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/*
* 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/mastering_display_metadata.h"
#include "libavutil/mathematics.h"
#include "libavutil/opt.h"
#include "libavutil/time_internal.h"
#include "libavutil/spherical.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
#include "qtpalette.h"
#define EBML_UNKNOWN_LENGTH UINT64_MAX /* EBML unknown length, in uint64_t */
#define NEEDS_CHECKING 2 /* Indicates that some error checks
* still need to be performed */
avformat/matroskadec: Redo level handling This commit changes how levels are handled: If the level used for ebml_parse ends directly after an element that has been consumed, then ebml_parse ends the level itself (and any known-length levels that end there as well) and informs the caller via the return value; if the current level is of unknown-length, then the level is ended as soon as an element that is not valid on the current level, but on a higher level is encountered (or if EOF has been encountered). This is designed for situations where one wants to parse master elements incrementally, i.e. not in one go via ebml_parse_nest. The (incremental) parsing of clusters still mixes levels by using a syntax list that contains elements from different levels and the level is still ended manually via a call to ebml_level_end if the last cluster was an unknown-length cluster (known-length clusters are already ended when their last element is read), but only if the next element is a cluster, too. A different level 1 element following an unknown-length cluster will currently simply be presumed to be part of the earlier cluster. Fixing this will be done in a future patch. The modifications to matroska_parse_cluster contained in this patch are only intended not to cause regressions. Nevertheless, the fact that known-length levels are automatically ended in ebml_parse when their last element has been read already fixes a bogus error message introduced in 9326117b that was emitted when a known-length cluster is followed by another level 1 element other than a cluster in which case the cluster's level was not ended (which only happened when a new cluster has been encountered) so that the length check (introduced in 9326117b) failed for the level 1 element as it is of course not contained in the previous cluster. Most Matroska files were affected by this. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
#define LEVEL_ENDED 3 /* return value of ebml_parse when the
* syntax level used for parsing ended. */
#define SKIP_THRESHOLD 1024 * 1024 /* In non-seekable mode, if more than SKIP_THRESHOLD
* of unkown, potentially damaged data is encountered,
* it is considered an error. */
#define UNKNOWN_EQUIV 50 * 1024 /* An unknown element is considered equivalent
* to this many bytes of unknown data for the
* SKIP_THRESHOLD check. */
typedef enum {
EBML_NONE,
EBML_UINT,
EBML_SINT,
EBML_FLOAT,
EBML_STR,
EBML_UTF8,
EBML_BIN,
EBML_NEST,
EBML_LEVEL1,
EBML_STOP,
EBML_TYPE_COUNT
} EbmlType;
typedef const struct EbmlSyntax {
uint32_t id;
EbmlType type;
size_t list_elem_size;
size_t data_offset;
union {
int64_t i;
uint64_t u;
double f;
const char *s;
const struct EbmlSyntax *n;
} def;
} EbmlSyntax;
typedef struct EbmlList {
int nb_elem;
unsigned int alloc_elem_size;
void *elem;
} EbmlList;
typedef struct EbmlBin {
int size;
AVBufferRef *buf;
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 MatroskaMasteringMeta {
double r_x;
double r_y;
double g_x;
double g_y;
double b_x;
double b_y;
double white_x;
double white_y;
double max_luminance;
double min_luminance;
} MatroskaMasteringMeta;
typedef struct MatroskaTrackVideoColor {
uint64_t matrix_coefficients;
uint64_t bits_per_channel;
uint64_t chroma_sub_horz;
uint64_t chroma_sub_vert;
uint64_t cb_sub_horz;
uint64_t cb_sub_vert;
uint64_t chroma_siting_horz;
uint64_t chroma_siting_vert;
uint64_t range;
uint64_t transfer_characteristics;
uint64_t primaries;
uint64_t max_cll;
uint64_t max_fall;
MatroskaMasteringMeta mastering_meta;
} MatroskaTrackVideoColor;
typedef struct MatroskaTrackVideoProjection {
uint64_t type;
EbmlBin private;
double yaw;
double pitch;
double roll;
} MatroskaTrackVideoProjection;
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 display_unit;
uint64_t interlaced;
uint64_t field_order;
uint64_t stereo_mode;
uint64_t alpha_mode;
EbmlList color;
MatroskaTrackVideoProjection projection;
} 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;
uint64_t codec_delay_in_track_tb;
AVStream *stream;
int64_t end_timecode;
int ms_compat;
uint64_t max_block_additional_id;
uint32_t palette[AVPALETTE_COUNT];
int has_palette;
} 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 MatroskaBlock {
uint64_t duration;
int64_t reference;
uint64_t non_simple;
EbmlBin bin;
uint64_t additional_id;
EbmlBin additional;
int64_t discard_padding;
} MatroskaBlock;
typedef struct MatroskaCluster {
MatroskaBlock block;
uint64_t timecode;
int64_t pos;
} MatroskaCluster;
typedef struct MatroskaLevel1Element {
int64_t pos;
uint32_t id;
int parsed;
} MatroskaLevel1Element;
typedef struct MatroskaDemuxContext {
const AVClass *class;
AVFormatContext *ctx;
/* EBML stuff */
MatroskaLevel levels[EBML_MAX_DEPTH];
int num_levels;
uint32_t current_id;
avformat/matroskadec: Introduce a "last known good" position Currently, resyncing during reading packets works as follows: The current position is recorded, then a call to matroska_parse_cluster is made and if said call fails, the demuxer tries to resync from the earlier position. If the call doesn't fail, but also doesn't deliver a packet, then this is looped. There are two problems with this approach: 1. The Matroska file format aims to be forward-compatible; to achieve this, a demuxer should simply ignore and skip elements it doesn't know about. But it is not possible to reliably distinguish unknown elements from junk. If matroska_parse_cluster encounters an unknown element, it can therefore not simply error out; instead it returns zero and the loop is iterated which includes an update of the position that is intended to be used in case of errors, i.e. the element that is skipped is not searched for level 1 element ids to resync to at all if later calls to matroska_parse_cluster return an error. Notice that in case that sync has been lost there can be a chain of several unknown/possibly junk elements before an error is detected. 2. Even if a call to matroska_parse_cluster delivers a packet, this does not mean that everything is fine. E.g. it might be that some of the block's data is missing and that the data that was presumed to be from the block just read actually contains the beginning of the next element. This will only be apparent at the next call of matroska_read_packet, which uses the (false) end of the earlier block as resync position so that in the (not unlikely) case that the call to matroska_parse_cluster fails, the data believed to be part of the earlier block is not searched for a level 1 element to resync to. To counter this, a "last known good" position is introduced. When an element id that is known to be allowed at this position in the hierarchy (according to the syntax currently in use for parsing) is read and some further checks (regarding the length of the element and its containing master element) are passed, then the beginning of the current element is treated as a "good" position and recorded as such in the MatroskaDemuxContext. Because of 2., only the start of the element is treated as a "good" position, not the whole element. If an error occurs later during parsing of clusters, the resync process starts at the last known good position. Given that when the header is damaged the subsequent resync never skips over data and is therefore unaffected by both issues, the "last known good" concept is not used there. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
int64_t resync_pos;
int unknown_count;
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 */
AVPacketList *queue;
AVPacketList *queue_end;
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;
MatroskaCluster current_cluster;
/* WebM DASH Manifest live flag */
int is_live;
/* Bandwidth value for WebM DASH Manifest */
int bandwidth;
} MatroskaDemuxContext;
#define CHILD_OF(parent) { .def = { .n = parent } }
// The following forward declarations need their size because
// a tentative definition with internal linkage must not be an
// incomplete type (6.7.2 in C90, 6.9.2 in C99).
// Removing the sizes breaks MSVC.
static EbmlSyntax ebml_syntax[3], matroska_segment[9], matroska_track_video_color[15], matroska_track_video[19],
matroska_track[27], matroska_track_encoding[6], matroska_track_encodings[2],
matroska_track_combine_planes[2], matroska_track_operation[2], matroska_tracks[2],
matroska_attachments[2], matroska_chapter_entry[9], matroska_chapter[6], matroska_chapters[2],
matroska_index_entry[3], matroska_index[2], matroska_tag[3], matroska_tags[2], matroska_seekhead[2],
matroska_blockadditions[2], matroska_blockgroup[8], matroska_cluster_parsing[8];
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 },
CHILD_OF(ebml_syntax)
};
static EbmlSyntax ebml_syntax[] = {
{ EBML_ID_HEADER, EBML_NEST, 0, 0, { .n = ebml_header } },
{ MATROSKA_ID_SEGMENT, EBML_STOP },
{ 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 },
CHILD_OF(matroska_segment)
};
static EbmlSyntax matroska_mastering_meta[] = {
{ MATROSKA_ID_VIDEOCOLOR_RX, EBML_FLOAT, 0, offsetof(MatroskaMasteringMeta, r_x), { .f=-1 } },
{ MATROSKA_ID_VIDEOCOLOR_RY, EBML_FLOAT, 0, offsetof(MatroskaMasteringMeta, r_y), { .f=-1 } },
{ MATROSKA_ID_VIDEOCOLOR_GX, EBML_FLOAT, 0, offsetof(MatroskaMasteringMeta, g_x), { .f=-1 } },
{ MATROSKA_ID_VIDEOCOLOR_GY, EBML_FLOAT, 0, offsetof(MatroskaMasteringMeta, g_y), { .f=-1 } },
{ MATROSKA_ID_VIDEOCOLOR_BX, EBML_FLOAT, 0, offsetof(MatroskaMasteringMeta, b_x), { .f=-1 } },
{ MATROSKA_ID_VIDEOCOLOR_BY, EBML_FLOAT, 0, offsetof(MatroskaMasteringMeta, b_y), { .f=-1 } },
{ MATROSKA_ID_VIDEOCOLOR_WHITEX, EBML_FLOAT, 0, offsetof(MatroskaMasteringMeta, white_x), { .f=-1 } },
{ MATROSKA_ID_VIDEOCOLOR_WHITEY, EBML_FLOAT, 0, offsetof(MatroskaMasteringMeta, white_y), { .f=-1 } },
{ MATROSKA_ID_VIDEOCOLOR_LUMINANCEMIN, EBML_FLOAT, 0, offsetof(MatroskaMasteringMeta, min_luminance), { .f=-1 } },
{ MATROSKA_ID_VIDEOCOLOR_LUMINANCEMAX, EBML_FLOAT, 0, offsetof(MatroskaMasteringMeta, max_luminance), { .f=-1 } },
CHILD_OF(matroska_track_video_color)
};
static EbmlSyntax matroska_track_video_color[] = {
{ MATROSKA_ID_VIDEOCOLORMATRIXCOEFF, EBML_UINT, 0, offsetof(MatroskaTrackVideoColor, matrix_coefficients), { .u = AVCOL_SPC_UNSPECIFIED } },
{ MATROSKA_ID_VIDEOCOLORBITSPERCHANNEL, EBML_UINT, 0, offsetof(MatroskaTrackVideoColor, bits_per_channel), { .u=0 } },
{ MATROSKA_ID_VIDEOCOLORCHROMASUBHORZ, EBML_UINT, 0, offsetof(MatroskaTrackVideoColor, chroma_sub_horz), { .u=0 } },
{ MATROSKA_ID_VIDEOCOLORCHROMASUBVERT, EBML_UINT, 0, offsetof(MatroskaTrackVideoColor, chroma_sub_vert), { .u=0 } },
{ MATROSKA_ID_VIDEOCOLORCBSUBHORZ, EBML_UINT, 0, offsetof(MatroskaTrackVideoColor, cb_sub_horz), { .u=0 } },
{ MATROSKA_ID_VIDEOCOLORCBSUBVERT, EBML_UINT, 0, offsetof(MatroskaTrackVideoColor, cb_sub_vert), { .u=0 } },
{ MATROSKA_ID_VIDEOCOLORCHROMASITINGHORZ, EBML_UINT, 0, offsetof(MatroskaTrackVideoColor, chroma_siting_horz), { .u = MATROSKA_COLOUR_CHROMASITINGHORZ_UNDETERMINED } },
{ MATROSKA_ID_VIDEOCOLORCHROMASITINGVERT, EBML_UINT, 0, offsetof(MatroskaTrackVideoColor, chroma_siting_vert), { .u = MATROSKA_COLOUR_CHROMASITINGVERT_UNDETERMINED } },
{ MATROSKA_ID_VIDEOCOLORRANGE, EBML_UINT, 0, offsetof(MatroskaTrackVideoColor, range), { .u = AVCOL_RANGE_UNSPECIFIED } },
{ MATROSKA_ID_VIDEOCOLORTRANSFERCHARACTERISTICS, EBML_UINT, 0, offsetof(MatroskaTrackVideoColor, transfer_characteristics), { .u = AVCOL_TRC_UNSPECIFIED } },
{ MATROSKA_ID_VIDEOCOLORPRIMARIES, EBML_UINT, 0, offsetof(MatroskaTrackVideoColor, primaries), { .u = AVCOL_PRI_UNSPECIFIED } },
{ MATROSKA_ID_VIDEOCOLORMAXCLL, EBML_UINT, 0, offsetof(MatroskaTrackVideoColor, max_cll), { .u=0 } },
{ MATROSKA_ID_VIDEOCOLORMAXFALL, EBML_UINT, 0, offsetof(MatroskaTrackVideoColor, max_fall), { .u=0 } },
{ MATROSKA_ID_VIDEOCOLORMASTERINGMETA, EBML_NEST, 0, offsetof(MatroskaTrackVideoColor, mastering_meta), { .n = matroska_mastering_meta } },
CHILD_OF(matroska_track_video)
};
static EbmlSyntax matroska_track_video_projection[] = {
{ MATROSKA_ID_VIDEOPROJECTIONTYPE, EBML_UINT, 0, offsetof(MatroskaTrackVideoProjection, type), { .u = MATROSKA_VIDEO_PROJECTION_TYPE_RECTANGULAR } },
{ MATROSKA_ID_VIDEOPROJECTIONPRIVATE, EBML_BIN, 0, offsetof(MatroskaTrackVideoProjection, private) },
{ MATROSKA_ID_VIDEOPROJECTIONPOSEYAW, EBML_FLOAT, 0, offsetof(MatroskaTrackVideoProjection, yaw), { .f=0.0 } },
{ MATROSKA_ID_VIDEOPROJECTIONPOSEPITCH, EBML_FLOAT, 0, offsetof(MatroskaTrackVideoProjection, pitch), { .f=0.0 } },
{ MATROSKA_ID_VIDEOPROJECTIONPOSEROLL, EBML_FLOAT, 0, offsetof(MatroskaTrackVideoProjection, roll), { .f=0.0 } },
CHILD_OF(matroska_track_video)
};
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_VIDEOCOLOR, EBML_NEST, sizeof(MatroskaTrackVideoColor), offsetof(MatroskaTrackVideo, color), { .n = matroska_track_video_color } },
{ MATROSKA_ID_VIDEOPROJECTION, EBML_NEST, 0, offsetof(MatroskaTrackVideo, projection), { .n = matroska_track_video_projection } },
{ MATROSKA_ID_VIDEOPIXELCROPB, EBML_NONE },
{ MATROSKA_ID_VIDEOPIXELCROPT, EBML_NONE },
{ MATROSKA_ID_VIDEOPIXELCROPL, EBML_NONE },
{ MATROSKA_ID_VIDEOPIXELCROPR, EBML_NONE },
{ MATROSKA_ID_VIDEODISPLAYUNIT, EBML_UINT, 0, offsetof(MatroskaTrackVideo, display_unit), { .u= MATROSKA_VIDEO_DISPLAYUNIT_PIXELS } },
{ MATROSKA_ID_VIDEOFLAGINTERLACED, EBML_UINT, 0, offsetof(MatroskaTrackVideo, interlaced), { .u = MATROSKA_VIDEO_INTERLACE_FLAG_UNDETERMINED } },
{ MATROSKA_ID_VIDEOFIELDORDER, EBML_UINT, 0, offsetof(MatroskaTrackVideo, field_order), { .u = MATROSKA_VIDEO_FIELDORDER_UNDETERMINED } },
{ MATROSKA_ID_VIDEOSTEREOMODE, EBML_UINT, 0, offsetof(MatroskaTrackVideo, stereo_mode), { .u = MATROSKA_VIDEO_STEREOMODE_TYPE_NB } },
{ MATROSKA_ID_VIDEOASPECTRATIO, EBML_NONE },
CHILD_OF(matroska_track)
};
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 } },
CHILD_OF(matroska_track)
};
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) },
CHILD_OF(matroska_track_encoding)
};
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 },
CHILD_OF(matroska_track_encoding)
};
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 },
CHILD_OF(matroska_track_encodings)
};
static EbmlSyntax matroska_track_encodings[] = {
{ MATROSKA_ID_TRACKCONTENTENCODING, EBML_NEST, sizeof(MatroskaTrackEncoding), offsetof(MatroskaTrack, encodings), { .n = matroska_track_encoding } },
CHILD_OF(matroska_track)
};
static EbmlSyntax matroska_track_plane[] = {
{ MATROSKA_ID_TRACKPLANEUID, EBML_UINT, 0, offsetof(MatroskaTrackPlane,uid) },
{ MATROSKA_ID_TRACKPLANETYPE, EBML_UINT, 0, offsetof(MatroskaTrackPlane,type) },
CHILD_OF(matroska_track_combine_planes)
};
static EbmlSyntax matroska_track_combine_planes[] = {
{ MATROSKA_ID_TRACKPLANE, EBML_NEST, sizeof(MatroskaTrackPlane), offsetof(MatroskaTrackOperation,combine_planes), {.n = matroska_track_plane} },
CHILD_OF(matroska_track_operation)
};
static EbmlSyntax matroska_track_operation[] = {
{ MATROSKA_ID_TRACKCOMBINEPLANES, EBML_NEST, 0, 0, {.n = matroska_track_combine_planes} },
CHILD_OF(matroska_track)
};
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 },
CHILD_OF(matroska_tracks)
};
static EbmlSyntax matroska_tracks[] = {
{ MATROSKA_ID_TRACKENTRY, EBML_NEST, sizeof(MatroskaTrack), offsetof(MatroskaDemuxContext, tracks), { .n = matroska_track } },
CHILD_OF(matroska_segment)
};
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 },
CHILD_OF(matroska_attachments)
};
static EbmlSyntax matroska_attachments[] = {
{ MATROSKA_ID_ATTACHEDFILE, EBML_NEST, sizeof(MatroskaAttachment), offsetof(MatroskaDemuxContext, attachments), { .n = matroska_attachment } },
CHILD_OF(matroska_segment)
};
static EbmlSyntax matroska_chapter_display[] = {
{ MATROSKA_ID_CHAPSTRING, EBML_UTF8, 0, offsetof(MatroskaChapter, title) },
{ MATROSKA_ID_CHAPLANG, EBML_NONE },
{ MATROSKA_ID_CHAPCOUNTRY, EBML_NONE },
CHILD_OF(matroska_chapter_entry)
};
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 },
CHILD_OF(matroska_chapter)
};
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 },
CHILD_OF(matroska_chapters)
};
static EbmlSyntax matroska_chapters[] = {
{ MATROSKA_ID_EDITIONENTRY, EBML_NEST, 0, 0, { .n = matroska_chapter } },
CHILD_OF(matroska_segment)
};
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 },
CHILD_OF(matroska_index_entry)
};
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 } },
CHILD_OF(matroska_index)
};
static EbmlSyntax matroska_index[] = {
{ MATROSKA_ID_POINTENTRY, EBML_NEST, sizeof(MatroskaIndex), offsetof(MatroskaDemuxContext, index), { .n = matroska_index_entry } },
CHILD_OF(matroska_segment)
};
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 } },
CHILD_OF(matroska_tag)
};
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) },
CHILD_OF(matroska_tag)
};
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 } },
CHILD_OF(matroska_tags)
};
static EbmlSyntax matroska_tags[] = {
{ MATROSKA_ID_TAG, EBML_NEST, sizeof(MatroskaTags), offsetof(MatroskaDemuxContext, tags), { .n = matroska_tag } },
CHILD_OF(matroska_segment)
};
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 } },
CHILD_OF(matroska_seekhead)
};
static EbmlSyntax matroska_seekhead[] = {
{ MATROSKA_ID_SEEKENTRY, EBML_NEST, sizeof(MatroskaSeekhead), offsetof(MatroskaDemuxContext, seekhead), { .n = matroska_seekhead_entry } },
CHILD_OF(matroska_segment)
};
static EbmlSyntax matroska_segment[] = {
{ MATROSKA_ID_CLUSTER, EBML_STOP },
{ 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 } },
{ 0 } /* We don't want to go back to level 0, so don't add the parent. */
};
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), { .u = 1 } },
{ MATROSKA_ID_BLOCKADDITIONAL, EBML_BIN, 0, offsetof(MatroskaBlock,additional) },
CHILD_OF(matroska_blockadditions)
};
static EbmlSyntax matroska_blockadditions[] = {
{ MATROSKA_ID_BLOCKMORE, EBML_NEST, 0, 0, {.n = matroska_blockmore} },
CHILD_OF(matroska_blockgroup)
};
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_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), { .i = INT64_MIN } },
{ MATROSKA_ID_CODECSTATE, EBML_NONE },
{ 1, EBML_UINT, 0, offsetof(MatroskaBlock, non_simple), { .u = 1 } },
CHILD_OF(matroska_cluster_parsing)
};
// The following array contains SimpleBlock and BlockGroup twice
// in order to reuse the other values for matroska_cluster_enter.
static EbmlSyntax matroska_cluster_parsing[] = {
{ MATROSKA_ID_SIMPLEBLOCK, EBML_BIN, 0, offsetof(MatroskaBlock, bin) },
{ MATROSKA_ID_BLOCKGROUP, EBML_NEST, 0, 0, { .n = matroska_blockgroup } },
{ MATROSKA_ID_CLUSTERTIMECODE, EBML_UINT, 0, offsetof(MatroskaCluster, timecode) },
{ MATROSKA_ID_SIMPLEBLOCK, EBML_STOP },
{ MATROSKA_ID_BLOCKGROUP, EBML_STOP },
{ MATROSKA_ID_CLUSTERPOSITION, EBML_NONE },
{ MATROSKA_ID_CLUSTERPREVSIZE, EBML_NONE },
CHILD_OF(matroska_segment)
};
static EbmlSyntax matroska_cluster_enter[] = {
{ MATROSKA_ID_CLUSTER, EBML_NEST, 0, 0, { .n = &matroska_cluster_parsing[2] } },
{ 0 }
};
#undef CHILD_OF
static const char *const matroska_doctypes[] = { "matroska", "webm" };
static int matroska_read_close(AVFormatContext *s);
/*
* This function prepares the status for parsing of level 1 elements.
*/
static int matroska_reset_status(MatroskaDemuxContext *matroska,
uint32_t id, int64_t position)
{
if (position >= 0) {
int64_t err = avio_seek(matroska->ctx->pb, position, SEEK_SET);
if (err < 0)
return err;
}
matroska->current_id = id;
matroska->num_levels = 1;
matroska->unknown_count = 0;
avformat/matroskadec: Introduce a "last known good" position Currently, resyncing during reading packets works as follows: The current position is recorded, then a call to matroska_parse_cluster is made and if said call fails, the demuxer tries to resync from the earlier position. If the call doesn't fail, but also doesn't deliver a packet, then this is looped. There are two problems with this approach: 1. The Matroska file format aims to be forward-compatible; to achieve this, a demuxer should simply ignore and skip elements it doesn't know about. But it is not possible to reliably distinguish unknown elements from junk. If matroska_parse_cluster encounters an unknown element, it can therefore not simply error out; instead it returns zero and the loop is iterated which includes an update of the position that is intended to be used in case of errors, i.e. the element that is skipped is not searched for level 1 element ids to resync to at all if later calls to matroska_parse_cluster return an error. Notice that in case that sync has been lost there can be a chain of several unknown/possibly junk elements before an error is detected. 2. Even if a call to matroska_parse_cluster delivers a packet, this does not mean that everything is fine. E.g. it might be that some of the block's data is missing and that the data that was presumed to be from the block just read actually contains the beginning of the next element. This will only be apparent at the next call of matroska_read_packet, which uses the (false) end of the earlier block as resync position so that in the (not unlikely) case that the call to matroska_parse_cluster fails, the data believed to be part of the earlier block is not searched for a level 1 element to resync to. To counter this, a "last known good" position is introduced. When an element id that is known to be allowed at this position in the hierarchy (according to the syntax currently in use for parsing) is read and some further checks (regarding the length of the element and its containing master element) are passed, then the beginning of the current element is treated as a "good" position and recorded as such in the MatroskaDemuxContext. Because of 2., only the start of the element is treated as a "good" position, not the whole element. If an error occurs later during parsing of clusters, the resync process starts at the last known good position. Given that when the header is damaged the subsequent resync never skips over data and is therefore unaffected by both issues, the "last known good" concept is not used there. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
matroska->resync_pos = avio_tell(matroska->ctx->pb);
if (id)
matroska->resync_pos -= (av_log2(id) + 7) / 8;
return 0;
}
static int matroska_resync(MatroskaDemuxContext *matroska, int64_t last_pos)
{
AVIOContext *pb = matroska->ctx->pb;
uint32_t id;
avformat/matroskadec: Don't abort resyncing upon seek failure When an error happens, the Matroska demuxer tries to resync to level 1 elements from an earlier position onwards. If the seek to said earlier position fails, the demuxer currently treats this as an unrecoverable error. And that behaviour is suboptimal as said failure is nothing unrecoverable or unexpected (when the input isn't seekable). It is preferable to simply resync from the earliest position available (i.e. the start of the AVIOContext's buffer) onwards if the seek failed. Here are some scenarios that might be treated as unrecoverable errors by the current code if the input isn't seekable. They all have in common that the current position is so far away from the desired position that the seek can't be fulfilled from the AVIOContext's buffer: 1. Blocks (both SimpleBlocks as well as a Block in a BlockGroup) for which reading them as binary EBML elements succeeds, but whose parsing triggers an error (e.g. an invalid TrackNumber). In this case the earlier position from which resyncing begins is at the start of the block (or even earlier). 2. BlockGroups, whose parsing fails in one of the latter elements. Just as in 1., the start of the BlockGroup (the target of the seek) might be so far away from the current position that it is no longer in the buffer. 3. At the beginning of parsing a cluster, the cluster is parsed until a SimpleBlock or a BlockGroup is encountered. So if the input is damaged between the beginning of the cluster and the first occurrence of a SimpleBlock/BlockGroup and if said damage makes the demuxer read/skip so much data that the beginning of the cluster is no longer in the buffer, demuxing will currently fail completely. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
/* Try to seek to the last position to resync from. If this doesn't work,
* we resync from the earliest position available: The start of the buffer. */
if (last_pos < avio_tell(pb) && avio_seek(pb, last_pos + 1, SEEK_SET) < 0) {
av_log(matroska->ctx, AV_LOG_WARNING,
"Seek to desired resync point failed. Seeking to "
"earliest point available instead.\n");
avio_seek(pb, FFMAX(avio_tell(pb) + (pb->buffer - pb->buf_ptr),
last_pos + 1), SEEK_SET);
}
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) {
/* Prepare the context for parsing of a level 1 element. */
matroska_reset_status(matroska, id, -1);
/* Given that we are here means that an error has occurred,
* so treat the segment as unknown length in order not to
* discard valid data that happens to be beyond the designated
* end of the segment. */
matroska->levels[0].length = EBML_UNKNOWN_LENGTH;
return 0;
}
id = (id << 8) | avio_r8(pb);
}
matroska->done = 1;
avformat/matroskadec: Don't abort resyncing upon seek failure When an error happens, the Matroska demuxer tries to resync to level 1 elements from an earlier position onwards. If the seek to said earlier position fails, the demuxer currently treats this as an unrecoverable error. And that behaviour is suboptimal as said failure is nothing unrecoverable or unexpected (when the input isn't seekable). It is preferable to simply resync from the earliest position available (i.e. the start of the AVIOContext's buffer) onwards if the seek failed. Here are some scenarios that might be treated as unrecoverable errors by the current code if the input isn't seekable. They all have in common that the current position is so far away from the desired position that the seek can't be fulfilled from the AVIOContext's buffer: 1. Blocks (both SimpleBlocks as well as a Block in a BlockGroup) for which reading them as binary EBML elements succeeds, but whose parsing triggers an error (e.g. an invalid TrackNumber). In this case the earlier position from which resyncing begins is at the start of the block (or even earlier). 2. BlockGroups, whose parsing fails in one of the latter elements. Just as in 1., the start of the BlockGroup (the target of the seek) might be so far away from the current position that it is no longer in the buffer. 3. At the beginning of parsing a cluster, the cluster is parsed until a SimpleBlock or a BlockGroup is encountered. So if the input is damaged between the beginning of the cluster and the first occurrence of a SimpleBlock/BlockGroup and if said damage makes the demuxer read/skip so much data that the beginning of the cluster is no longer in the buffer, demuxing will currently fail completely. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
return pb->error ? pb->error : AVERROR_EOF;
}
/*
* 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 eof_forbidden)
{
int read, n = 1;
uint64_t total;
int64_t pos;
/* The first byte tells us the length in bytes - except when it is zero. */
total = avio_r8(pb);
if (pb->eof_reached)
goto err;
/* get the length of the EBML number */
read = 8 - ff_log2_tab[total];
if (!total || read > max_size) {
pos = avio_tell(pb) - 1;
if (!total) {
av_log(matroska->ctx, AV_LOG_ERROR,
"0x00 at pos %"PRId64" (0x%"PRIx64") invalid as first byte "
"of an EBML number\n", pos, pos);
} else {
av_log(matroska->ctx, AV_LOG_ERROR,
"Length %d indicated by an EBML number's first byte 0x%02x "
"at pos %"PRId64" (0x%"PRIx64") exceeds max length %d.\n",
read, (uint8_t) total, pos, pos, max_size);
}
return AVERROR_INVALIDDATA;
}
/* read out length */
total ^= 1 << ff_log2_tab[total];
while (n++ < read)
total = (total << 8) | avio_r8(pb);
if (pb->eof_reached) {
eof_forbidden = 1;
goto err;
}
*number = total;
return read;
err:
pos = avio_tell(pb);
if (pb->error) {
av_log(matroska->ctx, AV_LOG_ERROR,
"Read error at pos. %"PRIu64" (0x%"PRIx64")\n",
pos, pos);
return pb->error;
}
if (eof_forbidden) {
av_log(matroska->ctx, AV_LOG_ERROR, "File ended prematurely "
"at pos. %"PRIu64" (0x%"PRIx64")\n", pos, pos);
return AVERROR(EIO);
}
return AVERROR_EOF;
}
/**
* 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, 1);
if (res > 0 && *number + 1 == 1ULL << (7 * res))
*number = EBML_UNKNOWN_LENGTH;
return res;
}
/*
* Read the next element as an unsigned int.
* Returns NEEDS_CHECKING.
*/
static int ebml_read_uint(AVIOContext *pb, int size, uint64_t *num)
{
int n = 0;
/* big-endian ordering; build up number */
*num = 0;
while (n++ < size)
*num = (*num << 8) | avio_r8(pb);
return NEEDS_CHECKING;
}
/*
* Read the next element as a signed int.
* Returns NEEDS_CHECKING.
*/
static int ebml_read_sint(AVIOContext *pb, int size, int64_t *num)
{
int n = 1;
if (size == 0) {
*num = 0;
} else {
*num = sign_extend(avio_r8(pb), 8);
/* big-endian ordering; build up number */
while (n++ < size)
*num = ((uint64_t)*num << 8) | avio_r8(pb);
}
return NEEDS_CHECKING;
}
/*
* Read the next element as a float.
* Returns NEEDS_CHECKING or < 0 on obvious 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 NEEDS_CHECKING;
}
/*
* Read the next element as an ASCII string.
* 0 is success, < 0 or NEEDS_CHECKING is failure.
*/
static int ebml_read_ascii(AVIOContext *pb, int size, char **str)
{
char *res;
int ret;
/* 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 ((ret = avio_read(pb, (uint8_t *) res, size)) != size) {
av_free(res);
return ret < 0 ? ret : NEEDS_CHECKING;
}
(res)[size] = '\0';
av_free(*str);
*str = res;
return 0;
}
/*
* Read the next element as binary data.
* 0 is success, < 0 or NEEDS_CHECKING is failure.
*/
static int ebml_read_binary(AVIOContext *pb, int length,
int64_t pos, EbmlBin *bin)
{
int ret;
ret = av_buffer_realloc(&bin->buf, length + AV_INPUT_BUFFER_PADDING_SIZE);
if (ret < 0)
return ret;
memset(bin->buf->data + length, 0, AV_INPUT_BUFFER_PADDING_SIZE);
bin->data = bin->buf->data;
bin->size = length;
bin->pos = pos;
if ((ret = avio_read(pb, bin->data, length)) != length) {
av_buffer_unref(&bin->buf);
bin->data = NULL;
bin->size = 0;
return ret < 0 ? ret : NEEDS_CHECKING;
}
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, int64_t pos)
{
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 = pos;
level->length = length;
return 0;
}
/*
* Read a signed "EBML number"
* Return: number of bytes processed, < 0 on error
*/
static int matroska_ebmlnum_sint(MatroskaDemuxContext *matroska,
AVIOContext *pb, int64_t *num)
{
uint64_t unum;
int res;
/* read as unsigned number first */
if ((res = ebml_read_num(matroska, pb, 8, &unum, 1)) < 0)
return res;
/* make signed (weird way) */
*num = unum - ((1LL << (7 * res - 1)) - 1);
return res;
}
static int ebml_parse(MatroskaDemuxContext *matroska,
EbmlSyntax *syntax, void *data);
static EbmlSyntax *ebml_parse_id(EbmlSyntax *syntax, uint32_t id)
{
int i;
// Whoever touches this should be aware of the duplication
// existing in matroska_cluster_parsing.
for (i = 0; syntax[i].id; i++)
if (id == syntax[i].id)
break;
return &syntax[i];
}
static int ebml_parse_nest(MatroskaDemuxContext *matroska, EbmlSyntax *syntax,
void *data)
{
int res;
if (data) {
for (int 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_SINT:
*(int64_t *) ((char *) data + syntax[i].data_offset) = syntax[i].def.i;
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;
}
if (!matroska->levels[matroska->num_levels - 1].length) {
matroska->num_levels--;
return 0;
}
}
avformat/matroskadec: Redo level handling This commit changes how levels are handled: If the level used for ebml_parse ends directly after an element that has been consumed, then ebml_parse ends the level itself (and any known-length levels that end there as well) and informs the caller via the return value; if the current level is of unknown-length, then the level is ended as soon as an element that is not valid on the current level, but on a higher level is encountered (or if EOF has been encountered). This is designed for situations where one wants to parse master elements incrementally, i.e. not in one go via ebml_parse_nest. The (incremental) parsing of clusters still mixes levels by using a syntax list that contains elements from different levels and the level is still ended manually via a call to ebml_level_end if the last cluster was an unknown-length cluster (known-length clusters are already ended when their last element is read), but only if the next element is a cluster, too. A different level 1 element following an unknown-length cluster will currently simply be presumed to be part of the earlier cluster. Fixing this will be done in a future patch. The modifications to matroska_parse_cluster contained in this patch are only intended not to cause regressions. Nevertheless, the fact that known-length levels are automatically ended in ebml_parse when their last element has been read already fixes a bogus error message introduced in 9326117b that was emitted when a known-length cluster is followed by another level 1 element other than a cluster in which case the cluster's level was not ended (which only happened when a new cluster has been encountered) so that the length check (introduced in 9326117b) failed for the level 1 element as it is of course not contained in the previous cluster. Most Matroska files were affected by this. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
do {
res = ebml_parse(matroska, syntax, data);
avformat/matroskadec: Redo level handling This commit changes how levels are handled: If the level used for ebml_parse ends directly after an element that has been consumed, then ebml_parse ends the level itself (and any known-length levels that end there as well) and informs the caller via the return value; if the current level is of unknown-length, then the level is ended as soon as an element that is not valid on the current level, but on a higher level is encountered (or if EOF has been encountered). This is designed for situations where one wants to parse master elements incrementally, i.e. not in one go via ebml_parse_nest. The (incremental) parsing of clusters still mixes levels by using a syntax list that contains elements from different levels and the level is still ended manually via a call to ebml_level_end if the last cluster was an unknown-length cluster (known-length clusters are already ended when their last element is read), but only if the next element is a cluster, too. A different level 1 element following an unknown-length cluster will currently simply be presumed to be part of the earlier cluster. Fixing this will be done in a future patch. The modifications to matroska_parse_cluster contained in this patch are only intended not to cause regressions. Nevertheless, the fact that known-length levels are automatically ended in ebml_parse when their last element has been read already fixes a bogus error message introduced in 9326117b that was emitted when a known-length cluster is followed by another level 1 element other than a cluster in which case the cluster's level was not ended (which only happened when a new cluster has been encountered) so that the length check (introduced in 9326117b) failed for the level 1 element as it is of course not contained in the previous cluster. Most Matroska files were affected by this. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
} while (!res);
avformat/matroskadec: Redo level handling This commit changes how levels are handled: If the level used for ebml_parse ends directly after an element that has been consumed, then ebml_parse ends the level itself (and any known-length levels that end there as well) and informs the caller via the return value; if the current level is of unknown-length, then the level is ended as soon as an element that is not valid on the current level, but on a higher level is encountered (or if EOF has been encountered). This is designed for situations where one wants to parse master elements incrementally, i.e. not in one go via ebml_parse_nest. The (incremental) parsing of clusters still mixes levels by using a syntax list that contains elements from different levels and the level is still ended manually via a call to ebml_level_end if the last cluster was an unknown-length cluster (known-length clusters are already ended when their last element is read), but only if the next element is a cluster, too. A different level 1 element following an unknown-length cluster will currently simply be presumed to be part of the earlier cluster. Fixing this will be done in a future patch. The modifications to matroska_parse_cluster contained in this patch are only intended not to cause regressions. Nevertheless, the fact that known-length levels are automatically ended in ebml_parse when their last element has been read already fixes a bogus error message introduced in 9326117b that was emitted when a known-length cluster is followed by another level 1 element other than a cluster in which case the cluster's level was not ended (which only happened when a new cluster has been encountered) so that the length check (introduced in 9326117b) failed for the level 1 element as it is of course not contained in the previous cluster. Most Matroska files were affected by this. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
return res == LEVEL_ENDED ? 0 : res;
}
static int is_ebml_id_valid(uint32_t id)
{
// Due to endian nonsense in Matroska, the highest byte with any bits set
// will contain the leading length bit. This bit in turn identifies the
// total byte length of the element by its position within the byte.
unsigned int bits = av_log2(id);
return id && (bits + 7) / 8 == (8 - bits % 8);
}
/*
* 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;
if (!is_ebml_id_valid(id))
return NULL;
// 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(MatroskaDemuxContext *matroska,
EbmlSyntax *syntax, void *data)
{
static const uint64_t max_lengths[EBML_TYPE_COUNT] = {
avformat/matroskadec: Improve invalid length error handling 1. Up until now, the error message for EBML numbers whose length exceeds the limits imposed upon them because of the element's type did not distinguish between known-length and unknown-length elements. As a consequence, the numerical value of the define constant EBML_UNKNOWN_LENGTH was emitted as part of the error message which is of course not appropriate. This commit changes this by adding error messages designed for unknown-length elements. 2. We impose some (arbitrary) sanity checks on the lengths of certain element types; these checks were conducted before the checks depending on whether the element exceeds its containing master element. Now the order has been reversed, because a failure at the (formerly) latter check implies that the file is truly erroneous and not only fails our arbitrary length limit. Moreover, this increases the informativeness of the error messages. 3. Furthermore, the error message in general has been changed by replacing the type of the element (something internal to this demuxer and therefore suitable as debug output at best, not as an error message intended for ordinary users) with the element ID. The element's position has been added, too. 4. Finally, the length limit for EBML_NONE elements has been changed so that all unknown-length elements of EBML_NONE-type trigger an error. This is done because unknown-length elements can't be skipped and need to be parsed, but there is no syntax to parse available for EBML_NONE elements. This is done in preparation for a further patch which allows more unknown-length elements than just clusters and segments. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
// Forbid unknown-length EBML_NONE elements.
[EBML_NONE] = EBML_UNKNOWN_LENGTH - 1,
[EBML_UINT] = 8,
[EBML_SINT] = 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;
uint64_t length;
int64_t pos = avio_tell(pb), pos_alt;
avformat/matroskadec: Redo level handling This commit changes how levels are handled: If the level used for ebml_parse ends directly after an element that has been consumed, then ebml_parse ends the level itself (and any known-length levels that end there as well) and informs the caller via the return value; if the current level is of unknown-length, then the level is ended as soon as an element that is not valid on the current level, but on a higher level is encountered (or if EOF has been encountered). This is designed for situations where one wants to parse master elements incrementally, i.e. not in one go via ebml_parse_nest. The (incremental) parsing of clusters still mixes levels by using a syntax list that contains elements from different levels and the level is still ended manually via a call to ebml_level_end if the last cluster was an unknown-length cluster (known-length clusters are already ended when their last element is read), but only if the next element is a cluster, too. A different level 1 element following an unknown-length cluster will currently simply be presumed to be part of the earlier cluster. Fixing this will be done in a future patch. The modifications to matroska_parse_cluster contained in this patch are only intended not to cause regressions. Nevertheless, the fact that known-length levels are automatically ended in ebml_parse when their last element has been read already fixes a bogus error message introduced in 9326117b that was emitted when a known-length cluster is followed by another level 1 element other than a cluster in which case the cluster's level was not ended (which only happened when a new cluster has been encountered) so that the length check (introduced in 9326117b) failed for the level 1 element as it is of course not contained in the previous cluster. Most Matroska files were affected by this. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
int res, update_pos = 1, level_check;
MatroskaLevel1Element *level1_elem;
avformat/matroskadec: Redo level handling This commit changes how levels are handled: If the level used for ebml_parse ends directly after an element that has been consumed, then ebml_parse ends the level itself (and any known-length levels that end there as well) and informs the caller via the return value; if the current level is of unknown-length, then the level is ended as soon as an element that is not valid on the current level, but on a higher level is encountered (or if EOF has been encountered). This is designed for situations where one wants to parse master elements incrementally, i.e. not in one go via ebml_parse_nest. The (incremental) parsing of clusters still mixes levels by using a syntax list that contains elements from different levels and the level is still ended manually via a call to ebml_level_end if the last cluster was an unknown-length cluster (known-length clusters are already ended when their last element is read), but only if the next element is a cluster, too. A different level 1 element following an unknown-length cluster will currently simply be presumed to be part of the earlier cluster. Fixing this will be done in a future patch. The modifications to matroska_parse_cluster contained in this patch are only intended not to cause regressions. Nevertheless, the fact that known-length levels are automatically ended in ebml_parse when their last element has been read already fixes a bogus error message introduced in 9326117b that was emitted when a known-length cluster is followed by another level 1 element other than a cluster in which case the cluster's level was not ended (which only happened when a new cluster has been encountered) so that the length check (introduced in 9326117b) failed for the level 1 element as it is of course not contained in the previous cluster. Most Matroska files were affected by this. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
MatroskaLevel *level = matroska->num_levels ? &matroska->levels[matroska->num_levels - 1] : NULL;
if (!matroska->current_id) {
uint64_t id;
res = ebml_read_num(matroska, pb, 4, &id, 0);
if (res < 0) {
avformat/matroskadec: Redo level handling This commit changes how levels are handled: If the level used for ebml_parse ends directly after an element that has been consumed, then ebml_parse ends the level itself (and any known-length levels that end there as well) and informs the caller via the return value; if the current level is of unknown-length, then the level is ended as soon as an element that is not valid on the current level, but on a higher level is encountered (or if EOF has been encountered). This is designed for situations where one wants to parse master elements incrementally, i.e. not in one go via ebml_parse_nest. The (incremental) parsing of clusters still mixes levels by using a syntax list that contains elements from different levels and the level is still ended manually via a call to ebml_level_end if the last cluster was an unknown-length cluster (known-length clusters are already ended when their last element is read), but only if the next element is a cluster, too. A different level 1 element following an unknown-length cluster will currently simply be presumed to be part of the earlier cluster. Fixing this will be done in a future patch. The modifications to matroska_parse_cluster contained in this patch are only intended not to cause regressions. Nevertheless, the fact that known-length levels are automatically ended in ebml_parse when their last element has been read already fixes a bogus error message introduced in 9326117b that was emitted when a known-length cluster is followed by another level 1 element other than a cluster in which case the cluster's level was not ended (which only happened when a new cluster has been encountered) so that the length check (introduced in 9326117b) failed for the level 1 element as it is of course not contained in the previous cluster. Most Matroska files were affected by this. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
if (pb->eof_reached && res == AVERROR_EOF) {
if (matroska->is_live)
// in live mode, finish parsing if EOF is reached.
return 1;
if (level && pos == avio_tell(pb)) {
if (level->length == EBML_UNKNOWN_LENGTH) {
// Unknown-length levels automatically end at EOF.
matroska->num_levels--;
return LEVEL_ENDED;
} else {
av_log(matroska->ctx, AV_LOG_ERROR, "File ended prematurely "
"at pos. %"PRIu64" (0x%"PRIx64")\n", pos, pos);
}
avformat/matroskadec: Redo level handling This commit changes how levels are handled: If the level used for ebml_parse ends directly after an element that has been consumed, then ebml_parse ends the level itself (and any known-length levels that end there as well) and informs the caller via the return value; if the current level is of unknown-length, then the level is ended as soon as an element that is not valid on the current level, but on a higher level is encountered (or if EOF has been encountered). This is designed for situations where one wants to parse master elements incrementally, i.e. not in one go via ebml_parse_nest. The (incremental) parsing of clusters still mixes levels by using a syntax list that contains elements from different levels and the level is still ended manually via a call to ebml_level_end if the last cluster was an unknown-length cluster (known-length clusters are already ended when their last element is read), but only if the next element is a cluster, too. A different level 1 element following an unknown-length cluster will currently simply be presumed to be part of the earlier cluster. Fixing this will be done in a future patch. The modifications to matroska_parse_cluster contained in this patch are only intended not to cause regressions. Nevertheless, the fact that known-length levels are automatically ended in ebml_parse when their last element has been read already fixes a bogus error message introduced in 9326117b that was emitted when a known-length cluster is followed by another level 1 element other than a cluster in which case the cluster's level was not ended (which only happened when a new cluster has been encountered) so that the length check (introduced in 9326117b) failed for the level 1 element as it is of course not contained in the previous cluster. Most Matroska files were affected by this. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
}
}
return res;
}
matroska->current_id = id | 1 << 7 * res;
pos_alt = pos + res;
} else {
pos_alt = pos;
pos -= (av_log2(matroska->current_id) + 7) / 8;
}
id = matroska->current_id;
syntax = ebml_parse_id(syntax, id);
if (!syntax->id && id != EBML_ID_VOID && id != EBML_ID_CRC32) {
avformat/matroskadec: Redo level handling This commit changes how levels are handled: If the level used for ebml_parse ends directly after an element that has been consumed, then ebml_parse ends the level itself (and any known-length levels that end there as well) and informs the caller via the return value; if the current level is of unknown-length, then the level is ended as soon as an element that is not valid on the current level, but on a higher level is encountered (or if EOF has been encountered). This is designed for situations where one wants to parse master elements incrementally, i.e. not in one go via ebml_parse_nest. The (incremental) parsing of clusters still mixes levels by using a syntax list that contains elements from different levels and the level is still ended manually via a call to ebml_level_end if the last cluster was an unknown-length cluster (known-length clusters are already ended when their last element is read), but only if the next element is a cluster, too. A different level 1 element following an unknown-length cluster will currently simply be presumed to be part of the earlier cluster. Fixing this will be done in a future patch. The modifications to matroska_parse_cluster contained in this patch are only intended not to cause regressions. Nevertheless, the fact that known-length levels are automatically ended in ebml_parse when their last element has been read already fixes a bogus error message introduced in 9326117b that was emitted when a known-length cluster is followed by another level 1 element other than a cluster in which case the cluster's level was not ended (which only happened when a new cluster has been encountered) so that the length check (introduced in 9326117b) failed for the level 1 element as it is of course not contained in the previous cluster. Most Matroska files were affected by this. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
if (level && level->length == EBML_UNKNOWN_LENGTH) {
// Unknown-length levels end when an element from an upper level
// in the hierarchy is encountered.
while (syntax->def.n) {
syntax = ebml_parse_id(syntax->def.n, id);
if (syntax->id) {
matroska->num_levels--;
return LEVEL_ENDED;
}
};
}
av_log(matroska->ctx, AV_LOG_DEBUG, "Unknown entry 0x%"PRIX32" at pos. "
"%"PRId64"\n", id, pos);
update_pos = 0; /* Don't update resync_pos as an error might have happened. */
}
if (data) {
data = (char *) data + syntax->data_offset;
if (syntax->list_elem_size) {
EbmlList *list = data;
void *newelem;
if ((unsigned)list->nb_elem + 1 >= UINT_MAX / syntax->list_elem_size)
return AVERROR(ENOMEM);
newelem = av_fast_realloc(list->elem,
&list->alloc_elem_size,
(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_STOP) {
matroska->current_id = 0;
if ((res = ebml_read_length(matroska, pb, &length)) < 0)
return res;
pos_alt += res;
if (matroska->num_levels > 0) {
if (length != EBML_UNKNOWN_LENGTH &&
level->length != EBML_UNKNOWN_LENGTH) {
uint64_t elem_end = pos_alt + length,
level_end = level->start + level->length;
avformat/matroskadec: Redo level handling This commit changes how levels are handled: If the level used for ebml_parse ends directly after an element that has been consumed, then ebml_parse ends the level itself (and any known-length levels that end there as well) and informs the caller via the return value; if the current level is of unknown-length, then the level is ended as soon as an element that is not valid on the current level, but on a higher level is encountered (or if EOF has been encountered). This is designed for situations where one wants to parse master elements incrementally, i.e. not in one go via ebml_parse_nest. The (incremental) parsing of clusters still mixes levels by using a syntax list that contains elements from different levels and the level is still ended manually via a call to ebml_level_end if the last cluster was an unknown-length cluster (known-length clusters are already ended when their last element is read), but only if the next element is a cluster, too. A different level 1 element following an unknown-length cluster will currently simply be presumed to be part of the earlier cluster. Fixing this will be done in a future patch. The modifications to matroska_parse_cluster contained in this patch are only intended not to cause regressions. Nevertheless, the fact that known-length levels are automatically ended in ebml_parse when their last element has been read already fixes a bogus error message introduced in 9326117b that was emitted when a known-length cluster is followed by another level 1 element other than a cluster in which case the cluster's level was not ended (which only happened when a new cluster has been encountered) so that the length check (introduced in 9326117b) failed for the level 1 element as it is of course not contained in the previous cluster. Most Matroska files were affected by this. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
if (elem_end < level_end) {
level_check = 0;
} else if (elem_end == level_end) {
level_check = LEVEL_ENDED;
} else {
av_log(matroska->ctx, AV_LOG_ERROR,
"Element at 0x%"PRIx64" ending at 0x%"PRIx64" exceeds "
"containing master element ending at 0x%"PRIx64"\n",
pos, elem_end, level_end);
return AVERROR_INVALIDDATA;
}
avformat/matroskadec: Redo level handling This commit changes how levels are handled: If the level used for ebml_parse ends directly after an element that has been consumed, then ebml_parse ends the level itself (and any known-length levels that end there as well) and informs the caller via the return value; if the current level is of unknown-length, then the level is ended as soon as an element that is not valid on the current level, but on a higher level is encountered (or if EOF has been encountered). This is designed for situations where one wants to parse master elements incrementally, i.e. not in one go via ebml_parse_nest. The (incremental) parsing of clusters still mixes levels by using a syntax list that contains elements from different levels and the level is still ended manually via a call to ebml_level_end if the last cluster was an unknown-length cluster (known-length clusters are already ended when their last element is read), but only if the next element is a cluster, too. A different level 1 element following an unknown-length cluster will currently simply be presumed to be part of the earlier cluster. Fixing this will be done in a future patch. The modifications to matroska_parse_cluster contained in this patch are only intended not to cause regressions. Nevertheless, the fact that known-length levels are automatically ended in ebml_parse when their last element has been read already fixes a bogus error message introduced in 9326117b that was emitted when a known-length cluster is followed by another level 1 element other than a cluster in which case the cluster's level was not ended (which only happened when a new cluster has been encountered) so that the length check (introduced in 9326117b) failed for the level 1 element as it is of course not contained in the previous cluster. Most Matroska files were affected by this. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
} else if (length != EBML_UNKNOWN_LENGTH) {
level_check = 0;
} else if (level->length != EBML_UNKNOWN_LENGTH) {
av_log(matroska->ctx, AV_LOG_ERROR, "Unknown-sized element "
"at 0x%"PRIx64" inside parent with finite size\n", pos);
return AVERROR_INVALIDDATA;
avformat/matroskadec: Accept more unknown-length elements The current Matroska specifications mandate that only two elements may use an unknown-length length: Segments and clusters. But this was not always so: For the greater part of Matroska's existence, all master elements were allowed to make use of the unknown-length feature. And there were muxers creating such files: For several years libavformat's Matroska muxer used unknown-length for all master elements when the output wasn't seekable. This only stopped in March 2010 with 2529bb30. And even afterwards it was possible (albeit unlikely) for libavformat to create unknown-length master elements that are in violation of today's specifications, namely if the master element was so big that the seek backwards to update the size could no longer be performed inside the AVIOContext's write buffer. This has only been fixed in October 2016 (with the patches that introduced support for writing CRC-32 elements). Libavformat's Matroska demuxer meanwhile has never really supported unknown-length elements besides segments and clusters. Support for the latter was hardcoded. This commit changes this: Now all master elements for which a syntax to parse them is available are supported. This includes the files produced by old versions of libavformat's muxer. More precisely, master elements that have unknown length and are about to be parsed (not skipped) are supported; only a warning is emitted for them. For normal files, this means that level 1 elements after the clusters that are encountered after the clusters have been parsed (i.e. not because they are referenced by the seekhead at the beginning of the file) are still unsupported (they would be skipped at this point if their length were known). Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
} else {
avformat/matroskadec: Redo level handling This commit changes how levels are handled: If the level used for ebml_parse ends directly after an element that has been consumed, then ebml_parse ends the level itself (and any known-length levels that end there as well) and informs the caller via the return value; if the current level is of unknown-length, then the level is ended as soon as an element that is not valid on the current level, but on a higher level is encountered (or if EOF has been encountered). This is designed for situations where one wants to parse master elements incrementally, i.e. not in one go via ebml_parse_nest. The (incremental) parsing of clusters still mixes levels by using a syntax list that contains elements from different levels and the level is still ended manually via a call to ebml_level_end if the last cluster was an unknown-length cluster (known-length clusters are already ended when their last element is read), but only if the next element is a cluster, too. A different level 1 element following an unknown-length cluster will currently simply be presumed to be part of the earlier cluster. Fixing this will be done in a future patch. The modifications to matroska_parse_cluster contained in this patch are only intended not to cause regressions. Nevertheless, the fact that known-length levels are automatically ended in ebml_parse when their last element has been read already fixes a bogus error message introduced in 9326117b that was emitted when a known-length cluster is followed by another level 1 element other than a cluster in which case the cluster's level was not ended (which only happened when a new cluster has been encountered) so that the length check (introduced in 9326117b) failed for the level 1 element as it is of course not contained in the previous cluster. Most Matroska files were affected by this. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
level_check = 0;
avformat/matroskadec: Accept more unknown-length elements The current Matroska specifications mandate that only two elements may use an unknown-length length: Segments and clusters. But this was not always so: For the greater part of Matroska's existence, all master elements were allowed to make use of the unknown-length feature. And there were muxers creating such files: For several years libavformat's Matroska muxer used unknown-length for all master elements when the output wasn't seekable. This only stopped in March 2010 with 2529bb30. And even afterwards it was possible (albeit unlikely) for libavformat to create unknown-length master elements that are in violation of today's specifications, namely if the master element was so big that the seek backwards to update the size could no longer be performed inside the AVIOContext's write buffer. This has only been fixed in October 2016 (with the patches that introduced support for writing CRC-32 elements). Libavformat's Matroska demuxer meanwhile has never really supported unknown-length elements besides segments and clusters. Support for the latter was hardcoded. This commit changes this: Now all master elements for which a syntax to parse them is available are supported. This includes the files produced by old versions of libavformat's muxer. More precisely, master elements that have unknown length and are about to be parsed (not skipped) are supported; only a warning is emitted for them. For normal files, this means that level 1 elements after the clusters that are encountered after the clusters have been parsed (i.e. not because they are referenced by the seekhead at the beginning of the file) are still unsupported (they would be skipped at this point if their length were known). Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
if (id != MATROSKA_ID_CLUSTER && (syntax->type == EBML_LEVEL1
|| syntax->type == EBML_NEST)) {
// According to the current specifications only clusters and
// segments are allowed to be unknown-length. We also accept
// other unknown-length master elements.
av_log(matroska->ctx, AV_LOG_WARNING,
"Found unknown-length element 0x%"PRIX32" other than "
"a cluster at 0x%"PRIx64". Spec-incompliant, but "
"parsing will nevertheless be attempted.\n", id, pos);
update_pos = -1;
}
}
avformat/matroskadec: Redo level handling This commit changes how levels are handled: If the level used for ebml_parse ends directly after an element that has been consumed, then ebml_parse ends the level itself (and any known-length levels that end there as well) and informs the caller via the return value; if the current level is of unknown-length, then the level is ended as soon as an element that is not valid on the current level, but on a higher level is encountered (or if EOF has been encountered). This is designed for situations where one wants to parse master elements incrementally, i.e. not in one go via ebml_parse_nest. The (incremental) parsing of clusters still mixes levels by using a syntax list that contains elements from different levels and the level is still ended manually via a call to ebml_level_end if the last cluster was an unknown-length cluster (known-length clusters are already ended when their last element is read), but only if the next element is a cluster, too. A different level 1 element following an unknown-length cluster will currently simply be presumed to be part of the earlier cluster. Fixing this will be done in a future patch. The modifications to matroska_parse_cluster contained in this patch are only intended not to cause regressions. Nevertheless, the fact that known-length levels are automatically ended in ebml_parse when their last element has been read already fixes a bogus error message introduced in 9326117b that was emitted when a known-length cluster is followed by another level 1 element other than a cluster in which case the cluster's level was not ended (which only happened when a new cluster has been encountered) so that the length check (introduced in 9326117b) failed for the level 1 element as it is of course not contained in the previous cluster. Most Matroska files were affected by this. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
} else
level_check = 0;
avformat/matroskadec: Introduce a "last known good" position Currently, resyncing during reading packets works as follows: The current position is recorded, then a call to matroska_parse_cluster is made and if said call fails, the demuxer tries to resync from the earlier position. If the call doesn't fail, but also doesn't deliver a packet, then this is looped. There are two problems with this approach: 1. The Matroska file format aims to be forward-compatible; to achieve this, a demuxer should simply ignore and skip elements it doesn't know about. But it is not possible to reliably distinguish unknown elements from junk. If matroska_parse_cluster encounters an unknown element, it can therefore not simply error out; instead it returns zero and the loop is iterated which includes an update of the position that is intended to be used in case of errors, i.e. the element that is skipped is not searched for level 1 element ids to resync to at all if later calls to matroska_parse_cluster return an error. Notice that in case that sync has been lost there can be a chain of several unknown/possibly junk elements before an error is detected. 2. Even if a call to matroska_parse_cluster delivers a packet, this does not mean that everything is fine. E.g. it might be that some of the block's data is missing and that the data that was presumed to be from the block just read actually contains the beginning of the next element. This will only be apparent at the next call of matroska_read_packet, which uses the (false) end of the earlier block as resync position so that in the (not unlikely) case that the call to matroska_parse_cluster fails, the data believed to be part of the earlier block is not searched for a level 1 element to resync to. To counter this, a "last known good" position is introduced. When an element id that is known to be allowed at this position in the hierarchy (according to the syntax currently in use for parsing) is read and some further checks (regarding the length of the element and its containing master element) are passed, then the beginning of the current element is treated as a "good" position and recorded as such in the MatroskaDemuxContext. Because of 2., only the start of the element is treated as a "good" position, not the whole element. If an error occurs later during parsing of clusters, the resync process starts at the last known good position. Given that when the header is damaged the subsequent resync never skips over data and is therefore unaffected by both issues, the "last known good" concept is not used there. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
avformat/matroskadec: Improve invalid length error handling 1. Up until now, the error message for EBML numbers whose length exceeds the limits imposed upon them because of the element's type did not distinguish between known-length and unknown-length elements. As a consequence, the numerical value of the define constant EBML_UNKNOWN_LENGTH was emitted as part of the error message which is of course not appropriate. This commit changes this by adding error messages designed for unknown-length elements. 2. We impose some (arbitrary) sanity checks on the lengths of certain element types; these checks were conducted before the checks depending on whether the element exceeds its containing master element. Now the order has been reversed, because a failure at the (formerly) latter check implies that the file is truly erroneous and not only fails our arbitrary length limit. Moreover, this increases the informativeness of the error messages. 3. Furthermore, the error message in general has been changed by replacing the type of the element (something internal to this demuxer and therefore suitable as debug output at best, not as an error message intended for ordinary users) with the element ID. The element's position has been added, too. 4. Finally, the length limit for EBML_NONE elements has been changed so that all unknown-length elements of EBML_NONE-type trigger an error. This is done because unknown-length elements can't be skipped and need to be parsed, but there is no syntax to parse available for EBML_NONE elements. This is done in preparation for a further patch which allows more unknown-length elements than just clusters and segments. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
if (max_lengths[syntax->type] && length > max_lengths[syntax->type]) {
if (length != EBML_UNKNOWN_LENGTH) {
av_log(matroska->ctx, AV_LOG_ERROR,
"Invalid length 0x%"PRIx64" > 0x%"PRIx64" for element "
"with ID 0x%"PRIX32" at 0x%"PRIx64"\n",
length, max_lengths[syntax->type], id, pos);
} else if (syntax->type != EBML_NONE) {
av_log(matroska->ctx, AV_LOG_ERROR,
"Element with ID 0x%"PRIX32" at pos. 0x%"PRIx64" has "
"unknown length, yet the length of an element of its "
"type must be known.\n", id, pos);
} else {
av_log(matroska->ctx, AV_LOG_ERROR,
"Found unknown-length element with ID 0x%"PRIX32" at "
"pos. 0x%"PRIx64" for which no syntax for parsing is "
"available.\n", id, pos);
}
return AVERROR_INVALIDDATA;
}
if (!(pb->seekable & AVIO_SEEKABLE_NORMAL)) {
// Loosing sync will likely manifest itself as encountering unknown
// elements which are not reliably distinguishable from elements
// belonging to future extensions of the format.
// We use a heuristic to detect such situations: If the current
// element is not expected at the current syntax level and there
// were only a few unknown elements in a row, then the element is
// skipped or considered defective based upon the length of the
// current element (i.e. how much would be skipped); if there were
// more than a few skipped elements in a row and skipping the current
// element would lead us more than SKIP_THRESHOLD away from the last
// known good position, then it is inferred that an error occurred.
// The dependency on the number of unknown elements in a row exists
// because the distance to the last known good position is
// automatically big if the last parsed element was big.
// In both cases, each unknown element is considered equivalent to
// UNKNOWN_EQUIV of skipped bytes for the check.
// The whole check is only done for non-seekable output, because
// in this situation skipped data can't simply be rechecked later.
// This is especially important when using unkown length elements
// as the check for whether a child exceeds its containing master
// element is not effective in this situation.
if (update_pos) {
matroska->unknown_count = 0;
} else {
int64_t dist = length + UNKNOWN_EQUIV * matroska->unknown_count++;
if (matroska->unknown_count > 3)
dist += pos_alt - matroska->resync_pos;
if (dist > SKIP_THRESHOLD) {
av_log(matroska->ctx, AV_LOG_ERROR,
"Unknown element %"PRIX32" at pos. 0x%"PRIx64" with "
"length 0x%"PRIx64" considered as invalid data. Last "
"known good position 0x%"PRIx64", %d unknown elements"
" in a row\n", id, pos, length, matroska->resync_pos,
matroska->unknown_count);
return AVERROR_INVALIDDATA;
}
}
}
avformat/matroskadec: Accept more unknown-length elements The current Matroska specifications mandate that only two elements may use an unknown-length length: Segments and clusters. But this was not always so: For the greater part of Matroska's existence, all master elements were allowed to make use of the unknown-length feature. And there were muxers creating such files: For several years libavformat's Matroska muxer used unknown-length for all master elements when the output wasn't seekable. This only stopped in March 2010 with 2529bb30. And even afterwards it was possible (albeit unlikely) for libavformat to create unknown-length master elements that are in violation of today's specifications, namely if the master element was so big that the seek backwards to update the size could no longer be performed inside the AVIOContext's write buffer. This has only been fixed in October 2016 (with the patches that introduced support for writing CRC-32 elements). Libavformat's Matroska demuxer meanwhile has never really supported unknown-length elements besides segments and clusters. Support for the latter was hardcoded. This commit changes this: Now all master elements for which a syntax to parse them is available are supported. This includes the files produced by old versions of libavformat's muxer. More precisely, master elements that have unknown length and are about to be parsed (not skipped) are supported; only a warning is emitted for them. For normal files, this means that level 1 elements after the clusters that are encountered after the clusters have been parsed (i.e. not because they are referenced by the seekhead at the beginning of the file) are still unsupported (they would be skipped at this point if their length were known). Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
if (update_pos > 0) {
avformat/matroskadec: Introduce a "last known good" position Currently, resyncing during reading packets works as follows: The current position is recorded, then a call to matroska_parse_cluster is made and if said call fails, the demuxer tries to resync from the earlier position. If the call doesn't fail, but also doesn't deliver a packet, then this is looped. There are two problems with this approach: 1. The Matroska file format aims to be forward-compatible; to achieve this, a demuxer should simply ignore and skip elements it doesn't know about. But it is not possible to reliably distinguish unknown elements from junk. If matroska_parse_cluster encounters an unknown element, it can therefore not simply error out; instead it returns zero and the loop is iterated which includes an update of the position that is intended to be used in case of errors, i.e. the element that is skipped is not searched for level 1 element ids to resync to at all if later calls to matroska_parse_cluster return an error. Notice that in case that sync has been lost there can be a chain of several unknown/possibly junk elements before an error is detected. 2. Even if a call to matroska_parse_cluster delivers a packet, this does not mean that everything is fine. E.g. it might be that some of the block's data is missing and that the data that was presumed to be from the block just read actually contains the beginning of the next element. This will only be apparent at the next call of matroska_read_packet, which uses the (false) end of the earlier block as resync position so that in the (not unlikely) case that the call to matroska_parse_cluster fails, the data believed to be part of the earlier block is not searched for a level 1 element to resync to. To counter this, a "last known good" position is introduced. When an element id that is known to be allowed at this position in the hierarchy (according to the syntax currently in use for parsing) is read and some further checks (regarding the length of the element and its containing master element) are passed, then the beginning of the current element is treated as a "good" position and recorded as such in the MatroskaDemuxContext. Because of 2., only the start of the element is treated as a "good" position, not the whole element. If an error occurs later during parsing of clusters, the resync process starts at the last known good position. Given that when the header is damaged the subsequent resync never skips over data and is therefore unaffected by both issues, the "last known good" concept is not used there. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
// We have found an element that is allowed at this place
// in the hierarchy and it passed all checks, so treat the beginning
// of the element as the "last known good" position.
matroska->resync_pos = pos;
}
if (!data && length != EBML_UNKNOWN_LENGTH)
goto skip;
}
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, pos_alt, data);
break;
case EBML_LEVEL1:
case EBML_NEST:
if ((res = ebml_read_master(matroska, length, pos_alt)) < 0)
return res;
if (id == MATROSKA_ID_SEGMENT)
matroska->segment_start = pos_alt;
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->pos) {
// Zero is not a valid position for a level 1 element.
level1_elem->pos = pos;
} else if (level1_elem->pos != pos)
av_log(matroska->ctx, AV_LOG_ERROR, "Duplicate element\n");
level1_elem->parsed = 1;
}
avformat/matroskadec: Redo level handling This commit changes how levels are handled: If the level used for ebml_parse ends directly after an element that has been consumed, then ebml_parse ends the level itself (and any known-length levels that end there as well) and informs the caller via the return value; if the current level is of unknown-length, then the level is ended as soon as an element that is not valid on the current level, but on a higher level is encountered (or if EOF has been encountered). This is designed for situations where one wants to parse master elements incrementally, i.e. not in one go via ebml_parse_nest. The (incremental) parsing of clusters still mixes levels by using a syntax list that contains elements from different levels and the level is still ended manually via a call to ebml_level_end if the last cluster was an unknown-length cluster (known-length clusters are already ended when their last element is read), but only if the next element is a cluster, too. A different level 1 element following an unknown-length cluster will currently simply be presumed to be part of the earlier cluster. Fixing this will be done in a future patch. The modifications to matroska_parse_cluster contained in this patch are only intended not to cause regressions. Nevertheless, the fact that known-length levels are automatically ended in ebml_parse when their last element has been read already fixes a bogus error message introduced in 9326117b that was emitted when a known-length cluster is followed by another level 1 element other than a cluster in which case the cluster's level was not ended (which only happened when a new cluster has been encountered) so that the length check (introduced in 9326117b) failed for the level 1 element as it is of course not contained in the previous cluster. Most Matroska files were affected by this. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
if (res = ebml_parse_nest(matroska, syntax->def.n, data))
return res;
break;
case EBML_STOP:
return 1;
skip:
default:
if (length) {
int64_t res2;
if (ffio_limit(pb, length) != length) {
// ffio_limit emits its own error message,
// so we don't have to.
return AVERROR(EIO);
}
if ((res2 = avio_skip(pb, length - 1)) >= 0) {
// avio_skip might take us past EOF. We check for this
// by skipping only length - 1 bytes, reading a byte and
// checking the error flags. This is done in order to check
// that the element has been properly skipped even when
// no filesize (that ffio_limit relies on) is available.
avio_r8(pb);
res = NEEDS_CHECKING;
} else
res = res2;
} else
res = 0;
}
if (res) {
if (res == NEEDS_CHECKING) {
if (pb->eof_reached) {
if (pb->error)
res = pb->error;
else
res = AVERROR_EOF;
} else
avformat/matroskadec: Redo level handling This commit changes how levels are handled: If the level used for ebml_parse ends directly after an element that has been consumed, then ebml_parse ends the level itself (and any known-length levels that end there as well) and informs the caller via the return value; if the current level is of unknown-length, then the level is ended as soon as an element that is not valid on the current level, but on a higher level is encountered (or if EOF has been encountered). This is designed for situations where one wants to parse master elements incrementally, i.e. not in one go via ebml_parse_nest. The (incremental) parsing of clusters still mixes levels by using a syntax list that contains elements from different levels and the level is still ended manually via a call to ebml_level_end if the last cluster was an unknown-length cluster (known-length clusters are already ended when their last element is read), but only if the next element is a cluster, too. A different level 1 element following an unknown-length cluster will currently simply be presumed to be part of the earlier cluster. Fixing this will be done in a future patch. The modifications to matroska_parse_cluster contained in this patch are only intended not to cause regressions. Nevertheless, the fact that known-length levels are automatically ended in ebml_parse when their last element has been read already fixes a bogus error message introduced in 9326117b that was emitted when a known-length cluster is followed by another level 1 element other than a cluster in which case the cluster's level was not ended (which only happened when a new cluster has been encountered) so that the length check (introduced in 9326117b) failed for the level 1 element as it is of course not contained in the previous cluster. Most Matroska files were affected by this. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
goto level_check;
}
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");
else if (res == AVERROR_EOF) {
av_log(matroska->ctx, AV_LOG_ERROR, "File ended prematurely\n");
res = AVERROR(EIO);
}
avformat/matroskadec: Redo level handling This commit changes how levels are handled: If the level used for ebml_parse ends directly after an element that has been consumed, then ebml_parse ends the level itself (and any known-length levels that end there as well) and informs the caller via the return value; if the current level is of unknown-length, then the level is ended as soon as an element that is not valid on the current level, but on a higher level is encountered (or if EOF has been encountered). This is designed for situations where one wants to parse master elements incrementally, i.e. not in one go via ebml_parse_nest. The (incremental) parsing of clusters still mixes levels by using a syntax list that contains elements from different levels and the level is still ended manually via a call to ebml_level_end if the last cluster was an unknown-length cluster (known-length clusters are already ended when their last element is read), but only if the next element is a cluster, too. A different level 1 element following an unknown-length cluster will currently simply be presumed to be part of the earlier cluster. Fixing this will be done in a future patch. The modifications to matroska_parse_cluster contained in this patch are only intended not to cause regressions. Nevertheless, the fact that known-length levels are automatically ended in ebml_parse when their last element has been read already fixes a bogus error message introduced in 9326117b that was emitted when a known-length cluster is followed by another level 1 element other than a cluster in which case the cluster's level was not ended (which only happened when a new cluster has been encountered) so that the length check (introduced in 9326117b) failed for the level 1 element as it is of course not contained in the previous cluster. Most Matroska files were affected by this. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
return res;
}
avformat/matroskadec: Redo level handling This commit changes how levels are handled: If the level used for ebml_parse ends directly after an element that has been consumed, then ebml_parse ends the level itself (and any known-length levels that end there as well) and informs the caller via the return value; if the current level is of unknown-length, then the level is ended as soon as an element that is not valid on the current level, but on a higher level is encountered (or if EOF has been encountered). This is designed for situations where one wants to parse master elements incrementally, i.e. not in one go via ebml_parse_nest. The (incremental) parsing of clusters still mixes levels by using a syntax list that contains elements from different levels and the level is still ended manually via a call to ebml_level_end if the last cluster was an unknown-length cluster (known-length clusters are already ended when their last element is read), but only if the next element is a cluster, too. A different level 1 element following an unknown-length cluster will currently simply be presumed to be part of the earlier cluster. Fixing this will be done in a future patch. The modifications to matroska_parse_cluster contained in this patch are only intended not to cause regressions. Nevertheless, the fact that known-length levels are automatically ended in ebml_parse when their last element has been read already fixes a bogus error message introduced in 9326117b that was emitted when a known-length cluster is followed by another level 1 element other than a cluster in which case the cluster's level was not ended (which only happened when a new cluster has been encountered) so that the length check (introduced in 9326117b) failed for the level 1 element as it is of course not contained in the previous cluster. Most Matroska files were affected by this. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
level_check:
if (level_check == LEVEL_ENDED && matroska->num_levels) {
level = &matroska->levels[matroska->num_levels - 1];
pos = avio_tell(pb);
// Given that pos >= level->start no check for
// level->length != EBML_UNKNOWN_LENGTH is necessary.
while (matroska->num_levels && pos == level->start + level->length) {
matroska->num_levels--;
level--;
}
}
return level_check;
}
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_buffer_unref(&((EbmlBin *) data_off)->buf);
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);
list->nb_elem = 0;
list->alloc_elem_size = 0;
} else
ebml_free(syntax[i].def.n, data_off);
default:
break;
}
}
}
/*
* Autodetecting...
*/
static int matroska_probe(const 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++];
if (total + 1 == 1ULL << (7 * size)){
/* Unknown-length header - simply parse the whole buffer. */
total = p->buf_size - 4 - size;
} else {
/* 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++) {
size_t 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 + AV_INPUT_BUFFER_PADDING_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 {
int insize = isize;
olen = pkt_size *= 3;
newpktdata = av_realloc(pkt_data, pkt_size + AV_LZO_OUTPUT_PADDING
+ AV_INPUT_BUFFER_PADDING_SIZE);
if (!newpktdata) {
result = AVERROR(ENOMEM);
goto failed;
}
pkt_data = newpktdata;
result = av_lzo1x_decode(pkt_data, &olen, data, &insize);
} 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 + AV_INPUT_BUFFER_PADDING_SIZE);
if (!newpktdata) {
inflateEnd(&zstream);
result = AVERROR(ENOMEM);
goto failed;
}
pkt_data = newpktdata;
zstream.avail_out = pkt_size - zstream.total_out;
zstream.next_out = pkt_data + zstream.total_out;
result = inflate(&zstream, Z_NO_FLUSH);
} 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 + AV_INPUT_BUFFER_PADDING_SIZE);
if (!newpktdata) {
BZ2_bzDecompressEnd(&bzstream);
result = AVERROR(ENOMEM);
goto failed;
}
pkt_data = newpktdata;
bzstream.avail_out = pkt_size - bzstream.total_out_lo32;
bzstream.next_out = pkt_data + bzstream.total_out_lo32;
result = BZ2_bzDecompress(&bzstream);
} 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;
}
memset(pkt_data + pkt_size, 0, AV_INPUT_BUFFER_PADDING_SIZE);
*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;
int found = 0;
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);
found = 1;
}
}
if (!found) {
av_log(NULL, AV_LOG_WARNING,
"The tags at index %d refer to a "
"non-existent attachment %"PRId64".\n",
i, tags[i].target.attachuid);
}
} else if (tags[i].target.chapteruid) {
MatroskaChapter *chapter = matroska->chapters.elem;
int found = 0;
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);
found = 1;
}
}
if (!found) {
av_log(NULL, AV_LOG_WARNING,
"The tags at index %d refer to a non-existent chapter "
"%"PRId64".\n",
i, tags[i].target.chapteruid);
}
} else if (tags[i].target.trackuid) {
MatroskaTrack *track = matroska->tracks.elem;
int found = 0;
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);
found = 1;
}
}
if (!found) {
av_log(NULL, AV_LOG_WARNING,
"The tags at index %d refer to a non-existent track "
"%"PRId64".\n",
i, tags[i].target.trackuid);
}
} else {
matroska_convert_tag(s, &tags[i].tag, &s->metadata,
tags[i].target.type);
}
}
}
static int matroska_parse_seekhead_entry(MatroskaDemuxContext *matroska,
int64_t pos)
{
uint32_t saved_id = matroska->current_id;
int64_t before_pos = avio_tell(matroska->ctx->pb);
int ret = 0;
/* seek */
if (avio_seek(matroska->ctx->pb, pos, SEEK_SET) == pos) {
/* 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 {
matroska->levels[matroska->num_levels] = (MatroskaLevel) { 0, EBML_UNKNOWN_LENGTH };
matroska->num_levels++;
matroska->current_id = 0;
ret = ebml_parse(matroska, matroska_segment, matroska);
avformat/matroskadec: Redo level handling This commit changes how levels are handled: If the level used for ebml_parse ends directly after an element that has been consumed, then ebml_parse ends the level itself (and any known-length levels that end there as well) and informs the caller via the return value; if the current level is of unknown-length, then the level is ended as soon as an element that is not valid on the current level, but on a higher level is encountered (or if EOF has been encountered). This is designed for situations where one wants to parse master elements incrementally, i.e. not in one go via ebml_parse_nest. The (incremental) parsing of clusters still mixes levels by using a syntax list that contains elements from different levels and the level is still ended manually via a call to ebml_level_end if the last cluster was an unknown-length cluster (known-length clusters are already ended when their last element is read), but only if the next element is a cluster, too. A different level 1 element following an unknown-length cluster will currently simply be presumed to be part of the earlier cluster. Fixing this will be done in a future patch. The modifications to matroska_parse_cluster contained in this patch are only intended not to cause regressions. Nevertheless, the fact that known-length levels are automatically ended in ebml_parse when their last element has been read already fixes a bogus error message introduced in 9326117b that was emitted when a known-length cluster is followed by another level 1 element other than a cluster in which case the cluster's level was not ended (which only happened when a new cluster has been encountered) so that the length check (introduced in 9326117b) failed for the level 1 element as it is of course not contained in the previous cluster. Most Matroska files were affected by this. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
if (ret == LEVEL_ENDED) {
/* This can only happen if the seek brought us beyond EOF. */
ret = AVERROR_EOF;
}
}
}
/* Seek back - notice that in all instances where this is used
* it is safe to set the level to 1. */
matroska_reset_status(matroska, saved_id, before_pos);
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 & AVIO_SEEKABLE_NORMAL))
return;
for (i = 0; i < seekhead_list->nb_elem; i++) {
MatroskaSeekhead *seekheads = seekhead_list->elem;
uint32_t id = seekheads[i].id;
int64_t pos = seekheads[i].pos + matroska->segment_start;
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;
uint64_t 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 < 2)
return;
if (index[1].time > 1E14 / matroska->time_scale) {
av_log(matroska->ctx, AV_LOG_WARNING, "Dropping apparently-broken index.\n");
return;
}
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)
{
/* Convert to seconds and adjust by number of seconds between 2001-01-01 and Epoch */
avpriv_dict_set_timestamp(metadata, "creation_time", date_utc / 1000 + 978307200000000LL);
}
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
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
st->codecpar->channel_layout = mask;
}
av_dict_free(&dict);
}
p += block_size;
size -= block_size;
}
return 0;
}
static int mkv_field_order(MatroskaDemuxContext *matroska, int64_t field_order)
{
int major, minor, micro, bttb = 0;
/* workaround a bug in our Matroska muxer, introduced in version 57.36 alongside
* this function, and fixed in 57.52 */
if (matroska->muxingapp && sscanf(matroska->muxingapp, "Lavf%d.%d.%d", &major, &minor, &micro) == 3)
bttb = (major == 57 && minor >= 36 && minor <= 51 && micro >= 100);
switch (field_order) {
case MATROSKA_VIDEO_FIELDORDER_PROGRESSIVE:
return AV_FIELD_PROGRESSIVE;
case MATROSKA_VIDEO_FIELDORDER_UNDETERMINED:
return AV_FIELD_UNKNOWN;
case MATROSKA_VIDEO_FIELDORDER_TT:
return AV_FIELD_TT;
case MATROSKA_VIDEO_FIELDORDER_BB:
return AV_FIELD_BB;
case MATROSKA_VIDEO_FIELDORDER_BT:
return bttb ? AV_FIELD_TB : AV_FIELD_BT;
case MATROSKA_VIDEO_FIELDORDER_TB:
return bttb ? AV_FIELD_BT : AV_FIELD_TB;
default:
return AV_FIELD_UNKNOWN;
}
}
static void mkv_stereo_mode_display_mul(int stereo_mode,
int *h_width, int *h_height)
{
switch (stereo_mode) {
case MATROSKA_VIDEO_STEREOMODE_TYPE_MONO:
case MATROSKA_VIDEO_STEREOMODE_TYPE_CHECKERBOARD_RL:
case MATROSKA_VIDEO_STEREOMODE_TYPE_CHECKERBOARD_LR:
case MATROSKA_VIDEO_STEREOMODE_TYPE_BOTH_EYES_BLOCK_RL:
case MATROSKA_VIDEO_STEREOMODE_TYPE_BOTH_EYES_BLOCK_LR:
break;
case MATROSKA_VIDEO_STEREOMODE_TYPE_RIGHT_LEFT:
case MATROSKA_VIDEO_STEREOMODE_TYPE_LEFT_RIGHT:
case MATROSKA_VIDEO_STEREOMODE_TYPE_COL_INTERLEAVED_RL:
case MATROSKA_VIDEO_STEREOMODE_TYPE_COL_INTERLEAVED_LR:
*h_width = 2;
break;
case MATROSKA_VIDEO_STEREOMODE_TYPE_BOTTOM_TOP:
case MATROSKA_VIDEO_STEREOMODE_TYPE_TOP_BOTTOM:
case MATROSKA_VIDEO_STEREOMODE_TYPE_ROW_INTERLEAVED_RL:
case MATROSKA_VIDEO_STEREOMODE_TYPE_ROW_INTERLEAVED_LR:
*h_height = 2;
break;
}
}
static int mkv_parse_video_color(AVStream *st, const MatroskaTrack *track) {
const MatroskaTrackVideoColor *color = track->video.color.elem;
const MatroskaMasteringMeta *mastering_meta;
int has_mastering_primaries, has_mastering_luminance;
if (!track->video.color.nb_elem)
return 0;
mastering_meta = &color->mastering_meta;
// Mastering primaries are CIE 1931 coords, and must be > 0.
has_mastering_primaries =
mastering_meta->r_x > 0 && mastering_meta->r_y > 0 &&
mastering_meta->g_x > 0 && mastering_meta->g_y > 0 &&
mastering_meta->b_x > 0 && mastering_meta->b_y > 0 &&
mastering_meta->white_x > 0 && mastering_meta->white_y > 0;
has_mastering_luminance = mastering_meta->max_luminance > 0;
if (color->matrix_coefficients != AVCOL_SPC_RESERVED)
st->codecpar->color_space = color->matrix_coefficients;
if (color->primaries != AVCOL_PRI_RESERVED &&
color->primaries != AVCOL_PRI_RESERVED0)
st->codecpar->color_primaries = color->primaries;
if (color->transfer_characteristics != AVCOL_TRC_RESERVED &&
color->transfer_characteristics != AVCOL_TRC_RESERVED0)
st->codecpar->color_trc = color->transfer_characteristics;
if (color->range != AVCOL_RANGE_UNSPECIFIED &&
color->range <= AVCOL_RANGE_JPEG)
st->codecpar->color_range = color->range;
if (color->chroma_siting_horz != MATROSKA_COLOUR_CHROMASITINGHORZ_UNDETERMINED &&
color->chroma_siting_vert != MATROSKA_COLOUR_CHROMASITINGVERT_UNDETERMINED &&
color->chroma_siting_horz < MATROSKA_COLOUR_CHROMASITINGHORZ_NB &&
color->chroma_siting_vert < MATROSKA_COLOUR_CHROMASITINGVERT_NB) {
st->codecpar->chroma_location =
avcodec_chroma_pos_to_enum((color->chroma_siting_horz - 1) << 7,
(color->chroma_siting_vert - 1) << 7);
}
if (color->max_cll && color->max_fall) {
size_t size = 0;
int ret;
AVContentLightMetadata *metadata = av_content_light_metadata_alloc(&size);
if (!metadata)
return AVERROR(ENOMEM);
ret = av_stream_add_side_data(st, AV_PKT_DATA_CONTENT_LIGHT_LEVEL,
(uint8_t *)metadata, size);
if (ret < 0) {
av_freep(&metadata);
return ret;
}
metadata->MaxCLL = color->max_cll;
metadata->MaxFALL = color->max_fall;
}
if (has_mastering_primaries || has_mastering_luminance) {
AVMasteringDisplayMetadata *metadata =
(AVMasteringDisplayMetadata*) av_stream_new_side_data(
st, AV_PKT_DATA_MASTERING_DISPLAY_METADATA,
sizeof(AVMasteringDisplayMetadata));
if (!metadata) {
return AVERROR(ENOMEM);
}
memset(metadata, 0, sizeof(AVMasteringDisplayMetadata));
if (has_mastering_primaries) {
metadata->display_primaries[0][0] = av_d2q(mastering_meta->r_x, INT_MAX);
metadata->display_primaries[0][1] = av_d2q(mastering_meta->r_y, INT_MAX);
metadata->display_primaries[1][0] = av_d2q(mastering_meta->g_x, INT_MAX);
metadata->display_primaries[1][1] = av_d2q(mastering_meta->g_y, INT_MAX);
metadata->display_primaries[2][0] = av_d2q(mastering_meta->b_x, INT_MAX);
metadata->display_primaries[2][1] = av_d2q(mastering_meta->b_y, INT_MAX);
metadata->white_point[0] = av_d2q(mastering_meta->white_x, INT_MAX);
metadata->white_point[1] = av_d2q(mastering_meta->white_y, INT_MAX);
metadata->has_primaries = 1;
}
if (has_mastering_luminance) {
metadata->max_luminance = av_d2q(mastering_meta->max_luminance, INT_MAX);
metadata->min_luminance = av_d2q(mastering_meta->min_luminance, INT_MAX);
metadata->has_luminance = 1;
}
}
return 0;
}
static int mkv_parse_video_projection(AVStream *st, const MatroskaTrack *track) {
AVSphericalMapping *spherical;
enum AVSphericalProjection projection;
size_t spherical_size;
uint32_t l = 0, t = 0, r = 0, b = 0;
uint32_t padding = 0;
int ret;
GetByteContext gb;
bytestream2_init(&gb, track->video.projection.private.data,
track->video.projection.private.size);
if (bytestream2_get_byte(&gb) != 0) {
av_log(NULL, AV_LOG_WARNING, "Unknown spherical metadata\n");
return 0;
}
bytestream2_skip(&gb, 3); // flags
switch (track->video.projection.type) {
case MATROSKA_VIDEO_PROJECTION_TYPE_EQUIRECTANGULAR:
if (track->video.projection.private.size == 20) {
t = bytestream2_get_be32(&gb);
b = bytestream2_get_be32(&gb);
l = bytestream2_get_be32(&gb);
r = bytestream2_get_be32(&gb);
if (b >= UINT_MAX - t || r >= UINT_MAX - l) {
av_log(NULL, AV_LOG_ERROR,
"Invalid bounding rectangle coordinates "
"%"PRIu32",%"PRIu32",%"PRIu32",%"PRIu32"\n",
l, t, r, b);
return AVERROR_INVALIDDATA;
}
} else if (track->video.projection.private.size != 0) {
av_log(NULL, AV_LOG_ERROR, "Unknown spherical metadata\n");
return AVERROR_INVALIDDATA;
}
if (l || t || r || b)
projection = AV_SPHERICAL_EQUIRECTANGULAR_TILE;
else
projection = AV_SPHERICAL_EQUIRECTANGULAR;
break;
case MATROSKA_VIDEO_PROJECTION_TYPE_CUBEMAP:
if (track->video.projection.private.size < 4) {
av_log(NULL, AV_LOG_ERROR, "Missing projection private properties\n");
return AVERROR_INVALIDDATA;
} else if (track->video.projection.private.size == 12) {
uint32_t layout = bytestream2_get_be32(&gb);
if (layout) {
av_log(NULL, AV_LOG_WARNING,
"Unknown spherical cubemap layout %"PRIu32"\n", layout);
return 0;
}
projection = AV_SPHERICAL_CUBEMAP;
padding = bytestream2_get_be32(&gb);
} else {
av_log(NULL, AV_LOG_ERROR, "Unknown spherical metadata\n");
return AVERROR_INVALIDDATA;
}
break;
case MATROSKA_VIDEO_PROJECTION_TYPE_RECTANGULAR:
/* No Spherical metadata */
return 0;
default:
av_log(NULL, AV_LOG_WARNING,
"Unknown spherical metadata type %"PRIu64"\n",
track->video.projection.type);
return 0;
}
spherical = av_spherical_alloc(&spherical_size);
if (!spherical)
return AVERROR(ENOMEM);
spherical->projection = projection;
spherical->yaw = (int32_t) (track->video.projection.yaw * (1 << 16));
spherical->pitch = (int32_t) (track->video.projection.pitch * (1 << 16));
spherical->roll = (int32_t) (track->video.projection.roll * (1 << 16));
spherical->padding = padding;
spherical->bound_left = l;
spherical->bound_top = t;
spherical->bound_right = r;
spherical->bound_bottom = b;
ret = av_stream_add_side_data(st, AV_PKT_DATA_SPHERICAL, (uint8_t *)spherical,
spherical_size);
if (ret < 0) {
av_freep(&spherical);
return ret;
}
return 0;
}
static int get_qt_codec(MatroskaTrack *track, uint32_t *fourcc, enum AVCodecID *codec_id)
{
const AVCodecTag *codec_tags;
codec_tags = track->type == MATROSKA_TRACK_TYPE_VIDEO ?
ff_codec_movvideo_tags : ff_codec_movaudio_tags;
/* Normalize noncompliant private data that starts with the fourcc
* by expanding/shifting the data by 4 bytes and storing the data
* size at the start. */
if (ff_codec_get_id(codec_tags, AV_RL32(track->codec_priv.data))) {
int ret = av_buffer_realloc(&track->codec_priv.buf,
track->codec_priv.size + 4 + AV_INPUT_BUFFER_PADDING_SIZE);
if (ret < 0)
return ret;
track->codec_priv.data = track->codec_priv.buf->data;
memmove(track->codec_priv.data + 4, track->codec_priv.data, track->codec_priv.size);
track->codec_priv.size += 4;
AV_WB32(track->codec_priv.data, track->codec_priv.size);
}
*fourcc = AV_RL32(track->codec_priv.data + 4);
*codec_id = ff_codec_get_id(codec_tags, *fourcc);
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->audio.samplerate < 0 || track->audio.samplerate > INT_MAX ||
isnan(track->audio.samplerate)) {
av_log(matroska->ctx, AV_LOG_WARNING,
"Invalid sample rate %f, defaulting to 8000 instead.\n",
track->audio.samplerate);
track->audio.samplerate = 8000;
}
if (track->type == MATROSKA_TRACK_TYPE_VIDEO) {
if (!track->default_duration && track->video.frame_rate > 0) {
double default_duration = 1000000000 / track->video.frame_rate;
if (default_duration > UINT64_MAX || default_duration < 0) {
av_log(matroska->ctx, AV_LOG_WARNING,
"Invalid frame rate %e. Cannot calculate default duration.\n",
track->video.frame_rate);
} else {
track->default_duration = default_duration;
}
}
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_buffer_unref(&track->codec_priv.buf);
if (track->codec_priv.data) {
track->codec_priv.buf = av_buffer_create(track->codec_priv.data,
track->codec_priv.size + AV_INPUT_BUFFER_PADDING_SIZE,
NULL, NULL, 0);
if (!track->codec_priv.buf) {
av_freep(&track->codec_priv.data);
track->codec_priv.size = 0;
return AVERROR(ENOMEM);
}
}
}
}
}
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,
AV_DICT_DONT_STRDUP_VAL);
}
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(s, &b, st->codecpar, track->codec_priv.size, 0);
if (ret < 0)
return ret;
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
codec_id = st->codecpar->codec_id;
fourcc = st->codecpar->codec_tag;
extradata_offset = FFMIN(track->codec_priv.size, 18);
} else if (!strcmp(track->codec_id, "A_QUICKTIME")
/* Normally 36, but allow noncompliant private data */
&& (track->codec_priv.size >= 32)
&& (track->codec_priv.data)) {
uint16_t sample_size;
int ret = get_qt_codec(track, &fourcc, &codec_id);
if (ret < 0)
return ret;
sample_size = AV_RB16(track->codec_priv.data + 26);
if (fourcc == 0) {
if (sample_size == 8) {
fourcc = MKTAG('r','a','w',' ');
codec_id = ff_codec_get_id(ff_codec_movaudio_tags, fourcc);
} else if (sample_size == 16) {
fourcc = MKTAG('t','w','o','s');
codec_id = ff_codec_get_id(ff_codec_movaudio_tags, fourcc);
}
}
if ((fourcc == MKTAG('t','w','o','s') ||
fourcc == MKTAG('s','o','w','t')) &&
sample_size == 8)
codec_id = AV_CODEC_ID_PCM_S8;
} else if (!strcmp(track->codec_id, "V_QUICKTIME") &&
(track->codec_priv.size >= 21) &&
(track->codec_priv.data)) {
int ret = get_qt_codec(track, &fourcc, &codec_id);
if (ret < 0)
return ret;
if (codec_id == AV_CODEC_ID_NONE && AV_RL32(track->codec_priv.data+4) == AV_RL32("SMI ")) {
fourcc = MKTAG('S','V','Q','3');
codec_id = ff_codec_get_id(ff_codec_movvideo_tags, fourcc);
}
if (codec_id == AV_CODEC_ID_NONE)
av_log(matroska->ctx, AV_LOG_ERROR,
"mov FourCC not found %s.\n", av_fourcc2str(fourcc));
if (track->codec_priv.size >= 86) {
bit_depth = AV_RB16(track->codec_priv.data + 82);
ffio_init_context(&b, track->codec_priv.data,
track->codec_priv.size,
0, NULL, NULL, NULL, NULL);
if (ff_get_qtpalette(codec_id, &b, track->palette)) {
bit_depth &= 0x1F;
track->has_palette = 1;
}
}
} 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 + AV_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;
Merge commit '059a934806d61f7af9ab3fd9f74994b838ea5eba' * commit '059a934806d61f7af9ab3fd9f74994b838ea5eba': lavc: Consistently prefix input buffer defines Conflicts: doc/examples/decoding_encoding.c libavcodec/4xm.c libavcodec/aac_adtstoasc_bsf.c libavcodec/aacdec.c libavcodec/aacenc.c libavcodec/ac3dec.h libavcodec/asvenc.c libavcodec/avcodec.h libavcodec/avpacket.c libavcodec/dvdec.c libavcodec/ffv1enc.c libavcodec/g2meet.c libavcodec/gif.c libavcodec/h264.c libavcodec/h264_mp4toannexb_bsf.c libavcodec/huffyuvdec.c libavcodec/huffyuvenc.c libavcodec/jpeglsenc.c libavcodec/libxvid.c libavcodec/mdec.c libavcodec/motionpixels.c libavcodec/mpeg4videodec.c libavcodec/mpegvideo.c libavcodec/noise_bsf.c libavcodec/nuv.c libavcodec/nvenc.c libavcodec/options.c libavcodec/parser.c libavcodec/pngenc.c libavcodec/proresenc_kostya.c libavcodec/qsvdec.c libavcodec/svq1enc.c libavcodec/tiffenc.c libavcodec/truemotion2.c libavcodec/utils.c libavcodec/utvideoenc.c libavcodec/vc1dec.c libavcodec/wmalosslessdec.c libavformat/adxdec.c libavformat/aiffdec.c libavformat/apc.c libavformat/apetag.c libavformat/avidec.c libavformat/bink.c libavformat/cafdec.c libavformat/flvdec.c libavformat/id3v2.c libavformat/isom.c libavformat/matroskadec.c libavformat/mov.c libavformat/mpc.c libavformat/mpc8.c libavformat/mpegts.c libavformat/mvi.c libavformat/mxfdec.c libavformat/mxg.c libavformat/nutdec.c libavformat/oggdec.c libavformat/oggparsecelt.c libavformat/oggparseflac.c libavformat/oggparseopus.c libavformat/oggparsespeex.c libavformat/omadec.c libavformat/rawdec.c libavformat/riffdec.c libavformat/rl2.c libavformat/rmdec.c libavformat/rtpdec_latm.c libavformat/rtpdec_mpeg4.c libavformat/rtpdec_qdm2.c libavformat/rtpdec_svq3.c libavformat/sierravmd.c libavformat/smacker.c libavformat/smush.c libavformat/spdifenc.c libavformat/takdec.c libavformat/tta.c libavformat/utils.c libavformat/vqf.c libavformat/westwood_vqa.c libavformat/xmv.c libavformat/xwma.c libavformat/yop.c Merged-by: Michael Niedermayer <michael@niedermayer.cc>
10 years ago
} else if (codec_id == AV_CODEC_ID_ALAC && track->codec_priv.size && track->codec_priv.size < INT_MAX - 12 - AV_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 +
AV_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) {
uint8_t *ptr;
if (track->audio.channels > UINT16_MAX ||
track->audio.bitdepth > UINT16_MAX) {
av_log(matroska->ctx, AV_LOG_WARNING,
"Too large audio channel number %"PRIu64
" or bitdepth %"PRIu64". Skipping track.\n",
track->audio.channels, track->audio.bitdepth);
if (matroska->ctx->error_recognition & AV_EF_EXPLODE)
return AVERROR_INVALIDDATA;
else
continue;
}
if (track->audio.out_samplerate < 0 || track->audio.out_samplerate > INT_MAX)
return AVERROR_INVALIDDATA;
extradata_size = 22;
extradata = av_mallocz(extradata_size + AV_INPUT_BUFFER_PADDING_SIZE);
if (!extradata)
return AVERROR(ENOMEM);
ptr = extradata;
bytestream_put_be32(&ptr, AV_RB32("TTA1"));
bytestream_put_le16(&ptr, 1);
bytestream_put_le16(&ptr, track->audio.channels);
bytestream_put_le16(&ptr, track->audio.bitdepth);
bytestream_put_le32(&ptr, track->audio.out_samplerate);
bytestream_put_le32(&ptr, 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 && codec_id != AV_CODEC_ID_SIPR)
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) {
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
st->codecpar->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];
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
st->codecpar->bit_rate = sipr_bit_rate[flavor];
}
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
st->codecpar->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);
} else if (codec_id == AV_CODEC_ID_VP9 && track->codec_priv.size) {
/* we don't need any value stored in CodecPrivate.
make sure that it's not exported as extradata. */
track->codec_priv.size = 0;
} else if (codec_id == AV_CODEC_ID_AV1 && track->codec_priv.size) {
/* For now, propagate only the OBUs, if any. Once libavcodec is
updated to handle isobmff style extradata this can be removed. */
extradata_offset = 4;
}
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_in_track_tb = av_rescale_q(track->codec_delay,
(AVRational){ 1, 1000000000 },
st->time_base);
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
st->codecpar->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;
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
if (!st->codecpar->extradata) {
if (extradata) {
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
st->codecpar->extradata = extradata;
st->codecpar->extradata_size = extradata_size;
} else if (track->codec_priv.data && track->codec_priv.size > 0) {
if (ff_alloc_extradata(st->codecpar, track->codec_priv.size))
return AVERROR(ENOMEM);
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
memcpy(st->codecpar->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;
int display_width_mul = 1;
int display_height_mul = 1;
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
st->codecpar->codec_type = AVMEDIA_TYPE_VIDEO;
st->codecpar->codec_tag = fourcc;
if (bit_depth >= 0)
st->codecpar->bits_per_coded_sample = bit_depth;
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
st->codecpar->width = track->video.pixel_width;
st->codecpar->height = track->video.pixel_height;
if (track->video.interlaced == MATROSKA_VIDEO_INTERLACE_FLAG_INTERLACED)
st->codecpar->field_order = mkv_field_order(matroska, track->video.field_order);
else if (track->video.interlaced == MATROSKA_VIDEO_INTERLACE_FLAG_PROGRESSIVE)
st->codecpar->field_order = AV_FIELD_PROGRESSIVE;
if (track->video.stereo_mode && track->video.stereo_mode < MATROSKA_VIDEO_STEREOMODE_TYPE_NB)
mkv_stereo_mode_display_mul(track->video.stereo_mode, &display_width_mul, &display_height_mul);
if (track->video.display_unit < MATROSKA_VIDEO_DISPLAYUNIT_UNKNOWN) {
av_reduce(&st->sample_aspect_ratio.num,
&st->sample_aspect_ratio.den,
st->codecpar->height * track->video.display_width * display_width_mul,
st->codecpar->width * track->video.display_height * display_height_mul,
255);
}
if (st->codecpar->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 && tracks[k].stream) {
av_dict_set(&tracks[k].stream->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;
}
ret = mkv_parse_video_color(st, track);
if (ret < 0)
return ret;
ret = mkv_parse_video_projection(st, track);
if (ret < 0)
return ret;
} else if (track->type == MATROSKA_TRACK_TYPE_AUDIO) {
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
st->codecpar->codec_type = AVMEDIA_TYPE_AUDIO;
st->codecpar->codec_tag = fourcc;
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
st->codecpar->sample_rate = track->audio.out_samplerate;
st->codecpar->channels = track->audio.channels;
if (!st->codecpar->bits_per_coded_sample)
st->codecpar->bits_per_coded_sample = track->audio.bitdepth;
if (st->codecpar->codec_id == AV_CODEC_ID_MP3 ||
st->codecpar->codec_id == AV_CODEC_ID_MLP ||
st->codecpar->codec_id == AV_CODEC_ID_TRUEHD)
st->need_parsing = AVSTREAM_PARSE_FULL;
else if (st->codecpar->codec_id != AV_CODEC_ID_AAC)
st->need_parsing = AVSTREAM_PARSE_HEADERS;
if (track->codec_delay > 0) {
st->codecpar->initial_padding = av_rescale_q(track->codec_delay,
(AVRational){1, 1000000000},
(AVRational){1, st->codecpar->codec_id == AV_CODEC_ID_OPUS ?
48000 : st->codecpar->sample_rate});
}
if (track->seek_preroll > 0) {
st->codecpar->seek_preroll = av_rescale_q(track->seek_preroll,
(AVRational){1, 1000000000},
(AVRational){1, st->codecpar->sample_rate});
}
} else if (codec_id == AV_CODEC_ID_WEBVTT) {
st->codecpar->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) {
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
st->codecpar->codec_type = AVMEDIA_TYPE_SUBTITLE;
}
}
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.doctype) {
av_log(matroska->ctx, AV_LOG_ERROR, "EBML header parsing failed\n");
ebml_free(ebml_syntax, &ebml);
return AVERROR_INVALIDDATA;
}
if (ebml.version > EBML_VERSION ||
ebml.max_size > sizeof(uint64_t) ||
ebml.id_length > sizeof(uint32_t) ||
ebml.doctype_version > 3) {
avpriv_report_missing_feature(matroska->ctx,
"EBML version %"PRIu64", doctype %s, doc version %"PRIu64,
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 an EBML_STOP type element.
while (res != 1) {
res = matroska_resync(matroska, pos);
if (res < 0)
goto fail;
pos = avio_tell(matroska->ctx->pb);
res = ebml_parse(matroska, matroska_segment, matroska);
}
/* Set data_offset as it might be needed later by seek_frame_generic. */
if (matroska->current_id == MATROSKA_ID_CLUSTER)
s->internal->data_offset = avio_tell(matroska->ctx->pb) - 4;
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)
goto fail;
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);
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
st->codecpar->codec_id = AV_CODEC_ID_NONE;
for (i = 0; ff_mkv_image_mime_tags[i].id != AV_CODEC_ID_NONE; i++) {
if (!strncmp(ff_mkv_image_mime_tags[i].str, attachments[j].mime,
strlen(ff_mkv_image_mime_tags[i].str))) {
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
st->codecpar->codec_id = ff_mkv_image_mime_tags[i].id;
break;
}
}
attachments[j].stream = st;
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
if (st->codecpar->codec_id != AV_CODEC_ID_NONE) {
AVPacket *pkt = &st->attached_pic;
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
st->disposition |= AV_DISPOSITION_ATTACHED_PIC;
st->codecpar->codec_type = AVMEDIA_TYPE_VIDEO;
av_init_packet(pkt);
pkt->buf = av_buffer_ref(attachments[j].bin.buf);
if (!pkt->buf)
return AVERROR(ENOMEM);
pkt->data = attachments[j].bin.data;
pkt->size = attachments[j].bin.size;
pkt->stream_index = st->index;
pkt->flags |= AV_PKT_FLAG_KEY;
} else {
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
st->codecpar->codec_type = AVMEDIA_TYPE_ATTACHMENT;
if (ff_alloc_extradata(st->codecpar, attachments[j].bin.size))
break;
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
memcpy(st->codecpar->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))) {
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
st->codecpar->codec_id = ff_mkv_mime_tags[i].id;
break;
}
}
}
}
}
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;
fail:
matroska_read_close(s);
return res;
}
/*
* 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->queue) {
MatroskaTrack *tracks = matroska->tracks.elem;
MatroskaTrack *track;
ff_packet_list_get(&matroska->queue, &matroska->queue_end, pkt);
track = &tracks[pkt->stream_index];
if (track->has_palette) {
uint8_t *pal = av_packet_new_side_data(pkt, AV_PKT_DATA_PALETTE, AVPALETTE_SIZE);
if (!pal) {
av_log(matroska->ctx, AV_LOG_ERROR, "Cannot append palette to packet\n");
} else {
memcpy(pal, track->palette, AVPALETTE_SIZE);
}
track->has_palette = 0;
}
return 0;
}
return -1;
}
/*
* Free all packets in our internal queue.
*/
static void matroska_clear_queue(MatroskaDemuxContext *matroska)
{
ff_packet_list_free(&matroska->queue, &matroska->queue_end);
}
static int matroska_parse_laces(MatroskaDemuxContext *matroska, uint8_t **buf,
int size, int type, AVIOContext *pb,
uint32_t lace_size[256], int *laces)
{
int n;
uint8_t *data = *buf;
if (!type) {
*laces = 1;
lace_size[0] = size;
return 0;
}
av_assert0(size > 0);
*laces = *data + 1;
data += 1;
size -= 1;
switch (type) {
case 0x1: /* Xiph lacing */
{
uint8_t temp;
uint32_t total = 0;
for (n = 0; n < *laces - 1; n++) {
lace_size[n] = 0;
while (1) {
if (size <= total) {
return AVERROR_INVALIDDATA;
}
temp = *data;
total += temp;
lace_size[n] += temp;
data += 1;
size -= 1;
if (temp != 0xff)
break;
}
}
if (size <= total) {
return AVERROR_INVALIDDATA;
}
lace_size[n] = size - total;
break;
}
case 0x2: /* fixed-size lacing */
if (size % (*laces)) {
return AVERROR_INVALIDDATA;
}
for (n = 0; n < *laces; n++)
lace_size[n] = size / *laces;
break;
case 0x3: /* EBML lacing */
{
uint64_t num;
uint64_t total;
int offset;
avio_skip(pb, 4);
n = ebml_read_num(matroska, pb, 8, &num, 1);
if (n < 0)
return n;
if (num > INT_MAX)
return AVERROR_INVALIDDATA;
total = lace_size[0] = num;
offset = n;
for (n = 1; n < *laces - 1; n++) {
int64_t snum;
int r;
r = matroska_ebmlnum_sint(matroska, pb, &snum);
if (r < 0)
return r;
if (lace_size[n - 1] + snum > (uint64_t)INT_MAX)
return AVERROR_INVALIDDATA;
lace_size[n] = lace_size[n - 1] + snum;
total += lace_size[n];
offset += r;
}
data += offset;
size -= offset;
if (size <= total) {
return AVERROR_INVALIDDATA;
}
lace_size[*laces - 1] = size - total;
break;
}
}
*buf = data;
return 0;
}
static int matroska_parse_rm_audio(MatroskaDemuxContext *matroska,
MatroskaTrack *track, AVStream *st,
uint8_t *data, int size, uint64_t timecode,
int64_t pos)
{
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
int a = st->codecpar->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;
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
if (st->codecpar->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);
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
} else if (st->codecpar->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) {
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
if (st->codecpar->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 pktl, *pkt = &pktl;
ret = av_new_packet(pkt, a);
if (ret < 0) {
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;
ret = ff_packet_list_put(&matroska->queue, &matroska->queue_end, pkt, 0);
if (ret < 0) {
av_packet_unref(pkt);
return AVERROR(ENOMEM);
}
}
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;
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
if (srclen < 12 || track->stream->codecpar->extradata_size < 2)
return AVERROR_INVALIDDATA;
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
ver = AV_RL16(track->stream->codecpar->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 + AV_INPUT_BUFFER_PADDING_SIZE);
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;
}
memset(dst + dstlen, 0, AV_INPUT_BUFFER_PADDING_SIZE);
*pdst = dst;
*size = dstlen;
return 0;
fail:
av_freep(&dst);
return ret;
}
static int matroska_parse_prores(MatroskaTrack *track, uint8_t *src,
uint8_t **pdst, int *size)
{
avformat/matroskadec: Fix use-after-free when demuxing ProRes ProRes in Matroska is supposed to not contain the first atom header (containing a size field and the tag "icpf") and therefore the Matroska demuxer has to recreate it; this involves an allocation and copy, of course. Whether the old buffer (containing the data without the atom header) needs to be freed or not depends upon whether it is what was directly read (in which case it is owned by an AVBuffer) or whether it has been allocated when reversing the track's content compression (e.g. zlib compression) that Matroska supports. So there are three pointers involved: The one pointing to the directly read data (owned by the AVBuffer), the one pointing to the currently valid data (which coincides with the former if no content compression needed to be reverted) and the one pointing to the new data with the first atom header. The check for whether to free the second of these is simply whether the first two are different. This works mostly, but there is a complication: Some muxers don't strip the first atom header away and in this case, it is also not reinserted and no new buffer is allocated; instead, the second and the third pointers agree. In this case, one must never free the second buffer. Yet it is currently done if the track is e.g. zlib compressed. This commit fixes this. This is a regression since b8e75a2a. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com> Signed-off-by: James Almer <jamrial@gmail.com>
5 years ago
uint8_t *dst;
int dstlen = *size + 8;
dst = av_malloc(dstlen + AV_INPUT_BUFFER_PADDING_SIZE);
if (!dst)
return AVERROR(ENOMEM);
AV_WB32(dst, dstlen);
AV_WB32(dst + 4, MKBETAG('i', 'c', 'p', 'f'));
memcpy(dst + 8, src, dstlen - 8);
memset(dst + dstlen, 0, AV_INPUT_BUFFER_PADDING_SIZE);
*pdst = dst;
*size = dstlen;
return 0;
}
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 pktl, *pkt = &pktl;
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;
err = av_new_packet(pkt, text_len);
if (err < 0) {
return 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_packet_unref(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_packet_unref(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;
err = ff_packet_list_put(&matroska->queue, &matroska->queue_end, pkt, 0);
if (err < 0) {
av_packet_unref(pkt);
return AVERROR(ENOMEM);
}
return 0;
}
static int matroska_parse_frame(MatroskaDemuxContext *matroska,
MatroskaTrack *track, AVStream *st,
AVBufferRef *buf, 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 res;
AVPacket pktl, *pkt = &pktl;
if (encodings && !encodings->type && encodings->scope & 1) {
res = matroska_decode_buffer(&pkt_data, &pkt_size, track);
if (res < 0)
return res;
}
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
if (st->codecpar->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;
}
avformat/matroskadec: Fix use-after-free when demuxing ProRes ProRes in Matroska is supposed to not contain the first atom header (containing a size field and the tag "icpf") and therefore the Matroska demuxer has to recreate it; this involves an allocation and copy, of course. Whether the old buffer (containing the data without the atom header) needs to be freed or not depends upon whether it is what was directly read (in which case it is owned by an AVBuffer) or whether it has been allocated when reversing the track's content compression (e.g. zlib compression) that Matroska supports. So there are three pointers involved: The one pointing to the directly read data (owned by the AVBuffer), the one pointing to the currently valid data (which coincides with the former if no content compression needed to be reverted) and the one pointing to the new data with the first atom header. The check for whether to free the second of these is simply whether the first two are different. This works mostly, but there is a complication: Some muxers don't strip the first atom header away and in this case, it is also not reinserted and no new buffer is allocated; instead, the second and the third pointers agree. In this case, one must never free the second buffer. Yet it is currently done if the track is e.g. zlib compressed. This commit fixes this. This is a regression since b8e75a2a. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com> Signed-off-by: James Almer <jamrial@gmail.com>
5 years ago
if (st->codecpar->codec_id == AV_CODEC_ID_PRORES &&
AV_RB32(pkt_data + 4) != MKBETAG('i', 'c', 'p', 'f')) {
uint8_t *pr_data;
res = matroska_parse_prores(track, pkt_data, &pr_data, &pkt_size);
if (res < 0) {
av_log(matroska->ctx, AV_LOG_ERROR,
"Error parsing a prores block.\n");
goto fail;
}
if (pkt_data != data)
av_freep(&pkt_data);
pkt_data = pr_data;
}
av_init_packet(pkt);
if (pkt_data != data)
pkt->buf = av_buffer_create(pkt_data, pkt_size + AV_INPUT_BUFFER_PADDING_SIZE,
NULL, NULL, 0);
else
pkt->buf = av_buffer_ref(buf);
if (!pkt->buf) {
res = AVERROR(ENOMEM);
goto fail;
}
pkt->data = pkt_data;
pkt->size = pkt_size;
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_packet_unref(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_packet_unref(pkt);
return AVERROR(ENOMEM);
}
discard_padding = av_rescale_q(discard_padding,
(AVRational){1, 1000000000},
(AVRational){1, st->codecpar->sample_rate});
if (discard_padding > 0) {
AV_WL32(side_data + 4, discard_padding);
} else {
AV_WL32(side_data, -discard_padding);
}
}
if (track->ms_compat)
pkt->dts = timecode;
else
pkt->pts = timecode;
pkt->pos = pos;
pkt->duration = lace_duration;
#if FF_API_CONVERGENCE_DURATION
FF_DISABLE_DEPRECATION_WARNINGS
if (st->codecpar->codec_id == AV_CODEC_ID_SUBRIP) {
pkt->convergence_duration = lace_duration;
}
FF_ENABLE_DEPRECATION_WARNINGS
#endif
res = ff_packet_list_put(&matroska->queue, &matroska->queue_end, pkt, 0);
if (res < 0) {
av_packet_unref(pkt);
return AVERROR(ENOMEM);
}
return 0;
fail:
if (pkt_data != data)
av_freep(&pkt_data);
return res;
}
static int matroska_parse_block(MatroskaDemuxContext *matroska, AVBufferRef *buf, 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;
AVIOContext pb;
int res = 0;
AVStream *st;
int16_t block_time;
uint32_t lace_size[256];
int n, flags, laces = 0;
uint64_t num;
int trust_default_duration = 1;
ffio_init_context(&pb, data, size, 0, NULL, NULL, NULL, NULL);
if ((n = ebml_read_num(matroska, &pb, 8, &num, 1)) < 0)
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"\n", num);
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_in_track_tb;
if (track->type == MATROSKA_TRACK_TYPE_SUBTITLE &&
timecode < track->end_timecode)
is_keyframe = 0; /* overlapping subtitles are not key frame */
if (is_keyframe) {
ff_reduce_index(matroska->ctx, st->index);
av_add_index_entry(st, cluster_pos, timecode, 0, 0,
AVINDEX_KEYFRAME);
}
}
if (matroska->skip_to_keyframe &&
track->type != MATROSKA_TRACK_TYPE_SUBTITLE) {
// Compare signed timecodes. Timecode may be negative due to codec delay
// offset. We don't support timestamps greater than int64_t anyway - see
// AVPacket's pts.
if ((int64_t)timecode < (int64_t)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,
&pb, lace_size, &laces);
if (res < 0) {
av_log(matroska->ctx, AV_LOG_ERROR, "Error parsing frame sizes.\n");
return res;
}
if (track->audio.samplerate == 8000) {
// If this is needed for more codecs, then add them here
if (st->codecpar->codec_id == AV_CODEC_ID_AC3) {
if (track->audio.samplerate != st->codecpar->sample_rate || !st->codecpar->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;
lavf: replace AVStream.codec with AVStream.codecpar Currently, AVStream contains an embedded AVCodecContext instance, which is used by demuxers to export stream parameters to the caller and by muxers to receive stream parameters from the caller. It is also used internally as the codec context that is passed to parsers. In addition, it is also widely used by the callers as the decoding (when demuxer) or encoding (when muxing) context, though this has been officially discouraged since Libav 11. There are multiple important problems with this approach: - the fields in AVCodecContext are in general one of * stream parameters * codec options * codec state However, it's not clear which ones are which. It is consequently unclear which fields are a demuxer allowed to set or a muxer allowed to read. This leads to erratic behaviour depending on whether decoding or encoding is being performed or not (and whether it uses the AVStream embedded codec context). - various synchronization issues arising from the fact that the same context is used by several different APIs (muxers/demuxers, parsers, bitstream filters and encoders/decoders) simultaneously, with there being no clear rules for who can modify what and the different processes being typically delayed with respect to each other. - avformat_find_stream_info() making it necessary to support opening and closing a single codec context multiple times, thus complicating the semantics of freeing various allocated objects in the codec context. Those problems are resolved by replacing the AVStream embedded codec context with a newly added AVCodecParameters instance, which stores only the stream parameters exported by the demuxers or read by the muxers.
11 years ago
if ((st->codecpar->codec_id == AV_CODEC_ID_RA_288 ||
st->codecpar->codec_id == AV_CODEC_ID_COOK ||
st->codecpar->codec_id == AV_CODEC_ID_SIPR ||
st->codecpar->codec_id == AV_CODEC_ID_ATRAC3) &&
st->codecpar->block_align && track->audio.sub_packet_size) {
res = matroska_parse_rm_audio(matroska, track, st, data,
lace_size[n],
timecode, pos);
if (res)
return res;
} else if (st->codecpar->codec_id == AV_CODEC_ID_WEBVTT) {
res = matroska_parse_webvtt(matroska, track, st,
data, lace_size[n],
timecode, lace_duration,
pos);
if (res)
return res;
} else {
res = matroska_parse_frame(matroska, track, st, buf, data, lace_size[n],
timecode, lace_duration, pos,
!n ? is_keyframe : 0,
additional, additional_id, additional_size,
discard_padding);
if (res)
return res;
}
if (timecode != AV_NOPTS_VALUE)
timecode = lace_duration ? timecode + lace_duration : AV_NOPTS_VALUE;
data += lace_size[n];
}
return 0;
}
static int matroska_parse_cluster(MatroskaDemuxContext *matroska)
{
MatroskaCluster *cluster = &matroska->current_cluster;
MatroskaBlock *block = &cluster->block;
int res;
av_assert0(matroska->num_levels <= 2);
if (matroska->num_levels == 1) {
res = ebml_parse(matroska, matroska_segment, NULL);
if (res == 1) {
/* Found a cluster: subtract the size of the ID already read. */
cluster->pos = avio_tell(matroska->ctx->pb) - 4;
res = ebml_parse(matroska, matroska_cluster_enter, cluster);
if (res < 0)
return res;
}
}
if (matroska->num_levels == 2) {
/* We are inside a cluster. */
res = ebml_parse(matroska, matroska_cluster_parsing, cluster);
if (res >= 0 && block->bin.size > 0) {
int is_keyframe = block->non_simple ? block->reference == INT64_MIN : -1;
uint8_t* additional = block->additional.size > 0 ?
block->additional.data : NULL;
res = matroska_parse_block(matroska, block->bin.buf, block->bin.data,
block->bin.size, block->bin.pos,
cluster->timecode, block->duration,
is_keyframe, additional, block->additional_id,
block->additional.size, cluster->pos,
block->discard_padding);
}
ebml_free(matroska_blockgroup, block);
memset(block, 0, sizeof(*block));
} else if (!matroska->num_levels) {
if (!avio_feof(matroska->ctx->pb)) {
avio_r8(matroska->ctx->pb);
if (!avio_feof(matroska->ctx->pb)) {
av_log(matroska->ctx, AV_LOG_WARNING, "File extends beyond "
"end of segment.\n");
return AVERROR_INVALIDDATA;
}
}
matroska->done = 1;
return AVERROR_EOF;
}
return res;
}
static int matroska_read_packet(AVFormatContext *s, AVPacket *pkt)
{
MatroskaDemuxContext *matroska = s->priv_data;
int ret = 0;
avformat/matroskadec: Introduce a "last known good" position Currently, resyncing during reading packets works as follows: The current position is recorded, then a call to matroska_parse_cluster is made and if said call fails, the demuxer tries to resync from the earlier position. If the call doesn't fail, but also doesn't deliver a packet, then this is looped. There are two problems with this approach: 1. The Matroska file format aims to be forward-compatible; to achieve this, a demuxer should simply ignore and skip elements it doesn't know about. But it is not possible to reliably distinguish unknown elements from junk. If matroska_parse_cluster encounters an unknown element, it can therefore not simply error out; instead it returns zero and the loop is iterated which includes an update of the position that is intended to be used in case of errors, i.e. the element that is skipped is not searched for level 1 element ids to resync to at all if later calls to matroska_parse_cluster return an error. Notice that in case that sync has been lost there can be a chain of several unknown/possibly junk elements before an error is detected. 2. Even if a call to matroska_parse_cluster delivers a packet, this does not mean that everything is fine. E.g. it might be that some of the block's data is missing and that the data that was presumed to be from the block just read actually contains the beginning of the next element. This will only be apparent at the next call of matroska_read_packet, which uses the (false) end of the earlier block as resync position so that in the (not unlikely) case that the call to matroska_parse_cluster fails, the data believed to be part of the earlier block is not searched for a level 1 element to resync to. To counter this, a "last known good" position is introduced. When an element id that is known to be allowed at this position in the hierarchy (according to the syntax currently in use for parsing) is read and some further checks (regarding the length of the element and its containing master element) are passed, then the beginning of the current element is treated as a "good" position and recorded as such in the MatroskaDemuxContext. Because of 2., only the start of the element is treated as a "good" position, not the whole element. If an error occurs later during parsing of clusters, the resync process starts at the last known good position. Given that when the header is damaged the subsequent resync never skips over data and is therefore unaffected by both issues, the "last known good" concept is not used there. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
if (matroska->resync_pos == -1) {
// This can only happen if generic seeking has been used.
matroska->resync_pos = avio_tell(s->pb);
}
while (matroska_deliver_packet(matroska, pkt)) {
if (matroska->done)
return (ret < 0) ? ret : AVERROR_EOF;
if (matroska_parse_cluster(matroska) < 0 && !matroska->done)
avformat/matroskadec: Introduce a "last known good" position Currently, resyncing during reading packets works as follows: The current position is recorded, then a call to matroska_parse_cluster is made and if said call fails, the demuxer tries to resync from the earlier position. If the call doesn't fail, but also doesn't deliver a packet, then this is looped. There are two problems with this approach: 1. The Matroska file format aims to be forward-compatible; to achieve this, a demuxer should simply ignore and skip elements it doesn't know about. But it is not possible to reliably distinguish unknown elements from junk. If matroska_parse_cluster encounters an unknown element, it can therefore not simply error out; instead it returns zero and the loop is iterated which includes an update of the position that is intended to be used in case of errors, i.e. the element that is skipped is not searched for level 1 element ids to resync to at all if later calls to matroska_parse_cluster return an error. Notice that in case that sync has been lost there can be a chain of several unknown/possibly junk elements before an error is detected. 2. Even if a call to matroska_parse_cluster delivers a packet, this does not mean that everything is fine. E.g. it might be that some of the block's data is missing and that the data that was presumed to be from the block just read actually contains the beginning of the next element. This will only be apparent at the next call of matroska_read_packet, which uses the (false) end of the earlier block as resync position so that in the (not unlikely) case that the call to matroska_parse_cluster fails, the data believed to be part of the earlier block is not searched for a level 1 element to resync to. To counter this, a "last known good" position is introduced. When an element id that is known to be allowed at this position in the hierarchy (according to the syntax currently in use for parsing) is read and some further checks (regarding the length of the element and its containing master element) are passed, then the beginning of the current element is treated as a "good" position and recorded as such in the MatroskaDemuxContext. Because of 2., only the start of the element is treated as a "good" position, not the whole element. If an error occurs later during parsing of clusters, the resync process starts at the last known good position. Given that when the header is damaged the subsequent resync never skips over data and is therefore unaffected by both issues, the "last known good" concept is not used there. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
ret = matroska_resync(matroska, matroska->resync_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;
/* 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) {
matroska_reset_status(matroska, 0, st->index_entries[st->nb_index_entries - 1].pos);
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;
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;
}
/* We seek to a level 1 element, so set the appropriate status. */
matroska_reset_status(matroska, 0, st->index_entries[index].pos);
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;
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_reset_status(matroska, 0, -1);
avformat/matroskadec: Introduce a "last known good" position Currently, resyncing during reading packets works as follows: The current position is recorded, then a call to matroska_parse_cluster is made and if said call fails, the demuxer tries to resync from the earlier position. If the call doesn't fail, but also doesn't deliver a packet, then this is looped. There are two problems with this approach: 1. The Matroska file format aims to be forward-compatible; to achieve this, a demuxer should simply ignore and skip elements it doesn't know about. But it is not possible to reliably distinguish unknown elements from junk. If matroska_parse_cluster encounters an unknown element, it can therefore not simply error out; instead it returns zero and the loop is iterated which includes an update of the position that is intended to be used in case of errors, i.e. the element that is skipped is not searched for level 1 element ids to resync to at all if later calls to matroska_parse_cluster return an error. Notice that in case that sync has been lost there can be a chain of several unknown/possibly junk elements before an error is detected. 2. Even if a call to matroska_parse_cluster delivers a packet, this does not mean that everything is fine. E.g. it might be that some of the block's data is missing and that the data that was presumed to be from the block just read actually contains the beginning of the next element. This will only be apparent at the next call of matroska_read_packet, which uses the (false) end of the earlier block as resync position so that in the (not unlikely) case that the call to matroska_parse_cluster fails, the data believed to be part of the earlier block is not searched for a level 1 element to resync to. To counter this, a "last known good" position is introduced. When an element id that is known to be allowed at this position in the hierarchy (according to the syntax currently in use for parsing) is read and some further checks (regarding the length of the element and its containing master element) are passed, then the beginning of the current element is treated as a "good" position and recorded as such in the MatroskaDemuxContext. Because of 2., only the start of the element is treated as a "good" position, not the whole element. If an error occurs later during parsing of clusters, the resync process starts at the last known good position. Given that when the header is damaged the subsequent resync never skips over data and is therefore unaffected by both issues, the "last known good" concept is not used there. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
6 years ago
matroska->resync_pos = -1;
matroska_clear_queue(matroska);
st->skip_to_keyframe =
matroska->skip_to_keyframe = 0;
matroska->done = 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_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 to
* 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;
uint32_t id = matroska->current_id;
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) {
uint64_t cluster_id, cluster_length;
int read;
AVPacket *pkt;
avio_seek(s->pb, cluster_pos, SEEK_SET);
// read cluster id and length
read = ebml_read_num(matroska, matroska->ctx->pb, 4, &cluster_id, 1);
if (read < 0 || cluster_id != 0xF43B675) // done with all clusters
break;
read = ebml_read_length(matroska, matroska->ctx->pb, &cluster_length);
if (read < 0)
break;
matroska_reset_status(matroska, 0, cluster_pos);
matroska_clear_queue(matroska);
if (matroska_parse_cluster(matroska) < 0 ||
!matroska->queue) {
break;
}
pkt = &matroska->queue->pkt;
// 4 + read is the length of the cluster id and the cluster length field.
cluster_pos += 4 + read + cluster_length;
if (!(pkt->flags & AV_PKT_FLAG_KEY)) {
rv = 0;
break;
}
}
/* Restore the status after matroska_read_header: */
matroska_reset_status(matroska, id, before_pos);
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, int64_t init_range)
{
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;
int end = 0;
// 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 (i.e. 4) + EBML length of the Cues element.
// cues_end is inclusive and the above sum is reduced by 1.
uint64_t cues_length, cues_id;
int bytes_read;
bytes_read = ebml_read_num (matroska, matroska->ctx->pb, 4, &cues_id, 1);
if (bytes_read < 0 || cues_id != (MATROSKA_ID_CUES & 0xfffffff))
return bytes_read < 0 ? bytes_read : AVERROR_INVALIDDATA;
bytes_read = ebml_read_length(matroska, matroska->ctx->pb, &cues_length);
if (bytes_read < 0)
return bytes_read;
cues_end = cues_start + 4 + bytes_read + cues_length - 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);
// if the file has cues at the start, fix up the init range so that
// it does not include it
if (cues_start <= init_range)
av_dict_set_int(&s->streams[0]->metadata, INITIALIZATION_RANGE, cues_start - 1, 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);
if (!buf) return -1;
strcpy(buf, "");
for (i = 0; i < s->streams[0]->nb_index_entries; i++) {
int ret = snprintf(buf + end, 20,
"%" PRId64"%s", s->streams[0]->index_entries[i].timestamp,
i != s->streams[0]->nb_index_entries - 1 ? "," : "");
if (ret <= 0 || (ret == 20 && i == s->streams[0]->nb_index_entries - 1)) {
av_log(s, AV_LOG_ERROR, "timestamp too long.\n");
av_free(buf);
return AVERROR_INVALIDDATA;
}
end += ret;
}
av_dict_set(&s->streams[0]->metadata, CUE_TIMESTAMPS,
buf, AV_DICT_DONT_STRDUP_VAL);
return 0;
}
static int webm_dash_manifest_read_header(AVFormatContext *s)
{
char *buf;
int ret = matroska_read_header(s);
int64_t init_range;
MatroskaTrack *tracks;
MatroskaDemuxContext *matroska = s->priv_data;
if (ret) {
av_log(s, AV_LOG_ERROR, "Failed to read file headers\n");
return -1;
}
if (!s->nb_streams) {
matroska_read_close(s);
av_log(s, AV_LOG_ERROR, "No streams found\n");
return AVERROR_INVALIDDATA;
}
if (!matroska->is_live) {
buf = av_asprintf("%g", matroska->duration);
if (!buf) return AVERROR(ENOMEM);
av_dict_set(&s->streams[0]->metadata, DURATION,
buf, AV_DICT_DONT_STRDUP_VAL);
// initialization range
// 5 is the offset of Cluster ID.
init_range = avio_tell(s->pb) - 5;
av_dict_set_int(&s->streams[0]->metadata, INITIALIZATION_RANGE, init_range, 0);
}
// basename of the file
buf = strrchr(s->url, '/');
av_dict_set(&s->streams[0]->metadata, FILENAME, buf ? ++buf : s->url, 0);
// 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
if (!matroska->is_live) {
ret = webm_dash_manifest_cues(s, init_range);
if (ret < 0) {
av_log(s, AV_LOG_ERROR, "Error parsing Cues\n");
return ret;
}
}
// use the bandwidth from the command line if it was provided
if (matroska->bandwidth > 0) {
av_dict_set_int(&s->streams[0]->metadata, BANDWIDTH,
matroska->bandwidth, 0);
}
return 0;
}
static int webm_dash_manifest_read_packet(AVFormatContext *s, AVPacket *pkt)
{
return AVERROR_EOF;
}
#define OFFSET(x) offsetof(MatroskaDemuxContext, x)
static const AVOption options[] = {
{ "live", "flag indicating that the input is a live file that only has the headers.", OFFSET(is_live), AV_OPT_TYPE_BOOL, {.i64 = 0}, 0, 1, AV_OPT_FLAG_DECODING_PARAM },
{ "bandwidth", "bandwidth of this stream to be specified in the DASH manifest.", OFFSET(bandwidth), AV_OPT_TYPE_INT, {.i64 = 0}, 0, INT_MAX, AV_OPT_FLAG_DECODING_PARAM },
{ NULL },
};
static const AVClass webm_dash_class = {
.class_name = "WebM DASH Manifest demuxer",
.item_name = av_default_item_name,
.option = options,
.version = LIBAVUTIL_VERSION_INT,
};
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,
.priv_class = &webm_dash_class,
};