 75 true Mean: 75 true Blur: ROI X Qt::AlignRight|Qt::AlignTrailing|Qt::AlignVCenter Y Qt::AlignRight|Qt::AlignTrailing|Qt::AlignVCenter T Qt::AlignRight|Qt::AlignTrailing|Qt::AlignVCenter Off true Time range Frame PlotWidget QWidget
..widgets.PlotWidget
1 GraphicsView QGraphicsView
..widgets.GraphicsView
 HistogramLUTWidget QGraphicsView
..widgets.HistogramLUTWidget
 pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/imageview/ImageViewTemplate_pyqt.py000066400000000000000000000211151300727121400266150ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file 'ImageViewTemplate.ui' # # Created: Thu May 1 15:20:40 2014 # by: PyQt4 UI code generator 4.10.4 # # WARNING! All changes made in this file will be lost! from ..Qt import QtCore, QtGui try: _fromUtf8 = QtCore.QString.fromUtf8 except AttributeError: def _fromUtf8(s): return s try: _encoding = QtGui.QApplication.UnicodeUTF8 def _translate(context, text, disambig): return QtGui.QApplication.translate(context, text, disambig, _encoding) except AttributeError: def _translate(context, text, disambig): return QtGui.QApplication.translate(context, text, disambig) class Ui_Form(object): def setupUi(self, Form): Form.setObjectName(_fromUtf8("Form")) Form.resize(726, 588) self.gridLayout_3 = QtGui.QGridLayout(Form) self.gridLayout_3.setMargin(0) self.gridLayout_3.setSpacing(0) self.gridLayout_3.setObjectName(_fromUtf8("gridLayout_3")) self.splitter = QtGui.QSplitter(Form) self.splitter.setOrientation(QtCore.Qt.Vertical) self.splitter.setObjectName(_fromUtf8("splitter")) self.layoutWidget = QtGui.QWidget(self.splitter) self.layoutWidget.setObjectName(_fromUtf8("layoutWidget")) self.gridLayout = QtGui.QGridLayout(self.layoutWidget) self.gridLayout.setSpacing(0) self.gridLayout.setMargin(0) self.gridLayout.setObjectName(_fromUtf8("gridLayout")) self.graphicsView = GraphicsView(self.layoutWidget) self.graphicsView.setObjectName(_fromUtf8("graphicsView")) self.gridLayout.addWidget(self.graphicsView, 0, 0, 2, 1) self.histogram = HistogramLUTWidget(self.layoutWidget) self.histogram.setObjectName(_fromUtf8("histogram")) self.gridLayout.addWidget(self.histogram, 0, 1, 1, 2) self.roiBtn = QtGui.QPushButton(self.layoutWidget) sizePolicy = QtGui.QSizePolicy(QtGui.QSizePolicy.Minimum, QtGui.QSizePolicy.Fixed) sizePolicy.setHorizontalStretch(0) sizePolicy.setVerticalStretch(1) sizePolicy.setHeightForWidth(self.roiBtn.sizePolicy().hasHeightForWidth()) self.roiBtn.setSizePolicy(sizePolicy) self.roiBtn.setCheckable(True) self.roiBtn.setObjectName(_fromUtf8("roiBtn")) self.gridLayout.addWidget(self.roiBtn, 1, 1, 1, 1) self.menuBtn = QtGui.QPushButton(self.layoutWidget) sizePolicy = QtGui.QSizePolicy(QtGui.QSizePolicy.Minimum, QtGui.QSizePolicy.Fixed) sizePolicy.setHorizontalStretch(0) sizePolicy.setVerticalStretch(1) sizePolicy.setHeightForWidth(self.menuBtn.sizePolicy().hasHeightForWidth()) self.menuBtn.setSizePolicy(sizePolicy) self.menuBtn.setObjectName(_fromUtf8("menuBtn")) self.gridLayout.addWidget(self.menuBtn, 1, 2, 1, 1) self.roiPlot = PlotWidget(self.splitter) sizePolicy = QtGui.QSizePolicy(QtGui.QSizePolicy.Preferred, QtGui.QSizePolicy.Preferred) sizePolicy.setHorizontalStretch(0) sizePolicy.setVerticalStretch(0) sizePolicy.setHeightForWidth(self.roiPlot.sizePolicy().hasHeightForWidth()) self.roiPlot.setSizePolicy(sizePolicy) self.roiPlot.setMinimumSize(QtCore.QSize(0, 40)) self.roiPlot.setObjectName(_fromUtf8("roiPlot")) self.gridLayout_3.addWidget(self.splitter, 0, 0, 1, 1) self.normGroup = QtGui.QGroupBox(Form) self.normGroup.setObjectName(_fromUtf8("normGroup")) self.gridLayout_2 = QtGui.QGridLayout(self.normGroup) self.gridLayout_2.setMargin(0) self.gridLayout_2.setSpacing(0) self.gridLayout_2.setObjectName(_fromUtf8("gridLayout_2")) self.normSubtractRadio = QtGui.QRadioButton(self.normGroup) self.normSubtractRadio.setObjectName(_fromUtf8("normSubtractRadio")) self.gridLayout_2.addWidget(self.normSubtractRadio, 0, 2, 1, 1) self.normDivideRadio = QtGui.QRadioButton(self.normGroup) self.normDivideRadio.setChecked(False) self.normDivideRadio.setObjectName(_fromUtf8("normDivideRadio")) self.gridLayout_2.addWidget(self.normDivideRadio, 0, 1, 1, 1) self.label_5 = QtGui.QLabel(self.normGroup) font = QtGui.QFont() font.setBold(True) font.setWeight(75) self.label_5.setFont(font) self.label_5.setObjectName(_fromUtf8("label_5")) self.gridLayout_2.addWidget(self.label_5, 0, 0, 1, 1) self.label_3 = QtGui.QLabel(self.normGroup) font = QtGui.QFont() font.setBold(True) font.setWeight(75) self.label_3.setFont(font) self.label_3.setObjectName(_fromUtf8("label_3")) self.gridLayout_2.addWidget(self.label_3, 1, 0, 1, 1) self.label_4 = QtGui.QLabel(self.normGroup) font = QtGui.QFont() font.setBold(True) font.setWeight(75) self.label_4.setFont(font) self.label_4.setObjectName(_fromUtf8("label_4")) self.gridLayout_2.addWidget(self.label_4, 2, 0, 1, 1) self.normROICheck = QtGui.QCheckBox(self.normGroup) self.normROICheck.setObjectName(_fromUtf8("normROICheck")) self.gridLayout_2.addWidget(self.normROICheck, 1, 1, 1, 1) self.normXBlurSpin = QtGui.QDoubleSpinBox(self.normGroup) self.normXBlurSpin.setObjectName(_fromUtf8("normXBlurSpin")) self.gridLayout_2.addWidget(self.normXBlurSpin, 2, 2, 1, 1) self.label_8 = QtGui.QLabel(self.normGroup) self.label_8.setAlignment(QtCore.Qt.AlignRight|QtCore.Qt.AlignTrailing|QtCore.Qt.AlignVCenter) self.label_8.setObjectName(_fromUtf8("label_8")) self.gridLayout_2.addWidget(self.label_8, 2, 1, 1, 1) self.label_9 = QtGui.QLabel(self.normGroup) self.label_9.setAlignment(QtCore.Qt.AlignRight|QtCore.Qt.AlignTrailing|QtCore.Qt.AlignVCenter) self.label_9.setObjectName(_fromUtf8("label_9")) self.gridLayout_2.addWidget(self.label_9, 2, 3, 1, 1) self.normYBlurSpin = QtGui.QDoubleSpinBox(self.normGroup) self.normYBlurSpin.setObjectName(_fromUtf8("normYBlurSpin")) self.gridLayout_2.addWidget(self.normYBlurSpin, 2, 4, 1, 1) self.label_10 = QtGui.QLabel(self.normGroup) self.label_10.setAlignment(QtCore.Qt.AlignRight|QtCore.Qt.AlignTrailing|QtCore.Qt.AlignVCenter) self.label_10.setObjectName(_fromUtf8("label_10")) self.gridLayout_2.addWidget(self.label_10, 2, 5, 1, 1) self.normOffRadio = QtGui.QRadioButton(self.normGroup) self.normOffRadio.setChecked(True) self.normOffRadio.setObjectName(_fromUtf8("normOffRadio")) self.gridLayout_2.addWidget(self.normOffRadio, 0, 3, 1, 1) self.normTimeRangeCheck = QtGui.QCheckBox(self.normGroup) self.normTimeRangeCheck.setObjectName(_fromUtf8("normTimeRangeCheck")) self.gridLayout_2.addWidget(self.normTimeRangeCheck, 1, 3, 1, 1) self.normFrameCheck = QtGui.QCheckBox(self.normGroup) self.normFrameCheck.setObjectName(_fromUtf8("normFrameCheck")) self.gridLayout_2.addWidget(self.normFrameCheck, 1, 2, 1, 1) self.normTBlurSpin = QtGui.QDoubleSpinBox(self.normGroup) self.normTBlurSpin.setObjectName(_fromUtf8("normTBlurSpin")) self.gridLayout_2.addWidget(self.normTBlurSpin, 2, 6, 1, 1) self.gridLayout_3.addWidget(self.normGroup, 1, 0, 1, 1) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): Form.setWindowTitle(_translate("Form", "Form", None)) self.roiBtn.setText(_translate("Form", "ROI", None)) self.menuBtn.setText(_translate("Form", "Menu", None)) self.normGroup.setTitle(_translate("Form", "Normalization", None)) self.normSubtractRadio.setText(_translate("Form", "Subtract", None)) self.normDivideRadio.setText(_translate("Form", "Divide", None)) self.label_5.setText(_translate("Form", "Operation:", None)) self.label_3.setText(_translate("Form", "Mean:", None)) self.label_4.setText(_translate("Form", "Blur:", None)) self.normROICheck.setText(_translate("Form", "ROI", None)) self.label_8.setText(_translate("Form", "X", None)) self.label_9.setText(_translate("Form", "Y", None)) self.label_10.setText(_translate("Form", "T", None)) self.normOffRadio.setText(_translate("Form", "Off", None)) self.normTimeRangeCheck.setText(_translate("Form", "Time range", None)) self.normFrameCheck.setText(_translate("Form", "Frame", None)) from ..widgets.HistogramLUTWidget import HistogramLUTWidget from ..widgets.GraphicsView import GraphicsView from ..widgets.PlotWidget import PlotWidget pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/imageview/ImageViewTemplate_pyqt5.py000066400000000000000000000201231300727121400267000ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file './pyqtgraph/imageview/ImageViewTemplate.ui' # # Created: Wed Mar 26 15:09:28 2014 # by: PyQt5 UI code generator 5.0.1 # # WARNING! All changes made in this file will be lost! from PyQt5 import QtCore, QtGui, QtWidgets class Ui_Form(object): def setupUi(self, Form): Form.setObjectName("Form") Form.resize(726, 588) self.gridLayout_3 = QtWidgets.QGridLayout(Form) self.gridLayout_3.setContentsMargins(0, 0, 0, 0) self.gridLayout_3.setSpacing(0) self.gridLayout_3.setObjectName("gridLayout_3") self.splitter = QtWidgets.QSplitter(Form) self.splitter.setOrientation(QtCore.Qt.Vertical) self.splitter.setObjectName("splitter") self.layoutWidget = QtWidgets.QWidget(self.splitter) self.layoutWidget.setObjectName("layoutWidget") self.gridLayout = QtWidgets.QGridLayout(self.layoutWidget) self.gridLayout.setSpacing(0) self.gridLayout.setContentsMargins(0, 0, 0, 0) self.gridLayout.setObjectName("gridLayout") self.graphicsView = GraphicsView(self.layoutWidget) self.graphicsView.setObjectName("graphicsView") self.gridLayout.addWidget(self.graphicsView, 0, 0, 2, 1) self.histogram = HistogramLUTWidget(self.layoutWidget) self.histogram.setObjectName("histogram") self.gridLayout.addWidget(self.histogram, 0, 1, 1, 2) self.roiBtn = QtWidgets.QPushButton(self.layoutWidget) sizePolicy = QtWidgets.QSizePolicy(QtWidgets.QSizePolicy.Minimum, QtWidgets.QSizePolicy.Fixed) sizePolicy.setHorizontalStretch(0) sizePolicy.setVerticalStretch(1) sizePolicy.setHeightForWidth(self.roiBtn.sizePolicy().hasHeightForWidth()) self.roiBtn.setSizePolicy(sizePolicy) self.roiBtn.setCheckable(True) self.roiBtn.setObjectName("roiBtn") self.gridLayout.addWidget(self.roiBtn, 1, 1, 1, 1) self.normBtn = QtWidgets.QPushButton(self.layoutWidget) sizePolicy = QtWidgets.QSizePolicy(QtWidgets.QSizePolicy.Minimum, QtWidgets.QSizePolicy.Fixed) sizePolicy.setHorizontalStretch(0) sizePolicy.setVerticalStretch(1) sizePolicy.setHeightForWidth(self.normBtn.sizePolicy().hasHeightForWidth()) self.normBtn.setSizePolicy(sizePolicy) self.normBtn.setCheckable(True) self.normBtn.setObjectName("normBtn") self.gridLayout.addWidget(self.normBtn, 1, 2, 1, 1) self.roiPlot = PlotWidget(self.splitter) sizePolicy = QtWidgets.QSizePolicy(QtWidgets.QSizePolicy.Preferred, QtWidgets.QSizePolicy.Preferred) sizePolicy.setHorizontalStretch(0) sizePolicy.setVerticalStretch(0) sizePolicy.setHeightForWidth(self.roiPlot.sizePolicy().hasHeightForWidth()) self.roiPlot.setSizePolicy(sizePolicy) self.roiPlot.setMinimumSize(QtCore.QSize(0, 40)) self.roiPlot.setObjectName("roiPlot") self.gridLayout_3.addWidget(self.splitter, 0, 0, 1, 1) self.normGroup = QtWidgets.QGroupBox(Form) self.normGroup.setObjectName("normGroup") self.gridLayout_2 = QtWidgets.QGridLayout(self.normGroup) self.gridLayout_2.setContentsMargins(0, 0, 0, 0) self.gridLayout_2.setSpacing(0) self.gridLayout_2.setObjectName("gridLayout_2") self.normSubtractRadio = QtWidgets.QRadioButton(self.normGroup) self.normSubtractRadio.setObjectName("normSubtractRadio") self.gridLayout_2.addWidget(self.normSubtractRadio, 0, 2, 1, 1) self.normDivideRadio = QtWidgets.QRadioButton(self.normGroup) self.normDivideRadio.setChecked(False) self.normDivideRadio.setObjectName("normDivideRadio") self.gridLayout_2.addWidget(self.normDivideRadio, 0, 1, 1, 1) self.label_5 = QtWidgets.QLabel(self.normGroup) font = QtGui.QFont() font.setBold(True) font.setWeight(75) self.label_5.setFont(font) self.label_5.setObjectName("label_5") self.gridLayout_2.addWidget(self.label_5, 0, 0, 1, 1) self.label_3 = QtWidgets.QLabel(self.normGroup) font = QtGui.QFont() font.setBold(True) font.setWeight(75) self.label_3.setFont(font) self.label_3.setObjectName("label_3") self.gridLayout_2.addWidget(self.label_3, 1, 0, 1, 1) self.label_4 = QtWidgets.QLabel(self.normGroup) font = QtGui.QFont() font.setBold(True) font.setWeight(75) self.label_4.setFont(font) self.label_4.setObjectName("label_4") self.gridLayout_2.addWidget(self.label_4, 2, 0, 1, 1) self.normROICheck = QtWidgets.QCheckBox(self.normGroup) self.normROICheck.setObjectName("normROICheck") self.gridLayout_2.addWidget(self.normROICheck, 1, 1, 1, 1) self.normXBlurSpin = QtWidgets.QDoubleSpinBox(self.normGroup) self.normXBlurSpin.setObjectName("normXBlurSpin") self.gridLayout_2.addWidget(self.normXBlurSpin, 2, 2, 1, 1) self.label_8 = QtWidgets.QLabel(self.normGroup) self.label_8.setAlignment(QtCore.Qt.AlignRight|QtCore.Qt.AlignTrailing|QtCore.Qt.AlignVCenter) self.label_8.setObjectName("label_8") self.gridLayout_2.addWidget(self.label_8, 2, 1, 1, 1) self.label_9 = QtWidgets.QLabel(self.normGroup) self.label_9.setAlignment(QtCore.Qt.AlignRight|QtCore.Qt.AlignTrailing|QtCore.Qt.AlignVCenter) self.label_9.setObjectName("label_9") self.gridLayout_2.addWidget(self.label_9, 2, 3, 1, 1) self.normYBlurSpin = QtWidgets.QDoubleSpinBox(self.normGroup) self.normYBlurSpin.setObjectName("normYBlurSpin") self.gridLayout_2.addWidget(self.normYBlurSpin, 2, 4, 1, 1) self.label_10 = QtWidgets.QLabel(self.normGroup) self.label_10.setAlignment(QtCore.Qt.AlignRight|QtCore.Qt.AlignTrailing|QtCore.Qt.AlignVCenter) self.label_10.setObjectName("label_10") self.gridLayout_2.addWidget(self.label_10, 2, 5, 1, 1) self.normOffRadio = QtWidgets.QRadioButton(self.normGroup) self.normOffRadio.setChecked(True) self.normOffRadio.setObjectName("normOffRadio") self.gridLayout_2.addWidget(self.normOffRadio, 0, 3, 1, 1) self.normTimeRangeCheck = QtWidgets.QCheckBox(self.normGroup) self.normTimeRangeCheck.setObjectName("normTimeRangeCheck") self.gridLayout_2.addWidget(self.normTimeRangeCheck, 1, 3, 1, 1) self.normFrameCheck = QtWidgets.QCheckBox(self.normGroup) self.normFrameCheck.setObjectName("normFrameCheck") self.gridLayout_2.addWidget(self.normFrameCheck, 1, 2, 1, 1) self.normTBlurSpin = QtWidgets.QDoubleSpinBox(self.normGroup) self.normTBlurSpin.setObjectName("normTBlurSpin") self.gridLayout_2.addWidget(self.normTBlurSpin, 2, 6, 1, 1) self.gridLayout_3.addWidget(self.normGroup, 1, 0, 1, 1) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): _translate = QtCore.QCoreApplication.translate Form.setWindowTitle(_translate("Form", "Form")) self.roiBtn.setText(_translate("Form", "ROI")) self.normBtn.setText(_translate("Form", "Norm")) self.normGroup.setTitle(_translate("Form", "Normalization")) self.normSubtractRadio.setText(_translate("Form", "Subtract")) self.normDivideRadio.setText(_translate("Form", "Divide")) self.label_5.setText(_translate("Form", "Operation:")) self.label_3.setText(_translate("Form", "Mean:")) self.label_4.setText(_translate("Form", "Blur:")) self.normROICheck.setText(_translate("Form", "ROI")) self.label_8.setText(_translate("Form", "X")) self.label_9.setText(_translate("Form", "Y")) self.label_10.setText(_translate("Form", "T")) self.normOffRadio.setText(_translate("Form", "Off")) self.normTimeRangeCheck.setText(_translate("Form", "Time range")) self.normFrameCheck.setText(_translate("Form", "Frame")) from ..widgets.HistogramLUTWidget import HistogramLUTWidget from ..widgets.PlotWidget import PlotWidget from ..widgets.GraphicsView import GraphicsView pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/imageview/ImageViewTemplate_pyside.py000066400000000000000000000213401300727121400271150ustar00rootroot00000000000000# -*- coding: utf-8 -*- # Form implementation generated from reading ui file 'ImageViewTemplate.ui' # # Created: Thu May 1 15:20:42 2014 # by: pyside-uic 0.2.15 running on PySide 1.2.1 # # WARNING! All changes made in this file will be lost! from PySide import QtCore, QtGui class Ui_Form(object): def setupUi(self, Form): Form.setObjectName("Form") Form.resize(726, 588) self.gridLayout_3 = QtGui.QGridLayout(Form) self.gridLayout_3.setContentsMargins(0, 0, 0, 0) self.gridLayout_3.setSpacing(0) self.gridLayout_3.setObjectName("gridLayout_3") self.splitter = QtGui.QSplitter(Form) self.splitter.setOrientation(QtCore.Qt.Vertical) self.splitter.setObjectName("splitter") self.layoutWidget = QtGui.QWidget(self.splitter) self.layoutWidget.setObjectName("layoutWidget") self.gridLayout = QtGui.QGridLayout(self.layoutWidget) self.gridLayout.setSpacing(0) self.gridLayout.setContentsMargins(0, 0, 0, 0) self.gridLayout.setObjectName("gridLayout") self.graphicsView = GraphicsView(self.layoutWidget) self.graphicsView.setObjectName("graphicsView") self.gridLayout.addWidget(self.graphicsView, 0, 0, 2, 1) self.histogram = HistogramLUTWidget(self.layoutWidget) self.histogram.setObjectName("histogram") self.gridLayout.addWidget(self.histogram, 0, 1, 1, 2) self.roiBtn = QtGui.QPushButton(self.layoutWidget) sizePolicy = QtGui.QSizePolicy(QtGui.QSizePolicy.Minimum, QtGui.QSizePolicy.Fixed) sizePolicy.setHorizontalStretch(0) sizePolicy.setVerticalStretch(1) sizePolicy.setHeightForWidth(self.roiBtn.sizePolicy().hasHeightForWidth()) self.roiBtn.setSizePolicy(sizePolicy) self.roiBtn.setCheckable(True) self.roiBtn.setObjectName("roiBtn") self.gridLayout.addWidget(self.roiBtn, 1, 1, 1, 1) self.menuBtn = QtGui.QPushButton(self.layoutWidget) sizePolicy = QtGui.QSizePolicy(QtGui.QSizePolicy.Minimum, QtGui.QSizePolicy.Fixed) sizePolicy.setHorizontalStretch(0) sizePolicy.setVerticalStretch(1) sizePolicy.setHeightForWidth(self.menuBtn.sizePolicy().hasHeightForWidth()) self.menuBtn.setSizePolicy(sizePolicy) self.menuBtn.setObjectName("menuBtn") self.gridLayout.addWidget(self.menuBtn, 1, 2, 1, 1) self.roiPlot = PlotWidget(self.splitter) sizePolicy = QtGui.QSizePolicy(QtGui.QSizePolicy.Preferred, QtGui.QSizePolicy.Preferred) sizePolicy.setHorizontalStretch(0) sizePolicy.setVerticalStretch(0) sizePolicy.setHeightForWidth(self.roiPlot.sizePolicy().hasHeightForWidth()) self.roiPlot.setSizePolicy(sizePolicy) self.roiPlot.setMinimumSize(QtCore.QSize(0, 40)) self.roiPlot.setObjectName("roiPlot") self.gridLayout_3.addWidget(self.splitter, 0, 0, 1, 1) self.normGroup = QtGui.QGroupBox(Form) self.normGroup.setObjectName("normGroup") self.gridLayout_2 = QtGui.QGridLayout(self.normGroup) self.gridLayout_2.setContentsMargins(0, 0, 0, 0) self.gridLayout_2.setSpacing(0) self.gridLayout_2.setObjectName("gridLayout_2") self.normSubtractRadio = QtGui.QRadioButton(self.normGroup) self.normSubtractRadio.setObjectName("normSubtractRadio") self.gridLayout_2.addWidget(self.normSubtractRadio, 0, 2, 1, 1) self.normDivideRadio = QtGui.QRadioButton(self.normGroup) self.normDivideRadio.setChecked(False) self.normDivideRadio.setObjectName("normDivideRadio") self.gridLayout_2.addWidget(self.normDivideRadio, 0, 1, 1, 1) self.label_5 = QtGui.QLabel(self.normGroup) font = QtGui.QFont() font.setWeight(75) font.setBold(True) self.label_5.setFont(font) self.label_5.setObjectName("label_5") self.gridLayout_2.addWidget(self.label_5, 0, 0, 1, 1) self.label_3 = QtGui.QLabel(self.normGroup) font = QtGui.QFont() font.setWeight(75) font.setBold(True) self.label_3.setFont(font) self.label_3.setObjectName("label_3") self.gridLayout_2.addWidget(self.label_3, 1, 0, 1, 1) self.label_4 = QtGui.QLabel(self.normGroup) font = QtGui.QFont() font.setWeight(75) font.setBold(True) self.label_4.setFont(font) self.label_4.setObjectName("label_4") self.gridLayout_2.addWidget(self.label_4, 2, 0, 1, 1) self.normROICheck = QtGui.QCheckBox(self.normGroup) self.normROICheck.setObjectName("normROICheck") self.gridLayout_2.addWidget(self.normROICheck, 1, 1, 1, 1) self.normXBlurSpin = QtGui.QDoubleSpinBox(self.normGroup) self.normXBlurSpin.setObjectName("normXBlurSpin") self.gridLayout_2.addWidget(self.normXBlurSpin, 2, 2, 1, 1) self.label_8 = QtGui.QLabel(self.normGroup) self.label_8.setAlignment(QtCore.Qt.AlignRight|QtCore.Qt.AlignTrailing|QtCore.Qt.AlignVCenter) self.label_8.setObjectName("label_8") self.gridLayout_2.addWidget(self.label_8, 2, 1, 1, 1) self.label_9 = QtGui.QLabel(self.normGroup) self.label_9.setAlignment(QtCore.Qt.AlignRight|QtCore.Qt.AlignTrailing|QtCore.Qt.AlignVCenter) self.label_9.setObjectName("label_9") self.gridLayout_2.addWidget(self.label_9, 2, 3, 1, 1) self.normYBlurSpin = QtGui.QDoubleSpinBox(self.normGroup) self.normYBlurSpin.setObjectName("normYBlurSpin") self.gridLayout_2.addWidget(self.normYBlurSpin, 2, 4, 1, 1) self.label_10 = QtGui.QLabel(self.normGroup) self.label_10.setAlignment(QtCore.Qt.AlignRight|QtCore.Qt.AlignTrailing|QtCore.Qt.AlignVCenter) self.label_10.setObjectName("label_10") self.gridLayout_2.addWidget(self.label_10, 2, 5, 1, 1) self.normOffRadio = QtGui.QRadioButton(self.normGroup) self.normOffRadio.setChecked(True) self.normOffRadio.setObjectName("normOffRadio") self.gridLayout_2.addWidget(self.normOffRadio, 0, 3, 1, 1) self.normTimeRangeCheck = QtGui.QCheckBox(self.normGroup) self.normTimeRangeCheck.setObjectName("normTimeRangeCheck") self.gridLayout_2.addWidget(self.normTimeRangeCheck, 1, 3, 1, 1) self.normFrameCheck = QtGui.QCheckBox(self.normGroup) self.normFrameCheck.setObjectName("normFrameCheck") self.gridLayout_2.addWidget(self.normFrameCheck, 1, 2, 1, 1) self.normTBlurSpin = QtGui.QDoubleSpinBox(self.normGroup) self.normTBlurSpin.setObjectName("normTBlurSpin") self.gridLayout_2.addWidget(self.normTBlurSpin, 2, 6, 1, 1) self.gridLayout_3.addWidget(self.normGroup, 1, 0, 1, 1) self.retranslateUi(Form) QtCore.QMetaObject.connectSlotsByName(Form) def retranslateUi(self, Form): Form.setWindowTitle(QtGui.QApplication.translate("Form", "Form", None, QtGui.QApplication.UnicodeUTF8)) self.roiBtn.setText(QtGui.QApplication.translate("Form", "ROI", None, QtGui.QApplication.UnicodeUTF8)) self.menuBtn.setText(QtGui.QApplication.translate("Form", "Menu", None, QtGui.QApplication.UnicodeUTF8)) self.normGroup.setTitle(QtGui.QApplication.translate("Form", "Normalization", None, QtGui.QApplication.UnicodeUTF8)) self.normSubtractRadio.setText(QtGui.QApplication.translate("Form", "Subtract", None, QtGui.QApplication.UnicodeUTF8)) self.normDivideRadio.setText(QtGui.QApplication.translate("Form", "Divide", None, QtGui.QApplication.UnicodeUTF8)) self.label_5.setText(QtGui.QApplication.translate("Form", "Operation:", None, QtGui.QApplication.UnicodeUTF8)) self.label_3.setText(QtGui.QApplication.translate("Form", "Mean:", None, QtGui.QApplication.UnicodeUTF8)) self.label_4.setText(QtGui.QApplication.translate("Form", "Blur:", None, QtGui.QApplication.UnicodeUTF8)) self.normROICheck.setText(QtGui.QApplication.translate("Form", "ROI", None, QtGui.QApplication.UnicodeUTF8)) self.label_8.setText(QtGui.QApplication.translate("Form", "X", None, QtGui.QApplication.UnicodeUTF8)) self.label_9.setText(QtGui.QApplication.translate("Form", "Y", None, QtGui.QApplication.UnicodeUTF8)) self.label_10.setText(QtGui.QApplication.translate("Form", "T", None, QtGui.QApplication.UnicodeUTF8)) self.normOffRadio.setText(QtGui.QApplication.translate("Form", "Off", None, QtGui.QApplication.UnicodeUTF8)) self.normTimeRangeCheck.setText(QtGui.QApplication.translate("Form", "Time range", None, QtGui.QApplication.UnicodeUTF8)) self.normFrameCheck.setText(QtGui.QApplication.translate("Form", "Frame", None, QtGui.QApplication.UnicodeUTF8)) from ..widgets.HistogramLUTWidget import HistogramLUTWidget from ..widgets.GraphicsView import GraphicsView from ..widgets.PlotWidget import PlotWidget pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/imageview/__init__.py000066400000000000000000000002411300727121400237230ustar00rootroot00000000000000""" Widget used for display and analysis of 2D and 3D image data. Includes ROI plotting over time and image normalization. """ from .ImageView import ImageView pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/imageview/tests/000077500000000000000000000000001300727121400227575ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/imageview/tests/test_imageview.py000066400000000000000000000003511300727121400263440ustar00rootroot00000000000000import pyqtgraph as pg import numpy as np app = pg.mkQApp() def test_nan_image(): img = np.ones((10,10)) img[0,0] = np.nan v = pg.image(img) v.imageItem.getHistogram() app.processEvents() v.window().close() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/metaarray/000077500000000000000000000000001300727121400216255ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/metaarray/MetaArray.py000066400000000000000000001600471300727121400240740ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ MetaArray.py - Class encapsulating ndarray with meta data Copyright 2010 Luke Campagnola Distributed under MIT/X11 license. See license.txt for more infomation. MetaArray is an array class based on numpy.ndarray that allows storage of per-axis meta data such as axis values, names, units, column names, etc. It also enables several new methods for slicing and indexing the array based on this meta data. More info at http://www.scipy.org/Cookbook/MetaArray """ import types, copy, threading, os, re import pickle from functools import reduce import numpy as np from ..python2_3 import basestring #import traceback ## By default, the library will use HDF5 when writing files. ## This can be overridden by setting USE_HDF5 = False USE_HDF5 = True try: import h5py HAVE_HDF5 = True except: USE_HDF5 = False HAVE_HDF5 = False def axis(name=None, cols=None, values=None, units=None): """Convenience function for generating axis descriptions when defining MetaArrays""" ax = {} cNameOrder = ['name', 'units', 'title'] if name is not None: ax['name'] = name if values is not None: ax['values'] = values if units is not None: ax['units'] = units if cols is not None: ax['cols'] = [] for c in cols: if type(c) != list and type(c) != tuple: c = [c] col = {} for i in range(0,len(c)): col[cNameOrder[i]] = c[i] ax['cols'].append(col) return ax class sliceGenerator(object): """Just a compact way to generate tuples of slice objects.""" def __getitem__(self, arg): return arg def __getslice__(self, arg): return arg SLICER = sliceGenerator() class MetaArray(object): """N-dimensional array with meta data such as axis titles, units, and column names. May be initialized with a file name, a tuple representing the dimensions of the array, or any arguments that could be passed on to numpy.array() The info argument sets the metadata for the entire array. It is composed of a list of axis descriptions where each axis may have a name, title, units, and a list of column descriptions. An additional dict at the end of the axis list may specify parameters that apply to values in the entire array. For example: A 2D array of altitude values for a topographical map might look like info=[ {'name': 'lat', 'title': 'Lattitude'}, {'name': 'lon', 'title': 'Longitude'}, {'title': 'Altitude', 'units': 'm'} ] In this case, every value in the array represents the altitude in feet at the lat, lon position represented by the array index. All of the following return the value at lat=10, lon=5: array[10, 5] array['lon':5, 'lat':10] array['lat':10][5] Now suppose we want to combine this data with another array of equal dimensions that represents the average rainfall for each location. We could easily store these as two separate arrays or combine them into a 3D array with this description: info=[ {'name': 'vals', 'cols': [ {'name': 'altitude', 'units': 'm'}, {'name': 'rainfall', 'units': 'cm/year'} ]}, {'name': 'lat', 'title': 'Lattitude'}, {'name': 'lon', 'title': 'Longitude'} ] We can now access the altitude values with array[0] or array['altitude'], and the rainfall values with array[1] or array['rainfall']. All of the following return the rainfall value at lat=10, lon=5: array[1, 10, 5] array['lon':5, 'lat':10, 'val': 'rainfall'] array['rainfall', 'lon':5, 'lat':10] Notice that in the second example, there is no need for an extra (4th) axis description since the actual values are described (name and units) in the column info for the first axis. """ version = '2' # Default hdf5 compression to use when writing # 'gzip' is widely available and somewhat slow # 'lzf' is faster, but generally not available outside h5py # 'szip' is also faster, but lacks write support on windows # (so by default, we use no compression) # May also be a tuple (filter, opts), such as ('gzip', 3) defaultCompression = None ## Types allowed as axis or column names nameTypes = [basestring, tuple] @staticmethod def isNameType(var): return any([isinstance(var, t) for t in MetaArray.nameTypes]) ## methods to wrap from embedded ndarray / HDF5 wrapMethods = set(['__eq__', '__ne__', '__le__', '__lt__', '__ge__', '__gt__']) def __init__(self, data=None, info=None, dtype=None, file=None, copy=False, **kwargs): object.__init__(self) #self._infoOwned = False self._isHDF = False if file is not None: self._data = None self.readFile(file, **kwargs) if kwargs.get("readAllData", True) and self._data is None: raise Exception("File read failed: %s" % file) else: self._info = info if (hasattr(data, 'implements') and data.implements('MetaArray')): self._info = data._info self._data = data.asarray() elif isinstance(data, tuple): ## create empty array with specified shape self._data = np.empty(data, dtype=dtype) else: self._data = np.array(data, dtype=dtype, copy=copy) ## run sanity checks on info structure self.checkInfo() def checkInfo(self): info = self._info if info is None: if self._data is None: return else: self._info = [{} for i in range(self.ndim + 1)] return else: try: info = list(info) except: raise Exception("Info must be a list of axis specifications") if len(info) < self.ndim+1: info.extend([{}]*(self.ndim+1-len(info))) elif len(info) > self.ndim+1: raise Exception("Info parameter must be list of length ndim+1 or less.") for i in range(len(info)): if not isinstance(info[i], dict): if info[i] is None: info[i] = {} else: raise Exception("Axis specification must be Dict or None") if i < self.ndim and 'values' in info[i]: if type(info[i]['values']) is list: info[i]['values'] = np.array(info[i]['values']) elif type(info[i]['values']) is not np.ndarray: raise Exception("Axis values must be specified as list or ndarray") if info[i]['values'].ndim != 1 or info[i]['values'].shape[0] != self.shape[i]: raise Exception("Values array for axis %d has incorrect shape. (given %s, but should be %s)" % (i, str(info[i]['values'].shape), str((self.shape[i],)))) if i < self.ndim and 'cols' in info[i]: if not isinstance(info[i]['cols'], list): info[i]['cols'] = list(info[i]['cols']) if len(info[i]['cols']) != self.shape[i]: raise Exception('Length of column list for axis %d does not match data. (given %d, but should be %d)' % (i, len(info[i]['cols']), self.shape[i])) self._info = info def implements(self, name=None): ## Rather than isinstance(obj, MetaArray) use object.implements('MetaArray') if name is None: return ['MetaArray'] else: return name == 'MetaArray' #def __array_finalize__(self,obj): ### array_finalize is called every time a MetaArray is created ### (whereas __new__ is not necessarily called every time) ### obj is the object from which this array was generated (for example, when slicing or view()ing) ## We use the getattr method to set a default if 'obj' doesn't have the 'info' attribute ##print "Create new MA from object", str(type(obj)) ##import traceback ##traceback.print_stack() ##print "finalize", type(self), type(obj) #if not hasattr(self, '_info'): ##if isinstance(obj, MetaArray): ##print " copy info:", obj._info #self._info = getattr(obj, '_info', [{}]*(obj.ndim+1)) #self._infoOwned = False ## Do not make changes to _info until it is copied at least once ##print " self info:", self._info ## We could have checked first whether self._info was already defined: ##if not hasattr(self, 'info'): ## self._info = getattr(obj, 'info', {}) def __getitem__(self, ind): #print "getitem:", ind ## should catch scalar requests as early as possible to speed things up (?) nInd = self._interpretIndexes(ind) #a = np.ndarray.__getitem__(self, nInd) a = self._data[nInd] if len(nInd) == self.ndim: if np.all([not isinstance(ind, slice) for ind in nInd]): ## no slices; we have requested a single value from the array return a #if type(a) != type(self._data) and not isinstance(a, np.ndarray): ## indexing returned single value #return a ## indexing returned a sub-array; generate new info array to go with it #print " new MA:", type(a), a.shape info = [] extraInfo = self._info[-1].copy() for i in range(0, len(nInd)): ## iterate over all axes #print " axis", i if type(nInd[i]) in [slice, list] or isinstance(nInd[i], np.ndarray): ## If the axis is sliced, keep the info but chop if necessary #print " slice axis", i, nInd[i] #a._info[i] = self._axisSlice(i, nInd[i]) #print " info:", a._info[i] info.append(self._axisSlice(i, nInd[i])) else: ## If the axis is indexed, then move the information from that single index to the last info dictionary #print "indexed:", i, nInd[i], type(nInd[i]) newInfo = self._axisSlice(i, nInd[i]) name = None colName = None for k in newInfo: if k == 'cols': if 'cols' not in extraInfo: extraInfo['cols'] = [] extraInfo['cols'].append(newInfo[k]) if 'units' in newInfo[k]: extraInfo['units'] = newInfo[k]['units'] if 'name' in newInfo[k]: colName = newInfo[k]['name'] elif k == 'name': name = newInfo[k] else: if k not in extraInfo: extraInfo[k] = newInfo[k] extraInfo[k] = newInfo[k] if 'name' not in extraInfo: if name is None: if colName is not None: extraInfo['name'] = colName else: if colName is not None: extraInfo['name'] = str(name) + ': ' + str(colName) else: extraInfo['name'] = name #print "Lost info:", newInfo #a._info[i] = None #if 'name' in newInfo: #a._info[-1][newInfo['name']] = newInfo info.append(extraInfo) #self._infoOwned = False #while None in a._info: #a._info.remove(None) return MetaArray(a, info=info) @property def ndim(self): return len(self.shape) ## hdf5 objects do not have ndim property. @property def shape(self): return self._data.shape @property def dtype(self): return self._data.dtype def __len__(self): return len(self._data) def __getslice__(self, *args): return self.__getitem__(slice(*args)) def __setitem__(self, ind, val): nInd = self._interpretIndexes(ind) try: self._data[nInd] = val except: print(self, nInd, val) raise def __getattr__(self, attr): if attr in self.wrapMethods: return getattr(self._data, attr) else: raise AttributeError(attr) #return lambda *args, **kwargs: MetaArray(getattr(a.view(ndarray), attr)(*args, **kwargs) def __eq__(self, b): return self._binop('__eq__', b) def __ne__(self, b): return self._binop('__ne__', b) #if isinstance(b, MetaArray): #b = b.asarray() #return self.asarray() != b def __sub__(self, b): return self._binop('__sub__', b) #if isinstance(b, MetaArray): #b = b.asarray() #return MetaArray(self.asarray() - b, info=self.infoCopy()) def __add__(self, b): return self._binop('__add__', b) def __mul__(self, b): return self._binop('__mul__', b) def __div__(self, b): return self._binop('__div__', b) def __truediv__(self, b): return self._binop('__truediv__', b) def _binop(self, op, b): if isinstance(b, MetaArray): b = b.asarray() a = self.asarray() c = getattr(a, op)(b) if c.shape != a.shape: raise Exception("Binary operators with MetaArray must return an array of the same shape (this shape is %s, result shape was %s)" % (a.shape, c.shape)) return MetaArray(c, info=self.infoCopy()) def asarray(self): if isinstance(self._data, np.ndarray): return self._data else: return np.array(self._data) def __array__(self): ## supports np.array(metaarray_instance) return self.asarray() def view(self, typ): ## deprecated; kept for backward compatibility if typ is np.ndarray: return self.asarray() else: raise Exception('invalid view type: %s' % str(typ)) def axisValues(self, axis): """Return the list of values for an axis""" ax = self._interpretAxis(axis) if 'values' in self._info[ax]: return self._info[ax]['values'] else: raise Exception('Array axis %s (%d) has no associated values.' % (str(axis), ax)) def xvals(self, axis): """Synonym for axisValues()""" return self.axisValues(axis) def axisHasValues(self, axis): ax = self._interpretAxis(axis) return 'values' in self._info[ax] def axisHasColumns(self, axis): ax = self._interpretAxis(axis) return 'cols' in self._info[ax] def axisUnits(self, axis): """Return the units for axis""" ax = self._info[self._interpretAxis(axis)] if 'units' in ax: return ax['units'] def hasColumn(self, axis, col): ax = self._info[self._interpretAxis(axis)] if 'cols' in ax: for c in ax['cols']: if c['name'] == col: return True return False def listColumns(self, axis=None): """Return a list of column names for axis. If axis is not specified, then return a dict of {axisName: (column names), ...}.""" if axis is None: ret = {} for i in range(self.ndim): if 'cols' in self._info[i]: cols = [c['name'] for c in self._info[i]['cols']] else: cols = [] ret[self.axisName(i)] = cols return ret else: axis = self._interpretAxis(axis) return [c['name'] for c in self._info[axis]['cols']] def columnName(self, axis, col): ax = self._info[self._interpretAxis(axis)] return ax['cols'][col]['name'] def axisName(self, n): return self._info[n].get('name', n) def columnUnits(self, axis, column): """Return the units for column in axis""" ax = self._info[self._interpretAxis(axis)] if 'cols' in ax: for c in ax['cols']: if c['name'] == column: return c['units'] raise Exception("Axis %s has no column named %s" % (str(axis), str(column))) else: raise Exception("Axis %s has no column definitions" % str(axis)) def rowsort(self, axis, key=0): """Return this object with all records sorted along axis using key as the index to the values to compare. Does not yet modify meta info.""" ## make sure _info is copied locally before modifying it! keyList = self[key] order = keyList.argsort() if type(axis) == int: ind = [slice(None)]*axis ind.append(order) elif isinstance(axis, basestring): ind = (slice(axis, order),) return self[tuple(ind)] def append(self, val, axis): """Return this object with val appended along axis. Does not yet combine meta info.""" ## make sure _info is copied locally before modifying it! s = list(self.shape) axis = self._interpretAxis(axis) s[axis] += 1 n = MetaArray(tuple(s), info=self._info, dtype=self.dtype) ind = [slice(None)]*self.ndim ind[axis] = slice(None,-1) n[tuple(ind)] = self ind[axis] = -1 n[tuple(ind)] = val return n def extend(self, val, axis): """Return the concatenation along axis of this object and val. Does not yet combine meta info.""" ## make sure _info is copied locally before modifying it! axis = self._interpretAxis(axis) return MetaArray(np.concatenate(self, val, axis), info=self._info) def infoCopy(self, axis=None): """Return a deep copy of the axis meta info for this object""" if axis is None: return copy.deepcopy(self._info) else: return copy.deepcopy(self._info[self._interpretAxis(axis)]) def copy(self): return MetaArray(self._data.copy(), info=self.infoCopy()) def _interpretIndexes(self, ind): #print "interpret", ind if not isinstance(ind, tuple): ## a list of slices should be interpreted as a tuple of slices. if isinstance(ind, list) and len(ind) > 0 and isinstance(ind[0], slice): ind = tuple(ind) ## everything else can just be converted to a length-1 tuple else: ind = (ind,) nInd = [slice(None)]*self.ndim numOk = True ## Named indices not started yet; numbered sill ok for i in range(0,len(ind)): (axis, index, isNamed) = self._interpretIndex(ind[i], i, numOk) #try: nInd[axis] = index #except: #print "ndim:", self.ndim #print "axis:", axis #print "index spec:", ind[i] #print "index num:", index #raise if isNamed: numOk = False return tuple(nInd) def _interpretAxis(self, axis): if isinstance(axis, basestring) or isinstance(axis, tuple): return self._getAxis(axis) else: return axis def _interpretIndex(self, ind, pos, numOk): #print "Interpreting index", ind, pos, numOk ## should probably check for int first to speed things up.. if type(ind) is int: if not numOk: raise Exception("string and integer indexes may not follow named indexes") #print " normal numerical index" return (pos, ind, False) if MetaArray.isNameType(ind): if not numOk: raise Exception("string and integer indexes may not follow named indexes") #print " String index, column is ", self._getIndex(pos, ind) return (pos, self._getIndex(pos, ind), False) elif type(ind) is slice: #print " Slice index" if MetaArray.isNameType(ind.start) or MetaArray.isNameType(ind.stop): ## Not an actual slice! #print " ..not a real slice" axis = self._interpretAxis(ind.start) #print " axis is", axis ## x[Axis:Column] if MetaArray.isNameType(ind.stop): #print " column name, column is ", self._getIndex(axis, ind.stop) index = self._getIndex(axis, ind.stop) ## x[Axis:min:max] elif (isinstance(ind.stop, float) or isinstance(ind.step, float)) and ('values' in self._info[axis]): #print " axis value range" if ind.stop is None: mask = self.xvals(axis) < ind.step elif ind.step is None: mask = self.xvals(axis) >= ind.stop else: mask = (self.xvals(axis) >= ind.stop) * (self.xvals(axis) < ind.step) ##print "mask:", mask index = mask ## x[Axis:columnIndex] elif isinstance(ind.stop, int) or isinstance(ind.step, int): #print " normal slice after named axis" if ind.step is None: index = ind.stop else: index = slice(ind.stop, ind.step) ## x[Axis: [list]] elif type(ind.stop) is list: #print " list of indexes from named axis" index = [] for i in ind.stop: if type(i) is int: index.append(i) elif MetaArray.isNameType(i): index.append(self._getIndex(axis, i)) else: ## unrecognized type, try just passing on to array index = ind.stop break else: #print " other type.. forward on to array for handling", type(ind.stop) index = ind.stop #print "Axis %s (%s) : %s" % (ind.start, str(axis), str(type(index))) #if type(index) is np.ndarray: #print " ", index.shape return (axis, index, True) else: #print " Looks like a real slice, passing on to array" return (pos, ind, False) elif type(ind) is list: #print " List index., interpreting each element individually" indList = [self._interpretIndex(i, pos, numOk)[1] for i in ind] return (pos, indList, False) else: if not numOk: raise Exception("string and integer indexes may not follow named indexes") #print " normal numerical index" return (pos, ind, False) def _getAxis(self, name): for i in range(0, len(self._info)): axis = self._info[i] if 'name' in axis and axis['name'] == name: return i raise Exception("No axis named %s.\n info=%s" % (name, self._info)) def _getIndex(self, axis, name): ax = self._info[axis] if ax is not None and 'cols' in ax: for i in range(0, len(ax['cols'])): if 'name' in ax['cols'][i] and ax['cols'][i]['name'] == name: return i raise Exception("Axis %d has no column named %s.\n info=%s" % (axis, name, self._info)) def _axisCopy(self, i): return copy.deepcopy(self._info[i]) def _axisSlice(self, i, cols): #print "axisSlice", i, cols if 'cols' in self._info[i] or 'values' in self._info[i]: ax = self._axisCopy(i) if 'cols' in ax: #print " slicing columns..", array(ax['cols']), cols sl = np.array(ax['cols'])[cols] if isinstance(sl, np.ndarray): sl = list(sl) ax['cols'] = sl #print " result:", ax['cols'] if 'values' in ax: ax['values'] = np.array(ax['values'])[cols] else: ax = self._info[i] #print " ", ax return ax def prettyInfo(self): s = '' titles = [] maxl = 0 for i in range(len(self._info)-1): ax = self._info[i] axs = '' if 'name' in ax: axs += '"%s"' % str(ax['name']) else: axs += "%d" % i if 'units' in ax: axs += " (%s)" % str(ax['units']) titles.append(axs) if len(axs) > maxl: maxl = len(axs) for i in range(min(self.ndim, len(self._info) - 1)): ax = self._info[i] axs = titles[i] axs += '%s[%d] :' % (' ' * (maxl - len(axs) + 5 - len(str(self.shape[i]))), self.shape[i]) if 'values' in ax: if self.shape[i] > 0: v0 = ax['values'][0] axs += " values: [%g" % (v0) if self.shape[i] > 1: v1 = ax['values'][-1] axs += " ... %g] (step %g)" % (v1, (v1 - v0) / (self.shape[i] - 1)) else: axs += "]" else: axs += " values: []" if 'cols' in ax: axs += " columns: " colstrs = [] for c in range(len(ax['cols'])): col = ax['cols'][c] cs = str(col.get('name', c)) if 'units' in col: cs += " (%s)" % col['units'] colstrs.append(cs) axs += '[' + ', '.join(colstrs) + ']' s += axs + "\n" s += str(self._info[-1]) return s def __repr__(self): return "%s\n-----------------------------------------------\n%s" % (self.view(np.ndarray).__repr__(), self.prettyInfo()) def __str__(self): return self.__repr__() def axisCollapsingFn(self, fn, axis=None, *args, **kargs): #arr = self.view(np.ndarray) fn = getattr(self._data, fn) if axis is None: return fn(axis, *args, **kargs) else: info = self.infoCopy() axis = self._interpretAxis(axis) info.pop(axis) return MetaArray(fn(axis, *args, **kargs), info=info) def mean(self, axis=None, *args, **kargs): return self.axisCollapsingFn('mean', axis, *args, **kargs) def min(self, axis=None, *args, **kargs): return self.axisCollapsingFn('min', axis, *args, **kargs) def max(self, axis=None, *args, **kargs): return self.axisCollapsingFn('max', axis, *args, **kargs) def transpose(self, *args): if len(args) == 1 and hasattr(args[0], '__iter__'): order = args[0] else: order = args order = [self._interpretAxis(ax) for ax in order] infoOrder = order + list(range(len(order), len(self._info))) info = [self._info[i] for i in infoOrder] order = order + list(range(len(order), self.ndim)) try: if self._isHDF: return MetaArray(np.array(self._data).transpose(order), info=info) else: return MetaArray(self._data.transpose(order), info=info) except: print(order) raise #### File I/O Routines def readFile(self, filename, **kwargs): """Load the data and meta info stored in *filename* Different arguments are allowed depending on the type of file. For HDF5 files: *writable* (bool) if True, then any modifications to data in the array will be stored to disk. *readAllData* (bool) if True, then all data in the array is immediately read from disk and the file is closed (this is the default for files < 500MB). Otherwise, the file will be left open and data will be read only as requested (this is the default for files >= 500MB). """ ## decide which read function to use with open(filename, 'rb') as fd: magic = fd.read(8) if magic == '\x89HDF\r\n\x1a\n': fd.close() self._readHDF5(filename, **kwargs) self._isHDF = True else: fd.seek(0) meta = MetaArray._readMeta(fd) if not kwargs.get("readAllData", True): self._data = np.empty(meta['shape'], dtype=meta['type']) if 'version' in meta: ver = meta['version'] else: ver = 1 rFuncName = '_readData%s' % str(ver) if not hasattr(MetaArray, rFuncName): raise Exception("This MetaArray library does not support array version '%s'" % ver) rFunc = getattr(self, rFuncName) rFunc(fd, meta, **kwargs) self._isHDF = False @staticmethod def _readMeta(fd): """Read meta array from the top of a file. Read lines until a blank line is reached. This function should ideally work for ALL versions of MetaArray. """ meta = '' ## Read meta information until the first blank line while True: line = fd.readline().strip() if line == '': break meta += line ret = eval(meta) #print ret return ret def _readData1(self, fd, meta, mmap=False, **kwds): ## Read array data from the file descriptor for MetaArray v1 files ## read in axis values for any axis that specifies a length frameSize = 1 for ax in meta['info']: if 'values_len' in ax: ax['values'] = np.fromstring(fd.read(ax['values_len']), dtype=ax['values_type']) frameSize *= ax['values_len'] del ax['values_len'] del ax['values_type'] self._info = meta['info'] if not kwds.get("readAllData", True): return ## the remaining data is the actual array if mmap: subarr = np.memmap(fd, dtype=meta['type'], mode='r', shape=meta['shape']) else: subarr = np.fromstring(fd.read(), dtype=meta['type']) subarr.shape = meta['shape'] self._data = subarr def _readData2(self, fd, meta, mmap=False, subset=None, **kwds): ## read in axis values dynAxis = None frameSize = 1 ## read in axis values for any axis that specifies a length for i in range(len(meta['info'])): ax = meta['info'][i] if 'values_len' in ax: if ax['values_len'] == 'dynamic': if dynAxis is not None: raise Exception("MetaArray has more than one dynamic axis! (this is not allowed)") dynAxis = i else: ax['values'] = np.fromstring(fd.read(ax['values_len']), dtype=ax['values_type']) frameSize *= ax['values_len'] del ax['values_len'] del ax['values_type'] self._info = meta['info'] if not kwds.get("readAllData", True): return ## No axes are dynamic, just read the entire array in at once if dynAxis is None: #if rewriteDynamic is not None: #raise Exception("") if meta['type'] == 'object': if mmap: raise Exception('memmap not supported for arrays with dtype=object') subarr = pickle.loads(fd.read()) else: if mmap: subarr = np.memmap(fd, dtype=meta['type'], mode='r', shape=meta['shape']) else: subarr = np.fromstring(fd.read(), dtype=meta['type']) #subarr = subarr.view(subtype) subarr.shape = meta['shape'] #subarr._info = meta['info'] ## One axis is dynamic, read in a frame at a time else: if mmap: raise Exception('memmap not supported for non-contiguous arrays. Use rewriteContiguous() to convert.') ax = meta['info'][dynAxis] xVals = [] frames = [] frameShape = list(meta['shape']) frameShape[dynAxis] = 1 frameSize = reduce(lambda a,b: a*b, frameShape) n = 0 while True: ## Extract one non-blank line while True: line = fd.readline() if line != '\n': break if line == '': break ## evaluate line inf = eval(line) ## read data block #print "read %d bytes as %s" % (inf['len'], meta['type']) if meta['type'] == 'object': data = pickle.loads(fd.read(inf['len'])) else: data = np.fromstring(fd.read(inf['len']), dtype=meta['type']) if data.size != frameSize * inf['numFrames']: #print data.size, frameSize, inf['numFrames'] raise Exception("Wrong frame size in MetaArray file! (frame %d)" % n) ## read in data block shape = list(frameShape) shape[dynAxis] = inf['numFrames'] data.shape = shape if subset is not None: dSlice = subset[dynAxis] if dSlice.start is None: dStart = 0 else: dStart = max(0, dSlice.start - n) if dSlice.stop is None: dStop = data.shape[dynAxis] else: dStop = min(data.shape[dynAxis], dSlice.stop - n) newSubset = list(subset[:]) newSubset[dynAxis] = slice(dStart, dStop) if dStop > dStart: #print n, data.shape, " => ", newSubset, data[tuple(newSubset)].shape frames.append(data[tuple(newSubset)].copy()) else: #data = data[subset].copy() ## what's this for?? frames.append(data) n += inf['numFrames'] if 'xVals' in inf: xVals.extend(inf['xVals']) subarr = np.concatenate(frames, axis=dynAxis) if len(xVals)> 0: ax['values'] = np.array(xVals, dtype=ax['values_type']) del ax['values_len'] del ax['values_type'] #subarr = subarr.view(subtype) #subarr._info = meta['info'] self._info = meta['info'] self._data = subarr #raise Exception() ## stress-testing #return subarr def _readHDF5(self, fileName, readAllData=None, writable=False, **kargs): if 'close' in kargs and readAllData is None: ## for backward compatibility readAllData = kargs['close'] if readAllData is True and writable is True: raise Exception("Incompatible arguments: readAllData=True and writable=True") if not HAVE_HDF5: try: assert writable==False assert readAllData != False self._readHDF5Remote(fileName) return except: raise Exception("The file '%s' is HDF5-formatted, but the HDF5 library (h5py) was not found." % fileName) ## by default, readAllData=True for files < 500MB if readAllData is None: size = os.stat(fileName).st_size readAllData = (size < 500e6) if writable is True: mode = 'r+' else: mode = 'r' f = h5py.File(fileName, mode) ver = f.attrs['MetaArray'] if ver > MetaArray.version: print("Warning: This file was written with MetaArray version %s, but you are using version %s. (Will attempt to read anyway)" % (str(ver), str(MetaArray.version))) meta = MetaArray.readHDF5Meta(f['info']) self._info = meta if writable or not readAllData: ## read all data, convert to ndarray, close file self._data = f['data'] self._openFile = f else: self._data = f['data'][:] f.close() def _readHDF5Remote(self, fileName): ## Used to read HDF5 files via remote process. ## This is needed in the case that HDF5 is not importable due to the use of python-dbg. proc = getattr(MetaArray, '_hdf5Process', None) if proc == False: raise Exception('remote read failed') if proc == None: from .. import multiprocess as mp #print "new process" proc = mp.Process(executable='/usr/bin/python') proc.setProxyOptions(deferGetattr=True) MetaArray._hdf5Process = proc MetaArray._h5py_metaarray = proc._import('pyqtgraph.metaarray') ma = MetaArray._h5py_metaarray.MetaArray(file=fileName) self._data = ma.asarray()._getValue() self._info = ma._info._getValue() #print MetaArray._hdf5Process #import inspect #print MetaArray, id(MetaArray), inspect.getmodule(MetaArray) @staticmethod def mapHDF5Array(data, writable=False): off = data.id.get_offset() if writable: mode = 'r+' else: mode = 'r' if off is None: raise Exception("This dataset uses chunked storage; it can not be memory-mapped. (store using mappable=True)") return np.memmap(filename=data.file.filename, offset=off, dtype=data.dtype, shape=data.shape, mode=mode) @staticmethod def readHDF5Meta(root, mmap=False): data = {} ## Pull list of values from attributes and child objects for k in root.attrs: val = root.attrs[k] if isinstance(val, basestring): ## strings need to be re-evaluated to their original types try: val = eval(val) except: raise Exception('Can not evaluate string: "%s"' % val) data[k] = val for k in root: obj = root[k] if isinstance(obj, h5py.highlevel.Group): val = MetaArray.readHDF5Meta(obj) elif isinstance(obj, h5py.highlevel.Dataset): if mmap: val = MetaArray.mapHDF5Array(obj) else: val = obj[:] else: raise Exception("Don't know what to do with type '%s'" % str(type(obj))) data[k] = val typ = root.attrs['_metaType_'] del data['_metaType_'] if typ == 'dict': return data elif typ == 'list' or typ == 'tuple': d2 = [None]*len(data) for k in data: d2[int(k)] = data[k] if typ == 'tuple': d2 = tuple(d2) return d2 else: raise Exception("Don't understand metaType '%s'" % typ) def write(self, fileName, **opts): """Write this object to a file. The object can be restored by calling MetaArray(file=fileName) opts: appendAxis: the name (or index) of the appendable axis. Allows the array to grow. compression: None, 'gzip' (good compression), 'lzf' (fast compression), etc. chunks: bool or tuple specifying chunk shape """ if USE_HDF5 and HAVE_HDF5: return self.writeHDF5(fileName, **opts) else: return self.writeMa(fileName, **opts) def writeMeta(self, fileName): """Used to re-write meta info to the given file. This feature is only available for HDF5 files.""" f = h5py.File(fileName, 'r+') if f.attrs['MetaArray'] != MetaArray.version: raise Exception("The file %s was created with a different version of MetaArray. Will not modify." % fileName) del f['info'] self.writeHDF5Meta(f, 'info', self._info) f.close() def writeHDF5(self, fileName, **opts): ## default options for writing datasets comp = self.defaultCompression if isinstance(comp, tuple): comp, copts = comp else: copts = None dsOpts = { 'compression': comp, 'chunks': True, } if copts is not None: dsOpts['compression_opts'] = copts ## if there is an appendable axis, then we can guess the desired chunk shape (optimized for appending) appAxis = opts.get('appendAxis', None) if appAxis is not None: appAxis = self._interpretAxis(appAxis) cs = [min(100000, x) for x in self.shape] cs[appAxis] = 1 dsOpts['chunks'] = tuple(cs) ## if there are columns, then we can guess a different chunk shape ## (read one column at a time) else: cs = [min(100000, x) for x in self.shape] for i in range(self.ndim): if 'cols' in self._info[i]: cs[i] = 1 dsOpts['chunks'] = tuple(cs) ## update options if they were passed in for k in dsOpts: if k in opts: dsOpts[k] = opts[k] ## If mappable is in options, it disables chunking/compression if opts.get('mappable', False): dsOpts = { 'chunks': None, 'compression': None } ## set maximum shape to allow expansion along appendAxis append = False if appAxis is not None: maxShape = list(self.shape) ax = self._interpretAxis(appAxis) maxShape[ax] = None if os.path.exists(fileName): append = True dsOpts['maxshape'] = tuple(maxShape) else: dsOpts['maxshape'] = None if append: f = h5py.File(fileName, 'r+') if f.attrs['MetaArray'] != MetaArray.version: raise Exception("The file %s was created with a different version of MetaArray. Will not modify." % fileName) ## resize data and write in new values data = f['data'] shape = list(data.shape) shape[ax] += self.shape[ax] data.resize(tuple(shape)) sl = [slice(None)] * len(data.shape) sl[ax] = slice(-self.shape[ax], None) data[tuple(sl)] = self.view(np.ndarray) ## add axis values if they are present. axInfo = f['info'][str(ax)] if 'values' in axInfo: v = axInfo['values'] v2 = self._info[ax]['values'] shape = list(v.shape) shape[0] += v2.shape[0] v.resize(shape) v[-v2.shape[0]:] = v2 f.close() else: f = h5py.File(fileName, 'w') f.attrs['MetaArray'] = MetaArray.version #print dsOpts f.create_dataset('data', data=self.view(np.ndarray), **dsOpts) ## dsOpts is used when storing meta data whenever an array is encountered ## however, 'chunks' will no longer be valid for these arrays if it specifies a chunk shape. ## 'maxshape' is right-out. if isinstance(dsOpts['chunks'], tuple): dsOpts['chunks'] = True if 'maxshape' in dsOpts: del dsOpts['maxshape'] self.writeHDF5Meta(f, 'info', self._info, **dsOpts) f.close() def writeHDF5Meta(self, root, name, data, **dsOpts): if isinstance(data, np.ndarray): dsOpts['maxshape'] = (None,) + data.shape[1:] root.create_dataset(name, data=data, **dsOpts) elif isinstance(data, list) or isinstance(data, tuple): gr = root.create_group(name) if isinstance(data, list): gr.attrs['_metaType_'] = 'list' else: gr.attrs['_metaType_'] = 'tuple' #n = int(np.log10(len(data))) + 1 for i in range(len(data)): self.writeHDF5Meta(gr, str(i), data[i], **dsOpts) elif isinstance(data, dict): gr = root.create_group(name) gr.attrs['_metaType_'] = 'dict' for k, v in data.items(): self.writeHDF5Meta(gr, k, v, **dsOpts) elif isinstance(data, int) or isinstance(data, float) or isinstance(data, np.integer) or isinstance(data, np.floating): root.attrs[name] = data else: try: ## strings, bools, None are stored as repr() strings root.attrs[name] = repr(data) except: print("Can not store meta data of type '%s' in HDF5. (key is '%s')" % (str(type(data)), str(name))) raise def writeMa(self, fileName, appendAxis=None, newFile=False): """Write an old-style .ma file""" meta = {'shape':self.shape, 'type':str(self.dtype), 'info':self.infoCopy(), 'version':MetaArray.version} axstrs = [] ## copy out axis values for dynamic axis if requested if appendAxis is not None: if MetaArray.isNameType(appendAxis): appendAxis = self._interpretAxis(appendAxis) ax = meta['info'][appendAxis] ax['values_len'] = 'dynamic' if 'values' in ax: ax['values_type'] = str(ax['values'].dtype) dynXVals = ax['values'] del ax['values'] else: dynXVals = None ## Generate axis data string, modify axis info so we know how to read it back in later for ax in meta['info']: if 'values' in ax: axstrs.append(ax['values'].tostring()) ax['values_len'] = len(axstrs[-1]) ax['values_type'] = str(ax['values'].dtype) del ax['values'] ## Decide whether to output the meta block for a new file if not newFile: ## If the file does not exist or its size is 0, then we must write the header newFile = (not os.path.exists(fileName)) or (os.stat(fileName).st_size == 0) ## write data to file if appendAxis is None or newFile: fd = open(fileName, 'wb') fd.write(str(meta) + '\n\n') for ax in axstrs: fd.write(ax) else: fd = open(fileName, 'ab') if self.dtype != object: dataStr = self.view(np.ndarray).tostring() else: dataStr = pickle.dumps(self.view(np.ndarray)) #print self.size, len(dataStr), self.dtype if appendAxis is not None: frameInfo = {'len':len(dataStr), 'numFrames':self.shape[appendAxis]} if dynXVals is not None: frameInfo['xVals'] = list(dynXVals) fd.write('\n'+str(frameInfo)+'\n') fd.write(dataStr) fd.close() def writeCsv(self, fileName=None): """Write 2D array to CSV file or return the string if no filename is given""" if self.ndim > 2: raise Exception("CSV Export is only for 2D arrays") if fileName is not None: file = open(fileName, 'w') ret = '' if 'cols' in self._info[0]: s = ','.join([x['name'] for x in self._info[0]['cols']]) + '\n' if fileName is not None: file.write(s) else: ret += s for row in range(0, self.shape[1]): s = ','.join(["%g" % x for x in self[:, row]]) + '\n' if fileName is not None: file.write(s) else: ret += s if fileName is not None: file.close() else: return ret #class H5MetaList(): #def rewriteContiguous(fileName, newName): #"""Rewrite a dynamic array file as contiguous""" #def _readData2(fd, meta, subtype, mmap): ### read in axis values #dynAxis = None #frameSize = 1 ### read in axis values for any axis that specifies a length #for i in range(len(meta['info'])): #ax = meta['info'][i] #if ax.has_key('values_len'): #if ax['values_len'] == 'dynamic': #if dynAxis is not None: #raise Exception("MetaArray has more than one dynamic axis! (this is not allowed)") #dynAxis = i #else: #ax['values'] = fromstring(fd.read(ax['values_len']), dtype=ax['values_type']) #frameSize *= ax['values_len'] #del ax['values_len'] #del ax['values_type'] ### No axes are dynamic, just read the entire array in at once #if dynAxis is None: #raise Exception('Array has no dynamic axes.') ### One axis is dynamic, read in a frame at a time #else: #if mmap: #raise Exception('memmap not supported for non-contiguous arrays. Use rewriteContiguous() to convert.') #ax = meta['info'][dynAxis] #xVals = [] #frames = [] #frameShape = list(meta['shape']) #frameShape[dynAxis] = 1 #frameSize = reduce(lambda a,b: a*b, frameShape) #n = 0 #while True: ### Extract one non-blank line #while True: #line = fd.readline() #if line != '\n': #break #if line == '': #break ### evaluate line #inf = eval(line) ### read data block ##print "read %d bytes as %s" % (inf['len'], meta['type']) #if meta['type'] == 'object': #data = pickle.loads(fd.read(inf['len'])) #else: #data = fromstring(fd.read(inf['len']), dtype=meta['type']) #if data.size != frameSize * inf['numFrames']: ##print data.size, frameSize, inf['numFrames'] #raise Exception("Wrong frame size in MetaArray file! (frame %d)" % n) ### read in data block #shape = list(frameShape) #shape[dynAxis] = inf['numFrames'] #data.shape = shape #frames.append(data) #n += inf['numFrames'] #if 'xVals' in inf: #xVals.extend(inf['xVals']) #subarr = np.concatenate(frames, axis=dynAxis) #if len(xVals)> 0: #ax['values'] = array(xVals, dtype=ax['values_type']) #del ax['values_len'] #del ax['values_type'] #subarr = subarr.view(subtype) #subarr._info = meta['info'] #return subarr if __name__ == '__main__': ## Create an array with every option possible arr = np.zeros((2, 5, 3, 5), dtype=int) for i in range(arr.shape[0]): for j in range(arr.shape[1]): for k in range(arr.shape[2]): for l in range(arr.shape[3]): arr[i,j,k,l] = (i+1)*1000 + (j+1)*100 + (k+1)*10 + (l+1) info = [ axis('Axis1'), axis('Axis2', values=[1,2,3,4,5]), axis('Axis3', cols=[ ('Ax3Col1'), ('Ax3Col2', 'mV', 'Axis3 Column2'), (('Ax3','Col3'), 'A', 'Axis3 Column3')]), {'name': 'Axis4', 'values': np.array([1.1, 1.2, 1.3, 1.4, 1.5]), 'units': 's'}, {'extra': 'info'} ] ma = MetaArray(arr, info=info) print("==== Original Array =======") print(ma) print("\n\n") #### Tests follow: #### Index/slice tests: check that all values and meta info are correct after slice print("\n -- normal integer indexing\n") print("\n ma[1]") print(ma[1]) print("\n ma[1, 2:4]") print(ma[1, 2:4]) print("\n ma[1, 1:5:2]") print(ma[1, 1:5:2]) print("\n -- named axis indexing\n") print("\n ma['Axis2':3]") print(ma['Axis2':3]) print("\n ma['Axis2':3:5]") print(ma['Axis2':3:5]) print("\n ma[1, 'Axis2':3]") print(ma[1, 'Axis2':3]) print("\n ma[:, 'Axis2':3]") print(ma[:, 'Axis2':3]) print("\n ma['Axis2':3, 'Axis4':0:2]") print(ma['Axis2':3, 'Axis4':0:2]) print("\n -- column name indexing\n") print("\n ma['Axis3':'Ax3Col1']") print(ma['Axis3':'Ax3Col1']) print("\n ma['Axis3':('Ax3','Col3')]") print(ma['Axis3':('Ax3','Col3')]) print("\n ma[:, :, 'Ax3Col2']") print(ma[:, :, 'Ax3Col2']) print("\n ma[:, :, ('Ax3','Col3')]") print(ma[:, :, ('Ax3','Col3')]) print("\n -- axis value range indexing\n") print("\n ma['Axis2':1.5:4.5]") print(ma['Axis2':1.5:4.5]) print("\n ma['Axis4':1.15:1.45]") print(ma['Axis4':1.15:1.45]) print("\n ma['Axis4':1.15:1.25]") print(ma['Axis4':1.15:1.25]) print("\n -- list indexing\n") print("\n ma[:, [0,2,4]]") print(ma[:, [0,2,4]]) print("\n ma['Axis4':[0,2,4]]") print(ma['Axis4':[0,2,4]]) print("\n ma['Axis3':[0, ('Ax3','Col3')]]") print(ma['Axis3':[0, ('Ax3','Col3')]]) print("\n -- boolean indexing\n") print("\n ma[:, array([True, True, False, True, False])]") print(ma[:, np.array([True, True, False, True, False])]) print("\n ma['Axis4':array([True, False, False, False])]") print(ma['Axis4':np.array([True, False, False, False])]) #### Array operations # - Concatenate # - Append # - Extend # - Rowsort #### File I/O tests print("\n================ File I/O Tests ===================\n") import tempfile tf = tempfile.mktemp() tf = 'test.ma' # write whole array print("\n -- write/read test") ma.write(tf) ma2 = MetaArray(file=tf) #print ma2 print("\nArrays are equivalent:", (ma == ma2).all()) #print "Meta info is equivalent:", ma.infoCopy() == ma2.infoCopy() os.remove(tf) # CSV write # append mode print("\n================append test (%s)===============" % tf) ma['Axis2':0:2].write(tf, appendAxis='Axis2') for i in range(2,ma.shape[1]): ma['Axis2':[i]].write(tf, appendAxis='Axis2') ma2 = MetaArray(file=tf) #print ma2 print("\nArrays are equivalent:", (ma == ma2).all()) #print "Meta info is equivalent:", ma.infoCopy() == ma2.infoCopy() os.remove(tf) ## memmap test print("\n==========Memmap test============") ma.write(tf, mappable=True) ma2 = MetaArray(file=tf, mmap=True) print("\nArrays are equivalent:", (ma == ma2).all()) os.remove(tf) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/metaarray/__init__.py000066400000000000000000000000311300727121400237300ustar00rootroot00000000000000from .MetaArray import * pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/metaarray/license.txt000066400000000000000000000021341300727121400240100ustar00rootroot00000000000000Copyright (c) 2010 Luke Campagnola ('luke.campagnola@%s.com' % 'gmail') The MIT License Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/metaarray/readMeta.m000066400000000000000000000033301300727121400235240ustar00rootroot00000000000000function f = readMeta(file) info = hdf5info(file); f = readMetaRecursive(info.GroupHierarchy.Groups(1)); end function f = readMetaRecursive(root) typ = 0; for i = 1:length(root.Attributes) if strcmp(root.Attributes(i).Shortname, '_metaType_') typ = root.Attributes(i).Value.Data; break end end if typ == 0 printf('group has no _metaType_') typ = 'dict'; end list = 0; if strcmp(typ, 'list') || strcmp(typ, 'tuple') data = {}; list = 1; elseif strcmp(typ, 'dict') data = struct(); else printf('Unrecognized meta type %s', typ); data = struct(); end for i = 1:length(root.Attributes) name = root.Attributes(i).Shortname; if strcmp(name, '_metaType_') continue end val = root.Attributes(i).Value; if isa(val, 'hdf5.h5string') val = val.Data; end if list ind = str2num(name)+1; data{ind} = val; else data.(name) = val; end end for i = 1:length(root.Datasets) fullName = root.Datasets(i).Name; name = stripName(fullName); file = root.Datasets(i).Filename; data2 = hdf5read(file, fullName); if list ind = str2num(name)+1; data{ind} = data2; else data.(name) = data2; end end for i = 1:length(root.Groups) name = stripName(root.Groups(i).Name); data2 = readMetaRecursive(root.Groups(i)); if list ind = str2num(name)+1; data{ind} = data2; else data.(name) = data2; end end f = data; return; end function f = stripName(str) inds = strfind(str, '/'); if isempty(inds) f = str; else f = str(inds(length(inds))+1:length(str)); end end pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/multiprocess/000077500000000000000000000000001300727121400223715ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/multiprocess/__init__.py000066400000000000000000000015741300727121400245110ustar00rootroot00000000000000""" Multiprocessing utility library (parallelization done the way I like it) Luke Campagnola 2012.06.10 This library provides: - simple mechanism for starting a new python interpreter process that can be controlled from the original process (this allows, for example, displaying and manipulating plots in a remote process while the parent process is free to do other work) - proxy system that allows objects hosted in the remote process to be used as if they were local - Qt signal connection between processes - very simple in-line parallelization (fork only; does not work on windows) for number-crunching TODO: allow remote processes to serve as rendering engines that pass pixmaps back to the parent process for display (RemoteGraphicsView class) """ from .processes import * from .parallelizer import Parallelize, CanceledError from .remoteproxy import proxypyqtgraph-pyqtgraph-0.10.0/pyqtgraph/multiprocess/bootstrap.py000066400000000000000000000022121300727121400247550ustar00rootroot00000000000000"""For starting up remote processes""" import sys, pickle, os if __name__ == '__main__': if hasattr(os, 'setpgrp'): os.setpgrp() ## prevents signals (notably keyboard interrupt) being forwarded from parent to this process if sys.version[0] == '3': #name, port, authkey, ppid, targetStr, path, pyside = pickle.load(sys.stdin.buffer) opts = pickle.load(sys.stdin.buffer) else: #name, port, authkey, ppid, targetStr, path, pyside = pickle.load(sys.stdin) opts = pickle.load(sys.stdin) #print "key:", ' '.join([str(ord(x)) for x in authkey]) path = opts.pop('path', None) if path is not None: ## rewrite sys.path without assigning a new object--no idea who already has a reference to the existing list. while len(sys.path) > 0: sys.path.pop() sys.path.extend(path) if opts.pop('pyside', False): import PySide targetStr = opts.pop('targetStr') target = pickle.loads(targetStr) ## unpickling the target should import everything we need target(**opts) ## Send all other options to the target function sys.exit(0) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/multiprocess/parallelizer.py000066400000000000000000000277771300727121400254550ustar00rootroot00000000000000import os, sys, time, multiprocessing, re from .processes import ForkedProcess from .remoteproxy import ClosedError from ..python2_3 import basestring, xrange class CanceledError(Exception): """Raised when the progress dialog is canceled during a processing operation.""" pass class Parallelize(object): """ Class for ultra-simple inline parallelization on multi-core CPUs Example:: ## Here is the serial (single-process) task: tasks = [1, 2, 4, 8] results = [] for task in tasks: result = processTask(task) results.append(result) print(results) ## Here is the parallelized version: tasks = [1, 2, 4, 8] results = [] with Parallelize(tasks, workers=4, results=results) as tasker: for task in tasker: result = processTask(task) tasker.results.append(result) print(results) The only major caveat is that *result* in the example above must be picklable, since it is automatically sent via pipe back to the parent process. """ def __init__(self, tasks=None, workers=None, block=True, progressDialog=None, randomReseed=True, **kwds): """ =============== =================================================================== **Arguments:** tasks list of objects to be processed (Parallelize will determine how to distribute the tasks). If unspecified, then each worker will receive a single task with a unique id number. workers number of worker processes or None to use number of CPUs in the system progressDialog optional dict of arguments for ProgressDialog to update while tasks are processed randomReseed If True, each forked process will reseed its random number generator to ensure independent results. Works with the built-in random and numpy.random. kwds objects to be shared by proxy with child processes (they will appear as attributes of the tasker) =============== =================================================================== """ ## Generate progress dialog. ## Note that we want to avoid letting forked child processes play with progress dialogs.. self.showProgress = False if progressDialog is not None: self.showProgress = True if isinstance(progressDialog, basestring): progressDialog = {'labelText': progressDialog} from ..widgets.ProgressDialog import ProgressDialog self.progressDlg = ProgressDialog(**progressDialog) if workers is None: workers = self.suggestedWorkerCount() if not hasattr(os, 'fork'): workers = 1 self.workers = workers if tasks is None: tasks = range(workers) self.tasks = list(tasks) self.reseed = randomReseed self.kwds = kwds.copy() self.kwds['_taskStarted'] = self._taskStarted def __enter__(self): self.proc = None if self.workers == 1: return self.runSerial() else: return self.runParallel() def __exit__(self, *exc_info): if self.proc is not None: ## worker exceptOccurred = exc_info[0] is not None ## hit an exception during processing. try: if exceptOccurred: sys.excepthook(*exc_info) finally: #print os.getpid(), 'exit' os._exit(1 if exceptOccurred else 0) else: ## parent if self.showProgress: self.progressDlg.__exit__(None, None, None) def runSerial(self): if self.showProgress: self.progressDlg.__enter__() self.progressDlg.setMaximum(len(self.tasks)) self.progress = {os.getpid(): []} return Tasker(self, None, self.tasks, self.kwds) def runParallel(self): self.childs = [] ## break up tasks into one set per worker workers = self.workers chunks = [[] for i in xrange(workers)] i = 0 for i in range(len(self.tasks)): chunks[i%workers].append(self.tasks[i]) ## fork and assign tasks to each worker for i in range(workers): proc = ForkedProcess(target=None, preProxy=self.kwds, randomReseed=self.reseed) if not proc.isParent: self.proc = proc return Tasker(self, proc, chunks[i], proc.forkedProxies) else: self.childs.append(proc) ## Keep track of the progress of each worker independently. self.progress = dict([(ch.childPid, []) for ch in self.childs]) ## for each child process, self.progress[pid] is a list ## of task indexes. The last index is the task currently being ## processed; all others are finished. try: if self.showProgress: self.progressDlg.__enter__() self.progressDlg.setMaximum(len(self.tasks)) ## process events from workers until all have exited. activeChilds = self.childs[:] self.exitCodes = [] pollInterval = 0.01 while len(activeChilds) > 0: waitingChildren = 0 rem = [] for ch in activeChilds: try: n = ch.processRequests() if n > 0: waitingChildren += 1 except ClosedError: #print ch.childPid, 'process finished' rem.append(ch) if self.showProgress: self.progressDlg += 1 #print "remove:", [ch.childPid for ch in rem] for ch in rem: activeChilds.remove(ch) while True: try: pid, exitcode = os.waitpid(ch.childPid, 0) self.exitCodes.append(exitcode) break except OSError as ex: if ex.errno == 4: ## If we get this error, just try again continue #print "Ignored system call interruption" else: raise #print [ch.childPid for ch in activeChilds] if self.showProgress and self.progressDlg.wasCanceled(): for ch in activeChilds: ch.kill() raise CanceledError() ## adjust polling interval--prefer to get exactly 1 event per poll cycle. if waitingChildren > 1: pollInterval *= 0.7 elif waitingChildren == 0: pollInterval /= 0.7 pollInterval = max(min(pollInterval, 0.5), 0.0005) ## but keep it within reasonable limits time.sleep(pollInterval) finally: if self.showProgress: self.progressDlg.__exit__(None, None, None) if len(self.exitCodes) < len(self.childs): raise Exception("Parallelizer started %d processes but only received exit codes from %d." % (len(self.childs), len(self.exitCodes))) for code in self.exitCodes: if code != 0: raise Exception("Error occurred in parallel-executed subprocess (console output may have more information).") return [] ## no tasks for parent process. @staticmethod def suggestedWorkerCount(): if 'linux' in sys.platform: ## I think we can do a little better here.. ## cpu_count does not consider that there is little extra benefit to using hyperthreaded cores. try: cores = {} pid = None for line in open('/proc/cpuinfo'): m = re.match(r'physical id\s+:\s+(\d+)', line) if m is not None: pid = m.groups()[0] m = re.match(r'cpu cores\s+:\s+(\d+)', line) if m is not None: cores[pid] = int(m.groups()[0]) return sum(cores.values()) except: return multiprocessing.cpu_count() else: return multiprocessing.cpu_count() def _taskStarted(self, pid, i, **kwds): ## called remotely by tasker to indicate it has started working on task i #print pid, 'reported starting task', i if self.showProgress: if len(self.progress[pid]) > 0: self.progressDlg += 1 if pid == os.getpid(): ## single-worker process if self.progressDlg.wasCanceled(): raise CanceledError() self.progress[pid].append(i) class Tasker(object): def __init__(self, parallelizer, process, tasks, kwds): self.proc = process self.par = parallelizer self.tasks = tasks for k, v in kwds.iteritems(): setattr(self, k, v) def __iter__(self): ## we could fix this up such that tasks are retrieved from the parent process one at a time.. for i, task in enumerate(self.tasks): self.index = i #print os.getpid(), 'starting task', i self._taskStarted(os.getpid(), i, _callSync='off') yield task if self.proc is not None: #print os.getpid(), 'no more tasks' self.proc.close() def process(self): """ Process requests from parent. Usually it is not necessary to call this unless you would like to receive messages (such as exit requests) during an iteration. """ if self.proc is not None: self.proc.processRequests() def numWorkers(self): """ Return the number of parallel workers """ return self.par.workers #class Parallelizer: #""" #Use:: #p = Parallelizer() #with p(4) as i: #p.finish(do_work(i)) #print p.results() #""" #def __init__(self): #pass #def __call__(self, n): #self.replies = [] #self.conn = None ## indicates this is the parent process #return Session(self, n) #def finish(self, data): #if self.conn is None: #self.replies.append((self.i, data)) #else: ##print "send", self.i, data #self.conn.send((self.i, data)) #os._exit(0) #def result(self): #print self.replies #class Session: #def __init__(self, par, n): #self.par = par #self.n = n #def __enter__(self): #self.childs = [] #for i in range(1, self.n): #c1, c2 = multiprocessing.Pipe() #pid = os.fork() #if pid == 0: ## child #self.par.i = i #self.par.conn = c2 #self.childs = None #c1.close() #return i #else: #self.childs.append(c1) #c2.close() #self.par.i = 0 #return 0 #def __exit__(self, *exc_info): #if exc_info[0] is not None: #sys.excepthook(*exc_info) #if self.childs is not None: #self.par.replies.extend([conn.recv() for conn in self.childs]) #else: #self.par.finish(None) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/multiprocess/processes.py000066400000000000000000000503511300727121400247550ustar00rootroot00000000000000import subprocess, atexit, os, sys, time, random, socket, signal import multiprocessing.connection try: import cPickle as pickle except ImportError: import pickle from .remoteproxy import RemoteEventHandler, ClosedError, NoResultError, LocalObjectProxy, ObjectProxy from ..Qt import USE_PYSIDE from ..util import cprint # color printing for debugging __all__ = ['Process', 'QtProcess', 'ForkedProcess', 'ClosedError', 'NoResultError'] class Process(RemoteEventHandler): """ Bases: RemoteEventHandler This class is used to spawn and control a new python interpreter. It uses subprocess.Popen to start the new process and communicates with it using multiprocessing.Connection objects over a network socket. By default, the remote process will immediately enter an event-processing loop that carries out requests send from the parent process. Remote control works mainly through proxy objects:: proc = Process() ## starts process, returns handle rsys = proc._import('sys') ## asks remote process to import 'sys', returns ## a proxy which references the imported module rsys.stdout.write('hello\n') ## This message will be printed from the remote ## process. Proxy objects can usually be used ## exactly as regular objects are. proc.close() ## Request the remote process shut down Requests made via proxy objects may be synchronous or asynchronous and may return objects either by proxy or by value (if they are picklable). See ProxyObject for more information. """ _process_count = 1 # just used for assigning colors to each process for debugging def __init__(self, name=None, target=None, executable=None, copySysPath=True, debug=False, timeout=20, wrapStdout=None): """ ============== ============================================================= **Arguments:** name Optional name for this process used when printing messages from the remote process. target Optional function to call after starting remote process. By default, this is startEventLoop(), which causes the remote process to process requests from the parent process until it is asked to quit. If you wish to specify a different target, it must be picklable (bound methods are not). copySysPath If True, copy the contents of sys.path to the remote process debug If True, print detailed information about communication with the child process. wrapStdout If True (default on windows) then stdout and stderr from the child process will be caught by the parent process and forwarded to its stdout/stderr. This provides a workaround for a python bug: http://bugs.python.org/issue3905 but has the side effect that child output is significantly delayed relative to the parent output. ============== ============================================================= """ if target is None: target = startEventLoop if name is None: name = str(self) if executable is None: executable = sys.executable self.debug = 7 if debug is True else False # 7 causes printing in white ## random authentication key authkey = os.urandom(20) ## Windows seems to have a hard time with hmac if sys.platform.startswith('win'): authkey = None #print "key:", ' '.join([str(ord(x)) for x in authkey]) ## Listen for connection from remote process (and find free port number) l = multiprocessing.connection.Listener(('localhost', 0), authkey=authkey) port = l.address[1] ## start remote process, instruct it to run target function sysPath = sys.path if copySysPath else None bootstrap = os.path.abspath(os.path.join(os.path.dirname(__file__), 'bootstrap.py')) self.debugMsg('Starting child process (%s %s)' % (executable, bootstrap)) # Decide on printing color for this process if debug: procDebug = (Process._process_count%6) + 1 # pick a color for this process to print in Process._process_count += 1 else: procDebug = False if wrapStdout is None: wrapStdout = sys.platform.startswith('win') if wrapStdout: ## note: we need all three streams to have their own PIPE due to this bug: ## http://bugs.python.org/issue3905 stdout = subprocess.PIPE stderr = subprocess.PIPE self.proc = subprocess.Popen((executable, bootstrap), stdin=subprocess.PIPE, stdout=stdout, stderr=stderr) ## to circumvent the bug and still make the output visible, we use ## background threads to pass data from pipes to stdout/stderr self._stdoutForwarder = FileForwarder(self.proc.stdout, "stdout", procDebug) self._stderrForwarder = FileForwarder(self.proc.stderr, "stderr", procDebug) else: self.proc = subprocess.Popen((executable, bootstrap), stdin=subprocess.PIPE) targetStr = pickle.dumps(target) ## double-pickle target so that child has a chance to ## set its sys.path properly before unpickling the target pid = os.getpid() # we must send pid to child because windows does not have getppid ## Send everything the remote process needs to start correctly data = dict( name=name+'_child', port=port, authkey=authkey, ppid=pid, targetStr=targetStr, path=sysPath, pyside=USE_PYSIDE, debug=procDebug ) pickle.dump(data, self.proc.stdin) self.proc.stdin.close() ## open connection for remote process self.debugMsg('Listening for child process on port %d, authkey=%s..' % (port, repr(authkey))) while True: try: conn = l.accept() break except IOError as err: if err.errno == 4: # interrupted; try again continue else: raise RemoteEventHandler.__init__(self, conn, name+'_parent', pid=self.proc.pid, debug=self.debug) self.debugMsg('Connected to child process.') atexit.register(self.join) def join(self, timeout=10): self.debugMsg('Joining child process..') if self.proc.poll() is None: self.close() start = time.time() while self.proc.poll() is None: if timeout is not None and time.time() - start > timeout: raise Exception('Timed out waiting for remote process to end.') time.sleep(0.05) self.debugMsg('Child process exited. (%d)' % self.proc.returncode) def debugMsg(self, msg, *args): if hasattr(self, '_stdoutForwarder'): ## Lock output from subprocess to make sure we do not get line collisions with self._stdoutForwarder.lock: with self._stderrForwarder.lock: RemoteEventHandler.debugMsg(self, msg, *args) else: RemoteEventHandler.debugMsg(self, msg, *args) def startEventLoop(name, port, authkey, ppid, debug=False): if debug: import os cprint.cout(debug, '[%d] connecting to server at port localhost:%d, authkey=%s..\n' % (os.getpid(), port, repr(authkey)), -1) conn = multiprocessing.connection.Client(('localhost', int(port)), authkey=authkey) if debug: cprint.cout(debug, '[%d] connected; starting remote proxy.\n' % os.getpid(), -1) global HANDLER #ppid = 0 if not hasattr(os, 'getppid') else os.getppid() HANDLER = RemoteEventHandler(conn, name, ppid, debug=debug) while True: try: HANDLER.processRequests() # exception raised when the loop should exit time.sleep(0.01) except ClosedError: break class ForkedProcess(RemoteEventHandler): """ ForkedProcess is a substitute for Process that uses os.fork() to generate a new process. This is much faster than starting a completely new interpreter and child processes automatically have a copy of the entire program state from before the fork. This makes it an appealing approach when parallelizing expensive computations. (see also Parallelizer) However, fork() comes with some caveats and limitations: - fork() is not available on Windows. - It is not possible to have a QApplication in both parent and child process (unless both QApplications are created _after_ the call to fork()) Attempts by the forked process to access Qt GUI elements created by the parent will most likely cause the child to crash. - Likewise, database connections are unlikely to function correctly in a forked child. - Threads are not copied by fork(); the new process will have only one thread that starts wherever fork() was called in the parent process. - Forked processes are unceremoniously terminated when join() is called; they are not given any opportunity to clean up. (This prevents them calling any cleanup code that was only intended to be used by the parent process) - Normally when fork()ing, open file handles are shared with the parent process, which is potentially dangerous. ForkedProcess is careful to close all file handles that are not explicitly needed--stdout, stderr, and a single pipe to the parent process. """ def __init__(self, name=None, target=0, preProxy=None, randomReseed=True): """ When initializing, an optional target may be given. If no target is specified, self.eventLoop will be used. If None is given, no target will be called (and it will be up to the caller to properly shut down the forked process) preProxy may be a dict of values that will appear as ObjectProxy in the remote process (but do not need to be sent explicitly since they are available immediately before the call to fork(). Proxies will be availabe as self.proxies[name]. If randomReseed is True, the built-in random and numpy.random generators will be reseeded in the child process. """ self.hasJoined = False if target == 0: target = self.eventLoop if name is None: name = str(self) conn, remoteConn = multiprocessing.Pipe() proxyIDs = {} if preProxy is not None: for k, v in preProxy.iteritems(): proxyId = LocalObjectProxy.registerObject(v) proxyIDs[k] = proxyId ppid = os.getpid() # write this down now; windows doesn't have getppid pid = os.fork() if pid == 0: self.isParent = False ## We are now in the forked process; need to be extra careful what we touch while here. ## - no reading/writing file handles/sockets owned by parent process (stdout is ok) ## - don't touch QtGui or QApplication at all; these are landmines. ## - don't let the process call exit handlers os.setpgrp() ## prevents signals (notably keyboard interrupt) being forwarded from parent to this process ## close all file handles we do not want shared with parent conn.close() sys.stdin.close() ## otherwise we screw with interactive prompts. fid = remoteConn.fileno() os.closerange(3, fid) os.closerange(fid+1, 4096) ## just guessing on the maximum descriptor count.. ## Override any custom exception hooks def excepthook(*args): import traceback traceback.print_exception(*args) sys.excepthook = excepthook ## Make it harder to access QApplication instance for qtlib in ('PyQt4', 'PySide', 'PyQt5'): if qtlib in sys.modules: sys.modules[qtlib+'.QtGui'].QApplication = None sys.modules.pop(qtlib+'.QtGui', None) sys.modules.pop(qtlib+'.QtCore', None) ## sabotage atexit callbacks atexit._exithandlers = [] atexit.register(lambda: os._exit(0)) if randomReseed: if 'numpy.random' in sys.modules: sys.modules['numpy.random'].seed(os.getpid() ^ int(time.time()*10000%10000)) if 'random' in sys.modules: sys.modules['random'].seed(os.getpid() ^ int(time.time()*10000%10000)) #ppid = 0 if not hasattr(os, 'getppid') else os.getppid() RemoteEventHandler.__init__(self, remoteConn, name+'_child', pid=ppid) self.forkedProxies = {} for name, proxyId in proxyIDs.iteritems(): self.forkedProxies[name] = ObjectProxy(ppid, proxyId=proxyId, typeStr=repr(preProxy[name])) if target is not None: target() else: self.isParent = True self.childPid = pid remoteConn.close() RemoteEventHandler.handlers = {} ## don't want to inherit any of this from the parent. RemoteEventHandler.__init__(self, conn, name+'_parent', pid=pid) atexit.register(self.join) def eventLoop(self): while True: try: self.processRequests() # exception raised when the loop should exit time.sleep(0.01) except ClosedError: break except: print("Error occurred in forked event loop:") sys.excepthook(*sys.exc_info()) sys.exit(0) def join(self, timeout=10): if self.hasJoined: return #os.kill(pid, 9) try: self.close(callSync='sync', timeout=timeout, noCleanup=True) ## ask the child process to exit and require that it return a confirmation. os.waitpid(self.childPid, 0) except IOError: ## probably remote process has already quit pass self.hasJoined = True def kill(self): """Immediately kill the forked remote process. This is generally safe because forked processes are already expected to _avoid_ any cleanup at exit.""" os.kill(self.childPid, signal.SIGKILL) self.hasJoined = True ##Special set of subclasses that implement a Qt event loop instead. class RemoteQtEventHandler(RemoteEventHandler): def __init__(self, *args, **kwds): RemoteEventHandler.__init__(self, *args, **kwds) def startEventTimer(self): from ..Qt import QtGui, QtCore self.timer = QtCore.QTimer() self.timer.timeout.connect(self.processRequests) self.timer.start(10) def processRequests(self): try: RemoteEventHandler.processRequests(self) except ClosedError: from ..Qt import QtGui, QtCore QtGui.QApplication.instance().quit() self.timer.stop() #raise SystemExit class QtProcess(Process): """ QtProcess is essentially the same as Process, with two major differences: - The remote process starts by running startQtEventLoop() which creates a QApplication in the remote process and uses a QTimer to trigger remote event processing. This allows the remote process to have its own GUI. - A QTimer is also started on the parent process which polls for requests from the child process. This allows Qt signals emitted within the child process to invoke slots on the parent process and vice-versa. This can be disabled using processRequests=False in the constructor. Example:: proc = QtProcess() rQtGui = proc._import('PyQt4.QtGui') btn = rQtGui.QPushButton('button on child process') btn.show() def slot(): print('slot invoked on parent process') btn.clicked.connect(proxy(slot)) # be sure to send a proxy of the slot """ def __init__(self, **kwds): if 'target' not in kwds: kwds['target'] = startQtEventLoop from ..Qt import QtGui ## avoid module-level import to keep bootstrap snappy. self._processRequests = kwds.pop('processRequests', True) if self._processRequests and QtGui.QApplication.instance() is None: raise Exception("Must create QApplication before starting QtProcess, or use QtProcess(processRequests=False)") Process.__init__(self, **kwds) self.startEventTimer() def startEventTimer(self): from ..Qt import QtCore ## avoid module-level import to keep bootstrap snappy. self.timer = QtCore.QTimer() if self._processRequests: self.startRequestProcessing() def startRequestProcessing(self, interval=0.01): """Start listening for requests coming from the child process. This allows signals to be connected from the child process to the parent. """ self.timer.timeout.connect(self.processRequests) self.timer.start(interval*1000) def stopRequestProcessing(self): self.timer.stop() def processRequests(self): try: Process.processRequests(self) except ClosedError: self.timer.stop() def startQtEventLoop(name, port, authkey, ppid, debug=False): if debug: import os cprint.cout(debug, '[%d] connecting to server at port localhost:%d, authkey=%s..\n' % (os.getpid(), port, repr(authkey)), -1) conn = multiprocessing.connection.Client(('localhost', int(port)), authkey=authkey) if debug: cprint.cout(debug, '[%d] connected; starting remote proxy.\n' % os.getpid(), -1) from ..Qt import QtGui, QtCore app = QtGui.QApplication.instance() #print app if app is None: app = QtGui.QApplication([]) app.setQuitOnLastWindowClosed(False) ## generally we want the event loop to stay open ## until it is explicitly closed by the parent process. global HANDLER HANDLER = RemoteQtEventHandler(conn, name, ppid, debug=debug) HANDLER.startEventTimer() app.exec_() import threading class FileForwarder(threading.Thread): """ Background thread that forwards data from one pipe to another. This is used to catch data from stdout/stderr of the child process and print it back out to stdout/stderr. We need this because this bug: http://bugs.python.org/issue3905 _requires_ us to catch stdout/stderr. *output* may be a file or 'stdout' or 'stderr'. In the latter cases, sys.stdout/stderr are retrieved once for every line that is output, which ensures that the correct behavior is achieved even if sys.stdout/stderr are replaced at runtime. """ def __init__(self, input, output, color): threading.Thread.__init__(self) self.input = input self.output = output self.lock = threading.Lock() self.daemon = True self.color = color self.start() def run(self): if self.output == 'stdout': while True: line = self.input.readline() with self.lock: cprint.cout(self.color, line, -1) elif self.output == 'stderr': while True: line = self.input.readline() with self.lock: cprint.cerr(self.color, line, -1) else: while True: line = self.input.readline() with self.lock: self.output.write(line) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/multiprocess/remoteproxy.py000066400000000000000000001363021300727121400253450ustar00rootroot00000000000000import os, time, sys, traceback, weakref import numpy as np import threading try: import __builtin__ as builtins import cPickle as pickle except ImportError: import builtins import pickle # color printing for debugging from ..util import cprint class ClosedError(Exception): """Raised when an event handler receives a request to close the connection or discovers that the connection has been closed.""" pass class NoResultError(Exception): """Raised when a request for the return value of a remote call fails because the call has not yet returned.""" pass class RemoteEventHandler(object): """ This class handles communication between two processes. One instance is present on each process and listens for communication from the other process. This enables (amongst other things) ObjectProxy instances to look up their attributes and call their methods. This class is responsible for carrying out actions on behalf of the remote process. Each instance holds one end of a Connection which allows python objects to be passed between processes. For the most common operations, see _import(), close(), and transfer() To handle and respond to incoming requests, RemoteEventHandler requires that its processRequests method is called repeatedly (this is usually handled by the Process classes defined in multiprocess.processes). """ handlers = {} ## maps {process ID : handler}. This allows unpickler to determine which process ## an object proxy belongs to def __init__(self, connection, name, pid, debug=False): self.debug = debug self.conn = connection self.name = name self.results = {} ## reqId: (status, result); cache of request results received from the remote process ## status is either 'result' or 'error' ## if 'error', then result will be (exception, formatted exceprion) ## where exception may be None if it could not be passed through the Connection. self.resultLock = threading.RLock() self.proxies = {} ## maps {weakref(proxy): proxyId}; used to inform the remote process when a proxy has been deleted. self.proxyLock = threading.RLock() ## attributes that affect the behavior of the proxy. ## See ObjectProxy._setProxyOptions for description self.proxyOptions = { 'callSync': 'sync', ## 'sync', 'async', 'off' 'timeout': 10, ## float 'returnType': 'auto', ## 'proxy', 'value', 'auto' 'autoProxy': False, ## bool 'deferGetattr': False, ## True, False 'noProxyTypes': [ type(None), str, int, float, tuple, list, dict, LocalObjectProxy, ObjectProxy ], } if int(sys.version[0]) < 3: self.proxyOptions['noProxyTypes'].append(unicode) else: self.proxyOptions['noProxyTypes'].append(bytes) self.optsLock = threading.RLock() self.nextRequestId = 0 self.exited = False # Mutexes to help prevent issues when multiple threads access the same RemoteEventHandler self.processLock = threading.RLock() self.sendLock = threading.RLock() RemoteEventHandler.handlers[pid] = self ## register this handler as the one communicating with pid @classmethod def getHandler(cls, pid): try: return cls.handlers[pid] except: print(pid, cls.handlers) raise def debugMsg(self, msg, *args): if not self.debug: return cprint.cout(self.debug, "[%d] %s\n" % (os.getpid(), str(msg)%args), -1) def getProxyOption(self, opt): with self.optsLock: return self.proxyOptions[opt] def setProxyOptions(self, **kwds): """ Set the default behavior options for object proxies. See ObjectProxy._setProxyOptions for more info. """ with self.optsLock: self.proxyOptions.update(kwds) def processRequests(self): """Process all pending requests from the pipe, return after no more events are immediately available. (non-blocking) Returns the number of events processed. """ with self.processLock: if self.exited: self.debugMsg(' processRequests: exited already; raise ClosedError.') raise ClosedError() numProcessed = 0 while self.conn.poll(): #try: #poll = self.conn.poll() #if not poll: #break #except IOError: # this can happen if the remote process dies. ## might it also happen in other circumstances? #raise ClosedError() try: self.handleRequest() numProcessed += 1 except ClosedError: self.debugMsg('processRequests: got ClosedError from handleRequest; setting exited=True.') self.exited = True raise #except IOError as err: ## let handleRequest take care of this. #self.debugMsg(' got IOError from handleRequest; try again.') #if err.errno == 4: ## interrupted system call; try again #continue #else: #raise except: print("Error in process %s" % self.name) sys.excepthook(*sys.exc_info()) if numProcessed > 0: self.debugMsg('processRequests: finished %d requests', numProcessed) return numProcessed def handleRequest(self): """Handle a single request from the remote process. Blocks until a request is available.""" result = None while True: try: ## args, kwds are double-pickled to ensure this recv() call never fails cmd, reqId, nByteMsgs, optStr = self.conn.recv() break except EOFError: self.debugMsg(' handleRequest: got EOFError from recv; raise ClosedError.') ## remote process has shut down; end event loop raise ClosedError() except IOError as err: if err.errno == 4: ## interrupted system call; try again self.debugMsg(' handleRequest: got IOError 4 from recv; try again.') continue else: self.debugMsg(' handleRequest: got IOError %d from recv (%s); raise ClosedError.', err.errno, err.strerror) raise ClosedError() self.debugMsg(" handleRequest: received %s %s", cmd, reqId) ## read byte messages following the main request byteData = [] if nByteMsgs > 0: self.debugMsg(" handleRequest: reading %d byte messages", nByteMsgs) for i in range(nByteMsgs): while True: try: byteData.append(self.conn.recv_bytes()) break except EOFError: self.debugMsg(" handleRequest: got EOF while reading byte messages; raise ClosedError.") raise ClosedError() except IOError as err: if err.errno == 4: self.debugMsg(" handleRequest: got IOError 4 while reading byte messages; try again.") continue else: self.debugMsg(" handleRequest: got IOError while reading byte messages; raise ClosedError.") raise ClosedError() try: if cmd == 'result' or cmd == 'error': resultId = reqId reqId = None ## prevents attempt to return information from this request ## (this is already a return from a previous request) opts = pickle.loads(optStr) self.debugMsg(" handleRequest: id=%s opts=%s", reqId, opts) #print os.getpid(), "received request:", cmd, reqId, opts returnType = opts.get('returnType', 'auto') if cmd == 'result': with self.resultLock: self.results[resultId] = ('result', opts['result']) elif cmd == 'error': with self.resultLock: self.results[resultId] = ('error', (opts['exception'], opts['excString'])) elif cmd == 'getObjAttr': result = getattr(opts['obj'], opts['attr']) elif cmd == 'callObj': obj = opts['obj'] fnargs = opts['args'] fnkwds = opts['kwds'] ## If arrays were sent as byte messages, they must be re-inserted into the ## arguments if len(byteData) > 0: for i,arg in enumerate(fnargs): if isinstance(arg, tuple) and len(arg) > 0 and arg[0] == '__byte_message__': ind = arg[1] dtype, shape = arg[2] fnargs[i] = np.fromstring(byteData[ind], dtype=dtype).reshape(shape) for k,arg in fnkwds.items(): if isinstance(arg, tuple) and len(arg) > 0 and arg[0] == '__byte_message__': ind = arg[1] dtype, shape = arg[2] fnkwds[k] = np.fromstring(byteData[ind], dtype=dtype).reshape(shape) if len(fnkwds) == 0: ## need to do this because some functions do not allow keyword arguments. try: result = obj(*fnargs) except: print("Failed to call object %s: %d, %s" % (obj, len(fnargs), fnargs[1:])) raise else: result = obj(*fnargs, **fnkwds) elif cmd == 'getObjValue': result = opts['obj'] ## has already been unpickled into its local value returnType = 'value' elif cmd == 'transfer': result = opts['obj'] returnType = 'proxy' elif cmd == 'transferArray': ## read array data from next message: result = np.fromstring(byteData[0], dtype=opts['dtype']).reshape(opts['shape']) returnType = 'proxy' elif cmd == 'import': name = opts['module'] fromlist = opts.get('fromlist', []) mod = builtins.__import__(name, fromlist=fromlist) if len(fromlist) == 0: parts = name.lstrip('.').split('.') result = mod for part in parts[1:]: result = getattr(result, part) else: result = map(mod.__getattr__, fromlist) elif cmd == 'del': LocalObjectProxy.releaseProxyId(opts['proxyId']) #del self.proxiedObjects[opts['objId']] elif cmd == 'close': if reqId is not None: result = True returnType = 'value' exc = None except: exc = sys.exc_info() if reqId is not None: if exc is None: self.debugMsg(" handleRequest: sending return value for %d: %s", reqId, result) #print "returnValue:", returnValue, result if returnType == 'auto': with self.optsLock: noProxyTypes = self.proxyOptions['noProxyTypes'] result = self.autoProxy(result, noProxyTypes) elif returnType == 'proxy': result = LocalObjectProxy(result) try: self.replyResult(reqId, result) except: sys.excepthook(*sys.exc_info()) self.replyError(reqId, *sys.exc_info()) else: self.debugMsg(" handleRequest: returning exception for %d", reqId) self.replyError(reqId, *exc) elif exc is not None: sys.excepthook(*exc) if cmd == 'close': if opts.get('noCleanup', False) is True: os._exit(0) ## exit immediately, do not pass GO, do not collect $200. ## (more importantly, do not call any code that would ## normally be invoked at exit) else: raise ClosedError() def replyResult(self, reqId, result): self.send(request='result', reqId=reqId, callSync='off', opts=dict(result=result)) def replyError(self, reqId, *exc): print("error: %s %s %s" % (self.name, str(reqId), str(exc[1]))) excStr = traceback.format_exception(*exc) try: self.send(request='error', reqId=reqId, callSync='off', opts=dict(exception=exc[1], excString=excStr)) except: self.send(request='error', reqId=reqId, callSync='off', opts=dict(exception=None, excString=excStr)) def send(self, request, opts=None, reqId=None, callSync='sync', timeout=10, returnType=None, byteData=None, **kwds): """Send a request or return packet to the remote process. Generally it is not necessary to call this method directly; it is for internal use. (The docstring has information that is nevertheless useful to the programmer as it describes the internal protocol used to communicate between processes) ============== ==================================================================== **Arguments:** request String describing the type of request being sent (see below) reqId Integer uniquely linking a result back to the request that generated it. (most requests leave this blank) callSync 'sync': return the actual result of the request 'async': return a Request object which can be used to look up the result later 'off': return no result timeout Time in seconds to wait for a response when callSync=='sync' opts Extra arguments sent to the remote process that determine the way the request will be handled (see below) returnType 'proxy', 'value', or 'auto' byteData If specified, this is a list of objects to be sent as byte messages to the remote process. This is used to send large arrays without the cost of pickling. ============== ==================================================================== Description of request strings and options allowed for each: ============= ============= ======================================================== request option description ------------- ------------- -------------------------------------------------------- getObjAttr Request the remote process return (proxy to) an attribute of an object. obj reference to object whose attribute should be returned attr string name of attribute to return returnValue bool or 'auto' indicating whether to return a proxy or the actual value. callObj Request the remote process call a function or method. If a request ID is given, then the call's return value will be sent back (or information about the error that occurred while running the function) obj the (reference to) object to call args tuple of arguments to pass to callable kwds dict of keyword arguments to pass to callable returnValue bool or 'auto' indicating whether to return a proxy or the actual value. getObjValue Request the remote process return the value of a proxied object (must be picklable) obj reference to object whose value should be returned transfer Copy an object to the remote process and request it return a proxy for the new object. obj The object to transfer. import Request the remote process import new symbols and return proxy(ies) to the imported objects module the string name of the module to import fromlist optional list of string names to import from module del Inform the remote process that a proxy has been released (thus the remote process may be able to release the original object) proxyId id of proxy which is no longer referenced by remote host close Instruct the remote process to stop its event loop and exit. Optionally, this request may return a confirmation. result Inform the remote process that its request has been processed result return value of a request error Inform the remote process that its request failed exception the Exception that was raised (or None if the exception could not be pickled) excString string-formatted version of the exception and traceback ============= ===================================================================== """ if self.exited: self.debugMsg(' send: exited already; raise ClosedError.') raise ClosedError() with self.sendLock: #if len(kwds) > 0: #print "Warning: send() ignored args:", kwds if opts is None: opts = {} assert callSync in ['off', 'sync', 'async'], 'callSync must be one of "off", "sync", or "async"' if reqId is None: if callSync != 'off': ## requested return value; use the next available request ID reqId = self.nextRequestId self.nextRequestId += 1 else: ## If requestId is provided, this _must_ be a response to a previously received request. assert request in ['result', 'error'] if returnType is not None: opts['returnType'] = returnType #print os.getpid(), "send request:", request, reqId, opts ## double-pickle args to ensure that at least status and request ID get through try: optStr = pickle.dumps(opts) except: print("==== Error pickling this object: ====") print(opts) print("=======================================") raise nByteMsgs = 0 if byteData is not None: nByteMsgs = len(byteData) ## Send primary request request = (request, reqId, nByteMsgs, optStr) self.debugMsg('send request: cmd=%s nByteMsgs=%d id=%s opts=%s', request[0], nByteMsgs, reqId, opts) self.conn.send(request) ## follow up by sending byte messages if byteData is not None: for obj in byteData: ## Remote process _must_ be prepared to read the same number of byte messages! self.conn.send_bytes(obj) self.debugMsg(' sent %d byte messages', len(byteData)) self.debugMsg(' call sync: %s', callSync) if callSync == 'off': return req = Request(self, reqId, description=str(request), timeout=timeout) if callSync == 'async': return req if callSync == 'sync': try: return req.result() except NoResultError: return req def close(self, callSync='off', noCleanup=False, **kwds): try: self.send(request='close', opts=dict(noCleanup=noCleanup), callSync=callSync, **kwds) self.exited = True except ClosedError: pass def getResult(self, reqId): ## raises NoResultError if the result is not available yet #print self.results.keys(), os.getpid() with self.resultLock: haveResult = reqId in self.results if not haveResult: try: self.processRequests() except ClosedError: ## even if remote connection has closed, we may have ## received new data during this call to processRequests() pass with self.resultLock: if reqId not in self.results: raise NoResultError() status, result = self.results.pop(reqId) if status == 'result': return result elif status == 'error': #print ''.join(result) exc, excStr = result if exc is not None: print("===== Remote process raised exception on request: =====") print(''.join(excStr)) print("===== Local Traceback to request follows: =====") raise exc else: print(''.join(excStr)) raise Exception("Error getting result. See above for exception from remote process.") else: raise Exception("Internal error.") def _import(self, mod, **kwds): """ Request the remote process import a module (or symbols from a module) and return the proxied results. Uses built-in __import__() function, but adds a bit more processing: _import('module') => returns module _import('module.submodule') => returns submodule (note this differs from behavior of __import__) _import('module', fromlist=[name1, name2, ...]) => returns [module.name1, module.name2, ...] (this also differs from behavior of __import__) """ return self.send(request='import', callSync='sync', opts=dict(module=mod), **kwds) def getObjAttr(self, obj, attr, **kwds): return self.send(request='getObjAttr', opts=dict(obj=obj, attr=attr), **kwds) def getObjValue(self, obj, **kwds): return self.send(request='getObjValue', opts=dict(obj=obj), **kwds) def callObj(self, obj, args, kwds, **opts): opts = opts.copy() args = list(args) ## Decide whether to send arguments by value or by proxy with self.optsLock: noProxyTypes = opts.pop('noProxyTypes', None) if noProxyTypes is None: noProxyTypes = self.proxyOptions['noProxyTypes'] autoProxy = opts.pop('autoProxy', self.proxyOptions['autoProxy']) if autoProxy is True: args = [self.autoProxy(v, noProxyTypes) for v in args] for k, v in kwds.iteritems(): opts[k] = self.autoProxy(v, noProxyTypes) byteMsgs = [] ## If there are arrays in the arguments, send those as byte messages. ## We do this because pickling arrays is too expensive. for i,arg in enumerate(args): if arg.__class__ == np.ndarray: args[i] = ("__byte_message__", len(byteMsgs), (arg.dtype, arg.shape)) byteMsgs.append(arg) for k,v in kwds.items(): if v.__class__ == np.ndarray: kwds[k] = ("__byte_message__", len(byteMsgs), (v.dtype, v.shape)) byteMsgs.append(v) return self.send(request='callObj', opts=dict(obj=obj, args=args, kwds=kwds), byteData=byteMsgs, **opts) def registerProxy(self, proxy): with self.proxyLock: ref = weakref.ref(proxy, self.deleteProxy) self.proxies[ref] = proxy._proxyId def deleteProxy(self, ref): with self.proxyLock: proxyId = self.proxies.pop(ref) try: self.send(request='del', opts=dict(proxyId=proxyId), callSync='off') except ClosedError: ## if remote process has closed down, there is no need to send delete requests anymore pass def transfer(self, obj, **kwds): """ Transfer an object by value to the remote host (the object must be picklable) and return a proxy for the new remote object. """ if obj.__class__ is np.ndarray: opts = {'dtype': obj.dtype, 'shape': obj.shape} return self.send(request='transferArray', opts=opts, byteData=[obj], **kwds) else: return self.send(request='transfer', opts=dict(obj=obj), **kwds) def autoProxy(self, obj, noProxyTypes): ## Return object wrapped in LocalObjectProxy _unless_ its type is in noProxyTypes. for typ in noProxyTypes: if isinstance(obj, typ): return obj return LocalObjectProxy(obj) class Request(object): """ Request objects are returned when calling an ObjectProxy in asynchronous mode or if a synchronous call has timed out. Use hasResult() to ask whether the result of the call has been returned yet. Use result() to get the returned value. """ def __init__(self, process, reqId, description=None, timeout=10): self.proc = process self.description = description self.reqId = reqId self.gotResult = False self._result = None self.timeout = timeout def result(self, block=True, timeout=None): """ Return the result for this request. If block is True, wait until the result has arrived or *timeout* seconds passes. If the timeout is reached, raise NoResultError. (use timeout=None to disable) If block is False, raise NoResultError immediately if the result has not arrived yet. If the process's connection has closed before the result arrives, raise ClosedError. """ if self.gotResult: return self._result if timeout is None: timeout = self.timeout if block: start = time.time() while not self.hasResult(): if self.proc.exited: raise ClosedError() time.sleep(0.005) if timeout >= 0 and time.time() - start > timeout: print("Request timed out: %s" % self.description) import traceback traceback.print_stack() raise NoResultError() return self._result else: self._result = self.proc.getResult(self.reqId) ## raises NoResultError if result is not available yet self.gotResult = True return self._result def hasResult(self): """Returns True if the result for this request has arrived.""" try: self.result(block=False) except NoResultError: pass return self.gotResult class LocalObjectProxy(object): """ Used for wrapping local objects to ensure that they are send by proxy to a remote host. Note that 'proxy' is just a shorter alias for LocalObjectProxy. For example:: data = [1,2,3,4,5] remotePlot.plot(data) ## by default, lists are pickled and sent by value remotePlot.plot(proxy(data)) ## force the object to be sent by proxy """ nextProxyId = 0 proxiedObjects = {} ## maps {proxyId: object} @classmethod def registerObject(cls, obj): ## assign it a unique ID so we can keep a reference to the local object pid = cls.nextProxyId cls.nextProxyId += 1 cls.proxiedObjects[pid] = obj #print "register:", cls.proxiedObjects return pid @classmethod def lookupProxyId(cls, pid): return cls.proxiedObjects[pid] @classmethod def releaseProxyId(cls, pid): del cls.proxiedObjects[pid] #print "release:", cls.proxiedObjects def __init__(self, obj, **opts): """ Create a 'local' proxy object that, when sent to a remote host, will appear as a normal ObjectProxy to *obj*. Any extra keyword arguments are passed to proxy._setProxyOptions() on the remote side. """ self.processId = os.getpid() #self.objectId = id(obj) self.typeStr = repr(obj) #self.handler = handler self.obj = obj self.opts = opts def __reduce__(self): ## a proxy is being pickled and sent to a remote process. ## every time this happens, a new proxy will be generated in the remote process, ## so we keep a new ID so we can track when each is released. pid = LocalObjectProxy.registerObject(self.obj) return (unpickleObjectProxy, (self.processId, pid, self.typeStr, None, self.opts)) ## alias proxy = LocalObjectProxy def unpickleObjectProxy(processId, proxyId, typeStr, attributes=None, opts=None): if processId == os.getpid(): obj = LocalObjectProxy.lookupProxyId(proxyId) if attributes is not None: for attr in attributes: obj = getattr(obj, attr) return obj else: proxy = ObjectProxy(processId, proxyId=proxyId, typeStr=typeStr) if opts is not None: proxy._setProxyOptions(**opts) return proxy class ObjectProxy(object): """ Proxy to an object stored by the remote process. Proxies are created by calling Process._import(), Process.transfer(), or by requesting/calling attributes on existing proxy objects. For the most part, this object can be used exactly as if it were a local object:: rsys = proc._import('sys') # returns proxy to sys module on remote process rsys.stdout # proxy to remote sys.stdout rsys.stdout.write # proxy to remote sys.stdout.write rsys.stdout.write('hello') # calls sys.stdout.write('hello') on remote machine # and returns the result (None) When calling a proxy to a remote function, the call can be made synchronous (result of call is returned immediately), asynchronous (result is returned later), or return can be disabled entirely:: ros = proc._import('os') ## synchronous call; result is returned immediately pid = ros.getpid() ## asynchronous call request = ros.getpid(_callSync='async') while not request.hasResult(): time.sleep(0.01) pid = request.result() ## disable return when we know it isn't needed rsys.stdout.write('hello', _callSync='off') Additionally, values returned from a remote function call are automatically returned either by value (must be picklable) or by proxy. This behavior can be forced:: rnp = proc._import('numpy') arrProxy = rnp.array([1,2,3,4], _returnType='proxy') arrValue = rnp.array([1,2,3,4], _returnType='value') The default callSync and returnType behaviors (as well as others) can be set for each proxy individually using ObjectProxy._setProxyOptions() or globally using proc.setProxyOptions(). """ def __init__(self, processId, proxyId, typeStr='', parent=None): object.__init__(self) ## can't set attributes directly because setattr is overridden. self.__dict__['_processId'] = processId self.__dict__['_typeStr'] = typeStr self.__dict__['_proxyId'] = proxyId self.__dict__['_attributes'] = () ## attributes that affect the behavior of the proxy. ## in all cases, a value of None causes the proxy to ask ## its parent event handler to make the decision self.__dict__['_proxyOptions'] = { 'callSync': None, ## 'sync', 'async', None 'timeout': None, ## float, None 'returnType': None, ## 'proxy', 'value', 'auto', None 'deferGetattr': None, ## True, False, None 'noProxyTypes': None, ## list of types to send by value instead of by proxy 'autoProxy': None, } self.__dict__['_handler'] = RemoteEventHandler.getHandler(processId) self.__dict__['_handler'].registerProxy(self) ## handler will watch proxy; inform remote process when the proxy is deleted. def _setProxyOptions(self, **kwds): """ Change the behavior of this proxy. For all options, a value of None will cause the proxy to instead use the default behavior defined by its parent Process. Options are: ============= ============================================================= callSync 'sync', 'async', 'off', or None. If 'async', then calling methods will return a Request object which can be used to inquire later about the result of the method call. If 'sync', then calling a method will block until the remote process has returned its result or the timeout has elapsed (in this case, a Request object is returned instead). If 'off', then the remote process is instructed _not_ to reply and the method call will return None immediately. returnType 'auto', 'proxy', 'value', or None. If 'proxy', then the value returned when calling a method will be a proxy to the object on the remote process. If 'value', then attempt to pickle the returned object and send it back. If 'auto', then the decision is made by consulting the 'noProxyTypes' option. autoProxy bool or None. If True, arguments to __call__ are automatically converted to proxy unless their type is listed in noProxyTypes (see below). If False, arguments are left untouched. Use proxy(obj) to manually convert arguments before sending. timeout float or None. Length of time to wait during synchronous requests before returning a Request object instead. deferGetattr True, False, or None. If False, all attribute requests will be sent to the remote process immediately and will block until a response is received (or timeout has elapsed). If True, requesting an attribute from the proxy returns a new proxy immediately. The remote process is _not_ contacted to make this request. This is faster, but it is possible to request an attribute that does not exist on the proxied object. In this case, AttributeError will not be raised until an attempt is made to look up the attribute on the remote process. noProxyTypes List of object types that should _not_ be proxied when sent to the remote process. ============= ============================================================= """ for k in kwds: if k not in self._proxyOptions: raise KeyError("Unrecognized proxy option '%s'" % k) self._proxyOptions.update(kwds) def _getValue(self): """ Return the value of the proxied object (the remote object must be picklable) """ return self._handler.getObjValue(self) def _getProxyOption(self, opt): val = self._proxyOptions[opt] if val is None: return self._handler.getProxyOption(opt) return val def _getProxyOptions(self): return dict([(k, self._getProxyOption(k)) for k in self._proxyOptions]) def __reduce__(self): return (unpickleObjectProxy, (self._processId, self._proxyId, self._typeStr, self._attributes)) def __repr__(self): #objRepr = self.__getattr__('__repr__')(callSync='value') return "" % (self._processId, self._proxyId, self._typeStr) def __getattr__(self, attr, **kwds): """ Calls __getattr__ on the remote object and returns the attribute by value or by proxy depending on the options set (see ObjectProxy._setProxyOptions and RemoteEventHandler.setProxyOptions) If the option 'deferGetattr' is True for this proxy, then a new proxy object is returned _without_ asking the remote object whether the named attribute exists. This can save time when making multiple chained attribute requests, but may also defer a possible AttributeError until later, making them more difficult to debug. """ opts = self._getProxyOptions() for k in opts: if '_'+k in kwds: opts[k] = kwds.pop('_'+k) if opts['deferGetattr'] is True: return self._deferredAttr(attr) else: #opts = self._getProxyOptions() return self._handler.getObjAttr(self, attr, **opts) def _deferredAttr(self, attr): return DeferredObjectProxy(self, attr) def __call__(self, *args, **kwds): """ Attempts to call the proxied object from the remote process. Accepts extra keyword arguments: _callSync 'off', 'sync', or 'async' _returnType 'value', 'proxy', or 'auto' If the remote call raises an exception on the remote process, it will be re-raised on the local process. """ opts = self._getProxyOptions() for k in opts: if '_'+k in kwds: opts[k] = kwds.pop('_'+k) return self._handler.callObj(obj=self, args=args, kwds=kwds, **opts) ## Explicitly proxy special methods. Is there a better way to do this?? def _getSpecialAttr(self, attr): ## this just gives us an easy way to change the behavior of the special methods return self._deferredAttr(attr) def __getitem__(self, *args): return self._getSpecialAttr('__getitem__')(*args) def __setitem__(self, *args): return self._getSpecialAttr('__setitem__')(*args, _callSync='off') def __setattr__(self, *args): return self._getSpecialAttr('__setattr__')(*args, _callSync='off') def __str__(self, *args): return self._getSpecialAttr('__str__')(*args, _returnType='value') def __len__(self, *args): return self._getSpecialAttr('__len__')(*args) def __add__(self, *args): return self._getSpecialAttr('__add__')(*args) def __sub__(self, *args): return self._getSpecialAttr('__sub__')(*args) def __div__(self, *args): return self._getSpecialAttr('__div__')(*args) def __truediv__(self, *args): return self._getSpecialAttr('__truediv__')(*args) def __floordiv__(self, *args): return self._getSpecialAttr('__floordiv__')(*args) def __mul__(self, *args): return self._getSpecialAttr('__mul__')(*args) def __pow__(self, *args): return self._getSpecialAttr('__pow__')(*args) def __iadd__(self, *args): return self._getSpecialAttr('__iadd__')(*args, _callSync='off') def __isub__(self, *args): return self._getSpecialAttr('__isub__')(*args, _callSync='off') def __idiv__(self, *args): return self._getSpecialAttr('__idiv__')(*args, _callSync='off') def __itruediv__(self, *args): return self._getSpecialAttr('__itruediv__')(*args, _callSync='off') def __ifloordiv__(self, *args): return self._getSpecialAttr('__ifloordiv__')(*args, _callSync='off') def __imul__(self, *args): return self._getSpecialAttr('__imul__')(*args, _callSync='off') def __ipow__(self, *args): return self._getSpecialAttr('__ipow__')(*args, _callSync='off') def __rshift__(self, *args): return self._getSpecialAttr('__rshift__')(*args) def __lshift__(self, *args): return self._getSpecialAttr('__lshift__')(*args) def __irshift__(self, *args): return self._getSpecialAttr('__irshift__')(*args, _callSync='off') def __ilshift__(self, *args): return self._getSpecialAttr('__ilshift__')(*args, _callSync='off') def __eq__(self, *args): return self._getSpecialAttr('__eq__')(*args) def __ne__(self, *args): return self._getSpecialAttr('__ne__')(*args) def __lt__(self, *args): return self._getSpecialAttr('__lt__')(*args) def __gt__(self, *args): return self._getSpecialAttr('__gt__')(*args) def __le__(self, *args): return self._getSpecialAttr('__le__')(*args) def __ge__(self, *args): return self._getSpecialAttr('__ge__')(*args) def __and__(self, *args): return self._getSpecialAttr('__and__')(*args) def __or__(self, *args): return self._getSpecialAttr('__or__')(*args) def __xor__(self, *args): return self._getSpecialAttr('__xor__')(*args) def __iand__(self, *args): return self._getSpecialAttr('__iand__')(*args, _callSync='off') def __ior__(self, *args): return self._getSpecialAttr('__ior__')(*args, _callSync='off') def __ixor__(self, *args): return self._getSpecialAttr('__ixor__')(*args, _callSync='off') def __mod__(self, *args): return self._getSpecialAttr('__mod__')(*args) def __radd__(self, *args): return self._getSpecialAttr('__radd__')(*args) def __rsub__(self, *args): return self._getSpecialAttr('__rsub__')(*args) def __rdiv__(self, *args): return self._getSpecialAttr('__rdiv__')(*args) def __rfloordiv__(self, *args): return self._getSpecialAttr('__rfloordiv__')(*args) def __rtruediv__(self, *args): return self._getSpecialAttr('__rtruediv__')(*args) def __rmul__(self, *args): return self._getSpecialAttr('__rmul__')(*args) def __rpow__(self, *args): return self._getSpecialAttr('__rpow__')(*args) def __rrshift__(self, *args): return self._getSpecialAttr('__rrshift__')(*args) def __rlshift__(self, *args): return self._getSpecialAttr('__rlshift__')(*args) def __rand__(self, *args): return self._getSpecialAttr('__rand__')(*args) def __ror__(self, *args): return self._getSpecialAttr('__ror__')(*args) def __rxor__(self, *args): return self._getSpecialAttr('__ror__')(*args) def __rmod__(self, *args): return self._getSpecialAttr('__rmod__')(*args) def __hash__(self): ## Required for python3 since __eq__ is defined. return id(self) class DeferredObjectProxy(ObjectProxy): """ This class represents an attribute (or sub-attribute) of a proxied object. It is used to speed up attribute requests. Take the following scenario:: rsys = proc._import('sys') rsys.stdout.write('hello') For this simple example, a total of 4 synchronous requests are made to the remote process: 1) import sys 2) getattr(sys, 'stdout') 3) getattr(stdout, 'write') 4) write('hello') This takes a lot longer than running the equivalent code locally. To speed things up, we can 'defer' the two attribute lookups so they are only carried out when neccessary:: rsys = proc._import('sys') rsys._setProxyOptions(deferGetattr=True) rsys.stdout.write('hello') This example only makes two requests to the remote process; the two attribute lookups immediately return DeferredObjectProxy instances immediately without contacting the remote process. When the call to write() is made, all attribute requests are processed at the same time. Note that if the attributes requested do not exist on the remote object, making the call to write() will raise an AttributeError. """ def __init__(self, parentProxy, attribute): ## can't set attributes directly because setattr is overridden. for k in ['_processId', '_typeStr', '_proxyId', '_handler']: self.__dict__[k] = getattr(parentProxy, k) self.__dict__['_parent'] = parentProxy ## make sure parent stays alive self.__dict__['_attributes'] = parentProxy._attributes + (attribute,) self.__dict__['_proxyOptions'] = parentProxy._proxyOptions.copy() def __repr__(self): return ObjectProxy.__repr__(self) + '.' + '.'.join(self._attributes) def _undefer(self): """ Return a non-deferred ObjectProxy referencing the same object """ return self._parent.__getattr__(self._attributes[-1], _deferGetattr=False) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/numpy_fix.py000066400000000000000000000015341300727121400222330ustar00rootroot00000000000000try: import numpy as np ## Wrap np.concatenate to catch and avoid a segmentation fault bug ## (numpy trac issue #2084) if not hasattr(np, 'concatenate_orig'): np.concatenate_orig = np.concatenate def concatenate(vals, *args, **kwds): """Wrapper around numpy.concatenate (see pyqtgraph/numpy_fix.py)""" dtypes = [getattr(v, 'dtype', None) for v in vals] names = [getattr(dt, 'names', None) for dt in dtypes] if len(dtypes) < 2 or all([n is None for n in names]): return np.concatenate_orig(vals, *args, **kwds) if any([dt != dtypes[0] for dt in dtypes[1:]]): raise TypeError("Cannot concatenate structured arrays of different dtype.") return np.concatenate_orig(vals, *args, **kwds) np.concatenate = concatenate except ImportError: pass pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/opengl/000077500000000000000000000000001300727121400211245ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/opengl/GLGraphicsItem.py000066400000000000000000000235521300727121400243070ustar00rootroot00000000000000from OpenGL.GL import * from OpenGL import GL from ..Qt import QtGui, QtCore from .. import Transform3D from ..python2_3 import basestring GLOptions = { 'opaque': { GL_DEPTH_TEST: True, GL_BLEND: False, GL_ALPHA_TEST: False, GL_CULL_FACE: False, }, 'translucent': { GL_DEPTH_TEST: True, GL_BLEND: True, GL_ALPHA_TEST: False, GL_CULL_FACE: False, 'glBlendFunc': (GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA), }, 'additive': { GL_DEPTH_TEST: False, GL_BLEND: True, GL_ALPHA_TEST: False, GL_CULL_FACE: False, 'glBlendFunc': (GL_SRC_ALPHA, GL_ONE), }, } class GLGraphicsItem(QtCore.QObject): _nextId = 0 def __init__(self, parentItem=None): QtCore.QObject.__init__(self) self._id = GLGraphicsItem._nextId GLGraphicsItem._nextId += 1 self.__parent = None self.__view = None self.__children = set() self.__transform = Transform3D() self.__visible = True self.setParentItem(parentItem) self.setDepthValue(0) self.__glOpts = {} def setParentItem(self, item): """Set this item's parent in the scenegraph hierarchy.""" if self.__parent is not None: self.__parent.__children.remove(self) if item is not None: item.__children.add(self) self.__parent = item if self.__parent is not None and self.view() is not self.__parent.view(): if self.view() is not None: self.view().removeItem(self) self.__parent.view().addItem(self) def setGLOptions(self, opts): """ Set the OpenGL state options to use immediately before drawing this item. (Note that subclasses must call setupGLState before painting for this to work) The simplest way to invoke this method is to pass in the name of a predefined set of options (see the GLOptions variable): ============= ====================================================== opaque Enables depth testing and disables blending translucent Enables depth testing and blending Elements must be drawn sorted back-to-front for translucency to work correctly. additive Disables depth testing, enables blending. Colors are added together, so sorting is not required. ============= ====================================================== It is also possible to specify any arbitrary settings as a dictionary. This may consist of {'functionName': (args...)} pairs where functionName must be a callable attribute of OpenGL.GL, or {GL_STATE_VAR: bool} pairs which will be interpreted as calls to glEnable or glDisable(GL_STATE_VAR). For example:: { GL_ALPHA_TEST: True, GL_CULL_FACE: False, 'glBlendFunc': (GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA), } """ if isinstance(opts, basestring): opts = GLOptions[opts] self.__glOpts = opts.copy() self.update() def updateGLOptions(self, opts): """ Modify the OpenGL state options to use immediately before drawing this item. *opts* must be a dictionary as specified by setGLOptions. Values may also be None, in which case the key will be ignored. """ self.__glOpts.update(opts) def parentItem(self): """Return a this item's parent in the scenegraph hierarchy.""" return self.__parent def childItems(self): """Return a list of this item's children in the scenegraph hierarchy.""" return list(self.__children) def _setView(self, v): self.__view = v def view(self): return self.__view def setDepthValue(self, value): """ Sets the depth value of this item. Default is 0. This controls the order in which items are drawn--those with a greater depth value will be drawn later. Items with negative depth values are drawn before their parent. (This is analogous to QGraphicsItem.zValue) The depthValue does NOT affect the position of the item or the values it imparts to the GL depth buffer. """ self.__depthValue = value def depthValue(self): """Return the depth value of this item. See setDepthValue for more information.""" return self.__depthValue def setTransform(self, tr): """Set the local transform for this object. Must be a :class:`Transform3D ` instance. This transform determines how the local coordinate system of the item is mapped to the coordinate system of its parent.""" self.__transform = Transform3D(tr) self.update() def resetTransform(self): """Reset this item's transform to an identity transformation.""" self.__transform.setToIdentity() self.update() def applyTransform(self, tr, local): """ Multiply this object's transform by *tr*. If local is True, then *tr* is multiplied on the right of the current transform:: newTransform = transform * tr If local is False, then *tr* is instead multiplied on the left:: newTransform = tr * transform """ if local: self.setTransform(self.transform() * tr) else: self.setTransform(tr * self.transform()) def transform(self): """Return this item's transform object.""" return self.__transform def viewTransform(self): """Return the transform mapping this item's local coordinate system to the view coordinate system.""" tr = self.__transform p = self while True: p = p.parentItem() if p is None: break tr = p.transform() * tr return Transform3D(tr) def translate(self, dx, dy, dz, local=False): """ Translate the object by (*dx*, *dy*, *dz*) in its parent's coordinate system. If *local* is True, then translation takes place in local coordinates. """ tr = Transform3D() tr.translate(dx, dy, dz) self.applyTransform(tr, local=local) def rotate(self, angle, x, y, z, local=False): """ Rotate the object around the axis specified by (x,y,z). *angle* is in degrees. """ tr = Transform3D() tr.rotate(angle, x, y, z) self.applyTransform(tr, local=local) def scale(self, x, y, z, local=True): """ Scale the object by (*dx*, *dy*, *dz*) in its local coordinate system. If *local* is False, then scale takes place in the parent's coordinates. """ tr = Transform3D() tr.scale(x, y, z) self.applyTransform(tr, local=local) def hide(self): """Hide this item. This is equivalent to setVisible(False).""" self.setVisible(False) def show(self): """Make this item visible if it was previously hidden. This is equivalent to setVisible(True).""" self.setVisible(True) def setVisible(self, vis): """Set the visibility of this item.""" self.__visible = vis self.update() def visible(self): """Return True if the item is currently set to be visible. Note that this does not guarantee that the item actually appears in the view, as it may be obscured or outside of the current view area.""" return self.__visible def initializeGL(self): """ Called after an item is added to a GLViewWidget. The widget's GL context is made current before this method is called. (So this would be an appropriate time to generate lists, upload textures, etc.) """ pass def setupGLState(self): """ This method is responsible for preparing the GL state options needed to render this item (blending, depth testing, etc). The method is called immediately before painting the item. """ for k,v in self.__glOpts.items(): if v is None: continue if isinstance(k, basestring): func = getattr(GL, k) func(*v) else: if v is True: glEnable(k) else: glDisable(k) def paint(self): """ Called by the GLViewWidget to draw this item. It is the responsibility of the item to set up its own modelview matrix, but the caller will take care of pushing/popping. """ self.setupGLState() def update(self): """ Indicates that this item needs to be redrawn, and schedules an update with the view it is displayed in. """ v = self.view() if v is None: return v.update() def mapToParent(self, point): tr = self.transform() if tr is None: return point return tr.map(point) def mapFromParent(self, point): tr = self.transform() if tr is None: return point return tr.inverted()[0].map(point) def mapToView(self, point): tr = self.viewTransform() if tr is None: return point return tr.map(point) def mapFromView(self, point): tr = self.viewTransform() if tr is None: return point return tr.inverted()[0].map(point) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/opengl/GLViewWidget.py000066400000000000000000000433631300727121400240100ustar00rootroot00000000000000from ..Qt import QtCore, QtGui, QtOpenGL, USE_PYQT5 from OpenGL.GL import * import OpenGL.GL.framebufferobjects as glfbo import numpy as np from .. import Vector from .. import functions as fn ##Vector = QtGui.QVector3D ShareWidget = None class GLViewWidget(QtOpenGL.QGLWidget): """ Basic widget for displaying 3D data - Rotation/scale controls - Axis/grid display - Export options """ def __init__(self, parent=None): global ShareWidget if ShareWidget is None: ## create a dummy widget to allow sharing objects (textures, shaders, etc) between views ShareWidget = QtOpenGL.QGLWidget() QtOpenGL.QGLWidget.__init__(self, parent, ShareWidget) self.setFocusPolicy(QtCore.Qt.ClickFocus) self.opts = { 'center': Vector(0,0,0), ## will always appear at the center of the widget 'distance': 10.0, ## distance of camera from center 'fov': 60, ## horizontal field of view in degrees 'elevation': 30, ## camera's angle of elevation in degrees 'azimuth': 45, ## camera's azimuthal angle in degrees ## (rotation around z-axis 0 points along x-axis) 'viewport': None, ## glViewport params; None == whole widget } self.setBackgroundColor('k') self.items = [] self.noRepeatKeys = [QtCore.Qt.Key_Right, QtCore.Qt.Key_Left, QtCore.Qt.Key_Up, QtCore.Qt.Key_Down, QtCore.Qt.Key_PageUp, QtCore.Qt.Key_PageDown] self.keysPressed = {} self.keyTimer = QtCore.QTimer() self.keyTimer.timeout.connect(self.evalKeyState) self.makeCurrent() def addItem(self, item): self.items.append(item) if hasattr(item, 'initializeGL'): self.makeCurrent() try: item.initializeGL() except: self.checkOpenGLVersion('Error while adding item %s to GLViewWidget.' % str(item)) item._setView(self) #print "set view", item, self, item.view() self.update() def removeItem(self, item): self.items.remove(item) item._setView(None) self.update() def initializeGL(self): self.resizeGL(self.width(), self.height()) def setBackgroundColor(self, *args, **kwds): """ Set the background color of the widget. Accepts the same arguments as pg.mkColor() and pg.glColor(). """ self.opts['bgcolor'] = fn.glColor(*args, **kwds) self.update() def getViewport(self): vp = self.opts['viewport'] if vp is None: return (0, 0, self.width(), self.height()) else: return vp def resizeGL(self, w, h): pass #glViewport(*self.getViewport()) #self.update() def setProjection(self, region=None): m = self.projectionMatrix(region) glMatrixMode(GL_PROJECTION) glLoadIdentity() a = np.array(m.copyDataTo()).reshape((4,4)) glMultMatrixf(a.transpose()) def projectionMatrix(self, region=None): # Xw = (Xnd + 1) * width/2 + X if region is None: region = (0, 0, self.width(), self.height()) x0, y0, w, h = self.getViewport() dist = self.opts['distance'] fov = self.opts['fov'] nearClip = dist * 0.001 farClip = dist * 1000. r = nearClip * np.tan(fov * 0.5 * np.pi / 180.) t = r * h / w # convert screen coordinates (region) to normalized device coordinates # Xnd = (Xw - X0) * 2/width - 1 ## Note that X0 and width in these equations must be the values used in viewport left = r * ((region[0]-x0) * (2.0/w) - 1) right = r * ((region[0]+region[2]-x0) * (2.0/w) - 1) bottom = t * ((region[1]-y0) * (2.0/h) - 1) top = t * ((region[1]+region[3]-y0) * (2.0/h) - 1) tr = QtGui.QMatrix4x4() tr.frustum(left, right, bottom, top, nearClip, farClip) return tr def setModelview(self): glMatrixMode(GL_MODELVIEW) glLoadIdentity() m = self.viewMatrix() a = np.array(m.copyDataTo()).reshape((4,4)) glMultMatrixf(a.transpose()) def viewMatrix(self): tr = QtGui.QMatrix4x4() tr.translate( 0.0, 0.0, -self.opts['distance']) tr.rotate(self.opts['elevation']-90, 1, 0, 0) tr.rotate(self.opts['azimuth']+90, 0, 0, -1) center = self.opts['center'] tr.translate(-center.x(), -center.y(), -center.z()) return tr def itemsAt(self, region=None): """ Return a list of the items displayed in the region (x, y, w, h) relative to the widget. """ region = (region[0], self.height()-(region[1]+region[3]), region[2], region[3]) #buf = np.zeros(100000, dtype=np.uint) buf = glSelectBuffer(100000) try: glRenderMode(GL_SELECT) glInitNames() glPushName(0) self._itemNames = {} self.paintGL(region=region, useItemNames=True) finally: hits = glRenderMode(GL_RENDER) items = [(h.near, h.names[0]) for h in hits] items.sort(key=lambda i: i[0]) return [self._itemNames[i[1]] for i in items] def paintGL(self, region=None, viewport=None, useItemNames=False): """ viewport specifies the arguments to glViewport. If None, then we use self.opts['viewport'] region specifies the sub-region of self.opts['viewport'] that should be rendered. Note that we may use viewport != self.opts['viewport'] when exporting. """ if viewport is None: glViewport(*self.getViewport()) else: glViewport(*viewport) self.setProjection(region=region) self.setModelview() bgcolor = self.opts['bgcolor'] glClearColor(*bgcolor) glClear( GL_DEPTH_BUFFER_BIT | GL_COLOR_BUFFER_BIT ) self.drawItemTree(useItemNames=useItemNames) def drawItemTree(self, item=None, useItemNames=False): if item is None: items = [x for x in self.items if x.parentItem() is None] else: items = item.childItems() items.append(item) items.sort(key=lambda a: a.depthValue()) for i in items: if not i.visible(): continue if i is item: try: glPushAttrib(GL_ALL_ATTRIB_BITS) if useItemNames: glLoadName(i._id) self._itemNames[i._id] = i i.paint() except: from .. import debug debug.printExc() msg = "Error while drawing item %s." % str(item) ver = glGetString(GL_VERSION) if ver is not None: ver = ver.split()[0] if int(ver.split(b'.')[0]) < 2: print(msg + " The original exception is printed above; however, pyqtgraph requires OpenGL version 2.0 or greater for many of its 3D features and your OpenGL version is %s. Installing updated display drivers may resolve this issue." % ver) else: print(msg) finally: glPopAttrib() else: glMatrixMode(GL_MODELVIEW) glPushMatrix() try: tr = i.transform() a = np.array(tr.copyDataTo()).reshape((4,4)) glMultMatrixf(a.transpose()) self.drawItemTree(i, useItemNames=useItemNames) finally: glMatrixMode(GL_MODELVIEW) glPopMatrix() def setCameraPosition(self, pos=None, distance=None, elevation=None, azimuth=None): if distance is not None: self.opts['distance'] = distance if elevation is not None: self.opts['elevation'] = elevation if azimuth is not None: self.opts['azimuth'] = azimuth self.update() def cameraPosition(self): """Return current position of camera based on center, dist, elevation, and azimuth""" center = self.opts['center'] dist = self.opts['distance'] elev = self.opts['elevation'] * np.pi/180. azim = self.opts['azimuth'] * np.pi/180. pos = Vector( center.x() + dist * np.cos(elev) * np.cos(azim), center.y() + dist * np.cos(elev) * np.sin(azim), center.z() + dist * np.sin(elev) ) return pos def orbit(self, azim, elev): """Orbits the camera around the center position. *azim* and *elev* are given in degrees.""" self.opts['azimuth'] += azim #self.opts['elevation'] += elev self.opts['elevation'] = np.clip(self.opts['elevation'] + elev, -90, 90) self.update() def pan(self, dx, dy, dz, relative=False): """ Moves the center (look-at) position while holding the camera in place. If relative=True, then the coordinates are interpreted such that x if in the global xy plane and points to the right side of the view, y is in the global xy plane and orthogonal to x, and z points in the global z direction. Distances are scaled roughly such that a value of 1.0 moves by one pixel on screen. """ if not relative: self.opts['center'] += QtGui.QVector3D(dx, dy, dz) else: cPos = self.cameraPosition() cVec = self.opts['center'] - cPos dist = cVec.length() ## distance from camera to center xDist = dist * 2. * np.tan(0.5 * self.opts['fov'] * np.pi / 180.) ## approx. width of view at distance of center point xScale = xDist / self.width() zVec = QtGui.QVector3D(0,0,1) xVec = QtGui.QVector3D.crossProduct(zVec, cVec).normalized() yVec = QtGui.QVector3D.crossProduct(xVec, zVec).normalized() self.opts['center'] = self.opts['center'] + xVec * xScale * dx + yVec * xScale * dy + zVec * xScale * dz self.update() def pixelSize(self, pos): """ Return the approximate size of a screen pixel at the location pos Pos may be a Vector or an (N,3) array of locations """ cam = self.cameraPosition() if isinstance(pos, np.ndarray): cam = np.array(cam).reshape((1,)*(pos.ndim-1)+(3,)) dist = ((pos-cam)**2).sum(axis=-1)**0.5 else: dist = (pos-cam).length() xDist = dist * 2. * np.tan(0.5 * self.opts['fov'] * np.pi / 180.) return xDist / self.width() def mousePressEvent(self, ev): self.mousePos = ev.pos() def mouseMoveEvent(self, ev): diff = ev.pos() - self.mousePos self.mousePos = ev.pos() if ev.buttons() == QtCore.Qt.LeftButton: self.orbit(-diff.x(), diff.y()) #print self.opts['azimuth'], self.opts['elevation'] elif ev.buttons() == QtCore.Qt.MidButton: if (ev.modifiers() & QtCore.Qt.ControlModifier): self.pan(diff.x(), 0, diff.y(), relative=True) else: self.pan(diff.x(), diff.y(), 0, relative=True) def mouseReleaseEvent(self, ev): pass # Example item selection code: #region = (ev.pos().x()-5, ev.pos().y()-5, 10, 10) #print(self.itemsAt(region)) ## debugging code: draw the picking region #glViewport(*self.getViewport()) #glClear( GL_DEPTH_BUFFER_BIT | GL_COLOR_BUFFER_BIT ) #region = (region[0], self.height()-(region[1]+region[3]), region[2], region[3]) #self.paintGL(region=region) #self.swapBuffers() def wheelEvent(self, ev): delta = 0 if not USE_PYQT5: delta = ev.delta() else: delta = ev.angleDelta().x() if delta == 0: delta = ev.angleDelta().y() if (ev.modifiers() & QtCore.Qt.ControlModifier): self.opts['fov'] *= 0.999**delta else: self.opts['distance'] *= 0.999**delta self.update() def keyPressEvent(self, ev): if ev.key() in self.noRepeatKeys: ev.accept() if ev.isAutoRepeat(): return self.keysPressed[ev.key()] = 1 self.evalKeyState() def keyReleaseEvent(self, ev): if ev.key() in self.noRepeatKeys: ev.accept() if ev.isAutoRepeat(): return try: del self.keysPressed[ev.key()] except: self.keysPressed = {} self.evalKeyState() def evalKeyState(self): speed = 2.0 if len(self.keysPressed) > 0: for key in self.keysPressed: if key == QtCore.Qt.Key_Right: self.orbit(azim=-speed, elev=0) elif key == QtCore.Qt.Key_Left: self.orbit(azim=speed, elev=0) elif key == QtCore.Qt.Key_Up: self.orbit(azim=0, elev=-speed) elif key == QtCore.Qt.Key_Down: self.orbit(azim=0, elev=speed) elif key == QtCore.Qt.Key_PageUp: pass elif key == QtCore.Qt.Key_PageDown: pass self.keyTimer.start(16) else: self.keyTimer.stop() def checkOpenGLVersion(self, msg): ## Only to be called from within exception handler. ver = glGetString(GL_VERSION).split()[0] if int(ver.split('.')[0]) < 2: from .. import debug pyqtgraph.debug.printExc() raise Exception(msg + " The original exception is printed above; however, pyqtgraph requires OpenGL version 2.0 or greater for many of its 3D features and your OpenGL version is %s. Installing updated display drivers may resolve this issue." % ver) else: raise def readQImage(self): """ Read the current buffer pixels out as a QImage. """ w = self.width() h = self.height() self.repaint() pixels = np.empty((h, w, 4), dtype=np.ubyte) pixels[:] = 128 pixels[...,0] = 50 pixels[...,3] = 255 glReadPixels(0, 0, w, h, GL_RGBA, GL_UNSIGNED_BYTE, pixels) # swap B,R channels for Qt tmp = pixels[...,0].copy() pixels[...,0] = pixels[...,2] pixels[...,2] = tmp pixels = pixels[::-1] # flip vertical img = fn.makeQImage(pixels, transpose=False) return img def renderToArray(self, size, format=GL_BGRA, type=GL_UNSIGNED_BYTE, textureSize=1024, padding=256): w,h = map(int, size) self.makeCurrent() tex = None fb = None try: output = np.empty((w, h, 4), dtype=np.ubyte) fb = glfbo.glGenFramebuffers(1) glfbo.glBindFramebuffer(glfbo.GL_FRAMEBUFFER, fb ) glEnable(GL_TEXTURE_2D) tex = glGenTextures(1) glBindTexture(GL_TEXTURE_2D, tex) texwidth = textureSize data = np.zeros((texwidth,texwidth,4), dtype=np.ubyte) ## Test texture dimensions first glTexImage2D(GL_PROXY_TEXTURE_2D, 0, GL_RGBA, texwidth, texwidth, 0, GL_RGBA, GL_UNSIGNED_BYTE, None) if glGetTexLevelParameteriv(GL_PROXY_TEXTURE_2D, 0, GL_TEXTURE_WIDTH) == 0: raise Exception("OpenGL failed to create 2D texture (%dx%d); too large for this hardware." % shape[:2]) ## create teture glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA, texwidth, texwidth, 0, GL_RGBA, GL_UNSIGNED_BYTE, data.transpose((1,0,2))) self.opts['viewport'] = (0, 0, w, h) # viewport is the complete image; this ensures that paintGL(region=...) # is interpreted correctly. p2 = 2 * padding for x in range(-padding, w-padding, texwidth-p2): for y in range(-padding, h-padding, texwidth-p2): x2 = min(x+texwidth, w+padding) y2 = min(y+texwidth, h+padding) w2 = x2-x h2 = y2-y ## render to texture glfbo.glFramebufferTexture2D(glfbo.GL_FRAMEBUFFER, glfbo.GL_COLOR_ATTACHMENT0, GL_TEXTURE_2D, tex, 0) self.paintGL(region=(x, h-y-h2, w2, h2), viewport=(0, 0, w2, h2)) # only render sub-region ## read texture back to array data = glGetTexImage(GL_TEXTURE_2D, 0, format, type) data = np.fromstring(data, dtype=np.ubyte).reshape(texwidth,texwidth,4).transpose(1,0,2)[:, ::-1] output[x+padding:x2-padding, y+padding:y2-padding] = data[padding:w2-padding, -(h2-padding):-padding] finally: self.opts['viewport'] = None glfbo.glBindFramebuffer(glfbo.GL_FRAMEBUFFER, 0) glBindTexture(GL_TEXTURE_2D, 0) if tex is not None: glDeleteTextures([tex]) if fb is not None: glfbo.glDeleteFramebuffers([fb]) return output pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/opengl/MeshData.py000066400000000000000000000532531300727121400231740ustar00rootroot00000000000000import numpy as np from ..Qt import QtGui from .. import functions as fn from ..python2_3 import xrange class MeshData(object): """ Class for storing and operating on 3D mesh data. May contain: - list of vertex locations - list of edges - list of triangles - colors per vertex, edge, or tri - normals per vertex or tri This class handles conversion between the standard [list of vertexes, list of faces] format (suitable for use with glDrawElements) and 'indexed' [list of vertexes] format (suitable for use with glDrawArrays). It will automatically compute face normal vectors as well as averaged vertex normal vectors. The class attempts to be as efficient as possible in caching conversion results and avoiding unnecessary conversions. """ def __init__(self, vertexes=None, faces=None, edges=None, vertexColors=None, faceColors=None): """ ============== ===================================================== **Arguments:** vertexes (Nv, 3) array of vertex coordinates. If faces is not specified, then this will instead be interpreted as (Nf, 3, 3) array of coordinates. faces (Nf, 3) array of indexes into the vertex array. edges [not available yet] vertexColors (Nv, 4) array of vertex colors. If faces is not specified, then this will instead be interpreted as (Nf, 3, 4) array of colors. faceColors (Nf, 4) array of face colors. ============== ===================================================== All arguments are optional. """ self._vertexes = None # (Nv,3) array of vertex coordinates self._vertexesIndexedByFaces = None # (Nf, 3, 3) array of vertex coordinates self._vertexesIndexedByEdges = None # (Ne, 2, 3) array of vertex coordinates ## mappings between vertexes, faces, and edges self._faces = None # Nx3 array of indexes into self._vertexes specifying three vertexes for each face self._edges = None # Nx2 array of indexes into self._vertexes specifying two vertexes per edge self._vertexFaces = None ## maps vertex ID to a list of face IDs (inverse mapping of _faces) self._vertexEdges = None ## maps vertex ID to a list of edge IDs (inverse mapping of _edges) ## Per-vertex data self._vertexNormals = None # (Nv, 3) array of normals, one per vertex self._vertexNormalsIndexedByFaces = None # (Nf, 3, 3) array of normals self._vertexColors = None # (Nv, 3) array of colors self._vertexColorsIndexedByFaces = None # (Nf, 3, 4) array of colors self._vertexColorsIndexedByEdges = None # (Nf, 2, 4) array of colors ## Per-face data self._faceNormals = None # (Nf, 3) array of face normals self._faceNormalsIndexedByFaces = None # (Nf, 3, 3) array of face normals self._faceColors = None # (Nf, 4) array of face colors self._faceColorsIndexedByFaces = None # (Nf, 3, 4) array of face colors self._faceColorsIndexedByEdges = None # (Ne, 2, 4) array of face colors ## Per-edge data self._edgeColors = None # (Ne, 4) array of edge colors self._edgeColorsIndexedByEdges = None # (Ne, 2, 4) array of edge colors #self._meshColor = (1, 1, 1, 0.1) # default color to use if no face/edge/vertex colors are given if vertexes is not None: if faces is None: self.setVertexes(vertexes, indexed='faces') if vertexColors is not None: self.setVertexColors(vertexColors, indexed='faces') if faceColors is not None: self.setFaceColors(faceColors, indexed='faces') else: self.setVertexes(vertexes) self.setFaces(faces) if vertexColors is not None: self.setVertexColors(vertexColors) if faceColors is not None: self.setFaceColors(faceColors) def faces(self): """Return an array (Nf, 3) of vertex indexes, three per triangular face in the mesh. If faces have not been computed for this mesh, the function returns None. """ return self._faces def edges(self): """Return an array (Nf, 3) of vertex indexes, two per edge in the mesh.""" if self._edges is None: self._computeEdges() return self._edges def setFaces(self, faces): """Set the (Nf, 3) array of faces. Each rown in the array contains three indexes into the vertex array, specifying the three corners of a triangular face.""" self._faces = faces self._edges = None self._vertexFaces = None self._vertexesIndexedByFaces = None self.resetNormals() self._vertexColorsIndexedByFaces = None self._faceColorsIndexedByFaces = None def vertexes(self, indexed=None): """Return an array (N,3) of the positions of vertexes in the mesh. By default, each unique vertex appears only once in the array. If indexed is 'faces', then the array will instead contain three vertexes per face in the mesh (and a single vertex may appear more than once in the array).""" if indexed is None: if self._vertexes is None and self._vertexesIndexedByFaces is not None: self._computeUnindexedVertexes() return self._vertexes elif indexed == 'faces': if self._vertexesIndexedByFaces is None and self._vertexes is not None: self._vertexesIndexedByFaces = self._vertexes[self.faces()] return self._vertexesIndexedByFaces else: raise Exception("Invalid indexing mode. Accepts: None, 'faces'") def setVertexes(self, verts=None, indexed=None, resetNormals=True): """ Set the array (Nv, 3) of vertex coordinates. If indexed=='faces', then the data must have shape (Nf, 3, 3) and is assumed to be already indexed as a list of faces. This will cause any pre-existing normal vectors to be cleared unless resetNormals=False. """ if indexed is None: if verts is not None: self._vertexes = verts self._vertexesIndexedByFaces = None elif indexed=='faces': self._vertexes = None if verts is not None: self._vertexesIndexedByFaces = verts else: raise Exception("Invalid indexing mode. Accepts: None, 'faces'") if resetNormals: self.resetNormals() def resetNormals(self): self._vertexNormals = None self._vertexNormalsIndexedByFaces = None self._faceNormals = None self._faceNormalsIndexedByFaces = None def hasFaceIndexedData(self): """Return True if this object already has vertex positions indexed by face""" return self._vertexesIndexedByFaces is not None def hasEdgeIndexedData(self): return self._vertexesIndexedByEdges is not None def hasVertexColor(self): """Return True if this data set has vertex color information""" for v in (self._vertexColors, self._vertexColorsIndexedByFaces, self._vertexColorsIndexedByEdges): if v is not None: return True return False def hasFaceColor(self): """Return True if this data set has face color information""" for v in (self._faceColors, self._faceColorsIndexedByFaces, self._faceColorsIndexedByEdges): if v is not None: return True return False def faceNormals(self, indexed=None): """ Return an array (Nf, 3) of normal vectors for each face. If indexed='faces', then instead return an indexed array (Nf, 3, 3) (this is just the same array with each vector copied three times). """ if self._faceNormals is None: v = self.vertexes(indexed='faces') self._faceNormals = np.cross(v[:,1]-v[:,0], v[:,2]-v[:,0]) if indexed is None: return self._faceNormals elif indexed == 'faces': if self._faceNormalsIndexedByFaces is None: norms = np.empty((self._faceNormals.shape[0], 3, 3)) norms[:] = self._faceNormals[:,np.newaxis,:] self._faceNormalsIndexedByFaces = norms return self._faceNormalsIndexedByFaces else: raise Exception("Invalid indexing mode. Accepts: None, 'faces'") def vertexNormals(self, indexed=None): """ Return an array of normal vectors. By default, the array will be (N, 3) with one entry per unique vertex in the mesh. If indexed is 'faces', then the array will contain three normal vectors per face (and some vertexes may be repeated). """ if self._vertexNormals is None: faceNorms = self.faceNormals() vertFaces = self.vertexFaces() self._vertexNormals = np.empty(self._vertexes.shape, dtype=float) for vindex in xrange(self._vertexes.shape[0]): faces = vertFaces[vindex] if len(faces) == 0: self._vertexNormals[vindex] = (0,0,0) continue norms = faceNorms[faces] ## get all face normals norm = norms.sum(axis=0) ## sum normals norm /= (norm**2).sum()**0.5 ## and re-normalize self._vertexNormals[vindex] = norm if indexed is None: return self._vertexNormals elif indexed == 'faces': return self._vertexNormals[self.faces()] else: raise Exception("Invalid indexing mode. Accepts: None, 'faces'") def vertexColors(self, indexed=None): """ Return an array (Nv, 4) of vertex colors. If indexed=='faces', then instead return an indexed array (Nf, 3, 4). """ if indexed is None: return self._vertexColors elif indexed == 'faces': if self._vertexColorsIndexedByFaces is None: self._vertexColorsIndexedByFaces = self._vertexColors[self.faces()] return self._vertexColorsIndexedByFaces else: raise Exception("Invalid indexing mode. Accepts: None, 'faces'") def setVertexColors(self, colors, indexed=None): """ Set the vertex color array (Nv, 4). If indexed=='faces', then the array will be interpreted as indexed and should have shape (Nf, 3, 4) """ if indexed is None: self._vertexColors = colors self._vertexColorsIndexedByFaces = None elif indexed == 'faces': self._vertexColors = None self._vertexColorsIndexedByFaces = colors else: raise Exception("Invalid indexing mode. Accepts: None, 'faces'") def faceColors(self, indexed=None): """ Return an array (Nf, 4) of face colors. If indexed=='faces', then instead return an indexed array (Nf, 3, 4) (note this is just the same array with each color repeated three times). """ if indexed is None: return self._faceColors elif indexed == 'faces': if self._faceColorsIndexedByFaces is None and self._faceColors is not None: Nf = self._faceColors.shape[0] self._faceColorsIndexedByFaces = np.empty((Nf, 3, 4), dtype=self._faceColors.dtype) self._faceColorsIndexedByFaces[:] = self._faceColors.reshape(Nf, 1, 4) return self._faceColorsIndexedByFaces else: raise Exception("Invalid indexing mode. Accepts: None, 'faces'") def setFaceColors(self, colors, indexed=None): """ Set the face color array (Nf, 4). If indexed=='faces', then the array will be interpreted as indexed and should have shape (Nf, 3, 4) """ if indexed is None: self._faceColors = colors self._faceColorsIndexedByFaces = None elif indexed == 'faces': self._faceColors = None self._faceColorsIndexedByFaces = colors else: raise Exception("Invalid indexing mode. Accepts: None, 'faces'") def faceCount(self): """ Return the number of faces in the mesh. """ if self._faces is not None: return self._faces.shape[0] elif self._vertexesIndexedByFaces is not None: return self._vertexesIndexedByFaces.shape[0] def edgeColors(self): return self._edgeColors #def _setIndexedFaces(self, faces, vertexColors=None, faceColors=None): #self._vertexesIndexedByFaces = faces #self._vertexColorsIndexedByFaces = vertexColors #self._faceColorsIndexedByFaces = faceColors def _computeUnindexedVertexes(self): ## Given (Nv, 3, 3) array of vertexes-indexed-by-face, convert backward to unindexed vertexes ## This is done by collapsing into a list of 'unique' vertexes (difference < 1e-14) ## I think generally this should be discouraged.. faces = self._vertexesIndexedByFaces verts = {} ## used to remember the index of each vertex position self._faces = np.empty(faces.shape[:2], dtype=np.uint) self._vertexes = [] self._vertexFaces = [] self._faceNormals = None self._vertexNormals = None for i in xrange(faces.shape[0]): face = faces[i] inds = [] for j in range(face.shape[0]): pt = face[j] pt2 = tuple([round(x*1e14) for x in pt]) ## quantize to be sure that nearly-identical points will be merged index = verts.get(pt2, None) if index is None: #self._vertexes.append(QtGui.QVector3D(*pt)) self._vertexes.append(pt) self._vertexFaces.append([]) index = len(self._vertexes)-1 verts[pt2] = index self._vertexFaces[index].append(i) # keep track of which vertexes belong to which faces self._faces[i,j] = index self._vertexes = np.array(self._vertexes, dtype=float) #def _setUnindexedFaces(self, faces, vertexes, vertexColors=None, faceColors=None): #self._vertexes = vertexes #[QtGui.QVector3D(*v) for v in vertexes] #self._faces = faces.astype(np.uint) #self._edges = None #self._vertexFaces = None #self._faceNormals = None #self._vertexNormals = None #self._vertexColors = vertexColors #self._faceColors = faceColors def vertexFaces(self): """ Return list mapping each vertex index to a list of face indexes that use the vertex. """ if self._vertexFaces is None: self._vertexFaces = [[] for i in xrange(len(self.vertexes()))] for i in xrange(self._faces.shape[0]): face = self._faces[i] for ind in face: self._vertexFaces[ind].append(i) return self._vertexFaces #def reverseNormals(self): #""" #Reverses the direction of all normal vectors. #""" #pass #def generateEdgesFromFaces(self): #""" #Generate a set of edges by listing all the edges of faces and removing any duplicates. #Useful for displaying wireframe meshes. #""" #pass def _computeEdges(self): if not self.hasFaceIndexedData: ## generate self._edges from self._faces nf = len(self._faces) edges = np.empty(nf*3, dtype=[('i', np.uint, 2)]) edges['i'][0:nf] = self._faces[:,:2] edges['i'][nf:2*nf] = self._faces[:,1:3] edges['i'][-nf:,0] = self._faces[:,2] edges['i'][-nf:,1] = self._faces[:,0] # sort per-edge mask = edges['i'][:,0] > edges['i'][:,1] edges['i'][mask] = edges['i'][mask][:,::-1] # remove duplicate entries self._edges = np.unique(edges)['i'] #print self._edges elif self._vertexesIndexedByFaces is not None: verts = self._vertexesIndexedByFaces edges = np.empty((verts.shape[0], 3, 2), dtype=np.uint) nf = verts.shape[0] edges[:,0,0] = np.arange(nf) * 3 edges[:,0,1] = edges[:,0,0] + 1 edges[:,1,0] = edges[:,0,1] edges[:,1,1] = edges[:,1,0] + 1 edges[:,2,0] = edges[:,1,1] edges[:,2,1] = edges[:,0,0] self._edges = edges else: raise Exception("MeshData cannot generate edges--no faces in this data.") def save(self): """Serialize this mesh to a string appropriate for disk storage""" import pickle if self._faces is not None: names = ['_vertexes', '_faces'] else: names = ['_vertexesIndexedByFaces'] if self._vertexColors is not None: names.append('_vertexColors') elif self._vertexColorsIndexedByFaces is not None: names.append('_vertexColorsIndexedByFaces') if self._faceColors is not None: names.append('_faceColors') elif self._faceColorsIndexedByFaces is not None: names.append('_faceColorsIndexedByFaces') state = dict([(n,getattr(self, n)) for n in names]) return pickle.dumps(state) def restore(self, state): """Restore the state of a mesh previously saved using save()""" import pickle state = pickle.loads(state) for k in state: if isinstance(state[k], list): if isinstance(state[k][0], QtGui.QVector3D): state[k] = [[v.x(), v.y(), v.z()] for v in state[k]] state[k] = np.array(state[k]) setattr(self, k, state[k]) @staticmethod def sphere(rows, cols, radius=1.0, offset=True): """ Return a MeshData instance with vertexes and faces computed for a spherical surface. """ verts = np.empty((rows+1, cols, 3), dtype=float) ## compute vertexes phi = (np.arange(rows+1) * np.pi / rows).reshape(rows+1, 1) s = radius * np.sin(phi) verts[...,2] = radius * np.cos(phi) th = ((np.arange(cols) * 2 * np.pi / cols).reshape(1, cols)) if offset: th = th + ((np.pi / cols) * np.arange(rows+1).reshape(rows+1,1)) ## rotate each row by 1/2 column verts[...,0] = s * np.cos(th) verts[...,1] = s * np.sin(th) verts = verts.reshape((rows+1)*cols, 3)[cols-1:-(cols-1)] ## remove redundant vertexes from top and bottom ## compute faces faces = np.empty((rows*cols*2, 3), dtype=np.uint) rowtemplate1 = ((np.arange(cols).reshape(cols, 1) + np.array([[0, 1, 0]])) % cols) + np.array([[0, 0, cols]]) rowtemplate2 = ((np.arange(cols).reshape(cols, 1) + np.array([[0, 1, 1]])) % cols) + np.array([[cols, 0, cols]]) for row in range(rows): start = row * cols * 2 faces[start:start+cols] = rowtemplate1 + row * cols faces[start+cols:start+(cols*2)] = rowtemplate2 + row * cols faces = faces[cols:-cols] ## cut off zero-area triangles at top and bottom ## adjust for redundant vertexes that were removed from top and bottom vmin = cols-1 faces[facesvmax] = vmax return MeshData(vertexes=verts, faces=faces) @staticmethod def cylinder(rows, cols, radius=[1.0, 1.0], length=1.0, offset=False): """ Return a MeshData instance with vertexes and faces computed for a cylindrical surface. The cylinder may be tapered with different radii at each end (truncated cone) """ verts = np.empty((rows+1, cols, 3), dtype=float) if isinstance(radius, int): radius = [radius, radius] # convert to list ## compute vertexes th = np.linspace(2 * np.pi, 0, cols).reshape(1, cols) r = np.linspace(radius[0],radius[1],num=rows+1, endpoint=True).reshape(rows+1, 1) # radius as a function of z verts[...,2] = np.linspace(0, length, num=rows+1, endpoint=True).reshape(rows+1, 1) # z if offset: th = th + ((np.pi / cols) * np.arange(rows+1).reshape(rows+1,1)) ## rotate each row by 1/2 column verts[...,0] = r * np.cos(th) # x = r cos(th) verts[...,1] = r * np.sin(th) # y = r sin(th) verts = verts.reshape((rows+1)*cols, 3) # just reshape: no redundant vertices... ## compute faces faces = np.empty((rows*cols*2, 3), dtype=np.uint) rowtemplate1 = ((np.arange(cols).reshape(cols, 1) + np.array([[0, 1, 0]])) % cols) + np.array([[0, 0, cols]]) rowtemplate2 = ((np.arange(cols).reshape(cols, 1) + np.array([[0, 1, 1]])) % cols) + np.array([[cols, 0, cols]]) for row in range(rows): start = row * cols * 2 faces[start:start+cols] = rowtemplate1 + row * cols faces[start+cols:start+(cols*2)] = rowtemplate2 + row * cols return MeshData(vertexes=verts, faces=faces) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/opengl/__init__.py000066400000000000000000000031161300727121400232360ustar00rootroot00000000000000from .GLViewWidget import GLViewWidget ## dynamic imports cause too many problems. #from .. import importAll #importAll('items', globals(), locals()) from .items.GLGridItem import * from .items.GLBarGraphItem import * from .items.GLScatterPlotItem import * from .items.GLMeshItem import * from .items.GLLinePlotItem import * from .items.GLAxisItem import * from .items.GLImageItem import * from .items.GLSurfacePlotItem import * from .items.GLBoxItem import * from .items.GLVolumeItem import * from .MeshData import MeshData ## for backward compatibility: #MeshData.MeshData = MeshData ## breaks autodoc. from . import shaders pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/opengl/glInfo.py000066400000000000000000000007701300727121400227200ustar00rootroot00000000000000from ..Qt import QtCore, QtGui, QtOpenGL from OpenGL.GL import * app = QtGui.QApplication([]) class GLTest(QtOpenGL.QGLWidget): def __init__(self): QtOpenGL.QGLWidget.__init__(self) self.makeCurrent() print("GL version:" + glGetString(GL_VERSION)) print("MAX_TEXTURE_SIZE: %d" % glGetIntegerv(GL_MAX_TEXTURE_SIZE)) print("MAX_3D_TEXTURE_SIZE: %d" % glGetIntegerv(GL_MAX_3D_TEXTURE_SIZE)) print("Extensions: " + glGetString(GL_EXTENSIONS)) GLTest() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/opengl/items/000077500000000000000000000000001300727121400222455ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/opengl/items/GLAxisItem.py000066400000000000000000000034001300727121400245620ustar00rootroot00000000000000from OpenGL.GL import * from .. GLGraphicsItem import GLGraphicsItem from ... import QtGui __all__ = ['GLAxisItem'] class GLAxisItem(GLGraphicsItem): """ **Bases:** :class:`GLGraphicsItem ` Displays three lines indicating origin and orientation of local coordinate system. """ def __init__(self, size=None, antialias=True, glOptions='translucent'): GLGraphicsItem.__init__(self) if size is None: size = QtGui.QVector3D(1,1,1) self.antialias = antialias self.setSize(size=size) self.setGLOptions(glOptions) def setSize(self, x=None, y=None, z=None, size=None): """ Set the size of the axes (in its local coordinate system; this does not affect the transform) Arguments can be x,y,z or size=QVector3D(). """ if size is not None: x = size.x() y = size.y() z = size.z() self.__size = [x,y,z] self.update() def size(self): return self.__size[:] def paint(self): #glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA) #glEnable( GL_BLEND ) #glEnable( GL_ALPHA_TEST ) self.setupGLState() if self.antialias: glEnable(GL_LINE_SMOOTH) glHint(GL_LINE_SMOOTH_HINT, GL_NICEST) glBegin( GL_LINES ) x,y,z = self.size() glColor4f(0, 1, 0, .6) # z is green glVertex3f(0, 0, 0) glVertex3f(0, 0, z) glColor4f(1, 1, 0, .6) # y is yellow glVertex3f(0, 0, 0) glVertex3f(0, y, 0) glColor4f(0, 0, 1, .6) # x is blue glVertex3f(0, 0, 0) glVertex3f(x, 0, 0) glEnd() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/opengl/items/GLBarGraphItem.py000066400000000000000000000020401300727121400253430ustar00rootroot00000000000000from .GLMeshItem import GLMeshItem from ..MeshData import MeshData import numpy as np class GLBarGraphItem(GLMeshItem): def __init__(self, pos, size): """ pos is (...,3) array of the bar positions (the corner of each bar) size is (...,3) array of the sizes of each bar """ nCubes = reduce(lambda a,b: a*b, pos.shape[:-1]) cubeVerts = np.mgrid[0:2,0:2,0:2].reshape(3,8).transpose().reshape(1,8,3) cubeFaces = np.array([ [0,1,2], [3,2,1], [4,5,6], [7,6,5], [0,1,4], [5,4,1], [2,3,6], [7,6,3], [0,2,4], [6,4,2], [1,3,5], [7,5,3]]).reshape(1,12,3) size = size.reshape((nCubes, 1, 3)) pos = pos.reshape((nCubes, 1, 3)) verts = cubeVerts * size + pos faces = cubeFaces + (np.arange(nCubes) * 8).reshape(nCubes,1,1) md = MeshData(verts.reshape(nCubes*8,3), faces.reshape(nCubes*12,3)) GLMeshItem.__init__(self, meshdata=md, shader='shaded', smooth=False) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/opengl/items/GLBoxItem.py000066400000000000000000000046461300727121400244230ustar00rootroot00000000000000from OpenGL.GL import * from .. GLGraphicsItem import GLGraphicsItem from ...Qt import QtGui from ... import functions as fn __all__ = ['GLBoxItem'] class GLBoxItem(GLGraphicsItem): """ **Bases:** :class:`GLGraphicsItem ` Displays a wire-frame box. """ def __init__(self, size=None, color=None, glOptions='translucent'): GLGraphicsItem.__init__(self) if size is None: size = QtGui.QVector3D(1,1,1) self.setSize(size=size) if color is None: color = (255,255,255,80) self.setColor(color) self.setGLOptions(glOptions) def setSize(self, x=None, y=None, z=None, size=None): """ Set the size of the box (in its local coordinate system; this does not affect the transform) Arguments can be x,y,z or size=QVector3D(). """ if size is not None: x = size.x() y = size.y() z = size.z() self.__size = [x,y,z] self.update() def size(self): return self.__size[:] def setColor(self, *args): """Set the color of the box. Arguments are the same as those accepted by functions.mkColor()""" self.__color = fn.Color(*args) def color(self): return self.__color def paint(self): #glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA) #glEnable( GL_BLEND ) #glEnable( GL_ALPHA_TEST ) ##glAlphaFunc( GL_ALWAYS,0.5 ) #glEnable( GL_POINT_SMOOTH ) #glDisable( GL_DEPTH_TEST ) self.setupGLState() glBegin( GL_LINES ) glColor4f(*self.color().glColor()) x,y,z = self.size() glVertex3f(0, 0, 0) glVertex3f(0, 0, z) glVertex3f(x, 0, 0) glVertex3f(x, 0, z) glVertex3f(0, y, 0) glVertex3f(0, y, z) glVertex3f(x, y, 0) glVertex3f(x, y, z) glVertex3f(0, 0, 0) glVertex3f(0, y, 0) glVertex3f(x, 0, 0) glVertex3f(x, y, 0) glVertex3f(0, 0, z) glVertex3f(0, y, z) glVertex3f(x, 0, z) glVertex3f(x, y, z) glVertex3f(0, 0, 0) glVertex3f(x, 0, 0) glVertex3f(0, y, 0) glVertex3f(x, y, 0) glVertex3f(0, 0, z) glVertex3f(x, 0, z) glVertex3f(0, y, z) glVertex3f(x, y, z) glEnd() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/opengl/items/GLGridItem.py000066400000000000000000000043451300727121400245540ustar00rootroot00000000000000import numpy as np from OpenGL.GL import * from .. GLGraphicsItem import GLGraphicsItem from ... import QtGui __all__ = ['GLGridItem'] class GLGridItem(GLGraphicsItem): """ **Bases:** :class:`GLGraphicsItem ` Displays a wire-grame grid. """ def __init__(self, size=None, color=None, antialias=True, glOptions='translucent'): GLGraphicsItem.__init__(self) self.setGLOptions(glOptions) self.antialias = antialias if size is None: size = QtGui.QVector3D(20,20,1) self.setSize(size=size) self.setSpacing(1, 1, 1) def setSize(self, x=None, y=None, z=None, size=None): """ Set the size of the axes (in its local coordinate system; this does not affect the transform) Arguments can be x,y,z or size=QVector3D(). """ if size is not None: x = size.x() y = size.y() z = size.z() self.__size = [x,y,z] self.update() def size(self): return self.__size[:] def setSpacing(self, x=None, y=None, z=None, spacing=None): """ Set the spacing between grid lines. Arguments can be x,y,z or spacing=QVector3D(). """ if spacing is not None: x = spacing.x() y = spacing.y() z = spacing.z() self.__spacing = [x,y,z] self.update() def spacing(self): return self.__spacing[:] def paint(self): self.setupGLState() if self.antialias: glEnable(GL_LINE_SMOOTH) glEnable(GL_BLEND) glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA) glHint(GL_LINE_SMOOTH_HINT, GL_NICEST) glBegin( GL_LINES ) x,y,z = self.size() xs,ys,zs = self.spacing() xvals = np.arange(-x/2., x/2. + xs*0.001, xs) yvals = np.arange(-y/2., y/2. + ys*0.001, ys) glColor4f(1, 1, 1, .3) for x in xvals: glVertex3f(x, yvals[0], 0) glVertex3f(x, yvals[-1], 0) for y in yvals: glVertex3f(xvals[0], y, 0) glVertex3f(xvals[-1], y, 0) glEnd() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/opengl/items/GLImageItem.py000066400000000000000000000071201300727121400247030ustar00rootroot00000000000000from OpenGL.GL import * from .. GLGraphicsItem import GLGraphicsItem from ...Qt import QtGui import numpy as np __all__ = ['GLImageItem'] class GLImageItem(GLGraphicsItem): """ **Bases:** :class:`GLGraphicsItem ` Displays image data as a textured quad. """ def __init__(self, data, smooth=False, glOptions='translucent'): """ ============== ======================================================================================= **Arguments:** data Volume data to be rendered. *Must* be 3D numpy array (x, y, RGBA) with dtype=ubyte. (See functions.makeRGBA) smooth (bool) If True, the volume slices are rendered with linear interpolation ============== ======================================================================================= """ self.smooth = smooth self._needUpdate = False GLGraphicsItem.__init__(self) self.setData(data) self.setGLOptions(glOptions) def initializeGL(self): glEnable(GL_TEXTURE_2D) self.texture = glGenTextures(1) def setData(self, data): self.data = data self._needUpdate = True self.update() def _updateTexture(self): glBindTexture(GL_TEXTURE_2D, self.texture) if self.smooth: glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR) glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_LINEAR) else: glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_NEAREST) glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_NEAREST) glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_BORDER) glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_BORDER) #glTexParameteri(GL_TEXTURE_3D, GL_TEXTURE_WRAP_R, GL_CLAMP_TO_BORDER) shape = self.data.shape ## Test texture dimensions first glTexImage2D(GL_PROXY_TEXTURE_2D, 0, GL_RGBA, shape[0], shape[1], 0, GL_RGBA, GL_UNSIGNED_BYTE, None) if glGetTexLevelParameteriv(GL_PROXY_TEXTURE_2D, 0, GL_TEXTURE_WIDTH) == 0: raise Exception("OpenGL failed to create 2D texture (%dx%d); too large for this hardware." % shape[:2]) glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA, shape[0], shape[1], 0, GL_RGBA, GL_UNSIGNED_BYTE, self.data.transpose((1,0,2))) glDisable(GL_TEXTURE_2D) #self.lists = {} #for ax in [0,1,2]: #for d in [-1, 1]: #l = glGenLists(1) #self.lists[(ax,d)] = l #glNewList(l, GL_COMPILE) #self.drawVolume(ax, d) #glEndList() def paint(self): if self._needUpdate: self._updateTexture() glEnable(GL_TEXTURE_2D) glBindTexture(GL_TEXTURE_2D, self.texture) self.setupGLState() #glEnable(GL_DEPTH_TEST) ##glDisable(GL_CULL_FACE) #glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA) #glEnable( GL_BLEND ) #glEnable( GL_ALPHA_TEST ) glColor4f(1,1,1,1) glBegin(GL_QUADS) glTexCoord2f(0,0) glVertex3f(0,0,0) glTexCoord2f(1,0) glVertex3f(self.data.shape[0], 0, 0) glTexCoord2f(1,1) glVertex3f(self.data.shape[0], self.data.shape[1], 0) glTexCoord2f(0,1) glVertex3f(0, self.data.shape[1], 0) glEnd() glDisable(GL_TEXTURE_3D) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/opengl/items/GLLinePlotItem.py000066400000000000000000000104261300727121400254120ustar00rootroot00000000000000from OpenGL.GL import * from OpenGL.arrays import vbo from .. GLGraphicsItem import GLGraphicsItem from .. import shaders from ... import QtGui import numpy as np __all__ = ['GLLinePlotItem'] class GLLinePlotItem(GLGraphicsItem): """Draws line plots in 3D.""" def __init__(self, **kwds): """All keyword arguments are passed to setData()""" GLGraphicsItem.__init__(self) glopts = kwds.pop('glOptions', 'additive') self.setGLOptions(glopts) self.pos = None self.mode = 'line_strip' self.width = 1. self.color = (1.0,1.0,1.0,1.0) self.setData(**kwds) def setData(self, **kwds): """ Update the data displayed by this item. All arguments are optional; for example it is allowed to update vertex positions while leaving colors unchanged, etc. ==================== ================================================== **Arguments:** ------------------------------------------------------------------------ pos (N,3) array of floats specifying point locations. color (N,4) array of floats (0.0-1.0) or tuple of floats specifying a single color for the entire item. width float specifying line width antialias enables smooth line drawing mode 'lines': Each pair of vertexes draws a single line segment. 'line_strip': All vertexes are drawn as a continuous set of line segments. ==================== ================================================== """ args = ['pos', 'color', 'width', 'mode', 'antialias'] for k in kwds.keys(): if k not in args: raise Exception('Invalid keyword argument: %s (allowed arguments are %s)' % (k, str(args))) self.antialias = False for arg in args: if arg in kwds: setattr(self, arg, kwds[arg]) #self.vbo.pop(arg, None) self.update() def initializeGL(self): pass #def setupGLState(self): #"""Prepare OpenGL state for drawing. This function is called immediately before painting.""" ##glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA) ## requires z-sorting to render properly. #glBlendFunc(GL_SRC_ALPHA, GL_ONE) #glEnable( GL_BLEND ) #glEnable( GL_ALPHA_TEST ) #glDisable( GL_DEPTH_TEST ) ##glEnable( GL_POINT_SMOOTH ) ##glHint(GL_POINT_SMOOTH_HINT, GL_NICEST) ##glPointParameterfv(GL_POINT_DISTANCE_ATTENUATION, (0, 0, -1e-3)) ##glPointParameterfv(GL_POINT_SIZE_MAX, (65500,)) ##glPointParameterfv(GL_POINT_SIZE_MIN, (0,)) def paint(self): if self.pos is None: return self.setupGLState() glEnableClientState(GL_VERTEX_ARRAY) try: glVertexPointerf(self.pos) if isinstance(self.color, np.ndarray): glEnableClientState(GL_COLOR_ARRAY) glColorPointerf(self.color) else: if isinstance(self.color, QtGui.QColor): glColor4f(*fn.glColor(self.color)) else: glColor4f(*self.color) glLineWidth(self.width) #glPointSize(self.width) if self.antialias: glEnable(GL_LINE_SMOOTH) glEnable(GL_BLEND) glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA) glHint(GL_LINE_SMOOTH_HINT, GL_NICEST) if self.mode == 'line_strip': glDrawArrays(GL_LINE_STRIP, 0, int(self.pos.size / self.pos.shape[-1])) elif self.mode == 'lines': glDrawArrays(GL_LINES, 0, int(self.pos.size / self.pos.shape[-1])) else: raise Exception("Unknown line mode '%s'. (must be 'lines' or 'line_strip')" % self.mode) finally: glDisableClientState(GL_COLOR_ARRAY) glDisableClientState(GL_VERTEX_ARRAY) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/opengl/items/GLMeshItem.py000066400000000000000000000206511300727121400245610ustar00rootroot00000000000000from OpenGL.GL import * from .. GLGraphicsItem import GLGraphicsItem from .. MeshData import MeshData from ...Qt import QtGui from .. import shaders from ... import functions as fn import numpy as np __all__ = ['GLMeshItem'] class GLMeshItem(GLGraphicsItem): """ **Bases:** :class:`GLGraphicsItem ` Displays a 3D triangle mesh. """ def __init__(self, **kwds): """ ============== ===================================================== **Arguments:** meshdata MeshData object from which to determine geometry for this item. color Default face color used if no vertex or face colors are specified. edgeColor Default edge color to use if no edge colors are specified in the mesh data. drawEdges If True, a wireframe mesh will be drawn. (default=False) drawFaces If True, mesh faces are drawn. (default=True) shader Name of shader program to use when drawing faces. (None for no shader) smooth If True, normal vectors are computed for each vertex and interpolated within each face. computeNormals If False, then computation of normal vectors is disabled. This can provide a performance boost for meshes that do not make use of normals. ============== ===================================================== """ self.opts = { 'meshdata': None, 'color': (1., 1., 1., 1.), 'drawEdges': False, 'drawFaces': True, 'edgeColor': (0.5, 0.5, 0.5, 1.0), 'shader': None, 'smooth': True, 'computeNormals': True, } GLGraphicsItem.__init__(self) glopts = kwds.pop('glOptions', 'opaque') self.setGLOptions(glopts) shader = kwds.pop('shader', None) self.setShader(shader) self.setMeshData(**kwds) ## storage for data compiled from MeshData object self.vertexes = None self.normals = None self.colors = None self.faces = None def setShader(self, shader): """Set the shader used when rendering faces in the mesh. (see the GL shaders example)""" self.opts['shader'] = shader self.update() def shader(self): shader = self.opts['shader'] if isinstance(shader, shaders.ShaderProgram): return shader else: return shaders.getShaderProgram(shader) def setColor(self, c): """Set the default color to use when no vertex or face colors are specified.""" self.opts['color'] = c self.update() def setMeshData(self, **kwds): """ Set mesh data for this item. This can be invoked two ways: 1. Specify *meshdata* argument with a new MeshData object 2. Specify keyword arguments to be passed to MeshData(..) to create a new instance. """ md = kwds.get('meshdata', None) if md is None: opts = {} for k in ['vertexes', 'faces', 'edges', 'vertexColors', 'faceColors']: try: opts[k] = kwds.pop(k) except KeyError: pass md = MeshData(**opts) self.opts['meshdata'] = md self.opts.update(kwds) self.meshDataChanged() self.update() def meshDataChanged(self): """ This method must be called to inform the item that the MeshData object has been altered. """ self.vertexes = None self.faces = None self.normals = None self.colors = None self.edges = None self.edgeColors = None self.update() def parseMeshData(self): ## interpret vertex / normal data before drawing ## This can: ## - automatically generate normals if they were not specified ## - pull vertexes/noormals/faces from MeshData if that was specified if self.vertexes is not None and self.normals is not None: return #if self.opts['normals'] is None: #if self.opts['meshdata'] is None: #self.opts['meshdata'] = MeshData(vertexes=self.opts['vertexes'], faces=self.opts['faces']) if self.opts['meshdata'] is not None: md = self.opts['meshdata'] if self.opts['smooth'] and not md.hasFaceIndexedData(): self.vertexes = md.vertexes() if self.opts['computeNormals']: self.normals = md.vertexNormals() self.faces = md.faces() if md.hasVertexColor(): self.colors = md.vertexColors() if md.hasFaceColor(): self.colors = md.faceColors() else: self.vertexes = md.vertexes(indexed='faces') if self.opts['computeNormals']: if self.opts['smooth']: self.normals = md.vertexNormals(indexed='faces') else: self.normals = md.faceNormals(indexed='faces') self.faces = None if md.hasVertexColor(): self.colors = md.vertexColors(indexed='faces') elif md.hasFaceColor(): self.colors = md.faceColors(indexed='faces') if self.opts['drawEdges']: if not md.hasFaceIndexedData(): self.edges = md.edges() self.edgeVerts = md.vertexes() else: self.edges = md.edges() self.edgeVerts = md.vertexes(indexed='faces') return def paint(self): self.setupGLState() self.parseMeshData() if self.opts['drawFaces']: with self.shader(): verts = self.vertexes norms = self.normals color = self.colors faces = self.faces if verts is None: return glEnableClientState(GL_VERTEX_ARRAY) try: glVertexPointerf(verts) if self.colors is None: color = self.opts['color'] if isinstance(color, QtGui.QColor): glColor4f(*fn.glColor(color)) else: glColor4f(*color) else: glEnableClientState(GL_COLOR_ARRAY) glColorPointerf(color) if norms is not None: glEnableClientState(GL_NORMAL_ARRAY) glNormalPointerf(norms) if faces is None: glDrawArrays(GL_TRIANGLES, 0, np.product(verts.shape[:-1])) else: faces = faces.astype(np.uint).flatten() glDrawElements(GL_TRIANGLES, faces.shape[0], GL_UNSIGNED_INT, faces) finally: glDisableClientState(GL_NORMAL_ARRAY) glDisableClientState(GL_VERTEX_ARRAY) glDisableClientState(GL_COLOR_ARRAY) if self.opts['drawEdges']: verts = self.edgeVerts edges = self.edges glEnableClientState(GL_VERTEX_ARRAY) try: glVertexPointerf(verts) if self.edgeColors is None: color = self.opts['edgeColor'] if isinstance(color, QtGui.QColor): glColor4f(*fn.glColor(color)) else: glColor4f(*color) else: glEnableClientState(GL_COLOR_ARRAY) glColorPointerf(color) edges = edges.flatten() glDrawElements(GL_LINES, edges.shape[0], GL_UNSIGNED_INT, edges) finally: glDisableClientState(GL_VERTEX_ARRAY) glDisableClientState(GL_COLOR_ARRAY) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/opengl/items/GLScatterPlotItem.py000066400000000000000000000164051300727121400261330ustar00rootroot00000000000000from OpenGL.GL import * from OpenGL.arrays import vbo from .. GLGraphicsItem import GLGraphicsItem from .. import shaders from ... import QtGui import numpy as np __all__ = ['GLScatterPlotItem'] class GLScatterPlotItem(GLGraphicsItem): """Draws points at a list of 3D positions.""" def __init__(self, **kwds): GLGraphicsItem.__init__(self) glopts = kwds.pop('glOptions', 'additive') self.setGLOptions(glopts) self.pos = [] self.size = 10 self.color = [1.0,1.0,1.0,0.5] self.pxMode = True #self.vbo = {} ## VBO does not appear to improve performance very much. self.setData(**kwds) def setData(self, **kwds): """ Update the data displayed by this item. All arguments are optional; for example it is allowed to update spot positions while leaving colors unchanged, etc. ==================== ================================================== **Arguments:** pos (N,3) array of floats specifying point locations. color (N,4) array of floats (0.0-1.0) specifying spot colors OR a tuple of floats specifying a single color for all spots. size (N,) array of floats specifying spot sizes or a single value to apply to all spots. pxMode If True, spot sizes are expressed in pixels. Otherwise, they are expressed in item coordinates. ==================== ================================================== """ args = ['pos', 'color', 'size', 'pxMode'] for k in kwds.keys(): if k not in args: raise Exception('Invalid keyword argument: %s (allowed arguments are %s)' % (k, str(args))) args.remove('pxMode') for arg in args: if arg in kwds: setattr(self, arg, kwds[arg]) #self.vbo.pop(arg, None) self.pxMode = kwds.get('pxMode', self.pxMode) self.update() def initializeGL(self): ## Generate texture for rendering points w = 64 def fn(x,y): r = ((x-w/2.)**2 + (y-w/2.)**2) ** 0.5 return 255 * (w/2. - np.clip(r, w/2.-1.0, w/2.)) pData = np.empty((w, w, 4)) pData[:] = 255 pData[:,:,3] = np.fromfunction(fn, pData.shape[:2]) #print pData.shape, pData.min(), pData.max() pData = pData.astype(np.ubyte) if getattr(self, "pointTexture", None) is None: self.pointTexture = glGenTextures(1) glActiveTexture(GL_TEXTURE0) glEnable(GL_TEXTURE_2D) glBindTexture(GL_TEXTURE_2D, self.pointTexture) glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA, pData.shape[0], pData.shape[1], 0, GL_RGBA, GL_UNSIGNED_BYTE, pData) self.shader = shaders.getShaderProgram('pointSprite') #def getVBO(self, name): #if name not in self.vbo: #self.vbo[name] = vbo.VBO(getattr(self, name).astype('f')) #return self.vbo[name] #def setupGLState(self): #"""Prepare OpenGL state for drawing. This function is called immediately before painting.""" ##glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA) ## requires z-sorting to render properly. #glBlendFunc(GL_SRC_ALPHA, GL_ONE) #glEnable( GL_BLEND ) #glEnable( GL_ALPHA_TEST ) #glDisable( GL_DEPTH_TEST ) ##glEnable( GL_POINT_SMOOTH ) ##glHint(GL_POINT_SMOOTH_HINT, GL_NICEST) ##glPointParameterfv(GL_POINT_DISTANCE_ATTENUATION, (0, 0, -1e-3)) ##glPointParameterfv(GL_POINT_SIZE_MAX, (65500,)) ##glPointParameterfv(GL_POINT_SIZE_MIN, (0,)) def paint(self): self.setupGLState() glEnable(GL_POINT_SPRITE) glActiveTexture(GL_TEXTURE0) glEnable( GL_TEXTURE_2D ) glBindTexture(GL_TEXTURE_2D, self.pointTexture) glTexEnvi(GL_POINT_SPRITE, GL_COORD_REPLACE, GL_TRUE) #glTexEnvi(GL_TEXTURE_ENV, GL_TEXTURE_ENV_MODE, GL_REPLACE) ## use texture color exactly #glTexEnvf( GL_TEXTURE_ENV, GL_TEXTURE_ENV_MODE, GL_MODULATE ) ## texture modulates current color glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR) glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_LINEAR) glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_EDGE) glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_EDGE) glEnable(GL_PROGRAM_POINT_SIZE) with self.shader: #glUniform1i(self.shader.uniform('texture'), 0) ## inform the shader which texture to use glEnableClientState(GL_VERTEX_ARRAY) try: pos = self.pos #if pos.ndim > 2: #pos = pos.reshape((reduce(lambda a,b: a*b, pos.shape[:-1]), pos.shape[-1])) glVertexPointerf(pos) if isinstance(self.color, np.ndarray): glEnableClientState(GL_COLOR_ARRAY) glColorPointerf(self.color) else: if isinstance(self.color, QtGui.QColor): glColor4f(*fn.glColor(self.color)) else: glColor4f(*self.color) if not self.pxMode or isinstance(self.size, np.ndarray): glEnableClientState(GL_NORMAL_ARRAY) norm = np.empty(pos.shape) if self.pxMode: norm[...,0] = self.size else: gpos = self.mapToView(pos.transpose()).transpose() pxSize = self.view().pixelSize(gpos) norm[...,0] = self.size / pxSize glNormalPointerf(norm) else: glNormal3f(self.size, 0, 0) ## vertex shader uses norm.x to determine point size #glPointSize(self.size) glDrawArrays(GL_POINTS, 0, int(pos.size / pos.shape[-1])) finally: glDisableClientState(GL_NORMAL_ARRAY) glDisableClientState(GL_VERTEX_ARRAY) glDisableClientState(GL_COLOR_ARRAY) #posVBO.unbind() #for i in range(len(self.pos)): #pos = self.pos[i] #if isinstance(self.color, np.ndarray): #color = self.color[i] #else: #color = self.color #if isinstance(self.color, QtGui.QColor): #color = fn.glColor(self.color) #if isinstance(self.size, np.ndarray): #size = self.size[i] #else: #size = self.size #pxSize = self.view().pixelSize(QtGui.QVector3D(*pos)) #glPointSize(size / pxSize) #glBegin( GL_POINTS ) #glColor4f(*color) # x is blue ##glNormal3f(size, 0, 0) #glVertex3f(*pos) #glEnd() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/opengl/items/GLSurfacePlotItem.py000066400000000000000000000121241300727121400261100ustar00rootroot00000000000000from OpenGL.GL import * from .GLMeshItem import GLMeshItem from .. MeshData import MeshData from ...Qt import QtGui import numpy as np __all__ = ['GLSurfacePlotItem'] class GLSurfacePlotItem(GLMeshItem): """ **Bases:** :class:`GLMeshItem ` Displays a surface plot on a regular x,y grid """ def __init__(self, x=None, y=None, z=None, colors=None, **kwds): """ The x, y, z, and colors arguments are passed to setData(). All other keyword arguments are passed to GLMeshItem.__init__(). """ self._x = None self._y = None self._z = None self._color = None self._vertexes = None self._meshdata = MeshData() GLMeshItem.__init__(self, meshdata=self._meshdata, **kwds) self.setData(x, y, z, colors) def setData(self, x=None, y=None, z=None, colors=None): """ Update the data in this surface plot. ============== ===================================================================== **Arguments:** x,y 1D arrays of values specifying the x,y positions of vertexes in the grid. If these are omitted, then the values will be assumed to be integers. z 2D array of height values for each grid vertex. colors (width, height, 4) array of vertex colors. ============== ===================================================================== All arguments are optional. Note that if vertex positions are updated, the normal vectors for each triangle must be recomputed. This is somewhat expensive if the surface was initialized with smooth=False and very expensive if smooth=True. For faster performance, initialize with computeNormals=False and use per-vertex colors or a normal-independent shader program. """ if x is not None: if self._x is None or len(x) != len(self._x): self._vertexes = None self._x = x if y is not None: if self._y is None or len(y) != len(self._y): self._vertexes = None self._y = y if z is not None: #if self._x is None: #self._x = np.arange(z.shape[0]) #self._vertexes = None #if self._y is None: #self._y = np.arange(z.shape[1]) #self._vertexes = None if self._x is not None and z.shape[0] != len(self._x): raise Exception('Z values must have shape (len(x), len(y))') if self._y is not None and z.shape[1] != len(self._y): raise Exception('Z values must have shape (len(x), len(y))') self._z = z if self._vertexes is not None and self._z.shape != self._vertexes.shape[:2]: self._vertexes = None if colors is not None: self._colors = colors self._meshdata.setVertexColors(colors) if self._z is None: return updateMesh = False newVertexes = False ## Generate vertex and face array if self._vertexes is None: newVertexes = True self._vertexes = np.empty((self._z.shape[0], self._z.shape[1], 3), dtype=float) self.generateFaces() self._meshdata.setFaces(self._faces) updateMesh = True ## Copy x, y, z data into vertex array if newVertexes or x is not None: if x is None: if self._x is None: x = np.arange(self._z.shape[0]) else: x = self._x self._vertexes[:, :, 0] = x.reshape(len(x), 1) updateMesh = True if newVertexes or y is not None: if y is None: if self._y is None: y = np.arange(self._z.shape[1]) else: y = self._y self._vertexes[:, :, 1] = y.reshape(1, len(y)) updateMesh = True if newVertexes or z is not None: self._vertexes[...,2] = self._z updateMesh = True ## Update MeshData if updateMesh: self._meshdata.setVertexes(self._vertexes.reshape(self._vertexes.shape[0]*self._vertexes.shape[1], 3)) self.meshDataChanged() def generateFaces(self): cols = self._z.shape[1]-1 rows = self._z.shape[0]-1 faces = np.empty((cols*rows*2, 3), dtype=np.uint) rowtemplate1 = np.arange(cols).reshape(cols, 1) + np.array([[0, 1, cols+1]]) rowtemplate2 = np.arange(cols).reshape(cols, 1) + np.array([[cols+1, 1, cols+2]]) for row in range(rows): start = row * cols * 2 faces[start:start+cols] = rowtemplate1 + row * (cols+1) faces[start+cols:start+(cols*2)] = rowtemplate2 + row * (cols+1) self._faces = faces pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/opengl/items/GLVolumeItem.py000066400000000000000000000167521300727121400251430ustar00rootroot00000000000000from OpenGL.GL import * from .. GLGraphicsItem import GLGraphicsItem from ...Qt import QtGui import numpy as np from ... import debug __all__ = ['GLVolumeItem'] class GLVolumeItem(GLGraphicsItem): """ **Bases:** :class:`GLGraphicsItem ` Displays volumetric data. """ def __init__(self, data, sliceDensity=1, smooth=True, glOptions='translucent'): """ ============== ======================================================================================= **Arguments:** data Volume data to be rendered. *Must* be 4D numpy array (x, y, z, RGBA) with dtype=ubyte. sliceDensity Density of slices to render through the volume. A value of 1 means one slice per voxel. smooth (bool) If True, the volume slices are rendered with linear interpolation ============== ======================================================================================= """ self.sliceDensity = sliceDensity self.smooth = smooth self.data = None self._needUpload = False self.texture = None GLGraphicsItem.__init__(self) self.setGLOptions(glOptions) self.setData(data) def setData(self, data): self.data = data self._needUpload = True self.update() def _uploadData(self): glEnable(GL_TEXTURE_3D) if self.texture is None: self.texture = glGenTextures(1) glBindTexture(GL_TEXTURE_3D, self.texture) if self.smooth: glTexParameteri(GL_TEXTURE_3D, GL_TEXTURE_MIN_FILTER, GL_LINEAR) glTexParameteri(GL_TEXTURE_3D, GL_TEXTURE_MAG_FILTER, GL_LINEAR) else: glTexParameteri(GL_TEXTURE_3D, GL_TEXTURE_MIN_FILTER, GL_NEAREST) glTexParameteri(GL_TEXTURE_3D, GL_TEXTURE_MAG_FILTER, GL_NEAREST) glTexParameteri(GL_TEXTURE_3D, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_BORDER) glTexParameteri(GL_TEXTURE_3D, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_BORDER) glTexParameteri(GL_TEXTURE_3D, GL_TEXTURE_WRAP_R, GL_CLAMP_TO_BORDER) shape = self.data.shape ## Test texture dimensions first glTexImage3D(GL_PROXY_TEXTURE_3D, 0, GL_RGBA, shape[0], shape[1], shape[2], 0, GL_RGBA, GL_UNSIGNED_BYTE, None) if glGetTexLevelParameteriv(GL_PROXY_TEXTURE_3D, 0, GL_TEXTURE_WIDTH) == 0: raise Exception("OpenGL failed to create 3D texture (%dx%dx%d); too large for this hardware." % shape[:3]) glTexImage3D(GL_TEXTURE_3D, 0, GL_RGBA, shape[0], shape[1], shape[2], 0, GL_RGBA, GL_UNSIGNED_BYTE, self.data.transpose((2,1,0,3))) glDisable(GL_TEXTURE_3D) self.lists = {} for ax in [0,1,2]: for d in [-1, 1]: l = glGenLists(1) self.lists[(ax,d)] = l glNewList(l, GL_COMPILE) self.drawVolume(ax, d) glEndList() self._needUpload = False def paint(self): if self.data is None: return if self._needUpload: self._uploadData() self.setupGLState() glEnable(GL_TEXTURE_3D) glBindTexture(GL_TEXTURE_3D, self.texture) #glEnable(GL_DEPTH_TEST) #glDisable(GL_CULL_FACE) #glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA) #glEnable( GL_BLEND ) #glEnable( GL_ALPHA_TEST ) glColor4f(1,1,1,1) view = self.view() center = QtGui.QVector3D(*[x/2. for x in self.data.shape[:3]]) cam = self.mapFromParent(view.cameraPosition()) - center #print "center", center, "cam", view.cameraPosition(), self.mapFromParent(view.cameraPosition()), "diff", cam cam = np.array([cam.x(), cam.y(), cam.z()]) ax = np.argmax(abs(cam)) d = 1 if cam[ax] > 0 else -1 glCallList(self.lists[(ax,d)]) ## draw axes glDisable(GL_TEXTURE_3D) def drawVolume(self, ax, d): N = 5 imax = [0,1,2] imax.remove(ax) tp = [[0,0,0],[0,0,0],[0,0,0],[0,0,0]] vp = [[0,0,0],[0,0,0],[0,0,0],[0,0,0]] nudge = [0.5/x for x in self.data.shape] tp[0][imax[0]] = 0+nudge[imax[0]] tp[0][imax[1]] = 0+nudge[imax[1]] tp[1][imax[0]] = 1-nudge[imax[0]] tp[1][imax[1]] = 0+nudge[imax[1]] tp[2][imax[0]] = 1-nudge[imax[0]] tp[2][imax[1]] = 1-nudge[imax[1]] tp[3][imax[0]] = 0+nudge[imax[0]] tp[3][imax[1]] = 1-nudge[imax[1]] vp[0][imax[0]] = 0 vp[0][imax[1]] = 0 vp[1][imax[0]] = self.data.shape[imax[0]] vp[1][imax[1]] = 0 vp[2][imax[0]] = self.data.shape[imax[0]] vp[2][imax[1]] = self.data.shape[imax[1]] vp[3][imax[0]] = 0 vp[3][imax[1]] = self.data.shape[imax[1]] slices = self.data.shape[ax] * self.sliceDensity r = list(range(slices)) if d == -1: r = r[::-1] glBegin(GL_QUADS) tzVals = np.linspace(nudge[ax], 1.0-nudge[ax], slices) vzVals = np.linspace(0, self.data.shape[ax], slices) for i in r: z = tzVals[i] w = vzVals[i] tp[0][ax] = z tp[1][ax] = z tp[2][ax] = z tp[3][ax] = z vp[0][ax] = w vp[1][ax] = w vp[2][ax] = w vp[3][ax] = w glTexCoord3f(*tp[0]) glVertex3f(*vp[0]) glTexCoord3f(*tp[1]) glVertex3f(*vp[1]) glTexCoord3f(*tp[2]) glVertex3f(*vp[2]) glTexCoord3f(*tp[3]) glVertex3f(*vp[3]) glEnd() ## Interesting idea: ## remove projection/modelview matrixes, recreate in texture coords. ## it _sorta_ works, but needs tweaking. #mvm = glGetDoublev(GL_MODELVIEW_MATRIX) #pm = glGetDoublev(GL_PROJECTION_MATRIX) #m = QtGui.QMatrix4x4(mvm.flatten()).inverted()[0] #p = QtGui.QMatrix4x4(pm.flatten()).inverted()[0] #glMatrixMode(GL_PROJECTION) #glPushMatrix() #glLoadIdentity() #N=1 #glOrtho(-N,N,-N,N,-100,100) #glMatrixMode(GL_MODELVIEW) #glLoadIdentity() #glMatrixMode(GL_TEXTURE) #glLoadIdentity() #glMultMatrixf(m.copyDataTo()) #view = self.view() #w = view.width() #h = view.height() #dist = view.opts['distance'] #fov = view.opts['fov'] #nearClip = dist * .1 #farClip = dist * 5. #r = nearClip * np.tan(fov) #t = r * h / w #p = QtGui.QMatrix4x4() #p.frustum( -r, r, -t, t, nearClip, farClip) #glMultMatrixf(p.inverted()[0].copyDataTo()) #glBegin(GL_QUADS) #M=1 #for i in range(500): #z = i/500. #w = -i/500. #glTexCoord3f(-M, -M, z) #glVertex3f(-N, -N, w) #glTexCoord3f(M, -M, z) #glVertex3f(N, -N, w) #glTexCoord3f(M, M, z) #glVertex3f(N, N, w) #glTexCoord3f(-M, M, z) #glVertex3f(-N, N, w) #glEnd() #glDisable(GL_TEXTURE_3D) #glMatrixMode(GL_PROJECTION) #glPopMatrix() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/opengl/items/__init__.py000066400000000000000000000000001300727121400243440ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/opengl/shaders.py000066400000000000000000000372111300727121400231330ustar00rootroot00000000000000try: from OpenGL import NullFunctionError except ImportError: from OpenGL.error import NullFunctionError from OpenGL.GL import * from OpenGL.GL import shaders import re ## For centralizing and managing vertex/fragment shader programs. def initShaders(): global Shaders Shaders = [ ShaderProgram(None, []), ## increases fragment alpha as the normal turns orthogonal to the view ## this is useful for viewing shells that enclose a volume (such as isosurfaces) ShaderProgram('balloon', [ VertexShader(""" varying vec3 normal; void main() { // compute here for use in fragment shader normal = normalize(gl_NormalMatrix * gl_Normal); gl_FrontColor = gl_Color; gl_BackColor = gl_Color; gl_Position = ftransform(); } """), FragmentShader(""" varying vec3 normal; void main() { vec4 color = gl_Color; color.w = min(color.w + 2.0 * color.w * pow(normal.x*normal.x + normal.y*normal.y, 5.0), 1.0); gl_FragColor = color; } """) ]), ## colors fragments based on face normals relative to view ## This means that the colors will change depending on how the view is rotated ShaderProgram('viewNormalColor', [ VertexShader(""" varying vec3 normal; void main() { // compute here for use in fragment shader normal = normalize(gl_NormalMatrix * gl_Normal); gl_FrontColor = gl_Color; gl_BackColor = gl_Color; gl_Position = ftransform(); } """), FragmentShader(""" varying vec3 normal; void main() { vec4 color = gl_Color; color.x = (normal.x + 1.0) * 0.5; color.y = (normal.y + 1.0) * 0.5; color.z = (normal.z + 1.0) * 0.5; gl_FragColor = color; } """) ]), ## colors fragments based on absolute face normals. ShaderProgram('normalColor', [ VertexShader(""" varying vec3 normal; void main() { // compute here for use in fragment shader normal = normalize(gl_Normal); gl_FrontColor = gl_Color; gl_BackColor = gl_Color; gl_Position = ftransform(); } """), FragmentShader(""" varying vec3 normal; void main() { vec4 color = gl_Color; color.x = (normal.x + 1.0) * 0.5; color.y = (normal.y + 1.0) * 0.5; color.z = (normal.z + 1.0) * 0.5; gl_FragColor = color; } """) ]), ## very simple simulation of lighting. ## The light source position is always relative to the camera. ShaderProgram('shaded', [ VertexShader(""" varying vec3 normal; void main() { // compute here for use in fragment shader normal = normalize(gl_NormalMatrix * gl_Normal); gl_FrontColor = gl_Color; gl_BackColor = gl_Color; gl_Position = ftransform(); } """), FragmentShader(""" varying vec3 normal; void main() { float p = dot(normal, normalize(vec3(1.0, -1.0, -1.0))); p = p < 0. ? 0. : p * 0.8; vec4 color = gl_Color; color.x = color.x * (0.2 + p); color.y = color.y * (0.2 + p); color.z = color.z * (0.2 + p); gl_FragColor = color; } """) ]), ## colors get brighter near edges of object ShaderProgram('edgeHilight', [ VertexShader(""" varying vec3 normal; void main() { // compute here for use in fragment shader normal = normalize(gl_NormalMatrix * gl_Normal); gl_FrontColor = gl_Color; gl_BackColor = gl_Color; gl_Position = ftransform(); } """), FragmentShader(""" varying vec3 normal; void main() { vec4 color = gl_Color; float s = pow(normal.x*normal.x + normal.y*normal.y, 2.0); color.x = color.x + s * (1.0-color.x); color.y = color.y + s * (1.0-color.y); color.z = color.z + s * (1.0-color.z); gl_FragColor = color; } """) ]), ## colors fragments by z-value. ## This is useful for coloring surface plots by height. ## This shader uses a uniform called "colorMap" to determine how to map the colors: ## red = pow(z * colorMap[0] + colorMap[1], colorMap[2]) ## green = pow(z * colorMap[3] + colorMap[4], colorMap[5]) ## blue = pow(z * colorMap[6] + colorMap[7], colorMap[8]) ## (set the values like this: shader['uniformMap'] = array([...]) ShaderProgram('heightColor', [ VertexShader(""" varying vec4 pos; void main() { gl_FrontColor = gl_Color; gl_BackColor = gl_Color; pos = gl_Vertex; gl_Position = ftransform(); } """), FragmentShader(""" uniform float colorMap[9]; varying vec4 pos; //out vec4 gl_FragColor; // only needed for later glsl versions //in vec4 gl_Color; void main() { vec4 color = gl_Color; color.x = colorMap[0] * (pos.z + colorMap[1]); if (colorMap[2] != 1.0) color.x = pow(color.x, colorMap[2]); color.x = color.x < 0. ? 0. : (color.x > 1. ? 1. : color.x); color.y = colorMap[3] * (pos.z + colorMap[4]); if (colorMap[5] != 1.0) color.y = pow(color.y, colorMap[5]); color.y = color.y < 0. ? 0. : (color.y > 1. ? 1. : color.y); color.z = colorMap[6] * (pos.z + colorMap[7]); if (colorMap[8] != 1.0) color.z = pow(color.z, colorMap[8]); color.z = color.z < 0. ? 0. : (color.z > 1. ? 1. : color.z); color.w = 1.0; gl_FragColor = color; } """), ], uniforms={'colorMap': [1, 1, 1, 1, 0.5, 1, 1, 0, 1]}), ShaderProgram('pointSprite', [ ## allows specifying point size using normal.x ## See: ## ## http://stackoverflow.com/questions/9609423/applying-part-of-a-texture-sprite-sheet-texture-map-to-a-point-sprite-in-ios ## http://stackoverflow.com/questions/3497068/textured-points-in-opengl-es-2-0 ## ## VertexShader(""" void main() { gl_FrontColor=gl_Color; gl_PointSize = gl_Normal.x; gl_Position = ftransform(); } """), #FragmentShader(""" ##version 120 #uniform sampler2D texture; #void main ( ) #{ #gl_FragColor = texture2D(texture, gl_PointCoord) * gl_Color; #} #""") ]), ] CompiledShaderPrograms = {} def getShaderProgram(name): return ShaderProgram.names[name] class Shader(object): def __init__(self, shaderType, code): self.shaderType = shaderType self.code = code self.compiled = None def shader(self): if self.compiled is None: try: self.compiled = shaders.compileShader(self.code, self.shaderType) except NullFunctionError: raise Exception("This OpenGL implementation does not support shader programs; many OpenGL features in pyqtgraph will not work.") except RuntimeError as exc: ## Format compile errors a bit more nicely if len(exc.args) == 3: err, code, typ = exc.args if not err.startswith('Shader compile failure'): raise code = code[0].decode('utf_8').split('\n') err, c, msgs = err.partition(':') err = err + '\n' msgs = re.sub('b\'','',msgs) msgs = re.sub('\'$','',msgs) msgs = re.sub('\\\\n','\n',msgs) msgs = msgs.split('\n') errNums = [()] * len(code) for i, msg in enumerate(msgs): msg = msg.strip() if msg == '': continue m = re.match(r'(\d+\:)?\d+\((\d+)\)', msg) if m is not None: line = int(m.groups()[1]) errNums[line-1] = errNums[line-1] + (str(i+1),) #code[line-1] = '%d\t%s' % (i+1, code[line-1]) err = err + "%d %s\n" % (i+1, msg) errNums = [','.join(n) for n in errNums] maxlen = max(map(len, errNums)) code = [errNums[i] + " "*(maxlen-len(errNums[i])) + line for i, line in enumerate(code)] err = err + '\n'.join(code) raise Exception(err) else: raise return self.compiled class VertexShader(Shader): def __init__(self, code): Shader.__init__(self, GL_VERTEX_SHADER, code) class FragmentShader(Shader): def __init__(self, code): Shader.__init__(self, GL_FRAGMENT_SHADER, code) class ShaderProgram(object): names = {} def __init__(self, name, shaders, uniforms=None): self.name = name ShaderProgram.names[name] = self self.shaders = shaders self.prog = None self.blockData = {} self.uniformData = {} ## parse extra options from the shader definition if uniforms is not None: for k,v in uniforms.items(): self[k] = v def setBlockData(self, blockName, data): if data is None: del self.blockData[blockName] else: self.blockData[blockName] = data def setUniformData(self, uniformName, data): if data is None: del self.uniformData[uniformName] else: self.uniformData[uniformName] = data def __setitem__(self, item, val): self.setUniformData(item, val) def __delitem__(self, item): self.setUniformData(item, None) def program(self): if self.prog is None: try: compiled = [s.shader() for s in self.shaders] ## compile all shaders self.prog = shaders.compileProgram(*compiled) ## compile program except: self.prog = -1 raise return self.prog def __enter__(self): if len(self.shaders) > 0 and self.program() != -1: glUseProgram(self.program()) try: ## load uniform values into program for uniformName, data in self.uniformData.items(): loc = self.uniform(uniformName) if loc == -1: raise Exception('Could not find uniform variable "%s"' % uniformName) glUniform1fv(loc, len(data), data) ### bind buffer data to program blocks #if len(self.blockData) > 0: #bindPoint = 1 #for blockName, data in self.blockData.items(): ### Program should have a uniform block declared: ### ### layout (std140) uniform blockName { ### vec4 diffuse; ### }; ### pick any-old binding point. (there are a limited number of these per-program #bindPoint = 1 ### get the block index for a uniform variable in the shader #blockIndex = glGetUniformBlockIndex(self.program(), blockName) ### give the shader block a binding point #glUniformBlockBinding(self.program(), blockIndex, bindPoint) ### create a buffer #buf = glGenBuffers(1) #glBindBuffer(GL_UNIFORM_BUFFER, buf) #glBufferData(GL_UNIFORM_BUFFER, size, data, GL_DYNAMIC_DRAW) ### also possible to use glBufferSubData to fill parts of the buffer ### bind buffer to the same binding point #glBindBufferBase(GL_UNIFORM_BUFFER, bindPoint, buf) except: glUseProgram(0) raise def __exit__(self, *args): if len(self.shaders) > 0: glUseProgram(0) def uniform(self, name): """Return the location integer for a uniform variable in this program""" return glGetUniformLocation(self.program(), name.encode('utf_8')) #def uniformBlockInfo(self, blockName): #blockIndex = glGetUniformBlockIndex(self.program(), blockName) #count = glGetActiveUniformBlockiv(self.program(), blockIndex, GL_UNIFORM_BLOCK_ACTIVE_UNIFORMS) #indices = [] #for i in range(count): #indices.append(glGetActiveUniformBlockiv(self.program(), blockIndex, GL_UNIFORM_BLOCK_ACTIVE_UNIFORM_INDICES)) class HeightColorShader(ShaderProgram): def __enter__(self): ## Program should have a uniform block declared: ## ## layout (std140) uniform blockName { ## vec4 diffuse; ## vec4 ambient; ## }; ## pick any-old binding point. (there are a limited number of these per-program bindPoint = 1 ## get the block index for a uniform variable in the shader blockIndex = glGetUniformBlockIndex(self.program(), "blockName") ## give the shader block a binding point glUniformBlockBinding(self.program(), blockIndex, bindPoint) ## create a buffer buf = glGenBuffers(1) glBindBuffer(GL_UNIFORM_BUFFER, buf) glBufferData(GL_UNIFORM_BUFFER, size, data, GL_DYNAMIC_DRAW) ## also possible to use glBufferSubData to fill parts of the buffer ## bind buffer to the same binding point glBindBufferBase(GL_UNIFORM_BUFFER, bindPoint, buf) initShaders() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/ordereddict.py000066400000000000000000000077761300727121400225230ustar00rootroot00000000000000# Copyright (c) 2009 Raymond Hettinger # # Permission is hereby granted, free of charge, to any person # obtaining a copy of this software and associated documentation files # (the "Software"), to deal in the Software without restriction, # including without limitation the rights to use, copy, modify, merge, # publish, distribute, sublicense, and/or sell copies of the Software, # and to permit persons to whom the Software is furnished to do so, # subject to the following conditions: # # The above copyright notice and this permission notice shall be # included in all copies or substantial portions of the Software. # # THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, # EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES # OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND # NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT # HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, # WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING # FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR # OTHER DEALINGS IN THE SOFTWARE. from UserDict import DictMixin class OrderedDict(dict, DictMixin): def __init__(self, *args, **kwds): if len(args) > 1: raise TypeError('expected at most 1 arguments, got %d' % len(args)) try: self.__end except AttributeError: self.clear() self.update(*args, **kwds) def clear(self): self.__end = end = [] end += [None, end, end] # sentinel node for doubly linked list self.__map = {} # key --> [key, prev, next] dict.clear(self) def __setitem__(self, key, value): if key not in self: end = self.__end curr = end[1] curr[2] = end[1] = self.__map[key] = [key, curr, end] dict.__setitem__(self, key, value) def __delitem__(self, key): dict.__delitem__(self, key) key, prev, next = self.__map.pop(key) prev[2] = next next[1] = prev def __iter__(self): end = self.__end curr = end[2] while curr is not end: yield curr[0] curr = curr[2] def __reversed__(self): end = self.__end curr = end[1] while curr is not end: yield curr[0] curr = curr[1] def popitem(self, last=True): if not self: raise KeyError('dictionary is empty') if last: key = reversed(self).next() else: key = iter(self).next() value = self.pop(key) return key, value def __reduce__(self): items = [[k, self[k]] for k in self] tmp = self.__map, self.__end del self.__map, self.__end inst_dict = vars(self).copy() self.__map, self.__end = tmp if inst_dict: return (self.__class__, (items,), inst_dict) return self.__class__, (items,) def keys(self): return list(self) setdefault = DictMixin.setdefault update = DictMixin.update pop = DictMixin.pop values = DictMixin.values items = DictMixin.items iterkeys = DictMixin.iterkeys itervalues = DictMixin.itervalues iteritems = DictMixin.iteritems def __repr__(self): if not self: return '%s()' % (self.__class__.__name__,) return '%s(%r)' % (self.__class__.__name__, self.items()) def copy(self): return self.__class__(self) @classmethod def fromkeys(cls, iterable, value=None): d = cls() for key in iterable: d[key] = value return d def __eq__(self, other): if isinstance(other, OrderedDict): if len(self) != len(other): return False for p, q in zip(self.items(), other.items()): if p != q: return False return True return dict.__eq__(self, other) def __ne__(self, other): return not self == other pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/parametertree/000077500000000000000000000000001300727121400225005ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/parametertree/Parameter.py000066400000000000000000000771361300727121400250100ustar00rootroot00000000000000from ..Qt import QtGui, QtCore import os, weakref, re from ..pgcollections import OrderedDict from ..python2_3 import asUnicode, basestring from .ParameterItem import ParameterItem PARAM_TYPES = {} PARAM_NAMES = {} def registerParameterType(name, cls, override=False): global PARAM_TYPES if name in PARAM_TYPES and not override: raise Exception("Parameter type '%s' already exists (use override=True to replace)" % name) PARAM_TYPES[name] = cls PARAM_NAMES[cls] = name def __reload__(old): PARAM_TYPES.update(old.get('PARAM_TYPES', {})) PARAM_NAMES.update(old.get('PARAM_NAMES', {})) class Parameter(QtCore.QObject): """ A Parameter is the basic unit of data in a parameter tree. Each parameter has a name, a type, a value, and several other properties that modify the behavior of the Parameter. Parameters may have parent / child / sibling relationships to construct organized hierarchies. Parameters generally do not have any inherent GUI or visual interpretation; instead they manage ParameterItem instances which take care of display and user interaction. Note: It is fairly uncommon to use the Parameter class directly; mostly you will use subclasses which provide specialized type and data handling. The static pethod Parameter.create(...) is an easy way to generate instances of these subclasses. For more Parameter types, see ParameterTree.parameterTypes module. =================================== ========================================================= **Signals:** sigStateChanged(self, change, info) Emitted when anything changes about this parameter at all. The second argument is a string indicating what changed ('value', 'childAdded', etc..) The third argument can be any extra information about the change sigTreeStateChanged(self, changes) Emitted when any child in the tree changes state (but only if monitorChildren() is called) the format of *changes* is [(param, change, info), ...] sigValueChanged(self, value) Emitted when value is finished changing sigValueChanging(self, value) Emitted immediately for all value changes, including during editing. sigChildAdded(self, child, index) Emitted when a child is added sigChildRemoved(self, child) Emitted when a child is removed sigRemoved(self) Emitted when this parameter is removed sigParentChanged(self, parent) Emitted when this parameter's parent has changed sigLimitsChanged(self, limits) Emitted when this parameter's limits have changed sigDefaultChanged(self, default) Emitted when this parameter's default value has changed sigNameChanged(self, name) Emitted when this parameter's name has changed sigOptionsChanged(self, opts) Emitted when any of this parameter's options have changed =================================== ========================================================= """ ## name, type, limits, etc. ## can also carry UI hints (slider vs spinbox, etc.) sigValueChanged = QtCore.Signal(object, object) ## self, value emitted when value is finished being edited sigValueChanging = QtCore.Signal(object, object) ## self, value emitted as value is being edited sigChildAdded = QtCore.Signal(object, object, object) ## self, child, index sigChildRemoved = QtCore.Signal(object, object) ## self, child sigRemoved = QtCore.Signal(object) ## self sigParentChanged = QtCore.Signal(object, object) ## self, parent sigLimitsChanged = QtCore.Signal(object, object) ## self, limits sigDefaultChanged = QtCore.Signal(object, object) ## self, default sigNameChanged = QtCore.Signal(object, object) ## self, name sigOptionsChanged = QtCore.Signal(object, object) ## self, {opt:val, ...} ## Emitted when anything changes about this parameter at all. ## The second argument is a string indicating what changed ('value', 'childAdded', etc..) ## The third argument can be any extra information about the change sigStateChanged = QtCore.Signal(object, object, object) ## self, change, info ## emitted when any child in the tree changes state ## (but only if monitorChildren() is called) sigTreeStateChanged = QtCore.Signal(object, object) # self, changes # changes = [(param, change, info), ...] # bad planning. #def __new__(cls, *args, **opts): #try: #cls = PARAM_TYPES[opts['type']] #except KeyError: #pass #return QtCore.QObject.__new__(cls, *args, **opts) @staticmethod def create(**opts): """ Static method that creates a new Parameter (or subclass) instance using opts['type'] to select the appropriate class. All options are passed directly to the new Parameter's __init__ method. Use registerParameterType() to add new class types. """ typ = opts.get('type', None) if typ is None: cls = Parameter else: cls = PARAM_TYPES[opts['type']] return cls(**opts) def __init__(self, **opts): """ Initialize a Parameter object. Although it is rare to directly create a Parameter instance, the options available to this method are also allowed by most Parameter subclasses. ======================= ========================================================= **Keyword Arguments:** name The name to give this Parameter. This is the name that will appear in the left-most column of a ParameterTree for this Parameter. value The value to initially assign to this Parameter. default The default value for this Parameter (most Parameters provide an option to 'reset to default'). children A list of children for this Parameter. Children may be given either as a Parameter instance or as a dictionary to pass to Parameter.create(). In this way, it is possible to specify complex hierarchies of Parameters from a single nested data structure. readonly If True, the user will not be allowed to edit this Parameter. (default=False) enabled If False, any widget(s) for this parameter will appear disabled. (default=True) visible If False, the Parameter will not appear when displayed in a ParameterTree. (default=True) renamable If True, the user may rename this Parameter. (default=False) removable If True, the user may remove this Parameter. (default=False) expanded If True, the Parameter will appear expanded when displayed in a ParameterTree (its children will be visible). (default=True) title (str or None) If specified, then the parameter will be displayed to the user using this string as its name. However, the parameter will still be referred to internally using the *name* specified above. Note that this option is not compatible with renamable=True. (default=None; added in version 0.9.9) ======================= ========================================================= """ QtCore.QObject.__init__(self) self.opts = { 'type': None, 'readonly': False, 'visible': True, 'enabled': True, 'renamable': False, 'removable': False, 'strictNaming': False, # forces name to be usable as a python variable 'expanded': True, 'title': None, #'limits': None, ## This is a bad plan--each parameter type may have a different data type for limits. } self.opts.update(opts) self.childs = [] self.names = {} ## map name:child self.items = weakref.WeakKeyDictionary() ## keeps track of tree items representing this parameter self._parent = None self.treeStateChanges = [] ## cache of tree state changes to be delivered on next emit self.blockTreeChangeEmit = 0 #self.monitoringChildren = False ## prevent calling monitorChildren more than once if 'value' not in self.opts: self.opts['value'] = None if 'name' not in self.opts or not isinstance(self.opts['name'], basestring): raise Exception("Parameter must have a string name specified in opts.") self.setName(opts['name']) self.addChildren(self.opts.get('children', [])) if 'value' in self.opts and 'default' not in self.opts: self.opts['default'] = self.opts['value'] ## Connect all state changed signals to the general sigStateChanged self.sigValueChanged.connect(lambda param, data: self.emitStateChanged('value', data)) self.sigChildAdded.connect(lambda param, *data: self.emitStateChanged('childAdded', data)) self.sigChildRemoved.connect(lambda param, data: self.emitStateChanged('childRemoved', data)) self.sigParentChanged.connect(lambda param, data: self.emitStateChanged('parent', data)) self.sigLimitsChanged.connect(lambda param, data: self.emitStateChanged('limits', data)) self.sigDefaultChanged.connect(lambda param, data: self.emitStateChanged('default', data)) self.sigNameChanged.connect(lambda param, data: self.emitStateChanged('name', data)) self.sigOptionsChanged.connect(lambda param, data: self.emitStateChanged('options', data)) #self.watchParam(self) ## emit treechange signals if our own state changes def name(self): """Return the name of this Parameter.""" return self.opts['name'] def setName(self, name): """Attempt to change the name of this parameter; return the actual name. (The parameter may reject the name change or automatically pick a different name)""" if self.opts['strictNaming']: if len(name) < 1 or re.search(r'\W', name) or re.match(r'\d', name[0]): raise Exception("Parameter name '%s' is invalid. (Must contain only alphanumeric and underscore characters and may not start with a number)" % name) parent = self.parent() if parent is not None: name = parent._renameChild(self, name) ## first ask parent if it's ok to rename if self.opts['name'] != name: self.opts['name'] = name self.sigNameChanged.emit(self, name) return name def type(self): """Return the type string for this Parameter.""" return self.opts['type'] def isType(self, typ): """ Return True if this parameter type matches the name *typ*. This can occur either of two ways: - If self.type() == *typ* - If this parameter's class is registered with the name *typ* """ if self.type() == typ: return True global PARAM_TYPES cls = PARAM_TYPES.get(typ, None) if cls is None: raise Exception("Type name '%s' is not registered." % str(typ)) return self.__class__ is cls def childPath(self, child): """ Return the path of parameter names from self to child. If child is not a (grand)child of self, return None. """ path = [] while child is not self: path.insert(0, child.name()) child = child.parent() if child is None: return None return path def setValue(self, value, blockSignal=None): """ Set the value of this Parameter; return the actual value that was set. (this may be different from the value that was requested) """ try: if blockSignal is not None: self.sigValueChanged.disconnect(blockSignal) if self.opts['value'] == value: return value self.opts['value'] = value self.sigValueChanged.emit(self, value) finally: if blockSignal is not None: self.sigValueChanged.connect(blockSignal) return value def value(self): """ Return the value of this Parameter. """ return self.opts['value'] def getValues(self): """Return a tree of all values that are children of this parameter""" vals = OrderedDict() for ch in self: vals[ch.name()] = (ch.value(), ch.getValues()) return vals def saveState(self, filter=None): """ Return a structure representing the entire state of the parameter tree. The tree state may be restored from this structure using restoreState(). If *filter* is set to 'user', then only user-settable data will be included in the returned state. """ if filter is None: state = self.opts.copy() if state['type'] is None: global PARAM_NAMES state['type'] = PARAM_NAMES.get(type(self), None) elif filter == 'user': state = {'value': self.value()} else: raise ValueError("Unrecognized filter argument: '%s'" % filter) ch = OrderedDict([(ch.name(), ch.saveState(filter=filter)) for ch in self]) if len(ch) > 0: state['children'] = ch return state def restoreState(self, state, recursive=True, addChildren=True, removeChildren=True, blockSignals=True): """ Restore the state of this parameter and its children from a structure generated using saveState() If recursive is True, then attempt to restore the state of child parameters as well. If addChildren is True, then any children which are referenced in the state object will be created if they do not already exist. If removeChildren is True, then any children which are not referenced in the state object will be removed. If blockSignals is True, no signals will be emitted until the tree has been completely restored. This prevents signal handlers from responding to a partially-rebuilt network. """ state = state.copy() childState = state.pop('children', []) ## list of children may be stored either as list or dict. if isinstance(childState, dict): cs = [] for k,v in childState.items(): cs.append(v.copy()) cs[-1].setdefault('name', k) childState = cs if blockSignals: self.blockTreeChangeSignal() try: self.setOpts(**state) if not recursive: return ptr = 0 ## pointer to first child that has not been restored yet foundChilds = set() #print "==============", self.name() for ch in childState: name = ch['name'] #typ = ch.get('type', None) #print('child: %s, %s' % (self.name()+'.'+name, typ)) ## First, see if there is already a child with this name gotChild = False for i, ch2 in enumerate(self.childs[ptr:]): #print " ", ch2.name(), ch2.type() if ch2.name() != name: # or not ch2.isType(typ): continue gotChild = True #print " found it" if i != 0: ## move parameter to next position #self.removeChild(ch2) self.insertChild(ptr, ch2) #print " moved to position", ptr ch2.restoreState(ch, recursive=recursive, addChildren=addChildren, removeChildren=removeChildren) foundChilds.add(ch2) break if not gotChild: if not addChildren: #print " ignored child" continue #print " created new" ch2 = Parameter.create(**ch) self.insertChild(ptr, ch2) foundChilds.add(ch2) ptr += 1 if removeChildren: for ch in self.childs[:]: if ch not in foundChilds: #print " remove:", ch self.removeChild(ch) finally: if blockSignals: self.unblockTreeChangeSignal() def defaultValue(self): """Return the default value for this parameter.""" return self.opts['default'] def setDefault(self, val): """Set the default value for this parameter.""" if self.opts['default'] == val: return self.opts['default'] = val self.sigDefaultChanged.emit(self, val) def setToDefault(self): """Set this parameter's value to the default.""" if self.hasDefault(): self.setValue(self.defaultValue()) def hasDefault(self): """Returns True if this parameter has a default value.""" return 'default' in self.opts def valueIsDefault(self): """Returns True if this parameter's value is equal to the default value.""" return self.value() == self.defaultValue() def setLimits(self, limits): """Set limits on the acceptable values for this parameter. The format of limits depends on the type of the parameter and some parameters do not make use of limits at all.""" if 'limits' in self.opts and self.opts['limits'] == limits: return self.opts['limits'] = limits self.sigLimitsChanged.emit(self, limits) return limits def writable(self): """ Returns True if this parameter's value can be changed by the user. Note that the value of the parameter can *always* be changed by calling setValue(). """ return not self.readonly() def setWritable(self, writable=True): """Set whether this Parameter should be editable by the user. (This is exactly the opposite of setReadonly).""" self.setOpts(readonly=not writable) def readonly(self): """ Return True if this parameter is read-only. (this is the opposite of writable()) """ return self.opts.get('readonly', False) def setReadonly(self, readonly=True): """Set whether this Parameter's value may be edited by the user (this is the opposite of setWritable()).""" self.setOpts(readonly=readonly) def setOpts(self, **opts): """ Set any arbitrary options on this parameter. The exact behavior of this function will depend on the parameter type, but most parameters will accept a common set of options: value, name, limits, default, readonly, removable, renamable, visible, enabled, and expanded. See :func:`Parameter.__init__ ` for more information on default options. """ changed = OrderedDict() for k in opts: if k == 'value': self.setValue(opts[k]) elif k == 'name': self.setName(opts[k]) elif k == 'limits': self.setLimits(opts[k]) elif k == 'default': self.setDefault(opts[k]) elif k not in self.opts or self.opts[k] != opts[k]: self.opts[k] = opts[k] changed[k] = opts[k] if len(changed) > 0: self.sigOptionsChanged.emit(self, changed) def emitStateChanged(self, changeDesc, data): ## Emits stateChanged signal and ## requests emission of new treeStateChanged signal self.sigStateChanged.emit(self, changeDesc, data) #self.treeStateChanged(self, changeDesc, data) self.treeStateChanges.append((self, changeDesc, data)) self.emitTreeChanges() def makeTreeItem(self, depth): """ Return a TreeWidgetItem suitable for displaying/controlling the content of this parameter. This is called automatically when a ParameterTree attempts to display this Parameter. Most subclasses will want to override this function. """ if hasattr(self, 'itemClass'): #print "Param:", self, "Make item from itemClass:", self.itemClass return self.itemClass(self, depth) else: return ParameterItem(self, depth=depth) def addChild(self, child, autoIncrementName=None): """ Add another parameter to the end of this parameter's child list. See insertChild() for a description of the *autoIncrementName* argument. """ return self.insertChild(len(self.childs), child, autoIncrementName=autoIncrementName) def addChildren(self, children): """ Add a list or dict of children to this parameter. This method calls addChild once for each value in *children*. """ ## If children was specified as dict, then assume keys are the names. if isinstance(children, dict): ch2 = [] for name, opts in children.items(): if isinstance(opts, dict) and 'name' not in opts: opts = opts.copy() opts['name'] = name ch2.append(opts) children = ch2 for chOpts in children: #print self, "Add child:", type(chOpts), id(chOpts) self.addChild(chOpts) def insertChild(self, pos, child, autoIncrementName=None): """ Insert a new child at pos. If pos is a Parameter, then insert at the position of that Parameter. If child is a dict, then a parameter is constructed using :func:`Parameter.create `. By default, the child's 'autoIncrementName' option determines whether the name will be adjusted to avoid prior name collisions. This behavior may be overridden by specifying the *autoIncrementName* argument. This argument was added in version 0.9.9. """ if isinstance(child, dict): child = Parameter.create(**child) name = child.name() if name in self.names and child is not self.names[name]: if autoIncrementName is True or (autoIncrementName is None and child.opts.get('autoIncrementName', False)): name = self.incrementName(name) child.setName(name) else: raise Exception("Already have child named %s" % str(name)) if isinstance(pos, Parameter): pos = self.childs.index(pos) with self.treeChangeBlocker(): if child.parent() is not None: child.remove() self.names[name] = child self.childs.insert(pos, child) child.parentChanged(self) self.sigChildAdded.emit(self, child, pos) child.sigTreeStateChanged.connect(self.treeStateChanged) return child def removeChild(self, child): """Remove a child parameter.""" name = child.name() if name not in self.names or self.names[name] is not child: raise Exception("Parameter %s is not my child; can't remove." % str(child)) del self.names[name] self.childs.pop(self.childs.index(child)) child.parentChanged(None) self.sigChildRemoved.emit(self, child) try: child.sigTreeStateChanged.disconnect(self.treeStateChanged) except (TypeError, RuntimeError): ## already disconnected pass def clearChildren(self): """Remove all child parameters.""" for ch in self.childs[:]: self.removeChild(ch) def children(self): """Return a list of this parameter's children. Warning: this overrides QObject.children """ return self.childs[:] def hasChildren(self): """Return True if this Parameter has children.""" return len(self.childs) > 0 def parentChanged(self, parent): """This method is called when the parameter's parent has changed. It may be useful to extend this method in subclasses.""" self._parent = parent self.sigParentChanged.emit(self, parent) def parent(self): """Return the parent of this parameter.""" return self._parent def remove(self): """Remove this parameter from its parent's child list""" parent = self.parent() if parent is None: raise Exception("Cannot remove; no parent.") parent.removeChild(self) self.sigRemoved.emit(self) def incrementName(self, name): ## return an unused name by adding a number to the name given base, num = re.match('(.*)(\d*)', name).groups() numLen = len(num) if numLen == 0: num = 2 numLen = 1 else: num = int(num) while True: newName = base + ("%%0%dd"%numLen) % num if newName not in self.names: return newName num += 1 def __iter__(self): for ch in self.childs: yield ch def __getitem__(self, names): """Get the value of a child parameter. The name may also be a tuple giving the path to a sub-parameter:: value = param[('child', 'grandchild')] """ if not isinstance(names, tuple): names = (names,) return self.param(*names).value() def __setitem__(self, names, value): """Set the value of a child parameter. The name may also be a tuple giving the path to a sub-parameter:: param[('child', 'grandchild')] = value """ if isinstance(names, basestring): names = (names,) return self.param(*names).setValue(value) def child(self, *names): """Return a child parameter. Accepts the name of the child or a tuple (path, to, child) Added in version 0.9.9. Ealier versions used the 'param' method, which is still implemented for backward compatibility.""" try: param = self.names[names[0]] except KeyError: raise Exception("Parameter %s has no child named %s" % (self.name(), names[0])) if len(names) > 1: return param.param(*names[1:]) else: return param def param(self, *names): # for backward compatibility. return self.child(*names) def __repr__(self): return asUnicode("<%s '%s' at 0x%x>") % (self.__class__.__name__, self.name(), id(self)) def __getattr__(self, attr): ## Leaving this undocumented because I might like to remove it in the future.. #print type(self), attr if 'names' not in self.__dict__: raise AttributeError(attr) if attr in self.names: import traceback traceback.print_stack() print("Warning: Use of Parameter.subParam is deprecated. Use Parameter.param(name) instead.") return self.param(attr) else: raise AttributeError(attr) def _renameChild(self, child, name): ## Only to be called from Parameter.rename if name in self.names: return child.name() self.names[name] = child del self.names[child.name()] return name def registerItem(self, item): self.items[item] = None def hide(self): """Hide this parameter. It and its children will no longer be visible in any ParameterTree widgets it is connected to.""" self.show(False) def show(self, s=True): """Show this parameter. """ self.opts['visible'] = s self.sigOptionsChanged.emit(self, {'visible': s}) def treeChangeBlocker(self): """ Return an object that can be used to temporarily block and accumulate sigTreeStateChanged signals. This is meant to be used when numerous changes are about to be made to the tree and only one change signal should be emitted at the end. Example:: with param.treeChangeBlocker(): param.addChild(...) param.removeChild(...) param.setValue(...) """ return SignalBlocker(self.blockTreeChangeSignal, self.unblockTreeChangeSignal) def blockTreeChangeSignal(self): """ Used to temporarily block and accumulate tree change signals. *You must remember to unblock*, so it is advisable to use treeChangeBlocker() instead. """ self.blockTreeChangeEmit += 1 def unblockTreeChangeSignal(self): """Unblocks enission of sigTreeStateChanged and flushes the changes out through a single signal.""" self.blockTreeChangeEmit -= 1 self.emitTreeChanges() def treeStateChanged(self, param, changes): """ Called when the state of any sub-parameter has changed. ============== ================================================================ **Arguments:** param The immediate child whose tree state has changed. note that the change may have originated from a grandchild. changes List of tuples describing all changes that have been made in this event: (param, changeDescr, data) ============== ================================================================ This function can be extended to react to tree state changes. """ self.treeStateChanges.extend(changes) self.emitTreeChanges() def emitTreeChanges(self): if self.blockTreeChangeEmit == 0: changes = self.treeStateChanges self.treeStateChanges = [] if len(changes) > 0: self.sigTreeStateChanged.emit(self, changes) class SignalBlocker(object): def __init__(self, enterFn, exitFn): self.enterFn = enterFn self.exitFn = exitFn def __enter__(self): self.enterFn() def __exit__(self, exc_type, exc_value, tb): self.exitFn() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/parametertree/ParameterItem.py000066400000000000000000000146151300727121400256200ustar00rootroot00000000000000from ..Qt import QtGui, QtCore from ..python2_3 import asUnicode import os, weakref, re class ParameterItem(QtGui.QTreeWidgetItem): """ Abstract ParameterTree item. Used to represent the state of a Parameter from within a ParameterTree. - Sets first column of item to name - generates context menu if item is renamable or removable - handles child added / removed events - provides virtual functions for handling changes from parameter For more ParameterItem types, see ParameterTree.parameterTypes module. """ def __init__(self, param, depth=0): title = param.opts.get('title', None) if title is None: title = param.name() QtGui.QTreeWidgetItem.__init__(self, [title, '']) self.param = param self.param.registerItem(self) ## let parameter know this item is connected to it (for debugging) self.depth = depth param.sigValueChanged.connect(self.valueChanged) param.sigChildAdded.connect(self.childAdded) param.sigChildRemoved.connect(self.childRemoved) param.sigNameChanged.connect(self.nameChanged) param.sigLimitsChanged.connect(self.limitsChanged) param.sigDefaultChanged.connect(self.defaultChanged) param.sigOptionsChanged.connect(self.optsChanged) param.sigParentChanged.connect(self.parentChanged) opts = param.opts ## Generate context menu for renaming/removing parameter self.contextMenu = QtGui.QMenu() self.contextMenu.addSeparator() flags = QtCore.Qt.ItemIsSelectable | QtCore.Qt.ItemIsEnabled if opts.get('renamable', False): if param.opts.get('title', None) is not None: raise Exception("Cannot make parameter with both title != None and renamable == True.") flags |= QtCore.Qt.ItemIsEditable self.contextMenu.addAction('Rename').triggered.connect(self.editName) if opts.get('removable', False): self.contextMenu.addAction("Remove").triggered.connect(self.requestRemove) ## handle movable / dropEnabled options if opts.get('movable', False): flags |= QtCore.Qt.ItemIsDragEnabled if opts.get('dropEnabled', False): flags |= QtCore.Qt.ItemIsDropEnabled self.setFlags(flags) ## flag used internally during name editing self.ignoreNameColumnChange = False def valueChanged(self, param, val): ## called when the parameter's value has changed pass def isFocusable(self): """Return True if this item should be included in the tab-focus order""" return False def setFocus(self): """Give input focus to this item. Can be reimplemented to display editor widgets, etc. """ pass def focusNext(self, forward=True): """Give focus to the next (or previous) focusable item in the parameter tree""" self.treeWidget().focusNext(self, forward=forward) def treeWidgetChanged(self): """Called when this item is added or removed from a tree. Expansion, visibility, and column widgets must all be configured AFTER the item is added to a tree, not during __init__. """ self.setHidden(not self.param.opts.get('visible', True)) self.setExpanded(self.param.opts.get('expanded', True)) def childAdded(self, param, child, pos): item = child.makeTreeItem(depth=self.depth+1) self.insertChild(pos, item) item.treeWidgetChanged() for i, ch in enumerate(child): item.childAdded(child, ch, i) def childRemoved(self, param, child): for i in range(self.childCount()): item = self.child(i) if item.param is child: self.takeChild(i) break def parentChanged(self, param, parent): ## called when the parameter's parent has changed. pass def contextMenuEvent(self, ev): if not self.param.opts.get('removable', False) and not self.param.opts.get('renamable', False): return self.contextMenu.popup(ev.globalPos()) def columnChangedEvent(self, col): """Called when the text in a column has been edited (or otherwise changed). By default, we only use changes to column 0 to rename the parameter. """ if col == 0 and (self.param.opts.get('title', None) is None): if self.ignoreNameColumnChange: return try: newName = self.param.setName(asUnicode(self.text(col))) except Exception: self.setText(0, self.param.name()) raise try: self.ignoreNameColumnChange = True self.nameChanged(self, newName) ## If the parameter rejects the name change, we need to set it back. finally: self.ignoreNameColumnChange = False def nameChanged(self, param, name): ## called when the parameter's name has changed. if self.param.opts.get('title', None) is None: self.setText(0, name) def limitsChanged(self, param, limits): """Called when the parameter's limits have changed""" pass def defaultChanged(self, param, default): """Called when the parameter's default value has changed""" pass def optsChanged(self, param, opts): """Called when any options are changed that are not name, value, default, or limits""" #print opts if 'visible' in opts: self.setHidden(not opts['visible']) def editName(self): self.treeWidget().editItem(self, 0) def selected(self, sel): """Called when this item has been selected (sel=True) OR deselected (sel=False)""" pass def requestRemove(self): ## called when remove is selected from the context menu. ## we need to delay removal until the action is complete ## since destroying the menu in mid-action will cause a crash. QtCore.QTimer.singleShot(0, self.param.remove) ## for python 3 support, we need to redefine hash and eq methods. def __hash__(self): return id(self) def __eq__(self, x): return x is self pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/parametertree/ParameterSystem.py000066400000000000000000000107661300727121400262110ustar00rootroot00000000000000from .parameterTypes import GroupParameter from .. import functions as fn from .SystemSolver import SystemSolver class ParameterSystem(GroupParameter): """ ParameterSystem is a subclass of GroupParameter that manages a tree of sub-parameters with a set of interdependencies--changing any one parameter may affect other parameters in the system. See parametertree/SystemSolver for more information. NOTE: This API is experimental and may change substantially across minor version numbers. """ def __init__(self, *args, **kwds): GroupParameter.__init__(self, *args, **kwds) self._system = None self._fixParams = [] # all auto-generated 'fixed' params sys = kwds.pop('system', None) if sys is not None: self.setSystem(sys) self._ignoreChange = [] # params whose changes should be ignored temporarily self.sigTreeStateChanged.connect(self.updateSystem) def setSystem(self, sys): self._system = sys # auto-generate defaults to match child parameters defaults = {} vals = {} for param in self: name = param.name() constraints = '' if hasattr(sys, '_' + name): constraints += 'n' if not param.readonly(): constraints += 'f' if 'n' in constraints: ch = param.addChild(dict(name='fixed', type='bool', value=False)) self._fixParams.append(ch) param.setReadonly(True) param.setOpts(expanded=False) else: vals[name] = param.value() ch = param.addChild(dict(name='fixed', type='bool', value=True, readonly=True)) #self._fixParams.append(ch) defaults[name] = [None, param.type(), None, constraints] sys.defaultState.update(defaults) sys.reset() for name, value in vals.items(): setattr(sys, name, value) self.updateAllParams() def updateSystem(self, param, changes): changes = [ch for ch in changes if ch[0] not in self._ignoreChange] #resets = [ch[0] for ch in changes if ch[1] == 'setToDefault'] sets = [ch[0] for ch in changes if ch[1] == 'value'] #for param in resets: #setattr(self._system, param.name(), None) for param in sets: #if param in resets: #continue #if param in self._fixParams: #param.parent().setWritable(param.value()) #else: if param in self._fixParams: parent = param.parent() if param.value(): setattr(self._system, parent.name(), parent.value()) else: setattr(self._system, parent.name(), None) else: setattr(self._system, param.name(), param.value()) self.updateAllParams() def updateAllParams(self): try: self.sigTreeStateChanged.disconnect(self.updateSystem) for name, state in self._system._vars.items(): param = self.child(name) try: v = getattr(self._system, name) if self._system._vars[name][2] is None: self.updateParamState(self.child(name), 'autoSet') param.setValue(v) else: self.updateParamState(self.child(name), 'fixed') except RuntimeError: self.updateParamState(param, 'autoUnset') finally: self.sigTreeStateChanged.connect(self.updateSystem) def updateParamState(self, param, state): if state == 'autoSet': bg = fn.mkBrush((200, 255, 200, 255)) bold = False readonly = True elif state == 'autoUnset': bg = fn.mkBrush(None) bold = False readonly = False elif state == 'fixed': bg = fn.mkBrush('y') bold = True readonly = False param.setReadonly(readonly) #for item in param.items: #item.setBackground(0, bg) #f = item.font(0) #f.setWeight(f.Bold if bold else f.Normal) #item.setFont(0, f) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/parametertree/ParameterTree.py000066400000000000000000000130361300727121400256150ustar00rootroot00000000000000from ..Qt import QtCore, QtGui from ..widgets.TreeWidget import TreeWidget import os, weakref, re from .ParameterItem import ParameterItem #import functions as fn class ParameterTree(TreeWidget): """Widget used to display or control data from a hierarchy of Parameters""" def __init__(self, parent=None, showHeader=True): """ ============== ======================================================== **Arguments:** parent (QWidget) An optional parent widget showHeader (bool) If True, then the QTreeView header is displayed. ============== ======================================================== """ TreeWidget.__init__(self, parent) self.setVerticalScrollMode(self.ScrollPerPixel) self.setHorizontalScrollMode(self.ScrollPerPixel) self.setAnimated(False) self.setColumnCount(2) self.setHeaderLabels(["Parameter", "Value"]) self.setAlternatingRowColors(True) self.paramSet = None self.header().setResizeMode(QtGui.QHeaderView.ResizeToContents) self.setHeaderHidden(not showHeader) self.itemChanged.connect(self.itemChangedEvent) self.lastSel = None self.setRootIsDecorated(False) def setParameters(self, param, showTop=True): """ Set the top-level :class:`Parameter ` to be displayed in this ParameterTree. If *showTop* is False, then the top-level parameter is hidden and only its children will be visible. This is a convenience method equivalent to:: tree.clear() tree.addParameters(param, showTop) """ self.clear() self.addParameters(param, showTop=showTop) def addParameters(self, param, root=None, depth=0, showTop=True): """ Adds one top-level :class:`Parameter ` to the view. ============== ========================================================== **Arguments:** param The :class:`Parameter ` to add. root The item within the tree to which *param* should be added. By default, *param* is added as a top-level item. showTop If False, then *param* will be hidden, and only its children will be visible in the tree. ============== ========================================================== """ item = param.makeTreeItem(depth=depth) if root is None: root = self.invisibleRootItem() ## Hide top-level item if not showTop: item.setText(0, '') item.setSizeHint(0, QtCore.QSize(1,1)) item.setSizeHint(1, QtCore.QSize(1,1)) depth -= 1 root.addChild(item) item.treeWidgetChanged() for ch in param: self.addParameters(ch, root=item, depth=depth+1) def clear(self): """ Remove all parameters from the tree. """ self.invisibleRootItem().takeChildren() def focusNext(self, item, forward=True): """Give input focus to the next (or previous) item after *item* """ while True: parent = item.parent() if parent is None: return nextItem = self.nextFocusableChild(parent, item, forward=forward) if nextItem is not None: nextItem.setFocus() self.setCurrentItem(nextItem) return item = parent def focusPrevious(self, item): self.focusNext(item, forward=False) def nextFocusableChild(self, root, startItem=None, forward=True): if startItem is None: if forward: index = 0 else: index = root.childCount()-1 else: if forward: index = root.indexOfChild(startItem) + 1 else: index = root.indexOfChild(startItem) - 1 if forward: inds = list(range(index, root.childCount())) else: inds = list(range(index, -1, -1)) for i in inds: item = root.child(i) if hasattr(item, 'isFocusable') and item.isFocusable(): return item else: item = self.nextFocusableChild(item, forward=forward) if item is not None: return item return None def contextMenuEvent(self, ev): item = self.currentItem() if hasattr(item, 'contextMenuEvent'): item.contextMenuEvent(ev) def itemChangedEvent(self, item, col): if hasattr(item, 'columnChangedEvent'): item.columnChangedEvent(col) def selectionChanged(self, *args): sel = self.selectedItems() if len(sel) != 1: sel = None if self.lastSel is not None and isinstance(self.lastSel, ParameterItem): self.lastSel.selected(False) if sel is None: self.lastSel = None return self.lastSel = sel[0] if hasattr(sel[0], 'selected'): sel[0].selected(True) return TreeWidget.selectionChanged(self, *args) def wheelEvent(self, ev): self.clearSelection() return TreeWidget.wheelEvent(self, ev) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/parametertree/SystemSolver.py000066400000000000000000000375321300727121400255430ustar00rootroot00000000000000from ..pgcollections import OrderedDict import numpy as np class SystemSolver(object): """ This abstract class is used to formalize and manage user interaction with a complex system of equations (related to "constraint satisfaction problems"). It is often the case that devices must be controlled through a large number of free variables, and interactions between these variables make the system difficult to manage and conceptualize as a user interface. This class does _not_ attempt to numerically solve the system of equations. Rather, it provides a framework for subdividing the system into manageable pieces and specifying closed-form solutions to these small pieces. For an example, see the simple Camera class below. Theory of operation: Conceptualize the system as 1) a set of variables whose values may be either user-specified or automatically generated, and 2) a set of functions that define *how* each variable should be generated. When a variable is accessed (as an instance attribute), the solver first checks to see if it already has a value (either user-supplied, or cached from a previous calculation). If it does not, then the solver calls a method on itself (the method must be named `_variableName`) that will either return the calculated value (which usually involves acccessing other variables in the system), or raise RuntimeError if it is unable to calculate the value (usually because the user has not provided sufficient input to fully constrain the system). Each method that calculates a variable value may include multiple try/except blocks, so that if one method generates a RuntimeError, it may fall back on others. In this way, the system may be solved by recursively searching the tree of possible relationships between variables. This allows the user flexibility in deciding which variables are the most important to specify, while avoiding the apparent combinatorial explosion of calculation pathways that must be considered by the developer. Solved values are cached for efficiency, and automatically cleared when a state change invalidates the cache. The rules for this are simple: any time a value is set, it invalidates the cache *unless* the previous value was None (which indicates that no other variable has yet requested that value). More complex cache management may be defined in subclasses. Subclasses must define: 1) The *defaultState* class attribute: This is a dict containing a description of the variables in the system--their default values, data types, and the ways they can be constrained. The format is:: { name: [value, type, constraint, allowed_constraints], ...} * *value* is the default value. May be None if it has not been specified yet. * *type* may be float, int, bool, np.ndarray, ... * *constraint* may be None, single value, or (min, max) * None indicates that the value is not constrained--it may be automatically generated if the value is requested. * *allowed_constraints* is a string composed of (n)one, (f)ixed, and (r)ange. Note: do not put mutable objects inside defaultState! 2) For each variable that may be automatically determined, a method must be defined with the name `_variableName`. This method may either return the """ defaultState = OrderedDict() def __init__(self): self.__dict__['_vars'] = OrderedDict() self.__dict__['_currentGets'] = set() self.reset() def reset(self): """ Reset all variables in the solver to their default state. """ self._currentGets.clear() for k in self.defaultState: self._vars[k] = self.defaultState[k][:] def __getattr__(self, name): if name in self._vars: return self.get(name) raise AttributeError(name) def __setattr__(self, name, value): """ Set the value of a state variable. If None is given for the value, then the constraint will also be set to None. If a tuple is given for a scalar variable, then the tuple is used as a range constraint instead of a value. Otherwise, the constraint is set to 'fixed'. """ # First check this is a valid attribute if name in self._vars: if value is None: self.set(name, value, None) elif isinstance(value, tuple) and self._vars[name][1] is not np.ndarray: self.set(name, None, value) else: self.set(name, value, 'fixed') else: # also allow setting any other pre-existing attribute if hasattr(self, name): object.__setattr__(self, name, value) else: raise AttributeError(name) def get(self, name): """ Return the value for parameter *name*. If the value has not been specified, then attempt to compute it from other interacting parameters. If no value can be determined, then raise RuntimeError. """ if name in self._currentGets: raise RuntimeError("Cyclic dependency while calculating '%s'." % name) self._currentGets.add(name) try: v = self._vars[name][0] if v is None: cfunc = getattr(self, '_' + name, None) if cfunc is None: v = None else: v = cfunc() if v is None: raise RuntimeError("Parameter '%s' is not specified." % name) v = self.set(name, v) finally: self._currentGets.remove(name) return v def set(self, name, value=None, constraint=True): """ Set a variable *name* to *value*. The actual set value is returned (in some cases, the value may be cast into another type). If *value* is None, then the value is left to be determined in the future. At any time, the value may be re-assigned arbitrarily unless a constraint is given. If *constraint* is True (the default), then supplying a value that violates a previously specified constraint will raise an exception. If *constraint* is 'fixed', then the value is set (if provided) and the variable will not be updated automatically in the future. If *constraint* is a tuple, then the value is constrained to be within the given (min, max). Either constraint may be None to disable it. In some cases, a constraint cannot be satisfied automatically, and the user will be forced to resolve the constraint manually. If *constraint* is None, then any constraints are removed for the variable. """ var = self._vars[name] if constraint is None: if 'n' not in var[3]: raise TypeError("Empty constraints not allowed for '%s'" % name) var[2] = constraint elif constraint == 'fixed': if 'f' not in var[3]: raise TypeError("Fixed constraints not allowed for '%s'" % name) var[2] = constraint elif isinstance(constraint, tuple): if 'r' not in var[3]: raise TypeError("Range constraints not allowed for '%s'" % name) assert len(constraint) == 2 var[2] = constraint elif constraint is not True: raise TypeError("constraint must be None, True, 'fixed', or tuple. (got %s)" % constraint) # type checking / massaging if var[1] is np.ndarray: value = np.array(value, dtype=float) elif var[1] in (int, float, tuple) and value is not None: value = var[1](value) # constraint checks if constraint is True and not self.check_constraint(name, value): raise ValueError("Setting %s = %s violates constraint %s" % (name, value, var[2])) # invalidate other dependent values if var[0] is not None: # todo: we can make this more clever..(and might need to) # we just know that a value of None cannot have dependencies # (because if anyone else had asked for this value, it wouldn't be # None anymore) self.resetUnfixed() var[0] = value return value def check_constraint(self, name, value): c = self._vars[name][2] if c is None or value is None: return True if isinstance(c, tuple): return ((c[0] is None or c[0] <= value) and (c[1] is None or c[1] >= value)) else: return value == c def saveState(self): """ Return a serializable description of the solver's current state. """ state = OrderedDict() for name, var in self._vars.items(): state[name] = (var[0], var[2]) return state def restoreState(self, state): """ Restore the state of all values and constraints in the solver. """ self.reset() for name, var in state.items(): self.set(name, var[0], var[1]) def resetUnfixed(self): """ For any variable that does not have a fixed value, reset its value to None. """ for var in self._vars.values(): if var[2] != 'fixed': var[0] = None def solve(self): for k in self._vars: getattr(self, k) def __repr__(self): state = OrderedDict() for name, var in self._vars.items(): if var[2] == 'fixed': state[name] = var[0] state = ', '.join(["%s=%s" % (n, v) for n,v in state.items()]) return "<%s %s>" % (self.__class__.__name__, state) if __name__ == '__main__': class Camera(SystemSolver): """ Consider a simple SLR camera. The variables we will consider that affect the camera's behavior while acquiring a photo are aperture, shutter speed, ISO, and flash (of course there are many more, but let's keep the example simple). In rare cases, the user wants to manually specify each of these variables and no more work needs to be done to take the photo. More often, the user wants to specify more interesting constraints like depth of field, overall exposure, or maximum allowed ISO value. If we add a simple light meter measurement into this system and an 'exposure' variable that indicates the desired exposure (0 is "perfect", -1 is one stop darker, etc), then the system of equations governing the camera behavior would have the following variables: aperture, shutter, iso, flash, exposure, light meter The first four variables are the "outputs" of the system (they directly drive the camera), the last is a constant (the camera itself cannot affect the reading on the light meter), and 'exposure' specifies a desired relationship between other variables in the system. So the question is: how can I formalize a system like this as a user interface? Typical cameras have a fairly limited approach: provide the user with a list of modes, each of which defines a particular set of constraints. For example: manual: user provides aperture, shutter, iso, and flash aperture priority: user provides aperture and exposure, camera selects iso, shutter, and flash automatically shutter priority: user provides shutter and exposure, camera selects iso, aperture, and flash program: user specifies exposure, camera selects all other variables automatically action: camera selects all variables while attempting to maximize shutter speed portrait: camera selects all variables while attempting to minimize aperture A more general approach might allow the user to provide more explicit constraints on each variable (for example: I want a shutter speed of 1/30 or slower, an ISO no greater than 400, an exposure between -1 and 1, and the smallest aperture possible given all other constraints) and have the camera solve the system of equations, with a warning if no solution is found. This is exactly what we will implement in this example class. """ defaultState = OrderedDict([ # Field stop aperture ('aperture', [None, float, None, 'nf']), # Duration that shutter is held open. ('shutter', [None, float, None, 'nf']), # ISO (sensitivity) value. 100, 200, 400, 800, 1600.. ('iso', [None, int, None, 'nf']), # Flash is a value indicating the brightness of the flash. A table # is used to decide on "balanced" settings for each flash level: # 0: no flash # 1: s=1/60, a=2.0, iso=100 # 2: s=1/60, a=4.0, iso=100 ..and so on.. ('flash', [None, float, None, 'nf']), # exposure is a value indicating how many stops brighter (+1) or # darker (-1) the photographer would like the photo to appear from # the 'balanced' settings indicated by the light meter (see below). ('exposure', [None, float, None, 'f']), # Let's define this as an external light meter (not affected by # aperture) with logarithmic output. We arbitrarily choose the # following settings as "well balanced" for each light meter value: # -1: s=1/60, a=2.0, iso=100 # 0: s=1/60, a=4.0, iso=100 # 1: s=1/120, a=4.0, iso=100 ..and so on.. # Note that the only allowed constraint mode is (f)ixed, since the # camera never _computes_ the light meter value, it only reads it. ('lightMeter', [None, float, None, 'f']), # Indicates the camera's final decision on how it thinks the photo will # look, given the chosen settings. This value is _only_ determined # automatically. ('balance', [None, float, None, 'n']), ]) def _aperture(self): """ Determine aperture automatically under a variety of conditions. """ iso = self.iso exp = self.exposure light = self.lightMeter try: # shutter-priority mode sh = self.shutter # this raises RuntimeError if shutter has not # been specified ap = 4.0 * (sh / (1./60.)) * (iso / 100.) * (2 ** exp) * (2 ** light) ap = np.clip(ap, 2.0, 16.0) except RuntimeError: # program mode; we can select a suitable shutter # value at the same time. sh = (1./60.) raise return ap def _balance(self): iso = self.iso light = self.lightMeter sh = self.shutter ap = self.aperture fl = self.flash bal = (4.0 / ap) * (sh / (1./60.)) * (iso / 100.) * (2 ** light) return np.log2(bal) camera = Camera() camera.iso = 100 camera.exposure = 0 camera.lightMeter = 2 camera.shutter = 1./60. camera.flash = 0 camera.solve() print(camera.saveState()) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/parametertree/__init__.py000066400000000000000000000003521300727121400246110ustar00rootroot00000000000000from .Parameter import Parameter, registerParameterType from .ParameterTree import ParameterTree from .ParameterItem import ParameterItem from .ParameterSystem import ParameterSystem, SystemSolver from . import parameterTypes as typespyqtgraph-pyqtgraph-0.10.0/pyqtgraph/parametertree/parameterTypes.py000066400000000000000000000602211300727121400260600ustar00rootroot00000000000000from ..Qt import QtCore, QtGui from ..python2_3 import asUnicode from .Parameter import Parameter, registerParameterType from .ParameterItem import ParameterItem from ..widgets.SpinBox import SpinBox from ..widgets.ColorButton import ColorButton #from ..widgets.GradientWidget import GradientWidget ## creates import loop from .. import pixmaps as pixmaps from .. import functions as fn import os from ..pgcollections import OrderedDict class WidgetParameterItem(ParameterItem): """ ParameterTree item with: * label in second column for displaying value * simple widget for editing value (displayed instead of label when item is selected) * button that resets value to default ========================== ============================================================= **Registered Types:** int Displays a :class:`SpinBox ` in integer mode. float Displays a :class:`SpinBox `. bool Displays a QCheckBox str Displays a QLineEdit color Displays a :class:`ColorButton ` colormap Displays a :class:`GradientWidget ` ========================== ============================================================= This class can be subclassed by overriding makeWidget() to provide a custom widget. """ def __init__(self, param, depth): ParameterItem.__init__(self, param, depth) self.hideWidget = True ## hide edit widget, replace with label when not selected ## set this to False to keep the editor widget always visible ## build widget into column 1 with a display label and default button. w = self.makeWidget() self.widget = w self.eventProxy = EventProxy(w, self.widgetEventFilter) opts = self.param.opts if 'tip' in opts: w.setToolTip(opts['tip']) self.defaultBtn = QtGui.QPushButton() self.defaultBtn.setFixedWidth(20) self.defaultBtn.setFixedHeight(20) modDir = os.path.dirname(__file__) self.defaultBtn.setIcon(QtGui.QIcon(pixmaps.getPixmap('default'))) self.defaultBtn.clicked.connect(self.defaultClicked) self.displayLabel = QtGui.QLabel() layout = QtGui.QHBoxLayout() layout.setContentsMargins(0, 0, 0, 0) layout.setSpacing(2) layout.addWidget(w) layout.addWidget(self.displayLabel) layout.addWidget(self.defaultBtn) self.layoutWidget = QtGui.QWidget() self.layoutWidget.setLayout(layout) if w.sigChanged is not None: w.sigChanged.connect(self.widgetValueChanged) if hasattr(w, 'sigChanging'): w.sigChanging.connect(self.widgetValueChanging) ## update value shown in widget. if opts.get('value', None) is not None: self.valueChanged(self, opts['value'], force=True) else: ## no starting value was given; use whatever the widget has self.widgetValueChanged() self.updateDefaultBtn() def makeWidget(self): """ Return a single widget that should be placed in the second tree column. The widget must be given three attributes: ========== ============================================================ sigChanged a signal that is emitted when the widget's value is changed value a function that returns the value setValue a function that sets the value ========== ============================================================ This is a good function to override in subclasses. """ opts = self.param.opts t = opts['type'] if t in ('int', 'float'): defs = { 'value': 0, 'min': None, 'max': None, 'step': 1.0, 'dec': False, 'siPrefix': False, 'suffix': '', 'decimals': 3, } if t == 'int': defs['int'] = True defs['minStep'] = 1.0 for k in defs: if k in opts: defs[k] = opts[k] if 'limits' in opts: defs['bounds'] = opts['limits'] w = SpinBox() w.setOpts(**defs) w.sigChanged = w.sigValueChanged w.sigChanging = w.sigValueChanging elif t == 'bool': w = QtGui.QCheckBox() w.sigChanged = w.toggled w.value = w.isChecked w.setValue = w.setChecked w.setEnabled(not opts.get('readonly', False)) self.hideWidget = False elif t == 'str': w = QtGui.QLineEdit() w.sigChanged = w.editingFinished w.value = lambda: asUnicode(w.text()) w.setValue = lambda v: w.setText(asUnicode(v)) w.sigChanging = w.textChanged elif t == 'color': w = ColorButton() w.sigChanged = w.sigColorChanged w.sigChanging = w.sigColorChanging w.value = w.color w.setValue = w.setColor self.hideWidget = False w.setFlat(True) w.setEnabled(not opts.get('readonly', False)) elif t == 'colormap': from ..widgets.GradientWidget import GradientWidget ## need this here to avoid import loop w = GradientWidget(orientation='bottom') w.sigChanged = w.sigGradientChangeFinished w.sigChanging = w.sigGradientChanged w.value = w.colorMap w.setValue = w.setColorMap self.hideWidget = False else: raise Exception("Unknown type '%s'" % asUnicode(t)) return w def widgetEventFilter(self, obj, ev): ## filter widget's events ## catch TAB to change focus ## catch focusOut to hide editor if ev.type() == ev.KeyPress: if ev.key() == QtCore.Qt.Key_Tab: self.focusNext(forward=True) return True ## don't let anyone else see this event elif ev.key() == QtCore.Qt.Key_Backtab: self.focusNext(forward=False) return True ## don't let anyone else see this event #elif ev.type() == ev.FocusOut: #self.hideEditor() return False def setFocus(self): self.showEditor() def isFocusable(self): return self.param.writable() def valueChanged(self, param, val, force=False): ## called when the parameter's value has changed ParameterItem.valueChanged(self, param, val) self.widget.sigChanged.disconnect(self.widgetValueChanged) try: if force or val != self.widget.value(): self.widget.setValue(val) self.updateDisplayLabel(val) ## always make sure label is updated, even if values match! finally: self.widget.sigChanged.connect(self.widgetValueChanged) self.updateDefaultBtn() def updateDefaultBtn(self): ## enable/disable default btn self.defaultBtn.setEnabled(not self.param.valueIsDefault() and self.param.writable()) # hide / show self.defaultBtn.setVisible(not self.param.readonly()) def updateDisplayLabel(self, value=None): """Update the display label to reflect the value of the parameter.""" if value is None: value = self.param.value() opts = self.param.opts if isinstance(self.widget, QtGui.QAbstractSpinBox): text = asUnicode(self.widget.lineEdit().text()) elif isinstance(self.widget, QtGui.QComboBox): text = self.widget.currentText() else: text = asUnicode(value) self.displayLabel.setText(text) def widgetValueChanged(self): ## called when the widget's value has been changed by the user val = self.widget.value() newVal = self.param.setValue(val) def widgetValueChanging(self, *args): """ Called when the widget's value is changing, but not finalized. For example: editing text before pressing enter or changing focus. """ # This is a bit sketchy: assume the last argument of each signal is # the value.. self.param.sigValueChanging.emit(self.param, args[-1]) def selected(self, sel): """Called when this item has been selected (sel=True) OR deselected (sel=False)""" ParameterItem.selected(self, sel) if self.widget is None: return if sel and self.param.writable(): self.showEditor() elif self.hideWidget: self.hideEditor() def showEditor(self): self.widget.show() self.displayLabel.hide() self.widget.setFocus(QtCore.Qt.OtherFocusReason) if isinstance(self.widget, SpinBox): self.widget.selectNumber() # select the numerical portion of the text for quick editing def hideEditor(self): self.widget.hide() self.displayLabel.show() def limitsChanged(self, param, limits): """Called when the parameter's limits have changed""" ParameterItem.limitsChanged(self, param, limits) t = self.param.opts['type'] if t == 'int' or t == 'float': self.widget.setOpts(bounds=limits) else: return ## don't know what to do with any other types.. def defaultChanged(self, param, value): self.updateDefaultBtn() def treeWidgetChanged(self): """Called when this item is added or removed from a tree.""" ParameterItem.treeWidgetChanged(self) ## add all widgets for this item into the tree if self.widget is not None: tree = self.treeWidget() if tree is None: return tree.setItemWidget(self, 1, self.layoutWidget) self.displayLabel.hide() self.selected(False) def defaultClicked(self): self.param.setToDefault() def optsChanged(self, param, opts): """Called when any options are changed that are not name, value, default, or limits""" #print "opts changed:", opts ParameterItem.optsChanged(self, param, opts) if 'readonly' in opts: self.updateDefaultBtn() if isinstance(self.widget, (QtGui.QCheckBox,ColorButton)): self.widget.setEnabled(not opts['readonly']) ## If widget is a SpinBox, pass options straight through if isinstance(self.widget, SpinBox): if 'units' in opts and 'suffix' not in opts: opts['suffix'] = opts['units'] self.widget.setOpts(**opts) self.updateDisplayLabel() class EventProxy(QtCore.QObject): def __init__(self, qobj, callback): QtCore.QObject.__init__(self) self.callback = callback qobj.installEventFilter(self) def eventFilter(self, obj, ev): return self.callback(obj, ev) class SimpleParameter(Parameter): itemClass = WidgetParameterItem def __init__(self, *args, **kargs): Parameter.__init__(self, *args, **kargs) ## override a few methods for color parameters if self.opts['type'] == 'color': self.value = self.colorValue self.saveState = self.saveColorState def colorValue(self): return fn.mkColor(Parameter.value(self)) def saveColorState(self, *args, **kwds): state = Parameter.saveState(self, *args, **kwds) state['value'] = fn.colorTuple(self.value()) return state registerParameterType('int', SimpleParameter, override=True) registerParameterType('float', SimpleParameter, override=True) registerParameterType('bool', SimpleParameter, override=True) registerParameterType('str', SimpleParameter, override=True) registerParameterType('color', SimpleParameter, override=True) registerParameterType('colormap', SimpleParameter, override=True) class GroupParameterItem(ParameterItem): """ Group parameters are used mainly as a generic parent item that holds (and groups!) a set of child parameters. It also provides a simple mechanism for displaying a button or combo that can be used to add new parameters to the group. """ def __init__(self, param, depth): ParameterItem.__init__(self, param, depth) self.updateDepth(depth) self.addItem = None if 'addText' in param.opts: addText = param.opts['addText'] if 'addList' in param.opts: self.addWidget = QtGui.QComboBox() self.addWidget.setSizeAdjustPolicy(QtGui.QComboBox.AdjustToContents) self.updateAddList() self.addWidget.currentIndexChanged.connect(self.addChanged) else: self.addWidget = QtGui.QPushButton(addText) self.addWidget.clicked.connect(self.addClicked) w = QtGui.QWidget() l = QtGui.QHBoxLayout() l.setContentsMargins(0,0,0,0) w.setLayout(l) l.addWidget(self.addWidget) l.addStretch() #l.addItem(QtGui.QSpacerItem(200, 10, QtGui.QSizePolicy.Expanding, QtGui.QSizePolicy.Minimum)) self.addWidgetBox = w self.addItem = QtGui.QTreeWidgetItem([]) self.addItem.setFlags(QtCore.Qt.ItemIsEnabled) ParameterItem.addChild(self, self.addItem) def updateDepth(self, depth): ## Change item's appearance based on its depth in the tree ## This allows highest-level groups to be displayed more prominently. if depth == 0: for c in [0,1]: self.setBackground(c, QtGui.QBrush(QtGui.QColor(100,100,100))) self.setForeground(c, QtGui.QBrush(QtGui.QColor(220,220,255))) font = self.font(c) font.setBold(True) font.setPointSize(font.pointSize()+1) self.setFont(c, font) self.setSizeHint(0, QtCore.QSize(0, 25)) else: for c in [0,1]: self.setBackground(c, QtGui.QBrush(QtGui.QColor(220,220,220))) font = self.font(c) font.setBold(True) #font.setPointSize(font.pointSize()+1) self.setFont(c, font) self.setSizeHint(0, QtCore.QSize(0, 20)) def addClicked(self): """Called when "add new" button is clicked The parameter MUST have an 'addNew' method defined. """ self.param.addNew() def addChanged(self): """Called when "add new" combo is changed The parameter MUST have an 'addNew' method defined. """ if self.addWidget.currentIndex() == 0: return typ = asUnicode(self.addWidget.currentText()) self.param.addNew(typ) self.addWidget.setCurrentIndex(0) def treeWidgetChanged(self): ParameterItem.treeWidgetChanged(self) self.treeWidget().setFirstItemColumnSpanned(self, True) if self.addItem is not None: self.treeWidget().setItemWidget(self.addItem, 0, self.addWidgetBox) self.treeWidget().setFirstItemColumnSpanned(self.addItem, True) def addChild(self, child): ## make sure added childs are actually inserted before add btn if self.addItem is not None: ParameterItem.insertChild(self, self.childCount()-1, child) else: ParameterItem.addChild(self, child) def optsChanged(self, param, changed): if 'addList' in changed: self.updateAddList() def updateAddList(self): self.addWidget.blockSignals(True) try: self.addWidget.clear() self.addWidget.addItem(self.param.opts['addText']) for t in self.param.opts['addList']: self.addWidget.addItem(t) finally: self.addWidget.blockSignals(False) class GroupParameter(Parameter): """ Group parameters are used mainly as a generic parent item that holds (and groups!) a set of child parameters. It also provides a simple mechanism for displaying a button or combo that can be used to add new parameters to the group. To enable this, the group must be initialized with the 'addText' option (the text will be displayed on a button which, when clicked, will cause addNew() to be called). If the 'addList' option is specified as well, then a dropdown-list of addable items will be displayed instead of a button. """ itemClass = GroupParameterItem def addNew(self, typ=None): """ This method is called when the user has requested to add a new item to the group. """ raise Exception("Must override this function in subclass.") def setAddList(self, vals): """Change the list of options available for the user to add to the group.""" self.setOpts(addList=vals) registerParameterType('group', GroupParameter, override=True) class ListParameterItem(WidgetParameterItem): """ WidgetParameterItem subclass providing comboBox that lets the user select from a list of options. """ def __init__(self, param, depth): self.targetValue = None WidgetParameterItem.__init__(self, param, depth) def makeWidget(self): opts = self.param.opts t = opts['type'] w = QtGui.QComboBox() w.setMaximumHeight(20) ## set to match height of spin box and line edit w.sigChanged = w.currentIndexChanged w.value = self.value w.setValue = self.setValue self.widget = w ## needs to be set before limits are changed self.limitsChanged(self.param, self.param.opts['limits']) if len(self.forward) > 0: self.setValue(self.param.value()) return w def value(self): key = asUnicode(self.widget.currentText()) return self.forward.get(key, None) def setValue(self, val): self.targetValue = val if val not in self.reverse[0]: self.widget.setCurrentIndex(0) else: key = self.reverse[1][self.reverse[0].index(val)] ind = self.widget.findText(key) self.widget.setCurrentIndex(ind) def limitsChanged(self, param, limits): # set up forward / reverse mappings for name:value if len(limits) == 0: limits = [''] ## Can never have an empty list--there is always at least a singhe blank item. self.forward, self.reverse = ListParameter.mapping(limits) try: self.widget.blockSignals(True) val = self.targetValue #asUnicode(self.widget.currentText()) self.widget.clear() for k in self.forward: self.widget.addItem(k) if k == val: self.widget.setCurrentIndex(self.widget.count()-1) self.updateDisplayLabel() finally: self.widget.blockSignals(False) class ListParameter(Parameter): itemClass = ListParameterItem def __init__(self, **opts): self.forward = OrderedDict() ## {name: value, ...} self.reverse = ([], []) ## ([value, ...], [name, ...]) ## Parameter uses 'limits' option to define the set of allowed values if 'values' in opts: opts['limits'] = opts['values'] if opts.get('limits', None) is None: opts['limits'] = [] Parameter.__init__(self, **opts) self.setLimits(opts['limits']) def setLimits(self, limits): self.forward, self.reverse = self.mapping(limits) Parameter.setLimits(self, limits) if len(self.reverse[0]) > 0 and self.value() not in self.reverse[0]: self.setValue(self.reverse[0][0]) #def addItem(self, name, value=None): #if name in self.forward: #raise Exception("Name '%s' is already in use for this parameter" % name) #limits = self.opts['limits'] #if isinstance(limits, dict): #limits = limits.copy() #limits[name] = value #self.setLimits(limits) #else: #if value is not None: #raise Exception ## raise exception or convert to dict? #limits = limits[:] #limits.append(name) ## what if limits == None? @staticmethod def mapping(limits): ## Return forward and reverse mapping objects given a limit specification forward = OrderedDict() ## {name: value, ...} reverse = ([], []) ## ([value, ...], [name, ...]) if isinstance(limits, dict): for k, v in limits.items(): forward[k] = v reverse[0].append(v) reverse[1].append(k) else: for v in limits: n = asUnicode(v) forward[n] = v reverse[0].append(v) reverse[1].append(n) return forward, reverse registerParameterType('list', ListParameter, override=True) class ActionParameterItem(ParameterItem): def __init__(self, param, depth): ParameterItem.__init__(self, param, depth) self.layoutWidget = QtGui.QWidget() self.layout = QtGui.QHBoxLayout() self.layoutWidget.setLayout(self.layout) self.button = QtGui.QPushButton(param.name()) #self.layout.addSpacing(100) self.layout.addWidget(self.button) self.layout.addStretch() self.button.clicked.connect(self.buttonClicked) param.sigNameChanged.connect(self.paramRenamed) self.setText(0, '') def treeWidgetChanged(self): ParameterItem.treeWidgetChanged(self) tree = self.treeWidget() if tree is None: return tree.setFirstItemColumnSpanned(self, True) tree.setItemWidget(self, 0, self.layoutWidget) def paramRenamed(self, param, name): self.button.setText(name) def buttonClicked(self): self.param.activate() class ActionParameter(Parameter): """Used for displaying a button within the tree.""" itemClass = ActionParameterItem sigActivated = QtCore.Signal(object) def activate(self): self.sigActivated.emit(self) self.emitStateChanged('activated', None) registerParameterType('action', ActionParameter, override=True) class TextParameterItem(WidgetParameterItem): def __init__(self, param, depth): WidgetParameterItem.__init__(self, param, depth) self.hideWidget = False self.subItem = QtGui.QTreeWidgetItem() self.addChild(self.subItem) def treeWidgetChanged(self): ## TODO: fix so that superclass method can be called ## (WidgetParameter should just natively support this style) #WidgetParameterItem.treeWidgetChanged(self) self.treeWidget().setFirstItemColumnSpanned(self.subItem, True) self.treeWidget().setItemWidget(self.subItem, 0, self.textBox) # for now, these are copied from ParameterItem.treeWidgetChanged self.setHidden(not self.param.opts.get('visible', True)) self.setExpanded(self.param.opts.get('expanded', True)) def makeWidget(self): self.textBox = QtGui.QTextEdit() self.textBox.setMaximumHeight(100) self.textBox.setReadOnly(self.param.opts.get('readonly', False)) self.textBox.value = lambda: str(self.textBox.toPlainText()) self.textBox.setValue = self.textBox.setPlainText self.textBox.sigChanged = self.textBox.textChanged return self.textBox class TextParameter(Parameter): """Editable string; displayed as large text box in the tree.""" itemClass = TextParameterItem registerParameterType('text', TextParameter, override=True) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/parametertree/tests/000077500000000000000000000000001300727121400236425ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/parametertree/tests/test_parametertypes.py000066400000000000000000000010341300727121400303160ustar00rootroot00000000000000import pyqtgraph.parametertree as pt import pyqtgraph as pg app = pg.mkQApp() def test_opts(): paramSpec = [ dict(name='bool', type='bool', readonly=True), dict(name='color', type='color', readonly=True), ] param = pt.Parameter.create(name='params', type='group', children=paramSpec) tree = pt.ParameterTree() tree.setParameters(param) assert list(param.param('bool').items.keys())[0].widget.isEnabled() is False assert list(param.param('color').items.keys())[0].widget.isEnabled() is False pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/pgcollections.py000066400000000000000000000363701300727121400230700ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ advancedTypes.py - Basic data structures not included with python Copyright 2010 Luke Campagnola Distributed under MIT/X11 license. See license.txt for more infomation. Includes: - OrderedDict - Dictionary which preserves the order of its elements - BiDict, ReverseDict - Bi-directional dictionaries - ThreadsafeDict, ThreadsafeList - Self-mutexed data structures """ import threading, sys, copy, collections #from debug import * try: from collections import OrderedDict except ImportError: # fallback: try to use the ordereddict backport when using python 2.6 from ordereddict import OrderedDict class ReverseDict(dict): """extends dict so that reverse lookups are possible by requesting the key as a list of length 1: d = BiDict({'x': 1, 'y': 2}) d['x'] 1 d[[2]] 'y' """ def __init__(self, data=None): if data is None: data = {} self.reverse = {} for k in data: self.reverse[data[k]] = k dict.__init__(self, data) def __getitem__(self, item): if type(item) is list: return self.reverse[item[0]] else: return dict.__getitem__(self, item) def __setitem__(self, item, value): self.reverse[value] = item dict.__setitem__(self, item, value) def __deepcopy__(self, memo): raise Exception("deepcopy not implemented") class BiDict(dict): """extends dict so that reverse lookups are possible by adding each reverse combination to the dict. This only works if all values and keys are unique.""" def __init__(self, data=None): if data is None: data = {} dict.__init__(self) for k in data: self[data[k]] = k def __setitem__(self, item, value): dict.__setitem__(self, item, value) dict.__setitem__(self, value, item) def __deepcopy__(self, memo): raise Exception("deepcopy not implemented") class ThreadsafeDict(dict): """Extends dict so that getitem, setitem, and contains are all thread-safe. Also adds lock/unlock functions for extended exclusive operations Converts all sub-dicts and lists to threadsafe as well. """ def __init__(self, *args, **kwargs): self.mutex = threading.RLock() dict.__init__(self, *args, **kwargs) for k in self: if type(self[k]) is dict: self[k] = ThreadsafeDict(self[k]) def __getitem__(self, attr): self.lock() try: val = dict.__getitem__(self, attr) finally: self.unlock() return val def __setitem__(self, attr, val): if type(val) is dict: val = ThreadsafeDict(val) self.lock() try: dict.__setitem__(self, attr, val) finally: self.unlock() def __contains__(self, attr): self.lock() try: val = dict.__contains__(self, attr) finally: self.unlock() return val def __len__(self): self.lock() try: val = dict.__len__(self) finally: self.unlock() return val def clear(self): self.lock() try: dict.clear(self) finally: self.unlock() def lock(self): self.mutex.acquire() def unlock(self): self.mutex.release() def __deepcopy__(self, memo): raise Exception("deepcopy not implemented") class ThreadsafeList(list): """Extends list so that getitem, setitem, and contains are all thread-safe. Also adds lock/unlock functions for extended exclusive operations Converts all sub-lists and dicts to threadsafe as well. """ def __init__(self, *args, **kwargs): self.mutex = threading.RLock() list.__init__(self, *args, **kwargs) for k in self: self[k] = mkThreadsafe(self[k]) def __getitem__(self, attr): self.lock() try: val = list.__getitem__(self, attr) finally: self.unlock() return val def __setitem__(self, attr, val): val = makeThreadsafe(val) self.lock() try: list.__setitem__(self, attr, val) finally: self.unlock() def __contains__(self, attr): self.lock() try: val = list.__contains__(self, attr) finally: self.unlock() return val def __len__(self): self.lock() try: val = list.__len__(self) finally: self.unlock() return val def lock(self): self.mutex.acquire() def unlock(self): self.mutex.release() def __deepcopy__(self, memo): raise Exception("deepcopy not implemented") def makeThreadsafe(obj): if type(obj) is dict: return ThreadsafeDict(obj) elif type(obj) is list: return ThreadsafeList(obj) elif type(obj) in [str, int, float, bool, tuple]: return obj else: raise Exception("Not sure how to make object of type %s thread-safe" % str(type(obj))) class Locker(object): def __init__(self, lock): self.lock = lock self.lock.acquire() def __del__(self): try: self.lock.release() except: pass class CaselessDict(OrderedDict): """Case-insensitive dict. Values can be set and retrieved using keys of any case. Note that when iterating, the original case is returned for each key.""" def __init__(self, *args): OrderedDict.__init__(self, {}) ## requirement for the empty {} here seems to be a python bug? self.keyMap = OrderedDict([(k.lower(), k) for k in OrderedDict.keys(self)]) if len(args) == 0: return elif len(args) == 1 and isinstance(args[0], dict): for k in args[0]: self[k] = args[0][k] else: raise Exception("CaselessDict may only be instantiated with a single dict.") #def keys(self): #return self.keyMap.values() def __setitem__(self, key, val): kl = key.lower() if kl in self.keyMap: OrderedDict.__setitem__(self, self.keyMap[kl], val) else: OrderedDict.__setitem__(self, key, val) self.keyMap[kl] = key def __getitem__(self, key): kl = key.lower() if kl not in self.keyMap: raise KeyError(key) return OrderedDict.__getitem__(self, self.keyMap[kl]) def __contains__(self, key): return key.lower() in self.keyMap def update(self, d): for k, v in d.iteritems(): self[k] = v def copy(self): return CaselessDict(OrderedDict.copy(self)) def __delitem__(self, key): kl = key.lower() if kl not in self.keyMap: raise KeyError(key) OrderedDict.__delitem__(self, self.keyMap[kl]) del self.keyMap[kl] def __deepcopy__(self, memo): raise Exception("deepcopy not implemented") def clear(self): OrderedDict.clear(self) self.keyMap.clear() class ProtectedDict(dict): """ A class allowing read-only 'view' of a dict. The object can be treated like a normal dict, but will never modify the original dict it points to. Any values accessed from the dict will also be read-only. """ def __init__(self, data): self._data_ = data ## List of methods to directly wrap from _data_ wrapMethods = ['_cmp_', '__contains__', '__eq__', '__format__', '__ge__', '__gt__', '__le__', '__len__', '__lt__', '__ne__', '__reduce__', '__reduce_ex__', '__repr__', '__str__', 'count', 'has_key', 'iterkeys', 'keys', ] ## List of methods which wrap from _data_ but return protected results protectMethods = ['__getitem__', '__iter__', 'get', 'items', 'values'] ## List of methods to disable disableMethods = ['__delitem__', '__setitem__', 'clear', 'pop', 'popitem', 'setdefault', 'update'] ## Template methods def wrapMethod(methodName): return lambda self, *a, **k: getattr(self._data_, methodName)(*a, **k) def protectMethod(methodName): return lambda self, *a, **k: protect(getattr(self._data_, methodName)(*a, **k)) def error(self, *args, **kargs): raise Exception("Can not modify read-only list.") ## Directly (and explicitly) wrap some methods from _data_ ## Many of these methods can not be intercepted using __getattribute__, so they ## must be implemented explicitly for methodName in wrapMethods: locals()[methodName] = wrapMethod(methodName) ## Wrap some methods from _data_ with the results converted to protected objects for methodName in protectMethods: locals()[methodName] = protectMethod(methodName) ## Disable any methods that could change data in the list for methodName in disableMethods: locals()[methodName] = error ## Add a few extra methods. def copy(self): raise Exception("It is not safe to copy protected dicts! (instead try deepcopy, but be careful.)") def itervalues(self): for v in self._data_.itervalues(): yield protect(v) def iteritems(self): for k, v in self._data_.iteritems(): yield (k, protect(v)) def deepcopy(self): return copy.deepcopy(self._data_) def __deepcopy__(self, memo): return copy.deepcopy(self._data_, memo) class ProtectedList(collections.Sequence): """ A class allowing read-only 'view' of a list or dict. The object can be treated like a normal list, but will never modify the original list it points to. Any values accessed from the list will also be read-only. Note: It would be nice if we could inherit from list or tuple so that isinstance checks would work. However, doing this causes tuple(obj) to return unprotected results (importantly, this means unpacking into function arguments will also fail) """ def __init__(self, data): self._data_ = data #self.__mro__ = (ProtectedList, object) ## List of methods to directly wrap from _data_ wrapMethods = ['__contains__', '__eq__', '__format__', '__ge__', '__gt__', '__le__', '__len__', '__lt__', '__ne__', '__reduce__', '__reduce_ex__', '__repr__', '__str__', 'count', 'index'] ## List of methods which wrap from _data_ but return protected results protectMethods = ['__getitem__', '__getslice__', '__mul__', '__reversed__', '__rmul__'] ## List of methods to disable disableMethods = ['__delitem__', '__delslice__', '__iadd__', '__imul__', '__setitem__', '__setslice__', 'append', 'extend', 'insert', 'pop', 'remove', 'reverse', 'sort'] ## Template methods def wrapMethod(methodName): return lambda self, *a, **k: getattr(self._data_, methodName)(*a, **k) def protectMethod(methodName): return lambda self, *a, **k: protect(getattr(self._data_, methodName)(*a, **k)) def error(self, *args, **kargs): raise Exception("Can not modify read-only list.") ## Directly (and explicitly) wrap some methods from _data_ ## Many of these methods can not be intercepted using __getattribute__, so they ## must be implemented explicitly for methodName in wrapMethods: locals()[methodName] = wrapMethod(methodName) ## Wrap some methods from _data_ with the results converted to protected objects for methodName in protectMethods: locals()[methodName] = protectMethod(methodName) ## Disable any methods that could change data in the list for methodName in disableMethods: locals()[methodName] = error ## Add a few extra methods. def __iter__(self): for item in self._data_: yield protect(item) def __add__(self, op): if isinstance(op, ProtectedList): return protect(self._data_.__add__(op._data_)) elif isinstance(op, list): return protect(self._data_.__add__(op)) else: raise TypeError("Argument must be a list.") def __radd__(self, op): if isinstance(op, ProtectedList): return protect(op._data_.__add__(self._data_)) elif isinstance(op, list): return protect(op.__add__(self._data_)) else: raise TypeError("Argument must be a list.") def deepcopy(self): return copy.deepcopy(self._data_) def __deepcopy__(self, memo): return copy.deepcopy(self._data_, memo) def poop(self): raise Exception("This is a list. It does not poop.") class ProtectedTuple(collections.Sequence): """ A class allowing read-only 'view' of a tuple. The object can be treated like a normal tuple, but its contents will be returned as protected objects. Note: It would be nice if we could inherit from list or tuple so that isinstance checks would work. However, doing this causes tuple(obj) to return unprotected results (importantly, this means unpacking into function arguments will also fail) """ def __init__(self, data): self._data_ = data ## List of methods to directly wrap from _data_ wrapMethods = ['__contains__', '__eq__', '__format__', '__ge__', '__getnewargs__', '__gt__', '__hash__', '__le__', '__len__', '__lt__', '__ne__', '__reduce__', '__reduce_ex__', '__repr__', '__str__', 'count', 'index'] ## List of methods which wrap from _data_ but return protected results protectMethods = ['__getitem__', '__getslice__', '__iter__', '__add__', '__mul__', '__reversed__', '__rmul__'] ## Template methods def wrapMethod(methodName): return lambda self, *a, **k: getattr(self._data_, methodName)(*a, **k) def protectMethod(methodName): return lambda self, *a, **k: protect(getattr(self._data_, methodName)(*a, **k)) ## Directly (and explicitly) wrap some methods from _data_ ## Many of these methods can not be intercepted using __getattribute__, so they ## must be implemented explicitly for methodName in wrapMethods: locals()[methodName] = wrapMethod(methodName) ## Wrap some methods from _data_ with the results converted to protected objects for methodName in protectMethods: locals()[methodName] = protectMethod(methodName) ## Add a few extra methods. def deepcopy(self): return copy.deepcopy(self._data_) def __deepcopy__(self, memo): return copy.deepcopy(self._data_, memo) def protect(obj): if isinstance(obj, dict): return ProtectedDict(obj) elif isinstance(obj, list): return ProtectedList(obj) elif isinstance(obj, tuple): return ProtectedTuple(obj) else: return obj if __name__ == '__main__': d = {'x': 1, 'y': [1,2], 'z': ({'a': 2, 'b': [3,4], 'c': (5,6)}, 1, 2)} dp = protect(d) l = [1, 'x', ['a', 'b'], ('c', 'd'), {'x': 1, 'y': 2}] lp = protect(l) t = (1, 'x', ['a', 'b'], ('c', 'd'), {'x': 1, 'y': 2}) tp = protect(t) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/pixmaps/000077500000000000000000000000001300727121400213215ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/pixmaps/__init__.py000066400000000000000000000014431300727121400234340ustar00rootroot00000000000000""" Allows easy loading of pixmaps used in UI elements. Provides support for frozen environments as well. """ import os, sys, pickle from ..functions import makeQImage from ..Qt import QtGui from ..python2_3 import basestring if sys.version_info[0] == 2: from . import pixmapData_2 as pixmapData else: from . import pixmapData_3 as pixmapData def getPixmap(name): """ Return a QPixmap corresponding to the image file with the given name. (eg. getPixmap('auto') loads pyqtgraph/pixmaps/auto.png) """ key = name+'.png' data = pixmapData.pixmapData[key] if isinstance(data, basestring) or isinstance(data, bytes): pixmapData.pixmapData[key] = pickle.loads(data) arr = pixmapData.pixmapData[key] return QtGui.QPixmap(makeQImage(arr, alpha=True)) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/pixmaps/auto.png000066400000000000000000000017761300727121400230120ustar00rootroot00000000000000PNG  IHDR szzsBIT|d pHYsKg<tEXtSoftwarewww.inkscape.org<{IDATX͗OHǿCbc]$+HV " GЀvR!D6:!$t,B"V!ȱkqlV9q|߼y0`$Io FBs+3BgAbH0/4) |P,iVM (Hj7(BQaqrL!LLiZ8)ggg |>VWWQ%krX[[C$s$ɆqAET59022h4(u-ժժ;]UU.W- HRi gi,خj6t:,,,PmۺRbb&I" app/J899,˶\emea\.MMM! 5 J!S$Iei@޿* btD"yҬ{RZ4PTUΎ_}oڊL&Ci X^^3:::===X X__wӰV?ۋx!~ B[ PU5low6}IY!ϡP(YH& Q$Nc(J@ibۍCez{{-sVsjjjI1a_XXRdKpRD6@ @{{;@Pr!(Qs0 E6;FM^sxxHgg糶sSStwwG"xr{ר\gggI$3220%2 u\;VVV-b||^](ׯ(ī 0b1l* \\\Tonn١&D4T*E$m%n섨.h%L&C,cssx8XgVf90yXNa *0Lp` m<b0Ho?9KPbbpra*-奱h+@?0d%N&ii(> IW[ @ F"`a8&[[2'ٯVާ5=O&2kOcYŞŞ0h7Rb1~y,|]#4/YPwX'\gREo 67 $-`pTxo65:=Lc.4r}1 6ORuỴxrl´b60?`pQEOc*kl+ҘqۥHAsnߟ/[}&e&NdaY[ &s(4x!É^p)"]g]mD= "$Pbn2yTSޮ=Jw%A}lBtXo)[Q 2+ێ e75|xZyrݣ_Co|)eV^bWyN3g?ѼCjWVT\k*/~jW IENDB`pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/pixmaps/icons.svg000066400000000000000000000143501300727121400231600ustar00rootroot00000000000000 image/svg+xml A pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/pixmaps/lock.png000066400000000000000000000016211300727121400227570ustar00rootroot00000000000000PNG  IHDR szzsBIT|d pHYsKg<tEXtSoftwarewww.inkscape.org<IDATX헽k#G#V *V] q1u*8T-& X\NUJ@68*FR|>%N᧚cyy_1L`ד5=Q;\.4_L&7@|AB_c.kK!oYbBVTUI/s\C:%z˲F ( Y[[}!7OB xP܏H&f]fdYt]lq0H&AJp4)z=?( @8T*-N8C\W.bhT*`f`0JF H$z.?}!\/3oB nmmۛ}i۟/@Q*yyyL&(`TUt]XE<_Yg!nPUEQp8\HU<(tU!$@$4MmۦVͭx8Z^it^4_W,WVVD"pwwoKDR ~~[Es)ZMMR0IENDB`pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/pixmaps/pixmapData_2.py000066400000000000000000002001401300727121400242010ustar00rootroot00000000000000import numpy as np; pixmapData={'lock.png': 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-*- coding: utf-8 -*- """ ptime.py - Precision time function made os-independent (should have been taken care of by python) Copyright 2010 Luke Campagnola Distributed under MIT/X11 license. See license.txt for more infomation. """ import sys import time as systime START_TIME = None time = None def winTime(): """Return the current time in seconds with high precision (windows version, use Manager.time() to stay platform independent).""" return systime.clock() + START_TIME #return systime.time() def unixTime(): """Return the current time in seconds with high precision (unix version, use Manager.time() to stay platform independent).""" return systime.time() if sys.platform.startswith('win'): cstart = systime.clock() ### Required to start the clock in windows START_TIME = systime.time() - cstart time = winTime else: time = unixTime pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/python2_3.py000066400000000000000000000027341300727121400220450ustar00rootroot00000000000000""" Helper functions that smooth out the differences between python 2 and 3. """ import sys def asUnicode(x): if sys.version_info[0] == 2: if isinstance(x, unicode): return x elif isinstance(x, str): return x.decode('UTF-8') else: return unicode(x) else: return str(x) def cmpToKey(mycmp): 'Convert a cmp= function into a key= function' class K(object): def __init__(self, obj, *args): self.obj = obj def __lt__(self, other): return mycmp(self.obj, other.obj) < 0 def __gt__(self, other): return mycmp(self.obj, other.obj) > 0 def __eq__(self, other): return mycmp(self.obj, other.obj) == 0 def __le__(self, other): return mycmp(self.obj, other.obj) <= 0 def __ge__(self, other): return mycmp(self.obj, other.obj) >= 0 def __ne__(self, other): return mycmp(self.obj, other.obj) != 0 return K def sortList(l, cmpFunc): if sys.version_info[0] == 2: l.sort(cmpFunc) else: l.sort(key=cmpToKey(cmpFunc)) if sys.version_info[0] == 3: basestring = str def cmp(a,b): if a>b: return 1 elif b > a: return -1 else: return 0 xrange = range else: import __builtin__ basestring = __builtin__.basestring cmp = __builtin__.cmp xrange = __builtin__.xrange pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/reload.py000066400000000000000000000411351300727121400214640ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Magic Reload Library Luke Campagnola 2010 Python reload function that actually works (the way you expect it to) - No re-importing necessary - Modules can be reloaded in any order - Replaces functions and methods with their updated code - Changes instances to use updated classes - Automatically decides which modules to update by comparing file modification times Does NOT: - re-initialize exting instances, even if __init__ changes - update references to any module-level objects ie, this does not reload correctly: from module import someObject print someObject ..but you can use this instead: (this works even for the builtin reload) import module print module.someObject """ import inspect, os, sys, gc, traceback try: import __builtin__ as builtins except ImportError: import builtins from .debug import printExc def reloadAll(prefix=None, debug=False): """Automatically reload everything whose __file__ begins with prefix. - Skips reload if the file has not been updated (if .pyc is newer than .py) - if prefix is None, checks all loaded modules """ failed = [] changed = [] for modName, mod in list(sys.modules.items()): ## don't use iteritems; size may change during reload if not inspect.ismodule(mod): continue if modName == '__main__': continue ## Ignore if the file name does not start with prefix if not hasattr(mod, '__file__') or os.path.splitext(mod.__file__)[1] not in ['.py', '.pyc']: continue if prefix is not None and mod.__file__[:len(prefix)] != prefix: continue ## ignore if the .pyc is newer than the .py (or if there is no pyc or py) py = os.path.splitext(mod.__file__)[0] + '.py' pyc = py + 'c' if py not in changed and os.path.isfile(pyc) and os.path.isfile(py) and os.stat(pyc).st_mtime >= os.stat(py).st_mtime: #if debug: #print "Ignoring module %s; unchanged" % str(mod) continue changed.append(py) ## keep track of which modules have changed to insure that duplicate-import modules get reloaded. try: reload(mod, debug=debug) except: printExc("Error while reloading module %s, skipping\n" % mod) failed.append(mod.__name__) if len(failed) > 0: raise Exception("Some modules failed to reload: %s" % ', '.join(failed)) def reload(module, debug=False, lists=False, dicts=False): """Replacement for the builtin reload function: - Reloads the module as usual - Updates all old functions and class methods to use the new code - Updates all instances of each modified class to use the new class - Can update lists and dicts, but this is disabled by default - Requires that class and function names have not changed """ if debug: print("Reloading %s" % str(module)) ## make a copy of the old module dictionary, reload, then grab the new module dictionary for comparison oldDict = module.__dict__.copy() builtins.reload(module) newDict = module.__dict__ ## Allow modules access to the old dictionary after they reload if hasattr(module, '__reload__'): module.__reload__(oldDict) ## compare old and new elements from each dict; update where appropriate for k in oldDict: old = oldDict[k] new = newDict.get(k, None) if old is new or new is None: continue if inspect.isclass(old): if debug: print(" Updating class %s.%s (0x%x -> 0x%x)" % (module.__name__, k, id(old), id(new))) updateClass(old, new, debug) elif inspect.isfunction(old): depth = updateFunction(old, new, debug) if debug: extra = "" if depth > 0: extra = " (and %d previous versions)" % depth print(" Updating function %s.%s%s" % (module.__name__, k, extra)) elif lists and isinstance(old, list): l = old.len() old.extend(new) for i in range(l): old.pop(0) elif dicts and isinstance(old, dict): old.update(new) for k in old: if k not in new: del old[k] ## For functions: ## 1) update the code and defaults to new versions. ## 2) keep a reference to the previous version so ALL versions get updated for every reload def updateFunction(old, new, debug, depth=0, visited=None): #if debug and depth > 0: #print " -> also updating previous version", old, " -> ", new old.__code__ = new.__code__ old.__defaults__ = new.__defaults__ if visited is None: visited = [] if old in visited: return visited.append(old) ## finally, update any previous versions still hanging around.. if hasattr(old, '__previous_reload_version__'): maxDepth = updateFunction(old.__previous_reload_version__, new, debug, depth=depth+1, visited=visited) else: maxDepth = depth ## We need to keep a pointer to the previous version so we remember to update BOTH ## when the next reload comes around. if depth == 0: new.__previous_reload_version__ = old return maxDepth ## For classes: ## 1) find all instances of the old class and set instance.__class__ to the new class ## 2) update all old class methods to use code from the new class methods def updateClass(old, new, debug): ## Track town all instances and subclasses of old refs = gc.get_referrers(old) for ref in refs: try: if isinstance(ref, old) and ref.__class__ is old: ref.__class__ = new if debug: print(" Changed class for %s" % safeStr(ref)) elif inspect.isclass(ref) and issubclass(ref, old) and old in ref.__bases__: ind = ref.__bases__.index(old) ## Does not work: #ref.__bases__ = ref.__bases__[:ind] + (new,) + ref.__bases__[ind+1:] ## reason: Even though we change the code on methods, they remain bound ## to their old classes (changing im_class is not allowed). Instead, ## we have to update the __bases__ such that this class will be allowed ## as an argument to older methods. ## This seems to work. Is there any reason not to? ## Note that every time we reload, the class hierarchy becomes more complex. ## (and I presume this may slow things down?) ref.__bases__ = ref.__bases__[:ind] + (new,old) + ref.__bases__[ind+1:] if debug: print(" Changed superclass for %s" % safeStr(ref)) #else: #if debug: #print " Ignoring reference", type(ref) except: print("Error updating reference (%s) for class change (%s -> %s)" % (safeStr(ref), safeStr(old), safeStr(new))) raise ## update all class methods to use new code. ## Generally this is not needed since instances already know about the new class, ## but it fixes a few specific cases (pyqt signals, for one) for attr in dir(old): oa = getattr(old, attr) if inspect.ismethod(oa): try: na = getattr(new, attr) except AttributeError: if debug: print(" Skipping method update for %s; new class does not have this attribute" % attr) continue if hasattr(oa, 'im_func') and hasattr(na, 'im_func') and oa.__func__ is not na.__func__: depth = updateFunction(oa.__func__, na.__func__, debug) #oa.im_class = new ## bind old method to new class ## not allowed if debug: extra = "" if depth > 0: extra = " (and %d previous versions)" % depth print(" Updating method %s%s" % (attr, extra)) ## And copy in new functions that didn't exist previously for attr in dir(new): if not hasattr(old, attr): if debug: print(" Adding missing attribute %s" % attr) setattr(old, attr, getattr(new, attr)) ## finally, update any previous versions still hanging around.. if hasattr(old, '__previous_reload_version__'): updateClass(old.__previous_reload_version__, new, debug) ## It is possible to build classes for which str(obj) just causes an exception. ## Avoid thusly: def safeStr(obj): try: s = str(obj) except: try: s = repr(obj) except: s = "" % (safeStr(type(obj)), id(obj)) return s ## Tests: # write modules to disk, import, then re-write and run again if __name__ == '__main__': doQtTest = True try: from PyQt4 import QtCore if not hasattr(QtCore, 'Signal'): QtCore.Signal = QtCore.pyqtSignal #app = QtGui.QApplication([]) class Btn(QtCore.QObject): sig = QtCore.Signal() def emit(self): self.sig.emit() btn = Btn() except: raise print("Error; skipping Qt tests") doQtTest = False import os if not os.path.isdir('test1'): os.mkdir('test1') open('test1/__init__.py', 'w') modFile1 = "test1/test1.py" modCode1 = """ import sys class A(object): def __init__(self, msg): object.__init__(self) self.msg = msg def fn(self, pfx = ""): print(pfx+"A class: %%s %%s" %% (str(self.__class__), str(id(self.__class__)))) print(pfx+" %%s: %d" %% self.msg) class B(A): def fn(self, pfx=""): print(pfx+"B class:", self.__class__, id(self.__class__)) print(pfx+" %%s: %d" %% self.msg) print(pfx+" calling superclass.. (%%s)" %% id(A) ) A.fn(self, " ") """ modFile2 = "test2.py" modCode2 = """ from test1.test1 import A from test1.test1 import B a1 = A("ax1") b1 = B("bx1") class C(A): def __init__(self, msg): #print "| C init:" #print "| C.__bases__ = ", map(id, C.__bases__) #print "| A:", id(A) #print "| A.__init__ = ", id(A.__init__.im_func), id(A.__init__.im_func.__code__), id(A.__init__.im_class) A.__init__(self, msg + "(init from C)") def fn(): print("fn: %s") """ open(modFile1, 'w').write(modCode1%(1,1)) open(modFile2, 'w').write(modCode2%"message 1") import test1.test1 as test1 import test2 print("Test 1 originals:") A1 = test1.A B1 = test1.B a1 = test1.A("a1") b1 = test1.B("b1") a1.fn() b1.fn() #print "function IDs a1 bound method: %d a1 func: %d a1 class: %d b1 func: %d b1 class: %d" % (id(a1.fn), id(a1.fn.im_func), id(a1.fn.im_class), id(b1.fn.im_func), id(b1.fn.im_class)) from test2 import fn, C if doQtTest: print("Button test before:") btn.sig.connect(fn) btn.sig.connect(a1.fn) btn.emit() #btn.sig.emit() print("") #print "a1.fn referrers:", sys.getrefcount(a1.fn.im_func), gc.get_referrers(a1.fn.im_func) print("Test2 before reload:") fn() oldfn = fn test2.a1.fn() test2.b1.fn() c1 = test2.C('c1') c1.fn() os.remove(modFile1+'c') open(modFile1, 'w').write(modCode1%(2,2)) print("\n----RELOAD test1-----\n") reloadAll(os.path.abspath(__file__)[:10], debug=True) print("Subclass test:") c2 = test2.C('c2') c2.fn() os.remove(modFile2+'c') open(modFile2, 'w').write(modCode2%"message 2") print("\n----RELOAD test2-----\n") reloadAll(os.path.abspath(__file__)[:10], debug=True) if doQtTest: print("Button test after:") btn.emit() #btn.sig.emit() #print "a1.fn referrers:", sys.getrefcount(a1.fn.im_func), gc.get_referrers(a1.fn.im_func) print("Test2 after reload:") fn() test2.a1.fn() test2.b1.fn() print("\n==> Test 1 Old instances:") a1.fn() b1.fn() c1.fn() #print "function IDs a1 bound method: %d a1 func: %d a1 class: %d b1 func: %d b1 class: %d" % (id(a1.fn), id(a1.fn.im_func), id(a1.fn.im_class), id(b1.fn.im_func), id(b1.fn.im_class)) print("\n==> Test 1 New instances:") a2 = test1.A("a2") b2 = test1.B("b2") a2.fn() b2.fn() c2 = test2.C('c2') c2.fn() #print "function IDs a1 bound method: %d a1 func: %d a1 class: %d b1 func: %d b1 class: %d" % (id(a1.fn), id(a1.fn.im_func), id(a1.fn.im_class), id(b1.fn.im_func), id(b1.fn.im_class)) os.remove(modFile1+'c') os.remove(modFile2+'c') open(modFile1, 'w').write(modCode1%(3,3)) open(modFile2, 'w').write(modCode2%"message 3") print("\n----RELOAD-----\n") reloadAll(os.path.abspath(__file__)[:10], debug=True) if doQtTest: print("Button test after:") btn.emit() #btn.sig.emit() #print "a1.fn referrers:", sys.getrefcount(a1.fn.im_func), gc.get_referrers(a1.fn.im_func) print("Test2 after reload:") fn() test2.a1.fn() test2.b1.fn() print("\n==> Test 1 Old instances:") a1.fn() b1.fn() print("function IDs a1 bound method: %d a1 func: %d a1 class: %d b1 func: %d b1 class: %d" % (id(a1.fn), id(a1.fn.__func__), id(a1.fn.__self__.__class__), id(b1.fn.__func__), id(b1.fn.__self__.__class__))) print("\n==> Test 1 New instances:") a2 = test1.A("a2") b2 = test1.B("b2") a2.fn() b2.fn() print("function IDs a1 bound method: %d a1 func: %d a1 class: %d b1 func: %d b1 class: %d" % (id(a1.fn), id(a1.fn.__func__), id(a1.fn.__self__.__class__), id(b1.fn.__func__), id(b1.fn.__self__.__class__))) os.remove(modFile1) os.remove(modFile2) os.remove(modFile1+'c') os.remove(modFile2+'c') os.system('rm -r test1') # # Failure graveyard ahead: # """Reload Importer: Hooks into import system to 1) keep a record of module dependencies as they are imported 2) make sure modules are always reloaded in correct order 3) update old classes and functions to use reloaded code""" #import imp, sys ## python's import hook mechanism doesn't work since we need to be ## informed every time there is an import statement, not just for new imports #class ReloadImporter: #def __init__(self): #self.depth = 0 #def find_module(self, name, path): #print " "*self.depth + "find: ", name, path ##if name == 'PyQt4' and path is None: ##print "PyQt4 -> PySide" ##self.modData = imp.find_module('PySide') ##return self ##return None ## return none to allow the import to proceed normally; return self to intercept with load_module #self.modData = imp.find_module(name, path) #self.depth += 1 ##sys.path_importer_cache = {} #return self #def load_module(self, name): #mod = imp.load_module(name, *self.modData) #self.depth -= 1 #print " "*self.depth + "load: ", name #return mod #def pathHook(path): #print "path hook:", path #raise ImportError #sys.path_hooks.append(pathHook) #sys.meta_path.append(ReloadImporter()) ### replace __import__ with a wrapper that tracks module dependencies #modDeps = {} #reloadModule = None #origImport = __builtins__.__import__ #def _import(name, globals=None, locals=None, fromlist=None, level=-1, stack=[]): ### Note that stack behaves as a static variable. ##print " "*len(importStack) + "import %s" % args[0] #stack.append(set()) #mod = origImport(name, globals, locals, fromlist, level) #deps = stack.pop() #if len(stack) > 0: #stack[-1].add(mod) #elif reloadModule is not None: ## If this is the top level import AND we're inside a module reload #modDeps[reloadModule].add(mod) #if mod in modDeps: #modDeps[mod] |= deps #else: #modDeps[mod] = deps #return mod #__builtins__.__import__ = _import ### replace #origReload = __builtins__.reload #def _reload(mod): #reloadModule = mod #ret = origReload(mod) #reloadModule = None #return ret #__builtins__.reload = _reload #def reload(mod, visited=None): #if visited is None: #visited = set() #if mod in visited: #return #visited.add(mod) #for dep in modDeps.get(mod, []): #reload(dep, visited) #__builtins__.reload(mod) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/tests/000077500000000000000000000000001300727121400210025ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/tests/__init__.py000066400000000000000000000002271300727121400231140ustar00rootroot00000000000000from .image_testing import assertImageApproved, TransposedImageItem from .ui_testing import mousePress, mouseMove, mouseRelease, mouseDrag, mouseClick pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/tests/image_testing.py000066400000000000000000000545761300727121400242140ustar00rootroot00000000000000# Image-based testing borrowed from vispy """ Procedure for unit-testing with images: 1. Run unit tests at least once; this initializes a git clone of pyqtgraph/test-data in ~/.pyqtgraph. 2. Run individual test scripts with the PYQTGRAPH_AUDIT environment variable set: $ PYQTGRAPH_AUDIT=1 python pyqtgraph/graphicsItems/tests/test_PlotCurveItem.py Any failing tests will display the test results, standard image, and the differences between the two. If the test result is bad, then press (f)ail. If the test result is good, then press (p)ass and the new image will be saved to the test-data directory. 3. After adding or changing test images, create a new commit: $ cd ~/.pyqtgraph/test-data $ git add ... $ git commit -a 4. Look up the most recent tag name from the `testDataTag` global variable below. Increment the tag name by 1 and create a new tag in the test-data repository: $ git tag test-data-NNN $ git push --tags origin master This tag is used to ensure that each pyqtgraph commit is linked to a specific commit in the test-data repository. This makes it possible to push new commits to the test-data repository without interfering with existing tests, and also allows unit tests to continue working on older pyqtgraph versions. """ # This is the name of a tag in the test-data repository that this version of # pyqtgraph should be tested against. When adding or changing test images, # create and push a new tag and update this variable. To test locally, begin # by creating the tag in your ~/.pyqtgraph/test-data repository. testDataTag = 'test-data-6' import time import os import sys import inspect import base64 import subprocess as sp import numpy as np if sys.version[0] >= '3': import http.client as httplib import urllib.parse as urllib else: import httplib import urllib from ..Qt import QtGui, QtCore, QtTest, QT_LIB from .. import functions as fn from .. import GraphicsLayoutWidget from .. import ImageItem, TextItem tester = None # Convenient stamp used for ensuring image orientation is correct axisImg = [ " 1 1 1 ", " 1 1 1 1 1 1 ", " 1 1 1 1 1 1 1 1 1 1", " 1 1 1 1 1 ", " 1 1 1 1 1 1 ", " 1 1 ", " 1 1 ", " 1 ", " ", " 1 ", " 1 ", " 1 ", "1 1 1 1 1 ", "1 1 1 1 1 ", " 1 1 1 ", " 1 1 1 ", " 1 ", " 1 ", ] axisImg = np.array([map(int, row[::2].replace(' ', '0')) for row in axisImg]) def getTester(): global tester if tester is None: tester = ImageTester() return tester def assertImageApproved(image, standardFile, message=None, **kwargs): """Check that an image test result matches a pre-approved standard. If the result does not match, then the user can optionally invoke a GUI to compare the images and decide whether to fail the test or save the new image as the standard. This function will automatically clone the test-data repository into ~/.pyqtgraph/test-data. However, it is up to the user to ensure this repository is kept up to date and to commit/push new images after they are saved. Run the test with the environment variable PYQTGRAPH_AUDIT=1 to bring up the auditing GUI. Parameters ---------- image : (h, w, 4) ndarray standardFile : str The name of the approved test image to check against. This file name is relative to the root of the pyqtgraph test-data repository and will be automatically fetched. message : str A string description of the image. It is recommended to describe specific features that an auditor should look for when deciding whether to fail a test. Extra keyword arguments are used to set the thresholds for automatic image comparison (see ``assertImageMatch()``). """ if isinstance(image, QtGui.QWidget): w = image # just to be sure the widget size is correct (new window may be resized): QtGui.QApplication.processEvents() graphstate = scenegraphState(w, standardFile) image = np.zeros((w.height(), w.width(), 4), dtype=np.ubyte) qimg = fn.makeQImage(image, alpha=True, copy=False, transpose=False) painter = QtGui.QPainter(qimg) w.render(painter) painter.end() # transpose BGRA to RGBA image = image[..., [2, 1, 0, 3]] if message is None: code = inspect.currentframe().f_back.f_code message = "%s::%s" % (code.co_filename, code.co_name) # Make sure we have a test data repo available, possibly invoking git dataPath = getTestDataRepo() # Read the standard image if it exists stdFileName = os.path.join(dataPath, standardFile + '.png') if not os.path.isfile(stdFileName): stdImage = None else: pxm = QtGui.QPixmap() pxm.load(stdFileName) stdImage = fn.imageToArray(pxm.toImage(), copy=True, transpose=False) # If the test image does not match, then we go to audit if requested. try: if image.shape[2] != stdImage.shape[2]: raise Exception("Test result has different channel count than standard image" "(%d vs %d)" % (image.shape[2], stdImage.shape[2])) if image.shape != stdImage.shape: # Allow im1 to be an integer multiple larger than im2 to account # for high-resolution displays ims1 = np.array(image.shape).astype(float) ims2 = np.array(stdImage.shape).astype(float) sr = ims1 / ims2 if ims1[0] > ims2[0] else ims2 / ims1 if (sr[0] != sr[1] or not np.allclose(sr, np.round(sr)) or sr[0] < 1): raise TypeError("Test result shape %s is not an integer factor" " different than standard image shape %s." % (ims1, ims2)) sr = np.round(sr).astype(int) image = fn.downsample(image, sr[0], axis=(0, 1)).astype(image.dtype) assertImageMatch(image, stdImage, **kwargs) if bool(os.getenv('PYQTGRAPH_PRINT_TEST_STATE', False)): print(graphstate) if os.getenv('PYQTGRAPH_AUDIT_ALL') == '1': raise Exception("Image test passed, but auditing due to PYQTGRAPH_AUDIT_ALL evnironment variable.") except Exception: if stdFileName in gitStatus(dataPath): print("\n\nWARNING: unit test failed against modified standard " "image %s.\nTo revert this file, run `cd %s; git checkout " "%s`\n" % (stdFileName, dataPath, standardFile)) if os.getenv('PYQTGRAPH_AUDIT') == '1' or os.getenv('PYQTGRAPH_AUDIT_ALL') == '1': sys.excepthook(*sys.exc_info()) getTester().test(image, stdImage, message) stdPath = os.path.dirname(stdFileName) print('Saving new standard image to "%s"' % stdFileName) if not os.path.isdir(stdPath): os.makedirs(stdPath) img = fn.makeQImage(image, alpha=True, transpose=False) img.save(stdFileName) else: if stdImage is None: raise Exception("Test standard %s does not exist. Set " "PYQTGRAPH_AUDIT=1 to add this image." % stdFileName) else: if os.getenv('TRAVIS') is not None: saveFailedTest(image, stdImage, standardFile) print(graphstate) raise def assertImageMatch(im1, im2, minCorr=None, pxThreshold=50., pxCount=-1, maxPxDiff=None, avgPxDiff=None, imgDiff=None): """Check that two images match. Images that differ in shape or dtype will fail unconditionally. Further tests for similarity depend on the arguments supplied. By default, images may have no pixels that gave a value difference greater than 50. Parameters ---------- im1 : (h, w, 4) ndarray Test output image im2 : (h, w, 4) ndarray Test standard image minCorr : float or None Minimum allowed correlation coefficient between corresponding image values (see numpy.corrcoef) pxThreshold : float Minimum value difference at which two pixels are considered different pxCount : int or None Maximum number of pixels that may differ. Default is 0 for Qt4 and 1% of image size for Qt5. maxPxDiff : float or None Maximum allowed difference between pixels avgPxDiff : float or None Average allowed difference between pixels imgDiff : float or None Maximum allowed summed difference between images """ assert im1.ndim == 3 assert im1.shape[2] == 4 assert im1.dtype == im2.dtype if pxCount == -1: if QT_LIB == 'PyQt5': # Qt5 generates slightly different results; relax the tolerance # until test images are updated. pxCount = int(im1.shape[0] * im1.shape[1] * 0.01) else: pxCount = 0 diff = im1.astype(float) - im2.astype(float) if imgDiff is not None: assert np.abs(diff).sum() <= imgDiff pxdiff = diff.max(axis=2) # largest value difference per pixel mask = np.abs(pxdiff) >= pxThreshold if pxCount is not None: assert mask.sum() <= pxCount maskedDiff = diff[mask] if maxPxDiff is not None and maskedDiff.size > 0: assert maskedDiff.max() <= maxPxDiff if avgPxDiff is not None and maskedDiff.size > 0: assert maskedDiff.mean() <= avgPxDiff if minCorr is not None: with np.errstate(invalid='ignore'): corr = np.corrcoef(im1.ravel(), im2.ravel())[0, 1] assert corr >= minCorr def saveFailedTest(data, expect, filename): """Upload failed test images to web server to allow CI test debugging. """ commit = runSubprocess(['git', 'rev-parse', 'HEAD']) name = filename.split('/') name.insert(-1, commit.strip()) filename = '/'.join(name) host = 'data.pyqtgraph.org' # concatenate data, expect, and diff into a single image ds = data.shape es = expect.shape shape = (max(ds[0], es[0]) + 4, ds[1] + es[1] + 8 + max(ds[1], es[1]), 4) img = np.empty(shape, dtype=np.ubyte) img[..., :3] = 100 img[..., 3] = 255 img[2:2+ds[0], 2:2+ds[1], :ds[2]] = data img[2:2+es[0], ds[1]+4:ds[1]+4+es[1], :es[2]] = expect diff = makeDiffImage(data, expect) img[2:2+diff.shape[0], -diff.shape[1]-2:-2] = diff png = makePng(img) conn = httplib.HTTPConnection(host) req = urllib.urlencode({'name': filename, 'data': base64.b64encode(png)}) conn.request('POST', '/upload.py', req) response = conn.getresponse().read() conn.close() print("\nImage comparison failed. Test result: %s %s Expected result: " "%s %s" % (data.shape, data.dtype, expect.shape, expect.dtype)) print("Uploaded to: \nhttp://%s/data/%s" % (host, filename)) if not response.startswith(b'OK'): print("WARNING: Error uploading data to %s" % host) print(response) def makePng(img): """Given an array like (H, W, 4), return a PNG-encoded byte string. """ io = QtCore.QBuffer() qim = fn.makeQImage(img.transpose(1, 0, 2), alpha=False) qim.save(io, 'PNG') png = bytes(io.data().data()) return png def makeDiffImage(im1, im2): """Return image array showing the differences between im1 and im2. Handles images of different shape. Alpha channels are not compared. """ ds = im1.shape es = im2.shape diff = np.empty((max(ds[0], es[0]), max(ds[1], es[1]), 4), dtype=int) diff[..., :3] = 128 diff[..., 3] = 255 diff[:ds[0], :ds[1], :min(ds[2], 3)] += im1[..., :3] diff[:es[0], :es[1], :min(es[2], 3)] -= im2[..., :3] diff = np.clip(diff, 0, 255).astype(np.ubyte) return diff class ImageTester(QtGui.QWidget): """Graphical interface for auditing image comparison tests. """ def __init__(self): self.lastKey = None QtGui.QWidget.__init__(self) self.resize(1200, 800) #self.showFullScreen() self.layout = QtGui.QGridLayout() self.setLayout(self.layout) self.view = GraphicsLayoutWidget() self.layout.addWidget(self.view, 0, 0, 1, 2) self.label = QtGui.QLabel() self.layout.addWidget(self.label, 1, 0, 1, 2) self.label.setWordWrap(True) font = QtGui.QFont("monospace", 14, QtGui.QFont.Bold) self.label.setFont(font) self.passBtn = QtGui.QPushButton('Pass') self.failBtn = QtGui.QPushButton('Fail') self.layout.addWidget(self.passBtn, 2, 0) self.layout.addWidget(self.failBtn, 2, 1) self.passBtn.clicked.connect(self.passTest) self.failBtn.clicked.connect(self.failTest) self.views = (self.view.addViewBox(row=0, col=0), self.view.addViewBox(row=0, col=1), self.view.addViewBox(row=0, col=2)) labelText = ['test output', 'standard', 'diff'] for i, v in enumerate(self.views): v.setAspectLocked(1) v.invertY() v.image = ImageItem(axisOrder='row-major') v.image.setAutoDownsample(True) v.addItem(v.image) v.label = TextItem(labelText[i]) v.setBackgroundColor(0.5) self.views[1].setXLink(self.views[0]) self.views[1].setYLink(self.views[0]) self.views[2].setXLink(self.views[0]) self.views[2].setYLink(self.views[0]) def test(self, im1, im2, message): """Ask the user to decide whether an image test passes or fails. This method displays the test image, reference image, and the difference between the two. It then blocks until the user selects the test output by clicking a pass/fail button or typing p/f. If the user fails the test, then an exception is raised. """ self.show() if im2 is None: message += '\nImage1: %s %s Image2: [no standard]' % (im1.shape, im1.dtype) im2 = np.zeros((1, 1, 3), dtype=np.ubyte) else: message += '\nImage1: %s %s Image2: %s %s' % (im1.shape, im1.dtype, im2.shape, im2.dtype) self.label.setText(message) self.views[0].image.setImage(im1) self.views[1].image.setImage(im2) diff = makeDiffImage(im1, im2) self.views[2].image.setImage(diff) self.views[0].autoRange() while True: QtGui.QApplication.processEvents() lastKey = self.lastKey self.lastKey = None if lastKey in ('f', 'esc') or not self.isVisible(): raise Exception("User rejected test result.") elif lastKey == 'p': break time.sleep(0.03) for v in self.views: v.image.setImage(np.zeros((1, 1, 3), dtype=np.ubyte)) def keyPressEvent(self, event): if event.key() == QtCore.Qt.Key_Escape: self.lastKey = 'esc' else: self.lastKey = str(event.text()).lower() def passTest(self): self.lastKey = 'p' def failTest(self): self.lastKey = 'f' def getTestDataRepo(): """Return the path to a git repository with the required commit checked out. If the repository does not exist, then it is cloned from https://github.com/pyqtgraph/test-data. If the repository already exists then the required commit is checked out. """ global testDataTag dataPath = os.path.join(os.path.expanduser('~'), '.pyqtgraph', 'test-data') gitPath = 'https://github.com/pyqtgraph/test-data' gitbase = gitCmdBase(dataPath) if os.path.isdir(dataPath): # Already have a test-data repository to work with. # Get the commit ID of testDataTag. Do a fetch if necessary. try: tagCommit = gitCommitId(dataPath, testDataTag) except NameError: cmd = gitbase + ['fetch', '--tags', 'origin'] print(' '.join(cmd)) sp.check_call(cmd) try: tagCommit = gitCommitId(dataPath, testDataTag) except NameError: raise Exception("Could not find tag '%s' in test-data repo at" " %s" % (testDataTag, dataPath)) except Exception: if not os.path.exists(os.path.join(dataPath, '.git')): raise Exception("Directory '%s' does not appear to be a git " "repository. Please remove this directory." % dataPath) else: raise # If HEAD is not the correct commit, then do a checkout if gitCommitId(dataPath, 'HEAD') != tagCommit: print("Checking out test-data tag '%s'" % testDataTag) sp.check_call(gitbase + ['checkout', testDataTag]) else: print("Attempting to create git clone of test data repo in %s.." % dataPath) parentPath = os.path.split(dataPath)[0] if not os.path.isdir(parentPath): os.makedirs(parentPath) if os.getenv('TRAVIS') is not None: # Create a shallow clone of the test-data repository (to avoid # downloading more data than is necessary) os.makedirs(dataPath) cmds = [ gitbase + ['init'], gitbase + ['remote', 'add', 'origin', gitPath], gitbase + ['fetch', '--tags', 'origin', testDataTag, '--depth=1'], gitbase + ['checkout', '-b', 'master', 'FETCH_HEAD'], ] else: # Create a full clone cmds = [['git', 'clone', gitPath, dataPath]] for cmd in cmds: print(' '.join(cmd)) rval = sp.check_call(cmd) if rval == 0: continue raise RuntimeError("Test data path '%s' does not exist and could " "not be created with git. Please create a git " "clone of %s at this path." % (dataPath, gitPath)) return dataPath def gitCmdBase(path): return ['git', '--git-dir=%s/.git' % path, '--work-tree=%s' % path] def gitStatus(path): """Return a string listing all changes to the working tree in a git repository. """ cmd = gitCmdBase(path) + ['status', '--porcelain'] return runSubprocess(cmd, stderr=None, universal_newlines=True) def gitCommitId(path, ref): """Return the commit id of *ref* in the git repository at *path*. """ cmd = gitCmdBase(path) + ['show', ref] try: output = runSubprocess(cmd, stderr=None, universal_newlines=True) except sp.CalledProcessError: print(cmd) raise NameError("Unknown git reference '%s'" % ref) commit = output.split('\n')[0] assert commit[:7] == 'commit ' return commit[7:] def runSubprocess(command, return_code=False, **kwargs): """Run command using subprocess.Popen Similar to subprocess.check_output(), which is not available in 2.6. Run command and wait for command to complete. If the return code was zero then return, otherwise raise CalledProcessError. By default, this will also add stdout= and stderr=subproces.PIPE to the call to Popen to suppress printing to the terminal. Parameters ---------- command : list of str Command to run as subprocess (see subprocess.Popen documentation). **kwargs : dict Additional kwargs to pass to ``subprocess.Popen``. Returns ------- stdout : str Stdout returned by the process. """ # code adapted with permission from mne-python use_kwargs = dict(stderr=None, stdout=sp.PIPE) use_kwargs.update(kwargs) p = sp.Popen(command, **use_kwargs) output = p.communicate()[0] # communicate() may return bytes, str, or None depending on the kwargs # passed to Popen(). Convert all to unicode str: output = '' if output is None else output output = output.decode('utf-8') if isinstance(output, bytes) else output if p.returncode != 0: print(output) err_fun = sp.CalledProcessError.__init__ if 'output' in inspect.getargspec(err_fun).args: raise sp.CalledProcessError(p.returncode, command, output) else: raise sp.CalledProcessError(p.returncode, command) return output def scenegraphState(view, name): """Return information about the scenegraph for debugging test failures. """ state = "====== Scenegraph state for %s ======\n" % name state += "view size: %dx%d\n" % (view.width(), view.height()) state += "view transform:\n" + indent(transformStr(view.transform()), " ") for item in view.scene().items(): if item.parentItem() is None: state += itemState(item) + '\n' return state def itemState(root): state = str(root) + '\n' from .. import ViewBox state += 'bounding rect: ' + str(root.boundingRect()) + '\n' if isinstance(root, ViewBox): state += "view range: " + str(root.viewRange()) + '\n' state += "transform:\n" + indent(transformStr(root.transform()).strip(), " ") + '\n' for item in root.childItems(): state += indent(itemState(item).strip(), " ") + '\n' return state def transformStr(t): return ("[%0.2f %0.2f %0.2f]\n"*3) % (t.m11(), t.m12(), t.m13(), t.m21(), t.m22(), t.m23(), t.m31(), t.m32(), t.m33()) def indent(s, pfx): return '\n'.join([pfx+line for line in s.split('\n')]) class TransposedImageItem(ImageItem): # used for testing image axis order; we can test row-major and col-major using # the same test images def __init__(self, *args, **kwds): self.__transpose = kwds.pop('transpose', False) ImageItem.__init__(self, *args, **kwds) def setImage(self, image=None, **kwds): if image is not None and self.__transpose is True: image = np.swapaxes(image, 0, 1) return ImageItem.setImage(self, image, **kwds) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/tests/test_exit_crash.py000066400000000000000000000022361300727121400245470ustar00rootroot00000000000000import os, sys, subprocess, tempfile import pyqtgraph as pg import six import pytest code = """ import sys sys.path.insert(0, '{path}') import pyqtgraph as pg app = pg.mkQApp() w = pg.{classname}({args}) """ skipmessage = ('unclear why this test is failing. skipping until someone has' ' time to fix it') @pytest.mark.skipif(True, reason=skipmessage) def test_exit_crash(): # For each Widget subclass, run a simple python script that creates an # instance and then shuts down. The intent is to check for segmentation # faults when each script exits. tmp = tempfile.mktemp(".py") path = os.path.dirname(pg.__file__) initArgs = { 'CheckTable': "[]", 'ProgressDialog': '"msg"', 'VerticalLabel': '"msg"', } for name in dir(pg): obj = getattr(pg, name) if not isinstance(obj, type) or not issubclass(obj, pg.QtGui.QWidget): continue print(name) argstr = initArgs.get(name, "") open(tmp, 'w').write(code.format(path=path, classname=name, args=argstr)) proc = subprocess.Popen([sys.executable, tmp]) assert proc.wait() == 0 os.remove(tmp) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/tests/test_functions.py000066400000000000000000000257311300727121400244330ustar00rootroot00000000000000import pyqtgraph as pg import numpy as np from numpy.testing import assert_array_almost_equal, assert_almost_equal import pytest np.random.seed(12345) def testSolve3D(): p1 = np.array([[0,0,0,1], [1,0,0,1], [0,1,0,1], [0,0,1,1]], dtype=float) # transform points through random matrix tr = np.random.normal(size=(4, 4)) tr[3] = (0,0,0,1) p2 = np.dot(tr, p1.T).T[:,:3] # solve to see if we can recover the transformation matrix. tr2 = pg.solve3DTransform(p1, p2) assert_array_almost_equal(tr[:3], tr2[:3]) def test_interpolateArray(): def interpolateArray(data, x): result = pg.interpolateArray(data, x) assert result.shape == x.shape[:-1] + data.shape[x.shape[-1]:] return result data = np.array([[ 1., 2., 4. ], [ 10., 20., 40. ], [ 100., 200., 400.]]) # test various x shapes interpolateArray(data, np.ones((1,))) interpolateArray(data, np.ones((2,))) interpolateArray(data, np.ones((1, 1))) interpolateArray(data, np.ones((1, 2))) interpolateArray(data, np.ones((5, 1))) interpolateArray(data, np.ones((5, 2))) interpolateArray(data, np.ones((5, 5, 1))) interpolateArray(data, np.ones((5, 5, 2))) with pytest.raises(TypeError): interpolateArray(data, np.ones((3,))) with pytest.raises(TypeError): interpolateArray(data, np.ones((1, 3,))) with pytest.raises(TypeError): interpolateArray(data, np.ones((5, 5, 3,))) x = np.array([[ 0.3, 0.6], [ 1. , 1. ], [ 0.5, 1. ], [ 0.5, 2.5], [ 10. , 10. ]]) result = interpolateArray(data, x) #import scipy.ndimage #spresult = scipy.ndimage.map_coordinates(data, x.T, order=1) spresult = np.array([ 5.92, 20. , 11. , 0. , 0. ]) # generated with the above line assert_array_almost_equal(result, spresult) # test mapping when x.shape[-1] < data.ndim x = np.array([[ 0.3, 0], [ 0.3, 1], [ 0.3, 2]]) r1 = interpolateArray(data, x) x = np.array([0.3]) # should broadcast across axis 1 r2 = interpolateArray(data, x) assert_array_almost_equal(r1, r2) # test mapping 2D array of locations x = np.array([[[0.5, 0.5], [0.5, 1.0], [0.5, 1.5]], [[1.5, 0.5], [1.5, 1.0], [1.5, 1.5]]]) r1 = interpolateArray(data, x) #r2 = scipy.ndimage.map_coordinates(data, x.transpose(2,0,1), order=1) r2 = np.array([[ 8.25, 11. , 16.5 ], # generated with the above line [ 82.5 , 110. , 165. ]]) assert_array_almost_equal(r1, r2) # test interpolate where data.ndim > x.shape[1] data = np.array([[[1, 2, 3], [4, 5, 6]], [[7, 8, 9], [10, 11, 12]]]) # 2x2x3 x = np.array([[1, 1], [0, 0.5], [5, 5]]) r1 = interpolateArray(data, x) assert np.all(r1[0] == data[1, 1]) assert np.all(r1[1] == 0.5 * (data[0, 0] + data[0, 1])) assert np.all(r1[2] == 0) def test_subArray(): a = np.array([0, 0, 111, 112, 113, 0, 121, 122, 123, 0, 0, 0, 211, 212, 213, 0, 221, 222, 223, 0, 0, 0, 0]) b = pg.subArray(a, offset=2, shape=(2,2,3), stride=(10,4,1)) c = np.array([[[111,112,113], [121,122,123]], [[211,212,213], [221,222,223]]]) assert np.all(b == c) # operate over first axis; broadcast over the rest aa = np.vstack([a, a/100.]).T cc = np.empty(c.shape + (2,)) cc[..., 0] = c cc[..., 1] = c / 100. bb = pg.subArray(aa, offset=2, shape=(2,2,3), stride=(10,4,1)) assert np.all(bb == cc) def test_rescaleData(): dtypes = map(np.dtype, ('ubyte', 'uint16', 'byte', 'int16', 'int', 'float')) for dtype1 in dtypes: for dtype2 in dtypes: data = (np.random.random(size=10) * 2**32 - 2**31).astype(dtype1) for scale, offset in [(10, 0), (10., 0.), (1, -50), (0.2, 0.5), (0.001, 0)]: if dtype2.kind in 'iu': lim = np.iinfo(dtype2) lim = lim.min, lim.max else: lim = (-np.inf, np.inf) s1 = np.clip(float(scale) * (data-float(offset)), *lim).astype(dtype2) s2 = pg.rescaleData(data, scale, offset, dtype2) assert s1.dtype == s2.dtype if dtype2.kind in 'iu': assert np.all(s1 == s2) else: assert np.allclose(s1, s2) def test_makeARGB(): # Many parameters to test here: # * data dtype (ubyte, uint16, float, others) # * data ndim (2 or 3) # * levels (None, 1D, or 2D) # * lut dtype # * lut size # * lut ndim (1 or 2) # * useRGBA argument # Need to check that all input values map to the correct output values, especially # at and beyond the edges of the level range. def checkArrays(a, b): # because py.test output is difficult to read for arrays if not np.all(a == b): comp = [] for i in range(a.shape[0]): if a.shape[1] > 1: comp.append('[') for j in range(a.shape[1]): m = a[i,j] == b[i,j] comp.append('%d,%d %s %s %s%s' % (i, j, str(a[i,j]).ljust(15), str(b[i,j]).ljust(15), m, ' ********' if not np.all(m) else '')) if a.shape[1] > 1: comp.append(']') raise Exception("arrays do not match:\n%s" % '\n'.join(comp)) def checkImage(img, check, alpha, alphaCheck): assert img.dtype == np.ubyte assert alpha is alphaCheck if alpha is False: checkArrays(img[..., 3], 255) if np.isscalar(check) or check.ndim == 3: checkArrays(img[..., :3], check) elif check.ndim == 2: checkArrays(img[..., :3], check[..., np.newaxis]) elif check.ndim == 1: checkArrays(img[..., :3], check[..., np.newaxis, np.newaxis]) else: raise Exception('invalid check array ndim') # uint8 data tests im1 = np.arange(256).astype('ubyte').reshape(256, 1) im2, alpha = pg.makeARGB(im1, levels=(0, 255)) checkImage(im2, im1, alpha, False) im3, alpha = pg.makeARGB(im1, levels=(0.0, 255.0)) checkImage(im3, im1, alpha, False) im4, alpha = pg.makeARGB(im1, levels=(255, 0)) checkImage(im4, 255-im1, alpha, False) im5, alpha = pg.makeARGB(np.concatenate([im1]*3, axis=1), levels=[(0, 255), (0.0, 255.0), (255, 0)]) checkImage(im5, np.concatenate([im1, im1, 255-im1], axis=1), alpha, False) im2, alpha = pg.makeARGB(im1, levels=(128,383)) checkImage(im2[:128], 0, alpha, False) checkImage(im2[128:], im1[:128], alpha, False) # uint8 data + uint8 LUT lut = np.arange(256)[::-1].astype(np.uint8) im2, alpha = pg.makeARGB(im1, lut=lut) checkImage(im2, lut, alpha, False) # lut larger than maxint lut = np.arange(511).astype(np.uint8) im2, alpha = pg.makeARGB(im1, lut=lut) checkImage(im2, lut[::2], alpha, False) # lut smaller than maxint lut = np.arange(128).astype(np.uint8) im2, alpha = pg.makeARGB(im1, lut=lut) checkImage(im2, np.linspace(0, 127, 256).astype('ubyte'), alpha, False) # lut + levels lut = np.arange(256)[::-1].astype(np.uint8) im2, alpha = pg.makeARGB(im1, lut=lut, levels=[-128, 384]) checkImage(im2, np.linspace(192, 65.5, 256).astype('ubyte'), alpha, False) im2, alpha = pg.makeARGB(im1, lut=lut, levels=[64, 192]) checkImage(im2, np.clip(np.linspace(385.5, -126.5, 256), 0, 255).astype('ubyte'), alpha, False) # uint8 data + uint16 LUT lut = np.arange(4096)[::-1].astype(np.uint16) // 16 im2, alpha = pg.makeARGB(im1, lut=lut) checkImage(im2, np.arange(256)[::-1].astype('ubyte'), alpha, False) # uint8 data + float LUT lut = np.linspace(10., 137., 256) im2, alpha = pg.makeARGB(im1, lut=lut) checkImage(im2, lut.astype('ubyte'), alpha, False) # uint8 data + 2D LUT lut = np.zeros((256, 3), dtype='ubyte') lut[:,0] = np.arange(256) lut[:,1] = np.arange(256)[::-1] lut[:,2] = 7 im2, alpha = pg.makeARGB(im1, lut=lut) checkImage(im2, lut[:,None,::-1], alpha, False) # check useRGBA im2, alpha = pg.makeARGB(im1, lut=lut, useRGBA=True) checkImage(im2, lut[:,None,:], alpha, False) # uint16 data tests im1 = np.arange(0, 2**16, 256).astype('uint16')[:, None] im2, alpha = pg.makeARGB(im1, levels=(512, 2**16)) checkImage(im2, np.clip(np.linspace(-2, 253, 256), 0, 255).astype('ubyte'), alpha, False) lut = (np.arange(512, 2**16)[::-1] // 256).astype('ubyte') im2, alpha = pg.makeARGB(im1, lut=lut, levels=(512, 2**16-256)) checkImage(im2, np.clip(np.linspace(257, 2, 256), 0, 255).astype('ubyte'), alpha, False) lut = np.zeros(2**16, dtype='ubyte') lut[1000:1256] = np.arange(256) lut[1256:] = 255 im1 = np.arange(1000, 1256).astype('uint16')[:, None] im2, alpha = pg.makeARGB(im1, lut=lut) checkImage(im2, np.arange(256).astype('ubyte'), alpha, False) # float data tests im1 = np.linspace(1.0, 17.0, 256)[:, None] im2, alpha = pg.makeARGB(im1, levels=(5.0, 13.0)) checkImage(im2, np.clip(np.linspace(-128, 383, 256), 0, 255).astype('ubyte'), alpha, False) lut = (np.arange(1280)[::-1] // 10).astype('ubyte') im2, alpha = pg.makeARGB(im1, lut=lut, levels=(1, 17)) checkImage(im2, np.linspace(127.5, 0, 256).astype('ubyte'), alpha, False) # test sanity checks class AssertExc(object): def __init__(self, exc=Exception): self.exc = exc def __enter__(self): return self def __exit__(self, *args): assert args[0] is self.exc, "Should have raised %s (got %s)" % (self.exc, args[0]) return True with AssertExc(TypeError): # invalid image shape pg.makeARGB(np.zeros((2,), dtype='float')) with AssertExc(TypeError): # invalid image shape pg.makeARGB(np.zeros((2,2,7), dtype='float')) with AssertExc(): # float images require levels arg pg.makeARGB(np.zeros((2,2), dtype='float')) with AssertExc(): # bad levels arg pg.makeARGB(np.zeros((2,2), dtype='float'), levels=[1]) with AssertExc(): # bad levels arg pg.makeARGB(np.zeros((2,2), dtype='float'), levels=[1,2,3]) with AssertExc(): # can't mix 3-channel levels and LUT pg.makeARGB(np.zeros((2,2)), lut=np.zeros((10,3), dtype='ubyte'), levels=[(0,1)]*3) with AssertExc(): # multichannel levels must have same number of channels as image pg.makeARGB(np.zeros((2,2,3), dtype='float'), levels=[(1,2)]*4) with AssertExc(): # 3d levels not allowed pg.makeARGB(np.zeros((2,2,3), dtype='float'), levels=np.zeros([3, 2, 2])) if __name__ == '__main__': test_interpolateArray()pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/tests/test_qt.py000066400000000000000000000011651300727121400230420ustar00rootroot00000000000000import pyqtgraph as pg import gc, os import pytest app = pg.mkQApp() def test_isQObjectAlive(): o1 = pg.QtCore.QObject() o2 = pg.QtCore.QObject() o2.setParent(o1) del o1 gc.collect() assert not pg.Qt.isQObjectAlive(o2) @pytest.mark.skipif(pg.Qt.USE_PYSIDE, reason='pysideuic does not appear to be ' 'packaged with conda') def test_loadUiType(): path = os.path.dirname(__file__) formClass, baseClass = pg.Qt.loadUiType(os.path.join(path, 'uictest.ui')) w = baseClass() ui = formClass() ui.setupUi(w) w.show() app.processEvents() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/tests/test_ref_cycles.py000066400000000000000000000047031300727121400245350ustar00rootroot00000000000000""" Test for unwanted reference cycles """ import pyqtgraph as pg import numpy as np import gc, weakref import six import pytest app = pg.mkQApp() skipreason = ('unclear why test is failing on python 3. skipping until someone ' 'has time to fix it. Or pyside is being used. This test is ' 'failing on pyside for an unknown reason too.') def assert_alldead(refs): for ref in refs: assert ref() is None def qObjectTree(root): """Return root and its entire tree of qobject children""" childs = [root] for ch in pg.QtCore.QObject.children(root): childs += qObjectTree(ch) return childs def mkrefs(*objs): """Return a list of weakrefs to each object in *objs. QObject instances are expanded to include all child objects. """ allObjs = {} for obj in objs: if isinstance(obj, pg.QtCore.QObject): obj = qObjectTree(obj) else: obj = [obj] for o in obj: allObjs[id(o)] = o return map(weakref.ref, allObjs.values()) @pytest.mark.skipif(six.PY3 or pg.Qt.USE_PYSIDE, reason=skipreason) def test_PlotWidget(): def mkobjs(*args, **kwds): w = pg.PlotWidget(*args, **kwds) data = pg.np.array([1,5,2,4,3]) c = w.plot(data, name='stuff') w.addLegend() # test that connections do not keep objects alive w.plotItem.vb.sigRangeChanged.connect(mkrefs) app.focusChanged.connect(w.plotItem.vb.invertY) # return weakrefs to a bunch of objects that should die when the scope exits. return mkrefs(w, c, data, w.plotItem, w.plotItem.vb, w.plotItem.getMenu(), w.plotItem.getAxis('left')) for i in range(5): assert_alldead(mkobjs()) @pytest.mark.skipif(six.PY3 or pg.Qt.USE_PYSIDE, reason=skipreason) def test_ImageView(): def mkobjs(): iv = pg.ImageView() data = np.zeros((10,10,5)) iv.setImage(data) return mkrefs(iv, iv.imageItem, iv.view, iv.ui.histogram, data) for i in range(5): assert_alldead(mkobjs()) @pytest.mark.skipif(six.PY3 or pg.Qt.USE_PYSIDE, reason=skipreason) def test_GraphicsWindow(): def mkobjs(): w = pg.GraphicsWindow() p1 = w.addPlot() v1 = w.addViewBox() return mkrefs(w, p1, v1) for i in range(5): assert_alldead(mkobjs()) if __name__ == '__main__': ot = test_PlotItem() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/tests/test_srttransform3d.py000066400000000000000000000024731300727121400254140ustar00rootroot00000000000000import pyqtgraph as pg from pyqtgraph.Qt import QtCore, QtGui import numpy as np from numpy.testing import assert_array_almost_equal, assert_almost_equal testPoints = np.array([ [0, 0, 0], [1, 0, 0], [0, 1, 0], [0, 0, 1], [-1, -1, 0], [0, -1, -1]]) def testMatrix(): """ SRTTransform3D => Transform3D => SRTTransform3D """ tr = pg.SRTTransform3D() tr.setRotate(45, (0, 0, 1)) tr.setScale(0.2, 0.4, 1) tr.setTranslate(10, 20, 40) assert tr.getRotation() == (45, QtGui.QVector3D(0, 0, 1)) assert tr.getScale() == QtGui.QVector3D(0.2, 0.4, 1) assert tr.getTranslation() == QtGui.QVector3D(10, 20, 40) tr2 = pg.Transform3D(tr) assert np.all(tr.matrix() == tr2.matrix()) # This is the most important test: # The transition from Transform3D to SRTTransform3D is a tricky one. tr3 = pg.SRTTransform3D(tr2) assert_array_almost_equal(tr.matrix(), tr3.matrix()) assert_almost_equal(tr3.getRotation()[0], tr.getRotation()[0]) assert_array_almost_equal(tr3.getRotation()[1], tr.getRotation()[1]) assert_array_almost_equal(tr3.getScale(), tr.getScale()) assert_array_almost_equal(tr3.getTranslation(), tr.getTranslation()) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/tests/test_stability.py000066400000000000000000000067571300727121400244360ustar00rootroot00000000000000""" PyQt/PySide stress test: Create lots of random widgets and graphics items, connect them together randomly, the tear them down repeatedly. The purpose of this is to attempt to generate segmentation faults. """ from pyqtgraph.Qt import QtTest import pyqtgraph as pg from random import seed, randint import sys, gc, weakref app = pg.mkQApp() seed(12345) widgetTypes = [ pg.PlotWidget, pg.ImageView, pg.GraphicsView, pg.QtGui.QWidget, pg.QtGui.QTreeWidget, pg.QtGui.QPushButton, ] itemTypes = [ pg.PlotCurveItem, pg.ImageItem, pg.PlotDataItem, pg.ViewBox, pg.QtGui.QGraphicsRectItem ] widgets = [] items = [] allWidgets = weakref.WeakKeyDictionary() def crashtest(): global allWidgets try: gc.disable() actions = [ createWidget, #setParent, forgetWidget, showWidget, processEvents, #raiseException, #addReference, ] thread = WorkThread() thread.start() while True: try: action = randItem(actions) action() print('[%d widgets alive, %d zombie]' % (len(allWidgets), len(allWidgets) - len(widgets))) except KeyboardInterrupt: print("Caught interrupt; send another to exit.") try: for i in range(100): QtTest.QTest.qWait(100) except KeyboardInterrupt: thread.terminate() break except: sys.excepthook(*sys.exc_info()) finally: gc.enable() class WorkThread(pg.QtCore.QThread): '''Intended to give the gc an opportunity to run from a non-gui thread.''' def run(self): i = 0 while True: i += 1 if (i % 1000000) == 0: print('--worker--') def randItem(items): return items[randint(0, len(items)-1)] def p(msg): print(msg) sys.stdout.flush() def createWidget(): p('create widget') global widgets, allWidgets if len(widgets) > 50: return widget = randItem(widgetTypes)() widget.setWindowTitle(widget.__class__.__name__) widgets.append(widget) allWidgets[widget] = 1 p(" %s" % widget) return widget def setParent(): p('set parent') global widgets if len(widgets) < 2: return child = parent = None while child is parent: child = randItem(widgets) parent = randItem(widgets) p(" %s parent of %s" % (parent, child)) child.setParent(parent) def forgetWidget(): p('forget widget') global widgets if len(widgets) < 1: return widget = randItem(widgets) p(' %s' % widget) widgets.remove(widget) def showWidget(): p('show widget') global widgets if len(widgets) < 1: return widget = randItem(widgets) p(' %s' % widget) widget.show() def processEvents(): p('process events') QtTest.QTest.qWait(25) class TstException(Exception): pass def raiseException(): p('raise exception') raise TstException("A test exception") def addReference(): p('add reference') global widgets if len(widgets) < 1: return obj1 = randItem(widgets) obj2 = randItem(widgets) p(' %s -> %s' % (obj1, obj2)) obj1._testref = obj2 if __name__ == '__main__': test_stability() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/tests/ui_testing.py000066400000000000000000000040611300727121400235270ustar00rootroot00000000000000 # Functions for generating user input events. # We would like to use QTest for this purpose, but it seems to be broken. # See: http://stackoverflow.com/questions/16299779/qt-qgraphicsview-unit-testing-how-to-keep-the-mouse-in-a-pressed-state from ..Qt import QtCore, QtGui, QT_LIB def mousePress(widget, pos, button, modifier=None): if isinstance(widget, QtGui.QGraphicsView): widget = widget.viewport() if modifier is None: modifier = QtCore.Qt.NoModifier if QT_LIB != 'PyQt5' and isinstance(pos, QtCore.QPointF): pos = pos.toPoint() event = QtGui.QMouseEvent(QtCore.QEvent.MouseButtonPress, pos, button, QtCore.Qt.NoButton, modifier) QtGui.QApplication.sendEvent(widget, event) def mouseRelease(widget, pos, button, modifier=None): if isinstance(widget, QtGui.QGraphicsView): widget = widget.viewport() if modifier is None: modifier = QtCore.Qt.NoModifier if QT_LIB != 'PyQt5' and isinstance(pos, QtCore.QPointF): pos = pos.toPoint() event = QtGui.QMouseEvent(QtCore.QEvent.MouseButtonRelease, pos, button, QtCore.Qt.NoButton, modifier) QtGui.QApplication.sendEvent(widget, event) def mouseMove(widget, pos, buttons=None, modifier=None): if isinstance(widget, QtGui.QGraphicsView): widget = widget.viewport() if modifier is None: modifier = QtCore.Qt.NoModifier if buttons is None: buttons = QtCore.Qt.NoButton if QT_LIB != 'PyQt5' and isinstance(pos, QtCore.QPointF): pos = pos.toPoint() event = QtGui.QMouseEvent(QtCore.QEvent.MouseMove, pos, QtCore.Qt.NoButton, buttons, modifier) QtGui.QApplication.sendEvent(widget, event) def mouseDrag(widget, pos1, pos2, button, modifier=None): mouseMove(widget, pos1) mousePress(widget, pos1, button, modifier) mouseMove(widget, pos2, button, modifier) mouseRelease(widget, pos2, button, modifier) def mouseClick(widget, pos, button, modifier=None): mouseMove(widget, pos) mousePress(widget, pos, button, modifier) mouseRelease(widget, pos, button, modifier) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/tests/uictest.ui000066400000000000000000000021731300727121400230240ustar00rootroot00000000000000 Form 0 0 400 300 Form 10 10 120 80 10 110 120 80 PlotWidget QWidget
pyqtgraph
1 ImageView QWidget
pyqtgraph
1 pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/units.py000066400000000000000000000025721300727121400213620ustar00rootroot00000000000000# -*- coding: utf-8 -*- ## Very simple unit support: ## - creates variable names like 'mV' and 'kHz' ## - the value assigned to the variable corresponds to the scale prefix ## (mV = 0.001) ## - the actual units are purely cosmetic for making code clearer: ## ## x = 20*pA is identical to x = 20*1e-12 ## No unicode variable names (μ,Ω) allowed until python 3 SI_PREFIXES = 'yzafpnum kMGTPEZY' UNITS = 'm,s,g,W,J,V,A,F,T,Hz,Ohm,S,N,C,px,b,B'.split(',') allUnits = {} def addUnit(p, n): g = globals() v = 1000**n for u in UNITS: g[p+u] = v allUnits[p+u] = v for p in SI_PREFIXES: if p == ' ': p = '' n = 0 elif p == 'u': n = -2 else: n = SI_PREFIXES.index(p) - 8 addUnit(p, n) cm = 0.01 def evalUnits(unitStr): """ Evaluate a unit string into ([numerators,...], [denominators,...]) Examples: N m/s^2 => ([N, m], [s, s]) A*s / V => ([A, s], [V,]) """ pass def formatUnits(units): """ Format a unit specification ([numerators,...], [denominators,...]) into a string (this is the inverse of evalUnits) """ pass def simplify(units): """ Cancel units that appear in both numerator and denominator, then attempt to replace groups of units with single units where possible (ie, J/s => W) """ pass pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/util/000077500000000000000000000000001300727121400206155ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/util/__init__.py000066400000000000000000000000001300727121400227140ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/util/colorama/000077500000000000000000000000001300727121400224125ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/util/colorama/LICENSE.txt000066400000000000000000000027241300727121400242420ustar00rootroot00000000000000Copyright (c) 2010 Jonathan Hartley All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of the copyright holders, nor those of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/util/colorama/README.txt000066400000000000000000000242351300727121400241160ustar00rootroot00000000000000Download and docs: http://pypi.python.org/pypi/colorama Development: http://code.google.com/p/colorama Discussion group: https://groups.google.com/forum/#!forum/python-colorama Description =========== Makes ANSI escape character sequences for producing colored terminal text and cursor positioning work under MS Windows. ANSI escape character sequences have long been used to produce colored terminal text and cursor positioning on Unix and Macs. Colorama makes this work on Windows, too, by wrapping stdout, stripping ANSI sequences it finds (which otherwise show up as gobbledygook in your output), and converting them into the appropriate win32 calls to modify the state of the terminal. On other platforms, Colorama does nothing. Colorama also provides some shortcuts to help generate ANSI sequences but works fine in conjunction with any other ANSI sequence generation library, such as Termcolor (http://pypi.python.org/pypi/termcolor.) This has the upshot of providing a simple cross-platform API for printing colored terminal text from Python, and has the happy side-effect that existing applications or libraries which use ANSI sequences to produce colored output on Linux or Macs can now also work on Windows, simply by calling ``colorama.init()``. An alternative approach is to install 'ansi.sys' on Windows machines, which provides the same behaviour for all applications running in terminals. Colorama is intended for situations where that isn't easy (e.g. maybe your app doesn't have an installer.) Demo scripts in the source code repository prints some colored text using ANSI sequences. Compare their output under Gnome-terminal's built in ANSI handling, versus on Windows Command-Prompt using Colorama: .. image:: http://colorama.googlecode.com/hg/screenshots/ubuntu-demo.png :width: 661 :height: 357 :alt: ANSI sequences on Ubuntu under gnome-terminal. .. image:: http://colorama.googlecode.com/hg/screenshots/windows-demo.png :width: 668 :height: 325 :alt: Same ANSI sequences on Windows, using Colorama. These screengrabs show that Colorama on Windows does not support ANSI 'dim text': it looks the same as 'normal text'. License ======= Copyright Jonathan Hartley 2013. BSD 3-Clause license, see LICENSE file. Dependencies ============ None, other than Python. Tested on Python 2.5.5, 2.6.5, 2.7, 3.1.2, and 3.2 Usage ===== Initialisation -------------- Applications should initialise Colorama using:: from colorama import init init() If you are on Windows, the call to ``init()`` will start filtering ANSI escape sequences out of any text sent to stdout or stderr, and will replace them with equivalent Win32 calls. Calling ``init()`` has no effect on other platforms (unless you request other optional functionality, see keyword args below.) The intention is that applications can call ``init()`` unconditionally on all platforms, after which ANSI output should just work. To stop using colorama before your program exits, simply call ``deinit()``. This will restore stdout and stderr to their original values, so that Colorama is disabled. To start using Colorama again, call ``reinit()``, which wraps stdout and stderr again, but is cheaper to call than doing ``init()`` all over again. Colored Output -------------- Cross-platform printing of colored text can then be done using Colorama's constant shorthand for ANSI escape sequences:: from colorama import Fore, Back, Style print(Fore.RED + 'some red text') print(Back.GREEN + 'and with a green background') print(Style.DIM + 'and in dim text') print(Fore.RESET + Back.RESET + Style.RESET_ALL) print('back to normal now') or simply by manually printing ANSI sequences from your own code:: print('/033[31m' + 'some red text') print('/033[30m' # and reset to default color) or Colorama can be used happily in conjunction with existing ANSI libraries such as Termcolor:: from colorama import init from termcolor import colored # use Colorama to make Termcolor work on Windows too init() # then use Termcolor for all colored text output print(colored('Hello, World!', 'green', 'on_red')) Available formatting constants are:: Fore: BLACK, RED, GREEN, YELLOW, BLUE, MAGENTA, CYAN, WHITE, RESET. Back: BLACK, RED, GREEN, YELLOW, BLUE, MAGENTA, CYAN, WHITE, RESET. Style: DIM, NORMAL, BRIGHT, RESET_ALL Style.RESET_ALL resets foreground, background and brightness. Colorama will perform this reset automatically on program exit. Cursor Positioning ------------------ ANSI codes to reposition the cursor are supported. See demos/demo06.py for an example of how to generate them. Init Keyword Args ----------------- ``init()`` accepts some kwargs to override default behaviour. init(autoreset=False): If you find yourself repeatedly sending reset sequences to turn off color changes at the end of every print, then ``init(autoreset=True)`` will automate that:: from colorama import init init(autoreset=True) print(Fore.RED + 'some red text') print('automatically back to default color again') init(strip=None): Pass ``True`` or ``False`` to override whether ansi codes should be stripped from the output. The default behaviour is to strip if on Windows. init(convert=None): Pass ``True`` or ``False`` to override whether to convert ansi codes in the output into win32 calls. The default behaviour is to convert if on Windows and output is to a tty (terminal). init(wrap=True): On Windows, colorama works by replacing ``sys.stdout`` and ``sys.stderr`` with proxy objects, which override the .write() method to do their work. If this wrapping causes you problems, then this can be disabled by passing ``init(wrap=False)``. The default behaviour is to wrap if autoreset or strip or convert are True. When wrapping is disabled, colored printing on non-Windows platforms will continue to work as normal. To do cross-platform colored output, you can use Colorama's ``AnsiToWin32`` proxy directly:: import sys from colorama import init, AnsiToWin32 init(wrap=False) stream = AnsiToWin32(sys.stderr).stream # Python 2 print >>stream, Fore.BLUE + 'blue text on stderr' # Python 3 print(Fore.BLUE + 'blue text on stderr', file=stream) Status & Known Problems ======================= I've personally only tested it on WinXP (CMD, Console2), Ubuntu (gnome-terminal, xterm), and OSX. Some presumably valid ANSI sequences aren't recognised (see details below) but to my knowledge nobody has yet complained about this. Puzzling. See outstanding issues and wishlist at: http://code.google.com/p/colorama/issues/list If anything doesn't work for you, or doesn't do what you expected or hoped for, I'd love to hear about it on that issues list, would be delighted by patches, and would be happy to grant commit access to anyone who submits a working patch or two. Recognised ANSI Sequences ========================= ANSI sequences generally take the form: ESC [ ; ... Where is an integer, and is a single letter. Zero or more params are passed to a . If no params are passed, it is generally synonymous with passing a single zero. No spaces exist in the sequence, they have just been inserted here to make it easy to read. The only ANSI sequences that colorama converts into win32 calls are:: ESC [ 0 m # reset all (colors and brightness) ESC [ 1 m # bright ESC [ 2 m # dim (looks same as normal brightness) ESC [ 22 m # normal brightness # FOREGROUND: ESC [ 30 m # black ESC [ 31 m # red ESC [ 32 m # green ESC [ 33 m # yellow ESC [ 34 m # blue ESC [ 35 m # magenta ESC [ 36 m # cyan ESC [ 37 m # white ESC [ 39 m # reset # BACKGROUND ESC [ 40 m # black ESC [ 41 m # red ESC [ 42 m # green ESC [ 43 m # yellow ESC [ 44 m # blue ESC [ 45 m # magenta ESC [ 46 m # cyan ESC [ 47 m # white ESC [ 49 m # reset # cursor positioning ESC [ y;x H # position cursor at x across, y down # clear the screen ESC [ mode J # clear the screen. Only mode 2 (clear entire screen) # is supported. It should be easy to add other modes, # let me know if that would be useful. Multiple numeric params to the 'm' command can be combined into a single sequence, eg:: ESC [ 36 ; 45 ; 1 m # bright cyan text on magenta background All other ANSI sequences of the form ``ESC [ ; ... `` are silently stripped from the output on Windows. Any other form of ANSI sequence, such as single-character codes or alternative initial characters, are not recognised nor stripped. It would be cool to add them though. Let me know if it would be useful for you, via the issues on google code. Development =========== Help and fixes welcome! Ask Jonathan for commit rights, you'll get them. Running tests requires: - Michael Foord's 'mock' module to be installed. - Tests are written using the 2010 era updates to 'unittest', and require to be run either using Python2.7 or greater, or else to have Michael Foord's 'unittest2' module installed. unittest2 test discovery doesn't work for colorama, so I use 'nose':: nosetests -s The -s is required because 'nosetests' otherwise applies a proxy of its own to stdout, which confuses the unit tests. Contact ======= Created by Jonathan Hartley, tartley@tartley.com Thanks ====== | Ben Hoyt, for a magnificent fix under 64-bit Windows. | Jesse@EmptySquare for submitting a fix for examples in the README. | User 'jamessp', an observant documentation fix for cursor positioning. | User 'vaal1239', Dave Mckee & Lackner Kristof for a tiny but much-needed Win7 fix. | Julien Stuyck, for wisely suggesting Python3 compatible updates to README. | Daniel Griffith for multiple fabulous patches. | Oscar Lesta for valuable fix to stop ANSI chars being sent to non-tty output. | Roger Binns, for many suggestions, valuable feedback, & bug reports. | Tim Golden for thought and much appreciated feedback on the initial idea. pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/util/colorama/__init__.py000066400000000000000000000000001300727121400245110ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/util/colorama/win32.py000066400000000000000000000114451300727121400237330ustar00rootroot00000000000000# Copyright Jonathan Hartley 2013. BSD 3-Clause license, see LICENSE file. # from winbase.h STDOUT = -11 STDERR = -12 try: from ctypes import windll from ctypes import wintypes except ImportError: windll = None SetConsoleTextAttribute = lambda *_: None else: from ctypes import ( byref, Structure, c_char, c_short, c_int, c_uint32, c_ushort, c_void_p, POINTER ) class CONSOLE_SCREEN_BUFFER_INFO(Structure): """struct in wincon.h.""" _fields_ = [ ("dwSize", wintypes._COORD), ("dwCursorPosition", wintypes._COORD), ("wAttributes", wintypes.WORD), ("srWindow", wintypes.SMALL_RECT), ("dwMaximumWindowSize", wintypes._COORD), ] def __str__(self): return '(%d,%d,%d,%d,%d,%d,%d,%d,%d,%d,%d)' % ( self.dwSize.Y, self.dwSize.X , self.dwCursorPosition.Y, self.dwCursorPosition.X , self.wAttributes , self.srWindow.Top, self.srWindow.Left, self.srWindow.Bottom, self.srWindow.Right , self.dwMaximumWindowSize.Y, self.dwMaximumWindowSize.X ) _GetStdHandle = windll.kernel32.GetStdHandle _GetStdHandle.argtypes = [ wintypes.DWORD, ] _GetStdHandle.restype = wintypes.HANDLE _GetConsoleScreenBufferInfo = windll.kernel32.GetConsoleScreenBufferInfo _GetConsoleScreenBufferInfo.argtypes = [ wintypes.HANDLE, c_void_p, #POINTER(CONSOLE_SCREEN_BUFFER_INFO), ] _GetConsoleScreenBufferInfo.restype = wintypes.BOOL _SetConsoleTextAttribute = windll.kernel32.SetConsoleTextAttribute _SetConsoleTextAttribute.argtypes = [ wintypes.HANDLE, wintypes.WORD, ] _SetConsoleTextAttribute.restype = wintypes.BOOL _SetConsoleCursorPosition = windll.kernel32.SetConsoleCursorPosition _SetConsoleCursorPosition.argtypes = [ wintypes.HANDLE, c_int, #wintypes._COORD, ] _SetConsoleCursorPosition.restype = wintypes.BOOL _FillConsoleOutputCharacterA = windll.kernel32.FillConsoleOutputCharacterA _FillConsoleOutputCharacterA.argtypes = [ wintypes.HANDLE, c_char, wintypes.DWORD, wintypes._COORD, POINTER(wintypes.DWORD), ] _FillConsoleOutputCharacterA.restype = wintypes.BOOL _FillConsoleOutputAttribute = windll.kernel32.FillConsoleOutputAttribute _FillConsoleOutputAttribute.argtypes = [ wintypes.HANDLE, wintypes.WORD, wintypes.DWORD, c_int, #wintypes._COORD, POINTER(wintypes.DWORD), ] _FillConsoleOutputAttribute.restype = wintypes.BOOL handles = { STDOUT: _GetStdHandle(STDOUT), STDERR: _GetStdHandle(STDERR), } def GetConsoleScreenBufferInfo(stream_id=STDOUT): handle = handles[stream_id] csbi = CONSOLE_SCREEN_BUFFER_INFO() success = _GetConsoleScreenBufferInfo( handle, byref(csbi)) return csbi def SetConsoleTextAttribute(stream_id, attrs): handle = handles[stream_id] return _SetConsoleTextAttribute(handle, attrs) def SetConsoleCursorPosition(stream_id, position): position = wintypes._COORD(*position) # If the position is out of range, do nothing. if position.Y <= 0 or position.X <= 0: return # Adjust for Windows' SetConsoleCursorPosition: # 1. being 0-based, while ANSI is 1-based. # 2. expecting (x,y), while ANSI uses (y,x). adjusted_position = wintypes._COORD(position.Y - 1, position.X - 1) # Adjust for viewport's scroll position sr = GetConsoleScreenBufferInfo(STDOUT).srWindow adjusted_position.Y += sr.Top adjusted_position.X += sr.Left # Resume normal processing handle = handles[stream_id] return _SetConsoleCursorPosition(handle, adjusted_position) def FillConsoleOutputCharacter(stream_id, char, length, start): handle = handles[stream_id] char = c_char(char) length = wintypes.DWORD(length) num_written = wintypes.DWORD(0) # Note that this is hard-coded for ANSI (vs wide) bytes. success = _FillConsoleOutputCharacterA( handle, char, length, start, byref(num_written)) return num_written.value def FillConsoleOutputAttribute(stream_id, attr, length, start): ''' FillConsoleOutputAttribute( hConsole, csbi.wAttributes, dwConSize, coordScreen, &cCharsWritten )''' handle = handles[stream_id] attribute = wintypes.WORD(attr) length = wintypes.DWORD(length) num_written = wintypes.DWORD(0) # Note that this is hard-coded for ANSI (vs wide) bytes. return _FillConsoleOutputAttribute( handle, attribute, length, start, byref(num_written)) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/util/colorama/winterm.py000066400000000000000000000101551300727121400244530ustar00rootroot00000000000000# Copyright Jonathan Hartley 2013. BSD 3-Clause license, see LICENSE file. from . import win32 # from wincon.h class WinColor(object): BLACK = 0 BLUE = 1 GREEN = 2 CYAN = 3 RED = 4 MAGENTA = 5 YELLOW = 6 GREY = 7 # from wincon.h class WinStyle(object): NORMAL = 0x00 # dim text, dim background BRIGHT = 0x08 # bright text, dim background class WinTerm(object): def __init__(self): self._default = win32.GetConsoleScreenBufferInfo(win32.STDOUT).wAttributes self.set_attrs(self._default) self._default_fore = self._fore self._default_back = self._back self._default_style = self._style def get_attrs(self): return self._fore + self._back * 16 + self._style def set_attrs(self, value): self._fore = value & 7 self._back = (value >> 4) & 7 self._style = value & WinStyle.BRIGHT def reset_all(self, on_stderr=None): self.set_attrs(self._default) self.set_console(attrs=self._default) def fore(self, fore=None, on_stderr=False): if fore is None: fore = self._default_fore self._fore = fore self.set_console(on_stderr=on_stderr) def back(self, back=None, on_stderr=False): if back is None: back = self._default_back self._back = back self.set_console(on_stderr=on_stderr) def style(self, style=None, on_stderr=False): if style is None: style = self._default_style self._style = style self.set_console(on_stderr=on_stderr) def set_console(self, attrs=None, on_stderr=False): if attrs is None: attrs = self.get_attrs() handle = win32.STDOUT if on_stderr: handle = win32.STDERR win32.SetConsoleTextAttribute(handle, attrs) def get_position(self, handle): position = win32.GetConsoleScreenBufferInfo(handle).dwCursorPosition # Because Windows coordinates are 0-based, # and win32.SetConsoleCursorPosition expects 1-based. position.X += 1 position.Y += 1 return position def set_cursor_position(self, position=None, on_stderr=False): if position is None: #I'm not currently tracking the position, so there is no default. #position = self.get_position() return handle = win32.STDOUT if on_stderr: handle = win32.STDERR win32.SetConsoleCursorPosition(handle, position) def cursor_up(self, num_rows=0, on_stderr=False): if num_rows == 0: return handle = win32.STDOUT if on_stderr: handle = win32.STDERR position = self.get_position(handle) adjusted_position = (position.Y - num_rows, position.X) self.set_cursor_position(adjusted_position, on_stderr) def erase_data(self, mode=0, on_stderr=False): # 0 (or None) should clear from the cursor to the end of the screen. # 1 should clear from the cursor to the beginning of the screen. # 2 should clear the entire screen. (And maybe move cursor to (1,1)?) # # At the moment, I only support mode 2. From looking at the API, it # should be possible to calculate a different number of bytes to clear, # and to do so relative to the cursor position. if mode[0] not in (2,): return handle = win32.STDOUT if on_stderr: handle = win32.STDERR # here's where we'll home the cursor coord_screen = win32.COORD(0,0) csbi = win32.GetConsoleScreenBufferInfo(handle) # get the number of character cells in the current buffer dw_con_size = csbi.dwSize.X * csbi.dwSize.Y # fill the entire screen with blanks win32.FillConsoleOutputCharacter(handle, ' ', dw_con_size, coord_screen) # now set the buffer's attributes accordingly win32.FillConsoleOutputAttribute(handle, self.get_attrs(), dw_con_size, coord_screen ) # put the cursor at (0, 0) win32.SetConsoleCursorPosition(handle, (coord_screen.X, coord_screen.Y)) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/util/cprint.py000066400000000000000000000057241300727121400224760ustar00rootroot00000000000000""" Cross-platform color text printing Based on colorama (see pyqtgraph/util/colorama/README.txt) """ import sys, re from .colorama.winterm import WinTerm, WinColor, WinStyle from .colorama.win32 import windll from ..python2_3 import basestring _WIN = sys.platform.startswith('win') if windll is not None: winterm = WinTerm() else: _WIN = False def winset(reset=False, fore=None, back=None, style=None, stderr=False): if reset: winterm.reset_all() if fore is not None: winterm.fore(fore, stderr) if back is not None: winterm.back(back, stderr) if style is not None: winterm.style(style, stderr) ANSI = {} WIN = {} for i,color in enumerate(['BLACK', 'RED', 'GREEN', 'YELLOW', 'BLUE', 'MAGENTA', 'CYAN', 'WHITE']): globals()[color] = i globals()['BR_' + color] = i + 8 globals()['BACK_' + color] = i + 40 ANSI[i] = "\033[%dm" % (30+i) ANSI[i+8] = "\033[2;%dm" % (30+i) ANSI[i+40] = "\033[%dm" % (40+i) color = 'GREY' if color == 'WHITE' else color WIN[i] = {'fore': getattr(WinColor, color), 'style': WinStyle.NORMAL} WIN[i+8] = {'fore': getattr(WinColor, color), 'style': WinStyle.BRIGHT} WIN[i+40] = {'back': getattr(WinColor, color)} RESET = -1 ANSI[RESET] = "\033[0m" WIN[RESET] = {'reset': True} def cprint(stream, *args, **kwds): """ Print with color. Examples:: # colors are BLACK, RED, GREEN, YELLOW, BLUE, MAGENTA, CYAN, WHITE cprint('stdout', RED, 'This is in red. ', RESET, 'and this is normal\n') # Adding BR_ before the color manes it bright cprint('stdout', BR_GREEN, 'This is bright green.\n', RESET) # Adding BACK_ changes background color cprint('stderr', BACK_BLUE, WHITE, 'This is white-on-blue.', -1) # Integers 0-7 for normal, 8-15 for bright, and 40-47 for background. # -1 to reset. cprint('stderr', 1, 'This is in red.', -1) """ if isinstance(stream, basestring): stream = kwds.get('stream', 'stdout') err = stream == 'stderr' stream = getattr(sys, stream) else: err = kwds.get('stderr', False) if hasattr(stream, 'isatty') and stream.isatty(): if _WIN: # convert to win32 calls for arg in args: if isinstance(arg, basestring): stream.write(arg) else: kwds = WIN[arg] winset(stderr=err, **kwds) else: # convert to ANSI for arg in args: if isinstance(arg, basestring): stream.write(arg) else: stream.write(ANSI[arg]) else: # ignore colors for arg in args: if isinstance(arg, basestring): stream.write(arg) def cout(*args): """Shorthand for cprint('stdout', ...)""" cprint('stdout', *args) def cerr(*args): """Shorthand for cprint('stderr', ...)""" cprint('stderr', *args) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/util/garbage_collector.py000066400000000000000000000030771300727121400246340ustar00rootroot00000000000000import gc from ..Qt import QtCore class GarbageCollector(object): ''' Disable automatic garbage collection and instead collect manually on a timer. This is done to ensure that garbage collection only happens in the GUI thread, as otherwise Qt can crash. Credit: Erik Janssens Source: http://pydev.blogspot.com/2014/03/should-python-garbage-collector-be.html ''' def __init__(self, interval=1.0, debug=False): self.debug = debug if debug: gc.set_debug(gc.DEBUG_LEAK) self.timer = QtCore.QTimer() self.timer.timeout.connect(self.check) self.threshold = gc.get_threshold() gc.disable() self.timer.start(interval * 1000) def check(self): #return self.debug_cycles() # uncomment to just debug cycles l0, l1, l2 = gc.get_count() if self.debug: print('gc_check called:', l0, l1, l2) if l0 > self.threshold[0]: num = gc.collect(0) if self.debug: print('collecting gen 0, found: %d unreachable' % num) if l1 > self.threshold[1]: num = gc.collect(1) if self.debug: print('collecting gen 1, found: %d unreachable' % num) if l2 > self.threshold[2]: num = gc.collect(2) if self.debug: print('collecting gen 2, found: %d unreachable' % num) def debug_cycles(self): gc.collect() for obj in gc.garbage: print(obj, repr(obj), type(obj)) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/util/lru_cache.py000066400000000000000000000102501300727121400231120ustar00rootroot00000000000000import operator import sys import itertools _IS_PY3 = sys.version_info[0] == 3 class LRUCache(object): ''' This LRU cache should be reasonable for short collections (until around 100 items), as it does a sort on the items if the collection would become too big (so, it is very fast for getting and setting but when its size would become higher than the max size it does one sort based on the internal time to decide which items should be removed -- which should be Ok if the resizeTo isn't too close to the maxSize so that it becomes an operation that doesn't happen all the time). ''' def __init__(self, maxSize=100, resizeTo=70): ''' ============== ========================================================= **Arguments:** maxSize (int) This is the maximum size of the cache. When some item is added and the cache would become bigger than this, it's resized to the value passed on resizeTo. resizeTo (int) When a resize operation happens, this is the size of the final cache. ============== ========================================================= ''' assert resizeTo < maxSize self.maxSize = maxSize self.resizeTo = resizeTo self._counter = 0 self._dict = {} if _IS_PY3: self._nextTime = itertools.count(0).__next__ else: self._nextTime = itertools.count(0).next def __getitem__(self, key): item = self._dict[key] item[2] = self._nextTime() return item[1] def __len__(self): return len(self._dict) def __setitem__(self, key, value): item = self._dict.get(key) if item is None: if len(self._dict) + 1 > self.maxSize: self._resizeTo() item = [key, value, self._nextTime()] self._dict[key] = item else: item[1] = value item[2] = self._nextTime() def __delitem__(self, key): del self._dict[key] def get(self, key, default=None): try: return self[key] except KeyError: return default def clear(self): self._dict.clear() if _IS_PY3: def values(self): return [i[1] for i in self._dict.values()] def keys(self): return [x[0] for x in self._dict.values()] def _resizeTo(self): ordered = sorted(self._dict.values(), key=operator.itemgetter(2))[:self.resizeTo] for i in ordered: del self._dict[i[0]] def iteritems(self, accessTime=False): ''' :param bool accessTime: If True sorts the returned items by the internal access time. ''' if accessTime: for x in sorted(self._dict.values(), key=operator.itemgetter(2)): yield x[0], x[1] else: for x in self._dict.items(): yield x[0], x[1] else: def values(self): return [i[1] for i in self._dict.itervalues()] def keys(self): return [x[0] for x in self._dict.itervalues()] def _resizeTo(self): ordered = sorted(self._dict.itervalues(), key=operator.itemgetter(2))[:self.resizeTo] for i in ordered: del self._dict[i[0]] def iteritems(self, accessTime=False): ''' ============= ====================================================== **Arguments** accessTime (bool) If True sorts the returned items by the internal access time. ============= ====================================================== ''' if accessTime: for x in sorted(self._dict.itervalues(), key=operator.itemgetter(2)): yield x[0], x[1] else: for x in self._dict.iteritems(): yield x[0], x[1] pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/util/mutex.py000066400000000000000000000055721300727121400223420ustar00rootroot00000000000000# -*- coding: utf-8 -*- from ..Qt import QtCore import traceback class Mutex(QtCore.QMutex): """ Subclass of QMutex that provides useful debugging information during deadlocks--tracebacks are printed for both the code location that is attempting to lock the mutex as well as the location that has already acquired the lock. Also provides __enter__ and __exit__ methods for use in "with" statements. """ def __init__(self, *args, **kargs): if kargs.get('recursive', False): args = (QtCore.QMutex.Recursive,) QtCore.QMutex.__init__(self, *args) self.l = QtCore.QMutex() ## for serializing access to self.tb self.tb = [] self.debug = True ## True to enable debugging functions def tryLock(self, timeout=None, id=None): if timeout is None: locked = QtCore.QMutex.tryLock(self) else: locked = QtCore.QMutex.tryLock(self, timeout) if self.debug and locked: self.l.lock() try: if id is None: self.tb.append(''.join(traceback.format_stack()[:-1])) else: self.tb.append(" " + str(id)) #print 'trylock', self, len(self.tb) finally: self.l.unlock() return locked def lock(self, id=None): c = 0 waitTime = 5000 # in ms while True: if self.tryLock(waitTime, id): break c += 1 if self.debug: self.l.lock() try: print("Waiting for mutex lock (%0.1f sec). Traceback follows:" % (c*waitTime/1000.)) traceback.print_stack() if len(self.tb) > 0: print("Mutex is currently locked from:\n") print(self.tb[-1]) else: print("Mutex is currently locked from [???]") finally: self.l.unlock() #print 'lock', self, len(self.tb) def unlock(self): QtCore.QMutex.unlock(self) if self.debug: self.l.lock() try: #print 'unlock', self, len(self.tb) if len(self.tb) > 0: self.tb.pop() else: raise Exception("Attempt to unlock mutex before it has been locked") finally: self.l.unlock() def depth(self): self.l.lock() n = len(self.tb) self.l.unlock() return n def traceback(self): self.l.lock() try: ret = self.tb[:] finally: self.l.unlock() return ret def __exit__(self, *args): self.unlock() def __enter__(self): self.lock() return selfpyqtgraph-pyqtgraph-0.10.0/pyqtgraph/util/pil_fix.py000066400000000000000000000040051300727121400226200ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ Importing this module installs support for 16-bit images in PIL. This works by patching objects in the PIL namespace; no files are modified. """ from PIL import Image if Image.VERSION == '1.1.7': Image._MODE_CONV["I;16"] = ('%su2' % Image._ENDIAN, None) Image._fromarray_typemap[((1, 1), " ndmax: raise ValueError("Too many dimensions.") size = shape[:2][::-1] if strides is not None: obj = obj.tostring() return frombuffer(mode, size, obj, "raw", mode, 0, 1) Image.fromarray=fromarraypyqtgraph-pyqtgraph-0.10.0/pyqtgraph/util/tests/000077500000000000000000000000001300727121400217575ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/util/tests/test_lru_cache.py000066400000000000000000000023071300727121400253170ustar00rootroot00000000000000from pyqtgraph.util.lru_cache import LRUCache def testLRU(): lru = LRUCache(2, 1) # check twice checkLru(lru) checkLru(lru) def checkLru(lru): lru[1] = 1 lru[2] = 2 lru[3] = 3 assert len(lru) == 2 assert set([2, 3]) == set(lru.keys()) assert set([2, 3]) == set(lru.values()) lru[2] = 2 assert set([2, 3]) == set(lru.values()) lru[1] = 1 set([2, 1]) == set(lru.values()) #Iterates from the used in the last access to others based on access time. assert [(2, 2), (1, 1)] == list(lru.iteritems(accessTime=True)) lru[2] = 2 assert [(1, 1), (2, 2)] == list(lru.iteritems(accessTime=True)) del lru[2] assert [(1, 1), ] == list(lru.iteritems(accessTime=True)) lru[2] = 2 assert [(1, 1), (2, 2)] == list(lru.iteritems(accessTime=True)) _a = lru[1] assert [(2, 2), (1, 1)] == list(lru.iteritems(accessTime=True)) _a = lru[2] assert [(1, 1), (2, 2)] == list(lru.iteritems(accessTime=True)) assert lru.get(2) == 2 assert lru.get(3) == None assert [(1, 1), (2, 2)] == list(lru.iteritems(accessTime=True)) lru.clear() assert [] == list(lru.iteritems()) if __name__ == '__main__': testLRU() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/000077500000000000000000000000001300727121400213065ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/BusyCursor.py000066400000000000000000000011241300727121400237760ustar00rootroot00000000000000from ..Qt import QtGui, QtCore __all__ = ['BusyCursor'] class BusyCursor(object): """Class for displaying a busy mouse cursor during long operations. Usage:: with pyqtgraph.BusyCursor(): doLongOperation() May be nested. """ active = [] def __enter__(self): QtGui.QApplication.setOverrideCursor(QtGui.QCursor(QtCore.Qt.WaitCursor)) BusyCursor.active.append(self) def __exit__(self, *args): BusyCursor.active.pop(-1) if len(BusyCursor.active) == 0: QtGui.QApplication.restoreOverrideCursor() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/CheckTable.py000066400000000000000000000064411300727121400236520ustar00rootroot00000000000000# -*- coding: utf-8 -*- from ..Qt import QtGui, QtCore from . import VerticalLabel __all__ = ['CheckTable'] class CheckTable(QtGui.QWidget): sigStateChanged = QtCore.Signal(object, object, object) # (row, col, state) def __init__(self, columns): QtGui.QWidget.__init__(self) self.layout = QtGui.QGridLayout() self.layout.setSpacing(0) self.setLayout(self.layout) self.headers = [] self.columns = columns col = 1 for c in columns: label = VerticalLabel.VerticalLabel(c, orientation='vertical') self.headers.append(label) self.layout.addWidget(label, 0, col) col += 1 self.rowNames = [] self.rowWidgets = [] self.oldRows = {} ## remember settings from removed rows; reapply if they reappear. def updateRows(self, rows): for r in self.rowNames[:]: if r not in rows: self.removeRow(r) for r in rows: if r not in self.rowNames: self.addRow(r) def addRow(self, name): label = QtGui.QLabel(name) row = len(self.rowNames)+1 self.layout.addWidget(label, row, 0) checks = [] col = 1 for c in self.columns: check = QtGui.QCheckBox('') check.col = c check.row = name self.layout.addWidget(check, row, col) checks.append(check) if name in self.oldRows: check.setChecked(self.oldRows[name][col]) col += 1 #QtCore.QObject.connect(check, QtCore.SIGNAL('stateChanged(int)'), self.checkChanged) check.stateChanged.connect(self.checkChanged) self.rowNames.append(name) self.rowWidgets.append([label] + checks) def removeRow(self, name): row = self.rowNames.index(name) self.oldRows[name] = self.saveState()['rows'][row] ## save for later self.rowNames.pop(row) for w in self.rowWidgets[row]: w.setParent(None) #QtCore.QObject.disconnect(w, QtCore.SIGNAL('stateChanged(int)'), self.checkChanged) if isinstance(w, QtGui.QCheckBox): w.stateChanged.disconnect(self.checkChanged) self.rowWidgets.pop(row) for i in range(row, len(self.rowNames)): widgets = self.rowWidgets[i] for j in range(len(widgets)): widgets[j].setParent(None) self.layout.addWidget(widgets[j], i+1, j) def checkChanged(self, state): check = QtCore.QObject.sender(self) #self.emit(QtCore.SIGNAL('stateChanged'), check.row, check.col, state) self.sigStateChanged.emit(check.row, check.col, state) def saveState(self): rows = [] for i in range(len(self.rowNames)): row = [self.rowNames[i]] + [c.isChecked() for c in self.rowWidgets[i][1:]] rows.append(row) return {'cols': self.columns, 'rows': rows} def restoreState(self, state): rows = [r[0] for r in state['rows']] self.updateRows(rows) for r in state['rows']: rowNum = self.rowNames.index(r[0]) for i in range(1, len(r)): self.rowWidgets[rowNum][i].setChecked(r[i]) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/ColorButton.py000066400000000000000000000072531300727121400241410ustar00rootroot00000000000000# -*- coding: utf-8 -*- from ..Qt import QtGui, QtCore from .. import functions as functions __all__ = ['ColorButton'] class ColorButton(QtGui.QPushButton): """ **Bases:** QtGui.QPushButton Button displaying a color and allowing the user to select a new color. ====================== ============================================================ **Signals:** sigColorChanging(self) emitted whenever a new color is picked in the color dialog sigColorChanged(self) emitted when the selected color is accepted (user clicks OK) ====================== ============================================================ """ sigColorChanging = QtCore.Signal(object) ## emitted whenever a new color is picked in the color dialog sigColorChanged = QtCore.Signal(object) ## emitted when the selected color is accepted (user clicks OK) def __init__(self, parent=None, color=(128,128,128)): QtGui.QPushButton.__init__(self, parent) self.setColor(color) self.colorDialog = QtGui.QColorDialog() self.colorDialog.setOption(QtGui.QColorDialog.ShowAlphaChannel, True) self.colorDialog.setOption(QtGui.QColorDialog.DontUseNativeDialog, True) self.colorDialog.currentColorChanged.connect(self.dialogColorChanged) self.colorDialog.rejected.connect(self.colorRejected) self.colorDialog.colorSelected.connect(self.colorSelected) #QtCore.QObject.connect(self.colorDialog, QtCore.SIGNAL('currentColorChanged(const QColor&)'), self.currentColorChanged) #QtCore.QObject.connect(self.colorDialog, QtCore.SIGNAL('rejected()'), self.currentColorRejected) self.clicked.connect(self.selectColor) self.setMinimumHeight(15) self.setMinimumWidth(15) def paintEvent(self, ev): QtGui.QPushButton.paintEvent(self, ev) p = QtGui.QPainter(self) rect = self.rect().adjusted(6, 6, -6, -6) ## draw white base, then texture for indicating transparency, then actual color p.setBrush(functions.mkBrush('w')) p.drawRect(rect) p.setBrush(QtGui.QBrush(QtCore.Qt.DiagCrossPattern)) p.drawRect(rect) p.setBrush(functions.mkBrush(self._color)) p.drawRect(rect) p.end() def setColor(self, color, finished=True): """Sets the button's color and emits both sigColorChanged and sigColorChanging.""" self._color = functions.mkColor(color) if finished: self.sigColorChanged.emit(self) else: self.sigColorChanging.emit(self) self.update() def selectColor(self): self.origColor = self.color() self.colorDialog.setCurrentColor(self.color()) self.colorDialog.open() def dialogColorChanged(self, color): if color.isValid(): self.setColor(color, finished=False) def colorRejected(self): self.setColor(self.origColor, finished=False) def colorSelected(self, color): self.setColor(self._color, finished=True) def saveState(self): return functions.colorTuple(self._color) def restoreState(self, state): self.setColor(state) def color(self, mode='qcolor'): color = functions.mkColor(self._color) if mode == 'qcolor': return color elif mode == 'byte': return (color.red(), color.green(), color.blue(), color.alpha()) elif mode == 'float': return (color.red()/255., color.green()/255., color.blue()/255., color.alpha()/255.) def widgetGroupInterface(self): return (self.sigColorChanged, ColorButton.saveState, ColorButton.restoreState) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/ColorMapWidget.py000066400000000000000000000233151300727121400245440ustar00rootroot00000000000000from ..Qt import QtGui, QtCore from .. import parametertree as ptree import numpy as np from ..pgcollections import OrderedDict from .. import functions as fn __all__ = ['ColorMapWidget'] class ColorMapWidget(ptree.ParameterTree): """ This class provides a widget allowing the user to customize color mapping for multi-column data. Given a list of field names, the user may specify multiple criteria for assigning colors to each record in a numpy record array. Multiple criteria are evaluated and combined into a single color for each record by user-defined compositing methods. For simpler color mapping using a single gradient editor, see :class:`GradientWidget ` """ sigColorMapChanged = QtCore.Signal(object) def __init__(self, parent=None): ptree.ParameterTree.__init__(self, parent=parent, showHeader=False) self.params = ColorMapParameter() self.setParameters(self.params) self.params.sigTreeStateChanged.connect(self.mapChanged) ## wrap a couple methods self.setFields = self.params.setFields self.map = self.params.map def mapChanged(self): self.sigColorMapChanged.emit(self) def widgetGroupInterface(self): return (self.sigColorMapChanged, self.saveState, self.restoreState) def saveState(self): return self.params.saveState() def restoreState(self, state): self.params.restoreState(state) class ColorMapParameter(ptree.types.GroupParameter): sigColorMapChanged = QtCore.Signal(object) def __init__(self): self.fields = {} ptree.types.GroupParameter.__init__(self, name='Color Map', addText='Add Mapping..', addList=[]) self.sigTreeStateChanged.connect(self.mapChanged) def mapChanged(self): self.sigColorMapChanged.emit(self) def addNew(self, name): mode = self.fields[name].get('mode', 'range') if mode == 'range': item = RangeColorMapItem(name, self.fields[name]) elif mode == 'enum': item = EnumColorMapItem(name, self.fields[name]) self.addChild(item) return item def fieldNames(self): return self.fields.keys() def setFields(self, fields): """ Set the list of fields to be used by the mapper. The format of *fields* is:: [ (fieldName, {options}), ... ] ============== ============================================================ Field Options: mode Either 'range' or 'enum' (default is range). For 'range', The user may specify a gradient of colors to be applied linearly across a specific range of values. For 'enum', the user specifies a single color for each unique value (see *values* option). units String indicating the units of the data for this field. values List of unique values for which the user may assign a color when mode=='enum'. Optionally may specify a dict instead {value: name}. ============== ============================================================ """ self.fields = OrderedDict(fields) #self.fields = fields #self.fields.sort() names = self.fieldNames() self.setAddList(names) def map(self, data, mode='byte'): """ Return an array of colors corresponding to *data*. ============== ================================================================= **Arguments:** data A numpy record array where the fields in data.dtype match those defined by a prior call to setFields(). mode Either 'byte' or 'float'. For 'byte', the method returns an array of dtype ubyte with values scaled 0-255. For 'float', colors are returned as 0.0-1.0 float values. ============== ================================================================= """ if isinstance(data, dict): data = np.array([tuple(data.values())], dtype=[(k, float) for k in data.keys()]) colors = np.zeros((len(data),4)) for item in self.children(): if not item['Enabled']: continue chans = item.param('Channels..') mask = np.empty((len(data), 4), dtype=bool) for i,f in enumerate(['Red', 'Green', 'Blue', 'Alpha']): mask[:,i] = chans[f] colors2 = item.map(data) op = item['Operation'] if op == 'Add': colors[mask] = colors[mask] + colors2[mask] elif op == 'Multiply': colors[mask] *= colors2[mask] elif op == 'Overlay': a = colors2[:,3:4] c3 = colors * (1-a) + colors2 * a c3[:,3:4] = colors[:,3:4] + (1-colors[:,3:4]) * a colors = c3 elif op == 'Set': colors[mask] = colors2[mask] colors = np.clip(colors, 0, 1) if mode == 'byte': colors = (colors * 255).astype(np.ubyte) return colors def saveState(self): items = OrderedDict() for item in self: itemState = item.saveState(filter='user') itemState['field'] = item.fieldName items[item.name()] = itemState state = {'fields': self.fields, 'items': items} return state def restoreState(self, state): if 'fields' in state: self.setFields(state['fields']) for itemState in state['items']: item = self.addNew(itemState['field']) item.restoreState(itemState) class RangeColorMapItem(ptree.types.SimpleParameter): mapType = 'range' def __init__(self, name, opts): self.fieldName = name units = opts.get('units', '') ptree.types.SimpleParameter.__init__(self, name=name, autoIncrementName=True, type='colormap', removable=True, renamable=True, children=[ #dict(name="Field", type='list', value=name, values=fields), dict(name='Min', type='float', value=0.0, suffix=units, siPrefix=True), dict(name='Max', type='float', value=1.0, suffix=units, siPrefix=True), dict(name='Operation', type='list', value='Overlay', values=['Overlay', 'Add', 'Multiply', 'Set']), dict(name='Channels..', type='group', expanded=False, children=[ dict(name='Red', type='bool', value=True), dict(name='Green', type='bool', value=True), dict(name='Blue', type='bool', value=True), dict(name='Alpha', type='bool', value=True), ]), dict(name='Enabled', type='bool', value=True), dict(name='NaN', type='color'), ]) def map(self, data): data = data[self.fieldName] scaled = np.clip((data-self['Min']) / (self['Max']-self['Min']), 0, 1) cmap = self.value() colors = cmap.map(scaled, mode='float') mask = np.isnan(data) | np.isinf(data) nanColor = self['NaN'] nanColor = (nanColor.red()/255., nanColor.green()/255., nanColor.blue()/255., nanColor.alpha()/255.) colors[mask] = nanColor return colors class EnumColorMapItem(ptree.types.GroupParameter): mapType = 'enum' def __init__(self, name, opts): self.fieldName = name vals = opts.get('values', []) if isinstance(vals, list): vals = OrderedDict([(v,str(v)) for v in vals]) childs = [{'name': v, 'type': 'color'} for v in vals] childs = [] for val,vname in vals.items(): ch = ptree.Parameter.create(name=vname, type='color') ch.maskValue = val childs.append(ch) ptree.types.GroupParameter.__init__(self, name=name, autoIncrementName=True, removable=True, renamable=True, children=[ dict(name='Values', type='group', children=childs), dict(name='Operation', type='list', value='Overlay', values=['Overlay', 'Add', 'Multiply', 'Set']), dict(name='Channels..', type='group', expanded=False, children=[ dict(name='Red', type='bool', value=True), dict(name='Green', type='bool', value=True), dict(name='Blue', type='bool', value=True), dict(name='Alpha', type='bool', value=True), ]), dict(name='Enabled', type='bool', value=True), dict(name='Default', type='color'), ]) def map(self, data): data = data[self.fieldName] colors = np.empty((len(data), 4)) default = np.array(fn.colorTuple(self['Default'])) / 255. colors[:] = default for v in self.param('Values'): mask = data == v.maskValue c = np.array(fn.colorTuple(v.value())) / 255. colors[mask] = c #scaled = np.clip((data-self['Min']) / (self['Max']-self['Min']), 0, 1) #cmap = self.value() #colors = cmap.map(scaled, mode='float') #mask = np.isnan(data) | np.isinf(data) #nanColor = self['NaN'] #nanColor = (nanColor.red()/255., nanColor.green()/255., nanColor.blue()/255., nanColor.alpha()/255.) #colors[mask] = nanColor return colors pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/ComboBox.py000066400000000000000000000161261300727121400233760ustar00rootroot00000000000000import sys from ..Qt import QtGui, QtCore from ..SignalProxy import SignalProxy from ..pgcollections import OrderedDict from ..python2_3 import asUnicode, basestring class ComboBox(QtGui.QComboBox): """Extends QComboBox to add extra functionality. * Handles dict mappings -- user selects a text key, and the ComboBox indicates the selected value. * Requires item strings to be unique * Remembers selected value if list is cleared and subsequently repopulated * setItems() replaces the items in the ComboBox and blocks signals if the value ultimately does not change. """ def __init__(self, parent=None, items=None, default=None): QtGui.QComboBox.__init__(self, parent) self.currentIndexChanged.connect(self.indexChanged) self._ignoreIndexChange = False #self.value = default if 'darwin' in sys.platform: ## because MacOSX can show names that are wider than the comboBox self.setSizeAdjustPolicy(QtGui.QComboBox.AdjustToMinimumContentsLength) #self.setMinimumContentsLength(10) self._chosenText = None self._items = OrderedDict() if items is not None: self.setItems(items) if default is not None: self.setValue(default) def setValue(self, value): """Set the selected item to the first one having the given value.""" text = None for k,v in self._items.items(): if v == value: text = k break if text is None: raise ValueError(value) self.setText(text) def setText(self, text): """Set the selected item to the first one having the given text.""" ind = self.findText(text) if ind == -1: raise ValueError(text) #self.value = value self.setCurrentIndex(ind) def value(self): """ If items were given as a list of strings, then return the currently selected text. If items were given as a dict, then return the value corresponding to the currently selected key. If the combo list is empty, return None. """ if self.count() == 0: return None text = asUnicode(self.currentText()) return self._items[text] def ignoreIndexChange(func): # Decorator that prevents updates to self._chosenText def fn(self, *args, **kwds): prev = self._ignoreIndexChange self._ignoreIndexChange = True try: ret = func(self, *args, **kwds) finally: self._ignoreIndexChange = prev return ret return fn def blockIfUnchanged(func): # decorator that blocks signal emission during complex operations # and emits currentIndexChanged only if the value has actually # changed at the end. def fn(self, *args, **kwds): prevVal = self.value() blocked = self.signalsBlocked() self.blockSignals(True) try: ret = func(self, *args, **kwds) finally: self.blockSignals(blocked) # only emit if the value has changed if self.value() != prevVal: self.currentIndexChanged.emit(self.currentIndex()) return ret return fn @ignoreIndexChange @blockIfUnchanged def setItems(self, items): """ *items* may be a list or a dict. If a dict is given, then the keys are used to populate the combo box and the values will be used for both value() and setValue(). """ prevVal = self.value() self.blockSignals(True) try: self.clear() self.addItems(items) finally: self.blockSignals(False) # only emit if we were not able to re-set the original value if self.value() != prevVal: self.currentIndexChanged.emit(self.currentIndex()) def items(self): return self.items.copy() def updateList(self, items): # for backward compatibility return self.setItems(items) def indexChanged(self, index): # current index has changed; need to remember new 'chosen text' if self._ignoreIndexChange: return self._chosenText = asUnicode(self.currentText()) def setCurrentIndex(self, index): QtGui.QComboBox.setCurrentIndex(self, index) def itemsChanged(self): # try to set the value to the last one selected, if it is available. if self._chosenText is not None: try: self.setText(self._chosenText) except ValueError: pass @ignoreIndexChange def insertItem(self, *args): raise NotImplementedError() #QtGui.QComboBox.insertItem(self, *args) #self.itemsChanged() @ignoreIndexChange def insertItems(self, *args): raise NotImplementedError() #QtGui.QComboBox.insertItems(self, *args) #self.itemsChanged() @ignoreIndexChange def addItem(self, *args, **kwds): # Need to handle two different function signatures for QComboBox.addItem try: if isinstance(args[0], basestring): text = args[0] if len(args) == 2: value = args[1] else: value = kwds.get('value', text) else: text = args[1] if len(args) == 3: value = args[2] else: value = kwds.get('value', text) except IndexError: raise TypeError("First or second argument of addItem must be a string.") if text in self._items: raise Exception('ComboBox already has item named "%s".' % text) self._items[text] = value QtGui.QComboBox.addItem(self, *args) self.itemsChanged() def setItemValue(self, name, value): if name not in self._items: self.addItem(name, value) else: self._items[name] = value @ignoreIndexChange @blockIfUnchanged def addItems(self, items): if isinstance(items, list): texts = items items = dict([(x, x) for x in items]) elif isinstance(items, dict): texts = list(items.keys()) else: raise TypeError("items argument must be list or dict (got %s)." % type(items)) for t in texts: if t in self._items: raise Exception('ComboBox already has item named "%s".' % t) for k,v in items.items(): self._items[k] = v QtGui.QComboBox.addItems(self, list(texts)) self.itemsChanged() @ignoreIndexChange def clear(self): self._items = OrderedDict() QtGui.QComboBox.clear(self) self.itemsChanged() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/DataFilterWidget.py000066400000000000000000000124361300727121400250510ustar00rootroot00000000000000from ..Qt import QtGui, QtCore from .. import parametertree as ptree import numpy as np from ..pgcollections import OrderedDict from .. import functions as fn __all__ = ['DataFilterWidget'] class DataFilterWidget(ptree.ParameterTree): """ This class allows the user to filter multi-column data sets by specifying multiple criteria """ sigFilterChanged = QtCore.Signal(object) def __init__(self): ptree.ParameterTree.__init__(self, showHeader=False) self.params = DataFilterParameter() self.setParameters(self.params) self.params.sigTreeStateChanged.connect(self.filterChanged) self.setFields = self.params.setFields self.filterData = self.params.filterData self.describe = self.params.describe def filterChanged(self): self.sigFilterChanged.emit(self) def parameters(self): return self.params class DataFilterParameter(ptree.types.GroupParameter): sigFilterChanged = QtCore.Signal(object) def __init__(self): self.fields = {} ptree.types.GroupParameter.__init__(self, name='Data Filter', addText='Add filter..', addList=[]) self.sigTreeStateChanged.connect(self.filterChanged) def filterChanged(self): self.sigFilterChanged.emit(self) def addNew(self, name): mode = self.fields[name].get('mode', 'range') if mode == 'range': self.addChild(RangeFilterItem(name, self.fields[name])) elif mode == 'enum': self.addChild(EnumFilterItem(name, self.fields[name])) def fieldNames(self): return self.fields.keys() def setFields(self, fields): self.fields = OrderedDict(fields) names = self.fieldNames() self.setAddList(names) def filterData(self, data): if len(data) == 0: return data return data[self.generateMask(data)] def generateMask(self, data): mask = np.ones(len(data), dtype=bool) if len(data) == 0: return mask for fp in self: if fp.value() is False: continue mask &= fp.generateMask(data, mask.copy()) #key, mn, mx = fp.fieldName, fp['Min'], fp['Max'] #vals = data[key] #mask &= (vals >= mn) #mask &= (vals < mx) ## Use inclusive minimum and non-inclusive maximum. This makes it easier to create non-overlapping selections return mask def describe(self): """Return a list of strings describing the currently enabled filters.""" desc = [] for fp in self: if fp.value() is False: continue desc.append(fp.describe()) return desc class RangeFilterItem(ptree.types.SimpleParameter): def __init__(self, name, opts): self.fieldName = name units = opts.get('units', '') self.units = units ptree.types.SimpleParameter.__init__(self, name=name, autoIncrementName=True, type='bool', value=True, removable=True, renamable=True, children=[ #dict(name="Field", type='list', value=name, values=fields), dict(name='Min', type='float', value=0.0, suffix=units, siPrefix=True), dict(name='Max', type='float', value=1.0, suffix=units, siPrefix=True), ]) def generateMask(self, data, mask): vals = data[self.fieldName][mask] mask[mask] = (vals >= self['Min']) & (vals < self['Max']) ## Use inclusive minimum and non-inclusive maximum. This makes it easier to create non-overlapping selections return mask def describe(self): return "%s < %s < %s" % (fn.siFormat(self['Min'], suffix=self.units), self.fieldName, fn.siFormat(self['Max'], suffix=self.units)) class EnumFilterItem(ptree.types.SimpleParameter): def __init__(self, name, opts): self.fieldName = name vals = opts.get('values', []) childs = [] if isinstance(vals, list): vals = OrderedDict([(v,str(v)) for v in vals]) for val,vname in vals.items(): ch = ptree.Parameter.create(name=vname, type='bool', value=True) ch.maskValue = val childs.append(ch) ch = ptree.Parameter.create(name='(other)', type='bool', value=True) ch.maskValue = '__other__' childs.append(ch) ptree.types.SimpleParameter.__init__(self, name=name, autoIncrementName=True, type='bool', value=True, removable=True, renamable=True, children=childs) def generateMask(self, data, startMask): vals = data[self.fieldName][startMask] mask = np.ones(len(vals), dtype=bool) otherMask = np.ones(len(vals), dtype=bool) for c in self: key = c.maskValue if key == '__other__': m = ~otherMask else: m = vals != key otherMask &= m if c.value() is False: mask &= m startMask[startMask] = mask return startMask def describe(self): vals = [ch.name() for ch in self if ch.value() is True] return "%s: %s" % (self.fieldName, ', '.join(vals))pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/DataTreeWidget.py000066400000000000000000000055061300727121400245230ustar00rootroot00000000000000# -*- coding: utf-8 -*- from ..Qt import QtGui, QtCore from ..pgcollections import OrderedDict import types, traceback import numpy as np try: import metaarray HAVE_METAARRAY = True except: HAVE_METAARRAY = False __all__ = ['DataTreeWidget'] class DataTreeWidget(QtGui.QTreeWidget): """ Widget for displaying hierarchical python data structures (eg, nested dicts, lists, and arrays) """ def __init__(self, parent=None, data=None): QtGui.QTreeWidget.__init__(self, parent) self.setVerticalScrollMode(self.ScrollPerPixel) self.setData(data) self.setColumnCount(3) self.setHeaderLabels(['key / index', 'type', 'value']) def setData(self, data, hideRoot=False): """data should be a dictionary.""" self.clear() self.buildTree(data, self.invisibleRootItem(), hideRoot=hideRoot) #node = self.mkNode('', data) #while node.childCount() > 0: #c = node.child(0) #node.removeChild(c) #self.invisibleRootItem().addChild(c) self.expandToDepth(3) self.resizeColumnToContents(0) def buildTree(self, data, parent, name='', hideRoot=False): if hideRoot: node = parent else: typeStr = type(data).__name__ if typeStr == 'instance': typeStr += ": " + data.__class__.__name__ node = QtGui.QTreeWidgetItem([name, typeStr, ""]) parent.addChild(node) if isinstance(data, types.TracebackType): ## convert traceback to a list of strings data = list(map(str.strip, traceback.format_list(traceback.extract_tb(data)))) elif HAVE_METAARRAY and (hasattr(data, 'implements') and data.implements('MetaArray')): data = { 'data': data.view(np.ndarray), 'meta': data.infoCopy() } if isinstance(data, dict): for k in data.keys(): self.buildTree(data[k], node, str(k)) elif isinstance(data, list) or isinstance(data, tuple): for i in range(len(data)): self.buildTree(data[i], node, str(i)) else: node.setText(2, str(data)) #def mkNode(self, name, v): #if type(v) is list and len(v) > 0 and isinstance(v[0], dict): #inds = map(unicode, range(len(v))) #v = OrderedDict(zip(inds, v)) #if isinstance(v, dict): ##print "\nadd tree", k, v #node = QtGui.QTreeWidgetItem([name]) #for k in v: #newNode = self.mkNode(k, v[k]) #node.addChild(newNode) #else: ##print "\nadd value", k, str(v) #node = QtGui.QTreeWidgetItem([unicode(name), unicode(v)]) #return node pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/FeedbackButton.py000066400000000000000000000144351300727121400245470ustar00rootroot00000000000000# -*- coding: utf-8 -*- from ..Qt import QtCore, QtGui __all__ = ['FeedbackButton'] class FeedbackButton(QtGui.QPushButton): """ QPushButton which flashes success/failure indication for slow or asynchronous procedures. """ ### For thread-safetyness sigCallSuccess = QtCore.Signal(object, object, object) sigCallFailure = QtCore.Signal(object, object, object) sigCallProcess = QtCore.Signal(object, object, object) sigReset = QtCore.Signal() def __init__(self, *args): QtGui.QPushButton.__init__(self, *args) self.origStyle = None self.origText = self.text() self.origStyle = self.styleSheet() self.origTip = self.toolTip() self.limitedTime = True #self.textTimer = QtCore.QTimer() #self.tipTimer = QtCore.QTimer() #self.textTimer.timeout.connect(self.setText) #self.tipTimer.timeout.connect(self.setToolTip) self.sigCallSuccess.connect(self.success) self.sigCallFailure.connect(self.failure) self.sigCallProcess.connect(self.processing) self.sigReset.connect(self.reset) def feedback(self, success, message=None, tip="", limitedTime=True): """Calls success() or failure(). If you want the message to be displayed until the user takes an action, set limitedTime to False. Then call self.reset() after the desired action.Threadsafe.""" if success: self.success(message, tip, limitedTime=limitedTime) else: self.failure(message, tip, limitedTime=limitedTime) def success(self, message=None, tip="", limitedTime=True): """Displays specified message on button and flashes button green to let user know action was successful. If you want the success to be displayed until the user takes an action, set limitedTime to False. Then call self.reset() after the desired action. Threadsafe.""" isGuiThread = QtCore.QThread.currentThread() == QtCore.QCoreApplication.instance().thread() if isGuiThread: self.setEnabled(True) #print "success" self.startBlink("#0F0", message, tip, limitedTime=limitedTime) else: self.sigCallSuccess.emit(message, tip, limitedTime) def failure(self, message=None, tip="", limitedTime=True): """Displays specified message on button and flashes button red to let user know there was an error. If you want the error to be displayed until the user takes an action, set limitedTime to False. Then call self.reset() after the desired action. Threadsafe. """ isGuiThread = QtCore.QThread.currentThread() == QtCore.QCoreApplication.instance().thread() if isGuiThread: self.setEnabled(True) #print "fail" self.startBlink("#F00", message, tip, limitedTime=limitedTime) else: self.sigCallFailure.emit(message, tip, limitedTime) def processing(self, message="Processing..", tip="", processEvents=True): """Displays specified message on button to let user know the action is in progress. Threadsafe. """ isGuiThread = QtCore.QThread.currentThread() == QtCore.QCoreApplication.instance().thread() if isGuiThread: self.setEnabled(False) self.setText(message, temporary=True) self.setToolTip(tip, temporary=True) if processEvents: QtGui.QApplication.processEvents() else: self.sigCallProcess.emit(message, tip, processEvents) def reset(self): """Resets the button to its original text and style. Threadsafe.""" isGuiThread = QtCore.QThread.currentThread() == QtCore.QCoreApplication.instance().thread() if isGuiThread: self.limitedTime = True self.setText() self.setToolTip() self.setStyleSheet() else: self.sigReset.emit() def startBlink(self, color, message=None, tip="", limitedTime=True): #if self.origStyle is None: #self.origStyle = self.styleSheet() #self.origText = self.text() self.setFixedHeight(self.height()) if message is not None: self.setText(message, temporary=True) self.setToolTip(tip, temporary=True) self.count = 0 #self.indStyle = "QPushButton {border: 2px solid %s; border-radius: 5px}" % color self.indStyle = "QPushButton {background-color: %s}" % color self.limitedTime = limitedTime self.borderOn() if limitedTime: QtCore.QTimer.singleShot(2000, self.setText) QtCore.QTimer.singleShot(10000, self.setToolTip) def borderOn(self): self.setStyleSheet(self.indStyle, temporary=True) if self.limitedTime or self.count <=2: QtCore.QTimer.singleShot(100, self.borderOff) def borderOff(self): self.setStyleSheet() self.count += 1 if self.count >= 2: if self.limitedTime: return QtCore.QTimer.singleShot(30, self.borderOn) def setText(self, text=None, temporary=False): if text is None: text = self.origText #print text QtGui.QPushButton.setText(self, text) if not temporary: self.origText = text def setToolTip(self, text=None, temporary=False): if text is None: text = self.origTip QtGui.QPushButton.setToolTip(self, text) if not temporary: self.origTip = text def setStyleSheet(self, style=None, temporary=False): if style is None: style = self.origStyle QtGui.QPushButton.setStyleSheet(self, style) if not temporary: self.origStyle = style if __name__ == '__main__': import time app = QtGui.QApplication([]) win = QtGui.QMainWindow() btn = FeedbackButton("Button") fail = True def click(): btn.processing("Hold on..") time.sleep(2.0) global fail fail = not fail if fail: btn.failure(message="FAIL.", tip="There was a failure. Get over it.") else: btn.success(message="Bueno!") btn.clicked.connect(click) win.setCentralWidget(btn) win.show()pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/FileDialog.py000066400000000000000000000007361300727121400236650ustar00rootroot00000000000000from ..Qt import QtGui, QtCore import sys __all__ = ['FileDialog'] class FileDialog(QtGui.QFileDialog): ## Compatibility fix for OSX: ## For some reason the native dialog doesn't show up when you set AcceptMode to AcceptSave on OS X, so we don't use the native dialog def __init__(self, *args): QtGui.QFileDialog.__init__(self, *args) if sys.platform == 'darwin': self.setOption(QtGui.QFileDialog.DontUseNativeDialog)pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/GradientWidget.py000066400000000000000000000055251300727121400245700ustar00rootroot00000000000000# -*- coding: utf-8 -*- from ..Qt import QtGui, QtCore from .GraphicsView import GraphicsView from ..graphicsItems.GradientEditorItem import GradientEditorItem import weakref import numpy as np __all__ = ['GradientWidget'] class GradientWidget(GraphicsView): """ Widget displaying an editable color gradient. The user may add, move, recolor, or remove colors from the gradient. Additionally, a context menu allows the user to select from pre-defined gradients. """ sigGradientChanged = QtCore.Signal(object) sigGradientChangeFinished = QtCore.Signal(object) def __init__(self, parent=None, orientation='bottom', *args, **kargs): """ The *orientation* argument may be 'bottom', 'top', 'left', or 'right' indicating whether the gradient is displayed horizontally (top, bottom) or vertically (left, right) and on what side of the gradient the editable ticks will appear. All other arguments are passed to :func:`GradientEditorItem.__init__ `. Note: For convenience, this class wraps methods from :class:`GradientEditorItem `. """ GraphicsView.__init__(self, parent, useOpenGL=False, background=None) self.maxDim = 31 kargs['tickPen'] = 'k' self.item = GradientEditorItem(*args, **kargs) self.item.sigGradientChanged.connect(self.sigGradientChanged) self.item.sigGradientChangeFinished.connect(self.sigGradientChangeFinished) self.setCentralItem(self.item) self.setOrientation(orientation) self.setCacheMode(self.CacheNone) self.setRenderHints(QtGui.QPainter.Antialiasing | QtGui.QPainter.TextAntialiasing) self.setFrameStyle(QtGui.QFrame.NoFrame | QtGui.QFrame.Plain) #self.setBackgroundRole(QtGui.QPalette.NoRole) #self.setBackgroundBrush(QtGui.QBrush(QtCore.Qt.NoBrush)) #self.setAutoFillBackground(False) #self.setAttribute(QtCore.Qt.WA_PaintOnScreen, False) #self.setAttribute(QtCore.Qt.WA_OpaquePaintEvent, True) def setOrientation(self, ort): """Set the orientation of the widget. May be one of 'bottom', 'top', 'left', or 'right'.""" self.item.setOrientation(ort) self.orientation = ort self.setMaxDim() def setMaxDim(self, mx=None): if mx is None: mx = self.maxDim else: self.maxDim = mx if self.orientation in ['bottom', 'top']: self.setFixedHeight(mx) self.setMaximumWidth(16777215) else: self.setFixedWidth(mx) self.setMaximumHeight(16777215) def __getattr__(self, attr): ### wrap methods from GradientEditorItem return getattr(self.item, attr) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/GraphicsLayoutWidget.py000066400000000000000000000027061300727121400257670ustar00rootroot00000000000000from ..Qt import QtGui from ..graphicsItems.GraphicsLayout import GraphicsLayout from .GraphicsView import GraphicsView __all__ = ['GraphicsLayoutWidget'] class GraphicsLayoutWidget(GraphicsView): """ Convenience class consisting of a :class:`GraphicsView ` with a single :class:`GraphicsLayout ` as its central item. This class wraps several methods from its internal GraphicsLayout: :func:`nextRow ` :func:`nextColumn ` :func:`addPlot ` :func:`addViewBox ` :func:`addItem ` :func:`getItem ` :func:`addLabel ` :func:`addLayout ` :func:`removeItem ` :func:`itemIndex ` :func:`clear ` """ def __init__(self, parent=None, **kargs): GraphicsView.__init__(self, parent) self.ci = GraphicsLayout(**kargs) for n in ['nextRow', 'nextCol', 'nextColumn', 'addPlot', 'addViewBox', 'addItem', 'getItem', 'addLayout', 'addLabel', 'removeItem', 'itemIndex', 'clear']: setattr(self, n, getattr(self.ci, n)) self.setCentralItem(self.ci) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/GraphicsView.py000066400000000000000000000360671300727121400242670ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ GraphicsView.py - Extension of QGraphicsView Copyright 2010 Luke Campagnola Distributed under MIT/X11 license. See license.txt for more infomation. """ from ..Qt import QtCore, QtGui, USE_PYSIDE try: from ..Qt import QtOpenGL HAVE_OPENGL = True except ImportError: HAVE_OPENGL = False from ..Point import Point import sys, os from .FileDialog import FileDialog from ..GraphicsScene import GraphicsScene import numpy as np from .. import functions as fn from .. import debug as debug from .. import getConfigOption __all__ = ['GraphicsView'] class GraphicsView(QtGui.QGraphicsView): """Re-implementation of QGraphicsView that removes scrollbars and allows unambiguous control of the viewed coordinate range. Also automatically creates a GraphicsScene and a central QGraphicsWidget that is automatically scaled to the full view geometry. This widget is the basis for :class:`PlotWidget `, :class:`GraphicsLayoutWidget `, and the view widget in :class:`ImageView `. By default, the view coordinate system matches the widget's pixel coordinates and automatically updates when the view is resized. This can be overridden by setting autoPixelRange=False. The exact visible range can be set with setRange(). The view can be panned using the middle mouse button and scaled using the right mouse button if enabled via enableMouse() (but ordinarily, we use ViewBox for this functionality).""" sigDeviceRangeChanged = QtCore.Signal(object, object) sigDeviceTransformChanged = QtCore.Signal(object) sigMouseReleased = QtCore.Signal(object) sigSceneMouseMoved = QtCore.Signal(object) #sigRegionChanged = QtCore.Signal(object) sigScaleChanged = QtCore.Signal(object) lastFileDir = None def __init__(self, parent=None, useOpenGL=None, background='default'): """ ============== ============================================================ **Arguments:** parent Optional parent widget useOpenGL If True, the GraphicsView will use OpenGL to do all of its rendering. This can improve performance on some systems, but may also introduce bugs (the combination of QGraphicsView and QGLWidget is still an 'experimental' feature of Qt) background Set the background color of the GraphicsView. Accepts any single argument accepted by :func:`mkColor `. By default, the background color is determined using the 'backgroundColor' configuration option (see :func:`setConfigOptions `). ============== ============================================================ """ self.closed = False QtGui.QGraphicsView.__init__(self, parent) # This connects a cleanup function to QApplication.aboutToQuit. It is # called from here because we have no good way to react when the # QApplication is created by the user. # See pyqtgraph.__init__.py from .. import _connectCleanup _connectCleanup() if useOpenGL is None: useOpenGL = getConfigOption('useOpenGL') self.useOpenGL(useOpenGL) self.setCacheMode(self.CacheBackground) ## This might help, but it's probably dangerous in the general case.. #self.setOptimizationFlag(self.DontSavePainterState, True) self.setBackgroundRole(QtGui.QPalette.NoRole) self.setBackground(background) self.setFocusPolicy(QtCore.Qt.StrongFocus) self.setFrameShape(QtGui.QFrame.NoFrame) self.setVerticalScrollBarPolicy(QtCore.Qt.ScrollBarAlwaysOff) self.setHorizontalScrollBarPolicy(QtCore.Qt.ScrollBarAlwaysOff) self.setTransformationAnchor(QtGui.QGraphicsView.NoAnchor) self.setResizeAnchor(QtGui.QGraphicsView.AnchorViewCenter) self.setViewportUpdateMode(QtGui.QGraphicsView.MinimalViewportUpdate) self.lockedViewports = [] self.lastMousePos = None self.setMouseTracking(True) self.aspectLocked = False self.range = QtCore.QRectF(0, 0, 1, 1) self.autoPixelRange = True self.currentItem = None self.clearMouse() self.updateMatrix() # GraphicsScene must have parent or expect crashes! self.sceneObj = GraphicsScene(parent=self) self.setScene(self.sceneObj) ## Workaround for PySide crash ## This ensures that the scene will outlive the view. if USE_PYSIDE: self.sceneObj._view_ref_workaround = self ## by default we set up a central widget with a grid layout. ## this can be replaced if needed. self.centralWidget = None self.setCentralItem(QtGui.QGraphicsWidget()) self.centralLayout = QtGui.QGraphicsGridLayout() self.centralWidget.setLayout(self.centralLayout) self.mouseEnabled = False self.scaleCenter = False ## should scaling center around view center (True) or mouse click (False) self.clickAccepted = False def setAntialiasing(self, aa): """Enable or disable default antialiasing. Note that this will only affect items that do not specify their own antialiasing options.""" if aa: self.setRenderHints(self.renderHints() | QtGui.QPainter.Antialiasing) else: self.setRenderHints(self.renderHints() & ~QtGui.QPainter.Antialiasing) def setBackground(self, background): """ Set the background color of the GraphicsView. To use the defaults specified py pyqtgraph.setConfigOption, use background='default'. To make the background transparent, use background=None. """ self._background = background if background == 'default': background = getConfigOption('background') brush = fn.mkBrush(background) self.setBackgroundBrush(brush) def paintEvent(self, ev): self.scene().prepareForPaint() return QtGui.QGraphicsView.paintEvent(self, ev) def render(self, *args, **kwds): self.scene().prepareForPaint() return QtGui.QGraphicsView.render(self, *args, **kwds) def close(self): self.centralWidget = None self.scene().clear() self.currentItem = None self.sceneObj = None self.closed = True self.setViewport(None) super(GraphicsView, self).close() def useOpenGL(self, b=True): if b: if not HAVE_OPENGL: raise Exception("Requested to use OpenGL with QGraphicsView, but QtOpenGL module is not available.") v = QtOpenGL.QGLWidget() else: v = QtGui.QWidget() self.setViewport(v) def keyPressEvent(self, ev): self.scene().keyPressEvent(ev) ## bypass view, hand event directly to scene ## (view likes to eat arrow key events) def setCentralItem(self, item): return self.setCentralWidget(item) def setCentralWidget(self, item): """Sets a QGraphicsWidget to automatically fill the entire view (the item will be automatically resize whenever the GraphicsView is resized).""" if self.centralWidget is not None: self.scene().removeItem(self.centralWidget) self.centralWidget = item if item is not None: self.sceneObj.addItem(item) self.resizeEvent(None) def addItem(self, *args): return self.scene().addItem(*args) def removeItem(self, *args): return self.scene().removeItem(*args) def enableMouse(self, b=True): self.mouseEnabled = b self.autoPixelRange = (not b) def clearMouse(self): self.mouseTrail = [] self.lastButtonReleased = None def resizeEvent(self, ev): if self.closed: return if self.autoPixelRange: self.range = QtCore.QRectF(0, 0, self.size().width(), self.size().height()) GraphicsView.setRange(self, self.range, padding=0, disableAutoPixel=False) ## we do this because some subclasses like to redefine setRange in an incompatible way. self.updateMatrix() def updateMatrix(self, propagate=True): self.setSceneRect(self.range) if self.autoPixelRange: self.resetTransform() else: if self.aspectLocked: self.fitInView(self.range, QtCore.Qt.KeepAspectRatio) else: self.fitInView(self.range, QtCore.Qt.IgnoreAspectRatio) self.sigDeviceRangeChanged.emit(self, self.range) self.sigDeviceTransformChanged.emit(self) if propagate: for v in self.lockedViewports: v.setXRange(self.range, padding=0) def viewRect(self): """Return the boundaries of the view in scene coordinates""" ## easier to just return self.range ? r = QtCore.QRectF(self.rect()) return self.viewportTransform().inverted()[0].mapRect(r) def visibleRange(self): ## for backward compatibility return self.viewRect() def translate(self, dx, dy): self.range.adjust(dx, dy, dx, dy) self.updateMatrix() def scale(self, sx, sy, center=None): scale = [sx, sy] if self.aspectLocked: scale[0] = scale[1] if self.scaleCenter: center = None if center is None: center = self.range.center() w = self.range.width() / scale[0] h = self.range.height() / scale[1] self.range = QtCore.QRectF(center.x() - (center.x()-self.range.left()) / scale[0], center.y() - (center.y()-self.range.top()) /scale[1], w, h) self.updateMatrix() self.sigScaleChanged.emit(self) def setRange(self, newRect=None, padding=0.05, lockAspect=None, propagate=True, disableAutoPixel=True): if disableAutoPixel: self.autoPixelRange=False if newRect is None: newRect = self.visibleRange() padding = 0 padding = Point(padding) newRect = QtCore.QRectF(newRect) pw = newRect.width() * padding[0] ph = newRect.height() * padding[1] newRect = newRect.adjusted(-pw, -ph, pw, ph) scaleChanged = False if self.range.width() != newRect.width() or self.range.height() != newRect.height(): scaleChanged = True self.range = newRect #print "New Range:", self.range if self.centralWidget is not None: self.centralWidget.setGeometry(self.range) self.updateMatrix(propagate) if scaleChanged: self.sigScaleChanged.emit(self) def scaleToImage(self, image): """Scales such that pixels in image are the same size as screen pixels. This may result in a significant performance increase.""" pxSize = image.pixelSize() image.setPxMode(True) try: self.sigScaleChanged.disconnect(image.setScaledMode) except (TypeError, RuntimeError): pass tl = image.sceneBoundingRect().topLeft() w = self.size().width() * pxSize[0] h = self.size().height() * pxSize[1] range = QtCore.QRectF(tl.x(), tl.y(), w, h) GraphicsView.setRange(self, range, padding=0) self.sigScaleChanged.connect(image.setScaledMode) def lockXRange(self, v1): if not v1 in self.lockedViewports: self.lockedViewports.append(v1) def setXRange(self, r, padding=0.05): r1 = QtCore.QRectF(self.range) r1.setLeft(r.left()) r1.setRight(r.right()) GraphicsView.setRange(self, r1, padding=[padding, 0], propagate=False) def setYRange(self, r, padding=0.05): r1 = QtCore.QRectF(self.range) r1.setTop(r.top()) r1.setBottom(r.bottom()) GraphicsView.setRange(self, r1, padding=[0, padding], propagate=False) def wheelEvent(self, ev): QtGui.QGraphicsView.wheelEvent(self, ev) if not self.mouseEnabled: ev.ignore() return sc = 1.001 ** ev.delta() #self.scale *= sc #self.updateMatrix() self.scale(sc, sc) def setAspectLocked(self, s): self.aspectLocked = s def leaveEvent(self, ev): self.scene().leaveEvent(ev) ## inform scene when mouse leaves def mousePressEvent(self, ev): QtGui.QGraphicsView.mousePressEvent(self, ev) if not self.mouseEnabled: return self.lastMousePos = Point(ev.pos()) self.mousePressPos = ev.pos() self.clickAccepted = ev.isAccepted() if not self.clickAccepted: self.scene().clearSelection() return ## Everything below disabled for now.. def mouseReleaseEvent(self, ev): QtGui.QGraphicsView.mouseReleaseEvent(self, ev) if not self.mouseEnabled: return self.sigMouseReleased.emit(ev) self.lastButtonReleased = ev.button() return ## Everything below disabled for now.. def mouseMoveEvent(self, ev): if self.lastMousePos is None: self.lastMousePos = Point(ev.pos()) delta = Point(ev.pos() - self.lastMousePos) self.lastMousePos = Point(ev.pos()) QtGui.QGraphicsView.mouseMoveEvent(self, ev) if not self.mouseEnabled: return self.sigSceneMouseMoved.emit(self.mapToScene(ev.pos())) if self.clickAccepted: ## Ignore event if an item in the scene has already claimed it. return if ev.buttons() == QtCore.Qt.RightButton: delta = Point(np.clip(delta[0], -50, 50), np.clip(-delta[1], -50, 50)) scale = 1.01 ** delta self.scale(scale[0], scale[1], center=self.mapToScene(self.mousePressPos)) self.sigDeviceRangeChanged.emit(self, self.range) elif ev.buttons() in [QtCore.Qt.MidButton, QtCore.Qt.LeftButton]: ## Allow panning by left or mid button. px = self.pixelSize() tr = -delta * px self.translate(tr[0], tr[1]) self.sigDeviceRangeChanged.emit(self, self.range) def pixelSize(self): """Return vector with the length and width of one view pixel in scene coordinates""" p0 = Point(0,0) p1 = Point(1,1) tr = self.transform().inverted()[0] p01 = tr.map(p0) p11 = tr.map(p1) return Point(p11 - p01) def dragEnterEvent(self, ev): ev.ignore() ## not sure why, but for some reason this class likes to consume drag events pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/HistogramLUTWidget.py000066400000000000000000000016541300727121400253540ustar00rootroot00000000000000""" Widget displaying an image histogram along with gradient editor. Can be used to adjust the appearance of images. This is a wrapper around HistogramLUTItem """ from ..Qt import QtGui, QtCore from .GraphicsView import GraphicsView from ..graphicsItems.HistogramLUTItem import HistogramLUTItem __all__ = ['HistogramLUTWidget'] class HistogramLUTWidget(GraphicsView): def __init__(self, parent=None, *args, **kargs): background = kargs.get('background', 'default') GraphicsView.__init__(self, parent, useOpenGL=False, background=background) self.item = HistogramLUTItem(*args, **kargs) self.setCentralItem(self.item) self.setSizePolicy(QtGui.QSizePolicy.Preferred, QtGui.QSizePolicy.Expanding) self.setMinimumWidth(95) def sizeHint(self): return QtCore.QSize(115, 200) def __getattr__(self, attr): return getattr(self.item, attr) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/JoystickButton.py000066400000000000000000000046341300727121400246620ustar00rootroot00000000000000from ..Qt import QtGui, QtCore __all__ = ['JoystickButton'] class JoystickButton(QtGui.QPushButton): sigStateChanged = QtCore.Signal(object, object) ## self, state def __init__(self, parent=None): QtGui.QPushButton.__init__(self, parent) self.radius = 200 self.setCheckable(True) self.state = None self.setState(0,0) self.setFixedWidth(50) self.setFixedHeight(50) def mousePressEvent(self, ev): self.setChecked(True) self.pressPos = ev.pos() ev.accept() def mouseMoveEvent(self, ev): dif = ev.pos()-self.pressPos self.setState(dif.x(), -dif.y()) def mouseReleaseEvent(self, ev): self.setChecked(False) self.setState(0,0) def wheelEvent(self, ev): ev.accept() def doubleClickEvent(self, ev): ev.accept() def getState(self): return self.state def setState(self, *xy): xy = list(xy) d = (xy[0]**2 + xy[1]**2)**0.5 nxy = [0,0] for i in [0,1]: if xy[i] == 0: nxy[i] = 0 else: nxy[i] = xy[i]/d if d > self.radius: d = self.radius d = (d/self.radius)**2 xy = [nxy[0]*d, nxy[1]*d] w2 = self.width()/2. h2 = self.height()/2 self.spotPos = QtCore.QPoint(w2*(1+xy[0]), h2*(1-xy[1])) self.update() if self.state == xy: return self.state = xy self.sigStateChanged.emit(self, self.state) def paintEvent(self, ev): QtGui.QPushButton.paintEvent(self, ev) p = QtGui.QPainter(self) p.setBrush(QtGui.QBrush(QtGui.QColor(0,0,0))) p.drawEllipse(self.spotPos.x()-3,self.spotPos.y()-3,6,6) def resizeEvent(self, ev): self.setState(*self.state) QtGui.QPushButton.resizeEvent(self, ev) if __name__ == '__main__': app = QtGui.QApplication([]) w = QtGui.QMainWindow() b = JoystickButton() w.setCentralWidget(b) w.show() w.resize(100, 100) def fn(b, s): print("state changed:", s) b.sigStateChanged.connect(fn) ## Start Qt event loop unless running in interactive mode. import sys if sys.flags.interactive != 1: app.exec_() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/LayoutWidget.py000066400000000000000000000065411300727121400243070ustar00rootroot00000000000000from ..Qt import QtGui, QtCore __all__ = ['LayoutWidget'] class LayoutWidget(QtGui.QWidget): """ Convenience class used for laying out QWidgets in a grid. (It's just a little less effort to use than QGridLayout) """ def __init__(self, parent=None): QtGui.QWidget.__init__(self, parent) self.layout = QtGui.QGridLayout() self.setLayout(self.layout) self.items = {} self.rows = {} self.currentRow = 0 self.currentCol = 0 def nextRow(self): """Advance to next row for automatic widget placement""" self.currentRow += 1 self.currentCol = 0 def nextColumn(self, colspan=1): """Advance to next column, while returning the current column number (generally only for internal use--called by addWidget)""" self.currentCol += colspan return self.currentCol-colspan def nextCol(self, *args, **kargs): """Alias of nextColumn""" return self.nextColumn(*args, **kargs) def addLabel(self, text=' ', row=None, col=None, rowspan=1, colspan=1, **kargs): """ Create a QLabel with *text* and place it in the next available cell (or in the cell specified) All extra keyword arguments are passed to QLabel(). Returns the created widget. """ text = QtGui.QLabel(text, **kargs) self.addItem(text, row, col, rowspan, colspan) return text def addLayout(self, row=None, col=None, rowspan=1, colspan=1, **kargs): """ Create an empty LayoutWidget and place it in the next available cell (or in the cell specified) All extra keyword arguments are passed to :func:`LayoutWidget.__init__ ` Returns the created widget. """ layout = LayoutWidget(**kargs) self.addItem(layout, row, col, rowspan, colspan) return layout def addWidget(self, item, row=None, col=None, rowspan=1, colspan=1): """ Add a widget to the layout and place it in the next available cell (or in the cell specified). """ if row == 'next': self.nextRow() row = self.currentRow elif row is None: row = self.currentRow if col is None: col = self.nextCol(colspan) if row not in self.rows: self.rows[row] = {} self.rows[row][col] = item self.items[item] = (row, col) self.layout.addWidget(item, row, col, rowspan, colspan) def getWidget(self, row, col): """Return the widget in (*row*, *col*)""" return self.row[row][col] #def itemIndex(self, item): #for i in range(self.layout.count()): #if self.layout.itemAt(i).graphicsItem() is item: #return i #raise Exception("Could not determine index of item " + str(item)) #def removeItem(self, item): #"""Remove *item* from the layout.""" #ind = self.itemIndex(item) #self.layout.removeAt(ind) #self.scene().removeItem(item) #r,c = self.items[item] #del self.items[item] #del self.rows[r][c] #self.update() #def clear(self): #items = [] #for i in list(self.items.keys()): #self.removeItem(i) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/MatplotlibWidget.py000066400000000000000000000030501300727121400251310ustar00rootroot00000000000000from ..Qt import QtGui, QtCore, USE_PYSIDE, USE_PYQT5 import matplotlib if not USE_PYQT5: if USE_PYSIDE: matplotlib.rcParams['backend.qt4']='PySide' from matplotlib.backends.backend_qt4agg import FigureCanvasQTAgg as FigureCanvas try: from matplotlib.backends.backend_qt4agg import NavigationToolbar2QTAgg as NavigationToolbar except ImportError: from matplotlib.backends.backend_qt4agg import NavigationToolbar2QT as NavigationToolbar else: from matplotlib.backends.backend_qt5agg import FigureCanvasQTAgg as FigureCanvas from matplotlib.backends.backend_qt5agg import NavigationToolbar2QT as NavigationToolbar from matplotlib.figure import Figure class MatplotlibWidget(QtGui.QWidget): """ Implements a Matplotlib figure inside a QWidget. Use getFigure() and redraw() to interact with matplotlib. Example:: mw = MatplotlibWidget() subplot = mw.getFigure().add_subplot(111) subplot.plot(x,y) mw.draw() """ def __init__(self, size=(5.0, 4.0), dpi=100): QtGui.QWidget.__init__(self) self.fig = Figure(size, dpi=dpi) self.canvas = FigureCanvas(self.fig) self.canvas.setParent(self) self.toolbar = NavigationToolbar(self.canvas, self) self.vbox = QtGui.QVBoxLayout() self.vbox.addWidget(self.toolbar) self.vbox.addWidget(self.canvas) self.setLayout(self.vbox) def getFigure(self): return self.fig def draw(self): self.canvas.draw() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/MultiPlotWidget.py000066400000000000000000000056511300727121400247640ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ MultiPlotWidget.py - Convenience class--GraphicsView widget displaying a MultiPlotItem Copyright 2010 Luke Campagnola Distributed under MIT/X11 license. See license.txt for more infomation. """ from ..Qt import QtCore from .GraphicsView import GraphicsView from ..graphicsItems import MultiPlotItem as MultiPlotItem __all__ = ['MultiPlotWidget'] class MultiPlotWidget(GraphicsView): """Widget implementing a graphicsView with a single MultiPlotItem inside.""" def __init__(self, parent=None): self.minPlotHeight = 50 self.mPlotItem = MultiPlotItem.MultiPlotItem() GraphicsView.__init__(self, parent) self.enableMouse(False) self.setCentralItem(self.mPlotItem) ## Explicitly wrap methods from mPlotItem #for m in ['setData']: #setattr(self, m, getattr(self.mPlotItem, m)) self.setVerticalScrollBarPolicy(QtCore.Qt.ScrollBarAsNeeded) self.setHorizontalScrollBarPolicy(QtCore.Qt.ScrollBarAsNeeded) def __getattr__(self, attr): ## implicitly wrap methods from plotItem if hasattr(self.mPlotItem, attr): m = getattr(self.mPlotItem, attr) if hasattr(m, '__call__'): return m raise AttributeError(attr) def setMinimumPlotHeight(self, min): """Set the minimum height for each sub-plot displayed. If the total height of all plots is greater than the height of the widget, then a scroll bar will appear to provide access to the entire set of plots. Added in version 0.9.9 """ self.minPlotHeight = min self.resizeEvent(None) def widgetGroupInterface(self): return (None, MultiPlotWidget.saveState, MultiPlotWidget.restoreState) def saveState(self): return {} #return self.plotItem.saveState() def restoreState(self, state): pass #return self.plotItem.restoreState(state) def close(self): self.mPlotItem.close() self.mPlotItem = None self.setParent(None) GraphicsView.close(self) def setRange(self, *args, **kwds): GraphicsView.setRange(self, *args, **kwds) if self.centralWidget is not None: r = self.range minHeight = len(self.mPlotItem.plots) * self.minPlotHeight if r.height() < minHeight: r.setHeight(minHeight) r.setWidth(r.width() - self.verticalScrollBar().width()) self.centralWidget.setGeometry(r) def resizeEvent(self, ev): if self.closed: return if self.autoPixelRange: self.range = QtCore.QRectF(0, 0, self.size().width(), self.size().height()) MultiPlotWidget.setRange(self, self.range, padding=0, disableAutoPixel=False) ## we do this because some subclasses like to redefine setRange in an incompatible way. self.updateMatrix() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/PathButton.py000066400000000000000000000030241300727121400237470ustar00rootroot00000000000000from ..Qt import QtGui, QtCore from .. import functions as fn __all__ = ['PathButton'] class PathButton(QtGui.QPushButton): """Simple PushButton extension which paints a QPainterPath on its face""" def __init__(self, parent=None, path=None, pen='default', brush=None, size=(30,30)): QtGui.QPushButton.__init__(self, parent) self.path = None if pen == 'default': pen = 'k' self.setPen(pen) self.setBrush(brush) if path is not None: self.setPath(path) if size is not None: self.setFixedWidth(size[0]) self.setFixedHeight(size[1]) def setBrush(self, brush): self.brush = fn.mkBrush(brush) def setPen(self, *args, **kwargs): self.pen = fn.mkPen(*args, **kwargs) def setPath(self, path): self.path = path self.update() def paintEvent(self, ev): QtGui.QPushButton.paintEvent(self, ev) margin = 7 geom = QtCore.QRectF(0, 0, self.width(), self.height()).adjusted(margin, margin, -margin, -margin) rect = self.path.boundingRect() scale = min(geom.width() / float(rect.width()), geom.height() / float(rect.height())) p = QtGui.QPainter(self) p.setRenderHint(p.Antialiasing) p.translate(geom.center()) p.scale(scale, scale) p.translate(-rect.center()) p.setPen(self.pen) p.setBrush(self.brush) p.drawPath(self.path) p.end() pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/PlotWidget.py000066400000000000000000000077641300727121400237600ustar00rootroot00000000000000# -*- coding: utf-8 -*- """ PlotWidget.py - Convenience class--GraphicsView widget displaying a single PlotItem Copyright 2010 Luke Campagnola Distributed under MIT/X11 license. See license.txt for more infomation. """ from ..Qt import QtCore, QtGui from .GraphicsView import * from ..graphicsItems.PlotItem import * __all__ = ['PlotWidget'] class PlotWidget(GraphicsView): # signals wrapped from PlotItem / ViewBox sigRangeChanged = QtCore.Signal(object, object) sigTransformChanged = QtCore.Signal(object) """ :class:`GraphicsView ` widget with a single :class:`PlotItem ` inside. The following methods are wrapped directly from PlotItem: :func:`addItem `, :func:`removeItem `, :func:`clear `, :func:`setXRange `, :func:`setYRange `, :func:`setRange `, :func:`autoRange `, :func:`setXLink `, :func:`setYLink `, :func:`viewRect `, :func:`setMouseEnabled `, :func:`enableAutoRange `, :func:`disableAutoRange `, :func:`setAspectLocked `, :func:`setLimits `, :func:`register `, :func:`unregister ` For all other methods, use :func:`getPlotItem `. """ def __init__(self, parent=None, background='default', **kargs): """When initializing PlotWidget, *parent* and *background* are passed to :func:`GraphicsWidget.__init__() ` and all others are passed to :func:`PlotItem.__init__() `.""" GraphicsView.__init__(self, parent, background=background) self.setSizePolicy(QtGui.QSizePolicy.Expanding, QtGui.QSizePolicy.Expanding) self.enableMouse(False) self.plotItem = PlotItem(**kargs) self.setCentralItem(self.plotItem) ## Explicitly wrap methods from plotItem ## NOTE: If you change this list, update the documentation above as well. for m in ['addItem', 'removeItem', 'autoRange', 'clear', 'setXRange', 'setYRange', 'setRange', 'setAspectLocked', 'setMouseEnabled', 'setXLink', 'setYLink', 'enableAutoRange', 'disableAutoRange', 'setLimits', 'register', 'unregister', 'viewRect']: setattr(self, m, getattr(self.plotItem, m)) #QtCore.QObject.connect(self.plotItem, QtCore.SIGNAL('viewChanged'), self.viewChanged) self.plotItem.sigRangeChanged.connect(self.viewRangeChanged) def close(self): self.plotItem.close() self.plotItem = None #self.scene().clear() #self.mPlotItem.close() self.setParent(None) super(PlotWidget, self).close() def __getattr__(self, attr): ## implicitly wrap methods from plotItem if hasattr(self.plotItem, attr): m = getattr(self.plotItem, attr) if hasattr(m, '__call__'): return m raise NameError(attr) def viewRangeChanged(self, view, range): #self.emit(QtCore.SIGNAL('viewChanged'), *args) self.sigRangeChanged.emit(self, range) def widgetGroupInterface(self): return (None, PlotWidget.saveState, PlotWidget.restoreState) def saveState(self): return self.plotItem.saveState() def restoreState(self, state): return self.plotItem.restoreState(state) def getPlotItem(self): """Return the PlotItem contained within.""" return self.plotItem pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/ProgressDialog.py000066400000000000000000000072471300727121400246160ustar00rootroot00000000000000# -*- coding: utf-8 -*- from ..Qt import QtGui, QtCore __all__ = ['ProgressDialog'] class ProgressDialog(QtGui.QProgressDialog): """ Extends QProgressDialog for use in 'with' statements. Example:: with ProgressDialog("Processing..", minVal, maxVal) as dlg: # do stuff dlg.setValue(i) ## could also use dlg += 1 if dlg.wasCanceled(): raise Exception("Processing canceled by user") """ def __init__(self, labelText, minimum=0, maximum=100, cancelText='Cancel', parent=None, wait=250, busyCursor=False, disable=False): """ ============== ================================================================ **Arguments:** labelText (required) cancelText Text to display on cancel button, or None to disable it. minimum maximum parent wait Length of time (im ms) to wait before displaying dialog busyCursor If True, show busy cursor until dialog finishes disable If True, the progress dialog will not be displayed and calls to wasCanceled() will always return False. If ProgressDialog is entered from a non-gui thread, it will always be disabled. ============== ================================================================ """ isGuiThread = QtCore.QThread.currentThread() == QtCore.QCoreApplication.instance().thread() self.disabled = disable or (not isGuiThread) if self.disabled: return noCancel = False if cancelText is None: cancelText = '' noCancel = True self.busyCursor = busyCursor QtGui.QProgressDialog.__init__(self, labelText, cancelText, minimum, maximum, parent) self.setMinimumDuration(wait) self.setWindowModality(QtCore.Qt.WindowModal) self.setValue(self.minimum()) if noCancel: self.setCancelButton(None) def __enter__(self): if self.disabled: return self if self.busyCursor: QtGui.QApplication.setOverrideCursor(QtGui.QCursor(QtCore.Qt.WaitCursor)) return self def __exit__(self, exType, exValue, exTrace): if self.disabled: return if self.busyCursor: QtGui.QApplication.restoreOverrideCursor() self.setValue(self.maximum()) def __iadd__(self, val): """Use inplace-addition operator for easy incrementing.""" if self.disabled: return self self.setValue(self.value()+val) return self ## wrap all other functions to make sure they aren't being called from non-gui threads def setValue(self, val): if self.disabled: return QtGui.QProgressDialog.setValue(self, val) def setLabelText(self, val): if self.disabled: return QtGui.QProgressDialog.setLabelText(self, val) def setMaximum(self, val): if self.disabled: return QtGui.QProgressDialog.setMaximum(self, val) def setMinimum(self, val): if self.disabled: return QtGui.QProgressDialog.setMinimum(self, val) def wasCanceled(self): if self.disabled: return False return QtGui.QProgressDialog.wasCanceled(self) def maximum(self): if self.disabled: return 0 return QtGui.QProgressDialog.maximum(self) def minimum(self): if self.disabled: return 0 return QtGui.QProgressDialog.minimum(self) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/RawImageWidget.py000066400000000000000000000126271300727121400245300ustar00rootroot00000000000000from ..Qt import QtCore, QtGui try: from ..Qt import QtOpenGL from OpenGL.GL import * HAVE_OPENGL = True except Exception: # Would prefer `except ImportError` here, but some versions of pyopengl generate # AttributeError upon import HAVE_OPENGL = False from .. import functions as fn import numpy as np class RawImageWidget(QtGui.QWidget): """ Widget optimized for very fast video display. Generally using an ImageItem inside GraphicsView is fast enough. On some systems this may provide faster video. See the VideoSpeedTest example for benchmarking. """ def __init__(self, parent=None, scaled=False): """ Setting scaled=True will cause the entire image to be displayed within the boundaries of the widget. This also greatly reduces the speed at which it will draw frames. """ QtGui.QWidget.__init__(self, parent=None) self.setSizePolicy(QtGui.QSizePolicy(QtGui.QSizePolicy.Expanding,QtGui.QSizePolicy.Expanding)) self.scaled = scaled self.opts = None self.image = None def setImage(self, img, *args, **kargs): """ img must be ndarray of shape (x,y), (x,y,3), or (x,y,4). Extra arguments are sent to functions.makeARGB """ self.opts = (img, args, kargs) self.image = None self.update() def paintEvent(self, ev): if self.opts is None: return if self.image is None: argb, alpha = fn.makeARGB(self.opts[0], *self.opts[1], **self.opts[2]) self.image = fn.makeQImage(argb, alpha) self.opts = () #if self.pixmap is None: #self.pixmap = QtGui.QPixmap.fromImage(self.image) p = QtGui.QPainter(self) if self.scaled: rect = self.rect() ar = rect.width() / float(rect.height()) imar = self.image.width() / float(self.image.height()) if ar > imar: rect.setWidth(int(rect.width() * imar/ar)) else: rect.setHeight(int(rect.height() * ar/imar)) p.drawImage(rect, self.image) else: p.drawImage(QtCore.QPointF(), self.image) #p.drawPixmap(self.rect(), self.pixmap) p.end() if HAVE_OPENGL: class RawImageGLWidget(QtOpenGL.QGLWidget): """ Similar to RawImageWidget, but uses a GL widget to do all drawing. Perfomance varies between platforms; see examples/VideoSpeedTest for benchmarking. """ def __init__(self, parent=None, scaled=False): QtOpenGL.QGLWidget.__init__(self, parent=None) self.scaled = scaled self.image = None self.uploaded = False self.smooth = False self.opts = None def setImage(self, img, *args, **kargs): """ img must be ndarray of shape (x,y), (x,y,3), or (x,y,4). Extra arguments are sent to functions.makeARGB """ self.opts = (img, args, kargs) self.image = None self.uploaded = False self.update() def initializeGL(self): self.texture = glGenTextures(1) def uploadTexture(self): glEnable(GL_TEXTURE_2D) glBindTexture(GL_TEXTURE_2D, self.texture) if self.smooth: glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR) glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_LINEAR) else: glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_NEAREST) glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_NEAREST) glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_BORDER) glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_BORDER) #glTexParameteri(GL_TEXTURE_3D, GL_TEXTURE_WRAP_R, GL_CLAMP_TO_BORDER) shape = self.image.shape ### Test texture dimensions first #glTexImage2D(GL_PROXY_TEXTURE_2D, 0, GL_RGBA, shape[0], shape[1], 0, GL_RGBA, GL_UNSIGNED_BYTE, None) #if glGetTexLevelParameteriv(GL_PROXY_TEXTURE_2D, 0, GL_TEXTURE_WIDTH) == 0: #raise Exception("OpenGL failed to create 2D texture (%dx%d); too large for this hardware." % shape[:2]) glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA, shape[0], shape[1], 0, GL_RGBA, GL_UNSIGNED_BYTE, self.image.transpose((1,0,2))) glDisable(GL_TEXTURE_2D) def paintGL(self): if self.image is None: if self.opts is None: return img, args, kwds = self.opts kwds['useRGBA'] = True self.image, alpha = fn.makeARGB(img, *args, **kwds) if not self.uploaded: self.uploadTexture() glViewport(0, 0, self.width(), self.height()) glEnable(GL_TEXTURE_2D) glBindTexture(GL_TEXTURE_2D, self.texture) glColor4f(1,1,1,1) glBegin(GL_QUADS) glTexCoord2f(0,0) glVertex3f(-1,-1,0) glTexCoord2f(1,0) glVertex3f(1, -1, 0) glTexCoord2f(1,1) glVertex3f(1, 1, 0) glTexCoord2f(0,1) glVertex3f(-1, 1, 0) glEnd() glDisable(GL_TEXTURE_3D) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/RemoteGraphicsView.py000066400000000000000000000302001300727121400254220ustar00rootroot00000000000000from ..Qt import QtGui, QtCore, USE_PYSIDE if not USE_PYSIDE: import sip from .. import multiprocess as mp from .GraphicsView import GraphicsView from .. import CONFIG_OPTIONS import numpy as np import mmap, tempfile, ctypes, atexit, sys, random __all__ = ['RemoteGraphicsView'] class RemoteGraphicsView(QtGui.QWidget): """ Replacement for GraphicsView that does all scene management and rendering on a remote process, while displaying on the local widget. GraphicsItems must be created by proxy to the remote process. """ def __init__(self, parent=None, *args, **kwds): """ The keyword arguments 'useOpenGL' and 'backgound', if specified, are passed to the remote GraphicsView.__init__(). All other keyword arguments are passed to multiprocess.QtProcess.__init__(). """ self._img = None self._imgReq = None self._sizeHint = (640,480) ## no clue why this is needed, but it seems to be the default sizeHint for GraphicsView. ## without it, the widget will not compete for space against another GraphicsView. QtGui.QWidget.__init__(self) # separate local keyword arguments from remote. remoteKwds = {} for kwd in ['useOpenGL', 'background']: if kwd in kwds: remoteKwds[kwd] = kwds.pop(kwd) self._proc = mp.QtProcess(**kwds) self.pg = self._proc._import('pyqtgraph') self.pg.setConfigOptions(**CONFIG_OPTIONS) rpgRemote = self._proc._import('pyqtgraph.widgets.RemoteGraphicsView') self._view = rpgRemote.Renderer(*args, **remoteKwds) self._view._setProxyOptions(deferGetattr=True) self.setFocusPolicy(QtCore.Qt.StrongFocus) self.setSizePolicy(QtGui.QSizePolicy.Expanding, QtGui.QSizePolicy.Expanding) self.setMouseTracking(True) self.shm = None shmFileName = self._view.shmFileName() if sys.platform.startswith('win'): self.shmtag = shmFileName else: self.shmFile = open(shmFileName, 'r') self._view.sceneRendered.connect(mp.proxy(self.remoteSceneChanged)) #, callSync='off')) ## Note: we need synchronous signals ## even though there is no return value-- ## this informs the renderer that it is ## safe to begin rendering again. for method in ['scene', 'setCentralItem']: setattr(self, method, getattr(self._view, method)) def resizeEvent(self, ev): ret = QtGui.QWidget.resizeEvent(self, ev) self._view.resize(self.size(), _callSync='off') return ret def sizeHint(self): return QtCore.QSize(*self._sizeHint) def remoteSceneChanged(self, data): w, h, size, newfile = data #self._sizeHint = (whint, hhint) if self.shm is None or self.shm.size != size: if self.shm is not None: self.shm.close() if sys.platform.startswith('win'): self.shmtag = newfile ## on windows, we create a new tag for every resize self.shm = mmap.mmap(-1, size, self.shmtag) ## can't use tmpfile on windows because the file can only be opened once. elif sys.platform == 'darwin': self.shmFile.close() self.shmFile = open(self._view.shmFileName(), 'r') self.shm = mmap.mmap(self.shmFile.fileno(), size, mmap.MAP_SHARED, mmap.PROT_READ) else: self.shm = mmap.mmap(self.shmFile.fileno(), size, mmap.MAP_SHARED, mmap.PROT_READ) self.shm.seek(0) data = self.shm.read(w*h*4) self._img = QtGui.QImage(data, w, h, QtGui.QImage.Format_ARGB32) self._img.data = data # data must be kept alive or PySide 1.2.1 (and probably earlier) will crash. self.update() def paintEvent(self, ev): if self._img is None: return p = QtGui.QPainter(self) p.drawImage(self.rect(), self._img, QtCore.QRect(0, 0, self._img.width(), self._img.height())) p.end() def mousePressEvent(self, ev): self._view.mousePressEvent(int(ev.type()), ev.pos(), ev.globalPos(), int(ev.button()), int(ev.buttons()), int(ev.modifiers()), _callSync='off') ev.accept() return QtGui.QWidget.mousePressEvent(self, ev) def mouseReleaseEvent(self, ev): self._view.mouseReleaseEvent(int(ev.type()), ev.pos(), ev.globalPos(), int(ev.button()), int(ev.buttons()), int(ev.modifiers()), _callSync='off') ev.accept() return QtGui.QWidget.mouseReleaseEvent(self, ev) def mouseMoveEvent(self, ev): self._view.mouseMoveEvent(int(ev.type()), ev.pos(), ev.globalPos(), int(ev.button()), int(ev.buttons()), int(ev.modifiers()), _callSync='off') ev.accept() return QtGui.QWidget.mouseMoveEvent(self, ev) def wheelEvent(self, ev): self._view.wheelEvent(ev.pos(), ev.globalPos(), ev.delta(), int(ev.buttons()), int(ev.modifiers()), int(ev.orientation()), _callSync='off') ev.accept() return QtGui.QWidget.wheelEvent(self, ev) def keyEvent(self, ev): if self._view.keyEvent(int(ev.type()), int(ev.modifiers()), text, autorep, count): ev.accept() return QtGui.QWidget.keyEvent(self, ev) def enterEvent(self, ev): self._view.enterEvent(int(ev.type()), _callSync='off') return QtGui.QWidget.enterEvent(self, ev) def leaveEvent(self, ev): self._view.leaveEvent(int(ev.type()), _callSync='off') return QtGui.QWidget.leaveEvent(self, ev) def remoteProcess(self): """Return the remote process handle. (see multiprocess.remoteproxy.RemoteEventHandler)""" return self._proc def close(self): """Close the remote process. After this call, the widget will no longer be updated.""" self._proc.close() class Renderer(GraphicsView): ## Created by the remote process to handle render requests sceneRendered = QtCore.Signal(object) def __init__(self, *args, **kwds): ## Create shared memory for rendered image #pg.dbg(namespace={'r': self}) if sys.platform.startswith('win'): self.shmtag = "pyqtgraph_shmem_" + ''.join([chr((random.getrandbits(20)%25) + 97) for i in range(20)]) self.shm = mmap.mmap(-1, mmap.PAGESIZE, self.shmtag) # use anonymous mmap on windows else: self.shmFile = tempfile.NamedTemporaryFile(prefix='pyqtgraph_shmem_') self.shmFile.write(b'\x00' * (mmap.PAGESIZE+1)) fd = self.shmFile.fileno() self.shm = mmap.mmap(fd, mmap.PAGESIZE, mmap.MAP_SHARED, mmap.PROT_WRITE) atexit.register(self.close) GraphicsView.__init__(self, *args, **kwds) self.scene().changed.connect(self.update) self.img = None self.renderTimer = QtCore.QTimer() self.renderTimer.timeout.connect(self.renderView) self.renderTimer.start(16) def close(self): self.shm.close() if not sys.platform.startswith('win'): self.shmFile.close() def shmFileName(self): if sys.platform.startswith('win'): return self.shmtag else: return self.shmFile.name def update(self): self.img = None return GraphicsView.update(self) def resize(self, size): oldSize = self.size() GraphicsView.resize(self, size) self.resizeEvent(QtGui.QResizeEvent(size, oldSize)) self.update() def renderView(self): if self.img is None: ## make sure shm is large enough and get its address if self.width() == 0 or self.height() == 0: return size = self.width() * self.height() * 4 if size > self.shm.size(): if sys.platform.startswith('win'): ## windows says "WindowsError: [Error 87] the parameter is incorrect" if we try to resize the mmap self.shm.close() ## it also says (sometimes) 'access is denied' if we try to reuse the tag. self.shmtag = "pyqtgraph_shmem_" + ''.join([chr((random.getrandbits(20)%25) + 97) for i in range(20)]) self.shm = mmap.mmap(-1, size, self.shmtag) elif sys.platform == 'darwin': self.shm.close() self.shmFile.close() self.shmFile = tempfile.NamedTemporaryFile(prefix='pyqtgraph_shmem_') self.shmFile.write(b'\x00' * (size + 1)) self.shmFile.flush() self.shm = mmap.mmap(self.shmFile.fileno(), size, mmap.MAP_SHARED, mmap.PROT_WRITE) else: self.shm.resize(size) ## render the scene directly to shared memory if USE_PYSIDE: ch = ctypes.c_char.from_buffer(self.shm, 0) #ch = ctypes.c_char_p(address) self.img = QtGui.QImage(ch, self.width(), self.height(), QtGui.QImage.Format_ARGB32) else: address = ctypes.addressof(ctypes.c_char.from_buffer(self.shm, 0)) # different versions of pyqt have different requirements here.. try: self.img = QtGui.QImage(sip.voidptr(address), self.width(), self.height(), QtGui.QImage.Format_ARGB32) except TypeError: try: self.img = QtGui.QImage(memoryview(buffer(self.shm)), self.width(), self.height(), QtGui.QImage.Format_ARGB32) except TypeError: # Works on PyQt 4.9.6 self.img = QtGui.QImage(address, self.width(), self.height(), QtGui.QImage.Format_ARGB32) self.img.fill(0xffffffff) p = QtGui.QPainter(self.img) self.render(p, self.viewRect(), self.rect()) p.end() self.sceneRendered.emit((self.width(), self.height(), self.shm.size(), self.shmFileName())) def mousePressEvent(self, typ, pos, gpos, btn, btns, mods): typ = QtCore.QEvent.Type(typ) btn = QtCore.Qt.MouseButton(btn) btns = QtCore.Qt.MouseButtons(btns) mods = QtCore.Qt.KeyboardModifiers(mods) return GraphicsView.mousePressEvent(self, QtGui.QMouseEvent(typ, pos, gpos, btn, btns, mods)) def mouseMoveEvent(self, typ, pos, gpos, btn, btns, mods): typ = QtCore.QEvent.Type(typ) btn = QtCore.Qt.MouseButton(btn) btns = QtCore.Qt.MouseButtons(btns) mods = QtCore.Qt.KeyboardModifiers(mods) return GraphicsView.mouseMoveEvent(self, QtGui.QMouseEvent(typ, pos, gpos, btn, btns, mods)) def mouseReleaseEvent(self, typ, pos, gpos, btn, btns, mods): typ = QtCore.QEvent.Type(typ) btn = QtCore.Qt.MouseButton(btn) btns = QtCore.Qt.MouseButtons(btns) mods = QtCore.Qt.KeyboardModifiers(mods) return GraphicsView.mouseReleaseEvent(self, QtGui.QMouseEvent(typ, pos, gpos, btn, btns, mods)) def wheelEvent(self, pos, gpos, d, btns, mods, ori): btns = QtCore.Qt.MouseButtons(btns) mods = QtCore.Qt.KeyboardModifiers(mods) ori = (None, QtCore.Qt.Horizontal, QtCore.Qt.Vertical)[ori] return GraphicsView.wheelEvent(self, QtGui.QWheelEvent(pos, gpos, d, btns, mods, ori)) def keyEvent(self, typ, mods, text, autorep, count): typ = QtCore.QEvent.Type(typ) mods = QtCore.Qt.KeyboardModifiers(mods) GraphicsView.keyEvent(self, QtGui.QKeyEvent(typ, mods, text, autorep, count)) return ev.accepted() def enterEvent(self, typ): ev = QtCore.QEvent(QtCore.QEvent.Type(typ)) return GraphicsView.enterEvent(self, ev) def leaveEvent(self, typ): ev = QtCore.QEvent(QtCore.QEvent.Type(typ)) return GraphicsView.leaveEvent(self, ev) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/ScatterPlotWidget.py000066400000000000000000000203701300727121400252720ustar00rootroot00000000000000from ..Qt import QtGui, QtCore from .PlotWidget import PlotWidget from .DataFilterWidget import DataFilterParameter from .ColorMapWidget import ColorMapParameter from .. import parametertree as ptree from .. import functions as fn from .. import getConfigOption from ..graphicsItems.TextItem import TextItem import numpy as np from ..pgcollections import OrderedDict __all__ = ['ScatterPlotWidget'] class ScatterPlotWidget(QtGui.QSplitter): """ This is a high-level widget for exploring relationships in tabular data. Given a multi-column record array, the widget displays a scatter plot of a specific subset of the data. Includes controls for selecting the columns to plot, filtering data, and determining symbol color and shape. The widget consists of four components: 1) A list of column names from which the user may select 1 or 2 columns to plot. If one column is selected, the data for that column will be plotted in a histogram-like manner by using :func:`pseudoScatter() `. If two columns are selected, then the scatter plot will be generated with x determined by the first column that was selected and y by the second. 2) A DataFilter that allows the user to select a subset of the data by specifying multiple selection criteria. 3) A ColorMap that allows the user to determine how points are colored by specifying multiple criteria. 4) A PlotWidget for displaying the data. """ def __init__(self, parent=None): QtGui.QSplitter.__init__(self, QtCore.Qt.Horizontal) self.ctrlPanel = QtGui.QSplitter(QtCore.Qt.Vertical) self.addWidget(self.ctrlPanel) self.fieldList = QtGui.QListWidget() self.fieldList.setSelectionMode(self.fieldList.ExtendedSelection) self.ptree = ptree.ParameterTree(showHeader=False) self.filter = DataFilterParameter() self.colorMap = ColorMapParameter() self.params = ptree.Parameter.create(name='params', type='group', children=[self.filter, self.colorMap]) self.ptree.setParameters(self.params, showTop=False) self.plot = PlotWidget() self.ctrlPanel.addWidget(self.fieldList) self.ctrlPanel.addWidget(self.ptree) self.addWidget(self.plot) bg = fn.mkColor(getConfigOption('background')) bg.setAlpha(150) self.filterText = TextItem(border=getConfigOption('foreground'), color=bg) self.filterText.setPos(60,20) self.filterText.setParentItem(self.plot.plotItem) self.data = None self.mouseOverField = None self.scatterPlot = None self.style = dict(pen=None, symbol='o') self.fieldList.itemSelectionChanged.connect(self.fieldSelectionChanged) self.filter.sigFilterChanged.connect(self.filterChanged) self.colorMap.sigColorMapChanged.connect(self.updatePlot) def setFields(self, fields, mouseOverField=None): """ Set the list of field names/units to be processed. The format of *fields* is the same as used by :func:`ColorMapWidget.setFields ` """ self.fields = OrderedDict(fields) self.mouseOverField = mouseOverField self.fieldList.clear() for f,opts in fields: item = QtGui.QListWidgetItem(f) item.opts = opts item = self.fieldList.addItem(item) self.filter.setFields(fields) self.colorMap.setFields(fields) def setData(self, data): """ Set the data to be processed and displayed. Argument must be a numpy record array. """ self.data = data self.filtered = None self.updatePlot() def fieldSelectionChanged(self): sel = self.fieldList.selectedItems() if len(sel) > 2: self.fieldList.blockSignals(True) try: for item in sel[1:-1]: item.setSelected(False) finally: self.fieldList.blockSignals(False) self.updatePlot() def filterChanged(self, f): self.filtered = None self.updatePlot() desc = self.filter.describe() if len(desc) == 0: self.filterText.setVisible(False) else: self.filterText.setText('\n'.join(desc)) self.filterText.setVisible(True) def updatePlot(self): self.plot.clear() if self.data is None: return if self.filtered is None: self.filtered = self.filter.filterData(self.data) data = self.filtered if len(data) == 0: return colors = np.array([fn.mkBrush(*x) for x in self.colorMap.map(data)]) style = self.style.copy() ## Look up selected columns and units sel = list([str(item.text()) for item in self.fieldList.selectedItems()]) units = list([item.opts.get('units', '') for item in self.fieldList.selectedItems()]) if len(sel) == 0: self.plot.setTitle('') return if len(sel) == 1: self.plot.setLabels(left=('N', ''), bottom=(sel[0], units[0]), title='') if len(data) == 0: return #x = data[sel[0]] #y = None xy = [data[sel[0]], None] elif len(sel) == 2: self.plot.setLabels(left=(sel[1],units[1]), bottom=(sel[0],units[0])) if len(data) == 0: return xy = [data[sel[0]], data[sel[1]]] #xydata = [] #for ax in [0,1]: #d = data[sel[ax]] ### scatter catecorical values just a bit so they show up better in the scatter plot. ##if sel[ax] in ['MorphologyBSMean', 'MorphologyTDMean', 'FIType']: ##d += np.random.normal(size=len(cells), scale=0.1) #xydata.append(d) #x,y = xydata ## convert enum-type fields to float, set axis labels enum = [False, False] for i in [0,1]: axis = self.plot.getAxis(['bottom', 'left'][i]) if xy[i] is not None and (self.fields[sel[i]].get('mode', None) == 'enum' or xy[i].dtype.kind in ('S', 'O')): vals = self.fields[sel[i]].get('values', list(set(xy[i]))) xy[i] = np.array([vals.index(x) if x in vals else len(vals) for x in xy[i]], dtype=float) axis.setTicks([list(enumerate(vals))]) enum[i] = True else: axis.setTicks(None) # reset to automatic ticking ## mask out any nan values mask = np.ones(len(xy[0]), dtype=bool) if xy[0].dtype.kind == 'f': mask &= ~np.isnan(xy[0]) if xy[1] is not None and xy[1].dtype.kind == 'f': mask &= ~np.isnan(xy[1]) xy[0] = xy[0][mask] style['symbolBrush'] = colors[mask] ## Scatter y-values for a histogram-like appearance if xy[1] is None: ## column scatter plot xy[1] = fn.pseudoScatter(xy[0]) else: ## beeswarm plots xy[1] = xy[1][mask] for ax in [0,1]: if not enum[ax]: continue imax = int(xy[ax].max()) if len(xy[ax]) > 0 else 0 for i in range(imax+1): keymask = xy[ax] == i scatter = fn.pseudoScatter(xy[1-ax][keymask], bidir=True) if len(scatter) == 0: continue smax = np.abs(scatter).max() if smax != 0: scatter *= 0.2 / smax xy[ax][keymask] += scatter if self.scatterPlot is not None: try: self.scatterPlot.sigPointsClicked.disconnect(self.plotClicked) except: pass self.scatterPlot = self.plot.plot(xy[0], xy[1], data=data[mask], **style) self.scatterPlot.sigPointsClicked.connect(self.plotClicked) def plotClicked(self, plot, points): pass pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/SpinBox.py000066400000000000000000000466431300727121400232570ustar00rootroot00000000000000# -*- coding: utf-8 -*- from ..Qt import QtGui, QtCore from ..python2_3 import asUnicode from ..SignalProxy import SignalProxy from .. import functions as fn from math import log from decimal import Decimal as D ## Use decimal to avoid accumulating floating-point errors from decimal import * import weakref __all__ = ['SpinBox'] class SpinBox(QtGui.QAbstractSpinBox): """ **Bases:** QtGui.QAbstractSpinBox QSpinBox widget on steroids. Allows selection of numerical value, with extra features: - SI prefix notation (eg, automatically display "300 mV" instead of "0.003 V") - Float values with linear and decimal stepping (1-9, 10-90, 100-900, etc.) - Option for unbounded values - Delayed signals (allows multiple rapid changes with only one change signal) ============================= ============================================== **Signals:** valueChanged(value) Same as QSpinBox; emitted every time the value has changed. sigValueChanged(self) Emitted when value has changed, but also combines multiple rapid changes into one signal (eg, when rolling the mouse wheel). sigValueChanging(self, value) Emitted immediately for all value changes. ============================= ============================================== """ ## There's a PyQt bug that leaks a reference to the ## QLineEdit returned from QAbstractSpinBox.lineEdit() ## This makes it possible to crash the entire program ## by making accesses to the LineEdit after the spinBox has been deleted. ## I have no idea how to get around this.. valueChanged = QtCore.Signal(object) # (value) for compatibility with QSpinBox sigValueChanged = QtCore.Signal(object) # (self) sigValueChanging = QtCore.Signal(object, object) # (self, value) sent immediately; no delay. def __init__(self, parent=None, value=0.0, **kwargs): """ ============== ======================================================================== **Arguments:** parent Sets the parent widget for this SpinBox (optional). Default is None. value (float/int) initial value. Default is 0.0. bounds (min,max) Minimum and maximum values allowed in the SpinBox. Either may be None to leave the value unbounded. By default, values are unbounded. suffix (str) suffix (units) to display after the numerical value. By default, suffix is an empty str. siPrefix (bool) If True, then an SI prefix is automatically prepended to the units and the value is scaled accordingly. For example, if value=0.003 and suffix='V', then the SpinBox will display "300 mV" (but a call to SpinBox.value will still return 0.003). Default is False. step (float) The size of a single step. This is used when clicking the up/ down arrows, when rolling the mouse wheel, or when pressing keyboard arrows while the widget has keyboard focus. Note that the interpretation of this value is different when specifying the 'dec' argument. Default is 0.01. dec (bool) If True, then the step value will be adjusted to match the current size of the variable (for example, a value of 15 might step in increments of 1 whereas a value of 1500 would step in increments of 100). In this case, the 'step' argument is interpreted *relative* to the current value. The most common 'step' values when dec=True are 0.1, 0.2, 0.5, and 1.0. Default is False. minStep (float) When dec=True, this specifies the minimum allowable step size. int (bool) if True, the value is forced to integer type. Default is False decimals (int) Number of decimal values to display. Default is 2. ============== ======================================================================== """ QtGui.QAbstractSpinBox.__init__(self, parent) self.lastValEmitted = None self.lastText = '' self.textValid = True ## If false, we draw a red border self.setMinimumWidth(0) self.setMaximumHeight(20) self.setSizePolicy(QtGui.QSizePolicy.Expanding, QtGui.QSizePolicy.Preferred) self.opts = { 'bounds': [None, None], ## Log scaling options #### Log mode is no longer supported. #'step': 0.1, #'minStep': 0.001, #'log': True, #'dec': False, ## decimal scaling option - example #'step': 0.1, #'minStep': .001, #'log': False, #'dec': True, ## normal arithmetic step 'step': D('0.01'), ## if 'dec' is false, the spinBox steps by 'step' every time ## if 'dec' is True, the step size is relative to the value ## 'step' needs to be an integral divisor of ten, ie 'step'*n=10 for some integer value of n (but only if dec is True) 'log': False, 'dec': False, ## if true, does decimal stepping. ie from 1-10 it steps by 'step', from 10 to 100 it steps by 10*'step', etc. ## if true, minStep must be set in order to cross zero. 'int': False, ## Set True to force value to be integer 'suffix': '', 'siPrefix': False, ## Set to True to display numbers with SI prefix (ie, 100pA instead of 1e-10A) 'delay': 0.3, ## delay sending wheel update signals for 300ms 'delayUntilEditFinished': True, ## do not send signals until text editing has finished 'decimals': 3, } self.decOpts = ['step', 'minStep'] self.val = D(asUnicode(value)) ## Value is precise decimal. Ordinary math not allowed. self.updateText() self.skipValidate = False self.setCorrectionMode(self.CorrectToPreviousValue) self.setKeyboardTracking(False) self.setOpts(**kwargs) self.editingFinished.connect(self.editingFinishedEvent) self.proxy = SignalProxy(self.sigValueChanging, slot=self.delayedChange, delay=self.opts['delay']) def event(self, ev): ret = QtGui.QAbstractSpinBox.event(self, ev) if ev.type() == QtCore.QEvent.KeyPress and ev.key() == QtCore.Qt.Key_Return: ret = True ## For some reason, spinbox pretends to ignore return key press return ret ##lots of config options, just gonna stuff 'em all in here rather than do the get/set crap. def setOpts(self, **opts): """ Changes the behavior of the SpinBox. Accepts most of the arguments allowed in :func:`__init__ `. """ #print opts for k in opts: if k == 'bounds': self.setMinimum(opts[k][0], update=False) self.setMaximum(opts[k][1], update=False) elif k == 'min': self.setMinimum(opts[k], update=False) elif k == 'max': self.setMaximum(opts[k], update=False) elif k in ['step', 'minStep']: self.opts[k] = D(asUnicode(opts[k])) elif k == 'value': pass ## don't set value until bounds have been set elif k in self.opts: self.opts[k] = opts[k] else: raise TypeError("Invalid keyword argument '%s'." % k) if 'value' in opts: self.setValue(opts['value']) ## If bounds have changed, update value to match if 'bounds' in opts and 'value' not in opts: self.setValue() ## sanity checks: if self.opts['int']: if 'step' in opts: step = opts['step'] ## not necessary.. #if int(step) != step: #raise Exception('Integer SpinBox must have integer step size.') else: self.opts['step'] = int(self.opts['step']) if 'minStep' in opts: step = opts['minStep'] if int(step) != step: raise Exception('Integer SpinBox must have integer minStep size.') else: ms = int(self.opts.get('minStep', 1)) if ms < 1: ms = 1 self.opts['minStep'] = ms if 'delay' in opts: self.proxy.setDelay(opts['delay']) self.updateText() def setMaximum(self, m, update=True): """Set the maximum allowed value (or None for no limit)""" if m is not None: m = D(asUnicode(m)) self.opts['bounds'][1] = m if update: self.setValue() def setMinimum(self, m, update=True): """Set the minimum allowed value (or None for no limit)""" if m is not None: m = D(asUnicode(m)) self.opts['bounds'][0] = m if update: self.setValue() def setPrefix(self, p): """Set a string prefix. """ self.setOpts(prefix=p) def setRange(self, r0, r1): """Set the upper and lower limits for values in the spinbox. """ self.setOpts(bounds = [r0,r1]) def setProperty(self, prop, val): ## for QSpinBox compatibility if prop == 'value': #if type(val) is QtCore.QVariant: #val = val.toDouble()[0] self.setValue(val) else: print("Warning: SpinBox.setProperty('%s', ..) not supported." % prop) def setSuffix(self, suf): """Set the string suffix appended to the spinbox text. """ self.setOpts(suffix=suf) def setSingleStep(self, step): """Set the step size used when responding to the mouse wheel, arrow buttons, or arrow keys. """ self.setOpts(step=step) def setDecimals(self, decimals): """Set the number of decimals to be displayed when formatting numeric values. """ self.setOpts(decimals=decimals) def selectNumber(self): """ Select the numerical portion of the text to allow quick editing by the user. """ le = self.lineEdit() text = asUnicode(le.text()) if self.opts['suffix'] == '': le.setSelection(0, len(text)) else: try: index = text.index(' ') except ValueError: return le.setSelection(0, index) def value(self): """ Return the value of this SpinBox. """ if self.opts['int']: return int(self.val) else: return float(self.val) def setValue(self, value=None, update=True, delaySignal=False): """ Set the value of this spin. If the value is out of bounds, it will be clipped to the nearest boundary. If the spin is integer type, the value will be coerced to int. Returns the actual value set. If value is None, then the current value is used (this is for resetting the value after bounds, etc. have changed) """ if value is None: value = self.value() bounds = self.opts['bounds'] if bounds[0] is not None and value < bounds[0]: value = bounds[0] if bounds[1] is not None and value > bounds[1]: value = bounds[1] if self.opts['int']: value = int(value) value = D(asUnicode(value)) if value == self.val: return prev = self.val self.val = value if update: self.updateText(prev=prev) self.sigValueChanging.emit(self, float(self.val)) ## change will be emitted in 300ms if there are no subsequent changes. if not delaySignal: self.emitChanged() return value def emitChanged(self): self.lastValEmitted = self.val self.valueChanged.emit(float(self.val)) self.sigValueChanged.emit(self) def delayedChange(self): try: if self.val != self.lastValEmitted: self.emitChanged() except RuntimeError: pass ## This can happen if we try to handle a delayed signal after someone else has already deleted the underlying C++ object. def widgetGroupInterface(self): return (self.valueChanged, SpinBox.value, SpinBox.setValue) def sizeHint(self): return QtCore.QSize(120, 0) def stepEnabled(self): return self.StepUpEnabled | self.StepDownEnabled #def fixup(self, *args): #print "fixup:", args def stepBy(self, n): n = D(int(n)) ## n must be integral number of steps. s = [D(-1), D(1)][n >= 0] ## determine sign of step val = self.val for i in range(int(abs(n))): if self.opts['log']: raise Exception("Log mode no longer supported.") # step = abs(val) * self.opts['step'] # if 'minStep' in self.opts: # step = max(step, self.opts['minStep']) # val += step * s if self.opts['dec']: if val == 0: step = self.opts['minStep'] exp = None else: vs = [D(-1), D(1)][val >= 0] #exp = D(int(abs(val*(D('1.01')**(s*vs))).log10())) fudge = D('1.01')**(s*vs) ## fudge factor. at some places, the step size depends on the step sign. exp = abs(val * fudge).log10().quantize(1, ROUND_FLOOR) step = self.opts['step'] * D(10)**exp if 'minStep' in self.opts: step = max(step, self.opts['minStep']) val += s * step #print "Exp:", exp, "step", step, "val", val else: val += s*self.opts['step'] if 'minStep' in self.opts and abs(val) < self.opts['minStep']: val = D(0) self.setValue(val, delaySignal=True) ## note all steps (arrow buttons, wheel, up/down keys..) emit delayed signals only. def valueInRange(self, value): bounds = self.opts['bounds'] if bounds[0] is not None and value < bounds[0]: return False if bounds[1] is not None and value > bounds[1]: return False if self.opts.get('int', False): if int(value) != value: return False return True def updateText(self, prev=None): # get the number of decimal places to print decimals = self.opts.get('decimals') # temporarily disable validation self.skipValidate = True # add a prefix to the units if requested if self.opts['siPrefix']: # special case: if it's zero use the previous prefix if self.val == 0 and prev is not None: (s, p) = fn.siScale(prev) # NOTE: insert optional format string here? txt = ("%."+str(decimals)+"g %s%s") % (0, p, self.opts['suffix']) else: # NOTE: insert optional format string here as an argument? txt = fn.siFormat(float(self.val), precision=decimals, suffix=self.opts['suffix']) # otherwise, format the string manually else: # NOTE: insert optional format string here? txt = ('%.'+str(decimals)+'g%s') % (self.val , self.opts['suffix']) # actually set the text self.lineEdit().setText(txt) self.lastText = txt # re-enable the validation self.skipValidate = False def validate(self, strn, pos): if self.skipValidate: ret = QtGui.QValidator.Acceptable else: try: ## first make sure we didn't mess with the suffix suff = self.opts.get('suffix', '') if len(suff) > 0 and asUnicode(strn)[-len(suff):] != suff: ret = QtGui.QValidator.Invalid ## next see if we actually have an interpretable value else: val = self.interpret() if val is False: ret = QtGui.QValidator.Intermediate else: if self.valueInRange(val): if not self.opts['delayUntilEditFinished']: self.setValue(val, update=False) ret = QtGui.QValidator.Acceptable else: ret = QtGui.QValidator.Intermediate except: ret = QtGui.QValidator.Intermediate ## draw / clear border if ret == QtGui.QValidator.Intermediate: self.textValid = False elif ret == QtGui.QValidator.Acceptable: self.textValid = True ## note: if text is invalid, we don't change the textValid flag ## since the text will be forced to its previous state anyway self.update() ## support 2 different pyqt APIs. Bleh. if hasattr(QtCore, 'QString'): return (ret, pos) else: return (ret, strn, pos) def paintEvent(self, ev): QtGui.QAbstractSpinBox.paintEvent(self, ev) ## draw red border if text is invalid if not self.textValid: p = QtGui.QPainter(self) p.setRenderHint(p.Antialiasing) p.setPen(fn.mkPen((200,50,50), width=2)) p.drawRoundedRect(self.rect().adjusted(2, 2, -2, -2), 4, 4) p.end() def interpret(self): """Return value of text. Return False if text is invalid, raise exception if text is intermediate""" strn = self.lineEdit().text() suf = self.opts['suffix'] if len(suf) > 0: if strn[-len(suf):] != suf: return False #raise Exception("Units are invalid.") strn = strn[:-len(suf)] try: val = fn.siEval(strn) except: #sys.excepthook(*sys.exc_info()) #print "invalid" return False #print val return val def editingFinishedEvent(self): """Edit has finished; set value.""" #print "Edit finished." if asUnicode(self.lineEdit().text()) == self.lastText: #print "no text change." return try: val = self.interpret() except: return if val is False: #print "value invalid:", str(self.lineEdit().text()) return if val == self.val: #print "no value change:", val, self.val return self.setValue(val, delaySignal=False) ## allow text update so that values are reformatted pretty-like pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/TableWidget.py000066400000000000000000000433621300727121400240630ustar00rootroot00000000000000# -*- coding: utf-8 -*- import numpy as np from ..Qt import QtGui, QtCore from ..python2_3 import asUnicode, basestring from .. import metaarray __all__ = ['TableWidget'] def _defersort(fn): def defersort(self, *args, **kwds): # may be called recursively; only the first call needs to block sorting setSorting = False if self._sorting is None: self._sorting = self.isSortingEnabled() setSorting = True self.setSortingEnabled(False) try: return fn(self, *args, **kwds) finally: if setSorting: self.setSortingEnabled(self._sorting) self._sorting = None return defersort class TableWidget(QtGui.QTableWidget): """Extends QTableWidget with some useful functions for automatic data handling and copy / export context menu. Can automatically format and display a variety of data types (see :func:`setData() ` for more information. """ def __init__(self, *args, **kwds): """ All positional arguments are passed to QTableWidget.__init__(). ===================== ================================================= **Keyword Arguments** editable (bool) If True, cells in the table can be edited by the user. Default is False. sortable (bool) If True, the table may be soted by clicking on column headers. Note that this also causes rows to appear initially shuffled until a sort column is selected. Default is True. *(added in version 0.9.9)* ===================== ================================================= """ QtGui.QTableWidget.__init__(self, *args) self.itemClass = TableWidgetItem self.setVerticalScrollMode(self.ScrollPerPixel) self.setSelectionMode(QtGui.QAbstractItemView.ContiguousSelection) self.setSizePolicy(QtGui.QSizePolicy.Preferred, QtGui.QSizePolicy.Preferred) self.clear() kwds.setdefault('sortable', True) kwds.setdefault('editable', False) self.setEditable(kwds.pop('editable')) self.setSortingEnabled(kwds.pop('sortable')) if len(kwds) > 0: raise TypeError("Invalid keyword arguments '%s'" % kwds.keys()) self._sorting = None # used when temporarily disabling sorting self._formats = {None: None} # stores per-column formats and entire table format self.sortModes = {} # stores per-column sort mode self.itemChanged.connect(self.handleItemChanged) self.contextMenu = QtGui.QMenu() self.contextMenu.addAction('Copy Selection').triggered.connect(self.copySel) self.contextMenu.addAction('Copy All').triggered.connect(self.copyAll) self.contextMenu.addAction('Save Selection').triggered.connect(self.saveSel) self.contextMenu.addAction('Save All').triggered.connect(self.saveAll) def clear(self): """Clear all contents from the table.""" QtGui.QTableWidget.clear(self) self.verticalHeadersSet = False self.horizontalHeadersSet = False self.items = [] self.setRowCount(0) self.setColumnCount(0) self.sortModes = {} def setData(self, data): """Set the data displayed in the table. Allowed formats are: * numpy arrays * numpy record arrays * metaarrays * list-of-lists [[1,2,3], [4,5,6]] * dict-of-lists {'x': [1,2,3], 'y': [4,5,6]} * list-of-dicts [{'x': 1, 'y': 4}, {'x': 2, 'y': 5}, ...] """ self.clear() self.appendData(data) self.resizeColumnsToContents() @_defersort def appendData(self, data): """ Add new rows to the table. See :func:`setData() ` for accepted data types. """ startRow = self.rowCount() fn0, header0 = self.iteratorFn(data) if fn0 is None: self.clear() return it0 = fn0(data) try: first = next(it0) except StopIteration: return fn1, header1 = self.iteratorFn(first) if fn1 is None: self.clear() return firstVals = [x for x in fn1(first)] self.setColumnCount(len(firstVals)) if not self.verticalHeadersSet and header0 is not None: labels = [self.verticalHeaderItem(i).text() for i in range(self.rowCount())] self.setRowCount(startRow + len(header0)) self.setVerticalHeaderLabels(labels + header0) self.verticalHeadersSet = True if not self.horizontalHeadersSet and header1 is not None: self.setHorizontalHeaderLabels(header1) self.horizontalHeadersSet = True i = startRow self.setRow(i, firstVals) for row in it0: i += 1 self.setRow(i, [x for x in fn1(row)]) if self._sorting and self.horizontalHeader().sortIndicatorSection() >= self.columnCount(): self.sortByColumn(0, QtCore.Qt.AscendingOrder) def setEditable(self, editable=True): self.editable = editable for item in self.items: item.setEditable(editable) def setFormat(self, format, column=None): """ Specify the default text formatting for the entire table, or for a single column if *column* is specified. If a string is specified, it is used as a format string for converting float values (and all other types are converted using str). If a function is specified, it will be called with the item as its only argument and must return a string. Setting format = None causes the default formatter to be used instead. Added in version 0.9.9. """ if format is not None and not isinstance(format, basestring) and not callable(format): raise ValueError("Format argument must string, callable, or None. (got %s)" % format) self._formats[column] = format if column is None: # update format of all items that do not have a column format # specified for c in range(self.columnCount()): if self._formats.get(c, None) is None: for r in range(self.rowCount()): item = self.item(r, c) if item is None: continue item.setFormat(format) else: # set all items in the column to use this format, or the default # table format if None was specified. if format is None: format = self._formats[None] for r in range(self.rowCount()): item = self.item(r, column) if item is None: continue item.setFormat(format) def iteratorFn(self, data): ## Return 1) a function that will provide an iterator for data and 2) a list of header strings if isinstance(data, list) or isinstance(data, tuple): return lambda d: d.__iter__(), None elif isinstance(data, dict): return lambda d: iter(d.values()), list(map(asUnicode, data.keys())) elif (hasattr(data, 'implements') and data.implements('MetaArray')): if data.axisHasColumns(0): header = [asUnicode(data.columnName(0, i)) for i in range(data.shape[0])] elif data.axisHasValues(0): header = list(map(asUnicode, data.xvals(0))) else: header = None return self.iterFirstAxis, header elif isinstance(data, np.ndarray): return self.iterFirstAxis, None elif isinstance(data, np.void): return self.iterate, list(map(asUnicode, data.dtype.names)) elif data is None: return (None,None) else: msg = "Don't know how to iterate over data type: {!s}".format(type(data)) raise TypeError(msg) def iterFirstAxis(self, data): for i in range(data.shape[0]): yield data[i] def iterate(self, data): # for numpy.void, which can be iterated but mysteriously # has no __iter__ (??) for x in data: yield x def appendRow(self, data): self.appendData([data]) @_defersort def addRow(self, vals): row = self.rowCount() self.setRowCount(row + 1) self.setRow(row, vals) @_defersort def setRow(self, row, vals): if row > self.rowCount() - 1: self.setRowCount(row + 1) for col in range(len(vals)): val = vals[col] item = self.itemClass(val, row) item.setEditable(self.editable) sortMode = self.sortModes.get(col, None) if sortMode is not None: item.setSortMode(sortMode) format = self._formats.get(col, self._formats[None]) item.setFormat(format) self.items.append(item) self.setItem(row, col, item) item.setValue(val) # Required--the text-change callback is invoked # when we call setItem. def setSortMode(self, column, mode): """ Set the mode used to sort *column*. ============== ======================================================== **Sort Modes** value Compares item.value if available; falls back to text comparison. text Compares item.text() index Compares by the order in which items were inserted. ============== ======================================================== Added in version 0.9.9 """ for r in range(self.rowCount()): item = self.item(r, column) if hasattr(item, 'setSortMode'): item.setSortMode(mode) self.sortModes[column] = mode def sizeHint(self): # based on http://stackoverflow.com/a/7195443/54056 width = sum(self.columnWidth(i) for i in range(self.columnCount())) width += self.verticalHeader().sizeHint().width() width += self.verticalScrollBar().sizeHint().width() width += self.frameWidth() * 2 height = sum(self.rowHeight(i) for i in range(self.rowCount())) height += self.verticalHeader().sizeHint().height() height += self.horizontalScrollBar().sizeHint().height() return QtCore.QSize(width, height) def serialize(self, useSelection=False): """Convert entire table (or just selected area) into tab-separated text values""" if useSelection: selection = self.selectedRanges()[0] rows = list(range(selection.topRow(), selection.bottomRow() + 1)) columns = list(range(selection.leftColumn(), selection.rightColumn() + 1)) else: rows = list(range(self.rowCount())) columns = list(range(self.columnCount())) data = [] if self.horizontalHeadersSet: row = [] if self.verticalHeadersSet: row.append(asUnicode('')) for c in columns: row.append(asUnicode(self.horizontalHeaderItem(c).text())) data.append(row) for r in rows: row = [] if self.verticalHeadersSet: row.append(asUnicode(self.verticalHeaderItem(r).text())) for c in columns: item = self.item(r, c) if item is not None: row.append(asUnicode(item.value)) else: row.append(asUnicode('')) data.append(row) s = '' for row in data: s += ('\t'.join(row) + '\n') return s def copySel(self): """Copy selected data to clipboard.""" QtGui.QApplication.clipboard().setText(self.serialize(useSelection=True)) def copyAll(self): """Copy all data to clipboard.""" QtGui.QApplication.clipboard().setText(self.serialize(useSelection=False)) def saveSel(self): """Save selected data to file.""" self.save(self.serialize(useSelection=True)) def saveAll(self): """Save all data to file.""" self.save(self.serialize(useSelection=False)) def save(self, data): fileName = QtGui.QFileDialog.getSaveFileName(self, "Save As..", "", "Tab-separated values (*.tsv)") if fileName == '': return open(fileName, 'w').write(data) def contextMenuEvent(self, ev): self.contextMenu.popup(ev.globalPos()) def keyPressEvent(self, ev): if ev.key() == QtCore.Qt.Key_C and ev.modifiers() == QtCore.Qt.ControlModifier: ev.accept() self.copySel() else: QtGui.QTableWidget.keyPressEvent(self, ev) def handleItemChanged(self, item): item.itemChanged() class TableWidgetItem(QtGui.QTableWidgetItem): def __init__(self, val, index, format=None): QtGui.QTableWidgetItem.__init__(self, '') self._blockValueChange = False self._format = None self._defaultFormat = '%0.3g' self.sortMode = 'value' self.index = index flags = QtCore.Qt.ItemIsSelectable | QtCore.Qt.ItemIsEnabled self.setFlags(flags) self.setValue(val) self.setFormat(format) def setEditable(self, editable): """ Set whether this item is user-editable. """ if editable: self.setFlags(self.flags() | QtCore.Qt.ItemIsEditable) else: self.setFlags(self.flags() & ~QtCore.Qt.ItemIsEditable) def setSortMode(self, mode): """ Set the mode used to sort this item against others in its column. ============== ======================================================== **Sort Modes** value Compares item.value if available; falls back to text comparison. text Compares item.text() index Compares by the order in which items were inserted. ============== ======================================================== """ modes = ('value', 'text', 'index', None) if mode not in modes: raise ValueError('Sort mode must be one of %s' % str(modes)) self.sortMode = mode def setFormat(self, fmt): """Define the conversion from item value to displayed text. If a string is specified, it is used as a format string for converting float values (and all other types are converted using str). If a function is specified, it will be called with the item as its only argument and must return a string. Added in version 0.9.9. """ if fmt is not None and not isinstance(fmt, basestring) and not callable(fmt): raise ValueError("Format argument must string, callable, or None. (got %s)" % fmt) self._format = fmt self._updateText() def _updateText(self): self._blockValueChange = True try: self._text = self.format() self.setText(self._text) finally: self._blockValueChange = False def setValue(self, value): self.value = value self._updateText() def itemChanged(self): """Called when the data of this item has changed.""" if self.text() != self._text: self.textChanged() def textChanged(self): """Called when this item's text has changed for any reason.""" self._text = self.text() if self._blockValueChange: # text change was result of value or format change; do not # propagate. return try: self.value = type(self.value)(self.text()) except ValueError: self.value = str(self.text()) def format(self): if callable(self._format): return self._format(self) if isinstance(self.value, (float, np.floating)): if self._format is None: return self._defaultFormat % self.value else: return self._format % self.value else: return asUnicode(self.value) def __lt__(self, other): if self.sortMode == 'index' and hasattr(other, 'index'): return self.index < other.index if self.sortMode == 'value' and hasattr(other, 'value'): return self.value < other.value else: return self.text() < other.text() if __name__ == '__main__': app = QtGui.QApplication([]) win = QtGui.QMainWindow() t = TableWidget() win.setCentralWidget(t) win.resize(800,600) win.show() ll = [[1,2,3,4,5]] * 20 ld = [{'x': 1, 'y': 2, 'z': 3}] * 20 dl = {'x': list(range(20)), 'y': list(range(20)), 'z': list(range(20))} a = np.ones((20, 5)) ra = np.ones((20,), dtype=[('x', int), ('y', int), ('z', int)]) t.setData(ll) ma = metaarray.MetaArray(np.ones((20, 3)), info=[ {'values': np.linspace(1, 5, 20)}, {'cols': [ {'name': 'x'}, {'name': 'y'}, {'name': 'z'}, ]} ]) t.setData(ma) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/TreeWidget.py000066400000000000000000000240621300727121400237270ustar00rootroot00000000000000# -*- coding: utf-8 -*- from weakref import * from ..Qt import QtGui, QtCore from ..python2_3 import xrange __all__ = ['TreeWidget', 'TreeWidgetItem'] class TreeWidget(QtGui.QTreeWidget): """Extends QTreeWidget to allow internal drag/drop with widgets in the tree. Also maintains the expanded state of subtrees as they are moved. This class demonstrates the absurd lengths one must go to to make drag/drop work.""" sigItemMoved = QtCore.Signal(object, object, object) # (item, parent, index) def __init__(self, parent=None): QtGui.QTreeWidget.__init__(self, parent) #self.itemWidgets = WeakKeyDictionary() self.setAcceptDrops(True) self.setDragEnabled(True) self.setEditTriggers(QtGui.QAbstractItemView.EditKeyPressed|QtGui.QAbstractItemView.SelectedClicked) self.placeholders = [] self.childNestingLimit = None def setItemWidget(self, item, col, wid): """ Overrides QTreeWidget.setItemWidget such that widgets are added inside an invisible wrapper widget. This makes it possible to move the item in and out of the tree without its widgets being automatically deleted. """ w = QtGui.QWidget() ## foster parent / surrogate child widget l = QtGui.QVBoxLayout() l.setContentsMargins(0,0,0,0) w.setLayout(l) w.setSizePolicy(wid.sizePolicy()) w.setMinimumHeight(wid.minimumHeight()) w.setMinimumWidth(wid.minimumWidth()) l.addWidget(wid) w.realChild = wid self.placeholders.append(w) QtGui.QTreeWidget.setItemWidget(self, item, col, w) def itemWidget(self, item, col): w = QtGui.QTreeWidget.itemWidget(self, item, col) if w is not None: w = w.realChild return w def dropMimeData(self, parent, index, data, action): item = self.currentItem() p = parent #print "drop", item, "->", parent, index while True: if p is None: break if p is item: return False #raise Exception("Can not move item into itself.") p = p.parent() if not self.itemMoving(item, parent, index): return False currentParent = item.parent() if currentParent is None: currentParent = self.invisibleRootItem() if parent is None: parent = self.invisibleRootItem() if currentParent is parent and index > parent.indexOfChild(item): index -= 1 self.prepareMove(item) currentParent.removeChild(item) #print " insert child to index", index parent.insertChild(index, item) ## index will not be correct self.setCurrentItem(item) self.recoverMove(item) #self.emit(QtCore.SIGNAL('itemMoved'), item, parent, index) self.sigItemMoved.emit(item, parent, index) return True def itemMoving(self, item, parent, index): """Called when item has been dropped elsewhere in the tree. Return True to accept the move, False to reject.""" return True def prepareMove(self, item): item.__widgets = [] item.__expanded = item.isExpanded() for i in range(self.columnCount()): w = self.itemWidget(item, i) item.__widgets.append(w) if w is None: continue w.setParent(None) for i in range(item.childCount()): self.prepareMove(item.child(i)) def recoverMove(self, item): for i in range(self.columnCount()): w = item.__widgets[i] if w is None: continue self.setItemWidget(item, i, w) for i in range(item.childCount()): self.recoverMove(item.child(i)) item.setExpanded(False) ## Items do not re-expand correctly unless they are collapsed first. QtGui.QApplication.instance().processEvents() item.setExpanded(item.__expanded) def collapseTree(self, item): item.setExpanded(False) for i in range(item.childCount()): self.collapseTree(item.child(i)) def removeTopLevelItem(self, item): for i in range(self.topLevelItemCount()): if self.topLevelItem(i) is item: self.takeTopLevelItem(i) return raise Exception("Item '%s' not in top-level items." % str(item)) def listAllItems(self, item=None): items = [] if item != None: items.append(item) else: item = self.invisibleRootItem() for cindex in range(item.childCount()): foundItems = self.listAllItems(item=item.child(cindex)) for f in foundItems: items.append(f) return items def dropEvent(self, ev): QtGui.QTreeWidget.dropEvent(self, ev) self.updateDropFlags() def updateDropFlags(self): ### intended to put a limit on how deep nests of children can go. ### self.childNestingLimit is upheld when moving items without children, but if the item being moved has children/grandchildren, the children/grandchildren ### can end up over the childNestingLimit. if self.childNestingLimit == None: pass # enable drops in all items (but only if there are drops that aren't enabled? for performance...) else: items = self.listAllItems() for item in items: parentCount = 0 p = item.parent() while p is not None: parentCount += 1 p = p.parent() if parentCount >= self.childNestingLimit: item.setFlags(item.flags() & (~QtCore.Qt.ItemIsDropEnabled)) else: item.setFlags(item.flags() | QtCore.Qt.ItemIsDropEnabled) @staticmethod def informTreeWidgetChange(item): if hasattr(item, 'treeWidgetChanged'): item.treeWidgetChanged() else: for i in xrange(item.childCount()): TreeWidget.informTreeWidgetChange(item.child(i)) def addTopLevelItem(self, item): QtGui.QTreeWidget.addTopLevelItem(self, item) self.informTreeWidgetChange(item) def addTopLevelItems(self, items): QtGui.QTreeWidget.addTopLevelItems(self, items) for item in items: self.informTreeWidgetChange(item) def insertTopLevelItem(self, index, item): QtGui.QTreeWidget.insertTopLevelItem(self, index, item) self.informTreeWidgetChange(item) def insertTopLevelItems(self, index, items): QtGui.QTreeWidget.insertTopLevelItems(self, index, items) for item in items: self.informTreeWidgetChange(item) def takeTopLevelItem(self, index): item = self.topLevelItem(index) if item is not None: self.prepareMove(item) item = QtGui.QTreeWidget.takeTopLevelItem(self, index) self.prepareMove(item) self.informTreeWidgetChange(item) return item def topLevelItems(self): return map(self.topLevelItem, xrange(self.topLevelItemCount())) def clear(self): items = self.topLevelItems() for item in items: self.prepareMove(item) QtGui.QTreeWidget.clear(self) ## Why do we want to do this? It causes RuntimeErrors. #for item in items: #self.informTreeWidgetChange(item) class TreeWidgetItem(QtGui.QTreeWidgetItem): """ TreeWidgetItem that keeps track of its own widgets. Widgets may be added to columns before the item is added to a tree. """ def __init__(self, *args): QtGui.QTreeWidgetItem.__init__(self, *args) self._widgets = {} # col: widget self._tree = None def setChecked(self, column, checked): self.setCheckState(column, QtCore.Qt.Checked if checked else QtCore.Qt.Unchecked) def setWidget(self, column, widget): if column in self._widgets: self.removeWidget(column) self._widgets[column] = widget tree = self.treeWidget() if tree is None: return else: tree.setItemWidget(self, column, widget) def removeWidget(self, column): del self._widgets[column] tree = self.treeWidget() if tree is None: return tree.removeItemWidget(self, column) def treeWidgetChanged(self): tree = self.treeWidget() if self._tree is tree: return self._tree = self.treeWidget() if tree is None: return for col, widget in self._widgets.items(): tree.setItemWidget(self, col, widget) def addChild(self, child): QtGui.QTreeWidgetItem.addChild(self, child) TreeWidget.informTreeWidgetChange(child) def addChildren(self, childs): QtGui.QTreeWidgetItem.addChildren(self, childs) for child in childs: TreeWidget.informTreeWidgetChange(child) def insertChild(self, index, child): QtGui.QTreeWidgetItem.insertChild(self, index, child) TreeWidget.informTreeWidgetChange(child) def insertChildren(self, index, childs): QtGui.QTreeWidgetItem.addChildren(self, index, childs) for child in childs: TreeWidget.informTreeWidgetChange(child) def removeChild(self, child): QtGui.QTreeWidgetItem.removeChild(self, child) TreeWidget.informTreeWidgetChange(child) def takeChild(self, index): child = QtGui.QTreeWidgetItem.takeChild(self, index) TreeWidget.informTreeWidgetChange(child) return child def takeChildren(self): childs = QtGui.QTreeWidgetItem.takeChildren(self) for child in childs: TreeWidget.informTreeWidgetChange(child) return childs pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/ValueLabel.py000066400000000000000000000055531300727121400237040ustar00rootroot00000000000000from ..Qt import QtCore, QtGui from ..ptime import time from .. import functions as fn from functools import reduce __all__ = ['ValueLabel'] class ValueLabel(QtGui.QLabel): """ QLabel specifically for displaying numerical values. Extends QLabel adding some extra functionality: - displaying units with si prefix - built-in exponential averaging """ def __init__(self, parent=None, suffix='', siPrefix=False, averageTime=0, formatStr=None): """ ============== ================================================================================== **Arguments:** suffix (str or None) The suffix to place after the value siPrefix (bool) Whether to add an SI prefix to the units and display a scaled value averageTime (float) The length of time in seconds to average values. If this value is 0, then no averaging is performed. As this value increases the display value will appear to change more slowly and smoothly. formatStr (str) Optionally, provide a format string to use when displaying text. The text will be generated by calling formatStr.format(value=, avgValue=, suffix=) (see Python documentation on str.format) This option is not compatible with siPrefix ============== ================================================================================== """ QtGui.QLabel.__init__(self, parent) self.values = [] self.averageTime = averageTime ## no averaging by default self.suffix = suffix self.siPrefix = siPrefix if formatStr is None: formatStr = '{avgValue:0.2g} {suffix}' self.formatStr = formatStr def setValue(self, value): now = time() self.values.append((now, value)) cutoff = now - self.averageTime while len(self.values) > 0 and self.values[0][0] < cutoff: self.values.pop(0) self.update() def setFormatStr(self, text): self.formatStr = text self.update() def setAverageTime(self, t): self.averageTime = t def averageValue(self): return reduce(lambda a,b: a+b, [v[1] for v in self.values]) / float(len(self.values)) def paintEvent(self, ev): self.setText(self.generateText()) return QtGui.QLabel.paintEvent(self, ev) def generateText(self): if len(self.values) == 0: return '' avg = self.averageValue() val = self.values[-1][1] if self.siPrefix: return fn.siFormat(avg, suffix=self.suffix) else: return self.formatStr.format(value=val, avgValue=avg, suffix=self.suffix) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/VerticalLabel.py000066400000000000000000000064401300727121400243750ustar00rootroot00000000000000# -*- coding: utf-8 -*- from ..Qt import QtGui, QtCore __all__ = ['VerticalLabel'] #class VerticalLabel(QtGui.QLabel): #def paintEvent(self, ev): #p = QtGui.QPainter(self) #p.rotate(-90) #self.hint = p.drawText(QtCore.QRect(-self.height(), 0, self.height(), self.width()), QtCore.Qt.AlignLeft|QtCore.Qt.AlignVCenter, self.text()) #p.end() #self.setMinimumWidth(self.hint.height()) #self.setMinimumHeight(self.hint.width()) #def sizeHint(self): #if hasattr(self, 'hint'): #return QtCore.QSize(self.hint.height(), self.hint.width()) #else: #return QtCore.QSize(16, 50) class VerticalLabel(QtGui.QLabel): def __init__(self, text, orientation='vertical', forceWidth=True): QtGui.QLabel.__init__(self, text) self.forceWidth = forceWidth self.orientation = None self.setOrientation(orientation) def setOrientation(self, o): if self.orientation == o: return self.orientation = o self.update() self.updateGeometry() def paintEvent(self, ev): p = QtGui.QPainter(self) #p.setBrush(QtGui.QBrush(QtGui.QColor(100, 100, 200))) #p.setPen(QtGui.QPen(QtGui.QColor(50, 50, 100))) #p.drawRect(self.rect().adjusted(0, 0, -1, -1)) #p.setPen(QtGui.QPen(QtGui.QColor(255, 255, 255))) if self.orientation == 'vertical': p.rotate(-90) rgn = QtCore.QRect(-self.height(), 0, self.height(), self.width()) else: rgn = self.contentsRect() align = self.alignment() #align = QtCore.Qt.AlignTop|QtCore.Qt.AlignHCenter self.hint = p.drawText(rgn, align, self.text()) p.end() if self.orientation == 'vertical': self.setMaximumWidth(self.hint.height()) self.setMinimumWidth(0) self.setMaximumHeight(16777215) if self.forceWidth: self.setMinimumHeight(self.hint.width()) else: self.setMinimumHeight(0) else: self.setMaximumHeight(self.hint.height()) self.setMinimumHeight(0) self.setMaximumWidth(16777215) if self.forceWidth: self.setMinimumWidth(self.hint.width()) else: self.setMinimumWidth(0) def sizeHint(self): if self.orientation == 'vertical': if hasattr(self, 'hint'): return QtCore.QSize(self.hint.height(), self.hint.width()) else: return QtCore.QSize(19, 50) else: if hasattr(self, 'hint'): return QtCore.QSize(self.hint.width(), self.hint.height()) else: return QtCore.QSize(50, 19) if __name__ == '__main__': app = QtGui.QApplication([]) win = QtGui.QMainWindow() w = QtGui.QWidget() l = QtGui.QGridLayout() w.setLayout(l) l1 = VerticalLabel("text 1", orientation='horizontal') l2 = VerticalLabel("text 2") l3 = VerticalLabel("text 3") l4 = VerticalLabel("text 4", orientation='horizontal') l.addWidget(l1, 0, 0) l.addWidget(l2, 1, 1) l.addWidget(l3, 2, 2) l.addWidget(l4, 3, 3) win.setCentralWidget(w) win.show()pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/__init__.py000066400000000000000000000011071300727121400234160ustar00rootroot00000000000000## just import everything from sub-modules #import os #d = os.path.split(__file__)[0] #files = [] #for f in os.listdir(d): #if os.path.isdir(os.path.join(d, f)): #files.append(f) #elif f[-3:] == '.py' and f != '__init__.py': #files.append(f[:-3]) #for modName in files: #mod = __import__(modName, globals(), locals(), fromlist=['*']) #if hasattr(mod, '__all__'): #names = mod.__all__ #else: #names = [n for n in dir(mod) if n[0] != '_'] #for k in names: #print modName, k #globals()[k] = getattr(mod, k) pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/tests/000077500000000000000000000000001300727121400224505ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/tests/test_combobox.py000066400000000000000000000021171300727121400256720ustar00rootroot00000000000000import pyqtgraph as pg pg.mkQApp() def test_combobox(): cb = pg.ComboBox() items = {'a': 1, 'b': 2, 'c': 3} cb.setItems(items) cb.setValue(2) assert str(cb.currentText()) == 'b' assert cb.value() == 2 # Clear item list; value should be None cb.clear() assert cb.value() == None # Reset item list; value should be set automatically cb.setItems(items) assert cb.value() == 2 # Clear item list; repopulate with same names and new values items = {'a': 4, 'b': 5, 'c': 6} cb.clear() cb.setItems(items) assert cb.value() == 5 # Set list instead of dict cb.setItems(list(items.keys())) assert str(cb.currentText()) == 'b' cb.setValue('c') assert cb.value() == str(cb.currentText()) assert cb.value() == 'c' cb.setItemValue('c', 7) assert cb.value() == 7 if __name__ == '__main__': cb = pg.ComboBox() cb.show() cb.setItems({'': None, 'a': 1, 'b': 2, 'c': 3}) def fn(ind): print("New value: %s" % cb.value()) cb.currentIndexChanged.connect(fn)pyqtgraph-pyqtgraph-0.10.0/pyqtgraph/widgets/tests/test_tablewidget.py000066400000000000000000000075771300727121400263740ustar00rootroot00000000000000import pyqtgraph as pg import numpy as np from pyqtgraph.pgcollections import OrderedDict app = pg.mkQApp() listOfTuples = [('text_%d' % i, i, i/9.) for i in range(12)] listOfLists = [list(row) for row in listOfTuples] plainArray = np.array(listOfLists, dtype=object) recordArray = np.array(listOfTuples, dtype=[('string', object), ('integer', int), ('floating', float)]) dictOfLists = OrderedDict([(name, list(recordArray[name])) for name in recordArray.dtype.names]) listOfDicts = [OrderedDict([(name, rec[name]) for name in recordArray.dtype.names]) for rec in recordArray] transposed = [[row[col] for row in listOfTuples] for col in range(len(listOfTuples[0]))] def assertTableData(table, data): assert len(data) == table.rowCount() rows = list(range(table.rowCount())) columns = list(range(table.columnCount())) for r in rows: assert len(data[r]) == table.columnCount() row = [] for c in columns: item = table.item(r, c) if item is not None: row.append(item.value) else: row.append(None) assert row == list(data[r]) def test_TableWidget(): w = pg.TableWidget(sortable=False) # Test all input data types w.setData(listOfTuples) assertTableData(w, listOfTuples) w.setData(listOfLists) assertTableData(w, listOfTuples) w.setData(plainArray) assertTableData(w, listOfTuples) w.setData(recordArray) assertTableData(w, listOfTuples) w.setData(dictOfLists) assertTableData(w, transposed) w.appendData(dictOfLists) assertTableData(w, transposed * 2) w.setData(listOfDicts) assertTableData(w, listOfTuples) w.appendData(listOfDicts) assertTableData(w, listOfTuples * 2) # Test sorting w.setData(listOfTuples) w.sortByColumn(0, pg.QtCore.Qt.AscendingOrder) assertTableData(w, sorted(listOfTuples, key=lambda a: a[0])) w.sortByColumn(1, pg.QtCore.Qt.AscendingOrder) assertTableData(w, sorted(listOfTuples, key=lambda a: a[1])) w.sortByColumn(2, pg.QtCore.Qt.AscendingOrder) assertTableData(w, sorted(listOfTuples, key=lambda a: a[2])) w.setSortMode(1, 'text') w.sortByColumn(1, pg.QtCore.Qt.AscendingOrder) assertTableData(w, sorted(listOfTuples, key=lambda a: str(a[1]))) w.setSortMode(1, 'index') w.sortByColumn(1, pg.QtCore.Qt.AscendingOrder) assertTableData(w, listOfTuples) # Test formatting item = w.item(0, 2) assert item.text() == ('%0.3g' % item.value) w.setFormat('%0.6f') assert item.text() == ('%0.6f' % item.value) w.setFormat('X%0.7f', column=2) assert isinstance(item.value, float) assert item.text() == ('X%0.7f' % item.value) # test setting items that do not exist yet w.setFormat('X%0.7f', column=3) # test append uses correct formatting w.appendRow(('x', 10, 7.3)) item = w.item(w.rowCount()-1, 2) assert isinstance(item.value, float) assert item.text() == ('X%0.7f' % item.value) # test reset back to defaults w.setFormat(None, column=2) assert isinstance(item.value, float) assert item.text() == ('%0.6f' % item.value) w.setFormat(None) assert isinstance(item.value, float) assert item.text() == ('%0.3g' % item.value) # test function formatter def fmt(item): if isinstance(item.value, float): return "%d %f" % (item.index, item.value) else: return pg.asUnicode(item.value) w.setFormat(fmt) assert isinstance(item.value, float) assert isinstance(item.index, int) assert item.text() == ("%d %f" % (item.index, item.value)) if __name__ == '__main__': w = pg.TableWidget(editable=True) w.setData(listOfTuples) w.resize(600, 600) w.show() pyqtgraph-pyqtgraph-0.10.0/setup.py000066400000000000000000000120351300727121400173340ustar00rootroot00000000000000DESCRIPTION = """\ PyQtGraph is a pure-python graphics and GUI library built on PyQt4/PySide and numpy. It is intended for use in mathematics / scientific / engineering applications. Despite being written entirely in python, the library is very fast due to its heavy leverage of numpy for number crunching, Qt's GraphicsView framework for 2D display, and OpenGL for 3D display. """ setupOpts = dict( name='pyqtgraph', description='Scientific Graphics and GUI Library for Python', long_description=DESCRIPTION, license='MIT', url='http://www.pyqtgraph.org', author='Luke Campagnola', author_email='luke.campagnola@gmail.com', classifiers = [ "Programming Language :: Python", "Programming Language :: Python :: 2", "Programming Language :: Python :: 2.6", "Programming Language :: Python :: 2.7", "Programming Language :: Python :: 3", "Development Status :: 4 - Beta", "Environment :: Other Environment", "Intended Audience :: Science/Research", "License :: OSI Approved :: MIT License", "Operating System :: OS Independent", "Topic :: Software Development :: Libraries :: Python Modules", "Topic :: Scientific/Engineering :: Visualization", "Topic :: Software Development :: User Interfaces", ], ) import distutils.dir_util from distutils.command import build import os, sys, re try: import setuptools from setuptools import setup from setuptools.command import install except ImportError: sys.stderr.write("Warning: could not import setuptools; falling back to distutils.\n") from distutils.core import setup from distutils.command import install # Work around mbcs bug in distutils. # http://bugs.python.org/issue10945 import codecs try: codecs.lookup('mbcs') except LookupError: ascii = codecs.lookup('ascii') func = lambda name, enc=ascii: {True: enc}.get(name=='mbcs') codecs.register(func) path = os.path.split(__file__)[0] sys.path.insert(0, os.path.join(path, 'tools')) import setupHelpers as helpers ## generate list of all sub-packages allPackages = (helpers.listAllPackages(pkgroot='pyqtgraph') + ['pyqtgraph.'+x for x in helpers.listAllPackages(pkgroot='examples')]) ## Decide what version string to use in the build version, forcedVersion, gitVersion, initVersion = helpers.getVersionStrings(pkg='pyqtgraph') class Build(build.build): """ * Clear build path before building """ def run(self): global path ## Make sure build directory is clean buildPath = os.path.join(path, self.build_lib) if os.path.isdir(buildPath): distutils.dir_util.remove_tree(buildPath) ret = build.build.run(self) class Install(install.install): """ * Check for previously-installed version before installing * Set version string in __init__ after building. This helps to ensure that we know when an installation came from a non-release code base. """ def run(self): global path, version, initVersion, forcedVersion, installVersion name = self.config_vars['dist_name'] path = os.path.join(self.install_libbase, 'pyqtgraph') if os.path.exists(path): raise Exception("It appears another version of %s is already " "installed at %s; remove this before installing." % (name, path)) print("Installing to %s" % path) rval = install.install.run(self) # If the version in __init__ is different from the automatically-generated # version string, then we will update __init__ in the install directory if initVersion == version: return rval try: initfile = os.path.join(path, '__init__.py') data = open(initfile, 'r').read() open(initfile, 'w').write(re.sub(r"__version__ = .*", "__version__ = '%s'" % version, data)) installVersion = version except: sys.stderr.write("Warning: Error occurred while setting version string in build path. " "Installation will use the original version string " "%s instead.\n" % (initVersion) ) if forcedVersion: raise installVersion = initVersion sys.excepthook(*sys.exc_info()) return rval setup( version=version, cmdclass={'build': Build, 'install': Install, 'deb': helpers.DebCommand, 'test': helpers.TestCommand, 'debug': helpers.DebugCommand, 'mergetest': helpers.MergeTestCommand, 'style': helpers.StyleCommand}, packages=allPackages, package_dir={'pyqtgraph.examples': 'examples'}, ## install examples along with the rest of the source package_data={'pyqtgraph.examples': ['optics/*.gz', 'relativity/presets/*.cfg']}, install_requires = [ 'numpy', ], **setupOpts ) pyqtgraph-pyqtgraph-0.10.0/tools/000077500000000000000000000000001300727121400167615ustar00rootroot00000000000000pyqtgraph-pyqtgraph-0.10.0/tools/generateChangelog.py000066400000000000000000000052121300727121400227350ustar00rootroot00000000000000import re, time, sys def generateDebianChangelog(package, logFile, version, maintainer): """ ------- Convert CHANGELOG format like: pyqtgraph-0.9.1 2012-12-29 - change - change -------- to debian changelog format: python-pyqtgraph (0.9.1-1) UNRELEASED; urgency=low * Initial release. -- Luke Sat, 29 Dec 2012 01:07:23 -0500 *package* is the name of the python package. *logFile* is the CHANGELOG file to read; must have the format described above. *version* will be used to check that the most recent log entry corresponds to the current package version. *maintainer* should be string like "Luke ". """ releases = [] current_version = None current_log = None current_date = None for line in open(logFile).readlines(): match = re.match(package+r'-(\d+\.\d+\.\d+(\.\d+)?)\s*(\d+-\d+-\d+)\s*$', line) if match is None: if current_log is not None: current_log.append(line) else: if current_log is not None: releases.append((current_version, current_log, current_date)) current_version, current_date = match.groups()[0], match.groups()[2] #sys.stderr.write("Found release %s\n" % current_version) current_log = [] if releases[0][0] != version: raise Exception("Latest release in changelog (%s) does not match current release (%s)\n" % (releases[0][0], version)) output = [] for release, changes, date in releases: date = time.strptime(date, '%Y-%m-%d') changeset = [ "python-%s (%s-1) UNRELEASED; urgency=low\n" % (package, release), "\n"] + changes + [ " -- %s %s -0%d00\n" % (maintainer, time.strftime('%a, %d %b %Y %H:%M:%S', date), time.timezone/3600), "\n" ] # remove consecutive blank lines except between releases clean = "" lastBlank = True for line in changeset: if line.strip() == '': if lastBlank: continue else: clean += line lastBlank = True else: clean += line lastBlank = False output.append(clean) output.append("") return "\n".join(output) + "\n" if __name__ == '__main__': if len(sys.argv) < 5: sys.stderr.write('Usage: generateChangelog.py package_name log_file version "Maintainer "\n') sys.exit(-1) print(generateDebianChangelog(*sys.argv[1:])) pyqtgraph-pyqtgraph-0.10.0/tools/pg-release.py000066400000000000000000000210731300727121400213620ustar00rootroot00000000000000#!/usr/bin/python import os, sys, argparse, random from shell import shell, ssh description="Build release packages for pyqtgraph." epilog = """ Package build is done in several steps: * Attempt to clone branch release-x.y.z from source-repo * Merge release branch into master * Write new version numbers into the source * Roll over unreleased CHANGELOG entries * Commit and tag new release * Build HTML documentation * Build source package * Build deb packages (if running on Linux) * Build Windows exe installers Release packages may be published by using the --publish flag: * Uploads release files to website * Pushes tagged git commit to github * Uploads source package to pypi Building source packages requires: * * * python-sphinx Building deb packages requires several dependencies: * build-essential * python-all, python3-all * python-stdeb, python3-stdeb Note: building windows .exe files should be possible on any OS. However, Debian/Ubuntu systems do not include the necessary wininst*.exe files; these must be manually copied from the Python source to the distutils/command submodule path (/usr/lib/pythonX.X/distutils/command). Additionally, it may be necessary to rename (or copy / link) wininst-9.0-amd64.exe to wininst-6.0-amd64.exe. """ path = os.path.abspath(os.path.join(os.path.dirname(__file__), '..')) build_dir = os.path.join(path, 'release-build') pkg_dir = os.path.join(path, 'release-packages') ap = argparse.ArgumentParser(description=description, epilog=epilog, formatter_class=argparse.RawDescriptionHelpFormatter) ap.add_argument('version', help='The x.y.z version to generate release packages for. ' 'There must be a corresponding pyqtgraph-x.y.z branch in the source repository.') ap.add_argument('--publish', metavar='', help='Publish previously built package files (must be stored in pkg-dir/version) and tagged release commit (from build-dir).', action='store_const', const=True, default=False) ap.add_argument('--source-repo', metavar='', help='Repository from which release and master branches will be cloned. Default is the repo containing this script.', default=path) ap.add_argument('--build-dir', metavar='', help='Directory where packages will be staged and built. Default is source_root/release-build.', default=build_dir) ap.add_argument('--pkg-dir', metavar='', help='Directory where packages will be stored. Default is source_root/release-packages.', default=pkg_dir) ap.add_argument('--skip-pip-test', metavar='', help='Skip testing pip install.', action='store_const', const=True, default=False) ap.add_argument('--no-deb', metavar='', help='Skip building Debian packages.', action='store_const', const=True, default=False) ap.add_argument('--no-exe', metavar='', help='Skip building Windows exe installers.', action='store_const', const=True, default=False) def build(args): if os.path.exists(args.build_dir): sys.stderr.write("Please remove the build directory %s before proceeding, or specify a different path with --build-dir.\n" % args.build_dir) sys.exit(-1) if os.path.exists(args.pkg_dir): sys.stderr.write("Please remove the package directory %s before proceeding, or specify a different path with --pkg-dir.\n" % args.pkg_dir) sys.exit(-1) # Clone source repository and tag the release branch shell(''' # Clone and merge release branch into previous master mkdir -p {build_dir} cd {build_dir} rm -rf pyqtgraph git clone --depth 1 -b master {source_repo} pyqtgraph cd pyqtgraph git checkout -b release-{version} git pull {source_repo} release-{version} git checkout master git merge --no-ff --no-commit release-{version} # Write new version number into the source sed -i "s/__version__ = .*/__version__ = '{version}'/" pyqtgraph/__init__.py sed -i "s/version = .*/version = '{version}'/" doc/source/conf.py sed -i "s/release = .*/release = '{version}'/" doc/source/conf.py # make sure changelog mentions unreleased changes grep "pyqtgraph-{version}.*unreleased.*" CHANGELOG sed -i "s/pyqtgraph-{version}.*unreleased.*/pyqtgraph-{version}/" CHANGELOG # Commit and tag new release git commit -a -m "PyQtGraph release {version}" git tag pyqtgraph-{version} # Build HTML documentation cd doc make clean make html cd .. find ./ -name "*.pyc" -delete # package source distribution python setup.py sdist mkdir -p {pkg_dir} cp dist/*.tar.gz {pkg_dir} # source package build complete. '''.format(**args.__dict__)) if args.skip_pip_test: args.pip_test = 'skipped' else: shell(''' # test pip install source distribution rm -rf release-{version}-virtenv virtualenv --system-site-packages release-{version}-virtenv . release-{version}-virtenv/bin/activate echo "PATH: $PATH" echo "ENV: $VIRTUAL_ENV" pip install --no-index --no-deps dist/pyqtgraph-{version}.tar.gz deactivate # pip install test passed '''.format(**args.__dict__)) args.pip_test = 'passed' if 'linux' in sys.platform and not args.no_deb: shell(''' # build deb packages cd {build_dir}/pyqtgraph python setup.py --command-packages=stdeb.command sdist_dsc cd deb_dist/pyqtgraph-{version} sed -i "s/^Depends:.*/Depends: python (>= 2.6), python-qt4 | python-pyside, python-numpy/" debian/control dpkg-buildpackage cd ../../ mv deb_dist {pkg_dir}/pyqtgraph-{version}-deb # deb package build complete. '''.format(**args.__dict__)) args.deb_status = 'built' else: args.deb_status = 'skipped' if not args.no_exe: shell(""" # Build windows executables cd {build_dir}/pyqtgraph python setup.py build bdist_wininst --plat-name=win32 python setup.py build bdist_wininst --plat-name=win-amd64 cp dist/*.exe {pkg_dir} """.format(**args.__dict__)) args.exe_status = 'built' else: args.exe_status = 'skipped' print(unindent(""" ======== Build complete. ========= * Source package: built * Pip install test: {pip_test} * Debian packages: {deb_status} * Windows installers: {exe_status} * Package files in {pkg_dir} Next steps to publish: * Test all packages * Run script again with --publish """).format(**args.__dict__)) def publish(args): if not os.path.isfile(os.path.expanduser('~/.pypirc')): print(unindent(""" Missing ~/.pypirc file. Should look like: ----------------------------------------- [distutils] index-servers = pypi [pypi] username:your_username password:your_password """)) sys.exit(-1) ### Upload everything to server shell(""" # Uploading documentation.. cd {build_dir}/pyqtgraph rsync -rv doc/build/* pyqtgraph.org:/www/code/pyqtgraph/pyqtgraph/documentation/build/ # Uploading release packages to website rsync -v {pkg_dir}/{version} pyqtgraph.org:/www/code/pyqtgraph/downloads/ # Push to github git push --tags https://github.com/pyqtgraph/pyqtgraph master:master # Upload to pypi.. python setup.py sdist upload """.format(**args.__dict__)) print(unindent(""" ======== Upload complete. ========= Next steps to publish: - update website - mailing list announcement - new conda recipe (http://conda.pydata.org/docs/build.html) - contact deb maintainer (gianfranco costamagna) - other package maintainers? """).format(**args.__dict__)) def unindent(msg): ind = 1e6 lines = msg.split('\n') for line in lines: if len(line.strip()) == 0: continue ind = min(ind, len(line) - len(line.lstrip())) return '\n'.join([line[ind:] for line in lines]) if __name__ == '__main__': args = ap.parse_args() args.build_dir = os.path.abspath(args.build_dir) args.pkg_dir = os.path.join(os.path.abspath(args.pkg_dir), args.version) if args.publish: publish(args) else: build(args) pyqtgraph-pyqtgraph-0.10.0/tools/py2exe.bat000066400000000000000000000005121300727121400206630ustar00rootroot00000000000000rem rem This is a simple windows batch file containing the commands needed to package rem a program with pyqtgraph and py2exe. See the packaging tutorial at rem http://luke.campagnola.me/code/pyqtgraph for more information. rem rmdir /S /Q dist rmdir /S /Q build python .\py2exeSetupWindows.py py2exe --includes sip pause pyqtgraph-pyqtgraph-0.10.0/tools/py2exeSetupWindows.py000066400000000000000000000014101300727121400231370ustar00rootroot00000000000000""" Example distutils setup script for packaging a program with pyqtgraph and py2exe. See the packaging tutorial at http://luke.campagnola.me/code/pyqtgraph for more information. """ from distutils.core import setup from glob import glob import py2exe import sys ## This path must contain msvcm90.dll, msvcp90.dll, msvcr90.dll, and Microsoft.VC90.CRT.manifest ## (see http://www.py2exe.org/index.cgi/Tutorial) dllpath = r'C:\Windows\WinSxS\x86_Microsoft.VC90.CRT...' sys.path.append(dllpath) data_files = [ ## Instruct setup to copy the needed DLL files into the build directory ("Microsoft.VC90.CRT", glob(dllpath + r'\*.*')), ] setup( data_files=data_files, windows=['main.py'] , options={"py2exe": {"excludes":["Tkconstants", "Tkinter", "tcl"]}} ) pyqtgraph-pyqtgraph-0.10.0/tools/pyuic5000077500000000000000000000000521300727121400201220ustar00rootroot00000000000000#!/usr/bin/python3 import PyQt5.uic.pyuic pyqtgraph-pyqtgraph-0.10.0/tools/rebuildUi.py000066400000000000000000000030261300727121400212600ustar00rootroot00000000000000""" Script for compiling Qt Designer .ui files to .py """ import os, sys, subprocess, tempfile pyqtuic = 'pyuic4' pysideuic = 'pyside-uic' pyqt5uic = 'pyuic5' usage = """Compile .ui files to .py for all supported pyqt/pyside versions. Usage: python rebuildUi.py [.ui files|search paths] May specify a list of .ui files and/or directories to search recursively for .ui files. """ args = sys.argv[1:] if len(args) == 0: print(usage) sys.exit(-1) uifiles = [] for arg in args: if os.path.isfile(arg) and arg.endswith('.ui'): uifiles.append(arg) elif os.path.isdir(arg): # recursively search for ui files in this directory for path, sd, files in os.walk(arg): for f in files: if not f.endswith('.ui'): continue uifiles.append(os.path.join(path, f)) else: print('Argument "%s" is not a directory or .ui file.' % arg) sys.exit(-1) # rebuild all requested ui files for ui in uifiles: base, _ = os.path.splitext(ui) for compiler, ext in [(pyqtuic, '_pyqt.py'), (pysideuic, '_pyside.py'), (pyqt5uic, '_pyqt5.py')]: py = base + ext if os.path.exists(py) and os.stat(ui).st_mtime <= os.stat(py).st_mtime: print("Skipping %s; already compiled." % py) else: cmd = '%s %s > %s' % (compiler, ui, py) print(cmd) try: subprocess.check_call(cmd, shell=True) except subprocess.CalledProcessError: os.remove(py) pyqtgraph-pyqtgraph-0.10.0/tools/release_instructions.md000066400000000000000000000021711300727121400235500ustar00rootroot00000000000000PyQtGraph Release Procedure --------------------------- 1. Create a release-x.x.x branch 2. Run pyqtgraph/tools/pg-release.py script (this has only been tested on linux) - creates clone of master - merges release branch into master - updates version numbers in code - creates pyqtgraph-x.x.x tag - creates release commit - builds documentation - builds source package - tests pip install - builds windows .exe installers (note: it may be necessary to manually copy wininst*.exe files from the python source packages) - builds deb package (note: official debian packages are built elsewhere; these locally-built deb packages may be phased out) 3. test build files - test setup.py, pip on OSX - test setup.py, pip, 32/64 exe on windows - test setup.py, pip, deb on linux (py2, py3) 4. Run pg-release.py script again with --publish flag - website upload - github push + release - pip upload 5. publish - update website - mailing list announcement - new conda recipe (http://conda.pydata.org/docs/build.html) - contact various package maintainers pyqtgraph-pyqtgraph-0.10.0/tools/setupHelpers.py000066400000000000000000000455651300727121400220350ustar00rootroot00000000000000# -*- coding: utf-8 -*- import os, sys, re try: from subprocess import check_output, check_call except ImportError: import subprocess as sp def check_output(*args, **kwds): kwds['stdout'] = sp.PIPE proc = sp.Popen(*args, **kwds) output = proc.stdout.read() proc.wait() if proc.returncode != 0: ex = Exception("Process had nonzero return value %d" % proc.returncode) ex.returncode = proc.returncode ex.output = output raise ex return output # Maximum allowed repository size difference (in kB) following merge. # This is used to prevent large files from being inappropriately added to # the repository history. MERGE_SIZE_LIMIT = 100 # Paths that are checked for style by flake and flake_diff FLAKE_CHECK_PATHS = ['pyqtgraph', 'examples', 'tools'] # Flake style checks -- mandatory, recommended, optional # See: http://pep8.readthedocs.org/en/1.4.6/intro.html # and https://flake8.readthedocs.org/en/2.0/warnings.html FLAKE_MANDATORY = set([ 'E101', # indentation contains mixed spaces and tabs 'E112', # expected an indented block 'E122', # continuation line missing indentation or outdented 'E125', # continuation line does not distinguish itself from next line 'E133', # closing bracket is missing indentation 'E223', # tab before operator 'E224', # tab after operator 'E242', # tab after ‘,’ 'E273', # tab after keyword 'E274', # tab before keyword 'E901', # SyntaxError or IndentationError 'E902', # IOError 'W191', # indentation contains tabs 'W601', # .has_key() is deprecated, use ‘in’ 'W602', # deprecated form of raising exception 'W603', # ‘<>’ is deprecated, use ‘!=’ 'W604', # backticks are deprecated, use ‘repr()’ ]) FLAKE_RECOMMENDED = set([ 'E124', # closing bracket does not match visual indentation 'E231', # missing whitespace after ‘,’ 'E211', # whitespace before ‘(‘ 'E261', # at least two spaces before inline comment 'E271', # multiple spaces after keyword 'E272', # multiple spaces before keyword 'E304', # blank lines found after function decorator 'F401', # module imported but unused 'F402', # import module from line N shadowed by loop variable 'F403', # ‘from module import *’ used; unable to detect undefined names 'F404', # future import(s) name after other statements 'E501', # line too long (82 > 79 characters) 'E502', # the backslash is redundant between brackets 'E702', # multiple statements on one line (semicolon) 'E703', # statement ends with a semicolon 'E711', # comparison to None should be ‘if cond is None:’ 'E712', # comparison to True should be ‘if cond is True:’ or ‘if cond:’ 'E721', # do not compare types, use ‘isinstance()’ 'F811', # redefinition of unused name from line N 'F812', # list comprehension redefines name from line N 'F821', # undefined name name 'F822', # undefined name name in __all__ 'F823', # local variable name ... referenced before assignment 'F831', # duplicate argument name in function definition 'F841', # local variable name is assigned to but never used 'W292', # no newline at end of file ]) FLAKE_OPTIONAL = set([ 'E121', # continuation line indentation is not a multiple of four 'E123', # closing bracket does not match indentation of opening bracket 'E126', # continuation line over-indented for hanging indent 'E127', # continuation line over-indented for visual indent 'E128', # continuation line under-indented for visual indent 'E201', # whitespace after ‘(‘ 'E202', # whitespace before ‘)’ 'E203', # whitespace before ‘:’ 'E221', # multiple spaces before operator 'E222', # multiple spaces after operator 'E225', # missing whitespace around operator 'E227', # missing whitespace around bitwise or shift operator 'E226', # missing whitespace around arithmetic operator 'E228', # missing whitespace around modulo operator 'E241', # multiple spaces after ‘,’ 'E251', # unexpected spaces around keyword / parameter equals 'E262', # inline comment should start with ‘# ‘ 'E301', # expected 1 blank line, found 0 'E302', # expected 2 blank lines, found 0 'E303', # too many blank lines (3) 'E401', # multiple imports on one line 'E701', # multiple statements on one line (colon) 'W291', # trailing whitespace 'W293', # blank line contains whitespace 'W391', # blank line at end of file ]) FLAKE_IGNORE = set([ # 111 and 113 are ignored because they appear to be broken. 'E111', # indentation is not a multiple of four 'E113', # unexpected indentation ]) #def checkStyle(): #try: #out = check_output(['flake8', '--select=%s' % FLAKE_TESTS, '--statistics', 'pyqtgraph/']) #ret = 0 #print("All style checks OK.") #except Exception as e: #out = e.output #ret = e.returncode #print(out.decode('utf-8')) #return ret def checkStyle(): """ Run flake8, checking only lines that are modified since the last git commit. """ test = [ 1,2,3 ] # First check _all_ code against mandatory error codes print('flake8: check all code against mandatory error set...') errors = ','.join(FLAKE_MANDATORY) cmd = ['flake8', '--select=' + errors] + FLAKE_CHECK_PATHS proc = subprocess.Popen(cmd, stdout=subprocess.PIPE) #ret = proc.wait() output = proc.stdout.read().decode('utf-8') ret = proc.wait() printFlakeOutput(output) # Check for DOS newlines print('check line endings in all files...') count = 0 allowedEndings = set([None, '\n']) for path, dirs, files in os.walk('.'): for f in files: if os.path.splitext(f)[1] not in ('.py', '.rst'): continue filename = os.path.join(path, f) fh = open(filename, 'U') x = fh.readlines() endings = set(fh.newlines if isinstance(fh.newlines, tuple) else (fh.newlines,)) endings -= allowedEndings if len(endings) > 0: print("\033[0;31m" + "File has invalid line endings: %s" % filename + "\033[0m") ret = ret | 2 count += 1 print('checked line endings in %d files' % count) # Next check new code with optional error codes print('flake8: check new code against recommended error set...') diff = subprocess.check_output(['git', 'diff']) proc = subprocess.Popen(['flake8', '--diff', #'--show-source', '--ignore=' + errors], stdin=subprocess.PIPE, stdout=subprocess.PIPE) proc.stdin.write(diff) proc.stdin.close() output = proc.stdout.read().decode('utf-8') ret |= printFlakeOutput(output) if ret == 0: print('style test passed.') else: print('style test failed: %d' % ret) return ret def printFlakeOutput(text): """ Print flake output, colored by error category. Return 2 if there were any mandatory errors, 1 if only recommended / optional errors, and 0 if only optional errors. """ ret = 0 gotError = False for line in text.split('\n'): m = re.match(r'[^\:]+\:\d+\:\d+\: (\w+) .*', line) if m is None: print(line) else: gotError = True error = m.group(1) if error in FLAKE_MANDATORY: print("\033[0;31m" + line + "\033[0m") ret |= 2 elif error in FLAKE_RECOMMENDED: print("\033[0;33m" + line + "\033[0m") #ret |= 1 elif error in FLAKE_OPTIONAL: print("\033[0;32m" + line + "\033[0m") elif error in FLAKE_IGNORE: continue else: print("\033[0;36m" + line + "\033[0m") if not gotError: print(" [ no errors ]\n") return ret def unitTests(): """ Run all unit tests (using py.test) Return the exit code. """ try: if sys.version[0] == '3': out = check_output('PYTHONPATH=. py.test-3', shell=True) else: out = check_output('PYTHONPATH=. py.test', shell=True) ret = 0 except Exception as e: out = e.output ret = e.returncode print(out.decode('utf-8')) return ret def checkMergeSize(sourceBranch=None, targetBranch=None, sourceRepo=None, targetRepo=None): """ Check that a git merge would not increase the repository size by MERGE_SIZE_LIMIT. """ if sourceBranch is None: sourceBranch = getGitBranch() sourceRepo = '..' if targetBranch is None: if sourceBranch == 'develop': targetBranch = 'develop' targetRepo = 'https://github.com/pyqtgraph/pyqtgraph.git' else: targetBranch = 'develop' targetRepo = '..' workingDir = '__merge-test-clone' env = dict(TARGET_BRANCH=targetBranch, SOURCE_BRANCH=sourceBranch, TARGET_REPO=targetRepo, SOURCE_REPO=sourceRepo, WORKING_DIR=workingDir, ) print("Testing merge size difference:\n" " SOURCE: {SOURCE_REPO} {SOURCE_BRANCH}\n" " TARGET: {TARGET_BRANCH} {TARGET_REPO}".format(**env)) setup = """ mkdir {WORKING_DIR} && cd {WORKING_DIR} && git init && git remote add -t {TARGET_BRANCH} target {TARGET_REPO} && git fetch target {TARGET_BRANCH} && git checkout -qf target/{TARGET_BRANCH} && git gc -q --aggressive """.format(**env) checkSize = """ cd {WORKING_DIR} && du -s . | sed -e "s/\t.*//" """.format(**env) merge = """ cd {WORKING_DIR} && git pull -q {SOURCE_REPO} {SOURCE_BRANCH} && git gc -q --aggressive """.format(**env) try: print("Check out target branch:\n" + setup) check_call(setup, shell=True) targetSize = int(check_output(checkSize, shell=True)) print("TARGET SIZE: %d kB" % targetSize) print("Merge source branch:\n" + merge) check_call(merge, shell=True) mergeSize = int(check_output(checkSize, shell=True)) print("MERGE SIZE: %d kB" % mergeSize) diff = mergeSize - targetSize if diff <= MERGE_SIZE_LIMIT: print("DIFFERENCE: %d kB [OK]" % diff) return 0 else: print("\033[0;31m" + "DIFFERENCE: %d kB [exceeds %d kB]" % (diff, MERGE_SIZE_LIMIT) + "\033[0m") return 2 finally: if os.path.isdir(workingDir): shutil.rmtree(workingDir) def mergeTests(): ret = checkMergeSize() ret |= unitTests() ret |= checkStyle() if ret == 0: print("\033[0;32m" + "\nAll merge tests passed." + "\033[0m") else: print("\033[0;31m" + "\nMerge tests failed." + "\033[0m") return ret def listAllPackages(pkgroot): path = os.getcwd() n = len(path.split(os.path.sep)) subdirs = [i[0].split(os.path.sep)[n:] for i in os.walk(os.path.join(path, pkgroot)) if '__init__.py' in i[2]] return ['.'.join(p) for p in subdirs] def getInitVersion(pkgroot): """Return the version string defined in __init__.py""" path = os.getcwd() initfile = os.path.join(path, pkgroot, '__init__.py') init = open(initfile).read() m = re.search(r'__version__ = (\S+)\n', init) if m is None or len(m.groups()) != 1: raise Exception("Cannot determine __version__ from init file: '%s'!" % initfile) version = m.group(1).strip('\'\"') return version def gitCommit(name): """Return the commit ID for the given name.""" commit = check_output(['git', 'show', name], universal_newlines=True).split('\n')[0] assert commit[:7] == 'commit ' return commit[7:] def getGitVersion(tagPrefix): """Return a version string with information about this git checkout. If the checkout is an unmodified, tagged commit, then return the tag version. If this is not a tagged commit, return the output of ``git describe --tags``. If this checkout has been modified, append "+" to the version. """ path = os.getcwd() if not os.path.isdir(os.path.join(path, '.git')): return None v = check_output(['git', 'describe', '--tags', '--dirty', '--match=%s*'%tagPrefix]).strip().decode('utf-8') # chop off prefix assert v.startswith(tagPrefix) v = v[len(tagPrefix):] # split up version parts parts = v.split('-') # has working tree been modified? modified = False if parts[-1] == 'dirty': modified = True parts = parts[:-1] # have commits been added on top of last tagged version? # (git describe adds -NNN-gXXXXXXX if this is the case) local = None if len(parts) > 2 and re.match(r'\d+', parts[-2]) and re.match(r'g[0-9a-f]{7}', parts[-1]): local = parts[-1] parts = parts[:-2] gitVersion = '-'.join(parts) if local is not None: gitVersion += '+' + local if modified: gitVersion += 'm' return gitVersion def getGitBranch(): m = re.search(r'\* (.*)', check_output(['git', 'branch'], universal_newlines=True)) if m is None: return '' else: return m.group(1) def getVersionStrings(pkg): """ Returns 4 version strings: * the version string to use for this build, * version string requested with --force-version (or None) * version string that describes the current git checkout (or None). * version string in the pkg/__init__.py, The first return value is (forceVersion or gitVersion or initVersion). """ ## Determine current version string from __init__.py initVersion = getInitVersion(pkgroot=pkg) ## If this is a git checkout, try to generate a more descriptive version string try: gitVersion = getGitVersion(tagPrefix=pkg+'-') except: gitVersion = None sys.stderr.write("This appears to be a git checkout, but an error occurred " "while attempting to determine a version string for the " "current commit.\n") sys.excepthook(*sys.exc_info()) # See whether a --force-version flag was given forcedVersion = None for i,arg in enumerate(sys.argv): if arg.startswith('--force-version'): if arg == '--force-version': forcedVersion = sys.argv[i+1] sys.argv.pop(i) sys.argv.pop(i) elif arg.startswith('--force-version='): forcedVersion = sys.argv[i].replace('--force-version=', '') sys.argv.pop(i) ## Finally decide on a version string to use: if forcedVersion is not None: version = forcedVersion elif gitVersion is not None and getGitBranch() != 'debian': # ignore git version if this is debian branch version = gitVersion sys.stderr.write("Detected git commit; will use version string: '%s'\n" % version) else: version = initVersion return version, forcedVersion, gitVersion, initVersion from distutils.core import Command import shutil, subprocess from generateChangelog import generateDebianChangelog class DebCommand(Command): description = "build .deb package using `debuild -us -uc`" maintainer = "Luke Campagnola " debTemplate = "debian" debDir = "deb_build" user_options = [] def initialize_options(self): self.cwd = None def finalize_options(self): self.cwd = os.getcwd() def run(self): version = self.distribution.get_version() pkgName = self.distribution.get_name() debName = "python-" + pkgName debDir = self.debDir assert os.getcwd() == self.cwd, 'Must be in package root: %s' % self.cwd if os.path.isdir(debDir): raise Exception('DEB build dir already exists: "%s"' % debDir) sdist = "dist/%s-%s.tar.gz" % (pkgName, version) if not os.path.isfile(sdist): raise Exception("No source distribution; run `setup.py sdist` first.") # copy sdist to build directory and extract os.mkdir(debDir) renamedSdist = '%s_%s.orig.tar.gz' % (debName, version) print("copy %s => %s" % (sdist, os.path.join(debDir, renamedSdist))) shutil.copy(sdist, os.path.join(debDir, renamedSdist)) print("cd %s; tar -xzf %s" % (debDir, renamedSdist)) if os.system("cd %s; tar -xzf %s" % (debDir, renamedSdist)) != 0: raise Exception("Error extracting source distribution.") buildDir = '%s/%s-%s' % (debDir, pkgName, version) # copy debian control structure print("copytree %s => %s" % (self.debTemplate, buildDir+'/debian')) shutil.copytree(self.debTemplate, buildDir+'/debian') # Write new changelog chlog = generateDebianChangelog(pkgName, 'CHANGELOG', version, self.maintainer) print("write changelog %s" % buildDir+'/debian/changelog') open(buildDir+'/debian/changelog', 'w').write(chlog) # build package print('cd %s; debuild -us -uc' % buildDir) if os.system('cd %s; debuild -us -uc' % buildDir) != 0: raise Exception("Error during debuild.") class DebugCommand(Command): """Just for learning about distutils.""" description = "" user_options = [] def initialize_options(self): pass def finalize_options(self): pass def run(self): global cmd cmd = self print(self.distribution.name) print(self.distribution.version) class TestCommand(Command): description = "Run all package tests and exit immediately with informative return code." user_options = [] def run(self): sys.exit(unitTests()) def initialize_options(self): pass def finalize_options(self): pass class StyleCommand(Command): description = "Check all code for style, exit immediately with informative return code." user_options = [] def run(self): sys.exit(checkStyle()) def initialize_options(self): pass def finalize_options(self): pass class MergeTestCommand(Command): description = "Run all tests needed to determine whether the current code is suitable for merge." user_options = [] def run(self): sys.exit(mergeTests()) def initialize_options(self): pass def finalize_options(self): pass pyqtgraph-pyqtgraph-0.10.0/tools/shell.py000066400000000000000000000021071300727121400204420ustar00rootroot00000000000000import os, sys import subprocess as sp def shell(cmd): """Run each line of a shell script; raise an exception if any line returns a nonzero value. """ pin, pout = os.pipe() proc = sp.Popen('/bin/bash', stdin=sp.PIPE) for line in cmd.split('\n'): line = line.strip() if line.startswith('#'): print('\033[33m> ' + line + '\033[0m') else: print('\033[32m> ' + line + '\033[0m') if line.startswith('cd '): os.chdir(line[3:]) proc.stdin.write((line + '\n').encode('utf-8')) proc.stdin.write(('echo $? 1>&%d\n' % pout).encode('utf-8')) ret = "" while not ret.endswith('\n'): ret += os.read(pin, 1) ret = int(ret.strip()) if ret != 0: print("\033[31mLast command returned %d; bailing out.\033[0m" % ret) sys.exit(-1) proc.stdin.close() proc.wait() def ssh(host, cmd): """Run commands on a remote host by ssh. """ proc = sp.Popen(['ssh', host], stdin=sp.PIPE) proc.stdin.write(cmd) proc.wait()