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|
{-# LANGUAGE MagicHash, CPP, UnboxedTuples, BangPatterns #-}
-----------------------------------------------------------------------------
-- |
-- Module : Data.Packed.Internal.Vector
-- Copyright : (c) Alberto Ruiz 2007
-- License : GPL-style
--
-- Maintainer : Alberto Ruiz <aruiz@um.es>
-- Stability : provisional
-- Portability : portable (uses FFI)
--
-- Vector implementation
--
-----------------------------------------------------------------------------
-- #hide
module Data.Packed.Internal.Vector where
import Data.Packed.Internal.Common
import Foreign
import Foreign.C.String
import Foreign.C.Types(CInt,CChar)
import Complex
import Control.Monad(when)
#if __GLASGOW_HASKELL__ >= 605
import GHC.ForeignPtr (mallocPlainForeignPtrBytes)
#else
import Foreign.ForeignPtr (mallocForeignPtrBytes)
#endif
import GHC.Base
import GHC.IOBase
-- | A one-dimensional array of objects stored in a contiguous memory block.
data Vector t =
V { dim :: {-# UNPACK #-} !Int -- ^ number of elements
, fptr :: {-# UNPACK #-} !(ForeignPtr t) -- ^ foreign pointer to the memory block
}
-- C-Haskell vector adapter
vec :: Adapt (CInt -> Ptr t -> r) (Vector t) r
vec = withVector
withVector (V n fp) f = withForeignPtr fp $ \p -> do
let v g = do
g (fi n) p
f v
-- allocates memory for a new vector
createVector :: Storable a => Int -> IO (Vector a)
createVector n = do
when (n <= 0) $ error ("trying to createVector of dim "++show n)
fp <- doMalloc undefined
return $ V n fp
where
--
-- Use the much cheaper Haskell heap allocated storage
-- for foreign pointer space we control
--
doMalloc :: Storable b => b -> IO (ForeignPtr b)
doMalloc dummy = do
#if __GLASGOW_HASKELL__ >= 605
mallocPlainForeignPtrBytes (n * sizeOf dummy)
#else
mallocForeignPtrBytes (n * sizeOf dummy)
#endif
{- | creates a Vector from a list:
@> fromList [2,3,5,7]
4 |> [2.0,3.0,5.0,7.0]@
-}
fromList :: Storable a => [a] -> Vector a
fromList l = unsafePerformIO $ do
v <- createVector (length l)
let f _ p = pokeArray p l >> return 0
app1 f vec v "fromList"
return v
safeRead v = inlinePerformIO . withForeignPtr (fptr v)
{-# INLINE safeRead #-}
inlinePerformIO :: IO a -> a
inlinePerformIO (IO m) = case m realWorld# of (# _, r #) -> r
{-# INLINE inlinePerformIO #-}
{- | extracts the Vector elements to a list
@> toList (linspace 5 (1,10))
[1.0,3.25,5.5,7.75,10.0]@
-}
toList :: Storable a => Vector a -> [a]
toList v = safeRead v $ peekArray (dim v)
{- | An alternative to 'fromList' with explicit dimension. The input
list is explicitly truncated if it is too long, so it may safely
be used, for instance, with infinite lists.
This is the format used in the instances for Show (Vector a).
-}
(|>) :: (Storable a) => Int -> [a] -> Vector a
infixl 9 |>
n |> l = if length l' == n
then fromList l'
else error "list too short for |>"
where l' = take n l
-- | access to Vector elements without range checking
at' :: Storable a => Vector a -> Int -> a
at' v n = safeRead v $ flip peekElemOff n
{-# INLINE at' #-}
--
-- turn off bounds checking with -funsafe at configure time.
-- ghc will optimise away the salways true case at compile time.
--
#if defined(UNSAFE)
safe :: Bool
safe = False
#else
safe = True
#endif
-- | access to Vector elements with range checking.
at :: Storable a => Vector a -> Int -> a
at v n
| safe = if n >= 0 && n < dim v
then at' v n
else error "vector index out of range"
| otherwise = at' v n
{-# INLINE at #-}
{- | takes a number of consecutive elements from a Vector
@> subVector 2 3 (fromList [1..10])
3 |> [3.0,4.0,5.0]@
-}
subVector :: Storable t => Int -- ^ index of the starting element
-> Int -- ^ number of elements to extract
-> Vector t -- ^ source
-> Vector t -- ^ result
subVector k l (v@V {dim=n})
| k<0 || k >= n || k+l > n || l < 0 = error "subVector out of range"
| otherwise = unsafePerformIO $ do
r <- createVector l
let f _ s _ d = copyArray d (advancePtr s k) l >> return 0
app2 f vec v vec r "subVector"
return r
{- | Reads a vector position:
@> fromList [0..9] \@\> 7
7.0@
-}
(@>) :: Storable t => Vector t -> Int -> t
infixl 9 @>
(@>) = at
{- | creates a new Vector by joining a list of Vectors
@> join [fromList [1..5], constant 1 3]
8 |> [1.0,2.0,3.0,4.0,5.0,1.0,1.0,1.0]@
-}
join :: Storable t => [Vector t] -> Vector t
join [] = error "joining zero vectors"
join [v] = v
join as = unsafePerformIO $ do
let tot = sum (map dim as)
r@V {fptr = p} <- createVector tot
withForeignPtr p $ \ptr ->
joiner as tot ptr
return r
where joiner [] _ _ = return ()
joiner (V {dim = n, fptr = b} : cs) _ p = do
withForeignPtr b $ \pb -> copyArray p pb n
joiner cs 0 (advancePtr p n)
-- | transforms a complex vector into a real vector with alternating real and imaginary parts
asReal :: Vector (Complex Double) -> Vector Double
asReal v = V { dim = 2*dim v, fptr = castForeignPtr (fptr v) }
-- | transforms a real vector into a complex vector with alternating real and imaginary parts
asComplex :: Vector Double -> Vector (Complex Double)
asComplex v = V { dim = dim v `div` 2, fptr = castForeignPtr (fptr v) }
----------------------------------------------------------------
liftVector f x = mapVector f x
liftVector2 f u v = zipVector f u v
-----------------------------------------------------------------
cloneVector :: Storable t => Vector t -> IO (Vector t)
cloneVector (v@V {dim=n}) = do
r <- createVector n
let f _ s _ d = copyArray d s n >> return 0
app2 f vec v vec r "cloneVector"
return r
------------------------------------------------------------------
-- | map on Vectors
mapVector :: (Storable a, Storable b) => (a-> b) -> Vector a -> Vector b
mapVector f v = unsafePerformIO $ do
w <- createVector (dim v)
withForeignPtr (fptr v) $ \p ->
withForeignPtr (fptr w) $ \q -> do
let go (-1) = return ()
go !k = do x <- peekElemOff p k
pokeElemOff q k (f x)
go (k-1)
go (dim v -1)
return w
{-# INLINE mapVector #-}
-- | zipWith for Vectors
zipVector :: (Storable a, Storable b, Storable c) => (a-> b -> c) -> Vector a -> Vector b -> Vector c
zipVector f u v = unsafePerformIO $ do
let n = min (dim u) (dim v)
w <- createVector n
withForeignPtr (fptr u) $ \pu ->
withForeignPtr (fptr v) $ \pv ->
withForeignPtr (fptr w) $ \pw -> do
let go (-1) = return ()
go !k = do x <- peekElemOff pu k
y <- peekElemOff pv k
pokeElemOff pw k (f x y)
go (k-1)
go (n -1)
return w
{-# INLINE zipVector #-}
foldVector f x v = unsafePerformIO $
withForeignPtr (fptr (v::Vector Double)) $ \p -> do
let go (-1) s = return s
go !k !s = do y <- peekElemOff p k
go (k-1::Int) (f y s)
go (dim v -1) x
{-# INLINE foldVector #-}
foldLoop f s0 d = go (d - 1) s0
where
go 0 s = f (0::Int) s
go !j !s = go (j - 1) (f j s)
foldVectorG f s0 v = foldLoop g s0 (dim v)
where g !k !s = f k (at' v) s
{-# INLINE g #-} -- Thanks to Ryan Ingram (http://permalink.gmane.org/gmane.comp.lang.haskell.cafe/46479)
{-# INLINE foldVectorG #-}
-------------------------------------------------------------------
-- | Loads a vector from an ASCII file (the number of elements must be known in advance).
fscanfVector :: FilePath -> Int -> IO (Vector Double)
fscanfVector filename n = do
charname <- newCString filename
res <- createVector n
app1 (gsl_vector_fscanf charname) vec res "gsl_vector_fscanf"
free charname
return res
foreign import ccall "vector_fscanf" gsl_vector_fscanf:: Ptr CChar -> TV
-- | Saves the elements of a vector, with a given format (%f, %e, %g), to an ASCII file.
fprintfVector :: FilePath -> String -> Vector Double -> IO ()
fprintfVector filename fmt v = do
charname <- newCString filename
charfmt <- newCString fmt
app1 (gsl_vector_fprintf charname charfmt) vec v "gsl_vector_fprintf"
free charname
free charfmt
foreign import ccall "vector_fprintf" gsl_vector_fprintf :: Ptr CChar -> Ptr CChar -> TV
-- | Loads a vector from a binary file (the number of elements must be known in advance).
freadVector :: FilePath -> Int -> IO (Vector Double)
freadVector filename n = do
charname <- newCString filename
res <- createVector n
app1 (gsl_vector_fread charname) vec res "gsl_vector_fread"
free charname
return res
foreign import ccall "vector_fread" gsl_vector_fread:: Ptr CChar -> TV
-- | Saves the elements of a vector to a binary file.
fwriteVector :: FilePath -> Vector Double -> IO ()
fwriteVector filename v = do
charname <- newCString filename
app1 (gsl_vector_fwrite charname) vec v "gsl_vector_fwrite"
free charname
foreign import ccall "vector_fwrite" gsl_vector_fwrite :: Ptr CChar -> TV
|