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webrtc / src / 43c108b7e9a7436d43e0eb36f5898a432b4d840e / . / pc / media_session_unittest.cc
blob: ba4db0a674b53388337b8b58a92c8487231ee094 [file] [log] [blame]
/*
* Copyright 2004 The WebRTC project authors. All Rights Reserved.
*
* Use of this source code is governed by a BSD-style license
* that can be found in the LICENSE file in the root of the source
* tree. An additional intellectual property rights grant can be found
* in the file PATENTS. All contributing project authors may
* be found in the AUTHORS file in the root of the source tree.
*/
#include "pc/media_session.h"
#include <algorithm>
#include <memory>
#include <string>
#include <utility>
#include <vector>
#include "absl/algorithm/container.h"
#include "absl/memory/memory.h"
#include "absl/strings/match.h"
#include "media/base/codec.h"
#include "media/base/test_utils.h"
#include "media/sctp/sctp_transport_internal.h"
#include "p2p/base/p2p_constants.h"
#include "p2p/base/transport_description.h"
#include "p2p/base/transport_info.h"
#include "pc/rtp_media_utils.h"
#include "pc/srtp_filter.h"
#include "rtc_base/checks.h"
#include "rtc_base/fake_ssl_identity.h"
#include "rtc_base/gunit.h"
#include "rtc_base/message_digest.h"
#include "rtc_base/ssl_adapter.h"
#include "rtc_base/strings/string_builder.h"
#include "rtc_base/unique_id_generator.h"
#include "test/gmock.h"
#define ASSERT_CRYPTO(cd, s, cs) \
ASSERT_EQ(s, cd->cryptos().size()); \
ASSERT_EQ(cs, cd->cryptos()[0].cipher_suite)
typedef std::vector<cricket::Candidate> Candidates;
using cricket::AudioCodec;
using cricket::AudioContentDescription;
using cricket::ContentInfo;
using cricket::CryptoParamsVec;
using cricket::GetFirstAudioContent;
using cricket::GetFirstAudioContentDescription;
using cricket::GetFirstDataContent;
using cricket::GetFirstRtpDataContentDescription;
using cricket::GetFirstVideoContent;
using cricket::GetFirstVideoContentDescription;
using cricket::kAutoBandwidth;
using cricket::MEDIA_TYPE_AUDIO;
using cricket::MEDIA_TYPE_DATA;
using cricket::MEDIA_TYPE_VIDEO;
using cricket::MediaContentDescription;
using cricket::MediaDescriptionOptions;
using cricket::MediaProtocolType;
using cricket::MediaSessionDescriptionFactory;
using cricket::MediaSessionOptions;
using cricket::MediaType;
using cricket::RidDescription;
using cricket::RidDirection;
using cricket::RtpDataCodec;
using cricket::RtpDataContentDescription;
using cricket::SctpDataContentDescription;
using cricket::SEC_DISABLED;
using cricket::SEC_ENABLED;
using cricket::SEC_REQUIRED;
using cricket::SessionDescription;
using cricket::SimulcastDescription;
using cricket::SimulcastLayer;
using cricket::SimulcastLayerList;
using cricket::SsrcGroup;
using cricket::StreamParams;
using cricket::StreamParamsVec;
using cricket::TransportDescription;
using cricket::TransportDescriptionFactory;
using cricket::TransportInfo;
using cricket::VideoCodec;
using cricket::VideoContentDescription;
using rtc::CS_AEAD_AES_128_GCM;
using rtc::CS_AEAD_AES_256_GCM;
using rtc::CS_AES_CM_128_HMAC_SHA1_32;
using rtc::CS_AES_CM_128_HMAC_SHA1_80;
using rtc::UniqueRandomIdGenerator;
using ::testing::Contains;
using ::testing::Each;
using ::testing::ElementsAre;
using ::testing::ElementsAreArray;
using ::testing::Eq;
using ::testing::Field;
using ::testing::IsEmpty;
using ::testing::IsFalse;
using ::testing::Ne;
using ::testing::Not;
using ::testing::Pointwise;
using ::testing::SizeIs;
using webrtc::RtpExtension;
using webrtc::RtpTransceiverDirection;
static const AudioCodec kAudioCodecs1[] = {
AudioCodec(103, "ISAC", 16000, -1, 1),
AudioCodec(102, "iLBC", 8000, 13300, 1),
AudioCodec(0, "PCMU", 8000, 64000, 1),
AudioCodec(8, "PCMA", 8000, 64000, 1),
AudioCodec(117, "red", 8000, 0, 1),
AudioCodec(107, "CN", 48000, 0, 1)};
static const AudioCodec kAudioCodecs2[] = {
AudioCodec(126, "foo", 16000, 22000, 1),
AudioCodec(0, "PCMU", 8000, 64000, 1),
AudioCodec(127, "iLBC", 8000, 13300, 1),
};
static const AudioCodec kAudioCodecsAnswer[] = {
AudioCodec(102, "iLBC", 8000, 13300, 1),
AudioCodec(0, "PCMU", 8000, 64000, 1),
};
static const VideoCodec kVideoCodecs1[] = {VideoCodec(96, "H264-SVC"),
VideoCodec(97, "H264")};
static const VideoCodec kVideoCodecs1Reverse[] = {VideoCodec(97, "H264"),
VideoCodec(96, "H264-SVC")};
static const VideoCodec kVideoCodecs2[] = {VideoCodec(126, "H264"),
VideoCodec(127, "H263")};
static const VideoCodec kVideoCodecsAnswer[] = {VideoCodec(97, "H264")};
static const RtpDataCodec kDataCodecs1[] = {RtpDataCodec(98, "binary-data"),
RtpDataCodec(99, "utf8-text")};
static const RtpDataCodec kDataCodecs2[] = {RtpDataCodec(126, "binary-data"),
RtpDataCodec(127, "utf8-text")};
static const RtpDataCodec kDataCodecsAnswer[] = {
RtpDataCodec(98, "binary-data"), RtpDataCodec(99, "utf8-text")};
static const RtpExtension kAudioRtpExtension1[] = {
RtpExtension("urn:ietf:params:rtp-hdrext:ssrc-audio-level", 8),
RtpExtension("http://google.com/testing/audio_something", 10),
};
static const RtpExtension kAudioRtpExtensionEncrypted1[] = {
RtpExtension("urn:ietf:params:rtp-hdrext:ssrc-audio-level", 8),
RtpExtension("http://google.com/testing/audio_something", 10),
RtpExtension("urn:ietf:params:rtp-hdrext:ssrc-audio-level", 12, true),
};
static const RtpExtension kAudioRtpExtension2[] = {
RtpExtension("urn:ietf:params:rtp-hdrext:ssrc-audio-level", 2),
RtpExtension("http://google.com/testing/audio_something_else", 8),
RtpExtension("http://google.com/testing/both_audio_and_video", 7),
};
static const RtpExtension kAudioRtpExtension3[] = {
RtpExtension("http://google.com/testing/audio_something", 2),
RtpExtension("http://google.com/testing/both_audio_and_video", 3),
};
static const RtpExtension kAudioRtpExtension3ForEncryption[] = {
RtpExtension("http://google.com/testing/audio_something", 2),
// Use RTP extension that supports encryption.
RtpExtension("urn:ietf:params:rtp-hdrext:toffset", 3),
};
static const RtpExtension kAudioRtpExtension3ForEncryptionOffer[] = {
RtpExtension("http://google.com/testing/audio_something", 2),
RtpExtension("urn:ietf:params:rtp-hdrext:toffset", 3),
RtpExtension("urn:ietf:params:rtp-hdrext:toffset", 14, true),
};
static const RtpExtension kAudioRtpExtensionAnswer[] = {
RtpExtension("urn:ietf:params:rtp-hdrext:ssrc-audio-level", 8),
};
static const RtpExtension kAudioRtpExtensionEncryptedAnswer[] = {
RtpExtension("urn:ietf:params:rtp-hdrext:ssrc-audio-level", 12, true),
};
static const RtpExtension kVideoRtpExtension1[] = {
RtpExtension("urn:ietf:params:rtp-hdrext:toffset", 14),
RtpExtension("http://google.com/testing/video_something", 13),
};
static const RtpExtension kVideoRtpExtensionEncrypted1[] = {
RtpExtension("urn:ietf:params:rtp-hdrext:toffset", 14),
RtpExtension("http://google.com/testing/video_something", 13),
RtpExtension("urn:ietf:params:rtp-hdrext:toffset", 11, true),
};
static const RtpExtension kVideoRtpExtension2[] = {
RtpExtension("urn:ietf:params:rtp-hdrext:toffset", 2),
RtpExtension("http://google.com/testing/video_something_else", 14),
RtpExtension("http://google.com/testing/both_audio_and_video", 7),
};
static const RtpExtension kVideoRtpExtension3[] = {
RtpExtension("http://google.com/testing/video_something", 4),
RtpExtension("http://google.com/testing/both_audio_and_video", 5),
};
static const RtpExtension kVideoRtpExtension3ForEncryption[] = {
RtpExtension("http://google.com/testing/video_something", 4),
// Use RTP extension that supports encryption.
RtpExtension("urn:ietf:params:rtp-hdrext:toffset", 5),
};
static const RtpExtension kVideoRtpExtensionAnswer[] = {
RtpExtension("urn:ietf:params:rtp-hdrext:toffset", 14),
};
static const RtpExtension kVideoRtpExtensionEncryptedAnswer[] = {
RtpExtension("urn:ietf:params:rtp-hdrext:toffset", 11, true),
};
static const RtpExtension kRtpExtensionTransportSequenceNumber01[] = {
RtpExtension("http://www.ietf.org/id/"
"draft-holmer-rmcat-transport-wide-cc-extensions-01",
1),
};
static const RtpExtension kRtpExtensionTransportSequenceNumber01And02[] = {
RtpExtension("http://www.ietf.org/id/"
"draft-holmer-rmcat-transport-wide-cc-extensions-01",
1),
RtpExtension(
"http://www.webrtc.org/experiments/rtp-hdrext/transport-wide-cc-02",
2),
};
static const RtpExtension kRtpExtensionTransportSequenceNumber02[] = {
RtpExtension(
"http://www.webrtc.org/experiments/rtp-hdrext/transport-wide-cc-02",
2),
};
static const RtpExtension kRtpExtensionGenericFrameDescriptorUri00[] = {
RtpExtension("http://www.webrtc.org/experiments/rtp-hdrext/"
"generic-frame-descriptor-00",
3),
};
static const uint32_t kSimulcastParamsSsrc[] = {10, 11, 20, 21, 30, 31};
static const uint32_t kSimSsrc[] = {10, 20, 30};
static const uint32_t kFec1Ssrc[] = {10, 11};
static const uint32_t kFec2Ssrc[] = {20, 21};
static const uint32_t kFec3Ssrc[] = {30, 31};
static const char kMediaStream1[] = "stream_1";
static const char kMediaStream2[] = "stream_2";
static const char kVideoTrack1[] = "video_1";
static const char kVideoTrack2[] = "video_2";
static const char kAudioTrack1[] = "audio_1";
static const char kAudioTrack2[] = "audio_2";
static const char kAudioTrack3[] = "audio_3";
static const char kDataTrack1[] = "data_1";
static const char kDataTrack2[] = "data_2";
static const char kDataTrack3[] = "data_3";
static const char* kMediaProtocols[] = {"RTP/AVP", "RTP/SAVP", "RTP/AVPF",
"RTP/SAVPF"};
static const char* kMediaProtocolsDtls[] = {
"TCP/TLS/RTP/SAVPF", "TCP/TLS/RTP/SAVP", "UDP/TLS/RTP/SAVPF",
"UDP/TLS/RTP/SAVP"};
// SRTP cipher name negotiated by the tests. This must be updated if the
// default changes.
static const char* kDefaultSrtpCryptoSuite = CS_AES_CM_128_HMAC_SHA1_80;
static const char* kDefaultSrtpCryptoSuiteGcm = CS_AEAD_AES_256_GCM;
// These constants are used to make the code using "AddMediaDescriptionOptions"
// more readable.
static constexpr bool kStopped = true;
static constexpr bool kActive = false;
static bool IsMediaContentOfType(const ContentInfo* content,
MediaType media_type) {
RTC_DCHECK(content);
return content->media_description()->type() == media_type;
}
static RtpTransceiverDirection GetMediaDirection(const ContentInfo* content) {
RTC_DCHECK(content);
return content->media_description()->direction();
}
static void AddRtxCodec(const VideoCodec& rtx_codec,
std::vector<VideoCodec>* codecs) {
ASSERT_FALSE(cricket::FindCodecById(*codecs, rtx_codec.id));
codecs->push_back(rtx_codec);
}
template <class T>
static std::vector<std::string> GetCodecNames(const std::vector<T>& codecs) {
std::vector<std::string> codec_names;
codec_names.reserve(codecs.size());
for (const auto& codec : codecs) {
codec_names.push_back(codec.name);
}
return codec_names;
}
// This is used for test only. MIDs are not the identification of the
// MediaDescriptionOptions since some end points may not support MID and the SDP
// may not contain 'mid'.
std::vector<MediaDescriptionOptions>::iterator FindFirstMediaDescriptionByMid(
const std::string& mid,
MediaSessionOptions* opts) {
return absl::c_find_if(
opts->media_description_options,
[&mid](const MediaDescriptionOptions& t) { return t.mid == mid; });
}
std::vector<MediaDescriptionOptions>::const_iterator
FindFirstMediaDescriptionByMid(const std::string& mid,
const MediaSessionOptions& opts) {
return absl::c_find_if(
opts.media_description_options,
[&mid](const MediaDescriptionOptions& t) { return t.mid == mid; });
}
// Add a media section to the |session_options|.
static void AddMediaDescriptionOptions(MediaType type,
const std::string& mid,
RtpTransceiverDirection direction,
bool stopped,
MediaSessionOptions* opts) {
opts->media_description_options.push_back(
MediaDescriptionOptions(type, mid, direction, stopped));
}
static void AddAudioVideoSections(RtpTransceiverDirection direction,
MediaSessionOptions* opts) {
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio", direction, kActive,
opts);
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video", direction, kActive,
opts);
}
static void AddDataSection(cricket::DataChannelType dct,
RtpTransceiverDirection direction,
MediaSessionOptions* opts) {
opts->data_channel_type = dct;
AddMediaDescriptionOptions(MEDIA_TYPE_DATA, "data", direction, kActive, opts);
}
static void AttachSenderToMediaDescriptionOptions(
const std::string& mid,
MediaType type,
const std::string& track_id,
const std::vector<std::string>& stream_ids,
const std::vector<RidDescription>& rids,
const SimulcastLayerList& simulcast_layers,
int num_sim_layer,
MediaSessionOptions* session_options) {
auto it = FindFirstMediaDescriptionByMid(mid, session_options);
switch (type) {
case MEDIA_TYPE_AUDIO:
it->AddAudioSender(track_id, stream_ids);
break;
case MEDIA_TYPE_VIDEO:
it->AddVideoSender(track_id, stream_ids, rids, simulcast_layers,
num_sim_layer);
break;
case MEDIA_TYPE_DATA:
RTC_CHECK(stream_ids.size() == 1U);
it->AddRtpDataChannel(track_id, stream_ids[0]);
break;
default:
RTC_NOTREACHED();
}
}
static void AttachSenderToMediaDescriptionOptions(
const std::string& mid,
MediaType type,
const std::string& track_id,
const std::vector<std::string>& stream_ids,
int num_sim_layer,
MediaSessionOptions* session_options) {
AttachSenderToMediaDescriptionOptions(mid, type, track_id, stream_ids, {},
SimulcastLayerList(), num_sim_layer,
session_options);
}
static void DetachSenderFromMediaSection(const std::string& mid,
const std::string& track_id,
MediaSessionOptions* session_options) {
std::vector<cricket::SenderOptions>& sender_options_list =
FindFirstMediaDescriptionByMid(mid, session_options)->sender_options;
auto sender_it =
absl::c_find_if(sender_options_list,
[track_id](const cricket::SenderOptions& sender_options) {
return sender_options.track_id == track_id;
});
RTC_DCHECK(sender_it != sender_options_list.end());
sender_options_list.erase(sender_it);
}
// Helper function used to create a default MediaSessionOptions for Plan B SDP.
// (https://tools.ietf.org/html/draft-uberti-rtcweb-plan-00).
static MediaSessionOptions CreatePlanBMediaSessionOptions() {
MediaSessionOptions session_options;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio",
RtpTransceiverDirection::kRecvOnly, kActive,
&session_options);
return session_options;
}
// prefers GCM SDES crypto suites by removing non-GCM defaults.
void PreferGcmCryptoParameters(CryptoParamsVec* cryptos) {
cryptos->erase(
std::remove_if(cryptos->begin(), cryptos->end(),
[](const cricket::CryptoParams& crypto) {
return crypto.cipher_suite != CS_AEAD_AES_256_GCM &&
crypto.cipher_suite != CS_AEAD_AES_128_GCM;
}),
cryptos->end());
}
// TODO(zhihuang): Most of these tests were written while MediaSessionOptions
// was designed for Plan B SDP, where only one audio "m=" section and one video
// "m=" section could be generated, and ordering couldn't be controlled. Many of
// these tests may be obsolete as a result, and should be refactored or removed.
class MediaSessionDescriptionFactoryTest : public ::testing::Test {
public:
MediaSessionDescriptionFactoryTest()
: f1_(&tdf1_, &ssrc_generator1), f2_(&tdf2_, &ssrc_generator2) {
f1_.set_audio_codecs(MAKE_VECTOR(kAudioCodecs1),
MAKE_VECTOR(kAudioCodecs1));
f1_.set_video_codecs(MAKE_VECTOR(kVideoCodecs1),
MAKE_VECTOR(kVideoCodecs1));
f1_.set_rtp_data_codecs(MAKE_VECTOR(kDataCodecs1));
f2_.set_audio_codecs(MAKE_VECTOR(kAudioCodecs2),
MAKE_VECTOR(kAudioCodecs2));
f2_.set_video_codecs(MAKE_VECTOR(kVideoCodecs2),
MAKE_VECTOR(kVideoCodecs2));
f2_.set_rtp_data_codecs(MAKE_VECTOR(kDataCodecs2));
tdf1_.set_certificate(rtc::RTCCertificate::Create(
std::unique_ptr<rtc::SSLIdentity>(new rtc::FakeSSLIdentity("id1"))));
tdf2_.set_certificate(rtc::RTCCertificate::Create(
std::unique_ptr<rtc::SSLIdentity>(new rtc::FakeSSLIdentity("id2"))));
}
// Create a video StreamParamsVec object with:
// - one video stream with 3 simulcast streams and FEC,
StreamParamsVec CreateComplexVideoStreamParamsVec() {
SsrcGroup sim_group("SIM", MAKE_VECTOR(kSimSsrc));
SsrcGroup fec_group1("FEC", MAKE_VECTOR(kFec1Ssrc));
SsrcGroup fec_group2("FEC", MAKE_VECTOR(kFec2Ssrc));
SsrcGroup fec_group3("FEC", MAKE_VECTOR(kFec3Ssrc));
std::vector<SsrcGroup> ssrc_groups;
ssrc_groups.push_back(sim_group);
ssrc_groups.push_back(fec_group1);
ssrc_groups.push_back(fec_group2);
ssrc_groups.push_back(fec_group3);
StreamParams simulcast_params;
simulcast_params.id = kVideoTrack1;
simulcast_params.ssrcs = MAKE_VECTOR(kSimulcastParamsSsrc);
simulcast_params.ssrc_groups = ssrc_groups;
simulcast_params.cname = "Video_SIM_FEC";
simulcast_params.set_stream_ids({kMediaStream1});
StreamParamsVec video_streams;
video_streams.push_back(simulcast_params);
return video_streams;
}
bool CompareCryptoParams(const CryptoParamsVec& c1,
const CryptoParamsVec& c2) {
if (c1.size() != c2.size())
return false;
for (size_t i = 0; i < c1.size(); ++i)
if (c1[i].tag != c2[i].tag || c1[i].cipher_suite != c2[i].cipher_suite ||
c1[i].key_params != c2[i].key_params ||
c1[i].session_params != c2[i].session_params)
return false;
return true;
}
// Returns true if the transport info contains "renomination" as an
// ICE option.
bool GetIceRenomination(const TransportInfo* transport_info) {
return absl::c_linear_search(transport_info->description.transport_options,
"renomination");
}
void TestTransportInfo(bool offer,
const MediaSessionOptions& options,
bool has_current_desc) {
const std::string current_audio_ufrag = "current_audio_ufrag";
const std::string current_audio_pwd = "current_audio_pwd";
const std::string current_video_ufrag = "current_video_ufrag";
const std::string current_video_pwd = "current_video_pwd";
const std::string current_data_ufrag = "current_data_ufrag";
const std::string current_data_pwd = "current_data_pwd";
std::unique_ptr<SessionDescription> current_desc;
std::unique_ptr<SessionDescription> desc;
if (has_current_desc) {
current_desc = std::make_unique<SessionDescription>();
current_desc->AddTransportInfo(TransportInfo(
"audio",
TransportDescription(current_audio_ufrag, current_audio_pwd)));
current_desc->AddTransportInfo(TransportInfo(
"video",
TransportDescription(current_video_ufrag, current_video_pwd)));
current_desc->AddTransportInfo(TransportInfo(
"data", TransportDescription(current_data_ufrag, current_data_pwd)));
}
if (offer) {
desc = f1_.CreateOffer(options, current_desc.get());
} else {
std::unique_ptr<SessionDescription> offer;
offer = f1_.CreateOffer(options, NULL);
desc = f1_.CreateAnswer(offer.get(), options, current_desc.get());
}
ASSERT_TRUE(desc.get() != NULL);
const TransportInfo* ti_audio = desc->GetTransportInfoByName("audio");
if (options.has_audio()) {
EXPECT_TRUE(ti_audio != NULL);
if (has_current_desc) {
EXPECT_EQ(current_audio_ufrag, ti_audio->description.ice_ufrag);
EXPECT_EQ(current_audio_pwd, ti_audio->description.ice_pwd);
} else {
EXPECT_EQ(static_cast<size_t>(cricket::ICE_UFRAG_LENGTH),
ti_audio->description.ice_ufrag.size());
EXPECT_EQ(static_cast<size_t>(cricket::ICE_PWD_LENGTH),
ti_audio->description.ice_pwd.size());
}
auto media_desc_options_it =
FindFirstMediaDescriptionByMid("audio", options);
EXPECT_EQ(
media_desc_options_it->transport_options.enable_ice_renomination,
GetIceRenomination(ti_audio));
EXPECT_EQ(media_desc_options_it->transport_options.opaque_parameters,
ti_audio->description.opaque_parameters);
} else {
EXPECT_TRUE(ti_audio == NULL);
}
const TransportInfo* ti_video = desc->GetTransportInfoByName("video");
if (options.has_video()) {
EXPECT_TRUE(ti_video != NULL);
auto media_desc_options_it =
FindFirstMediaDescriptionByMid("video", options);
if (options.bundle_enabled) {
EXPECT_EQ(ti_audio->description.ice_ufrag,
ti_video->description.ice_ufrag);
EXPECT_EQ(ti_audio->description.ice_pwd, ti_video->description.ice_pwd);
EXPECT_EQ(ti_audio->description.opaque_parameters,
ti_video->description.opaque_parameters);
} else {
if (has_current_desc) {
EXPECT_EQ(current_video_ufrag, ti_video->description.ice_ufrag);
EXPECT_EQ(current_video_pwd, ti_video->description.ice_pwd);
} else {
EXPECT_EQ(static_cast<size_t>(cricket::ICE_UFRAG_LENGTH),
ti_video->description.ice_ufrag.size());
EXPECT_EQ(static_cast<size_t>(cricket::ICE_PWD_LENGTH),
ti_video->description.ice_pwd.size());
}
EXPECT_EQ(media_desc_options_it->transport_options.opaque_parameters,
ti_video->description.opaque_parameters);
}
EXPECT_EQ(
media_desc_options_it->transport_options.enable_ice_renomination,
GetIceRenomination(ti_video));
} else {
EXPECT_TRUE(ti_video == NULL);
}
const TransportInfo* ti_data = desc->GetTransportInfoByName("data");
if (options.has_data()) {
EXPECT_TRUE(ti_data != NULL);
if (options.bundle_enabled) {
EXPECT_EQ(ti_audio->description.ice_ufrag,
ti_data->description.ice_ufrag);
EXPECT_EQ(ti_audio->description.ice_pwd, ti_data->description.ice_pwd);
} else {
if (has_current_desc) {
EXPECT_EQ(current_data_ufrag, ti_data->description.ice_ufrag);
EXPECT_EQ(current_data_pwd, ti_data->description.ice_pwd);
} else {
EXPECT_EQ(static_cast<size_t>(cricket::ICE_UFRAG_LENGTH),
ti_data->description.ice_ufrag.size());
EXPECT_EQ(static_cast<size_t>(cricket::ICE_PWD_LENGTH),
ti_data->description.ice_pwd.size());
}
}
auto media_desc_options_it =
FindFirstMediaDescriptionByMid("data", options);
EXPECT_EQ(
media_desc_options_it->transport_options.enable_ice_renomination,
GetIceRenomination(ti_data));
} else {
EXPECT_TRUE(ti_data == NULL);
}
}
void TestCryptoWithBundle(bool offer) {
f1_.set_secure(SEC_ENABLED);
MediaSessionOptions options;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &options);
AddDataSection(cricket::DCT_RTP, RtpTransceiverDirection::kRecvOnly,
&options);
std::unique_ptr<SessionDescription> ref_desc;
std::unique_ptr<SessionDescription> desc;
if (offer) {
options.bundle_enabled = false;
ref_desc = f1_.CreateOffer(options, NULL);
options.bundle_enabled = true;
desc = f1_.CreateOffer(options, ref_desc.get());
} else {
options.bundle_enabled = true;
ref_desc = f1_.CreateOffer(options, NULL);
desc = f1_.CreateAnswer(ref_desc.get(), options, NULL);
}
ASSERT_TRUE(desc);
const cricket::MediaContentDescription* audio_media_desc =
desc->GetContentDescriptionByName("audio");
ASSERT_TRUE(audio_media_desc);
const cricket::MediaContentDescription* video_media_desc =
desc->GetContentDescriptionByName("video");
ASSERT_TRUE(video_media_desc);
EXPECT_TRUE(CompareCryptoParams(audio_media_desc->cryptos(),
video_media_desc->cryptos()));
EXPECT_EQ(1u, audio_media_desc->cryptos().size());
EXPECT_EQ(kDefaultSrtpCryptoSuite,
audio_media_desc->cryptos()[0].cipher_suite);
// Verify the selected crypto is one from the reference audio
// media content.
const cricket::MediaContentDescription* ref_audio_media_desc =
ref_desc->GetContentDescriptionByName("audio");
bool found = false;
for (size_t i = 0; i < ref_audio_media_desc->cryptos().size(); ++i) {
if (ref_audio_media_desc->cryptos()[i].Matches(
audio_media_desc->cryptos()[0])) {
found = true;
break;
}
}
EXPECT_TRUE(found);
}
// This test that the audio and video media direction is set to
// |expected_direction_in_answer| in an answer if the offer direction is set
// to |direction_in_offer| and the answer is willing to both send and receive.
void TestMediaDirectionInAnswer(
RtpTransceiverDirection direction_in_offer,
RtpTransceiverDirection expected_direction_in_answer) {
MediaSessionOptions offer_opts;
AddAudioVideoSections(direction_in_offer, &offer_opts);
std::unique_ptr<SessionDescription> offer =
f1_.CreateOffer(offer_opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
ContentInfo* ac_offer = offer->GetContentByName("audio");
ASSERT_TRUE(ac_offer != NULL);
ContentInfo* vc_offer = offer->GetContentByName("video");
ASSERT_TRUE(vc_offer != NULL);
MediaSessionOptions answer_opts;
AddAudioVideoSections(RtpTransceiverDirection::kSendRecv, &answer_opts);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), answer_opts, NULL);
const AudioContentDescription* acd_answer =
GetFirstAudioContentDescription(answer.get());
EXPECT_EQ(expected_direction_in_answer, acd_answer->direction());
const VideoContentDescription* vcd_answer =
GetFirstVideoContentDescription(answer.get());
EXPECT_EQ(expected_direction_in_answer, vcd_answer->direction());
}
bool VerifyNoCNCodecs(const cricket::ContentInfo* content) {
RTC_DCHECK(content);
RTC_CHECK(content->media_description());
const cricket::AudioContentDescription* audio_desc =
content->media_description()->as_audio();
RTC_CHECK(audio_desc);
for (const cricket::AudioCodec& codec : audio_desc->codecs()) {
if (codec.name == "CN") {
return false;
}
}
return true;
}
void TestVideoGcmCipher(bool gcm_offer, bool gcm_answer) {
MediaSessionOptions offer_opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &offer_opts);
offer_opts.crypto_options.srtp.enable_gcm_crypto_suites = gcm_offer;
MediaSessionOptions answer_opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &answer_opts);
answer_opts.crypto_options.srtp.enable_gcm_crypto_suites = gcm_answer;
f1_.set_secure(SEC_ENABLED);
f2_.set_secure(SEC_ENABLED);
std::unique_ptr<SessionDescription> offer =
f1_.CreateOffer(offer_opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
if (gcm_offer && gcm_answer) {
for (cricket::ContentInfo& content : offer->contents()) {
auto cryptos = content.media_description()->cryptos();
PreferGcmCryptoParameters(&cryptos);
content.media_description()->set_cryptos(cryptos);
}
}
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), answer_opts, NULL);
const ContentInfo* ac = answer->GetContentByName("audio");
const ContentInfo* vc = answer->GetContentByName("video");
ASSERT_TRUE(ac != NULL);
ASSERT_TRUE(vc != NULL);
EXPECT_EQ(MediaProtocolType::kRtp, ac->type);
EXPECT_EQ(MediaProtocolType::kRtp, vc->type);
const AudioContentDescription* acd = ac->media_description()->as_audio();
const VideoContentDescription* vcd = vc->media_description()->as_video();
EXPECT_EQ(MEDIA_TYPE_AUDIO, acd->type());
EXPECT_THAT(acd->codecs(), ElementsAreArray(kAudioCodecsAnswer));
EXPECT_EQ(kAutoBandwidth, acd->bandwidth()); // negotiated auto bw
EXPECT_EQ(0U, acd->first_ssrc()); // no sender is attached
EXPECT_TRUE(acd->rtcp_mux()); // negotiated rtcp-mux
if (gcm_offer && gcm_answer) {
ASSERT_CRYPTO(acd, 1U, kDefaultSrtpCryptoSuiteGcm);
} else {
ASSERT_CRYPTO(acd, 1U, kDefaultSrtpCryptoSuite);
}
EXPECT_EQ(MEDIA_TYPE_VIDEO, vcd->type());
EXPECT_THAT(vcd->codecs(), ElementsAreArray(kVideoCodecsAnswer));
EXPECT_EQ(0U, vcd->first_ssrc()); // no sender is attached
EXPECT_TRUE(vcd->rtcp_mux()); // negotiated rtcp-mux
if (gcm_offer && gcm_answer) {
ASSERT_CRYPTO(vcd, 1U, kDefaultSrtpCryptoSuiteGcm);
} else {
ASSERT_CRYPTO(vcd, 1U, kDefaultSrtpCryptoSuite);
}
EXPECT_EQ(cricket::kMediaProtocolSavpf, vcd->protocol());
}
void TestTransportSequenceNumberNegotiation(
const cricket::RtpHeaderExtensions& local,
const cricket::RtpHeaderExtensions& offered,
const cricket::RtpHeaderExtensions& expectedAnswer) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
f1_.set_audio_rtp_header_extensions(offered);
f1_.set_video_rtp_header_extensions(offered);
f2_.set_audio_rtp_header_extensions(local);
f2_.set_video_rtp_header_extensions(local);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
EXPECT_EQ(
expectedAnswer,
GetFirstAudioContentDescription(answer.get())->rtp_header_extensions());
EXPECT_EQ(
expectedAnswer,
GetFirstVideoContentDescription(answer.get())->rtp_header_extensions());
}
protected:
UniqueRandomIdGenerator ssrc_generator1;
UniqueRandomIdGenerator ssrc_generator2;
MediaSessionDescriptionFactory f1_;
MediaSessionDescriptionFactory f2_;
TransportDescriptionFactory tdf1_;
TransportDescriptionFactory tdf2_;
};
// Create a typical audio offer, and ensure it matches what we expect.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateAudioOffer) {
f1_.set_secure(SEC_ENABLED);
std::unique_ptr<SessionDescription> offer =
f1_.CreateOffer(CreatePlanBMediaSessionOptions(), NULL);
ASSERT_TRUE(offer.get() != NULL);
const ContentInfo* ac = offer->GetContentByName("audio");
const ContentInfo* vc = offer->GetContentByName("video");
ASSERT_TRUE(ac != NULL);
ASSERT_TRUE(vc == NULL);
EXPECT_EQ(MediaProtocolType::kRtp, ac->type);
const AudioContentDescription* acd = ac->media_description()->as_audio();
EXPECT_EQ(MEDIA_TYPE_AUDIO, acd->type());
EXPECT_EQ(f1_.audio_sendrecv_codecs(), acd->codecs());
EXPECT_EQ(0U, acd->first_ssrc()); // no sender is attached.
EXPECT_EQ(kAutoBandwidth, acd->bandwidth()); // default bandwidth (auto)
EXPECT_TRUE(acd->rtcp_mux()); // rtcp-mux defaults on
ASSERT_CRYPTO(acd, 1U, kDefaultSrtpCryptoSuite);
EXPECT_EQ(cricket::kMediaProtocolSavpf, acd->protocol());
}
// Create a typical video offer, and ensure it matches what we expect.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateVideoOffer) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
f1_.set_secure(SEC_ENABLED);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
const ContentInfo* ac = offer->GetContentByName("audio");
const ContentInfo* vc = offer->GetContentByName("video");
ASSERT_TRUE(ac != NULL);
ASSERT_TRUE(vc != NULL);
EXPECT_EQ(MediaProtocolType::kRtp, ac->type);
EXPECT_EQ(MediaProtocolType::kRtp, vc->type);
const AudioContentDescription* acd = ac->media_description()->as_audio();
const VideoContentDescription* vcd = vc->media_description()->as_video();
EXPECT_EQ(MEDIA_TYPE_AUDIO, acd->type());
EXPECT_EQ(f1_.audio_sendrecv_codecs(), acd->codecs());
EXPECT_EQ(0U, acd->first_ssrc()); // no sender is attached
EXPECT_EQ(kAutoBandwidth, acd->bandwidth()); // default bandwidth (auto)
EXPECT_TRUE(acd->rtcp_mux()); // rtcp-mux defaults on
ASSERT_CRYPTO(acd, 1U, kDefaultSrtpCryptoSuite);
EXPECT_EQ(cricket::kMediaProtocolSavpf, acd->protocol());
EXPECT_EQ(MEDIA_TYPE_VIDEO, vcd->type());
EXPECT_EQ(f1_.video_sendrecv_codecs(), vcd->codecs());
EXPECT_EQ(0U, vcd->first_ssrc()); // no sender is attached
EXPECT_EQ(kAutoBandwidth, vcd->bandwidth()); // default bandwidth (auto)
EXPECT_TRUE(vcd->rtcp_mux()); // rtcp-mux defaults on
ASSERT_CRYPTO(vcd, 1U, kDefaultSrtpCryptoSuite);
EXPECT_EQ(cricket::kMediaProtocolSavpf, vcd->protocol());
}
// Test creating an offer with bundle where the Codecs have the same dynamic
// RTP playlod type. The test verifies that the offer don't contain the
// duplicate RTP payload types.
TEST_F(MediaSessionDescriptionFactoryTest, TestBundleOfferWithSameCodecPlType) {
const VideoCodec& offered_video_codec = f2_.video_sendrecv_codecs()[0];
const AudioCodec& offered_audio_codec = f2_.audio_sendrecv_codecs()[0];
const RtpDataCodec& offered_data_codec = f2_.rtp_data_codecs()[0];
ASSERT_EQ(offered_video_codec.id, offered_audio_codec.id);
ASSERT_EQ(offered_video_codec.id, offered_data_codec.id);
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
AddDataSection(cricket::DCT_RTP, RtpTransceiverDirection::kRecvOnly, &opts);
opts.bundle_enabled = true;
std::unique_ptr<SessionDescription> offer = f2_.CreateOffer(opts, NULL);
const VideoContentDescription* vcd =
GetFirstVideoContentDescription(offer.get());
const AudioContentDescription* acd =
GetFirstAudioContentDescription(offer.get());
const RtpDataContentDescription* dcd =
GetFirstRtpDataContentDescription(offer.get());
ASSERT_TRUE(NULL != vcd);
ASSERT_TRUE(NULL != acd);
ASSERT_TRUE(NULL != dcd);
EXPECT_NE(vcd->codecs()[0].id, acd->codecs()[0].id);
EXPECT_NE(vcd->codecs()[0].id, dcd->codecs()[0].id);
EXPECT_NE(acd->codecs()[0].id, dcd->codecs()[0].id);
EXPECT_EQ(vcd->codecs()[0].name, offered_video_codec.name);
EXPECT_EQ(acd->codecs()[0].name, offered_audio_codec.name);
EXPECT_EQ(dcd->codecs()[0].name, offered_data_codec.name);
}
// Test creating an updated offer with bundle, audio, video and data
// after an audio only session has been negotiated.
TEST_F(MediaSessionDescriptionFactoryTest,
TestCreateUpdatedVideoOfferWithBundle) {
f1_.set_secure(SEC_ENABLED);
f2_.set_secure(SEC_ENABLED);
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio",
RtpTransceiverDirection::kRecvOnly, kActive,
&opts);
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kInactive, kStopped,
&opts);
opts.data_channel_type = cricket::DCT_NONE;
opts.bundle_enabled = true;
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
MediaSessionOptions updated_opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &updated_opts);
AddDataSection(cricket::DCT_RTP, RtpTransceiverDirection::kRecvOnly,
&updated_opts);
updated_opts.bundle_enabled = true;
std::unique_ptr<SessionDescription> updated_offer(
f1_.CreateOffer(updated_opts, answer.get()));
const AudioContentDescription* acd =
GetFirstAudioContentDescription(updated_offer.get());
const VideoContentDescription* vcd =
GetFirstVideoContentDescription(updated_offer.get());
const RtpDataContentDescription* dcd =
GetFirstRtpDataContentDescription(updated_offer.get());
EXPECT_TRUE(NULL != vcd);
EXPECT_TRUE(NULL != acd);
EXPECT_TRUE(NULL != dcd);
ASSERT_CRYPTO(acd, 1U, kDefaultSrtpCryptoSuite);
EXPECT_EQ(cricket::kMediaProtocolSavpf, acd->protocol());
ASSERT_CRYPTO(vcd, 1U, kDefaultSrtpCryptoSuite);
EXPECT_EQ(cricket::kMediaProtocolSavpf, vcd->protocol());
ASSERT_CRYPTO(dcd, 1U, kDefaultSrtpCryptoSuite);
EXPECT_EQ(cricket::kMediaProtocolSavpf, dcd->protocol());
}
// Create a RTP data offer, and ensure it matches what we expect.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateRtpDataOffer) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
AddDataSection(cricket::DCT_RTP, RtpTransceiverDirection::kRecvOnly, &opts);
f1_.set_secure(SEC_ENABLED);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
const ContentInfo* ac = offer->GetContentByName("audio");
const ContentInfo* dc = offer->GetContentByName("data");
ASSERT_TRUE(ac != NULL);
ASSERT_TRUE(dc != NULL);
EXPECT_EQ(MediaProtocolType::kRtp, ac->type);
EXPECT_EQ(MediaProtocolType::kRtp, dc->type);
const AudioContentDescription* acd = ac->media_description()->as_audio();
const RtpDataContentDescription* dcd = dc->media_description()->as_rtp_data();
EXPECT_EQ(MEDIA_TYPE_AUDIO, acd->type());
EXPECT_EQ(f1_.audio_sendrecv_codecs(), acd->codecs());
EXPECT_EQ(0U, acd->first_ssrc()); // no sender is attched.
EXPECT_EQ(kAutoBandwidth, acd->bandwidth()); // default bandwidth (auto)
EXPECT_TRUE(acd->rtcp_mux()); // rtcp-mux defaults on
ASSERT_CRYPTO(acd, 1U, kDefaultSrtpCryptoSuite);
EXPECT_EQ(cricket::kMediaProtocolSavpf, acd->protocol());
EXPECT_EQ(MEDIA_TYPE_DATA, dcd->type());
EXPECT_EQ(f1_.rtp_data_codecs(), dcd->codecs());
EXPECT_EQ(0U, dcd->first_ssrc()); // no sender is attached.
EXPECT_EQ(cricket::kDataMaxBandwidth,
dcd->bandwidth()); // default bandwidth (auto)
EXPECT_TRUE(dcd->rtcp_mux()); // rtcp-mux defaults on
ASSERT_CRYPTO(dcd, 1U, kDefaultSrtpCryptoSuite);
EXPECT_EQ(cricket::kMediaProtocolSavpf, dcd->protocol());
}
// Create an SCTP data offer with bundle without error.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateSctpDataOffer) {
MediaSessionOptions opts;
opts.bundle_enabled = true;
AddDataSection(cricket::DCT_SCTP, RtpTransceiverDirection::kSendRecv, &opts);
f1_.set_secure(SEC_ENABLED);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
EXPECT_TRUE(offer.get() != NULL);
EXPECT_TRUE(offer->GetContentByName("data") != NULL);
auto dcd = GetFirstSctpDataContentDescription(offer.get());
ASSERT_TRUE(dcd);
// Since this transport is insecure, the protocol should be "SCTP".
EXPECT_EQ(cricket::kMediaProtocolSctp, dcd->protocol());
}
// Create an SCTP data offer with bundle without error.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateSecureSctpDataOffer) {
MediaSessionOptions opts;
opts.bundle_enabled = true;
AddDataSection(cricket::DCT_SCTP, RtpTransceiverDirection::kSendRecv, &opts);
f1_.set_secure(SEC_ENABLED);
tdf1_.set_secure(SEC_ENABLED);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
EXPECT_TRUE(offer.get() != NULL);
EXPECT_TRUE(offer->GetContentByName("data") != NULL);
auto dcd = GetFirstSctpDataContentDescription(offer.get());
ASSERT_TRUE(dcd);
// The protocol should now be "UDP/DTLS/SCTP"
EXPECT_EQ(cricket::kMediaProtocolUdpDtlsSctp, dcd->protocol());
}
// Test creating an sctp data channel from an already generated offer.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateImplicitSctpDataOffer) {
MediaSessionOptions opts;
opts.bundle_enabled = true;
AddDataSection(cricket::DCT_SCTP, RtpTransceiverDirection::kSendRecv, &opts);
f1_.set_secure(SEC_ENABLED);
std::unique_ptr<SessionDescription> offer1(f1_.CreateOffer(opts, NULL));
ASSERT_TRUE(offer1.get() != NULL);
const ContentInfo* data = offer1->GetContentByName("data");
ASSERT_TRUE(data != NULL);
ASSERT_EQ(cricket::kMediaProtocolSctp, data->media_description()->protocol());
// Now set data_channel_type to 'none' (default) and make sure that the
// datachannel type that gets generated from the previous offer, is of the
// same type.
opts.data_channel_type = cricket::DCT_NONE;
std::unique_ptr<SessionDescription> offer2(
f1_.CreateOffer(opts, offer1.get()));
data = offer2->GetContentByName("data");
ASSERT_TRUE(data != NULL);
EXPECT_EQ(cricket::kMediaProtocolSctp, data->media_description()->protocol());
}
// Test that if BUNDLE is enabled and all media sections are rejected then the
// BUNDLE group is not present in the re-offer.
TEST_F(MediaSessionDescriptionFactoryTest, ReOfferNoBundleGroupIfAllRejected) {
MediaSessionOptions opts;
opts.bundle_enabled = true;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
opts.media_description_options[0].stopped = true;
std::unique_ptr<SessionDescription> reoffer =
f1_.CreateOffer(opts, offer.get());
EXPECT_FALSE(reoffer->GetGroupByName(cricket::GROUP_TYPE_BUNDLE));
}
// Test that if BUNDLE is enabled and the remote re-offer does not include a
// BUNDLE group since all media sections are rejected, then the re-answer also
// does not include a BUNDLE group.
TEST_F(MediaSessionDescriptionFactoryTest, ReAnswerNoBundleGroupIfAllRejected) {
MediaSessionOptions opts;
opts.bundle_enabled = true;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, nullptr);
opts.media_description_options[0].stopped = true;
std::unique_ptr<SessionDescription> reoffer =
f1_.CreateOffer(opts, offer.get());
std::unique_ptr<SessionDescription> reanswer =
f2_.CreateAnswer(reoffer.get(), opts, answer.get());
EXPECT_FALSE(reanswer->GetGroupByName(cricket::GROUP_TYPE_BUNDLE));
}
// Test that if BUNDLE is enabled and the previous offerer-tagged media section
// was rejected then the new offerer-tagged media section is the non-rejected
// media section.
TEST_F(MediaSessionDescriptionFactoryTest, ReOfferChangeBundleOffererTagged) {
MediaSessionOptions opts;
opts.bundle_enabled = true;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
// Reject the audio m= section and add a video m= section.
opts.media_description_options[0].stopped = true;
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
std::unique_ptr<SessionDescription> reoffer =
f1_.CreateOffer(opts, offer.get());
const cricket::ContentGroup* bundle_group =
reoffer->GetGroupByName(cricket::GROUP_TYPE_BUNDLE);
ASSERT_TRUE(bundle_group);
EXPECT_FALSE(bundle_group->HasContentName("audio"));
EXPECT_TRUE(bundle_group->HasContentName("video"));
}
// Test that if BUNDLE is enabled and the previous offerer-tagged media section
// was rejected and a new media section is added, then the re-answer BUNDLE
// group will contain only the non-rejected media section.
TEST_F(MediaSessionDescriptionFactoryTest, ReAnswerChangedBundleOffererTagged) {
MediaSessionOptions opts;
opts.bundle_enabled = true;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, nullptr);
// Reject the audio m= section and add a video m= section.
opts.media_description_options[0].stopped = true;
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
std::unique_ptr<SessionDescription> reoffer =
f1_.CreateOffer(opts, offer.get());
std::unique_ptr<SessionDescription> reanswer =
f2_.CreateAnswer(reoffer.get(), opts, answer.get());
const cricket::ContentGroup* bundle_group =
reanswer->GetGroupByName(cricket::GROUP_TYPE_BUNDLE);
ASSERT_TRUE(bundle_group);
EXPECT_FALSE(bundle_group->HasContentName("audio"));
EXPECT_TRUE(bundle_group->HasContentName("video"));
}
// Test that if the BUNDLE offerer-tagged media section is changed in a reoffer
// and there is still a non-rejected media section that was in the initial
// offer, then the ICE credentials do not change in the reoffer offerer-tagged
// media section.
TEST_F(MediaSessionDescriptionFactoryTest,
ReOfferChangeBundleOffererTaggedKeepsIceCredentials) {
MediaSessionOptions opts;
opts.bundle_enabled = true;
AddAudioVideoSections(RtpTransceiverDirection::kSendRecv, &opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, nullptr);
// Reject the audio m= section.
opts.media_description_options[0].stopped = true;
std::unique_ptr<SessionDescription> reoffer =
f1_.CreateOffer(opts, offer.get());
const TransportDescription* offer_tagged =
offer->GetTransportDescriptionByName("audio");
ASSERT_TRUE(offer_tagged);
const TransportDescription* reoffer_tagged =
reoffer->GetTransportDescriptionByName("video");
ASSERT_TRUE(reoffer_tagged);
EXPECT_EQ(offer_tagged->ice_ufrag, reoffer_tagged->ice_ufrag);
EXPECT_EQ(offer_tagged->ice_pwd, reoffer_tagged->ice_pwd);
}
// Test that if the BUNDLE offerer-tagged media section is changed in a reoffer
// and there is still a non-rejected media section that was in the initial
// offer, then the ICE credentials do not change in the reanswer answerer-tagged
// media section.
TEST_F(MediaSessionDescriptionFactoryTest,
ReAnswerChangeBundleOffererTaggedKeepsIceCredentials) {
MediaSessionOptions opts;
opts.bundle_enabled = true;
AddAudioVideoSections(RtpTransceiverDirection::kSendRecv, &opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, nullptr);
// Reject the audio m= section.
opts.media_description_options[0].stopped = true;
std::unique_ptr<SessionDescription> reoffer =
f1_.CreateOffer(opts, offer.get());
std::unique_ptr<SessionDescription> reanswer =
f2_.CreateAnswer(reoffer.get(), opts, answer.get());
const TransportDescription* answer_tagged =
answer->GetTransportDescriptionByName("audio");
ASSERT_TRUE(answer_tagged);
const TransportDescription* reanswer_tagged =
reanswer->GetTransportDescriptionByName("video");
ASSERT_TRUE(reanswer_tagged);
EXPECT_EQ(answer_tagged->ice_ufrag, reanswer_tagged->ice_ufrag);
EXPECT_EQ(answer_tagged->ice_pwd, reanswer_tagged->ice_pwd);
}
// Create an audio, video offer without legacy StreamParams.
TEST_F(MediaSessionDescriptionFactoryTest,
TestCreateOfferWithoutLegacyStreams) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
const ContentInfo* ac = offer->GetContentByName("audio");
const ContentInfo* vc = offer->GetContentByName("video");
ASSERT_TRUE(ac != NULL);
ASSERT_TRUE(vc != NULL);
const AudioContentDescription* acd = ac->media_description()->as_audio();
const VideoContentDescription* vcd = vc->media_description()->as_video();
EXPECT_FALSE(vcd->has_ssrcs()); // No StreamParams.
EXPECT_FALSE(acd->has_ssrcs()); // No StreamParams.
}
// Creates an audio+video sendonly offer.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateSendOnlyOffer) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kSendOnly, &opts);
AttachSenderToMediaDescriptionOptions("video", MEDIA_TYPE_VIDEO, kVideoTrack1,
{kMediaStream1}, 1, &opts);
AttachSenderToMediaDescriptionOptions("audio", MEDIA_TYPE_AUDIO, kAudioTrack1,
{kMediaStream1}, 1, &opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
EXPECT_EQ(2u, offer->contents().size());
EXPECT_TRUE(IsMediaContentOfType(&offer->contents()[0], MEDIA_TYPE_AUDIO));
EXPECT_TRUE(IsMediaContentOfType(&offer->contents()[1], MEDIA_TYPE_VIDEO));
EXPECT_EQ(RtpTransceiverDirection::kSendOnly,
GetMediaDirection(&offer->contents()[0]));
EXPECT_EQ(RtpTransceiverDirection::kSendOnly,
GetMediaDirection(&offer->contents()[1]));
}
// Verifies that the order of the media contents in the current
// SessionDescription is preserved in the new SessionDescription.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateOfferContentOrder) {
MediaSessionOptions opts;
AddDataSection(cricket::DCT_SCTP, RtpTransceiverDirection::kSendRecv, &opts);
std::unique_ptr<SessionDescription> offer1(f1_.CreateOffer(opts, NULL));
ASSERT_TRUE(offer1.get() != NULL);
EXPECT_EQ(1u, offer1->contents().size());
EXPECT_TRUE(IsMediaContentOfType(&offer1->contents()[0], MEDIA_TYPE_DATA));
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kRecvOnly, kActive,
&opts);
std::unique_ptr<SessionDescription> offer2(
f1_.CreateOffer(opts, offer1.get()));
ASSERT_TRUE(offer2.get() != NULL);
EXPECT_EQ(2u, offer2->contents().size());
EXPECT_TRUE(IsMediaContentOfType(&offer2->contents()[0], MEDIA_TYPE_DATA));
EXPECT_TRUE(IsMediaContentOfType(&offer2->contents()[1], MEDIA_TYPE_VIDEO));
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio",
RtpTransceiverDirection::kRecvOnly, kActive,
&opts);
std::unique_ptr<SessionDescription> offer3(
f1_.CreateOffer(opts, offer2.get()));
ASSERT_TRUE(offer3.get() != NULL);
EXPECT_EQ(3u, offer3->contents().size());
EXPECT_TRUE(IsMediaContentOfType(&offer3->contents()[0], MEDIA_TYPE_DATA));
EXPECT_TRUE(IsMediaContentOfType(&offer3->contents()[1], MEDIA_TYPE_VIDEO));
EXPECT_TRUE(IsMediaContentOfType(&offer3->contents()[2], MEDIA_TYPE_AUDIO));
}
// Create a typical audio answer, and ensure it matches what we expect.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateAudioAnswer) {
f1_.set_secure(SEC_ENABLED);
f2_.set_secure(SEC_ENABLED);
std::unique_ptr<SessionDescription> offer =
f1_.CreateOffer(CreatePlanBMediaSessionOptions(), NULL);
ASSERT_TRUE(offer.get() != NULL);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), CreatePlanBMediaSessionOptions(), NULL);
const ContentInfo* ac = answer->GetContentByName("audio");
const ContentInfo* vc = answer->GetContentByName("video");
ASSERT_TRUE(ac != NULL);
ASSERT_TRUE(vc == NULL);
EXPECT_EQ(MediaProtocolType::kRtp, ac->type);
const AudioContentDescription* acd = ac->media_description()->as_audio();
EXPECT_EQ(MEDIA_TYPE_AUDIO, acd->type());
EXPECT_THAT(acd->codecs(), ElementsAreArray(kAudioCodecsAnswer));
EXPECT_EQ(0U, acd->first_ssrc()); // no sender is attached
EXPECT_EQ(kAutoBandwidth, acd->bandwidth()); // negotiated auto bw
EXPECT_TRUE(acd->rtcp_mux()); // negotiated rtcp-mux
ASSERT_CRYPTO(acd, 1U, kDefaultSrtpCryptoSuite);
EXPECT_EQ(cricket::kMediaProtocolSavpf, acd->protocol());
}
// Create a typical audio answer with GCM ciphers enabled, and ensure it
// matches what we expect.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateAudioAnswerGcm) {
f1_.set_secure(SEC_ENABLED);
f2_.set_secure(SEC_ENABLED);
MediaSessionOptions opts = CreatePlanBMediaSessionOptions();
opts.crypto_options.srtp.enable_gcm_crypto_suites = true;
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
for (cricket::ContentInfo& content : offer->contents()) {
auto cryptos = content.media_description()->cryptos();
PreferGcmCryptoParameters(&cryptos);
content.media_description()->set_cryptos(cryptos);
}
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
const ContentInfo* ac = answer->GetContentByName("audio");
const ContentInfo* vc = answer->GetContentByName("video");
ASSERT_TRUE(ac != NULL);
ASSERT_TRUE(vc == NULL);
EXPECT_EQ(MediaProtocolType::kRtp, ac->type);
const AudioContentDescription* acd = ac->media_description()->as_audio();
EXPECT_EQ(MEDIA_TYPE_AUDIO, acd->type());
EXPECT_THAT(acd->codecs(), ElementsAreArray(kAudioCodecsAnswer));
EXPECT_EQ(0U, acd->first_ssrc()); // no sender is attached
EXPECT_EQ(kAutoBandwidth, acd->bandwidth()); // negotiated auto bw
EXPECT_TRUE(acd->rtcp_mux()); // negotiated rtcp-mux
ASSERT_CRYPTO(acd, 1U, kDefaultSrtpCryptoSuiteGcm);
EXPECT_EQ(cricket::kMediaProtocolSavpf, acd->protocol());
}
// Create a typical video answer, and ensure it matches what we expect.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateVideoAnswer) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
f1_.set_secure(SEC_ENABLED);
f2_.set_secure(SEC_ENABLED);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
const ContentInfo* ac = answer->GetContentByName("audio");
const ContentInfo* vc = answer->GetContentByName("video");
ASSERT_TRUE(ac != NULL);
ASSERT_TRUE(vc != NULL);
EXPECT_EQ(MediaProtocolType::kRtp, ac->type);
EXPECT_EQ(MediaProtocolType::kRtp, vc->type);
const AudioContentDescription* acd = ac->media_description()->as_audio();
const VideoContentDescription* vcd = vc->media_description()->as_video();
EXPECT_EQ(MEDIA_TYPE_AUDIO, acd->type());
EXPECT_THAT(acd->codecs(), ElementsAreArray(kAudioCodecsAnswer));
EXPECT_EQ(kAutoBandwidth, acd->bandwidth()); // negotiated auto bw
EXPECT_EQ(0U, acd->first_ssrc()); // no sender is attached
EXPECT_TRUE(acd->rtcp_mux()); // negotiated rtcp-mux
ASSERT_CRYPTO(acd, 1U, kDefaultSrtpCryptoSuite);
EXPECT_EQ(MEDIA_TYPE_VIDEO, vcd->type());
EXPECT_THAT(vcd->codecs(), ElementsAreArray(kVideoCodecsAnswer));
EXPECT_EQ(0U, vcd->first_ssrc()); // no sender is attached
EXPECT_TRUE(vcd->rtcp_mux()); // negotiated rtcp-mux
ASSERT_CRYPTO(vcd, 1U, kDefaultSrtpCryptoSuite);
EXPECT_EQ(cricket::kMediaProtocolSavpf, vcd->protocol());
}
// Create a typical video answer with GCM ciphers enabled, and ensure it
// matches what we expect.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateVideoAnswerGcm) {
TestVideoGcmCipher(true, true);
}
// Create a typical video answer with GCM ciphers enabled for the offer only,
// and ensure it matches what we expect.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateVideoAnswerGcmOffer) {
TestVideoGcmCipher(true, false);
}
// Create a typical video answer with GCM ciphers enabled for the answer only,
// and ensure it matches what we expect.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateVideoAnswerGcmAnswer) {
TestVideoGcmCipher(false, true);
}
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateDataAnswer) {
MediaSessionOptions opts = CreatePlanBMediaSessionOptions();
AddDataSection(cricket::DCT_RTP, RtpTransceiverDirection::kRecvOnly, &opts);
f1_.set_secure(SEC_ENABLED);
f2_.set_secure(SEC_ENABLED);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
const ContentInfo* ac = answer->GetContentByName("audio");
const ContentInfo* dc = answer->GetContentByName("data");
ASSERT_TRUE(ac != NULL);
ASSERT_TRUE(dc != NULL);
EXPECT_EQ(MediaProtocolType::kRtp, ac->type);
EXPECT_EQ(MediaProtocolType::kRtp, dc->type);
const AudioContentDescription* acd = ac->media_description()->as_audio();
const RtpDataContentDescription* dcd = dc->media_description()->as_rtp_data();
EXPECT_EQ(MEDIA_TYPE_AUDIO, acd->type());
EXPECT_THAT(acd->codecs(), ElementsAreArray(kAudioCodecsAnswer));
EXPECT_EQ(kAutoBandwidth, acd->bandwidth()); // negotiated auto bw
EXPECT_EQ(0U, acd->first_ssrc()); // no sender is attached
EXPECT_TRUE(acd->rtcp_mux()); // negotiated rtcp-mux
ASSERT_CRYPTO(acd, 1U, kDefaultSrtpCryptoSuite);
EXPECT_EQ(MEDIA_TYPE_DATA, dcd->type());
EXPECT_THAT(dcd->codecs(), ElementsAreArray(kDataCodecsAnswer));
EXPECT_EQ(0U, dcd->first_ssrc()); // no sender is attached
EXPECT_TRUE(dcd->rtcp_mux()); // negotiated rtcp-mux
ASSERT_CRYPTO(dcd, 1U, kDefaultSrtpCryptoSuite);
EXPECT_EQ(cricket::kMediaProtocolSavpf, dcd->protocol());
}
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateDataAnswerGcm) {
MediaSessionOptions opts = CreatePlanBMediaSessionOptions();
AddDataSection(cricket::DCT_RTP, RtpTransceiverDirection::kRecvOnly, &opts);
opts.crypto_options.srtp.enable_gcm_crypto_suites = true;
f1_.set_secure(SEC_ENABLED);
f2_.set_secure(SEC_ENABLED);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
for (cricket::ContentInfo& content : offer->contents()) {
auto cryptos = content.media_description()->cryptos();
PreferGcmCryptoParameters(&cryptos);
content.media_description()->set_cryptos(cryptos);
}
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
const ContentInfo* ac = answer->GetContentByName("audio");
const ContentInfo* dc = answer->GetContentByName("data");
ASSERT_TRUE(ac != NULL);
ASSERT_TRUE(dc != NULL);
EXPECT_EQ(MediaProtocolType::kRtp, ac->type);
EXPECT_EQ(MediaProtocolType::kRtp, dc->type);
const AudioContentDescription* acd = ac->media_description()->as_audio();
const RtpDataContentDescription* dcd = dc->media_description()->as_rtp_data();
EXPECT_EQ(MEDIA_TYPE_AUDIO, acd->type());
EXPECT_THAT(acd->codecs(), ElementsAreArray(kAudioCodecsAnswer));
EXPECT_EQ(kAutoBandwidth, acd->bandwidth()); // negotiated auto bw
EXPECT_EQ(0U, acd->first_ssrc()); // no sender is attached
EXPECT_TRUE(acd->rtcp_mux()); // negotiated rtcp-mux
ASSERT_CRYPTO(acd, 1U, kDefaultSrtpCryptoSuiteGcm);
EXPECT_EQ(MEDIA_TYPE_DATA, dcd->type());
EXPECT_THAT(dcd->codecs(), ElementsAreArray(kDataCodecsAnswer));
EXPECT_EQ(0U, dcd->first_ssrc()); // no sender is attached
EXPECT_TRUE(dcd->rtcp_mux()); // negotiated rtcp-mux
ASSERT_CRYPTO(dcd, 1U, kDefaultSrtpCryptoSuiteGcm);
EXPECT_EQ(cricket::kMediaProtocolSavpf, dcd->protocol());
}
// The use_sctpmap flag should be set in an Sctp DataContentDescription by
// default. The answer's use_sctpmap flag should match the offer's.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateDataAnswerUsesSctpmap) {
MediaSessionOptions opts;
AddDataSection(cricket::DCT_SCTP, RtpTransceiverDirection::kSendRecv, &opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
ContentInfo* dc_offer = offer->GetContentByName("data");
ASSERT_TRUE(dc_offer != NULL);
SctpDataContentDescription* dcd_offer =
dc_offer->media_description()->as_sctp();
EXPECT_TRUE(dcd_offer->use_sctpmap());
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
const ContentInfo* dc_answer = answer->GetContentByName("data");
ASSERT_TRUE(dc_answer != NULL);
const SctpDataContentDescription* dcd_answer =
dc_answer->media_description()->as_sctp();
EXPECT_TRUE(dcd_answer->use_sctpmap());
}
// The answer's use_sctpmap flag should match the offer's.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateDataAnswerWithoutSctpmap) {
MediaSessionOptions opts;
AddDataSection(cricket::DCT_SCTP, RtpTransceiverDirection::kSendRecv, &opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
ContentInfo* dc_offer = offer->GetContentByName("data");
ASSERT_TRUE(dc_offer != NULL);
SctpDataContentDescription* dcd_offer =
dc_offer->media_description()->as_sctp();
dcd_offer->set_use_sctpmap(false);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
const ContentInfo* dc_answer = answer->GetContentByName("data");
ASSERT_TRUE(dc_answer != NULL);
const SctpDataContentDescription* dcd_answer =
dc_answer->media_description()->as_sctp();
EXPECT_FALSE(dcd_answer->use_sctpmap());
}
// Test that a valid answer will be created for "DTLS/SCTP", "UDP/DTLS/SCTP"
// and "TCP/DTLS/SCTP" offers.
TEST_F(MediaSessionDescriptionFactoryTest,
TestCreateDataAnswerToDifferentOfferedProtos) {
// Need to enable DTLS offer/answer generation (disabled by default in this
// test).
f1_.set_secure(SEC_ENABLED);
f2_.set_secure(SEC_ENABLED);
tdf1_.set_secure(SEC_ENABLED);
tdf2_.set_secure(SEC_ENABLED);
MediaSessionOptions opts;
AddDataSection(cricket::DCT_SCTP, RtpTransceiverDirection::kSendRecv, &opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
ASSERT_TRUE(offer.get() != nullptr);
ContentInfo* dc_offer = offer->GetContentByName("data");
ASSERT_TRUE(dc_offer != nullptr);
SctpDataContentDescription* dcd_offer =
dc_offer->media_description()->as_sctp();
ASSERT_TRUE(dcd_offer);
std::vector<std::string> protos = {"DTLS/SCTP", "UDP/DTLS/SCTP",
"TCP/DTLS/SCTP"};
for (const std::string& proto : protos) {
dcd_offer->set_protocol(proto);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, nullptr);
const ContentInfo* dc_answer = answer->GetContentByName("data");
ASSERT_TRUE(dc_answer != nullptr);
const SctpDataContentDescription* dcd_answer =
dc_answer->media_description()->as_sctp();
EXPECT_FALSE(dc_answer->rejected);
EXPECT_EQ(proto, dcd_answer->protocol());
}
}
TEST_F(MediaSessionDescriptionFactoryTest,
TestCreateDataAnswerToOfferWithDefinedMessageSize) {
// Need to enable DTLS offer/answer generation (disabled by default in this
// test).
f1_.set_secure(SEC_ENABLED);
f2_.set_secure(SEC_ENABLED);
tdf1_.set_secure(SEC_ENABLED);
tdf2_.set_secure(SEC_ENABLED);
MediaSessionOptions opts;
AddDataSection(cricket::DCT_SCTP, RtpTransceiverDirection::kSendRecv, &opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
ASSERT_TRUE(offer.get() != nullptr);
ContentInfo* dc_offer = offer->GetContentByName("data");
ASSERT_TRUE(dc_offer != nullptr);
SctpDataContentDescription* dcd_offer =
dc_offer->media_description()->as_sctp();
ASSERT_TRUE(dcd_offer);
dcd_offer->set_max_message_size(1234);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, nullptr);
const ContentInfo* dc_answer = answer->GetContentByName("data");
ASSERT_TRUE(dc_answer != nullptr);
const SctpDataContentDescription* dcd_answer =
dc_answer->media_description()->as_sctp();
EXPECT_FALSE(dc_answer->rejected);
EXPECT_EQ(1234, dcd_answer->max_message_size());
}
TEST_F(MediaSessionDescriptionFactoryTest,
TestCreateDataAnswerToOfferWithZeroMessageSize) {
// Need to enable DTLS offer/answer generation (disabled by default in this
// test).
f1_.set_secure(SEC_ENABLED);
f2_.set_secure(SEC_ENABLED);
tdf1_.set_secure(SEC_ENABLED);
tdf2_.set_secure(SEC_ENABLED);
MediaSessionOptions opts;
AddDataSection(cricket::DCT_SCTP, RtpTransceiverDirection::kSendRecv, &opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
ASSERT_TRUE(offer.get() != nullptr);
ContentInfo* dc_offer = offer->GetContentByName("data");
ASSERT_TRUE(dc_offer != nullptr);
SctpDataContentDescription* dcd_offer =
dc_offer->media_description()->as_sctp();
ASSERT_TRUE(dcd_offer);
dcd_offer->set_max_message_size(0);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, nullptr);
const ContentInfo* dc_answer = answer->GetContentByName("data");
ASSERT_TRUE(dc_answer != nullptr);
const SctpDataContentDescription* dcd_answer =
dc_answer->media_description()->as_sctp();
EXPECT_FALSE(dc_answer->rejected);
EXPECT_EQ(cricket::kSctpSendBufferSize, dcd_answer->max_message_size());
}
// Verifies that the order of the media contents in the offer is preserved in
// the answer.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateAnswerContentOrder) {
MediaSessionOptions opts;
// Creates a data only offer.
AddDataSection(cricket::DCT_SCTP, RtpTransceiverDirection::kSendRecv, &opts);
std::unique_ptr<SessionDescription> offer1(f1_.CreateOffer(opts, NULL));
ASSERT_TRUE(offer1.get() != NULL);
// Appends audio to the offer.
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio",
RtpTransceiverDirection::kRecvOnly, kActive,
&opts);
std::unique_ptr<SessionDescription> offer2(
f1_.CreateOffer(opts, offer1.get()));
ASSERT_TRUE(offer2.get() != NULL);
// Appends video to the offer.
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kRecvOnly, kActive,
&opts);
std::unique_ptr<SessionDescription> offer3(
f1_.CreateOffer(opts, offer2.get()));
ASSERT_TRUE(offer3.get() != NULL);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer3.get(), opts, NULL);
ASSERT_TRUE(answer.get() != NULL);
EXPECT_EQ(3u, answer->contents().size());
EXPECT_TRUE(IsMediaContentOfType(&answer->contents()[0], MEDIA_TYPE_DATA));
EXPECT_TRUE(IsMediaContentOfType(&answer->contents()[1], MEDIA_TYPE_AUDIO));
EXPECT_TRUE(IsMediaContentOfType(&answer->contents()[2], MEDIA_TYPE_VIDEO));
}
// TODO(deadbeef): Extend these tests to ensure the correct direction with other
// answerer settings.
// This test that the media direction is set to send/receive in an answer if
// the offer is send receive.
TEST_F(MediaSessionDescriptionFactoryTest, CreateAnswerToSendReceiveOffer) {
TestMediaDirectionInAnswer(RtpTransceiverDirection::kSendRecv,
RtpTransceiverDirection::kSendRecv);
}
// This test that the media direction is set to receive only in an answer if
// the offer is send only.
TEST_F(MediaSessionDescriptionFactoryTest, CreateAnswerToSendOnlyOffer) {
TestMediaDirectionInAnswer(RtpTransceiverDirection::kSendOnly,
RtpTransceiverDirection::kRecvOnly);
}
// This test that the media direction is set to send only in an answer if
// the offer is recv only.
TEST_F(MediaSessionDescriptionFactoryTest, CreateAnswerToRecvOnlyOffer) {
TestMediaDirectionInAnswer(RtpTransceiverDirection::kRecvOnly,
RtpTransceiverDirection::kSendOnly);
}
// This test that the media direction is set to inactive in an answer if
// the offer is inactive.
TEST_F(MediaSessionDescriptionFactoryTest, CreateAnswerToInactiveOffer) {
TestMediaDirectionInAnswer(RtpTransceiverDirection::kInactive,
RtpTransceiverDirection::kInactive);
}
// Test that a data content with an unknown protocol is rejected in an answer.
TEST_F(MediaSessionDescriptionFactoryTest,
CreateDataAnswerToOfferWithUnknownProtocol) {
MediaSessionOptions opts;
AddDataSection(cricket::DCT_RTP, RtpTransceiverDirection::kRecvOnly, &opts);
f1_.set_secure(SEC_ENABLED);
f2_.set_secure(SEC_ENABLED);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ContentInfo* dc_offer = offer->GetContentByName("data");
ASSERT_TRUE(dc_offer != NULL);
RtpDataContentDescription* dcd_offer =
dc_offer->media_description()->as_rtp_data();
ASSERT_TRUE(dcd_offer != NULL);
// Offer must be acceptable as an RTP protocol in order to be set.
std::string protocol = "RTP/a weird unknown protocol";
dcd_offer->set_protocol(protocol);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
const ContentInfo* dc_answer = answer->GetContentByName("data");
ASSERT_TRUE(dc_answer != NULL);
EXPECT_TRUE(dc_answer->rejected);
const RtpDataContentDescription* dcd_answer =
dc_answer->media_description()->as_rtp_data();
ASSERT_TRUE(dcd_answer != NULL);
EXPECT_EQ(protocol, dcd_answer->protocol());
}
// Test that the media protocol is RTP/AVPF if DTLS and SDES are disabled.
TEST_F(MediaSessionDescriptionFactoryTest, AudioOfferAnswerWithCryptoDisabled) {
MediaSessionOptions opts = CreatePlanBMediaSessionOptions();
f1_.set_secure(SEC_DISABLED);
f2_.set_secure(SEC_DISABLED);
tdf1_.set_secure(SEC_DISABLED);
tdf2_.set_secure(SEC_DISABLED);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
const AudioContentDescription* offer_acd =
GetFirstAudioContentDescription(offer.get());
ASSERT_TRUE(offer_acd != NULL);
EXPECT_EQ(cricket::kMediaProtocolAvpf, offer_acd->protocol());
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
const ContentInfo* ac_answer = answer->GetContentByName("audio");
ASSERT_TRUE(ac_answer != NULL);
EXPECT_FALSE(ac_answer->rejected);
const AudioContentDescription* answer_acd =
GetFirstAudioContentDescription(answer.get());
ASSERT_TRUE(answer_acd != NULL);
EXPECT_EQ(cricket::kMediaProtocolAvpf, answer_acd->protocol());
}
// Create a video offer and answer and ensure the RTP header extensions
// matches what we expect.
TEST_F(MediaSessionDescriptionFactoryTest, TestOfferAnswerWithRtpExtensions) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
f1_.set_audio_rtp_header_extensions(MAKE_VECTOR(kAudioRtpExtension1));
f1_.set_video_rtp_header_extensions(MAKE_VECTOR(kVideoRtpExtension1));
f2_.set_audio_rtp_header_extensions(MAKE_VECTOR(kAudioRtpExtension2));
f2_.set_video_rtp_header_extensions(MAKE_VECTOR(kVideoRtpExtension2));
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
EXPECT_EQ(
MAKE_VECTOR(kAudioRtpExtension1),
GetFirstAudioContentDescription(offer.get())->rtp_header_extensions());
EXPECT_EQ(
MAKE_VECTOR(kVideoRtpExtension1),
GetFirstVideoContentDescription(offer.get())->rtp_header_extensions());
EXPECT_EQ(
MAKE_VECTOR(kAudioRtpExtensionAnswer),
GetFirstAudioContentDescription(answer.get())->rtp_header_extensions());
EXPECT_EQ(
MAKE_VECTOR(kVideoRtpExtensionAnswer),
GetFirstVideoContentDescription(answer.get())->rtp_header_extensions());
}
// Create a audio/video offer and answer and ensure that the
// TransportSequenceNumber RTP header extensions are handled correctly. 02 is
// supported and should take precedence even though not listed among locally
// supported extensions.
TEST_F(MediaSessionDescriptionFactoryTest,
TestOfferAnswerWithTransportSequenceNumberInOffer) {
TestTransportSequenceNumberNegotiation(
MAKE_VECTOR(kRtpExtensionTransportSequenceNumber01), // Local.
MAKE_VECTOR(kRtpExtensionTransportSequenceNumber01), // Offer.
MAKE_VECTOR(kRtpExtensionTransportSequenceNumber01)); // Expected answer.
}
TEST_F(MediaSessionDescriptionFactoryTest,
TestOfferAnswerWithTransportSequenceNumber01And02InOffer) {
TestTransportSequenceNumberNegotiation(
MAKE_VECTOR(kRtpExtensionTransportSequenceNumber01), // Local.
MAKE_VECTOR(kRtpExtensionTransportSequenceNumber01And02), // Offer.
MAKE_VECTOR(kRtpExtensionTransportSequenceNumber02)); // Expected answer.
}
TEST_F(MediaSessionDescriptionFactoryTest,
TestOfferAnswerWithTransportSequenceNumber02InOffer) {
TestTransportSequenceNumberNegotiation(
MAKE_VECTOR(kRtpExtensionTransportSequenceNumber01), // Local.
MAKE_VECTOR(kRtpExtensionTransportSequenceNumber02), // Offer.
MAKE_VECTOR(kRtpExtensionTransportSequenceNumber02)); // Expected answer.
}
TEST_F(MediaSessionDescriptionFactoryTest,
TestNegotiateFrameDescriptorWhenUnexposedLocally) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
const auto offered = MAKE_VECTOR(kRtpExtensionGenericFrameDescriptorUri00);
f1_.set_audio_rtp_header_extensions(offered);
f1_.set_video_rtp_header_extensions(offered);
const auto local = MAKE_VECTOR(kRtpExtensionTransportSequenceNumber01);
f2_.set_audio_rtp_header_extensions(local);
f2_.set_video_rtp_header_extensions(local);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, nullptr);
EXPECT_THAT(
GetFirstAudioContentDescription(answer.get())->rtp_header_extensions(),
ElementsAreArray(offered));
EXPECT_THAT(
GetFirstVideoContentDescription(answer.get())->rtp_header_extensions(),
ElementsAreArray(offered));
}
TEST_F(MediaSessionDescriptionFactoryTest,
TestNegotiateFrameDescriptorWhenExposedLocally) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
const auto offered = MAKE_VECTOR(kRtpExtensionGenericFrameDescriptorUri00);
f1_.set_audio_rtp_header_extensions(offered);
f1_.set_video_rtp_header_extensions(offered);
const auto local = MAKE_VECTOR(kRtpExtensionGenericFrameDescriptorUri00);
f2_.set_audio_rtp_header_extensions(local);
f2_.set_video_rtp_header_extensions(local);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, nullptr);
EXPECT_THAT(
GetFirstAudioContentDescription(answer.get())->rtp_header_extensions(),
ElementsAreArray(offered));
EXPECT_THAT(
GetFirstVideoContentDescription(answer.get())->rtp_header_extensions(),
ElementsAreArray(offered));
}
TEST_F(MediaSessionDescriptionFactoryTest,
NegotiateDependencyDescriptorWhenUnexposedLocally) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
RtpExtension offer_dd(RtpExtension::kDependencyDescriptorUri, 7);
RtpExtension local_tsn(RtpExtension::kTransportSequenceNumberUri, 5);
f1_.set_video_rtp_header_extensions({offer_dd});
f2_.set_video_rtp_header_extensions({local_tsn});
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, nullptr);
EXPECT_THAT(
GetFirstVideoContentDescription(answer.get())->rtp_header_extensions(),
ElementsAre(offer_dd));
}
TEST_F(MediaSessionDescriptionFactoryTest,
NegotiateDependencyDescriptorWhenExposedLocally) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
RtpExtension offer_dd(RtpExtension::kDependencyDescriptorUri, 7);
RtpExtension local_dd(RtpExtension::kDependencyDescriptorUri, 5);
f1_.set_video_rtp_header_extensions({offer_dd});
f2_.set_video_rtp_header_extensions({local_dd});
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, nullptr);
EXPECT_THAT(
GetFirstVideoContentDescription(answer.get())->rtp_header_extensions(),
ElementsAre(offer_dd));
}
TEST_F(MediaSessionDescriptionFactoryTest,
NegotiateAbsoluteCaptureTimeWhenUnexposedLocally) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
const cricket::RtpHeaderExtensions offered_extensions = {
RtpExtension(RtpExtension::kAbsoluteCaptureTimeUri, 7)};
const cricket::RtpHeaderExtensions local_extensions = {
RtpExtension(RtpExtension::kTransportSequenceNumberUri, 5)};
f1_.set_video_rtp_header_extensions(offered_extensions);
f1_.set_audio_rtp_header_extensions(offered_extensions);
f2_.set_video_rtp_header_extensions(local_extensions);
f2_.set_audio_rtp_header_extensions(local_extensions);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, nullptr);
EXPECT_THAT(
GetFirstVideoContentDescription(answer.get())->rtp_header_extensions(),
ElementsAreArray(offered_extensions));
EXPECT_THAT(
GetFirstAudioContentDescription(answer.get())->rtp_header_extensions(),
ElementsAreArray(offered_extensions));
}
TEST_F(MediaSessionDescriptionFactoryTest,
NegotiateAbsoluteCaptureTimeWhenExposedLocally) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
const cricket::RtpHeaderExtensions offered_extensions = {
RtpExtension(RtpExtension::kAbsoluteCaptureTimeUri, 7)};
const cricket::RtpHeaderExtensions local_extensions = {
RtpExtension(RtpExtension::kAbsoluteCaptureTimeUri, 5)};
f1_.set_video_rtp_header_extensions(offered_extensions);
f1_.set_audio_rtp_header_extensions(offered_extensions);
f2_.set_video_rtp_header_extensions(local_extensions);
f2_.set_audio_rtp_header_extensions(local_extensions);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, nullptr);
EXPECT_THAT(
GetFirstVideoContentDescription(answer.get())->rtp_header_extensions(),
ElementsAreArray(offered_extensions));
EXPECT_THAT(
GetFirstAudioContentDescription(answer.get())->rtp_header_extensions(),
ElementsAreArray(offered_extensions));
}
TEST_F(MediaSessionDescriptionFactoryTest,
DoNotNegotiateAbsoluteCaptureTimeWhenNotOffered) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
const cricket::RtpHeaderExtensions offered_extensions = {
RtpExtension(RtpExtension::kTransportSequenceNumberUri, 7)};
const cricket::RtpHeaderExtensions local_extensions = {
RtpExtension(RtpExtension::kAbsoluteCaptureTimeUri, 5)};
f1_.set_video_rtp_header_extensions(offered_extensions);
f1_.set_audio_rtp_header_extensions(offered_extensions);
f2_.set_video_rtp_header_extensions(local_extensions);
f2_.set_audio_rtp_header_extensions(local_extensions);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, nullptr);
EXPECT_THAT(
GetFirstVideoContentDescription(answer.get())->rtp_header_extensions(),
IsEmpty());
EXPECT_THAT(
GetFirstAudioContentDescription(answer.get())->rtp_header_extensions(),
IsEmpty());
}
TEST_F(MediaSessionDescriptionFactoryTest,
TestOfferAnswerWithEncryptedRtpExtensionsBoth) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
f1_.set_enable_encrypted_rtp_header_extensions(true);
f2_.set_enable_encrypted_rtp_header_extensions(true);
f1_.set_audio_rtp_header_extensions(MAKE_VECTOR(kAudioRtpExtension1));
f1_.set_video_rtp_header_extensions(MAKE_VECTOR(kVideoRtpExtension1));
f2_.set_audio_rtp_header_extensions(MAKE_VECTOR(kAudioRtpExtension2));
f2_.set_video_rtp_header_extensions(MAKE_VECTOR(kVideoRtpExtension2));
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
EXPECT_EQ(
MAKE_VECTOR(kAudioRtpExtensionEncrypted1),
GetFirstAudioContentDescription(offer.get())->rtp_header_extensions());
EXPECT_EQ(
MAKE_VECTOR(kVideoRtpExtensionEncrypted1),
GetFirstVideoContentDescription(offer.get())->rtp_header_extensions());
EXPECT_EQ(
MAKE_VECTOR(kAudioRtpExtensionEncryptedAnswer),
GetFirstAudioContentDescription(answer.get())->rtp_header_extensions());
EXPECT_EQ(
MAKE_VECTOR(kVideoRtpExtensionEncryptedAnswer),
GetFirstVideoContentDescription(answer.get())->rtp_header_extensions());
}
TEST_F(MediaSessionDescriptionFactoryTest,
TestOfferAnswerWithEncryptedRtpExtensionsOffer) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
f1_.set_enable_encrypted_rtp_header_extensions(true);
f1_.set_audio_rtp_header_extensions(MAKE_VECTOR(kAudioRtpExtension1));
f1_.set_video_rtp_header_extensions(MAKE_VECTOR(kVideoRtpExtension1));
f2_.set_audio_rtp_header_extensions(MAKE_VECTOR(kAudioRtpExtension2));
f2_.set_video_rtp_header_extensions(MAKE_VECTOR(kVideoRtpExtension2));
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
EXPECT_EQ(
MAKE_VECTOR(kAudioRtpExtensionEncrypted1),
GetFirstAudioContentDescription(offer.get())->rtp_header_extensions());
EXPECT_EQ(
MAKE_VECTOR(kVideoRtpExtensionEncrypted1),
GetFirstVideoContentDescription(offer.get())->rtp_header_extensions());
EXPECT_EQ(
MAKE_VECTOR(kAudioRtpExtensionAnswer),
GetFirstAudioContentDescription(answer.get())->rtp_header_extensions());
EXPECT_EQ(
MAKE_VECTOR(kVideoRtpExtensionAnswer),
GetFirstVideoContentDescription(answer.get())->rtp_header_extensions());
}
TEST_F(MediaSessionDescriptionFactoryTest,
TestOfferAnswerWithEncryptedRtpExtensionsAnswer) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
f2_.set_enable_encrypted_rtp_header_extensions(true);
f1_.set_audio_rtp_header_extensions(MAKE_VECTOR(kAudioRtpExtension1));
f1_.set_video_rtp_header_extensions(MAKE_VECTOR(kVideoRtpExtension1));
f2_.set_audio_rtp_header_extensions(MAKE_VECTOR(kAudioRtpExtension2));
f2_.set_video_rtp_header_extensions(MAKE_VECTOR(kVideoRtpExtension2));
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
EXPECT_EQ(
MAKE_VECTOR(kAudioRtpExtension1),
GetFirstAudioContentDescription(offer.get())->rtp_header_extensions());
EXPECT_EQ(
MAKE_VECTOR(kVideoRtpExtension1),
GetFirstVideoContentDescription(offer.get())->rtp_header_extensions());
EXPECT_EQ(
MAKE_VECTOR(kAudioRtpExtensionAnswer),
GetFirstAudioContentDescription(answer.get())->rtp_header_extensions());
EXPECT_EQ(
MAKE_VECTOR(kVideoRtpExtensionAnswer),
GetFirstVideoContentDescription(answer.get())->rtp_header_extensions());
}
// Create an audio, video, data answer without legacy StreamParams.
TEST_F(MediaSessionDescriptionFactoryTest,
TestCreateAnswerWithoutLegacyStreams) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
AddDataSection(cricket::DCT_RTP, RtpTransceiverDirection::kRecvOnly, &opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
const ContentInfo* ac = answer->GetContentByName("audio");
const ContentInfo* vc = answer->GetContentByName("video");
const ContentInfo* dc = answer->GetContentByName("data");
ASSERT_TRUE(ac != NULL);
ASSERT_TRUE(vc != NULL);
const AudioContentDescription* acd = ac->media_description()->as_audio();
const VideoContentDescription* vcd = vc->media_description()->as_video();
const RtpDataContentDescription* dcd = dc->media_description()->as_rtp_data();
EXPECT_FALSE(acd->has_ssrcs()); // No StreamParams.
EXPECT_FALSE(vcd->has_ssrcs()); // No StreamParams.
EXPECT_FALSE(dcd->has_ssrcs()); // No StreamParams.
}
// Create a typical video answer, and ensure it matches what we expect.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateVideoAnswerRtcpMux) {
MediaSessionOptions offer_opts;
AddAudioVideoSections(RtpTransceiverDirection::kSendRecv, &offer_opts);
AddDataSection(cricket::DCT_RTP, RtpTransceiverDirection::kSendRecv,
&offer_opts);
MediaSessionOptions answer_opts;
AddAudioVideoSections(RtpTransceiverDirection::kSendRecv, &answer_opts);
AddDataSection(cricket::DCT_RTP, RtpTransceiverDirection::kSendRecv,
&answer_opts);
std::unique_ptr<SessionDescription> offer;
std::unique_ptr<SessionDescription> answer;
offer_opts.rtcp_mux_enabled = true;
answer_opts.rtcp_mux_enabled = true;
offer = f1_.CreateOffer(offer_opts, NULL);
answer = f2_.CreateAnswer(offer.get(), answer_opts, NULL);
ASSERT_TRUE(NULL != GetFirstAudioContentDescription(offer.get()));
ASSERT_TRUE(NULL != GetFirstVideoContentDescription(offer.get()));
ASSERT_TRUE(NULL != GetFirstRtpDataContentDescription(offer.get()));
ASSERT_TRUE(NULL != GetFirstAudioContentDescription(answer.get()));
ASSERT_TRUE(NULL != GetFirstVideoContentDescription(answer.get()));
ASSERT_TRUE(NULL != GetFirstRtpDataContentDescription(answer.get()));
EXPECT_TRUE(GetFirstAudioContentDescription(offer.get())->rtcp_mux());
EXPECT_TRUE(GetFirstVideoContentDescription(offer.get())->rtcp_mux());
EXPECT_TRUE(GetFirstRtpDataContentDescription(offer.get())->rtcp_mux());
EXPECT_TRUE(GetFirstAudioContentDescription(answer.get())->rtcp_mux());
EXPECT_TRUE(GetFirstVideoContentDescription(answer.get())->rtcp_mux());
EXPECT_TRUE(GetFirstRtpDataContentDescription(answer.get())->rtcp_mux());
offer_opts.rtcp_mux_enabled = true;
answer_opts.rtcp_mux_enabled = false;
offer = f1_.CreateOffer(offer_opts, NULL);
answer = f2_.CreateAnswer(offer.get(), answer_opts, NULL);
ASSERT_TRUE(NULL != GetFirstAudioContentDescription(offer.get()));
ASSERT_TRUE(NULL != GetFirstVideoContentDescription(offer.get()));
ASSERT_TRUE(NULL != GetFirstRtpDataContentDescription(offer.get()));
ASSERT_TRUE(NULL != GetFirstAudioContentDescription(answer.get()));
ASSERT_TRUE(NULL != GetFirstVideoContentDescription(answer.get()));
ASSERT_TRUE(NULL != GetFirstRtpDataContentDescription(answer.get()));
EXPECT_TRUE(GetFirstAudioContentDescription(offer.get())->rtcp_mux());
EXPECT_TRUE(GetFirstVideoContentDescription(offer.get())->rtcp_mux());
EXPECT_TRUE(GetFirstRtpDataContentDescription(offer.get())->rtcp_mux());
EXPECT_FALSE(GetFirstAudioContentDescription(answer.get())->rtcp_mux());
EXPECT_FALSE(GetFirstVideoContentDescription(answer.get())->rtcp_mux());
EXPECT_FALSE(GetFirstRtpDataContentDescription(answer.get())->rtcp_mux());
offer_opts.rtcp_mux_enabled = false;
answer_opts.rtcp_mux_enabled = true;
offer = f1_.CreateOffer(offer_opts, NULL);
answer = f2_.CreateAnswer(offer.get(), answer_opts, NULL);
ASSERT_TRUE(NULL != GetFirstAudioContentDescription(offer.get()));
ASSERT_TRUE(NULL != GetFirstVideoContentDescription(offer.get()));
ASSERT_TRUE(NULL != GetFirstRtpDataContentDescription(offer.get()));
ASSERT_TRUE(NULL != GetFirstAudioContentDescription(answer.get()));
ASSERT_TRUE(NULL != GetFirstVideoContentDescription(answer.get()));
ASSERT_TRUE(NULL != GetFirstRtpDataContentDescription(answer.get()));
EXPECT_FALSE(GetFirstAudioContentDescription(offer.get())->rtcp_mux());
EXPECT_FALSE(GetFirstVideoContentDescription(offer.get())->rtcp_mux());
EXPECT_FALSE(GetFirstRtpDataContentDescription(offer.get())->rtcp_mux());
EXPECT_FALSE(GetFirstAudioContentDescription(answer.get())->rtcp_mux());
EXPECT_FALSE(GetFirstVideoContentDescription(answer.get())->rtcp_mux());
EXPECT_FALSE(GetFirstRtpDataContentDescription(answer.get())->rtcp_mux());
offer_opts.rtcp_mux_enabled = false;
answer_opts.rtcp_mux_enabled = false;
offer = f1_.CreateOffer(offer_opts, NULL);
answer = f2_.CreateAnswer(offer.get(), answer_opts, NULL);
ASSERT_TRUE(NULL != GetFirstAudioContentDescription(offer.get()));
ASSERT_TRUE(NULL != GetFirstVideoContentDescription(offer.get()));
ASSERT_TRUE(NULL != GetFirstRtpDataContentDescription(offer.get()));
ASSERT_TRUE(NULL != GetFirstAudioContentDescription(answer.get()));
ASSERT_TRUE(NULL != GetFirstVideoContentDescription(answer.get()));
ASSERT_TRUE(NULL != GetFirstRtpDataContentDescription(answer.get()));
EXPECT_FALSE(GetFirstAudioContentDescription(offer.get())->rtcp_mux());
EXPECT_FALSE(GetFirstVideoContentDescription(offer.get())->rtcp_mux());
EXPECT_FALSE(GetFirstRtpDataContentDescription(offer.get())->rtcp_mux());
EXPECT_FALSE(GetFirstAudioContentDescription(answer.get())->rtcp_mux());
EXPECT_FALSE(GetFirstVideoContentDescription(answer.get())->rtcp_mux());
EXPECT_FALSE(GetFirstRtpDataContentDescription(answer.get())->rtcp_mux());
}
// Create an audio-only answer to a video offer.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateAudioAnswerToVideo) {
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio",
RtpTransceiverDirection::kRecvOnly, kActive,
&opts);
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kRecvOnly, kActive,
&opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
opts.media_description_options[1].stopped = true;
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
const ContentInfo* ac = answer->GetContentByName("audio");
const ContentInfo* vc = answer->GetContentByName("video");
ASSERT_TRUE(ac != NULL);
ASSERT_TRUE(vc != NULL);
ASSERT_TRUE(vc->media_description() != NULL);
EXPECT_TRUE(vc->rejected);
}
// Create an audio-only answer to an offer with data.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateNoDataAnswerToDataOffer) {
MediaSessionOptions opts = CreatePlanBMediaSessionOptions();
opts.data_channel_type = cricket::DCT_RTP;
AddMediaDescriptionOptions(MEDIA_TYPE_DATA, "data",
RtpTransceiverDirection::kRecvOnly, kActive,
&opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
opts.media_description_options[1].stopped = true;
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
const ContentInfo* ac = answer->GetContentByName("audio");
const ContentInfo* dc = answer->GetContentByName("data");
ASSERT_TRUE(ac != NULL);
ASSERT_TRUE(dc != NULL);
ASSERT_TRUE(dc->media_description() != NULL);
EXPECT_TRUE(dc->rejected);
}
// Create an answer that rejects the contents which are rejected in the offer.
TEST_F(MediaSessionDescriptionFactoryTest,
CreateAnswerToOfferWithRejectedMedia) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
AddDataSection(cricket::DCT_RTP, RtpTransceiverDirection::kRecvOnly, &opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
ContentInfo* ac = offer->GetContentByName("audio");
ContentInfo* vc = offer->GetContentByName("video");
ContentInfo* dc = offer->GetContentByName("data");
ASSERT_TRUE(ac != NULL);
ASSERT_TRUE(vc != NULL);
ASSERT_TRUE(dc != NULL);
ac->rejected = true;
vc->rejected = true;
dc->rejected = true;
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
ac = answer->GetContentByName("audio");
vc = answer->GetContentByName("video");
dc = answer->GetContentByName("data");
ASSERT_TRUE(ac != NULL);
ASSERT_TRUE(vc != NULL);
ASSERT_TRUE(dc != NULL);
EXPECT_TRUE(ac->rejected);
EXPECT_TRUE(vc->rejected);
EXPECT_TRUE(dc->rejected);
}
TEST_F(MediaSessionDescriptionFactoryTest,
CreateAnswerSupportsMixedOneAndTwoByteHeaderExtensions) {
MediaSessionOptions opts;
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
// Offer without request of mixed one- and two-byte header extensions.
offer->set_extmap_allow_mixed(false);
ASSERT_TRUE(offer.get() != NULL);
std::unique_ptr<SessionDescription> answer_no_support(
f2_.CreateAnswer(offer.get(), opts, NULL));
EXPECT_FALSE(answer_no_support->extmap_allow_mixed());
// Offer with request of mixed one- and two-byte header extensions.
offer->set_extmap_allow_mixed(true);
ASSERT_TRUE(offer.get() != NULL);
std::unique_ptr<SessionDescription> answer_support(
f2_.CreateAnswer(offer.get(), opts, NULL));
EXPECT_TRUE(answer_support->extmap_allow_mixed());
}
TEST_F(MediaSessionDescriptionFactoryTest,
CreateAnswerSupportsMixedOneAndTwoByteHeaderExtensionsOnMediaLevel) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kSendRecv, &opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
MediaContentDescription* video_offer =
offer->GetContentDescriptionByName("video");
ASSERT_TRUE(video_offer);
MediaContentDescription* audio_offer =
offer->GetContentDescriptionByName("audio");
ASSERT_TRUE(audio_offer);
// Explicit disable of mixed one-two byte header support in offer.
video_offer->set_extmap_allow_mixed_enum(MediaContentDescription::kNo);
audio_offer->set_extmap_allow_mixed_enum(MediaContentDescription::kNo);
ASSERT_TRUE(offer.get() != NULL);
std::unique_ptr<SessionDescription> answer_no_support(
f2_.CreateAnswer(offer.get(), opts, NULL));
MediaContentDescription* video_answer =
answer_no_support->GetContentDescriptionByName("video");
MediaContentDescription* audio_answer =
answer_no_support->GetContentDescriptionByName("audio");
EXPECT_EQ(MediaContentDescription::kNo,
video_answer->extmap_allow_mixed_enum());
EXPECT_EQ(MediaContentDescription::kNo,
audio_answer->extmap_allow_mixed_enum());
// Enable mixed one-two byte header support in offer.
video_offer->set_extmap_allow_mixed_enum(MediaContentDescription::kMedia);
audio_offer->set_extmap_allow_mixed_enum(MediaContentDescription::kMedia);
ASSERT_TRUE(offer.get() != NULL);
std::unique_ptr<SessionDescription> answer_support(
f2_.CreateAnswer(offer.get(), opts, NULL));
video_answer = answer_support->GetContentDescriptionByName("video");
audio_answer = answer_support->GetContentDescriptionByName("audio");
EXPECT_EQ(MediaContentDescription::kMedia,
video_answer->extmap_allow_mixed_enum());
EXPECT_EQ(MediaContentDescription::kMedia,
audio_answer->extmap_allow_mixed_enum());
}
// Create an audio and video offer with:
// - one video track
// - two audio tracks
// - two data tracks
// and ensure it matches what we expect. Also updates the initial offer by
// adding a new video track and replaces one of the audio tracks.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateMultiStreamVideoOffer) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kSendRecv, &opts);
AttachSenderToMediaDescriptionOptions("video", MEDIA_TYPE_VIDEO, kVideoTrack1,
{kMediaStream1}, 1, &opts);
AttachSenderToMediaDescriptionOptions("audio", MEDIA_TYPE_AUDIO, kAudioTrack1,
{kMediaStream1}, 1, &opts);
AttachSenderToMediaDescriptionOptions("audio", MEDIA_TYPE_AUDIO, kAudioTrack2,
{kMediaStream1}, 1, &opts);
AddDataSection(cricket::DCT_RTP, RtpTransceiverDirection::kSendRecv, &opts);
AttachSenderToMediaDescriptionOptions("data", MEDIA_TYPE_DATA, kDataTrack1,
{kMediaStream1}, 1, &opts);
AttachSenderToMediaDescriptionOptions("data", MEDIA_TYPE_DATA, kDataTrack2,
{kMediaStream1}, 1, &opts);
f1_.set_secure(SEC_ENABLED);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
const ContentInfo* ac = offer->GetContentByName("audio");
const ContentInfo* vc = offer->GetContentByName("video");
const ContentInfo* dc = offer->GetContentByName("data");
ASSERT_TRUE(ac != NULL);
ASSERT_TRUE(vc != NULL);
ASSERT_TRUE(dc != NULL);
const AudioContentDescription* acd = ac->media_description()->as_audio();
const VideoContentDescription* vcd = vc->media_description()->as_video();
const RtpDataContentDescription* dcd = dc->media_description()->as_rtp_data();
EXPECT_EQ(MEDIA_TYPE_AUDIO, acd->type());
EXPECT_EQ(f1_.audio_sendrecv_codecs(), acd->codecs());
const StreamParamsVec& audio_streams = acd->streams();
ASSERT_EQ(2U, audio_streams.size());
EXPECT_EQ(audio_streams[0].cname, audio_streams[1].cname);
EXPECT_EQ(kAudioTrack1, audio_streams[0].id);
ASSERT_EQ(1U, audio_streams[0].ssrcs.size());
EXPECT_NE(0U, audio_streams[0].ssrcs[0]);
EXPECT_EQ(kAudioTrack2, audio_streams[1].id);
ASSERT_EQ(1U, audio_streams[1].ssrcs.size());
EXPECT_NE(0U, audio_streams[1].ssrcs[0]);
EXPECT_EQ(kAutoBandwidth, acd->bandwidth()); // default bandwidth (auto)
EXPECT_TRUE(acd->rtcp_mux()); // rtcp-mux defaults on
ASSERT_CRYPTO(acd, 1U, kDefaultSrtpCryptoSuite);
EXPECT_EQ(MEDIA_TYPE_VIDEO, vcd->type());
EXPECT_EQ(f1_.video_sendrecv_codecs(), vcd->codecs());
ASSERT_CRYPTO(vcd, 1U, kDefaultSrtpCryptoSuite);
const StreamParamsVec& video_streams = vcd->streams();
ASSERT_EQ(1U, video_streams.size());
EXPECT_EQ(video_streams[0].cname, audio_streams[0].cname);
EXPECT_EQ(kVideoTrack1, video_streams[0].id);
EXPECT_EQ(kAutoBandwidth, vcd->bandwidth()); // default bandwidth (auto)
EXPECT_TRUE(vcd->rtcp_mux()); // rtcp-mux defaults on
EXPECT_EQ(MEDIA_TYPE_DATA, dcd->type());
EXPECT_EQ(f1_.rtp_data_codecs(), dcd->codecs());
ASSERT_CRYPTO(dcd, 1U, kDefaultSrtpCryptoSuite);
const StreamParamsVec& data_streams = dcd->streams();
ASSERT_EQ(2U, data_streams.size());
EXPECT_EQ(data_streams[0].cname, data_streams[1].cname);
EXPECT_EQ(kDataTrack1, data_streams[0].id);
ASSERT_EQ(1U, data_streams[0].ssrcs.size());
EXPECT_NE(0U, data_streams[0].ssrcs[0]);
EXPECT_EQ(kDataTrack2, data_streams[1].id);
ASSERT_EQ(1U, data_streams[1].ssrcs.size());
EXPECT_NE(0U, data_streams[1].ssrcs[0]);
EXPECT_EQ(cricket::kDataMaxBandwidth,
dcd->bandwidth()); // default bandwidth (auto)
EXPECT_TRUE(dcd->rtcp_mux()); // rtcp-mux defaults on
ASSERT_CRYPTO(dcd, 1U, kDefaultSrtpCryptoSuite);
// Update the offer. Add a new video track that is not synched to the
// other tracks and replace audio track 2 with audio track 3.
AttachSenderToMediaDescriptionOptions("video", MEDIA_TYPE_VIDEO, kVideoTrack2,
{kMediaStream2}, 1, &opts);
DetachSenderFromMediaSection("audio", kAudioTrack2, &opts);
AttachSenderToMediaDescriptionOptions("audio", MEDIA_TYPE_AUDIO, kAudioTrack3,
{kMediaStream1}, 1, &opts);
DetachSenderFromMediaSection("data", kDataTrack2, &opts);
AttachSenderToMediaDescriptionOptions("data", MEDIA_TYPE_DATA, kDataTrack3,
{kMediaStream1}, 1, &opts);
std::unique_ptr<SessionDescription> updated_offer(
f1_.CreateOffer(opts, offer.get()));
ASSERT_TRUE(updated_offer.get() != NULL);
ac = updated_offer->GetContentByName("audio");
vc = updated_offer->GetContentByName("video");
dc = updated_offer->GetContentByName("data");
ASSERT_TRUE(ac != NULL);
ASSERT_TRUE(vc != NULL);
ASSERT_TRUE(dc != NULL);
const AudioContentDescription* updated_acd =
ac->media_description()->as_audio();
const VideoContentDescription* updated_vcd =
vc->media_description()->as_video();
const RtpDataContentDescription* updated_dcd =
dc->media_description()->as_rtp_data();
EXPECT_EQ(acd->type(), updated_acd->type());
EXPECT_EQ(acd->codecs(), updated_acd->codecs());
EXPECT_EQ(vcd->type(), updated_vcd->type());
EXPECT_EQ(vcd->codecs(), updated_vcd->codecs());
EXPECT_EQ(dcd->type(), updated_dcd->type());
EXPECT_EQ(dcd->codecs(), updated_dcd->codecs());
ASSERT_CRYPTO(updated_acd, 1U, kDefaultSrtpCryptoSuite);
EXPECT_TRUE(CompareCryptoParams(acd->cryptos(), updated_acd->cryptos()));
ASSERT_CRYPTO(updated_vcd, 1U, kDefaultSrtpCryptoSuite);
EXPECT_TRUE(CompareCryptoParams(vcd->cryptos(), updated_vcd->cryptos()));
ASSERT_CRYPTO(updated_dcd, 1U, kDefaultSrtpCryptoSuite);
EXPECT_TRUE(CompareCryptoParams(dcd->cryptos(), updated_dcd->cryptos()));
const StreamParamsVec& updated_audio_streams = updated_acd->streams();
ASSERT_EQ(2U, updated_audio_streams.size());
EXPECT_EQ(audio_streams[0], updated_audio_streams[0]);
EXPECT_EQ(kAudioTrack3, updated_audio_streams[1].id); // New audio track.
ASSERT_EQ(1U, updated_audio_streams[1].ssrcs.size());
EXPECT_NE(0U, updated_audio_streams[1].ssrcs[0]);
EXPECT_EQ(updated_audio_streams[0].cname, updated_audio_streams[1].cname);
const StreamParamsVec& updated_video_streams = updated_vcd->streams();
ASSERT_EQ(2U, updated_video_streams.size());
EXPECT_EQ(video_streams[0], updated_video_streams[0]);
EXPECT_EQ(kVideoTrack2, updated_video_streams[1].id);
// All the media streams in one PeerConnection share one RTCP CNAME.
EXPECT_EQ(updated_video_streams[1].cname, updated_video_streams[0].cname);
const StreamParamsVec& updated_data_streams = updated_dcd->streams();
ASSERT_EQ(2U, updated_data_streams.size());
EXPECT_EQ(data_streams[0], updated_data_streams[0]);
EXPECT_EQ(kDataTrack3, updated_data_streams[1].id); // New data track.
ASSERT_EQ(1U, updated_data_streams[1].ssrcs.size());
EXPECT_NE(0U, updated_data_streams[1].ssrcs[0]);
EXPECT_EQ(updated_data_streams[0].cname, updated_data_streams[1].cname);
// The stream correctly got the CNAME from the MediaSessionOptions.
// The Expected RTCP CNAME is the default one as we are using the default
// MediaSessionOptions.
EXPECT_EQ(updated_data_streams[0].cname, cricket::kDefaultRtcpCname);
}
// Create an offer with simulcast video stream.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateSimulcastVideoOffer) {
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio",
RtpTransceiverDirection::kRecvOnly, kActive,
&opts);
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
const int num_sim_layers = 3;
AttachSenderToMediaDescriptionOptions("video", MEDIA_TYPE_VIDEO, kVideoTrack1,
{kMediaStream1}, num_sim_layers, &opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
const ContentInfo* vc = offer->GetContentByName("video");
ASSERT_TRUE(vc != NULL);
const VideoContentDescription* vcd = vc->media_description()->as_video();
const StreamParamsVec& video_streams = vcd->streams();
ASSERT_EQ(1U, video_streams.size());
EXPECT_EQ(kVideoTrack1, video_streams[0].id);
const SsrcGroup* sim_ssrc_group =
video_streams[0].get_ssrc_group(cricket::kSimSsrcGroupSemantics);
ASSERT_TRUE(sim_ssrc_group != NULL);
EXPECT_EQ(static_cast<size_t>(num_sim_layers), sim_ssrc_group->ssrcs.size());
}
MATCHER(RidDescriptionEquals, "Verifies that two RidDescriptions are equal.") {
const RidDescription& rid1 = ::testing::get<0>(arg);
const RidDescription& rid2 = ::testing::get<1>(arg);
return rid1.rid == rid2.rid && rid1.direction == rid2.direction;
}
static void CheckSimulcastInSessionDescription(
const SessionDescription* description,
const std::string& content_name,
const std::vector<RidDescription>& send_rids,
const SimulcastLayerList& send_layers) {
ASSERT_NE(description, nullptr);
const ContentInfo* content = description->GetContentByName(content_name);
ASSERT_NE(content, nullptr);
const MediaContentDescription* cd = content->media_description();
ASSERT_NE(cd, nullptr);
const StreamParamsVec& streams = cd->streams();
ASSERT_THAT(streams, SizeIs(1));
const StreamParams& stream = streams[0];
ASSERT_THAT(stream.ssrcs, IsEmpty());
EXPECT_TRUE(stream.has_rids());
const std::vector<RidDescription> rids = stream.rids();
EXPECT_THAT(rids, Pointwise(RidDescriptionEquals(), send_rids));
EXPECT_TRUE(cd->HasSimulcast());
const SimulcastDescription& simulcast = cd->simulcast_description();
EXPECT_THAT(simulcast.send_layers(), SizeIs(send_layers.size()));
EXPECT_THAT(simulcast.send_layers(), Pointwise(Eq(), send_layers));
ASSERT_THAT(simulcast.receive_layers().GetAllLayers(), SizeIs(0));
}
// Create an offer with spec-compliant simulcast video stream.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateCompliantSimulcastOffer) {
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
std::vector<RidDescription> send_rids;
send_rids.push_back(RidDescription("f", RidDirection::kSend));
send_rids.push_back(RidDescription("h", RidDirection::kSend));
send_rids.push_back(RidDescription("q", RidDirection::kSend));
SimulcastLayerList simulcast_layers;
simulcast_layers.AddLayer(SimulcastLayer(send_rids[0].rid, false));
simulcast_layers.AddLayer(SimulcastLayer(send_rids[1].rid, true));
simulcast_layers.AddLayer(SimulcastLayer(send_rids[2].rid, false));
AttachSenderToMediaDescriptionOptions("video", MEDIA_TYPE_VIDEO, kVideoTrack1,
{kMediaStream1}, send_rids,
simulcast_layers, 0, &opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
CheckSimulcastInSessionDescription(offer.get(), "video", send_rids,
simulcast_layers);
}
// Create an offer that signals RIDs (not SSRCs) without Simulcast.
// In this scenario, RIDs do not need to be negotiated (there is only one).
TEST_F(MediaSessionDescriptionFactoryTest, TestOfferWithRidsNoSimulcast) {
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
RidDescription rid("f", RidDirection::kSend);
AttachSenderToMediaDescriptionOptions("video", MEDIA_TYPE_VIDEO, kVideoTrack1,
{kMediaStream1}, {rid},
SimulcastLayerList(), 0, &opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
ASSERT_NE(offer.get(), nullptr);
const ContentInfo* content = offer->GetContentByName("video");
ASSERT_NE(content, nullptr);
const MediaContentDescription* cd = content->media_description();
ASSERT_NE(cd, nullptr);
const StreamParamsVec& streams = cd->streams();
ASSERT_THAT(streams, SizeIs(1));
const StreamParams& stream = streams[0];
ASSERT_THAT(stream.ssrcs, IsEmpty());
EXPECT_FALSE(stream.has_rids());
EXPECT_FALSE(cd->HasSimulcast());
}
// Create an answer with spec-compliant simulcast video stream.
// In this scenario, the SFU is the caller requesting that we send Simulcast.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateCompliantSimulcastAnswer) {
MediaSessionOptions offer_opts;
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kSendRecv, kActive,
&offer_opts);
AttachSenderToMediaDescriptionOptions("video", MEDIA_TYPE_VIDEO, kVideoTrack1,
{kMediaStream1}, 1, &offer_opts);
std::unique_ptr<SessionDescription> offer =
f1_.CreateOffer(offer_opts, nullptr);
MediaSessionOptions answer_opts;
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kSendRecv, kActive,
&answer_opts);
std::vector<RidDescription> rid_descriptions{
RidDescription("f", RidDirection::kSend),
RidDescription("h", RidDirection::kSend),
RidDescription("q", RidDirection::kSend),
};
SimulcastLayerList simulcast_layers;
simulcast_layers.AddLayer(SimulcastLayer(rid_descriptions[0].rid, false));
simulcast_layers.AddLayer(SimulcastLayer(rid_descriptions[1].rid, true));
simulcast_layers.AddLayer(SimulcastLayer(rid_descriptions[2].rid, false));
AttachSenderToMediaDescriptionOptions("video", MEDIA_TYPE_VIDEO, kVideoTrack1,
{kMediaStream1}, rid_descriptions,
simulcast_layers, 0, &answer_opts);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), answer_opts, nullptr);
CheckSimulcastInSessionDescription(answer.get(), "video", rid_descriptions,
simulcast_layers);
}
// Create an answer that signals RIDs (not SSRCs) without Simulcast.
// In this scenario, RIDs do not need to be negotiated (there is only one).
// Note that RID Direction is not the same as the transceiver direction.
TEST_F(MediaSessionDescriptionFactoryTest, TestAnswerWithRidsNoSimulcast) {
MediaSessionOptions offer_opts;
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kSendRecv, kActive,
&offer_opts);
RidDescription rid_offer("f", RidDirection::kSend);
AttachSenderToMediaDescriptionOptions("video", MEDIA_TYPE_VIDEO, kVideoTrack1,
{kMediaStream1}, {rid_offer},
SimulcastLayerList(), 0, &offer_opts);
std::unique_ptr<SessionDescription> offer =
f1_.CreateOffer(offer_opts, nullptr);
MediaSessionOptions answer_opts;
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kSendRecv, kActive,
&answer_opts);
RidDescription rid_answer("f", RidDirection::kReceive);
AttachSenderToMediaDescriptionOptions("video", MEDIA_TYPE_VIDEO, kVideoTrack1,
{kMediaStream1}, {rid_answer},
SimulcastLayerList(), 0, &answer_opts);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), answer_opts, nullptr);
ASSERT_NE(answer.get(), nullptr);
const ContentInfo* content = offer->GetContentByName("video");
ASSERT_NE(content, nullptr);
const MediaContentDescription* cd = content->media_description();
ASSERT_NE(cd, nullptr);
const StreamParamsVec& streams = cd->streams();
ASSERT_THAT(streams, SizeIs(1));
const StreamParams& stream = streams[0];
ASSERT_THAT(stream.ssrcs, IsEmpty());
EXPECT_FALSE(stream.has_rids());
EXPECT_FALSE(cd->HasSimulcast());
}
// Create an audio and video answer to a standard video offer with:
// - one video track
// - two audio tracks
// - two data tracks
// and ensure it matches what we expect. Also updates the initial answer by
// adding a new video track and removes one of the audio tracks.
TEST_F(MediaSessionDescriptionFactoryTest, TestCreateMultiStreamVideoAnswer) {
MediaSessionOptions offer_opts;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio",
RtpTransceiverDirection::kRecvOnly, kActive,
&offer_opts);
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kRecvOnly, kActive,
&offer_opts);
offer_opts.data_channel_type = cricket::DCT_RTP;
AddMediaDescriptionOptions(MEDIA_TYPE_DATA, "data",
RtpTransceiverDirection::kRecvOnly, kActive,
&offer_opts);
f1_.set_secure(SEC_ENABLED);
f2_.set_secure(SEC_ENABLED);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(offer_opts, NULL);
MediaSessionOptions answer_opts;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio",
RtpTransceiverDirection::kSendRecv, kActive,
&answer_opts);
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kSendRecv, kActive,
&answer_opts);
AttachSenderToMediaDescriptionOptions("video", MEDIA_TYPE_VIDEO, kVideoTrack1,
{kMediaStream1}, 1, &answer_opts);
AttachSenderToMediaDescriptionOptions("audio", MEDIA_TYPE_AUDIO, kAudioTrack1,
{kMediaStream1}, 1, &answer_opts);
AttachSenderToMediaDescriptionOptions("audio", MEDIA_TYPE_AUDIO, kAudioTrack2,
{kMediaStream1}, 1, &answer_opts);
AddMediaDescriptionOptions(MEDIA_TYPE_DATA, "data",
RtpTransceiverDirection::kSendRecv, kActive,
&answer_opts);
AttachSenderToMediaDescriptionOptions("data", MEDIA_TYPE_DATA, kDataTrack1,
{kMediaStream1}, 1, &answer_opts);
AttachSenderToMediaDescriptionOptions("data", MEDIA_TYPE_DATA, kDataTrack2,
{kMediaStream1}, 1, &answer_opts);
answer_opts.data_channel_type = cricket::DCT_RTP;
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), answer_opts, NULL);
ASSERT_TRUE(answer.get() != NULL);
const ContentInfo* ac = answer->GetContentByName("audio");
const ContentInfo* vc = answer->GetContentByName("video");
const ContentInfo* dc = answer->GetContentByName("data");
ASSERT_TRUE(ac != NULL);
ASSERT_TRUE(vc != NULL);
ASSERT_TRUE(dc != NULL);
const AudioContentDescription* acd = ac->media_description()->as_audio();
const VideoContentDescription* vcd = vc->media_description()->as_video();
const RtpDataContentDescription* dcd = dc->media_description()->as_rtp_data();
ASSERT_CRYPTO(acd, 1U, kDefaultSrtpCryptoSuite);
ASSERT_CRYPTO(vcd, 1U, kDefaultSrtpCryptoSuite);
ASSERT_CRYPTO(dcd, 1U, kDefaultSrtpCryptoSuite);
EXPECT_EQ(MEDIA_TYPE_AUDIO, acd->type());
EXPECT_THAT(acd->codecs(), ElementsAreArray(kAudioCodecsAnswer));
const StreamParamsVec& audio_streams = acd->streams();
ASSERT_EQ(2U, audio_streams.size());
EXPECT_TRUE(audio_streams[0].cname == audio_streams[1].cname);
EXPECT_EQ(kAudioTrack1, audio_streams[0].id);
ASSERT_EQ(1U, audio_streams[0].ssrcs.size());
EXPECT_NE(0U, audio_streams[0].ssrcs[0]);
EXPECT_EQ(kAudioTrack2, audio_streams[1].id);
ASSERT_EQ(1U, audio_streams[1].ssrcs.size());
EXPECT_NE(0U, audio_streams[1].ssrcs[0]);
EXPECT_EQ(kAutoBandwidth, acd->bandwidth()); // default bandwidth (auto)
EXPECT_TRUE(acd->rtcp_mux()); // rtcp-mux defaults on
EXPECT_EQ(MEDIA_TYPE_VIDEO, vcd->type());
EXPECT_THAT(vcd->codecs(), ElementsAreArray(kVideoCodecsAnswer));
const StreamParamsVec& video_streams = vcd->streams();
ASSERT_EQ(1U, video_streams.size());
EXPECT_EQ(video_streams[0].cname, audio_streams[0].cname);
EXPECT_EQ(kVideoTrack1, video_streams[0].id);
EXPECT_EQ(kAutoBandwidth, vcd->bandwidth()); // default bandwidth (auto)
EXPECT_TRUE(vcd->rtcp_mux()); // rtcp-mux defaults on
EXPECT_EQ(MEDIA_TYPE_DATA, dcd->type());
EXPECT_THAT(dcd->codecs(), ElementsAreArray(kDataCodecsAnswer));
const StreamParamsVec& data_streams = dcd->streams();
ASSERT_EQ(2U, data_streams.size());
EXPECT_TRUE(data_streams[0].cname == data_streams[1].cname);
EXPECT_EQ(kDataTrack1, data_streams[0].id);
ASSERT_EQ(1U, data_streams[0].ssrcs.size());
EXPECT_NE(0U, data_streams[0].ssrcs[0]);
EXPECT_EQ(kDataTrack2, data_streams[1].id);
ASSERT_EQ(1U, data_streams[1].ssrcs.size());
EXPECT_NE(0U, data_streams[1].ssrcs[0]);
EXPECT_EQ(cricket::kDataMaxBandwidth,
dcd->bandwidth()); // default bandwidth (auto)
EXPECT_TRUE(dcd->rtcp_mux()); // rtcp-mux defaults on
// Update the answer. Add a new video track that is not synched to the
// other tracks and remove 1 audio track.
AttachSenderToMediaDescriptionOptions("video", MEDIA_TYPE_VIDEO, kVideoTrack2,
{kMediaStream2}, 1, &answer_opts);
DetachSenderFromMediaSection("audio", kAudioTrack2, &answer_opts);
DetachSenderFromMediaSection("data", kDataTrack2, &answer_opts);
std::unique_ptr<SessionDescription> updated_answer(
f2_.CreateAnswer(offer.get(), answer_opts, answer.get()));
ASSERT_TRUE(updated_answer.get() != NULL);
ac = updated_answer->GetContentByName("audio");
vc = updated_answer->GetContentByName("video");
dc = updated_answer->GetContentByName("data");
ASSERT_TRUE(ac != NULL);
ASSERT_TRUE(vc != NULL);
ASSERT_TRUE(dc != NULL);
const AudioContentDescription* updated_acd =
ac->media_description()->as_audio();
const VideoContentDescription* updated_vcd =
vc->media_description()->as_video();
const RtpDataContentDescription* updated_dcd =
dc->media_description()->as_rtp_data();
ASSERT_CRYPTO(updated_acd, 1U, kDefaultSrtpCryptoSuite);
EXPECT_TRUE(CompareCryptoParams(acd->cryptos(), updated_acd->cryptos()));
ASSERT_CRYPTO(updated_vcd, 1U, kDefaultSrtpCryptoSuite);
EXPECT_TRUE(CompareCryptoParams(vcd->cryptos(), updated_vcd->cryptos()));
ASSERT_CRYPTO(updated_dcd, 1U, kDefaultSrtpCryptoSuite);
EXPECT_TRUE(CompareCryptoParams(dcd->cryptos(), updated_dcd->cryptos()));
EXPECT_EQ(acd->type(), updated_acd->type());
EXPECT_EQ(acd->codecs(), updated_acd->codecs());
EXPECT_EQ(vcd->type(), updated_vcd->type());
EXPECT_EQ(vcd->codecs(), updated_vcd->codecs());
EXPECT_EQ(dcd->type(), updated_dcd->type());
EXPECT_EQ(dcd->codecs(), updated_dcd->codecs());
const StreamParamsVec& updated_audio_streams = updated_acd->streams();
ASSERT_EQ(1U, updated_audio_streams.size());
EXPECT_TRUE(audio_streams[0] == updated_audio_streams[0]);
const StreamParamsVec& updated_video_streams = updated_vcd->streams();
ASSERT_EQ(2U, updated_video_streams.size());
EXPECT_EQ(video_streams[0], updated_video_streams[0]);
EXPECT_EQ(kVideoTrack2, updated_video_streams[1].id);
// All media streams in one PeerConnection share one CNAME.
EXPECT_EQ(updated_video_streams[1].cname, updated_video_streams[0].cname);
const StreamParamsVec& updated_data_streams = updated_dcd->streams();
ASSERT_EQ(1U, updated_data_streams.size());
EXPECT_TRUE(data_streams[0] == updated_data_streams[0]);
}
// Create an updated offer after creating an answer to the original offer and
// verify that the codecs that were part of the original answer are not changed
// in the updated offer.
TEST_F(MediaSessionDescriptionFactoryTest,
RespondentCreatesOfferAfterCreatingAnswer) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
const AudioContentDescription* acd =
GetFirstAudioContentDescription(answer.get());
EXPECT_THAT(acd->codecs(), ElementsAreArray(kAudioCodecsAnswer));
const VideoContentDescription* vcd =
GetFirstVideoContentDescription(answer.get());
EXPECT_THAT(vcd->codecs(), ElementsAreArray(kVideoCodecsAnswer));
std::unique_ptr<SessionDescription> updated_offer(
f2_.CreateOffer(opts, answer.get()));
// The expected audio codecs are the common audio codecs from the first
// offer/answer exchange plus the audio codecs only |f2_| offer, sorted in
// preference order.
// TODO(wu): |updated_offer| should not include the codec
// (i.e. |kAudioCodecs2[0]|) the other side doesn't support.
const AudioCodec kUpdatedAudioCodecOffer[] = {
kAudioCodecsAnswer[0],
kAudioCodecsAnswer[1],
kAudioCodecs2[0],
};
// The expected video codecs are the common video codecs from the first
// offer/answer exchange plus the video codecs only |f2_| offer, sorted in
// preference order.
const VideoCodec kUpdatedVideoCodecOffer[] = {
kVideoCodecsAnswer[0],
kVideoCodecs2[1],
};
const AudioContentDescription* updated_acd =
GetFirstAudioContentDescription(updated_offer.get());
EXPECT_THAT(updated_acd->codecs(), ElementsAreArray(kUpdatedAudioCodecOffer));
const VideoContentDescription* updated_vcd =
GetFirstVideoContentDescription(updated_offer.get());
EXPECT_THAT(updated_vcd->codecs(), ElementsAreArray(kUpdatedVideoCodecOffer));
}
// Test that a reoffer does not reuse audio codecs from a previous media section
// that is being recycled.
TEST_F(MediaSessionDescriptionFactoryTest,
ReOfferDoesNotReUseRecycledAudioCodecs) {
f1_.set_video_codecs({}, {});
f2_.set_video_codecs({}, {});
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "a0",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, nullptr);
// Recycle the media section by changing its mid.
opts.media_description_options[0].mid = "a1";
std::unique_ptr<SessionDescription> reoffer =
f2_.CreateOffer(opts, answer.get());
// Expect that the results of the first negotiation are ignored. If the m=
// section was not recycled the payload types would match the initial offerer.
const AudioContentDescription* acd =
GetFirstAudioContentDescription(reoffer.get());
EXPECT_THAT(acd->codecs(), ElementsAreArray(kAudioCodecs2));
}
// Test that a reoffer does not reuse video codecs from a previous media section
// that is being recycled.
TEST_F(MediaSessionDescriptionFactoryTest,
ReOfferDoesNotReUseRecycledVideoCodecs) {
f1_.set_audio_codecs({}, {});
f2_.set_audio_codecs({}, {});
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "v0",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
auto answer = f2_.CreateAnswer(offer.get(), opts, nullptr);
// Recycle the media section by changing its mid.
opts.media_description_options[0].mid = "v1";
std::unique_ptr<SessionDescription> reoffer =
f2_.CreateOffer(opts, answer.get());
// Expect that the results of the first negotiation are ignored. If the m=
// section was not recycled the payload types would match the initial offerer.
const VideoContentDescription* vcd =
GetFirstVideoContentDescription(reoffer.get());
EXPECT_THAT(vcd->codecs(), ElementsAreArray(kVideoCodecs2));
}
// Test that a reanswer does not reuse audio codecs from a previous media
// section that is being recycled.
TEST_F(MediaSessionDescriptionFactoryTest,
ReAnswerDoesNotReUseRecycledAudioCodecs) {
f1_.set_video_codecs({}, {});
f2_.set_video_codecs({}, {});
// Perform initial offer/answer in reverse (|f2_| as offerer) so that the
// second offer/answer is forward (|f1_| as offerer).
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "a0",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
std::unique_ptr<SessionDescription> offer = f2_.CreateOffer(opts, nullptr);
std::unique_ptr<SessionDescription> answer =
f1_.CreateAnswer(offer.get(), opts, nullptr);
// Recycle the media section by changing its mid.
opts.media_description_options[0].mid = "a1";
std::unique_ptr<SessionDescription> reoffer =
f1_.CreateOffer(opts, answer.get());
std::unique_ptr<SessionDescription> reanswer =
f2_.CreateAnswer(reoffer.get(), opts, offer.get());
// Expect that the results of the first negotiation are ignored. If the m=
// section was not recycled the payload types would match the initial offerer.
const AudioContentDescription* acd =
GetFirstAudioContentDescription(reanswer.get());
EXPECT_THAT(acd->codecs(), ElementsAreArray(kAudioCodecsAnswer));
}
// Test that a reanswer does not reuse video codecs from a previous media
// section that is being recycled.
TEST_F(MediaSessionDescriptionFactoryTest,
ReAnswerDoesNotReUseRecycledVideoCodecs) {
f1_.set_audio_codecs({}, {});
f2_.set_audio_codecs({}, {});
// Perform initial offer/answer in reverse (|f2_| as offerer) so that the
// second offer/answer is forward (|f1_| as offerer).
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "v0",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
std::unique_ptr<SessionDescription> offer = f2_.CreateOffer(opts, nullptr);
std::unique_ptr<SessionDescription> answer =
f1_.CreateAnswer(offer.get(), opts, nullptr);
// Recycle the media section by changing its mid.
opts.media_description_options[0].mid = "v1";
std::unique_ptr<SessionDescription> reoffer =
f1_.CreateOffer(opts, answer.get());
std::unique_ptr<SessionDescription> reanswer =
f2_.CreateAnswer(reoffer.get(), opts, offer.get());
// Expect that the results of the first negotiation are ignored. If the m=
// section was not recycled the payload types would match the initial offerer.
const VideoContentDescription* vcd =
GetFirstVideoContentDescription(reanswer.get());
EXPECT_THAT(vcd->codecs(), ElementsAreArray(kVideoCodecsAnswer));
}
// Create an updated offer after creating an answer to the original offer and
// verify that the codecs that were part of the original answer are not changed
// in the updated offer. In this test Rtx is enabled.
TEST_F(MediaSessionDescriptionFactoryTest,
RespondentCreatesOfferAfterCreatingAnswerWithRtx) {
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kRecvOnly, kActive,
&opts);
std::vector<VideoCodec> f1_codecs = MAKE_VECTOR(kVideoCodecs1);
// This creates rtx for H264 with the payload type |f1_| uses.
AddRtxCodec(VideoCodec::CreateRtxCodec(126, kVideoCodecs1[1].id), &f1_codecs);
f1_.set_video_codecs(f1_codecs, f1_codecs);
std::vector<VideoCodec> f2_codecs = MAKE_VECTOR(kVideoCodecs2);
// This creates rtx for H264 with the payload type |f2_| uses.
AddRtxCodec(VideoCodec::CreateRtxCodec(125, kVideoCodecs2[0].id), &f2_codecs);
f2_.set_video_codecs(f2_codecs, f2_codecs);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
const VideoContentDescription* vcd =
GetFirstVideoContentDescription(answer.get());
std::vector<VideoCodec> expected_codecs = MAKE_VECTOR(kVideoCodecsAnswer);
AddRtxCodec(VideoCodec::CreateRtxCodec(126, kVideoCodecs1[1].id),
&expected_codecs);
EXPECT_EQ(expected_codecs, vcd->codecs());
// Now, make sure we get same result (except for the order) if |f2_| creates
// an updated offer even though the default payload types between |f1_| and
// |f2_| are different.
std::unique_ptr<SessionDescription> updated_offer(
f2_.CreateOffer(opts, answer.get()));
ASSERT_TRUE(updated_offer);
std::unique_ptr<SessionDescription> updated_answer(
f1_.CreateAnswer(updated_offer.get(), opts, answer.get()));
const VideoContentDescription* updated_vcd =
GetFirstVideoContentDescription(updated_answer.get());
EXPECT_EQ(expected_codecs, updated_vcd->codecs());
}
// Regression test for:
// https://bugs.chromium.org/p/webrtc/issues/detail?id=8332
// Existing codecs should always appear before new codecs in re-offers. But
// under a specific set of circumstances, the existing RTX codec was ending up
// added to the end of the list.
TEST_F(MediaSessionDescriptionFactoryTest,
RespondentCreatesOfferAfterCreatingAnswerWithRemappedRtxPayloadType) {
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kRecvOnly, kActive,
&opts);
// We specifically choose different preferred payload types for VP8 to
// trigger the issue.
cricket::VideoCodec vp8_offerer(100, "VP8");
cricket::VideoCodec vp8_offerer_rtx =
VideoCodec::CreateRtxCodec(101, vp8_offerer.id);
cricket::VideoCodec vp8_answerer(110, "VP8");
cricket::VideoCodec vp8_answerer_rtx =
VideoCodec::CreateRtxCodec(111, vp8_answerer.id);
cricket::VideoCodec vp9(120, "VP9");
cricket::VideoCodec vp9_rtx = VideoCodec::CreateRtxCodec(121, vp9.id);
std::vector<VideoCodec> f1_codecs = {vp8_offerer, vp8_offerer_rtx};
// We also specifically cause the answerer to prefer VP9, such that if it
// *doesn't* honor the existing preferred codec (VP8) we'll notice.
std::vector<VideoCodec> f2_codecs = {vp9, vp9_rtx, vp8_answerer,
vp8_answerer_rtx};
f1_.set_video_codecs(f1_codecs, f1_codecs);
f2_.set_video_codecs(f2_codecs, f2_codecs);
std::vector<AudioCodec> audio_codecs;
f1_.set_audio_codecs(audio_codecs, audio_codecs);
f2_.set_audio_codecs(audio_codecs, audio_codecs);
// Offer will be {VP8, RTX for VP8}. Answer will be the same.
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
// Updated offer *should* be {VP8, RTX for VP8, VP9, RTX for VP9}.
// But if the bug is triggered, RTX for VP8 ends up last.
std::unique_ptr<SessionDescription> updated_offer(
f2_.CreateOffer(opts, answer.get()));
const VideoContentDescription* vcd =
GetFirstVideoContentDescription(updated_offer.get());
std::vector<cricket::VideoCodec> codecs = vcd->codecs();
ASSERT_EQ(4u, codecs.size());
EXPECT_EQ(vp8_offerer, codecs[0]);
EXPECT_EQ(vp8_offerer_rtx, codecs[1]);
EXPECT_EQ(vp9, codecs[2]);
EXPECT_EQ(vp9_rtx, codecs[3]);
}
// Create an updated offer that adds video after creating an audio only answer
// to the original offer. This test verifies that if a video codec and the RTX
// codec have the same default payload type as an audio codec that is already in
// use, the added codecs payload types are changed.
TEST_F(MediaSessionDescriptionFactoryTest,
RespondentCreatesOfferWithVideoAndRtxAfterCreatingAudioAnswer) {
std::vector<VideoCodec> f1_codecs = MAKE_VECTOR(kVideoCodecs1);
// This creates rtx for H264 with the payload type |f1_| uses.
AddRtxCodec(VideoCodec::CreateRtxCodec(126, kVideoCodecs1[1].id), &f1_codecs);
f1_.set_video_codecs(f1_codecs, f1_codecs);
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio",
RtpTransceiverDirection::kRecvOnly, kActive,
&opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
const AudioContentDescription* acd =
GetFirstAudioContentDescription(answer.get());
EXPECT_THAT(acd->codecs(), ElementsAreArray(kAudioCodecsAnswer));
// Now - let |f2_| add video with RTX and let the payload type the RTX codec
// reference be the same as an audio codec that was negotiated in the
// first offer/answer exchange.
opts.media_description_options.clear();
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
std::vector<VideoCodec> f2_codecs = MAKE_VECTOR(kVideoCodecs2);
int used_pl_type = acd->codecs()[0].id;
f2_codecs[0].id = used_pl_type; // Set the payload type for H264.
AddRtxCodec(VideoCodec::CreateRtxCodec(125, used_pl_type), &f2_codecs);
f2_.set_video_codecs(f2_codecs, f2_codecs);
std::unique_ptr<SessionDescription> updated_offer(
f2_.CreateOffer(opts, answer.get()));
ASSERT_TRUE(updated_offer);
std::unique_ptr<SessionDescription> updated_answer(
f1_.CreateAnswer(updated_offer.get(), opts, answer.get()));
const AudioContentDescription* updated_acd =
GetFirstAudioContentDescription(answer.get());
EXPECT_THAT(updated_acd->codecs(), ElementsAreArray(kAudioCodecsAnswer));
const VideoContentDescription* updated_vcd =
GetFirstVideoContentDescription(updated_answer.get());
ASSERT_EQ("H264", updated_vcd->codecs()[0].name);
ASSERT_EQ(cricket::kRtxCodecName, updated_vcd->codecs()[1].name);
int new_h264_pl_type = updated_vcd->codecs()[0].id;
EXPECT_NE(used_pl_type, new_h264_pl_type);
VideoCodec rtx = updated_vcd->codecs()[1];
int pt_referenced_by_rtx = rtc::FromString<int>(
rtx.params[cricket::kCodecParamAssociatedPayloadType]);
EXPECT_EQ(new_h264_pl_type, pt_referenced_by_rtx);
}
// Create an updated offer with RTX after creating an answer to an offer
// without RTX, and with different default payload types.
// Verify that the added RTX codec references the correct payload type.
TEST_F(MediaSessionDescriptionFactoryTest,
RespondentCreatesOfferWithRtxAfterCreatingAnswerWithoutRtx) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
std::vector<VideoCodec> f2_codecs = MAKE_VECTOR(kVideoCodecs2);
// This creates rtx for H264 with the payload type |f2_| uses.
AddRtxCodec(VideoCodec::CreateRtxCodec(125, kVideoCodecs2[0].id), &f2_codecs);
f2_.set_video_codecs(f2_codecs, f2_codecs);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
ASSERT_TRUE(offer.get() != nullptr);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, nullptr);
const VideoContentDescription* vcd =
GetFirstVideoContentDescription(answer.get());
std::vector<VideoCodec> expected_codecs = MAKE_VECTOR(kVideoCodecsAnswer);
EXPECT_EQ(expected_codecs, vcd->codecs());
// Now, ensure that the RTX codec is created correctly when |f2_| creates an
// updated offer, even though the default payload types are different from
// those of |f1_|.
std::unique_ptr<SessionDescription> updated_offer(
f2_.CreateOffer(opts, answer.get()));
ASSERT_TRUE(updated_offer);
const VideoContentDescription* updated_vcd =
GetFirstVideoContentDescription(updated_offer.get());
// New offer should attempt to add H263, and RTX for H264.
expected_codecs.push_back(kVideoCodecs2[1]);
AddRtxCodec(VideoCodec::CreateRtxCodec(125, kVideoCodecs1[1].id),
&expected_codecs);
EXPECT_EQ(expected_codecs, updated_vcd->codecs());
}
// Test that RTX is ignored when there is no associated payload type parameter.
TEST_F(MediaSessionDescriptionFactoryTest, RtxWithoutApt) {
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kRecvOnly, kActive,
&opts);
std::vector<VideoCodec> f1_codecs = MAKE_VECTOR(kVideoCodecs1);
// This creates RTX without associated payload type parameter.
AddRtxCodec(VideoCodec(126, cricket::kRtxCodecName), &f1_codecs);
f1_.set_video_codecs(f1_codecs, f1_codecs);
std::vector<VideoCodec> f2_codecs = MAKE_VECTOR(kVideoCodecs2);
// This creates RTX for H264 with the payload type |f2_| uses.
AddRtxCodec(VideoCodec::CreateRtxCodec(125, kVideoCodecs2[0].id), &f2_codecs);
f2_.set_video_codecs(f2_codecs, f2_codecs);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
// kCodecParamAssociatedPayloadType will always be added to the offer when RTX
// is selected. Manually remove kCodecParamAssociatedPayloadType so that it
// is possible to test that that RTX is dropped when
// kCodecParamAssociatedPayloadType is missing in the offer.
MediaContentDescription* media_desc =
offer->GetContentDescriptionByName(cricket::CN_VIDEO);
ASSERT_TRUE(media_desc);
VideoContentDescription* desc = media_desc->as_video();
std::vector<VideoCodec> codecs = desc->codecs();
for (VideoCodec& codec : codecs) {
if (absl::StartsWith(codec.name, cricket::kRtxCodecName)) {
codec.params.clear();
}
}
desc->set_codecs(codecs);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
EXPECT_THAT(
GetCodecNames(GetFirstVideoContentDescription(answer.get())->codecs()),
Not(Contains(cricket::kRtxCodecName)));
}
// Test that RTX will be filtered out in the answer if its associated payload
// type doesn't match the local value.
TEST_F(MediaSessionDescriptionFactoryTest, FilterOutRtxIfAptDoesntMatch) {
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kRecvOnly, kActive,
&opts);
std::vector<VideoCodec> f1_codecs = MAKE_VECTOR(kVideoCodecs1);
// This creates RTX for H264 in sender.
AddRtxCodec(VideoCodec::CreateRtxCodec(126, kVideoCodecs1[1].id), &f1_codecs);
f1_.set_video_codecs(f1_codecs, f1_codecs);
std::vector<VideoCodec> f2_codecs = MAKE_VECTOR(kVideoCodecs2);
// This creates RTX for H263 in receiver.
AddRtxCodec(VideoCodec::CreateRtxCodec(125, kVideoCodecs2[1].id), &f2_codecs);
f2_.set_video_codecs(f2_codecs, f2_codecs);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
// Associated payload type doesn't match, therefore, RTX codec is removed in
// the answer.
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
EXPECT_THAT(
GetCodecNames(GetFirstVideoContentDescription(answer.get())->codecs()),
Not(Contains(cricket::kRtxCodecName)));
}
// Test that when multiple RTX codecs are offered, only the matched RTX codec
// is added in the answer, and the unsupported RTX codec is filtered out.
TEST_F(MediaSessionDescriptionFactoryTest,
FilterOutUnsupportedRtxWhenCreatingAnswer) {
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kRecvOnly, kActive,
&opts);
std::vector<VideoCodec> f1_codecs = MAKE_VECTOR(kVideoCodecs1);
// This creates RTX for H264-SVC in sender.
AddRtxCodec(VideoCodec::CreateRtxCodec(125, kVideoCodecs1[0].id), &f1_codecs);
f1_.set_video_codecs(f1_codecs, f1_codecs);
// This creates RTX for H264 in sender.
AddRtxCodec(VideoCodec::CreateRtxCodec(126, kVideoCodecs1[1].id), &f1_codecs);
f1_.set_video_codecs(f1_codecs, f1_codecs);
std::vector<VideoCodec> f2_codecs = MAKE_VECTOR(kVideoCodecs2);
// This creates RTX for H264 in receiver.
AddRtxCodec(VideoCodec::CreateRtxCodec(124, kVideoCodecs2[0].id), &f2_codecs);
f2_.set_video_codecs(f2_codecs, f1_codecs);
// H264-SVC codec is removed in the answer, therefore, associated RTX codec
// for H264-SVC should also be removed.
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
const VideoContentDescription* vcd =
GetFirstVideoContentDescription(answer.get());
std::vector<VideoCodec> expected_codecs = MAKE_VECTOR(kVideoCodecsAnswer);
AddRtxCodec(VideoCodec::CreateRtxCodec(126, kVideoCodecs1[1].id),
&expected_codecs);
EXPECT_EQ(expected_codecs, vcd->codecs());
}
// Test that after one RTX codec has been negotiated, a new offer can attempt
// to add another.
TEST_F(MediaSessionDescriptionFactoryTest, AddSecondRtxInNewOffer) {
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kRecvOnly, kActive,
&opts);
std::vector<VideoCodec> f1_codecs = MAKE_VECTOR(kVideoCodecs1);
// This creates RTX for H264 for the offerer.
AddRtxCodec(VideoCodec::CreateRtxCodec(126, kVideoCodecs1[1].id), &f1_codecs);
f1_.set_video_codecs(f1_codecs, f1_codecs);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
ASSERT_TRUE(offer);
const VideoContentDescription* vcd =
GetFirstVideoContentDescription(offer.get());
std::vector<VideoCodec> expected_codecs = MAKE_VECTOR(kVideoCodecs1);
AddRtxCodec(VideoCodec::CreateRtxCodec(126, kVideoCodecs1[1].id),
&expected_codecs);
EXPECT_EQ(expected_codecs, vcd->codecs());
// Now, attempt to add RTX for H264-SVC.
AddRtxCodec(VideoCodec::CreateRtxCodec(125, kVideoCodecs1[0].id), &f1_codecs);
f1_.set_video_codecs(f1_codecs, f1_codecs);
std::unique_ptr<SessionDescription> updated_offer(
f1_.CreateOffer(opts, offer.get()));
ASSERT_TRUE(updated_offer);
vcd = GetFirstVideoContentDescription(updated_offer.get());
AddRtxCodec(VideoCodec::CreateRtxCodec(125, kVideoCodecs1[0].id),
&expected_codecs);
EXPECT_EQ(expected_codecs, vcd->codecs());
}
// Test that when RTX is used in conjunction with simulcast, an RTX ssrc is
// generated for each simulcast ssrc and correctly grouped.
TEST_F(MediaSessionDescriptionFactoryTest, SimSsrcsGenerateMultipleRtxSsrcs) {
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
// Add simulcast streams.
AttachSenderToMediaDescriptionOptions("video", MEDIA_TYPE_VIDEO, "stream1",
{"stream1label"}, 3, &opts);
// Use a single real codec, and then add RTX for it.
std::vector<VideoCodec> f1_codecs;
f1_codecs.push_back(VideoCodec(97, "H264"));
AddRtxCodec(VideoCodec::CreateRtxCodec(125, 97), &f1_codecs);
f1_.set_video_codecs(f1_codecs, f1_codecs);
// Ensure that the offer has an RTX ssrc for each regular ssrc, and that there
// is a FID ssrc + grouping for each.
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
MediaContentDescription* media_desc =
offer->GetContentDescriptionByName(cricket::CN_VIDEO);
ASSERT_TRUE(media_desc);
VideoContentDescription* desc = media_desc->as_video();
const StreamParamsVec& streams = desc->streams();
// Single stream.
ASSERT_EQ(1u, streams.size());
// Stream should have 6 ssrcs: 3 for video, 3 for RTX.
EXPECT_EQ(6u, streams[0].ssrcs.size());
// And should have a SIM group for the simulcast.
EXPECT_TRUE(streams[0].has_ssrc_group("SIM"));
// And a FID group for RTX.
EXPECT_TRUE(streams[0].has_ssrc_group("FID"));
std::vector<uint32_t> primary_ssrcs;
streams[0].GetPrimarySsrcs(&primary_ssrcs);
EXPECT_EQ(3u, primary_ssrcs.size());
std::vector<uint32_t> fid_ssrcs;
streams[0].GetFidSsrcs(primary_ssrcs, &fid_ssrcs);
EXPECT_EQ(3u, fid_ssrcs.size());
}
// Test that, when the FlexFEC codec is added, a FlexFEC ssrc is created
// together with a FEC-FR grouping.
TEST_F(MediaSessionDescriptionFactoryTest, GenerateFlexfecSsrc) {
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
// Add single stream.
AttachSenderToMediaDescriptionOptions("video", MEDIA_TYPE_VIDEO, "stream1",
{"stream1label"}, 1, &opts);
// Use a single real codec, and then add FlexFEC for it.
std::vector<VideoCodec> f1_codecs;
f1_codecs.push_back(VideoCodec(97, "H264"));
f1_codecs.push_back(VideoCodec(118, "flexfec-03"));
f1_.set_video_codecs(f1_codecs, f1_codecs);
// Ensure that the offer has a single FlexFEC ssrc and that
// there is no FEC-FR ssrc + grouping for each.
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
ASSERT_TRUE(offer.get() != nullptr);
MediaContentDescription* media_desc =
offer->GetContentDescriptionByName(cricket::CN_VIDEO);
ASSERT_TRUE(media_desc);
VideoContentDescription* desc = media_desc->as_video();
const StreamParamsVec& streams = desc->streams();
// Single stream.
ASSERT_EQ(1u, streams.size());
// Stream should have 2 ssrcs: 1 for video, 1 for FlexFEC.
EXPECT_EQ(2u, streams[0].ssrcs.size());
// And should have a FEC-FR group for FlexFEC.
EXPECT_TRUE(streams[0].has_ssrc_group("FEC-FR"));
std::vector<uint32_t> primary_ssrcs;
streams[0].GetPrimarySsrcs(&primary_ssrcs);
ASSERT_EQ(1u, primary_ssrcs.size());
uint32_t flexfec_ssrc;
EXPECT_TRUE(streams[0].GetFecFrSsrc(primary_ssrcs[0], &flexfec_ssrc));
EXPECT_NE(flexfec_ssrc, 0u);
}
// Test that FlexFEC is disabled for simulcast.
// TODO(brandtr): Remove this test when we support simulcast, either through
// multiple FlexfecSenders, or through multistream protection.
TEST_F(MediaSessionDescriptionFactoryTest, SimSsrcsGenerateNoFlexfecSsrcs) {
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
// Add simulcast streams.
AttachSenderToMediaDescriptionOptions("video", MEDIA_TYPE_VIDEO, "stream1",
{"stream1label"}, 3, &opts);
// Use a single real codec, and then add FlexFEC for it.
std::vector<VideoCodec> f1_codecs;
f1_codecs.push_back(VideoCodec(97, "H264"));
f1_codecs.push_back(VideoCodec(118, "flexfec-03"));
f1_.set_video_codecs(f1_codecs, f1_codecs);
// Ensure that the offer has no FlexFEC ssrcs for each regular ssrc, and that
// there is no FEC-FR ssrc + grouping for each.
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
ASSERT_TRUE(offer.get() != nullptr);
MediaContentDescription* media_desc =
offer->GetContentDescriptionByName(cricket::CN_VIDEO);
ASSERT_TRUE(media_desc);
VideoContentDescription* desc = media_desc->as_video();
const StreamParamsVec& streams = desc->streams();
// Single stream.
ASSERT_EQ(1u, streams.size());
// Stream should have 3 ssrcs: 3 for video, 0 for FlexFEC.
EXPECT_EQ(3u, streams[0].ssrcs.size());
// And should have a SIM group for the simulcast.
EXPECT_TRUE(streams[0].has_ssrc_group("SIM"));
// And not a FEC-FR group for FlexFEC.
EXPECT_FALSE(streams[0].has_ssrc_group("FEC-FR"));
std::vector<uint32_t> primary_ssrcs;
streams[0].GetPrimarySsrcs(&primary_ssrcs);
EXPECT_EQ(3u, primary_ssrcs.size());
for (uint32_t primary_ssrc : primary_ssrcs) {
uint32_t flexfec_ssrc;
EXPECT_FALSE(streams[0].GetFecFrSsrc(primary_ssrc, &flexfec_ssrc));
}
}
// Create an updated offer after creating an answer to the original offer and
// verify that the RTP header extensions that were part of the original answer
// are not changed in the updated offer.
TEST_F(MediaSessionDescriptionFactoryTest,
RespondentCreatesOfferAfterCreatingAnswerWithRtpExtensions) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
f1_.set_audio_rtp_header_extensions(MAKE_VECTOR(kAudioRtpExtension1));
f1_.set_video_rtp_header_extensions(MAKE_VECTOR(kVideoRtpExtension1));
f2_.set_audio_rtp_header_extensions(MAKE_VECTOR(kAudioRtpExtension2));
f2_.set_video_rtp_header_extensions(MAKE_VECTOR(kVideoRtpExtension2));
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, NULL);
EXPECT_EQ(
MAKE_VECTOR(kAudioRtpExtensionAnswer),
GetFirstAudioContentDescription(answer.get())->rtp_header_extensions());
EXPECT_EQ(
MAKE_VECTOR(kVideoRtpExtensionAnswer),
GetFirstVideoContentDescription(answer.get())->rtp_header_extensions());
std::unique_ptr<SessionDescription> updated_offer(
f2_.CreateOffer(opts, answer.get()));
// The expected RTP header extensions in the new offer are the resulting
// extensions from the first offer/answer exchange plus the extensions only
// |f2_| offer.
// Since the default local extension id |f2_| uses has already been used by
// |f1_| for another extensions, it is changed to 13.
const RtpExtension kUpdatedAudioRtpExtensions[] = {
kAudioRtpExtensionAnswer[0],
RtpExtension(kAudioRtpExtension2[1].uri, 13),
kAudioRtpExtension2[2],
};
// Since the default local extension id |f2_| uses has already been used by
// |f1_| for another extensions, is is changed to 12.
const RtpExtension kUpdatedVideoRtpExtensions[] = {
kVideoRtpExtensionAnswer[0],
RtpExtension(kVideoRtpExtension2[1].uri, 12),
kVideoRtpExtension2[2],
};
const AudioContentDescription* updated_acd =
GetFirstAudioContentDescription(updated_offer.get());
EXPECT_EQ(MAKE_VECTOR(kUpdatedAudioRtpExtensions),
updated_acd->rtp_header_extensions());
const VideoContentDescription* updated_vcd =
GetFirstVideoContentDescription(updated_offer.get());
EXPECT_EQ(MAKE_VECTOR(kUpdatedVideoRtpExtensions),
updated_vcd->rtp_header_extensions());
}
// Verify that if the same RTP extension URI is used for audio and video, the
// same ID is used. Also verify that the ID isn't changed when creating an
// updated offer (this was previously a bug).
TEST_F(MediaSessionDescriptionFactoryTest, RtpExtensionIdReused) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
f1_.set_audio_rtp_header_extensions(MAKE_VECTOR(kAudioRtpExtension3));
f1_.set_video_rtp_header_extensions(MAKE_VECTOR(kVideoRtpExtension3));
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
// Since the audio extensions used ID 3 for "both_audio_and_video", so should
// the video extensions.
const RtpExtension kExpectedVideoRtpExtension[] = {
kVideoRtpExtension3[0],
kAudioRtpExtension3[1],
};
EXPECT_EQ(
MAKE_VECTOR(kAudioRtpExtension3),
GetFirstAudioContentDescription(offer.get())->rtp_header_extensions());
EXPECT_EQ(
MAKE_VECTOR(kExpectedVideoRtpExtension),
GetFirstVideoContentDescription(offer.get())->rtp_header_extensions());
// Nothing should change when creating a new offer
std::unique_ptr<SessionDescription> updated_offer(
f1_.CreateOffer(opts, offer.get()));
EXPECT_EQ(MAKE_VECTOR(kAudioRtpExtension3),
GetFirstAudioContentDescription(updated_offer.get())
->rtp_header_extensions());
EXPECT_EQ(MAKE_VECTOR(kExpectedVideoRtpExtension),
GetFirstVideoContentDescription(updated_offer.get())
->rtp_header_extensions());
}
// Same as "RtpExtensionIdReused" above for encrypted RTP extensions.
TEST_F(MediaSessionDescriptionFactoryTest, RtpExtensionIdReusedEncrypted) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
f1_.set_enable_encrypted_rtp_header_extensions(true);
f2_.set_enable_encrypted_rtp_header_extensions(true);
f1_.set_audio_rtp_header_extensions(
MAKE_VECTOR(kAudioRtpExtension3ForEncryption));
f1_.set_video_rtp_header_extensions(
MAKE_VECTOR(kVideoRtpExtension3ForEncryption));
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, NULL);
// The extensions that are shared between audio and video should use the same
// id.
const RtpExtension kExpectedVideoRtpExtension[] = {
kVideoRtpExtension3ForEncryption[0],
kAudioRtpExtension3ForEncryptionOffer[1],
kAudioRtpExtension3ForEncryptionOffer[2],
};
EXPECT_EQ(
MAKE_VECTOR(kAudioRtpExtension3ForEncryptionOffer),
GetFirstAudioContentDescription(offer.get())->rtp_header_extensions());
EXPECT_EQ(
MAKE_VECTOR(kExpectedVideoRtpExtension),
GetFirstVideoContentDescription(offer.get())->rtp_header_extensions());
// Nothing should change when creating a new offer
std::unique_ptr<SessionDescription> updated_offer(
f1_.CreateOffer(opts, offer.get()));
EXPECT_EQ(MAKE_VECTOR(kAudioRtpExtension3ForEncryptionOffer),
GetFirstAudioContentDescription(updated_offer.get())
->rtp_header_extensions());
EXPECT_EQ(MAKE_VECTOR(kExpectedVideoRtpExtension),
GetFirstVideoContentDescription(updated_offer.get())
->rtp_header_extensions());
}
TEST(MediaSessionDescription, CopySessionDescription) {
SessionDescription source;
cricket::ContentGroup group(cricket::CN_AUDIO);
source.AddGroup(group);
std::unique_ptr<AudioContentDescription> acd =
std::make_unique<AudioContentDescription>();
acd->set_codecs(MAKE_VECTOR(kAudioCodecs1));
acd->AddLegacyStream(1);
source.AddContent(cricket::CN_AUDIO, MediaProtocolType::kRtp, acd->Clone());
std::unique_ptr<VideoContentDescription> vcd =
std::make_unique<VideoContentDescription>();
vcd->set_codecs(MAKE_VECTOR(kVideoCodecs1));
vcd->AddLegacyStream(2);
source.AddContent(cricket::CN_VIDEO, MediaProtocolType::kRtp, vcd->Clone());
std::unique_ptr<SessionDescription> copy = source.Clone();
ASSERT_TRUE(copy.get() != NULL);
EXPECT_TRUE(copy->HasGroup(cricket::CN_AUDIO));
const ContentInfo* ac = copy->GetContentByName("audio");
const ContentInfo* vc = copy->GetContentByName("video");
ASSERT_TRUE(ac != NULL);
ASSERT_TRUE(vc != NULL);
EXPECT_EQ(MediaProtocolType::kRtp, ac->type);
const AudioContentDescription* acd_copy = ac->media_description()->as_audio();
EXPECT_EQ(acd->codecs(), acd_copy->codecs());
EXPECT_EQ(1u, acd->first_ssrc());
EXPECT_EQ(MediaProtocolType::kRtp, vc->type);
const VideoContentDescription* vcd_copy = vc->media_description()->as_video();
EXPECT_EQ(vcd->codecs(), vcd_copy->codecs());
EXPECT_EQ(2u, vcd->first_ssrc());
}
// The below TestTransportInfoXXX tests create different offers/answers, and
// ensure the TransportInfo in the SessionDescription matches what we expect.
TEST_F(MediaSessionDescriptionFactoryTest, TestTransportInfoOfferAudio) {
MediaSessionOptions options;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio",
RtpTransceiverDirection::kRecvOnly, kActive,
&options);
TestTransportInfo(true, options, false);
}
TEST_F(MediaSessionDescriptionFactoryTest,
TestTransportInfoOfferIceRenomination) {
MediaSessionOptions options;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio",
RtpTransceiverDirection::kRecvOnly, kActive,
&options);
options.media_description_options[0]
.transport_options.enable_ice_renomination = true;
TestTransportInfo(true, options, false);
}
TEST_F(MediaSessionDescriptionFactoryTest, TestTransportInfoOfferAudioCurrent) {
MediaSessionOptions options;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio",
RtpTransceiverDirection::kRecvOnly, kActive,
&options);
TestTransportInfo(true, options, true);
}
TEST_F(MediaSessionDescriptionFactoryTest, TestTransportInfoOfferMultimedia) {
MediaSessionOptions options;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &options);
AddDataSection(cricket::DCT_RTP, RtpTransceiverDirection::kRecvOnly,
&options);
TestTransportInfo(true, options, false);
}
TEST_F(MediaSessionDescriptionFactoryTest,
TestTransportInfoOfferMultimediaCurrent) {
MediaSessionOptions options;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &options);
AddDataSection(cricket::DCT_RTP, RtpTransceiverDirection::kRecvOnly,
&options);
TestTransportInfo(true, options, true);
}
TEST_F(MediaSessionDescriptionFactoryTest, TestTransportInfoOfferBundle) {
MediaSessionOptions options;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &options);
AddDataSection(cricket::DCT_RTP, RtpTransceiverDirection::kRecvOnly,
&options);
options.bundle_enabled = true;
TestTransportInfo(true, options, false);
}
TEST_F(MediaSessionDescriptionFactoryTest,
TestTransportInfoOfferBundleCurrent) {
MediaSessionOptions options;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &options);
AddDataSection(cricket::DCT_RTP, RtpTransceiverDirection::kRecvOnly,
&options);
options.bundle_enabled = true;
TestTransportInfo(true, options, true);
}
TEST_F(MediaSessionDescriptionFactoryTest, TestTransportInfoAnswerAudio) {
MediaSessionOptions options;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio",
RtpTransceiverDirection::kRecvOnly, kActive,
&options);
TestTransportInfo(false, options, false);
}
TEST_F(MediaSessionDescriptionFactoryTest,
TestTransportInfoAnswerIceRenomination) {
MediaSessionOptions options;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio",
RtpTransceiverDirection::kRecvOnly, kActive,
&options);
options.media_description_options[0]
.transport_options.enable_ice_renomination = true;
TestTransportInfo(false, options, false);
}
TEST_F(MediaSessionDescriptionFactoryTest,
TestTransportInfoAnswerAudioCurrent) {
MediaSessionOptions options;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio",
RtpTransceiverDirection::kRecvOnly, kActive,
&options);
TestTransportInfo(false, options, true);
}
TEST_F(MediaSessionDescriptionFactoryTest, TestTransportInfoAnswerMultimedia) {
MediaSessionOptions options;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &options);
AddDataSection(cricket::DCT_RTP, RtpTransceiverDirection::kRecvOnly,
&options);
TestTransportInfo(false, options, false);
}
TEST_F(MediaSessionDescriptionFactoryTest,
TestTransportInfoAnswerMultimediaCurrent) {
MediaSessionOptions options;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &options);
AddDataSection(cricket::DCT_RTP, RtpTransceiverDirection::kRecvOnly,
&options);
TestTransportInfo(false, options, true);
}
TEST_F(MediaSessionDescriptionFactoryTest, TestTransportInfoAnswerBundle) {
MediaSessionOptions options;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &options);
AddDataSection(cricket::DCT_RTP, RtpTransceiverDirection::kRecvOnly,
&options);
options.bundle_enabled = true;
TestTransportInfo(false, options, false);
}
TEST_F(MediaSessionDescriptionFactoryTest,
TestTransportInfoAnswerBundleCurrent) {
MediaSessionOptions options;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &options);
AddDataSection(cricket::DCT_RTP, RtpTransceiverDirection::kRecvOnly,
&options);
options.bundle_enabled = true;
TestTransportInfo(false, options, true);
}
TEST_F(MediaSessionDescriptionFactoryTest,
TestTransportInfoOfferBundlesTransportOptions) {
MediaSessionOptions options;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &options);
cricket::OpaqueTransportParameters audio_params;
audio_params.protocol = "audio-transport";
audio_params.parameters = "audio-params";
FindFirstMediaDescriptionByMid("audio", &options)
->transport_options.opaque_parameters = audio_params;
cricket::OpaqueTransportParameters video_params;
video_params.protocol = "video-transport";
video_params.parameters = "video-params";
FindFirstMediaDescriptionByMid("video", &options)
->transport_options.opaque_parameters = video_params;
TestTransportInfo(/*offer=*/true, options, /*has_current_desc=*/false);
}
TEST_F(MediaSessionDescriptionFactoryTest,
TestTransportInfoAnswerBundlesTransportOptions) {
MediaSessionOptions options;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &options);
cricket::OpaqueTransportParameters audio_params;
audio_params.protocol = "audio-transport";
audio_params.parameters = "audio-params";
FindFirstMediaDescriptionByMid("audio", &options)
->transport_options.opaque_parameters = audio_params;
cricket::OpaqueTransportParameters video_params;
video_params.protocol = "video-transport";
video_params.parameters = "video-params";
FindFirstMediaDescriptionByMid("video", &options)
->transport_options.opaque_parameters = video_params;
TestTransportInfo(/*offer=*/false, options, /*has_current_desc=*/false);
}
TEST_F(MediaSessionDescriptionFactoryTest, AltProtocolAddedToOffer) {
MediaSessionOptions options;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &options);
AddDataSection(cricket::DCT_RTP, RtpTransceiverDirection::kRecvOnly,
&options);
FindFirstMediaDescriptionByMid("audio", &options)->alt_protocol = "foo";
FindFirstMediaDescriptionByMid("video", &options)->alt_protocol = "bar";
FindFirstMediaDescriptionByMid("data", &options)->alt_protocol = "baz";
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(options, nullptr);
EXPECT_EQ(offer->GetContentDescriptionByName("audio")->alt_protocol(), "foo");
EXPECT_EQ(offer->GetContentDescriptionByName("video")->alt_protocol(), "bar");
EXPECT_EQ(offer->GetContentDescriptionByName("data")->alt_protocol(), "baz");
}
TEST_F(MediaSessionDescriptionFactoryTest, AltProtocolAddedToAnswer) {
MediaSessionOptions options;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &options);
AddDataSection(cricket::DCT_SCTP, RtpTransceiverDirection::kRecvOnly,
&options);
FindFirstMediaDescriptionByMid("audio", &options)->alt_protocol = "foo";
FindFirstMediaDescriptionByMid("video", &options)->alt_protocol = "bar";
FindFirstMediaDescriptionByMid("data", &options)->alt_protocol = "baz";
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(options, nullptr);
std::unique_ptr<SessionDescription> answer =
f1_.CreateAnswer(offer.get(), options, nullptr);
EXPECT_EQ(answer->GetContentDescriptionByName("audio")->alt_protocol(),
"foo");
EXPECT_EQ(answer->GetContentDescriptionByName("video")->alt_protocol(),
"bar");
EXPECT_EQ(answer->GetContentDescriptionByName("data")->alt_protocol(), "baz");
}
TEST_F(MediaSessionDescriptionFactoryTest, AltProtocolNotInOffer) {
MediaSessionOptions options;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &options);
AddDataSection(cricket::DCT_SCTP, RtpTransceiverDirection::kRecvOnly,
&options);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(options, nullptr);
FindFirstMediaDescriptionByMid("audio", &options)->alt_protocol = "foo";
FindFirstMediaDescriptionByMid("video", &options)->alt_protocol = "bar";
FindFirstMediaDescriptionByMid("data", &options)->alt_protocol = "baz";
std::unique_ptr<SessionDescription> answer =
f1_.CreateAnswer(offer.get(), options, nullptr);
EXPECT_EQ(answer->GetContentDescriptionByName("audio")->alt_protocol(),
absl::nullopt);
EXPECT_EQ(answer->GetContentDescriptionByName("video")->alt_protocol(),
absl::nullopt);
EXPECT_EQ(answer->GetContentDescriptionByName("data")->alt_protocol(),
absl::nullopt);
}
TEST_F(MediaSessionDescriptionFactoryTest, AltProtocolDifferentInOffer) {
MediaSessionOptions options;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &options);
AddDataSection(cricket::DCT_SCTP, RtpTransceiverDirection::kRecvOnly,
&options);
FindFirstMediaDescriptionByMid("audio", &options)->alt_protocol = "not-foo";
FindFirstMediaDescriptionByMid("video", &options)->alt_protocol = "not-bar";
FindFirstMediaDescriptionByMid("data", &options)->alt_protocol = "not-baz";
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(options, nullptr);
FindFirstMediaDescriptionByMid("audio", &options)->alt_protocol = "foo";
FindFirstMediaDescriptionByMid("video", &options)->alt_protocol = "bar";
FindFirstMediaDescriptionByMid("data", &options)->alt_protocol = "baz";
std::unique_ptr<SessionDescription> answer =
f1_.CreateAnswer(offer.get(), options, nullptr);
EXPECT_EQ(answer->GetContentDescriptionByName("audio")->alt_protocol(),
absl::nullopt);
EXPECT_EQ(answer->GetContentDescriptionByName("video")->alt_protocol(),
absl::nullopt);
EXPECT_EQ(answer->GetContentDescriptionByName("data")->alt_protocol(),
absl::nullopt);
}
TEST_F(MediaSessionDescriptionFactoryTest, AltProtocolNotInAnswer) {
MediaSessionOptions options;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &options);
AddDataSection(cricket::DCT_SCTP, RtpTransceiverDirection::kRecvOnly,
&options);
FindFirstMediaDescriptionByMid("audio", &options)->alt_protocol = "foo";
FindFirstMediaDescriptionByMid("video", &options)->alt_protocol = "bar";
FindFirstMediaDescriptionByMid("data", &options)->alt_protocol = "baz";
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(options, nullptr);
FindFirstMediaDescriptionByMid("audio", &options)->alt_protocol =
absl::nullopt;
FindFirstMediaDescriptionByMid("video", &options)->alt_protocol =
absl::nullopt;
FindFirstMediaDescriptionByMid("data", &options)->alt_protocol =
absl::nullopt;
std::unique_ptr<SessionDescription> answer =
f1_.CreateAnswer(offer.get(), options, nullptr);
EXPECT_EQ(answer->GetContentDescriptionByName("audio")->alt_protocol(),
absl::nullopt);
EXPECT_EQ(answer->GetContentDescriptionByName("video")->alt_protocol(),
absl::nullopt);
EXPECT_EQ(answer->GetContentDescriptionByName("data")->alt_protocol(),
absl::nullopt);
}
// Create an offer with bundle enabled and verify the crypto parameters are
// the common set of the available cryptos.
TEST_F(MediaSessionDescriptionFactoryTest, TestCryptoWithOfferBundle) {
TestCryptoWithBundle(true);
}
// Create an answer with bundle enabled and verify the crypto parameters are
// the common set of the available cryptos.
TEST_F(MediaSessionDescriptionFactoryTest, TestCryptoWithAnswerBundle) {
TestCryptoWithBundle(false);
}
// Verifies that creating answer fails if the offer has UDP/TLS/RTP/SAVPF but
// DTLS is not enabled locally.
TEST_F(MediaSessionDescriptionFactoryTest,
TestOfferDtlsSavpfWithoutDtlsFailed) {
f1_.set_secure(SEC_ENABLED);
f2_.set_secure(SEC_ENABLED);
tdf1_.set_secure(SEC_DISABLED);
tdf2_.set_secure(SEC_DISABLED);
std::unique_ptr<SessionDescription> offer =
f1_.CreateOffer(CreatePlanBMediaSessionOptions(), NULL);
ASSERT_TRUE(offer.get() != NULL);
ContentInfo* offer_content = offer->GetContentByName("audio");
ASSERT_TRUE(offer_content != NULL);
AudioContentDescription* offer_audio_desc =
offer_content->media_description()->as_audio();
offer_audio_desc->set_protocol(cricket::kMediaProtocolDtlsSavpf);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), CreatePlanBMediaSessionOptions(), NULL);
ASSERT_TRUE(answer != NULL);
ContentInfo* answer_content = answer->GetContentByName("audio");
ASSERT_TRUE(answer_content != NULL);
ASSERT_TRUE(answer_content->rejected);
}
// Offers UDP/TLS/RTP/SAVPF and verifies the answer can be created and contains
// UDP/TLS/RTP/SAVPF.
TEST_F(MediaSessionDescriptionFactoryTest, TestOfferDtlsSavpfCreateAnswer) {
f1_.set_secure(SEC_ENABLED);
f2_.set_secure(SEC_ENABLED);
tdf1_.set_secure(SEC_ENABLED);
tdf2_.set_secure(SEC_ENABLED);
std::unique_ptr<SessionDescription> offer =
f1_.CreateOffer(CreatePlanBMediaSessionOptions(), NULL);
ASSERT_TRUE(offer.get() != NULL);
ContentInfo* offer_content = offer->GetContentByName("audio");
ASSERT_TRUE(offer_content != NULL);
AudioContentDescription* offer_audio_desc =
offer_content->media_description()->as_audio();
offer_audio_desc->set_protocol(cricket::kMediaProtocolDtlsSavpf);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), CreatePlanBMediaSessionOptions(), NULL);
ASSERT_TRUE(answer != NULL);
const ContentInfo* answer_content = answer->GetContentByName("audio");
ASSERT_TRUE(answer_content != NULL);
ASSERT_FALSE(answer_content->rejected);
const AudioContentDescription* answer_audio_desc =
answer_content->media_description()->as_audio();
EXPECT_EQ(cricket::kMediaProtocolDtlsSavpf, answer_audio_desc->protocol());
}
// Test that we include both SDES and DTLS in the offer, but only include SDES
// in the answer if DTLS isn't negotiated.
TEST_F(MediaSessionDescriptionFactoryTest, TestCryptoDtls) {
f1_.set_secure(SEC_ENABLED);
f2_.set_secure(SEC_ENABLED);
tdf1_.set_secure(SEC_ENABLED);
tdf2_.set_secure(SEC_DISABLED);
MediaSessionOptions options;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &options);
std::unique_ptr<SessionDescription> offer, answer;
const cricket::MediaContentDescription* audio_media_desc;
const cricket::MediaContentDescription* video_media_desc;
const cricket::TransportDescription* audio_trans_desc;
const cricket::TransportDescription* video_trans_desc;
// Generate an offer with SDES and DTLS support.
offer = f1_.CreateOffer(options, NULL);
ASSERT_TRUE(offer.get() != NULL);
audio_media_desc = offer->GetContentDescriptionByName("audio");
ASSERT_TRUE(audio_media_desc != NULL);
video_media_desc = offer->GetContentDescriptionByName("video");
ASSERT_TRUE(video_media_desc != NULL);
EXPECT_EQ(1u, audio_media_desc->cryptos().size());
EXPECT_EQ(1u, video_media_desc->cryptos().size());
audio_trans_desc = offer->GetTransportDescriptionByName("audio");
ASSERT_TRUE(audio_trans_desc != NULL);
video_trans_desc = offer->GetTransportDescriptionByName("video");
ASSERT_TRUE(video_trans_desc != NULL);
ASSERT_TRUE(audio_trans_desc->identity_fingerprint.get() != NULL);
ASSERT_TRUE(video_trans_desc->identity_fingerprint.get() != NULL);
// Generate an answer with only SDES support, since tdf2 has crypto disabled.
answer = f2_.CreateAnswer(offer.get(), options, NULL);
ASSERT_TRUE(answer.get() != NULL);
audio_media_desc = answer->GetContentDescriptionByName("audio");
ASSERT_TRUE(audio_media_desc != NULL);
video_media_desc = answer->GetContentDescriptionByName("video");
ASSERT_TRUE(video_media_desc != NULL);
EXPECT_EQ(1u, audio_media_desc->cryptos().size());
EXPECT_EQ(1u, video_media_desc->cryptos().size());
audio_trans_desc = answer->GetTransportDescriptionByName("audio");
ASSERT_TRUE(audio_trans_desc != NULL);
video_trans_desc = answer->GetTransportDescriptionByName("video");
ASSERT_TRUE(video_trans_desc != NULL);
ASSERT_TRUE(audio_trans_desc->identity_fingerprint.get() == NULL);
ASSERT_TRUE(video_trans_desc->identity_fingerprint.get() == NULL);
// Enable DTLS; the answer should now only have DTLS support.
tdf2_.set_secure(SEC_ENABLED);
answer = f2_.CreateAnswer(offer.get(), options, NULL);
ASSERT_TRUE(answer.get() != NULL);
audio_media_desc = answer->GetContentDescriptionByName("audio");
ASSERT_TRUE(audio_media_desc != NULL);
video_media_desc = answer->GetContentDescriptionByName("video");
ASSERT_TRUE(video_media_desc != NULL);
EXPECT_TRUE(audio_media_desc->cryptos().empty());
EXPECT_TRUE(video_media_desc->cryptos().empty());
EXPECT_EQ(cricket::kMediaProtocolSavpf, audio_media_desc->protocol());
EXPECT_EQ(cricket::kMediaProtocolSavpf, video_media_desc->protocol());
audio_trans_desc = answer->GetTransportDescriptionByName("audio");
ASSERT_TRUE(audio_trans_desc != NULL);
video_trans_desc = answer->GetTransportDescriptionByName("video");
ASSERT_TRUE(video_trans_desc != NULL);
ASSERT_TRUE(audio_trans_desc->identity_fingerprint.get() != NULL);
ASSERT_TRUE(video_trans_desc->identity_fingerprint.get() != NULL);
// Try creating offer again. DTLS enabled now, crypto's should be empty
// in new offer.
offer = f1_.CreateOffer(options, offer.get());
ASSERT_TRUE(offer.get() != NULL);
audio_media_desc = offer->GetContentDescriptionByName("audio");
ASSERT_TRUE(audio_media_desc != NULL);
video_media_desc = offer->GetContentDescriptionByName("video");
ASSERT_TRUE(video_media_desc != NULL);
EXPECT_TRUE(audio_media_desc->cryptos().empty());
EXPECT_TRUE(video_media_desc->cryptos().empty());
audio_trans_desc = offer->GetTransportDescriptionByName("audio");
ASSERT_TRUE(audio_trans_desc != NULL);
video_trans_desc = offer->GetTransportDescriptionByName("video");
ASSERT_TRUE(video_trans_desc != NULL);
ASSERT_TRUE(audio_trans_desc->identity_fingerprint.get() != NULL);
ASSERT_TRUE(video_trans_desc->identity_fingerprint.get() != NULL);
}
// Test that an answer can't be created if cryptos are required but the offer is
// unsecure.
TEST_F(MediaSessionDescriptionFactoryTest, TestSecureAnswerToUnsecureOffer) {
MediaSessionOptions options = CreatePlanBMediaSessionOptions();
f1_.set_secure(SEC_DISABLED);
tdf1_.set_secure(SEC_DISABLED);
f2_.set_secure(SEC_REQUIRED);
tdf1_.set_secure(SEC_ENABLED);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(options, NULL);
ASSERT_TRUE(offer.get() != NULL);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), options, NULL);
EXPECT_TRUE(answer.get() == NULL);
}
// Test that we accept a DTLS offer without SDES and create an appropriate
// answer.
TEST_F(MediaSessionDescriptionFactoryTest, TestCryptoOfferDtlsButNotSdes) {
f1_.set_secure(SEC_DISABLED);
f2_.set_secure(SEC_ENABLED);
tdf1_.set_secure(SEC_ENABLED);
tdf2_.set_secure(SEC_ENABLED);
MediaSessionOptions options;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &options);
AddDataSection(cricket::DCT_RTP, RtpTransceiverDirection::kRecvOnly,
&options);
// Generate an offer with DTLS but without SDES.
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(options, NULL);
ASSERT_TRUE(offer.get() != NULL);
const AudioContentDescription* audio_offer =
GetFirstAudioContentDescription(offer.get());
ASSERT_TRUE(audio_offer->cryptos().empty());
const VideoContentDescription* video_offer =
GetFirstVideoContentDescription(offer.get());
ASSERT_TRUE(video_offer->cryptos().empty());
const RtpDataContentDescription* data_offer =
GetFirstRtpDataContentDescription(offer.get());
ASSERT_TRUE(data_offer->cryptos().empty());
const cricket::TransportDescription* audio_offer_trans_desc =
offer->GetTransportDescriptionByName("audio");
ASSERT_TRUE(audio_offer_trans_desc->identity_fingerprint.get() != NULL);
const cricket::TransportDescription* video_offer_trans_desc =
offer->GetTransportDescriptionByName("video");
ASSERT_TRUE(video_offer_trans_desc->identity_fingerprint.get() != NULL);
const cricket::TransportDescription* data_offer_trans_desc =
offer->GetTransportDescriptionByName("data");
ASSERT_TRUE(data_offer_trans_desc->identity_fingerprint.get() != NULL);
// Generate an answer with DTLS.
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), options, NULL);
ASSERT_TRUE(answer.get() != NULL);
const cricket::TransportDescription* audio_answer_trans_desc =
answer->GetTransportDescriptionByName("audio");
EXPECT_TRUE(audio_answer_trans_desc->identity_fingerprint.get() != NULL);
const cricket::TransportDescription* video_answer_trans_desc =
answer->GetTransportDescriptionByName("video");
EXPECT_TRUE(video_answer_trans_desc->identity_fingerprint.get() != NULL);
const cricket::TransportDescription* data_answer_trans_desc =
answer->GetTransportDescriptionByName("data");
EXPECT_TRUE(data_answer_trans_desc->identity_fingerprint.get() != NULL);
}
// Verifies if vad_enabled option is set to false, CN codecs are not present in
// offer or answer.
TEST_F(MediaSessionDescriptionFactoryTest, TestVADEnableOption) {
MediaSessionOptions options;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &options);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(options, NULL);
ASSERT_TRUE(offer.get() != NULL);
const ContentInfo* audio_content = offer->GetContentByName("audio");
EXPECT_FALSE(VerifyNoCNCodecs(audio_content));
options.vad_enabled = false;
offer = f1_.CreateOffer(options, NULL);
ASSERT_TRUE(offer.get() != NULL);
audio_content = offer->GetContentByName("audio");
EXPECT_TRUE(VerifyNoCNCodecs(audio_content));
std::unique_ptr<SessionDescription> answer =
f1_.CreateAnswer(offer.get(), options, NULL);
ASSERT_TRUE(answer.get() != NULL);
audio_content = answer->GetContentByName("audio");
EXPECT_TRUE(VerifyNoCNCodecs(audio_content));
}
// Test that the generated MIDs match the existing offer.
TEST_F(MediaSessionDescriptionFactoryTest, TestMIDsMatchesExistingOffer) {
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio_modified",
RtpTransceiverDirection::kRecvOnly, kActive,
&opts);
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video_modified",
RtpTransceiverDirection::kRecvOnly, kActive,
&opts);
opts.data_channel_type = cricket::DCT_SCTP;
AddMediaDescriptionOptions(MEDIA_TYPE_DATA, "data_modified",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
// Create offer.
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
std::unique_ptr<SessionDescription> updated_offer(
f1_.CreateOffer(opts, offer.get()));
const ContentInfo* audio_content = GetFirstAudioContent(updated_offer.get());
const ContentInfo* video_content = GetFirstVideoContent(updated_offer.get());
const ContentInfo* data_content = GetFirstDataContent(updated_offer.get());
ASSERT_TRUE(audio_content != nullptr);
ASSERT_TRUE(video_content != nullptr);
ASSERT_TRUE(data_content != nullptr);
EXPECT_EQ("audio_modified", audio_content->name);
EXPECT_EQ("video_modified", video_content->name);
EXPECT_EQ("data_modified", data_content->name);
}
// The following tests verify that the unified plan SDP is supported.
// Test that we can create an offer with multiple media sections of same media
// type.
TEST_F(MediaSessionDescriptionFactoryTest,
CreateOfferWithMultipleAVMediaSections) {
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio_1",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
AttachSenderToMediaDescriptionOptions(
"audio_1", MEDIA_TYPE_AUDIO, kAudioTrack1, {kMediaStream1}, 1, &opts);
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video_1",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
AttachSenderToMediaDescriptionOptions(
"video_1", MEDIA_TYPE_VIDEO, kVideoTrack1, {kMediaStream1}, 1, &opts);
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio_2",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
AttachSenderToMediaDescriptionOptions(
"audio_2", MEDIA_TYPE_AUDIO, kAudioTrack2, {kMediaStream2}, 1, &opts);
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video_2",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
AttachSenderToMediaDescriptionOptions(
"video_2", MEDIA_TYPE_VIDEO, kVideoTrack2, {kMediaStream2}, 1, &opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
ASSERT_TRUE(offer);
ASSERT_EQ(4u, offer->contents().size());
EXPECT_FALSE(offer->contents()[0].rejected);
const AudioContentDescription* acd =
offer->contents()[0].media_description()->as_audio();
ASSERT_EQ(1u, acd->streams().size());
EXPECT_EQ(kAudioTrack1, acd->streams()[0].id);
EXPECT_EQ(RtpTransceiverDirection::kSendRecv, acd->direction());
EXPECT_FALSE(offer->contents()[1].rejected);
const VideoContentDescription* vcd =
offer->contents()[1].media_description()->as_video();
ASSERT_EQ(1u, vcd->streams().size());
EXPECT_EQ(kVideoTrack1, vcd->streams()[0].id);
EXPECT_EQ(RtpTransceiverDirection::kSendRecv, vcd->direction());
EXPECT_FALSE(offer->contents()[2].rejected);
acd = offer->contents()[2].media_description()->as_audio();
ASSERT_EQ(1u, acd->streams().size());
EXPECT_EQ(kAudioTrack2, acd->streams()[0].id);
EXPECT_EQ(RtpTransceiverDirection::kSendRecv, acd->direction());
EXPECT_FALSE(offer->contents()[3].rejected);
vcd = offer->contents()[3].media_description()->as_video();
ASSERT_EQ(1u, vcd->streams().size());
EXPECT_EQ(kVideoTrack2, vcd->streams()[0].id);
EXPECT_EQ(RtpTransceiverDirection::kSendRecv, vcd->direction());
}
// Test that we can create an answer with multiple media sections of same media
// type.
TEST_F(MediaSessionDescriptionFactoryTest,
CreateAnswerWithMultipleAVMediaSections) {
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio_1",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
AttachSenderToMediaDescriptionOptions(
"audio_1", MEDIA_TYPE_AUDIO, kAudioTrack1, {kMediaStream1}, 1, &opts);
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video_1",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
AttachSenderToMediaDescriptionOptions(
"video_1", MEDIA_TYPE_VIDEO, kVideoTrack1, {kMediaStream1}, 1, &opts);
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio_2",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
AttachSenderToMediaDescriptionOptions(
"audio_2", MEDIA_TYPE_AUDIO, kAudioTrack2, {kMediaStream2}, 1, &opts);
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video_2",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
AttachSenderToMediaDescriptionOptions(
"video_2", MEDIA_TYPE_VIDEO, kVideoTrack2, {kMediaStream2}, 1, &opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
ASSERT_TRUE(offer);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, nullptr);
ASSERT_EQ(4u, answer->contents().size());
EXPECT_FALSE(answer->contents()[0].rejected);
const AudioContentDescription* acd =
answer->contents()[0].media_description()->as_audio();
ASSERT_EQ(1u, acd->streams().size());
EXPECT_EQ(kAudioTrack1, acd->streams()[0].id);
EXPECT_EQ(RtpTransceiverDirection::kSendRecv, acd->direction());
EXPECT_FALSE(answer->contents()[1].rejected);
const VideoContentDescription* vcd =
answer->contents()[1].media_description()->as_video();
ASSERT_EQ(1u, vcd->streams().size());
EXPECT_EQ(kVideoTrack1, vcd->streams()[0].id);
EXPECT_EQ(RtpTransceiverDirection::kSendRecv, vcd->direction());
EXPECT_FALSE(answer->contents()[2].rejected);
acd = answer->contents()[2].media_description()->as_audio();
ASSERT_EQ(1u, acd->streams().size());
EXPECT_EQ(kAudioTrack2, acd->streams()[0].id);
EXPECT_EQ(RtpTransceiverDirection::kSendRecv, acd->direction());
EXPECT_FALSE(answer->contents()[3].rejected);
vcd = answer->contents()[3].media_description()->as_video();
ASSERT_EQ(1u, vcd->streams().size());
EXPECT_EQ(kVideoTrack2, vcd->streams()[0].id);
EXPECT_EQ(RtpTransceiverDirection::kSendRecv, vcd->direction());
}
// Test that the media section will be rejected in offer if the corresponding
// MediaDescriptionOptions is stopped by the offerer.
TEST_F(MediaSessionDescriptionFactoryTest,
CreateOfferWithMediaSectionStoppedByOfferer) {
// Create an offer with two audio sections and one of them is stopped.
MediaSessionOptions offer_opts;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio1",
RtpTransceiverDirection::kSendRecv, kActive,
&offer_opts);
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio2",
RtpTransceiverDirection::kInactive, kStopped,
&offer_opts);
std::unique_ptr<SessionDescription> offer =
f1_.CreateOffer(offer_opts, nullptr);
ASSERT_TRUE(offer);
ASSERT_EQ(2u, offer->contents().size());
EXPECT_FALSE(offer->contents()[0].rejected);
EXPECT_TRUE(offer->contents()[1].rejected);
}
// Test that the media section will be rejected in answer if the corresponding
// MediaDescriptionOptions is stopped by the offerer.
TEST_F(MediaSessionDescriptionFactoryTest,
CreateAnswerWithMediaSectionStoppedByOfferer) {
// Create an offer with two audio sections and one of them is stopped.
MediaSessionOptions offer_opts;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio1",
RtpTransceiverDirection::kSendRecv, kActive,
&offer_opts);
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio2",
RtpTransceiverDirection::kInactive, kStopped,
&offer_opts);
std::unique_ptr<SessionDescription> offer =
f1_.CreateOffer(offer_opts, nullptr);
ASSERT_TRUE(offer);
ASSERT_EQ(2u, offer->contents().size());
EXPECT_FALSE(offer->contents()[0].rejected);
EXPECT_TRUE(offer->contents()[1].rejected);
// Create an answer based on the offer.
MediaSessionOptions answer_opts;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio1",
RtpTransceiverDirection::kSendRecv, kActive,
&answer_opts);
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio2",
RtpTransceiverDirection::kSendRecv, kActive,
&answer_opts);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), answer_opts, nullptr);
ASSERT_EQ(2u, answer->contents().size());
EXPECT_FALSE(answer->contents()[0].rejected);
EXPECT_TRUE(answer->contents()[1].rejected);
}
// Test that the media section will be rejected in answer if the corresponding
// MediaDescriptionOptions is stopped by the answerer.
TEST_F(MediaSessionDescriptionFactoryTest,
CreateAnswerWithMediaSectionRejectedByAnswerer) {
// Create an offer with two audio sections.
MediaSessionOptions offer_opts;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio1",
RtpTransceiverDirection::kSendRecv, kActive,
&offer_opts);
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio2",
RtpTransceiverDirection::kSendRecv, kActive,
&offer_opts);
std::unique_ptr<SessionDescription> offer =
f1_.CreateOffer(offer_opts, nullptr);
ASSERT_TRUE(offer);
ASSERT_EQ(2u, offer->contents().size());
ASSERT_FALSE(offer->contents()[0].rejected);
ASSERT_FALSE(offer->contents()[1].rejected);
// The answerer rejects one of the audio sections.
MediaSessionOptions answer_opts;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio1",
RtpTransceiverDirection::kSendRecv, kActive,
&answer_opts);
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio2",
RtpTransceiverDirection::kInactive, kStopped,
&answer_opts);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), answer_opts, nullptr);
ASSERT_EQ(2u, answer->contents().size());
EXPECT_FALSE(answer->contents()[0].rejected);
EXPECT_TRUE(answer->contents()[1].rejected);
// The TransportInfo of the rejected m= section is expected to be added in the
// answer.
EXPECT_EQ(offer->transport_infos().size(), answer->transport_infos().size());
}
// Test the generated media sections has the same order of the
// corresponding MediaDescriptionOptions.
TEST_F(MediaSessionDescriptionFactoryTest,
CreateOfferRespectsMediaDescriptionOptionsOrder) {
MediaSessionOptions opts;
// This tests put video section first because normally audio comes first by
// default.
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
ASSERT_TRUE(offer);
ASSERT_EQ(2u, offer->contents().size());
EXPECT_EQ("video", offer->contents()[0].name);
EXPECT_EQ("audio", offer->contents()[1].name);
}
// Test that different media sections using the same codec have same payload
// type.
TEST_F(MediaSessionDescriptionFactoryTest,
PayloadTypesSharedByMediaSectionsOfSameType) {
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video1",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video2",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
// Create an offer with two video sections using same codecs.
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
ASSERT_TRUE(offer);
ASSERT_EQ(2u, offer->contents().size());
const VideoContentDescription* vcd1 =
offer->contents()[0].media_description()->as_video();
const VideoContentDescription* vcd2 =
offer->contents()[1].media_description()->as_video();
EXPECT_EQ(vcd1->codecs().size(), vcd2->codecs().size());
ASSERT_EQ(2u, vcd1->codecs().size());
EXPECT_EQ(vcd1->codecs()[0].name, vcd2->codecs()[0].name);
EXPECT_EQ(vcd1->codecs()[0].id, vcd2->codecs()[0].id);
EXPECT_EQ(vcd1->codecs()[1].name, vcd2->codecs()[1].name);
EXPECT_EQ(vcd1->codecs()[1].id, vcd2->codecs()[1].id);
// Create answer and negotiate the codecs.
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, nullptr);
ASSERT_TRUE(answer);
ASSERT_EQ(2u, answer->contents().size());
vcd1 = answer->contents()[0].media_description()->as_video();
vcd2 = answer->contents()[1].media_description()->as_video();
EXPECT_EQ(vcd1->codecs().size(), vcd2->codecs().size());
ASSERT_EQ(1u, vcd1->codecs().size());
EXPECT_EQ(vcd1->codecs()[0].name, vcd2->codecs()[0].name);
EXPECT_EQ(vcd1->codecs()[0].id, vcd2->codecs()[0].id);
}
// Test that the codec preference order per media section is respected in
// subsequent offer.
TEST_F(MediaSessionDescriptionFactoryTest,
CreateOfferRespectsCodecPreferenceOrder) {
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video1",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video2",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
// Create an offer with two video sections using same codecs.
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
ASSERT_TRUE(offer);
ASSERT_EQ(2u, offer->contents().size());
VideoContentDescription* vcd1 =
offer->contents()[0].media_description()->as_video();
const VideoContentDescription* vcd2 =
offer->contents()[1].media_description()->as_video();
auto video_codecs = MAKE_VECTOR(kVideoCodecs1);
EXPECT_EQ(video_codecs, vcd1->codecs());
EXPECT_EQ(video_codecs, vcd2->codecs());
// Change the codec preference of the first video section and create a
// follow-up offer.
auto video_codecs_reverse = MAKE_VECTOR(kVideoCodecs1Reverse);
vcd1->set_codecs(video_codecs_reverse);
std::unique_ptr<SessionDescription> updated_offer(
f1_.CreateOffer(opts, offer.get()));
vcd1 = updated_offer->contents()[0].media_description()->as_video();
vcd2 = updated_offer->contents()[1].media_description()->as_video();
// The video codec preference order should be respected.
EXPECT_EQ(video_codecs_reverse, vcd1->codecs());
EXPECT_EQ(video_codecs, vcd2->codecs());
}
// Test that the codec preference order per media section is respected in
// the answer.
TEST_F(MediaSessionDescriptionFactoryTest,
CreateAnswerRespectsCodecPreferenceOrder) {
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video1",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video2",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
// Create an offer with two video sections using same codecs.
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
ASSERT_TRUE(offer);
ASSERT_EQ(2u, offer->contents().size());
VideoContentDescription* vcd1 =
offer->contents()[0].media_description()->as_video();
const VideoContentDescription* vcd2 =
offer->contents()[1].media_description()->as_video();
auto video_codecs = MAKE_VECTOR(kVideoCodecs1);
EXPECT_EQ(video_codecs, vcd1->codecs());
EXPECT_EQ(video_codecs, vcd2->codecs());
// Change the codec preference of the first video section and create an
// answer.
auto video_codecs_reverse = MAKE_VECTOR(kVideoCodecs1Reverse);
vcd1->set_codecs(video_codecs_reverse);
std::unique_ptr<SessionDescription> answer =
f1_.CreateAnswer(offer.get(), opts, nullptr);
vcd1 = answer->contents()[0].media_description()->as_video();
vcd2 = answer->contents()[1].media_description()->as_video();
// The video codec preference order should be respected.
EXPECT_EQ(video_codecs_reverse, vcd1->codecs());
EXPECT_EQ(video_codecs, vcd2->codecs());
}
// Test that when creating an answer, the codecs use local parameters instead of
// the remote ones.
TEST_F(MediaSessionDescriptionFactoryTest, CreateAnswerWithLocalCodecParams) {
const std::string audio_param_name = "audio_param";
const std::string audio_value1 = "audio_v1";
const std::string audio_value2 = "audio_v2";
const std::string video_param_name = "video_param";
const std::string video_value1 = "video_v1";
const std::string video_value2 = "video_v2";
auto audio_codecs1 = MAKE_VECTOR(kAudioCodecs1);
auto audio_codecs2 = MAKE_VECTOR(kAudioCodecs1);
auto video_codecs1 = MAKE_VECTOR(kVideoCodecs1);
auto video_codecs2 = MAKE_VECTOR(kVideoCodecs1);
// Set the parameters for codecs.
audio_codecs1[0].SetParam(audio_param_name, audio_value1);
video_codecs1[0].SetParam(video_param_name, video_value1);
audio_codecs2[0].SetParam(audio_param_name, audio_value2);
video_codecs2[0].SetParam(video_param_name, video_value2);
f1_.set_audio_codecs(audio_codecs1, audio_codecs1);
f1_.set_video_codecs(video_codecs1, video_codecs1);
f2_.set_audio_codecs(audio_codecs2, audio_codecs2);
f2_.set_video_codecs(video_codecs2, video_codecs2);
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
ASSERT_TRUE(offer);
auto offer_acd = offer->contents()[0].media_description()->as_audio();
auto offer_vcd = offer->contents()[1].media_description()->as_video();
std::string value;
EXPECT_TRUE(offer_acd->codecs()[0].GetParam(audio_param_name, &value));
EXPECT_EQ(audio_value1, value);
EXPECT_TRUE(offer_vcd->codecs()[0].GetParam(video_param_name, &value));
EXPECT_EQ(video_value1, value);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, nullptr);
ASSERT_TRUE(answer);
auto answer_acd = answer->contents()[0].media_description()->as_audio();
auto answer_vcd = answer->contents()[1].media_description()->as_video();
// Use the parameters from the local codecs.
EXPECT_TRUE(answer_acd->codecs()[0].GetParam(audio_param_name, &value));
EXPECT_EQ(audio_value2, value);
EXPECT_TRUE(answer_vcd->codecs()[0].GetParam(video_param_name, &value));
EXPECT_EQ(video_value2, value);
}
// Test that matching packetization-mode is part of the criteria for matching
// H264 codecs (in addition to profile-level-id). Previously, this was not the
// case, so the first H264 codec with the same profile-level-id would match and
// the payload type in the answer would be incorrect.
// This is a regression test for bugs.webrtc.org/8808
TEST_F(MediaSessionDescriptionFactoryTest,
H264MatchCriteriaIncludesPacketizationMode) {
// Create two H264 codecs with the same profile level ID and different
// packetization modes.
VideoCodec h264_pm0(96, "H264");
h264_pm0.params[cricket::kH264FmtpProfileLevelId] = "42c01f";
h264_pm0.params[cricket::kH264FmtpPacketizationMode] = "0";
VideoCodec h264_pm1(97, "H264");
h264_pm1.params[cricket::kH264FmtpProfileLevelId] = "42c01f";
h264_pm1.params[cricket::kH264FmtpPacketizationMode] = "1";
// Offerer will send both codecs, answerer should choose the one with matching
// packetization mode (and not the first one it sees).
f1_.set_video_codecs({h264_pm0, h264_pm1}, {h264_pm0, h264_pm1});
f2_.set_video_codecs({h264_pm1}, {h264_pm1});
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_VIDEO, "video",
RtpTransceiverDirection::kSendRecv, kActive,
&opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
ASSERT_TRUE(offer);
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, nullptr);
ASSERT_TRUE(answer);
// Answer should have one negotiated codec with packetization-mode=1 using the
// offered payload type.
ASSERT_EQ(1u, answer->contents().size());
auto answer_vcd = answer->contents()[0].media_description()->as_video();
ASSERT_EQ(1u, answer_vcd->codecs().size());
auto answer_codec = answer_vcd->codecs()[0];
EXPECT_EQ(h264_pm1.id, answer_codec.id);
}
class MediaProtocolTest : public ::testing::TestWithParam<const char*> {
public:
MediaProtocolTest()
: f1_(&tdf1_, &ssrc_generator1), f2_(&tdf2_, &ssrc_generator2) {
f1_.set_audio_codecs(MAKE_VECTOR(kAudioCodecs1),
MAKE_VECTOR(kAudioCodecs1));
f1_.set_video_codecs(MAKE_VECTOR(kVideoCodecs1),
MAKE_VECTOR(kVideoCodecs1));
f1_.set_rtp_data_codecs(MAKE_VECTOR(kDataCodecs1));
f2_.set_audio_codecs(MAKE_VECTOR(kAudioCodecs2),
MAKE_VECTOR(kAudioCodecs2));
f2_.set_video_codecs(MAKE_VECTOR(kVideoCodecs2),
MAKE_VECTOR(kVideoCodecs2));
f2_.set_rtp_data_codecs(MAKE_VECTOR(kDataCodecs2));
f1_.set_secure(SEC_ENABLED);
f2_.set_secure(SEC_ENABLED);
tdf1_.set_certificate(rtc::RTCCertificate::Create(
std::unique_ptr<rtc::SSLIdentity>(new rtc::FakeSSLIdentity("id1"))));
tdf2_.set_certificate(rtc::RTCCertificate::Create(
std::unique_ptr<rtc::SSLIdentity>(new rtc::FakeSSLIdentity("id2"))));
tdf1_.set_secure(SEC_ENABLED);
tdf2_.set_secure(SEC_ENABLED);
}
protected:
MediaSessionDescriptionFactory f1_;
MediaSessionDescriptionFactory f2_;
TransportDescriptionFactory tdf1_;
TransportDescriptionFactory tdf2_;
UniqueRandomIdGenerator ssrc_generator1;
UniqueRandomIdGenerator ssrc_generator2;
};
TEST_P(MediaProtocolTest, TestAudioVideoAcceptance) {
MediaSessionOptions opts;
AddAudioVideoSections(RtpTransceiverDirection::kRecvOnly, &opts);
std::unique_ptr<SessionDescription> offer = f1_.CreateOffer(opts, nullptr);
ASSERT_TRUE(offer.get() != nullptr);
// Set the protocol for all the contents.
for (auto& content : offer.get()->contents()) {
content.media_description()->set_protocol(GetParam());
}
std::unique_ptr<SessionDescription> answer =
f2_.CreateAnswer(offer.get(), opts, nullptr);
const ContentInfo* ac = answer->GetContentByName("audio");
const ContentInfo* vc = answer->GetContentByName("video");
ASSERT_TRUE(ac != nullptr);
ASSERT_TRUE(vc != nullptr);
EXPECT_FALSE(ac->rejected); // the offer is accepted
EXPECT_FALSE(vc->rejected);
const AudioContentDescription* acd = ac->media_description()->as_audio();
const VideoContentDescription* vcd = vc->media_description()->as_video();
EXPECT_EQ(GetParam(), acd->protocol());
EXPECT_EQ(GetParam(), vcd->protocol());
}
INSTANTIATE_TEST_SUITE_P(MediaProtocolPatternTest,
MediaProtocolTest,
::testing::ValuesIn(kMediaProtocols));
INSTANTIATE_TEST_SUITE_P(MediaProtocolDtlsPatternTest,
MediaProtocolTest,
::testing::ValuesIn(kMediaProtocolsDtls));
TEST_F(MediaSessionDescriptionFactoryTest, TestSetAudioCodecs) {
TransportDescriptionFactory tdf;
UniqueRandomIdGenerator ssrc_generator;
MediaSessionDescriptionFactory sf(&tdf, &ssrc_generator);
std::vector<AudioCodec> send_codecs = MAKE_VECTOR(kAudioCodecs1);
std::vector<AudioCodec> recv_codecs = MAKE_VECTOR(kAudioCodecs2);
// The merged list of codecs should contain any send codecs that are also
// nominally in the recieve codecs list. Payload types should be picked from
// the send codecs and a number-of-channels of 0 and 1 should be equivalent
// (set to 1). This equals what happens when the send codecs are used in an
// offer and the receive codecs are used in the following answer.
const std::vector<AudioCodec> sendrecv_codecs =
MAKE_VECTOR(kAudioCodecsAnswer);
const std::vector<AudioCodec> no_codecs;
RTC_CHECK_EQ(send_codecs[1].name, "iLBC")
<< "Please don't change shared test data!";
RTC_CHECK_EQ(recv_codecs[2].name, "iLBC")
<< "Please don't change shared test data!";
// Alter iLBC send codec to have zero channels, to test that that is handled
// properly.
send_codecs[1].channels = 0;
// Alther iLBC receive codec to be lowercase, to test that case conversions
// are handled properly.
recv_codecs[2].name = "ilbc";
// Test proper merge
sf.set_audio_codecs(send_codecs, recv_codecs);
EXPECT_EQ(send_codecs, sf.audio_send_codecs());
EXPECT_EQ(recv_codecs, sf.audio_recv_codecs());
EXPECT_EQ(sendrecv_codecs, sf.audio_sendrecv_codecs());
// Test empty send codecs list
sf.set_audio_codecs(no_codecs, recv_codecs);
EXPECT_EQ(no_codecs, sf.audio_send_codecs());
EXPECT_EQ(recv_codecs, sf.audio_recv_codecs());
EXPECT_EQ(no_codecs, sf.audio_sendrecv_codecs());
// Test empty recv codecs list
sf.set_audio_codecs(send_codecs, no_codecs);
EXPECT_EQ(send_codecs, sf.audio_send_codecs());
EXPECT_EQ(no_codecs, sf.audio_recv_codecs());
EXPECT_EQ(no_codecs, sf.audio_sendrecv_codecs());
// Test all empty codec lists
sf.set_audio_codecs(no_codecs, no_codecs);
EXPECT_EQ(no_codecs, sf.audio_send_codecs());
EXPECT_EQ(no_codecs, sf.audio_recv_codecs());
EXPECT_EQ(no_codecs, sf.audio_sendrecv_codecs());
}
namespace {
// Compare the two vectors of codecs ignoring the payload type.
template <class Codec>
bool CodecsMatch(const std::vector<Codec>& codecs1,
const std::vector<Codec>& codecs2) {
if (codecs1.size() != codecs2.size()) {
return false;
}
for (size_t i = 0; i < codecs1.size(); ++i) {
if (!codecs1[i].Matches(codecs2[i])) {
return false;
}
}
return true;
}
void TestAudioCodecsOffer(RtpTransceiverDirection direction) {
TransportDescriptionFactory tdf;
UniqueRandomIdGenerator ssrc_generator;
MediaSessionDescriptionFactory sf(&tdf, &ssrc_generator);
const std::vector<AudioCodec> send_codecs = MAKE_VECTOR(kAudioCodecs1);
const std::vector<AudioCodec> recv_codecs = MAKE_VECTOR(kAudioCodecs2);
const std::vector<AudioCodec> sendrecv_codecs =
MAKE_VECTOR(kAudioCodecsAnswer);
sf.set_audio_codecs(send_codecs, recv_codecs);
MediaSessionOptions opts;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio", direction, kActive,
&opts);
if (direction == RtpTransceiverDirection::kSendRecv ||
direction == RtpTransceiverDirection::kSendOnly) {
AttachSenderToMediaDescriptionOptions(
"audio", MEDIA_TYPE_AUDIO, kAudioTrack1, {kMediaStream1}, 1, &opts);
}
std::unique_ptr<SessionDescription> offer = sf.CreateOffer(opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
ContentInfo* ac = offer->GetContentByName("audio");
// If the factory didn't add any audio content to the offer, we cannot check
// that the codecs put in are right. This happens when we neither want to
// send nor receive audio. The checks are still in place if at some point
// we'd instead create an inactive stream.
if (ac) {
AudioContentDescription* acd = ac->media_description()->as_audio();
// sendrecv and inactive should both present lists as if the channel was
// to be used for sending and receiving. Inactive essentially means it
// might eventually be used anything, but we don't know more at this
// moment.
if (acd->direction() == RtpTransceiverDirection::kSendOnly) {
EXPECT_TRUE(CodecsMatch<AudioCodec>(send_codecs, acd->codecs()));
} else if (acd->direction() == RtpTransceiverDirection::kRecvOnly) {
EXPECT_TRUE(CodecsMatch<AudioCodec>(recv_codecs, acd->codecs()));
} else {
EXPECT_TRUE(CodecsMatch<AudioCodec>(sendrecv_codecs, acd->codecs()));
}
}
}
static const AudioCodec kOfferAnswerCodecs[] = {
AudioCodec(0, "codec0", 16000, -1, 1),
AudioCodec(1, "codec1", 8000, 13300, 1),
AudioCodec(2, "codec2", 8000, 64000, 1),
AudioCodec(3, "codec3", 8000, 64000, 1),
AudioCodec(4, "codec4", 8000, 0, 2),
AudioCodec(5, "codec5", 32000, 0, 1),
AudioCodec(6, "codec6", 48000, 0, 1)};
/* The codecs groups below are chosen as per the matrix below. The objective
* is to have different sets of codecs in the inputs, to get unique sets of
* codecs after negotiation, depending on offer and answer communication
* directions. One-way directions in the offer should either result in the
* opposite direction in the answer, or an inactive answer. Regardless, the
* choice of codecs should be as if the answer contained the opposite
* direction. Inactive offers should be treated as sendrecv/sendrecv.
*
* | Offer | Answer | Result
* codec|send recv sr | send recv sr | s/r r/s sr/s sr/r sr/sr
* 0 | x - - | - x - | x - - - -
* 1 | x x x | - x - | x - - x -
* 2 | - x - | x - - | - x - - -
* 3 | x x x | x - - | - x x - -
* 4 | - x - | x x x | - x - - -
* 5 | x - - | x x x | x - - - -
* 6 | x x x | x x x | x x x x x
*/
// Codecs used by offerer in the AudioCodecsAnswerTest
static const int kOfferSendCodecs[] = {0, 1, 3, 5, 6};
static const int kOfferRecvCodecs[] = {1, 2, 3, 4, 6};
// Codecs used in the answerer in the AudioCodecsAnswerTest. The order is
// jumbled to catch the answer not following the order in the offer.
static const int kAnswerSendCodecs[] = {6, 5, 2, 3, 4};
static const int kAnswerRecvCodecs[] = {6, 5, 4, 1, 0};
// The resulting sets of codecs in the answer in the AudioCodecsAnswerTest
static const int kResultSend_RecvCodecs[] = {0, 1, 5, 6};
static const int kResultRecv_SendCodecs[] = {2, 3, 4, 6};
static const int kResultSendrecv_SendCodecs[] = {3, 6};
static const int kResultSendrecv_RecvCodecs[] = {1, 6};
static const int kResultSendrecv_SendrecvCodecs[] = {6};
template <typename T, int IDXS>
std::vector<T> VectorFromIndices(const T* array, const int (&indices)[IDXS]) {
std::vector<T> out;
out.reserve(IDXS);
for (int idx : indices)
out.push_back(array[idx]);
return out;
}
void TestAudioCodecsAnswer(RtpTransceiverDirection offer_direction,
RtpTransceiverDirection answer_direction,
bool add_legacy_stream) {
TransportDescriptionFactory offer_tdf;
TransportDescriptionFactory answer_tdf;
UniqueRandomIdGenerator ssrc_generator1, ssrc_generator2;
MediaSessionDescriptionFactory offer_factory(&offer_tdf, &ssrc_generator1);
MediaSessionDescriptionFactory answer_factory(&answer_tdf, &ssrc_generator2);
offer_factory.set_audio_codecs(
VectorFromIndices(kOfferAnswerCodecs, kOfferSendCodecs),
VectorFromIndices(kOfferAnswerCodecs, kOfferRecvCodecs));
answer_factory.set_audio_codecs(
VectorFromIndices(kOfferAnswerCodecs, kAnswerSendCodecs),
VectorFromIndices(kOfferAnswerCodecs, kAnswerRecvCodecs));
MediaSessionOptions offer_opts;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio", offer_direction,
kActive, &offer_opts);
if (webrtc::RtpTransceiverDirectionHasSend(offer_direction)) {
AttachSenderToMediaDescriptionOptions("audio", MEDIA_TYPE_AUDIO,
kAudioTrack1, {kMediaStream1}, 1,
&offer_opts);
}
std::unique_ptr<SessionDescription> offer =
offer_factory.CreateOffer(offer_opts, NULL);
ASSERT_TRUE(offer.get() != NULL);
MediaSessionOptions answer_opts;
AddMediaDescriptionOptions(MEDIA_TYPE_AUDIO, "audio", answer_direction,
kActive, &answer_opts);
if (webrtc::RtpTransceiverDirectionHasSend(answer_direction)) {
AttachSenderToMediaDescriptionOptions("audio", MEDIA_TYPE_AUDIO,
kAudioTrack1, {kMediaStream1}, 1,
&answer_opts);
}
std::unique_ptr<SessionDescription> answer =
answer_factory.CreateAnswer(offer.get(), answer_opts, NULL);
const ContentInfo* ac = answer->GetContentByName("audio");
// If the factory didn't add any audio content to the answer, we cannot
// check that the codecs put in are right. This happens when we neither want
// to send nor receive audio. The checks are still in place if at some point
// we'd instead create an inactive stream.
if (ac) {
ASSERT_EQ(MEDIA_TYPE_AUDIO, ac->media_description()->type());
const AudioContentDescription* acd = ac->media_description()->as_audio();
std::vector<AudioCodec> target_codecs;
// For offers with sendrecv or inactive, we should never reply with more
// codecs than offered, with these codec sets.
switch (offer_direction) {
case RtpTransceiverDirection::kInactive:
target_codecs = VectorFromIndices(kOfferAnswerCodecs,
kResultSendrecv_SendrecvCodecs);
break;
case RtpTransceiverDirection::kSendOnly:
target_codecs =
VectorFromIndices(kOfferAnswerCodecs, kResultSend_RecvCodecs);
break;
case RtpTransceiverDirection::kRecvOnly:
target_codecs =
VectorFromIndices(kOfferAnswerCodecs, kResultRecv_SendCodecs);
break;
case RtpTransceiverDirection::kSendRecv:
if (acd->direction() == RtpTransceiverDirection::kSendOnly) {
target_codecs =
VectorFromIndices(kOfferAnswerCodecs, kResultSendrecv_SendCodecs);
} else if (acd->direction() == RtpTransceiverDirection::kRecvOnly) {
target_codecs =
VectorFromIndices(kOfferAnswerCodecs, kResultSendrecv_RecvCodecs);
} else {
target_codecs = VectorFromIndices(kOfferAnswerCodecs,
kResultSendrecv_SendrecvCodecs);
}
break;
default:
RTC_NOTREACHED();
}
auto format_codecs = [](const std::vector<AudioCodec>& codecs) {
rtc::StringBuilder os;
bool first = true;
os << "{";
for (const auto& c : codecs) {
os << (first ? " " : ", ") << c.id;
first = false;
}
os << " }";
return os.Release();
};
EXPECT_TRUE(acd->codecs() == target_codecs)
<< "Expected: " << format_codecs(target_codecs)
<< ", got: " << format_codecs(acd->codecs()) << "; Offered: "
<< webrtc::RtpTransceiverDirectionToString(offer_direction)
<< ", answerer wants: "
<< webrtc::RtpTransceiverDirectionToString(answer_direction)
<< "; got: "
<< webrtc::RtpTransceiverDirectionToString(acd->direction());
} else {
EXPECT_EQ(offer_direction, RtpTransceiverDirection::kInactive)
<< "Only inactive offers are allowed to not generate any audio "
"content";
}
}
} // namespace
class AudioCodecsOfferTest
: public ::testing::TestWithParam<RtpTransceiverDirection> {};
TEST_P(AudioCodecsOfferTest, TestCodecsInOffer) {
TestAudioCodecsOffer(GetParam());
}
INSTANTIATE_TEST_SUITE_P(MediaSessionDescriptionFactoryTest,
AudioCodecsOfferTest,
::testing::Values(RtpTransceiverDirection::kSendOnly,
RtpTransceiverDirection::kRecvOnly,
RtpTransceiverDirection::kSendRecv,
RtpTransceiverDirection::kInactive));
class AudioCodecsAnswerTest
: public ::testing::TestWithParam<::testing::tuple<RtpTransceiverDirection,
RtpTransceiverDirection,
bool>> {};
TEST_P(AudioCodecsAnswerTest, TestCodecsInAnswer) {
TestAudioCodecsAnswer(::testing::get<0>(GetParam()),
::testing::get<1>(GetParam()),
::testing::get<2>(GetParam()));
}
INSTANTIATE_TEST_SUITE_P(
MediaSessionDescriptionFactoryTest,
AudioCodecsAnswerTest,
::testing::Combine(::testing::Values(RtpTransceiverDirection::kSendOnly,
RtpTransceiverDirection::kRecvOnly,
RtpTransceiverDirection::kSendRecv,
RtpTransceiverDirection::kInactive),
::testing::Values(RtpTransceiverDirection::kSendOnly,
RtpTransceiverDirection::kRecvOnly,
RtpTransceiverDirection::kSendRecv,
RtpTransceiverDirection::kInactive),
::testing::Bool()));