{-# LANGUAGE BangPatterns #-}
{-# LANGUAGE CPP #-}
{-# LANGUAGE MagicHash #-}
{-# LANGUAGE NoImplicitPrelude #-}
{-# LANGUAGE UnboxedSums #-}
{-# LANGUAGE UnboxedTuples #-}
{-# OPTIONS_GHC -Wno-unused-imports -fobject-code #-}
#include "MachDeps.h"
module Numeric.Floating.IEEE.Internal.IntegerInternals
( integerToIntMaybe
, naturalToWordMaybe
, unsafeShiftLInteger
, unsafeShiftRInteger
, roundingMode
, countTrailingZerosInteger
, integerIsPowerOf2
, integerLog2IsPowerOf2
) where
import Data.Bits
import GHC.Exts (Int#, Word#, ctz#, int2Word#, plusWord#, quotRemInt#,
uncheckedShiftL#, word2Int#, (+#), (-#))
import GHC.Int (Int (I#))
import GHC.Word (Word (W#))
import MyPrelude
import Numeric.Floating.IEEE.Internal.Base
import Numeric.Natural
#if defined(MIN_VERSION_ghc_bignum)
import qualified GHC.Num.BigNat
import GHC.Num.Integer (Integer (IN, IP, IS))
import qualified GHC.Num.Integer
import GHC.Num.Natural (Natural (NS))
#elif defined(MIN_VERSION_integer_gmp)
import qualified GHC.Integer
import GHC.Integer.GMP.Internals (Integer (Jn#, Jp#, S#),
indexBigNat#)
import qualified GHC.Integer.Logarithms.Internals
import GHC.Natural (Natural (NatS#))
#define IN Jn#
#define IP Jp#
#define IS S#
#define NS NatS#
#else
import Math.NumberTheory.Logarithms (integerLog2')
#endif
integerToIntMaybe :: Integer -> Maybe Int
naturalToWordMaybe :: Natural -> Maybe Word
unsafeShiftLInteger :: Integer -> Int -> Integer
unsafeShiftRInteger :: Integer -> Int -> Integer
roundingMode :: Integer
-> Int
-> Ordering
countTrailingZerosInteger :: Integer -> Int
integerIsPowerOf2 :: Integer -> Maybe Int
integerLog2IsPowerOf2 :: Integer -> (Int, Bool)
#if defined(MIN_VERSION_ghc_bignum) || defined(MIN_VERSION_integer_gmp)
integerToIntMaybe :: Integer -> Maybe Int
integerToIntMaybe (IS Int#
x) = forall a. a -> Maybe a
Just (Int# -> Int
I# Int#
x)
integerToIntMaybe Integer
_ = forall a. Maybe a
Nothing
{-# INLINE [0] integerToIntMaybe #-}
naturalToWordMaybe :: Natural -> Maybe Word
naturalToWordMaybe (NS Word#
x) = forall a. a -> Maybe a
Just (Word# -> Word
W# Word#
x)
naturalToWordMaybe Natural
_ = forall a. Maybe a
Nothing
{-# INLINE [0] naturalToWordMaybe #-}
integerToIntMaybe2 :: Bool -> Integer -> Maybe Int
integerToIntMaybe2 :: Bool -> Integer -> Maybe Int
integerToIntMaybe2 Bool
_ (IS Int#
x) = forall a. a -> Maybe a
Just (Int# -> Int
I# Int#
x)
integerToIntMaybe2 Bool
_ Integer
_ = forall a. Maybe a
Nothing
{-# INLINE [0] integerToIntMaybe2 #-}
naturalToWordMaybe2 :: Bool -> Natural -> Maybe Word
naturalToWordMaybe2 :: Bool -> Natural -> Maybe Word
naturalToWordMaybe2 Bool
_ (NS Word#
x) = forall a. a -> Maybe a
Just (Word# -> Word
W# Word#
x)
naturalToWordMaybe2 Bool
_ Natural
_ = forall a. Maybe a
Nothing
{-# INLINE [0] naturalToWordMaybe2 #-}
minBoundIntAsInteger :: Integer
minBoundIntAsInteger :: Integer
minBoundIntAsInteger = forall a b. (Integral a, Num b) => a -> b
fromIntegral (forall a. Bounded a => a
minBound :: Int)
{-# INLINE minBoundIntAsInteger #-}
maxBoundIntAsInteger :: Integer
maxBoundIntAsInteger :: Integer
maxBoundIntAsInteger = forall a b. (Integral a, Num b) => a -> b
fromIntegral (forall a. Bounded a => a
maxBound :: Int)
{-# INLINE maxBoundIntAsInteger #-}
maxBoundWordAsNatural :: Natural
maxBoundWordAsNatural :: Natural
maxBoundWordAsNatural = forall a b. (Integral a, Num b) => a -> b
fromIntegral (forall a. Bounded a => a
maxBound :: Word)
{-# INLINE maxBoundWordAsNatural #-}
{-# RULES
"integerToIntMaybe" [~0] forall x.
integerToIntMaybe x = integerToIntMaybe2 (minBoundIntAsInteger <= x && x <= maxBoundIntAsInteger) x
"integerToIntMaybe2/small" forall x.
integerToIntMaybe2 True x = Just (fromIntegral x)
"integerToIntMaybe2/large" forall x.
integerToIntMaybe2 False x = Nothing
"naturalToWordMaybe" [~0] forall x.
naturalToWordMaybe x = naturalToWordMaybe2 (x <= maxBoundWordAsNatural) x
"naturalToWordIntMaybe2/small" forall x.
naturalToWordMaybe2 True x = Just (fromIntegral x)
"naturalToWordIntMaybe2/large" forall x.
naturalToWordMaybe2 False x = Nothing
#-}
#else
integerToIntMaybe = toIntegralSized
naturalToWordMaybe = toIntegralSized
{-# INLINE integerToIntMaybe #-}
{-# INLINE naturalToWordMaybe #-}
#endif
#if defined(MIN_VERSION_ghc_bignum)
unsafeShiftLInteger :: Integer -> Int -> Integer
unsafeShiftLInteger Integer
x (I# Int#
i) = Integer -> Word# -> Integer
GHC.Num.Integer.integerShiftL# Integer
x (Int# -> Word#
int2Word# Int#
i)
unsafeShiftRInteger :: Integer -> Int -> Integer
unsafeShiftRInteger Integer
x (I# Int#
i) = Integer -> Word# -> Integer
GHC.Num.Integer.integerShiftR# Integer
x (Int# -> Word#
int2Word# Int#
i)
#elif defined(MIN_VERSION_integer_gmp)
unsafeShiftLInteger x (I# i) = GHC.Integer.shiftLInteger x i
unsafeShiftRInteger x (I# i) = GHC.Integer.shiftRInteger x i
#else
unsafeShiftLInteger = unsafeShiftL
unsafeShiftRInteger = unsafeShiftR
#endif
{-# INLINE unsafeShiftLInteger #-}
{-# INLINE unsafeShiftRInteger #-}
#if defined(MIN_VERSION_ghc_bignum) || defined(MIN_VERSION_integer_gmp)
countTrailingZerosInteger# :: Integer -> Word#
countTrailingZerosInteger# :: Integer -> Word#
countTrailingZerosInteger# (IS Int#
x) = Word# -> Word#
ctz# (Int# -> Word#
int2Word# Int#
x)
countTrailingZerosInteger# (IN ByteArray#
bn) = Integer -> Word#
countTrailingZerosInteger# (ByteArray# -> Integer
IP ByteArray#
bn)
countTrailingZerosInteger# (IP ByteArray#
bn) = Int# -> Word# -> Word#
loop Int#
0# Word#
0##
where
loop :: Int# -> Word# -> Word#
loop Int#
i Word#
acc =
let
#if defined(MIN_VERSION_ghc_bignum)
!bn_i :: Word#
bn_i = ByteArray# -> Int# -> Word#
GHC.Num.BigNat.bigNatIndex# ByteArray#
bn Int#
i
#else
!bn_i = indexBigNat# bn i
#endif
in case Word#
bn_i of
Word#
0## -> Int# -> Word# -> Word#
loop (Int#
i Int# -> Int# -> Int#
+# Int#
1#) (Word#
acc Word# -> Word# -> Word#
`plusWord#` WORD_SIZE_IN_BITS##)
Word#
w -> Word#
acc Word# -> Word# -> Word#
`plusWord#` Word# -> Word#
ctz# Word#
w
countTrailingZerosInteger :: Integer -> Int
countTrailingZerosInteger Integer
0 = forall a. HasCallStack => [Char] -> a
error [Char]
"countTrailingZerosInteger: zero"
countTrailingZerosInteger Integer
x = Int# -> Int
I# (Word# -> Int#
word2Int# (Integer -> Word#
countTrailingZerosInteger# Integer
x))
{-# INLINE countTrailingZerosInteger #-}
#else
countTrailingZerosInteger 0 = error "countTrailingZerosInteger: zero"
countTrailingZerosInteger x = integerLog2' (x `xor` (x - 1))
{-# INLINE countTrailingZerosInteger #-}
#endif
#if defined(MIN_VERSION_ghc_bignum)
roundingMode# :: Integer -> Int# -> Ordering
roundingMode# :: Integer -> Int# -> Ordering
roundingMode# (IS Int#
x) Int#
t = let !w :: Word#
w = Int# -> Word#
int2Word# Int#
x
in forall a. Ord a => a -> a -> Ordering
compare (Word# -> Word
W# (Word#
w Word# -> Int# -> Word#
`uncheckedShiftL#` (WORD_SIZE_IN_BITS# Word# -> Word
-# 1# -# t))) (W# (1## `uncheckedShiftL#` (WORD_SIZE_IN_BITS# -# 1#)))
roundingMode# (IN ByteArray#
bn) Int#
t = Integer -> Int# -> Ordering
roundingMode# (ByteArray# -> Integer
IP ByteArray#
bn) Int#
t
roundingMode# (IP ByteArray#
bn) Int#
t = case Int#
t Int# -> Int# -> (# Int#, Int# #)
`quotRemInt#` WORD_SIZE_IN_BITS# of
(# Int#
s, Int#
r #) -> let !w :: Word#
w = ByteArray# -> Int# -> Word#
GHC.Num.BigNat.bigNatIndex# ByteArray#
bn Int#
s
in forall a. Ord a => a -> a -> Ordering
compare (Word# -> Word
W# (Word#
w Word# -> Int# -> Word#
`uncheckedShiftL#` (WORD_SIZE_IN_BITS# Word# -> Word
-# 1# -# r))) (W# (1## `uncheckedShiftL#` (WORD_SIZE_IN_BITS# -# 1#)))
forall a. Semigroup a => a -> a -> a
<> Int# -> Ordering
loop Int#
s
where
loop :: Int# -> Ordering
loop Int#
0# = Ordering
EQ
loop Int#
i = case ByteArray# -> Int# -> Word#
GHC.Num.BigNat.bigNatIndex# ByteArray#
bn (Int#
i Int# -> Int# -> Int#
-# Int#
1#) of
Word#
0## -> Int# -> Ordering
loop (Int#
i Int# -> Int# -> Int#
-# Int#
1#)
Word#
_ -> Ordering
GT
roundingMode :: Integer -> Int -> Ordering
roundingMode Integer
x (I# Int#
t) = Integer -> Int# -> Ordering
roundingMode# Integer
x Int#
t
{-# INLINE roundingMode #-}
integerIsPowerOf2 :: Integer -> Maybe Int
integerIsPowerOf2 Integer
x = case Integer -> (# (# #) | Word# #)
GHC.Num.Integer.integerIsPowerOf2# Integer
x of
(# (# #)
_ | #) -> forall a. Maybe a
Nothing
(# | Word#
w #) -> forall a. a -> Maybe a
Just (Int# -> Int
I# (Word# -> Int#
word2Int# Word#
w))
{-# INLINE integerIsPowerOf2 #-}
integerLog2IsPowerOf2 :: Integer -> (Int, Bool)
integerLog2IsPowerOf2 Integer
x = case Integer -> (# (# #) | Word# #)
GHC.Num.Integer.integerIsPowerOf2# Integer
x of
(# (# #)
_ | #) -> (Int# -> Int
I# (Word# -> Int#
word2Int# (Integer -> Word#
GHC.Num.Integer.integerLog2# Integer
x)), Bool
False)
(# | Word#
w #) -> (Int# -> Int
I# (Word# -> Int#
word2Int# Word#
w), Bool
True)
{-# INLINE integerLog2IsPowerOf2 #-}
#elif defined(MIN_VERSION_integer_gmp)
roundingMode x (I# t#) = case GHC.Integer.Logarithms.Internals.roundingMode# x t# of
0# -> LT
1# -> EQ
_ -> GT
{-# INLINE roundingMode #-}
integerIsPowerOf2 x = case GHC.Integer.Logarithms.Internals.integerLog2IsPowerOf2# x of
(# l, 0# #) -> Just (I# l)
(# _, _ #) -> Nothing
{-# INLINE integerIsPowerOf2 #-}
integerLog2IsPowerOf2 x = case GHC.Integer.Logarithms.Internals.integerLog2IsPowerOf2# x of
(# l, 0# #) -> (I# l, True)
(# l, _ #) -> (I# l, False)
{-# INLINE integerLog2IsPowerOf2 #-}
#else
roundingMode x t = compare (x .&. (bit (t + 1) - 1)) (bit t)
{-# INLINE roundingMode #-}
integerIsPowerOf2 x = if x .&. (x - 1) == 0 then
Just (integerLog2' x)
else
Nothing
integerLog2IsPowerOf2 x = (integerLog2' x, x .&. (x - 1) == 0)
{-# INLINE integerLog2IsPowerOf2 #-}
#endif