WebRTC VideoEngine超详细教程（三）——集成X264编码和ffmpeg解码

转自：http://blog.csdn.net/nonmarking/article/details/47958395

本系列目前共三篇文章，后续还会更新

WebRTC VideoEngine超详细教程（一）——视频通话的基本流程

WebRTC VideoEngine超详细教程（二）——集成OPENH264编解码器

WebRTC VideoEngine超详细教程（三）——集成X264编码和ffmpeg解码

总述

在前一篇文章中，讲解了如何将OPENH264编解码器集成到WebRTC中，但是OPENH264只能编码baseline的H264视频，而且就编码质量而言，还是X264最好，本文就来讲解一下如何将X264编码器集成到WebRTC中，为了实现解码，同时要用到ffmpeg。总体流程和之前一样，分为重新封装编解码器和注册调用两大步骤，注册调用这一步没有任何不同，主要是重新封装这一步骤有较大区别。

重新封装X264编码功能

首先当然还是要下载X264源码编译出相应的库以供调用。在windows下使用mingw进行编译，再使用poxports工具导出库，最后得到libx264.dll和libx264.lib，同时把x264.h和x264_config.h总共四个文件放到工程目录下，并在项目属性中进行相应配置。

 

使用x264进行视频编码的基本流程如下

#include <stdint.h>
#include <stdio.h>
#include <x264.h>

int main( int argc, char **argv )
{
    int width, height;
    x264_param_t param;
    x264_picture_t pic;
    x264_picture_t pic_out;
    x264_t *h;
    int i_frame = 0;
    int i_frame_size;
    x264_nal_t *nal;
    int i_nal;

    /* Get default params for preset/tuning */
    if( x264_param_default_preset( &param, "medium", NULL ) < 0 )
        goto fail;

    /* Configure non-default params */
    param.i_csp = X264_CSP_I420;
    param.i_width  = width;
    param.i_height = height;
    param.b_vfr_input = 0;
    param.b_repeat_headers = 1;
    param.b_annexb = 1;

    /* Apply profile restrictions. */
    if( x264_param_apply_profile( &param, "high" ) < 0 )
        goto fail;

    if( x264_picture_alloc( &pic, param.i_csp, param.i_width, param.i_height ) < 0 )
        goto fail;

    h = x264_encoder_open( &param);
    if( !h )
        goto fail;

    int luma_size = width * height;
    int chroma_size = luma_size / 4;
    /* Encode frames */
    for( ;; i_frame++ )
    {
        /* Read input frame */
        if( fread( pic.img.plane[0], 1, luma_size, stdin ) != luma_size )
            break;
        if( fread( pic.img.plane[1], 1, chroma_size, stdin ) != chroma_size )
            break;
        if( fread( pic.img.plane[2], 1, chroma_size, stdin ) != chroma_size )
            break;

        pic.i_pts = i_frame;
        i_frame_size = x264_encoder_encode( h, &nal, &i_nal, &pic, &pic_out );
        if( i_frame_size < 0 )
            goto fail;
        else if( i_frame_size )
        {
            if( !fwrite( nal->p_payload, i_frame_size, 1, stdout ) )
                goto fail;
        }
    }
    /* Flush delayed frames */
    while( x264_encoder_delayed_frames( h ) )
    {
        i_frame_size = x264_encoder_encode( h, &nal, &i_nal, NULL, &pic_out );
        if( i_frame_size < 0 )
            goto fail;
        else if( i_frame_size )
        {
            if( !fwrite( nal->p_payload, i_frame_size, 1, stdout ) )
                goto fail;
        }
    }

    x264_encoder_close( h );
    x264_picture_clean( &pic );
    return 0;
}

还是一样，照葫芦画瓢，改写上一篇文章中提到的H264EncoderImpl类

首先是类的定义，去掉了原来的私有成员变量ISVCEncoder* encoder_，加入了以下几项，其他内容不变

x264_picture_t pic;
x264_picture_t pic_out;
x264_t *encoder_;
int i_frame = 0;//frame index
x264_nal_t *nal;

相应的，构造函数和析构函数也要改变，这里就不赘述了，重点看InitEncode方法和Encode方法。

InitEncode方法的实现改写如下

int H264EncoderImpl::InitEncode(const VideoCodec* inst,
        int number_of_cores,
        size_t max_payload_size) {
        if (inst == NULL) {
            return WEBRTC_VIDEO_CODEC_ERR_PARAMETER;
        }
        if (inst->maxFramerate < 1) {
            return WEBRTC_VIDEO_CODEC_ERR_PARAMETER;
        }
        // allow zero to represent an unspecified maxBitRate
        if (inst->maxBitrate > 0 && inst->startBitrate > inst->maxBitrate) {
            return WEBRTC_VIDEO_CODEC_ERR_PARAMETER;
        }
        if (inst->width < 1 || inst->height < 1) {
            return WEBRTC_VIDEO_CODEC_ERR_PARAMETER;
        }
        if (number_of_cores < 1) {
            return WEBRTC_VIDEO_CODEC_ERR_PARAMETER;
        }

        int ret_val = Release();
        if (ret_val < 0) {
            return ret_val;
        }
        /* Get default params for preset/tuning */
        x264_param_t param;
        ret_val = x264_param_default_preset(&param, "medium", NULL);
        if (ret_val != 0) {
            WEBRTC_TRACE(webrtc::kTraceError, webrtc::kTraceVideoCoding, -1,
                "H264EncoderImpl::InitEncode() fails to initialize encoder ret_val %d",
                ret_val);
            x264_encoder_close(encoder_);
            encoder_ = NULL;
            return WEBRTC_VIDEO_CODEC_ERROR;
        }
        /* Configure non-default params */
        param.i_csp = X264_CSP_I420;
        param.i_width = inst->width;
        param.i_height = inst->height;
        param.b_vfr_input = 0;
        param.b_repeat_headers = 1;
        param.b_annexb = 0;//这里设置为0，是为了使编码后的NAL统一有4字节的起始码，便于处理，否则会同时有3字节和4字节的起始码，很麻烦
        param.i_fps_num = 1;
        param.i_fps_num = codec_.maxFramerate;
        param.rc.i_bitrate = codec_.maxBitrate;
        /* Apply profile restrictions. */
        ret_val = x264_param_apply_profile(&param, "high");
        if (ret_val != 0) {
            WEBRTC_TRACE(webrtc::kTraceError, webrtc::kTraceVideoCoding, -1,
                "H264EncoderImpl::InitEncode() fails to initialize encoder ret_val %d",
                ret_val);
            x264_encoder_close(encoder_);
            encoder_ = NULL;
            return WEBRTC_VIDEO_CODEC_ERROR;
        }

        ret_val = x264_picture_alloc(&pic, param.i_csp, param.i_width, param.i_height);
        if (ret_val != 0) {
            WEBRTC_TRACE(webrtc::kTraceError, webrtc::kTraceVideoCoding, -1,
                "H264EncoderImpl::InitEncode() fails to initialize encoder ret_val %d",
                ret_val);
            x264_encoder_close(encoder_);
            encoder_ = NULL;
            return WEBRTC_VIDEO_CODEC_ERROR;
        }

        encoder_ = x264_encoder_open(&param);
        if (!encoder_){
            WEBRTC_TRACE(webrtc::kTraceError, webrtc::kTraceVideoCoding, -1,
                "H264EncoderImpl::InitEncode() fails to initialize encoder ret_val %d",
                ret_val);
            x264_encoder_close(encoder_);
            x264_picture_clean(&pic);
            encoder_ = NULL;
            return WEBRTC_VIDEO_CODEC_ERROR;
        }

        if (&codec_ != inst) {
            codec_ = *inst;
        }

        if (encoded_image_._buffer != NULL) {
            delete[] encoded_image_._buffer;
        }
        encoded_image_._size = CalcBufferSize(kI420, codec_.width, codec_.height);
        encoded_image_._buffer = new uint8_t[encoded_image_._size];
        encoded_image_._completeFrame = true;

        inited_ = true;
        WEBRTC_TRACE(webrtc::kTraceApiCall, webrtc::kTraceVideoCoding, -1,
            "H264EncoderImpl::InitEncode(%d, height:%d, framerate:%d, start_bitrate:%d, max_bitrate:%d)",
            inst->width, inst->height, inst->maxFramerate, inst->startBitrate, inst->maxBitrate);

        return WEBRTC_VIDEO_CODEC_OK;
    }

Encode方法的实现改写如下

int H264EncoderImpl::Encode(const I420VideoFrame& input_image,
        const CodecSpecificInfo* codec_specific_info,
        const std::vector<VideoFrameType>* frame_types) {
        if (!inited_) {
            return WEBRTC_VIDEO_CODEC_UNINITIALIZED;
        }
        if (input_image.IsZeroSize()) {
            return WEBRTC_VIDEO_CODEC_ERR_PARAMETER;
        }
        if (encoded_complete_callback_ == NULL) {
            return WEBRTC_VIDEO_CODEC_UNINITIALIZED;
        }

        VideoFrameType frame_type = kDeltaFrame;
        // We only support one stream at the moment.
        if (frame_types && frame_types->size() > 0) {
            frame_type = (*frame_types)[0];
        }

        bool send_keyframe = (frame_type == kKeyFrame);
        if (send_keyframe) {
            pic.b_keyframe = TRUE;
            WEBRTC_TRACE(webrtc::kTraceApiCall, webrtc::kTraceVideoCoding, -1,
                "H264EncoderImpl::EncodeKeyFrame(%d, height:%d)",
                input_image.width(), input_image.height());
        }

        // Check for change in frame size.
        if (input_image.width() != codec_.width ||
            input_image.height() != codec_.height) {
            int ret = UpdateCodecFrameSize(input_image);
            if (ret < 0) {
                return ret;
            }
        }

        /* Read input frame */
        pic.img.plane[0] = const_cast<uint8_t*>(input_image.buffer(kYPlane));
        pic.img.plane[1] = const_cast<uint8_t*>(input_image.buffer(kUPlane));
        pic.img.plane[2] = const_cast<uint8_t*>(input_image.buffer(kVPlane));
        pic.i_pts = i_frame;

        int i_nal = 0;
        int i_frame_size = x264_encoder_encode(encoder_, &nal, &i_nal, &pic, &pic_out);
        if (i_frame_size < 0)
        {
            WEBRTC_TRACE(webrtc::kTraceError, webrtc::kTraceVideoCoding, -1,
                "H264EncoderImpl::Encode() fails to encode %d",
                i_frame_size);
            x264_encoder_close(encoder_);
            x264_picture_clean(&pic);
            encoder_ = NULL;
            return WEBRTC_VIDEO_CODEC_ERROR;
        }

        RTPFragmentationHeader frag_info;

        if (i_frame_size)
        {
            if (i_nal == 0) {
                return WEBRTC_VIDEO_CODEC_OK;
            }
            frag_info.VerifyAndAllocateFragmentationHeader(i_nal);

            encoded_image_._length = 0;

            uint32_t totalNaluIndex = 0;
            for (int nal_index = 0; nal_index < i_nal; nal_index++)
            {
                uint32_t currentNaluSize = 0;
                currentNaluSize = nal[nal_index].i_payload - 4; //x264_encoder_encode编码得到的nal单元是已经带有起始码的，此外，这里直接使用nal[index]即可，不必再使用x264_nal_encode函数
                memcpy(encoded_image_._buffer + encoded_image_._length, nal[nal_index].p_payload + 4, currentNaluSize);//encoded_image_中存有的是去掉起始码的数据
                encoded_image_._length += currentNaluSize;

                WEBRTC_TRACE(webrtc::kTraceApiCall, webrtc::kTraceVideoCoding, -1,
                    "H264EncoderImpl::Encode() nal_type %d, length:%d",
                    nal[nal_index].i_type, encoded_image_._length);

                frag_info.fragmentationOffset[totalNaluIndex] = encoded_image_._length - currentNaluSize;
                frag_info.fragmentationLength[totalNaluIndex] = currentNaluSize;
                frag_info.fragmentationPlType[totalNaluIndex] = nal[nal_index].i_type;
                frag_info.fragmentationTimeDiff[totalNaluIndex] = 0;
                totalNaluIndex++;
            }
        }
        i_frame++;
        if (encoded_image_._length > 0) {
            encoded_image_._timeStamp = input_image.timestamp();
            encoded_image_.capture_time_ms_ = input_image.render_time_ms();
            encoded_image_._encodedHeight = codec_.height;
            encoded_image_._encodedWidth = codec_.width;
            encoded_image_._frameType = frame_type;
            // call back
            encoded_complete_callback_->Encoded(encoded_image_, NULL, &frag_info);
        }
        return WEBRTC_VIDEO_CODEC_OK;
    }

其他方法的实现均没有改变。

至此，X264编码器重新封装完毕，还是比较好理解的。

重新封装ffmpeg解码功能

首先还是一样，获得ffmpeg的头文件和库文件，加入工程中并进行相应设置，这里只需使用avcodec avformat avutil swscale四个库，头文件也可以做相应的删减。

ffmpeg解码的基本流程如下，实际集成之后是从WebRTC的EncodedImage& input_image中获得待解码数据的，所以不能使用常见的基于文件的解码流程

AVCodec *codec = avcodec_find_decoder(AV_CODEC_ID_H264);
AVCodecContext *codecCtx = avcodec_alloc_context3(codec);
avcodec_open2(codecCtx, codec, nil);
char *videoData;
int len;
AVFrame *frame = av_frame_alloc();
AVPacket packet;
av_new_packet(&packet, len);
memcpy(packet.data, videoData, len);
int ret, got_picture;
ret = avcodec_decode_video2(codecCtx, frame, &got_picture, &packet);
if (ret > 0){
    if(got_picture){
    //进行下一步的处理
    }
}

相应的，对H264DecoderImpl类的定义和各方法的实现要进行改写。
首先是类的定义，去掉了ISVCDecoder* decoder_，加入了以下私有成员变量

AVCodecContext  *pCodecCtx;
  AVCodec           *pCodec;
  AVFrame   *pFrame, *pFrameYUV;
  AVPacket *packet;
  struct SwsContext *img_convert_ctx;
  uint8_t *decode_buffer;//存储最开始收到的SPS、PPS和IDR帧以便进行最开始的解码
  uint8_t *out_buffer;
  int framecnt = 0;
  int encoded_length = 0;

构造函数和析构函数的改写省略不表，重点看一下InitDecode方法和Decode方法

InitDecode方法改写如下

int H264DecoderImpl::InitDecode(const VideoCodec* inst, int number_of_cores) {
        if (inst == NULL) {
            return WEBRTC_VIDEO_CODEC_ERR_PARAMETER;
        }
        int ret_val = Release();
        if (ret_val < 0) {
            return ret_val;
        }

        if (&codec_ != inst) {
            // Save VideoCodec instance for later; mainly for duplicating the decoder.
            codec_ = *inst;
        }
        pCodec = avcodec_find_decoder(AV_CODEC_ID_H264);
        pCodecCtx = avcodec_alloc_context3(pCodec);
        pCodecCtx->pix_fmt = PIX_FMT_YUV420P;
        pCodecCtx->width = codec_.width;
        pCodecCtx->height = codec_.height;
        //pCodecCtx->bit_rate = codec_.targetBitrate*1000;
        pCodecCtx->time_base.num = 1;
        pCodecCtx->time_base.den = codec_.maxFramerate;

        if (pCodec == NULL){
            WEBRTC_TRACE(webrtc::kTraceError, webrtc::kTraceVideoCoding, -1,
                "H264DecoderImpl::InitDecode, Codec not found.");
            return WEBRTC_VIDEO_CODEC_ERROR;
        }
        if (avcodec_open2(pCodecCtx, pCodec, NULL) < 0){
            WEBRTC_TRACE(webrtc::kTraceError, webrtc::kTraceVideoCoding, -1,
                "H264DecoderImpl::InitDecode, Could not open codec.");
            return WEBRTC_VIDEO_CODEC_ERROR;
        }
        inited_ = true;

        // Always start with a complete key frame.
        key_frame_required_ = true;
        WEBRTC_TRACE(webrtc::kTraceApiCall, webrtc::kTraceVideoCoding, -1,
            "H264DecoderImpl::InitDecode(%d, height:%d, framerate:%d, start_bitrate:%d, max_bitrate:%d)",
            inst->width, inst->height, inst->maxFramerate, inst->startBitrate, inst->maxBitrate);
        return WEBRTC_VIDEO_CODEC_OK;
    }

Decode方法的实现改写如下

int H264DecoderImpl::Decode(const EncodedImage& input_image,
        bool missing_frames,
        const RTPFragmentationHeader* fragmentation,
        const CodecSpecificInfo* codec_specific_info,
        int64_t /*render_time_ms*/) {
        if (!inited_) {
            WEBRTC_TRACE(webrtc::kTraceError, webrtc::kTraceVideoCoding, -1,
                "H264DecoderImpl::Decode, decoder is not initialized");
            return WEBRTC_VIDEO_CODEC_UNINITIALIZED;
        }

        if (decode_complete_callback_ == NULL) {
            WEBRTC_TRACE(webrtc::kTraceError, webrtc::kTraceVideoCoding, -1,
                "H264DecoderImpl::Decode, decode complete call back is not set");
            return WEBRTC_VIDEO_CODEC_UNINITIALIZED;
        }

        if (input_image._buffer == NULL) {
            WEBRTC_TRACE(webrtc::kTraceError, webrtc::kTraceVideoCoding, -1,
                "H264DecoderImpl::Decode, null buffer");
            return WEBRTC_VIDEO_CODEC_ERR_PARAMETER;
        }
        if (!codec_specific_info) {
            WEBRTC_TRACE(webrtc::kTraceError, webrtc::kTraceVideoCoding, -1,
                "H264EncoderImpl::Decode, no codec info");
            return WEBRTC_VIDEO_CODEC_ERROR;
        }
        if (codec_specific_info->codecType != kVideoCodecH264) {
            WEBRTC_TRACE(webrtc::kTraceError, webrtc::kTraceVideoCoding, -1,
                "H264EncoderImpl::Decode, non h264 codec %d", codec_specific_info->codecType);
            return WEBRTC_VIDEO_CODEC_ERROR;
        }

        WEBRTC_TRACE(webrtc::kTraceApiCall, webrtc::kTraceVideoCoding, -1,
            "H264DecoderImpl::Decode(frame_type:%d, length:%d",
            input_image._frameType, input_image._length);

        if (framecnt < 2)
        {//存储最开始的SPS PPS 和 IDR帧以便进行初始的解码
            memcpy(decode_buffer + encoded_length, input_image._buffer, input_image._length);
            encoded_length += input_image._length;
            framecnt++;
        }
        else
        {
            pFrame = av_frame_alloc();
            pFrameYUV = av_frame_alloc();
            out_buffer = (uint8_t *)av_malloc(avpicture_get_size(PIX_FMT_YUV420P, pCodecCtx->width, pCodecCtx->height));
            avpicture_fill((AVPicture *)pFrameYUV, out_buffer, PIX_FMT_YUV420P, pCodecCtx->width, pCodecCtx->height);
            img_convert_ctx = sws_getContext(pCodecCtx->width, pCodecCtx->height, pCodecCtx->pix_fmt,
                pCodecCtx->width, pCodecCtx->height, PIX_FMT_YUV420P, SWS_BICUBIC, NULL, NULL, NULL);

            if (framecnt == 2)
            {
                packet = (AVPacket *)av_malloc(sizeof(AVPacket));
                av_new_packet(packet, encoded_length);
                memcpy(packet->data, decode_buffer, encoded_length);
                av_free(decode_buffer);
                framecnt++;
                printf("

Loading");
            }
            else
            {
                packet = (AVPacket *)av_malloc(sizeof(AVPacket));
                av_new_packet(packet, input_image._length);
                memcpy(packet->data, input_image._buffer, input_image._length);
            }

            int got_picture = 0;
            int ret = avcodec_decode_video2(pCodecCtx, pFrame, &got_picture, packet);
            if (ret < 0){
                WEBRTC_TRACE(webrtc::kTraceError, webrtc::kTraceVideoCoding, -1,
                    "H264DecoderImpl::Decode, Decode Error.");
                return WEBRTC_VIDEO_CODEC_ERROR;
            }
            if (got_picture){
                sws_scale(img_convert_ctx, (const uint8_t* const*)pFrame->data, pFrame->linesize, 0, pCodecCtx->height,
                    pFrameYUV->data, pFrameYUV->linesize);

                int size_y = pFrameYUV->linesize[0] * pCodecCtx->height;
                int size_u = pFrameYUV->linesize[1] * pCodecCtx->height / 2;
                int size_v = pFrameYUV->linesize[2] * pCodecCtx->height / 2;

                decoded_image_.CreateFrame(size_y, static_cast<uint8_t*>(pFrameYUV->data[0]),
                    size_u, static_cast<uint8_t*>(pFrameYUV->data[1]),
                    size_v, static_cast<uint8_t*>(pFrameYUV->data[2]),
                    pCodecCtx->width,
                    pCodecCtx->height,
                    pFrameYUV->linesize[0],
                    pFrameYUV->linesize[1],
                    pFrameYUV->linesize[2]);

                decoded_image_.set_timestamp(input_image._timeStamp);
                decode_complete_callback_->Decoded(decoded_image_);
                return WEBRTC_VIDEO_CODEC_OK;
            }
            else
                printf(".");
            av_free_packet(packet);
        }
        return WEBRTC_VIDEO_CODEC_OK;
    }

其他方法的实现保持不变，至此ffmpeg解码功能的重新封装也完成了。

 

从最后实现的效果来看，X264的视频质量的确是最好的，但是播放端的解码延时比较高，暂时还不清楚原因，希望了解的朋友指教。
本项目源代码