blob: b0d56fcb97daea8aadb25a7cd01c097e9f6dec59 [file] [log] [blame]
/*
* Copyright 2017 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 <stddef.h>
#include <stdint.h>
#include <memory>
#include <string>
#include <tuple>
#include <type_traits>
#include <utility>
#include <vector>
#include "absl/types/optional.h"
#include "api/audio/audio_mixer.h"
#include "api/candidate.h"
#include "api/ice_transport_interface.h"
#include "api/jsep.h"
#include "api/media_types.h"
#include "api/peer_connection_interface.h"
#include "api/rtc_error.h"
#include "api/scoped_refptr.h"
#include "modules/audio_device/include/audio_device.h"
#include "modules/audio_processing/include/audio_processing.h"
#include "p2p/base/fake_port_allocator.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/transport_description.h"
#include "p2p/base/transport_info.h"
#include "p2p/client/basic_port_allocator.h"
#include "pc/channel_interface.h"
#include "pc/dtls_transport.h"
#include "pc/media_session.h"
#include "pc/peer_connection.h"
#include "pc/peer_connection_wrapper.h"
#include "pc/rtp_transceiver.h"
#include "pc/sdp_utils.h"
#include "pc/session_description.h"
#include "rtc_base/checks.h"
#include "rtc_base/internal/default_socket_server.h"
#include "rtc_base/ip_address.h"
#include "rtc_base/logging.h"
#include "rtc_base/net_helper.h"
#include "rtc_base/rtc_certificate_generator.h"
#include "rtc_base/socket_address.h"
#include "rtc_base/thread.h"
#include "test/gtest.h"
#ifdef WEBRTC_ANDROID
#include "pc/test/android_test_initializer.h"
#endif
#include "api/audio_codecs/builtin_audio_decoder_factory.h"
#include "api/audio_codecs/builtin_audio_encoder_factory.h"
#include "api/create_peerconnection_factory.h"
#include "api/uma_metrics.h"
#include "api/video_codecs/builtin_video_decoder_factory.h"
#include "api/video_codecs/builtin_video_encoder_factory.h"
#include "pc/peer_connection_proxy.h"
#include "pc/test/fake_audio_capture_module.h"
#include "pc/test/mock_peer_connection_observers.h"
#include "rtc_base/fake_network.h"
#include "rtc_base/gunit.h"
#include "rtc_base/strings/string_builder.h"
#include "rtc_base/virtual_socket_server.h"
#include "system_wrappers/include/metrics.h"
#include "test/gmock.h"
namespace webrtc {
using RTCConfiguration = PeerConnectionInterface::RTCConfiguration;
using RTCOfferAnswerOptions = PeerConnectionInterface::RTCOfferAnswerOptions;
using rtc::SocketAddress;
using ::testing::Combine;
using ::testing::ElementsAre;
using ::testing::Pair;
using ::testing::Values;
constexpr int kIceCandidatesTimeout = 10000;
constexpr int64_t kWaitTimeout = 10000;
constexpr uint64_t kTiebreakerDefault = 44444;
class PeerConnectionWrapperForIceTest : public PeerConnectionWrapper {
public:
using PeerConnectionWrapper::PeerConnectionWrapper;
std::unique_ptr<IceCandidateInterface> CreateJsepCandidateForFirstTransport(
cricket::Candidate* candidate) {
RTC_DCHECK(pc()->remote_description());
const auto* desc = pc()->remote_description()->description();
RTC_DCHECK(desc->contents().size() > 0);
const auto& first_content = desc->contents()[0];
candidate->set_transport_name(first_content.name);
return CreateIceCandidate(first_content.name, -1, *candidate);
}
// Adds a new ICE candidate to the first transport.
bool AddIceCandidate(cricket::Candidate* candidate) {
return pc()->AddIceCandidate(
CreateJsepCandidateForFirstTransport(candidate).get());
}
// Returns ICE candidates from the remote session description.
std::vector<const IceCandidateInterface*>
GetIceCandidatesFromRemoteDescription() {
const SessionDescriptionInterface* sdesc = pc()->remote_description();
RTC_DCHECK(sdesc);
std::vector<const IceCandidateInterface*> candidates;
for (size_t mline_index = 0; mline_index < sdesc->number_of_mediasections();
mline_index++) {
const auto* candidate_collection = sdesc->candidates(mline_index);
for (size_t i = 0; i < candidate_collection->count(); i++) {
candidates.push_back(candidate_collection->at(i));
}
}
return candidates;
}
rtc::FakeNetworkManager* network() { return network_; }
void set_network(rtc::FakeNetworkManager* network) { network_ = network; }
// The port allocator used by this PC.
cricket::PortAllocator* port_allocator_;
private:
rtc::FakeNetworkManager* network_;
};
class PeerConnectionIceBaseTest : public ::testing::Test {
protected:
typedef std::unique_ptr<PeerConnectionWrapperForIceTest> WrapperPtr;
explicit PeerConnectionIceBaseTest(SdpSemantics sdp_semantics)
: vss_(new rtc::VirtualSocketServer()),
main_(vss_.get()),
sdp_semantics_(sdp_semantics) {
#ifdef WEBRTC_ANDROID
InitializeAndroidObjects();
#endif
pc_factory_ = CreatePeerConnectionFactory(
rtc::Thread::Current(), rtc::Thread::Current(), rtc::Thread::Current(),
rtc::scoped_refptr<AudioDeviceModule>(FakeAudioCaptureModule::Create()),
CreateBuiltinAudioEncoderFactory(), CreateBuiltinAudioDecoderFactory(),
CreateBuiltinVideoEncoderFactory(), CreateBuiltinVideoDecoderFactory(),
nullptr /* audio_mixer */, nullptr /* audio_processing */);
}
WrapperPtr CreatePeerConnection() {
return CreatePeerConnection(RTCConfiguration());
}
WrapperPtr CreatePeerConnection(const RTCConfiguration& config) {
auto* fake_network = NewFakeNetwork();
auto port_allocator = std::make_unique<cricket::BasicPortAllocator>(
fake_network,
std::make_unique<rtc::BasicPacketSocketFactory>(vss_.get()));
port_allocator->set_flags(cricket::PORTALLOCATOR_DISABLE_TCP |
cricket::PORTALLOCATOR_DISABLE_RELAY);
port_allocator->set_step_delay(cricket::kMinimumStepDelay);
RTCConfiguration modified_config = config;
modified_config.sdp_semantics = sdp_semantics_;
auto observer = std::make_unique<MockPeerConnectionObserver>();
auto port_allocator_copy = port_allocator.get();
PeerConnectionDependencies pc_dependencies(observer.get());
pc_dependencies.allocator = std::move(port_allocator);
auto result = pc_factory_->CreatePeerConnectionOrError(
modified_config, std::move(pc_dependencies));
if (!result.ok()) {
return nullptr;
}
observer->SetPeerConnectionInterface(result.value().get());
auto wrapper = std::make_unique<PeerConnectionWrapperForIceTest>(
pc_factory_, result.MoveValue(), std::move(observer));
wrapper->set_network(fake_network);
wrapper->port_allocator_ = port_allocator_copy;
return wrapper;
}
// Accepts the same arguments as CreatePeerConnection and adds default audio
// and video tracks.
template <typename... Args>
WrapperPtr CreatePeerConnectionWithAudioVideo(Args&&... args) {
auto wrapper = CreatePeerConnection(std::forward<Args>(args)...);
if (!wrapper) {
return nullptr;
}
wrapper->AddAudioTrack("a");
wrapper->AddVideoTrack("v");
return wrapper;
}
cricket::Candidate CreateLocalUdpCandidate(
const rtc::SocketAddress& address) {
cricket::Candidate candidate;
candidate.set_component(cricket::ICE_CANDIDATE_COMPONENT_DEFAULT);
candidate.set_protocol(cricket::UDP_PROTOCOL_NAME);
candidate.set_address(address);
candidate.set_type(cricket::LOCAL_PORT_TYPE);
return candidate;
}
// Remove all ICE ufrag/pwd lines from the given session description.
void RemoveIceUfragPwd(SessionDescriptionInterface* sdesc) {
SetIceUfragPwd(sdesc, "", "");
}
// Sets all ICE ufrag/pwds on the given session description.
void SetIceUfragPwd(SessionDescriptionInterface* sdesc,
const std::string& ufrag,
const std::string& pwd) {
auto* desc = sdesc->description();
for (const auto& content : desc->contents()) {
auto* transport_info = desc->GetTransportInfoByName(content.name);
transport_info->description.ice_ufrag = ufrag;
transport_info->description.ice_pwd = pwd;
}
}
// Set ICE mode on the given session description.
void SetIceMode(SessionDescriptionInterface* sdesc,
const cricket::IceMode ice_mode) {
auto* desc = sdesc->description();
for (const auto& content : desc->contents()) {
auto* transport_info = desc->GetTransportInfoByName(content.name);
transport_info->description.ice_mode = ice_mode;
}
}
cricket::TransportDescription* GetFirstTransportDescription(
SessionDescriptionInterface* sdesc) {
auto* desc = sdesc->description();
RTC_DCHECK(desc->contents().size() > 0);
auto* transport_info =
desc->GetTransportInfoByName(desc->contents()[0].name);
RTC_DCHECK(transport_info);
return &transport_info->description;
}
const cricket::TransportDescription* GetFirstTransportDescription(
const SessionDescriptionInterface* sdesc) {
auto* desc = sdesc->description();
RTC_DCHECK(desc->contents().size() > 0);
auto* transport_info =
desc->GetTransportInfoByName(desc->contents()[0].name);
RTC_DCHECK(transport_info);
return &transport_info->description;
}
// TODO(qingsi): Rewrite this method in terms of the standard IceTransport
// after it is implemented.
cricket::IceRole GetIceRole(const WrapperPtr& pc_wrapper_ptr) {
auto* pc_proxy =
static_cast<PeerConnectionProxyWithInternal<PeerConnectionInterface>*>(
pc_wrapper_ptr->pc());
PeerConnection* pc = static_cast<PeerConnection*>(pc_proxy->internal());
for (const auto& transceiver : pc->GetTransceiversInternal()) {
if (transceiver->media_type() == cricket::MEDIA_TYPE_AUDIO) {
auto dtls_transport = pc->LookupDtlsTransportByMidInternal(
transceiver->internal()->channel()->mid());
return dtls_transport->ice_transport()->internal()->GetIceRole();
}
}
RTC_DCHECK_NOTREACHED();
return cricket::ICEROLE_UNKNOWN;
}
// Returns a list of (ufrag, pwd) pairs in the order that they appear in
// `description`, or the empty list if `description` is null.
std::vector<std::pair<std::string, std::string>> GetIceCredentials(
const SessionDescriptionInterface* description) {
std::vector<std::pair<std::string, std::string>> ice_credentials;
if (!description)
return ice_credentials;
const auto* desc = description->description();
for (const auto& content_info : desc->contents()) {
const auto* transport_info =
desc->GetTransportInfoByName(content_info.name);
if (transport_info) {
ice_credentials.push_back(
std::make_pair(transport_info->description.ice_ufrag,
transport_info->description.ice_pwd));
}
}
return ice_credentials;
}
bool AddCandidateToFirstTransport(cricket::Candidate* candidate,
SessionDescriptionInterface* sdesc) {
auto* desc = sdesc->description();
RTC_DCHECK(desc->contents().size() > 0);
const auto& first_content = desc->contents()[0];
candidate->set_transport_name(first_content.name);
std::unique_ptr<IceCandidateInterface> jsep_candidate =
CreateIceCandidate(first_content.name, 0, *candidate);
return sdesc->AddCandidate(jsep_candidate.get());
}
rtc::FakeNetworkManager* NewFakeNetwork() {
// The PeerConnection's port allocator is tied to the PeerConnection's
// lifetime and expects the underlying NetworkManager to outlive it. That
// prevents us from having the PeerConnectionWrapper own the fake network.
// Therefore, the test fixture will own all the fake networks even though
// tests should access the fake network through the PeerConnectionWrapper.
auto* fake_network = new rtc::FakeNetworkManager();
fake_networks_.emplace_back(fake_network);
return fake_network;
}
std::unique_ptr<rtc::VirtualSocketServer> vss_;
rtc::AutoSocketServerThread main_;
rtc::scoped_refptr<PeerConnectionFactoryInterface> pc_factory_;
std::vector<std::unique_ptr<rtc::FakeNetworkManager>> fake_networks_;
const SdpSemantics sdp_semantics_;
};
class PeerConnectionIceTest
: public PeerConnectionIceBaseTest,
public ::testing::WithParamInterface<SdpSemantics> {
protected:
PeerConnectionIceTest() : PeerConnectionIceBaseTest(GetParam()) {
webrtc::metrics::Reset();
}
};
::testing::AssertionResult AssertCandidatesEqual(const char* a_expr,
const char* b_expr,
const cricket::Candidate& a,
const cricket::Candidate& b) {
rtc::StringBuilder failure_info;
if (a.component() != b.component()) {
failure_info << "\ncomponent: " << a.component() << " != " << b.component();
}
if (a.protocol() != b.protocol()) {
failure_info << "\nprotocol: " << a.protocol() << " != " << b.protocol();
}
if (a.address() != b.address()) {
failure_info << "\naddress: " << a.address().ToString()
<< " != " << b.address().ToString();
}
if (a.type() != b.type()) {
failure_info << "\ntype: " << a.type() << " != " << b.type();
}
std::string failure_info_str = failure_info.str();
if (failure_info_str.empty()) {
return ::testing::AssertionSuccess();
} else {
return ::testing::AssertionFailure()
<< a_expr << " and " << b_expr << " are not equal"
<< failure_info_str;
}
}
TEST_P(PeerConnectionIceTest, OfferContainsGatheredCandidates) {
const SocketAddress kLocalAddress("1.1.1.1", 0);
auto caller = CreatePeerConnectionWithAudioVideo();
caller->network()->AddInterface(kLocalAddress);
// Start ICE candidate gathering by setting the local offer.
ASSERT_TRUE(caller->SetLocalDescription(caller->CreateOffer()));
EXPECT_TRUE_WAIT(caller->IsIceGatheringDone(), kIceCandidatesTimeout);
auto offer = caller->CreateOffer();
EXPECT_LT(0u, caller->observer()->GetCandidatesByMline(0).size());
EXPECT_EQ(caller->observer()->GetCandidatesByMline(0).size(),
offer->candidates(0)->count());
EXPECT_LT(0u, caller->observer()->GetCandidatesByMline(1).size());
EXPECT_EQ(caller->observer()->GetCandidatesByMline(1).size(),
offer->candidates(1)->count());
}
TEST_P(PeerConnectionIceTest, AnswerContainsGatheredCandidates) {
const SocketAddress kCallerAddress("1.1.1.1", 0);
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
caller->network()->AddInterface(kCallerAddress);
ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal()));
ASSERT_TRUE(callee->SetLocalDescription(callee->CreateAnswer()));
EXPECT_TRUE_WAIT(callee->IsIceGatheringDone(), kIceCandidatesTimeout);
auto* answer = callee->pc()->local_description();
EXPECT_LT(0u, caller->observer()->GetCandidatesByMline(0).size());
EXPECT_EQ(callee->observer()->GetCandidatesByMline(0).size(),
answer->candidates(0)->count());
EXPECT_LT(0u, caller->observer()->GetCandidatesByMline(1).size());
EXPECT_EQ(callee->observer()->GetCandidatesByMline(1).size(),
answer->candidates(1)->count());
}
TEST_P(PeerConnectionIceTest,
CanSetRemoteSessionDescriptionWithRemoteCandidates) {
const SocketAddress kCallerAddress("1.1.1.1", 1111);
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
auto offer = caller->CreateOfferAndSetAsLocal();
cricket::Candidate candidate = CreateLocalUdpCandidate(kCallerAddress);
AddCandidateToFirstTransport(&candidate, offer.get());
ASSERT_TRUE(callee->SetRemoteDescription(std::move(offer)));
auto remote_candidates = callee->GetIceCandidatesFromRemoteDescription();
ASSERT_EQ(1u, remote_candidates.size());
EXPECT_PRED_FORMAT2(AssertCandidatesEqual, candidate,
remote_candidates[0]->candidate());
}
TEST_P(PeerConnectionIceTest, SetLocalDescriptionFailsIfNoIceCredentials) {
auto caller = CreatePeerConnectionWithAudioVideo();
auto offer = caller->CreateOffer();
RemoveIceUfragPwd(offer.get());
EXPECT_FALSE(caller->SetLocalDescription(std::move(offer)));
}
TEST_P(PeerConnectionIceTest, SetRemoteDescriptionFailsIfNoIceCredentials) {
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
auto offer = caller->CreateOfferAndSetAsLocal();
RemoveIceUfragPwd(offer.get());
EXPECT_FALSE(callee->SetRemoteDescription(std::move(offer)));
}
// Test that doing an offer/answer exchange with no transport (i.e., no data
// channel or media) results in the ICE connection state staying at New.
TEST_P(PeerConnectionIceTest,
OfferAnswerWithNoTransportsDoesNotChangeIceConnectionState) {
auto caller = CreatePeerConnection();
auto callee = CreatePeerConnection();
ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get()));
EXPECT_EQ(PeerConnectionInterface::kIceConnectionNew,
caller->pc()->ice_connection_state());
EXPECT_EQ(PeerConnectionInterface::kIceConnectionNew,
callee->pc()->ice_connection_state());
}
// The following group tests that ICE candidates are not generated before
// SetLocalDescription is called on a PeerConnection.
TEST_P(PeerConnectionIceTest, NoIceCandidatesBeforeSetLocalDescription) {
const SocketAddress kLocalAddress("1.1.1.1", 0);
auto caller = CreatePeerConnectionWithAudioVideo();
caller->network()->AddInterface(kLocalAddress);
// Pump for 1 second and verify that no candidates are generated.
rtc::Thread::Current()->ProcessMessages(1000);
EXPECT_EQ(0u, caller->observer()->candidates_.size());
}
TEST_P(PeerConnectionIceTest,
NoIceCandidatesBeforeAnswerSetAsLocalDescription) {
const SocketAddress kCallerAddress("1.1.1.1", 1111);
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
caller->network()->AddInterface(kCallerAddress);
auto offer = caller->CreateOfferAndSetAsLocal();
cricket::Candidate candidate = CreateLocalUdpCandidate(kCallerAddress);
AddCandidateToFirstTransport(&candidate, offer.get());
ASSERT_TRUE(callee->SetRemoteDescription(std::move(offer)));
// Pump for 1 second and verify that no candidates are generated.
rtc::Thread::Current()->ProcessMessages(1000);
EXPECT_EQ(0u, callee->observer()->candidates_.size());
}
TEST_P(PeerConnectionIceTest, CannotAddCandidateWhenRemoteDescriptionNotSet) {
const SocketAddress kCalleeAddress("1.1.1.1", 1111);
auto caller = CreatePeerConnectionWithAudioVideo();
cricket::Candidate candidate = CreateLocalUdpCandidate(kCalleeAddress);
std::unique_ptr<IceCandidateInterface> jsep_candidate =
CreateIceCandidate(cricket::CN_AUDIO, 0, candidate);
EXPECT_FALSE(caller->pc()->AddIceCandidate(jsep_candidate.get()));
caller->CreateOfferAndSetAsLocal();
EXPECT_FALSE(caller->pc()->AddIceCandidate(jsep_candidate.get()));
EXPECT_METRIC_THAT(
webrtc::metrics::Samples("WebRTC.PeerConnection.AddIceCandidate"),
ElementsAre(Pair(kAddIceCandidateFailNoRemoteDescription, 2)));
}
TEST_P(PeerConnectionIceTest, CannotAddCandidateWhenPeerConnectionClosed) {
const SocketAddress kCalleeAddress("1.1.1.1", 1111);
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get()));
cricket::Candidate candidate = CreateLocalUdpCandidate(kCalleeAddress);
auto* audio_content = cricket::GetFirstAudioContent(
caller->pc()->local_description()->description());
std::unique_ptr<IceCandidateInterface> jsep_candidate =
CreateIceCandidate(audio_content->name, 0, candidate);
caller->pc()->Close();
EXPECT_FALSE(caller->pc()->AddIceCandidate(jsep_candidate.get()));
}
TEST_P(PeerConnectionIceTest, DuplicateIceCandidateIgnoredWhenAdded) {
const SocketAddress kCalleeAddress("1.1.1.1", 1111);
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal()));
ASSERT_TRUE(
caller->SetRemoteDescription(callee->CreateAnswerAndSetAsLocal()));
cricket::Candidate candidate = CreateLocalUdpCandidate(kCalleeAddress);
caller->AddIceCandidate(&candidate);
EXPECT_TRUE(caller->AddIceCandidate(&candidate));
EXPECT_EQ(1u, caller->GetIceCandidatesFromRemoteDescription().size());
}
// TODO(tommi): Re-enable after updating RTCPeerConnection-blockedPorts.html in
// Chromium (the test needs setRemoteDescription to succeed for an invalid
// candidate).
TEST_P(PeerConnectionIceTest, DISABLED_ErrorOnInvalidRemoteIceCandidateAdded) {
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal()));
// Add a candidate to the remote description with a candidate that has an
// invalid address (port number == 2).
auto answer = callee->CreateAnswerAndSetAsLocal();
cricket::Candidate bad_candidate =
CreateLocalUdpCandidate(SocketAddress("2.2.2.2", 2));
RTC_LOG(LS_INFO) << "Bad candidate: " << bad_candidate.ToString();
AddCandidateToFirstTransport(&bad_candidate, answer.get());
// Now the call to SetRemoteDescription should fail.
EXPECT_FALSE(caller->SetRemoteDescription(std::move(answer)));
}
TEST_P(PeerConnectionIceTest,
CannotRemoveIceCandidatesWhenPeerConnectionClosed) {
const SocketAddress kCalleeAddress("1.1.1.1", 1111);
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get()));
cricket::Candidate candidate = CreateLocalUdpCandidate(kCalleeAddress);
auto* audio_content = cricket::GetFirstAudioContent(
caller->pc()->local_description()->description());
std::unique_ptr<IceCandidateInterface> ice_candidate =
CreateIceCandidate(audio_content->name, 0, candidate);
ASSERT_TRUE(caller->pc()->AddIceCandidate(ice_candidate.get()));
caller->pc()->Close();
EXPECT_FALSE(caller->pc()->RemoveIceCandidates({candidate}));
}
TEST_P(PeerConnectionIceTest,
AddRemoveCandidateWithEmptyTransportDoesNotCrash) {
const SocketAddress kCalleeAddress("1.1.1.1", 1111);
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal()));
ASSERT_TRUE(
caller->SetRemoteDescription(callee->CreateAnswerAndSetAsLocal()));
// `candidate.transport_name()` is empty.
cricket::Candidate candidate = CreateLocalUdpCandidate(kCalleeAddress);
auto* audio_content = cricket::GetFirstAudioContent(
caller->pc()->local_description()->description());
std::unique_ptr<IceCandidateInterface> ice_candidate =
CreateIceCandidate(audio_content->name, 0, candidate);
EXPECT_TRUE(caller->pc()->AddIceCandidate(ice_candidate.get()));
EXPECT_TRUE(caller->pc()->RemoveIceCandidates({candidate}));
}
TEST_P(PeerConnectionIceTest, RemoveCandidateRemovesFromRemoteDescription) {
const SocketAddress kCalleeAddress("1.1.1.1", 1111);
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal()));
ASSERT_TRUE(
caller->SetRemoteDescription(callee->CreateAnswerAndSetAsLocal()));
cricket::Candidate candidate = CreateLocalUdpCandidate(kCalleeAddress);
ASSERT_TRUE(caller->AddIceCandidate(&candidate));
EXPECT_TRUE(caller->pc()->RemoveIceCandidates({candidate}));
EXPECT_EQ(0u, caller->GetIceCandidatesFromRemoteDescription().size());
}
// Test that if a candidate is added via AddIceCandidate and via an updated
// remote description, then both candidates appear in the stored remote
// description.
TEST_P(PeerConnectionIceTest,
CandidateInSubsequentOfferIsAddedToRemoteDescription) {
const SocketAddress kCallerAddress1("1.1.1.1", 1111);
const SocketAddress kCallerAddress2("2.2.2.2", 2222);
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal()));
ASSERT_TRUE(
caller->SetRemoteDescription(callee->CreateAnswerAndSetAsLocal()));
// Add one candidate via `AddIceCandidate`.
cricket::Candidate candidate1 = CreateLocalUdpCandidate(kCallerAddress1);
ASSERT_TRUE(callee->AddIceCandidate(&candidate1));
// Add the second candidate via a reoffer.
auto offer = caller->CreateOffer();
cricket::Candidate candidate2 = CreateLocalUdpCandidate(kCallerAddress2);
AddCandidateToFirstTransport(&candidate2, offer.get());
// Expect both candidates to appear in the callee's remote description.
ASSERT_TRUE(callee->SetRemoteDescription(std::move(offer)));
EXPECT_EQ(2u, callee->GetIceCandidatesFromRemoteDescription().size());
}
// The follow test verifies that SetLocal/RemoteDescription fails when an offer
// has either ICE ufrag/pwd too short or too long and succeeds otherwise.
// The standard (https://tools.ietf.org/html/rfc5245#section-15.4) says that
// pwd must be 22-256 characters and ufrag must be 4-256 characters.
TEST_P(PeerConnectionIceTest, VerifyUfragPwdLength) {
auto set_local_description_with_ufrag_pwd_length = [this](int ufrag_len,
int pwd_len) {
auto pc = CreatePeerConnectionWithAudioVideo();
auto offer = pc->CreateOffer();
SetIceUfragPwd(offer.get(), std::string(ufrag_len, 'x'),
std::string(pwd_len, 'x'));
return pc->SetLocalDescription(std::move(offer));
};
auto set_remote_description_with_ufrag_pwd_length = [this](int ufrag_len,
int pwd_len) {
auto pc = CreatePeerConnectionWithAudioVideo();
auto offer = pc->CreateOffer();
SetIceUfragPwd(offer.get(), std::string(ufrag_len, 'x'),
std::string(pwd_len, 'x'));
return pc->SetRemoteDescription(std::move(offer));
};
EXPECT_FALSE(set_local_description_with_ufrag_pwd_length(3, 22));
EXPECT_FALSE(set_remote_description_with_ufrag_pwd_length(3, 22));
EXPECT_FALSE(set_local_description_with_ufrag_pwd_length(257, 22));
EXPECT_FALSE(set_remote_description_with_ufrag_pwd_length(257, 22));
EXPECT_FALSE(set_local_description_with_ufrag_pwd_length(4, 21));
EXPECT_FALSE(set_remote_description_with_ufrag_pwd_length(4, 21));
EXPECT_FALSE(set_local_description_with_ufrag_pwd_length(4, 257));
EXPECT_FALSE(set_remote_description_with_ufrag_pwd_length(4, 257));
EXPECT_TRUE(set_local_description_with_ufrag_pwd_length(4, 22));
EXPECT_TRUE(set_remote_description_with_ufrag_pwd_length(4, 22));
EXPECT_TRUE(set_local_description_with_ufrag_pwd_length(256, 256));
EXPECT_TRUE(set_remote_description_with_ufrag_pwd_length(256, 256));
}
::testing::AssertionResult AssertIpInCandidates(
const char* address_expr,
const char* candidates_expr,
const SocketAddress& address,
const std::vector<IceCandidateInterface*> candidates) {
rtc::StringBuilder candidate_hosts;
for (const auto* candidate : candidates) {
const auto& candidate_ip = candidate->candidate().address().ipaddr();
if (candidate_ip == address.ipaddr()) {
return ::testing::AssertionSuccess();
}
candidate_hosts << "\n" << candidate_ip.ToString();
}
return ::testing::AssertionFailure()
<< address_expr << " (host " << address.HostAsURIString()
<< ") not in " << candidates_expr
<< " which have the following address hosts:" << candidate_hosts.str();
}
TEST_P(PeerConnectionIceTest, CandidatesGeneratedForEachLocalInterface) {
const SocketAddress kLocalAddress1("1.1.1.1", 0);
const SocketAddress kLocalAddress2("2.2.2.2", 0);
auto caller = CreatePeerConnectionWithAudioVideo();
caller->network()->AddInterface(kLocalAddress1);
caller->network()->AddInterface(kLocalAddress2);
caller->CreateOfferAndSetAsLocal();
EXPECT_TRUE_WAIT(caller->IsIceGatheringDone(), kIceCandidatesTimeout);
auto candidates = caller->observer()->GetCandidatesByMline(0);
EXPECT_PRED_FORMAT2(AssertIpInCandidates, kLocalAddress1, candidates);
EXPECT_PRED_FORMAT2(AssertIpInCandidates, kLocalAddress2, candidates);
}
TEST_P(PeerConnectionIceTest, TrickledSingleCandidateAddedToRemoteDescription) {
const SocketAddress kCallerAddress("1.1.1.1", 1111);
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal()));
cricket::Candidate candidate = CreateLocalUdpCandidate(kCallerAddress);
callee->AddIceCandidate(&candidate);
auto candidates = callee->GetIceCandidatesFromRemoteDescription();
ASSERT_EQ(1u, candidates.size());
EXPECT_PRED_FORMAT2(AssertCandidatesEqual, candidate,
candidates[0]->candidate());
}
TEST_P(PeerConnectionIceTest, TwoTrickledCandidatesAddedToRemoteDescription) {
const SocketAddress kCalleeAddress1("1.1.1.1", 1111);
const SocketAddress kCalleeAddress2("2.2.2.2", 2222);
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal()));
ASSERT_TRUE(
caller->SetRemoteDescription(callee->CreateAnswerAndSetAsLocal()));
cricket::Candidate candidate1 = CreateLocalUdpCandidate(kCalleeAddress1);
caller->AddIceCandidate(&candidate1);
cricket::Candidate candidate2 = CreateLocalUdpCandidate(kCalleeAddress2);
caller->AddIceCandidate(&candidate2);
auto candidates = caller->GetIceCandidatesFromRemoteDescription();
ASSERT_EQ(2u, candidates.size());
EXPECT_PRED_FORMAT2(AssertCandidatesEqual, candidate1,
candidates[0]->candidate());
EXPECT_PRED_FORMAT2(AssertCandidatesEqual, candidate2,
candidates[1]->candidate());
}
TEST_P(PeerConnectionIceTest, AsyncAddIceCandidateIsAddedToRemoteDescription) {
auto candidate = CreateLocalUdpCandidate(SocketAddress("1.1.1.1", 1111));
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal()));
auto jsep_candidate =
callee->CreateJsepCandidateForFirstTransport(&candidate);
bool operation_completed = false;
callee->pc()->AddIceCandidate(std::move(jsep_candidate),
[&operation_completed](RTCError result) {
EXPECT_TRUE(result.ok());
operation_completed = true;
});
EXPECT_TRUE_WAIT(operation_completed, kWaitTimeout);
auto candidates = callee->GetIceCandidatesFromRemoteDescription();
ASSERT_EQ(1u, candidates.size());
EXPECT_PRED_FORMAT2(AssertCandidatesEqual, candidate,
candidates[0]->candidate());
}
TEST_P(PeerConnectionIceTest,
AsyncAddIceCandidateCompletesImmediatelyIfNoPendingOperation) {
auto candidate = CreateLocalUdpCandidate(SocketAddress("1.1.1.1", 1111));
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal()));
auto jsep_candidate =
callee->CreateJsepCandidateForFirstTransport(&candidate);
bool operation_completed = false;
callee->pc()->AddIceCandidate(
std::move(jsep_candidate),
[&operation_completed](RTCError result) { operation_completed = true; });
EXPECT_TRUE(operation_completed);
}
TEST_P(PeerConnectionIceTest,
AsyncAddIceCandidateCompletesWhenPendingOperationCompletes) {
auto candidate = CreateLocalUdpCandidate(SocketAddress("1.1.1.1", 1111));
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal()));
// Chain an operation that will block AddIceCandidate() from executing.
auto answer_observer =
rtc::make_ref_counted<MockCreateSessionDescriptionObserver>();
callee->pc()->CreateAnswer(answer_observer.get(), RTCOfferAnswerOptions());
auto jsep_candidate =
callee->CreateJsepCandidateForFirstTransport(&candidate);
bool operation_completed = false;
callee->pc()->AddIceCandidate(
std::move(jsep_candidate),
[&operation_completed](RTCError result) { operation_completed = true; });
// The operation will not be able to complete until we EXPECT_TRUE_WAIT()
// allowing CreateAnswer() to complete.
EXPECT_FALSE(operation_completed);
EXPECT_TRUE_WAIT(answer_observer->called(), kWaitTimeout);
// As soon as it does, AddIceCandidate() will execute without delay, so it
// must also have completed.
EXPECT_TRUE(operation_completed);
}
TEST_P(PeerConnectionIceTest,
AsyncAddIceCandidateFailsBeforeSetRemoteDescription) {
auto candidate = CreateLocalUdpCandidate(SocketAddress("1.1.1.1", 1111));
auto caller = CreatePeerConnectionWithAudioVideo();
std::unique_ptr<IceCandidateInterface> jsep_candidate =
CreateIceCandidate(cricket::CN_AUDIO, 0, candidate);
bool operation_completed = false;
caller->pc()->AddIceCandidate(
std::move(jsep_candidate), [&operation_completed](RTCError result) {
EXPECT_FALSE(result.ok());
EXPECT_EQ(result.message(),
std::string("The remote description was null"));
operation_completed = true;
});
EXPECT_TRUE_WAIT(operation_completed, kWaitTimeout);
}
TEST_P(PeerConnectionIceTest,
AsyncAddIceCandidateFailsIfPeerConnectionDestroyed) {
auto candidate = CreateLocalUdpCandidate(SocketAddress("1.1.1.1", 1111));
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal()));
// Chain an operation that will block AddIceCandidate() from executing.
auto answer_observer =
rtc::make_ref_counted<MockCreateSessionDescriptionObserver>();
callee->pc()->CreateAnswer(answer_observer.get(), RTCOfferAnswerOptions());
auto jsep_candidate =
callee->CreateJsepCandidateForFirstTransport(&candidate);
bool operation_completed = false;
callee->pc()->AddIceCandidate(
std::move(jsep_candidate), [&operation_completed](RTCError result) {
EXPECT_FALSE(result.ok());
EXPECT_EQ(
result.message(),
std::string(
"AddIceCandidate failed because the session was shut down"));
operation_completed = true;
});
// The operation will not be able to run until EXPECT_TRUE_WAIT(), giving us
// time to remove all references to the PeerConnection.
EXPECT_FALSE(operation_completed);
// This should delete the callee PC.
callee = nullptr;
EXPECT_TRUE_WAIT(operation_completed, kWaitTimeout);
}
TEST_P(PeerConnectionIceTest, LocalDescriptionUpdatedWhenContinualGathering) {
const SocketAddress kLocalAddress("1.1.1.1", 0);
RTCConfiguration config;
config.sdp_semantics = SdpSemantics::kUnifiedPlan;
config.continual_gathering_policy =
PeerConnectionInterface::GATHER_CONTINUALLY;
auto caller = CreatePeerConnectionWithAudioVideo(config);
caller->network()->AddInterface(kLocalAddress);
// Start ICE candidate gathering by setting the local offer.
ASSERT_TRUE(caller->SetLocalDescription(caller->CreateOffer()));
// Since we're using continual gathering, we won't get "gathering done".
EXPECT_TRUE_WAIT(
caller->pc()->local_description()->candidates(0)->count() > 0,
kIceCandidatesTimeout);
}
// Test that when continual gathering is enabled, and a network interface goes
// down, the candidate is signaled as removed and removed from the local
// description.
TEST_P(PeerConnectionIceTest,
LocalCandidatesRemovedWhenNetworkDownIfGatheringContinually) {
const SocketAddress kLocalAddress("1.1.1.1", 0);
RTCConfiguration config;
config.sdp_semantics = SdpSemantics::kUnifiedPlan;
config.continual_gathering_policy =
PeerConnectionInterface::GATHER_CONTINUALLY;
auto caller = CreatePeerConnectionWithAudioVideo(config);
caller->network()->AddInterface(kLocalAddress);
// Start ICE candidate gathering by setting the local offer.
ASSERT_TRUE(caller->SetLocalDescription(caller->CreateOffer()));
EXPECT_TRUE_WAIT(
caller->pc()->local_description()->candidates(0)->count() > 0,
kIceCandidatesTimeout);
// Remove the only network interface, causing the PeerConnection to signal
// the removal of all candidates derived from this interface.
caller->network()->RemoveInterface(kLocalAddress);
EXPECT_EQ_WAIT(0u, caller->pc()->local_description()->candidates(0)->count(),
kIceCandidatesTimeout);
EXPECT_LT(0, caller->observer()->num_candidates_removed_);
}
TEST_P(PeerConnectionIceTest,
LocalCandidatesNotRemovedWhenNetworkDownIfGatheringOnce) {
const SocketAddress kLocalAddress("1.1.1.1", 0);
RTCConfiguration config;
config.sdp_semantics = SdpSemantics::kUnifiedPlan;
config.continual_gathering_policy = PeerConnectionInterface::GATHER_ONCE;
auto caller = CreatePeerConnectionWithAudioVideo(config);
caller->network()->AddInterface(kLocalAddress);
// Start ICE candidate gathering by setting the local offer.
ASSERT_TRUE(caller->SetLocalDescription(caller->CreateOffer()));
EXPECT_TRUE_WAIT(caller->IsIceGatheringDone(), kIceCandidatesTimeout);
caller->network()->RemoveInterface(kLocalAddress);
// Verify that the local candidates are not removed;
rtc::Thread::Current()->ProcessMessages(1000);
EXPECT_EQ(0, caller->observer()->num_candidates_removed_);
}
// The following group tests that when an offer includes a new ufrag or pwd
// (indicating an ICE restart) the old candidates are removed and new candidates
// added to the remote description.
TEST_P(PeerConnectionIceTest, IceRestartOfferClearsExistingCandidate) {
const SocketAddress kCallerAddress("1.1.1.1", 1111);
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
auto offer = caller->CreateOfferAndSetAsLocal();
cricket::Candidate candidate = CreateLocalUdpCandidate(kCallerAddress);
AddCandidateToFirstTransport(&candidate, offer.get());
ASSERT_TRUE(callee->SetRemoteDescription(std::move(offer)));
RTCOfferAnswerOptions options;
options.ice_restart = true;
ASSERT_TRUE(
callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal(options)));
EXPECT_EQ(0u, callee->GetIceCandidatesFromRemoteDescription().size());
}
TEST_P(PeerConnectionIceTest,
IceRestartOfferCandidateReplacesExistingCandidate) {
const SocketAddress kFirstCallerAddress("1.1.1.1", 1111);
const SocketAddress kRestartedCallerAddress("2.2.2.2", 2222);
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
auto offer = caller->CreateOfferAndSetAsLocal();
cricket::Candidate old_candidate =
CreateLocalUdpCandidate(kFirstCallerAddress);
AddCandidateToFirstTransport(&old_candidate, offer.get());
ASSERT_TRUE(callee->SetRemoteDescription(std::move(offer)));
RTCOfferAnswerOptions options;
options.ice_restart = true;
auto restart_offer = caller->CreateOfferAndSetAsLocal(options);
cricket::Candidate new_candidate =
CreateLocalUdpCandidate(kRestartedCallerAddress);
AddCandidateToFirstTransport(&new_candidate, restart_offer.get());
ASSERT_TRUE(callee->SetRemoteDescription(std::move(restart_offer)));
auto remote_candidates = callee->GetIceCandidatesFromRemoteDescription();
ASSERT_EQ(1u, remote_candidates.size());
EXPECT_PRED_FORMAT2(AssertCandidatesEqual, new_candidate,
remote_candidates[0]->candidate());
}
// Test that if there is not an ICE restart (i.e., nothing changes), then the
// answer to a later offer should have the same ufrag/pwd as the first answer.
TEST_P(PeerConnectionIceTest, LaterAnswerHasSameIceCredentialsIfNoIceRestart) {
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal()));
ASSERT_TRUE(
caller->SetRemoteDescription(callee->CreateAnswerAndSetAsLocal()));
// Re-offer.
ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal()));
auto answer = callee->CreateAnswer();
auto* answer_transport_desc = GetFirstTransportDescription(answer.get());
auto* local_transport_desc =
GetFirstTransportDescription(callee->pc()->local_description());
EXPECT_EQ(answer_transport_desc->ice_ufrag, local_transport_desc->ice_ufrag);
EXPECT_EQ(answer_transport_desc->ice_pwd, local_transport_desc->ice_pwd);
}
TEST_P(PeerConnectionIceTest, RestartIceGeneratesNewCredentials) {
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get()));
auto initial_ice_credentials =
GetIceCredentials(caller->pc()->local_description());
caller->pc()->RestartIce();
ASSERT_TRUE(caller->CreateOfferAndSetAsLocal());
auto restarted_ice_credentials =
GetIceCredentials(caller->pc()->local_description());
EXPECT_NE(initial_ice_credentials, restarted_ice_credentials);
}
TEST_P(PeerConnectionIceTest,
RestartIceWhileLocalOfferIsPendingGeneratesNewCredentialsInNextOffer) {
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal()));
auto initial_ice_credentials =
GetIceCredentials(caller->pc()->local_description());
// ICE restart becomes needed while an O/A is pending and `caller` is the
// offerer.
caller->pc()->RestartIce();
ASSERT_TRUE(
caller->SetRemoteDescription(callee->CreateAnswerAndSetAsLocal()));
ASSERT_TRUE(caller->CreateOfferAndSetAsLocal());
auto restarted_ice_credentials =
GetIceCredentials(caller->pc()->local_description());
EXPECT_NE(initial_ice_credentials, restarted_ice_credentials);
}
TEST_P(PeerConnectionIceTest,
RestartIceWhileRemoteOfferIsPendingGeneratesNewCredentialsInNextOffer) {
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get()));
auto initial_ice_credentials =
GetIceCredentials(caller->pc()->local_description());
ASSERT_TRUE(caller->SetRemoteDescription(callee->CreateOfferAndSetAsLocal()));
// ICE restart becomes needed while an O/A is pending and `caller` is the
// answerer.
caller->pc()->RestartIce();
ASSERT_TRUE(
callee->SetRemoteDescription(caller->CreateAnswerAndSetAsLocal()));
ASSERT_TRUE(caller->CreateOfferAndSetAsLocal());
auto restarted_ice_credentials =
GetIceCredentials(caller->pc()->local_description());
EXPECT_NE(initial_ice_credentials, restarted_ice_credentials);
}
TEST_P(PeerConnectionIceTest, RestartIceTriggeredByRemoteSide) {
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get()));
auto initial_ice_credentials =
GetIceCredentials(caller->pc()->local_description());
// Remote restart and O/A exchange with `caller` as the answerer should
// restart ICE locally as well.
callee->pc()->RestartIce();
ASSERT_TRUE(callee->ExchangeOfferAnswerWith(caller.get()));
auto restarted_ice_credentials =
GetIceCredentials(caller->pc()->local_description());
EXPECT_NE(initial_ice_credentials, restarted_ice_credentials);
}
TEST_P(PeerConnectionIceTest, RestartIceCausesNegotiationNeeded) {
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get()));
caller->observer()->clear_legacy_renegotiation_needed();
caller->observer()->clear_latest_negotiation_needed_event();
caller->pc()->RestartIce();
EXPECT_TRUE(caller->observer()->legacy_renegotiation_needed());
EXPECT_TRUE(caller->observer()->has_negotiation_needed_event());
}
// In Unified Plan, "onnegotiationneeded" is spec-compliant, including not
// firing multipe times in a row, or firing when returning to the stable
// signaling state if negotiation is still needed. In Plan B it fires any time
// something changes. As such, some tests are SdpSemantics-specific.
class PeerConnectionIceTestUnifiedPlan : public PeerConnectionIceBaseTest {
protected:
PeerConnectionIceTestUnifiedPlan()
: PeerConnectionIceBaseTest(SdpSemantics::kUnifiedPlan) {}
};
TEST_F(PeerConnectionIceTestUnifiedPlan,
RestartIceWhileLocalOfferIsPendingCausesNegotiationNeededWhenStable) {
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal()));
// ICE restart becomes needed while an O/A is pending and `caller` is the
// offerer.
caller->observer()->clear_legacy_renegotiation_needed();
caller->observer()->clear_latest_negotiation_needed_event();
caller->pc()->RestartIce();
// In Unified Plan, the event should not fire until we are back in the stable
// signaling state.
EXPECT_FALSE(caller->observer()->legacy_renegotiation_needed());
EXPECT_FALSE(caller->observer()->has_negotiation_needed_event());
ASSERT_TRUE(
caller->SetRemoteDescription(callee->CreateAnswerAndSetAsLocal()));
EXPECT_TRUE(caller->observer()->legacy_renegotiation_needed());
EXPECT_TRUE(caller->observer()->has_negotiation_needed_event());
}
TEST_F(PeerConnectionIceTestUnifiedPlan,
RestartIceWhileRemoteOfferIsPendingCausesNegotiationNeededWhenStable) {
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
// Establish initial credentials as the caller.
ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get()));
ASSERT_TRUE(caller->SetRemoteDescription(callee->CreateOfferAndSetAsLocal()));
// ICE restart becomes needed while an O/A is pending and `caller` is the
// answerer.
caller->observer()->clear_legacy_renegotiation_needed();
caller->observer()->clear_latest_negotiation_needed_event();
caller->pc()->RestartIce();
// In Unified Plan, the event should not fire until we are back in the stable
// signaling state.
EXPECT_FALSE(caller->observer()->legacy_renegotiation_needed());
EXPECT_FALSE(caller->observer()->has_negotiation_needed_event());
ASSERT_TRUE(
callee->SetRemoteDescription(caller->CreateAnswerAndSetAsLocal()));
EXPECT_TRUE(caller->observer()->legacy_renegotiation_needed());
EXPECT_TRUE(caller->observer()->has_negotiation_needed_event());
}
TEST_F(PeerConnectionIceTestUnifiedPlan,
RestartIceTriggeredByRemoteSideCauseNegotiationNotNeeded) {
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get()));
// Local restart.
caller->pc()->RestartIce();
caller->observer()->clear_legacy_renegotiation_needed();
caller->observer()->clear_latest_negotiation_needed_event();
// Remote restart and O/A exchange with `caller` as the answerer should
// restart ICE locally as well.
callee->pc()->RestartIce();
ASSERT_TRUE(callee->ExchangeOfferAnswerWith(caller.get()));
// Having restarted ICE by the remote offer, we do not need to renegotiate ICE
// credentials when back in the stable signaling state.
EXPECT_FALSE(caller->observer()->legacy_renegotiation_needed());
EXPECT_FALSE(caller->observer()->has_negotiation_needed_event());
}
TEST_F(PeerConnectionIceTestUnifiedPlan,
RestartIceTwiceDoesNotFireNegotiationNeededTwice) {
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get()));
caller->pc()->RestartIce();
EXPECT_TRUE(caller->observer()->legacy_renegotiation_needed());
EXPECT_TRUE(caller->observer()->has_negotiation_needed_event());
caller->observer()->clear_legacy_renegotiation_needed();
caller->observer()->clear_latest_negotiation_needed_event();
caller->pc()->RestartIce();
EXPECT_FALSE(caller->observer()->legacy_renegotiation_needed());
EXPECT_FALSE(caller->observer()->has_negotiation_needed_event());
}
// In Plan B, "onnegotiationneeded" is not spec-compliant, firing based on if
// something changed rather than if negotiation is needed. In Unified Plan it
// fires according to spec. As such, some tests are SdpSemantics-specific.
class PeerConnectionIceTestPlanB : public PeerConnectionIceBaseTest {
protected:
PeerConnectionIceTestPlanB()
: PeerConnectionIceBaseTest(SdpSemantics::kPlanB_DEPRECATED) {}
};
TEST_F(PeerConnectionIceTestPlanB,
RestartIceWhileOfferIsPendingCausesNegotiationNeededImmediately) {
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal()));
caller->observer()->clear_legacy_renegotiation_needed();
caller->observer()->clear_latest_negotiation_needed_event();
caller->pc()->RestartIce();
EXPECT_TRUE(caller->observer()->legacy_renegotiation_needed());
EXPECT_TRUE(caller->observer()->has_negotiation_needed_event());
caller->observer()->clear_legacy_renegotiation_needed();
caller->observer()->clear_latest_negotiation_needed_event();
ASSERT_TRUE(
caller->SetRemoteDescription(callee->CreateAnswerAndSetAsLocal()));
// In Plan B, the event fired early so we don't expect it to fire now. This is
// not spec-compliant but follows the pattern of existing Plan B behavior.
EXPECT_FALSE(caller->observer()->legacy_renegotiation_needed());
EXPECT_FALSE(caller->observer()->has_negotiation_needed_event());
}
TEST_F(PeerConnectionIceTestPlanB,
RestartIceTwiceDoesFireNegotiationNeededTwice) {
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get()));
caller->observer()->clear_legacy_renegotiation_needed();
caller->observer()->clear_latest_negotiation_needed_event();
caller->pc()->RestartIce();
EXPECT_TRUE(caller->observer()->legacy_renegotiation_needed());
EXPECT_TRUE(caller->observer()->has_negotiation_needed_event());
caller->observer()->clear_legacy_renegotiation_needed();
caller->observer()->clear_latest_negotiation_needed_event();
caller->pc()->RestartIce();
// In Plan B, the event fires every time something changed, even if we have
// already fired the event. This is not spec-compliant but follows the same
// pattern of existing Plan B behavior.
EXPECT_TRUE(caller->observer()->legacy_renegotiation_needed());
EXPECT_TRUE(caller->observer()->has_negotiation_needed_event());
}
// The following parameterized test verifies that if an offer is sent with a
// modified ICE ufrag and/or ICE pwd, then the answer should identify that the
// other side has initiated an ICE restart and generate a new ufrag and pwd.
// RFC 5245 says: "If the offer contained a change in the a=ice-ufrag or
// a=ice-pwd attributes compared to the previous SDP from the peer, it
// indicates that ICE is restarting for this media stream."
class PeerConnectionIceUfragPwdAnswerTest
: public PeerConnectionIceBaseTest,
public ::testing::WithParamInterface<
std::tuple<SdpSemantics, std::tuple<bool, bool>>> {
protected:
PeerConnectionIceUfragPwdAnswerTest()
: PeerConnectionIceBaseTest(std::get<0>(GetParam())) {
auto param = std::get<1>(GetParam());
offer_new_ufrag_ = std::get<0>(param);
offer_new_pwd_ = std::get<1>(param);
}
bool offer_new_ufrag_;
bool offer_new_pwd_;
};
TEST_P(PeerConnectionIceUfragPwdAnswerTest, TestIncludedInAnswer) {
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal()));
ASSERT_TRUE(
caller->SetRemoteDescription(callee->CreateAnswerAndSetAsLocal()));
auto offer = caller->CreateOffer();
auto* offer_transport_desc = GetFirstTransportDescription(offer.get());
if (offer_new_ufrag_) {
offer_transport_desc->ice_ufrag += "+new";
}
if (offer_new_pwd_) {
offer_transport_desc->ice_pwd += "+new";
}
ASSERT_TRUE(callee->SetRemoteDescription(std::move(offer)));
auto answer = callee->CreateAnswer();
auto* answer_transport_desc = GetFirstTransportDescription(answer.get());
auto* local_transport_desc =
GetFirstTransportDescription(callee->pc()->local_description());
EXPECT_NE(answer_transport_desc->ice_ufrag, local_transport_desc->ice_ufrag);
EXPECT_NE(answer_transport_desc->ice_pwd, local_transport_desc->ice_pwd);
}
INSTANTIATE_TEST_SUITE_P(
PeerConnectionIceTest,
PeerConnectionIceUfragPwdAnswerTest,
Combine(Values(SdpSemantics::kPlanB_DEPRECATED, SdpSemantics::kUnifiedPlan),
Values(std::make_pair(true, true), // Both changed.
std::make_pair(true, false), // Only ufrag changed.
std::make_pair(false, true)))); // Only pwd changed.
// Test that if an ICE restart is offered on one media section, then the answer
// will only change ICE ufrag/pwd for that section and keep the other sections
// the same.
// Note that this only works if we have disabled BUNDLE, otherwise all media
// sections will share the same transport.
TEST_P(PeerConnectionIceTest,
CreateAnswerHasNewUfragPwdForOnlyMediaSectionWhichRestarted) {
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal()));
ASSERT_TRUE(
caller->SetRemoteDescription(callee->CreateAnswerAndSetAsLocal()));
RTCOfferAnswerOptions disable_bundle_options;
disable_bundle_options.use_rtp_mux = false;
auto offer = caller->CreateOffer(disable_bundle_options);
// Signal ICE restart on the first media section.
auto* offer_transport_desc = GetFirstTransportDescription(offer.get());
offer_transport_desc->ice_ufrag += "+new";
offer_transport_desc->ice_pwd += "+new";
ASSERT_TRUE(callee->SetRemoteDescription(std::move(offer)));
auto answer = callee->CreateAnswer(disable_bundle_options);
const auto& answer_transports = answer->description()->transport_infos();
const auto& local_transports =
callee->pc()->local_description()->description()->transport_infos();
EXPECT_NE(answer_transports[0].description.ice_ufrag,
local_transports[0].description.ice_ufrag);
EXPECT_NE(answer_transports[0].description.ice_pwd,
local_transports[0].description.ice_pwd);
EXPECT_EQ(answer_transports[1].description.ice_ufrag,
local_transports[1].description.ice_ufrag);
EXPECT_EQ(answer_transports[1].description.ice_pwd,
local_transports[1].description.ice_pwd);
}
// Test that when the initial offerer (caller) uses the lite implementation of
// ICE and the callee uses the full implementation, the caller takes the
// CONTROLLED role and the callee takes the CONTROLLING role. This is specified
// in RFC5245 Section 5.1.1.
TEST_P(PeerConnectionIceTest,
OfferFromLiteIceControlledAndAnswerFromFullIceControlling) {
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
auto offer = caller->CreateOffer();
SetIceMode(offer.get(), cricket::IceMode::ICEMODE_LITE);
ASSERT_TRUE(
caller->SetLocalDescription(CloneSessionDescription(offer.get())));
ASSERT_TRUE(callee->SetRemoteDescription(std::move(offer)));
auto answer = callee->CreateAnswer();
SetIceMode(answer.get(), cricket::IceMode::ICEMODE_FULL);
ASSERT_TRUE(
callee->SetLocalDescription(CloneSessionDescription(answer.get())));
ASSERT_TRUE(caller->SetRemoteDescription(std::move(answer)));
EXPECT_EQ(cricket::ICEROLE_CONTROLLED, GetIceRole(caller));
EXPECT_EQ(cricket::ICEROLE_CONTROLLING, GetIceRole(callee));
}
// Test that when the caller and the callee both use the lite implementation of
// ICE, the initial offerer (caller) takes the CONTROLLING role and the callee
// takes the CONTROLLED role. This is specified in RFC5245 Section 5.1.1.
TEST_P(PeerConnectionIceTest,
OfferFromLiteIceControllingAndAnswerFromLiteIceControlled) {
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
auto offer = caller->CreateOffer();
SetIceMode(offer.get(), cricket::IceMode::ICEMODE_LITE);
ASSERT_TRUE(
caller->SetLocalDescription(CloneSessionDescription(offer.get())));
ASSERT_TRUE(callee->SetRemoteDescription(std::move(offer)));
auto answer = callee->CreateAnswer();
SetIceMode(answer.get(), cricket::IceMode::ICEMODE_LITE);
ASSERT_TRUE(
callee->SetLocalDescription(CloneSessionDescription(answer.get())));
ASSERT_TRUE(caller->SetRemoteDescription(std::move(answer)));
EXPECT_EQ(cricket::ICEROLE_CONTROLLING, GetIceRole(caller));
EXPECT_EQ(cricket::ICEROLE_CONTROLLED, GetIceRole(callee));
}
INSTANTIATE_TEST_SUITE_P(PeerConnectionIceTest,
PeerConnectionIceTest,
Values(SdpSemantics::kPlanB_DEPRECATED,
SdpSemantics::kUnifiedPlan));
class PeerConnectionIceConfigTest : public ::testing::Test {
public:
PeerConnectionIceConfigTest()
: socket_server_(rtc::CreateDefaultSocketServer()),
main_thread_(socket_server_.get()) {}
protected:
void SetUp() override {
pc_factory_ = CreatePeerConnectionFactory(
rtc::Thread::Current(), rtc::Thread::Current(), rtc::Thread::Current(),
FakeAudioCaptureModule::Create(), CreateBuiltinAudioEncoderFactory(),
CreateBuiltinAudioDecoderFactory(), CreateBuiltinVideoEncoderFactory(),
CreateBuiltinVideoDecoderFactory(), nullptr /* audio_mixer */,
nullptr /* audio_processing */);
}
void CreatePeerConnection(const RTCConfiguration& config) {
packet_socket_factory_.reset(
new rtc::BasicPacketSocketFactory(socket_server_.get()));
std::unique_ptr<cricket::FakePortAllocator> port_allocator(
new cricket::FakePortAllocator(rtc::Thread::Current(),
packet_socket_factory_.get()));
port_allocator_ = port_allocator.get();
port_allocator_->SetIceTiebreaker(kTiebreakerDefault);
PeerConnectionDependencies pc_dependencies(&observer_);
pc_dependencies.allocator = std::move(port_allocator);
auto result = pc_factory_->CreatePeerConnectionOrError(
config, std::move(pc_dependencies));
EXPECT_TRUE(result.ok());
pc_ = result.MoveValue();
}
std::unique_ptr<rtc::SocketServer> socket_server_;
rtc::AutoSocketServerThread main_thread_;
rtc::scoped_refptr<PeerConnectionFactoryInterface> pc_factory_ = nullptr;
rtc::scoped_refptr<PeerConnectionInterface> pc_ = nullptr;
std::unique_ptr<rtc::PacketSocketFactory> packet_socket_factory_;
cricket::FakePortAllocator* port_allocator_ = nullptr;
MockPeerConnectionObserver observer_;
};
TEST_F(PeerConnectionIceConfigTest, SetStunCandidateKeepaliveInterval) {
RTCConfiguration config;
config.sdp_semantics = SdpSemantics::kUnifiedPlan;
config.stun_candidate_keepalive_interval = 123;
config.ice_candidate_pool_size = 1;
CreatePeerConnection(config);
ASSERT_NE(port_allocator_, nullptr);
absl::optional<int> actual_stun_keepalive_interval =
port_allocator_->stun_candidate_keepalive_interval();
EXPECT_EQ(actual_stun_keepalive_interval.value_or(-1), 123);
config.stun_candidate_keepalive_interval = 321;
ASSERT_TRUE(pc_->SetConfiguration(config).ok());
actual_stun_keepalive_interval =
port_allocator_->stun_candidate_keepalive_interval();
EXPECT_EQ(actual_stun_keepalive_interval.value_or(-1), 321);
}
TEST_F(PeerConnectionIceConfigTest, SetStableWritableConnectionInterval) {
RTCConfiguration config;
config.sdp_semantics = SdpSemantics::kUnifiedPlan;
config.stable_writable_connection_ping_interval_ms = 3500;
CreatePeerConnection(config);
EXPECT_TRUE(pc_->SetConfiguration(config).ok());
EXPECT_EQ(pc_->GetConfiguration().stable_writable_connection_ping_interval_ms,
config.stable_writable_connection_ping_interval_ms);
}
TEST_F(PeerConnectionIceConfigTest,
SetStableWritableConnectionInterval_FailsValidation) {
RTCConfiguration config;
config.sdp_semantics = SdpSemantics::kUnifiedPlan;
CreatePeerConnection(config);
ASSERT_TRUE(pc_->SetConfiguration(config).ok());
config.stable_writable_connection_ping_interval_ms = 5000;
config.ice_check_interval_strong_connectivity = 7500;
EXPECT_FALSE(pc_->SetConfiguration(config).ok());
}
TEST_F(PeerConnectionIceConfigTest,
SetStableWritableConnectionInterval_DefaultValue_FailsValidation) {
RTCConfiguration config;
config.sdp_semantics = SdpSemantics::kUnifiedPlan;
CreatePeerConnection(config);
ASSERT_TRUE(pc_->SetConfiguration(config).ok());
config.ice_check_interval_strong_connectivity = 2500;
EXPECT_TRUE(pc_->SetConfiguration(config).ok());
config.ice_check_interval_strong_connectivity = 2501;
EXPECT_FALSE(pc_->SetConfiguration(config).ok());
}
TEST_P(PeerConnectionIceTest, IceCredentialsCreateOffer) {
RTCConfiguration config;
config.sdp_semantics = SdpSemantics::kUnifiedPlan;
config.ice_candidate_pool_size = 1;
auto pc = CreatePeerConnectionWithAudioVideo(config);
ASSERT_NE(pc->port_allocator_, nullptr);
auto offer = pc->CreateOffer();
auto credentials = pc->port_allocator_->GetPooledIceCredentials();
ASSERT_EQ(1u, credentials.size());
auto* desc = offer->description();
for (const auto& content : desc->contents()) {
auto* transport_info = desc->GetTransportInfoByName(content.name);
EXPECT_EQ(transport_info->description.ice_ufrag, credentials[0].ufrag);
EXPECT_EQ(transport_info->description.ice_pwd, credentials[0].pwd);
}
}
TEST_P(PeerConnectionIceTest, IceCredentialsCreateAnswer) {
RTCConfiguration config;
config.sdp_semantics = SdpSemantics::kUnifiedPlan;
config.ice_candidate_pool_size = 1;
auto pc = CreatePeerConnectionWithAudioVideo(config);
ASSERT_NE(pc->port_allocator_, nullptr);
auto offer = pc->CreateOffer();
ASSERT_TRUE(pc->SetRemoteDescription(std::move(offer)));
auto answer = pc->CreateAnswer();
auto credentials = pc->port_allocator_->GetPooledIceCredentials();
ASSERT_EQ(1u, credentials.size());
auto* desc = answer->description();
for (const auto& content : desc->contents()) {
auto* transport_info = desc->GetTransportInfoByName(content.name);
EXPECT_EQ(transport_info->description.ice_ufrag, credentials[0].ufrag);
EXPECT_EQ(transport_info->description.ice_pwd, credentials[0].pwd);
}
}
// Regression test for https://bugs.chromium.org/p/webrtc/issues/detail?id=4728
TEST_P(PeerConnectionIceTest, CloseDoesNotTransitionGatheringStateToComplete) {
auto pc = CreatePeerConnectionWithAudioVideo();
pc->pc()->Close();
EXPECT_FALSE(pc->IsIceGatheringDone());
EXPECT_EQ(PeerConnectionInterface::kIceGatheringNew,
pc->pc()->ice_gathering_state());
}
TEST_P(PeerConnectionIceTest, PrefersMidOverMLineIndex) {
const SocketAddress kCalleeAddress("1.1.1.1", 1111);
auto caller = CreatePeerConnectionWithAudioVideo();
auto callee = CreatePeerConnectionWithAudioVideo();
ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal()));
ASSERT_TRUE(
caller->SetRemoteDescription(callee->CreateAnswerAndSetAsLocal()));
// `candidate.transport_name()` is empty.
cricket::Candidate candidate = CreateLocalUdpCandidate(kCalleeAddress);
auto* audio_content = cricket::GetFirstAudioContent(
caller->pc()->local_description()->description());
std::unique_ptr<IceCandidateInterface> ice_candidate =
CreateIceCandidate(audio_content->name, 65535, candidate);
EXPECT_TRUE(caller->pc()->AddIceCandidate(ice_candidate.get()));
EXPECT_TRUE(caller->pc()->RemoveIceCandidates({candidate}));
}
} // namespace webrtc