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vpx/nestegg/src/nestegg.c
John Koleszar ad252daf65 ivfdec: webm reader support 
This patch enables ivfdec to decode WebM files. WebM demuxing is
provided by the Matthew Gregan's Nestegg library.

This patch also makes minor changes to the timebase->framerate
handling when doing Y4M output. For WebM files, the framerate is
guessed by looking at the first second of video. For IVF files,
the timebase=1/(2*fps) hack is still in place, but is only used
if the timebase denominator is less than 1000. This is in anticipation
of change I8d25b5b, which introduces the distinction between
framerate and timebase to ivfenc. In the case of high resolution
timebases, like 100ns, we would have to guess the framerate
like we do for WebM, but since WebM support in ivfenc will
deprecate IVF output, we just assume 30fps rather than writing the
lookahead code.

Change-Id: I1dd8600f13bf6071533d2816f005da9ede4f60a2
2010-10-25 22:01:40 -04:00

1939 lines
42 KiB
C
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/*
* Copyright © 2010 Mozilla Foundation
*
* This program is made available under an ISC-style license. See the
* accompanying file LICENSE for details.
*/
#include <assert.h>
#include <stdlib.h>
#include <string.h>
#include "nestegg/halloc/halloc.h"
#include "nestegg/include/nestegg/nestegg.h"
/* EBML Elements */
#define ID_EBML 0x1a45dfa3
#define ID_EBML_VERSION 0x4286
#define ID_EBML_READ_VERSION 0x42f7
#define ID_EBML_MAX_ID_LENGTH 0x42f2
#define ID_EBML_MAX_SIZE_LENGTH 0x42f3
#define ID_DOCTYPE 0x4282
#define ID_DOCTYPE_VERSION 0x4287
#define ID_DOCTYPE_READ_VERSION 0x4285
/* Global Elements */
#define ID_VOID 0xec
#define ID_CRC32 0xbf
/* WebMedia Elements */
#define ID_SEGMENT 0x18538067
/* Seek Head Elements */
#define ID_SEEK_HEAD 0x114d9b74
#define ID_SEEK 0x4dbb
#define ID_SEEK_ID 0x53ab
#define ID_SEEK_POSITION 0x53ac
/* Info Elements */
#define ID_INFO 0x1549a966
#define ID_TIMECODE_SCALE 0x2ad7b1
#define ID_DURATION 0x4489
/* Cluster Elements */
#define ID_CLUSTER 0x1f43b675
#define ID_TIMECODE 0xe7
#define ID_BLOCK_GROUP 0xa0
#define ID_SIMPLE_BLOCK 0xa3
/* BlockGroup Elements */
#define ID_BLOCK 0xa1
#define ID_BLOCK_DURATION 0x9b
#define ID_REFERENCE_BLOCK 0xfb
/* Tracks Elements */
#define ID_TRACKS 0x1654ae6b
#define ID_TRACK_ENTRY 0xae
#define ID_TRACK_NUMBER 0xd7
#define ID_TRACK_UID 0x73c5
#define ID_TRACK_TYPE 0x83
#define ID_FLAG_ENABLED 0xb9
#define ID_FLAG_DEFAULT 0x88
#define ID_FLAG_LACING 0x9c
#define ID_TRACK_TIMECODE_SCALE 0x23314f
#define ID_LANGUAGE 0x22b59c
#define ID_CODEC_ID 0x86
#define ID_CODEC_PRIVATE 0x63a2
/* Video Elements */
#define ID_VIDEO 0xe0
#define ID_PIXEL_WIDTH 0xb0
#define ID_PIXEL_HEIGHT 0xba
#define ID_PIXEL_CROP_BOTTOM 0x54aa
#define ID_PIXEL_CROP_TOP 0x54bb
#define ID_PIXEL_CROP_LEFT 0x54cc
#define ID_PIXEL_CROP_RIGHT 0x54dd
#define ID_DISPLAY_WIDTH 0x54b0
#define ID_DISPLAY_HEIGHT 0x54ba
/* Audio Elements */
#define ID_AUDIO 0xe1
#define ID_SAMPLING_FREQUENCY 0xb5
#define ID_CHANNELS 0x9f
#define ID_BIT_DEPTH 0x6264
/* Cues Elements */
#define ID_CUES 0x1c53bb6b
#define ID_CUE_POINT 0xbb
#define ID_CUE_TIME 0xb3
#define ID_CUE_TRACK_POSITIONS 0xb7
#define ID_CUE_TRACK 0xf7
#define ID_CUE_CLUSTER_POSITION 0xf1
#define ID_CUE_BLOCK_NUMBER 0x5378
/* EBML Types */
enum ebml_type_enum {
TYPE_UNKNOWN,
TYPE_MASTER,
TYPE_UINT,
TYPE_FLOAT,
TYPE_INT,
TYPE_STRING,
TYPE_BINARY
};
#define LIMIT_STRING (1 << 20)
#define LIMIT_BINARY (1 << 24)
#define LIMIT_BLOCK (1 << 30)
#define LIMIT_FRAME (1 << 28)
/* Field Flags */
#define DESC_FLAG_NONE 0
#define DESC_FLAG_MULTI (1 << 0)
#define DESC_FLAG_SUSPEND (1 << 1)
#define DESC_FLAG_OFFSET (1 << 2)
/* Block Header Flags */
#define BLOCK_FLAGS_LACING 6
/* Lacing Constants */
#define LACING_NONE 0
#define LACING_XIPH 1
#define LACING_FIXED 2
#define LACING_EBML 3
/* Track Types */
#define TRACK_TYPE_VIDEO 1
#define TRACK_TYPE_AUDIO 2
/* Track IDs */
#define TRACK_ID_VP8 "V_VP8"
#define TRACK_ID_VORBIS "A_VORBIS"
enum vint_mask {
MASK_NONE,
MASK_FIRST_BIT
};
struct ebml_binary {
unsigned char * data;
size_t length;
};
struct ebml_list_node {
struct ebml_list_node * next;
uint64_t id;
void * data;
};
struct ebml_list {
struct ebml_list_node * head;
struct ebml_list_node * tail;
};
struct ebml_type {
union ebml_value {
uint64_t u;
double f;
int64_t i;
char * s;
struct ebml_binary b;
} v;
enum ebml_type_enum type;
int read;
};
/* EBML Definitions */
struct ebml {
struct ebml_type ebml_version;
struct ebml_type ebml_read_version;
struct ebml_type ebml_max_id_length;
struct ebml_type ebml_max_size_length;
struct ebml_type doctype;
struct ebml_type doctype_version;
struct ebml_type doctype_read_version;
};
/* Matroksa Definitions */
struct seek {
struct ebml_type id;
struct ebml_type position;
};
struct seek_head {
struct ebml_list seek;
};
struct info {
struct ebml_type timecode_scale;
struct ebml_type duration;
};
struct block_group {
struct ebml_type duration;
struct ebml_type reference_block;
};
struct cluster {
struct ebml_type timecode;
struct ebml_list block_group;
};
struct video {
struct ebml_type pixel_width;
struct ebml_type pixel_height;
struct ebml_type pixel_crop_bottom;
struct ebml_type pixel_crop_top;
struct ebml_type pixel_crop_left;
struct ebml_type pixel_crop_right;
struct ebml_type display_width;
struct ebml_type display_height;
};
struct audio {
struct ebml_type sampling_frequency;
struct ebml_type channels;
struct ebml_type bit_depth;
};
struct track_entry {
struct ebml_type number;
struct ebml_type uid;
struct ebml_type type;
struct ebml_type flag_enabled;
struct ebml_type flag_default;
struct ebml_type flag_lacing;
struct ebml_type track_timecode_scale;
struct ebml_type language;
struct ebml_type codec_id;
struct ebml_type codec_private;
struct video video;
struct audio audio;
};
struct tracks {
struct ebml_list track_entry;
};
struct cue_track_positions {
struct ebml_type track;
struct ebml_type cluster_position;
struct ebml_type block_number;
};
struct cue_point {
struct ebml_type time;
struct ebml_list cue_track_positions;
};
struct cues {
struct ebml_list cue_point;
};
struct segment {
struct ebml_list seek_head;
struct info info;
struct ebml_list cluster;
struct tracks tracks;
struct cues cues;
};
/* Misc. */
struct pool_ctx {
char dummy;
};
struct list_node {
struct list_node * previous;
struct ebml_element_desc * node;
unsigned char * data;
};
struct saved_state {
int64_t stream_offset;
struct list_node * ancestor;
uint64_t last_id;
uint64_t last_size;
};
struct frame {
unsigned char * data;
size_t length;
struct frame * next;
};
/* Public (opaque) Structures */
struct nestegg {
nestegg_io * io;
nestegg_log log;
struct pool_ctx * alloc_pool;
uint64_t last_id;
uint64_t last_size;
struct list_node * ancestor;
struct ebml ebml;
struct segment segment;
int64_t segment_offset;
unsigned int track_count;
};
struct nestegg_packet {
uint64_t track;
uint64_t timecode;
struct frame * frame;
};
/* Element Descriptor */
struct ebml_element_desc {
char const * name;
uint64_t id;
enum ebml_type_enum type;
size_t offset;
unsigned int flags;
struct ebml_element_desc * children;
size_t size;
size_t data_offset;
};
#define E_FIELD(ID, TYPE, STRUCT, FIELD) \
{ #ID, ID, TYPE, offsetof(STRUCT, FIELD), DESC_FLAG_NONE, NULL, 0, 0 }
#define E_MASTER(ID, TYPE, STRUCT, FIELD) \
{ #ID, ID, TYPE, offsetof(STRUCT, FIELD), DESC_FLAG_MULTI, ne_ ## FIELD ## _elements, \
sizeof(struct FIELD), 0 }
#define E_SINGLE_MASTER_O(ID, TYPE, STRUCT, FIELD) \
{ #ID, ID, TYPE, offsetof(STRUCT, FIELD), DESC_FLAG_OFFSET, ne_ ## FIELD ## _elements, 0, \
offsetof(STRUCT, FIELD ## _offset) }
#define E_SINGLE_MASTER(ID, TYPE, STRUCT, FIELD) \
{ #ID, ID, TYPE, offsetof(STRUCT, FIELD), DESC_FLAG_NONE, ne_ ## FIELD ## _elements, 0, 0 }
#define E_SUSPEND(ID, TYPE) \
{ #ID, ID, TYPE, 0, DESC_FLAG_SUSPEND, NULL, 0, 0 }
#define E_LAST \
{ NULL, 0, 0, 0, DESC_FLAG_NONE, NULL, 0, 0 }
/* EBML Element Lists */
static struct ebml_element_desc ne_ebml_elements[] = {
E_FIELD(ID_EBML_VERSION, TYPE_UINT, struct ebml, ebml_version),
E_FIELD(ID_EBML_READ_VERSION, TYPE_UINT, struct ebml, ebml_read_version),
E_FIELD(ID_EBML_MAX_ID_LENGTH, TYPE_UINT, struct ebml, ebml_max_id_length),
E_FIELD(ID_EBML_MAX_SIZE_LENGTH, TYPE_UINT, struct ebml, ebml_max_size_length),
E_FIELD(ID_DOCTYPE, TYPE_STRING, struct ebml, doctype),
E_FIELD(ID_DOCTYPE_VERSION, TYPE_UINT, struct ebml, doctype_version),
E_FIELD(ID_DOCTYPE_READ_VERSION, TYPE_UINT, struct ebml, doctype_read_version),
E_LAST
};
/* WebMedia Element Lists */
static struct ebml_element_desc ne_seek_elements[] = {
E_FIELD(ID_SEEK_ID, TYPE_BINARY, struct seek, id),
E_FIELD(ID_SEEK_POSITION, TYPE_UINT, struct seek, position),
E_LAST
};
static struct ebml_element_desc ne_seek_head_elements[] = {
E_MASTER(ID_SEEK, TYPE_MASTER, struct seek_head, seek),
E_LAST
};
static struct ebml_element_desc ne_info_elements[] = {
E_FIELD(ID_TIMECODE_SCALE, TYPE_UINT, struct info, timecode_scale),
E_FIELD(ID_DURATION, TYPE_FLOAT, struct info, duration),
E_LAST
};
static struct ebml_element_desc ne_block_group_elements[] = {
E_SUSPEND(ID_BLOCK, TYPE_BINARY),
E_FIELD(ID_BLOCK_DURATION, TYPE_UINT, struct block_group, duration),
E_FIELD(ID_REFERENCE_BLOCK, TYPE_INT, struct block_group, reference_block),
E_LAST
};
static struct ebml_element_desc ne_cluster_elements[] = {
E_FIELD(ID_TIMECODE, TYPE_UINT, struct cluster, timecode),
E_MASTER(ID_BLOCK_GROUP, TYPE_MASTER, struct cluster, block_group),
E_SUSPEND(ID_SIMPLE_BLOCK, TYPE_BINARY),
E_LAST
};
static struct ebml_element_desc ne_video_elements[] = {
E_FIELD(ID_PIXEL_WIDTH, TYPE_UINT, struct video, pixel_width),
E_FIELD(ID_PIXEL_HEIGHT, TYPE_UINT, struct video, pixel_height),
E_FIELD(ID_PIXEL_CROP_BOTTOM, TYPE_UINT, struct video, pixel_crop_bottom),
E_FIELD(ID_PIXEL_CROP_TOP, TYPE_UINT, struct video, pixel_crop_top),
E_FIELD(ID_PIXEL_CROP_LEFT, TYPE_UINT, struct video, pixel_crop_left),
E_FIELD(ID_PIXEL_CROP_RIGHT, TYPE_UINT, struct video, pixel_crop_right),
E_FIELD(ID_DISPLAY_WIDTH, TYPE_UINT, struct video, display_width),
E_FIELD(ID_DISPLAY_HEIGHT, TYPE_UINT, struct video, display_height),
E_LAST
};
static struct ebml_element_desc ne_audio_elements[] = {
E_FIELD(ID_SAMPLING_FREQUENCY, TYPE_FLOAT, struct audio, sampling_frequency),
E_FIELD(ID_CHANNELS, TYPE_UINT, struct audio, channels),
E_FIELD(ID_BIT_DEPTH, TYPE_UINT, struct audio, bit_depth),
E_LAST
};
static struct ebml_element_desc ne_track_entry_elements[] = {
E_FIELD(ID_TRACK_NUMBER, TYPE_UINT, struct track_entry, number),
E_FIELD(ID_TRACK_UID, TYPE_UINT, struct track_entry, uid),
E_FIELD(ID_TRACK_TYPE, TYPE_UINT, struct track_entry, type),
E_FIELD(ID_FLAG_ENABLED, TYPE_UINT, struct track_entry, flag_enabled),
E_FIELD(ID_FLAG_DEFAULT, TYPE_UINT, struct track_entry, flag_default),
E_FIELD(ID_FLAG_LACING, TYPE_UINT, struct track_entry, flag_lacing),
E_FIELD(ID_TRACK_TIMECODE_SCALE, TYPE_FLOAT, struct track_entry, track_timecode_scale),
E_FIELD(ID_LANGUAGE, TYPE_STRING, struct track_entry, language),
E_FIELD(ID_CODEC_ID, TYPE_STRING, struct track_entry, codec_id),
E_FIELD(ID_CODEC_PRIVATE, TYPE_BINARY, struct track_entry, codec_private),
E_SINGLE_MASTER(ID_VIDEO, TYPE_MASTER, struct track_entry, video),
E_SINGLE_MASTER(ID_AUDIO, TYPE_MASTER, struct track_entry, audio),
E_LAST
};
static struct ebml_element_desc ne_tracks_elements[] = {
E_MASTER(ID_TRACK_ENTRY, TYPE_MASTER, struct tracks, track_entry),
E_LAST
};
static struct ebml_element_desc ne_cue_track_positions_elements[] = {
E_FIELD(ID_CUE_TRACK, TYPE_UINT, struct cue_track_positions, track),
E_FIELD(ID_CUE_CLUSTER_POSITION, TYPE_UINT, struct cue_track_positions, cluster_position),
E_FIELD(ID_CUE_BLOCK_NUMBER, TYPE_UINT, struct cue_track_positions, block_number),
E_LAST
};
static struct ebml_element_desc ne_cue_point_elements[] = {
E_FIELD(ID_CUE_TIME, TYPE_UINT, struct cue_point, time),
E_MASTER(ID_CUE_TRACK_POSITIONS, TYPE_MASTER, struct cue_point, cue_track_positions),
E_LAST
};
static struct ebml_element_desc ne_cues_elements[] = {
E_MASTER(ID_CUE_POINT, TYPE_MASTER, struct cues, cue_point),
E_LAST
};
static struct ebml_element_desc ne_segment_elements[] = {
E_MASTER(ID_SEEK_HEAD, TYPE_MASTER, struct segment, seek_head),
E_SINGLE_MASTER(ID_INFO, TYPE_MASTER, struct segment, info),
E_MASTER(ID_CLUSTER, TYPE_MASTER, struct segment, cluster),
E_SINGLE_MASTER(ID_TRACKS, TYPE_MASTER, struct segment, tracks),
E_SINGLE_MASTER(ID_CUES, TYPE_MASTER, struct segment, cues),
E_LAST
};
static struct ebml_element_desc ne_top_level_elements[] = {
E_SINGLE_MASTER(ID_EBML, TYPE_MASTER, nestegg, ebml),
E_SINGLE_MASTER_O(ID_SEGMENT, TYPE_MASTER, nestegg, segment),
E_LAST
};
#undef E_FIELD
#undef E_MASTER
#undef E_SINGLE_MASTER_O
#undef E_SINGLE_MASTER
#undef E_SUSPEND
#undef E_LAST
static struct pool_ctx *
ne_pool_init(void)
{
struct pool_ctx * pool;
pool = h_malloc(sizeof(*pool));
if (!pool)
abort();
return pool;
}
static void
ne_pool_destroy(struct pool_ctx * pool)
{
h_free(pool);
}
static void *
ne_pool_alloc(size_t size, struct pool_ctx * pool)
{
void * p;
p = h_malloc(size);
if (!p)
abort();
hattach(p, pool);
memset(p, 0, size);
return p;
}
static void *
ne_alloc(size_t size)
{
void * p;
p = calloc(1, size);
if (!p)
abort();
return p;
}
static int
ne_io_read(nestegg_io * io, void * buffer, size_t length)
{
return io->read(buffer, length, io->userdata);
}
static int
ne_io_seek(nestegg_io * io, int64_t offset, int whence)
{
return io->seek(offset, whence, io->userdata);
}
static int
ne_io_read_skip(nestegg_io * io, size_t length)
{
size_t get;
unsigned char buf[8192];
int r = 1;
while (length > 0) {
get = length < sizeof(buf) ? length : sizeof(buf);
r = ne_io_read(io, buf, get);
if (r != 1)
break;
length -= get;
}
return r;
}
static int64_t
ne_io_tell(nestegg_io * io)
{
return io->tell(io->userdata);
}
static int
ne_bare_read_vint(nestegg_io * io, uint64_t * value, uint64_t * length, enum vint_mask maskflag)
{
int r;
unsigned char b;
size_t maxlen = 8;
unsigned int count = 1, mask = 1 << 7;
r = ne_io_read(io, &b, 1);
if (r != 1)
return r;
while (count < maxlen) {
if ((b & mask) != 0)
break;
mask >>= 1;
count += 1;
}
if (length)
*length = count;
*value = b;
if (maskflag == MASK_FIRST_BIT)
*value = b & ~mask;
while (--count) {
r = ne_io_read(io, &b, 1);
if (r != 1)
return r;
*value <<= 8;
*value |= b;
}
return 1;
}
static int
ne_read_id(nestegg_io * io, uint64_t * value, uint64_t * length)
{
return ne_bare_read_vint(io, value, length, MASK_NONE);
}
static int
ne_read_vint(nestegg_io * io, uint64_t * value, uint64_t * length)
{
return ne_bare_read_vint(io, value, length, MASK_FIRST_BIT);
}
static int
ne_read_svint(nestegg_io * io, int64_t * value, uint64_t * length)
{
int r;
uint64_t uvalue;
uint64_t ulength;
int64_t svint_subtr[] = {
0x3f, 0x1fff,
0xfffff, 0x7ffffff,
0x3ffffffffLL, 0x1ffffffffffLL,
0xffffffffffffLL, 0x7fffffffffffffLL
};
r = ne_bare_read_vint(io, &uvalue, &ulength, MASK_FIRST_BIT);
if (r != 1)
return r;
*value = uvalue - svint_subtr[ulength - 1];
if (length)
*length = ulength;
return r;
}
static int
ne_read_uint(nestegg_io * io, uint64_t * val, uint64_t length)
{
unsigned char b;
int r;
if (length == 0 || length > 8)
return -1;
r = ne_io_read(io, &b, 1);
if (r != 1)
return r;
*val = b;
while (--length) {
r = ne_io_read(io, &b, 1);
if (r != 1)
return r;
*val <<= 8;
*val |= b;
}
return 1;
}
static int
ne_read_int(nestegg_io * io, int64_t * val, uint64_t length)
{
int r;
uint64_t uval, base;
r = ne_read_uint(io, &uval, length);
if (r != 1)
return r;
if (length < sizeof(int64_t)) {
base = 1;
base <<= length * 8 - 1;
if (uval >= base) {
base = 1;
base <<= length * 8;
} else {
base = 0;
}
*val = uval - base;
} else {
*val = (int64_t) uval;
}
return 1;
}
static int
ne_read_float(nestegg_io * io, double * val, uint64_t length)
{
union {
uint64_t u;
float f;
double d;
} value;
int r;
/* length == 10 not implemented */
if (length != 4 && length != 8)
return -1;
r = ne_read_uint(io, &value.u, length);
if (r != 1)
return r;
if (length == 4)
*val = value.f;
else
*val = value.d;
return 1;
}
static int
ne_read_string(nestegg * ctx, char ** val, uint64_t length)
{
char * str;
int r;
if (length == 0 || length > LIMIT_STRING)
return -1;
str = ne_pool_alloc(length + 1, ctx->alloc_pool);
r = ne_io_read(ctx->io, (unsigned char *) str, length);
if (r != 1)
return r;
str[length] = '\0';
*val = str;
return 1;
}
static int
ne_read_binary(nestegg * ctx, struct ebml_binary * val, uint64_t length)
{
if (length == 0 || length > LIMIT_BINARY)
return -1;
val->data = ne_pool_alloc(length, ctx->alloc_pool);
val->length = length;
return ne_io_read(ctx->io, val->data, length);
}
static int
ne_get_uint(struct ebml_type type, uint64_t * value)
{
if (!type.read)
return -1;
assert(type.type == TYPE_UINT);
*value = type.v.u;
return 0;
}
static int
ne_get_float(struct ebml_type type, double * value)
{
if (!type.read)
return -1;
assert(type.type == TYPE_FLOAT);
*value = type.v.f;
return 0;
}
static int
ne_get_string(struct ebml_type type, char ** value)
{
if (!type.read)
return -1;
assert(type.type == TYPE_STRING);
*value = type.v.s;
return 0;
}
static int
ne_get_binary(struct ebml_type type, struct ebml_binary * value)
{
if (!type.read)
return -1;
assert(type.type == TYPE_BINARY);
*value = type.v.b;
return 0;
}
static int
ne_is_ancestor_element(uint64_t id, struct list_node * ancestor)
{
struct ebml_element_desc * element;
for (; ancestor; ancestor = ancestor->previous)
for (element = ancestor->node; element->id; ++element)
if (element->id == id)
return 1;
return 0;
}
static struct ebml_element_desc *
ne_find_element(uint64_t id, struct ebml_element_desc * elements)
{
struct ebml_element_desc * element;
for (element = elements; element->id; ++element)
if (element->id == id)
return element;
return NULL;
}
static void
ne_ctx_push(nestegg * ctx, struct ebml_element_desc * ancestor, void * data)
{
struct list_node * item;
item = ne_alloc(sizeof(*item));
item->previous = ctx->ancestor;
item->node = ancestor;
item->data = data;
ctx->ancestor = item;
}
static void
ne_ctx_pop(nestegg * ctx)
{
struct list_node * item;
item = ctx->ancestor;
ctx->ancestor = item->previous;
free(item);
}
static int
ne_ctx_save(nestegg * ctx, struct saved_state * s)
{
s->stream_offset = ne_io_tell(ctx->io);
if (s->stream_offset < 0)
return -1;
s->ancestor = ctx->ancestor;
s->last_id = ctx->last_id;
s->last_size = ctx->last_size;
return 0;
}
static int
ne_ctx_restore(nestegg * ctx, struct saved_state * s)
{
int r;
r = ne_io_seek(ctx->io, s->stream_offset, NESTEGG_SEEK_SET);
if (r != 0)
return -1;
ctx->ancestor = s->ancestor;
ctx->last_id = s->last_id;
ctx->last_size = s->last_size;
return 0;
}
static int
ne_peek_element(nestegg * ctx, uint64_t * id, uint64_t * size)
{
int r;
if (ctx->last_id && ctx->last_size) {
if (id)
*id = ctx->last_id;
if (size)
*size = ctx->last_size;
return 1;
}
r = ne_read_id(ctx->io, &ctx->last_id, NULL);
if (r != 1)
return r;
r = ne_read_vint(ctx->io, &ctx->last_size, NULL);
if (r != 1)
return r;
if (id)
*id = ctx->last_id;
if (size)
*size = ctx->last_size;
return 1;
}
static int
ne_read_element(nestegg * ctx, uint64_t * id, uint64_t * size)
{
int r;
r = ne_peek_element(ctx, id, size);
if (r != 1)
return r;
ctx->last_id = 0;
ctx->last_size = 0;
return 1;
}
static void
ne_read_master(nestegg * ctx, struct ebml_element_desc * desc)
{
struct ebml_list * list;
struct ebml_list_node * node, * oldtail;
assert(desc->type == TYPE_MASTER && desc->flags & DESC_FLAG_MULTI);
ctx->log(ctx, NESTEGG_LOG_DEBUG, "multi master element %llx (%s)",
desc->id, desc->name);
list = (struct ebml_list *) (ctx->ancestor->data + desc->offset);
node = ne_pool_alloc(sizeof(*node), ctx->alloc_pool);
node->id = desc->id;
node->data = ne_pool_alloc(desc->size, ctx->alloc_pool);
oldtail = list->tail;
if (oldtail)
oldtail->next = node;
list->tail = node;
if (!list->head)
list->head = node;
ctx->log(ctx, NESTEGG_LOG_DEBUG, " -> using data %p", node->data);
ne_ctx_push(ctx, desc->children, node->data);
}
static void
ne_read_single_master(nestegg * ctx, struct ebml_element_desc * desc)
{
assert(desc->type == TYPE_MASTER && !(desc->flags & DESC_FLAG_MULTI));
ctx->log(ctx, NESTEGG_LOG_DEBUG, "single master element %llx (%s)",
desc->id, desc->name);
ctx->log(ctx, NESTEGG_LOG_DEBUG, " -> using data %p (%u)",
ctx->ancestor->data + desc->offset, desc->offset);
ne_ctx_push(ctx, desc->children, ctx->ancestor->data + desc->offset);
}
static int
ne_read_simple(nestegg * ctx, struct ebml_element_desc * desc, size_t length)
{
struct ebml_type * storage;
int r;
storage = (struct ebml_type *) (ctx->ancestor->data + desc->offset);
if (storage->read) {
ctx->log(ctx, NESTEGG_LOG_DEBUG, "element %llx (%s) already read, skipping",
desc->id, desc->name);
return 0;
}
storage->type = desc->type;
ctx->log(ctx, NESTEGG_LOG_DEBUG, "element %llx (%s) -> %p (%u)",
desc->id, desc->name, storage, desc->offset);
r = -1;
switch (desc->type) {
case TYPE_UINT:
r = ne_read_uint(ctx->io, &storage->v.u, length);
break;
case TYPE_FLOAT:
r = ne_read_float(ctx->io, &storage->v.f, length);
break;
case TYPE_INT:
r = ne_read_int(ctx->io, &storage->v.i, length);
break;
case TYPE_STRING:
r = ne_read_string(ctx, &storage->v.s, length);
break;
case TYPE_BINARY:
r = ne_read_binary(ctx, &storage->v.b, length);
break;
case TYPE_MASTER:
case TYPE_UNKNOWN:
assert(0);
break;
}
if (r == 1)
storage->read = 1;
return r;
}
static int
ne_parse(nestegg * ctx, struct ebml_element_desc * top_level)
{
int r;
int64_t * data_offset;
uint64_t id, size;
struct ebml_element_desc * element;
/* loop until we need to return:
- hit suspend point
- parse complete
- error occurred */
/* loop over elements at current level reading them if sublevel found,
push ctx onto stack and continue if sublevel ended, pop ctx off stack
and continue */
if (!ctx->ancestor)
return -1;
for (;;) {
r = ne_peek_element(ctx, &id, &size);
if (r != 1)
break;
element = ne_find_element(id, ctx->ancestor->node);
if (element) {
if (element->flags & DESC_FLAG_SUSPEND) {
assert(element->type == TYPE_BINARY);
ctx->log(ctx, NESTEGG_LOG_DEBUG, "suspend parse at %llx", id);
r = 1;
break;
}
r = ne_read_element(ctx, &id, &size);
if (r != 1)
break;
if (element->flags & DESC_FLAG_OFFSET) {
data_offset = (int64_t *) (ctx->ancestor->data + element->data_offset);
*data_offset = ne_io_tell(ctx->io);
if (*data_offset < 0) {
r = -1;
break;
}
}
if (element->type == TYPE_MASTER) {
if (element->flags & DESC_FLAG_MULTI)
ne_read_master(ctx, element);
else
ne_read_single_master(ctx, element);
continue;
} else {
r = ne_read_simple(ctx, element, size);
if (r < 0)
break;
}
} else if (ne_is_ancestor_element(id, ctx->ancestor->previous)) {
ctx->log(ctx, NESTEGG_LOG_DEBUG, "parent element %llx", id);
if (top_level && ctx->ancestor->node == top_level) {
ctx->log(ctx, NESTEGG_LOG_DEBUG, "*** parse about to back up past top_level");
r = 1;
break;
}
ne_ctx_pop(ctx);
} else {
r = ne_read_element(ctx, &id, &size);
if (r != 1)
break;
if (id != ID_VOID && id != ID_CRC32)
ctx->log(ctx, NESTEGG_LOG_DEBUG, "unknown element %llx", id);
r = ne_io_read_skip(ctx->io, size);
if (r != 1)
break;
}
}
if (r != 1)
while (ctx->ancestor)
ne_ctx_pop(ctx);
return r;
}
static uint64_t
ne_xiph_lace_value(unsigned char ** np)
{
uint64_t lace;
uint64_t value;
unsigned char * p = *np;
lace = *p++;
value = lace;
while (lace == 255) {
lace = *p++;
value += lace;
}
*np = p;
return value;
}
static int
ne_read_xiph_lace_value(nestegg_io * io, uint64_t * value, size_t * consumed)
{
int r;
uint64_t lace;
r = ne_read_uint(io, &lace, 1);
if (r != 1)
return r;
*consumed += 1;
*value = lace;
while (lace == 255) {
r = ne_read_uint(io, &lace, 1);
if (r != 1)
return r;
*consumed += 1;
*value += lace;
}
return 1;
}
static int
ne_read_xiph_lacing(nestegg_io * io, size_t block, size_t * read, uint64_t n, uint64_t * sizes)
{
int r;
size_t i = 0;
uint64_t sum = 0;
while (--n) {
r = ne_read_xiph_lace_value(io, &sizes[i], read);
if (r != 1)
return r;
sum += sizes[i];
i += 1;
}
if (*read + sum > block)
return -1;
/* last frame is the remainder of the block */
sizes[i] = block - *read - sum;
return 1;
}
static int
ne_read_ebml_lacing(nestegg_io * io, size_t block, size_t * read, uint64_t n, uint64_t * sizes)
{
int r;
uint64_t lace, sum, length;
int64_t slace;
size_t i = 0;
r = ne_read_vint(io, &lace, &length);
if (r != 1)
return r;
*read += length;
sizes[i] = lace;
sum = sizes[i];
i += 1;
n -= 1;
while (--n) {
r = ne_read_svint(io, &slace, &length);
if (r != 1)
return r;
*read += length;
sizes[i] = sizes[i - 1] + slace;
sum += sizes[i];
i += 1;
}
if (*read + sum > block)
return -1;
/* last frame is the remainder of the block */
sizes[i] = block - *read - sum;
return 1;
}
static uint64_t
ne_get_timecode_scale(nestegg * ctx)
{
uint64_t scale;
if (ne_get_uint(ctx->segment.info.timecode_scale, &scale) != 0)
scale = 1000000;
return scale;
}
static struct track_entry *
ne_find_track_entry(nestegg * ctx, unsigned int track)
{
struct ebml_list_node * node;
unsigned int tracks = 0;
node = ctx->segment.tracks.track_entry.head;
while (node) {
assert(node->id == ID_TRACK_ENTRY);
if (track == tracks)
return node->data;
tracks += 1;
node = node->next;
}
return NULL;
}
static int
ne_read_block(nestegg * ctx, uint64_t block_id, uint64_t block_size, nestegg_packet ** data)
{
int r;
int64_t timecode, abs_timecode;
nestegg_packet * pkt;
struct cluster * cluster;
struct frame * f, * last;
struct track_entry * entry;
double track_scale;
uint64_t track, length, frame_sizes[256], cluster_tc, flags, frames, tc_scale, total;
unsigned int i, lacing;
size_t consumed = 0;
*data = NULL;
if (block_size > LIMIT_BLOCK)
return -1;
r = ne_read_vint(ctx->io, &track, &length);
if (r != 1)
return r;
if (track == 0 || track > ctx->track_count)
return -1;
consumed += length;
r = ne_read_int(ctx->io, &timecode, 2);
if (r != 1)
return r;
consumed += 2;
r = ne_read_uint(ctx->io, &flags, 1);
if (r != 1)
return r;
consumed += 1;
frames = 0;
/* flags are different between block and simpleblock, but lacing is
encoded the same way */
lacing = (flags & BLOCK_FLAGS_LACING) >> 1;
switch (lacing) {
case LACING_NONE:
frames = 1;
break;
case LACING_XIPH:
case LACING_FIXED:
case LACING_EBML:
r = ne_read_uint(ctx->io, &frames, 1);
if (r != 1)
return r;
consumed += 1;
frames += 1;
}
if (frames > 256)
return -1;
switch (lacing) {
case LACING_NONE:
frame_sizes[0] = block_size - consumed;
break;
case LACING_XIPH:
if (frames == 1)
return -1;
r = ne_read_xiph_lacing(ctx->io, block_size, &consumed, frames, frame_sizes);
if (r != 1)
return r;
break;
case LACING_FIXED:
if ((block_size - consumed) % frames)
return -1;
for (i = 0; i < frames; ++i)
frame_sizes[i] = (block_size - consumed) / frames;
break;
case LACING_EBML:
if (frames == 1)
return -1;
r = ne_read_ebml_lacing(ctx->io, block_size, &consumed, frames, frame_sizes);
if (r != 1)
return r;
break;
}
/* sanity check unlaced frame sizes against total block size. */
total = consumed;
for (i = 0; i < frames; ++i)
total += frame_sizes[i];
if (total > block_size)
return -1;
entry = ne_find_track_entry(ctx, track - 1);
if (!entry)
return -1;
track_scale = 1.0;
tc_scale = ne_get_timecode_scale(ctx);
assert(ctx->segment.cluster.tail->id == ID_CLUSTER);
cluster = ctx->segment.cluster.tail->data;
if (ne_get_uint(cluster->timecode, &cluster_tc) != 0)
return -1;
abs_timecode = timecode + cluster_tc;
if (abs_timecode < 0)
return -1;
pkt = ne_alloc(sizeof(*pkt));
pkt->track = track - 1;
pkt->timecode = abs_timecode * tc_scale * track_scale;
ctx->log(ctx, NESTEGG_LOG_DEBUG, "%sblock t %lld pts %f f %llx frames: %llu",
block_id == ID_BLOCK ? "" : "simple", pkt->track, pkt->timecode / 1e9, flags, frames);
last = NULL;
for (i = 0; i < frames; ++i) {
if (frame_sizes[i] > LIMIT_FRAME) {
nestegg_free_packet(pkt);
return -1;
}
f = ne_alloc(sizeof(*f));
f->data = ne_alloc(frame_sizes[i]);
f->length = frame_sizes[i];
r = ne_io_read(ctx->io, f->data, frame_sizes[i]);
if (r != 1) {
free(f->data);
free(f);
nestegg_free_packet(pkt);
return -1;
}
if (!last)
pkt->frame = f;
else
last->next = f;
last = f;
}
*data = pkt;
return 1;
}
static uint64_t
ne_buf_read_id(unsigned char const * p, size_t length)
{
uint64_t id = 0;
while (length--) {
id <<= 8;
id |= *p++;
}
return id;
}
static struct seek *
ne_find_seek_for_id(struct ebml_list_node * seek_head, uint64_t id)
{
struct ebml_list * head;
struct ebml_list_node * seek;
struct ebml_binary binary_id;
struct seek * s;
while (seek_head) {
assert(seek_head->id == ID_SEEK_HEAD);
head = seek_head->data;
seek = head->head;
while (seek) {
assert(seek->id == ID_SEEK);
s = seek->data;
if (ne_get_binary(s->id, &binary_id) == 0 &&
ne_buf_read_id(binary_id.data, binary_id.length) == id)
return s;
seek = seek->next;
}
seek_head = seek_head->next;
}
return NULL;
}
static struct cue_point *
ne_find_cue_point_for_tstamp(struct ebml_list_node * cue_point, uint64_t scale, uint64_t tstamp)
{
uint64_t time;
struct cue_point * c, * prev = NULL;
while (cue_point) {
assert(cue_point->id == ID_CUE_POINT);
c = cue_point->data;
if (!prev)
prev = c;
if (ne_get_uint(c->time, &time) == 0 && time * scale > tstamp)
break;
prev = cue_point->data;
cue_point = cue_point->next;
}
return prev;
}
static int
ne_is_suspend_element(uint64_t id)
{
/* this could search the tree of elements for DESC_FLAG_SUSPEND */
if (id == ID_SIMPLE_BLOCK || id == ID_BLOCK)
return 1;
return 0;
}
static void
ne_null_log_callback(nestegg * ctx, unsigned int severity, char const * fmt, ...)
{
if (ctx && severity && fmt)
return;
}
int
nestegg_init(nestegg ** context, nestegg_io io, nestegg_log callback)
{
int r;
uint64_t id, version, docversion;
struct ebml_list_node * track;
char * doctype;
nestegg * ctx = NULL;
if (!(io.read && io.seek && io.tell))
return -1;
ctx = ne_alloc(sizeof(*ctx));
ctx->io = ne_alloc(sizeof(*ctx->io));
*ctx->io = io;
ctx->log = callback;
ctx->alloc_pool = ne_pool_init();
if (!ctx->log)
ctx->log = ne_null_log_callback;
r = ne_peek_element(ctx, &id, NULL);
if (r != 1) {
nestegg_destroy(ctx);
return -1;
}
if (id != ID_EBML) {
nestegg_destroy(ctx);
return -1;
}
ctx->log(ctx, NESTEGG_LOG_DEBUG, "ctx %p", ctx);
ne_ctx_push(ctx, ne_top_level_elements, ctx);
r = ne_parse(ctx, NULL);
if (r != 1) {
nestegg_destroy(ctx);
return -1;
}
if (ne_get_uint(ctx->ebml.ebml_read_version, &version) != 0)
version = 1;
if (version != 1) {
nestegg_destroy(ctx);
return -1;
}
if (ne_get_string(ctx->ebml.doctype, &doctype) != 0)
doctype = "matroska";
if (strcmp(doctype, "webm") != 0) {
nestegg_destroy(ctx);
return -1;
}
if (ne_get_uint(ctx->ebml.doctype_read_version, &docversion) != 0)
docversion = 1;
if (docversion < 1 || docversion > 2) {
nestegg_destroy(ctx);
return -1;
}
if (!ctx->segment.tracks.track_entry.head) {
nestegg_destroy(ctx);
return -1;
}
track = ctx->segment.tracks.track_entry.head;
ctx->track_count = 0;
while (track) {
ctx->track_count += 1;
track = track->next;
}
*context = ctx;
return 0;
}
void
nestegg_destroy(nestegg * ctx)
{
while (ctx->ancestor)
ne_ctx_pop(ctx);
ne_pool_destroy(ctx->alloc_pool);
free(ctx->io);
free(ctx);
}
int
nestegg_duration(nestegg * ctx, uint64_t * duration)
{
uint64_t tc_scale;
double unscaled_duration;
if (ne_get_float(ctx->segment.info.duration, &unscaled_duration) != 0)
return -1;
tc_scale = ne_get_timecode_scale(ctx);
*duration = (uint64_t) (unscaled_duration * tc_scale);
return 0;
}
int
nestegg_tstamp_scale(nestegg * ctx, uint64_t * scale)
{
*scale = ne_get_timecode_scale(ctx);
return 0;
}
int
nestegg_track_count(nestegg * ctx, unsigned int * tracks)
{
*tracks = ctx->track_count;
return 0;
}
int
nestegg_track_seek(nestegg * ctx, unsigned int track, uint64_t tstamp)
{
int r;
struct cue_point * cue_point;
struct cue_track_positions * pos;
struct saved_state state;
struct seek * found;
uint64_t seek_pos, tc_scale, t, id;
struct ebml_list_node * node = ctx->segment.cues.cue_point.head;
/* If there are no cues loaded, check for cues element in the seek head
and load it. */
if (!node) {
found = ne_find_seek_for_id(ctx->segment.seek_head.head, ID_CUES);
if (!found)
return -1;
if (ne_get_uint(found->position, &seek_pos) != 0)
return -1;
/* Save old parser state. */
r = ne_ctx_save(ctx, &state);
if (r != 0)
return -1;
/* Seek and set up parser state for segment-level element (Cues). */
r = ne_io_seek(ctx->io, ctx->segment_offset + seek_pos, NESTEGG_SEEK_SET);
if (r != 0)
return -1;
ctx->last_id = 0;
ctx->last_size = 0;
r = ne_read_element(ctx, &id, NULL);
if (r != 1)
return -1;
if (id != ID_CUES)
return -1;
ctx->ancestor = NULL;
ne_ctx_push(ctx, ne_top_level_elements, ctx);
ne_ctx_push(ctx, ne_segment_elements, &ctx->segment);
ne_ctx_push(ctx, ne_cues_elements, &ctx->segment.cues);
/* parser will run until end of cues element. */
ctx->log(ctx, NESTEGG_LOG_DEBUG, "seek: parsing cue elements");
r = ne_parse(ctx, ne_cues_elements);
while (ctx->ancestor)
ne_ctx_pop(ctx);
/* Reset parser state to original state and seek back to old position. */
if (ne_ctx_restore(ctx, &state) != 0)
return -1;
if (r < 0)
return -1;
}
tc_scale = ne_get_timecode_scale(ctx);
cue_point = ne_find_cue_point_for_tstamp(ctx->segment.cues.cue_point.head, tc_scale, tstamp);
if (!cue_point)
return -1;
node = cue_point->cue_track_positions.head;
seek_pos = 0;
while (node) {
assert(node->id == ID_CUE_TRACK_POSITIONS);
pos = node->data;
if (ne_get_uint(pos->track, &t) == 0 && t - 1 == track) {
if (ne_get_uint(pos->cluster_position, &seek_pos) != 0)
return -1;
break;
}
node = node->next;
}
/* Seek and set up parser state for segment-level element (Cluster). */
r = ne_io_seek(ctx->io, ctx->segment_offset + seek_pos, NESTEGG_SEEK_SET);
if (r != 0)
return -1;
ctx->last_id = 0;
ctx->last_size = 0;
while (ctx->ancestor)
ne_ctx_pop(ctx);
ne_ctx_push(ctx, ne_top_level_elements, ctx);
ne_ctx_push(ctx, ne_segment_elements, &ctx->segment);
ctx->log(ctx, NESTEGG_LOG_DEBUG, "seek: parsing cluster elements");
r = ne_parse(ctx, NULL);
if (r != 1)
return -1;
if (!ne_is_suspend_element(ctx->last_id))
return -1;
return 0;
}
int
nestegg_track_type(nestegg * ctx, unsigned int track)
{
struct track_entry * entry;
uint64_t type;
entry = ne_find_track_entry(ctx, track);
if (!entry)
return -1;
if (ne_get_uint(entry->type, &type) != 0)
return -1;
if (type & TRACK_TYPE_VIDEO)
return NESTEGG_TRACK_VIDEO;
if (type & TRACK_TYPE_AUDIO)
return NESTEGG_TRACK_AUDIO;
return -1;
}
int
nestegg_track_codec_id(nestegg * ctx, unsigned int track)
{
char * codec_id;
struct track_entry * entry;
entry = ne_find_track_entry(ctx, track);
if (!entry)
return -1;
if (ne_get_string(entry->codec_id, &codec_id) != 0)
return -1;
if (strcmp(codec_id, TRACK_ID_VP8) == 0)
return NESTEGG_CODEC_VP8;
if (strcmp(codec_id, TRACK_ID_VORBIS) == 0)
return NESTEGG_CODEC_VORBIS;
return -1;
}
int
nestegg_track_codec_data_count(nestegg * ctx, unsigned int track,
unsigned int * count)
{
struct track_entry * entry;
struct ebml_binary codec_private;
unsigned char * p;
*count = 0;
entry = ne_find_track_entry(ctx, track);
if (!entry)
return -1;
if (nestegg_track_codec_id(ctx, track) != NESTEGG_CODEC_VORBIS)
return -1;
if (ne_get_binary(entry->codec_private, &codec_private) != 0)
return -1;
if (codec_private.length < 1)
return -1;
p = codec_private.data;
*count = *p + 1;
if (*count > 3)
return -1;
return 0;
}
int
nestegg_track_codec_data(nestegg * ctx, unsigned int track, unsigned int item,
unsigned char ** data, size_t * length)
{
struct track_entry * entry;
struct ebml_binary codec_private;
uint64_t sizes[3], total;
unsigned char * p;
unsigned int count, i;
*data = NULL;
*length = 0;
entry = ne_find_track_entry(ctx, track);
if (!entry)
return -1;
if (nestegg_track_codec_id(ctx, track) != NESTEGG_CODEC_VORBIS)
return -1;
if (ne_get_binary(entry->codec_private, &codec_private) != 0)
return -1;
p = codec_private.data;
count = *p++ + 1;
if (count > 3)
return -1;
i = 0;
total = 0;
while (--count) {
sizes[i] = ne_xiph_lace_value(&p);
total += sizes[i];
i += 1;
}
sizes[i] = codec_private.length - total - (p - codec_private.data);
for (i = 0; i < item; ++i) {
if (sizes[i] > LIMIT_FRAME)
return -1;
p += sizes[i];
}
*data = p;
*length = sizes[item];
return 0;
}
int
nestegg_track_video_params(nestegg * ctx, unsigned int track,
nestegg_video_params * params)
{
struct track_entry * entry;
uint64_t value;
memset(params, 0, sizeof(*params));
entry = ne_find_track_entry(ctx, track);
if (!entry)
return -1;
if (nestegg_track_type(ctx, track) != NESTEGG_TRACK_VIDEO)
return -1;
if (ne_get_uint(entry->video.pixel_width, &value) != 0)
return -1;
params->width = value;
if (ne_get_uint(entry->video.pixel_height, &value) != 0)
return -1;
params->height = value;
value = 0;
ne_get_uint(entry->video.pixel_crop_bottom, &value);
params->crop_bottom = value;
value = 0;
ne_get_uint(entry->video.pixel_crop_top, &value);
params->crop_top = value;
value = 0;
ne_get_uint(entry->video.pixel_crop_left, &value);
params->crop_left = value;
value = 0;
ne_get_uint(entry->video.pixel_crop_right, &value);
params->crop_right = value;
value = params->width;
ne_get_uint(entry->video.display_width, &value);
params->display_width = value;
value = params->height;
ne_get_uint(entry->video.display_height, &value);
params->display_height = value;
return 0;
}
int
nestegg_track_audio_params(nestegg * ctx, unsigned int track,
nestegg_audio_params * params)
{
struct track_entry * entry;
uint64_t value;
memset(params, 0, sizeof(*params));
entry = ne_find_track_entry(ctx, track);
if (!entry)
return -1;
if (nestegg_track_type(ctx, track) != NESTEGG_TRACK_AUDIO)
return -1;
params->rate = 8000;
ne_get_float(entry->audio.sampling_frequency, &params->rate);
value = 1;
ne_get_uint(entry->audio.channels, &value);
params->channels = value;
value = 16;
ne_get_uint(entry->audio.bit_depth, &value);
params->depth = value;
return 0;
}
int
nestegg_read_packet(nestegg * ctx, nestegg_packet ** pkt)
{
int r;
uint64_t id, size;
*pkt = NULL;
for (;;) {
r = ne_peek_element(ctx, &id, &size);
if (r != 1)
return r;
/* any suspend fields must be handled here */
if (ne_is_suspend_element(id)) {
r = ne_read_element(ctx, &id, &size);
if (r != 1)
return r;
/* the only suspend fields are blocks and simple blocks, which we
handle directly. */
r = ne_read_block(ctx, id, size, pkt);
return r;
}
r = ne_parse(ctx, NULL);
if (r != 1)
return r;
}
return 1;
}
void
nestegg_free_packet(nestegg_packet * pkt)
{
struct frame * frame;
while (pkt->frame) {
frame = pkt->frame;
pkt->frame = frame->next;
free(frame->data);
free(frame);
}
free(pkt);
}
int
nestegg_packet_track(nestegg_packet * pkt, unsigned int * track)
{
*track = pkt->track;
return 0;
}
int
nestegg_packet_tstamp(nestegg_packet * pkt, uint64_t * tstamp)
{
*tstamp = pkt->timecode;
return 0;
}
int
nestegg_packet_count(nestegg_packet * pkt, unsigned int * count)
{
struct frame * f = pkt->frame;
*count = 0;
while (f) {
*count += 1;
f = f->next;
}
return 0;
}
int
nestegg_packet_data(nestegg_packet * pkt, unsigned int item,
unsigned char ** data, size_t * length)
{
struct frame * f = pkt->frame;
unsigned int count = 0;
*data = NULL;
*length = 0;
while (f) {
if (count == item) {
*data = f->data;
*length = f->length;
return 0;
}
count += 1;
f = f->next;
}
return -1;
}
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