pc/srtp_transport_unittest.cc - src/ - Git at Google

 /*
  *  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/srtp_transport.h"

 #include <string.h>

 #include <vector>

 #include "call/rtp_demuxer.h"
 #include "media/base/fake_rtp.h"
 #include "p2p/base/dtls_transport_internal.h"
 #include "p2p/base/fake_packet_transport.h"
 #include "pc/test/rtp_transport_test_util.h"
 #include "pc/test/srtp_test_util.h"
 #include "rtc_base/async_packet_socket.h"
 #include "rtc_base/byte_order.h"
 #include "rtc_base/checks.h"
 #include "rtc_base/containers/flat_set.h"
 #include "rtc_base/ssl_stream_adapter.h"
 #include "rtc_base/third_party/sigslot/sigslot.h"
 #include "test/gtest.h"
 #include "test/scoped_key_value_config.h"

 using rtc::kSrtpAeadAes128Gcm;
 using rtc::kTestKey1;
 using rtc::kTestKey2;
 using rtc::kTestKeyLen;

 namespace webrtc {
 static const uint8_t kTestKeyGcm128_1[] = "ABCDEFGHIJKLMNOPQRSTUVWXYZ12";
 static const uint8_t kTestKeyGcm128_2[] = "21ZYXWVUTSRQPONMLKJIHGFEDCBA";
 static const int kTestKeyGcm128Len = 28;  // 128 bits key + 96 bits salt.
 static const uint8_t kTestKeyGcm256_1[] =
     "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqr";
 static const uint8_t kTestKeyGcm256_2[] =
     "rqponmlkjihgfedcbaZYXWVUTSRQPONMLKJIHGFEDCBA";
 static const int kTestKeyGcm256Len = 44;  // 256 bits key + 96 bits salt.

 class SrtpTransportTest : public ::testing::Test, public sigslot::has_slots<> {
  protected:
   SrtpTransportTest() {
     bool rtcp_mux_enabled = true;

     rtp_packet_transport1_ =
         std::make_unique<rtc::FakePacketTransport>("fake_packet_transport1");
     rtp_packet_transport2_ =
         std::make_unique<rtc::FakePacketTransport>("fake_packet_transport2");

     bool asymmetric = false;
     rtp_packet_transport1_->SetDestination(rtp_packet_transport2_.get(),
                                            asymmetric);

     srtp_transport1_ =
         std::make_unique<SrtpTransport>(rtcp_mux_enabled, field_trials_);
     srtp_transport2_ =
         std::make_unique<SrtpTransport>(rtcp_mux_enabled, field_trials_);

     srtp_transport1_->SetRtpPacketTransport(rtp_packet_transport1_.get());
     srtp_transport2_->SetRtpPacketTransport(rtp_packet_transport2_.get());

     srtp_transport1_->SubscribeRtcpPacketReceived(
         &rtp_sink1_,
         [this](rtc::CopyOnWriteBuffer* buffer, int64_t packet_time_ms) {
           rtp_sink1_.OnRtcpPacketReceived(buffer, packet_time_ms);
         });
     srtp_transport2_->SubscribeRtcpPacketReceived(
         &rtp_sink2_,
         [this](rtc::CopyOnWriteBuffer* buffer, int64_t packet_time_ms) {
           rtp_sink2_.OnRtcpPacketReceived(buffer, packet_time_ms);
         });

     RtpDemuxerCriteria demuxer_criteria;
     // 0x00 is the payload type used in kPcmuFrame.
     demuxer_criteria.payload_types().insert(0x00);

     srtp_transport1_->RegisterRtpDemuxerSink(demuxer_criteria, &rtp_sink1_);
     srtp_transport2_->RegisterRtpDemuxerSink(demuxer_criteria, &rtp_sink2_);
   }

   ~SrtpTransportTest() {
     if (srtp_transport1_) {
       srtp_transport1_->UnregisterRtpDemuxerSink(&rtp_sink1_);
     }
     if (srtp_transport2_) {
       srtp_transport2_->UnregisterRtpDemuxerSink(&rtp_sink2_);
     }
   }

   // With external auth enabled, SRTP doesn't write the auth tag and
   // unprotect would fail. Check accessing the information about the
   // tag instead, similar to what the actual code would do that relies
   // on external auth.
   void TestRtpAuthParams(SrtpTransport* transport, const std::string& cs) {
     int overhead;
     EXPECT_TRUE(transport->GetSrtpOverhead(&overhead));
     switch (rtc::SrtpCryptoSuiteFromName(cs)) {
       case rtc::kSrtpAes128CmSha1_32:
         EXPECT_EQ(32 / 8, overhead);  // 32-bit tag.
         break;
       case rtc::kSrtpAes128CmSha1_80:
         EXPECT_EQ(80 / 8, overhead);  // 80-bit tag.
         break;
       default:
         RTC_DCHECK_NOTREACHED();
         break;
     }

     uint8_t* auth_key = nullptr;
     int key_len = 0;
     int tag_len = 0;
     EXPECT_TRUE(transport->GetRtpAuthParams(&auth_key, &key_len, &tag_len));
     EXPECT_NE(nullptr, auth_key);
     EXPECT_EQ(160 / 8, key_len);  // Length of SHA-1 is 160 bits.
     EXPECT_EQ(overhead, tag_len);
   }

   void TestSendRecvRtpPacket(const std::string& cipher_suite_name) {
     size_t rtp_len = sizeof(kPcmuFrame);
     size_t packet_size = rtp_len + rtc::rtp_auth_tag_len(cipher_suite_name);
     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);

     char original_rtp_data[sizeof(kPcmuFrame)];
     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(srtp_transport1_->SendRtpPacket(&rtp_packet1to2, options,
                                                 cricket::PF_SRTP_BYPASS));
     if (srtp_transport1_->IsExternalAuthActive()) {
       TestRtpAuthParams(srtp_transport1_.get(), cipher_suite_name);
     } else {
       ASSERT_TRUE(rtp_sink2_.last_recv_rtp_packet().data());
       EXPECT_EQ(0, memcmp(rtp_sink2_.last_recv_rtp_packet().data(),
                           original_rtp_data, rtp_len));
       // Get the encrypted packet from underneath packet transport and verify
       // the data is actually encrypted.
       auto fake_rtp_packet_transport = static_cast<rtc::FakePacketTransport*>(
           srtp_transport1_->rtp_packet_transport());
       EXPECT_NE(0, memcmp(fake_rtp_packet_transport->last_sent_packet()->data(),
                           original_rtp_data, rtp_len));
     }

     // Do the same thing in the opposite direction;
     ASSERT_TRUE(srtp_transport2_->SendRtpPacket(&rtp_packet2to1, options,
                                                 cricket::PF_SRTP_BYPASS));
     if (srtp_transport2_->IsExternalAuthActive()) {
       TestRtpAuthParams(srtp_transport2_.get(), cipher_suite_name);
     } else {
       ASSERT_TRUE(rtp_sink1_.last_recv_rtp_packet().data());
       EXPECT_EQ(0, memcmp(rtp_sink1_.last_recv_rtp_packet().data(),
                           original_rtp_data, rtp_len));
       auto fake_rtp_packet_transport = static_cast<rtc::FakePacketTransport*>(
           srtp_transport2_->rtp_packet_transport());
       EXPECT_NE(0, memcmp(fake_rtp_packet_transport->last_sent_packet()->data(),
                           original_rtp_data, rtp_len));
     }
   }

   void TestSendRecvRtcpPacket(const std::string& cipher_suite_name) {
     size_t rtcp_len = sizeof(::kRtcpReport);
     size_t packet_size =
         rtcp_len + 4 + rtc::rtcp_auth_tag_len(cipher_suite_name);
     rtc::Buffer rtcp_packet_buffer(packet_size);
     char* rtcp_packet_data = rtcp_packet_buffer.data<char>();
     memcpy(rtcp_packet_data, ::kRtcpReport, rtcp_len);

     rtc::CopyOnWriteBuffer rtcp_packet1to2(rtcp_packet_data, rtcp_len,
                                            packet_size);
     rtc::CopyOnWriteBuffer rtcp_packet2to1(rtcp_packet_data, 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.
     ASSERT_TRUE(srtp_transport1_->SendRtcpPacket(&rtcp_packet1to2, options,
                                                  cricket::PF_SRTP_BYPASS));
     ASSERT_TRUE(rtp_sink2_.last_recv_rtcp_packet().data());
     EXPECT_EQ(0, memcmp(rtp_sink2_.last_recv_rtcp_packet().data(),
                         rtcp_packet_data, rtcp_len));
     // Get the encrypted packet from underneath packet transport and verify the
     // data is actually encrypted.
     auto fake_rtp_packet_transport = static_cast<rtc::FakePacketTransport*>(
         srtp_transport1_->rtp_packet_transport());
     EXPECT_NE(0, memcmp(fake_rtp_packet_transport->last_sent_packet()->data(),
                         rtcp_packet_data, rtcp_len));

     // Do the same thing in the opposite direction;
     ASSERT_TRUE(srtp_transport2_->SendRtcpPacket(&rtcp_packet2to1, options,
                                                  cricket::PF_SRTP_BYPASS));
     ASSERT_TRUE(rtp_sink1_.last_recv_rtcp_packet().data());
     EXPECT_EQ(0, memcmp(rtp_sink1_.last_recv_rtcp_packet().data(),
                         rtcp_packet_data, rtcp_len));
     fake_rtp_packet_transport = static_cast<rtc::FakePacketTransport*>(
         srtp_transport2_->rtp_packet_transport());
     EXPECT_NE(0, memcmp(fake_rtp_packet_transport->last_sent_packet()->data(),
                         rtcp_packet_data, rtcp_len));
   }

   void TestSendRecvPacket(bool enable_external_auth,
                           int cs,
                           const uint8_t* key1,
                           int key1_len,
                           const uint8_t* key2,
                           int key2_len,
                           const std::string& cipher_suite_name) {
     EXPECT_EQ(key1_len, key2_len);
     EXPECT_EQ(cipher_suite_name, rtc::SrtpCryptoSuiteToName(cs));
     if (enable_external_auth) {
       srtp_transport1_->EnableExternalAuth();
       srtp_transport2_->EnableExternalAuth();
     }
     std::vector<int> extension_ids;
     EXPECT_TRUE(srtp_transport1_->SetRtpParams(
         cs, key1, key1_len, extension_ids, cs, key2, key2_len, extension_ids));
     EXPECT_TRUE(srtp_transport2_->SetRtpParams(
         cs, key2, key2_len, extension_ids, cs, key1, key1_len, extension_ids));
     EXPECT_TRUE(srtp_transport1_->SetRtcpParams(
         cs, key1, key1_len, extension_ids, cs, key2, key2_len, extension_ids));
     EXPECT_TRUE(srtp_transport2_->SetRtcpParams(
         cs, key2, key2_len, extension_ids, cs, key1, key1_len, extension_ids));
     EXPECT_TRUE(srtp_transport1_->IsSrtpActive());
     EXPECT_TRUE(srtp_transport2_->IsSrtpActive());
     if (rtc::IsGcmCryptoSuite(cs)) {
       EXPECT_FALSE(srtp_transport1_->IsExternalAuthActive());
       EXPECT_FALSE(srtp_transport2_->IsExternalAuthActive());
     } else if (enable_external_auth) {
       EXPECT_TRUE(srtp_transport1_->IsExternalAuthActive());
       EXPECT_TRUE(srtp_transport2_->IsExternalAuthActive());
     }
     TestSendRecvRtpPacket(cipher_suite_name);
     TestSendRecvRtcpPacket(cipher_suite_name);
   }

   void TestSendRecvPacketWithEncryptedHeaderExtension(
       const std::string& cs,
       const std::vector<int>& encrypted_header_ids) {
     size_t rtp_len = sizeof(kPcmuFrameWithExtensions);
     size_t packet_size = rtp_len + rtc::rtp_auth_tag_len(cs);
     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(srtp_transport1_->SendRtpPacket(&rtp_packet1to2, options,
                                                 cricket::PF_SRTP_BYPASS));
     ASSERT_TRUE(rtp_sink2_.last_recv_rtp_packet().data());
     EXPECT_EQ(0, memcmp(rtp_sink2_.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_rtp_packet_transport = static_cast<rtc::FakePacketTransport*>(
         srtp_transport1_->rtp_packet_transport());
     EXPECT_NE(0, memcmp(fake_rtp_packet_transport->last_sent_packet()->data(),
                         original_rtp_data, rtp_len));
     CompareHeaderExtensions(
         reinterpret_cast<const char*>(
             fake_rtp_packet_transport->last_sent_packet()->data()),
         fake_rtp_packet_transport->last_sent_packet()->size(),
         original_rtp_data, rtp_len, encrypted_header_ids, false);

     // Do the same thing in the opposite direction;
     ASSERT_TRUE(srtp_transport2_->SendRtpPacket(&rtp_packet2to1, options,
                                                 cricket::PF_SRTP_BYPASS));
     ASSERT_TRUE(rtp_sink1_.last_recv_rtp_packet().data());
     EXPECT_EQ(0, memcmp(rtp_sink1_.last_recv_rtp_packet().data(),
                         original_rtp_data, rtp_len));
     fake_rtp_packet_transport = static_cast<rtc::FakePacketTransport*>(
         srtp_transport2_->rtp_packet_transport());
     EXPECT_NE(0, memcmp(fake_rtp_packet_transport->last_sent_packet()->data(),
                         original_rtp_data, rtp_len));
     CompareHeaderExtensions(
         reinterpret_cast<const char*>(
             fake_rtp_packet_transport->last_sent_packet()->data()),
         fake_rtp_packet_transport->last_sent_packet()->size(),
         original_rtp_data, rtp_len, encrypted_header_ids, false);
   }

   void TestSendRecvEncryptedHeaderExtension(int cs,
                                             const uint8_t* key1,
                                             int key1_len,
                                             const uint8_t* key2,
                                             int key2_len,
                                             const std::string& cs_name) {
     std::vector<int> encrypted_headers;
     encrypted_headers.push_back(kHeaderExtensionIDs[0]);
     // Don't encrypt header ids 2 and 3.
     encrypted_headers.push_back(kHeaderExtensionIDs[1]);
     EXPECT_EQ(key1_len, key2_len);
     EXPECT_EQ(cs_name, rtc::SrtpCryptoSuiteToName(cs));
     EXPECT_TRUE(srtp_transport1_->SetRtpParams(cs, key1, key1_len,
                                                encrypted_headers, cs, key2,
                                                key2_len, encrypted_headers));
     EXPECT_TRUE(srtp_transport2_->SetRtpParams(cs, key2, key2_len,
                                                encrypted_headers, cs, key1,
                                                key1_len, encrypted_headers));
     EXPECT_TRUE(srtp_transport1_->IsSrtpActive());
     EXPECT_TRUE(srtp_transport2_->IsSrtpActive());
     EXPECT_FALSE(srtp_transport1_->IsExternalAuthActive());
     EXPECT_FALSE(srtp_transport2_->IsExternalAuthActive());
     TestSendRecvPacketWithEncryptedHeaderExtension(cs_name, encrypted_headers);
   }

   std::unique_ptr<SrtpTransport> srtp_transport1_;
   std::unique_ptr<SrtpTransport> srtp_transport2_;

   std::unique_ptr<rtc::FakePacketTransport> rtp_packet_transport1_;
   std::unique_ptr<rtc::FakePacketTransport> rtp_packet_transport2_;

   TransportObserver rtp_sink1_;
   TransportObserver rtp_sink2_;

   int sequence_number_ = 0;
   test::ScopedKeyValueConfig field_trials_;
 };

 class SrtpTransportTestWithExternalAuth
     : public SrtpTransportTest,
       public ::testing::WithParamInterface<bool> {};

 TEST_P(SrtpTransportTestWithExternalAuth,
        SendAndRecvPacket_AES_CM_128_HMAC_SHA1_80) {
   bool enable_external_auth = GetParam();
   TestSendRecvPacket(enable_external_auth, rtc::kSrtpAes128CmSha1_80, kTestKey1,
                      kTestKeyLen, kTestKey2, kTestKeyLen,
                      rtc::kCsAesCm128HmacSha1_80);
 }

 TEST_F(SrtpTransportTest,
        SendAndRecvPacketWithHeaderExtension_AES_CM_128_HMAC_SHA1_80) {
   TestSendRecvEncryptedHeaderExtension(rtc::kSrtpAes128CmSha1_80, kTestKey1,
                                        kTestKeyLen, kTestKey2, kTestKeyLen,
                                        rtc::kCsAesCm128HmacSha1_80);
 }

 TEST_P(SrtpTransportTestWithExternalAuth,
        SendAndRecvPacket_AES_CM_128_HMAC_SHA1_32) {
   bool enable_external_auth = GetParam();
   TestSendRecvPacket(enable_external_auth, rtc::kSrtpAes128CmSha1_32, kTestKey1,
                      kTestKeyLen, kTestKey2, kTestKeyLen,
                      rtc::kCsAesCm128HmacSha1_32);
 }

 TEST_F(SrtpTransportTest,
        SendAndRecvPacketWithHeaderExtension_AES_CM_128_HMAC_SHA1_32) {
   TestSendRecvEncryptedHeaderExtension(rtc::kSrtpAes128CmSha1_32, kTestKey1,
                                        kTestKeyLen, kTestKey2, kTestKeyLen,
                                        rtc::kCsAesCm128HmacSha1_32);
 }

 TEST_P(SrtpTransportTestWithExternalAuth,
        SendAndRecvPacket_kSrtpAeadAes128Gcm) {
   bool enable_external_auth = GetParam();
   TestSendRecvPacket(enable_external_auth, rtc::kSrtpAeadAes128Gcm,
                      kTestKeyGcm128_1, kTestKeyGcm128Len, kTestKeyGcm128_2,
                      kTestKeyGcm128Len, rtc::kCsAeadAes128Gcm);
 }

 TEST_F(SrtpTransportTest,
        SendAndRecvPacketWithHeaderExtension_kSrtpAeadAes128Gcm) {
   TestSendRecvEncryptedHeaderExtension(
       rtc::kSrtpAeadAes128Gcm, kTestKeyGcm128_1, kTestKeyGcm128Len,
       kTestKeyGcm128_2, kTestKeyGcm128Len, rtc::kCsAeadAes128Gcm);
 }

 TEST_P(SrtpTransportTestWithExternalAuth,
        SendAndRecvPacket_kSrtpAeadAes256Gcm) {
   bool enable_external_auth = GetParam();
   TestSendRecvPacket(enable_external_auth, rtc::kSrtpAeadAes256Gcm,
                      kTestKeyGcm256_1, kTestKeyGcm256Len, kTestKeyGcm256_2,
                      kTestKeyGcm256Len, rtc::kCsAeadAes256Gcm);
 }

 TEST_F(SrtpTransportTest,
        SendAndRecvPacketWithHeaderExtension_kSrtpAeadAes256Gcm) {
   TestSendRecvEncryptedHeaderExtension(
       rtc::kSrtpAeadAes256Gcm, kTestKeyGcm256_1, kTestKeyGcm256Len,
       kTestKeyGcm256_2, kTestKeyGcm256Len, rtc::kCsAeadAes256Gcm);
 }

 // Run all tests both with and without external auth enabled.
 INSTANTIATE_TEST_SUITE_P(ExternalAuth,
                          SrtpTransportTestWithExternalAuth,
                          ::testing::Values(true, false));

 // Test directly setting the params with bogus keys.
 TEST_F(SrtpTransportTest, TestSetParamsKeyTooShort) {
   std::vector<int> extension_ids;
   EXPECT_FALSE(srtp_transport1_->SetRtpParams(
       rtc::kSrtpAes128CmSha1_80, kTestKey1, kTestKeyLen - 1, extension_ids,
       rtc::kSrtpAes128CmSha1_80, kTestKey1, kTestKeyLen - 1, extension_ids));
   EXPECT_FALSE(srtp_transport1_->SetRtcpParams(
       rtc::kSrtpAes128CmSha1_80, kTestKey1, kTestKeyLen - 1, extension_ids,
       rtc::kSrtpAes128CmSha1_80, kTestKey1, kTestKeyLen - 1, extension_ids));
 }

 TEST_F(SrtpTransportTest, RemoveSrtpReceiveStream) {
   test::ScopedKeyValueConfig field_trials(
       "WebRTC-SrtpRemoveReceiveStream/Enabled/");
   auto srtp_transport =
       std::make_unique<SrtpTransport>(/*rtcp_mux_enabled=*/true, field_trials);
   auto rtp_packet_transport = std::make_unique<rtc::FakePacketTransport>(
       "fake_packet_transport_loopback");

   bool asymmetric = false;
   rtp_packet_transport->SetDestination(rtp_packet_transport.get(), asymmetric);
   srtp_transport->SetRtpPacketTransport(rtp_packet_transport.get());

   TransportObserver rtp_sink;

   std::vector<int> extension_ids;
   EXPECT_TRUE(srtp_transport->SetRtpParams(
       rtc::kSrtpAeadAes128Gcm, kTestKeyGcm128_1, kTestKeyGcm128Len,
       extension_ids, rtc::kSrtpAeadAes128Gcm, kTestKeyGcm128_1,
       kTestKeyGcm128Len, extension_ids));

   RtpDemuxerCriteria demuxer_criteria;
   uint32_t ssrc = 0x1;  // SSRC of kPcmuFrame
   demuxer_criteria.ssrcs().insert(ssrc);
   EXPECT_TRUE(
       srtp_transport->RegisterRtpDemuxerSink(demuxer_criteria, &rtp_sink));

   // Create a packet and try to send it three times.
   size_t rtp_len = sizeof(kPcmuFrame);
   size_t packet_size = rtp_len + rtc::rtp_auth_tag_len(rtc::kCsAeadAes128Gcm);
   rtc::Buffer rtp_packet_buffer(packet_size);
   char* rtp_packet_data = rtp_packet_buffer.data<char>();
   memcpy(rtp_packet_data, kPcmuFrame, rtp_len);

   // First attempt will succeed.
   rtc::CopyOnWriteBuffer first_try(rtp_packet_data, rtp_len, packet_size);
   EXPECT_TRUE(srtp_transport->SendRtpPacket(&first_try, rtc::PacketOptions(),
                                             cricket::PF_SRTP_BYPASS));
   EXPECT_EQ(rtp_sink.rtp_count(), 1);

   // Second attempt will be rejected by libSRTP as a replay attack
   // (srtp_err_status_replay_fail) since the sequence number was already seen.
   // Hence the packet never reaches the sink.
   rtc::CopyOnWriteBuffer second_try(rtp_packet_data, rtp_len, packet_size);
   EXPECT_TRUE(srtp_transport->SendRtpPacket(&second_try, rtc::PacketOptions(),
                                             cricket::PF_SRTP_BYPASS));
   EXPECT_EQ(rtp_sink.rtp_count(), 1);

   // Reset the sink.
   EXPECT_TRUE(srtp_transport->UnregisterRtpDemuxerSink(&rtp_sink));
   EXPECT_TRUE(
       srtp_transport->RegisterRtpDemuxerSink(demuxer_criteria, &rtp_sink));

   // Third attempt will succeed again since libSRTP does not remember seeing
   // the sequence number after the reset.
   rtc::CopyOnWriteBuffer third_try(rtp_packet_data, rtp_len, packet_size);
   EXPECT_TRUE(srtp_transport->SendRtpPacket(&third_try, rtc::PacketOptions(),
                                             cricket::PF_SRTP_BYPASS));
   EXPECT_EQ(rtp_sink.rtp_count(), 2);
   // Clear the sink to clean up.
   srtp_transport->UnregisterRtpDemuxerSink(&rtp_sink);
 }

 }  // namespace webrtc
	/*
	* 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/srtp_transport.h"

	#include <string.h>

	#include <vector>

	#include "call/rtp_demuxer.h"
	#include "media/base/fake_rtp.h"
	#include "p2p/base/dtls_transport_internal.h"
	#include "p2p/base/fake_packet_transport.h"
	#include "pc/test/rtp_transport_test_util.h"
	#include "pc/test/srtp_test_util.h"
	#include "rtc_base/async_packet_socket.h"
	#include "rtc_base/byte_order.h"
	#include "rtc_base/checks.h"
	#include "rtc_base/containers/flat_set.h"
	#include "rtc_base/ssl_stream_adapter.h"
	#include "rtc_base/third_party/sigslot/sigslot.h"
	#include "test/gtest.h"
	#include "test/scoped_key_value_config.h"

	using rtc::kSrtpAeadAes128Gcm;
	using rtc::kTestKey1;
	using rtc::kTestKey2;
	using rtc::kTestKeyLen;

	namespace webrtc {
	static const uint8_t kTestKeyGcm128_1[] = "ABCDEFGHIJKLMNOPQRSTUVWXYZ12";
	static const uint8_t kTestKeyGcm128_2[] = "21ZYXWVUTSRQPONMLKJIHGFEDCBA";
	static const int kTestKeyGcm128Len = 28; // 128 bits key + 96 bits salt.
	static const uint8_t kTestKeyGcm256_1[] =
	"ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqr";
	static const uint8_t kTestKeyGcm256_2[] =
	"rqponmlkjihgfedcbaZYXWVUTSRQPONMLKJIHGFEDCBA";
	static const int kTestKeyGcm256Len = 44; // 256 bits key + 96 bits salt.

	class SrtpTransportTest : public ::testing::Test, public sigslot::has_slots<> {
	protected:
	SrtpTransportTest() {
	bool rtcp_mux_enabled = true;

	rtp_packet_transport1_ =
	std::make_unique<rtc::FakePacketTransport>("fake_packet_transport1");
	rtp_packet_transport2_ =
	std::make_unique<rtc::FakePacketTransport>("fake_packet_transport2");

	bool asymmetric = false;
	rtp_packet_transport1_->SetDestination(rtp_packet_transport2_.get(),
	asymmetric);

	srtp_transport1_ =
	std::make_unique<SrtpTransport>(rtcp_mux_enabled, field_trials_);
	srtp_transport2_ =
	std::make_unique<SrtpTransport>(rtcp_mux_enabled, field_trials_);

	srtp_transport1_->SetRtpPacketTransport(rtp_packet_transport1_.get());
	srtp_transport2_->SetRtpPacketTransport(rtp_packet_transport2_.get());

	srtp_transport1_->SubscribeRtcpPacketReceived(
	&rtp_sink1_,
	[this](rtc::CopyOnWriteBuffer* buffer, int64_t packet_time_ms) {
	rtp_sink1_.OnRtcpPacketReceived(buffer, packet_time_ms);
	});
	srtp_transport2_->SubscribeRtcpPacketReceived(
	&rtp_sink2_,
	[this](rtc::CopyOnWriteBuffer* buffer, int64_t packet_time_ms) {
	rtp_sink2_.OnRtcpPacketReceived(buffer, packet_time_ms);
	});

	RtpDemuxerCriteria demuxer_criteria;
	// 0x00 is the payload type used in kPcmuFrame.
	demuxer_criteria.payload_types().insert(0x00);

	srtp_transport1_->RegisterRtpDemuxerSink(demuxer_criteria, &rtp_sink1_);
	srtp_transport2_->RegisterRtpDemuxerSink(demuxer_criteria, &rtp_sink2_);
	}

	~SrtpTransportTest() {
	if (srtp_transport1_) {
	srtp_transport1_->UnregisterRtpDemuxerSink(&rtp_sink1_);
	}
	if (srtp_transport2_) {
	srtp_transport2_->UnregisterRtpDemuxerSink(&rtp_sink2_);
	}
	}

	// With external auth enabled, SRTP doesn't write the auth tag and
	// unprotect would fail. Check accessing the information about the
	// tag instead, similar to what the actual code would do that relies
	// on external auth.
	void TestRtpAuthParams(SrtpTransport* transport, const std::string& cs) {
	int overhead;
	EXPECT_TRUE(transport->GetSrtpOverhead(&overhead));
	switch (rtc::SrtpCryptoSuiteFromName(cs)) {
	case rtc::kSrtpAes128CmSha1_32:
	EXPECT_EQ(32 / 8, overhead); // 32-bit tag.
	break;
	case rtc::kSrtpAes128CmSha1_80:
	EXPECT_EQ(80 / 8, overhead); // 80-bit tag.
	break;
	default:
	RTC_DCHECK_NOTREACHED();
	break;
	}

	uint8_t* auth_key = nullptr;
	int key_len = 0;
	int tag_len = 0;
	EXPECT_TRUE(transport->GetRtpAuthParams(&auth_key, &key_len, &tag_len));
	EXPECT_NE(nullptr, auth_key);
	EXPECT_EQ(160 / 8, key_len); // Length of SHA-1 is 160 bits.
	EXPECT_EQ(overhead, tag_len);
	}

	void TestSendRecvRtpPacket(const std::string& cipher_suite_name) {
	size_t rtp_len = sizeof(kPcmuFrame);
	size_t packet_size = rtp_len + rtc::rtp_auth_tag_len(cipher_suite_name);
	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);

	char original_rtp_data[sizeof(kPcmuFrame)];
	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(srtp_transport1_->SendRtpPacket(&rtp_packet1to2, options,
	cricket::PF_SRTP_BYPASS));
	if (srtp_transport1_->IsExternalAuthActive()) {
	TestRtpAuthParams(srtp_transport1_.get(), cipher_suite_name);
	} else {
	ASSERT_TRUE(rtp_sink2_.last_recv_rtp_packet().data());
	EXPECT_EQ(0, memcmp(rtp_sink2_.last_recv_rtp_packet().data(),
	original_rtp_data, rtp_len));
	// Get the encrypted packet from underneath packet transport and verify
	// the data is actually encrypted.
	auto fake_rtp_packet_transport = static_cast<rtc::FakePacketTransport*>(
	srtp_transport1_->rtp_packet_transport());
	EXPECT_NE(0, memcmp(fake_rtp_packet_transport->last_sent_packet()->data(),
	original_rtp_data, rtp_len));
	}

	// Do the same thing in the opposite direction;
	ASSERT_TRUE(srtp_transport2_->SendRtpPacket(&rtp_packet2to1, options,
	cricket::PF_SRTP_BYPASS));
	if (srtp_transport2_->IsExternalAuthActive()) {
	TestRtpAuthParams(srtp_transport2_.get(), cipher_suite_name);
	} else {
	ASSERT_TRUE(rtp_sink1_.last_recv_rtp_packet().data());
	EXPECT_EQ(0, memcmp(rtp_sink1_.last_recv_rtp_packet().data(),
	original_rtp_data, rtp_len));
	auto fake_rtp_packet_transport = static_cast<rtc::FakePacketTransport*>(
	srtp_transport2_->rtp_packet_transport());
	EXPECT_NE(0, memcmp(fake_rtp_packet_transport->last_sent_packet()->data(),
	original_rtp_data, rtp_len));
	}
	}

	void TestSendRecvRtcpPacket(const std::string& cipher_suite_name) {
	size_t rtcp_len = sizeof(::kRtcpReport);
	size_t packet_size =
	rtcp_len + 4 + rtc::rtcp_auth_tag_len(cipher_suite_name);
	rtc::Buffer rtcp_packet_buffer(packet_size);
	char* rtcp_packet_data = rtcp_packet_buffer.data<char>();
	memcpy(rtcp_packet_data, ::kRtcpReport, rtcp_len);

	rtc::CopyOnWriteBuffer rtcp_packet1to2(rtcp_packet_data, rtcp_len,
	packet_size);
	rtc::CopyOnWriteBuffer rtcp_packet2to1(rtcp_packet_data, 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.
	ASSERT_TRUE(srtp_transport1_->SendRtcpPacket(&rtcp_packet1to2, options,
	cricket::PF_SRTP_BYPASS));
	ASSERT_TRUE(rtp_sink2_.last_recv_rtcp_packet().data());
	EXPECT_EQ(0, memcmp(rtp_sink2_.last_recv_rtcp_packet().data(),
	rtcp_packet_data, rtcp_len));
	// Get the encrypted packet from underneath packet transport and verify the
	// data is actually encrypted.
	auto fake_rtp_packet_transport = static_cast<rtc::FakePacketTransport*>(
	srtp_transport1_->rtp_packet_transport());
	EXPECT_NE(0, memcmp(fake_rtp_packet_transport->last_sent_packet()->data(),
	rtcp_packet_data, rtcp_len));

	// Do the same thing in the opposite direction;
	ASSERT_TRUE(srtp_transport2_->SendRtcpPacket(&rtcp_packet2to1, options,
	cricket::PF_SRTP_BYPASS));
	ASSERT_TRUE(rtp_sink1_.last_recv_rtcp_packet().data());
	EXPECT_EQ(0, memcmp(rtp_sink1_.last_recv_rtcp_packet().data(),
	rtcp_packet_data, rtcp_len));
	fake_rtp_packet_transport = static_cast<rtc::FakePacketTransport*>(
	srtp_transport2_->rtp_packet_transport());
	EXPECT_NE(0, memcmp(fake_rtp_packet_transport->last_sent_packet()->data(),
	rtcp_packet_data, rtcp_len));
	}

	void TestSendRecvPacket(bool enable_external_auth,
	int cs,
	const uint8_t* key1,
	int key1_len,
	const uint8_t* key2,
	int key2_len,
	const std::string& cipher_suite_name) {
	EXPECT_EQ(key1_len, key2_len);
	EXPECT_EQ(cipher_suite_name, rtc::SrtpCryptoSuiteToName(cs));
	if (enable_external_auth) {
	srtp_transport1_->EnableExternalAuth();
	srtp_transport2_->EnableExternalAuth();
	}
	std::vector<int> extension_ids;
	EXPECT_TRUE(srtp_transport1_->SetRtpParams(
	cs, key1, key1_len, extension_ids, cs, key2, key2_len, extension_ids));
	EXPECT_TRUE(srtp_transport2_->SetRtpParams(
	cs, key2, key2_len, extension_ids, cs, key1, key1_len, extension_ids));
	EXPECT_TRUE(srtp_transport1_->SetRtcpParams(
	cs, key1, key1_len, extension_ids, cs, key2, key2_len, extension_ids));
	EXPECT_TRUE(srtp_transport2_->SetRtcpParams(
	cs, key2, key2_len, extension_ids, cs, key1, key1_len, extension_ids));
	EXPECT_TRUE(srtp_transport1_->IsSrtpActive());
	EXPECT_TRUE(srtp_transport2_->IsSrtpActive());
	if (rtc::IsGcmCryptoSuite(cs)) {
	EXPECT_FALSE(srtp_transport1_->IsExternalAuthActive());
	EXPECT_FALSE(srtp_transport2_->IsExternalAuthActive());
	} else if (enable_external_auth) {
	EXPECT_TRUE(srtp_transport1_->IsExternalAuthActive());
	EXPECT_TRUE(srtp_transport2_->IsExternalAuthActive());
	}
	TestSendRecvRtpPacket(cipher_suite_name);
	TestSendRecvRtcpPacket(cipher_suite_name);
	}

	void TestSendRecvPacketWithEncryptedHeaderExtension(
	const std::string& cs,
	const std::vector<int>& encrypted_header_ids) {
	size_t rtp_len = sizeof(kPcmuFrameWithExtensions);
	size_t packet_size = rtp_len + rtc::rtp_auth_tag_len(cs);
	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(srtp_transport1_->SendRtpPacket(&rtp_packet1to2, options,
	cricket::PF_SRTP_BYPASS));
	ASSERT_TRUE(rtp_sink2_.last_recv_rtp_packet().data());
	EXPECT_EQ(0, memcmp(rtp_sink2_.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_rtp_packet_transport = static_cast<rtc::FakePacketTransport*>(
	srtp_transport1_->rtp_packet_transport());
	EXPECT_NE(0, memcmp(fake_rtp_packet_transport->last_sent_packet()->data(),
	original_rtp_data, rtp_len));
	CompareHeaderExtensions(
	reinterpret_cast<const char*>(
	fake_rtp_packet_transport->last_sent_packet()->data()),
	fake_rtp_packet_transport->last_sent_packet()->size(),
	original_rtp_data, rtp_len, encrypted_header_ids, false);

	// Do the same thing in the opposite direction;
	ASSERT_TRUE(srtp_transport2_->SendRtpPacket(&rtp_packet2to1, options,
	cricket::PF_SRTP_BYPASS));
	ASSERT_TRUE(rtp_sink1_.last_recv_rtp_packet().data());
	EXPECT_EQ(0, memcmp(rtp_sink1_.last_recv_rtp_packet().data(),
	original_rtp_data, rtp_len));
	fake_rtp_packet_transport = static_cast<rtc::FakePacketTransport*>(
	srtp_transport2_->rtp_packet_transport());
	EXPECT_NE(0, memcmp(fake_rtp_packet_transport->last_sent_packet()->data(),
	original_rtp_data, rtp_len));
	CompareHeaderExtensions(
	reinterpret_cast<const char*>(
	fake_rtp_packet_transport->last_sent_packet()->data()),
	fake_rtp_packet_transport->last_sent_packet()->size(),
	original_rtp_data, rtp_len, encrypted_header_ids, false);
	}

	void TestSendRecvEncryptedHeaderExtension(int cs,
	const uint8_t* key1,
	int key1_len,
	const uint8_t* key2,
	int key2_len,
	const std::string& cs_name) {
	std::vector<int> encrypted_headers;
	encrypted_headers.push_back(kHeaderExtensionIDs[0]);
	// Don't encrypt header ids 2 and 3.
	encrypted_headers.push_back(kHeaderExtensionIDs[1]);
	EXPECT_EQ(key1_len, key2_len);
	EXPECT_EQ(cs_name, rtc::SrtpCryptoSuiteToName(cs));
	EXPECT_TRUE(srtp_transport1_->SetRtpParams(cs, key1, key1_len,
	encrypted_headers, cs, key2,
	key2_len, encrypted_headers));
	EXPECT_TRUE(srtp_transport2_->SetRtpParams(cs, key2, key2_len,
	encrypted_headers, cs, key1,
	key1_len, encrypted_headers));
	EXPECT_TRUE(srtp_transport1_->IsSrtpActive());
	EXPECT_TRUE(srtp_transport2_->IsSrtpActive());
	EXPECT_FALSE(srtp_transport1_->IsExternalAuthActive());
	EXPECT_FALSE(srtp_transport2_->IsExternalAuthActive());
	TestSendRecvPacketWithEncryptedHeaderExtension(cs_name, encrypted_headers);
	}

	std::unique_ptr<SrtpTransport> srtp_transport1_;
	std::unique_ptr<SrtpTransport> srtp_transport2_;

	std::unique_ptr<rtc::FakePacketTransport> rtp_packet_transport1_;
	std::unique_ptr<rtc::FakePacketTransport> rtp_packet_transport2_;

	TransportObserver rtp_sink1_;
	TransportObserver rtp_sink2_;

	int sequence_number_ = 0;
	test::ScopedKeyValueConfig field_trials_;
	};

	class SrtpTransportTestWithExternalAuth
	: public SrtpTransportTest,
	public ::testing::WithParamInterface<bool> {};

	TEST_P(SrtpTransportTestWithExternalAuth,
	SendAndRecvPacket_AES_CM_128_HMAC_SHA1_80) {
	bool enable_external_auth = GetParam();
	TestSendRecvPacket(enable_external_auth, rtc::kSrtpAes128CmSha1_80, kTestKey1,
	kTestKeyLen, kTestKey2, kTestKeyLen,
	rtc::kCsAesCm128HmacSha1_80);
	}

	TEST_F(SrtpTransportTest,
	SendAndRecvPacketWithHeaderExtension_AES_CM_128_HMAC_SHA1_80) {
	TestSendRecvEncryptedHeaderExtension(rtc::kSrtpAes128CmSha1_80, kTestKey1,
	kTestKeyLen, kTestKey2, kTestKeyLen,
	rtc::kCsAesCm128HmacSha1_80);
	}

	TEST_P(SrtpTransportTestWithExternalAuth,
	SendAndRecvPacket_AES_CM_128_HMAC_SHA1_32) {
	bool enable_external_auth = GetParam();
	TestSendRecvPacket(enable_external_auth, rtc::kSrtpAes128CmSha1_32, kTestKey1,
	kTestKeyLen, kTestKey2, kTestKeyLen,
	rtc::kCsAesCm128HmacSha1_32);
	}

	TEST_F(SrtpTransportTest,
	SendAndRecvPacketWithHeaderExtension_AES_CM_128_HMAC_SHA1_32) {
	TestSendRecvEncryptedHeaderExtension(rtc::kSrtpAes128CmSha1_32, kTestKey1,
	kTestKeyLen, kTestKey2, kTestKeyLen,
	rtc::kCsAesCm128HmacSha1_32);
	}

	TEST_P(SrtpTransportTestWithExternalAuth,
	SendAndRecvPacket_kSrtpAeadAes128Gcm) {
	bool enable_external_auth = GetParam();
	TestSendRecvPacket(enable_external_auth, rtc::kSrtpAeadAes128Gcm,
	kTestKeyGcm128_1, kTestKeyGcm128Len, kTestKeyGcm128_2,
	kTestKeyGcm128Len, rtc::kCsAeadAes128Gcm);
	}

	TEST_F(SrtpTransportTest,
	SendAndRecvPacketWithHeaderExtension_kSrtpAeadAes128Gcm) {
	TestSendRecvEncryptedHeaderExtension(
	rtc::kSrtpAeadAes128Gcm, kTestKeyGcm128_1, kTestKeyGcm128Len,
	kTestKeyGcm128_2, kTestKeyGcm128Len, rtc::kCsAeadAes128Gcm);
	}

	TEST_P(SrtpTransportTestWithExternalAuth,
	SendAndRecvPacket_kSrtpAeadAes256Gcm) {
	bool enable_external_auth = GetParam();
	TestSendRecvPacket(enable_external_auth, rtc::kSrtpAeadAes256Gcm,
	kTestKeyGcm256_1, kTestKeyGcm256Len, kTestKeyGcm256_2,
	kTestKeyGcm256Len, rtc::kCsAeadAes256Gcm);
	}

	TEST_F(SrtpTransportTest,
	SendAndRecvPacketWithHeaderExtension_kSrtpAeadAes256Gcm) {
	TestSendRecvEncryptedHeaderExtension(
	rtc::kSrtpAeadAes256Gcm, kTestKeyGcm256_1, kTestKeyGcm256Len,
	kTestKeyGcm256_2, kTestKeyGcm256Len, rtc::kCsAeadAes256Gcm);
	}

	// Run all tests both with and without external auth enabled.
	INSTANTIATE_TEST_SUITE_P(ExternalAuth,
	SrtpTransportTestWithExternalAuth,
	::testing::Values(true, false));

	// Test directly setting the params with bogus keys.
	TEST_F(SrtpTransportTest, TestSetParamsKeyTooShort) {
	std::vector<int> extension_ids;
	EXPECT_FALSE(srtp_transport1_->SetRtpParams(
	rtc::kSrtpAes128CmSha1_80, kTestKey1, kTestKeyLen - 1, extension_ids,
	rtc::kSrtpAes128CmSha1_80, kTestKey1, kTestKeyLen - 1, extension_ids));
	EXPECT_FALSE(srtp_transport1_->SetRtcpParams(
	rtc::kSrtpAes128CmSha1_80, kTestKey1, kTestKeyLen - 1, extension_ids,
	rtc::kSrtpAes128CmSha1_80, kTestKey1, kTestKeyLen - 1, extension_ids));
	}

	TEST_F(SrtpTransportTest, RemoveSrtpReceiveStream) {
	test::ScopedKeyValueConfig field_trials(
	"WebRTC-SrtpRemoveReceiveStream/Enabled/");
	auto srtp_transport =
	std::make_unique<SrtpTransport>(/rtcp_mux_enabled=/true, field_trials);
	auto rtp_packet_transport = std::make_unique<rtc::FakePacketTransport>(
	"fake_packet_transport_loopback");

	bool asymmetric = false;
	rtp_packet_transport->SetDestination(rtp_packet_transport.get(), asymmetric);
	srtp_transport->SetRtpPacketTransport(rtp_packet_transport.get());

	TransportObserver rtp_sink;

	std::vector<int> extension_ids;
	EXPECT_TRUE(srtp_transport->SetRtpParams(
	rtc::kSrtpAeadAes128Gcm, kTestKeyGcm128_1, kTestKeyGcm128Len,
	extension_ids, rtc::kSrtpAeadAes128Gcm, kTestKeyGcm128_1,
	kTestKeyGcm128Len, extension_ids));

	RtpDemuxerCriteria demuxer_criteria;
	uint32_t ssrc = 0x1; // SSRC of kPcmuFrame
	demuxer_criteria.ssrcs().insert(ssrc);
	EXPECT_TRUE(
	srtp_transport->RegisterRtpDemuxerSink(demuxer_criteria, &rtp_sink));

	// Create a packet and try to send it three times.
	size_t rtp_len = sizeof(kPcmuFrame);
	size_t packet_size = rtp_len + rtc::rtp_auth_tag_len(rtc::kCsAeadAes128Gcm);
	rtc::Buffer rtp_packet_buffer(packet_size);
	char* rtp_packet_data = rtp_packet_buffer.data<char>();
	memcpy(rtp_packet_data, kPcmuFrame, rtp_len);

	// First attempt will succeed.
	rtc::CopyOnWriteBuffer first_try(rtp_packet_data, rtp_len, packet_size);
	EXPECT_TRUE(srtp_transport->SendRtpPacket(&first_try, rtc::PacketOptions(),
	cricket::PF_SRTP_BYPASS));
	EXPECT_EQ(rtp_sink.rtp_count(), 1);

	// Second attempt will be rejected by libSRTP as a replay attack
	// (srtp_err_status_replay_fail) since the sequence number was already seen.
	// Hence the packet never reaches the sink.
	rtc::CopyOnWriteBuffer second_try(rtp_packet_data, rtp_len, packet_size);
	EXPECT_TRUE(srtp_transport->SendRtpPacket(&second_try, rtc::PacketOptions(),
	cricket::PF_SRTP_BYPASS));
	EXPECT_EQ(rtp_sink.rtp_count(), 1);

	// Reset the sink.
	EXPECT_TRUE(srtp_transport->UnregisterRtpDemuxerSink(&rtp_sink));
	EXPECT_TRUE(
	srtp_transport->RegisterRtpDemuxerSink(demuxer_criteria, &rtp_sink));

	// Third attempt will succeed again since libSRTP does not remember seeing
	// the sequence number after the reset.
	rtc::CopyOnWriteBuffer third_try(rtp_packet_data, rtp_len, packet_size);
	EXPECT_TRUE(srtp_transport->SendRtpPacket(&third_try, rtc::PacketOptions(),
	cricket::PF_SRTP_BYPASS));
	EXPECT_EQ(rtp_sink.rtp_count(), 2);
	// Clear the sink to clean up.
	srtp_transport->UnregisterRtpDemuxerSink(&rtp_sink);
	}

	} // namespace webrtc