pc/test/integration_test_helpers.cc - src - Git at Google

 /*
  *  Copyright 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 "pc/test/integration_test_helpers.h"

 namespace webrtc {

 PeerConnectionInterface::RTCOfferAnswerOptions IceRestartOfferAnswerOptions() {
   PeerConnectionInterface::RTCOfferAnswerOptions options;
   options.ice_restart = true;
   return options;
 }

 void RemoveSsrcsAndMsids(cricket::SessionDescription* desc) {
   for (ContentInfo& content : desc->contents()) {
     content.media_description()->mutable_streams().clear();
   }
   desc->set_msid_signaling(0);
 }

 void RemoveSsrcsAndKeepMsids(cricket::SessionDescription* desc) {
   for (ContentInfo& content : desc->contents()) {
     std::string track_id;
     std::vector<std::string> stream_ids;
     if (!content.media_description()->streams().empty()) {
       const StreamParams& first_stream =
           content.media_description()->streams()[0];
       track_id = first_stream.id;
       stream_ids = first_stream.stream_ids();
     }
     content.media_description()->mutable_streams().clear();
     StreamParams new_stream;
     new_stream.id = track_id;
     new_stream.set_stream_ids(stream_ids);
     content.media_description()->AddStream(new_stream);
   }
 }

 int FindFirstMediaStatsIndexByKind(
     const std::string& kind,
     const std::vector<const RTCInboundRtpStreamStats*>& inbound_rtps) {
   for (size_t i = 0; i < inbound_rtps.size(); i++) {
     if (*inbound_rtps[i]->kind == kind) {
       return i;
     }
   }
   return -1;
 }

 void ReplaceFirstSsrc(StreamParams& stream, uint32_t ssrc) {
   stream.ssrcs[0] = ssrc;
   for (auto& group : stream.ssrc_groups) {
     group.ssrcs[0] = ssrc;
   }
 }

 TaskQueueMetronome::TaskQueueMetronome(TimeDelta tick_period)
     : tick_period_(tick_period) {}

 TaskQueueMetronome::~TaskQueueMetronome() {
   RTC_DCHECK_RUN_ON(&sequence_checker_);
 }
 void TaskQueueMetronome::RequestCallOnNextTick(
     absl::AnyInvocable<void() &&> callback) {
   RTC_DCHECK_RUN_ON(&sequence_checker_);
   callbacks_.push_back(std::move(callback));
   // Only schedule a tick callback for the first `callback` addition.
   // Schedule on the current task queue to comply with RequestCallOnNextTick
   // requirements.
   if (callbacks_.size() == 1) {
     TaskQueueBase::Current()->PostDelayedTask(
         SafeTask(safety_.flag(),
                  [this] {
                    RTC_DCHECK_RUN_ON(&sequence_checker_);
                    std::vector<absl::AnyInvocable<void() &&>> callbacks;
                    callbacks_.swap(callbacks);
                    for (auto& callback : callbacks)
                      std::move(callback)();
                  }),
         tick_period_);
   }
 }

 TimeDelta TaskQueueMetronome::TickPeriod() const {
   RTC_DCHECK_RUN_ON(&sequence_checker_);
   return tick_period_;
 }

 // Implementation of PeerConnectionIntegrationWrapper functions
 void PeerConnectionIntegrationWrapper::StartWatchingDelayStats() {
   // Get the baseline numbers for audio_packets and audio_delay.
   auto received_stats = NewGetStats();
   auto rtp_stats =
       received_stats->GetStatsOfType<RTCInboundRtpStreamStats>()[0];
   ASSERT_TRUE(rtp_stats->relative_packet_arrival_delay.has_value());
   ASSERT_TRUE(rtp_stats->packets_received.has_value());
   rtp_stats_id_ = rtp_stats->id();
   audio_packets_stat_ = *rtp_stats->packets_received;
   audio_delay_stat_ = *rtp_stats->relative_packet_arrival_delay;
   audio_samples_stat_ = *rtp_stats->total_samples_received;
   audio_concealed_stat_ = *rtp_stats->concealed_samples;
 }

 void PeerConnectionIntegrationWrapper::UpdateDelayStats(std::string tag,
                                                         int desc_size) {
   auto report = NewGetStats();
   auto rtp_stats = report->GetAs<RTCInboundRtpStreamStats>(rtp_stats_id_);
   ASSERT_TRUE(rtp_stats);
   auto delta_packets = *rtp_stats->packets_received - audio_packets_stat_;
   auto delta_rpad =
       *rtp_stats->relative_packet_arrival_delay - audio_delay_stat_;
   auto recent_delay = delta_packets > 0 ? delta_rpad / delta_packets : -1;
   // The purpose of these checks is to sound the alarm early if we introduce
   // serious regressions. The numbers are not acceptable for production, but
   // occur on slow bots.
   //
   // An average relative packet arrival delay over the renegotiation of
   // > 100 ms indicates that something is dramatically wrong, and will impact
   // quality for sure.
   // Worst bots:
   // linux_x86_dbg at 0.206
 #if !defined(NDEBUG)
   EXPECT_GT(0.25, recent_delay) << tag << " size " << desc_size;
 #else
   EXPECT_GT(0.1, recent_delay) << tag << " size " << desc_size;
 #endif
   auto delta_samples = *rtp_stats->total_samples_received - audio_samples_stat_;
   auto delta_concealed = *rtp_stats->concealed_samples - audio_concealed_stat_;
   // These limits should be adjusted down as we improve:
   //
   // Concealing more than 4000 samples during a renegotiation is unacceptable.
   // But some bots are slow.

   // Worst bots:
   // linux_more_configs bot at conceal count 5184
   // android_arm_rel at conceal count 9241
   // linux_x86_dbg at 15174
 #if !defined(NDEBUG)
   EXPECT_GT(18000U, delta_concealed) << "Concealed " << delta_concealed
                                      << " of " << delta_samples << " samples";
 #else
   EXPECT_GT(15000U, delta_concealed) << "Concealed " << delta_concealed
                                      << " of " << delta_samples << " samples";
 #endif
   // Concealing more than 20% of samples during a renegotiation is
   // unacceptable.
   // Worst bots:
   // Nondebug: Linux32 Release at conceal rate 0.606597 (CI run)
   // Debug: linux_x86_dbg bot at conceal rate 0.854
   //        internal bot at conceal rate 0.967 (b/294020344)
   // TODO(https://crbug.com/webrtc/15393): Improve audio quality during
   // renegotiation so that we can reduce these thresholds, 99% is not even
   // close to the 20% deemed unacceptable above or the 0% that would be ideal.
   if (delta_samples > 0) {
 #if !defined(NDEBUG)
     EXPECT_LT(1.0 * delta_concealed / delta_samples, 0.99)
         << "Concealed " << delta_concealed << " of " << delta_samples
         << " samples";
 #else
     EXPECT_LT(1.0 * delta_concealed / delta_samples, 0.7)
         << "Concealed " << delta_concealed << " of " << delta_samples
         << " samples";
 #endif
   }
   // Increment trailing counters
   audio_packets_stat_ = *rtp_stats->packets_received;
   audio_delay_stat_ = *rtp_stats->relative_packet_arrival_delay;
   audio_samples_stat_ = *rtp_stats->total_samples_received;
   audio_concealed_stat_ = *rtp_stats->concealed_samples;
 }

 bool PeerConnectionIntegrationWrapper::Init(
     const PeerConnectionFactory::Options* options,
     const PeerConnectionInterface::RTCConfiguration* config,
     PeerConnectionDependencies dependencies,
     rtc::SocketServer* socket_server,
     rtc::Thread* network_thread,
     rtc::Thread* worker_thread,
     std::unique_ptr<FakeRtcEventLogFactory> event_log_factory,
     bool reset_encoder_factory,
     bool reset_decoder_factory,
     bool create_media_engine) {
   // There's an error in this test code if Init ends up being called twice.
   RTC_DCHECK(!peer_connection_);
   RTC_DCHECK(!peer_connection_factory_);

   fake_network_manager_.reset(new rtc::FakeNetworkManager());
   fake_network_manager_->AddInterface(kDefaultLocalAddress);

   socket_factory_.reset(new rtc::BasicPacketSocketFactory(socket_server));

   std::unique_ptr<cricket::PortAllocator> port_allocator(
       new cricket::BasicPortAllocator(fake_network_manager_.get(),
                                       socket_factory_.get()));
   port_allocator_ = port_allocator.get();
   fake_audio_capture_module_ = FakeAudioCaptureModule::Create();
   if (!fake_audio_capture_module_) {
     return false;
   }
   rtc::Thread* const signaling_thread = rtc::Thread::Current();

   PeerConnectionFactoryDependencies pc_factory_dependencies;
   pc_factory_dependencies.network_thread = network_thread;
   pc_factory_dependencies.worker_thread = worker_thread;
   pc_factory_dependencies.signaling_thread = signaling_thread;
   pc_factory_dependencies.task_queue_factory = CreateDefaultTaskQueueFactory();
   pc_factory_dependencies.trials = std::make_unique<FieldTrialBasedConfig>();
   pc_factory_dependencies.decode_metronome =
       std::make_unique<TaskQueueMetronome>(TimeDelta::Millis(8));

   pc_factory_dependencies.adm = fake_audio_capture_module_;
   if (create_media_engine) {
     EnableMediaWithDefaults(pc_factory_dependencies);
   }

   if (reset_encoder_factory) {
     pc_factory_dependencies.video_encoder_factory.reset();
   }
   if (reset_decoder_factory) {
     pc_factory_dependencies.video_decoder_factory.reset();
   }

   if (!pc_factory_dependencies.audio_processing) {
     // If the standard Creation method for APM returns a null pointer, instead
     // use the builder for testing to create an APM object.
     pc_factory_dependencies.audio_processing =
         AudioProcessingBuilderForTesting().Create();
   }

   if (event_log_factory) {
     event_log_factory_ = event_log_factory.get();
     pc_factory_dependencies.event_log_factory = std::move(event_log_factory);
   } else {
     pc_factory_dependencies.event_log_factory =
         std::make_unique<RtcEventLogFactory>();
   }
   peer_connection_factory_ =
       CreateModularPeerConnectionFactory(std::move(pc_factory_dependencies));

   if (!peer_connection_factory_) {
     return false;
   }
   if (options) {
     peer_connection_factory_->SetOptions(*options);
   }
   if (config) {
     sdp_semantics_ = config->sdp_semantics;
   }

   dependencies.allocator = std::move(port_allocator);
   peer_connection_ = CreatePeerConnection(config, std::move(dependencies));
   return peer_connection_.get() != nullptr;
 }

 }  // namespace webrtc
	/*
	* Copyright 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 "pc/test/integration_test_helpers.h"

	namespace webrtc {

	PeerConnectionInterface::RTCOfferAnswerOptions IceRestartOfferAnswerOptions() {
	PeerConnectionInterface::RTCOfferAnswerOptions options;
	options.ice_restart = true;
	return options;
	}

	void RemoveSsrcsAndMsids(cricket::SessionDescription* desc) {
	for (ContentInfo& content : desc->contents()) {
	content.media_description()->mutable_streams().clear();
	}
	desc->set_msid_signaling(0);
	}

	void RemoveSsrcsAndKeepMsids(cricket::SessionDescription* desc) {
	for (ContentInfo& content : desc->contents()) {
	std::string track_id;
	std::vector<std::string> stream_ids;
	if (!content.media_description()->streams().empty()) {
	const StreamParams& first_stream =
	content.media_description()->streams()[0];
	track_id = first_stream.id;
	stream_ids = first_stream.stream_ids();
	}
	content.media_description()->mutable_streams().clear();
	StreamParams new_stream;
	new_stream.id = track_id;
	new_stream.set_stream_ids(stream_ids);
	content.media_description()->AddStream(new_stream);
	}
	}

	int FindFirstMediaStatsIndexByKind(
	const std::string& kind,
	const std::vector<const RTCInboundRtpStreamStats*>& inbound_rtps) {
	for (size_t i = 0; i < inbound_rtps.size(); i++) {
	if (*inbound_rtps[i]->kind == kind) {
	return i;
	}
	}
	return -1;
	}

	void ReplaceFirstSsrc(StreamParams& stream, uint32_t ssrc) {
	stream.ssrcs[0] = ssrc;
	for (auto& group : stream.ssrc_groups) {
	group.ssrcs[0] = ssrc;
	}
	}

	TaskQueueMetronome::TaskQueueMetronome(TimeDelta tick_period)
	: tick_period_(tick_period) {}

	TaskQueueMetronome::~TaskQueueMetronome() {
	RTC_DCHECK_RUN_ON(&sequence_checker_);
	}
	void TaskQueueMetronome::RequestCallOnNextTick(
	absl::AnyInvocable<void() &&> callback) {
	RTC_DCHECK_RUN_ON(&sequence_checker_);
	callbacks_.push_back(std::move(callback));
	// Only schedule a tick callback for the first `callback` addition.
	// Schedule on the current task queue to comply with RequestCallOnNextTick
	// requirements.
	if (callbacks_.size() == 1) {
	TaskQueueBase::Current()->PostDelayedTask(
	SafeTask(safety_.flag(),
	[this] {
	RTC_DCHECK_RUN_ON(&sequence_checker_);
	std::vector<absl::AnyInvocable<void() &&>> callbacks;
	callbacks_.swap(callbacks);
	for (auto& callback : callbacks)
	std::move(callback)();
	}),
	tick_period_);
	}
	}

	TimeDelta TaskQueueMetronome::TickPeriod() const {
	RTC_DCHECK_RUN_ON(&sequence_checker_);
	return tick_period_;
	}

	// Implementation of PeerConnectionIntegrationWrapper functions
	void PeerConnectionIntegrationWrapper::StartWatchingDelayStats() {
	// Get the baseline numbers for audio_packets and audio_delay.
	auto received_stats = NewGetStats();
	auto rtp_stats =
	received_stats->GetStatsOfType<RTCInboundRtpStreamStats>()[0];
	ASSERT_TRUE(rtp_stats->relative_packet_arrival_delay.has_value());
	ASSERT_TRUE(rtp_stats->packets_received.has_value());
	rtp_stats_id_ = rtp_stats->id();
	audio_packets_stat_ = *rtp_stats->packets_received;
	audio_delay_stat_ = *rtp_stats->relative_packet_arrival_delay;
	audio_samples_stat_ = *rtp_stats->total_samples_received;
	audio_concealed_stat_ = *rtp_stats->concealed_samples;
	}

	void PeerConnectionIntegrationWrapper::UpdateDelayStats(std::string tag,
	int desc_size) {
	auto report = NewGetStats();
	auto rtp_stats = report->GetAs<RTCInboundRtpStreamStats>(rtp_stats_id_);
	ASSERT_TRUE(rtp_stats);
	auto delta_packets = *rtp_stats->packets_received - audio_packets_stat_;
	auto delta_rpad =
	*rtp_stats->relative_packet_arrival_delay - audio_delay_stat_;
	auto recent_delay = delta_packets > 0 ? delta_rpad / delta_packets : -1;
	// The purpose of these checks is to sound the alarm early if we introduce
	// serious regressions. The numbers are not acceptable for production, but
	// occur on slow bots.
	//
	// An average relative packet arrival delay over the renegotiation of
	// > 100 ms indicates that something is dramatically wrong, and will impact
	// quality for sure.
	// Worst bots:
	// linux_x86_dbg at 0.206
	#if !defined(NDEBUG)
	EXPECT_GT(0.25, recent_delay) << tag << " size " << desc_size;
	#else
	EXPECT_GT(0.1, recent_delay) << tag << " size " << desc_size;
	#endif
	auto delta_samples = *rtp_stats->total_samples_received - audio_samples_stat_;
	auto delta_concealed = *rtp_stats->concealed_samples - audio_concealed_stat_;
	// These limits should be adjusted down as we improve:
	//
	// Concealing more than 4000 samples during a renegotiation is unacceptable.
	// But some bots are slow.

	// Worst bots:
	// linux_more_configs bot at conceal count 5184
	// android_arm_rel at conceal count 9241
	// linux_x86_dbg at 15174
	#if !defined(NDEBUG)
	EXPECT_GT(18000U, delta_concealed) << "Concealed " << delta_concealed
	<< " of " << delta_samples << " samples";
	#else
	EXPECT_GT(15000U, delta_concealed) << "Concealed " << delta_concealed
	<< " of " << delta_samples << " samples";
	#endif
	// Concealing more than 20% of samples during a renegotiation is
	// unacceptable.
	// Worst bots:
	// Nondebug: Linux32 Release at conceal rate 0.606597 (CI run)
	// Debug: linux_x86_dbg bot at conceal rate 0.854
	// internal bot at conceal rate 0.967 (b/294020344)
	// TODO(https://crbug.com/webrtc/15393): Improve audio quality during
	// renegotiation so that we can reduce these thresholds, 99% is not even
	// close to the 20% deemed unacceptable above or the 0% that would be ideal.
	if (delta_samples > 0) {
	#if !defined(NDEBUG)
	EXPECT_LT(1.0 * delta_concealed / delta_samples, 0.99)
	<< "Concealed " << delta_concealed << " of " << delta_samples
	<< " samples";
	#else
	EXPECT_LT(1.0 * delta_concealed / delta_samples, 0.7)
	<< "Concealed " << delta_concealed << " of " << delta_samples
	<< " samples";
	#endif
	}
	// Increment trailing counters
	audio_packets_stat_ = *rtp_stats->packets_received;
	audio_delay_stat_ = *rtp_stats->relative_packet_arrival_delay;
	audio_samples_stat_ = *rtp_stats->total_samples_received;
	audio_concealed_stat_ = *rtp_stats->concealed_samples;
	}

	bool PeerConnectionIntegrationWrapper::Init(
	const PeerConnectionFactory::Options* options,
	const PeerConnectionInterface::RTCConfiguration* config,
	PeerConnectionDependencies dependencies,
	rtc::SocketServer* socket_server,
	rtc::Thread* network_thread,
	rtc::Thread* worker_thread,
	std::unique_ptr<FakeRtcEventLogFactory> event_log_factory,
	bool reset_encoder_factory,
	bool reset_decoder_factory,
	bool create_media_engine) {
	// There's an error in this test code if Init ends up being called twice.
	RTC_DCHECK(!peer_connection_);
	RTC_DCHECK(!peer_connection_factory_);

	fake_network_manager_.reset(new rtc::FakeNetworkManager());
	fake_network_manager_->AddInterface(kDefaultLocalAddress);

	socket_factory_.reset(new rtc::BasicPacketSocketFactory(socket_server));

	std::unique_ptr<cricket::PortAllocator> port_allocator(
	new cricket::BasicPortAllocator(fake_network_manager_.get(),
	socket_factory_.get()));
	port_allocator_ = port_allocator.get();
	fake_audio_capture_module_ = FakeAudioCaptureModule::Create();
	if (!fake_audio_capture_module_) {
	return false;
	}
	rtc::Thread* const signaling_thread = rtc::Thread::Current();

	PeerConnectionFactoryDependencies pc_factory_dependencies;
	pc_factory_dependencies.network_thread = network_thread;
	pc_factory_dependencies.worker_thread = worker_thread;
	pc_factory_dependencies.signaling_thread = signaling_thread;
	pc_factory_dependencies.task_queue_factory = CreateDefaultTaskQueueFactory();
	pc_factory_dependencies.trials = std::make_unique<FieldTrialBasedConfig>();
	pc_factory_dependencies.decode_metronome =
	std::make_unique<TaskQueueMetronome>(TimeDelta::Millis(8));

	pc_factory_dependencies.adm = fake_audio_capture_module_;
	if (create_media_engine) {
	EnableMediaWithDefaults(pc_factory_dependencies);
	}

	if (reset_encoder_factory) {
	pc_factory_dependencies.video_encoder_factory.reset();
	}
	if (reset_decoder_factory) {
	pc_factory_dependencies.video_decoder_factory.reset();
	}

	if (!pc_factory_dependencies.audio_processing) {
	// If the standard Creation method for APM returns a null pointer, instead
	// use the builder for testing to create an APM object.
	pc_factory_dependencies.audio_processing =
	AudioProcessingBuilderForTesting().Create();
	}

	if (event_log_factory) {
	event_log_factory_ = event_log_factory.get();
	pc_factory_dependencies.event_log_factory = std::move(event_log_factory);
	} else {
	pc_factory_dependencies.event_log_factory =
	std::make_unique<RtcEventLogFactory>();
	}
	peer_connection_factory_ =
	CreateModularPeerConnectionFactory(std::move(pc_factory_dependencies));

	if (!peer_connection_factory_) {
	return false;
	}
	if (options) {
	peer_connection_factory_->SetOptions(*options);
	}
	if (config) {
	sdp_semantics_ = config->sdp_semantics;
	}

	dependencies.allocator = std::move(port_allocator);
	peer_connection_ = CreatePeerConnection(config, std::move(dependencies));
	return peer_connection_.get() != nullptr;
	}

	} // namespace webrtc