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I am trying to model a system where there are multiple threads producing data, and a single thread consuming the data. The trick is that I don't want a dedicated thread to consume the data because all of the threads live in a pool. Instead, I want one of the producers to empty the queue when there is work, and yield if another producer is already clearing the queue.

The basic idea is that there is a queue of work, and a lock around the processing. Each producer pushes its payload onto the queue, and then attempts to enter the lock. The attempt is non-blocking and returns either true (the lock was acquired), or false (the lock is held by someone else).

If the lock is acquired, then that thread then processes all of the data in the queue until it is empty (including any new payloads introduced by other producers during processing). Once all of the work has been processed, the thread releases the lock and quits out.

The following is C++ code for the algorithm:

void Process(ITask *task) {
     // queue is a thread safe implementation of a regular queue

     // crit_sec is some handle to a critical section like object
     // try_scoped_lock uses RAII to attempt to acquire the lock in the constructor
     //                 if the lock was acquired, it will release the lock in the
     //                 destructor
     try_scoped_lock lock(crit_sec);

     // See if this thread won the lottery. Prize is doing all of the dishes
     if (!lock.Acquired())

     // This thread got the lock, so it needs to do the work
     ITask *currTask;
     while (queue.try_pop(currTask)) {
          ... execute task ...

In general this code works fine, and I have never actually witnessed the behavior I am about to describe below, but that implementation makes me feel uneasy. It stands to reason that a race condition is introduced between when the thread exits the while loop and when it releases the critical section.

The whole algorithm relies on the assumption that if the lock is being held, then a thread is servicing the queue.

I am essentially looking for enlightenment on 2 questions:

  1. Am I correct that there is a race condition as described (bonus for other races)
  2. Is there a standard pattern for implementing this mechanism that is performant and doesn't introduce race conditions?
share|improve this question
up vote 1 down vote accepted

Yes, there is a race condition.

Thread A adds a task, gets the lock, processes itself, then asks for a task from the queue. It is rejected.

Thread B at this point adds a task to the queue. It then attempts to get the lock, and fails, because thread A has the lock. Thread B exits.

Thread A then exits, with the queue non-empty, and nobody processing the task on it.

This will be difficult to find, because that window is relatively narrow. To make it more likely to find, after the while loop introduce a "sleep for 10 seconds". In the calling code, insert a task, wait 5 seconds, then insert a second task. After 10 more seconds, check that both insert tasks are finished, and there is still a task to be processed on the queue.

One way to fix this would be to change try_pop to try_pop_or_unlock, and pass in your lock to it. try_pop_or_unlock then atomically checks for an empty queue, and if so unlocks the lock and returns false.

Another approach is to improve the thread pool. Add a counting semaphore based "consume" task launcher to it.

semaphore_bool bTaskActive;
counting_semaphore counter;

when (counter || !bTaskActive)
  if (bTaskActive)
  bTaskActive = true
  launch_task( process_one_off_queue, when_done( [&]{ bTaskActive=false ) );

When the counting semaphore is active, or when poked by the finished consume task, it launches a consume task if there is no consume task active.

But that is just off the top of my head.

share|improve this answer
The try_pop_or_unlock method is actually a really compelling idea. How would I go about making that function atomic? – Mranz Feb 28 '13 at 23:48
Did you implement the queue? A simple thread-safe queue simply has a mutex in it -- in that case, just unlock the passed-in lock while still holding the mutex when the queue is empty. For fancier thread-safe queues, things get harder. – Yakk Feb 28 '13 at 23:51
Unfortunately this implementation is the latter. – Mranz Feb 28 '13 at 23:52
If the queue had a thread safe size() function or empty() function, would it also work to check empty() after releasing the lock. If not empty, attempt to get the lock back and start processing again? – Mranz Feb 28 '13 at 23:59
In some memory models, yes. I don't know how your queue and your lock memory models interact. I also encourage you to prove that it works yourself. X occurs after Y is the basic unit of logic in these kind of problems. If you are messing about with multithreaded programming, you should seek to understand the memory models of your various concurrency primitives. – Yakk Mar 1 '13 at 0:01

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