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/*
* Copyright 2023 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 <algorithm>
#include <cstddef>
#include <cstdint>
#include <memory>
#include <set>
#include <string>
#include <string_view>
#include <vector>
#include "absl/strings/match.h"
#include "absl/strings/string_view.h"
#include "absl/types/optional.h"
#include "api/audio_codecs/builtin_audio_decoder_factory.h"
#include "api/audio_codecs/builtin_audio_encoder_factory.h"
#include "api/audio_options.h"
#include "api/jsep.h"
#include "api/make_ref_counted.h"
#include "api/media_stream_interface.h"
#include "api/media_types.h"
#include "api/rtc_error.h"
#include "api/rtp_parameters.h"
#include "api/rtp_sender_interface.h"
#include "api/rtp_transceiver_direction.h"
#include "api/rtp_transceiver_interface.h"
#include "api/scoped_refptr.h"
#include "api/stats/rtc_stats_report.h"
#include "api/stats/rtcstats_objects.h"
#include "api/units/data_rate.h"
#include "api/units/time_delta.h"
#include "api/video/resolution.h"
#include "pc/sdp_utils.h"
#include "pc/session_description.h"
#include "pc/simulcast_description.h"
#include "pc/test/mock_peer_connection_observers.h"
#include "pc/test/peer_connection_test_wrapper.h"
#include "pc/test/simulcast_layer_util.h"
#include "rtc_base/checks.h"
#include "rtc_base/gunit.h"
#include "rtc_base/logging.h"
#include "rtc_base/physical_socket_server.h"
#include "rtc_base/thread.h"
#include "test/gmock.h"
#include "test/gtest.h"
using ::testing::Eq;
using ::testing::Optional;
using ::testing::SizeIs;
using ::testing::StrCaseEq;
using ::testing::StrEq;
namespace webrtc {
namespace {
constexpr TimeDelta kDefaultTimeout = TimeDelta::Seconds(5);
// Most tests pass in 20-30 seconds, but some tests take longer such as AV1
// requiring additional ramp-up time (https://crbug.com/webrtc/15006) or SVC
// (LxTx_KEY) being slower than simulcast to send top spatial layer.
// TODO(https://crbug.com/webrtc/15076): Remove need for long rampup timeouts by
// using simulated time.
constexpr TimeDelta kLongTimeoutForRampingUp = TimeDelta::Minutes(1);
// The max bitrate 1500 kbps may be subject to change in the future. What we're
// interested in here is that all code paths that result in L1T3 result in the
// same target bitrate which does not exceed this limit.
constexpr DataRate kVp9ExpectedMaxBitrateForL1T3 =
DataRate::KilobitsPerSec(1500);
struct StringParamToString {
std::string operator()(const ::testing::TestParamInfo<std::string>& info) {
return info.param;
}
};
std::string GetCurrentCodecMimeType(
rtc::scoped_refptr<const RTCStatsReport> report,
const RTCOutboundRtpStreamStats& outbound_rtp) {
return outbound_rtp.codec_id.has_value()
? *report->GetAs<RTCCodecStats>(*outbound_rtp.codec_id)->mime_type
: "";
}
struct RidAndResolution {
std::string rid;
uint32_t width;
uint32_t height;
};
const RTCOutboundRtpStreamStats* FindOutboundRtpByRid(
const std::vector<const RTCOutboundRtpStreamStats*>& outbound_rtps,
const absl::string_view& rid) {
for (const auto* outbound_rtp : outbound_rtps) {
if (outbound_rtp->rid.has_value() && *outbound_rtp->rid == rid) {
return outbound_rtp;
}
}
return nullptr;
}
} // namespace
class PeerConnectionEncodingsIntegrationTest : public ::testing::Test {
public:
PeerConnectionEncodingsIntegrationTest()
: background_thread_(std::make_unique<rtc::Thread>(&pss_)) {
RTC_CHECK(background_thread_->Start());
}
rtc::scoped_refptr<PeerConnectionTestWrapper> CreatePc() {
auto pc_wrapper = rtc::make_ref_counted<PeerConnectionTestWrapper>(
"pc", &pss_, background_thread_.get(), background_thread_.get());
pc_wrapper->CreatePc({}, CreateBuiltinAudioEncoderFactory(),
CreateBuiltinAudioDecoderFactory());
return pc_wrapper;
}
rtc::scoped_refptr<RtpTransceiverInterface> AddTransceiverWithSimulcastLayers(
rtc::scoped_refptr<PeerConnectionTestWrapper> local,
rtc::scoped_refptr<PeerConnectionTestWrapper> remote,
std::vector<cricket::SimulcastLayer> init_layers) {
rtc::scoped_refptr<MediaStreamInterface> stream = local->GetUserMedia(
/*audio=*/false, cricket::AudioOptions(), /*video=*/true,
{.width = 1280, .height = 720});
rtc::scoped_refptr<VideoTrackInterface> track = stream->GetVideoTracks()[0];
RTCErrorOr<rtc::scoped_refptr<RtpTransceiverInterface>>
transceiver_or_error = local->pc()->AddTransceiver(
track, CreateTransceiverInit(init_layers));
EXPECT_TRUE(transceiver_or_error.ok());
return transceiver_or_error.value();
}
bool HasReceiverVideoCodecCapability(
rtc::scoped_refptr<PeerConnectionTestWrapper> pc_wrapper,
absl::string_view codec_name) {
std::vector<RtpCodecCapability> codecs =
pc_wrapper->pc_factory()
->GetRtpReceiverCapabilities(cricket::MEDIA_TYPE_VIDEO)
.codecs;
return std::find_if(codecs.begin(), codecs.end(),
[&codec_name](const RtpCodecCapability& codec) {
return absl::EqualsIgnoreCase(codec.name, codec_name);
}) != codecs.end();
}
std::vector<RtpCodecCapability> GetCapabilitiesAndRestrictToCodec(
rtc::scoped_refptr<PeerConnectionTestWrapper> pc_wrapper,
absl::string_view codec_name) {
std::vector<RtpCodecCapability> codecs =
pc_wrapper->pc_factory()
->GetRtpReceiverCapabilities(cricket::MEDIA_TYPE_VIDEO)
.codecs;
codecs.erase(std::remove_if(codecs.begin(), codecs.end(),
[&codec_name](const RtpCodecCapability& codec) {
return !codec.IsResiliencyCodec() &&
!absl::EqualsIgnoreCase(codec.name,
codec_name);
}),
codecs.end());
RTC_DCHECK(std::find_if(codecs.begin(), codecs.end(),
[&codec_name](const RtpCodecCapability& codec) {
return absl::EqualsIgnoreCase(codec.name,
codec_name);
}) != codecs.end());
return codecs;
}
void ExchangeIceCandidates(
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper,
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper) {
local_pc_wrapper->SignalOnIceCandidateReady.connect(
remote_pc_wrapper.get(), &PeerConnectionTestWrapper::AddIceCandidate);
remote_pc_wrapper->SignalOnIceCandidateReady.connect(
local_pc_wrapper.get(), &PeerConnectionTestWrapper::AddIceCandidate);
}
void NegotiateWithSimulcastTweaks(
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper,
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper) {
// Create and set offer for `local_pc_wrapper`.
std::unique_ptr<SessionDescriptionInterface> offer =
CreateOffer(local_pc_wrapper);
rtc::scoped_refptr<MockSetSessionDescriptionObserver> p1 =
SetLocalDescription(local_pc_wrapper, offer.get());
// Modify the offer before handoff because `remote_pc_wrapper` only supports
// receiving singlecast.
cricket::SimulcastDescription simulcast_description =
RemoveSimulcast(offer.get());
rtc::scoped_refptr<MockSetSessionDescriptionObserver> p2 =
SetRemoteDescription(remote_pc_wrapper, offer.get());
EXPECT_TRUE(Await({p1, p2}));
// Create and set answer for `remote_pc_wrapper`.
std::unique_ptr<SessionDescriptionInterface> answer =
CreateAnswer(remote_pc_wrapper);
p1 = SetLocalDescription(remote_pc_wrapper, answer.get());
// Modify the answer before handoff because `local_pc_wrapper` should still
// send simulcast.
cricket::MediaContentDescription* mcd_answer =
answer->description()->contents()[0].media_description();
mcd_answer->mutable_streams().clear();
std::vector<cricket::SimulcastLayer> simulcast_layers =
simulcast_description.send_layers().GetAllLayers();
cricket::SimulcastLayerList& receive_layers =
mcd_answer->simulcast_description().receive_layers();
for (const auto& layer : simulcast_layers) {
receive_layers.AddLayer(layer);
}
p2 = SetRemoteDescription(local_pc_wrapper, answer.get());
EXPECT_TRUE(Await({p1, p2}));
}
rtc::scoped_refptr<const RTCStatsReport> GetStats(
rtc::scoped_refptr<PeerConnectionTestWrapper> pc_wrapper) {
auto callback = rtc::make_ref_counted<MockRTCStatsCollectorCallback>();
pc_wrapper->pc()->GetStats(callback.get());
EXPECT_TRUE_WAIT(callback->called(), kDefaultTimeout.ms());
return callback->report();
}
bool IsCodecIdDifferent(
rtc::scoped_refptr<PeerConnectionTestWrapper> pc_wrapper,
size_t index,
const std::string& codec_id) {
return IsCodecIdDifferentWithScalabilityMode(pc_wrapper, index, codec_id,
absl::nullopt);
}
bool IsCodecIdDifferentWithScalabilityMode(
rtc::scoped_refptr<PeerConnectionTestWrapper> pc_wrapper,
size_t index,
const std::string& codec_id,
absl::optional<std::string> wanted_scalability_mode) {
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
return outbound_rtps[index]->codec_id.value() != codec_id &&
(!wanted_scalability_mode ||
(outbound_rtps[index]->scalability_mode.has_value() &&
outbound_rtps[index]->scalability_mode.value() ==
wanted_scalability_mode));
}
bool HasOutboundRtpBytesSent(
rtc::scoped_refptr<PeerConnectionTestWrapper> pc_wrapper,
size_t num_layers) {
return HasOutboundRtpBytesSent(pc_wrapper, num_layers, num_layers);
}
bool HasOutboundRtpBytesSent(
rtc::scoped_refptr<PeerConnectionTestWrapper> pc_wrapper,
size_t num_layers,
size_t num_active_layers) {
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
if (outbound_rtps.size() != num_layers) {
return false;
}
size_t num_sending_layers = 0;
for (const auto* outbound_rtp : outbound_rtps) {
if (outbound_rtp->bytes_sent.has_value() &&
*outbound_rtp->bytes_sent > 0u) {
++num_sending_layers;
}
}
return num_sending_layers == num_active_layers;
}
int EncodedFrames(rtc::scoped_refptr<PeerConnectionTestWrapper> pc_wrapper,
std::string_view rid) {
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
for (const auto* outbound_rtp : outbound_rtps) {
if (outbound_rtp->rid.value_or("") == rid) {
return outbound_rtp->frames_encoded.value_or(0);
}
}
return 0;
}
bool EncodingIsActive(
rtc::scoped_refptr<PeerConnectionTestWrapper> pc_wrapper,
std::string_view rid) {
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
for (const auto* outbound_rtp : outbound_rtps) {
if (outbound_rtp->rid.value_or("") == rid) {
return *outbound_rtp->active;
}
}
RTC_CHECK(false) << "Rid not found: " << rid;
return false;
}
Resolution GetEncodingResolution(
rtc::scoped_refptr<PeerConnectionTestWrapper> pc_wrapper,
std::string_view rid = "") {
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
for (const auto* outbound_rtp : outbound_rtps) {
if (outbound_rtp->rid.value_or("") == rid) {
return {
.width = static_cast<int>(outbound_rtp->frame_width.value_or(0)),
.height = static_cast<int>(outbound_rtp->frame_height.value_or(0))};
}
}
RTC_CHECK(false) << "Rid not found: " << rid;
return {};
}
bool HasOutboundRtpWithRidAndScalabilityMode(
rtc::scoped_refptr<PeerConnectionTestWrapper> pc_wrapper,
absl::string_view rid,
absl::string_view expected_scalability_mode,
uint32_t frame_height) {
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
auto* outbound_rtp = FindOutboundRtpByRid(outbound_rtps, rid);
if (!outbound_rtp || !outbound_rtp->scalability_mode.has_value() ||
*outbound_rtp->scalability_mode != expected_scalability_mode) {
RTC_LOG(LS_INFO) << "Waiting for scalability mode ("
<< (outbound_rtp
? outbound_rtp->scalability_mode.value_or(
"nullopt")
: "not found")
<< ") to be " << expected_scalability_mode;
// Sleep to avoid log spam when this is used in ASSERT_TRUE_WAIT().
rtc::Thread::Current()->SleepMs(1000);
return false;
}
if (outbound_rtp->frame_height.has_value()) {
RTC_LOG(LS_INFO) << "Waiting for target resolution (" << frame_height
<< "p). Currently at " << *outbound_rtp->frame_height
<< "p...";
} else {
RTC_LOG(LS_INFO)
<< "Waiting for target resolution. No frames encoded yet...";
}
if (!outbound_rtp->frame_height.has_value() ||
*outbound_rtp->frame_height != frame_height) {
// Sleep to avoid log spam when this is used in ASSERT_TRUE_WAIT().
rtc::Thread::Current()->SleepMs(1000);
return false;
}
return true;
}
bool OutboundRtpResolutionsAreLessThanOrEqualToExpectations(
rtc::scoped_refptr<PeerConnectionTestWrapper> pc_wrapper,
std::vector<RidAndResolution> resolutions) {
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
for (const RidAndResolution& resolution : resolutions) {
const RTCOutboundRtpStreamStats* outbound_rtp = nullptr;
if (!resolution.rid.empty()) {
outbound_rtp = FindOutboundRtpByRid(outbound_rtps, resolution.rid);
} else if (outbound_rtps.size() == 1u) {
outbound_rtp = outbound_rtps[0];
}
if (!outbound_rtp || !outbound_rtp->frame_width.has_value() ||
!outbound_rtp->frame_height.has_value()) {
// RTP not found by rid or has not encoded a frame yet.
RTC_LOG(LS_ERROR) << "rid=" << resolution.rid << " does not have "
<< "resolution metrics";
return false;
}
if (*outbound_rtp->frame_width > resolution.width ||
*outbound_rtp->frame_height > resolution.height) {
RTC_LOG(LS_ERROR) << "rid=" << resolution.rid << " is "
<< *outbound_rtp->frame_width << "x"
<< *outbound_rtp->frame_height
<< ", this is greater than the " << "expected "
<< resolution.width << "x" << resolution.height;
return false;
}
}
return true;
}
protected:
std::unique_ptr<SessionDescriptionInterface> CreateOffer(
rtc::scoped_refptr<PeerConnectionTestWrapper> pc_wrapper) {
auto observer =
rtc::make_ref_counted<MockCreateSessionDescriptionObserver>();
pc_wrapper->pc()->CreateOffer(observer.get(), {});
EXPECT_EQ_WAIT(true, observer->called(), kDefaultTimeout.ms());
return observer->MoveDescription();
}
std::unique_ptr<SessionDescriptionInterface> CreateAnswer(
rtc::scoped_refptr<PeerConnectionTestWrapper> pc_wrapper) {
auto observer =
rtc::make_ref_counted<MockCreateSessionDescriptionObserver>();
pc_wrapper->pc()->CreateAnswer(observer.get(), {});
EXPECT_EQ_WAIT(true, observer->called(), kDefaultTimeout.ms());
return observer->MoveDescription();
}
rtc::scoped_refptr<MockSetSessionDescriptionObserver> SetLocalDescription(
rtc::scoped_refptr<PeerConnectionTestWrapper> pc_wrapper,
SessionDescriptionInterface* sdp) {
auto observer = rtc::make_ref_counted<MockSetSessionDescriptionObserver>();
pc_wrapper->pc()->SetLocalDescription(
observer.get(), CloneSessionDescription(sdp).release());
return observer;
}
rtc::scoped_refptr<MockSetSessionDescriptionObserver> SetRemoteDescription(
rtc::scoped_refptr<PeerConnectionTestWrapper> pc_wrapper,
SessionDescriptionInterface* sdp) {
auto observer = rtc::make_ref_counted<MockSetSessionDescriptionObserver>();
pc_wrapper->pc()->SetRemoteDescription(
observer.get(), CloneSessionDescription(sdp).release());
return observer;
}
// To avoid ICE candidates arriving before the remote endpoint has received
// the offer it is important to SetLocalDescription() and
// SetRemoteDescription() are kicked off without awaiting in-between. This
// helper is used to await multiple observers.
bool Await(std::vector<rtc::scoped_refptr<MockSetSessionDescriptionObserver>>
observers) {
for (auto& observer : observers) {
EXPECT_EQ_WAIT(true, observer->called(), kDefaultTimeout.ms());
if (!observer->result()) {
return false;
}
}
return true;
}
rtc::PhysicalSocketServer pss_;
std::unique_ptr<rtc::Thread> background_thread_;
};
TEST_F(PeerConnectionEncodingsIntegrationTest,
VP8_SingleEncodingDefaultsToL1T1) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
std::vector<cricket::SimulcastLayer> layers =
CreateLayers({"f"}, /*active=*/true);
rtc::scoped_refptr<RtpTransceiverInterface> transceiver =
AddTransceiverWithSimulcastLayers(local_pc_wrapper, remote_pc_wrapper,
layers);
std::vector<RtpCodecCapability> codecs =
GetCapabilitiesAndRestrictToCodec(remote_pc_wrapper, "VP8");
transceiver->SetCodecPreferences(codecs);
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
// Wait until media is flowing.
ASSERT_TRUE_WAIT(HasOutboundRtpBytesSent(local_pc_wrapper, 1u),
kDefaultTimeout.ms());
EXPECT_TRUE(OutboundRtpResolutionsAreLessThanOrEqualToExpectations(
local_pc_wrapper, {{"", 1280, 720}}));
// Verify codec and scalability mode.
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(local_pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
ASSERT_THAT(outbound_rtps, SizeIs(1u));
EXPECT_THAT(GetCurrentCodecMimeType(report, *outbound_rtps[0]),
StrCaseEq("video/VP8"));
EXPECT_THAT(*outbound_rtps[0]->scalability_mode, StrEq("L1T1"));
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
VP8_RejectsSvcAndDefaultsToL1T1) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
std::vector<cricket::SimulcastLayer> layers =
CreateLayers({"f"}, /*active=*/true);
rtc::scoped_refptr<RtpTransceiverInterface> transceiver =
AddTransceiverWithSimulcastLayers(local_pc_wrapper, remote_pc_wrapper,
layers);
// Restricting the local receive codecs will restrict what we offer and
// hence the answer if it is a subset of our offer.
std::vector<RtpCodecCapability> codecs =
GetCapabilitiesAndRestrictToCodec(local_pc_wrapper, "VP8");
transceiver->SetCodecPreferences(codecs);
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
// Attempt SVC (L3T3_KEY). This is not possible because only VP8 is up for
// negotiation and VP8 does not support it.
rtc::scoped_refptr<RtpSenderInterface> sender = transceiver->sender();
RtpParameters parameters = sender->GetParameters();
ASSERT_EQ(parameters.encodings.size(), 1u);
parameters.encodings[0].scalability_mode = "L3T3_KEY";
parameters.encodings[0].scale_resolution_down_by = 1;
EXPECT_FALSE(sender->SetParameters(parameters).ok());
// `scalability_mode` remains unset because SetParameters() failed.
parameters = sender->GetParameters();
ASSERT_EQ(parameters.encodings.size(), 1u);
EXPECT_THAT(parameters.encodings[0].scalability_mode, Eq(absl::nullopt));
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
// Wait until media is flowing.
ASSERT_TRUE_WAIT(HasOutboundRtpBytesSent(local_pc_wrapper, 1u),
kDefaultTimeout.ms());
// When `scalability_mode` is not set, VP8 defaults to L1T1.
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(local_pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
ASSERT_THAT(outbound_rtps, SizeIs(1u));
EXPECT_THAT(GetCurrentCodecMimeType(report, *outbound_rtps[0]),
StrCaseEq("video/VP8"));
EXPECT_THAT(*outbound_rtps[0]->scalability_mode, StrEq("L1T1"));
// GetParameters() confirms `scalability_mode` is still not set.
parameters = sender->GetParameters();
ASSERT_EQ(parameters.encodings.size(), 1u);
EXPECT_THAT(parameters.encodings[0].scalability_mode, Eq(absl::nullopt));
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
SetParametersWithScalabilityModeNotSupportedBySubsequentNegotiation) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
std::vector<cricket::SimulcastLayer> layers =
CreateLayers({"f"}, /*active=*/true);
rtc::scoped_refptr<RtpTransceiverInterface> transceiver =
AddTransceiverWithSimulcastLayers(local_pc_wrapper, remote_pc_wrapper,
layers);
// Restricting the local receive codecs will restrict what we offer and
// hence the answer if it is a subset of our offer.
std::vector<RtpCodecCapability> codecs =
GetCapabilitiesAndRestrictToCodec(local_pc_wrapper, "VP8");
transceiver->SetCodecPreferences(codecs);
// Attempt SVC (L3T3_KEY). This is still possible because VP9 might be
// available from the remote end.
rtc::scoped_refptr<RtpSenderInterface> sender = transceiver->sender();
RtpParameters parameters = sender->GetParameters();
ASSERT_EQ(parameters.encodings.size(), 1u);
parameters.encodings[0].scalability_mode = "L3T3_KEY";
parameters.encodings[0].scale_resolution_down_by = 1;
EXPECT_TRUE(sender->SetParameters(parameters).ok());
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
// `scalability_mode` is set to the VP8 default since that is what was
// negotiated.
parameters = sender->GetParameters();
ASSERT_EQ(parameters.encodings.size(), 1u);
EXPECT_THAT(parameters.encodings[0].scalability_mode, Eq("L1T2"));
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
// Wait until media is flowing.
ASSERT_TRUE_WAIT(HasOutboundRtpBytesSent(local_pc_wrapper, 1u),
kDefaultTimeout.ms());
// When `scalability_mode` is not set, VP8 defaults to L1T1.
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(local_pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
ASSERT_THAT(outbound_rtps, SizeIs(1u));
EXPECT_THAT(GetCurrentCodecMimeType(report, *outbound_rtps[0]),
StrCaseEq("video/VP8"));
EXPECT_THAT(*outbound_rtps[0]->scalability_mode, StrEq("L1T2"));
// GetParameters() confirms `scalability_mode` is still not set.
parameters = sender->GetParameters();
ASSERT_EQ(parameters.encodings.size(), 1u);
EXPECT_THAT(parameters.encodings[0].scalability_mode, Eq("L1T2"));
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
VP8_FallbackFromSvcResultsInL1T2) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
std::vector<cricket::SimulcastLayer> layers =
CreateLayers({"f"}, /*active=*/true);
rtc::scoped_refptr<RtpTransceiverInterface> transceiver =
AddTransceiverWithSimulcastLayers(local_pc_wrapper, remote_pc_wrapper,
layers);
// Verify test assumption that VP8 is first in the list, but don't modify the
// codec preferences because we want the sender to think SVC is a possibility.
std::vector<RtpCodecCapability> codecs =
local_pc_wrapper->pc_factory()
->GetRtpSenderCapabilities(cricket::MEDIA_TYPE_VIDEO)
.codecs;
EXPECT_THAT(codecs[0].name, StrCaseEq("VP8"));
// Attempt SVC (L3T3_KEY), which is not possible with VP8, but the sender does
// not yet know which codec we'll use so the parameters will be accepted.
rtc::scoped_refptr<RtpSenderInterface> sender = transceiver->sender();
RtpParameters parameters = sender->GetParameters();
ASSERT_EQ(parameters.encodings.size(), 1u);
parameters.encodings[0].scalability_mode = "L3T3_KEY";
parameters.encodings[0].scale_resolution_down_by = 1;
EXPECT_TRUE(sender->SetParameters(parameters).ok());
// Verify fallback has not happened yet.
parameters = sender->GetParameters();
ASSERT_EQ(parameters.encodings.size(), 1u);
EXPECT_THAT(parameters.encodings[0].scalability_mode,
Optional(std::string("L3T3_KEY")));
// Negotiate, this results in VP8 being picked and fallback happening.
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
// `scalaiblity_mode` is assigned the fallback value "L1T2" which is different
// than the default of absl::nullopt.
parameters = sender->GetParameters();
ASSERT_EQ(parameters.encodings.size(), 1u);
EXPECT_THAT(parameters.encodings[0].scalability_mode,
Optional(std::string("L1T2")));
// Wait until media is flowing, no significant time needed because we only
// have one layer.
ASSERT_TRUE_WAIT(HasOutboundRtpBytesSent(local_pc_wrapper, 1u),
kDefaultTimeout.ms());
// GetStats() confirms "L1T2" is used which is different than the "L1T1"
// default or the "L3T3_KEY" that was attempted.
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(local_pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
ASSERT_THAT(outbound_rtps, SizeIs(1u));
EXPECT_THAT(GetCurrentCodecMimeType(report, *outbound_rtps[0]),
StrCaseEq("video/VP8"));
EXPECT_THAT(*outbound_rtps[0]->scalability_mode, StrEq("L1T2"));
// Now that we know VP8 is used, try setting L3T3 which should fail.
parameters = sender->GetParameters();
ASSERT_EQ(parameters.encodings.size(), 1u);
parameters.encodings[0].scalability_mode = "L3T3_KEY";
parameters.encodings[0].scale_resolution_down_by = 1;
EXPECT_FALSE(sender->SetParameters(parameters).ok());
}
// The legacy SVC path is triggered when VP9 us used, but `scalability_mode` has
// not been specified.
// TODO(https://crbug.com/webrtc/14889): When legacy VP9 SVC path has been
// deprecated and removed, update this test to assert that simulcast is used
// (i.e. VP9 is not treated differently than VP8).
TEST_F(PeerConnectionEncodingsIntegrationTest,
VP9_LegacySvcWhenScalabilityModeNotSpecified) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
std::vector<cricket::SimulcastLayer> layers =
CreateLayers({"f", "h", "q"}, /*active=*/true);
rtc::scoped_refptr<RtpTransceiverInterface> transceiver =
AddTransceiverWithSimulcastLayers(local_pc_wrapper, remote_pc_wrapper,
layers);
std::vector<RtpCodecCapability> codecs =
GetCapabilitiesAndRestrictToCodec(remote_pc_wrapper, "VP9");
transceiver->SetCodecPreferences(codecs);
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
// Wait until media is flowing. We only expect a single RTP stream.
// We expect to see bytes flowing almost immediately on the lowest layer.
ASSERT_TRUE_WAIT(HasOutboundRtpBytesSent(local_pc_wrapper, 1u),
kDefaultTimeout.ms());
// Wait until scalability mode is reported and expected resolution reached.
// Ramp up time may be significant.
ASSERT_TRUE_WAIT(HasOutboundRtpWithRidAndScalabilityMode(
local_pc_wrapper, "f", "L3T3_KEY", 720),
kLongTimeoutForRampingUp.ms());
// Despite SVC being used on a single RTP stream, GetParameters() returns the
// three encodings that we configured earlier (this is not spec-compliant but
// it is how legacy SVC behaves).
rtc::scoped_refptr<RtpSenderInterface> sender = transceiver->sender();
std::vector<RtpEncodingParameters> encodings =
sender->GetParameters().encodings;
ASSERT_EQ(encodings.size(), 3u);
// When legacy SVC is used, `scalability_mode` is not specified.
EXPECT_FALSE(encodings[0].scalability_mode.has_value());
EXPECT_FALSE(encodings[1].scalability_mode.has_value());
EXPECT_FALSE(encodings[2].scalability_mode.has_value());
}
// The spec-compliant way to configure SVC for a single stream. The expected
// outcome is the same as for the legacy SVC case except that we only have one
// encoding in GetParameters().
TEST_F(PeerConnectionEncodingsIntegrationTest,
VP9_StandardSvcWithOnlyOneEncoding) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
std::vector<cricket::SimulcastLayer> layers =
CreateLayers({"f"}, /*active=*/true);
rtc::scoped_refptr<RtpTransceiverInterface> transceiver =
AddTransceiverWithSimulcastLayers(local_pc_wrapper, remote_pc_wrapper,
layers);
std::vector<RtpCodecCapability> codecs =
GetCapabilitiesAndRestrictToCodec(remote_pc_wrapper, "VP9");
transceiver->SetCodecPreferences(codecs);
// Configure SVC, a.k.a. "L3T3_KEY".
rtc::scoped_refptr<RtpSenderInterface> sender = transceiver->sender();
RtpParameters parameters = sender->GetParameters();
ASSERT_EQ(parameters.encodings.size(), 1u);
parameters.encodings[0].scalability_mode = "L3T3_KEY";
parameters.encodings[0].scale_resolution_down_by = 1;
EXPECT_TRUE(sender->SetParameters(parameters).ok());
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
// Wait until media is flowing. We only expect a single RTP stream.
// We expect to see bytes flowing almost immediately on the lowest layer.
ASSERT_TRUE_WAIT(HasOutboundRtpBytesSent(local_pc_wrapper, 1u),
kDefaultTimeout.ms());
EXPECT_TRUE(OutboundRtpResolutionsAreLessThanOrEqualToExpectations(
local_pc_wrapper, {{"", 1280, 720}}));
// Verify codec and scalability mode.
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(local_pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
ASSERT_THAT(outbound_rtps, SizeIs(1u));
EXPECT_THAT(GetCurrentCodecMimeType(report, *outbound_rtps[0]),
StrCaseEq("video/VP9"));
EXPECT_THAT(*outbound_rtps[0]->scalability_mode, StrEq("L3T3_KEY"));
// GetParameters() is consistent with what we asked for and got.
parameters = sender->GetParameters();
ASSERT_EQ(parameters.encodings.size(), 1u);
EXPECT_THAT(parameters.encodings[0].scalability_mode,
Optional(std::string("L3T3_KEY")));
}
// The {active,inactive,inactive} case is technically simulcast but since we
// only have one active stream, we're able to do SVC (multiple spatial layers
// is not supported if multiple encodings are active). The expected outcome is
// the same as above except we end up with two inactive RTP streams which are
// observable in GetStats().
TEST_F(PeerConnectionEncodingsIntegrationTest,
VP9_StandardSvcWithSingleActiveEncoding) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
std::vector<cricket::SimulcastLayer> layers =
CreateLayers({"f", "h", "q"}, /*active=*/true);
rtc::scoped_refptr<RtpTransceiverInterface> transceiver =
AddTransceiverWithSimulcastLayers(local_pc_wrapper, remote_pc_wrapper,
layers);
std::vector<RtpCodecCapability> codecs =
GetCapabilitiesAndRestrictToCodec(remote_pc_wrapper, "VP9");
transceiver->SetCodecPreferences(codecs);
// Configure SVC, a.k.a. "L3T3_KEY".
rtc::scoped_refptr<RtpSenderInterface> sender = transceiver->sender();
RtpParameters parameters = sender->GetParameters();
ASSERT_THAT(parameters.encodings, SizeIs(3));
parameters.encodings[0].scalability_mode = "L3T3_KEY";
parameters.encodings[0].scale_resolution_down_by = 1;
parameters.encodings[1].active = false;
parameters.encodings[2].active = false;
EXPECT_TRUE(sender->SetParameters(parameters).ok());
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
// Since the standard API is configuring simulcast we get three outbound-rtps,
// but only one is active.
ASSERT_TRUE_WAIT(HasOutboundRtpBytesSent(local_pc_wrapper, 3u, 1u),
kDefaultTimeout.ms());
// Wait until scalability mode is reported and expected resolution reached.
// Ramp up time is significant.
ASSERT_TRUE_WAIT(HasOutboundRtpWithRidAndScalabilityMode(
local_pc_wrapper, "f", "L3T3_KEY", 720),
kLongTimeoutForRampingUp.ms());
// GetParameters() is consistent with what we asked for and got.
parameters = sender->GetParameters();
ASSERT_THAT(parameters.encodings, SizeIs(3));
EXPECT_THAT(parameters.encodings[0].scalability_mode,
Optional(std::string("L3T3_KEY")));
EXPECT_FALSE(parameters.encodings[1].scalability_mode.has_value());
EXPECT_FALSE(parameters.encodings[2].scalability_mode.has_value());
}
// Exercise common path where `scalability_mode` is not specified until after
// negotiation, requring us to recreate the stream when the number of streams
// changes from 1 (legacy SVC) to 3 (standard simulcast).
TEST_F(PeerConnectionEncodingsIntegrationTest,
VP9_SwitchFromLegacySvcToStandardSingleActiveEncodingSvc) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
std::vector<cricket::SimulcastLayer> layers =
CreateLayers({"f", "h", "q"}, /*active=*/true);
rtc::scoped_refptr<RtpTransceiverInterface> transceiver =
AddTransceiverWithSimulcastLayers(local_pc_wrapper, remote_pc_wrapper,
layers);
std::vector<RtpCodecCapability> codecs =
GetCapabilitiesAndRestrictToCodec(remote_pc_wrapper, "VP9");
transceiver->SetCodecPreferences(codecs);
// The original negotiation triggers legacy SVC because we didn't specify
// any scalability mode.
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
// Switch to the standard mode. Despite only having a single active stream in
// both cases, this internally reconfigures from 1 stream to 3 streams.
// Test coverage for https://crbug.com/webrtc/15016.
rtc::scoped_refptr<RtpSenderInterface> sender = transceiver->sender();
RtpParameters parameters = sender->GetParameters();
ASSERT_THAT(parameters.encodings, SizeIs(3));
parameters.encodings[0].active = true;
parameters.encodings[0].scalability_mode = "L2T2_KEY";
parameters.encodings[0].scale_resolution_down_by = 2.0;
parameters.encodings[1].active = false;
parameters.encodings[1].scalability_mode = absl::nullopt;
parameters.encodings[2].active = false;
parameters.encodings[2].scalability_mode = absl::nullopt;
sender->SetParameters(parameters);
// Since the standard API is configuring simulcast we get three outbound-rtps,
// but only one is active.
ASSERT_TRUE_WAIT(HasOutboundRtpBytesSent(local_pc_wrapper, 3u, 1u),
kDefaultTimeout.ms());
// Wait until scalability mode is reported and expected resolution reached.
// Ramp up time may be significant.
ASSERT_TRUE_WAIT(HasOutboundRtpWithRidAndScalabilityMode(
local_pc_wrapper, "f", "L2T2_KEY", 720 / 2),
kLongTimeoutForRampingUp.ms());
// GetParameters() does not report any fallback.
parameters = sender->GetParameters();
ASSERT_THAT(parameters.encodings, SizeIs(3));
EXPECT_THAT(parameters.encodings[0].scalability_mode,
Optional(std::string("L2T2_KEY")));
EXPECT_FALSE(parameters.encodings[1].scalability_mode.has_value());
EXPECT_FALSE(parameters.encodings[2].scalability_mode.has_value());
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
VP9_SimulcastMultiplLayersActive_StandardSvc) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
std::vector<cricket::SimulcastLayer> layers =
CreateLayers({"q", "h", "f"}, /*active=*/true);
rtc::scoped_refptr<RtpTransceiverInterface> transceiver =
AddTransceiverWithSimulcastLayers(local_pc_wrapper, remote_pc_wrapper,
layers);
std::vector<RtpCodecCapability> codecs =
GetCapabilitiesAndRestrictToCodec(remote_pc_wrapper, "VP9");
transceiver->SetCodecPreferences(codecs);
// Switch to the standard mode. Despite only having a single active stream in
// both cases, this internally reconfigures from 1 stream to 3 streams.
// Test coverage for https://crbug.com/webrtc/15016.
rtc::scoped_refptr<RtpSenderInterface> sender = transceiver->sender();
RtpParameters parameters = sender->GetParameters();
ASSERT_THAT(parameters.encodings, SizeIs(3));
parameters.encodings[0].active = true;
parameters.encodings[0].scalability_mode = "L1T3";
parameters.encodings[0].scale_resolution_down_by = 4.0;
parameters.encodings[1].active = true;
parameters.encodings[1].scalability_mode = "L1T1";
parameters.encodings[1].scale_resolution_down_by = 2.0;
parameters.encodings[2].active = false;
parameters.encodings[2].scalability_mode = absl::nullopt;
EXPECT_TRUE(sender->SetParameters(parameters).ok());
// The original negotiation triggers legacy SVC because we didn't specify
// any scalability mode.
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
// Since the standard API is configuring simulcast we get three outbound-rtps,
// and two are active.
ASSERT_TRUE_WAIT(HasOutboundRtpBytesSent(local_pc_wrapper, /*num_layers=*/3u,
/*num_active_layers=*/2u),
kDefaultTimeout.ms());
// Wait until scalability mode is reported and expected resolution reached.
// Ramp up time may be significant.
ASSERT_TRUE_WAIT(HasOutboundRtpWithRidAndScalabilityMode(
local_pc_wrapper, "q", "L1T3", 720 / 4),
kLongTimeoutForRampingUp.ms() / 2);
ASSERT_TRUE_WAIT(HasOutboundRtpWithRidAndScalabilityMode(
local_pc_wrapper, "h", "L1T1", 720 / 2),
kLongTimeoutForRampingUp.ms() / 2);
// GetParameters() does not report any fallback.
parameters = sender->GetParameters();
ASSERT_THAT(parameters.encodings, SizeIs(3));
EXPECT_THAT(parameters.encodings[0].scalability_mode,
Optional(StrEq("L1T3")));
EXPECT_THAT(parameters.encodings[1].scalability_mode,
Optional(StrEq("L1T1")));
EXPECT_THAT(parameters.encodings[2].scalability_mode, Eq(absl::nullopt));
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
VP9_Simulcast_SwitchToLegacySvc) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
std::vector<cricket::SimulcastLayer> layers =
CreateLayers({"f", "h", "q"}, /*active=*/true);
rtc::scoped_refptr<RtpTransceiverInterface> transceiver =
AddTransceiverWithSimulcastLayers(local_pc_wrapper, remote_pc_wrapper,
layers);
std::vector<RtpCodecCapability> codecs =
GetCapabilitiesAndRestrictToCodec(remote_pc_wrapper, "VP9");
transceiver->SetCodecPreferences(codecs);
// Switch to the standard mode. Despite only having a single active stream in
// both cases, this internally reconfigures from 1 stream to 3 streams.
// Test coverage for https://crbug.com/webrtc/15016.
rtc::scoped_refptr<RtpSenderInterface> sender = transceiver->sender();
RtpParameters parameters = sender->GetParameters();
ASSERT_THAT(parameters.encodings, SizeIs(3));
parameters.encodings[0].active = false;
parameters.encodings[1].active = true;
parameters.encodings[1].scalability_mode = "L1T1";
parameters.encodings[1].scale_resolution_down_by = 2.0;
parameters.encodings[2].active = true;
parameters.encodings[2].scalability_mode = "L1T3";
parameters.encodings[2].scale_resolution_down_by = 4.0;
EXPECT_TRUE(sender->SetParameters(parameters).ok());
// The original negotiation triggers legacy SVC because we didn't specify
// any scalability mode.
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
// Since the standard API is configuring simulcast we get three outbound-rtps,
// and two are active.
ASSERT_TRUE_WAIT(HasOutboundRtpBytesSent(local_pc_wrapper, /*num_layers=*/3u,
/*num_active_layers=*/2u),
kLongTimeoutForRampingUp.ms());
// Wait until scalability mode is reported and expected resolution reached.
// Ramp up time may be significant.
ASSERT_TRUE_WAIT(HasOutboundRtpWithRidAndScalabilityMode(
local_pc_wrapper, "q", "L1T3", 720 / 4),
kLongTimeoutForRampingUp.ms() / 2);
ASSERT_TRUE_WAIT(HasOutboundRtpWithRidAndScalabilityMode(
local_pc_wrapper, "h", "L1T1", 720 / 2),
kLongTimeoutForRampingUp.ms() / 2);
// GetParameters() does not report any fallback.
parameters = sender->GetParameters();
ASSERT_THAT(parameters.encodings, SizeIs(3));
EXPECT_THAT(parameters.encodings[0].scalability_mode, Eq(absl::nullopt));
EXPECT_THAT(parameters.encodings[1].scalability_mode,
Optional(StrEq("L1T1")));
EXPECT_THAT(parameters.encodings[2].scalability_mode,
Optional(StrEq("L1T3")));
// Switch to legacy SVC mode.
parameters.encodings[0].active = true;
parameters.encodings[0].scalability_mode = absl::nullopt;
parameters.encodings[0].scale_resolution_down_by = absl::nullopt;
parameters.encodings[1].active = true;
parameters.encodings[1].scalability_mode = absl::nullopt;
parameters.encodings[1].scale_resolution_down_by = absl::nullopt;
parameters.encodings[2].active = false;
parameters.encodings[2].scalability_mode = absl::nullopt;
parameters.encodings[2].scale_resolution_down_by = absl::nullopt;
EXPECT_TRUE(sender->SetParameters(parameters).ok());
// Ensure that we are getting VGA at L1T3 from the "f" rid.
ASSERT_TRUE_WAIT(HasOutboundRtpWithRidAndScalabilityMode(
local_pc_wrapper, "f", "L2T3_KEY", 720 / 2),
kLongTimeoutForRampingUp.ms());
}
TEST_F(PeerConnectionEncodingsIntegrationTest, VP9_OneLayerActive_LegacySvc) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
std::vector<cricket::SimulcastLayer> layers =
CreateLayers({"f", "h", "q"}, /*active=*/true);
rtc::scoped_refptr<RtpTransceiverInterface> transceiver =
AddTransceiverWithSimulcastLayers(local_pc_wrapper, remote_pc_wrapper,
layers);
std::vector<RtpCodecCapability> codecs =
GetCapabilitiesAndRestrictToCodec(remote_pc_wrapper, "VP9");
transceiver->SetCodecPreferences(codecs);
// Sending L1T3 with legacy SVC mode means setting 1 layer active.
rtc::scoped_refptr<RtpSenderInterface> sender = transceiver->sender();
RtpParameters parameters = sender->GetParameters();
ASSERT_THAT(parameters.encodings, SizeIs(3));
parameters.encodings[0].active = true;
parameters.encodings[1].active = false;
parameters.encodings[2].active = false;
sender->SetParameters(parameters);
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
// Ensure that we are getting 180P at L1T3 from the "f" rid.
ASSERT_TRUE_WAIT(HasOutboundRtpWithRidAndScalabilityMode(
local_pc_wrapper, "f", "L1T3", 720 / 4),
kLongTimeoutForRampingUp.ms());
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
VP9_AllLayersInactive_LegacySvc) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
std::vector<cricket::SimulcastLayer> layers =
CreateLayers({"f", "h", "q"}, /*active=*/true);
rtc::scoped_refptr<RtpTransceiverInterface> transceiver =
AddTransceiverWithSimulcastLayers(local_pc_wrapper, remote_pc_wrapper,
layers);
std::vector<RtpCodecCapability> codecs =
GetCapabilitiesAndRestrictToCodec(remote_pc_wrapper, "VP9");
transceiver->SetCodecPreferences(codecs);
// Legacy SVC mode and all layers inactive.
rtc::scoped_refptr<RtpSenderInterface> sender = transceiver->sender();
RtpParameters parameters = sender->GetParameters();
ASSERT_THAT(parameters.encodings, SizeIs(3));
parameters.encodings[0].active = false;
parameters.encodings[1].active = false;
parameters.encodings[2].active = false;
sender->SetParameters(parameters);
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
// Ensure no media is flowing (1 second should be enough).
rtc::Thread::Current()->SleepMs(1000);
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(local_pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
ASSERT_THAT(outbound_rtps, SizeIs(1u));
EXPECT_EQ(*outbound_rtps[0]->bytes_sent, 0u);
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
VP9_AllLayersInactive_StandardSvc) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
std::vector<cricket::SimulcastLayer> layers =
CreateLayers({"f", "h", "q"}, /*active=*/true);
rtc::scoped_refptr<RtpTransceiverInterface> transceiver =
AddTransceiverWithSimulcastLayers(local_pc_wrapper, remote_pc_wrapper,
layers);
std::vector<RtpCodecCapability> codecs =
GetCapabilitiesAndRestrictToCodec(remote_pc_wrapper, "VP9");
transceiver->SetCodecPreferences(codecs);
// Standard mode and all layers inactive.
rtc::scoped_refptr<RtpSenderInterface> sender = transceiver->sender();
RtpParameters parameters = sender->GetParameters();
ASSERT_THAT(parameters.encodings, SizeIs(3));
parameters.encodings[0].scalability_mode = "L3T3_KEY";
parameters.encodings[0].scale_resolution_down_by = 1;
parameters.encodings[0].active = false;
parameters.encodings[1].active = false;
parameters.encodings[2].active = false;
sender->SetParameters(parameters);
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
// Ensure no media is flowing (1 second should be enough).
rtc::Thread::Current()->SleepMs(1000);
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(local_pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
ASSERT_THAT(outbound_rtps, SizeIs(3u));
EXPECT_EQ(*outbound_rtps[0]->bytes_sent, 0u);
EXPECT_EQ(*outbound_rtps[1]->bytes_sent, 0u);
EXPECT_EQ(*outbound_rtps[2]->bytes_sent, 0u);
}
TEST_F(PeerConnectionEncodingsIntegrationTest, VP9_TargetBitrate_LegacyL1T3) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
std::vector<cricket::SimulcastLayer> layers =
CreateLayers({"f", "h", "q"}, /*active=*/true);
rtc::scoped_refptr<RtpTransceiverInterface> transceiver =
AddTransceiverWithSimulcastLayers(local_pc_wrapper, remote_pc_wrapper,
layers);
std::vector<RtpCodecCapability> codecs =
GetCapabilitiesAndRestrictToCodec(remote_pc_wrapper, "VP9");
transceiver->SetCodecPreferences(codecs);
// In legacy SVC, disabling the bottom two layers encodings is interpreted as
// disabling the bottom two spatial layers resulting in L1T3.
rtc::scoped_refptr<RtpSenderInterface> sender = transceiver->sender();
RtpParameters parameters = sender->GetParameters();
parameters.encodings[0].active = false;
parameters.encodings[1].active = false;
parameters.encodings[2].active = true;
sender->SetParameters(parameters);
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
// Wait until 720p L1T3 has ramped up to 720p. It may take additional time
// for the target bitrate to reach its maximum.
ASSERT_TRUE_WAIT(HasOutboundRtpWithRidAndScalabilityMode(local_pc_wrapper,
"f", "L1T3", 720),
kLongTimeoutForRampingUp.ms());
// The target bitrate typically reaches `kVp9ExpectedMaxBitrateForL1T3`
// in a short period of time. However to reduce risk of flakiness in bot
// environments, this test only fails if we we exceed the expected target.
rtc::Thread::Current()->SleepMs(1000);
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(local_pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
ASSERT_THAT(outbound_rtps, SizeIs(1));
DataRate target_bitrate =
DataRate::BitsPerSec(*outbound_rtps[0]->target_bitrate);
EXPECT_LE(target_bitrate.kbps(), kVp9ExpectedMaxBitrateForL1T3.kbps());
}
// Test coverage for https://crbug.com/1455039.
TEST_F(PeerConnectionEncodingsIntegrationTest, VP9_TargetBitrate_StandardL1T3) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
std::vector<cricket::SimulcastLayer> layers =
CreateLayers({"f", "h", "q"}, /*active=*/true);
rtc::scoped_refptr<RtpTransceiverInterface> transceiver =
AddTransceiverWithSimulcastLayers(local_pc_wrapper, remote_pc_wrapper,
layers);
std::vector<RtpCodecCapability> codecs =
GetCapabilitiesAndRestrictToCodec(remote_pc_wrapper, "VP9");
transceiver->SetCodecPreferences(codecs);
// With standard APIs, L1T3 is explicitly specified and the encodings refers
// to the RTP streams, not the spatial layers. The end result should be
// equivalent to the legacy L1T3 case.
rtc::scoped_refptr<RtpSenderInterface> sender = transceiver->sender();
RtpParameters parameters = sender->GetParameters();
parameters.encodings[0].active = true;
parameters.encodings[0].scale_resolution_down_by = 1.0;
parameters.encodings[0].scalability_mode = "L1T3";
parameters.encodings[1].active = false;
parameters.encodings[2].active = false;
sender->SetParameters(parameters);
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
// Wait until 720p L1T3 has ramped up to 720p. It may take additional time
// for the target bitrate to reach its maximum.
ASSERT_TRUE_WAIT(HasOutboundRtpWithRidAndScalabilityMode(local_pc_wrapper,
"f", "L1T3", 720),
kLongTimeoutForRampingUp.ms());
// The target bitrate typically reaches `kVp9ExpectedMaxBitrateForL1T3`
// in a short period of time. However to reduce risk of flakiness in bot
// environments, this test only fails if we we exceed the expected target.
rtc::Thread::Current()->SleepMs(1000);
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(local_pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
ASSERT_THAT(outbound_rtps, SizeIs(3));
auto* outbound_rtp = FindOutboundRtpByRid(outbound_rtps, "f");
ASSERT_TRUE(outbound_rtp);
DataRate target_bitrate = DataRate::BitsPerSec(*outbound_rtp->target_bitrate);
EXPECT_LE(target_bitrate.kbps(), kVp9ExpectedMaxBitrateForL1T3.kbps());
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
SimulcastProducesUniqueSsrcAndRtxSsrcs) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
std::vector<cricket::SimulcastLayer> layers =
CreateLayers({"f", "h", "q"}, /*active=*/true);
rtc::scoped_refptr<RtpTransceiverInterface> transceiver =
AddTransceiverWithSimulcastLayers(local_pc_wrapper, remote_pc_wrapper,
layers);
std::vector<RtpCodecCapability> codecs =
GetCapabilitiesAndRestrictToCodec(remote_pc_wrapper, "VP8");
transceiver->SetCodecPreferences(codecs);
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
// Wait until media is flowing on all three layers.
// Ramp up time is needed before all three layers are sending.
ASSERT_TRUE_WAIT(HasOutboundRtpBytesSent(local_pc_wrapper, 3u),
kLongTimeoutForRampingUp.ms());
// Verify SSRCs and RTX SSRCs.
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(local_pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
ASSERT_THAT(outbound_rtps, SizeIs(3u));
std::set<uint32_t> ssrcs;
std::set<uint32_t> rtx_ssrcs;
for (const auto& outbound_rtp : outbound_rtps) {
ASSERT_TRUE(outbound_rtp->ssrc.has_value());
ASSERT_TRUE(outbound_rtp->rtx_ssrc.has_value());
ssrcs.insert(*outbound_rtp->ssrc);
rtx_ssrcs.insert(*outbound_rtp->rtx_ssrc);
}
EXPECT_EQ(ssrcs.size(), 3u);
EXPECT_EQ(rtx_ssrcs.size(), 3u);
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
EncodingParameterCodecIsEmptyWhenCreatedAudio) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
auto transceiver_or_error =
local_pc_wrapper->pc()->AddTransceiver(cricket::MEDIA_TYPE_AUDIO);
rtc::scoped_refptr<RtpTransceiverInterface> audio_transceiver =
transceiver_or_error.MoveValue();
RtpParameters parameters = audio_transceiver->sender()->GetParameters();
EXPECT_FALSE(parameters.encodings[0].codec.has_value());
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
EncodingParameterCodecIsEmptyWhenCreatedVideo) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
auto transceiver_or_error =
local_pc_wrapper->pc()->AddTransceiver(cricket::MEDIA_TYPE_VIDEO);
rtc::scoped_refptr<RtpTransceiverInterface> video_transceiver =
transceiver_or_error.MoveValue();
RtpParameters parameters = video_transceiver->sender()->GetParameters();
EXPECT_FALSE(parameters.encodings[0].codec.has_value());
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
EncodingParameterCodecIsSetByAddTransceiverAudio) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
rtc::scoped_refptr<MediaStreamInterface> stream =
local_pc_wrapper->GetUserMedia(
/*audio=*/true, {}, /*video=*/false, {});
rtc::scoped_refptr<AudioTrackInterface> track = stream->GetAudioTracks()[0];
absl::optional<RtpCodecCapability> pcmu =
local_pc_wrapper->FindFirstSendCodecWithName(cricket::MEDIA_TYPE_AUDIO,
"pcmu");
ASSERT_TRUE(pcmu);
RtpTransceiverInit init;
init.direction = RtpTransceiverDirection::kSendOnly;
RtpEncodingParameters encoding_parameters;
encoding_parameters.codec = pcmu;
init.send_encodings.push_back(encoding_parameters);
auto transceiver_or_error =
local_pc_wrapper->pc()->AddTransceiver(track, init);
rtc::scoped_refptr<RtpTransceiverInterface> audio_transceiver =
transceiver_or_error.MoveValue();
RtpParameters parameters = audio_transceiver->sender()->GetParameters();
EXPECT_EQ(*parameters.encodings[0].codec, *pcmu);
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(local_pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
ASSERT_EQ(outbound_rtps.size(), 1u);
std::string codec_name = GetCurrentCodecMimeType(report, *outbound_rtps[0]);
EXPECT_STRCASEEQ(("audio/" + pcmu->name).c_str(), codec_name.c_str());
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
EncodingParameterCodecIsSetByAddTransceiverVideo) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
rtc::scoped_refptr<MediaStreamInterface> stream =
local_pc_wrapper->GetUserMedia(
/*audio=*/false, {}, /*video=*/true, {.width = 1280, .height = 720});
rtc::scoped_refptr<VideoTrackInterface> track = stream->GetVideoTracks()[0];
absl::optional<RtpCodecCapability> vp9 =
local_pc_wrapper->FindFirstSendCodecWithName(cricket::MEDIA_TYPE_VIDEO,
"vp9");
ASSERT_TRUE(vp9);
RtpTransceiverInit init;
init.direction = RtpTransceiverDirection::kSendOnly;
RtpEncodingParameters encoding_parameters;
encoding_parameters.codec = vp9;
encoding_parameters.scalability_mode = "L3T3";
init.send_encodings.push_back(encoding_parameters);
auto transceiver_or_error =
local_pc_wrapper->pc()->AddTransceiver(track, init);
rtc::scoped_refptr<RtpTransceiverInterface> audio_transceiver =
transceiver_or_error.MoveValue();
RtpParameters parameters = audio_transceiver->sender()->GetParameters();
EXPECT_EQ(*parameters.encodings[0].codec, *vp9);
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
EXPECT_TRUE_WAIT(
IsCodecIdDifferentWithScalabilityMode(local_pc_wrapper, 0, "", "L3T3"),
kDefaultTimeout.ms());
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(local_pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
ASSERT_EQ(outbound_rtps.size(), 1u);
std::string codec_name = GetCurrentCodecMimeType(report, *outbound_rtps[0]);
EXPECT_STRCASEEQ(("video/" + vp9->name).c_str(), codec_name.c_str());
EXPECT_EQ(outbound_rtps[0]->scalability_mode.value(), "L3T3");
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
EncodingParameterCodecIsSetBySetParametersBeforeNegotiationAudio) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
rtc::scoped_refptr<MediaStreamInterface> stream =
local_pc_wrapper->GetUserMedia(
/*audio=*/true, {}, /*video=*/false, {});
rtc::scoped_refptr<AudioTrackInterface> track = stream->GetAudioTracks()[0];
absl::optional<RtpCodecCapability> pcmu =
local_pc_wrapper->FindFirstSendCodecWithName(cricket::MEDIA_TYPE_AUDIO,
"pcmu");
auto transceiver_or_error = local_pc_wrapper->pc()->AddTransceiver(track);
rtc::scoped_refptr<RtpTransceiverInterface> audio_transceiver =
transceiver_or_error.MoveValue();
RtpParameters parameters = audio_transceiver->sender()->GetParameters();
parameters.encodings[0].codec = pcmu;
EXPECT_TRUE(audio_transceiver->sender()->SetParameters(parameters).ok());
parameters = audio_transceiver->sender()->GetParameters();
EXPECT_EQ(parameters.encodings[0].codec, pcmu);
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(local_pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
ASSERT_EQ(outbound_rtps.size(), 1u);
std::string codec_name = GetCurrentCodecMimeType(report, *outbound_rtps[0]);
EXPECT_STRCASEEQ(("audio/" + pcmu->name).c_str(), codec_name.c_str());
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
EncodingParameterCodecIsSetBySetParametersAfterNegotiationAudio) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
rtc::scoped_refptr<MediaStreamInterface> stream =
local_pc_wrapper->GetUserMedia(
/*audio=*/true, {}, /*video=*/false, {});
rtc::scoped_refptr<AudioTrackInterface> track = stream->GetAudioTracks()[0];
absl::optional<RtpCodecCapability> pcmu =
local_pc_wrapper->FindFirstSendCodecWithName(cricket::MEDIA_TYPE_AUDIO,
"pcmu");
auto transceiver_or_error = local_pc_wrapper->pc()->AddTransceiver(track);
rtc::scoped_refptr<RtpTransceiverInterface> audio_transceiver =
transceiver_or_error.MoveValue();
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(local_pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
ASSERT_EQ(outbound_rtps.size(), 1u);
std::string codec_name = GetCurrentCodecMimeType(report, *outbound_rtps[0]);
EXPECT_STRCASENE(("audio/" + pcmu->name).c_str(), codec_name.c_str());
std::string last_codec_id = outbound_rtps[0]->codec_id.value();
RtpParameters parameters = audio_transceiver->sender()->GetParameters();
parameters.encodings[0].codec = pcmu;
EXPECT_TRUE(audio_transceiver->sender()->SetParameters(parameters).ok());
parameters = audio_transceiver->sender()->GetParameters();
EXPECT_EQ(parameters.encodings[0].codec, pcmu);
EXPECT_TRUE_WAIT(IsCodecIdDifferent(local_pc_wrapper, 0, last_codec_id),
kDefaultTimeout.ms());
report = GetStats(local_pc_wrapper);
outbound_rtps = report->GetStatsOfType<RTCOutboundRtpStreamStats>();
ASSERT_EQ(outbound_rtps.size(), 1u);
codec_name = GetCurrentCodecMimeType(report, *outbound_rtps[0]);
EXPECT_STRCASEEQ(("audio/" + pcmu->name).c_str(), codec_name.c_str());
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
EncodingParameterCodecIsSetBySetParametersBeforeNegotiationVideo) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
rtc::scoped_refptr<MediaStreamInterface> stream =
local_pc_wrapper->GetUserMedia(
/*audio=*/false, {}, /*video=*/true, {.width = 1280, .height = 720});
rtc::scoped_refptr<VideoTrackInterface> track = stream->GetVideoTracks()[0];
absl::optional<RtpCodecCapability> vp9 =
local_pc_wrapper->FindFirstSendCodecWithName(cricket::MEDIA_TYPE_VIDEO,
"vp9");
auto transceiver_or_error = local_pc_wrapper->pc()->AddTransceiver(track);
rtc::scoped_refptr<RtpTransceiverInterface> video_transceiver =
transceiver_or_error.MoveValue();
RtpParameters parameters = video_transceiver->sender()->GetParameters();
parameters.encodings[0].codec = vp9;
parameters.encodings[0].scalability_mode = "L3T3";
EXPECT_TRUE(video_transceiver->sender()->SetParameters(parameters).ok());
parameters = video_transceiver->sender()->GetParameters();
EXPECT_EQ(parameters.encodings[0].codec, vp9);
EXPECT_EQ(parameters.encodings[0].scalability_mode, "L3T3");
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
EXPECT_TRUE_WAIT(
IsCodecIdDifferentWithScalabilityMode(local_pc_wrapper, 0, "", "L3T3"),
kDefaultTimeout.ms());
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(local_pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
ASSERT_EQ(outbound_rtps.size(), 1u);
std::string codec_name = GetCurrentCodecMimeType(report, *outbound_rtps[0]);
EXPECT_STRCASEEQ(("video/" + vp9->name).c_str(), codec_name.c_str());
EXPECT_EQ(outbound_rtps[0]->scalability_mode.value_or(""), "L3T3");
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
EncodingParameterCodecIsSetBySetParametersAfterNegotiationVideo) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
rtc::scoped_refptr<MediaStreamInterface> stream =
local_pc_wrapper->GetUserMedia(
/*audio=*/false, {}, /*video=*/true, {.width = 1280, .height = 720});
rtc::scoped_refptr<VideoTrackInterface> track = stream->GetVideoTracks()[0];
absl::optional<RtpCodecCapability> vp9 =
local_pc_wrapper->FindFirstSendCodecWithName(cricket::MEDIA_TYPE_VIDEO,
"vp9");
auto transceiver_or_error = local_pc_wrapper->pc()->AddTransceiver(track);
rtc::scoped_refptr<RtpTransceiverInterface> video_transceiver =
transceiver_or_error.MoveValue();
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(local_pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
ASSERT_EQ(outbound_rtps.size(), 1u);
std::string codec_name = GetCurrentCodecMimeType(report, *outbound_rtps[0]);
EXPECT_STRCASENE(("audio/" + vp9->name).c_str(), codec_name.c_str());
std::string last_codec_id = outbound_rtps[0]->codec_id.value();
RtpParameters parameters = video_transceiver->sender()->GetParameters();
parameters.encodings[0].codec = vp9;
parameters.encodings[0].scalability_mode = "L3T3";
EXPECT_TRUE(video_transceiver->sender()->SetParameters(parameters).ok());
parameters = video_transceiver->sender()->GetParameters();
EXPECT_EQ(parameters.encodings[0].codec, vp9);
EXPECT_EQ(parameters.encodings[0].scalability_mode, "L3T3");
EXPECT_TRUE_WAIT(IsCodecIdDifferentWithScalabilityMode(local_pc_wrapper, 0,
last_codec_id, "L3T3"),
kDefaultTimeout.ms());
report = GetStats(local_pc_wrapper);
outbound_rtps = report->GetStatsOfType<RTCOutboundRtpStreamStats>();
ASSERT_EQ(outbound_rtps.size(), 1u);
codec_name = GetCurrentCodecMimeType(report, *outbound_rtps[0]);
EXPECT_STRCASEEQ(("video/" + vp9->name).c_str(), codec_name.c_str());
EXPECT_EQ(outbound_rtps[0]->scalability_mode.value(), "L3T3");
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
AddTransceiverRejectsUnknownCodecParameterAudio) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
RtpCodec dummy_codec;
dummy_codec.kind = cricket::MEDIA_TYPE_AUDIO;
dummy_codec.name = "FOOBAR";
dummy_codec.clock_rate = 90000;
dummy_codec.num_channels = 2;
RtpTransceiverInit init;
init.direction = RtpTransceiverDirection::kSendOnly;
RtpEncodingParameters encoding_parameters;
encoding_parameters.codec = dummy_codec;
init.send_encodings.push_back(encoding_parameters);
auto transceiver_or_error =
local_pc_wrapper->pc()->AddTransceiver(cricket::MEDIA_TYPE_AUDIO, init);
EXPECT_FALSE(transceiver_or_error.ok());
EXPECT_EQ(transceiver_or_error.error().type(),
RTCErrorType::UNSUPPORTED_OPERATION);
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
AddTransceiverRejectsUnknownCodecParameterVideo) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
RtpCodec dummy_codec;
dummy_codec.kind = cricket::MEDIA_TYPE_VIDEO;
dummy_codec.name = "FOOBAR";
dummy_codec.clock_rate = 90000;
RtpTransceiverInit init;
init.direction = RtpTransceiverDirection::kSendOnly;
RtpEncodingParameters encoding_parameters;
encoding_parameters.codec = dummy_codec;
init.send_encodings.push_back(encoding_parameters);
auto transceiver_or_error =
local_pc_wrapper->pc()->AddTransceiver(cricket::MEDIA_TYPE_VIDEO, init);
EXPECT_FALSE(transceiver_or_error.ok());
EXPECT_EQ(transceiver_or_error.error().type(),
RTCErrorType::UNSUPPORTED_OPERATION);
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
SetParametersRejectsUnknownCodecParameterAudio) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
RtpCodec dummy_codec;
dummy_codec.kind = cricket::MEDIA_TYPE_AUDIO;
dummy_codec.name = "FOOBAR";
dummy_codec.clock_rate = 90000;
dummy_codec.num_channels = 2;
auto transceiver_or_error =
local_pc_wrapper->pc()->AddTransceiver(cricket::MEDIA_TYPE_AUDIO);
ASSERT_TRUE(transceiver_or_error.ok());
rtc::scoped_refptr<RtpTransceiverInterface> audio_transceiver =
transceiver_or_error.MoveValue();
RtpParameters parameters = audio_transceiver->sender()->GetParameters();
parameters.encodings[0].codec = dummy_codec;
RTCError error = audio_transceiver->sender()->SetParameters(parameters);
EXPECT_EQ(error.type(), RTCErrorType::INVALID_MODIFICATION);
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
SetParametersRejectsUnknownCodecParameterVideo) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
RtpCodec dummy_codec;
dummy_codec.kind = cricket::MEDIA_TYPE_VIDEO;
dummy_codec.name = "FOOBAR";
dummy_codec.clock_rate = 90000;
auto transceiver_or_error =
local_pc_wrapper->pc()->AddTransceiver(cricket::MEDIA_TYPE_VIDEO);
ASSERT_TRUE(transceiver_or_error.ok());
rtc::scoped_refptr<RtpTransceiverInterface> video_transceiver =
transceiver_or_error.MoveValue();
RtpParameters parameters = video_transceiver->sender()->GetParameters();
parameters.encodings[0].codec = dummy_codec;
RTCError error = video_transceiver->sender()->SetParameters(parameters);
EXPECT_EQ(error.type(), RTCErrorType::INVALID_MODIFICATION);
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
SetParametersRejectsNonNegotiatedCodecParameterAudio) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
absl::optional<RtpCodecCapability> opus =
local_pc_wrapper->FindFirstSendCodecWithName(cricket::MEDIA_TYPE_AUDIO,
"opus");
ASSERT_TRUE(opus);
std::vector<RtpCodecCapability> not_opus_codecs =
local_pc_wrapper->pc_factory()
->GetRtpSenderCapabilities(cricket::MEDIA_TYPE_AUDIO)
.codecs;
not_opus_codecs.erase(
std::remove_if(not_opus_codecs.begin(), not_opus_codecs.end(),
[&](const auto& codec) {
return absl::EqualsIgnoreCase(codec.name, opus->name);
}),
not_opus_codecs.end());
auto transceiver_or_error =
local_pc_wrapper->pc()->AddTransceiver(cricket::MEDIA_TYPE_AUDIO);
ASSERT_TRUE(transceiver_or_error.ok());
rtc::scoped_refptr<RtpTransceiverInterface> audio_transceiver =
transceiver_or_error.MoveValue();
ASSERT_TRUE(audio_transceiver->SetCodecPreferences(not_opus_codecs).ok());
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
RtpParameters parameters = audio_transceiver->sender()->GetParameters();
parameters.encodings[0].codec = opus;
RTCError error = audio_transceiver->sender()->SetParameters(parameters);
EXPECT_EQ(error.type(), RTCErrorType::INVALID_MODIFICATION);
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
SetParametersRejectsNonRemotelyNegotiatedCodecParameterAudio) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
absl::optional<RtpCodecCapability> opus =
local_pc_wrapper->FindFirstSendCodecWithName(cricket::MEDIA_TYPE_AUDIO,
"opus");
ASSERT_TRUE(opus);
std::vector<RtpCodecCapability> not_opus_codecs =
local_pc_wrapper->pc_factory()
->GetRtpSenderCapabilities(cricket::MEDIA_TYPE_AUDIO)
.codecs;
not_opus_codecs.erase(
std::remove_if(not_opus_codecs.begin(), not_opus_codecs.end(),
[&](const auto& codec) {
return absl::EqualsIgnoreCase(codec.name, opus->name);
}),
not_opus_codecs.end());
auto transceiver_or_error =
local_pc_wrapper->pc()->AddTransceiver(cricket::MEDIA_TYPE_AUDIO);
ASSERT_TRUE(transceiver_or_error.ok());
rtc::scoped_refptr<RtpTransceiverInterface> audio_transceiver =
transceiver_or_error.MoveValue();
// Negotiation, create offer and apply it
std::unique_ptr<SessionDescriptionInterface> offer =
CreateOffer(local_pc_wrapper);
rtc::scoped_refptr<MockSetSessionDescriptionObserver> p1 =
SetLocalDescription(local_pc_wrapper, offer.get());
rtc::scoped_refptr<MockSetSessionDescriptionObserver> p2 =
SetRemoteDescription(remote_pc_wrapper, offer.get());
EXPECT_TRUE(Await({p1, p2}));
// Update the remote transceiver to reject Opus
std::vector<rtc::scoped_refptr<RtpTransceiverInterface>> remote_transceivers =
remote_pc_wrapper->pc()->GetTransceivers();
ASSERT_TRUE(!remote_transceivers.empty());
rtc::scoped_refptr<RtpTransceiverInterface> remote_audio_transceiver =
remote_transceivers[0];
ASSERT_TRUE(
remote_audio_transceiver->SetCodecPreferences(not_opus_codecs).ok());
// Create answer and apply it
std::unique_ptr<SessionDescriptionInterface> answer =
CreateAnswer(remote_pc_wrapper);
p1 = SetLocalDescription(remote_pc_wrapper, answer.get());
p2 = SetRemoteDescription(local_pc_wrapper, answer.get());
EXPECT_TRUE(Await({p1, p2}));
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
RtpParameters parameters = audio_transceiver->sender()->GetParameters();
parameters.encodings[0].codec = opus;
RTCError error = audio_transceiver->sender()->SetParameters(parameters);
EXPECT_EQ(error.type(), RTCErrorType::INVALID_MODIFICATION);
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
SetParametersRejectsNonNegotiatedCodecParameterVideo) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
absl::optional<RtpCodecCapability> vp8 =
local_pc_wrapper->FindFirstSendCodecWithName(cricket::MEDIA_TYPE_VIDEO,
"vp8");
ASSERT_TRUE(vp8);
std::vector<RtpCodecCapability> not_vp8_codecs =
local_pc_wrapper->pc_factory()
->GetRtpSenderCapabilities(cricket::MEDIA_TYPE_VIDEO)
.codecs;
not_vp8_codecs.erase(
std::remove_if(not_vp8_codecs.begin(), not_vp8_codecs.end(),
[&](const auto& codec) {
return absl::EqualsIgnoreCase(codec.name, vp8->name);
}),
not_vp8_codecs.end());
auto transceiver_or_error =
local_pc_wrapper->pc()->AddTransceiver(cricket::MEDIA_TYPE_VIDEO);
ASSERT_TRUE(transceiver_or_error.ok());
rtc::scoped_refptr<RtpTransceiverInterface> video_transceiver =
transceiver_or_error.MoveValue();
ASSERT_TRUE(video_transceiver->SetCodecPreferences(not_vp8_codecs).ok());
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
RtpParameters parameters = video_transceiver->sender()->GetParameters();
parameters.encodings[0].codec = vp8;
RTCError error = video_transceiver->sender()->SetParameters(parameters);
EXPECT_EQ(error.type(), RTCErrorType::INVALID_MODIFICATION);
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
SetParametersRejectsNonRemotelyNegotiatedCodecParameterVideo) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
absl::optional<RtpCodecCapability> vp8 =
local_pc_wrapper->FindFirstSendCodecWithName(cricket::MEDIA_TYPE_VIDEO,
"vp8");
ASSERT_TRUE(vp8);
std::vector<RtpCodecCapability> not_vp8_codecs =
local_pc_wrapper->pc_factory()
->GetRtpSenderCapabilities(cricket::MEDIA_TYPE_VIDEO)
.codecs;
not_vp8_codecs.erase(
std::remove_if(not_vp8_codecs.begin(), not_vp8_codecs.end(),
[&](const auto& codec) {
return absl::EqualsIgnoreCase(codec.name, vp8->name);
}),
not_vp8_codecs.end());
auto transceiver_or_error =
local_pc_wrapper->pc()->AddTransceiver(cricket::MEDIA_TYPE_VIDEO);
ASSERT_TRUE(transceiver_or_error.ok());
rtc::scoped_refptr<RtpTransceiverInterface> video_transceiver =
transceiver_or_error.MoveValue();
// Negotiation, create offer and apply it
std::unique_ptr<SessionDescriptionInterface> offer =
CreateOffer(local_pc_wrapper);
rtc::scoped_refptr<MockSetSessionDescriptionObserver> p1 =
SetLocalDescription(local_pc_wrapper, offer.get());
rtc::scoped_refptr<MockSetSessionDescriptionObserver> p2 =
SetRemoteDescription(remote_pc_wrapper, offer.get());
EXPECT_TRUE(Await({p1, p2}));
// Update the remote transceiver to reject VP8
std::vector<rtc::scoped_refptr<RtpTransceiverInterface>> remote_transceivers =
remote_pc_wrapper->pc()->GetTransceivers();
ASSERT_TRUE(!remote_transceivers.empty());
rtc::scoped_refptr<RtpTransceiverInterface> remote_video_transceiver =
remote_transceivers[0];
ASSERT_TRUE(
remote_video_transceiver->SetCodecPreferences(not_vp8_codecs).ok());
// Create answer and apply it
std::unique_ptr<SessionDescriptionInterface> answer =
CreateAnswer(remote_pc_wrapper);
p1 = SetLocalDescription(remote_pc_wrapper, answer.get());
p2 = SetRemoteDescription(local_pc_wrapper, answer.get());
EXPECT_TRUE(Await({p1, p2}));
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
RtpParameters parameters = video_transceiver->sender()->GetParameters();
parameters.encodings[0].codec = vp8;
RTCError error = video_transceiver->sender()->SetParameters(parameters);
EXPECT_EQ(error.type(), RTCErrorType::INVALID_MODIFICATION);
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
EncodingParametersCodecRemovedAfterNegotiationAudio) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
absl::optional<RtpCodecCapability> opus =
local_pc_wrapper->FindFirstSendCodecWithName(cricket::MEDIA_TYPE_AUDIO,
"opus");
ASSERT_TRUE(opus);
std::vector<RtpCodecCapability> not_opus_codecs =
local_pc_wrapper->pc_factory()
->GetRtpSenderCapabilities(cricket::MEDIA_TYPE_AUDIO)
.codecs;
not_opus_codecs.erase(
std::remove_if(not_opus_codecs.begin(), not_opus_codecs.end(),
[&](const auto& codec) {
return absl::EqualsIgnoreCase(codec.name, opus->name);
}),
not_opus_codecs.end());
RtpTransceiverInit init;
init.direction = RtpTransceiverDirection::kSendOnly;
RtpEncodingParameters encoding_parameters;
encoding_parameters.codec = opus;
init.send_encodings.push_back(encoding_parameters);
auto transceiver_or_error =
local_pc_wrapper->pc()->AddTransceiver(cricket::MEDIA_TYPE_AUDIO, init);
ASSERT_TRUE(transceiver_or_error.ok());
rtc::scoped_refptr<RtpTransceiverInterface> audio_transceiver =
transceiver_or_error.MoveValue();
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
RtpParameters parameters = audio_transceiver->sender()->GetParameters();
EXPECT_EQ(parameters.encodings[0].codec, opus);
ASSERT_TRUE(audio_transceiver->SetCodecPreferences(not_opus_codecs).ok());
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
parameters = audio_transceiver->sender()->GetParameters();
EXPECT_FALSE(parameters.encodings[0].codec);
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
EncodingParametersRedEnabledBeforeNegotiationAudio) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
std::vector<RtpCodecCapability> send_codecs =
local_pc_wrapper->pc_factory()
->GetRtpSenderCapabilities(cricket::MEDIA_TYPE_AUDIO)
.codecs;
absl::optional<RtpCodecCapability> opus =
local_pc_wrapper->FindFirstSendCodecWithName(cricket::MEDIA_TYPE_AUDIO,
"opus");
ASSERT_TRUE(opus);
absl::optional<RtpCodecCapability> red =
local_pc_wrapper->FindFirstSendCodecWithName(cricket::MEDIA_TYPE_AUDIO,
"red");
ASSERT_TRUE(red);
RtpTransceiverInit init;
init.direction = RtpTransceiverDirection::kSendOnly;
RtpEncodingParameters encoding_parameters;
encoding_parameters.codec = opus;
init.send_encodings.push_back(encoding_parameters);
auto transceiver_or_error =
local_pc_wrapper->pc()->AddTransceiver(cricket::MEDIA_TYPE_AUDIO, init);
ASSERT_TRUE(transceiver_or_error.ok());
rtc::scoped_refptr<RtpTransceiverInterface> audio_transceiver =
transceiver_or_error.MoveValue();
// Preferring RED over Opus should enable RED with Opus encoding.
send_codecs[0] = red.value();
send_codecs[1] = opus.value();
ASSERT_TRUE(audio_transceiver->SetCodecPreferences(send_codecs).ok());
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
RtpParameters parameters = audio_transceiver->sender()->GetParameters();
EXPECT_EQ(parameters.encodings[0].codec, opus);
EXPECT_EQ(parameters.codecs[0].payload_type, red->preferred_payload_type);
EXPECT_EQ(parameters.codecs[0].name, red->name);
// Check that it's possible to switch back to Opus without RED.
send_codecs[0] = opus.value();
send_codecs[1] = red.value();
ASSERT_TRUE(audio_transceiver->SetCodecPreferences(send_codecs).ok());
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
parameters = audio_transceiver->sender()->GetParameters();
EXPECT_EQ(parameters.encodings[0].codec, opus);
EXPECT_EQ(parameters.codecs[0].payload_type, opus->preferred_payload_type);
EXPECT_EQ(parameters.codecs[0].name, opus->name);
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
SetParametersRejectsScalabilityModeForSelectedCodec) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
absl::optional<RtpCodecCapability> vp8 =
local_pc_wrapper->FindFirstSendCodecWithName(cricket::MEDIA_TYPE_VIDEO,
"vp8");
ASSERT_TRUE(vp8);
RtpTransceiverInit init;
init.direction = RtpTransceiverDirection::kSendOnly;
RtpEncodingParameters encoding_parameters;
encoding_parameters.codec = vp8;
encoding_parameters.scalability_mode = "L1T3";
init.send_encodings.push_back(encoding_parameters);
auto transceiver_or_error =
local_pc_wrapper->pc()->AddTransceiver(cricket::MEDIA_TYPE_VIDEO, init);
ASSERT_TRUE(transceiver_or_error.ok());
rtc::scoped_refptr<RtpTransceiverInterface> video_transceiver =
transceiver_or_error.MoveValue();
RtpParameters parameters = video_transceiver->sender()->GetParameters();
parameters.encodings[0].scalability_mode = "L3T3";
RTCError error = video_transceiver->sender()->SetParameters(parameters);
EXPECT_EQ(error.type(), RTCErrorType::INVALID_MODIFICATION);
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
EncodingParametersCodecRemovedByNegotiationVideo) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
absl::optional<RtpCodecCapability> vp8 =
local_pc_wrapper->FindFirstSendCodecWithName(cricket::MEDIA_TYPE_VIDEO,
"vp8");
ASSERT_TRUE(vp8);
std::vector<RtpCodecCapability> not_vp8_codecs =
local_pc_wrapper->pc_factory()
->GetRtpSenderCapabilities(cricket::MEDIA_TYPE_VIDEO)
.codecs;
not_vp8_codecs.erase(
std::remove_if(not_vp8_codecs.begin(), not_vp8_codecs.end(),
[&](const auto& codec) {
return absl::EqualsIgnoreCase(codec.name, vp8->name);
}),
not_vp8_codecs.end());
RtpTransceiverInit init;
init.direction = RtpTransceiverDirection::kSendOnly;
RtpEncodingParameters encoding_parameters;
encoding_parameters.rid = "h";
encoding_parameters.codec = vp8;
encoding_parameters.scale_resolution_down_by = 2;
init.send_encodings.push_back(encoding_parameters);
encoding_parameters.rid = "f";
encoding_parameters.scale_resolution_down_by = 1;
init.send_encodings.push_back(encoding_parameters);
auto transceiver_or_error =
local_pc_wrapper->pc()->AddTransceiver(cricket::MEDIA_TYPE_VIDEO, init);
ASSERT_TRUE(transceiver_or_error.ok());
rtc::scoped_refptr<RtpTransceiverInterface> video_transceiver =
transceiver_or_error.MoveValue();
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
RtpParameters parameters = video_transceiver->sender()->GetParameters();
ASSERT_EQ(parameters.encodings.size(), 2u);
EXPECT_EQ(parameters.encodings[0].codec, vp8);
EXPECT_EQ(parameters.encodings[1].codec, vp8);
ASSERT_TRUE(video_transceiver->SetCodecPreferences(not_vp8_codecs).ok());
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
parameters = video_transceiver->sender()->GetParameters();
EXPECT_FALSE(parameters.encodings[0].codec);
EXPECT_FALSE(parameters.encodings[1].codec);
}
TEST_F(PeerConnectionEncodingsIntegrationTest,
AddTransceiverRejectsMixedCodecSimulcast) {
// Mixed Codec Simulcast is not yet supported, so we ensure that we reject
// such parameters.
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
absl::optional<RtpCodecCapability> vp8 =
local_pc_wrapper->FindFirstSendCodecWithName(cricket::MEDIA_TYPE_VIDEO,
"vp8");
ASSERT_TRUE(vp8);
absl::optional<RtpCodecCapability> vp9 =
local_pc_wrapper->FindFirstSendCodecWithName(cricket::MEDIA_TYPE_VIDEO,
"vp9");
RtpTransceiverInit init;
init.direction = RtpTransceiverDirection::kSendOnly;
RtpEncodingParameters encoding_parameters;
encoding_parameters.rid = "h";
encoding_parameters.codec = vp8;
encoding_parameters.scale_resolution_down_by = 2;
init.send_encodings.push_back(encoding_parameters);
encoding_parameters.rid = "f";
encoding_parameters.codec = vp9;
encoding_parameters.scale_resolution_down_by = 1;
init.send_encodings.push_back(encoding_parameters);
auto transceiver_or_error =
local_pc_wrapper->pc()->AddTransceiver(cricket::MEDIA_TYPE_VIDEO, init);
ASSERT_FALSE(transceiver_or_error.ok());
EXPECT_EQ(transceiver_or_error.error().type(),
RTCErrorType::UNSUPPORTED_OPERATION);
}
// Tests that use the standard path (specifying both `scalability_mode` and
// `scale_resolution_down_by` or `requested_resolution`) should pass for all
// codecs.
class PeerConnectionEncodingsIntegrationParameterizedTest
: public PeerConnectionEncodingsIntegrationTest,
public ::testing::WithParamInterface<std::string> {
public:
PeerConnectionEncodingsIntegrationParameterizedTest()
: codec_name_(GetParam()), mime_type_("video/" + codec_name_) {}
// Work-around for the fact that whether or not AV1 is supported is not known
// at compile-time so we have to skip tests early if missing.
// TODO(https://crbug.com/webrtc/15011): Increase availability of AV1 or make
// it possible to check support at compile-time.
bool SkipTestDueToAv1Missing(
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper) {
if (codec_name_ == "AV1" &&
!HasReceiverVideoCodecCapability(local_pc_wrapper, "AV1")) {
RTC_LOG(LS_WARNING) << "\n***\nAV1 is not available, skipping test.\n***";
return true;
}
return false;
}
protected:
const std::string codec_name_; // E.g. "VP9"
const std::string mime_type_; // E.g. "video/VP9"
};
TEST_P(PeerConnectionEncodingsIntegrationParameterizedTest, AllLayersInactive) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
if (SkipTestDueToAv1Missing(local_pc_wrapper)) {
return;
}
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
std::vector<cricket::SimulcastLayer> layers =
CreateLayers({"f", "h", "q"}, /*active=*/true);
rtc::scoped_refptr<RtpTransceiverInterface> transceiver =
AddTransceiverWithSimulcastLayers(local_pc_wrapper, remote_pc_wrapper,
layers);
std::vector<RtpCodecCapability> codecs =
GetCapabilitiesAndRestrictToCodec(remote_pc_wrapper, codec_name_);
transceiver->SetCodecPreferences(codecs);
// Standard mode and all layers inactive.
rtc::scoped_refptr<RtpSenderInterface> sender = transceiver->sender();
RtpParameters parameters = sender->GetParameters();
ASSERT_THAT(parameters.encodings, SizeIs(3));
parameters.encodings[0].scalability_mode = "L1T3";
parameters.encodings[0].scale_resolution_down_by = 1;
parameters.encodings[0].active = false;
parameters.encodings[1].active = false;
parameters.encodings[2].active = false;
sender->SetParameters(parameters);
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
// Ensure no media is flowing (1 second should be enough).
rtc::Thread::Current()->SleepMs(1000);
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(local_pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
ASSERT_THAT(outbound_rtps, SizeIs(3u));
EXPECT_EQ(*outbound_rtps[0]->bytes_sent, 0u);
EXPECT_EQ(*outbound_rtps[1]->bytes_sent, 0u);
EXPECT_EQ(*outbound_rtps[2]->bytes_sent, 0u);
}
// Configure 4:2:1 using `scale_resolution_down_by`.
TEST_P(PeerConnectionEncodingsIntegrationParameterizedTest, Simulcast) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
if (SkipTestDueToAv1Missing(local_pc_wrapper)) {
return;
}
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
std::vector<cricket::SimulcastLayer> layers =
CreateLayers({"q", "h", "f"}, /*active=*/true);
rtc::scoped_refptr<RtpTransceiverInterface> transceiver =
AddTransceiverWithSimulcastLayers(local_pc_wrapper, remote_pc_wrapper,
layers);
std::vector<RtpCodecCapability> codecs =
GetCapabilitiesAndRestrictToCodec(remote_pc_wrapper, codec_name_);
transceiver->SetCodecPreferences(codecs);
rtc::scoped_refptr<RtpSenderInterface> sender = transceiver->sender();
RtpParameters parameters = sender->GetParameters();
ASSERT_THAT(parameters.encodings, SizeIs(3));
parameters.encodings[0].scalability_mode = "L1T3";
parameters.encodings[0].scale_resolution_down_by = 4;
parameters.encodings[1].scalability_mode = "L1T3";
parameters.encodings[1].scale_resolution_down_by = 2;
parameters.encodings[2].scalability_mode = "L1T3";
parameters.encodings[2].scale_resolution_down_by = 1;
sender->SetParameters(parameters);
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
// GetParameters() does not report any fallback.
parameters = sender->GetParameters();
ASSERT_THAT(parameters.encodings, SizeIs(3));
EXPECT_THAT(parameters.encodings[0].scalability_mode,
Optional(std::string("L1T3")));
EXPECT_THAT(parameters.encodings[1].scalability_mode,
Optional(std::string("L1T3")));
EXPECT_THAT(parameters.encodings[2].scalability_mode,
Optional(std::string("L1T3")));
// Wait until media is flowing on all three layers.
// Ramp up time is needed before all three layers are sending.
ASSERT_TRUE_WAIT(HasOutboundRtpBytesSent(local_pc_wrapper, 3u),
kLongTimeoutForRampingUp.ms());
EXPECT_TRUE(OutboundRtpResolutionsAreLessThanOrEqualToExpectations(
local_pc_wrapper, {{"q", 320, 180}, {"h", 640, 360}, {"f", 1280, 720}}));
// Verify codec and scalability mode.
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(local_pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
ASSERT_THAT(outbound_rtps, SizeIs(3u));
EXPECT_THAT(GetCurrentCodecMimeType(report, *outbound_rtps[0]),
StrCaseEq(mime_type_));
EXPECT_THAT(GetCurrentCodecMimeType(report, *outbound_rtps[1]),
StrCaseEq(mime_type_));
EXPECT_THAT(GetCurrentCodecMimeType(report, *outbound_rtps[2]),
StrCaseEq(mime_type_));
EXPECT_THAT(*outbound_rtps[0]->scalability_mode, StrEq("L1T3"));
EXPECT_THAT(*outbound_rtps[1]->scalability_mode, StrEq("L1T3"));
EXPECT_THAT(*outbound_rtps[2]->scalability_mode, StrEq("L1T3"));
}
// Configure 4:2:1 using `requested_resolution`.
TEST_P(PeerConnectionEncodingsIntegrationParameterizedTest,
SimulcastWithRequestedResolution) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
if (SkipTestDueToAv1Missing(local_pc_wrapper)) {
return;
}
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
std::vector<cricket::SimulcastLayer> layers =
CreateLayers({"q", "h", "f"}, /*active=*/true);
rtc::scoped_refptr<RtpTransceiverInterface> transceiver =
AddTransceiverWithSimulcastLayers(local_pc_wrapper, remote_pc_wrapper,
layers);
std::vector<RtpCodecCapability> codecs =
GetCapabilitiesAndRestrictToCodec(remote_pc_wrapper, codec_name_);
transceiver->SetCodecPreferences(codecs);
rtc::scoped_refptr<RtpSenderInterface> sender = transceiver->sender();
RtpParameters parameters = sender->GetParameters();
ASSERT_THAT(parameters.encodings, SizeIs(3));
parameters.encodings[0].scalability_mode = "L1T3";
parameters.encodings[0].requested_resolution = {.width = 320, .height = 180};
parameters.encodings[1].scalability_mode = "L1T3";
parameters.encodings[1].requested_resolution = {.width = 640, .height = 360};
parameters.encodings[2].scalability_mode = "L1T3";
parameters.encodings[2].requested_resolution = {.width = 1280, .height = 720};
sender->SetParameters(parameters);
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
// GetParameters() does not report any fallback.
parameters = sender->GetParameters();
ASSERT_THAT(parameters.encodings, SizeIs(3));
EXPECT_THAT(parameters.encodings[0].scalability_mode,
Optional(std::string("L1T3")));
EXPECT_THAT(parameters.encodings[1].scalability_mode,
Optional(std::string("L1T3")));
EXPECT_THAT(parameters.encodings[2].scalability_mode,
Optional(std::string("L1T3")));
// Wait until media is flowing on all three layers.
// Ramp up time is needed before all three layers are sending.
ASSERT_TRUE_WAIT(HasOutboundRtpBytesSent(local_pc_wrapper, 3u),
kLongTimeoutForRampingUp.ms());
EXPECT_TRUE(OutboundRtpResolutionsAreLessThanOrEqualToExpectations(
local_pc_wrapper, {{"q", 320, 180}, {"h", 640, 360}, {"f", 1280, 720}}));
// Verify codec and scalability mode.
rtc::scoped_refptr<const RTCStatsReport> report = GetStats(local_pc_wrapper);
std::vector<const RTCOutboundRtpStreamStats*> outbound_rtps =
report->GetStatsOfType<RTCOutboundRtpStreamStats>();
ASSERT_THAT(outbound_rtps, SizeIs(3u));
EXPECT_THAT(GetCurrentCodecMimeType(report, *outbound_rtps[0]),
StrCaseEq(mime_type_));
EXPECT_THAT(GetCurrentCodecMimeType(report, *outbound_rtps[1]),
StrCaseEq(mime_type_));
EXPECT_THAT(GetCurrentCodecMimeType(report, *outbound_rtps[2]),
StrCaseEq(mime_type_));
EXPECT_THAT(*outbound_rtps[0]->scalability_mode, StrEq("L1T3"));
EXPECT_THAT(*outbound_rtps[1]->scalability_mode, StrEq("L1T3"));
EXPECT_THAT(*outbound_rtps[2]->scalability_mode, StrEq("L1T3"));
}
TEST_P(PeerConnectionEncodingsIntegrationParameterizedTest,
SimulcastEncodingStopWhenRtpEncodingChangeToInactive) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
if (SkipTestDueToAv1Missing(local_pc_wrapper)) {
return;
}
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
std::vector<cricket::SimulcastLayer> layers =
CreateLayers({"q", "h", "f"}, /*active=*/true);
rtc::scoped_refptr<RtpTransceiverInterface> transceiver =
AddTransceiverWithSimulcastLayers(local_pc_wrapper, remote_pc_wrapper,
layers);
std::vector<RtpCodecCapability> codecs =
GetCapabilitiesAndRestrictToCodec(local_pc_wrapper, codec_name_);
transceiver->SetCodecPreferences(codecs);
rtc::scoped_refptr<RtpSenderInterface> sender = transceiver->sender();
RtpParameters parameters = sender->GetParameters();
ASSERT_THAT(parameters.encodings, SizeIs(3));
ASSERT_EQ(parameters.encodings[0].rid, "q");
parameters.encodings[0].scalability_mode = "L1T3";
parameters.encodings[0].scale_resolution_down_by = 4;
ASSERT_EQ(parameters.encodings[1].rid, "h");
parameters.encodings[1].scalability_mode = "L1T3";
parameters.encodings[1].scale_resolution_down_by = 2;
ASSERT_EQ(parameters.encodings[2].rid, "f");
parameters.encodings[2].scalability_mode = "L1T3";
parameters.encodings[2].scale_resolution_down_by = 1;
sender->SetParameters(parameters);
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
ASSERT_TRUE_WAIT(EncodedFrames(local_pc_wrapper, "f") > 1,
kLongTimeoutForRampingUp.ms());
// Switch higest layer to Inactive.
parameters = sender->GetParameters();
ASSERT_THAT(parameters.encodings, SizeIs(3));
parameters.encodings[2].active = false;
sender->SetParameters(parameters);
ASSERT_TRUE_WAIT(!EncodingIsActive(local_pc_wrapper, "f"),
kDefaultTimeout.ms());
int encoded_frames_f = EncodedFrames(local_pc_wrapper, "f");
int encoded_frames_h = EncodedFrames(local_pc_wrapper, "h");
int encoded_frames_q = EncodedFrames(local_pc_wrapper, "q");
// Wait until the encoder has encoded another 10 frames on lower layers.
ASSERT_TRUE_WAIT(EncodedFrames(local_pc_wrapper, "q") > encoded_frames_q + 10,
kDefaultTimeout.ms());
ASSERT_TRUE_WAIT(EncodedFrames(local_pc_wrapper, "h") > encoded_frames_h + 10,
kDefaultTimeout.ms());
EXPECT_LE(EncodedFrames(local_pc_wrapper, "f") - encoded_frames_f, 2);
}
TEST_P(PeerConnectionEncodingsIntegrationParameterizedTest,
RequestedResolutionDownscaleAndThenUpscale) {
rtc::scoped_refptr<PeerConnectionTestWrapper> local_pc_wrapper = CreatePc();
if (SkipTestDueToAv1Missing(local_pc_wrapper)) {
return;
}
rtc::scoped_refptr<PeerConnectionTestWrapper> remote_pc_wrapper = CreatePc();
ExchangeIceCandidates(local_pc_wrapper, remote_pc_wrapper);
std::vector<cricket::SimulcastLayer> layers =
CreateLayers({"f"}, /*active=*/true);
// This transceiver receives a 1280x720 source.
rtc::scoped_refptr<RtpTransceiverInterface> transceiver =
AddTransceiverWithSimulcastLayers(local_pc_wrapper, remote_pc_wrapper,
layers);
std::vector<RtpCodecCapability> codecs =
GetCapabilitiesAndRestrictToCodec(remote_pc_wrapper, codec_name_);
transceiver->SetCodecPreferences(codecs);
NegotiateWithSimulcastTweaks(local_pc_wrapper, remote_pc_wrapper);
local_pc_wrapper->WaitForConnection();
remote_pc_wrapper->WaitForConnection();
// Request 640x360, which is the same as scaling down by 2.
rtc::scoped_refptr<RtpSenderInterface> sender = transceiver->sender();
RtpParameters parameters = sender->GetParameters();
ASSERT_THAT(parameters.encodings, SizeIs(1));
parameters.encodings[0].scalability_mode = "L1T3";
parameters.encodings[0].requested_resolution = {.width = 640, .height = 360};
sender->SetParameters(parameters);
// Confirm 640x360 is sent.
ASSERT_TRUE_WAIT(GetEncodingResolution(local_pc_wrapper) ==
(Resolution{.width = 640, .height = 360}),
kLongTimeoutForRampingUp.ms());
// Test coverage for https://crbug.com/webrtc/361477261:
// Due initial frame dropping, OnFrameDroppedDueToSize() should have created
// some resolution restrictions by now. With 720p input frame, restriction is
// 540p which is not observable when sending 360p, but it prevents us from
// immediately sending 720p. Restrictions will be lifted after a few seconds
// (when good QP is reported by QualityScaler) and 720p should be sent. The
// bug was not reconfiguring the encoder when restrictions were updated so the
// restrictions at the time of the SetParameter() call were made indefinite.
// Request the full 1280x720 resolution.
parameters = sender->GetParameters();
parameters.encodings[0].requested_resolution = {.width = 1280, .height = 720};
sender->SetParameters(parameters);
// Confirm 1280x720 is sent.
ASSERT_TRUE_WAIT(GetEncodingResolution(local_pc_wrapper) ==
(Resolution{.width = 1280, .height = 720}),
kLongTimeoutForRampingUp.ms());
}
INSTANTIATE_TEST_SUITE_P(StandardPath,
PeerConnectionEncodingsIntegrationParameterizedTest,
::testing::Values("VP8",
"VP9",
#if defined(WEBRTC_USE_H264)
"H264",
#endif // defined(WEBRTC_USE_H264)
"AV1"),
StringParamToString());
} // namespace webrtc