{-# LANGUAGE FlexibleContexts #-} -- | Module define byte sources. module Raaz.Core.ByteSource ( -- * Byte sources. -- $bytesource$ ByteSource(..), PureByteSource -- InfiniteSource(..) , FillResult(..) , fill, processChunks , withFillResult ) where import Control.Applicative import Control.Monad.IO.Class import qualified Data.ByteString as B import qualified Data.ByteString.Lazy as L import Prelude hiding(length) import System.IO (Handle) import Raaz.Core.MonoidalAction import Raaz.Core.Types (BYTES, Pointer, LengthUnit (..)) import Raaz.Core.Util.ByteString( unsafeCopyToPointer , unsafeNCopyToPointer , length ) import Raaz.Core.Types.Pointer (hFillBuf) -- $bytesource$ -- -- Cryptographic input come from various sources; they can come from -- network sockets or might be just a string in the Haskell. To give a -- uniform interfaces for all such inputs, we define the abstract -- concept of a /byte source/. Essentially a byte source is one from -- which we can fill a buffer with bytes. Depending on the nature of -- the source we have two classes: `ByteSource` which captures bounded -- sources and `InfiniteSource` that captures never ending source of -- bytes. -- -- Among instances of `ByteSource`, some like for example -- `B.ByteString` are /pure/ in the sense filling a buffer with bytes -- from such a source has no other side-effects. This is in contrast -- to a source like a sockets. The type class `PureByteSource` -- captures such byte sources. -- -- | This type captures the result of a fill operation. data FillResult a = Remaining a -- ^ the buffer is filled completely | Exhausted (BYTES Int) -- ^ source exhausted with so much -- bytes read. instance Functor FillResult where fmap f (Remaining a ) = Remaining $ f a fmap _ (Exhausted sz) = Exhausted sz -- | Combinator to handle a fill result. withFillResult :: (a -> b) -- ^ stuff to do when filled -> (BYTES Int -> b) -- ^ stuff to do when exhausted -> FillResult a -- ^ the fill result to process -> b withFillResult continueWith _ (Remaining a) = continueWith a withFillResult _ endBy (Exhausted sz) = endBy sz ------------------------ Byte sources ---------------------------------- -- | Abstract byte sources. A bytesource is something that you can use -- to fill a buffer. class ByteSource src where -- | Fills a buffer from the source. fillBytes :: BYTES Int -- ^ Buffer size -> src -- ^ The source to fill. -> Pointer -- ^ Buffer pointer -> IO (FillResult src) -- default fillBytes :: InfiniteSource src => BYTES Int -> src -> Pointer -> IO (FillResult src) -- fillBytes sz src pointer = Remaining <$> slurp sz src pointer -- | A version of fillBytes that takes type safe lengths as input. fill :: ( LengthUnit len , ByteSource src ) => len -> src -> Pointer -> IO (FillResult src) fill = fillBytes . inBytes {-# INLINE fill #-} {-- -- | Never ending stream of bytes. The reads to the stream might get -- delayed but it will always return the number of bytes that were -- asked for. class InfiniteSource src where slurpBytes :: BYTES Int -- ^ bytes to read, -> src -- ^ the source to fill from, -> Pointer -- ^ the buffer source to fill. -> IO src -- | A version of slurp that takes type safe lengths as input. slurp :: ( LengthUnit len , InfiniteSource src ) => len -> src -> Pointer -> IO src slurp = slurpBytes . inBytes --} -- | Process data from a source in chunks of a particular size. processChunks :: ( MonadIO m, LengthUnit chunkSize, ByteSource src) => m a -- action on a complete chunk, -> (BYTES Int -> m b) -- action on the last partial chunk, -> src -- the source -> chunkSize -- size of the chunksize -> Pointer -- buffer to fill the chunk in -> m b processChunks mid end source csz ptr = go source where fillChunk src = liftIO $ fill csz src ptr step src = mid >> go src go src = fillChunk src >>= withFillResult step end -- | A byte source src is pure if filling from it does not have any -- other side effect on the state of the byte source. Formally, two -- different fills form the same source should fill the buffer with -- the same bytes. This additional constraint on the source helps to -- /purify/ certain crypto computations like computing the hash or mac -- of the source. Usualy sources like `B.ByteString` etc are pure byte -- sources. A file handle is a byte source that is /not/ a pure -- source. class ByteSource src => PureByteSource src where ----------------------- Instances of byte source ----------------------- instance ByteSource Handle where {-# INLINE fillBytes #-} fillBytes sz hand cptr = do count <- hFillBuf hand cptr sz return (if count < sz then Exhausted count else Remaining hand) instance ByteSource B.ByteString where {-# INLINE fillBytes #-} fillBytes sz bs cptr | l < sz = do unsafeCopyToPointer bs cptr return $ Exhausted l | otherwise = do unsafeNCopyToPointer sz bs cptr return $ Remaining rest where l = length bs rest = B.drop (fromIntegral sz) bs instance ByteSource L.ByteString where {-# INLINE fillBytes #-} fillBytes sz bs = fmap (fmap L.fromChunks) . fillBytes sz (L.toChunks bs) instance ByteSource src => ByteSource (Maybe src) where {-# INLINE fillBytes #-} fillBytes sz ma cptr = maybe exhausted fillIt ma where exhausted = return $ Exhausted 0 fillIt a = fmap Just <$> fillBytes sz a cptr instance ByteSource src => ByteSource [src] where fillBytes _ [] _ = return $ Exhausted 0 fillBytes sz (x:xs) cptr = do result <- fillBytes sz x cptr case result of Exhausted rbytes -> let nptr = rbytes <.> cptr in fillBytes (sz - rbytes) xs nptr Remaining nx -> return $ Remaining $ nx:xs --------------------- Instances of pure byte source -------------------- instance PureByteSource B.ByteString where instance PureByteSource L.ByteString where instance PureByteSource src => PureByteSource [src] instance PureByteSource src => PureByteSource (Maybe src)