// Copyright (c) 2011 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 #include "base/logging.h" #include "testing/gtest/include/gtest/gtest.h" namespace crypto { namespace { bool RunExchange(P224EncryptedKeyExchange* client, P224EncryptedKeyExchange* server) { for (;;) { std::string client_message, server_message; client_message = client->GetMessage(); server_message = server->GetMessage(); P224EncryptedKeyExchange::Result client_result, server_result; client_result = client->ProcessMessage(server_message); server_result = server->ProcessMessage(client_message); // Check that we never hit the case where only one succeeds. if ((client_result == P224EncryptedKeyExchange::kResultSuccess) ^ (server_result == P224EncryptedKeyExchange::kResultSuccess)) { CHECK(false) << "Parties differ on whether authentication was successful"; } if (client_result == P224EncryptedKeyExchange::kResultFailed || server_result == P224EncryptedKeyExchange::kResultFailed) { return false; } if (client_result == P224EncryptedKeyExchange::kResultSuccess && server_result == P224EncryptedKeyExchange::kResultSuccess) { return true; } CHECK_EQ(P224EncryptedKeyExchange::kResultPending, client_result); CHECK_EQ(P224EncryptedKeyExchange::kResultPending, server_result); } } const char kPassword[] = "foo"; } // namespace TEST(MutualAuth, CorrectAuth) { P224EncryptedKeyExchange client( P224EncryptedKeyExchange::kPeerTypeClient, kPassword); P224EncryptedKeyExchange server( P224EncryptedKeyExchange::kPeerTypeServer, kPassword); EXPECT_TRUE(RunExchange(&client, &server)); EXPECT_EQ(client.GetKey(), server.GetKey()); } TEST(MutualAuth, IncorrectPassword) { P224EncryptedKeyExchange client( P224EncryptedKeyExchange::kPeerTypeClient, kPassword); P224EncryptedKeyExchange server( P224EncryptedKeyExchange::kPeerTypeServer, "wrongpassword"); EXPECT_FALSE(RunExchange(&client, &server)); } TEST(MutualAuth, Fuzz) { static const unsigned kIterations = 40; for (unsigned i = 0; i < kIterations; i++) { P224EncryptedKeyExchange client( P224EncryptedKeyExchange::kPeerTypeClient, kPassword); P224EncryptedKeyExchange server( P224EncryptedKeyExchange::kPeerTypeServer, kPassword); // We'll only be testing small values of i, but we don't want that to bias // the test coverage. So we disperse the value of i by multiplying by the // FNV, 32-bit prime, producing a poor-man's PRNG. const uint32 rand = i * 16777619; for (unsigned round = 0;; round++) { std::string client_message, server_message; client_message = client.GetMessage(); server_message = server.GetMessage(); if ((rand & 1) == round) { const bool server_or_client = rand & 2; std::string* m = server_or_client ? &server_message : &client_message; if (rand & 4) { // Truncate *m = m->substr(0, (i >> 3) % m->size()); } else { // Corrupt const size_t bits = m->size() * 8; const size_t bit_to_corrupt = (rand >> 3) % bits; const_cast(m->data())[bit_to_corrupt / 8] ^= 1 << (bit_to_corrupt % 8); } } P224EncryptedKeyExchange::Result client_result, server_result; client_result = client.ProcessMessage(server_message); server_result = server.ProcessMessage(client_message); // If we have corrupted anything, we expect the authentication to fail, // although one side can succeed if we happen to corrupt the second round // message to the other. ASSERT_FALSE( client_result == P224EncryptedKeyExchange::kResultSuccess && server_result == P224EncryptedKeyExchange::kResultSuccess); if (client_result == P224EncryptedKeyExchange::kResultFailed || server_result == P224EncryptedKeyExchange::kResultFailed) { break; } ASSERT_EQ(P224EncryptedKeyExchange::kResultPending, client_result); ASSERT_EQ(P224EncryptedKeyExchange::kResultPending, server_result); } } } } // namespace crypto