rtc_base/rate_statistics_unittest.cc - src - Git at Google

 /*
  *  Copyright (c) 2012 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 <cstdlib>

 #include "rtc_base/rate_statistics.h"
 #include "test/gtest.h"

 namespace {

 using webrtc::RateStatistics;

 const int64_t kWindowMs = 500;

 class RateStatisticsTest : public ::testing::Test {
  protected:
   RateStatisticsTest() : stats_(kWindowMs, 8000) {}
   RateStatistics stats_;
 };

 TEST_F(RateStatisticsTest, TestStrictMode) {
   int64_t now_ms = 0;
   EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));

   const uint32_t kPacketSize = 1500u;
   const uint32_t kExpectedRateBps = kPacketSize * 1000 * 8;

   // Single data point is not enough for valid estimate.
   stats_.Update(kPacketSize, now_ms++);
   EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));

   // Expecting 1200 kbps since the window is initially kept small and grows as
   // we have more data.
   stats_.Update(kPacketSize, now_ms);
   EXPECT_EQ(kExpectedRateBps, *stats_.Rate(now_ms));

   stats_.Reset();
   // Expecting 0 after init.
   EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));

   const int kInterval = 10;
   for (int i = 0; i < 100000; ++i) {
     if (i % kInterval == 0)
       stats_.Update(kPacketSize, now_ms);

     // Approximately 1200 kbps expected. Not exact since when packets
     // are removed we will jump 10 ms to the next packet.
     if (i > kInterval) {
       absl::optional<uint32_t> rate = stats_.Rate(now_ms);
       EXPECT_TRUE(static_cast<bool>(rate));
       uint32_t samples = i / kInterval + 1;
       uint64_t total_bits = samples * kPacketSize * 8;
       uint32_t rate_bps = static_cast<uint32_t>((1000 * total_bits) / (i + 1));
       EXPECT_NEAR(rate_bps, *rate, 22000u);
     }
     now_ms += 1;
   }
   now_ms += kWindowMs;
   // The window is 2 seconds. If nothing has been received for that time
   // the estimate should be 0.
   EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));
 }

 TEST_F(RateStatisticsTest, IncreasingThenDecreasingBitrate) {
   int64_t now_ms = 0;
   stats_.Reset();
   // Expecting 0 after init.
   EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));

   stats_.Update(1000, ++now_ms);
   const uint32_t kExpectedBitrate = 8000000;
   // 1000 bytes per millisecond until plateau is reached.
   int prev_error = kExpectedBitrate;
   absl::optional<uint32_t> bitrate;
   while (++now_ms < 10000) {
     stats_.Update(1000, now_ms);
     bitrate = stats_.Rate(now_ms);
     EXPECT_TRUE(static_cast<bool>(bitrate));
     int error = kExpectedBitrate - *bitrate;
     error = std::abs(error);
     // Expect the estimation error to decrease as the window is extended.
     EXPECT_LE(error, prev_error + 1);
     prev_error = error;
   }
   // Window filled, expect to be close to 8000000.
   EXPECT_EQ(kExpectedBitrate, *bitrate);

   // 1000 bytes per millisecond until 10-second mark, 8000 kbps expected.
   while (++now_ms < 10000) {
     stats_.Update(1000, now_ms);
     bitrate = stats_.Rate(now_ms);
     EXPECT_EQ(kExpectedBitrate, *bitrate);
   }

   // Zero bytes per millisecond until 0 is reached.
   while (++now_ms < 20000) {
     stats_.Update(0, now_ms);
     absl::optional<uint32_t> new_bitrate = stats_.Rate(now_ms);
     if (static_cast<bool>(new_bitrate) && *new_bitrate != *bitrate) {
       // New bitrate must be lower than previous one.
       EXPECT_LT(*new_bitrate, *bitrate);
     } else {
       // 0 kbps expected.
       EXPECT_EQ(0u, *new_bitrate);
       break;
     }
     bitrate = new_bitrate;
   }

   // Zero bytes per millisecond until 20-second mark, 0 kbps expected.
   while (++now_ms < 20000) {
     stats_.Update(0, now_ms);
     EXPECT_EQ(0u, *stats_.Rate(now_ms));
   }
 }

 TEST_F(RateStatisticsTest, ResetAfterSilence) {
   int64_t now_ms = 0;
   stats_.Reset();
   // Expecting 0 after init.
   EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));

   const uint32_t kExpectedBitrate = 8000000;
   // 1000 bytes per millisecond until the window has been filled.
   int prev_error = kExpectedBitrate;
   absl::optional<uint32_t> bitrate;
   while (++now_ms < 10000) {
     stats_.Update(1000, now_ms);
     bitrate = stats_.Rate(now_ms);
     if (bitrate) {
       int error = kExpectedBitrate - *bitrate;
       error = std::abs(error);
       // Expect the estimation error to decrease as the window is extended.
       EXPECT_LE(error, prev_error + 1);
       prev_error = error;
     }
   }
   // Window filled, expect to be close to 8000000.
   EXPECT_EQ(kExpectedBitrate, *bitrate);

   now_ms += kWindowMs + 1;
   EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));
   stats_.Update(1000, now_ms);
   ++now_ms;
   stats_.Update(1000, now_ms);
   // We expect two samples of 1000 bytes, and that the bitrate is measured over
   // 500 ms, i.e. 2 * 8 * 1000 / 0.500 = 32000.
   EXPECT_EQ(32000u, *stats_.Rate(now_ms));

   // Reset, add the same samples again.
   stats_.Reset();
   EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));
   stats_.Update(1000, now_ms);
   ++now_ms;
   stats_.Update(1000, now_ms);
   // We expect two samples of 1000 bytes, and that the bitrate is measured over
   // 2 ms (window size has been reset) i.e. 2 * 8 * 1000 / 0.002 = 8000000.
   EXPECT_EQ(kExpectedBitrate, *stats_.Rate(now_ms));
 }

 TEST_F(RateStatisticsTest, HandlesChangingWindowSize) {
   int64_t now_ms = 0;
   stats_.Reset();

   // Sanity test window size.
   EXPECT_TRUE(stats_.SetWindowSize(kWindowMs, now_ms));
   EXPECT_FALSE(stats_.SetWindowSize(kWindowMs + 1, now_ms));
   EXPECT_FALSE(stats_.SetWindowSize(0, now_ms));
   EXPECT_TRUE(stats_.SetWindowSize(1, now_ms));
   EXPECT_TRUE(stats_.SetWindowSize(kWindowMs, now_ms));

   // Fill the buffer at a rate of 1 byte / millisecond (8 kbps).
   const int kBatchSize = 10;
   for (int i = 0; i <= kWindowMs; i += kBatchSize)
     stats_.Update(kBatchSize, now_ms += kBatchSize);
   EXPECT_EQ(static_cast<uint32_t>(8000), *stats_.Rate(now_ms));

   // Halve the window size, rate should stay the same.
   EXPECT_TRUE(stats_.SetWindowSize(kWindowMs / 2, now_ms));
   EXPECT_EQ(static_cast<uint32_t>(8000), *stats_.Rate(now_ms));

   // Double the window size again, rate should stay the same. (As the window
   // won't actually expand until new bit and bobs fall into it.
   EXPECT_TRUE(stats_.SetWindowSize(kWindowMs, now_ms));
   EXPECT_EQ(static_cast<uint32_t>(8000), *stats_.Rate(now_ms));

   // Fill the now empty half with bits it twice the rate.
   for (int i = 0; i < kWindowMs / 2; i += kBatchSize)
     stats_.Update(kBatchSize * 2, now_ms += kBatchSize);

   // Rate should have increase be 50%.
   EXPECT_EQ(static_cast<uint32_t>((8000 * 3) / 2), *stats_.Rate(now_ms));
 }

 TEST_F(RateStatisticsTest, RespectsWindowSizeEdges) {
   int64_t now_ms = 0;
   stats_.Reset();
   // Expecting 0 after init.
   EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));

   // One byte per ms, using one big sample.
   stats_.Update(kWindowMs, now_ms);
   now_ms += kWindowMs - 2;
   // Shouldn't work! (Only one sample, not full window size.)
   EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));

   // Window size should be full, and the single data point should be accepted.
   ++now_ms;
   absl::optional<uint32_t> bitrate = stats_.Rate(now_ms);
   EXPECT_TRUE(static_cast<bool>(bitrate));
   EXPECT_EQ(1000 * 8u, *bitrate);

   // Add another, now we have twice the bitrate.
   stats_.Update(kWindowMs, now_ms);
   bitrate = stats_.Rate(now_ms);
   EXPECT_TRUE(static_cast<bool>(bitrate));
   EXPECT_EQ(2 * 1000 * 8u, *bitrate);

   // Now that first sample should drop out...
   now_ms += 1;
   bitrate = stats_.Rate(now_ms);
   EXPECT_TRUE(static_cast<bool>(bitrate));
   EXPECT_EQ(1000 * 8u, *bitrate);
 }

 TEST_F(RateStatisticsTest, HandlesZeroCounts) {
   int64_t now_ms = 0;
   stats_.Reset();
   // Expecting 0 after init.
   EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));

   stats_.Update(kWindowMs, now_ms);
   now_ms += kWindowMs - 1;
   stats_.Update(0, now_ms);
   absl::optional<uint32_t> bitrate = stats_.Rate(now_ms);
   EXPECT_TRUE(static_cast<bool>(bitrate));
   EXPECT_EQ(1000 * 8u, *bitrate);

   // Move window along so first data point falls out.
   ++now_ms;
   bitrate = stats_.Rate(now_ms);
   EXPECT_TRUE(static_cast<bool>(bitrate));
   EXPECT_EQ(0u, *bitrate);

   // Move window so last data point falls out.
   now_ms += kWindowMs;
   EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));
 }

 TEST_F(RateStatisticsTest, HandlesQuietPeriods) {
   int64_t now_ms = 0;
   stats_.Reset();
   // Expecting 0 after init.
   EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));

   stats_.Update(0, now_ms);
   now_ms += kWindowMs - 1;
   absl::optional<uint32_t> bitrate = stats_.Rate(now_ms);
   EXPECT_TRUE(static_cast<bool>(bitrate));
   EXPECT_EQ(0u, *bitrate);

   // Move window along so first data point falls out.
   ++now_ms;
   EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));

   // Move window a long way out.
   now_ms += 2 * kWindowMs;
   stats_.Update(0, now_ms);
   bitrate = stats_.Rate(now_ms);
   EXPECT_TRUE(static_cast<bool>(bitrate));
   EXPECT_EQ(0u, *bitrate);
 }
 }  // namespace
	/*
	* Copyright (c) 2012 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 <cstdlib>

	#include "rtc_base/rate_statistics.h"
	#include "test/gtest.h"

	namespace {

	using webrtc::RateStatistics;

	const int64_t kWindowMs = 500;

	class RateStatisticsTest : public ::testing::Test {
	protected:
	RateStatisticsTest() : stats_(kWindowMs, 8000) {}
	RateStatistics stats_;
	};

	TEST_F(RateStatisticsTest, TestStrictMode) {
	int64_t now_ms = 0;
	EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));

	const uint32_t kPacketSize = 1500u;
	const uint32_t kExpectedRateBps = kPacketSize * 1000 * 8;

	// Single data point is not enough for valid estimate.
	stats_.Update(kPacketSize, now_ms++);
	EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));

	// Expecting 1200 kbps since the window is initially kept small and grows as
	// we have more data.
	stats_.Update(kPacketSize, now_ms);
	EXPECT_EQ(kExpectedRateBps, *stats_.Rate(now_ms));

	stats_.Reset();
	// Expecting 0 after init.
	EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));

	const int kInterval = 10;
	for (int i = 0; i < 100000; ++i) {
	if (i % kInterval == 0)
	stats_.Update(kPacketSize, now_ms);

	// Approximately 1200 kbps expected. Not exact since when packets
	// are removed we will jump 10 ms to the next packet.
	if (i > kInterval) {
	absl::optional<uint32_t> rate = stats_.Rate(now_ms);
	EXPECT_TRUE(static_cast<bool>(rate));
	uint32_t samples = i / kInterval + 1;
	uint64_t total_bits = samples * kPacketSize * 8;
	uint32_t rate_bps = static_cast<uint32_t>((1000 * total_bits) / (i + 1));
	EXPECT_NEAR(rate_bps, *rate, 22000u);
	}
	now_ms += 1;
	}
	now_ms += kWindowMs;
	// The window is 2 seconds. If nothing has been received for that time
	// the estimate should be 0.
	EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));
	}

	TEST_F(RateStatisticsTest, IncreasingThenDecreasingBitrate) {
	int64_t now_ms = 0;
	stats_.Reset();
	// Expecting 0 after init.
	EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));

	stats_.Update(1000, ++now_ms);
	const uint32_t kExpectedBitrate = 8000000;
	// 1000 bytes per millisecond until plateau is reached.
	int prev_error = kExpectedBitrate;
	absl::optional<uint32_t> bitrate;
	while (++now_ms < 10000) {
	stats_.Update(1000, now_ms);
	bitrate = stats_.Rate(now_ms);
	EXPECT_TRUE(static_cast<bool>(bitrate));
	int error = kExpectedBitrate - *bitrate;
	error = std::abs(error);
	// Expect the estimation error to decrease as the window is extended.
	EXPECT_LE(error, prev_error + 1);
	prev_error = error;
	}
	// Window filled, expect to be close to 8000000.
	EXPECT_EQ(kExpectedBitrate, *bitrate);

	// 1000 bytes per millisecond until 10-second mark, 8000 kbps expected.
	while (++now_ms < 10000) {
	stats_.Update(1000, now_ms);
	bitrate = stats_.Rate(now_ms);
	EXPECT_EQ(kExpectedBitrate, *bitrate);
	}

	// Zero bytes per millisecond until 0 is reached.
	while (++now_ms < 20000) {
	stats_.Update(0, now_ms);
	absl::optional<uint32_t> new_bitrate = stats_.Rate(now_ms);
	if (static_cast<bool>(new_bitrate) && new_bitrate != bitrate) {
	// New bitrate must be lower than previous one.
	EXPECT_LT(new_bitrate, bitrate);
	} else {
	// 0 kbps expected.
	EXPECT_EQ(0u, *new_bitrate);
	break;
	}
	bitrate = new_bitrate;
	}

	// Zero bytes per millisecond until 20-second mark, 0 kbps expected.
	while (++now_ms < 20000) {
	stats_.Update(0, now_ms);
	EXPECT_EQ(0u, *stats_.Rate(now_ms));
	}
	}

	TEST_F(RateStatisticsTest, ResetAfterSilence) {
	int64_t now_ms = 0;
	stats_.Reset();
	// Expecting 0 after init.
	EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));

	const uint32_t kExpectedBitrate = 8000000;
	// 1000 bytes per millisecond until the window has been filled.
	int prev_error = kExpectedBitrate;
	absl::optional<uint32_t> bitrate;
	while (++now_ms < 10000) {
	stats_.Update(1000, now_ms);
	bitrate = stats_.Rate(now_ms);
	if (bitrate) {
	int error = kExpectedBitrate - *bitrate;
	error = std::abs(error);
	// Expect the estimation error to decrease as the window is extended.
	EXPECT_LE(error, prev_error + 1);
	prev_error = error;
	}
	}
	// Window filled, expect to be close to 8000000.
	EXPECT_EQ(kExpectedBitrate, *bitrate);

	now_ms += kWindowMs + 1;
	EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));
	stats_.Update(1000, now_ms);
	++now_ms;
	stats_.Update(1000, now_ms);
	// We expect two samples of 1000 bytes, and that the bitrate is measured over
	// 500 ms, i.e. 2 * 8 * 1000 / 0.500 = 32000.
	EXPECT_EQ(32000u, *stats_.Rate(now_ms));

	// Reset, add the same samples again.
	stats_.Reset();
	EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));
	stats_.Update(1000, now_ms);
	++now_ms;
	stats_.Update(1000, now_ms);
	// We expect two samples of 1000 bytes, and that the bitrate is measured over
	// 2 ms (window size has been reset) i.e. 2 * 8 * 1000 / 0.002 = 8000000.
	EXPECT_EQ(kExpectedBitrate, *stats_.Rate(now_ms));
	}

	TEST_F(RateStatisticsTest, HandlesChangingWindowSize) {
	int64_t now_ms = 0;
	stats_.Reset();

	// Sanity test window size.
	EXPECT_TRUE(stats_.SetWindowSize(kWindowMs, now_ms));
	EXPECT_FALSE(stats_.SetWindowSize(kWindowMs + 1, now_ms));
	EXPECT_FALSE(stats_.SetWindowSize(0, now_ms));
	EXPECT_TRUE(stats_.SetWindowSize(1, now_ms));
	EXPECT_TRUE(stats_.SetWindowSize(kWindowMs, now_ms));

	// Fill the buffer at a rate of 1 byte / millisecond (8 kbps).
	const int kBatchSize = 10;
	for (int i = 0; i <= kWindowMs; i += kBatchSize)
	stats_.Update(kBatchSize, now_ms += kBatchSize);
	EXPECT_EQ(static_cast<uint32_t>(8000), *stats_.Rate(now_ms));

	// Halve the window size, rate should stay the same.
	EXPECT_TRUE(stats_.SetWindowSize(kWindowMs / 2, now_ms));
	EXPECT_EQ(static_cast<uint32_t>(8000), *stats_.Rate(now_ms));

	// Double the window size again, rate should stay the same. (As the window
	// won't actually expand until new bit and bobs fall into it.
	EXPECT_TRUE(stats_.SetWindowSize(kWindowMs, now_ms));
	EXPECT_EQ(static_cast<uint32_t>(8000), *stats_.Rate(now_ms));

	// Fill the now empty half with bits it twice the rate.
	for (int i = 0; i < kWindowMs / 2; i += kBatchSize)
	stats_.Update(kBatchSize * 2, now_ms += kBatchSize);

	// Rate should have increase be 50%.
	EXPECT_EQ(static_cast<uint32_t>((8000 * 3) / 2), *stats_.Rate(now_ms));
	}

	TEST_F(RateStatisticsTest, RespectsWindowSizeEdges) {
	int64_t now_ms = 0;
	stats_.Reset();
	// Expecting 0 after init.
	EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));

	// One byte per ms, using one big sample.
	stats_.Update(kWindowMs, now_ms);
	now_ms += kWindowMs - 2;
	// Shouldn't work! (Only one sample, not full window size.)
	EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));

	// Window size should be full, and the single data point should be accepted.
	++now_ms;
	absl::optional<uint32_t> bitrate = stats_.Rate(now_ms);
	EXPECT_TRUE(static_cast<bool>(bitrate));
	EXPECT_EQ(1000 * 8u, *bitrate);

	// Add another, now we have twice the bitrate.
	stats_.Update(kWindowMs, now_ms);
	bitrate = stats_.Rate(now_ms);
	EXPECT_TRUE(static_cast<bool>(bitrate));
	EXPECT_EQ(2 * 1000 * 8u, *bitrate);

	// Now that first sample should drop out...
	now_ms += 1;
	bitrate = stats_.Rate(now_ms);
	EXPECT_TRUE(static_cast<bool>(bitrate));
	EXPECT_EQ(1000 * 8u, *bitrate);
	}

	TEST_F(RateStatisticsTest, HandlesZeroCounts) {
	int64_t now_ms = 0;
	stats_.Reset();
	// Expecting 0 after init.
	EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));

	stats_.Update(kWindowMs, now_ms);
	now_ms += kWindowMs - 1;
	stats_.Update(0, now_ms);
	absl::optional<uint32_t> bitrate = stats_.Rate(now_ms);
	EXPECT_TRUE(static_cast<bool>(bitrate));
	EXPECT_EQ(1000 * 8u, *bitrate);

	// Move window along so first data point falls out.
	++now_ms;
	bitrate = stats_.Rate(now_ms);
	EXPECT_TRUE(static_cast<bool>(bitrate));
	EXPECT_EQ(0u, *bitrate);

	// Move window so last data point falls out.
	now_ms += kWindowMs;
	EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));
	}

	TEST_F(RateStatisticsTest, HandlesQuietPeriods) {
	int64_t now_ms = 0;
	stats_.Reset();
	// Expecting 0 after init.
	EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));

	stats_.Update(0, now_ms);
	now_ms += kWindowMs - 1;
	absl::optional<uint32_t> bitrate = stats_.Rate(now_ms);
	EXPECT_TRUE(static_cast<bool>(bitrate));
	EXPECT_EQ(0u, *bitrate);

	// Move window along so first data point falls out.
	++now_ms;
	EXPECT_FALSE(static_cast<bool>(stats_.Rate(now_ms)));

	// Move window a long way out.
	now_ms += 2 * kWindowMs;
	stats_.Update(0, now_ms);
	bitrate = stats_.Rate(now_ms);
	EXPECT_TRUE(static_cast<bool>(bitrate));
	EXPECT_EQ(0u, *bitrate);
	}
	} // namespace