{-# LANGUAGE BangPatterns #-}
{-# LANGUAGE CPP #-}
{-# LANGUAGE DeriveDataTypeable #-}
{-# LANGUAGE MagicHash #-}
{-# LANGUAGE MultiParamTypeClasses #-}
{-# LANGUAGE StrictData #-}
{-# LANGUAGE UnboxedTuples #-}
{-# OPTIONS_GHC -funbox-strict-fields #-}
#include <MachDeps.h>
module Data.WideWord.Int128
( Int128 (..)
, byteSwapInt128
, showHexInt128
, zeroInt128
) where
import Control.DeepSeq (NFData (..))
import Data.Bits (Bits (..), FiniteBits (..), shiftL)
import Data.Data (Data, Typeable)
import Data.Ix (Ix)
import Data.WideWord.Word128
import Numeric
import Foreign.Ptr (Ptr, castPtr)
import Foreign.Storable (Storable (..))
import GHC.Base (Int (..), and#, int2Word#, minusWord#, not#, or#, plusWord#, plusWord2#
, subWordC#, timesWord#, timesWord2#, word2Int#, xor#)
import GHC.Enum (predError, succError)
import GHC.Exts ((+#), (*#), State#, Int#, Addr#, ByteArray#, MutableByteArray#)
import GHC.Int (Int64 (..))
import GHC.Real ((%))
import GHC.Word (Word64 (..), Word32, byteSwap64)
import Data.Primitive.Types (Prim (..), defaultSetByteArray#, defaultSetOffAddr#)
data Int128 = Int128
{ int128Hi64 :: {-# UNPACK #-} !Word64
, int128Lo64 :: {-# UNPACK #-} !Word64
}
deriving (Eq, Data, Ix, Typeable)
byteSwapInt128 :: Int128 -> Int128
byteSwapInt128 (Int128 a1 a0) = Int128 (byteSwap64 a0) (byteSwap64 a1)
showHexInt128 :: Int128 -> String
showHexInt128 (Int128 a1 a0)
| a1 == 0 = showHex a0 ""
| otherwise = showHex a1 zeros ++ showHex a0 ""
where
h0 = showHex a0 ""
zeros = replicate (16 - length h0) '0'
instance Show Int128 where
show = show . toInteger
instance Read Int128 where
readsPrec p s = [(fromInteger128 (x :: Integer), r) | (x, r) <- readsPrec p s]
instance Ord Int128 where
compare = compare128
instance Bounded Int128 where
minBound = Int128 0x8000000000000000 0
maxBound = Int128 0x7fffffffffffffff maxBound
instance Enum Int128 where
succ = succ128
pred = pred128
toEnum = toEnum128
fromEnum = fromEnum128
instance Num Int128 where
(+) = plus128
(-) = minus128
(*) = times128
negate = negate128
abs = abs128
signum = signum128
fromInteger = fromInteger128
instance Bits Int128 where
(.&.) = and128
(.|.) = or128
xor = xor128
complement = complement128
shiftL = shiftL128
unsafeShiftL = shiftL128
shiftR = shiftR128
unsafeShiftR = shiftR128
rotateL = rotateL128
rotateR = rotateR128
bitSize _ = 128
bitSizeMaybe _ = Just 128
isSigned _ = False
testBit = testBit128
bit = bit128
popCount = popCount128
instance FiniteBits Int128 where
finiteBitSize _ = 128
countLeadingZeros = countLeadingZeros128
countTrailingZeros = countTrailingZeros128
instance Real Int128 where
toRational x = toInteger128 x % 1
instance Integral Int128 where
quot n d = fst (quotRem128 n d)
rem n d = snd (quotRem128 n d)
div n d = fst (divMod128 n d)
mod n d = snd (divMod128 n d)
quotRem = quotRem128
divMod = divMod128
toInteger = toInteger128
instance Storable Int128 where
sizeOf _ = 2 * sizeOf (0 :: Word64)
alignment _ = 2 * alignment (0 :: Word64)
peek = peek128
peekElemOff = peekElemOff128
poke = poke128
pokeElemOff = pokeElemOff128
instance NFData Int128 where
rnf (Int128 a1 a0) = rnf a1 `seq` rnf a0
instance Prim Int128 where
sizeOf# = sizeOf128#
alignment# = alignment128#
indexByteArray# = indexByteArray128#
readByteArray# = readByteArray128#
writeByteArray# = writeByteArray128#
setByteArray# = setByteArray128#
indexOffAddr# = indexOffAddr128#
readOffAddr# = readOffAddr128#
writeOffAddr# = writeOffAddr128#
setOffAddr# = setOffAddr128#
{-# INLINE sizeOf# #-}
{-# INLINE alignment# #-}
{-# INLINE indexByteArray# #-}
{-# INLINE readByteArray# #-}
{-# INLINE writeByteArray# #-}
{-# INLINE setByteArray# #-}
{-# INLINE indexOffAddr# #-}
{-# INLINE readOffAddr# #-}
{-# INLINE writeOffAddr# #-}
{-# INLINE setOffAddr# #-}
{-# RULES
"fromIntegral :: Int128 -> Int128" fromIntegral = id :: Int128 -> Int128
"fromIntegral :: Word128 -> Int128" fromIntegral = \(Word128 a1 a0) -> Int128 a1 a0
"fromIntegral :: Int128 -> Word128" fromIntegral = \(Int128 a1 a0) -> Word128 a1 a0
"fromIntegral :: Word -> Int128" fromIntegral = Int128 0 . (fromIntegral :: Word -> Word64)
"fromIntegral :: Word32 -> Int128" fromIntegral = Int128 0 . (fromIntegral :: Word32 -> Word64)
"fromIntegral :: Word64 -> Int128" fromIntegral = Int128 0
#-}
compare128 :: Int128 -> Int128 -> Ordering
compare128 (Int128 a1 a0) (Int128 b1 b0) =
case compare (int64OfWord64 a1) (int64OfWord64 b1) of
EQ -> compare a0 b0
LT -> LT
GT -> GT
where
int64OfWord64 (W64# w) = I64# (word2Int# w)
succ128 :: Int128 -> Int128
succ128 (Int128 a1 a0)
| a0 == maxBound = if a1 == 0x7fffffffffffffff
then succError "Int128"
else Int128 (a1 + 1) 0
| otherwise = Int128 a1 (a0 + 1)
pred128 :: Int128 -> Int128
pred128 (Int128 a1 a0)
| a0 == 0 = if a1 == 0x8000000000000000
then predError "Int128"
else Int128 (a1 - 1) maxBound
| otherwise = Int128 a1 (a0 - 1)
{-# INLINABLE toEnum128 #-}
toEnum128 :: Int -> Int128
toEnum128 i = Int128 0 (toEnum i)
{-# INLINABLE fromEnum128 #-}
fromEnum128 :: Int128 -> Int
fromEnum128 (Int128 _ a0) = fromEnum a0
{-# INLINABLE plus128 #-}
plus128 :: Int128 -> Int128 -> Int128
plus128 (Int128 (W64# a1) (W64# a0)) (Int128 (W64# b1) (W64# b0)) =
Int128 (W64# s1) (W64# s0)
where
!(# c1, s0 #) = plusWord2# a0 b0
s1a = plusWord# a1 b1
s1 = plusWord# c1 s1a
{-# INLINABLE minus128 #-}
minus128 :: Int128 -> Int128 -> Int128
minus128 (Int128 (W64# a1) (W64# a0)) (Int128 (W64# b1) (W64# b0)) =
Int128 (W64# d1) (W64# d0)
where
!(# d0, c1 #) = subWordC# a0 b0
a1c = minusWord# a1 (int2Word# c1)
d1 = minusWord# a1c b1
times128 :: Int128 -> Int128 -> Int128
times128 (Int128 (W64# a1) (W64# a0)) (Int128 (W64# b1) (W64# b0)) =
Int128 (W64# p1) (W64# p0)
where
!(# c1, p0 #) = timesWord2# a0 b0
p1a = timesWord# a1 b0
p1b = timesWord# a0 b1
p1c = plusWord# p1a p1b
p1 = plusWord# p1c c1
{-# INLINABLE negate128 #-}
negate128 :: Int128 -> Int128
negate128 (Int128 (W64# a1) (W64# a0)) =
case plusWord2# (not# a0) 1## of
(# c, s #) -> Int128 (W64# (plusWord# (not# a1) c)) (W64# s)
{-# INLINABLE abs128 #-}
abs128 :: Int128 -> Int128
abs128 i@(Int128 a1 _)
| testBit a1 63 = negate128 i
| otherwise = i
{-# INLINABLE signum128 #-}
signum128 :: Int128 -> Int128
signum128 (Int128 a1 a0)
| a1 == 0 && a0 == 0 = zeroInt128
| testBit a1 63 = minusOneInt128
| otherwise = oneInt128
{-# INLINABLE complement128 #-}
complement128 :: Int128 -> Int128
complement128 (Int128 a1 a0) = Int128 (complement a1) (complement a0)
fromInteger128 :: Integer -> Int128
fromInteger128 i =
Int128 (fromIntegral $ i `shiftR` 64) (fromIntegral i)
{-# INLINABLE and128 #-}
and128 :: Int128 -> Int128 -> Int128
and128 (Int128 (W64# a1) (W64# a0)) (Int128 (W64# b1) (W64# b0)) =
Int128 (W64# (and# a1 b1)) (W64# (and# a0 b0))
{-# INLINABLE or128 #-}
or128 :: Int128 -> Int128 -> Int128
or128 (Int128 (W64# a1) (W64# a0)) (Int128 (W64# b1) (W64# b0)) =
Int128 (W64# (or# a1 b1)) (W64# (or# a0 b0))
{-# INLINABLE xor128 #-}
xor128 :: Int128 -> Int128 -> Int128
xor128 (Int128 (W64# a1) (W64# a0)) (Int128 (W64# b1) (W64# b0)) =
Int128 (W64# (xor# a1 b1)) (W64# (xor# a0 b0))
shiftL128 :: Int128 -> Int -> Int128
shiftL128 w@(Int128 a1 a0) s
| s == 0 = w
| s < 0 = shiftL128 w (128 - (abs s `mod` 128))
| s >= 128 = zeroInt128
| s == 64 = Int128 a0 0
| s > 64 = Int128 (a0 `shiftL` (s - 64)) 0
| otherwise =
Int128 s1 s0
where
s0 = a0 `shiftL` s
s1 = a1 `shiftL` s + a0 `shiftR` (64 - s)
shiftR128 :: Int128 -> Int -> Int128
shiftR128 i@(Int128 a1 a0) s
| s < 0 = zeroInt128
| s == 0 = i
| topBitSetWord64 a1 = complement128 (shiftR128 (complement128 i) s)
| s >= 128 = zeroInt128
| s == 64 = Int128 0 a1
| s > 64 = Int128 0 (a1 `shiftR` (s - 64))
| otherwise = Int128 s1 s0
where
s1 = a1 `shiftR` s
s0 = a0 `shiftR` s + a1 `shiftL` (64 - s)
rotateL128 :: Int128 -> Int -> Int128
rotateL128 w@(Int128 a1 a0) r
| r < 0 = zeroInt128
| r == 0 = w
| r >= 128 = rotateL128 w (r `mod` 128)
| r == 64 = Int128 a0 a1
| r > 64 = rotateL128 (Int128 a0 a1) (r `mod` 64)
| otherwise =
Int128 s1 s0
where
s0 = a0 `shiftL` r + a1 `shiftR` (64 - r)
s1 = a1 `shiftL` r + a0 `shiftR` (64 - r)
rotateR128 :: Int128 -> Int -> Int128
rotateR128 w@(Int128 a1 a0) r
| r < 0 = rotateR128 w (128 - (abs r `mod` 128))
| r == 0 = w
| r >= 128 = rotateR128 w (r `mod` 128)
| r == 64 = Int128 a0 a1
| r > 64 = rotateR128 (Int128 a0 a1) (r `mod` 64)
| otherwise =
Int128 s1 s0
where
s0 = a0 `shiftR` r + a1 `shiftL` (64 - r)
s1 = a1 `shiftR` r + a0 `shiftL` (64 - r)
testBit128 :: Int128 -> Int -> Bool
testBit128 (Int128 a1 a0) i
| i < 0 = False
| i >= 128 = False
| i >= 64 = testBit a1 (i - 64)
| otherwise = testBit a0 i
bit128 :: Int -> Int128
bit128 indx
| indx < 0 = zeroInt128
| indx >= 128 = zeroInt128
| otherwise = shiftL128 oneInt128 indx
popCount128 :: Int128 -> Int
popCount128 (Int128 a1 a0) = popCount a1 + popCount a0
countLeadingZeros128 :: Int128 -> Int
countLeadingZeros128 (Int128 a1 a0) =
case countLeadingZeros a1 of
64 -> 64 + countLeadingZeros a0
res -> res
countTrailingZeros128 :: Int128 -> Int
countTrailingZeros128 (Int128 a1 a0) =
case countTrailingZeros a0 of
64 -> 64 + countTrailingZeros a1
res -> res
quotRem128 :: Int128 -> Int128 -> (Int128, Int128)
quotRem128 numer denom
| isNeg numer && isNeg denom = (word128ToInt128 wq, word128ToInt128 (negate wr))
| isNeg numer = (word128ToInt128 (negate wq), word128ToInt128 (negate wr))
| isNeg denom = (word128ToInt128 (negate wq), word128ToInt128 wr)
| otherwise = (word128ToInt128 wq, word128ToInt128 wr)
where
(wq, wr) = quotRem absNumerW absDenomW
absNumerW = int128ToWord128 $ abs128 numer
absDenomW = int128ToWord128 $ abs128 denom
isNeg = topBitSetWord64 . int128Hi64
divMod128 :: Int128 -> Int128 -> (Int128, Int128)
divMod128 numer denom
| isNeg numer && isNeg denom = (word128ToInt128 wq, word128ToInt128 (negate wr))
| isNeg numer && wr == 0 = (word128ToInt128 (negate wq), 0)
| isNeg numer = (word128ToInt128 (negate $ wq + 1), word128ToInt128 (absDenomW - wr))
| isNeg denom && wr == 0 = (word128ToInt128 (negate wq), 0)
| isNeg denom = (word128ToInt128 (negate $ wq + 1), word128ToInt128 (negate $ absDenomW - wr))
| otherwise = (word128ToInt128 wq, word128ToInt128 wr)
where
(wq, wr) = quotRem absNumerW absDenomW
isNeg = topBitSetWord64 . int128Hi64
absNumerW = int128ToWord128 $ abs128 numer
absDenomW = int128ToWord128 $ abs128 denom
toInteger128 :: Int128 -> Integer
toInteger128 i@(Int128 a1 a0)
| popCount a1 == 64 && popCount a0 == 64 = -1
| not (testBit a1 63) = fromIntegral a1 `shiftL` 64 + fromIntegral a0
| otherwise =
case negate128 i of
Int128 n1 n0 -> negate (fromIntegral n1 `shiftL` 64 + fromIntegral n0)
peek128 :: Ptr Int128 -> IO Int128
peek128 ptr =
Int128 <$> peekElemOff (castPtr ptr) index1 <*> peekElemOff (castPtr ptr) index0
peekElemOff128 :: Ptr Int128 -> Int -> IO Int128
peekElemOff128 ptr idx =
Int128 <$> peekElemOff (castPtr ptr) (idx2 + index1)
<*> peekElemOff (castPtr ptr) (idx2 + index0)
where idx2 = 2 * idx
poke128 :: Ptr Int128 -> Int128 -> IO ()
poke128 ptr (Int128 a1 a0) =
pokeElemOff (castPtr ptr) index1 a1 >> pokeElemOff (castPtr ptr) index0 a0
pokeElemOff128 :: Ptr Int128 -> Int -> Int128 -> IO ()
pokeElemOff128 ptr idx (Int128 a1 a0) = do
let idx2 = 2 * idx
pokeElemOff (castPtr ptr) (idx2 + index0) a0
pokeElemOff (castPtr ptr) (idx2 + index1) a1
{-# INLINE int128ToWord128 #-}
int128ToWord128 :: Int128 -> Word128
int128ToWord128 (Int128 a1 a0) = Word128 a1 a0
{-# INLINE topBitSetWord64 #-}
topBitSetWord64 :: Word64 -> Bool
topBitSetWord64 w = testBit w 63
{-# INLINE word128ToInt128 #-}
word128ToInt128 :: Word128 -> Int128
word128ToInt128 (Word128 a1 a0) = Int128 a1 a0
{-# INLINE sizeOf128# #-}
sizeOf128# :: Int128 -> Int#
sizeOf128# _ = 2# *# sizeOf# (undefined :: Word64)
{-# INLINE alignment128# #-}
alignment128# :: Int128 -> Int#
alignment128# _ = 2# *# alignment# (undefined :: Word64)
{-# INLINE indexByteArray128# #-}
indexByteArray128# :: ByteArray# -> Int# -> Int128
indexByteArray128# arr# i# =
let i2# = 2# *# i#
x = indexByteArray# arr# (i2# +# unInt index1)
y = indexByteArray# arr# (i2# +# unInt index0)
in Int128 x y
{-# INLINE readByteArray128# #-}
readByteArray128# :: MutableByteArray# s -> Int# -> State# s -> (# State# s, Int128 #)
readByteArray128# arr# i# =
\s0 -> case readByteArray# arr# (i2# +# unInt index1) s0 of
(# s1, x #) -> case readByteArray# arr# (i2# +# unInt index0) s1 of
(# s2, y #) -> (# s2, Int128 x y #)
where i2# = 2# *# i#
{-# INLINE writeByteArray128# #-}
writeByteArray128# :: MutableByteArray# s -> Int# -> Int128 -> State# s -> State# s
writeByteArray128# arr# i# (Int128 a b) =
\s0 -> case writeByteArray# arr# (i2# +# unInt index1) a s0 of
s1 -> case writeByteArray# arr# (i2# +# unInt index0) b s1 of
s2 -> s2
where i2# = 2# *# i#
{-# INLINE setByteArray128# #-}
setByteArray128# :: MutableByteArray# s -> Int# -> Int# -> Int128 -> State# s -> State# s
setByteArray128# = defaultSetByteArray#
{-# INLINE indexOffAddr128# #-}
indexOffAddr128# :: Addr# -> Int# -> Int128
indexOffAddr128# addr# i# =
let i2# = 2# *# i#
x = indexOffAddr# addr# (i2# +# unInt index1)
y = indexOffAddr# addr# (i2# +# unInt index0)
in Int128 x y
{-# INLINE readOffAddr128# #-}
readOffAddr128# :: Addr# -> Int# -> State# s -> (# State# s, Int128 #)
readOffAddr128# addr# i# =
\s0 -> case readOffAddr# addr# (i2# +# unInt index1) s0 of
(# s1, x #) -> case readOffAddr# addr# (i2# +# unInt index0) s1 of
(# s2, y #) -> (# s2, Int128 x y #)
where i2# = 2# *# i#
{-# INLINE writeOffAddr128# #-}
writeOffAddr128# :: Addr# -> Int# -> Int128 -> State# s -> State# s
writeOffAddr128# addr# i# (Int128 a b) =
\s0 -> case writeOffAddr# addr# (i2# +# unInt index1) a s0 of
s1 -> case writeOffAddr# addr# (i2# +# unInt index0) b s1 of
s2 -> s2
where i2# = 2# *# i#
{-# INLINE setOffAddr128# #-}
setOffAddr128# :: Addr# -> Int# -> Int# -> Int128 -> State# s -> State# s
setOffAddr128# = defaultSetOffAddr#
zeroInt128 :: Int128
zeroInt128 = Int128 0 0
oneInt128 :: Int128
oneInt128 = Int128 0 1
minusOneInt128 :: Int128
minusOneInt128 = Int128 maxBound maxBound
unInt :: Int -> Int#
unInt (I# i#) = i#
index0, index1 :: Int
#if WORDS_BIGENDIAN
index0 = 1
index1 = 0
#else
index0 = 0
index1 = 1
#endif