quic/core/tls_server_handshaker_test.cc

// 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 <memory>
#include <utility>
#include <vector>

#include "absl/base/macros.h"
#include "absl/strings/string_view.h"
#include "quic/core/crypto/proof_source.h"
#include "quic/core/crypto/quic_random.h"
#include "quic/core/quic_crypto_client_stream.h"
#include "quic/core/quic_session.h"
#include "quic/core/quic_utils.h"
#include "quic/core/quic_versions.h"
#include "quic/core/tls_client_handshaker.h"
#include "quic/core/tls_server_handshaker.h"
#include "quic/platform/api/quic_flags.h"
#include "quic/platform/api/quic_logging.h"
#include "quic/platform/api/quic_test.h"
#include "quic/test_tools/crypto_test_utils.h"
#include "quic/test_tools/failing_proof_source.h"
#include "quic/test_tools/fake_proof_source.h"
#include "quic/test_tools/fake_proof_source_handle.h"
#include "quic/test_tools/quic_test_utils.h"
#include "quic/test_tools/simple_session_cache.h"
#include "quic/test_tools/test_ticket_crypter.h"

namespace quic {
class QuicConnection;
class QuicStream;
}  // namespace quic

using testing::_;
using testing::NiceMock;
using testing::Return;

namespace quic {
namespace test {

namespace {

const char kServerHostname[] = "test.example.com";
const uint16_t kServerPort = 443;

struct TestParams {
  ParsedQuicVersion version;
  bool disable_resumption;
};

// Used by ::testing::PrintToStringParamName().
std::string PrintToString(const TestParams& p) {
  return absl::StrCat(
      ParsedQuicVersionToString(p.version), "_",
      (p.disable_resumption ? "ResumptionDisabled" : "ResumptionEnabled"));
}

// Constructs test permutations.
std::vector<TestParams> GetTestParams() {
  std::vector<TestParams> params;
  for (const auto& version : AllSupportedVersionsWithTls()) {
    for (bool disable_resumption : {false, true}) {
      params.push_back(TestParams{version, disable_resumption});
    }
  }
  return params;
}

class TestTlsServerHandshaker : public TlsServerHandshaker {
 public:
  TestTlsServerHandshaker(QuicSession* session,
                          const QuicCryptoServerConfig* crypto_config)
      : TlsServerHandshaker(session, crypto_config),
        proof_source_(crypto_config->proof_source()) {
    ON_CALL(*this, MaybeCreateProofSourceHandle())
        .WillByDefault(testing::Invoke(
            this, &TestTlsServerHandshaker::RealMaybeCreateProofSourceHandle));
  }

  MOCK_METHOD(std::unique_ptr<ProofSourceHandle>,
              MaybeCreateProofSourceHandle,
              (),
              (override));

  void SetupProofSourceHandle(
      FakeProofSourceHandle::Action select_cert_action,
      FakeProofSourceHandle::Action compute_signature_action) {
    EXPECT_CALL(*this, MaybeCreateProofSourceHandle())
        .WillOnce(testing::Invoke(
            [this, select_cert_action, compute_signature_action]() {
              auto handle = std::make_unique<FakeProofSourceHandle>(
                  proof_source_, this, select_cert_action,
                  compute_signature_action);
              fake_proof_source_handle_ = handle.get();
              return handle;
            }));
  }

  FakeProofSourceHandle* fake_proof_source_handle() {
    return fake_proof_source_handle_;
  }

  using TlsServerHandshaker::expected_ssl_error;

 private:
  std::unique_ptr<ProofSourceHandle> RealMaybeCreateProofSourceHandle() {
    return TlsServerHandshaker::MaybeCreateProofSourceHandle();
  }

  // Owned by TlsServerHandshaker.
  FakeProofSourceHandle* fake_proof_source_handle_ = nullptr;
  ProofSource* proof_source_ = nullptr;
};

class TlsServerHandshakerTestSession : public TestQuicSpdyServerSession {
 public:
  using TestQuicSpdyServerSession::TestQuicSpdyServerSession;

  std::unique_ptr<QuicCryptoServerStreamBase> CreateQuicCryptoServerStream(
      const QuicCryptoServerConfig* crypto_config,
      QuicCompressedCertsCache* /*compressed_certs_cache*/) override {
    if (connection()->version().handshake_protocol == PROTOCOL_TLS1_3) {
      return std::make_unique<NiceMock<TestTlsServerHandshaker>>(this,
                                                                 crypto_config);
    }

    QUICHE_CHECK(false) << "Unsupported handshake protocol: "
                        << connection()->version().handshake_protocol;
    return nullptr;
  }
};

class TlsServerHandshakerTest : public QuicTestWithParam<TestParams> {
 public:
  TlsServerHandshakerTest()
      : server_compressed_certs_cache_(
            QuicCompressedCertsCache::kQuicCompressedCertsCacheSize),
        server_id_(kServerHostname, kServerPort, false),
        supported_versions_({GetParam().version}) {
    SetQuicRestartFlag(quic_enable_zero_rtt_for_tls_v2, true);
    SetQuicFlag(FLAGS_quic_disable_server_tls_resumption,
                GetParam().disable_resumption);
    client_crypto_config_ = std::make_unique<QuicCryptoClientConfig>(
        crypto_test_utils::ProofVerifierForTesting(),
        std::make_unique<test::SimpleSessionCache>());
    InitializeServerConfig();
    InitializeServer();
    InitializeFakeClient();
  }

  ~TlsServerHandshakerTest() override {
    // Ensure that anything that might reference |helpers_| is destroyed before
    // |helpers_| is destroyed.
    server_session_.reset();
    client_session_.reset();
    helpers_.clear();
    alarm_factories_.clear();
  }

  void InitializeServerConfig() {
    auto ticket_crypter = std::make_unique<TestTicketCrypter>();
    ticket_crypter_ = ticket_crypter.get();
    auto proof_source = std::make_unique<FakeProofSource>();
    proof_source_ = proof_source.get();
    proof_source_->SetTicketCrypter(std::move(ticket_crypter));
    server_crypto_config_ = std::make_unique<QuicCryptoServerConfig>(
        QuicCryptoServerConfig::TESTING, QuicRandom::GetInstance(),
        std::move(proof_source), KeyExchangeSource::Default());
  }

  void InitializeServerConfigWithFailingProofSource() {
    server_crypto_config_ = std::make_unique<QuicCryptoServerConfig>(
        QuicCryptoServerConfig::TESTING, QuicRandom::GetInstance(),
        std::make_unique<FailingProofSource>(), KeyExchangeSource::Default());
  }

  void CreateTlsServerHandshakerTestSession(MockQuicConnectionHelper* helper,
                                            MockAlarmFactory* alarm_factory) {
    server_connection_ = new PacketSavingConnection(
        helper, alarm_factory, Perspective::IS_SERVER,
        ParsedVersionOfIndex(supported_versions_, 0));

    TlsServerHandshakerTestSession* server_session =
        new TlsServerHandshakerTestSession(
            server_connection_, DefaultQuicConfig(), supported_versions_,
            server_crypto_config_.get(), &server_compressed_certs_cache_);
    server_session->Initialize();

    // We advance the clock initially because the default time is zero and the
    // strike register worries that we've just overflowed a uint32_t time.
    server_connection_->AdvanceTime(QuicTime::Delta::FromSeconds(100000));

    QUICHE_CHECK(server_session);
    server_session_.reset(server_session);
  }

  void InitializeServerWithFakeProofSourceHandle() {
    helpers_.push_back(std::make_unique<NiceMock<MockQuicConnectionHelper>>());
    alarm_factories_.push_back(std::make_unique<MockAlarmFactory>());
    CreateTlsServerHandshakerTestSession(helpers_.back().get(),
                                         alarm_factories_.back().get());
    server_handshaker_ = static_cast<NiceMock<TestTlsServerHandshaker>*>(
        server_session_->GetMutableCryptoStream());
    EXPECT_CALL(*server_session_->helper(), CanAcceptClientHello(_, _, _, _, _))
        .Times(testing::AnyNumber());
    EXPECT_CALL(*server_session_, SelectAlpn(_))
        .WillRepeatedly([this](const std::vector<absl::string_view>& alpns) {
          return std::find(
              alpns.cbegin(), alpns.cend(),
              AlpnForVersion(server_session_->connection()->version()));
        });
    crypto_test_utils::SetupCryptoServerConfigForTest(
        server_connection_->clock(), server_connection_->random_generator(),
        server_crypto_config_.get());
  }

  // Initializes the crypto server stream state for testing.  May be
  // called multiple times.
  void InitializeServer() {
    TestQuicSpdyServerSession* server_session = nullptr;
    helpers_.push_back(std::make_unique<NiceMock<MockQuicConnectionHelper>>());
    alarm_factories_.push_back(std::make_unique<MockAlarmFactory>());
    CreateServerSessionForTest(
        server_id_, QuicTime::Delta::FromSeconds(100000), supported_versions_,
        helpers_.back().get(), alarm_factories_.back().get(),
        server_crypto_config_.get(), &server_compressed_certs_cache_,
        &server_connection_, &server_session);
    QUICHE_CHECK(server_session);
    server_session_.reset(server_session);
    server_handshaker_ = nullptr;
    EXPECT_CALL(*server_session_->helper(), CanAcceptClientHello(_, _, _, _, _))
        .Times(testing::AnyNumber());
    EXPECT_CALL(*server_session_, SelectAlpn(_))
        .WillRepeatedly([this](const std::vector<absl::string_view>& alpns) {
          return std::find(
              alpns.cbegin(), alpns.cend(),
              AlpnForVersion(server_session_->connection()->version()));
        });
    crypto_test_utils::SetupCryptoServerConfigForTest(
        server_connection_->clock(), server_connection_->random_generator(),
        server_crypto_config_.get());
  }

  QuicCryptoServerStreamBase* server_stream() {
    return server_session_->GetMutableCryptoStream();
  }

  QuicCryptoClientStream* client_stream() {
    return client_session_->GetMutableCryptoStream();
  }

  // Initializes a fake client, and all its associated state, for
  // testing.  May be called multiple times.
  void InitializeFakeClient() {
    TestQuicSpdyClientSession* client_session = nullptr;
    helpers_.push_back(std::make_unique<NiceMock<MockQuicConnectionHelper>>());
    alarm_factories_.push_back(std::make_unique<MockAlarmFactory>());
    CreateClientSessionForTest(
        server_id_, QuicTime::Delta::FromSeconds(100000), supported_versions_,
        helpers_.back().get(), alarm_factories_.back().get(),
        client_crypto_config_.get(), &client_connection_, &client_session);
    const std::string default_alpn =
        AlpnForVersion(client_connection_->version());
    ON_CALL(*client_session, GetAlpnsToOffer())
        .WillByDefault(Return(std::vector<std::string>({default_alpn})));
    QUICHE_CHECK(client_session);
    client_session_.reset(client_session);
    moved_messages_counts_ = {0, 0};
  }

  void CompleteCryptoHandshake() {
    while (!client_stream()->one_rtt_keys_available() ||
           !server_stream()->one_rtt_keys_available()) {
      auto previous_moved_messages_counts = moved_messages_counts_;
      AdvanceHandshakeWithFakeClient();
      // Check that the handshake has made forward progress
      ASSERT_NE(previous_moved_messages_counts, moved_messages_counts_);
    }
  }

  // Performs a single round of handshake message-exchange between the
  // client and server.
  void AdvanceHandshakeWithFakeClient() {
    QUICHE_CHECK(server_connection_);
    QUICHE_CHECK(client_session_ != nullptr);

    EXPECT_CALL(*client_session_, OnProofValid(_)).Times(testing::AnyNumber());
    EXPECT_CALL(*client_session_, OnProofVerifyDetailsAvailable(_))
        .Times(testing::AnyNumber());
    EXPECT_CALL(*client_connection_, OnCanWrite()).Times(testing::AnyNumber());
    EXPECT_CALL(*server_connection_, OnCanWrite()).Times(testing::AnyNumber());
    // Call CryptoConnect if we haven't moved any client messages yet.
    if (moved_messages_counts_.first == 0) {
      client_stream()->CryptoConnect();
    }
    moved_messages_counts_ = crypto_test_utils::AdvanceHandshake(
        client_connection_, client_stream(), moved_messages_counts_.first,
        server_connection_, server_stream(), moved_messages_counts_.second);
  }

  void ExpectHandshakeSuccessful() {
    EXPECT_TRUE(client_stream()->one_rtt_keys_available());
    EXPECT_TRUE(client_stream()->encryption_established());
    EXPECT_TRUE(server_stream()->one_rtt_keys_available());
    EXPECT_TRUE(server_stream()->encryption_established());
    EXPECT_EQ(HANDSHAKE_COMPLETE, client_stream()->GetHandshakeState());
    EXPECT_EQ(HANDSHAKE_CONFIRMED, server_stream()->GetHandshakeState());

    const auto& client_crypto_params =
        client_stream()->crypto_negotiated_params();
    const auto& server_crypto_params =
        server_stream()->crypto_negotiated_params();
    // The TLS params should be filled in on the client.
    EXPECT_NE(0, client_crypto_params.cipher_suite);
    EXPECT_NE(0, client_crypto_params.key_exchange_group);
    EXPECT_NE(0, client_crypto_params.peer_signature_algorithm);

    // The cipher suite and key exchange group should match on the client and
    // server.
    EXPECT_EQ(client_crypto_params.cipher_suite,
              server_crypto_params.cipher_suite);
    EXPECT_EQ(client_crypto_params.key_exchange_group,
              server_crypto_params.key_exchange_group);
    // We don't support client certs on the server (yet), so the server
    // shouldn't have a peer signature algorithm to report.
    EXPECT_EQ(0, server_crypto_params.peer_signature_algorithm);
  }

 protected:
  // Every connection gets its own MockQuicConnectionHelper and
  // MockAlarmFactory, tracked separately from the server and client state so
  // their lifetimes persist through the whole test.
  std::vector<std::unique_ptr<MockQuicConnectionHelper>> helpers_;
  std::vector<std::unique_ptr<MockAlarmFactory>> alarm_factories_;

  // Server state.
  PacketSavingConnection* server_connection_;
  std::unique_ptr<TestQuicSpdyServerSession> server_session_;
  // Only set when initialized with InitializeServerWithFakeProofSourceHandle.
  NiceMock<TestTlsServerHandshaker>* server_handshaker_ = nullptr;
  TestTicketCrypter* ticket_crypter_;  // owned by proof_source_
  FakeProofSource* proof_source_;      // owned by server_crypto_config_
  std::unique_ptr<QuicCryptoServerConfig> server_crypto_config_;
  QuicCompressedCertsCache server_compressed_certs_cache_;
  QuicServerId server_id_;

  // Client state.
  PacketSavingConnection* client_connection_;
  std::unique_ptr<QuicCryptoClientConfig> client_crypto_config_;
  std::unique_ptr<TestQuicSpdyClientSession> client_session_;

  crypto_test_utils::FakeClientOptions client_options_;
  // How many handshake messages have been moved from client to server and
  // server to client.
  std::pair<size_t, size_t> moved_messages_counts_ = {0, 0};

  // Which QUIC versions the client and server support.
  ParsedQuicVersionVector supported_versions_;
};

INSTANTIATE_TEST_SUITE_P(TlsServerHandshakerTests,
                         TlsServerHandshakerTest,
                         ::testing::ValuesIn(GetTestParams()),
                         ::testing::PrintToStringParamName());

TEST_P(TlsServerHandshakerTest, NotInitiallyConected) {
  EXPECT_FALSE(server_stream()->encryption_established());
  EXPECT_FALSE(server_stream()->one_rtt_keys_available());
}

TEST_P(TlsServerHandshakerTest, ConnectedAfterTlsHandshake) {
  CompleteCryptoHandshake();
  EXPECT_EQ(PROTOCOL_TLS1_3, server_stream()->handshake_protocol());
  ExpectHandshakeSuccessful();
}

TEST_P(TlsServerHandshakerTest, HandshakeWithAsyncSelectCertSuccess) {
  if (!(GetQuicReloadableFlag(quic_tls_use_early_select_cert) &&
        GetQuicReloadableFlag(quic_tls_use_per_handshaker_proof_source))) {
    return;
  }

  InitializeServerWithFakeProofSourceHandle();
  server_handshaker_->SetupProofSourceHandle(
      /*select_cert_action=*/FakeProofSourceHandle::Action::DELEGATE_ASYNC,
      /*compute_signature_action=*/FakeProofSourceHandle::Action::
          DELEGATE_SYNC);

  EXPECT_CALL(*client_connection_, CloseConnection(_, _, _)).Times(0);
  EXPECT_CALL(*server_connection_, CloseConnection(_, _, _)).Times(0);

  // Start handshake.
  AdvanceHandshakeWithFakeClient();

  ASSERT_TRUE(
      server_handshaker_->fake_proof_source_handle()->HasPendingOperation());
  server_handshaker_->fake_proof_source_handle()->CompletePendingOperation();

  CompleteCryptoHandshake();

  ExpectHandshakeSuccessful();
}

TEST_P(TlsServerHandshakerTest, HandshakeWithAsyncSelectCertFailure) {
  if (!(GetQuicReloadableFlag(quic_tls_use_early_select_cert) &&
        GetQuicReloadableFlag(quic_tls_use_per_handshaker_proof_source))) {
    return;
  }

  InitializeServerWithFakeProofSourceHandle();
  server_handshaker_->SetupProofSourceHandle(
      /*select_cert_action=*/FakeProofSourceHandle::Action::FAIL_ASYNC,
      /*compute_signature_action=*/FakeProofSourceHandle::Action::
          DELEGATE_SYNC);

  // Start handshake.
  AdvanceHandshakeWithFakeClient();

  ASSERT_TRUE(
      server_handshaker_->fake_proof_source_handle()->HasPendingOperation());
  server_handshaker_->fake_proof_source_handle()->CompletePendingOperation();

  // Check that the server didn't send any handshake messages, because it failed
  // to handshake.
  EXPECT_EQ(moved_messages_counts_.second, 0u);
}

TEST_P(TlsServerHandshakerTest, HandshakeWithAsyncSelectCertAndSignature) {
  if (!(GetQuicReloadableFlag(quic_tls_use_early_select_cert) &&
        GetQuicReloadableFlag(quic_tls_use_per_handshaker_proof_source))) {
    return;
  }

  InitializeServerWithFakeProofSourceHandle();
  server_handshaker_->SetupProofSourceHandle(
      /*select_cert_action=*/FakeProofSourceHandle::Action::DELEGATE_ASYNC,
      /*compute_signature_action=*/FakeProofSourceHandle::Action::
          DELEGATE_ASYNC);

  EXPECT_CALL(*client_connection_, CloseConnection(_, _, _)).Times(0);
  EXPECT_CALL(*server_connection_, CloseConnection(_, _, _)).Times(0);

  // Start handshake.
  AdvanceHandshakeWithFakeClient();

  // A select cert operation is now pending.
  ASSERT_TRUE(
      server_handshaker_->fake_proof_source_handle()->HasPendingOperation());
  EXPECT_EQ(server_handshaker_->expected_ssl_error(),
            SSL_ERROR_PENDING_CERTIFICATE);

  // Complete the pending select cert. It should advance the handshake to
  // compute a signature, which will also be saved as a pending operation.
  server_handshaker_->fake_proof_source_handle()->CompletePendingOperation();

  // A compute signature operation is now pending.
  ASSERT_TRUE(
      server_handshaker_->fake_proof_source_handle()->HasPendingOperation());
  EXPECT_EQ(server_handshaker_->expected_ssl_error(),
            SSL_ERROR_WANT_PRIVATE_KEY_OPERATION);

  server_handshaker_->fake_proof_source_handle()->CompletePendingOperation();

  CompleteCryptoHandshake();

  ExpectHandshakeSuccessful();
}

TEST_P(TlsServerHandshakerTest, HandshakeWithAsyncSignature) {
  EXPECT_CALL(*client_connection_, CloseConnection(_, _, _)).Times(0);
  EXPECT_CALL(*server_connection_, CloseConnection(_, _, _)).Times(0);
  // Enable FakeProofSource to capture call to ComputeTlsSignature and run it
  // asynchronously.
  proof_source_->Activate();

  // Start handshake.
  AdvanceHandshakeWithFakeClient();

  ASSERT_EQ(proof_source_->NumPendingCallbacks(), 1);
  proof_source_->InvokePendingCallback(0);

  CompleteCryptoHandshake();

  ExpectHandshakeSuccessful();
}

TEST_P(TlsServerHandshakerTest, CancelPendingSelectCert) {
  if (!(GetQuicReloadableFlag(quic_tls_use_early_select_cert) &&
        GetQuicReloadableFlag(quic_tls_use_per_handshaker_proof_source))) {
    return;
  }

  InitializeServerWithFakeProofSourceHandle();
  server_handshaker_->SetupProofSourceHandle(
      /*select_cert_action=*/FakeProofSourceHandle::Action::DELEGATE_ASYNC,
      /*compute_signature_action=*/FakeProofSourceHandle::Action::
          DELEGATE_SYNC);

  EXPECT_CALL(*client_connection_, CloseConnection(_, _, _)).Times(0);
  EXPECT_CALL(*server_connection_, CloseConnection(_, _, _)).Times(0);

  // Start handshake.
  AdvanceHandshakeWithFakeClient();

  ASSERT_TRUE(
      server_handshaker_->fake_proof_source_handle()->HasPendingOperation());
  server_handshaker_->CancelOutstandingCallbacks();
  ASSERT_FALSE(
      server_handshaker_->fake_proof_source_handle()->HasPendingOperation());
  // CompletePendingOperation should be noop.
  server_handshaker_->fake_proof_source_handle()->CompletePendingOperation();
}

TEST_P(TlsServerHandshakerTest, CancelPendingSignature) {
  EXPECT_CALL(*client_connection_, CloseConnection(_, _, _)).Times(0);
  EXPECT_CALL(*server_connection_, CloseConnection(_, _, _)).Times(0);
  // Enable FakeProofSource to capture call to ComputeTlsSignature and run it
  // asynchronously.
  proof_source_->Activate();

  // Start handshake.
  AdvanceHandshakeWithFakeClient();

  ASSERT_EQ(proof_source_->NumPendingCallbacks(), 1);
  server_session_ = nullptr;

  proof_source_->InvokePendingCallback(0);
}

TEST_P(TlsServerHandshakerTest, ExtractSNI) {
  CompleteCryptoHandshake();
  ExpectHandshakeSuccessful();

  EXPECT_EQ(server_stream()->crypto_negotiated_params().sni,
            "test.example.com");
}

TEST_P(TlsServerHandshakerTest, ConnectionClosedOnTlsError) {
  if (GetQuicReloadableFlag(quic_send_tls_crypto_error_code)) {
    EXPECT_CALL(*server_connection_,
                CloseConnection(QUIC_HANDSHAKE_FAILED, _, _, _));
  } else {
    EXPECT_CALL(*server_connection_,
                CloseConnection(QUIC_HANDSHAKE_FAILED, _, _));
  }

  // Send a zero-length ClientHello from client to server.
  char bogus_handshake_message[] = {
      // Handshake struct (RFC 8446 appendix B.3)
      1,        // HandshakeType client_hello
      0, 0, 0,  // uint24 length
  };
  server_stream()->crypto_message_parser()->ProcessInput(
      absl::string_view(bogus_handshake_message,
                        ABSL_ARRAYSIZE(bogus_handshake_message)),
      ENCRYPTION_INITIAL);

  EXPECT_FALSE(server_stream()->one_rtt_keys_available());
}

TEST_P(TlsServerHandshakerTest, ClientSendingBadALPN) {
  const std::string kTestBadClientAlpn = "bad-client-alpn";
  EXPECT_CALL(*client_session_, GetAlpnsToOffer())
      .WillOnce(Return(std::vector<std::string>({kTestBadClientAlpn})));
  if (GetQuicReloadableFlag(quic_send_tls_crypto_error_code)) {
    EXPECT_CALL(
        *server_connection_,
        CloseConnection(
            QUIC_HANDSHAKE_FAILED,
            static_cast<QuicIetfTransportErrorCodes>(CRYPTO_ERROR_FIRST + 120),
            "TLS handshake failure (ENCRYPTION_INITIAL) 120: "
            "no application protocol",
            _));
  } else {
    EXPECT_CALL(
        *server_connection_,
        CloseConnection(QUIC_HANDSHAKE_FAILED,
                        "TLS handshake failure (ENCRYPTION_INITIAL) 120: "
                        "no application protocol",
                        _));
  }

  AdvanceHandshakeWithFakeClient();

  EXPECT_FALSE(client_stream()->one_rtt_keys_available());
  EXPECT_FALSE(client_stream()->encryption_established());
  EXPECT_FALSE(server_stream()->one_rtt_keys_available());
  EXPECT_FALSE(server_stream()->encryption_established());
}

TEST_P(TlsServerHandshakerTest, CustomALPNNegotiation) {
  EXPECT_CALL(*client_connection_, CloseConnection(_, _, _)).Times(0);
  EXPECT_CALL(*server_connection_, CloseConnection(_, _, _)).Times(0);

  const std::string kTestAlpn = "A Custom ALPN Value";
  const std::vector<std::string> kTestAlpns(
      {"foo", "bar", kTestAlpn, "something else"});
  EXPECT_CALL(*client_session_, GetAlpnsToOffer())
      .WillRepeatedly(Return(kTestAlpns));
  EXPECT_CALL(*server_session_, SelectAlpn(_))
      .WillOnce(
          [kTestAlpn, kTestAlpns](const std::vector<absl::string_view>& alpns) {
            EXPECT_THAT(alpns, testing::ElementsAreArray(kTestAlpns));
            return std::find(alpns.cbegin(), alpns.cend(), kTestAlpn);
          });
  EXPECT_CALL(*client_session_, OnAlpnSelected(absl::string_view(kTestAlpn)));
  EXPECT_CALL(*server_session_, OnAlpnSelected(absl::string_view(kTestAlpn)));

  CompleteCryptoHandshake();
  ExpectHandshakeSuccessful();
}

TEST_P(TlsServerHandshakerTest, RejectInvalidSNI) {
  server_id_ = QuicServerId("invalid!.example.com", kServerPort, false);
  InitializeFakeClient();
  static_cast<TlsClientHandshaker*>(
      QuicCryptoClientStreamPeer::GetHandshaker(client_stream()))
      ->AllowInvalidSNIForTests();

  // Run the handshake and expect it to fail.
  AdvanceHandshakeWithFakeClient();
  EXPECT_FALSE(server_stream()->encryption_established());
  EXPECT_FALSE(server_stream()->one_rtt_keys_available());
}

TEST_P(TlsServerHandshakerTest, Resumption) {
  // Do the first handshake
  InitializeFakeClient();
  CompleteCryptoHandshake();
  ExpectHandshakeSuccessful();
  EXPECT_FALSE(client_stream()->IsResumption());
  EXPECT_FALSE(server_stream()->IsResumption());
  EXPECT_FALSE(server_stream()->ResumptionAttempted());

  // Now do another handshake
  InitializeServer();
  InitializeFakeClient();
  CompleteCryptoHandshake();
  ExpectHandshakeSuccessful();
  EXPECT_NE(client_stream()->IsResumption(), GetParam().disable_resumption);
  EXPECT_NE(server_stream()->IsResumption(), GetParam().disable_resumption);
  EXPECT_NE(server_stream()->ResumptionAttempted(),
            GetParam().disable_resumption);
}

TEST_P(TlsServerHandshakerTest, ResumptionWithAsyncDecryptCallback) {
  // Do the first handshake
  InitializeFakeClient();
  CompleteCryptoHandshake();
  ExpectHandshakeSuccessful();

  ticket_crypter_->SetRunCallbacksAsync(true);
  // Now do another handshake
  InitializeServer();
  InitializeFakeClient();

  AdvanceHandshakeWithFakeClient();
  if (GetParam().disable_resumption) {
    ASSERT_EQ(ticket_crypter_->NumPendingCallbacks(), 0u);
    return;
  }
  // Test that the DecryptCallback will be run asynchronously, and then run it.
  ASSERT_EQ(ticket_crypter_->NumPendingCallbacks(), 1u);
  ticket_crypter_->RunPendingCallback(0);

  CompleteCryptoHandshake();
  ExpectHandshakeSuccessful();
  EXPECT_TRUE(client_stream()->IsResumption());
  EXPECT_TRUE(server_stream()->IsResumption());
  EXPECT_TRUE(server_stream()->ResumptionAttempted());
}

TEST_P(TlsServerHandshakerTest, ResumptionWithFailingDecryptCallback) {
  if (GetParam().disable_resumption) {
    return;
  }

  // Do the first handshake
  InitializeFakeClient();
  CompleteCryptoHandshake();
  ExpectHandshakeSuccessful();

  ticket_crypter_->set_fail_decrypt(true);
  // Now do another handshake
  InitializeServer();
  InitializeFakeClient();
  CompleteCryptoHandshake();
  ExpectHandshakeSuccessful();
  EXPECT_FALSE(client_stream()->IsResumption());
  EXPECT_FALSE(server_stream()->IsResumption());
  EXPECT_TRUE(server_stream()->ResumptionAttempted());
}

TEST_P(TlsServerHandshakerTest, ResumptionWithFailingAsyncDecryptCallback) {
  if (GetParam().disable_resumption) {
    return;
  }

  // Do the first handshake
  InitializeFakeClient();
  CompleteCryptoHandshake();
  ExpectHandshakeSuccessful();

  ticket_crypter_->set_fail_decrypt(true);
  ticket_crypter_->SetRunCallbacksAsync(true);
  // Now do another handshake
  InitializeServer();
  InitializeFakeClient();

  AdvanceHandshakeWithFakeClient();
  // Test that the DecryptCallback will be run asynchronously, and then run it.
  ASSERT_EQ(ticket_crypter_->NumPendingCallbacks(), 1u);
  ticket_crypter_->RunPendingCallback(0);

  CompleteCryptoHandshake();
  ExpectHandshakeSuccessful();
  EXPECT_FALSE(client_stream()->IsResumption());
  EXPECT_FALSE(server_stream()->IsResumption());
  EXPECT_TRUE(server_stream()->ResumptionAttempted());
}

TEST_P(TlsServerHandshakerTest, HandshakeFailsWithFailingProofSource) {
  InitializeServerConfigWithFailingProofSource();
  InitializeServer();
  InitializeFakeClient();

  // Attempt handshake.
  AdvanceHandshakeWithFakeClient();
  // Check that the server didn't send any handshake messages, because it failed
  // to handshake.
  EXPECT_EQ(moved_messages_counts_.second, 0u);
}

TEST_P(TlsServerHandshakerTest, ZeroRttResumption) {
  std::vector<uint8_t> application_state = {0, 1, 2, 3};

  // Do the first handshake
  server_stream()->SetServerApplicationStateForResumption(
      std::make_unique<ApplicationState>(application_state));
  InitializeFakeClient();
  CompleteCryptoHandshake();
  ExpectHandshakeSuccessful();
  EXPECT_FALSE(client_stream()->IsResumption());
  EXPECT_FALSE(server_stream()->IsZeroRtt());

  // Now do another handshake
  InitializeServer();
  server_stream()->SetServerApplicationStateForResumption(
      std::make_unique<ApplicationState>(application_state));
  InitializeFakeClient();
  CompleteCryptoHandshake();
  ExpectHandshakeSuccessful();
  EXPECT_NE(client_stream()->IsResumption(), GetParam().disable_resumption);
  EXPECT_NE(server_stream()->IsZeroRtt(), GetParam().disable_resumption);
}

TEST_P(TlsServerHandshakerTest, ZeroRttRejectOnApplicationStateChange) {
  std::vector<uint8_t> original_application_state = {1, 2};
  std::vector<uint8_t> new_application_state = {3, 4};

  // Do the first handshake
  server_stream()->SetServerApplicationStateForResumption(
      std::make_unique<ApplicationState>(original_application_state));
  InitializeFakeClient();
  CompleteCryptoHandshake();
  ExpectHandshakeSuccessful();
  EXPECT_FALSE(client_stream()->IsResumption());
  EXPECT_FALSE(server_stream()->IsZeroRtt());

  // Do another handshake, but change the application state
  InitializeServer();
  server_stream()->SetServerApplicationStateForResumption(
      std::make_unique<ApplicationState>(new_application_state));
  InitializeFakeClient();
  CompleteCryptoHandshake();
  ExpectHandshakeSuccessful();
  EXPECT_NE(client_stream()->IsResumption(), GetParam().disable_resumption);
  EXPECT_FALSE(server_stream()->IsZeroRtt());
}

}  // namespace
}  // namespace test
}  // namespace quic