{-# LANGUAGE Trustworthy #-} {-# LANGUAGE CPP #-} #ifdef __GLASGOW_HASKELL__ {-# LANGUAGE DeriveDataTypeable, BangPatterns #-} #endif {-# OPTIONS_GHC -funbox-strict-fields #-} ----------------------------------------------------------------------------- -- | -- Module : Control.Concurrent.QSemN -- 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) -- -- Quantity semaphores in which each thread may wait for an arbitrary -- \"amount\". -- ----------------------------------------------------------------------------- module Control.Concurrent.QSemN ( -- * General Quantity Semaphores QSemN, -- abstract newQSemN, -- :: Int -> IO QSemN waitQSemN, -- :: QSemN -> Int -> IO () signalQSemN -- :: QSemN -> Int -> IO () ) where import Control.Concurrent.MVar ( MVar, newEmptyMVar, takeMVar, tryTakeMVar , putMVar, newMVar , tryPutMVar, isEmptyMVar) import Data.Typeable import Control.Exception import Data.Maybe -- | 'QSemN' is a quantity semaphore in which the resource is aqcuired -- and released in units of one. It provides guaranteed FIFO ordering -- for satisfying blocked `waitQSemN` calls. -- -- The pattern -- -- > bracket_ (waitQSemN n) (signalQSemN n) (...) -- -- is safe; it never loses any of the resource. -- data QSemN = QSemN !(MVar (Int, [(Int, MVar ())], [(Int, MVar ())])) deriving Typeable -- The semaphore state (i, xs, ys): -- -- i is the current resource value -- -- (xs,ys) is the queue of blocked threads, where the queue is -- given by xs ++ reverse ys. We can enqueue new blocked threads -- by consing onto ys, and dequeue by removing from the head of xs. -- -- A blocked thread is represented by an empty (MVar ()). To unblock -- the thread, we put () into the MVar. -- -- A thread can dequeue itself by also putting () into the MVar, which -- it must do if it receives an exception while blocked in waitQSemN. -- This means that when unblocking a thread in signalQSemN we must -- first check whether the MVar is already full; the MVar lock on the -- semaphore itself resolves race conditions between signalQSemN and a -- thread attempting to dequeue itself. -- |Build a new 'QSemN' with a supplied initial quantity. -- The initial quantity must be at least 0. newQSemN :: Int -> IO QSemN newQSemN initial | initial < 0 = fail "newQSemN: Initial quantity must be non-negative" | otherwise = do sem <- newMVar (initial, [], []) return (QSemN sem) -- |Wait for the specified quantity to become available waitQSemN :: QSemN -> Int -> IO () waitQSemN (QSemN m) sz = mask_ $ do (i,b1,b2) <- takeMVar m let z = i-sz if z < 0 then do b <- newEmptyMVar putMVar m (i, b1, (sz,b):b2) wait b else do putMVar m (z, b1, b2) return () where wait b = do takeMVar b `onException` (uninterruptibleMask_ $ do -- Note [signal uninterruptible] (i,b1,b2) <- takeMVar m r <- tryTakeMVar b r' <- if isJust r then signal sz (i,b1,b2) else do putMVar b (); return (i,b1,b2) putMVar m r') -- |Signal that a given quantity is now available from the 'QSemN'. signalQSemN :: QSemN -> Int -> IO () signalQSemN (QSemN m) sz = uninterruptibleMask_ $ do r <- takeMVar m r' <- signal sz r putMVar m r' signal :: Int -> (Int,[(Int,MVar ())],[(Int,MVar ())]) -> IO (Int,[(Int,MVar ())],[(Int,MVar ())]) signal sz0 (i,a1,a2) = loop (sz0 + i) a1 a2 where loop 0 bs b2 = return (0, bs, b2) loop sz [] [] = return (sz, [], []) loop sz [] b2 = loop sz (reverse b2) [] loop sz ((j,b):bs) b2 | j > sz = do r <- isEmptyMVar b if r then return (sz, (j,b):bs, b2) else loop sz bs b2 | otherwise = do r <- tryPutMVar b () if r then loop (sz-j) bs b2 else loop sz bs b2