{-# LANGUAGE CPP, DeriveDataTypeable, NoImplicitPrelude, UnicodeSyntax #-} -------------------------------------------------------------------------------- -- | -- Module : Control.Concurrent.Lock -- Copyright : (c) 2010 Bas van Dijk & Roel van Dijk -- License : BSD3 (see the file LICENSE) -- Maintainer : Bas van Dijk <v.dijk.bas@gmail.com> -- , Roel van Dijk <vandijk.roel@gmail.com> -- -- This module provides the 'Lock' synchronisation mechanism. It was inspired by -- the Python and Java @Lock@ objects and should behave in a similar way. See: -- -- <http://docs.python.org/3.1/library/threading.html#lock-objects> -- -- and: -- -- <http://java.sun.com/javase/7/docs/api/java/util/concurrent/locks/Lock.html> -- -- All functions are /exception safe/. Throwing asynchronous exceptions will not -- compromise the internal state of a 'Lock'. -- -- This module is intended to be imported qualified. We suggest importing it like: -- -- @ -- import Control.Concurrent.Lock ( Lock ) -- import qualified Control.Concurrent.Lock as Lock ( ... ) -- @ -- -------------------------------------------------------------------------------- module Control.Concurrent.Lock ( Lock -- * Creating locks , new , newAcquired -- * Locking and unlocking , acquire , tryAcquire , release -- * Convenience functions , with , tryWith , wait -- * Querying locks , locked ) where -------------------------------------------------------------------------------- -- Imports -------------------------------------------------------------------------------- -- from base: import Control.Applicative ( liftA2 ) import Control.Concurrent.MVar ( MVar, newMVar, newEmptyMVar , takeMVar, tryTakeMVar , putMVar, tryPutMVar , isEmptyMVar ) import Control.Exception ( bracket_, onException ) import Control.Monad ( Monad, return, (>>), when ) import Data.Bool ( Bool, not ) #ifdef __HADDOCK__ import Data.Bool ( Bool(False, True) ) #endif import Data.Eq ( Eq ) import Data.Function ( ($) ) import Data.Functor ( fmap, (<$>) ) import Data.Maybe ( Maybe(Nothing, Just), isJust ) import Data.Typeable ( Typeable ) import Prelude ( error ) import System.IO ( IO ) #if __GLASGOW_HASKELL__ < 700 import Control.Monad ( (>>=), fail ) #endif -- from base-unicode-symbols: import Data.Function.Unicode ( (∘) ) -- from concurrent-extra (this package): import Utils ( mask, mask_ ) -------------------------------------------------------------------------------- -- Locks -------------------------------------------------------------------------------- -- | A lock is in one of two states: \"locked\" or \"unlocked\". newtype Lock = Lock {un ∷ MVar ()} deriving (Eq, Typeable) -------------------------------------------------------------------------------- -- Creating locks -------------------------------------------------------------------------------- -- | Create a lock in the \"unlocked\" state. new ∷ IO Lock new = Lock <$> newMVar () -- | Create a lock in the \"locked\" state. newAcquired ∷ IO Lock newAcquired = Lock <$> newEmptyMVar -------------------------------------------------------------------------------- -- Locking and unlocking -------------------------------------------------------------------------------- {-| Acquires the 'Lock'. Blocks if another thread has acquired the 'Lock'. @acquire@ behaves as follows: * When the state is \"unlocked\" @acquire@ changes the state to \"locked\". * When the state is \"locked\" @acquire@ /blocks/ until a call to 'release' in another thread wakes the calling thread. Upon awakening it will change the state to \"locked\". There are two further important properties of @acquire@: * @acquire@ is single-wakeup. That is, if there are multiple threads blocked on @acquire@ and the lock is released, only one thread will be woken up. The runtime guarantees that the woken thread completes its @acquire@ operation. * When multiple threads are blocked on @acquire@, they are woken up in FIFO order. This is useful for providing fairness properties of abstractions built using locks. (Note that this differs from the Python implementation where the wake-up order is undefined.) -} acquire ∷ Lock → IO () acquire = takeMVar ∘ un {-| A non-blocking 'acquire'. * When the state is \"unlocked\" @tryAcquire@ changes the state to \"locked\" and returns 'True'. * When the state is \"locked\" @tryAcquire@ leaves the state unchanged and returns 'False'. -} tryAcquire ∷ Lock → IO Bool tryAcquire = fmap isJust ∘ tryTakeMVar ∘ un {-| @release@ changes the state to \"unlocked\" and returns immediately. Note that it is an error to release a lock in the \"unlocked\" state! If there are any threads blocked on 'acquire' the thread that first called @acquire@ will be woken up. -} release ∷ Lock → IO () release (Lock mv) = do b ← tryPutMVar mv () when (not b) $ error "Control.Concurrent.Lock.release: Can't release unlocked Lock!" -------------------------------------------------------------------------------- -- Convenience functions -------------------------------------------------------------------------------- {-| A convenience function which first acquires the lock and then performs the computation. When the computation terminates, whether normally or by raising an exception, the lock is released. Note that: @with = 'liftA2' 'bracket_' 'acquire' 'release'@. -} with ∷ Lock → IO a → IO a with = liftA2 bracket_ acquire release {-| A non-blocking 'with'. @tryWith@ is a convenience function which first tries to acquire the lock. If that fails, 'Nothing' is returned. If it succeeds, the computation is performed. When the computation terminates, whether normally or by raising an exception, the lock is released and 'Just' the result of the computation is returned. -} tryWith ∷ Lock → IO α → IO (Maybe α) tryWith l a = mask $ \restore → do acquired ← tryAcquire l if acquired then do r ← restore a `onException` release l release l return $ Just r else return Nothing {-| * When the state is \"locked\", @wait@ /blocks/ until a call to 'release' in another thread changes it to \"unlocked\". * When the state is \"unlocked\" @wait@ returns immediately. @wait@ does not alter the state of the lock. Note that @wait@ is just a convenience function we can be defined as: @wait l = 'block' '$' 'acquire' l '>>' 'release' l@ -} wait ∷ Lock → IO () wait (Lock mv) = mask_ $ takeMVar mv >> putMVar mv () -------------------------------------------------------------------------------- -- Querying locks -------------------------------------------------------------------------------- {-| Determines if the lock is in the \"locked\" state. Note that this is only a snapshot of the state. By the time a program reacts on its result it may already be out of date. -} locked ∷ Lock → IO Bool locked = isEmptyMVar ∘ un -- The End ---------------------------------------------------------------------