dejafu/Control/Monad/Conc/Fixed.hs

315 lines
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Haskell
Executable File

{-# LANGUAGE ExistentialQuantification #-}
{-# LANGUAGE GeneralizedNewtypeDeriving #-}
{-# LANGUAGE MultiParamTypeClasses #-}
{-# LANGUAGE RankNTypes #-}
-- | Concurrent monads with a fixed scheduler.
module Control.Monad.Conc.Fixed
( -- * The Conc Monad
Conc
, runConc
, runConc'
, liftIO
, spawn
, fork
-- * Communication: CVars
, CVar
, new
, put
, get
, take
, tryTake
-- * Scheduling
, Scheduler
, ThreadId
, randomSched
, randomSchedNP
, roundRobinSched
, roundRobinSchedNP
) where
import Prelude hiding (take)
import Control.Applicative (Applicative(..), (<$>))
import Control.Concurrent.MVar (MVar, newEmptyMVar, putMVar, takeMVar, tryTakeMVar)
import Control.Monad.Cont (Cont, cont, runCont)
import Data.Map (Map)
import Data.Maybe (fromJust, fromMaybe, isNothing, isJust)
import Data.IORef (IORef, newIORef, readIORef, writeIORef, modifyIORef')
import System.Random (RandomGen, randomR)
import qualified Control.Monad.Conc.Class as C
import qualified Control.Monad.IO.Class as IO
import qualified Data.Map as M
-- | Scheduling is done in terms of a trace of 'Action's. Blocking can
-- only occur as a result of an action, and they cover (most of) the
-- primitives of the concurrency. `spawn` is absent as it can be
-- derived from `new`, `fork` and `put`.
data Action =
Fork Action Action
| forall t a. Put (CVar t a) a Action
| forall t a. Get (CVar t a) (a -> Action)
| forall t a. Take (CVar t a) (a -> Action)
| forall t a. TryTake (CVar t a) (Maybe a -> Action)
| Lift (IO Action)
| Stop
-- | The @Conc@ monad itself. Under the hood, this uses continuations
-- so it's able to interrupt and resume a monadic computation at any
-- point where a primitive is used.
--
-- This uses the same universally-quantified indexing state trick as
-- used by 'ST' and 'STRef's to prevent mutable references from
-- leaking out of the monad. See 'runConc' for an example of what this
-- means.
newtype Conc t a = C (Cont (Action) a) deriving (Functor, Applicative, Monad)
instance IO.MonadIO (Conc t) where
liftIO = liftIO
instance C.ConcFuture (CVar t) (Conc t) where
spawn = spawn
get = get
instance C.ConcCVar (CVar t) (Conc t) where
fork = fork
new = new
put = put
take = take
tryTake = tryTake
-- | The concurrent variable type used with the 'Conc'
-- monad. Internally, these are implemented as 'IORef's, but they are
-- structured to behave fairly similarly to 'MVar's. One notable
-- difference is that 'MVar's are single-wakeup, and wake up in a FIFO
-- order. Writing to a @CVar@ wakes up all threads blocked on reading
-- it, and it is up to the scheduler which one runs next. Taking from
-- a @CVar@ behaves analogously.
newtype CVar t a = V (IORef (Maybe a, [Block])) deriving Eq
-- | Lift an 'IO' action into the 'Conc' monad.
--
-- Caution! Blocking on the action of another thread in @liftIO@
-- cannot be detected! So if you perform some potentially blocking
-- action in a 'liftIO' the entire collection of threads may deadlock!
-- You should therefore keep 'IO' blocks small, and only perform
-- blocking operations with the supplied primitives, insofar as
-- possible.
liftIO :: IO a -> Conc t a
liftIO ma = C $ cont lifted where
lifted c = Lift $ c <$> ma
-- | Run the provided computation concurrently, returning the result.
spawn :: Conc t a -> Conc t (CVar t a)
spawn ma = do
cvar <- new
fork $ ma >>= put cvar
return cvar
-- | Block on a 'CVar' until it is full, then read from it (without
-- emptying).
get :: CVar t a -> Conc t a
get cvar = C $ cont $ Get cvar
-- | Run the provided computation concurrently.
fork :: Conc t () -> Conc t ()
fork (C ma) = C $ cont $ \c -> Fork (runCont ma $ const Stop) $ c ()
-- | Create a new empty 'CVar'.
new :: Conc t (CVar t a)
new = liftIO $ do
ioref <- newIORef (Nothing, [])
return $ V ioref
-- | Block on a 'CVar' until it is empty, then write to it.
put :: CVar t a -> a -> Conc t ()
put cvar a = C $ cont $ \c -> Put cvar a $ c ()
-- | Block on a 'CVar' until it is full, then read from it (with
-- emptying).
take :: CVar t a -> Conc t a
take cvar = C $ cont $ Take cvar
-- | Read a value from a 'CVar' if there is one, without blocking.
tryTake :: CVar t a -> Conc t (Maybe a)
tryTake cvar = C $ cont $ TryTake cvar
-- | Every thread has a unique identitifer. These are implemented as
-- integers, but you shouldn't assume they are necessarily contiguous.
type ThreadId = Int
-- | A @Scheduler@ maintains some internal state, `s`, takes the
-- 'ThreadId' of the last thread scheduled, and the list of runnable
-- threads (which will never be empty). It produces a 'ThreadId' to
-- schedule, and a new state.
--
-- Note: In order to prevent deadlock, the 'Conc' runtime will assume
-- that a deadlock situation has arisen if the scheduler attempts to
-- (a) schedule a blocked thread, or (b) schedule a nonexistant
-- thread. In either of those cases, the computation will be halted.
type Scheduler s = s -> ThreadId -> [ThreadId] -> (ThreadId, s)
-- | Run a concurrent computation with a given 'Scheduler' and initial
-- state, returning `Just result` if it terminates, and `Nothing` if a
-- deadlock is detected.
--
-- Note how the `t` in 'Conc' is universally quantified, what this
-- means in practice is that you can't do something like this:
--
-- > runConc (\s _ (x:_) -> (x, s)) () $ new >>= return
--
-- So 'CVar's cannot leak out of the 'Conc' computation. If this is
-- making your head hurt, check out the \"How `runST` works\" section
-- of <https://ocharles.org.uk/blog/guest-posts/2014-12-18-rank-n-types.html>
runConc :: Scheduler s -> s -> (forall t. Conc t a) -> IO (Maybe a)
runConc sched s ma = fst <$> runConc' sched s ma
-- | variant of 'runConc' which returns the final state of the
-- scheduler.
runConc' :: Scheduler s -> s -> (forall t. Conc t a) -> IO (Maybe a, s)
runConc' sched s ma = do
mvar <- newEmptyMVar
let (C c) = ma >>= liftIO . putMVar mvar . Just
s' <- runThreads (negate 1) sched s (M.fromList [(0, (runCont c $ const Stop, False))]) mvar
out <- takeMVar mvar
return (out, s')
-- | A simple random scheduler which, at every step, picks a random
-- thread to run.
randomSched :: RandomGen g => Scheduler g
randomSched g _ threads = (threads !! choice, g') where
(choice, g') = randomR (0, length threads - 1) g
-- | A random scheduler which doesn't pre-empt the running
-- thread. That is, if the last thread scheduled is still runnable,
-- run that, otherwise schedule randomly.
randomSchedNP :: RandomGen g => Scheduler g
randomSchedNP = makeNP randomSched
-- | A round-robin scheduler which, at every step, schedules the
-- thread with the next 'ThreadId'.
roundRobinSched :: Scheduler ()
roundRobinSched _ last threads
| last >= maximum threads = (minimum threads, ())
| otherwise = (minimum $ filter (<=last) threads, ())
-- | A round-robin scheduler which doesn't pre-empt the running
-- thread.
roundRobinSchedNP :: Scheduler ()
roundRobinSchedNP = makeNP roundRobinSched
-- | Turn a potentially pre-emptive scheduler into a non-preemptive
-- one.
makeNP :: Scheduler s -> Scheduler s
makeNP sched = newsched where
newsched s last threads
| last `elem` threads = (last, s)
| otherwise = sched s last threads
-------------------- Internal stuff --------------------
-- | A @Block@ is used to determine what sort of block a thread is
-- experiencing.
data Block = WaitFull ThreadId | WaitEmpty ThreadId deriving Eq
-- | Run a collection of threads, until there are no threads left.
--
-- A thread is represented as a tuple of (next action, is blocked).
runThreads :: ThreadId -> Scheduler s -> s -> Map ThreadId (Action, Bool) -> MVar (Maybe a) -> IO s
runThreads last sched s threads mvar
| M.null threads = return s
| M.null runnable = do
-- If we're here, it's possible the main thread has terminated
-- successfully, in which case we DON'T have a deadlock.
val <- fromMaybe Nothing <$> tryTakeMVar mvar
putMVar mvar val
return s
| isBlocked = putStrLn "Attempted to run a blocked thread, assuming deadlock." >> putMVar mvar Nothing >> return s
| isNothing thread = putStrLn "Attempted to run a nonexistant thread, assuming deadlock." >> putMVar mvar Nothing >> return s
| otherwise = do
threads <- runThread (fst $ fromJust thread, chosen) threads
runThreads chosen sched s' threads mvar
where
(chosen, s') = if last == -1 then (0, s) else sched s last $ M.keys runnable
runnable = M.filter (not . snd) threads
thread = M.lookup chosen threads
isBlocked = snd . fromJust $ M.lookup chosen threads
-- | Run a single thread one step, by dispatching on the type of
-- 'Action'.
runThread :: (Action, ThreadId) -> Map ThreadId (Action, Bool) -> IO (Map ThreadId (Action, Bool))
runThread (Fork a b, i) threads = return . goto b i $ launch a threads
runThread (Put v a c, i) threads = do
let (V ref) = v
(val, blocks) <- readIORef ref
case val of
Just _ -> block v WaitEmpty i threads
Nothing -> do
writeIORef ref (Just a, blocks)
goto c i <$> wake v WaitFull threads
runThread (Get v c, i) threads = do
let (V ref) = v
(val, _) <- readIORef ref
case val of
Just val' -> return $ goto (c val') i threads
Nothing -> block v WaitFull i threads
runThread (Take v c, i) threads = do
let (V ref) = v
(val, blocks) <- readIORef ref
case val of
Just val' -> do
writeIORef ref (Nothing, blocks)
goto (c val') i <$> wake v WaitEmpty threads
Nothing -> block v WaitFull i threads
runThread (TryTake v c, i) threads = do
let (V ref) = v
(val, _) <- readIORef ref
return $ goto (c val) i threads
runThread (Lift io, i) threads = do
a <- io
return $ goto a i threads
runThread (Stop, i) threads = return $ kill i threads
-- | Replace the 'Action' of a thread.
goto :: Ord k => a -> k -> Map k (a, b) -> Map k (a, b)
goto a = M.alter $ \(Just (_, b)) -> Just (a, b)
-- | Block a thread on a 'CVar'.
block :: Ord k => CVar t v -> (k -> Block) -> k -> Map k (a, Bool) -> IO (Map k (a, Bool))
block (V ref) typ tid threads = do
(val, blocks) <- readIORef ref
writeIORef ref (val, typ tid : blocks)
return $ M.alter (\(Just (a, _)) -> Just (a, True)) tid threads
-- | Start a thread with the next free ID.
launch :: (Ord k, Enum k) => a -> Map k (a, Bool) -> Map k (a, Bool)
launch a m = M.insert (succ . maximum $ M.keys m) (a, False) m
-- | Kill a thread.
kill :: Ord k => k -> Map k (a, b) -> Map k (a, b)
kill = M.delete
-- | Wake every thread blocked on a 'CVar' read.
wake :: Ord k => CVar t v -> (k -> Block) -> Map k (a, Bool) -> IO (Map k (a, Bool))
wake (V ref) typ = fmap M.fromList . mapM wake . M.toList where
wake a@(tid, (act, True)) = do
let block = typ tid
(val, blocks) <- readIORef ref
if block `elem` blocks
then writeIORef ref (val, filter (/= block) blocks) >> return (tid, (act, False))
else return a
wake a = return a