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Is there a way to implement a lock in Python for multithreading purposes whose acquire method can have an arbitrary timeout? The only working solutions I found so far use polling, which

  • I find inelegant and inefficient
  • Doesn't preserve the bounded waiting / progress guarantee of the lock as a solution to the critical section problem

Is there a better way to implement this?

share|improve this question
You might want a threading.Condition object (see docs.python.org/library/threading.html#threading.Condition). The Condition object wraps a lock and has a wait method with a timeout. The wait is interrupted when it times out or when notify is called on the Condition object. –  Steven Rumbalski Dec 5 '11 at 22:24
I'm not sure if that is a solution to my problem. According to the docs and from a quick glance at the source code, I figured that threading.Condition just wraps a threading.RLock object. Before calling wait you need to acquire the underlying Lock. Apart from that, it seems that wait is implemented using a busy loop. Am I missing something here? –  Niklas B. Dec 5 '11 at 22:35

3 Answers 3

up vote 11 down vote accepted

to elaborate on Steven's comment suggestion:

import threading
import time

lock = threading.Lock()
cond = threading.Condition(threading.Lock())

def waitLock(timeout):
    with cond:
        current_time = start_time = time.time()
        while current_time < start_time + timeout:
            if lock.acquire(False):
                return True
                cond.wait(timeout - current_time + start_time)
                current_time = time.time()
    return False

Things to notice:

  • there are two threading.Lock() objects, one is internal to the threading.Condition().
  • when manipulating cond, it's lock is acquired; the wait() operation unlocks it, though, so any number of threads can watch it.
  • the wait is embedded inside a for loop that keeps track of the time. threading.Condition can become notified for reasons other than timeouts, so you still need to track the time if you really want it to expire.
  • even with the condition, you still 'poll' the real lock, because its possible for more than one thread to wake and race for the lock. if the lock.acquire fails, the loop returns to waiting.
  • callers of this waitLock function should follow a lock.release() with a cond.notify() so that other threads waiting on it are notified that they should retry aquiring the lock. This is not shown in the example.
share|improve this answer
Thanks very much, this is okay as polling seems to be the only option. Should have read the documentation more thoroughly, it seems :) –  Niklas B. Dec 5 '11 at 22:57
You could wrap this all up in a class to implement a TimeoutLock, so you don't rely on callers using both the lock and the condition variable correctly. I'm kind of amused though at using a condition variable (which is implemented with a lock) to implement a lock. :) –  Ben Dec 5 '11 at 23:11
@Ben: as far as I know, this is not strictly necessary from the perspective of what's available from OS provided locking primitives; nearly all OSes provide a regular mutex with a timeout acquire capability. Building one from 'scratch' as it were is mostly an artifact of the threading module itself, which has just one timeout capable primitive. since a condition is not itself anything like a mutex, it instead has to manage access to a mutex. –  SingleNegationElimination Dec 6 '11 at 1:26
@TokenMacGuy: Oh yes, I didn't mean that as any sort of criticism. It just entertained me. –  Ben Dec 6 '11 at 2:08

My version using thread safe queues http://docs.python.org/2/library/queue.html and their put/get methods that supports timeout.

Until now is working fine, but if someone can do a peer review on it I'll be grateful.

Thread-safe lock mechanism with timeout support module.

from threading import ThreadError, current_thread
from Queue import Queue, Full, Empty

class TimeoutLock(object):
    Thread-safe lock mechanism with timeout support.

    def __init__(self, mutex=True):
        Mutex parameter specifies if the lock should behave like a Mutex, and
        thus use the concept of thread ownership.
        self._queue = Queue(maxsize=1)
        self._owner = None
        self._mutex = mutex

    def acquire(self, timeout=0):
        Acquire the lock.
        Returns True if the lock was succesfully acquired, False otherwise.

        - < 0 : Wait forever.
        -   0 : No wait.
        - > 0 : Wait x seconds.
        th = current_thread()
                th, block=(timeout != 0),
                timeout=(None if timeout < 0 else timeout)
        except Full:
            return False

        self._owner = th
        return True

    def release(self):
        Release the lock.
        If the lock is configured as a Mutex, only the owner thread can release
        the lock. If another thread attempts to release the lock a
        ThreadException is raised.
        th = current_thread()
        if self._mutex and th != self._owner:
            raise ThreadError('This lock isn\'t owned by this thread.')

        self._owner = None
            return True
        except Empty:
            raise ThreadError('This lock was released already.')
share|improve this answer

I'm doubtful that this can be done.

If you want to implement this without any sort of polling, then you need the OS to know that the thread is blocked, and the OS needs to be aware of the timeout, in order to unblock the thread after a while. For that, support needs to already exist in the OS; you can't implement this at the Python level.

(You could have the thread blocked at either OS-level or app-level, and have a mechanism whereby it can be woken up by a different thread at the appropriate time, but then you need that other thread to be effectively polling)

In general you don't have a truly bounded waiting/progress guarantee of the lock anyway, as your thread will have to wait an unbounded time for a context switch to take place for it to notice that it's been unblocked. So unless you can put an upper bound on the amount of CPU contention going on, you're not going to be able to use the timeout to hit any hard real-time deadlines. But you probably don't need that, otherwise you wouldn't dream of using locks implemented in Python.

Due to the Python GIL (Global Interpreter Lock), those polling-based solutions probably aren't as inefficient or as badly unbounded as you think (depending on how they're implemented) (and assuming you're using either CPython or PyPy).

There's only ever one thread running at a time, and by definition there's another thread that you want to run (the one that holds the lock you're waiting for). The GIL is held for a while by one thread to execute a bunch of bytecodes, then dropped and reacquired to give someone else a chance at it. So if the blocked-with-timeout thread is just in a loop checking the time and yielding to other threads, it will only wake up every so often when it gets the GIL and then almost immediately drop it back to someone else and block on the GIL again. Because this thread could only ever wake up when it gets a turn at the GIL anyway, it will also do this check as soon after the timeout expires as it would be able to resume execution even if the timeout was magically perfect.

The only time this will cause a lot of inefficiency is if your thread is blocked waiting for the lock-holding thread, which is blocked waiting for something that can't be caused by another Python thread (say, blocked on IO), and there are no other runnable Python threads. Then your polling timeout really will just sit there checking the time repeatedly, which could be bad if you expect this situation to happen for long periods of time.

share|improve this answer
Maybe I need to clarify the progress/bounded waiting thing a bit. I actually meant that if the threads try to acquire the lock non-blocking, it is more or less random which of the threads can execute their critical section next. Your information about the GIL is very useful and makes me confident that a polling-based solution is probably as good as it can get without too much effort. Thanks. –  Niklas B. Dec 5 '11 at 22:50
I'm accepting Token's answer because I think it might be most interesting for others, although yours was more directly related to the original question. –  Niklas B. Dec 5 '11 at 23:04

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