/* * Copyright (C) 2015-17 Espen Jurgensen * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ #ifdef HAVE_CONFIG_H # include #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "logger.h" #include "conffile.h" #include "db.h" #include "avio_evbuffer.h" #include "misc.h" #include "transcode.h" // Interval between ICY metadata checks for streams, in seconds #define METADATA_ICY_INTERVAL 5 // Maximum number of streams in a file that we will accept #define MAX_STREAMS 64 // Maximum number of times we retry when we encounter bad packets #define MAX_BAD_PACKETS 5 // How long to wait (in microsec) before interrupting av_read_frame #define READ_TIMEOUT 30000000 static const char *default_codecs = "mpeg,wav"; static const char *roku_codecs = "mpeg,mp4a,wma,wav"; static const char *itunes_codecs = "mpeg,mp4a,mp4v,alac,wav"; // Used for passing errors to DPRINTF (can't count on av_err2str being present) static char errbuf[64]; // The settings struct will be filled out based on the profile enum struct settings_ctx { bool encode_video; bool encode_audio; // Silence some log messages bool silent; // Output format (for the muxer) const char *format; // Input format (for the demuxer) const char *in_format; // Audio settings enum AVCodecID audio_codec; int sample_rate; uint64_t channel_layout; int channels; int bit_rate; enum AVSampleFormat sample_format; bool wavheader; bool icy; // Video settings enum AVCodecID video_codec; const char *video_codec_name; enum AVPixelFormat pix_fmt; int height; int width; }; struct stream_ctx { AVStream *stream; AVCodecContext *codec; AVFilterContext *buffersink_ctx; AVFilterContext *buffersrc_ctx; AVFilterGraph *filter_graph; // Used for seeking int64_t prev_pts; int64_t offset_pts; }; struct decode_ctx { // Settings derived from the profile struct settings_ctx settings; // Input format context AVFormatContext *ifmt_ctx; // IO Context for non-file input AVIOContext *avio; // Stream and decoder data struct stream_ctx audio_stream; struct stream_ctx video_stream; // Duration (used to make wav header) uint32_t duration; // Data kind (used to determine if ICY metadata is relevant to look for) enum data_kind data_kind; // Set to true if we just seeked bool resume; // Set to true if we have reached eof bool eof; // Set to true if avcodec_receive_frame() gave us a frame bool got_frame; // Contains the most recent packet from av_read_frame() AVPacket *packet; // Contains the most recent frame from avcodec_receive_frame() AVFrame *decoded_frame; // Used to measure if av_read_frame is taking too long int64_t timestamp; }; struct encode_ctx { // Settings derived from the profile struct settings_ctx settings; // Output format context AVFormatContext *ofmt_ctx; // Stream, filter and decoder data struct stream_ctx audio_stream; struct stream_ctx video_stream; // The ffmpeg muxer writes to this buffer using the avio_evbuffer interface struct evbuffer *obuf; // Contains the most recent packet from av_buffersink_get_frame() AVFrame *filt_frame; // Contains the most recent packet from avcodec_receive_packet() AVPacket *encoded_pkt; // How many output bytes we have processed in total off_t total_bytes; // Used to check for ICY metadata changes at certain intervals uint32_t icy_interval; uint32_t icy_hash; // WAV header uint8_t header[44]; }; /* -------------------------- PROFILE CONFIGURATION ------------------------ */ static int init_settings(struct settings_ctx *settings, enum transcode_profile profile, struct media_quality *quality) { memset(settings, 0, sizeof(struct settings_ctx)); switch (profile) { case XCODE_PCM_NATIVE: // Sample rate and bit depth determined by source settings->encode_audio = 1; settings->icy = 1; break; case XCODE_PCM16_HEADER: settings->wavheader = 1; case XCODE_PCM16: settings->encode_audio = 1; settings->format = "s16le"; settings->audio_codec = AV_CODEC_ID_PCM_S16LE; settings->sample_format = AV_SAMPLE_FMT_S16; break; case XCODE_PCM24: settings->encode_audio = 1; settings->format = "s24le"; settings->audio_codec = AV_CODEC_ID_PCM_S24LE; settings->sample_format = AV_SAMPLE_FMT_S32; break; case XCODE_PCM32: settings->encode_audio = 1; settings->format = "s32le"; settings->audio_codec = AV_CODEC_ID_PCM_S32LE; settings->sample_format = AV_SAMPLE_FMT_S32; break; case XCODE_MP3: settings->encode_audio = 1; settings->format = "mp3"; settings->audio_codec = AV_CODEC_ID_MP3; settings->sample_format = AV_SAMPLE_FMT_S16P; break; case XCODE_OPUS: settings->encode_audio = 1; settings->format = "data"; // Means we get the raw packet from the encoder, no muxing settings->audio_codec = AV_CODEC_ID_OPUS; settings->sample_format = AV_SAMPLE_FMT_S16; // Only libopus support break; case XCODE_JPEG: settings->encode_video = 1; settings->silent = 1; // With ffmpeg 4.3 (> libavformet 58.29) "image2" only works for actual file // output. It's possible we should have used "image2pipe" all along, but since // "image2" has been working we only replace it going forward. #if (LIBAVFORMAT_VERSION_MAJOR > 58) || ((LIBAVFORMAT_VERSION_MAJOR == 58) && (LIBAVFORMAT_VERSION_MINOR > 29)) settings->format = "image2pipe"; #else settings->format = "image2"; #endif settings->in_format = "mjpeg"; settings->pix_fmt = AV_PIX_FMT_YUVJ420P; settings->video_codec = AV_CODEC_ID_MJPEG; break; case XCODE_PNG: settings->encode_video = 1; settings->silent = 1; // See explanation above #if (LIBAVFORMAT_VERSION_MAJOR > 58) || ((LIBAVFORMAT_VERSION_MAJOR == 58) && (LIBAVFORMAT_VERSION_MINOR > 29)) settings->format = "image2pipe"; #else settings->format = "image2"; #endif settings->pix_fmt = AV_PIX_FMT_RGB24; settings->video_codec = AV_CODEC_ID_PNG; break; case XCODE_VP8: settings->encode_video = 1; settings->silent = 1; // See explanation above #if (LIBAVFORMAT_VERSION_MAJOR > 58) || ((LIBAVFORMAT_VERSION_MAJOR == 58) && (LIBAVFORMAT_VERSION_MINOR > 29)) settings->format = "image2pipe"; #else settings->format = "image2"; #endif settings->pix_fmt = AV_PIX_FMT_YUVJ420P; settings->video_codec = AV_CODEC_ID_VP8; break; default: DPRINTF(E_LOG, L_XCODE, "Bug! Unknown transcoding profile\n"); return -1; } if (quality && quality->sample_rate) { settings->sample_rate = quality->sample_rate; } if (quality && quality->channels) { settings->channels = quality->channels; settings->channel_layout = av_get_default_channel_layout(quality->channels); } if (quality && quality->bit_rate) { settings->bit_rate = quality->bit_rate; } if (quality && quality->bits_per_sample && (quality->bits_per_sample != 8 * av_get_bytes_per_sample(settings->sample_format))) { DPRINTF(E_LOG, L_XCODE, "Bug! Mismatch between profile (%d bps) and media quality (%d bps)\n", 8 * av_get_bytes_per_sample(settings->sample_format), quality->bits_per_sample); return -1; } return 0; } static void stream_settings_set(struct stream_ctx *s, struct settings_ctx *settings, enum AVMediaType type) { if (type == AVMEDIA_TYPE_AUDIO) { s->codec->sample_rate = settings->sample_rate; s->codec->channel_layout = settings->channel_layout; s->codec->channels = settings->channels; s->codec->sample_fmt = settings->sample_format; s->codec->time_base = (AVRational){1, settings->sample_rate}; s->codec->bit_rate = settings->bit_rate; } else if (type == AVMEDIA_TYPE_VIDEO) { s->codec->height = settings->height; s->codec->width = settings->width; s->codec->pix_fmt = settings->pix_fmt; s->codec->time_base = (AVRational){1, 25}; } } /* -------------------------------- HELPERS -------------------------------- */ static enum AVSampleFormat bitdepth2format(int bits_per_sample) { if (bits_per_sample == 16) return AV_SAMPLE_FMT_S16; else if (bits_per_sample == 24) return AV_SAMPLE_FMT_S32; else if (bits_per_sample == 32) return AV_SAMPLE_FMT_S32; else return AV_SAMPLE_FMT_NONE; } static inline char * err2str(int errnum) { av_strerror(errnum, errbuf, sizeof(errbuf)); return errbuf; } static inline void add_le16(uint8_t *dst, uint16_t val) { dst[0] = val & 0xff; dst[1] = (val >> 8) & 0xff; } static inline void add_le32(uint8_t *dst, uint32_t val) { dst[0] = val & 0xff; dst[1] = (val >> 8) & 0xff; dst[2] = (val >> 16) & 0xff; dst[3] = (val >> 24) & 0xff; } static void make_wav_header(struct encode_ctx *ctx, struct decode_ctx *src_ctx, off_t *est_size) { uint32_t wav_len; int duration; int bps; if (src_ctx->duration) duration = src_ctx->duration; else duration = 3 * 60 * 1000; /* 3 minutes, in ms */ bps = av_get_bytes_per_sample(ctx->settings.sample_format); wav_len = ctx->settings.channels * bps * ctx->settings.sample_rate * (duration / 1000); if (est_size) *est_size = wav_len + sizeof(ctx->header); memcpy(ctx->header, "RIFF", 4); add_le32(ctx->header + 4, 36 + wav_len); memcpy(ctx->header + 8, "WAVEfmt ", 8); add_le32(ctx->header + 16, 16); add_le16(ctx->header + 20, 1); add_le16(ctx->header + 22, ctx->settings.channels); /* channels */ add_le32(ctx->header + 24, ctx->settings.sample_rate); /* samplerate */ add_le32(ctx->header + 28, ctx->settings.sample_rate * ctx->settings.channels * bps); /* byte rate */ add_le16(ctx->header + 32, ctx->settings.channels * bps); /* block align */ add_le16(ctx->header + 34, 8 * bps); /* bits per sample */ memcpy(ctx->header + 36, "data", 4); add_le32(ctx->header + 40, wav_len); } /* * Checks if this stream index is one that we are decoding * * @in ctx Decode context * @in stream_index Index of stream to check * @return Type of stream, unknown if we are not decoding the stream */ static enum AVMediaType stream_find(struct decode_ctx *ctx, unsigned int stream_index) { if (ctx->audio_stream.stream && (stream_index == ctx->audio_stream.stream->index)) return AVMEDIA_TYPE_AUDIO; if (ctx->video_stream.stream && (stream_index == ctx->video_stream.stream->index)) return AVMEDIA_TYPE_VIDEO; return AVMEDIA_TYPE_UNKNOWN; } /* * Adds a stream to an output * * @out ctx A pre-allocated stream ctx where we save stream and codec info * @in output Output to add the stream to * @in codec_id What kind of codec should we use * @return Negative on failure, otherwise zero */ static int stream_add(struct encode_ctx *ctx, struct stream_ctx *s, enum AVCodecID codec_id) { const AVCodecDescriptor *codec_desc; AVCodec *encoder; AVDictionary *options = NULL; int ret; codec_desc = avcodec_descriptor_get(codec_id); if (!codec_desc) { DPRINTF(E_LOG, L_XCODE, "Invalid codec ID (%d)\n", codec_id); return -1; } encoder = avcodec_find_encoder(codec_id); if (!encoder) { DPRINTF(E_LOG, L_XCODE, "Necessary encoder (%s) not found\n", codec_desc->name); return -1; } CHECK_NULL(L_XCODE, s->stream = avformat_new_stream(ctx->ofmt_ctx, NULL)); CHECK_NULL(L_XCODE, s->codec = avcodec_alloc_context3(encoder)); stream_settings_set(s, &ctx->settings, encoder->type); if (!s->codec->pix_fmt) { s->codec->pix_fmt = avcodec_default_get_format(s->codec, encoder->pix_fmts); DPRINTF(E_DBG, L_XCODE, "Pixel format set to %s (encoder is %s)\n", av_get_pix_fmt_name(s->codec->pix_fmt), codec_desc->name); } if (ctx->ofmt_ctx->oformat->flags & AVFMT_GLOBALHEADER) s->codec->flags |= AV_CODEC_FLAG_GLOBAL_HEADER; // With ffmpeg 3.4, jpeg encoding with optimal huffman tables will segfault, see issue #502 if (codec_id == AV_CODEC_ID_MJPEG) av_dict_set(&options, "huffman", "default", 0); // 20 ms frames is the current ffmpeg default, but we set it anyway, so that // we don't risk issues if future versions change the default (it would become // an issue because outputs/cast.c relies on 20 ms frames) if (codec_id == AV_CODEC_ID_OPUS) av_dict_set(&options, "frame_duration", "20", 0); ret = avcodec_open2(s->codec, NULL, &options); if (ret < 0) { DPRINTF(E_LOG, L_XCODE, "Cannot open encoder (%s): %s\n", codec_desc->name, err2str(ret)); avcodec_free_context(&s->codec); return -1; } // Copy the codec parameters we just set to the stream, so the muxer knows them ret = avcodec_parameters_from_context(s->stream->codecpar, s->codec); if (ret < 0) { DPRINTF(E_LOG, L_XCODE, "Cannot copy stream parameters (%s): %s\n", codec_desc->name, err2str(ret)); avcodec_free_context(&s->codec); return -1; } return 0; } /* * Called by libavformat while demuxing. Used to interrupt/unblock av_read_frame * in case a source (especially a network stream) becomes unavailable. * * @in arg Will point to the decode context * @return Non-zero if av_read_frame should be interrupted */ static int decode_interrupt_cb(void *arg) { struct decode_ctx *ctx; ctx = (struct decode_ctx *)arg; if (av_gettime() - ctx->timestamp > READ_TIMEOUT) { DPRINTF(E_LOG, L_XCODE, "Timeout while reading source (connection problem?)\n"); return 1; } return 0; } /* Will read the next packet from the source, unless we are resuming after a * seek in which case the most recent packet found by transcode_seek() will be * returned. The packet will be put in ctx->packet. * * @out type Media type of packet * @in ctx Decode context * @return 0 if OK, < 0 on error or end of file */ static int read_packet(enum AVMediaType *type, struct decode_ctx *dec_ctx) { int ret; // We just seeked, so transcode_seek() will have found a new ctx->packet and // we should just use start with that (if the stream is one are ok with) if (dec_ctx->resume) { dec_ctx->resume = 0; *type = stream_find(dec_ctx, dec_ctx->packet->stream_index); if (*type != AVMEDIA_TYPE_UNKNOWN) return 0; } do { dec_ctx->timestamp = av_gettime(); av_packet_unref(dec_ctx->packet); ret = av_read_frame(dec_ctx->ifmt_ctx, dec_ctx->packet); if (ret < 0) { DPRINTF(E_WARN, L_XCODE, "Could not read frame: %s\n", err2str(ret)); return ret; } *type = stream_find(dec_ctx, dec_ctx->packet->stream_index); } while (*type == AVMEDIA_TYPE_UNKNOWN); return 0; } // Prepares a packet from the encoder for muxing static void packet_prepare(AVPacket *pkt, struct stream_ctx *s) { pkt->stream_index = s->stream->index; // This "wonderful" peace of code makes sure that the timestamp always increases, // even if the user seeked backwards. The muxer will not accept non-increasing // timestamps. pkt->pts += s->offset_pts; if (pkt->pts < s->prev_pts) { s->offset_pts += s->prev_pts - pkt->pts; pkt->pts = s->prev_pts; } s->prev_pts = pkt->pts; pkt->dts = pkt->pts; //FIXME av_packet_rescale_ts(pkt, s->codec->time_base, s->stream->time_base); } /* * Part 4+5 of the conversion chain: read -> decode -> filter -> encode -> write * */ static int encode_write(struct encode_ctx *ctx, struct stream_ctx *s, AVFrame *filt_frame) { int ret; // If filt_frame is null then flushing will be initiated by the codec ret = avcodec_send_frame(s->codec, filt_frame); if (ret < 0) return ret; while (1) { ret = avcodec_receive_packet(s->codec, ctx->encoded_pkt); if (ret < 0) { if (ret == AVERROR(EAGAIN)) ret = 0; break; } packet_prepare(ctx->encoded_pkt, s); ret = av_interleaved_write_frame(ctx->ofmt_ctx, ctx->encoded_pkt); if (ret < 0) { DPRINTF(E_WARN, L_XCODE, "av_interleaved_write_frame() failed: %s\n", err2str(ret)); break; } } return ret; } /* * Part 3 of the conversion chain: read -> decode -> filter -> encode -> write * * transcode_encode() starts here since the caller already has a frame * */ static int filter_encode_write(struct encode_ctx *ctx, struct stream_ctx *s, AVFrame *frame) { int ret; // Push the decoded frame into the filtergraph if (frame) { ret = av_buffersrc_add_frame(s->buffersrc_ctx, frame); if (ret < 0) { DPRINTF(E_LOG, L_XCODE, "Error while feeding the filtergraph: %s\n", err2str(ret)); return -1; } } // Pull filtered frames from the filtergraph and pass to encoder while (1) { ret = av_buffersink_get_frame(s->buffersink_ctx, ctx->filt_frame); if (ret < 0) { if (!frame) // We are flushing ret = encode_write(ctx, s, NULL); else if (ret == AVERROR(EAGAIN)) ret = 0; break; } ret = encode_write(ctx, s, ctx->filt_frame); av_frame_unref(ctx->filt_frame); if (ret < 0) break; } return ret; } /* * Part 2 of the conversion chain: read -> decode -> filter -> encode -> write * * If there is no encode_ctx the chain will aborted here * */ static int decode_filter_encode_write(struct transcode_ctx *ctx, struct stream_ctx *s, AVPacket *pkt, enum AVMediaType type) { struct decode_ctx *dec_ctx = ctx->decode_ctx; struct stream_ctx *out_stream = NULL; int ret; ret = avcodec_send_packet(s->codec, pkt); if (ret < 0 && (ret != AVERROR_INVALIDDATA) && (ret != AVERROR(EAGAIN))) // We don't bail on invalid data, some streams work anyway { DPRINTF(E_LOG, L_XCODE, "Decoder error, avcodec_send_packet said '%s' (%d)\n", err2str(ret), ret); return ret; } if (ctx->encode_ctx) { if (type == AVMEDIA_TYPE_AUDIO) out_stream = &ctx->encode_ctx->audio_stream; else if (type == AVMEDIA_TYPE_VIDEO) out_stream = &ctx->encode_ctx->video_stream; else return -1; } while (1) { ret = avcodec_receive_frame(s->codec, dec_ctx->decoded_frame); if (ret < 0) { if (ret == AVERROR(EAGAIN)) ret = 0; else if (out_stream) ret = filter_encode_write(ctx->encode_ctx, out_stream, NULL); // Flush break; } dec_ctx->got_frame = 1; if (!out_stream) break; ret = filter_encode_write(ctx->encode_ctx, out_stream, dec_ctx->decoded_frame); if (ret < 0) break; } return ret; } /* * Part 1 of the conversion chain: read -> decode -> filter -> encode -> write * * Will read exactly one packet from the input and put it in the chain. You * cannot count on anything coming out of the other end from just one packet, * so you probably should loop when calling this and check the contents of * enc_ctx->obuf. * */ static int read_decode_filter_encode_write(struct transcode_ctx *ctx) { struct decode_ctx *dec_ctx = ctx->decode_ctx; enum AVMediaType type; int ret; ret = read_packet(&type, dec_ctx); if (ret < 0) { if (ret == AVERROR_EOF) dec_ctx->eof = 1; if (dec_ctx->audio_stream.stream) decode_filter_encode_write(ctx, &dec_ctx->audio_stream, NULL, AVMEDIA_TYPE_AUDIO); if (dec_ctx->video_stream.stream) decode_filter_encode_write(ctx, &dec_ctx->video_stream, NULL, AVMEDIA_TYPE_VIDEO); // Flush muxer if (ctx->encode_ctx) { av_interleaved_write_frame(ctx->encode_ctx->ofmt_ctx, NULL); av_write_trailer(ctx->encode_ctx->ofmt_ctx); } return ret; } if (type == AVMEDIA_TYPE_AUDIO) ret = decode_filter_encode_write(ctx, &dec_ctx->audio_stream, dec_ctx->packet, type); else if (type == AVMEDIA_TYPE_VIDEO) ret = decode_filter_encode_write(ctx, &dec_ctx->video_stream, dec_ctx->packet, type); return ret; } /* --------------------------- INPUT/OUTPUT INIT --------------------------- */ static AVCodecContext * open_decoder(unsigned int *stream_index, struct decode_ctx *ctx, enum AVMediaType type) { AVCodecContext *dec_ctx; AVCodec *decoder; int ret; ret = av_find_best_stream(ctx->ifmt_ctx, type, -1, -1, &decoder, 0); if ((ret < 0) || (!decoder)) { if (!ctx->settings.silent) DPRINTF(E_LOG, L_XCODE, "No stream data or decoder found: %s\n", err2str(ret)); return NULL; } *stream_index = (unsigned int)ret; CHECK_NULL(L_XCODE, dec_ctx = avcodec_alloc_context3(decoder)); // In open_filter() we need to tell the sample rate and format that the decoder // is giving us - however sample rate of dec_ctx will be 0 if we don't prime it // with the streams codecpar data. ret = avcodec_parameters_to_context(dec_ctx, ctx->ifmt_ctx->streams[*stream_index]->codecpar); if (ret < 0) { DPRINTF(E_LOG, L_XCODE, "Failed to copy codecpar for stream #%d: %s\n", *stream_index, err2str(ret)); avcodec_free_context(&dec_ctx); return NULL; } if (type == AVMEDIA_TYPE_AUDIO) { dec_ctx->request_sample_fmt = ctx->settings.sample_format; dec_ctx->request_channel_layout = ctx->settings.channel_layout; } ret = avcodec_open2(dec_ctx, NULL, NULL); if (ret < 0) { DPRINTF(E_LOG, L_XCODE, "Failed to open decoder for stream #%d: %s\n", *stream_index, err2str(ret)); avcodec_free_context(&dec_ctx); return NULL; } return dec_ctx; } static int open_input(struct decode_ctx *ctx, const char *path, struct evbuffer *evbuf) { AVDictionary *options = NULL; AVCodecContext *dec_ctx; AVInputFormat *ifmt; unsigned int stream_index; const char *user_agent; int ret; CHECK_NULL(L_XCODE, ctx->ifmt_ctx = avformat_alloc_context()); if (ctx->data_kind == DATA_KIND_HTTP) { // We take the chance of a small probe size to start quicker + search for // embedded artwork quicker. The standard probe size takes around 5 sec // for an mp3, while the below only takes around a second. ctx->ifmt_ctx->probesize = 65536; ctx->ifmt_ctx->format_probesize = 65536; av_dict_set(&options, "icy", "1", 0); user_agent = cfg_getstr(cfg_getsec(cfg, "general"), "user_agent"); av_dict_set(&options, "user_agent", user_agent, 0); av_dict_set(&options, "reconnect", "1", 0); // The below option disabled because it does not work with m3u8 streams, // see https://lists.ffmpeg.org/pipermail/ffmpeg-user/2018-September/041109.html // av_dict_set(&options, "reconnect_at_eof", "1", 0); av_dict_set(&options, "reconnect_streamed", "1", 0); } // TODO Newest versions of ffmpeg have timeout and reconnect options we should use ctx->ifmt_ctx->interrupt_callback.callback = decode_interrupt_cb; ctx->ifmt_ctx->interrupt_callback.opaque = ctx; ctx->timestamp = av_gettime(); if (evbuf) { ifmt = av_find_input_format(ctx->settings.in_format); if (!ifmt) { DPRINTF(E_LOG, L_XCODE, "Could not find input format: '%s'\n", ctx->settings.in_format); return -1; } CHECK_NULL(L_XCODE, ctx->avio = avio_input_evbuffer_open(evbuf)); ctx->ifmt_ctx->pb = ctx->avio; ret = avformat_open_input(&ctx->ifmt_ctx, NULL, ifmt, &options); } else { ret = avformat_open_input(&ctx->ifmt_ctx, path, NULL, &options); } if (options) av_dict_free(&options); if (ret < 0) { DPRINTF(E_LOG, L_XCODE, "Cannot open '%s': %s\n", path, err2str(ret)); return -1; } ret = avformat_find_stream_info(ctx->ifmt_ctx, NULL); if (ret < 0) { DPRINTF(E_LOG, L_XCODE, "Cannot find stream information: %s\n", err2str(ret)); goto out_fail; } if (ctx->ifmt_ctx->nb_streams > MAX_STREAMS) { DPRINTF(E_LOG, L_XCODE, "File '%s' has too many streams (%u)\n", path, ctx->ifmt_ctx->nb_streams); goto out_fail; } if (ctx->settings.encode_audio) { dec_ctx = open_decoder(&stream_index, ctx, AVMEDIA_TYPE_AUDIO); if (!dec_ctx) goto out_fail; ctx->audio_stream.codec = dec_ctx; ctx->audio_stream.stream = ctx->ifmt_ctx->streams[stream_index]; } if (ctx->settings.encode_video) { dec_ctx = open_decoder(&stream_index, ctx, AVMEDIA_TYPE_VIDEO); if (!dec_ctx) goto out_fail; ctx->video_stream.codec = dec_ctx; ctx->video_stream.stream = ctx->ifmt_ctx->streams[stream_index]; } return 0; out_fail: avio_evbuffer_close(ctx->avio); avcodec_free_context(&ctx->audio_stream.codec); avcodec_free_context(&ctx->video_stream.codec); avformat_close_input(&ctx->ifmt_ctx); return -1; } static void close_input(struct decode_ctx *ctx) { avio_evbuffer_close(ctx->avio); avcodec_free_context(&ctx->audio_stream.codec); avcodec_free_context(&ctx->video_stream.codec); avformat_close_input(&ctx->ifmt_ctx); } static int open_output(struct encode_ctx *ctx, struct decode_ctx *src_ctx) { AVOutputFormat *oformat; int ret; oformat = av_guess_format(ctx->settings.format, NULL, NULL); if (!oformat) { DPRINTF(E_LOG, L_XCODE, "ffmpeg/libav could not find the '%s' output format\n", ctx->settings.format); return -1; } // Clear AVFMT_NOFILE bit, it is not allowed as we will set our own AVIOContext oformat->flags &= ~AVFMT_NOFILE; CHECK_NULL(L_XCODE, ctx->ofmt_ctx = avformat_alloc_context()); ctx->ofmt_ctx->oformat = oformat; ctx->obuf = evbuffer_new(); if (!ctx->obuf) { DPRINTF(E_LOG, L_XCODE, "Could not create output evbuffer\n"); goto out_free_output; } ctx->ofmt_ctx->pb = avio_output_evbuffer_open(ctx->obuf); if (!ctx->ofmt_ctx->pb) { DPRINTF(E_LOG, L_XCODE, "Could not create output avio pb\n"); goto out_free_evbuf; } if (ctx->settings.encode_audio) { ret = stream_add(ctx, &ctx->audio_stream, ctx->settings.audio_codec); if (ret < 0) goto out_free_streams; } if (ctx->settings.encode_video) { ret = stream_add(ctx, &ctx->video_stream, ctx->settings.video_codec); if (ret < 0) goto out_free_streams; } // Notice, this will not write WAV header (so we do that manually) ret = avformat_write_header(ctx->ofmt_ctx, NULL); if (ret < 0) { DPRINTF(E_LOG, L_XCODE, "Error writing header to output buffer: %s\n", err2str(ret)); goto out_free_streams; } if (ctx->settings.wavheader) { evbuffer_add(ctx->obuf, ctx->header, sizeof(ctx->header)); } return 0; out_free_streams: avcodec_free_context(&ctx->audio_stream.codec); avcodec_free_context(&ctx->video_stream.codec); avio_evbuffer_close(ctx->ofmt_ctx->pb); out_free_evbuf: evbuffer_free(ctx->obuf); out_free_output: avformat_free_context(ctx->ofmt_ctx); return -1; } static void close_output(struct encode_ctx *ctx) { avcodec_free_context(&ctx->audio_stream.codec); avcodec_free_context(&ctx->video_stream.codec); avio_evbuffer_close(ctx->ofmt_ctx->pb); evbuffer_free(ctx->obuf); avformat_free_context(ctx->ofmt_ctx); } static int open_filter(struct stream_ctx *out_stream, struct stream_ctx *in_stream) { const AVFilter *buffersrc; const AVFilter *format; const AVFilter *scale; const AVFilter *buffersink; AVFilterContext *buffersrc_ctx; AVFilterContext *format_ctx; AVFilterContext *scale_ctx; AVFilterContext *buffersink_ctx; AVFilterGraph *filter_graph; char args[512]; int ret; CHECK_NULL(L_XCODE, filter_graph = avfilter_graph_alloc()); if (in_stream->codec->codec_type == AVMEDIA_TYPE_AUDIO) { buffersrc = avfilter_get_by_name("abuffer"); format = avfilter_get_by_name("aformat"); buffersink = avfilter_get_by_name("abuffersink"); if (!buffersrc || !format || !buffersink) { DPRINTF(E_LOG, L_XCODE, "Filtering source, format or sink element not found\n"); goto out_fail; } if (!in_stream->codec->channel_layout) in_stream->codec->channel_layout = av_get_default_channel_layout(in_stream->codec->channels); snprintf(args, sizeof(args), "time_base=%d/%d:sample_rate=%d:sample_fmt=%s:channel_layout=0x%"PRIx64, in_stream->stream->time_base.num, in_stream->stream->time_base.den, in_stream->codec->sample_rate, av_get_sample_fmt_name(in_stream->codec->sample_fmt), in_stream->codec->channel_layout); ret = avfilter_graph_create_filter(&buffersrc_ctx, buffersrc, "in", args, NULL, filter_graph); if (ret < 0) { DPRINTF(E_LOG, L_XCODE, "Cannot create audio buffer source (%s): %s\n", args, err2str(ret)); goto out_fail; } DPRINTF(E_DBG, L_XCODE, "Created 'in' filter: %s\n", args); // For some AIFF files, ffmpeg (3.4.6) will not give us a channel_layout (bug in ffmpeg?) if (!out_stream->codec->channel_layout) out_stream->codec->channel_layout = av_get_default_channel_layout(out_stream->codec->channels); snprintf(args, sizeof(args), "sample_fmts=%s:sample_rates=%d:channel_layouts=0x%"PRIx64, av_get_sample_fmt_name(out_stream->codec->sample_fmt), out_stream->codec->sample_rate, out_stream->codec->channel_layout); ret = avfilter_graph_create_filter(&format_ctx, format, "format", args, NULL, filter_graph); if (ret < 0) { DPRINTF(E_LOG, L_XCODE, "Cannot create audio format filter (%s): %s\n", args, err2str(ret)); goto out_fail; } DPRINTF(E_DBG, L_XCODE, "Created 'format' filter: %s\n", args); ret = avfilter_graph_create_filter(&buffersink_ctx, buffersink, "out", NULL, NULL, filter_graph); if (ret < 0) { DPRINTF(E_LOG, L_XCODE, "Cannot create audio buffer sink: %s\n", err2str(ret)); goto out_fail; } if ( (ret = avfilter_link(buffersrc_ctx, 0, format_ctx, 0)) < 0 || (ret = avfilter_link(format_ctx, 0, buffersink_ctx, 0)) < 0 ) { DPRINTF(E_LOG, L_XCODE, "Error connecting audio filters: %s\n", err2str(ret)); goto out_fail; } } else if (in_stream->codec->codec_type == AVMEDIA_TYPE_VIDEO) { buffersrc = avfilter_get_by_name("buffer"); format = avfilter_get_by_name("format"); scale = avfilter_get_by_name("scale"); buffersink = avfilter_get_by_name("buffersink"); if (!buffersrc || !format || !buffersink) { DPRINTF(E_LOG, L_XCODE, "Filtering source, format, scale or sink element not found\n"); goto out_fail; } snprintf(args, sizeof(args), "width=%d:height=%d:pix_fmt=%s:time_base=%d/%d:sar=%d/%d", in_stream->codec->width, in_stream->codec->height, av_get_pix_fmt_name(in_stream->codec->pix_fmt), in_stream->stream->time_base.num, in_stream->stream->time_base.den, in_stream->codec->sample_aspect_ratio.num, in_stream->codec->sample_aspect_ratio.den); ret = avfilter_graph_create_filter(&buffersrc_ctx, buffersrc, "in", args, NULL, filter_graph); if (ret < 0) { DPRINTF(E_LOG, L_XCODE, "Cannot create buffer source (%s): %s\n", args, err2str(ret)); goto out_fail; } snprintf(args, sizeof(args), "pix_fmts=%s", av_get_pix_fmt_name(out_stream->codec->pix_fmt)); ret = avfilter_graph_create_filter(&format_ctx, format, "format", args, NULL, filter_graph); if (ret < 0) { DPRINTF(E_LOG, L_XCODE, "Cannot create format filter (%s): %s\n", args, err2str(ret)); goto out_fail; } snprintf(args, sizeof(args), "w=%d:h=%d", out_stream->codec->width, out_stream->codec->height); ret = avfilter_graph_create_filter(&scale_ctx, scale, "scale", args, NULL, filter_graph); if (ret < 0) { DPRINTF(E_LOG, L_XCODE, "Cannot create scale filter (%s): %s\n", args, err2str(ret)); goto out_fail; } ret = avfilter_graph_create_filter(&buffersink_ctx, buffersink, "out", NULL, NULL, filter_graph); if (ret < 0) { DPRINTF(E_LOG, L_XCODE, "Cannot create buffer sink: %s\n", err2str(ret)); goto out_fail; } if ( (ret = avfilter_link(buffersrc_ctx, 0, format_ctx, 0)) < 0 || (ret = avfilter_link(format_ctx, 0, scale_ctx, 0)) < 0 || (ret = avfilter_link(scale_ctx, 0, buffersink_ctx, 0)) < 0 ) { DPRINTF(E_LOG, L_XCODE, "Error connecting video filters: %s\n", err2str(ret)); goto out_fail; } } else { DPRINTF(E_LOG, L_XCODE, "Bug! Unknown type passed to filter graph init\n"); goto out_fail; } ret = avfilter_graph_config(filter_graph, NULL); if (ret < 0) goto out_fail; /* Fill filtering context */ out_stream->buffersrc_ctx = buffersrc_ctx; out_stream->buffersink_ctx = buffersink_ctx; out_stream->filter_graph = filter_graph; return 0; out_fail: avfilter_graph_free(&filter_graph); return -1; } static int open_filters(struct encode_ctx *ctx, struct decode_ctx *src_ctx) { int ret; if (ctx->settings.encode_audio) { ret = open_filter(&ctx->audio_stream, &src_ctx->audio_stream); if (ret < 0) goto out_fail; } if (ctx->settings.encode_video) { ret = open_filter(&ctx->video_stream, &src_ctx->video_stream); if (ret < 0) goto out_fail; } return 0; out_fail: avfilter_graph_free(&ctx->audio_stream.filter_graph); avfilter_graph_free(&ctx->video_stream.filter_graph); return -1; } static void close_filters(struct encode_ctx *ctx) { avfilter_graph_free(&ctx->audio_stream.filter_graph); avfilter_graph_free(&ctx->video_stream.filter_graph); } /* ----------------------------- TRANSCODE API ----------------------------- */ /* Setup */ struct decode_ctx * transcode_decode_setup(enum transcode_profile profile, struct media_quality *quality, enum data_kind data_kind, const char *path, struct evbuffer *evbuf, uint32_t song_length) { struct decode_ctx *ctx; CHECK_NULL(L_XCODE, ctx = calloc(1, sizeof(struct decode_ctx))); CHECK_NULL(L_XCODE, ctx->decoded_frame = av_frame_alloc()); CHECK_NULL(L_XCODE, ctx->packet = av_packet_alloc()); ctx->duration = song_length; ctx->data_kind = data_kind; if ((init_settings(&ctx->settings, profile, quality) < 0) || (open_input(ctx, path, evbuf) < 0)) goto fail_free; return ctx; fail_free: av_packet_free(&ctx->packet); av_frame_free(&ctx->decoded_frame); free(ctx); return NULL; } struct encode_ctx * transcode_encode_setup(enum transcode_profile profile, struct media_quality *quality, struct decode_ctx *src_ctx, off_t *est_size, int width, int height) { struct encode_ctx *ctx; int bps; CHECK_NULL(L_XCODE, ctx = calloc(1, sizeof(struct encode_ctx))); CHECK_NULL(L_XCODE, ctx->filt_frame = av_frame_alloc()); CHECK_NULL(L_XCODE, ctx->encoded_pkt = av_packet_alloc()); if (init_settings(&ctx->settings, profile, quality) < 0) goto fail_free; ctx->settings.width = width; ctx->settings.height = height; // Caller did not specify a sample rate -> use same as source if (!ctx->settings.sample_rate && ctx->settings.encode_audio) { ctx->settings.sample_rate = src_ctx->audio_stream.codec->sample_rate; } // Caller did not specify a sample format -> use same as source if (!ctx->settings.sample_format && ctx->settings.encode_audio) { bps = av_get_bytes_per_sample(src_ctx->audio_stream.codec->sample_fmt); if (bps == 4) { ctx->settings.sample_format = AV_SAMPLE_FMT_S32; ctx->settings.audio_codec = AV_CODEC_ID_PCM_S32LE; ctx->settings.format = "s32le"; } else { ctx->settings.sample_format = AV_SAMPLE_FMT_S16; ctx->settings.audio_codec = AV_CODEC_ID_PCM_S16LE; ctx->settings.format = "s16le"; } } // Caller did not specify channels -> use same as source if (!ctx->settings.channels && ctx->settings.encode_audio) { ctx->settings.channels = src_ctx->audio_stream.codec->channels; ctx->settings.channel_layout = src_ctx->audio_stream.codec->channel_layout; } if (ctx->settings.wavheader) make_wav_header(ctx, src_ctx, est_size); if (open_output(ctx, src_ctx) < 0) goto fail_free; if (open_filters(ctx, src_ctx) < 0) goto fail_close; if (ctx->settings.icy && src_ctx->data_kind == DATA_KIND_HTTP) { bps = av_get_bytes_per_sample(ctx->settings.sample_format); ctx->icy_interval = METADATA_ICY_INTERVAL * ctx->settings.channels * bps * ctx->settings.sample_rate; } return ctx; fail_close: close_output(ctx); fail_free: av_packet_free(&ctx->encoded_pkt); av_frame_free(&ctx->filt_frame); free(ctx); return NULL; } struct transcode_ctx * transcode_setup(enum transcode_profile profile, struct media_quality *quality, enum data_kind data_kind, const char *path, uint32_t song_length, off_t *est_size) { struct transcode_ctx *ctx; CHECK_NULL(L_XCODE, ctx = calloc(1, sizeof(struct transcode_ctx))); ctx->decode_ctx = transcode_decode_setup(profile, quality, data_kind, path, NULL, song_length); if (!ctx->decode_ctx) { free(ctx); return NULL; } ctx->encode_ctx = transcode_encode_setup(profile, quality, ctx->decode_ctx, est_size, 0, 0); if (!ctx->encode_ctx) { transcode_decode_cleanup(&ctx->decode_ctx); free(ctx); return NULL; } return ctx; } struct decode_ctx * transcode_decode_setup_raw(enum transcode_profile profile, struct media_quality *quality) { const AVCodecDescriptor *codec_desc; struct decode_ctx *ctx; AVCodec *decoder; int ret; CHECK_NULL(L_XCODE, ctx = calloc(1, sizeof(struct decode_ctx))); if (init_settings(&ctx->settings, profile, quality) < 0) { goto out_free_ctx; } codec_desc = avcodec_descriptor_get(ctx->settings.audio_codec); if (!codec_desc) { DPRINTF(E_LOG, L_XCODE, "Invalid codec ID (%d)\n", ctx->settings.audio_codec); goto out_free_ctx; } // In raw mode we won't actually need to read or decode, but we still setup // the decode_ctx because transcode_encode_setup() gets info about the input // through this structure (TODO dont' do that) decoder = avcodec_find_decoder(ctx->settings.audio_codec); if (!decoder) { DPRINTF(E_LOG, L_XCODE, "Could not find decoder for: %s\n", codec_desc->name); goto out_free_ctx; } CHECK_NULL(L_XCODE, ctx->ifmt_ctx = avformat_alloc_context()); CHECK_NULL(L_XCODE, ctx->audio_stream.codec = avcodec_alloc_context3(decoder)); CHECK_NULL(L_XCODE, ctx->audio_stream.stream = avformat_new_stream(ctx->ifmt_ctx, NULL)); stream_settings_set(&ctx->audio_stream, &ctx->settings, decoder->type); // Copy the data we just set to the structs we will be querying later, e.g. in open_filter ctx->audio_stream.stream->time_base = ctx->audio_stream.codec->time_base; ret = avcodec_parameters_from_context(ctx->audio_stream.stream->codecpar, ctx->audio_stream.codec); if (ret < 0) { DPRINTF(E_LOG, L_XCODE, "Cannot copy stream parameters (%s): %s\n", codec_desc->name, err2str(ret)); goto out_free_codec; } return ctx; out_free_codec: avcodec_free_context(&ctx->audio_stream.codec); avformat_free_context(ctx->ifmt_ctx); out_free_ctx: free(ctx); return NULL; } int transcode_needed(const char *user_agent, const char *client_codecs, char *file_codectype) { char *codectype; cfg_t *lib; int size; int i; if (!file_codectype) { DPRINTF(E_LOG, L_XCODE, "Can't determine decode status, codec type is unknown\n"); return -1; } lib = cfg_getsec(cfg, "library"); size = cfg_size(lib, "no_decode"); if (size > 0) { for (i = 0; i < size; i++) { codectype = cfg_getnstr(lib, "no_decode", i); if (strcmp(file_codectype, codectype) == 0) return 0; // Codectype is in no_decode } } size = cfg_size(lib, "force_decode"); if (size > 0) { for (i = 0; i < size; i++) { codectype = cfg_getnstr(lib, "force_decode", i); if (strcmp(file_codectype, codectype) == 0) return 1; // Codectype is in force_decode } } if (!client_codecs) { if (user_agent) { if (strncmp(user_agent, "iTunes", strlen("iTunes")) == 0) client_codecs = itunes_codecs; else if (strncmp(user_agent, "QuickTime", strlen("QuickTime")) == 0) client_codecs = itunes_codecs; // Use iTunes codecs else if (strncmp(user_agent, "Front%20Row", strlen("Front%20Row")) == 0) client_codecs = itunes_codecs; // Use iTunes codecs else if (strncmp(user_agent, "AppleCoreMedia", strlen("AppleCoreMedia")) == 0) client_codecs = itunes_codecs; // Use iTunes codecs else if (strncmp(user_agent, "Roku", strlen("Roku")) == 0) client_codecs = roku_codecs; else if (strncmp(user_agent, "Hifidelio", strlen("Hifidelio")) == 0) /* Allegedly can't transcode for Hifidelio because their * HTTP implementation doesn't honour Connection: close. * At least, that's why mt-daapd didn't do it. */ return 0; } } else DPRINTF(E_SPAM, L_XCODE, "Client advertises codecs: %s\n", client_codecs); if (!client_codecs) { DPRINTF(E_SPAM, L_XCODE, "Could not identify client, using default codectype set\n"); client_codecs = default_codecs; } if (strstr(client_codecs, file_codectype)) { DPRINTF(E_SPAM, L_XCODE, "Codectype supported by client, no decoding needed\n"); return 0; } DPRINTF(E_SPAM, L_XCODE, "Will decode\n"); return 1; } /* Cleanup */ void transcode_decode_cleanup(struct decode_ctx **ctx) { if (!(*ctx)) return; close_input(*ctx); av_packet_free(&(*ctx)->packet); av_frame_free(&(*ctx)->decoded_frame); free(*ctx); *ctx = NULL; } void transcode_encode_cleanup(struct encode_ctx **ctx) { if (!*ctx) return; close_filters(*ctx); close_output(*ctx); av_packet_free(&(*ctx)->encoded_pkt); av_frame_free(&(*ctx)->filt_frame); free(*ctx); *ctx = NULL; } void transcode_cleanup(struct transcode_ctx **ctx) { if (!*ctx) return; transcode_encode_cleanup(&(*ctx)->encode_ctx); transcode_decode_cleanup(&(*ctx)->decode_ctx); free(*ctx); *ctx = NULL; } /* Encoding, decoding and transcoding */ int transcode_decode(transcode_frame **frame, struct decode_ctx *dec_ctx) { struct transcode_ctx ctx; int ret; if (dec_ctx->got_frame) DPRINTF(E_LOG, L_XCODE, "Bug! Currently no support for multiple calls to transcode_decode()\n"); ctx.decode_ctx = dec_ctx; ctx.encode_ctx = NULL; do { // This function stops after decoding because ctx->encode_ctx is NULL ret = read_decode_filter_encode_write(&ctx); } while ((ret == 0) && (!dec_ctx->got_frame)); if (ret < 0) return -1; *frame = dec_ctx->decoded_frame; if (dec_ctx->eof) return 0; return 1; } // Filters and encodes int transcode_encode(struct evbuffer *evbuf, struct encode_ctx *ctx, transcode_frame *frame, int eof) { AVFrame *f = frame; struct stream_ctx *s; size_t start_length; int ret; start_length = evbuffer_get_length(ctx->obuf); // Really crappy way of detecting if frame is audio, video or something else if (f->channel_layout && f->sample_rate) s = &ctx->audio_stream; else if (f->width && f->height) s = &ctx->video_stream; else { DPRINTF(E_LOG, L_XCODE, "Bug! Encoder could not detect frame type\n"); return -1; } ret = filter_encode_write(ctx, s, f); if (ret < 0) { DPRINTF(E_LOG, L_XCODE, "Error occurred while encoding: %s\n", err2str(ret)); return ret; } // Flush if (eof) { filter_encode_write(ctx, s, NULL); av_write_trailer(ctx->ofmt_ctx); } ret = evbuffer_get_length(ctx->obuf) - start_length; evbuffer_add_buffer(evbuf, ctx->obuf); return ret; } int transcode(struct evbuffer *evbuf, int *icy_timer, struct transcode_ctx *ctx, int want_bytes) { size_t start_length; int processed = 0; int ret; if (icy_timer) *icy_timer = 0; if (ctx->decode_ctx->eof) return 0; start_length = evbuffer_get_length(ctx->encode_ctx->obuf); do { ret = read_decode_filter_encode_write(ctx); processed = evbuffer_get_length(ctx->encode_ctx->obuf) - start_length; } while ((ret == 0) && (!want_bytes || (processed < want_bytes))); evbuffer_add_buffer(evbuf, ctx->encode_ctx->obuf); ctx->encode_ctx->total_bytes += processed; if (icy_timer && ctx->encode_ctx->icy_interval) *icy_timer = (ctx->encode_ctx->total_bytes % ctx->encode_ctx->icy_interval < processed); if ((ret < 0) && (ret != AVERROR_EOF)) return ret; return processed; } transcode_frame * transcode_frame_new(void *data, size_t size, int nsamples, struct media_quality *quality) { AVFrame *f; int ret; f = av_frame_alloc(); if (!f) { DPRINTF(E_LOG, L_XCODE, "Out of memory for frame\n"); return NULL; } f->format = bitdepth2format(quality->bits_per_sample); if (f->format == AV_SAMPLE_FMT_NONE) { DPRINTF(E_LOG, L_XCODE, "transcode_frame_new() called with unsupported bps (%d)\n", quality->bits_per_sample); av_frame_free(&f); return NULL; } f->sample_rate = quality->sample_rate; f->nb_samples = nsamples; f->channel_layout = av_get_default_channel_layout(quality->channels); #ifdef HAVE_FFMPEG f->channels = quality->channels; #endif f->pts = AV_NOPTS_VALUE; // We don't align because the frame won't be given directly to the encoder // anyway, it will first go through the filter (which might align it...?) ret = avcodec_fill_audio_frame(f, quality->channels, f->format, data, size, 1); if (ret < 0) { DPRINTF(E_LOG, L_XCODE, "Error filling frame with rawbuf, size %zu, samples %d (%d/%d/%d): %s\n", size, nsamples, quality->sample_rate, quality->bits_per_sample, quality->channels, err2str(ret)); av_frame_free(&f); return NULL; } return f; } void transcode_frame_free(transcode_frame *frame) { AVFrame *f = frame; av_frame_free(&f); } /* Seeking */ int transcode_seek(struct transcode_ctx *ctx, int ms) { struct decode_ctx *dec_ctx = ctx->decode_ctx; struct stream_ctx *s; int64_t start_time; int64_t target_pts; int64_t got_pts; int got_ms; int ret; s = &dec_ctx->audio_stream; if (!s->stream) { DPRINTF(E_LOG, L_XCODE, "Could not seek in non-audio input\n"); return -1; } start_time = s->stream->start_time; target_pts = ms; target_pts = target_pts * AV_TIME_BASE / 1000; target_pts = av_rescale_q(target_pts, AV_TIME_BASE_Q, s->stream->time_base); if ((start_time != AV_NOPTS_VALUE) && (start_time > 0)) target_pts += start_time; ret = av_seek_frame(dec_ctx->ifmt_ctx, s->stream->index, target_pts, AVSEEK_FLAG_BACKWARD); if (ret < 0) { DPRINTF(E_WARN, L_XCODE, "Could not seek into stream: %s\n", err2str(ret)); return -1; } avcodec_flush_buffers(s->codec); // Fast forward until first packet with a timestamp is found s->codec->skip_frame = AVDISCARD_NONREF; while (1) { dec_ctx->timestamp = av_gettime(); av_packet_unref(dec_ctx->packet); ret = av_read_frame(dec_ctx->ifmt_ctx, dec_ctx->packet); if (ret < 0) { DPRINTF(E_WARN, L_XCODE, "Could not read more data while seeking: %s\n", err2str(ret)); s->codec->skip_frame = AVDISCARD_DEFAULT; return -1; } if (stream_find(dec_ctx, dec_ctx->packet->stream_index) == AVMEDIA_TYPE_UNKNOWN) continue; // Need a pts to return the real position if (dec_ctx->packet->pts == AV_NOPTS_VALUE) continue; break; } s->codec->skip_frame = AVDISCARD_DEFAULT; // Tell read_packet() to resume with dec_ctx->packet dec_ctx->resume = 1; // Compute position in ms from pts got_pts = dec_ctx->packet->pts; if ((start_time != AV_NOPTS_VALUE) && (start_time > 0)) got_pts -= start_time; got_pts = av_rescale_q(got_pts, s->stream->time_base, AV_TIME_BASE_Q); got_ms = got_pts / (AV_TIME_BASE / 1000); // Since negative return would mean error, we disallow it here if (got_ms < 0) got_ms = 0; DPRINTF(E_DBG, L_XCODE, "Seek wanted %d ms, got %d ms\n", ms, got_ms); return got_ms; } /* Querying */ int transcode_decode_query(struct decode_ctx *ctx, const char *query) { if (strcmp(query, "width") == 0) { if (ctx->video_stream.stream) return ctx->video_stream.stream->codecpar->width; } else if (strcmp(query, "height") == 0) { if (ctx->video_stream.stream) return ctx->video_stream.stream->codecpar->height; } else if (strcmp(query, "is_png") == 0) { if (ctx->video_stream.stream) return (ctx->video_stream.stream->codecpar->codec_id == AV_CODEC_ID_PNG); } else if (strcmp(query, "is_jpeg") == 0) { if (ctx->video_stream.stream) return (ctx->video_stream.stream->codecpar->codec_id == AV_CODEC_ID_MJPEG); } return -1; } int transcode_encode_query(struct encode_ctx *ctx, const char *query) { if (strcmp(query, "sample_rate") == 0) { if (ctx->audio_stream.stream) return ctx->audio_stream.stream->codecpar->sample_rate; } else if (strcmp(query, "bits_per_sample") == 0) { if (ctx->audio_stream.stream) return av_get_bits_per_sample(ctx->audio_stream.stream->codecpar->codec_id); } else if (strcmp(query, "channels") == 0) { if (ctx->audio_stream.stream) return ctx->audio_stream.stream->codecpar->channels; } return -1; } /* Metadata */ struct http_icy_metadata * transcode_metadata(struct transcode_ctx *ctx, int *changed) { struct http_icy_metadata *m; if (!ctx->decode_ctx->ifmt_ctx) return NULL; m = http_icy_metadata_get(ctx->decode_ctx->ifmt_ctx, 1); if (!m) return NULL; *changed = (m->hash != ctx->encode_ctx->icy_hash); ctx->encode_ctx->icy_hash = m->hash; return m; }