In an application I've to analyse movie files (let's say compute the differences of consecutive frame pairs). For this I use opencv (which uses ffmpeg as lib/ codecs). Depending on the video format there are different cpu loads/ uses. For wmv3 there seems to be not more than 1 core used. So it was close by hand to let multiple threads work on different parts of the movie, as the data is independent (beside having to stitch the parts afterwards). The code (stripped by the lap-parameter) is quite simple:

int main(int argc, char *argv[])
    const string source = "move.wmv";

    VideoCapture capt(source);
    if (!capt.isOpened())
        cout  << "Could not open file " << source << endl;
        return -1;

    unsigned short nThreads (8);

    double *pDiffArray = new double [(size_t) (capt.get(CV_CAP_PROP_FRAME_COUNT)];


    ComputeDifferences (source, pDiffArray, nThreads);

    return 0;

int ComputeDifferences (const string& source, double *pDiffArray, const unsigned short& nThreads)
    std::vector<std::thread *> threadVector;

    for (unsigned int i=0; i< nThreads; i++)
        threadVector.push_back (new std::thread (ComputePart, source, pDiffArray, nThreads, i));

    for (unsigned int i=0; i< nThreads; i++)
        threadVector.at (i)->join();

    // Stitching

    return 0;

void ComputePart (const string source, double *pDiffArray,
                  const unsigned int& nThreads, const unsigned int& nThreadNo)
    VideoCapture capt(source);
    if (!capt.isOpened())
        cout  << "Could not open file " << source << endl;

    size_t startPosDiffArray;

    startPosDiffArray = nThreadNo * (capt.get(CV_CAP_PROP_FRAME_COUNT) / nThreads);

    size_t sizePart (capt.get(CV_CAP_PROP_FRAME_COUNT) / nThreads);

    size_t startPosFrame;

    startPosFrame = capt.get(CV_CAP_PROP_FRAME_COUNT) / nThreads * nThreadNo;

    capt.set(CAP_PROP_POS_FRAMES, startPosFrame);

    Size refS = Size((int) capt.get(CAP_PROP_FRAME_WIDTH),
                     (int) capt.get(CAP_PROP_FRAME_HEIGHT));

    Mat frame, frameRes;
    std::array<Mat, 2> frameDuo;
    Scalar s;

    capt >> frameDuo [0];
    if (!frameDuo [0].data)

    for (size_t i = 1; i < sizePart; i++) {
        capt >> frameDuo [i%2];

        if (!frameDuo [i%2].data)

        absdiff (frameDuo [(i-1)%2], frameDuo [i%2], frameRes);

        s = sum (frameRes);

        pDiffArray [i-1+startPosDiffArray] = (s [0] + s [1] + s [2])/ (refS.height * refS.width);


If I use it on a wmv3 video, 1280x720, abt. 50,000 frames, I get this speedups (at an Intel i7), relative to single thread (190 sec).

  • MT2 1.8
  • MT4 2.6
  • MT8 3.0

Beside being very disappointed I do not understand what is happening here. I do know Amdahl's law etc., but in this case I expected a far better speedup. Does anyone have a hint for me (being a newbie on that)? It's not the positioning (capt.set ()), as disabling that doesn't change anything. Is it about ffmpeg-lib, opencv, thread-switch of std-lib, working set problem?


As of a hint in the comments I found that 80% of the time is used in

capt >> frameDuo [i%2];

This consists of reading from file, decoding and copying into opencv structure. And from this only the reading from file is of "sequential type" (in Amdahl's sense). As the HDD doesn't show heavy access (even when MT8), and there is no difference when using a quick SSD I don't understand why this sequential part should have such a big effect. How is it possible that 8 cores are fully working but only have a speedup of 3? And: how can I do better?]

  • if you know amdahls law, the results shouldnt be that surprising, taking into account that you have quite some non-parallel stuff. Jun 27, 2017 at 11:38
  • Maybe I don't understand it correctly. To my thinking there isn't any non-parallel stuff (???). Could you please be specific? And maybe then: how to make better ...
    – User42
    Jun 27, 2017 at 11:48
  • there is always a non-parallel part. You open a file, you start and join threads etc... Jun 27, 2017 at 11:49
  • Yes, of course, I do understand. But these operations (opening the file, starting and joining threads) do make only a very small fraction of the quite long (190s) work. Most of it (the processing within the threads) should be done completly independent (???)
    – User42
    Jun 27, 2017 at 11:55
  • 1
    how do you know that it is only a very small fraction? Did you measure it? What is VideoCapture capt(source); doing? Jun 27, 2017 at 12:08

1 Answer 1


The largest part of your numbers can indeed be explained by Amdahls law. If I take your result for two threads and try to compute the fraction that is done in parallel I get a value of p = 0.88888. And using this value for 4/8 threads I get

2   1.8 
4   2.99
8   4.48

Those numbers do not precicesly reproduce what you measured, but on top of Amdahls law you have an overhead per thread and more stuff that has to be considered to get realistic numbers, so it is just a first approximation and in this sense the agreement is quite ok.

As a conclusion: The numbers you get are not that bad. Its just what one would expect with a parallel fraction that is in the order of ~85% when considering Amdahls law.

  • How do you calculate the fraction that is done in parallel?
    – KjMag
    Jun 27, 2017 at 13:19
  • @KjMag from wikipedia: S = 1 / (1-p + p/s) with S=1.8 and s=2 I get p = 0.888888 Jun 27, 2017 at 13:21

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