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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set ts=2 et sw=2 tw=80: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this file,
* You can obtain one at http://mozilla.org/MPL/2.0/. */
#include <functional>
#include <memory>
#include <vector>
#include "secerr.h"
#include "ssl.h"
#include "sslerr.h"
#include "sslproto.h"
extern "C" {
// This is not something that should make you happy.
#include "libssl_internals.h"
}
#include "gtest_utils.h"
#include "nss_scoped_ptrs.h"
#include "tls_connect.h"
#include "tls_filter.h"
#include "tls_parser.h"
namespace nss_test {
TEST_P(TlsConnectGeneric, SetupOnly) {}
TEST_P(TlsConnectGeneric, Connect) {
SetExpectedVersion(std::get<1>(GetParam()));
Connect();
CheckKeys();
}
TEST_P(TlsConnectGeneric, ConnectEcdsa) {
SetExpectedVersion(std::get<1>(GetParam()));
Reset(TlsAgent::kServerEcdsa256);
Connect();
CheckKeys(ssl_kea_ecdh, ssl_auth_ecdsa);
}
TEST_P(TlsConnectGeneric, CipherSuiteMismatch) {
EnsureTlsSetup();
if (version_ >= SSL_LIBRARY_VERSION_TLS_1_3) {
client_->EnableSingleCipher(TLS_AES_128_GCM_SHA256);
server_->EnableSingleCipher(TLS_AES_256_GCM_SHA384);
} else {
client_->EnableSingleCipher(TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA);
server_->EnableSingleCipher(TLS_ECDHE_RSA_WITH_AES_256_CBC_SHA);
}
ConnectExpectAlert(server_, kTlsAlertHandshakeFailure);
client_->CheckErrorCode(SSL_ERROR_NO_CYPHER_OVERLAP);
server_->CheckErrorCode(SSL_ERROR_NO_CYPHER_OVERLAP);
}
class TlsAlertRecorder : public TlsRecordFilter {
public:
TlsAlertRecorder(const std::shared_ptr<TlsAgent>& a)
: TlsRecordFilter(a), level_(255), description_(255) {}
PacketFilter::Action FilterRecord(const TlsRecordHeader& header,
const DataBuffer& input,
DataBuffer* output) override {
if (level_ != 255) { // Already captured.
return KEEP;
}
if (header.content_type() != ssl_ct_alert) {
return KEEP;
}
std::cerr << "Alert: " << input << std::endl;
TlsParser parser(input);
EXPECT_TRUE(parser.Read(&level_));
EXPECT_TRUE(parser.Read(&description_));
return KEEP;
}
uint8_t level() const { return level_; }
uint8_t description() const { return description_; }
private:
uint8_t level_;
uint8_t description_;
};
class HelloTruncator : public TlsHandshakeFilter {
public:
HelloTruncator(const std::shared_ptr<TlsAgent>& a)
: TlsHandshakeFilter(
a, {kTlsHandshakeClientHello, kTlsHandshakeServerHello}) {}
PacketFilter::Action FilterHandshake(const HandshakeHeader& header,
const DataBuffer& input,
DataBuffer* output) override {
output->Assign(input.data(), input.len() - 1);
return CHANGE;
}
};
// Verify that when NSS reports that an alert is sent, it is actually sent.
TEST_P(TlsConnectGeneric, CaptureAlertServer) {
MakeTlsFilter<HelloTruncator>(client_);
auto alert_recorder = MakeTlsFilter<TlsAlertRecorder>(server_);
ConnectExpectAlert(server_, kTlsAlertDecodeError);
EXPECT_EQ(kTlsAlertFatal, alert_recorder->level());
EXPECT_EQ(kTlsAlertDecodeError, alert_recorder->description());
}
TEST_P(TlsConnectGenericPre13, CaptureAlertClient) {
MakeTlsFilter<HelloTruncator>(server_);
auto alert_recorder = MakeTlsFilter<TlsAlertRecorder>(client_);
ConnectExpectAlert(client_, kTlsAlertDecodeError);
EXPECT_EQ(kTlsAlertFatal, alert_recorder->level());
EXPECT_EQ(kTlsAlertDecodeError, alert_recorder->description());
}
// In TLS 1.3, the server can't read the client alert.
TEST_P(TlsConnectTls13, CaptureAlertClient) {
MakeTlsFilter<HelloTruncator>(server_);
auto alert_recorder = MakeTlsFilter<TlsAlertRecorder>(client_);
StartConnect();
client_->Handshake();
client_->ExpectSendAlert(kTlsAlertDecodeError);
server_->Handshake();
client_->Handshake();
if (variant_ == ssl_variant_stream) {
// DTLS just drops the alert it can't decrypt.
server_->ExpectSendAlert(kTlsAlertUnexpectedMessage);
}
server_->Handshake();
EXPECT_EQ(kTlsAlertFatal, alert_recorder->level());
EXPECT_EQ(kTlsAlertDecodeError, alert_recorder->description());
}
TEST_P(TlsConnectGenericPre13, ConnectFalseStart) {
client_->EnableFalseStart();
Connect();
SendReceive();
}
TEST_P(TlsConnectGeneric, ConnectAlpn) {
EnableAlpn();
Connect();
CheckAlpn("a");
}
TEST_P(TlsConnectGeneric, ConnectAlpnPriorityA) {
// "alpn" "npn"
// alpn is the fallback here. npn has the highest priority and should be
// picked.
const std::vector<uint8_t> alpn = {0x04, 0x61, 0x6c, 0x70, 0x6e,
0x03, 0x6e, 0x70, 0x6e};
EnableAlpn(alpn);
Connect();
CheckAlpn("npn");
}
TEST_P(TlsConnectGeneric, ConnectAlpnPriorityB) {
// "alpn" "npn" "http"
// npn has the highest priority and should be picked.
const std::vector<uint8_t> alpn = {0x04, 0x61, 0x6c, 0x70, 0x6e, 0x03, 0x6e,
0x70, 0x6e, 0x04, 0x68, 0x74, 0x74, 0x70};
EnableAlpn(alpn);
Connect();
CheckAlpn("npn");
}
TEST_P(TlsConnectGeneric, ConnectAlpnClone) {
EnsureModelSockets();
client_model_->EnableAlpn(alpn_dummy_val_, sizeof(alpn_dummy_val_));
server_model_->EnableAlpn(alpn_dummy_val_, sizeof(alpn_dummy_val_));
Connect();
CheckAlpn("a");
}
TEST_P(TlsConnectGeneric, ConnectAlpnWithCustomCallbackA) {
// "ab" "alpn"
const std::vector<uint8_t> client_alpn = {0x02, 0x61, 0x62, 0x04,
0x61, 0x6c, 0x70, 0x6e};
EnableAlpnWithCallback(client_alpn, "alpn");
Connect();
CheckAlpn("alpn");
}
TEST_P(TlsConnectGeneric, ConnectAlpnWithCustomCallbackB) {
// "ab" "alpn"
const std::vector<uint8_t> client_alpn = {0x02, 0x61, 0x62, 0x04,
0x61, 0x6c, 0x70, 0x6e};
EnableAlpnWithCallback(client_alpn, "ab");
Connect();
CheckAlpn("ab");
}
TEST_P(TlsConnectGeneric, ConnectAlpnWithCustomCallbackC) {
// "cd" "npn" "alpn"
const std::vector<uint8_t> client_alpn = {0x02, 0x63, 0x64, 0x03, 0x6e, 0x70,
0x6e, 0x04, 0x61, 0x6c, 0x70, 0x6e};
EnableAlpnWithCallback(client_alpn, "npn");
Connect();
CheckAlpn("npn");
}
TEST_P(TlsConnectDatagram, ConnectSrtp) {
EnableSrtp();
Connect();
CheckSrtp();
SendReceive();
}
TEST_P(TlsConnectGeneric, ConnectSendReceive) {
Connect();
SendReceive();
}
class SaveTlsRecord : public TlsRecordFilter {
public:
SaveTlsRecord(const std::shared_ptr<TlsAgent>& a, size_t index)
: TlsRecordFilter(a), index_(index), count_(0), contents_() {}
const DataBuffer& contents() const { return contents_; }
protected:
PacketFilter::Action FilterRecord(const TlsRecordHeader& header,
const DataBuffer& data,
DataBuffer* changed) override {
if (count_++ == index_) {
contents_ = data;
}
return KEEP;
}
private:
const size_t index_;
size_t count_;
DataBuffer contents_;
};
// Check that decrypting filters work and can read any record.
// This test (currently) only works in TLS 1.3 where we can decrypt.
TEST_F(TlsConnectStreamTls13, DecryptRecordClient) {
EnsureTlsSetup();
// 0 = ClientHello, 1 = Finished, 2 = SendReceive, 3 = SendBuffer
auto saved = MakeTlsFilter<SaveTlsRecord>(client_, 3);
saved->EnableDecryption();
Connect();
SendReceive();
static const uint8_t data[] = {0xde, 0xad, 0xdc};
DataBuffer buf(data, sizeof(data));
client_->SendBuffer(buf);
EXPECT_EQ(buf, saved->contents());
}
TEST_F(TlsConnectStreamTls13, DecryptRecordServer) {
EnsureTlsSetup();
// Disable tickets so that we are sure to not get NewSessionTicket.
EXPECT_EQ(SECSuccess, SSL_OptionSet(server_->ssl_fd(),
SSL_ENABLE_SESSION_TICKETS, PR_FALSE));
// 0 = ServerHello, 1 = other handshake, 2 = SendReceive, 3 = SendBuffer
auto saved = MakeTlsFilter<SaveTlsRecord>(server_, 3);
saved->EnableDecryption();
Connect();
SendReceive();
static const uint8_t data[] = {0xde, 0xad, 0xd5};
DataBuffer buf(data, sizeof(data));
server_->SendBuffer(buf);
EXPECT_EQ(buf, saved->contents());
}
class DropTlsRecord : public TlsRecordFilter {
public:
DropTlsRecord(const std::shared_ptr<TlsAgent>& a, size_t index)
: TlsRecordFilter(a), index_(index), count_(0) {}
protected:
PacketFilter::Action FilterRecord(const TlsRecordHeader& header,
const DataBuffer& data,
DataBuffer* changed) override {
if (count_++ == index_) {
return DROP;
}
return KEEP;
}
private:
const size_t index_;
size_t count_;
};
// Test that decrypting filters work correctly and are able to drop records.
TEST_F(TlsConnectStreamTls13, DropRecordServer) {
EnsureTlsSetup();
// Disable session tickets so that the server doesn't send an extra record.
EXPECT_EQ(SECSuccess, SSL_OptionSet(server_->ssl_fd(),
SSL_ENABLE_SESSION_TICKETS, PR_FALSE));
// 0 = ServerHello, 1 = other handshake, 2 = first write
auto filter = MakeTlsFilter<DropTlsRecord>(server_, 2);
filter->EnableDecryption();
Connect();
server_->SendData(23, 23); // This should be dropped, so it won't be counted.
server_->ResetSentBytes();
SendReceive();
}
TEST_F(TlsConnectStreamTls13, DropRecordClient) {
EnsureTlsSetup();
// 0 = ClientHello, 1 = Finished, 2 = first write
auto filter = MakeTlsFilter<DropTlsRecord>(client_, 2);
filter->EnableDecryption();
Connect();
client_->SendData(26, 26); // This should be dropped, so it won't be counted.
client_->ResetSentBytes();
SendReceive();
}
// Check that a server can use 0.5 RTT if client authentication isn't enabled.
TEST_P(TlsConnectTls13, WriteBeforeClientFinished) {
EnsureTlsSetup();
StartConnect();
client_->Handshake(); // ClientHello
server_->Handshake(); // ServerHello
server_->SendData(10);
client_->ReadBytes(10); // Client should emit the Finished as a side-effect.
server_->Handshake(); // Server consumes the Finished.
CheckConnected();
}
// We don't allow 0.5 RTT if client authentication is requested.
TEST_P(TlsConnectTls13, WriteBeforeClientFinishedClientAuth) {
client_->SetupClientAuth();
server_->RequestClientAuth(false);
StartConnect();
client_->Handshake(); // ClientHello
server_->Handshake(); // ServerHello
static const uint8_t data[] = {1, 2, 3};
EXPECT_GT(0, PR_Write(server_->ssl_fd(), data, sizeof(data)));
EXPECT_EQ(PR_WOULD_BLOCK_ERROR, PORT_GetError());
Handshake();
CheckConnected();
SendReceive();
}
// 0.5 RTT should fail with client authentication required.
TEST_P(TlsConnectTls13, WriteBeforeClientFinishedClientAuthRequired) {
client_->SetupClientAuth();
server_->RequestClientAuth(true);
StartConnect();
client_->Handshake(); // ClientHello
server_->Handshake(); // ServerHello
static const uint8_t data[] = {1, 2, 3};
EXPECT_GT(0, PR_Write(server_->ssl_fd(), data, sizeof(data)));
EXPECT_EQ(PR_WOULD_BLOCK_ERROR, PORT_GetError());
Handshake();
CheckConnected();
SendReceive();
}
// The next two tests takes advantage of the fact that we
// automatically read the first 1024 bytes, so if
// we provide 1200 bytes, they overrun the read buffer
// provided by the calling test.
// DTLS should return an error.
TEST_P(TlsConnectDatagram, ShortRead) {
Connect();
client_->ExpectReadWriteError();
server_->SendData(50, 50);
client_->ReadBytes(20);
EXPECT_EQ(0U, client_->received_bytes());
EXPECT_EQ(SSL_ERROR_RX_SHORT_DTLS_READ, PORT_GetError());
// Now send and receive another packet.
server_->ResetSentBytes(); // Reset the counter.
SendReceive();
}
// TLS should get the write in two chunks.
TEST_P(TlsConnectStream, ShortRead) {
// This test behaves oddly with TLS 1.0 because of 1/n+1 splitting,
// so skip in that case.
if (version_ < SSL_LIBRARY_VERSION_TLS_1_1) return;
Connect();
server_->SendData(50, 50);
// Read the first tranche.
client_->ReadBytes(20);
ASSERT_EQ(20U, client_->received_bytes());
// The second tranche should now immediately be available.
client_->ReadBytes();
ASSERT_EQ(50U, client_->received_bytes());
}
// We enable compression via the API but it's disabled internally,
// so we should never get it.
TEST_P(TlsConnectGeneric, ConnectWithCompressionEnabled) {
EnsureTlsSetup();
client_->SetOption(SSL_ENABLE_DEFLATE, PR_TRUE);
server_->SetOption(SSL_ENABLE_DEFLATE, PR_TRUE);
Connect();
EXPECT_FALSE(client_->is_compressed());
SendReceive();
}
class TlsHolddownTest : public TlsConnectDatagram {
protected:
// This causes all timers to run to completion. It advances the clock and
// handshakes on both peers until both peers have no more timers pending,
// which should happen at the end of a handshake. This is necessary to ensure
// that the relatively long holddown timer expires, but that any other timers
// also expire and run correctly.
void RunAllTimersDown() {
while (true) {
PRIntervalTime time;
SECStatus rv = DTLS_GetHandshakeTimeout(client_->ssl_fd(), &time);
if (rv != SECSuccess) {
rv = DTLS_GetHandshakeTimeout(server_->ssl_fd(), &time);
if (rv != SECSuccess) {
break; // Neither peer has an outstanding timer.
}
}
if (g_ssl_gtest_verbose) {
std::cerr << "Shifting timers" << std::endl;
}
ShiftDtlsTimers();
Handshake();
}
}
};
TEST_P(TlsHolddownTest, TestDtlsHolddownExpiry) {
Connect();
std::cerr << "Expiring holddown timer" << std::endl;
RunAllTimersDown();
SendReceive();
if (version_ >= SSL_LIBRARY_VERSION_TLS_1_3) {
// One for send, one for receive.
EXPECT_EQ(2, SSLInt_CountCipherSpecs(client_->ssl_fd()));
}
}
TEST_P(TlsHolddownTest, TestDtlsHolddownExpiryResumption) {
ConfigureSessionCache(RESUME_BOTH, RESUME_TICKET);
Connect();
SendReceive();
Reset();
ConfigureSessionCache(RESUME_BOTH, RESUME_TICKET);
ExpectResumption(RESUME_TICKET);
Connect();
RunAllTimersDown();
SendReceive();
// One for send, one for receive.
EXPECT_EQ(2, SSLInt_CountCipherSpecs(client_->ssl_fd()));
}
class TlsPreCCSHeaderInjector : public TlsRecordFilter {
public:
TlsPreCCSHeaderInjector(const std::shared_ptr<TlsAgent>& a)
: TlsRecordFilter(a) {}
virtual PacketFilter::Action FilterRecord(
const TlsRecordHeader& record_header, const DataBuffer& input,
size_t* offset, DataBuffer* output) override {
if (record_header.content_type() != ssl_ct_change_cipher_spec) {
return KEEP;
}
std::cerr << "Injecting Finished header before CCS\n";
const uint8_t hhdr[] = {kTlsHandshakeFinished, 0x00, 0x00, 0x0c};
DataBuffer hhdr_buf(hhdr, sizeof(hhdr));
TlsRecordHeader nhdr(record_header.variant(), record_header.version(),
ssl_ct_handshake, 0);
*offset = nhdr.Write(output, *offset, hhdr_buf);
*offset = record_header.Write(output, *offset, input);
return CHANGE;
}
};
TEST_P(TlsConnectStreamPre13, ClientFinishedHeaderBeforeCCS) {
MakeTlsFilter<TlsPreCCSHeaderInjector>(client_);
ConnectExpectAlert(server_, kTlsAlertUnexpectedMessage);
client_->CheckErrorCode(SSL_ERROR_HANDSHAKE_UNEXPECTED_ALERT);
server_->CheckErrorCode(SSL_ERROR_RX_UNEXPECTED_CHANGE_CIPHER);
}
TEST_P(TlsConnectStreamPre13, ServerFinishedHeaderBeforeCCS) {
MakeTlsFilter<TlsPreCCSHeaderInjector>(server_);
StartConnect();
ExpectAlert(client_, kTlsAlertUnexpectedMessage);
Handshake();
EXPECT_EQ(TlsAgent::STATE_ERROR, client_->state());
client_->CheckErrorCode(SSL_ERROR_RX_UNEXPECTED_CHANGE_CIPHER);
EXPECT_EQ(TlsAgent::STATE_CONNECTED, server_->state());
server_->Handshake(); // Make sure alert is consumed.
}
TEST_P(TlsConnectTls13, UnknownAlert) {
Connect();
server_->ExpectSendAlert(0xff, kTlsAlertWarning);
client_->ExpectReceiveAlert(0xff, kTlsAlertWarning);
SSLInt_SendAlert(server_->ssl_fd(), kTlsAlertWarning,
0xff); // Unknown value.
client_->ExpectReadWriteError();
client_->WaitForErrorCode(SSL_ERROR_RX_UNKNOWN_ALERT, 2000);
}
TEST_P(TlsConnectTls13, AlertWrongLevel) {
Connect();
server_->ExpectSendAlert(kTlsAlertUnexpectedMessage, kTlsAlertWarning);
client_->ExpectReceiveAlert(kTlsAlertUnexpectedMessage, kTlsAlertWarning);
SSLInt_SendAlert(server_->ssl_fd(), kTlsAlertWarning,
kTlsAlertUnexpectedMessage);
client_->ExpectReadWriteError();
client_->WaitForErrorCode(SSL_ERROR_HANDSHAKE_UNEXPECTED_ALERT, 2000);
}
TEST_P(TlsConnectTls13, UnknownRecord) {
static const uint8_t kUknownRecord[] = {
0xff, SSL_LIBRARY_VERSION_TLS_1_2 >> 8,
SSL_LIBRARY_VERSION_TLS_1_2 & 0xff, 0, 0};
Connect();
if (variant_ == ssl_variant_stream) {
// DTLS just drops the record with an invalid type.
server_->ExpectSendAlert(kTlsAlertUnexpectedMessage);
}
client_->SendDirect(DataBuffer(kUknownRecord, sizeof(kUknownRecord)));
server_->ExpectReadWriteError();
server_->ReadBytes();
if (variant_ == ssl_variant_stream) {
EXPECT_EQ(SSL_ERROR_RX_UNEXPECTED_RECORD_TYPE, server_->error_code());
} else {
EXPECT_EQ(SSL_ERROR_RX_UNKNOWN_RECORD_TYPE, server_->error_code());
}
}
TEST_F(TlsConnectStreamTls13, Tls13FailedWriteSecondFlight) {
EnsureTlsSetup();
StartConnect();
client_->Handshake();
server_->Handshake(); // Send first flight.
client_->adapter()->SetWriteError(PR_IO_ERROR);
client_->Handshake(); // This will get an error, but shouldn't crash.
client_->CheckErrorCode(SSL_ERROR_SOCKET_WRITE_FAILURE);
}
TEST_P(TlsConnectDatagram, BlockedWrite) {
Connect();
// Mark the socket as blocked.
client_->adapter()->SetWriteError(PR_WOULD_BLOCK_ERROR);
static const uint8_t data[] = {1, 2, 3};
int32_t rv = PR_Write(client_->ssl_fd(), data, sizeof(data));
EXPECT_GT(0, rv);
EXPECT_EQ(PR_WOULD_BLOCK_ERROR, PORT_GetError());
// Remove the write error and though the previous write failed, future reads
// and writes should just work as if it never happened.
client_->adapter()->SetWriteError(0);
SendReceive();
}
TEST_F(TlsConnectTest, ConnectSSLv3) {
ConfigureVersion(SSL_LIBRARY_VERSION_3_0);
EnableOnlyStaticRsaCiphers();
Connect();
CheckKeys(ssl_kea_rsa, ssl_grp_none, ssl_auth_rsa_decrypt, ssl_sig_none);
}
TEST_F(TlsConnectTest, ConnectSSLv3ClientAuth) {
ConfigureVersion(SSL_LIBRARY_VERSION_3_0);
EnableOnlyStaticRsaCiphers();
client_->SetupClientAuth();
server_->RequestClientAuth(true);
Connect();
CheckKeys(ssl_kea_rsa, ssl_grp_none, ssl_auth_rsa_decrypt, ssl_sig_none);
}
static size_t ExpectedCbcLen(size_t in, size_t hmac = 20, size_t block = 16) {
// MAC-then-Encrypt expansion formula:
return ((in + hmac + (block - 1)) / block) * block;
}
TEST_F(TlsConnectTest, OneNRecordSplitting) {
ConfigureVersion(SSL_LIBRARY_VERSION_TLS_1_0);
EnsureTlsSetup();
ConnectWithCipherSuite(TLS_RSA_WITH_AES_128_CBC_SHA);
auto records = MakeTlsFilter<TlsRecordRecorder>(server_);
// This should be split into 1, 16384 and 20.
DataBuffer big_buffer;
big_buffer.Allocate(1 + 16384 + 20);
server_->SendBuffer(big_buffer);
ASSERT_EQ(3U, records->count());
EXPECT_EQ(ExpectedCbcLen(1), records->record(0).buffer.len());
EXPECT_EQ(ExpectedCbcLen(16384), records->record(1).buffer.len());
EXPECT_EQ(ExpectedCbcLen(20), records->record(2).buffer.len());
}
// We can't test for randomness easily here, but we can test that we don't
// produce a zero value, or produce the same value twice. There are 5 values
// here: two ClientHello.random, two ServerHello.random, and one zero value.
// Matrix them and fail if any are the same.
TEST_P(TlsConnectGeneric, CheckRandoms) {
ConfigureSessionCache(RESUME_NONE, RESUME_NONE);
static const size_t random_len = 32;
uint8_t crandom1[random_len], srandom1[random_len];
uint8_t z[random_len] = {0};
auto ch = MakeTlsFilter<TlsHandshakeRecorder>(client_, ssl_hs_client_hello);
auto sh = MakeTlsFilter<TlsHandshakeRecorder>(server_, ssl_hs_server_hello);
Connect();
ASSERT_TRUE(ch->buffer().len() > (random_len + 2));
ASSERT_TRUE(sh->buffer().len() > (random_len + 2));
memcpy(crandom1, ch->buffer().data() + 2, random_len);
memcpy(srandom1, sh->buffer().data() + 2, random_len);
EXPECT_NE(0, memcmp(crandom1, srandom1, random_len));
EXPECT_NE(0, memcmp(crandom1, z, random_len));
EXPECT_NE(0, memcmp(srandom1, z, random_len));
Reset();
ch = MakeTlsFilter<TlsHandshakeRecorder>(client_, ssl_hs_client_hello);
sh = MakeTlsFilter<TlsHandshakeRecorder>(server_, ssl_hs_server_hello);
Connect();
ASSERT_TRUE(ch->buffer().len() > (random_len + 2));
ASSERT_TRUE(sh->buffer().len() > (random_len + 2));
const uint8_t* crandom2 = ch->buffer().data() + 2;
const uint8_t* srandom2 = sh->buffer().data() + 2;
EXPECT_NE(0, memcmp(crandom2, srandom2, random_len));
EXPECT_NE(0, memcmp(crandom2, z, random_len));
EXPECT_NE(0, memcmp(srandom2, z, random_len));
EXPECT_NE(0, memcmp(crandom1, crandom2, random_len));
EXPECT_NE(0, memcmp(crandom1, srandom2, random_len));
EXPECT_NE(0, memcmp(srandom1, crandom2, random_len));
EXPECT_NE(0, memcmp(srandom1, srandom2, random_len));
}
void FailOnCloseNotify(const PRFileDesc* fd, void* arg, const SSLAlert* alert) {
ADD_FAILURE() << "received alert " << alert->description;
}
void CheckCloseNotify(const PRFileDesc* fd, void* arg, const SSLAlert* alert) {
*reinterpret_cast<bool*>(arg) = true;
EXPECT_EQ(close_notify, alert->description);
EXPECT_EQ(alert_warning, alert->level);
}
TEST_P(TlsConnectGeneric, ShutdownOneSide) {
Connect();
// Setup to check alerts.
EXPECT_EQ(SECSuccess, SSL_AlertSentCallback(server_->ssl_fd(),
FailOnCloseNotify, nullptr));
EXPECT_EQ(SECSuccess, SSL_AlertReceivedCallback(client_->ssl_fd(),
FailOnCloseNotify, nullptr));
bool client_sent = false;
EXPECT_EQ(SECSuccess, SSL_AlertSentCallback(client_->ssl_fd(),
CheckCloseNotify, &client_sent));
bool server_received = false;
EXPECT_EQ(SECSuccess,
SSL_AlertReceivedCallback(server_->ssl_fd(), CheckCloseNotify,
&server_received));
EXPECT_EQ(PR_SUCCESS, PR_Shutdown(client_->ssl_fd(), PR_SHUTDOWN_SEND));
// Make sure that the server reads out the close_notify.
uint8_t buf[10];
EXPECT_EQ(0, PR_Read(server_->ssl_fd(), buf, sizeof(buf)));
// Reading and writing should still work in the one open direction.
EXPECT_TRUE(client_sent);
EXPECT_TRUE(server_received);
server_->SendData(10, 10);
client_->ReadBytes(10);
// Now close the other side and do the same checks.
bool server_sent = false;
EXPECT_EQ(SECSuccess, SSL_AlertSentCallback(server_->ssl_fd(),
CheckCloseNotify, &server_sent));
bool client_received = false;
EXPECT_EQ(SECSuccess,
SSL_AlertReceivedCallback(client_->ssl_fd(), CheckCloseNotify,
&client_received));
EXPECT_EQ(PR_SUCCESS, PR_Shutdown(server_->ssl_fd(), PR_SHUTDOWN_SEND));
EXPECT_EQ(0, PR_Read(client_->ssl_fd(), buf, sizeof(buf)));
EXPECT_TRUE(server_sent);
EXPECT_TRUE(client_received);
}
TEST_P(TlsConnectGeneric, ShutdownOneSideThenCloseTcp) {
Connect();
bool client_sent = false;
EXPECT_EQ(SECSuccess, SSL_AlertSentCallback(client_->ssl_fd(),
CheckCloseNotify, &client_sent));
bool server_received = false;
EXPECT_EQ(SECSuccess,
SSL_AlertReceivedCallback(server_->ssl_fd(), CheckCloseNotify,
&server_received));
EXPECT_EQ(PR_SUCCESS, PR_Shutdown(client_->ssl_fd(), PR_SHUTDOWN_SEND));
// Make sure that the server reads out the close_notify.
uint8_t buf[10];
EXPECT_EQ(0, PR_Read(server_->ssl_fd(), buf, sizeof(buf)));
// Now simulate the underlying connection closing.
client_->adapter()->Reset();
// Now close the other side and see that things don't explode.
EXPECT_EQ(PR_SUCCESS, PR_Shutdown(server_->ssl_fd(), PR_SHUTDOWN_SEND));
EXPECT_GT(0, PR_Read(client_->ssl_fd(), buf, sizeof(buf)));
EXPECT_EQ(PR_NOT_CONNECTED_ERROR, PR_GetError());
}
INSTANTIATE_TEST_CASE_P(
GenericStream, TlsConnectGeneric,
::testing::Combine(TlsConnectTestBase::kTlsVariantsStream,
TlsConnectTestBase::kTlsVAll));
INSTANTIATE_TEST_CASE_P(
GenericDatagram, TlsConnectGeneric,
::testing::Combine(TlsConnectTestBase::kTlsVariantsDatagram,
TlsConnectTestBase::kTlsV11Plus));
INSTANTIATE_TEST_CASE_P(StreamOnly, TlsConnectStream,
TlsConnectTestBase::kTlsVAll);
INSTANTIATE_TEST_CASE_P(DatagramOnly, TlsConnectDatagram,
TlsConnectTestBase::kTlsV11Plus);
INSTANTIATE_TEST_CASE_P(DatagramHolddown, TlsHolddownTest,
TlsConnectTestBase::kTlsV11Plus);
INSTANTIATE_TEST_CASE_P(
Pre12Stream, TlsConnectPre12,
::testing::Combine(TlsConnectTestBase::kTlsVariantsStream,
TlsConnectTestBase::kTlsV10V11));
INSTANTIATE_TEST_CASE_P(
Pre12Datagram, TlsConnectPre12,
::testing::Combine(TlsConnectTestBase::kTlsVariantsDatagram,
TlsConnectTestBase::kTlsV11));
INSTANTIATE_TEST_CASE_P(Version12Only, TlsConnectTls12,
TlsConnectTestBase::kTlsVariantsAll);
#ifndef NSS_DISABLE_TLS_1_3
INSTANTIATE_TEST_CASE_P(Version13Only, TlsConnectTls13,
TlsConnectTestBase::kTlsVariantsAll);
#endif
INSTANTIATE_TEST_CASE_P(
Pre13Stream, TlsConnectGenericPre13,
::testing::Combine(TlsConnectTestBase::kTlsVariantsStream,
TlsConnectTestBase::kTlsV10ToV12));
INSTANTIATE_TEST_CASE_P(
Pre13Datagram, TlsConnectGenericPre13,
::testing::Combine(TlsConnectTestBase::kTlsVariantsDatagram,
TlsConnectTestBase::kTlsV11V12));
INSTANTIATE_TEST_CASE_P(Pre13StreamOnly, TlsConnectStreamPre13,
TlsConnectTestBase::kTlsV10ToV12);
INSTANTIATE_TEST_CASE_P(Version12Plus, TlsConnectTls12Plus,
::testing::Combine(TlsConnectTestBase::kTlsVariantsAll,
TlsConnectTestBase::kTlsV12Plus));
INSTANTIATE_TEST_CASE_P(
GenericStream, TlsConnectGenericResumption,
::testing::Combine(TlsConnectTestBase::kTlsVariantsStream,
TlsConnectTestBase::kTlsVAll,
::testing::Values(true, false)));
INSTANTIATE_TEST_CASE_P(
GenericDatagram, TlsConnectGenericResumption,
::testing::Combine(TlsConnectTestBase::kTlsVariantsDatagram,
TlsConnectTestBase::kTlsV11Plus,
::testing::Values(true, false)));
INSTANTIATE_TEST_CASE_P(
GenericStream, TlsConnectGenericResumptionToken,
::testing::Combine(TlsConnectTestBase::kTlsVariantsStream,
TlsConnectTestBase::kTlsVAll));
INSTANTIATE_TEST_CASE_P(
GenericDatagram, TlsConnectGenericResumptionToken,
::testing::Combine(TlsConnectTestBase::kTlsVariantsDatagram,
TlsConnectTestBase::kTlsV11Plus));
INSTANTIATE_TEST_CASE_P(GenericDatagram, TlsConnectTls13ResumptionToken,
TlsConnectTestBase::kTlsVariantsAll);
} // namespace nss_test
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