pem-0.2.2/0000755000000000000000000000000012323560433010463 5ustar0000000000000000pem-0.2.2/README.md0000644000000000000000000000012712323560433011742 0ustar0000000000000000PEM haskell library =================== Handle Privacy Enhanced Message (PEM) format. pem-0.2.2/pem.cabal0000644000000000000000000000267612323560433012243 0ustar0000000000000000Name: pem Version: 0.2.2 Description: Privacy Enhanced Mail (PEM) format reader and writer. License: BSD3 License-file: LICENSE Copyright: Vincent Hanquez Author: Vincent Hanquez Maintainer: Vincent Hanquez Synopsis: Privacy Enhanced Mail (PEM) format reader and writer. Build-Type: Simple Category: Data stability: experimental Cabal-Version: >=1.8 Homepage: http://github.com/vincenthz/hs-pem data-files: README.md extra-source-files: Tests/pem.hs Library Build-Depends: base >= 3 && < 5 , mtl , bytestring , base64-bytestring >= 1.0.0 Exposed-modules: Data.PEM Other-modules: Data.PEM.Parser Data.PEM.Writer Data.PEM.Types ghc-options: -Wall Test-Suite test-pem type: exitcode-stdio-1.0 hs-source-dirs: Tests main-is: pem.hs build-depends: base , bytestring , test-framework >= 0.3.3 , test-framework-quickcheck2 , test-framework-hunit , HUnit , QuickCheck >= 2.4.0.1 , pem source-repository head type: git location: git://github.com/vincenthz/hs-pem pem-0.2.2/Setup.hs0000644000000000000000000000005612323560433012120 0ustar0000000000000000import Distribution.Simple main = defaultMain pem-0.2.2/LICENSE0000644000000000000000000000273112323560433011473 0ustar0000000000000000Copyright (c) 2010-2012 Vincent Hanquez All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: 1. Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. 2. Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. 3. Neither the name of the author nor the names of his contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHORS OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. pem-0.2.2/Data/0000755000000000000000000000000012323560433011334 5ustar0000000000000000pem-0.2.2/Data/PEM.hs0000644000000000000000000000057212323560433012315 0ustar0000000000000000-- | -- Module : Data.PEM -- License : BSD-style -- Maintainer : Vincent Hanquez -- Stability : experimental -- Portability : portable -- -- Read and write PEM files -- module Data.PEM ( module Data.PEM.Types , module Data.PEM.Writer , module Data.PEM.Parser ) where import Data.PEM.Types import Data.PEM.Writer import Data.PEM.Parser pem-0.2.2/Data/PEM/0000755000000000000000000000000012323560433011755 5ustar0000000000000000pem-0.2.2/Data/PEM/Parser.hs0000644000000000000000000000733112323560433013551 0ustar0000000000000000{-# LANGUAGE OverloadedStrings #-} -- | -- Module : Data.PEM.Parser -- License : BSD-style -- Maintainer : Vincent Hanquez -- Stability : experimental -- Portability : portable -- -- Parse PEM content. -- -- A PEM contains contains from one to many PEM sections. -- Each section contains an optional key-value pair header -- and a binary content encoded in base64. -- module Data.PEM.Parser ( pemParseBS , pemParseLBS ) where import Data.Either (partitionEithers) import Data.ByteString (ByteString) import qualified Data.ByteString.Char8 as BC import qualified Data.ByteString.Lazy as L import qualified Data.ByteString.Lazy.Char8 as LC import qualified Data.ByteString.Base64.Lazy as Base64 import Data.PEM.Types type Line = L.ByteString parseOnePEM :: [Line] -> Either (Maybe String) (PEM, [Line]) parseOnePEM = findPem where beginMarker = "-----BEGIN " endMarker = "-----END " findPem [] = Left Nothing findPem (l:ls) = case beginMarker `prefixEat` l of Nothing -> findPem ls Just n -> getPemName getPemHeaders n ls getPemName next n ls = let (name, r) = L.break (== 0x2d) n in case r of "-----" -> next (LC.unpack name) ls _ -> Left $ Just "invalid PEM delimiter found" getPemHeaders name lbs = case getPemHeaderLoop lbs of Left err -> Left err Right (hdrs, lbs2) -> getPemContent name hdrs [] lbs2 where getPemHeaderLoop [] = Left $ Just "invalid PEM: no more content in header context" getPemHeaderLoop (r:rs) = -- FIXME doesn't properly parse headers yet Right ([], r:rs) getPemContent name hdrs contentLines lbs = case lbs of [] -> Left $ Just "invalid PEM: no end marker found" (l:ls) -> case endMarker `prefixEat` l of Nothing -> let content = Base64.decodeLenient l in getPemContent name hdrs (content : contentLines) ls Just n -> getPemName (finalizePem name hdrs contentLines) n ls finalizePem name hdrs contentLines nameEnd lbs | nameEnd /= name = Left $ Just "invalid PEM: end name doesn't match start name" | otherwise = let pem = PEM { pemName = name , pemHeader = hdrs , pemContent = toSBS $ L.concat $ reverse contentLines } in Right (pem, lbs) toSBS = BC.concat . L.toChunks prefixEat prefix x = let (x1, x2) = L.splitAt (L.length prefix) x in if x1 == prefix then Just x2 else Nothing -- | parser to get PEM sections pemParse :: [Line] -> [Either String PEM] pemParse l | null l = [] | otherwise = case parseOnePEM l of Left Nothing -> [] Left (Just err) -> [Left err] Right (p, remaining) -> Right p : pemParse remaining -- | parse a PEM content using a strict bytestring pemParseBS :: ByteString -> Either String [PEM] pemParseBS b = pemParseLBS $ L.fromChunks [b] -- | parse a PEM content using a dynamic bytestring pemParseLBS :: L.ByteString -> Either String [PEM] pemParseLBS bs = case partitionEithers $ pemParse $ map unCR $ LC.lines bs of (x:_,_ ) -> Left x ([] ,pems) -> Right pems where unCR b | L.length b > 0 && L.last b == cr = L.init b | otherwise = b cr = fromIntegral $ fromEnum '\r' pem-0.2.2/Data/PEM/Types.hs0000644000000000000000000000131512323560433013415 0ustar0000000000000000-- | -- Module : Data.PEM.Types -- License : BSD-style -- Maintainer : Vincent Hanquez -- Stability : experimental -- Portability : portable -- module Data.PEM.Types where import Data.ByteString (ByteString) -- | Represent one PEM section -- -- for now headers are not serialized at all. -- this is just available here as a placeholder for a later implementation. data PEM = PEM { pemName :: String -- ^ the name of the section, found after the dash BEGIN tag. , pemHeader :: [(String, ByteString)] -- ^ optionals key value pair header , pemContent :: ByteString -- ^ binary content of the section } deriving (Show,Eq) pem-0.2.2/Data/PEM/Writer.hs0000644000000000000000000000334112323560433013566 0ustar0000000000000000{-# LANGUAGE OverloadedStrings #-} -- | -- Module : Data.PEM.Writer -- License : BSD-style -- Maintainer : Vincent Hanquez -- Stability : experimental -- Portability : portable -- module Data.PEM.Writer ( pemWriteLBS , pemWriteBS ) where import Data.PEM.Types import Data.ByteString (ByteString) import qualified Data.ByteString as B import qualified Data.ByteString.Char8 as BC import qualified Data.ByteString.Lazy as L import qualified Data.ByteString.Base64 as Base64 -- | write a PEM structure to a builder pemWrite :: PEM -> L.ByteString pemWrite pem = L.fromChunks $ ([begin,header]++section++[end]) where begin = B.concat ["-----BEGIN ", sectionName, "-----\n"] end = B.concat ["-----END ", sectionName, "-----\n" ] section :: [ByteString] section = map encodeLine $ splitChunks $ pemContent pem header :: ByteString header = if null $ pemHeader pem then B.empty else B.concat ((concatMap toHeader (pemHeader pem)) ++ ["\n"]) toHeader :: (String, ByteString) -> [ByteString] toHeader (k,v) = [ BC.pack k, ":", v, "\n" ] -- expect only ASCII. need to find a type to represent it. sectionName = BC.pack $ pemName pem encodeLine l = Base64.encode l `B.append` "\n" splitChunks b | B.length b > 48 = let (x,y) = B.splitAt 48 b in x : splitChunks y | otherwise = [b] -- | convert a PEM structure to a bytestring pemWriteBS :: PEM -> ByteString pemWriteBS = B.concat . L.toChunks . pemWrite -- | convert a PEM structure to a lazy bytestring pemWriteLBS :: PEM -> L.ByteString pemWriteLBS = pemWrite pem-0.2.2/Tests/0000755000000000000000000000000012323560433011565 5ustar0000000000000000pem-0.2.2/Tests/pem.hs0000644000000000000000000000621112323560433012702 0ustar0000000000000000module Main where import Control.Applicative import Control.Monad import qualified Data.ByteString.Char8 as BC import Test.QuickCheck hiding ((.&.)) import Test.Framework (Test, defaultMain, testGroup) import Test.Framework.Providers.QuickCheck2 (testProperty) import Test.Framework.Providers.HUnit (testCase) import Test.HUnit ((@=?)) import Data.PEM import qualified Data.ByteString as B main :: IO () main = defaultMain tests tests :: [Test] tests = [ testGroup "units" $ testUnits , testDecodingMultiple , testUnmatchingNames , testProperty "marshall" testMarshall ] testUnits = map (\(i, (p,bs)) -> testCase (show i) (pemWriteBS p @=? BC.pack bs)) $ zip [0..] [ (p1, bp1), (p2, bp2) ] where p1 = PEM { pemName = "abc", pemHeader = [], pemContent = B.replicate 64 0 } bp1 = unlines [ "-----BEGIN abc-----" , "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA" , "AAAAAAAAAAAAAAAAAAAAAA==" , "-----END abc-----" ] p2 = PEM { pemName = "xxx", pemHeader = [], pemContent = B.replicate 12 3 } bp2 = unlines [ "-----BEGIN xxx-----" , "AwMDAwMDAwMDAwMD" , "-----END xxx-----" ] testDecodingMultiple = testCase ("multiple pems") (pemParseBS content @=? Right expected) where expected = [ PEM { pemName = "marker", pemHeader = [], pemContent = B.replicate 12 3 } , PEM { pemName = "marker2", pemHeader = [], pemContent = B.replicate 64 0 } ] content = BC.pack $ unlines [ "some text that is not related to PEM" , "and is just going to be ignored by the PEM parser." , "" , "even empty lines should be skip until the rightful marker" , "-----BEGIN marker-----" , "AwMDAwMDAwMDAwMD" , "-----END marker-----" , "some middle text" , "-----BEGIN marker2-----" , "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA" , "AAAAAAAAAAAAAAAAAAAAAA==" , "-----END marker2-----" , "and finally some trailing text." ] testUnmatchingNames = testCase "unmatching name" (let r = pemParseBS content in case r of Left _ -> True @=? True _ -> r @=? Left "") where content = BC.pack $ unlines [ "-----BEGIN marker-----" , "AAAA" , "-----END marker2-----" ] testMarshall pems = readPems == Right pems where readPems = pemParseBS writtenPems writtenPems = B.concat (map pemWriteBS pems) arbitraryName = choose (1, 30) >>= \i -> replicateM i arbitraryAscii where arbitraryAscii = elements ['A'..'Z'] arbitraryContent = choose (1,100) >>= \i -> (B.pack . map fromIntegral) `fmap` replicateM i (choose (0,255) :: Gen Int) instance Arbitrary PEM where arbitrary = PEM <$> arbitraryName <*> pure [] <*> arbitraryContent