{-# LANGUAGE Rank2Types #-} {-# LANGUAGE FlexibleInstances #-} {-# LANGUAGE UndecidableInstances #-} {-# LANGUAGE MultiParamTypeClasses #-} ----------------------------------------------------------------------------- -- | -- Module : Control.Monad.Free.Church -- Copyright : (C) 2011-2012 Edward Kmett -- License : BSD-style (see the file LICENSE) -- -- Maintainer : Edward Kmett <ekmett@gmail.com> -- Stability : provisional -- Portability : non-portable (rank-2 polymorphism) -- -- \"Free Monads for Less\" -- -- The most straightforward way of implementing free monads is as a recursive -- datatype that allows for arbitrarily deep nesting of the base functor. This is -- akin to a tree, with the leaves containing the values, and the nodes being a -- level of 'Functor' over subtrees. -- -- For each time that the `fmap` or `>>=` operations is used, the old tree is -- traversed up to the leaves, a new set of nodes is allocated, and -- the old ones are garbage collected. Even if the Haskell runtime -- optimizes some of the overhead through laziness and generational garbage -- collection, the asymptotic runtime is still quadratic. -- -- On the other hand, if the Church encoding is used, the tree only needs to be -- constructed once, because: -- -- * All uses of `fmap` are collapsed into a single one, so that the values on the -- _leaves_ are transformed in one pass. -- -- prop> fmap f . fmap g == fmap (f . g) -- -- * All uses of `>>=` are right associated, so that every new subtree created -- is final. -- -- prop> (m >>= f) >>= g == m >>= (\x -> f x >>= g) -- -- Asymptotically, the Church encoding supports the monadic operations more -- efficiently than the naïve 'Free'. -- -- This is based on the \"Free Monads for Less\" series of articles by Edward Kmett: -- -- * <http://comonad.com/reader/2011/free-monads-for-less/ Free monads for less — Part 1> -- -- * <http://comonad.com/reader/2011/free-monads-for-less-2/ Free monads for less — Part 2> ---------------------------------------------------------------------------- module Control.Monad.Free.Church ( F(..) , improve , fromF , iterM , toF , retract , MonadFree(..) , liftF ) where import Control.Applicative import Control.Monad as Monad import Control.Monad.Fix import Control.Monad.Free hiding (retract, iterM) import Control.Monad.Reader.Class import Control.Monad.Writer.Class import Control.Monad.Cont.Class import Control.Monad.Trans.Class import Control.Monad.State.Class import Data.Functor.Bind -- | The Church-encoded free monad for a functor @f@. -- -- It is /asymptotically/ more efficient to use ('>>=') for 'F' than it is to ('>>=') with 'Free'. -- -- <http://comonad.com/reader/2011/free-monads-for-less-2/> newtype F f a = F { runF :: forall r. (a -> r) -> (f r -> r) -> r } -- | Like iter for monadic values. iterM :: (Monad m, Functor f) => (f (m a) -> m a) -> F f a -> m a iterM phi xs = runF xs return phi instance Functor (F f) where fmap f (F g) = F (\kp -> g (kp . f)) instance Apply (F f) where (<.>) = (<*>) instance Applicative (F f) where pure a = F (\kp _ -> kp a) F f <*> F g = F (\kp kf -> f (\a -> g (kp . a) kf) kf) instance Alternative f => Alternative (F f) where empty = F (\_ kf -> kf empty) F f <|> F g = F (\kp kf -> kf (pure (f kp kf) <|> pure (g kp kf))) instance Bind (F f) where (>>-) = (>>=) instance Monad (F f) where return a = F (\kp _ -> kp a) F m >>= f = F (\kp kf -> m (\a -> runF (f a) kp kf) kf) instance MonadFix (F f) where mfix f = a where a = f (impure a) impure (F x) = x id (error "MonadFix (F f): wrap") instance MonadPlus f => MonadPlus (F f) where mzero = F (\_ kf -> kf mzero) F f `mplus` F g = F (\kp kf -> kf (return (f kp kf) `mplus` return (g kp kf))) instance MonadTrans F where lift f = F (\kp kf -> kf (liftM kp f)) instance Functor f => MonadFree f (F f) where wrap f = F (\kp kf -> kf (fmap (\ (F m) -> m kp kf) f)) instance MonadState s m => MonadState s (F m) where get = lift get put = lift . put instance MonadReader e m => MonadReader e (F m) where ask = lift ask local f = lift . local f . retract instance MonadWriter w m => MonadWriter w (F m) where tell = lift . tell pass = lift . pass . retract listen = lift . listen . retract instance MonadCont m => MonadCont (F m) where callCC f = lift $ callCC (retract . f . fmap lift) -- | -- 'retract' is the left inverse of 'lift' and 'liftF' -- -- @ -- 'retract' . 'lift' = 'id' -- 'retract' . 'liftF' = 'id' -- @ retract :: Monad m => F m a -> m a retract (F m) = m return Monad.join {-# INLINE retract #-} -- | Convert to another free monad representation. fromF :: MonadFree f m => F f a -> m a fromF (F m) = m return wrap {-# INLINE fromF #-} -- | Generate a Church-encoded free monad from a 'Free' monad. toF :: Functor f => Free f a -> F f a toF xs = F (\kp kf -> go kp kf xs) where go kp _ (Pure a) = kp a go kp kf (Free fma) = kf (fmap (go kp kf) fma) -- | Improve the asymptotic performance of code that builds a free monad with only binds and returns by using 'F' behind the scenes. -- -- This is based on the \"Free Monads for Less\" series of articles by Edward Kmett: -- -- * <http://comonad.com/reader/2011/free-monads-for-less/ Free monads for less — Part 1> -- -- * <http://comonad.com/reader/2011/free-monads-for-less-2/ Free monads for less — Part 2> -- -- and <http://www.iai.uni-bonn.de/~jv/mpc08.pdf \"Asymptotic Improvement of Computations over Free Monads\"> by Janis Voightländer. improve :: Functor f => (forall m. MonadFree f m => m a) -> Free f a improve m = fromF m {-# INLINE improve #-}