module NHC.FFI ( -- allocation mallocArray, -- :: Storable a => Int -> IO (Ptr a) mallocArray0, -- :: Storable a => Int -> IO (Ptr a) allocaArray, -- :: Storable a => Int -> (Ptr a -> IO b) -> IO b allocaArray0, -- :: Storable a => Int -> (Ptr a -> IO b) -> IO b reallocArray, -- :: Storable a => Ptr a -> Int -> IO (Ptr a) reallocArray0, -- :: Storable a => Ptr a -> Int -> IO (Ptr a) -- marshalling peekArray, -- :: Storable a => Int -> Ptr a -> IO [a] peekArray0, -- :: (Storable a, Eq a) => a -> Ptr a -> IO [a] pokeArray, -- :: Storable a => Ptr a -> [a] -> IO () pokeArray0, -- :: Storable a => a -> Ptr a -> [a] -> IO () -- combined allocation and marshalling newArray, -- :: Storable a => [a] -> IO (Ptr a) newArray0, -- :: Storable a => a -> [a] -> IO (Ptr a) withArray, -- :: Storable a => [a] -> (Ptr a -> IO b) -> IO b withArray0, -- :: Storable a => a -> [a] -> (Ptr a -> IO b) -> IO b -- destruction destructArray, -- :: Storable a => Int -> Ptr a -> IO () destructArray0, -- :: (Storable a, Eq a) => a -> Ptr a -> IO () -- copying (argument order: destination, source) copyArray, -- :: Storable a => Ptr a -> Ptr a -> Int -> IO () moveArray, -- :: Storable a => Ptr a -> Ptr a -> Int -> IO () -- finding the length lengthArray0, -- :: (Storable a, Eq a) => a -> Ptr a -> IO Int -- indexing advancePtr -- :: Storable a => Ptr a -> Int -> Ptr a ) where import Ptr import Storable import MarshalAlloc import MarshalUtils import Monad (zipWithM_) -- allocation -- ---------- -- allocate storage for the given number of elements of a storable type -- mallocArray :: Storable a => Int -> IO (Ptr a) mallocArray = doMalloc undefined where doMalloc :: Storable a => a -> Int -> IO (Ptr a) doMalloc dummy size = mallocBytes (size * sizeOf dummy) -- like `mallocArray', but add an extra element to signal the end of the array -- mallocArray0 :: Storable a => Int -> IO (Ptr a) mallocArray0 size = mallocArray (size + 1) -- temporarily allocate space for the given number of elements -- -- * see `MarshalAlloc.alloca' for the storage lifetime constraints -- allocaArray :: Storable a => Int -> (Ptr a -> IO b) -> IO b allocaArray = doAlloca undefined where doAlloca :: Storable a => a -> Int -> (Ptr a -> IO b) -> IO b doAlloca dummy size = allocaBytes (size * sizeOf dummy) -- like `allocaArray', but add an extra element to signal the end of the array -- allocaArray0 :: Storable a => Int -> (Ptr a -> IO b) -> IO b allocaArray0 size = allocaArray (size + 1) -- adjust the size of an array -- reallocArray :: Storable a => Ptr a -> Int -> IO (Ptr a) reallocArray = doRealloc undefined where doRealloc :: Storable a => a -> Ptr a -> Int -> IO (Ptr a) doRealloc dummy ptr size = reallocBytes ptr (size * sizeOf dummy) -- adjust the size of an array while adding an element for the end marker -- reallocArray0 :: Storable a => Ptr a -> Int -> IO (Ptr a) reallocArray0 ptr size = reallocArray ptr (size + 1) -- marshalling -- ----------- -- convert an array of given length into a Haskell list. This version -- traverses the array backwards using an accumulating parameter, -- which uses constant stack space. The previous version using mapM -- needed linear stack space. -- peekArray :: Storable a => Int -> Ptr a -> IO [a] peekArray size ptr | size <= 0 = return [] | otherwise = f (size-1) [] where f 0 acc = do e <- peekElemOff ptr 0; return (e:acc) f n acc = do e <- peekElemOff ptr n; f (n-1) (e:acc) -- convert an array terminated by the given end marker into a Haskell list -- peekArray0 :: (Storable a, Eq a) => a -> Ptr a -> IO [a] peekArray0 marker ptr = loop 0 where loop i = do val <- peekElemOff ptr i if val == marker then return [] else do rest <- loop (i+1) return (val:rest) -- write the list elements consecutive into memory -- pokeArray :: Storable a => Ptr a -> [a] -> IO () pokeArray ptr vals = zipWithM_ (pokeElemOff ptr) [0..] vals -- write the list elements consecutive into memory and terminate them with the -- given marker element -- pokeArray0 :: Storable a => a -> Ptr a -> [a] -> IO () pokeArray0 marker ptr vals = do pokeArray ptr vals pokeElemOff ptr (length vals) marker -- combined allocation and marshalling -- ----------------------------------- -- write a list of storable elements into a newly allocated, consecutive -- sequence of storable values -- newArray :: Storable a => [a] -> IO (Ptr a) newArray vals = do ptr <- mallocArray (length vals) pokeArray ptr vals return ptr -- write a list of storable elements into a newly allocated, consecutive -- sequence of storable values, where the end is fixed by the given end marker -- newArray0 :: Storable a => a -> [a] -> IO (Ptr a) newArray0 marker vals = do ptr <- mallocArray0 (length vals) pokeArray0 marker ptr vals return ptr -- temporarily store a list of storable values in memory -- withArray :: Storable a => [a] -> (Ptr a -> IO b) -> IO b withArray vals f = allocaArray len $ \ptr -> do pokeArray ptr vals res <- f ptr destructArray len ptr return res where len = length vals -- like `withArray', but a terminator indicates where the array ends -- withArray0 :: Storable a => a -> [a] -> (Ptr a -> IO b) -> IO b withArray0 marker vals f = allocaArray0 len $ \ptr -> do pokeArray0 marker ptr vals res <- f ptr destructArray (len+1) ptr return res where len = length vals -- destruction -- ----------- -- destruct each element of an array (in reverse order) -- destructArray :: Storable a => Int -> Ptr a -> IO () destructArray size ptr = sequence_ [destruct (ptr `advancePtr` i) | i <- [size-1, size-2 .. 0]] -- like `destructArray', but a terminator indicates where the array ends -- destructArray0 :: (Storable a, Eq a) => a -> Ptr a -> IO () destructArray0 marker ptr = do size <- lengthArray0 marker ptr sequence_ [destruct (ptr `advancePtr` i) | i <- [size, size-1 .. 0]] -- copying (argument order: destination, source) -- ------- -- copy the given number of elements from the second array (source) into the -- first array (destination); the copied areas may *not* overlap -- copyArray :: Storable a => Ptr a -> Ptr a -> Int -> IO () copyArray = doCopy undefined where doCopy :: Storable a => a -> Ptr a -> Ptr a -> Int -> IO () doCopy dummy dest src size = copyBytes dest src (size * sizeOf dummy) -- copy the given number of elements from the second array (source) into the -- first array (destination); the copied areas *may* overlap -- moveArray :: Storable a => Ptr a -> Ptr a -> Int -> IO () moveArray = doMove undefined where doMove :: Storable a => a -> Ptr a -> Ptr a -> Int -> IO () doMove dummy dest src size = moveBytes dest src (size * sizeOf dummy) -- finding the length -- ------------------ -- return the number of elements in an array, excluding the terminator -- lengthArray0 :: (Storable a, Eq a) => a -> Ptr a -> IO Int lengthArray0 marker ptr = loop 0 where loop i = do val <- peekElemOff ptr i if val == marker then return i else loop (i+1) -- indexing -- -------- -- advance a pointer into an array by the given number of elements -- advancePtr :: Storable a => Ptr a -> Int -> Ptr a advancePtr = doAdvance undefined where doAdvance :: Storable a => a -> Ptr a -> Int -> Ptr a doAdvance dummy ptr i = ptr `plusPtr` (i * sizeOf dummy)