Copyright	(C) 2015 mniip
License	BSD3
Maintainer	mniip <mniip@mniip.com>
Stability	experimental
Portability	portable
Safe Haskell	Safe
Language	Haskell2010

Data.Finite

Description

Synopsis

Documentation

data Finite n Source #

Finite number type. Finite n is inhabited by exactly n values. Invariants:

getFinite x < natVal x

getFinite x >= 0

Instances

KnownNat n => Bounded (Finite n) Source #	Throws an error for `Finite 0`
Methods minBound :: Finite n # maxBound :: Finite n #
KnownNat n => Enum (Finite n) Source #
Methods succ :: Finite n -> Finite n # pred :: Finite n -> Finite n # toEnum :: Int -> Finite n # fromEnum :: Finite n -> Int # enumFrom :: Finite n -> [Finite n] # enumFromThen :: Finite n -> Finite n -> [Finite n] # enumFromTo :: Finite n -> Finite n -> [Finite n] # enumFromThenTo :: Finite n -> Finite n -> Finite n -> [Finite n] #
Eq (Finite n) Source #
Methods (==) :: Finite n -> Finite n -> Bool # (/=) :: Finite n -> Finite n -> Bool #
KnownNat n => Integral (Finite n) Source #
Methods quot :: Finite n -> Finite n -> Finite n # rem :: Finite n -> Finite n -> Finite n # div :: Finite n -> Finite n -> Finite n # mod :: Finite n -> Finite n -> Finite n # quotRem :: Finite n -> Finite n -> (Finite n, Finite n) # divMod :: Finite n -> Finite n -> (Finite n, Finite n) # toInteger :: Finite n -> Integer #
KnownNat n => Num (Finite n) Source #	Modulo arithmetic. Only the `fromInteger` function is supposed to be useful.
Methods (+) :: Finite n -> Finite n -> Finite n # (-) :: Finite n -> Finite n -> Finite n # (*) :: Finite n -> Finite n -> Finite n # negate :: Finite n -> Finite n # abs :: Finite n -> Finite n # signum :: Finite n -> Finite n # fromInteger :: Integer -> Finite n #
Ord (Finite n) Source #
Methods compare :: Finite n -> Finite n -> Ordering # (<) :: Finite n -> Finite n -> Bool # (<=) :: Finite n -> Finite n -> Bool # (>) :: Finite n -> Finite n -> Bool # (>=) :: Finite n -> Finite n -> Bool # max :: Finite n -> Finite n -> Finite n # min :: Finite n -> Finite n -> Finite n #
KnownNat n => Read (Finite n) Source #
Methods readsPrec :: Int -> ReadS (Finite n) # readList :: ReadS [Finite n] # readPrec :: ReadPrec (Finite n) # readListPrec :: ReadPrec [Finite n] #
KnownNat n => Real (Finite n) Source #
Methods toRational :: Finite n -> Rational #
Show (Finite n) Source #
Methods showsPrec :: Int -> Finite n -> ShowS # show :: Finite n -> String # showList :: [Finite n] -> ShowS #
Generic (Finite n) Source #
Associated Types type Rep (Finite n) :: * -> * # Methods from :: Finite n -> Rep (Finite n) x # to :: Rep (Finite n) x -> Finite n #
NFData (Finite n) Source #
Methods rnf :: Finite n -> () #
type Rep (Finite n) Source #
type Rep (Finite n) = D1 (MetaData "Finite" "Data.Finite.Internal" "finite-typelits-0.1.3.0-3IB9vwQKJS8RiaHvY0GBC" True) (C1 (MetaCons "Finite" PrefixI False) (S1 (MetaSel (Nothing Symbol) NoSourceUnpackedness NoSourceStrictness DecidedLazy) (Rec0 Integer)))

packFinite :: KnownNat n => Integer -> Maybe (Finite n) Source #

Convert an Integer into a Finite, returning Nothing if the input is out of bounds.

packFiniteProxy :: KnownNat n => proxy n -> Integer -> Maybe (Finite n) Source #

Same as packFinite but with a proxy argument to avoid type signatures.

finite :: KnownNat n => Integer -> Finite n Source #

Convert an Integer into a Finite, throwing an error if the input is out of bounds.

finiteProxy :: KnownNat n => proxy n -> Integer -> Finite n Source #

Same as finite but with a proxy argument to avoid type signatures.

getFinite :: Finite n -> Integer Source #

Convert a Finite into the corresponding Integer.

finites :: KnownNat n => [Finite n] Source #

Generate a list of length n of all elements of Finite n.

finitesProxy :: KnownNat n => proxy n -> [Finite n] Source #

Same as finites but with a proxy argument to avoid type signatures.

equals :: Finite n -> Finite m -> Bool infix 4 Source #

Test two different types of finite numbers for equality.

cmp :: Finite n -> Finite m -> Ordering Source #

Compare two different types of finite numbers.

natToFinite :: (KnownNat n, KnownNat m, (n + 1) <= m) => proxy n -> Finite m Source #

Convert a type-level literal into a Finite.

weaken :: Finite n -> Finite (n + 1) Source #

Add one inhabitant in the end.

strengthen :: KnownNat n => Finite (n + 1) -> Maybe (Finite n) Source #

Remove one inhabitant from the end. Returns Nothing if the input was the removed inhabitant.

shift :: Finite n -> Finite (n + 1) Source #

Add one inhabitant in the beginning, shifting everything up by one.

unshift :: Finite (n + 1) -> Maybe (Finite n) Source #

Remove one inhabitant from the beginning, shifting everything down by one. Returns Nothing if the input was the removed inhabitant.

weakenN :: n <= m => Finite n -> Finite m Source #

Add multiple inhabitants in the end.

strengthenN :: (KnownNat n, n <= m) => Finite m -> Maybe (Finite n) Source #

Remove multiple inhabitants from the end. Returns Nothing if the input was one of the removed inhabitants.

shiftN :: (KnownNat n, KnownNat m, n <= m) => Finite n -> Finite m Source #

Add multiple inhabitant in the beginning, shifting everything up by the amount of inhabitants added.

unshiftN :: (KnownNat n, KnownNat m, n <= m) => Finite m -> Maybe (Finite n) Source #

Remove multiple inhabitants from the beginning, shifting everything down by the amount of inhabitants removed. Returns Nothing if the input was one of the removed inhabitants.

weakenProxy :: proxy k -> Finite n -> Finite (n + k) Source #

strengthenProxy :: KnownNat n => proxy k -> Finite (n + k) -> Maybe (Finite n) Source #

shiftProxy :: KnownNat k => proxy k -> Finite n -> Finite (n + k) Source #

unshiftProxy :: KnownNat k => proxy k -> Finite (n + k) -> Maybe (Finite n) Source #

add :: Finite n -> Finite m -> Finite (n + m) Source #

Add two Finites.

sub :: Finite n -> Finite m -> Either (Finite m) (Finite n) Source #

Subtract two Finites. Returns Left for negative results, and Right for positive results. Note that this function never returns Left 0.

multiply :: Finite n -> Finite m -> Finite (n * m) Source #

Multiply two Finites.

combineSum :: KnownNat n => Either (Finite n) (Finite m) -> Finite (n + m) Source #

Left-biased (left values come first) disjoint union of finite sets.

combineProduct :: KnownNat n => (Finite n, Finite m) -> Finite (n * m) Source #

fst-biased (fst is the inner, and snd is the outer iteratee) product of finite sets.

separateSum :: KnownNat n => Finite (n + m) -> Either (Finite n) (Finite m) Source #

Take a Left-biased disjoint union apart.

separateProduct :: KnownNat n => Finite (n * m) -> (Finite n, Finite m) Source #

Take a fst-biased product apart.

isValidFinite :: KnownNat n => Finite n -> Bool Source #

Verifies that a given Finite is valid. Should always return True unles you bring the Data.Finite.Internal.Finite constructor into the scope, or use unsafeCoerce or other nasty hacks