{-# LANGUAGE Unsafe #-} {-# LANGUAGE NoImplicitPrelude, MagicHash, UnboxedTuples, RoleAnnotations #-} {-# OPTIONS_HADDOCK hide #-} ----------------------------------------------------------------------------- -- | -- Module : GHC.Arr -- Copyright : (c) The University of Glasgow, 1994-2000 -- License : see libraries/base/LICENSE -- -- Maintainer : cvs-ghc@haskell.org -- Stability : internal -- Portability : non-portable (GHC extensions) -- -- GHC\'s array implementation. -- ----------------------------------------------------------------------------- module GHC.Arr ( Ix(..), Array(..), STArray(..), indexError, hopelessIndexError, arrEleBottom, array, listArray, (!), safeRangeSize, negRange, safeIndex, badSafeIndex, bounds, numElements, numElementsSTArray, indices, elems, assocs, accumArray, adjust, (//), accum, amap, ixmap, eqArray, cmpArray, cmpIntArray, newSTArray, boundsSTArray, readSTArray, writeSTArray, freezeSTArray, thawSTArray, foldlElems, foldlElems', foldl1Elems, foldrElems, foldrElems', foldr1Elems, -- * Unsafe operations fill, done, unsafeArray, unsafeArray', lessSafeIndex, unsafeAt, unsafeReplace, unsafeAccumArray, unsafeAccumArray', unsafeAccum, unsafeReadSTArray, unsafeWriteSTArray, unsafeFreezeSTArray, unsafeThawSTArray, ) where import GHC.Enum import GHC.Num import GHC.ST import GHC.Base import GHC.List import GHC.Real( fromIntegral ) import GHC.Show infixl 9 !, // default () -- | The 'Ix' class is used to map a contiguous subrange of values in -- a type onto integers. It is used primarily for array indexing -- (see the array package). -- -- The first argument @(l,u)@ of each of these operations is a pair -- specifying the lower and upper bounds of a contiguous subrange of values. -- -- An implementation is entitled to assume the following laws about these -- operations: -- -- * @'inRange' (l,u) i == 'elem' i ('range' (l,u))@ @ @ -- -- * @'range' (l,u) '!!' 'index' (l,u) i == i@, when @'inRange' (l,u) i@ -- -- * @'map' ('index' (l,u)) ('range' (l,u))) == [0..'rangeSize' (l,u)-1]@ @ @ -- -- * @'rangeSize' (l,u) == 'length' ('range' (l,u))@ @ @ -- class (Ord a) => Ix a where {-# MINIMAL range, (index | unsafeIndex), inRange #-} -- | The list of values in the subrange defined by a bounding pair. range :: (a,a) -> [a] -- | The position of a subscript in the subrange. index :: (a,a) -> a -> Int -- | Like 'index', but without checking that the value is in range. unsafeIndex :: (a,a) -> a -> Int -- | Returns 'True' the given subscript lies in the range defined -- the bounding pair. inRange :: (a,a) -> a -> Bool -- | The size of the subrange defined by a bounding pair. rangeSize :: (a,a) -> Int -- | like 'rangeSize', but without checking that the upper bound is -- in range. unsafeRangeSize :: (a,a) -> Int -- Must specify one of index, unsafeIndex -- 'index' is typically over-ridden in instances, with essentially -- the same code, but using indexError instead of hopelessIndexError -- Reason: we have 'Show' at the instances {-# INLINE index #-} -- See Note [Inlining index] index b i | inRange b i = unsafeIndex b i | otherwise = hopelessIndexError unsafeIndex b i = index b i rangeSize b@(_l,h) | inRange b h = unsafeIndex b h + 1 | otherwise = 0 -- This case is only here to -- check for an empty range -- NB: replacing (inRange b h) by (l <= h) fails for -- tuples. E.g. (1,2) <= (2,1) but the range is empty unsafeRangeSize b@(_l,h) = unsafeIndex b h + 1 {- Note that the following is NOT right rangeSize (l,h) | l <= h = index b h + 1 | otherwise = 0 Because it might be the case that l<h, but the range is nevertheless empty. Consider ((1,2),(2,1)) Here l<h, but the second index ranges from 2..1 and hence is empty Note [Inlining index] ~~~~~~~~~~~~~~~~~~~~~ We inline the 'index' operation, * Partly because it generates much faster code (although bigger); see Trac #1216 * Partly because it exposes the bounds checks to the simplifier which might help a big. If you make a per-instance index method, you may consider inlining it. Note [Double bounds-checking of index values] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ When you index an array, a!x, there are two possible bounds checks we might make: (A) Check that (inRange (bounds a) x) holds. (A) is checked in the method for 'index' (B) Check that (index (bounds a) x) lies in the range 0..n, where n is the size of the underlying array (B) is checked in the top-level function (!), in safeIndex. Of course it *should* be the case that (A) holds iff (B) holds, but that is a property of the particular instances of index, bounds, and inRange, so GHC cannot guarantee it. * If you do (A) and not (B), then you might get a seg-fault, by indexing at some bizarre location. Trac #1610 * If you do (B) but not (A), you may get no complaint when you index an array out of its semantic bounds. Trac #2120 At various times we have had (A) and not (B), or (B) and not (A); both led to complaints. So now we implement *both* checks (Trac #2669). For 1-d, 2-d, and 3-d arrays of Int we have specialised instances to avoid this. Note [Out-of-bounds error messages] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ The default method for 'index' generates hoplelessIndexError, because Ix doesn't have Show as a superclass. For particular base types we can do better, so we override the default method for index. -} -- Abstract these errors from the relevant index functions so that -- the guts of the function will be small enough to inline. {-# NOINLINE indexError #-} indexError :: Show a => (a,a) -> a -> String -> b indexError rng i tp = errorWithoutStackTrace (showString "Ix{" . showString tp . showString "}.index: Index " . showParen True (showsPrec 0 i) . showString " out of range " $ showParen True (showsPrec 0 rng) "") hopelessIndexError :: Int -- Try to use 'indexError' instead! hopelessIndexError = errorWithoutStackTrace "Error in array index" ---------------------------------------------------------------------- -- | @since 2.01 instance Ix Char where {-# INLINE range #-} range (m,n) = [m..n] {-# INLINE unsafeIndex #-} unsafeIndex (m,_n) i = fromEnum i - fromEnum m {-# INLINE index #-} -- See Note [Out-of-bounds error messages] -- and Note [Inlining index] index b i | inRange b i = unsafeIndex b i | otherwise = indexError b i "Char" inRange (m,n) i = m <= i && i <= n ---------------------------------------------------------------------- -- | @since 2.01 instance Ix Int where {-# INLINE range #-} -- The INLINE stops the build in the RHS from getting inlined, -- so that callers can fuse with the result of range range (m,n) = [m..n] {-# INLINE unsafeIndex #-} unsafeIndex (m,_n) i = i - m {-# INLINE index #-} -- See Note [Out-of-bounds error messages] -- and Note [Inlining index] index b i | inRange b i = unsafeIndex b i | otherwise = indexError b i "Int" {-# INLINE inRange #-} inRange (I# m,I# n) (I# i) = isTrue# (m <=# i) && isTrue# (i <=# n) -- | @since 4.6.0.0 instance Ix Word where range (m,n) = [m..n] unsafeIndex (m,_) i = fromIntegral (i - m) inRange (m,n) i = m <= i && i <= n ---------------------------------------------------------------------- -- | @since 2.01 instance Ix Integer where {-# INLINE range #-} range (m,n) = [m..n] {-# INLINE unsafeIndex #-} unsafeIndex (m,_n) i = fromInteger (i - m) {-# INLINE index #-} -- See Note [Out-of-bounds error messages] -- and Note [Inlining index] index b i | inRange b i = unsafeIndex b i | otherwise = indexError b i "Integer" inRange (m,n) i = m <= i && i <= n ---------------------------------------------------------------------- -- | @since 2.01 instance Ix Bool where -- as derived {-# INLINE range #-} range (m,n) = [m..n] {-# INLINE unsafeIndex #-} unsafeIndex (l,_) i = fromEnum i - fromEnum l {-# INLINE index #-} -- See Note [Out-of-bounds error messages] -- and Note [Inlining index] index b i | inRange b i = unsafeIndex b i | otherwise = indexError b i "Bool" inRange (l,u) i = fromEnum i >= fromEnum l && fromEnum i <= fromEnum u ---------------------------------------------------------------------- -- | @since 2.01 instance Ix Ordering where -- as derived {-# INLINE range #-} range (m,n) = [m..n] {-# INLINE unsafeIndex #-} unsafeIndex (l,_) i = fromEnum i - fromEnum l {-# INLINE index #-} -- See Note [Out-of-bounds error messages] -- and Note [Inlining index] index b i | inRange b i = unsafeIndex b i | otherwise = indexError b i "Ordering" inRange (l,u) i = fromEnum i >= fromEnum l && fromEnum i <= fromEnum u ---------------------------------------------------------------------- -- | @since 2.01 instance Ix () where {-# INLINE range #-} range ((), ()) = [()] {-# INLINE unsafeIndex #-} unsafeIndex ((), ()) () = 0 {-# INLINE inRange #-} inRange ((), ()) () = True {-# INLINE index #-} -- See Note [Inlining index] index b i = unsafeIndex b i ---------------------------------------------------------------------- -- | @since 2.01 instance (Ix a, Ix b) => Ix (a, b) where -- as derived {-# SPECIALISE instance Ix (Int,Int) #-} {-# INLINE range #-} range ((l1,l2),(u1,u2)) = [ (i1,i2) | i1 <- range (l1,u1), i2 <- range (l2,u2) ] {-# INLINE unsafeIndex #-} unsafeIndex ((l1,l2),(u1,u2)) (i1,i2) = unsafeIndex (l1,u1) i1 * unsafeRangeSize (l2,u2) + unsafeIndex (l2,u2) i2 {-# INLINE inRange #-} inRange ((l1,l2),(u1,u2)) (i1,i2) = inRange (l1,u1) i1 && inRange (l2,u2) i2 -- Default method for index ---------------------------------------------------------------------- -- | @since 2.01 instance (Ix a1, Ix a2, Ix a3) => Ix (a1,a2,a3) where {-# SPECIALISE instance Ix (Int,Int,Int) #-} range ((l1,l2,l3),(u1,u2,u3)) = [(i1,i2,i3) | i1 <- range (l1,u1), i2 <- range (l2,u2), i3 <- range (l3,u3)] unsafeIndex ((l1,l2,l3),(u1,u2,u3)) (i1,i2,i3) = unsafeIndex (l3,u3) i3 + unsafeRangeSize (l3,u3) * ( unsafeIndex (l2,u2) i2 + unsafeRangeSize (l2,u2) * ( unsafeIndex (l1,u1) i1)) inRange ((l1,l2,l3),(u1,u2,u3)) (i1,i2,i3) = inRange (l1,u1) i1 && inRange (l2,u2) i2 && inRange (l3,u3) i3 -- Default method for index ---------------------------------------------------------------------- -- | @since 2.01 instance (Ix a1, Ix a2, Ix a3, Ix a4) => Ix (a1,a2,a3,a4) where range ((l1,l2,l3,l4),(u1,u2,u3,u4)) = [(i1,i2,i3,i4) | i1 <- range (l1,u1), i2 <- range (l2,u2), i3 <- range (l3,u3), i4 <- range (l4,u4)] unsafeIndex ((l1,l2,l3,l4),(u1,u2,u3,u4)) (i1,i2,i3,i4) = unsafeIndex (l4,u4) i4 + unsafeRangeSize (l4,u4) * ( unsafeIndex (l3,u3) i3 + unsafeRangeSize (l3,u3) * ( unsafeIndex (l2,u2) i2 + unsafeRangeSize (l2,u2) * ( unsafeIndex (l1,u1) i1))) inRange ((l1,l2,l3,l4),(u1,u2,u3,u4)) (i1,i2,i3,i4) = inRange (l1,u1) i1 && inRange (l2,u2) i2 && inRange (l3,u3) i3 && inRange (l4,u4) i4 -- Default method for index -- | @since 2.01 instance (Ix a1, Ix a2, Ix a3, Ix a4, Ix a5) => Ix (a1,a2,a3,a4,a5) where range ((l1,l2,l3,l4,l5),(u1,u2,u3,u4,u5)) = [(i1,i2,i3,i4,i5) | i1 <- range (l1,u1), i2 <- range (l2,u2), i3 <- range (l3,u3), i4 <- range (l4,u4), i5 <- range (l5,u5)] unsafeIndex ((l1,l2,l3,l4,l5),(u1,u2,u3,u4,u5)) (i1,i2,i3,i4,i5) = unsafeIndex (l5,u5) i5 + unsafeRangeSize (l5,u5) * ( unsafeIndex (l4,u4) i4 + unsafeRangeSize (l4,u4) * ( unsafeIndex (l3,u3) i3 + unsafeRangeSize (l3,u3) * ( unsafeIndex (l2,u2) i2 + unsafeRangeSize (l2,u2) * ( unsafeIndex (l1,u1) i1)))) inRange ((l1,l2,l3,l4,l5),(u1,u2,u3,u4,u5)) (i1,i2,i3,i4,i5) = inRange (l1,u1) i1 && inRange (l2,u2) i2 && inRange (l3,u3) i3 && inRange (l4,u4) i4 && inRange (l5,u5) i5 -- Default method for index -- | The type of immutable non-strict (boxed) arrays -- with indices in @i@ and elements in @e@. data Array i e = Array !i -- the lower bound, l !i -- the upper bound, u {-# UNPACK #-} !Int -- A cache of (rangeSize (l,u)) -- used to make sure an index is -- really in range (Array# e) -- The actual elements -- | Mutable, boxed, non-strict arrays in the 'ST' monad. The type -- arguments are as follows: -- -- * @s@: the state variable argument for the 'ST' type -- -- * @i@: the index type of the array (should be an instance of 'Ix') -- -- * @e@: the element type of the array. -- data STArray s i e = STArray !i -- the lower bound, l !i -- the upper bound, u {-# UNPACK #-} !Int -- A cache of (rangeSize (l,u)) -- used to make sure an index is -- really in range (MutableArray# s e) -- The actual elements -- No Ix context for STArray. They are stupid, -- and force an Ix context on the equality instance. -- Index types should have nominal role, because of Ix class. See also #9220. type role Array nominal representational type role STArray nominal nominal representational -- Just pointer equality on mutable arrays: -- | @since 2.01 instance Eq (STArray s i e) where STArray _ _ _ arr1# == STArray _ _ _ arr2# = isTrue# (sameMutableArray# arr1# arr2#) ---------------------------------------------------------------------- -- Operations on immutable arrays {-# NOINLINE arrEleBottom #-} arrEleBottom :: a arrEleBottom = errorWithoutStackTrace "(Array.!): undefined array element" -- | Construct an array with the specified bounds and containing values -- for given indices within these bounds. -- -- The array is undefined (i.e. bottom) if any index in the list is -- out of bounds. The Haskell 2010 Report further specifies that if any -- two associations in the list have the same index, the value at that -- index is undefined (i.e. bottom). However in GHC's implementation, -- the value at such an index is the value part of the last association -- with that index in the list. -- -- Because the indices must be checked for these errors, 'array' is -- strict in the bounds argument and in the indices of the association -- list, but non-strict in the values. Thus, recurrences such as the -- following are possible: -- -- > a = array (1,100) ((1,1) : [(i, i * a!(i-1)) | i <- [2..100]]) -- -- Not every index within the bounds of the array need appear in the -- association list, but the values associated with indices that do not -- appear will be undefined (i.e. bottom). -- -- If, in any dimension, the lower bound is greater than the upper bound, -- then the array is legal, but empty. Indexing an empty array always -- gives an array-bounds error, but 'bounds' still yields the bounds -- with which the array was constructed. {-# INLINE array #-} array :: Ix i => (i,i) -- ^ a pair of /bounds/, each of the index type -- of the array. These bounds are the lowest and -- highest indices in the array, in that order. -- For example, a one-origin vector of length -- '10' has bounds '(1,10)', and a one-origin '10' -- by '10' matrix has bounds '((1,1),(10,10))'. -> [(i, e)] -- ^ a list of /associations/ of the form -- (/index/, /value/). Typically, this list will -- be expressed as a comprehension. An -- association '(i, x)' defines the value of -- the array at index 'i' to be 'x'. -> Array i e array (l,u) ies = let n = safeRangeSize (l,u) in unsafeArray' (l,u) n [(safeIndex (l,u) n i, e) | (i, e) <- ies] {-# INLINE unsafeArray #-} unsafeArray :: Ix i => (i,i) -> [(Int, e)] -> Array i e unsafeArray b ies = unsafeArray' b (rangeSize b) ies {-# INLINE unsafeArray' #-} unsafeArray' :: (i,i) -> Int -> [(Int, e)] -> Array i e unsafeArray' (l,u) n@(I# n#) ies = runST (ST $ \s1# -> case newArray# n# arrEleBottom s1# of (# s2#, marr# #) -> foldr (fill marr#) (done l u n marr#) ies s2#) {-# INLINE fill #-} fill :: MutableArray# s e -> (Int, e) -> STRep s a -> STRep s a -- NB: put the \s after the "=" so that 'fill' -- inlines when applied to three args fill marr# (I# i#, e) next = \s1# -> case writeArray# marr# i# e s1# of s2# -> next s2# {-# INLINE done #-} done :: i -> i -> Int -> MutableArray# s e -> STRep s (Array i e) -- See NB on 'fill' -- Make sure it is strict in 'n' done l u n@(I# _) marr# = \s1# -> case unsafeFreezeArray# marr# s1# of (# s2#, arr# #) -> (# s2#, Array l u n arr# #) -- | Construct an array from a pair of bounds and a list of values in -- index order. {-# INLINE listArray #-} listArray :: Ix i => (i,i) -> [e] -> Array i e listArray (l,u) es = runST (ST $ \s1# -> case safeRangeSize (l,u) of { n@(I# n#) -> case newArray# n# arrEleBottom s1# of { (# s2#, marr# #) -> let go y r = \ i# s3# -> case writeArray# marr# i# y s3# of s4# -> if (isTrue# (i# ==# n# -# 1#)) then s4# else r (i# +# 1#) s4# in done l u n marr# ( if n == 0 then s2# else foldr go (\_ s# -> s#) es 0# s2#)}}) -- | The value at the given index in an array. {-# INLINE (!) #-} (!) :: Ix i => Array i e -> i -> e arr@(Array l u n _) ! i = unsafeAt arr $ safeIndex (l,u) n i {-# INLINE safeRangeSize #-} safeRangeSize :: Ix i => (i, i) -> Int safeRangeSize (l,u) = let r = rangeSize (l, u) in if r < 0 then negRange else r -- Don't inline this error message everywhere!! negRange :: Int -- Uninformative, but Ix does not provide Show negRange = errorWithoutStackTrace "Negative range size" {-# INLINE[1] safeIndex #-} -- See Note [Double bounds-checking of index values] -- Inline *after* (!) so the rules can fire -- Make sure it is strict in n safeIndex :: Ix i => (i, i) -> Int -> i -> Int safeIndex (l,u) n@(I# _) i | (0 <= i') && (i' < n) = i' | otherwise = badSafeIndex i' n where i' = index (l,u) i -- See Note [Double bounds-checking of index values] {-# RULES "safeIndex/I" safeIndex = lessSafeIndex :: (Int,Int) -> Int -> Int -> Int "safeIndex/(I,I)" safeIndex = lessSafeIndex :: ((Int,Int),(Int,Int)) -> Int -> (Int,Int) -> Int "safeIndex/(I,I,I)" safeIndex = lessSafeIndex :: ((Int,Int,Int),(Int,Int,Int)) -> Int -> (Int,Int,Int) -> Int #-} lessSafeIndex :: Ix i => (i, i) -> Int -> i -> Int -- See Note [Double bounds-checking of index values] -- Do only (A), the semantic check lessSafeIndex (l,u) _ i = index (l,u) i -- Don't inline this long error message everywhere!! badSafeIndex :: Int -> Int -> Int badSafeIndex i' n = errorWithoutStackTrace ("Error in array index; " ++ show i' ++ " not in range [0.." ++ show n ++ ")") {-# INLINE unsafeAt #-} unsafeAt :: Array i e -> Int -> e unsafeAt (Array _ _ _ arr#) (I# i#) = case indexArray# arr# i# of (# e #) -> e -- | The bounds with which an array was constructed. {-# INLINE bounds #-} bounds :: Array i e -> (i,i) bounds (Array l u _ _) = (l,u) -- | The number of elements in the array. {-# INLINE numElements #-} numElements :: Array i e -> Int numElements (Array _ _ n _) = n -- | The list of indices of an array in ascending order. {-# INLINE indices #-} indices :: Ix i => Array i e -> [i] indices (Array l u _ _) = range (l,u) -- | The list of elements of an array in index order. {-# INLINE elems #-} elems :: Array i e -> [e] elems arr@(Array _ _ n _) = [unsafeAt arr i | i <- [0 .. n - 1]] -- | A right fold over the elements {-# INLINABLE foldrElems #-} foldrElems :: (a -> b -> b) -> b -> Array i a -> b foldrElems f b0 = \ arr@(Array _ _ n _) -> let go i | i == n = b0 | otherwise = f (unsafeAt arr i) (go (i+1)) in go 0 -- | A left fold over the elements {-# INLINABLE foldlElems #-} foldlElems :: (b -> a -> b) -> b -> Array i a -> b foldlElems f b0 = \ arr@(Array _ _ n _) -> let go i | i == (-1) = b0 | otherwise = f (go (i-1)) (unsafeAt arr i) in go (n-1) -- | A strict right fold over the elements {-# INLINABLE foldrElems' #-} foldrElems' :: (a -> b -> b) -> b -> Array i a -> b foldrElems' f b0 = \ arr@(Array _ _ n _) -> let go i a | i == (-1) = a | otherwise = go (i-1) (f (unsafeAt arr i) $! a) in go (n-1) b0 -- | A strict left fold over the elements {-# INLINABLE foldlElems' #-} foldlElems' :: (b -> a -> b) -> b -> Array i a -> b foldlElems' f b0 = \ arr@(Array _ _ n _) -> let go i a | i == n = a | otherwise = go (i+1) (a `seq` f a (unsafeAt arr i)) in go 0 b0 -- | A left fold over the elements with no starting value {-# INLINABLE foldl1Elems #-} foldl1Elems :: (a -> a -> a) -> Array i a -> a foldl1Elems f = \ arr@(Array _ _ n _) -> let go i | i == 0 = unsafeAt arr 0 | otherwise = f (go (i-1)) (unsafeAt arr i) in if n == 0 then errorWithoutStackTrace "foldl1: empty Array" else go (n-1) -- | A right fold over the elements with no starting value {-# INLINABLE foldr1Elems #-} foldr1Elems :: (a -> a -> a) -> Array i a -> a foldr1Elems f = \ arr@(Array _ _ n _) -> let go i | i == n-1 = unsafeAt arr i | otherwise = f (unsafeAt arr i) (go (i + 1)) in if n == 0 then errorWithoutStackTrace "foldr1: empty Array" else go 0 -- | The list of associations of an array in index order. {-# INLINE assocs #-} assocs :: Ix i => Array i e -> [(i, e)] assocs arr@(Array l u _ _) = [(i, arr ! i) | i <- range (l,u)] -- | The 'accumArray' function deals with repeated indices in the association -- list using an /accumulating function/ which combines the values of -- associations with the same index. -- For example, given a list of values of some index type, @hist@ -- produces a histogram of the number of occurrences of each index within -- a specified range: -- -- > hist :: (Ix a, Num b) => (a,a) -> [a] -> Array a b -- > hist bnds is = accumArray (+) 0 bnds [(i, 1) | i<-is, inRange bnds i] -- -- If the accumulating function is strict, then 'accumArray' is strict in -- the values, as well as the indices, in the association list. Thus, -- unlike ordinary arrays built with 'array', accumulated arrays should -- not in general be recursive. {-# INLINE accumArray #-} accumArray :: Ix i => (e -> a -> e) -- ^ accumulating function -> e -- ^ initial value -> (i,i) -- ^ bounds of the array -> [(i, a)] -- ^ association list -> Array i e accumArray f initial (l,u) ies = let n = safeRangeSize (l,u) in unsafeAccumArray' f initial (l,u) n [(safeIndex (l,u) n i, e) | (i, e) <- ies] {-# INLINE unsafeAccumArray #-} unsafeAccumArray :: Ix i => (e -> a -> e) -> e -> (i,i) -> [(Int, a)] -> Array i e unsafeAccumArray f initial b ies = unsafeAccumArray' f initial b (rangeSize b) ies {-# INLINE unsafeAccumArray' #-} unsafeAccumArray' :: (e -> a -> e) -> e -> (i,i) -> Int -> [(Int, a)] -> Array i e unsafeAccumArray' f initial (l,u) n@(I# n#) ies = runST (ST $ \s1# -> case newArray# n# initial s1# of { (# s2#, marr# #) -> foldr (adjust f marr#) (done l u n marr#) ies s2# }) {-# INLINE adjust #-} adjust :: (e -> a -> e) -> MutableArray# s e -> (Int, a) -> STRep s b -> STRep s b -- See NB on 'fill' adjust f marr# (I# i#, new) next = \s1# -> case readArray# marr# i# s1# of (# s2#, old #) -> case writeArray# marr# i# (f old new) s2# of s3# -> next s3# -- | Constructs an array identical to the first argument except that it has -- been updated by the associations in the right argument. -- For example, if @m@ is a 1-origin, @n@ by @n@ matrix, then -- -- > m//[((i,i), 0) | i <- [1..n]] -- -- is the same matrix, except with the diagonal zeroed. -- -- Repeated indices in the association list are handled as for 'array': -- Haskell 2010 specifies that the resulting array is undefined (i.e. bottom), -- but GHC's implementation uses the last association for each index. {-# INLINE (//) #-} (//) :: Ix i => Array i e -> [(i, e)] -> Array i e arr@(Array l u n _) // ies = unsafeReplace arr [(safeIndex (l,u) n i, e) | (i, e) <- ies] {-# INLINE unsafeReplace #-} unsafeReplace :: Array i e -> [(Int, e)] -> Array i e unsafeReplace arr ies = runST (do STArray l u n marr# <- thawSTArray arr ST (foldr (fill marr#) (done l u n marr#) ies)) -- | @'accum' f@ takes an array and an association list and accumulates -- pairs from the list into the array with the accumulating function @f@. -- Thus 'accumArray' can be defined using 'accum': -- -- > accumArray f z b = accum f (array b [(i, z) | i <- range b]) -- {-# INLINE accum #-} accum :: Ix i => (e -> a -> e) -> Array i e -> [(i, a)] -> Array i e accum f arr@(Array l u n _) ies = unsafeAccum f arr [(safeIndex (l,u) n i, e) | (i, e) <- ies] {-# INLINE unsafeAccum #-} unsafeAccum :: (e -> a -> e) -> Array i e -> [(Int, a)] -> Array i e unsafeAccum f arr ies = runST (do STArray l u n marr# <- thawSTArray arr ST (foldr (adjust f marr#) (done l u n marr#) ies)) {-# INLINE [1] amap #-} -- See Note [amap] amap :: (a -> b) -> Array i a -> Array i b amap f arr@(Array l u n@(I# n#) _) = runST (ST $ \s1# -> case newArray# n# arrEleBottom s1# of (# s2#, marr# #) -> let go i s# | i == n = done l u n marr# s# | otherwise = fill marr# (i, f (unsafeAt arr i)) (go (i+1)) s# in go 0 s2# ) {- Note [amap] ~~~~~~~~~~~~~~ amap was originally defined like this: amap f arr@(Array l u n _) = unsafeArray' (l,u) n [(i, f (unsafeAt arr i)) | i <- [0 .. n - 1]] There are two problems: 1. The enumFromTo implementation produces (spurious) code for the impossible case of n<0 that ends up duplicating the array freezing code. 2. This implementation relies on list fusion for efficiency. In order to implement the "amap/coerce" rule, we need to delay inlining amap until simplifier phase 1, which is when the eftIntList rule kicks in and makes that impossible. (c.f. Trac #8767) -} -- See Breitner, Eisenberg, Peyton Jones, and Weirich, "Safe Zero-cost -- Coercions for Haskell", section 6.5: -- http://research.microsoft.com/en-us/um/people/simonpj/papers/ext-f/coercible.pdf {-# RULES "amap/coerce" amap coerce = coerce -- See Note [amap] #-} -- Second functor law: {-# RULES "amap/amap" forall f g a . amap f (amap g a) = amap (f . g) a #-} -- | 'ixmap' allows for transformations on array indices. -- It may be thought of as providing function composition on the right -- with the mapping that the original array embodies. -- -- A similar transformation of array values may be achieved using 'fmap' -- from the 'Array' instance of the 'Functor' class. {-# INLINE ixmap #-} ixmap :: (Ix i, Ix j) => (i,i) -> (i -> j) -> Array j e -> Array i e ixmap (l,u) f arr = array (l,u) [(i, arr ! f i) | i <- range (l,u)] {-# INLINE eqArray #-} eqArray :: (Ix i, Eq e) => Array i e -> Array i e -> Bool eqArray arr1@(Array l1 u1 n1 _) arr2@(Array l2 u2 n2 _) = if n1 == 0 then n2 == 0 else l1 == l2 && u1 == u2 && and [unsafeAt arr1 i == unsafeAt arr2 i | i <- [0 .. n1 - 1]] {-# INLINE [1] cmpArray #-} cmpArray :: (Ix i, Ord e) => Array i e -> Array i e -> Ordering cmpArray arr1 arr2 = compare (assocs arr1) (assocs arr2) {-# INLINE cmpIntArray #-} cmpIntArray :: Ord e => Array Int e -> Array Int e -> Ordering cmpIntArray arr1@(Array l1 u1 n1 _) arr2@(Array l2 u2 n2 _) = if n1 == 0 then if n2 == 0 then EQ else LT else if n2 == 0 then GT else case compare l1 l2 of EQ -> foldr cmp (compare u1 u2) [0 .. (n1 `min` n2) - 1] other -> other where cmp i rest = case compare (unsafeAt arr1 i) (unsafeAt arr2 i) of EQ -> rest other -> other {-# RULES "cmpArray/Int" cmpArray = cmpIntArray #-} ---------------------------------------------------------------------- -- Array instances -- | @since 2.01 instance Functor (Array i) where fmap = amap -- | @since 2.01 instance (Ix i, Eq e) => Eq (Array i e) where (==) = eqArray -- | @since 2.01 instance (Ix i, Ord e) => Ord (Array i e) where compare = cmpArray -- | @since 2.01 instance (Ix a, Show a, Show b) => Show (Array a b) where showsPrec p a = showParen (p > appPrec) $ showString "array " . showsPrec appPrec1 (bounds a) . showChar ' ' . showsPrec appPrec1 (assocs a) -- Precedence of 'array' is the precedence of application -- The Read instance is in GHC.Read ---------------------------------------------------------------------- -- Operations on mutable arrays {- Idle ADR question: What's the tradeoff here between flattening these datatypes into @STArray ix ix (MutableArray# s elt)@ and using it as is? As I see it, the former uses slightly less heap and provides faster access to the individual parts of the bounds while the code used has the benefit of providing a ready-made @(lo, hi)@ pair as required by many array-related functions. Which wins? Is the difference significant (probably not). Idle AJG answer: When I looked at the outputted code (though it was 2 years ago) it seems like you often needed the tuple, and we build it frequently. Now we've got the overloading specialiser things might be different, though. -} {-# INLINE newSTArray #-} newSTArray :: Ix i => (i,i) -> e -> ST s (STArray s i e) newSTArray (l,u) initial = ST $ \s1# -> case safeRangeSize (l,u) of { n@(I# n#) -> case newArray# n# initial s1# of { (# s2#, marr# #) -> (# s2#, STArray l u n marr# #) }} {-# INLINE boundsSTArray #-} boundsSTArray :: STArray s i e -> (i,i) boundsSTArray (STArray l u _ _) = (l,u) {-# INLINE numElementsSTArray #-} numElementsSTArray :: STArray s i e -> Int numElementsSTArray (STArray _ _ n _) = n {-# INLINE readSTArray #-} readSTArray :: Ix i => STArray s i e -> i -> ST s e readSTArray marr@(STArray l u n _) i = unsafeReadSTArray marr (safeIndex (l,u) n i) {-# INLINE unsafeReadSTArray #-} unsafeReadSTArray :: STArray s i e -> Int -> ST s e unsafeReadSTArray (STArray _ _ _ marr#) (I# i#) = ST $ \s1# -> readArray# marr# i# s1# {-# INLINE writeSTArray #-} writeSTArray :: Ix i => STArray s i e -> i -> e -> ST s () writeSTArray marr@(STArray l u n _) i e = unsafeWriteSTArray marr (safeIndex (l,u) n i) e {-# INLINE unsafeWriteSTArray #-} unsafeWriteSTArray :: STArray s i e -> Int -> e -> ST s () unsafeWriteSTArray (STArray _ _ _ marr#) (I# i#) e = ST $ \s1# -> case writeArray# marr# i# e s1# of s2# -> (# s2#, () #) ---------------------------------------------------------------------- -- Moving between mutable and immutable freezeSTArray :: STArray s i e -> ST s (Array i e) freezeSTArray (STArray l u n@(I# n#) marr#) = ST $ \s1# -> case newArray# n# arrEleBottom s1# of { (# s2#, marr'# #) -> let copy i# s3# | isTrue# (i# ==# n#) = s3# | otherwise = case readArray# marr# i# s3# of { (# s4#, e #) -> case writeArray# marr'# i# e s4# of { s5# -> copy (i# +# 1#) s5# }} in case copy 0# s2# of { s3# -> case unsafeFreezeArray# marr'# s3# of { (# s4#, arr# #) -> (# s4#, Array l u n arr# #) }}} {-# INLINE unsafeFreezeSTArray #-} unsafeFreezeSTArray :: STArray s i e -> ST s (Array i e) unsafeFreezeSTArray (STArray l u n marr#) = ST $ \s1# -> case unsafeFreezeArray# marr# s1# of { (# s2#, arr# #) -> (# s2#, Array l u n arr# #) } thawSTArray :: Array i e -> ST s (STArray s i e) thawSTArray (Array l u n@(I# n#) arr#) = ST $ \s1# -> case newArray# n# arrEleBottom s1# of { (# s2#, marr# #) -> let copy i# s3# | isTrue# (i# ==# n#) = s3# | otherwise = case indexArray# arr# i# of { (# e #) -> case writeArray# marr# i# e s3# of { s4# -> copy (i# +# 1#) s4# }} in case copy 0# s2# of { s3# -> (# s3#, STArray l u n marr# #) }} {-# INLINE unsafeThawSTArray #-} unsafeThawSTArray :: Array i e -> ST s (STArray s i e) unsafeThawSTArray (Array l u n arr#) = ST $ \s1# -> case unsafeThawArray# arr# s1# of { (# s2#, marr# #) -> (# s2#, STArray l u n marr# #) }