src/crypto/ec_private_key_unittest.cc - cobalt - Git at Google

 // 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 "crypto/ec_private_key.h"

 #include <vector>

 #include "base/memory/scoped_ptr.h"
 #include "testing/gtest/include/gtest/gtest.h"

 #if defined(USE_OPENSSL)
 // Once ECPrivateKey is implemented for OpenSSL, remove this #if block.
 // TODO(mattm): When that happens, also add some exported keys from each to test
 // interop between NSS and OpenSSL.
 TEST(ECPrivateKeyUnitTest, OpenSSLStub) {
   scoped_ptr<crypto::ECPrivateKey> keypair1(
       crypto::ECPrivateKey::Create());
   ASSERT_FALSE(keypair1.get());
 }
 #else
 // Generate random private keys. Export, then re-import. We should get
 // back the same exact public key, and the private key should have the same
 // value and elliptic curve params.
 TEST(ECPrivateKeyUnitTest, InitRandomTest) {
   const std::string password1 = "";
   const std::string password2 = "test";

   scoped_ptr<crypto::ECPrivateKey> keypair1(
       crypto::ECPrivateKey::Create());
   scoped_ptr<crypto::ECPrivateKey> keypair2(
       crypto::ECPrivateKey::Create());
   ASSERT_TRUE(keypair1.get());
   ASSERT_TRUE(keypair2.get());

   std::vector<uint8> key1value;
   std::vector<uint8> key2value;
   std::vector<uint8> key1params;
   std::vector<uint8> key2params;
   EXPECT_TRUE(keypair1->ExportValue(&key1value));
   EXPECT_TRUE(keypair2->ExportValue(&key2value));
   EXPECT_TRUE(keypair1->ExportECParams(&key1params));
   EXPECT_TRUE(keypair2->ExportECParams(&key2params));

   std::vector<uint8> privkey1;
   std::vector<uint8> privkey2;
   std::vector<uint8> pubkey1;
   std::vector<uint8> pubkey2;
   ASSERT_TRUE(keypair1->ExportEncryptedPrivateKey(
       password1, 1, &privkey1));
   ASSERT_TRUE(keypair2->ExportEncryptedPrivateKey(
       password2, 1, &privkey2));
   EXPECT_TRUE(keypair1->ExportPublicKey(&pubkey1));
   EXPECT_TRUE(keypair2->ExportPublicKey(&pubkey2));

   scoped_ptr<crypto::ECPrivateKey> keypair3(
       crypto::ECPrivateKey::CreateFromEncryptedPrivateKeyInfo(
           password1, privkey1, pubkey1));
   scoped_ptr<crypto::ECPrivateKey> keypair4(
       crypto::ECPrivateKey::CreateFromEncryptedPrivateKeyInfo(
           password2, privkey2, pubkey2));
   ASSERT_TRUE(keypair3.get());
   ASSERT_TRUE(keypair4.get());

   std::vector<uint8> key3value;
   std::vector<uint8> key4value;
   std::vector<uint8> key3params;
   std::vector<uint8> key4params;
   EXPECT_TRUE(keypair3->ExportValue(&key3value));
   EXPECT_TRUE(keypair4->ExportValue(&key4value));
   EXPECT_TRUE(keypair3->ExportECParams(&key3params));
   EXPECT_TRUE(keypair4->ExportECParams(&key4params));

   EXPECT_EQ(key1value, key3value);
   EXPECT_EQ(key2value, key4value);
   EXPECT_EQ(key1params, key3params);
   EXPECT_EQ(key2params, key4params);

   std::vector<uint8> pubkey3;
   std::vector<uint8> pubkey4;
   EXPECT_TRUE(keypair3->ExportPublicKey(&pubkey3));
   EXPECT_TRUE(keypair4->ExportPublicKey(&pubkey4));

   EXPECT_EQ(pubkey1, pubkey3);
   EXPECT_EQ(pubkey2, pubkey4);
 }

 TEST(ECPrivateKeyUnitTest, BadPasswordTest) {
   const std::string password1 = "";
   const std::string password2 = "test";

   scoped_ptr<crypto::ECPrivateKey> keypair1(
       crypto::ECPrivateKey::Create());
   ASSERT_TRUE(keypair1.get());

   std::vector<uint8> privkey1;
   std::vector<uint8> pubkey1;
   ASSERT_TRUE(keypair1->ExportEncryptedPrivateKey(
       password1, 1, &privkey1));
   ASSERT_TRUE(keypair1->ExportPublicKey(&pubkey1));

   scoped_ptr<crypto::ECPrivateKey> keypair2(
       crypto::ECPrivateKey::CreateFromEncryptedPrivateKeyInfo(
           password2, privkey1, pubkey1));
   ASSERT_FALSE(keypair2.get());
 }
 #endif  // !defined(USE_OPENSSL)
	// 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 "crypto/ec_private_key.h"

	#include <vector>

	#include "base/memory/scoped_ptr.h"
	#include "testing/gtest/include/gtest/gtest.h"

	#if defined(USE_OPENSSL)
	// Once ECPrivateKey is implemented for OpenSSL, remove this #if block.
	// TODO(mattm): When that happens, also add some exported keys from each to test
	// interop between NSS and OpenSSL.
	TEST(ECPrivateKeyUnitTest, OpenSSLStub) {
	scoped_ptr<crypto::ECPrivateKey> keypair1(
	crypto::ECPrivateKey::Create());
	ASSERT_FALSE(keypair1.get());
	}
	#else
	// Generate random private keys. Export, then re-import. We should get
	// back the same exact public key, and the private key should have the same
	// value and elliptic curve params.
	TEST(ECPrivateKeyUnitTest, InitRandomTest) {
	const std::string password1 = "";
	const std::string password2 = "test";

	scoped_ptr<crypto::ECPrivateKey> keypair1(
	crypto::ECPrivateKey::Create());
	scoped_ptr<crypto::ECPrivateKey> keypair2(
	crypto::ECPrivateKey::Create());
	ASSERT_TRUE(keypair1.get());
	ASSERT_TRUE(keypair2.get());

	std::vector<uint8> key1value;
	std::vector<uint8> key2value;
	std::vector<uint8> key1params;
	std::vector<uint8> key2params;
	EXPECT_TRUE(keypair1->ExportValue(&key1value));
	EXPECT_TRUE(keypair2->ExportValue(&key2value));
	EXPECT_TRUE(keypair1->ExportECParams(&key1params));
	EXPECT_TRUE(keypair2->ExportECParams(&key2params));

	std::vector<uint8> privkey1;
	std::vector<uint8> privkey2;
	std::vector<uint8> pubkey1;
	std::vector<uint8> pubkey2;
	ASSERT_TRUE(keypair1->ExportEncryptedPrivateKey(
	password1, 1, &privkey1));
	ASSERT_TRUE(keypair2->ExportEncryptedPrivateKey(
	password2, 1, &privkey2));
	EXPECT_TRUE(keypair1->ExportPublicKey(&pubkey1));
	EXPECT_TRUE(keypair2->ExportPublicKey(&pubkey2));

	scoped_ptr<crypto::ECPrivateKey> keypair3(
	crypto::ECPrivateKey::CreateFromEncryptedPrivateKeyInfo(
	password1, privkey1, pubkey1));
	scoped_ptr<crypto::ECPrivateKey> keypair4(
	crypto::ECPrivateKey::CreateFromEncryptedPrivateKeyInfo(
	password2, privkey2, pubkey2));
	ASSERT_TRUE(keypair3.get());
	ASSERT_TRUE(keypair4.get());

	std::vector<uint8> key3value;
	std::vector<uint8> key4value;
	std::vector<uint8> key3params;
	std::vector<uint8> key4params;
	EXPECT_TRUE(keypair3->ExportValue(&key3value));
	EXPECT_TRUE(keypair4->ExportValue(&key4value));
	EXPECT_TRUE(keypair3->ExportECParams(&key3params));
	EXPECT_TRUE(keypair4->ExportECParams(&key4params));

	EXPECT_EQ(key1value, key3value);
	EXPECT_EQ(key2value, key4value);
	EXPECT_EQ(key1params, key3params);
	EXPECT_EQ(key2params, key4params);

	std::vector<uint8> pubkey3;
	std::vector<uint8> pubkey4;
	EXPECT_TRUE(keypair3->ExportPublicKey(&pubkey3));
	EXPECT_TRUE(keypair4->ExportPublicKey(&pubkey4));

	EXPECT_EQ(pubkey1, pubkey3);
	EXPECT_EQ(pubkey2, pubkey4);
	}

	TEST(ECPrivateKeyUnitTest, BadPasswordTest) {
	const std::string password1 = "";
	const std::string password2 = "test";

	scoped_ptr<crypto::ECPrivateKey> keypair1(
	crypto::ECPrivateKey::Create());
	ASSERT_TRUE(keypair1.get());

	std::vector<uint8> privkey1;
	std::vector<uint8> pubkey1;
	ASSERT_TRUE(keypair1->ExportEncryptedPrivateKey(
	password1, 1, &privkey1));
	ASSERT_TRUE(keypair1->ExportPublicKey(&pubkey1));

	scoped_ptr<crypto::ECPrivateKey> keypair2(
	crypto::ECPrivateKey::CreateFromEncryptedPrivateKeyInfo(
	password2, privkey1, pubkey1));
	ASSERT_FALSE(keypair2.get());
	}
	#endif // !defined(USE_OPENSSL)