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It seems there are lots of improvements in .NET 4.0 related to concurrency that might rely on concurrent priority queues. Is there decent priority queue implementation inside framework available for reuse?

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have a look: msdn.microsoft.com/en-us/library/… – Mitch Wheat Oct 25 '10 at 16:09
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@Mitch: unfortunately I am looking for priority queue implementation (en.wikipedia.org/wiki/Priority_queue). The regular FIFO queue would not do what I need. – user166010 Oct 25 '10 at 16:16
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You may need to roll your own. A relatively easy way would be to have an array of regular queues, with priority decreasing. – Steven Sudit Oct 25 '10 at 16:25
    
I've changed my comment into an answer. – Steven Sudit Oct 25 '10 at 16:35
    

There is an implementation as part of "Samples for Parallel Programming with the .NET Framework" at msdn. See ParallelExtensionsExtras.

Direct link to source code for file ConcurrentPriorityQueue.cs

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there appears to be a bug in that implementation. If you wrap it in a BlockingCollection and call Add 5 times, it puts the items in the wrong order in the exposed collection. If you dig down into the private members of the blockingConcurrentPriorityQueue, you can see that the underlying CPQ itself contains the right data in the right order. But the exposed collection is out of order (CPQ contains 0,1,2,3,4; exposed collection contains 0,4,3,2,1). So - don't use this version as part of a Blocking Collection. – Joe Aug 29 '12 at 5:44
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But which one to use? Do you know anything better? – ironic Apr 29 '13 at 12:14
    
@Joe: I've also tried to use it wrapped into BlockingCollection and your problem doesn't repro for me... so if you have some more details on how to repro the problem - I'll appreciate it! – Timur Sadykov Apr 21 '15 at 4:18

You may need to roll your own. A relatively easy way would be to have an array of regular queues, with priority decreasing.

Basically, you would insert into the queue for the appropriate priority. Then, on the consumer side, you would go down the list, from highest to lowest priority, checking to see if the queue is non-empty, and consuming an entry if so.

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+1, I forget to mention how to implement due think it pretty straightful :) Without that my answer is not full. – Nick Martyshchenko Oct 25 '10 at 16:40
    
It's not much of an implementation. It could probably be improved by having a ManualResetEvent that's signaled after inserting into any of the queues, so that the consumer can poll once, then wait until the signal fires. In practice, it would be best for that wait to be finite and relatively short (perhaps a quarter of a second) so as to avoid circumstances where the signal is missed. – Steven Sudit Oct 25 '10 at 17:20
    
Paw's implementation locks unnecessarily, but the overall structure is a good starting point. – Steven Sudit Oct 25 '10 at 22:49

Maybe you can use my own implementation of a PriorityQueue. It implements alot more than the usual push/pop/peek, features that I implemented whenever I found the need for it. It also has locks for concurrency.

Comments to the code is much appreciated :)

public class PriorityQueue<T> where T : class
{
    private readonly object lockObject = new object();
    private readonly SortedList<int, Queue<T>> list = new SortedList<int, Queue<T>>();

    public int Count
    {
        get
        {
            lock (this.lockObject)
            {
                return list.Sum(keyValuePair => keyValuePair.Value.Count);
            }
        }
    }

    public void Push(int priority, T item)
    {
        lock (this.lockObject)
        {
            if (!this.list.ContainsKey(priority))
                this.list.Add(priority, new Queue<T>());
            this.list[priority].Enqueue(item);
        }
    }
    public T Pop()
    {
        lock (this.lockObject)
        {
            if (this.list.Count > 0)
            {
                T obj = this.list.First().Value.Dequeue();
                if (this.list.First().Value.Count == 0)
                    this.list.Remove(this.list.First().Key);
                return obj;
            }
        }
        return null;
    }
    public T PopPriority(int priority)
    {
        lock (this.lockObject)
        {
            if (this.list.ContainsKey(priority))
            {
                T obj = this.list[priority].Dequeue();
                if (this.list[priority].Count == 0)
                    this.list.Remove(priority);
                return obj;
            }
        }
        return null;
    }
    public IEnumerable<T> PopAllPriority(int priority)
    {
        List<T> ret = new List<T>();
        lock(this.lockObject)
        {
            if (this.list.ContainsKey(priority))
            {
                while(this.list.ContainsKey(priority) && this.list[priority].Count > 0)
                    ret.Add(PopPriority(priority));
                return ret;
            }
        }
        return ret;
    }
    public T Peek()
    {
        lock (this.lockObject)
        {
            if (this.list.Count > 0)
                return this.list.First().Value.Peek();
        }
        return null;
    }
    public IEnumerable<T> PeekAll()
    {
        List<T> ret = new List<T>();
        lock (this.lockObject)
        {
            foreach (KeyValuePair<int, Queue<T>> keyValuePair in list)
                ret.AddRange(keyValuePair.Value.AsEnumerable());
        }
        return ret;
    }
    public IEnumerable<T> PopAll()
    {
        List<T> ret = new List<T>();
        lock (this.lockObject)
        {
            while (this.list.Count > 0)
                ret.Add(Pop());
        }
        return ret;
    }
}
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Aside from not following .NET conventions, it looks correct but slow. The slowness comes from locking everything, whereas the .NET 4.0 concurrent queue is lockless. See: codethinked.com/post/2010/02/04/… – Steven Sudit Oct 25 '10 at 22:48
    
In any case, +1 for the overall structure. – Steven Sudit Oct 25 '10 at 22:50
    
What do you mean by not following .NET conventions? – Paw Baltzersen Oct 26 '10 at 6:43
    
I was thinking about making the Queue inside the SortedList a ConcurrentQueue and then only lock when adding or deleting a new item in the SortedList, and not when working on the Queues. But I'd still have to lock when checking if a given priority is present in the SortedList, so that didn't help much. – Paw Baltzersen Oct 26 '10 at 6:45
    
What's about this implementation stackoverflow.com/a/4994931/206730 ? which is better ? – Kiquenet Jun 8 '13 at 10:30

Check Thread-safe Collections in .NET Framework 4 and Their Performance Characteristics but AFAIK there are no ready to use priority queue. All new thread-safe collections doesn't maintain order but you can make your own on top of them. Check @Steven's way.

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Since all the current answers are out-of-date or don't offer a viable solution, there's an implementation on MSDN that's usable. Note that lower priorities get processed first in this implementation.

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Options:

1) If your queue isn't ever going to become large, use a heap and lock the entire structure for each insertion and deletion.

2) If your queue is going to become large, you could use an algorithm like this:

http://www.research.ibm.com/people/m/michael/ipl-1996.pdf

This algorithm allows multiple threads to be working with the heap structure concurrently without risking corruption or deadlocks by supporting fine-grained locking of just parts of the tree at once. You'd have to benchmark to see whether the overhead of additional locking and unlocking operations cost more than contention over locking the entire heap.

3) If you aim to avoid locks altogether, another algorithm, mentioned in the link above, suggests using a FIFO queue of requests (easily implementable with no locks), and a separate thread which is the only thing that touches the heap. You'd have to measure to see how the overhead of switching focus between threads using synchronization objects compared to the overhead of plain straight-up locking.

Before you even get started, it would be worthwhile seeing just how bad the hit is on a straightforward implementation using locking. It may not be the most efficient implementation, but if it still performs orders of magnitude faster than you'll ever need then the ease of maintenance (that is, anyone, including yourself a year can now, being able to simply look at the code and understand what it does) may outweigh the tiny fraction of CPU time spent busy in the queuing mechanism.

Hope this helps :-)

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To elaborate slightly -- it is worth noting that the number of lock operations in the algorithm in 2) is proportional to the height of the tree, which is O(lg n). So, each time you want to add one lock/unlock operation, you need to double the number of items you're queuing up. – Jonathan Gilbert May 9 '13 at 18:38
    
Also, to clarify on 3), I haven't read the referenced paper directly, but I believe the idea is that the front end presented to consumers who want to enqueue or dequeue items is basically an adapter to the thread running the actual requests. In either case, a request structure is built with something like a ManualResetEvent and put into the FIFO. It then waits on the event. The request processor thread picks it up, does the work, and sets the event before moving on. This serializes all access to the heap without using locks, but the blocking operations and thread switches may be just as bad. – Jonathan Gilbert May 9 '13 at 18:41
    
Worth noting that only consumers would actually have to wait on their requests, though. Producers could "fire and forget". :-) – Jonathan Gilbert May 9 '13 at 18:41

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