root/libavformat/matroskadec.c

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DEFINITIONS

This source file includes following definitions.
  1. matroska_resync
  2. ebml_level_end
  3. ebml_read_num
  4. ebml_read_length
  5. ebml_read_uint
  6. ebml_read_sint
  7. ebml_read_float
  8. ebml_read_ascii
  9. ebml_read_binary
  10. ebml_read_master
  11. matroska_ebmlnum_uint
  12. matroska_ebmlnum_sint
  13. ebml_parse_id
  14. ebml_parse
  15. ebml_parse_nest
  16. matroska_find_level1_elem
  17. ebml_parse_elem
  18. ebml_free
  19. matroska_probe
  20. matroska_find_track_by_num
  21. matroska_decode_buffer
  22. matroska_convert_tag
  23. matroska_convert_tags
  24. matroska_parse_seekhead_entry
  25. matroska_execute_seekhead
  26. matroska_add_index_entries
  27. matroska_parse_cues
  28. matroska_aac_profile
  29. matroska_aac_sri
  30. matroska_metadata_creation_time
  31. matroska_parse_flac
  32. matroska_parse_tracks
  33. matroska_read_header
  34. matroska_deliver_packet
  35. matroska_clear_queue
  36. matroska_parse_laces
  37. matroska_parse_rm_audio
  38. matroska_parse_wavpack
  39. matroska_parse_webvtt
  40. matroska_parse_frame
  41. matroska_parse_block
  42. matroska_parse_cluster_incremental
  43. matroska_parse_cluster
  44. matroska_read_packet
  45. matroska_read_seek
  46. matroska_read_close
  47. get_cue_desc
  48. webm_clusters_start_with_keyframe
  49. buffer_size_after_time_downloaded
  50. webm_dash_manifest_compute_bandwidth
  51. webm_dash_manifest_cues
  52. webm_dash_manifest_read_header
  53. webm_dash_manifest_read_packet

/*
 * Matroska file demuxer
 * Copyright (c) 2003-2008 The FFmpeg Project
 *
 * This file is part of FFmpeg.
 *
 * FFmpeg is free software; you can redistribute it and/or
 * modify it under the terms of the GNU Lesser General Public
 * License as published by the Free Software Foundation; either
 * version 2.1 of the License, or (at your option) any later version.
 *
 * FFmpeg 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
 * Lesser General Public License for more details.
 *
 * You should have received a copy of the GNU Lesser General Public
 * License along with FFmpeg; if not, write to the Free Software
 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
 */

/**
 * @file
 * Matroska file demuxer
 * @author Ronald Bultje <rbultje@ronald.bitfreak.net>
 * @author with a little help from Moritz Bunkus <moritz@bunkus.org>
 * @author totally reworked by Aurelien Jacobs <aurel@gnuage.org>
 * @see specs available on the Matroska project page: http://www.matroska.org/
 */

#include "config.h"

#include <inttypes.h>
#include <stdio.h>

#include "libavutil/avstring.h"
#include "libavutil/base64.h"
#include "libavutil/dict.h"
#include "libavutil/intfloat.h"
#include "libavutil/intreadwrite.h"
#include "libavutil/lzo.h"
#include "libavutil/mathematics.h"
#include "libavutil/time_internal.h"

#include "libavcodec/bytestream.h"
#include "libavcodec/flac.h"
#include "libavcodec/mpeg4audio.h"

#include "avformat.h"
#include "avio_internal.h"
#include "internal.h"
#include "isom.h"
#include "matroska.h"
#include "oggdec.h"
/* For ff_codec_get_id(). */
#include "riff.h"
#include "rmsipr.h"

#if CONFIG_BZLIB
#include <bzlib.h>
#endif
#if CONFIG_ZLIB
#include <zlib.h>
#endif

typedef enum {
    EBML_NONE,
    EBML_UINT,
    EBML_FLOAT,
    EBML_STR,
    EBML_UTF8,
    EBML_BIN,
    EBML_NEST,
    EBML_LEVEL1,
    EBML_PASS,
    EBML_STOP,
    EBML_SINT,
    EBML_TYPE_COUNT
} EbmlType;

typedef const struct EbmlSyntax {
    uint32_t id;
    EbmlType type;
    int list_elem_size;
    int data_offset;
    union {
        uint64_t    u;
        double      f;
        const char *s;
        const struct EbmlSyntax *n;
    } def;
} EbmlSyntax;

typedef struct EbmlList {
    int nb_elem;
    void *elem;
} EbmlList;

typedef struct EbmlBin {
    int      size;
    uint8_t *data;
    int64_t  pos;
} EbmlBin;

typedef struct Ebml {
    uint64_t version;
    uint64_t max_size;
    uint64_t id_length;
    char    *doctype;
    uint64_t doctype_version;
} Ebml;

typedef struct MatroskaTrackCompression {
    uint64_t algo;
    EbmlBin  settings;
} MatroskaTrackCompression;

typedef struct MatroskaTrackEncryption {
    uint64_t algo;
    EbmlBin  key_id;
} MatroskaTrackEncryption;

typedef struct MatroskaTrackEncoding {
    uint64_t scope;
    uint64_t type;
    MatroskaTrackCompression compression;
    MatroskaTrackEncryption encryption;
} MatroskaTrackEncoding;

typedef struct MatroskaTrackVideo {
    double   frame_rate;
    uint64_t display_width;
    uint64_t display_height;
    uint64_t pixel_width;
    uint64_t pixel_height;
    EbmlBin color_space;
    uint64_t stereo_mode;
    uint64_t alpha_mode;
} MatroskaTrackVideo;

typedef struct MatroskaTrackAudio {
    double   samplerate;
    double   out_samplerate;
    uint64_t bitdepth;
    uint64_t channels;

    /* real audio header (extracted from extradata) */
    int      coded_framesize;
    int      sub_packet_h;
    int      frame_size;
    int      sub_packet_size;
    int      sub_packet_cnt;
    int      pkt_cnt;
    uint64_t buf_timecode;
    uint8_t *buf;
} MatroskaTrackAudio;

typedef struct MatroskaTrackPlane {
    uint64_t uid;
    uint64_t type;
} MatroskaTrackPlane;

typedef struct MatroskaTrackOperation {
    EbmlList combine_planes;
} MatroskaTrackOperation;

typedef struct MatroskaTrack {
    uint64_t num;
    uint64_t uid;
    uint64_t type;
    char    *name;
    char    *codec_id;
    EbmlBin  codec_priv;
    char    *language;
    double time_scale;
    uint64_t default_duration;
    uint64_t flag_default;
    uint64_t flag_forced;
    uint64_t seek_preroll;
    MatroskaTrackVideo video;
    MatroskaTrackAudio audio;
    MatroskaTrackOperation operation;
    EbmlList encodings;
    uint64_t codec_delay;

    AVStream *stream;
    int64_t end_timecode;
    int ms_compat;
    uint64_t max_block_additional_id;
} MatroskaTrack;

typedef struct MatroskaAttachment {
    uint64_t uid;
    char *filename;
    char *mime;
    EbmlBin bin;

    AVStream *stream;
} MatroskaAttachment;

typedef struct MatroskaChapter {
    uint64_t start;
    uint64_t end;
    uint64_t uid;
    char    *title;

    AVChapter *chapter;
} MatroskaChapter;

typedef struct MatroskaIndexPos {
    uint64_t track;
    uint64_t pos;
} MatroskaIndexPos;

typedef struct MatroskaIndex {
    uint64_t time;
    EbmlList pos;
} MatroskaIndex;

typedef struct MatroskaTag {
    char *name;
    char *string;
    char *lang;
    uint64_t def;
    EbmlList sub;
} MatroskaTag;

typedef struct MatroskaTagTarget {
    char    *type;
    uint64_t typevalue;
    uint64_t trackuid;
    uint64_t chapteruid;
    uint64_t attachuid;
} MatroskaTagTarget;

typedef struct MatroskaTags {
    MatroskaTagTarget target;
    EbmlList tag;
} MatroskaTags;

typedef struct MatroskaSeekhead {
    uint64_t id;
    uint64_t pos;
} MatroskaSeekhead;

typedef struct MatroskaLevel {
    uint64_t start;
    uint64_t length;
} MatroskaLevel;

typedef struct MatroskaCluster {
    uint64_t timecode;
    EbmlList blocks;
} MatroskaCluster;

typedef struct MatroskaLevel1Element {
    uint64_t id;
    uint64_t pos;
    int parsed;
} MatroskaLevel1Element;

typedef struct MatroskaDemuxContext {
    AVFormatContext *ctx;

    /* EBML stuff */
    int num_levels;
    MatroskaLevel levels[EBML_MAX_DEPTH];
    int level_up;
    uint32_t current_id;

    uint64_t time_scale;
    double   duration;
    char    *title;
    char    *muxingapp;
    EbmlBin date_utc;
    EbmlList tracks;
    EbmlList attachments;
    EbmlList chapters;
    EbmlList index;
    EbmlList tags;
    EbmlList seekhead;

    /* byte position of the segment inside the stream */
    int64_t segment_start;

    /* the packet queue */
    AVPacket **packets;
    int num_packets;
    AVPacket *prev_pkt;

    int done;

    /* What to skip before effectively reading a packet. */
    int skip_to_keyframe;
    uint64_t skip_to_timecode;

    /* File has a CUES element, but we defer parsing until it is needed. */
    int cues_parsing_deferred;

    /* Level1 elements and whether they were read yet */
    MatroskaLevel1Element level1_elems[64];
    int num_level1_elems;

    int current_cluster_num_blocks;
    int64_t current_cluster_pos;
    MatroskaCluster current_cluster;

    /* File has SSA subtitles which prevent incremental cluster parsing. */
    int contains_ssa;
} MatroskaDemuxContext;

typedef struct MatroskaBlock {
    uint64_t duration;
    int64_t  reference;
    uint64_t non_simple;
    EbmlBin  bin;
    uint64_t additional_id;
    EbmlBin  additional;
    int64_t discard_padding;
} MatroskaBlock;

static EbmlSyntax ebml_header[] = {
    { EBML_ID_EBMLREADVERSION,    EBML_UINT, 0, offsetof(Ebml, version),         { .u = EBML_VERSION } },
    { EBML_ID_EBMLMAXSIZELENGTH,  EBML_UINT, 0, offsetof(Ebml, max_size),        { .u = 8 } },
    { EBML_ID_EBMLMAXIDLENGTH,    EBML_UINT, 0, offsetof(Ebml, id_length),       { .u = 4 } },
    { EBML_ID_DOCTYPE,            EBML_STR,  0, offsetof(Ebml, doctype),         { .s = "(none)" } },
    { EBML_ID_DOCTYPEREADVERSION, EBML_UINT, 0, offsetof(Ebml, doctype_version), { .u = 1 } },
    { EBML_ID_EBMLVERSION,        EBML_NONE },
    { EBML_ID_DOCTYPEVERSION,     EBML_NONE },
    { 0 }
};

static EbmlSyntax ebml_syntax[] = {
    { EBML_ID_HEADER, EBML_NEST, 0, 0, { .n = ebml_header } },
    { 0 }
};

static EbmlSyntax matroska_info[] = {
    { MATROSKA_ID_TIMECODESCALE, EBML_UINT,  0, offsetof(MatroskaDemuxContext, time_scale), { .u = 1000000 } },
    { MATROSKA_ID_DURATION,      EBML_FLOAT, 0, offsetof(MatroskaDemuxContext, duration) },
    { MATROSKA_ID_TITLE,         EBML_UTF8,  0, offsetof(MatroskaDemuxContext, title) },
    { MATROSKA_ID_WRITINGAPP,    EBML_NONE },
    { MATROSKA_ID_MUXINGAPP,     EBML_UTF8, 0, offsetof(MatroskaDemuxContext, muxingapp) },
    { MATROSKA_ID_DATEUTC,       EBML_BIN,  0, offsetof(MatroskaDemuxContext, date_utc) },
    { MATROSKA_ID_SEGMENTUID,    EBML_NONE },
    { 0 }
};

static EbmlSyntax matroska_track_video[] = {
    { MATROSKA_ID_VIDEOFRAMERATE,      EBML_FLOAT, 0, offsetof(MatroskaTrackVideo, frame_rate) },
    { MATROSKA_ID_VIDEODISPLAYWIDTH,   EBML_UINT,  0, offsetof(MatroskaTrackVideo, display_width), { .u=-1 } },
    { MATROSKA_ID_VIDEODISPLAYHEIGHT,  EBML_UINT,  0, offsetof(MatroskaTrackVideo, display_height), { .u=-1 } },
    { MATROSKA_ID_VIDEOPIXELWIDTH,     EBML_UINT,  0, offsetof(MatroskaTrackVideo, pixel_width) },
    { MATROSKA_ID_VIDEOPIXELHEIGHT,    EBML_UINT,  0, offsetof(MatroskaTrackVideo, pixel_height) },
    { MATROSKA_ID_VIDEOCOLORSPACE,     EBML_BIN,   0, offsetof(MatroskaTrackVideo, color_space) },
    { MATROSKA_ID_VIDEOALPHAMODE,      EBML_UINT,  0, offsetof(MatroskaTrackVideo, alpha_mode) },
    { MATROSKA_ID_VIDEOPIXELCROPB,     EBML_NONE },
    { MATROSKA_ID_VIDEOPIXELCROPT,     EBML_NONE },
    { MATROSKA_ID_VIDEOPIXELCROPL,     EBML_NONE },
    { MATROSKA_ID_VIDEOPIXELCROPR,     EBML_NONE },
    { MATROSKA_ID_VIDEODISPLAYUNIT,    EBML_NONE },
    { MATROSKA_ID_VIDEOFLAGINTERLACED, EBML_NONE },
    { MATROSKA_ID_VIDEOSTEREOMODE,     EBML_UINT,  0, offsetof(MatroskaTrackVideo, stereo_mode), { .u = MATROSKA_VIDEO_STEREOMODE_TYPE_NB } },
    { MATROSKA_ID_VIDEOASPECTRATIO,    EBML_NONE },
    { 0 }
};

static EbmlSyntax matroska_track_audio[] = {
    { MATROSKA_ID_AUDIOSAMPLINGFREQ,    EBML_FLOAT, 0, offsetof(MatroskaTrackAudio, samplerate), { .f = 8000.0 } },
    { MATROSKA_ID_AUDIOOUTSAMPLINGFREQ, EBML_FLOAT, 0, offsetof(MatroskaTrackAudio, out_samplerate) },
    { MATROSKA_ID_AUDIOBITDEPTH,        EBML_UINT,  0, offsetof(MatroskaTrackAudio, bitdepth) },
    { MATROSKA_ID_AUDIOCHANNELS,        EBML_UINT,  0, offsetof(MatroskaTrackAudio, channels),   { .u = 1 } },
    { 0 }
};

static EbmlSyntax matroska_track_encoding_compression[] = {
    { MATROSKA_ID_ENCODINGCOMPALGO,     EBML_UINT, 0, offsetof(MatroskaTrackCompression, algo), { .u = 0 } },
    { MATROSKA_ID_ENCODINGCOMPSETTINGS, EBML_BIN,  0, offsetof(MatroskaTrackCompression, settings) },
    { 0 }
};

static EbmlSyntax matroska_track_encoding_encryption[] = {
    { MATROSKA_ID_ENCODINGENCALGO,        EBML_UINT, 0, offsetof(MatroskaTrackEncryption,algo), {.u = 0} },
    { MATROSKA_ID_ENCODINGENCKEYID,       EBML_BIN, 0, offsetof(MatroskaTrackEncryption,key_id) },
    { MATROSKA_ID_ENCODINGENCAESSETTINGS, EBML_NONE },
    { MATROSKA_ID_ENCODINGSIGALGO,        EBML_NONE },
    { MATROSKA_ID_ENCODINGSIGHASHALGO,    EBML_NONE },
    { MATROSKA_ID_ENCODINGSIGKEYID,       EBML_NONE },
    { MATROSKA_ID_ENCODINGSIGNATURE,      EBML_NONE },
    { 0 }
};
static EbmlSyntax matroska_track_encoding[] = {
    { MATROSKA_ID_ENCODINGSCOPE,       EBML_UINT, 0, offsetof(MatroskaTrackEncoding, scope),       { .u = 1 } },
    { MATROSKA_ID_ENCODINGTYPE,        EBML_UINT, 0, offsetof(MatroskaTrackEncoding, type),        { .u = 0 } },
    { MATROSKA_ID_ENCODINGCOMPRESSION, EBML_NEST, 0, offsetof(MatroskaTrackEncoding, compression), { .n = matroska_track_encoding_compression } },
    { MATROSKA_ID_ENCODINGENCRYPTION,  EBML_NEST, 0, offsetof(MatroskaTrackEncoding, encryption),  { .n = matroska_track_encoding_encryption } },
    { MATROSKA_ID_ENCODINGORDER,       EBML_NONE },
    { 0 }
};

static EbmlSyntax matroska_track_encodings[] = {
    { MATROSKA_ID_TRACKCONTENTENCODING, EBML_NEST, sizeof(MatroskaTrackEncoding), offsetof(MatroskaTrack, encodings), { .n = matroska_track_encoding } },
    { 0 }
};

static EbmlSyntax matroska_track_plane[] = {
    { MATROSKA_ID_TRACKPLANEUID,  EBML_UINT, 0, offsetof(MatroskaTrackPlane,uid) },
    { MATROSKA_ID_TRACKPLANETYPE, EBML_UINT, 0, offsetof(MatroskaTrackPlane,type) },
    { 0 }
};

static EbmlSyntax matroska_track_combine_planes[] = {
    { MATROSKA_ID_TRACKPLANE, EBML_NEST, sizeof(MatroskaTrackPlane), offsetof(MatroskaTrackOperation,combine_planes), {.n = matroska_track_plane} },
    { 0 }
};

static EbmlSyntax matroska_track_operation[] = {
    { MATROSKA_ID_TRACKCOMBINEPLANES, EBML_NEST, 0, 0, {.n = matroska_track_combine_planes} },
    { 0 }
};

static EbmlSyntax matroska_track[] = {
    { MATROSKA_ID_TRACKNUMBER,           EBML_UINT,  0, offsetof(MatroskaTrack, num) },
    { MATROSKA_ID_TRACKNAME,             EBML_UTF8,  0, offsetof(MatroskaTrack, name) },
    { MATROSKA_ID_TRACKUID,              EBML_UINT,  0, offsetof(MatroskaTrack, uid) },
    { MATROSKA_ID_TRACKTYPE,             EBML_UINT,  0, offsetof(MatroskaTrack, type) },
    { MATROSKA_ID_CODECID,               EBML_STR,   0, offsetof(MatroskaTrack, codec_id) },
    { MATROSKA_ID_CODECPRIVATE,          EBML_BIN,   0, offsetof(MatroskaTrack, codec_priv) },
    { MATROSKA_ID_CODECDELAY,            EBML_UINT,  0, offsetof(MatroskaTrack, codec_delay) },
    { MATROSKA_ID_TRACKLANGUAGE,         EBML_UTF8,  0, offsetof(MatroskaTrack, language),     { .s = "eng" } },
    { MATROSKA_ID_TRACKDEFAULTDURATION,  EBML_UINT,  0, offsetof(MatroskaTrack, default_duration) },
    { MATROSKA_ID_TRACKTIMECODESCALE,    EBML_FLOAT, 0, offsetof(MatroskaTrack, time_scale),   { .f = 1.0 } },
    { MATROSKA_ID_TRACKFLAGDEFAULT,      EBML_UINT,  0, offsetof(MatroskaTrack, flag_default), { .u = 1 } },
    { MATROSKA_ID_TRACKFLAGFORCED,       EBML_UINT,  0, offsetof(MatroskaTrack, flag_forced),  { .u = 0 } },
    { MATROSKA_ID_TRACKVIDEO,            EBML_NEST,  0, offsetof(MatroskaTrack, video),        { .n = matroska_track_video } },
    { MATROSKA_ID_TRACKAUDIO,            EBML_NEST,  0, offsetof(MatroskaTrack, audio),        { .n = matroska_track_audio } },
    { MATROSKA_ID_TRACKOPERATION,        EBML_NEST,  0, offsetof(MatroskaTrack, operation),    { .n = matroska_track_operation } },
    { MATROSKA_ID_TRACKCONTENTENCODINGS, EBML_NEST,  0, 0,                                     { .n = matroska_track_encodings } },
    { MATROSKA_ID_TRACKMAXBLKADDID,      EBML_UINT,  0, offsetof(MatroskaTrack, max_block_additional_id) },
    { MATROSKA_ID_SEEKPREROLL,           EBML_UINT,  0, offsetof(MatroskaTrack, seek_preroll) },
    { MATROSKA_ID_TRACKFLAGENABLED,      EBML_NONE },
    { MATROSKA_ID_TRACKFLAGLACING,       EBML_NONE },
    { MATROSKA_ID_CODECNAME,             EBML_NONE },
    { MATROSKA_ID_CODECDECODEALL,        EBML_NONE },
    { MATROSKA_ID_CODECINFOURL,          EBML_NONE },
    { MATROSKA_ID_CODECDOWNLOADURL,      EBML_NONE },
    { MATROSKA_ID_TRACKMINCACHE,         EBML_NONE },
    { MATROSKA_ID_TRACKMAXCACHE,         EBML_NONE },
    { 0 }
};

static EbmlSyntax matroska_tracks[] = {
    { MATROSKA_ID_TRACKENTRY, EBML_NEST, sizeof(MatroskaTrack), offsetof(MatroskaDemuxContext, tracks), { .n = matroska_track } },
    { 0 }
};

static EbmlSyntax matroska_attachment[] = {
    { MATROSKA_ID_FILEUID,      EBML_UINT, 0, offsetof(MatroskaAttachment, uid) },
    { MATROSKA_ID_FILENAME,     EBML_UTF8, 0, offsetof(MatroskaAttachment, filename) },
    { MATROSKA_ID_FILEMIMETYPE, EBML_STR,  0, offsetof(MatroskaAttachment, mime) },
    { MATROSKA_ID_FILEDATA,     EBML_BIN,  0, offsetof(MatroskaAttachment, bin) },
    { MATROSKA_ID_FILEDESC,     EBML_NONE },
    { 0 }
};

static EbmlSyntax matroska_attachments[] = {
    { MATROSKA_ID_ATTACHEDFILE, EBML_NEST, sizeof(MatroskaAttachment), offsetof(MatroskaDemuxContext, attachments), { .n = matroska_attachment } },
    { 0 }
};

static EbmlSyntax matroska_chapter_display[] = {
    { MATROSKA_ID_CHAPSTRING, EBML_UTF8, 0, offsetof(MatroskaChapter, title) },
    { MATROSKA_ID_CHAPLANG,   EBML_NONE },
    { 0 }
};

static EbmlSyntax matroska_chapter_entry[] = {
    { MATROSKA_ID_CHAPTERTIMESTART,   EBML_UINT, 0, offsetof(MatroskaChapter, start), { .u = AV_NOPTS_VALUE } },
    { MATROSKA_ID_CHAPTERTIMEEND,     EBML_UINT, 0, offsetof(MatroskaChapter, end),   { .u = AV_NOPTS_VALUE } },
    { MATROSKA_ID_CHAPTERUID,         EBML_UINT, 0, offsetof(MatroskaChapter, uid) },
    { MATROSKA_ID_CHAPTERDISPLAY,     EBML_NEST, 0,                        0,         { .n = matroska_chapter_display } },
    { MATROSKA_ID_CHAPTERFLAGHIDDEN,  EBML_NONE },
    { MATROSKA_ID_CHAPTERFLAGENABLED, EBML_NONE },
    { MATROSKA_ID_CHAPTERPHYSEQUIV,   EBML_NONE },
    { MATROSKA_ID_CHAPTERATOM,        EBML_NONE },
    { 0 }
};

static EbmlSyntax matroska_chapter[] = {
    { MATROSKA_ID_CHAPTERATOM,        EBML_NEST, sizeof(MatroskaChapter), offsetof(MatroskaDemuxContext, chapters), { .n = matroska_chapter_entry } },
    { MATROSKA_ID_EDITIONUID,         EBML_NONE },
    { MATROSKA_ID_EDITIONFLAGHIDDEN,  EBML_NONE },
    { MATROSKA_ID_EDITIONFLAGDEFAULT, EBML_NONE },
    { MATROSKA_ID_EDITIONFLAGORDERED, EBML_NONE },
    { 0 }
};

static EbmlSyntax matroska_chapters[] = {
    { MATROSKA_ID_EDITIONENTRY, EBML_NEST, 0, 0, { .n = matroska_chapter } },
    { 0 }
};

static EbmlSyntax matroska_index_pos[] = {
    { MATROSKA_ID_CUETRACK,           EBML_UINT, 0, offsetof(MatroskaIndexPos, track) },
    { MATROSKA_ID_CUECLUSTERPOSITION, EBML_UINT, 0, offsetof(MatroskaIndexPos, pos) },
    { MATROSKA_ID_CUERELATIVEPOSITION,EBML_NONE },
    { MATROSKA_ID_CUEDURATION,        EBML_NONE },
    { MATROSKA_ID_CUEBLOCKNUMBER,     EBML_NONE },
    { 0 }
};

static EbmlSyntax matroska_index_entry[] = {
    { MATROSKA_ID_CUETIME,          EBML_UINT, 0,                        offsetof(MatroskaIndex, time) },
    { MATROSKA_ID_CUETRACKPOSITION, EBML_NEST, sizeof(MatroskaIndexPos), offsetof(MatroskaIndex, pos), { .n = matroska_index_pos } },
    { 0 }
};

static EbmlSyntax matroska_index[] = {
    { MATROSKA_ID_POINTENTRY, EBML_NEST, sizeof(MatroskaIndex), offsetof(MatroskaDemuxContext, index), { .n = matroska_index_entry } },
    { 0 }
};

static EbmlSyntax matroska_simpletag[] = {
    { MATROSKA_ID_TAGNAME,        EBML_UTF8, 0,                   offsetof(MatroskaTag, name) },
    { MATROSKA_ID_TAGSTRING,      EBML_UTF8, 0,                   offsetof(MatroskaTag, string) },
    { MATROSKA_ID_TAGLANG,        EBML_STR,  0,                   offsetof(MatroskaTag, lang), { .s = "und" } },
    { MATROSKA_ID_TAGDEFAULT,     EBML_UINT, 0,                   offsetof(MatroskaTag, def) },
    { MATROSKA_ID_TAGDEFAULT_BUG, EBML_UINT, 0,                   offsetof(MatroskaTag, def) },
    { MATROSKA_ID_SIMPLETAG,      EBML_NEST, sizeof(MatroskaTag), offsetof(MatroskaTag, sub),  { .n = matroska_simpletag } },
    { 0 }
};

static EbmlSyntax matroska_tagtargets[] = {
    { MATROSKA_ID_TAGTARGETS_TYPE,       EBML_STR,  0, offsetof(MatroskaTagTarget, type) },
    { MATROSKA_ID_TAGTARGETS_TYPEVALUE,  EBML_UINT, 0, offsetof(MatroskaTagTarget, typevalue), { .u = 50 } },
    { MATROSKA_ID_TAGTARGETS_TRACKUID,   EBML_UINT, 0, offsetof(MatroskaTagTarget, trackuid) },
    { MATROSKA_ID_TAGTARGETS_CHAPTERUID, EBML_UINT, 0, offsetof(MatroskaTagTarget, chapteruid) },
    { MATROSKA_ID_TAGTARGETS_ATTACHUID,  EBML_UINT, 0, offsetof(MatroskaTagTarget, attachuid) },
    { 0 }
};

static EbmlSyntax matroska_tag[] = {
    { MATROSKA_ID_SIMPLETAG,  EBML_NEST, sizeof(MatroskaTag), offsetof(MatroskaTags, tag),    { .n = matroska_simpletag } },
    { MATROSKA_ID_TAGTARGETS, EBML_NEST, 0,                   offsetof(MatroskaTags, target), { .n = matroska_tagtargets } },
    { 0 }
};

static EbmlSyntax matroska_tags[] = {
    { MATROSKA_ID_TAG, EBML_NEST, sizeof(MatroskaTags), offsetof(MatroskaDemuxContext, tags), { .n = matroska_tag } },
    { 0 }
};

static EbmlSyntax matroska_seekhead_entry[] = {
    { MATROSKA_ID_SEEKID,       EBML_UINT, 0, offsetof(MatroskaSeekhead, id) },
    { MATROSKA_ID_SEEKPOSITION, EBML_UINT, 0, offsetof(MatroskaSeekhead, pos), { .u = -1 } },
    { 0 }
};

static EbmlSyntax matroska_seekhead[] = {
    { MATROSKA_ID_SEEKENTRY, EBML_NEST, sizeof(MatroskaSeekhead), offsetof(MatroskaDemuxContext, seekhead), { .n = matroska_seekhead_entry } },
    { 0 }
};

static EbmlSyntax matroska_segment[] = {
    { MATROSKA_ID_INFO,        EBML_LEVEL1, 0, 0, { .n = matroska_info } },
    { MATROSKA_ID_TRACKS,      EBML_LEVEL1, 0, 0, { .n = matroska_tracks } },
    { MATROSKA_ID_ATTACHMENTS, EBML_LEVEL1, 0, 0, { .n = matroska_attachments } },
    { MATROSKA_ID_CHAPTERS,    EBML_LEVEL1, 0, 0, { .n = matroska_chapters } },
    { MATROSKA_ID_CUES,        EBML_LEVEL1, 0, 0, { .n = matroska_index } },
    { MATROSKA_ID_TAGS,        EBML_LEVEL1, 0, 0, { .n = matroska_tags } },
    { MATROSKA_ID_SEEKHEAD,    EBML_LEVEL1, 0, 0, { .n = matroska_seekhead } },
    { MATROSKA_ID_CLUSTER,     EBML_STOP },
    { 0 }
};

static EbmlSyntax matroska_segments[] = {
    { MATROSKA_ID_SEGMENT, EBML_NEST, 0, 0, { .n = matroska_segment } },
    { 0 }
};

static EbmlSyntax matroska_blockmore[] = {
    { MATROSKA_ID_BLOCKADDID,      EBML_UINT, 0, offsetof(MatroskaBlock,additional_id) },
    { MATROSKA_ID_BLOCKADDITIONAL, EBML_BIN,  0, offsetof(MatroskaBlock,additional) },
    { 0 }
};

static EbmlSyntax matroska_blockadditions[] = {
    { MATROSKA_ID_BLOCKMORE, EBML_NEST, 0, 0, {.n = matroska_blockmore} },
    { 0 }
};

static EbmlSyntax matroska_blockgroup[] = {
    { MATROSKA_ID_BLOCK,          EBML_BIN,  0, offsetof(MatroskaBlock, bin) },
    { MATROSKA_ID_BLOCKADDITIONS, EBML_NEST, 0, 0, { .n = matroska_blockadditions} },
    { MATROSKA_ID_SIMPLEBLOCK,    EBML_BIN,  0, offsetof(MatroskaBlock, bin) },
    { MATROSKA_ID_BLOCKDURATION,  EBML_UINT, 0, offsetof(MatroskaBlock, duration) },
    { MATROSKA_ID_DISCARDPADDING, EBML_SINT, 0, offsetof(MatroskaBlock, discard_padding) },
    { MATROSKA_ID_BLOCKREFERENCE, EBML_SINT, 0, offsetof(MatroskaBlock, reference) },
    { MATROSKA_ID_CODECSTATE,     EBML_NONE },
    {                          1, EBML_UINT, 0, offsetof(MatroskaBlock, non_simple), { .u = 1 } },
    { 0 }
};

static EbmlSyntax matroska_cluster[] = {
    { MATROSKA_ID_CLUSTERTIMECODE, EBML_UINT, 0,                     offsetof(MatroskaCluster, timecode) },
    { MATROSKA_ID_BLOCKGROUP,      EBML_NEST, sizeof(MatroskaBlock), offsetof(MatroskaCluster, blocks), { .n = matroska_blockgroup } },
    { MATROSKA_ID_SIMPLEBLOCK,     EBML_PASS, sizeof(MatroskaBlock), offsetof(MatroskaCluster, blocks), { .n = matroska_blockgroup } },
    { MATROSKA_ID_CLUSTERPOSITION, EBML_NONE },
    { MATROSKA_ID_CLUSTERPREVSIZE, EBML_NONE },
    { 0 }
};

static EbmlSyntax matroska_clusters[] = {
    { MATROSKA_ID_CLUSTER,  EBML_NEST, 0, 0, { .n = matroska_cluster } },
    { MATROSKA_ID_INFO,     EBML_NONE },
    { MATROSKA_ID_CUES,     EBML_NONE },
    { MATROSKA_ID_TAGS,     EBML_NONE },
    { MATROSKA_ID_SEEKHEAD, EBML_NONE },
    { 0 }
};

static EbmlSyntax matroska_cluster_incremental_parsing[] = {
    { MATROSKA_ID_CLUSTERTIMECODE, EBML_UINT, 0,                     offsetof(MatroskaCluster, timecode) },
    { MATROSKA_ID_BLOCKGROUP,      EBML_NEST, sizeof(MatroskaBlock), offsetof(MatroskaCluster, blocks), { .n = matroska_blockgroup } },
    { MATROSKA_ID_SIMPLEBLOCK,     EBML_PASS, sizeof(MatroskaBlock), offsetof(MatroskaCluster, blocks), { .n = matroska_blockgroup } },
    { MATROSKA_ID_CLUSTERPOSITION, EBML_NONE },
    { MATROSKA_ID_CLUSTERPREVSIZE, EBML_NONE },
    { MATROSKA_ID_INFO,            EBML_NONE },
    { MATROSKA_ID_CUES,            EBML_NONE },
    { MATROSKA_ID_TAGS,            EBML_NONE },
    { MATROSKA_ID_SEEKHEAD,        EBML_NONE },
    { MATROSKA_ID_CLUSTER,         EBML_STOP },
    { 0 }
};

static EbmlSyntax matroska_cluster_incremental[] = {
    { MATROSKA_ID_CLUSTERTIMECODE, EBML_UINT, 0, offsetof(MatroskaCluster, timecode) },
    { MATROSKA_ID_BLOCKGROUP,      EBML_STOP },
    { MATROSKA_ID_SIMPLEBLOCK,     EBML_STOP },
    { MATROSKA_ID_CLUSTERPOSITION, EBML_NONE },
    { MATROSKA_ID_CLUSTERPREVSIZE, EBML_NONE },
    { 0 }
};

static EbmlSyntax matroska_clusters_incremental[] = {
    { MATROSKA_ID_CLUSTER,  EBML_NEST, 0, 0, { .n = matroska_cluster_incremental } },
    { MATROSKA_ID_INFO,     EBML_NONE },
    { MATROSKA_ID_CUES,     EBML_NONE },
    { MATROSKA_ID_TAGS,     EBML_NONE },
    { MATROSKA_ID_SEEKHEAD, EBML_NONE },
    { 0 }
};

static const char *const matroska_doctypes[] = { "matroska", "webm" };

static int matroska_resync(MatroskaDemuxContext *matroska, int64_t last_pos)
{
    AVIOContext *pb = matroska->ctx->pb;
    uint32_t id;
    matroska->current_id = 0;
    matroska->num_levels = 0;

    /* seek to next position to resync from */
    if (avio_seek(pb, last_pos + 1, SEEK_SET) < 0)
        goto eof;

    id = avio_rb32(pb);

    // try to find a toplevel element
    while (!avio_feof(pb)) {
        if (id == MATROSKA_ID_INFO     || id == MATROSKA_ID_TRACKS      ||
            id == MATROSKA_ID_CUES     || id == MATROSKA_ID_TAGS        ||
            id == MATROSKA_ID_SEEKHEAD || id == MATROSKA_ID_ATTACHMENTS ||
            id == MATROSKA_ID_CLUSTER  || id == MATROSKA_ID_CHAPTERS) {
            matroska->current_id = id;
            return 0;
        }
        id = (id << 8) | avio_r8(pb);
    }

eof:
    matroska->done = 1;
    return AVERROR_EOF;
}

/*
 * Return: Whether we reached the end of a level in the hierarchy or not.
 */
static int ebml_level_end(MatroskaDemuxContext *matroska)
{
    AVIOContext *pb = matroska->ctx->pb;
    int64_t pos = avio_tell(pb);

    if (matroska->num_levels > 0) {
        MatroskaLevel *level = &matroska->levels[matroska->num_levels - 1];
        if (pos - level->start >= level->length || matroska->current_id) {
            matroska->num_levels--;
            return 1;
        }
    }
    return 0;
}

/*
 * Read: an "EBML number", which is defined as a variable-length
 * array of bytes. The first byte indicates the length by giving a
 * number of 0-bits followed by a one. The position of the first
 * "one" bit inside the first byte indicates the length of this
 * number.
 * Returns: number of bytes read, < 0 on error
 */
static int ebml_read_num(MatroskaDemuxContext *matroska, AVIOContext *pb,
                         int max_size, uint64_t *number)
{
    int read = 1, n = 1;
    uint64_t total = 0;

    /* The first byte tells us the length in bytes - avio_r8() can normally
     * return 0, but since that's not a valid first ebmlID byte, we can
     * use it safely here to catch EOS. */
    if (!(total = avio_r8(pb))) {
        /* we might encounter EOS here */
        if (!avio_feof(pb)) {
            int64_t pos = avio_tell(pb);
            av_log(matroska->ctx, AV_LOG_ERROR,
                   "Read error at pos. %"PRIu64" (0x%"PRIx64")\n",
                   pos, pos);
            return pb->error ? pb->error : AVERROR(EIO);
        }
        return AVERROR_EOF;
    }

    /* get the length of the EBML number */
    read = 8 - ff_log2_tab[total];
    if (read > max_size) {
        int64_t pos = avio_tell(pb) - 1;
        av_log(matroska->ctx, AV_LOG_ERROR,
               "Invalid EBML number size tag 0x%02x at pos %"PRIu64" (0x%"PRIx64")\n",
               (uint8_t) total, pos, pos);
        return AVERROR_INVALIDDATA;
    }

    /* read out length */
    total ^= 1 << ff_log2_tab[total];
    while (n++ < read)
        total = (total << 8) | avio_r8(pb);

    *number = total;

    return read;
}

/**
 * Read a EBML length value.
 * This needs special handling for the "unknown length" case which has multiple
 * encodings.
 */
static int ebml_read_length(MatroskaDemuxContext *matroska, AVIOContext *pb,
                            uint64_t *number)
{
    int res = ebml_read_num(matroska, pb, 8, number);
    if (res > 0 && *number + 1 == 1ULL << (7 * res))
        *number = 0xffffffffffffffULL;
    return res;
}

/*
 * Read the next element as an unsigned int.
 * 0 is success, < 0 is failure.
 */
static int ebml_read_uint(AVIOContext *pb, int size, uint64_t *num)
{
    int n = 0;

    if (size > 8)
        return AVERROR_INVALIDDATA;

    /* big-endian ordering; build up number */
    *num = 0;
    while (n++ < size)
        *num = (*num << 8) | avio_r8(pb);

    return 0;
}

/*
 * Read the next element as a signed int.
 * 0 is success, < 0 is failure.
 */
static int ebml_read_sint(AVIOContext *pb, int size, int64_t *num)
{
    int n = 1;

    if (size > 8)
        return AVERROR_INVALIDDATA;

    if (size == 0) {
        *num = 0;
    } else {
        *num = sign_extend(avio_r8(pb), 8);

        /* big-endian ordering; build up number */
        while (n++ < size)
            *num = (*num << 8) | avio_r8(pb);
    }

    return 0;
}

/*
 * Read the next element as a float.
 * 0 is success, < 0 is failure.
 */
static int ebml_read_float(AVIOContext *pb, int size, double *num)
{
    if (size == 0)
        *num = 0;
    else if (size == 4)
        *num = av_int2float(avio_rb32(pb));
    else if (size == 8)
        *num = av_int2double(avio_rb64(pb));
    else
        return AVERROR_INVALIDDATA;

    return 0;
}

/*
 * Read the next element as an ASCII string.
 * 0 is success, < 0 is failure.
 */
static int ebml_read_ascii(AVIOContext *pb, int size, char **str)
{
    char *res;

    /* EBML strings are usually not 0-terminated, so we allocate one
     * byte more, read the string and NULL-terminate it ourselves. */
    if (!(res = av_malloc(size + 1)))
        return AVERROR(ENOMEM);
    if (avio_read(pb, (uint8_t *) res, size) != size) {
        av_free(res);
        return AVERROR(EIO);
    }
    (res)[size] = '\0';
    av_free(*str);
    *str = res;

    return 0;
}

/*
 * Read the next element as binary data.
 * 0 is success, < 0 is failure.
 */
static int ebml_read_binary(AVIOContext *pb, int length, EbmlBin *bin)
{
    av_fast_padded_malloc(&bin->data, &bin->size, length);
    if (!bin->data)
        return AVERROR(ENOMEM);

    bin->size = length;
    bin->pos  = avio_tell(pb);
    if (avio_read(pb, bin->data, length) != length) {
        av_freep(&bin->data);
        bin->size = 0;
        return AVERROR(EIO);
    }

    return 0;
}

/*
 * Read the next element, but only the header. The contents
 * are supposed to be sub-elements which can be read separately.
 * 0 is success, < 0 is failure.
 */
static int ebml_read_master(MatroskaDemuxContext *matroska, uint64_t length)
{
    AVIOContext *pb = matroska->ctx->pb;
    MatroskaLevel *level;

    if (matroska->num_levels >= EBML_MAX_DEPTH) {
        av_log(matroska->ctx, AV_LOG_ERROR,
               "File moves beyond max. allowed depth (%d)\n", EBML_MAX_DEPTH);
        return AVERROR(ENOSYS);
    }

    level         = &matroska->levels[matroska->num_levels++];
    level->start  = avio_tell(pb);
    level->length = length;

    return 0;
}

/*
 * Read signed/unsigned "EBML" numbers.
 * Return: number of bytes processed, < 0 on error
 */
static int matroska_ebmlnum_uint(MatroskaDemuxContext *matroska,
                                 uint8_t *data, uint32_t size, uint64_t *num)
{
    AVIOContext pb;
    ffio_init_context(&pb, data, size, 0, NULL, NULL, NULL, NULL);
    return ebml_read_num(matroska, &pb, FFMIN(size, 8), num);
}

/*
 * Same as above, but signed.
 */
static int matroska_ebmlnum_sint(MatroskaDemuxContext *matroska,
                                 uint8_t *data, uint32_t size, int64_t *num)
{
    uint64_t unum;
    int res;

    /* read as unsigned number first */
    if ((res = matroska_ebmlnum_uint(matroska, data, size, &unum)) < 0)
        return res;

    /* make signed (weird way) */
    *num = unum - ((1LL << (7 * res - 1)) - 1);

    return res;
}

static int ebml_parse_elem(MatroskaDemuxContext *matroska,
                           EbmlSyntax *syntax, void *data);

static int ebml_parse_id(MatroskaDemuxContext *matroska, EbmlSyntax *syntax,
                         uint32_t id, void *data)
{
    int i;
    for (i = 0; syntax[i].id; i++)
        if (id == syntax[i].id)
            break;
    if (!syntax[i].id && id == MATROSKA_ID_CLUSTER &&
        matroska->num_levels > 0                   &&
        matroska->levels[matroska->num_levels - 1].length == 0xffffffffffffff)
        return 0;  // we reached the end of an unknown size cluster
    if (!syntax[i].id && id != EBML_ID_VOID && id != EBML_ID_CRC32) {
        av_log(matroska->ctx, AV_LOG_DEBUG, "Unknown entry 0x%"PRIX32"\n", id);
    }
    return ebml_parse_elem(matroska, &syntax[i], data);
}

static int ebml_parse(MatroskaDemuxContext *matroska, EbmlSyntax *syntax,
                      void *data)
{
    if (!matroska->current_id) {
        uint64_t id;
        int res = ebml_read_num(matroska, matroska->ctx->pb, 4, &id);
        if (res < 0)
            return res;
        matroska->current_id = id | 1 << 7 * res;
    }
    return ebml_parse_id(matroska, syntax, matroska->current_id, data);
}

static int ebml_parse_nest(MatroskaDemuxContext *matroska, EbmlSyntax *syntax,
                           void *data)
{
    int i, res = 0;

    for (i = 0; syntax[i].id; i++)
        switch (syntax[i].type) {
        case EBML_UINT:
            *(uint64_t *) ((char *) data + syntax[i].data_offset) = syntax[i].def.u;
            break;
        case EBML_FLOAT:
            *(double *) ((char *) data + syntax[i].data_offset) = syntax[i].def.f;
            break;
        case EBML_STR:
        case EBML_UTF8:
            // the default may be NULL
            if (syntax[i].def.s) {
                uint8_t **dst = (uint8_t **) ((uint8_t *) data + syntax[i].data_offset);
                *dst = av_strdup(syntax[i].def.s);
                if (!*dst)
                    return AVERROR(ENOMEM);
            }
            break;
        }

    while (!res && !ebml_level_end(matroska))
        res = ebml_parse(matroska, syntax, data);

    return res;
}

/*
 * Allocate and return the entry for the level1 element with the given ID. If
 * an entry already exists, return the existing entry.
 */
static MatroskaLevel1Element *matroska_find_level1_elem(MatroskaDemuxContext *matroska,
                                                        uint32_t id)
{
    int i;
    MatroskaLevel1Element *elem;

    // Some files link to all clusters; useless.
    if (id == MATROSKA_ID_CLUSTER)
        return NULL;

    // There can be multiple seekheads.
    if (id != MATROSKA_ID_SEEKHEAD) {
        for (i = 0; i < matroska->num_level1_elems; i++) {
            if (matroska->level1_elems[i].id == id)
                return &matroska->level1_elems[i];
        }
    }

    // Only a completely broken file would have more elements.
    // It also provides a low-effort way to escape from circular seekheads
    // (every iteration will add a level1 entry).
    if (matroska->num_level1_elems >= FF_ARRAY_ELEMS(matroska->level1_elems)) {
        av_log(matroska->ctx, AV_LOG_ERROR, "Too many level1 elements or circular seekheads.\n");
        return NULL;
    }

    elem = &matroska->level1_elems[matroska->num_level1_elems++];
    *elem = (MatroskaLevel1Element){.id = id};

    return elem;
}

static int ebml_parse_elem(MatroskaDemuxContext *matroska,
                           EbmlSyntax *syntax, void *data)
{
    static const uint64_t max_lengths[EBML_TYPE_COUNT] = {
        [EBML_UINT]  = 8,
        [EBML_FLOAT] = 8,
        // max. 16 MB for strings
        [EBML_STR]   = 0x1000000,
        [EBML_UTF8]  = 0x1000000,
        // max. 256 MB for binary data
        [EBML_BIN]   = 0x10000000,
        // no limits for anything else
    };
    AVIOContext *pb = matroska->ctx->pb;
    uint32_t id = syntax->id;
    uint64_t length;
    int res;
    void *newelem;
    MatroskaLevel1Element *level1_elem;

    data = (char *) data + syntax->data_offset;
    if (syntax->list_elem_size) {
        EbmlList *list = data;
        newelem = av_realloc_array(list->elem, list->nb_elem + 1, syntax->list_elem_size);
        if (!newelem)
            return AVERROR(ENOMEM);
        list->elem = newelem;
        data = (char *) list->elem + list->nb_elem * syntax->list_elem_size;
        memset(data, 0, syntax->list_elem_size);
        list->nb_elem++;
    }

    if (syntax->type != EBML_PASS && syntax->type != EBML_STOP) {
        matroska->current_id = 0;
        if ((res = ebml_read_length(matroska, pb, &length)) < 0)
            return res;
        if (max_lengths[syntax->type] && length > max_lengths[syntax->type]) {
            av_log(matroska->ctx, AV_LOG_ERROR,
                   "Invalid length 0x%"PRIx64" > 0x%"PRIx64" for syntax element %i\n",
                   length, max_lengths[syntax->type], syntax->type);
            return AVERROR_INVALIDDATA;
        }
    }

    switch (syntax->type) {
    case EBML_UINT:
        res = ebml_read_uint(pb, length, data);
        break;
    case EBML_SINT:
        res = ebml_read_sint(pb, length, data);
        break;
    case EBML_FLOAT:
        res = ebml_read_float(pb, length, data);
        break;
    case EBML_STR:
    case EBML_UTF8:
        res = ebml_read_ascii(pb, length, data);
        break;
    case EBML_BIN:
        res = ebml_read_binary(pb, length, data);
        break;
    case EBML_LEVEL1:
    case EBML_NEST:
        if ((res = ebml_read_master(matroska, length)) < 0)
            return res;
        if (id == MATROSKA_ID_SEGMENT)
            matroska->segment_start = avio_tell(matroska->ctx->pb);
        if (id == MATROSKA_ID_CUES)
            matroska->cues_parsing_deferred = 0;
        if (syntax->type == EBML_LEVEL1 &&
            (level1_elem = matroska_find_level1_elem(matroska, syntax->id))) {
            if (level1_elem->parsed)
                av_log(matroska->ctx, AV_LOG_ERROR, "Duplicate element\n");
            level1_elem->parsed = 1;
        }
        return ebml_parse_nest(matroska, syntax->def.n, data);
    case EBML_PASS:
        return ebml_parse_id(matroska, syntax->def.n, id, data);
    case EBML_STOP:
        return 1;
    default:
        if (ffio_limit(pb, length) != length)
            return AVERROR(EIO);
        return avio_skip(pb, length) < 0 ? AVERROR(EIO) : 0;
    }
    if (res == AVERROR_INVALIDDATA)
        av_log(matroska->ctx, AV_LOG_ERROR, "Invalid element\n");
    else if (res == AVERROR(EIO))
        av_log(matroska->ctx, AV_LOG_ERROR, "Read error\n");
    return res;
}

static void ebml_free(EbmlSyntax *syntax, void *data)
{
    int i, j;
    for (i = 0; syntax[i].id; i++) {
        void *data_off = (char *) data + syntax[i].data_offset;
        switch (syntax[i].type) {
        case EBML_STR:
        case EBML_UTF8:
            av_freep(data_off);
            break;
        case EBML_BIN:
            av_freep(&((EbmlBin *) data_off)->data);
            break;
        case EBML_LEVEL1:
        case EBML_NEST:
            if (syntax[i].list_elem_size) {
                EbmlList *list = data_off;
                char *ptr = list->elem;
                for (j = 0; j < list->nb_elem;
                     j++, ptr += syntax[i].list_elem_size)
                    ebml_free(syntax[i].def.n, ptr);
                av_freep(&list->elem);
            } else
                ebml_free(syntax[i].def.n, data_off);
        default:
            break;
        }
    }
}

/*
 * Autodetecting...
 */
static int matroska_probe(AVProbeData *p)
{
    uint64_t total = 0;
    int len_mask = 0x80, size = 1, n = 1, i;

    /* EBML header? */
    if (AV_RB32(p->buf) != EBML_ID_HEADER)
        return 0;

    /* length of header */
    total = p->buf[4];
    while (size <= 8 && !(total & len_mask)) {
        size++;
        len_mask >>= 1;
    }
    if (size > 8)
        return 0;
    total &= (len_mask - 1);
    while (n < size)
        total = (total << 8) | p->buf[4 + n++];

    /* Does the probe data contain the whole header? */
    if (p->buf_size < 4 + size + total)
        return 0;

    /* The header should contain a known document type. For now,
     * we don't parse the whole header but simply check for the
     * availability of that array of characters inside the header.
     * Not fully fool-proof, but good enough. */
    for (i = 0; i < FF_ARRAY_ELEMS(matroska_doctypes); i++) {
        int probelen = strlen(matroska_doctypes[i]);
        if (total < probelen)
            continue;
        for (n = 4 + size; n <= 4 + size + total - probelen; n++)
            if (!memcmp(p->buf + n, matroska_doctypes[i], probelen))
                return AVPROBE_SCORE_MAX;
    }

    // probably valid EBML header but no recognized doctype
    return AVPROBE_SCORE_EXTENSION;
}

static MatroskaTrack *matroska_find_track_by_num(MatroskaDemuxContext *matroska,
                                                 int num)
{
    MatroskaTrack *tracks = matroska->tracks.elem;
    int i;

    for (i = 0; i < matroska->tracks.nb_elem; i++)
        if (tracks[i].num == num)
            return &tracks[i];

    av_log(matroska->ctx, AV_LOG_ERROR, "Invalid track number %d\n", num);
    return NULL;
}

static int matroska_decode_buffer(uint8_t **buf, int *buf_size,
                                  MatroskaTrack *track)
{
    MatroskaTrackEncoding *encodings = track->encodings.elem;
    uint8_t *data = *buf;
    int isize = *buf_size;
    uint8_t *pkt_data = NULL;
    uint8_t av_unused *newpktdata;
    int pkt_size = isize;
    int result = 0;
    int olen;

    if (pkt_size >= 10000000U)
        return AVERROR_INVALIDDATA;

    switch (encodings[0].compression.algo) {
    case MATROSKA_TRACK_ENCODING_COMP_HEADERSTRIP:
    {
        int header_size = encodings[0].compression.settings.size;
        uint8_t *header = encodings[0].compression.settings.data;

        if (header_size && !header) {
            av_log(NULL, AV_LOG_ERROR, "Compression size but no data in headerstrip\n");
            return -1;
        }

        if (!header_size)
            return 0;

        pkt_size = isize + header_size;
        pkt_data = av_malloc(pkt_size);
        if (!pkt_data)
            return AVERROR(ENOMEM);

        memcpy(pkt_data, header, header_size);
        memcpy(pkt_data + header_size, data, isize);
        break;
    }
#if CONFIG_LZO
    case MATROSKA_TRACK_ENCODING_COMP_LZO:
        do {
            olen       = pkt_size *= 3;
            newpktdata = av_realloc(pkt_data, pkt_size + AV_LZO_OUTPUT_PADDING);
            if (!newpktdata) {
                result = AVERROR(ENOMEM);
                goto failed;
            }
            pkt_data = newpktdata;
            result   = av_lzo1x_decode(pkt_data, &olen, data, &isize);
        } while (result == AV_LZO_OUTPUT_FULL && pkt_size < 10000000);
        if (result) {
            result = AVERROR_INVALIDDATA;
            goto failed;
        }
        pkt_size -= olen;
        break;
#endif
#if CONFIG_ZLIB
    case MATROSKA_TRACK_ENCODING_COMP_ZLIB:
    {
        z_stream zstream = { 0 };
        if (inflateInit(&zstream) != Z_OK)
            return -1;
        zstream.next_in  = data;
        zstream.avail_in = isize;
        do {
            pkt_size  *= 3;
            newpktdata = av_realloc(pkt_data, pkt_size);
            if (!newpktdata) {
                inflateEnd(&zstream);
                goto failed;
            }
            pkt_data          = newpktdata;
            zstream.avail_out = pkt_size - zstream.total_out;
            zstream.next_out  = pkt_data + zstream.total_out;
            if (pkt_data) {
                result = inflate(&zstream, Z_NO_FLUSH);
            } else
                result = Z_MEM_ERROR;
        } while (result == Z_OK && pkt_size < 10000000);
        pkt_size = zstream.total_out;
        inflateEnd(&zstream);
        if (result != Z_STREAM_END) {
            if (result == Z_MEM_ERROR)
                result = AVERROR(ENOMEM);
            else
                result = AVERROR_INVALIDDATA;
            goto failed;
        }
        break;
    }
#endif
#if CONFIG_BZLIB
    case MATROSKA_TRACK_ENCODING_COMP_BZLIB:
    {
        bz_stream bzstream = { 0 };
        if (BZ2_bzDecompressInit(&bzstream, 0, 0) != BZ_OK)
            return -1;
        bzstream.next_in  = data;
        bzstream.avail_in = isize;
        do {
            pkt_size  *= 3;
            newpktdata = av_realloc(pkt_data, pkt_size);
            if (!newpktdata) {
                BZ2_bzDecompressEnd(&bzstream);
                goto failed;
            }
            pkt_data           = newpktdata;
            bzstream.avail_out = pkt_size - bzstream.total_out_lo32;
            bzstream.next_out  = pkt_data + bzstream.total_out_lo32;
            if (pkt_data) {
                result = BZ2_bzDecompress(&bzstream);
            } else
                result = BZ_MEM_ERROR;
        } while (result == BZ_OK && pkt_size < 10000000);
        pkt_size = bzstream.total_out_lo32;
        BZ2_bzDecompressEnd(&bzstream);
        if (result != BZ_STREAM_END) {
            if (result == BZ_MEM_ERROR)
                result = AVERROR(ENOMEM);
            else
                result = AVERROR_INVALIDDATA;
            goto failed;
        }
        break;
    }
#endif
    default:
        return AVERROR_INVALIDDATA;
    }

    *buf      = pkt_data;
    *buf_size = pkt_size;
    return 0;

failed:
    av_free(pkt_data);
    return result;
}

static void matroska_convert_tag(AVFormatContext *s, EbmlList *list,
                                 AVDictionary **metadata, char *prefix)
{
    MatroskaTag *tags = list->elem;
    char key[1024];
    int i;

    for (i = 0; i < list->nb_elem; i++) {
        const char *lang = tags[i].lang &&
                           strcmp(tags[i].lang, "und") ? tags[i].lang : NULL;

        if (!tags[i].name) {
            av_log(s, AV_LOG_WARNING, "Skipping invalid tag with no TagName.\n");
            continue;
        }
        if (prefix)
            snprintf(key, sizeof(key), "%s/%s", prefix, tags[i].name);
        else
            av_strlcpy(key, tags[i].name, sizeof(key));
        if (tags[i].def || !lang) {
            av_dict_set(metadata, key, tags[i].string, 0);
            if (tags[i].sub.nb_elem)
                matroska_convert_tag(s, &tags[i].sub, metadata, key);
        }
        if (lang) {
            av_strlcat(key, "-", sizeof(key));
            av_strlcat(key, lang, sizeof(key));
            av_dict_set(metadata, key, tags[i].string, 0);
            if (tags[i].sub.nb_elem)
                matroska_convert_tag(s, &tags[i].sub, metadata, key);
        }
    }
    ff_metadata_conv(metadata, NULL, ff_mkv_metadata_conv);
}

static void matroska_convert_tags(AVFormatContext *s)
{
    MatroskaDemuxContext *matroska = s->priv_data;
    MatroskaTags *tags = matroska->tags.elem;
    int i, j;

    for (i = 0; i < matroska->tags.nb_elem; i++) {
        if (tags[i].target.attachuid) {
            MatroskaAttachment *attachment = matroska->attachments.elem;
            for (j = 0; j < matroska->attachments.nb_elem; j++)
                if (attachment[j].uid == tags[i].target.attachuid &&
                    attachment[j].stream)
                    matroska_convert_tag(s, &tags[i].tag,
                                         &attachment[j].stream->metadata, NULL);
        } else if (tags[i].target.chapteruid) {
            MatroskaChapter *chapter = matroska->chapters.elem;
            for (j = 0; j < matroska->chapters.nb_elem; j++)
                if (chapter[j].uid == tags[i].target.chapteruid &&
                    chapter[j].chapter)
                    matroska_convert_tag(s, &tags[i].tag,
                                         &chapter[j].chapter->metadata, NULL);
        } else if (tags[i].target.trackuid) {
            MatroskaTrack *track = matroska->tracks.elem;
            for (j = 0; j < matroska->tracks.nb_elem; j++)
                if (track[j].uid == tags[i].target.trackuid && track[j].stream)
                    matroska_convert_tag(s, &tags[i].tag,
                                         &track[j].stream->metadata, NULL);
        } else {
            matroska_convert_tag(s, &tags[i].tag, &s->metadata,
                                 tags[i].target.type);
        }
    }
}

static int matroska_parse_seekhead_entry(MatroskaDemuxContext *matroska,
                                         uint64_t pos)
{
    uint32_t level_up       = matroska->level_up;
    uint32_t saved_id       = matroska->current_id;
    int64_t before_pos = avio_tell(matroska->ctx->pb);
    MatroskaLevel level;
    int64_t offset;
    int ret = 0;

    /* seek */
    offset = pos + matroska->segment_start;
    if (avio_seek(matroska->ctx->pb, offset, SEEK_SET) == offset) {
        /* We don't want to lose our seekhead level, so we add
         * a dummy. This is a crude hack. */
        if (matroska->num_levels == EBML_MAX_DEPTH) {
            av_log(matroska->ctx, AV_LOG_INFO,
                   "Max EBML element depth (%d) reached, "
                   "cannot parse further.\n", EBML_MAX_DEPTH);
            ret = AVERROR_INVALIDDATA;
        } else {
            level.start  = 0;
            level.length = (uint64_t) -1;
            matroska->levels[matroska->num_levels] = level;
            matroska->num_levels++;
            matroska->current_id                   = 0;

            ret = ebml_parse(matroska, matroska_segment, matroska);

            /* remove dummy level */
            while (matroska->num_levels) {
                uint64_t length = matroska->levels[--matroska->num_levels].length;
                if (length == (uint64_t) -1)
                    break;
            }
        }
    }
    /* seek back */
    avio_seek(matroska->ctx->pb, before_pos, SEEK_SET);
    matroska->level_up   = level_up;
    matroska->current_id = saved_id;

    return ret;
}

static void matroska_execute_seekhead(MatroskaDemuxContext *matroska)
{
    EbmlList *seekhead_list = &matroska->seekhead;
    int i;

    // we should not do any seeking in the streaming case
    if (!matroska->ctx->pb->seekable)
        return;

    for (i = 0; i < seekhead_list->nb_elem; i++) {
        MatroskaSeekhead *seekheads = seekhead_list->elem;
        uint32_t id  = seekheads[i].id;
        uint64_t pos = seekheads[i].pos;

        MatroskaLevel1Element *elem = matroska_find_level1_elem(matroska, id);
        if (!elem || elem->parsed)
            continue;

        elem->pos = pos;

        // defer cues parsing until we actually need cue data.
        if (id == MATROSKA_ID_CUES)
            continue;

        if (matroska_parse_seekhead_entry(matroska, pos) < 0) {
            // mark index as broken
            matroska->cues_parsing_deferred = -1;
            break;
        }

        elem->parsed = 1;
    }
}

static void matroska_add_index_entries(MatroskaDemuxContext *matroska)
{
    EbmlList *index_list;
    MatroskaIndex *index;
    int index_scale = 1;
    int i, j;

    if (matroska->ctx->flags & AVFMT_FLAG_IGNIDX)
        return;

    index_list = &matroska->index;
    index      = index_list->elem;
    if (index_list->nb_elem &&
        index[0].time > 1E14 / matroska->time_scale) {
        av_log(matroska->ctx, AV_LOG_WARNING, "Working around broken index.\n");
        index_scale = matroska->time_scale;
    }
    for (i = 0; i < index_list->nb_elem; i++) {
        EbmlList *pos_list    = &index[i].pos;
        MatroskaIndexPos *pos = pos_list->elem;
        for (j = 0; j < pos_list->nb_elem; j++) {
            MatroskaTrack *track = matroska_find_track_by_num(matroska,
                                                              pos[j].track);
            if (track && track->stream)
                av_add_index_entry(track->stream,
                                   pos[j].pos + matroska->segment_start,
                                   index[i].time / index_scale, 0, 0,
                                   AVINDEX_KEYFRAME);
        }
    }
}

static void matroska_parse_cues(MatroskaDemuxContext *matroska) {
    int i;

    if (matroska->ctx->flags & AVFMT_FLAG_IGNIDX)
        return;

    for (i = 0; i < matroska->num_level1_elems; i++) {
        MatroskaLevel1Element *elem = &matroska->level1_elems[i];
        if (elem->id == MATROSKA_ID_CUES && !elem->parsed) {
            if (matroska_parse_seekhead_entry(matroska, elem->pos) < 0)
                matroska->cues_parsing_deferred = -1;
            elem->parsed = 1;
            break;
        }
    }

    matroska_add_index_entries(matroska);
}

static int matroska_aac_profile(char *codec_id)
{
    static const char *const aac_profiles[] = { "MAIN", "LC", "SSR" };
    int profile;

    for (profile = 0; profile < FF_ARRAY_ELEMS(aac_profiles); profile++)
        if (strstr(codec_id, aac_profiles[profile]))
            break;
    return profile + 1;
}

static int matroska_aac_sri(int samplerate)
{
    int sri;

    for (sri = 0; sri < FF_ARRAY_ELEMS(avpriv_mpeg4audio_sample_rates); sri++)
        if (avpriv_mpeg4audio_sample_rates[sri] == samplerate)
            break;
    return sri;
}

static void matroska_metadata_creation_time(AVDictionary **metadata, int64_t date_utc)
{
    char buffer[32];
    /* Convert to seconds and adjust by number of seconds between 2001-01-01 and Epoch */
    time_t creation_time = date_utc / 1000000000 + 978307200;
    struct tm tmpbuf, *ptm = gmtime_r(&creation_time, &tmpbuf);
    if (!ptm) return;
    if (strftime(buffer, sizeof(buffer), "%Y-%m-%d %H:%M:%S", ptm))
        av_dict_set(metadata, "creation_time", buffer, 0);
}

static int matroska_parse_flac(AVFormatContext *s,
                               MatroskaTrack *track,
                               int *offset)
{
    AVStream *st = track->stream;
    uint8_t *p = track->codec_priv.data;
    int size   = track->codec_priv.size;

    if (size < 8 + FLAC_STREAMINFO_SIZE || p[4] & 0x7f) {
        av_log(s, AV_LOG_WARNING, "Invalid FLAC private data\n");
        track->codec_priv.size = 0;
        return 0;
    }
    *offset = 8;
    track->codec_priv.size = 8 + FLAC_STREAMINFO_SIZE;

    p    += track->codec_priv.size;
    size -= track->codec_priv.size;

    /* parse the remaining metadata blocks if present */
    while (size >= 4) {
        int block_last, block_type, block_size;

        flac_parse_block_header(p, &block_last, &block_type, &block_size);

        p    += 4;
        size -= 4;
        if (block_size > size)
            return 0;

        /* check for the channel mask */
        if (block_type == FLAC_METADATA_TYPE_VORBIS_COMMENT) {
            AVDictionary *dict = NULL;
            AVDictionaryEntry *chmask;

            ff_vorbis_comment(s, &dict, p, block_size, 0);
            chmask = av_dict_get(dict, "WAVEFORMATEXTENSIBLE_CHANNEL_MASK", NULL, 0);
            if (chmask) {
                uint64_t mask = strtol(chmask->value, NULL, 0);
                if (!mask || mask & ~0x3ffffULL) {
                    av_log(s, AV_LOG_WARNING,
                           "Invalid value of WAVEFORMATEXTENSIBLE_CHANNEL_MASK\n");
                } else
                    st->codec->channel_layout = mask;
            }
            av_dict_free(&dict);
        }

        p    += block_size;
        size -= block_size;
    }

    return 0;
}

static int matroska_parse_tracks(AVFormatContext *s)
{
    MatroskaDemuxContext *matroska = s->priv_data;
    MatroskaTrack *tracks = matroska->tracks.elem;
    AVStream *st;
    int i, j, ret;
    int k;

    for (i = 0; i < matroska->tracks.nb_elem; i++) {
        MatroskaTrack *track = &tracks[i];
        enum AVCodecID codec_id = AV_CODEC_ID_NONE;
        EbmlList *encodings_list = &track->encodings;
        MatroskaTrackEncoding *encodings = encodings_list->elem;
        uint8_t *extradata = NULL;
        int extradata_size = 0;
        int extradata_offset = 0;
        uint32_t fourcc = 0;
        AVIOContext b;
        char* key_id_base64 = NULL;
        int bit_depth = -1;

        /* Apply some sanity checks. */
        if (track->type != MATROSKA_TRACK_TYPE_VIDEO &&
            track->type != MATROSKA_TRACK_TYPE_AUDIO &&
            track->type != MATROSKA_TRACK_TYPE_SUBTITLE &&
            track->type != MATROSKA_TRACK_TYPE_METADATA) {
            av_log(matroska->ctx, AV_LOG_INFO,
                   "Unknown or unsupported track type %"PRIu64"\n",
                   track->type);
            continue;
        }
        if (!track->codec_id)
            continue;

        if (track->type == MATROSKA_TRACK_TYPE_VIDEO) {
            if (!track->default_duration && track->video.frame_rate > 0)
                track->default_duration = 1000000000 / track->video.frame_rate;
            if (track->video.display_width == -1)
                track->video.display_width = track->video.pixel_width;
            if (track->video.display_height == -1)
                track->video.display_height = track->video.pixel_height;
            if (track->video.color_space.size == 4)
                fourcc = AV_RL32(track->video.color_space.data);
        } else if (track->type == MATROSKA_TRACK_TYPE_AUDIO) {
            if (!track->audio.out_samplerate)
                track->audio.out_samplerate = track->audio.samplerate;
        }
        if (encodings_list->nb_elem > 1) {
            av_log(matroska->ctx, AV_LOG_ERROR,
                   "Multiple combined encodings not supported");
        } else if (encodings_list->nb_elem == 1) {
            if (encodings[0].type) {
                if (encodings[0].encryption.key_id.size > 0) {
                    /* Save the encryption key id to be stored later as a
                       metadata tag. */
                    const int b64_size = AV_BASE64_SIZE(encodings[0].encryption.key_id.size);
                    key_id_base64 = av_malloc(b64_size);
                    if (key_id_base64 == NULL)
                        return AVERROR(ENOMEM);

                    av_base64_encode(key_id_base64, b64_size,
                                     encodings[0].encryption.key_id.data,
                                     encodings[0].encryption.key_id.size);
                } else {
                    encodings[0].scope = 0;
                    av_log(matroska->ctx, AV_LOG_ERROR,
                           "Unsupported encoding type");
                }
            } else if (
#if CONFIG_ZLIB
                 encodings[0].compression.algo != MATROSKA_TRACK_ENCODING_COMP_ZLIB  &&
#endif
#if CONFIG_BZLIB
                 encodings[0].compression.algo != MATROSKA_TRACK_ENCODING_COMP_BZLIB &&
#endif
#if CONFIG_LZO
                 encodings[0].compression.algo != MATROSKA_TRACK_ENCODING_COMP_LZO   &&
#endif
                 encodings[0].compression.algo != MATROSKA_TRACK_ENCODING_COMP_HEADERSTRIP) {
                encodings[0].scope = 0;
                av_log(matroska->ctx, AV_LOG_ERROR,
                       "Unsupported encoding type");
            } else if (track->codec_priv.size && encodings[0].scope & 2) {
                uint8_t *codec_priv = track->codec_priv.data;
                int ret = matroska_decode_buffer(&track->codec_priv.data,
                                                 &track->codec_priv.size,
                                                 track);
                if (ret < 0) {
                    track->codec_priv.data = NULL;
                    track->codec_priv.size = 0;
                    av_log(matroska->ctx, AV_LOG_ERROR,
                           "Failed to decode codec private data\n");
                }

                if (codec_priv != track->codec_priv.data)
                    av_free(codec_priv);
            }
        }

        for (j = 0; ff_mkv_codec_tags[j].id != AV_CODEC_ID_NONE; j++) {
            if (!strncmp(ff_mkv_codec_tags[j].str, track->codec_id,
                         strlen(ff_mkv_codec_tags[j].str))) {
                codec_id = ff_mkv_codec_tags[j].id;
                break;
            }
        }

        st = track->stream = avformat_new_stream(s, NULL);
        if (!st) {
            av_free(key_id_base64);
            return AVERROR(ENOMEM);
        }

        if (key_id_base64) {
            /* export encryption key id as base64 metadata tag */
            av_dict_set(&st->metadata, "enc_key_id", key_id_base64, 0);
            av_freep(&key_id_base64);
        }

        if (!strcmp(track->codec_id, "V_MS/VFW/FOURCC") &&
             track->codec_priv.size >= 40               &&
            track->codec_priv.data) {
            track->ms_compat    = 1;
            bit_depth           = AV_RL16(track->codec_priv.data + 14);
            fourcc              = AV_RL32(track->codec_priv.data + 16);
            codec_id            = ff_codec_get_id(ff_codec_bmp_tags,
                                                  fourcc);
            if (!codec_id)
                codec_id        = ff_codec_get_id(ff_codec_movvideo_tags,
                                                  fourcc);
            extradata_offset    = 40;
        } else if (!strcmp(track->codec_id, "A_MS/ACM") &&
                   track->codec_priv.size >= 14         &&
                   track->codec_priv.data) {
            int ret;
            ffio_init_context(&b, track->codec_priv.data,
                              track->codec_priv.size,
                              0, NULL, NULL, NULL, NULL);
            ret = ff_get_wav_header(&b, st->codec, track->codec_priv.size, 0);
            if (ret < 0)
                return ret;
            codec_id         = st->codec->codec_id;
            extradata_offset = FFMIN(track->codec_priv.size, 18);
        } else if (!strcmp(track->codec_id, "A_QUICKTIME")
                   && (track->codec_priv.size >= 86)
                   && (track->codec_priv.data)) {
            fourcc = AV_RL32(track->codec_priv.data + 4);
            codec_id = ff_codec_get_id(ff_codec_movaudio_tags, fourcc);
            if (ff_codec_get_id(ff_codec_movaudio_tags, AV_RL32(track->codec_priv.data))) {
                fourcc = AV_RL32(track->codec_priv.data);
                codec_id = ff_codec_get_id(ff_codec_movaudio_tags, fourcc);
            }
        } else if (!strcmp(track->codec_id, "V_QUICKTIME") &&
                   (track->codec_priv.size >= 21)          &&
                   (track->codec_priv.data)) {
            fourcc   = AV_RL32(track->codec_priv.data + 4);
            codec_id = ff_codec_get_id(ff_codec_movvideo_tags, fourcc);
            if (ff_codec_get_id(ff_codec_movvideo_tags, AV_RL32(track->codec_priv.data))) {
                fourcc   = AV_RL32(track->codec_priv.data);
                codec_id = ff_codec_get_id(ff_codec_movvideo_tags, fourcc);
            }
            if (codec_id == AV_CODEC_ID_NONE && AV_RL32(track->codec_priv.data+4) == AV_RL32("SMI "))
                codec_id = AV_CODEC_ID_SVQ3;
        } else if (codec_id == AV_CODEC_ID_PCM_S16BE) {
            switch (track->audio.bitdepth) {
            case  8:
                codec_id = AV_CODEC_ID_PCM_U8;
                break;
            case 24:
                codec_id = AV_CODEC_ID_PCM_S24BE;
                break;
            case 32:
                codec_id = AV_CODEC_ID_PCM_S32BE;
                break;
            }
        } else if (codec_id == AV_CODEC_ID_PCM_S16LE) {
            switch (track->audio.bitdepth) {
            case  8:
                codec_id = AV_CODEC_ID_PCM_U8;
                break;
            case 24:
                codec_id = AV_CODEC_ID_PCM_S24LE;
                break;
            case 32:
                codec_id = AV_CODEC_ID_PCM_S32LE;
                break;
            }
        } else if (codec_id == AV_CODEC_ID_PCM_F32LE &&
                   track->audio.bitdepth == 64) {
            codec_id = AV_CODEC_ID_PCM_F64LE;
        } else if (codec_id == AV_CODEC_ID_AAC && !track->codec_priv.size) {
            int profile = matroska_aac_profile(track->codec_id);
            int sri     = matroska_aac_sri(track->audio.samplerate);
            extradata   = av_mallocz(5 + FF_INPUT_BUFFER_PADDING_SIZE);
            if (!extradata)
                return AVERROR(ENOMEM);
            extradata[0] = (profile << 3) | ((sri & 0x0E) >> 1);
            extradata[1] = ((sri & 0x01) << 7) | (track->audio.channels << 3);
            if (strstr(track->codec_id, "SBR")) {
                sri            = matroska_aac_sri(track->audio.out_samplerate);
                extradata[2]   = 0x56;
                extradata[3]   = 0xE5;
                extradata[4]   = 0x80 | (sri << 3);
                extradata_size = 5;
            } else
                extradata_size = 2;
        } else if (codec_id == AV_CODEC_ID_ALAC && track->codec_priv.size && track->codec_priv.size < INT_MAX - 12 - FF_INPUT_BUFFER_PADDING_SIZE) {
            /* Only ALAC's magic cookie is stored in Matroska's track headers.
             * Create the "atom size", "tag", and "tag version" fields the
             * decoder expects manually. */
            extradata_size = 12 + track->codec_priv.size;
            extradata      = av_mallocz(extradata_size +
                                        FF_INPUT_BUFFER_PADDING_SIZE);
            if (!extradata)
                return AVERROR(ENOMEM);
            AV_WB32(extradata, extradata_size);
            memcpy(&extradata[4], "alac", 4);
            AV_WB32(&extradata[8], 0);
            memcpy(&extradata[12], track->codec_priv.data,
                   track->codec_priv.size);
        } else if (codec_id == AV_CODEC_ID_TTA) {
            extradata_size = 30;
            extradata      = av_mallocz(extradata_size + FF_INPUT_BUFFER_PADDING_SIZE);
            if (!extradata)
                return AVERROR(ENOMEM);
            ffio_init_context(&b, extradata, extradata_size, 1,
                              NULL, NULL, NULL, NULL);
            avio_write(&b, "TTA1", 4);
            avio_wl16(&b, 1);
            avio_wl16(&b, track->audio.channels);
            avio_wl16(&b, track->audio.bitdepth);
            if (track->audio.out_samplerate < 0 || track->audio.out_samplerate > INT_MAX)
                return AVERROR_INVALIDDATA;
            avio_wl32(&b, track->audio.out_samplerate);
            avio_wl32(&b, av_rescale((matroska->duration * matroska->time_scale),
                                     track->audio.out_samplerate,
                                     AV_TIME_BASE * 1000));
        } else if (codec_id == AV_CODEC_ID_RV10 ||
                   codec_id == AV_CODEC_ID_RV20 ||
                   codec_id == AV_CODEC_ID_RV30 ||
                   codec_id == AV_CODEC_ID_RV40) {
            extradata_offset = 26;
        } else if (codec_id == AV_CODEC_ID_RA_144) {
            track->audio.out_samplerate = 8000;
            track->audio.channels       = 1;
        } else if ((codec_id == AV_CODEC_ID_RA_288 ||
                    codec_id == AV_CODEC_ID_COOK   ||
                    codec_id == AV_CODEC_ID_ATRAC3 ||
                    codec_id == AV_CODEC_ID_SIPR)
                      && track->codec_priv.data) {
            int flavor;

            ffio_init_context(&b, track->codec_priv.data,
                              track->codec_priv.size,
                              0, NULL, NULL, NULL, NULL);
            avio_skip(&b, 22);
            flavor                       = avio_rb16(&b);
            track->audio.coded_framesize = avio_rb32(&b);
            avio_skip(&b, 12);
            track->audio.sub_packet_h    = avio_rb16(&b);
            track->audio.frame_size      = avio_rb16(&b);
            track->audio.sub_packet_size = avio_rb16(&b);
            if (flavor                        < 0 ||
                track->audio.coded_framesize <= 0 ||
                track->audio.sub_packet_h    <= 0 ||
                track->audio.frame_size      <= 0 ||
                track->audio.sub_packet_size <= 0)
                return AVERROR_INVALIDDATA;
            track->audio.buf = av_malloc_array(track->audio.sub_packet_h,
                                               track->audio.frame_size);
            if (!track->audio.buf)
                return AVERROR(ENOMEM);
            if (codec_id == AV_CODEC_ID_RA_288) {
                st->codec->block_align = track->audio.coded_framesize;
                track->codec_priv.size = 0;
            } else {
                if (codec_id == AV_CODEC_ID_SIPR && flavor < 4) {
                    static const int sipr_bit_rate[4] = { 6504, 8496, 5000, 16000 };
                    track->audio.sub_packet_size = ff_sipr_subpk_size[flavor];
                    st->codec->bit_rate          = sipr_bit_rate[flavor];
                }
                st->codec->block_align = track->audio.sub_packet_size;
                extradata_offset       = 78;
            }
        } else if (codec_id == AV_CODEC_ID_FLAC && track->codec_priv.size) {
            ret = matroska_parse_flac(s, track, &extradata_offset);
            if (ret < 0)
                return ret;
        } else if (codec_id == AV_CODEC_ID_PRORES && track->codec_priv.size == 4) {
            fourcc = AV_RL32(track->codec_priv.data);
        }
        track->codec_priv.size -= extradata_offset;

        if (codec_id == AV_CODEC_ID_NONE)
            av_log(matroska->ctx, AV_LOG_INFO,
                   "Unknown/unsupported AVCodecID %s.\n", track->codec_id);

        if (track->time_scale < 0.01)
            track->time_scale = 1.0;
        avpriv_set_pts_info(st, 64, matroska->time_scale * track->time_scale,
                            1000 * 1000 * 1000);    /* 64 bit pts in ns */

        /* convert the delay from ns to the track timebase */
        track->codec_delay = av_rescale_q(track->codec_delay,
                                          (AVRational){ 1, 1000000000 },
                                          st->time_base);

        st->codec->codec_id = codec_id;

        if (strcmp(track->language, "und"))
            av_dict_set(&st->metadata, "language", track->language, 0);
        av_dict_set(&st->metadata, "title", track->name, 0);

        if (track->flag_default)
            st->disposition |= AV_DISPOSITION_DEFAULT;
        if (track->flag_forced)
            st->disposition |= AV_DISPOSITION_FORCED;

        if (!st->codec->extradata) {
            if (extradata) {
                st->codec->extradata      = extradata;
                st->codec->extradata_size = extradata_size;
            } else if (track->codec_priv.data && track->codec_priv.size > 0) {
                if (ff_alloc_extradata(st->codec, track->codec_priv.size))
                    return AVERROR(ENOMEM);
                memcpy(st->codec->extradata,
                       track->codec_priv.data + extradata_offset,
                       track->codec_priv.size);
            }
        }

        if (track->type == MATROSKA_TRACK_TYPE_VIDEO) {
            MatroskaTrackPlane *planes = track->operation.combine_planes.elem;

            st->codec->codec_type = AVMEDIA_TYPE_VIDEO;
            st->codec->codec_tag  = fourcc;
            if (bit_depth >= 0)
                st->codec->bits_per_coded_sample = bit_depth;
            st->codec->width      = track->video.pixel_width;
            st->codec->height     = track->video.pixel_height;
            av_reduce(&st->sample_aspect_ratio.num,
                      &st->sample_aspect_ratio.den,
                      st->codec->height * track->video.display_width,
                      st->codec->width  * track->video.display_height,
                      255);
            if (st->codec->codec_id != AV_CODEC_ID_HEVC)
                st->need_parsing = AVSTREAM_PARSE_HEADERS;

            if (track->default_duration) {
                av_reduce(&st->avg_frame_rate.num, &st->avg_frame_rate.den,
                          1000000000, track->default_duration, 30000);
#if FF_API_R_FRAME_RATE
                if (   st->avg_frame_rate.num < st->avg_frame_rate.den * 1000LL
                    && st->avg_frame_rate.num > st->avg_frame_rate.den * 5LL)
                    st->r_frame_rate = st->avg_frame_rate;
#endif
            }

            /* export stereo mode flag as metadata tag */
            if (track->video.stereo_mode && track->video.stereo_mode < MATROSKA_VIDEO_STEREOMODE_TYPE_NB)
                av_dict_set(&st->metadata, "stereo_mode", ff_matroska_video_stereo_mode[track->video.stereo_mode], 0);

            /* export alpha mode flag as metadata tag  */
            if (track->video.alpha_mode)
                av_dict_set(&st->metadata, "alpha_mode", "1", 0);

            /* if we have virtual track, mark the real tracks */
            for (j=0; j < track->operation.combine_planes.nb_elem; j++) {
                char buf[32];
                if (planes[j].type >= MATROSKA_VIDEO_STEREO_PLANE_COUNT)
                    continue;
                snprintf(buf, sizeof(buf), "%s_%d",
                         ff_matroska_video_stereo_plane[planes[j].type], i);
                for (k=0; k < matroska->tracks.nb_elem; k++)
                    if (planes[j].uid == tracks[k].uid) {
                        av_dict_set(&s->streams[k]->metadata,
                                    "stereo_mode", buf, 0);
                        break;
                    }
            }
            // add stream level stereo3d side data if it is a supported format
            if (track->video.stereo_mode < MATROSKA_VIDEO_STEREOMODE_TYPE_NB &&
                track->video.stereo_mode != 10 && track->video.stereo_mode != 12) {
                int ret = ff_mkv_stereo3d_conv(st, track->video.stereo_mode);
                if (ret < 0)
                    return ret;
            }
        } else if (track->type == MATROSKA_TRACK_TYPE_AUDIO) {
            st->codec->codec_type  = AVMEDIA_TYPE_AUDIO;
            st->codec->sample_rate = track->audio.out_samplerate;
            st->codec->channels    = track->audio.channels;
            if (!st->codec->bits_per_coded_sample)
                st->codec->bits_per_coded_sample = track->audio.bitdepth;
            if (st->codec->codec_id != AV_CODEC_ID_AAC)
                st->need_parsing = AVSTREAM_PARSE_HEADERS;
            if (track->codec_delay > 0) {
                st->codec->delay = av_rescale_q(track->codec_delay,
                                                st->time_base,
                                                (AVRational){1, st->codec->sample_rate});
            }
            if (track->seek_preroll > 0) {
                av_codec_set_seek_preroll(st->codec,
                                          av_rescale_q(track->seek_preroll,
                                                       (AVRational){1, 1000000000},
                                                       (AVRational){1, st->codec->sample_rate}));
            }
        } else if (codec_id == AV_CODEC_ID_WEBVTT) {
            st->codec->codec_type = AVMEDIA_TYPE_SUBTITLE;

            if (!strcmp(track->codec_id, "D_WEBVTT/CAPTIONS")) {
                st->disposition |= AV_DISPOSITION_CAPTIONS;
            } else if (!strcmp(track->codec_id, "D_WEBVTT/DESCRIPTIONS")) {
                st->disposition |= AV_DISPOSITION_DESCRIPTIONS;
            } else if (!strcmp(track->codec_id, "D_WEBVTT/METADATA")) {
                st->disposition |= AV_DISPOSITION_METADATA;
            }
        } else if (track->type == MATROSKA_TRACK_TYPE_SUBTITLE) {
            st->codec->codec_type = AVMEDIA_TYPE_SUBTITLE;
            if (st->codec->codec_id == AV_CODEC_ID_ASS)
                matroska->contains_ssa = 1;
        }
    }

    return 0;
}

static int matroska_read_header(AVFormatContext *s)
{
    MatroskaDemuxContext *matroska = s->priv_data;
    EbmlList *attachments_list = &matroska->attachments;
    EbmlList *chapters_list    = &matroska->chapters;
    MatroskaAttachment *attachments;
    MatroskaChapter *chapters;
    uint64_t max_start = 0;
    int64_t pos;
    Ebml ebml = { 0 };
    int i, j, res;

    matroska->ctx = s;
    matroska->cues_parsing_deferred = 1;

    /* First read the EBML header. */
    if (ebml_parse(matroska, ebml_syntax, &ebml) ||
        ebml.version         > EBML_VERSION      ||
        ebml.max_size        > sizeof(uint64_t)  ||
        ebml.id_length       > sizeof(uint32_t)  ||
        ebml.doctype_version > 3                 ||
        !ebml.doctype) {
        av_log(matroska->ctx, AV_LOG_ERROR,
               "EBML header using unsupported features\n"
               "(EBML version %"PRIu64", doctype %s, doc version %"PRIu64")\n",
               ebml.version, ebml.doctype, ebml.doctype_version);
        ebml_free(ebml_syntax, &ebml);
        return AVERROR_PATCHWELCOME;
    } else if (ebml.doctype_version == 3) {
        av_log(matroska->ctx, AV_LOG_WARNING,
               "EBML header using unsupported features\n"
               "(EBML version %"PRIu64", doctype %s, doc version %"PRIu64")\n",
               ebml.version, ebml.doctype, ebml.doctype_version);
    }
    for (i = 0; i < FF_ARRAY_ELEMS(matroska_doctypes); i++)
        if (!strcmp(ebml.doctype, matroska_doctypes[i]))
            break;
    if (i >= FF_ARRAY_ELEMS(matroska_doctypes)) {
        av_log(s, AV_LOG_WARNING, "Unknown EBML doctype '%s'\n", ebml.doctype);
        if (matroska->ctx->error_recognition & AV_EF_EXPLODE) {
            ebml_free(ebml_syntax, &ebml);
            return AVERROR_INVALIDDATA;
        }
    }
    ebml_free(ebml_syntax, &ebml);

    /* The next thing is a segment. */
    pos = avio_tell(matroska->ctx->pb);
    res = ebml_parse(matroska, matroska_segments, matroska);
    // try resyncing until we find a EBML_STOP type element.
    while (res != 1) {
        res = matroska_resync(matroska, pos);
        if (res < 0)
            return res;
        pos = avio_tell(matroska->ctx->pb);
        res = ebml_parse(matroska, matroska_segment, matroska);
    }
    matroska_execute_seekhead(matroska);

    if (!matroska->time_scale)
        matroska->time_scale = 1000000;
    if (matroska->duration)
        matroska->ctx->duration = matroska->duration * matroska->time_scale *
                                  1000 / AV_TIME_BASE;
    av_dict_set(&s->metadata, "title", matroska->title, 0);
    av_dict_set(&s->metadata, "encoder", matroska->muxingapp, 0);

    if (matroska->date_utc.size == 8)
        matroska_metadata_creation_time(&s->metadata, AV_RB64(matroska->date_utc.data));

    res = matroska_parse_tracks(s);
    if (res < 0)
        return res;

    attachments = attachments_list->elem;
    for (j = 0; j < attachments_list->nb_elem; j++) {
        if (!(attachments[j].filename && attachments[j].mime &&
              attachments[j].bin.data && attachments[j].bin.size > 0)) {
            av_log(matroska->ctx, AV_LOG_ERROR, "incomplete attachment\n");
        } else {
            AVStream *st = avformat_new_stream(s, NULL);
            if (!st)
                break;
            av_dict_set(&st->metadata, "filename", attachments[j].filename, 0);
            av_dict_set(&st->metadata, "mimetype", attachments[j].mime, 0);
            st->codec->codec_id   = AV_CODEC_ID_NONE;
            st->codec->codec_type = AVMEDIA_TYPE_ATTACHMENT;
            if (ff_alloc_extradata(st->codec, attachments[j].bin.size))
                break;
            memcpy(st->codec->extradata, attachments[j].bin.data,
                   attachments[j].bin.size);

            for (i = 0; ff_mkv_mime_tags[i].id != AV_CODEC_ID_NONE; i++) {
                if (!strncmp(ff_mkv_mime_tags[i].str, attachments[j].mime,
                             strlen(ff_mkv_mime_tags[i].str))) {
                    st->codec->codec_id = ff_mkv_mime_tags[i].id;
                    break;
                }
            }
            attachments[j].stream = st;
        }
    }

    chapters = chapters_list->elem;
    for (i = 0; i < chapters_list->nb_elem; i++)
        if (chapters[i].start != AV_NOPTS_VALUE && chapters[i].uid &&
            (max_start == 0 || chapters[i].start > max_start)) {
            chapters[i].chapter =
                avpriv_new_chapter(s, chapters[i].uid,
                                   (AVRational) { 1, 1000000000 },
                                   chapters[i].start, chapters[i].end,
                                   chapters[i].title);
            if (chapters[i].chapter) {
                av_dict_set(&chapters[i].chapter->metadata,
                            "title", chapters[i].title, 0);
            }
            max_start = chapters[i].start;
        }

    matroska_add_index_entries(matroska);

    matroska_convert_tags(s);

    return 0;
}

/*
 * Put one packet in an application-supplied AVPacket struct.
 * Returns 0 on success or -1 on failure.
 */
static int matroska_deliver_packet(MatroskaDemuxContext *matroska,
                                   AVPacket *pkt)
{
    if (matroska->num_packets > 0) {
        memcpy(pkt, matroska->packets[0], sizeof(AVPacket));
        av_freep(&matroska->packets[0]);
        if (matroska->num_packets > 1) {
            void *newpackets;
            memmove(&matroska->packets[0], &matroska->packets[1],
                    (matroska->num_packets - 1) * sizeof(AVPacket *));
            newpackets = av_realloc(matroska->packets,
                                    (matroska->num_packets - 1) *
                                    sizeof(AVPacket *));
            if (newpackets)
                matroska->packets = newpackets;
        } else {
            av_freep(&matroska->packets);
            matroska->prev_pkt = NULL;
        }
        matroska->num_packets--;
        return 0;
    }

    return -1;
}

/*
 * Free all packets in our internal queue.
 */
static void matroska_clear_queue(MatroskaDemuxContext *matroska)
{
    matroska->prev_pkt = NULL;
    if (matroska->packets) {
        int n;
        for (n = 0; n < matroska->num_packets; n++) {
            av_free_packet(matroska->packets[n]);
            av_freep(&matroska->packets[n]);
        }
        av_freep(&matroska->packets);
        matroska->num_packets = 0;
    }
}

static int matroska_parse_laces(MatroskaDemuxContext *matroska, uint8_t **buf,
                                int *buf_size, int type,
                                uint32_t **lace_buf, int *laces)
{
    int res = 0, n, size = *buf_size;
    uint8_t *data = *buf;
    uint32_t *lace_size;

    if (!type) {
        *laces    = 1;
        *lace_buf = av_mallocz(sizeof(int));
        if (!*lace_buf)
            return AVERROR(ENOMEM);

        *lace_buf[0] = size;
        return 0;
    }

    av_assert0(size > 0);
    *laces    = *data + 1;
    data     += 1;
    size     -= 1;
    lace_size = av_mallocz(*laces * sizeof(int));
    if (!lace_size)
        return AVERROR(ENOMEM);

    switch (type) {
    case 0x1: /* Xiph lacing */
    {
        uint8_t temp;
        uint32_t total = 0;
        for (n = 0; res == 0 && n < *laces - 1; n++) {
            while (1) {
                if (size <= total) {
                    res = AVERROR_INVALIDDATA;
                    break;
                }
                temp          = *data;
                total        += temp;
                lace_size[n] += temp;
                data         += 1;
                size         -= 1;
                if (temp != 0xff)
                    break;
            }
        }
        if (size <= total) {
            res = AVERROR_INVALIDDATA;
            break;
        }

        lace_size[n] = size - total;
        break;
    }

    case 0x2: /* fixed-size lacing */
        if (size % (*laces)) {
            res = AVERROR_INVALIDDATA;
            break;
        }
        for (n = 0; n < *laces; n++)
            lace_size[n] = size / *laces;
        break;

    case 0x3: /* EBML lacing */
    {
        uint64_t num;
        uint64_t total;
        n = matroska_ebmlnum_uint(matroska, data, size, &num);
        if (n < 0 || num > INT_MAX) {
            av_log(matroska->ctx, AV_LOG_INFO,
                   "EBML block data error\n");
            res = n<0 ? n : AVERROR_INVALIDDATA;
            break;
        }
        data += n;
        size -= n;
        total = lace_size[0] = num;
        for (n = 1; res == 0 && n < *laces - 1; n++) {
            int64_t snum;
            int r;
            r = matroska_ebmlnum_sint(matroska, data, size, &snum);
            if (r < 0 || lace_size[n - 1] + snum > (uint64_t)INT_MAX) {
                av_log(matroska->ctx, AV_LOG_INFO,
                       "EBML block data error\n");
                res = r<0 ? r : AVERROR_INVALIDDATA;
                break;
            }
            data        += r;
            size        -= r;
            lace_size[n] = lace_size[n - 1] + snum;
            total       += lace_size[n];
        }
        if (size <= total) {
            res = AVERROR_INVALIDDATA;
            break;
        }
        lace_size[*laces - 1] = size - total;
        break;
    }
    }

    *buf      = data;
    *lace_buf = lace_size;
    *buf_size = size;

    return res;
}

static int matroska_parse_rm_audio(MatroskaDemuxContext *matroska,
                                   MatroskaTrack *track, AVStream *st,
                                   uint8_t *data, int size, uint64_t timecode,
                                   int64_t pos)
{
    int a = st->codec->block_align;
    int sps = track->audio.sub_packet_size;
    int cfs = track->audio.coded_framesize;
    int h   = track->audio.sub_packet_h;
    int y   = track->audio.sub_packet_cnt;
    int w   = track->audio.frame_size;
    int x;

    if (!track->audio.pkt_cnt) {
        if (track->audio.sub_packet_cnt == 0)
            track->audio.buf_timecode = timecode;
        if (st->codec->codec_id == AV_CODEC_ID_RA_288) {
            if (size < cfs * h / 2) {
                av_log(matroska->ctx, AV_LOG_ERROR,
                       "Corrupt int4 RM-style audio packet size\n");
                return AVERROR_INVALIDDATA;
            }
            for (x = 0; x < h / 2; x++)
                memcpy(track->audio.buf + x * 2 * w + y * cfs,
                       data + x * cfs, cfs);
        } else if (st->codec->codec_id == AV_CODEC_ID_SIPR) {
            if (size < w) {
                av_log(matroska->ctx, AV_LOG_ERROR,
                       "Corrupt sipr RM-style audio packet size\n");
                return AVERROR_INVALIDDATA;
            }
            memcpy(track->audio.buf + y * w, data, w);
        } else {
            if (size < sps * w / sps || h<=0 || w%sps) {
                av_log(matroska->ctx, AV_LOG_ERROR,
                       "Corrupt generic RM-style audio packet size\n");
                return AVERROR_INVALIDDATA;
            }
            for (x = 0; x < w / sps; x++)
                memcpy(track->audio.buf +
                       sps * (h * x + ((h + 1) / 2) * (y & 1) + (y >> 1)),
                       data + x * sps, sps);
        }

        if (++track->audio.sub_packet_cnt >= h) {
            if (st->codec->codec_id == AV_CODEC_ID_SIPR)
                ff_rm_reorder_sipr_data(track->audio.buf, h, w);
            track->audio.sub_packet_cnt = 0;
            track->audio.pkt_cnt        = h * w / a;
        }
    }

    while (track->audio.pkt_cnt) {
        int ret;
        AVPacket *pkt = av_mallocz(sizeof(AVPacket));
        if (!pkt)
            return AVERROR(ENOMEM);

        ret = av_new_packet(pkt, a);
        if (ret < 0) {
            av_free(pkt);
            return ret;
        }
        memcpy(pkt->data,
               track->audio.buf + a * (h * w / a - track->audio.pkt_cnt--),
               a);
        pkt->pts                  = track->audio.buf_timecode;
        track->audio.buf_timecode = AV_NOPTS_VALUE;
        pkt->pos                  = pos;
        pkt->stream_index         = st->index;
        dynarray_add(&matroska->packets, &matroska->num_packets, pkt);
    }

    return 0;
}

/* reconstruct full wavpack blocks from mangled matroska ones */
static int matroska_parse_wavpack(MatroskaTrack *track, uint8_t *src,
                                  uint8_t **pdst, int *size)
{
    uint8_t *dst = NULL;
    int dstlen   = 0;
    int srclen   = *size;
    uint32_t samples;
    uint16_t ver;
    int ret, offset = 0;

    if (srclen < 12 || track->stream->codec->extradata_size < 2)
        return AVERROR_INVALIDDATA;

    ver = AV_RL16(track->stream->codec->extradata);

    samples = AV_RL32(src);
    src    += 4;
    srclen -= 4;

    while (srclen >= 8) {
        int multiblock;
        uint32_t blocksize;
        uint8_t *tmp;

        uint32_t flags = AV_RL32(src);
        uint32_t crc   = AV_RL32(src + 4);
        src    += 8;
        srclen -= 8;

        multiblock = (flags & 0x1800) != 0x1800;
        if (multiblock) {
            if (srclen < 4) {
                ret = AVERROR_INVALIDDATA;
                goto fail;
            }
            blocksize = AV_RL32(src);
            src      += 4;
            srclen   -= 4;
        } else
            blocksize = srclen;

        if (blocksize > srclen) {
            ret = AVERROR_INVALIDDATA;
            goto fail;
        }

        tmp = av_realloc(dst, dstlen + blocksize + 32);
        if (!tmp) {
            ret = AVERROR(ENOMEM);
            goto fail;
        }
        dst     = tmp;
        dstlen += blocksize + 32;

        AV_WL32(dst + offset, MKTAG('w', 'v', 'p', 'k'));   // tag
        AV_WL32(dst + offset +  4, blocksize + 24);         // blocksize - 8
        AV_WL16(dst + offset +  8, ver);                    // version
        AV_WL16(dst + offset + 10, 0);                      // track/index_no
        AV_WL32(dst + offset + 12, 0);                      // total samples
        AV_WL32(dst + offset + 16, 0);                      // block index
        AV_WL32(dst + offset + 20, samples);                // number of samples
        AV_WL32(dst + offset + 24, flags);                  // flags
        AV_WL32(dst + offset + 28, crc);                    // crc
        memcpy(dst + offset + 32, src, blocksize);          // block data

        src    += blocksize;
        srclen -= blocksize;
        offset += blocksize + 32;
    }

    *pdst = dst;
    *size = dstlen;

    return 0;

fail:
    av_freep(&dst);
    return ret;
}

static int matroska_parse_webvtt(MatroskaDemuxContext *matroska,
                                 MatroskaTrack *track,
                                 AVStream *st,
                                 uint8_t *data, int data_len,
                                 uint64_t timecode,
                                 uint64_t duration,
                                 int64_t pos)
{
    AVPacket *pkt;
    uint8_t *id, *settings, *text, *buf;
    int id_len, settings_len, text_len;
    uint8_t *p, *q;
    int err;

    if (data_len <= 0)
        return AVERROR_INVALIDDATA;

    p = data;
    q = data + data_len;

    id = p;
    id_len = -1;
    while (p < q) {
        if (*p == '\r' || *p == '\n') {
            id_len = p - id;
            if (*p == '\r')
                p++;
            break;
        }
        p++;
    }

    if (p >= q || *p != '\n')
        return AVERROR_INVALIDDATA;
    p++;

    settings = p;
    settings_len = -1;
    while (p < q) {
        if (*p == '\r' || *p == '\n') {
            settings_len = p - settings;
            if (*p == '\r')
                p++;
            break;
        }
        p++;
    }

    if (p >= q || *p != '\n')
        return AVERROR_INVALIDDATA;
    p++;

    text = p;
    text_len = q - p;
    while (text_len > 0) {
        const int len = text_len - 1;
        const uint8_t c = p[len];
        if (c != '\r' && c != '\n')
            break;
        text_len = len;
    }

    if (text_len <= 0)
        return AVERROR_INVALIDDATA;

    pkt = av_mallocz(sizeof(*pkt));
    if (!pkt)
        return AVERROR(ENOMEM);
    err = av_new_packet(pkt, text_len);
    if (err < 0) {
        av_free(pkt);
        return AVERROR(err);
    }

    memcpy(pkt->data, text, text_len);

    if (id_len > 0) {
        buf = av_packet_new_side_data(pkt,
                                      AV_PKT_DATA_WEBVTT_IDENTIFIER,
                                      id_len);
        if (!buf) {
            av_free(pkt);
            return AVERROR(ENOMEM);
        }
        memcpy(buf, id, id_len);
    }

    if (settings_len > 0) {
        buf = av_packet_new_side_data(pkt,
                                      AV_PKT_DATA_WEBVTT_SETTINGS,
                                      settings_len);
        if (!buf) {
            av_free(pkt);
            return AVERROR(ENOMEM);
        }
        memcpy(buf, settings, settings_len);
    }

    // Do we need this for subtitles?
    // pkt->flags = AV_PKT_FLAG_KEY;

    pkt->stream_index = st->index;
    pkt->pts = timecode;

    // Do we need this for subtitles?
    // pkt->dts = timecode;

    pkt->duration = duration;
    pkt->pos = pos;

    dynarray_add(&matroska->packets, &matroska->num_packets, pkt);
    matroska->prev_pkt = pkt;

    return 0;
}

static int matroska_parse_frame(MatroskaDemuxContext *matroska,
                                MatroskaTrack *track, AVStream *st,
                                uint8_t *data, int pkt_size,
                                uint64_t timecode, uint64_t lace_duration,
                                int64_t pos, int is_keyframe,
                                uint8_t *additional, uint64_t additional_id, int additional_size,
                                int64_t discard_padding)
{
    MatroskaTrackEncoding *encodings = track->encodings.elem;
    uint8_t *pkt_data = data;
    int offset = 0, res;
    AVPacket *pkt;

    if (encodings && !encodings->type && encodings->scope & 1) {
        res = matroska_decode_buffer(&pkt_data, &pkt_size, track);
        if (res < 0)
            return res;
    }

    if (st->codec->codec_id == AV_CODEC_ID_WAVPACK) {
        uint8_t *wv_data;
        res = matroska_parse_wavpack(track, pkt_data, &wv_data, &pkt_size);
        if (res < 0) {
            av_log(matroska->ctx, AV_LOG_ERROR,
                   "Error parsing a wavpack block.\n");
            goto fail;
        }
        if (pkt_data != data)
            av_freep(&pkt_data);
        pkt_data = wv_data;
    }

    if (st->codec->codec_id == AV_CODEC_ID_PRORES &&
        AV_RB32(&data[4]) != MKBETAG('i', 'c', 'p', 'f'))
        offset = 8;

    pkt = av_mallocz(sizeof(AVPacket));
    if (!pkt)
        return AVERROR(ENOMEM);
    /* XXX: prevent data copy... */
    if (av_new_packet(pkt, pkt_size + offset) < 0) {
        av_free(pkt);
        res = AVERROR(ENOMEM);
        goto fail;
    }

    if (st->codec->codec_id == AV_CODEC_ID_PRORES && offset == 8) {
        uint8_t *buf = pkt->data;
        bytestream_put_be32(&buf, pkt_size);
        bytestream_put_be32(&buf, MKBETAG('i', 'c', 'p', 'f'));
    }

    memcpy(pkt->data + offset, pkt_data, pkt_size);

    if (pkt_data != data)
        av_freep(&pkt_data);

    pkt->flags        = is_keyframe;
    pkt->stream_index = st->index;

    if (additional_size > 0) {
        uint8_t *side_data = av_packet_new_side_data(pkt,
                                                     AV_PKT_DATA_MATROSKA_BLOCKADDITIONAL,
                                                     additional_size + 8);
        if (!side_data) {
            av_free_packet(pkt);
            av_free(pkt);
            return AVERROR(ENOMEM);
        }
        AV_WB64(side_data, additional_id);
        memcpy(side_data + 8, additional, additional_size);
    }

    if (discard_padding) {
        uint8_t *side_data = av_packet_new_side_data(pkt,
                                                     AV_PKT_DATA_SKIP_SAMPLES,
                                                     10);
        if (!side_data) {
            av_free_packet(pkt);
            av_free(pkt);
            return AVERROR(ENOMEM);
        }
        AV_WL32(side_data, 0);
        AV_WL32(side_data + 4, av_rescale_q(discard_padding,
                                            (AVRational){1, 1000000000},
                                            (AVRational){1, st->codec->sample_rate}));
    }

    if (track->ms_compat)
        pkt->dts = timecode;
    else
        pkt->pts = timecode;
    pkt->pos = pos;
    if (st->codec->codec_id == AV_CODEC_ID_SUBRIP) {
        /*
         * For backward compatibility.
         * Historically, we have put subtitle duration
         * in convergence_duration, on the off chance
         * that the time_scale is less than 1us, which
         * could result in a 32bit overflow on the
         * normal duration field.
         */
        pkt->convergence_duration = lace_duration;
    }

    if (track->type != MATROSKA_TRACK_TYPE_SUBTITLE ||
        lace_duration <= INT_MAX) {
        /*
         * For non subtitle tracks, just store the duration
         * as normal.
         *
         * If it's a subtitle track and duration value does
         * not overflow a uint32, then also store it normally.
         */
        pkt->duration = lace_duration;
    }

    dynarray_add(&matroska->packets, &matroska->num_packets, pkt);
    matroska->prev_pkt = pkt;

    return 0;

fail:
    if (pkt_data != data)
        av_freep(&pkt_data);
    return res;
}

static int matroska_parse_block(MatroskaDemuxContext *matroska, uint8_t *data,
                                int size, int64_t pos, uint64_t cluster_time,
                                uint64_t block_duration, int is_keyframe,
                                uint8_t *additional, uint64_t additional_id, int additional_size,
                                int64_t cluster_pos, int64_t discard_padding)
{
    uint64_t timecode = AV_NOPTS_VALUE;
    MatroskaTrack *track;
    int res = 0;
    AVStream *st;
    int16_t block_time;
    uint32_t *lace_size = NULL;
    int n, flags, laces = 0;
    uint64_t num;
    int trust_default_duration = 1;

    if ((n = matroska_ebmlnum_uint(matroska, data, size, &num)) < 0) {
        av_log(matroska->ctx, AV_LOG_ERROR, "EBML block data error\n");
        return n;
    }
    data += n;
    size -= n;

    track = matroska_find_track_by_num(matroska, num);
    if (!track || !track->stream) {
        av_log(matroska->ctx, AV_LOG_INFO,
               "Invalid stream %"PRIu64" or size %u\n", num, size);
        return AVERROR_INVALIDDATA;
    } else if (size <= 3)
        return 0;
    st = track->stream;
    if (st->discard >= AVDISCARD_ALL)
        return res;
    av_assert1(block_duration != AV_NOPTS_VALUE);

    block_time = sign_extend(AV_RB16(data), 16);
    data      += 2;
    flags      = *data++;
    size      -= 3;
    if (is_keyframe == -1)
        is_keyframe = flags & 0x80 ? AV_PKT_FLAG_KEY : 0;

    if (cluster_time != (uint64_t) -1 &&
        (block_time >= 0 || cluster_time >= -block_time)) {
        timecode = cluster_time + block_time - track->codec_delay;
        if (track->type == MATROSKA_TRACK_TYPE_SUBTITLE &&
            timecode < track->end_timecode)
            is_keyframe = 0;  /* overlapping subtitles are not key frame */
        if (is_keyframe)
            av_add_index_entry(st, cluster_pos, timecode, 0, 0,
                               AVINDEX_KEYFRAME);
    }

    if (matroska->skip_to_keyframe &&
        track->type != MATROSKA_TRACK_TYPE_SUBTITLE) {
        if (timecode < matroska->skip_to_timecode)
            return res;
        if (is_keyframe)
            matroska->skip_to_keyframe = 0;
        else if (!st->skip_to_keyframe) {
            av_log(matroska->ctx, AV_LOG_ERROR, "File is broken, keyframes not correctly marked!\n");
            matroska->skip_to_keyframe = 0;
        }
    }

    res = matroska_parse_laces(matroska, &data, &size, (flags & 0x06) >> 1,
                               &lace_size, &laces);

    if (res)
        goto end;

    if (track->audio.samplerate == 8000) {
        // If this is needed for more codecs, then add them here
        if (st->codec->codec_id == AV_CODEC_ID_AC3) {
            if (track->audio.samplerate != st->codec->sample_rate || !st->codec->frame_size)
                trust_default_duration = 0;
        }
    }

    if (!block_duration && trust_default_duration)
        block_duration = track->default_duration * laces / matroska->time_scale;

    if (cluster_time != (uint64_t)-1 && (block_time >= 0 || cluster_time >= -block_time))
        track->end_timecode =
            FFMAX(track->end_timecode, timecode + block_duration);

    for (n = 0; n < laces; n++) {
        int64_t lace_duration = block_duration*(n+1) / laces - block_duration*n / laces;

        if (lace_size[n] > size) {
            av_log(matroska->ctx, AV_LOG_ERROR, "Invalid packet size\n");
            break;
        }

        if ((st->codec->codec_id == AV_CODEC_ID_RA_288 ||
             st->codec->codec_id == AV_CODEC_ID_COOK   ||
             st->codec->codec_id == AV_CODEC_ID_SIPR   ||
             st->codec->codec_id == AV_CODEC_ID_ATRAC3) &&
            st->codec->block_align && track->audio.sub_packet_size) {
            res = matroska_parse_rm_audio(matroska, track, st, data,
                                          lace_size[n],
                                          timecode, pos);
            if (res)
                goto end;

        } else if (st->codec->codec_id == AV_CODEC_ID_WEBVTT) {
            res = matroska_parse_webvtt(matroska, track, st,
                                        data, lace_size[n],
                                        timecode, lace_duration,
                                        pos);
            if (res)
                goto end;
        } else {
            res = matroska_parse_frame(matroska, track, st, data, lace_size[n],
                                       timecode, lace_duration, pos,
                                       !n ? is_keyframe : 0,
                                       additional, additional_id, additional_size,
                                       discard_padding);
            if (res)
                goto end;
        }

        if (timecode != AV_NOPTS_VALUE)
            timecode = lace_duration ? timecode + lace_duration : AV_NOPTS_VALUE;
        data += lace_size[n];
        size -= lace_size[n];
    }

end:
    av_free(lace_size);
    return res;
}

static int matroska_parse_cluster_incremental(MatroskaDemuxContext *matroska)
{
    EbmlList *blocks_list;
    MatroskaBlock *blocks;
    int i, res;
    res = ebml_parse(matroska,
                     matroska_cluster_incremental_parsing,
                     &matroska->current_cluster);
    if (res == 1) {
        /* New Cluster */
        if (matroska->current_cluster_pos)
            ebml_level_end(matroska);
        ebml_free(matroska_cluster, &matroska->current_cluster);
        memset(&matroska->current_cluster, 0, sizeof(MatroskaCluster));
        matroska->current_cluster_num_blocks = 0;
        matroska->current_cluster_pos        = avio_tell(matroska->ctx->pb);
        matroska->prev_pkt                   = NULL;
        /* sizeof the ID which was already read */
        if (matroska->current_id)
            matroska->current_cluster_pos -= 4;
        res = ebml_parse(matroska,
                         matroska_clusters_incremental,
                         &matroska->current_cluster);
        /* Try parsing the block again. */
        if (res == 1)
            res = ebml_parse(matroska,
                             matroska_cluster_incremental_parsing,
                             &matroska->current_cluster);
    }

    if (!res &&
        matroska->current_cluster_num_blocks <
        matroska->current_cluster.blocks.nb_elem) {
        blocks_list = &matroska->current_cluster.blocks;
        blocks      = blocks_list->elem;

        matroska->current_cluster_num_blocks = blocks_list->nb_elem;
        i                                    = blocks_list->nb_elem - 1;
        if (blocks[i].bin.size > 0 && blocks[i].bin.data) {
            int is_keyframe = blocks[i].non_simple ? !blocks[i].reference : -1;
            uint8_t* additional = blocks[i].additional.size > 0 ?
                                    blocks[i].additional.data : NULL;
            if (!blocks[i].non_simple)
                blocks[i].duration = 0;
            res = matroska_parse_block(matroska, blocks[i].bin.data,
                                       blocks[i].bin.size, blocks[i].bin.pos,
                                       matroska->current_cluster.timecode,
                                       blocks[i].duration, is_keyframe,
                                       additional, blocks[i].additional_id,
                                       blocks[i].additional.size,
                                       matroska->current_cluster_pos,
                                       blocks[i].discard_padding);
        }
    }

    return res;
}

static int matroska_parse_cluster(MatroskaDemuxContext *matroska)
{
    MatroskaCluster cluster = { 0 };
    EbmlList *blocks_list;
    MatroskaBlock *blocks;
    int i, res;
    int64_t pos;

    if (!matroska->contains_ssa)
        return matroska_parse_cluster_incremental(matroska);
    pos = avio_tell(matroska->ctx->pb);
    matroska->prev_pkt = NULL;
    if (matroska->current_id)
        pos -= 4;  /* sizeof the ID which was already read */
    res         = ebml_parse(matroska, matroska_clusters, &cluster);
    blocks_list = &cluster.blocks;
    blocks      = blocks_list->elem;
    for (i = 0; i < blocks_list->nb_elem; i++)
        if (blocks[i].bin.size > 0 && blocks[i].bin.data) {
            int is_keyframe = blocks[i].non_simple ? !blocks[i].reference : -1;
            res = matroska_parse_block(matroska, blocks[i].bin.data,
                                       blocks[i].bin.size, blocks[i].bin.pos,
                                       cluster.timecode, blocks[i].duration,
                                       is_keyframe, NULL, 0, 0, pos,
                                       blocks[i].discard_padding);
        }
    ebml_free(matroska_cluster, &cluster);
    return res;
}

static int matroska_read_packet(AVFormatContext *s, AVPacket *pkt)
{
    MatroskaDemuxContext *matroska = s->priv_data;

    while (matroska_deliver_packet(matroska, pkt)) {
        int64_t pos = avio_tell(matroska->ctx->pb);
        if (matroska->done)
            return AVERROR_EOF;
        if (matroska_parse_cluster(matroska) < 0)
            matroska_resync(matroska, pos);
    }

    return 0;
}

static int matroska_read_seek(AVFormatContext *s, int stream_index,
                              int64_t timestamp, int flags)
{
    MatroskaDemuxContext *matroska = s->priv_data;
    MatroskaTrack *tracks = NULL;
    AVStream *st = s->streams[stream_index];
    int i, index, index_sub, index_min;

    /* Parse the CUES now since we need the index data to seek. */
    if (matroska->cues_parsing_deferred > 0) {
        matroska->cues_parsing_deferred = 0;
        matroska_parse_cues(matroska);
    }

    if (!st->nb_index_entries)
        goto err;
    timestamp = FFMAX(timestamp, st->index_entries[0].timestamp);

    if ((index = av_index_search_timestamp(st, timestamp, flags)) < 0 || index == st->nb_index_entries - 1) {
        avio_seek(s->pb, st->index_entries[st->nb_index_entries - 1].pos,
                  SEEK_SET);
        matroska->current_id = 0;
        while ((index = av_index_search_timestamp(st, timestamp, flags)) < 0 || index == st->nb_index_entries - 1) {
            matroska_clear_queue(matroska);
            if (matroska_parse_cluster(matroska) < 0)
                break;
        }
    }

    matroska_clear_queue(matroska);
    if (index < 0 || (matroska->cues_parsing_deferred < 0 && index == st->nb_index_entries - 1))
        goto err;

    index_min = index;
    tracks = matroska->tracks.elem;
    for (i = 0; i < matroska->tracks.nb_elem; i++) {
        tracks[i].audio.pkt_cnt        = 0;
        tracks[i].audio.sub_packet_cnt = 0;
        tracks[i].audio.buf_timecode   = AV_NOPTS_VALUE;
        tracks[i].end_timecode         = 0;
        if (tracks[i].type == MATROSKA_TRACK_TYPE_SUBTITLE &&
            tracks[i].stream->discard != AVDISCARD_ALL) {
            index_sub = av_index_search_timestamp(
                tracks[i].stream, st->index_entries[index].timestamp,
                AVSEEK_FLAG_BACKWARD);
            while (index_sub >= 0 &&
                  index_min > 0 &&
                  tracks[i].stream->index_entries[index_sub].pos < st->index_entries[index_min].pos &&
                  st->index_entries[index].timestamp - tracks[i].stream->index_entries[index_sub].timestamp < 30000000000 / matroska->time_scale)
                index_min--;
        }
    }

    avio_seek(s->pb, st->index_entries[index_min].pos, SEEK_SET);
    matroska->current_id       = 0;
    if (flags & AVSEEK_FLAG_ANY) {
        st->skip_to_keyframe = 0;
        matroska->skip_to_timecode = timestamp;
    } else {
        st->skip_to_keyframe = 1;
        matroska->skip_to_timecode = st->index_entries[index].timestamp;
    }
    matroska->skip_to_keyframe = 1;
    matroska->done             = 0;
    matroska->num_levels       = 0;
    ff_update_cur_dts(s, st, st->index_entries[index].timestamp);
    return 0;
err:
    // slightly hackish but allows proper fallback to
    // the generic seeking code.
    matroska_clear_queue(matroska);
    matroska->current_id = 0;
    st->skip_to_keyframe =
    matroska->skip_to_keyframe = 0;
    matroska->done = 0;
    matroska->num_levels = 0;
    return -1;
}

static int matroska_read_close(AVFormatContext *s)
{
    MatroskaDemuxContext *matroska = s->priv_data;
    MatroskaTrack *tracks = matroska->tracks.elem;
    int n;

    matroska_clear_queue(matroska);

    for (n = 0; n < matroska->tracks.nb_elem; n++)
        if (tracks[n].type == MATROSKA_TRACK_TYPE_AUDIO)
            av_freep(&tracks[n].audio.buf);
    ebml_free(matroska_cluster, &matroska->current_cluster);
    ebml_free(matroska_segment, matroska);

    return 0;
}

typedef struct {
    int64_t start_time_ns;
    int64_t end_time_ns;
    int64_t start_offset;
    int64_t end_offset;
} CueDesc;

/* This function searches all the Cues and returns the CueDesc corresponding the
 * the timestamp ts. Returned CueDesc will be such that start_time_ns <= ts <
 * end_time_ns. All 4 fields will be set to -1 if ts >= file's duration.
 */
static CueDesc get_cue_desc(AVFormatContext *s, int64_t ts, int64_t cues_start) {
    MatroskaDemuxContext *matroska = s->priv_data;
    CueDesc cue_desc;
    int i;
    int nb_index_entries = s->streams[0]->nb_index_entries;
    AVIndexEntry *index_entries = s->streams[0]->index_entries;
    if (ts >= matroska->duration * matroska->time_scale) return (CueDesc) {-1, -1, -1, -1};
    for (i = 1; i < nb_index_entries; i++) {
        if (index_entries[i - 1].timestamp * matroska->time_scale <= ts &&
            index_entries[i].timestamp * matroska->time_scale > ts) {
            break;
        }
    }
    --i;
    cue_desc.start_time_ns = index_entries[i].timestamp * matroska->time_scale;
    cue_desc.start_offset = index_entries[i].pos - matroska->segment_start;
    if (i != nb_index_entries - 1) {
        cue_desc.end_time_ns = index_entries[i + 1].timestamp * matroska->time_scale;
        cue_desc.end_offset = index_entries[i + 1].pos - matroska->segment_start;
    } else {
        cue_desc.end_time_ns = matroska->duration * matroska->time_scale;
        // FIXME: this needs special handling for files where Cues appear
        // before Clusters. the current logic assumes Cues appear after
        // Clusters.
        cue_desc.end_offset = cues_start - matroska->segment_start;
    }
    return cue_desc;
}

static int webm_clusters_start_with_keyframe(AVFormatContext *s)
{
    MatroskaDemuxContext *matroska = s->priv_data;
    int64_t cluster_pos, before_pos;
    int index, rv = 1;
    if (s->streams[0]->nb_index_entries <= 0) return 0;
    // seek to the first cluster using cues.
    index = av_index_search_timestamp(s->streams[0], 0, 0);
    if (index < 0)  return 0;
    cluster_pos = s->streams[0]->index_entries[index].pos;
    before_pos = avio_tell(s->pb);
    while (1) {
        int64_t cluster_id = 0, cluster_length = 0;
        AVPacket *pkt;
        avio_seek(s->pb, cluster_pos, SEEK_SET);
        // read cluster id and length
        ebml_read_num(matroska, matroska->ctx->pb, 4, &cluster_id);
        ebml_read_length(matroska, matroska->ctx->pb, &cluster_length);
        if (cluster_id != 0xF43B675) { // done with all clusters
            break;
        }
        avio_seek(s->pb, cluster_pos, SEEK_SET);
        matroska->current_id = 0;
        matroska_clear_queue(matroska);
        if (matroska_parse_cluster(matroska) < 0 ||
            matroska->num_packets <= 0) {
            break;
        }
        pkt = matroska->packets[0];
        cluster_pos += cluster_length + 12; // 12 is the offset of the cluster id and length.
        if (!(pkt->flags & AV_PKT_FLAG_KEY)) {
            rv = 0;
            break;
        }
    }
    avio_seek(s->pb, before_pos, SEEK_SET);
    return rv;
}

static int buffer_size_after_time_downloaded(int64_t time_ns, double search_sec, int64_t bps,
                                             double min_buffer, double* buffer,
                                             double* sec_to_download, AVFormatContext *s,
                                             int64_t cues_start)
{
    double nano_seconds_per_second = 1000000000.0;
    double time_sec = time_ns / nano_seconds_per_second;
    int rv = 0;
    int64_t time_to_search_ns = (int64_t)(search_sec * nano_seconds_per_second);
    int64_t end_time_ns = time_ns + time_to_search_ns;
    double sec_downloaded = 0.0;
    CueDesc desc_curr = get_cue_desc(s, time_ns, cues_start);
    if (desc_curr.start_time_ns == -1)
      return -1;
    *sec_to_download = 0.0;

    // Check for non cue start time.
    if (time_ns > desc_curr.start_time_ns) {
      int64_t cue_nano = desc_curr.end_time_ns - time_ns;
      double percent = (double)(cue_nano) / (desc_curr.end_time_ns - desc_curr.start_time_ns);
      double cueBytes = (desc_curr.end_offset - desc_curr.start_offset) * percent;
      double timeToDownload = (cueBytes * 8.0) / bps;

      sec_downloaded += (cue_nano / nano_seconds_per_second) - timeToDownload;
      *sec_to_download += timeToDownload;

      // Check if the search ends within the first cue.
      if (desc_curr.end_time_ns >= end_time_ns) {
          double desc_end_time_sec = desc_curr.end_time_ns / nano_seconds_per_second;
          double percent_to_sub = search_sec / (desc_end_time_sec - time_sec);
          sec_downloaded = percent_to_sub * sec_downloaded;
          *sec_to_download = percent_to_sub * *sec_to_download;
      }

      if ((sec_downloaded + *buffer) <= min_buffer) {
          return 1;
      }

      // Get the next Cue.
      desc_curr = get_cue_desc(s, desc_curr.end_time_ns, cues_start);
    }

    while (desc_curr.start_time_ns != -1) {
        int64_t desc_bytes = desc_curr.end_offset - desc_curr.start_offset;
        int64_t desc_ns = desc_curr.end_time_ns - desc_curr.start_time_ns;
        double desc_sec = desc_ns / nano_seconds_per_second;
        double bits = (desc_bytes * 8.0);
        double time_to_download = bits / bps;

        sec_downloaded += desc_sec - time_to_download;
        *sec_to_download += time_to_download;

        if (desc_curr.end_time_ns >= end_time_ns) {
            double desc_end_time_sec = desc_curr.end_time_ns / nano_seconds_per_second;
            double percent_to_sub = search_sec / (desc_end_time_sec - time_sec);
            sec_downloaded = percent_to_sub * sec_downloaded;
            *sec_to_download = percent_to_sub * *sec_to_download;

            if ((sec_downloaded + *buffer) <= min_buffer)
                rv = 1;
            break;
        }

        if ((sec_downloaded + *buffer) <= min_buffer) {
            rv = 1;
            break;
        }

        desc_curr = get_cue_desc(s, desc_curr.end_time_ns, cues_start);
    }
    *buffer = *buffer + sec_downloaded;
    return rv;
}

/* This function computes the bandwidth of the WebM file with the help of
 * buffer_size_after_time_downloaded() function. Both of these functions are
 * adapted from WebM Tools project and are adapted to work with FFmpeg's
 * Matroska parsing mechanism.
 *
 * Returns the bandwidth of the file on success; -1 on error.
 * */
static int64_t webm_dash_manifest_compute_bandwidth(AVFormatContext *s, int64_t cues_start)
{
    MatroskaDemuxContext *matroska = s->priv_data;
    AVStream *st = s->streams[0];
    double bandwidth = 0.0;
    int i;

    for (i = 0; i < st->nb_index_entries; i++) {
        int64_t prebuffer_ns = 1000000000;
        int64_t time_ns = st->index_entries[i].timestamp * matroska->time_scale;
        double nano_seconds_per_second = 1000000000.0;
        int64_t prebuffered_ns = time_ns + prebuffer_ns;
        double prebuffer_bytes = 0.0;
        int64_t temp_prebuffer_ns = prebuffer_ns;
        int64_t pre_bytes, pre_ns;
        double pre_sec, prebuffer, bits_per_second;
        CueDesc desc_beg = get_cue_desc(s, time_ns, cues_start);

        // Start with the first Cue.
        CueDesc desc_end = desc_beg;

        // Figure out how much data we have downloaded for the prebuffer. This will
        // be used later to adjust the bits per sample to try.
        while (desc_end.start_time_ns != -1 && desc_end.end_time_ns < prebuffered_ns) {
            // Prebuffered the entire Cue.
            prebuffer_bytes += desc_end.end_offset - desc_end.start_offset;
            temp_prebuffer_ns -= desc_end.end_time_ns - desc_end.start_time_ns;
            desc_end = get_cue_desc(s, desc_end.end_time_ns, cues_start);
        }
        if (desc_end.start_time_ns == -1) {
            // The prebuffer is larger than the duration.
            if (matroska->duration * matroska->time_scale >= prebuffered_ns)
              return -1;
            bits_per_second = 0.0;
        } else {
            // The prebuffer ends in the last Cue. Estimate how much data was
            // prebuffered.
            pre_bytes = desc_end.end_offset - desc_end.start_offset;
            pre_ns = desc_end.end_time_ns - desc_end.start_time_ns;
            pre_sec = pre_ns / nano_seconds_per_second;
            prebuffer_bytes +=
                pre_bytes * ((temp_prebuffer_ns / nano_seconds_per_second) / pre_sec);

            prebuffer = prebuffer_ns / nano_seconds_per_second;

            // Set this to 0.0 in case our prebuffer buffers the entire video.
            bits_per_second = 0.0;
            do {
                int64_t desc_bytes = desc_end.end_offset - desc_beg.start_offset;
                int64_t desc_ns = desc_end.end_time_ns - desc_beg.start_time_ns;
                double desc_sec = desc_ns / nano_seconds_per_second;
                double calc_bits_per_second = (desc_bytes * 8) / desc_sec;

                // Drop the bps by the percentage of bytes buffered.
                double percent = (desc_bytes - prebuffer_bytes) / desc_bytes;
                double mod_bits_per_second = calc_bits_per_second * percent;

                if (prebuffer < desc_sec) {
                    double search_sec =
                        (double)(matroska->duration * matroska->time_scale) / nano_seconds_per_second;

                    // Add 1 so the bits per second should be a little bit greater than file
                    // datarate.
                    int64_t bps = (int64_t)(mod_bits_per_second) + 1;
                    const double min_buffer = 0.0;
                    double buffer = prebuffer;
                    double sec_to_download = 0.0;

                    int rv = buffer_size_after_time_downloaded(prebuffered_ns, search_sec, bps,
                                                               min_buffer, &buffer, &sec_to_download,
                                                               s, cues_start);
                    if (rv < 0) {
                        return -1;
                    } else if (rv == 0) {
                        bits_per_second = (double)(bps);
                        break;
                    }
                }

                desc_end = get_cue_desc(s, desc_end.end_time_ns, cues_start);
            } while (desc_end.start_time_ns != -1);
        }
        if (bandwidth < bits_per_second) bandwidth = bits_per_second;
    }
    return (int64_t)bandwidth;
}

static int webm_dash_manifest_cues(AVFormatContext *s)
{
    MatroskaDemuxContext *matroska = s->priv_data;
    EbmlList *seekhead_list = &matroska->seekhead;
    MatroskaSeekhead *seekhead = seekhead_list->elem;
    char *buf;
    int64_t cues_start = -1, cues_end = -1, before_pos, bandwidth;
    int i;

    // determine cues start and end positions
    for (i = 0; i < seekhead_list->nb_elem; i++)
        if (seekhead[i].id == MATROSKA_ID_CUES)
            break;

    if (i >= seekhead_list->nb_elem) return -1;

    before_pos = avio_tell(matroska->ctx->pb);
    cues_start = seekhead[i].pos + matroska->segment_start;
    if (avio_seek(matroska->ctx->pb, cues_start, SEEK_SET) == cues_start) {
        // cues_end is computed as cues_start + cues_length + length of the
        // Cues element ID + EBML length of the Cues element. cues_end is
        // inclusive and the above sum is reduced by 1.
        uint64_t cues_length = 0, cues_id = 0, bytes_read = 0;
        bytes_read += ebml_read_num(matroska, matroska->ctx->pb, 4, &cues_id);
        bytes_read += ebml_read_length(matroska, matroska->ctx->pb, &cues_length);
        cues_end = cues_start + cues_length + bytes_read - 1;
    }
    avio_seek(matroska->ctx->pb, before_pos, SEEK_SET);
    if (cues_start == -1 || cues_end == -1) return -1;

    // parse the cues
    matroska_parse_cues(matroska);

    // cues start
    av_dict_set_int(&s->streams[0]->metadata, CUES_START, cues_start, 0);

    // cues end
    av_dict_set_int(&s->streams[0]->metadata, CUES_END, cues_end, 0);

    // bandwidth
    bandwidth = webm_dash_manifest_compute_bandwidth(s, cues_start);
    if (bandwidth < 0) return -1;
    av_dict_set_int(&s->streams[0]->metadata, BANDWIDTH, bandwidth, 0);

    // check if all clusters start with key frames
    av_dict_set_int(&s->streams[0]->metadata, CLUSTER_KEYFRAME, webm_clusters_start_with_keyframe(s), 0);

    // store cue point timestamps as a comma separated list for checking subsegment alignment in
    // the muxer. assumes that each timestamp cannot be more than 20 characters long.
    buf = av_malloc_array(s->streams[0]->nb_index_entries, 20 * sizeof(char));
    if (!buf) return -1;
    strcpy(buf, "");
    for (i = 0; i < s->streams[0]->nb_index_entries; i++) {
        snprintf(buf, (i + 1) * 20 * sizeof(char),
                 "%s%" PRId64, buf, s->streams[0]->index_entries[i].timestamp);
        if (i != s->streams[0]->nb_index_entries - 1)
            strncat(buf, ",", sizeof(char));
    }
    av_dict_set(&s->streams[0]->metadata, CUE_TIMESTAMPS, buf, 0);
    av_free(buf);

    return 0;
}

static int webm_dash_manifest_read_header(AVFormatContext *s)
{
    char *buf;
    int ret = matroska_read_header(s);
    MatroskaTrack *tracks;
    MatroskaDemuxContext *matroska = s->priv_data;
    if (ret) {
        av_log(s, AV_LOG_ERROR, "Failed to read file headers\n");
        return -1;
    }

    // initialization range
    // 5 is the offset of Cluster ID.
    av_dict_set_int(&s->streams[0]->metadata, INITIALIZATION_RANGE, avio_tell(s->pb) - 5, 0);

    // basename of the file
    buf = strrchr(s->filename, '/');
    av_dict_set(&s->streams[0]->metadata, FILENAME, buf ? ++buf : s->filename, 0);

    // duration
    buf = av_asprintf("%g", matroska->duration);
    if (!buf) return AVERROR(ENOMEM);
    av_dict_set(&s->streams[0]->metadata, DURATION, buf, 0);
    av_free(buf);

    // track number
    tracks = matroska->tracks.elem;
    av_dict_set_int(&s->streams[0]->metadata, TRACK_NUMBER, tracks[0].num, 0);

    // parse the cues and populate Cue related fields
    return webm_dash_manifest_cues(s);
}

static int webm_dash_manifest_read_packet(AVFormatContext *s, AVPacket *pkt)
{
    return AVERROR_EOF;
}

AVInputFormat ff_matroska_demuxer = {
    .name           = "matroska,webm",
    .long_name      = NULL_IF_CONFIG_SMALL("Matroska / WebM"),
    .extensions     = "mkv,mk3d,mka,mks",
    .priv_data_size = sizeof(MatroskaDemuxContext),
    .read_probe     = matroska_probe,
    .read_header    = matroska_read_header,
    .read_packet    = matroska_read_packet,
    .read_close     = matroska_read_close,
    .read_seek      = matroska_read_seek,
    .mime_type      = "audio/webm,audio/x-matroska,video/webm,video/x-matroska"
};

AVInputFormat ff_webm_dash_manifest_demuxer = {
    .name           = "webm_dash_manifest",
    .long_name      = NULL_IF_CONFIG_SMALL("WebM DASH Manifest"),
    .priv_data_size = sizeof(MatroskaDemuxContext),
    .read_header    = webm_dash_manifest_read_header,
    .read_packet    = webm_dash_manifest_read_packet,
    .read_close     = matroska_read_close,
};

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