{-# LANGUAGE DeriveFunctor, CPP #-}
module General.Wait(
Wait(Now,Later), runWait, quickly, fromLater,
firstJustWaitUnordered, firstLeftWaitUnordered
) where
import Control.Monad.Extra
import Control.Monad.IO.Class
import Data.IORef.Extra
import Data.List.Extra
import Data.Primitive.Array
import GHC.Exts(RealWorld)
#if __GLASGOW_HASKELL__ >= 800
import Control.Monad.Fail
#endif
runWait :: Monad m => Wait m a -> m (Wait m a)
runWait (Lift x) = runWait =<< x
runWait x = return x
fromLater :: Monad m => Wait m a -> (a -> m ()) -> m ()
fromLater (Lift x) f = do x <- x; fromLater x f
fromLater (Now x) f = f x
fromLater (Later x) f = x f
quickly :: Functor m => m a -> Wait m a
quickly = Lift . fmap Now
data Wait m a = Now a
| Lift (m (Wait m a))
| Later ((a -> m ()) -> m ())
deriving Functor
instance (Monad m, Applicative m) => Applicative (Wait m) where
pure = Now
Now x <*> y = x <$> y
Lift x <*> y = Lift $ (<*> y) <$> x
Later x <*> Now y = Later $ \c -> x $ \x -> c $ x y
Later x <*> Lift y = Lift $ do y <- y; return $ Later x <*> y
Later x <*> Later y = Later $ \c -> x $ \x -> y $ \y -> c $ x y
instance (Monad m, Applicative m) => Monad (Wait m) where
return = pure
(>>) = (*>)
Now x >>= f = f x
Lift x >>= f = Lift $ do x <- x; return $ x >>= f
Later x >>= f = Later $ \c -> x $ \x -> do
x <- runWait $ f x
case x of
Now x -> c x
_ -> fromLater x c
instance (MonadIO m, Applicative m) => MonadIO (Wait m) where
liftIO = Lift . liftIO . fmap Now
#if __GLASGOW_HASKELL__ >= 800
instance MonadFail m => MonadFail (Wait m) where
fail = Lift . Control.Monad.Fail.fail
#endif
firstJustWaitUnordered :: MonadIO m => (a -> Wait m (Maybe b)) -> [a] -> Wait m (Maybe b)
firstJustWaitUnordered f = go [] . map f
where
go :: MonadIO m => [(Maybe a -> m ()) -> m ()] -> [Wait m (Maybe a)] -> Wait m (Maybe a)
go later (x:xs) = case x of
Now (Just a) -> Now $ Just a
Now Nothing -> go later xs
Later l -> go (l:later) xs
Lift x -> Lift $ do
x <- x
return $ go later (x:xs)
go [] [] = Now Nothing
go [l] [] = Later l
go ls [] = Later $ \callback -> do
ref <- liftIO $ newIORef $ length ls
forM_ ls $ \l -> l $ \r -> do
old <- liftIO $ readIORef ref
when (old > 0) $ case r of
Just a -> do
liftIO $ writeIORef' ref 0
callback $ Just a
Nothing -> do
liftIO $ writeIORef' ref $ old-1
when (old == 1) $ callback Nothing
firstLeftWaitUnordered :: (Applicative m, MonadIO m) => (a -> Wait m (Either e b)) -> [a] -> Wait m (Either e [b])
firstLeftWaitUnordered f xs = do
let n = length xs
mut <- liftIO $ newArray n undefined
res <- go mut [] $ zipFrom 0 $ map f xs
case res of
Just e -> return $ Left e
Nothing -> liftIO $ Right <$> mapM (readArray mut) [0..n-1]
where
go :: (Applicative m, MonadIO m) => MutableArray RealWorld b -> [(Int, (Either e b -> m ()) -> m ())] -> [(Int, Wait m (Either e b))] -> Wait m (Maybe e)
go mut later ((i,x):xs) = case x of
Now (Left e) -> Now $ Just e
Now (Right b) -> do
liftIO $ writeArray mut i b
go mut later xs
Later l -> go mut ((i,l):later) xs
Lift x -> Lift $ do
x <- x
return $ go mut later ((i,x):xs)
go _ [] [] = Now Nothing
go mut ls [] = Later $ \callback -> do
ref <- liftIO $ newIORef $ length ls
forM_ ls $ \(i,l) -> l $ \r -> do
old <- liftIO $ readIORef ref
when (old > 0) $ case r of
Left a -> do
liftIO $ writeIORef' ref 0
callback $ Just a
Right v -> do
liftIO $ writeArray mut i v
liftIO $ writeIORef' ref $ old-1
when (old == 1) $ callback Nothing