Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

is there any C++ implementation (source codes) of "optmistic approach to lock-free FIFO queues" algorithm?

share|improve this question

5 Answers 5

up vote 8 down vote accepted

Herb Sutter covered just such a queue as part of his Effective Concurency column in Dr. Dobbs Journal.

Writing Lock-Free Code: A Corrected Queue

share|improve this answer
that is theory, what i'am asking is the implementation. is there any source codes or library that implement those algorithm? –  uray May 31 '10 at 19:34
@uray: Yes. In the article. –  greyfade May 31 '10 at 19:41
where? i don't see any source code files there. –  uray May 31 '10 at 19:50
Did you even read the article? All of page 2 is annotated source code. –  greyfade May 31 '10 at 19:53
ok, sorry about that, i'am expecting it is wrapped as library or something... so I just include the source to my project and use it. is there any benchmark of this algorithm compared to the paper I refer above? –  uray May 31 '10 at 20:28

I want to conclude the answer given by greyfade, which is based on http://www.drdobbs.com/high-performance-computing/212201163 (the last part of the article), the optimized code would be (with some modification to suit my naming and coding convention) : `

template <typename T> class LFQueue {
    struct LFQNode {
        LFQNode( T* val ) : value(val), next(nullptr) { }
        T* value;
        AtomicPtr<LFQNode> next;
        char pad[CACHE_LINE_SIZE - sizeof(T*) - sizeof(AtomicPtr<LFQNode>)];

    char pad0[CACHE_LINE_SIZE];
    LFQNode* first;                 // for one consumer at a time
    char pad1[CACHE_LINE_SIZE - sizeof(LFQNode*)];
    InterlockedFlag consumerLock;   // shared among consumers
    char pad2[CACHE_LINE_SIZE - sizeof(InterlockedFlag)];
    LFQNode* last;                  // for one producer at a time
    char pad3[CACHE_LINE_SIZE - sizeof(LFQNode*)];
    InterlockedFlag producerLock;   // shared among producers
    char pad4[CACHE_LINE_SIZE - sizeof(InterlockedFlag)];
    LFQueue() {
        first = last = new LFQNode( nullptr ); // no more divider
        producerLock = consumerLock = false;

    ~LFQueue() {
        while( first != nullptr ) {
            LFQNode* tmp = first;
            first = tmp->next;
            delete tmp;

    bool pop( T& result ) {
        while( consumerLock.set(true) ) 
        { }                             // acquire exclusivity
        if( first->next != nullptr ) {  // if queue is nonempty 
            LFQNode* oldFirst = first;
            first = first->next;
            T* value = first->value;    // take it out
            first->value = nullptr;     // of the Node
            consumerLock = false;       // release exclusivity
            result = *value;            // now copy it back
            delete value;               // and clean up
            delete oldFirst;            // both allocations
            return true;                // and report success
        consumerLock = false;           // release exclusivity
        return false;                   // queue was empty

    bool push( const T& t )  {
        LFQNode* tmp = new LFQNode( t );    // do work off to the side
        while( producerLock.set(true) ) 
        { }                             // acquire exclusivity
        last->next = tmp;               // A: publish the new item
        last = tmp;                     // B: not "last->next"
        producerLock = false;           // release exclusivity
        return true;


another question is how do you define CACHE_LINE_SIZE? its vary on ever CPUs right?

share|improve this answer
A good number to choose would be 64 bytes, I think. But you'll probably want to balance it with size, so I'd suggest looking at your target CPUs and choose a size that fits the most common ones you expect to target. –  greyfade Jun 1 '10 at 1:54
Just a quick note: this is not a forum, so people can't be assume to "browse the thread". If you wish to ask another question, you should better use the "Ask Question" field rather than the "Your Answer" one. –  Matthieu M. Jun 1 '10 at 6:26
I'am indeed re-answering the question, but i was wrong asking in the answer field, I should add new comment under my own new answer. sorry about that. –  uray Jun 1 '10 at 11:51
I'am done benchmarking the above code against std::queue with CRITICAL_SECTION lock in windows, the lock-free queue is actually 2~3 times slower than implementation of std::queue with lock. do you know why? it is because of linked list? –  uray Jun 1 '10 at 11:53
sharing benchmark code including what system you're running would be useful here. Also what is the intended usage in your app, that's what matters. –  Rick Jun 1 '10 at 20:40

If you're looking for a good lock free queue implementation both Microsoft Visual Studio 2010 & Intel's Thread Building Blocks contain a good LF queue which is similar to the paper.

Here's a link to the one in VC 2010

share|improve this answer
Herb's of course is fine too and correct :) –  Rick May 31 '10 at 22:46
I try the vs2010 one and benchmarked, it is faster than "std::queue with lock" on small data sets, but exponentialy slower on large dataset –  uray Jun 1 '10 at 17:05

I've implemented the M&S queue in C.


Note that release 7 is almost out. The current release, 6, unfortunately has the enqueue and dequeue pointers on the same cache line. Decoupling those gave a 30% performance improvement.

share|improve this answer

Here is my implementation of a lock-free FIFO.

Make sure each item of T is a multiple of 64 bytes (the cache line size in the Intel CPUs) to avoid false sharing.

This code compiles with gcc/mingw and should compile with clang. It's optimized for 64-bit, so to get it to run on 32-bit would need some refactoring.


vsx_fifo<my_struct, 512> my_fifo;


my_struct my_struct_inst;
... fill it out ...
while (!my_fifo.produce(my_struct_inst)) {}


my_struct my_struct_recv;
  ...do stuff...
share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.