{-| Copyright : (C) 2016 , University of Twente, 2017-2018, QBayLogic B.V., 2017 , Google Inc. License : BSD2 (see the file LICENSE) Maintainer : Christiaan Baaij <christiaan.baaij@gmail.com> Some \"magic\" classes and instances to get the "GHC.TypeLits.KnownNat.Solver" type checker plugin working. = Usage Let's say you defined a closed type family @Max@: @ import Data.Type.Bool (If) import GHC.TypeLits type family Max (a :: Nat) (b :: Nat) :: Nat where Max 0 b = b Max a b = If (a <=? b) b a @ if you then want the "GHC.TypeLits.KnownNat.Solver" to solve 'KnownNat' constraints over @Max@, given just 'KnownNat' constraints for the arguments of @Max@, then you must define: @ \{\-# LANGUAGE DataKinds, FlexibleInstances, GADTs, KindSignatures, MultiParamTypeClasses, ScopedTypeVariables, TemplateHaskell, TypeApplications, TypeFamilies, TypeOperators, UndecidableInstances \#-\} import Data.Proxy (Proxy (..)) import GHC.TypeLits.KnownNat instance (KnownNat a, KnownNat b) => 'KnownNat2' $('nameToSymbol' ''Max) a b where natSing2 = let x = natVal (Proxy @a) y = natVal (Proxy @b) z = max x y in 'SNatKn' z \{\-# INLINE natSing2 \#-\} @ = FAQ ==== 1. "GHC.TypeLits.KnownNat.Solver" does not seem to find the corresponding 'KnownNat2' instance for my type-level operation At the Core-level, GHCs internal mini-Haskell, type families that only have a single equation are treated like type synonyms. For example, let's say we defined a closed type family @Max@: @ import Data.Type.Bool (If) import GHC.TypeLits type family Max (a :: Nat) (b :: Nat) :: Nat where Max a b = If (a <=? b) b a @ Now, a Haskell-level program might contain a constraint @ KnownNat (Max a b) @ , however, at the Core-level, this constraint is expanded to: @ KnownNat (If (a <=? b) b a) @ "GHC.TypeLits.KnownNat.Solver" never sees any reference to the @Max@ type family, so it will not look for the corresponding 'KnownNat2' instance either. To fix this, ensure that your type-level operations always have at least two equations. For @Max@ this means we have to redefine it as: @ type family Max (a :: Nat) (b :: Nat) :: Nat where Max 0 b = b Max a b = If (a <=? b) b a @ -} {-# LANGUAGE AllowAmbiguousTypes #-} {-# LANGUAGE CPP #-} {-# LANGUAGE DataKinds #-} {-# LANGUAGE FlexibleInstances #-} {-# LANGUAGE GADTs #-} {-# LANGUAGE KindSignatures #-} {-# LANGUAGE MagicHash #-} {-# LANGUAGE MultiParamTypeClasses #-} {-# LANGUAGE PolyKinds #-} {-# LANGUAGE ScopedTypeVariables #-} {-# LANGUAGE TemplateHaskell #-} {-# LANGUAGE TypeApplications #-} {-# LANGUAGE TypeOperators #-} {-# LANGUAGE TypeFamilies #-} #if MIN_VERSION_ghc(8,6,0) {-# LANGUAGE NoStarIsType #-} #endif {-# LANGUAGE Trustworthy #-} {-# OPTIONS_GHC -Wno-unused-top-binds -fexpose-all-unfoldings #-} {-# OPTIONS_HADDOCK show-extensions #-} module GHC.TypeLits.KnownNat ( -- * Singleton natural number SNatKn (..) -- * Constraint-level arithmetic classes , KnownNat1 (..) , KnownNat2 (..) , KnownNat3 (..) -- * Singleton boolean , SBool (..) , boolVal -- * KnownBool , KnownBool (..) -- ** Constraint-level boolean functions , SBoolKb (..) , KnownNat2Bool (..) , KnownBoolNat2 (..) -- * Template Haskell helper , nameToSymbol ) where import Data.Bits (shiftL) import Data.Proxy (Proxy (..)) import Data.Type.Bool (If) import GHC.Prim (Proxy#) #if MIN_VERSION_ghc(8,2,0) import GHC.TypeNats (KnownNat, Nat, type (+), type (*), type (^), type (-), type (<=?), type (<=), natVal) #if MIN_VERSION_base(4,11,0) import GHC.TypeNats (Div, Mod) #endif import GHC.TypeLits (Symbol) import Numeric.Natural (Natural) #else import GHC.TypeLits (KnownNat, Nat, Symbol, type (+), type (*), type (^), type (-), type (<=?), type (<=), natVal) #endif import GHC.TypeLits.KnownNat.TH -- | Singleton natural number newtype SNatKn (f :: Symbol) = #if MIN_VERSION_ghc(8,2,0) SNatKn Natural #else SNatKn Integer #endif -- | Class for arithmetic functions with /one/ argument. -- -- The 'Symbol' /f/ must correspond to the fully qualified name of the -- type-level operation. Use 'nameToSymbol' to get the fully qualified -- TH Name as a 'Symbol' class KnownNat1 (f :: Symbol) (a :: Nat) where natSing1 :: SNatKn f -- | Class for arithmetic functions with /two/ arguments. -- -- The 'Symbol' /f/ must correspond to the fully qualified name of the -- type-level operation. Use 'nameToSymbol' to get the fully qualified -- TH Name as a 'Symbol' class KnownNat2 (f :: Symbol) (a :: Nat) (b :: Nat) where natSing2 :: SNatKn f -- | Class for arithmetic functions with /three/ arguments. -- -- The 'Symbol' /f/ must correspond to the fully qualified name of the -- type-level operation. Use 'nameToSymbol' to get the fully qualified -- TH Name as a 'Symbol' class KnownNat3 (f :: Symbol) (a :: Nat) (b :: Nat) (c :: Nat) where natSing3 :: SNatKn f -- | 'KnownNat2' instance for "GHC.TypeLits"' 'GHC.TypeLits.+' instance (KnownNat a, KnownNat b) => KnownNat2 $(nameToSymbol ''(+)) a b where natSing2 = SNatKn (natVal (Proxy @a) + natVal (Proxy @b)) {-# INLINE natSing2 #-} -- | 'KnownNat2' instance for "GHC.TypeLits"' 'GHC.TypeLits.*' instance (KnownNat a, KnownNat b) => KnownNat2 $(nameToSymbol ''(*)) a b where natSing2 = SNatKn (natVal (Proxy @a) * natVal (Proxy @b)) {-# INLINE natSing2 #-} -- | 'KnownNat2' instance for "GHC.TypeLits"' 'GHC.TypeLits.^' instance (KnownNat a, KnownNat b) => KnownNat2 $(nameToSymbol ''(^)) a b where natSing2 = let x = natVal (Proxy @a) y = natVal (Proxy @b) z = case x of 2 -> shiftL 1 (fromIntegral y) _ -> x ^ y in SNatKn z {-# INLINE natSing2 #-} -- | 'KnownNat2' instance for "GHC.TypeLits"' 'GHC.TypeLits.-' instance (KnownNat a, KnownNat b, b <= a) => KnownNat2 $(nameToSymbol ''(-)) a b where natSing2 = SNatKn (natVal (Proxy @a) - natVal (Proxy @b)) {-# INLINE natSing2 #-} #if MIN_VERSION_base(4,11,0) instance (KnownNat x, KnownNat y, 1 <= y) => KnownNat2 $(nameToSymbol ''Div) x y where natSing2 = SNatKn (quot (natVal (Proxy @x)) (natVal (Proxy @y))) instance (KnownNat x, KnownNat y, 1 <= y) => KnownNat2 $(nameToSymbol ''Mod) x y where natSing2 = SNatKn (rem (natVal (Proxy @x)) (natVal (Proxy @y))) #endif -- | Singleton version of 'Bool' data SBool (b :: Bool) where SFalse :: SBool 'False STrue :: SBool 'True class KnownBool (b :: Bool) where boolSing :: SBool b instance KnownBool 'False where boolSing = SFalse instance KnownBool 'True where boolSing = STrue -- | Get the 'Bool' value associated with a type-level 'Bool' -- -- Use 'boolVal' if you want to perform the standard boolean operations on the -- reified type-level 'Bool'. -- -- Use 'boolSing' if you need a context in which the type-checker needs the -- type-level 'Bool' to be either 'True' or 'False' -- -- @ -- f :: forall proxy b r . KnownBool b => r -- f = case boolSing @b of -- SFalse -> -- context with b ~ False -- STrue -> -- context with b ~ True -- @ boolVal :: forall b proxy . KnownBool b => proxy b -> Bool boolVal _ = case boolSing :: SBool b of SFalse -> False _ -> True -- | Get the `Bool` value associated with a type-level `Bool`. See also -- 'boolVal' and 'Proxy#'. boolVal' :: forall b . KnownBool b => Proxy# b -> Bool boolVal' _ = case boolSing :: SBool b of SFalse -> False _ -> True -- | A type "representationally equal" to 'SBool', used for simpler -- implementation of constraint-level functions that need to create instances of -- 'KnownBool' newtype SBoolKb (f :: Symbol) = SBoolKb Bool -- | Class for binary functions with a Boolean result. -- -- The 'Symbol' /f/ must correspond to the fully qualified name of the -- type-level operation. Use 'nameToSymbol' to get the fully qualified -- TH Name as a 'Symbol' class KnownBoolNat2 (f :: Symbol) (a :: k) (b :: k) where boolNatSing2 :: SBoolKb f instance (KnownNat a, KnownNat b) => KnownBoolNat2 $(nameToSymbol ''(<=?)) a b where boolNatSing2 = SBoolKb (natVal (Proxy @a) <= natVal (Proxy @b)) {-# INLINE boolNatSing2 #-} -- | Class for ternary functions with a Natural result. -- -- The 'Symbol' /f/ must correspond to the fully qualified name of the -- type-level operation. Use 'nameToSymbol' to get the fully qualified -- TH Name as a 'Symbol' class KnownNat2Bool (f :: Symbol) (a :: Bool) (b :: k) (c :: k) where natBoolSing3 :: SNatKn f instance (KnownBool a, KnownNat b, KnownNat c) => KnownNat2Bool $(nameToSymbol ''If) a b c where natBoolSing3 = SNatKn (if boolVal (Proxy @a) then natVal (Proxy @b) else natVal (Proxy @c))