/* muxcommon.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" #define MIN_BUFFERING (1024*1024*10) #define MAX_BUFFERING (1024*1024*50) struct hb_mux_object_s { HB_MUX_COMMON; }; typedef struct { hb_buffer_t **fifo; uint32_t in; // number of bufs put into fifo uint32_t out; // number of bufs taken out of fifo uint32_t flen; // fifo length (must be power of two) } mux_fifo_t; typedef struct { hb_mux_data_t * mux_data; uint64_t frames; uint64_t bytes; mux_fifo_t mf; int buffered_size; } hb_track_t; typedef struct { hb_lock_t * mutex; int ref; int done; hb_mux_object_t * m; double pts; // end time of next muxing chunk double interleave; // size in 90KHz ticks of media chunks we mux uint32_t ntracks; // total number of tracks we're muxing uint32_t eof; // bitmask of track with eof uint32_t rdy; // bitmask of tracks ready to output uint32_t allEof; // valid bits in eof (all tracks) uint32_t allRdy; // valid bits in rdy (audio & video tracks) hb_track_t * track[32]; // array of tracks to mux ('ntrack' elements) // NOTE- this array could be dynamically // allocated but the eof & rdy logic has to // be changed to handle more than 32 tracks // anyway so we keep it simple and fast. int buffered_size; } hb_mux_t; struct hb_work_private_s { hb_job_t * job; int track; hb_mux_t * mux; }; // The muxer handles two different kinds of media: Video and audio tracks // are continuous: once they start they generate continuous, consecutive // sequence of bufs until they end. The muxer will time align all continuous // media tracks so that their data will be well interleaved in the output file. // (Smooth, low latency playback with minimal player buffering requires that // data that's going to be presented close together in time also be close // together in the output file). Since HB's audio and video encoders run at // different speeds, the time-aligning involves buffering *all* the continuous // media tracks until a frame with a timestamp beyond the current alignment // point arrives on the slowest fifo (usually the video encoder). // // The other kind of media, subtitles, close-captions, vobsubs and // similar tracks, are intermittent. They generate frames sporadically or on // human time scales (seconds) rather than near the video frame rate (milliseconds). // If intermittent sources were treated like continuous sources huge sections of // audio and video would get buffered waiting for the next subtitle to show up. // To keep this from happening the muxer doesn't wait for intermittent tracks // (essentially it assumes that they will always go through the HB processing // pipeline faster than the associated video). They are still time aligned and // interleaved at the appropriate point in the output file. // This routine adds another track for the muxer to process. The media input // stream will be read from HandBrake fifo 'fifo'. Buffers read from that // stream will be time-aligned with all the other media streams then passed // to the container-specific 'mux' routine with argument 'mux_data' (see // routine OutputTrackChunk). 'is_continuous' must be 1 for an audio or video // track and 0 otherwise (see above). static void add_mux_track( hb_mux_t *mux, hb_mux_data_t *mux_data, int is_continuous ) { int max_tracks = sizeof(mux->track) / sizeof(*(mux->track)); if ( mux->ntracks >= max_tracks ) { hb_error( "add_mux_track: too many tracks (>%d)", max_tracks ); return; } hb_track_t *track = calloc( sizeof( hb_track_t ), 1 ); track->mux_data = mux_data; track->mf.flen = 8; track->mf.fifo = calloc( sizeof(track->mf.fifo[0]), track->mf.flen ); int t = mux->ntracks++; mux->track[t] = track; mux->allEof |= 1 << t; mux->allRdy |= is_continuous << t; } static int mf_full( hb_track_t * track ) { if ( track->buffered_size > MAX_BUFFERING ) return 1; return 0; } static void mf_push( hb_mux_t * mux, int tk, hb_buffer_t *buf ) { hb_track_t * track = mux->track[tk]; uint32_t mask = track->mf.flen - 1; uint32_t in = track->mf.in; hb_buffer_reduce( buf, buf->size ); if ( track->buffered_size > MAX_BUFFERING ) { mux->rdy = mux->allRdy; } if ( ( ( in + 1 ) & mask ) == ( track->mf.out & mask ) ) { // fifo is full - expand it to double the current size. // This is a bit tricky because when we change the size // it changes the modulus (mask) used to convert the in // and out counters to fifo indices. Since existing items // will be referenced at a new location after the expand // we can't just realloc the fifo. If there were // hundreds of fifo entries it would be worth it to have code // for each of the four possible before/after configurations // but these fifos are small so we just allocate a new chunk // of memory then do element by element copies using the old & // new masks then free the old fifo's memory.. track->mf.flen *= 2; uint32_t nmask = track->mf.flen - 1; hb_buffer_t **nfifo = malloc( track->mf.flen * sizeof(*nfifo) ); int indx = track->mf.out; while ( indx != track->mf.in ) { nfifo[indx & nmask] = track->mf.fifo[indx & mask]; ++indx; } free( track->mf.fifo ); track->mf.fifo = nfifo; mask = nmask; } track->mf.fifo[in & mask] = buf; track->mf.in = in + 1; track->buffered_size += buf->size; mux->buffered_size += buf->size; } static hb_buffer_t *mf_pull( hb_mux_t * mux, int tk ) { hb_track_t *track =mux->track[tk]; hb_buffer_t *b = NULL; if ( track->mf.out != track->mf.in ) { // the fifo isn't empty b = track->mf.fifo[track->mf.out & (track->mf.flen - 1)]; ++track->mf.out; track->buffered_size -= b->size; mux->buffered_size -= b->size; } return b; } static hb_buffer_t *mf_peek( hb_track_t *track ) { return track->mf.out == track->mf.in ? NULL : track->mf.fifo[track->mf.out & (track->mf.flen - 1)]; } static void MoveToInternalFifos( int tk, hb_mux_t *mux, hb_buffer_t * buf ) { // move all the buffers on the track's fifo to our internal // fifo so that (a) we don't deadlock in the reader and // (b) we can control how data from multiple tracks is // interleaved in the output file. mf_push( mux, tk, buf ); if ( buf->s.stop >= mux->pts ) { // buffer is past our next interleave point so // note that this track is ready to be output. mux->rdy |= ( 1 << tk ); } } static void OutputTrackChunk( hb_mux_t *mux, int tk, hb_mux_object_t *m ) { hb_track_t *track = mux->track[tk]; hb_buffer_t *buf; while ( ( buf = mf_peek( track ) ) != NULL && buf->s.start < mux->pts ) { buf = mf_pull( mux, tk ); track->frames += 1; track->bytes += buf->size; m->mux( m, track->mux_data, buf ); } } static int muxWork( hb_work_object_t * w, hb_buffer_t ** buf_in, hb_buffer_t ** buf_out ) { hb_work_private_t * pv = w->private_data; hb_job_t * job = pv->job; hb_mux_t * mux = pv->mux; hb_track_t * track; int i; hb_buffer_t * buf = *buf_in; hb_lock( mux->mutex ); if ( mux->done ) { hb_unlock( mux->mutex ); return HB_WORK_DONE; } if ( buf->size <= 0 ) { // EOF - mark this track as done hb_buffer_close( &buf ); mux->eof |= ( 1 << pv->track ); mux->rdy |= ( 1 << pv->track ); } else if ( ( job->pass != 0 && job->pass != 2 ) || ( mux->eof & (1 << pv->track) ) ) { hb_buffer_close( &buf ); } else { MoveToInternalFifos( pv->track, mux, buf ); } *buf_in = NULL; if ( ( mux->rdy & mux->allRdy ) != mux->allRdy ) { hb_unlock( mux->mutex ); return HB_WORK_OK; } int more = mux->rdy; // all tracks have at least 'interleave' ticks of data. Output // all that we can in 'interleave' size chunks. while ( (( mux->rdy & mux->allRdy ) == mux->allRdy && more && mux->buffered_size > MIN_BUFFERING ) || ( mux->eof == mux->allEof ) ) { more = 0; for ( i = 0; i < mux->ntracks; ++i ) { track = mux->track[i]; OutputTrackChunk( mux, i, mux->m ); if ( mf_full( track ) ) { // If the track's fifo is still full, advance // the currint interleave point and try again. mux->rdy = mux->allRdy; break; } // if the track is at eof or still has data that's past // our next interleave point then leave it marked as rdy. // Otherwise clear rdy. if ( ( mux->eof & (1 << i) ) == 0 && ( track->mf.out == track->mf.in || track->mf.fifo[(track->mf.in-1) & (track->mf.flen-1)]->s.stop < mux->pts + mux->interleave ) ) { mux->rdy &=~ ( 1 << i ); } if ( track->mf.out != track->mf.in ) { more |= ( 1 << i ); } } // if all the tracks are at eof we're just purging their // remaining data -- keep going until all internal fifos are empty. if ( mux->eof == mux->allEof ) { for ( i = 0; i < mux->ntracks; ++i ) { if ( mux->track[i]->mf.out != mux->track[i]->mf.in ) { break; } } if ( i >= mux->ntracks ) { mux->done = 1; hb_unlock( mux->mutex ); return HB_WORK_DONE; } } mux->pts += mux->interleave; } hb_unlock( mux->mutex ); return HB_WORK_OK; } void muxClose( hb_work_object_t * w ) { hb_work_private_t * pv = w->private_data; hb_mux_t * mux = pv->mux; hb_job_t * job = pv->job; hb_track_t * track; int i; hb_lock( mux->mutex ); if ( --mux->ref == 0 ) { // Update state before closing muxer. Closing the muxer // may initiate optimization which can take a while and // we want the muxing state to be visible while this is // happening. if( job->pass == 0 || job->pass == 2 ) { /* Update the UI */ hb_state_t state; state.state = HB_STATE_MUXING; state.param.muxing.progress = 0; hb_set_state( job->h, &state ); } if( mux->m ) { mux->m->end( mux->m ); free( mux->m ); } // we're all done muxing -- print final stats and cleanup. if( job->pass == 0 || job->pass == 2 ) { struct stat sb; uint64_t bytes_total, frames_total; if( !stat( job->file, &sb ) ) { hb_deep_log( 2, "mux: file size, %"PRId64" bytes", (uint64_t) sb.st_size ); bytes_total = 0; frames_total = 0; for( i = 0; i < mux->ntracks; ++i ) { track = mux->track[i]; hb_log( "mux: track %d, %"PRId64" frames, %"PRId64" bytes, %.2f kbps, fifo %d", i, track->frames, track->bytes, 90000.0 * track->bytes / mux->pts / 125, track->mf.flen ); if( !i && job->vquality < 0 ) { /* Video */ hb_deep_log( 2, "mux: video bitrate error, %+"PRId64" bytes", (int64_t)(track->bytes - mux->pts * job->vbitrate * 125 / 90000) ); } bytes_total += track->bytes; frames_total += track->frames; } if( bytes_total && frames_total ) { hb_deep_log( 2, "mux: overhead, %.2f bytes per frame", (float) ( sb.st_size - bytes_total ) / frames_total ); } } } for( i = 0; i < mux->ntracks; ++i ) { hb_buffer_t * b; track = mux->track[i]; while ( (b = mf_pull( mux, i )) != NULL ) { hb_buffer_close( &b ); } if( track->mux_data ) { free( track->mux_data ); free( track->mf.fifo ); } free( track ); } hb_unlock( mux->mutex ); hb_lock_close( &mux->mutex ); free( mux ); } else { hb_unlock( mux->mutex ); } free( pv ); w->private_data = NULL; } static void mux_loop( void * _w ) { hb_work_object_t * w = _w; hb_work_private_t * pv = w->private_data; hb_job_t * job = pv->job; hb_buffer_t * buf_in; while ( !*job->die && w->status != HB_WORK_DONE ) { buf_in = hb_fifo_get_wait( w->fifo_in ); if ( pv->mux->done ) break; if ( buf_in == NULL ) continue; if ( *job->die ) { if( buf_in ) { hb_buffer_close( &buf_in ); } break; } w->status = w->work( w, &buf_in, NULL ); if( buf_in ) { hb_buffer_close( &buf_in ); } } } hb_work_object_t * hb_muxer_init( hb_job_t * job ) { hb_title_t * title = job->title; int i; hb_mux_t * mux = calloc( sizeof( hb_mux_t ), 1 ); hb_work_object_t * w; hb_work_object_t * muxer; mux->mutex = hb_lock_init(); // set up to interleave track data in blocks of 1 video frame time. // (the best case for buffering and playout latency). The container- // specific muxers can reblock this into bigger chunks if necessary. mux->interleave = 90000. * (double)job->vrate_base / (double)job->vrate; mux->pts = mux->interleave; /* Get a real muxer */ if( job->pass == 0 || job->pass == 2) { switch( job->mux ) { case HB_MUX_MP4: mux->m = hb_mux_mp4_init( job ); break; case HB_MUX_MKV: mux->m = hb_mux_mkv_init( job ); break; default: hb_error( "No muxer selected, exiting" ); *job->die = 1; return NULL; } /* Create file, write headers */ if( mux->m ) { mux->m->init( mux->m ); } } /* Initialize the work objects that will receive fifo data */ muxer = hb_get_work( WORK_MUX ); muxer->private_data = calloc( sizeof( hb_work_private_t ), 1 ); muxer->private_data->job = job; muxer->private_data->mux = mux; mux->ref++; muxer->private_data->track = mux->ntracks; muxer->fifo_in = job->fifo_mpeg4; add_mux_track( mux, job->mux_data, 1 ); muxer->done = &muxer->private_data->mux->done; for( i = 0; i < hb_list_count( title->list_audio ); i++ ) { hb_audio_t *audio = hb_list_item( title->list_audio, i ); w = hb_get_work( WORK_MUX ); w->private_data = calloc( sizeof( hb_work_private_t ), 1 ); w->private_data->job = job; w->private_data->mux = mux; mux->ref++; w->private_data->track = mux->ntracks; w->fifo_in = audio->priv.fifo_out; add_mux_track( mux, audio->priv.mux_data, 1 ); w->done = &job->done; hb_list_add( job->list_work, w ); w->thread = hb_thread_init( w->name, mux_loop, w, HB_NORMAL_PRIORITY ); } for( i = 0; i < hb_list_count( title->list_subtitle ); i++ ) { hb_subtitle_t *subtitle = hb_list_item( title->list_subtitle, i ); if (subtitle->config.dest != PASSTHRUSUB) continue; w = hb_get_work( WORK_MUX ); w->private_data = calloc( sizeof( hb_work_private_t ), 1 ); w->private_data->job = job; w->private_data->mux = mux; mux->ref++; w->private_data->track = mux->ntracks; w->fifo_in = subtitle->fifo_out; add_mux_track( mux, subtitle->mux_data, 0 ); w->done = &job->done; hb_list_add( job->list_work, w ); w->thread = hb_thread_init( w->name, mux_loop, w, HB_NORMAL_PRIORITY ); } return muxer; } // muxInit does nothing because the muxer has a special initializer // that takes care of initializing all muxer work objects static int muxInit( hb_work_object_t * w, hb_job_t * job ) { return 0; } hb_work_object_t hb_muxer = { WORK_MUX, "Muxer", muxInit, muxWork, muxClose };