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