shaka-packager/media/mp4/aac.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 "media/mp4/aac.h"
#include <algorithm>
#include "base/logging.h"
#include "media/base/bit_reader.h"
#include "media/mp4/rcheck.h"
namespace {
// Sampling Frequency Index table, from ISO 14496-3 Table 1.16
static const uint32 kSampleRates[] = {
96000, 88200, 64000, 48000, 44100, 32000, 24000,
22050, 16000, 12000, 11025, 8000, 7350
};
// Channel Configuration table, from ISO 14496-3 Table 1.17
const uint8 kChannelConfigs[] = {0, 1, 2, 3, 4, 5, 6, 8};
} // namespace
namespace media {
namespace mp4 {
AAC::AAC()
: audio_object_type_(0), frequency_index_(0), channel_config_(0),
ps_present_(false), frequency_(0), extension_frequency_(0),
num_channels_(0) {
}
AAC::~AAC() {
}
bool AAC::Parse(const std::vector<uint8>& data) {
if (data.empty())
return false;
BitReader reader(&data[0], data.size());
uint8 extension_type = 0;
uint8 extension_frequency_index = 0xff;
ps_present_ = false;
frequency_ = 0;
extension_frequency_ = 0;
// The following code is written according to ISO 14496 Part 3 Table 1.13 -
// Syntax of AudioSpecificConfig.
// Read base configuration.
// Audio Object Types specified in ISO 14496-3, Table 1.15.
RCHECK(reader.ReadBits(5, &audio_object_type_));
// Audio objects type >=31 is not supported yet.
RCHECK(audio_object_type_ < 31);
RCHECK(reader.ReadBits(4, &frequency_index_));
if (frequency_index_ == 0xf)
RCHECK(reader.ReadBits(24, &frequency_));
RCHECK(reader.ReadBits(4, &channel_config_));
// Read extension configuration.
if (audio_object_type_ == 5 || audio_object_type_ == 29) {
ps_present_ = (audio_object_type_ == 29);
extension_type = 5;
RCHECK(reader.ReadBits(4, &extension_frequency_index));
if (extension_frequency_index == 0xf)
RCHECK(reader.ReadBits(24, &extension_frequency_));
RCHECK(reader.ReadBits(5, &audio_object_type_));
// Audio objects type >=31 is not supported yet.
RCHECK(audio_object_type_ < 31);
}
RCHECK(SkipDecoderGASpecificConfig(&reader));
RCHECK(SkipErrorSpecificConfig());
// Read extension configuration again
// Note: The check for 16 available bits comes from the AAC spec.
if (extension_type != 5 && reader.bits_available() >= 16) {
uint16 sync_extension_type;
uint8 sbr_present_flag;
uint8 ps_present_flag;
if (reader.ReadBits(11, &sync_extension_type) &&
sync_extension_type == 0x2b7) {
if (reader.ReadBits(5, &extension_type) && extension_type == 5) {
RCHECK(reader.ReadBits(1, &sbr_present_flag));
if (sbr_present_flag) {
RCHECK(reader.ReadBits(4, &extension_frequency_index));
if (extension_frequency_index == 0xf)
RCHECK(reader.ReadBits(24, &extension_frequency_));
// Note: The check for 12 available bits comes from the AAC spec.
if (reader.bits_available() >= 12) {
RCHECK(reader.ReadBits(11, &sync_extension_type));
if (sync_extension_type == 0x548) {
RCHECK(reader.ReadBits(1, &ps_present_flag));
ps_present_ = ps_present_flag != 0;
}
}
}
}
}
}
if (frequency_ == 0) {
RCHECK(frequency_index_ < arraysize(kSampleRates));
frequency_ = kSampleRates[frequency_index_];
}
if (extension_frequency_ == 0 && extension_frequency_index != 0xff) {
RCHECK(extension_frequency_index < arraysize(kSampleRates));
extension_frequency_ = kSampleRates[extension_frequency_index];
}
RCHECK(channel_config_ < arraysize(kChannelConfigs));
num_channels_ = kChannelConfigs[channel_config_];
return frequency_ != 0 && num_channels_ != 0 && audio_object_type_ >= 1 &&
audio_object_type_ <= 4 && frequency_index_ != 0xf &&
channel_config_ <= 7;
}
uint32 AAC::GetOutputSamplesPerSecond(bool sbr_in_mimetype) const {
if (extension_frequency_ > 0)
return extension_frequency_;
if (!sbr_in_mimetype)
return frequency_;
// The following code is written according to ISO 14496 Part 3 Table 1.11 and
// Table 1.22. (Table 1.11 refers to the capping to 48000, Table 1.22 refers
// to SBR doubling the AAC sample rate.)
// TODO(acolwell) : Extend sample rate cap to 96kHz for Level 5 content.
DCHECK_GT(frequency_, 0);
return std::min(2 * frequency_, 48000u);
}
uint8 AAC::GetNumChannels(bool sbr_in_mimetype) const {
// Check for implicit signalling of HE-AAC and indicate stereo output
// if the mono channel configuration is signalled.
// See ISO-14496-3 Section 1.6.6.1.2 for details about this special casing.
if (sbr_in_mimetype && channel_config_ == 1)
return 2; // CHANNEL_LAYOUT_STEREO
// When Parametric Stereo is on, mono will be played as stereo.
if (ps_present_ && channel_config_ == 1)
return 2; // CHANNEL_LAYOUT_STEREO
return num_channels_;
}
bool AAC::ConvertToADTS(std::vector<uint8>* buffer) const {
size_t size = buffer->size() + kADTSHeaderSize;
DCHECK(audio_object_type_ >= 1 && audio_object_type_ <= 4 &&
frequency_index_ != 0xf && channel_config_ <= 7);
// ADTS header uses 13 bits for packet size.
if (size >= (1 << 13))
return false;
std::vector<uint8>& adts = *buffer;
adts.insert(buffer->begin(), kADTSHeaderSize, 0);
adts[0] = 0xff;
adts[1] = 0xf1;
adts[2] = ((audio_object_type_ - 1) << 6) + (frequency_index_ << 2) +
(channel_config_ >> 2);
adts[3] = ((channel_config_ & 0x3) << 6) + (size >> 11);
adts[4] = (size & 0x7ff) >> 3;
adts[5] = ((size & 7) << 5) + 0x1f;
adts[6] = 0xfc;
return true;
}
// Currently this function only support GASpecificConfig defined in
// ISO 14496 Part 3 Table 4.1 - Syntax of GASpecificConfig()
bool AAC::SkipDecoderGASpecificConfig(BitReader* bit_reader) const {
switch (audio_object_type_) {
case 1:
case 2:
case 3:
case 4:
case 6:
case 7:
case 17:
case 19:
case 20:
case 21:
case 22:
case 23:
return SkipGASpecificConfig(bit_reader);
default:
break;
}
return false;
}
bool AAC::SkipErrorSpecificConfig() const {
switch (audio_object_type_) {
case 17:
case 19:
case 20:
case 21:
case 22:
case 23:
case 24:
case 25:
case 26:
case 27:
return false;
default:
break;
}
return true;
}
// The following code is written according to ISO 14496 part 3 Table 4.1 -
// GASpecificConfig.
bool AAC::SkipGASpecificConfig(BitReader* bit_reader) const {
uint8 extension_flag = 0;
uint8 depends_on_core_coder;
uint16 dummy;
RCHECK(bit_reader->ReadBits(1, &dummy)); // frameLengthFlag
RCHECK(bit_reader->ReadBits(1, &depends_on_core_coder));
if (depends_on_core_coder == 1)
RCHECK(bit_reader->ReadBits(14, &dummy)); // coreCoderDelay
RCHECK(bit_reader->ReadBits(1, &extension_flag));
RCHECK(channel_config_ != 0);
if (audio_object_type_ == 6 || audio_object_type_ == 20)
RCHECK(bit_reader->ReadBits(3, &dummy)); // layerNr
if (extension_flag) {
if (audio_object_type_ == 22) {
RCHECK(bit_reader->ReadBits(5, &dummy)); // numOfSubFrame
RCHECK(bit_reader->ReadBits(11, &dummy)); // layer_length
}
if (audio_object_type_ == 17 || audio_object_type_ == 19 ||
audio_object_type_ == 20 || audio_object_type_ == 23) {
RCHECK(bit_reader->ReadBits(3, &dummy)); // resilience flags
}
RCHECK(bit_reader->ReadBits(1, &dummy)); // extensionFlag3
}
return true;
}
} // namespace mp4
} // namespace media