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For a while at my company we've used a home-grown ObjectPool<T> implementation that provides blocking access to its contents. It's pretty straightforward: a Queue<T>, an object to lock on, and an AutoResetEvent to signal to a "borrowing" thread when an item is added.

The meat of the class is really these two methods:

public T Borrow() {
    lock (_queueLock) {
        if (_queue.Count > 0)
            return _queue.Dequeue();
    }

    _objectAvailableEvent.WaitOne();

    return Borrow();
}

public void Return(T obj) {
    lock (_queueLock) {
        _queue.Enqueue(obj);
    }

    _objectAvailableEvent.Set();
}

We have been using this and a few other collection classes instead of those provided by System.Collections.Concurrent because we are using .NET 3.5, not 4.0. But recently we discovered that since we are using Reactive Extensions, we actually do have the Concurrent namespace available to us (in System.Threading.dll).

Naturally, I figured that since BlockingCollection<T> is one of the core classes in the Concurrent namespace, it would probably offer better performance than anything I or my teammates wrote.

So I tried writing a new implementation that works very simply:

public T Borrow() {
    return _blockingCollection.Take();
}

public void Return(T obj) {
    _blockingCollection.Add(obj);
}

To my surprise, according to some simple tests (borrowing/returning to the pool a few thousand times from multiple threads), our original implementation significantly beats BlockingCollection<T> in terms of performance. They both appear to work correctly; it's just that our original implementation seems to be much faster.

My question:

  1. Why would this be? Is it perhaps because BlockingCollection<T> offers greater flexibility (I understand it works by wrapping an IProducerConsumerCollection<T>), which necessarily introduces performance overhead?
  2. Is this just a flat-out misguided use of the BlockingCollection<T> class?
  3. If this is an appropriate use of BlockingCollection<T>, am I just not using properly? For example, is the Take/Add approach overly simplistic, and there's a far better-performing way to get the same functionality?

Unless anyone has some insight to offer in response to that third question, it looks like we'll be sticking with our original implementation for now.

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Without seeing your benchmark, it's difficult to comment. Maybe BlockingCollection<T> is optimized for scenarii that are different from your benchmark? –  Joe Jun 14 '10 at 18:19
    
@Joe: scenarii? Haha, nice. Anyway, point taken -- I will provide a benchmark shortly. –  Dan Tao Jun 14 '10 at 18:21
2  
Have you seen the Microsoft whitepaper on the .net 4 collection performance characteristics? Could just be a non-optimal scenario: blogs.msdn.com/b/pfxteam/archive/2010/04/26/9997562.aspx –  piers7 Jul 13 '10 at 14:35
    
@piers: Thanks for the awesome link! I hadn't read that paper; I skimmed over it just now and plan to read it more in-depth sometime soon. –  Dan Tao Jul 13 '10 at 15:59

2 Answers 2

up vote 21 down vote accepted

There are a couple of potential possibilities, here.

First, BlockingCollection<T> in the Reactive Extensions is a backport, and not exactly the same as the .NET 4 final version. I wouldn't be surprised if the performance of this backport differs from .NET 4 RTM (though I haven't profiled this collection, specifically). Much of the TPL performs better in .NET 4 than in the .NET 3.5 backport.

That being said, I'd suspect your implementation will out-perform BlockingCollection<T> if you have a single producer thread and a single consumer thread. With one producer and one consumer, your lock is going to have a smaller impact on the total performance, and the reset event is a very effective means of waiting on the consumer side.

However, BlockingCollection<T> is designed to allow many producer threads to "enqueue" data very well. This will not perform well with your implementation, as the locking contention will start to become problematic fairly quickly.

That being said, I'd also like to point out one misconception here:

...it would probably offer better performance than anything I or my teammates wrote.

This is often not true. The framework collection classes typically perform very well, but are often not the most performant option for a given scenario. That being said, they tend to perform well while being very flexible and very robust. They often tend to scale very well. "Home-written" collection classes often outperform framework collections in specific scenarios, but tend to be problematic when used in scenarios outside of the one for which they were specifically designed. I suspect this is one of those situations.

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I don't see how the code would differ from two threads vs many threads. You would still use the same locking constructs. Presumably he is testing both using the same number of threads. –  BC. Jun 14 '10 at 18:33
4  
@BC: BlockingCollection is actually a lockless collection. This causes it to scale quite differently than the OP's implementation. –  Reed Copsey Jun 14 '10 at 18:35

I tried BlockingCollection against a ConurrentQueue/AutoResetEvent combo (similar to OP's solution, but lockless) in .Net 4, and the latter combo was so much faster for my use case, that I ditched BlockingCollection. Unfortunately this was almost a year ago and I couldn't find the benchmark results.

Using a separate AutoResetEvent doesn't make things too much more complicated. In fact, one could even abstract it away, once and for all, into a BlockingCollectionSlim....

BlockingCollection internally relies on a ConcurrentQueue as well, but does some additional juggling with slim semaphores and cancellation tokens, which yields additional features, but at a cost, even when not used. It should also be noted that BlockingCollection is not married to ConcurrentQueue, but can be used with other implementors of IProducerConsumerCollection instead as well.


A (hastily written, completely untested) bare bones BlockingCollectionSlim implementation:

class BlockingCollectionSlim<T>
{
    private readonly ConcurrentQueue<T> _queue = new ConcurrentQueue<T>();
    private readonly AutoResetEvent _autoResetEvent = new AutoResetEvent(false);
    public void Enqueue(T item)
    {
        _queue.Enqueue(item);
        _autoResetEvent.Set();
    }
    public T Take()
    {
        T item;
        while (!_queue.TryDequeue(out item))
            _autoResetEvent.WaitOne();
        return item;
    }
    public bool TryTake(out T item, TimeSpan patience)
    {
        if (_queue.TryDequeue(out item))
            return true;
        var stopwatch = Stopwatch.StartNew();
        while (stopwatch.Elapsed < patience)
        {
            if (_queue.TryDequeue(out item))
                return true;
            var patienceLeft = (patience - stopwatch.Elapsed);
            if (patienceLeft < MinWait)
                // otherwise the while loop will degenerate into a busy loop,
                // for the last millisecond before patience runs out
                patienceLeft = MinWait;
            _autoResetEvent.WaitOne(patienceLeft);
        }
        return false;
    }
    private static readonly TimeSpan MinWait = TimeSpan.FromMilliseconds(1);
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