Safe Haskell	None
Language	Haskell2010

GHC.Internal.Integer

Contents

Construct Integers
Conversion to other integral types
Helpers for RealFloat type-class operations
Arithmetic operations
Comparison predicates
- Int#-boolean valued versions of comparison predicates
Bit-operations
Hashing

Description

Compatibility module for pre ghc-bignum code.

Synopsis

data Integer
smallInteger :: Int# -> Integer
wordToInteger :: Word# -> Integer
integerToWord :: Integer -> Word#
integerToInt :: Integer -> Int#
encodeFloatInteger :: Integer -> Int# -> Float#
encodeDoubleInteger :: Integer -> Int# -> Double#
decodeDoubleInteger :: Double# -> (# Integer, Int# #)
plusInteger :: Integer -> Integer -> Integer
minusInteger :: Integer -> Integer -> Integer
timesInteger :: Integer -> Integer -> Integer
negateInteger :: Integer -> Integer
absInteger :: Integer -> Integer
signumInteger :: Integer -> Integer
divModInteger :: Integer -> Integer -> (# Integer, Integer #)
divInteger :: Integer -> Integer -> Integer
modInteger :: Integer -> Integer -> Integer
quotRemInteger :: Integer -> Integer -> (# Integer, Integer #)
quotInteger :: Integer -> Integer -> Integer
remInteger :: Integer -> Integer -> Integer
eqInteger :: Integer -> Integer -> Bool
neqInteger :: Integer -> Integer -> Bool
leInteger :: Integer -> Integer -> Bool
gtInteger :: Integer -> Integer -> Bool
ltInteger :: Integer -> Integer -> Bool
geInteger :: Integer -> Integer -> Bool
compareInteger :: Integer -> Integer -> Ordering
eqInteger# :: Integer -> Integer -> Int#
neqInteger# :: Integer -> Integer -> Int#
leInteger# :: Integer -> Integer -> Int#
gtInteger# :: Integer -> Integer -> Int#
ltInteger# :: Integer -> Integer -> Int#
geInteger# :: Integer -> Integer -> Int#
andInteger :: Integer -> Integer -> Integer
orInteger :: Integer -> Integer -> Integer
xorInteger :: Integer -> Integer -> Integer
complementInteger :: Integer -> Integer
shiftLInteger :: Integer -> Int# -> Integer
shiftRInteger :: Integer -> Int# -> Integer
testBitInteger :: Integer -> Int# -> Bool
popCountInteger :: Integer -> Int#
bitInteger :: Int# -> Integer
hashInteger :: Integer -> Int#

Documentation

data Integer #

Arbitrary precision integers. In contrast with fixed-size integral types such as Int, the Integer type represents the entire infinite range of integers.

Integers are stored in a kind of sign-magnitude form, hence do not expect two's complement form when using bit operations.

If the value is small (i.e., fits into an Int), the IS constructor is used. Otherwise IP and IN constructors are used to store a BigNat representing the positive or the negative value magnitude, respectively.

Invariant: IP and IN are used iff the value does not fit in IS.

Instances

Instances details

Bits Integer #	Since: base-2.1
Instance details Defined in GHC.Internal.Bits Methods (.&.) :: Integer -> Integer -> Integer # (.\|.) :: Integer -> Integer -> Integer # xor :: Integer -> Integer -> Integer # complement :: Integer -> Integer # shift :: Integer -> Int -> Integer # rotate :: Integer -> Int -> Integer # zeroBits :: Integer # bit :: Int -> Integer # setBit :: Integer -> Int -> Integer # clearBit :: Integer -> Int -> Integer # complementBit :: Integer -> Int -> Integer # testBit :: Integer -> Int -> Bool # bitSizeMaybe :: Integer -> Maybe Int # bitSize :: Integer -> Int # isSigned :: Integer -> Bool # shiftL :: Integer -> Int -> Integer # unsafeShiftL :: Integer -> Int -> Integer # shiftR :: Integer -> Int -> Integer # unsafeShiftR :: Integer -> Int -> Integer # rotateL :: Integer -> Int -> Integer # rotateR :: Integer -> Int -> Integer # popCount :: Integer -> Int #
Eq Integer #
Instance details Defined in GHC.Internal.Bignum.Integer Methods (==) :: Integer -> Integer -> Bool # (/=) :: Integer -> Integer -> Bool #
Ord Integer #
Instance details Defined in GHC.Internal.Bignum.Integer Methods compare :: Integer -> Integer -> Ordering # (<) :: Integer -> Integer -> Bool # (<=) :: Integer -> Integer -> Bool # (>) :: Integer -> Integer -> Bool # (>=) :: Integer -> Integer -> Bool # max :: Integer -> Integer -> Integer # min :: Integer -> Integer -> Integer #
Data Integer #	Since: base-4.0.0.0
Instance details Defined in GHC.Internal.Data.Data Methods gfoldl :: (forall d b. Data d => c (d -> b) -> d -> c b) -> (forall g. g -> c g) -> Integer -> c Integer # gunfold :: (forall b r. Data b => c (b -> r) -> c r) -> (forall r. r -> c r) -> Constr -> c Integer # toConstr :: Integer -> Constr # dataTypeOf :: Integer -> DataType # dataCast1 :: Typeable t => (forall d. Data d => c (t d)) -> Maybe (c Integer) # dataCast2 :: Typeable t => (forall d e. (Data d, Data e) => c (t d e)) -> Maybe (c Integer) # gmapT :: (forall b. Data b => b -> b) -> Integer -> Integer # gmapQl :: (r -> r' -> r) -> r -> (forall d. Data d => d -> r') -> Integer -> r # gmapQr :: forall r r'. (r' -> r -> r) -> r -> (forall d. Data d => d -> r') -> Integer -> r # gmapQ :: (forall d. Data d => d -> u) -> Integer -> [u] # gmapQi :: Int -> (forall d. Data d => d -> u) -> Integer -> u # gmapM :: Monad m => (forall d. Data d => d -> m d) -> Integer -> m Integer # gmapMp :: MonadPlus m => (forall d. Data d => d -> m d) -> Integer -> m Integer # gmapMo :: MonadPlus m => (forall d. Data d => d -> m d) -> Integer -> m Integer #
Enum Integer #	Since: base-2.1
Instance details Defined in GHC.Internal.Enum Methods succ :: Integer -> Integer # pred :: Integer -> Integer # toEnum :: Int -> Integer # fromEnum :: Integer -> Int # enumFrom :: Integer -> [Integer] # enumFromThen :: Integer -> Integer -> [Integer] # enumFromTo :: Integer -> Integer -> [Integer] # enumFromThenTo :: Integer -> Integer -> Integer -> [Integer] #
Ix Integer #	Since: base-2.1
Instance details Defined in GHC.Internal.Ix Methods range :: (Integer, Integer) -> [Integer] # index :: (Integer, Integer) -> Integer -> Int # unsafeIndex :: (Integer, Integer) -> Integer -> Int # inRange :: (Integer, Integer) -> Integer -> Bool # rangeSize :: (Integer, Integer) -> Int # unsafeRangeSize :: (Integer, Integer) -> Int #
Num Integer #	Since: base-2.1
Instance details Defined in GHC.Internal.Num Methods (+) :: Integer -> Integer -> Integer # (-) :: Integer -> Integer -> Integer # (*) :: Integer -> Integer -> Integer # negate :: Integer -> Integer # abs :: Integer -> Integer # signum :: Integer -> Integer # fromInteger :: Integer -> Integer #
Read Integer #	Since: base-2.1
Instance details Defined in GHC.Internal.Read Methods readsPrec :: Int -> ReadS Integer # readList :: ReadS [Integer] # readPrec :: ReadPrec Integer # readListPrec :: ReadPrec [Integer] #
Integral Integer #	Since: base-2.0.1
Instance details Defined in GHC.Internal.Real Methods quot :: Integer -> Integer -> Integer # rem :: Integer -> Integer -> Integer # div :: Integer -> Integer -> Integer # mod :: Integer -> Integer -> Integer # quotRem :: Integer -> Integer -> (Integer, Integer) # divMod :: Integer -> Integer -> (Integer, Integer) # toInteger :: Integer -> Integer #
Real Integer #	Since: base-2.0.1
Instance details Defined in GHC.Internal.Real Methods toRational :: Integer -> Rational #
Show Integer #	Since: base-2.1
Instance details Defined in GHC.Internal.Show Methods showsPrec :: Int -> Integer -> ShowS # show :: Integer -> String # showList :: [Integer] -> ShowS #
Lift Integer #
Instance details Defined in GHC.Internal.TH.Lift Methods lift :: Quote m => Integer -> m Exp # liftTyped :: forall (m :: Type -> Type). Quote m => Integer -> Code m Integer #

Construct `Integer`s

smallInteger :: Int# -> Integer #

wordToInteger :: Word# -> Integer #

Conversion to other integral types

integerToWord :: Integer -> Word# #

integerToInt :: Integer -> Int# #

Helpers for `RealFloat` type-class operations

encodeFloatInteger :: Integer -> Int# -> Float# #

encodeDoubleInteger :: Integer -> Int# -> Double# #

decodeDoubleInteger :: Double# -> (# Integer, Int# #) #

Arithmetic operations

plusInteger :: Integer -> Integer -> Integer #

Used to implement (+) for the Num typeclass. This gives the sum of two integers.

Example

Expand

>>> plusInteger 3 2
5

>>> (+) 3 2
5

minusInteger :: Integer -> Integer -> Integer #

Used to implement (-) for the Num typeclass. This gives the difference of two integers.

Example

Expand

>>> minusInteger 3 2
1

>>> (-) 3 2
1

timesInteger :: Integer -> Integer -> Integer #

Used to implement (*) for the Num typeclass. This gives the product of two integers.

Example

Expand

>>> timesInteger 3 2
6

>>> (*) 3 2
6

negateInteger :: Integer -> Integer #

Used to implement negate for the Num typeclass. This changes the sign of whatever integer is passed into it.

Example

Expand

>>> negateInteger (-6)
6

>>> negate (-6)
6

absInteger :: Integer -> Integer #

Used to implement abs for the Num typeclass. This gives the absolute value of whatever integer is passed into it.

Example

Expand

>>> absInteger (-6)
6

>>> abs (-6)
6

signumInteger :: Integer -> Integer #

Used to implement signum for the Num typeclass. This gives 1 for a positive integer, and -1 for a negative integer.

Example

Expand

>>> signumInteger 5
1

>>> signum 5
1

divModInteger :: Integer -> Integer -> (# Integer, Integer #) #

Used to implement divMod for the Integral typeclass. This gives a tuple equivalent to

(div x y, mod x y)

Example

Expand

>>> divModInteger 10 2
(5,0)

>>> divMod 10 2
(5,0)

divInteger :: Integer -> Integer -> Integer #

Used to implement div for the Integral typeclass. This performs integer division on its two parameters, truncated towards negative infinity.

Example

Expand

>>> 10 `divInteger` 2
5

>>> 10 `div` 2

modInteger :: Integer -> Integer -> Integer #

Used to implement mod for the Integral typeclass. This performs the modulo operation, satisfying

((x `div` y) * y) + (x `mod` y) == x

Example

Expand

>>> 7 `modInteger` 3
1

>>> 7 `mod` 3
1

quotRemInteger :: Integer -> Integer -> (# Integer, Integer #) #

Used to implement quotRem for the Integral typeclass. This gives a tuple equivalent to

(quot x y, mod x y)

Example

Expand

>>> quotRemInteger 10 2
(5,0)

>>> quotRem 10 2
(5,0)

quotInteger :: Integer -> Integer -> Integer #

Used to implement quot for the Integral typeclass. This performs integer division on its two parameters, truncated towards zero.

Example

Expand

>>> quotInteger 10 2
5

>>> quot 10 2
5

remInteger :: Integer -> Integer -> Integer #

Used to implement rem for the Integral typeclass. This gives the remainder after integer division of its two parameters, satisfying

((x `quot` y) * y) + (x `rem` y) == x

Example

Expand

>>> remInteger 3 2
1

>>> rem 3 2
1

Comparison predicates

eqInteger :: Integer -> Integer -> Bool #

Used to implement (==) for the Eq typeclass. Outputs True if two integers are equal to each other.

Example

Expand

>>> 6 `eqInteger` 6
True

>>> 6 == 6
True

neqInteger :: Integer -> Integer -> Bool #

Used to implement (/=) for the Eq typeclass. Outputs True if two integers are not equal to each other.

Example

Expand

>>> 6 `neqInteger` 7
True

>>> 6 /= 7
True

leInteger :: Integer -> Integer -> Bool #

Used to implement (<=) for the Ord typeclass. Outputs True if the first argument is less than or equal to the second.

Example

Expand

>>> 3 `leInteger` 5
True

>>> 3 <= 5
True

gtInteger :: Integer -> Integer -> Bool #

Used to implement (>) for the Ord typeclass. Outputs True if the first argument is greater than the second.

Example

Expand

>>> 5 `gtInteger` 3
True

>>> 5 > 3
True

ltInteger :: Integer -> Integer -> Bool #

Used to implement (<) for the Ord typeclass. Outputs True if the first argument is less than the second.

Example

Expand

>>> 3 `ltInteger` 5
True

>>> 3 < 5
True

geInteger :: Integer -> Integer -> Bool #

Used to implement (>=) for the Ord typeclass. Outputs True if the first argument is greater than or equal to the second.

Example

Expand

>>> 5 `geInteger` 3
True

>>> 5 >= 3
True

compareInteger :: Integer -> Integer -> Ordering #

Used to implement compare for the Integral typeclass. This takes two integers, and outputs whether the first is less than, equal to, or greater than the second.