#include "AudioStreamingPartInternal.h" #include "rtc_base/logging.h" #include "rtc_base/third_party/base64/base64.h" extern "C" { #include #include #include } #include #include #include #include namespace tgcalls { namespace { int16_t sampleFloatToInt16(float sample) { return av_clip_int16 (static_cast(lrint(sample*32767))); } uint32_t stringToUInt32(std::string const &string) { std::stringstream stringStream(string); uint32_t value = 0; stringStream >> value; return value; } template void splitString(const std::string &s, char delim, Out result) { std::istringstream iss(s); std::string item; while (std::getline(iss, item, delim)) { *result++ = item; } } std::vector splitString(const std::string &s, char delim) { std::vector elems; splitString(s, delim, std::back_inserter(elems)); return elems; } static absl::optional readInt32(std::string const &data, int &offset) { if (offset + 4 > data.length()) { return absl::nullopt; } int32_t value = 0; memcpy(&value, data.data() + offset, 4); offset += 4; return value; } std::vector parseChannelUpdates(std::string const &data, int &offset) { std::vector result; auto channels = readInt32(data, offset); if (!channels) { return {}; } auto count = readInt32(data, offset); if (!count) { return {}; } for (int i = 0; i < count.value(); i++) { auto frameIndex = readInt32(data, offset); if (!frameIndex) { return {}; } auto channelId = readInt32(data, offset); if (!channelId) { return {}; } auto ssrc = readInt32(data, offset); if (!ssrc) { return {}; } AudioStreamingPartInternal::ChannelUpdate update; update.frameIndex = frameIndex.value(); update.id = channelId.value(); update.ssrc = ssrc.value(); result.push_back(update); } return result; } } AudioStreamingPartInternal::AudioStreamingPartInternal(std::vector &&fileData, std::string const &container) : _avIoContext(std::move(fileData)) { int ret = 0; _frame = av_frame_alloc(); #if LIBAVFORMAT_VERSION_MAJOR >= 59 const #endif AVInputFormat *inputFormat = av_find_input_format(container.c_str()); if (!inputFormat) { _didReadToEnd = true; return; } _inputFormatContext = avformat_alloc_context(); if (!_inputFormatContext) { _didReadToEnd = true; return; } _inputFormatContext->pb = _avIoContext.getContext(); if ((ret = avformat_open_input(&_inputFormatContext, "", inputFormat, nullptr)) < 0) { _didReadToEnd = true; return; } if ((ret = avformat_find_stream_info(_inputFormatContext, nullptr)) < 0) { _didReadToEnd = true; avformat_close_input(&_inputFormatContext); _inputFormatContext = nullptr; return; } for (int i = 0; i < _inputFormatContext->nb_streams; i++) { AVStream *inStream = _inputFormatContext->streams[i]; AVCodecParameters *inCodecpar = inStream->codecpar; if (inCodecpar->codec_type != AVMEDIA_TYPE_AUDIO) { continue; } _audioCodecParameters = avcodec_parameters_alloc(); avcodec_parameters_copy(_audioCodecParameters, inCodecpar); _streamId = i; _durationInMilliseconds = (int)(inStream->duration * av_q2d(inStream->time_base) * 1000); if (inStream->metadata) { AVDictionaryEntry *entry = av_dict_get(inStream->metadata, "TG_META", nullptr, 0); if (entry && entry->value) { std::string result; size_t data_used = 0; std::string sourceBase64 = (const char *)entry->value; rtc::Base64::Decode(sourceBase64, rtc::Base64::DO_LAX, &result, &data_used); if (result.size() != 0) { int offset = 0; _channelUpdates = parseChannelUpdates(result, offset); } } uint32_t videoChannelMask = 0; entry = av_dict_get(inStream->metadata, "ACTIVE_MASK", nullptr, 0); if (entry && entry->value) { std::string sourceString = (const char *)entry->value; videoChannelMask = stringToUInt32(sourceString); } std::vector endpointList; entry = av_dict_get(inStream->metadata, "ENDPOINTS", nullptr, 0); if (entry && entry->value) { std::string sourceString = (const char *)entry->value; endpointList = splitString(sourceString, ' '); } std::bitset<32> videoChannels(videoChannelMask); size_t endpointIndex = 0; if (videoChannels.count() == endpointList.size()) { for (size_t i = 0; i < videoChannels.size(); i++) { if (videoChannels[i]) { _endpointMapping.insert(std::make_pair(endpointList[endpointIndex], i)); endpointIndex++; } } } } break; } if (_streamId == -1) { _didReadToEnd = true; } } AudioStreamingPartInternal::~AudioStreamingPartInternal() { if (_frame) { av_frame_unref(_frame); } if (_inputFormatContext) { avformat_close_input(&_inputFormatContext); } if (_audioCodecParameters) { avcodec_parameters_free(&_audioCodecParameters); } } AudioStreamingPartInternal::ReadPcmResult AudioStreamingPartInternal::readPcm(AudioStreamingPartPersistentDecoder &persistentDecoder, std::vector &outPcm) { if (_didReadToEnd) { return AudioStreamingPartInternal::ReadPcmResult(); } int outPcmSampleOffset = 0; ReadPcmResult result; if (_pcmBufferSampleOffset >= _pcmBufferSampleSize) { fillPcmBuffer(persistentDecoder); } if (outPcm.size() != 480 * _channelCount) { outPcm.resize(480 * _channelCount); } int readSamples = 0; if (_channelCount != 0) { readSamples = (int)outPcm.size() / _channelCount; } while (outPcmSampleOffset < readSamples) { if (_pcmBufferSampleOffset >= _pcmBufferSampleSize) { fillPcmBuffer(persistentDecoder); if (_pcmBufferSampleOffset >= _pcmBufferSampleSize) { break; } } int readFromPcmBufferSamples = std::min(_pcmBufferSampleSize - _pcmBufferSampleOffset, readSamples - outPcmSampleOffset); if (readFromPcmBufferSamples != 0) { std::copy(_pcmBuffer.begin() + _pcmBufferSampleOffset * _channelCount, _pcmBuffer.begin() + _pcmBufferSampleOffset * _channelCount + readFromPcmBufferSamples * _channelCount, outPcm.begin() + outPcmSampleOffset * _channelCount); _pcmBufferSampleOffset += readFromPcmBufferSamples; outPcmSampleOffset += readFromPcmBufferSamples; result.numSamples += readFromPcmBufferSamples; _readSampleCount += readFromPcmBufferSamples; } } result.numChannels = _channelCount; // Uncomment for debugging incomplete frames /*if (result.numSamples != 480 && result.numSamples != 0) { RTC_LOG(LS_INFO) << "result.numSamples = " << result.numSamples << ", _readSampleCount = " << _readSampleCount << ", duration = " << _inputFormatContext->streams[_streamId]->duration; }*/ return result; } int AudioStreamingPartInternal::getDurationInMilliseconds() const { return _durationInMilliseconds; } std::vector const &AudioStreamingPartInternal::getChannelUpdates() const { return _channelUpdates; } std::map AudioStreamingPartInternal::getEndpointMapping() const { return _endpointMapping; } void AudioStreamingPartInternal::fillPcmBuffer(AudioStreamingPartPersistentDecoder &persistentDecoder) { _pcmBufferSampleSize = 0; _pcmBufferSampleOffset = 0; if (_didReadToEnd) { return; } if (!_inputFormatContext) { _didReadToEnd = true; return; } int ret = 0; while (true) { ret = av_read_frame(_inputFormatContext, &_packet); if (ret < 0) { _didReadToEnd = true; return; } if (_packet.stream_index != _streamId) { continue; } ret = persistentDecoder.decode(_audioCodecParameters, _inputFormatContext->streams[_streamId]->time_base, _packet, _frame); if (ret == AVERROR(EAGAIN)) { continue; } break; } if (ret != 0) { _didReadToEnd = true; return; } if (_channelCount == 0) { _channelCount = _frame->channels; } if (_channelCount == 0) { _didReadToEnd = true; return; } if (_frame->channels != _channelCount || _frame->channels > 8) { _didReadToEnd = true; return; } if (_pcmBuffer.size() < _frame->nb_samples * _frame->channels) { _pcmBuffer.resize(_frame->nb_samples * _frame->channels); } switch (_frame->format) { case AV_SAMPLE_FMT_S16: { memcpy(_pcmBuffer.data(), _frame->data[0], _frame->nb_samples * 2 * _frame->channels); } break; case AV_SAMPLE_FMT_S16P: { int16_t *to = _pcmBuffer.data(); for (int sample = 0; sample < _frame->nb_samples; ++sample) { for (int channel = 0; channel < _frame->channels; ++channel) { int16_t *shortChannel = (int16_t*)_frame->data[channel]; *to++ = shortChannel[sample]; } } } break; case AV_SAMPLE_FMT_FLT: { float *floatData = (float *)&_frame->data[0]; for (int i = 0; i < _frame->nb_samples * _frame->channels; i++) { _pcmBuffer[i] = sampleFloatToInt16(floatData[i]); } } break; case AV_SAMPLE_FMT_FLTP: { int16_t *to = _pcmBuffer.data(); for (int sample = 0; sample < _frame->nb_samples; ++sample) { for (int channel = 0; channel < _frame->channels; ++channel) { float *floatChannel = (float*)_frame->data[channel]; *to++ = sampleFloatToInt16(floatChannel[sample]); } } } break; default: { RTC_FATAL() << "Unexpected sample_fmt"; } break; } _pcmBufferSampleSize = _frame->nb_samples; _pcmBufferSampleOffset = 0; } }