/* -*- 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 <set>
#include "secerr.h"
#include "ssl.h"
#include "sslerr.h"
#include "sslproto.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, ConnectDhe) {
EnableOnlyDheCiphers();
Connect();
CheckKeys(ssl_kea_dh, ssl_grp_ffdhe_2048, ssl_auth_rsa_sign,
ssl_sig_rsa_pss_rsae_sha256);
}
TEST_P(TlsConnectTls13, SharesForBothEcdheAndDhe) {
EnsureTlsSetup();
client_->ConfigNamedGroups(kAllDHEGroups);
auto groups_capture =
std::make_shared<TlsExtensionCapture>(client_, ssl_supported_groups_xtn);
auto shares_capture =
std::make_shared<TlsExtensionCapture>(client_, ssl_tls13_key_share_xtn);
std::vector<std::shared_ptr<PacketFilter>> captures = {groups_capture,
shares_capture};
client_->SetFilter(std::make_shared<ChainedPacketFilter>(captures));
Connect();
CheckKeys();
bool ec, dh;
auto track_group_type = [&ec, &dh](SSLNamedGroup group) {
if ((group & 0xff00U) == 0x100U) {
dh =
true;
}
else {
ec =
true;
}
};
CheckGroups(groups_capture->extension(), track_group_type);
CheckShares(shares_capture->extension(), track_group_type);
EXPECT_TRUE(ec) <<
"Should include an EC group and share";
EXPECT_TRUE(dh) <<
"Should include an FFDHE group and share";
}
TEST_P(TlsConnectGeneric, ConnectFfdheClient) {
EnableOnlyDheCiphers();
client_->SetOption(SSL_REQUIRE_DH_NAMED_GROUPS, PR_TRUE);
auto groups_capture =
std::make_shared<TlsExtensionCapture>(client_, ssl_supported_groups_xtn);
auto shares_capture =
std::make_shared<TlsExtensionCapture>(client_, ssl_tls13_key_share_xtn);
std::vector<std::shared_ptr<PacketFilter>> captures = {groups_capture,
shares_capture};
client_->SetFilter(std::make_shared<ChainedPacketFilter>(captures));
Connect();
CheckKeys(ssl_kea_dh, ssl_auth_rsa_sign);
auto is_ffdhe = [](SSLNamedGroup group) {
// The group has to be in this range.
EXPECT_LE(ssl_grp_ffdhe_2048, group);
EXPECT_GE(ssl_grp_ffdhe_8192, group);
};
CheckGroups(groups_capture->extension(), is_ffdhe);
if (version_ == SSL_LIBRARY_VERSION_TLS_1_3) {
CheckShares(shares_capture->extension(), is_ffdhe);
}
else {
EXPECT_EQ(0U, shares_capture->extension().len());
}
}
// Requiring the FFDHE extension on the server alone means that clients won't be
// able to connect using a DHE suite. They should still connect in TLS 1.3,
// because the client automatically sends the supported groups extension.
TEST_P(TlsConnectGenericPre13, ConnectFfdheServer) {
EnableOnlyDheCiphers();
server_->SetOption(SSL_REQUIRE_DH_NAMED_GROUPS, PR_TRUE);
if (version_ >= SSL_LIBRARY_VERSION_TLS_1_3) {
Connect();
CheckKeys(ssl_kea_dh, ssl_auth_rsa_sign);
}
else {
ConnectExpectAlert(server_, kTlsAlertHandshakeFailure);
client_->CheckErrorCode(SSL_ERROR_NO_CYPHER_OVERLAP);
server_->CheckErrorCode(SSL_ERROR_NO_CYPHER_OVERLAP);
}
}
class TlsDheServerKeyExchangeDamager :
public TlsHandshakeFilter {
public:
TlsDheServerKeyExchangeDamager(
const std::shared_ptr<TlsAgent>& a)
: TlsHandshakeFilter(a, {kTlsHandshakeServerKeyExchange}) {}
virtual PacketFilter::Action FilterHandshake(
const TlsHandshakeFilter::HandshakeHeader& header,
const DataBuffer& input, DataBuffer* output) {
// Damage the first octet of dh_p. Anything other than the known prime will
// be rejected as "weak" when we have SSL_REQUIRE_DH_NAMED_GROUPS enabled.
*output = input;
output->data()[3] ^= 73;
return CHANGE;
}
};
// Changing the prime in the server's key share results in an error. This will
// invalidate the signature over the ServerKeyShare. That's ok, NSS won't check
// the signature until everything else has been checked.
TEST_P(TlsConnectGenericPre13, DamageServerKeyShare) {
EnableOnlyDheCiphers();
client_->SetOption(SSL_REQUIRE_DH_NAMED_GROUPS, PR_TRUE);
MakeTlsFilter<TlsDheServerKeyExchangeDamager>(server_);
ConnectExpectAlert(client_, kTlsAlertIllegalParameter);
client_->CheckErrorCode(SSL_ERROR_WEAK_SERVER_EPHEMERAL_DH_KEY);
server_->CheckErrorCode(SSL_ERROR_ILLEGAL_PARAMETER_ALERT);
}
class TlsDheSkeChangeY :
public TlsHandshakeFilter {
public:
enum ChangeYTo {
kYZero,
kYOne,
kYPMinusOne,
kYGreaterThanP,
kYTooLarge,
kYZeroPad
};
TlsDheSkeChangeY(
const std::shared_ptr<TlsAgent>& a, uint8_t handshake_type,
ChangeYTo change)
: TlsHandshakeFilter(a, {handshake_type}), change_Y_(change) {}
protected:
void ChangeY(
const DataBuffer& input, DataBuffer* output, size_t offset,
const DataBuffer& prime) {
static const uint8_t kExtraZero = 0;
static const uint8_t kTooLargeExtra = 1;
uint32_t dh_Ys_len;
EXPECT_TRUE(input.Read(offset, 2, &dh_Ys_len));
EXPECT_LT(offset + dh_Ys_len, input.len());
offset += 2;
// This isn't generally true, but our code pads.
EXPECT_EQ(prime.len(), dh_Ys_len)
<<
"Length of dh_Ys must equal length of dh_p";
*output = input;
switch (change_Y_) {
case kYZero:
memset(output->data() + offset, 0, prime.len());
break;
case kYOne:
memset(output->data() + offset, 0, prime.len() - 1);
output->Write(offset + prime.len() - 1, 1U, 1);
break;
case kYPMinusOne:
output->Write(offset, prime);
EXPECT_TRUE(output->data()[offset + prime.len() - 1] & 0x01)
<<
"P must at least be odd";
--output->data()[offset + prime.len() - 1];
break;
case kYGreaterThanP:
// Set the first 32 octets of Y to 0xff, except the first which we set
// to p[0]. This will make Y > p. That is, unless p is Mersenne, or
// improbably large (but still the same bit length). We currently only
// use a fixed prime that isn't a problem for this code.
EXPECT_LT(0, prime.data()[0]) <<
"dh_p should not be zero-padded";
offset = output->Write(offset, prime.data()[0], 1);
memset(output->data() + offset, 0xff, 31);
break;
case kYTooLarge:
// Increase the dh_Ys length.
output->Write(offset - 2, prime.len() +
sizeof(kTooLargeExtra), 2);
// Then insert the octet.
output->Splice(&kTooLargeExtra,
sizeof(kTooLargeExtra), offset);
break;
case kYZeroPad:
output->Write(offset - 2, prime.len() +
sizeof(kExtraZero), 2);
output->Splice(&kExtraZero,
sizeof(kExtraZero), offset);
break;
}
}
private:
ChangeYTo change_Y_;
};
class TlsDheSkeChangeYServer :
public TlsDheSkeChangeY {
public:
TlsDheSkeChangeYServer(
const std::shared_ptr<TlsAgent>& a, ChangeYTo change,
bool modify)
: TlsDheSkeChangeY(a, kTlsHandshakeServerKeyExchange, change),
modify_(modify),
p_() {}
const DataBuffer& prime()
const {
return p_; }
protected:
virtual PacketFilter::Action FilterHandshake(
const TlsHandshakeFilter::HandshakeHeader& header,
const DataBuffer& input, DataBuffer* output) override {
size_t offset = 2;
// Read dh_p
uint32_t dh_len = 0;
EXPECT_TRUE(input.Read(0, 2, &dh_len));
EXPECT_GT(input.len(), offset + dh_len);
p_.Assign(input.data() + offset, dh_len);
offset += dh_len;
// Skip dh_g to find dh_Ys
EXPECT_TRUE(input.Read(offset, 2, &dh_len));
offset += 2 + dh_len;
if (modify_) {
ChangeY(input, output, offset, p_);
return CHANGE;
}
return KEEP;
}
private:
bool modify_;
DataBuffer p_;
};
class TlsDheSkeChangeYClient :
public TlsDheSkeChangeY {
public:
TlsDheSkeChangeYClient(
const std::shared_ptr<TlsAgent>& a, ChangeYTo change,
std::shared_ptr<
const TlsDheSkeChangeYServer> server_filter)
: TlsDheSkeChangeY(a, kTlsHandshakeClientKeyExchange, change),
server_filter_(server_filter) {}
protected:
virtual PacketFilter::Action FilterHandshake(
const TlsHandshakeFilter::HandshakeHeader& header,
const DataBuffer& input, DataBuffer* output) override {
ChangeY(input, output, 0, server_filter_->prime());
return CHANGE;
}
private:
std::shared_ptr<
const TlsDheSkeChangeYServer> server_filter_;
};
/* This matrix includes: variant (stream/datagram), TLS version, what change to
* make to dh_Ys, whether the client will be configured to require DH named
* groups. Test all combinations. */
typedef std::tuple<SSLProtocolVariant, uint16_t, TlsDheSkeChangeY::ChangeYTo,
bool>
DamageDHYProfile;
class TlsDamageDHYTest
:
public TlsConnectTestBase,
public ::testing::WithParamInterface<DamageDHYProfile> {
public:
TlsDamageDHYTest()
: TlsConnectTestBase(std::get<0>(GetParam()), std::get<1>(GetParam())) {}
};
TEST_P(TlsDamageDHYTest, DamageServerY) {
EnableOnlyDheCiphers();
if (std::get<3>(GetParam())) {
client_->SetOption(SSL_REQUIRE_DH_NAMED_GROUPS, PR_TRUE);
}
TlsDheSkeChangeY::ChangeYTo change = std::get<2>(GetParam());
MakeTlsFilter<TlsDheSkeChangeYServer>(server_, change,
true);
if (change == TlsDheSkeChangeY::kYZeroPad) {
ExpectAlert(client_, kTlsAlertDecryptError);
}
else {
ExpectAlert(client_, kTlsAlertIllegalParameter);
}
ConnectExpectFail();
if (change == TlsDheSkeChangeY::kYZeroPad) {
// Zero padding Y only manifests in a signature failure.
// In TLS 1.0 and 1.1, the client reports a device error.
if (version_ < SSL_LIBRARY_VERSION_TLS_1_2) {
client_->CheckErrorCode(SEC_ERROR_PKCS11_DEVICE_ERROR);
}
else {
client_->CheckErrorCode(SEC_ERROR_BAD_SIGNATURE);
}
server_->CheckErrorCode(SSL_ERROR_DECRYPT_ERROR_ALERT);
}
else {
client_->CheckErrorCode(SSL_ERROR_RX_MALFORMED_DHE_KEY_SHARE);
server_->CheckErrorCode(SSL_ERROR_ILLEGAL_PARAMETER_ALERT);
}
}
TEST_P(TlsDamageDHYTest, DamageClientY) {
EnableOnlyDheCiphers();
if (std::get<3>(GetParam())) {
client_->SetOption(SSL_REQUIRE_DH_NAMED_GROUPS, PR_TRUE);
}
// The filter on the server is required to capture the prime.
auto server_filter = MakeTlsFilter<TlsDheSkeChangeYServer>(
server_, TlsDheSkeChangeY::kYZero,
false);
// The client filter does the damage.
TlsDheSkeChangeY::ChangeYTo change = std::get<2>(GetParam());
MakeTlsFilter<TlsDheSkeChangeYClient>(client_, change, server_filter);
if (change == TlsDheSkeChangeY::kYZeroPad) {
ExpectAlert(server_, kTlsAlertDecryptError);
}
else {
ExpectAlert(server_, kTlsAlertHandshakeFailure);
}
ConnectExpectFail();
if (change == TlsDheSkeChangeY::kYZeroPad) {
// Zero padding Y only manifests in a finished error.
client_->CheckErrorCode(SSL_ERROR_DECRYPT_ERROR_ALERT);
server_->CheckErrorCode(SSL_ERROR_BAD_HANDSHAKE_HASH_VALUE);
}
else {
client_->CheckErrorCode(SSL_ERROR_HANDSHAKE_FAILURE_ALERT);
server_->CheckErrorCode(SSL_ERROR_RX_MALFORMED_DHE_KEY_SHARE);
}
}
static const TlsDheSkeChangeY::ChangeYTo kAllYArr[] = {
TlsDheSkeChangeY::kYZero, TlsDheSkeChangeY::kYOne,
TlsDheSkeChangeY::kYPMinusOne, TlsDheSkeChangeY::kYGreaterThanP,
TlsDheSkeChangeY::kYTooLarge, TlsDheSkeChangeY::kYZeroPad};
static ::testing::internal::ParamGenerator<TlsDheSkeChangeY::ChangeYTo> kAllY =
::testing::ValuesIn(kAllYArr);
static const bool kTrueFalseArr[] = {
true,
false};
static ::testing::internal::ParamGenerator<
bool> kTrueFalse =
::testing::ValuesIn(kTrueFalseArr);
INSTANTIATE_TEST_SUITE_P(
DamageYStream, TlsDamageDHYTest,
::testing::Combine(TlsConnectTestBase::kTlsVariantsStream,
TlsConnectTestBase::kTlsV10ToV12, kAllY, kTrueFalse));
INSTANTIATE_TEST_SUITE_P(
DamageYDatagram, TlsDamageDHYTest,
::testing::Combine(TlsConnectTestBase::kTlsVariantsDatagram,
TlsConnectTestBase::kTlsV11V12, kAllY, kTrueFalse));
class TlsDheSkeMakePEven :
public TlsHandshakeFilter {
public:
TlsDheSkeMakePEven(
const std::shared_ptr<TlsAgent>& a)
: TlsHandshakeFilter(a, {kTlsHandshakeServerKeyExchange}) {}
virtual PacketFilter::Action FilterHandshake(
const TlsHandshakeFilter::HandshakeHeader& header,
const DataBuffer& input, DataBuffer* output) {
// Find the end of dh_p
uint32_t dh_len = 0;
EXPECT_TRUE(input.Read(0, 2, &dh_len));
EXPECT_GT(input.len(), 2 + dh_len) <<
"enough space for dh_p";
size_t offset = 2 + dh_len - 1;
EXPECT_TRUE((input.data()[offset] & 0x01) == 0x01) <<
"p should be odd";
*output = input;
output->data()[offset] &= 0xfe;
return CHANGE;
}
};
// Even without requiring named groups, an even value for p is bad news.
TEST_P(TlsConnectGenericPre13, MakeDhePEven) {
EnableOnlyDheCiphers();
MakeTlsFilter<TlsDheSkeMakePEven>(server_);
ConnectExpectAlert(client_, kTlsAlertIllegalParameter);
client_->CheckErrorCode(SSL_ERROR_RX_MALFORMED_DHE_KEY_SHARE);
server_->CheckErrorCode(SSL_ERROR_ILLEGAL_PARAMETER_ALERT);
}
class TlsDheSkeZeroPadP :
public TlsHandshakeFilter {
public:
TlsDheSkeZeroPadP(
const std::shared_ptr<TlsAgent>& a)
: TlsHandshakeFilter(a, {kTlsHandshakeServerKeyExchange}) {}
virtual PacketFilter::Action FilterHandshake(
const TlsHandshakeFilter::HandshakeHeader& header,
const DataBuffer& input, DataBuffer* output) {
*output = input;
uint32_t dh_len = 0;
EXPECT_TRUE(input.Read(0, 2, &dh_len));
static const uint8_t kZeroPad = 0;
output->Write(0, dh_len +
sizeof(kZeroPad), 2);
// increment the length
output->Splice(&kZeroPad,
sizeof(kZeroPad), 2);
// insert a zero
return CHANGE;
}
};
// Zero padding only causes signature failure.
TEST_P(TlsConnectGenericPre13, PadDheP) {
EnableOnlyDheCiphers();
MakeTlsFilter<TlsDheSkeZeroPadP>(server_);
ConnectExpectAlert(client_, kTlsAlertDecryptError);
// In TLS 1.0 and 1.1, the client reports a device error.
if (version_ < SSL_LIBRARY_VERSION_TLS_1_2) {
client_->CheckErrorCode(SEC_ERROR_PKCS11_DEVICE_ERROR);
}
else {
client_->CheckErrorCode(SEC_ERROR_BAD_SIGNATURE);
}
server_->CheckErrorCode(SSL_ERROR_DECRYPT_ERROR_ALERT);
}
// The server should not pick the weak DH group if the client includes FFDHE
// named groups in the supported_groups extension. The server then picks a
// commonly-supported named DH group and this connects.
//
// Note: This test case can take ages to generate the weak DH key.
TEST_P(TlsConnectGenericPre13, WeakDHGroup) {
EnableOnlyDheCiphers();
client_->SetOption(SSL_REQUIRE_DH_NAMED_GROUPS, PR_TRUE);
EXPECT_EQ(SECSuccess,
SSL_EnableWeakDHEPrimeGroup(server_->ssl_fd(), PR_TRUE));
Connect();
}
TEST_P(TlsConnectGeneric, Ffdhe3072) {
EnableOnlyDheCiphers();
static const std::vector<SSLNamedGroup> groups = {ssl_grp_ffdhe_3072};
client_->ConfigNamedGroups(groups);
Connect();
}
// Even though the client doesn't have DHE groups enabled the server assumes it
// does. Because the client doesn't require named groups it accepts FF3072 as
// custom group.
TEST_P(TlsConnectGenericPre13, NamedGroupMismatchPre13) {
EnableOnlyDheCiphers();
static const std::vector<SSLNamedGroup> server_groups = {ssl_grp_ffdhe_3072};
static const std::vector<SSLNamedGroup> client_groups = {
ssl_grp_ec_secp256r1};
server_->ConfigNamedGroups(server_groups);
client_->ConfigNamedGroups(client_groups);
Connect();
CheckKeys(ssl_kea_dh, ssl_grp_ffdhe_custom, ssl_auth_rsa_sign,
ssl_sig_rsa_pss_rsae_sha256);
}
// Same test but for TLS 1.3. This has to fail.
TEST_P(TlsConnectTls13, NamedGroupMismatch13) {
EnableOnlyDheCiphers();
static const std::vector<SSLNamedGroup> server_groups = {ssl_grp_ffdhe_3072};
static const std::vector<SSLNamedGroup> client_groups = {
ssl_grp_ec_secp256r1};
server_->ConfigNamedGroups(server_groups);
client_->ConfigNamedGroups(client_groups);
ConnectExpectAlert(server_, kTlsAlertHandshakeFailure);
server_->CheckErrorCode(SSL_ERROR_NO_CYPHER_OVERLAP);
client_->CheckErrorCode(SSL_ERROR_NO_CYPHER_OVERLAP);
}
// Replace the key share in the server key exchange message with one that's
// larger than 8192 bits.
class TooLongDHEServerKEXFilter :
public TlsHandshakeFilter {
public:
TooLongDHEServerKEXFilter(
const std::shared_ptr<TlsAgent>& server)
: TlsHandshakeFilter(server, {kTlsHandshakeServerKeyExchange}) {}
protected:
virtual PacketFilter::Action FilterHandshake(
const HandshakeHeader& header,
const DataBuffer& input,
DataBuffer* output) {
// Replace the server key exchange message very large DH shares that are
// not supported by NSS.
const uint32_t share_len = 0x401;
const uint8_t zero_share[share_len] = {0x80};
size_t offset = 0;
// Write dh_p.
offset = output->Write(offset, share_len, 2);
offset = output->Write(offset, zero_share, share_len);
// Write dh_g.
offset = output->Write(offset, share_len, 2);
offset = output->Write(offset, zero_share, share_len);
// Write dh_Y.
offset = output->Write(offset, share_len, 2);
offset = output->Write(offset, zero_share, share_len);
return CHANGE;
}
};
TEST_P(TlsConnectGenericPre13, TooBigDHGroup) {
EnableOnlyDheCiphers();
MakeTlsFilter<TooLongDHEServerKEXFilter>(server_);
client_->SetOption(SSL_REQUIRE_DH_NAMED_GROUPS, PR_FALSE);
ConnectExpectAlert(client_, kTlsAlertIllegalParameter);
server_->CheckErrorCode(SSL_ERROR_ILLEGAL_PARAMETER_ALERT);
client_->CheckErrorCode(SSL_ERROR_DH_KEY_TOO_LONG);
}
// Even though the client doesn't have DHE groups enabled the server assumes it
// does. The client requires named groups and thus does not accept FF3072 as
// custom group in contrast to the previous test.
TEST_P(TlsConnectGenericPre13, RequireNamedGroupsMismatchPre13) {
EnableOnlyDheCiphers();
client_->SetOption(SSL_REQUIRE_DH_NAMED_GROUPS, PR_TRUE);
static const std::vector<SSLNamedGroup> server_groups = {ssl_grp_ffdhe_3072};
static const std::vector<SSLNamedGroup> client_groups = {ssl_grp_ec_secp256r1,
ssl_grp_ffdhe_2048};
server_->ConfigNamedGroups(server_groups);
client_->ConfigNamedGroups(client_groups);
ConnectExpectAlert(server_, kTlsAlertHandshakeFailure);
server_->CheckErrorCode(SSL_ERROR_NO_CYPHER_OVERLAP);
client_->CheckErrorCode(SSL_ERROR_NO_CYPHER_OVERLAP);
}
TEST_P(TlsConnectGenericPre13, PreferredFfdhe) {
EnableOnlyDheCiphers();
static const SSLDHEGroupType groups[] = {ssl_ff_dhe_3072_group,
ssl_ff_dhe_2048_group};
EXPECT_EQ(SECSuccess, SSL_DHEGroupPrefSet(server_->ssl_fd(), groups,
PR_ARRAY_SIZE(groups)));
Connect();
client_->CheckKEA(ssl_kea_dh, ssl_grp_ffdhe_3072, 3072);
server_->CheckKEA(ssl_kea_dh, ssl_grp_ffdhe_3072, 3072);
client_->CheckAuthType(ssl_auth_rsa_sign, ssl_sig_rsa_pss_rsae_sha256);
server_->CheckAuthType(ssl_auth_rsa_sign, ssl_sig_rsa_pss_rsae_sha256);
}
TEST_P(TlsConnectGenericPre13, MismatchDHE) {
EnableOnlyDheCiphers();
client_->SetOption(SSL_REQUIRE_DH_NAMED_GROUPS, PR_TRUE);
static const SSLDHEGroupType serverGroups[] = {ssl_ff_dhe_3072_group};
EXPECT_EQ(SECSuccess, SSL_DHEGroupPrefSet(server_->ssl_fd(), serverGroups,
PR_ARRAY_SIZE(serverGroups)));
static const SSLDHEGroupType clientGroups[] = {ssl_ff_dhe_2048_group};
EXPECT_EQ(SECSuccess, SSL_DHEGroupPrefSet(client_->ssl_fd(), clientGroups,
PR_ARRAY_SIZE(clientGroups)));
ConnectExpectAlert(server_, kTlsAlertHandshakeFailure);
server_->CheckErrorCode(SSL_ERROR_NO_CYPHER_OVERLAP);
client_->CheckErrorCode(SSL_ERROR_NO_CYPHER_OVERLAP);
}
TEST_P(TlsConnectTls13, ResumeFfdhe) {
EnableOnlyDheCiphers();
ConfigureSessionCache(RESUME_BOTH, RESUME_TICKET);
Connect();
SendReceive();
// Need to read so that we absorb the session ticket.
CheckKeys(ssl_kea_dh, ssl_grp_ffdhe_2048, ssl_auth_rsa_sign,
ssl_sig_rsa_pss_rsae_sha256);
Reset();
ConfigureSessionCache(RESUME_BOTH, RESUME_TICKET);
EnableOnlyDheCiphers();
auto clientCapture =
MakeTlsFilter<TlsExtensionCapture>(client_, ssl_tls13_pre_shared_key_xtn);
auto serverCapture =
MakeTlsFilter<TlsExtensionCapture>(server_, ssl_tls13_pre_shared_key_xtn);
ExpectResumption(RESUME_TICKET);
Connect();
CheckKeys(ssl_kea_dh, ssl_grp_ffdhe_2048, ssl_auth_rsa_sign,
ssl_sig_rsa_pss_rsae_sha256);
ASSERT_LT(0UL, clientCapture->extension().len());
ASSERT_LT(0UL, serverCapture->extension().len());
}
class TlsDheSkeChangeSignature :
public TlsHandshakeFilter {
public:
TlsDheSkeChangeSignature(
const std::shared_ptr<TlsAgent>& a, uint16_t version,
const uint8_t* data, size_t len)
: TlsHandshakeFilter(a, {kTlsHandshakeServerKeyExchange}),
version_(version),
data_(data),
len_(len) {}
protected:
virtual PacketFilter::Action FilterHandshake(
const HandshakeHeader& header,
const DataBuffer& input,
DataBuffer* output) {
TlsParser parser(input);
EXPECT_TRUE(parser.SkipVariable(2));
// dh_p
EXPECT_TRUE(parser.SkipVariable(2));
// dh_g
EXPECT_TRUE(parser.SkipVariable(2));
// dh_Ys
// Copy DH params to output.
size_t offset = output->Write(0, input.data(), parser.consumed());
if (version_ == SSL_LIBRARY_VERSION_TLS_1_2) {
// Write signature algorithm.
offset = output->Write(offset, ssl_sig_dsa_sha256, 2);
}
// Write new signature.
offset = output->Write(offset, len_, 2);
offset = output->Write(offset, data_, len_);
return CHANGE;
}
private:
uint16_t version_;
const uint8_t* data_;
size_t len_;
};
TEST_P(TlsConnectGenericPre13, InvalidDERSignatureFfdhe) {
const uint8_t kBogusDheSignature[] = {
0x30, 0x69, 0x3c, 0x02, 0x1c, 0x7d, 0x0b, 0x2f, 0x64, 0x00, 0x27,
0xae, 0xcf, 0x1e, 0x28, 0x08, 0x6a, 0x7f, 0xb1, 0xbd, 0x78, 0xb5,
0x3b, 0x8c, 0x8f, 0x59, 0xed, 0x8f, 0xee, 0x78, 0xeb, 0x2c, 0xe9,
0x02, 0x1c, 0x6d, 0x7f, 0x3c, 0x0f, 0xf4, 0x44, 0x35, 0x0b, 0xb2,
0x6d, 0xdc, 0xb8, 0x21, 0x87, 0xdd, 0x0d, 0xb9, 0x46, 0x09, 0x3e,
0xef, 0x81, 0x5b, 0x37, 0x09, 0x39, 0xeb};
Reset(TlsAgent::kServerDsa);
const std::vector<SSLNamedGroup> client_groups = {ssl_grp_ffdhe_2048};
client_->ConfigNamedGroups(client_groups);
MakeTlsFilter<TlsDheSkeChangeSignature>(server_, version_, kBogusDheSignature,
sizeof(kBogusDheSignature));
ConnectExpectAlert(client_, kTlsAlertDecryptError);
client_->CheckErrorCode(SSL_ERROR_BAD_HANDSHAKE_HASH_VALUE);
}
TEST_P(TlsConnectTls12, ConnectInconsistentSigAlgDHE) {
EnableOnlyDheCiphers();
MakeTlsFilter<DHEServerKEXSigAlgReplacer>(server_,
ssl_sig_ecdsa_secp256r1_sha256);
ConnectExpectAlert(client_, kTlsAlertIllegalParameter);
}
static void CheckSkeSigScheme(
std::shared_ptr<TlsHandshakeRecorder>& capture_ske,
uint16_t expected_scheme) {
TlsParser parser(capture_ske->buffer());
EXPECT_TRUE(parser.SkipVariable(2)) <<
" read dh_p";
EXPECT_TRUE(parser.SkipVariable(2)) <<
" read dh_q";
EXPECT_TRUE(parser.SkipVariable(2)) <<
" read dh_Ys";
uint32_t tmp;
EXPECT_TRUE(parser.Read(&tmp, 2)) <<
" read sig_scheme";
EXPECT_EQ(expected_scheme,
static_cast<uint16_t>(tmp));
}
TEST_P(TlsConnectTls12, ConnectSigAlgEnabledByPolicyDhe) {
EnableOnlyDheCiphers();
const std::vector<SSLSignatureScheme> schemes = {ssl_sig_rsa_pkcs1_sha1,
ssl_sig_rsa_pkcs1_sha384};
EnsureTlsSetup();
client_->SetSignatureSchemes(schemes.data(), schemes.size());
server_->SetSignatureSchemes(schemes.data(), schemes.size());
auto capture_ske = MakeTlsFilter<TlsHandshakeRecorder>(
server_, kTlsHandshakeServerKeyExchange);
StartConnect();
client_->Handshake();
// Send ClientHello
// Enable SHA-1 by policy.
SECStatus rv = NSS_SetAlgorithmPolicy(SEC_OID_SHA1, NSS_USE_ALG_IN_SSL_KX, 0);
ASSERT_EQ(SECSuccess, rv);
rv = NSS_SetAlgorithmPolicy(SEC_OID_APPLY_SSL_POLICY, NSS_USE_POLICY_IN_SSL,
0);
ASSERT_EQ(SECSuccess, rv);
Handshake();
// Remainder of handshake
// The server should now report that it is connected
EXPECT_EQ(TlsAgent::STATE_CONNECTED, server_->state());
CheckSkeSigScheme(capture_ske, ssl_sig_rsa_pkcs1_sha1);
}
TEST_P(TlsConnectTls12, ConnectSigAlgDisabledByPolicyDhe) {
EnableOnlyDheCiphers();
const std::vector<SSLSignatureScheme> schemes = {ssl_sig_rsa_pkcs1_sha1,
ssl_sig_rsa_pkcs1_sha384};
EnsureTlsSetup();
client_->SetSignatureSchemes(schemes.data(), schemes.size());
server_->SetSignatureSchemes(schemes.data(), schemes.size());
auto capture_ske = MakeTlsFilter<TlsHandshakeRecorder>(
server_, kTlsHandshakeServerKeyExchange);
StartConnect();
client_->Handshake();
// Send ClientHello
// Disable SHA-1 by policy after sending ClientHello so that CH
// includes SHA-1 signature scheme.
SECStatus rv = NSS_SetAlgorithmPolicy(SEC_OID_SHA1, 0, NSS_USE_ALG_IN_SSL_KX);
ASSERT_EQ(SECSuccess, rv);
rv = NSS_SetAlgorithmPolicy(SEC_OID_APPLY_SSL_POLICY, NSS_USE_POLICY_IN_SSL,
0);
ASSERT_EQ(SECSuccess, rv);
Handshake();
// Remainder of handshake
// The server should now report that it is connected
EXPECT_EQ(TlsAgent::STATE_CONNECTED, server_->state());
CheckSkeSigScheme(capture_ske, ssl_sig_rsa_pkcs1_sha384);
}
TEST_P(TlsConnectPre12, ConnectSigAlgDisabledWeakGroupByOption3072DhePre12) {
EnableOnlyDheCiphers();
// explicitly enable the weak groups
EXPECT_EQ(SECSuccess,
SSL_EnableWeakDHEPrimeGroup(server_->ssl_fd(), PR_TRUE));
EXPECT_EQ(SECSuccess,
SSL_EnableWeakDHEPrimeGroup(client_->ssl_fd(), PR_TRUE));
server_->SetNssOption(NSS_DH_MIN_KEY_SIZE, 3072);
Connect();
client_->CheckKEA(ssl_kea_dh, ssl_grp_ffdhe_3072, 3072);
server_->CheckKEA(ssl_kea_dh, ssl_grp_ffdhe_3072, 3072);
}
TEST_P(TlsConnectPre12, ConnectSigAlgDisabledWeakGroupByOption2048DhePre12) {
EnableOnlyDheCiphers();
// explicitly enable the weak groups
EXPECT_EQ(SECSuccess,
SSL_EnableWeakDHEPrimeGroup(server_->ssl_fd(), PR_TRUE));
EXPECT_EQ(SECSuccess,
SSL_EnableWeakDHEPrimeGroup(client_->ssl_fd(), PR_TRUE));
server_->SetNssOption(NSS_DH_MIN_KEY_SIZE, 2048);
Connect();
client_->CheckKEA(ssl_kea_dh, ssl_grp_ffdhe_2048, 2048);
server_->CheckKEA(ssl_kea_dh, ssl_grp_ffdhe_2048, 2048);
}
TEST_P(TlsConnectPre12, ConnectSigAlgDisabledByPolicyDhePre12) {
EnableOnlyDheCiphers();
EnsureTlsSetup();
StartConnect();
client_->Handshake();
// Send ClientHello
// Disable SHA-1 by policy. This will cause the connection fail as
// TLS 1.1 or earlier uses combined SHA-1 + MD5 signature.
SECStatus rv = NSS_SetAlgorithmPolicy(SEC_OID_SHA1, 0, NSS_USE_ALG_IN_SSL_KX);
ASSERT_EQ(SECSuccess, rv);
rv = NSS_SetAlgorithmPolicy(SEC_OID_APPLY_SSL_POLICY, NSS_USE_POLICY_IN_SSL,
0);
ASSERT_EQ(SECSuccess, rv);
server_->ExpectSendAlert(kTlsAlertHandshakeFailure);
client_->ExpectReceiveAlert(kTlsAlertHandshakeFailure);
// Remainder of handshake
Handshake();
server_->CheckErrorCode(SSL_ERROR_UNSUPPORTED_HASH_ALGORITHM);
}
TEST_P(TlsConnectTls12, ConnectSigAlgDisablePreferredGroupByOption3072Dhe) {
EnableOnlyDheCiphers();
static const SSLDHEGroupType dhe_groups[] = {
ssl_ff_dhe_2048_group,
// first in the lists is the preferred group
ssl_ff_dhe_3072_group};
server_->SetNssOption(NSS_DH_MIN_KEY_SIZE, 3072);
EXPECT_EQ(SECSuccess, SSL_DHEGroupPrefSet(server_->ssl_fd(), &dhe_groups[0],
PR_ARRAY_SIZE(dhe_groups)));
Connect();
// our option size should override the preferred group
client_->CheckKEA(ssl_kea_dh, ssl_grp_ffdhe_3072, 3072);
server_->CheckKEA(ssl_kea_dh, ssl_grp_ffdhe_3072, 3072);
}
TEST_P(TlsConnectTls12, ConnectSigAlgDisableGroupByOption3072Dhe) {
EnableOnlyDheCiphers();
server_->SetNssOption(NSS_DH_MIN_KEY_SIZE, 3072);
Connect();
client_->CheckKEA(ssl_kea_dh, ssl_grp_ffdhe_3072, 3072);
server_->CheckKEA(ssl_kea_dh, ssl_grp_ffdhe_3072, 3072);
}
}
// namespace nss_test
