blob: 38d04582afbcb98159ff074c2b6e3eb027157434 [file] [log] [blame]
/*
* Copyright 2017 The WebRTC project authors. All Rights Reserved.
*
* Use of this source code is governed by a BSD-style license
* that can be found in the LICENSE file in the root of the source
* tree. An additional intellectual property rights grant can be found
* in the file PATENTS. All contributing project authors may
* be found in the AUTHORS file in the root of the source tree.
*/
#include "pc/dtls_srtp_transport.h"
#include <string.h>
#include <cstdint>
#include <memory>
#include <set>
#include "absl/memory/memory.h"
#include "call/rtp_demuxer.h"
#include "media/base/fake_rtp.h"
#include "p2p/base/dtls_transport_internal.h"
#include "p2p/base/fake_dtls_transport.h"
#include "p2p/base/fake_ice_transport.h"
#include "p2p/base/p2p_constants.h"
#include "pc/rtp_transport.h"
#include "pc/test/rtp_transport_test_util.h"
#include "rtc_base/async_packet_socket.h"
#include "rtc_base/byte_order.h"
#include "rtc_base/copy_on_write_buffer.h"
#include "rtc_base/rtc_certificate.h"
#include "rtc_base/ssl_identity.h"
#include "test/gtest.h"
using cricket::FakeDtlsTransport;
using cricket::FakeIceTransport;
using webrtc::DtlsSrtpTransport;
using webrtc::RtpTransport;
using webrtc::SrtpTransport;
const int kRtpAuthTagLen = 10;
class DtlsSrtpTransportTest : public ::testing::Test,
public sigslot::has_slots<> {
protected:
DtlsSrtpTransportTest() {}
~DtlsSrtpTransportTest() {
if (dtls_srtp_transport1_) {
dtls_srtp_transport1_->UnregisterRtpDemuxerSink(&transport_observer1_);
}
if (dtls_srtp_transport2_) {
dtls_srtp_transport2_->UnregisterRtpDemuxerSink(&transport_observer2_);
}
}
std::unique_ptr<DtlsSrtpTransport> MakeDtlsSrtpTransport(
FakeDtlsTransport* rtp_dtls,
FakeDtlsTransport* rtcp_dtls,
bool rtcp_mux_enabled) {
auto dtls_srtp_transport =
absl::make_unique<DtlsSrtpTransport>(rtcp_mux_enabled);
dtls_srtp_transport->SetDtlsTransports(rtp_dtls, rtcp_dtls);
return dtls_srtp_transport;
}
void MakeDtlsSrtpTransports(FakeDtlsTransport* rtp_dtls1,
FakeDtlsTransport* rtcp_dtls1,
FakeDtlsTransport* rtp_dtls2,
FakeDtlsTransport* rtcp_dtls2,
bool rtcp_mux_enabled) {
dtls_srtp_transport1_ =
MakeDtlsSrtpTransport(rtp_dtls1, rtcp_dtls1, rtcp_mux_enabled);
dtls_srtp_transport2_ =
MakeDtlsSrtpTransport(rtp_dtls2, rtcp_dtls2, rtcp_mux_enabled);
dtls_srtp_transport1_->SignalRtcpPacketReceived.connect(
&transport_observer1_,
&webrtc::TransportObserver::OnRtcpPacketReceived);
dtls_srtp_transport1_->SignalReadyToSend.connect(
&transport_observer1_, &webrtc::TransportObserver::OnReadyToSend);
dtls_srtp_transport2_->SignalRtcpPacketReceived.connect(
&transport_observer2_,
&webrtc::TransportObserver::OnRtcpPacketReceived);
dtls_srtp_transport2_->SignalReadyToSend.connect(
&transport_observer2_, &webrtc::TransportObserver::OnReadyToSend);
webrtc::RtpDemuxerCriteria demuxer_criteria;
// 0x00 is the payload type used in kPcmuFrame.
demuxer_criteria.payload_types = {0x00};
dtls_srtp_transport1_->RegisterRtpDemuxerSink(demuxer_criteria,
&transport_observer1_);
dtls_srtp_transport2_->RegisterRtpDemuxerSink(demuxer_criteria,
&transport_observer2_);
}
void CompleteDtlsHandshake(FakeDtlsTransport* fake_dtls1,
FakeDtlsTransport* fake_dtls2) {
auto cert1 = rtc::RTCCertificate::Create(std::unique_ptr<rtc::SSLIdentity>(
rtc::SSLIdentity::Generate("session1", rtc::KT_DEFAULT)));
fake_dtls1->SetLocalCertificate(cert1);
auto cert2 = rtc::RTCCertificate::Create(std::unique_ptr<rtc::SSLIdentity>(
rtc::SSLIdentity::Generate("session1", rtc::KT_DEFAULT)));
fake_dtls2->SetLocalCertificate(cert2);
fake_dtls1->SetDestination(fake_dtls2);
}
void SendRecvRtpPackets() {
ASSERT_TRUE(dtls_srtp_transport1_);
ASSERT_TRUE(dtls_srtp_transport2_);
ASSERT_TRUE(dtls_srtp_transport1_->IsSrtpActive());
ASSERT_TRUE(dtls_srtp_transport2_->IsSrtpActive());
size_t rtp_len = sizeof(kPcmuFrame);
size_t packet_size = rtp_len + kRtpAuthTagLen;
rtc::Buffer rtp_packet_buffer(packet_size);
char* rtp_packet_data = rtp_packet_buffer.data<char>();
memcpy(rtp_packet_data, kPcmuFrame, rtp_len);
// In order to be able to run this test function multiple times we can not
// use the same sequence number twice. Increase the sequence number by one.
rtc::SetBE16(reinterpret_cast<uint8_t*>(rtp_packet_data) + 2,
++sequence_number_);
rtc::CopyOnWriteBuffer rtp_packet1to2(rtp_packet_data, rtp_len,
packet_size);
rtc::CopyOnWriteBuffer rtp_packet2to1(rtp_packet_data, rtp_len,
packet_size);
rtc::PacketOptions options;
// Send a packet from |srtp_transport1_| to |srtp_transport2_| and verify
// that the packet can be successfully received and decrypted.
int prev_received_packets = transport_observer2_.rtp_count();
ASSERT_TRUE(dtls_srtp_transport1_->SendRtpPacket(&rtp_packet1to2, options,
cricket::PF_SRTP_BYPASS));
ASSERT_TRUE(transport_observer2_.last_recv_rtp_packet().data());
EXPECT_EQ(0, memcmp(transport_observer2_.last_recv_rtp_packet().data(),
kPcmuFrame, rtp_len));
EXPECT_EQ(prev_received_packets + 1, transport_observer2_.rtp_count());
prev_received_packets = transport_observer1_.rtp_count();
ASSERT_TRUE(dtls_srtp_transport2_->SendRtpPacket(&rtp_packet2to1, options,
cricket::PF_SRTP_BYPASS));
ASSERT_TRUE(transport_observer1_.last_recv_rtp_packet().data());
EXPECT_EQ(0, memcmp(transport_observer1_.last_recv_rtp_packet().data(),
kPcmuFrame, rtp_len));
EXPECT_EQ(prev_received_packets + 1, transport_observer1_.rtp_count());
}
void SendRecvRtcpPackets() {
size_t rtcp_len = sizeof(kRtcpReport);
size_t packet_size = rtcp_len + 4 + kRtpAuthTagLen;
rtc::Buffer rtcp_packet_buffer(packet_size);
// TODO(zhihuang): Remove the extra copy when the SendRtpPacket method
// doesn't take the CopyOnWriteBuffer by pointer.
rtc::CopyOnWriteBuffer rtcp_packet1to2(kRtcpReport, rtcp_len, packet_size);
rtc::CopyOnWriteBuffer rtcp_packet2to1(kRtcpReport, rtcp_len, packet_size);
rtc::PacketOptions options;
// Send a packet from |srtp_transport1_| to |srtp_transport2_| and verify
// that the packet can be successfully received and decrypted.
int prev_received_packets = transport_observer2_.rtcp_count();
ASSERT_TRUE(dtls_srtp_transport1_->SendRtcpPacket(&rtcp_packet1to2, options,
cricket::PF_SRTP_BYPASS));
ASSERT_TRUE(transport_observer2_.last_recv_rtcp_packet().data());
EXPECT_EQ(0, memcmp(transport_observer2_.last_recv_rtcp_packet().data(),
kRtcpReport, rtcp_len));
EXPECT_EQ(prev_received_packets + 1, transport_observer2_.rtcp_count());
// Do the same thing in the opposite direction;
prev_received_packets = transport_observer1_.rtcp_count();
ASSERT_TRUE(dtls_srtp_transport2_->SendRtcpPacket(&rtcp_packet2to1, options,
cricket::PF_SRTP_BYPASS));
ASSERT_TRUE(transport_observer1_.last_recv_rtcp_packet().data());
EXPECT_EQ(0, memcmp(transport_observer1_.last_recv_rtcp_packet().data(),
kRtcpReport, rtcp_len));
EXPECT_EQ(prev_received_packets + 1, transport_observer1_.rtcp_count());
}
void SendRecvRtpPacketsWithHeaderExtension(
const std::vector<int>& encrypted_header_ids) {
ASSERT_TRUE(dtls_srtp_transport1_);
ASSERT_TRUE(dtls_srtp_transport2_);
ASSERT_TRUE(dtls_srtp_transport1_->IsSrtpActive());
ASSERT_TRUE(dtls_srtp_transport2_->IsSrtpActive());
size_t rtp_len = sizeof(kPcmuFrameWithExtensions);
size_t packet_size = rtp_len + kRtpAuthTagLen;
rtc::Buffer rtp_packet_buffer(packet_size);
char* rtp_packet_data = rtp_packet_buffer.data<char>();
memcpy(rtp_packet_data, kPcmuFrameWithExtensions, rtp_len);
// In order to be able to run this test function multiple times we can not
// use the same sequence number twice. Increase the sequence number by one.
rtc::SetBE16(reinterpret_cast<uint8_t*>(rtp_packet_data) + 2,
++sequence_number_);
rtc::CopyOnWriteBuffer rtp_packet1to2(rtp_packet_data, rtp_len,
packet_size);
rtc::CopyOnWriteBuffer rtp_packet2to1(rtp_packet_data, rtp_len,
packet_size);
char original_rtp_data[sizeof(kPcmuFrameWithExtensions)];
memcpy(original_rtp_data, rtp_packet_data, rtp_len);
rtc::PacketOptions options;
// Send a packet from |srtp_transport1_| to |srtp_transport2_| and verify
// that the packet can be successfully received and decrypted.
ASSERT_TRUE(dtls_srtp_transport1_->SendRtpPacket(&rtp_packet1to2, options,
cricket::PF_SRTP_BYPASS));
ASSERT_TRUE(transport_observer2_.last_recv_rtp_packet().data());
EXPECT_EQ(0, memcmp(transport_observer2_.last_recv_rtp_packet().data(),
original_rtp_data, rtp_len));
// Get the encrypted packet from underneath packet transport and verify the
// data and header extension are actually encrypted.
auto fake_dtls_transport = static_cast<FakeDtlsTransport*>(
dtls_srtp_transport1_->rtp_packet_transport());
auto fake_ice_transport =
static_cast<FakeIceTransport*>(fake_dtls_transport->ice_transport());
EXPECT_NE(0, memcmp(fake_ice_transport->last_sent_packet().data(),
original_rtp_data, rtp_len));
CompareHeaderExtensions(reinterpret_cast<const char*>(
fake_ice_transport->last_sent_packet().data()),
fake_ice_transport->last_sent_packet().size(),
original_rtp_data, rtp_len, encrypted_header_ids,
false);
// Do the same thing in the opposite direction.
ASSERT_TRUE(dtls_srtp_transport2_->SendRtpPacket(&rtp_packet2to1, options,
cricket::PF_SRTP_BYPASS));
ASSERT_TRUE(transport_observer1_.last_recv_rtp_packet().data());
EXPECT_EQ(0, memcmp(transport_observer1_.last_recv_rtp_packet().data(),
original_rtp_data, rtp_len));
// Get the encrypted packet from underneath packet transport and verify the
// data and header extension are actually encrypted.
fake_dtls_transport = static_cast<FakeDtlsTransport*>(
dtls_srtp_transport2_->rtp_packet_transport());
fake_ice_transport =
static_cast<FakeIceTransport*>(fake_dtls_transport->ice_transport());
EXPECT_NE(0, memcmp(fake_ice_transport->last_sent_packet().data(),
original_rtp_data, rtp_len));
CompareHeaderExtensions(reinterpret_cast<const char*>(
fake_ice_transport->last_sent_packet().data()),
fake_ice_transport->last_sent_packet().size(),
original_rtp_data, rtp_len, encrypted_header_ids,
false);
}
void SendRecvPackets() {
SendRecvRtpPackets();
SendRecvRtcpPackets();
}
std::unique_ptr<DtlsSrtpTransport> dtls_srtp_transport1_;
std::unique_ptr<DtlsSrtpTransport> dtls_srtp_transport2_;
webrtc::TransportObserver transport_observer1_;
webrtc::TransportObserver transport_observer2_;
int sequence_number_ = 0;
};
// Tests that if RTCP muxing is enabled and transports are set after RTP
// transport finished the handshake, SRTP is set up.
TEST_F(DtlsSrtpTransportTest, SetTransportsAfterHandshakeCompleteWithRtcpMux) {
auto rtp_dtls1 = absl::make_unique<FakeDtlsTransport>(
"video", cricket::ICE_CANDIDATE_COMPONENT_RTP);
auto rtp_dtls2 = absl::make_unique<FakeDtlsTransport>(
"video", cricket::ICE_CANDIDATE_COMPONENT_RTP);
MakeDtlsSrtpTransports(rtp_dtls1.get(), nullptr, rtp_dtls2.get(), nullptr,
/*rtcp_mux_enabled=*/true);
auto rtp_dtls3 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTP);
auto rtp_dtls4 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTP);
CompleteDtlsHandshake(rtp_dtls3.get(), rtp_dtls4.get());
dtls_srtp_transport1_->SetDtlsTransports(rtp_dtls3.get(), nullptr);
dtls_srtp_transport2_->SetDtlsTransports(rtp_dtls4.get(), nullptr);
SendRecvPackets();
}
// Tests that if RTCP muxing is not enabled and transports are set after both
// RTP and RTCP transports finished the handshake, SRTP is set up.
TEST_F(DtlsSrtpTransportTest,
SetTransportsAfterHandshakeCompleteWithoutRtcpMux) {
auto rtp_dtls1 = absl::make_unique<FakeDtlsTransport>(
"video", cricket::ICE_CANDIDATE_COMPONENT_RTP);
auto rtcp_dtls1 = absl::make_unique<FakeDtlsTransport>(
"video", cricket::ICE_CANDIDATE_COMPONENT_RTCP);
auto rtp_dtls2 = absl::make_unique<FakeDtlsTransport>(
"video", cricket::ICE_CANDIDATE_COMPONENT_RTP);
auto rtcp_dtls2 = absl::make_unique<FakeDtlsTransport>(
"video", cricket::ICE_CANDIDATE_COMPONENT_RTCP);
MakeDtlsSrtpTransports(rtp_dtls1.get(), rtcp_dtls1.get(), rtp_dtls2.get(),
rtcp_dtls2.get(), /*rtcp_mux_enabled=*/false);
auto rtp_dtls3 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTP);
auto rtcp_dtls3 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTCP);
auto rtp_dtls4 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTP);
auto rtcp_dtls4 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTCP);
CompleteDtlsHandshake(rtp_dtls3.get(), rtp_dtls4.get());
CompleteDtlsHandshake(rtcp_dtls3.get(), rtcp_dtls4.get());
dtls_srtp_transport1_->SetDtlsTransports(rtp_dtls3.get(), rtcp_dtls3.get());
dtls_srtp_transport2_->SetDtlsTransports(rtp_dtls4.get(), rtcp_dtls4.get());
SendRecvPackets();
}
// Tests if RTCP muxing is enabled, SRTP is set up as soon as the RTP DTLS
// handshake is finished.
TEST_F(DtlsSrtpTransportTest, SetTransportsBeforeHandshakeCompleteWithRtcpMux) {
auto rtp_dtls1 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTP);
auto rtcp_dtls1 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTCP);
auto rtp_dtls2 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTP);
auto rtcp_dtls2 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTCP);
MakeDtlsSrtpTransports(rtp_dtls1.get(), rtcp_dtls1.get(), rtp_dtls2.get(),
rtcp_dtls2.get(),
/*rtcp_mux_enabled=*/false);
dtls_srtp_transport1_->SetRtcpMuxEnabled(true);
dtls_srtp_transport2_->SetRtcpMuxEnabled(true);
CompleteDtlsHandshake(rtp_dtls1.get(), rtp_dtls2.get());
SendRecvPackets();
}
// Tests if RTCP muxing is not enabled, SRTP is set up when both the RTP and
// RTCP DTLS handshake are finished.
TEST_F(DtlsSrtpTransportTest,
SetTransportsBeforeHandshakeCompleteWithoutRtcpMux) {
auto rtp_dtls1 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTP);
auto rtcp_dtls1 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTCP);
auto rtp_dtls2 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTP);
auto rtcp_dtls2 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTCP);
MakeDtlsSrtpTransports(rtp_dtls1.get(), rtcp_dtls1.get(), rtp_dtls2.get(),
rtcp_dtls2.get(), /*rtcp_mux_enabled=*/false);
CompleteDtlsHandshake(rtp_dtls1.get(), rtp_dtls2.get());
EXPECT_FALSE(dtls_srtp_transport1_->IsSrtpActive());
EXPECT_FALSE(dtls_srtp_transport2_->IsSrtpActive());
CompleteDtlsHandshake(rtcp_dtls1.get(), rtcp_dtls2.get());
SendRecvPackets();
}
// Tests that if the DtlsTransport underneath is changed, the previous DTLS-SRTP
// context will be reset and will be re-setup once the new transports' handshake
// complete.
TEST_F(DtlsSrtpTransportTest, DtlsSrtpResetAfterDtlsTransportChange) {
auto rtp_dtls1 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTP);
auto rtp_dtls2 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTP);
MakeDtlsSrtpTransports(rtp_dtls1.get(), nullptr, rtp_dtls2.get(), nullptr,
/*rtcp_mux_enabled=*/true);
CompleteDtlsHandshake(rtp_dtls1.get(), rtp_dtls2.get());
EXPECT_TRUE(dtls_srtp_transport1_->IsSrtpActive());
EXPECT_TRUE(dtls_srtp_transport2_->IsSrtpActive());
auto rtp_dtls3 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTP);
auto rtp_dtls4 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTP);
// The previous context is reset.
dtls_srtp_transport1_->SetDtlsTransports(rtp_dtls3.get(), nullptr);
dtls_srtp_transport2_->SetDtlsTransports(rtp_dtls4.get(), nullptr);
EXPECT_FALSE(dtls_srtp_transport1_->IsSrtpActive());
EXPECT_FALSE(dtls_srtp_transport2_->IsSrtpActive());
// Re-setup.
CompleteDtlsHandshake(rtp_dtls3.get(), rtp_dtls4.get());
SendRecvPackets();
}
// Tests if only the RTP DTLS handshake complete, and then RTCP muxing is
// enabled, SRTP is set up.
TEST_F(DtlsSrtpTransportTest,
RtcpMuxEnabledAfterRtpTransportHandshakeComplete) {
auto rtp_dtls1 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTP);
auto rtcp_dtls1 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTCP);
auto rtp_dtls2 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTP);
auto rtcp_dtls2 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTCP);
MakeDtlsSrtpTransports(rtp_dtls1.get(), rtcp_dtls1.get(), rtp_dtls2.get(),
rtcp_dtls2.get(), /*rtcp_mux_enabled=*/false);
CompleteDtlsHandshake(rtp_dtls1.get(), rtp_dtls2.get());
// Inactive because the RTCP transport handshake didn't complete.
EXPECT_FALSE(dtls_srtp_transport1_->IsSrtpActive());
EXPECT_FALSE(dtls_srtp_transport2_->IsSrtpActive());
dtls_srtp_transport1_->SetRtcpMuxEnabled(true);
dtls_srtp_transport2_->SetRtcpMuxEnabled(true);
// The transports should be active and be able to send packets when the
// RTCP muxing is enabled.
SendRecvPackets();
}
// Tests that when SetSend/RecvEncryptedHeaderExtensionIds is called, the SRTP
// sessions are updated with new encryped header extension IDs immediately.
TEST_F(DtlsSrtpTransportTest, EncryptedHeaderExtensionIdUpdated) {
auto rtp_dtls1 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTP);
auto rtp_dtls2 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTP);
MakeDtlsSrtpTransports(rtp_dtls1.get(), nullptr, rtp_dtls2.get(), nullptr,
/*rtcp_mux_enabled=*/true);
CompleteDtlsHandshake(rtp_dtls1.get(), rtp_dtls2.get());
std::vector<int> encrypted_headers;
encrypted_headers.push_back(kHeaderExtensionIDs[0]);
encrypted_headers.push_back(kHeaderExtensionIDs[1]);
dtls_srtp_transport1_->UpdateSendEncryptedHeaderExtensionIds(
encrypted_headers);
dtls_srtp_transport1_->UpdateRecvEncryptedHeaderExtensionIds(
encrypted_headers);
dtls_srtp_transport2_->UpdateSendEncryptedHeaderExtensionIds(
encrypted_headers);
dtls_srtp_transport2_->UpdateRecvEncryptedHeaderExtensionIds(
encrypted_headers);
}
// Tests if RTCP muxing is enabled. DtlsSrtpTransport is ready to send once the
// RTP DtlsTransport is ready.
TEST_F(DtlsSrtpTransportTest, SignalReadyToSendFiredWithRtcpMux) {
auto rtp_dtls1 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTP);
auto rtp_dtls2 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTP);
MakeDtlsSrtpTransports(rtp_dtls1.get(), nullptr, rtp_dtls2.get(), nullptr,
/*rtcp_mux_enabled=*/true);
rtp_dtls1->SetDestination(rtp_dtls2.get());
EXPECT_TRUE(transport_observer1_.ready_to_send());
EXPECT_TRUE(transport_observer2_.ready_to_send());
}
// Tests if RTCP muxing is not enabled. DtlsSrtpTransport is ready to send once
// both the RTP and RTCP DtlsTransport are ready.
TEST_F(DtlsSrtpTransportTest, SignalReadyToSendFiredWithoutRtcpMux) {
auto rtp_dtls1 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTP);
auto rtcp_dtls1 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTCP);
auto rtp_dtls2 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTP);
auto rtcp_dtls2 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTCP);
MakeDtlsSrtpTransports(rtp_dtls1.get(), rtcp_dtls1.get(), rtp_dtls2.get(),
rtcp_dtls2.get(), /*rtcp_mux_enabled=*/false);
rtp_dtls1->SetDestination(rtp_dtls2.get());
EXPECT_FALSE(transport_observer1_.ready_to_send());
EXPECT_FALSE(transport_observer2_.ready_to_send());
rtcp_dtls1->SetDestination(rtcp_dtls2.get());
EXPECT_TRUE(transport_observer1_.ready_to_send());
EXPECT_TRUE(transport_observer2_.ready_to_send());
}
// Test that if an endpoint "fully" enables RTCP mux, setting the RTCP
// transport to null, it *doesn't* reset its SRTP context. That would cause the
// ROC and SRTCP index to be reset, causing replay detection and other errors
// when attempting to unprotect packets.
// Regression test for bugs.webrtc.org/8996
TEST_F(DtlsSrtpTransportTest, SrtpSessionNotResetWhenRtcpTransportRemoved) {
auto rtp_dtls1 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTP);
auto rtcp_dtls1 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTCP);
auto rtp_dtls2 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTP);
auto rtcp_dtls2 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTCP);
MakeDtlsSrtpTransports(rtp_dtls1.get(), rtcp_dtls1.get(), rtp_dtls2.get(),
rtcp_dtls2.get(), /*rtcp_mux_enabled=*/true);
CompleteDtlsHandshake(rtp_dtls1.get(), rtp_dtls2.get());
CompleteDtlsHandshake(rtcp_dtls1.get(), rtcp_dtls2.get());
// Send some RTCP packets, causing the SRTCP index to be incremented.
SendRecvRtcpPackets();
// Set RTCP transport to null, which previously would trigger this problem.
dtls_srtp_transport1_->SetDtlsTransports(rtp_dtls1.get(), nullptr);
// Attempt to send more RTCP packets. If the issue occurred, one side would
// reset its context while the other would not, causing replay detection
// errors when a packet with a duplicate SRTCP index is received.
SendRecvRtcpPackets();
}
// Tests that RTCP packets can be sent and received if both sides actively reset
// the SRTP parameters with the |active_reset_srtp_params_| flag.
TEST_F(DtlsSrtpTransportTest, ActivelyResetSrtpParams) {
auto rtp_dtls1 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTP);
auto rtcp_dtls1 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTCP);
auto rtp_dtls2 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTP);
auto rtcp_dtls2 = absl::make_unique<FakeDtlsTransport>(
"audio", cricket::ICE_CANDIDATE_COMPONENT_RTCP);
MakeDtlsSrtpTransports(rtp_dtls1.get(), rtcp_dtls1.get(), rtp_dtls2.get(),
rtcp_dtls2.get(), /*rtcp_mux_enabled=*/true);
CompleteDtlsHandshake(rtp_dtls1.get(), rtp_dtls2.get());
CompleteDtlsHandshake(rtcp_dtls1.get(), rtcp_dtls2.get());
// Send some RTCP packets, causing the SRTCP index to be incremented.
SendRecvRtcpPackets();
// Only set the |active_reset_srtp_params_| flag to be true one side.
dtls_srtp_transport1_->SetActiveResetSrtpParams(true);
// Set RTCP transport to null to trigger the SRTP parameters update.
dtls_srtp_transport1_->SetDtlsTransports(rtp_dtls1.get(), nullptr);
dtls_srtp_transport2_->SetDtlsTransports(rtp_dtls2.get(), nullptr);
// Sending some RTCP packets.
size_t rtcp_len = sizeof(kRtcpReport);
size_t packet_size = rtcp_len + 4 + kRtpAuthTagLen;
rtc::Buffer rtcp_packet_buffer(packet_size);
rtc::CopyOnWriteBuffer rtcp_packet(kRtcpReport, rtcp_len, packet_size);
int prev_received_packets = transport_observer2_.rtcp_count();
ASSERT_TRUE(dtls_srtp_transport1_->SendRtcpPacket(
&rtcp_packet, rtc::PacketOptions(), cricket::PF_SRTP_BYPASS));
// The RTCP packet is not exepected to be received because the SRTP parameters
// are only reset on one side and the SRTCP index is out of sync.
EXPECT_EQ(prev_received_packets, transport_observer2_.rtcp_count());
// Set the flag to be true on the other side.
dtls_srtp_transport2_->SetActiveResetSrtpParams(true);
// Set RTCP transport to null to trigger the SRTP parameters update.
dtls_srtp_transport1_->SetDtlsTransports(rtp_dtls1.get(), nullptr);
dtls_srtp_transport2_->SetDtlsTransports(rtp_dtls2.get(), nullptr);
// RTCP packets flow is expected to work just fine.
SendRecvRtcpPackets();
}