blob: aff3a5f01499a9314e52199d19a051a7466f806b [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/srtpsession.h"
#include <string>
#include "absl/memory/memory.h"
#include "media/base/fakertp.h"
#include "pc/srtptestutil.h"
#include "rtc_base/gunit.h"
#include "rtc_base/sslstreamadapter.h" // For rtc::SRTP_*
#include "system_wrappers/include/metrics.h"
#include "third_party/libsrtp/include/srtp.h"
namespace rtc {
std::vector<int> kEncryptedHeaderExtensionIds;
class SrtpSessionTest : public testing::Test {
public:
SrtpSessionTest() { webrtc::metrics::Reset(); }
protected:
virtual void SetUp() {
rtp_len_ = sizeof(kPcmuFrame);
rtcp_len_ = sizeof(kRtcpReport);
memcpy(rtp_packet_, kPcmuFrame, rtp_len_);
memcpy(rtcp_packet_, kRtcpReport, rtcp_len_);
}
void TestProtectRtp(const std::string& cs) {
int out_len = 0;
EXPECT_TRUE(
s1_.ProtectRtp(rtp_packet_, rtp_len_, sizeof(rtp_packet_), &out_len));
EXPECT_EQ(out_len, rtp_len_ + rtp_auth_tag_len(cs));
EXPECT_NE(0, memcmp(rtp_packet_, kPcmuFrame, rtp_len_));
rtp_len_ = out_len;
}
void TestProtectRtcp(const std::string& cs) {
int out_len = 0;
EXPECT_TRUE(s1_.ProtectRtcp(rtcp_packet_, rtcp_len_, sizeof(rtcp_packet_),
&out_len));
EXPECT_EQ(out_len, rtcp_len_ + 4 + rtcp_auth_tag_len(cs)); // NOLINT
EXPECT_NE(0, memcmp(rtcp_packet_, kRtcpReport, rtcp_len_));
rtcp_len_ = out_len;
}
void TestUnprotectRtp(const std::string& cs) {
int out_len = 0, expected_len = sizeof(kPcmuFrame);
EXPECT_TRUE(s2_.UnprotectRtp(rtp_packet_, rtp_len_, &out_len));
EXPECT_EQ(expected_len, out_len);
EXPECT_EQ(0, memcmp(rtp_packet_, kPcmuFrame, out_len));
}
void TestUnprotectRtcp(const std::string& cs) {
int out_len = 0, expected_len = sizeof(kRtcpReport);
EXPECT_TRUE(s2_.UnprotectRtcp(rtcp_packet_, rtcp_len_, &out_len));
EXPECT_EQ(expected_len, out_len);
EXPECT_EQ(0, memcmp(rtcp_packet_, kRtcpReport, out_len));
}
cricket::SrtpSession s1_;
cricket::SrtpSession s2_;
char rtp_packet_[sizeof(kPcmuFrame) + 10];
char rtcp_packet_[sizeof(kRtcpReport) + 4 + 10];
int rtp_len_;
int rtcp_len_;
};
// Test that we can set up the session and keys properly.
TEST_F(SrtpSessionTest, TestGoodSetup) {
EXPECT_TRUE(s1_.SetSend(SRTP_AES128_CM_SHA1_80, kTestKey1, kTestKeyLen,
kEncryptedHeaderExtensionIds));
EXPECT_TRUE(s2_.SetRecv(SRTP_AES128_CM_SHA1_80, kTestKey1, kTestKeyLen,
kEncryptedHeaderExtensionIds));
}
// Test that we can't change the keys once set.
TEST_F(SrtpSessionTest, TestBadSetup) {
EXPECT_TRUE(s1_.SetSend(SRTP_AES128_CM_SHA1_80, kTestKey1, kTestKeyLen,
kEncryptedHeaderExtensionIds));
EXPECT_TRUE(s2_.SetRecv(SRTP_AES128_CM_SHA1_80, kTestKey1, kTestKeyLen,
kEncryptedHeaderExtensionIds));
EXPECT_FALSE(s1_.SetSend(SRTP_AES128_CM_SHA1_80, kTestKey2, kTestKeyLen,
kEncryptedHeaderExtensionIds));
EXPECT_FALSE(s2_.SetRecv(SRTP_AES128_CM_SHA1_80, kTestKey2, kTestKeyLen,
kEncryptedHeaderExtensionIds));
}
// Test that we fail keys of the wrong length.
TEST_F(SrtpSessionTest, TestKeysTooShort) {
EXPECT_FALSE(s1_.SetSend(SRTP_AES128_CM_SHA1_80, kTestKey1, 1,
kEncryptedHeaderExtensionIds));
EXPECT_FALSE(s2_.SetRecv(SRTP_AES128_CM_SHA1_80, kTestKey1, 1,
kEncryptedHeaderExtensionIds));
}
// Test that we can encrypt and decrypt RTP/RTCP using AES_CM_128_HMAC_SHA1_80.
TEST_F(SrtpSessionTest, TestProtect_AES_CM_128_HMAC_SHA1_80) {
EXPECT_TRUE(s1_.SetSend(SRTP_AES128_CM_SHA1_80, kTestKey1, kTestKeyLen,
kEncryptedHeaderExtensionIds));
EXPECT_TRUE(s2_.SetRecv(SRTP_AES128_CM_SHA1_80, kTestKey1, kTestKeyLen,
kEncryptedHeaderExtensionIds));
TestProtectRtp(CS_AES_CM_128_HMAC_SHA1_80);
TestProtectRtcp(CS_AES_CM_128_HMAC_SHA1_80);
TestUnprotectRtp(CS_AES_CM_128_HMAC_SHA1_80);
TestUnprotectRtcp(CS_AES_CM_128_HMAC_SHA1_80);
}
// Test that we can encrypt and decrypt RTP/RTCP using AES_CM_128_HMAC_SHA1_32.
TEST_F(SrtpSessionTest, TestProtect_AES_CM_128_HMAC_SHA1_32) {
EXPECT_TRUE(s1_.SetSend(SRTP_AES128_CM_SHA1_32, kTestKey1, kTestKeyLen,
kEncryptedHeaderExtensionIds));
EXPECT_TRUE(s2_.SetRecv(SRTP_AES128_CM_SHA1_32, kTestKey1, kTestKeyLen,
kEncryptedHeaderExtensionIds));
TestProtectRtp(CS_AES_CM_128_HMAC_SHA1_32);
TestProtectRtcp(CS_AES_CM_128_HMAC_SHA1_32);
TestUnprotectRtp(CS_AES_CM_128_HMAC_SHA1_32);
TestUnprotectRtcp(CS_AES_CM_128_HMAC_SHA1_32);
}
TEST_F(SrtpSessionTest, TestGetSendStreamPacketIndex) {
EXPECT_TRUE(s1_.SetSend(SRTP_AES128_CM_SHA1_32, kTestKey1, kTestKeyLen,
kEncryptedHeaderExtensionIds));
int64_t index;
int out_len = 0;
EXPECT_TRUE(s1_.ProtectRtp(rtp_packet_, rtp_len_, sizeof(rtp_packet_),
&out_len, &index));
// |index| will be shifted by 16.
int64_t be64_index = static_cast<int64_t>(NetworkToHost64(1 << 16));
EXPECT_EQ(be64_index, index);
}
// Test that we fail to unprotect if someone tampers with the RTP/RTCP paylaods.
TEST_F(SrtpSessionTest, TestTamperReject) {
int out_len;
EXPECT_TRUE(s1_.SetSend(SRTP_AES128_CM_SHA1_80, kTestKey1, kTestKeyLen,
kEncryptedHeaderExtensionIds));
EXPECT_TRUE(s2_.SetRecv(SRTP_AES128_CM_SHA1_80, kTestKey1, kTestKeyLen,
kEncryptedHeaderExtensionIds));
TestProtectRtp(CS_AES_CM_128_HMAC_SHA1_80);
TestProtectRtcp(CS_AES_CM_128_HMAC_SHA1_80);
rtp_packet_[0] = 0x12;
rtcp_packet_[1] = 0x34;
EXPECT_FALSE(s2_.UnprotectRtp(rtp_packet_, rtp_len_, &out_len));
EXPECT_EQ(1, webrtc::metrics::NumSamples(
"WebRTC.PeerConnection.SrtpUnprotectError"));
EXPECT_EQ(
1, webrtc::metrics::NumEvents("WebRTC.PeerConnection.SrtpUnprotectError",
srtp_err_status_bad_param));
EXPECT_FALSE(s2_.UnprotectRtcp(rtcp_packet_, rtcp_len_, &out_len));
EXPECT_EQ(1, webrtc::metrics::NumSamples(
"WebRTC.PeerConnection.SrtcpUnprotectError"));
EXPECT_EQ(
1, webrtc::metrics::NumEvents("WebRTC.PeerConnection.SrtcpUnprotectError",
srtp_err_status_auth_fail));
}
// Test that we fail to unprotect if the payloads are not authenticated.
TEST_F(SrtpSessionTest, TestUnencryptReject) {
int out_len;
EXPECT_TRUE(s1_.SetSend(SRTP_AES128_CM_SHA1_80, kTestKey1, kTestKeyLen,
kEncryptedHeaderExtensionIds));
EXPECT_TRUE(s2_.SetRecv(SRTP_AES128_CM_SHA1_80, kTestKey1, kTestKeyLen,
kEncryptedHeaderExtensionIds));
EXPECT_FALSE(s2_.UnprotectRtp(rtp_packet_, rtp_len_, &out_len));
EXPECT_EQ(1, webrtc::metrics::NumSamples(
"WebRTC.PeerConnection.SrtpUnprotectError"));
EXPECT_EQ(
1, webrtc::metrics::NumEvents("WebRTC.PeerConnection.SrtpUnprotectError",
srtp_err_status_auth_fail));
EXPECT_FALSE(s2_.UnprotectRtcp(rtcp_packet_, rtcp_len_, &out_len));
EXPECT_EQ(1, webrtc::metrics::NumSamples(
"WebRTC.PeerConnection.SrtcpUnprotectError"));
EXPECT_EQ(
1, webrtc::metrics::NumEvents("WebRTC.PeerConnection.SrtcpUnprotectError",
srtp_err_status_cant_check));
}
// Test that we fail when using buffers that are too small.
TEST_F(SrtpSessionTest, TestBuffersTooSmall) {
int out_len;
EXPECT_TRUE(s1_.SetSend(SRTP_AES128_CM_SHA1_80, kTestKey1, kTestKeyLen,
kEncryptedHeaderExtensionIds));
EXPECT_FALSE(s1_.ProtectRtp(rtp_packet_, rtp_len_, sizeof(rtp_packet_) - 10,
&out_len));
EXPECT_FALSE(s1_.ProtectRtcp(rtcp_packet_, rtcp_len_,
sizeof(rtcp_packet_) - 14, &out_len));
}
TEST_F(SrtpSessionTest, TestReplay) {
static const uint16_t kMaxSeqnum = static_cast<uint16_t>(-1);
static const uint16_t seqnum_big = 62275;
static const uint16_t seqnum_small = 10;
static const uint16_t replay_window = 1024;
int out_len;
EXPECT_TRUE(s1_.SetSend(SRTP_AES128_CM_SHA1_80, kTestKey1, kTestKeyLen,
kEncryptedHeaderExtensionIds));
EXPECT_TRUE(s2_.SetRecv(SRTP_AES128_CM_SHA1_80, kTestKey1, kTestKeyLen,
kEncryptedHeaderExtensionIds));
// Initial sequence number.
SetBE16(reinterpret_cast<uint8_t*>(rtp_packet_) + 2, seqnum_big);
EXPECT_TRUE(
s1_.ProtectRtp(rtp_packet_, rtp_len_, sizeof(rtp_packet_), &out_len));
// Replay within the 1024 window should succeed.
SetBE16(reinterpret_cast<uint8_t*>(rtp_packet_) + 2,
seqnum_big - replay_window + 1);
EXPECT_TRUE(
s1_.ProtectRtp(rtp_packet_, rtp_len_, sizeof(rtp_packet_), &out_len));
// Replay out side of the 1024 window should fail.
SetBE16(reinterpret_cast<uint8_t*>(rtp_packet_) + 2,
seqnum_big - replay_window - 1);
EXPECT_FALSE(
s1_.ProtectRtp(rtp_packet_, rtp_len_, sizeof(rtp_packet_), &out_len));
// Increment sequence number to a small number.
SetBE16(reinterpret_cast<uint8_t*>(rtp_packet_) + 2, seqnum_small);
EXPECT_TRUE(
s1_.ProtectRtp(rtp_packet_, rtp_len_, sizeof(rtp_packet_), &out_len));
// Replay around 0 but out side of the 1024 window should fail.
SetBE16(reinterpret_cast<uint8_t*>(rtp_packet_) + 2,
kMaxSeqnum + seqnum_small - replay_window - 1);
EXPECT_FALSE(
s1_.ProtectRtp(rtp_packet_, rtp_len_, sizeof(rtp_packet_), &out_len));
// Replay around 0 but within the 1024 window should succeed.
for (uint16_t seqnum = 65000; seqnum < 65003; ++seqnum) {
SetBE16(reinterpret_cast<uint8_t*>(rtp_packet_) + 2, seqnum);
EXPECT_TRUE(
s1_.ProtectRtp(rtp_packet_, rtp_len_, sizeof(rtp_packet_), &out_len));
}
// Go back to normal sequence nubmer.
// NOTE: without the fix in libsrtp, this would fail. This is because
// without the fix, the loop above would keep incrementing local sequence
// number in libsrtp, eventually the new sequence number would go out side
// of the window.
SetBE16(reinterpret_cast<uint8_t*>(rtp_packet_) + 2, seqnum_small + 1);
EXPECT_TRUE(
s1_.ProtectRtp(rtp_packet_, rtp_len_, sizeof(rtp_packet_), &out_len));
}
} // namespace rtc