chancle 2020-02-22
Linux下用 FFMPEG 采集 usb摄像头视频 和 摄像头内置麦克风音频 到RTMP服务
ffmpeg -f video4linux2 -qscale 10 -r 12 -s 640x480 -i /dev/video0 -f alsa -i hw:1 -ab 16 -ar 22050 -ac 1 -f mp3 -f flv rtmp://127.0.0.1/rtmpsvr/rtmp1
./ffmpeg -f video4linux2 -s 640x480 -i /dev/video0 -f flv rtmp://127.0.0.1:1935/live/live
首先说一下推流,主要使用ffmpeg命令进行本地摄像头的推流,为了实现首屏秒开使用-g设置gop大小,同时使用-b降低网络负载,保证流畅度。
linux ffmpeg -r 30 -i /dev/video0 -vcodec h264 -max_delay 100 -f flv -g 5 -b 700000 rtmp://219.216.87.170/live/test1 window ffmpeg -r 30 -f vfwcap -i 0 -vcodec h264 -max_delay 100 -f flv -g 5 -b 700000 rtmp://219.216.87.170/live/test1 ffmpeg -list_devices true -f dshow -i dummy ffmpeg -r 30 -f dshow -i video="1.3M HD WebCam" -vcodec h264 -max_delay 100 -f flv -g 5 -b 700000 rtmp://219.216.87.170/live/tes t1
其次是収流,収流最开始的时候,有很大的延迟,大约5秒,后来通过优化,现在延时保证在1s以内,还是可以接收的,直接上収流的程序
AVFormatContext *pFormatCtx; int i, videoindex; AVCodecContext *pCodecCtx; AVCodec *pCodec; AVFrame *pFrame, *pFrameRGB; uint8_t *out_buffer; AVPacket *packet; //int y_size; int ret, got_picture; struct SwsContext *img_convert_ctx; //输入文件路径 // char filepath[] = "rtmp://219.216.87.170/vod/test.flv"; char filepath[] = "rtmp://219.216.87.170/live/test1"; int frame_cnt; printf("wait for playing %s\n", filepath); av_register_all(); avformat_network_init(); pFormatCtx = avformat_alloc_context(); printf("size %ld\tduration %ld\n", pFormatCtx->probesize, pFormatCtx->max_analyze_duration); pFormatCtx->probesize = 20000000; pFormatCtx->max_analyze_duration = 2000; // pFormatCtx->interrupt_callback.callback = timout_callback; // pFormatCtx->interrupt_callback.opaque = pFormatCtx; // pFormatCtx->flags |= AVFMT_FLAG_NONBLOCK; AVDictionary* options = NULL; av_dict_set(&options, "fflags", "nobuffer", 0); // av_dict_set(&options, "max_delay", "100000", 0); // av_dict_set(&options, "rtmp_transport", "tcp", 0); // av_dict_set(&options, "stimeout", "6", 0); printf("wating for opening file\n"); if (avformat_open_input(&pFormatCtx, filepath, NULL, &options) != 0) { printf("Couldn't open input stream.\n"); return -1; } av_dict_free(&options); printf("wating for finding stream\n"); if (avformat_find_stream_info(pFormatCtx, NULL) < 0) { printf("Couldn't find stream information.\n"); return -1; } videoindex = -1; for (i = 0; i < pFormatCtx->nb_streams; i++) if (pFormatCtx->streams[i]->codec->codec_type == AVMEDIA_TYPE_VIDEO) { videoindex = i; break; } if (videoindex == -1) { printf("Didn't find a video stream.\n"); return -1; } pCodecCtx = pFormatCtx->streams[videoindex]->codec; pCodec = avcodec_find_decoder(pCodecCtx->codec_id); if (pCodec == NULL) { printf("Codec not found.\n"); return -1; } if (avcodec_open2(pCodecCtx, pCodec, NULL) < 0) { printf("Could not open codec.\n"); return -1; } /* * 在此处添加输出视频信息的代码 * 取自于pFormatCtx,使用fprintf() */ pFrame = av_frame_alloc(); pFrameRGB = av_frame_alloc(); out_buffer = (uint8_t *) av_malloc( avpicture_get_size(AV_PIX_FMT_BGR24, pCodecCtx->width, pCodecCtx->height)); avpicture_fill((AVPicture *) pFrameRGB, out_buffer, AV_PIX_FMT_BGR24, pCodecCtx->width, pCodecCtx->height); packet = (AVPacket *) av_malloc(sizeof(AVPacket)); //Output Info----------------------------- printf("--------------- File Information ----------------\n"); av_dump_format(pFormatCtx, 0, filepath, 0); printf("-------------------------------------------------\n"); img_convert_ctx = sws_getContext(pCodecCtx->width, pCodecCtx->height, pCodecCtx->pix_fmt, pCodecCtx->width, pCodecCtx->height, AV_PIX_FMT_BGR24, SWS_BICUBIC, NULL, NULL, NULL); CvSize imagesize; imagesize.width = pCodecCtx->width; imagesize.height = pCodecCtx->height; IplImage *image = cvCreateImageHeader(imagesize, IPL_DEPTH_8U, 3); cvSetData(image, out_buffer, imagesize.width * 3); cvNamedWindow(filepath, CV_WINDOW_AUTOSIZE); frame_cnt = 0; int num = 0; while (av_read_frame(pFormatCtx, packet) >= 0) { if (packet->stream_index == videoindex) { /* * 在此处添加输出H264码流的代码 * 取自于packet,使用fwrite() */ ret = avcodec_decode_video2(pCodecCtx, pFrame, &got_picture, packet); if (ret < 0) { printf("Decode Error.\n"); return -1; } if (got_picture) { sws_scale(img_convert_ctx, (const uint8_t* const *) pFrame->data, pFrame->linesize, 0, pCodecCtx->height, pFrameRGB->data, pFrameRGB->linesize); printf("Decoded frame index: %d\n", frame_cnt); /* * 在此处添加输出YUV的代码 * 取自于pFrameYUV,使用fwrite() */ frame_cnt++; cvShowImage(filepath, image); cvWaitKey(30); } } av_free_packet(packet); } sws_freeContext(img_convert_ctx); av_frame_free(&pFrameRGB); av_frame_free(&pFrame); avcodec_close(pCodecCtx); avformat_close_input(&pFormatCtx); return 0;
将解压后的数据区与opencv的IplImage的数据区映射,实现opencv显示。
检测部分,主要使用IplImage与yolo中的图像进行对接,在图像转换方面,进行了部分优化,缩减一些不必要的步骤。然后使用线程区接收ffmepg流,主循环里区做检测并显示。需要做线程同步处理,只有当收到新流时,才去检测。