{-# LANGUAGE Rank2Types, FlexibleInstances, FlexibleContexts, TypeOperators, CPP #-} #if __GLASGOW_HASKELL__ >= 707 {-# LANGUAGE DeriveDataTypeable #-} #endif ----------------------------------------------------------------------------- -- | -- Module : Control.Object -- Copyright : (c) Fumiaki Kinoshita 2014 -- License : BSD3 -- -- Maintainer : Fumiaki Kinoshita -- Stability : experimental -- Portability : non-portable -- -- Stateful effect transducer: The Mealy machine for effects. -- ----------------------------------------------------------------------------- module Control.Object ( -- * Construction Object(..), liftO, echo, oneshot, stateful, variable, -- * Composition (.>>.), transObject, adaptObject, -- * Extensible objects loner, (.|>.), sharing ) where import Control.Monad.Trans.State.Strict import Control.Monad import Data.Typeable import Control.Applicative import Data.OpenUnion1.Clean -- | The type 'Object e m' represents objects which can handle messages @e@, perform actions in the environment @m@. -- It can be thought of as an automaton that converts effects. -- 'Object's can be composed just like functions using '.>>.'; the identity element is 'echo'. newtype Object e m = Object { runObject :: forall x. e x -> m (x, Object e m) } #if __GLASGOW_HASKELL__ >= 707 deriving (Typeable) #else instance (Typeable1 f, Typeable1 m) => Typeable (Object f m) where typeOf t = mkTyConApp objectTyCon [typeOf1 (f t), typeOf1 (g t)] where f :: Object f m -> f a f = undefined g :: Object f m -> m a g = undefined objectTyCon :: TyCon #if __GLASGOW_HASKELL__ < 704 objectTyCon = mkTyCon "Control.Object.Object" #else objectTyCon = mkTyCon3 "object" "Control.Object" "Object" #endif {-# NOINLINE objectTyCon #-} #endif -- | Lift a natural transformation into an object. liftO :: Functor f => (forall x. e x -> f x) -> Object e f liftO f = Object $ fmap (\x -> (x, liftO f)) . f -- | Change the workspace of the object. transObject :: Functor g => (forall x. f x -> g x) -> Object e f -> Object e g transObject f (Object m) = Object $ fmap (fmap (transObject f)) . f . m -- | Apply a function to the messages coming into the object. adaptObject :: Functor m => (forall x. e x -> f x) -> Object f m -> Object e m adaptObject f (Object m) = Object $ fmap (fmap (adaptObject f)) . m . f -- | Parrots messages given. echo :: Functor e => Object e e echo = Object (fmap (\x -> (x, echo))) -- | Compose two objects (aka Dependency Injection). (.>>.) :: Functor n => Object e m -> Object m n -> Object e n Object m .>>. Object n = Object $ \e -> fmap (\((x, m'), n') -> (x, m' .>>. n')) $ n (m e) infixr 4 .>>. -- | Build an object using continuation passing style. oneshot :: (Functor e, Monad m) => (forall a. e (m a) -> m a) -> Object e m oneshot m = go where go = Object $ \e -> m (fmap return e) >>= \a -> return (a, go) {-# INLINE oneshot #-} -- | Build a stateful object. stateful :: Monad m => (forall a. e a -> StateT s m a) -> s -> Object e m stateful h = go where go s = Object $ liftM (\(a, s') -> (a, go s')) . flip runStateT s . h {-# INLINE stateful #-} -- | A mutable variable. variable :: Applicative f => s -> Object (State s) f variable s = Object $ \m -> let (a, s') = runState m s in pure (a, variable s') -- | Build a stateful object, sharing out the state. sharing :: Monad m => (forall a. e a -> StateT s m a) -> s -> Object (State s |> e |> Nil) m sharing m = go where go s = Object $ \k -> liftM (fmap go) $ ($k) $ (\n -> return $ runState n s) ||> (\e -> runStateT (m e) s) ||> exhaust {-# INLINE sharing #-} -- | An object that won't accept any messages. loner :: Functor m => Object Nil m loner = liftO exhaust -- | Extend an object by adding another independent object. (.|>.) :: Functor m => Object f m -> Object (Union s) m -> Object (f |> Union s) m p .|>. q = Object $ fmap (fmap (.|>.q)) . runObject p ||> fmap (fmap (p .|>.)) . runObject q infixr 3 .|>.