I have a Queue on which the Enqueue operation would be performed by one thread and Dequeue would be performed by another. Needless to say, I had to implement some thread safety for it.

I first tried using a lock on the queue before each Enqueue/Dequeue as it gives a better control for the locking mechanism. It worked well, but my curious mind led me to test some more.

I then tried using Queue.Synchronized wrapper keeping everything else the same. Now, I am not sure if its true, but the performance does seem a tad bit faster with this approach.

Do you think, there actually is some difference in perfomance between the two, or I am just imagining things here..? :)

  • 3
    Just taking out a lock using either method is insanely quick. The performance hit comes from how much contention there is for the locks.
    – serg10
    Jan 27, 2011 at 15:54

3 Answers 3


When requesting Queue.Synchonized you get a SynchronizedQueue in return which uses a lock very minimally around calls to Enqueue and Dequeue on an inner queue. Therefore, the performance should be the same as using a Queue and managing locking yourself for Enqueue and Dequeue with your own lock.

You are indeed imagining things - they should be the same.


There is actually the fact that when using a SynchronizedQueue you are adding a layer of indirection as you have to go through the wrapper methods to get to the inner queue which it is managing. If anything this should slow things down very fractionally as you've got an extra frame on the stack that needs to be managed for each call. God knows if in-lining cancels this out though. Whatever - it's minimal.

Update 2

I have now benchmarked this, and as predicted in my previous update:

"Queue.Synchronized" is slower than "Queue+lock"

I carried out a single-threaded test as they both use the same locking technique (i.e. lock) so testing pure overhead in a "straight line" seems reasonable.

My benchmark produced the following results for a Release build:

Iterations      :10,000,000

Queue+Lock      :539.14ms
Queue+Lock      :540.55ms
Queue+Lock      :539.46ms
Queue+Lock      :540.46ms
Queue+Lock      :539.75ms

Using the following code:

private readonly object _syncObj = new object();

public object measure_queue_locking_performance()
    const int TestIterations = 5;
    const int Iterations = (10 * 1000 * 1000);

    Action<string, Action> time = (name, test) =>
        for (int i = 0; i < TestIterations; i++)
            TimeSpan elapsed = TimeTest(test, Iterations);
            Console.WriteLine("{0}:{1:F2}ms", name, elapsed.TotalMilliseconds);

    object itemOut, itemIn = new object();
    Queue queue = new Queue();
    Queue syncQueue = Queue.Synchronized(queue);

    Action test1 = () =>
        lock (_syncObj) queue.Enqueue(itemIn);
        lock (_syncObj) itemOut = queue.Dequeue();

    Action test2 = () =>
        itemOut = syncQueue.Dequeue();

    Console.WriteLine("Iterations:{0:0,0}\r\n", Iterations);
    time("Queue+Lock", test1);
    time("SynchonizedQueue", test2);

    return itemOut;

[SuppressMessage("Microsoft.Reliability", "CA2001:AvoidCallingProblematicMethods", MessageId = "System.GC.Collect")]
private static TimeSpan TimeTest(Action action, int iterations)
    Action gc = () =>

    Action empty = () => { };

    Stopwatch stopwatch1 = Stopwatch.StartNew();

    for (int j = 0; j < iterations; j++)

    TimeSpan loopElapsed = stopwatch1.Elapsed;

    action(); //JIT
    action(); //Optimize

    Stopwatch stopwatch2 = Stopwatch.StartNew();

    for (int j = 0; j < iterations; j++) action();


    TimeSpan testElapsed = stopwatch2.Elapsed;

    return (testElapsed - loopElapsed);
  • Not if the OP is not aggressive enough in releasing the lock, or is too eager in acquiring it.
    – jason
    Jan 27, 2011 at 15:31
  • @Jason I am making the assumption that the OP is using locking minimally around Enqueue and Dequeue calls, but I see your point. I have clarified a little in my answer.
    – Tim Lloyd
    Jan 27, 2011 at 15:32
  • thanks for investing time and efforts in getting an authoritive answer to this problem. Kudos to you. Jan 28, 2011 at 14:39
  • 2
    How do the values in the tests above compare to using a ConcurrentQueue? Aug 13, 2013 at 14:04

We can't answer this for you. Only you can answer it for yourself by getting a profiler and testing both scenarios (Queue.Synchronized vs. Lock) on real-world data from your application. It might not even be a bottleneck in your application.

That said, you should probably just be using ConcurrentQueue.

  • 1
    @Danish: Check out Rx. It has a backport of ConcurrentQueue<T> for .NET 3.5.
    – Dan Tao
    Jan 28, 2011 at 13:58
  • @Dan Is that version of ConcurrentQueue<T> actually generally faster though? I have seen that advice a few times, but no actual performance figures. Any figures?
    – Tim Lloyd
    Jan 28, 2011 at 14:09
  • @chibacity: Are you asking if it's as fast as the ConcurrentQueue<T> in .NET 4.0, or if it's faster than a plain vanilla Queue<T> guarded by lock statements? In the former case, I don't know. In the latter case, it depends on the level of contention (with little to no contention, Queue<T> with locks is better; as potential contention increases, the concurrent version leads more and more). I could probably dig up some numbers somewhere if you want.
    – Dan Tao
    Jan 28, 2011 at 14:14
  • @Dan My main point is I know there is a version in Rx (3.5), but I'm guessing this is not the same version that is in .Net 4.0.
    – Tim Lloyd
    Jan 28, 2011 at 14:16
  • @chibacity: Well, it's hardly an authoritative answer, but a quick look in Reflector at the decompiled versions of both types suggests they are identical. For what it's worth, Rx has a lot of the parallelization-related functionality from .NET 4.0, such as the entire System.Threading.Tasks namespace for example, as well.
    – Dan Tao
    Jan 28, 2011 at 14:26
  1. Queue.Synchronize Wraps a new queue Synchronized while Lock Queue.SyncRoot gives an Object to access the Queue synchronized way so this way you can ensure Thread Safety in the Queue while using the operations Enqueue and Dequeue simultaneously using Threads.

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