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We had a bit of a problem. :)

We want to ensure that only N threads are doing background tasks at any time. To do this, we used a fixed thread pool executor. It seemed to be working fine.

Then we found an issue. Suppose you have a class which uses the executor to do some parallel work and then it calls some other class while in the executor thread which also does some parallel work, intending to wait on it. Here's what happens:

  • Main thread calls the first level method.
  • This method thinks it can parallelise into 16 tasks and splits up its work.
  • 16 tasks are submitted to the executor.
  • Main thread starts waiting for its tasks to complete.
  • Supposing there are four threads available, the first four tasks each get picked up and run. So there are 12 tasks left on the queue.
  • Now, one of these tasks calls some other method.
  • This new method thinks it can parallelise into 2 tasks. Let's say it's the first step in a parallel merge sort or something along those lines.
  • 2 tasks are submitted to the executor.
  • This thread now starts waiting for its tasks to complete.

Uh-oh. So at this point, all four threads will now be waiting for tasks to complete but they are collaboratively blocking the executor actually running those tasks.

Solution 1 to this problem was as follows: on submitting a new task to the executor, if we are already running all our threads, and we are already running on one of the executor threads, run the task inline. This worked fine for 10 months, but now we have hit a problem with it. If the new tasks it is submitting are still relatively large, then you can get into a situation where the new task blocks the method from adding the other tasks to the queue, which would otherwise be able to be picked up by the other worker threads. So you get periods of huge delays while a thread is processing the work inline.

Is there a better solution to the core problem of executing a potentially unbounded tree of background tasks? I understand that .NET's equivalent to the executor service has some kind of in-built ability to steal from the queue which prevents the original deadlock issue from occurring, which as far as I can tell is an ideal solution. But what about over in Java land?

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So did you guys solve your problem? Were any of the answers what you were looking for? –  Matt Crinklaw-Vogt Mar 15 '11 at 15:24
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3 Answers 3

up vote 3 down vote accepted

Java 7 has the concept of a ForkJoinPool that allows a task to "fork" off another task by submitting it tot he same Executor. Then gives it the option of later attempting to "help join" that task by attempting to run it if it has not been run.

I believe the same thing can be done in Java 6 by simple combining an Executor with FutureTask. Like so:

public class Fib implements Callable<Integer> {
    int n;
    Executor exec;

    Fib(final int n, final Executor exec) {
        this.n = n;
        this.exec = exec;
    }

    /**
     * {@inheritDoc}
     */
    @Override
    public Integer call() throws Exception {
        if (n == 0 || n == 1) {
            return n;
        }

        //Divide the problem
        final Fib n1 = new Fib(n - 1, exec);
        final Fib n2 = new Fib(n - 2, exec);

        //FutureTask only allows run to complete once
        final FutureTask<Integer> n2Task = new FutureTask<Integer>(n2);
        //Ask the Executor for help
        exec.execute(n2Task);

        //Do half the work ourselves
        final int partialResult = n1.call();

        //Do the other half of the work if the Executor hasn't
        n2Task.run();

        //Return the combined result
        return partialResult + n2Task.get();
    }

}        
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This seems to be the way to go. And I can't wait for Java 7. ForkJoinPool is perfect! –  Trejkaz Mar 29 '11 at 0:10
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You could make use of callbacks instead of having your thread wait for the tasks to complete. Your tasks themselves will need to be callbacks since they submit more tasks.

E.g.:

public class ParallelTask implements Runnable, Callback {
  private final Callback mCB;
  private final int mNumChildTasks;
  private int mTimesCalledBack = 0;
  private final Object mLock = new Object();
  private boolean mCompleted = false;
  public ParallelTask(Callback cb) {
    mCB = cb;
    mNumChildTasks = N; // the number of direct child tasks you know this task will spawn
    // only going down 1 generation
    // of course you could figure this number out in the run method (will need to be volatile if so)
   // just as long as it is set before submitting any child tasks for execution
  }

  @Override
  public void run() {
    // do your stuff
    // and submit your child tasks, but don't wait on them to complete
    synchronized(mLock) {
      mCompleted = true;
      if (mNumChildTasks == mTimesCalledBack) {
        mCB.taskCompleted();
      }
    }
  }

  // Callback interface
  // taskCompleted is being called from the threads that this task's children are running in
  @Override
  public void taskCompleted() {
    synchronized(mLock) {
      mTimesCalledBack++;
      // only call our parent back if our direct children have all called us back
      // and our own task is done
      if (mCompleted && mTimesCalledBack == mNumChildTasks) {
        mCB.taskCompleted();
      }
    }
  }
}

In your main thread you submit your root task and register some callback to be executed.

Since all child tasks don't report completion until their children have reported completion, your root callback shouldn't be called until everything is done.

I wrote this on the fly and haven't tested or compiled it, so there may be some errors.

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It seems like the issue is that the tasks also try to parallelize themselves which makes it difficult to avoid resource constraints. Why do you need to do this? Why not always run the subtasks inline?

If you're fully utilizing the cpu already by parallelization then you're not going to buy much in terms of overall work accomplished by dividing the work up again into smaller tasks.

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Because without splitting at some level, the OP would just have one large task which can only be solved by a single CPU. Splitting the problem is fine, but the OP is trying to reduce context switching by limiting the number of threads and now the problem is that most threads are simply doing nothing. –  Tim Bender Mar 10 '11 at 1:53
    
Sure, sure. I understand that but he didn't give much context for the duration of tasks and how much benefit you'd get from parallelization at that level relative to the overhead of context switching. I hoped the OP would provide more context. –  Jeremy Mar 10 '11 at 3:47
    
Tim's answer is half of it - sometimes you divide at the top level and then one of the top-level tasks is still larger than the others (i.e. the very kind of task which causes the problem with the solution I named above.) The other answer is that sometimes what you're calling the "bottom level" here is the "top level". –  Trejkaz Mar 13 '11 at 0:15
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