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/*
* Copyright (c) 2019 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 "test/pc/e2e/peer_connection_quality_test.h"
#include <algorithm>
#include <memory>
#include <set>
#include <utility>
#include "absl/strings/string_view.h"
#include "api/jsep.h"
#include "api/media_stream_interface.h"
#include "api/peer_connection_interface.h"
#include "api/rtc_event_log/rtc_event_log.h"
#include "api/rtc_event_log_output_file.h"
#include "api/scoped_refptr.h"
#include "api/test/time_controller.h"
#include "api/test/video_quality_analyzer_interface.h"
#include "pc/sdp_utils.h"
#include "pc/test/mock_peer_connection_observers.h"
#include "rtc_base/gunit.h"
#include "rtc_base/numerics/safe_conversions.h"
#include "rtc_base/strings/string_builder.h"
#include "system_wrappers/include/cpu_info.h"
#include "system_wrappers/include/field_trial.h"
#include "test/field_trial.h"
#include "test/pc/e2e/analyzer/audio/default_audio_quality_analyzer.h"
#include "test/pc/e2e/analyzer/video/default_video_quality_analyzer.h"
#include "test/pc/e2e/analyzer/video/video_quality_metrics_reporter.h"
#include "test/pc/e2e/cross_media_metrics_reporter.h"
#include "test/pc/e2e/stats_poller.h"
#include "test/pc/e2e/test_peer_factory.h"
#include "test/testsupport/file_utils.h"
#include "test/testsupport/perf_test.h"
namespace webrtc {
namespace webrtc_pc_e2e {
namespace {
using VideoConfig = PeerConnectionE2EQualityTestFixture::VideoConfig;
using VideoCodecConfig = PeerConnectionE2EQualityTestFixture::VideoCodecConfig;
constexpr TimeDelta kDefaultTimeout = TimeDelta::Seconds(10);
constexpr char kSignalThreadName[] = "signaling_thread";
// 1 signaling, 2 network, 2 worker and 2 extra for codecs etc.
constexpr int kPeerConnectionUsedThreads = 7;
// Framework has extra thread for network layer and extra thread for peer
// connection stats polling.
constexpr int kFrameworkUsedThreads = 2;
constexpr int kMaxVideoAnalyzerThreads = 8;
constexpr TimeDelta kStatsUpdateInterval = TimeDelta::Seconds(1);
constexpr TimeDelta kAliveMessageLogInterval = TimeDelta::Seconds(30);
constexpr TimeDelta kQuickTestModeRunDuration = TimeDelta::Millis(100);
// Field trials to enable Flex FEC advertising and receiving.
constexpr char kFlexFecEnabledFieldTrials[] =
"WebRTC-FlexFEC-03-Advertised/Enabled/WebRTC-FlexFEC-03/Enabled/";
constexpr char kUseStandardsBytesStats[] =
"WebRTC-UseStandardBytesStats/Enabled/";
class FixturePeerConnectionObserver : public MockPeerConnectionObserver {
public:
// `on_track_callback` will be called when any new track will be added to peer
// connection.
// `on_connected_callback` will be called when peer connection will come to
// either connected or completed state. Client should notice that in the case
// of reconnect this callback can be called again, so it should be tolerant
// to such behavior.
FixturePeerConnectionObserver(
std::function<void(rtc::scoped_refptr<RtpTransceiverInterface>)>
on_track_callback,
std::function<void()> on_connected_callback)
: on_track_callback_(std::move(on_track_callback)),
on_connected_callback_(std::move(on_connected_callback)) {}
void OnTrack(
rtc::scoped_refptr<RtpTransceiverInterface> transceiver) override {
MockPeerConnectionObserver::OnTrack(transceiver);
on_track_callback_(transceiver);
}
void OnIceConnectionChange(
PeerConnectionInterface::IceConnectionState new_state) override {
MockPeerConnectionObserver::OnIceConnectionChange(new_state);
if (ice_connected_) {
on_connected_callback_();
}
}
private:
std::function<void(rtc::scoped_refptr<RtpTransceiverInterface>)>
on_track_callback_;
std::function<void()> on_connected_callback_;
};
} // namespace
PeerConnectionE2EQualityTest::PeerConnectionE2EQualityTest(
std::string test_case_name,
TimeController& time_controller,
std::unique_ptr<AudioQualityAnalyzerInterface> audio_quality_analyzer,
std::unique_ptr<VideoQualityAnalyzerInterface> video_quality_analyzer)
: time_controller_(time_controller),
task_queue_factory_(time_controller_.CreateTaskQueueFactory()),
test_case_name_(std::move(test_case_name)),
executor_(std::make_unique<TestActivitiesExecutor>(
time_controller_.GetClock())) {
// Create default video quality analyzer. We will always create an analyzer,
// even if there are no video streams, because it will be installed into video
// encoder/decoder factories.
if (video_quality_analyzer == nullptr) {
video_quality_analyzer = std::make_unique<DefaultVideoQualityAnalyzer>(
time_controller_.GetClock());
}
encoded_image_data_propagator_ =
std::make_unique<SingleProcessEncodedImageDataInjector>();
video_quality_analyzer_injection_helper_ =
std::make_unique<VideoQualityAnalyzerInjectionHelper>(
std::move(video_quality_analyzer),
encoded_image_data_propagator_.get(),
encoded_image_data_propagator_.get());
if (audio_quality_analyzer == nullptr) {
audio_quality_analyzer = std::make_unique<DefaultAudioQualityAnalyzer>();
}
audio_quality_analyzer_.swap(audio_quality_analyzer);
}
void PeerConnectionE2EQualityTest::ExecuteAt(
TimeDelta target_time_since_start,
std::function<void(TimeDelta)> func) {
executor_->ScheduleActivity(target_time_since_start, absl::nullopt, func);
}
void PeerConnectionE2EQualityTest::ExecuteEvery(
TimeDelta initial_delay_since_start,
TimeDelta interval,
std::function<void(TimeDelta)> func) {
executor_->ScheduleActivity(initial_delay_since_start, interval, func);
}
void PeerConnectionE2EQualityTest::AddQualityMetricsReporter(
std::unique_ptr<QualityMetricsReporter> quality_metrics_reporter) {
quality_metrics_reporters_.push_back(std::move(quality_metrics_reporter));
}
void PeerConnectionE2EQualityTest::AddPeer(
rtc::Thread* network_thread,
rtc::NetworkManager* network_manager,
rtc::FunctionView<void(PeerConfigurer*)> configurer) {
peer_configurations_.push_back(
std::make_unique<PeerConfigurerImpl>(network_thread, network_manager));
configurer(peer_configurations_.back().get());
}
void PeerConnectionE2EQualityTest::Run(RunParams run_params) {
SetDefaultValuesForMissingParams(&run_params, &peer_configurations_);
ValidateParams(run_params, peer_configurations_);
RTC_CHECK_EQ(peer_configurations_.size(), 2)
<< "Only peer to peer calls are allowed, please add 2 peers";
std::unique_ptr<PeerConfigurerImpl> alice_configurer =
std::move(peer_configurations_[0]);
std::unique_ptr<PeerConfigurerImpl> bob_configurer =
std::move(peer_configurations_[1]);
peer_configurations_.clear();
for (size_t i = 0; i < bob_configurer->params()->video_configs.size(); ++i) {
// We support simulcast only from caller.
RTC_CHECK(!bob_configurer->params()->video_configs[i].simulcast_config)
<< "Only simulcast stream from first peer is supported";
}
test::ScopedFieldTrials field_trials(GetFieldTrials(run_params));
// Print test summary
RTC_LOG(INFO) << "Media quality test: " << *alice_configurer->params()->name
<< " will make a call to " << *bob_configurer->params()->name
<< " with media video="
<< !alice_configurer->params()->video_configs.empty()
<< "; audio="
<< alice_configurer->params()->audio_config.has_value() << ". "
<< *bob_configurer->params()->name
<< " will respond with media video="
<< !bob_configurer->params()->video_configs.empty()
<< "; audio="
<< bob_configurer->params()->audio_config.has_value();
const std::unique_ptr<rtc::Thread> signaling_thread =
time_controller_.CreateThread(kSignalThreadName);
media_helper_ = std::make_unique<MediaHelper>(
video_quality_analyzer_injection_helper_.get(), task_queue_factory_.get(),
time_controller_.GetClock());
// Create a `task_queue_`.
task_queue_ = std::make_unique<webrtc::TaskQueueForTest>(
time_controller_.GetTaskQueueFactory()->CreateTaskQueue(
"pc_e2e_quality_test", webrtc::TaskQueueFactory::Priority::NORMAL));
// Create call participants: Alice and Bob.
// Audio streams are intercepted in AudioDeviceModule, so if it is required to
// catch output of Alice's stream, Alice's output_dump_file_name should be
// passed to Bob's TestPeer setup as audio output file name.
absl::optional<RemotePeerAudioConfig> alice_remote_audio_config =
RemotePeerAudioConfig::Create(bob_configurer->params()->audio_config);
absl::optional<RemotePeerAudioConfig> bob_remote_audio_config =
RemotePeerAudioConfig::Create(alice_configurer->params()->audio_config);
// Copy Alice and Bob video configs and names to correctly pass them into
// lambdas.
std::vector<VideoConfig> alice_video_configs =
alice_configurer->params()->video_configs;
std::string alice_name = alice_configurer->params()->name.value();
std::vector<VideoConfig> bob_video_configs =
bob_configurer->params()->video_configs;
std::string bob_name = bob_configurer->params()->name.value();
TestPeerFactory test_peer_factory(
signaling_thread.get(), time_controller_,
video_quality_analyzer_injection_helper_.get(), task_queue_.get());
alice_ = test_peer_factory.CreateTestPeer(
std::move(alice_configurer),
std::make_unique<FixturePeerConnectionObserver>(
[this, bob_video_configs, alice_name](
rtc::scoped_refptr<RtpTransceiverInterface> transceiver) {
OnTrackCallback(alice_name, transceiver, bob_video_configs);
},
[this]() { StartVideo(alice_video_sources_); }),
alice_remote_audio_config, run_params.video_encoder_bitrate_multiplier,
run_params.echo_emulation_config);
bob_ = test_peer_factory.CreateTestPeer(
std::move(bob_configurer),
std::make_unique<FixturePeerConnectionObserver>(
[this, alice_video_configs,
bob_name](rtc::scoped_refptr<RtpTransceiverInterface> transceiver) {
OnTrackCallback(bob_name, transceiver, alice_video_configs);
},
[this]() { StartVideo(bob_video_sources_); }),
bob_remote_audio_config, run_params.video_encoder_bitrate_multiplier,
run_params.echo_emulation_config);
int num_cores = CpuInfo::DetectNumberOfCores();
RTC_DCHECK_GE(num_cores, 1);
int video_analyzer_threads =
num_cores - kPeerConnectionUsedThreads - kFrameworkUsedThreads;
if (video_analyzer_threads <= 0) {
video_analyzer_threads = 1;
}
video_analyzer_threads =
std::min(video_analyzer_threads, kMaxVideoAnalyzerThreads);
RTC_LOG(INFO) << "video_analyzer_threads=" << video_analyzer_threads;
quality_metrics_reporters_.push_back(
std::make_unique<VideoQualityMetricsReporter>(
time_controller_.GetClock()));
quality_metrics_reporters_.push_back(
std::make_unique<CrossMediaMetricsReporter>());
video_quality_analyzer_injection_helper_->Start(
test_case_name_,
std::vector<std::string>{alice_->params()->name.value(),
bob_->params()->name.value()},
video_analyzer_threads);
audio_quality_analyzer_->Start(test_case_name_, &analyzer_helper_);
for (auto& reporter : quality_metrics_reporters_) {
reporter->Start(test_case_name_, &analyzer_helper_);
}
// Start RTCEventLog recording if requested.
if (alice_->params()->rtc_event_log_path) {
auto alice_rtc_event_log = std::make_unique<webrtc::RtcEventLogOutputFile>(
alice_->params()->rtc_event_log_path.value());
alice_->pc()->StartRtcEventLog(std::move(alice_rtc_event_log),
webrtc::RtcEventLog::kImmediateOutput);
}
if (bob_->params()->rtc_event_log_path) {
auto bob_rtc_event_log = std::make_unique<webrtc::RtcEventLogOutputFile>(
bob_->params()->rtc_event_log_path.value());
bob_->pc()->StartRtcEventLog(std::move(bob_rtc_event_log),
webrtc::RtcEventLog::kImmediateOutput);
}
// Setup alive logging. It is done to prevent test infra to think that test is
// dead.
RepeatingTaskHandle::DelayedStart(task_queue_->Get(),
kAliveMessageLogInterval, []() {
std::printf("Test is still running...\n");
return kAliveMessageLogInterval;
});
RTC_LOG(INFO) << "Configuration is done. Now " << *alice_->params()->name
<< " is calling to " << *bob_->params()->name << "...";
// Setup stats poller.
std::vector<StatsObserverInterface*> observers = {
audio_quality_analyzer_.get(),
video_quality_analyzer_injection_helper_.get()};
for (auto& reporter : quality_metrics_reporters_) {
observers.push_back(reporter.get());
}
StatsPoller stats_poller(observers, {{*alice_->params()->name, alice_.get()},
{*bob_->params()->name, bob_.get()}});
executor_->ScheduleActivity(TimeDelta::Zero(), kStatsUpdateInterval,
[&stats_poller](TimeDelta) {
stats_poller.PollStatsAndNotifyObservers();
});
// Setup call.
signaling_thread->Invoke<void>(RTC_FROM_HERE, [this, &run_params] {
SetupCallOnSignalingThread(run_params);
});
std::unique_ptr<SignalingInterceptor> signaling_interceptor =
CreateSignalingInterceptor(run_params);
// Connect peers.
signaling_thread->Invoke<void>(RTC_FROM_HERE, [this, &signaling_interceptor] {
ExchangeOfferAnswer(signaling_interceptor.get());
});
WaitUntilIceCandidatesGathered(signaling_thread.get());
signaling_thread->Invoke<void>(RTC_FROM_HERE, [this, &signaling_interceptor] {
ExchangeIceCandidates(signaling_interceptor.get());
});
WaitUntilPeersAreConnected(signaling_thread.get());
executor_->Start(task_queue_.get());
Timestamp start_time = Now();
bool is_quick_test_enabled = field_trial::IsEnabled("WebRTC-QuickPerfTest");
if (is_quick_test_enabled) {
time_controller_.AdvanceTime(kQuickTestModeRunDuration);
} else {
time_controller_.AdvanceTime(run_params.run_duration);
}
RTC_LOG(INFO) << "Test is done, initiating disconnect sequence.";
// Stop all client started tasks to prevent their access to any call related
// objects after these objects will be destroyed during call tear down.
executor_->Stop();
// There is no guarantee, that last stats collection will happen at the end
// of the call, so we force it after executor, which is among others is doing
// stats collection, was stopped.
task_queue_->SendTask(
[&stats_poller]() {
// Get final end-of-call stats.
stats_poller.PollStatsAndNotifyObservers();
},
RTC_FROM_HERE);
// We need to detach AEC dumping from peers, because dump uses `task_queue_`
// inside.
alice_->DetachAecDump();
bob_->DetachAecDump();
// Tear down the call.
signaling_thread->Invoke<void>(RTC_FROM_HERE,
[this] { TearDownCallOnSignalingThread(); });
Timestamp end_time = Now();
RTC_LOG(INFO) << "All peers are disconnected.";
{
MutexLock lock(&lock_);
real_test_duration_ = end_time - start_time;
}
ReportGeneralTestResults();
audio_quality_analyzer_->Stop();
video_quality_analyzer_injection_helper_->Stop();
for (auto& reporter : quality_metrics_reporters_) {
reporter->StopAndReportResults();
}
// Reset `task_queue_` after test to cleanup.
task_queue_.reset();
alice_ = nullptr;
bob_ = nullptr;
// Ensuring that TestVideoCapturerVideoTrackSource are destroyed on the right
// thread.
RTC_CHECK(alice_video_sources_.empty());
RTC_CHECK(bob_video_sources_.empty());
}
std::string PeerConnectionE2EQualityTest::GetFieldTrials(
const RunParams& run_params) {
std::vector<absl::string_view> default_field_trials = {
kUseStandardsBytesStats};
if (run_params.use_flex_fec) {
default_field_trials.push_back(kFlexFecEnabledFieldTrials);
}
rtc::StringBuilder sb;
sb << field_trial::GetFieldTrialString();
for (const absl::string_view& field_trial : default_field_trials) {
sb << field_trial;
}
return sb.Release();
}
void PeerConnectionE2EQualityTest::OnTrackCallback(
absl::string_view peer_name,
rtc::scoped_refptr<RtpTransceiverInterface> transceiver,
std::vector<VideoConfig> remote_video_configs) {
const rtc::scoped_refptr<MediaStreamTrackInterface>& track =
transceiver->receiver()->track();
RTC_CHECK_EQ(transceiver->receiver()->stream_ids().size(), 2)
<< "Expected 2 stream ids: 1st - sync group, 2nd - unique stream label";
std::string sync_group = transceiver->receiver()->stream_ids()[0];
std::string stream_label = transceiver->receiver()->stream_ids()[1];
analyzer_helper_.AddTrackToStreamMapping(track->id(), stream_label,
sync_group);
if (track->kind() != MediaStreamTrackInterface::kVideoKind) {
return;
}
// It is safe to cast here, because it is checked above that
// track->kind() is kVideoKind.
auto* video_track = static_cast<VideoTrackInterface*>(track.get());
std::unique_ptr<rtc::VideoSinkInterface<VideoFrame>> video_sink =
video_quality_analyzer_injection_helper_->CreateVideoSink(peer_name);
video_track->AddOrUpdateSink(video_sink.get(), rtc::VideoSinkWants());
output_video_sinks_.push_back(std::move(video_sink));
}
void PeerConnectionE2EQualityTest::SetupCallOnSignalingThread(
const RunParams& run_params) {
// We need receive-only transceivers for Bob's media stream, so there will
// be media section in SDP for that streams in Alice's offer, because it is
// forbidden to add new media sections in answer in Unified Plan.
RtpTransceiverInit receive_only_transceiver_init;
receive_only_transceiver_init.direction = RtpTransceiverDirection::kRecvOnly;
int alice_transceivers_counter = 0;
if (bob_->params()->audio_config) {
// Setup receive audio transceiver if Bob has audio to send. If we'll need
// multiple audio streams, then we need transceiver for each Bob's audio
// stream.
RTCErrorOr<rtc::scoped_refptr<RtpTransceiverInterface>> result =
alice_->AddTransceiver(cricket::MediaType::MEDIA_TYPE_AUDIO,
receive_only_transceiver_init);
RTC_CHECK(result.ok());
alice_transceivers_counter++;
}
size_t alice_video_transceivers_non_simulcast_counter = 0;
for (auto& video_config : alice_->params()->video_configs) {
RtpTransceiverInit transceiver_params;
if (video_config.simulcast_config) {
transceiver_params.direction = RtpTransceiverDirection::kSendOnly;
// Because simulcast enabled `alice_->params()->video_codecs` has only 1
// element.
if (alice_->params()->video_codecs[0].name == cricket::kVp8CodecName) {
// For Vp8 simulcast we need to add as many RtpEncodingParameters to the
// track as many simulcast streams requested. If they specified in
// `video_config.simulcast_config` it should be copied from there.
for (int i = 0;
i < video_config.simulcast_config->simulcast_streams_count; ++i) {
RtpEncodingParameters enc_params;
if (video_config.simulcast_config->encoding_params.size() > 0) {
enc_params = video_config.simulcast_config->encoding_params[i];
}
// We need to be sure, that all rids will be unique with all mids.
enc_params.rid = std::to_string(alice_transceivers_counter) + "000" +
std::to_string(i);
transceiver_params.send_encodings.push_back(enc_params);
}
}
} else {
transceiver_params.direction = RtpTransceiverDirection::kSendRecv;
RtpEncodingParameters enc_params;
enc_params.max_bitrate_bps = video_config.max_encode_bitrate_bps;
enc_params.min_bitrate_bps = video_config.min_encode_bitrate_bps;
transceiver_params.send_encodings.push_back(enc_params);
alice_video_transceivers_non_simulcast_counter++;
}
RTCErrorOr<rtc::scoped_refptr<RtpTransceiverInterface>> result =
alice_->AddTransceiver(cricket::MediaType::MEDIA_TYPE_VIDEO,
transceiver_params);
RTC_CHECK(result.ok());
alice_transceivers_counter++;
}
// Add receive only transceivers in case Bob has more video_configs than
// Alice.
for (size_t i = alice_video_transceivers_non_simulcast_counter;
i < bob_->params()->video_configs.size(); ++i) {
RTCErrorOr<rtc::scoped_refptr<RtpTransceiverInterface>> result =
alice_->AddTransceiver(cricket::MediaType::MEDIA_TYPE_VIDEO,
receive_only_transceiver_init);
RTC_CHECK(result.ok());
alice_transceivers_counter++;
}
// Then add media for Alice and Bob
media_helper_->MaybeAddAudio(alice_.get());
alice_video_sources_ = media_helper_->MaybeAddVideo(alice_.get());
media_helper_->MaybeAddAudio(bob_.get());
bob_video_sources_ = media_helper_->MaybeAddVideo(bob_.get());
SetPeerCodecPreferences(alice_.get(), run_params);
SetPeerCodecPreferences(bob_.get(), run_params);
}
void PeerConnectionE2EQualityTest::TearDownCallOnSignalingThread() {
TearDownCall();
}
void PeerConnectionE2EQualityTest::SetPeerCodecPreferences(
TestPeer* peer,
const RunParams& run_params) {
std::vector<RtpCodecCapability> with_rtx_video_capabilities =
FilterVideoCodecCapabilities(
peer->params()->video_codecs, true, run_params.use_ulp_fec,
run_params.use_flex_fec,
peer->pc_factory()
->GetRtpSenderCapabilities(cricket::MediaType::MEDIA_TYPE_VIDEO)
.codecs);
std::vector<RtpCodecCapability> without_rtx_video_capabilities =
FilterVideoCodecCapabilities(
peer->params()->video_codecs, false, run_params.use_ulp_fec,
run_params.use_flex_fec,
peer->pc_factory()
->GetRtpSenderCapabilities(cricket::MediaType::MEDIA_TYPE_VIDEO)
.codecs);
// Set codecs for transceivers
for (auto transceiver : peer->pc()->GetTransceivers()) {
if (transceiver->media_type() == cricket::MediaType::MEDIA_TYPE_VIDEO) {
if (transceiver->sender()->init_send_encodings().size() > 1) {
// If transceiver's sender has more then 1 send encodings, it means it
// has multiple simulcast streams, so we need disable RTX on it.
RTCError result =
transceiver->SetCodecPreferences(without_rtx_video_capabilities);
RTC_CHECK(result.ok());
} else {
RTCError result =
transceiver->SetCodecPreferences(with_rtx_video_capabilities);
RTC_CHECK(result.ok());
}
}
}
}
std::unique_ptr<SignalingInterceptor>
PeerConnectionE2EQualityTest::CreateSignalingInterceptor(
const RunParams& run_params) {
std::map<std::string, int> stream_label_to_simulcast_streams_count;
// We add only Alice here, because simulcast/svc is supported only from the
// first peer.
for (auto& video_config : alice_->params()->video_configs) {
if (video_config.simulcast_config) {
stream_label_to_simulcast_streams_count.insert(
{*video_config.stream_label,
video_config.simulcast_config->simulcast_streams_count});
}
}
PatchingParams patching_params(run_params.use_conference_mode,
stream_label_to_simulcast_streams_count);
return std::make_unique<SignalingInterceptor>(patching_params);
}
void PeerConnectionE2EQualityTest::WaitUntilIceCandidatesGathered(
rtc::Thread* signaling_thread) {
ASSERT_TRUE(time_controller_.Wait(
[&]() {
return signaling_thread->Invoke<bool>(RTC_FROM_HERE, [&]() {
return alice_->IsIceGatheringDone() && bob_->IsIceGatheringDone();
});
},
2 * kDefaultTimeout));
}
void PeerConnectionE2EQualityTest::WaitUntilPeersAreConnected(
rtc::Thread* signaling_thread) {
// This means that ICE and DTLS are connected.
alice_connected_ = time_controller_.Wait(
[&]() {
return signaling_thread->Invoke<bool>(
RTC_FROM_HERE, [&]() { return alice_->IsIceConnected(); });
},
kDefaultTimeout);
bob_connected_ = time_controller_.Wait(
[&]() {
return signaling_thread->Invoke<bool>(
RTC_FROM_HERE, [&]() { return bob_->IsIceConnected(); });
},
kDefaultTimeout);
}
void PeerConnectionE2EQualityTest::ExchangeOfferAnswer(
SignalingInterceptor* signaling_interceptor) {
std::string log_output;
auto offer = alice_->CreateOffer();
RTC_CHECK(offer);
offer->ToString(&log_output);
RTC_LOG(INFO) << "Original offer: " << log_output;
LocalAndRemoteSdp patch_result = signaling_interceptor->PatchOffer(
std::move(offer), alice_->params()->video_codecs[0]);
patch_result.local_sdp->ToString(&log_output);
RTC_LOG(INFO) << "Offer to set as local description: " << log_output;
patch_result.remote_sdp->ToString(&log_output);
RTC_LOG(INFO) << "Offer to set as remote description: " << log_output;
bool set_local_offer =
alice_->SetLocalDescription(std::move(patch_result.local_sdp));
RTC_CHECK(set_local_offer);
bool set_remote_offer =
bob_->SetRemoteDescription(std::move(patch_result.remote_sdp));
RTC_CHECK(set_remote_offer);
auto answer = bob_->CreateAnswer();
RTC_CHECK(answer);
answer->ToString(&log_output);
RTC_LOG(INFO) << "Original answer: " << log_output;
patch_result = signaling_interceptor->PatchAnswer(
std::move(answer), bob_->params()->video_codecs[0]);
patch_result.local_sdp->ToString(&log_output);
RTC_LOG(INFO) << "Answer to set as local description: " << log_output;
patch_result.remote_sdp->ToString(&log_output);
RTC_LOG(INFO) << "Answer to set as remote description: " << log_output;
bool set_local_answer =
bob_->SetLocalDescription(std::move(patch_result.local_sdp));
RTC_CHECK(set_local_answer);
bool set_remote_answer =
alice_->SetRemoteDescription(std::move(patch_result.remote_sdp));
RTC_CHECK(set_remote_answer);
}
void PeerConnectionE2EQualityTest::ExchangeIceCandidates(
SignalingInterceptor* signaling_interceptor) {
// Connect an ICE candidate pairs.
std::vector<std::unique_ptr<IceCandidateInterface>> alice_candidates =
signaling_interceptor->PatchOffererIceCandidates(
alice_->observer()->GetAllCandidates());
for (auto& candidate : alice_candidates) {
std::string candidate_str;
RTC_CHECK(candidate->ToString(&candidate_str));
RTC_LOG(INFO) << *alice_->params()->name
<< " ICE candidate(mid= " << candidate->sdp_mid()
<< "): " << candidate_str;
}
ASSERT_TRUE(bob_->AddIceCandidates(std::move(alice_candidates)));
std::vector<std::unique_ptr<IceCandidateInterface>> bob_candidates =
signaling_interceptor->PatchAnswererIceCandidates(
bob_->observer()->GetAllCandidates());
for (auto& candidate : bob_candidates) {
std::string candidate_str;
RTC_CHECK(candidate->ToString(&candidate_str));
RTC_LOG(INFO) << *bob_->params()->name
<< " ICE candidate(mid= " << candidate->sdp_mid()
<< "): " << candidate_str;
}
ASSERT_TRUE(alice_->AddIceCandidates(std::move(bob_candidates)));
}
void PeerConnectionE2EQualityTest::StartVideo(
const std::vector<rtc::scoped_refptr<TestVideoCapturerVideoTrackSource>>&
sources) {
for (auto& source : sources) {
if (source->state() != MediaSourceInterface::SourceState::kLive) {
source->Start();
}
}
}
void PeerConnectionE2EQualityTest::TearDownCall() {
for (const auto& video_source : alice_video_sources_) {
video_source->Stop();
}
for (const auto& video_source : bob_video_sources_) {
video_source->Stop();
}
alice_video_sources_.clear();
bob_video_sources_.clear();
alice_->Close();
bob_->Close();
media_helper_ = nullptr;
}
void PeerConnectionE2EQualityTest::ReportGeneralTestResults() {
test::PrintResult(*alice_->params()->name + "_connected", "", test_case_name_,
alice_connected_, "unitless",
/*important=*/false,
test::ImproveDirection::kBiggerIsBetter);
test::PrintResult(*bob_->params()->name + "_connected", "", test_case_name_,
bob_connected_, "unitless",
/*important=*/false,
test::ImproveDirection::kBiggerIsBetter);
}
Timestamp PeerConnectionE2EQualityTest::Now() const {
return time_controller_.GetClock()->CurrentTime();
}
} // namespace webrtc_pc_e2e
} // namespace webrtc