Portability | non-portable (GHC extensions) |
---|---|
Stability | internal |
Maintainer | cvs-ghc@haskell.org |
Basic concurrency stuff.
- data ThreadId = ThreadId ThreadId#
- forkIO :: IO () -> IO ThreadId
- forkIOUnmasked :: IO () -> IO ThreadId
- forkIOWithUnmask :: ((forall a. IO a -> IO a) -> IO ()) -> IO ThreadId
- forkOn :: Int -> IO () -> IO ThreadId
- forkOnIO :: Int -> IO () -> IO ThreadId
- forkOnIOUnmasked :: Int -> IO () -> IO ThreadId
- forkOnWithUnmask :: Int -> ((forall a. IO a -> IO a) -> IO ()) -> IO ThreadId
- numCapabilities :: Int
- getNumCapabilities :: IO Int
- numSparks :: IO Int
- childHandler :: SomeException -> IO ()
- myThreadId :: IO ThreadId
- killThread :: ThreadId -> IO ()
- throwTo :: Exception e => ThreadId -> e -> IO ()
- par :: a -> b -> b
- pseq :: a -> b -> b
- runSparks :: IO ()
- yield :: IO ()
- labelThread :: ThreadId -> String -> IO ()
- data ThreadStatus
- data BlockReason
- threadStatus :: ThreadId -> IO ThreadStatus
- threadCapability :: ThreadId -> IO (Int, Bool)
- newtype STM a = STM (State# RealWorld -> (#State# RealWorld, a#))
- atomically :: STM a -> IO a
- retry :: STM a
- orElse :: STM a -> STM a -> STM a
- throwSTM :: Exception e => e -> STM a
- catchSTM :: Exception e => STM a -> (e -> STM a) -> STM a
- alwaysSucceeds :: STM a -> STM ()
- always :: STM Bool -> STM ()
- data TVar a = TVar (TVar# RealWorld a)
- newTVar :: a -> STM (TVar a)
- newTVarIO :: a -> IO (TVar a)
- readTVar :: TVar a -> STM a
- readTVarIO :: TVar a -> IO a
- writeTVar :: TVar a -> a -> STM ()
- unsafeIOToSTM :: IO a -> STM a
- withMVar :: MVar a -> (a -> IO b) -> IO b
- modifyMVar_ :: MVar a -> (a -> IO a) -> IO ()
- setUncaughtExceptionHandler :: (SomeException -> IO ()) -> IO ()
- getUncaughtExceptionHandler :: IO (SomeException -> IO ())
- reportError :: SomeException -> IO ()
- reportStackOverflow :: IO ()
- sharedCAF :: a -> (Ptr a -> IO (Ptr a)) -> IO a
Documentation
A ThreadId
is an abstract type representing a handle to a thread.
ThreadId
is an instance of Eq
, Ord
and Show
, where
the Ord
instance implements an arbitrary total ordering over
ThreadId
s. The Show
instance lets you convert an arbitrary-valued
ThreadId
to string form; showing a ThreadId
value is occasionally
useful when debugging or diagnosing the behaviour of a concurrent
program.
Note: in GHC, if you have a ThreadId
, you essentially have
a pointer to the thread itself. This means the thread itself can't be
garbage collected until you drop the ThreadId
.
This misfeature will hopefully be corrected at a later date.
Note: Hugs does not provide any operations on other threads;
it defines ThreadId
as a synonym for ().
Forking and suchlike
forkIO :: IO () -> IO ThreadIdSource
Sparks off a new thread to run the IO
computation passed as the
first argument, and returns the ThreadId
of the newly created
thread.
The new thread will be a lightweight thread; if you want to use a foreign
library that uses thread-local storage, use Control.Concurrent.forkOS
instead.
GHC note: the new thread inherits the masked state of the parent
(see Control.Exception.mask
).
The newly created thread has an exception handler that discards the
exceptions BlockedIndefinitelyOnMVar
, BlockedIndefinitelyOnSTM
, and
ThreadKilled
, and passes all other exceptions to the uncaught
exception handler (see setUncaughtExceptionHandler
).
forkIOUnmasked :: IO () -> IO ThreadIdSource
This function is deprecated; use forkIOWIthUnmask
instead
forkIOWithUnmask :: ((forall a. IO a -> IO a) -> IO ()) -> IO ThreadIdSource
Like forkIO
, but the child thread is passed a function that can
be used to unmask asynchronous exceptions. This function is
typically used in the following way
... mask_ $ forkIOWithUnmask $ \unmask -> catch (unmask ...) handler
so that the exception handler in the child thread is established with asynchronous exceptions masked, meanwhile the main body of the child thread is executed in the unmasked state.
Note that the unmask function passed to the child thread should only be used in that thread; the behaviour is undefined if it is invoked in a different thread.
forkOn :: Int -> IO () -> IO ThreadIdSource
Like forkIO
, but lets you specify on which processor the thread
should run. Unlike a forkIO
thread, a thread created by forkOn
will stay on the same processor for its entire lifetime (forkIO
threads can migrate between processors according to the scheduling
policy). forkOn
is useful for overriding the scheduling policy when
you know in advance how best to distribute the threads.
The Int
argument specifies a capability number (see
getNumCapabilities
). Typically capabilities correspond to physical
processors, but the exact behaviour is implementation-dependent. The
value passed to forkOn
is interpreted modulo the total number of
capabilities as returned by getNumCapabilities
.
GHC note: the number of capabilities is specified by the +RTS -N
option when the program is started. Capabilities can be fixed to
actual processor cores with +RTS -qa
if the underlying operating
system supports that, although in practice this is usually unnecessary
(and may actually degrade perforamnce in some cases - experimentation
is recommended).
forkOnIOUnmasked :: Int -> IO () -> IO ThreadIdSource
This function is deprecated; use forkOnWIthUnmask
instead
forkOnWithUnmask :: Int -> ((forall a. IO a -> IO a) -> IO ()) -> IO ThreadIdSource
Like forkIOWithUnmask
, but the child thread is pinned to the
given CPU, as with forkOn
.
the value passed to the +RTS -N
flag. This is the number of
Haskell threads that can run truly simultaneously at any given
time, and is typically set to the number of physical processor cores on
the machine.
Strictly speaking it is better to use getNumCapabilities
, because
the number of capabilities might vary at runtime.
getNumCapabilities :: IO IntSource
Returns 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.
An implementation in which Haskell threads are mapped directly to
OS threads might return the number of physical processor cores in
the machine, and forkOn
would be implemented using the OS's
affinity facilities. An implementation that schedules Haskell
threads onto a smaller number of OS threads (like GHC) would return
the number of such OS threads that can be running simultaneously.
GHC notes: this returns the number passed as the argument to the
+RTS -N
flag. In current implementations, the value is fixed
when the program starts and never changes, but it is possible that
in the future the number of capabilities might vary at runtime.
childHandler :: SomeException -> IO ()Source
myThreadId :: IO ThreadIdSource
Returns the ThreadId
of the calling thread (GHC only).
killThread :: ThreadId -> IO ()Source
killThread
raises the ThreadKilled
exception in the given
thread (GHC only).
killThread tid = throwTo tid ThreadKilled
throwTo :: Exception e => ThreadId -> e -> IO ()Source
throwTo
raises an arbitrary exception in the target thread (GHC only).
throwTo
does not return until the exception has been raised in the
target thread.
The calling thread can thus be certain that the target
thread has received the exception. This is a useful property to know
when dealing with race conditions: eg. if there are two threads that
can kill each other, it is guaranteed that only one of the threads
will get to kill the other.
Whatever work the target thread was doing when the exception was raised is not lost: the computation is suspended until required by another thread.
If the target thread is currently making a foreign call, then the
exception will not be raised (and hence throwTo
will not return)
until the call has completed. This is the case regardless of whether
the call is inside a mask
or not. However, in GHC a foreign call
can be annotated as interruptible
, in which case a throwTo
will
cause the RTS to attempt to cause the call to return; see the GHC
documentation for more details.
Important note: the behaviour of throwTo
differs from that described in
the paper "Asynchronous exceptions in Haskell"
(http://research.microsoft.com/~simonpj/Papers/asynch-exns.htm).
In the paper, throwTo
is non-blocking; but the library implementation adopts
a more synchronous design in which throwTo
does not return until the exception
is received by the target thread. The trade-off is discussed in Section 9 of the paper.
Like any blocking operation, throwTo
is therefore interruptible (see Section 5.3 of
the paper). Unlike other interruptible operations, however, throwTo
is always interruptible, even if it does not actually block.
There is no guarantee that the exception will be delivered promptly,
although the runtime will endeavour to ensure that arbitrary
delays don't occur. In GHC, an exception can only be raised when a
thread reaches a safe point, where a safe point is where memory
allocation occurs. Some loops do not perform any memory allocation
inside the loop and therefore cannot be interrupted by a throwTo
.
If the target of throwTo
is the calling thread, then the behaviour
is the same as Control.Exception.throwIO
, except that the exception
is thrown as an asynchronous exception. This means that if there is
an enclosing pure computation, which would be the case if the current
IO operation is inside unsafePerformIO
or unsafeInterleaveIO
, that
computation is not permanently replaced by the exception, but is
suspended as if it had received an asynchronous exception.
Note that if throwTo
is called with the current thread as the
target, the exception will be thrown even if the thread is currently
inside mask
or uninterruptibleMask
.
The yield
action allows (forces, in a co-operative multitasking
implementation) a context-switch to any other currently runnable
threads (if any), and is occasionally useful when implementing
concurrency abstractions.
labelThread :: ThreadId -> String -> IO ()Source
labelThread
stores a string as identifier for this thread if
you built a RTS with debugging support. This identifier will be used in
the debugging output to make distinction of different threads easier
(otherwise you only have the thread state object's address in the heap).
Other applications like the graphical Concurrent Haskell Debugger
(http://www.informatik.uni-kiel.de/~fhu/chd/) may choose to overload
labelThread
for their purposes as well.
data ThreadStatus Source
The current status of a thread
ThreadRunning | the thread is currently runnable or running |
ThreadFinished | the thread has finished |
ThreadBlocked BlockReason | the thread is blocked on some resource |
ThreadDied | the thread received an uncaught exception |
data BlockReason Source
BlockedOnMVar | blocked on on |
BlockedOnBlackHole | blocked on a computation in progress by another thread |
BlockedOnException | blocked in |
BlockedOnSTM | blocked in |
BlockedOnForeignCall | currently in a foreign call |
BlockedOnOther | blocked on some other resource. Without |
threadCapability :: ThreadId -> IO (Int, Bool)Source
returns the number of the capability on which the thread is currently
running, and a boolean indicating whether the thread is locked to
that capability or not. A thread is locked to a capability if it
was created with forkOn
.
TVars
A monad supporting atomic memory transactions.
atomically :: STM a -> IO aSource
Perform a series of STM actions atomically.
You cannot use atomically
inside an unsafePerformIO
or unsafeInterleaveIO
.
Any attempt to do so will result in a runtime error. (Reason: allowing
this would effectively allow a transaction inside a transaction, depending
on exactly when the thunk is evaluated.)
However, see newTVarIO
, which can be called inside unsafePerformIO
,
and which allows top-level TVars to be allocated.
Retry execution of the current memory transaction because it has seen values in TVars which mean that it should not continue (e.g. the TVars represent a shared buffer that is now empty). The implementation may block the thread until one of the TVars that it has read from has been udpated. (GHC only)
orElse :: STM a -> STM a -> STM aSource
Compose two alternative STM actions (GHC only). If the first action completes without retrying then it forms the result of the orElse. Otherwise, if the first action retries, then the second action is tried in its place. If both actions retry then the orElse as a whole retries.
throwSTM :: Exception e => e -> STM aSource
A variant of throw
that can only be used within the STM
monad.
Throwing an exception in STM
aborts the transaction and propagates the
exception.
Although throwSTM
has a type that is an instance of the type of throw
, the
two functions are subtly different:
throw e `seq` x ===> throw e throwSTM e `seq` x ===> x
The first example will cause the exception e
to be raised,
whereas the second one won't. In fact, throwSTM
will only cause
an exception to be raised when it is used within the STM
monad.
The throwSTM
variant should be used in preference to throw
to
raise an exception within the STM
monad because it guarantees
ordering with respect to other STM
operations, whereas throw
does not.
catchSTM :: Exception e => STM a -> (e -> STM a) -> STM aSource
Exception handling within STM actions.
alwaysSucceeds :: STM a -> STM ()Source
alwaysSucceeds adds a new invariant that must be true when passed to alwaysSucceeds, at the end of the current transaction, and at the end of every subsequent transaction. If it fails at any of those points then the transaction violating it is aborted and the exception raised by the invariant is propagated.
always :: STM Bool -> STM ()Source
always is a variant of alwaysSucceeds in which the invariant is expressed as an STM Bool action that must return True. Returning False or raising an exception are both treated as invariant failures.
Shared memory locations that support atomic memory transactions.
newTVarIO :: a -> IO (TVar a)Source
IO
version of newTVar
. This is useful for creating top-level
TVar
s using System.IO.Unsafe.unsafePerformIO
, because using
atomically
inside System.IO.Unsafe.unsafePerformIO
isn't
possible.
readTVarIO :: TVar a -> IO aSource
Return the current value stored in a TVar. This is equivalent to
readTVarIO = atomically . readTVar
but works much faster, because it doesn't perform a complete
transaction, it just reads the current value of the TVar
.
unsafeIOToSTM :: IO a -> STM aSource
Unsafely performs IO in the STM monad. Beware: this is a highly dangerous thing to do.
- The STM implementation will often run transactions multiple times, so you need to be prepared for this if your IO has any side effects.
- The STM implementation will abort transactions that are known to
be invalid and need to be restarted. This may happen in the middle
of
unsafeIOToSTM
, so make sure you don't acquire any resources that need releasing (exception handlers are ignored when aborting the transaction). That includes doing any IO using Handles, for example. Getting this wrong will probably lead to random deadlocks. - The transaction may have seen an inconsistent view of memory when
the IO runs. Invariants that you expect to be true throughout
your program may not be true inside a transaction, due to the
way transactions are implemented. Normally this wouldn't be visible
to the programmer, but using
unsafeIOToSTM
can expose it.
Miscellaneous
setUncaughtExceptionHandler :: (SomeException -> IO ()) -> IO ()Source
reportError :: SomeException -> IO ()Source