{-# LANGUAGE RankNTypes, StandaloneDeriving,DeriveDataTypeable, BangPatterns #-} {-# LANGUAGE UndecidableInstances, CPP, FlexibleInstances, MultiParamTypeClasses #-} {-#LANGUAGE Trustworthy #-} module Streaming.Internal ( -- * The free monad transformer -- $stream Stream (..) -- * Introducing a stream , unfold , replicates , repeats , repeatsM , effect , wrap , yields , streamBuild , cycles , delays , never , untilJust -- * Eliminating a stream , intercalates , concats , iterT , iterTM , destroy , streamFold -- * Inspecting a stream wrap by wrap , inspect -- * Transforming streams , maps , mapsM , decompose , mapsM_ , run , distribute , groups -- , groupInL -- * Splitting streams , chunksOf , splitsAt , takes , cutoff -- , period -- , periods -- * Zipping and unzipping streams , zipsWith , zips , unzips , interleaves , separate , unseparate -- * Assorted Data.Functor.x help , switch -- * ResourceT help , bracketStream -- * For use in implementation , unexposed , hoistExposed , mapsExposed , mapsMExposed , destroyExposed ) where import Control.Monad import Control.Monad.Trans import Control.Monad.Trans.Class import Control.Monad.Reader.Class import Control.Monad.Writer.Class import Control.Monad.State.Class import Control.Monad.Error.Class import Control.Monad.Cont.Class import Control.Applicative import Data.Foldable ( Foldable(..) ) import Data.Traversable import Control.Monad.Morph import Data.Monoid (Monoid (..), (<>)) import Data.Functor.Identity import Data.Data ( Data, Typeable ) import Prelude hiding (splitAt) import Data.Functor.Compose import Data.Functor.Sum import Control.Concurrent (threadDelay) import Control.Monad.Base import Control.Monad.Trans.Resource import Control.Monad.Catch (MonadCatch (..)) import Control.Monad.Trans.Control {- $stream The 'Stream' data type is equivalent to @FreeT@ and can represent any effectful succession of steps, where the form of the steps or 'commands' is specified by the first (functor) parameter. > data Stream f m r = Step !(f (Stream f m r)) | Effect (m (Stream f m r)) | Return r The /producer/ concept uses the simple functor @ (a,_) @ \- or the stricter @ Of a _ @. Then the news at each step or layer is just: an individual item of type @a@. Since @Stream (Of a) m r@ is equivalent to @Pipe.Producer a m r@, much of the @pipes@ @Prelude@ can easily be mirrored in a @streaming@ @Prelude@. Similarly, a simple @Consumer a m r@ or @Parser a m r@ concept arises when the base functor is @ (a -> _) @ . @Stream ((->) input) m result@ consumes @input@ until it returns a @result@. To avoid breaking reasoning principles, the constructors should not be used directly. A pattern-match should go by way of 'inspect' \ \- or, in the producer case, 'Streaming.Prelude.next' The constructors are exported by the 'Internal' module. -} data Stream f m r = Step !(f (Stream f m r)) | Effect (m (Stream f m r)) | Return r #if __GLASGOW_HASKELL__ >= 710 deriving (Typeable) #endif deriving instance (Show r, Show (m (Stream f m r)) , Show (f (Stream f m r))) => Show (Stream f m r) deriving instance (Eq r, Eq (m (Stream f m r)) , Eq (f (Stream f m r))) => Eq (Stream f m r) #if __GLASGOW_HASKELL__ >= 710 deriving instance (Typeable f, Typeable m, Data r, Data (m (Stream f m r)) , Data (f (Stream f m r))) => Data (Stream f m r) #endif instance (Functor f, Monad m) => Functor (Stream f m) where fmap f = loop where loop stream = case stream of Return r -> Return (f r) Effect m -> Effect (do {stream' <- m; return (loop stream')}) Step f -> Step (fmap loop f) {-# INLINABLE fmap #-} a <$ stream0 = loop stream0 where loop stream = case stream of Return r -> Return a Effect m -> Effect (do {stream' <- m; return (loop stream')}) Step f -> Step (fmap loop f) {-# INLINABLE (<$) #-} instance (Functor f, Monad m) => Monad (Stream f m) where return = Return {-# INLINE return #-} stream1 >> stream2 = loop stream1 where loop stream = case stream of Return _ -> stream2 Effect m -> Effect (liftM loop m) Step f -> Step (fmap loop f) {-# INLINABLE (>>) #-} -- (>>=) = _bind -- {-#INLINE (>>=) #-} -- stream >>= f = loop stream where loop stream0 = case stream0 of Step fstr -> Step (fmap loop fstr) Effect m -> Effect (liftM loop m) Return r -> f r {-# INLINABLE (>>=) #-} fail = lift . fail {-#INLINE fail #-} -- _bind -- :: (Functor f, Monad m) -- => Stream f m r -- -> (r -> Stream f m s) -- -> Stream f m s -- _bind p0 f = go p0 where -- go p = case p of -- Step fstr -> Step (fmap go fstr) -- Effect m -> Effect (m >>= \s -> return (go s)) -- Return r -> f r -- {-#INLINABLE _bind #-} -- -- see https://github.com/Gabriel439/Haskell-Pipes-Library/pull/163 -- for a plan to delay inlining and manage interaction with other operations. -- {-# RULES -- "_bind (Step fstr) f" forall fstr f . -- _bind (Step fstr) f = Step (fmap (\p -> _bind p f) fstr); -- "_bind (Effect m) f" forall m f . -- _bind (Effect m) f = Effect (m >>= \p -> return (_bind p f)); -- "_bind (Return r) f" forall r f . -- _bind (Return r) f = f r; -- #-} instance (Functor f, Monad m) => Applicative (Stream f m) where pure = Return {-# INLINE pure #-} streamf <*> streamx = do {f <- streamf; x <- streamx; return (f x)} {-# INLINE (<*>) #-} {- | The 'Alternative' instance glues streams together stepwise. > empty = never > (<|>) = zipsWith (liftA2 (,)) See also 'never', 'untilJust' and 'delays' -} instance (Applicative f, Monad m) => Alternative (Stream f m) where empty = never {-#INLINE empty #-} str <|> str' = zipsWith (liftA2 (,)) str str' {-#INLINE (<|>) #-} instance (Functor f, Monad m, Monoid w) => Monoid (Stream f m w) where mempty = return mempty {-#INLINE mempty #-} mappend a b = a >>= \w -> fmap (w <>) b {-#INLINE mappend #-} instance (Applicative f, Monad m) => MonadPlus (Stream f m) where mzero = empty mplus = (<|>) instance Functor f => MonadTrans (Stream f) where lift = Effect . liftM Return {-# INLINE lift #-} instance Functor f => MFunctor (Stream f) where hoist trans = loop where loop stream = case stream of Return r -> Return r Effect m -> Effect (trans (liftM loop m)) Step f -> Step (fmap loop f) {-# INLINABLE hoist #-} instance Functor f => MMonad (Stream f) where embed phi = loop where loop stream = case stream of Return r -> Return r Effect m -> phi m >>= loop Step f -> Step (fmap loop f) {-# INLINABLE embed #-} instance (MonadIO m, Functor f) => MonadIO (Stream f m) where liftIO = Effect . liftM Return . liftIO {-# INLINE liftIO #-} instance (MonadBase b m, Functor f) => MonadBase b (Stream f m) where liftBase = effect . fmap return . liftBase {-#INLINE liftBase #-} instance (MonadThrow m, Functor f) => MonadThrow (Stream f m) where throwM = lift . throwM {-#INLINE throwM #-} instance (MonadCatch m, Functor f) => MonadCatch (Stream f m) where catch str f = go str where go p = case p of Step f -> Step (fmap go f) Return r -> Return r Effect m -> Effect (catch (do p' <- m return (go p')) (\e -> return (f e)) ) {-#INLINABLE catch #-} instance (MonadResource m, Functor f) => MonadResource (Stream f m) where liftResourceT = lift . liftResourceT {-#INLINE liftResourceT #-} instance (Functor f, MonadReader r m) => MonadReader r (Stream f m) where ask = lift ask {-# INLINE ask #-} local f = hoist (local f) {-# INLINE local #-} -- instance (Functor f, MonadWriter w m) => MonadWriter w (Stream f m) where -- tell = lift . tell -- {-# INLINE tell #-} -- -- listen (FreeT m) = FreeT $ liftM concat' $ listen (fmap listen `liftM` m) -- where -- concat' (Pure x, w) = Pure (x, w) -- concat' (Free y, w) = Free $ fmap (second (w <>)) <$> y -- pass m = FreeT . pass' . runFreeT . hoist clean $ listen m -- where -- clean = pass . liftM (\x -> (x, const mempty)) -- pass' = join . liftM g -- g (Pure ((x, f), w)) = tell (f w) >> return (Pure x) -- g (Free f) = return . Free . fmap (FreeT . pass' . runFreeT) $ f -- #if MIN_VERSION_mtl(2,1,1) -- writer w = lift (writer w) -- {-# INLINE writer #-} -- #endif -- instance (Functor f, MonadState s m) => MonadState s (Stream f m) where get = lift get {-# INLINE get #-} put = lift . put {-# INLINE put #-} #if MIN_VERSION_mtl(2,1,1) state f = lift (state f) {-# INLINE state #-} #endif instance (Functor f, MonadError e m) => MonadError e (Stream f m) where throwError = lift . throwError {-# INLINE throwError #-} str `catchError` f = loop str where loop str = case str of Return r -> Return r Effect m -> Effect $ liftM loop m `catchError` (return . f) Step f -> Step (fmap loop f) {-# INLINABLE catchError #-} bracketStream :: (Functor f, MonadResource m) => IO a -> (a -> IO ()) -> (a -> Stream f m b) -> Stream f m b bracketStream alloc free inside = do (key, seed) <- lift (allocate alloc free) clean key (inside seed) where clean key = loop where loop str = case str of Return r -> Effect (release key >> return (Return r)) Effect m -> Effect (liftM loop m) Step f -> Step (fmap loop f) {-#INLINABLE bracketStream #-} {-| Map a stream directly to its church encoding; compare @Data.List.foldr@ -} destroy :: (Functor f, Monad m) => Stream f m r -> (f b -> b) -> (m b -> b) -> (r -> b) -> b destroy stream0 construct effect done = loop stream0 where loop stream = case stream of Return r -> done r Effect m -> effect (liftM loop m) Step fs -> construct (fmap loop fs) {-# INLINABLE destroy #-} {-| 'streamFold' reorders the arguments of 'destroy' to be more akin to @foldr@ It is more convenient to query in ghci to figure out what kind of \'algebra\' you need to write. >>> :t streamFold return join (Monad m, Functor f) => (f (m a) -> m a) -> Stream f m a -> m a -- iterT >>> :t streamFold return (join . lift) (Monad m, Monad (t m), Functor f, MonadTrans t) => (f (t m a) -> t m a) -> Stream f m a -> t m a -- iterTM >>> :t streamFold return effect (Monad m, Functor f, Functor g) => (f (Stream g m r) -> Stream g m r) -> Stream f m r -> Stream g m r >>> :t \f -> streamFold return effect (wrap . f) (Monad m, Functor f, Functor g) => (f (Stream g m a) -> g (Stream g m a)) -> Stream f m a -> Stream g m a -- maps >>> :t \f -> streamFold return effect (effect . liftM wrap . f) (Monad m, Functor f, Functor g) => (f (Stream g m a) -> m (g (Stream g m a))) -> Stream f m a -> Stream g m a -- mapped -} streamFold :: (Functor f, Monad m) => (r -> b) -> (m b -> b) -> (f b -> b) -> Stream f m r -> b streamFold done effect construct stream = destroy stream construct effect done {-#INLINE streamFold #-} {- | Reflect a church-encoded stream; cp. @GHC.Exts.build@ > streamFold return_ effect_ step_ (streamBuild psi) = psi return_ effect_ step_ -} streamBuild :: (forall b . (r -> b) -> (m b -> b) -> (f b -> b) -> b) -> Stream f m r streamBuild = \phi -> phi Return Effect Step {-# INLINE streamBuild #-} {-| Inspect the first stage of a freely layered sequence. Compare @Pipes.next@ and the replica @Streaming.Prelude.next@. This is the 'uncons' for the general 'unfold'. > unfold inspect = id > Streaming.Prelude.unfoldr StreamingPrelude.next = id -} inspect :: (Functor f, Monad m) => Stream f m r -> m (Either r (f (Stream f m r))) inspect = loop where loop stream = case stream of Return r -> return (Left r) Effect m -> m >>= loop Step fs -> return (Right fs) {-# INLINABLE inspect #-} {-| Build a @Stream@ by unfolding steps starting from a seed. See also the specialized 'Streaming.Prelude.unfoldr' in the prelude. > unfold inspect = id -- modulo the quotient we work with > unfold Pipes.next :: Monad m => Producer a m r -> Stream ((,) a) m r > unfold (curry (:>) . Pipes.next) :: Monad m => Producer a m r -> Stream (Of a) m r -} unfold :: (Monad m, Functor f) => (s -> m (Either r (f s))) -> s -> Stream f m r unfold step = loop where loop s0 = Effect $ do e <- step s0 case e of Left r -> return (Return r) Right fs -> return (Step (fmap loop fs)) {-# INLINABLE unfold #-} {- | Map layers of one functor to another with a transformation. Compare hoist, which has a similar effect on the 'monadic' parameter. > maps id = id > maps f . maps g = maps (f . g) -} maps :: (Monad m, Functor f) => (forall x . f x -> g x) -> Stream f m r -> Stream g m r maps phi = loop where loop stream = case stream of Return r -> Return r Effect m -> Effect (liftM loop m) Step f -> Step (phi (fmap loop f)) {-# INLINABLE maps #-} {- | Map layers of one functor to another with a transformation involving the base monad @maps@ is more fundamental than @mapsM@, which is best understood as a convenience for effecting this frequent composition: > mapsM phi = decompose . maps (Compose . phi) The streaming prelude exports the same function under the better name @mapped@, which overlaps with the lens libraries. -} mapsM :: (Monad m, Functor f) => (forall x . f x -> m (g x)) -> Stream f m r -> Stream g m r mapsM phi = loop where loop stream = case stream of Return r -> Return r Effect m -> Effect (liftM loop m) Step f -> Effect (liftM Step (phi (fmap loop f))) {-# INLINABLE mapsM #-} {-| Rearrange a succession of layers of the form @Compose m (f x)@. we could as well define @decompose@ by @mapsM@: > decompose = mapped getCompose but @mapped@ is best understood as: > mapped phi = decompose . maps (Compose . phi) since @maps@ and @hoist@ are the really fundamental operations that preserve the shape of the stream: > maps :: (Monad m, Functor f) => (forall x. f x -> g x) -> Stream f m r -> Stream g m r > hoist :: (Monad m, Functor f) => (forall a. m a -> n a) -> Stream f m r -> Stream f n r -} decompose :: (Monad m, Functor f) => Stream (Compose m f) m r -> Stream f m r decompose = loop where loop stream = case stream of Return r -> Return r Effect m -> Effect (liftM loop m) Step (Compose mstr) -> Effect $ do str <- mstr return (Step (fmap loop str)) {-| Run the effects in a stream that merely layers effects. -} run :: Monad m => Stream m m r -> m r run = loop where loop stream = case stream of Return r -> return r Effect m -> m >>= loop Step mrest -> mrest >>= loop {-# INLINABLE run #-} {-| Map each layer to an effect, and run them all. -} mapsM_ :: (Functor f, Monad m) => (forall x . f x -> m x) -> Stream f m r -> m r mapsM_ f = run . maps f {-# INLINE mapsM_ #-} {-| Interpolate a layer at each segment. This specializes to e.g. > intercalates :: (Monad m, Functor f) => Stream f m () -> Stream (Stream f m) m r -> Stream f m r -} intercalates :: (Monad m, Monad (t m), MonadTrans t) => t m x -> Stream (t m) m r -> t m r intercalates sep = go0 where go0 f = case f of Return r -> return r Effect m -> lift m >>= go0 Step fstr -> do f' <- fstr go1 f' go1 f = case f of Return r -> return r Effect m -> lift m >>= go1 Step fstr -> do sep f' <- fstr go1 f' {-# INLINABLE intercalates #-} {-| Specialized fold following the usage of @Control.Monad.Trans.Free@ > iterTM alg = streamFold return (join . lift) -} iterTM :: (Functor f, Monad m, MonadTrans t, Monad (t m)) => (f (t m a) -> t m a) -> Stream f m a -> t m a iterTM out stream = destroyExposed stream out (join . lift) return {-# INLINE iterTM #-} {-| Specialized fold following the usage of @Control.Monad.Trans.Free@ > iterT alg = streamFold return join alg -} iterT :: (Functor f, Monad m) => (f (m a) -> m a) -> Stream f m a -> m a iterT out stream = destroyExposed stream out join return {-# INLINE iterT #-} {-| Dissolves the segmentation into layers of @Stream f m@ layers. -} concats :: (Monad m, Functor f) => Stream (Stream f m) m r -> Stream f m r concats = loop where loop stream = case stream of Return r -> return r Effect m -> join $ lift (liftM loop m) Step fs -> join (fmap loop fs) {-# INLINE concats #-} {-| Split a succession of layers after some number, returning a streaming or effectful pair. >>> rest <- S.print $ S.splitAt 1 $ each [1..3] 1 >>> S.print rest 2 3 > splitAt 0 = return > splitAt n >=> splitAt m = splitAt (m+n) Thus, e.g. >>> rest <- S.print $ splitsAt 2 >=> splitsAt 2 $ each [1..5] 1 2 3 4 >>> S.print rest 5 -} splitsAt :: (Monad m, Functor f) => Int -> Stream f m r -> Stream f m (Stream f m r) splitsAt = loop where loop !n stream | n <= 0 = Return stream | otherwise = case stream of Return r -> Return (Return r) Effect m -> Effect (liftM (loop n) m) Step fs -> case n of 0 -> Return (Step fs) _ -> Step (fmap (loop (n-1)) fs) {-# INLINABLE splitsAt #-} {- Functor-general take. @takes 3@ can take three individual values >>> S.print $ takes 3 $ each [1..] 1 2 3 or three sub-streams >>> S.print $ mapped S.toList $ takes 3 $ chunksOf 2 $ each [1..] [1,2] [3,4] [5,6] Or, using 'Data.ByteString.Streaming.Char' (here called @Q@), three byte streams. >>> Q.stdout $ Q.unlines $ takes 3 $ Q.lines $ Q.chunk "a\nb\nc\nd\ne\nf" a b c -} takes :: (Monad m, Functor f) => Int -> Stream f m r -> Stream f m () takes n = void . splitsAt n {-# INLINE takes #-} {-| Break a stream into substreams each with n functorial layers. >>> S.print $ mapped S.sum $ chunksOf 2 $ each [1,1,1,1,1] 2 2 1 -} chunksOf :: (Monad m, Functor f) => Int -> Stream f m r -> Stream (Stream f m) m r chunksOf n0 = loop where loop stream = case stream of Return r -> Return r Effect m -> Effect (liftM loop m) Step fs -> Step (Step (fmap (fmap loop . splitsAt (n0-1)) fs)) {-# INLINABLE chunksOf #-} {- | Make it possible to \'run\' the underlying transformed monad. -} distribute :: (Monad m, Functor f, MonadTrans t, MFunctor t, Monad (t (Stream f m))) => Stream f (t m) r -> t (Stream f m) r distribute = loop where loop stream = case stream of Return r -> lift (Return r) Effect tmstr -> hoist lift tmstr >>= loop Step fstr -> join (lift (Step (fmap (Return . loop) fstr))) {-#INLINABLE distribute #-} -- | Repeat a functorial layer (a \"command\" or \"instruction\") forever. repeats :: (Monad m, Functor f) => f () -> Stream f m r repeats f = loop where loop = Effect (return (Step (fmap (\_ -> loop) f))) -- | Repeat an effect containing a functorial layer, command or instruction forever. repeatsM :: (Monad m, Functor f) => m (f ()) -> Stream f m r repeatsM mf = loop where loop = Effect $ do f <- mf return $ Step $ fmap (\_ -> loop) f {- | Repeat a functorial layer, command or instruction a fixed number of times. > replicates n = takes n . repeats -} replicates :: (Monad m, Functor f) => Int -> f () -> Stream f m () replicates n f = splitsAt n (repeats f) >> return () {-| Construct an infinite stream by cycling a finite one > cycles = forever >>> -} cycles :: (Monad m, Functor f) => Stream f m () -> Stream f m r cycles = forever hoistExposed trans = loop where loop stream = case stream of Return r -> Return r Effect m -> Effect (trans (liftM loop m)) Step f -> Step (fmap loop f) mapsExposed :: (Monad m, Functor f) => (forall x . f x -> g x) -> Stream f m r -> Stream g m r mapsExposed phi = loop where loop stream = case stream of Return r -> Return r Effect m -> Effect (liftM loop m) Step f -> Step (phi (fmap loop f)) {-# INLINABLE mapsExposed #-} mapsMExposed phi = loop where loop stream = case stream of Return r -> Return r Effect m -> Effect (liftM loop m) Step f -> Effect (liftM Step (phi (fmap loop f))) {-# INLINABLE mapsMExposed #-} -- Map a stream directly to its church encoding; compare @Data.List.foldr@ -- It permits distinctions that should be hidden, as can be seen from -- e.g. -- -- isPure stream = destroy (const True) (const False) (const True) -- -- and similar nonsense. The crucial -- constraint is that the @m x -> x@ argument is an /Eilenberg-Moore algebra/. -- See Atkey "Reasoning about Stream Processing with Effects" destroyExposed stream0 construct effect done = loop stream0 where loop stream = case stream of Return r -> done r Effect m -> effect (liftM loop m) Step fs -> construct (fmap loop fs) {-# INLINABLE destroyExposed #-} {-| This is akin to the @observe@ of @Pipes.Internal@ . It reeffects the layering in instances of @Stream f m r@ so that it replicates that of @FreeT@. -} unexposed :: (Functor f, Monad m) => Stream f m r -> Stream f m r unexposed = Effect . loop where loop stream = case stream of Return r -> return (Return r) Effect m -> m >>= loop Step f -> return (Step (fmap (Effect . loop) f)) {-# INLINABLE unexposed #-} {-| Wrap a new layer of a stream. So, e.g. > S.cons :: Monad m => a -> Stream (Of a) m r -> Stream (Of a) m r > S.cons a str = wrap (a :> str) and, recursively: > S.each :: (Monad m, Foldable t) => t a -> Stream (Of a) m () > S.each = foldr (\a b -> wrap (a :> b)) (return ()) The two operations > wrap :: (Monad m, Functor f ) => f (Stream f m r) -> Stream f m r > effect :: (Monad m, Functor f ) => m (Stream f m r) -> Stream f m r are fundamental. We can define the parallel operations @yields@ and @lift@ in terms of them > yields :: (Monad m, Functor f ) => f r -> Stream f m r > yields = wrap . fmap return > lift :: (Monad m, Functor f ) => m r -> Stream f m r > lift = effect . fmap return -} wrap :: (Monad m, Functor f ) => f (Stream f m r) -> Stream f m r wrap = Step {-#INLINE wrap #-} {- | Wrap an effect that returns a stream > effect = join . lift -} effect :: (Monad m, Functor f ) => m (Stream f m r) -> Stream f m r effect = Effect {-#INLINE effect #-} {-| @yields@ is like @lift@ for items in the streamed functor. It makes a singleton or one-layer succession. > lift :: (Monad m, Functor f) => m r -> Stream f m r > yields :: (Monad m, Functor f) => f r -> Stream f m r Viewed in another light, it is like a functor-general version of @yield@: > S.yield a = yields (a :> ()) -} yields :: (Monad m, Functor f) => f r -> Stream f m r yields fr = Step (fmap Return fr) {-#INLINE yields #-} zipsWith :: (Monad m, Functor f, Functor g, Functor h) => (forall x y . f x -> g y -> h (x,y)) -> Stream f m r -> Stream g m r -> Stream h m r zipsWith phi s t = loop (s,t) where loop (s1, s2) = Effect (go s1 s2) go s1 s2 = do e <- inspect s1 e' <- inspect s2 case (e,e') of (Left r, _) -> return (Return r) (_, Left r) -> return (Return r) (Right fstr, Right gstr) -> return $ Step $ fmap loop (phi fstr gstr) {-# INLINABLE zipsWith #-} zips :: (Monad m, Functor f, Functor g) => Stream f m r -> Stream g m r -> Stream (Compose f g) m r zips = zipsWith go where go fx gy = Compose (fmap (\x -> fmap (\y -> (x,y)) gy) fx) {-# INLINE zips #-} {-| Interleave functor layers, with the effects of the first preceding the effects of the second. > interleaves = zipsWith (liftA2 (,)) >>> let paste = \a b -> interleaves (Q.lines a) (maps (Q.cons' '\t') (Q.lines b)) >>> Q.stdout $ Q.unlines $ paste "hello\nworld\n" "goodbye\nworld\n" hello goodbye world world -} interleaves :: (Monad m, Applicative h) => Stream h m r -> Stream h m r -> Stream h m r interleaves = zipsWith (liftA2 (,)) {-# INLINE interleaves #-} {-| Swap the order of functors in a sum of functors. >>> S.toList $ S.print $ separate $ maps S.switch $ maps (S.distinguish (=='a')) $ S.each "banana" 'a' 'a' 'a' "bnn" :> () >>> S.toList $ S.print $ separate $ maps (S.distinguish (=='a')) $ S.each "banana" 'b' 'n' 'n' "aaa" :> () -} switch :: Sum f g r -> Sum g f r switch s = case s of InL a -> InR a; InR a -> InL a {-#INLINE switch #-} {-| Given a stream on a sum of functors, make it a stream on the left functor, with the streaming on the other functor as the governing monad. This is useful for acting on one or the other functor with a fold, leaving the other material for another treatment. It generalizes 'Data.Either.partitionEithers', but actually streams properly. >>> let odd_even = S.maps (S.distinguish even) $ S.each [1..10::Int] >>> :t separate odd_even separate odd_even :: Monad m => Stream (Of Int) (Stream (Of Int) m) () Now, for example, it is convenient to fold on the left and right values separately: >>> S.toList $ S.toList $ separate odd_even [2,4,6,8,10] :> ([1,3,5,7,9] :> ()) Or we can write them to separate files or whatever: >>> runResourceT $ S.writeFile "even.txt" . S.show $ S.writeFile "odd.txt" . S.show $ S.separate odd_even >>> :! cat even.txt 2 4 6 8 10 >>> :! cat odd.txt 1 3 5 7 9 Of course, in the special case of @Stream (Of a) m r@, we can achieve the above effects more simply by using 'Streaming.Prelude.copy' >>> S.toList . S.filter even $ S.toList . S.filter odd $ S.copy $ each [1..10::Int] [2,4,6,8,10] :> ([1,3,5,7,9] :> ()) But 'separate' and 'unseparate' are functor-general. -} separate :: (Monad m, Functor f, Functor g) => Stream (Sum f g) m r -> Stream f (Stream g m) r separate str = destroyExposed str (\x -> case x of InL fss -> wrap fss; InR gss -> effect (yields gss)) (effect . lift) return {-#INLINABLE separate #-} unseparate :: (Monad m, Functor f, Functor g) => Stream f (Stream g m) r -> Stream (Sum f g) m r unseparate str = destroyExposed str (wrap . InL) (join . maps InR) return {-#INLINABLE unseparate #-} unzips :: (Monad m, Functor f, Functor g) => Stream (Compose f g) m r -> Stream f (Stream g m) r unzips str = destroyExposed str (\(Compose fgstr) -> Step (fmap (Effect . yields) fgstr)) (Effect . lift) return {-#INLINABLE unzips #-} {-| Group layers in an alternating stream into adjoining sub-streams of one type or another. -} groups :: (Monad m, Functor f, Functor g) => Stream (Sum f g) m r -> Stream (Sum (Stream f m) (Stream g m)) m r groups = loop where loop str = do e <- lift $ inspect str case e of Left r -> return r Right ostr -> case ostr of InR gstr -> wrap $ InR (fmap loop (cleanR (wrap (InR gstr)))) InL fstr -> wrap $ InL (fmap loop (cleanL (wrap (InL fstr)))) cleanL :: (Monad m, Functor f, Functor g) => Stream (Sum f g) m r -> Stream f m (Stream (Sum f g) m r) cleanL = loop where loop s = do e <- lift $ inspect s case e of Left r -> return (return r) Right (InL fstr) -> wrap (fmap loop fstr) Right (InR gstr) -> return (wrap (InR gstr)) cleanR :: (Monad m, Functor f, Functor g) => Stream (Sum f g) m r -> Stream g m (Stream (Sum f g) m r) -- cleanR = fmap (maps switch) . cleanL . maps switch cleanR = loop where loop s = do e <- lift $ inspect s case e of Left r -> return (return r) Right (InL fstr) -> return (wrap (InL fstr)) Right (InR gstr) -> wrap (fmap loop gstr) {-#INLINABLE groups #-} -- groupInL :: (Monad m, Functor f, Functor g) -- => Stream (Sum f g) m r -- -> Stream (Sum (Stream f m) g) m r -- groupInL = loop -- where -- loop str = do -- e <- lift $ inspect str -- case e of -- Left r -> return r -- Right ostr -> case ostr of -- InR gstr -> wrap $ InR (fmap loop gstr) -- InL fstr -> wrap $ InL (fmap loop (cleanL (wrap (InL fstr)))) -- cleanL :: (Monad m, Functor f, Functor g) => -- Stream (Sum f g) m r -> Stream f m (Stream (Sum f g) m r) -- cleanL = loop where -- loop s = dos -- e <- lift $ inspect s -- case e of -- Left r -> return (return r) -- Right (InL fstr) -> wrap (fmap loop fstr) -- Right (InR gstr) -> return (wrap (InR gstr)) {- | 'never' interleaves the pure applicative action with the return of the monad forever. It is the 'empty' of the 'Alternative' instance, thus > never <|> a = a > a <|> never = a and so on. If w is a monoid then @never :: Stream (Of w) m r@ is the infinite sequence of 'mempty', and @str1 \<|\> str2@ appends the elements monoidally until one of streams ends. Thus we have, e.g. >>> S.stdoutLn $ S.take 2 $ S.stdinLn <|> S.repeat " " <|> S.stdinLn <|> S.repeat " " <|> S.stdinLn 1<Enter> 2<Enter> 3<Enter> 1 2 3 4<Enter> 5<Enter> 6<Enter> 4 5 6 This is equivalent to >>> S.stdoutLn $ S.take 2 $ foldr (<|>) never [S.stdinLn, S.repeat " ", S.stdinLn, S.repeat " ", S.stdinLn ] Where 'f' is a monad, @(\<|\>)@ sequences the conjoined streams stepwise. See the definition of @paste@ <https://gist.github.com/michaelt/6c6843e6dd8030e95d58 here>, where the separate steps are bytestreams corresponding to the lines of a file. Given, say, > data Branch r = Branch r r deriving Functor -- add obvious applicative instance then @never :: Stream Branch Identity r@ is the pure infinite binary tree with (inaccessible) @r@s in its leaves. Given two binary trees, @tree1 \<|\> tree2@ intersects them, preserving the leaves that came first, so @tree1 \<|\> never = tree1@ @Stream Identity m r@ is an action in @m@ that is indefinitely delayed. Such an action can be constructed with e.g. 'untilJust'. > untilJust :: (Monad m, Applicative f) => m (Maybe r) -> Stream f m r Given two such items, @\<|\>@ instance races them. It is thus the iterative monad transformer specially defined in <https://hackage.haskell.org/package/free-4.12.1/docs/Control-Monad-Trans-Iter.html Control.Monad.Trans.Iter> So, for example, we might write >>> let justFour str = if length str == 4 then Just str else Nothing >>> let four = untilJust (liftM justFour getLine) >>> run four one<Enter> two<Enter> three<Enter> four<Enter> "four" The 'Alternative' instance in <https://hackage.haskell.org/package/free-4.12.1/docs/Control-Monad-Trans-Free.html Control.Monad.Trans.Free> is avowedly wrong, though no explanation is given for this. -} never :: (Monad m, Applicative f) => Stream f m r never = let loop = Effect $ return $ Step $ pure loop in loop {-#INLINABLE never #-} delays :: (MonadIO m, Applicative f) => Double -> Stream f m r delays seconds = loop where loop = Effect $ liftIO (threadDelay delay) >> return (Step (pure loop)) delay = fromInteger (truncate (1000000 * seconds)) {-#INLINABLE delays #-} -- {-| Permit streamed actions to proceed unless the clock has run out. -- -- -} -- period :: (MonadIO m, Functor f) => Double -> Stream f m r -> Stream f m (Stream f m r) -- period seconds str = do -- utc <- liftIO getCurrentTime -- let loop s = do -- utc' <- liftIO getCurrentTime -- if diffUTCTime utc' utc > (cutoff / 1000000000) -- then return s -- else case s of -- Return r -> Return (Return r) -- Effect m -> Effect (liftM loop m) -- Step f -> Step (fmap loop f) -- loop str -- where -- cutoff = fromInteger (truncate (1000000000 * seconds)) -- {-#INLINABLE period #-} -- -- -- {-| Divide a succession of phases according to a specified time interval. If time runs out -- while an action is proceeding, it is allowed to run to completion. The clock is only then -- restarted. -- -} -- periods :: (MonadIO m, Functor f) => Double -> Stream f m r -> Stream (Stream f m) m r -- periods seconds s = do -- utc <- liftIO getCurrentTime -- loop (addUTCTime cutoff utc) s -- -- where -- cutoff = fromInteger (truncate (1000000000 * seconds)) / 1000000000 -- loop final stream = do -- utc <- liftIO getCurrentTime -- if utc > final -- then loop (addUTCTime cutoff utc) stream -- else case stream of -- Return r -> Return r -- Effect m -> Effect $ liftM (loop final) m -- Step fstr -> Step $ fmap (periods seconds) (cutoff_ final (Step fstr)) -- -- -- do -- -- let sloop s = do -- -- utc' <- liftIO getCurrentTime -- -- if final < utc' -- -- then return s -- -- else case s of -- -- Return r -> Return (Return r) -- -- Effect m -> Effect (liftM sloop m) -- -- Step f -> Step (fmap sloop f) -- -- Step (Step (fmap (fmap (periods seconds) . sloop) fstr)) -- -- str <- m -- -- utc' <- liftIO getCurrentTime -- -- if diffUTCTime utc' utc > (cutoff / 1000000000) -- -- then return (loop utc' str) -- -- else return (loop utc str) -- -- Step fs -> do -- -- let check str = do -- -- utc' <- liftIO getCurrentTime -- -- loop utc' str -- -- -- {-# INLINABLE periods #-} -- -- cutoff_ final str = do -- let loop s = do -- utc' <- liftIO getCurrentTime -- if utc' > final -- then Return s -- else case s of -- Return r -> Return (Return r) -- Effect m -> Effect (liftM loop m) -- Step f -> Step (fmap loop f) -- loop str {- | Repeat a -} untilJust :: (Monad m, Applicative f) => m (Maybe r) -> Stream f m r untilJust act = loop where loop = Effect $ do m <- act case m of Nothing -> return $ Step $ pure loop Just a -> return $ Return a cutoff :: (Monad m, Functor f) => Int -> Stream f m r -> Stream f m (Maybe r) cutoff = loop where loop 0 str = return Nothing loop n str = do e <- lift $ inspect str case e of Left r -> return (Just r) Right (frest) -> Step $ fmap (loop (n-1)) frest