shaka-packager/packager/media/formats/mp4/box_definitions.cc

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// Copyright (c) 2012 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "packager/media/formats/mp4/box_definitions.h"
#include <limits>
#include "packager/base/logging.h"
#include "packager/media/base/bit_reader.h"
#include "packager/media/formats/mp4/box_buffer.h"
#include "packager/media/formats/mp4/rcheck.h"
namespace {
const uint32_t kFourCCSize = 4;
// Key Id size as defined in CENC spec.
const uint32_t kCencKeyIdSize = 16;
// 9 uint32_t in big endian formatted array.
const uint8_t kUnityMatrix[] = {0, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 1, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0x40, 0, 0, 0};
// Default entries for HandlerReference box.
const char kVideoHandlerName[] = "VideoHandler";
const char kAudioHandlerName[] = "SoundHandler";
// Default values for VideoSampleEntry box.
const uint32_t kVideoResolution = 0x00480000; // 72 dpi.
const uint16_t kVideoFrameCount = 1;
const uint16_t kVideoDepth = 0x0018;
const uint32_t kCompressorNameSize = 32u;
const char kAvcCompressorName[] = "\012AVC Coding";
const char kHevcCompressorName[] = "\013HEVC Coding";
const char kVpcCompressorName[] = "\012VPC Coding";
// Utility functions to check if the 64bit integers can fit in 32bit integer.
bool IsFitIn32Bits(uint64_t a) {
return a <= std::numeric_limits<uint32_t>::max();
}
bool IsFitIn32Bits(int64_t a) {
return a <= std::numeric_limits<int32_t>::max() &&
a >= std::numeric_limits<int32_t>::min();
}
template <typename T1, typename T2>
bool IsFitIn32Bits(T1 a1, T2 a2) {
return IsFitIn32Bits(a1) && IsFitIn32Bits(a2);
}
template <typename T1, typename T2, typename T3>
bool IsFitIn32Bits(T1 a1, T2 a2, T3 a3) {
return IsFitIn32Bits(a1) && IsFitIn32Bits(a2) && IsFitIn32Bits(a3);
}
} // namespace
namespace edash_packager {
namespace media {
namespace mp4 {
FileType::FileType() : major_brand(FOURCC_NULL), minor_version(0) {}
FileType::~FileType() {}
FourCC FileType::BoxType() const { return FOURCC_FTYP; }
bool FileType::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->ReadWriteFourCC(&major_brand) &&
buffer->ReadWriteUInt32(&minor_version));
size_t num_brands;
if (buffer->Reading()) {
num_brands = (buffer->Size() - buffer->Pos()) / sizeof(FourCC);
compatible_brands.resize(num_brands);
} else {
num_brands = compatible_brands.size();
}
for (size_t i = 0; i < num_brands; ++i)
RCHECK(buffer->ReadWriteFourCC(&compatible_brands[i]));
return true;
}
uint32_t FileType::ComputeSizeInternal() {
return HeaderSize() + kFourCCSize + sizeof(minor_version) +
kFourCCSize * compatible_brands.size();
}
FourCC SegmentType::BoxType() const { return FOURCC_STYP; }
ProtectionSystemSpecificHeader::ProtectionSystemSpecificHeader() {}
ProtectionSystemSpecificHeader::~ProtectionSystemSpecificHeader() {}
FourCC ProtectionSystemSpecificHeader::BoxType() const { return FOURCC_PSSH; }
bool ProtectionSystemSpecificHeader::ReadWriteInternal(BoxBuffer* buffer) {
if (!buffer->Reading() && !raw_box.empty()) {
// Write the raw box directly.
buffer->writer()->AppendVector(raw_box);
return true;
}
uint32_t size = data.size();
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->ReadWriteVector(&system_id, 16) &&
buffer->ReadWriteUInt32(&size) &&
buffer->ReadWriteVector(&data, size));
if (buffer->Reading()) {
// Copy the entire box, including the header, for passing to EME as
// initData.
DCHECK(raw_box.empty());
BoxReader* reader = buffer->reader();
DCHECK(reader);
raw_box.assign(reader->data(), reader->data() + reader->size());
}
return true;
}
uint32_t ProtectionSystemSpecificHeader::ComputeSizeInternal() {
if (!raw_box.empty()) {
return raw_box.size();
} else {
return HeaderSize() + system_id.size() + sizeof(uint32_t) + data.size();
}
}
SampleAuxiliaryInformationOffset::SampleAuxiliaryInformationOffset() {}
SampleAuxiliaryInformationOffset::~SampleAuxiliaryInformationOffset() {}
FourCC SampleAuxiliaryInformationOffset::BoxType() const { return FOURCC_SAIO; }
bool SampleAuxiliaryInformationOffset::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer));
if (flags & 1)
RCHECK(buffer->IgnoreBytes(8)); // aux_info_type and parameter.
uint32_t count = offsets.size();
RCHECK(buffer->ReadWriteUInt32(&count));
offsets.resize(count);
size_t num_bytes = (version == 1) ? sizeof(uint64_t) : sizeof(uint32_t);
for (uint32_t i = 0; i < count; ++i)
RCHECK(buffer->ReadWriteUInt64NBytes(&offsets[i], num_bytes));
return true;
}
uint32_t SampleAuxiliaryInformationOffset::ComputeSizeInternal() {
// This box is optional. Skip it if it is empty.
if (offsets.size() == 0)
return 0;
size_t num_bytes = (version == 1) ? sizeof(uint64_t) : sizeof(uint32_t);
return HeaderSize() + sizeof(uint32_t) + num_bytes * offsets.size();
}
SampleAuxiliaryInformationSize::SampleAuxiliaryInformationSize()
: default_sample_info_size(0), sample_count(0) {}
SampleAuxiliaryInformationSize::~SampleAuxiliaryInformationSize() {}
FourCC SampleAuxiliaryInformationSize::BoxType() const { return FOURCC_SAIZ; }
bool SampleAuxiliaryInformationSize::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer));
if (flags & 1)
RCHECK(buffer->IgnoreBytes(8));
RCHECK(buffer->ReadWriteUInt8(&default_sample_info_size) &&
buffer->ReadWriteUInt32(&sample_count));
if (default_sample_info_size == 0)
RCHECK(buffer->ReadWriteVector(&sample_info_sizes, sample_count));
return true;
}
uint32_t SampleAuxiliaryInformationSize::ComputeSizeInternal() {
// This box is optional. Skip it if it is empty.
if (sample_count == 0)
return 0;
return HeaderSize() + sizeof(default_sample_info_size) +
sizeof(sample_count) +
(default_sample_info_size == 0 ? sample_info_sizes.size() : 0);
}
OriginalFormat::OriginalFormat() : format(FOURCC_NULL) {}
OriginalFormat::~OriginalFormat() {}
FourCC OriginalFormat::BoxType() const { return FOURCC_FRMA; }
bool OriginalFormat::ReadWriteInternal(BoxBuffer* buffer) {
return ReadWriteHeaderInternal(buffer) && buffer->ReadWriteFourCC(&format);
}
uint32_t OriginalFormat::ComputeSizeInternal() {
return HeaderSize() + kFourCCSize;
}
SchemeType::SchemeType() : type(FOURCC_NULL), version(0) {}
SchemeType::~SchemeType() {}
FourCC SchemeType::BoxType() const { return FOURCC_SCHM; }
bool SchemeType::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->ReadWriteFourCC(&type) &&
buffer->ReadWriteUInt32(&version));
return true;
}
uint32_t SchemeType::ComputeSizeInternal() {
return HeaderSize() + kFourCCSize + sizeof(version);
}
TrackEncryption::TrackEncryption()
: is_encrypted(false), default_iv_size(0), default_kid(16, 0) {}
TrackEncryption::~TrackEncryption() {}
FourCC TrackEncryption::BoxType() const { return FOURCC_TENC; }
bool TrackEncryption::ReadWriteInternal(BoxBuffer* buffer) {
if (!buffer->Reading()) {
if (default_kid.size() != kCencKeyIdSize) {
LOG(WARNING) << "CENC defines key id length of " << kCencKeyIdSize
<< " bytes; got " << default_kid.size()
<< ". Resized accordingly.";
default_kid.resize(kCencKeyIdSize);
}
}
uint8_t flag = is_encrypted ? 1 : 0;
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->IgnoreBytes(2) && // reserved.
buffer->ReadWriteUInt8(&flag) &&
buffer->ReadWriteUInt8(&default_iv_size) &&
buffer->ReadWriteVector(&default_kid, kCencKeyIdSize));
if (buffer->Reading()) {
is_encrypted = (flag != 0);
if (is_encrypted) {
RCHECK(default_iv_size == 8 || default_iv_size == 16);
} else {
RCHECK(default_iv_size == 0);
}
}
return true;
}
uint32_t TrackEncryption::ComputeSizeInternal() {
return HeaderSize() + sizeof(uint32_t) + kCencKeyIdSize;
}
SchemeInfo::SchemeInfo() {}
SchemeInfo::~SchemeInfo() {}
FourCC SchemeInfo::BoxType() const { return FOURCC_SCHI; }
bool SchemeInfo::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer) && buffer->PrepareChildren() &&
buffer->ReadWriteChild(&track_encryption));
return true;
}
uint32_t SchemeInfo::ComputeSizeInternal() {
return HeaderSize() + track_encryption.ComputeSize();
}
ProtectionSchemeInfo::ProtectionSchemeInfo() {}
ProtectionSchemeInfo::~ProtectionSchemeInfo() {}
FourCC ProtectionSchemeInfo::BoxType() const { return FOURCC_SINF; }
bool ProtectionSchemeInfo::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->PrepareChildren() &&
buffer->ReadWriteChild(&format) &&
buffer->ReadWriteChild(&type));
if (type.type == FOURCC_CENC)
RCHECK(buffer->ReadWriteChild(&info));
// Other protection schemes are silently ignored. Since the protection scheme
// type can't be determined until this box is opened, we return 'true' for
// non-CENC protection scheme types. It is the parent box's responsibility to
// ensure that this scheme type is a supported one.
return true;
}
uint32_t ProtectionSchemeInfo::ComputeSizeInternal() {
// Skip sinf box if it is not initialized.
if (format.format == FOURCC_NULL)
return 0;
return HeaderSize() + format.ComputeSize() + type.ComputeSize() +
info.ComputeSize();
}
MovieHeader::MovieHeader()
: creation_time(0),
modification_time(0),
timescale(0),
duration(0),
rate(1 << 16),
volume(1 << 8),
next_track_id(0) {}
MovieHeader::~MovieHeader() {}
FourCC MovieHeader::BoxType() const { return FOURCC_MVHD; }
bool MovieHeader::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer));
size_t num_bytes = (version == 1) ? sizeof(uint64_t) : sizeof(uint32_t);
RCHECK(buffer->ReadWriteUInt64NBytes(&creation_time, num_bytes) &&
buffer->ReadWriteUInt64NBytes(&modification_time, num_bytes) &&
buffer->ReadWriteUInt32(&timescale) &&
buffer->ReadWriteUInt64NBytes(&duration, num_bytes));
std::vector<uint8_t> matrix(kUnityMatrix,
kUnityMatrix + arraysize(kUnityMatrix));
RCHECK(buffer->ReadWriteInt32(&rate) &&
buffer->ReadWriteInt16(&volume) &&
buffer->IgnoreBytes(10) && // reserved
buffer->ReadWriteVector(&matrix, matrix.size()) &&
buffer->IgnoreBytes(24) && // predefined zero
buffer->ReadWriteUInt32(&next_track_id));
return true;
}
uint32_t MovieHeader::ComputeSizeInternal() {
version = IsFitIn32Bits(creation_time, modification_time, duration) ? 0 : 1;
return HeaderSize() + sizeof(uint32_t) * (1 + version) * 3 +
sizeof(timescale) + sizeof(rate) + sizeof(volume) +
sizeof(next_track_id) + sizeof(kUnityMatrix) + 10 +
24; // 10 bytes reserved, 24 bytes predefined.
}
TrackHeader::TrackHeader()
: creation_time(0),
modification_time(0),
track_id(0),
duration(0),
layer(0),
alternate_group(0),
volume(-1),
width(0),
height(0) {
flags = kTrackEnabled | kTrackInMovie;
}
TrackHeader::~TrackHeader() {}
FourCC TrackHeader::BoxType() const { return FOURCC_TKHD; }
bool TrackHeader::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer));
size_t num_bytes = (version == 1) ? sizeof(uint64_t) : sizeof(uint32_t);
RCHECK(buffer->ReadWriteUInt64NBytes(&creation_time, num_bytes) &&
buffer->ReadWriteUInt64NBytes(&modification_time, num_bytes) &&
buffer->ReadWriteUInt32(&track_id) &&
buffer->IgnoreBytes(4) && // reserved
buffer->ReadWriteUInt64NBytes(&duration, num_bytes));
if (!buffer->Reading()) {
// Set default value for volume, if track is audio, 0x100 else 0.
if (volume == -1)
volume = (width != 0 && height != 0) ? 0 : 0x100;
}
std::vector<uint8_t> matrix(kUnityMatrix,
kUnityMatrix + arraysize(kUnityMatrix));
RCHECK(buffer->IgnoreBytes(8) && // reserved
buffer->ReadWriteInt16(&layer) &&
buffer->ReadWriteInt16(&alternate_group) &&
buffer->ReadWriteInt16(&volume) &&
buffer->IgnoreBytes(2) && // reserved
buffer->ReadWriteVector(&matrix, matrix.size()) &&
buffer->ReadWriteUInt32(&width) &&
buffer->ReadWriteUInt32(&height));
return true;
}
uint32_t TrackHeader::ComputeSizeInternal() {
version = IsFitIn32Bits(creation_time, modification_time, duration) ? 0 : 1;
return HeaderSize() + sizeof(track_id) +
sizeof(uint32_t) * (1 + version) * 3 + sizeof(layer) +
sizeof(alternate_group) + sizeof(volume) + sizeof(width) +
sizeof(height) + sizeof(kUnityMatrix) + 14; // 14 bytes reserved.
}
SampleDescription::SampleDescription() : type(kInvalid) {}
SampleDescription::~SampleDescription() {}
FourCC SampleDescription::BoxType() const { return FOURCC_STSD; }
bool SampleDescription::ReadWriteInternal(BoxBuffer* buffer) {
uint32_t count = 0;
if (type == kVideo)
count = video_entries.size();
else
count = audio_entries.size();
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->ReadWriteUInt32(&count));
if (buffer->Reading()) {
BoxReader* reader = buffer->reader();
DCHECK(reader);
video_entries.clear();
audio_entries.clear();
// Note: this value is preset before scanning begins. See comments in the
// Parse(Media*) function.
if (type == kVideo) {
RCHECK(reader->ReadAllChildren(&video_entries));
RCHECK(video_entries.size() == count);
} else if (type == kAudio) {
RCHECK(reader->ReadAllChildren(&audio_entries));
RCHECK(audio_entries.size() == count);
}
} else {
DCHECK_LT(0u, count);
if (type == kVideo) {
for (uint32_t i = 0; i < count; ++i)
RCHECK(buffer->ReadWriteChild(&video_entries[i]));
} else if (type == kAudio) {
for (uint32_t i = 0; i < count; ++i)
RCHECK(buffer->ReadWriteChild(&audio_entries[i]));
} else {
NOTIMPLEMENTED();
}
}
return true;
}
uint32_t SampleDescription::ComputeSizeInternal() {
uint32_t box_size = HeaderSize() + sizeof(uint32_t);
if (type == kVideo) {
for (uint32_t i = 0; i < video_entries.size(); ++i)
box_size += video_entries[i].ComputeSize();
} else if (type == kAudio) {
for (uint32_t i = 0; i < audio_entries.size(); ++i)
box_size += audio_entries[i].ComputeSize();
}
return box_size;
}
DecodingTimeToSample::DecodingTimeToSample() {}
DecodingTimeToSample::~DecodingTimeToSample() {}
FourCC DecodingTimeToSample::BoxType() const { return FOURCC_STTS; }
bool DecodingTimeToSample::ReadWriteInternal(BoxBuffer* buffer) {
uint32_t count = decoding_time.size();
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->ReadWriteUInt32(&count));
decoding_time.resize(count);
for (uint32_t i = 0; i < count; ++i) {
RCHECK(buffer->ReadWriteUInt32(&decoding_time[i].sample_count) &&
buffer->ReadWriteUInt32(&decoding_time[i].sample_delta));
}
return true;
}
uint32_t DecodingTimeToSample::ComputeSizeInternal() {
return HeaderSize() + sizeof(uint32_t) +
sizeof(DecodingTime) * decoding_time.size();
}
CompositionTimeToSample::CompositionTimeToSample() {}
CompositionTimeToSample::~CompositionTimeToSample() {}
FourCC CompositionTimeToSample::BoxType() const { return FOURCC_CTTS; }
bool CompositionTimeToSample::ReadWriteInternal(BoxBuffer* buffer) {
uint32_t count = composition_offset.size();
if (!buffer->Reading()) {
// Determine whether version 0 or version 1 should be used.
// Use version 0 if possible, use version 1 if there is a negative
// sample_offset value.
version = 0;
for (uint32_t i = 0; i < count; ++i) {
if (composition_offset[i].sample_offset < 0) {
version = 1;
break;
}
}
}
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->ReadWriteUInt32(&count));
composition_offset.resize(count);
for (uint32_t i = 0; i < count; ++i) {
RCHECK(buffer->ReadWriteUInt32(&composition_offset[i].sample_count));
if (version == 0) {
uint32_t sample_offset = composition_offset[i].sample_offset;
RCHECK(buffer->ReadWriteUInt32(&sample_offset));
composition_offset[i].sample_offset = sample_offset;
} else {
int32_t sample_offset = composition_offset[i].sample_offset;
RCHECK(buffer->ReadWriteInt32(&sample_offset));
composition_offset[i].sample_offset = sample_offset;
}
}
return true;
}
uint32_t CompositionTimeToSample::ComputeSizeInternal() {
// This box is optional. Skip it if it is empty.
if (composition_offset.empty())
return 0;
// Structure CompositionOffset contains |sample_offset| (uint32_t) and
// |sample_offset| (int64_t). The actual size of |sample_offset| is
// 4 bytes (uint32_t for version 0 and int32_t for version 1).
const uint32_t kCompositionOffsetSize = sizeof(uint32_t) * 2;
return HeaderSize() + sizeof(uint32_t) +
kCompositionOffsetSize * composition_offset.size();
}
SampleToChunk::SampleToChunk() {}
SampleToChunk::~SampleToChunk() {}
FourCC SampleToChunk::BoxType() const { return FOURCC_STSC; }
bool SampleToChunk::ReadWriteInternal(BoxBuffer* buffer) {
uint32_t count = chunk_info.size();
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->ReadWriteUInt32(&count));
chunk_info.resize(count);
for (uint32_t i = 0; i < count; ++i) {
RCHECK(buffer->ReadWriteUInt32(&chunk_info[i].first_chunk) &&
buffer->ReadWriteUInt32(&chunk_info[i].samples_per_chunk) &&
buffer->ReadWriteUInt32(&chunk_info[i].sample_description_index));
// first_chunk values are always increasing.
RCHECK(i == 0 ? chunk_info[i].first_chunk == 1
: chunk_info[i].first_chunk > chunk_info[i - 1].first_chunk);
}
return true;
}
uint32_t SampleToChunk::ComputeSizeInternal() {
return HeaderSize() + sizeof(uint32_t) +
sizeof(ChunkInfo) * chunk_info.size();
}
SampleSize::SampleSize() : sample_size(0), sample_count(0) {}
SampleSize::~SampleSize() {}
FourCC SampleSize::BoxType() const { return FOURCC_STSZ; }
bool SampleSize::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->ReadWriteUInt32(&sample_size) &&
buffer->ReadWriteUInt32(&sample_count));
if (sample_size == 0) {
if (buffer->Reading())
sizes.resize(sample_count);
else
DCHECK(sample_count == sizes.size());
for (uint32_t i = 0; i < sample_count; ++i)
RCHECK(buffer->ReadWriteUInt32(&sizes[i]));
}
return true;
}
uint32_t SampleSize::ComputeSizeInternal() {
return HeaderSize() + sizeof(sample_size) + sizeof(sample_count) +
(sample_size == 0 ? sizeof(uint32_t) * sizes.size() : 0);
}
CompactSampleSize::CompactSampleSize() : field_size(0) {}
CompactSampleSize::~CompactSampleSize() {}
FourCC CompactSampleSize::BoxType() const { return FOURCC_STZ2; }
bool CompactSampleSize::ReadWriteInternal(BoxBuffer* buffer) {
uint32_t sample_count = sizes.size();
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->IgnoreBytes(3) &&
buffer->ReadWriteUInt8(&field_size) &&
buffer->ReadWriteUInt32(&sample_count));
// Reserve one more entry if field size is 4 bits.
sizes.resize(sample_count + (field_size == 4 ? 1 : 0), 0);
switch (field_size) {
case 4:
for (uint32_t i = 0; i < sample_count; i += 2) {
if (buffer->Reading()) {
uint8_t size = 0;
RCHECK(buffer->ReadWriteUInt8(&size));
sizes[i] = size >> 4;
sizes[i + 1] = size & 0x0F;
} else {
DCHECK_LT(sizes[i], 16u);
DCHECK_LT(sizes[i + 1], 16u);
uint8_t size = (sizes[i] << 4) | sizes[i + 1];
RCHECK(buffer->ReadWriteUInt8(&size));
}
}
break;
case 8:
for (uint32_t i = 0; i < sample_count; ++i) {
uint8_t size = sizes[i];
RCHECK(buffer->ReadWriteUInt8(&size));
sizes[i] = size;
}
break;
case 16:
for (uint32_t i = 0; i < sample_count; ++i) {
uint16_t size = sizes[i];
RCHECK(buffer->ReadWriteUInt16(&size));
sizes[i] = size;
}
break;
default:
RCHECK(false);
}
sizes.resize(sample_count);
return true;
}
uint32_t CompactSampleSize::ComputeSizeInternal() {
return HeaderSize() + sizeof(uint32_t) + sizeof(uint32_t) +
(field_size * sizes.size() + 7) / 8;
}
ChunkOffset::ChunkOffset() {}
ChunkOffset::~ChunkOffset() {}
FourCC ChunkOffset::BoxType() const { return FOURCC_STCO; }
bool ChunkOffset::ReadWriteInternal(BoxBuffer* buffer) {
uint32_t count = offsets.size();
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->ReadWriteUInt32(&count));
offsets.resize(count);
for (uint32_t i = 0; i < count; ++i)
RCHECK(buffer->ReadWriteUInt64NBytes(&offsets[i], sizeof(uint32_t)));
return true;
}
uint32_t ChunkOffset::ComputeSizeInternal() {
return HeaderSize() + sizeof(uint32_t) + sizeof(uint32_t) * offsets.size();
}
ChunkLargeOffset::ChunkLargeOffset() {}
ChunkLargeOffset::~ChunkLargeOffset() {}
FourCC ChunkLargeOffset::BoxType() const { return FOURCC_CO64; }
bool ChunkLargeOffset::ReadWriteInternal(BoxBuffer* buffer) {
uint32_t count = offsets.size();
if (!buffer->Reading()) {
// Switch to ChunkOffset box if it is able to fit in 32 bits offset.
if (count == 0 || IsFitIn32Bits(offsets[count - 1])) {
ChunkOffset stco;
stco.offsets.swap(offsets);
DCHECK(buffer->writer());
stco.Write(buffer->writer());
stco.offsets.swap(offsets);
return true;
}
}
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->ReadWriteUInt32(&count));
offsets.resize(count);
for (uint32_t i = 0; i < count; ++i)
RCHECK(buffer->ReadWriteUInt64(&offsets[i]));
return true;
}
uint32_t ChunkLargeOffset::ComputeSizeInternal() {
uint32_t count = offsets.size();
int use_large_offset =
(count > 0 && !IsFitIn32Bits(offsets[count - 1])) ? 1 : 0;
return HeaderSize() + sizeof(count) +
sizeof(uint32_t) * (1 + use_large_offset) * offsets.size();
}
SyncSample::SyncSample() {}
SyncSample::~SyncSample() {}
FourCC SyncSample::BoxType() const { return FOURCC_STSS; }
bool SyncSample::ReadWriteInternal(BoxBuffer* buffer) {
uint32_t count = sample_number.size();
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->ReadWriteUInt32(&count));
sample_number.resize(count);
for (uint32_t i = 0; i < count; ++i)
RCHECK(buffer->ReadWriteUInt32(&sample_number[i]));
return true;
}
uint32_t SyncSample::ComputeSizeInternal() {
// Sync sample box is optional. Skip it if it is empty.
if (sample_number.empty())
return 0;
return HeaderSize() + sizeof(uint32_t) +
sizeof(uint32_t) * sample_number.size();
}
SampleTable::SampleTable() {}
SampleTable::~SampleTable() {}
FourCC SampleTable::BoxType() const { return FOURCC_STBL; }
bool SampleTable::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->PrepareChildren() &&
buffer->ReadWriteChild(&description) &&
buffer->ReadWriteChild(&decoding_time_to_sample) &&
buffer->TryReadWriteChild(&composition_time_to_sample) &&
buffer->ReadWriteChild(&sample_to_chunk));
if (buffer->Reading()) {
BoxReader* reader = buffer->reader();
DCHECK(reader);
// Either SampleSize or CompactSampleSize must present.
if (reader->ChildExist(&sample_size)) {
RCHECK(reader->ReadChild(&sample_size));
} else {
CompactSampleSize compact_sample_size;
RCHECK(reader->ReadChild(&compact_sample_size));
sample_size.sample_size = 0;
sample_size.sample_count = compact_sample_size.sizes.size();
sample_size.sizes.swap(compact_sample_size.sizes);
}
// Either ChunkOffset or ChunkLargeOffset must present.
if (reader->ChildExist(&chunk_large_offset)) {
RCHECK(reader->ReadChild(&chunk_large_offset));
} else {
ChunkOffset chunk_offset;
RCHECK(reader->ReadChild(&chunk_offset));
chunk_large_offset.offsets.swap(chunk_offset.offsets);
}
} else {
RCHECK(buffer->ReadWriteChild(&sample_size) &&
buffer->ReadWriteChild(&chunk_large_offset));
}
RCHECK(buffer->TryReadWriteChild(&sync_sample));
return true;
}
uint32_t SampleTable::ComputeSizeInternal() {
return HeaderSize() + description.ComputeSize() +
decoding_time_to_sample.ComputeSize() +
composition_time_to_sample.ComputeSize() +
sample_to_chunk.ComputeSize() + sample_size.ComputeSize() +
chunk_large_offset.ComputeSize() + sync_sample.ComputeSize();
}
EditList::EditList() {}
EditList::~EditList() {}
FourCC EditList::BoxType() const { return FOURCC_ELST; }
bool EditList::ReadWriteInternal(BoxBuffer* buffer) {
uint32_t count = edits.size();
RCHECK(ReadWriteHeaderInternal(buffer) && buffer->ReadWriteUInt32(&count));
edits.resize(count);
size_t num_bytes = (version == 1) ? sizeof(uint64_t) : sizeof(uint32_t);
for (uint32_t i = 0; i < count; ++i) {
RCHECK(
buffer->ReadWriteUInt64NBytes(&edits[i].segment_duration, num_bytes) &&
buffer->ReadWriteInt64NBytes(&edits[i].media_time, num_bytes) &&
buffer->ReadWriteInt16(&edits[i].media_rate_integer) &&
buffer->ReadWriteInt16(&edits[i].media_rate_fraction));
}
return true;
}
uint32_t EditList::ComputeSizeInternal() {
// EditList box is optional. Skip it if it is empty.
if (edits.empty())
return 0;
version = 0;
for (uint32_t i = 0; i < edits.size(); ++i) {
if (!IsFitIn32Bits(edits[i].segment_duration, edits[i].media_time)) {
version = 1;
break;
}
}
return HeaderSize() + sizeof(uint32_t) +
(sizeof(uint32_t) * (1 + version) * 2 + sizeof(int16_t) * 2) *
edits.size();
}
Edit::Edit() {}
Edit::~Edit() {}
FourCC Edit::BoxType() const { return FOURCC_EDTS; }
bool Edit::ReadWriteInternal(BoxBuffer* buffer) {
return ReadWriteHeaderInternal(buffer) &&
buffer->PrepareChildren() &&
buffer->ReadWriteChild(&list);
}
uint32_t Edit::ComputeSizeInternal() {
// Edit box is optional. Skip it if it is empty.
if (list.edits.empty())
return 0;
return HeaderSize() + list.ComputeSize();
}
HandlerReference::HandlerReference() : type(kInvalid) {}
HandlerReference::~HandlerReference() {}
FourCC HandlerReference::BoxType() const { return FOURCC_HDLR; }
bool HandlerReference::ReadWriteInternal(BoxBuffer* buffer) {
FourCC hdlr_type = FOURCC_NULL;
std::vector<uint8_t> handler_name;
if (!buffer->Reading()) {
if (type == kVideo) {
hdlr_type = FOURCC_VIDE;
handler_name.assign(kVideoHandlerName,
kVideoHandlerName + arraysize(kVideoHandlerName));
} else if (type == kAudio) {
hdlr_type = FOURCC_SOUN;
handler_name.assign(kAudioHandlerName,
kAudioHandlerName + arraysize(kAudioHandlerName));
} else {
NOTIMPLEMENTED();
return false;
}
}
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->IgnoreBytes(4) && // predefined.
buffer->ReadWriteFourCC(&hdlr_type));
if (buffer->Reading()) {
// Note: for reading, remaining fields in box ignored.
if (hdlr_type == FOURCC_VIDE) {
type = kVideo;
} else if (hdlr_type == FOURCC_SOUN) {
type = kAudio;
} else {
type = kInvalid;
}
} else {
RCHECK(buffer->IgnoreBytes(12) && // reserved.
buffer->ReadWriteVector(&handler_name, handler_name.size()));
}
return true;
}
uint32_t HandlerReference::ComputeSizeInternal() {
return HeaderSize() + kFourCCSize + 16 + // 16 bytes Reserved
(type == kVideo ? sizeof(kVideoHandlerName)
: sizeof(kAudioHandlerName));
}
CodecConfigurationRecord::CodecConfigurationRecord() : box_type(FOURCC_NULL) {}
CodecConfigurationRecord::~CodecConfigurationRecord() {}
FourCC CodecConfigurationRecord::BoxType() const {
// CodecConfigurationRecord should be parsed according to format recovered in
// VideoSampleEntry. |box_type| is determined dynamically there.
return box_type;
}
bool CodecConfigurationRecord::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer));
if (buffer->Reading()) {
RCHECK(buffer->ReadWriteVector(&data, buffer->Size() - buffer->Pos()));
} else {
RCHECK(buffer->ReadWriteVector(&data, data.size()));
}
return true;
}
uint32_t CodecConfigurationRecord::ComputeSizeInternal() {
if (data.empty())
return 0;
return HeaderSize() + data.size();
}
PixelAspectRatio::PixelAspectRatio() : h_spacing(0), v_spacing(0) {}
PixelAspectRatio::~PixelAspectRatio() {}
FourCC PixelAspectRatio::BoxType() const { return FOURCC_PASP; }
bool PixelAspectRatio::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->ReadWriteUInt32(&h_spacing) &&
buffer->ReadWriteUInt32(&v_spacing));
return true;
}
uint32_t PixelAspectRatio::ComputeSizeInternal() {
// This box is optional. Skip it if it is not initialized.
if (h_spacing == 0 && v_spacing == 0)
return 0;
// Both values must be positive.
DCHECK(h_spacing != 0 && v_spacing != 0);
return HeaderSize() + sizeof(h_spacing) + sizeof(v_spacing);
}
VideoSampleEntry::VideoSampleEntry()
: format(FOURCC_NULL), data_reference_index(1), width(0), height(0) {}
VideoSampleEntry::~VideoSampleEntry() {}
FourCC VideoSampleEntry::BoxType() const {
if (format == FOURCC_NULL) {
LOG(ERROR) << "VideoSampleEntry should be parsed according to the "
<< "handler type recovered in its Media ancestor.";
}
return format;
}
bool VideoSampleEntry::ReadWriteInternal(BoxBuffer* buffer) {
std::vector<uint8_t> compressor_name;
if (buffer->Reading()) {
DCHECK(buffer->reader());
format = buffer->reader()->type();
} else {
RCHECK(ReadWriteHeaderInternal(buffer));
const FourCC actual_format = GetActualFormat();
switch (actual_format) {
case FOURCC_AVC1:
compressor_name.assign(
kAvcCompressorName,
kAvcCompressorName + arraysize(kAvcCompressorName));
break;
case FOURCC_HEV1:
case FOURCC_HVC1:
compressor_name.assign(
kHevcCompressorName,
kHevcCompressorName + arraysize(kHevcCompressorName));
break;
case FOURCC_VP08:
case FOURCC_VP09:
case FOURCC_VP10:
compressor_name.assign(
kVpcCompressorName,
kVpcCompressorName + arraysize(kVpcCompressorName));
break;
default:
LOG(ERROR) << FourCCToString(actual_format) << " is not supported.";
return false;
}
compressor_name.resize(kCompressorNameSize);
}
uint32_t video_resolution = kVideoResolution;
uint16_t video_frame_count = kVideoFrameCount;
uint16_t video_depth = kVideoDepth;
int16_t predefined = -1;
RCHECK(buffer->IgnoreBytes(6) && // reserved.
buffer->ReadWriteUInt16(&data_reference_index) &&
buffer->IgnoreBytes(16) && // predefined 0.
buffer->ReadWriteUInt16(&width) &&
buffer->ReadWriteUInt16(&height) &&
buffer->ReadWriteUInt32(&video_resolution) &&
buffer->ReadWriteUInt32(&video_resolution) &&
buffer->IgnoreBytes(4) && // reserved.
buffer->ReadWriteUInt16(&video_frame_count) &&
buffer->ReadWriteVector(&compressor_name, kCompressorNameSize) &&
buffer->ReadWriteUInt16(&video_depth) &&
buffer->ReadWriteInt16(&predefined));
RCHECK(buffer->PrepareChildren());
if (format == FOURCC_ENCV) {
if (buffer->Reading()) {
// Continue scanning until a recognized protection scheme is found,
// or until we run out of protection schemes.
while (sinf.type.type != FOURCC_CENC) {
if (!buffer->ReadWriteChild(&sinf))
return false;
}
} else {
RCHECK(buffer->ReadWriteChild(&sinf));
}
}
const FourCC actual_format = GetActualFormat();
switch (actual_format) {
case FOURCC_AVC1:
codec_config_record.box_type = FOURCC_AVCC;
break;
case FOURCC_HEV1:
case FOURCC_HVC1:
codec_config_record.box_type = FOURCC_HVCC;
break;
case FOURCC_VP08:
case FOURCC_VP09:
case FOURCC_VP10:
codec_config_record.box_type = FOURCC_VPCC;
break;
default:
LOG(ERROR) << FourCCToString(actual_format) << " is not supported.";
return false;
}
RCHECK(buffer->ReadWriteChild(&codec_config_record));
RCHECK(buffer->TryReadWriteChild(&pixel_aspect));
return true;
}
uint32_t VideoSampleEntry::ComputeSizeInternal() {
return HeaderSize() + sizeof(data_reference_index) + sizeof(width) +
sizeof(height) + sizeof(kVideoResolution) * 2 +
sizeof(kVideoFrameCount) + sizeof(kVideoDepth) +
pixel_aspect.ComputeSize() + sinf.ComputeSize() +
codec_config_record.ComputeSize() + kCompressorNameSize + 6 + 4 + 16 +
2; // 6 + 4 bytes reserved, 16 + 2 bytes predefined.
}
ElementaryStreamDescriptor::ElementaryStreamDescriptor() {}
ElementaryStreamDescriptor::~ElementaryStreamDescriptor() {}
FourCC ElementaryStreamDescriptor::BoxType() const { return FOURCC_ESDS; }
bool ElementaryStreamDescriptor::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer));
if (buffer->Reading()) {
std::vector<uint8_t> data;
RCHECK(buffer->ReadWriteVector(&data, buffer->Size() - buffer->Pos()));
RCHECK(es_descriptor.Parse(data));
if (es_descriptor.IsAAC()) {
RCHECK(aac_audio_specific_config.Parse(
es_descriptor.decoder_specific_info()));
}
} else {
DCHECK(buffer->writer());
es_descriptor.Write(buffer->writer());
}
return true;
}
uint32_t ElementaryStreamDescriptor::ComputeSizeInternal() {
// This box is optional. Skip it if not initialized.
if (es_descriptor.object_type() == kForbidden)
return 0;
return HeaderSize() + es_descriptor.ComputeSize();
}
DTSSpecific::DTSSpecific() {}
DTSSpecific::~DTSSpecific() {}
FourCC DTSSpecific::BoxType() const { return FOURCC_DDTS; }
bool DTSSpecific::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer));
if (buffer->Reading()) {
RCHECK(
buffer->ReadWriteVector(&data, buffer->Size() - buffer->Pos()));
} else {
RCHECK(buffer->ReadWriteVector(&data, data.size()));
}
return true;
}
uint32_t DTSSpecific::ComputeSizeInternal() {
// This box is optional. Skip it if not initialized.
if (data.size() == 0)
return 0;
return HeaderSize() + data.size();
}
AudioSampleEntry::AudioSampleEntry()
: format(FOURCC_NULL),
data_reference_index(1),
channelcount(2),
samplesize(16),
samplerate(0) {}
AudioSampleEntry::~AudioSampleEntry() {}
FourCC AudioSampleEntry::BoxType() const {
if (format == FOURCC_NULL) {
LOG(ERROR) << "AudioSampleEntry should be parsed according to the "
<< "handler type recovered in its Media ancestor.";
}
return format;
}
bool AudioSampleEntry::ReadWriteInternal(BoxBuffer* buffer) {
if (buffer->Reading()) {
DCHECK(buffer->reader());
format = buffer->reader()->type();
} else {
RCHECK(ReadWriteHeaderInternal(buffer));
}
// Convert from integer to 16.16 fixed point for writing.
samplerate <<= 16;
RCHECK(buffer->IgnoreBytes(6) && // reserved.
buffer->ReadWriteUInt16(&data_reference_index) &&
buffer->IgnoreBytes(8) && // reserved.
buffer->ReadWriteUInt16(&channelcount) &&
buffer->ReadWriteUInt16(&samplesize) &&
buffer->IgnoreBytes(4) && // predefined.
buffer->ReadWriteUInt32(&samplerate));
// Convert from 16.16 fixed point to integer.
samplerate >>= 16;
RCHECK(buffer->PrepareChildren());
if (format == FOURCC_ENCA) {
if (buffer->Reading()) {
// Continue scanning until a recognized protection scheme is found,
// or until we run out of protection schemes.
while (sinf.type.type != FOURCC_CENC) {
if (!buffer->ReadWriteChild(&sinf))
return false;
}
} else {
RCHECK(buffer->ReadWriteChild(&sinf));
}
}
RCHECK(buffer->TryReadWriteChild(&esds));
RCHECK(buffer->TryReadWriteChild(&ddts));
return true;
}
uint32_t AudioSampleEntry::ComputeSizeInternal() {
return HeaderSize() + sizeof(data_reference_index) + sizeof(channelcount) +
sizeof(samplesize) + sizeof(samplerate) + sinf.ComputeSize() +
esds.ComputeSize() + ddts.ComputeSize() + 6 +
8 + // 6 + 8 bytes reserved.
4; // 4 bytes predefined.
}
MediaHeader::MediaHeader()
: creation_time(0), modification_time(0), timescale(0), duration(0) {
language[0] = 0;
}
MediaHeader::~MediaHeader() {}
FourCC MediaHeader::BoxType() const { return FOURCC_MDHD; }
bool MediaHeader::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer));
uint8_t num_bytes = (version == 1) ? sizeof(uint64_t) : sizeof(uint32_t);
RCHECK(buffer->ReadWriteUInt64NBytes(&creation_time, num_bytes) &&
buffer->ReadWriteUInt64NBytes(&modification_time, num_bytes) &&
buffer->ReadWriteUInt32(&timescale) &&
buffer->ReadWriteUInt64NBytes(&duration, num_bytes));
if (buffer->Reading()) {
// Read language codes into temp first then use BitReader to read the
// values. ISO-639-2/T language code: unsigned int(5)[3] language (2 bytes).
std::vector<uint8_t> temp;
RCHECK(buffer->ReadWriteVector(&temp, 2));
BitReader bit_reader(&temp[0], 2);
bit_reader.SkipBits(1);
for (int i = 0; i < 3; ++i) {
CHECK(bit_reader.ReadBits(5, &language[i]));
language[i] += 0x60;
}
language[3] = '\0';
} else {
// Set up default language if it is not set.
const char kUndefinedLanguage[] = "und";
if (language[0] == 0)
strcpy(language, kUndefinedLanguage);
// Lang format: bit(1) pad, unsigned int(5)[3] language.
uint16_t lang = 0;
for (int i = 0; i < 3; ++i)
lang |= (language[i] - 0x60) << ((2 - i) * 5);
RCHECK(buffer->ReadWriteUInt16(&lang));
}
RCHECK(buffer->IgnoreBytes(2)); // predefined.
return true;
}
uint32_t MediaHeader::ComputeSizeInternal() {
version = IsFitIn32Bits(creation_time, modification_time, duration) ? 0 : 1;
return HeaderSize() + sizeof(timescale) +
sizeof(uint32_t) * (1 + version) * 3 + 2 + // 2 bytes language.
2; // 2 bytes predefined.
}
VideoMediaHeader::VideoMediaHeader()
: graphicsmode(0), opcolor_red(0), opcolor_green(0), opcolor_blue(0) {
const uint32_t kVideoMediaHeaderFlags = 1;
flags = kVideoMediaHeaderFlags;
}
VideoMediaHeader::~VideoMediaHeader() {}
FourCC VideoMediaHeader::BoxType() const { return FOURCC_VMHD; }
bool VideoMediaHeader::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->ReadWriteUInt16(&graphicsmode) &&
buffer->ReadWriteUInt16(&opcolor_red) &&
buffer->ReadWriteUInt16(&opcolor_green) &&
buffer->ReadWriteUInt16(&opcolor_blue));
return true;
}
uint32_t VideoMediaHeader::ComputeSizeInternal() {
return HeaderSize() + sizeof(graphicsmode) + sizeof(opcolor_red) +
sizeof(opcolor_green) + sizeof(opcolor_blue);
}
SoundMediaHeader::SoundMediaHeader() : balance(0) {}
SoundMediaHeader::~SoundMediaHeader() {}
FourCC SoundMediaHeader::BoxType() const { return FOURCC_SMHD; }
bool SoundMediaHeader::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->ReadWriteUInt16(&balance) &&
buffer->IgnoreBytes(2)); // reserved.
return true;
}
uint32_t SoundMediaHeader::ComputeSizeInternal() {
return HeaderSize() + sizeof(balance) + sizeof(uint16_t);
}
DataEntryUrl::DataEntryUrl() {
const uint32_t kDataEntryUrlFlags = 1;
flags = kDataEntryUrlFlags;
}
DataEntryUrl::~DataEntryUrl() {}
FourCC DataEntryUrl::BoxType() const { return FOURCC_URL; }
bool DataEntryUrl::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer));
if (buffer->Reading()) {
RCHECK(buffer->ReadWriteVector(&location, buffer->Size() - buffer->Pos()));
} else {
RCHECK(buffer->ReadWriteVector(&location, location.size()));
}
return true;
}
uint32_t DataEntryUrl::ComputeSizeInternal() {
return HeaderSize() + location.size();
}
DataReference::DataReference() {
// Default 1 entry.
data_entry.resize(1);
}
DataReference::~DataReference() {}
FourCC DataReference::BoxType() const { return FOURCC_DREF; }
bool DataReference::ReadWriteInternal(BoxBuffer* buffer) {
uint32_t entry_count = data_entry.size();
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->ReadWriteUInt32(&entry_count));
data_entry.resize(entry_count);
RCHECK(buffer->PrepareChildren());
for (uint32_t i = 0; i < entry_count; ++i)
RCHECK(buffer->ReadWriteChild(&data_entry[i]));
return true;
}
uint32_t DataReference::ComputeSizeInternal() {
uint32_t count = data_entry.size();
uint32_t box_size = HeaderSize() + sizeof(count);
for (uint32_t i = 0; i < count; ++i)
box_size += data_entry[i].ComputeSize();
return box_size;
}
DataInformation::DataInformation() {}
DataInformation::~DataInformation() {}
FourCC DataInformation::BoxType() const { return FOURCC_DINF; }
bool DataInformation::ReadWriteInternal(BoxBuffer* buffer) {
return ReadWriteHeaderInternal(buffer) &&
buffer->PrepareChildren() &&
buffer->ReadWriteChild(&dref);
}
uint32_t DataInformation::ComputeSizeInternal() {
return HeaderSize() + dref.ComputeSize();
}
MediaInformation::MediaInformation() {}
MediaInformation::~MediaInformation() {}
FourCC MediaInformation::BoxType() const { return FOURCC_MINF; }
bool MediaInformation::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->PrepareChildren() &&
buffer->ReadWriteChild(&dinf) &&
buffer->ReadWriteChild(&sample_table));
if (sample_table.description.type == kVideo)
RCHECK(buffer->ReadWriteChild(&vmhd));
else if (sample_table.description.type == kAudio)
RCHECK(buffer->ReadWriteChild(&smhd));
else
NOTIMPLEMENTED();
// Hint is not supported for now.
return true;
}
uint32_t MediaInformation::ComputeSizeInternal() {
uint32_t box_size =
HeaderSize() + dinf.ComputeSize() + sample_table.ComputeSize();
if (sample_table.description.type == kVideo)
box_size += vmhd.ComputeSize();
else if (sample_table.description.type == kAudio)
box_size += smhd.ComputeSize();
return box_size;
}
Media::Media() {}
Media::~Media() {}
FourCC Media::BoxType() const { return FOURCC_MDIA; }
bool Media::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->PrepareChildren() &&
buffer->ReadWriteChild(&header) &&
buffer->ReadWriteChild(&handler));
if (buffer->Reading()) {
// Maddeningly, the HandlerReference box specifies how to parse the
// SampleDescription box, making the latter the only box (of those that we
// support) which cannot be parsed correctly on its own (or even with
// information from its strict ancestor tree). We thus copy the handler type
// to the sample description box *before* parsing it to provide this
// information while parsing.
information.sample_table.description.type = handler.type;
} else {
DCHECK_EQ(information.sample_table.description.type, handler.type);
}
RCHECK(buffer->ReadWriteChild(&information));
return true;
}
uint32_t Media::ComputeSizeInternal() {
return HeaderSize() + header.ComputeSize() + handler.ComputeSize() +
information.ComputeSize();
}
Track::Track() {}
Track::~Track() {}
FourCC Track::BoxType() const { return FOURCC_TRAK; }
bool Track::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->PrepareChildren() &&
buffer->ReadWriteChild(&header) &&
buffer->ReadWriteChild(&media) &&
buffer->TryReadWriteChild(&edit));
return true;
}
uint32_t Track::ComputeSizeInternal() {
return HeaderSize() + header.ComputeSize() + media.ComputeSize() +
edit.ComputeSize();
}
MovieExtendsHeader::MovieExtendsHeader() : fragment_duration(0) {}
MovieExtendsHeader::~MovieExtendsHeader() {}
FourCC MovieExtendsHeader::BoxType() const { return FOURCC_MEHD; }
bool MovieExtendsHeader::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer));
size_t num_bytes = (version == 1) ? sizeof(uint64_t) : sizeof(uint32_t);
RCHECK(buffer->ReadWriteUInt64NBytes(&fragment_duration, num_bytes));
return true;
}
uint32_t MovieExtendsHeader::ComputeSizeInternal() {
// This box is optional. Skip it if it is not used.
if (fragment_duration == 0)
return 0;
version = IsFitIn32Bits(fragment_duration) ? 0 : 1;
return HeaderSize() + sizeof(uint32_t) * (1 + version);
}
TrackExtends::TrackExtends()
: track_id(0),
default_sample_description_index(0),
default_sample_duration(0),
default_sample_size(0),
default_sample_flags(0) {}
TrackExtends::~TrackExtends() {}
FourCC TrackExtends::BoxType() const { return FOURCC_TREX; }
bool TrackExtends::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->ReadWriteUInt32(&track_id) &&
buffer->ReadWriteUInt32(&default_sample_description_index) &&
buffer->ReadWriteUInt32(&default_sample_duration) &&
buffer->ReadWriteUInt32(&default_sample_size) &&
buffer->ReadWriteUInt32(&default_sample_flags));
return true;
}
uint32_t TrackExtends::ComputeSizeInternal() {
return HeaderSize() + sizeof(track_id) +
sizeof(default_sample_description_index) +
sizeof(default_sample_duration) + sizeof(default_sample_size) +
sizeof(default_sample_flags);
}
MovieExtends::MovieExtends() {}
MovieExtends::~MovieExtends() {}
FourCC MovieExtends::BoxType() const { return FOURCC_MVEX; }
bool MovieExtends::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->PrepareChildren() &&
buffer->TryReadWriteChild(&header));
if (buffer->Reading()) {
DCHECK(buffer->reader());
RCHECK(buffer->reader()->ReadChildren(&tracks));
} else {
for (uint32_t i = 0; i < tracks.size(); ++i)
RCHECK(buffer->ReadWriteChild(&tracks[i]));
}
return true;
}
uint32_t MovieExtends::ComputeSizeInternal() {
// This box is optional. Skip it if it does not contain any track.
if (tracks.size() == 0)
return 0;
uint32_t box_size = HeaderSize() + header.ComputeSize();
for (uint32_t i = 0; i < tracks.size(); ++i)
box_size += tracks[i].ComputeSize();
return box_size;
}
Movie::Movie() {}
Movie::~Movie() {}
FourCC Movie::BoxType() const { return FOURCC_MOOV; }
bool Movie::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->PrepareChildren() &&
buffer->ReadWriteChild(&header) &&
buffer->TryReadWriteChild(&extends));
if (buffer->Reading()) {
BoxReader* reader = buffer->reader();
DCHECK(reader);
RCHECK(reader->ReadChildren(&tracks) &&
reader->TryReadChildren(&pssh));
} else {
for (uint32_t i = 0; i < tracks.size(); ++i)
RCHECK(buffer->ReadWriteChild(&tracks[i]));
for (uint32_t i = 0; i < pssh.size(); ++i)
RCHECK(buffer->ReadWriteChild(&pssh[i]));
}
return true;
}
uint32_t Movie::ComputeSizeInternal() {
uint32_t box_size =
HeaderSize() + header.ComputeSize() + extends.ComputeSize();
for (uint32_t i = 0; i < tracks.size(); ++i)
box_size += tracks[i].ComputeSize();
for (uint32_t i = 0; i < pssh.size(); ++i)
box_size += pssh[i].ComputeSize();
return box_size;
}
TrackFragmentDecodeTime::TrackFragmentDecodeTime() : decode_time(0) {}
TrackFragmentDecodeTime::~TrackFragmentDecodeTime() {}
FourCC TrackFragmentDecodeTime::BoxType() const { return FOURCC_TFDT; }
bool TrackFragmentDecodeTime::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer));
size_t num_bytes = (version == 1) ? sizeof(uint64_t) : sizeof(uint32_t);
RCHECK(buffer->ReadWriteUInt64NBytes(&decode_time, num_bytes));
return true;
}
uint32_t TrackFragmentDecodeTime::ComputeSizeInternal() {
version = IsFitIn32Bits(decode_time) ? 0 : 1;
return HeaderSize() + sizeof(uint32_t) * (1 + version);
}
MovieFragmentHeader::MovieFragmentHeader() : sequence_number(0) {}
MovieFragmentHeader::~MovieFragmentHeader() {}
FourCC MovieFragmentHeader::BoxType() const { return FOURCC_MFHD; }
bool MovieFragmentHeader::ReadWriteInternal(BoxBuffer* buffer) {
return ReadWriteHeaderInternal(buffer) &&
buffer->ReadWriteUInt32(&sequence_number);
}
uint32_t MovieFragmentHeader::ComputeSizeInternal() {
return HeaderSize() + sizeof(sequence_number);
}
TrackFragmentHeader::TrackFragmentHeader()
: track_id(0),
sample_description_index(0),
default_sample_duration(0),
default_sample_size(0),
default_sample_flags(0) {}
TrackFragmentHeader::~TrackFragmentHeader() {}
FourCC TrackFragmentHeader::BoxType() const { return FOURCC_TFHD; }
bool TrackFragmentHeader::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->ReadWriteUInt32(&track_id));
if (flags & kBaseDataOffsetPresentMask) {
// MSE requires 'default-base-is-moof' to be set and
// 'base-data-offset-present' not to be set. We omit these checks as some
// valid files in the wild don't follow these rules, though they use moof as
// base.
uint64_t base_data_offset;
RCHECK(buffer->ReadWriteUInt64(&base_data_offset));
DLOG(WARNING) << "base-data-offset-present is not expected. Assumes "
"default-base-is-moof.";
}
if (flags & kSampleDescriptionIndexPresentMask) {
RCHECK(buffer->ReadWriteUInt32(&sample_description_index));
} else if (buffer->Reading()) {
sample_description_index = 0;
}
if (flags & kDefaultSampleDurationPresentMask) {
RCHECK(buffer->ReadWriteUInt32(&default_sample_duration));
} else if (buffer->Reading()) {
default_sample_duration = 0;
}
if (flags & kDefaultSampleSizePresentMask) {
RCHECK(buffer->ReadWriteUInt32(&default_sample_size));
} else if (buffer->Reading()) {
default_sample_size = 0;
}
if (flags & kDefaultSampleFlagsPresentMask)
RCHECK(buffer->ReadWriteUInt32(&default_sample_flags));
return true;
}
uint32_t TrackFragmentHeader::ComputeSizeInternal() {
uint32_t box_size = HeaderSize() + sizeof(track_id);
if (flags & kSampleDescriptionIndexPresentMask)
box_size += sizeof(sample_description_index);
if (flags & kDefaultSampleDurationPresentMask)
box_size += sizeof(default_sample_duration);
if (flags & kDefaultSampleSizePresentMask)
box_size += sizeof(default_sample_size);
if (flags & kDefaultSampleFlagsPresentMask)
box_size += sizeof(default_sample_flags);
return box_size;
}
TrackFragmentRun::TrackFragmentRun() : sample_count(0), data_offset(0) {}
TrackFragmentRun::~TrackFragmentRun() {}
FourCC TrackFragmentRun::BoxType() const { return FOURCC_TRUN; }
bool TrackFragmentRun::ReadWriteInternal(BoxBuffer* buffer) {
if (!buffer->Reading()) {
// Determine whether version 0 or version 1 should be used.
// Use version 0 if possible, use version 1 if there is a negative
// sample_offset value.
version = 0;
if (flags & kSampleCompTimeOffsetsPresentMask) {
for (uint32_t i = 0; i < sample_count; ++i) {
if (sample_composition_time_offsets[i] < 0) {
version = 1;
break;
}
}
}
}
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->ReadWriteUInt32(&sample_count));
bool data_offset_present = (flags & kDataOffsetPresentMask) != 0;
bool first_sample_flags_present = (flags & kFirstSampleFlagsPresentMask) != 0;
bool sample_duration_present = (flags & kSampleDurationPresentMask) != 0;
bool sample_size_present = (flags & kSampleSizePresentMask) != 0;
bool sample_flags_present = (flags & kSampleFlagsPresentMask) != 0;
bool sample_composition_time_offsets_present =
(flags & kSampleCompTimeOffsetsPresentMask) != 0;
if (data_offset_present) {
RCHECK(buffer->ReadWriteUInt32(&data_offset));
} else {
// NOTE: If the data-offset is not present, then the data for this run
// starts immediately after the data of the previous run, or at the
// base-data-offset defined by the track fragment header if this is the
// first run in a track fragment. If the data-offset is present, it is
// relative to the base-data-offset established in the track fragment
// header.
NOTIMPLEMENTED();
}
uint32_t first_sample_flags;
if (buffer->Reading()) {
if (first_sample_flags_present)
RCHECK(buffer->ReadWriteUInt32(&first_sample_flags));
if (sample_duration_present)
sample_durations.resize(sample_count);
if (sample_size_present)
sample_sizes.resize(sample_count);
if (sample_flags_present)
sample_flags.resize(sample_count);
if (sample_composition_time_offsets_present)
sample_composition_time_offsets.resize(sample_count);
} else {
if (first_sample_flags_present) {
first_sample_flags = sample_flags[0];
DCHECK(sample_flags.size() == 1);
RCHECK(buffer->ReadWriteUInt32(&first_sample_flags));
}
if (sample_duration_present)
DCHECK(sample_durations.size() == sample_count);
if (sample_size_present)
DCHECK(sample_sizes.size() == sample_count);
if (sample_flags_present)
DCHECK(sample_flags.size() == sample_count);
if (sample_composition_time_offsets_present)
DCHECK(sample_composition_time_offsets.size() == sample_count);
}
for (uint32_t i = 0; i < sample_count; ++i) {
if (sample_duration_present)
RCHECK(buffer->ReadWriteUInt32(&sample_durations[i]));
if (sample_size_present)
RCHECK(buffer->ReadWriteUInt32(&sample_sizes[i]));
if (sample_flags_present)
RCHECK(buffer->ReadWriteUInt32(&sample_flags[i]));
if (sample_composition_time_offsets_present) {
if (version == 0) {
uint32_t sample_offset = sample_composition_time_offsets[i];
RCHECK(buffer->ReadWriteUInt32(&sample_offset));
sample_composition_time_offsets[i] = sample_offset;
} else {
int32_t sample_offset = sample_composition_time_offsets[i];
RCHECK(buffer->ReadWriteInt32(&sample_offset));
sample_composition_time_offsets[i] = sample_offset;
}
}
}
if (buffer->Reading()) {
if (first_sample_flags_present) {
if (sample_flags.size() == 0) {
sample_flags.push_back(first_sample_flags);
} else {
sample_flags[0] = first_sample_flags;
}
}
}
return true;
}
uint32_t TrackFragmentRun::ComputeSizeInternal() {
uint32_t box_size = HeaderSize() + sizeof(sample_count);
if (flags & kDataOffsetPresentMask)
box_size += sizeof(data_offset);
if (flags & kFirstSampleFlagsPresentMask)
box_size += sizeof(uint32_t);
uint32_t fields = (flags & kSampleDurationPresentMask ? 1 : 0) +
(flags & kSampleSizePresentMask ? 1 : 0) +
(flags & kSampleFlagsPresentMask ? 1 : 0) +
(flags & kSampleCompTimeOffsetsPresentMask ? 1 : 0);
box_size += fields * sizeof(uint32_t) * sample_count;
return box_size;
}
SampleToGroup::SampleToGroup() : grouping_type(0), grouping_type_parameter(0) {}
SampleToGroup::~SampleToGroup() {}
FourCC SampleToGroup::BoxType() const { return FOURCC_SBGP; }
bool SampleToGroup::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->ReadWriteUInt32(&grouping_type));
if (version == 1)
RCHECK(buffer->ReadWriteUInt32(&grouping_type_parameter));
if (grouping_type != FOURCC_SEIG) {
DCHECK(buffer->Reading());
DLOG(WARNING) << "Sample group "
<< FourCCToString(static_cast<FourCC>(grouping_type))
<< " is not supported.";
return true;
}
uint32_t count = entries.size();
RCHECK(buffer->ReadWriteUInt32(&count));
entries.resize(count);
for (uint32_t i = 0; i < count; ++i) {
RCHECK(buffer->ReadWriteUInt32(&entries[i].sample_count) &&
buffer->ReadWriteUInt32(&entries[i].group_description_index));
}
return true;
}
uint32_t SampleToGroup::ComputeSizeInternal() {
// This box is optional. Skip it if it is not used.
if (entries.empty())
return 0;
return HeaderSize() + sizeof(grouping_type) +
(version == 1 ? sizeof(grouping_type_parameter) : 0) +
sizeof(uint32_t) + entries.size() * sizeof(entries[0]);
}
CencSampleEncryptionInfoEntry::CencSampleEncryptionInfoEntry()
: is_encrypted(false), iv_size(0) {
}
CencSampleEncryptionInfoEntry::~CencSampleEncryptionInfoEntry() {};
SampleGroupDescription::SampleGroupDescription() : grouping_type(0) {}
SampleGroupDescription::~SampleGroupDescription() {}
FourCC SampleGroupDescription::BoxType() const { return FOURCC_SGPD; }
bool SampleGroupDescription::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->ReadWriteUInt32(&grouping_type));
if (grouping_type != FOURCC_SEIG) {
DCHECK(buffer->Reading());
DLOG(WARNING) << "Sample group '" << grouping_type << "' is not supported.";
return true;
}
const size_t kEntrySize = sizeof(uint32_t) + kCencKeyIdSize;
uint32_t default_length = 0;
if (version == 1) {
if (buffer->Reading()) {
RCHECK(buffer->ReadWriteUInt32(&default_length));
RCHECK(default_length == 0 || default_length >= kEntrySize);
} else {
default_length = kEntrySize;
RCHECK(buffer->ReadWriteUInt32(&default_length));
}
}
uint32_t count = entries.size();
RCHECK(buffer->ReadWriteUInt32(&count));
entries.resize(count);
for (uint32_t i = 0; i < count; ++i) {
if (version == 1) {
if (buffer->Reading() && default_length == 0) {
uint32_t description_length = 0;
RCHECK(buffer->ReadWriteUInt32(&description_length));
RCHECK(description_length >= kEntrySize);
}
}
if (!buffer->Reading()) {
if (entries[i].key_id.size() != kCencKeyIdSize) {
LOG(WARNING) << "CENC defines key id length of " << kCencKeyIdSize
<< " bytes; got " << entries[i].key_id.size()
<< ". Resized accordingly.";
entries[i].key_id.resize(kCencKeyIdSize);
}
}
uint8_t flag = entries[i].is_encrypted ? 1 : 0;
RCHECK(buffer->IgnoreBytes(2) && // reserved.
buffer->ReadWriteUInt8(&flag) &&
buffer->ReadWriteUInt8(&entries[i].iv_size) &&
buffer->ReadWriteVector(&entries[i].key_id, kCencKeyIdSize));
if (buffer->Reading()) {
entries[i].is_encrypted = (flag != 0);
if (entries[i].is_encrypted) {
RCHECK(entries[i].iv_size == 8 || entries[i].iv_size == 16);
} else {
RCHECK(entries[i].iv_size == 0);
}
}
}
return true;
}
uint32_t SampleGroupDescription::ComputeSizeInternal() {
// Version 0 is obsoleted, so always generate version 1 box.
version = 1;
// This box is optional. Skip it if it is not used.
if (entries.empty())
return 0;
const size_t kEntrySize = sizeof(uint32_t) + kCencKeyIdSize;
return HeaderSize() + sizeof(grouping_type) +
(version == 1 ? sizeof(uint32_t) : 0) + sizeof(uint32_t) +
entries.size() * kEntrySize;
}
TrackFragment::TrackFragment() : decode_time_absent(false) {}
TrackFragment::~TrackFragment() {}
FourCC TrackFragment::BoxType() const { return FOURCC_TRAF; }
bool TrackFragment::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->PrepareChildren() &&
buffer->ReadWriteChild(&header));
if (buffer->Reading()) {
DCHECK(buffer->reader());
decode_time_absent = !buffer->reader()->ChildExist(&decode_time);
if (!decode_time_absent)
RCHECK(buffer->ReadWriteChild(&decode_time));
RCHECK(buffer->reader()->TryReadChildren(&runs));
// There could be multiple SampleGroupDescription and SampleToGroup boxes
// with different grouping types. For common encryption, the relevant
// grouping type is 'seig'. Continue reading until 'seig' is found, or
// until running out of child boxes.
while (sample_to_group.grouping_type != FOURCC_SEIG &&
buffer->reader()->ChildExist(&sample_to_group)) {
RCHECK(buffer->reader()->ReadChild(&sample_to_group));
}
while (sample_group_description.grouping_type != FOURCC_SEIG &&
buffer->reader()->ChildExist(&sample_group_description)) {
RCHECK(buffer->reader()->ReadChild(&sample_group_description));
}
} else {
if (!decode_time_absent)
RCHECK(buffer->ReadWriteChild(&decode_time));
for (uint32_t i = 0; i < runs.size(); ++i)
RCHECK(buffer->ReadWriteChild(&runs[i]));
RCHECK(buffer->TryReadWriteChild(&sample_to_group) &&
buffer->TryReadWriteChild(&sample_group_description));
}
return buffer->TryReadWriteChild(&auxiliary_size) &&
buffer->TryReadWriteChild(&auxiliary_offset);
}
uint32_t TrackFragment::ComputeSizeInternal() {
uint32_t box_size =
HeaderSize() + header.ComputeSize() + decode_time.ComputeSize() +
sample_to_group.ComputeSize() + sample_group_description.ComputeSize() +
auxiliary_size.ComputeSize() + auxiliary_offset.ComputeSize();
for (uint32_t i = 0; i < runs.size(); ++i)
box_size += runs[i].ComputeSize();
return box_size;
}
MovieFragment::MovieFragment() {}
MovieFragment::~MovieFragment() {}
FourCC MovieFragment::BoxType() const { return FOURCC_MOOF; }
bool MovieFragment::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->PrepareChildren() &&
buffer->ReadWriteChild(&header));
if (buffer->Reading()) {
BoxReader* reader = buffer->reader();
DCHECK(reader);
RCHECK(reader->ReadChildren(&tracks) &&
reader->TryReadChildren(&pssh));
} else {
for (uint32_t i = 0; i < tracks.size(); ++i)
RCHECK(buffer->ReadWriteChild(&tracks[i]));
for (uint32_t i = 0; i < pssh.size(); ++i)
RCHECK(buffer->ReadWriteChild(&pssh[i]));
}
return true;
}
uint32_t MovieFragment::ComputeSizeInternal() {
uint32_t box_size = HeaderSize() + header.ComputeSize();
for (uint32_t i = 0; i < tracks.size(); ++i)
box_size += tracks[i].ComputeSize();
for (uint32_t i = 0; i < pssh.size(); ++i)
box_size += pssh[i].ComputeSize();
return box_size;
}
SegmentIndex::SegmentIndex()
: reference_id(0),
timescale(0),
earliest_presentation_time(0),
first_offset(0) {}
SegmentIndex::~SegmentIndex() {}
FourCC SegmentIndex::BoxType() const { return FOURCC_SIDX; }
bool SegmentIndex::ReadWriteInternal(BoxBuffer* buffer) {
RCHECK(ReadWriteHeaderInternal(buffer) &&
buffer->ReadWriteUInt32(&reference_id) &&
buffer->ReadWriteUInt32(&timescale));
size_t num_bytes = (version == 1) ? sizeof(uint64_t) : sizeof(uint32_t);
RCHECK(
buffer->ReadWriteUInt64NBytes(&earliest_presentation_time, num_bytes) &&
buffer->ReadWriteUInt64NBytes(&first_offset, num_bytes));
uint16_t reference_count = references.size();
RCHECK(buffer->IgnoreBytes(2) && // reserved.
buffer->ReadWriteUInt16(&reference_count));
references.resize(reference_count);
uint32_t reference_type_size;
uint32_t sap;
for (uint32_t i = 0; i < reference_count; ++i) {
if (!buffer->Reading()) {
reference_type_size = references[i].referenced_size;
if (references[i].reference_type)
reference_type_size |= (1 << 31);
sap = (references[i].sap_type << 28) | references[i].sap_delta_time;
if (references[i].starts_with_sap)
sap |= (1 << 31);
}
RCHECK(buffer->ReadWriteUInt32(&reference_type_size) &&
buffer->ReadWriteUInt32(&references[i].subsegment_duration) &&
buffer->ReadWriteUInt32(&sap));
if (buffer->Reading()) {
references[i].reference_type = (reference_type_size >> 31) ? true : false;
references[i].referenced_size = reference_type_size & ~(1 << 31);
references[i].starts_with_sap = (sap >> 31) ? true : false;
references[i].sap_type =
static_cast<SegmentReference::SAPType>((sap >> 28) & 0x07);
references[i].sap_delta_time = sap & ~(0xF << 28);
}
}
return true;
}
uint32_t SegmentIndex::ComputeSizeInternal() {
version = IsFitIn32Bits(earliest_presentation_time, first_offset) ? 0 : 1;
return HeaderSize() + sizeof(reference_id) + sizeof(timescale) +
sizeof(uint32_t) * (1 + version) * 2 + 2 * sizeof(uint16_t) +
3 * sizeof(uint32_t) * references.size();
}
MediaData::MediaData() : data_size(0) {}
MediaData::~MediaData() {}
FourCC MediaData::BoxType() const { return FOURCC_MDAT; }
bool MediaData::ReadWriteInternal(BoxBuffer* buffer) {
NOTIMPLEMENTED() << "Actual data is parsed and written separately.";
return false;
}
uint32_t MediaData::ComputeSizeInternal() {
return HeaderSize() + data_size;
}
} // namespace mp4
} // namespace media
} // namespace edash_packager