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

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5 Answers 5

up vote 7 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

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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
3  
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 {
private:
    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)];
public:
    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?

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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

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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.

http://www.liblds.org

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.

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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.

https://github.com/vovoid/vsxu/blob/master/engine/include/vsx_fifo.h

vsx_fifo<my_struct, 512> my_fifo;

Sender:

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

Receiver:

my_struct my_struct_recv;
while(my_fifo.consume(my_struct_recv)) 
{ 
  ...do stuff...
}
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