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webrtc / src.git / e486a7bdf72e02c65b80e29a8e4988d7754c1ec2 / . / pc / channel_unittest.cc
blob: 725ee349189db90f5434de11f686c70c6330c2b6 [file] [log] [blame]
/*
* Copyright 2009 The WebRTC project authors. All Rights Reserved.
*
* Use of this source code is governed by a BSD-style license
* that can be found in the LICENSE file in the root of the source
* tree. An additional intellectual property rights grant can be found
* in the file PATENTS. All contributing project authors may
* be found in the AUTHORS file in the root of the source tree.
*/
#include "pc/channel.h"
#include <stddef.h>
#include <cstdint>
#include <string>
#include <type_traits>
#include "api/array_view.h"
#include "api/audio_options.h"
#include "api/rtp_parameters.h"
#include "media/base/codec.h"
#include "media/base/fake_media_engine.h"
#include "media/base/fake_rtp.h"
#include "media/base/media_channel.h"
#include "media/base/media_constants.h"
#include "media/base/rid_description.h"
#include "p2p/base/candidate_pair_interface.h"
#include "p2p/base/dtls_transport_internal.h"
#include "p2p/base/fake_dtls_transport.h"
#include "p2p/base/fake_packet_transport.h"
#include "p2p/base/ice_transport_internal.h"
#include "p2p/base/p2p_constants.h"
#include "p2p/base/packet_transport_internal.h"
#include "pc/dtls_srtp_transport.h"
#include "pc/jsep_transport.h"
#include "pc/rtp_transport.h"
#include "rtc_base/arraysize.h"
#include "rtc_base/buffer.h"
#include "rtc_base/byte_order.h"
#include "rtc_base/checks.h"
#include "rtc_base/location.h"
#include "rtc_base/rtc_certificate.h"
#include "rtc_base/ssl_identity.h"
#include "rtc_base/task_utils/pending_task_safety_flag.h"
#include "rtc_base/task_utils/to_queued_task.h"
#include "test/gmock.h"
#include "test/gtest.h"
#include "test/scoped_key_value_config.h"
using cricket::DtlsTransportInternal;
using cricket::FakeVoiceMediaChannel;
using cricket::RidDescription;
using cricket::RidDirection;
using cricket::StreamParams;
using webrtc::RtpTransceiverDirection;
using webrtc::SdpType;
namespace {
const cricket::AudioCodec kPcmuCodec(0, "PCMU", 64000, 8000, 1);
const cricket::AudioCodec kPcmaCodec(8, "PCMA", 64000, 8000, 1);
const cricket::AudioCodec kIsacCodec(103, "ISAC", 40000, 16000, 1);
const cricket::VideoCodec kH264Codec(97, "H264");
const cricket::VideoCodec kH264SvcCodec(99, "H264-SVC");
const uint32_t kSsrc1 = 0x1111;
const uint32_t kSsrc2 = 0x2222;
const uint32_t kSsrc3 = 0x3333;
const uint32_t kSsrc4 = 0x4444;
const int kAudioPts[] = {0, 8};
const int kVideoPts[] = {97, 99};
enum class NetworkIsWorker { Yes, No };
} // namespace
template <class ChannelT,
class MediaChannelT,
class ContentT,
class CodecT,
class MediaInfoT,
class OptionsT>
class Traits {
public:
typedef ChannelT Channel;
typedef MediaChannelT MediaChannel;
typedef ContentT Content;
typedef CodecT Codec;
typedef MediaInfoT MediaInfo;
typedef OptionsT Options;
};
class VoiceTraits : public Traits<cricket::VoiceChannel,
cricket::FakeVoiceMediaChannel,
cricket::AudioContentDescription,
cricket::AudioCodec,
cricket::VoiceMediaInfo,
cricket::AudioOptions> {};
class VideoTraits : public Traits<cricket::VideoChannel,
cricket::FakeVideoMediaChannel,
cricket::VideoContentDescription,
cricket::VideoCodec,
cricket::VideoMediaInfo,
cricket::VideoOptions> {};
// Base class for Voice/Video tests
template <class T>
class ChannelTest : public ::testing::Test, public sigslot::has_slots<> {
public:
enum Flags {
RTCP_MUX = 0x1,
SSRC_MUX = 0x8,
DTLS = 0x10,
// Use BaseChannel with PacketTransportInternal rather than
// DtlsTransportInternal.
RAW_PACKET_TRANSPORT = 0x20,
};
ChannelTest(bool verify_playout,
rtc::ArrayView<const uint8_t> rtp_data,
rtc::ArrayView<const uint8_t> rtcp_data,
NetworkIsWorker network_is_worker)
: verify_playout_(verify_playout),
rtp_packet_(rtp_data.data(), rtp_data.size()),
rtcp_packet_(rtcp_data.data(), rtcp_data.size()) {
if (network_is_worker == NetworkIsWorker::Yes) {
network_thread_ = rtc::Thread::Current();
} else {
network_thread_keeper_ = rtc::Thread::Create();
network_thread_keeper_->SetName("Network", nullptr);
network_thread_ = network_thread_keeper_.get();
}
RTC_DCHECK(network_thread_);
}
~ChannelTest() {
if (network_thread_) {
network_thread_->Invoke<void>(RTC_FROM_HERE, [this]() {
network_thread_safety_->SetNotAlive();
DeinitChannels();
});
}
}
void CreateChannels(int flags1, int flags2) {
CreateChannels(std::make_unique<typename T::MediaChannel>(
nullptr, typename T::Options(), network_thread_),
std::make_unique<typename T::MediaChannel>(
nullptr, typename T::Options(), network_thread_),
flags1, flags2);
}
void CreateChannels(std::unique_ptr<typename T::MediaChannel> ch1,
std::unique_ptr<typename T::MediaChannel> ch2,
int flags1,
int flags2) {
RTC_DCHECK(!channel1_);
RTC_DCHECK(!channel2_);
// Network thread is started in CreateChannels, to allow the test to
// configure a fake clock before any threads are spawned and attempt to
// access the time.
if (network_thread_keeper_) {
network_thread_keeper_->Start();
}
// Make sure if using raw packet transports, they're used for both
// channels.
RTC_DCHECK_EQ(flags1 & RAW_PACKET_TRANSPORT, flags2 & RAW_PACKET_TRANSPORT);
rtc::Thread* worker_thread = rtc::Thread::Current();
// Based on flags, create fake DTLS or raw packet transports.
if (flags1 & RAW_PACKET_TRANSPORT) {
fake_rtp_packet_transport1_.reset(
new rtc::FakePacketTransport("channel1_rtp"));
if (!(flags1 & RTCP_MUX)) {
fake_rtcp_packet_transport1_.reset(
new rtc::FakePacketTransport("channel1_rtcp"));
}
} else {
// Confirmed to work with KT_RSA and KT_ECDSA.
fake_rtp_dtls_transport1_.reset(new cricket::FakeDtlsTransport(
"channel1", cricket::ICE_CANDIDATE_COMPONENT_RTP, network_thread_));
if (!(flags1 & RTCP_MUX)) {
fake_rtcp_dtls_transport1_.reset(new cricket::FakeDtlsTransport(
"channel1", cricket::ICE_CANDIDATE_COMPONENT_RTCP,
network_thread_));
}
if (flags1 & DTLS) {
auto cert1 = rtc::RTCCertificate::Create(
rtc::SSLIdentity::Create("session1", rtc::KT_DEFAULT));
fake_rtp_dtls_transport1_->SetLocalCertificate(cert1);
if (fake_rtcp_dtls_transport1_) {
fake_rtcp_dtls_transport1_->SetLocalCertificate(cert1);
}
}
}
// Based on flags, create fake DTLS or raw packet transports.
if (flags2 & RAW_PACKET_TRANSPORT) {
fake_rtp_packet_transport2_.reset(
new rtc::FakePacketTransport("channel2_rtp"));
if (!(flags2 & RTCP_MUX)) {
fake_rtcp_packet_transport2_.reset(
new rtc::FakePacketTransport("channel2_rtcp"));
}
} else {
// Confirmed to work with KT_RSA and KT_ECDSA.
fake_rtp_dtls_transport2_.reset(new cricket::FakeDtlsTransport(
"channel2", cricket::ICE_CANDIDATE_COMPONENT_RTP, network_thread_));
if (!(flags2 & RTCP_MUX)) {
fake_rtcp_dtls_transport2_.reset(new cricket::FakeDtlsTransport(
"channel2", cricket::ICE_CANDIDATE_COMPONENT_RTCP,
network_thread_));
}
if (flags2 & DTLS) {
auto cert2 = rtc::RTCCertificate::Create(
rtc::SSLIdentity::Create("session2", rtc::KT_DEFAULT));
fake_rtp_dtls_transport2_->SetLocalCertificate(cert2);
if (fake_rtcp_dtls_transport2_) {
fake_rtcp_dtls_transport2_->SetLocalCertificate(cert2);
}
}
}
rtp_transport1_ = CreateRtpTransportBasedOnFlags(
fake_rtp_packet_transport1_.get(), fake_rtcp_packet_transport1_.get(),
fake_rtp_dtls_transport1_.get(), fake_rtcp_dtls_transport1_.get(),
flags1);
rtp_transport2_ = CreateRtpTransportBasedOnFlags(
fake_rtp_packet_transport2_.get(), fake_rtcp_packet_transport2_.get(),
fake_rtp_dtls_transport2_.get(), fake_rtcp_dtls_transport2_.get(),
flags2);
channel1_ = CreateChannel(worker_thread, network_thread_, std::move(ch1),
rtp_transport1_.get(), flags1);
channel2_ = CreateChannel(worker_thread, network_thread_, std::move(ch2),
rtp_transport2_.get(), flags2);
CreateContent(flags1, kPcmuCodec, kH264Codec, &local_media_content1_);
CreateContent(flags2, kPcmuCodec, kH264Codec, &local_media_content2_);
CopyContent(local_media_content1_, &remote_media_content1_);
CopyContent(local_media_content2_, &remote_media_content2_);
// Add stream information (SSRC) to the local content but not to the remote
// content. This means that we per default know the SSRC of what we send but
// not what we receive.
AddLegacyStreamInContent(kSsrc1, flags1, &local_media_content1_);
AddLegacyStreamInContent(kSsrc2, flags2, &local_media_content2_);
// If SSRC_MUX is used we also need to know the SSRC of the incoming stream.
if (flags1 & SSRC_MUX) {
AddLegacyStreamInContent(kSsrc1, flags1, &remote_media_content1_);
}
if (flags2 & SSRC_MUX) {
AddLegacyStreamInContent(kSsrc2, flags2, &remote_media_content2_);
}
}
std::unique_ptr<typename T::Channel> CreateChannel(
rtc::Thread* worker_thread,
rtc::Thread* network_thread,
std::unique_ptr<typename T::MediaChannel> ch,
webrtc::RtpTransportInternal* rtp_transport,
int flags);
std::unique_ptr<webrtc::RtpTransportInternal> CreateRtpTransportBasedOnFlags(
rtc::PacketTransportInternal* rtp_packet_transport,
rtc::PacketTransportInternal* rtcp_packet_transport,
DtlsTransportInternal* rtp_dtls_transport,
DtlsTransportInternal* rtcp_dtls_transport,
int flags) {
if (flags & RTCP_MUX) {
rtcp_packet_transport = nullptr;
rtcp_dtls_transport = nullptr;
}
if (flags & DTLS) {
return CreateDtlsSrtpTransport(rtp_dtls_transport, rtcp_dtls_transport);
} else {
if (flags & RAW_PACKET_TRANSPORT) {
return CreateUnencryptedTransport(rtp_packet_transport,
rtcp_packet_transport);
} else {
return CreateUnencryptedTransport(rtp_dtls_transport,
rtcp_dtls_transport);
}
}
}
// Unininitializes the channels on the network thread.
void DeinitChannels() {
if (!channel1_ && !channel2_)
return;
network_thread_->Invoke<void>(RTC_FROM_HERE, [this]() {
if (channel1_) {
RTC_DCHECK_RUN_ON(channel1_->network_thread());
channel1_->SetRtpTransport(nullptr);
}
if (channel2_) {
RTC_DCHECK_RUN_ON(channel2_->network_thread());
channel2_->SetRtpTransport(nullptr);
}
});
}
std::unique_ptr<webrtc::RtpTransport> CreateUnencryptedTransport(
rtc::PacketTransportInternal* rtp_packet_transport,
rtc::PacketTransportInternal* rtcp_packet_transport) {
auto rtp_transport = std::make_unique<webrtc::RtpTransport>(
rtcp_packet_transport == nullptr);
network_thread_->Invoke<void>(
RTC_FROM_HERE,
[&rtp_transport, rtp_packet_transport, rtcp_packet_transport] {
rtp_transport->SetRtpPacketTransport(rtp_packet_transport);
if (rtcp_packet_transport) {
rtp_transport->SetRtcpPacketTransport(rtcp_packet_transport);
}
});
return rtp_transport;
}
std::unique_ptr<webrtc::DtlsSrtpTransport> CreateDtlsSrtpTransport(
cricket::DtlsTransportInternal* rtp_dtls_transport,
cricket::DtlsTransportInternal* rtcp_dtls_transport) {
auto dtls_srtp_transport = std::make_unique<webrtc::DtlsSrtpTransport>(
rtcp_dtls_transport == nullptr, field_trials_);
network_thread_->Invoke<void>(
RTC_FROM_HERE,
[&dtls_srtp_transport, rtp_dtls_transport, rtcp_dtls_transport] {
dtls_srtp_transport->SetDtlsTransports(rtp_dtls_transport,
rtcp_dtls_transport);
});
return dtls_srtp_transport;
}
void ConnectFakeTransports() {
network_thread_->Invoke<void>(RTC_FROM_HERE, [this] {
bool asymmetric = false;
// Depending on test flags, could be using DTLS or raw packet transport.
if (fake_rtp_dtls_transport1_ && fake_rtp_dtls_transport2_) {
fake_rtp_dtls_transport1_->SetDestination(
fake_rtp_dtls_transport2_.get(), asymmetric);
}
if (fake_rtcp_dtls_transport1_ && fake_rtcp_dtls_transport2_) {
fake_rtcp_dtls_transport1_->SetDestination(
fake_rtcp_dtls_transport2_.get(), asymmetric);
}
if (fake_rtp_packet_transport1_ && fake_rtp_packet_transport2_) {
fake_rtp_packet_transport1_->SetDestination(
fake_rtp_packet_transport2_.get(), asymmetric);
}
if (fake_rtcp_packet_transport1_ && fake_rtcp_packet_transport2_) {
fake_rtcp_packet_transport1_->SetDestination(
fake_rtcp_packet_transport2_.get(), asymmetric);
}
});
// The transport becoming writable will asynchronously update the send state
// on the worker thread; since this test uses the main thread as the worker
// thread, we must process the message queue for this to occur.
WaitForThreads();
}
bool SendInitiate() {
std::string err;
bool result = channel1_->SetLocalContent(&local_media_content1_,
SdpType::kOffer, err);
if (result) {
channel1_->Enable(true);
FlushCurrentThread();
result = channel2_->SetRemoteContent(&remote_media_content1_,
SdpType::kOffer, err);
if (result) {
ConnectFakeTransports();
result = channel2_->SetLocalContent(&local_media_content2_,
SdpType::kAnswer, err);
}
}
return result;
}
bool SendAccept() {
channel2_->Enable(true);
FlushCurrentThread();
std::string err;
return channel1_->SetRemoteContent(&remote_media_content2_,
SdpType::kAnswer, err);
}
bool SendOffer() {
std::string err;
bool result = channel1_->SetLocalContent(&local_media_content1_,
SdpType::kOffer, err);
if (result) {
channel1_->Enable(true);
result = channel2_->SetRemoteContent(&remote_media_content1_,
SdpType::kOffer, err);
}
return result;
}
bool SendProvisionalAnswer() {
std::string err;
bool result = channel2_->SetLocalContent(&local_media_content2_,
SdpType::kPrAnswer, err);
if (result) {
channel2_->Enable(true);
result = channel1_->SetRemoteContent(&remote_media_content2_,
SdpType::kPrAnswer, err);
ConnectFakeTransports();
}
return result;
}
bool SendFinalAnswer() {
std::string err;
bool result = channel2_->SetLocalContent(&local_media_content2_,
SdpType::kAnswer, err);
if (result) {
result = channel1_->SetRemoteContent(&remote_media_content2_,
SdpType::kAnswer, err);
}
return result;
}
void SendRtp(typename T::MediaChannel* media_channel, rtc::Buffer data) {
network_thread_->PostTask(webrtc::ToQueuedTask(
network_thread_safety_, [media_channel, data = std::move(data)]() {
media_channel->SendRtp(data.data(), data.size(),
rtc::PacketOptions());
}));
}
void SendRtp1() {
SendRtp1(rtc::Buffer(rtp_packet_.data(), rtp_packet_.size()));
}
void SendRtp1(rtc::Buffer data) {
SendRtp(media_channel1(), std::move(data));
}
void SendRtp2() {
SendRtp2(rtc::Buffer(rtp_packet_.data(), rtp_packet_.size()));
}
void SendRtp2(rtc::Buffer data) {
SendRtp(media_channel2(), std::move(data));
}
// Methods to send custom data.
void SendCustomRtp1(uint32_t ssrc, int sequence_number, int pl_type = -1) {
SendRtp1(CreateRtpData(ssrc, sequence_number, pl_type));
}
void SendCustomRtp2(uint32_t ssrc, int sequence_number, int pl_type = -1) {
SendRtp2(CreateRtpData(ssrc, sequence_number, pl_type));
}
bool CheckRtp1() {
return media_channel1()->CheckRtp(rtp_packet_.data(), rtp_packet_.size());
}
bool CheckRtp2() {
return media_channel2()->CheckRtp(rtp_packet_.data(), rtp_packet_.size());
}
// Methods to check custom data.
bool CheckCustomRtp1(uint32_t ssrc, int sequence_number, int pl_type = -1) {
rtc::Buffer data = CreateRtpData(ssrc, sequence_number, pl_type);
return media_channel1()->CheckRtp(data.data(), data.size());
}
bool CheckCustomRtp2(uint32_t ssrc, int sequence_number, int pl_type = -1) {
rtc::Buffer data = CreateRtpData(ssrc, sequence_number, pl_type);
return media_channel2()->CheckRtp(data.data(), data.size());
}
rtc::Buffer CreateRtpData(uint32_t ssrc, int sequence_number, int pl_type) {
rtc::Buffer data(rtp_packet_.data(), rtp_packet_.size());
// Set SSRC in the rtp packet copy.
rtc::SetBE32(data.data() + 8, ssrc);
rtc::SetBE16(data.data() + 2, sequence_number);
if (pl_type >= 0) {
rtc::Set8(data.data(), 1, static_cast<uint8_t>(pl_type));
}
return data;
}
bool CheckNoRtp1() { return media_channel1()->CheckNoRtp(); }
bool CheckNoRtp2() { return media_channel2()->CheckNoRtp(); }
void CreateContent(int flags,
const cricket::AudioCodec& audio_codec,
const cricket::VideoCodec& video_codec,
typename T::Content* content) {
// overridden in specialized classes
}
void CopyContent(const typename T::Content& source,
typename T::Content* content) {
// overridden in specialized classes
}
// Creates a MediaContent with one stream.
// kPcmuCodec is used as audio codec and kH264Codec is used as video codec.
typename T::Content* CreateMediaContentWithStream(uint32_t ssrc) {
typename T::Content* content = new typename T::Content();
CreateContent(0, kPcmuCodec, kH264Codec, content);
AddLegacyStreamInContent(ssrc, 0, content);
return content;
}
// Will manage the lifetime of a CallThread, making sure it's
// destroyed before this object goes out of scope.
class ScopedCallThread {
public:
template <class FunctorT>
explicit ScopedCallThread(FunctorT&& functor)
: thread_(rtc::Thread::Create()) {
thread_->Start();
thread_->PostTask(std::forward<FunctorT>(functor));
}
~ScopedCallThread() { thread_->Stop(); }
rtc::Thread* thread() { return thread_.get(); }
private:
std::unique_ptr<rtc::Thread> thread_;
};
bool CodecMatches(const typename T::Codec& c1, const typename T::Codec& c2) {
return false; // overridden in specialized classes
}
cricket::CandidatePairInterface* last_selected_candidate_pair() {
return last_selected_candidate_pair_;
}
void AddLegacyStreamInContent(uint32_t ssrc,
int flags,
typename T::Content* content) {
// Base implementation.
}
// Utility method that calls BaseChannel::srtp_active() on the network thread
// and returns the result. The `srtp_active()` state is maintained on the
// network thread, which callers need to factor in.
bool IsSrtpActive(std::unique_ptr<typename T::Channel>& channel) {
RTC_DCHECK(channel.get());
return network_thread_->Invoke<bool>(
RTC_FROM_HERE, [&] { return channel->srtp_active(); });
}
// Returns true iff the transport is set for a channel and rtcp_mux_enabled()
// returns true.
bool IsRtcpMuxEnabled(std::unique_ptr<typename T::Channel>& channel) {
RTC_DCHECK(channel.get());
return network_thread_->Invoke<bool>(RTC_FROM_HERE, [&] {
return channel->rtp_transport() &&
channel->rtp_transport()->rtcp_mux_enabled();
});
}
// Tests that can be used by derived classes.
// Basic sanity check.
void TestInit() {
CreateChannels(0, 0);
EXPECT_FALSE(IsSrtpActive(channel1_));
EXPECT_FALSE(media_channel1()->sending());
if (verify_playout_) {
EXPECT_FALSE(media_channel1()->playout());
}
EXPECT_TRUE(media_channel1()->codecs().empty());
EXPECT_TRUE(media_channel1()->recv_streams().empty());
EXPECT_TRUE(media_channel1()->rtp_packets().empty());
}
// Test that SetLocalContent and SetRemoteContent properly configure
// the codecs.
void TestSetContents() {
CreateChannels(0, 0);
typename T::Content content;
CreateContent(0, kPcmuCodec, kH264Codec, &content);
std::string err;
EXPECT_TRUE(channel1_->SetLocalContent(&content, SdpType::kOffer, err));
EXPECT_EQ(0U, media_channel1()->codecs().size());
EXPECT_TRUE(channel1_->SetRemoteContent(&content, SdpType::kAnswer, err));
ASSERT_EQ(1U, media_channel1()->codecs().size());
EXPECT_TRUE(
CodecMatches(content.codecs()[0], media_channel1()->codecs()[0]));
}
// Test that SetLocalContent and SetRemoteContent properly configure
// extmap-allow-mixed.
void TestSetContentsExtmapAllowMixedCaller(bool offer, bool answer) {
// For a caller, SetLocalContent() is called first with an offer and next
// SetRemoteContent() is called with the answer.
CreateChannels(0, 0);
typename T::Content content;
CreateContent(0, kPcmuCodec, kH264Codec, &content);
auto offer_enum = offer ? (T::Content::kSession) : (T::Content::kNo);
auto answer_enum = answer ? (T::Content::kSession) : (T::Content::kNo);
content.set_extmap_allow_mixed_enum(offer_enum);
std::string err;
EXPECT_TRUE(channel1_->SetLocalContent(&content, SdpType::kOffer, err));
content.set_extmap_allow_mixed_enum(answer_enum);
EXPECT_TRUE(channel1_->SetRemoteContent(&content, SdpType::kAnswer, err));
EXPECT_EQ(answer, media_channel1()->ExtmapAllowMixed());
}
void TestSetContentsExtmapAllowMixedCallee(bool offer, bool answer) {
// For a callee, SetRemoteContent() is called first with an offer and next
// SetLocalContent() is called with the answer.
CreateChannels(0, 0);
typename T::Content content;
CreateContent(0, kPcmuCodec, kH264Codec, &content);
auto offer_enum = offer ? (T::Content::kSession) : (T::Content::kNo);
auto answer_enum = answer ? (T::Content::kSession) : (T::Content::kNo);
content.set_extmap_allow_mixed_enum(offer_enum);
std::string err;
EXPECT_TRUE(channel1_->SetRemoteContent(&content, SdpType::kOffer, err));
content.set_extmap_allow_mixed_enum(answer_enum);
EXPECT_TRUE(channel1_->SetLocalContent(&content, SdpType::kAnswer, err));
EXPECT_EQ(answer, media_channel1()->ExtmapAllowMixed());
}
// Test that SetLocalContent and SetRemoteContent properly deals
// with an empty offer.
void TestSetContentsNullOffer() {
CreateChannels(0, 0);
typename T::Content content;
std::string err;
EXPECT_TRUE(channel1_->SetLocalContent(&content, SdpType::kOffer, err));
CreateContent(0, kPcmuCodec, kH264Codec, &content);
EXPECT_EQ(0U, media_channel1()->codecs().size());
EXPECT_TRUE(channel1_->SetRemoteContent(&content, SdpType::kAnswer, err));
ASSERT_EQ(1U, media_channel1()->codecs().size());
EXPECT_TRUE(
CodecMatches(content.codecs()[0], media_channel1()->codecs()[0]));
}
// Test that SetLocalContent and SetRemoteContent properly set RTCP
// mux.
void TestSetContentsRtcpMux() {
CreateChannels(0, 0);
typename T::Content content;
CreateContent(0, kPcmuCodec, kH264Codec, &content);
// Both sides agree on mux. Should no longer be a separate RTCP channel.
content.set_rtcp_mux(true);
std::string err;
EXPECT_TRUE(channel1_->SetLocalContent(&content, SdpType::kOffer, err));
EXPECT_TRUE(channel1_->SetRemoteContent(&content, SdpType::kAnswer, err));
// Only initiator supports mux. Should still have a separate RTCP channel.
EXPECT_TRUE(channel2_->SetLocalContent(&content, SdpType::kOffer, err));
content.set_rtcp_mux(false);
EXPECT_TRUE(channel2_->SetRemoteContent(&content, SdpType::kAnswer, err));
}
// Test that SetLocalContent and SetRemoteContent properly
// handles adding and removing StreamParams when the action is a full
// SdpType::kOffer / SdpType::kAnswer.
void TestChangeStreamParamsInContent() {
cricket::StreamParams stream1;
stream1.id = "stream1";
stream1.ssrcs.push_back(kSsrc1);
stream1.cname = "stream1_cname";
cricket::StreamParams stream2;
stream2.id = "stream2";
stream2.ssrcs.push_back(kSsrc2);
stream2.cname = "stream2_cname";
// Setup a call where channel 1 send `stream1` to channel 2.
CreateChannels(0, 0);
typename T::Content content1;
CreateContent(0, kPcmuCodec, kH264Codec, &content1);
content1.AddStream(stream1);
std::string err;
EXPECT_TRUE(channel1_->SetLocalContent(&content1, SdpType::kOffer, err));
channel1_->Enable(true);
EXPECT_EQ(1u, media_channel1()->send_streams().size());
EXPECT_TRUE(channel2_->SetRemoteContent(&content1, SdpType::kOffer, err));
EXPECT_EQ(1u, media_channel2()->recv_streams().size());
ConnectFakeTransports();
// Channel 2 do not send anything.
typename T::Content content2;
CreateContent(0, kPcmuCodec, kH264Codec, &content2);
EXPECT_TRUE(channel1_->SetRemoteContent(&content2, SdpType::kAnswer, err));
EXPECT_EQ(0u, media_channel1()->recv_streams().size());
EXPECT_TRUE(channel2_->SetLocalContent(&content2, SdpType::kAnswer, err));
channel2_->Enable(true);
EXPECT_EQ(0u, media_channel2()->send_streams().size());
SendCustomRtp1(kSsrc1, 0);
WaitForThreads();
EXPECT_TRUE(CheckCustomRtp2(kSsrc1, 0));
// Let channel 2 update the content by sending `stream2` and enable SRTP.
typename T::Content content3;
CreateContent(0, kPcmuCodec, kH264Codec, &content3);
content3.AddStream(stream2);
EXPECT_TRUE(channel2_->SetLocalContent(&content3, SdpType::kOffer, err));
ASSERT_EQ(1u, media_channel2()->send_streams().size());
EXPECT_EQ(stream2, media_channel2()->send_streams()[0]);
EXPECT_TRUE(channel1_->SetRemoteContent(&content3, SdpType::kOffer, err));
ASSERT_EQ(1u, media_channel1()->recv_streams().size());
EXPECT_EQ(stream2, media_channel1()->recv_streams()[0]);
// Channel 1 replies but stop sending stream1.
typename T::Content content4;
CreateContent(0, kPcmuCodec, kH264Codec, &content4);
EXPECT_TRUE(channel1_->SetLocalContent(&content4, SdpType::kAnswer, err));
EXPECT_EQ(0u, media_channel1()->send_streams().size());
EXPECT_TRUE(channel2_->SetRemoteContent(&content4, SdpType::kAnswer, err));
EXPECT_EQ(0u, media_channel2()->recv_streams().size());
SendCustomRtp2(kSsrc2, 0);
WaitForThreads();
EXPECT_TRUE(CheckCustomRtp1(kSsrc2, 0));
}
// Test that we only start playout and sending at the right times.
void TestPlayoutAndSendingStates() {
CreateChannels(0, 0);
if (verify_playout_) {
EXPECT_FALSE(media_channel1()->playout());
}
EXPECT_FALSE(media_channel1()->sending());
if (verify_playout_) {
EXPECT_FALSE(media_channel2()->playout());
}
EXPECT_FALSE(media_channel2()->sending());
channel1_->Enable(true);
FlushCurrentThread();
if (verify_playout_) {
EXPECT_FALSE(media_channel1()->playout());
}
EXPECT_FALSE(media_channel1()->sending());
std::string err;
EXPECT_TRUE(channel1_->SetLocalContent(&local_media_content1_,
SdpType::kOffer, err));
if (verify_playout_) {
EXPECT_TRUE(media_channel1()->playout());
}
EXPECT_FALSE(media_channel1()->sending());
EXPECT_TRUE(channel2_->SetRemoteContent(&local_media_content1_,
SdpType::kOffer, err));
if (verify_playout_) {
EXPECT_FALSE(media_channel2()->playout());
}
EXPECT_FALSE(media_channel2()->sending());
EXPECT_TRUE(channel2_->SetLocalContent(&local_media_content2_,
SdpType::kAnswer, err));
if (verify_playout_) {
EXPECT_FALSE(media_channel2()->playout());
}
EXPECT_FALSE(media_channel2()->sending());
ConnectFakeTransports();
if (verify_playout_) {
EXPECT_TRUE(media_channel1()->playout());
}
EXPECT_FALSE(media_channel1()->sending());
if (verify_playout_) {
EXPECT_FALSE(media_channel2()->playout());
}
EXPECT_FALSE(media_channel2()->sending());
channel2_->Enable(true);
FlushCurrentThread();
if (verify_playout_) {
EXPECT_TRUE(media_channel2()->playout());
}
EXPECT_TRUE(media_channel2()->sending());
EXPECT_TRUE(channel1_->SetRemoteContent(&local_media_content2_,
SdpType::kAnswer, err));
if (verify_playout_) {
EXPECT_TRUE(media_channel1()->playout());
}
EXPECT_TRUE(media_channel1()->sending());
}
// Test that changing the MediaContentDirection in the local and remote
// session description start playout and sending at the right time.
void TestMediaContentDirection() {
CreateChannels(0, 0);
typename T::Content content1;
CreateContent(0, kPcmuCodec, kH264Codec, &content1);
typename T::Content content2;
CreateContent(0, kPcmuCodec, kH264Codec, &content2);
// Set `content2` to be InActive.
content2.set_direction(RtpTransceiverDirection::kInactive);
channel1_->Enable(true);
channel2_->Enable(true);
FlushCurrentThread();
if (verify_playout_) {
EXPECT_FALSE(media_channel1()->playout());
}
EXPECT_FALSE(media_channel1()->sending());
if (verify_playout_) {
EXPECT_FALSE(media_channel2()->playout());
}
EXPECT_FALSE(media_channel2()->sending());
std::string err;
EXPECT_TRUE(channel1_->SetLocalContent(&content1, SdpType::kOffer, err));
EXPECT_TRUE(channel2_->SetRemoteContent(&content1, SdpType::kOffer, err));
EXPECT_TRUE(channel2_->SetLocalContent(&content2, SdpType::kPrAnswer, err));
EXPECT_TRUE(
channel1_->SetRemoteContent(&content2, SdpType::kPrAnswer, err));
ConnectFakeTransports();
if (verify_playout_) {
EXPECT_TRUE(media_channel1()->playout());
}
EXPECT_FALSE(media_channel1()->sending()); // remote InActive
if (verify_playout_) {
EXPECT_FALSE(media_channel2()->playout()); // local InActive
}
EXPECT_FALSE(media_channel2()->sending()); // local InActive
// Update `content2` to be RecvOnly.
content2.set_direction(RtpTransceiverDirection::kRecvOnly);
EXPECT_TRUE(channel2_->SetLocalContent(&content2, SdpType::kPrAnswer, err));
EXPECT_TRUE(
channel1_->SetRemoteContent(&content2, SdpType::kPrAnswer, err));
if (verify_playout_) {
EXPECT_TRUE(media_channel1()->playout());
}
EXPECT_TRUE(media_channel1()->sending());
if (verify_playout_) {
EXPECT_TRUE(media_channel2()->playout()); // local RecvOnly
}
EXPECT_FALSE(media_channel2()->sending()); // local RecvOnly
// Update `content2` to be SendRecv.
content2.set_direction(RtpTransceiverDirection::kSendRecv);
EXPECT_TRUE(channel2_->SetLocalContent(&content2, SdpType::kAnswer, err));
EXPECT_TRUE(channel1_->SetRemoteContent(&content2, SdpType::kAnswer, err));
if (verify_playout_) {
EXPECT_TRUE(media_channel1()->playout());
}
EXPECT_TRUE(media_channel1()->sending());
if (verify_playout_) {
EXPECT_TRUE(media_channel2()->playout());
}
EXPECT_TRUE(media_channel2()->sending());
}
// Tests that when the transport channel signals a candidate pair change
// event, the media channel will receive a call on the network route change.
void TestNetworkRouteChanges() {
static constexpr uint16_t kLocalNetId = 1;
static constexpr uint16_t kRemoteNetId = 2;
static constexpr int kLastPacketId = 100;
// Ipv4(20) + UDP(8).
static constexpr int kTransportOverheadPerPacket = 28;
static constexpr int kSrtpOverheadPerPacket = 10;
CreateChannels(DTLS, DTLS);
SendInitiate();
typename T::MediaChannel* media_channel1 =
static_cast<typename T::MediaChannel*>(channel1_->media_channel());
ASSERT_TRUE(media_channel1);
// Need to wait for the threads before calling
// `set_num_network_route_changes` because the network route would be set
// when creating the channel.
WaitForThreads();
media_channel1->set_num_network_route_changes(0);
network_thread_->Invoke<void>(RTC_FROM_HERE, [this] {
rtc::NetworkRoute network_route;
// The transport channel becomes disconnected.
fake_rtp_dtls_transport1_->ice_transport()->SignalNetworkRouteChanged(
absl::optional<rtc::NetworkRoute>(network_route));
});
WaitForThreads();
EXPECT_EQ(1, media_channel1->num_network_route_changes());
EXPECT_FALSE(media_channel1->last_network_route().connected);
media_channel1->set_num_network_route_changes(0);
network_thread_->Invoke<void>(RTC_FROM_HERE, [this] {
rtc::NetworkRoute network_route;
network_route.connected = true;
network_route.local =
rtc::RouteEndpoint::CreateWithNetworkId(kLocalNetId);
network_route.remote =
rtc::RouteEndpoint::CreateWithNetworkId(kRemoteNetId);
network_route.last_sent_packet_id = kLastPacketId;
network_route.packet_overhead = kTransportOverheadPerPacket;
// The transport channel becomes connected.
fake_rtp_dtls_transport1_->ice_transport()->SignalNetworkRouteChanged(
absl::optional<rtc::NetworkRoute>(network_route));
});
WaitForThreads();
EXPECT_EQ(1, media_channel1->num_network_route_changes());
EXPECT_TRUE(media_channel1->last_network_route().connected);
EXPECT_EQ(kLocalNetId,
media_channel1->last_network_route().local.network_id());
EXPECT_EQ(kRemoteNetId,
media_channel1->last_network_route().remote.network_id());
EXPECT_EQ(kLastPacketId,
media_channel1->last_network_route().last_sent_packet_id);
EXPECT_EQ(kTransportOverheadPerPacket + kSrtpOverheadPerPacket,
media_channel1->transport_overhead_per_packet());
}
// Test setting up a call.
void TestCallSetup() {
CreateChannels(0, 0);
EXPECT_FALSE(IsSrtpActive(channel1_));
EXPECT_TRUE(SendInitiate());
if (verify_playout_) {
EXPECT_TRUE(media_channel1()->playout());
}
EXPECT_FALSE(media_channel1()->sending());
EXPECT_TRUE(SendAccept());
EXPECT_FALSE(IsSrtpActive(channel1_));
EXPECT_TRUE(media_channel1()->sending());
EXPECT_EQ(1U, media_channel1()->codecs().size());
if (verify_playout_) {
EXPECT_TRUE(media_channel2()->playout());
}
EXPECT_TRUE(media_channel2()->sending());
EXPECT_EQ(1U, media_channel2()->codecs().size());
}
// Send voice RTP data to the other side and ensure it gets there.
void SendRtpToRtp() {
CreateChannels(RTCP_MUX, RTCP_MUX);
EXPECT_TRUE(SendInitiate());
EXPECT_TRUE(SendAccept());
EXPECT_TRUE(IsRtcpMuxEnabled(channel1_));
EXPECT_TRUE(IsRtcpMuxEnabled(channel2_));
SendRtp1();
SendRtp2();
WaitForThreads();
EXPECT_TRUE(CheckRtp1());
EXPECT_TRUE(CheckRtp2());
EXPECT_TRUE(CheckNoRtp1());
EXPECT_TRUE(CheckNoRtp2());
}
void TestDeinit() {
CreateChannels(0, 0);
EXPECT_TRUE(SendInitiate());
EXPECT_TRUE(SendAccept());
SendRtp1();
SendRtp2();
DeinitChannels();
// Do not wait, destroy channels.
channel1_.reset(nullptr);
channel2_.reset(nullptr);
}
void SendDtlsSrtpToDtlsSrtp(int flags1, int flags2) {
CreateChannels(flags1 | DTLS, flags2 | DTLS);
EXPECT_FALSE(IsSrtpActive(channel1_));
EXPECT_FALSE(IsSrtpActive(channel2_));
EXPECT_TRUE(SendInitiate());
WaitForThreads();
EXPECT_TRUE(SendAccept());
EXPECT_TRUE(IsSrtpActive(channel1_));
EXPECT_TRUE(IsSrtpActive(channel2_));
SendRtp1();
SendRtp2();
WaitForThreads();
EXPECT_TRUE(CheckRtp1());
EXPECT_TRUE(CheckRtp2());
EXPECT_TRUE(CheckNoRtp1());
EXPECT_TRUE(CheckNoRtp2());
}
// Test that we can send and receive early media when a provisional answer is
// sent and received. The test uses SRTP, RTCP mux and SSRC mux.
void SendEarlyMediaUsingRtcpMuxSrtp() {
int sequence_number1_1 = 0, sequence_number2_2 = 0;
CreateChannels(SSRC_MUX | RTCP_MUX | DTLS, SSRC_MUX | RTCP_MUX | DTLS);
EXPECT_TRUE(SendOffer());
EXPECT_TRUE(SendProvisionalAnswer());
EXPECT_TRUE(IsSrtpActive(channel1_));
EXPECT_TRUE(IsSrtpActive(channel2_));
EXPECT_TRUE(IsRtcpMuxEnabled(channel1_));
EXPECT_TRUE(IsRtcpMuxEnabled(channel2_));
WaitForThreads(); // Wait for 'sending' flag go through network thread.
SendCustomRtp1(kSsrc1, ++sequence_number1_1);
WaitForThreads();
EXPECT_TRUE(CheckCustomRtp2(kSsrc1, sequence_number1_1));
// Send packets from callee and verify that it is received.
SendCustomRtp2(kSsrc2, ++sequence_number2_2);
WaitForThreads();
EXPECT_TRUE(CheckCustomRtp1(kSsrc2, sequence_number2_2));
// Complete call setup and ensure everything is still OK.
EXPECT_TRUE(SendFinalAnswer());
EXPECT_TRUE(IsSrtpActive(channel1_));
EXPECT_TRUE(IsSrtpActive(channel2_));
SendCustomRtp1(kSsrc1, ++sequence_number1_1);
SendCustomRtp2(kSsrc2, ++sequence_number2_2);
WaitForThreads();
EXPECT_TRUE(CheckCustomRtp2(kSsrc1, sequence_number1_1));
EXPECT_TRUE(CheckCustomRtp1(kSsrc2, sequence_number2_2));
}
// Test that we properly send RTP without SRTP from a thread.
void SendRtpToRtpOnThread() {
CreateChannels(0, 0);
EXPECT_TRUE(SendInitiate());
EXPECT_TRUE(SendAccept());
ScopedCallThread send_rtp1([this] { SendRtp1(); });
ScopedCallThread send_rtp2([this] { SendRtp2(); });
rtc::Thread* involved_threads[] = {send_rtp1.thread(), send_rtp2.thread()};
WaitForThreads(involved_threads);
EXPECT_TRUE(CheckRtp1());
EXPECT_TRUE(CheckRtp2());
EXPECT_TRUE(CheckNoRtp1());
EXPECT_TRUE(CheckNoRtp2());
}
// Test that the mediachannel retains its sending state after the transport
// becomes non-writable.
void SendWithWritabilityLoss() {
CreateChannels(RTCP_MUX, RTCP_MUX);
EXPECT_TRUE(SendInitiate());
EXPECT_TRUE(SendAccept());
EXPECT_TRUE(IsRtcpMuxEnabled(channel1_));
EXPECT_TRUE(IsRtcpMuxEnabled(channel2_));
SendRtp1();
SendRtp2();
WaitForThreads();
EXPECT_TRUE(CheckRtp1());
EXPECT_TRUE(CheckRtp2());
EXPECT_TRUE(CheckNoRtp1());
EXPECT_TRUE(CheckNoRtp2());
// Lose writability, which should fail.
network_thread_->Invoke<void>(RTC_FROM_HERE, [this] {
fake_rtp_dtls_transport1_->SetWritable(false);
});
SendRtp1();
SendRtp2();
WaitForThreads();
EXPECT_TRUE(CheckRtp1());
EXPECT_TRUE(CheckNoRtp2());
// Regain writability
network_thread_->Invoke<void>(RTC_FROM_HERE, [this] {
fake_rtp_dtls_transport1_->SetWritable(true);
});
EXPECT_TRUE(media_channel1()->sending());
SendRtp1();
SendRtp2();
WaitForThreads();
EXPECT_TRUE(CheckRtp1());
EXPECT_TRUE(CheckRtp2());
EXPECT_TRUE(CheckNoRtp1());
EXPECT_TRUE(CheckNoRtp2());
// Lose writability completely
network_thread_->Invoke<void>(RTC_FROM_HERE, [this] {
bool asymmetric = true;
fake_rtp_dtls_transport1_->SetDestination(nullptr, asymmetric);
});
EXPECT_TRUE(media_channel1()->sending());
// Should fail also.
SendRtp1();
SendRtp2();
WaitForThreads();
EXPECT_TRUE(CheckRtp1());
EXPECT_TRUE(CheckNoRtp2());
EXPECT_TRUE(CheckNoRtp1());
// Gain writability back
network_thread_->Invoke<void>(RTC_FROM_HERE, [this] {
bool asymmetric = true;
fake_rtp_dtls_transport1_->SetDestination(fake_rtp_dtls_transport2_.get(),
asymmetric);
});
EXPECT_TRUE(media_channel1()->sending());
SendRtp1();
SendRtp2();
WaitForThreads();
EXPECT_TRUE(CheckRtp1());
EXPECT_TRUE(CheckRtp2());
EXPECT_TRUE(CheckNoRtp1());
EXPECT_TRUE(CheckNoRtp2());
}
void SendBundleToBundle(const int* pl_types,
int len,
bool rtcp_mux,
bool secure) {
ASSERT_EQ(2, len);
int sequence_number1_1 = 0, sequence_number2_2 = 0;
// Only pl_type1 was added to the bundle filter for both `channel1_`
// and `channel2_`.
int pl_type1 = pl_types[0];
int pl_type2 = pl_types[1];
int flags = SSRC_MUX;
if (secure)
flags |= DTLS;
if (rtcp_mux) {
flags |= RTCP_MUX;
}
CreateChannels(flags, flags);
EXPECT_TRUE(SendInitiate());
EXPECT_TRUE(SendAccept());
// Both channels can receive pl_type1 only.
SendCustomRtp1(kSsrc1, ++sequence_number1_1, pl_type1);
SendCustomRtp2(kSsrc2, ++sequence_number2_2, pl_type1);
WaitForThreads();
EXPECT_TRUE(CheckCustomRtp2(kSsrc1, sequence_number1_1, pl_type1));
EXPECT_TRUE(CheckCustomRtp1(kSsrc2, sequence_number2_2, pl_type1));
EXPECT_TRUE(CheckNoRtp1());
EXPECT_TRUE(CheckNoRtp2());
SendCustomRtp1(kSsrc3, ++sequence_number1_1, pl_type2);
SendCustomRtp2(kSsrc4, ++sequence_number2_2, pl_type2);
WaitForThreads();
EXPECT_FALSE(CheckCustomRtp2(kSsrc3, sequence_number1_1, pl_type2));
EXPECT_FALSE(CheckCustomRtp1(kSsrc4, sequence_number2_2, pl_type2));
}
void TestSetContentFailure() {
CreateChannels(0, 0);
std::string err;
std::unique_ptr<typename T::Content> content(
CreateMediaContentWithStream(1));
media_channel1()->set_fail_set_recv_codecs(true);
EXPECT_FALSE(
channel1_->SetLocalContent(content.get(), SdpType::kOffer, err));
EXPECT_FALSE(
channel1_->SetLocalContent(content.get(), SdpType::kAnswer, err));
media_channel1()->set_fail_set_send_codecs(true);
EXPECT_FALSE(
channel1_->SetRemoteContent(content.get(), SdpType::kOffer, err));
media_channel1()->set_fail_set_send_codecs(true);
EXPECT_FALSE(
channel1_->SetRemoteContent(content.get(), SdpType::kAnswer, err));
}
void TestSendTwoOffers() {
CreateChannels(0, 0);
std::string err;
std::unique_ptr<typename T::Content> content1(
CreateMediaContentWithStream(1));
EXPECT_TRUE(
channel1_->SetLocalContent(content1.get(), SdpType::kOffer, err));
EXPECT_TRUE(media_channel1()->HasSendStream(1));
std::unique_ptr<typename T::Content> content2(
CreateMediaContentWithStream(2));
EXPECT_TRUE(
channel1_->SetLocalContent(content2.get(), SdpType::kOffer, err));
EXPECT_FALSE(media_channel1()->HasSendStream(1));
EXPECT_TRUE(media_channel1()->HasSendStream(2));
}
void TestReceiveTwoOffers() {
CreateChannels(0, 0);
std::string err;
std::unique_ptr<typename T::Content> content1(
CreateMediaContentWithStream(1));
EXPECT_TRUE(
channel1_->SetRemoteContent(content1.get(), SdpType::kOffer, err));
EXPECT_TRUE(media_channel1()->HasRecvStream(1));
std::unique_ptr<typename T::Content> content2(
CreateMediaContentWithStream(2));
EXPECT_TRUE(
channel1_->SetRemoteContent(content2.get(), SdpType::kOffer, err));
EXPECT_FALSE(media_channel1()->HasRecvStream(1));
EXPECT_TRUE(media_channel1()->HasRecvStream(2));
}
void TestSendPrAnswer() {
CreateChannels(0, 0);
std::string err;
// Receive offer
std::unique_ptr<typename T::Content> content1(
CreateMediaContentWithStream(1));
EXPECT_TRUE(
channel1_->SetRemoteContent(content1.get(), SdpType::kOffer, err));
EXPECT_TRUE(media_channel1()->HasRecvStream(1));
// Send PR answer
std::unique_ptr<typename T::Content> content2(
CreateMediaContentWithStream(2));
EXPECT_TRUE(
channel1_->SetLocalContent(content2.get(), SdpType::kPrAnswer, err));
EXPECT_TRUE(media_channel1()->HasRecvStream(1));
EXPECT_TRUE(media_channel1()->HasSendStream(2));
// Send answer
std::unique_ptr<typename T::Content> content3(
CreateMediaContentWithStream(3));
EXPECT_TRUE(
channel1_->SetLocalContent(content3.get(), SdpType::kAnswer, err));
EXPECT_TRUE(media_channel1()->HasRecvStream(1));
EXPECT_FALSE(media_channel1()->HasSendStream(2));
EXPECT_TRUE(media_channel1()->HasSendStream(3));
}
void TestReceivePrAnswer() {
CreateChannels(0, 0);
std::string err;
// Send offer
std::unique_ptr<typename T::Content> content1(
CreateMediaContentWithStream(1));
EXPECT_TRUE(
channel1_->SetLocalContent(content1.get(), SdpType::kOffer, err));
EXPECT_TRUE(media_channel1()->HasSendStream(1));
// Receive PR answer
std::unique_ptr<typename T::Content> content2(
CreateMediaContentWithStream(2));
EXPECT_TRUE(
channel1_->SetRemoteContent(content2.get(), SdpType::kPrAnswer, err));
EXPECT_TRUE(media_channel1()->HasSendStream(1));
EXPECT_TRUE(media_channel1()->HasRecvStream(2));
// Receive answer
std::unique_ptr<typename T::Content> content3(
CreateMediaContentWithStream(3));
EXPECT_TRUE(
channel1_->SetRemoteContent(content3.get(), SdpType::kAnswer, err));
EXPECT_TRUE(media_channel1()->HasSendStream(1));
EXPECT_FALSE(media_channel1()->HasRecvStream(2));
EXPECT_TRUE(media_channel1()->HasRecvStream(3));
}
void TestOnTransportReadyToSend() {
CreateChannels(0, 0);
EXPECT_FALSE(media_channel1()->ready_to_send());
network_thread_->PostTask(
[this] { channel1_->OnTransportReadyToSend(true); });
WaitForThreads();
EXPECT_TRUE(media_channel1()->ready_to_send());
network_thread_->PostTask(
[this] { channel1_->OnTransportReadyToSend(false); });
WaitForThreads();
EXPECT_FALSE(media_channel1()->ready_to_send());
}
bool SetRemoteContentWithBitrateLimit(int remote_limit) {
typename T::Content content;
CreateContent(0, kPcmuCodec, kH264Codec, &content);
content.set_bandwidth(remote_limit);
return channel1_->SetRemoteContent(&content, SdpType::kOffer, NULL);
}
webrtc::RtpParameters BitrateLimitedParameters(absl::optional<int> limit) {
webrtc::RtpParameters parameters;
webrtc::RtpEncodingParameters encoding;
encoding.max_bitrate_bps = limit;
parameters.encodings.push_back(encoding);
return parameters;
}
void VerifyMaxBitrate(const webrtc::RtpParameters& parameters,
absl::optional<int> expected_bitrate) {
EXPECT_EQ(1UL, parameters.encodings.size());
EXPECT_EQ(expected_bitrate, parameters.encodings[0].max_bitrate_bps);
}
void DefaultMaxBitrateIsUnlimited() {
CreateChannels(0, 0);
std::string err;
EXPECT_TRUE(channel1_->SetLocalContent(&local_media_content1_,
SdpType::kOffer, err));
EXPECT_EQ(media_channel1()->max_bps(), -1);
VerifyMaxBitrate(media_channel1()->GetRtpSendParameters(kSsrc1),
absl::nullopt);
}
// Test that when a channel gets new RtpTransport with a call to
// `SetRtpTransport`, the socket options from the old RtpTransport is merged
// with the options on the new one.
// For example, audio and video may use separate socket options, but initially
// be unbundled, then later become bundled. When this happens, their preferred
// socket options should be merged to the underlying transport they share.
void SocketOptionsMergedOnSetTransport() {
constexpr int kSndBufSize = 4000;
constexpr int kRcvBufSize = 8000;
CreateChannels(DTLS, DTLS);
new_rtp_transport_ = CreateDtlsSrtpTransport(
fake_rtp_dtls_transport2_.get(), fake_rtcp_dtls_transport2_.get());
bool rcv_success, send_success;
int rcv_buf, send_buf;
network_thread_->Invoke<void>(RTC_FROM_HERE, [&] {
channel1_->SetOption(cricket::BaseChannel::ST_RTP,
rtc::Socket::Option::OPT_SNDBUF, kSndBufSize);
channel2_->SetOption(cricket::BaseChannel::ST_RTP,
rtc::Socket::Option::OPT_RCVBUF, kRcvBufSize);
channel1_->SetRtpTransport(new_rtp_transport_.get());
send_success = fake_rtp_dtls_transport2_->GetOption(
rtc::Socket::Option::OPT_SNDBUF, &send_buf);
rcv_success = fake_rtp_dtls_transport2_->GetOption(
rtc::Socket::Option::OPT_RCVBUF, &rcv_buf);
});
ASSERT_TRUE(send_success);
EXPECT_EQ(kSndBufSize, send_buf);
ASSERT_TRUE(rcv_success);
EXPECT_EQ(kRcvBufSize, rcv_buf);
}
void CreateSimulcastContent(const std::vector<std::string>& rids,
typename T::Content* content) {
std::vector<RidDescription> rid_descriptions;
for (const std::string& name : rids) {
rid_descriptions.push_back(RidDescription(name, RidDirection::kSend));
}
StreamParams stream;
stream.set_rids(rid_descriptions);
CreateContent(0, kPcmuCodec, kH264Codec, content);
// This is for unified plan, so there can be only one StreamParams.
content->mutable_streams().clear();
content->AddStream(stream);
}
void VerifySimulcastStreamParams(const StreamParams& expected,
const typename T::Channel* channel) {
const std::vector<StreamParams>& streams = channel->local_streams();
ASSERT_EQ(1u, streams.size());
const StreamParams& result = streams[0];
EXPECT_EQ(expected.rids(), result.rids());
EXPECT_TRUE(result.has_ssrcs());
EXPECT_EQ(expected.rids().size() * 2, result.ssrcs.size());
std::vector<uint32_t> primary_ssrcs;
result.GetPrimarySsrcs(&primary_ssrcs);
EXPECT_EQ(expected.rids().size(), primary_ssrcs.size());
}
void TestUpdateLocalStreamsWithSimulcast() {
CreateChannels(0, 0);
typename T::Content content1, content2, content3;
CreateSimulcastContent({"f", "h", "q"}, &content1);
std::string err;
EXPECT_TRUE(channel1_->SetLocalContent(&content1, SdpType::kOffer, err));
VerifySimulcastStreamParams(content1.streams()[0], channel1_.get());
StreamParams stream1 = channel1_->local_streams()[0];
// Create a similar offer. SetLocalContent should not remove and add.
CreateSimulcastContent({"f", "h", "q"}, &content2);
EXPECT_TRUE(channel1_->SetLocalContent(&content2, SdpType::kOffer, err));
VerifySimulcastStreamParams(content2.streams()[0], channel1_.get());
StreamParams stream2 = channel1_->local_streams()[0];
// Check that the streams are identical (SSRCs didn't change).
EXPECT_EQ(stream1, stream2);
// Create third offer that has same RIDs in different order.
CreateSimulcastContent({"f", "q", "h"}, &content3);
EXPECT_TRUE(channel1_->SetLocalContent(&content3, SdpType::kOffer, err));
VerifySimulcastStreamParams(content3.streams()[0], channel1_.get());
}
protected:
void WaitForThreads() { WaitForThreads(rtc::ArrayView<rtc::Thread*>()); }
static void ProcessThreadQueue(rtc::Thread* thread) {
RTC_DCHECK(thread->IsCurrent());
while (!thread->empty()) {
thread->ProcessMessages(0);
}
}
static void FlushCurrentThread() {
rtc::Thread::Current()->ProcessMessages(0);
}
void WaitForThreads(rtc::ArrayView<rtc::Thread*> threads) {
// `threads` and current thread post packets to network thread.
for (rtc::Thread* thread : threads) {
thread->Invoke<void>(RTC_FROM_HERE,
[thread] { ProcessThreadQueue(thread); });
}
ProcessThreadQueue(rtc::Thread::Current());
// Network thread move them around and post back to worker = current thread.
if (!network_thread_->IsCurrent()) {
network_thread_->Invoke<void>(
RTC_FROM_HERE, [this] { ProcessThreadQueue(network_thread_); });
}
// Worker thread = current Thread process received messages.
ProcessThreadQueue(rtc::Thread::Current());
}
typename T::MediaChannel* media_channel1() {
RTC_DCHECK(channel1_);
RTC_DCHECK(channel1_->media_channel());
return static_cast<typename T::MediaChannel*>(channel1_->media_channel());
}
typename T::MediaChannel* media_channel2() {
RTC_DCHECK(channel2_);
RTC_DCHECK(channel2_->media_channel());
return static_cast<typename T::MediaChannel*>(channel2_->media_channel());
}
// TODO(pbos): Remove playout from all media channels and let renderers mute
// themselves.
const bool verify_playout_;
rtc::scoped_refptr<webrtc::PendingTaskSafetyFlag> network_thread_safety_ =
webrtc::PendingTaskSafetyFlag::CreateDetached();
std::unique_ptr<rtc::Thread> network_thread_keeper_;
rtc::Thread* network_thread_;
std::unique_ptr<cricket::FakeDtlsTransport> fake_rtp_dtls_transport1_;
std::unique_ptr<cricket::FakeDtlsTransport> fake_rtcp_dtls_transport1_;
std::unique_ptr<cricket::FakeDtlsTransport> fake_rtp_dtls_transport2_;
std::unique_ptr<cricket::FakeDtlsTransport> fake_rtcp_dtls_transport2_;
std::unique_ptr<rtc::FakePacketTransport> fake_rtp_packet_transport1_;
std::unique_ptr<rtc::FakePacketTransport> fake_rtcp_packet_transport1_;
std::unique_ptr<rtc::FakePacketTransport> fake_rtp_packet_transport2_;
std::unique_ptr<rtc::FakePacketTransport> fake_rtcp_packet_transport2_;
std::unique_ptr<webrtc::RtpTransportInternal> rtp_transport1_;
std::unique_ptr<webrtc::RtpTransportInternal> rtp_transport2_;
std::unique_ptr<webrtc::RtpTransportInternal> new_rtp_transport_;
cricket::FakeMediaEngine media_engine_;
std::unique_ptr<typename T::Channel> channel1_;
std::unique_ptr<typename T::Channel> channel2_;
typename T::Content local_media_content1_;
typename T::Content local_media_content2_;
typename T::Content remote_media_content1_;
typename T::Content remote_media_content2_;
// The RTP and RTCP packets to send in the tests.
rtc::Buffer rtp_packet_;
rtc::Buffer rtcp_packet_;
cricket::CandidatePairInterface* last_selected_candidate_pair_;
rtc::UniqueRandomIdGenerator ssrc_generator_;
webrtc::test::ScopedKeyValueConfig field_trials_;
};
template <>
std::unique_ptr<cricket::VoiceChannel> ChannelTest<VoiceTraits>::CreateChannel(
rtc::Thread* worker_thread,
rtc::Thread* network_thread,
std::unique_ptr<cricket::FakeVoiceMediaChannel> ch,
webrtc::RtpTransportInternal* rtp_transport,
int flags) {
rtc::Thread* signaling_thread = rtc::Thread::Current();
auto channel = std::make_unique<cricket::VoiceChannel>(
worker_thread, network_thread, signaling_thread, std::move(ch),
cricket::CN_AUDIO, (flags & DTLS) != 0, webrtc::CryptoOptions(),
&ssrc_generator_);
network_thread->Invoke<void>(RTC_FROM_HERE, [&]() {
RTC_DCHECK_RUN_ON(channel->network_thread());
channel->SetRtpTransport(rtp_transport);
});
return channel;
}
template <>
void ChannelTest<VoiceTraits>::CreateContent(
int flags,
const cricket::AudioCodec& audio_codec,
const cricket::VideoCodec& video_codec,
cricket::AudioContentDescription* audio) {
audio->AddCodec(audio_codec);
audio->set_rtcp_mux((flags & RTCP_MUX) != 0);
}
template <>
void ChannelTest<VoiceTraits>::CopyContent(
const cricket::AudioContentDescription& source,
cricket::AudioContentDescription* audio) {
*audio = source;
}
template <>
bool ChannelTest<VoiceTraits>::CodecMatches(const cricket::AudioCodec& c1,
const cricket::AudioCodec& c2) {
return c1.name == c2.name && c1.clockrate == c2.clockrate &&
c1.bitrate == c2.bitrate && c1.channels == c2.channels;
}
template <>
void ChannelTest<VoiceTraits>::AddLegacyStreamInContent(
uint32_t ssrc,
int flags,
cricket::AudioContentDescription* audio) {
audio->AddLegacyStream(ssrc);
}
class VoiceChannelSingleThreadTest : public ChannelTest<VoiceTraits> {
public:
typedef ChannelTest<VoiceTraits> Base;
VoiceChannelSingleThreadTest()
: Base(true, kPcmuFrame, kRtcpReport, NetworkIsWorker::Yes) {}
};
class VoiceChannelDoubleThreadTest : public ChannelTest<VoiceTraits> {
public:
typedef ChannelTest<VoiceTraits> Base;
VoiceChannelDoubleThreadTest()
: Base(true, kPcmuFrame, kRtcpReport, NetworkIsWorker::No) {}
};
class VoiceChannelWithEncryptedRtpHeaderExtensionsSingleThreadTest
: public ChannelTest<VoiceTraits> {
public:
typedef ChannelTest<VoiceTraits> Base;
VoiceChannelWithEncryptedRtpHeaderExtensionsSingleThreadTest()
: Base(true,
kPcmuFrameWithExtensions,
kRtcpReport,
NetworkIsWorker::Yes) {}
};
class VoiceChannelWithEncryptedRtpHeaderExtensionsDoubleThreadTest
: public ChannelTest<VoiceTraits> {
public:
typedef ChannelTest<VoiceTraits> Base;
VoiceChannelWithEncryptedRtpHeaderExtensionsDoubleThreadTest()
: Base(true, kPcmuFrameWithExtensions, kRtcpReport, NetworkIsWorker::No) {
}
};
// override to add NULL parameter
template <>
std::unique_ptr<cricket::VideoChannel> ChannelTest<VideoTraits>::CreateChannel(
rtc::Thread* worker_thread,
rtc::Thread* network_thread,
std::unique_ptr<cricket::FakeVideoMediaChannel> ch,
webrtc::RtpTransportInternal* rtp_transport,
int flags) {
rtc::Thread* signaling_thread = rtc::Thread::Current();
auto channel = std::make_unique<cricket::VideoChannel>(
worker_thread, network_thread, signaling_thread, std::move(ch),
cricket::CN_VIDEO, (flags & DTLS) != 0, webrtc::CryptoOptions(),
&ssrc_generator_);
network_thread->Invoke<void>(RTC_FROM_HERE, [&]() {
RTC_DCHECK_RUN_ON(channel->network_thread());
channel->SetRtpTransport(rtp_transport);
});
return channel;
}
template <>
void ChannelTest<VideoTraits>::CreateContent(
int flags,
const cricket::AudioCodec& audio_codec,
const cricket::VideoCodec& video_codec,
cricket::VideoContentDescription* video) {
video->AddCodec(video_codec);
video->set_rtcp_mux((flags & RTCP_MUX) != 0);
}
template <>
void ChannelTest<VideoTraits>::CopyContent(
const cricket::VideoContentDescription& source,
cricket::VideoContentDescription* video) {
*video = source;
}
template <>
bool ChannelTest<VideoTraits>::CodecMatches(const cricket::VideoCodec& c1,
const cricket::VideoCodec& c2) {
return c1.name == c2.name;
}
template <>
void ChannelTest<VideoTraits>::AddLegacyStreamInContent(
uint32_t ssrc,
int flags,
cricket::VideoContentDescription* video) {
video->AddLegacyStream(ssrc);
}
class VideoChannelSingleThreadTest : public ChannelTest<VideoTraits> {
public:
typedef ChannelTest<VideoTraits> Base;
VideoChannelSingleThreadTest()
: Base(false, kH264Packet, kRtcpReport, NetworkIsWorker::Yes) {}
};
class VideoChannelDoubleThreadTest : public ChannelTest<VideoTraits> {
public:
typedef ChannelTest<VideoTraits> Base;
VideoChannelDoubleThreadTest()
: Base(false, kH264Packet, kRtcpReport, NetworkIsWorker::No) {}
};
TEST_F(VoiceChannelSingleThreadTest, TestInit) {
Base::TestInit();
EXPECT_FALSE(media_channel1()->IsStreamMuted(0));
EXPECT_TRUE(media_channel1()->dtmf_info_queue().empty());
}
TEST_F(VoiceChannelSingleThreadTest, TestDeinit) {
Base::TestDeinit();
}
TEST_F(VoiceChannelSingleThreadTest, TestSetContents) {
Base::TestSetContents();
}
TEST_F(VoiceChannelSingleThreadTest, TestSetContentsExtmapAllowMixedAsCaller) {
Base::TestSetContentsExtmapAllowMixedCaller(/*offer=*/true, /*answer=*/true);
}
TEST_F(VoiceChannelSingleThreadTest,
TestSetContentsExtmapAllowMixedNotSupportedAsCaller) {
Base::TestSetContentsExtmapAllowMixedCaller(/*offer=*/true, /*answer=*/false);
}
TEST_F(VoiceChannelSingleThreadTest, TestSetContentsExtmapAllowMixedAsCallee) {
Base::TestSetContentsExtmapAllowMixedCallee(/*offer=*/true, /*answer=*/true);
}
TEST_F(VoiceChannelSingleThreadTest,
TestSetContentsExtmapAllowMixedNotSupportedAsCallee) {
Base::TestSetContentsExtmapAllowMixedCallee(/*offer=*/true, /*answer=*/false);
}
TEST_F(VoiceChannelSingleThreadTest, TestSetContentsNullOffer) {
Base::TestSetContentsNullOffer();
}
TEST_F(VoiceChannelSingleThreadTest, TestSetContentsRtcpMux) {
Base::TestSetContentsRtcpMux();
}
TEST_F(VoiceChannelSingleThreadTest, TestSetContentsRtcpMuxWithPrAnswer) {
Base::TestSetContentsRtcpMux();
}
TEST_F(VoiceChannelSingleThreadTest, TestChangeStreamParamsInContent) {
Base::TestChangeStreamParamsInContent();
}
TEST_F(VoiceChannelSingleThreadTest, TestPlayoutAndSendingStates) {
Base::TestPlayoutAndSendingStates();
}
TEST_F(VoiceChannelSingleThreadTest, TestMediaContentDirection) {
Base::TestMediaContentDirection();
}
TEST_F(VoiceChannelSingleThreadTest, TestNetworkRouteChanges) {
Base::TestNetworkRouteChanges();
}
TEST_F(VoiceChannelSingleThreadTest, TestCallSetup) {
Base::TestCallSetup();
}
TEST_F(VoiceChannelSingleThreadTest, SendRtpToRtp) {
Base::SendRtpToRtp();
}
TEST_F(VoiceChannelSingleThreadTest, SendDtlsSrtpToDtlsSrtp) {
Base::SendDtlsSrtpToDtlsSrtp(0, 0);
}
TEST_F(VoiceChannelSingleThreadTest, SendDtlsSrtpToDtlsSrtpRtcpMux) {
Base::SendDtlsSrtpToDtlsSrtp(RTCP_MUX, RTCP_MUX);
}
TEST_F(VoiceChannelSingleThreadTest, SendEarlyMediaUsingRtcpMuxSrtp) {
Base::SendEarlyMediaUsingRtcpMuxSrtp();
}
TEST_F(VoiceChannelSingleThreadTest, SendRtpToRtpOnThread) {
Base::SendRtpToRtpOnThread();
}
TEST_F(VoiceChannelSingleThreadTest, SendWithWritabilityLoss) {
Base::SendWithWritabilityLoss();
}
TEST_F(VoiceChannelSingleThreadTest, TestSetContentFailure) {
Base::TestSetContentFailure();
}
TEST_F(VoiceChannelSingleThreadTest, TestSendTwoOffers) {
Base::TestSendTwoOffers();
}
TEST_F(VoiceChannelSingleThreadTest, TestReceiveTwoOffers) {
Base::TestReceiveTwoOffers();
}
TEST_F(VoiceChannelSingleThreadTest, TestSendPrAnswer) {
Base::TestSendPrAnswer();
}
TEST_F(VoiceChannelSingleThreadTest, TestReceivePrAnswer) {
Base::TestReceivePrAnswer();
}
TEST_F(VoiceChannelSingleThreadTest, TestOnTransportReadyToSend) {
Base::TestOnTransportReadyToSend();
}
TEST_F(VoiceChannelSingleThreadTest, SendBundleToBundle) {
Base::SendBundleToBundle(kAudioPts, arraysize(kAudioPts), false, false);
}
TEST_F(VoiceChannelSingleThreadTest, SendBundleToBundleSecure) {
Base::SendBundleToBundle(kAudioPts, arraysize(kAudioPts), false, true);
}
TEST_F(VoiceChannelSingleThreadTest, SendBundleToBundleWithRtcpMux) {
Base::SendBundleToBundle(kAudioPts, arraysize(kAudioPts), true, false);
}
TEST_F(VoiceChannelSingleThreadTest, SendBundleToBundleWithRtcpMuxSecure) {
Base::SendBundleToBundle(kAudioPts, arraysize(kAudioPts), true, true);
}
TEST_F(VoiceChannelSingleThreadTest, DefaultMaxBitrateIsUnlimited) {
Base::DefaultMaxBitrateIsUnlimited();
}
TEST_F(VoiceChannelSingleThreadTest, SocketOptionsMergedOnSetTransport) {
Base::SocketOptionsMergedOnSetTransport();
}
// VoiceChannelDoubleThreadTest
TEST_F(VoiceChannelDoubleThreadTest, TestInit) {
Base::TestInit();
EXPECT_FALSE(media_channel1()->IsStreamMuted(0));
EXPECT_TRUE(media_channel1()->dtmf_info_queue().empty());
}
TEST_F(VoiceChannelDoubleThreadTest, TestDeinit) {
Base::TestDeinit();
}
TEST_F(VoiceChannelDoubleThreadTest, TestSetContents) {
Base::TestSetContents();
}
TEST_F(VoiceChannelDoubleThreadTest, TestSetContentsExtmapAllowMixedAsCaller) {
Base::TestSetContentsExtmapAllowMixedCaller(/*offer=*/true, /*answer=*/true);
}
TEST_F(VoiceChannelDoubleThreadTest,
TestSetContentsExtmapAllowMixedNotSupportedAsCaller) {
Base::TestSetContentsExtmapAllowMixedCaller(/*offer=*/true, /*answer=*/false);
}
TEST_F(VoiceChannelDoubleThreadTest, TestSetContentsExtmapAllowMixedAsCallee) {
Base::TestSetContentsExtmapAllowMixedCallee(/*offer=*/true, /*answer=*/true);
}
TEST_F(VoiceChannelDoubleThreadTest,
TestSetContentsExtmapAllowMixedNotSupportedAsCallee) {
Base::TestSetContentsExtmapAllowMixedCallee(/*offer=*/true, /*answer=*/false);
}
TEST_F(VoiceChannelDoubleThreadTest, TestSetContentsNullOffer) {
Base::TestSetContentsNullOffer();
}
TEST_F(VoiceChannelDoubleThreadTest, TestSetContentsRtcpMux) {
Base::TestSetContentsRtcpMux();
}
TEST_F(VoiceChannelDoubleThreadTest, TestSetContentsRtcpMuxWithPrAnswer) {
Base::TestSetContentsRtcpMux();
}
TEST_F(VoiceChannelDoubleThreadTest, TestChangeStreamParamsInContent) {
Base::TestChangeStreamParamsInContent();
}
TEST_F(VoiceChannelDoubleThreadTest, TestPlayoutAndSendingStates) {
Base::TestPlayoutAndSendingStates();
}
TEST_F(VoiceChannelDoubleThreadTest, TestMediaContentDirection) {
Base::TestMediaContentDirection();
}
TEST_F(VoiceChannelDoubleThreadTest, TestNetworkRouteChanges) {
Base::TestNetworkRouteChanges();
}
TEST_F(VoiceChannelDoubleThreadTest, TestCallSetup) {
Base::TestCallSetup();
}
TEST_F(VoiceChannelDoubleThreadTest, SendRtpToRtp) {
Base::SendRtpToRtp();
}
TEST_F(VoiceChannelDoubleThreadTest, SendDtlsSrtpToDtlsSrtp) {
Base::SendDtlsSrtpToDtlsSrtp(0, 0);
}
TEST_F(VoiceChannelDoubleThreadTest, SendDtlsSrtpToDtlsSrtpRtcpMux) {
Base::SendDtlsSrtpToDtlsSrtp(RTCP_MUX, RTCP_MUX);
}
TEST_F(VoiceChannelDoubleThreadTest, SendEarlyMediaUsingRtcpMuxSrtp) {
Base::SendEarlyMediaUsingRtcpMuxSrtp();
}
TEST_F(VoiceChannelDoubleThreadTest, SendRtpToRtpOnThread) {
Base::SendRtpToRtpOnThread();
}
TEST_F(VoiceChannelDoubleThreadTest, SendWithWritabilityLoss) {
Base::SendWithWritabilityLoss();
}
TEST_F(VoiceChannelDoubleThreadTest, TestSetContentFailure) {
Base::TestSetContentFailure();
}
TEST_F(VoiceChannelDoubleThreadTest, TestSendTwoOffers) {
Base::TestSendTwoOffers();
}
TEST_F(VoiceChannelDoubleThreadTest, TestReceiveTwoOffers) {
Base::TestReceiveTwoOffers();
}
TEST_F(VoiceChannelDoubleThreadTest, TestSendPrAnswer) {
Base::TestSendPrAnswer();
}
TEST_F(VoiceChannelDoubleThreadTest, TestReceivePrAnswer) {
Base::TestReceivePrAnswer();
}
TEST_F(VoiceChannelDoubleThreadTest, TestOnTransportReadyToSend) {
Base::TestOnTransportReadyToSend();
}
TEST_F(VoiceChannelDoubleThreadTest, SendBundleToBundle) {
Base::SendBundleToBundle(kAudioPts, arraysize(kAudioPts), false, false);
}
TEST_F(VoiceChannelDoubleThreadTest, SendBundleToBundleSecure) {
Base::SendBundleToBundle(kAudioPts, arraysize(kAudioPts), false, true);
}
TEST_F(VoiceChannelDoubleThreadTest, SendBundleToBundleWithRtcpMux) {
Base::SendBundleToBundle(kAudioPts, arraysize(kAudioPts), true, false);
}
TEST_F(VoiceChannelDoubleThreadTest, SendBundleToBundleWithRtcpMuxSecure) {
Base::SendBundleToBundle(kAudioPts, arraysize(kAudioPts), true, true);
}
TEST_F(VoiceChannelDoubleThreadTest, DefaultMaxBitrateIsUnlimited) {
Base::DefaultMaxBitrateIsUnlimited();
}
TEST_F(VoiceChannelDoubleThreadTest, SocketOptionsMergedOnSetTransport) {
Base::SocketOptionsMergedOnSetTransport();
}
// VideoChannelSingleThreadTest
TEST_F(VideoChannelSingleThreadTest, TestInit) {
Base::TestInit();
}
TEST_F(VideoChannelSingleThreadTest, TestDeinit) {
Base::TestDeinit();
}
TEST_F(VideoChannelSingleThreadTest, TestSetContents) {
Base::TestSetContents();
}
TEST_F(VideoChannelSingleThreadTest, TestSetContentsExtmapAllowMixedAsCaller) {
Base::TestSetContentsExtmapAllowMixedCaller(/*offer=*/true, /*answer=*/true);
}
TEST_F(VideoChannelSingleThreadTest,
TestSetContentsExtmapAllowMixedNotSupportedAsCaller) {
Base::TestSetContentsExtmapAllowMixedCaller(/*offer=*/true, /*answer=*/false);
}
TEST_F(VideoChannelSingleThreadTest, TestSetContentsExtmapAllowMixedAsCallee) {
Base::TestSetContentsExtmapAllowMixedCallee(/*offer=*/true, /*answer=*/true);
}
TEST_F(VideoChannelSingleThreadTest,
TestSetContentsExtmapAllowMixedNotSupportedAsCallee) {
Base::TestSetContentsExtmapAllowMixedCallee(/*offer=*/true, /*answer=*/false);
}
TEST_F(VideoChannelSingleThreadTest, TestSetContentsNullOffer) {
Base::TestSetContentsNullOffer();
}
TEST_F(VideoChannelSingleThreadTest, TestSetContentsRtcpMux) {
Base::TestSetContentsRtcpMux();
}
TEST_F(VideoChannelSingleThreadTest, TestSetContentsRtcpMuxWithPrAnswer) {
Base::TestSetContentsRtcpMux();
}
TEST_F(VideoChannelSingleThreadTest, TestChangeStreamParamsInContent) {
Base::TestChangeStreamParamsInContent();
}
TEST_F(VideoChannelSingleThreadTest, TestPlayoutAndSendingStates) {
Base::TestPlayoutAndSendingStates();
}
TEST_F(VideoChannelSingleThreadTest, TestMediaContentDirection) {
Base::TestMediaContentDirection();
}
TEST_F(VideoChannelSingleThreadTest, TestNetworkRouteChanges) {
Base::TestNetworkRouteChanges();
}
TEST_F(VideoChannelSingleThreadTest, TestCallSetup) {
Base::TestCallSetup();
}
TEST_F(VideoChannelSingleThreadTest, SendRtpToRtp) {
Base::SendRtpToRtp();
}
TEST_F(VideoChannelSingleThreadTest, SendDtlsSrtpToDtlsSrtp) {
Base::SendDtlsSrtpToDtlsSrtp(0, 0);
}
TEST_F(VideoChannelSingleThreadTest, SendDtlsSrtpToDtlsSrtpRtcpMux) {
Base::SendDtlsSrtpToDtlsSrtp(RTCP_MUX, RTCP_MUX);
}
TEST_F(VideoChannelSingleThreadTest, SendEarlyMediaUsingRtcpMuxSrtp) {
Base::SendEarlyMediaUsingRtcpMuxSrtp();
}
TEST_F(VideoChannelSingleThreadTest, SendRtpToRtpOnThread) {
Base::SendRtpToRtpOnThread();
}
TEST_F(VideoChannelSingleThreadTest, SendWithWritabilityLoss) {
Base::SendWithWritabilityLoss();
}
TEST_F(VideoChannelSingleThreadTest, TestSetContentFailure) {
Base::TestSetContentFailure();
}
TEST_F(VideoChannelSingleThreadTest, TestSendTwoOffers) {
Base::TestSendTwoOffers();
}
TEST_F(VideoChannelSingleThreadTest, TestReceiveTwoOffers) {
Base::TestReceiveTwoOffers();
}
TEST_F(VideoChannelSingleThreadTest, TestSendPrAnswer) {
Base::TestSendPrAnswer();
}
TEST_F(VideoChannelSingleThreadTest, TestReceivePrAnswer) {
Base::TestReceivePrAnswer();
}
TEST_F(VideoChannelSingleThreadTest, SendBundleToBundle) {
Base::SendBundleToBundle(kVideoPts, arraysize(kVideoPts), false, false);
}
TEST_F(VideoChannelSingleThreadTest, SendBundleToBundleSecure) {
Base::SendBundleToBundle(kVideoPts, arraysize(kVideoPts), false, true);
}
TEST_F(VideoChannelSingleThreadTest, SendBundleToBundleWithRtcpMux) {
Base::SendBundleToBundle(kVideoPts, arraysize(kVideoPts), true, false);
}
TEST_F(VideoChannelSingleThreadTest, SendBundleToBundleWithRtcpMuxSecure) {
Base::SendBundleToBundle(kVideoPts, arraysize(kVideoPts), true, true);
}
TEST_F(VideoChannelSingleThreadTest, TestOnTransportReadyToSend) {
Base::TestOnTransportReadyToSend();
}
TEST_F(VideoChannelSingleThreadTest, DefaultMaxBitrateIsUnlimited) {
Base::DefaultMaxBitrateIsUnlimited();
}
TEST_F(VideoChannelSingleThreadTest, SocketOptionsMergedOnSetTransport) {
Base::SocketOptionsMergedOnSetTransport();
}
TEST_F(VideoChannelSingleThreadTest, UpdateLocalStreamsWithSimulcast) {
Base::TestUpdateLocalStreamsWithSimulcast();
}
TEST_F(VideoChannelSingleThreadTest, TestSetLocalOfferWithPacketization) {
const cricket::VideoCodec kVp8Codec(97, "VP8");
cricket::VideoCodec vp9_codec(98, "VP9");
vp9_codec.packetization = cricket::kPacketizationParamRaw;
cricket::VideoContentDescription video;
video.set_codecs({kVp8Codec, vp9_codec});
CreateChannels(0, 0);
std::string err;
EXPECT_TRUE(channel1_->SetLocalContent(&video, SdpType::kOffer, err));
EXPECT_THAT(media_channel1()->send_codecs(), testing::IsEmpty());
ASSERT_THAT(media_channel1()->recv_codecs(), testing::SizeIs(2));
EXPECT_TRUE(
media_channel1()->recv_codecs()[0].Matches(kVp8Codec, &field_trials_));
EXPECT_EQ(media_channel1()->recv_codecs()[0].packetization, absl::nullopt);
EXPECT_TRUE(
media_channel1()->recv_codecs()[1].Matches(vp9_codec, &field_trials_));
EXPECT_EQ(media_channel1()->recv_codecs()[1].packetization,
cricket::kPacketizationParamRaw);
}
TEST_F(VideoChannelSingleThreadTest, TestSetRemoteOfferWithPacketization) {
const cricket::VideoCodec kVp8Codec(97, "VP8");
cricket::VideoCodec vp9_codec(98, "VP9");
vp9_codec.packetization = cricket::kPacketizationParamRaw;
cricket::VideoContentDescription video;
video.set_codecs({kVp8Codec, vp9_codec});
CreateChannels(0, 0);
std::string err;
EXPECT_TRUE(channel1_->SetRemoteContent(&video, SdpType::kOffer, err));
EXPECT_TRUE(err.empty());
EXPECT_THAT(media_channel1()->recv_codecs(), testing::IsEmpty());
ASSERT_THAT(media_channel1()->send_codecs(), testing::SizeIs(2));
EXPECT_TRUE(
media_channel1()->send_codecs()[0].Matches(kVp8Codec, &field_trials_));
EXPECT_EQ(media_channel1()->send_codecs()[0].packetization, absl::nullopt);
EXPECT_TRUE(
media_channel1()->send_codecs()[1].Matches(vp9_codec, &field_trials_));
EXPECT_EQ(media_channel1()->send_codecs()[1].packetization,
cricket::kPacketizationParamRaw);
}
TEST_F(VideoChannelSingleThreadTest, TestSetAnswerWithPacketization) {
const cricket::VideoCodec kVp8Codec(97, "VP8");
cricket::VideoCodec vp9_codec(98, "VP9");
vp9_codec.packetization = cricket::kPacketizationParamRaw;
cricket::VideoContentDescription video;
video.set_codecs({kVp8Codec, vp9_codec});
CreateChannels(0, 0);
std::string err;
EXPECT_TRUE(channel1_->SetLocalContent(&video, SdpType::kOffer, err));
EXPECT_TRUE(err.empty());
EXPECT_TRUE(channel1_->SetRemoteContent(&video, SdpType::kAnswer, err));
EXPECT_TRUE(err.empty());
ASSERT_THAT(media_channel1()->recv_codecs(), testing::SizeIs(2));
EXPECT_TRUE(
media_channel1()->recv_codecs()[0].Matches(kVp8Codec, &field_trials_));
EXPECT_EQ(media_channel1()->recv_codecs()[0].packetization, absl::nullopt);
EXPECT_TRUE(
media_channel1()->recv_codecs()[1].Matches(vp9_codec, &field_trials_));
EXPECT_EQ(media_channel1()->recv_codecs()[1].packetization,
cricket::kPacketizationParamRaw);
EXPECT_THAT(media_channel1()->send_codecs(), testing::SizeIs(2));
EXPECT_TRUE(
media_channel1()->send_codecs()[0].Matches(kVp8Codec, &field_trials_));
EXPECT_EQ(media_channel1()->send_codecs()[0].packetization, absl::nullopt);
EXPECT_TRUE(
media_channel1()->send_codecs()[1].Matches(vp9_codec, &field_trials_));
EXPECT_EQ(media_channel1()->send_codecs()[1].packetization,
cricket::kPacketizationParamRaw);
}
TEST_F(VideoChannelSingleThreadTest, TestSetLocalAnswerWithoutPacketization) {
const cricket::VideoCodec kLocalCodec(98, "VP8");
cricket::VideoCodec remote_codec(99, "VP8");
remote_codec.packetization = cricket::kPacketizationParamRaw;
cricket::VideoContentDescription local_video;
local_video.set_codecs({kLocalCodec});
cricket::VideoContentDescription remote_video;
remote_video.set_codecs({remote_codec});
CreateChannels(0, 0);
std::string err;
EXPECT_TRUE(channel1_->SetRemoteContent(&remote_video, SdpType::kOffer, err));
EXPECT_TRUE(channel1_->SetLocalContent(&local_video, SdpType::kAnswer, err));
ASSERT_THAT(media_channel1()->recv_codecs(), testing::SizeIs(1));
EXPECT_EQ(media_channel1()->recv_codecs()[0].packetization, absl::nullopt);
ASSERT_THAT(media_channel1()->send_codecs(), testing::SizeIs(1));
EXPECT_EQ(media_channel1()->send_codecs()[0].packetization, absl::nullopt);
}
TEST_F(VideoChannelSingleThreadTest, TestSetRemoteAnswerWithoutPacketization) {
cricket::VideoCodec local_codec(98, "VP8");
local_codec.packetization = cricket::kPacketizationParamRaw;
const cricket::VideoCodec kRemoteCodec(99, "VP8");
cricket::VideoContentDescription local_video;
local_video.set_codecs({local_codec});
cricket::VideoContentDescription remote_video;
remote_video.set_codecs({kRemoteCodec});
CreateChannels(0, 0);
std::string err;
EXPECT_TRUE(channel1_->SetLocalContent(&local_video, SdpType::kOffer, err));
EXPECT_TRUE(
channel1_->SetRemoteContent(&remote_video, SdpType::kAnswer, err));
ASSERT_THAT(media_channel1()->recv_codecs(), testing::SizeIs(1));
EXPECT_EQ(media_channel1()->recv_codecs()[0].packetization, absl::nullopt);
ASSERT_THAT(media_channel1()->send_codecs(), testing::SizeIs(1));
EXPECT_EQ(media_channel1()->send_codecs()[0].packetization, absl::nullopt);
}
TEST_F(VideoChannelSingleThreadTest,
TestSetRemoteAnswerWithInvalidPacketization) {
cricket::VideoCodec local_codec(98, "VP8");
local_codec.packetization = cricket::kPacketizationParamRaw;
cricket::VideoCodec remote_codec(99, "VP8");
remote_codec.packetization = "unknownpacketizationattributevalue";
cricket::VideoContentDescription local_video;
local_video.set_codecs({local_codec});
cricket::VideoContentDescription remote_video;
remote_video.set_codecs({remote_codec});
CreateChannels(0, 0);
std::string err;
EXPECT_TRUE(channel1_->SetLocalContent(&local_video, SdpType::kOffer, err));
EXPECT_TRUE(err.empty());
EXPECT_FALSE(
channel1_->SetRemoteContent(&remote_video, SdpType::kAnswer, err));
EXPECT_FALSE(err.empty());
ASSERT_THAT(media_channel1()->recv_codecs(), testing::SizeIs(1));
EXPECT_EQ(media_channel1()->recv_codecs()[0].packetization,
cricket::kPacketizationParamRaw);
EXPECT_THAT(media_channel1()->send_codecs(), testing::IsEmpty());
}
TEST_F(VideoChannelSingleThreadTest,
TestSetLocalAnswerWithInvalidPacketization) {
cricket::VideoCodec local_codec(98, "VP8");
local_codec.packetization = cricket::kPacketizationParamRaw;
const cricket::VideoCodec kRemoteCodec(99, "VP8");
cricket::VideoContentDescription local_video;
local_video.set_codecs({local_codec});
cricket::VideoContentDescription remote_video;
remote_video.set_codecs({kRemoteCodec});
CreateChannels(0, 0);
std::string err;
EXPECT_TRUE(channel1_->SetRemoteContent(&remote_video, SdpType::kOffer, err));
EXPECT_TRUE(err.empty());
EXPECT_FALSE(channel1_->SetLocalContent(&local_video, SdpType::kAnswer, err));
EXPECT_FALSE(err.empty());
EXPECT_THAT(media_channel1()->recv_codecs(), testing::IsEmpty());
ASSERT_THAT(media_channel1()->send_codecs(), testing::SizeIs(1));
EXPECT_EQ(media_channel1()->send_codecs()[0].packetization, absl::nullopt);
}
// VideoChannelDoubleThreadTest
TEST_F(VideoChannelDoubleThreadTest, TestInit) {
Base::TestInit();
}
TEST_F(VideoChannelDoubleThreadTest, TestDeinit) {
Base::TestDeinit();
}
TEST_F(VideoChannelDoubleThreadTest, TestSetContents) {
Base::TestSetContents();
}
TEST_F(VideoChannelDoubleThreadTest, TestSetContentsExtmapAllowMixedAsCaller) {
Base::TestSetContentsExtmapAllowMixedCaller(/*offer=*/true, /*answer=*/true);
}
TEST_F(VideoChannelDoubleThreadTest,
TestSetContentsExtmapAllowMixedNotSupportedAsCaller) {
Base::TestSetContentsExtmapAllowMixedCaller(/*offer=*/true, /*answer=*/false);
}
TEST_F(VideoChannelDoubleThreadTest, TestSetContentsExtmapAllowMixedAsCallee) {
Base::TestSetContentsExtmapAllowMixedCallee(/*offer=*/true, /*answer=*/true);
}
TEST_F(VideoChannelDoubleThreadTest,
TestSetContentsExtmapAllowMixedNotSupportedAsCallee) {
Base::TestSetContentsExtmapAllowMixedCallee(/*offer=*/true, /*answer=*/false);
}
TEST_F(VideoChannelDoubleThreadTest, TestSetContentsNullOffer) {
Base::TestSetContentsNullOffer();
}
TEST_F(VideoChannelDoubleThreadTest, TestSetContentsRtcpMux) {
Base::TestSetContentsRtcpMux();
}
TEST_F(VideoChannelDoubleThreadTest, TestSetContentsRtcpMuxWithPrAnswer) {
Base::TestSetContentsRtcpMux();
}
TEST_F(VideoChannelDoubleThreadTest, TestChangeStreamParamsInContent) {
Base::TestChangeStreamParamsInContent();
}
TEST_F(VideoChannelDoubleThreadTest, TestPlayoutAndSendingStates) {
Base::TestPlayoutAndSendingStates();
}
TEST_F(VideoChannelDoubleThreadTest, TestMediaContentDirection) {
Base::TestMediaContentDirection();
}
TEST_F(VideoChannelDoubleThreadTest, TestNetworkRouteChanges) {
Base::TestNetworkRouteChanges();
}
TEST_F(VideoChannelDoubleThreadTest, TestCallSetup) {
Base::TestCallSetup();
}
TEST_F(VideoChannelDoubleThreadTest, SendRtpToRtp) {
Base::SendRtpToRtp();
}
TEST_F(VideoChannelDoubleThreadTest, SendDtlsSrtpToDtlsSrtp) {
Base::SendDtlsSrtpToDtlsSrtp(0, 0);
}
TEST_F(VideoChannelDoubleThreadTest, SendDtlsSrtpToDtlsSrtpRtcpMux) {
Base::SendDtlsSrtpToDtlsSrtp(RTCP_MUX, RTCP_MUX);
}
TEST_F(VideoChannelDoubleThreadTest, SendEarlyMediaUsingRtcpMuxSrtp) {
Base::SendEarlyMediaUsingRtcpMuxSrtp();
}
TEST_F(VideoChannelDoubleThreadTest, SendRtpToRtpOnThread) {
Base::SendRtpToRtpOnThread();
}
TEST_F(VideoChannelDoubleThreadTest, SendWithWritabilityLoss) {
Base::SendWithWritabilityLoss();
}
TEST_F(VideoChannelDoubleThreadTest, TestSetContentFailure) {
Base::TestSetContentFailure();
}
TEST_F(VideoChannelDoubleThreadTest, TestSendTwoOffers) {
Base::TestSendTwoOffers();
}
TEST_F(VideoChannelDoubleThreadTest, TestReceiveTwoOffers) {
Base::TestReceiveTwoOffers();
}
TEST_F(VideoChannelDoubleThreadTest, TestSendPrAnswer) {
Base::TestSendPrAnswer();
}
TEST_F(VideoChannelDoubleThreadTest, TestReceivePrAnswer) {
Base::TestReceivePrAnswer();
}
TEST_F(VideoChannelDoubleThreadTest, SendBundleToBundle) {
Base::SendBundleToBundle(kVideoPts, arraysize(kVideoPts), false, false);
}
TEST_F(VideoChannelDoubleThreadTest, SendBundleToBundleSecure) {
Base::SendBundleToBundle(kVideoPts, arraysize(kVideoPts), false, true);
}
TEST_F(VideoChannelDoubleThreadTest, SendBundleToBundleWithRtcpMux) {
Base::SendBundleToBundle(kVideoPts, arraysize(kVideoPts), true, false);
}
TEST_F(VideoChannelDoubleThreadTest, SendBundleToBundleWithRtcpMuxSecure) {
Base::SendBundleToBundle(kVideoPts, arraysize(kVideoPts), true, true);
}
TEST_F(VideoChannelDoubleThreadTest, TestOnTransportReadyToSend) {
Base::TestOnTransportReadyToSend();
}
TEST_F(VideoChannelDoubleThreadTest, DefaultMaxBitrateIsUnlimited) {
Base::DefaultMaxBitrateIsUnlimited();
}
TEST_F(VideoChannelDoubleThreadTest, SocketOptionsMergedOnSetTransport) {
Base::SocketOptionsMergedOnSetTransport();
}
// TODO(pthatcher): TestSetReceiver?