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I have been searching lately for information on how to construct a lock-free priority queue in C#. I have yet to even find an implementation in any language, or a decent paper on the matter. I have found several papers which appear to be copies or at least referencing one particular paper which is not actually a paper on lock free priority queues, despite its name; it is in fact a paper on a priority queue which uses fine grained locks.

The responses I have been receiving from elsewhere include "use a single thread" and "you do not need it to be lock free" and "it is impossible". All three of these responses are incorrect.

If someone has some information on this, I would greatly appreciate it.

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How do you know they are all wrong? –  soandos May 15 '11 at 1:37
@soandos Using a single thread defeats the purpose of this data structure, if I did not need it to be lock free then I would not be asking this question, and it is not impossible because it has been done before. –  Michael J. Gray May 15 '11 at 1:44
What are your requirements that a priority queue with some locking wouldn't be good enough? –  BrandonAGr May 15 '11 at 1:57
@BrandonAGr In excess of 10,000 concurrent operations happening per second across more than 128 processing units. Lock contention inside this message queue alone becomes more time consuming than the main execution loop of the message handler and I have several message queues for this same loop. All of the message queues and handlers need quality of service capabilities as well, and that is why I need a priority queue. –  Michael J. Gray May 15 '11 at 4:03
fine grained locks is what you are looking for, i think 100% lock free is impossible. –  NickD May 15 '11 at 8:39

2 Answers 2

up vote 4 down vote accepted

Generally, it's a bad idea to write this kind of code yourself.

However, if you really want to write this kind of code, I say take a page from Eric Lippert's book (or blog, as it were), where basically, you would implement the queue but instead of having all the functions that make modifications on the queue modify the instance you call the method on, the methods return completely new instances of the queue.

This is semantically similar to the pattern that System.String uses to maintain immutability; all operations return a new System.String, the original is not modified.

The result of this is that you are forced to reassign the reference returned on every call. Because the assignments of references are atomic operations, there is no concern about thread-safety; you are guaranteed that the reads/writes will be atomic.

However, this will result in a last-in-wins situation; it's possible that multiple modifications are being made to the queue, but only the last assignment will hold, losing the other insertions into the queue.

This might be acceptable; if not, you have to use synchronization around the assignment and reading of the reference. You will still have a lock-free-priority queue, but if you have concerns about thread-safety and maintaining the integrity of the operations, you have done nothing but move the concern about synchronization outside of the data structure (which is almost all cases, is a good thing, as it gives you fine-grained explicit control).

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Could you elaborate on implementation specifics regarding the lock free priority queue? I do not quite follow how this would work in practice, but I understand the theory behind why it might be applicable. –  Michael J. Gray May 15 '11 at 1:54
@JNZ: Let's say the PriorityQueue has a Push method. Instead of having a void return type, it would return a new instance of the PriorityQueue; the instance returned would have the items in the original queue, plus the new item pushed onto it. This works without locks because it involves a read operation on the original, and the write operation on the new one occurs in the constructor, which will always be thread-safe. All mutable operations would return a new instance. You would just have to make sure that you keep track of the new reference. –  casperOne May 15 '11 at 1:58
@casperOne Alright so let me see if I have this right then. I follow how the Pop method works. A Push method would take in an item and return a new PriorityQueue which has the item in there. The immutable PriorityQueue singleton would update its reference with the one that was just returned, in an atomic operation. Is that how it should be? –  Michael J. Gray May 15 '11 at 2:26
What if two or more threads simultaneously do Pop? Wouldn't they all pop the same single item? –  hsmiths May 15 '11 at 2:39
@JNZ: Yep, that's right. Remember, the Pop method would not actually remove anything, but return a new PriorityQueue with the item removed. The link to Eric Lippert's blog show how this is done for a number of data structures. –  casperOne May 15 '11 at 2:53

The Art of Multiprocessor Programming. Look at Chapter 15 - Priority Queues. Book is in Java, but can be easily translated to C# since they both have GC (which is important for most implementations in the book).

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That example utilizes a test and set nstruction in its implementation, a feature which is unavailable in C# without specific additions to the execution engine (.NET, Mono, ...); .NET does not offer such a feature unfortunately. –  Michael J. Gray May 15 '11 at 1:49
@JNZ isn't Interlocked.CompareExchange what you're looking for? –  MerickOWA May 15 '11 at 2:11
@MerickOWA No, because that's a compare and swap and not a test and set or test, test, and set. They are fundamentally different and cannot compose eachother unfortunately; we need execution level control here. –  Michael J. Gray May 15 '11 at 4:00
if test and set means... (if location == 0 then location = 1, return true else return false) as a single atomic instruction, why isn't Interlock.CompareExchange( ref location, 0, 1 ) == 0 the same as test and set? –  MerickOWA May 15 '11 at 20:57

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