/* * Copyright (c) 2018 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. */ // Test to verify correct operation when using the decoder-internal PLC. #include #include #include #include "absl/types/optional.h" #include "modules/audio_coding/codecs/pcm16b/audio_encoder_pcm16b.h" #include "modules/audio_coding/neteq/tools/audio_checksum.h" #include "modules/audio_coding/neteq/tools/audio_sink.h" #include "modules/audio_coding/neteq/tools/encode_neteq_input.h" #include "modules/audio_coding/neteq/tools/fake_decode_from_file.h" #include "modules/audio_coding/neteq/tools/input_audio_file.h" #include "modules/audio_coding/neteq/tools/neteq_test.h" #include "rtc_base/numerics/safe_conversions.h" #include "test/audio_decoder_proxy_factory.h" #include "test/gtest.h" #include "test/testsupport/file_utils.h" namespace webrtc { namespace test { namespace { constexpr int kSampleRateHz = 32000; constexpr int kRunTimeMs = 10000; // This class implements a fake decoder. The decoder will read audio from a file // and present as output, both for regular decoding and for PLC. class AudioDecoderPlc : public AudioDecoder { public: AudioDecoderPlc(std::unique_ptr input, int sample_rate_hz) : input_(std::move(input)), sample_rate_hz_(sample_rate_hz) {} void Reset() override {} int SampleRateHz() const override { return sample_rate_hz_; } size_t Channels() const override { return 1; } int DecodeInternal(const uint8_t* /*encoded*/, size_t encoded_len, int sample_rate_hz, int16_t* decoded, SpeechType* speech_type) override { RTC_CHECK_GE(encoded_len / 2, 10 * sample_rate_hz_ / 1000); RTC_CHECK_LE(encoded_len / 2, 2 * 10 * sample_rate_hz_ / 1000); RTC_CHECK_EQ(sample_rate_hz, sample_rate_hz_); RTC_CHECK(decoded); RTC_CHECK(speech_type); RTC_CHECK(input_->Read(encoded_len / 2, decoded)); *speech_type = kSpeech; last_was_plc_ = false; return encoded_len / 2; } void GeneratePlc(size_t requested_samples_per_channel, rtc::BufferT* concealment_audio) override { // Instead of generating random data for GeneratePlc we use the same data as // the input, so we can check that we produce the same result independently // of the losses. RTC_DCHECK_EQ(requested_samples_per_channel, 10 * sample_rate_hz_ / 1000); // Must keep a local copy of this since DecodeInternal sets it to false. const bool last_was_plc = last_was_plc_; std::vector decoded(5760); SpeechType speech_type; int dec_len = DecodeInternal(nullptr, 2 * 10 * sample_rate_hz_ / 1000, sample_rate_hz_, decoded.data(), &speech_type); concealment_audio->AppendData(decoded.data(), dec_len); concealed_samples_ += rtc::checked_cast(dec_len); if (!last_was_plc) { ++concealment_events_; } last_was_plc_ = true; } size_t concealed_samples() { return concealed_samples_; } size_t concealment_events() { return concealment_events_; } private: const std::unique_ptr input_; const int sample_rate_hz_; size_t concealed_samples_ = 0; size_t concealment_events_ = 0; bool last_was_plc_ = false; }; // An input sample generator which generates only zero-samples. class ZeroSampleGenerator : public EncodeNetEqInput::Generator { public: rtc::ArrayView Generate(size_t num_samples) override { vec.resize(num_samples, 0); rtc::ArrayView view(vec); RTC_DCHECK_EQ(view.size(), num_samples); return view; } private: std::vector vec; }; // A NetEqInput which connects to another NetEqInput, but drops a number of // consecutive packets on the way class LossyInput : public NetEqInput { public: LossyInput(int loss_cadence, int burst_length, std::unique_ptr input) : loss_cadence_(loss_cadence), burst_length_(burst_length), input_(std::move(input)) {} absl::optional NextPacketTime() const override { return input_->NextPacketTime(); } absl::optional NextOutputEventTime() const override { return input_->NextOutputEventTime(); } std::unique_ptr PopPacket() override { if (loss_cadence_ != 0 && (++count_ % loss_cadence_) == 0) { // Pop `burst_length_` packets to create the loss. auto packet_to_return = input_->PopPacket(); for (int i = 0; i < burst_length_; i++) { input_->PopPacket(); } return packet_to_return; } return input_->PopPacket(); } void AdvanceOutputEvent() override { return input_->AdvanceOutputEvent(); } bool ended() const override { return input_->ended(); } absl::optional NextHeader() const override { return input_->NextHeader(); } private: const int loss_cadence_; const int burst_length_; int count_ = 0; const std::unique_ptr input_; }; class AudioChecksumWithOutput : public AudioChecksum { public: explicit AudioChecksumWithOutput(std::string* output_str) : output_str_(*output_str) {} ~AudioChecksumWithOutput() { output_str_ = Finish(); } private: std::string& output_str_; }; struct TestStatistics { NetEqNetworkStatistics network; NetEqLifetimeStatistics lifetime; }; TestStatistics RunTest(int loss_cadence, int burst_length, std::string* checksum) { NetEq::Config config; config.for_test_no_time_stretching = true; // The input is mostly useless. It sends zero-samples to a PCM16b encoder, // but the actual encoded samples will never be used by the decoder in the // test. See below about the decoder. auto generator = std::make_unique(); constexpr int kPayloadType = 100; AudioEncoderPcm16B::Config encoder_config; encoder_config.sample_rate_hz = kSampleRateHz; encoder_config.payload_type = kPayloadType; auto encoder = std::make_unique(encoder_config); auto input = std::make_unique( std::move(generator), std::move(encoder), kRunTimeMs); // Wrap the input in a loss function. auto lossy_input = std::make_unique(loss_cadence, burst_length, std::move(input)); // Setting up decoders. NetEqTest::DecoderMap decoders; // Using a fake decoder which simply reads the output audio from a file. auto input_file = std::make_unique( webrtc::test::ResourcePath("audio_coding/testfile32kHz", "pcm")); AudioDecoderPlc dec(std::move(input_file), kSampleRateHz); // Masquerading as a PCM16b decoder. decoders.emplace(kPayloadType, SdpAudioFormat("l16", 32000, 1)); // Output is simply a checksum calculator. auto output = std::make_unique(checksum); // No callback objects. NetEqTest::Callbacks callbacks; NetEqTest neteq_test( config, /*decoder_factory=*/ rtc::make_ref_counted(&dec), /*codecs=*/decoders, /*text_log=*/nullptr, /*neteq_factory=*/nullptr, /*input=*/std::move(lossy_input), std::move(output), callbacks); EXPECT_LE(kRunTimeMs, neteq_test.Run()); auto lifetime_stats = neteq_test.LifetimeStats(); EXPECT_EQ(dec.concealed_samples(), lifetime_stats.concealed_samples); EXPECT_EQ(dec.concealment_events(), lifetime_stats.concealment_events); return {neteq_test.SimulationStats(), neteq_test.LifetimeStats()}; } } // namespace // Check that some basic metrics are produced in the right direction. In // particular, expand_rate should only increase if there are losses present. Our // dummy decoder is designed such as the checksum should always be the same // regardless of the losses given that calls are executed in the right order. TEST(NetEqDecoderPlc, BasicMetrics) { std::string checksum; // Drop 1 packet every 10 packets. auto stats = RunTest(10, 1, &checksum); std::string checksum_no_loss; auto stats_no_loss = RunTest(0, 0, &checksum_no_loss); EXPECT_EQ(checksum, checksum_no_loss); EXPECT_EQ(stats.network.preemptive_rate, stats_no_loss.network.preemptive_rate); EXPECT_EQ(stats.network.accelerate_rate, stats_no_loss.network.accelerate_rate); EXPECT_EQ(0, stats_no_loss.network.expand_rate); EXPECT_GT(stats.network.expand_rate, 0); } // Checks that interruptions are not counted in small losses but they are // correctly counted in long interruptions. TEST(NetEqDecoderPlc, CountInterruptions) { std::string checksum; std::string checksum_2; std::string checksum_3; // Half of the packets lost but in short interruptions. auto stats_no_interruptions = RunTest(1, 1, &checksum); // One lost of 500 ms (250 packets). auto stats_one_interruption = RunTest(200, 250, &checksum_2); // Two losses of 250ms each (125 packets). auto stats_two_interruptions = RunTest(125, 125, &checksum_3); EXPECT_EQ(checksum, checksum_2); EXPECT_EQ(checksum, checksum_3); EXPECT_GT(stats_no_interruptions.network.expand_rate, 0); EXPECT_EQ(stats_no_interruptions.lifetime.total_interruption_duration_ms, 0); EXPECT_EQ(stats_no_interruptions.lifetime.interruption_count, 0); EXPECT_GT(stats_one_interruption.network.expand_rate, 0); EXPECT_EQ(stats_one_interruption.lifetime.total_interruption_duration_ms, 5000); EXPECT_EQ(stats_one_interruption.lifetime.interruption_count, 1); EXPECT_GT(stats_two_interruptions.network.expand_rate, 0); EXPECT_EQ(stats_two_interruptions.lifetime.total_interruption_duration_ms, 5000); EXPECT_EQ(stats_two_interruptions.lifetime.interruption_count, 2); } // Checks that small losses do not produce interruptions. TEST(NetEqDecoderPlc, NoInterruptionsInSmallLosses) { std::string checksum_1; std::string checksum_4; auto stats_1 = RunTest(300, 1, &checksum_1); auto stats_4 = RunTest(300, 4, &checksum_4); EXPECT_EQ(checksum_1, checksum_4); EXPECT_EQ(stats_1.lifetime.interruption_count, 0); EXPECT_EQ(stats_1.lifetime.total_interruption_duration_ms, 0); EXPECT_EQ(stats_1.lifetime.concealed_samples, 640u); // 20ms of concealment. EXPECT_EQ(stats_1.lifetime.concealment_events, 1u); // in just one event. EXPECT_EQ(stats_4.lifetime.interruption_count, 0); EXPECT_EQ(stats_4.lifetime.total_interruption_duration_ms, 0); EXPECT_EQ(stats_4.lifetime.concealed_samples, 2560u); // 80ms of concealment. EXPECT_EQ(stats_4.lifetime.concealment_events, 1u); // in just one event. } // Checks that interruptions of different sizes report correct duration. TEST(NetEqDecoderPlc, InterruptionsReportCorrectSize) { std::string checksum; for (int burst_length = 5; burst_length < 10; burst_length++) { auto stats = RunTest(300, burst_length, &checksum); auto duration = stats.lifetime.total_interruption_duration_ms; if (burst_length < 8) { EXPECT_EQ(duration, 0); } else { EXPECT_EQ(duration, burst_length * 20); } } } } // namespace test } // namespace webrtc