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  • Submit bugs and patches

    13 avril 2011

    Unfortunately a software is never perfect.
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  • Supporting all media types

    13 avril 2011, par

    Unlike most software and media-sharing platforms, MediaSPIP aims to manage as many different media types as possible. The following are just a few examples from an ever-expanding list of supported formats : images : png, gif, jpg, bmp and more audio : MP3, Ogg, Wav and more video : AVI, MP4, OGV, mpg, mov, wmv and more text, code and other data : OpenOffice, Microsoft Office (Word, PowerPoint, Excel), web (html, CSS), LaTeX, Google Earth and (...)

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    10 avril 2011

    Si vous avez développé une nouvelle extension permettant d’ajouter une ou plusieurs fonctionnalités utiles à MediaSPIP, faites le nous savoir et son intégration dans la distribution officielle sera envisagée.
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  • Greed is Good ; Greed Works

    25 novembre 2010, par Multimedia Mike — VP8

    Greed, for lack of a better word, is good ; Greed works. Well, most of the time. Maybe.

    Picking Prediction Modes
    VP8 uses one of 4 prediction modes to predict a 16x16 luma block or 8x8 chroma block before processing it (for luma, a block can also be broken into 16 4x4 blocks for individual prediction using even more modes).

    So, how to pick the best predictor mode ? I had no idea when I started writing my VP8 encoder. I did not read any literature on the matter ; I just sat down and thought of a brute-force approach. According to the comments in my code :

    // naive, greedy algorithm :
//   residual = source - predictor
//   mean = mean(residual)
//   residual -= mean
//   find the max diff between the mean and the residual
// the thinking is that, post-prediction, the best block will
// be comprised of similar samples

    After removing the predictor from the macroblock, individual 4x4 subblocks are put through a forward DCT and quantized. Optimal compression in this scenario results when all samples are the same since only the DC coefficient will be non-zero. Failing that, when the input samples are at least similar to each other, few of the AC coefficients will be non-zero, which helps compression. When the samples are all over the scale, there aren’t a whole lot of non-zero coefficients unless you crank up the quantizer, which results in poor quality in the reconstructed subblocks.

    Thus, my goal was to pick a prediction mode that, when applied to the input block, resulted in a residual in which each element would feature the least deviation from the mean of the residual (relative to other prediction choices).

    Greedy Approach
    I realized that this algorithm falls into the broad general category of "greedy" algorithms— one that makes locally optimal decisions at each stage. There are most likely smarter algorithms. But this one was good enough for making an encoder that just barely works.

    Compression Results
    I checked the total file compression size on my usual 640x360 Big Buck Bunny logo image while forcing prediction modes vs. using my greedy prediction picking algorithm. In this very simple test, DC-only actually resulted in slightly better compression than the greedy algorithm (which says nothing about overall quality).

    prediction mode quantizer index = 0 (minimum) quantizer index = 10
    greedy 286260 98028
    DC 280593 95378
    vertical 297206 105316
    horizontal 295357 104185
    TrueMotion 311660 113480

    As another data point, in both quantizer cases, my greedy algorithm selected a healthy mix of prediction modes :

    • quantizer index 0 : DC = 521, VERT = 151, HORIZ = 183, TM = 65
    • quantizer index 10 : DC = 486, VERT = 167, HORIZ = 190, TM = 77

    Size vs. Quality
    Again, note that this ad-hoc test only measures one property (a highly objective one)— compression size. It did not account for quality which is a far more controversial topic that I have yet to wade into.

  • Converting uint8_t data to AVFrame with FFmpeg

    30 octobre 2017, par J.Lefebvre

    I am currently working in C++ with the Autodesk 3DStudio Max 2014 SDK (toolset 100) and the Ffmpeg library in Visual Studio 2015 and trying to convert a DIB (Device Independent Bitmap) to uint8_t pointer array and then convert these data to an AVFrame.

    I don’t have any errors, but my video is still black and without meta data.
    (no time display, etc)

    I made approximatively the same with a Visual Studio Console application to convert jpeg image sequence from disk and this is working fine.
    (The only difference is that instead of converting jpeg to AVFrame with the Ffmpeg library, I try to convert raw data to an AVFrame.)

    So I think the problem could be either on the DIB conversion to the uint8_t data or the uint8_t data to the AVFrame.
    (The second is more plausible, because I used the SFML library to display a window with my rgb uint8_t* data for debuging and it is working fine.)

    I first initialize the ffmpeg library :

    This function is called once at the beginning.

    int Converter::Initialize(AVCodecID codec_id, int width, int height, int fps, const char *filename)
    
{
    
    avcodec_register_all();
    
    av_register_all();
    

    
    AVCodec *codec;
    
    inputFrame = NULL;
    
    codecContext = NULL;
    
    pkt = NULL;
    
    file = NULL;
    
    outputFilename = new char[strlen(filename)]();
    
    *outputFilename = '\0';
    
    strcpy(outputFilename, filename);
    

    
    int ret;
    

    
    //Initializing AVCodecContext and getting PixelFormat supported by encoder
    
    codec = avcodec_find_encoder(codec_id);
    
    if (!codec)
    
        return 1;
    

    
    AVPixelFormat pixFormat = codec->pix_fmts[0];
    
    codecContext = avcodec_alloc_context3(codec);
    
    if (!codecContext)
    
        return 1;
    

    
    codecContext->bit_rate = 400000;
    
    codecContext->width = width;
    
    codecContext->height = height;
    
    codecContext->time_base.num = 1;
    
    codecContext->time_base.den = fps;
    
    codecContext->gop_size = 10;
    
    codecContext->max_b_frames = 1;
    
    codecContext->pix_fmt = pixFormat;
    

    
    if (codec_id == AV_CODEC_ID_H264)
    
        av_opt_set(codecContext->priv_data, "preset", "slow", 0);
    

    
    //Actually opening the encoder
    
    if (avcodec_open2(codecContext, codec, NULL) < 0)
    
        return 1;
    

    
    file = fopen(outputFilename, "wb");
    
    if (!file)
    
        return 1;
    

    
    inputFrame = av_frame_alloc();
    
    inputFrame->format = codecContext->pix_fmt;
    
    inputFrame->width = codecContext->width;
    
    inputFrame->height = codecContext->height;
    

    
    ret = av_image_alloc(inputFrame->data, inputFrame->linesize, codecContext->width, codecContext->height, codecContext->pix_fmt, 32);
    

    
    if (ret < 0)
    
        return 1;
    

    
    return 0;
    
}

    Then for each frame, I get the DIB and convert to a uint8_t* it with this function :

    uint8_t* Util::ToUint8_t(RGBQUAD *data, int width, int height)
    
{
    
    uint8_t* buf = (uint8_t*)data;
    

    
    int imageSize = width * height;
    
    size_t rgbquad_size = sizeof(RGBQUAD);
    
    size_t total_bytes = imageSize * rgbquad_size;
    
    uint8_t * pCopyBuffer = new uint8_t[total_bytes];
    

    
    for (int x = 0; x < width; x++)
    
    {
    
        for (int y = 0; y < height; y++)
    
        {
    
            int index = (x + width * y) * rgbquad_size;
    
            int invertIndex = (x + width* (height - y - 1)) * rgbquad_size;
    

    
            //BGRA to RGBA
    
            pCopyBuffer[index] = buf[invertIndex + 2];
    
            pCopyBuffer[index + 1] = buf[invertIndex + 1];
    
            pCopyBuffer[index + 2] = buf[invertIndex];
    
            pCopyBuffer[index + 3] = 0xFF;
    
        }
    
    }
    

    
    return pCopyBuffer;
    
}
    

    
void GetDIBBuffer(Interface* ip, BITMAPINFO *bmi, uint8_t** outBuffer)
    
{
    
    int size;
    

    
    ViewExp& view = ip->GetActiveViewExp();
    

    
    view.getGW()->getDIB(NULL, &size);
    

    
    bmi = (BITMAPINFO *)malloc(size);
    
    BITMAPINFOHEADER *bmih = (BITMAPINFOHEADER *)bmi;
    
    view.getGW()->getDIB(bmi, &size);
    

    
    uint8_t * pCopyBuffer = Util::ToUint8_t(bmi->bmiColors, bmih->biWidth, bmih->biHeight);
    

    
    *outBuffer = pCopyBuffer;
    
}

    This function is used to get the DIB :

    void GetViewportDIB(Interface* ip, BITMAPINFO *bmi, BITMAPINFOHEADER *bmih, BitmapInfo biFile, Bitmap *map)
    
{
    
    int size;
    

    
    if (!biFile.Name()[0])
    
        return;
    

    
    ViewExp& view = ip->GetActiveViewExp();
    

    
    view.getGW()->getDIB(NULL, &size);
    

    
    bmi = (BITMAPINFO *)malloc(size);
    
    bmih = (BITMAPINFOHEADER *)bmi;
    

    
    view.getGW()->getDIB(bmi, &size);
    

    
    biFile.SetWidth((WORD)bmih->biWidth);
    
    biFile.SetHeight((WORD)bmih->biHeight);
    
    biFile.SetType(BMM_TRUE_32);
    

    
    map = TheManager->Create(&biFile);
    
    map->OpenOutput(&biFile);
    
    map->FromDib(bmi);
    
    map->Write(&biFile);
    
    map->Close(&biFile);
    
}

    And after the conversion to AVFrame and video encoding :

    The EncodeFromMem function is call each frame.

    int Converter::EncodeFromMem(const char *outputDir, int frameNumber, uint8_t* data)
    
{
    
    int ret;
    

    
    inputFrame->pts = frameNumber;
    
    EncodeFrame(data, codecContext, inputFrame, &pkt, file);
    

    
    return 0;
    
}
    

    
static void RgbToYuv(uint8_t *rgb, AVCodecContext *c, AVFrame *frame)
    
{
    
    struct SwsContext *swsCtx = NULL;
    
    const int in_linesize[1] = { 3 * c->width };// RGB stride
    
    swsCtx = sws_getCachedContext(swsCtx, c->width, c->height, AV_PIX_FMT_RGB24, c->width, c->height, AV_PIX_FMT_YUV420P, 0, 0, 0, 0);
    
    sws_scale(swsCtx, (const uint8_t * const *)&rgb, in_linesize, 0, c->height, frame->data, frame->linesize);
    
}
    

    
static void EncodeFrame(uint8_t *rgb, AVCodecContext *c, AVFrame *frame, AVPacket **pkt, FILE *file)
    
{
    
    int ret, got_output;
    

    
    RgbToYuv(rgb, c, frame);
    

    
    *pkt = av_packet_alloc();
    
    av_init_packet(*pkt);
    
    (*pkt)->data = NULL;
    
    (*pkt)->size = 0;
    

    
    ret = avcodec_encode_video2(c, *pkt, frame, &got_output);
    
    if (ret < 0)
    
    {
    
        fprintf(stderr, "Error encoding frame/n");
    
        exit(1);
    
    }
    
    if (got_output)
    
    {
    
        fwrite((*pkt)->data, 1, (*pkt)->size, file);
    
        av_packet_unref(*pkt);
    
    }
    
}

    To finish I have a function that write the packets and free the memory :
    This function is called once at the end of the time range.

    int Converter::Finalize()
    
{
    
    int ret, got_output;
    
    uint8_t endcode[] = { 0, 0, 1, 0xb7 };
    

    
    /* get the delayed frames */
    
    do
    
    {
    
        fflush(stdout);
    
        ret = avcodec_encode_video2(codecContext, pkt, NULL, &got_output);
    
        if (ret < 0)
    
        {
    
            fprintf(stderr, "Error encoding frame/n");
    
            return 1;
    
        }
    
        if (got_output)
    
        {
    
            fwrite(pkt->data, 1, pkt->size, file);
    
            av_packet_unref(pkt);
    
        }
    
    } while (got_output);
    

    
    fwrite(endcode, 1, sizeof(endcode), file);
    
    fclose(file);
    

    
    avcodec_close(codecContext);
    
    av_free(codecContext);
    

    
    av_frame_unref(inputFrame);
    
    av_frame_free(&inputFrame);
    
    //av_freep(&inputFrame->data[0]); //Crash
    

    
    delete outputFilename;
    
    outputFilename = 0;
    

    
    return 0;
    
}

    EDIT :

    I modify my RgbToYuv function and create another one to convert back the yuv frame to an rgb one.

    This not really solve the problem, but maybe focus the problem on the conversion from YuvToRgb.

    This is the result of the conversion from YUV to RGB :

     ![YuvToRgb result] : https://img42.com/kHqpt+

    static void YuvToRgb(AVCodecContext *c, AVFrame *frame)
    
{
    
    struct SwsContext *img_convert_ctx = sws_getContext(c->width, c->height, AV_PIX_FMT_YUV420P, c->width, c->height, AV_PIX_FMT_RGB24, SWS_BICUBIC, NULL, NULL, NULL);
    
    AVFrame * rgbPictInfo = av_frame_alloc();
    
    avpicture_fill((AVPicture*)rgbPictInfo, *(frame)->data, AV_PIX_FMT_RGB24, c->width, c->height);
    
    sws_scale(img_convert_ctx, frame->data, frame->linesize, 0, c->height, rgbPictInfo->data, rgbPictInfo->linesize);
    

    
    Util::DebugWindow(c->width, c->height, rgbPictInfo->data[0]);
    
}
    
static void RgbToYuv(uint8_t *rgb, AVCodecContext *c, AVFrame *frame)
    
{
    
    AVFrame * rgbPictInfo = av_frame_alloc();
    
    avpicture_fill((AVPicture*)rgbPictInfo, rgb, AV_PIX_FMT_RGBA, c->width, c->height);
    

    
    struct SwsContext *swsCtx = sws_getContext(c->width, c->height, AV_PIX_FMT_RGBA, c->width, c->height, AV_PIX_FMT_YUV420P, SWS_BICUBIC, NULL, NULL, NULL);
    
    avpicture_fill((AVPicture*)frame, rgb, AV_PIX_FMT_YUV420P, c->width, c->height);    
    
    sws_scale(swsCtx, rgbPictInfo->data, rgbPictInfo->linesize, 0, c->height, frame->data, frame->linesize);
    

    
    YuvToRgb(c, frame);
    
}

  • qsv : add requirement for the mininal version of libmfx

    22 mai 2022, par Haihao Xiang
    qsv : add requirement for the mininal version of libmfx

    libmfx 1.28 was released 3 years ago, it is easy to get a greater
    
version than 1.28. We may remove lots of compile-time checks if adding
    
the requirement for the minimal version in the configure script.
    

    Reviewed-by : softworkz <softworkz@hotmail.com>
    
Signed-off-by : Jean-Baptiste Kempf <jb@videolan.org>
    
Signed-off-by : Haihao Xiang <haihao.xiang@intel.com>
    • [DH] configure
    • [DH] libavcodec/qsv.c
    • [DH] libavcodec/qsvenc.c
    • [DH] libavcodec/qsvenc.h
    • [DH] libavcodec/qsvenc_h264.c
    • [DH] libavcodec/qsvenc_hevc.c
    • [DH] libavfilter/vf_scale_qsv.c
    • [DH] libavfilter/vf_vpp_qsv.c
    • [DH] libavutil/hwcontext_qsv.c

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