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platform-external-webrtc/video/overuse_frame_detector_unittest.cc
Niels Möller d1f7eb6e83 Postpone setting of CpuOveruseOptions. 
This will enable changing thresholds when switching between hardware
and software encoders. It is also a partial revert of
https://webrtc-review.googlesource.com/33340: construction of the
OveruseFrameDetector is still in VideoSendStream, but configuration is
moved back to VideoStreamEncoder.

Longer term, information about HW vs SW, or generally, about resources
consumed by the encoder, should be passed in the per-frame callbacks
to OveruseFrameDetector, and then the CpuOveruseOptions could move
back to construction time.

Bug: webrtc:8504, webrtc:8830
Change-Id: I44577519d4e05356730cac9bd9ae3c74bfc17ed7
Reviewed-on: https://webrtc-review.googlesource.com/65163
Reviewed-by: Erik Språng <sprang@webrtc.org>
Commit-Queue: Niels Moller <nisse@webrtc.org>
Cr-Commit-Position: refs/heads/master@{#22761}
2018-04-06 08:34:32 +00:00

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/*
* Copyright (c) 2013 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 <memory>
#include "api/video/i420_buffer.h"
#include "common_video/include/video_frame.h"
#include "modules/video_coding/utility/quality_scaler.h"
#include "rtc_base/event.h"
#include "rtc_base/fakeclock.h"
#include "rtc_base/random.h"
#include "test/gmock.h"
#include "test/gtest.h"
#include "video/overuse_frame_detector.h"
namespace webrtc {
using ::testing::InvokeWithoutArgs;
using ::testing::_;
namespace {
const int kWidth = 640;
const int kHeight = 480;
// Corresponds to load of 15%
const int kFrameIntervalUs = 33 * rtc::kNumMicrosecsPerMillisec;
const int kProcessTimeUs = 5 * rtc::kNumMicrosecsPerMillisec;
} // namespace
class MockCpuOveruseObserver : public AdaptationObserverInterface {
public:
MockCpuOveruseObserver() {}
virtual ~MockCpuOveruseObserver() {}
MOCK_METHOD1(AdaptUp, void(AdaptReason));
MOCK_METHOD1(AdaptDown, void(AdaptReason));
};
class CpuOveruseObserverImpl : public AdaptationObserverInterface {
public:
CpuOveruseObserverImpl() :
overuse_(0),
normaluse_(0) {}
virtual ~CpuOveruseObserverImpl() {}
void AdaptDown(AdaptReason) { ++overuse_; }
void AdaptUp(AdaptReason) { ++normaluse_; }
int overuse_;
int normaluse_;
};
class OveruseFrameDetectorUnderTest : public OveruseFrameDetector {
public:
explicit OveruseFrameDetectorUnderTest(
CpuOveruseMetricsObserver* metrics_observer)
: OveruseFrameDetector(metrics_observer) {}
~OveruseFrameDetectorUnderTest() {}
using OveruseFrameDetector::CheckForOveruse;
using OveruseFrameDetector::SetOptions;
};
class OveruseFrameDetectorTest : public ::testing::Test,
public CpuOveruseMetricsObserver {
protected:
void SetUp() override {
observer_ = &mock_observer_;
options_.min_process_count = 0;
overuse_detector_ = rtc::MakeUnique<OveruseFrameDetectorUnderTest>(this);
// Unfortunately, we can't call SetOptions here, since that would break
// single-threading requirements in the RunOnTqNormalUsage test.
}
void OnEncodedFrameTimeMeasured(int encode_time_ms,
const CpuOveruseMetrics& metrics) override {
metrics_ = metrics;
}
int InitialUsage() {
return ((options_.low_encode_usage_threshold_percent +
options_.high_encode_usage_threshold_percent) / 2.0f) + 0.5;
}
virtual void InsertAndSendFramesWithInterval(int num_frames,
int interval_us,
int width,
int height,
int delay_us) {
VideoFrame frame(I420Buffer::Create(width, height),
webrtc::kVideoRotation_0, 0);
uint32_t timestamp = 0;
while (num_frames-- > 0) {
frame.set_timestamp(timestamp);
int64_t capture_time_us = rtc::TimeMicros();
overuse_detector_->FrameCaptured(frame, capture_time_us);
clock_.AdvanceTimeMicros(delay_us);
overuse_detector_->FrameSent(timestamp, rtc::TimeMicros(),
capture_time_us, delay_us);
clock_.AdvanceTimeMicros(interval_us - delay_us);
timestamp += interval_us * 90 / 1000;
}
}
virtual void InsertAndSendFramesWithRandomInterval(int num_frames,
int min_interval_us,
int max_interval_us,
int width,
int height,
int delay_us) {
webrtc::Random random(17);
VideoFrame frame(I420Buffer::Create(width, height),
webrtc::kVideoRotation_0, 0);
uint32_t timestamp = 0;
while (num_frames-- > 0) {
frame.set_timestamp(timestamp);
int interval_us = random.Rand(min_interval_us, max_interval_us);
int64_t capture_time_us = rtc::TimeMicros();
overuse_detector_->FrameCaptured(frame, capture_time_us);
clock_.AdvanceTimeMicros(delay_us);
overuse_detector_->FrameSent(timestamp, rtc::TimeMicros(),
capture_time_us,
rtc::Optional<int>(delay_us));
overuse_detector_->CheckForOveruse(observer_);
// Avoid turning clock backwards.
if (interval_us > delay_us)
clock_.AdvanceTimeMicros(interval_us - delay_us);
timestamp += interval_us * 90 / 1000;
}
}
virtual void ForceUpdate(int width, int height) {
// Insert one frame, wait a second and then put in another to force update
// the usage. From the tests where these are used, adding another sample
// doesn't affect the expected outcome (this is mainly to check initial
// values and whether the overuse detector has been reset or not).
InsertAndSendFramesWithInterval(2, rtc::kNumMicrosecsPerSec,
width, height, kFrameIntervalUs);
}
void TriggerOveruse(int num_times) {
const int kDelayUs = 32 * rtc::kNumMicrosecsPerMillisec;
for (int i = 0; i < num_times; ++i) {
InsertAndSendFramesWithInterval(
1000, kFrameIntervalUs, kWidth, kHeight, kDelayUs);
overuse_detector_->CheckForOveruse(observer_);
}
}
void TriggerUnderuse() {
const int kDelayUs1 = 5000;
const int kDelayUs2 = 6000;
InsertAndSendFramesWithInterval(
1300, kFrameIntervalUs, kWidth, kHeight, kDelayUs1);
InsertAndSendFramesWithInterval(
1, kFrameIntervalUs, kWidth, kHeight, kDelayUs2);
overuse_detector_->CheckForOveruse(observer_);
}
int UsagePercent() { return metrics_.encode_usage_percent; }
int64_t OveruseProcessingTimeLimitForFramerate(int fps) const {
int64_t frame_interval = rtc::kNumMicrosecsPerSec / fps;
int64_t max_processing_time_us =
(frame_interval * options_.high_encode_usage_threshold_percent) / 100;
return max_processing_time_us;
}
int64_t UnderuseProcessingTimeLimitForFramerate(int fps) const {
int64_t frame_interval = rtc::kNumMicrosecsPerSec / fps;
int64_t max_processing_time_us =
(frame_interval * options_.low_encode_usage_threshold_percent) / 100;
return max_processing_time_us;
}
CpuOveruseOptions options_;
rtc::ScopedFakeClock clock_;
MockCpuOveruseObserver mock_observer_;
AdaptationObserverInterface* observer_;
std::unique_ptr<OveruseFrameDetectorUnderTest> overuse_detector_;
CpuOveruseMetrics metrics_;
static const auto reason_ = AdaptationObserverInterface::AdaptReason::kCpu;
};
// UsagePercent() > high_encode_usage_threshold_percent => overuse.
// UsagePercent() < low_encode_usage_threshold_percent => underuse.
TEST_F(OveruseFrameDetectorTest, TriggerOveruse) {
// usage > high => overuse
overuse_detector_->SetOptions(options_);
EXPECT_CALL(mock_observer_, AdaptDown(reason_)).Times(1);
TriggerOveruse(options_.high_threshold_consecutive_count);
}
TEST_F(OveruseFrameDetectorTest, OveruseAndRecover) {
// usage > high => overuse
overuse_detector_->SetOptions(options_);
EXPECT_CALL(mock_observer_, AdaptDown(reason_)).Times(1);
TriggerOveruse(options_.high_threshold_consecutive_count);
// usage < low => underuse
EXPECT_CALL(mock_observer_, AdaptUp(reason_)).Times(testing::AtLeast(1));
TriggerUnderuse();
}
TEST_F(OveruseFrameDetectorTest, DoubleOveruseAndRecover) {
overuse_detector_->SetOptions(options_);
EXPECT_CALL(mock_observer_, AdaptDown(reason_)).Times(2);
TriggerOveruse(options_.high_threshold_consecutive_count);
TriggerOveruse(options_.high_threshold_consecutive_count);
EXPECT_CALL(mock_observer_, AdaptUp(reason_)).Times(testing::AtLeast(1));
TriggerUnderuse();
}
TEST_F(OveruseFrameDetectorTest, TriggerUnderuseWithMinProcessCount) {
const int kProcessIntervalUs = 5 * rtc::kNumMicrosecsPerSec;
options_.min_process_count = 1;
CpuOveruseObserverImpl overuse_observer;
observer_ = nullptr;
overuse_detector_->SetOptions(options_);
InsertAndSendFramesWithInterval(
1200, kFrameIntervalUs, kWidth, kHeight, kProcessTimeUs);
overuse_detector_->CheckForOveruse(&overuse_observer);
EXPECT_EQ(0, overuse_observer.normaluse_);
clock_.AdvanceTimeMicros(kProcessIntervalUs);
overuse_detector_->CheckForOveruse(&overuse_observer);
EXPECT_EQ(1, overuse_observer.normaluse_);
}
TEST_F(OveruseFrameDetectorTest, ConstantOveruseGivesNoNormalUsage) {
overuse_detector_->SetOptions(options_);
EXPECT_CALL(mock_observer_, AdaptUp(reason_)).Times(0);
EXPECT_CALL(mock_observer_, AdaptDown(reason_)).Times(64);
for (size_t i = 0; i < 64; ++i) {
TriggerOveruse(options_.high_threshold_consecutive_count);
}
}
TEST_F(OveruseFrameDetectorTest, ConsecutiveCountTriggersOveruse) {
overuse_detector_->SetOptions(options_);
EXPECT_CALL(mock_observer_, AdaptDown(reason_)).Times(1);
options_.high_threshold_consecutive_count = 2;
overuse_detector_->SetOptions(options_);
TriggerOveruse(2);
}
TEST_F(OveruseFrameDetectorTest, IncorrectConsecutiveCountTriggersNoOveruse) {
overuse_detector_->SetOptions(options_);
EXPECT_CALL(mock_observer_, AdaptDown(reason_)).Times(0);
options_.high_threshold_consecutive_count = 2;
overuse_detector_->SetOptions(options_);
TriggerOveruse(1);
}
TEST_F(OveruseFrameDetectorTest, ProcessingUsage) {
overuse_detector_->SetOptions(options_);
InsertAndSendFramesWithInterval(
1000, kFrameIntervalUs, kWidth, kHeight, kProcessTimeUs);
EXPECT_EQ(kProcessTimeUs * 100 / kFrameIntervalUs, UsagePercent());
}
TEST_F(OveruseFrameDetectorTest, ResetAfterResolutionChange) {
overuse_detector_->SetOptions(options_);
ForceUpdate(kWidth, kHeight);
EXPECT_EQ(InitialUsage(), UsagePercent());
InsertAndSendFramesWithInterval(
1000, kFrameIntervalUs, kWidth, kHeight, kProcessTimeUs);
EXPECT_NE(InitialUsage(), UsagePercent());
// Verify reset (with new width/height).
ForceUpdate(kWidth, kHeight + 1);
EXPECT_EQ(InitialUsage(), UsagePercent());
}
TEST_F(OveruseFrameDetectorTest, ResetAfterFrameTimeout) {
overuse_detector_->SetOptions(options_);
ForceUpdate(kWidth, kHeight);
EXPECT_EQ(InitialUsage(), UsagePercent());
InsertAndSendFramesWithInterval(
1000, kFrameIntervalUs, kWidth, kHeight, kProcessTimeUs);
EXPECT_NE(InitialUsage(), UsagePercent());
InsertAndSendFramesWithInterval(
2, options_.frame_timeout_interval_ms *
rtc::kNumMicrosecsPerMillisec, kWidth, kHeight, kProcessTimeUs);
EXPECT_NE(InitialUsage(), UsagePercent());
// Verify reset.
InsertAndSendFramesWithInterval(
2, (options_.frame_timeout_interval_ms + 1) *
rtc::kNumMicrosecsPerMillisec, kWidth, kHeight, kProcessTimeUs);
ForceUpdate(kWidth, kHeight);
EXPECT_EQ(InitialUsage(), UsagePercent());
}
TEST_F(OveruseFrameDetectorTest, MinFrameSamplesBeforeUpdating) {
options_.min_frame_samples = 40;
overuse_detector_->SetOptions(options_);
InsertAndSendFramesWithInterval(
40, kFrameIntervalUs, kWidth, kHeight, kProcessTimeUs);
EXPECT_EQ(InitialUsage(), UsagePercent());
// Pass time far enough to digest all previous samples.
clock_.AdvanceTimeMicros(rtc::kNumMicrosecsPerSec);
InsertAndSendFramesWithInterval(1, kFrameIntervalUs, kWidth, kHeight,
kProcessTimeUs);
// The last sample has not been processed here.
EXPECT_EQ(InitialUsage(), UsagePercent());
// Pass time far enough to digest all previous samples, 41 in total.
clock_.AdvanceTimeMicros(rtc::kNumMicrosecsPerSec);
InsertAndSendFramesWithInterval(
1, kFrameIntervalUs, kWidth, kHeight, kProcessTimeUs);
EXPECT_NE(InitialUsage(), UsagePercent());
}
TEST_F(OveruseFrameDetectorTest, InitialProcessingUsage) {
overuse_detector_->SetOptions(options_);
ForceUpdate(kWidth, kHeight);
EXPECT_EQ(InitialUsage(), UsagePercent());
}
TEST_F(OveruseFrameDetectorTest, MeasuresMultipleConcurrentSamples) {
overuse_detector_->SetOptions(options_);
EXPECT_CALL(mock_observer_, AdaptDown(reason_))
.Times(testing::AtLeast(1));
static const int kIntervalUs = 33 * rtc::kNumMicrosecsPerMillisec;
static const size_t kNumFramesEncodingDelay = 3;
VideoFrame frame(I420Buffer::Create(kWidth, kHeight),
webrtc::kVideoRotation_0, 0);
for (size_t i = 0; i < 1000; ++i) {
// Unique timestamps.
frame.set_timestamp(static_cast<uint32_t>(i));
int64_t capture_time_us = rtc::TimeMicros();
overuse_detector_->FrameCaptured(frame, capture_time_us);
clock_.AdvanceTimeMicros(kIntervalUs);
if (i > kNumFramesEncodingDelay) {
overuse_detector_->FrameSent(
static_cast<uint32_t>(i - kNumFramesEncodingDelay), rtc::TimeMicros(),
capture_time_us, kIntervalUs);
}
overuse_detector_->CheckForOveruse(observer_);
}
}
TEST_F(OveruseFrameDetectorTest, UpdatesExistingSamples) {
// >85% encoding time should trigger overuse.
overuse_detector_->SetOptions(options_);
EXPECT_CALL(mock_observer_, AdaptDown(reason_))
.Times(testing::AtLeast(1));
static const int kIntervalUs = 33 * rtc::kNumMicrosecsPerMillisec;
static const int kDelayUs = 30 * rtc::kNumMicrosecsPerMillisec;
VideoFrame frame(I420Buffer::Create(kWidth, kHeight),
webrtc::kVideoRotation_0, 0);
uint32_t timestamp = 0;
for (size_t i = 0; i < 1000; ++i) {
frame.set_timestamp(timestamp);
int64_t capture_time_us = rtc::TimeMicros();
overuse_detector_->FrameCaptured(frame, capture_time_us);
// Encode and send first parts almost instantly.
clock_.AdvanceTimeMicros(rtc::kNumMicrosecsPerMillisec);
overuse_detector_->FrameSent(timestamp, rtc::TimeMicros(), capture_time_us,
rtc::kNumMicrosecsPerMillisec);
// Encode heavier part, resulting in >85% usage total.
clock_.AdvanceTimeMicros(kDelayUs - rtc::kNumMicrosecsPerMillisec);
overuse_detector_->FrameSent(timestamp, rtc::TimeMicros(), capture_time_us,
kDelayUs);
clock_.AdvanceTimeMicros(kIntervalUs - kDelayUs);
timestamp += kIntervalUs * 90 / 1000;
overuse_detector_->CheckForOveruse(observer_);
}
}
TEST_F(OveruseFrameDetectorTest, RunOnTqNormalUsage) {
rtc::TaskQueue queue("OveruseFrameDetectorTestQueue");
rtc::Event event(false, false);
queue.PostTask([this, &event] {
overuse_detector_->StartCheckForOveruse(options_, observer_);
event.Set();
});
event.Wait(rtc::Event::kForever);
// Expect NormalUsage(). When called, stop the |overuse_detector_| and then
// set |event| to end the test.
EXPECT_CALL(mock_observer_, AdaptUp(reason_))
.WillOnce(InvokeWithoutArgs([this, &event] {
overuse_detector_->StopCheckForOveruse();
event.Set();
}));
queue.PostTask([this] {
const int kDelayUs1 = 5 * rtc::kNumMicrosecsPerMillisec;
const int kDelayUs2 = 6 * rtc::kNumMicrosecsPerMillisec;
InsertAndSendFramesWithInterval(1300, kFrameIntervalUs, kWidth, kHeight,
kDelayUs1);
InsertAndSendFramesWithInterval(1, kFrameIntervalUs, kWidth, kHeight,
kDelayUs2);
});
EXPECT_TRUE(event.Wait(10000));
}
TEST_F(OveruseFrameDetectorTest, MaxIntervalScalesWithFramerate) {
const int kCapturerMaxFrameRate = 30;
const int kEncodeMaxFrameRate = 20; // Maximum fps the encoder can sustain.
overuse_detector_->SetOptions(options_);
// Trigger overuse.
int64_t frame_interval_us = rtc::kNumMicrosecsPerSec / kCapturerMaxFrameRate;
// Processing time just below over use limit given kEncodeMaxFrameRate.
int64_t processing_time_us =
(98 * OveruseProcessingTimeLimitForFramerate(kEncodeMaxFrameRate)) / 100;
EXPECT_CALL(mock_observer_, AdaptDown(reason_)).Times(1);
for (int i = 0; i < options_.high_threshold_consecutive_count; ++i) {
InsertAndSendFramesWithInterval(1200, frame_interval_us, kWidth, kHeight,
processing_time_us);
overuse_detector_->CheckForOveruse(observer_);
}
// Simulate frame rate reduction and normal usage.
frame_interval_us = rtc::kNumMicrosecsPerSec / kEncodeMaxFrameRate;
overuse_detector_->OnTargetFramerateUpdated(kEncodeMaxFrameRate);
EXPECT_CALL(mock_observer_, AdaptDown(reason_)).Times(0);
for (int i = 0; i < options_.high_threshold_consecutive_count; ++i) {
InsertAndSendFramesWithInterval(1200, frame_interval_us, kWidth, kHeight,
processing_time_us);
overuse_detector_->CheckForOveruse(observer_);
}
// Reduce processing time to trigger underuse.
processing_time_us =
(98 * UnderuseProcessingTimeLimitForFramerate(kEncodeMaxFrameRate)) / 100;
EXPECT_CALL(mock_observer_, AdaptUp(reason_)).Times(1);
InsertAndSendFramesWithInterval(1200, frame_interval_us, kWidth, kHeight,
processing_time_us);
overuse_detector_->CheckForOveruse(observer_);
}
TEST_F(OveruseFrameDetectorTest, RespectsMinFramerate) {
const int kMinFrameRate = 7; // Minimum fps allowed by current detector impl.
overuse_detector_->SetOptions(options_);
overuse_detector_->OnTargetFramerateUpdated(kMinFrameRate);
// Normal usage just at the limit.
int64_t frame_interval_us = rtc::kNumMicrosecsPerSec / kMinFrameRate;
// Processing time just below over use limit given kEncodeMaxFrameRate.
int64_t processing_time_us =
(98 * OveruseProcessingTimeLimitForFramerate(kMinFrameRate)) / 100;
EXPECT_CALL(mock_observer_, AdaptDown(reason_)).Times(0);
for (int i = 0; i < options_.high_threshold_consecutive_count; ++i) {
InsertAndSendFramesWithInterval(1200, frame_interval_us, kWidth, kHeight,
processing_time_us);
overuse_detector_->CheckForOveruse(observer_);
}
// Over the limit to overuse.
processing_time_us =
(102 * OveruseProcessingTimeLimitForFramerate(kMinFrameRate)) / 100;
EXPECT_CALL(mock_observer_, AdaptDown(reason_)).Times(1);
for (int i = 0; i < options_.high_threshold_consecutive_count; ++i) {
InsertAndSendFramesWithInterval(1200, frame_interval_us, kWidth, kHeight,
processing_time_us);
overuse_detector_->CheckForOveruse(observer_);
}
// Reduce input frame rate. Should still trigger overuse.
overuse_detector_->OnTargetFramerateUpdated(kMinFrameRate - 1);
EXPECT_CALL(mock_observer_, AdaptDown(reason_)).Times(1);
for (int i = 0; i < options_.high_threshold_consecutive_count; ++i) {
InsertAndSendFramesWithInterval(1200, frame_interval_us, kWidth, kHeight,
processing_time_us);
overuse_detector_->CheckForOveruse(observer_);
}
}
TEST_F(OveruseFrameDetectorTest, LimitsMaxFrameInterval) {
const int kMaxFrameRate = 20;
overuse_detector_->SetOptions(options_);
overuse_detector_->OnTargetFramerateUpdated(kMaxFrameRate);
int64_t frame_interval_us = rtc::kNumMicrosecsPerSec / kMaxFrameRate;
// Maximum frame interval allowed is 35% above ideal.
int64_t max_frame_interval_us = (135 * frame_interval_us) / 100;
// Maximum processing time, without triggering overuse, allowed with the above
// frame interval.
int64_t max_processing_time_us =
(max_frame_interval_us * options_.high_encode_usage_threshold_percent) /
100;
// Processing time just below overuse limit given kMaxFrameRate.
int64_t processing_time_us = (98 * max_processing_time_us) / 100;
EXPECT_CALL(mock_observer_, AdaptDown(reason_)).Times(0);
for (int i = 0; i < options_.high_threshold_consecutive_count; ++i) {
InsertAndSendFramesWithInterval(1200, max_frame_interval_us, kWidth,
kHeight, processing_time_us);
overuse_detector_->CheckForOveruse(observer_);
}
// Go above limit, trigger overuse.
processing_time_us = (102 * max_processing_time_us) / 100;
EXPECT_CALL(mock_observer_, AdaptDown(reason_)).Times(1);
for (int i = 0; i < options_.high_threshold_consecutive_count; ++i) {
InsertAndSendFramesWithInterval(1200, max_frame_interval_us, kWidth,
kHeight, processing_time_us);
overuse_detector_->CheckForOveruse(observer_);
}
// Increase frame interval, should still trigger overuse.
max_frame_interval_us *= 2;
EXPECT_CALL(mock_observer_, AdaptDown(reason_)).Times(1);
for (int i = 0; i < options_.high_threshold_consecutive_count; ++i) {
InsertAndSendFramesWithInterval(1200, max_frame_interval_us, kWidth,
kHeight, processing_time_us);
overuse_detector_->CheckForOveruse(observer_);
}
}
// Models screencast, with irregular arrival of frames which are heavy
// to encode.
TEST_F(OveruseFrameDetectorTest, NoOveruseForLargeRandomFrameInterval) {
// TODO(bugs.webrtc.org/8504): When new estimator is relanded,
// behavior is improved in this scenario, with only AdaptUp events,
// and estimated load closer to the true average.
// EXPECT_CALL(mock_observer_, AdaptDown(_)).Times(0);
// EXPECT_CALL(mock_observer_, AdaptUp(reason_))
// .Times(testing::AtLeast(1));
overuse_detector_->SetOptions(options_);
const int kNumFrames = 500;
const int kEncodeTimeUs = 100 * rtc::kNumMicrosecsPerMillisec;
const int kMinIntervalUs = 30 * rtc::kNumMicrosecsPerMillisec;
const int kMaxIntervalUs = 1000 * rtc::kNumMicrosecsPerMillisec;
const int kTargetFramerate = 5;
overuse_detector_->OnTargetFramerateUpdated(kTargetFramerate);
InsertAndSendFramesWithRandomInterval(kNumFrames,
kMinIntervalUs, kMaxIntervalUs,
kWidth, kHeight, kEncodeTimeUs);
// Average usage 19%. Check that estimate is in the right ball park.
// EXPECT_NEAR(UsagePercent(), 20, 10);
EXPECT_NEAR(UsagePercent(), 20, 35);
}
// Models screencast, with irregular arrival of frames, often
// exceeding the timeout interval.
TEST_F(OveruseFrameDetectorTest, NoOveruseForRandomFrameIntervalWithReset) {
// TODO(bugs.webrtc.org/8504): When new estimator is relanded,
// behavior is improved in this scenario, and we get AdaptUp events.
overuse_detector_->SetOptions(options_);
EXPECT_CALL(mock_observer_, AdaptDown(_)).Times(0);
// EXPECT_CALL(mock_observer_, AdaptUp(reason_))
// .Times(testing::AtLeast(1));
const int kNumFrames = 500;
const int kEncodeTimeUs = 100 * rtc::kNumMicrosecsPerMillisec;
const int kMinIntervalUs = 30 * rtc::kNumMicrosecsPerMillisec;
const int kMaxIntervalUs = 3000 * rtc::kNumMicrosecsPerMillisec;
const int kTargetFramerate = 5;
overuse_detector_->OnTargetFramerateUpdated(kTargetFramerate);
InsertAndSendFramesWithRandomInterval(kNumFrames,
kMinIntervalUs, kMaxIntervalUs,
kWidth, kHeight, kEncodeTimeUs);
// Average usage 6.6%, but since the frame_timeout_interval_ms is
// only 1500 ms, we often reset the estimate to the initial value.
// Check that estimate is in the right ball park.
EXPECT_GE(UsagePercent(), 1);
EXPECT_LE(UsagePercent(), InitialUsage() + 5);
}
// Tests using new cpu load estimator
class OveruseFrameDetectorTest2 : public OveruseFrameDetectorTest {
protected:
void SetUp() override {
options_.filter_time_ms = 5 * rtc::kNumMillisecsPerSec;
OveruseFrameDetectorTest::SetUp();
}
void InsertAndSendFramesWithInterval(int num_frames,
int interval_us,
int width,
int height,
int delay_us) override {
VideoFrame frame(I420Buffer::Create(width, height),
webrtc::kVideoRotation_0, 0);
while (num_frames-- > 0) {
int64_t capture_time_us = rtc::TimeMicros();
overuse_detector_->FrameCaptured(frame, capture_time_us /* ignored */);
overuse_detector_->FrameSent(0 /* ignored timestamp */,
0 /* ignored send_time_us */,
capture_time_us, delay_us);
clock_.AdvanceTimeMicros(interval_us);
}
}
void InsertAndSendFramesWithRandomInterval(int num_frames,
int min_interval_us,
int max_interval_us,
int width,
int height,
int delay_us) override {
webrtc::Random random(17);
VideoFrame frame(I420Buffer::Create(width, height),
webrtc::kVideoRotation_0, 0);
for (int i = 0; i < num_frames; i++) {
int interval_us = random.Rand(min_interval_us, max_interval_us);
int64_t capture_time_us = rtc::TimeMicros();
overuse_detector_->FrameCaptured(frame, capture_time_us);
overuse_detector_->FrameSent(0 /* ignored timestamp */,
0 /* ignored send_time_us */,
capture_time_us, delay_us);
overuse_detector_->CheckForOveruse(observer_);
clock_.AdvanceTimeMicros(interval_us);
}
}
void ForceUpdate(int width, int height) override {
// This is mainly to check initial values and whether the overuse
// detector has been reset or not.
InsertAndSendFramesWithInterval(1, rtc::kNumMicrosecsPerSec, width, height,
kFrameIntervalUs);
}
};
// UsagePercent() > high_encode_usage_threshold_percent => overuse.
// UsagePercent() < low_encode_usage_threshold_percent => underuse.
TEST_F(OveruseFrameDetectorTest2, TriggerOveruse) {
// usage > high => overuse
overuse_detector_->SetOptions(options_);
EXPECT_CALL(mock_observer_, AdaptDown(reason_)).Times(1);
TriggerOveruse(options_.high_threshold_consecutive_count);
}
TEST_F(OveruseFrameDetectorTest2, OveruseAndRecover) {
// usage > high => overuse
overuse_detector_->SetOptions(options_);
EXPECT_CALL(mock_observer_, AdaptDown(reason_)).Times(1);
TriggerOveruse(options_.high_threshold_consecutive_count);
// usage < low => underuse
EXPECT_CALL(mock_observer_, AdaptUp(reason_)).Times(testing::AtLeast(1));
TriggerUnderuse();
}
TEST_F(OveruseFrameDetectorTest2, DoubleOveruseAndRecover) {
overuse_detector_->SetOptions(options_);
EXPECT_CALL(mock_observer_, AdaptDown(reason_)).Times(2);
TriggerOveruse(options_.high_threshold_consecutive_count);
TriggerOveruse(options_.high_threshold_consecutive_count);
EXPECT_CALL(mock_observer_, AdaptUp(reason_)).Times(testing::AtLeast(1));
TriggerUnderuse();
}
TEST_F(OveruseFrameDetectorTest2, TriggerUnderuseWithMinProcessCount) {
const int kProcessIntervalUs = 5 * rtc::kNumMicrosecsPerSec;
options_.min_process_count = 1;
CpuOveruseObserverImpl overuse_observer;
observer_ = nullptr;
overuse_detector_->SetOptions(options_);
InsertAndSendFramesWithInterval(
1200, kFrameIntervalUs, kWidth, kHeight, kProcessTimeUs);
overuse_detector_->CheckForOveruse(&overuse_observer);
EXPECT_EQ(0, overuse_observer.normaluse_);
clock_.AdvanceTimeMicros(kProcessIntervalUs);
overuse_detector_->CheckForOveruse(&overuse_observer);
EXPECT_EQ(1, overuse_observer.normaluse_);
}
TEST_F(OveruseFrameDetectorTest2, ConstantOveruseGivesNoNormalUsage) {
overuse_detector_->SetOptions(options_);
EXPECT_CALL(mock_observer_, AdaptUp(reason_)).Times(0);
EXPECT_CALL(mock_observer_, AdaptDown(reason_)).Times(64);
for (size_t i = 0; i < 64; ++i) {
TriggerOveruse(options_.high_threshold_consecutive_count);
}
}
TEST_F(OveruseFrameDetectorTest2, ConsecutiveCountTriggersOveruse) {
EXPECT_CALL(mock_observer_, AdaptDown(reason_)).Times(1);
options_.high_threshold_consecutive_count = 2;
overuse_detector_->SetOptions(options_);
TriggerOveruse(2);
}
TEST_F(OveruseFrameDetectorTest2, IncorrectConsecutiveCountTriggersNoOveruse) {
EXPECT_CALL(mock_observer_, AdaptDown(reason_)).Times(0);
options_.high_threshold_consecutive_count = 2;
overuse_detector_->SetOptions(options_);
TriggerOveruse(1);
}
TEST_F(OveruseFrameDetectorTest2, ProcessingUsage) {
overuse_detector_->SetOptions(options_);
InsertAndSendFramesWithInterval(
1000, kFrameIntervalUs, kWidth, kHeight, kProcessTimeUs);
EXPECT_EQ(kProcessTimeUs * 100 / kFrameIntervalUs, UsagePercent());
}
TEST_F(OveruseFrameDetectorTest2, ResetAfterResolutionChange) {
overuse_detector_->SetOptions(options_);
ForceUpdate(kWidth, kHeight);
EXPECT_EQ(InitialUsage(), UsagePercent());
InsertAndSendFramesWithInterval(
1000, kFrameIntervalUs, kWidth, kHeight, kProcessTimeUs);
EXPECT_NE(InitialUsage(), UsagePercent());
// Verify reset (with new width/height).
ForceUpdate(kWidth, kHeight + 1);
EXPECT_EQ(InitialUsage(), UsagePercent());
}
TEST_F(OveruseFrameDetectorTest2, ResetAfterFrameTimeout) {
overuse_detector_->SetOptions(options_);
ForceUpdate(kWidth, kHeight);
EXPECT_EQ(InitialUsage(), UsagePercent());
InsertAndSendFramesWithInterval(
1000, kFrameIntervalUs, kWidth, kHeight, kProcessTimeUs);
EXPECT_NE(InitialUsage(), UsagePercent());
InsertAndSendFramesWithInterval(
2, options_.frame_timeout_interval_ms *
rtc::kNumMicrosecsPerMillisec, kWidth, kHeight, kProcessTimeUs);
EXPECT_NE(InitialUsage(), UsagePercent());
// Verify reset.
InsertAndSendFramesWithInterval(
2, (options_.frame_timeout_interval_ms + 1) *
rtc::kNumMicrosecsPerMillisec, kWidth, kHeight, kProcessTimeUs);
ForceUpdate(kWidth, kHeight);
EXPECT_EQ(InitialUsage(), UsagePercent());
}
TEST_F(OveruseFrameDetectorTest2, ConvergesSlowly) {
overuse_detector_->SetOptions(options_);
InsertAndSendFramesWithInterval(1, kFrameIntervalUs, kWidth, kHeight,
kProcessTimeUs);
// No update for the first sample.
EXPECT_EQ(InitialUsage(), UsagePercent());
// Total time approximately 40 * 33ms = 1.3s, significantly less
// than the 5s time constant.
InsertAndSendFramesWithInterval(
40, kFrameIntervalUs, kWidth, kHeight, kProcessTimeUs);
// Should have started to approach correct load of 15%, but not very far.
EXPECT_LT(UsagePercent(), InitialUsage());
EXPECT_GT(UsagePercent(), (InitialUsage() * 3 + 15) / 4);
// Run for roughly 10s more, should now be closer.
InsertAndSendFramesWithInterval(
300, kFrameIntervalUs, kWidth, kHeight, kProcessTimeUs);
EXPECT_NEAR(UsagePercent(), 20, 5);
}
TEST_F(OveruseFrameDetectorTest2, InitialProcessingUsage) {
overuse_detector_->SetOptions(options_);
ForceUpdate(kWidth, kHeight);
EXPECT_EQ(InitialUsage(), UsagePercent());
}
TEST_F(OveruseFrameDetectorTest2, MeasuresMultipleConcurrentSamples) {
overuse_detector_->SetOptions(options_);
EXPECT_CALL(mock_observer_, AdaptDown(reason_))
.Times(testing::AtLeast(1));
static const int kIntervalUs = 33 * rtc::kNumMicrosecsPerMillisec;
static const size_t kNumFramesEncodingDelay = 3;
VideoFrame frame(I420Buffer::Create(kWidth, kHeight),
webrtc::kVideoRotation_0, 0);
for (size_t i = 0; i < 1000; ++i) {
// Unique timestamps.
frame.set_timestamp(static_cast<uint32_t>(i));
int64_t capture_time_us = rtc::TimeMicros();
overuse_detector_->FrameCaptured(frame, capture_time_us);
clock_.AdvanceTimeMicros(kIntervalUs);
if (i > kNumFramesEncodingDelay) {
overuse_detector_->FrameSent(
static_cast<uint32_t>(i - kNumFramesEncodingDelay), rtc::TimeMicros(),
capture_time_us, kIntervalUs);
}
overuse_detector_->CheckForOveruse(observer_);
}
}
TEST_F(OveruseFrameDetectorTest2, UpdatesExistingSamples) {
// >85% encoding time should trigger overuse.
overuse_detector_->SetOptions(options_);
EXPECT_CALL(mock_observer_, AdaptDown(reason_))
.Times(testing::AtLeast(1));
static const int kIntervalUs = 33 * rtc::kNumMicrosecsPerMillisec;
static const int kDelayUs = 30 * rtc::kNumMicrosecsPerMillisec;
VideoFrame frame(I420Buffer::Create(kWidth, kHeight),
webrtc::kVideoRotation_0, 0);
uint32_t timestamp = 0;
for (size_t i = 0; i < 1000; ++i) {
frame.set_timestamp(timestamp);
int64_t capture_time_us = rtc::TimeMicros();
overuse_detector_->FrameCaptured(frame, capture_time_us);
// Encode and send first parts almost instantly.
clock_.AdvanceTimeMicros(rtc::kNumMicrosecsPerMillisec);
overuse_detector_->FrameSent(timestamp, rtc::TimeMicros(), capture_time_us,
rtc::kNumMicrosecsPerMillisec);
// Encode heavier part, resulting in >85% usage total.
clock_.AdvanceTimeMicros(kDelayUs - rtc::kNumMicrosecsPerMillisec);
overuse_detector_->FrameSent(timestamp, rtc::TimeMicros(), capture_time_us,
kDelayUs);
clock_.AdvanceTimeMicros(kIntervalUs - kDelayUs);
timestamp += kIntervalUs * 90 / 1000;
overuse_detector_->CheckForOveruse(observer_);
}
}
TEST_F(OveruseFrameDetectorTest2, RunOnTqNormalUsage) {
rtc::TaskQueue queue("OveruseFrameDetectorTestQueue");
rtc::Event event(false, false);
queue.PostTask([this, &event] {
overuse_detector_->StartCheckForOveruse(options_, observer_);
event.Set();
});
event.Wait(rtc::Event::kForever);
// Expect NormalUsage(). When called, stop the |overuse_detector_| and then
// set |event| to end the test.
EXPECT_CALL(mock_observer_, AdaptUp(reason_))
.WillOnce(InvokeWithoutArgs([this, &event] {
overuse_detector_->StopCheckForOveruse();
event.Set();
}));
queue.PostTask([this] {
const int kDelayUs1 = 5 * rtc::kNumMicrosecsPerMillisec;
const int kDelayUs2 = 6 * rtc::kNumMicrosecsPerMillisec;
InsertAndSendFramesWithInterval(1300, kFrameIntervalUs, kWidth, kHeight,
kDelayUs1);
InsertAndSendFramesWithInterval(1, kFrameIntervalUs, kWidth, kHeight,
kDelayUs2);
});
EXPECT_TRUE(event.Wait(10000));
}
// Models screencast, with irregular arrival of frames which are heavy
// to encode.
TEST_F(OveruseFrameDetectorTest2, NoOveruseForLargeRandomFrameInterval) {
overuse_detector_->SetOptions(options_);
EXPECT_CALL(mock_observer_, AdaptDown(_)).Times(0);
EXPECT_CALL(mock_observer_, AdaptUp(reason_))
.Times(testing::AtLeast(1));
const int kNumFrames = 500;
const int kEncodeTimeUs = 100 * rtc::kNumMicrosecsPerMillisec;
const int kMinIntervalUs = 30 * rtc::kNumMicrosecsPerMillisec;
const int kMaxIntervalUs = 1000 * rtc::kNumMicrosecsPerMillisec;
InsertAndSendFramesWithRandomInterval(kNumFrames,
kMinIntervalUs, kMaxIntervalUs,
kWidth, kHeight, kEncodeTimeUs);
// Average usage 19%. Check that estimate is in the right ball park.
EXPECT_NEAR(UsagePercent(), 20, 10);
}
// Models screencast, with irregular arrival of frames, often
// exceeding the timeout interval.
TEST_F(OveruseFrameDetectorTest2, NoOveruseForRandomFrameIntervalWithReset) {
overuse_detector_->SetOptions(options_);
EXPECT_CALL(mock_observer_, AdaptDown(_)).Times(0);
EXPECT_CALL(mock_observer_, AdaptUp(reason_))
.Times(testing::AtLeast(1));
const int kNumFrames = 500;
const int kEncodeTimeUs = 100 * rtc::kNumMicrosecsPerMillisec;
const int kMinIntervalUs = 30 * rtc::kNumMicrosecsPerMillisec;
const int kMaxIntervalUs = 3000 * rtc::kNumMicrosecsPerMillisec;
InsertAndSendFramesWithRandomInterval(kNumFrames,
kMinIntervalUs, kMaxIntervalUs,
kWidth, kHeight, kEncodeTimeUs);
// Average usage 6.6%, but since the frame_timeout_interval_ms is
// only 1500 ms, we often reset the estimate to the initial value.
// Check that estimate is in the right ball park.
EXPECT_GE(UsagePercent(), 1);
EXPECT_LE(UsagePercent(), InitialUsage() + 5);
}
} // namespace webrtc
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