/* reader.c Copyright (c) 2003-2012 HandBrake Team This file is part of the HandBrake source code Homepage: . It may be used under the terms of the GNU General Public License v2. For full terms see the file COPYING file or visit http://www.gnu.org/licenses/gpl-2.0.html */ #include "hb.h" static int hb_reader_init( hb_work_object_t * w, hb_job_t * job ); static void hb_reader_close( hb_work_object_t * w ); hb_work_object_t hb_reader = { WORK_READER, "Reader", hb_reader_init, NULL, hb_reader_close, NULL, NULL }; typedef struct { int startup; double average; // average time between packets int64_t last; // last timestamp seen on this stream int id; // stream id int is_audio; // != 0 if this is an audio stream int valid; // Stream timing is not valid until next scr. } stream_timing_t; struct hb_work_private_s { hb_job_t * job; hb_title_t * title; volatile int * die; hb_bd_t * bd; hb_dvd_t * dvd; hb_stream_t * stream; stream_timing_t *stream_timing; int64_t scr_offset; hb_psdemux_t demux; int scr_changes; uint32_t sequence; uint8_t st_slots; // size (in slots) of stream_timing array uint8_t saw_video; // != 0 if we've seen video uint8_t saw_audio; // != 0 if we've seen audio int start_found; // found pts_to_start point int64_t pts_to_start; uint64_t st_first; }; /*********************************************************************** * Local prototypes **********************************************************************/ static hb_fifo_t ** GetFifoForId( hb_job_t * job, int id ); static void UpdateState( hb_work_private_t * r, int64_t start); /*********************************************************************** * hb_reader_init *********************************************************************** * **********************************************************************/ static int hb_reader_open( hb_work_private_t * r ) { if ( r->title->type == HB_BD_TYPE ) { if ( !( r->bd = hb_bd_init( r->title->path ) ) ) return 1; } else if ( r->title->type == HB_DVD_TYPE ) { if ( !( r->dvd = hb_dvd_init( r->title->path ) ) ) return 1; } else if ( r->title->type == HB_STREAM_TYPE || r->title->type == HB_FF_STREAM_TYPE ) { if ( !( r->stream = hb_stream_open( r->title->path, r->title, 0 ) ) ) return 1; } else { // Unknown type, should never happen return 1; } return 0; } static int hb_reader_init( hb_work_object_t * w, hb_job_t * job ) { hb_work_private_t * r; r = calloc( sizeof( hb_work_private_t ), 1 ); w->private_data = r; r->job = job; r->title = job->title; r->die = job->die; r->sequence = 0; r->st_slots = 4; r->stream_timing = calloc( sizeof(stream_timing_t), r->st_slots ); r->stream_timing[0].id = r->title->video_id; r->stream_timing[0].average = 90000. * (double)job->vrate_base / (double)job->vrate; r->stream_timing[0].last = -r->stream_timing[0].average; r->stream_timing[0].valid = 1; r->stream_timing[0].startup = 10; r->stream_timing[1].id = -1; r->demux.last_scr = -1; if ( !job->pts_to_start ) r->start_found = 1; else { // The frame at the actual start time may not be an i-frame // so can't be decoded without starting a little early. // sync.c will drop early frames. r->pts_to_start = MAX(0, job->pts_to_start - 180000); } // The stream needs to be open before starting the reader thead // to prevent a race with decoders that may share information // with the reader. Specifically avcodec needs this. if ( hb_reader_open( r ) ) { free( r->stream_timing ); free( r ); return 1; } return 0; } static void hb_reader_close( hb_work_object_t * w ) { hb_work_private_t * r = w->private_data; if (r->bd) { hb_bd_stop( r->bd ); hb_bd_close( &r->bd ); } else if (r->dvd) { hb_dvd_stop( r->dvd ); hb_dvd_close( &r->dvd ); } else if (r->stream) { hb_stream_close(&r->stream); } if ( r->stream_timing ) { free( r->stream_timing ); } free( r ); } static void push_buf( const hb_work_private_t *r, hb_fifo_t *fifo, hb_buffer_t *buf ) { while ( !*r->die && !r->job->done ) { if ( hb_fifo_full_wait( fifo ) ) { hb_fifo_push( fifo, buf ); buf = NULL; break; } } if ( buf ) { hb_buffer_close( &buf ); } } static int is_audio( hb_work_private_t *r, int id ) { int i; hb_audio_t *audio; for( i = 0; ( audio = hb_list_item( r->title->list_audio, i ) ); ++i ) { if ( audio->id == id ) { return 1; } } return 0; } // The MPEG STD (Standard Target Decoder) essentially requires that we keep // per-stream timing so that when there's a timing discontinuity we can // seemlessly join packets on either side of the discontinuity. This join // requires that we know the timestamp of the previous packet and the // average inter-packet time (since we position the new packet at the end // of the previous packet). The next four routines keep track of this // per-stream timing. // find or create the per-stream timing state for 'buf' static stream_timing_t *id_to_st( hb_work_private_t *r, const hb_buffer_t *buf, int valid ) { stream_timing_t *st = r->stream_timing; while ( st->id != buf->s.id && st->id != -1) { ++st; } // if we haven't seen this stream add it. if ( st->id == -1 ) { // we keep the steam timing info in an array with some power-of-two // number of slots. If we don't have two slots left (one for our new // entry plus one for the "-1" eol) we need to expand the array. int slot = st - r->stream_timing; if ( slot + 1 >= r->st_slots ) { r->st_slots *= 2; r->stream_timing = realloc( r->stream_timing, r->st_slots * sizeof(*r->stream_timing) ); st = r->stream_timing + slot; } st->id = buf->s.id; st->average = 30.*90.; st->startup = 10; st->last = -st->average; if ( ( st->is_audio = is_audio( r, buf->s.id ) ) != 0 ) { r->saw_audio = 1; } st[1].id = -1; st->valid = valid; } return st; } // update the average inter-packet time of the stream associated with 'buf' // using a recursive low-pass filter with a 16 packet time constant. static void update_ipt( hb_work_private_t *r, const hb_buffer_t *buf ) { stream_timing_t *st = id_to_st( r, buf, 1 ); if( buf->s.renderOffset < 0 ) { st->last += st->average; return; } double dt = buf->s.renderOffset - st->last; // Protect against spurious bad timestamps if ( dt > -5 * 90000LL && dt < 5 * 90000LL ) { if( st->startup ) { st->average += ( dt - st->average ) * (1./2.); st->startup--; } else { st->average += ( dt - st->average ) * (1./32.); } st->last = buf->s.renderOffset; } st->valid = 1; } // use the per-stream state associated with 'buf' to compute a new scr_offset // such that 'buf' will follow the previous packet of this stream separated // by the average packet time of the stream. static void new_scr_offset( hb_work_private_t *r, hb_buffer_t *buf ) { stream_timing_t *st = id_to_st( r, buf, 1 ); int64_t last; if ( !st->valid ) { // !valid means we've not received any previous data // for this stream. There is no 'last' packet time. // So approximate it with video's last time. last = r->stream_timing[0].last; st->valid = 1; } else { last = st->last; } int64_t nxt = last + st->average; r->scr_offset = buf->s.renderOffset - nxt; // This log is handy when you need to debug timing problems... //hb_log("id %x last %ld avg %g nxt %ld renderOffset %ld scr_offset %ld", // buf->s.id, last, st->average, nxt, buf->s.renderOffset, r->scr_offset); r->scr_changes = r->demux.scr_changes; } /*********************************************************************** * ReaderFunc *********************************************************************** * **********************************************************************/ void ReadLoop( void * _w ) { hb_work_object_t * w = _w; hb_work_private_t * r = w->private_data; hb_fifo_t ** fifos; hb_buffer_t * buf; hb_list_t * list; int n; int chapter = -1; int chapter_end = r->job->chapter_end; if (r->bd) { if( !hb_bd_start( r->bd, r->title ) ) { hb_bd_close( &r->bd ); return; } if ( r->job->start_at_preview ) { // XXX code from DecodePreviews - should go into its own routine hb_bd_seek( r->bd, (float)r->job->start_at_preview / ( r->job->seek_points ? ( r->job->seek_points + 1.0 ) : 11.0 ) ); } else if ( r->job->pts_to_start ) { // Note, bd seeks always put us to an i-frame. no need // to start decoding early using r->pts_to_start hb_bd_seek_pts( r->bd, r->job->pts_to_start ); r->job->pts_to_start = 0; r->start_found = 1; } else { hb_bd_seek_chapter( r->bd, r->job->chapter_start ); } if (r->job->angle > 1) { hb_bd_set_angle( r->bd, r->job->angle - 1 ); } } else if (r->dvd) { /* * XXX this code is a temporary hack that should go away if/when * chapter merging goes away in libhb/dvd.c * map the start and end chapter numbers to on-media chapter * numbers since chapter merging could cause the handbrake numbers * to diverge from the media numbers and, if our chapter_end is after * a media chapter that got merged, we'll stop ripping too early. */ int start = r->job->chapter_start; hb_chapter_t *chap = hb_list_item( r->title->list_chapter, chapter_end - 1 ); chapter_end = chap->index; if (start > 1) { chap = hb_list_item( r->title->list_chapter, start - 1 ); start = chap->index; } /* end chapter mapping XXX */ if( !hb_dvd_start( r->dvd, r->title, start ) ) { hb_dvd_close( &r->dvd ); return; } if (r->job->angle) { hb_dvd_set_angle( r->dvd, r->job->angle ); } if ( r->job->start_at_preview ) { // XXX code from DecodePreviews - should go into its own routine hb_dvd_seek( r->dvd, (float)r->job->start_at_preview / ( r->job->seek_points ? ( r->job->seek_points + 1.0 ) : 11.0 ) ); } } else if ( r->stream && r->job->start_at_preview ) { // XXX code from DecodePreviews - should go into its own routine hb_stream_seek( r->stream, (float)( r->job->start_at_preview - 1 ) / ( r->job->seek_points ? ( r->job->seek_points + 1.0 ) : 11.0 ) ); } else if ( r->stream && r->job->pts_to_start ) { int64_t pts_to_start = r->job->pts_to_start; // Find out what the first timestamp of the stream is // and then seek to the appropriate offset from it if ( ( buf = hb_stream_read( r->stream ) ) ) { if ( buf->s.start > 0 ) { pts_to_start += buf->s.start; } } if ( hb_stream_seek_ts( r->stream, pts_to_start ) >= 0 ) { // Seek takes us to the nearest I-frame before the timestamp // that we want. So we will retrieve the start time of the // first packet we get, subtract that from pts_to_start, and // inspect the reset of the frames in sync. r->start_found = 2; r->job->pts_to_start = pts_to_start; } } else if( r->stream ) { /* * Standard stream, seek to the starting chapter, if set, and track the * end chapter so that we end at the right time. */ int start = r->job->chapter_start; hb_chapter_t *chap = hb_list_item( r->title->list_chapter, chapter_end - 1 ); chapter_end = chap->index; if (start > 1) { chap = hb_list_item( r->title->list_chapter, start - 1 ); start = chap->index; } /* * Seek to the start chapter. */ hb_stream_seek_chapter( r->stream, start ); } list = hb_list_init(); while( !*r->die && !r->job->done ) { if (r->bd) chapter = hb_bd_chapter( r->bd ); else if (r->dvd) chapter = hb_dvd_chapter( r->dvd ); else if (r->stream) chapter = hb_stream_chapter( r->stream ); if( chapter < 0 ) { hb_log( "reader: end of the title reached" ); break; } if( chapter > chapter_end ) { hb_log( "reader: end of chapter %d (media %d) reached at media chapter %d", r->job->chapter_end, chapter_end, chapter ); break; } if (r->bd) { if( (buf = hb_bd_read( r->bd )) == NULL ) { break; } } else if (r->dvd) { if( (buf = hb_dvd_read( r->dvd )) == NULL ) { break; } } else if (r->stream) { if ( (buf = hb_stream_read( r->stream )) == NULL ) { break; } if ( r->start_found == 2 ) { // We will inspect the timestamps of each frame in sync // to skip from this seek point to the timestamp we // want to start at. if ( buf->s.start > 0 && buf->s.start < r->job->pts_to_start ) { r->job->pts_to_start -= buf->s.start; } else if ( buf->s.start >= r->job->pts_to_start ) { r->job->pts_to_start = 0; r->start_found = 1; } } } if( r->job->indepth_scan ) { /* * Need to update the progress during a subtitle scan */ hb_state_t state; #define p state.param.working state.state = HB_STATE_WORKING; p.progress = (double)chapter / (double)r->job->chapter_end; if( p.progress > 1.0 ) { p.progress = 1.0; } p.rate_avg = 0.0; p.hours = -1; p.minutes = -1; p.seconds = -1; hb_set_state( r->job->h, &state ); } (hb_demux[r->title->demuxer])( buf, list, &r->demux ); while( ( buf = hb_list_item( list, 0 ) ) ) { hb_list_rem( list, buf ); fifos = GetFifoForId( r->job, buf->s.id ); if ( fifos && ! r->saw_video && !r->job->indepth_scan ) { // The first data packet with a PTS from an audio or video stream // that we're decoding defines 'time zero'. Discard packets until // we get one. if ( buf->s.start != -1 && buf->s.renderOffset != -1 && ( buf->s.id == r->title->video_id || is_audio( r, buf->s.id ) ) ) { // force a new scr offset computation r->scr_changes = r->demux.scr_changes - 1; // create a stream state if we don't have one so the // offset will get computed correctly. id_to_st( r, buf, 1 ); r->saw_video = 1; hb_log( "reader: first SCR %"PRId64" id 0x%x DTS %"PRId64, r->demux.last_scr, buf->s.id, buf->s.renderOffset ); } else { fifos = NULL; } } if( fifos ) { if ( buf->s.renderOffset != -1 ) { if ( r->scr_changes != r->demux.scr_changes ) { // This is the first audio or video packet after an SCR // change. Compute a new scr offset that would make this // packet follow the last of this stream with the // correct average spacing. stream_timing_t *st = id_to_st( r, buf, 0 ); // if this is the video stream and we don't have // audio yet or this is an audio stream // generate a new scr if ( st->is_audio || ( st == r->stream_timing && !r->saw_audio ) ) { new_scr_offset( r, buf ); } else { // defer the scr change until we get some // audio since audio has a timestamp per // frame but video & subtitles don't. Clear // the timestamps so the decoder will generate // them from the frame durations. buf->s.start = -1; buf->s.renderOffset = -1; } } } if ( buf->s.start != -1 ) { int64_t start = buf->s.start - r->scr_offset; if ( !r->start_found ) UpdateState( r, start ); if ( !r->start_found && start >= r->pts_to_start ) { // pts_to_start point found r->start_found = 1; } // This log is handy when you need to debug timing problems //hb_log("id %x scr_offset %ld start %ld --> %ld", // buf->s.id, r->scr_offset, buf->s.start, // buf->s.start - r->scr_offset); buf->s.start -= r->scr_offset; } if ( buf->s.renderOffset != -1 ) { // This packet is referenced to the same SCR as the last. // Adjust timestamp to remove the System Clock Reference // offset then update the average inter-packet time // for this stream. buf->s.renderOffset -= r->scr_offset; update_ipt( r, buf ); } else { update_ipt( r, buf ); } if ( !r->start_found ) { hb_buffer_close( &buf ); continue; } buf->sequence = r->sequence++; /* if there are mutiple output fifos, send a copy of the * buffer down all but the first (we have to not ship the * original buffer or we'll race with the thread that's * consuming the buffer & inject garbage into the data stream). */ for( n = 1; fifos[n] != NULL; n++) { hb_buffer_t *buf_copy = hb_buffer_init( buf->size ); buf_copy->s = buf->s; memcpy( buf_copy->data, buf->data, buf->size ); push_buf( r, fifos[n], buf_copy ); } push_buf( r, fifos[0], buf ); } else { hb_buffer_close( &buf ); } } } // send empty buffers downstream to video & audio decoders to signal we're done. if( !*r->die && !r->job->done ) { push_buf( r, r->job->fifo_mpeg2, hb_buffer_init(0) ); hb_audio_t *audio; for( n = 0; (audio = hb_list_item( r->job->title->list_audio, n)); ++n ) { if ( audio->priv.fifo_in ) push_buf( r, audio->priv.fifo_in, hb_buffer_init(0) ); } hb_subtitle_t *subtitle; for( n = 0; (subtitle = hb_list_item( r->job->title->list_subtitle, n)); ++n ) { if ( subtitle->fifo_in && subtitle->source == VOBSUB) push_buf( r, subtitle->fifo_in, hb_buffer_init(0) ); } } hb_list_empty( &list ); hb_log( "reader: done. %d scr changes", r->demux.scr_changes ); if ( r->demux.dts_drops ) { hb_log( "reader: %d drops because DTS out of range", r->demux.dts_drops ); } } static void UpdateState( hb_work_private_t * r, int64_t start) { hb_state_t state; uint64_t now; double avg; now = hb_get_date(); if( !r->st_first ) { r->st_first = now; } #define p state.param.working state.state = HB_STATE_SEARCHING; p.progress = (float) start / (float) r->job->pts_to_start; if( p.progress > 1.0 ) { p.progress = 1.0; } if (now > r->st_first) { int eta; avg = 1000.0 * (double)start / (now - r->st_first); eta = ( r->job->pts_to_start - start ) / avg; p.hours = eta / 3600; p.minutes = ( eta % 3600 ) / 60; p.seconds = eta % 60; } else { p.rate_avg = 0.0; p.hours = -1; p.minutes = -1; p.seconds = -1; } #undef p hb_set_state( r->job->h, &state ); } /*********************************************************************** * GetFifoForId *********************************************************************** * **********************************************************************/ static hb_fifo_t ** GetFifoForId( hb_job_t * job, int id ) { hb_title_t * title = job->title; hb_audio_t * audio; hb_subtitle_t * subtitle; int i, n, count; static hb_fifo_t * fifos[100]; memset(fifos, 0, sizeof(fifos)); if( id == title->video_id ) { if( job->indepth_scan ) { /* * Ditch the video here during the indepth scan until * we can improve the MPEG2 decode performance. */ return NULL; } else { fifos[0] = job->fifo_mpeg2; return fifos; } } count = hb_list_count( title->list_subtitle ); count = count > 99 ? 99 : count; for( i = n = 0; i < count; i++ ) { subtitle = hb_list_item( title->list_subtitle, i ); if (id == subtitle->id) { /* pass the subtitles to be processed */ fifos[n++] = subtitle->fifo_in; } } if ( n != 0 ) { return fifos; } if( !job->indepth_scan ) { for( i = n = 0; i < hb_list_count( title->list_audio ); i++ ) { audio = hb_list_item( title->list_audio, i ); if( id == audio->id ) { fifos[n++] = audio->priv.fifo_in; } } if( n != 0 ) { return fifos; } } return NULL; }