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webrtc/modules/congestion_controller/delay_based_bwe_unittest.cc
Sebastian Jansson 56da2f7868 Added unit tests for new congestion controller. 
This CL activates unit tests for the task queue based send side
congestion controller that will replace the current one in the future.

To be able to have the tests run side by side with the tests of the old
congestion controller, the old tests have been prefixed with "Legacy".

This CL also contains some minor fixes to the new congestion controller
code.

Bug: webrtc:8415
Change-Id: I5e7474d42f17fcbfef402e26f638846fa3424695
Reviewed-on: https://webrtc-review.googlesource.com/55381
Reviewed-by: Philip Eliasson <philipel@webrtc.org>
Reviewed-by: Björn Terelius <terelius@webrtc.org>
Commit-Queue: Sebastian Jansson <srte@webrtc.org>
Cr-Commit-Position: refs/heads/master@{#22229}
2018-02-28 14:03:48 +00:00

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/*
* Copyright (c) 2016 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/congestion_controller/delay_based_bwe.h"
#include "modules/congestion_controller/delay_based_bwe_unittest_helper.h"
#include "modules/pacing/paced_sender.h"
#include "rtc_base/constructormagic.h"
#include "system_wrappers/include/clock.h"
#include "test/field_trial.h"
#include "test/gtest.h"
namespace webrtc {
namespace {
constexpr int kNumProbesCluster0 = 5;
constexpr int kNumProbesCluster1 = 8;
const PacedPacketInfo kPacingInfo0(0, kNumProbesCluster0, 2000);
const PacedPacketInfo kPacingInfo1(1, kNumProbesCluster1, 4000);
constexpr float kTargetUtilizationFraction = 0.95f;
} // namespace
TEST_F(LegacyDelayBasedBweTest, NoCrashEmptyFeedback) {
std::vector<PacketFeedback> packet_feedback_vector;
bitrate_estimator_->IncomingPacketFeedbackVector(packet_feedback_vector,
rtc::nullopt);
}
TEST_F(LegacyDelayBasedBweTest, NoCrashOnlyLostFeedback) {
std::vector<PacketFeedback> packet_feedback_vector;
packet_feedback_vector.push_back(PacketFeedback(PacketFeedback::kNotReceived,
PacketFeedback::kNoSendTime,
0, 1500, PacedPacketInfo()));
packet_feedback_vector.push_back(PacketFeedback(PacketFeedback::kNotReceived,
PacketFeedback::kNoSendTime,
1, 1500, PacedPacketInfo()));
bitrate_estimator_->IncomingPacketFeedbackVector(packet_feedback_vector,
rtc::nullopt);
}
TEST_F(LegacyDelayBasedBweTest, ProbeDetection) {
int64_t now_ms = clock_.TimeInMilliseconds();
uint16_t seq_num = 0;
// First burst sent at 8 * 1000 / 10 = 800 kbps.
for (int i = 0; i < kNumProbesCluster0; ++i) {
clock_.AdvanceTimeMilliseconds(10);
now_ms = clock_.TimeInMilliseconds();
IncomingFeedback(now_ms, now_ms, seq_num++, 1000, kPacingInfo0);
}
EXPECT_TRUE(bitrate_observer_.updated());
// Second burst sent at 8 * 1000 / 5 = 1600 kbps.
for (int i = 0; i < kNumProbesCluster1; ++i) {
clock_.AdvanceTimeMilliseconds(5);
now_ms = clock_.TimeInMilliseconds();
IncomingFeedback(now_ms, now_ms, seq_num++, 1000, kPacingInfo1);
}
EXPECT_TRUE(bitrate_observer_.updated());
EXPECT_GT(bitrate_observer_.latest_bitrate(), 1500000u);
}
TEST_F(LegacyDelayBasedBweTest, ProbeDetectionNonPacedPackets) {
int64_t now_ms = clock_.TimeInMilliseconds();
uint16_t seq_num = 0;
// First burst sent at 8 * 1000 / 10 = 800 kbps, but with every other packet
// not being paced which could mess things up.
for (int i = 0; i < kNumProbesCluster0; ++i) {
clock_.AdvanceTimeMilliseconds(5);
now_ms = clock_.TimeInMilliseconds();
IncomingFeedback(now_ms, now_ms, seq_num++, 1000, kPacingInfo0);
// Non-paced packet, arriving 5 ms after.
clock_.AdvanceTimeMilliseconds(5);
IncomingFeedback(now_ms, now_ms, seq_num++, 100, PacedPacketInfo());
}
EXPECT_TRUE(bitrate_observer_.updated());
EXPECT_GT(bitrate_observer_.latest_bitrate(), 800000u);
}
TEST_F(LegacyDelayBasedBweTest, ProbeDetectionFasterArrival) {
int64_t now_ms = clock_.TimeInMilliseconds();
uint16_t seq_num = 0;
// First burst sent at 8 * 1000 / 10 = 800 kbps.
// Arriving at 8 * 1000 / 5 = 1600 kbps.
int64_t send_time_ms = 0;
for (int i = 0; i < kNumProbesCluster0; ++i) {
clock_.AdvanceTimeMilliseconds(1);
send_time_ms += 10;
now_ms = clock_.TimeInMilliseconds();
IncomingFeedback(now_ms, send_time_ms, seq_num++, 1000, kPacingInfo0);
}
EXPECT_FALSE(bitrate_observer_.updated());
}
TEST_F(LegacyDelayBasedBweTest, ProbeDetectionSlowerArrival) {
int64_t now_ms = clock_.TimeInMilliseconds();
uint16_t seq_num = 0;
// First burst sent at 8 * 1000 / 5 = 1600 kbps.
// Arriving at 8 * 1000 / 7 = 1142 kbps.
// Since the receive rate is significantly below the send rate, we expect to
// use 95% of the estimated capacity.
int64_t send_time_ms = 0;
for (int i = 0; i < kNumProbesCluster1; ++i) {
clock_.AdvanceTimeMilliseconds(7);
send_time_ms += 5;
now_ms = clock_.TimeInMilliseconds();
IncomingFeedback(now_ms, send_time_ms, seq_num++, 1000, kPacingInfo1);
}
EXPECT_TRUE(bitrate_observer_.updated());
EXPECT_NEAR(bitrate_observer_.latest_bitrate(),
kTargetUtilizationFraction * 1140000u, 10000u);
}
TEST_F(LegacyDelayBasedBweTest, ProbeDetectionSlowerArrivalHighBitrate) {
int64_t now_ms = clock_.TimeInMilliseconds();
uint16_t seq_num = 0;
// Burst sent at 8 * 1000 / 1 = 8000 kbps.
// Arriving at 8 * 1000 / 2 = 4000 kbps.
// Since the receive rate is significantly below the send rate, we expect to
// use 95% of the estimated capacity.
int64_t send_time_ms = 0;
for (int i = 0; i < kNumProbesCluster1; ++i) {
clock_.AdvanceTimeMilliseconds(2);
send_time_ms += 1;
now_ms = clock_.TimeInMilliseconds();
IncomingFeedback(now_ms, send_time_ms, seq_num++, 1000, kPacingInfo1);
}
EXPECT_TRUE(bitrate_observer_.updated());
EXPECT_NEAR(bitrate_observer_.latest_bitrate(),
kTargetUtilizationFraction * 4000000u, 10000u);
}
TEST_F(LegacyDelayBasedBweTest, GetExpectedBwePeriodMs) {
int64_t default_interval_ms = bitrate_estimator_->GetExpectedBwePeriodMs();
EXPECT_GT(default_interval_ms, 0);
CapacityDropTestHelper(1, true, 333, 0);
int64_t interval_ms = bitrate_estimator_->GetExpectedBwePeriodMs();
EXPECT_GT(interval_ms, 0);
EXPECT_NE(interval_ms, default_interval_ms);
}
TEST_F(LegacyDelayBasedBweTest, InitialBehavior) {
InitialBehaviorTestHelper(730000);
}
TEST_F(LegacyDelayBasedBweTest, RateIncreaseReordering) {
RateIncreaseReorderingTestHelper(730000);
}
TEST_F(LegacyDelayBasedBweTest, RateIncreaseRtpTimestamps) {
RateIncreaseRtpTimestampsTestHelper(627);
}
TEST_F(LegacyDelayBasedBweTest, CapacityDropOneStream) {
CapacityDropTestHelper(1, false, 300, 0);
}
TEST_F(LegacyDelayBasedBweTest, CapacityDropPosOffsetChange) {
CapacityDropTestHelper(1, false, 867, 30000);
}
TEST_F(LegacyDelayBasedBweTest, CapacityDropNegOffsetChange) {
CapacityDropTestHelper(1, false, 933, -30000);
}
TEST_F(LegacyDelayBasedBweTest, CapacityDropOneStreamWrap) {
CapacityDropTestHelper(1, true, 333, 0);
}
TEST_F(LegacyDelayBasedBweTest, TestTimestampGrouping) {
TestTimestampGroupingTestHelper();
}
TEST_F(LegacyDelayBasedBweTest, TestShortTimeoutAndWrap) {
// Simulate a client leaving and rejoining the call after 35 seconds. This
// will make abs send time wrap, so if streams aren't timed out properly
// the next 30 seconds of packets will be out of order.
TestWrappingHelper(35);
}
TEST_F(LegacyDelayBasedBweTest, TestLongTimeoutAndWrap) {
// Simulate a client leaving and rejoining the call after some multiple of
// 64 seconds later. This will cause a zero difference in abs send times due
// to the wrap, but a big difference in arrival time, if streams aren't
// properly timed out.
TestWrappingHelper(10 * 64);
}
TEST_F(LegacyDelayBasedBweTest, TestInitialOveruse) {
const uint32_t kStartBitrate = 300e3;
const uint32_t kInitialCapacityBps = 200e3;
const uint32_t kDummySsrc = 0;
// High FPS to ensure that we send a lot of packets in a short time.
const int kFps = 90;
stream_generator_->AddStream(new test::RtpStream(kFps, kStartBitrate));
stream_generator_->set_capacity_bps(kInitialCapacityBps);
// Needed to initialize the AimdRateControl.
bitrate_estimator_->SetStartBitrate(kStartBitrate);
// Produce 30 frames (in 1/3 second) and give them to the estimator.
uint32_t bitrate_bps = kStartBitrate;
bool seen_overuse = false;
for (int i = 0; i < 30; ++i) {
bool overuse = GenerateAndProcessFrame(kDummySsrc, bitrate_bps);
// The purpose of this test is to ensure that we back down even if we don't
// have any acknowledged bitrate estimate yet. Hence, if the test works
// as expected, we should not have a measured bitrate yet.
EXPECT_FALSE(acknowledged_bitrate_estimator_->bitrate_bps().has_value());
if (overuse) {
EXPECT_TRUE(bitrate_observer_.updated());
EXPECT_NEAR(bitrate_observer_.latest_bitrate(), kStartBitrate / 2, 15000);
bitrate_bps = bitrate_observer_.latest_bitrate();
seen_overuse = true;
break;
} else if (bitrate_observer_.updated()) {
bitrate_bps = bitrate_observer_.latest_bitrate();
bitrate_observer_.Reset();
}
}
EXPECT_TRUE(seen_overuse);
EXPECT_NEAR(bitrate_observer_.latest_bitrate(), kStartBitrate / 2, 15000);
}
} // namespace webrtc
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