blob: 8e0c01587f57bd50c08b18330a8ef10924e35043 [file] [log] [blame]
/* Copyright (c) 2014 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/video_coding/timing/jitter_estimator.h"
#include <stdint.h>
#include <memory>
#include <string>
#include <utility>
#include <vector>
#include "absl/types/optional.h"
#include "api/array_view.h"
#include "api/field_trials.h"
#include "api/units/data_size.h"
#include "api/units/frequency.h"
#include "api/units/time_delta.h"
#include "rtc_base/numerics/histogram_percentile_counter.h"
#include "rtc_base/time_utils.h"
#include "system_wrappers/include/clock.h"
#include "test/gtest.h"
namespace webrtc {
namespace {
// Generates some simple test data in the form of a sawtooth wave.
class ValueGenerator {
public:
explicit ValueGenerator(int32_t amplitude)
: amplitude_(amplitude), counter_(0) {}
virtual ~ValueGenerator() = default;
TimeDelta Delay() const {
return TimeDelta::Millis((counter_ % 11) - 5) * amplitude_;
}
DataSize FrameSize() const {
return DataSize::Bytes(1000 + Delay().ms() / 5);
}
void Advance() { ++counter_; }
private:
const int32_t amplitude_;
int64_t counter_;
};
class JitterEstimatorTest : public ::testing::Test {
protected:
explicit JitterEstimatorTest(const std::string& field_trials)
: fake_clock_(0),
field_trials_(FieldTrials::CreateNoGlobal(field_trials)),
estimator_(&fake_clock_, *field_trials_) {}
JitterEstimatorTest() : JitterEstimatorTest("") {}
virtual ~JitterEstimatorTest() {}
void Run(int duration_s, int framerate_fps, ValueGenerator& gen) {
TimeDelta tick = 1 / Frequency::Hertz(framerate_fps);
for (int i = 0; i < duration_s * framerate_fps; ++i) {
estimator_.UpdateEstimate(gen.Delay(), gen.FrameSize());
fake_clock_.AdvanceTime(tick);
gen.Advance();
}
}
SimulatedClock fake_clock_;
std::unique_ptr<FieldTrials> field_trials_;
JitterEstimator estimator_;
};
TEST_F(JitterEstimatorTest, SteadyStateConvergence) {
ValueGenerator gen(10);
Run(/*duration_s=*/60, /*framerate_fps=*/30, gen);
EXPECT_EQ(estimator_.GetJitterEstimate(0, absl::nullopt).ms(), 54);
}
TEST_F(JitterEstimatorTest,
SizeOutlierIsNotRejectedAndIncreasesJitterEstimate) {
ValueGenerator gen(10);
// Steady state.
Run(/*duration_s=*/60, /*framerate_fps=*/30, gen);
TimeDelta steady_state_jitter =
estimator_.GetJitterEstimate(0, absl::nullopt);
// A single outlier frame size...
estimator_.UpdateEstimate(gen.Delay(), 10 * gen.FrameSize());
TimeDelta outlier_jitter = estimator_.GetJitterEstimate(0, absl::nullopt);
// ...changes the estimate.
EXPECT_GT(outlier_jitter.ms(), 1.25 * steady_state_jitter.ms());
}
TEST_F(JitterEstimatorTest, LowFramerateDisablesJitterEstimator) {
ValueGenerator gen(10);
// At 5 fps, we disable jitter delay altogether.
TimeDelta time_delta = 1 / Frequency::Hertz(5);
for (int i = 0; i < 60; ++i) {
estimator_.UpdateEstimate(gen.Delay(), gen.FrameSize());
fake_clock_.AdvanceTime(time_delta);
if (i > 2)
EXPECT_EQ(estimator_.GetJitterEstimate(0, absl::nullopt),
TimeDelta::Zero());
gen.Advance();
}
}
TEST_F(JitterEstimatorTest, RttMultAddCap) {
std::vector<std::pair<TimeDelta, rtc::HistogramPercentileCounter>>
jitter_by_rtt_mult_cap;
jitter_by_rtt_mult_cap.emplace_back(
/*rtt_mult_add_cap=*/TimeDelta::Millis(10), /*long_tail_boundary=*/1000);
jitter_by_rtt_mult_cap.emplace_back(
/*rtt_mult_add_cap=*/TimeDelta::Millis(200), /*long_tail_boundary=*/1000);
for (auto& [rtt_mult_add_cap, jitter] : jitter_by_rtt_mult_cap) {
estimator_.Reset();
ValueGenerator gen(50);
TimeDelta time_delta = 1 / Frequency::Hertz(30);
constexpr TimeDelta kRtt = TimeDelta::Millis(250);
for (int i = 0; i < 100; ++i) {
estimator_.UpdateEstimate(gen.Delay(), gen.FrameSize());
fake_clock_.AdvanceTime(time_delta);
estimator_.FrameNacked();
estimator_.UpdateRtt(kRtt);
jitter.Add(
estimator_.GetJitterEstimate(/*rtt_mult=*/1.0, rtt_mult_add_cap)
.ms());
gen.Advance();
}
}
// 200ms cap should result in at least 25% higher max compared to 10ms.
EXPECT_GT(*jitter_by_rtt_mult_cap[1].second.GetPercentile(1.0),
*jitter_by_rtt_mult_cap[0].second.GetPercentile(1.0) * 1.25);
}
// By default, the `JitterEstimator` is not robust against single large frames.
TEST_F(JitterEstimatorTest, Single2xFrameSizeImpactsJitterEstimate) {
ValueGenerator gen(10);
// Steady state.
Run(/*duration_s=*/60, /*framerate_fps=*/30, gen);
TimeDelta steady_state_jitter =
estimator_.GetJitterEstimate(0, absl::nullopt);
// A single outlier frame size...
estimator_.UpdateEstimate(gen.Delay(), 2 * gen.FrameSize());
TimeDelta outlier_jitter = estimator_.GetJitterEstimate(0, absl::nullopt);
// ...impacts the estimate.
EXPECT_GT(outlier_jitter.ms(), steady_state_jitter.ms());
}
// Under the default config, congested frames are used when calculating the
// noise variance, meaning that they will impact the final jitter estimate.
TEST_F(JitterEstimatorTest, CongestedFrameImpactsJitterEstimate) {
ValueGenerator gen(10);
// Steady state.
Run(/*duration_s=*/10, /*framerate_fps=*/30, gen);
TimeDelta steady_state_jitter =
estimator_.GetJitterEstimate(0, absl::nullopt);
// Congested frame...
estimator_.UpdateEstimate(-10 * gen.Delay(), 0.1 * gen.FrameSize());
TimeDelta outlier_jitter = estimator_.GetJitterEstimate(0, absl::nullopt);
// ...impacts the estimate.
EXPECT_GT(outlier_jitter.ms(), steady_state_jitter.ms());
}
TEST_F(JitterEstimatorTest, EmptyFieldTrialsParsesToUnsetConfig) {
JitterEstimator::Config config = estimator_.GetConfigForTest();
EXPECT_FALSE(config.avg_frame_size_median);
EXPECT_FALSE(config.max_frame_size_percentile.has_value());
EXPECT_FALSE(config.frame_size_window.has_value());
EXPECT_FALSE(config.num_stddev_delay_clamp.has_value());
EXPECT_FALSE(config.num_stddev_delay_outlier.has_value());
EXPECT_FALSE(config.num_stddev_size_outlier.has_value());
EXPECT_FALSE(config.congestion_rejection_factor.has_value());
EXPECT_TRUE(config.estimate_noise_when_congested);
}
class FieldTrialsOverriddenJitterEstimatorTest : public JitterEstimatorTest {
protected:
FieldTrialsOverriddenJitterEstimatorTest()
: JitterEstimatorTest(
"WebRTC-JitterEstimatorConfig/"
"avg_frame_size_median:true,"
"max_frame_size_percentile:0.9,"
"frame_size_window:30,"
"num_stddev_delay_clamp:1.1,"
"num_stddev_delay_outlier:2,"
"num_stddev_size_outlier:3.1,"
"congestion_rejection_factor:-1.55,"
"estimate_noise_when_congested:false/") {}
~FieldTrialsOverriddenJitterEstimatorTest() {}
};
TEST_F(FieldTrialsOverriddenJitterEstimatorTest, FieldTrialsParsesCorrectly) {
JitterEstimator::Config config = estimator_.GetConfigForTest();
EXPECT_TRUE(config.avg_frame_size_median);
EXPECT_EQ(*config.max_frame_size_percentile, 0.9);
EXPECT_EQ(*config.frame_size_window, 30);
EXPECT_EQ(*config.num_stddev_delay_clamp, 1.1);
EXPECT_EQ(*config.num_stddev_delay_outlier, 2.0);
EXPECT_EQ(*config.num_stddev_size_outlier, 3.1);
EXPECT_EQ(*config.congestion_rejection_factor, -1.55);
EXPECT_FALSE(config.estimate_noise_when_congested);
}
TEST_F(FieldTrialsOverriddenJitterEstimatorTest,
DelayOutlierIsRejectedAndMaintainsJitterEstimate) {
ValueGenerator gen(10);
// Steady state.
Run(/*duration_s=*/60, /*framerate_fps=*/30, gen);
TimeDelta steady_state_jitter =
estimator_.GetJitterEstimate(0, absl::nullopt);
// A single outlier frame size...
estimator_.UpdateEstimate(10 * gen.Delay(), gen.FrameSize());
TimeDelta outlier_jitter = estimator_.GetJitterEstimate(0, absl::nullopt);
// ...does not change the estimate.
EXPECT_EQ(outlier_jitter.ms(), steady_state_jitter.ms());
}
// The field trial is configured to be robust against the `(1 - 0.9) = 10%`
// largest frames over a window of length `30`.
TEST_F(FieldTrialsOverriddenJitterEstimatorTest,
Four2xFrameSizesImpactJitterEstimate) {
ValueGenerator gen(10);
// Steady state.
Run(/*duration_s=*/60, /*framerate_fps=*/30, gen);
TimeDelta steady_state_jitter =
estimator_.GetJitterEstimate(0, absl::nullopt);
// Three outlier frames do not impact the jitter estimate.
for (int i = 0; i < 3; ++i) {
estimator_.UpdateEstimate(gen.Delay(), 2 * gen.FrameSize());
}
TimeDelta outlier_jitter_3x = estimator_.GetJitterEstimate(0, absl::nullopt);
EXPECT_EQ(outlier_jitter_3x.ms(), steady_state_jitter.ms());
// Four outlier frames do impact the jitter estimate.
estimator_.UpdateEstimate(gen.Delay(), 2 * gen.FrameSize());
TimeDelta outlier_jitter_4x = estimator_.GetJitterEstimate(0, absl::nullopt);
EXPECT_GT(outlier_jitter_4x.ms(), outlier_jitter_3x.ms());
}
// When so configured, congested frames are NOT used when calculating the
// noise variance, meaning that they will NOT impact the final jitter estimate.
TEST_F(FieldTrialsOverriddenJitterEstimatorTest,
CongestedFrameDoesNotImpactJitterEstimate) {
ValueGenerator gen(10);
// Steady state.
Run(/*duration_s=*/10, /*framerate_fps=*/30, gen);
TimeDelta steady_state_jitter =
estimator_.GetJitterEstimate(0, absl::nullopt);
// Congested frame...
estimator_.UpdateEstimate(-10 * gen.Delay(), 0.1 * gen.FrameSize());
TimeDelta outlier_jitter = estimator_.GetJitterEstimate(0, absl::nullopt);
// ...does not impact the estimate.
EXPECT_EQ(outlier_jitter.ms(), steady_state_jitter.ms());
}
class MisconfiguredFieldTrialsJitterEstimatorTest : public JitterEstimatorTest {
protected:
MisconfiguredFieldTrialsJitterEstimatorTest()
: JitterEstimatorTest(
"WebRTC-JitterEstimatorConfig/"
"max_frame_size_percentile:-0.9,"
"frame_size_window:-1,"
"num_stddev_delay_clamp:-1.9,"
"num_stddev_delay_outlier:-2,"
"num_stddev_size_outlier:-23.1/") {}
~MisconfiguredFieldTrialsJitterEstimatorTest() {}
};
TEST_F(MisconfiguredFieldTrialsJitterEstimatorTest, FieldTrialsAreValidated) {
JitterEstimator::Config config = estimator_.GetConfigForTest();
EXPECT_EQ(*config.max_frame_size_percentile, 0.0);
EXPECT_EQ(*config.frame_size_window, 1);
EXPECT_EQ(*config.num_stddev_delay_clamp, 0.0);
EXPECT_EQ(*config.num_stddev_delay_outlier, 0.0);
EXPECT_EQ(*config.num_stddev_size_outlier, 0.0);
}
} // namespace
} // namespace webrtc