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webrtc / src / 2f042f26a3d0c062c43dc553058a286bd4dd8f19 / . / webrtc / modules / audio_processing / test / debug_dump_test.cc
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/*
* Copyright (c) 2015 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 <stddef.h> // size_t
#include <string>
#include <vector>
#include "testing/gtest/include/gtest/gtest.h"
#include "webrtc/audio_processing/debug.pb.h"
#include "webrtc/base/checks.h"
#include "webrtc/base/scoped_ptr.h"
#include "webrtc/common_audio/channel_buffer.h"
#include "webrtc/modules/audio_coding/neteq/tools/resample_input_audio_file.h"
#include "webrtc/modules/audio_processing/include/audio_processing.h"
#include "webrtc/modules/audio_processing/test/protobuf_utils.h"
#include "webrtc/modules/audio_processing/test/test_utils.h"
#include "webrtc/test/testsupport/fileutils.h"
namespace webrtc {
namespace test {
namespace {
void MaybeResetBuffer(rtc::scoped_ptr<ChannelBuffer<float>>* buffer,
const StreamConfig& config) {
auto& buffer_ref = *buffer;
if (!buffer_ref.get() || buffer_ref->num_frames() != config.num_frames() ||
buffer_ref->num_channels() != config.num_channels()) {
buffer_ref.reset(new ChannelBuffer<float>(config.num_frames(),
config.num_channels()));
}
}
class DebugDumpGenerator {
public:
DebugDumpGenerator(const std::string& input_file_name,
int input_file_rate_hz,
int input_channels,
const std::string& reverse_file_name,
int reverse_file_rate_hz,
int reverse_channels,
const Config& config,
const std::string& dump_file_name);
// Constructor that uses default input files.
explicit DebugDumpGenerator(const Config& config);
~DebugDumpGenerator();
// Changes the sample rate of the input audio to the APM.
void SetInputRate(int rate_hz);
// Sets if converts stereo input signal to mono by discarding other channels.
void ForceInputMono(bool mono);
// Changes the sample rate of the reverse audio to the APM.
void SetReverseRate(int rate_hz);
// Sets if converts stereo reverse signal to mono by discarding other
// channels.
void ForceReverseMono(bool mono);
// Sets the required sample rate of the APM output.
void SetOutputRate(int rate_hz);
// Sets the required channels of the APM output.
void SetOutputChannels(int channels);
std::string dump_file_name() const { return dump_file_name_; }
void StartRecording();
void Process(size_t num_blocks);
void StopRecording();
AudioProcessing* apm() const { return apm_.get(); }
private:
static void ReadAndDeinterleave(ResampleInputAudioFile* audio, int channels,
const StreamConfig& config,
float* const* buffer);
// APM input/output settings.
StreamConfig input_config_;
StreamConfig reverse_config_;
StreamConfig output_config_;
// Input file format.
const std::string input_file_name_;
ResampleInputAudioFile input_audio_;
const int input_file_channels_;
// Reverse file format.
const std::string reverse_file_name_;
ResampleInputAudioFile reverse_audio_;
const int reverse_file_channels_;
// Buffer for APM input/output.
rtc::scoped_ptr<ChannelBuffer<float>> input_;
rtc::scoped_ptr<ChannelBuffer<float>> reverse_;
rtc::scoped_ptr<ChannelBuffer<float>> output_;
rtc::scoped_ptr<AudioProcessing> apm_;
const std::string dump_file_name_;
};
DebugDumpGenerator::DebugDumpGenerator(const std::string& input_file_name,
int input_rate_hz,
int input_channels,
const std::string& reverse_file_name,
int reverse_rate_hz,
int reverse_channels,
const Config& config,
const std::string& dump_file_name)
: input_config_(input_rate_hz, input_channels),
reverse_config_(reverse_rate_hz, reverse_channels),
output_config_(input_rate_hz, input_channels),
input_audio_(input_file_name, input_rate_hz, input_rate_hz),
input_file_channels_(input_channels),
reverse_audio_(reverse_file_name, reverse_rate_hz, reverse_rate_hz),
reverse_file_channels_(reverse_channels),
input_(new ChannelBuffer<float>(input_config_.num_frames(),
input_config_.num_channels())),
reverse_(new ChannelBuffer<float>(reverse_config_.num_frames(),
reverse_config_.num_channels())),
output_(new ChannelBuffer<float>(output_config_.num_frames(),
output_config_.num_channels())),
apm_(AudioProcessing::Create(config)),
dump_file_name_(dump_file_name) {
}
DebugDumpGenerator::DebugDumpGenerator(const Config& config)
: DebugDumpGenerator(ResourcePath("near32_stereo", "pcm"), 32000, 2,
ResourcePath("far32_stereo", "pcm"), 32000, 2,
config,
TempFilename(OutputPath(), "debug_aec")) {
}
DebugDumpGenerator::~DebugDumpGenerator() {
remove(dump_file_name_.c_str());
}
void DebugDumpGenerator::SetInputRate(int rate_hz) {
input_audio_.set_output_rate_hz(rate_hz);
input_config_.set_sample_rate_hz(rate_hz);
MaybeResetBuffer(&input_, input_config_);
}
void DebugDumpGenerator::ForceInputMono(bool mono) {
const int channels = mono ? 1 : input_file_channels_;
input_config_.set_num_channels(channels);
MaybeResetBuffer(&input_, input_config_);
}
void DebugDumpGenerator::SetReverseRate(int rate_hz) {
reverse_audio_.set_output_rate_hz(rate_hz);
reverse_config_.set_sample_rate_hz(rate_hz);
MaybeResetBuffer(&reverse_, reverse_config_);
}
void DebugDumpGenerator::ForceReverseMono(bool mono) {
const int channels = mono ? 1 : reverse_file_channels_;
reverse_config_.set_num_channels(channels);
MaybeResetBuffer(&reverse_, reverse_config_);
}
void DebugDumpGenerator::SetOutputRate(int rate_hz) {
output_config_.set_sample_rate_hz(rate_hz);
MaybeResetBuffer(&output_, output_config_);
}
void DebugDumpGenerator::SetOutputChannels(int channels) {
output_config_.set_num_channels(channels);
MaybeResetBuffer(&output_, output_config_);
}
void DebugDumpGenerator::StartRecording() {
apm_->StartDebugRecording(dump_file_name_.c_str());
}
void DebugDumpGenerator::Process(size_t num_blocks) {
for (size_t i = 0; i < num_blocks; ++i) {
ReadAndDeinterleave(&reverse_audio_, reverse_file_channels_,
reverse_config_, reverse_->channels());
ReadAndDeinterleave(&input_audio_, input_file_channels_, input_config_,
input_->channels());
RTC_CHECK_EQ(AudioProcessing::kNoError, apm_->set_stream_delay_ms(100));
apm_->set_stream_key_pressed(i % 10 == 9);
RTC_CHECK_EQ(AudioProcessing::kNoError,
apm_->ProcessStream(input_->channels(), input_config_,
output_config_, output_->channels()));
RTC_CHECK_EQ(AudioProcessing::kNoError,
apm_->ProcessReverseStream(reverse_->channels(),
reverse_config_,
reverse_config_,
reverse_->channels()));
}
}
void DebugDumpGenerator::StopRecording() {
apm_->StopDebugRecording();
}
void DebugDumpGenerator::ReadAndDeinterleave(ResampleInputAudioFile* audio,
int channels,
const StreamConfig& config,
float* const* buffer) {
const size_t num_frames = config.num_frames();
const int out_channels = config.num_channels();
std::vector<int16_t> signal(channels * num_frames);
audio->Read(num_frames * channels, &signal[0]);
// We only allow reducing number of channels by discarding some channels.
RTC_CHECK_LE(out_channels, channels);
for (int channel = 0; channel < out_channels; ++channel) {
for (size_t i = 0; i < num_frames; ++i) {
buffer[channel][i] = S16ToFloat(signal[i * channels + channel]);
}
}
}
} // namespace
class DebugDumpTest : public ::testing::Test {
public:
DebugDumpTest();
// VerifyDebugDump replays a debug dump using APM and verifies that the result
// is bit-exact-identical to the output channel in the dump. This is only
// guaranteed if the debug dump is started on the first frame.
void VerifyDebugDump(const std::string& dump_file_name);
private:
// Following functions are facilities for replaying debug dumps.
void OnInitEvent(const audioproc::Init& msg);
void OnStreamEvent(const audioproc::Stream& msg);
void OnReverseStreamEvent(const audioproc::ReverseStream& msg);
void OnConfigEvent(const audioproc::Config& msg);
void MaybeRecreateApm(const audioproc::Config& msg);
void ConfigureApm(const audioproc::Config& msg);
// Buffer for APM input/output.
rtc::scoped_ptr<ChannelBuffer<float>> input_;
rtc::scoped_ptr<ChannelBuffer<float>> reverse_;
rtc::scoped_ptr<ChannelBuffer<float>> output_;
rtc::scoped_ptr<AudioProcessing> apm_;
StreamConfig input_config_;
StreamConfig reverse_config_;
StreamConfig output_config_;
};
DebugDumpTest::DebugDumpTest()
: input_(nullptr), // will be created upon usage.
reverse_(nullptr),
output_(nullptr),
apm_(nullptr) {
}
void DebugDumpTest::VerifyDebugDump(const std::string& in_filename) {
FILE* in_file = fopen(in_filename.c_str(), "rb");
ASSERT_TRUE(in_file);
audioproc::Event event_msg;
while (ReadMessageFromFile(in_file, &event_msg)) {
switch (event_msg.type()) {
case audioproc::Event::INIT:
OnInitEvent(event_msg.init());
break;
case audioproc::Event::STREAM:
OnStreamEvent(event_msg.stream());
break;
case audioproc::Event::REVERSE_STREAM:
OnReverseStreamEvent(event_msg.reverse_stream());
break;
case audioproc::Event::CONFIG:
OnConfigEvent(event_msg.config());
break;
case audioproc::Event::UNKNOWN_EVENT:
// We do not expect receive UNKNOWN event currently.
FAIL();
}
}
fclose(in_file);
}
// OnInitEvent reset the input/output/reserve channel format.
void DebugDumpTest::OnInitEvent(const audioproc::Init& msg) {
ASSERT_TRUE(msg.has_num_input_channels());
ASSERT_TRUE(msg.has_output_sample_rate());
ASSERT_TRUE(msg.has_num_output_channels());
ASSERT_TRUE(msg.has_reverse_sample_rate());
ASSERT_TRUE(msg.has_num_reverse_channels());
input_config_ = StreamConfig(msg.sample_rate(), msg.num_input_channels());
output_config_ =
StreamConfig(msg.output_sample_rate(), msg.num_output_channels());
reverse_config_ =
StreamConfig(msg.reverse_sample_rate(), msg.num_reverse_channels());
MaybeResetBuffer(&input_, input_config_);
MaybeResetBuffer(&output_, output_config_);
MaybeResetBuffer(&reverse_, reverse_config_);
}
// OnStreamEvent replays an input signal and verifies the output.
void DebugDumpTest::OnStreamEvent(const audioproc::Stream& msg) {
// APM should have been created.
ASSERT_TRUE(apm_.get());
EXPECT_NOERR(apm_->gain_control()->set_stream_analog_level(msg.level()));
EXPECT_NOERR(apm_->set_stream_delay_ms(msg.delay()));
apm_->echo_cancellation()->set_stream_drift_samples(msg.drift());
if (msg.has_keypress())
apm_->set_stream_key_pressed(msg.keypress());
else
apm_->set_stream_key_pressed(true);
ASSERT_EQ(input_config_.num_channels(), msg.input_channel_size());
ASSERT_EQ(input_config_.num_frames() * sizeof(float),
msg.input_channel(0).size());
for (int i = 0; i < msg.input_channel_size(); ++i) {
memcpy(input_->channels()[i], msg.input_channel(i).data(),
msg.input_channel(i).size());
}
ASSERT_EQ(AudioProcessing::kNoError,
apm_->ProcessStream(input_->channels(), input_config_,
output_config_, output_->channels()));
// Check that output of APM is bit-exact to the output in the dump.
ASSERT_EQ(output_config_.num_channels(), msg.output_channel_size());
ASSERT_EQ(output_config_.num_frames() * sizeof(float),
msg.output_channel(0).size());
for (int i = 0; i < msg.output_channel_size(); ++i) {
ASSERT_EQ(0, memcmp(output_->channels()[i], msg.output_channel(i).data(),
msg.output_channel(i).size()));
}
}
void DebugDumpTest::OnReverseStreamEvent(const audioproc::ReverseStream& msg) {
// APM should have been created.
ASSERT_TRUE(apm_.get());
ASSERT_GT(msg.channel_size(), 0);
ASSERT_EQ(reverse_config_.num_channels(), msg.channel_size());
ASSERT_EQ(reverse_config_.num_frames() * sizeof(float),
msg.channel(0).size());
for (int i = 0; i < msg.channel_size(); ++i) {
memcpy(reverse_->channels()[i], msg.channel(i).data(),
msg.channel(i).size());
}
ASSERT_EQ(AudioProcessing::kNoError,
apm_->ProcessReverseStream(reverse_->channels(),
reverse_config_,
reverse_config_,
reverse_->channels()));
}
void DebugDumpTest::OnConfigEvent(const audioproc::Config& msg) {
MaybeRecreateApm(msg);
ConfigureApm(msg);
}
void DebugDumpTest::MaybeRecreateApm(const audioproc::Config& msg) {
// These configurations cannot be changed on the fly.
Config config;
ASSERT_TRUE(msg.has_aec_delay_agnostic_enabled());
config.Set<DelayAgnostic>(
new DelayAgnostic(msg.aec_delay_agnostic_enabled()));
ASSERT_TRUE(msg.has_noise_robust_agc_enabled());
config.Set<ExperimentalAgc>(
new ExperimentalAgc(msg.noise_robust_agc_enabled()));
ASSERT_TRUE(msg.has_transient_suppression_enabled());
config.Set<ExperimentalNs>(
new ExperimentalNs(msg.transient_suppression_enabled()));
ASSERT_TRUE(msg.has_aec_extended_filter_enabled());
config.Set<ExtendedFilter>(new ExtendedFilter(
msg.aec_extended_filter_enabled()));
// We only create APM once, since changes on these fields should not
// happen in current implementation.
if (!apm_.get()) {
apm_.reset(AudioProcessing::Create(config));
}
}
void DebugDumpTest::ConfigureApm(const audioproc::Config& msg) {
// AEC configs.
ASSERT_TRUE(msg.has_aec_enabled());
EXPECT_EQ(AudioProcessing::kNoError,
apm_->echo_cancellation()->Enable(msg.aec_enabled()));
ASSERT_TRUE(msg.has_aec_drift_compensation_enabled());
EXPECT_EQ(AudioProcessing::kNoError,
apm_->echo_cancellation()->enable_drift_compensation(
msg.aec_drift_compensation_enabled()));
ASSERT_TRUE(msg.has_aec_suppression_level());
EXPECT_EQ(AudioProcessing::kNoError,
apm_->echo_cancellation()->set_suppression_level(
static_cast<EchoCancellation::SuppressionLevel>(
msg.aec_suppression_level())));
// AECM configs.
ASSERT_TRUE(msg.has_aecm_enabled());
EXPECT_EQ(AudioProcessing::kNoError,
apm_->echo_control_mobile()->Enable(msg.aecm_enabled()));
ASSERT_TRUE(msg.has_aecm_comfort_noise_enabled());
EXPECT_EQ(AudioProcessing::kNoError,
apm_->echo_control_mobile()->enable_comfort_noise(
msg.aecm_comfort_noise_enabled()));
ASSERT_TRUE(msg.has_aecm_routing_mode());
EXPECT_EQ(AudioProcessing::kNoError,
apm_->echo_control_mobile()->set_routing_mode(
static_cast<EchoControlMobile::RoutingMode>(
msg.aecm_routing_mode())));
// AGC configs.
ASSERT_TRUE(msg.has_agc_enabled());
EXPECT_EQ(AudioProcessing::kNoError,
apm_->gain_control()->Enable(msg.agc_enabled()));
ASSERT_TRUE(msg.has_agc_mode());
EXPECT_EQ(AudioProcessing::kNoError,
apm_->gain_control()->set_mode(
static_cast<GainControl::Mode>(msg.agc_mode())));
ASSERT_TRUE(msg.has_agc_limiter_enabled());
EXPECT_EQ(AudioProcessing::kNoError,
apm_->gain_control()->enable_limiter(msg.agc_limiter_enabled()));
// HPF configs.
ASSERT_TRUE(msg.has_hpf_enabled());
EXPECT_EQ(AudioProcessing::kNoError,
apm_->high_pass_filter()->Enable(msg.hpf_enabled()));
// NS configs.
ASSERT_TRUE(msg.has_ns_enabled());
EXPECT_EQ(AudioProcessing::kNoError,
apm_->noise_suppression()->Enable(msg.ns_enabled()));
ASSERT_TRUE(msg.has_ns_level());
EXPECT_EQ(AudioProcessing::kNoError,
apm_->noise_suppression()->set_level(
static_cast<NoiseSuppression::Level>(msg.ns_level())));
}
TEST_F(DebugDumpTest, SimpleCase) {
Config config;
DebugDumpGenerator generator(config);
generator.StartRecording();
generator.Process(100);
generator.StopRecording();
VerifyDebugDump(generator.dump_file_name());
}
TEST_F(DebugDumpTest, ChangeInputFormat) {
Config config;
DebugDumpGenerator generator(config);
generator.StartRecording();
generator.Process(100);
generator.SetInputRate(48000);
generator.ForceInputMono(true);
// Number of output channel should not be larger than that of input. APM will
// fail otherwise.
generator.SetOutputChannels(1);
generator.Process(100);
generator.StopRecording();
VerifyDebugDump(generator.dump_file_name());
}
TEST_F(DebugDumpTest, ChangeReverseFormat) {
Config config;
DebugDumpGenerator generator(config);
generator.StartRecording();
generator.Process(100);
generator.SetReverseRate(48000);
generator.ForceReverseMono(true);
generator.Process(100);
generator.StopRecording();
VerifyDebugDump(generator.dump_file_name());
}
TEST_F(DebugDumpTest, ChangeOutputFormat) {
Config config;
DebugDumpGenerator generator(config);
generator.StartRecording();
generator.Process(100);
generator.SetOutputRate(48000);
generator.SetOutputChannels(1);
generator.Process(100);
generator.StopRecording();
VerifyDebugDump(generator.dump_file_name());
}
TEST_F(DebugDumpTest, ToggleAec) {
Config config;
DebugDumpGenerator generator(config);
generator.StartRecording();
generator.Process(100);
EchoCancellation* aec = generator.apm()->echo_cancellation();
EXPECT_EQ(AudioProcessing::kNoError, aec->Enable(!aec->is_enabled()));
generator.Process(100);
generator.StopRecording();
VerifyDebugDump(generator.dump_file_name());
}
TEST_F(DebugDumpTest, ToggleDelayAgnosticAec) {
Config config;
config.Set<DelayAgnostic>(new DelayAgnostic(true));
DebugDumpGenerator generator(config);
generator.StartRecording();
generator.Process(100);
EchoCancellation* aec = generator.apm()->echo_cancellation();
EXPECT_EQ(AudioProcessing::kNoError, aec->Enable(!aec->is_enabled()));
generator.Process(100);
generator.StopRecording();
VerifyDebugDump(generator.dump_file_name());
}
TEST_F(DebugDumpTest, ToggleAecLevel) {
Config config;
DebugDumpGenerator generator(config);
EchoCancellation* aec = generator.apm()->echo_cancellation();
EXPECT_EQ(AudioProcessing::kNoError, aec->Enable(true));
EXPECT_EQ(AudioProcessing::kNoError,
aec->set_suppression_level(EchoCancellation::kLowSuppression));
generator.StartRecording();
generator.Process(100);
EXPECT_EQ(AudioProcessing::kNoError,
aec->set_suppression_level(EchoCancellation::kHighSuppression));
generator.Process(100);
generator.StopRecording();
VerifyDebugDump(generator.dump_file_name());
}
#if defined(WEBRTC_ANDROID)
// AGC may not be supported on Android.
#define MAYBE_ToggleAgc DISABLED_ToggleAgc
#else
#define MAYBE_ToggleAgc ToggleAgc
#endif
TEST_F(DebugDumpTest, MAYBE_ToggleAgc) {
Config config;
DebugDumpGenerator generator(config);
generator.StartRecording();
generator.Process(100);
GainControl* agc = generator.apm()->gain_control();
EXPECT_EQ(AudioProcessing::kNoError, agc->Enable(!agc->is_enabled()));
generator.Process(100);
generator.StopRecording();
VerifyDebugDump(generator.dump_file_name());
}
TEST_F(DebugDumpTest, ToggleNs) {
Config config;
DebugDumpGenerator generator(config);
generator.StartRecording();
generator.Process(100);
NoiseSuppression* ns = generator.apm()->noise_suppression();
EXPECT_EQ(AudioProcessing::kNoError, ns->Enable(!ns->is_enabled()));
generator.Process(100);
generator.StopRecording();
VerifyDebugDump(generator.dump_file_name());
}
TEST_F(DebugDumpTest, TransientSuppressionOn) {
Config config;
config.Set<ExperimentalNs>(new ExperimentalNs(true));
DebugDumpGenerator generator(config);
generator.StartRecording();
generator.Process(100);
generator.StopRecording();
VerifyDebugDump(generator.dump_file_name());
}
} // namespace test
} // namespace webrtc