/* $Id: decavcodec.c,v 1.6 2005/03/06 04:08:54 titer Exp $ This file is part of the HandBrake source code. Homepage: . It may be used under the terms of the GNU General Public License. */ /* This module is Handbrake's interface to the ffmpeg decoder library (libavcodec & small parts of libavformat). It contains four Handbrake "work objects": decavcodec connects HB to an ffmpeg audio decoder decavcodecv connects HB to an ffmpeg video decoder (Two different routines are needed because the ffmpeg library has different decoder calling conventions for audio & video. The audio decoder should have had its name changed to "decavcodeca" but I got lazy.) These work objects are self-contained & follow all of HB's conventions for a decoder module. They can be used like any other HB decoder (deca52, decmpeg2, etc.). decavcodecai "internal" (incestuous?) version of decavcodec decavcodecvi "internal" (incestuous?) version of decavcodecv These routine are functionally equivalent to the routines above but can only be used by the ffmpeg-based stream reader in libhb/stream.c. The reason they exist is because the ffmpeg library leaves some of the information needed by the decoder in the AVStream (the data structure used by the stream reader) and we need to retrieve it to successfully decode frames. But in HB the reader and decoder modules are in completely separate threads and nothing goes between them but hb_buffers containing frames to be decoded. I.e., there's no easy way for the ffmpeg stream reader to pass a pointer to its AVStream over to the ffmpeg video or audio decoder. So the *i work objects use a private back door to the stream reader to get access to the AVStream (routines hb_ffmpeg_avstream and hb_ffmpeg_context) and the codec_param passed to these work objects is the key to this back door (it's basically an index that allows the correct AVStream to be retrieved). The normal & *i objects share a lot of code (the basic frame decoding and bitstream info code is factored out into subroutines that can be called by either) but the top level routines of the *i objects (decavcodecviWork, decavcodecviInfo, etc.) are different because: 1) they *have* to use the AVCodecContext that's contained in the reader's AVStream rather than just allocating & using their own, 2) the Info routines have access to stuff kept in the AVStream in addition to stuff kept in the AVCodecContext. This shouldn't be necessary but crucial information like video frame rate that should be in the AVCodecContext is either missing or wrong in the version of ffmpeg we're currently using. A consequence of the above is that the non-i work objects *can't* use information from the AVStream because there isn't one - they get their data from either the dvd reader or the mpeg reader, not the ffmpeg stream reader. That means that they have to make up for deficiencies in the AVCodecContext info by using stuff kept in the HB "title" struct. It also means that ffmpeg codecs that randomly scatter state needed by the decoder across both the AVCodecContext & the AVStream (e.g., the VC1 decoder) can't easily be used by the HB mpeg stream reader. */ #include "hb.h" #include "libavcodec/avcodec.h" #include "libavformat/avformat.h" #include "libswscale/swscale.h" static int decavcodecInit( hb_work_object_t *, hb_job_t * ); static int decavcodecWork( hb_work_object_t *, hb_buffer_t **, hb_buffer_t ** ); static void decavcodecClose( hb_work_object_t * ); static int decavcodecInfo( hb_work_object_t *, hb_work_info_t * ); static int decavcodecBSInfo( hb_work_object_t *, const hb_buffer_t *, hb_work_info_t * ); hb_work_object_t hb_decavcodec = { WORK_DECAVCODEC, "MPGA decoder (libavcodec)", decavcodecInit, decavcodecWork, decavcodecClose, decavcodecInfo, decavcodecBSInfo }; #define HEAP_SIZE 8 typedef struct { // there are nheap items on the heap indexed 1..nheap (i.e., top of // heap is 1). The 0th slot is unused - a marker is put there to check // for overwrite errs. int64_t h[HEAP_SIZE+1]; int nheap; } pts_heap_t; struct hb_work_private_s { hb_job_t *job; AVCodecContext *context; AVCodecParserContext *parser; hb_list_t *list; double duration; // frame duration (for video) double pts_next; // next pts we expect to generate int64_t pts; // (video) pts passing from parser to decoder int64_t chap_time; // time of next chap mark (if new_chap != 0) int new_chap; // output chapter mark pending uint32_t nframes; uint32_t ndrops; uint32_t decode_errors; int brokenByMicrosoft; // video stream may contain packed b-frames hb_buffer_t* delayq[HEAP_SIZE]; pts_heap_t pts_heap; void* buffer; struct SwsContext *sws_context; // if we have to rescale or convert color space }; static int64_t heap_pop( pts_heap_t *heap ) { int64_t result; if ( heap->nheap <= 0 ) { return -1; } // return the top of the heap then put the bottom element on top, // decrease the heap size by one & rebalence the heap. result = heap->h[1]; int64_t v = heap->h[heap->nheap--]; int parent = 1; int child = parent << 1; while ( child <= heap->nheap ) { // find the smallest of the two children of parent if (child < heap->nheap && heap->h[child] > heap->h[child+1] ) ++child; if (v <= heap->h[child]) // new item is smaller than either child so it's the new parent. break; // smallest child is smaller than new item so move it up then // check its children. int64_t hp = heap->h[child]; heap->h[parent] = hp; parent = child; child = parent << 1; } heap->h[parent] = v; return result; } static void heap_push( pts_heap_t *heap, int64_t v ) { if ( heap->nheap < HEAP_SIZE ) { ++heap->nheap; } // stick the new value on the bottom of the heap then bubble it // up to its correct spot. int child = heap->nheap; while (child > 1) { int parent = child >> 1; if (heap->h[parent] <= v) break; // move parent down int64_t hp = heap->h[parent]; heap->h[child] = hp; child = parent; } heap->h[child] = v; } /*********************************************************************** * hb_work_decavcodec_init *********************************************************************** * **********************************************************************/ static int decavcodecInit( hb_work_object_t * w, hb_job_t * job ) { AVCodec * codec; hb_work_private_t * pv = calloc( 1, sizeof( hb_work_private_t ) ); w->private_data = pv; pv->job = job; int codec_id = w->codec_param; /*XXX*/ if ( codec_id == 0 ) codec_id = CODEC_ID_MP2; codec = avcodec_find_decoder( codec_id ); pv->parser = av_parser_init( codec_id ); pv->context = avcodec_alloc_context(); avcodec_open( pv->context, codec ); return 0; } /*********************************************************************** * Close *********************************************************************** * **********************************************************************/ static void decavcodecClose( hb_work_object_t * w ) { hb_work_private_t * pv = w->private_data; if ( pv ) { if ( pv->job && pv->context && pv->context->codec ) { hb_log( "%s-decoder done: %u frames, %u decoder errors, %u drops", pv->context->codec->name, pv->nframes, pv->decode_errors, pv->ndrops ); } if ( pv->sws_context ) { sws_freeContext( pv->sws_context ); } if ( pv->parser ) { av_parser_close(pv->parser); } if ( pv->context && pv->context->codec ) { avcodec_close( pv->context ); } if ( pv->list ) { hb_list_close( &pv->list ); } if ( pv->buffer ) { free( pv->buffer ); pv->buffer = NULL; } free( pv ); w->private_data = NULL; } } /*********************************************************************** * Work *********************************************************************** * **********************************************************************/ static int decavcodecWork( hb_work_object_t * w, hb_buffer_t ** buf_in, hb_buffer_t ** buf_out ) { hb_work_private_t * pv = w->private_data; hb_buffer_t * in = *buf_in, * buf, * last = NULL; int pos, len, out_size, i, uncompressed_len; short buffer[AVCODEC_MAX_AUDIO_FRAME_SIZE]; uint64_t cur; unsigned char *parser_output_buffer; int parser_output_buffer_len; if ( (*buf_in)->size <= 0 ) { /* EOF on input stream - send it downstream & say that we're done */ *buf_out = *buf_in; *buf_in = NULL; return HB_WORK_DONE; } *buf_out = NULL; cur = ( in->start < 0 )? pv->pts_next : in->start; pos = 0; while( pos < in->size ) { len = av_parser_parse( pv->parser, pv->context, &parser_output_buffer, &parser_output_buffer_len, in->data + pos, in->size - pos, cur, cur ); out_size = 0; uncompressed_len = 0; if (parser_output_buffer_len) { out_size = sizeof(buffer); uncompressed_len = avcodec_decode_audio2( pv->context, buffer, &out_size, parser_output_buffer, parser_output_buffer_len ); } if( out_size ) { short * s16; float * fl32; buf = hb_buffer_init( 2 * out_size ); int sample_size_in_bytes = 2; // Default to 2 bytes switch (pv->context->sample_fmt) { case SAMPLE_FMT_S16: sample_size_in_bytes = 2; break; /* We should handle other formats here - but that needs additional format conversion work below */ /* For now we'll just report the error and try to carry on */ default: hb_log("decavcodecWork - Unknown Sample Format from avcodec_decode_audio (%d) !", pv->context->sample_fmt); break; } buf->start = cur; buf->stop = cur + 90000 * ( out_size / (sample_size_in_bytes * pv->context->channels) ) / pv->context->sample_rate; cur = buf->stop; s16 = buffer; fl32 = (float *) buf->data; for( i = 0; i < out_size / 2; i++ ) { fl32[i] = s16[i]; } if( last ) { last = last->next = buf; } else { *buf_out = last = buf; } } pos += len; } pv->pts_next = cur; return HB_WORK_OK; } static int decavcodecInfo( hb_work_object_t *w, hb_work_info_t *info ) { hb_work_private_t *pv = w->private_data; memset( info, 0, sizeof(*info) ); if ( pv && pv->context ) { AVCodecContext *context = pv->context; info->bitrate = context->bit_rate; info->rate = context->time_base.num; info->rate_base = context->time_base.den; info->profile = context->profile; info->level = context->level; return 1; } return 0; } static int decavcodecBSInfo( hb_work_object_t *w, const hb_buffer_t *buf, hb_work_info_t *info ) { hb_work_private_t *pv = w->private_data; memset( info, 0, sizeof(*info) ); if ( pv && pv->context ) { return decavcodecInfo( w, info ); } // XXX // We should parse the bitstream to find its parameters but for right // now we just return dummy values if there's a codec that will handle it. AVCodec *codec = avcodec_find_decoder( w->codec_param? w->codec_param : CODEC_ID_MP2 ); if ( codec ) { static char codec_name[64]; info->name = strncpy( codec_name, codec->name, sizeof(codec_name)-1 ); info->bitrate = 384000; info->rate = 48000; info->rate_base = 1; info->channel_layout = HB_INPUT_CH_LAYOUT_STEREO; return 1; } return -1; } /* ------------------------------------------------------------- * General purpose video decoder using libavcodec */ static uint8_t *copy_plane( uint8_t *dst, uint8_t* src, int dstride, int sstride, int h ) { if ( dstride == sstride ) { memcpy( dst, src, dstride * h ); return dst + dstride * h; } int lbytes = dstride <= sstride? dstride : sstride; while ( --h >= 0 ) { memcpy( dst, src, lbytes ); src += sstride; dst += dstride; } return dst; } // copy one video frame into an HB buf. If the frame isn't in our color space // or at least one of its dimensions is odd, use sws_scale to convert/rescale it. // Otherwise just copy the bits. static hb_buffer_t *copy_frame( hb_work_private_t *pv, AVFrame *frame ) { AVCodecContext *context = pv->context; int w, h; if ( ! pv->job ) { // if the dimensions are odd, drop the lsb since h264 requires that // both width and height be even. w = ( context->width >> 1 ) << 1; h = ( context->height >> 1 ) << 1; } else { w = pv->job->title->width; h = pv->job->title->height; } hb_buffer_t *buf = hb_buffer_init( w * h * 3 / 2 ); uint8_t *dst = buf->data; if ( context->pix_fmt != PIX_FMT_YUV420P || w != context->width || h != context->height ) { // have to convert to our internal color space and/or rescale AVPicture dstpic; avpicture_fill( &dstpic, dst, PIX_FMT_YUV420P, w, h ); if ( ! pv->sws_context ) { pv->sws_context = sws_getContext( context->width, context->height, context->pix_fmt, w, h, PIX_FMT_YUV420P, SWS_LANCZOS|SWS_ACCURATE_RND, NULL, NULL, NULL ); } sws_scale( pv->sws_context, frame->data, frame->linesize, 0, h, dstpic.data, dstpic.linesize ); } else { dst = copy_plane( dst, frame->data[0], w, frame->linesize[0], h ); w >>= 1; h >>= 1; dst = copy_plane( dst, frame->data[1], w, frame->linesize[1], h ); dst = copy_plane( dst, frame->data[2], w, frame->linesize[2], h ); } return buf; } static int get_frame_buf( AVCodecContext *context, AVFrame *frame ) { hb_work_private_t *pv = context->opaque; frame->pts = pv->pts; pv->pts = -1; return avcodec_default_get_buffer( context, frame ); } static void log_chapter( hb_work_private_t *pv, int chap_num, int64_t pts ) { hb_chapter_t *c = hb_list_item( pv->job->title->list_chapter, chap_num - 1 ); if ( c && c->title ) { hb_log( "%s: \"%s\" (%d) at frame %u time %lld", pv->context->codec->name, c->title, chap_num, pv->nframes, pts ); } else { hb_log( "%s: Chapter %d at frame %u time %lld", pv->context->codec->name, chap_num, pv->nframes, pts ); } } static void flushDelayQueue( hb_work_private_t *pv ) { hb_buffer_t *buf; int slot = pv->nframes & (HEAP_SIZE-1); // flush all the video packets left on our timestamp-reordering delay q while ( ( buf = pv->delayq[slot] ) != NULL ) { buf->start = heap_pop( &pv->pts_heap ); hb_list_add( pv->list, buf ); pv->delayq[slot] = NULL; slot = ( slot + 1 ) & (HEAP_SIZE-1); } } static int decodeFrame( hb_work_private_t *pv, uint8_t *data, int size ) { int got_picture; AVFrame frame; if ( avcodec_decode_video( pv->context, &frame, &got_picture, data, size ) < 0 ) { ++pv->decode_errors; } if( got_picture ) { // ffmpeg makes it hard to attach a pts to a frame. if the MPEG ES // packet had a pts we handed it to av_parser_parse (if the packet had // no pts we set it to -1 but before the parse we can't distinguish between // the start of a video frame with no pts & an intermediate packet of // some frame which never has a pts). we hope that when parse returns // the frame to us the pts we originally handed it will be in parser->pts. // we put this pts into pv->pts so that when a avcodec_decode_video // finally gets around to allocating an AVFrame to hold the decoded // frame we can stuff that pts into the frame. if all of these relays // worked at this point frame.pts should hold the frame's pts from the // original data stream or -1 if it didn't have one. in the latter case // we generate the next pts in sequence for it. double frame_dur = pv->duration; if ( frame_dur <= 0 ) { frame_dur = 90000. * (double)pv->context->time_base.num / (double)pv->context->time_base.den; pv->duration = frame_dur; } if ( frame.repeat_pict ) { frame_dur += frame.repeat_pict * frame_dur * 0.5; } // If there was no pts for this frame, assume constant frame rate // video & estimate the next frame time from the last & duration. double pts = frame.pts; if ( pts < 0 ) { pts = pv->pts_next; } pv->pts_next = pts + frame_dur; hb_buffer_t *buf; // if we're doing a scan or this content couldn't have been broken // by Microsoft we don't worry about timestamp reordering if ( ! pv->job || ! pv->brokenByMicrosoft ) { buf = copy_frame( pv, &frame ); buf->start = pts; hb_list_add( pv->list, buf ); ++pv->nframes; return got_picture; } // XXX This following probably addresses a libavcodec bug but I don't // see an easy fix so we workaround it here. // // The M$ 'packed B-frames' atrocity results in decoded frames with // the wrong timestamp. E.g., if there are 2 b-frames the timestamps // we see here will be "2 3 1 5 6 4 ..." instead of "1 2 3 4 5 6". // The frames are actually delivered in the right order but with // the wrong timestamp. To get the correct timestamp attached to // each frame we have a delay queue (longer than the max number of // b-frames) & a sorting heap for the timestamps. As each frame // comes out of the decoder the oldest frame in the queue is removed // and associated with the smallest timestamp. Then the new frame is // added to the queue & its timestamp is pushed on the heap. // This does nothing if the timestamps are correct (i.e., the video // uses a codec that Micro$oft hasn't broken yet) but the frames // get timestamped correctly even when M$ has munged them. // remove the oldest picture from the frame queue (if any) & // give it the smallest timestamp from our heap. The queue size // is a power of two so we get the slot of the oldest by masking // the frame count & this will become the slot of the newest // once we've removed & processed the oldest. int slot = pv->nframes & (HEAP_SIZE-1); if ( ( buf = pv->delayq[slot] ) != NULL ) { buf->start = heap_pop( &pv->pts_heap ); if ( pv->new_chap && buf->start >= pv->chap_time ) { buf->new_chap = pv->new_chap; pv->new_chap = 0; pv->chap_time = 0; log_chapter( pv, buf->new_chap, buf->start ); } else if ( pv->nframes == 0 ) { log_chapter( pv, pv->job->chapter_start, buf->start ); } hb_list_add( pv->list, buf ); } // add the new frame to the delayq & push its timestamp on the heap pv->delayq[slot] = copy_frame( pv, &frame ); heap_push( &pv->pts_heap, pts ); ++pv->nframes; } return got_picture; } static void decodeVideo( hb_work_private_t *pv, uint8_t *data, int size, int64_t pts, int64_t dts ) { /* * The following loop is a do..while because we need to handle both * data & the flush at the end (signaled by size=0). At the end there's * generally a frame in the parser & one or more frames in the decoder * (depending on the bframes setting). */ int pos = 0; do { uint8_t *pout; int pout_len; int len = av_parser_parse( pv->parser, pv->context, &pout, &pout_len, data + pos, size - pos, pts, dts ); pos += len; if ( pout_len > 0 ) { pv->pts = pv->parser->pts; decodeFrame( pv, pout, pout_len ); } } while ( pos < size ); /* the stuff above flushed the parser, now flush the decoder */ if ( size <= 0 ) { while ( decodeFrame( pv, NULL, 0 ) ) { } flushDelayQueue( pv ); } } static hb_buffer_t *link_buf_list( hb_work_private_t *pv ) { hb_buffer_t *head = hb_list_item( pv->list, 0 ); if ( head ) { hb_list_rem( pv->list, head ); hb_buffer_t *last = head, *buf; while ( ( buf = hb_list_item( pv->list, 0 ) ) != NULL ) { hb_list_rem( pv->list, buf ); last->next = buf; last = buf; } } return head; } static int decavcodecvInit( hb_work_object_t * w, hb_job_t * job ) { hb_work_private_t *pv = calloc( 1, sizeof( hb_work_private_t ) ); w->private_data = pv; pv->job = job; pv->list = hb_list_init(); int codec_id = w->codec_param; pv->parser = av_parser_init( codec_id ); pv->context = avcodec_alloc_context2( CODEC_TYPE_VIDEO ); /* we have to wrap ffmpeg's get_buffer to be able to set the pts (?!) */ pv->context->opaque = pv; pv->context->get_buffer = get_frame_buf; AVCodec *codec = avcodec_find_decoder( codec_id ); // we can't call the avstream funcs but the read_header func in the // AVInputFormat may set up some state in the AVContext. In particular // vc1t_read_header allocates 'extradata' to deal with header issues // related to Microsoft's bizarre engineering notions. We alloc a chunk // of space to make vc1 work then associate the codec with the context. pv->context->extradata_size = 32; pv->context->extradata = av_malloc(pv->context->extradata_size); avcodec_open( pv->context, codec ); return 0; } static int decavcodecvWork( hb_work_object_t * w, hb_buffer_t ** buf_in, hb_buffer_t ** buf_out ) { hb_work_private_t *pv = w->private_data; hb_buffer_t *in = *buf_in; int64_t pts = AV_NOPTS_VALUE; int64_t dts = pts; *buf_in = NULL; /* if we got an empty buffer signaling end-of-stream send it downstream */ if ( in->size == 0 ) { decodeVideo( pv, in->data, in->size, pts, dts ); hb_list_add( pv->list, in ); *buf_out = link_buf_list( pv ); return HB_WORK_DONE; } if( in->start >= 0 ) { pts = in->start; dts = in->renderOffset; } if ( in->new_chap ) { pv->new_chap = in->new_chap; pv->chap_time = pts >= 0? pts : pv->pts_next; } decodeVideo( pv, in->data, in->size, pts, dts ); hb_buffer_close( &in ); *buf_out = link_buf_list( pv ); return HB_WORK_OK; } static int decavcodecvInfo( hb_work_object_t *w, hb_work_info_t *info ) { hb_work_private_t *pv = w->private_data; memset( info, 0, sizeof(*info) ); if ( pv && pv->context ) { AVCodecContext *context = pv->context; info->bitrate = context->bit_rate; info->width = context->width; info->height = context->height; /* ffmpeg gives the frame rate in frames per second while HB wants * it in units of the 27MHz MPEG clock. */ info->rate = 27000000; info->rate_base = (int64_t)context->time_base.num * 27000000LL / context->time_base.den; /* Sometimes there's no pixel aspect set in the source. In that case, assume a 1:1 PAR. Otherwise, preserve the source PAR. */ info->pixel_aspect_width = context->sample_aspect_ratio.num ? context->sample_aspect_ratio.num : 1; info->pixel_aspect_height = context->sample_aspect_ratio.den ? context->sample_aspect_ratio.den : 1; /* ffmpeg returns the Pixel Aspect Ratio (PAR). Handbrake wants the * Display Aspect Ratio so we convert by scaling by the Storage * Aspect Ratio (w/h). We do the calc in floating point to get the * rounding right. */ info->aspect = (double)info->pixel_aspect_width * (double)context->width / (double)info->pixel_aspect_height / (double)context->height; info->profile = context->profile; info->level = context->level; info->name = context->codec->name; return 1; } return 0; } static int decavcodecvBSInfo( hb_work_object_t *w, const hb_buffer_t *buf, hb_work_info_t *info ) { return 0; } hb_work_object_t hb_decavcodecv = { WORK_DECAVCODECV, "Video decoder (libavcodec)", decavcodecvInit, decavcodecvWork, decavcodecClose, decavcodecvInfo, decavcodecvBSInfo }; // This is a special decoder for ffmpeg streams. The ffmpeg stream reader // includes a parser and passes information from the parser to the decoder // via a codec context kept in the AVStream of the reader's AVFormatContext. // We *have* to use that codec context to decode the stream or we'll get // garbage. ffmpeg_title_scan put a cookie that can be used to get to that // codec context in our codec_param. // this routine gets the appropriate context pointer from the ffmpeg // stream reader. it can't be called until we get the first buffer because // we can't guarantee that reader will be called before the our init // routine and if our init is called first we'll get a pointer to the // old scan stream (which has already been closed). static void init_ffmpeg_context( hb_work_object_t *w ) { hb_work_private_t *pv = w->private_data; pv->context = hb_ffmpeg_context( w->codec_param ); // during scan the decoder gets closed & reopened which will // close the codec so reopen it if it's not there if ( ! pv->context->codec ) { AVCodec *codec = avcodec_find_decoder( pv->context->codec_id ); avcodec_open( pv->context, codec ); } // set up our best guess at the frame duration. // the frame rate in the codec is usually bogus but it's sometimes // ok in the stream. AVStream *st = hb_ffmpeg_avstream( w->codec_param ); if ( st->nb_frames && st->duration ) { // compute the average frame duration from the total number // of frames & the total duration. pv->duration = ( (double)st->duration * (double)st->time_base.num ) / ( (double)st->nb_frames * (double)st->time_base.den ); } else { // XXX We don't have a frame count or duration so try to use the // far less reliable time base info in the stream. // Because the time bases are so screwed up, we only take values // in the range 8fps - 64fps. AVRational tb; if ( st->time_base.num * 64 > st->time_base.den && st->time_base.den > st->time_base.num * 8 ) { tb = st->time_base; } else if ( st->r_frame_rate.den * 64 > st->r_frame_rate.num && st->r_frame_rate.num > st->r_frame_rate.den * 8 ) { tb.num = st->r_frame_rate.den; tb.den = st->r_frame_rate.num; } else { tb.num = 1001; /*XXX*/ tb.den = 24000; /*XXX*/ } pv->duration = (double)tb.num / (double)tb.den; } pv->duration *= 90000.; // we have to wrap ffmpeg's get_buffer to be able to set the pts (?!) pv->context->opaque = pv; pv->context->get_buffer = get_frame_buf; // avi, mkv and possibly mp4 containers can contain the M$ VFW packed // b-frames abortion that messes up frame ordering and timestamps. // XXX ffmpeg knows which streams are broken but doesn't expose the // info externally. We should patch ffmpeg to add a flag to the // codec context for this but until then we mark all ffmpeg streams // as suspicious. pv->brokenByMicrosoft = 1; } static void prepare_ffmpeg_buffer( hb_buffer_t * in ) { // ffmpeg requires an extra 8 bytes of zero at the end of the buffer and // will seg fault in odd, data dependent ways if it's not there. (my guess // is this is a case of a local performance optimization creating a global // performance degradation since all the time wasted by extraneous data // copies & memory zeroing has to be huge compared to the minor reduction // in inner-loop instructions this affords - modern cpus bottleneck on // memory bandwidth not instruction bandwidth). if ( in->size + FF_INPUT_BUFFER_PADDING_SIZE > in->alloc ) { // have to realloc to add the padding hb_buffer_realloc( in, in->size + FF_INPUT_BUFFER_PADDING_SIZE ); } memset( in->data + in->size, 0, FF_INPUT_BUFFER_PADDING_SIZE ); } static int decavcodecviInit( hb_work_object_t * w, hb_job_t * job ) { hb_work_private_t *pv = calloc( 1, sizeof( hb_work_private_t ) ); w->private_data = pv; pv->job = job; pv->list = hb_list_init(); pv->pts_next = -1; pv->pts = -1; return 0; } static int decavcodecviWork( hb_work_object_t * w, hb_buffer_t ** buf_in, hb_buffer_t ** buf_out ) { hb_work_private_t *pv = w->private_data; if ( ! pv->context ) { init_ffmpeg_context( w ); } hb_buffer_t *in = *buf_in; *buf_in = NULL; /* if we got an empty buffer signaling end-of-stream send it downstream */ if ( in->size == 0 ) { /* flush any frames left in the decoder */ while ( decodeFrame( pv, NULL, 0 ) ) { } flushDelayQueue( pv ); hb_list_add( pv->list, in ); *buf_out = link_buf_list( pv ); return HB_WORK_DONE; } int64_t pts = in->start; if( pts >= 0 ) { // use the first timestamp as our 'next expected' pts if ( pv->pts_next < 0 ) { pv->pts_next = pts; } pv->pts = pts; } if ( in->new_chap ) { pv->new_chap = in->new_chap; pv->chap_time = pts >= 0? pts : pv->pts_next; } prepare_ffmpeg_buffer( in ); decodeFrame( pv, in->data, in->size ); hb_buffer_close( &in ); *buf_out = link_buf_list( pv ); return HB_WORK_OK; } static int decavcodecviInfo( hb_work_object_t *w, hb_work_info_t *info ) { if ( decavcodecvInfo( w, info ) ) { hb_work_private_t *pv = w->private_data; if ( ! pv->context ) { init_ffmpeg_context( w ); } // we have the frame duration in units of the 90KHz pts clock but // need it in units of the 27MHz MPEG clock. */ info->rate = 27000000; info->rate_base = pv->duration * 300.; return 1; } return 0; } static void decodeAudio( hb_work_private_t *pv, uint8_t *data, int size ) { AVCodecContext *context = pv->context; int pos = 0; while ( pos < size ) { int16_t *buffer = pv->buffer; if ( buffer == NULL ) { // XXX ffmpeg bug workaround // malloc a buffer for the audio decode. On an x86, ffmpeg // uses mmx/sse instructions on this buffer without checking // that it's 16 byte aligned and this will cause an abort if // the buffer is allocated on our stack. Rather than doing // complicated, machine dependent alignment here we use the // fact that malloc returns an aligned pointer on most architectures. pv->buffer = malloc( AVCODEC_MAX_AUDIO_FRAME_SIZE ); buffer = pv->buffer; } int out_size = AVCODEC_MAX_AUDIO_FRAME_SIZE; int len = avcodec_decode_audio2( context, buffer, &out_size, data + pos, size - pos ); if ( len <= 0 ) { return; } pos += len; if( out_size > 0 ) { hb_buffer_t *buf = hb_buffer_init( 2 * out_size ); // convert from bytes to total samples out_size >>= 1; double pts = pv->pts_next; buf->start = pts; pts += out_size * pv->duration; buf->stop = pts; pv->pts_next = pts; float *fl32 = (float *)buf->data; int i; for( i = 0; i < out_size; ++i ) { fl32[i] = buffer[i]; } hb_list_add( pv->list, buf ); } } } static int decavcodecaiWork( hb_work_object_t *w, hb_buffer_t **buf_in, hb_buffer_t **buf_out ) { if ( (*buf_in)->size <= 0 ) { /* EOF on input stream - send it downstream & say that we're done */ *buf_out = *buf_in; *buf_in = NULL; return HB_WORK_DONE; } hb_work_private_t *pv = w->private_data; if ( ! pv->context ) { init_ffmpeg_context( w ); // duration is a scaling factor to go from #bytes in the decoded // frame to frame time (in 90KHz mpeg ticks). 'channels' converts // total samples to per-channel samples. 'sample_rate' converts // per-channel samples to seconds per sample and the 90000 // is mpeg ticks per second. pv->duration = 90000. / (double)( pv->context->sample_rate * pv->context->channels ); } hb_buffer_t *in = *buf_in; // if the packet has a timestamp use it if we don't have a timestamp yet // or if there's been a timing discontinuity of more than 100ms. if ( in->start >= 0 && ( pv->pts_next < 0 || ( in->start - pv->pts_next ) > 90*100 ) ) { pv->pts_next = in->start; } prepare_ffmpeg_buffer( in ); decodeAudio( pv, in->data, in->size ); *buf_out = link_buf_list( pv ); return HB_WORK_OK; } hb_work_object_t hb_decavcodecvi = { WORK_DECAVCODECVI, "Video decoder (ffmpeg streams)", decavcodecviInit, decavcodecviWork, decavcodecClose, decavcodecviInfo, decavcodecvBSInfo }; hb_work_object_t hb_decavcodecai = { WORK_DECAVCODECAI, "Audio decoder (ffmpeg streams)", decavcodecviInit, decavcodecaiWork, decavcodecClose, decavcodecInfo, decavcodecBSInfo };