/* decavcodec.c Copyright (c) 2003-2020 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 */ /* This module is Handbrake's interface to the ffmpeg decoder library (libavcodec & small parts of libavformat). It contains four Handbrake "work objects": decavcodeca 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. 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 These decoders handle 2 kinds of input. Streams that are demuxed by HandBrake and streams that are demuxed by libavformat. In the case of streams that are demuxed by HandBrake, there is an extra parse step required that happens in decodeVideo and decavcodecaWork. In the case of streams that are demuxed by libavformat, there is context information that we need from the libavformat. This information is propagated from hb_stream_open to these decoders through title->opaque_priv. A consequence of the above is that the streams that are demuxed by HandBrake *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 "handbrake/handbrake.h" #include "handbrake/hbffmpeg.h" #include "handbrake/hbavfilter.h" #include "libavfilter/avfilter.h" #include "libavfilter/buffersrc.h" #include "libavfilter/buffersink.h" #include "libavutil/hwcontext.h" #include "handbrake/lang.h" #include "handbrake/audio_resample.h" #if HB_PROJECT_FEATURE_QSV #include "libavutil/hwcontext_qsv.h" #include "handbrake/qsv_common.h" #include "handbrake/qsv_libav.h" #endif static void compute_frame_duration( hb_work_private_t *pv ); static int decavcodecaInit( hb_work_object_t *, hb_job_t * ); static int decavcodecaWork( hb_work_object_t *, hb_buffer_t **, hb_buffer_t ** ); static void decavcodecClose( hb_work_object_t * ); static int decavcodecaInfo( hb_work_object_t *, hb_work_info_t * ); static int decavcodecaBSInfo( hb_work_object_t *, const hb_buffer_t *, hb_work_info_t * ); static int get_color_prim(int color_primaries, hb_geometry_t geometry, hb_rational_t rate); static int get_color_transfer(int color_trc); static int get_color_matrix(int colorspace, hb_geometry_t geometry); hb_work_object_t hb_decavcodeca = { .id = WORK_DECAVCODEC, .name = "Audio decoder (libavcodec)", .init = decavcodecaInit, .work = decavcodecaWork, .close = decavcodecClose, .info = decavcodecaInfo, .bsinfo = decavcodecaBSInfo }; typedef struct { uint8_t * data; int size; int64_t pts; int64_t dts; int frametype; int scr_sequence; int new_chap; int discard; } packet_info_t; typedef struct reordered_data_s reordered_data_t; struct reordered_data_s { int64_t sequence; int64_t pts; int scr_sequence; int new_chap; }; #define REORDERED_HASH_SZ (2 << 7) #define REORDERED_HASH_MASK (REORDERED_HASH_SZ - 1) struct video_filters_s { hb_avfilter_graph_t * graph; int width; int height; int pix_fmt; }; struct hb_work_private_s { hb_job_t * job; hb_title_t * title; AVCodec * codec; AVCodecContext * context; AVCodecParserContext * parser; AVFrame * frame; hb_buffer_t * palette; int threads; int video_codec_opened; hb_buffer_list_t list; double duration; // frame duration (for video) double field_duration; // field duration (for video) int64_t chap_time; // time of next chap mark int chap_scr; int new_chap; // output chapter mark pending int64_t last_pts; double next_pts; uint32_t nframes; uint32_t decode_errors; packet_info_t packet_info; uint8_t unfinished; reordered_data_t * reordered_hash[REORDERED_HASH_SZ]; int64_t sequence; int last_scr_sequence; int last_chapter; struct video_filters_s video_filters; hb_audio_t * audio; hb_audio_resample_t * resample; int drop_samples; #if HB_PROJECT_FEATURE_QSV // QSV-specific settings struct { int decode; hb_qsv_config config; const char * codec_name; } qsv; #endif hb_list_t * list_subtitle; }; static void decodeAudio( hb_work_private_t *pv, packet_info_t * packet_info ); /*********************************************************************** * hb_work_decavcodec_init *********************************************************************** * **********************************************************************/ static int decavcodecaInit( 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; pv->audio = w->audio; pv->drop_samples = w->audio->config.in.encoder_delay; pv->next_pts = (int64_t)AV_NOPTS_VALUE; if (job) pv->title = job->title; else pv->title = w->title; hb_buffer_list_clear(&pv->list); codec = avcodec_find_decoder(w->codec_param); pv->context = avcodec_alloc_context3(codec); if (pv->title->opaque_priv != NULL) { AVFormatContext *ic = (AVFormatContext*)pv->title->opaque_priv; avcodec_parameters_to_context(pv->context, ic->streams[w->audio->id]->codecpar); // libav's eac3 parser toggles the codec_id in the context as // it reads eac3 data between AV_CODEC_ID_AC3 and AV_CODEC_ID_EAC3. // It detects an AC3 sync pattern sometimes in ac3_sync() which // causes it to eventually set avctx->codec_id to AV_CODEC_ID_AC3 // in ff_aac_ac3_parse(). Since we are parsing some data before // we get here, the codec_id may have flipped. This will cause an // error in hb_avcodec_open(). So flip it back! pv->context->codec_id = w->codec_param; } else { pv->parser = av_parser_init(w->codec_param); } hb_ff_set_sample_fmt(pv->context, codec, AV_SAMPLE_FMT_FLT); /* Downmixing & sample_fmt conversion */ if (!(w->audio->config.out.codec & HB_ACODEC_PASS_FLAG)) { // Currently, samplerate conversion is performed in sync.c // So set output samplerate to input samplerate // This should someday get reworked to be part of an audio // filter pipleine. pv->resample = hb_audio_resample_init(AV_SAMPLE_FMT_FLT, w->audio->config.in.samplerate, w->audio->config.out.mixdown, w->audio->config.out.normalize_mix_level); if (pv->resample == NULL) { hb_error("decavcodecaInit: hb_audio_resample_init() failed"); return 1; } /* * Some audio decoders can downmix using embedded coefficients, * or dedicated audio substreams for a specific channel layout. * * But some will e.g. use normalized mix coefficients unconditionally, * so we need to make sure this matches what the user actually requested. */ int avcodec_downmix = 0; switch (w->codec_param) { case AV_CODEC_ID_AC3: case AV_CODEC_ID_EAC3: avcodec_downmix = w->audio->config.out.normalize_mix_level != 0; break; case AV_CODEC_ID_DTS: avcodec_downmix = w->audio->config.out.normalize_mix_level == 0; break; case AV_CODEC_ID_TRUEHD: avcodec_downmix = (w->audio->config.out.normalize_mix_level == 0 || w->audio->config.out.mixdown == HB_AMIXDOWN_MONO || w->audio->config.out.mixdown == HB_AMIXDOWN_DOLBY || w->audio->config.out.mixdown == HB_AMIXDOWN_DOLBYPLII); break; default: break; } if (avcodec_downmix) { switch (w->audio->config.out.mixdown) { // request 5.1 before downmixing to dpl1/dpl2 case HB_AMIXDOWN_DOLBY: case HB_AMIXDOWN_DOLBYPLII: pv->context->request_channel_layout = AV_CH_LAYOUT_5POINT1; break; // request the layout corresponding to the selected mixdown default: pv->context->request_channel_layout = hb_ff_mixdown_xlat(w->audio->config.out.mixdown, NULL); break; } } } // libavcodec can't decode TrueHD Mono (bug #356) // work around it by requesting Stereo and downmixing if (w->codec_param == AV_CODEC_ID_TRUEHD && w->audio->config.in.channel_layout == AV_CH_LAYOUT_MONO) { pv->context->request_channel_layout = AV_CH_LAYOUT_STEREO; } // Set decoder opts... AVDictionary * av_opts = NULL; av_dict_set( &av_opts, "refcounted_frames", "1", 0 ); // Dynamic Range Compression if (w->audio->config.out.dynamic_range_compression >= 0.0f && hb_audio_can_apply_drc(w->audio->config.in.codec, w->audio->config.in.codec_param, 0)) { float drc_scale_max = 1.0f; /* * avcodec_open will fail if the value for any of the options is out of * range, so assume a conservative maximum of 1 and try to determine the * option's actual upper limit. */ if (codec != NULL && codec->priv_class != NULL) { const AVOption *opt; opt = av_opt_find2((void*)&codec->priv_class, "drc_scale", NULL, AV_OPT_FLAG_DECODING_PARAM|AV_OPT_FLAG_AUDIO_PARAM, AV_OPT_SEARCH_FAKE_OBJ, NULL); if (opt != NULL) { drc_scale_max = opt->max; } } if (w->audio->config.out.dynamic_range_compression > drc_scale_max) { hb_log("decavcodecaInit: track %d, sanitizing out-of-range DRC %.2f to %.2f", w->audio->config.out.track, w->audio->config.out.dynamic_range_compression, drc_scale_max); w->audio->config.out.dynamic_range_compression = drc_scale_max; } char drc_scale[5]; // "?.??\n" snprintf(drc_scale, sizeof(drc_scale), "%.2f", w->audio->config.out.dynamic_range_compression); av_dict_set(&av_opts, "drc_scale", drc_scale, 0); } if (hb_avcodec_open(pv->context, codec, &av_opts, 0)) { av_dict_free( &av_opts ); hb_log("decavcodecaInit: avcodec_open failed"); return 1; } pv->context->pkt_timebase.num = pv->audio->config.in.timebase.num; pv->context->pkt_timebase.den = pv->audio->config.in.timebase.den; // avcodec_open populates av_opts with the things it didn't recognize. AVDictionaryEntry *t = NULL; while ((t = av_dict_get(av_opts, "", t, AV_DICT_IGNORE_SUFFIX)) != NULL) { hb_log("decavcodecaInit: unknown option '%s'", t->key); } av_dict_free( &av_opts ); pv->frame = av_frame_alloc(); if (pv->frame == NULL) { hb_log("decavcodecaInit: av_frame_alloc failed"); return 1; } return 0; } /*********************************************************************** * Close *********************************************************************** * **********************************************************************/ static void close_video_filters(hb_work_private_t *pv) { hb_avfilter_graph_close(&pv->video_filters.graph); } static void closePrivData( hb_work_private_t ** ppv ) { hb_work_private_t * pv = *ppv; if ( pv ) { hb_buffer_list_close(&pv->list); if ( pv->job && pv->context && pv->context->codec ) { hb_log( "%s-decoder done: %u frames, %u decoder errors", pv->context->codec->name, pv->nframes, pv->decode_errors); } av_frame_free(&pv->frame); close_video_filters(pv); if ( pv->parser ) { av_parser_close(pv->parser); } if ( pv->context && pv->context->codec ) { #if HB_PROJECT_FEATURE_QSV /* * FIXME: knowingly leaked. * * If we're using our FFmpeg QSV wrapper, qsv_decode_end() will call * MFXClose() on the QSV session. Even if decoding is complete, we * still need that session for QSV filtering and/or encoding, so we * we can't close the context here until we implement a proper fix. * * Interestingly, this may cause crashes even when QSV-accelerated * decoding and encoding sessions are independent (e.g. decoding via * libavcodec, but encoding using libhb, without us requesting any * form of communication between the two libmfx sessions). */ //if (!(pv->qsv.decode && pv->job != NULL && (pv->job->vcodec & HB_VCODEC_QSV_MASK))) hb_qsv_uninit_dec(pv->context); #endif { hb_avcodec_free_context(&pv->context); } } if ( pv->context ) { hb_avcodec_free_context(&pv->context); } hb_audio_resample_free(pv->resample); int ii; for (ii = 0; ii < REORDERED_HASH_SZ; ii++) { free(pv->reordered_hash[ii]); } free(pv); } *ppv = NULL; } static void decavcodecClose( hb_work_object_t * w ) { hb_work_private_t * pv = w->private_data; if ( pv ) { closePrivData( &pv ); w->private_data = NULL; } } static void audioParserFlush(hb_work_object_t * w) { hb_work_private_t * pv = w->private_data; uint8_t * pout = NULL; int pout_len = 0; int64_t parser_pts = AV_NOPTS_VALUE; do { if (pv->parser) { av_parser_parse2(pv->parser, pv->context, &pout, &pout_len, NULL, 0, AV_NOPTS_VALUE, AV_NOPTS_VALUE, 0 ); parser_pts = pv->parser->pts; } if (pout != NULL && pout_len > 0) { pv->packet_info.data = pout; pv->packet_info.size = pout_len; pv->packet_info.pts = parser_pts; decodeAudio(pv, &pv->packet_info); } } while (pout != NULL && pout_len > 0); } /*********************************************************************** * Work *********************************************************************** * **********************************************************************/ static int decavcodecaWork( 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; // libavcodec/mpeg12dec.c requires buffers to be zero padded. // If not zero padded, it can get stuck in an infinite loop. // It's likely there are other decoders that expect the same. if (in->data != NULL) { memset(in->data + in->size, 0, in->alloc - in->size); } if (in->s.flags & HB_BUF_FLAG_EOF) { /* EOF on input stream - send it downstream & say that we're done */ audioParserFlush(w); decodeAudio(pv, NULL); hb_buffer_list_append(&pv->list, in); *buf_in = NULL; *buf_out = hb_buffer_list_clear(&pv->list); return HB_WORK_DONE; } *buf_out = NULL; int pos, len; int64_t pts = in->s.start; // There are a 3 scenarios that can happen here. // 1. The buffer contains exactly one frame of data // 2. The buffer contains multiple frames of data // 3. The buffer contains a partial frame of data // // In scenario 2, we want to be sure that the timestamps are only // applied to the first frame in the buffer. Additional frames // in the buffer will have their timestamps computed in sync. // // In scenario 3, we need to save the ancillary buffer info of an // unfinished frame so it can be applied when we receive the last // buffer of that frame. if (!pv->unfinished) { // New packet, and no previous data pending pv->packet_info.scr_sequence = in->s.scr_sequence; pv->packet_info.new_chap = in->s.new_chap; pv->packet_info.frametype = in->s.frametype; pv->packet_info.discard = !!(in->s.flags & HB_FLAG_DISCARD); } for (pos = 0; pos < in->size; pos += len) { uint8_t * pout = NULL; int pout_len = 0; int64_t parser_pts; if ( pv->parser != NULL ) { len = av_parser_parse2(pv->parser, pv->context, &pout, &pout_len, in->data + pos, in->size - pos, pts, pts, 0 ); parser_pts = pv->parser->pts; pts = AV_NOPTS_VALUE; } else { pout = in->data; len = pout_len = in->size; parser_pts = in->s.start; } if (pout != NULL && pout_len > 0) { pv->packet_info.data = pout; pv->packet_info.size = pout_len; pv->packet_info.pts = parser_pts; decodeAudio(pv, &pv->packet_info); // There could have been an unfinished packet when we entered // decodeAudio that is now finished. The next packet is associated // with the input buffer, so set it's chapter and scr info. pv->packet_info.scr_sequence = in->s.scr_sequence; pv->packet_info.discard = !!(in->s.flags & HB_FLAG_DISCARD); pv->unfinished = 0; } if (len > 0 && pout_len <= 0) { pv->unfinished = 1; } } *buf_out = hb_buffer_list_clear(&pv->list); return HB_WORK_OK; } static int decavcodecaInfo( 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.num = context->time_base.num; info->rate.den = context->time_base.den; info->profile = context->profile; info->level = context->level; return 1; } return 0; } static int parse_adts_extradata( hb_audio_t * audio, AVCodecContext * context, AVPacket * pkt ) { const AVBitStreamFilter * bsf; AVBSFContext * ctx = NULL; int ret; bsf = av_bsf_get_by_name("aac_adtstoasc"); ret = av_bsf_alloc(bsf, &ctx); if (ret < 0) { hb_error("decavcodec: bitstream filter alloc failure"); return ret; } ctx->time_base_in.num = 1; ctx->time_base_in.den = audio->config.out.samplerate; avcodec_parameters_from_context(ctx->par_in, context); ret = av_bsf_init(ctx); if (ret < 0) { hb_error("decavcodec: bitstream filter init failure"); av_bsf_free(&ctx); return ret; } ret = av_bsf_send_packet(ctx, pkt); if (ret < 0) { hb_error("decavcodec: av_bsf_send_packet failure"); av_bsf_free(&ctx); return ret; } ret = av_bsf_receive_packet(ctx, pkt); av_bsf_free(&ctx); if (ret == AVERROR(EAGAIN) || ret == AVERROR_EOF) { return 0; } else if (ret < 0) { if (ret != AVERROR_INVALIDDATA) { hb_error("decavcodec: av_bsf_receive_packet failure %x", -ret); } return ret; } if (audio->priv.config.extradata.length == 0) { const uint8_t * extradata; int size; extradata = av_packet_get_side_data(pkt, AV_PKT_DATA_NEW_EXTRADATA, &size); if (extradata != NULL && size > 0) { int len; len = MIN(size, HB_CONFIG_MAX_SIZE); memcpy(audio->priv.config.extradata.bytes, extradata, len); audio->priv.config.extradata.length = len; } } return 0; } static int decavcodecaBSInfo( hb_work_object_t *w, const hb_buffer_t *buf, hb_work_info_t *info ) { hb_work_private_t *pv = w->private_data; int result = 0, done = 0; hb_audio_t *audio = w->audio; memset( info, 0, sizeof(*info) ); if ( pv && pv->context ) { return decavcodecaInfo( w, info ); } AVCodec *codec = avcodec_find_decoder( w->codec_param ); if ( ! codec ) { // there's no ffmpeg codec for this audio type - give up return -1; } static char codec_name[64]; info->name = strncpy( codec_name, codec->name, sizeof(codec_name)-1 ); AVCodecContext *context = avcodec_alloc_context3(codec); AVCodecParserContext *parser = NULL; if (w->title && w->title->opaque_priv != NULL) { AVFormatContext *ic = (AVFormatContext*)w->title->opaque_priv; avcodec_parameters_to_context(context, ic->streams[audio->id]->codecpar); // libav's eac3 parser toggles the codec_id in the context as // it reads eac3 data between AV_CODEC_ID_AC3 and AV_CODEC_ID_EAC3. // It detects an AC3 sync pattern sometimes in ac3_sync() which // causes it to eventually set avctx->codec_id to AV_CODEC_ID_AC3 // in ff_aac_ac3_parse(). Since we are parsing some data before // we get here, the codec_id may have flipped. This will cause an // error in hb_avcodec_open(). So flip it back! context->codec_id = w->codec_param; } else { parser = av_parser_init(codec->id); } hb_ff_set_sample_fmt( context, codec, AV_SAMPLE_FMT_FLT ); AVDictionary * av_opts = NULL; av_dict_set( &av_opts, "err_detect", "crccheck+explode", 0 ); if ( hb_avcodec_open( context, codec, &av_opts, 0 ) ) { av_dict_free( &av_opts ); return -1; } if (audio != NULL) { context->pkt_timebase.num = audio->config.in.timebase.num; context->pkt_timebase.den = audio->config.in.timebase.den; } av_dict_free( &av_opts ); unsigned char *parse_buffer; int parse_pos, parse_buffer_size; while (buf != NULL && !done) { parse_pos = 0; while (parse_pos < buf->size && !done) { int parse_len, truehd_mono = 0, ret; if (parser != NULL) { parse_len = av_parser_parse2(parser, context, &parse_buffer, &parse_buffer_size, buf->data + parse_pos, buf->size - parse_pos, buf->s.start, buf->s.start, 0); } else { parse_buffer = buf->data + parse_pos; parse_len = parse_buffer_size = buf->size - parse_pos; } if (parse_buffer_size == 0) { parse_pos += parse_len; continue; } // libavcodec can't decode TrueHD Mono (bug #356) // work around it by requesting Stereo before decoding if (context->codec_id == AV_CODEC_ID_TRUEHD && context->channel_layout == AV_CH_LAYOUT_MONO) { truehd_mono = 1; context->request_channel_layout = AV_CH_LAYOUT_STEREO; } else { context->request_channel_layout = 0; } AVPacket avp; av_init_packet(&avp); avp.data = parse_buffer; avp.size = parse_buffer_size; ret = avcodec_send_packet(context, &avp); if (ret < 0 && ret != AVERROR_EOF) { parse_pos += parse_len; av_packet_unref(&avp); continue; } AVFrame *frame = NULL; do { if (frame == NULL) { frame = av_frame_alloc(); } ret = avcodec_receive_frame(context, frame); if (ret >= 0) { // libavcoded doesn't consistently set frame->sample_rate if (frame->sample_rate != 0) { info->rate.num = frame->sample_rate; } else { info->rate.num = context->sample_rate; hb_log("decavcodecaBSInfo: warning: invalid frame sample_rate! Using context sample_rate."); } info->rate.den = 1; info->samples_per_frame = frame->nb_samples; info->sample_bit_depth = context->bits_per_raw_sample; int bps = av_get_bits_per_sample(context->codec_id); int channels; if (frame->channel_layout != 0) { channels = av_get_channel_layout_nb_channels( frame->channel_layout); } else { channels = frame->channels; } info->bitrate = bps * channels * info->rate.num; if (info->bitrate <= 0) { if (context->bit_rate > 0) { info->bitrate = context->bit_rate; } else { info->bitrate = 1; } } if (truehd_mono) { info->channel_layout = AV_CH_LAYOUT_MONO; info->matrix_encoding = AV_MATRIX_ENCODING_NONE; } else { AVFrameSideData *side_data; if ((side_data = av_frame_get_side_data(frame, AV_FRAME_DATA_MATRIXENCODING)) != NULL) { info->matrix_encoding = *side_data->data; } else { info->matrix_encoding = AV_MATRIX_ENCODING_NONE; } if (info->matrix_encoding == AV_MATRIX_ENCODING_DOLBY || info->matrix_encoding == AV_MATRIX_ENCODING_DPLII) { info->channel_layout = AV_CH_LAYOUT_STEREO_DOWNMIX; } else { info->channel_layout = frame->channel_layout; } } if (info->channel_layout == 0) { // Channel layout was not set. Guess a layout based // on number of channels. info->channel_layout = av_get_default_channel_layout( frame->channels); } if (context->codec_id == AV_CODEC_ID_AC3 || context->codec_id == AV_CODEC_ID_EAC3) { if (context->audio_service_type == AV_AUDIO_SERVICE_TYPE_KARAOKE) { info->mode = 7; } else { info->mode = context->audio_service_type; } } else if (context->codec_id == AV_CODEC_ID_AAC && context->extradata_size == 0) { // Parse ADTS AAC streams for AudioSpecificConfig. // This data is required in order to write // proper headers in MP4, WebM, and MKV files. parse_adts_extradata(audio, context, &avp); } result = 1; done = 1; av_frame_unref(frame); break; } } while (ret >= 0); av_packet_unref(&avp); av_frame_free(&frame); parse_pos += parse_len; } buf = buf->next; } info->profile = context->profile; info->level = context->level; info->channel_map = &hb_libav_chan_map; if ( parser != NULL ) av_parser_close( parser ); hb_avcodec_free_context(&context); return result; } reordered_data_t * reordered_hash_rem(hb_work_private_t * pv, int64_t sequence) { reordered_data_t * reordered; int slot = sequence & REORDERED_HASH_MASK; reordered = pv->reordered_hash[slot]; if (reordered == NULL) { // This shouldn't happen... // But, this happens sometimes when libav outputs exactly the same // frame twice for some reason. hb_deep_log(3, "decavcodec: missing sequence %"PRId64"", sequence); } pv->reordered_hash[slot] = NULL; return reordered; } void reordered_hash_add(hb_work_private_t * pv, reordered_data_t * reordered) { int slot = reordered->sequence & REORDERED_HASH_MASK; // Free any unused previous entries. // This can happen due to libav parser feeding partial // frames data to the decoder. // It can also happen due to decoding errors. free(pv->reordered_hash[slot]); pv->reordered_hash[slot] = reordered; } /* ------------------------------------------------------------- * General purpose video decoder using libavcodec */ // send cc_buf to the CC decoder(s) static void cc_send_to_decoder(hb_work_private_t *pv, hb_buffer_t *buf) { if (buf == NULL) return; // if there's more than one decoder for the captions send a copy // of the buffer to all. hb_subtitle_t *subtitle; int ii = 0, n = hb_list_count(pv->list_subtitle); while (--n > 0) { // make a copy of the buf then forward it to the decoder hb_buffer_t *cpy = hb_buffer_dup(buf); subtitle = hb_list_item(pv->list_subtitle, ii++); hb_fifo_push(subtitle->fifo_in, cpy); } subtitle = hb_list_item(pv->list_subtitle, ii); hb_fifo_push( subtitle->fifo_in, buf ); } static hb_buffer_t * cc_fill_buffer(hb_work_private_t *pv, uint8_t *cc, int size) { int cc_count[4] = {0,}; int ii; hb_buffer_t *buf = NULL; for (ii = 0; ii < size; ii += 3) { if ((cc[ii] & 0x04) == 0) // not valid continue; if ((cc[ii+1] & 0x7f) == 0 && (cc[ii+2] & 0x7f) == 0) // stuffing continue; int type = cc[ii] & 0x03; cc_count[type]++; } // Only handles CC1 for now. if (cc_count[0] > 0) { buf = hb_buffer_init(cc_count[0] * 2); int jj = 0; for (ii = 0; ii < size; ii += 3) { if ((cc[ii] & 0x04) == 0) // not valid continue; if ((cc[ii+1] & 0x7f) == 0 && (cc[ii+2] & 0x7f) == 0) // stuffing continue; int type = cc[ii] & 0x03; if (type == 0) { buf->data[jj++] = cc[ii+1]; buf->data[jj++] = cc[ii+2]; } } } return buf; } // 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 ) { reordered_data_t * reordered = NULL; hb_buffer_t * out; #if HB_PROJECT_FEATURE_QSV // no need to copy the frame data when decoding with QSV to opaque memory if (pv->qsv.decode && pv->qsv.config.io_pattern == MFX_IOPATTERN_OUT_VIDEO_MEMORY) { out = hb_qsv_copy_frame(pv->frame, pv->job->qsv.ctx); } else #endif { out = hb_avframe_to_video_buffer(pv->frame, (AVRational){1,1}); } if (pv->frame->pts != AV_NOPTS_VALUE) { reordered = reordered_hash_rem(pv, pv->frame->pts); } if (reordered != NULL) { out->s.scr_sequence = reordered->scr_sequence; out->s.start = reordered->pts; out->s.new_chap = reordered->new_chap; pv->last_scr_sequence = reordered->scr_sequence; pv->last_chapter = reordered->new_chap; free(reordered); } else { out->s.scr_sequence = pv->last_scr_sequence; out->s.start = AV_NOPTS_VALUE; } double frame_dur = pv->duration; if (pv->frame->repeat_pict) { frame_dur += pv->frame->repeat_pict * pv->field_duration; } if (out->s.start == AV_NOPTS_VALUE) { out->s.start = pv->next_pts; } else { pv->next_pts = out->s.start; } if (pv->next_pts != (int64_t)AV_NOPTS_VALUE) { pv->next_pts += frame_dur; out->s.stop = pv->next_pts; } out->s.duration = frame_dur; if (out->s.new_chap > 0 && out->s.new_chap == pv->new_chap) { pv->new_chap = 0; } // It is possible that the buffer with new_chap gets dropped // by the decoder. So also check if the output buffer is after // the new_chap in the timeline. if (pv->new_chap > 0 && (out->s.scr_sequence > pv->chap_scr || (out->s.scr_sequence == pv->chap_scr && out->s.start > pv->chap_time))) { out->s.new_chap = pv->new_chap; pv->new_chap = 0; } // Check for CC data AVFrameSideData *sd; sd = av_frame_get_side_data(pv->frame, AV_FRAME_DATA_A53_CC); if (sd != NULL) { if (!pv->job && pv->title && sd->size > 0) { hb_subtitle_t *subtitle; int i = 0; while ((subtitle = hb_list_item(pv->title->list_subtitle, i++))) { /* * Let's call them 608 subs for now even if they aren't, * since they are the only types we grok. */ if (subtitle->source == CC608SUB) { break; } } if (subtitle == NULL) { iso639_lang_t * lang; hb_audio_t * audio; subtitle = calloc(sizeof( hb_subtitle_t ), 1); subtitle->track = hb_list_count(pv->title->list_subtitle); subtitle->id = HB_SUBTITLE_EMBEDDED_CC_TAG; subtitle->format = TEXTSUB; subtitle->source = CC608SUB; subtitle->config.dest = PASSTHRUSUB; subtitle->codec = WORK_DECCC608; subtitle->attributes = HB_SUBTITLE_ATTR_CC; /* * The language of the subtitles will be the same as the * first audio track, i.e. the same as the video. */ audio = hb_list_item(pv->title->list_audio, 0); if (audio != NULL) { lang = lang_for_code2( audio->config.lang.iso639_2 ); } else { lang = lang_for_code2( "und" ); } snprintf(subtitle->lang, sizeof(subtitle->lang), "%s, Closed Caption [%s]", strlen(lang->native_name) ? lang->native_name : lang->eng_name, hb_subsource_name(subtitle->source)); snprintf(subtitle->iso639_2, sizeof(subtitle->iso639_2), "%s", lang->iso639_2); hb_list_add(pv->title->list_subtitle, subtitle); } } if (pv->list_subtitle != NULL && sd->size > 0) { hb_buffer_t *cc_buf; cc_buf = cc_fill_buffer(pv, sd->data, sd->size); if (cc_buf != NULL) { cc_buf->s.start = out->s.start; cc_buf->s.scr_sequence = out->s.scr_sequence; } cc_send_to_decoder(pv, cc_buf); } } return out; } int reinit_video_filters(hb_work_private_t * pv) { int orig_width; int orig_height; hb_value_array_t * filters; hb_dict_t * settings; hb_filter_init_t filter_init; enum AVPixelFormat pix_fmt; #if HB_PROJECT_FEATURE_QSV if (pv->qsv.decode && pv->qsv.config.io_pattern == MFX_IOPATTERN_OUT_VIDEO_MEMORY) { // Can't use software filters when decoding with QSV opaque memory return 0; } #endif if (!pv->job) { // HandBrake's video pipeline uses yuv420 color. This means all // dimensions must be even. So we must adjust the dimensions // of incoming video if not even. orig_width = pv->context->width & ~1; orig_height = pv->context->height & ~1; pix_fmt = AV_PIX_FMT_YUV420P; } else { if (pv->title->rotation == HB_ROTATION_90 || pv->title->rotation == HB_ROTATION_270) { orig_width = pv->job->title->geometry.height; orig_height = pv->job->title->geometry.width; } else { orig_width = pv->job->title->geometry.width; orig_height = pv->job->title->geometry.height; } pix_fmt = pv->job->pix_fmt; } if (pix_fmt == pv->frame->format && orig_width == pv->frame->width && orig_height == pv->frame->height && HB_ROTATION_0 == pv->title->rotation) { // No filtering required. close_video_filters(pv); return 0; } if (pv->video_filters.graph != NULL && pv->video_filters.width == pv->frame->width && pv->video_filters.height == pv->frame->height && pv->video_filters.pix_fmt == pv->frame->format) { // Current filter settings are good return 0; } pv->video_filters.width = pv->frame->width; pv->video_filters.height = pv->frame->height; pv->video_filters.pix_fmt = pv->frame->format; // New filter required, create filter graph close_video_filters(pv); int clock_min, clock_max, clock; hb_rational_t vrate; hb_video_framerate_get_limits(&clock_min, &clock_max, &clock); vrate.num = clock; vrate.den = pv->duration * (clock / 90000.); filters = hb_value_array_init(); if (pix_fmt != pv->frame->format || orig_width != pv->frame->width || orig_height != pv->frame->height) { settings = hb_dict_init(); hb_dict_set(settings, "w", hb_value_int(orig_width)); hb_dict_set(settings, "h", hb_value_int(orig_height)); hb_dict_set(settings, "flags", hb_value_string("lanczos+accurate_rnd")); hb_avfilter_append_dict(filters, "scale", settings); settings = hb_dict_init(); hb_dict_set(settings, "pix_fmts", hb_value_string("yuv420p")); hb_avfilter_append_dict(filters, "format", settings); } if (pv->title->rotation != HB_ROTATION_0) { switch (pv->title->rotation) { case HB_ROTATION_90: settings = hb_dict_init(); hb_dict_set(settings, "dir", hb_value_string("cclock")); hb_avfilter_append_dict(filters, "transpose", settings); break; case HB_ROTATION_180: hb_avfilter_append_dict(filters, "hflip", hb_value_null()); hb_avfilter_append_dict(filters, "vflip", hb_value_null()); break; case HB_ROTATION_270: settings = hb_dict_init(); hb_dict_set(settings, "dir", hb_value_string("clock")); hb_avfilter_append_dict(filters, "transpose", settings); break; default: hb_log("reinit_video_filters: Unknown rotation, failed"); } } filter_init.pix_fmt = pv->frame->format; filter_init.geometry.width = pv->frame->width; filter_init.geometry.height = pv->frame->height; filter_init.geometry.par.num = pv->frame->sample_aspect_ratio.num; filter_init.geometry.par.den = pv->frame->sample_aspect_ratio.den; filter_init.time_base.num = 1; filter_init.time_base.den = 1; filter_init.vrate.num = vrate.num; filter_init.vrate.den = vrate.den; pv->video_filters.graph = hb_avfilter_graph_init(filters, &filter_init); hb_value_free(&filters); if (pv->video_filters.graph == NULL) { hb_error("reinit_video_filters: failed to create filter graph"); goto fail; } return 0; fail: close_video_filters(pv); return 1; } static void filter_video(hb_work_private_t *pv) { reinit_video_filters(pv); if (pv->video_filters.graph != NULL) { int result; hb_avfilter_add_frame(pv->video_filters.graph, pv->frame); result = hb_avfilter_get_frame(pv->video_filters.graph, pv->frame); while (result >= 0) { hb_buffer_t * buf = copy_frame(pv); hb_buffer_list_append(&pv->list, buf); av_frame_unref(pv->frame); ++pv->nframes; result = hb_avfilter_get_frame(pv->video_filters.graph, pv->frame); } } else { hb_buffer_t * buf = copy_frame(pv); hb_buffer_list_append(&pv->list, buf); av_frame_unref(pv->frame); ++pv->nframes; } } /* * Decodes a video frame from the specified raw packet data * ('data', 'size'). * The output of this function is stored in 'pv->list', which contains a list * of zero or more decoded packets. */ static int decodeFrame( hb_work_private_t * pv, packet_info_t * packet_info ) { int got_picture = 0, oldlevel = 0, ret; AVPacket avp; reordered_data_t * reordered; if ( global_verbosity_level <= 1 ) { oldlevel = av_log_get_level(); av_log_set_level( AV_LOG_QUIET ); } av_init_packet(&avp); if (packet_info != NULL) { avp.data = packet_info->data; avp.size = packet_info->size; avp.pts = pv->sequence; avp.dts = pv->sequence; reordered = malloc(sizeof(*reordered)); if (reordered != NULL) { reordered->sequence = pv->sequence++; reordered->pts = packet_info->pts; reordered->scr_sequence = packet_info->scr_sequence; reordered->new_chap = packet_info->new_chap; reordered_hash_add(pv, reordered); } // libav avcodec video decoder needs AVPacket flagged with // AV_PKT_FLAG_KEY for some codecs. For example, sequence of // PNG in a mov container. if (packet_info->frametype & HB_FRAME_MASK_KEY) { avp.flags |= AV_PKT_FLAG_KEY; } avp.flags |= packet_info->discard * AV_PKT_FLAG_DISCARD; } else { avp.data = NULL; avp.size = 0; } if (pv->palette != NULL) { uint8_t * palette; int size; palette = av_packet_new_side_data(&avp, AV_PKT_DATA_PALETTE, AVPALETTE_SIZE); size = MIN(pv->palette->size, AVPALETTE_SIZE); memcpy(palette, pv->palette->data, size); hb_buffer_close(&pv->palette); } ret = avcodec_send_packet(pv->context, &avp); av_packet_unref(&avp); if (ret < 0 && ret != AVERROR_EOF) { ++pv->decode_errors; return 0; } do { ret = avcodec_receive_frame(pv->context, pv->frame); if (ret < 0 && ret != AVERROR(EAGAIN) && ret != AVERROR_EOF) { ++pv->decode_errors; } if (ret < 0) { break; } got_picture = 1; // recompute the frame/field duration, because sometimes it changes compute_frame_duration( pv ); filter_video(pv); } while (ret >= 0); if ( global_verbosity_level <= 1 ) { av_log_set_level( oldlevel ); } return got_picture; } 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->next_pts = (int64_t)AV_NOPTS_VALUE; if ( job ) pv->title = job->title; else pv->title = w->title; if (pv->title->flags & HBTF_RAW_VIDEO) pv->next_pts = 0; hb_buffer_list_clear(&pv->list); #if HB_PROJECT_FEATURE_QSV if ((pv->qsv.decode = hb_qsv_decode_is_enabled(job))) { pv->qsv.codec_name = hb_qsv_decode_get_codec_name(w->codec_param); pv->qsv.config.io_pattern = MFX_IOPATTERN_OUT_SYSTEM_MEMORY; if(hb_qsv_full_path_is_enabled(job)) { hb_qsv_info_t *info = hb_qsv_info_get(job->vcodec); if (info != NULL) { // setup the QSV configuration pv->qsv.config.io_pattern = MFX_IOPATTERN_OUT_VIDEO_MEMORY; pv->qsv.config.impl_requested = info->implementation; pv->qsv.config.async_depth = job->qsv.async_depth; pv->qsv.config.sync_need = 0; pv->qsv.config.usage_threaded = 1; pv->qsv.config.additional_buffers = 64; // FIFO_LARGE if (info->capabilities & HB_QSV_CAP_RATECONTROL_LA) { // more surfaces may be needed for the lookahead pv->qsv.config.additional_buffers = 160; } if(!pv->job->qsv.ctx) { pv->job->qsv.ctx = av_mallocz(sizeof(hb_qsv_context)); if(!pv->job->qsv.ctx) { hb_error( "decavcodecvInit: qsv ctx alloc failed" ); return 1; } hb_qsv_add_context_usage(pv->job->qsv.ctx, 0); pv->job->qsv.ctx->dec_space = av_mallocz(sizeof(hb_qsv_space)); if(!pv->job->qsv.ctx->dec_space) { hb_error( "decavcodecvInit: dec_space alloc failed" ); return 1; } pv->job->qsv.ctx->dec_space->is_init_done = 1; } } } } #endif if( pv->job && pv->job->title && !pv->job->title->has_resolution_change ) { pv->threads = HB_FFMPEG_THREADS_AUTO; } #if HB_PROJECT_FEATURE_QSV if (pv->qsv.decode) { pv->codec = avcodec_find_decoder_by_name(pv->qsv.codec_name); } else #endif { pv->codec = avcodec_find_decoder(w->codec_param); } if ( pv->codec == NULL ) { hb_log( "decavcodecvInit: failed to find codec for id (%d)", w->codec_param ); return 1; } pv->context = avcodec_alloc_context3( pv->codec ); pv->context->workaround_bugs = FF_BUG_AUTODETECT; pv->context->err_recognition = AV_EF_CRCCHECK; pv->context->error_concealment = FF_EC_GUESS_MVS|FF_EC_DEBLOCK; if ( pv->title->opaque_priv ) { AVFormatContext *ic = (AVFormatContext*)pv->title->opaque_priv; avcodec_parameters_to_context(pv->context, ic->streams[pv->title->video_id]->codecpar); #if HB_PROJECT_FEATURE_QSV if (pv->qsv.decode && pv->qsv.config.io_pattern == MFX_IOPATTERN_OUT_VIDEO_MEMORY) { // assign callbacks pv->context->get_format = hb_qsv_get_format; pv->context->get_buffer2 = hb_qsv_get_buffer; pv->context->hwaccel_context = 0; } #endif // Set encoder opts AVDictionary * av_opts = NULL; av_dict_set( &av_opts, "refcounted_frames", "1", 0 ); if (pv->title->flags & HBTF_NO_IDR) { av_dict_set( &av_opts, "flags", "output_corrupt", 0 ); } #if HB_PROJECT_FEATURE_QSV if (pv->qsv.decode && pv->context->codec_id == AV_CODEC_ID_HEVC) { av_dict_set( &av_opts, "load_plugin", "hevc_hw", 0 ); } #endif if ( hb_avcodec_open( pv->context, pv->codec, &av_opts, pv->threads ) ) { av_dict_free( &av_opts ); hb_log( "decavcodecvInit: avcodec_open failed" ); return 1; } pv->context->pkt_timebase.num = pv->title->video_timebase.num; pv->context->pkt_timebase.den = pv->title->video_timebase.den; av_dict_free( &av_opts ); pv->video_codec_opened = 1; } else { pv->parser = av_parser_init( w->codec_param ); } pv->frame = av_frame_alloc(); if (pv->frame == NULL) { hb_log("decavcodecvInit: av_frame_alloc failed"); return 1; } /* * If not scanning, then are we supposed to extract Closed Captions * and send them to the decoder? */ if (job != NULL && hb_list_count(job->list_subtitle) > 0) { hb_subtitle_t *subtitle; int i = 0; while ((subtitle = hb_list_item(job->list_subtitle, i++)) != NULL) { if (subtitle->source == CC608SUB && subtitle->id == HB_SUBTITLE_EMBEDDED_CC_TAG) { if (pv->list_subtitle == NULL) { pv->list_subtitle = hb_list_init(); } hb_list_add(pv->list_subtitle, subtitle); } } } return 0; } static int setup_extradata( hb_work_private_t * pv, AVCodecContext * context ) { // 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. if (context->extradata == NULL) { if (pv->parser == NULL || pv->parser->parser == NULL || pv->parser->parser->split == NULL) { return 0; } else { int size; size = pv->parser->parser->split(pv->context, pv->packet_info.data, pv->packet_info.size); if (size > 0) { context->extradata_size = size; context->extradata = av_malloc(size + AV_INPUT_BUFFER_PADDING_SIZE); if (context->extradata == NULL) return 1; memcpy(context->extradata, pv->packet_info.data, size); return 0; } } return 1; } return 0; } static int decodePacket( hb_work_object_t * w ) { hb_work_private_t * pv = w->private_data; // if this is the first frame open the codec (we have to wait for the // first frame because of M$ VC1 braindamage). if ( !pv->video_codec_opened ) { AVCodecContext * context = avcodec_alloc_context3(pv->codec); if (setup_extradata(pv, context)) { // we didn't find the headers needed to set up extradata. // the codec will abort if we open it so just free the buf // and hope we eventually get the info we need. return HB_WORK_OK; } hb_avcodec_free_context(&pv->context); pv->context = context; pv->context->workaround_bugs = FF_BUG_AUTODETECT; pv->context->err_recognition = AV_EF_CRCCHECK; pv->context->error_concealment = FF_EC_GUESS_MVS|FF_EC_DEBLOCK; #if HB_PROJECT_FEATURE_QSV if (pv->qsv.decode && pv->qsv.config.io_pattern == MFX_IOPATTERN_OUT_VIDEO_MEMORY) { // set the QSV configuration before opening the decoder pv->context->hwaccel_context = &pv->qsv.config; } #endif AVDictionary * av_opts = NULL; av_dict_set( &av_opts, "refcounted_frames", "1", 0 ); if (pv->title->flags & HBTF_NO_IDR) { av_dict_set( &av_opts, "flags", "output_corrupt", 0 ); } // disable threaded decoding for scan, can cause crashes if ( hb_avcodec_open( pv->context, pv->codec, &av_opts, pv->threads ) ) { av_dict_free( &av_opts ); hb_log( "decavcodecvWork: avcodec_open failed" ); // avcodec_open can fail due to incorrectly parsed extradata // so try again when this fails av_freep( &pv->context->extradata ); pv->context->extradata_size = 0; return HB_WORK_OK; } pv->context->pkt_timebase.num = pv->title->video_timebase.num; pv->context->pkt_timebase.den = pv->title->video_timebase.den; av_dict_free( &av_opts ); pv->video_codec_opened = 1; } decodeFrame(pv, &pv->packet_info); return HB_WORK_OK; } static void videoParserFlush(hb_work_object_t * w) { hb_work_private_t * pv = w->private_data; int result; uint8_t * pout = NULL; int pout_len = 0; int64_t parser_pts = AV_NOPTS_VALUE; int64_t parser_dts = AV_NOPTS_VALUE; do { if (pv->parser) { av_parser_parse2(pv->parser, pv->context, &pout, &pout_len, NULL, 0, AV_NOPTS_VALUE, AV_NOPTS_VALUE, 0 ); parser_pts = pv->parser->pts; parser_dts = pv->parser->dts; } if (pout != NULL && pout_len > 0) { pv->packet_info.data = pout; pv->packet_info.size = pout_len; pv->packet_info.pts = parser_pts; pv->packet_info.dts = parser_dts; result = decodePacket(w); if (result != HB_WORK_OK) { break; } w->frame_count++; } } while (pout != NULL && pout_len > 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; int result = HB_WORK_OK; *buf_out = NULL; // libavcodec/mpeg12dec.c requires buffers to be zero padded. // If not zero padded, it can get stuck in an infinite loop. // It's likely there are other decoders that expect the same. if (in->data != NULL) { memset(in->data + in->size, 0, in->alloc - in->size); } if (in->palette != NULL) { pv->palette = in->palette; in->palette = NULL; } /* if we got an empty buffer signaling end-of-stream send it downstream */ if (in->s.flags & HB_BUF_FLAG_EOF) { if (pv->context != NULL && pv->context->codec != NULL) { videoParserFlush(w); while (decodeFrame(pv, NULL)) { continue; } } hb_buffer_list_append(&pv->list, hb_buffer_dup(in)); *buf_out = hb_buffer_list_clear(&pv->list); return HB_WORK_DONE; } /* * 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, len; int64_t pts = in->s.start; int64_t dts = in->s.renderOffset; if (in->s.new_chap > 0) { pv->new_chap = in->s.new_chap; pv->chap_scr = in->s.scr_sequence; if (in->s.start != AV_NOPTS_VALUE) { pv->chap_time = in->s.start; } else { pv->chap_time = pv->last_pts + 1; } } if (in->s.start != AV_NOPTS_VALUE) { pv->last_pts = in->s.start; } // There are a 3 scenarios that can happen here. // 1. The buffer contains exactly one frame of data // 2. The buffer contains multiple frames of data // 3. The buffer contains a partial frame of data // // In scenario 2, we want to be sure that the timestamps are only // applied to the first frame in the buffer. Additional frames // in the buffer will have their timestamps computed in sync. // // In scenario 3, we need to save the ancillary buffer info of an // unfinished frame so it can be applied when we receive the last // buffer of that frame. if (!pv->unfinished) { // New packet, and no previous data pending pv->packet_info.scr_sequence = in->s.scr_sequence; pv->packet_info.new_chap = in->s.new_chap; pv->packet_info.frametype = in->s.frametype; pv->packet_info.discard = !!(in->s.flags & HB_FLAG_DISCARD); } for (pos = 0; pos < in->size; pos += len) { uint8_t * pout = NULL; int pout_len = 0; int64_t parser_pts, parser_dts; if (pv->parser) { int codec_id = pv->context->codec_id; len = av_parser_parse2(pv->parser, pv->context, &pout, &pout_len, in->data + pos, in->size - pos, pts, dts, 0 ); parser_pts = pv->parser->pts; parser_dts = pv->parser->dts; pts = AV_NOPTS_VALUE; dts = AV_NOPTS_VALUE; if (codec_id != pv->context->codec_id) { // The parser has decided to change the decoder underneath // us. Update our context to match. This can happen // for MPEG-1/2 video, perhaps others pv->codec = avcodec_find_decoder(pv->context->codec_id); } } else { pout = in->data; len = pout_len = in->size; parser_pts = pts; parser_dts = dts; } if (pout != NULL && pout_len > 0) { pv->packet_info.data = pout; pv->packet_info.size = pout_len; pv->packet_info.pts = parser_pts; pv->packet_info.dts = parser_dts; result = decodePacket(w); if (result != HB_WORK_OK) { break; } w->frame_count++; // There could have been an unfinished packet that is now finished. // The next packet is associated with the input buffer, so set // it's chapter and scr info. pv->packet_info.scr_sequence = in->s.scr_sequence; pv->packet_info.new_chap = in->s.new_chap; pv->packet_info.frametype = in->s.frametype; pv->packet_info.discard = !!(in->s.flags & HB_FLAG_DISCARD); pv->unfinished = 0; } if (len > 0 && pout_len <= 0) { pv->unfinished = 1; } } *buf_out = hb_buffer_list_clear(&pv->list); return result; } static void compute_frame_duration( hb_work_private_t *pv ) { double duration = 0.; int64_t max_fps = 64LL; // context->time_base may be in fields, so set the max *fields* per second if ( pv->context->ticks_per_frame > 1 ) max_fps *= pv->context->ticks_per_frame; if ( pv->title->opaque_priv ) { // If ffmpeg is demuxing for us, it collects some additional // information about framerates that is often more accurate // than context->time_base. AVFormatContext *ic = (AVFormatContext*)pv->title->opaque_priv; AVStream *st = ic->streams[pv->title->video_id]; if ( st->nb_frames && st->duration ) { // compute the average frame duration from the total number // of frames & the total duration. duration = ( (double)st->duration * (double)st->time_base.num ) / ( (double)st->nb_frames * (double)st->time_base.den ); } // Raw demuxers set a default fps of 25 and do not parse // a value from the container. So use the codec time_base // for raw demuxers. else if (ic->iformat->raw_codec_id == AV_CODEC_ID_NONE) { // 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 = NULL; if ( st->avg_frame_rate.den * 64LL > st->avg_frame_rate.num && st->avg_frame_rate.num > st->avg_frame_rate.den * 8LL ) { tb = &(st->avg_frame_rate); duration = (double)tb->den / (double)tb->num; } else if ( st->time_base.num * 64LL > st->time_base.den && st->time_base.den > st->time_base.num * 8LL ) { tb = &(st->time_base); duration = (double)tb->num / (double)tb->den; } } if ( !duration && pv->context->time_base.num * max_fps > pv->context->time_base.den && pv->context->time_base.den > pv->context->time_base.num * 8LL ) { duration = (double)pv->context->time_base.num / (double)pv->context->time_base.den; if ( pv->context->ticks_per_frame > 1 ) { // for ffmpeg 0.5 & later, the H.264 & MPEG-2 time base is // field rate rather than frame rate so convert back to frames. duration *= pv->context->ticks_per_frame; } } } else { if ( pv->context->time_base.num * max_fps > pv->context->time_base.den && pv->context->time_base.den > pv->context->time_base.num * 8LL ) { duration = (double)pv->context->time_base.num / (double)pv->context->time_base.den; if ( pv->context->ticks_per_frame > 1 ) { // for ffmpeg 0.5 & later, the H.264 & MPEG-2 time base is // field rate rather than frame rate so convert back to frames. duration *= pv->context->ticks_per_frame; } } } if ( duration == 0 ) { // No valid timing info found in the stream, so pick some value duration = 1001. / 24000.; } pv->duration = duration * 90000.; pv->field_duration = pv->duration; if ( pv->context->ticks_per_frame > 1 ) { pv->field_duration /= pv->context->ticks_per_frame; } } static int get_color_prim(int color_primaries, hb_geometry_t geometry, hb_rational_t rate) { switch (color_primaries) { case AVCOL_PRI_BT709: return HB_COLR_PRI_BT709; case AVCOL_PRI_BT470M: return HB_COLR_PRI_BT470M; case AVCOL_PRI_BT470BG: return HB_COLR_PRI_EBUTECH; case AVCOL_PRI_SMPTE170M: case AVCOL_PRI_SMPTE240M: return HB_COLR_PRI_SMPTEC; case AVCOL_PRI_FILM: return HB_COLR_PRI_FILM; case AVCOL_PRI_SMPTE428: return HB_COLR_PRI_SMPTE428; case AVCOL_PRI_SMPTE431: return HB_COLR_PRI_SMPTE431; case AVCOL_PRI_SMPTE432: return HB_COLR_PRI_SMPTE432; case AVCOL_PRI_JEDEC_P22: return HB_COLR_PRI_JEDEC_P22; case AVCOL_PRI_BT2020: return HB_COLR_PRI_BT2020; default: { if ((geometry.width >= 1280 || geometry.height >= 720)|| (geometry.width > 720 && geometry.height > 576 )) // ITU BT.709 HD content return HB_COLR_PRI_BT709; else if (rate.den == 1080000) // ITU BT.601 DVD or SD TV content (PAL) return HB_COLR_PRI_EBUTECH; else // ITU BT.601 DVD or SD TV content (NTSC) return HB_COLR_PRI_SMPTEC; } } } static int get_color_transfer(int color_trc) { switch (color_trc) { case AVCOL_TRC_GAMMA22: return HB_COLR_TRA_GAMMA22; case AVCOL_TRC_GAMMA28: return HB_COLR_TRA_GAMMA28; case AVCOL_TRC_SMPTE170M: return HB_COLR_TRA_SMPTE170M; case AVCOL_TRC_LINEAR: return HB_COLR_TRA_LINEAR; case AVCOL_TRC_LOG: return HB_COLR_TRA_LOG; case AVCOL_TRC_LOG_SQRT: return HB_COLR_TRA_LOG_SQRT; case AVCOL_TRC_IEC61966_2_4: return HB_COLR_TRA_IEC61966_2_4; case AVCOL_TRC_BT1361_ECG: return HB_COLR_TRA_BT1361_ECG; case AVCOL_TRC_IEC61966_2_1: return HB_COLR_TRA_IEC61966_2_1; case AVCOL_TRC_SMPTE240M: return HB_COLR_TRA_SMPTE240M; case AVCOL_TRC_SMPTEST2084: return HB_COLR_TRA_SMPTEST2084; case AVCOL_TRC_ARIB_STD_B67: return HB_COLR_TRA_ARIB_STD_B67; case AVCOL_TRC_BT2020_10: return HB_COLR_TRA_BT2020_10; case AVCOL_TRC_BT2020_12: return HB_COLR_TRA_BT2020_12; default: // ITU BT.601, BT.709, anything else return HB_COLR_TRA_BT709; } } static int get_color_matrix(int colorspace, hb_geometry_t geometry) { switch (colorspace) { case AVCOL_SPC_RGB: return HB_COLR_MAT_RGB; case AVCOL_SPC_BT709: return HB_COLR_MAT_BT709; case AVCOL_SPC_FCC: return HB_COLR_MAT_FCC; case AVCOL_SPC_BT470BG: return HB_COLR_MAT_BT470BG; case AVCOL_SPC_SMPTE170M: return HB_COLR_MAT_SMPTE170M; case AVCOL_SPC_SMPTE240M: return HB_COLR_MAT_SMPTE240M; case AVCOL_SPC_YCGCO: return HB_COLR_MAT_YCGCO; case AVCOL_SPC_BT2020_NCL: return HB_COLR_MAT_BT2020_NCL; case AVCOL_SPC_BT2020_CL: return HB_COLR_MAT_BT2020_CL; case AVCOL_SPC_CHROMA_DERIVED_NCL: return HB_COLR_MAT_CD_NCL; case AVCOL_SPC_CHROMA_DERIVED_CL: return HB_COLR_MAT_CD_CL; case AVCOL_SPC_ICTCP: return HB_COLR_MAT_ICTCP; default: { if ((geometry.width >= 1280 || geometry.height >= 720)|| (geometry.width > 720 && geometry.height > 576 )) // ITU BT.709 HD content return HB_COLR_MAT_BT709; else // ITU BT.601 DVD or SD TV content (PAL) // ITU BT.601 DVD or SD TV content (NTSC) return HB_COLR_MAT_SMPTE170M; } } } static int decavcodecvInfo( hb_work_object_t *w, hb_work_info_t *info ) { hb_work_private_t *pv = w->private_data; int clock_min, clock_max, clock; hb_video_framerate_get_limits(&clock_min, &clock_max, &clock); memset( info, 0, sizeof(*info) ); if (pv->context == NULL || pv->context->codec == NULL) return 0; info->bitrate = pv->context->bit_rate; if (w->title->rotation == HB_ROTATION_90 || w->title->rotation == HB_ROTATION_270) { // HandBrake's video pipeline uses yuv420 color. This means all // dimensions must be even. So we must adjust the dimensions // of incoming video if not even. info->geometry.width = pv->context->height & ~1; info->geometry.height = pv->context->width & ~1; info->geometry.par.num = pv->context->sample_aspect_ratio.den; info->geometry.par.den = pv->context->sample_aspect_ratio.num; } else { // HandBrake's video pipeline uses yuv420 color. This means all // dimensions must be even. So we must adjust the dimensions // of incoming video if not even. info->geometry.width = pv->context->width & ~1; info->geometry.height = pv->context->height & ~1; info->geometry.par.num = pv->context->sample_aspect_ratio.num; info->geometry.par.den = pv->context->sample_aspect_ratio.den; } compute_frame_duration( pv ); info->rate.num = clock; info->rate.den = pv->duration * (clock / 90000.); info->profile = pv->context->profile; info->level = pv->context->level; info->name = pv->context->codec->name; info->pix_fmt = pv->context->pix_fmt; info->color_prim = get_color_prim(pv->context->color_primaries, info->geometry, info->rate); info->color_transfer = get_color_transfer(pv->context->color_trc); info->color_matrix = get_color_matrix(pv->context->colorspace, info->geometry); info->color_range = pv->context->color_range; info->video_decode_support = HB_DECODE_SUPPORT_SW; #if HB_PROJECT_FEATURE_QSV if (avcodec_find_decoder_by_name(hb_qsv_decode_get_codec_name(pv->context->codec_id))) { switch (pv->context->codec_id) { case AV_CODEC_ID_HEVC: case AV_CODEC_ID_H264: if (pv->context->pix_fmt == AV_PIX_FMT_YUV420P || pv->context->pix_fmt == AV_PIX_FMT_YUVJ420P || pv->context->pix_fmt == AV_PIX_FMT_YUV420P10LE) { info->video_decode_support |= HB_DECODE_SUPPORT_QSV; } break; default: break; } } #endif return 1; } static int decavcodecvBSInfo( hb_work_object_t *w, const hb_buffer_t *buf, hb_work_info_t *info ) { return 0; } static void decavcodecvFlush( hb_work_object_t *w ) { hb_work_private_t *pv = w->private_data; if (pv->context != NULL && pv->context->codec != NULL) { hb_buffer_list_close(&pv->list); if ( pv->title->opaque_priv == NULL ) { pv->video_codec_opened = 0; hb_avcodec_free_context(&pv->context); if ( pv->parser ) { av_parser_close(pv->parser); } pv->parser = av_parser_init( w->codec_param ); pv->context = avcodec_alloc_context3( pv->codec ); } else { avcodec_flush_buffers( pv->context ); } } } hb_work_object_t hb_decavcodecv = { .id = WORK_DECAVCODECV, .name = "Video decoder (libavcodec)", .init = decavcodecvInit, .work = decavcodecvWork, .close = decavcodecClose, .flush = decavcodecvFlush, .info = decavcodecvInfo, .bsinfo = decavcodecvBSInfo }; static void decodeAudio(hb_work_private_t *pv, packet_info_t * packet_info) { AVCodecContext * context = pv->context; AVPacket avp; int ret; // libav does not supply timestamps for wmapro audio (possibly others) // if there is an input timestamp, initialize next_pts if (pv->next_pts == (int64_t)AV_NOPTS_VALUE && packet_info != NULL && packet_info->pts != AV_NOPTS_VALUE) { pv->next_pts = packet_info->pts; } av_init_packet(&avp); if (packet_info != NULL) { avp.data = packet_info->data; avp.size = packet_info->size; avp.pts = packet_info->pts; avp.dts = AV_NOPTS_VALUE; avp.flags |= packet_info->discard * AV_PKT_FLAG_DISCARD; } else { avp.data = NULL; avp.size = 0; } ret = avcodec_send_packet(context, &avp); if (ret < 0 && ret != AVERROR_EOF) { av_packet_unref(&avp); return; } do { ret = avcodec_receive_frame(context, pv->frame); if (ret < 0 && ret != AVERROR(EAGAIN) && ret != AVERROR_EOF) { ++pv->decode_errors; } if (ret < 0) { break; } hb_buffer_t * out; int samplerate; // libavcoded doesn't yet consistently set frame->sample_rate if (pv->frame->sample_rate != 0) { samplerate = pv->frame->sample_rate; } else { samplerate = context->sample_rate; } pv->duration = (90000. * pv->frame->nb_samples / samplerate); int64_t pts = pv->frame->pts; double duration = pv->duration; if (pv->audio->config.out.codec & HB_ACODEC_PASS_FLAG) { // Note that even though we are doing passthru, we had to decode // so that we know the stop time and the pts of the next audio // packet. out = hb_buffer_init(avp.size); memcpy(out->data, avp.data, avp.size); } else { AVFrameSideData *side_data; uint64_t channel_layout; if ((side_data = av_frame_get_side_data(pv->frame, AV_FRAME_DATA_DOWNMIX_INFO)) != NULL) { double surround_mix_level, center_mix_level; AVDownmixInfo * downmix_info; downmix_info = (AVDownmixInfo*)side_data->data; if (pv->audio->config.out.mixdown == HB_AMIXDOWN_DOLBY || pv->audio->config.out.mixdown == HB_AMIXDOWN_DOLBYPLII) { surround_mix_level = downmix_info->surround_mix_level_ltrt; center_mix_level = downmix_info->center_mix_level_ltrt; } else { surround_mix_level = downmix_info->surround_mix_level; center_mix_level = downmix_info->center_mix_level; } hb_audio_resample_set_mix_levels(pv->resample, surround_mix_level, center_mix_level, downmix_info->lfe_mix_level); } channel_layout = pv->frame->channel_layout; if (channel_layout == 0) { channel_layout = av_get_default_channel_layout( pv->frame->channels); } hb_audio_resample_set_channel_layout(pv->resample, channel_layout); hb_audio_resample_set_sample_fmt(pv->resample, pv->frame->format); hb_audio_resample_set_sample_rate(pv->resample, pv->frame->sample_rate); if (hb_audio_resample_update(pv->resample)) { hb_log("decavcodec: hb_audio_resample_update() failed"); av_frame_unref(pv->frame); av_packet_unref(&avp); return; } out = hb_audio_resample(pv->resample, (const uint8_t **)pv->frame->extended_data, pv->frame->nb_samples); if (out != NULL && pv->drop_samples > 0) { /* drop audio samples that are part of the encoder delay */ int channels = hb_mixdown_get_discrete_channel_count( pv->audio->config.out.mixdown); int sample_size = channels * sizeof(float); int samples = out->size / sample_size; if (samples <= pv->drop_samples) { hb_buffer_close(&out); pv->drop_samples -= samples; } else { int size = pv->drop_samples * sample_size; double drop_duration = pv->drop_samples * 90000L / pv->audio->config.out.samplerate; memmove(out->data, out->data + size, out->size - size); out->size -= size; pts += drop_duration; duration -= drop_duration; pv->drop_samples = 0; } } } if (out != NULL) { out->s.scr_sequence = packet_info->scr_sequence; out->s.start = pts; out->s.duration = duration; if (out->s.start == AV_NOPTS_VALUE) { out->s.start = pv->next_pts; } else { pv->next_pts = out->s.start; } if (pv->next_pts != (int64_t)AV_NOPTS_VALUE) { pv->next_pts += pv->duration; out->s.stop = pv->next_pts; } hb_buffer_list_append(&pv->list, out); } av_frame_unref(pv->frame); ++pv->nframes; } while (ret >= 0); av_packet_unref(&avp); }