{-# LANGUAGE ScopedTypeVariables, CPP, BangPatterns #-} #if __GLASGOW_HASKELL__ >= 703 {-# LANGUAGE Unsafe #-} #endif {-# OPTIONS_HADDOCK hide #-} -- | -- Copyright : 2010-2011 Simon Meier, 2010 Jasper van der Jeugt -- License : BSD3-style (see LICENSE) -- -- Maintainer : Simon Meier -- Stability : unstable, private -- Portability : GHC -- -- *Warning:* this module is internal. If you find that you need it please -- contact the maintainers and explain what you are trying to do and discuss -- what you would need in the public API. It is important that you do this as -- the module may not be exposed at all in future releases. -- -- The maintainers are glad to accept patches for further -- standard encodings of standard Haskell values. -- -- If you need to write your own builder primitives, then be aware that you are -- writing code with /all saftey belts off/; i.e., -- *this is the code that might make your application vulnerable to buffer-overflow attacks!* -- The "Data.ByteString.Builder.Prim.Tests" module provides you with -- utilities for testing your encodings thoroughly. -- module Data.ByteString.Builder.Prim.Internal ( -- * Fixed-size builder primitives Size , FixedPrim , fixedPrim , size , runF , emptyF , contramapF , pairF -- , liftIOF , storableToF -- * Bounded-size builder primitives , BoundedPrim , boudedPrim , sizeBound , runB , emptyB , contramapB , pairB , eitherB , condB -- , liftIOB , toB , liftFixedToBounded -- , withSizeFB -- , withSizeBB -- * Shared operators , (>$<) , (>*<) ) where import Foreign import Prelude hiding (maxBound) #if !(__GLASGOW_HASKELL__ >= 612) -- ghc-6.10 and older do not support {-# INLINE CONLIKE #-} #define CONLIKE #endif ------------------------------------------------------------------------------ -- Supporting infrastructure ------------------------------------------------------------------------------ -- | Contravariant functors as in the @contravariant@ package. class Contravariant f where contramap :: (b -> a) -> f a -> f b infixl 4 >$< -- | A fmap-like operator for builder primitives, both bounded and fixed size. -- -- Builder primitives are contravariant so it's like the normal fmap, but -- backwards (look at the type). (If it helps to remember, the operator symbol -- is like (<$>) but backwards.) -- -- We can use it for example to prepend and/or append fixed values to an -- primitive. -- -- >showEncoding ((\x -> ('\'', (x, '\''))) >$< fixed3) 'x' = "'x'" -- > where -- > fixed3 = char7 >*< char7 >*< char7 -- -- Note that the rather verbose syntax for composition stems from the -- requirement to be able to compute the size / size bound at compile time. -- (>$<) :: Contravariant f => (b -> a) -> f a -> f b (>$<) = contramap instance Contravariant FixedPrim where contramap = contramapF instance Contravariant BoundedPrim where contramap = contramapB -- | Type-constructors supporting lifting of type-products. class Monoidal f where pair :: f a -> f b -> f (a, b) instance Monoidal FixedPrim where pair = pairF instance Monoidal BoundedPrim where pair = pairB infixr 5 >*< -- | A pairing/concatenation operator for builder primitives, both bounded and -- fixed size. -- -- For example, -- -- > toLazyByteString (primFixed (char7 >*< char7) ('x','y')) = "xy" -- -- We can combine multiple primitives using '>*<' multiple times. -- -- > toLazyByteString (primFixed (char7 >*< char7 >*< char7) ('x',('y','z'))) = "xyz" -- (>*<) :: Monoidal f => f a -> f b -> f (a, b) (>*<) = pair -- | The type used for sizes and sizeBounds of sizes. type Size = Int ------------------------------------------------------------------------------ -- Fixed-size builder primitives ------------------------------------------------------------------------------ -- | A builder primitive that always results in a sequence of bytes of a -- pre-determined, fixed size. data FixedPrim a = FP {-# UNPACK #-} !Int (a -> Ptr Word8 -> IO ()) fixedPrim :: Int -> (a -> Ptr Word8 -> IO ()) -> FixedPrim a fixedPrim = FP -- | The size of the sequences of bytes generated by this 'FixedPrim'. {-# INLINE CONLIKE size #-} size :: FixedPrim a -> Int size (FP l _) = l {-# INLINE CONLIKE runF #-} runF :: FixedPrim a -> a -> Ptr Word8 -> IO () runF (FP _ io) = io -- | The 'FixedPrim' that always results in the zero-length sequence. {-# INLINE CONLIKE emptyF #-} emptyF :: FixedPrim a emptyF = FP 0 (\_ _ -> return ()) -- | Encode a pair by encoding its first component and then its second component. {-# INLINE CONLIKE pairF #-} pairF :: FixedPrim a -> FixedPrim b -> FixedPrim (a, b) pairF (FP l1 io1) (FP l2 io2) = FP (l1 + l2) (\(x1,x2) op -> io1 x1 op >> io2 x2 (op `plusPtr` l1)) -- | Change a primitives such that it first applies a function to the value -- to be encoded. -- -- Note that primitives are 'Contrafunctors' -- . Hence, the following -- laws hold. -- -- >contramapF id = id -- >contramapF f . contramapF g = contramapF (g . f) {-# INLINE CONLIKE contramapF #-} contramapF :: (b -> a) -> FixedPrim a -> FixedPrim b contramapF f (FP l io) = FP l (\x op -> io (f x) op) -- | Convert a 'FixedPrim' to a 'BoundedPrim'. {-# INLINE CONLIKE toB #-} toB :: FixedPrim a -> BoundedPrim a toB (FP l io) = BP l (\x op -> io x op >> (return $! op `plusPtr` l)) -- | Lift a 'FixedPrim' to a 'BoundedPrim'. {-# INLINE CONLIKE liftFixedToBounded #-} liftFixedToBounded :: FixedPrim a -> BoundedPrim a liftFixedToBounded = toB {-# INLINE CONLIKE storableToF #-} storableToF :: forall a. Storable a => FixedPrim a storableToF = FP (sizeOf (undefined :: a)) (\x op -> poke (castPtr op) x) {- {-# INLINE CONLIKE liftIOF #-} liftIOF :: FixedPrim a -> FixedPrim (IO a) liftIOF (FP l io) = FP l (\xWrapped op -> do x <- xWrapped; io x op) -} ------------------------------------------------------------------------------ -- Bounded-size builder primitives ------------------------------------------------------------------------------ -- | A builder primitive that always results in sequence of bytes that is no longer -- than a pre-determined bound. data BoundedPrim a = BP {-# UNPACK #-} !Int (a -> Ptr Word8 -> IO (Ptr Word8)) -- | The bound on the size of sequences of bytes generated by this 'BoundedPrim'. {-# INLINE CONLIKE sizeBound #-} sizeBound :: BoundedPrim a -> Int sizeBound (BP b _) = b boudedPrim :: Int -> (a -> Ptr Word8 -> IO (Ptr Word8)) -> BoundedPrim a boudedPrim = BP {-# INLINE CONLIKE runB #-} runB :: BoundedPrim a -> a -> Ptr Word8 -> IO (Ptr Word8) runB (BP _ io) = io -- | Change a 'BoundedPrim' such that it first applies a function to the -- value to be encoded. -- -- Note that 'BoundedPrim's are 'Contrafunctors' -- . Hence, the following -- laws hold. -- -- >contramapB id = id -- >contramapB f . contramapB g = contramapB (g . f) {-# INLINE CONLIKE contramapB #-} contramapB :: (b -> a) -> BoundedPrim a -> BoundedPrim b contramapB f (BP b io) = BP b (\x op -> io (f x) op) -- | The 'BoundedPrim' that always results in the zero-length sequence. {-# INLINE CONLIKE emptyB #-} emptyB :: BoundedPrim a emptyB = BP 0 (\_ op -> return op) -- | Encode a pair by encoding its first component and then its second component. {-# INLINE CONLIKE pairB #-} pairB :: BoundedPrim a -> BoundedPrim b -> BoundedPrim (a, b) pairB (BP b1 io1) (BP b2 io2) = BP (b1 + b2) (\(x1,x2) op -> io1 x1 op >>= io2 x2) -- | Encode an 'Either' value using the first 'BoundedPrim' for 'Left' -- values and the second 'BoundedPrim' for 'Right' values. -- -- Note that the functions 'eitherB', 'pairB', and 'contramapB' (written below -- using '>$<') suffice to construct 'BoundedPrim's for all non-recursive -- algebraic datatypes. For example, -- -- @ --maybeB :: BoundedPrim () -> BoundedPrim a -> BoundedPrim (Maybe a) --maybeB nothing just = 'maybe' (Left ()) Right '>$<' eitherB nothing just -- @ {-# INLINE CONLIKE eitherB #-} eitherB :: BoundedPrim a -> BoundedPrim b -> BoundedPrim (Either a b) eitherB (BP b1 io1) (BP b2 io2) = BP (max b1 b2) (\x op -> case x of Left x1 -> io1 x1 op; Right x2 -> io2 x2 op) -- | Conditionally select a 'BoundedPrim'. -- For example, we can implement the ASCII primitive that drops characters with -- Unicode codepoints above 127 as follows. -- -- @ --charASCIIDrop = 'condB' (< '\128') ('fromF' 'char7') 'emptyB' -- @ {-# INLINE CONLIKE condB #-} condB :: (a -> Bool) -> BoundedPrim a -> BoundedPrim a -> BoundedPrim a condB p be1 be2 = contramapB (\x -> if p x then Left x else Right x) (eitherB be1 be2)