shaka-packager/packager/media/formats/mp2t/ac3_header.cc

164 lines
5.3 KiB
C++

// Copyright 2017 Google LLC. All rights reserved.
//
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file or at
// https://developers.google.com/open-source/licenses/bsd
#include <packager/media/formats/mp2t/ac3_header.h>
#include <packager/media/base/bit_reader.h>
#include <packager/media/base/bit_writer.h>
#include <packager/media/formats/mp2t/mp2t_common.h>
namespace shaka {
namespace media {
namespace mp2t {
namespace {
// ASTC Standard A/52:2012 Table 5.6 Sample Rate Codes.
const uint32_t kAc3SampleRateTable[] = {48000, 44100, 32000};
// ASTC Standard A/52:2012 Table 5.8 Audio Coding Mode.
const uint8_t kAc3NumChannelsTable[] = {2, 1, 2, 3, 3, 4, 4, 5};
// ATSC Standard A/52:2012 Table 5.18 Frame Size Code Table
// (in words = 16 bits).
const size_t kFrameSizeCodeTable[][3] = {
// {32kHz, 44.1kHz, 48kHz}
{96, 69, 64}, {96, 70, 64}, {120, 87, 80},
{120, 88, 80}, {144, 104, 96}, {144, 105, 96},
{168, 121, 112}, {168, 122, 112}, {192, 139, 128},
{192, 140, 128}, {240, 174, 160}, {240, 175, 160},
{288, 208, 192}, {288, 209, 192}, {336, 243, 224},
{336, 244, 224}, {384, 278, 256}, {384, 279, 256},
{480, 348, 320}, {480, 349, 320}, {576, 417, 384},
{576, 418, 384}, {672, 487, 448}, {672, 488, 448},
{768, 557, 512}, {768, 558, 512}, {960, 696, 640},
{960, 697, 640}, {1152, 835, 768}, {1152, 836, 768},
{1344, 975, 896}, {1344, 976, 896}, {1536, 1114, 1024},
{1536, 1115, 1024}, {1728, 1253, 1152}, {1728, 1254, 1152},
{1920, 1393, 1280}, {1920, 1394, 1280},
};
// Calculate the size of the frame from the sample rate code and the
// frame size code.
// @return the size of the frame (header + payload).
size_t CalcFrameSize(uint8_t fscod, uint8_t frmsizecod) {
const size_t kNumFscode = std::size(kAc3SampleRateTable);
DCHECK_LT(fscod, kNumFscode);
DCHECK_LT(frmsizecod, std::size(kFrameSizeCodeTable));
// The order of frequencies are reversed in |kFrameSizeCodeTable| compared to
// |kAc3SampleRateTable|.
const int index = kNumFscode - 1 - fscod;
return kFrameSizeCodeTable[frmsizecod][index] * 2;
}
} // namespace
bool Ac3Header::IsSyncWord(const uint8_t* buf) const {
DCHECK(buf);
// ATSC Standard A/52:2012 5.4.1 syncinfo: Synchronization Information.
return buf[0] == 0x0B && buf[1] == 0x77;
}
size_t Ac3Header::GetMinFrameSize() const {
// Arbitrary. Actual frame size starts with 96 words.
const size_t kMinAc3FrameSize = 10u;
return kMinAc3FrameSize;
}
size_t Ac3Header::GetSamplesPerFrame() const {
// ATSC Standard A/52:2012
// Annex A: AC-3 Elementary Streams in the MPEG-2 Multiplex.
const size_t kSamplesPerAc3Frame = 1536;
return kSamplesPerAc3Frame;
}
bool Ac3Header::Parse(const uint8_t* audio_frame, size_t audio_frame_size) {
BitReader frame(audio_frame, audio_frame_size);
// ASTC Standard A/52:2012 5. BIT STREAM SYNTAX.
// syncinfo: synchronization information section.
uint16_t syncword;
RCHECK(frame.ReadBits(16, &syncword));
RCHECK(syncword == 0x0B77);
uint16_t crc1;
RCHECK(frame.ReadBits(16, &crc1));
RCHECK(frame.ReadBits(2, &fscod_));
RCHECK(fscod_ < std::size(kAc3SampleRateTable));
RCHECK(frame.ReadBits(6, &frmsizecod_));
RCHECK(frmsizecod_ < std::size(kFrameSizeCodeTable));
// bsi: bit stream information section.
RCHECK(frame.ReadBits(5, &bsid_));
RCHECK(frame.ReadBits(3, &bsmod_));
RCHECK(frame.ReadBits(3, &acmod_));
RCHECK(acmod_ < std::size(kAc3NumChannelsTable));
// If 3 front channels.
if ((acmod_ & 0x01) && (acmod_ != 0x01))
RCHECK(frame.SkipBits(2)); // cmixlev.
// If a surround channel exists.
if (acmod_ & 0x04)
RCHECK(frame.SkipBits(2)); // surmixlev.
// If in 2/0 mode.
if (acmod_ == 0x02)
RCHECK(frame.SkipBits(2)); // dsurmod.
RCHECK(frame.ReadBits(1, &lfeon_));
return true;
}
size_t Ac3Header::GetHeaderSize() const {
// Unlike ADTS, for AC3, the whole frame is included in the media sample, so
// return 0 header size.
return 0;
}
size_t Ac3Header::GetFrameSize() const {
return CalcFrameSize(fscod_, frmsizecod_);
}
size_t Ac3Header::GetFrameSizeWithoutParsing(const uint8_t* data,
size_t num_bytes) const {
DCHECK_GT(num_bytes, static_cast<size_t>(4));
uint8_t fscod = data[4] >> 6;
uint8_t frmsizecod = data[4] & 0x3f;
return CalcFrameSize(fscod, frmsizecod);
}
void Ac3Header::GetAudioSpecificConfig(std::vector<uint8_t>* buffer) const {
DCHECK(buffer);
buffer->clear();
BitWriter config(buffer);
// Accoding to ETSI TS 102 366 V1.3.1 (2014-08) F.4 AC3SpecificBox.
config.WriteBits(fscod_, 2);
config.WriteBits(bsid_, 5);
config.WriteBits(bsmod_, 3);
config.WriteBits(acmod_, 3);
config.WriteBits(lfeon_, 1);
const uint8_t bit_rate_code = frmsizecod_ >> 1;
config.WriteBits(bit_rate_code, 5);
config.Flush();
}
uint8_t Ac3Header::GetObjectType() const {
// Only useful for AAC. Return a dummy value instead.
return 0;
}
uint32_t Ac3Header::GetSamplingFrequency() const {
DCHECK_LT(fscod_, std::size(kAc3SampleRateTable));
return kAc3SampleRateTable[fscod_];
}
uint8_t Ac3Header::GetNumChannels() const {
DCHECK_LT(acmod_, std::size(kAc3NumChannelsTable));
return kAc3NumChannelsTable[acmod_] + (lfeon_ ? 1 : 0);
}
} // namespace mp2t
} // namespace media
} // namespace shaka