lpc21isp_197/ 40777 0 0 0 12263447607 11300 5ustar usergrouplpc21isp_197/.gitignore100666 0 0 46 12263446324 13320 0ustar usergroupbin/ obj/ *.depend *.layout *.*~ lpc21isp_197/adprog.c100666 0 0 27405 12263307372 13037 0ustar usergroup/****************************************************************************** Project: Portable command line ISP for NXP LPC1000 / LPC2000 family and Analog Devices ADUC70xx Filename: adprog.c Compiler: Microsoft VC 6/7, Microsoft VS2008, Microsoft VS2010, GCC Cygwin, GCC Linux, GCC ARM ELF Author: Martin Maurer (Martin.Maurer@clibb.de) Copyright: (c) Martin Maurer 2003-2014, All rights reserved Portions Copyright (c) by Aeolus Development 2004 http://www.aeolusdevelopment.com This file is part of lpc21isp. lpc21isp is free software: you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation, either version 3 of the License, or any later version. lpc21isp is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License and GNU General Public License along with lpc21isp. If not, see . */ #if defined(_WIN32) #if !defined __BORLANDC__ #include "StdAfx.h" #endif #endif // defined(_WIN32) #include "lpc21isp.h" #ifdef AD_SUPPORT #include "adprog.h" /***************************** AnalogDevicesSync ************************/ /** Attempt to synchronize with an Analog Device ARM micro. Sends a backspace and reads back the microcontrollers response. Performs multiple retries. Exits the program on error, returns to caller in the case of success. */ static void AnalogDevicesSync(ISP_ENVIRONMENT *IspEnvironment) { BINARY sync; /* Holds sync command. */ AD_SYNC_RESPONSE response; /* Response from micro. */ int sync_attempts; /* Number of retries. */ /* Make sure we don't read garbage later instead of the */ /* response we expect from the micro. */ ClearSerialPortBuffers(IspEnvironment); DebugPrintf(2, "Synchronizing\n"); /* Progress report. */ sync = ANALOG_DEVICES_SYNC_CHAR; /* Build up sync command. */ /* Perform the actual sync attempt. First send the sync */ /* character, the attempt to read back the response. For the */ /* AD ARM micro this is a fixed length block. If response is */ /* received attempt to validate it by comparing the first */ /* characters to those expected. If the received block does */ /* not validate or is incomplete empty the serial buffer and */ /* retry. */ for (sync_attempts = 0; sync_attempts < 5; sync_attempts++) { SendComPortBlock(IspEnvironment, &sync, 1); if (ReceiveComPortBlockComplete(IspEnvironment, &response, sizeof(response), 500) == 0) { if (memcmp(response.product_id, ANALOG_DEVICES_SYNC_RESPONSE, ANALOG_DEVICES_SYNC_SIZE) == 0) { return; } else { DumpString(3, &response, sizeof(response), "Unexpected response to sync attempt "); } } else { DebugPrintf(3, "No (or incomplete) answer on sync attempt\n"); } ClearSerialPortBuffers(IspEnvironment); } DebugPrintf(1, "No (or unacceptable) answer on sync attempt\n"); exit(4); } typedef struct { char start1; char start2; BINARY bytes; char cmd; BINARY address_h; BINARY address_u; BINARY address_m; BINARY address_l; BINARY data[251]; } AD_PACKET; /***************************** AnalogDevicesFormPacket ******************/ /** Create an Analog Devices communication packet from the constituent elements. \param [in] cmd The command being sent, one of 'E' for erase, 'W' for write, 'V' for verify or 'R' for run.. \param [in] no_bytes the number of data bytes to send with the command in the packet. \param [in] address the address to apply the command to. \param [in] data the data to send with the packet, may be null if no_bytes is zero. \param[out] packet that will be filled. */ static void AnalogDevicesFormPacket(ISP_ENVIRONMENT *IspEnvironment, char cmd, int no_bytes, unsigned int address, const void *data, AD_PACKET *packet) { BINARY checksum; const BINARY *data_in; int i; (void)IspEnvironment; /* never used in this function */ /* Some sanity checking on the arguments. These should only */ /* fail if there is a bug in the caller. */ /* Check 1) that the number of data bytes is in an acceptable */ /* range, 2) that we have a non-null pointer if data is being */ /* put in the packet and 3) that we have a non-null pointer to */ /* the packet to be filled. We just exit with an error message */ /* if any of these tests fail. */ if ((no_bytes < 0) || (no_bytes > 250)) { DebugPrintf(1, "The number of bytes (%d) passed to FormPacket is invalid.\n", no_bytes); exit(-1); } if ((data == 0) && (no_bytes != 0)) { DebugPrintf(1, "A null pointer to data paased to FormPacket when data was expected.\n"); exit(-1); } if (packet == 0) { DebugPrintf(1, "A null packet pointer was passed to FormPacket.\n"); exit(-1); } checksum = 0; /* Checksum starts at zero. */ data_in = (BINARY*) data; /* Pointer pun so we can walk through */ /* the data. */ packet->start1 = 0x7; /* The start of the packet is constant.*/ packet->start2 = 0xE; /* Fill in the rest of the packet and calculate the checksum */ /* as we go. */ /* The number of bytes is the number of data bytes + the */ /* address bytes + the command byte. */ packet->bytes = (BINARY)(no_bytes + 5); checksum += packet->bytes; /* The command for the packet being sent. No error checking */ /* done on this. */ packet->cmd = cmd; checksum += cmd; /* Now break up the address and place in the proper packet */ /* locations. */ packet->address_l = (BINARY)(address & 0xFF); packet->address_m = (BINARY)((address >> 8) & 0xFF); packet->address_u = (BINARY)((address >> 16) & 0xFF); packet->address_h = (BINARY)((address >> 24) & 0xFF); checksum += packet->address_l; checksum += packet->address_m; checksum += packet->address_u; checksum += packet->address_h; /* Copy the data bytes into the packet. We could use memcpy */ /* but we have to calculate the checksum anyway. */ for (i = 0; i < no_bytes; i++) { packet->data[i] = data_in[i]; checksum += data_in[i]; } /* Finally, add the checksum to the end of the packet. */ packet->data[i] = (BINARY)-checksum; } /***************************** AnalogDevicesSendPacket ******************/ /** Send a previously form Analog Devices communication. Retry a couple of times if needed but fail by exiting the program if no ACK is forthcoming. \param [in] packet the packet to send. */ static void AnalogDevicesSendPacket(ISP_ENVIRONMENT *IspEnvironment, const AD_PACKET * packet) { BINARY response; int retry = 0; do { retry++; /* Make sure we don't read garbage later instead of */ /* the response we expect from the micro. */ ClearSerialPortBuffers(IspEnvironment); /* Send the packet, the size is the number of data */ /* bytes in the packet plus 3 bytes worth of header */ /* plus checksum. */ SendComPortBlock(IspEnvironment, packet, packet->bytes + 4); /* Receive the response and check, return to caller */ /* if successful. */ if (ReceiveComPortBlockComplete(IspEnvironment, &response, 1, 5000) == 0) { if (response == ANALOG_DEVICES_ACK) { DebugPrintf(3, "Packet Sent\n"); return; } if (response != ANALOG_DEVICES_NAK) { DebugPrintf(3, "Unexpected response to packet (%x)\n", (int)response); } DebugPrintf(2, "*"); } } while (retry < 3); DebugPrintf(1, "Send packet failed\n"); exit(-1); } /***************************** AnalogDevicesErase ***********************/ /** Erase the Analog Devices micro. We take the simple way out and just erase the whole thing. */ static void AnalogDevicesErase(ISP_ENVIRONMENT *IspEnvironment) { BINARY pages; AD_PACKET packet; pages = 0; DebugPrintf(2, "Erasing .. "); AnalogDevicesFormPacket(IspEnvironment, 'E', 1, 0, &pages, &packet); AnalogDevicesSendPacket(IspEnvironment, &packet); DebugPrintf(2, "Erased\n"); } #define AD_PACKET_SIZE (250) /***************************** AnalogDevicesWrite ***********************/ /** Write the program. \param [in] data the program to download to the micro. \param [in] address where to start placing the program. \param [in] bytes the size of the progrm to download. */ static void AnalogDevicesWrite(ISP_ENVIRONMENT *IspEnvironment, const void *data, long address, size_t bytes) { AD_PACKET packet; const BINARY *prog_data; DebugPrintf(2, "Writing %d bytes ", bytes); prog_data = (const BINARY*) data; while (bytes > AD_PACKET_SIZE) { AnalogDevicesFormPacket(IspEnvironment, 'W', AD_PACKET_SIZE, address, prog_data, &packet); AnalogDevicesSendPacket(IspEnvironment, &packet); address += AD_PACKET_SIZE; prog_data += AD_PACKET_SIZE; bytes -= AD_PACKET_SIZE; DebugPrintf(2, "."); } if (bytes > 0) { AnalogDevicesFormPacket(IspEnvironment, 'W', bytes, address, prog_data, &packet); AnalogDevicesSendPacket(IspEnvironment, &packet); DebugPrintf(2, "."); } } /***************************** AnalogDevicesDownload ********************/ /** Perform the download into an Analog Devices micro. As a quick and * dirty hack against flash relocations at 0x80000 * \return 0 if ok, error code else * \ToDo: possible to implement the return value instead of calling * exit() in sub-functions */ int AnalogDevicesDownload(ISP_ENVIRONMENT *IspEnvironment) { AnalogDevicesSync(IspEnvironment); AnalogDevicesErase(IspEnvironment); if (IspEnvironment->BinaryLength > 0x80000) { DebugPrintf(2, "Note: Flash remapped 0x80000 to 0.\n"); AnalogDevicesWrite(IspEnvironment, IspEnvironment->BinaryContent + 0x80000, 0, IspEnvironment->BinaryLength-0x80000); } else { AnalogDevicesWrite(IspEnvironment, IspEnvironment->BinaryContent, 0, IspEnvironment->BinaryLength); } return (0); } #endif // AD_SUPPORT lpc21isp_197/adprog.h100666 0 0 3472 12077715112 13020 0ustar usergroup/****************************************************************************** Project: Portable command line ISP for NXP LPC1000 / LPC2000 family and Analog Devices ADUC70xx Filename: adprog.h Compiler: Microsoft VC 6/7, Microsoft VS2008, Microsoft VS2010, GCC Cygwin, GCC Linux, GCC ARM ELF Author: Martin Maurer (Martin.Maurer@clibb.de) Copyright: (c) Martin Maurer 2003-2011, All rights reserved Portions Copyright (c) by Aeolus Development 2004 http://www.aeolusdevelopment.com This file is part of lpc21isp. lpc21isp is free software: you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation, either version 3 of the License, or any later version. lpc21isp is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License and GNU General Public License along with lpc21isp. If not, see . */ #define ANALOG_DEVICES_SYNC_CHAR ((BINARY)0x08) #define ANALOG_DEVICES_SYNC_RESPONSE ("ADuC") #define ANALOG_DEVICES_SYNC_SIZE (strlen(ANALOG_DEVICES_SYNC_RESPONSE)) #define ANALOG_DEVICES_ACK 0x6 #define ANALOG_DEVICES_NAK 0x7 typedef struct { BINARY product_id[15]; BINARY version[3]; BINARY reserved[4]; BINARY terminator[2]; } AD_SYNC_RESPONSE; int AnalogDevicesDownload(ISP_ENVIRONMENT *IspEnvironment); lpc21isp_197/gpl.txt100666 0 0 105755 12072733210 12757 0ustar usergroup GNU GENERAL PUBLIC LICENSE Version 3, 29 June 2007 Copyright (C) 2007 Free Software Foundation, Inc. Everyone is permitted to copy and distribute verbatim copies of this license document, but changing it is not allowed. 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Each version is given a distinguishing version number. If the Library as you received it specifies that a certain numbered version of the GNU Lesser General Public License "or any later version" applies to it, you have the option of following the terms and conditions either of that published version or of any later version published by the Free Software Foundation. If the Library as you received it does not specify a version number of the GNU Lesser General Public License, you may choose any version of the GNU Lesser General Public License ever published by the Free Software Foundation. If the Library as you received it specifies that a proxy can decide whether future versions of the GNU Lesser General Public License shall apply, that proxy's public statement of acceptance of any version is permanent authorization for you to choose that version for the Library. lpc21isp_197/lpc21isp.c100666 0 0 274473 12263447377 13263 0ustar usergroup/****************************************************************************** Project: Portable command line ISP for NXP LPC family and Analog Devices ADUC70xx Filename: lpc21isp.c Compiler: Microsoft VC 6/7, Microsoft VS2008, Microsoft VS2010, GCC Cygwin, GCC Linux, GCC ARM ELF Author: Martin Maurer (Martin.Maurer@clibb.de) Copyright: (c) Martin Maurer 2003-2014, All rights reserved Portions Copyright (c) by Aeolus Development 2004 http://www.aeolusdevelopment.com This file is part of lpc21isp. lpc21isp is free software: you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation, either version 3 of the License, or any later version. lpc21isp is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License and GNU General Public License along with lpc21isp. If not, see . */ #if defined(_WIN32) #if !defined __BORLANDC__ #include "StdAfx.h" // Precompiled Header for WIN32 #endif #endif // defined(_WIN32) #include "lpc21isp.h" // if using propriatory serial port communication (customize attached lpc21isp.h) #include "adprog.h" #include "lpcprog.h" #include "lpcterm.h" /* Change-History: 1.00 2004-01-08 Initial Version, tested for MSVC6/7 and GCC under Cygwin 1.01 2004-01-10 Porting to Linux (at least compiling must work) 1.02 2004-01-10 Implemented conversion intel hex format -> binary 1.03 2004-01-25 Preparation to upload to public website 1.04 2004-02-12 Merged in bugfixes by Soeren Gust 1.05 2004-03-14 Implement printing of error codes as text / strings 1.06 2004-03-09 Merged in bugfixes by Charles Manning: The '?' sychronisation does not reliably respond to the first '?'. I added some retries. The LPC2106 sometimes responds to the '?' by echoing them back. This sometimes causes an attempt to match "?Synchonized". Added code to strip off any leading '?'s. Timeouts were too long. Change from RTS/CTS to no flow control. Done because many/most people will use only 3-wire comms. Added some progress tracing. 1.07 2004-03-14 Implement handling of control lines for easier booting 1.08 2004-04-01 Bugfix for upload problem 1.09 2004-04-03 Redesign of upload routine Now always 180 byte blocks are uploaded, to prevent small junks in uuencoding 1.10 2004-04-03 Clear buffers before sending commands to LPC21xx, this prevents synchronizing errors when previously loaded program does a lot of output, so FIFO of PC runs full 1.11 2004-04-03 Small optimization for controlling reset line otherwise termonly starts LPC twice, free PC buffers 1.12 2004-04-04 Add switch to enable logging terminal output to lpc21isp.log 1.13 2004-05-19 Merged in improvement by Charles Manning: Instead of exiting the wrong hex file size is corrected 1.14 2004-07-07 Merged in improvement by Alex Holden: Remove little/big endian dependancy 1.15 2004-09-27 Temporary improvement by Cyril Holweck: Removed test (data echoed = data transmited) on the main data transfert, since this was the biggest failure reason and is covered by checksome anyway. Added COMPILE_FOR_LPC21, to have target dump it's own memory to stdout. 1.16 2004-10-09 Merged in bugfix / improvement by Sinelnikov Evgeny I found out that Linux and Windows serial port initialization are different with pinouts states. My board don't get reset signal at first cycle of DTR pinout moving. And I add this moving to initalization cycle. 1.17 2004-10-21 Changes by Cyril Holweck Divide main, take out the real programming function, that can also be used by a target to copy its own code to another. 1.18 2004-10-26 Changes by Cyril Holweck Added a "G 0 A\r\n" at end of programming to run code. 1.19 2004-11-03 Changes by Robert Adsett Add support for Analog Devices. Separate file load from programming. Change from a debug on/off flag to debug level Remove if (debug) tests and replace with DebugPrintf statements. Change serial I/O and timing so that the system dependancies are isolated to a few portability functions. Add support for binary serial I/O. Add doxygen support. 1.20 2004-11-07 Preparation for multiport booting (factory support) 1.21 2004-11-08 Bugfix from Robert Adsett BinaryLength was not initialized 1.22 2004-11-08 Changes from Cyril Holweck / Evgeny Sinelnikov Forgotten IspEnvironment-> and bugfixes if COMPILE_FOR_LINUX If COMPILE_FOR_LPC21, PhilipsDownload() 'acts as' main(): - it should not be static and should return int. - no sub-function can use exit() but only return () Use 'char' instead of 'byte' ;) 1.23 2005-01-16 Build in automatic detection of LPC chiptype (needed for 256 KByte support) 1.24B 2005-06-02 Changes by Thiadmer Riemersma: completed support for other chip types (LPC213x series and others). 1.24C 2005-06-11 Changes by Thiadmer Riemersma: added the device ID codes for chip types LPC2131 and LPC2132. 1.25 2005-06-19 Martin Maurer: Setup more parameters in DCB, otherwise wrong code is downloaded (only Windows and Cygwin) when a previous program has changed these parameters Check exact string of "G 0 A\r\n0\r\n" instead of whole received buffer, to prevent checking of already received by program start (error on running program, but reports CMD_SUCCESS) Add ifdefs for all baudrates (needed only for high baudrate, which seem to be not available on Macs...) 1.26 2005-06-26 Martin Maurer: Correct check again: "G 0 A\r\n0\r\n" is cutted, because of reboot (error on running program, but reports CMD_SUCCESS) 1.27 2005-06-29 Martin Maurer: Add LPC chip ID's (thanks to Robert from Philips) for missing LPC213x and upcoming new LPC214x chips (currently untested, because i don't have access to these chips, please give me feedback !) 1.28 2005-07-27 Anders Rosvall / Embedded Artists AB: Changed the reset timeout to 500 ms when entering the bootloader. Some external reset controllers have quite long timeout periods, so extening the timeout delay would be a good thing. 1.29 2005-09-14 Rob Jansen: Added functionality to download to RAM and run from there. In LoadFile() added record types 04 (Extended Linear Address Record) and 05 (Start Linear Address Record), added address offset (IspEnvironment->BinaryOffset) and start address (...->StartAddress). Changed PhilipsDownload to skip all Flash prepare/erase/copy commands. Note: Tested with VC7 only 1.30 2005-10-04 Rob Jansen: - forgot to change the version string in 1.29 - Wrong text in LoadFile corrected (printed text mentions record type 05, this should be 04 - Changed LoadFile to accept multiple record types 04 - Changed LoadFile to check on memory size, will not load more than x MB if linear extended address records are used 1.31 2005-11-13 Martin Maurer: Thanks to Frank Gutmann Updated number of sectors in device table for LPC2194, LPC2292 and LPC2294 1.32 2005-12-02 Martin Maurer: Corrected missing control of RTS/DTR in case user selected -termonly and -control Small correction (typo in debug) 1.33 2006-10-01 Jean-Marc Koller: Added support for MacOS X (difference on how to set termios baudrate). 1.34 2006-10-01 Cyril Holweck: Made it compile again for lpc21isp Added const keyword to constant variables to make it better code for embeded target. (decrease RAM usage) Replaced all regular call to printf() by DebugPrintf() Removed call to scanf() (not much usefull and cost a lot to my target) 1.35 2006-22-01 Cyril Holweck Added feature for LPC21: will start downloading at Sector 1 and upward, to finish with Sector 0, the one containing the checksum controling BSL entry 1.36 2006-25-01 Cyril Holweck PhilipsDownload() will now return a unique error code for each error 1.37 2006-10-03 Jeroen Domburg Added LPC2103 (and only the 2103, I can't find the IDs for 2101/2102) Corrected a loop which occured if the program completely fits in sector 0 1.38 2007-01-05 Ray Molenkamp Added feature for LPC21: Wipe entire device before programming to enable reflashing of chips with the lpc codeprotection feature enabled. 1.39 2007-01-12 Martin Maurer Added initial support for new processors LPC23xx and LPC24xx 1.40 2007-01-22 Martin Maurer Correction of chip id of LPC2458 1.41 2007-01-28 Jean-Marc Koller Modified Terminal() to disable ECHO with termios only once, instead of modifying and restoring termios in each getch and kbhit call (which caused a strange echo behaviour in MacOS X). 1.42 2007-01-28 Rob Probin Added -localecho command to allow local echoing in terminal mode for use where target does not echo back keystrokes. 1.43 2007-01-29 Martin Maurer Moved keyboard handling routines to own subroutines, so they can be used during aborting synchronisation. Newest cygwin made problems, StringOscillator always contained '\0x0d' at the end, when calling lpc21isp from batch file 1.44 2007-02-23 Yang Yang Added feature for LPC21: Verify the data in Flash after every writes to sector. To detect errors in writing to Flash ROM. 1.45 2007-02-25 Martin Maurer Replace printf syntax of DumpString by a simple pointer to a string printf syntax is a nice thing, but it is not working :-( and therefore makes debugging much more difficult... Moved VERSION_STR to top of file to avoid possible cosmetical errors 1.46 2007-02-25 Martin Maurer Again corrected debug output: should solve output of (FFFFFFB5) instead of (B5) 1.47 2007-02-27 Robert Adsett Raised timeout on AD send packet function. 1.48 2007-04-20 Martin Maurer Thanks to Josef Wolf for preventing to overwrite over end of array 1.49 2007-10-16 New Option -halfduplex allow single wire using. Implemented and tested only for Windows. Data Resend implemented. 1.50 2007-10-31 Changes by Simon Ellwood Formated the code for readablity Fixed some c++ compiler issues 1.51 2007-11-20 Changes by Simon Ellwood Split into seperate files Made more modular so when used in an embedded mode only the required code is built 1.52 2008-01-22 Changes by Manuel Koeppen Made compileable again for linux and windows Fixed bug in ClearSerialPortBuffers (linux) 1.53 2008-02-25 Changes by Michael Roth Get priority of debug messages with -control right 1.54 2008-03-03 Martin Maurer Try to bring lpc21isp back to a useable state in Windows, Cygwin, Linux and Mac OS. Merged in changes by Erika Stefanini, which were done only for old version 1.49: Added device ids for revision B chips 1.55 2008-03-03 Martin Maurer Thanks to Fausto Marzoli, bugfix for compiling latest version under Linux 1.56 2008-04-01 Steve Franks Integrate FreeBSD patch. Add support for swapping and/or inverting RTS & DTR 1.57 2008-04-06 Mauricio Scaff Changed OpenSerialPort to work with MacOS Corrected the number of sectors in some 512K devices (28 instead of 27) Added support for LPC2387 and LPC2388 Defined BL error 19 (Code Protected) 1.58 2008-05-10 Herbert Demmel dh2@demmel.com I had the special requirement to integrate the program into my own Windows software compiled with Borland C++ Builder 5. I had to do some minor changes for Borland (see defined __BORLANDC__) and modified to code slightly to have some simple callbacks for screen i/o (see define INTEGRATED_IN_WIN_APP). Please note that I do *not* check / modify the part for AnalogDevices !! Besides that I fixed some minor issues: added dcb.fOutxCtsFlow = FALSE and dcb.fOutxDsrFlow = FALSE (sometimes required) Now comparing one character less of answer to "Now launching ... code" command 1.59 2008-07-07 Peter Hayward Fixed freeze under Windows XP SP2 by removing redundant call to SetCommMask. 1.60 2008-07-21 Martin Maurer Added uptodate part ids for LPC2458, LPC2468 and LPC2478 Add comment "obsolete" for older part ids for LPC2458 and LPC2468 Add ", " between compile date and time 1.61 2008-10-21 Fausto Marzoli (thanks to Geoffrey Wossum for the patches) Fix for compiling latest version under Linux and "ControlLinesSwapped" issue 1.62 2008-11-19 Martin Maurer Added (untested) support for LPC2109 Added (untested) support for LPC2361 / LPC2362 Heavy update of part identification number of LPC23xx and LPC24xx Correct bug, that hex file must exist, when "-detectonly" is used Correct Makefile.vc: use /Fe instead of -o 1.63 2008-11-23 Martin Maurer Changed to GNU Lesser General Public License 1.64 2009-01-19 Steve Franks __FREEBSD__ changed to __FreeBSD__ at some point, plus other com port fixes 1.65 2009-03-26 Vito Marolda Added pre-erasure of sector 0 to invalidate checksum before starting modification of the other sectors, so that the bootloader restarts if programming gets aborted while writing on a non-empty part. 1.66 2009-03-26 Vito Marolda Corrected interpretation of intel hex record 03 which is execution start address and not data segment address 1.67 2009-04-19 SASANO Takayoshi Add OpenBSD support 1.68 2009-05-17 Martin Maurer Merge in changes done by Bruno Quoitin (baudrate problem when __APPLE__ is used) Remove TABs from source code and replaced them with spaces 1.69 2009-06-18 Martin Maurer Add support for LPC17xx devices 1.70 2009-06-29 Martin Maurer Further improvement of LPC17xx support Workaround for booter (4.1) of LPC17xx, which does not echo all sent characters (0D,0A,...) ISP command GO seems to be broken: Sending 'G 196 T(0A)' Answer(Length=15): 'G 196 T(0A)0(0D)(0A)' leads to 'prefetch_abort_exception(0D)(0A)1FFF07A5' No solution known...need your help here... Manual workaround: Use DTR and RTS toggling to start application (e.g. 2 batch files) 1.71 2009-07-19 Martin Maurer Added LPC17xx with CPUID starting with 0x26 (not according user manual) 1.72 2009-09-14 Martin Maurer Add support for LPC13xx devices 1.73 2009-09-14 Martin Maurer Correct again (hopefully the last time) the CPUIDs for some LPC17xx devices (Now according to User Manual LPC17xx Version 00.07 (31 July 2009)) 1.74 2009-09-14 Mario Ivancic Added support for multiple HEX files, besed on internal version 1.37B. NOTE: this feature is used in production in 1.37B but is not tested in this version. Added numeric debug level command line switch -debugn, n=[0-5] Added command line scitch -try n to specify nQuestionMarks limit. Default: 100 Merged in DoNotStart patch from cgommel_new Static functions declarations moved from lpc21isp.h to this file Modified LoadFile() to return error_code instead exit(1) Removed IspEnvironment.debug_level, all code uses global debug_level 1.75 2010-01-05 Martin Maurer Added support for LPC11xx devices (not tested at all) Changed Product in LPC_DEVICE_TYPE from number to string to distinguish new LPC11 devices Changed "unsigned" to "unsigned int" in LPC_DEVICE_TYPE 1.76 2010-02-01 Published test version without source code 1.77 2010-02-01 Martin Maurer Corrected chip id of LPC1342 and LPC1343 Added a new chip type for LPC11xx and LPC13xx microcontrollers Use higher area of RAM with LPC11xx and LPC13xx, because lower RAM is occupied by ISP Add code to lpcprog.c to read unique id, but not yet activate. Adapt block sizes for copying for each model of LPC11xx and LPC13xx 1.78 2010-02-16 Martin Maurer Corrected chip id of LPC1751 Added support for LPC1759, LPC1767 and LPC1769 1.79 2010-02-19 Andrew Pines Added __APPLE__ flag to CFLAGS in Makefile to detect and handle OS X Added -Wall to Makefile to report warnings more comprehensively Added #define in lpc21isp.h to substitute strnicmp with strncasecmp (needed for Unix) Fixed a few format specifiers in lpcprog.c to eliminate some warnings 1.80 2010-03-04 Philip Munts Added entries to LPCtypes[] in lpcprog.c for obsolete revisions of LPC2364/6/8/78. Added entry to LPCtypes[] in lpcprog.c for new LPC2387. 1.81 2011-03-30 Mario Ivancic As per message #517 from Thiadmer Riemersma, removed WaitForWatchDog and WatchDogSeconds in PhilipsDownload(). 1.82 2011-06-25 Moses McKnight Corrected MaxCopySize for a number of the LPC11xx series Added support for several more LPC11xx and LPC11Cxx series 1.83 2011-08-02 Martin Maurer Thanks to Conurus for detecting and fixing a bug with patching checksum (patching was too early, chip id was not yet available) (Re-)Added code to start downloaded via "G 0 T", when using LPC1xxx (Starting code at position 0 seems to work, compare to comment of version 1.70) Changed some occurances of Philips to NXP Added -static to Makefile (thanks to Camilo) Added support for LPC1311/01 and LPC1313/01 (they have separate identifiers) Correct flash size of LPC1342 to 16 KByte (thanks to Decio) Abort programming when unknown NXP chip id is detected 1.84 2012-09-27 Philip Munts Added chip id's for more LPC11xx parts, per UM10398 Rev. 11 26 July 2012 1.85 2012-12-13 Philip Munts Fixed conditional compilation logic in lpc21isp.h to allow compiling for ARM Linux. 1.86 2012-12-14 diskrepairman Added devices: LPC1114/203 LPC1114/303 LPC1114/323 LPC1114/333 LPC1115/303 1.87 2012-12-18 Philip Munts Added a section of code to ResetTarget() in lpc21isp.c to allow using Linux GPIO pin to control reset and ISP. 1.88 2013-04-25 Torsten Lang, Uwe Schneider GmbH Fixed answer evaluation Added sector tables for LPC1833 XON/XOFF handling according to LPC manual Changed COMMTIMEOUTS settings according to MS help Changed waiting code from tick counting to system time usage Set MM timers to 1ms resolution (otherwise waiting in the serial driver is limited to multiples of 10ms) Send all commands with according to NXP UM Change answer evaluation to match at least LPC17xx and LPC18xx families (LPC17xx just mirrors the first character of the LF sequence, LPC18xx mirrors the first character and adds an which then will lead to a sequence, all other lines are terminated with as documented) Change answer formatting by filtering leading characters because they can be left over from a previous response Store residual data of an answer (required for the J command which will deliver two words in case of the LPC18xx) Expanded configuration table by second identification word and usage flag Do a two stage scan in case that a device with two identification words is detected 1.89 2013-06-27 Martin Maurer Thanks to Manuel and Henri for bugfixes and speed-ups Bugfix: In case of LPC8XX, XON/XOFF handling must be switched off, otherwise download gets broken, because XON/XOFF are filtered out... 1.90 2013-06-27 Martin Maurer Add checksum calculation for LPC8XX winmm function only available in MSVC, put ifdefs around Workaround for lost characters of LPC8XX 1.91 2013-06-28 Torsten Lang, Uwe Schneider GmbH Minor bugfix for the residual data handling 1.92 2013-06-29 Martin Maurer Thanks to Phil for reporting Linux compile errors Update README 1.93 2013-07-05 Andrew Pines changed Makefile to exclude "-static" from CFLAGS when building for OS X changed serial timeout for *nix to use select added -boothold argument to assert ISP throughtout programming sequence added support for -try command line argument (was in help, didn't actually work) 1.94 2013-08-10 Martin Maurer Add (assumed) part id values for LPC4333 and LPC4337 Correct table entries for all LPC43xx part id numbers (missing flag for two word part ids and second word for LPC4333 and LPC4353) Merge in optimization (thanks to Stefan) to skip empty sectors Correct help output of "-boothold" Add workaround table entry for LPC4357 and word1 equal to 0x0EF60000 Bugfix for wrong check of word0/word1 combination Correct a lot entries in lpc property table of LPC18xx and LPC43xx LPC18xx and LPC43xx: Add warning message, that wipe erases only bank A 1.95 2014-01-08 Martin Maurer Add a lot of new chip ids for LPC1763, LPC11Exx, LPC11Uxx (completely untested because I don't have these chips) Corrected checking of 2 field chip ids (must be masked) Corrected Makefile (-static) Move while directory with files into a subdirectory 1.96 2014-01-08 Martin Maurer merged changes by Moses McKnight Added devices: LPC1315, LPC1316, LPC1317, LPC1345, LPC1346, LPC1347 Add .gitignore file (MM: Removed *.layout) Remove lpc21isp.depend 2014-01-08 Martin Maurer merged bugfix by smartavionics: - Wrong length in ReceiveComPort - Enable SerialTimeoutTick 2014-01-08 Martin Maurer merged bugfix by justyn: - Fix the total sector size fields for 1114.../323 and 1114.../333 2014-01-08 Martin Maurer merged bugfix by imyller: - Support for bad UARTs: added -writedelay command-line switch 1.97 2014-01-09 Martin Maurer Add some new chip ids for LPC11xx Updated .gitignore file (Now with ignored *.layout) Removed *.layout from lpc21isp project Removed *.depend from lpc21isp project */ // Please don't use TABs in the source code !!! // Don't forget to update the version string that is on the next line #define VERSION_STR "1.97" #if defined COMPILE_FOR_WINDOWS || defined COMPILE_FOR_CYGWIN static char RxTmpBuf[256]; // save received data to this buffer for half-duplex char * pRxTmpBuf = RxTmpBuf; #endif #if !defined COMPILE_FOR_LPC21 int debug_level = 2; #endif static void ControlModemLines(ISP_ENVIRONMENT *IspEnvironment, unsigned char DTR, unsigned char RTS); static unsigned char Ascii2Hex(unsigned char c); #ifdef COMPILE_FOR_WINDOWS static void SerialTimeoutSet(ISP_ENVIRONMENT *IspEnvironment, unsigned timeout_milliseconds); static int SerialTimeoutCheck(ISP_ENVIRONMENT *IspEnvironment); #endif // COMPILE_FOR_WINDOWS static int AddFileHex(ISP_ENVIRONMENT *IspEnvironment, const char *arg); static int AddFileBinary(ISP_ENVIRONMENT *IspEnvironment, const char *arg); static int LoadFile(ISP_ENVIRONMENT *IspEnvironment, const char *filename, int FileFormat); /************* Portability layer. Serial and console I/O differences */ /* are taken care of here. */ #if defined COMPILE_FOR_WINDOWS || defined COMPILE_FOR_CYGWIN static void OpenSerialPort(ISP_ENVIRONMENT *IspEnvironment) { DCB dcb; COMMTIMEOUTS commtimeouts; #ifdef _MSC_VER /* Torsten Lang 2013-05-06 Switch to higher timer resolution (we want to use 1ms timeouts in the serial device driver!) */ (void)timeBeginPeriod(1UL); #endif // _MSC_VER IspEnvironment->hCom = CreateFile(IspEnvironment->serial_port, GENERIC_READ | GENERIC_WRITE,0,NULL,OPEN_EXISTING,FILE_ATTRIBUTE_NORMAL,NULL); if (IspEnvironment->hCom == INVALID_HANDLE_VALUE) { DebugPrintf(1, "Can't open COM-Port %s ! - Error: %ld\n", IspEnvironment->serial_port, GetLastError()); exit(2); } DebugPrintf(3, "COM-Port %s opened...\n", IspEnvironment->serial_port); GetCommState(IspEnvironment->hCom, &dcb); dcb.BaudRate = atol(IspEnvironment->baud_rate); dcb.ByteSize = 8; dcb.StopBits = ONESTOPBIT; dcb.Parity = NOPARITY; dcb.fDtrControl = DTR_CONTROL_DISABLE; dcb.fOutX = TRUE; // TL TODO - according to LPC manual! FALSE; dcb.fInX = TRUE; // TL TODO - according to LPC manual! FALSE; dcb.fNull = FALSE; dcb.fRtsControl = RTS_CONTROL_DISABLE; // added by Herbert Demmel - iF CTS line has the wrong state, we would never send anything! dcb.fOutxCtsFlow = FALSE; dcb.fOutxDsrFlow = FALSE; if (SetCommState(IspEnvironment->hCom, &dcb) == 0) { DebugPrintf(1, "Can't set baudrate %s ! - Error: %ld", IspEnvironment->baud_rate, GetLastError()); exit(3); } /* * Peter Hayward 02 July 2008 * * The following call is only needed if the WaitCommEvent * or possibly the GetCommMask functions are used. They are * *not* in this implimentation. However, under Windows XP SP2 * on my laptop the use of this call causes XP to freeze (crash) while * this program is running, e.g. in section 5/6/7 ... of a largish * download. Removing this *unnecessary* call fixed the problem. * At the same time I've added a call to SetupComm to request * (not necessarity honoured) the operating system to provide * large I/O buffers for high speed I/O without handshaking. * * SetCommMask(IspEnvironment->hCom,EV_RXCHAR | EV_TXEMPTY); */ SetupComm(IspEnvironment->hCom, 32000, 32000); SetCommMask(IspEnvironment->hCom, EV_RXCHAR | EV_TXEMPTY); // Torsten Lang 2013-05-06: ReadFile may hang indefinitely with MAXDWORD/0/1/0/0 on FTDI devices!!! commtimeouts.ReadIntervalTimeout = MAXDWORD; commtimeouts.ReadTotalTimeoutMultiplier = MAXDWORD; commtimeouts.ReadTotalTimeoutConstant = 1; commtimeouts.WriteTotalTimeoutMultiplier = 0; commtimeouts.WriteTotalTimeoutConstant = 0; SetCommTimeouts(IspEnvironment->hCom, &commtimeouts); } #endif // defined COMPILE_FOR_WINDOWS || defined COMPILE_FOR_CYGWIN #if defined COMPILE_FOR_LINUX static void OpenSerialPort(ISP_ENVIRONMENT *IspEnvironment) { IspEnvironment->fdCom = open(IspEnvironment->serial_port, O_RDWR | O_NOCTTY | O_NONBLOCK); if (IspEnvironment->fdCom < 0) { int err = errno; DebugPrintf(1, "Can't open COM-Port %s ! (Error: %dd (0x%X))\n", IspEnvironment->serial_port, err, err); exit(2); } DebugPrintf(3, "COM-Port %s opened...\n", IspEnvironment->serial_port); /* clear input & output buffers, then switch to "blocking mode" */ tcflush(IspEnvironment->fdCom, TCOFLUSH); tcflush(IspEnvironment->fdCom, TCIFLUSH); fcntl(IspEnvironment->fdCom, F_SETFL, fcntl(IspEnvironment->fdCom, F_GETFL) & ~O_NONBLOCK); tcgetattr(IspEnvironment->fdCom, &IspEnvironment->oldtio); /* save current port settings */ bzero(&IspEnvironment->newtio, sizeof(IspEnvironment->newtio)); IspEnvironment->newtio.c_cflag = CS8 | CLOCAL | CREAD; #if defined(__FreeBSD__) || defined(__OpenBSD__) if(cfsetspeed(&IspEnvironment->newtio,(speed_t) strtol(IspEnvironment->baud_rate,NULL,10))) { DebugPrintf(1, "baudrate %s not supported\n", IspEnvironment->baud_rate); exit(3); }; #else #ifdef __APPLE__ #define NEWTERMIOS_SETBAUDARTE(bps) IspEnvironment->newtio.c_ispeed = IspEnvironment->newtio.c_ospeed = bps; #else #define NEWTERMIOS_SETBAUDARTE(bps) IspEnvironment->newtio.c_cflag |= bps; #endif switch (atol(IspEnvironment->baud_rate)) { #ifdef B1152000 case 1152000: NEWTERMIOS_SETBAUDARTE(B1152000); break; #endif // B1152000 #ifdef B576000 case 576000: NEWTERMIOS_SETBAUDARTE(B576000); break; #endif // B576000 #ifdef B230400 case 230400: NEWTERMIOS_SETBAUDARTE(B230400); break; #endif // B230400 #ifdef B115200 case 115200: NEWTERMIOS_SETBAUDARTE(B115200); break; #endif // B115200 #ifdef B57600 case 57600: NEWTERMIOS_SETBAUDARTE(B57600); break; #endif // B57600 #ifdef B38400 case 38400: NEWTERMIOS_SETBAUDARTE(B38400); break; #endif // B38400 #ifdef B19200 case 19200: NEWTERMIOS_SETBAUDARTE(B19200); break; #endif // B19200 #ifdef B9600 case 9600: NEWTERMIOS_SETBAUDARTE(B9600); break; #endif // B9600 // Special value // case 32000: NEWTERMIOS_SETBAUDARTE(32000); break; default: { DebugPrintf(1, "unknown baudrate %s\n", IspEnvironment->baud_rate); exit(3); } } #endif IspEnvironment->newtio.c_iflag = IGNPAR | IGNBRK | IXON | IXOFF; IspEnvironment->newtio.c_oflag = 0; /* set input mode (non-canonical, no echo,...) */ IspEnvironment->newtio.c_lflag = 0; cfmakeraw(&IspEnvironment->newtio); IspEnvironment->newtio.c_cc[VTIME] = 1; /* inter-character timer used */ IspEnvironment->newtio.c_cc[VMIN] = 0; /* blocking read until 0 chars received */ tcflush(IspEnvironment->fdCom, TCIFLUSH); if(tcsetattr(IspEnvironment->fdCom, TCSANOW, &IspEnvironment->newtio)) { DebugPrintf(1, "Could not change serial port behaviour (wrong baudrate?)\n"); exit(3); } } #endif // defined COMPILE_FOR_LINUX #if defined COMPILE_FOR_WINDOWS || defined COMPILE_FOR_CYGWIN static void CloseSerialPort(ISP_ENVIRONMENT *IspEnvironment) { CloseHandle(IspEnvironment->hCom); #ifdef _MSC_VER /* Torsten Lang 2013-05-06 Switch back timer resolution */ (void)timeEndPeriod(1UL); #endif // _MSC_VER } #endif // defined COMPILE_FOR_WINDOWS || defined COMPILE_FOR_CYGWIN #if defined COMPILE_FOR_LINUX static void CloseSerialPort(ISP_ENVIRONMENT *IspEnvironment) { tcflush(IspEnvironment->fdCom, TCOFLUSH); tcflush(IspEnvironment->fdCom, TCIFLUSH); tcsetattr(IspEnvironment->fdCom, TCSANOW, &IspEnvironment->oldtio); close(IspEnvironment->fdCom); } #endif // defined COMPILE_FOR_LINUX #if defined COMPILE_FOR_WINDOWS || defined COMPILE_FOR_CYGWIN void ControlXonXoffSerialPort(ISP_ENVIRONMENT *IspEnvironment, unsigned char XonXoff) { DCB dcb; GetCommState(IspEnvironment->hCom, &dcb); if(XonXoff) { dcb.fOutX = TRUE; dcb.fInX = TRUE; } else { dcb.fOutX = FALSE; dcb.fInX = FALSE; } if (SetCommState(IspEnvironment->hCom, &dcb) == 0) { DebugPrintf(1, "Can't set XonXoff ! - Error: %ld", GetLastError()); exit(3); } } #endif // defined COMPILE_FOR_WINDOWS || defined COMPILE_FOR_CYGWIN #if defined COMPILE_FOR_LINUX void ControlXonXoffSerialPort(ISP_ENVIRONMENT *IspEnvironment, unsigned char XonXoff) { if(tcgetattr(IspEnvironment->fdCom, &IspEnvironment->newtio)) { DebugPrintf(1, "Could not get serial port behaviour\n"); exit(3); } if(XonXoff) { IspEnvironment->newtio.c_iflag |= IXON; IspEnvironment->newtio.c_iflag |= IXOFF; } else { IspEnvironment->newtio.c_iflag &= ~IXON; IspEnvironment->newtio.c_iflag &= ~IXOFF; } if(tcsetattr(IspEnvironment->fdCom, TCSANOW, &IspEnvironment->newtio)) { DebugPrintf(1, "Could not set serial port behaviour\n"); exit(3); } } #endif // defined COMPILE_FOR_LINUX /***************************** SendComPortBlock *************************/ /** Sends a block of bytes out the opened com port. \param [in] s block to send. \param [in] n size of the block. */ void SendComPortBlock(ISP_ENVIRONMENT *IspEnvironment, const void *s, size_t n) { #if defined COMPILE_FOR_WINDOWS || defined COMPILE_FOR_CYGWIN unsigned long realsize; size_t m; unsigned long rxsize; char * pch; char * rxpch; #endif // defined COMPILE_FOR_WINDOWS || defined COMPILE_FOR_CYGWIN DumpString(4, s, n, "Sending "); #if defined COMPILE_FOR_WINDOWS || defined COMPILE_FOR_CYGWIN if (IspEnvironment->HalfDuplex == 0) { WriteFile(IspEnvironment->hCom, s, n, &realsize, NULL); } else { pch = (char *)s; rxpch = RxTmpBuf; pRxTmpBuf = RxTmpBuf; // avoid buffer otherflow if (n > sizeof (RxTmpBuf)) n = sizeof (RxTmpBuf); for (m = 0; m < n; m++) { WriteFile(IspEnvironment->hCom, pch, 1, &realsize, NULL); if ((*pch != '?') || (n != 1)) { do { ReadFile(IspEnvironment->hCom, rxpch, 1, &rxsize, NULL); }while (rxsize == 0); } pch++; rxpch++; } *rxpch = 0; // terminate echo string } #endif // defined COMPILE_FOR_WINDOWS || defined COMPILE_FOR_CYGWIN #if defined COMPILE_FOR_LINUX || defined COMPILE_FOR_LPC21 write(IspEnvironment->fdCom, s, n); #endif // defined COMPILE_FOR_LINUX || defined COMPILE_FOR_LPC21 if (IspEnvironment->WriteDelay == 1) { Sleep(100); // 100 ms delay after each block (makes lpc21isp to work with bad UARTs) } } /***************************** SendComPort ******************************/ /** Sends a string out the opened com port. \param [in] s string to send. */ void SendComPort(ISP_ENVIRONMENT *IspEnvironment, const char *s) { SendComPortBlock(IspEnvironment, s, strlen(s)); } /***************************** SerialTimeoutTick ************************/ /** Performs a timer tick. In this simple case all we do is count down with protection against underflow and wrapping at the low end. */ static void SerialTimeoutTick(ISP_ENVIRONMENT *IspEnvironment) { if (IspEnvironment->serial_timeout_count <= 1) { IspEnvironment->serial_timeout_count = 0; } else { IspEnvironment->serial_timeout_count--; } } /***************************** ReceiveComPortBlock **********************/ /** Receives a buffer from the open com port. Returns all the characters ready (waits for up to 'n' milliseconds before accepting that no more characters are ready) or when the buffer is full. 'n' is system dependant, see SerialTimeout routines. \param [out] answer buffer to hold the bytes read from the serial port. \param [in] max_size the size of buffer pointed to by answer. \param [out] real_size pointer to a long that returns the amout of the buffer that is actually used. */ static void ReceiveComPortBlock(ISP_ENVIRONMENT *IspEnvironment, void *answer, unsigned long max_size, unsigned long *real_size) { char tmp_string[32]; #if defined COMPILE_FOR_WINDOWS || defined COMPILE_FOR_CYGWIN if (IspEnvironment->HalfDuplex == 0) ReadFile(IspEnvironment->hCom, answer, max_size, real_size, NULL); else { *real_size = strlen (pRxTmpBuf); if (*real_size) { if (max_size >= *real_size) { strncpy((char*) answer, pRxTmpBuf, *real_size); RxTmpBuf[0] = 0; pRxTmpBuf = RxTmpBuf; } else { strncpy((char*) answer, pRxTmpBuf, max_size); *real_size = max_size; pRxTmpBuf += max_size; } } else ReadFile(IspEnvironment->hCom, answer, max_size, real_size, NULL); } #endif // defined COMPILE_FOR_WINDOWS || defined COMPILE_FOR_CYGWIN #if defined COMPILE_FOR_LPC21 *real_size = read(IspEnvironment->fdCom, answer, max_size); #endif // defined COMPILE_FOR_LPC21 #if defined COMPILE_FOR_LINUX { fd_set readSet; struct timeval timeVal; FD_ZERO(&readSet); // clear the set FD_SET(IspEnvironment->fdCom,&readSet); // add this descriptor to the set timeVal.tv_sec=0; // set up the timeout waiting for one to come ready (500ms) timeVal.tv_usec=500*1000; if(select(FD_SETSIZE,&readSet,NULL,NULL,&timeVal)==1) // wait up to 500 ms or until our data is ready { *real_size=read(IspEnvironment->fdCom, answer, max_size); } else { // timed out, show no characters received and timer expired *real_size=0; IspEnvironment->serial_timeout_count=0; } } #endif // defined COMPILE_FOR_LINUX sprintf(tmp_string, "Read(Length=%ld): ", (*real_size)); DumpString(5, answer, (*real_size), tmp_string); if (*real_size == 0) { SerialTimeoutTick(IspEnvironment); } } /***************************** SerialTimeoutSet *************************/ /** Sets (or resets) the timeout to the timout period requested. Starts counting to this period. This timeout support is a little odd in that the timeout specifies the accumulated deadtime waiting to read not the total time waiting to read. They should be close enought to the same for this use. Used by the serial input routines, the actual counting takes place in ReceiveComPortBlock. \param [in] timeout_milliseconds the time in milliseconds to use for timeout. Note that just because it is set in milliseconds doesn't mean that the granularity is that fine. In many cases (particularly Linux) it will be coarser. */ static void SerialTimeoutSet(ISP_ENVIRONMENT *IspEnvironment, unsigned timeout_milliseconds) { #if defined COMPILE_FOR_LINUX IspEnvironment->serial_timeout_count = timeout_milliseconds / 100; #elif defined COMPILE_FOR_LPC21 IspEnvironment->serial_timeout_count = timeout_milliseconds * 200; #else #ifdef _MSC_VER IspEnvironment->serial_timeout_count = timeGetTime() + timeout_milliseconds; #else IspEnvironment->serial_timeout_count = timeout_milliseconds; #endif // _MSC_VER #endif } /***************************** SerialTimeoutCheck ***********************/ /** Check to see if the serial timeout timer has run down. \retval 1 if timer has run out. \retval 0 if timer still has time left. */ static int SerialTimeoutCheck(ISP_ENVIRONMENT *IspEnvironment) { #if defined COMPILE_FOR_WINDOWS || defined COMPILE_FOR_CYGWIN #ifdef _MSC_VER if ((signed long)(IspEnvironment->serial_timeout_count - timeGetTime()) < 0) { return 1; } #else if (IspEnvironment->serial_timeout_count == 0) { return 1; } #endif // _MSC_VER #else if (IspEnvironment->serial_timeout_count == 0) { return 1; } #endif return 0; } #if defined COMPILE_FOR_LINUX || defined COMPILE_FOR_CYGWIN /***************************** getch ************************************/ /** Replacement for the common dos function of the same name. Reads a single unbuffered character from the 'keyboard'. \return The character read from the keyboard. */ int getch(void) { char ch; /* Read in one character */ read(0,&ch,1); return ch; } #endif // defined COMPILE_FOR_LINUX || defined COMPILE_FOR_CYGWIN #if defined COMPILE_FOR_LINUX || defined COMPILE_FOR_CYGWIN /***************************** kbhit ************************************/ /** Replacement for the common dos function of the same name. Indicates if there are characters to be read from the console. \retval 0 No characters ready. \retval 1 Characters from the console ready to be read. */ int kbhit(void) { /* return 0 for no key pressed, 1 for key pressed */ int return_value = 0; /* time struct for the select() function, to only wait a little while */ struct timeval select_time; /* file descriptor variable for the select() call */ fd_set readset; /* we're only interested in STDIN */ FD_ZERO(&readset); FD_SET(STDIN_FILENO, &readset); /* how long to block for - this must be > 0.0, but could be changed to some other setting. 10-18msec seems to work well and only minimally load the system (0% CPU loading) */ select_time.tv_sec = 0; select_time.tv_usec = 10; /* is there a keystroke there? */ if (select(1, &readset, NULL, NULL, &select_time)) { /* yes, remember it */ return_value = 1; } /* return with what we found out */ return return_value; } struct termios keyboard_origtty; #endif // defined COMPILE_FOR_LINUX || defined COMPILE_FOR_CYGWIN /***************************** PrepareKeyboardTtySettings ***************/ /** Set the keyboard tty to be able to check for new characters via kbhit getting them via getch */ void PrepareKeyboardTtySettings(void) { #if defined COMPILE_FOR_LINUX || defined COMPILE_FOR_CYGWIN /* store the current tty settings */ if (!tcgetattr(0, &keyboard_origtty)) { struct termios tty; /* start with the current settings */ tty = keyboard_origtty; /* make modifications to put it in raw mode, turn off echo */ tty.c_lflag &= ~ICANON; tty.c_lflag &= ~ECHO; tty.c_lflag &= ~ISIG; tty.c_cc[VMIN] = 1; tty.c_cc[VTIME] = 0; /* put the settings into effect */ tcsetattr(0, TCSADRAIN, &tty); } #endif } /***************************** ResetKeyboardTtySettings *****************/ /** Reset the keyboard tty to original settings */ void ResetKeyboardTtySettings(void) { #if defined COMPILE_FOR_LINUX || defined COMPILE_FOR_CYGWIN /* reset the tty to its original settings */ tcsetattr(0, TCSADRAIN, &keyboard_origtty); #endif } #if !defined COMPILE_FOR_LPC21 /***************************** ControlModemLines ************************/ /** Controls the modem lines to place the microcontroller into various states during the programming process. error rather abruptly terminates the program. \param [in] DTR the state to set the DTR line to. \param [in] RTS the state to set the RTS line to. */ static void ControlModemLines(ISP_ENVIRONMENT *IspEnvironment, unsigned char DTR, unsigned char RTS) { //handle wether to invert the control lines: DTR ^= IspEnvironment->ControlLinesInverted; RTS ^= IspEnvironment->ControlLinesInverted; //handle wether to swap the control lines if (IspEnvironment->ControlLinesSwapped) { unsigned char tempRTS; tempRTS = RTS; RTS = DTR; DTR = tempRTS; } #if defined COMPILE_FOR_LINUX int status; if (ioctl(IspEnvironment->fdCom, TIOCMGET, &status) == 0) { DebugPrintf(3, "ioctl get ok, status = %X\n",status); } else { DebugPrintf(1, "ioctl get failed\n"); } if (DTR) status |= TIOCM_DTR; else status &= ~TIOCM_DTR; if (RTS) status |= TIOCM_RTS; else status &= ~TIOCM_RTS; if (ioctl(IspEnvironment->fdCom, TIOCMSET, &status) == 0) { DebugPrintf(3, "ioctl set ok, status = %X\n",status); } else { DebugPrintf(1, "ioctl set failed\n"); } if (ioctl(IspEnvironment->fdCom, TIOCMGET, &status) == 0) { DebugPrintf(3, "ioctl get ok, status = %X\n",status); } else { DebugPrintf(1, "ioctl get failed\n"); } #endif // defined COMPILE_FOR_LINUX #if defined COMPILE_FOR_WINDOWS || defined COMPILE_FOR_CYGWIN if (DTR) EscapeCommFunction(IspEnvironment->hCom, SETDTR); else EscapeCommFunction(IspEnvironment->hCom, CLRDTR); if (RTS) EscapeCommFunction(IspEnvironment->hCom, SETRTS); else EscapeCommFunction(IspEnvironment->hCom, CLRRTS); #endif // defined COMPILE_FOR_WINDOWS || defined COMPILE_FOR_CYGWIN #if defined COMPILE_FOR_LPC21 LPC_RESET(DTR); LPC_BSL(RTS); #endif DebugPrintf(3, "DTR (%d), RTS (%d)\n", DTR, RTS); } /***************************** ClearSerialPortBuffers********************/ /** Empty the serial port buffers. Cleans things to a known state. */ void ClearSerialPortBuffers(ISP_ENVIRONMENT *IspEnvironment) { #if defined COMPILE_FOR_LINUX /* variables to store the current tty state, create a new one */ struct termios origtty, tty; /* store the current tty settings */ tcgetattr(IspEnvironment->fdCom, &origtty); // Flush input and output buffers tty=origtty; tcsetattr(IspEnvironment->fdCom, TCSAFLUSH, &tty); /* reset the tty to its original settings */ tcsetattr(IspEnvironment->fdCom, TCSADRAIN, &origtty); #endif // defined COMPILE_FOR_LINUX #if defined COMPILE_FOR_WINDOWS || defined COMPILE_FOR_CYGWIN PurgeComm(IspEnvironment->hCom, PURGE_TXABORT | PURGE_RXABORT | PURGE_TXCLEAR | PURGE_RXCLEAR); #endif // defined COMPILE_FOR_WINDOWS || defined COMPILE_FOR_CYGWIN } #endif // !defined COMPILE_FOR_LPC21 #if defined COMPILE_FOR_LINUX /***************************** Sleep ************************************/ /** Provide linux replacement for windows function. \param [in] Milliseconds the time to wait for in milliseconds. */ void Sleep(unsigned long MilliSeconds) { usleep(MilliSeconds*1000); //convert to microseconds } #endif // defined COMPILE_FOR_LINUX #if defined COMPILE_FOR_LPC21 /** Provide linux replacement for windows function. \note I implement that one in my private header file today... \param [in] Milliseconds the time to wait for in milliseconds. */ /*static void Sleep(unsigned long MilliSeconds) { # warning Sleep function not implemented } */ #endif // defined COMPILE_FOR_LPC21 /************* Applicationlayer. */ #if !defined COMPILE_FOR_LPC21 /***************************** DebugPrintf ******************************/ /** Prints a debug string depending the current debug level. The higher the debug level the more detail that will be printed. Each print has an associated level, the higher the level the more detailed the debugging information being sent. \param [in] level the debug level of the print statement, if the level is less than or equal to the current debug level it will be printed. \param [in] fmt a standard printf style format string. \param [in] ... the usual printf parameters. */ #if !defined INTEGRATED_IN_WIN_APP void DebugPrintf(int level, const char *fmt, ...) { va_list ap; if (level <= debug_level) { char pTemp[2000]; va_start(ap, fmt); //vprintf(fmt, ap); vsprintf(pTemp, fmt, ap); TRACE(pTemp); va_end(ap); fflush(stdout); } } #endif #endif // !defined COMPILE_FOR_LPC21 /***************************** ReceiveComPort ***************************/ /** Receives a buffer from the open com port. Returns when the buffer is filled, the numer of requested linefeeds has been received or the timeout period has passed. The bootloaders may send 0x0d,0x0a,0x0a or 0x0d,0x0a as linefeed pattern 2013-06-28 Torsten Lang Note: We *could* filter out surplus 0x0a characters like in but as we don't know how the individual bootloader behaves we don't want to wait for possible surplus (which would slow down the transfer). Thus, we just terminate after the expected number of sequences and leave it to the command handler in lpcprog.c to filter out surplus characters which then occur as leading character in answers or echoed commands. \param [in] ISPEnvironment. \param [out] Answer buffer to hold the bytes read from the serial port. \param [in] MaxSize the size of buffer pointed to by Answer. \param [out] RealSize pointer to a long that returns the amout of the buffer that is actually used. \param [in] WantedNr0x0A the maximum number of linefeeds to accept before returning. \param [in] timeOutMilliseconds the maximum amount of time to wait before reading with an incomplete buffer. */ void ReceiveComPort(ISP_ENVIRONMENT *IspEnvironment, const char *Ans, unsigned long MaxSize, unsigned long *RealSize, unsigned long WantedNr0x0A, unsigned timeOutMilliseconds) { unsigned long tmp_realsize; unsigned long nr_of_0x0A = 0; unsigned long nr_of_0x0D = 0; int eof = 0; unsigned long p; unsigned char *Answer; unsigned char *endPtr; char tmp_string[32]; static char residual_data[128] = {'\0'}; int lf = 0; Answer = (unsigned char*) Ans; SerialTimeoutSet(IspEnvironment, timeOutMilliseconds); *RealSize = 0; endPtr = NULL; do { if (residual_data[0] == '\0') { /* Receive new data */ ReceiveComPortBlock(IspEnvironment, Answer + (*RealSize), MaxSize - (*RealSize), &tmp_realsize); } else { /* Take over any old residual data */ strcpy((char *)Answer, residual_data); tmp_realsize = strlen((char *)Answer); residual_data[0] = '\0'; } if (tmp_realsize != 0) { for (p = (*RealSize); p < (*RealSize) + tmp_realsize; p++) { /* Torsten Lang 2013-05-06 Scan for 0x0d,0x0a,0x0a and 0x0d,0x0a as linefeed pattern */ if (Answer[p] == 0x0a) { if (lf != 0) { nr_of_0x0A++; lf = 0; if (nr_of_0x0A >= WantedNr0x0A) { endPtr = &Answer[p+1]; } } } else if (Answer[p] == 0x0d) { nr_of_0x0D++; lf = 1; } else if (((signed char) Answer[p]) < 0) { eof = 1; lf = 0; } else if (lf != 0) { nr_of_0x0D++; nr_of_0x0A++; lf = 0; if (nr_of_0x0A >= WantedNr0x0A) { endPtr = &Answer[p+1]; } } } (*RealSize) += tmp_realsize; } } while (((*RealSize) < MaxSize) && (SerialTimeoutCheck(IspEnvironment) == 0) && (nr_of_0x0A < WantedNr0x0A) && !eof); /* Torsten Lang 2013-05-06 Store residual data and cut answer after expected nr. of 0x0a */ Answer[*RealSize] = '\0'; if (endPtr != NULL) { strcpy(residual_data, (char *)endPtr); *endPtr = '\0'; /* Torsten Lang 2013-06-28 Update size info */ *RealSize = endPtr-Answer; } sprintf(tmp_string, "Answer(Length=%ld): ", (*RealSize)); DumpString(3, Answer, (*RealSize), tmp_string); } #if !defined COMPILE_FOR_LPC21 /***************************** ReceiveComPortBlockComplete **************/ /** Receives a fixed block from the open com port. Returns when the block is completely filled or the timeout period has passed \param [out] block buffer to hold the bytes read from the serial port. \param [in] size the size of the buffer pointed to by block. \param [in] timeOut the maximum amount of time to wait before guvung up on completing the read. \return 0 if successful, non-zero otherwise. */ int ReceiveComPortBlockComplete(ISP_ENVIRONMENT *IspEnvironment, void *block, size_t size, unsigned timeout) { unsigned long realsize = 0, read; char *result; char tmp_string[32]; result = (char*) block; SerialTimeoutSet(IspEnvironment, timeout); do { ReceiveComPortBlock(IspEnvironment, result + realsize, size - realsize, &read); realsize += read; } while ((realsize < size) && (SerialTimeoutCheck(IspEnvironment) == 0)); sprintf(tmp_string, "Answer(Length=%ld): ", realsize); DumpString(3, result, realsize, tmp_string); if (realsize != size) { return 1; } return 0; } /***************************** ReadArguments ****************************/ /** Reads the command line arguments and parses it for the various options. Uses the same arguments as main. Used to separate the command line parsing from main and improve its readability. This should also make it easier to modify the command line parsing in the future. \param [in] argc the number of arguments. \param [in] argv an array of pointers to the arguments. */ static void ReadArguments(ISP_ENVIRONMENT *IspEnvironment, unsigned int argc, char *argv[]) { unsigned int i; if (argc >= 5) { for (i = 1; i < argc - 3; i++) { if (stricmp(argv[i], "-wipe") == 0) { IspEnvironment->WipeDevice = 1; DebugPrintf(3, "Wipe entire device before writing.\n"); continue; } if (stricmp(argv[i], "-bin") == 0) { IspEnvironment->FileFormat = FORMAT_BINARY; DebugPrintf(3, "Binary format file input.\n"); continue; } if (stricmp(argv[i], "-hex") == 0) { IspEnvironment->FileFormat = FORMAT_HEX; DebugPrintf(3, "Hex format file input.\n"); continue; } if (stricmp(argv[i], "-logfile") == 0) { IspEnvironment->LogFile = 1; DebugPrintf(3, "Log terminal output.\n"); continue; } if (stricmp(argv[i], "-detectonly") == 0) { IspEnvironment->DetectOnly = 1; IspEnvironment->ProgramChip = 0; DebugPrintf(3, "Only detect LPC chip part id.\n"); continue; } if(strnicmp(argv[i],"-debug", 6) == 0) { char* num; num = argv[i] + 6; while(*num && isdigit(*num) == 0) num++; if(isdigit(*num) != 0) debug_level = atoi( num); else debug_level = 4; DebugPrintf(3, "Turn on debug, level: %d.\n", debug_level); continue; } if (stricmp(argv[i], "-boothold") == 0) { IspEnvironment->BootHold = 1; DebugPrintf(3, "hold EnableBootLoader asserted throughout programming sequence.\n"); continue; } if (stricmp(argv[i], "-donotstart") == 0) { IspEnvironment->DoNotStart = 1; DebugPrintf(3, "Do NOT start MCU after programming.\n"); continue; } if(strnicmp(argv[i],"-try", 4) == 0) { int retry; retry=atoi(&argv[i][4]); if(retry>0) { IspEnvironment->nQuestionMarks=retry; DebugPrintf(3, "Retry count: %d.\n", IspEnvironment->nQuestionMarks); } else { fprintf(stderr,"invalid argument for -try: \"%s\"\n",argv[i]); } continue; } if (stricmp(argv[i], "-control") == 0) { IspEnvironment->ControlLines = 1; DebugPrintf(3, "Use RTS/DTR to control target state.\n"); continue; } if (stricmp(argv[i], "-controlswap") == 0) { IspEnvironment->ControlLinesSwapped = 1; DebugPrintf(3, "Use RTS to control reset, and DTR to control P0.14(ISP).\n"); continue; } if (stricmp(argv[i], "-controlinv") == 0) { IspEnvironment->ControlLinesInverted = 1; DebugPrintf(3, "Invert state of RTS & DTR (0=true/assert/set, 1=false/deassert/clear).\n"); continue; } if (stricmp(argv[i], "-halfduplex") == 0) { IspEnvironment->HalfDuplex = 1; DebugPrintf(3, "halfduplex serial communication.\n"); continue; } if (stricmp(argv[i], "-writedelay") == 0) { IspEnvironment->WriteDelay = 1; DebugPrintf(3, "Write delay enabled.\n"); continue; } if (stricmp(argv[i], "-ADARM") == 0) { IspEnvironment->micro = ANALOG_DEVICES_ARM; DebugPrintf(2, "Target: Analog Devices.\n"); continue; } if (stricmp(argv[i], "-NXPARM") == 0 || stricmp(argv[i], "-PHILIPSARM") == 0) { IspEnvironment->micro = NXP_ARM; DebugPrintf(2, "Target: NXP.\n"); continue; } if (stricmp(argv[i], "-Verify") == 0) { IspEnvironment->Verify = 1; DebugPrintf(2, "Verify after copy RAM to Flash.\n"); continue; } #ifdef INTEGRATED_IN_WIN_APP if (stricmp(argv[i], "-nosync") == 0) { IspEnvironment->NoSync = 1; DebugPrintf(2, "Performing no syncing, already done.\n"); continue; } #endif #ifdef TERMINAL_SUPPORT if (CheckTerminalParameters(IspEnvironment, argv[i])) { continue; } #endif if(*argv[i] == '-') DebugPrintf( 2, "Unknown command line option: \"%s\"\n", argv[i]); else { int ret_val; if(IspEnvironment->FileFormat == FORMAT_HEX) { ret_val = AddFileHex(IspEnvironment, argv[i]); } else { ret_val = AddFileBinary(IspEnvironment, argv[i]); } if( ret_val != 0) { DebugPrintf( 2, "Unknown command line option: \"%s\"\n", argv[i]); } } } // Newest cygwin delivers a '\x0d' at the end of argument // when calling lpc21isp from batch file for (i = 0; i < strlen(argv[argc - 1]) && i < (sizeof(IspEnvironment->StringOscillator) - 1) && argv[argc - 1][i] >= '0' && argv[argc - 1][i] <= '9'; i++) { IspEnvironment->StringOscillator[i] = argv[argc - 1][i]; } IspEnvironment->StringOscillator[i] = 0; IspEnvironment->serial_port = argv[argc - 3]; IspEnvironment->baud_rate = argv[argc - 2]; } if (argc < 5) { debug_level = (debug_level < 2) ? 2 : debug_level; } if (argc < 5) { DebugPrintf(2, "\n" "Portable command line ISP\n" "for NXP LPC family and Analog Devices ADUC 70xx\n" "Version " VERSION_STR " compiled for " COMPILED_FOR ": " __DATE__ ", " __TIME__ "\n" "Copyright (c) by Martin Maurer, 2003-2013, Email: Martin.Maurer@clibb.de\n" "Portions Copyright (c) by Aeolus Development 2004, www.aeolusdevelopment.com\n" "\n"); DebugPrintf(1, "Syntax: lpc21isp [Options] file[ file[ ...]] comport baudrate Oscillator_in_kHz\n\n" "Example: lpc21isp test.hex com1 115200 14746\n\n" "Options: -bin for uploading binary file\n" " -hex for uploading file in intel hex format (default)\n" " -term for starting terminal after upload\n" " -termonly for starting terminal without an upload\n" " -localecho for local echo in terminal\n" " -detectonly detect only used LPC chiptype (NXPARM only)\n" " -debug0 for no debug\n" " -debug3 for progress info only\n" " -debug5 for full debug\n" " -donotstart do not start MCU after download\n" " -try try n times to synchronise\n" " -wipe Erase entire device before upload\n" " -control for controlling RS232 lines for easier booting\n" " (Reset = DTR, EnableBootLoader = RTS)\n" " -boothold hold EnableBootLoader asserted throughout sequence\n" #ifdef INTEGRATED_IN_WIN_APP " -nosync Do not synchronize device via '?'\n" #endif " -controlswap swap RS232 control lines\n" " (Reset = RTS, EnableBootLoader = DTR)\n" " -controlinv Invert state of RTS & DTR \n" " (0=true/assert/set, 1=false/deassert/clear).\n" " -verify Verify the data in Flash after every writes to\n" " sector. To detect errors in writing to Flash ROM\n" " -logfile for enabling logging of terminal output to lpc21isp.log\n" " -halfduplex use halfduplex serial communication (i.e. with K-Line)\n" " -writedelay Add delay after serial port writes (for compatibility)\n" " -ADARM for downloading to an Analog Devices\n" " ARM microcontroller ADUC70xx\n" " -NXPARM for downloading to a chip of NXP LPC family (default)\n"); exit(1); } if (IspEnvironment->micro == NXP_ARM) { // If StringOscillator is bigger than 100 MHz, there seems to be something wrong if (strlen(IspEnvironment->StringOscillator) > 5) { DebugPrintf(1, "Invalid crystal frequency %s\n", IspEnvironment->StringOscillator); exit(1); } } } /***************************** ResetTarget ******************************/ /** Resets the target leaving it in either download (program) mode or run mode. \param [in] mode the mode to leave the target in. */ void ResetTarget(ISP_ENVIRONMENT *IspEnvironment, TARGET_MODE mode) { #if defined(__linux__) && defined(GPIO_RST) && defined(GPIO_ISP) // This code section allows using Linux GPIO pins to control the -RST and -ISP // signals of the target microcontroller. // // Build lpc21isp to use Linux GPIO like this: // // make CFLAGS="-Wall -DGPIO_ISP=23 -DGPIO_RST=18" // // The GPIO pins must be pre-configured in /etc/rc.local (or other startup script) // similar to the following: // // # Configure -ISP signal // echo 23 >/sys/class/gpio/export // echo out >/sys/class/gpio/gpio23/direction // echo 1 >/sys/class/gpio/gpio23/value // chown root.gpio /sys/class/gpio/gpio23/value // chmod 660 /sys/class/gpio/gpio23/value // // # Configure -RST signal // echo 18 >/sys/class/gpio/export // echo out >/sys/class/gpio/gpio18/direction // echo 1 >/sys/class/gpio/gpio18/value // chown root.gpio /sys/class/gpio/gpio18/value // chmod 660 /sys/class/gpio/gpio18/value // // Then if the user is a member of the gpio group, lpc21isp will not requre any // special permissions to access the GPIO signals. char gpio_isp_filename[256]; char gpio_rst_filename[256]; int gpio_isp; int gpio_rst; memset(gpio_isp_filename, 0, sizeof(gpio_isp_filename)); sprintf(gpio_isp_filename, "/sys/class/gpio/gpio%d/value", GPIO_ISP); memset(gpio_rst_filename, 0, sizeof(gpio_rst_filename)); sprintf(gpio_rst_filename, "/sys/class/gpio/gpio%d/value", GPIO_RST); gpio_isp = open(gpio_isp_filename, O_WRONLY); if (gpio_isp < 0) { fprintf(stderr, "ERROR: open() for %s failed, %s\n", gpio_isp_filename, strerror(errno)); exit(1); } gpio_rst = open(gpio_rst_filename, O_WRONLY); if (gpio_rst < 0) { fprintf(stderr, "ERROR: open() for %s failed, %s\n", gpio_rst_filename, strerror(errno)); exit(1); } switch (mode) { case PROGRAM_MODE : write(gpio_isp, "0\n", 2); // Assert -ISP Sleep(100); write(gpio_rst, "0\n", 2); // Assert -RST Sleep(500); write(gpio_rst, "1\n", 2); // Deassert -RST Sleep(100); write(gpio_isp, "1\n", 2); // Deassert -ISP Sleep(100); break;; case RUN_MODE : write(gpio_rst, "0\n", 2); // Assert -RST Sleep(500); write(gpio_rst, "1\n", 2); // Deassert -ISP Sleep(100); break;; } close(gpio_isp); close(gpio_rst); return; #endif if (IspEnvironment->ControlLines) { switch (mode) { /* Reset and jump to boot loader. */ case PROGRAM_MODE: ControlModemLines(IspEnvironment, 1, 1); Sleep(100); ClearSerialPortBuffers(IspEnvironment); Sleep(100); ControlModemLines(IspEnvironment, 0, 1); //Longer delay is the Reset signal is conected to an external rest controller Sleep(500); // Clear the RTS line after having reset the micro // Needed for the "GO
" ISP command to work */ if(!IspEnvironment->BootHold) { ControlModemLines(IspEnvironment, 0, 0); } break; /* Reset and start uploaded program */ case RUN_MODE: ControlModemLines(IspEnvironment, 1, 0); Sleep(100); ClearSerialPortBuffers(IspEnvironment); Sleep(100); ControlModemLines(IspEnvironment, 0, 0); Sleep(100); break; } } } /***************************** Ascii2Hex ********************************/ /** Converts a hex character to its equivalent number value. In case of an error rather abruptly terminates the program. \param [in] c the hex digit to convert. \return the value of the hex digit. */ static unsigned char Ascii2Hex(unsigned char c) { if (c >= '0' && c <= '9') { return (unsigned char)(c - '0'); } if (c >= 'A' && c <= 'F') { return (unsigned char)(c - 'A' + 10); } if (c >= 'a' && c <= 'f') { return (unsigned char)(c - 'a' + 10); } DebugPrintf(1, "Wrong Hex-Nibble %c (%02X)\n", c, c); exit(1); return 0; // this "return" will never be reached, but some compilers give a warning if it is not present } /***************************** AddFileHex *******************************/ /** Add a file to the list of files to read in, flag it as hex format. \param [in] IspEnvironment Programming environment. \param [in] arg The argument that was passed to the program as a file name. \return 0 on success, an error code otherwise. */ static int AddFileHex(ISP_ENVIRONMENT *IspEnvironment, const char *arg) { FILE_LIST *entry; // Add file to list. If cannot allocate storage for node return an error. entry = malloc(sizeof(FILE_LIST)); if( entry == 0) { DebugPrintf(1, "Error %d Could not allocated memory for file node %s\n", ERR_ALLOC_FILE_LIST, arg); return ERR_ALLOC_FILE_LIST; } // Build up entry and insert it at the start of the list. entry->name = arg; entry->prev = IspEnvironment->f_list; entry->hex_flag = 1; IspEnvironment->f_list = entry; return 0; // Success. } /***************************** AddFileBinary ****************************/ /** Add a file to the list of files to read in, flag it as binary format. \param [in] IspEnvironment Programming environment. \param [in] arg The argument that was passed to the program as a file name. \return 0 on success, an error code otherwise. */ static int AddFileBinary(ISP_ENVIRONMENT *IspEnvironment, const char *arg) { FILE_LIST *entry; // Add file to list. If cannot allocate storage for node return an error. entry = malloc(sizeof(FILE_LIST)); if( entry == 0) { DebugPrintf( 1, "Error %d Could not allocated memory for file node %s\n", ERR_ALLOC_FILE_LIST, arg); return ERR_ALLOC_FILE_LIST; } // Build up entry and insert it at the start of the list. entry->name = arg; entry->prev = IspEnvironment->f_list; entry->hex_flag = 0; IspEnvironment->f_list = entry; return 0; // Success. } #if 0 void ReadHexFile(ISP_ENVIRONMENT *IspEnvironment) { LoadFile(IspEnvironment); if (IspEnvironment->BinaryLength) { BINARY* FileContent = IspEnvironment->FileContent; unsigned long Pos; unsigned char RecordLength; unsigned short RecordAddress; unsigned long RealAddress = 0; unsigned char RecordType; unsigned char Hexvalue; unsigned long StartAddress; int BinaryOffsetDefined = 0; unsigned char i; DebugPrintf(3, "Converting file %s to binary format...\n", IspEnvironment->input_file); Pos = 0; while (Pos < IspEnvironment->BinaryLength) { if (FileContent[Pos] == '\r') { Pos++; continue; } if (FileContent[Pos] == '\n') { Pos++; continue; } if (FileContent[Pos] != ':') { DebugPrintf(1, "Missing start of record (':') wrong byte %c / %02X\n", FileContent[Pos], FileContent[Pos]); exit(1); } Pos++; RecordLength = Ascii2Hex(FileContent[Pos++]); RecordLength <<= 4; RecordLength |= Ascii2Hex(FileContent[Pos++]); DebugPrintf(4, "RecordLength = %02X\n", RecordLength); RecordAddress = Ascii2Hex(FileContent[Pos++]); RecordAddress <<= 4; RecordAddress |= Ascii2Hex(FileContent[Pos++]); RecordAddress <<= 4; RecordAddress |= Ascii2Hex(FileContent[Pos++]); RecordAddress <<= 4; RecordAddress |= Ascii2Hex(FileContent[Pos++]); DebugPrintf(4, "RecordAddress = %04X\n", RecordAddress); RealAddress = RealAddress - (RealAddress & 0xffff) + RecordAddress; DebugPrintf(4, "RealAddress = %08lX\n", RealAddress); RecordType = Ascii2Hex(FileContent[Pos++]); RecordType <<= 4; RecordType |= Ascii2Hex(FileContent[Pos++]); DebugPrintf(4, "RecordType = %02X\n", RecordType); if (RecordType == 0x00) // 00 - Data record { /* * Binary Offset is defined as soon as first data record read */ //BinaryOffsetDefined = 1; // Memory for binary file big enough ? while ((RealAddress + RecordLength - IspEnvironment->BinaryOffset) > IspEnvironment->BinaryMemSize) { IspEnvironment->BinaryMemSize <<= 1; // Double the size allocated !!! IspEnvironment->BinaryContent = (BINARY*) realloc(IspEnvironment->BinaryContent, IspEnvironment->BinaryMemSize); } // We need to know, what the highest address is, // how many bytes / sectors we must flash if (RealAddress + RecordLength - IspEnvironment->BinaryOffset > IspEnvironment->BinaryLength) { IspEnvironment->BinaryLength = RealAddress + RecordLength - IspEnvironment->BinaryOffset; DebugPrintf(3, "Image size now: %ld\n", IspEnvironment->BinaryLength); } for (i = 0; i < RecordLength; i++) { Hexvalue = Ascii2Hex(FileContent[Pos++]); Hexvalue <<= 4; Hexvalue |= Ascii2Hex(FileContent[Pos++]); IspEnvironment->BinaryContent[RealAddress + i - IspEnvironment->BinaryOffset] = Hexvalue; } } else if (RecordType == 0x01) // 01 - End of file record { break; } else if (RecordType == 0x02) // 02 - Extended segment address record { for (i = 0; i < RecordLength * 2; i++) // double amount of nibbles { RealAddress <<= 4; if (i == 0) { RealAddress = Ascii2Hex(FileContent[Pos++]); } else { RealAddress |= Ascii2Hex(FileContent[Pos++]); } } RealAddress <<= 4; } else if (RecordType == 0x03) // 03 - Start segment address record { for (i = 0; i < RecordLength * 2; i++) // double amount of nibbles { RealAddress <<= 4; if (i == 0) { RealAddress = Ascii2Hex(FileContent[Pos++]); } else { RealAddress |= Ascii2Hex(FileContent[Pos++]); } } RealAddress <<= 8; } else if (RecordType == 0x04) // 04 - Extended linear address record, used by IAR { for (i = 0; i < RecordLength * 2; i++) // double amount of nibbles { RealAddress <<= 4; if (i == 0) { RealAddress = Ascii2Hex(FileContent[Pos++]); } else { RealAddress |= Ascii2Hex(FileContent[Pos++]); } } RealAddress <<= 16; if (!BinaryOffsetDefined) { // set startaddress of BinaryContent // use of LPC_FLASHMASK to allow a memory range, not taking the first // [04] record as actual start-address. IspEnvironment->BinaryOffset = RealAddress & LPC_FLASHMASK; } else { if ((RealAddress & LPC_FLASHMASK) != IspEnvironment->BinaryOffset) { DebugPrintf(1, "New Extended Linear Address Record [04] out of memory range\n" "Current Memory starts at: 0x%08X, new Address is: 0x%08X", IspEnvironment->BinaryOffset, RealAddress); exit(1); } } } else if (RecordType == 0x05) // 05 - Start linear address record { StartAddress = 0; for (i = 0; i < RecordLength * 2; i++) // double amount of nibbles { StartAddress <<= 4; if (i == 0) { StartAddress = Ascii2Hex(FileContent[Pos++]); } else { StartAddress |= Ascii2Hex(FileContent[Pos++]); } } DebugPrintf(1,"Start Address = 0x%08X\n", StartAddress); IspEnvironment->StartAddress = StartAddress; } while (FileContent[Pos++] != 0x0a) // Search till line end { } } DebugPrintf(2, "\tconverted to binary format...\n"); // When debugging is switched on, output result of conversion to file debugout.bin if (debug_level >= 4) { int fdout; fdout = open("debugout.bin", O_RDWR | O_BINARY | O_CREAT | O_TRUNC, 0777); write(fdout, IspEnvironment->BinaryContent, IspEnvironment->BinaryLength); close(fdout); } } } #endif // #if 0 /***************************** LoadFile *********************************/ /** Loads the requested file to download into memory. \param [in] IspEnvironment structure containing input filename \param [in] filename the name of the file to read in. \param [in] FileFormat the format of the file to read in (FORMAT_HEX or FORMAT_BINARY) \return 0 if successful, otherwise an error code. */ static int LoadFile(ISP_ENVIRONMENT *IspEnvironment, const char *filename, int FileFormat) { int fd; int i; int BinaryOffsetDefined; unsigned long Pos; unsigned long FileLength; BINARY *FileContent; /**< Used to store the content of a hex */ /* file before converting to binary. */ unsigned long BinaryMemSize; fd = open(filename, O_RDONLY | O_BINARY); if (fd == -1) { DebugPrintf(1, "Can't open file %s\n", filename); return ERR_FILE_OPEN_HEX; } FileLength = lseek(fd, 0L, 2); // Get file size if (FileLength == (size_t)-1) { DebugPrintf(1, "\nFileLength = -1 !?!\n"); return ERR_FILE_SIZE_HEX; } lseek(fd, 0L, 0); // Just read the entire file into memory to parse. FileContent = (BINARY*) malloc(FileLength); if( FileContent == 0) { DebugPrintf( 1, "\nCouldn't allocate enough memory for file.\n"); return ERR_FILE_ALLOC_HEX; } BinaryOffsetDefined = 0; BinaryMemSize = IspEnvironment->BinaryLength; read(fd, FileContent, FileLength); close(fd); DebugPrintf(2, "File %s:\n\tloaded...\n", filename); // Intel-Hex -> Binary Conversion if (FileFormat == FORMAT_HEX) { unsigned char RecordLength; unsigned short RecordAddress; unsigned long RealAddress = 0; unsigned char RecordType; unsigned char Hexvalue; unsigned long StartAddress; DebugPrintf(3, "Converting file %s to binary format...\n", filename); Pos = 0; while (Pos < FileLength) { if (FileContent[Pos] == '\r') { Pos++; continue; } if (FileContent[Pos] == '\n') { Pos++; continue; } if (FileContent[Pos] != ':') { DebugPrintf(1, "Missing start of record (':') wrong byte %c / %02X\n", FileContent[Pos], FileContent[Pos]); exit(1); } Pos++; RecordLength = Ascii2Hex(FileContent[Pos++]); RecordLength <<= 4; RecordLength |= Ascii2Hex(FileContent[Pos++]); DebugPrintf(4, "RecordLength = %02X\n", RecordLength); RecordAddress = Ascii2Hex(FileContent[Pos++]); RecordAddress <<= 4; RecordAddress |= Ascii2Hex(FileContent[Pos++]); RecordAddress <<= 4; RecordAddress |= Ascii2Hex(FileContent[Pos++]); RecordAddress <<= 4; RecordAddress |= Ascii2Hex(FileContent[Pos++]); DebugPrintf(4, "RecordAddress = %04X\n", RecordAddress); RealAddress = RealAddress - (RealAddress & 0xffff) + RecordAddress; DebugPrintf(4, "RealAddress = %08lX\n", RealAddress); RecordType = Ascii2Hex(FileContent[Pos++]); RecordType <<= 4; RecordType |= Ascii2Hex(FileContent[Pos++]); DebugPrintf(4, "RecordType = %02X\n", RecordType); if (RecordType == 0x00) // 00 - Data record { /* * Binary Offset is defined as soon as first data record read */ BinaryOffsetDefined = 1; // Memory for binary file big enough ? while (RealAddress + RecordLength - IspEnvironment->BinaryOffset > BinaryMemSize) { if(!BinaryMemSize) BinaryMemSize = FileLength * 2; else BinaryMemSize <<= 1; IspEnvironment->BinaryContent = realloc(IspEnvironment->BinaryContent, BinaryMemSize); } // We need to know, what the highest address is, // how many bytes / sectors we must flash if (RealAddress + RecordLength - IspEnvironment->BinaryOffset > IspEnvironment->BinaryLength) { IspEnvironment->BinaryLength = RealAddress + RecordLength - IspEnvironment->BinaryOffset; DebugPrintf(3, "Image size now: %ld\n", IspEnvironment->BinaryLength); } for (i = 0; i < RecordLength; i++) { Hexvalue = Ascii2Hex(FileContent[Pos++]); Hexvalue <<= 4; Hexvalue |= Ascii2Hex(FileContent[Pos++]); IspEnvironment->BinaryContent[RealAddress + i - IspEnvironment->BinaryOffset] = Hexvalue; } } else if (RecordType == 0x01) // 01 - End of file record { break; } else if (RecordType == 0x02) // 02 - Extended segment address record { for (i = 0; i < RecordLength * 2; i++) // double amount of nibbles { RealAddress <<= 4; if (i == 0) { RealAddress = Ascii2Hex(FileContent[Pos++]); } else { RealAddress |= Ascii2Hex(FileContent[Pos++]); } } RealAddress <<= 4; } else if (RecordType == 0x03) // 03 - Start segment address record { unsigned long cs,ip; StartAddress = 0; for (i = 0; i < RecordLength * 2; i++) // double amount of nibbles { StartAddress <<= 4; if (i == 0) { StartAddress = Ascii2Hex(FileContent[Pos++]); } else { StartAddress |= Ascii2Hex(FileContent[Pos++]); } } cs = StartAddress >> 16; //high part ip = StartAddress & 0xffff; //low part StartAddress = cs*16+ip; //segmented 20-bit space DebugPrintf(1,"Start Address = 0x%08X\n", StartAddress); IspEnvironment->StartAddress = StartAddress; } else if (RecordType == 0x04) // 04 - Extended linear address record, used by IAR { for (i = 0; i < RecordLength * 2; i++) // double amount of nibbles { RealAddress <<= 4; if (i == 0) { RealAddress = Ascii2Hex(FileContent[Pos++]); } else { RealAddress |= Ascii2Hex(FileContent[Pos++]); } } RealAddress <<= 16; if (!BinaryOffsetDefined) { // set startaddress of BinaryContent // use of LPC_FLASHMASK to allow a memory range, not taking the first // [04] record as actual start-address. IspEnvironment->BinaryOffset = RealAddress & LPC_FLASHMASK; } else { if ((RealAddress & LPC_FLASHMASK) != IspEnvironment->BinaryOffset) { DebugPrintf(1, "New Extended Linear Address Record [04] out of memory range\n"); DebugPrintf(1, "Current Memory starts at: 0x%08X, new Address is: 0x%08X", IspEnvironment->BinaryOffset, RealAddress); return ERR_MEMORY_RANGE; } } } else if (RecordType == 0x05) // 05 - Start linear address record { StartAddress = 0; for (i = 0; i < RecordLength * 2; i++) // double amount of nibbles { StartAddress <<= 4; if (i == 0) { StartAddress = Ascii2Hex(FileContent[Pos++]); } else { StartAddress |= Ascii2Hex(FileContent[Pos++]); } } DebugPrintf(1,"Start Address = 0x%08X\n", StartAddress); IspEnvironment->StartAddress = StartAddress; } else { free( FileContent); DebugPrintf( 1, "Error %d RecordType %02X not yet implemented\n", ERR_RECORD_TYPE_LOADFILE, RecordType); return( ERR_RECORD_TYPE_LOADFILE); } while (FileContent[Pos++] != 0x0a) // Search till line end { } } DebugPrintf(2, "\tconverted to binary format...\n"); // When debugging is switched on, output result of conversion to file debugout.bin if (debug_level >= 4) { int fdout; fdout = open("debugout.bin", O_RDWR | O_BINARY | O_CREAT | O_TRUNC, 0777); write(fdout, IspEnvironment->BinaryContent, IspEnvironment->BinaryLength); close(fdout); } free( FileContent); // Done with file contents } else // FORMAT_BINARY { IspEnvironment->BinaryContent = FileContent; IspEnvironment->BinaryLength = FileLength; } DebugPrintf(2, "\timage size : %ld\n", IspEnvironment->BinaryLength); return 0; } /***************************** LoadFiles1 ********************************/ /** Loads the requested files to download into memory. \param [in] IspEnvironment structure containing input filename(s). \param [in] file simple linked list of files to read \return 0 if successful, otherwise an error code. */ static int LoadFiles1(ISP_ENVIRONMENT *IspEnvironment, const FILE_LIST *file) { int ret_val; if( file->prev != 0) { DebugPrintf( 3, "Follow file list %s\n", file->name); ret_val = LoadFiles1( IspEnvironment, file->prev); if( ret_val != 0) { return ret_val; } } DebugPrintf( 3, "Attempt to read File %s\n", file->name); if(file->hex_flag != 0) { ret_val = LoadFile(IspEnvironment, file->name, FORMAT_HEX); } else { ret_val = LoadFile(IspEnvironment, file->name, FORMAT_BINARY); } if( ret_val != 0) { return ret_val; } return 0; } /***************************** LoadFiles ********************************/ /** Loads the requested files to download into memory. \param [in] IspEnvironment structure containing input filename(s). \param [in] file simple linked list of files to read \return 0 if successful, otherwise an error code. */ static int LoadFiles(ISP_ENVIRONMENT *IspEnvironment) { int ret_val; ret_val = LoadFiles1(IspEnvironment, IspEnvironment->f_list); if( ret_val != 0) { exit(1); // return ret_val; } DebugPrintf( 2, "Image size : %ld\n", IspEnvironment->BinaryLength); // check length to flash for correct alignment, can happen with broken ld-scripts if (IspEnvironment->BinaryLength % 4 != 0) { unsigned long NewBinaryLength = ((IspEnvironment->BinaryLength + 3)/4) * 4; DebugPrintf( 2, "Warning: data not aligned to 32 bits, padded (length was %lX, now %lX)\n", IspEnvironment->BinaryLength, NewBinaryLength); IspEnvironment->BinaryLength = NewBinaryLength; } // When debugging is switched on, output result of conversion to file debugout.bin if(debug_level >= 4) { int fdout; DebugPrintf( 1, "Dumping image file.\n"); fdout = open("debugout.bin", O_RDWR | O_BINARY | O_CREAT | O_TRUNC, 0777); write(fdout, IspEnvironment->BinaryContent, IspEnvironment->BinaryLength); close(fdout); } return 0; } #endif // !defined COMPILE_FOR_LPC21 #ifndef COMPILE_FOR_LPC21 int PerformActions(ISP_ENVIRONMENT *IspEnvironment) { int downloadResult = -1; DebugPrintf(2, "lpc21isp version " VERSION_STR "\n"); /* Download requested, read in the input file. */ if (IspEnvironment->ProgramChip) { LoadFiles(IspEnvironment); } OpenSerialPort(IspEnvironment); /* Open the serial port to the microcontroller. */ ResetTarget(IspEnvironment, PROGRAM_MODE); ClearSerialPortBuffers(IspEnvironment); /* Perform the requested download. */ if (IspEnvironment->ProgramChip || IspEnvironment->DetectOnly) { switch (IspEnvironment->micro) { #ifdef LPC_SUPPORT case NXP_ARM: downloadResult = NxpDownload(IspEnvironment); break; #endif #ifdef AD_SUPPORT case ANALOG_DEVICES_ARM: downloadResult = AnalogDevicesDownload(IspEnvironment); break; #endif } if (downloadResult != 0) { CloseSerialPort(IspEnvironment); exit(downloadResult); } } if (IspEnvironment->StartAddress == 0 || IspEnvironment->TerminalOnly) { /* Only reset target if startaddress = 0 * Otherwise stay with the running program as started in Download() */ ResetTarget(IspEnvironment, RUN_MODE); } debug_level = 1; /* From now on there is no more debug output !! */ /* Therefore switch it off... */ #ifdef TERMINAL_SUPPORT // Pass control to Terminal which will provide a terminal if one was asked for // User asked for terminal emulation, provide a really dumb terminal. Terminal(IspEnvironment); #endif CloseSerialPort(IspEnvironment); /* All done, close the serial port to the */ return 0; } #endif /***************************** main *************************************/ /** main. Everything starts from here. \param [in] argc the number of arguments. \param [in] argv an array of pointers to the arguments. */ #if !defined COMPILE_FOR_LPC21 #if defined INTEGRATED_IN_WIN_APP int AppDoProgram(int argc, char *argv[]) #else int main(int argc, char *argv[]) #endif { ISP_ENVIRONMENT IspEnvironment; // Initialize debug level debug_level = 2; // Initialize ISP Environment memset(&IspEnvironment, 0, sizeof(IspEnvironment)); // Clear the IspEnviroment to a known value IspEnvironment.micro = NXP_ARM; // Default Micro IspEnvironment.FileFormat = FORMAT_HEX; // Default File Format IspEnvironment.ProgramChip = TRUE; // Default to Programming the chip IspEnvironment.nQuestionMarks = 100; IspEnvironment.DoNotStart = 0; IspEnvironment.BootHold = 0; ReadArguments(&IspEnvironment, argc, argv); // Read and parse the command line return PerformActions(&IspEnvironment); // Do as requested ! } #endif // !defined COMPILE_FOR_LPC21 /***************************** DumpString ******************************/ /** Prints an area of memory to stdout. Converts non-printables to hex. \param [in] level the debug level of the block to be dumped. If this is less than or equal to the current debug level than the dump will happen otherwise this just returns. \param [in] b pointer to an area of memory. \param [in] size the length of the memory block to print. \param [in] prefix string is a pointer to a prefix string. */ void DumpString(int level, const void *b, size_t size, const char *prefix_string) { size_t i; const char * s = (const char*) b; unsigned char c; DebugPrintf(level, prefix_string); DebugPrintf(level, "'"); for (i = 0; i < size; i++) { c = s[i]; if (c >= 0x20 && c <= 0x7e) /*isprint?*/ { DebugPrintf(level, "%c", c); } else { DebugPrintf(level, "(%02X)", c); } } DebugPrintf(level, "'\n"); } lpc21isp_197/lpc21isp.cbp100666 0 0 2752 12072733210 13510 0ustar usergroup lpc21isp_197/lpc21isp.h100666 0 0 23430 12263307400 13207 0ustar usergroup/****************************************************************************** Project: Portable command line ISP for NXP LPC1000 / LPC2000 family and Analog Devices ADUC70xx Filename: lsp21isp.h Compiler: Microsoft VC 6/7, Microsoft VS2008, Microsoft VS2010, GCC Cygwin, GCC Linux, GCC ARM ELF Author: Martin Maurer (Martin.Maurer@clibb.de) Copyright: (c) Martin Maurer 2003-2014, All rights reserved Portions Copyright (c) by Aeolus Development 2004 http://www.aeolusdevelopment.com This file is part of lpc21isp. lpc21isp is free software: you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation, either version 3 of the License, or any later version. lpc21isp is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License and GNU General Public License along with lpc21isp. If not, see . */ // #define INTEGRATED_IN_WIN_APP #if defined(_WIN32) && !defined(__CYGWIN__) #define COMPILE_FOR_WINDOWS #define COMPILED_FOR "Windows" #elif defined(__CYGWIN__) #define COMPILE_FOR_CYGWIN #define COMPILED_FOR "Cygwin" #elif (defined(__arm__) || defined(__thumb__)) && !defined(__linux__) #define COMPILE_FOR_LPC21 #define COMPILED_FOR "ARM" #define printf iprintf #elif defined(__APPLE__) #define COMPILE_FOR_LINUX #define COMPILED_FOR "Apple MacOS X" #elif defined(__FreeBSD__) #define COMPILE_FOR_LINUX #define COMPILED_FOR "FreeBSD" #elif defined(__OpenBSD__) #define COMPILE_FOR_LINUX #define COMPILED_FOR "OpenBSD" #else #define COMPILE_FOR_LINUX #define COMPILED_FOR "Linux" #endif // The Required features can be enabled / disabled here #define LPC_SUPPORT #ifndef COMPILE_FOR_LPC21 #define AD_SUPPORT #define TERMINAL_SUPPORT #endif #if defined COMPILE_FOR_WINDOWS || defined COMPILE_FOR_CYGWIN #include #include #endif // defined COMPILE_FOR_WINDOWS || defined COMPILE_FOR_CYGWIN #if defined COMPILE_FOR_WINDOWS #include //#define TRACE(x) OutputDebugString(x) #define TRACE(x) printf("%s",x) #endif // defined COMPILE_FOR_WINDOWS #if defined COMPILE_FOR_CYGWIN //#define TRACE(x) OutputDebugString(x) #define TRACE(x) printf("%s",x) #endif // defined COMPILE_FOR_WINDOWS #if defined COMPILE_FOR_LINUX #include #include #include #include #include #include extern void Sleep(unsigned long MilliSeconds); #define TRACE(x) printf("%s",x) #endif // defined COMPILE_FOR_LINUX #if defined COMPILE_FOR_LINUX || defined COMPILE_FOR_CYGWIN #include #include // for read and return value of lseek #include // for select_time extern int kbhit(void); extern int getch(void); extern struct termios keyboard_origtty; #endif // defined COMPILE_FOR_LINUX || defined COMPILE_FOR_CYGWIN #include // isdigit() #include // stdout #include #include #if defined (COMPILE_FOR_LINUX) #if defined(__OpenBSD__) #include #else #include #endif #endif #if defined COMPILE_FOR_LPC21 #include #include //#include // if using libc serial port communication #else #include #endif typedef enum { NXP_ARM, ANALOG_DEVICES_ARM } TARGET; typedef enum { PROGRAM_MODE, RUN_MODE } TARGET_MODE; typedef enum { FORMAT_BINARY, FORMAT_HEX } FILE_FORMAT_TYPE; typedef unsigned char BINARY; // Data type used for microcontroller /** Used to create list of files to read in. */ typedef struct file_list FILE_LIST; #define ERR_RECORD_TYPE_LOADFILE 55 /**< File record type not yet implemented. */ #define ERR_ALLOC_FILE_LIST 60 /**< Error allocation file list. */ #define ERR_FILE_OPEN_HEX 61 /**< Couldn't open hex file. */ #define ERR_FILE_SIZE_HEX 62 /**< Unexpected hex file size. */ #define ERR_FILE_ALLOC_HEX 63 /**< Couldn't allocate enough memory for hex file. */ #define ERR_MEMORY_RANGE 69 /**< Out of memory range. */ /** Structure used to build list of input files. */ struct file_list { const char *name; /**< The name of the input file. */ FILE_LIST *prev; /**< The previous file name in the list.*/ char hex_flag; /**< True if the input file is hex. */ }; typedef struct { #if !defined COMPILE_FOR_LPC21 TARGET micro; // The type of micro that will be programmed. FILE_FORMAT_TYPE FileFormat; unsigned char ProgramChip; // Normally set unsigned char ControlLines; unsigned char ControlLinesSwapped; unsigned char ControlLinesInverted; unsigned char LogFile; FILE_LIST *f_list; // List of files to read in. int nQuestionMarks; // how many times to try to synchronise int DoNotStart; int BootHold; char *serial_port; // Name of the serial port to use to // communicate with the microcontroller. // Read from the command line. #endif // !defined COMPILE_FOR_LPC21 unsigned char TerminalOnly; // Declared here for lazyness saves ifdef's #ifdef TERMINAL_SUPPORT unsigned char TerminalAfterUpload; unsigned char LocalEcho; #endif unsigned char HalfDuplex; // Only used for LPC Programming unsigned char WriteDelay; unsigned char DetectOnly; unsigned char WipeDevice; unsigned char Verify; int DetectedDevice; /* index in LPCtypes[] array */ char *baud_rate; /**< Baud rate to use on the serial * port communicating with the * microcontroller. Read from the * command line. */ char StringOscillator[6]; /**< Holds representation of oscillator * speed from the command line. */ BINARY *FileContent; BINARY *BinaryContent; /**< Binary image of the */ /* microcontroller's memory. */ unsigned long BinaryLength; unsigned long BinaryOffset; unsigned long StartAddress; unsigned long BinaryMemSize; #if defined COMPILE_FOR_WINDOWS || defined COMPILE_FOR_CYGWIN HANDLE hCom; #endif // defined COMPILE_FOR_WINDOWS || defined COMPILE_FOR_CYGWIN #if defined COMPILE_FOR_LINUX || defined COMPILE_FOR_LPC21 int fdCom; #endif // defined COMPILE_FOR_LINUX || defined COMPILE_FOR_LPC21 #if defined COMPILE_FOR_LINUX struct termios oldtio, newtio; #endif // defined COMPILE_FOR_LINUX #ifdef INTEGRATED_IN_WIN_APP unsigned char NoSync; #endif #if defined COMPILE_FOR_WINDOWS || defined COMPILE_FOR_CYGWIN unsigned long serial_timeout_count; /**< Local used to track timeouts on serial port read. */ #else unsigned serial_timeout_count; /**< Local used to track timeouts on serial port read. */ #endif } ISP_ENVIRONMENT; #if defined COMPILE_FOR_LPC21 #define DebugPrintf(in, ...) #else extern int debug_level; #if defined INTEGRATED_IN_WIN_APP #define DebugPrintf AppDebugPrintf void AppDebugPrintf(int level, const char *fmt, ...); #define exit(val) AppException(val) void AppException(int exception_level); int AppDoProgram(int argc, char *argv[]); #define Exclude_kbhit 1 int AppSyncing(int trials); void AppWritten(int size); #else void DebugPrintf(int level, const char *fmt, ...); //#define DebugPrintf(level, ...) if (level <= debug_level) { TRACE( __VA_ARGS__ ); } #endif void ClearSerialPortBuffers(ISP_ENVIRONMENT *IspEnvironment); void ControlXonXoffSerialPort(ISP_ENVIRONMENT *IspEnvironment, unsigned char XonXoff); #endif #if defined COMPILE_FOR_LINUX #define stricmp strcasecmp #define strnicmp strncasecmp #endif // defined COMPILE_FOR_LINUX #ifndef O_BINARY #define O_BINARY 0 #endif // O_BINARY #ifndef DWORD #define DWORD unsigned long #endif // DWORD /* debug levels 0 - very quiet - Nothing gets printed at this level 1 - quiet - Only error messages should be printed 2 - indicate progress - Add progress messages 3 - first level debug - Major level tracing 4 - second level debug - Add detailed debugging 5 - log comm's - log serial I/O */ void ReceiveComPort(ISP_ENVIRONMENT *IspEnvironment, const char *Ans, unsigned long MaxSize, unsigned long *RealSize, unsigned long WantedNr0x0A, unsigned timeOutMilliseconds); void PrepareKeyboardTtySettings(void); void ResetKeyboardTtySettings(void); void ResetTarget(ISP_ENVIRONMENT *IspEnvironment, TARGET_MODE mode); void DumpString(int level, const void *s, size_t size, const char *prefix_string); void SendComPort(ISP_ENVIRONMENT *IspEnvironment, const char *s); void SendComPortBlock(ISP_ENVIRONMENT *IspEnvironment, const void *s, size_t n); int ReceiveComPortBlockComplete(ISP_ENVIRONMENT *IspEnvironment, void *block, size_t size, unsigned timeout); void ClearSerialPortBuffers(ISP_ENVIRONMENT *IspEnvironment); void ControlXonXoffSerialPort(ISP_ENVIRONMENT *IspEnvironment, unsigned char XonXoff); lpc21isp_197/lpcprog.c100666 0 0 245740 12263324462 13254 0ustar usergroup/****************************************************************************** Project: Portable command line ISP for NXP LPC1000 / LPC2000 family and Analog Devices ADUC70xx Filename: lpcprog.c Compiler: Microsoft VC 6/7, Microsoft VS2008, Microsoft VS2010, GCC Cygwin, GCC Linux, GCC ARM ELF Author: Martin Maurer (Martin.Maurer@clibb.de) Copyright: (c) Martin Maurer 2003-2014, All rights reserved Portions Copyright (c) by Aeolus Development 2004 http://www.aeolusdevelopment.com This file is part of lpc21isp. lpc21isp is free software: you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation, either version 3 of the License, or any later version. lpc21isp is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License and GNU General Public License along with lpc21isp. If not, see . */ // This file is for the Actual Programming of the LPC Chips #if defined(_WIN32) #include "malloc.h" #if !defined __BORLANDC__ #include "StdAfx.h" #endif #endif // defined(_WIN32) #include "lpc21isp.h" #ifdef LPC_SUPPORT #include "lpcprog.h" static const unsigned int SectorTable_210x[] = { 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192 }; static const unsigned int SectorTable_2103[] = { 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096 }; static const unsigned int SectorTable_2109[] = { 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192 }; static const unsigned int SectorTable_211x[] = { 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, }; static const unsigned int SectorTable_212x[] = { 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 65536, 65536, 8192, 8192, 8192, 8192, 8192, 8192, 8192 }; // Used for devices with 500K (LPC2138 and LPC2148) and // for devices with 504K (1 extra 4k block at the end) static const unsigned int SectorTable_213x[] = { 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 32768, 32768, 32768, 32768, 32768, 32768, 32768, 32768, 32768, 32768, 32768, 32768, 32768, 32768, 4096, 4096, 4096, 4096, 4096, 4096 }; // Used for LPC11xx devices static const unsigned int SectorTable_11xx[] = { 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096 }; // Used for LPC17xx devices static const unsigned int SectorTable_17xx[] = { 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 4096, 32768, 32768, 32768, 32768, 32768, 32768, 32768, 32768, 32768, 32768, 32768, 32768, 32768, 32768 }; // Used for LPC18xx devices static const unsigned int SectorTable_18xx[] = { 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 65536, 65536, 65536, 65536, 65536, 65536, 65536 }; // Used for LPC43xx devices static const unsigned int SectorTable_43xx[] = { 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 65536, 65536, 65536, 65536, 65536, 65536, 65536 }; // Used for LPC8xx devices static const unsigned int SectorTable_8xx[] = { 1024, 1024, 1024, 1024, 1024, 1024, 1024, 1024, 1024, 1024, 1024, 1024, 1024, 1024, 1024, 1024 }; static int unsigned SectorTable_RAM[] = { 65000 }; static LPC_DEVICE_TYPE LPCtypes[] = { { 0, 0, 0, 0, 0, 0, 0, 0, 0, CHIP_VARIANT_NONE }, /* unknown */ // id, id2, use id2, name of product, flash size, ram size, total number of sector, max copy size, sector table, chip variant { 0x00008100, 0x00000000, 0, "810M021FN8", 4, 1, 4, 256, SectorTable_8xx, CHIP_VARIANT_LPC8XX }, { 0x00008110, 0x00000000, 0, "811M001FDH16", 8, 2, 8, 1024, SectorTable_8xx, CHIP_VARIANT_LPC8XX }, { 0x00008120, 0x00000000, 0, "812M101FDH16", 16, 4, 16, 1024, SectorTable_8xx, CHIP_VARIANT_LPC8XX }, { 0x00008121, 0x00000000, 0, "812M101FD20", 16, 4, 16, 1024, SectorTable_8xx, CHIP_VARIANT_LPC8XX }, { 0x00008122, 0x00000000, 0, "812M101FDH20", 16, 4, 16, 1024, SectorTable_8xx, CHIP_VARIANT_LPC8XX }, { 0x2500102B, 0x00000000, 0, "1102", 32, 8, 8, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x0A07102B, 0x00000000, 0, "1110.../002", 4, 1, 1, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x1A07102B, 0x00000000, 0, "1110.../002", 4, 1, 1, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x0A16D02B, 0x00000000, 0, "1111.../002", 8, 2, 2, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x1A16D02B, 0x00000000, 0, "1111.../002", 8, 2, 2, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x041E502B, 0x00000000, 0, "1111.../101", 8, 2, 2, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x2516D02B, 0x00000000, 0, "1111.../102", 8, 2, 2, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x00010013, 0x00000000, 0, "1111.../103", 8, 2, 2, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x0416502B, 0x00000000, 0, "1111.../201", 8, 4, 2, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x2516902B, 0x00000000, 0, "1111.../202", 8, 4, 2, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x00010012, 0x00000000, 0, "1111.../203", 8, 4, 2, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x042D502B, 0x00000000, 0, "1112.../101", 16, 2, 4, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x2524D02B, 0x00000000, 0, "1112.../102", 16, 2, 4, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x0A24902B, 0x00000000, 0, "1112.../102", 16, 4, 4, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x1A24902B, 0x00000000, 0, "1112.../102", 16, 4, 4, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x00020023, 0x00000000, 0, "1112.../103", 16, 2, 4, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x0425502B, 0x00000000, 0, "1112.../201", 16, 4, 4, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x2524902B, 0x00000000, 0, "1112.../202", 16, 4, 4, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x00020022, 0x00000000, 0, "1112.../203", 16, 4, 4, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x0434502B, 0x00000000, 0, "1113.../201", 24, 4, 6, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x2532902B, 0x00000000, 0, "1113.../202", 24, 4, 6, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x00030032, 0x00000000, 0, "1113.../203", 24, 4, 6, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x0434102B, 0x00000000, 0, "1113.../301", 24, 8, 6, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x2532102B, 0x00000000, 0, "1113.../302", 24, 8, 6, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x00030030, 0x00000000, 0, "1113.../303", 24, 8, 6, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x0A40902B, 0x00000000, 0, "1114.../102", 32, 4, 8, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x1A40902B, 0x00000000, 0, "1114.../102", 32, 4, 8, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x0444502B, 0x00000000, 0, "1114.../201", 32, 4, 8, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x2540902B, 0x00000000, 0, "1114.../202", 32, 4, 8, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x00040042, 0x00000000, 0, "1114.../203", 32, 8, 8, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x0444102B, 0x00000000, 0, "1114.../301", 32, 8, 8, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x2540102B, 0x00000000, 0, "1114.../302", 32, 8, 8, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x00040040, 0x00000000, 0, "1114.../303", 32, 8, 8, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x00040060, 0x00000000, 0, "1114.../323", 32, 8, 12, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x00040070, 0x00000000, 0, "1114.../333", 32, 8, 14, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x00050080, 0x00000000, 0, "1115.../303", 64, 8, 16, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x1421102B, 0x00000000, 0, "11C12.../301", 16, 8, 4, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x1440102B, 0x00000000, 0, "11C14.../301", 32, 8, 8, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x1431102B, 0x00000000, 0, "11C22.../301", 16, 8, 4, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x1430102B, 0x00000000, 0, "11C24.../301", 32, 8, 8, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, { 0x293E902B, 0x00000000, 0, "11E11FHN33/101", 8, 4, 2, 1024, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10518 Rev. 3 -- 25 Nov 2013 */ { 0x2954502B, 0x00000000, 0, "11E12FBD48/201", 16, 6, 4, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10518 Rev. 3 -- 25 Nov 2013 */ { 0x296A102B, 0x00000000, 0, "11E13FBD48/301", 24, 8, 6, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10518 Rev. 3 -- 25 Nov 2013 */ { 0x2980102B, 0x00000000, 0, "11E14(FHN33,FBD48,FBD64)/401", 32, 10, 8, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10518 Rev. 3 -- 25 Nov 2013 */ { 0x00009C41, 0x00000000, 0, "11E36(FBD64,FHN33)/501", 96, 12, 24, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10518 Rev. 3 -- 25 Nov 2013 */ { 0x00007C45, 0x00000000, 0, "11E37HFBD64/401", 128, 10, 32, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10518 Rev. 3 -- 25 Nov 2013 */ { 0x00007C41, 0x00000000, 0, "11E37(FBD48,FBD64)/501", 128, 12, 32, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10518 Rev. 3 -- 25 Nov 2013 */ { 0x095C802B, 0x00000000, 0, "11U12(FHN33,FBD48)/201", 16, 6, 4, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10462 Rev. 5 -- 20 Nov 2013 */ { 0x295C802B, 0x00000000, 0, "11U12(FHN33,FBD48)/201", 16, 6, 4, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10462 Rev. 5 -- 20 Nov 2013 */ { 0x097A802B, 0x00000000, 0, "11U13FBD48/201", 24, 6, 6, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10462 Rev. 5 -- 20 Nov 2013 */ { 0x297A802B, 0x00000000, 0, "11U13FBD48/201", 24, 6, 6, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10462 Rev. 5 -- 20 Nov 2013 */ { 0x0998802B, 0x00000000, 0, "11U14FHN33/201", 32, 6, 8, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10462 Rev. 5 -- 20 Nov 2013 */ { 0x2998802B, 0x00000000, 0, "11U14(FHN,FHI)33/201", 32, 6, 8, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10462 Rev. 5 -- 20 Nov 2013 */ { 0x0998802B, 0x00000000, 0, "11U14(FBD,FET)48/201", 32, 6, 8, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10462 Rev. 5 -- 20 Nov 2013 */ { 0x2998802B, 0x00000000, 0, "11U14(FBD,FET)48/201", 32, 6, 8, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10462 Rev. 5 -- 20 Nov 2013 */ { 0x2972402B, 0x00000000, 0, "11U23FBD48/301", 24, 8, 6, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10462 Rev. 5 -- 20 Nov 2013 */ { 0x2988402B, 0x00000000, 0, "11U24(FHI33,FBD48,FET48)/301", 32, 8, 8, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10462 Rev. 5 -- 20 Nov 2013 */ { 0x2980002B, 0x00000000, 0, "11U24(FHN33,FBD48,FBD64)/401", 32, 10, 8, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10462 Rev. 5 -- 20 Nov 2013 */ { 0x0003D440, 0x00000000, 0, "11U34(FHN33,FBD48)/311", 40, 8, 10, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10462 Rev. 5 -- 20 Nov 2013 */ { 0x0001CC40, 0x00000000, 0, "11U34(FHN33,FBD48)/421", 48, 10, 12, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10462 Rev. 5 -- 20 Nov 2013 */ { 0x0001BC40, 0x00000000, 0, "11U35(FHN33,FBD48,FBD64)/401", 64, 10, 16, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10462 Rev. 5 -- 20 Nov 2013 */ { 0x0000BC40, 0x00000000, 0, "11U35(FHI33,FET48)/501", 64, 12, 16, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10462 Rev. 5 -- 20 Nov 2013 */ { 0x00019C40, 0x00000000, 0, "11U36(FBD48,FBD64)/401", 96, 10, 24, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10462 Rev. 5 -- 20 Nov 2013 */ { 0x00017C40, 0x00000000, 0, "11U37FBD48/401", 128, 10, 32, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10462 Rev. 5 -- 20 Nov 2013 */ { 0x00007C44, 0x00000000, 0, "11U37HFBD64/401", 128, 10, 32, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10462 Rev. 5 -- 20 Nov 2013 */ { 0x00007C40, 0x00000000, 0, "11U37FBD64/501", 128, 12, 32, 4096, SectorTable_11xx, CHIP_VARIANT_LPC11XX }, /* From UM10462 Rev. 5 -- 20 Nov 2013 */ { 0x3640C02B, 0x00000000, 0, "1224.../101", 32, 8, 4, 2048, SectorTable_17xx, CHIP_VARIANT_LPC11XX }, { 0x3642C02B, 0x00000000, 0, "1224.../121", 48, 12, 32, 4096, SectorTable_17xx, CHIP_VARIANT_LPC11XX }, { 0x3650002B, 0x00000000, 0, "1225.../301", 64, 16, 32, 4096, SectorTable_17xx, CHIP_VARIANT_LPC11XX }, { 0x3652002B, 0x00000000, 0, "1225.../321", 80, 20, 32, 4096, SectorTable_17xx, CHIP_VARIANT_LPC11XX }, { 0x3660002B, 0x00000000, 0, "1226", 96, 24, 32, 4096, SectorTable_17xx, CHIP_VARIANT_LPC11XX }, { 0x3670002B, 0x00000000, 0, "1227", 128, 32, 32, 4096, SectorTable_17xx, CHIP_VARIANT_LPC11XX }, { 0x2C42502B, 0x00000000, 0, "1311", 8, 4, 2, 1024, SectorTable_17xx, CHIP_VARIANT_LPC13XX }, { 0x1816902B, 0x00000000, 0, "1311/01", 8, 4, 2, 1024, SectorTable_17xx, CHIP_VARIANT_LPC13XX }, { 0x2C40102B, 0x00000000, 0, "1313", 32, 8, 8, 4096, SectorTable_17xx, CHIP_VARIANT_LPC13XX }, { 0x1830102B, 0x00000000, 0, "1313/01", 32, 8, 8, 4096, SectorTable_17xx, CHIP_VARIANT_LPC13XX }, { 0x3A010523, 0x00000000, 0, "1315", 32, 8, 8, 4096, SectorTable_17xx, CHIP_VARIANT_LPC13XX }, { 0x1A018524, 0x00000000, 0, "1316", 48, 8, 12, 4096, SectorTable_17xx, CHIP_VARIANT_LPC13XX }, { 0x1A020525, 0x00000000, 0, "1317", 64, 8, 16, 4096, SectorTable_17xx, CHIP_VARIANT_LPC13XX }, { 0x3D01402B, 0x00000000, 0, "1342", 16, 4, 4, 1024, SectorTable_17xx, CHIP_VARIANT_LPC13XX }, { 0x3D00002B, 0x00000000, 0, "1343", 32, 8, 8, 4096, SectorTable_17xx, CHIP_VARIANT_LPC13XX }, { 0x28010541, 0x00000000, 0, "1345", 32, 8, 8, 4096, SectorTable_17xx, CHIP_VARIANT_LPC13XX }, { 0x08018542, 0x00000000, 0, "1346", 48, 8, 12, 4096, SectorTable_17xx, CHIP_VARIANT_LPC13XX }, { 0x08020543, 0x00000000, 0, "1347", 64, 8, 16, 4096, SectorTable_17xx, CHIP_VARIANT_LPC13XX }, { 0x25001118, 0x00000000, 0, "1751", 32, 8, 8, 4096, SectorTable_17xx, CHIP_VARIANT_LPC17XX }, { 0x25001121, 0x00000000, 0, "1752", 64, 16, 16, 4096, SectorTable_17xx, CHIP_VARIANT_LPC17XX }, { 0x25011722, 0x00000000, 0, "1754", 128, 32, 18, 4096, SectorTable_17xx, CHIP_VARIANT_LPC17XX }, { 0x25011723, 0x00000000, 0, "1756", 256, 32, 22, 4096, SectorTable_17xx, CHIP_VARIANT_LPC17XX }, { 0x25013F37, 0x00000000, 0, "1758", 512, 64, 30, 4096, SectorTable_17xx, CHIP_VARIANT_LPC17XX }, { 0x25113737, 0x00000000, 0, "1759", 512, 64, 30, 4096, SectorTable_17xx, CHIP_VARIANT_LPC17XX }, { 0x26012033, 0x00000000, 0, "1763", 256, 64, 22, 4096, SectorTable_17xx, CHIP_VARIANT_LPC17XX }, { 0x26011922, 0x00000000, 0, "1764", 128, 32, 18, 4096, SectorTable_17xx, CHIP_VARIANT_LPC17XX }, { 0x26013733, 0x00000000, 0, "1765", 256, 64, 22, 4096, SectorTable_17xx, CHIP_VARIANT_LPC17XX }, { 0x26013F33, 0x00000000, 0, "1766", 256, 64, 22, 4096, SectorTable_17xx, CHIP_VARIANT_LPC17XX }, { 0x26012837, 0x00000000, 0, "1767", 512, 64, 30, 4096, SectorTable_17xx, CHIP_VARIANT_LPC17XX }, { 0x26013F37, 0x00000000, 0, "1768", 512, 64, 30, 4096, SectorTable_17xx, CHIP_VARIANT_LPC17XX }, { 0x26113F37, 0x00000000, 0, "1769", 512, 64, 30, 4096, SectorTable_17xx, CHIP_VARIANT_LPC17XX }, { 0x27011132, 0x00000000, 0, "1774", 128, 40, 18, 4096, SectorTable_17xx, CHIP_VARIANT_LPC17XX }, { 0x27191F43, 0x00000000, 0, "1776", 256, 80, 22, 4096, SectorTable_17xx, CHIP_VARIANT_LPC17XX }, { 0x27193747, 0x00000000, 0, "1777", 512, 96, 30, 4096, SectorTable_17xx, CHIP_VARIANT_LPC17XX }, { 0x27193F47, 0x00000000, 0, "1778", 512, 96, 30, 4096, SectorTable_17xx, CHIP_VARIANT_LPC17XX }, { 0x281D1743, 0x00000000, 0, "1785", 256, 80, 22, 4096, SectorTable_17xx, CHIP_VARIANT_LPC17XX }, { 0x281D1F43, 0x00000000, 0, "1786", 256, 80, 22, 4096, SectorTable_17xx, CHIP_VARIANT_LPC17XX }, { 0x281D3747, 0x00000000, 0, "1787", 512, 96, 30, 4096, SectorTable_17xx, CHIP_VARIANT_LPC17XX }, { 0x281D3F47, 0x00000000, 0, "1788", 512, 96, 30, 4096, SectorTable_17xx, CHIP_VARIANT_LPC17XX }, // LPC18xx { 0xF00B1B3F, 0x00000000, 1, "1810", 0, 32, 0, 8192, SectorTable_18xx, CHIP_VARIANT_LPC18XX }, // Flashless { 0xF001D830, 0x00000000, 1, "1812", 512, 32, 15, 8192, SectorTable_18xx, CHIP_VARIANT_LPC18XX }, { 0xF001D830, 0x00000000, 1, "1813", 512, 32, 11, 8192, SectorTable_18xx, CHIP_VARIANT_LPC18XX }, { 0xF001D830, 0x00000000, 1, "1815", 768, 32, 13, 8192, SectorTable_18xx, CHIP_VARIANT_LPC18XX }, { 0xF001D830, 0x00000000, 1, "1817", 1024, 32, 15, 8192, SectorTable_18xx, CHIP_VARIANT_LPC18XX }, { 0xF00A9B3C, 0x00000000, 1, "1820", 0, 32, 0, 8192, SectorTable_18xx, CHIP_VARIANT_LPC18XX }, // Flashless { 0xF001D830, 0x00000000, 1, "1822", 512, 32, 15, 8192, SectorTable_18xx, CHIP_VARIANT_LPC18XX }, { 0xF001D830, 0x00000000, 1, "1823", 512, 32, 11, 8192, SectorTable_18xx, CHIP_VARIANT_LPC18XX }, { 0xF001D830, 0x00000000, 1, "1825", 768, 32, 13, 8192, SectorTable_18xx, CHIP_VARIANT_LPC18XX }, { 0xF001D830, 0x00000000, 1, "1827", 1024, 32, 15, 8192, SectorTable_18xx, CHIP_VARIANT_LPC18XX }, { 0xF0009A30, 0x00000000, 1, "1830", 0, 32, 0, 8192, SectorTable_18xx, CHIP_VARIANT_LPC18XX }, // Flashless { 0xF001DA30, 0x00000044, 1, "1833", 512, 32, 11, 8192, SectorTable_18xx, CHIP_VARIANT_LPC18XX }, { 0xF001DA30, 0x00000000, 1, "1837", 1024, 32, 15, 8192, SectorTable_18xx, CHIP_VARIANT_LPC18XX }, { 0xF0009830, 0x00000000, 1, "1850", 0, 32, 0, 8192, SectorTable_18xx, CHIP_VARIANT_LPC18XX }, // Flashless { 0xF001D830, 0x00000044, 1, "1853", 512, 32, 11, 8192, SectorTable_18xx, CHIP_VARIANT_LPC18XX }, { 0xF001D830, 0x00000000, 1, "1857", 1024, 32, 15, 8192, SectorTable_18xx, CHIP_VARIANT_LPC18XX }, { 0x0004FF11, 0x00000000, 0, "2103", 32, 8, 8, 4096, SectorTable_2103, CHIP_VARIANT_LPC2XXX }, { 0xFFF0FF12, 0x00000000, 0, "2104", 128, 16, 15, 8192, SectorTable_210x, CHIP_VARIANT_LPC2XXX }, { 0xFFF0FF22, 0x00000000, 0, "2105", 128, 32, 15, 8192, SectorTable_210x, CHIP_VARIANT_LPC2XXX }, { 0xFFF0FF32, 0x00000000, 0, "2106", 128, 64, 15, 8192, SectorTable_210x, CHIP_VARIANT_LPC2XXX }, { 0x0201FF01, 0x00000000, 0, "2109", 64, 8, 8, 4096, SectorTable_2109, CHIP_VARIANT_LPC2XXX }, { 0x0101FF12, 0x00000000, 0, "2114", 128, 16, 15, 8192, SectorTable_211x, CHIP_VARIANT_LPC2XXX }, { 0x0201FF12, 0x00000000, 0, "2119", 128, 16, 15, 8192, SectorTable_211x, CHIP_VARIANT_LPC2XXX }, { 0x0101FF13, 0x00000000, 0, "2124", 256, 16, 17, 8192, SectorTable_212x, CHIP_VARIANT_LPC2XXX }, { 0x0201FF13, 0x00000000, 0, "2129", 256, 16, 17, 8192, SectorTable_212x, CHIP_VARIANT_LPC2XXX }, { 0x0002FF01, 0x00000000, 0, "2131", 32, 8, 8, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, { 0x0002FF11, 0x00000000, 0, "2132", 64, 16, 9, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, { 0x0002FF12, 0x00000000, 0, "2134", 128, 16, 11, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, { 0x0002FF23, 0x00000000, 0, "2136", 256, 32, 15, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, { 0x0002FF25, 0x00000000, 0, "2138", 512, 32, 27, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, { 0x0402FF01, 0x00000000, 0, "2141", 32, 8, 8, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, { 0x0402FF11, 0x00000000, 0, "2142", 64, 16, 9, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, { 0x0402FF12, 0x00000000, 0, "2144", 128, 16, 11, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, { 0x0402FF23, 0x00000000, 0, "2146", 256, 40, 15, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, { 0x0402FF25, 0x00000000, 0, "2148", 512, 40, 27, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, { 0x0301FF13, 0x00000000, 0, "2194", 256, 16, 17, 8192, SectorTable_212x, CHIP_VARIANT_LPC2XXX }, { 0x0301FF12, 0x00000000, 0, "2210", 0, 16, 0, 8192, SectorTable_211x, CHIP_VARIANT_LPC2XXX }, /* table is a "don't care" */ { 0x0401FF12, 0x00000000, 0, "2212", 128, 16, 15, 8192, SectorTable_211x, CHIP_VARIANT_LPC2XXX }, { 0x0601FF13, 0x00000000, 0, "2214", 256, 16, 17, 8192, SectorTable_212x, CHIP_VARIANT_LPC2XXX }, /* "2290"; same id as the LPC2210 */ { 0x0401FF13, 0x00000000, 0, "2292", 256, 16, 17, 8192, SectorTable_212x, CHIP_VARIANT_LPC2XXX }, { 0x0501FF13, 0x00000000, 0, "2294", 256, 16, 17, 8192, SectorTable_212x, CHIP_VARIANT_LPC2XXX }, { 0x1600F701, 0x00000000, 0, "2361", 128, 34, 11, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, /* From UM10211 Rev. 4.1 -- 5 Sep 2012 */ { 0x1600FF22, 0x00000000, 0, "2362", 128, 34, 11, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, /* From UM10211 Rev. 4.1 -- 5 Sep 2012 */ { 0x0603FB02, 0x00000000, 0, "2364", 128, 34, 11, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, /* From UM10211 Rev. 01 -- 6 July 2007 */ { 0x1600F902, 0x00000000, 0, "2364", 128, 34, 11, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, { 0x1600E823, 0x00000000, 0, "2365", 256, 58, 15, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, { 0x0603FB23, 0x00000000, 0, "2366", 256, 58, 15, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, /* From UM10211 Rev. 01 -- 6 July 2007 */ { 0x1600F923, 0x00000000, 0, "2366", 256, 58, 15, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, { 0x1600E825, 0x00000000, 0, "2367", 512, 58, 15, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, { 0x0603FB25, 0x00000000, 0, "2368", 512, 58, 28, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, /* From UM10211 Rev. 01 -- 6 July 2007 */ { 0x1600F925, 0x00000000, 0, "2368", 512, 58, 28, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, { 0x1700E825, 0x00000000, 0, "2377", 512, 58, 28, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, { 0x0703FF25, 0x00000000, 0, "2378", 512, 58, 28, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, /* From UM10211 Rev. 01 -- 6 July 2007 */ { 0x1600FD25, 0x00000000, 0, "2378", 512, 58, 28, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, /* From UM10211 Rev. 01 -- 29 October 2007 */ { 0x1700FD25, 0x00000000, 0, "2378", 512, 58, 28, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, { 0x1700FF35, 0x00000000, 0, "2387", 512, 98, 28, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, /* From UM10211 Rev. 03 -- 25 August 2008 */ { 0x1800F935, 0x00000000, 0, "2387", 512, 98, 28, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, { 0x1800FF35, 0x00000000, 0, "2388", 512, 98, 28, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, { 0x1500FF35, 0x00000000, 0, "2458", 512, 98, 28, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, { 0x1600FF30, 0x00000000, 0, "2460", 0, 98, 0, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, { 0x1600FF35, 0x00000000, 0, "2468", 512, 98, 28, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, { 0x1701FF30, 0x00000000, 0, "2470", 0, 98, 0, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, { 0x1701FF35, 0x00000000, 0, "2478", 512, 98, 28, 4096, SectorTable_213x, CHIP_VARIANT_LPC2XXX }, { 0xA00A8B3F, 0x00000000, 1, "4310", 0, 168, 0, 4096, SectorTable_43xx, CHIP_VARIANT_LPC43XX }, /* From UM10503 Rev. 1.4 -- 3 Sep 2012 */ { 0xA00BCB3F, 0x00000080, 1, "4312", 512, 104, 15, 4096, SectorTable_43xx, CHIP_VARIANT_LPC43XX }, /* info not yet available */ { 0xA00BCB3F, 0x00000044, 1, "4313", 512, 104, 11, 4096, SectorTable_43xx, CHIP_VARIANT_LPC43XX }, /* info not yet available */ { 0xA001CB3F, 0x00000022, 1, "4315", 768, 136, 13, 4096, SectorTable_43xx, CHIP_VARIANT_LPC43XX }, /* info not yet available */ { 0xA001CB3F, 0x00000000, 1, "4317", 1024, 136, 15, 4096, SectorTable_43xx, CHIP_VARIANT_LPC43XX }, /* info not yet available */ { 0xA0008B3C, 0x00000000, 1, "4320", 0, 200, 0, 4096, SectorTable_43xx, CHIP_VARIANT_LPC43XX }, /* From UM10503 Rev. 1.4 -- 3 Sep 2012 */ { 0xA00BCB3C, 0x00000080, 1, "4322", 512, 104, 15, 4096, SectorTable_43xx, CHIP_VARIANT_LPC43XX }, /* info not yet available */ { 0xA00BCB3C, 0x00000044, 1, "4323", 512, 104, 11, 4096, SectorTable_43xx, CHIP_VARIANT_LPC43XX }, /* info not yet available */ { 0xA001CB3C, 0x00000022, 1, "4325", 768, 136, 13, 4096, SectorTable_43xx, CHIP_VARIANT_LPC43XX }, /* info not yet available */ { 0xA001CB3C, 0x00000000, 1, "4327", 1024, 136, 15, 4096, SectorTable_43xx, CHIP_VARIANT_LPC43XX }, /* info not yet available */ { 0xA0000A30, 0x00000000, 1, "4330", 0, 264, 0, 4096, SectorTable_43xx, CHIP_VARIANT_LPC43XX }, /* From UM10503 Rev. 1.4 -- 3 Sep 2012 */ { 0xA001CA30, 0x00000044, 1, "4333", 512, 512, 11, 4096, SectorTable_43xx, CHIP_VARIANT_LPC43XX }, /* info not yet available */ { 0xA001CA30, 0x00000000, 1, "4337", 1024, 512, 15, 4096, SectorTable_43xx, CHIP_VARIANT_LPC43XX }, /* info not yet available */ { 0xA0000830, 0x00000000, 1, "4350", 0, 264, 0, 4096, SectorTable_43xx, CHIP_VARIANT_LPC43XX }, /* From UM10503 Rev. 1.4 -- 3 Sep 2012 */ { 0xA001C830, 0x00000044, 1, "4353", 512, 512, 11, 4096, SectorTable_43xx, CHIP_VARIANT_LPC43XX }, /* From UM10503 Rev. 1.4 -- 3 Sep 2012 */ { 0xA001C830, 0x00000000, 1, "4357", 1024, 512, 15, 4096, SectorTable_43xx, CHIP_VARIANT_LPC43XX } /* From UM10503 Rev. 1.4 -- 3 Sep 2012 */ }; /***************************** NXP Download *********************************/ /** Download the file from the internal memory image to the NXP microcontroller. * This function is visible from outside if COMPILE_FOR_LPC21 */ /***************************** FormatCommand ********************************/ /** 2013-06-28 Torsten Lang, Uwe Schneider GmbH According to the various NXP user manuals the ISP bootloader commands should be terminated with , the echo and/or answer should have the same line termination. So far for the theory... In fact, the bootloader also accepts as line termination, but it may or may not echo the linebreak character. Some bootloaders convert the character into , some leave the and append another one ( in the answer). Furthermore, during uuencoded data transfer the bootloader may or may not append an additional character at the end of the answer (leading to a sequence). A reliable way to handle these deviations from the UM is to strictly send the commands according to the description in the UM and to re-format commands and answers after a transfer. FormatCommand works in a way that it drops any leading linefeeds which only can be surplus characters from a previous answer. It then converts any sequence of and into a single character. FormatCommand can work in place, meaning that In==Out is allowed! \param [in] In Pointer to input buffer. \param [out] Out Pointer to output buffer. */ static void FormatCommand(const char *In, char *Out) { size_t i, j; for (i = 0, j = 0; In[j] != '\0'; i++, j++) { if ((In[j] == '\r') || (In[j] == '\n')) { if (i > 0) // Ignore leading line breaks (they must be leftovers from a previous answer) { Out[i] = '\n'; } else { i--; } while ((In[j+1] == '\r') || (In[j+1] == '\n')) { j++; } } else { Out[i] = In[j]; } } Out[i] = '\0'; } static int SendAndVerify(ISP_ENVIRONMENT *IspEnvironment, const char *Command, char *AnswerBuffer, int AnswerLength) { unsigned long realsize; int cmdlen; char *FormattedCommand; SendComPort(IspEnvironment, Command); ReceiveComPort(IspEnvironment, AnswerBuffer, AnswerLength - 1, &realsize, 2, 5000); cmdlen = strlen(Command); FormattedCommand = (char *)alloca(cmdlen+1); FormatCommand(Command, FormattedCommand); FormatCommand(AnswerBuffer, AnswerBuffer); cmdlen = strlen(FormattedCommand); return (strncmp(AnswerBuffer, FormattedCommand, cmdlen) == 0 && strcmp(AnswerBuffer + cmdlen, "0\n") == 0); } /***************************** NxpOutputErrorMessage ***********************/ /** Given an error number find and print the appropriate error message. \param [in] ErrorNumber The number of the error. */ #if defined COMPILE_FOR_LPC21 #define NxpOutputErrorMessage(in) // Cleanly remove this feature from the embedded version !! #else static void NxpOutputErrorMessage(unsigned char ErrorNumber) { switch (ErrorNumber) { case 0: DebugPrintf(1, "CMD_SUCCESS\n"); break; case 1: DebugPrintf(1, "INVALID_COMMAND\n"); break; case 2: DebugPrintf(1, "SRC_ADDR_ERROR: Source address is not on word boundary.\n"); break; case 3: DebugPrintf(1, "DST_ADDR_ERROR: Destination address is not on a correct boundary.\n"); break; case 4: DebugPrintf(1, "SRC_ADDR_NOT_MAPPED: Source address is not mapped in the memory map.\n" " Count value is taken into consideration where applicable.\n"); break; case 5: DebugPrintf(1, "DST_ADDR_NOT_MAPPED: Destination address is not mapped in the memory map.\n" " Count value is taken into consideration where applicable.\n"); break; case 6: DebugPrintf(1, "COUNT_ERROR: Byte count is not multiple of 4 or is not a permitted value.\n"); break; case 7: DebugPrintf(1, "INVALID_SECTOR: Sector number is invalid or end sector number is\n" " greater than start sector number.\n"); break; case 8: DebugPrintf(1, "SECTOR_NOT_BLANK\n"); break; case 9: DebugPrintf(1, "SECTOR_NOT_PREPARED_FOR_WRITE_OPERATION:\n" "Command to prepare sector for write operation was not executed.\n"); break; case 10: DebugPrintf(1, "COMPARE_ERROR: Source and destination data not equal.\n"); break; case 11: DebugPrintf(1, "BUSY: Flash programming hardware interface is busy.\n"); break; case 12: DebugPrintf(1, "PARAM_ERROR: Insufficient number of parameters or invalid parameter.\n"); break; case 13: DebugPrintf(1, "ADDR_ERROR: Address is not on word boundary.\n"); break; case 14: DebugPrintf(1, "ADDR_NOT_MAPPED: Address is not mapped in the memory map.\n" " Count value is taken in to consideration where applicable.\n"); break; case 15: DebugPrintf(1, "CMD_LOCKED\n"); break; case 16: DebugPrintf(1, "INVALID_CODE: Unlock code is invalid.\n"); break; case 17: DebugPrintf(1, "INVALID_BAUD_RATE: Invalid baud rate setting.\n"); break; case 18: DebugPrintf(1, "INVALID_STOP_BIT: Invalid stop bit setting.\n"); break; case 19: DebugPrintf( 1, "CODE READ PROTECTION ENABLED\n"); break; case 255: break; default: DebugPrintf(1, "unknown error %u\n", ErrorNumber); break; } //DebugPrintf(1, "error (%u), see NxpOutputErrorMessage() in lpc21isp.c for help \n\r", ErrorNumber); } #endif // !defined COMPILE_FOR_LPC21 /***************************** GetAndReportErrorNumber ***************************/ /** Find error number in string. This will normally be the string returned from the microcontroller. \param [in] Answer the buffer to search for the error number. \return the error number found, if no linefeed found before the end of the string an error value of 255 is returned. If a non-numeric value is found then it is printed to stdout and an error value of 255 is returned. */ static unsigned char GetAndReportErrorNumber(const char *Answer) { unsigned char Result = 0xFF; // Error !!! unsigned int i = 0; while (1) { if (Answer[i] == 0x00) { break; } if (Answer[i] == 0x0a) { i++; if (Answer[i] < '0' || Answer[i] > '9') { DebugPrintf(1, "ErrorString: %s", &Answer[i]); break; } Result = (unsigned char) (atoi(&Answer[i])); break; } i++; } NxpOutputErrorMessage(Result); return Result; } int NxpDownload(ISP_ENVIRONMENT *IspEnvironment) { unsigned long realsize; char Answer[128]; char ExpectedAnswer[128]; char temp[128]; /*const*/ char *strippedAnswer, *endPtr; int strippedsize; int nQuestionMarks; int found; unsigned long Sector; unsigned long SectorLength; unsigned long SectorStart, SectorOffset, SectorChunk; char tmpString[128]; char uuencode_table[64]; int Line; unsigned long tmpStringPos; unsigned long BlockOffset; unsigned long Block; unsigned long Pos; unsigned long Id[2]; unsigned long Id1Masked; unsigned long CopyLength; int c,k=0,i; unsigned long ivt_CRC; // CRC over interrupt vector table unsigned long block_CRC; time_t tStartUpload=0, tDoneUpload=0; char tmp_string[64]; char * cmdstr; #if !defined COMPILE_FOR_LPC21 #if defined __BORLANDC__ #define local_static static #else #define local_static #endif // char * cmdstr; int repeat = 0; // Puffer for data to resend after "RESEND\r\n" Target responce local_static char sendbuf0[128]; local_static char sendbuf1[128]; local_static char sendbuf2[128]; local_static char sendbuf3[128]; local_static char sendbuf4[128]; local_static char sendbuf5[128]; local_static char sendbuf6[128]; local_static char sendbuf7[128]; local_static char sendbuf8[128]; local_static char sendbuf9[128]; local_static char sendbuf10[128]; local_static char sendbuf11[128]; local_static char sendbuf12[128]; local_static char sendbuf13[128]; local_static char sendbuf14[128]; local_static char sendbuf15[128]; local_static char sendbuf16[128]; local_static char sendbuf17[128]; local_static char sendbuf18[128]; local_static char sendbuf19[128]; char * sendbuf[20] = { sendbuf0, sendbuf1, sendbuf2, sendbuf3, sendbuf4, sendbuf5, sendbuf6, sendbuf7, sendbuf8, sendbuf9, sendbuf10, sendbuf11, sendbuf12, sendbuf13, sendbuf14, sendbuf15, sendbuf16, sendbuf17, sendbuf18, sendbuf19}; #endif DebugPrintf(2, "Synchronizing (ESC to abort)"); PrepareKeyboardTtySettings(); #if defined INTEGRATED_IN_WIN_APP if (IspEnvironment->NoSync) { found = 1; } else #endif { for (nQuestionMarks = found = 0; !found && nQuestionMarks < IspEnvironment->nQuestionMarks; nQuestionMarks++) { #if defined INTEGRATED_IN_WIN_APP // allow calling application to abort when syncing takes too long if (!AppSyncing(nQuestionMarks)) { return (USER_ABORT_SYNC); } #else #ifndef Exclude_kbhit if (kbhit()) { if (getch() == 0x1b) { ResetKeyboardTtySettings(); DebugPrintf(2, "\nUser aborted during synchronisation\n"); return (USER_ABORT_SYNC); } } #endif #endif DebugPrintf(2, "."); SendComPort(IspEnvironment, "?"); memset(Answer,0,sizeof(Answer)); ReceiveComPort(IspEnvironment, Answer, sizeof(Answer)-1, &realsize, 1,100); strippedAnswer = Answer; strippedsize = realsize; while ((strippedsize > 0) && ((*strippedAnswer == '?') || (*strippedAnswer == 0))) { strippedAnswer++; strippedsize--; } sprintf(tmp_string, "StrippedAnswer(Length=%d): ", strippedsize); DumpString(3, strippedAnswer, strippedsize, tmp_string); tStartUpload = time(NULL); FormatCommand(strippedAnswer, strippedAnswer); if (strcmp(strippedAnswer, "Synchronized\n") == 0) { found = 1; } #if !defined COMPILE_FOR_LPC21 else { ResetTarget(IspEnvironment, PROGRAM_MODE); } #endif } } ResetKeyboardTtySettings(); if (!found) { DebugPrintf(1, " no answer on '?'\n"); return (NO_ANSWER_QM); } #if defined INTEGRATED_IN_WIN_APP AppSyncing(-1); // flag syncing done #endif DebugPrintf(2, " OK\n"); SendComPort(IspEnvironment, "Synchronized\r\n"); ReceiveComPort(IspEnvironment, Answer, sizeof(Answer) - 1, &realsize, 2, 1000); FormatCommand(Answer, Answer); if (strcmp(Answer, "Synchronized\nOK\n") != 0) { DebugPrintf(1, "No answer on 'Synchronized'\n"); return (NO_ANSWER_SYNC); } DebugPrintf(3, "Synchronized 1\n"); DebugPrintf(3, "Setting oscillator\n"); sprintf(temp, "%s\r\n", IspEnvironment->StringOscillator); SendComPort(IspEnvironment, temp); ReceiveComPort(IspEnvironment, Answer, sizeof(Answer)-1, &realsize, 2, 1000); sprintf(temp, "%s\nOK\n", IspEnvironment->StringOscillator); FormatCommand(Answer, Answer); if (strcmp(Answer, temp) != 0) { DebugPrintf(1, "No answer on Oscillator-Command\n"); return (NO_ANSWER_OSC); } DebugPrintf(3, "Unlock\n"); cmdstr = "U 23130\r\n"; if (!SendAndVerify(IspEnvironment, cmdstr, Answer, sizeof Answer)) { DebugPrintf(1, "Unlock-Command:\n"); return (UNLOCK_ERROR + GetAndReportErrorNumber(Answer)); } DebugPrintf(2, "Read bootcode version: "); cmdstr = "K\r\n"; SendComPort(IspEnvironment, cmdstr); ReceiveComPort(IspEnvironment, Answer, sizeof(Answer)-1, &realsize, 4,5000); FormatCommand(cmdstr, temp); FormatCommand(Answer, Answer); if (strncmp(Answer, temp, strlen(temp)) != 0) { DebugPrintf(1, "no answer on Read Boot Code Version\n"); return (NO_ANSWER_RBV); } if (strncmp(Answer + strlen(temp), "0\n", 2) == 0) { strippedAnswer = Answer + strlen(temp) + 2; /* int maj, min, build; if (sscanf(strippedAnswer, "%d %d %d", &build, &min, &maj) == 2) { maj = min; min = build; build = 0; } // if DebugPrintf(2, "%d.%d.%d\n", maj, min, build); */ DebugPrintf(2, strippedAnswer); } else { DebugPrintf(2, "unknown\n"); } DebugPrintf(2, "Read part ID: "); cmdstr = "J\r\n"; SendComPort(IspEnvironment, cmdstr); ReceiveComPort(IspEnvironment, Answer, sizeof(Answer)-1, &realsize, 3, 5000); FormatCommand(cmdstr, temp); FormatCommand(Answer, Answer); if (strncmp(Answer, temp, strlen(temp)) != 0) { DebugPrintf(1, "no answer on Read Part Id\n"); return (NO_ANSWER_RPID); } strippedAnswer = (strncmp(Answer, "J\n0\n", 4) == 0) ? Answer + 4 : Answer; Id[0] = strtoul(strippedAnswer, &endPtr, 10); Id[1] = 0UL; *endPtr = '\0'; /* delete \r\n */ for (i = sizeof LPCtypes / sizeof LPCtypes[0] - 1; i > 0 && LPCtypes[i].id != Id[0]; i--) /* nothing */; IspEnvironment->DetectedDevice = i; if (LPCtypes[IspEnvironment->DetectedDevice].EvalId2 != 0) { /* Read out the second configuration word and run the search again */ *endPtr = '\n'; endPtr++; if ((endPtr[0] == '\0') || (endPtr[strlen(endPtr)-1] != '\n')) { /* No or incomplete word 2 */ ReceiveComPort(IspEnvironment, endPtr, sizeof(Answer)-(endPtr-Answer)-1, &realsize, 1, 100); } FormatCommand(endPtr, endPtr); if ((*endPtr == '\0') || (*endPtr == '\n')) { DebugPrintf(1, "incomplete answer on Read Part Id (second configuration word missing)\n"); return (NO_ANSWER_RPID); } Id[1] = strtoul(endPtr, &endPtr, 10); *endPtr = '\0'; /* delete \r\n */ Id1Masked = Id[1] & 0xFF; /* now search the table again */ for (i = sizeof LPCtypes / sizeof LPCtypes[0] - 1; i > 0 && (LPCtypes[i].id != Id[0] || LPCtypes[i].id2 != Id1Masked); i--) /* nothing */; IspEnvironment->DetectedDevice = i; } if (IspEnvironment->DetectedDevice == 0) { DebugPrintf(2, "unknown"); } else { DebugPrintf(2, "LPC%s, %d kiB FLASH / %d kiB SRAM", LPCtypes[IspEnvironment->DetectedDevice].Product, LPCtypes[IspEnvironment->DetectedDevice].FlashSize, LPCtypes[IspEnvironment->DetectedDevice].RAMSize); } if (LPCtypes[IspEnvironment->DetectedDevice].EvalId2 != 0) { DebugPrintf(2, " (0x%08lX / 0x%08lX -> %08lX)\n", Id[0], Id[1], Id1Masked); } else { DebugPrintf(2, " (0x%08lX)\n", Id[0]); } if (!IspEnvironment->DetectOnly) { // Build up uuencode table uuencode_table[0] = 0x60; // 0x20 is translated to 0x60 ! for (i = 1; i < 64; i++) { uuencode_table[i] = (char)(0x20 + i); } if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC2XXX) { // Patch 0x14, otherwise it is not running and jumps to boot mode ivt_CRC = 0; // Clear the vector at 0x14 so it doesn't affect the checksum: for (i = 0; i < 4; i++) { IspEnvironment->BinaryContent[i + 0x14] = 0; } // Calculate a native checksum of the little endian vector table: for (i = 0; i < (4 * 8);) { ivt_CRC += IspEnvironment->BinaryContent[i++]; ivt_CRC += IspEnvironment->BinaryContent[i++] << 8; ivt_CRC += IspEnvironment->BinaryContent[i++] << 16; ivt_CRC += IspEnvironment->BinaryContent[i++] << 24; } /* Negate the result and place in the vector at 0x14 as little endian * again. The resulting vector table should checksum to 0. */ ivt_CRC = (unsigned long) (0 - ivt_CRC); for (i = 0; i < 4; i++) { IspEnvironment->BinaryContent[i + 0x14] = (unsigned char)(ivt_CRC >> (8 * i)); } DebugPrintf(3, "Position 0x14 patched: ivt_CRC = 0x%08lX\n", ivt_CRC); } else if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC43XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC18XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC17XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC13XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC11XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC8XX) { // Patch 0x1C, otherwise it is not running and jumps to boot mode ivt_CRC = 0; // Clear the vector at 0x1C so it doesn't affect the checksum: for (i = 0; i < 4; i++) { IspEnvironment->BinaryContent[i + 0x1C] = 0; } // Calculate a native checksum of the little endian vector table: for (i = 0; i < (4 * 8);) { ivt_CRC += IspEnvironment->BinaryContent[i++]; ivt_CRC += IspEnvironment->BinaryContent[i++] << 8; ivt_CRC += IspEnvironment->BinaryContent[i++] << 16; ivt_CRC += IspEnvironment->BinaryContent[i++] << 24; } /* Negate the result and place in the vector at 0x1C as little endian * again. The resulting vector table should checksum to 0. */ ivt_CRC = (unsigned long) (0 - ivt_CRC); for (i = 0; i < 4; i++) { IspEnvironment->BinaryContent[i + 0x1C] = (unsigned char)(ivt_CRC >> (8 * i)); } DebugPrintf(3, "Position 0x1C patched: ivt_CRC = 0x%08lX\n", ivt_CRC); } else { DebugPrintf(1, "Internal error: wrong chip variant %d (detected device %d)\n", LPCtypes[IspEnvironment->DetectedDevice].ChipVariant, IspEnvironment->DetectedDevice); exit(1); } } #if 0 DebugPrintf(2, "Read Unique ID:\n"); cmdstr = "N\r\n"; SendComPort(IspEnvironment, cmdstr); ReceiveComPort(IspEnvironment, Answer, sizeof(Answer)-1, &realsize, 5,5000); FormatCommand(cmdstr, temp); FormatCommand(Answer, Answer); if (strncmp(Answer, temp, strlen(temp)) != 0) { DebugPrintf(1, "no answer on Read Unique ID\n"); return (NO_ANSWER_RBV); } if (strncmp(Answer + strlen(cmdstr), "0\n", 2) == 0) { strippedAnswer = Answer + strlen(temp) + 2; DebugPrintf(2, strippedAnswer); } else { DebugPrintf(2, "unknown\n"); } #endif // 0 /* In case of a download to RAM, use full RAM for downloading * set the flash parameters to full RAM also. * This makes sure that all code is downloaded as one big sector */ if ( (IspEnvironment->BinaryOffset >= ReturnValueLpcRamStart(IspEnvironment)) &&(IspEnvironment->BinaryOffset + IspEnvironment->BinaryLength <= ReturnValueLpcRamStart(IspEnvironment)+(LPCtypes[IspEnvironment->DetectedDevice].RAMSize*1024))) { LPCtypes[IspEnvironment->DetectedDevice].FlashSectors = 1; LPCtypes[IspEnvironment->DetectedDevice].MaxCopySize = LPCtypes[IspEnvironment->DetectedDevice].RAMSize*1024 - (ReturnValueLpcRamBase(IspEnvironment) - ReturnValueLpcRamStart(IspEnvironment)); LPCtypes[IspEnvironment->DetectedDevice].SectorTable = SectorTable_RAM; SectorTable_RAM[0] = LPCtypes[IspEnvironment->DetectedDevice].MaxCopySize; } if (IspEnvironment->DetectOnly) return (0); if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC8XX) { // XON/XOFF must be switched off for LPC8XX // otherwise problem during binary transmission of data to LPC8XX DebugPrintf(3, "Switch off XON/XOFF !!!\n"); ControlXonXoffSerialPort(IspEnvironment, 0); } // Start with sector 1 and go upward... Sector 0 containing the interrupt vectors // will be loaded last, since it contains a checksum and device will re-enter // bootloader mode as long as this checksum is invalid. DebugPrintf(2, "Will start programming at Sector 1 if possible, and conclude with Sector 0 to ensure that checksum is written last.\n"); if (LPCtypes[IspEnvironment->DetectedDevice].SectorTable[0] >= IspEnvironment->BinaryLength) { Sector = 0; SectorStart = 0; } else { SectorStart = LPCtypes[IspEnvironment->DetectedDevice].SectorTable[0]; Sector = 1; } if (IspEnvironment->WipeDevice == 1) { DebugPrintf(2, "Wiping Device. "); if (LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC43XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC18XX) { // TODO: Quick and dirty hack to address bank 0 sprintf(tmpString, "P %d %d 0\r\n", 0, LPCtypes[IspEnvironment->DetectedDevice].FlashSectors-1); } else { sprintf(tmpString, "P %d %d\r\n", 0, LPCtypes[IspEnvironment->DetectedDevice].FlashSectors-1); } if (!SendAndVerify(IspEnvironment, tmpString, Answer, sizeof Answer)) { DebugPrintf(1, "Wrong answer on Prepare-Command\n"); return (WRONG_ANSWER_PREP + GetAndReportErrorNumber(Answer)); } if (LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC43XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC18XX) { // TODO: Quick and dirty hack to address bank 0 sprintf(tmpString, "E %d %d 0\r\n", 0, LPCtypes[IspEnvironment->DetectedDevice].FlashSectors-1); } else { sprintf(tmpString, "E %d %d\r\n", 0, LPCtypes[IspEnvironment->DetectedDevice].FlashSectors-1); } if (!SendAndVerify(IspEnvironment, tmpString, Answer, sizeof Answer)) { DebugPrintf(1, "Wrong answer on Erase-Command\n"); return (WRONG_ANSWER_ERAS + GetAndReportErrorNumber(Answer)); } DebugPrintf(2, "OK \n"); if (LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC43XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC18XX) { DebugPrintf(2, "ATTENTION: Only bank A was wiped!!!\n"); } } else{ //no wiping requested: erasing sector 0 first DebugPrintf(2, "Erasing sector 0 first, to invalidate checksum. "); if (LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC43XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC18XX) { // TODO: Quick and dirty hack to address bank 0 sprintf(tmpString, "P %d %d 0\r\n", 0, 0); } else { sprintf(tmpString, "P %d %d\r\n", 0, 0); } if (!SendAndVerify(IspEnvironment, tmpString, Answer, sizeof Answer)) { DebugPrintf(1, "Wrong answer on Prepare-Command\n"); return (WRONG_ANSWER_PREP + GetAndReportErrorNumber(Answer)); } if (LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC43XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC18XX) { // TODO: Quick and dirty hack to address bank 0 sprintf(tmpString, "E %d %d 0\r\n", 0, 0); } else { sprintf(tmpString, "E %d %d\r\n", 0, 0); } if (!SendAndVerify(IspEnvironment, tmpString, Answer, sizeof Answer)) { DebugPrintf(1, "Wrong answer on Erase-Command\n"); return (WRONG_ANSWER_ERAS + GetAndReportErrorNumber(Answer)); } DebugPrintf(2, "OK \n"); } while (1) { if (Sector >= LPCtypes[IspEnvironment->DetectedDevice].FlashSectors) { DebugPrintf(1, "Program too large; running out of Flash sectors.\n"); return (PROGRAM_TOO_LARGE); } DebugPrintf(2, "Sector %ld: ", Sector); fflush(stdout); if ( (IspEnvironment->BinaryOffset < ReturnValueLpcRamStart(IspEnvironment)) // Skip Erase when running from RAM ||(IspEnvironment->BinaryOffset >= ReturnValueLpcRamStart(IspEnvironment)+(LPCtypes[IspEnvironment->DetectedDevice].RAMSize*1024))) { if (LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC43XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC18XX) { // TODO: Quick and dirty hack to address bank 0 sprintf(tmpString, "P %ld %ld 0\r\n", Sector, Sector); } else { sprintf(tmpString, "P %ld %ld\r\n", Sector, Sector); } if (!SendAndVerify(IspEnvironment, tmpString, Answer, sizeof Answer)) { DebugPrintf(1, "Wrong answer on Prepare-Command (1) (Sector %ld)\n", Sector); return (WRONG_ANSWER_PREP + GetAndReportErrorNumber(Answer)); } DebugPrintf(2, "."); fflush(stdout); if (IspEnvironment->WipeDevice == 0 && (Sector!=0)) //Sector 0 already erased { if (LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC43XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC18XX) { // TODO: Quick and dirty hack to address bank 0 sprintf(tmpString, "E %ld %ld 0\r\n", Sector, Sector); } else { sprintf(tmpString, "E %ld %ld\r\n", Sector, Sector); } if (!SendAndVerify(IspEnvironment, tmpString, Answer, sizeof Answer)) { DebugPrintf(1, "Wrong answer on Erase-Command (Sector %ld)\n", Sector); return (WRONG_ANSWER_ERAS + GetAndReportErrorNumber(Answer)); } DebugPrintf(2, "."); fflush(stdout); } } SectorLength = LPCtypes[IspEnvironment->DetectedDevice].SectorTable[Sector]; if (SectorLength > IspEnvironment->BinaryLength - SectorStart) { SectorLength = IspEnvironment->BinaryLength - SectorStart; } for (SectorOffset = 0; SectorOffset < SectorLength; SectorOffset += SectorChunk) { // Check if we are to write only 0xFFs - it would be just a waste of time.. if (SectorOffset == 0) { for (SectorOffset = 0; SectorOffset < SectorLength; ++SectorOffset) { if (IspEnvironment->BinaryContent[SectorStart + SectorOffset] != 0xFF) break; } if (SectorOffset == SectorLength) // all data contents were 0xFFs { DebugPrintf(2, "Whole sector contents is 0xFFs, skipping programming."); fflush(stdout); break; } SectorOffset = 0; // re-set otherwise } if (SectorOffset > 0) { // Add a visible marker between segments in a sector DebugPrintf(2, "|"); /* means: partial segment copied */ fflush(stdout); } // If the Flash ROM sector size is bigger than the number of bytes // we can copy from RAM to Flash, we must "chop up" the sector and // copy these individually. // This is especially needed in the case where a Flash sector is // bigger than the amount of SRAM. SectorChunk = SectorLength - SectorOffset; if (SectorChunk > (unsigned)LPCtypes[IspEnvironment->DetectedDevice].MaxCopySize) { SectorChunk = LPCtypes[IspEnvironment->DetectedDevice].MaxCopySize; } // Write multiple of 45 * 4 Byte blocks to RAM, but copy maximum of on sector to Flash // In worst case we transfer up to 180 byte too much to RAM // but then we can always use full 45 byte blocks and length is multiple of 4 CopyLength = SectorChunk; if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC2XXX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC17XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC13XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC11XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC18XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC43XX) { if ((CopyLength % (45 * 4)) != 0) { CopyLength += ((45 * 4) - (CopyLength % (45 * 4))); } } sprintf(tmpString, "W %ld %ld\r\n", ReturnValueLpcRamBase(IspEnvironment), CopyLength); if (!SendAndVerify(IspEnvironment, tmpString, Answer, sizeof Answer)) { DebugPrintf(1, "Wrong answer on Write-Command\n"); return (WRONG_ANSWER_WRIT + GetAndReportErrorNumber(Answer)); } DebugPrintf(2, "."); fflush(stdout); if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC2XXX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC17XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC13XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC11XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC18XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC43XX) { block_CRC = 0; Line = 0; // Transfer blocks of 45 * 4 bytes to RAM for (Pos = SectorStart + SectorOffset; (Pos < SectorStart + SectorOffset + CopyLength) && (Pos < IspEnvironment->BinaryLength); Pos += (45 * 4)) { for (Block = 0; Block < 4; Block++) // Each block 45 bytes { DebugPrintf(2, "."); fflush(stdout); #if defined INTEGRATED_IN_WIN_APP // inform the calling application about having written another chuck of data AppWritten(45); #endif // Uuencode one 45 byte block tmpStringPos = 0; #if !defined COMPILE_FOR_LPC21 sendbuf[Line][tmpStringPos++] = (char)(' ' + 45); // Encode Length of block #else tmpString[tmpStringPos++] = (char)(' ' + 45); // Encode Length of block #endif for (BlockOffset = 0; BlockOffset < 45; BlockOffset++) { if ( (IspEnvironment->BinaryOffset < ReturnValueLpcRamStart(IspEnvironment)) ||(IspEnvironment->BinaryOffset >= ReturnValueLpcRamStart(IspEnvironment)+(LPCtypes[IspEnvironment->DetectedDevice].RAMSize*1024))) { // Flash: use full memory c = IspEnvironment->BinaryContent[Pos + Block * 45 + BlockOffset]; } else { // RAM: Skip first 0x200 bytes, these are used by the download program in LPC21xx c = IspEnvironment->BinaryContent[Pos + Block * 45 + BlockOffset + 0x200]; } block_CRC += c; k = (k << 8) + (c & 255); if ((BlockOffset % 3) == 2) // Collecting always 3 Bytes, then do processing in 4 Bytes { #if !defined COMPILE_FOR_LPC21 sendbuf[Line][tmpStringPos++] = uuencode_table[(k >> 18) & 63]; sendbuf[Line][tmpStringPos++] = uuencode_table[(k >> 12) & 63]; sendbuf[Line][tmpStringPos++] = uuencode_table[(k >> 6) & 63]; sendbuf[Line][tmpStringPos++] = uuencode_table[ k & 63]; #else tmpString[tmpStringPos++] = uuencode_table[(k >> 18) & 63]; tmpString[tmpStringPos++] = uuencode_table[(k >> 12) & 63]; tmpString[tmpStringPos++] = uuencode_table[(k >> 6) & 63]; tmpString[tmpStringPos++] = uuencode_table[ k & 63]; #endif } } #if !defined COMPILE_FOR_LPC21 sendbuf[Line][tmpStringPos++] = '\r'; sendbuf[Line][tmpStringPos++] = '\n'; sendbuf[Line][tmpStringPos++] = 0; SendComPort(IspEnvironment, sendbuf[Line]); // receive only for debug proposes ReceiveComPort(IspEnvironment, Answer, sizeof(Answer)-1, &realsize, 1, 5000); FormatCommand(sendbuf[Line], tmpString); FormatCommand(Answer, Answer); if (strncmp(Answer, tmpString, strlen(tmpString)) != 0) { DebugPrintf(1, "Error on writing data (1)\n"); return (ERROR_WRITE_DATA); } #else tmpString[tmpStringPos++] = '\r'; tmpString[tmpStringPos++] = '\n'; tmpString[tmpStringPos++] = 0; SendComPort(IspEnvironment, tmpString); ReceiveComPort(IspEnvironment, Answer, sizeof(Answer)-1, &realsize, 1, 5000); FormatCommand(tmpString, tmpString); FormatCommand(Answer, Answer); if (strncmp(Answer, tmpString, tmpStringPos) != 0) { DebugPrintf(1, "Error on writing data (1)\n"); return (ERROR_WRITE_DATA); } #endif Line++; DebugPrintf(3, "Line = %d\n", Line); if (Line == 20) { #if !defined COMPILE_FOR_LPC21 for (repeat = 0; repeat < 3; repeat++) { // DebugPrintf(1, "block_CRC = %ld\n", block_CRC); sprintf(tmpString, "%ld\r\n", block_CRC); SendComPort(IspEnvironment, tmpString); ReceiveComPort(IspEnvironment, Answer, sizeof(Answer)-1, &realsize, 2, 5000); sprintf(tmpString, "%ld\nOK\n", block_CRC); FormatCommand(tmpString, tmpString); FormatCommand(Answer, Answer); if (strcmp(Answer, tmpString) != 0) { for (i = 0; i < Line; i++) { SendComPort(IspEnvironment, sendbuf[i]); ReceiveComPort(IspEnvironment, Answer, sizeof(Answer)-1, &realsize, 1, 5000); } } else break; } if (repeat >= 3) { DebugPrintf(1, "Error on writing block_CRC (1)\n"); return (ERROR_WRITE_CRC); } #else // DebugPrintf(1, "block_CRC = %ld\n", block_CRC); sprintf(tmpString, "%ld\r\n", block_CRC); SendComPort(IspEnvironment, tmpString); ReceiveComPort(IspEnvironment, Answer, sizeof(Answer)-1, &realsize, 2,5000); sprintf(tmpString, "%ld\nOK\n", block_CRC); FormatCommand(tmpString, tmpString); FormatCommand(Answer, Answer); if (strcmp(Answer, tmpString) != 0) { DebugPrintf(1, "Error on writing block_CRC (2)\n"); return (ERROR_WRITE_CRC); } #endif Line = 0; block_CRC = 0; } } } if (Line != 0) { #if !defined COMPILE_FOR_LPC21 for (repeat = 0; repeat < 3; repeat++) { sprintf(tmpString, "%ld\r\n", block_CRC); SendComPort(IspEnvironment, tmpString); ReceiveComPort(IspEnvironment, Answer, sizeof(Answer)-1, &realsize, 2,5000); sprintf(tmpString, "%ld\nOK\n", block_CRC); FormatCommand(tmpString, tmpString); FormatCommand(Answer, Answer); if (strcmp(Answer, tmpString) != 0) { for (i = 0; i < Line; i++) { SendComPort(IspEnvironment, sendbuf[i]); ReceiveComPort(IspEnvironment, Answer, sizeof(Answer)-1, &realsize, 1,5000); } } else break; } if (repeat >= 3) { DebugPrintf(1, "Error on writing block_CRC (3)\n"); return (ERROR_WRITE_CRC2); } #else sprintf(tmpString, "%ld\r\n", block_CRC); SendComPort(IspEnvironment, tmpString); ReceiveComPort(IspEnvironment, Answer, sizeof(Answer)-1, &realsize, 2,5000); sprintf(tmpString, "%ld\nOK\n", block_CRC); FormatCommand(tmpString, tmpString); FormatCommand(Answer, Answer); if (strcmp(Answer, tmpString) != 0) { DebugPrintf(1, "Error on writing block_CRC (4)\n"); return (ERROR_WRITE_CRC2); } #endif } } else if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC8XX) { unsigned char BigAnswer[4096]; unsigned long CopyLengthPartialOffset = 0; unsigned long CopyLengthPartialRemainingBytes; while(CopyLengthPartialOffset < CopyLength) { CopyLengthPartialRemainingBytes = CopyLength - CopyLengthPartialOffset; if(CopyLengthPartialRemainingBytes > 256) { // There seems to be an error in LPC812: // When too much bytes are written at high speed, // bytes get lost // Workaround: Use smaller blocks CopyLengthPartialRemainingBytes = 256; } SendComPortBlock(IspEnvironment, &IspEnvironment->BinaryContent[SectorStart + SectorOffset + CopyLengthPartialOffset], CopyLengthPartialRemainingBytes); if (ReceiveComPortBlockComplete(IspEnvironment, &BigAnswer, CopyLengthPartialRemainingBytes, 10000) != 0) { return (ERROR_WRITE_DATA); } if(memcmp(&IspEnvironment->BinaryContent[SectorStart + SectorOffset + CopyLengthPartialOffset], BigAnswer, CopyLengthPartialRemainingBytes)) { return (ERROR_WRITE_DATA); } CopyLengthPartialOffset += CopyLengthPartialRemainingBytes; } } if ( (IspEnvironment->BinaryOffset < ReturnValueLpcRamStart(IspEnvironment)) ||(IspEnvironment->BinaryOffset >= ReturnValueLpcRamStart(IspEnvironment)+(LPCtypes[IspEnvironment->DetectedDevice].RAMSize*1024))) { // Prepare command must be repeated before every write if (LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC43XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC18XX) { // TODO: Quick and dirty hack to address bank 0 sprintf(tmpString, "P %ld %ld 0\r\n", Sector, Sector); } else { sprintf(tmpString, "P %ld %ld\r\n", Sector, Sector); } if (!SendAndVerify(IspEnvironment, tmpString, Answer, sizeof Answer)) { DebugPrintf(1, "Wrong answer on Prepare-Command (2) (Sector %ld)\n", Sector); return (WRONG_ANSWER_PREP2 + GetAndReportErrorNumber(Answer)); } // Round CopyLength up to one of the following values: 512, 1024, // 4096, 8192; but do not exceed the maximum copy size (usually // 8192, but chip-dependent) if (CopyLength < 512) { CopyLength = 512; } else if (SectorLength < 1024) { CopyLength = 1024; } else if (SectorLength < 4096) { CopyLength = 4096; } else { CopyLength = 8192; } if (CopyLength > (unsigned)LPCtypes[IspEnvironment->DetectedDevice].MaxCopySize) { CopyLength = LPCtypes[IspEnvironment->DetectedDevice].MaxCopySize; } sprintf(tmpString, "C %ld %ld %ld\r\n", IspEnvironment->BinaryOffset + SectorStart + SectorOffset, ReturnValueLpcRamBase(IspEnvironment), CopyLength); if (!SendAndVerify(IspEnvironment, tmpString, Answer, sizeof Answer)) { DebugPrintf(1, "Wrong answer on Copy-Command\n"); return (WRONG_ANSWER_COPY + GetAndReportErrorNumber(Answer)); } if (IspEnvironment->Verify) { //Avoid compare first 64 bytes. //Because first 64 bytes are re-mapped to flash boot sector, //and the compare result may not be correct. if (SectorStart + SectorOffset<64) { sprintf(tmpString, "M %d %ld %ld\r\n", 64, ReturnValueLpcRamBase(IspEnvironment) + (64 - SectorStart - SectorOffset), CopyLength-(64 - SectorStart - SectorOffset)); } else { sprintf(tmpString, "M %ld %ld %ld\r\n", SectorStart + SectorOffset, ReturnValueLpcRamBase(IspEnvironment), CopyLength); } if (!SendAndVerify(IspEnvironment, tmpString, Answer, sizeof Answer)) { DebugPrintf(1, "Wrong answer on Compare-Command\n"); return (WRONG_ANSWER_COPY + GetAndReportErrorNumber(Answer)); } } } } DebugPrintf(2, "\n"); fflush(stdout); if ((SectorStart + SectorLength) >= IspEnvironment->BinaryLength && Sector!=0) { Sector = 0; SectorStart = 0; } else if (Sector == 0) { break; } else { SectorStart += LPCtypes[IspEnvironment->DetectedDevice].SectorTable[Sector]; Sector++; } } tDoneUpload = time(NULL); if (IspEnvironment->Verify) DebugPrintf(2, "Download Finished and Verified correct... taking %d seconds\n", tDoneUpload - tStartUpload); else DebugPrintf(2, "Download Finished... taking %d seconds\n", tDoneUpload - tStartUpload); // For LPC18xx set boot bank to 0 if (LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC43XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC18XX) { if (!SendAndVerify(IspEnvironment, "S 0\r\n", Answer, sizeof Answer)) { DebugPrintf(1, "Wrong answer on SetActiveBootFlashBank-Command\n"); return (WRONG_ANSWER_BTBNK + GetAndReportErrorNumber(Answer)); } } if(IspEnvironment->DoNotStart == 0) { DebugPrintf(2, "Now launching the brand new code\n"); fflush(stdout); if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC2XXX) { sprintf(tmpString, "G %ld A\r\n", IspEnvironment->StartAddress); } else if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC43XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC18XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC17XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC13XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC11XX) { sprintf(tmpString, "G %ld T\r\n", IspEnvironment->StartAddress & ~1); } else if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC8XX) { sprintf(tmpString, "G 0 T\r\n"); } else { DebugPrintf(1, "Internal Error %s %d\n", __FILE__, __LINE__); exit(1); } SendComPort(IspEnvironment, tmpString); //goto 0 : run this fresh new downloaded code code if ( (IspEnvironment->BinaryOffset < ReturnValueLpcRamStart(IspEnvironment)) ||(IspEnvironment->BinaryOffset >= ReturnValueLpcRamStart(IspEnvironment)+(LPCtypes[IspEnvironment->DetectedDevice].RAMSize*1024))) { // Skip response on G command - show response on Terminal instead ReceiveComPort(IspEnvironment, Answer, sizeof(Answer)-1, &realsize, 2, 5000); /* the reply string is frequently terminated with a -1 (EOF) because the * connection gets broken; zero-terminate the string ourselves */ while (realsize > 0 && ((signed char) Answer[(int)realsize - 1]) < 0) realsize--; Answer[(int)realsize] = '\0'; /* Better to check only the first 9 chars instead of complete receive buffer, * because the answer can contain the output by the started programm */ if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC2XXX) { sprintf(ExpectedAnswer, "G %ld A\n0", IspEnvironment->StartAddress); } else if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC43XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC18XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC17XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC13XX || LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC11XX) { sprintf(ExpectedAnswer, "G %ld T\n0", IspEnvironment->StartAddress & ~1); } else if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC8XX) { sprintf(ExpectedAnswer, "G 0 T\n0"); } else { DebugPrintf(1, "Internal Error %s %d\n", __FILE__, __LINE__); exit(1); } FormatCommand(Answer, Answer); if (realsize == 0 || strncmp((const char *)Answer, /*cmdstr*/ExpectedAnswer, strlen(/*cmdstr*/ExpectedAnswer)) != 0) { DebugPrintf(2, "Failed to run the new downloaded code: "); return (FAILED_RUN + GetAndReportErrorNumber(Answer)); } } fflush(stdout); } return (0); } #endif // LPC_SUPPORT unsigned long ReturnValueLpcRamStart(ISP_ENVIRONMENT *IspEnvironment) { if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC43XX) { return LPC_RAMSTART_LPC43XX; } else if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC2XXX) { return LPC_RAMSTART_LPC2XXX; } else if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC18XX) { return LPC_RAMSTART_LPC18XX; } else if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC17XX) { return LPC_RAMSTART_LPC17XX; } else if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC13XX) { return LPC_RAMSTART_LPC13XX; } else if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC11XX) { return LPC_RAMSTART_LPC11XX; } else if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC8XX) { return LPC_RAMSTART_LPC8XX; } DebugPrintf(1, "Error in ReturnValueLpcRamStart (%d)\n", LPCtypes[IspEnvironment->DetectedDevice].ChipVariant); exit(1); } unsigned long ReturnValueLpcRamBase(ISP_ENVIRONMENT *IspEnvironment) { if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC43XX) { return LPC_RAMBASE_LPC43XX; } else if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC2XXX) { return LPC_RAMBASE_LPC2XXX; } else if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC18XX) { return LPC_RAMBASE_LPC18XX; } else if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC17XX) { return LPC_RAMBASE_LPC17XX; } else if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC13XX) { return LPC_RAMBASE_LPC13XX; } else if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC11XX) { return LPC_RAMBASE_LPC11XX; } else if(LPCtypes[IspEnvironment->DetectedDevice].ChipVariant == CHIP_VARIANT_LPC8XX) { return LPC_RAMBASE_LPC8XX; } DebugPrintf(1, "Error in ReturnValueLpcRamBase (%d)\n", LPCtypes[IspEnvironment->DetectedDevice].ChipVariant); exit(1); } lpc21isp_197/lpcprog.dsp100666 0 0 7015 12072733210 13540 0ustar usergroup# Microsoft Developer Studio Project File - Name="lpcprog" - Package Owner=<4> # Microsoft Developer Studio Generated Build File, Format Version 6.00 # ** DO NOT EDIT ** # TARGTYPE "Win32 (x86) Console Application" 0x0103 CFG=lpcprog - Win32 Debug !MESSAGE This is not a valid makefile. To build this project using NMAKE, !MESSAGE use the Export Makefile command and run !MESSAGE !MESSAGE NMAKE /f "lpcprog.mak". !MESSAGE !MESSAGE You can specify a configuration when running NMAKE !MESSAGE by defining the macro CFG on the command line. For example: !MESSAGE !MESSAGE NMAKE /f "lpcprog.mak" CFG="lpcprog - Win32 Debug" !MESSAGE !MESSAGE Possible choices for configuration are: !MESSAGE !MESSAGE "lpcprog - Win32 Release" (based on "Win32 (x86) Console Application") !MESSAGE "lpcprog - Win32 Debug" (based on "Win32 (x86) Console Application") !MESSAGE # Begin Project # PROP AllowPerConfigDependencies 0 # PROP Scc_ProjName "" # PROP Scc_LocalPath "" CPP=cl.exe RSC=rc.exe !IF "$(CFG)" == "lpcprog - Win32 Release" # PROP BASE Use_MFC 0 # PROP BASE Use_Debug_Libraries 0 # PROP BASE Output_Dir "Release" # PROP BASE Intermediate_Dir "Release" # PROP BASE Target_Dir "" # PROP Use_MFC 0 # PROP Use_Debug_Libraries 0 # PROP Output_Dir "Release" # PROP Intermediate_Dir "Release" # PROP Target_Dir "" # ADD BASE CPP /nologo /W3 /GX /O2 /D "WIN32" /D "NDEBUG" /D "_CONSOLE" /D "_MBCS" /YX /FD /c # ADD CPP /nologo /W3 /GX /O2 /D "WIN32" /D "NDEBUG" /D "_CONSOLE" /D "_MBCS" /YX /FD /c # ADD BASE RSC /l 0x809 /d "NDEBUG" # ADD RSC /l 0x809 /d "NDEBUG" BSC32=bscmake.exe # ADD BASE BSC32 /nologo # ADD BSC32 /nologo LINK32=link.exe # ADD BASE LINK32 kernel32.lib user32.lib gdi32.lib winspool.lib comdlg32.lib advapi32.lib shell32.lib ole32.lib oleaut32.lib uuid.lib odbc32.lib odbccp32.lib /nologo /subsystem:console /machine:I386 # ADD LINK32 kernel32.lib user32.lib gdi32.lib winspool.lib comdlg32.lib advapi32.lib shell32.lib ole32.lib oleaut32.lib uuid.lib odbc32.lib odbccp32.lib /nologo /subsystem:console /machine:I386 !ELSEIF "$(CFG)" == "lpcprog - Win32 Debug" # PROP BASE Use_MFC 0 # PROP BASE Use_Debug_Libraries 1 # PROP BASE Output_Dir "Debug" # PROP BASE Intermediate_Dir "Debug" # PROP BASE Target_Dir "" # PROP Use_MFC 0 # PROP Use_Debug_Libraries 1 # PROP Output_Dir "Debug" # PROP Intermediate_Dir "Debug" # PROP Target_Dir "" # ADD BASE CPP /nologo /W3 /Gm /GX /ZI /Od /D "WIN32" /D "_DEBUG" /D "_CONSOLE" /D "_MBCS" /YX /FD /GZ /c # ADD CPP /nologo /W3 /Gm /GX /ZI /Od /D "WIN32" /D "_DEBUG" /D "_CONSOLE" /D "_MBCS" /YX /FD /GZ /c # ADD BASE RSC /l 0x809 /d "_DEBUG" # ADD RSC /l 0x809 /d "_DEBUG" BSC32=bscmake.exe # ADD BASE BSC32 /nologo # ADD BSC32 /nologo LINK32=link.exe # ADD BASE LINK32 kernel32.lib user32.lib gdi32.lib winspool.lib comdlg32.lib advapi32.lib shell32.lib ole32.lib oleaut32.lib uuid.lib odbc32.lib odbccp32.lib /nologo /subsystem:console /debug /machine:I386 /pdbtype:sept # ADD LINK32 kernel32.lib user32.lib gdi32.lib winspool.lib comdlg32.lib advapi32.lib shell32.lib ole32.lib oleaut32.lib uuid.lib odbc32.lib odbccp32.lib /nologo /subsystem:console /debug /machine:I386 /pdbtype:sept !ENDIF # Begin Target # Name "lpcprog - Win32 Release" # Name "lpcprog - Win32 Debug" # Begin Source File SOURCE=.\adprog.c # End Source File # Begin Source File SOURCE=.\lpc21isp.c # End Source File # Begin Source File SOURCE=.\lpcprog.c # End Source File # Begin Source File SOURCE=.\lpcterm.c # End Source File # End Target # End Project lpc21isp_197/lpcprog.dsw100666 0 0 1031 12072733210 13537 0ustar usergroupMicrosoft Developer Studio Workspace File, Format Version 6.00 # WARNING: DO NOT EDIT OR DELETE THIS WORKSPACE FILE! ############################################################################### Project: "lpcprog"=.\lpcprog.dsp - Package Owner=<4> Package=<5> {{{ }}} Package=<4> {{{ }}} ############################################################################### Global: Package=<5> {{{ }}} Package=<3> {{{ }}} ############################################################################### lpc21isp_197/lpcprog.h100666 0 0 13441 12263307406 13227 0ustar usergroup/****************************************************************************** Project: Portable command line ISP for NXP LPC1000 / LPC2000 family and Analog Devices ADUC70xx Filename: lpcprog.h Compiler: Microsoft VC 6/7, Microsoft VS2008, Microsoft VS2010, GCC Cygwin, GCC Linux, GCC ARM ELF Author: Martin Maurer (Martin.Maurer@clibb.de) Copyright: (c) Martin Maurer 2003-2014, All rights reserved Portions Copyright (c) by Aeolus Development 2004 http://www.aeolusdevelopment.com This file is part of lpc21isp. lpc21isp is free software: you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation, either version 3 of the License, or any later version. lpc21isp is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License and GNU General Public License along with lpc21isp. If not, see . */ /* LPC_RAMSTART, LPC_RAMBASE * * Used in NxpDownload() to decide whether to Flash code or just place in in RAM * (works for .hex files only) * * LPC_RAMSTART - the Physical start address of the SRAM * LPC_RAMBASE - the base address where downloading starts. * Note that any code in the .hex file that resides in 0x4000,0000 ~ 0x4000,0200 * will _not_ be written to the LPCs SRAM. * This is due to the fact that 0x4000,0040 - 0x4000,0200 is used by the bootrom. * Any interrupt vectors must be copied to 0x4000,0000 and remapped to 0x0000,0000 * by the startup code. */ #define LPC_RAMSTART_LPC43XX 0x10000000L #define LPC_RAMBASE_LPC43XX 0x10000200L #define LPC_RAMSTART_LPC2XXX 0x40000000L #define LPC_RAMBASE_LPC2XXX 0x40000200L #define LPC_RAMSTART_LPC18XX 0x10000000L #define LPC_RAMBASE_LPC18XX 0x10000200L #define LPC_RAMSTART_LPC17XX 0x10000000L #define LPC_RAMBASE_LPC17XX 0x10000200L #define LPC_RAMSTART_LPC13XX 0x10000000L #define LPC_RAMBASE_LPC13XX 0x10000300L #define LPC_RAMSTART_LPC11XX 0x10000000L #define LPC_RAMBASE_LPC11XX 0x10000300L #define LPC_RAMSTART_LPC8XX 0x10000000L #define LPC_RAMBASE_LPC8XX 0x10000270L /* Return values used by NxpDownload(): reserving all values from 0x1000 to 0x1FFF */ #define NO_ANSWER_WDT 0x1000 #define NO_ANSWER_QM 0x1001 #define NO_ANSWER_SYNC 0x1002 #define NO_ANSWER_OSC 0x1003 #define NO_ANSWER_RBV 0x1004 #define NO_ANSWER_RPID 0x1005 #define ERROR_WRITE_DATA 0x1006 #define ERROR_WRITE_CRC 0x1007 #define ERROR_WRITE_CRC2 0x1008 #define PROGRAM_TOO_LARGE 0x1009 #define USER_ABORT_SYNC 0x100A /* User aborted synchronisation process */ #define UNKNOWN_LPC 0x100B /* Unknown LPC detected */ #define UNLOCK_ERROR 0x1100 /* return value is 0x1100 + NXP ISP returned value (0 to 255) */ #define WRONG_ANSWER_PREP 0x1200 /* return value is 0x1200 + NXP ISP returned value (0 to 255) */ #define WRONG_ANSWER_ERAS 0x1300 /* return value is 0x1300 + NXP ISP returned value (0 to 255) */ #define WRONG_ANSWER_WRIT 0x1400 /* return value is 0x1400 + NXP ISP returned value (0 to 255) */ #define WRONG_ANSWER_PREP2 0x1500 /* return value is 0x1500 + NXP ISP returned value (0 to 255) */ #define WRONG_ANSWER_COPY 0x1600 /* return value is 0x1600 + NXP ISP returned value (0 to 255) */ #define FAILED_RUN 0x1700 /* return value is 0x1700 + NXP ISP returned value (0 to 255) */ #define WRONG_ANSWER_BTBNK 0x1800 /* return value is 0x1800 + NXP ISP returned value (0 to 255) */ #if defined COMPILE_FOR_LPC21 #ifndef WIN32 #define LPC_BSL_PIN 13 #define LPC_RESET_PIN 47 #define LPC_RESET(in) NAsetGPIOpin(LPC_RESET_PIN, (in)) #define LPC_BSL(in) NAsetGPIOpin(LPC_BSL_PIN, (in)) #endif // WIN32 #endif // COMPILE_FOR_LPC21 /* LPC_FLASHMASK * * LPC_FLASHMASK - bitmask to define the maximum size of the Filesize to download. * LoadFile() will check any new segment address record (03) or extended linear * address record (04) to see if the addressed 64 kByte data block still falls * in the max. flash size. * LoadFile() will not load any files that are larger than this size. */ #define LPC_FLASHMASK 0xFFC00000 /* 22 bits = 4 MB */ typedef enum { CHIP_VARIANT_NONE, CHIP_VARIANT_LPC43XX, CHIP_VARIANT_LPC2XXX, CHIP_VARIANT_LPC18XX, CHIP_VARIANT_LPC17XX, CHIP_VARIANT_LPC13XX, CHIP_VARIANT_LPC11XX, CHIP_VARIANT_LPC8XX } CHIP_VARIANT; typedef struct { const unsigned long id; const unsigned long id2; const unsigned int EvalId2; const char *Product; const unsigned int FlashSize; /* in kiB, for informational purposes only */ const unsigned int RAMSize; /* in kiB, for informational purposes only */ unsigned int FlashSectors; /* total number of sectors */ unsigned int MaxCopySize; /* maximum size that can be copied to Flash in a single command */ const unsigned int *SectorTable; /* pointer to a sector table with constant the sector sizes */ const CHIP_VARIANT ChipVariant; } LPC_DEVICE_TYPE; int NxpDownload(ISP_ENVIRONMENT *IspEnvironment); unsigned long ReturnValueLpcRamStart(ISP_ENVIRONMENT *IspEnvironment); unsigned long ReturnValueLpcRamBase(ISP_ENVIRONMENT *IspEnvironment); lpc21isp_197/lpcterm.c100666 0 0 10244 12263307366 13225 0ustar usergroup/****************************************************************************** Project: Portable command line ISP for NXP LPC1000 / LPC2000 family and Analog Devices ADUC70xx Filename: lpcterm.c Compiler: Microsoft VC 6/7, Microsoft VS2008, Microsoft VS2010, GCC Cygwin, GCC Linux, GCC ARM ELF Author: Martin Maurer (Martin.Maurer@clibb.de) Copyright: (c) Martin Maurer 2003-2014, All rights reserved Portions Copyright (c) by Aeolus Development 2004 http://www.aeolusdevelopment.com This file is part of lpc21isp. lpc21isp is free software: you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation, either version 3 of the License, or any later version. lpc21isp is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License and GNU General Public License along with lpc21isp. If not, see . */ #if defined(_WIN32) #if !defined __BORLANDC__ #include "StdAfx.h" #endif #endif // defined(_WIN32) #include "lpc21isp.h" #include "lpcterm.h" #ifdef TERMINAL_SUPPORT /***************************** Terminal *********************************/ /** Acts as a simple dumb terminal. Press 'ESC' to exit. */ BOOL CheckTerminalParameters(ISP_ENVIRONMENT *IspEnvironment, char* pstr) { if (stricmp(pstr, "-localecho") == 0) { IspEnvironment->LocalEcho = 1; DebugPrintf(3, "Local echo in terminal mode.\n"); return TRUE; } if (stricmp(pstr, "-term") == 0) { IspEnvironment->TerminalAfterUpload = 1; DebugPrintf(3, "Invoke terminal after upload.\n"); return TRUE; } if (stricmp(pstr, "-termonly") == 0) { IspEnvironment->TerminalOnly = 1; IspEnvironment->ProgramChip = 0; DebugPrintf(3, "Only provide terminal.\n"); return TRUE; } return FALSE; } void Terminal(ISP_ENVIRONMENT *IspEnvironment) { if (IspEnvironment->TerminalAfterUpload || IspEnvironment->TerminalOnly) { int ch = 0; char buffer[128]; int fdlogfile = -1; unsigned long realsize; // When logging is switched on, output terminal output to lpc21isp.log if (IspEnvironment->LogFile) { fdlogfile = open("lpc21isp.log", O_RDWR | O_BINARY | O_CREAT | O_TRUNC, 0777); } PrepareKeyboardTtySettings(); DebugPrintf(1, "Terminal started (press Escape to abort)\n\n"); fflush(stdout); do { ReceiveComPort(IspEnvironment, buffer, sizeof(buffer) - 1, &realsize, 0,200); // Check for received characters if (realsize) { write(1, buffer, realsize); fflush(stdout); if (IspEnvironment->LogFile) // When logging is turned on, then copy output to logfile { write(fdlogfile, buffer, realsize); } } // check for keypress, and write any out the port. if (kbhit()) { ch = getch(); if (ch == 0x1b) { break; } buffer[0] = (unsigned char)ch; buffer[1] = 0; if (IspEnvironment->LocalEcho) { write(1, buffer, 1); } SendComPort(IspEnvironment, buffer); } } while (ch != 0x1b); DebugPrintf(1, "\n\nTerminal stopped\n\n"); fflush(stdout); ResetKeyboardTtySettings(); if (IspEnvironment->LogFile) { close(fdlogfile); } } } #endif lpc21isp_197/lpcterm.h100666 0 0 3024 12077715112 13203 0ustar usergroup/****************************************************************************** Project: Portable command line ISP for NXP LPC1000 / LPC2000 family and Analog Devices ADUC70xx Filename: lpcterm.h Compiler: Microsoft VC 6/7, Microsoft VS2008, Microsoft VS2010, GCC Cygwin, GCC Linux, GCC ARM ELF Author: Martin Maurer (Martin.Maurer@clibb.de) Copyright: (c) Martin Maurer 2003-2011, All rights reserved Portions Copyright (c) by Aeolus Development 2004 http://www.aeolusdevelopment.com This file is part of lpc21isp. lpc21isp is free software: you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation, either version 3 of the License, or any later version. lpc21isp is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License and GNU General Public License along with lpc21isp. If not, see . */ #ifndef TRUE #define TRUE (1) #endif #ifndef FALSE #define FALSE (0) #endif typedef int BOOL; void Terminal(ISP_ENVIRONMENT *IspEnvironment); BOOL CheckTerminalParameters(ISP_ENVIRONMENT *IspEnvironment, char* pstr); lpc21isp_197/Makefile100666 0 0 1451 12240173446 13026 0ustar usergroupall: lpc21isp GLOBAL_DEP = adprog.h lpc21isp.h lpcprog.h lpcterm.h CC = gcc ifneq ($(findstring(freebsd, $(OSTYPE))),) CFLAGS+=-D__FREEBSD__ endif ifeq ($(OSTYPE),) OSTYPE = $(shell uname) endif CFLAGS += -Wall ifneq ($(findstring Darwin,$(OSTYPE)),) CFLAGS+=-D__APPLE__ else CFLAGS += -static endif adprog.o: adprog.c $(GLOBAL_DEP) $(CC) $(CDEBUG) $(CFLAGS) -c -o adprog.o adprog.c lpcprog.o: lpcprog.c $(GLOBAL_DEP) $(CC) $(CDEBUG) $(CFLAGS) -c -o lpcprog.o lpcprog.c lpcterm.o: lpcterm.c $(GLOBAL_DEP) $(CC) $(CDEBUG) $(CFLAGS) -c -o lpcterm.o lpcterm.c lpc21isp: lpc21isp.c adprog.o lpcprog.o lpcterm.o $(GLOBAL_DEP) $(CC) $(CDEBUG) $(CFLAGS) -o lpc21isp lpc21isp.c adprog.o lpcprog.o lpcterm.o clean: $(RM) adprog.o lpcprog.o lpcterm.o lpc21isp lpc21isp_197/Makefile.vc100666 0 0 1257 12145442204 13434 0ustar usergroupall: lpc21isp.exe GLOBAL_DEP = lpc21isp.h adprog.h lpcprog.h lpcterm.h RM = del CC = cl # CFLAGS = -D_CRT_SECURE_NO_WARNINGS -D_CRT_NONSTDC_NO_WARNINGS CFLAGS = adprog.obj: adprog.c $(GLOBAL_DEP) $(CC) -c $(CFLAGS) adprog.c lpcprog.obj: lpcprog.c $(GLOBAL_DEP) $(CC) -c $(CFLAGS) lpcprog.c lpcterm.obj: lpcterm.c $(GLOBAL_DEP) $(CC) -c $(CFLAGS) lpcterm.c lpc21isp.obj: lpc21isp.c $(GLOBAL_DEP) $(CC) -c $(CFLAGS) lpc21isp.c lpc21isp.exe: lpc21isp.obj adprog.obj lpcprog.obj lpcterm.obj $(CC) /Felpc21isp.exe lpc21isp.obj adprog.obj lpcprog.obj lpcterm.obj winmm.lib clean: $(RM) adprog.obj lpcprog.obj lpcterm.obj lpc21isp.obj lpc21isp.exe vc*.pdb lpc21isp_197/README100666 0 0 3416 12164006746 12254 0ustar usergroup/****************************************************************************** Project: Portable command line ISP for NXP LPC family and Analog Devices ADUC70xx Filename: README Compiler: Microsoft VC 6/7, Microsoft VS2008, Microsoft VS2010, GCC Cygwin, GCC Linux, GCC ARM ELF Author: Martin Maurer (Martin.Maurer@clibb.de) Copyright: (c) Martin Maurer 2003-2013, All rights reserved Portions Copyright (c) by Aeolus Development 2004 http://www.aeolusdevelopment.com This file is part of lpc21isp. lpc21isp is free software: you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation, either version 3 of the License, or any later version. lpc21isp is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License and GNU General Public License along with lpc21isp. If not, see . */ To compile with microsoft visual studio: - Open console. Execute bat file from your installation, e.g. "c:\Program Files\Microsoft Visual Studio 9.0\VC\bin\vcvars32.bat" - Go to directory where you unpacked the source. - Run nmake /f Makefile.vc clean all To compile with gcc (linux, cygwin, ...) - Open shell / terminal windows - Run (if you want to use make and gcc) make -f Makefile.gnu clean all - Run (if you want to use gmake and gcc) gmake -f Makefile.gnu clean all lpc21isp_197/StdAfx.h100666 0 0 0 12077715112 12635 0ustar usergroup