module Data.Primitive.SmallArray
( SmallArray(..)
, SmallMutableArray(..)
, newSmallArray
, readSmallArray
, writeSmallArray
, copySmallArray
, copySmallMutableArray
, indexSmallArray
, indexSmallArrayM
, cloneSmallArray
, cloneSmallMutableArray
, freezeSmallArray
, unsafeFreezeSmallArray
, thawSmallArray
, unsafeThawSmallArray
, sizeofSmallArray
, sizeofSmallMutableArray
) where
#if (__GLASGOW_HASKELL__ >= 710)
#define HAVE_SMALL_ARRAY 1
#endif
#if MIN_VERSION_base(4,7,0)
import GHC.Exts hiding (toList)
import qualified GHC.Exts
#endif
import Control.Applicative
import Control.Monad
import Control.Monad.Fix
import Control.Monad.Primitive
import Control.Monad.ST
#if MIN_VERSION_base(4,4,0)
import Control.Monad.Zip
#endif
import Data.Data
import Data.Foldable
import Data.Functor.Identity
import Data.Monoid
import Text.ParserCombinators.ReadPrec
import Text.Read
import Text.Read.Lex
#if !(HAVE_SMALL_ARRAY)
import Data.Primitive.Array
import Data.Traversable
#endif
#if HAVE_SMALL_ARRAY
data SmallArray a = SmallArray (SmallArray# a)
deriving Typeable
#else
newtype SmallArray a = SmallArray (Array a) deriving
( Eq
, Ord
, Show
, Read
, Foldable
, Traversable
, Functor
, Applicative
, Alternative
, Monad
, MonadPlus
#if MIN_VERSION_base(4,4,0)
, MonadZip
#endif
, MonadFix
, Monoid
, Typeable
)
#if MIN_VERSION_base(4,7,0)
instance IsList (SmallArray a) where
type Item (SmallArray a) = a
fromListN n l = SmallArray (fromListN n l)
fromList l = SmallArray (fromList l)
toList (SmallArray a) = toList a
#endif
#endif
#if HAVE_SMALL_ARRAY
data SmallMutableArray s a = SmallMutableArray (SmallMutableArray# s a)
deriving Typeable
#else
newtype SmallMutableArray s a = SmallMutableArray (MutableArray s a)
deriving (Eq, Typeable)
#endif
newSmallArray
:: PrimMonad m
=> Int
-> a
-> m (SmallMutableArray (PrimState m) a)
#if HAVE_SMALL_ARRAY
newSmallArray (I# i#) x = primitive $ \s ->
case newSmallArray# i# x s of
(# s', sma# #) -> (# s', SmallMutableArray sma# #)
#else
newSmallArray n e = SmallMutableArray `liftM` newArray n e
#endif
readSmallArray
:: PrimMonad m
=> SmallMutableArray (PrimState m) a
-> Int
-> m a
#if HAVE_SMALL_ARRAY
readSmallArray (SmallMutableArray sma#) (I# i#) =
primitive $ readSmallArray# sma# i#
#else
readSmallArray (SmallMutableArray a) = readArray a
#endif
writeSmallArray
:: PrimMonad m
=> SmallMutableArray (PrimState m) a
-> Int
-> a
-> m ()
#if HAVE_SMALL_ARRAY
writeSmallArray (SmallMutableArray sma#) (I# i#) x =
primitive_ $ writeSmallArray# sma# i# x
#else
writeSmallArray (SmallMutableArray a) = writeArray a
#endif
indexSmallArrayM
:: Monad m
=> SmallArray a
-> Int
-> m a
#if HAVE_SMALL_ARRAY
indexSmallArrayM (SmallArray sa#) (I# i#) =
case indexSmallArray# sa# i# of
(# x #) -> pure x
#else
indexSmallArrayM (SmallArray a) = indexArrayM a
#endif
indexSmallArray
:: SmallArray a
-> Int
-> a
#if HAVE_SMALL_ARRAY
indexSmallArray sa i = runIdentity $ indexSmallArrayM sa i
#else
indexSmallArray (SmallArray a) = indexArray a
#endif
cloneSmallArray
:: SmallArray a
-> Int
-> Int
-> SmallArray a
#if HAVE_SMALL_ARRAY
cloneSmallArray (SmallArray sa#) (I# i#) (I# j#) =
SmallArray (cloneSmallArray# sa# i# j#)
#else
cloneSmallArray (SmallArray a) i j = SmallArray $ cloneArray a i j
#endif
cloneSmallMutableArray
:: PrimMonad m
=> SmallMutableArray (PrimState m) a
-> Int
-> Int
-> m (SmallMutableArray (PrimState m) a)
#if HAVE_SMALL_ARRAY
cloneSmallMutableArray (SmallMutableArray sma#) (I# o#) (I# l#) =
primitive $ \s -> case cloneSmallMutableArray# sma# o# l# s of
(# s', smb# #) -> (# s', SmallMutableArray smb# #)
#else
cloneSmallMutableArray (SmallMutableArray ma) i j =
SmallMutableArray `liftM` cloneMutableArray ma i j
#endif
freezeSmallArray
:: PrimMonad m
=> SmallMutableArray (PrimState m) a
-> Int
-> Int
-> m (SmallArray a)
#if HAVE_SMALL_ARRAY
freezeSmallArray (SmallMutableArray sma#) (I# i#) (I# j#) =
primitive $ \s -> case freezeSmallArray# sma# i# j# s of
(# s', sa# #) -> (# s', SmallArray sa# #)
#else
freezeSmallArray (SmallMutableArray ma) i j =
SmallArray `liftM` freezeArray ma i j
#endif
unsafeFreezeSmallArray
:: PrimMonad m => SmallMutableArray (PrimState m) a -> m (SmallArray a)
#if HAVE_SMALL_ARRAY
unsafeFreezeSmallArray (SmallMutableArray sma#) =
primitive $ \s -> case unsafeFreezeSmallArray# sma# s of
(# s', sa# #) -> (# s', SmallArray sa# #)
#else
unsafeFreezeSmallArray (SmallMutableArray ma) =
SmallArray `liftM` unsafeFreezeArray ma
#endif
thawSmallArray
:: PrimMonad m
=> SmallArray a
-> Int
-> Int
-> m (SmallMutableArray (PrimState m) a)
#if HAVE_SMALL_ARRAY
thawSmallArray (SmallArray sa#) (I# o#) (I# l#) =
primitive $ \s -> case thawSmallArray# sa# o# l# s of
(# s', sma# #) -> (# s', SmallMutableArray sma# #)
#else
thawSmallArray (SmallArray a) off len =
SmallMutableArray `liftM` thawArray a off len
#endif
unsafeThawSmallArray
:: PrimMonad m => SmallArray a -> m (SmallMutableArray (PrimState m) a)
#if HAVE_SMALL_ARRAY
unsafeThawSmallArray (SmallArray sa#) =
primitive $ \s -> case unsafeThawSmallArray# sa# s of
(# s', sma# #) -> (# s', SmallMutableArray sma# #)
#else
unsafeThawSmallArray (SmallArray a) = SmallMutableArray `liftM` unsafeThawArray a
#endif
copySmallArray
:: PrimMonad m
=> SmallMutableArray (PrimState m) a
-> Int
-> SmallArray a
-> Int
-> Int
-> m ()
#if HAVE_SMALL_ARRAY
copySmallArray
(SmallMutableArray dst#) (I# do#) (SmallArray src#) (I# so#) (I# l#) =
primitive_ $ copySmallArray# src# so# dst# do# l#
#else
copySmallArray (SmallMutableArray dst) i (SmallArray src) = copyArray dst i src
#endif
copySmallMutableArray
:: PrimMonad m
=> SmallMutableArray (PrimState m) a
-> Int
-> SmallMutableArray (PrimState m) a
-> Int
-> Int
-> m ()
#if HAVE_SMALL_ARRAY
copySmallMutableArray
(SmallMutableArray dst#) (I# do#)
(SmallMutableArray src#) (I# so#)
(I# l#) =
primitive_ $ copySmallMutableArray# src# so# dst# do# l#
#else
copySmallMutableArray (SmallMutableArray dst) i (SmallMutableArray src) =
copyMutableArray dst i src
#endif
sizeofSmallArray :: SmallArray a -> Int
#if HAVE_SMALL_ARRAY
sizeofSmallArray (SmallArray sa#) = I# (sizeofSmallArray# sa#)
#else
sizeofSmallArray (SmallArray a) = sizeofArray a
#endif
sizeofSmallMutableArray :: SmallMutableArray s a -> Int
#if HAVE_SMALL_ARRAY
sizeofSmallMutableArray (SmallMutableArray sa#) =
I# (sizeofSmallMutableArray# sa#)
#else
sizeofSmallMutableArray (SmallMutableArray ma) = sizeofMutableArray ma
#endif
#if HAVE_SMALL_ARRAY
die :: String -> String -> a
die fun problem = error $ "Data.Primitive.SmallArray." ++ fun ++ ": " ++ problem
emptySmallArray :: SmallArray a
emptySmallArray =
runST $ newSmallArray 0 (die "emptySmallArray" "impossible")
>>= unsafeFreezeSmallArray
createSmallArray
:: Int -> a -> (forall s. SmallMutableArray s a -> ST s ()) -> SmallArray a
createSmallArray 0 _ _ = emptySmallArray
createSmallArray i x k =
runST $ newSmallArray i x >>= \sa -> k sa *> unsafeFreezeSmallArray sa
infixl 1 ?
(?) :: (a -> b -> c) -> (b -> a -> c)
(?) = flip
noOp :: a -> ST s ()
noOp = const $ pure ()
instance Eq a => Eq (SmallArray a) where
sa1 == sa2 = length sa1 == length sa2 && loop (length sa1 1)
where
loop i
| i < 0 = True
| otherwise = indexSmallArray sa1 i == indexSmallArray sa2 i && loop (i1)
instance Eq (SmallMutableArray s a) where
SmallMutableArray sma1# == SmallMutableArray sma2# =
isTrue# (sameSmallMutableArray# sma1# sma2#)
instance Ord a => Ord (SmallArray a) where
compare sl sr = fix ? 0 $ \go i ->
if i < l
then compare (indexSmallArray sl i) (indexSmallArray sr i) <> go (i+1)
else compare (length sl) (length sr)
where l = length sl `min` length sr
instance Foldable SmallArray where
foldr f z sa = fix ? 0 $ \go i ->
if i < length sa
then f (indexSmallArray sa i) (go $ i+1)
else z
foldr' f z sa = fix ? z ? length sa 1 $ \go acc i ->
if i < 0
then acc
else go (f (indexSmallArray sa i) acc) (i1)
foldl f z sa = fix ? length sa 1 $ \go i ->
if i < 0
then z
else f (go $ i1) $ indexSmallArray sa i
foldl' f z sa = fix ? z ? 0 $ \go acc i ->
if i < length sa
then go (f acc $ indexSmallArray sa i) (i+1)
else acc
foldr1 f sa
| sz == 0 = die "foldr1" "empty list"
| otherwise = fix ? 0 $ \go i ->
if i < sz1
then f (indexSmallArray sa i) (go $ i+1)
else indexSmallArray sa $ sz1
where sz = sizeofSmallArray sa
foldl1 f sa
| sz == 0 = die "foldl1" "empty list"
| otherwise = fix ? sz1 $ \go i ->
if i < 1
then indexSmallArray sa 0
else f (go $ i1) (indexSmallArray sa i)
where sz = sizeofSmallArray sa
null sa = sizeofSmallArray sa == 0
length = sizeofSmallArray
instance Traversable SmallArray where
traverse f sa = fromListN l <$> traverse (f . indexSmallArray sa) [0..l1]
where l = length sa
instance Functor SmallArray where
fmap f sa = createSmallArray (length sa) (die "fmap" "impossible") $ \smb ->
fix ? 0 $ \go i ->
when (i < length sa) $
writeSmallArray smb i (f $ indexSmallArray sa i) *> go (i+1)
x <$ sa = createSmallArray (length sa) x noOp
instance Applicative SmallArray where
pure x = createSmallArray 1 x noOp
sa *> sb = createSmallArray (la*lb) (die "*>" "impossible") $ \smb ->
fix ? 0 $ \go i ->
when (i < la) $
copySmallArray smb 0 sb 0 lb *> go (i+1)
where
la = length sa ; lb = length sb
sa <* sb = createSmallArray (la*lb) (indexSmallArray sa $ la1) $ \sma ->
fix ? 0 $ \outer i -> when (i < la1) $ do
let a = indexSmallArray sa i
fix ? 0 $ \inner j ->
when (j < lb) $
writeSmallArray sma (la*i + j) a *> inner (j+1)
outer $ i+1
where
la = length sa ; lb = length sb
sf <*> sx = createSmallArray (lf*lx) (die "<*>" "impossible") $ \smb ->
fix ? 0 $ \outer i -> when (i < lf) $ do
let f = indexSmallArray sf i
fix ? 0 $ \inner j ->
when (j < lx) $
writeSmallArray smb (lf*i + j) (f $ indexSmallArray sx j)
*> inner (j+1)
outer $ i+1
where
lf = length sf ; lx = length sx
instance Alternative SmallArray where
empty = emptySmallArray
sl <|> sr =
createSmallArray (length sl + length sr) (die "<|>" "impossible") $ \sma ->
copySmallArray sma 0 sl 0 (length sl)
*> copySmallArray sma (length sl) sr 0 (length sr)
many sa | null sa = pure []
| otherwise = die "many" "infinite arrays are not well defined"
some sa | null sa = emptySmallArray
| otherwise = die "some" "infinite arrays are not well defined"
instance Monad SmallArray where
return = pure
(>>) = (*>)
sa >>= f = collect 0 [] (la1)
where
la = length sa
collect sz stk i
| i < 0 = createSmallArray sz (die ">>=" "impossible") $ fill 0 stk
| otherwise = let sb = f $ indexSmallArray sa i in
collect (sz + length sb) (sb:stk) (i1)
fill _ [ ] _ = return ()
fill off (sb:sbs) smb =
copySmallArray smb off sb 0 (length sb)
*> fill (off + length sb) sbs smb
fail _ = emptySmallArray
instance MonadPlus SmallArray where
mzero = empty
mplus = (<|>)
zipW :: String -> (a -> b -> c) -> SmallArray a -> SmallArray b -> SmallArray c
zipW nm = \f sa sb -> let mn = length sa `min` length sb in
createSmallArray mn (die nm "impossible") $ \mc ->
fix ? 0 $ \go i -> when (i < mn) $
writeSmallArray mc i (f (indexSmallArray sa i) (indexSmallArray sb i))
*> go (i+1)
instance MonadZip SmallArray where
mzip = zipW "mzip" (,)
mzipWith = zipW "mzipWith"
munzip sab = runST $ do
let sz = length sab
sma <- newSmallArray sz $ die "munzip" "impossible"
smb <- newSmallArray sz $ die "munzip" "impossible"
fix ? 0 $ \go i ->
when (i < sz) $ case indexSmallArray sab i of
(x, y) -> do writeSmallArray sma i x
writeSmallArray smb i y
go $ i+1
(,) <$> unsafeFreezeSmallArray sma
<*> unsafeFreezeSmallArray smb
instance MonadFix SmallArray where
mfix f = fromList . mfix $ toList . f
instance Monoid (SmallArray a) where
mempty = empty
mappend = (<|>)
mconcat sas = createSmallArray n (die "mconcat" "impossible") $ \sma ->
fix ? 0 ? sas $ \go off l -> case l of
[] -> return ()
sa:stk -> copySmallArray sma off sa 0 (length sa) *> go (off+1) stk
where n = sum . fmap length $ sas
instance IsList (SmallArray a) where
type Item (SmallArray a) = a
fromListN n l =
createSmallArray n (die "fromListN" "mismatched size and list") $ \sma ->
fix ? 0 ? l $ \go i li -> case li of
[] -> pure ()
x:xs -> writeSmallArray sma i x *> go (i+1) xs
fromList l = fromListN (length l) l
toList sa = indexSmallArray sa <$> [0 .. length sa 1]
instance Show a => Show (SmallArray a) where
showsPrec p sa = showParen (p > 10) $
showString "fromListN " . shows (length sa) . showString " "
. shows (toList sa)
instance Read a => Read (SmallArray a) where
readPrec = parens . prec 10 $ do
Symbol "fromListN" <- lexP
Number nu <- lexP
n <- maybe empty pure $ numberToInteger nu
fromListN (fromIntegral n) <$> readPrec
smallArrayDataType :: DataType
smallArrayDataType =
mkDataType "Data.Primitive.SmallArray.SmallArray" [fromListConstr]
fromListConstr :: Constr
fromListConstr = mkConstr smallArrayDataType "fromList" [] Prefix
instance Data a => Data (SmallArray a) where
toConstr _ = fromListConstr
dataTypeOf _ = smallArrayDataType
gunfold k z c = case constrIndex c of
1 -> k (z fromList)
_ -> die "gunfold" "SmallArray"
gfoldl f z m = z fromList `f` toList m
instance (Typeable s, Typeable a) => Data (SmallMutableArray s a) where
toConstr _ = die "toConstr" "SmallMutableArray"
gunfold _ _ = die "gunfold" "SmallMutableArray"
dataTypeOf _ = mkNoRepType "Data.Primitive.SmallArray.SmallMutableArray"
#endif