{-# LANGUAGE CPP, FlexibleInstances, FlexibleContexts #-} #if __GLASGOW_HASKELL__ >= 701 {-# LANGUAGE Trustworthy #-} #endif ----------------------------------------------------------------------------- -- | -- Module : Data.Binary -- Copyright : Lennart Kolmodin -- License : BSD3-style (see LICENSE) -- -- Maintainer : Lennart Kolmodin <kolmodin@dtek.chalmers.se> -- Stability : unstable -- Portability : portable to Hugs and GHC. Requires the FFI and some flexible instances -- -- Binary serialisation of Haskell values to and from lazy ByteStrings. -- The Binary library provides methods for encoding Haskell values as -- streams of bytes directly in memory. The resulting @ByteString@ can -- then be written to disk, sent over the network, or futher processed -- (for example, compressed with gzip). -- -- The 'Binary' package is notable in that it provides both pure, and -- high performance serialisation. -- -- Values are always encoded in network order (big endian) form, and -- encoded data should be portable across machine endianess, word size, -- or compiler version. For example, data encoded using the Binary class -- could be written from GHC, and read back in Hugs. -- ----------------------------------------------------------------------------- module Data.Binary ( -- * The Binary class Binary(..) -- $example -- * The Get and Put monads , Get , Put -- * Useful helpers for writing instances , putWord8 , getWord8 -- * Binary serialisation , encode -- :: Binary a => a -> ByteString , decode -- :: Binary a => ByteString -> a -- * IO functions for serialisation , encodeFile -- :: Binary a => FilePath -> a -> IO () , decodeFile -- :: Binary a => FilePath -> IO a -- Lazy put and get -- , lazyPut -- , lazyGet , module Data.Word -- useful ) where import Data.Word import Data.Binary.Put import Data.Binary.Get import Control.Monad import Foreign import Data.ByteString.Lazy (ByteString) import qualified Data.ByteString.Lazy as L import Data.Char (chr,ord) import Data.List (unfoldr) -- And needed for the instances: import qualified Data.ByteString as B import qualified Data.Map as Map import qualified Data.Set as Set import qualified Data.IntMap as IntMap import qualified Data.IntSet as IntSet import qualified Data.Ratio as R import qualified Data.Tree as T import Data.Array.Unboxed -- -- This isn't available in older Hugs or older GHC -- #if __GLASGOW_HASKELL__ >= 606 import qualified Data.Sequence as Seq import qualified Data.Foldable as Fold #endif ------------------------------------------------------------------------ -- | The @Binary@ class provides 'put' and 'get', methods to encode and -- decode a Haskell value to a lazy ByteString. It mirrors the Read and -- Show classes for textual representation of Haskell types, and is -- suitable for serialising Haskell values to disk, over the network. -- -- For parsing and generating simple external binary formats (e.g. C -- structures), Binary may be used, but in general is not suitable -- for complex protocols. Instead use the Put and Get primitives -- directly. -- -- Instances of Binary should satisfy the following property: -- -- > decode . encode == id -- -- That is, the 'get' and 'put' methods should be the inverse of each -- other. A range of instances are provided for basic Haskell types. -- class Binary t where -- | Encode a value in the Put monad. put :: t -> Put -- | Decode a value in the Get monad get :: Get t -- $example -- To serialise a custom type, an instance of Binary for that type is -- required. For example, suppose we have a data structure: -- -- > data Exp = IntE Int -- > | OpE String Exp Exp -- > deriving Show -- -- We can encode values of this type into bytestrings using the -- following instance, which proceeds by recursively breaking down the -- structure to serialise: -- -- > instance Binary Exp where -- > put (IntE i) = do put (0 :: Word8) -- > put i -- > put (OpE s e1 e2) = do put (1 :: Word8) -- > put s -- > put e1 -- > put e2 -- > -- > get = do t <- get :: Get Word8 -- > case t of -- > 0 -> do i <- get -- > return (IntE i) -- > 1 -> do s <- get -- > e1 <- get -- > e2 <- get -- > return (OpE s e1 e2) -- -- Note how we write an initial tag byte to indicate each variant of the -- data type. -- -- We can simplify the writing of 'get' instances using monadic -- combinators: -- -- > get = do tag <- getWord8 -- > case tag of -- > 0 -> liftM IntE get -- > 1 -> liftM3 OpE get get get -- -- The generation of Binary instances has been automated by a script -- using Scrap Your Boilerplate generics. Use the script here: -- <http://darcs.haskell.org/binary/tools/derive/BinaryDerive.hs>. -- -- To derive the instance for a type, load this script into GHCi, and -- bring your type into scope. Your type can then have its Binary -- instances derived as follows: -- -- > $ ghci -fglasgow-exts BinaryDerive.hs -- > *BinaryDerive> :l Example.hs -- > *Main> deriveM (undefined :: Drinks) -- > -- > instance Binary Main.Drinks where -- > put (Beer a) = putWord8 0 >> put a -- > put Coffee = putWord8 1 -- > put Tea = putWord8 2 -- > put EnergyDrink = putWord8 3 -- > put Water = putWord8 4 -- > put Wine = putWord8 5 -- > put Whisky = putWord8 6 -- > get = do -- > tag_ <- getWord8 -- > case tag_ of -- > 0 -> get >>= \a -> return (Beer a) -- > 1 -> return Coffee -- > 2 -> return Tea -- > 3 -> return EnergyDrink -- > 4 -> return Water -- > 5 -> return Wine -- > 6 -> return Whisky -- > -- -- To serialise this to a bytestring, we use 'encode', which packs the -- data structure into a binary format, in a lazy bytestring -- -- > > let e = OpE "*" (IntE 7) (OpE "/" (IntE 4) (IntE 2)) -- > > let v = encode e -- -- Where 'v' is a binary encoded data structure. To reconstruct the -- original data, we use 'decode' -- -- > > decode v :: Exp -- > OpE "*" (IntE 7) (OpE "/" (IntE 4) (IntE 2)) -- -- The lazy ByteString that results from 'encode' can be written to -- disk, and read from disk using Data.ByteString.Lazy IO functions, -- such as hPutStr or writeFile: -- -- > > writeFile "/tmp/exp.txt" (encode e) -- -- And read back with: -- -- > > readFile "/tmp/exp.txt" >>= return . decode :: IO Exp -- > OpE "*" (IntE 7) (OpE "/" (IntE 4) (IntE 2)) -- -- We can also directly serialise a value to and from a Handle, or a file: -- -- > > v <- decodeFile "/tmp/exp.txt" :: IO Exp -- > OpE "*" (IntE 7) (OpE "/" (IntE 4) (IntE 2)) -- -- And write a value to disk -- -- > > encodeFile "/tmp/a.txt" v -- ------------------------------------------------------------------------ -- Wrappers to run the underlying monad -- | Encode a value using binary serialisation to a lazy ByteString. -- encode :: Binary a => a -> ByteString encode = runPut . put {-# INLINE encode #-} -- | Decode a value from a lazy ByteString, reconstructing the original structure. -- decode :: Binary a => ByteString -> a decode = runGet get ------------------------------------------------------------------------ -- Convenience IO operations -- | Lazily serialise a value to a file -- -- This is just a convenience function, it's defined simply as: -- -- > encodeFile f = B.writeFile f . encode -- -- So for example if you wanted to compress as well, you could use: -- -- > B.writeFile f . compress . encode -- encodeFile :: Binary a => FilePath -> a -> IO () encodeFile f v = L.writeFile f (encode v) -- | Lazily reconstruct a value previously written to a file. -- -- This is just a convenience function, it's defined simply as: -- -- > decodeFile f = return . decode =<< B.readFile f -- -- So for example if you wanted to decompress as well, you could use: -- -- > return . decode . decompress =<< B.readFile f -- -- After contructing the data from the input file, 'decodeFile' checks -- if the file is empty, and in doing so will force the associated file -- handle closed, if it is indeed empty. If the file is not empty, -- it is up to the decoding instance to consume the rest of the data, -- or otherwise finalise the resource. -- decodeFile :: Binary a => FilePath -> IO a decodeFile f = do s <- L.readFile f return $ runGet (do v <- get m <- isEmpty m `seq` return v) s -- needs bytestring 0.9.1.x to work ------------------------------------------------------------------------ -- Lazy put and get -- lazyPut :: (Binary a) => a -> Put -- lazyPut a = put (encode a) -- lazyGet :: (Binary a) => Get a -- lazyGet = fmap decode get ------------------------------------------------------------------------ -- Simple instances -- The () type need never be written to disk: values of singleton type -- can be reconstructed from the type alone instance Binary () where put () = return () get = return () -- Bools are encoded as a byte in the range 0 .. 1 instance Binary Bool where put = putWord8 . fromIntegral . fromEnum get = liftM (toEnum . fromIntegral) getWord8 -- Values of type 'Ordering' are encoded as a byte in the range 0 .. 2 instance Binary Ordering where put = putWord8 . fromIntegral . fromEnum get = liftM (toEnum . fromIntegral) getWord8 ------------------------------------------------------------------------ -- Words and Ints -- Words8s are written as bytes instance Binary Word8 where put = putWord8 get = getWord8 -- Words16s are written as 2 bytes in big-endian (network) order instance Binary Word16 where put = putWord16be get = getWord16be -- Words32s are written as 4 bytes in big-endian (network) order instance Binary Word32 where put = putWord32be get = getWord32be -- Words64s are written as 8 bytes in big-endian (network) order instance Binary Word64 where put = putWord64be get = getWord64be -- Int8s are written as a single byte. instance Binary Int8 where put i = put (fromIntegral i :: Word8) get = liftM fromIntegral (get :: Get Word8) -- Int16s are written as a 2 bytes in big endian format instance Binary Int16 where put i = put (fromIntegral i :: Word16) get = liftM fromIntegral (get :: Get Word16) -- Int32s are written as a 4 bytes in big endian format instance Binary Int32 where put i = put (fromIntegral i :: Word32) get = liftM fromIntegral (get :: Get Word32) -- Int64s are written as a 4 bytes in big endian format instance Binary Int64 where put i = put (fromIntegral i :: Word64) get = liftM fromIntegral (get :: Get Word64) ------------------------------------------------------------------------ -- Words are are written as Word64s, that is, 8 bytes in big endian format instance Binary Word where put i = put (fromIntegral i :: Word64) get = liftM fromIntegral (get :: Get Word64) -- Ints are are written as Int64s, that is, 8 bytes in big endian format instance Binary Int where put i = put (fromIntegral i :: Int64) get = liftM fromIntegral (get :: Get Int64) ------------------------------------------------------------------------ -- -- Portable, and pretty efficient, serialisation of Integer -- -- Fixed-size type for a subset of Integer type SmallInt = Int32 -- Integers are encoded in two ways: if they fit inside a SmallInt, -- they're written as a byte tag, and that value. If the Integer value -- is too large to fit in a SmallInt, it is written as a byte array, -- along with a sign and length field. instance Binary Integer where {-# INLINE put #-} put n | n >= lo && n <= hi = do putWord8 0 put (fromIntegral n :: SmallInt) -- fast path where lo = fromIntegral (minBound :: SmallInt) :: Integer hi = fromIntegral (maxBound :: SmallInt) :: Integer put n = do putWord8 1 put sign put (unroll (abs n)) -- unroll the bytes where sign = fromIntegral (signum n) :: Word8 {-# INLINE get #-} get = do tag <- get :: Get Word8 case tag of 0 -> liftM fromIntegral (get :: Get SmallInt) _ -> do sign <- get bytes <- get let v = roll bytes return $! if sign == (1 :: Word8) then v else - v -- -- Fold and unfold an Integer to and from a list of its bytes -- unroll :: Integer -> [Word8] unroll = unfoldr step where step 0 = Nothing step i = Just (fromIntegral i, i `shiftR` 8) roll :: [Word8] -> Integer roll = foldr unstep 0 where unstep b a = a `shiftL` 8 .|. fromIntegral b {- -- -- An efficient, raw serialisation for Integer (GHC only) -- -- TODO This instance is not architecture portable. GMP stores numbers as -- arrays of machine sized words, so the byte format is not portable across -- architectures with different endianess and word size. import Data.ByteString.Base (toForeignPtr,unsafePackAddress, memcpy) import GHC.Base hiding (ord, chr) import GHC.Prim import GHC.Ptr (Ptr(..)) import GHC.IOBase (IO(..)) instance Binary Integer where put (S# i) = putWord8 0 >> put (I# i) put (J# s ba) = do putWord8 1 put (I# s) put (BA ba) get = do b <- getWord8 case b of 0 -> do (I# i#) <- get return (S# i#) _ -> do (I# s#) <- get (BA a#) <- get return (J# s# a#) instance Binary ByteArray where -- Pretty safe. put (BA ba) = let sz = sizeofByteArray# ba -- (primitive) in *bytes* addr = byteArrayContents# ba bs = unsafePackAddress (I# sz) addr in put bs -- write as a ByteString. easy, yay! -- Pretty scary. Should be quick though get = do (fp, off, n@(I# sz)) <- liftM toForeignPtr get -- so decode a ByteString assert (off == 0) $ return $ unsafePerformIO $ do (MBA arr) <- newByteArray sz -- and copy it into a ByteArray# let to = byteArrayContents# (unsafeCoerce# arr) -- urk, is this safe? withForeignPtr fp $ \from -> memcpy (Ptr to) from (fromIntegral n) freezeByteArray arr -- wrapper for ByteArray# data ByteArray = BA {-# UNPACK #-} !ByteArray# data MBA = MBA {-# UNPACK #-} !(MutableByteArray# RealWorld) newByteArray :: Int# -> IO MBA newByteArray sz = IO $ \s -> case newPinnedByteArray# sz s of { (# s', arr #) -> (# s', MBA arr #) } freezeByteArray :: MutableByteArray# RealWorld -> IO ByteArray freezeByteArray arr = IO $ \s -> case unsafeFreezeByteArray# arr s of { (# s', arr' #) -> (# s', BA arr' #) } -} instance (Binary a,Integral a) => Binary (R.Ratio a) where put r = put (R.numerator r) >> put (R.denominator r) get = liftM2 (R.%) get get ------------------------------------------------------------------------ -- Char is serialised as UTF-8 instance Binary Char where put a | c <= 0x7f = put (fromIntegral c :: Word8) | c <= 0x7ff = do put (0xc0 .|. y) put (0x80 .|. z) | c <= 0xffff = do put (0xe0 .|. x) put (0x80 .|. y) put (0x80 .|. z) | c <= 0x10ffff = do put (0xf0 .|. w) put (0x80 .|. x) put (0x80 .|. y) put (0x80 .|. z) | otherwise = error "Not a valid Unicode code point" where c = ord a z, y, x, w :: Word8 z = fromIntegral (c .&. 0x3f) y = fromIntegral (shiftR c 6 .&. 0x3f) x = fromIntegral (shiftR c 12 .&. 0x3f) w = fromIntegral (shiftR c 18 .&. 0x7) get = do let getByte = liftM (fromIntegral :: Word8 -> Int) get shiftL6 = flip shiftL 6 :: Int -> Int w <- getByte r <- case () of _ | w < 0x80 -> return w | w < 0xe0 -> do x <- liftM (xor 0x80) getByte return (x .|. shiftL6 (xor 0xc0 w)) | w < 0xf0 -> do x <- liftM (xor 0x80) getByte y <- liftM (xor 0x80) getByte return (y .|. shiftL6 (x .|. shiftL6 (xor 0xe0 w))) | otherwise -> do x <- liftM (xor 0x80) getByte y <- liftM (xor 0x80) getByte z <- liftM (xor 0x80) getByte return (z .|. shiftL6 (y .|. shiftL6 (x .|. shiftL6 (xor 0xf0 w)))) return $! chr r ------------------------------------------------------------------------ -- Instances for the first few tuples instance (Binary a, Binary b) => Binary (a,b) where put (a,b) = put a >> put b get = liftM2 (,) get get instance (Binary a, Binary b, Binary c) => Binary (a,b,c) where put (a,b,c) = put a >> put b >> put c get = liftM3 (,,) get get get instance (Binary a, Binary b, Binary c, Binary d) => Binary (a,b,c,d) where put (a,b,c,d) = put a >> put b >> put c >> put d get = liftM4 (,,,) get get get get instance (Binary a, Binary b, Binary c, Binary d, Binary e) => Binary (a,b,c,d,e) where put (a,b,c,d,e) = put a >> put b >> put c >> put d >> put e get = liftM5 (,,,,) get get get get get -- -- and now just recurse: -- instance (Binary a, Binary b, Binary c, Binary d, Binary e, Binary f) => Binary (a,b,c,d,e,f) where put (a,b,c,d,e,f) = put (a,(b,c,d,e,f)) get = do (a,(b,c,d,e,f)) <- get ; return (a,b,c,d,e,f) instance (Binary a, Binary b, Binary c, Binary d, Binary e, Binary f, Binary g) => Binary (a,b,c,d,e,f,g) where put (a,b,c,d,e,f,g) = put (a,(b,c,d,e,f,g)) get = do (a,(b,c,d,e,f,g)) <- get ; return (a,b,c,d,e,f,g) instance (Binary a, Binary b, Binary c, Binary d, Binary e, Binary f, Binary g, Binary h) => Binary (a,b,c,d,e,f,g,h) where put (a,b,c,d,e,f,g,h) = put (a,(b,c,d,e,f,g,h)) get = do (a,(b,c,d,e,f,g,h)) <- get ; return (a,b,c,d,e,f,g,h) instance (Binary a, Binary b, Binary c, Binary d, Binary e, Binary f, Binary g, Binary h, Binary i) => Binary (a,b,c,d,e,f,g,h,i) where put (a,b,c,d,e,f,g,h,i) = put (a,(b,c,d,e,f,g,h,i)) get = do (a,(b,c,d,e,f,g,h,i)) <- get ; return (a,b,c,d,e,f,g,h,i) instance (Binary a, Binary b, Binary c, Binary d, Binary e, Binary f, Binary g, Binary h, Binary i, Binary j) => Binary (a,b,c,d,e,f,g,h,i,j) where put (a,b,c,d,e,f,g,h,i,j) = put (a,(b,c,d,e,f,g,h,i,j)) get = do (a,(b,c,d,e,f,g,h,i,j)) <- get ; return (a,b,c,d,e,f,g,h,i,j) ------------------------------------------------------------------------ -- Container types instance Binary a => Binary [a] where put l = put (length l) >> mapM_ put l get = do n <- get :: Get Int getMany n -- | 'getMany n' get 'n' elements in order, without blowing the stack. getMany :: Binary a => Int -> Get [a] getMany n = go [] n where go xs 0 = return $! reverse xs go xs i = do x <- get -- we must seq x to avoid stack overflows due to laziness in -- (>>=) x `seq` go (x:xs) (i-1) {-# INLINE getMany #-} instance (Binary a) => Binary (Maybe a) where put Nothing = putWord8 0 put (Just x) = putWord8 1 >> put x get = do w <- getWord8 case w of 0 -> return Nothing _ -> liftM Just get instance (Binary a, Binary b) => Binary (Either a b) where put (Left a) = putWord8 0 >> put a put (Right b) = putWord8 1 >> put b get = do w <- getWord8 case w of 0 -> liftM Left get _ -> liftM Right get ------------------------------------------------------------------------ -- ByteStrings (have specially efficient instances) instance Binary B.ByteString where put bs = do put (B.length bs) putByteString bs get = get >>= getByteString -- -- Using old versions of fps, this is a type synonym, and non portable -- -- Requires 'flexible instances' -- instance Binary ByteString where put bs = do put (fromIntegral (L.length bs) :: Int) putLazyByteString bs get = get >>= getLazyByteString ------------------------------------------------------------------------ -- Maps and Sets instance (Ord a, Binary a) => Binary (Set.Set a) where put s = put (Set.size s) >> mapM_ put (Set.toAscList s) get = liftM Set.fromDistinctAscList get instance (Ord k, Binary k, Binary e) => Binary (Map.Map k e) where put m = put (Map.size m) >> mapM_ put (Map.toAscList m) get = liftM Map.fromDistinctAscList get instance Binary IntSet.IntSet where put s = put (IntSet.size s) >> mapM_ put (IntSet.toAscList s) get = liftM IntSet.fromDistinctAscList get instance (Binary e) => Binary (IntMap.IntMap e) where put m = put (IntMap.size m) >> mapM_ put (IntMap.toAscList m) get = liftM IntMap.fromDistinctAscList get ------------------------------------------------------------------------ -- Queues and Sequences #if __GLASGOW_HASKELL__ >= 606 -- -- This is valid Hugs, but you need the most recent Hugs -- instance (Binary e) => Binary (Seq.Seq e) where put s = put (Seq.length s) >> Fold.mapM_ put s get = do n <- get :: Get Int rep Seq.empty n get where rep xs 0 _ = return $! xs rep xs n g = xs `seq` n `seq` do x <- g rep (xs Seq.|> x) (n-1) g #endif ------------------------------------------------------------------------ -- Floating point instance Binary Double where put d = put (decodeFloat d) get = liftM2 encodeFloat get get instance Binary Float where put f = put (decodeFloat f) get = liftM2 encodeFloat get get ------------------------------------------------------------------------ -- Trees instance (Binary e) => Binary (T.Tree e) where put (T.Node r s) = put r >> put s get = liftM2 T.Node get get ------------------------------------------------------------------------ -- Arrays instance (Binary i, Ix i, Binary e) => Binary (Array i e) where put a = do put (bounds a) put (rangeSize $ bounds a) -- write the length mapM_ put (elems a) -- now the elems. get = do bs <- get n <- get -- read the length xs <- getMany n -- now the elems. return (listArray bs xs) -- -- The IArray UArray e constraint is non portable. Requires flexible instances -- instance (Binary i, Ix i, Binary e, IArray UArray e) => Binary (UArray i e) where put a = do put (bounds a) put (rangeSize $ bounds a) -- now write the length mapM_ put (elems a) get = do bs <- get n <- get xs <- getMany n return (listArray bs xs)