module Data.Conduit.Internal
(
Pipe (..)
, ConduitM (..)
, Source
, Producer
, Sink
, Consumer
, Conduit
, ResumableSource (..)
, await
, awaitE
, awaitForever
, yield
, yieldOr
, leftover
, bracketP
, addCleanup
, idP
, pipe
, pipeL
, connectResume
, runPipe
, injectLeftovers
, (>+>)
, (<+<)
, sourceToPipe
, sinkToPipe
, conduitToPipe
, toProducer
, toConsumer
, transPipe
, mapOutput
, mapOutputMaybe
, mapInput
, sourceList
, withUpstream
, unwrapResumable
) where
import Control.Applicative (Applicative (..))
import Control.Monad ((>=>), liftM, ap, when)
import Control.Monad.Error.Class(MonadError(..))
import Control.Monad.Reader.Class(MonadReader(..))
import Control.Monad.RWS.Class(MonadRWS())
import Control.Monad.Writer.Class(MonadWriter(..))
import Control.Monad.State.Class(MonadState(..))
import Control.Monad.Trans.Class (MonadTrans (lift))
import Control.Monad.IO.Class (MonadIO (liftIO))
import Control.Monad.Base (MonadBase (liftBase))
import Data.Void (Void, absurd)
import Data.Monoid (Monoid (mappend, mempty))
import Control.Monad.Trans.Resource
import qualified GHC.Exts
import qualified Data.IORef as I
import Control.Monad.Morph (MFunctor (..))
data Pipe l i o u m r =
HaveOutput (Pipe l i o u m r) (m ()) o
| NeedInput (i -> Pipe l i o u m r) (u -> Pipe l i o u m r)
| Done r
| PipeM (m (Pipe l i o u m r))
| Leftover (Pipe l i o u m r) l
instance Monad m => Functor (Pipe l i o u m) where
fmap = liftM
instance Monad m => Applicative (Pipe l i o u m) where
pure = return
(<*>) = ap
instance Monad m => Monad (Pipe l i o u m) where
return = Done
HaveOutput p c o >>= fp = HaveOutput (p >>= fp) c o
NeedInput p c >>= fp = NeedInput (p >=> fp) (c >=> fp)
Done x >>= fp = fp x
PipeM mp >>= fp = PipeM ((>>= fp) `liftM` mp)
Leftover p i >>= fp = Leftover (p >>= fp) i
instance MonadBase base m => MonadBase base (Pipe l i o u m) where
liftBase = lift . liftBase
instance MonadTrans (Pipe l i o u) where
lift mr = PipeM (Done `liftM` mr)
instance MonadIO m => MonadIO (Pipe l i o u m) where
liftIO = lift . liftIO
instance MonadThrow m => MonadThrow (Pipe l i o u m) where
monadThrow = lift . monadThrow
instance MonadActive m => MonadActive (Pipe l i o u m) where
monadActive = lift monadActive
instance Monad m => Monoid (Pipe l i o u m ()) where
mempty = return ()
mappend = (>>)
instance MonadResource m => MonadResource (Pipe l i o u m) where
liftResourceT = lift . liftResourceT
instance MonadReader r m => MonadReader r (Pipe l i o u m) where
ask = lift ask
local f (HaveOutput p c o) = HaveOutput (local f p) c o
local f (NeedInput p c) = NeedInput (\i -> local f (p i)) (\u -> local f (c u))
local _ (Done x) = Done x
local f (PipeM mp) = PipeM (local f mp)
local f (Leftover p i) = Leftover (local f p) i
#ifndef MIN_VERSION_mtl
#define MIN_VERSION_mtl(x, y, z) 0
#endif
instance MonadWriter w m => MonadWriter w (Pipe l i o u m) where
#if MIN_VERSION_mtl(2, 1, 0)
writer = lift . writer
#endif
tell = lift . tell
listen (HaveOutput p c o) = HaveOutput (listen p) c o
listen (NeedInput p c) = NeedInput (\i -> listen (p i)) (\u -> listen (c u))
listen (Done x) = Done (x,mempty)
listen (PipeM mp) =
PipeM $
do (p,w) <- listen mp
return $ do (x,w') <- listen p
return (x, w `mappend` w')
listen (Leftover p i) = Leftover (listen p) i
pass (HaveOutput p c o) = HaveOutput (pass p) c o
pass (NeedInput p c) = NeedInput (\i -> pass (p i)) (\u -> pass (c u))
pass (PipeM mp) = PipeM $ mp >>= (return . pass)
pass (Done (x,_)) = Done x
pass (Leftover p i) = Leftover (pass p) i
instance MonadState s m => MonadState s (Pipe l i o u m) where
get = lift get
put = lift . put
#if MIN_VERSION_mtl(2, 1, 0)
state = lift . state
#endif
instance MonadRWS r w s m => MonadRWS r w s (Pipe l i o u m)
instance MonadError e m => MonadError e (Pipe l i o u m) where
throwError = lift . throwError
catchError (HaveOutput p c o) f = HaveOutput (catchError p f) c o
catchError (NeedInput p c) f = NeedInput (\i -> catchError (p i) f) (\u -> catchError (c u) f)
catchError (Done x) _ = Done x
catchError (PipeM mp) f =
PipeM $ catchError (liftM (flip catchError f) mp) (\e -> return (f e))
catchError (Leftover p i) f = Leftover (catchError p f) i
newtype ConduitM i o m r = ConduitM { unConduitM :: Pipe i i o () m r }
deriving (Functor, Applicative, Monad, MonadIO, MonadTrans, MonadThrow, MonadActive, MonadResource, MFunctor)
instance MonadReader r m => MonadReader r (ConduitM i o m) where
ask = ConduitM ask
local f (ConduitM m) = ConduitM (local f m)
instance MonadWriter w m => MonadWriter w (ConduitM i o m) where
#if MIN_VERSION_mtl(2, 1, 0)
writer = ConduitM . writer
#endif
tell = ConduitM . tell
listen (ConduitM m) = ConduitM (listen m)
pass (ConduitM m) = ConduitM (pass m)
instance MonadState s m => MonadState s (ConduitM i o m) where
get = ConduitM get
put = ConduitM . put
#if MIN_VERSION_mtl(2, 1, 0)
state = ConduitM . state
#endif
instance MonadRWS r w s m => MonadRWS r w s (ConduitM i o m)
instance MonadError e m => MonadError e (ConduitM i o m) where
throwError = ConduitM . throwError
catchError (ConduitM m) f = ConduitM $ catchError m (unConduitM . f)
instance MonadBase base m => MonadBase base (ConduitM i o m) where
liftBase = lift . liftBase
instance Monad m => Monoid (ConduitM i o m ()) where
mempty = return ()
mappend = (>>)
type Source m o = ConduitM () o m ()
type Producer m o = forall i. ConduitM i o m ()
type Sink i m r = ConduitM i Void m r
type Consumer i m r = forall o. ConduitM i o m r
type Conduit i m o = ConduitM i o m ()
data ResumableSource m o = ResumableSource (Source m o) (m ())
await :: Pipe l i o u m (Maybe i)
await = NeedInput (Done . Just) (\_ -> Done Nothing)
awaitE :: Pipe l i o u m (Either u i)
awaitE = NeedInput (Done . Right) (Done . Left)
awaitForever :: Monad m => (i -> Pipe l i o r m r') -> Pipe l i o r m r
awaitForever inner =
self
where
self = awaitE >>= either return (\i -> inner i >> self)
yield :: Monad m
=> o
-> Pipe l i o u m ()
yield = HaveOutput (Done ()) (return ())
yieldOr :: Monad m
=> o
-> m ()
-> Pipe l i o u m ()
yieldOr o f = HaveOutput (Done ()) f o
leftover :: l -> Pipe l i o u m ()
leftover = Leftover (Done ())
bracketP :: MonadResource m
=> IO a
-> (a -> IO ())
-> (a -> Pipe l i o u m r)
-> Pipe l i o u m r
bracketP alloc free inside =
PipeM start
where
start = do
(key, seed) <- allocate alloc free
return $ addCleanup (const $ release key) (inside seed)
addCleanup :: Monad m
=> (Bool -> m ())
-> Pipe l i o u m r
-> Pipe l i o u m r
addCleanup cleanup (Done r) = PipeM (cleanup True >> return (Done r))
addCleanup cleanup (HaveOutput src close x) = HaveOutput
(addCleanup cleanup src)
(cleanup False >> close)
x
addCleanup cleanup (PipeM msrc) = PipeM (liftM (addCleanup cleanup) msrc)
addCleanup cleanup (NeedInput p c) = NeedInput
(addCleanup cleanup . p)
(addCleanup cleanup . c)
addCleanup cleanup (Leftover p i) = Leftover (addCleanup cleanup p) i
idP :: Monad m => Pipe l a a r m r
idP = NeedInput (HaveOutput idP (return ())) Done
pipe :: Monad m => Pipe l a b r0 m r1 -> Pipe Void b c r1 m r2 -> Pipe l a c r0 m r2
pipe =
goRight (return ())
where
goRight final left right =
case right of
HaveOutput p c o -> HaveOutput (recurse p) (c >> final) o
NeedInput rp rc -> goLeft rp rc final left
Done r2 -> PipeM (final >> return (Done r2))
PipeM mp -> PipeM (liftM recurse mp)
Leftover _ i -> absurd i
where
recurse = goRight final left
goLeft rp rc final left =
case left of
HaveOutput left' final' o -> goRight final' left' (rp o)
NeedInput left' lc -> NeedInput (recurse . left') (recurse . lc)
Done r1 -> goRight (return ()) (Done r1) (rc r1)
PipeM mp -> PipeM (liftM recurse mp)
Leftover left' i -> Leftover (recurse left') i
where
recurse = goLeft rp rc final
pipeL :: Monad m => Pipe l a b r0 m r1 -> Pipe b b c r1 m r2 -> Pipe l a c r0 m r2
pipeL =
goRight (return ())
where
goRight final left right =
case right of
HaveOutput p c o -> HaveOutput (recurse p) (c >> final) o
NeedInput rp rc -> goLeft rp rc final left
Done r2 -> PipeM (final >> return (Done r2))
PipeM mp -> PipeM (liftM recurse mp)
Leftover right' i -> goRight final (HaveOutput left final i) right'
where
recurse = goRight final left
goLeft rp rc final left =
case left of
HaveOutput left' final' o -> goRight final' left' (rp o)
NeedInput left' lc -> NeedInput (recurse . left') (recurse . lc)
Done r1 -> goRight (return ()) (Done r1) (rc r1)
PipeM mp -> PipeM (liftM recurse mp)
Leftover left' i -> Leftover (recurse left') i
where
recurse = goLeft rp rc final
connectResume :: Monad m
=> ResumableSource m o
-> Sink o m r
-> m (ResumableSource m o, r)
connectResume (ResumableSource (ConduitM left0) leftFinal0) (ConduitM right0) =
goRight leftFinal0 left0 right0
where
goRight leftFinal left right =
case right of
HaveOutput _ _ o -> absurd o
NeedInput rp rc -> goLeft rp rc leftFinal left
Done r2 -> return (ResumableSource (ConduitM left) leftFinal, r2)
PipeM mp -> mp >>= goRight leftFinal left
Leftover p i -> goRight leftFinal (HaveOutput left leftFinal i) p
goLeft rp rc leftFinal left =
case left of
HaveOutput left' leftFinal' o -> goRight leftFinal' left' (rp o)
NeedInput _ lc -> recurse (lc ())
Done () -> goRight (return ()) (Done ()) (rc ())
PipeM mp -> mp >>= recurse
Leftover p () -> recurse p
where
recurse = goLeft rp rc leftFinal
runPipe :: Monad m => Pipe Void () Void () m r -> m r
runPipe (HaveOutput _ _ o) = absurd o
runPipe (NeedInput _ c) = runPipe (c ())
runPipe (Done r) = return r
runPipe (PipeM mp) = mp >>= runPipe
runPipe (Leftover _ i) = absurd i
injectLeftovers :: Monad m => Pipe i i o u m r -> Pipe l i o u m r
injectLeftovers =
go []
where
go ls (HaveOutput p c o) = HaveOutput (go ls p) c o
go (l:ls) (NeedInput p _) = go ls $ p l
go [] (NeedInput p c) = NeedInput (go [] . p) (go [] . c)
go _ (Done r) = Done r
go ls (PipeM mp) = PipeM (liftM (go ls) mp)
go ls (Leftover p l) = go (l:ls) p
transPipe :: Monad m => (forall a. m a -> n a) -> Pipe l i o u m r -> Pipe l i o u n r
transPipe f (HaveOutput p c o) = HaveOutput (transPipe f p) (f c) o
transPipe f (NeedInput p c) = NeedInput (transPipe f . p) (transPipe f . c)
transPipe _ (Done r) = Done r
transPipe f (PipeM mp) =
PipeM (f $ liftM (transPipe f) $ collapse mp)
where
collapse mpipe = do
pipe' <- mpipe
case pipe' of
PipeM mpipe' -> collapse mpipe'
_ -> return pipe'
transPipe f (Leftover p i) = Leftover (transPipe f p) i
mapOutput :: Monad m => (o1 -> o2) -> Pipe l i o1 u m r -> Pipe l i o2 u m r
mapOutput f (HaveOutput p c o) = HaveOutput (mapOutput f p) c (f o)
mapOutput f (NeedInput p c) = NeedInput (mapOutput f . p) (mapOutput f . c)
mapOutput _ (Done r) = Done r
mapOutput f (PipeM mp) = PipeM (liftM (mapOutput f) mp)
mapOutput f (Leftover p i) = Leftover (mapOutput f p) i
mapOutputMaybe :: Monad m => (o1 -> Maybe o2) -> Pipe l i o1 u m r -> Pipe l i o2 u m r
mapOutputMaybe f (HaveOutput p c o) = maybe id (\o' p' -> HaveOutput p' c o') (f o) (mapOutputMaybe f p)
mapOutputMaybe f (NeedInput p c) = NeedInput (mapOutputMaybe f . p) (mapOutputMaybe f . c)
mapOutputMaybe _ (Done r) = Done r
mapOutputMaybe f (PipeM mp) = PipeM (liftM (mapOutputMaybe f) mp)
mapOutputMaybe f (Leftover p i) = Leftover (mapOutputMaybe f p) i
mapInput :: Monad m
=> (i1 -> i2)
-> (l2 -> Maybe l1)
-> Pipe l2 i2 o u m r
-> Pipe l1 i1 o u m r
mapInput f f' (HaveOutput p c o) = HaveOutput (mapInput f f' p) c o
mapInput f f' (NeedInput p c) = NeedInput (mapInput f f' . p . f) (mapInput f f' . c)
mapInput _ _ (Done r) = Done r
mapInput f f' (PipeM mp) = PipeM (liftM (mapInput f f') mp)
mapInput f f' (Leftover p i) = maybe id (flip Leftover) (f' i) $ mapInput f f' p
sourceList :: Monad m => [a] -> Pipe l i a u m ()
sourceList =
go
where
go [] = Done ()
go (o:os) = HaveOutput (go os) (return ()) o
build :: Monad m => (forall b. (o -> b -> b) -> b -> b) -> Pipe l i o u m ()
build g = g (\o p -> HaveOutput p (return ()) o) (return ())
sourceToPipe :: Monad m => Source m o -> Pipe l i o u m ()
sourceToPipe =
go . unConduitM
where
go (HaveOutput p c o) = HaveOutput (go p) c o
go (NeedInput _ c) = go $ c ()
go (Done ()) = Done ()
go (PipeM mp) = PipeM (liftM go mp)
go (Leftover p ()) = go p
sinkToPipe :: Monad m => Sink i m r -> Pipe l i o u m r
sinkToPipe =
go . injectLeftovers . unConduitM
where
go (HaveOutput _ _ o) = absurd o
go (NeedInput p c) = NeedInput (go . p) (const $ go $ c ())
go (Done r) = Done r
go (PipeM mp) = PipeM (liftM go mp)
go (Leftover _ l) = absurd l
conduitToPipe :: Monad m => Conduit i m o -> Pipe l i o u m ()
conduitToPipe =
go . injectLeftovers . unConduitM
where
go (HaveOutput p c o) = HaveOutput (go p) c o
go (NeedInput p c) = NeedInput (go . p) (const $ go $ c ())
go (Done ()) = Done ()
go (PipeM mp) = PipeM (liftM go mp)
go (Leftover _ l) = absurd l
withUpstream :: Monad m
=> Pipe l i o u m r
-> Pipe l i o u m (u, r)
withUpstream down =
down >>= go
where
go r =
loop
where
loop = awaitE >>= either (\u -> return (u, r)) (\_ -> loop)
unwrapResumable :: MonadIO m => ResumableSource m o -> m (Source m o, m ())
unwrapResumable (ResumableSource src final) = do
ref <- liftIO $ I.newIORef True
let final' = do
x <- liftIO $ I.readIORef ref
when x final
return (liftIO (I.writeIORef ref False) >> src, final')
infixr 9 <+<
infixl 9 >+>
(>+>) :: Monad m => Pipe l a b r0 m r1 -> Pipe Void b c r1 m r2 -> Pipe l a c r0 m r2
(>+>) = pipe
(<+<) :: Monad m => Pipe Void b c r1 m r2 -> Pipe l a b r0 m r1 -> Pipe l a c r0 m r2
(<+<) = flip pipe
toProducer :: Monad m => Source m a -> Producer m a
toProducer =
ConduitM . go . unConduitM
where
go (HaveOutput p c o) = HaveOutput (go p) c o
go (NeedInput _ c) = go (c ())
go (Done r) = Done r
go (PipeM mp) = PipeM (liftM go mp)
go (Leftover p ()) = go p
toConsumer :: Monad m => Sink a m b -> Consumer a m b
toConsumer =
ConduitM . go . unConduitM
where
go (HaveOutput _ _ o) = absurd o
go (NeedInput p c) = NeedInput (go . p) (go . c)
go (Done r) = Done r
go (PipeM mp) = PipeM (liftM go mp)
go (Leftover p l) = Leftover (go p) l
instance MFunctor (Pipe l i o u) where
hoist = transPipe