/* * Copyright (c) 2016 The WebRTC project authors. All Rights Reserved. * * Use of this source code is governed by a BSD-style license * that can be found in the LICENSE file in the root of the source * tree. An additional intellectual property rights grant can be found * in the file PATENTS. All contributing project authors may * be found in the AUTHORS file in the root of the source tree. */ #include "modules/audio_coding/neteq/tools/neteq_test.h" #include #include #include "modules/audio_coding/neteq/default_neteq_factory.h" #include "modules/rtp_rtcp/source/byte_io.h" #include "system_wrappers/include/clock.h" namespace webrtc { namespace test { namespace { absl::optional ActionToOperations( absl::optional a) { if (!a) { return absl::nullopt; } switch (*a) { case NetEqSimulator::Action::kAccelerate: return absl::make_optional(NetEq::Operation::kAccelerate); case NetEqSimulator::Action::kExpand: return absl::make_optional(NetEq::Operation::kExpand); case NetEqSimulator::Action::kNormal: return absl::make_optional(NetEq::Operation::kNormal); case NetEqSimulator::Action::kPreemptiveExpand: return absl::make_optional(NetEq::Operation::kPreemptiveExpand); } } std::unique_ptr CreateNetEq( const NetEq::Config& config, Clock* clock, const rtc::scoped_refptr& decoder_factory) { return DefaultNetEqFactory().CreateNetEq(config, decoder_factory, clock); } } // namespace void DefaultNetEqTestErrorCallback::OnInsertPacketError( const NetEqInput::PacketData& packet) { std::cerr << "InsertPacket returned an error." << std::endl; std::cerr << "Packet data: " << packet.ToString() << std::endl; FATAL(); } void DefaultNetEqTestErrorCallback::OnGetAudioError() { std::cerr << "GetAudio returned an error." << std::endl; FATAL(); } NetEqTest::NetEqTest(const NetEq::Config& config, rtc::scoped_refptr decoder_factory, const DecoderMap& codecs, std::unique_ptr text_log, NetEqFactory* neteq_factory, std::unique_ptr input, std::unique_ptr output, Callbacks callbacks) : clock_(0), neteq_(neteq_factory ? neteq_factory->CreateNetEq(config, decoder_factory, &clock_) : CreateNetEq(config, &clock_, decoder_factory)), input_(std::move(input)), output_(std::move(output)), callbacks_(callbacks), sample_rate_hz_(config.sample_rate_hz), text_log_(std::move(text_log)) { RTC_CHECK(!config.enable_muted_state) << "The code does not handle enable_muted_state"; RegisterDecoders(codecs); } NetEqTest::~NetEqTest() = default; int64_t NetEqTest::Run() { int64_t simulation_time = 0; SimulationStepResult step_result; do { step_result = RunToNextGetAudio(); simulation_time += step_result.simulation_step_ms; } while (!step_result.is_simulation_finished); if (callbacks_.simulation_ended_callback) { callbacks_.simulation_ended_callback->SimulationEnded(simulation_time, neteq_.get()); } return simulation_time; } NetEqTest::SimulationStepResult NetEqTest::RunToNextGetAudio() { SimulationStepResult result; const int64_t start_time_ms = *input_->NextEventTime(); int64_t time_now_ms = start_time_ms; current_state_.packet_iat_ms.clear(); while (!input_->ended()) { // Advance time to next event. RTC_DCHECK(input_->NextEventTime()); clock_.AdvanceTimeMilliseconds(*input_->NextEventTime() - time_now_ms); time_now_ms = *input_->NextEventTime(); // Check if it is time to insert packet. if (input_->NextPacketTime() && time_now_ms >= *input_->NextPacketTime()) { std::unique_ptr packet_data = input_->PopPacket(); RTC_CHECK(packet_data); const size_t payload_data_length = packet_data->payload.size() - packet_data->header.paddingLength; if (payload_data_length != 0) { int error = neteq_->InsertPacket( packet_data->header, rtc::ArrayView(packet_data->payload)); if (error != NetEq::kOK && callbacks_.error_callback) { callbacks_.error_callback->OnInsertPacketError(*packet_data); } if (callbacks_.post_insert_packet) { callbacks_.post_insert_packet->AfterInsertPacket(*packet_data, neteq_.get()); } } else { neteq_->InsertEmptyPacket(packet_data->header); } if (last_packet_time_ms_) { current_state_.packet_iat_ms.push_back(time_now_ms - *last_packet_time_ms_); } if (text_log_) { const auto ops_state = neteq_->GetOperationsAndState(); const auto delta_wallclock = last_packet_time_ms_ ? (time_now_ms - *last_packet_time_ms_) : -1; const auto delta_timestamp = last_packet_timestamp_ ? (static_cast(packet_data->header.timestamp) - *last_packet_timestamp_) * 1000 / sample_rate_hz_ : -1; const auto packet_size_bytes = packet_data->payload.size() == 12 ? ByteReader::ReadLittleEndian( &packet_data->payload[8]) : -1; *text_log_ << "Packet - wallclock: " << std::setw(5) << time_now_ms << ", delta wc: " << std::setw(4) << delta_wallclock << ", seq_no: " << packet_data->header.sequenceNumber << ", timestamp: " << std::setw(10) << packet_data->header.timestamp << ", delta ts: " << std::setw(4) << delta_timestamp << ", size: " << std::setw(5) << packet_size_bytes << ", frame size: " << std::setw(3) << ops_state.current_frame_size_ms << ", buffer size: " << std::setw(4) << ops_state.current_buffer_size_ms << std::endl; } last_packet_time_ms_ = absl::make_optional(time_now_ms); last_packet_timestamp_ = absl::make_optional(packet_data->header.timestamp); } // Check if it is time to get output audio. if (input_->NextOutputEventTime() && time_now_ms >= *input_->NextOutputEventTime()) { if (callbacks_.get_audio_callback) { callbacks_.get_audio_callback->BeforeGetAudio(neteq_.get()); } AudioFrame out_frame; bool muted; int error = neteq_->GetAudio(&out_frame, &muted, ActionToOperations(next_action_)); next_action_ = absl::nullopt; RTC_CHECK(!muted) << "The code does not handle enable_muted_state"; if (error != NetEq::kOK) { if (callbacks_.error_callback) { callbacks_.error_callback->OnGetAudioError(); } } else { sample_rate_hz_ = out_frame.sample_rate_hz_; } if (callbacks_.get_audio_callback) { callbacks_.get_audio_callback->AfterGetAudio(time_now_ms, out_frame, muted, neteq_.get()); } if (output_) { RTC_CHECK(output_->WriteArray( out_frame.data(), out_frame.samples_per_channel_ * out_frame.num_channels_)); } input_->AdvanceOutputEvent(); result.simulation_step_ms = input_->NextEventTime().value_or(time_now_ms) - start_time_ms; const auto operations_state = neteq_->GetOperationsAndState(); current_state_.current_delay_ms = operations_state.current_buffer_size_ms; current_state_.packet_size_ms = operations_state.current_frame_size_ms; current_state_.next_packet_available = operations_state.next_packet_available; current_state_.packet_buffer_flushed = operations_state.packet_buffer_flushes > prev_ops_state_.packet_buffer_flushes; // TODO(ivoc): Add more accurate reporting by tracking the origin of // samples in the sync buffer. result.action_times_ms[Action::kExpand] = 0; result.action_times_ms[Action::kAccelerate] = 0; result.action_times_ms[Action::kPreemptiveExpand] = 0; result.action_times_ms[Action::kNormal] = 0; if (out_frame.speech_type_ == AudioFrame::SpeechType::kPLC || out_frame.speech_type_ == AudioFrame::SpeechType::kPLCCNG) { // Consider the whole frame to be the result of expansion. result.action_times_ms[Action::kExpand] = 10; } else if (operations_state.accelerate_samples - prev_ops_state_.accelerate_samples > 0) { // Consider the whole frame to be the result of acceleration. result.action_times_ms[Action::kAccelerate] = 10; } else if (operations_state.preemptive_samples - prev_ops_state_.preemptive_samples > 0) { // Consider the whole frame to be the result of preemptive expansion. result.action_times_ms[Action::kPreemptiveExpand] = 10; } else { // Consider the whole frame to be the result of normal playout. result.action_times_ms[Action::kNormal] = 10; } auto lifetime_stats = LifetimeStats(); if (text_log_) { const bool plc = (out_frame.speech_type_ == AudioFrame::SpeechType::kPLC) || (out_frame.speech_type_ == AudioFrame::SpeechType::kPLCCNG); const bool cng = out_frame.speech_type_ == AudioFrame::SpeechType::kCNG; const bool voice_concealed = (lifetime_stats.concealed_samples - lifetime_stats.silent_concealed_samples) > (prev_lifetime_stats_.concealed_samples - prev_lifetime_stats_.silent_concealed_samples); *text_log_ << "GetAudio - wallclock: " << std::setw(5) << time_now_ms << ", delta wc: " << std::setw(4) << (input_->NextEventTime().value_or(time_now_ms) - start_time_ms) << ", CNG: " << cng << ", PLC: " << plc << ", voice concealed: " << voice_concealed << ", buffer size: " << std::setw(4) << current_state_.current_delay_ms << std::endl; if (operations_state.discarded_primary_packets > prev_ops_state_.discarded_primary_packets) { *text_log_ << "Discarded " << (operations_state.discarded_primary_packets - prev_ops_state_.discarded_primary_packets) << " primary packets." << std::endl; } if (operations_state.packet_buffer_flushes > prev_ops_state_.packet_buffer_flushes) { *text_log_ << "Flushed packet buffer " << (operations_state.packet_buffer_flushes - prev_ops_state_.packet_buffer_flushes) << " times." << std::endl; } } prev_lifetime_stats_ = lifetime_stats; const bool no_more_packets_to_decode = !input_->NextPacketTime() && !operations_state.next_packet_available; result.is_simulation_finished = no_more_packets_to_decode || input_->ended(); prev_ops_state_ = operations_state; return result; } } result.simulation_step_ms = input_->NextEventTime().value_or(time_now_ms) - start_time_ms; result.is_simulation_finished = true; return result; } void NetEqTest::SetNextAction(NetEqTest::Action next_operation) { next_action_ = absl::optional(next_operation); } NetEqTest::NetEqState NetEqTest::GetNetEqState() { return current_state_; } NetEqNetworkStatistics NetEqTest::SimulationStats() { NetEqNetworkStatistics stats; RTC_CHECK_EQ(neteq_->NetworkStatistics(&stats), 0); return stats; } NetEqLifetimeStatistics NetEqTest::LifetimeStats() const { return neteq_->GetLifetimeStatistics(); } NetEqTest::DecoderMap NetEqTest::StandardDecoderMap() { DecoderMap codecs = { {0, SdpAudioFormat("pcmu", 8000, 1)}, {8, SdpAudioFormat("pcma", 8000, 1)}, #ifdef WEBRTC_CODEC_ILBC {102, SdpAudioFormat("ilbc", 8000, 1)}, #endif {103, SdpAudioFormat("isac", 16000, 1)}, #if !defined(WEBRTC_ANDROID) {104, SdpAudioFormat("isac", 32000, 1)}, #endif #ifdef WEBRTC_CODEC_OPUS {111, SdpAudioFormat("opus", 48000, 2)}, #endif {93, SdpAudioFormat("l16", 8000, 1)}, {94, SdpAudioFormat("l16", 16000, 1)}, {95, SdpAudioFormat("l16", 32000, 1)}, {96, SdpAudioFormat("l16", 48000, 1)}, {9, SdpAudioFormat("g722", 8000, 1)}, {106, SdpAudioFormat("telephone-event", 8000, 1)}, {114, SdpAudioFormat("telephone-event", 16000, 1)}, {115, SdpAudioFormat("telephone-event", 32000, 1)}, {116, SdpAudioFormat("telephone-event", 48000, 1)}, {117, SdpAudioFormat("red", 8000, 1)}, {13, SdpAudioFormat("cn", 8000, 1)}, {98, SdpAudioFormat("cn", 16000, 1)}, {99, SdpAudioFormat("cn", 32000, 1)}, {100, SdpAudioFormat("cn", 48000, 1)} }; return codecs; } void NetEqTest::RegisterDecoders(const DecoderMap& codecs) { for (const auto& c : codecs) { RTC_CHECK(neteq_->RegisterPayloadType(c.first, c.second)) << "Cannot register " << c.second.name << " to payload type " << c.first; } } } // namespace test } // namespace webrtc