/* $Id: VideoFFmpeg.cpp 29240 2010-06-05 15:31:55Z campbellbarton $ ----------------------------------------------------------------------------- This source file is part of VideoTexture library Copyright (c) 2007 The Zdeno Ash Miklas This program is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA, or go to http://www.gnu.org/copyleft/lesser.txt. ----------------------------------------------------------------------------- */ #ifdef WITH_FFMPEG // INT64_C fix for some linux machines (C99ism) #ifndef __STDC_CONSTANT_MACROS #define __STDC_CONSTANT_MACROS #endif #include #include "MEM_guardedalloc.h" #include "PIL_time.h" #include #include "Exception.h" #include "VideoFFmpeg.h" // default framerate const double defFrameRate = 25.0; // time scale constant const long timeScale = 1000; // macro for exception handling and logging #define CATCH_EXCP catch (Exception & exp) \ { exp.report(); m_status = SourceError; } extern "C" void do_init_ffmpeg(); // class RenderVideo // constructor VideoFFmpeg::VideoFFmpeg (HRESULT * hRslt) : VideoBase(), m_codec(NULL), m_formatCtx(NULL), m_codecCtx(NULL), m_frame(NULL), m_frameDeinterlaced(NULL), m_frameRGB(NULL), m_imgConvertCtx(NULL), m_deinterlace(false), m_preseek(0), m_videoStream(-1), m_baseFrameRate(25.0), m_lastFrame(-1), m_eof(false), m_externTime(false), m_curPosition(-1), m_startTime(0), m_captWidth(0), m_captHeight(0), m_captRate(0.f), m_isImage(false), m_isThreaded(false), m_isStreaming(false), m_stopThread(false), m_cacheStarted(false) { // set video format m_format = RGB24; // force flip because ffmpeg always return the image in the wrong orientation for texture setFlip(true); // construction is OK *hRslt = S_OK; m_thread.first = m_thread.last = NULL; pthread_mutex_init(&m_cacheMutex, NULL); m_frameCacheFree.first = m_frameCacheFree.last = NULL; m_frameCacheBase.first = m_frameCacheBase.last = NULL; m_packetCacheFree.first = m_packetCacheFree.last = NULL; m_packetCacheBase.first = m_packetCacheBase.last = NULL; } // destructor VideoFFmpeg::~VideoFFmpeg () { } // release components bool VideoFFmpeg::release() { // release stopCache(); if (m_codecCtx) { avcodec_close(m_codecCtx); m_codecCtx = NULL; } if (m_formatCtx) { av_close_input_file(m_formatCtx); m_formatCtx = NULL; } if (m_frame) { av_free(m_frame); m_frame = NULL; } if (m_frameDeinterlaced) { MEM_freeN(m_frameDeinterlaced->data[0]); av_free(m_frameDeinterlaced); m_frameDeinterlaced = NULL; } if (m_frameRGB) { MEM_freeN(m_frameRGB->data[0]); av_free(m_frameRGB); m_frameRGB = NULL; } if (m_imgConvertCtx) { sws_freeContext(m_imgConvertCtx); m_imgConvertCtx = NULL; } m_codec = NULL; m_status = SourceStopped; m_lastFrame = -1; return true; } AVFrame *VideoFFmpeg::allocFrameRGB() { AVFrame *frame; frame = avcodec_alloc_frame(); if (m_format == RGBA32) { avpicture_fill((AVPicture*)frame, (uint8_t*)MEM_callocN(avpicture_get_size( PIX_FMT_RGBA, m_codecCtx->width, m_codecCtx->height), "ffmpeg rgba"), PIX_FMT_RGBA, m_codecCtx->width, m_codecCtx->height); } else { avpicture_fill((AVPicture*)frame, (uint8_t*)MEM_callocN(avpicture_get_size( PIX_FMT_RGB24, m_codecCtx->width, m_codecCtx->height), "ffmpeg rgb"), PIX_FMT_RGB24, m_codecCtx->width, m_codecCtx->height); } return frame; } // set initial parameters void VideoFFmpeg::initParams (short width, short height, float rate, bool image) { m_captWidth = width; m_captHeight = height; m_captRate = rate; m_isImage = image; } int VideoFFmpeg::openStream(const char *filename, AVInputFormat *inputFormat, AVFormatParameters *formatParams) { AVFormatContext *formatCtx; int i, videoStream; AVCodec *codec; AVCodecContext *codecCtx; if(av_open_input_file(&formatCtx, filename, inputFormat, 0, formatParams)!=0) return -1; if(av_find_stream_info(formatCtx)<0) { av_close_input_file(formatCtx); return -1; } /* Find the first video stream */ videoStream=-1; for(i=0; inb_streams; i++) { if(formatCtx->streams[i] && get_codec_from_stream(formatCtx->streams[i]) && (get_codec_from_stream(formatCtx->streams[i])->codec_type==CODEC_TYPE_VIDEO)) { videoStream=i; break; } } if(videoStream==-1) { av_close_input_file(formatCtx); return -1; } codecCtx = get_codec_from_stream(formatCtx->streams[videoStream]); /* Find the decoder for the video stream */ codec=avcodec_find_decoder(codecCtx->codec_id); if(codec==NULL) { av_close_input_file(formatCtx); return -1; } codecCtx->workaround_bugs = 1; if(avcodec_open(codecCtx, codec)<0) { av_close_input_file(formatCtx); return -1; } #ifdef FFMPEG_OLD_FRAME_RATE if(codecCtx->frame_rate>1000 && codecCtx->frame_rate_base==1) codecCtx->frame_rate_base=1000; m_baseFrameRate = (double)codecCtx->frame_rate / (double)codecCtx->frame_rate_base; #else m_baseFrameRate = av_q2d(formatCtx->streams[videoStream]->r_frame_rate); #endif if (m_baseFrameRate <= 0.0) m_baseFrameRate = defFrameRate; m_codec = codec; m_codecCtx = codecCtx; m_formatCtx = formatCtx; m_videoStream = videoStream; m_frame = avcodec_alloc_frame(); m_frameDeinterlaced = avcodec_alloc_frame(); // allocate buffer if deinterlacing is required avpicture_fill((AVPicture*)m_frameDeinterlaced, (uint8_t*)MEM_callocN(avpicture_get_size( m_codecCtx->pix_fmt, m_codecCtx->width, m_codecCtx->height), "ffmpeg deinterlace"), m_codecCtx->pix_fmt, m_codecCtx->width, m_codecCtx->height); // check if the pixel format supports Alpha if (m_codecCtx->pix_fmt == PIX_FMT_RGB32 || m_codecCtx->pix_fmt == PIX_FMT_BGR32 || m_codecCtx->pix_fmt == PIX_FMT_RGB32_1 || m_codecCtx->pix_fmt == PIX_FMT_BGR32_1) { // allocate buffer to store final decoded frame m_format = RGBA32; // allocate sws context m_imgConvertCtx = sws_getContext( m_codecCtx->width, m_codecCtx->height, m_codecCtx->pix_fmt, m_codecCtx->width, m_codecCtx->height, PIX_FMT_RGBA, SWS_FAST_BILINEAR, NULL, NULL, NULL); } else { // allocate buffer to store final decoded frame m_format = RGB24; // allocate sws context m_imgConvertCtx = sws_getContext( m_codecCtx->width, m_codecCtx->height, m_codecCtx->pix_fmt, m_codecCtx->width, m_codecCtx->height, PIX_FMT_RGB24, SWS_FAST_BILINEAR, NULL, NULL, NULL); } m_frameRGB = allocFrameRGB(); if (!m_imgConvertCtx) { avcodec_close(m_codecCtx); m_codecCtx = NULL; av_close_input_file(m_formatCtx); m_formatCtx = NULL; av_free(m_frame); m_frame = NULL; MEM_freeN(m_frameDeinterlaced->data[0]); av_free(m_frameDeinterlaced); m_frameDeinterlaced = NULL; MEM_freeN(m_frameRGB->data[0]); av_free(m_frameRGB); m_frameRGB = NULL; return -1; } return 0; } /* * This thread is used to load video frame asynchronously. * It provides a frame caching service. * The main thread is responsible for positionning the frame pointer in the * file correctly before calling startCache() which starts this thread. * The cache is organized in two layers: 1) a cache of 20-30 undecoded packets to keep * memory and CPU low 2) a cache of 5 decoded frames. * If the main thread does not find the frame in the cache (because the video has restarted * or because the GE is lagging), it stops the cache with StopCache() (this is a synchronous * function: it sends a signal to stop the cache thread and wait for confirmation), then * change the position in the stream and restarts the cache thread. */ void *VideoFFmpeg::cacheThread(void *data) { VideoFFmpeg* video = (VideoFFmpeg*)data; // holds the frame that is being decoded CacheFrame *currentFrame = NULL; CachePacket *cachePacket; bool endOfFile = false; int frameFinished = 0; double timeBase = av_q2d(video->m_formatCtx->streams[video->m_videoStream]->time_base); int64_t startTs = video->m_formatCtx->streams[video->m_videoStream]->start_time; if (startTs == AV_NOPTS_VALUE) startTs = 0; while (!video->m_stopThread) { // packet cache is used solely by this thread, no need to lock // In case the stream/file contains other stream than the one we are looking for, // allow a bit of cycling to get rid quickly of those frames frameFinished = 0; while ( !endOfFile && (cachePacket = (CachePacket *)video->m_packetCacheFree.first) != NULL && frameFinished < 25) { // free packet => packet cache is not full yet, just read more if (av_read_frame(video->m_formatCtx, &cachePacket->packet)>=0) { if (cachePacket->packet.stream_index == video->m_videoStream) { // make sure fresh memory is allocated for the packet and move it to queue av_dup_packet(&cachePacket->packet); BLI_remlink(&video->m_packetCacheFree, cachePacket); BLI_addtail(&video->m_packetCacheBase, cachePacket); break; } else { // this is not a good packet for us, just leave it on free queue // Note: here we could handle sound packet av_free_packet(&cachePacket->packet); frameFinished++; } } else { if (video->m_isFile) // this mark the end of the file endOfFile = true; // if we cannot read a packet, no need to continue break; } } // frame cache is also used by main thread, lock if (currentFrame == NULL) { // no current frame being decoded, take free one pthread_mutex_lock(&video->m_cacheMutex); if ((currentFrame = (CacheFrame *)video->m_frameCacheFree.first) != NULL) BLI_remlink(&video->m_frameCacheFree, currentFrame); pthread_mutex_unlock(&video->m_cacheMutex); } if (currentFrame != NULL) { // this frame is out of free and busy queue, we can manipulate it without locking frameFinished = 0; while (!frameFinished && (cachePacket = (CachePacket *)video->m_packetCacheBase.first) != NULL) { BLI_remlink(&video->m_packetCacheBase, cachePacket); // use m_frame because when caching, it is not used in main thread // we can't use currentFrame directly because we need to convert to RGB first avcodec_decode_video(video->m_codecCtx, video->m_frame, &frameFinished, cachePacket->packet.data, cachePacket->packet.size); if(frameFinished) { AVFrame * input = video->m_frame; /* This means the data wasnt read properly, this check stops crashing */ if ( input->data[0]!=0 || input->data[1]!=0 || input->data[2]!=0 || input->data[3]!=0) { if (video->m_deinterlace) { if (avpicture_deinterlace( (AVPicture*) video->m_frameDeinterlaced, (const AVPicture*) video->m_frame, video->m_codecCtx->pix_fmt, video->m_codecCtx->width, video->m_codecCtx->height) >= 0) { input = video->m_frameDeinterlaced; } } // convert to RGB24 sws_scale(video->m_imgConvertCtx, input->data, input->linesize, 0, video->m_codecCtx->height, currentFrame->frame->data, currentFrame->frame->linesize); // move frame to queue, this frame is necessarily the next one video->m_curPosition = (long)((cachePacket->packet.dts-startTs) * (video->m_baseFrameRate*timeBase) + 0.5); currentFrame->framePosition = video->m_curPosition; pthread_mutex_lock(&video->m_cacheMutex); BLI_addtail(&video->m_frameCacheBase, currentFrame); pthread_mutex_unlock(&video->m_cacheMutex); currentFrame = NULL; } } av_free_packet(&cachePacket->packet); BLI_addtail(&video->m_packetCacheFree, cachePacket); } if (currentFrame && endOfFile) { // no more packet and end of file => put a special frame that indicates that currentFrame->framePosition = -1; pthread_mutex_lock(&video->m_cacheMutex); BLI_addtail(&video->m_frameCacheBase, currentFrame); pthread_mutex_unlock(&video->m_cacheMutex); currentFrame = NULL; // no need to stay any longer in this thread break; } } // small sleep to avoid unnecessary looping PIL_sleep_ms(10); } // before quitting, put back the current frame to queue to allow freeing if (currentFrame) { pthread_mutex_lock(&video->m_cacheMutex); BLI_addtail(&video->m_frameCacheFree, currentFrame); pthread_mutex_unlock(&video->m_cacheMutex); } return 0; } // start thread to cache video frame from file/capture/stream // this function should be called only when the position in the stream is set for the // first frame to cache bool VideoFFmpeg::startCache() { if (!m_cacheStarted && m_isThreaded) { m_stopThread = false; for (int i=0; iframe = allocFrameRGB(); BLI_addtail(&m_frameCacheFree, frame); } for (int i=0; iframe->data[0]); av_free(frame->frame); delete frame; } while ((frame = (CacheFrame *)m_frameCacheFree.first) != NULL) { BLI_remlink(&m_frameCacheFree, frame); MEM_freeN(frame->frame->data[0]); av_free(frame->frame); delete frame; } while((packet = (CachePacket *)m_packetCacheBase.first) != NULL) { BLI_remlink(&m_packetCacheBase, packet); av_free_packet(&packet->packet); delete packet; } while((packet = (CachePacket *)m_packetCacheFree.first) != NULL) { BLI_remlink(&m_packetCacheFree, packet); delete packet; } m_cacheStarted = false; } } void VideoFFmpeg::releaseFrame(AVFrame* frame) { if (frame == m_frameRGB) { // this is not a frame from the cache, ignore return; } // this frame MUST be the first one of the queue pthread_mutex_lock(&m_cacheMutex); CacheFrame *cacheFrame = (CacheFrame *)m_frameCacheBase.first; assert (cacheFrame != NULL && cacheFrame->frame == frame); BLI_remlink(&m_frameCacheBase, cacheFrame); BLI_addtail(&m_frameCacheFree, cacheFrame); pthread_mutex_unlock(&m_cacheMutex); } // open video file void VideoFFmpeg::openFile (char * filename) { do_init_ffmpeg(); if (openStream(filename, NULL, NULL) != 0) return; if (m_codecCtx->gop_size) m_preseek = (m_codecCtx->gop_size < 25) ? m_codecCtx->gop_size+1 : 25; else if (m_codecCtx->has_b_frames) m_preseek = 25; // should determine gopsize else m_preseek = 0; // get video time range m_range[0] = 0.0; m_range[1] = (double)m_formatCtx->duration / AV_TIME_BASE; // open base class VideoBase::openFile(filename); if ( // ffmpeg reports that http source are actually non stream // but it is really not desirable to seek on http file, so force streaming. // It would be good to find this information from the context but there are no simple indication !strncmp(filename, "http://", 7) || #ifdef FFMPEG_PB_IS_POINTER (m_formatCtx->pb && m_formatCtx->pb->is_streamed) #else m_formatCtx->pb.is_streamed #endif ) { // the file is in fact a streaming source, treat as cam to prevent seeking m_isFile = false; // but it's not handled exactly like a camera. m_isStreaming = true; // for streaming it is important to do non blocking read m_formatCtx->flags |= AVFMT_FLAG_NONBLOCK; } if (m_isImage) { // the file is to be treated as an image, i.e. load the first frame only m_isFile = false; // in case of reload, the filename is taken from m_imageName, no need to change it if (m_imageName.Ptr() != filename) m_imageName = filename; m_preseek = 0; m_avail = false; play(); } // check if we should do multi-threading? if (!m_isImage && BLI_system_thread_count() > 1) { // never thread image: there are no frame to read ahead // no need to thread if the system has a single core m_isThreaded = true; } } // open video capture device void VideoFFmpeg::openCam (char * file, short camIdx) { // open camera source AVInputFormat *inputFormat; AVFormatParameters formatParams; AVRational frameRate; char *p, filename[28], rateStr[20]; do_init_ffmpeg(); memset(&formatParams, 0, sizeof(formatParams)); #ifdef WIN32 // video capture on windows only through Video For Windows driver inputFormat = av_find_input_format("vfwcap"); if (!inputFormat) // Video For Windows not supported?? return; sprintf(filename, "%d", camIdx); #else // In Linux we support two types of devices: VideoForLinux and DV1394. // the user specify it with the filename: // [][:] // : 'v4l' for VideoForLinux, 'dv1394' for DV1394. By default 'v4l' // : 'pal', 'secam' or 'ntsc'. By default 'ntsc' // The driver name is constructed automatically from the device type: // v4l : /dev/video // dv1394: /dev/dv1394/ // If you have different driver name, you can specify the driver name explicitely // instead of device type. Examples of valid filename: // /dev/v4l/video0:pal // /dev/ieee1394/1:ntsc // dv1394:secam // v4l:pal if (file && strstr(file, "1394") != NULL) { // the user specifies a driver, check if it is v4l or d41394 inputFormat = av_find_input_format("dv1394"); sprintf(filename, "/dev/dv1394/%d", camIdx); } else { inputFormat = av_find_input_format("video4linux"); sprintf(filename, "/dev/video%d", camIdx); } if (!inputFormat) // these format should be supported, check ffmpeg compilation return; if (file && strncmp(file, "/dev", 4) == 0) { // user does not specify a driver strncpy(filename, file, sizeof(filename)); filename[sizeof(filename)-1] = 0; if ((p = strchr(filename, ':')) != 0) *p = 0; } if (file && (p = strchr(file, ':')) != NULL) formatParams.standard = p+1; #endif //frame rate if (m_captRate <= 0.f) m_captRate = defFrameRate; sprintf(rateStr, "%f", m_captRate); av_parse_video_frame_rate(&frameRate, rateStr); // populate format parameters // need to specify the time base = inverse of rate formatParams.time_base.num = frameRate.den; formatParams.time_base.den = frameRate.num; formatParams.width = m_captWidth; formatParams.height = m_captHeight; if (openStream(filename, inputFormat, &formatParams) != 0) return; // for video capture it is important to do non blocking read m_formatCtx->flags |= AVFMT_FLAG_NONBLOCK; // open base class VideoBase::openCam(file, camIdx); // check if we should do multi-threading? if (BLI_system_thread_count() > 1) { // no need to thread if the system has a single core m_isThreaded = true; } } // play video bool VideoFFmpeg::play (void) { try { // if object is able to play if (VideoBase::play()) { // set video position setPositions(); // return success return true; } } CATCH_EXCP; return false; } // pause video bool VideoFFmpeg::pause (void) { try { if (VideoBase::pause()) { return true; } } CATCH_EXCP; return false; } // stop video bool VideoFFmpeg::stop (void) { try { VideoBase::stop(); // force restart when play m_lastFrame = -1; return true; } CATCH_EXCP; return false; } // set video range void VideoFFmpeg::setRange (double start, double stop) { try { // set range if (m_isFile) { VideoBase::setRange(start, stop); // set range for video setPositions(); } } CATCH_EXCP; } // set framerate void VideoFFmpeg::setFrameRate (float rate) { VideoBase::setFrameRate(rate); } // image calculation // load frame from video void VideoFFmpeg::calcImage (unsigned int texId, double ts) { if (m_status == SourcePlaying) { // get actual time double startTime = PIL_check_seconds_timer(); double actTime; // timestamp passed from audio actuators can sometimes be slightly negative if (m_isFile && ts >= -0.5) { // allow setting timestamp only when not streaming actTime = ts; if (actTime * actFrameRate() < m_lastFrame) { // user is asking to rewind, force a cache clear to make sure we will do a seek // note that this does not decrement m_repeat if ts didn't reach m_range[1] stopCache(); } } else { if (m_lastFrame == -1 && !m_isFile) m_startTime = startTime; actTime = startTime - m_startTime; } // if video has ended if (m_isFile && actTime * m_frameRate >= m_range[1]) { // in any case, this resets the cache stopCache(); // if repeats are set, decrease them if (m_repeat > 0) --m_repeat; // if video has to be replayed if (m_repeat != 0) { // reset its position actTime -= (m_range[1] - m_range[0]) / m_frameRate; m_startTime += (m_range[1] - m_range[0]) / m_frameRate; } // if video has to be stopped, stop it else { m_status = SourceStopped; return; } } // actual frame long actFrame = (m_isImage) ? m_lastFrame+1 : long(actTime * actFrameRate()); // if actual frame differs from last frame if (actFrame != m_lastFrame) { AVFrame* frame; // get image if((frame = grabFrame(actFrame)) != NULL) { if (!m_isFile && !m_cacheStarted) { // streaming without cache: detect synchronization problem double execTime = PIL_check_seconds_timer() - startTime; if (execTime > 0.005) { // exec time is too long, it means that the function was blocking // resynchronize the stream from this time m_startTime += execTime; } } // save actual frame m_lastFrame = actFrame; // init image, if needed init(short(m_codecCtx->width), short(m_codecCtx->height)); // process image process((BYTE*)(frame->data[0])); // finished with the frame, release it so that cache can reuse it releaseFrame(frame); // in case it is an image, automatically stop reading it if (m_isImage) { m_status = SourceStopped; // close the file as we don't need it anymore release(); } } else if (m_isStreaming) { // we didn't get a frame and we are streaming, this may be due to // a delay in the network or because we are getting the frame too fast. // In the later case, shift time by a small amount to compensate for a drift m_startTime += 0.001; } } } } // set actual position void VideoFFmpeg::setPositions (void) { // set video start time m_startTime = PIL_check_seconds_timer(); // if file is played and actual position is before end position if (!m_eof && m_lastFrame >= 0 && (!m_isFile || m_lastFrame < m_range[1] * actFrameRate())) // continue from actual position m_startTime -= double(m_lastFrame) / actFrameRate(); else { m_startTime -= m_range[0]; // start from begining, stop cache just in case stopCache(); } } // position pointer in file, position in second AVFrame *VideoFFmpeg::grabFrame(long position) { AVPacket packet; int frameFinished; int posFound = 1; bool frameLoaded = false; int64_t targetTs = 0; CacheFrame *frame; int64_t dts = 0; if (m_cacheStarted) { // when cache is active, we must not read the file directly do { pthread_mutex_lock(&m_cacheMutex); frame = (CacheFrame *)m_frameCacheBase.first; pthread_mutex_unlock(&m_cacheMutex); // no need to remove the frame from the queue: the cache thread does not touch the head, only the tail if (frame == NULL) { // no frame in cache, in case of file it is an abnormal situation if (m_isFile) { // go back to no threaded reading stopCache(); break; } return NULL; } if (frame->framePosition == -1) { // this frame mark the end of the file (only used for file) // leave in cache to make sure we don't miss it m_eof = true; return NULL; } // for streaming, always return the next frame, // that's what grabFrame does in non cache mode anyway. if (m_isStreaming || frame->framePosition == position) { return frame->frame; } // for cam, skip old frames to keep image realtime. // There should be no risk of clock drift since it all happens on the same CPU if (frame->framePosition > position) { // this can happen after rewind if the seek didn't find the first frame // the frame in the buffer is ahead of time, just leave it there return NULL; } // this frame is not useful, release it pthread_mutex_lock(&m_cacheMutex); BLI_remlink(&m_frameCacheBase, frame); BLI_addtail(&m_frameCacheFree, frame); pthread_mutex_unlock(&m_cacheMutex); } while (true); } double timeBase = av_q2d(m_formatCtx->streams[m_videoStream]->time_base); int64_t startTs = m_formatCtx->streams[m_videoStream]->start_time; if (startTs == AV_NOPTS_VALUE) startTs = 0; // come here when there is no cache or cache has been stopped // locate the frame, by seeking if necessary (seeking is only possible for files) if (m_isFile) { // first check if the position that we are looking for is in the preseek range // if so, just read the frame until we get there if (position > m_curPosition + 1 && m_preseek && position - (m_curPosition + 1) < m_preseek) { while(av_read_frame(m_formatCtx, &packet)>=0) { if (packet.stream_index == m_videoStream) { avcodec_decode_video( m_codecCtx, m_frame, &frameFinished, packet.data, packet.size); if (frameFinished) { m_curPosition = (long)((packet.dts-startTs) * (m_baseFrameRate*timeBase) + 0.5); } } av_free_packet(&packet); if (position == m_curPosition+1) break; } } // if the position is not in preseek, do a direct jump if (position != m_curPosition + 1) { int64_t pos = (int64_t)((position - m_preseek) / (m_baseFrameRate*timeBase)); if (pos < 0) pos = 0; pos += startTs; if (position <= m_curPosition || !m_eof) { #if 0 // Tried to make this work but couldn't: seeking on byte is ignored by the // format plugin and it will generally continue to read from last timestamp. // Too bad because frame seek is not always able to get the first frame // of the file. if (position <= m_preseek) { // we can safely go the begining of the file if (av_seek_frame(m_formatCtx, m_videoStream, 0, AVSEEK_FLAG_BYTE) >= 0) { // binary seek does not reset the timestamp, must do it now av_update_cur_dts(m_formatCtx, m_formatCtx->streams[m_videoStream], startTs); m_curPosition = 0; } } else #endif { // current position is now lost, guess a value. if (av_seek_frame(m_formatCtx, m_videoStream, pos, AVSEEK_FLAG_BACKWARD) >= 0) { // current position is now lost, guess a value. // It's not important because it will be set at this end of this function m_curPosition = position - m_preseek - 1; } } } // this is the timestamp of the frame we're looking for targetTs = (int64_t)(position / (m_baseFrameRate * timeBase)) + startTs; posFound = 0; avcodec_flush_buffers(m_codecCtx); } } else if (m_isThreaded) { // cache is not started but threading is possible // better not read the stream => make take some time, better start caching if (startCache()) return NULL; // Abnormal!!! could not start cache, fall back on direct read m_isThreaded = false; } // find the correct frame, in case of streaming and no cache, it means just // return the next frame. This is not quite correct, may need more work while(av_read_frame(m_formatCtx, &packet)>=0) { if(packet.stream_index == m_videoStream) { avcodec_decode_video(m_codecCtx, m_frame, &frameFinished, packet.data, packet.size); // remember dts to compute exact frame number dts = packet.dts; if (frameFinished && !posFound) { if (dts >= targetTs) { posFound = 1; } } if (frameFinished && posFound == 1) { AVFrame * input = m_frame; /* This means the data wasnt read properly, this check stops crashing */ if ( input->data[0]==0 && input->data[1]==0 && input->data[2]==0 && input->data[3]==0) { av_free_packet(&packet); break; } if (m_deinterlace) { if (avpicture_deinterlace( (AVPicture*) m_frameDeinterlaced, (const AVPicture*) m_frame, m_codecCtx->pix_fmt, m_codecCtx->width, m_codecCtx->height) >= 0) { input = m_frameDeinterlaced; } } // convert to RGB24 sws_scale(m_imgConvertCtx, input->data, input->linesize, 0, m_codecCtx->height, m_frameRGB->data, m_frameRGB->linesize); av_free_packet(&packet); frameLoaded = true; break; } } av_free_packet(&packet); } m_eof = m_isFile && !frameLoaded; if (frameLoaded) { m_curPosition = (long)((dts-startTs) * (m_baseFrameRate*timeBase) + 0.5); if (m_isThreaded) { // normal case for file: first locate, then start cache if (!startCache()) { // Abnormal!! could not start cache, return to non-cache mode m_isThreaded = false; } } return m_frameRGB; } return NULL; } // python methods // cast Image pointer to VideoFFmpeg inline VideoFFmpeg * getVideoFFmpeg (PyImage * self) { return static_cast(self->m_image); } // object initialization static int VideoFFmpeg_init (PyObject * pySelf, PyObject * args, PyObject * kwds) { PyImage * self = reinterpret_cast(pySelf); // parameters - video source // file name or format type for capture (only for Linux: video4linux or dv1394) char * file = NULL; // capture device number short capt = -1; // capture width, only if capt is >= 0 short width = 0; // capture height, only if capt is >= 0 short height = 0; // capture rate, only if capt is >= 0 float rate = 25.f; static const char *kwlist[] = {"file", "capture", "rate", "width", "height", NULL}; // get parameters if (!PyArg_ParseTupleAndKeywords(args, kwds, "s|hfhh", const_cast(kwlist), &file, &capt, &rate, &width, &height)) return -1; try { // create video object Video_init(self); // set thread usage getVideoFFmpeg(self)->initParams(width, height, rate); // open video source Video_open(getVideo(self), file, capt); } catch (Exception & exp) { exp.report(); return -1; } // initialization succeded return 0; } PyObject * VideoFFmpeg_getPreseek (PyImage *self, void * closure) { return Py_BuildValue("h", getFFmpeg(self)->getPreseek()); } // set range int VideoFFmpeg_setPreseek (PyImage * self, PyObject * value, void * closure) { // check validity of parameter if (value == NULL || !PyLong_Check(value)) { PyErr_SetString(PyExc_TypeError, "The value must be an integer"); return -1; } // set preseek getFFmpeg(self)->setPreseek(PyLong_AsSsize_t(value)); // success return 0; } // get deinterlace PyObject * VideoFFmpeg_getDeinterlace (PyImage * self, void * closure) { if (getFFmpeg(self)->getDeinterlace()) Py_RETURN_TRUE; else Py_RETURN_FALSE; } // set flip int VideoFFmpeg_setDeinterlace (PyImage * self, PyObject * value, void * closure) { // check parameter, report failure if (value == NULL || !PyBool_Check(value)) { PyErr_SetString(PyExc_TypeError, "The value must be a bool"); return -1; } // set deinterlace getFFmpeg(self)->setDeinterlace(value == Py_True); // success return 0; } // methods structure static PyMethodDef videoMethods[] = { // methods from VideoBase class {"play", (PyCFunction)Video_play, METH_NOARGS, "Play (restart) video"}, {"pause", (PyCFunction)Video_pause, METH_NOARGS, "pause video"}, {"stop", (PyCFunction)Video_stop, METH_NOARGS, "stop video (play will replay it from start)"}, {"refresh", (PyCFunction)Video_refresh, METH_NOARGS, "Refresh video - get its status"}, {NULL} }; // attributes structure static PyGetSetDef videoGetSets[] = { // methods from VideoBase class {(char*)"status", (getter)Video_getStatus, NULL, (char*)"video status", NULL}, {(char*)"range", (getter)Video_getRange, (setter)Video_setRange, (char*)"replay range", NULL}, {(char*)"repeat", (getter)Video_getRepeat, (setter)Video_setRepeat, (char*)"repeat count, -1 for infinite repeat", NULL}, {(char*)"framerate", (getter)Video_getFrameRate, (setter)Video_setFrameRate, (char*)"frame rate", NULL}, // attributes from ImageBase class {(char*)"valid", (getter)Image_valid, NULL, (char*)"bool to tell if an image is available", NULL}, {(char*)"image", (getter)Image_getImage, NULL, (char*)"image data", NULL}, {(char*)"size", (getter)Image_getSize, NULL, (char*)"image size", NULL}, {(char*)"scale", (getter)Image_getScale, (setter)Image_setScale, (char*)"fast scale of image (near neighbour)", NULL}, {(char*)"flip", (getter)Image_getFlip, (setter)Image_setFlip, (char*)"flip image vertically", NULL}, {(char*)"filter", (getter)Image_getFilter, (setter)Image_setFilter, (char*)"pixel filter", NULL}, {(char*)"preseek", (getter)VideoFFmpeg_getPreseek, (setter)VideoFFmpeg_setPreseek, (char*)"nb of frames of preseek", NULL}, {(char*)"deinterlace", (getter)VideoFFmpeg_getDeinterlace, (setter)VideoFFmpeg_setDeinterlace, (char*)"deinterlace image", NULL}, {NULL} }; // python type declaration PyTypeObject VideoFFmpegType = { PyVarObject_HEAD_INIT(NULL, 0) "VideoTexture.VideoFFmpeg", /*tp_name*/ sizeof(PyImage), /*tp_basicsize*/ 0, /*tp_itemsize*/ (destructor)Image_dealloc, /*tp_dealloc*/ 0, /*tp_print*/ 0, /*tp_getattr*/ 0, /*tp_setattr*/ 0, /*tp_compare*/ 0, /*tp_repr*/ 0, /*tp_as_number*/ 0, /*tp_as_sequence*/ 0, /*tp_as_mapping*/ 0, /*tp_hash */ 0, /*tp_call*/ 0, /*tp_str*/ 0, /*tp_getattro*/ 0, /*tp_setattro*/ &imageBufferProcs, /*tp_as_buffer*/ Py_TPFLAGS_DEFAULT, /*tp_flags*/ "FFmpeg video source", /* tp_doc */ 0, /* tp_traverse */ 0, /* tp_clear */ 0, /* tp_richcompare */ 0, /* tp_weaklistoffset */ 0, /* tp_iter */ 0, /* tp_iternext */ videoMethods, /* tp_methods */ 0, /* tp_members */ videoGetSets, /* tp_getset */ 0, /* tp_base */ 0, /* tp_dict */ 0, /* tp_descr_get */ 0, /* tp_descr_set */ 0, /* tp_dictoffset */ (initproc)VideoFFmpeg_init, /* tp_init */ 0, /* tp_alloc */ Image_allocNew, /* tp_new */ }; // object initialization static int ImageFFmpeg_init (PyObject * pySelf, PyObject * args, PyObject * kwds) { PyImage * self = reinterpret_cast(pySelf); // parameters - video source // file name or format type for capture (only for Linux: video4linux or dv1394) char * file = NULL; // get parameters if (!PyArg_ParseTuple(args, "s:ImageFFmpeg", &file)) return -1; try { // create video object Video_init(self); getVideoFFmpeg(self)->initParams(0, 0, 1.0, true); // open video source Video_open(getVideo(self), file, -1); } catch (Exception & exp) { exp.report(); return -1; } // initialization succeded return 0; } PyObject * Image_reload (PyImage * self, PyObject *args) { char * newname = NULL; if (!PyArg_ParseTuple(args, "|s:reload", &newname)) return NULL; if (self->m_image != NULL) { VideoFFmpeg* video = getFFmpeg(self); // check type of object if (!newname) newname = video->getImageName(); if (!newname) { // if not set, retport error PyErr_SetString(PyExc_RuntimeError, "No image file name given"); return NULL; } // make sure the previous file is cleared video->release(); // open the new file video->openFile(newname); } Py_RETURN_NONE; } // methods structure static PyMethodDef imageMethods[] = { // methods from VideoBase class {"refresh", (PyCFunction)Video_refresh, METH_NOARGS, "Refresh image, i.e. load it"}, {"reload", (PyCFunction)Image_reload, METH_VARARGS, "Reload image, i.e. reopen it"}, {NULL} }; // attributes structure static PyGetSetDef imageGetSets[] = { // methods from VideoBase class {(char*)"status", (getter)Video_getStatus, NULL, (char*)"video status", NULL}, // attributes from ImageBase class {(char*)"valid", (getter)Image_valid, NULL, (char*)"bool to tell if an image is available", NULL}, {(char*)"image", (getter)Image_getImage, NULL, (char*)"image data", NULL}, {(char*)"size", (getter)Image_getSize, NULL, (char*)"image size", NULL}, {(char*)"scale", (getter)Image_getScale, (setter)Image_setScale, (char*)"fast scale of image (near neighbour)", NULL}, {(char*)"flip", (getter)Image_getFlip, (setter)Image_setFlip, (char*)"flip image vertically", NULL}, {(char*)"filter", (getter)Image_getFilter, (setter)Image_setFilter, (char*)"pixel filter", NULL}, {NULL} }; // python type declaration PyTypeObject ImageFFmpegType = { PyVarObject_HEAD_INIT(NULL, 0) "VideoTexture.ImageFFmpeg", /*tp_name*/ sizeof(PyImage), /*tp_basicsize*/ 0, /*tp_itemsize*/ (destructor)Image_dealloc, /*tp_dealloc*/ 0, /*tp_print*/ 0, /*tp_getattr*/ 0, /*tp_setattr*/ 0, /*tp_compare*/ 0, /*tp_repr*/ 0, /*tp_as_number*/ 0, /*tp_as_sequence*/ 0, /*tp_as_mapping*/ 0, /*tp_hash */ 0, /*tp_call*/ 0, /*tp_str*/ 0, /*tp_getattro*/ 0, /*tp_setattro*/ &imageBufferProcs, /*tp_as_buffer*/ Py_TPFLAGS_DEFAULT, /*tp_flags*/ "FFmpeg image source", /* tp_doc */ 0, /* tp_traverse */ 0, /* tp_clear */ 0, /* tp_richcompare */ 0, /* tp_weaklistoffset */ 0, /* tp_iter */ 0, /* tp_iternext */ imageMethods, /* tp_methods */ 0, /* tp_members */ imageGetSets, /* tp_getset */ 0, /* tp_base */ 0, /* tp_dict */ 0, /* tp_descr_get */ 0, /* tp_descr_set */ 0, /* tp_dictoffset */ (initproc)ImageFFmpeg_init, /* tp_init */ 0, /* tp_alloc */ Image_allocNew, /* tp_new */ }; #endif //WITH_FFMPEG