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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 <utility>
#include "modules/audio_coding/audio_network_adaptor/controller_manager.h"
#include "modules/audio_coding/audio_network_adaptor/mock/mock_controller.h"
#include "modules/audio_coding/audio_network_adaptor/mock/mock_debug_dump_writer.h"
#include "rtc_base/fakeclock.h"
#include "rtc_base/ignore_wundef.h"
#include "rtc_base/protobuf_utils.h"
#include "test/gtest.h"
#if WEBRTC_ENABLE_PROTOBUF
RTC_PUSH_IGNORING_WUNDEF()
#ifdef WEBRTC_ANDROID_PLATFORM_BUILD
#include "external/webrtc/webrtc/modules/audio_coding/audio_network_adaptor/config.pb.h"
#else
#include "modules/audio_coding/audio_network_adaptor/config.pb.h"
#endif
RTC_POP_IGNORING_WUNDEF()
#endif
namespace webrtc {
using ::testing::_;
using ::testing::NiceMock;
namespace {
constexpr size_t kNumControllers = 4;
constexpr int kChracteristicBandwithBps[2] = {15000, 0};
constexpr float kChracteristicPacketLossFraction[2] = {0.2f, 0.0f};
constexpr int kMinReorderingTimeMs = 200;
constexpr int kFactor = 100;
constexpr float kMinReorderingSquareDistance = 1.0f / kFactor / kFactor;
// |kMinUplinkBandwidthBps| and |kMaxUplinkBandwidthBps| are copied from
// controller_manager.cc
constexpr int kMinUplinkBandwidthBps = 0;
constexpr int kMaxUplinkBandwidthBps = 120000;
constexpr int kMinBandwithChangeBps =
(kMaxUplinkBandwidthBps - kMinUplinkBandwidthBps) / kFactor;
struct ControllerManagerStates {
std::unique_ptr<ControllerManager> controller_manager;
std::vector<MockController*> mock_controllers;
};
ControllerManagerStates CreateControllerManager() {
ControllerManagerStates states;
std::vector<std::unique_ptr<Controller>> controllers;
std::map<const Controller*, std::pair<int, float>> chracteristic_points;
for (size_t i = 0; i < kNumControllers; ++i) {
auto controller =
std::unique_ptr<MockController>(new NiceMock<MockController>());
EXPECT_CALL(*controller, Die());
states.mock_controllers.push_back(controller.get());
controllers.push_back(std::move(controller));
}
// Assign characteristic points to the last two controllers.
chracteristic_points[states.mock_controllers[kNumControllers - 2]] =
std::make_pair(kChracteristicBandwithBps[0],
kChracteristicPacketLossFraction[0]);
chracteristic_points[states.mock_controllers[kNumControllers - 1]] =
std::make_pair(kChracteristicBandwithBps[1],
kChracteristicPacketLossFraction[1]);
states.controller_manager.reset(new ControllerManagerImpl(
ControllerManagerImpl::Config(kMinReorderingTimeMs,
kMinReorderingSquareDistance),
std::move(controllers), chracteristic_points));
return states;
}
// |expected_order| contains the expected indices of all controllers in the
// vector of controllers returned by GetSortedControllers(). A negative index
// means that we do not care about its exact place, but we do check that it
// exists in the vector.
void CheckControllersOrder(
ControllerManagerStates* states,
const absl::optional<int>& uplink_bandwidth_bps,
const absl::optional<float>& uplink_packet_loss_fraction,
const std::vector<int>& expected_order) {
RTC_DCHECK_EQ(kNumControllers, expected_order.size());
Controller::NetworkMetrics metrics;
metrics.uplink_bandwidth_bps = uplink_bandwidth_bps;
metrics.uplink_packet_loss_fraction = uplink_packet_loss_fraction;
auto check = states->controller_manager->GetSortedControllers(metrics);
EXPECT_EQ(states->mock_controllers.size(), check.size());
for (size_t i = 0; i < states->mock_controllers.size(); ++i) {
if (expected_order[i] >= 0) {
EXPECT_EQ(states->mock_controllers[i], check[expected_order[i]]);
} else {
EXPECT_NE(check.end(), std::find(check.begin(), check.end(),
states->mock_controllers[i]));
}
}
}
} // namespace
TEST(ControllerManagerTest, GetControllersReturnAllControllers) {
auto states = CreateControllerManager();
auto check = states.controller_manager->GetControllers();
// Verify that controllers in |check| are one-to-one mapped to those in
// |mock_controllers_|.
EXPECT_EQ(states.mock_controllers.size(), check.size());
for (auto& controller : check)
EXPECT_NE(states.mock_controllers.end(),
std::find(states.mock_controllers.begin(),
states.mock_controllers.end(), controller));
}
TEST(ControllerManagerTest, ControllersInDefaultOrderOnEmptyNetworkMetrics) {
auto states = CreateControllerManager();
// |network_metrics| are empty, and the controllers are supposed to follow the
// default order.
CheckControllersOrder(&states, absl::nullopt, absl::nullopt, {0, 1, 2, 3});
}
TEST(ControllerManagerTest, ControllersWithoutCharPointAtEndAndInDefaultOrder) {
auto states = CreateControllerManager();
CheckControllersOrder(&states, 0,
0.0,
{kNumControllers - 2, kNumControllers - 1, -1, -1});
}
TEST(ControllerManagerTest, ControllersWithCharPointDependOnNetworkMetrics) {
auto states = CreateControllerManager();
CheckControllersOrder(&states, kChracteristicBandwithBps[1],
kChracteristicPacketLossFraction[1],
{kNumControllers - 2, kNumControllers - 1, 1, 0});
}
TEST(ControllerManagerTest, DoNotReorderBeforeMinReordingTime) {
rtc::ScopedFakeClock fake_clock;
auto states = CreateControllerManager();
CheckControllersOrder(&states, kChracteristicBandwithBps[0],
kChracteristicPacketLossFraction[0],
{kNumControllers - 2, kNumControllers - 1, 0, 1});
fake_clock.AdvanceTime(TimeDelta::ms(kMinReorderingTimeMs - 1));
// Move uplink bandwidth and packet loss fraction to the other controller's
// characteristic point, which would cause controller manager to reorder the
// controllers if time had reached min reordering time.
CheckControllersOrder(&states, kChracteristicBandwithBps[1],
kChracteristicPacketLossFraction[1],
{kNumControllers - 2, kNumControllers - 1, 0, 1});
}
TEST(ControllerManagerTest, ReorderBeyondMinReordingTimeAndMinDistance) {
rtc::ScopedFakeClock fake_clock;
auto states = CreateControllerManager();
constexpr int kBandwidthBps =
(kChracteristicBandwithBps[0] + kChracteristicBandwithBps[1]) / 2;
constexpr float kPacketLossFraction = (kChracteristicPacketLossFraction[0] +
kChracteristicPacketLossFraction[1]) /
2.0f;
// Set network metrics to be in the middle between the characteristic points
// of two controllers.
CheckControllersOrder(&states, kBandwidthBps, kPacketLossFraction,
{kNumControllers - 2, kNumControllers - 1, 0, 1});
fake_clock.AdvanceTime(TimeDelta::ms(kMinReorderingTimeMs));
// Then let network metrics move a little towards the other controller.
CheckControllersOrder(&states, kBandwidthBps - kMinBandwithChangeBps - 1,
kPacketLossFraction,
{kNumControllers - 2, kNumControllers - 1, 1, 0});
}
TEST(ControllerManagerTest, DoNotReorderIfNetworkMetricsChangeTooSmall) {
rtc::ScopedFakeClock fake_clock;
auto states = CreateControllerManager();
constexpr int kBandwidthBps =
(kChracteristicBandwithBps[0] + kChracteristicBandwithBps[1]) / 2;
constexpr float kPacketLossFraction = (kChracteristicPacketLossFraction[0] +
kChracteristicPacketLossFraction[1]) /
2.0f;
// Set network metrics to be in the middle between the characteristic points
// of two controllers.
CheckControllersOrder(&states, kBandwidthBps, kPacketLossFraction,
{kNumControllers - 2, kNumControllers - 1, 0, 1});
fake_clock.AdvanceTime(TimeDelta::ms(kMinReorderingTimeMs));
// Then let network metrics move a little towards the other controller.
CheckControllersOrder(&states, kBandwidthBps - kMinBandwithChangeBps + 1,
kPacketLossFraction,
{kNumControllers - 2, kNumControllers - 1, 0, 1});
}
#if WEBRTC_ENABLE_PROTOBUF
namespace {
void AddBitrateControllerConfig(
audio_network_adaptor::config::ControllerManager* config) {
config->add_controllers()->mutable_bitrate_controller();
}
void AddChannelControllerConfig(
audio_network_adaptor::config::ControllerManager* config) {
auto controller_config =
config->add_controllers()->mutable_channel_controller();
controller_config->set_channel_1_to_2_bandwidth_bps(31000);
controller_config->set_channel_2_to_1_bandwidth_bps(29000);
}
void AddDtxControllerConfig(
audio_network_adaptor::config::ControllerManager* config) {
auto controller_config = config->add_controllers()->mutable_dtx_controller();
controller_config->set_dtx_enabling_bandwidth_bps(55000);
controller_config->set_dtx_disabling_bandwidth_bps(65000);
}
void AddFecControllerConfig(
audio_network_adaptor::config::ControllerManager* config) {
auto controller_config_ext = config->add_controllers();
auto controller_config = controller_config_ext->mutable_fec_controller();
auto fec_enabling_threshold =
controller_config->mutable_fec_enabling_threshold();
fec_enabling_threshold->set_low_bandwidth_bps(17000);
fec_enabling_threshold->set_low_bandwidth_packet_loss(0.1f);
fec_enabling_threshold->set_high_bandwidth_bps(64000);
fec_enabling_threshold->set_high_bandwidth_packet_loss(0.05f);
auto fec_disabling_threshold =
controller_config->mutable_fec_disabling_threshold();
fec_disabling_threshold->set_low_bandwidth_bps(15000);
fec_disabling_threshold->set_low_bandwidth_packet_loss(0.08f);
fec_disabling_threshold->set_high_bandwidth_bps(64000);
fec_disabling_threshold->set_high_bandwidth_packet_loss(0.01f);
controller_config->set_time_constant_ms(500);
auto scoring_point = controller_config_ext->mutable_scoring_point();
scoring_point->set_uplink_bandwidth_bps(kChracteristicBandwithBps[0]);
scoring_point->set_uplink_packet_loss_fraction(
kChracteristicPacketLossFraction[0]);
}
void AddFrameLengthControllerConfig(
audio_network_adaptor::config::ControllerManager* config) {
auto controller_config_ext = config->add_controllers();
auto controller_config =
controller_config_ext->mutable_frame_length_controller();
controller_config->set_fl_decreasing_packet_loss_fraction(0.05f);
controller_config->set_fl_increasing_packet_loss_fraction(0.04f);
controller_config->set_fl_20ms_to_60ms_bandwidth_bps(72000);
controller_config->set_fl_60ms_to_20ms_bandwidth_bps(88000);
auto scoring_point = controller_config_ext->mutable_scoring_point();
scoring_point->set_uplink_bandwidth_bps(kChracteristicBandwithBps[1]);
scoring_point->set_uplink_packet_loss_fraction(
kChracteristicPacketLossFraction[1]);
}
constexpr int kInitialBitrateBps = 24000;
constexpr size_t kIntialChannelsToEncode = 1;
constexpr bool kInitialDtxEnabled = true;
constexpr bool kInitialFecEnabled = true;
constexpr int kInitialFrameLengthMs = 60;
constexpr int kMinBitrateBps = 6000;
ControllerManagerStates CreateControllerManager(
const ProtoString& config_string) {
ControllerManagerStates states;
constexpr size_t kNumEncoderChannels = 2;
const std::vector<int> encoder_frame_lengths_ms = {20, 60};
states.controller_manager = ControllerManagerImpl::Create(
config_string, kNumEncoderChannels, encoder_frame_lengths_ms,
kMinBitrateBps, kIntialChannelsToEncode, kInitialFrameLengthMs,
kInitialBitrateBps, kInitialFecEnabled, kInitialDtxEnabled);
return states;
}
enum class ControllerType : int8_t {
FEC,
CHANNEL,
DTX,
FRAME_LENGTH,
BIT_RATE
};
void CheckControllersOrder(const std::vector<Controller*>& controllers,
const std::vector<ControllerType>& expected_types) {
ASSERT_EQ(expected_types.size(), controllers.size());
// We also check that the controllers follow the initial settings.
AudioEncoderRuntimeConfig encoder_config;
for (size_t i = 0; i < controllers.size(); ++i) {
AudioEncoderRuntimeConfig encoder_config;
// We check the order of |controllers| by judging their decisions.
controllers[i]->MakeDecision(&encoder_config);
// Since controllers are not provided with network metrics, they give the
// initial values.
switch (expected_types[i]) {
case ControllerType::FEC:
EXPECT_EQ(kInitialFecEnabled, encoder_config.enable_fec);
break;
case ControllerType::CHANNEL:
EXPECT_EQ(kIntialChannelsToEncode, encoder_config.num_channels);
break;
case ControllerType::DTX:
EXPECT_EQ(kInitialDtxEnabled, encoder_config.enable_dtx);
break;
case ControllerType::FRAME_LENGTH:
EXPECT_EQ(kInitialFrameLengthMs, encoder_config.frame_length_ms);
break;
case ControllerType::BIT_RATE:
EXPECT_EQ(kInitialBitrateBps, encoder_config.bitrate_bps);
}
}
}
MATCHER_P(ControllerManagerEqual, value, "") {
ProtoString value_string;
ProtoString arg_string;
EXPECT_TRUE(arg.SerializeToString(&arg_string));
EXPECT_TRUE(value.SerializeToString(&value_string));
return arg_string == value_string;
}
} // namespace
TEST(ControllerManagerTest, DebugDumpLoggedWhenCreateFromConfigString) {
audio_network_adaptor::config::ControllerManager config;
config.set_min_reordering_time_ms(kMinReorderingTimeMs);
config.set_min_reordering_squared_distance(kMinReorderingSquareDistance);
AddFecControllerConfig(&config);
AddChannelControllerConfig(&config);
AddDtxControllerConfig(&config);
AddFrameLengthControllerConfig(&config);
AddBitrateControllerConfig(&config);
ProtoString config_string;
config.SerializeToString(&config_string);
constexpr size_t kNumEncoderChannels = 2;
const std::vector<int> encoder_frame_lengths_ms = {20, 60};
constexpr int64_t kClockInitialTimeMs = 12345678;
rtc::ScopedFakeClock fake_clock;
fake_clock.AdvanceTime(TimeDelta::ms(kClockInitialTimeMs));
auto debug_dump_writer =
std::unique_ptr<MockDebugDumpWriter>(new NiceMock<MockDebugDumpWriter>());
EXPECT_CALL(*debug_dump_writer, Die());
EXPECT_CALL(*debug_dump_writer,
DumpControllerManagerConfig(ControllerManagerEqual(config),
kClockInitialTimeMs));
ControllerManagerImpl::Create(config_string, kNumEncoderChannels,
encoder_frame_lengths_ms, kMinBitrateBps,
kIntialChannelsToEncode, kInitialFrameLengthMs,
kInitialBitrateBps, kInitialFecEnabled,
kInitialDtxEnabled, debug_dump_writer.get());
}
TEST(ControllerManagerTest, CreateFromConfigStringAndCheckDefaultOrder) {
audio_network_adaptor::config::ControllerManager config;
config.set_min_reordering_time_ms(kMinReorderingTimeMs);
config.set_min_reordering_squared_distance(kMinReorderingSquareDistance);
AddFecControllerConfig(&config);
AddChannelControllerConfig(&config);
AddDtxControllerConfig(&config);
AddFrameLengthControllerConfig(&config);
AddBitrateControllerConfig(&config);
ProtoString config_string;
config.SerializeToString(&config_string);
auto states = CreateControllerManager(config_string);
Controller::NetworkMetrics metrics;
auto controllers = states.controller_manager->GetSortedControllers(metrics);
CheckControllersOrder(
controllers,
std::vector<ControllerType>{
ControllerType::FEC, ControllerType::CHANNEL, ControllerType::DTX,
ControllerType::FRAME_LENGTH, ControllerType::BIT_RATE});
}
TEST(ControllerManagerTest, CreateCharPointFreeConfigAndCheckDefaultOrder) {
audio_network_adaptor::config::ControllerManager config;
// Following controllers have no characteristic points.
AddChannelControllerConfig(&config);
AddDtxControllerConfig(&config);
AddBitrateControllerConfig(&config);
ProtoString config_string;
config.SerializeToString(&config_string);
auto states = CreateControllerManager(config_string);
Controller::NetworkMetrics metrics;
auto controllers = states.controller_manager->GetSortedControllers(metrics);
CheckControllersOrder(
controllers,
std::vector<ControllerType>{ControllerType::CHANNEL, ControllerType::DTX,
ControllerType::BIT_RATE});
}
TEST(ControllerManagerTest, CreateFromConfigStringAndCheckReordering) {
rtc::ScopedFakeClock fake_clock;
audio_network_adaptor::config::ControllerManager config;
config.set_min_reordering_time_ms(kMinReorderingTimeMs);
config.set_min_reordering_squared_distance(kMinReorderingSquareDistance);
AddChannelControllerConfig(&config);
// Internally associated with characteristic point 0.
AddFecControllerConfig(&config);
AddDtxControllerConfig(&config);
// Internally associated with characteristic point 1.
AddFrameLengthControllerConfig(&config);
AddBitrateControllerConfig(&config);
ProtoString config_string;
config.SerializeToString(&config_string);
auto states = CreateControllerManager(config_string);
Controller::NetworkMetrics metrics;
metrics.uplink_bandwidth_bps = kChracteristicBandwithBps[0];
metrics.uplink_packet_loss_fraction = kChracteristicPacketLossFraction[0];
auto controllers = states.controller_manager->GetSortedControllers(metrics);
CheckControllersOrder(controllers,
std::vector<ControllerType>{
ControllerType::FEC, ControllerType::FRAME_LENGTH,
ControllerType::CHANNEL, ControllerType::DTX,
ControllerType::BIT_RATE});
metrics.uplink_bandwidth_bps = kChracteristicBandwithBps[1];
metrics.uplink_packet_loss_fraction = kChracteristicPacketLossFraction[1];
fake_clock.AdvanceTime(TimeDelta::ms(kMinReorderingTimeMs - 1));
controllers = states.controller_manager->GetSortedControllers(metrics);
// Should not reorder since min reordering time is not met.
CheckControllersOrder(controllers,
std::vector<ControllerType>{
ControllerType::FEC, ControllerType::FRAME_LENGTH,
ControllerType::CHANNEL, ControllerType::DTX,
ControllerType::BIT_RATE});
fake_clock.AdvanceTime(TimeDelta::ms(1));
controllers = states.controller_manager->GetSortedControllers(metrics);
// Reorder now.
CheckControllersOrder(controllers,
std::vector<ControllerType>{
ControllerType::FRAME_LENGTH, ControllerType::FEC,
ControllerType::CHANNEL, ControllerType::DTX,
ControllerType::BIT_RATE});
}
#endif // WEBRTC_ENABLE_PROTOBUF
} // namespace webrtc