Copyright | (c) The University of Glasgow 2007 |
---|---|
License | BSD-style (see the file libraries/base/LICENSE) |
Maintainer | libraries@haskell.org |
Stability | experimental |
Portability | non-portable |
Safe Haskell | Safe |
Language | Haskell2010 |
Attach a timeout event to arbitrary IO
computations.
Documentation
An exception thrown to a thread by timeout
to interrupt a timed-out
computation.
Since: base-4.0
Instances
Exception Timeout # | Since: base-4.7.0.0 |
Defined in System.Timeout toException :: Timeout -> SomeException Source # fromException :: SomeException -> Maybe Timeout Source # displayException :: Timeout -> String Source # | |
Show Timeout # | Since: base-4.0 |
Eq Timeout # | |
timeout :: Int -> IO a -> IO (Maybe a) Source #
Wrap an IO
computation to time out and return Nothing
in case no result
is available within n
microseconds (1/10^6
seconds). In case a result
is available before the timeout expires, Just a
is returned. A negative
timeout interval means "wait indefinitely". When specifying long timeouts,
be careful not to exceed maxBound :: Int
.
>>>
timeout 1000000 (threadDelay 1000 *> pure "finished on time")
Just "finished on time"
>>>
timeout 10000 (threadDelay 100000 *> pure "finished on time")
Nothing
The design of this combinator was guided by the objective that timeout n f
should behave exactly the same as f
as long as f
doesn't time out. This
means that f
has the same myThreadId
it would have without the timeout
wrapper. Any exceptions f
might throw cancel the timeout and propagate
further up. It also possible for f
to receive exceptions thrown to it by
another thread.
A tricky implementation detail is the question of how to abort an IO
computation. This combinator relies on asynchronous exceptions internally
(namely throwing the computation the Timeout
exception). The technique
works very well for computations executing inside of the Haskell runtime
system, but it doesn't work at all for non-Haskell code. Foreign function
calls, for example, cannot be timed out with this combinator simply because
an arbitrary C function cannot receive asynchronous exceptions. When
timeout
is used to wrap an FFI call that blocks, no timeout event can be
delivered until the FFI call returns, which pretty much negates the purpose
of the combinator. In practice, however, this limitation is less severe than
it may sound. Standard I/O functions like hGetBuf
,
hPutBuf
, Network.Socket.accept, or hWaitForInput
appear to be blocking, but they really don't because the runtime system uses
scheduling mechanisms like select(2)
to perform asynchronous I/O, so it
is possible to interrupt standard socket I/O or file I/O using this
combinator.