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/*
* 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/bitrate_tracker.h"
#include <cstdint>
#include <cstdlib>
#include <limits>
#include <optional>
#include "api/units/data_rate.h"
#include "api/units/data_size.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::Ge;
using ::testing::Le;
constexpr TimeDelta kWindow = TimeDelta::Millis(500);
constexpr TimeDelta kEpsilon = TimeDelta::Millis(1);
TEST(BitrateTrackerTest, ReturnsNulloptInitially) {
Timestamp now = Timestamp::Seconds(12'345);
BitrateTracker stats(kWindow);
EXPECT_EQ(stats.Rate(now), std::nullopt);
}
TEST(BitrateTrackerTest, ReturnsNulloptAfterSingleDataPoint) {
Timestamp now = Timestamp::Seconds(12'345);
BitrateTracker stats(kWindow);
stats.Update(1'500, now);
now += TimeDelta::Millis(10);
EXPECT_EQ(stats.Rate(now), std::nullopt);
}
TEST(BitrateTrackerTest, ReturnsRateAfterTwoMeasurements) {
Timestamp now = Timestamp::Seconds(12'345);
BitrateTracker stats(kWindow);
stats.Update(1'500, now);
now += TimeDelta::Millis(10);
stats.Update(1'500, now);
// One packet every 10ms would result in 1.2 Mbps, but until window is full,
// it could be treated as two packets in ~10ms window, measuring twice that
// bitrate.
EXPECT_THAT(stats.Rate(now), AllOf(Ge(DataRate::BitsPerSec(1'200'000)),
Le(DataRate::BitsPerSec(2'400'000))));
}
TEST(BitrateTrackerTest, MeasuresConstantRate) {
const Timestamp start = Timestamp::Seconds(12'345);
const TimeDelta kInterval = TimeDelta::Millis(10);
const DataSize kPacketSize = DataSize::Bytes(1'500);
const DataRate kConstantRate = kPacketSize / kInterval;
Timestamp now = start;
BitrateTracker stats(kWindow);
stats.Update(kPacketSize, now);
DataSize total_size = kPacketSize;
DataRate last_error = DataRate::PlusInfinity();
for (TimeDelta i = TimeDelta::Zero(); i < kWindow; i += kInterval) {
SCOPED_TRACE(ToString(i));
now += kInterval;
total_size += kPacketSize;
stats.Update(kPacketSize, now);
// Until window is full, bitrate is measured over a smaller window and might
// look larger than the constant rate.
std::optional<DataRate> bitrate = stats.Rate(now);
ASSERT_THAT(bitrate,
AllOf(Ge(kConstantRate), Le(total_size / (now - start))));
// Expect the estimation error to decrease as the window is extended.
DataRate error = *bitrate - kConstantRate;
EXPECT_LE(error, last_error);
last_error = error;
}
// Once window is full, bitrate measurment should be stable.
for (TimeDelta i = TimeDelta::Zero(); i < kInterval;
i += TimeDelta::Millis(1)) {
SCOPED_TRACE(ToString(i));
EXPECT_EQ(stats.Rate(now + i), kConstantRate);
}
}
TEST(BitrateTrackerTest, IncreasingThenDecreasingBitrate) {
const DataSize kLargePacketSize = DataSize::Bytes(1'500);
const DataSize kSmallPacketSize = DataSize::Bytes(300);
const TimeDelta kLargeInterval = TimeDelta::Millis(10);
const TimeDelta kSmallInterval = TimeDelta::Millis(2);
Timestamp now = Timestamp::Seconds(12'345);
BitrateTracker stats(kWindow);
stats.Update(kLargePacketSize, now);
for (TimeDelta i = TimeDelta::Zero(); i < kWindow; i += kLargeInterval) {
SCOPED_TRACE(ToString(i));
now += kLargeInterval;
stats.Update(kLargePacketSize, now);
}
std::optional<DataRate> last_bitrate = stats.Rate(now);
EXPECT_EQ(last_bitrate, kLargePacketSize / kLargeInterval);
// Decrease bitrate with smaller measurments.
for (TimeDelta i = TimeDelta::Zero(); i < kWindow; i += kLargeInterval) {
SCOPED_TRACE(ToString(i));
now += kLargeInterval;
stats.Update(kSmallPacketSize, now);
std::optional<DataRate> bitrate = stats.Rate(now);
EXPECT_LT(bitrate, last_bitrate);
last_bitrate = bitrate;
}
EXPECT_EQ(last_bitrate, kSmallPacketSize / kLargeInterval);
// Increase bitrate with more frequent measurments.
for (TimeDelta i = TimeDelta::Zero(); i < kWindow; i += kSmallInterval) {
SCOPED_TRACE(ToString(i));
now += kSmallInterval;
stats.Update(kSmallPacketSize, now);
std::optional<DataRate> bitrate = stats.Rate(now);
EXPECT_GE(bitrate, last_bitrate);
last_bitrate = bitrate;
}
EXPECT_EQ(last_bitrate, kSmallPacketSize / kSmallInterval);
}
TEST(BitrateTrackerTest, ResetAfterSilence) {
const TimeDelta kInterval = TimeDelta::Millis(10);
const DataSize kPacketSize = DataSize::Bytes(1'500);
Timestamp now = Timestamp::Seconds(12'345);
BitrateTracker stats(kWindow);
// Feed data until window has been filled.
stats.Update(kPacketSize, now);
for (TimeDelta i = TimeDelta::Zero(); i < kWindow; i += kInterval) {
now += kInterval;
stats.Update(kPacketSize, now);
}
ASSERT_GT(stats.Rate(now), DataRate::Zero());
now += kWindow + kEpsilon;
// Silence over window size should trigger auto reset for coming sample.
EXPECT_EQ(stats.Rate(now), std::nullopt);
stats.Update(kPacketSize, now);
// Single measurment after reset is not enough to estimate the rate.
EXPECT_EQ(stats.Rate(now), std::nullopt);
// Manual reset, add the same check again.
stats.Reset();
EXPECT_EQ(stats.Rate(now), std::nullopt);
now += kInterval;
stats.Update(kPacketSize, now);
EXPECT_EQ(stats.Rate(now), std::nullopt);
}
TEST(BitrateTrackerTest, HandlesChangingWindowSize) {
Timestamp now = Timestamp::Seconds(12'345);
BitrateTracker stats(kWindow);
// Check window size is validated.
EXPECT_TRUE(stats.SetWindowSize(kWindow, now));
EXPECT_FALSE(stats.SetWindowSize(kWindow + kEpsilon, now));
EXPECT_FALSE(stats.SetWindowSize(TimeDelta::Zero(), now));
EXPECT_TRUE(stats.SetWindowSize(kEpsilon, now));
EXPECT_TRUE(stats.SetWindowSize(kWindow, now));
// Fill the buffer at a rate of 10 bytes per 10 ms (8 kbps).
const DataSize kValue = DataSize::Bytes(10);
const TimeDelta kInterval = TimeDelta::Millis(10);
for (TimeDelta i = TimeDelta::Zero(); i < kWindow; i += kInterval) {
now += kInterval;
stats.Update(kValue, now);
}
ASSERT_GT(stats.Rate(now), DataRate::BitsPerSec(8'000));
// Halve the window size, rate should stay the same.
EXPECT_TRUE(stats.SetWindowSize(kWindow / 2, now));
EXPECT_EQ(stats.Rate(now), DataRate::BitsPerSec(8'000));
// Double the window size again, rate should stay the same.
// The window won't actually expand until new calls to the `Update`.
EXPECT_TRUE(stats.SetWindowSize(kWindow, now));
EXPECT_EQ(stats.Rate(now), DataRate::BitsPerSec(8'000));
// Fill the now empty window half at twice the rate.
for (TimeDelta i = TimeDelta::Zero(); i < kWindow / 2; i += kInterval) {
now += kInterval;
stats.Update(2 * kValue, now);
}
// Rate should have increased by 50%.
EXPECT_EQ(stats.Rate(now), DataRate::BitsPerSec(12'000));
}
TEST(BitrateTrackerTest, HandlesZeroCounts) {
const DataSize kPacketSize = DataSize::Bytes(1'500);
const TimeDelta kInterval = TimeDelta::Millis(10);
const Timestamp start = Timestamp::Seconds(12'345);
Timestamp now = start;
BitrateTracker stats(kWindow);
stats.Update(kPacketSize, now);
ASSERT_EQ(stats.Rate(now), std::nullopt);
now += kInterval;
stats.Update(0, now);
std::optional<DataRate> last_bitrate = stats.Rate(now);
EXPECT_GT(last_bitrate, DataRate::Zero());
now += kInterval;
while (now < start + kWindow) {
SCOPED_TRACE(ToString(now - start));
stats.Update(0, now);
std::optional<DataRate> bitrate = stats.Rate(now);
EXPECT_GT(bitrate, DataRate::Zero());
// As window expands, average bitrate decreases.
EXPECT_LT(bitrate, last_bitrate);
last_bitrate = bitrate;
now += kInterval;
}
// Initial kPacketSize should be outside the window now, so overall bitrate
// should be zero
EXPECT_EQ(stats.Rate(now), DataRate::Zero());
// Single measurment should be enough to get non zero rate.
stats.Update(kPacketSize, now);
EXPECT_EQ(stats.Rate(now), kPacketSize / kWindow);
}
TEST(BitrateTrackerTest, ReturnsNulloptWhenOverflows) {
Timestamp now = Timestamp::Seconds(12'345);
BitrateTracker 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), std::nullopt);
}
} // namespace
} // namespace webrtc
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