{-# LANGUAGE FlexibleInstances #-} {-# LANGUAGE GeneralizedNewtypeDeriving #-} {-# LANGUAGE MultiParamTypeClasses #-} {-# LANGUAGE UndecidableInstances #-} module Polysemy.ConstraintAbsorber.MonadCont ( absorbCont ) where import Data.Coerce import qualified Control.Monad.Cont.Class as C import Polysemy import Polysemy.ConstraintAbsorber import Polysemy.Cont ------------------------------------------------------------------------------ -- | Introduce a local 'C.MonadCont' constraint on 'Sem' --- allowing it to -- interop nicely with MTL. -- -- @since 0.3.0.0 absorbCont :: Member (Cont ref) r => (C.MonadCont (Sem r) => Sem r a) -- ^ A computation that requires an instance of 'C.MonadCont' for -- 'Sem'. This might be something with type @'C.MonadCont' m => m a@. -> Sem r a absorbCont = absorbWithSem @C.MonadCont @Action (ContDict callCC) (Sub Dict) {-# INLINEABLE absorbCont #-} ------------------------------------------------------------------------------ -- | A dictionary of the functions we need to supply -- to make an instance of Cont newtype ContDict m = ContDict { callCC_ :: forall a b. ((a -> m b) -> m a) -> m a } ------------------------------------------------------------------------------ -- | Wrapper for a monadic action with phantom -- type parameter for reflection. -- Locally defined so that the instance we are going -- to build with reflection must be coherent, that is -- there cannot be orphans. newtype Action m s' a = Action (m a) deriving (Functor, Applicative, Monad) ------------------------------------------------------------------------------ -- | Given a reifiable mtl Cont dictionary, -- we can make an instance of @MonadCont@ for the action -- wrapped in @Action@. instance ( Monad m , Reifies s' (ContDict m) ) => C.MonadCont (Action m s') where callCC (cc :: (a -> Action m s' b) -> Action m s' a) = Action $ callCC_ (reflect $ Proxy @s') @a @b (coerce cc) {-# INLINEABLE callCC #-}