/* * Copyright (c) 2016 The ZLMediaKit project authors. All Rights Reserved. * * This file is part of ZLMediaKit(https://github.com/xia-chu/ZLMediaKit). * * Use of this source code is governed by MIT license that can be found in the * LICENSE file in the root of the source tree. All contributing project authors * may be found in the AUTHORS file in the root of the source tree. */ #include "AAC.h" #ifdef ENABLE_MP4 #include "mpeg4-aac.h" #endif namespace mediakit{ #ifndef ENABLE_MP4 unsigned const samplingFrequencyTable[16] = { 96000, 88200, 64000, 48000, 44100, 32000, 24000, 22050, 16000, 12000, 11025, 8000, 7350, 0, 0, 0 }; class AdtsHeader{ public: unsigned int syncword = 0; //12 bslbf 同步字The bit string ‘1111 1111 1111’,说明一个ADTS帧的开始 unsigned int id; //1 bslbf MPEG 标示符, 设置为1 unsigned int layer; //2 uimsbf Indicates which layer is used. Set to ‘00’ unsigned int protection_absent; //1 bslbf 表示是否误码校验 unsigned int profile; //2 uimsbf 表示使用哪个级别的AAC,如01 Low Complexity(LC)--- AACLC unsigned int sf_index; //4 uimsbf 表示使用的采样率下标 unsigned int private_bit; //1 bslbf unsigned int channel_configuration; //3 uimsbf 表示声道数 unsigned int original; //1 bslbf unsigned int home; //1 bslbf //下面的为改变的参数即每一帧都不同 unsigned int copyright_identification_bit; //1 bslbf unsigned int copyright_identification_start; //1 bslbf unsigned int aac_frame_length; // 13 bslbf 一个ADTS帧的长度包括ADTS头和raw data block unsigned int adts_buffer_fullness; //11 bslbf 0x7FF 说明是码率可变的码流 //no_raw_data_blocks_in_frame 表示ADTS帧中有number_of_raw_data_blocks_in_frame + 1个AAC原始帧. //所以说number_of_raw_data_blocks_in_frame == 0 //表示说ADTS帧中有一个AAC数据块并不是说没有。(一个AAC原始帧包含一段时间内1024个采样及相关数据) unsigned int no_raw_data_blocks_in_frame; //2 uimsfb }; static void dumpAdtsHeader(const AdtsHeader &hed, uint8_t *out) { out[0] = (hed.syncword >> 4 & 0xFF); //8bit out[1] = (hed.syncword << 4 & 0xF0); //4 bit out[1] |= (hed.id << 3 & 0x08); //1 bit out[1] |= (hed.layer << 1 & 0x06); //2bit out[1] |= (hed.protection_absent & 0x01); //1 bit out[2] = (hed.profile << 6 & 0xC0); // 2 bit out[2] |= (hed.sf_index << 2 & 0x3C); //4bit out[2] |= (hed.private_bit << 1 & 0x02); //1 bit out[2] |= (hed.channel_configuration >> 2 & 0x03); //1 bit out[3] = (hed.channel_configuration << 6 & 0xC0); // 2 bit out[3] |= (hed.original << 5 & 0x20); //1 bit out[3] |= (hed.home << 4 & 0x10); //1 bit out[3] |= (hed.copyright_identification_bit << 3 & 0x08); //1 bit out[3] |= (hed.copyright_identification_start << 2 & 0x04); //1 bit out[3] |= (hed.aac_frame_length >> 11 & 0x03); //2 bit out[4] = (hed.aac_frame_length >> 3 & 0xFF); //8 bit out[5] = (hed.aac_frame_length << 5 & 0xE0); //3 bit out[5] |= (hed.adts_buffer_fullness >> 6 & 0x1F); //5 bit out[6] = (hed.adts_buffer_fullness << 2 & 0xFC); //6 bit out[6] |= (hed.no_raw_data_blocks_in_frame & 0x03); //2 bit } static void parseAacConfig(const string &config, AdtsHeader &adts) { uint8_t cfg1 = config[0]; uint8_t cfg2 = config[1]; int audioObjectType; int sampling_frequency_index; int channel_configuration; audioObjectType = cfg1 >> 3; sampling_frequency_index = ((cfg1 & 0x07) << 1) | (cfg2 >> 7); channel_configuration = (cfg2 & 0x7F) >> 3; adts.syncword = 0x0FFF; adts.id = 0; adts.layer = 0; adts.protection_absent = 1; adts.profile = audioObjectType - 1; adts.sf_index = sampling_frequency_index; adts.private_bit = 0; adts.channel_configuration = channel_configuration; adts.original = 0; adts.home = 0; adts.copyright_identification_bit = 0; adts.copyright_identification_start = 0; adts.aac_frame_length = 7; adts.adts_buffer_fullness = 2047; adts.no_raw_data_blocks_in_frame = 0; } #endif// ENABLE_MP4 int getAacFrameLength(const uint8_t *data, size_t bytes) { uint16_t len; if (bytes < 7) return -1; if (0xFF != data[0] || 0xF0 != (data[1] & 0xF0)) { return -1; } len = ((uint16_t) (data[3] & 0x03) << 11) | ((uint16_t) data[4] << 3) | ((uint16_t) (data[5] >> 5) & 0x07); return len; } string makeAacConfig(const uint8_t *hex, size_t length){ #ifndef ENABLE_MP4 if (!(hex[0] == 0xFF && (hex[1] & 0xF0) == 0xF0)) { return ""; } // Get and check the 'profile': unsigned char profile = (hex[2] & 0xC0) >> 6; // 2 bits if (profile == 3) { return ""; } // Get and check the 'sampling_frequency_index': unsigned char sampling_frequency_index = (hex[2] & 0x3C) >> 2; // 4 bits if (samplingFrequencyTable[sampling_frequency_index] == 0) { return ""; } // Get and check the 'channel_configuration': unsigned char channel_configuration = ((hex[2] & 0x01) << 2) | ((hex[3] & 0xC0) >> 6); // 3 bits unsigned char audioSpecificConfig[2]; unsigned char const audioObjectType = profile + 1; audioSpecificConfig[0] = (audioObjectType << 3) | (sampling_frequency_index >> 1); audioSpecificConfig[1] = (sampling_frequency_index << 7) | (channel_configuration << 3); return string((char *)audioSpecificConfig,2); #else struct mpeg4_aac_t aac = {0}; if (mpeg4_aac_adts_load(hex, length, &aac) > 0) { char buf[32] = {0}; int len = mpeg4_aac_audio_specific_config_save(&aac, (uint8_t *) buf, sizeof(buf)); if (len > 0) { return string(buf, len); } } WarnL << "生成aac config失败, adts header:" << hexdump(hex, length); return ""; #endif } int dumpAacConfig(const string &config, size_t length, uint8_t *out, size_t out_size) { #ifndef ENABLE_MP4 AdtsHeader header; parseAacConfig(config, header); header.aac_frame_length = (decltype(header.aac_frame_length))(ADTS_HEADER_LEN + length); dumpAdtsHeader(header, out); return ADTS_HEADER_LEN; #else struct mpeg4_aac_t aac = {0}; int ret = mpeg4_aac_audio_specific_config_load((uint8_t *) config.data(), config.size(), &aac); if (ret > 0) { ret = mpeg4_aac_adts_save(&aac, length, out, out_size); } if (ret < 0) { WarnL << "生成adts头失败:" << ret << ", aac config:" << hexdump(config.data(), config.size()); } return ret; #endif } bool parseAacConfig(const string &config, int &samplerate, int &channels){ #ifndef ENABLE_MP4 AdtsHeader header; parseAacConfig(config, header); samplerate = samplingFrequencyTable[header.sf_index]; channels = header.channel_configuration; return true; #else struct mpeg4_aac_t aac = {0}; int ret = mpeg4_aac_audio_specific_config_load((uint8_t *) config.data(), config.size(), &aac); if (ret > 0) { samplerate = aac.sampling_frequency; channels = aac.channels; return true; } WarnL << "获取aac采样率、声道数失败:" << hexdump(config.data(), config.size()); return false; #endif } //////////////////////////////////////////////////////////////////////////////////////////////////// /** * aac类型SDP */ class AACSdp : public Sdp { public: /** * 构造函数 * @param aac_cfg aac两个字节的配置描述 * @param sample_rate 音频采样率 * @param payload_type rtp payload type 默认98 * @param bitrate 比特率 */ AACSdp(const string &aac_cfg, int sample_rate, int channels, int bitrate = 128, int payload_type = 98) : Sdp(sample_rate,payload_type){ _printer << "m=audio 0 RTP/AVP " << payload_type << "\r\n"; if (bitrate) { _printer << "b=AS:" << bitrate << "\r\n"; } _printer << "a=rtpmap:" << payload_type << " " << getCodecName() << "/" << sample_rate << "/" << channels << "\r\n"; string configStr; char buf[4] = {0}; for(auto &ch : aac_cfg){ snprintf(buf, sizeof(buf), "%02X", (uint8_t)ch); configStr.append(buf); } _printer << "a=fmtp:" << payload_type << " streamtype=5;profile-level-id=1;mode=AAC-hbr;" << "sizelength=13;indexlength=3;indexdeltalength=3;config=" << configStr << "\r\n"; _printer << "a=control:trackID=" << (int)TrackAudio << "\r\n"; } string getSdp() const override { return _printer; } CodecId getCodecId() const override { return CodecAAC; } private: _StrPrinter _printer; }; //////////////////////////////////////////////////////////////////////////////////////////////////// AACTrack::AACTrack(const string &aac_cfg) { if (aac_cfg.size() < 2) { throw std::invalid_argument("adts配置必须最少2个字节"); } _cfg = aac_cfg; onReady(); } const string &AACTrack::getAacCfg() const { return _cfg; } CodecId AACTrack::getCodecId() const { return CodecAAC; } bool AACTrack::ready() { return !_cfg.empty(); } int AACTrack::getAudioSampleRate() const { return _sampleRate; } int AACTrack::getAudioSampleBit() const { return _sampleBit; } int AACTrack::getAudioChannel() const { return _channel; } bool AACTrack::inputFrame(const Frame::Ptr &frame) { if (!frame->prefixSize()) { return inputFrame_l(frame); } bool ret = false; //有adts头,尝试分帧 auto ptr = frame->data(); auto end = frame->data() + frame->size(); while (ptr < end) { auto frame_len = getAacFrameLength((uint8_t *) ptr, end - ptr); if (frame_len < ADTS_HEADER_LEN) { break; } auto sub_frame = std::make_shared >(frame, (char *) ptr, frame_len, ADTS_HEADER_LEN); ptr += frame_len; if (ptr > end) { WarnL << "invalid aac length in adts header: " << frame_len << ", remain data size: " << end - (ptr - frame_len); break; } sub_frame->setCodecId(CodecAAC); if (inputFrame_l(sub_frame)) { ret = true; } } return ret; } bool AACTrack::inputFrame_l(const Frame::Ptr &frame) { if (_cfg.empty()) { //未获取到aac_cfg信息 if (frame->prefixSize()) { //根据7个字节的adts头生成aac config _cfg = makeAacConfig((uint8_t *) (frame->data()), frame->prefixSize()); onReady(); } else { WarnL << "无法获取adts头!"; } } if (frame->size() > frame->prefixSize()) { //除adts头外,有实际负载 return AudioTrack::inputFrame(frame); } return false; } void AACTrack::onReady() { if (_cfg.size() < 2) { return; } parseAacConfig(_cfg, _sampleRate, _channel); } Track::Ptr AACTrack::clone() { return std::make_shared::type>(*this); } Sdp::Ptr AACTrack::getSdp() { if(!ready()){ WarnL << getCodecName() << " Track未准备好"; return nullptr; } return std::make_shared(getAacCfg(), getAudioSampleRate(), getAudioChannel(), getBitRate() / 1024); } }//namespace mediakit