{-# LANGUAGE MultiParamTypeClasses, FunctionalDependencies #-} {-| Maintainer: Thomas.DuBuisson@gmail.com Stability: beta Portability: portable This is the heart of the crypto-api package. By making (or having) an instance of Hash, AsymCipher, BlockCipher or StreamCipher you provide (or obtain) access to any infrastructure built on these primitives include block cipher modes of operation, hashing, hmac, signing, etc. These classes allow users to build routines that are agnostic to the algorithm used so changing algorithms is as simple as changing a type signature. -} module Crypto.Classes ( -- * Hash class and helper functions Hash(..) , hash , hash' , hashFunc , hashFunc' -- * Cipher classes and helper functions , BlockCipher(..) , blockSizeBytes , buildKeyIO , StreamCipher(..) , buildStreamKeyIO , AsymCipher(..) , buildKeyPairIO , Signing(..) , buildSigningKeyPairIO -- * Misc helper functions , for , (.::.) ) where import Data.Serialize import qualified Data.ByteString.Lazy as L import qualified Data.ByteString as B import qualified Data.ByteString.Internal as I import Data.List (foldl') import Data.Word (Word64) import Data.Tagged import Crypto.Types import Crypto.Random import System.Entropy -- |The Hash class is intended as the generic interface -- targeted by maintainers of Haskell digest implementations. -- Using this generic interface, higher level functions -- such as 'hash' and 'hash'' provide a useful API -- for comsumers of hash implementations. -- -- Any instantiated implementation must handle unaligned data class (Serialize d, Eq d, Ord d) => Hash ctx d | d -> ctx, ctx -> d where outputLength :: Tagged d BitLength -- ^ The size of the digest when encoded blockLength :: Tagged d BitLength -- ^ The amount of data operated on in each round of the digest computation initialCtx :: ctx -- ^ An initial context, provided with the first call to 'updateCtx' updateCtx :: ctx -> B.ByteString -> ctx -- ^ Used to update a context, repeatedly called until all data is exhausted -- must operate correctly for imputs of @n*blockLength@ bytes for @n `elem` [0..]@ finalize :: ctx -> B.ByteString -> d -- ^ Finializing a context, plus any message data less than the block size, into a digest -- |Hash a lazy ByteString, creating a digest hash :: (Hash ctx d) => L.ByteString -> d hash msg = res where res = finalize ctx end ctx = foldl' updateCtx initialCtx blks (blks,end) = makeBlocks msg blockLen blockLen = (blockLength .::. res) `div` 8 -- |Hash a strict ByteString, creating a digest hash' :: (Hash ctx d) => B.ByteString -> d hash' msg = res where res = finalize (updateCtx initialCtx top) end (top, end) = B.splitAt remlen msg remlen = B.length msg - (B.length msg `rem` bLen) bLen = blockLength `for` res `div` 8 -- |Obtain a lazy hash function whose result is the same type -- as the given digest, which is discarded. If the type is already inferred then -- consider using the 'hash' function instead. hashFunc :: Hash c d => d -> (L.ByteString -> d) hashFunc d = f where f = hash a = f undefined `asTypeOf` d -- |Obtain a strict hash function whose result is the same type -- as the given digest, which is discarded. If the type is already inferred then -- consider using the 'hash'' function instead. hashFunc' :: Hash c d => d -> (B.ByteString -> d) hashFunc' d = f where f = hash' a = f undefined `asTypeOf` d {-# INLINE makeBlocks #-} makeBlocks :: L.ByteString -> ByteLength -> ([B.ByteString], B.ByteString) makeBlocks msg len = go (L.toChunks msg) where go [] = ([],B.empty) go (x:xs) | B.length x >= len = let l = B.length x - B.length x `rem` len (top,end) = B.splitAt l x (rest,trueEnd) = go (end:xs) in (top:rest, trueEnd) | otherwise = case xs of [] -> ([], x) (a:as) -> go (B.append x a : as) -- |Obtain a tagged value for a given type for :: Tagged a b -> a -> b for t _ = unTagged t -- |Infix `for` operator (.::.) :: Tagged a b -> a -> b (.::.) = for -- |The BlockCipher class is intended as the generic interface -- targeted by maintainers of Haskell cipher implementations. -- Using this generic interface higher level functions -- such as 'cbc', and other functions from Data.Crypto.Modes, provide a useful API -- for comsumers of cipher implementations. -- -- Instances must handle unaligned data class ( Serialize k) => BlockCipher k where blockSize :: Tagged k BitLength -- ^ The size of a single block; the smallest unit on which the cipher operates. encryptBlock :: k -> B.ByteString -> B.ByteString -- ^ encrypt data of size @n*blockSize@ where @n `elem` [0..]@ (ecb encryption) decryptBlock :: k -> B.ByteString -> B.ByteString -- ^ decrypt data of size @n*blockSize@ where @n `elem` [0..]@ (ecb decryption) buildKey :: B.ByteString -> Maybe k -- ^ smart constructor for keys from a bytestring. keyLength :: Tagged k BitLength -- ^ length of the cryptographic key -- |The number of bytes in a block cipher block blockSizeBytes :: (BlockCipher k) => Tagged k ByteLength blockSizeBytes = fmap (`div` 8) blockSize -- |Build a symmetric key using the system entropy (see 'System.Crypto.Random') buildKeyIO :: (BlockCipher k) => IO k buildKeyIO = go 0 where go 1000 = error "Tried 1000 times to generate a key from the system entropy.\ \ No keys were returned! Perhaps the system entropy is broken\ \ or perhaps the BlockCipher instance being used has a non-flat\ \ keyspace." go i = do let bs = keyLength kd <- getEntropy ((7 + untag bs) `div` 8) case buildKey kd of Nothing -> go (i+1) Just k -> return $ k `asTaggedTypeOf` bs -- |Asymetric ciphers (common ones being RSA or EC based) class (Serialize p, Serialize v) => AsymCipher p v where buildKeyPair :: CryptoRandomGen g => g -> BitLength -> Either GenError ((p,v),g) -- ^ build a public/private key pair using the provided generator encryptAsym :: (CryptoRandomGen g) => g -> p -> B.ByteString -> Either GenError (B.ByteString,g) -- ^ Asymetric encryption decryptAsym :: v -> B.ByteString -> Maybe B.ByteString -- ^ Asymetric decryption publicKeyLength :: p -> BitLength privateKeyLength :: v -> BitLength -- |Build a pair of asymmetric keys using the system random generator. buildKeyPairIO :: AsymCipher p v => BitLength -> IO (Either GenError (p,v)) buildKeyPairIO bl = do g <- newGenIO :: IO SystemRandom case buildKeyPair g bl of Left err -> return (Left err) Right (k,_) -> return (Right k) -- | A stream cipher class. Instance are expected to work on messages as small as one byte -- The length of the resulting cipher text should be equal -- to the length of the input message. class (Serialize k) => StreamCipher k iv | k -> iv where buildStreamKey :: B.ByteString -> Maybe k encryptStream :: k -> iv -> B.ByteString -> (B.ByteString, iv) decryptStream :: k -> iv -> B.ByteString -> (B.ByteString, iv) streamKeyLength :: Tagged k BitLength -- |Build a stream key using the system random generator buildStreamKeyIO :: StreamCipher k iv => IO k buildStreamKeyIO = go 0 where go 1000 = error "Tried 1000 times to generate a stream key from the system entropy.\ \ No keys were returned! Perhaps the system entropy is broken\ \ or perhaps the BlockCipher instance being used has a non-flat\ \ keyspace." go i = do let k = streamKeyLength kd <- getEntropy ((untag k + 7) `div` 8) case buildStreamKey kd of Nothing -> go (i+1) Just k' -> return $ k' `asTaggedTypeOf` k -- | A class for signing operations which inherently can not be as generic -- as asymetric ciphers (ex: DSA). class (Serialize p, Serialize v) => Signing p v | p -> v, v -> p where sign :: CryptoRandomGen g => g -> v -> L.ByteString -> Either GenError (B.ByteString, g) verify :: p -> L.ByteString -> B.ByteString -> Bool buildSigningPair :: CryptoRandomGen g => g -> BitLength -> Either GenError ((p, v), g) signingKeyLength :: v -> BitLength verifyingKeyLength :: p -> BitLength -- |Build a signing key using the system random generator buildSigningKeyPairIO :: (Signing p v) => BitLength -> IO (Either GenError (p,v)) buildSigningKeyPairIO bl = do g <- newGenIO :: IO SystemRandom case buildSigningPair g bl of Left err -> return $ Left err Right (k,_) -> return $ Right k