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So on SO, and the Internets in general, there is much confusion and frustration about how to make OpenMP's easy-to-use #pragma directives cooperate with C++'s equally easy-to-use STL containers.

Everyone talks about work-arounds for STL vector, but what about non-random access / bi-directional containers, like map, list, set, etc. ?

I encountered this problem and devised a very simple, obvious workaround. I present it here for STL map, but it is clearly generalizable.

Serial version:

for (std::map<A,B>::iterator it = my_map.begin();
        it != my_map.end();
    { /* do work with  it   */  }

My proposed solution to use OpenMP with STL map:

    //make an array of iterators.
    int loop_length = my_map.size();
    std::map<A,B>::iterator loop_array[ loop_length ];

    std::map<A,B>::iterator allocate_it = my_map.begin();
    for (int j=0; j<loop_length; ++j)
        loop_array[j] = allocate_it++;

    // now you can use OpenMP as usual:
    #pragma omp parallel for
    for (uint j=0; j<loop_length; ++j) 
       { /* do work with    loop_array[j]    */  }

I am far from an expert on OpenMP, however, so I would like to know if my proposed work-around is efficient and good practice.

Please assume that the programmer is responsible for thread-safe handling of the STL container within the for loop.

Finally, is my proposed solution more efficient than the following commonly-proposed solution (see answer to this SO Question), because, in my solution,each thread does not iterate over the whole container?

#pragma omp parallel
    for (std::map<A,B>::iterator it = my_map.begin();
            it != my_map.end();
    #pragma single nowait
       {   /*  do work  */   }

share|improve this question
I would suspect this to be faster (at least when A and B are large, otherwise you could just copy them into a vector). But have you tried it on your problem? Was it faster? –  larsmans May 3 '12 at 15:04
@larsmans I have not done any performance tests, and don't really plan too (sorry). I already have a large, sophisticated program written in serial, with STL containers everywhere, and am trying to multithread certain STL-for-loops. As such, I can't easily isolate and time it... –  M.P. May 3 '12 at 15:12
Not even if you copy the contents of the containers to a vector for testing purposes? –  larsmans May 3 '12 at 15:13
Sorry if my question is stupid but could you not simply iterate over j and then access the elements via allocate_it+j where allocate it is set as in your post. –  Azrael3000 May 4 '12 at 14:00
@Azrael3000 But isn't iterator arithmetic only valid for random-access iterators (like for vector) ? map , list, set, only use bi-directional iterators. –  M.P. May 4 '12 at 14:19
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1 Answer

OpenMP provides the task construct starting with version 3.0 which is quite useful for use with STL:

for (std::map<A,B>::iterator it = my_map.begin();
        it != my_map.end();
   #pragma omp task
   { /* do work with  it   */  }

Of course, data dependencies between iterations should not exist for this to work.

share|improve this answer
Is there extra overhead due to have the OpenMP command inside the loop? In general, I thought that performance is best improved by parallelizing the largest section of code possible (e.g. the outermost loop in nested loops). –  M.P. May 7 '12 at 12:35
That's generally true but using omp for on the for loop requires fast random access iterators (e.g. that run in constant time). As far as I know std::map does not provide a random access iterator at all and you should simulate one. –  Hristo Iliev May 7 '12 at 12:55
Yeah, that's what I was trying to do in my "proposed solution", by creating the conventional (random-access) array and then looping for that instead of the map directly. I was just concerned that your method created too much overhead (thread management at every iteration). –  M.P. May 7 '12 at 13:40
OpenMP does not create separate thread for each task. On the contrary, tasks are put in a "bag" and then each thread steals a task. My colleagues' research shows that the overhead is almost negligible while coding is greatly simplified. I am not trying to persuade you to use tasks - just try and see which one is faster and which one requires more programming. –  Hristo Iliev May 7 '12 at 13:49
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