Safe Haskell | Safe |
---|---|
Language | Haskell2010 |
Extra functions for Control.Concurrent.
This module includes three new types of MVar
, namely Lock
(no associated value),
Var
(never empty) and Barrier
(filled at most once). See
this blog post
for examples and justification.
If you need greater control of exceptions and threads see the slave-thread package. If you need elaborate relationships between threads see the async package.
- module Control.Concurrent
- getNumCapabilities :: IO Int
- setNumCapabilities :: Int -> IO ()
- withNumCapabilities :: Int -> IO a -> IO a
- forkFinally :: IO a -> (Either SomeException a -> IO ()) -> IO ThreadId
- once :: IO a -> IO (IO a)
- onceFork :: IO a -> IO (IO a)
- data Lock
- newLock :: IO Lock
- withLock :: Lock -> IO a -> IO a
- withLockTry :: Lock -> IO a -> IO (Maybe a)
- data Var a
- newVar :: a -> IO (Var a)
- readVar :: Var a -> IO a
- writeVar :: Var a -> a -> IO ()
- modifyVar :: Var a -> (a -> IO (a, b)) -> IO b
- modifyVar_ :: Var a -> (a -> IO a) -> IO ()
- withVar :: Var a -> (a -> IO b) -> IO b
- data Barrier a
- newBarrier :: IO (Barrier a)
- signalBarrier :: Partial => Barrier a -> a -> IO ()
- waitBarrier :: Barrier a -> IO a
- waitBarrierMaybe :: Barrier a -> IO (Maybe a)
Documentation
module Control.Concurrent
getNumCapabilities :: IO Int #
Returns the number of Haskell threads that can run truly
simultaneously (on separate physical processors) at any given time. To change
this value, use setNumCapabilities
.
Since: 4.4.0.0
setNumCapabilities :: Int -> IO () #
Set the number of Haskell threads that can run truly simultaneously
(on separate physical processors) at any given time. The number
passed to forkOn
is interpreted modulo this value. The initial
value is given by the +RTS -N
runtime flag.
This is also the number of threads that will participate in parallel garbage collection. It is strongly recommended that the number of capabilities is not set larger than the number of physical processor cores, and it may often be beneficial to leave one or more cores free to avoid contention with other processes in the machine.
Since: 4.5.0.0
withNumCapabilities :: Int -> IO a -> IO a Source #
On GHC 7.6 and above with the -threaded
flag, brackets a call to setNumCapabilities
.
On lower versions (which lack setNumCapabilities
) this function just runs the argument action.
forkFinally :: IO a -> (Either SomeException a -> IO ()) -> IO ThreadId #
Fork a thread and call the supplied function when the thread is about to terminate, with an exception or a returned value. The function is called with asynchronous exceptions masked.
forkFinally action and_then = mask $ \restore -> forkIO $ try (restore action) >>= and_then
This function is useful for informing the parent when a child terminates, for example.
Since: 4.6.0.0
once :: IO a -> IO (IO a) Source #
Given an action, produce a wrapped action that runs at most once. If the function raises an exception, the same exception will be reraised each time.
let x ||| y = do t1 <- onceFork x; t2 <- onceFork y; t1; t2 \(x :: IO Int) -> void (once x) == return () \(x :: IO Int) -> join (once x) == x \(x :: IO Int) -> (do y <- once x; y; y) == x \(x :: IO Int) -> (do y <- once x; y ||| y) == x
onceFork :: IO a -> IO (IO a) Source #
Like once
, but immediately starts running the computation on a background thread.
\(x :: IO Int) -> join (onceFork x) == x \(x :: IO Int) -> (do a <- onceFork x; a; a) == x
Lock
Like an MVar, but has no value. Used to guarantees single-threaded access, typically to some system resource. As an example:
lock <-newLock
let output =withLock
. putStrLn forkIO $ do ...; output "hello" forkIO $ do ...; output "world"
Here we are creating a lock to ensure that when writing output our messages do not get interleaved. This use of MVar never blocks on a put. It is permissible, but rare, that a withLock contains a withLock inside it - but if so, watch out for deadlocks.
Var
Like an MVar, but must always be full. Used to on a mutable variable in a thread-safe way. As an example:
hits <-newVar
0 forkIO $ do ...;modifyVar_
hits (+1); ... i <-readVar
hits print (HITS,i)
Here we have a variable which we modify atomically, so modifications are not interleaved. This use of MVar never blocks on a put. No modifyVar operation should ever block, and they should always complete in a reasonable timeframe. A Var should not be used to protect some external resource, only the variable contained within. Information from a readVar should not be subsequently inserted back into the Var.
modifyVar :: Var a -> (a -> IO (a, b)) -> IO b Source #
Modify a Var
producing a new value and a return result.
Barrier
Starts out empty, then is filled exactly once. As an example:
bar <-newBarrier
forkIO $ do ...; val <- ...;signalBarrier
bar val print =<<waitBarrier
bar
Here we create a barrier which will contain some computed value. A thread is forked to fill the barrier, while the main thread waits for it to complete. A barrier has similarities to a future or promise from other languages, has been known as an IVar in other Haskell work, and in some ways is like a manually managed thunk.
signalBarrier :: Partial => Barrier a -> a -> IO () Source #
Write a value into the Barrier, releasing anyone at waitBarrier
.
Any subsequent attempts to signal the Barrier
will throw an exception.
waitBarrier :: Barrier a -> IO a Source #
Wait until a barrier has been signaled with signalBarrier
.
waitBarrierMaybe :: Barrier a -> IO (Maybe a) Source #
A version of waitBarrier
that never blocks, returning Nothing
if the barrier has not yet been signaled.