{-# LANGUAGE CPP #-}
{-# LANGUAGE TypeFamilies #-}
{-# LANGUAGE MultiParamTypeClasses #-}
#ifndef MIN_VERSION_profunctors
#define MIN_VERSION_profunctors(x,y,z) 0
#endif
module Data.Machine.Moore
( Moore(..)
, logMoore
, unfoldMoore
) where
import Control.Applicative
import Control.Comonad
import Control.Monad.Fix
import Control.Monad.Reader.Class
import Control.Monad.Zip
import Data.Copointed
import Data.Distributive
import Data.Functor.Rep as Functor
import Data.Machine.Plan
import Data.Machine.Type
import Data.Machine.Process
import Data.Semigroup
import Data.Pointed
import Data.Profunctor.Closed
import Data.Profunctor
import Data.Profunctor.Sieve
import Data.Profunctor.Rep as Profunctor
import Prelude
data Moore a b = Moore b (a -> Moore a b)
logMoore :: Monoid m => Moore m m
logMoore = h mempty where
h m = Moore m (\a -> h (m `mappend` a))
{-# INLINE logMoore #-}
unfoldMoore :: (s -> (b, a -> s)) -> s -> Moore a b
unfoldMoore f = go where
go s = case f s of
(b, g) -> Moore b (go . g)
{-# INLINE unfoldMoore #-}
instance Automaton Moore where
auto = construct . go where
go (Moore b f) = do
yield b
await >>= go . f
{-# INLINE auto #-}
instance Functor (Moore a) where
fmap f (Moore b g) = Moore (f b) (fmap f . g)
{-# INLINE fmap #-}
a <$ _ = return a
{-# INLINE (<$) #-}
instance Profunctor Moore where
rmap = fmap
{-# INLINE rmap #-}
lmap f = go where
go (Moore b g) = Moore b (go . g . f)
{-# INLINE lmap #-}
#if MIN_VERSION_profunctors(3,1,1)
dimap f g = go where
go (Moore b h) = Moore (g b) (go . h . f)
{-# INLINE dimap #-}
#endif
instance Applicative (Moore a) where
pure a = r where r = Moore a (const r)
{-# INLINE pure #-}
Moore f ff <*> Moore a fa = Moore (f a) (\i -> ff i <*> fa i)
m <* _ = m
{-# INLINE (<*) #-}
_ *> n = n
{-# INLINE (*>) #-}
instance Pointed (Moore a) where
point a = r where r = Moore a (const r)
{-# INLINE point #-}
instance Monad (Moore a) where
return = pure
{-# INLINE return #-}
k >>= f = j (fmap f k) where
j (Moore a g) = Moore (extract a) (\x -> j $ fmap (\(Moore _ h) -> h x) (g x))
(>>) = (*>)
instance Copointed (Moore a) where
copoint (Moore b _) = b
{-# INLINE copoint #-}
instance Comonad (Moore a) where
extract (Moore b _) = b
{-# INLINE extract #-}
extend f w@(Moore _ g) = Moore (f w) (extend f . g)
instance ComonadApply (Moore a) where
Moore f ff <@> Moore a fa = Moore (f a) (\i -> ff i <@> fa i)
m <@ _ = m
{-# INLINE (<@) #-}
_ @> n = n
{-# INLINE (@>) #-}
instance Distributive (Moore a) where
distribute m = Moore (fmap extract m) (distribute . collect (\(Moore _ k) -> k) m)
instance Functor.Representable (Moore a) where
type Rep (Moore a) = [a]
index = cosieve
tabulate = cotabulate
{-# INLINE tabulate #-}
instance Cosieve Moore [] where
cosieve (Moore b _) [] = b
cosieve (Moore _ k) (a:as) = cosieve (k a) as
instance Costrong Moore where
unfirst = unfirstCorep
unsecond = unsecondCorep
instance Profunctor.Corepresentable Moore where
type Corep Moore = []
cotabulate f0 = go (f0 . reverse) where
go f = Moore (f []) $ \a -> go (f.(a:))
instance MonadFix (Moore a) where
mfix = mfixRep
instance MonadZip (Moore a) where
mzipWith = mzipWithRep
munzip m = (fmap fst m, fmap snd m)
instance MonadReader [a] (Moore a) where
ask = askRep
local = localRep
instance Closed Moore where
closed m = cotabulate $ \fs x -> cosieve m (fmap ($x) fs)
instance Semigroup b => Semigroup (Moore a b) where
Moore x f <> Moore y g = Moore (x <> y) (f <> g)
instance Monoid b => Monoid (Moore a b) where
mempty = Moore mempty mempty
#if !(MIN_VERSION_base(4,11,0))
Moore x f `mappend` Moore y g = Moore (x `mappend` y) (f `mappend` g)
#endif