{-# LANGUAGE CPP #-} #if __GLASGOW_HASKELL__ >= 702 {-# LANGUAGE Safe #-} #endif #if __GLASGOW_HASKELL__ >= 706 {-# LANGUAGE PolyKinds #-} #endif #if __GLASGOW_HASKELL__ >= 710 {-# LANGUAGE AutoDeriveTypeable #-} #endif ----------------------------------------------------------------------------- -- | -- Module : Control.Monad.Trans.Cont -- Copyright : (c) The University of Glasgow 2001 -- License : BSD-style (see the file LICENSE) -- -- Maintainer : R.Paterson@city.ac.uk -- Stability : experimental -- Portability : portable -- -- Continuation monads. -- -- Delimited continuation operators are taken from Kenichi Asai and Oleg -- Kiselyov's tutorial at CW 2011, \"Introduction to programming with -- shift and reset\" (<http://okmij.org/ftp/continuations/#tutorial>). -- ----------------------------------------------------------------------------- module Control.Monad.Trans.Cont ( -- * The Cont monad Cont, cont, runCont, evalCont, mapCont, withCont, -- ** Delimited continuations reset, shift, -- * The ContT monad transformer ContT(..), evalContT, mapContT, withContT, callCC, -- ** Delimited continuations resetT, shiftT, -- * Lifting other operations liftLocal, ) where import Control.Monad.IO.Class import Control.Monad.Trans.Class import Data.Functor.Identity import Control.Applicative #if MIN_VERSION_base(4,9,0) import qualified Control.Monad.Fail as Fail #endif {- | Continuation monad. @Cont r a@ is a CPS ("continuation-passing style") computation that produces an intermediate result of type @a@ within a CPS computation whose final result type is @r@. The @return@ function simply creates a continuation which passes the value on. The @>>=@ operator adds the bound function into the continuation chain. -} type Cont r = ContT r Identity -- | Construct a continuation-passing computation from a function. -- (The inverse of 'runCont') cont :: ((a -> r) -> r) -> Cont r a cont f = ContT (\ c -> Identity (f (runIdentity . c))) {-# INLINE cont #-} -- | The result of running a CPS computation with a given final continuation. -- (The inverse of 'cont') runCont :: Cont r a -- ^ continuation computation (@Cont@). -> (a -> r) -- ^ the final continuation, which produces -- the final result (often 'id'). -> r runCont m k = runIdentity (runContT m (Identity . k)) {-# INLINE runCont #-} -- | The result of running a CPS computation with the identity as the -- final continuation. -- -- * @'evalCont' ('return' x) = x@ evalCont :: Cont r r -> r evalCont m = runIdentity (evalContT m) {-# INLINE evalCont #-} -- | Apply a function to transform the result of a continuation-passing -- computation. -- -- * @'runCont' ('mapCont' f m) = f . 'runCont' m@ mapCont :: (r -> r) -> Cont r a -> Cont r a mapCont f = mapContT (Identity . f . runIdentity) {-# INLINE mapCont #-} -- | Apply a function to transform the continuation passed to a CPS -- computation. -- -- * @'runCont' ('withCont' f m) = 'runCont' m . f@ withCont :: ((b -> r) -> (a -> r)) -> Cont r a -> Cont r b withCont f = withContT ((Identity .) . f . (runIdentity .)) {-# INLINE withCont #-} -- | @'reset' m@ delimits the continuation of any 'shift' inside @m@. -- -- * @'reset' ('return' m) = 'return' m@ -- reset :: Cont r r -> Cont r' r reset = resetT {-# INLINE reset #-} -- | @'shift' f@ captures the continuation up to the nearest enclosing -- 'reset' and passes it to @f@: -- -- * @'reset' ('shift' f >>= k) = 'reset' (f ('evalCont' . k))@ -- shift :: ((a -> r) -> Cont r r) -> Cont r a shift f = shiftT (f . (runIdentity .)) {-# INLINE shift #-} -- | The continuation monad transformer. -- Can be used to add continuation handling to any type constructor: -- the 'Monad' instance and most of the operations do not require @m@ -- to be a monad. -- -- 'ContT' is not a functor on the category of monads, and many operations -- cannot be lifted through it. newtype ContT r m a = ContT { runContT :: (a -> m r) -> m r } -- | The result of running a CPS computation with 'return' as the -- final continuation. -- -- * @'evalContT' ('lift' m) = m@ evalContT :: (Monad m) => ContT r m r -> m r evalContT m = runContT m return {-# INLINE evalContT #-} -- | Apply a function to transform the result of a continuation-passing -- computation. This has a more restricted type than the @map@ operations -- for other monad transformers, because 'ContT' does not define a functor -- in the category of monads. -- -- * @'runContT' ('mapContT' f m) = f . 'runContT' m@ mapContT :: (m r -> m r) -> ContT r m a -> ContT r m a mapContT f m = ContT $ f . runContT m {-# INLINE mapContT #-} -- | Apply a function to transform the continuation passed to a CPS -- computation. -- -- * @'runContT' ('withContT' f m) = 'runContT' m . f@ withContT :: ((b -> m r) -> (a -> m r)) -> ContT r m a -> ContT r m b withContT f m = ContT $ runContT m . f {-# INLINE withContT #-} instance Functor (ContT r m) where fmap f m = ContT $ \ c -> runContT m (c . f) {-# INLINE fmap #-} instance Applicative (ContT r m) where pure x = ContT ($ x) {-# INLINE pure #-} f <*> v = ContT $ \ c -> runContT f $ \ g -> runContT v (c . g) {-# INLINE (<*>) #-} m *> k = m >>= \_ -> k {-# INLINE (*>) #-} instance Monad (ContT r m) where #if !(MIN_VERSION_base(4,8,0)) return x = ContT ($ x) {-# INLINE return #-} #endif m >>= k = ContT $ \ c -> runContT m (\ x -> runContT (k x) c) {-# INLINE (>>=) #-} #if MIN_VERSION_base(4,9,0) instance (Fail.MonadFail m) => Fail.MonadFail (ContT r m) where fail msg = ContT $ \ _ -> Fail.fail msg {-# INLINE fail #-} #endif instance MonadTrans (ContT r) where lift m = ContT (m >>=) {-# INLINE lift #-} instance (MonadIO m) => MonadIO (ContT r m) where liftIO = lift . liftIO {-# INLINE liftIO #-} -- | @callCC@ (call-with-current-continuation) calls its argument -- function, passing it the current continuation. It provides -- an escape continuation mechanism for use with continuation -- monads. Escape continuations one allow to abort the current -- computation and return a value immediately. They achieve -- a similar effect to 'Control.Monad.Trans.Except.throwE' -- and 'Control.Monad.Trans.Except.catchE' within an -- 'Control.Monad.Trans.Except.ExceptT' monad. The advantage of this -- function over calling 'return' is that it makes the continuation -- explicit, allowing more flexibility and better control. -- -- The standard idiom used with @callCC@ is to provide a lambda-expression -- to name the continuation. Then calling the named continuation anywhere -- within its scope will escape from the computation, even if it is many -- layers deep within nested computations. callCC :: ((a -> ContT r m b) -> ContT r m a) -> ContT r m a callCC f = ContT $ \ c -> runContT (f (\ x -> ContT $ \ _ -> c x)) c {-# INLINE callCC #-} -- | @'resetT' m@ delimits the continuation of any 'shiftT' inside @m@. -- -- * @'resetT' ('lift' m) = 'lift' m@ -- resetT :: (Monad m) => ContT r m r -> ContT r' m r resetT = lift . evalContT {-# INLINE resetT #-} -- | @'shiftT' f@ captures the continuation up to the nearest enclosing -- 'resetT' and passes it to @f@: -- -- * @'resetT' ('shiftT' f >>= k) = 'resetT' (f ('evalContT' . k))@ -- shiftT :: (Monad m) => ((a -> m r) -> ContT r m r) -> ContT r m a shiftT f = ContT (evalContT . f) {-# INLINE shiftT #-} -- | @'liftLocal' ask local@ yields a @local@ function for @'ContT' r m@. liftLocal :: (Monad m) => m r' -> ((r' -> r') -> m r -> m r) -> (r' -> r') -> ContT r m a -> ContT r m a liftLocal ask local f m = ContT $ \ c -> do r <- ask local f (runContT m (local (const r) . c)) {-# INLINE liftLocal #-}