blob: 8938ac2e08f1d9646753c2aceaa5d069fa9c5518 [file] [log] [blame]
/*
* 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.
*/
#ifndef PC_TEST_INTEGRATION_TEST_HELPERS_H_
#define PC_TEST_INTEGRATION_TEST_HELPERS_H_
#include <limits.h>
#include <stdint.h>
#include <stdio.h>
#include <algorithm>
#include <functional>
#include <limits>
#include <list>
#include <map>
#include <memory>
#include <optional>
#include <set>
#include <string>
#include <utility>
#include <vector>
#include "absl/algorithm/container.h"
#include "absl/memory/memory.h"
#include "absl/strings/string_view.h"
#include "api/audio/audio_device.h"
#include "api/audio/audio_processing.h"
#include "api/audio_options.h"
#include "api/candidate.h"
#include "api/crypto/crypto_options.h"
#include "api/data_channel_interface.h"
#include "api/enable_media_with_defaults.h"
#include "api/field_trials_view.h"
#include "api/ice_transport_interface.h"
#include "api/jsep.h"
#include "api/media_stream_interface.h"
#include "api/media_types.h"
#include "api/peer_connection_interface.h"
#include "api/rtc_error.h"
#include "api/rtc_event_log/rtc_event_log_factory.h"
#include "api/rtc_event_log/rtc_event_log_factory_interface.h"
#include "api/rtc_event_log_output.h"
#include "api/rtp_receiver_interface.h"
#include "api/rtp_sender_interface.h"
#include "api/rtp_transceiver_interface.h"
#include "api/scoped_refptr.h"
#include "api/stats/rtc_stats.h"
#include "api/stats/rtc_stats_report.h"
#include "api/stats/rtcstats_objects.h"
#include "api/task_queue/default_task_queue_factory.h"
#include "api/task_queue/pending_task_safety_flag.h"
#include "api/task_queue/task_queue_factory.h"
#include "api/test/mock_async_dns_resolver.h"
#include "api/transport/field_trial_based_config.h"
#include "api/uma_metrics.h"
#include "api/units/time_delta.h"
#include "api/video/video_rotation.h"
#include "api/video_codecs/sdp_video_format.h"
#include "api/video_codecs/video_decoder_factory.h"
#include "api/video_codecs/video_encoder_factory.h"
#include "call/call.h"
#include "logging/rtc_event_log/fake_rtc_event_log_factory.h"
#include "media/base/media_engine.h"
#include "media/base/stream_params.h"
#include "media/engine/fake_webrtc_video_engine.h"
#include "modules/audio_processing/test/audio_processing_builder_for_testing.h"
#include "p2p/base/fake_ice_transport.h"
#include "p2p/base/ice_transport_internal.h"
#include "p2p/base/p2p_constants.h"
#include "p2p/base/port.h"
#include "p2p/base/port_allocator.h"
#include "p2p/base/port_interface.h"
#include "p2p/base/test_stun_server.h"
#include "p2p/base/test_turn_customizer.h"
#include "p2p/base/test_turn_server.h"
#include "p2p/client/basic_port_allocator.h"
#include "pc/dtmf_sender.h"
#include "pc/local_audio_source.h"
#include "pc/media_session.h"
#include "pc/peer_connection.h"
#include "pc/peer_connection_factory.h"
#include "pc/peer_connection_proxy.h"
#include "pc/rtp_media_utils.h"
#include "pc/session_description.h"
#include "pc/test/fake_audio_capture_module.h"
#include "pc/test/fake_periodic_video_source.h"
#include "pc/test/fake_periodic_video_track_source.h"
#include "pc/test/fake_rtc_certificate_generator.h"
#include "pc/test/fake_video_track_renderer.h"
#include "pc/test/mock_peer_connection_observers.h"
#include "pc/video_track_source.h"
#include "rtc_base/checks.h"
#include "rtc_base/crypto_random.h"
#include "rtc_base/event.h"
#include "rtc_base/fake_clock.h"
#include "rtc_base/fake_mdns_responder.h"
#include "rtc_base/fake_network.h"
#include "rtc_base/firewall_socket_server.h"
#include "rtc_base/gunit.h"
#include "rtc_base/ip_address.h"
#include "rtc_base/logging.h"
#include "rtc_base/mdns_responder_interface.h"
#include "rtc_base/numerics/safe_conversions.h"
#include "rtc_base/rtc_certificate_generator.h"
#include "rtc_base/socket_address.h"
#include "rtc_base/ssl_stream_adapter.h"
#include "rtc_base/task_queue_for_test.h"
#include "rtc_base/task_utils/repeating_task.h"
#include "rtc_base/test_certificate_verifier.h"
#include "rtc_base/thread.h"
#include "rtc_base/thread_annotations.h"
#include "rtc_base/time_utils.h"
#include "rtc_base/virtual_socket_server.h"
#include "system_wrappers/include/metrics.h"
#include "test/gmock.h"
#include "test/scoped_key_value_config.h"
namespace webrtc {
using ::cricket::ContentInfo;
using ::cricket::StreamParams;
using ::rtc::SocketAddress;
using ::testing::_;
using ::testing::Combine;
using ::testing::Contains;
using ::testing::DoAll;
using ::testing::ElementsAre;
using ::testing::InvokeArgument;
using ::testing::NiceMock;
using ::testing::Return;
using ::testing::SetArgPointee;
using ::testing::UnorderedElementsAreArray;
using ::testing::Values;
using RTCConfiguration = PeerConnectionInterface::RTCConfiguration;
static const int kDefaultTimeout = 10000;
static const int kLongTimeout = 60000;
static const int kMaxWaitForStatsMs = 3000;
static const int kMaxWaitForActivationMs = 5000;
static const int kMaxWaitForFramesMs = 10000;
// Default number of audio/video frames to wait for before considering a test
// successful.
static const int kDefaultExpectedAudioFrameCount = 3;
static const int kDefaultExpectedVideoFrameCount = 3;
static const char kDataChannelLabel[] = "data_channel";
// SRTP cipher name negotiated by the tests. This must be updated if the
// default changes.
static const int kDefaultSrtpCryptoSuite = rtc::kSrtpAes128CmSha1_80;
static const int kDefaultSrtpCryptoSuiteGcm = rtc::kSrtpAeadAes256Gcm;
static const SocketAddress kDefaultLocalAddress("192.168.1.1", 0);
// Helper function for constructing offer/answer options to initiate an ICE
// restart.
PeerConnectionInterface::RTCOfferAnswerOptions IceRestartOfferAnswerOptions();
// Remove all stream information (SSRCs, track IDs, etc.) and "msid-semantic"
// attribute from received SDP, simulating a legacy endpoint.
void RemoveSsrcsAndMsids(std::unique_ptr<SessionDescriptionInterface>& desc);
// Removes all stream information besides the stream ids, simulating an
// endpoint that only signals a=msid lines to convey stream_ids.
void RemoveSsrcsAndKeepMsids(
std::unique_ptr<SessionDescriptionInterface>& desc);
// Set SdpType.
void SetSdpType(std::unique_ptr<SessionDescriptionInterface>& sdp,
SdpType sdpType);
// Replaces the stream's primary SSRC and updates the first SSRC of all
// ssrc-groups.
void ReplaceFirstSsrc(StreamParams& stream, uint32_t ssrc);
int FindFirstMediaStatsIndexByKind(
const std::string& kind,
const std::vector<const RTCInboundRtpStreamStats*>& inbound_rtps);
class TaskQueueMetronome : public Metronome {
public:
explicit TaskQueueMetronome(TimeDelta tick_period);
~TaskQueueMetronome() override;
// Metronome implementation.
void RequestCallOnNextTick(absl::AnyInvocable<void() &&> callback) override;
TimeDelta TickPeriod() const override;
private:
const TimeDelta tick_period_;
SequenceChecker sequence_checker_{SequenceChecker::kDetached};
std::vector<absl::AnyInvocable<void() &&>> callbacks_;
ScopedTaskSafetyDetached safety_;
};
class SignalingMessageReceiver {
public:
virtual void ReceiveSdpMessage(SdpType type, const std::string& msg) = 0;
virtual void ReceiveIceMessage(const std::string& sdp_mid,
int sdp_mline_index,
const std::string& msg) = 0;
protected:
SignalingMessageReceiver() {}
virtual ~SignalingMessageReceiver() {}
};
class MockRtpReceiverObserver : public RtpReceiverObserverInterface {
public:
explicit MockRtpReceiverObserver(cricket::MediaType media_type)
: expected_media_type_(media_type) {}
void OnFirstPacketReceived(cricket::MediaType media_type) override {
ASSERT_EQ(expected_media_type_, media_type);
first_packet_received_ = true;
}
bool first_packet_received() const { return first_packet_received_; }
virtual ~MockRtpReceiverObserver() {}
private:
bool first_packet_received_ = false;
cricket::MediaType expected_media_type_;
};
// Helper class that wraps a peer connection, observes it, and can accept
// signaling messages from another wrapper.
//
// Uses a fake network, fake A/V capture, and optionally fake
// encoders/decoders, though they aren't used by default since they don't
// advertise support of any codecs.
// TODO(steveanton): See how this could become a subclass of
// PeerConnectionWrapper defined in peerconnectionwrapper.h.
class PeerConnectionIntegrationWrapper : public PeerConnectionObserver,
public SignalingMessageReceiver {
public:
PeerConnectionFactoryInterface* pc_factory() const {
return peer_connection_factory_.get();
}
PeerConnectionInterface* pc() const { return peer_connection_.get(); }
// If a signaling message receiver is set (via ConnectFakeSignaling), this
// will set the whole offer/answer exchange in motion. Just need to wait for
// the signaling state to reach "stable".
void CreateAndSetAndSignalOffer() {
auto offer = CreateOfferAndWait();
ASSERT_NE(nullptr, offer);
EXPECT_TRUE(SetLocalDescriptionAndSendSdpMessage(std::move(offer)));
}
// Sets the options to be used when CreateAndSetAndSignalOffer is called, or
// when a remote offer is received (via fake signaling) and an answer is
// generated. By default, uses default options.
void SetOfferAnswerOptions(
const PeerConnectionInterface::RTCOfferAnswerOptions& options) {
offer_answer_options_ = options;
}
// Set a callback to be invoked when SDP is received via the fake signaling
// channel, which provides an opportunity to munge (modify) the SDP. This is
// used to test SDP being applied that a PeerConnection would normally not
// generate, but a non-JSEP endpoint might.
void SetReceivedSdpMunger(
std::function<void(std::unique_ptr<SessionDescriptionInterface>&)>
munger) {
received_sdp_munger_ = std::move(munger);
}
// Similar to the above, but this is run on SDP immediately after it's
// generated.
void SetGeneratedSdpMunger(
std::function<void(std::unique_ptr<SessionDescriptionInterface>&)>
munger) {
generated_sdp_munger_ = std::move(munger);
}
// Set a callback to be invoked when a remote offer is received via the fake
// signaling channel. This provides an opportunity to change the
// PeerConnection state before an answer is created and sent to the caller.
void SetRemoteOfferHandler(std::function<void()> handler) {
remote_offer_handler_ = std::move(handler);
}
void SetRemoteAsyncResolver(MockAsyncDnsResolver* resolver) {
remote_async_dns_resolver_ = resolver;
}
// Every ICE connection state in order that has been seen by the observer.
std::vector<PeerConnectionInterface::IceConnectionState>
ice_connection_state_history() const {
return ice_connection_state_history_;
}
void clear_ice_connection_state_history() {
ice_connection_state_history_.clear();
}
// Every standardized ICE connection state in order that has been seen by the
// observer.
std::vector<PeerConnectionInterface::IceConnectionState>
standardized_ice_connection_state_history() const {
return standardized_ice_connection_state_history_;
}
// Every PeerConnection state in order that has been seen by the observer.
std::vector<PeerConnectionInterface::PeerConnectionState>
peer_connection_state_history() const {
return peer_connection_state_history_;
}
// Every ICE gathering state in order that has been seen by the observer.
std::vector<PeerConnectionInterface::IceGatheringState>
ice_gathering_state_history() const {
return ice_gathering_state_history_;
}
std::vector<cricket::CandidatePairChangeEvent>
ice_candidate_pair_change_history() const {
return ice_candidate_pair_change_history_;
}
// Every PeerConnection signaling state in order that has been seen by the
// observer.
std::vector<PeerConnectionInterface::SignalingState>
peer_connection_signaling_state_history() const {
return peer_connection_signaling_state_history_;
}
void AddAudioVideoTracks() {
AddAudioTrack();
AddVideoTrack();
}
rtc::scoped_refptr<RtpSenderInterface> AddAudioTrack() {
return AddTrack(CreateLocalAudioTrack());
}
rtc::scoped_refptr<RtpSenderInterface> AddVideoTrack() {
return AddTrack(CreateLocalVideoTrack());
}
rtc::scoped_refptr<AudioTrackInterface> CreateLocalAudioTrack() {
cricket::AudioOptions options;
// Disable highpass filter so that we can get all the test audio frames.
options.highpass_filter = false;
rtc::scoped_refptr<AudioSourceInterface> source =
peer_connection_factory_->CreateAudioSource(options);
// TODO(perkj): Test audio source when it is implemented. Currently audio
// always use the default input.
return peer_connection_factory_->CreateAudioTrack(rtc::CreateRandomUuid(),
source.get());
}
rtc::scoped_refptr<VideoTrackInterface> CreateLocalVideoTrack() {
FakePeriodicVideoSource::Config config;
config.timestamp_offset_ms = rtc::TimeMillis();
return CreateLocalVideoTrackInternal(config);
}
rtc::scoped_refptr<VideoTrackInterface> CreateLocalVideoTrackWithConfig(
FakePeriodicVideoSource::Config config) {
return CreateLocalVideoTrackInternal(config);
}
rtc::scoped_refptr<VideoTrackInterface> CreateLocalVideoTrackWithRotation(
VideoRotation rotation) {
FakePeriodicVideoSource::Config config;
config.rotation = rotation;
config.timestamp_offset_ms = rtc::TimeMillis();
return CreateLocalVideoTrackInternal(config);
}
rtc::scoped_refptr<RtpSenderInterface> AddTrack(
rtc::scoped_refptr<MediaStreamTrackInterface> track,
const std::vector<std::string>& stream_ids = {}) {
EXPECT_TRUE(track);
if (!track) {
return nullptr;
}
auto result = pc()->AddTrack(track, stream_ids);
EXPECT_EQ(RTCErrorType::NONE, result.error().type());
if (result.ok()) {
return result.MoveValue();
} else {
return nullptr;
}
}
std::vector<rtc::scoped_refptr<RtpReceiverInterface>> GetReceiversOfType(
cricket::MediaType media_type) {
std::vector<rtc::scoped_refptr<RtpReceiverInterface>> receivers;
for (const auto& receiver : pc()->GetReceivers()) {
if (receiver->media_type() == media_type) {
receivers.push_back(receiver);
}
}
return receivers;
}
rtc::scoped_refptr<RtpTransceiverInterface> GetFirstTransceiverOfType(
cricket::MediaType media_type) {
for (auto transceiver : pc()->GetTransceivers()) {
if (transceiver->receiver()->media_type() == media_type) {
return transceiver;
}
}
return nullptr;
}
bool SignalingStateStable() {
return pc()->signaling_state() == PeerConnectionInterface::kStable;
}
bool IceGatheringStateComplete() {
return pc()->ice_gathering_state() ==
PeerConnectionInterface::kIceGatheringComplete;
}
void CreateDataChannel() { CreateDataChannel(nullptr); }
void CreateDataChannel(const DataChannelInit* init) {
CreateDataChannel(kDataChannelLabel, init);
}
void CreateDataChannel(const std::string& label,
const DataChannelInit* init) {
auto data_channel_or_error = pc()->CreateDataChannelOrError(label, init);
ASSERT_TRUE(data_channel_or_error.ok());
data_channels_.push_back(data_channel_or_error.MoveValue());
ASSERT_TRUE(data_channels_.back().get() != nullptr);
data_observers_.push_back(
std::make_unique<MockDataChannelObserver>(data_channels_.back().get()));
}
// Return the last observed data channel.
DataChannelInterface* data_channel() {
if (data_channels_.size() == 0) {
return nullptr;
}
return data_channels_.back().get();
}
// Return all data channels.
std::vector<rtc::scoped_refptr<DataChannelInterface>>& data_channels() {
return data_channels_;
}
const MockDataChannelObserver* data_observer() const {
if (data_observers_.size() == 0) {
return nullptr;
}
return data_observers_.back().get();
}
std::vector<std::unique_ptr<MockDataChannelObserver>>& data_observers() {
return data_observers_;
}
std::unique_ptr<SessionDescriptionInterface> CreateAnswerForTest() {
return CreateAnswer();
}
int audio_frames_received() const {
return fake_audio_capture_module_->frames_received();
}
// Takes minimum of video frames received for each track.
//
// Can be used like:
// EXPECT_GE(expected_frames, min_video_frames_received_per_track());
//
// To ensure that all video tracks received at least a certain number of
// frames.
int min_video_frames_received_per_track() const {
int min_frames = INT_MAX;
if (fake_video_renderers_.empty()) {
return 0;
}
for (const auto& pair : fake_video_renderers_) {
min_frames = std::min(min_frames, pair.second->num_rendered_frames());
}
return min_frames;
}
// Returns a MockStatsObserver in a state after stats gathering finished,
// which can be used to access the gathered stats.
rtc::scoped_refptr<MockStatsObserver> OldGetStatsForTrack(
MediaStreamTrackInterface* track) {
auto observer = rtc::make_ref_counted<MockStatsObserver>();
EXPECT_TRUE(peer_connection_->GetStats(
observer.get(), nullptr,
PeerConnectionInterface::kStatsOutputLevelStandard));
EXPECT_TRUE_WAIT(observer->called(), kDefaultTimeout);
return observer;
}
// Version that doesn't take a track "filter", and gathers all stats.
rtc::scoped_refptr<MockStatsObserver> OldGetStats() {
return OldGetStatsForTrack(nullptr);
}
// Synchronously gets stats and returns them. If it times out, fails the test
// and returns null.
rtc::scoped_refptr<const RTCStatsReport> NewGetStats() {
auto callback = rtc::make_ref_counted<MockRTCStatsCollectorCallback>();
peer_connection_->GetStats(callback.get());
EXPECT_TRUE_WAIT(callback->called(), kDefaultTimeout);
return callback->report();
}
int rendered_width() {
EXPECT_FALSE(fake_video_renderers_.empty());
return fake_video_renderers_.empty()
? 0
: fake_video_renderers_.begin()->second->width();
}
int rendered_height() {
EXPECT_FALSE(fake_video_renderers_.empty());
return fake_video_renderers_.empty()
? 0
: fake_video_renderers_.begin()->second->height();
}
double rendered_aspect_ratio() {
if (rendered_height() == 0) {
return 0.0;
}
return static_cast<double>(rendered_width()) / rendered_height();
}
VideoRotation rendered_rotation() {
EXPECT_FALSE(fake_video_renderers_.empty());
return fake_video_renderers_.empty()
? kVideoRotation_0
: fake_video_renderers_.begin()->second->rotation();
}
int local_rendered_width() {
return local_video_renderer_ ? local_video_renderer_->width() : 0;
}
int local_rendered_height() {
return local_video_renderer_ ? local_video_renderer_->height() : 0;
}
double local_rendered_aspect_ratio() {
if (local_rendered_height() == 0) {
return 0.0;
}
return static_cast<double>(local_rendered_width()) /
local_rendered_height();
}
size_t number_of_remote_streams() {
if (!pc()) {
return 0;
}
return pc()->remote_streams()->count();
}
StreamCollectionInterface* remote_streams() const {
if (!pc()) {
ADD_FAILURE();
return nullptr;
}
return pc()->remote_streams().get();
}
StreamCollectionInterface* local_streams() {
if (!pc()) {
ADD_FAILURE();
return nullptr;
}
return pc()->local_streams().get();
}
PeerConnectionInterface::SignalingState signaling_state() {
return pc()->signaling_state();
}
PeerConnectionInterface::IceConnectionState ice_connection_state() {
return pc()->ice_connection_state();
}
PeerConnectionInterface::IceConnectionState
standardized_ice_connection_state() {
return pc()->standardized_ice_connection_state();
}
PeerConnectionInterface::IceGatheringState ice_gathering_state() {
return pc()->ice_gathering_state();
}
// Returns a MockRtpReceiverObserver for each RtpReceiver returned by
// GetReceivers. They're updated automatically when a remote offer/answer
// from the fake signaling channel is applied, or when
// ResetRtpReceiverObservers below is called.
const std::vector<std::unique_ptr<MockRtpReceiverObserver>>&
rtp_receiver_observers() {
return rtp_receiver_observers_;
}
void ResetRtpReceiverObservers() {
rtp_receiver_observers_.clear();
for (const rtc::scoped_refptr<RtpReceiverInterface>& receiver :
pc()->GetReceivers()) {
std::unique_ptr<MockRtpReceiverObserver> observer(
new MockRtpReceiverObserver(receiver->media_type()));
receiver->SetObserver(observer.get());
rtp_receiver_observers_.push_back(std::move(observer));
}
}
rtc::FakeNetworkManager* network_manager() const {
return fake_network_manager_.get();
}
cricket::PortAllocator* port_allocator() const { return port_allocator_; }
FakeRtcEventLogFactory* event_log_factory() const {
return event_log_factory_;
}
const cricket::Candidate& last_candidate_gathered() const {
return last_candidate_gathered_;
}
const cricket::IceCandidateErrorEvent& error_event() const {
return error_event_;
}
// Sets the mDNS responder for the owned fake network manager and keeps a
// reference to the responder.
void SetMdnsResponder(std::unique_ptr<FakeMdnsResponder> mdns_responder) {
RTC_DCHECK(mdns_responder != nullptr);
mdns_responder_ = mdns_responder.get();
network_manager()->set_mdns_responder(std::move(mdns_responder));
}
// Returns null on failure.
std::unique_ptr<SessionDescriptionInterface> CreateOfferAndWait() {
auto observer =
rtc::make_ref_counted<MockCreateSessionDescriptionObserver>();
pc()->CreateOffer(observer.get(), offer_answer_options_);
return WaitForDescriptionFromObserver(observer.get());
}
bool Rollback() {
return SetRemoteDescription(
CreateSessionDescription(SdpType::kRollback, ""));
}
// Functions for querying stats.
void StartWatchingDelayStats();
void UpdateDelayStats(std::string tag, int desc_size);
// Sets number of candidates expected
void ExpectCandidates(int candidate_count) {
candidates_expected_ = candidate_count;
}
bool SetRemoteDescription(std::unique_ptr<SessionDescriptionInterface> desc) {
auto observer = rtc::make_ref_counted<FakeSetRemoteDescriptionObserver>();
std::string str;
desc->ToString(&str);
RTC_LOG(LS_INFO) << debug_name_ << ": SetRemoteDescription SDP:\n" << str;
pc()->SetRemoteDescription(std::move(desc), observer); // desc.release());
RemoveUnusedVideoRenderers();
EXPECT_TRUE_WAIT(observer->called(), kDefaultTimeout);
auto err = observer->error();
if (!err.ok()) {
RTC_LOG(LS_WARNING) << debug_name_
<< ": SetRemoteDescription error: " << err.message();
}
return observer->error().ok();
}
private:
// Constructor used by friend class PeerConnectionIntegrationBaseTest.
explicit PeerConnectionIntegrationWrapper(const std::string& debug_name)
: debug_name_(debug_name) {}
bool 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);
rtc::scoped_refptr<PeerConnectionInterface> CreatePeerConnection(
const PeerConnectionInterface::RTCConfiguration* config,
PeerConnectionDependencies dependencies) {
PeerConnectionInterface::RTCConfiguration modified_config;
modified_config.sdp_semantics = sdp_semantics_;
// If `config` is null, this will result in a default configuration being
// used.
if (config) {
modified_config = *config;
}
// Disable resolution adaptation; we don't want it interfering with the
// test results.
// TODO(deadbeef): Do something more robust. Since we're testing for aspect
// ratios and not specific resolutions, is this even necessary?
modified_config.set_cpu_adaptation(false);
dependencies.observer = this;
auto peer_connection_or_error =
peer_connection_factory_->CreatePeerConnectionOrError(
modified_config, std::move(dependencies));
return peer_connection_or_error.ok() ? peer_connection_or_error.MoveValue()
: nullptr;
}
void set_signaling_message_receiver(
SignalingMessageReceiver* signaling_message_receiver) {
signaling_message_receiver_ = signaling_message_receiver;
}
void set_signaling_delay_ms(int delay_ms) { signaling_delay_ms_ = delay_ms; }
void set_signal_ice_candidates(bool signal) {
signal_ice_candidates_ = signal;
}
rtc::scoped_refptr<VideoTrackInterface> CreateLocalVideoTrackInternal(
FakePeriodicVideoSource::Config config) {
// Set max frame rate to 10fps to reduce the risk of test flakiness.
// TODO(deadbeef): Do something more robust.
config.frame_interval_ms = 100;
video_track_sources_.emplace_back(
rtc::make_ref_counted<FakePeriodicVideoTrackSource>(
config, false /* remote */));
rtc::scoped_refptr<VideoTrackInterface> track =
peer_connection_factory_->CreateVideoTrack(video_track_sources_.back(),
rtc::CreateRandomUuid());
if (!local_video_renderer_) {
local_video_renderer_.reset(new FakeVideoTrackRenderer(track.get()));
}
return track;
}
void HandleIncomingOffer(const std::string& msg) {
RTC_LOG(LS_INFO) << debug_name_ << ": HandleIncomingOffer";
std::unique_ptr<SessionDescriptionInterface> desc =
CreateSessionDescription(SdpType::kOffer, msg);
if (received_sdp_munger_) {
received_sdp_munger_(desc);
}
EXPECT_TRUE(SetRemoteDescription(std::move(desc)));
// Setting a remote description may have changed the number of receivers,
// so reset the receiver observers.
ResetRtpReceiverObservers();
if (remote_offer_handler_) {
remote_offer_handler_();
}
auto answer = CreateAnswer();
ASSERT_NE(nullptr, answer);
EXPECT_TRUE(SetLocalDescriptionAndSendSdpMessage(std::move(answer)));
}
void HandleIncomingAnswer(SdpType type, const std::string& msg) {
RTC_LOG(LS_INFO) << debug_name_ << ": HandleIncomingAnswer of type "
<< SdpTypeToString(type);
std::unique_ptr<SessionDescriptionInterface> desc =
CreateSessionDescription(type, msg);
if (received_sdp_munger_) {
received_sdp_munger_(desc);
}
EXPECT_TRUE(SetRemoteDescription(std::move(desc)));
// Set the RtpReceiverObserver after receivers are created.
ResetRtpReceiverObservers();
}
// Returns null on failure.
std::unique_ptr<SessionDescriptionInterface> CreateAnswer() {
auto observer =
rtc::make_ref_counted<MockCreateSessionDescriptionObserver>();
pc()->CreateAnswer(observer.get(), offer_answer_options_);
return WaitForDescriptionFromObserver(observer.get());
}
std::unique_ptr<SessionDescriptionInterface> WaitForDescriptionFromObserver(
MockCreateSessionDescriptionObserver* observer) {
EXPECT_EQ_WAIT(true, observer->called(), kDefaultTimeout);
if (!observer->result()) {
return nullptr;
}
auto description = observer->MoveDescription();
if (generated_sdp_munger_) {
generated_sdp_munger_(description);
}
return description;
}
// Setting the local description and sending the SDP message over the fake
// signaling channel are combined into the same method because the SDP
// message needs to be sent as soon as SetLocalDescription finishes, without
// waiting for the observer to be called. This ensures that ICE candidates
// don't outrace the description.
bool SetLocalDescriptionAndSendSdpMessage(
std::unique_ptr<SessionDescriptionInterface> desc) {
auto observer = rtc::make_ref_counted<MockSetSessionDescriptionObserver>();
RTC_LOG(LS_INFO) << debug_name_ << ": SetLocalDescriptionAndSendSdpMessage";
SdpType type = desc->GetType();
std::string sdp;
EXPECT_TRUE(desc->ToString(&sdp));
RTC_LOG(LS_INFO) << debug_name_ << ": local SDP contents=\n" << sdp;
pc()->SetLocalDescription(observer.get(), desc.release());
RemoveUnusedVideoRenderers();
// As mentioned above, we need to send the message immediately after
// SetLocalDescription.
SendSdpMessage(type, sdp);
EXPECT_TRUE_WAIT(observer->called(), kDefaultTimeout);
return true;
}
// This is a work around to remove unused fake_video_renderers from
// transceivers that have either stopped or are no longer receiving.
void RemoveUnusedVideoRenderers() {
if (sdp_semantics_ != SdpSemantics::kUnifiedPlan) {
return;
}
auto transceivers = pc()->GetTransceivers();
std::set<std::string> active_renderers;
for (auto& transceiver : transceivers) {
// Note - we don't check for direction here. This function is called
// before direction is set, and in that case, we should not remove
// the renderer.
if (transceiver->receiver()->media_type() == cricket::MEDIA_TYPE_VIDEO) {
active_renderers.insert(transceiver->receiver()->track()->id());
}
}
for (auto it = fake_video_renderers_.begin();
it != fake_video_renderers_.end();) {
// Remove fake video renderers belonging to any non-active transceivers.
if (!active_renderers.count(it->first)) {
it = fake_video_renderers_.erase(it);
} else {
it++;
}
}
}
// Simulate sending a blob of SDP with delay `signaling_delay_ms_` (0 by
// default).
void SendSdpMessage(SdpType type, const std::string& msg) {
if (signaling_delay_ms_ == 0) {
RelaySdpMessageIfReceiverExists(type, msg);
} else {
rtc::Thread::Current()->PostDelayedTask(
SafeTask(task_safety_.flag(),
[this, type, msg] {
RelaySdpMessageIfReceiverExists(type, msg);
}),
TimeDelta::Millis(signaling_delay_ms_));
}
}
void RelaySdpMessageIfReceiverExists(SdpType type, const std::string& msg) {
if (signaling_message_receiver_) {
signaling_message_receiver_->ReceiveSdpMessage(type, msg);
}
}
// Simulate trickling an ICE candidate with delay `signaling_delay_ms_` (0 by
// default).
void SendIceMessage(const std::string& sdp_mid,
int sdp_mline_index,
const std::string& msg) {
if (signaling_delay_ms_ == 0) {
RelayIceMessageIfReceiverExists(sdp_mid, sdp_mline_index, msg);
} else {
rtc::Thread::Current()->PostDelayedTask(
SafeTask(task_safety_.flag(),
[this, sdp_mid, sdp_mline_index, msg] {
RelayIceMessageIfReceiverExists(sdp_mid, sdp_mline_index,
msg);
}),
TimeDelta::Millis(signaling_delay_ms_));
}
}
void RelayIceMessageIfReceiverExists(const std::string& sdp_mid,
int sdp_mline_index,
const std::string& msg) {
if (signaling_message_receiver_) {
signaling_message_receiver_->ReceiveIceMessage(sdp_mid, sdp_mline_index,
msg);
}
}
// SignalingMessageReceiver callbacks.
void ReceiveSdpMessage(SdpType type, const std::string& msg) override {
if (type == SdpType::kOffer) {
HandleIncomingOffer(msg);
} else {
HandleIncomingAnswer(type, msg);
}
}
void ReceiveIceMessage(const std::string& sdp_mid,
int sdp_mline_index,
const std::string& msg) override {
RTC_LOG(LS_INFO) << debug_name_ << ": ReceiveIceMessage";
std::optional<RTCError> result;
pc()->AddIceCandidate(absl::WrapUnique(CreateIceCandidate(
sdp_mid, sdp_mline_index, msg, nullptr)),
[&result](RTCError r) { result = r; });
EXPECT_TRUE_WAIT(result.has_value(), kDefaultTimeout);
EXPECT_TRUE(result.value().ok());
}
// PeerConnectionObserver callbacks.
void OnSignalingChange(
PeerConnectionInterface::SignalingState new_state) override {
EXPECT_EQ(pc()->signaling_state(), new_state);
peer_connection_signaling_state_history_.push_back(new_state);
}
void OnAddTrack(rtc::scoped_refptr<RtpReceiverInterface> receiver,
const std::vector<rtc::scoped_refptr<MediaStreamInterface>>&
streams) override {
if (receiver->media_type() == cricket::MEDIA_TYPE_VIDEO) {
rtc::scoped_refptr<VideoTrackInterface> video_track(
static_cast<VideoTrackInterface*>(receiver->track().get()));
ASSERT_TRUE(fake_video_renderers_.find(video_track->id()) ==
fake_video_renderers_.end());
fake_video_renderers_[video_track->id()] =
std::make_unique<FakeVideoTrackRenderer>(video_track.get());
}
}
void OnRemoveTrack(
rtc::scoped_refptr<RtpReceiverInterface> receiver) override {
if (receiver->media_type() == cricket::MEDIA_TYPE_VIDEO) {
auto it = fake_video_renderers_.find(receiver->track()->id());
if (it != fake_video_renderers_.end()) {
fake_video_renderers_.erase(it);
} else {
RTC_LOG(LS_ERROR) << "OnRemoveTrack called for non-active renderer";
}
}
}
void OnRenegotiationNeeded() override {}
void OnIceConnectionChange(
PeerConnectionInterface::IceConnectionState new_state) override {
EXPECT_EQ(pc()->ice_connection_state(), new_state);
ice_connection_state_history_.push_back(new_state);
}
void OnStandardizedIceConnectionChange(
PeerConnectionInterface::IceConnectionState new_state) override {
standardized_ice_connection_state_history_.push_back(new_state);
}
void OnConnectionChange(
PeerConnectionInterface::PeerConnectionState new_state) override {
peer_connection_state_history_.push_back(new_state);
}
void OnIceGatheringChange(
PeerConnectionInterface::IceGatheringState new_state) override {
EXPECT_EQ(pc()->ice_gathering_state(), new_state);
ice_gathering_state_history_.push_back(new_state);
}
void OnIceSelectedCandidatePairChanged(
const cricket::CandidatePairChangeEvent& event) {
ice_candidate_pair_change_history_.push_back(event);
}
void OnIceCandidate(const IceCandidateInterface* candidate) override {
RTC_LOG(LS_INFO) << debug_name_ << ": OnIceCandidate";
if (remote_async_dns_resolver_) {
const auto& local_candidate = candidate->candidate();
if (local_candidate.address().IsUnresolvedIP()) {
RTC_DCHECK(local_candidate.is_local());
const auto resolved_ip = mdns_responder_->GetMappedAddressForName(
local_candidate.address().hostname());
RTC_DCHECK(!resolved_ip.IsNil());
remote_async_dns_resolved_addr_ = local_candidate.address();
remote_async_dns_resolved_addr_.SetResolvedIP(resolved_ip);
EXPECT_CALL(*remote_async_dns_resolver_, Start(_, _))
.WillOnce([](const rtc::SocketAddress& addr,
absl::AnyInvocable<void()> callback) { callback(); });
EXPECT_CALL(*remote_async_dns_resolver_, result())
.WillOnce(ReturnRef(remote_async_dns_resolver_result_));
EXPECT_CALL(remote_async_dns_resolver_result_, GetResolvedAddress(_, _))
.WillOnce(DoAll(SetArgPointee<1>(remote_async_dns_resolved_addr_),
Return(true)));
}
}
// Check if we expected to have a candidate.
EXPECT_GT(candidates_expected_, 1);
candidates_expected_--;
std::string ice_sdp;
EXPECT_TRUE(candidate->ToString(&ice_sdp));
if (signaling_message_receiver_ == nullptr || !signal_ice_candidates_) {
// Remote party may be deleted.
return;
}
SendIceMessage(candidate->sdp_mid(), candidate->sdp_mline_index(), ice_sdp);
last_candidate_gathered_ = candidate->candidate();
}
void OnIceCandidateError(const std::string& address,
int port,
const std::string& url,
int error_code,
const std::string& error_text) override {
error_event_ = cricket::IceCandidateErrorEvent(address, port, url,
error_code, error_text);
}
void OnDataChannel(
rtc::scoped_refptr<DataChannelInterface> data_channel) override {
RTC_LOG(LS_INFO) << debug_name_ << ": OnDataChannel";
data_channels_.push_back(data_channel);
data_observers_.push_back(
std::make_unique<MockDataChannelObserver>(data_channel.get()));
}
std::string debug_name_;
std::unique_ptr<rtc::FakeNetworkManager> fake_network_manager_;
std::unique_ptr<rtc::BasicPacketSocketFactory> socket_factory_;
// Reference to the mDNS responder owned by `fake_network_manager_` after set.
FakeMdnsResponder* mdns_responder_ = nullptr;
rtc::scoped_refptr<PeerConnectionInterface> peer_connection_;
rtc::scoped_refptr<PeerConnectionFactoryInterface> peer_connection_factory_;
cricket::PortAllocator* port_allocator_;
// Needed to keep track of number of frames sent.
rtc::scoped_refptr<FakeAudioCaptureModule> fake_audio_capture_module_;
// Needed to keep track of number of frames received.
std::map<std::string, std::unique_ptr<FakeVideoTrackRenderer>>
fake_video_renderers_;
// Needed to ensure frames aren't received for removed tracks.
std::vector<std::unique_ptr<FakeVideoTrackRenderer>>
removed_fake_video_renderers_;
// For remote peer communication.
SignalingMessageReceiver* signaling_message_receiver_ = nullptr;
int signaling_delay_ms_ = 0;
bool signal_ice_candidates_ = true;
cricket::Candidate last_candidate_gathered_;
cricket::IceCandidateErrorEvent error_event_;
// Store references to the video sources we've created, so that we can stop
// them, if required.
std::vector<rtc::scoped_refptr<VideoTrackSource>> video_track_sources_;
// `local_video_renderer_` attached to the first created local video track.
std::unique_ptr<FakeVideoTrackRenderer> local_video_renderer_;
SdpSemantics sdp_semantics_;
PeerConnectionInterface::RTCOfferAnswerOptions offer_answer_options_;
std::function<void(std::unique_ptr<SessionDescriptionInterface>&)>
received_sdp_munger_;
std::function<void(std::unique_ptr<SessionDescriptionInterface>&)>
generated_sdp_munger_;
std::function<void()> remote_offer_handler_;
MockAsyncDnsResolver* remote_async_dns_resolver_ = nullptr;
// Result variables for the mock DNS resolver
NiceMock<MockAsyncDnsResolverResult> remote_async_dns_resolver_result_;
rtc::SocketAddress remote_async_dns_resolved_addr_;
// All data channels either created or observed on this peerconnection
std::vector<rtc::scoped_refptr<DataChannelInterface>> data_channels_;
std::vector<std::unique_ptr<MockDataChannelObserver>> data_observers_;
std::vector<std::unique_ptr<MockRtpReceiverObserver>> rtp_receiver_observers_;
std::vector<PeerConnectionInterface::IceConnectionState>
ice_connection_state_history_;
std::vector<PeerConnectionInterface::IceConnectionState>
standardized_ice_connection_state_history_;
std::vector<PeerConnectionInterface::PeerConnectionState>
peer_connection_state_history_;
std::vector<PeerConnectionInterface::IceGatheringState>
ice_gathering_state_history_;
std::vector<cricket::CandidatePairChangeEvent>
ice_candidate_pair_change_history_;
std::vector<PeerConnectionInterface::SignalingState>
peer_connection_signaling_state_history_;
FakeRtcEventLogFactory* event_log_factory_;
// Number of ICE candidates expected. The default is no limit.
int candidates_expected_ = std::numeric_limits<int>::max();
// Variables for tracking delay stats on an audio track
int audio_packets_stat_ = 0;
double audio_delay_stat_ = 0.0;
uint64_t audio_samples_stat_ = 0;
uint64_t audio_concealed_stat_ = 0;
std::string rtp_stats_id_;
ScopedTaskSafety task_safety_;
friend class PeerConnectionIntegrationBaseTest;
};
class MockRtcEventLogOutput : public RtcEventLogOutput {
public:
virtual ~MockRtcEventLogOutput() = default;
MOCK_METHOD(bool, IsActive, (), (const, override));
MOCK_METHOD(bool, Write, (absl::string_view), (override));
};
// This helper object is used for both specifying how many audio/video frames
// are expected to be received for a caller/callee. It provides helper functions
// to specify these expectations. The object initially starts in a state of no
// expectations.
class MediaExpectations {
public:
enum ExpectFrames {
kExpectSomeFrames,
kExpectNoFrames,
kNoExpectation,
};
void ExpectBidirectionalAudioAndVideo() {
ExpectBidirectionalAudio();
ExpectBidirectionalVideo();
}
void ExpectBidirectionalAudio() {
CallerExpectsSomeAudio();
CalleeExpectsSomeAudio();
}
void ExpectNoAudio() {
CallerExpectsNoAudio();
CalleeExpectsNoAudio();
}
void ExpectBidirectionalVideo() {
CallerExpectsSomeVideo();
CalleeExpectsSomeVideo();
}
void ExpectNoVideo() {
CallerExpectsNoVideo();
CalleeExpectsNoVideo();
}
void CallerExpectsSomeAudioAndVideo() {
CallerExpectsSomeAudio();
CallerExpectsSomeVideo();
}
void CalleeExpectsSomeAudioAndVideo() {
CalleeExpectsSomeAudio();
CalleeExpectsSomeVideo();
}
// Caller's audio functions.
void CallerExpectsSomeAudio(
int expected_audio_frames = kDefaultExpectedAudioFrameCount) {
caller_audio_expectation_ = kExpectSomeFrames;
caller_audio_frames_expected_ = expected_audio_frames;
}
void CallerExpectsNoAudio() {
caller_audio_expectation_ = kExpectNoFrames;
caller_audio_frames_expected_ = 0;
}
// Caller's video functions.
void CallerExpectsSomeVideo(
int expected_video_frames = kDefaultExpectedVideoFrameCount) {
caller_video_expectation_ = kExpectSomeFrames;
caller_video_frames_expected_ = expected_video_frames;
}
void CallerExpectsNoVideo() {
caller_video_expectation_ = kExpectNoFrames;
caller_video_frames_expected_ = 0;
}
// Callee's audio functions.
void CalleeExpectsSomeAudio(
int expected_audio_frames = kDefaultExpectedAudioFrameCount) {
callee_audio_expectation_ = kExpectSomeFrames;
callee_audio_frames_expected_ = expected_audio_frames;
}
void CalleeExpectsNoAudio() {
callee_audio_expectation_ = kExpectNoFrames;
callee_audio_frames_expected_ = 0;
}
// Callee's video functions.
void CalleeExpectsSomeVideo(
int expected_video_frames = kDefaultExpectedVideoFrameCount) {
callee_video_expectation_ = kExpectSomeFrames;
callee_video_frames_expected_ = expected_video_frames;
}
void CalleeExpectsNoVideo() {
callee_video_expectation_ = kExpectNoFrames;
callee_video_frames_expected_ = 0;
}
ExpectFrames caller_audio_expectation_ = kNoExpectation;
ExpectFrames caller_video_expectation_ = kNoExpectation;
ExpectFrames callee_audio_expectation_ = kNoExpectation;
ExpectFrames callee_video_expectation_ = kNoExpectation;
int caller_audio_frames_expected_ = 0;
int caller_video_frames_expected_ = 0;
int callee_audio_frames_expected_ = 0;
int callee_video_frames_expected_ = 0;
};
class MockIceTransport : public IceTransportInterface {
public:
MockIceTransport(const std::string& name, int component)
: internal_(std::make_unique<cricket::FakeIceTransport>(
name,
component,
nullptr /* network_thread */)) {}
~MockIceTransport() = default;
cricket::IceTransportInternal* internal() { return internal_.get(); }
private:
std::unique_ptr<cricket::FakeIceTransport> internal_;
};
class MockIceTransportFactory : public IceTransportFactory {
public:
~MockIceTransportFactory() override = default;
rtc::scoped_refptr<IceTransportInterface> CreateIceTransport(
const std::string& transport_name,
int component,
IceTransportInit init) {
RecordIceTransportCreated();
return rtc::make_ref_counted<MockIceTransport>(transport_name, component);
}
MOCK_METHOD(void, RecordIceTransportCreated, ());
};
// Tests two PeerConnections connecting to each other end-to-end, using a
// virtual network, fake A/V capture and fake encoder/decoders. The
// PeerConnections share the threads/socket servers, but use separate versions
// of everything else (including "PeerConnectionFactory"s).
class PeerConnectionIntegrationBaseTest : public ::testing::Test {
public:
PeerConnectionIntegrationBaseTest(
SdpSemantics sdp_semantics,
std::optional<std::string> field_trials = std::nullopt)
: sdp_semantics_(sdp_semantics),
ss_(new rtc::VirtualSocketServer()),
fss_(new rtc::FirewallSocketServer(ss_.get())),
network_thread_(new rtc::Thread(fss_.get())),
worker_thread_(rtc::Thread::Create()),
// TODO(bugs.webrtc.org/10335): Pass optional ScopedKeyValueConfig.
field_trials_(new test::ScopedKeyValueConfig(
field_trials.has_value() ? *field_trials : "")) {
network_thread_->SetName("PCNetworkThread", this);
worker_thread_->SetName("PCWorkerThread", this);
RTC_CHECK(network_thread_->Start());
RTC_CHECK(worker_thread_->Start());
metrics::Reset();
}
~PeerConnectionIntegrationBaseTest() {
// The PeerConnections should be deleted before the TurnCustomizers.
// A TurnPort is created with a raw pointer to a TurnCustomizer. The
// TurnPort has the same lifetime as the PeerConnection, so it's expected
// that the TurnCustomizer outlives the life of the PeerConnection or else
// when Send() is called it will hit a seg fault.
if (caller_) {
caller_->set_signaling_message_receiver(nullptr);
caller_->pc()->Close();
delete SetCallerPcWrapperAndReturnCurrent(nullptr);
}
if (callee_) {
callee_->set_signaling_message_receiver(nullptr);
callee_->pc()->Close();
delete SetCalleePcWrapperAndReturnCurrent(nullptr);
}
// If turn servers were created for the test they need to be destroyed on
// the network thread.
SendTask(network_thread(), [this] {
turn_servers_.clear();
turn_customizers_.clear();
});
}
bool SignalingStateStable() {
return caller_->SignalingStateStable() && callee_->SignalingStateStable();
}
bool DtlsConnected() {
// TODO(deadbeef): kIceConnectionConnected currently means both ICE and DTLS
// are connected. This is an important distinction. Once we have separate
// ICE and DTLS state, this check needs to use the DTLS state.
return (callee()->ice_connection_state() ==
PeerConnectionInterface::kIceConnectionConnected ||
callee()->ice_connection_state() ==
PeerConnectionInterface::kIceConnectionCompleted) &&
(caller()->ice_connection_state() ==
PeerConnectionInterface::kIceConnectionConnected ||
caller()->ice_connection_state() ==
PeerConnectionInterface::kIceConnectionCompleted);
}
// When `event_log_factory` is null, the default implementation of the event
// log factory will be used.
std::unique_ptr<PeerConnectionIntegrationWrapper> CreatePeerConnectionWrapper(
const std::string& debug_name,
const PeerConnectionFactory::Options* options,
const RTCConfiguration* config,
PeerConnectionDependencies dependencies,
std::unique_ptr<FakeRtcEventLogFactory> event_log_factory,
bool reset_encoder_factory,
bool reset_decoder_factory,
bool create_media_engine = true) {
RTCConfiguration modified_config;
if (config) {
modified_config = *config;
}
modified_config.sdp_semantics = sdp_semantics_;
if (!dependencies.cert_generator) {
dependencies.cert_generator =
std::make_unique<FakeRTCCertificateGenerator>();
}
std::unique_ptr<PeerConnectionIntegrationWrapper> client(
new PeerConnectionIntegrationWrapper(debug_name));
if (!client->Init(options, &modified_config, std::move(dependencies),
fss_.get(), network_thread_.get(), worker_thread_.get(),
std::move(event_log_factory), reset_encoder_factory,
reset_decoder_factory, create_media_engine)) {
return nullptr;
}
return client;
}
std::unique_ptr<PeerConnectionIntegrationWrapper>
CreatePeerConnectionWrapperWithFakeRtcEventLog(
const std::string& debug_name,
const PeerConnectionFactory::Options* options,
const RTCConfiguration* config,
PeerConnectionDependencies dependencies) {
return CreatePeerConnectionWrapper(
debug_name, options, config, std::move(dependencies),
std::make_unique<FakeRtcEventLogFactory>(),
/*reset_encoder_factory=*/false,
/*reset_decoder_factory=*/false);
}
bool CreatePeerConnectionWrappers() {
return CreatePeerConnectionWrappersWithConfig(
PeerConnectionInterface::RTCConfiguration(),
PeerConnectionInterface::RTCConfiguration());
}
bool CreatePeerConnectionWrappersWithSdpSemantics(
SdpSemantics caller_semantics,
SdpSemantics callee_semantics) {
// Can't specify the sdp_semantics in the passed-in configuration since it
// will be overwritten by CreatePeerConnectionWrapper with whatever is
// stored in sdp_semantics_. So get around this by modifying the instance
// variable before calling CreatePeerConnectionWrapper for the caller and
// callee PeerConnections.
SdpSemantics original_semantics = sdp_semantics_;
sdp_semantics_ = caller_semantics;
caller_ = CreatePeerConnectionWrapper("Caller", nullptr, nullptr,
PeerConnectionDependencies(nullptr),
nullptr,
/*reset_encoder_factory=*/false,
/*reset_decoder_factory=*/false);
sdp_semantics_ = callee_semantics;
callee_ = CreatePeerConnectionWrapper("Callee", nullptr, nullptr,
PeerConnectionDependencies(nullptr),
nullptr,
/*reset_encoder_factory=*/false,
/*reset_decoder_factory=*/false);
sdp_semantics_ = original_semantics;
return caller_ && callee_;
}
bool CreatePeerConnectionWrappersWithConfig(
const PeerConnectionInterface::RTCConfiguration& caller_config,
const PeerConnectionInterface::RTCConfiguration& callee_config) {
caller_ = CreatePeerConnectionWrapper("Caller", nullptr, &caller_config,
PeerConnectionDependencies(nullptr),
nullptr,
/*reset_encoder_factory=*/false,
/*reset_decoder_factory=*/false);
callee_ = CreatePeerConnectionWrapper("Callee", nullptr, &callee_config,
PeerConnectionDependencies(nullptr),
nullptr,
/*reset_encoder_factory=*/false,
/*reset_decoder_factory=*/false);
return caller_ && callee_;
}
bool CreatePeerConnectionWrappersWithConfigAndDeps(
const PeerConnectionInterface::RTCConfiguration& caller_config,
PeerConnectionDependencies caller_dependencies,
const PeerConnectionInterface::RTCConfiguration& callee_config,
PeerConnectionDependencies callee_dependencies) {
caller_ =
CreatePeerConnectionWrapper("Caller", nullptr, &caller_config,
std::move(caller_dependencies), nullptr,
/*reset_encoder_factory=*/false,
/*reset_decoder_factory=*/false);
callee_ =
CreatePeerConnectionWrapper("Callee", nullptr, &callee_config,
std::move(callee_dependencies), nullptr,
/*reset_encoder_factory=*/false,
/*reset_decoder_factory=*/false);
return caller_ && callee_;
}
bool CreatePeerConnectionWrappersWithOptions(
const PeerConnectionFactory::Options& caller_options,
const PeerConnectionFactory::Options& callee_options) {
caller_ = CreatePeerConnectionWrapper("Caller", &caller_options, nullptr,
PeerConnectionDependencies(nullptr),
nullptr,
/*reset_encoder_factory=*/false,
/*reset_decoder_factory=*/false);
callee_ = CreatePeerConnectionWrapper("Callee", &callee_options, nullptr,
PeerConnectionDependencies(nullptr),
nullptr,
/*reset_encoder_factory=*/false,
/*reset_decoder_factory=*/false);
return caller_ && callee_;
}
bool CreatePeerConnectionWrappersWithFakeRtcEventLog() {
PeerConnectionInterface::RTCConfiguration default_config;
caller_ = CreatePeerConnectionWrapperWithFakeRtcEventLog(
"Caller", nullptr, &default_config,
PeerConnectionDependencies(nullptr));
callee_ = CreatePeerConnectionWrapperWithFakeRtcEventLog(
"Callee", nullptr, &default_config,
PeerConnectionDependencies(nullptr));
return caller_ && callee_;
}
std::unique_ptr<PeerConnectionIntegrationWrapper>
CreatePeerConnectionWrapperWithAlternateKey() {
std::unique_ptr<FakeRTCCertificateGenerator> cert_generator(
new FakeRTCCertificateGenerator());
cert_generator->use_alternate_key();
PeerConnectionDependencies dependencies(nullptr);
dependencies.cert_generator = std::move(cert_generator);
return CreatePeerConnectionWrapper("New Peer", nullptr, nullptr,
std::move(dependencies), nullptr,
/*reset_encoder_factory=*/false,
/*reset_decoder_factory=*/false);
}
bool CreateOneDirectionalPeerConnectionWrappers(bool caller_to_callee) {
caller_ = CreatePeerConnectionWrapper(
"Caller", nullptr, nullptr, PeerConnectionDependencies(nullptr),
nullptr,
/*reset_encoder_factory=*/!caller_to_callee,
/*reset_decoder_factory=*/caller_to_callee);
callee_ = CreatePeerConnectionWrapper(
"Callee", nullptr, nullptr, PeerConnectionDependencies(nullptr),
nullptr,
/*reset_encoder_factory=*/caller_to_callee,
/*reset_decoder_factory=*/!caller_to_callee);
return caller_ && callee_;
}
bool CreatePeerConnectionWrappersWithoutMediaEngine() {
caller_ = CreatePeerConnectionWrapper("Caller", nullptr, nullptr,
PeerConnectionDependencies(nullptr),
nullptr,
/*reset_encoder_factory=*/false,
/*reset_decoder_factory=*/false,
/*create_media_engine=*/false);
callee_ = CreatePeerConnectionWrapper("Callee", nullptr, nullptr,
PeerConnectionDependencies(nullptr),
nullptr,
/*reset_encoder_factory=*/false,
/*reset_decoder_factory=*/false,
/*create_media_engine=*/false);
return caller_ && callee_;
}
cricket::TestTurnServer* CreateTurnServer(
rtc::SocketAddress internal_address,
rtc::SocketAddress external_address,
cricket::ProtocolType type = cricket::ProtocolType::PROTO_UDP,
const std::string& common_name = "test turn server") {
rtc::Thread* thread = network_thread();
rtc::SocketFactory* socket_factory = fss_.get();
std::unique_ptr<cricket::TestTurnServer> turn_server;
SendTask(network_thread(), [&] {
turn_server = std::make_unique<cricket::TestTurnServer>(
thread, socket_factory, internal_address, external_address, type,
/*ignore_bad_certs=*/true, common_name);
});
turn_servers_.push_back(std::move(turn_server));
// Interactions with the turn server should be done on the network thread.
return turn_servers_.back().get();
}
cricket::TestTurnCustomizer* CreateTurnCustomizer() {
std::unique_ptr<cricket::TestTurnCustomizer> turn_customizer;
SendTask(network_thread(), [&] {
turn_customizer = std::make_unique<cricket::TestTurnCustomizer>();
});
turn_customizers_.push_back(std::move(turn_customizer));
// Interactions with the turn customizer should be done on the network
// thread.
return turn_customizers_.back().get();
}
// Checks that the function counters for a TestTurnCustomizer are greater than
// 0.
void ExpectTurnCustomizerCountersIncremented(
cricket::TestTurnCustomizer* turn_customizer) {
SendTask(network_thread(), [turn_customizer] {
EXPECT_GT(turn_customizer->allow_channel_data_cnt_, 0u);
EXPECT_GT(turn_customizer->modify_cnt_, 0u);
});
}
// Once called, SDP blobs and ICE candidates will be automatically signaled
// between PeerConnections.
void ConnectFakeSignaling() {
caller_->set_signaling_message_receiver(callee_.get());
callee_->set_signaling_message_receiver(caller_.get());
}
// Once called, SDP blobs will be automatically signaled between
// PeerConnections. Note that ICE candidates will not be signaled unless they
// are in the exchanged SDP blobs.
void ConnectFakeSignalingForSdpOnly() {
ConnectFakeSignaling();
SetSignalIceCandidates(false);
}
void SetSignalingDelayMs(int delay_ms) {
caller_->set_signaling_delay_ms(delay_ms);
callee_->set_signaling_delay_ms(delay_ms);
}
void SetSignalIceCandidates(bool signal) {
caller_->set_signal_ice_candidates(signal);
callee_->set_signal_ice_candidates(signal);
}
// Messages may get lost on the unreliable DataChannel, so we send multiple
// times to avoid test flakiness.
void SendRtpDataWithRetries(DataChannelInterface* dc,
const std::string& data,
int retries) {
for (int i = 0; i < retries; ++i) {
dc->Send(DataBuffer(data));
}
}
rtc::Thread* network_thread() { return network_thread_.get(); }
rtc::VirtualSocketServer* virtual_socket_server() { return ss_.get(); }
PeerConnectionIntegrationWrapper* caller() { return caller_.get(); }
// Destroy peerconnections.
// This can be used to ensure that all pointers to on-stack mocks
// get dropped before exit.
void DestroyPeerConnections() {
if (caller_) {
caller_->pc()->Close();
}
if (callee_) {
callee_->pc()->Close();
}
caller_.reset();
callee_.reset();
}
// Set the `caller_` to the `wrapper` passed in and return the
// original `caller_`.
PeerConnectionIntegrationWrapper* SetCallerPcWrapperAndReturnCurrent(
PeerConnectionIntegrationWrapper* wrapper) {
PeerConnectionIntegrationWrapper* old = caller_.release();
caller_.reset(wrapper);
return old;
}
PeerConnectionIntegrationWrapper* callee() { return callee_.get(); }
// Set the `callee_` to the `wrapper` passed in and return the
// original `callee_`.
PeerConnectionIntegrationWrapper* SetCalleePcWrapperAndReturnCurrent(
PeerConnectionIntegrationWrapper* wrapper) {
PeerConnectionIntegrationWrapper* old = callee_.release();
callee_.reset(wrapper);
return old;
}
void SetPortAllocatorFlags(uint32_t caller_flags, uint32_t callee_flags) {
SendTask(network_thread(), [this, caller_flags] {
caller()->port_allocator()->set_flags(caller_flags);
});
SendTask(network_thread(), [this, callee_flags] {
callee()->port_allocator()->set_flags(callee_flags);
});
}
rtc::FirewallSocketServer* firewall() const { return fss_.get(); }
// Expects the provided number of new frames to be received within
// kMaxWaitForFramesMs. The new expected frames are specified in
// `media_expectations`. Returns false if any of the expectations were
// not met.
bool ExpectNewFrames(const MediaExpectations& media_expectations) {
// Make sure there are no bogus tracks confusing the issue.
caller()->RemoveUnusedVideoRenderers();
callee()->RemoveUnusedVideoRenderers();
// First initialize the expected frame counts based upon the current
// frame count.
int total_caller_audio_frames_expected = caller()->audio_frames_received();
if (media_expectations.caller_audio_expectation_ ==
MediaExpectations::kExpectSomeFrames) {
total_caller_audio_frames_expected +=
media_expectations.caller_audio_frames_expected_;
}
int total_caller_video_frames_expected =
caller()->min_video_frames_received_per_track();
if (media_expectations.caller_video_expectation_ ==
MediaExpectations::kExpectSomeFrames) {
total_caller_video_frames_expected +=
media_expectations.caller_video_frames_expected_;
}
int total_callee_audio_frames_expected = callee()->audio_frames_received();
if (media_expectations.callee_audio_expectation_ ==
MediaExpectations::kExpectSomeFrames) {
total_callee_audio_frames_expected +=
media_expectations.callee_audio_frames_expected_;
}
int total_callee_video_frames_expected =
callee()->min_video_frames_received_per_track();
if (media_expectations.callee_video_expectation_ ==
MediaExpectations::kExpectSomeFrames) {
total_callee_video_frames_expected +=
media_expectations.callee_video_frames_expected_;
}
// Wait for the expected frames.
EXPECT_TRUE_WAIT(caller()->audio_frames_received() >=
total_caller_audio_frames_expected &&
caller()->min_video_frames_received_per_track() >=
total_caller_video_frames_expected &&
callee()->audio_frames_received() >=
total_callee_audio_frames_expected &&
callee()->min_video_frames_received_per_track() >=
total_callee_video_frames_expected,
kMaxWaitForFramesMs);
bool expectations_correct =
caller()->audio_frames_received() >=
total_caller_audio_frames_expected &&
caller()->min_video_frames_received_per_track() >=
total_caller_video_frames_expected &&
callee()->audio_frames_received() >=
total_callee_audio_frames_expected &&
callee()->min_video_frames_received_per_track() >=
total_callee_video_frames_expected;
// After the combined wait, print out a more detailed message upon
// failure.
EXPECT_GE(caller()->audio_frames_received(),
total_caller_audio_frames_expected);
EXPECT_GE(caller()->min_video_frames_received_per_track(),
total_caller_video_frames_expected);
EXPECT_GE(callee()->audio_frames_received(),
total_callee_audio_frames_expected);
EXPECT_GE(callee()->min_video_frames_received_per_track(),
total_callee_video_frames_expected);
// We want to make sure nothing unexpected was received.
if (media_expectations.caller_audio_expectation_ ==
MediaExpectations::kExpectNoFrames) {
EXPECT_EQ(caller()->audio_frames_received(),
total_caller_audio_frames_expected);
if (caller()->audio_frames_received() !=
total_caller_audio_frames_expected) {
expectations_correct = false;
}
}
if (media_expectations.caller_video_expectation_ ==
MediaExpectations::kExpectNoFrames) {
EXPECT_EQ(caller()->min_video_frames_received_per_track(),
total_caller_video_frames_expected);
if (caller()->min_video_frames_received_per_track() !=
total_caller_video_frames_expected) {
expectations_correct = false;
}
}
if (media_expectations.callee_audio_expectation_ ==
MediaExpectations::kExpectNoFrames) {
EXPECT_EQ(callee()->audio_frames_received(),
total_callee_audio_frames_expected);
if (callee()->audio_frames_received() !=
total_callee_audio_frames_expected) {
expectations_correct = false;
}
}
if (media_expectations.callee_video_expectation_ ==
MediaExpectations::kExpectNoFrames) {
EXPECT_EQ(callee()->min_video_frames_received_per_track(),
total_callee_video_frames_expected);
if (callee()->min_video_frames_received_per_track() !=
total_callee_video_frames_expected) {
expectations_correct = false;
}
}
return expectations_correct;
}
void ClosePeerConnections() {
if (caller())
caller()->pc()->Close();
if (callee())
callee()->pc()->Close();
}
void TestNegotiatedCipherSuite(
const PeerConnectionFactory::Options& caller_options,
const PeerConnectionFactory::Options& callee_options,
int expected_cipher_suite) {
ASSERT_TRUE(CreatePeerConnectionWrappersWithOptions(caller_options,
callee_options));
ConnectFakeSignaling();
caller()->AddAudioVideoTracks();
callee()->AddAudioVideoTracks();
caller()->CreateAndSetAndSignalOffer();
ASSERT_TRUE_WAIT(DtlsConnected(), kDefaultTimeout);
EXPECT_EQ_WAIT(rtc::SrtpCryptoSuiteToName(expected_cipher_suite),
caller()->OldGetStats()->SrtpCipher(), kDefaultTimeout);
}
void TestGcmNegotiationUsesCipherSuite(bool local_gcm_enabled,
bool remote_gcm_enabled,
bool aes_ctr_enabled,
int expected_cipher_suite) {
PeerConnectionFactory::Options caller_options;
caller_options.crypto_options.srtp.enable_gcm_crypto_suites =
local_gcm_enabled;
caller_options.crypto_options.srtp.enable_aes128_sha1_80_crypto_cipher =
aes_ctr_enabled;
PeerConnectionFactory::Options callee_options;
callee_options.crypto_options.srtp.enable_gcm_crypto_suites =
remote_gcm_enabled;
callee_options.crypto_options.srtp.enable_aes128_sha1_80_crypto_cipher =
aes_ctr_enabled;
TestNegotiatedCipherSuite(caller_options, callee_options,
expected_cipher_suite);
}
const FieldTrialsView& trials() const { return *field_trials_.get(); }
protected:
SdpSemantics sdp_semantics_;
private:
rtc::AutoThread main_thread_; // Used as the signal thread by most tests.
// `ss_` is used by `network_thread_` so it must be destroyed later.
std::unique_ptr<rtc::VirtualSocketServer> ss_;
std::unique_ptr<rtc::FirewallSocketServer> fss_;
// `network_thread_` and `worker_thread_` are used by both
// `caller_` and `callee_` so they must be destroyed
// later.
std::unique_ptr<rtc::Thread> network_thread_;
std::unique_ptr<rtc::Thread> worker_thread_;
// The turn servers and turn customizers should be accessed & deleted on the
// network thread to avoid a race with the socket read/write that occurs
// on the network thread.
std::vector<std::unique_ptr<cricket::TestTurnServer>> turn_servers_;
std::vector<std::unique_ptr<cricket::TestTurnCustomizer>> turn_customizers_;
std::unique_ptr<PeerConnectionIntegrationWrapper> caller_;
std::unique_ptr<PeerConnectionIntegrationWrapper> callee_;
std::unique_ptr<FieldTrialsView> field_trials_;
};
} // namespace webrtc
#endif // PC_TEST_INTEGRATION_TEST_HELPERS_H_