{-# LANGUAGE RecordWildCards, RecursiveDo, BangPatterns, ScopedTypeVariables #-}
module Reactive.Banana.Prim.Plumbing where
import Control.Monad (join)
import Control.Monad.IO.Class
import Control.Monad.Trans.Class
import qualified Control.Monad.Trans.RWSIO as RWS
import qualified Control.Monad.Trans.Reader as Reader
import qualified Control.Monad.Trans.ReaderWriterIO as RW
import Data.Function (on)
import Data.Functor
import Data.IORef
import Data.List (sortBy)
import Data.Monoid
import qualified Data.Vault.Lazy as Lazy
import System.IO.Unsafe
import qualified Reactive.Banana.Prim.Dependencies as Deps
import Reactive.Banana.Prim.Types
import Reactive.Banana.Prim.Util
newPulse :: String -> EvalP (Maybe a) -> Build (Pulse a)
newPulse name eval = liftIO $ do
key <- Lazy.newKey
newRef $ Pulse
{ _keyP = key
, _seenP = agesAgo
, _evalP = eval
, _childrenP = []
, _parentsP = []
, _levelP = ground
, _nameP = name
}
neverP :: Build (Pulse a)
neverP = liftIO $ do
key <- Lazy.newKey
newRef $ Pulse
{ _keyP = key
, _seenP = agesAgo
, _evalP = return Nothing
, _childrenP = []
, _parentsP = []
, _levelP = ground
, _nameP = "neverP"
}
pureL :: a -> Latch a
pureL a = unsafePerformIO $ newRef $ Latch
{ _seenL = beginning
, _valueL = a
, _evalL = return a
}
newLatch :: forall a. a -> Build (Pulse a -> Build (), Latch a)
newLatch a = mdo
latch <- liftIO $ newRef $ Latch
{ _seenL = beginning
, _valueL = a
, _evalL = do
Latch {..} <- readRef latch
RW.tell _seenL
return _valueL
}
let
err = error "incorrect Latch write"
updateOn :: Pulse a -> Build ()
updateOn p = do
w <- liftIO $ mkWeakRefValue latch latch
lw <- liftIO $ newRef $ LatchWrite
{ _evalLW = maybe err id <$> readPulseP p
, _latchLW = w
}
_ <- liftIO $ mkWeakRefValue latch lw
(P p) `addChild` (L lw)
return (updateOn, latch)
cachedLatch :: EvalL a -> Latch a
cachedLatch eval = unsafePerformIO $ mdo
latch <- newRef $ Latch
{ _seenL = agesAgo
, _valueL = error "Undefined value of a cached latch."
, _evalL = do
Latch{..} <- liftIO $ readRef latch
(a,time) <- RW.listen eval
liftIO $ if time <= _seenL
then return _valueL
else do
let _seenL = time
let _valueL = a
a `seq` put latch (Latch {..})
return a
}
return latch
addOutput :: Pulse EvalO -> Build ()
addOutput p = do
o <- liftIO $ newRef $ Output
{ _evalO = maybe (return $ debug "nop") id <$> readPulseP p
}
(P p) `addChild` (O o)
RW.tell $ BuildW (mempty, [o], mempty, mempty)
runBuildIO :: BuildR -> BuildIO a -> IO (a, Action, [Output])
runBuildIO i m = {-# SCC runBuild #-} do
(a, BuildW (topologyUpdates, os, liftIOLaters, _)) <- unfold mempty m
doit $ liftIOLaters
return (a,Action $ Deps.buildDependencies topologyUpdates,os)
where
unfold :: BuildW -> BuildIO a -> IO (a, BuildW)
unfold w m = do
(a, BuildW (w1, w2, w3, later)) <- RW.runReaderWriterIOT m i
let w' = w <> BuildW (w1,w2,w3,mempty)
w'' <- case later of
Just m -> snd <$> unfold w' m
Nothing -> return w'
return (a,w'')
buildLater :: Build () -> Build ()
buildLater x = RW.tell $ BuildW (mempty, mempty, mempty, Just x)
buildLaterReadNow :: Build a -> Build a
buildLaterReadNow m = do
ref <- liftIO $ newIORef $
error "buildLaterReadNow: Trying to read before it is written."
buildLater $ m >>= liftIO . writeIORef ref
liftIO $ unsafeInterleaveIO $ readIORef ref
liftBuild :: Build a -> BuildIO a
liftBuild = id
getTimeB :: Build Time
getTimeB = (\(x,_) -> x) <$> RW.ask
alwaysP :: Build (Pulse ())
alwaysP = (\(_,x) -> x) <$> RW.ask
readLatchB :: Latch a -> Build a
readLatchB = liftIO . readLatchIO
dependOn :: Pulse child -> Pulse parent -> Build ()
dependOn child parent = (P parent) `addChild` (P child)
keepAlive :: Pulse child -> Pulse parent -> Build ()
keepAlive child parent = liftIO $ mkWeakRefValue child parent >> return ()
addChild :: SomeNode -> SomeNode -> Build ()
addChild parent child =
RW.tell $ BuildW (Deps.addChild parent child, mempty, mempty, mempty)
changeParent :: Pulse child -> Pulse parent -> Build ()
changeParent node parent =
RW.tell $ BuildW (Deps.changeParent node parent, mempty, mempty, mempty)
liftIOLater :: IO () -> Build ()
liftIOLater x = RW.tell $ BuildW (mempty, mempty, Action x, mempty)
readLatchIO :: Latch a -> IO a
readLatchIO latch = do
Latch{..} <- readRef latch
liftIO $ fst <$> RW.runReaderWriterIOT _evalL ()
getValueL :: Latch a -> EvalL a
getValueL latch = do
Latch{..} <- readRef latch
_evalL
runEvalP :: Lazy.Vault -> EvalP a -> Build (a, EvalPW)
runEvalP s1 m = RW.readerWriterIOT $ \r2 -> do
(a,_,(w1,w2)) <- RWS.runRWSIOT m r2 s1
return ((a,w1), w2)
liftBuildP :: Build a -> EvalP a
liftBuildP m = RWS.rwsT $ \r2 s -> do
(a,w2) <- RW.runReaderWriterIOT m r2
return (a,s,(mempty,w2))
askTime :: EvalP Time
askTime = fst <$> RWS.ask
readPulseP :: Pulse a -> EvalP (Maybe a)
readPulseP p = do
Pulse{..} <- readRef p
join . Lazy.lookup _keyP <$> RWS.get
writePulseP :: Lazy.Key (Maybe a) -> Maybe a -> EvalP ()
writePulseP key a = do
s <- RWS.get
RWS.put $ Lazy.insert key a s
readLatchP :: Latch a -> EvalP a
readLatchP = liftBuildP . readLatchB
readLatchFutureP :: Latch a -> EvalP (Future a)
readLatchFutureP = return . readLatchIO
rememberLatchUpdate :: IO () -> EvalP ()
rememberLatchUpdate x = RWS.tell ((Action x,mempty),mempty)
rememberOutput :: (Output, EvalO) -> EvalP ()
rememberOutput x = RWS.tell ((mempty,[x]),mempty)
unwrapEvalP :: RWS.Tuple r w s -> RWS.RWSIOT r w s m a -> m a
unwrapEvalP r m = RWS.run m r
wrapEvalP :: (RWS.Tuple r w s -> m a) -> RWS.RWSIOT r w s m a
wrapEvalP m = RWS.R m