rtc_base/frequency_tracker_unittest.cc - src/ - Git at Google

 /*
  *  Copyright (c) 2023 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 "rtc_base/frequency_tracker.h"

 #include <cstdlib>
 #include <limits>

 #include "absl/types/optional.h"
 #include "api/units/frequency.h"
 #include "api/units/time_delta.h"
 #include "api/units/timestamp.h"
 #include "test/gmock.h"
 #include "test/gtest.h"

 namespace webrtc {
 namespace {

 using ::testing::AllOf;
 using ::testing::Gt;
 using ::testing::Lt;

 constexpr TimeDelta kWindow = TimeDelta::Millis(500);
 constexpr TimeDelta kEpsilon = TimeDelta::Millis(1);

 TEST(FrequencyTrackerTest, ReturnsNulloptInitially) {
   Timestamp now = Timestamp::Seconds(12'345);
   FrequencyTracker stats(kWindow);

   EXPECT_EQ(stats.Rate(now), absl::nullopt);
 }

 TEST(FrequencyTrackerTest, ReturnsNulloptAfterSingleDataPoint) {
   Timestamp now = Timestamp::Seconds(12'345);
   FrequencyTracker stats(kWindow);

   stats.Update(now);
   now += TimeDelta::Millis(10);

   EXPECT_EQ(stats.Rate(now), absl::nullopt);
 }

 TEST(FrequencyTrackerTest, ReturnsRateAfterTwoMeasurements) {
   Timestamp now = Timestamp::Seconds(12'345);
   FrequencyTracker stats(kWindow);

   stats.Update(now);
   now += TimeDelta::Millis(1);
   stats.Update(now);

   // 1 event per 1 ms ~= 1'000 events per second.
   EXPECT_EQ(stats.Rate(now), Frequency::Hertz(1'000));
 }

 TEST(FrequencyTrackerTest, MeasuresConstantRate) {
   const Timestamp start = Timestamp::Seconds(12'345);
   const TimeDelta kInterval = TimeDelta::Millis(10);
   const Frequency kConstantRate = 1 / kInterval;

   Timestamp now = start;
   FrequencyTracker stats(kWindow);

   stats.Update(now);
   Frequency last_error = Frequency::PlusInfinity();
   for (TimeDelta i = TimeDelta::Zero(); i < kWindow; i += kInterval) {
     SCOPED_TRACE(i);
     now += kInterval;
     stats.Update(now);

     // Until window is full, rate is measured over a smaller window and might
     // look larger than the constant rate.
     absl::optional<Frequency> rate = stats.Rate(now);
     ASSERT_GE(rate, kConstantRate);

     // Expect the estimation error to decrease as the window is extended.
     Frequency error = *rate - kConstantRate;
     EXPECT_LE(error, last_error);
     last_error = error;
   }

   // Once window is full, rate measurment should be stable.
   for (TimeDelta i = TimeDelta::Zero(); i < kInterval;
        i += TimeDelta::Millis(1)) {
     SCOPED_TRACE(i);
     EXPECT_EQ(stats.Rate(now + i), kConstantRate);
   }
 }

 TEST(FrequencyTrackerTest, CanMeasureFractionalRate) {
   const TimeDelta kInterval = TimeDelta::Millis(134);
   Timestamp now = Timestamp::Seconds(12'345);
   // FrequencyTracker counts number of events in the window, thus when window is
   // fraction of 1 second, number of events per second would always be integer.
   const TimeDelta window = TimeDelta::Seconds(2);

   FrequencyTracker framerate(window);
   framerate.Update(now);
   for (TimeDelta i = TimeDelta::Zero(); i < window; i += kInterval) {
     now += kInterval;
     framerate.Update(now);
   }

   // Should be aproximitly 7.5 fps
   EXPECT_THAT(framerate.Rate(now),
               AllOf(Gt(Frequency::Hertz(7)), Lt(Frequency::Hertz(8))));
 }

 TEST(FrequencyTrackerTest, IncreasingThenDecreasingRate) {
   const int64_t kLargeSize = 1'500;
   const int64_t kSmallSize = 300;
   const TimeDelta kLargeInterval = TimeDelta::Millis(10);
   const TimeDelta kSmallInterval = TimeDelta::Millis(2);

   Timestamp now = Timestamp::Seconds(12'345);
   FrequencyTracker stats(kWindow);

   stats.Update(kLargeSize, now);
   for (TimeDelta i = TimeDelta::Zero(); i < kWindow; i += kLargeInterval) {
     SCOPED_TRACE(i);
     now += kLargeInterval;
     stats.Update(kLargeSize, now);
   }
   absl::optional<Frequency> last_rate = stats.Rate(now);
   EXPECT_EQ(last_rate, kLargeSize / kLargeInterval);

   // Decrease rate with smaller measurments.
   for (TimeDelta i = TimeDelta::Zero(); i < kWindow; i += kLargeInterval) {
     SCOPED_TRACE(i);
     now += kLargeInterval;
     stats.Update(kSmallSize, now);

     absl::optional<Frequency> rate = stats.Rate(now);
     EXPECT_LT(rate, last_rate);

     last_rate = rate;
   }
   EXPECT_EQ(last_rate, kSmallSize / kLargeInterval);

   // Increase rate with more frequent measurments.
   for (TimeDelta i = TimeDelta::Zero(); i < kWindow; i += kSmallInterval) {
     SCOPED_TRACE(i);
     now += kSmallInterval;
     stats.Update(kSmallSize, now);

     absl::optional<Frequency> rate = stats.Rate(now);
     EXPECT_GE(rate, last_rate);

     last_rate = rate;
   }
   EXPECT_EQ(last_rate, kSmallSize / kSmallInterval);
 }

 TEST(FrequencyTrackerTest, ResetAfterSilence) {
   const TimeDelta kInterval = TimeDelta::Millis(10);
   const int64_t kPixels = 640 * 360;

   Timestamp now = Timestamp::Seconds(12'345);
   FrequencyTracker pixel_rate(kWindow);

   // Feed data until window has been filled.
   pixel_rate.Update(kPixels, now);
   for (TimeDelta i = TimeDelta::Zero(); i < kWindow; i += kInterval) {
     now += kInterval;
     pixel_rate.Update(kPixels, now);
   }
   ASSERT_GT(pixel_rate.Rate(now), Frequency::Zero());

   now += kWindow + kEpsilon;
   // Silence over window size should trigger auto reset for coming sample.
   EXPECT_EQ(pixel_rate.Rate(now), absl::nullopt);
   pixel_rate.Update(kPixels, now);
   // Single measurment after reset is not enough to estimate the rate.
   EXPECT_EQ(pixel_rate.Rate(now), absl::nullopt);

   // Manual reset, add the same check again.
   pixel_rate.Reset();
   EXPECT_EQ(pixel_rate.Rate(now), absl::nullopt);
   now += kInterval;
   pixel_rate.Update(kPixels, now);
   EXPECT_EQ(pixel_rate.Rate(now), absl::nullopt);
 }

 TEST(FrequencyTrackerTest, ReturnsNulloptWhenOverflows) {
   Timestamp now = Timestamp::Seconds(12'345);
   FrequencyTracker stats(kWindow);

   int64_t very_large_number = std::numeric_limits<int64_t>::max();
   stats.Update(very_large_number, now);
   now += kEpsilon;
   stats.Update(very_large_number, now);

   EXPECT_EQ(stats.Rate(now), absl::nullopt);
 }

 }  // namespace
 }  // namespace webrtc
	/*
	* Copyright (c) 2023 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 "rtc_base/frequency_tracker.h"

	#include <cstdlib>
	#include <limits>

	#include "absl/types/optional.h"
	#include "api/units/frequency.h"
	#include "api/units/time_delta.h"
	#include "api/units/timestamp.h"
	#include "test/gmock.h"
	#include "test/gtest.h"

	namespace webrtc {
	namespace {

	using ::testing::AllOf;
	using ::testing::Gt;
	using ::testing::Lt;

	constexpr TimeDelta kWindow = TimeDelta::Millis(500);
	constexpr TimeDelta kEpsilon = TimeDelta::Millis(1);

	TEST(FrequencyTrackerTest, ReturnsNulloptInitially) {
	Timestamp now = Timestamp::Seconds(12'345);
	FrequencyTracker stats(kWindow);

	EXPECT_EQ(stats.Rate(now), absl::nullopt);
	}

	TEST(FrequencyTrackerTest, ReturnsNulloptAfterSingleDataPoint) {
	Timestamp now = Timestamp::Seconds(12'345);
	FrequencyTracker stats(kWindow);

	stats.Update(now);
	now += TimeDelta::Millis(10);

	EXPECT_EQ(stats.Rate(now), absl::nullopt);
	}

	TEST(FrequencyTrackerTest, ReturnsRateAfterTwoMeasurements) {
	Timestamp now = Timestamp::Seconds(12'345);
	FrequencyTracker stats(kWindow);

	stats.Update(now);
	now += TimeDelta::Millis(1);
	stats.Update(now);

	// 1 event per 1 ms ~= 1'000 events per second.
	EXPECT_EQ(stats.Rate(now), Frequency::Hertz(1'000));
	}

	TEST(FrequencyTrackerTest, MeasuresConstantRate) {
	const Timestamp start = Timestamp::Seconds(12'345);
	const TimeDelta kInterval = TimeDelta::Millis(10);
	const Frequency kConstantRate = 1 / kInterval;

	Timestamp now = start;
	FrequencyTracker stats(kWindow);

	stats.Update(now);
	Frequency last_error = Frequency::PlusInfinity();
	for (TimeDelta i = TimeDelta::Zero(); i < kWindow; i += kInterval) {
	SCOPED_TRACE(i);
	now += kInterval;
	stats.Update(now);

	// Until window is full, rate is measured over a smaller window and might
	// look larger than the constant rate.
	absl::optional<Frequency> rate = stats.Rate(now);
	ASSERT_GE(rate, kConstantRate);

	// Expect the estimation error to decrease as the window is extended.
	Frequency error = *rate - kConstantRate;
	EXPECT_LE(error, last_error);
	last_error = error;
	}

	// Once window is full, rate measurment should be stable.
	for (TimeDelta i = TimeDelta::Zero(); i < kInterval;
	i += TimeDelta::Millis(1)) {
	SCOPED_TRACE(i);
	EXPECT_EQ(stats.Rate(now + i), kConstantRate);
	}
	}

	TEST(FrequencyTrackerTest, CanMeasureFractionalRate) {
	const TimeDelta kInterval = TimeDelta::Millis(134);
	Timestamp now = Timestamp::Seconds(12'345);
	// FrequencyTracker counts number of events in the window, thus when window is
	// fraction of 1 second, number of events per second would always be integer.
	const TimeDelta window = TimeDelta::Seconds(2);

	FrequencyTracker framerate(window);
	framerate.Update(now);
	for (TimeDelta i = TimeDelta::Zero(); i < window; i += kInterval) {
	now += kInterval;
	framerate.Update(now);
	}

	// Should be aproximitly 7.5 fps
	EXPECT_THAT(framerate.Rate(now),
	AllOf(Gt(Frequency::Hertz(7)), Lt(Frequency::Hertz(8))));
	}

	TEST(FrequencyTrackerTest, IncreasingThenDecreasingRate) {
	const int64_t kLargeSize = 1'500;
	const int64_t kSmallSize = 300;
	const TimeDelta kLargeInterval = TimeDelta::Millis(10);
	const TimeDelta kSmallInterval = TimeDelta::Millis(2);

	Timestamp now = Timestamp::Seconds(12'345);
	FrequencyTracker stats(kWindow);

	stats.Update(kLargeSize, now);
	for (TimeDelta i = TimeDelta::Zero(); i < kWindow; i += kLargeInterval) {
	SCOPED_TRACE(i);
	now += kLargeInterval;
	stats.Update(kLargeSize, now);
	}
	absl::optional<Frequency> last_rate = stats.Rate(now);
	EXPECT_EQ(last_rate, kLargeSize / kLargeInterval);

	// Decrease rate with smaller measurments.
	for (TimeDelta i = TimeDelta::Zero(); i < kWindow; i += kLargeInterval) {
	SCOPED_TRACE(i);
	now += kLargeInterval;
	stats.Update(kSmallSize, now);

	absl::optional<Frequency> rate = stats.Rate(now);
	EXPECT_LT(rate, last_rate);

	last_rate = rate;
	}
	EXPECT_EQ(last_rate, kSmallSize / kLargeInterval);

	// Increase rate with more frequent measurments.
	for (TimeDelta i = TimeDelta::Zero(); i < kWindow; i += kSmallInterval) {
	SCOPED_TRACE(i);
	now += kSmallInterval;
	stats.Update(kSmallSize, now);

	absl::optional<Frequency> rate = stats.Rate(now);
	EXPECT_GE(rate, last_rate);

	last_rate = rate;
	}
	EXPECT_EQ(last_rate, kSmallSize / kSmallInterval);
	}

	TEST(FrequencyTrackerTest, ResetAfterSilence) {
	const TimeDelta kInterval = TimeDelta::Millis(10);
	const int64_t kPixels = 640 * 360;

	Timestamp now = Timestamp::Seconds(12'345);
	FrequencyTracker pixel_rate(kWindow);

	// Feed data until window has been filled.
	pixel_rate.Update(kPixels, now);
	for (TimeDelta i = TimeDelta::Zero(); i < kWindow; i += kInterval) {
	now += kInterval;
	pixel_rate.Update(kPixels, now);
	}
	ASSERT_GT(pixel_rate.Rate(now), Frequency::Zero());

	now += kWindow + kEpsilon;
	// Silence over window size should trigger auto reset for coming sample.
	EXPECT_EQ(pixel_rate.Rate(now), absl::nullopt);
	pixel_rate.Update(kPixels, now);
	// Single measurment after reset is not enough to estimate the rate.
	EXPECT_EQ(pixel_rate.Rate(now), absl::nullopt);

	// Manual reset, add the same check again.
	pixel_rate.Reset();
	EXPECT_EQ(pixel_rate.Rate(now), absl::nullopt);
	now += kInterval;
	pixel_rate.Update(kPixels, now);
	EXPECT_EQ(pixel_rate.Rate(now), absl::nullopt);
	}

	TEST(FrequencyTrackerTest, ReturnsNulloptWhenOverflows) {
	Timestamp now = Timestamp::Seconds(12'345);
	FrequencyTracker stats(kWindow);

	int64_t very_large_number = std::numeric_limits<int64_t>::max();
	stats.Update(very_large_number, now);
	now += kEpsilon;
	stats.Update(very_large_number, now);

	EXPECT_EQ(stats.Rate(now), absl::nullopt);
	}

	} // namespace
	} // namespace webrtc