{-# OPTIONS_GHC -fno-implicit-prelude #-} ----------------------------------------------------------------------------- -- | -- Module : GHC.Int -- Copyright : (c) The University of Glasgow 1997-2002 -- License : see libraries/base/LICENSE -- -- Maintainer : cvs-ghc@haskell.org -- Stability : internal -- Portability : non-portable (GHC Extensions) -- -- The sized integral datatypes, 'Int8', 'Int16', 'Int32', and 'Int64'. -- ----------------------------------------------------------------------------- #include "MachDeps.h" -- #hide module GHC.Int ( Int8(..), Int16(..), Int32(..), Int64(..)) where import Data.Bits import {-# SOURCE #-} GHC.Err import GHC.Base import GHC.Enum import GHC.Num import GHC.Real import GHC.Read import GHC.Arr import GHC.Word import GHC.Show ------------------------------------------------------------------------ -- type Int8 ------------------------------------------------------------------------ -- Int8 is represented in the same way as Int. Operations may assume -- and must ensure that it holds only values from its logical range. data Int8 = I8# Int# deriving (Eq, Ord) -- ^ 8-bit signed integer type instance Show Int8 where showsPrec p x = showsPrec p (fromIntegral x :: Int) instance Num Int8 where (I8# x#) + (I8# y#) = I8# (narrow8Int# (x# +# y#)) (I8# x#) - (I8# y#) = I8# (narrow8Int# (x# -# y#)) (I8# x#) * (I8# y#) = I8# (narrow8Int# (x# *# y#)) negate (I8# x#) = I8# (narrow8Int# (negateInt# x#)) abs x | x >= 0 = x | otherwise = negate x signum x | x > 0 = 1 signum 0 = 0 signum _ = -1 fromInteger (S# i#) = I8# (narrow8Int# i#) fromInteger (J# s# d#) = I8# (narrow8Int# (integer2Int# s# d#)) instance Real Int8 where toRational x = toInteger x % 1 instance Enum Int8 where succ x | x /= maxBound = x + 1 | otherwise = succError "Int8" pred x | x /= minBound = x - 1 | otherwise = predError "Int8" toEnum i@(I# i#) | i >= fromIntegral (minBound::Int8) && i <= fromIntegral (maxBound::Int8) = I8# i# | otherwise = toEnumError "Int8" i (minBound::Int8, maxBound::Int8) fromEnum (I8# x#) = I# x# enumFrom = boundedEnumFrom enumFromThen = boundedEnumFromThen instance Integral Int8 where quot x@(I8# x#) y@(I8# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = I8# (narrow8Int# (x# `quotInt#` y#)) rem x@(I8# x#) y@(I8# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = I8# (narrow8Int# (x# `remInt#` y#)) div x@(I8# x#) y@(I8# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = I8# (narrow8Int# (x# `divInt#` y#)) mod x@(I8# x#) y@(I8# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = I8# (narrow8Int# (x# `modInt#` y#)) quotRem x@(I8# x#) y@(I8# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = (I8# (narrow8Int# (x# `quotInt#` y#)), I8# (narrow8Int# (x# `remInt#` y#))) divMod x@(I8# x#) y@(I8# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = (I8# (narrow8Int# (x# `divInt#` y#)), I8# (narrow8Int# (x# `modInt#` y#))) toInteger (I8# x#) = S# x# instance Bounded Int8 where minBound = -0x80 maxBound = 0x7F instance Ix Int8 where range (m,n) = [m..n] unsafeIndex b@(m,_) i = fromIntegral i - fromIntegral m inRange (m,n) i = m <= i && i <= n instance Read Int8 where readsPrec p s = [(fromIntegral (x::Int), r) | (x, r) <- readsPrec p s] instance Bits Int8 where {-# INLINE shift #-} (I8# x#) .&. (I8# y#) = I8# (word2Int# (int2Word# x# `and#` int2Word# y#)) (I8# x#) .|. (I8# y#) = I8# (word2Int# (int2Word# x# `or#` int2Word# y#)) (I8# x#) `xor` (I8# y#) = I8# (word2Int# (int2Word# x# `xor#` int2Word# y#)) complement (I8# x#) = I8# (word2Int# (int2Word# x# `xor#` int2Word# (-1#))) (I8# x#) `shift` (I# i#) | i# >=# 0# = I8# (narrow8Int# (x# `iShiftL#` i#)) | otherwise = I8# (x# `iShiftRA#` negateInt# i#) (I8# x#) `rotate` (I# i#) | i'# ==# 0# = I8# x# | otherwise = I8# (narrow8Int# (word2Int# ((x'# `uncheckedShiftL#` i'#) `or#` (x'# `uncheckedShiftRL#` (8# -# i'#))))) where x'# = narrow8Word# (int2Word# x#) i'# = word2Int# (int2Word# i# `and#` int2Word# 7#) bitSize _ = 8 isSigned _ = True {-# RULES "fromIntegral/Int8->Int8" fromIntegral = id :: Int8 -> Int8 "fromIntegral/a->Int8" fromIntegral = \x -> case fromIntegral x of I# x# -> I8# (narrow8Int# x#) "fromIntegral/Int8->a" fromIntegral = \(I8# x#) -> fromIntegral (I# x#) #-} ------------------------------------------------------------------------ -- type Int16 ------------------------------------------------------------------------ -- Int16 is represented in the same way as Int. Operations may assume -- and must ensure that it holds only values from its logical range. data Int16 = I16# Int# deriving (Eq, Ord) -- ^ 16-bit signed integer type instance Show Int16 where showsPrec p x = showsPrec p (fromIntegral x :: Int) instance Num Int16 where (I16# x#) + (I16# y#) = I16# (narrow16Int# (x# +# y#)) (I16# x#) - (I16# y#) = I16# (narrow16Int# (x# -# y#)) (I16# x#) * (I16# y#) = I16# (narrow16Int# (x# *# y#)) negate (I16# x#) = I16# (narrow16Int# (negateInt# x#)) abs x | x >= 0 = x | otherwise = negate x signum x | x > 0 = 1 signum 0 = 0 signum _ = -1 fromInteger (S# i#) = I16# (narrow16Int# i#) fromInteger (J# s# d#) = I16# (narrow16Int# (integer2Int# s# d#)) instance Real Int16 where toRational x = toInteger x % 1 instance Enum Int16 where succ x | x /= maxBound = x + 1 | otherwise = succError "Int16" pred x | x /= minBound = x - 1 | otherwise = predError "Int16" toEnum i@(I# i#) | i >= fromIntegral (minBound::Int16) && i <= fromIntegral (maxBound::Int16) = I16# i# | otherwise = toEnumError "Int16" i (minBound::Int16, maxBound::Int16) fromEnum (I16# x#) = I# x# enumFrom = boundedEnumFrom enumFromThen = boundedEnumFromThen instance Integral Int16 where quot x@(I16# x#) y@(I16# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = I16# (narrow16Int# (x# `quotInt#` y#)) rem x@(I16# x#) y@(I16# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = I16# (narrow16Int# (x# `remInt#` y#)) div x@(I16# x#) y@(I16# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = I16# (narrow16Int# (x# `divInt#` y#)) mod x@(I16# x#) y@(I16# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = I16# (narrow16Int# (x# `modInt#` y#)) quotRem x@(I16# x#) y@(I16# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = (I16# (narrow16Int# (x# `quotInt#` y#)), I16# (narrow16Int# (x# `remInt#` y#))) divMod x@(I16# x#) y@(I16# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = (I16# (narrow16Int# (x# `divInt#` y#)), I16# (narrow16Int# (x# `modInt#` y#))) toInteger (I16# x#) = S# x# instance Bounded Int16 where minBound = -0x8000 maxBound = 0x7FFF instance Ix Int16 where range (m,n) = [m..n] unsafeIndex b@(m,_) i = fromIntegral i - fromIntegral m inRange (m,n) i = m <= i && i <= n instance Read Int16 where readsPrec p s = [(fromIntegral (x::Int), r) | (x, r) <- readsPrec p s] instance Bits Int16 where {-# INLINE shift #-} (I16# x#) .&. (I16# y#) = I16# (word2Int# (int2Word# x# `and#` int2Word# y#)) (I16# x#) .|. (I16# y#) = I16# (word2Int# (int2Word# x# `or#` int2Word# y#)) (I16# x#) `xor` (I16# y#) = I16# (word2Int# (int2Word# x# `xor#` int2Word# y#)) complement (I16# x#) = I16# (word2Int# (int2Word# x# `xor#` int2Word# (-1#))) (I16# x#) `shift` (I# i#) | i# >=# 0# = I16# (narrow16Int# (x# `iShiftL#` i#)) | otherwise = I16# (x# `iShiftRA#` negateInt# i#) (I16# x#) `rotate` (I# i#) | i'# ==# 0# = I16# x# | otherwise = I16# (narrow16Int# (word2Int# ((x'# `uncheckedShiftL#` i'#) `or#` (x'# `uncheckedShiftRL#` (16# -# i'#))))) where x'# = narrow16Word# (int2Word# x#) i'# = word2Int# (int2Word# i# `and#` int2Word# 15#) bitSize _ = 16 isSigned _ = True {-# RULES "fromIntegral/Word8->Int16" fromIntegral = \(W8# x#) -> I16# (word2Int# x#) "fromIntegral/Int8->Int16" fromIntegral = \(I8# x#) -> I16# x# "fromIntegral/Int16->Int16" fromIntegral = id :: Int16 -> Int16 "fromIntegral/a->Int16" fromIntegral = \x -> case fromIntegral x of I# x# -> I16# (narrow16Int# x#) "fromIntegral/Int16->a" fromIntegral = \(I16# x#) -> fromIntegral (I# x#) #-} ------------------------------------------------------------------------ -- type Int32 ------------------------------------------------------------------------ #if WORD_SIZE_IN_BITS < 32 data Int32 = I32# Int32# -- ^ 32-bit signed integer type instance Eq Int32 where (I32# x#) == (I32# y#) = x# `eqInt32#` y# (I32# x#) /= (I32# y#) = x# `neInt32#` y# instance Ord Int32 where (I32# x#) < (I32# y#) = x# `ltInt32#` y# (I32# x#) <= (I32# y#) = x# `leInt32#` y# (I32# x#) > (I32# y#) = x# `gtInt32#` y# (I32# x#) >= (I32# y#) = x# `geInt32#` y# instance Show Int32 where showsPrec p x = showsPrec p (toInteger x) instance Num Int32 where (I32# x#) + (I32# y#) = I32# (x# `plusInt32#` y#) (I32# x#) - (I32# y#) = I32# (x# `minusInt32#` y#) (I32# x#) * (I32# y#) = I32# (x# `timesInt32#` y#) negate (I32# x#) = I32# (negateInt32# x#) abs x | x >= 0 = x | otherwise = negate x signum x | x > 0 = 1 signum 0 = 0 signum _ = -1 fromInteger (S# i#) = I32# (intToInt32# i#) fromInteger (J# s# d#) = I32# (integerToInt32# s# d#) instance Enum Int32 where succ x | x /= maxBound = x + 1 | otherwise = succError "Int32" pred x | x /= minBound = x - 1 | otherwise = predError "Int32" toEnum (I# i#) = I32# (intToInt32# i#) fromEnum x@(I32# x#) | x >= fromIntegral (minBound::Int) && x <= fromIntegral (maxBound::Int) = I# (int32ToInt# x#) | otherwise = fromEnumError "Int32" x enumFrom = integralEnumFrom enumFromThen = integralEnumFromThen enumFromTo = integralEnumFromTo enumFromThenTo = integralEnumFromThenTo instance Integral Int32 where quot x@(I32# x#) y@(I32# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = I32# (x# `quotInt32#` y#) rem x@(I32# x#) y@(I32# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = I32# (x# `remInt32#` y#) div x@(I32# x#) y@(I32# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = I32# (x# `divInt32#` y#) mod x@(I32# x#) y@(I32# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = I32# (x# `modInt32#` y#) quotRem x@(I32# x#) y@(I32# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = (I32# (x# `quotInt32#` y#), I32# (x# `remInt32#` y#)) divMod x@(I32# x#) y@(I32# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = (I32# (x# `divInt32#` y#), I32# (x# `modInt32#` y#)) toInteger x@(I32# x#) | x >= fromIntegral (minBound::Int) && x <= fromIntegral (maxBound::Int) = S# (int32ToInt# x#) | otherwise = case int32ToInteger# x# of (# s, d #) -> J# s d divInt32#, modInt32# :: Int32# -> Int32# -> Int32# x# `divInt32#` y# | (x# `gtInt32#` intToInt32# 0#) && (y# `ltInt32#` intToInt32# 0#) = ((x# `minusInt32#` y#) `minusInt32#` intToInt32# 1#) `quotInt32#` y# | (x# `ltInt32#` intToInt32# 0#) && (y# `gtInt32#` intToInt32# 0#) = ((x# `minusInt32#` y#) `plusInt32#` intToInt32# 1#) `quotInt32#` y# | otherwise = x# `quotInt32#` y# x# `modInt32#` y# | (x# `gtInt32#` intToInt32# 0#) && (y# `ltInt32#` intToInt32# 0#) || (x# `ltInt32#` intToInt32# 0#) && (y# `gtInt32#` intToInt32# 0#) = if r# `neInt32#` intToInt32# 0# then r# `plusInt32#` y# else intToInt32# 0# | otherwise = r# where r# = x# `remInt32#` y# instance Read Int32 where readsPrec p s = [(fromInteger x, r) | (x, r) <- readsPrec p s] instance Bits Int32 where {-# INLINE shift #-} (I32# x#) .&. (I32# y#) = I32# (word32ToInt32# (int32ToWord32# x# `and32#` int32ToWord32# y#)) (I32# x#) .|. (I32# y#) = I32# (word32ToInt32# (int32ToWord32# x# `or32#` int32ToWord32# y#)) (I32# x#) `xor` (I32# y#) = I32# (word32ToInt32# (int32ToWord32# x# `xor32#` int32ToWord32# y#)) complement (I32# x#) = I32# (word32ToInt32# (not32# (int32ToWord32# x#))) (I32# x#) `shift` (I# i#) | i# >=# 0# = I32# (x# `iShiftL32#` i#) | otherwise = I32# (x# `iShiftRA32#` negateInt# i#) (I32# x#) `rotate` (I# i#) | i'# ==# 0# = I32# x# | otherwise = I32# (word32ToInt32# ((x'# `shiftL32#` i'#) `or32#` (x'# `shiftRL32#` (32# -# i'#)))) where x'# = int32ToWord32# x# i'# = word2Int# (int2Word# i# `and#` int2Word# 31#) bitSize _ = 32 isSigned _ = True foreign import "stg_eqInt32" unsafe eqInt32# :: Int32# -> Int32# -> Bool foreign import "stg_neInt32" unsafe neInt32# :: Int32# -> Int32# -> Bool foreign import "stg_ltInt32" unsafe ltInt32# :: Int32# -> Int32# -> Bool foreign import "stg_leInt32" unsafe leInt32# :: Int32# -> Int32# -> Bool foreign import "stg_gtInt32" unsafe gtInt32# :: Int32# -> Int32# -> Bool foreign import "stg_geInt32" unsafe geInt32# :: Int32# -> Int32# -> Bool foreign import "stg_plusInt32" unsafe plusInt32# :: Int32# -> Int32# -> Int32# foreign import "stg_minusInt32" unsafe minusInt32# :: Int32# -> Int32# -> Int32# foreign import "stg_timesInt32" unsafe timesInt32# :: Int32# -> Int32# -> Int32# foreign import "stg_negateInt32" unsafe negateInt32# :: Int32# -> Int32# foreign import "stg_quotInt32" unsafe quotInt32# :: Int32# -> Int32# -> Int32# foreign import "stg_remInt32" unsafe remInt32# :: Int32# -> Int32# -> Int32# foreign import "stg_intToInt32" unsafe intToInt32# :: Int# -> Int32# foreign import "stg_int32ToInt" unsafe int32ToInt# :: Int32# -> Int# foreign import "stg_wordToWord32" unsafe wordToWord32# :: Word# -> Word32# foreign import "stg_int32ToWord32" unsafe int32ToWord32# :: Int32# -> Word32# foreign import "stg_word32ToInt32" unsafe word32ToInt32# :: Word32# -> Int32# foreign import "stg_and32" unsafe and32# :: Word32# -> Word32# -> Word32# foreign import "stg_or32" unsafe or32# :: Word32# -> Word32# -> Word32# foreign import "stg_xor32" unsafe xor32# :: Word32# -> Word32# -> Word32# foreign import "stg_not32" unsafe not32# :: Word32# -> Word32# foreign import "stg_iShiftL32" unsafe iShiftL32# :: Int32# -> Int# -> Int32# foreign import "stg_iShiftRA32" unsafe iShiftRA32# :: Int32# -> Int# -> Int32# foreign import "stg_shiftL32" unsafe shiftL32# :: Word32# -> Int# -> Word32# foreign import "stg_shiftRL32" unsafe shiftRL32# :: Word32# -> Int# -> Word32# {-# RULES "fromIntegral/Int->Int32" fromIntegral = \(I# x#) -> I32# (intToInt32# x#) "fromIntegral/Word->Int32" fromIntegral = \(W# x#) -> I32# (word32ToInt32# (wordToWord32# x#)) "fromIntegral/Word32->Int32" fromIntegral = \(W32# x#) -> I32# (word32ToInt32# x#) "fromIntegral/Int32->Int" fromIntegral = \(I32# x#) -> I# (int32ToInt# x#) "fromIntegral/Int32->Word" fromIntegral = \(I32# x#) -> W# (int2Word# (int32ToInt# x#)) "fromIntegral/Int32->Word32" fromIntegral = \(I32# x#) -> W32# (int32ToWord32# x#) "fromIntegral/Int32->Int32" fromIntegral = id :: Int32 -> Int32 #-} #else -- Int32 is represented in the same way as Int. #if WORD_SIZE_IN_BITS > 32 -- Operations may assume and must ensure that it holds only values -- from its logical range. #endif data Int32 = I32# Int# deriving (Eq, Ord) -- ^ 32-bit signed integer type instance Show Int32 where showsPrec p x = showsPrec p (fromIntegral x :: Int) instance Num Int32 where (I32# x#) + (I32# y#) = I32# (narrow32Int# (x# +# y#)) (I32# x#) - (I32# y#) = I32# (narrow32Int# (x# -# y#)) (I32# x#) * (I32# y#) = I32# (narrow32Int# (x# *# y#)) negate (I32# x#) = I32# (narrow32Int# (negateInt# x#)) abs x | x >= 0 = x | otherwise = negate x signum x | x > 0 = 1 signum 0 = 0 signum _ = -1 fromInteger (S# i#) = I32# (narrow32Int# i#) fromInteger (J# s# d#) = I32# (narrow32Int# (integer2Int# s# d#)) instance Enum Int32 where succ x | x /= maxBound = x + 1 | otherwise = succError "Int32" pred x | x /= minBound = x - 1 | otherwise = predError "Int32" #if WORD_SIZE_IN_BITS == 32 toEnum (I# i#) = I32# i# #else toEnum i@(I# i#) | i >= fromIntegral (minBound::Int32) && i <= fromIntegral (maxBound::Int32) = I32# i# | otherwise = toEnumError "Int32" i (minBound::Int32, maxBound::Int32) #endif fromEnum (I32# x#) = I# x# enumFrom = boundedEnumFrom enumFromThen = boundedEnumFromThen instance Integral Int32 where quot x@(I32# x#) y@(I32# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = I32# (narrow32Int# (x# `quotInt#` y#)) rem x@(I32# x#) y@(I32# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = I32# (narrow32Int# (x# `remInt#` y#)) div x@(I32# x#) y@(I32# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = I32# (narrow32Int# (x# `divInt#` y#)) mod x@(I32# x#) y@(I32# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = I32# (narrow32Int# (x# `modInt#` y#)) quotRem x@(I32# x#) y@(I32# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = (I32# (narrow32Int# (x# `quotInt#` y#)), I32# (narrow32Int# (x# `remInt#` y#))) divMod x@(I32# x#) y@(I32# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = (I32# (narrow32Int# (x# `divInt#` y#)), I32# (narrow32Int# (x# `modInt#` y#))) toInteger (I32# x#) = S# x# instance Read Int32 where readsPrec p s = [(fromIntegral (x::Int), r) | (x, r) <- readsPrec p s] instance Bits Int32 where {-# INLINE shift #-} (I32# x#) .&. (I32# y#) = I32# (word2Int# (int2Word# x# `and#` int2Word# y#)) (I32# x#) .|. (I32# y#) = I32# (word2Int# (int2Word# x# `or#` int2Word# y#)) (I32# x#) `xor` (I32# y#) = I32# (word2Int# (int2Word# x# `xor#` int2Word# y#)) complement (I32# x#) = I32# (word2Int# (int2Word# x# `xor#` int2Word# (-1#))) (I32# x#) `shift` (I# i#) | i# >=# 0# = I32# (narrow32Int# (x# `iShiftL#` i#)) | otherwise = I32# (x# `iShiftRA#` negateInt# i#) (I32# x#) `rotate` (I# i#) | i'# ==# 0# = I32# x# | otherwise = I32# (narrow32Int# (word2Int# ((x'# `uncheckedShiftL#` i'#) `or#` (x'# `uncheckedShiftRL#` (32# -# i'#))))) where x'# = narrow32Word# (int2Word# x#) i'# = word2Int# (int2Word# i# `and#` int2Word# 31#) bitSize _ = 32 isSigned _ = True {-# RULES "fromIntegral/Word8->Int32" fromIntegral = \(W8# x#) -> I32# (word2Int# x#) "fromIntegral/Word16->Int32" fromIntegral = \(W16# x#) -> I32# (word2Int# x#) "fromIntegral/Int8->Int32" fromIntegral = \(I8# x#) -> I32# x# "fromIntegral/Int16->Int32" fromIntegral = \(I16# x#) -> I32# x# "fromIntegral/Int32->Int32" fromIntegral = id :: Int32 -> Int32 "fromIntegral/a->Int32" fromIntegral = \x -> case fromIntegral x of I# x# -> I32# (narrow32Int# x#) "fromIntegral/Int32->a" fromIntegral = \(I32# x#) -> fromIntegral (I# x#) #-} #endif instance Real Int32 where toRational x = toInteger x % 1 instance Bounded Int32 where minBound = -0x80000000 maxBound = 0x7FFFFFFF instance Ix Int32 where range (m,n) = [m..n] unsafeIndex b@(m,_) i = fromIntegral i - fromIntegral m inRange (m,n) i = m <= i && i <= n ------------------------------------------------------------------------ -- type Int64 ------------------------------------------------------------------------ #if WORD_SIZE_IN_BITS < 64 data Int64 = I64# Int64# -- ^ 64-bit signed integer type instance Eq Int64 where (I64# x#) == (I64# y#) = x# `eqInt64#` y# (I64# x#) /= (I64# y#) = x# `neInt64#` y# instance Ord Int64 where (I64# x#) < (I64# y#) = x# `ltInt64#` y# (I64# x#) <= (I64# y#) = x# `leInt64#` y# (I64# x#) > (I64# y#) = x# `gtInt64#` y# (I64# x#) >= (I64# y#) = x# `geInt64#` y# instance Show Int64 where showsPrec p x = showsPrec p (toInteger x) instance Num Int64 where (I64# x#) + (I64# y#) = I64# (x# `plusInt64#` y#) (I64# x#) - (I64# y#) = I64# (x# `minusInt64#` y#) (I64# x#) * (I64# y#) = I64# (x# `timesInt64#` y#) negate (I64# x#) = I64# (negateInt64# x#) abs x | x >= 0 = x | otherwise = negate x signum x | x > 0 = 1 signum 0 = 0 signum _ = -1 fromInteger (S# i#) = I64# (intToInt64# i#) fromInteger (J# s# d#) = I64# (integerToInt64# s# d#) instance Enum Int64 where succ x | x /= maxBound = x + 1 | otherwise = succError "Int64" pred x | x /= minBound = x - 1 | otherwise = predError "Int64" toEnum (I# i#) = I64# (intToInt64# i#) fromEnum x@(I64# x#) | x >= fromIntegral (minBound::Int) && x <= fromIntegral (maxBound::Int) = I# (int64ToInt# x#) | otherwise = fromEnumError "Int64" x enumFrom = integralEnumFrom enumFromThen = integralEnumFromThen enumFromTo = integralEnumFromTo enumFromThenTo = integralEnumFromThenTo instance Integral Int64 where quot x@(I64# x#) y@(I64# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = I64# (x# `quotInt64#` y#) rem x@(I64# x#) y@(I64# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = I64# (x# `remInt64#` y#) div x@(I64# x#) y@(I64# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = I64# (x# `divInt64#` y#) mod x@(I64# x#) y@(I64# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = I64# (x# `modInt64#` y#) quotRem x@(I64# x#) y@(I64# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = (I64# (x# `quotInt64#` y#), I64# (x# `remInt64#` y#)) divMod x@(I64# x#) y@(I64# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = (I64# (x# `divInt64#` y#), I64# (x# `modInt64#` y#)) toInteger x@(I64# x#) | x >= fromIntegral (minBound::Int) && x <= fromIntegral (maxBound::Int) = S# (int64ToInt# x#) | otherwise = case int64ToInteger# x# of (# s, d #) -> J# s d divInt64#, modInt64# :: Int64# -> Int64# -> Int64# x# `divInt64#` y# | (x# `gtInt64#` intToInt64# 0#) && (y# `ltInt64#` intToInt64# 0#) = ((x# `minusInt64#` y#) `minusInt64#` intToInt64# 1#) `quotInt64#` y# | (x# `ltInt64#` intToInt64# 0#) && (y# `gtInt64#` intToInt64# 0#) = ((x# `minusInt64#` y#) `plusInt64#` intToInt64# 1#) `quotInt64#` y# | otherwise = x# `quotInt64#` y# x# `modInt64#` y# | (x# `gtInt64#` intToInt64# 0#) && (y# `ltInt64#` intToInt64# 0#) || (x# `ltInt64#` intToInt64# 0#) && (y# `gtInt64#` intToInt64# 0#) = if r# `neInt64#` intToInt64# 0# then r# `plusInt64#` y# else intToInt64# 0# | otherwise = r# where r# = x# `remInt64#` y# instance Read Int64 where readsPrec p s = [(fromInteger x, r) | (x, r) <- readsPrec p s] instance Bits Int64 where {-# INLINE shift #-} (I64# x#) .&. (I64# y#) = I64# (word64ToInt64# (int64ToWord64# x# `and64#` int64ToWord64# y#)) (I64# x#) .|. (I64# y#) = I64# (word64ToInt64# (int64ToWord64# x# `or64#` int64ToWord64# y#)) (I64# x#) `xor` (I64# y#) = I64# (word64ToInt64# (int64ToWord64# x# `xor64#` int64ToWord64# y#)) complement (I64# x#) = I64# (word64ToInt64# (not64# (int64ToWord64# x#))) (I64# x#) `shift` (I# i#) | i# >=# 0# = I64# (x# `iShiftL64#` i#) | otherwise = I64# (x# `iShiftRA64#` negateInt# i#) (I64# x#) `rotate` (I# i#) | i'# ==# 0# = I64# x# | otherwise = I64# (word64ToInt64# ((x'# `uncheckedShiftL64#` i'#) `or64#` (x'# `uncheckedShiftRL64#` (64# -# i'#)))) where x'# = int64ToWord64# x# i'# = word2Int# (int2Word# i# `and#` int2Word# 63#) bitSize _ = 64 isSigned _ = True -- give the 64-bit shift operations the same treatment as the 32-bit -- ones (see GHC.Base), namely we wrap them in tests to catch the -- cases when we're shifting more than 64 bits to avoid unspecified -- behaviour in the C shift operations. iShiftL64#, iShiftRA64# :: Int64# -> Int# -> Int64# a `iShiftL64#` b | b >=# 64# = intToInt64# 0# | otherwise = a `uncheckedIShiftL64#` b a `iShiftRA64#` b | b >=# 64# = if a `ltInt64#` (intToInt64# 0#) then intToInt64# (-1#) else intToInt64# 0# | otherwise = a `uncheckedIShiftRA64#` b foreign import ccall unsafe "hs_eqInt64" eqInt64# :: Int64# -> Int64# -> Bool foreign import ccall unsafe "hs_neInt64" neInt64# :: Int64# -> Int64# -> Bool foreign import ccall unsafe "hs_ltInt64" ltInt64# :: Int64# -> Int64# -> Bool foreign import ccall unsafe "hs_leInt64" leInt64# :: Int64# -> Int64# -> Bool foreign import ccall unsafe "hs_gtInt64" gtInt64# :: Int64# -> Int64# -> Bool foreign import ccall unsafe "hs_geInt64" geInt64# :: Int64# -> Int64# -> Bool foreign import ccall unsafe "hs_plusInt64" plusInt64# :: Int64# -> Int64# -> Int64# foreign import ccall unsafe "hs_minusInt64" minusInt64# :: Int64# -> Int64# -> Int64# foreign import ccall unsafe "hs_timesInt64" timesInt64# :: Int64# -> Int64# -> Int64# foreign import ccall unsafe "hs_negateInt64" negateInt64# :: Int64# -> Int64# foreign import ccall unsafe "hs_quotInt64" quotInt64# :: Int64# -> Int64# -> Int64# foreign import ccall unsafe "hs_remInt64" remInt64# :: Int64# -> Int64# -> Int64# foreign import ccall unsafe "hs_intToInt64" intToInt64# :: Int# -> Int64# foreign import ccall unsafe "hs_int64ToInt" int64ToInt# :: Int64# -> Int# foreign import ccall unsafe "hs_wordToWord64" wordToWord64# :: Word# -> Word64# foreign import ccall unsafe "hs_int64ToWord64" int64ToWord64# :: Int64# -> Word64# foreign import ccall unsafe "hs_word64ToInt64" word64ToInt64# :: Word64# -> Int64# foreign import ccall unsafe "hs_and64" and64# :: Word64# -> Word64# -> Word64# foreign import ccall unsafe "hs_or64" or64# :: Word64# -> Word64# -> Word64# foreign import ccall unsafe "hs_xor64" xor64# :: Word64# -> Word64# -> Word64# foreign import ccall unsafe "hs_not64" not64# :: Word64# -> Word64# foreign import ccall unsafe "hs_uncheckedShiftL64" uncheckedShiftL64# :: Word64# -> Int# -> Word64# foreign import ccall unsafe "hs_uncheckedShiftRL64" uncheckedShiftRL64# :: Word64# -> Int# -> Word64# foreign import ccall unsafe "hs_uncheckedIShiftL64" uncheckedIShiftL64# :: Int64# -> Int# -> Int64# foreign import ccall unsafe "hs_uncheckedIShiftRA64" uncheckedIShiftRA64# :: Int64# -> Int# -> Int64# foreign import ccall unsafe "hs_integerToInt64" integerToInt64# :: Int# -> ByteArray# -> Int64# {-# RULES "fromIntegral/Int->Int64" fromIntegral = \(I# x#) -> I64# (intToInt64# x#) "fromIntegral/Word->Int64" fromIntegral = \(W# x#) -> I64# (word64ToInt64# (wordToWord64# x#)) "fromIntegral/Word64->Int64" fromIntegral = \(W64# x#) -> I64# (word64ToInt64# x#) "fromIntegral/Int64->Int" fromIntegral = \(I64# x#) -> I# (int64ToInt# x#) "fromIntegral/Int64->Word" fromIntegral = \(I64# x#) -> W# (int2Word# (int64ToInt# x#)) "fromIntegral/Int64->Word64" fromIntegral = \(I64# x#) -> W64# (int64ToWord64# x#) "fromIntegral/Int64->Int64" fromIntegral = id :: Int64 -> Int64 #-} #else -- Int64 is represented in the same way as Int. -- Operations may assume and must ensure that it holds only values -- from its logical range. data Int64 = I64# Int# deriving (Eq, Ord) -- ^ 64-bit signed integer type instance Show Int64 where showsPrec p x = showsPrec p (fromIntegral x :: Int) instance Num Int64 where (I64# x#) + (I64# y#) = I64# (x# +# y#) (I64# x#) - (I64# y#) = I64# (x# -# y#) (I64# x#) * (I64# y#) = I64# (x# *# y#) negate (I64# x#) = I64# (negateInt# x#) abs x | x >= 0 = x | otherwise = negate x signum x | x > 0 = 1 signum 0 = 0 signum _ = -1 fromInteger (S# i#) = I64# i# fromInteger (J# s# d#) = I64# (integer2Int# s# d#) instance Enum Int64 where succ x | x /= maxBound = x + 1 | otherwise = succError "Int64" pred x | x /= minBound = x - 1 | otherwise = predError "Int64" toEnum (I# i#) = I64# i# fromEnum (I64# x#) = I# x# enumFrom = boundedEnumFrom enumFromThen = boundedEnumFromThen instance Integral Int64 where quot x@(I64# x#) y@(I64# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = I64# (x# `quotInt#` y#) rem x@(I64# x#) y@(I64# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = I64# (x# `remInt#` y#) div x@(I64# x#) y@(I64# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = I64# (x# `divInt#` y#) mod x@(I64# x#) y@(I64# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = I64# (x# `modInt#` y#) quotRem x@(I64# x#) y@(I64# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = (I64# (x# `quotInt#` y#), I64# (x# `remInt#` y#)) divMod x@(I64# x#) y@(I64# y#) | y == 0 = divZeroError | x == minBound && y == (-1) = overflowError | otherwise = (I64# (x# `divInt#` y#), I64# (x# `modInt#` y#)) toInteger (I64# x#) = S# x# instance Read Int64 where readsPrec p s = [(fromIntegral (x::Int), r) | (x, r) <- readsPrec p s] instance Bits Int64 where {-# INLINE shift #-} (I64# x#) .&. (I64# y#) = I64# (word2Int# (int2Word# x# `and#` int2Word# y#)) (I64# x#) .|. (I64# y#) = I64# (word2Int# (int2Word# x# `or#` int2Word# y#)) (I64# x#) `xor` (I64# y#) = I64# (word2Int# (int2Word# x# `xor#` int2Word# y#)) complement (I64# x#) = I64# (word2Int# (int2Word# x# `xor#` int2Word# (-1#))) (I64# x#) `shift` (I# i#) | i# >=# 0# = I64# (x# `iShiftL#` i#) | otherwise = I64# (x# `iShiftRA#` negateInt# i#) (I64# x#) `rotate` (I# i#) | i'# ==# 0# = I64# x# | otherwise = I64# (word2Int# ((x'# `uncheckedShiftL#` i'#) `or#` (x'# `uncheckedShiftRL#` (64# -# i'#)))) where x'# = int2Word# x# i'# = word2Int# (int2Word# i# `and#` int2Word# 63#) bitSize _ = 64 isSigned _ = True {-# RULES "fromIntegral/a->Int64" fromIntegral = \x -> case fromIntegral x of I# x# -> I64# x# "fromIntegral/Int64->a" fromIntegral = \(I64# x#) -> fromIntegral (I# x#) #-} #endif instance Real Int64 where toRational x = toInteger x % 1 instance Bounded Int64 where minBound = -0x8000000000000000 maxBound = 0x7FFFFFFFFFFFFFFF instance Ix Int64 where range (m,n) = [m..n] unsafeIndex b@(m,_) i = fromIntegral i - fromIntegral m inRange (m,n) i = m <= i && i <= n