{-# LANGUAGE Trustworthy #-} {-# LANGUAGE DataKinds #-} {-# LANGUAGE TypeFamilies #-} {-# LANGUAGE TypeOperators #-} {-# LANGUAGE NoStarIsType #-} {-# LANGUAGE FlexibleInstances #-} {-# LANGUAGE FlexibleContexts #-} {-# LANGUAGE ScopedTypeVariables #-} {-# LANGUAGE ConstraintKinds #-} {-# LANGUAGE ExistentialQuantification #-} {-# LANGUAGE RankNTypes #-} {-# LANGUAGE NoImplicitPrelude #-} {-# LANGUAGE MagicHash #-} {-# LANGUAGE PolyKinds #-} {-# LANGUAGE TypeApplications #-} {-| This module is an internal GHC module. It declares the constants used in the implementation of type-level natural numbers. The programmer interface for working with type-level naturals should be defined in a separate library. @since 4.10.0.0 -} module GHC.TypeNats ( -- * Nat Kind Natural -- declared in GHC.Num.Natural in package ghc-bignum , Nat -- * Linking type and value level , KnownNat, natVal, natVal' , SomeNat(..) , someNatVal , sameNat -- * Functions on type literals , type (<=), type (<=?), type (+), type (*), type (^), type (-) , CmpNat , cmpNat , Div, Mod, Log2 ) where import GHC.Base(Eq(..), Ord(..), otherwise, withDict) import GHC.Types import GHC.Num.Natural(Natural) import GHC.Show(Show(..)) import GHC.Read(Read(..)) import GHC.Prim(Proxy#) import Data.Maybe(Maybe(..)) import Data.Proxy (Proxy(..)) import Data.Type.Equality((:~:)(Refl)) import Data.Type.Ord(OrderingI(..), type (<=), type (<=?)) import Unsafe.Coerce(unsafeCoerce) import GHC.TypeNats.Internal(CmpNat) -- | A type synonym for 'Natural'. -- -- Prevously, this was an opaque data type, but it was changed to a type synonym -- @since @base-4.15.0.0@. type Nat = Natural -------------------------------------------------------------------------------- -- | This class gives the integer associated with a type-level natural. -- There are instances of the class for every concrete literal: 0, 1, 2, etc. -- -- @since 4.7.0.0 class KnownNat (n :: Nat) where natSing :: SNat n -- | @since 4.10.0.0 natVal :: forall n proxy. KnownNat n => proxy n -> Natural natVal _ = case natSing :: SNat n of SNat x -> x -- | @since 4.10.0.0 natVal' :: forall n. KnownNat n => Proxy# n -> Natural natVal' _ = case natSing :: SNat n of SNat x -> x -- | This type represents unknown type-level natural numbers. -- -- @since 4.10.0.0 data SomeNat = forall n. KnownNat n => SomeNat (Proxy n) -- | Convert an integer into an unknown type-level natural. -- -- @since 4.10.0.0 someNatVal :: Natural -> SomeNat someNatVal n = withSNat SomeNat (SNat n) Proxy {-# NOINLINE someNatVal #-} -- See Note [NOINLINE someNatVal] {- Note [NOINLINE someNatVal] `someNatVal` converts a natural number to an existentially quantified dictionary for `KnownNat` (aka `SomeNat`). The existential quantification is very important, as it captures the fact that we don't know the type statically, although we do know that it exists. Because this type is fully opaque, we should never be able to prove that it matches anything else. This is why coherence should still hold: we can manufacture a `KnownNat k` dictionary, but it can never be confused with a `KnownNat 33` dictionary, because we should never be able to prove that `k ~ 33`. But how to implement `someNatVal`? We can't quite implement it "honestly" because `SomeNat` needs to "hide" the type of the newly created dictionary, but we don't know what the actual type is! If `someNatVal` was built into the language, then we could manufacture a new skolem constant, which should behave correctly. Since extra language constructors have additional maintenance costs, we use a trick to implement `someNatVal` in the library. The idea is that instead of generating a "fresh" type for each use of `someNatVal`, we simply use GHC's placeholder type `Any` (of kind `Nat`). So, the elaborated version of the code is: someNatVal n = withSNat @T (SomeNat @T) (SNat @T n) (Proxy @T) where type T = Any Nat After inlining and simplification, this ends up looking something like this: someNatVal n = SomeNat @T (KnownNat @T (SNat @T n)) (Proxy @T) where type T = Any Nat `KnownNat` is the constructor for dictionaries for the class `KnownNat`. See Note [withDict] in "GHC.HsToCore.Expr" for details on how we actually construct the dictionary. Note that using `Any Nat` is not really correct, as multilple calls to `someNatVal` would violate coherence: type T = Any Nat x = SomeNat @T (KnownNat @T (SNat @T 1)) (Proxy @T) y = SomeNat @T (KnownNat @T (SNat @T 2)) (Proxy @T) Note that now the code has two dictionaries with the same type, `KnownNat Any`, but they have different implementations, namely `SNat 1` and `SNat 2`. This is not good, as GHC assumes coherence, and it is free to interchange dictionaries of the same type, but in this case this would produce an incorrect result. See #16586 for examples of this happening. We can avoid this problem by making the definition of `someNatVal` opaque and we do this by using a `NOINLINE` pragma. This restores coherence, because GHC can only inspect the result of `someNatVal` by pattern matching on the existential, which would generate a new type. This restores correctness, at the cost of having a little more allocation for the `SomeNat` constructors. -} -- | @since 4.7.0.0 instance Eq SomeNat where SomeNat x == SomeNat y = natVal x == natVal y -- | @since 4.7.0.0 instance Ord SomeNat where compare (SomeNat x) (SomeNat y) = compare (natVal x) (natVal y) -- | @since 4.7.0.0 instance Show SomeNat where showsPrec p (SomeNat x) = showsPrec p (natVal x) -- | @since 4.7.0.0 instance Read SomeNat where readsPrec p xs = do (a,ys) <- readsPrec p xs [(someNatVal a, ys)] -------------------------------------------------------------------------------- infixl 6 +, - infixl 7 *, `Div`, `Mod` infixr 8 ^ -- | Addition of type-level naturals. -- -- @since 4.7.0.0 type family (m :: Nat) + (n :: Nat) :: Nat -- | Multiplication of type-level naturals. -- -- @since 4.7.0.0 type family (m :: Nat) * (n :: Nat) :: Nat -- | Exponentiation of type-level naturals. -- -- @since 4.7.0.0 type family (m :: Nat) ^ (n :: Nat) :: Nat -- | Subtraction of type-level naturals. -- -- @since 4.7.0.0 type family (m :: Nat) - (n :: Nat) :: Nat -- | Division (round down) of natural numbers. -- @Div x 0@ is undefined (i.e., it cannot be reduced). -- -- @since 4.11.0.0 type family Div (m :: Nat) (n :: Nat) :: Nat -- | Modulus of natural numbers. -- @Mod x 0@ is undefined (i.e., it cannot be reduced). -- -- @since 4.11.0.0 type family Mod (m :: Nat) (n :: Nat) :: Nat -- | Log base 2 (round down) of natural numbers. -- @Log 0@ is undefined (i.e., it cannot be reduced). -- -- @since 4.11.0.0 type family Log2 (m :: Nat) :: Nat -------------------------------------------------------------------------------- -- | We either get evidence that this function was instantiated with the -- same type-level numbers, or 'Nothing'. -- -- @since 4.7.0.0 sameNat :: (KnownNat a, KnownNat b) => proxy1 a -> proxy2 b -> Maybe (a :~: b) sameNat x y | natVal x == natVal y = Just (unsafeCoerce Refl) | otherwise = Nothing -- | Like 'sameNat', but if the numbers aren't equal, this additionally -- provides proof of LT or GT. -- @since 4.16.0.0 cmpNat :: forall a b proxy1 proxy2. (KnownNat a, KnownNat b) => proxy1 a -> proxy2 b -> OrderingI a b cmpNat x y = case compare (natVal x) (natVal y) of EQ -> case unsafeCoerce (Refl, Refl) :: (CmpNat a b :~: 'EQ, a :~: b) of (Refl, Refl) -> EQI LT -> case unsafeCoerce Refl :: (CmpNat a b :~: 'LT) of Refl -> LTI GT -> case unsafeCoerce Refl :: (CmpNat a b :~: 'GT) of Refl -> GTI -------------------------------------------------------------------------------- -- PRIVATE: newtype SNat (n :: Nat) = SNat Natural -- See Note [withDict] in "GHC.HsToCore.Expr" in GHC withSNat :: forall a b. (KnownNat a => Proxy a -> b) -> SNat a -> Proxy a -> b withSNat f x y = withDict @(SNat a) @(KnownNat a) x f y