----------------------------------------------------------------------------- -- | -- Module : Control.Concurrent.QSem -- Copyright : (c) The University of Glasgow 2001 -- License : BSD-style (see the file libraries/base/LICENSE) -- -- Maintainer : libraries@haskell.org -- Stability : experimental -- Portability : non-portable (concurrency) -- -- Simple quantity semaphores. -- ----------------------------------------------------------------------------- module Control.Concurrent.QSem ( -- * Simple Quantity Semaphores QSem, -- abstract newQSem, -- :: Int -> IO QSem waitQSem, -- :: QSem -> IO () signalQSem -- :: QSem -> IO () ) where import Prelude import Control.Concurrent.MVar import Data.Typeable #include "Typeable.h" -- General semaphores are also implemented readily in terms of shared -- @MVar@s, only have to catch the case when the semaphore is tried -- waited on when it is empty (==0). Implement this in the same way as -- shared variables are implemented - maintaining a list of @MVar@s -- representing threads currently waiting. The counter is a shared -- variable, ensuring the mutual exclusion on its access. -- |A 'QSem' is a simple quantity semaphore, in which the available -- \"quantity\" is always dealt with in units of one. newtype QSem = QSem (MVar (Int, [MVar ()])) INSTANCE_TYPEABLE0(QSem,qSemTc,"QSem") -- |Build a new 'QSem' newQSem :: Int -> IO QSem newQSem init = do sem <- newMVar (init,[]) return (QSem sem) -- |Wait for a unit to become available waitQSem :: QSem -> IO () waitQSem (QSem sem) = do (avail,blocked) <- takeMVar sem -- gain ex. access if avail > 0 then putMVar sem (avail-1,[]) else do block <- newEmptyMVar {- Stuff the reader at the back of the queue, so as to preserve waiting order. A signalling process then only have to pick the MVar at the front of the blocked list. The version of waitQSem given in the paper could lead to starvation. -} putMVar sem (0, blocked++[block]) takeMVar block -- |Signal that a unit of the 'QSem' is available signalQSem :: QSem -> IO () signalQSem (QSem sem) = do (avail,blocked) <- takeMVar sem case blocked of [] -> putMVar sem (avail+1,[]) (block:blocked') -> do putMVar sem (0,blocked') putMVar block ()