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quiche / quiche.git / refs/heads/roll/20190423c / . / quic / test_tools / crypto_test_utils.cc
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// Copyright (c) 2012 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "net/third_party/quiche/src/quic/test_tools/crypto_test_utils.h"
#include <memory>
#include <string>
#include "third_party/boringssl/src/include/openssl/bn.h"
#include "third_party/boringssl/src/include/openssl/ec.h"
#include "third_party/boringssl/src/include/openssl/ecdsa.h"
#include "third_party/boringssl/src/include/openssl/nid.h"
#include "third_party/boringssl/src/include/openssl/sha.h"
#include "net/third_party/quiche/src/quic/core/crypto/channel_id.h"
#include "net/third_party/quiche/src/quic/core/crypto/common_cert_set.h"
#include "net/third_party/quiche/src/quic/core/crypto/crypto_handshake.h"
#include "net/third_party/quiche/src/quic/core/crypto/quic_crypto_server_config.h"
#include "net/third_party/quiche/src/quic/core/crypto/quic_decrypter.h"
#include "net/third_party/quiche/src/quic/core/crypto/quic_encrypter.h"
#include "net/third_party/quiche/src/quic/core/crypto/quic_random.h"
#include "net/third_party/quiche/src/quic/core/proto/crypto_server_config.pb.h"
#include "net/third_party/quiche/src/quic/core/quic_crypto_client_stream.h"
#include "net/third_party/quiche/src/quic/core/quic_crypto_server_stream.h"
#include "net/third_party/quiche/src/quic/core/quic_crypto_stream.h"
#include "net/third_party/quiche/src/quic/core/quic_server_id.h"
#include "net/third_party/quiche/src/quic/core/quic_utils.h"
#include "net/third_party/quiche/src/quic/core/tls_client_handshaker.h"
#include "net/third_party/quiche/src/quic/core/tls_server_handshaker.h"
#include "net/third_party/quiche/src/quic/platform/api/quic_bug_tracker.h"
#include "net/third_party/quiche/src/quic/platform/api/quic_clock.h"
#include "net/third_party/quiche/src/quic/platform/api/quic_logging.h"
#include "net/third_party/quiche/src/quic/platform/api/quic_ptr_util.h"
#include "net/third_party/quiche/src/quic/platform/api/quic_socket_address.h"
#include "net/third_party/quiche/src/quic/platform/api/quic_test.h"
#include "net/third_party/quiche/src/quic/platform/api/quic_text_utils.h"
#include "net/third_party/quiche/src/quic/test_tools/quic_connection_peer.h"
#include "net/third_party/quiche/src/quic/test_tools/quic_framer_peer.h"
#include "net/third_party/quiche/src/quic/test_tools/quic_stream_peer.h"
#include "net/third_party/quiche/src/quic/test_tools/quic_test_utils.h"
#include "net/third_party/quiche/src/quic/test_tools/simple_quic_framer.h"
namespace quic {
namespace test {
TestChannelIDKey::TestChannelIDKey(EVP_PKEY* ecdsa_key)
: ecdsa_key_(ecdsa_key) {}
TestChannelIDKey::~TestChannelIDKey() {}
bool TestChannelIDKey::Sign(QuicStringPiece signed_data,
std::string* out_signature) const {
bssl::ScopedEVP_MD_CTX md_ctx;
if (EVP_DigestSignInit(md_ctx.get(), nullptr, EVP_sha256(), nullptr,
ecdsa_key_.get()) != 1) {
return false;
}
EVP_DigestUpdate(md_ctx.get(), ChannelIDVerifier::kContextStr,
strlen(ChannelIDVerifier::kContextStr) + 1);
EVP_DigestUpdate(md_ctx.get(), ChannelIDVerifier::kClientToServerStr,
strlen(ChannelIDVerifier::kClientToServerStr) + 1);
EVP_DigestUpdate(md_ctx.get(), signed_data.data(), signed_data.size());
size_t sig_len;
if (!EVP_DigestSignFinal(md_ctx.get(), nullptr, &sig_len)) {
return false;
}
std::unique_ptr<uint8_t[]> der_sig(new uint8_t[sig_len]);
if (!EVP_DigestSignFinal(md_ctx.get(), der_sig.get(), &sig_len)) {
return false;
}
uint8_t* derp = der_sig.get();
bssl::UniquePtr<ECDSA_SIG> sig(
d2i_ECDSA_SIG(nullptr, const_cast<const uint8_t**>(&derp), sig_len));
if (sig.get() == nullptr) {
return false;
}
// The signature consists of a pair of 32-byte numbers.
static const size_t kSignatureLength = 32 * 2;
std::unique_ptr<uint8_t[]> signature(new uint8_t[kSignatureLength]);
if (!BN_bn2bin_padded(&signature[0], 32, sig->r) ||
!BN_bn2bin_padded(&signature[32], 32, sig->s)) {
return false;
}
*out_signature =
std::string(reinterpret_cast<char*>(signature.get()), kSignatureLength);
return true;
}
std::string TestChannelIDKey::SerializeKey() const {
// i2d_PublicKey will produce an ANSI X9.62 public key which, for a P-256
// key, is 0x04 (meaning uncompressed) followed by the x and y field
// elements as 32-byte, big-endian numbers.
static const int kExpectedKeyLength = 65;
int len = i2d_PublicKey(ecdsa_key_.get(), nullptr);
if (len != kExpectedKeyLength) {
return "";
}
uint8_t buf[kExpectedKeyLength];
uint8_t* derp = buf;
i2d_PublicKey(ecdsa_key_.get(), &derp);
return std::string(reinterpret_cast<char*>(buf + 1), kExpectedKeyLength - 1);
}
TestChannelIDSource::~TestChannelIDSource() {}
QuicAsyncStatus TestChannelIDSource::GetChannelIDKey(
const std::string& hostname,
std::unique_ptr<ChannelIDKey>* channel_id_key,
ChannelIDSourceCallback* /*callback*/) {
*channel_id_key = QuicMakeUnique<TestChannelIDKey>(HostnameToKey(hostname));
return QUIC_SUCCESS;
}
// static
EVP_PKEY* TestChannelIDSource::HostnameToKey(const std::string& hostname) {
// In order to generate a deterministic key for a given hostname the
// hostname is hashed with SHA-256 and the resulting digest is treated as a
// big-endian number. The most-significant bit is cleared to ensure that
// the resulting value is less than the order of the group and then it's
// taken as a private key. Given the private key, the public key is
// calculated with a group multiplication.
SHA256_CTX sha256;
SHA256_Init(&sha256);
SHA256_Update(&sha256, hostname.data(), hostname.size());
unsigned char digest[SHA256_DIGEST_LENGTH];
SHA256_Final(digest, &sha256);
// Ensure that the digest is less than the order of the P-256 group by
// clearing the most-significant bit.
digest[0] &= 0x7f;
bssl::UniquePtr<BIGNUM> k(BN_new());
CHECK(BN_bin2bn(digest, sizeof(digest), k.get()) != nullptr);
bssl::UniquePtr<EC_GROUP> p256(
EC_GROUP_new_by_curve_name(NID_X9_62_prime256v1));
CHECK(p256);
bssl::UniquePtr<EC_KEY> ecdsa_key(EC_KEY_new());
CHECK(ecdsa_key && EC_KEY_set_group(ecdsa_key.get(), p256.get()));
bssl::UniquePtr<EC_POINT> point(EC_POINT_new(p256.get()));
CHECK(EC_POINT_mul(p256.get(), point.get(), k.get(), nullptr, nullptr,
nullptr));
EC_KEY_set_private_key(ecdsa_key.get(), k.get());
EC_KEY_set_public_key(ecdsa_key.get(), point.get());
bssl::UniquePtr<EVP_PKEY> pkey(EVP_PKEY_new());
// EVP_PKEY_set1_EC_KEY takes a reference so no |release| here.
EVP_PKEY_set1_EC_KEY(pkey.get(), ecdsa_key.get());
return pkey.release();
}
namespace crypto_test_utils {
namespace {
// CryptoFramerVisitor is a framer visitor that records handshake messages.
class CryptoFramerVisitor : public CryptoFramerVisitorInterface {
public:
CryptoFramerVisitor() : error_(false) {}
void OnError(CryptoFramer* framer) override { error_ = true; }
void OnHandshakeMessage(const CryptoHandshakeMessage& message) override {
messages_.push_back(message);
}
bool error() const { return error_; }
const std::vector<CryptoHandshakeMessage>& messages() const {
return messages_;
}
private:
bool error_;
std::vector<CryptoHandshakeMessage> messages_;
};
// HexChar parses |c| as a hex character. If valid, it sets |*value| to the
// value of the hex character and returns true. Otherwise it returns false.
bool HexChar(char c, uint8_t* value) {
if (c >= '0' && c <= '9') {
*value = c - '0';
return true;
}
if (c >= 'a' && c <= 'f') {
*value = c - 'a' + 10;
return true;
}
if (c >= 'A' && c <= 'F') {
*value = c - 'A' + 10;
return true;
}
return false;
}
// A ChannelIDSource that works in asynchronous mode unless the |callback|
// argument to GetChannelIDKey is nullptr.
class AsyncTestChannelIDSource : public ChannelIDSource, public CallbackSource {
public:
// |sync_source| is a synchronous ChannelIDSource.
explicit AsyncTestChannelIDSource(
std::unique_ptr<ChannelIDSource> sync_source)
: sync_source_(std::move(sync_source)) {}
~AsyncTestChannelIDSource() override {}
// ChannelIDSource implementation.
QuicAsyncStatus GetChannelIDKey(const std::string& hostname,
std::unique_ptr<ChannelIDKey>* channel_id_key,
ChannelIDSourceCallback* callback) override {
// Synchronous mode.
if (!callback) {
return sync_source_->GetChannelIDKey(hostname, channel_id_key, nullptr);
}
// Asynchronous mode.
QuicAsyncStatus status =
sync_source_->GetChannelIDKey(hostname, &channel_id_key_, nullptr);
if (status != QUIC_SUCCESS) {
return QUIC_FAILURE;
}
callback_.reset(callback);
return QUIC_PENDING;
}
// CallbackSource implementation.
void RunPendingCallbacks() override {
if (callback_) {
callback_->Run(&channel_id_key_);
callback_.reset();
}
}
private:
std::unique_ptr<ChannelIDSource> sync_source_;
std::unique_ptr<ChannelIDSourceCallback> callback_;
std::unique_ptr<ChannelIDKey> channel_id_key_;
};
} // anonymous namespace
FakeServerOptions::FakeServerOptions() {}
FakeServerOptions::~FakeServerOptions() {}
FakeClientOptions::FakeClientOptions()
: channel_id_enabled(false), channel_id_source_async(false) {}
FakeClientOptions::~FakeClientOptions() {}
namespace {
// This class is used by GenerateFullCHLO() to extract SCID and STK from
// REJ/SREJ and to construct a full CHLO with these fields and given inchoate
// CHLO.
class FullChloGenerator {
public:
FullChloGenerator(
QuicCryptoServerConfig* crypto_config,
QuicSocketAddress server_addr,
QuicSocketAddress client_addr,
const QuicClock* clock,
QuicReferenceCountedPointer<QuicSignedServerConfig> signed_config,
QuicCompressedCertsCache* compressed_certs_cache,
CryptoHandshakeMessage* out)
: crypto_config_(crypto_config),
server_addr_(server_addr),
client_addr_(client_addr),
clock_(clock),
signed_config_(signed_config),
compressed_certs_cache_(compressed_certs_cache),
out_(out),
params_(new QuicCryptoNegotiatedParameters) {}
class ValidateClientHelloCallback : public ValidateClientHelloResultCallback {
public:
explicit ValidateClientHelloCallback(FullChloGenerator* generator)
: generator_(generator) {}
void Run(QuicReferenceCountedPointer<
ValidateClientHelloResultCallback::Result> result,
std::unique_ptr<ProofSource::Details> /* details */) override {
generator_->ValidateClientHelloDone(std::move(result));
}
private:
FullChloGenerator* generator_;
};
std::unique_ptr<ValidateClientHelloCallback>
GetValidateClientHelloCallback() {
return QuicMakeUnique<ValidateClientHelloCallback>(this);
}
private:
void ValidateClientHelloDone(
QuicReferenceCountedPointer<ValidateClientHelloResultCallback::Result>
result) {
result_ = result;
crypto_config_->ProcessClientHello(
result_, /*reject_only=*/false, TestConnectionId(1), server_addr_,
client_addr_, AllSupportedVersions().front(), AllSupportedVersions(),
/*use_stateless_rejects=*/true,
/*server_designated_connection_id=*/TestConnectionId(2), clock_,
QuicRandom::GetInstance(), compressed_certs_cache_, params_,
signed_config_, /*total_framing_overhead=*/50, kDefaultMaxPacketSize,
GetProcessClientHelloCallback());
}
class ProcessClientHelloCallback : public ProcessClientHelloResultCallback {
public:
explicit ProcessClientHelloCallback(FullChloGenerator* generator)
: generator_(generator) {}
void Run(
QuicErrorCode error,
const std::string& error_details,
std::unique_ptr<CryptoHandshakeMessage> message,
std::unique_ptr<DiversificationNonce> diversification_nonce,
std::unique_ptr<ProofSource::Details> proof_source_details) override {
generator_->ProcessClientHelloDone(std::move(message));
}
private:
FullChloGenerator* generator_;
};
std::unique_ptr<ProcessClientHelloCallback> GetProcessClientHelloCallback() {
return QuicMakeUnique<ProcessClientHelloCallback>(this);
}
void ProcessClientHelloDone(std::unique_ptr<CryptoHandshakeMessage> rej) {
// Verify output is a REJ or SREJ.
EXPECT_THAT(rej->tag(),
testing::AnyOf(testing::Eq(kSREJ), testing::Eq(kREJ)));
VLOG(1) << "Extract valid STK and SCID from\n" << rej->DebugString();
QuicStringPiece srct;
ASSERT_TRUE(rej->GetStringPiece(kSourceAddressTokenTag, &srct));
QuicStringPiece scfg;
ASSERT_TRUE(rej->GetStringPiece(kSCFG, &scfg));
std::unique_ptr<CryptoHandshakeMessage> server_config(
CryptoFramer::ParseMessage(scfg));
QuicStringPiece scid;
ASSERT_TRUE(server_config->GetStringPiece(kSCID, &scid));
*out_ = result_->client_hello;
out_->SetStringPiece(kSCID, scid);
out_->SetStringPiece(kSourceAddressTokenTag, srct);
uint64_t xlct = LeafCertHashForTesting();
out_->SetValue(kXLCT, xlct);
}
protected:
QuicCryptoServerConfig* crypto_config_;
QuicSocketAddress server_addr_;
QuicSocketAddress client_addr_;
const QuicClock* clock_;
QuicReferenceCountedPointer<QuicSignedServerConfig> signed_config_;
QuicCompressedCertsCache* compressed_certs_cache_;
CryptoHandshakeMessage* out_;
QuicReferenceCountedPointer<QuicCryptoNegotiatedParameters> params_;
QuicReferenceCountedPointer<ValidateClientHelloResultCallback::Result>
result_;
};
} // namespace
int HandshakeWithFakeServer(QuicConfig* server_quic_config,
MockQuicConnectionHelper* helper,
MockAlarmFactory* alarm_factory,
PacketSavingConnection* client_conn,
QuicCryptoClientStream* client,
const FakeServerOptions& options) {
PacketSavingConnection* server_conn = new PacketSavingConnection(
helper, alarm_factory, Perspective::IS_SERVER,
ParsedVersionOfIndex(client_conn->supported_versions(), 0));
QuicCryptoServerConfig crypto_config(
QuicCryptoServerConfig::TESTING, QuicRandom::GetInstance(),
ProofSourceForTesting(), KeyExchangeSource::Default(),
TlsServerHandshaker::CreateSslCtx());
QuicCompressedCertsCache compressed_certs_cache(
QuicCompressedCertsCache::kQuicCompressedCertsCacheSize);
SetupCryptoServerConfigForTest(server_conn->clock(),
server_conn->random_generator(),
&crypto_config, options);
TestQuicSpdyServerSession server_session(
server_conn, *server_quic_config, client_conn->supported_versions(),
&crypto_config, &compressed_certs_cache);
server_session.OnSuccessfulVersionNegotiation(
client_conn->supported_versions().front());
EXPECT_CALL(*server_session.helper(),
CanAcceptClientHello(testing::_, testing::_, testing::_,
testing::_, testing::_))
.Times(testing::AnyNumber());
EXPECT_CALL(*server_session.helper(),
GenerateConnectionIdForReject(testing::_, testing::_))
.Times(testing::AnyNumber());
EXPECT_CALL(*server_conn, OnCanWrite()).Times(testing::AnyNumber());
EXPECT_CALL(*client_conn, OnCanWrite()).Times(testing::AnyNumber());
// The client's handshake must have been started already.
CHECK_NE(0u, client_conn->encrypted_packets_.size());
CommunicateHandshakeMessages(client_conn, client, server_conn,
server_session.GetMutableCryptoStream());
CompareClientAndServerKeys(client, server_session.GetMutableCryptoStream());
return client->num_sent_client_hellos();
}
int HandshakeWithFakeClient(MockQuicConnectionHelper* helper,
MockAlarmFactory* alarm_factory,
PacketSavingConnection* server_conn,
QuicCryptoServerStream* server,
const QuicServerId& server_id,
const FakeClientOptions& options) {
ParsedQuicVersionVector supported_versions = AllSupportedVersions();
if (options.only_tls_versions) {
supported_versions.clear();
for (QuicTransportVersion transport_version :
AllSupportedTransportVersions()) {
supported_versions.push_back(
ParsedQuicVersion(PROTOCOL_TLS1_3, transport_version));
}
}
PacketSavingConnection* client_conn = new PacketSavingConnection(
helper, alarm_factory, Perspective::IS_CLIENT, supported_versions);
// Advance the time, because timers do not like uninitialized times.
client_conn->AdvanceTime(QuicTime::Delta::FromSeconds(1));
QuicCryptoClientConfig crypto_config(ProofVerifierForTesting(),
TlsClientHandshaker::CreateSslCtx());
AsyncTestChannelIDSource* async_channel_id_source = nullptr;
if (options.channel_id_enabled) {
std::unique_ptr<ChannelIDSource> source = ChannelIDSourceForTesting();
if (options.channel_id_source_async) {
auto temp = QuicMakeUnique<AsyncTestChannelIDSource>(std::move(source));
async_channel_id_source = temp.get();
source = std::move(temp);
}
crypto_config.SetChannelIDSource(std::move(source));
}
if (!options.token_binding_params.empty()) {
crypto_config.tb_key_params = options.token_binding_params;
}
TestQuicSpdyClientSession client_session(client_conn, DefaultQuicConfig(),
supported_versions, server_id,
&crypto_config);
EXPECT_CALL(client_session, OnProofValid(testing::_))
.Times(testing::AnyNumber());
EXPECT_CALL(client_session, OnProofVerifyDetailsAvailable(testing::_))
.Times(testing::AnyNumber());
EXPECT_CALL(*client_conn, OnCanWrite()).Times(testing::AnyNumber());
client_session.GetMutableCryptoStream()->CryptoConnect();
CHECK_EQ(1u, client_conn->encrypted_packets_.size());
CommunicateHandshakeMessagesAndRunCallbacks(
client_conn, client_session.GetMutableCryptoStream(), server_conn, server,
async_channel_id_source);
if (server->handshake_confirmed() && server->encryption_established()) {
CompareClientAndServerKeys(client_session.GetMutableCryptoStream(), server);
if (options.channel_id_enabled) {
std::unique_ptr<ChannelIDKey> channel_id_key;
QuicAsyncStatus status =
crypto_config.channel_id_source()->GetChannelIDKey(
server_id.host(), &channel_id_key, nullptr);
EXPECT_EQ(QUIC_SUCCESS, status);
EXPECT_EQ(channel_id_key->SerializeKey(),
server->crypto_negotiated_params().channel_id);
EXPECT_EQ(
options.channel_id_source_async,
client_session.GetCryptoStream()->WasChannelIDSourceCallbackRun());
}
}
return client_session.GetCryptoStream()->num_sent_client_hellos();
}
void SetupCryptoServerConfigForTest(const QuicClock* clock,
QuicRandom* rand,
QuicCryptoServerConfig* crypto_config,
const FakeServerOptions& fake_options) {
QuicCryptoServerConfig::ConfigOptions options;
options.channel_id_enabled = true;
options.token_binding_params = fake_options.token_binding_params;
std::unique_ptr<CryptoHandshakeMessage> scfg =
crypto_config->AddDefaultConfig(rand, clock, options);
}
void SendHandshakeMessageToStream(QuicCryptoStream* stream,
const CryptoHandshakeMessage& message,
Perspective perspective) {
const QuicData& data = message.GetSerialized();
QuicSession* session = QuicStreamPeer::session(stream);
if (!QuicVersionUsesCryptoFrames(
session->connection()->transport_version())) {
QuicStreamFrame frame(QuicUtils::GetCryptoStreamId(
session->connection()->transport_version()),
false, stream->crypto_bytes_read(),
data.AsStringPiece());
stream->OnStreamFrame(frame);
} else {
EncryptionLevel level = session->connection()->last_decrypted_level();
QuicCryptoFrame frame(level, stream->BytesReadOnLevel(level),
data.AsStringPiece());
stream->OnCryptoFrame(frame);
}
}
void CommunicateHandshakeMessages(PacketSavingConnection* client_conn,
QuicCryptoStream* client,
PacketSavingConnection* server_conn,
QuicCryptoStream* server) {
CommunicateHandshakeMessagesAndRunCallbacks(client_conn, client, server_conn,
server, nullptr);
}
void CommunicateHandshakeMessagesAndRunCallbacks(
PacketSavingConnection* client_conn,
QuicCryptoStream* client,
PacketSavingConnection* server_conn,
QuicCryptoStream* server,
CallbackSource* callback_source) {
size_t client_i = 0, server_i = 0;
while (!client->handshake_confirmed() || !server->handshake_confirmed()) {
ASSERT_GT(client_conn->encrypted_packets_.size(), client_i);
QUIC_LOG(INFO) << "Processing "
<< client_conn->encrypted_packets_.size() - client_i
<< " packets client->server";
MovePackets(client_conn, &client_i, server, server_conn,
Perspective::IS_SERVER);
if (callback_source) {
callback_source->RunPendingCallbacks();
}
if (client->handshake_confirmed() && server->handshake_confirmed()) {
break;
}
ASSERT_GT(server_conn->encrypted_packets_.size(), server_i);
QUIC_LOG(INFO) << "Processing "
<< server_conn->encrypted_packets_.size() - server_i
<< " packets server->client";
MovePackets(server_conn, &server_i, client, client_conn,
Perspective::IS_CLIENT);
if (callback_source) {
callback_source->RunPendingCallbacks();
}
}
}
std::pair<size_t, size_t> AdvanceHandshake(PacketSavingConnection* client_conn,
QuicCryptoStream* client,
size_t client_i,
PacketSavingConnection* server_conn,
QuicCryptoStream* server,
size_t server_i) {
QUIC_LOG(INFO) << "Processing "
<< client_conn->encrypted_packets_.size() - client_i
<< " packets client->server";
MovePackets(client_conn, &client_i, server, server_conn,
Perspective::IS_SERVER);
QUIC_LOG(INFO) << "Processing "
<< server_conn->encrypted_packets_.size() - server_i
<< " packets server->client";
if (server_conn->encrypted_packets_.size() - server_i == 2) {
QUIC_LOG(INFO) << "here";
}
MovePackets(server_conn, &server_i, client, client_conn,
Perspective::IS_CLIENT);
return std::make_pair(client_i, server_i);
}
std::string GetValueForTag(const CryptoHandshakeMessage& message, QuicTag tag) {
auto it = message.tag_value_map().find(tag);
if (it == message.tag_value_map().end()) {
return std::string();
}
return it->second;
}
uint64_t LeafCertHashForTesting() {
QuicReferenceCountedPointer<ProofSource::Chain> chain;
QuicSocketAddress server_address(QuicIpAddress::Any4(), 42);
QuicCryptoProof proof;
std::unique_ptr<ProofSource> proof_source(ProofSourceForTesting());
class Callback : public ProofSource::Callback {
public:
Callback(bool* ok, QuicReferenceCountedPointer<ProofSource::Chain>* chain)
: ok_(ok), chain_(chain) {}
void Run(bool ok,
const QuicReferenceCountedPointer<ProofSource::Chain>& chain,
const QuicCryptoProof& /* proof */,
std::unique_ptr<ProofSource::Details> /* details */) override {
*ok_ = ok;
*chain_ = chain;
}
private:
bool* ok_;
QuicReferenceCountedPointer<ProofSource::Chain>* chain_;
};
// Note: relies on the callback being invoked synchronously
bool ok = false;
proof_source->GetProof(
server_address, "", "", AllSupportedTransportVersions().front(), "",
std::unique_ptr<ProofSource::Callback>(new Callback(&ok, &chain)));
if (!ok || chain->certs.empty()) {
DCHECK(false) << "Proof generation failed";
return 0;
}
return QuicUtils::FNV1a_64_Hash(chain->certs.at(0));
}
class MockCommonCertSets : public CommonCertSets {
public:
MockCommonCertSets(QuicStringPiece cert, uint64_t hash, uint32_t index)
: cert_(cert), hash_(hash), index_(index) {}
QuicStringPiece GetCommonHashes() const override {
QUIC_BUG << "not implemented";
return QuicStringPiece();
}
QuicStringPiece GetCert(uint64_t hash, uint32_t index) const override {
if (hash == hash_ && index == index_) {
return cert_;
}
return QuicStringPiece();
}
bool MatchCert(QuicStringPiece cert,
QuicStringPiece common_set_hashes,
uint64_t* out_hash,
uint32_t* out_index) const override {
if (cert != cert_) {
return false;
}
if (common_set_hashes.size() % sizeof(uint64_t) != 0) {
return false;
}
bool client_has_set = false;
for (size_t i = 0; i < common_set_hashes.size(); i += sizeof(uint64_t)) {
uint64_t hash;
memcpy(&hash, common_set_hashes.data() + i, sizeof(hash));
if (hash == hash_) {
client_has_set = true;
break;
}
}
if (!client_has_set) {
return false;
}
*out_hash = hash_;
*out_index = index_;
return true;
}
private:
const std::string cert_;
const uint64_t hash_;
const uint32_t index_;
};
CommonCertSets* MockCommonCertSets(QuicStringPiece cert,
uint64_t hash,
uint32_t index) {
return new class MockCommonCertSets(cert, hash, index);
}
void FillInDummyReject(CryptoHandshakeMessage* rej, bool reject_is_stateless) {
if (reject_is_stateless) {
rej->set_tag(kSREJ);
} else {
rej->set_tag(kREJ);
}
// Minimum SCFG that passes config validation checks.
// clang-format off
unsigned char scfg[] = {
// SCFG
0x53, 0x43, 0x46, 0x47,
// num entries
0x01, 0x00,
// padding
0x00, 0x00,
// EXPY
0x45, 0x58, 0x50, 0x59,
// EXPY end offset
0x08, 0x00, 0x00, 0x00,
// Value
'1', '2', '3', '4',
'5', '6', '7', '8'
};
// clang-format on
rej->SetValue(kSCFG, scfg);
rej->SetStringPiece(kServerNonceTag, "SERVER_NONCE");
int64_t ttl = 2 * 24 * 60 * 60;
rej->SetValue(kSTTL, ttl);
std::vector<QuicTag> reject_reasons;
reject_reasons.push_back(CLIENT_NONCE_INVALID_FAILURE);
rej->SetVector(kRREJ, reject_reasons);
}
namespace {
#define RETURN_STRING_LITERAL(x) \
case x: \
return #x
std::string EncryptionLevelString(EncryptionLevel level) {
switch (level) {
RETURN_STRING_LITERAL(ENCRYPTION_INITIAL);
RETURN_STRING_LITERAL(ENCRYPTION_HANDSHAKE);
RETURN_STRING_LITERAL(ENCRYPTION_ZERO_RTT);
RETURN_STRING_LITERAL(ENCRYPTION_FORWARD_SECURE);
default:
return "";
}
}
void CompareCrypters(const QuicEncrypter* encrypter,
const QuicDecrypter* decrypter,
std::string label) {
if (encrypter == nullptr || decrypter == nullptr) {
ADD_FAILURE() << "Expected non-null crypters; have " << encrypter << " and "
<< decrypter;
return;
}
QuicStringPiece encrypter_key = encrypter->GetKey();
QuicStringPiece encrypter_iv = encrypter->GetNoncePrefix();
QuicStringPiece decrypter_key = decrypter->GetKey();
QuicStringPiece decrypter_iv = decrypter->GetNoncePrefix();
CompareCharArraysWithHexError(label + " key", encrypter_key.data(),
encrypter_key.length(), decrypter_key.data(),
decrypter_key.length());
CompareCharArraysWithHexError(label + " iv", encrypter_iv.data(),
encrypter_iv.length(), decrypter_iv.data(),
decrypter_iv.length());
}
} // namespace
void CompareClientAndServerKeys(QuicCryptoClientStream* client,
QuicCryptoServerStream* server) {
QuicFramer* client_framer = QuicConnectionPeer::GetFramer(
QuicStreamPeer::session(client)->connection());
QuicFramer* server_framer = QuicConnectionPeer::GetFramer(
QuicStreamPeer::session(server)->connection());
for (EncryptionLevel level :
{ENCRYPTION_HANDSHAKE, ENCRYPTION_ZERO_RTT, ENCRYPTION_FORWARD_SECURE}) {
SCOPED_TRACE(EncryptionLevelString(level));
const QuicEncrypter* client_encrypter(
QuicFramerPeer::GetEncrypter(client_framer, level));
const QuicDecrypter* server_decrypter(
QuicFramerPeer::GetDecrypter(server_framer, level));
if (level == ENCRYPTION_FORWARD_SECURE ||
!(client_encrypter == nullptr && server_decrypter == nullptr)) {
CompareCrypters(client_encrypter, server_decrypter,
"client " + EncryptionLevelString(level) + " write");
}
const QuicEncrypter* server_encrypter(
QuicFramerPeer::GetEncrypter(server_framer, level));
const QuicDecrypter* client_decrypter(
QuicFramerPeer::GetDecrypter(client_framer, level));
if (level == ENCRYPTION_FORWARD_SECURE ||
!(server_encrypter == nullptr && client_decrypter == nullptr)) {
CompareCrypters(server_encrypter, client_decrypter,
"server " + EncryptionLevelString(level) + " write");
}
}
QuicStringPiece client_subkey_secret =
client->crypto_negotiated_params().subkey_secret;
QuicStringPiece server_subkey_secret =
server->crypto_negotiated_params().subkey_secret;
CompareCharArraysWithHexError("subkey secret", client_subkey_secret.data(),
client_subkey_secret.length(),
server_subkey_secret.data(),
server_subkey_secret.length());
const char kSampleLabel[] = "label";
const char kSampleContext[] = "context";
const size_t kSampleOutputLength = 32;
std::string client_key_extraction;
std::string server_key_extraction;
EXPECT_TRUE(client->ExportKeyingMaterial(kSampleLabel, kSampleContext,
kSampleOutputLength,
&client_key_extraction));
EXPECT_TRUE(server->ExportKeyingMaterial(kSampleLabel, kSampleContext,
kSampleOutputLength,
&server_key_extraction));
CompareCharArraysWithHexError(
"sample key extraction", client_key_extraction.data(),
client_key_extraction.length(), server_key_extraction.data(),
server_key_extraction.length());
}
QuicTag ParseTag(const char* tagstr) {
const size_t len = strlen(tagstr);
CHECK_NE(0u, len);
QuicTag tag = 0;
if (tagstr[0] == '#') {
CHECK_EQ(static_cast<size_t>(1 + 2 * 4), len);
tagstr++;
for (size_t i = 0; i < 8; i++) {
tag <<= 4;
uint8_t v = 0;
CHECK(HexChar(tagstr[i], &v));
tag |= v;
}
return tag;
}
CHECK_LE(len, 4u);
for (size_t i = 0; i < 4; i++) {
tag >>= 8;
if (i < len) {
tag |= static_cast<uint32_t>(tagstr[i]) << 24;
}
}
return tag;
}
CryptoHandshakeMessage CreateCHLO(
std::vector<std::pair<std::string, std::string>> tags_and_values) {
return CreateCHLO(tags_and_values, -1);
}
CryptoHandshakeMessage CreateCHLO(
std::vector<std::pair<std::string, std::string>> tags_and_values,
int minimum_size_bytes) {
CryptoHandshakeMessage msg;
msg.set_tag(MakeQuicTag('C', 'H', 'L', 'O'));
if (minimum_size_bytes > 0) {
msg.set_minimum_size(minimum_size_bytes);
}
for (const auto& tag_and_value : tags_and_values) {
const std::string& tag = tag_and_value.first;
const std::string& value = tag_and_value.second;
const QuicTag quic_tag = ParseTag(tag.c_str());
size_t value_len = value.length();
if (value_len > 0 && value[0] == '#') {
// This is ascii encoded hex.
std::string hex_value =
QuicTextUtils::HexDecode(QuicStringPiece(&value[1]));
msg.SetStringPiece(quic_tag, hex_value);
continue;
}
msg.SetStringPiece(quic_tag, value);
}
// The CryptoHandshakeMessage needs to be serialized and parsed to ensure
// that any padding is included.
std::unique_ptr<QuicData> bytes =
CryptoFramer::ConstructHandshakeMessage(msg);
std::unique_ptr<CryptoHandshakeMessage> parsed(
CryptoFramer::ParseMessage(bytes->AsStringPiece()));
CHECK(parsed);
return *parsed;
}
std::unique_ptr<ChannelIDSource> ChannelIDSourceForTesting() {
return QuicMakeUnique<TestChannelIDSource>();
}
void MovePackets(PacketSavingConnection* source_conn,
size_t* inout_packet_index,
QuicCryptoStream* dest_stream,
PacketSavingConnection* dest_conn,
Perspective dest_perspective) {
SimpleQuicFramer framer(source_conn->supported_versions(), dest_perspective);
SimpleQuicFramer null_encryption_framer(source_conn->supported_versions(),
dest_perspective);
size_t index = *inout_packet_index;
for (; index < source_conn->encrypted_packets_.size(); index++) {
// In order to properly test the code we need to perform encryption and
// decryption so that the crypters latch when expected. The crypters are in
// |dest_conn|, but we don't want to try and use them there. Instead we swap
// them into |framer|, perform the decryption with them, and then swap ther
// back.
QuicConnectionPeer::SwapCrypters(dest_conn, framer.framer());
if (!framer.ProcessPacket(*source_conn->encrypted_packets_[index])) {
// The framer will be unable to decrypt forward-secure packets sent after
// the handshake is complete. Don't treat them as handshake packets.
break;
}
QuicConnectionPeer::SwapCrypters(dest_conn, framer.framer());
dest_conn->OnDecryptedPacket(framer.last_decrypted_level());
if (dest_stream->handshake_protocol() == PROTOCOL_TLS1_3) {
// Try to process the packet with a framer that only has the NullDecrypter
// for decryption. If ProcessPacket succeeds, that means the packet was
// encrypted with the NullEncrypter. With the TLS handshaker in use, no
// packets should ever be encrypted with the NullEncrypter, instead
// they're encrypted with an obfuscation cipher based on QUIC version and
// connection ID.
ASSERT_FALSE(null_encryption_framer.ProcessPacket(
*source_conn->encrypted_packets_[index]))
<< "No TLS packets should be encrypted with the NullEncrypter";
}
// Since we're using QuicFramers separate from the connections to move
// packets, the QuicConnection never gets notified about what level the last
// packet was decrypted at. This is needed by TLS to know what encryption
// level was used for the data it's receiving, so we plumb this information
// from the SimpleQuicFramer back into the connection.
dest_conn->OnDecryptedPacket(framer.last_decrypted_level());
QuicConnectionPeer::SetCurrentPacket(
dest_conn, source_conn->encrypted_packets_[index]->AsStringPiece());
for (const auto& stream_frame : framer.stream_frames()) {
dest_stream->OnStreamFrame(*stream_frame);
}
for (const auto& crypto_frame : framer.crypto_frames()) {
dest_stream->OnCryptoFrame(*crypto_frame);
}
}
*inout_packet_index = index;
QuicConnectionPeer::SetCurrentPacket(dest_conn, QuicStringPiece(nullptr, 0));
}
CryptoHandshakeMessage GenerateDefaultInchoateCHLO(
const QuicClock* clock,
QuicTransportVersion version,
QuicCryptoServerConfig* crypto_config) {
// clang-format off
return CreateCHLO(
{{"PDMD", "X509"},
{"AEAD", "AESG"},
{"KEXS", "C255"},
{"PUBS", GenerateClientPublicValuesHex().c_str()},
{"NONC", GenerateClientNonceHex(clock, crypto_config).c_str()},
{"VER\0", QuicVersionLabelToString(
QuicVersionToQuicVersionLabel(version)).c_str()}},
kClientHelloMinimumSize);
// clang-format on
}
std::string GenerateClientNonceHex(const QuicClock* clock,
QuicCryptoServerConfig* crypto_config) {
QuicCryptoServerConfig::ConfigOptions old_config_options;
QuicCryptoServerConfig::ConfigOptions new_config_options;
old_config_options.id = "old-config-id";
crypto_config->AddDefaultConfig(QuicRandom::GetInstance(), clock,
old_config_options);
QuicServerConfigProtobuf primary_config = crypto_config->GenerateConfig(
QuicRandom::GetInstance(), clock, new_config_options);
primary_config.set_primary_time(clock->WallNow().ToUNIXSeconds());
std::unique_ptr<CryptoHandshakeMessage> msg =
crypto_config->AddConfig(std::move(primary_config), clock->WallNow());
QuicStringPiece orbit;
CHECK(msg->GetStringPiece(kORBT, &orbit));
std::string nonce;
CryptoUtils::GenerateNonce(clock->WallNow(), QuicRandom::GetInstance(), orbit,
&nonce);
return ("#" + QuicTextUtils::HexEncode(nonce));
}
std::string GenerateClientPublicValuesHex() {
char public_value[32];
memset(public_value, 42, sizeof(public_value));
return ("#" + QuicTextUtils::HexEncode(public_value, sizeof(public_value)));
}
void GenerateFullCHLO(const CryptoHandshakeMessage& inchoate_chlo,
QuicCryptoServerConfig* crypto_config,
QuicSocketAddress server_addr,
QuicSocketAddress client_addr,
QuicTransportVersion version,
const QuicClock* clock,
QuicReferenceCountedPointer<QuicSignedServerConfig> proof,
QuicCompressedCertsCache* compressed_certs_cache,
CryptoHandshakeMessage* out) {
// Pass a inchoate CHLO.
FullChloGenerator generator(crypto_config, server_addr, client_addr, clock,
proof, compressed_certs_cache, out);
crypto_config->ValidateClientHello(
inchoate_chlo, client_addr.host(), server_addr, version, clock, proof,
generator.GetValidateClientHelloCallback());
}
} // namespace crypto_test_utils
} // namespace test
} // namespace quic