attestation/common/crypto_utility_impl_test.cc - mirrors/cros/chromiumos/platform2 - Git at Google

 // Copyright 2015 The Chromium OS 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 <string>
 #include <vector>

 #include <base/check.h>
 #include <base/logging.h>
 #include <base/strings/string_number_conversions.h>
 #include <gmock/gmock.h>
 #include <gtest/gtest.h>
 #include <openssl/objects.h>

 #include "attestation/common/crypto_utility_impl.h"
 #include "attestation/common/mock_tpm_utility.h"

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

 namespace {

 const char kValidPublicKeyHex[] =
     "3082010A0282010100"
     "961037BC12D2A298BEBF06B2D5F8C9B64B832A2237F8CF27D5F96407A6041A4D"
     "AD383CB5F88E625F412E8ACD5E9D69DF0F4FA81FCE7955829A38366CBBA5A2B1"
     "CE3B48C14B59E9F094B51F0A39155874C8DE18A0C299EBF7A88114F806BE4F25"
     "3C29A509B10E4B19E31675AFE3B2DA77077D94F43D8CE61C205781ED04D183B4"
     "C349F61B1956C64B5398A3A98FAFF17D1B3D9120C832763EDFC8F4137F6EFBEF"
     "46D8F6DE03BD00E49DEF987C10BDD5B6F8758B6A855C23C982DDA14D8F0F2B74"
     "E6DEFA7EEE5A6FC717EB0FF103CB8049F693A2C8A5039EF1F5C025DC44BD8435"
     "E8D8375DADE00E0C0F5C196E04B8483CC98B1D5B03DCD7E0048B2AB343FFC11F"
     "0203"
     "010001";

 const char kValidModulusHex[] =
     "961037BC12D2A298BEBF06B2D5F8C9B64B832A2237F8CF27D5F96407A6041A4D"
     "AD383CB5F88E625F412E8ACD5E9D69DF0F4FA81FCE7955829A38366CBBA5A2B1"
     "CE3B48C14B59E9F094B51F0A39155874C8DE18A0C299EBF7A88114F806BE4F25"
     "3C29A509B10E4B19E31675AFE3B2DA77077D94F43D8CE61C205781ED04D183B4"
     "C349F61B1956C64B5398A3A98FAFF17D1B3D9120C832763EDFC8F4137F6EFBEF"
     "46D8F6DE03BD00E49DEF987C10BDD5B6F8758B6A855C23C982DDA14D8F0F2B74"
     "E6DEFA7EEE5A6FC717EB0FF103CB8049F693A2C8A5039EF1F5C025DC44BD8435"
     "E8D8375DADE00E0C0F5C196E04B8483CC98B1D5B03DCD7E0048B2AB343FFC11F";

 constexpr char kSelfSignedCertDerHex[] =
     "308201fd308201a3a00302010202147b54cc22c8b391d4f8da07d97dc1e48b94be1442300a"
     "06082a8648ce3d0403023044310b300906035504030c025457310b30090603550406130254"
     "573113301106035504080c0a4e6577205461697065693113301106035504070c0a4e657720"
     "546169706569301e170d3231303531343135303132345a170d323230353134313530313234"
     "5a3044310b300906035504030c025457310b30090603550406130254573113301106035504"
     "080c0a4e6577205461697065693113301106035504070c0a4e657720546169706569305930"
     "1306072a8648ce3d020106082a8648ce3d030107034200044ebf9113fcb118d4b2ac828f73"
     "ec374e2ca4e2983d791b3f846a4ab20a340710f84aae65c858bb26faa59a3baec969f573ae"
     "ae435c40c8c4fdada7a87043eb35a3733071301d0603551d0e041604145a6b9f9f94437d3f"
     "df85fb0cebc7a90d28f03f60301f0603551d230418301680145a6b9f9f94437d3fdf85fb0c"
     "ebc7a90d28f03f60300e0603551d0f0101ff0404030202a4301f0603551d11041830168214"
     "746573742e63657274696669636174652e636f6d300a06082a8648ce3d0403020348003045"
     "02204f96089130341b6545f4c2ea7cf34b8e60d187c39de18b227dcc5f7fd985b81c022100"
     "a661c5790d1677f02f2a073f4396d63a24add9a0f650e5ff5f926c8ef67342ee";
 constexpr char kSelfSignedPublikKeyDerHex[] =
     "3059301306072a8648ce3d020106082a8648ce3d030107034200044ebf9113fcb118d4b2ac"
     "828f73ec374e2ca4e2983d791b3f846a4ab20a340710f84aae65c858bb26faa59a3baec969"
     "f573aeae435c40c8c4fdada7a87043eb35";
 constexpr char kMismatchedPublicKeyDerHex[] =
     "3059301306072a8648ce3d020106082a8648ce3d03010703420004c84758541dd419adcfec"
     "8e9868ba4b59755a7c1e3bcf892d11e7bd0afe9714de3043063afe9face5b5d53ebcabc3de"
     "7df2a67726fde0a7f1f4c1ed070e942e92";

 std::string HexDecode(const std::string hex) {
   std::vector<uint8_t> output;
   CHECK(base::HexStringToBytes(hex, &output));
   return std::string(reinterpret_cast<char*>(output.data()), output.size());
 }

 }  // namespace

 namespace attestation {

 class CryptoUtilityImplTest : public testing::Test {
  public:
   ~CryptoUtilityImplTest() override = default;
   void SetUp() override {
     crypto_utility_.reset(new CryptoUtilityImpl(&mock_tpm_utility_));
   }

   bool EncryptIdentityCertificate(const std::string& credential,
                                   const std::string& certificate,
                                   EncryptedData* encrypted) {
     return crypto_utility_->EncryptWithSeed(
         CryptoUtilityImpl::KeyDerivationScheme::kHashWithHeaders, certificate,
         credential, encrypted);
   }

   std::string KDFa(const std::string& key,
                    const std::string& label,
                    const std::string& context,
                    int bits) {
     return crypto_utility_->Tpm2CompatibleKDFa(key, label, context, bits);
   }

  protected:
   NiceMock<MockTpmUtility> mock_tpm_utility_;
   std::unique_ptr<CryptoUtilityImpl> crypto_utility_;
 };

 TEST_F(CryptoUtilityImplTest, GetRandomSuccess) {
   std::string random1;
   EXPECT_TRUE(crypto_utility_->GetRandom(20, &random1));
   std::string random2;
   EXPECT_TRUE(crypto_utility_->GetRandom(20, &random2));
   EXPECT_NE(random1, random2);
 }

 TEST_F(CryptoUtilityImplTest, GetRandomIntOverflow) {
   size_t num_bytes = -1;
   std::string buffer;
   EXPECT_FALSE(crypto_utility_->GetRandom(num_bytes, &buffer));
 }

 TEST_F(CryptoUtilityImplTest, PairwiseSealedEncryption) {
   std::string key;
   std::string sealed_key;
   EXPECT_TRUE(crypto_utility_->CreateSealedKey(&key, &sealed_key));
   std::string data("test");
   std::string encrypted_data;
   EXPECT_TRUE(
       crypto_utility_->EncryptData(data, key, sealed_key, &encrypted_data));
   key.clear();
   sealed_key.clear();
   data.clear();
   EXPECT_TRUE(crypto_utility_->UnsealKey(encrypted_data, &key, &sealed_key));
   EXPECT_TRUE(crypto_utility_->DecryptData(encrypted_data, key, &data));
   EXPECT_EQ("test", data);
 }

 TEST_F(CryptoUtilityImplTest, SealFailure) {
   EXPECT_CALL(mock_tpm_utility_, SealToPCR0(_, _))
       .WillRepeatedly(Return(false));
   std::string key;
   std::string sealed_key;
   EXPECT_FALSE(crypto_utility_->CreateSealedKey(&key, &sealed_key));
 }

 TEST_F(CryptoUtilityImplTest, EncryptNoData) {
   std::string key(32, 0);
   std::string output;
   EXPECT_TRUE(crypto_utility_->EncryptData(std::string(), key, key, &output));
 }

 TEST_F(CryptoUtilityImplTest, EncryptInvalidKey) {
   std::string key(12, 0);
   std::string output;
   EXPECT_FALSE(crypto_utility_->EncryptData(std::string(), key, key, &output));
 }

 TEST_F(CryptoUtilityImplTest, UnsealInvalidData) {
   std::string output;
   EXPECT_FALSE(crypto_utility_->UnsealKey("invalid", &output, &output));
 }

 TEST_F(CryptoUtilityImplTest, UnsealError) {
   EXPECT_CALL(mock_tpm_utility_, Unseal(_, _)).WillRepeatedly(Return(false));
   std::string key(32, 0);
   std::string data;
   EXPECT_TRUE(crypto_utility_->EncryptData("data", key, key, &data));
   std::string output;
   EXPECT_FALSE(crypto_utility_->UnsealKey(data, &output, &output));
 }

 TEST_F(CryptoUtilityImplTest, DecryptInvalidKey) {
   std::string key(12, 0);
   std::string output;
   EXPECT_FALSE(crypto_utility_->DecryptData(std::string(), key, &output));
 }

 TEST_F(CryptoUtilityImplTest, DecryptInvalidData) {
   std::string key(32, 0);
   std::string output;
   EXPECT_FALSE(crypto_utility_->DecryptData("invalid", key, &output));
 }

 TEST_F(CryptoUtilityImplTest, DecryptInvalidData2) {
   std::string key(32, 0);
   std::string output;
   EncryptedData proto;
   std::string input;
   proto.SerializeToString(&input);
   EXPECT_FALSE(crypto_utility_->DecryptData(input, key, &output));
 }

 TEST_F(CryptoUtilityImplTest, GetRSASubjectPublicKeyInfo) {
   std::string public_key = HexDecode(kValidPublicKeyHex);
   std::string output;
   EXPECT_TRUE(crypto_utility_->GetRSASubjectPublicKeyInfo(public_key, &output));
 }

 TEST_F(CryptoUtilityImplTest, GetRSASubjectPublicKeyInfoBadInput) {
   std::string public_key = "bad_public_key";
   std::string output;
   EXPECT_FALSE(
       crypto_utility_->GetRSASubjectPublicKeyInfo(public_key, &output));
 }

 TEST_F(CryptoUtilityImplTest, GetRSASubjectPublicKeyInfoPairWise) {
   std::string public_key = HexDecode(kValidPublicKeyHex);
   std::string output;
   EXPECT_TRUE(crypto_utility_->GetRSASubjectPublicKeyInfo(public_key, &output));
   std::string public_key2;
   EXPECT_TRUE(crypto_utility_->GetRSAPublicKey(output, &public_key2));
   EXPECT_EQ(public_key, public_key2);
 }

 TEST_F(CryptoUtilityImplTest, EncryptIdentityCredential) {
   std::string public_key = HexDecode(kValidPublicKeyHex);
   EncryptedIdentityCredential output;
   EXPECT_TRUE(crypto_utility_->EncryptIdentityCredential(
       TPM_1_2, "credential", public_key, "aik", &output));
   EXPECT_TRUE(output.has_asym_ca_contents());
   EXPECT_TRUE(output.has_sym_ca_attestation());
   EXPECT_EQ(TPM_1_2, output.tpm_version());
 }

 TEST_F(CryptoUtilityImplTest, EncryptIdentityCredentialBadEK) {
   EncryptedIdentityCredential output;
   EXPECT_FALSE(crypto_utility_->EncryptIdentityCredential(
       TPM_1_2, "credential", "bad_ek", "aik", &output));
 }

 TEST_F(CryptoUtilityImplTest, EncryptIdentityCredentialTpm2) {
   std::string public_key = HexDecode(kValidPublicKeyHex);
   std::string public_key_info;
   EXPECT_TRUE(crypto_utility_->GetRSASubjectPublicKeyInfo(public_key,
                                                           &public_key_info));
   EncryptedIdentityCredential output;
   EXPECT_TRUE(crypto_utility_->EncryptIdentityCredential(
       TPM_2_0, "credential", public_key_info, "aik", &output));
   EXPECT_FALSE(output.has_asym_ca_contents());
   EXPECT_FALSE(output.has_sym_ca_attestation());
   EXPECT_TRUE(output.has_encrypted_seed());
   EXPECT_TRUE(output.has_credential_mac());
   EXPECT_TRUE(output.has_wrapped_certificate());
   EXPECT_EQ(TPM_2_0, output.tpm_version());
 }

 TEST_F(CryptoUtilityImplTest, EncryptIdentityCredentialTpm2BadEK) {
   EncryptedIdentityCredential output;
   EXPECT_FALSE(crypto_utility_->EncryptIdentityCredential(
       TPM_2_0, "credential", "bad_ek", "aik", &output));
 }

 TEST_F(CryptoUtilityImplTest, DecryptIdentityCertificateForTpm2) {
   std::string credential(32, 'A');
   std::string certificate(10000, 'B');
   EncryptedData encrypted;
   ASSERT_TRUE(EncryptIdentityCertificate(credential, certificate, &encrypted));
   std::string decrypted_certificate;
   EXPECT_TRUE(crypto_utility_->DecryptIdentityCertificateForTpm2(
       credential, encrypted, &decrypted_certificate));
   EXPECT_EQ(certificate, decrypted_certificate);
 }

 TEST_F(CryptoUtilityImplTest, DecryptIdentityCertificateForTpm2BadInput) {
   std::string credential(32, 'A');
   std::string certificate(10000, 'B');
   EncryptedData encrypted;
   std::string decrypted_certificate;
   EXPECT_FALSE(crypto_utility_->DecryptIdentityCertificateForTpm2(
       credential, encrypted, &decrypted_certificate));
 }

 TEST_F(CryptoUtilityImplTest, EncryptForUnbind) {
   std::string public_key = HexDecode(kValidPublicKeyHex);
   std::string public_key_info;
   EXPECT_TRUE(crypto_utility_->GetRSASubjectPublicKeyInfo(public_key,
                                                           &public_key_info));
   std::string output;
   EXPECT_TRUE(
       crypto_utility_->EncryptForUnbind(public_key_info, "input", &output));
   EXPECT_FALSE(output.empty());
 }

 TEST_F(CryptoUtilityImplTest, EncryptForUnbindBadKey) {
   std::string output;
   EXPECT_FALSE(crypto_utility_->EncryptForUnbind("bad_key", "input", &output));
 }

 TEST_F(CryptoUtilityImplTest, EncryptForUnbindLargeInput) {
   std::string public_key = HexDecode(kValidPublicKeyHex);
   std::string public_key_info;
   EXPECT_TRUE(crypto_utility_->GetRSASubjectPublicKeyInfo(public_key,
                                                           &public_key_info));
   std::string input(1000, 'A');
   std::string output;
   EXPECT_FALSE(
       crypto_utility_->EncryptForUnbind(public_key_info, input, &output));
 }

 TEST_F(CryptoUtilityImplTest, VerifySignatureBadSignature) {
   std::string public_key = HexDecode(kValidPublicKeyHex);
   std::string public_key_info;
   EXPECT_TRUE(crypto_utility_->GetRSASubjectPublicKeyInfo(public_key,
                                                           &public_key_info));
   std::string output;
   EXPECT_FALSE(crypto_utility_->VerifySignature(NID_sha256, public_key_info,
                                                 "input", "signature"));
 }

 TEST_F(CryptoUtilityImplTest, VerifySignatureBadKey) {
   EXPECT_FALSE(
       crypto_utility_->VerifySignature(NID_sha256, "bad_key", "input", ""));
 }

 TEST_F(CryptoUtilityImplTest, VerifyCertificateWithSubjectPublicKey) {
   EXPECT_TRUE(crypto_utility_->VerifyCertificateWithSubjectPublicKey(
       HexDecode(kSelfSignedCertDerHex), kSelfSignedPublikKeyDerHex));
 }

 TEST_F(CryptoUtilityImplTest,
        VerifyCertificateWithSubjectPublicKeyPublicKeyHexDecodeFailure) {
   constexpr char kBadHexEncodedContent[] = "Not a hex-encoded content";
   EXPECT_FALSE(crypto_utility_->VerifyCertificateWithSubjectPublicKey(
       HexDecode(kSelfSignedCertDerHex), kBadHexEncodedContent));
 }

 TEST_F(CryptoUtilityImplTest,
        VerifyCertificateWithSubjectPublicKeyPublicKeyCertificateParseFailure) {
   constexpr char kBadCertificateDer[] = "A bad certificate";
   EXPECT_FALSE(crypto_utility_->VerifyCertificateWithSubjectPublicKey(
       kBadCertificateDer, kSelfSignedPublikKeyDerHex));
 }

 TEST_F(CryptoUtilityImplTest,
        VerifyCertificateWithSubjectPublicKeyPublicKeyDecodeFailure) {
   constexpr char kBadPublicKeyDerHex[] = "badbad";
   EXPECT_FALSE(crypto_utility_->VerifyCertificateWithSubjectPublicKey(
       HexDecode(kSelfSignedCertDerHex), kBadPublicKeyDerHex));
 }

 TEST_F(CryptoUtilityImplTest,
        VerifyCertificateWithSubjectPublicKeyVerifyFailure) {
   EXPECT_FALSE(crypto_utility_->VerifyCertificateWithSubjectPublicKey(
       HexDecode(kSelfSignedCertDerHex), kMismatchedPublicKeyDerHex));
 }

 TEST_F(CryptoUtilityImplTest, EncryptDataForGoogle) {
   std::string certificate(10000, 'C');
   EncryptedData encrypted;
   ASSERT_TRUE(crypto_utility_->EncryptDataForGoogle(
       certificate, kValidModulusHex, "ID", &encrypted));
   EXPECT_EQ("ID", encrypted.wrapping_key_id());
   EXPECT_TRUE(encrypted.has_iv());
   EXPECT_TRUE(encrypted.has_mac());
   EXPECT_TRUE(encrypted.has_encrypted_data());
   EXPECT_TRUE(encrypted.has_wrapped_key());
 }

 TEST_F(CryptoUtilityImplTest, EncryptDataForGoogleBadInput) {
   std::string certificate(10000, 'C');
   EncryptedData encrypted;
   EXPECT_FALSE(crypto_utility_->EncryptDataForGoogle(
       certificate, "bad_public_key", "ID", &encrypted));
   EXPECT_FALSE(encrypted.has_wrapping_key_id());
   EXPECT_FALSE(encrypted.has_iv());
   EXPECT_FALSE(encrypted.has_mac());
   EXPECT_FALSE(encrypted.has_encrypted_data());
   EXPECT_FALSE(encrypted.has_wrapped_key());
 }

 TEST_F(CryptoUtilityImplTest, KDFaKnownAnswerTest) {
   std::string key = HexDecode(
       "BF88BFC2D0FFA48025830745960EE0A53A66B31E7206321F8FC95B89FD63E8C3");
   std::string context = HexDecode(
       "000BEDB60C6A4E2470EF4804FDE7FA35B94A5338DB7D5B5A3A1DE0E7EB12152A1A95");
   std::string expected_output_256 = HexDecode(
       "C8307D1197CBD3A26E78D5519C26E08661C79D36B528A1089E6156627441ECCD");
   std::string expected_output_128 =
       HexDecode("9FD97E677A4538557783B3442EC41993");
   EXPECT_EQ(expected_output_256, KDFa(key, "STORAGE", context, 256));
   EXPECT_EQ(expected_output_128, KDFa(key, "STORAGE", context, 128));
 }

 TEST_F(CryptoUtilityImplTest, HmacSha256KnownAnswerTest) {
   std::string key = HexDecode(
       "3DE45E7AC03354DE42C3B02A8D370FBEE98AAEC3F333D1475EC3BB62D4690A07");
   std::string data = HexDecode("706C656173655F686D61635F74686973");
   std::string expected_output = HexDecode(
       "02E3A9D63DA50426AF92AA849FE20D5BA7DB656E8E35CC1E1562D7365F9D893E");

   EXPECT_EQ(expected_output, crypto_utility_->HmacSha256(key, data));
 }

 TEST_F(CryptoUtilityImplTest, HmacSha512KnownAnswerTest) {
   std::string key = HexDecode(
       "3DE45E7AC03354DE42C3B02A8D370FBEE98AAEC3F333D1475EC3BB62D4690A07");
   std::string data = HexDecode("706C656173655F686D61635F74686973");
   std::string expected_output = HexDecode(
       "573C0E7F8CE36935F5110363CCC240B30225919226730121DC0D1982ECB007CCE2D85C11"
       "15921E13AC8180B4BD9454B1463B897462F9FAD831066E117CF1D077");

   EXPECT_EQ(expected_output, crypto_utility_->HmacSha512(key, data));
 }

 }  // namespace attestation
	// Copyright 2015 The Chromium OS 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 <string>
	#include <vector>

	#include <base/check.h>
	#include <base/logging.h>
	#include <base/strings/string_number_conversions.h>
	#include <gmock/gmock.h>
	#include <gtest/gtest.h>
	#include <openssl/objects.h>

	#include "attestation/common/crypto_utility_impl.h"
	#include "attestation/common/mock_tpm_utility.h"

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

	namespace {

	const char kValidPublicKeyHex[] =
	"3082010A0282010100"
	"961037BC12D2A298BEBF06B2D5F8C9B64B832A2237F8CF27D5F96407A6041A4D"
	"AD383CB5F88E625F412E8ACD5E9D69DF0F4FA81FCE7955829A38366CBBA5A2B1"
	"CE3B48C14B59E9F094B51F0A39155874C8DE18A0C299EBF7A88114F806BE4F25"
	"3C29A509B10E4B19E31675AFE3B2DA77077D94F43D8CE61C205781ED04D183B4"
	"C349F61B1956C64B5398A3A98FAFF17D1B3D9120C832763EDFC8F4137F6EFBEF"
	"46D8F6DE03BD00E49DEF987C10BDD5B6F8758B6A855C23C982DDA14D8F0F2B74"
	"E6DEFA7EEE5A6FC717EB0FF103CB8049F693A2C8A5039EF1F5C025DC44BD8435"
	"E8D8375DADE00E0C0F5C196E04B8483CC98B1D5B03DCD7E0048B2AB343FFC11F"
	"0203"
	"010001";

	const char kValidModulusHex[] =
	"961037BC12D2A298BEBF06B2D5F8C9B64B832A2237F8CF27D5F96407A6041A4D"
	"AD383CB5F88E625F412E8ACD5E9D69DF0F4FA81FCE7955829A38366CBBA5A2B1"
	"CE3B48C14B59E9F094B51F0A39155874C8DE18A0C299EBF7A88114F806BE4F25"
	"3C29A509B10E4B19E31675AFE3B2DA77077D94F43D8CE61C205781ED04D183B4"
	"C349F61B1956C64B5398A3A98FAFF17D1B3D9120C832763EDFC8F4137F6EFBEF"
	"46D8F6DE03BD00E49DEF987C10BDD5B6F8758B6A855C23C982DDA14D8F0F2B74"
	"E6DEFA7EEE5A6FC717EB0FF103CB8049F693A2C8A5039EF1F5C025DC44BD8435"
	"E8D8375DADE00E0C0F5C196E04B8483CC98B1D5B03DCD7E0048B2AB343FFC11F";

	constexpr char kSelfSignedCertDerHex[] =
	"308201fd308201a3a00302010202147b54cc22c8b391d4f8da07d97dc1e48b94be1442300a"
	"06082a8648ce3d0403023044310b300906035504030c025457310b30090603550406130254"
	"573113301106035504080c0a4e6577205461697065693113301106035504070c0a4e657720"
	"546169706569301e170d3231303531343135303132345a170d323230353134313530313234"
	"5a3044310b300906035504030c025457310b30090603550406130254573113301106035504"
	"080c0a4e6577205461697065693113301106035504070c0a4e657720546169706569305930"
	"1306072a8648ce3d020106082a8648ce3d030107034200044ebf9113fcb118d4b2ac828f73"
	"ec374e2ca4e2983d791b3f846a4ab20a340710f84aae65c858bb26faa59a3baec969f573ae"
	"ae435c40c8c4fdada7a87043eb35a3733071301d0603551d0e041604145a6b9f9f94437d3f"
	"df85fb0cebc7a90d28f03f60301f0603551d230418301680145a6b9f9f94437d3fdf85fb0c"
	"ebc7a90d28f03f60300e0603551d0f0101ff0404030202a4301f0603551d11041830168214"
	"746573742e63657274696669636174652e636f6d300a06082a8648ce3d0403020348003045"
	"02204f96089130341b6545f4c2ea7cf34b8e60d187c39de18b227dcc5f7fd985b81c022100"
	"a661c5790d1677f02f2a073f4396d63a24add9a0f650e5ff5f926c8ef67342ee";
	constexpr char kSelfSignedPublikKeyDerHex[] =
	"3059301306072a8648ce3d020106082a8648ce3d030107034200044ebf9113fcb118d4b2ac"
	"828f73ec374e2ca4e2983d791b3f846a4ab20a340710f84aae65c858bb26faa59a3baec969"
	"f573aeae435c40c8c4fdada7a87043eb35";
	constexpr char kMismatchedPublicKeyDerHex[] =
	"3059301306072a8648ce3d020106082a8648ce3d03010703420004c84758541dd419adcfec"
	"8e9868ba4b59755a7c1e3bcf892d11e7bd0afe9714de3043063afe9face5b5d53ebcabc3de"
	"7df2a67726fde0a7f1f4c1ed070e942e92";

	std::string HexDecode(const std::string hex) {
	std::vector<uint8_t> output;
	CHECK(base::HexStringToBytes(hex, &output));
	return std::string(reinterpret_cast<char*>(output.data()), output.size());
	}

	} // namespace

	namespace attestation {

	class CryptoUtilityImplTest : public testing::Test {
	public:
	~CryptoUtilityImplTest() override = default;
	void SetUp() override {
	crypto_utility_.reset(new CryptoUtilityImpl(&mock_tpm_utility_));
	}

	bool EncryptIdentityCertificate(const std::string& credential,
	const std::string& certificate,
	EncryptedData* encrypted) {
	return crypto_utility_->EncryptWithSeed(
	CryptoUtilityImpl::KeyDerivationScheme::kHashWithHeaders, certificate,
	credential, encrypted);
	}

	std::string KDFa(const std::string& key,
	const std::string& label,
	const std::string& context,
	int bits) {
	return crypto_utility_->Tpm2CompatibleKDFa(key, label, context, bits);
	}

	protected:
	NiceMock<MockTpmUtility> mock_tpm_utility_;
	std::unique_ptr<CryptoUtilityImpl> crypto_utility_;
	};

	TEST_F(CryptoUtilityImplTest, GetRandomSuccess) {
	std::string random1;
	EXPECT_TRUE(crypto_utility_->GetRandom(20, &random1));
	std::string random2;
	EXPECT_TRUE(crypto_utility_->GetRandom(20, &random2));
	EXPECT_NE(random1, random2);
	}

	TEST_F(CryptoUtilityImplTest, GetRandomIntOverflow) {
	size_t num_bytes = -1;
	std::string buffer;
	EXPECT_FALSE(crypto_utility_->GetRandom(num_bytes, &buffer));
	}

	TEST_F(CryptoUtilityImplTest, PairwiseSealedEncryption) {
	std::string key;
	std::string sealed_key;
	EXPECT_TRUE(crypto_utility_->CreateSealedKey(&key, &sealed_key));
	std::string data("test");
	std::string encrypted_data;
	EXPECT_TRUE(
	crypto_utility_->EncryptData(data, key, sealed_key, &encrypted_data));
	key.clear();
	sealed_key.clear();
	data.clear();
	EXPECT_TRUE(crypto_utility_->UnsealKey(encrypted_data, &key, &sealed_key));
	EXPECT_TRUE(crypto_utility_->DecryptData(encrypted_data, key, &data));
	EXPECT_EQ("test", data);
	}

	TEST_F(CryptoUtilityImplTest, SealFailure) {
	EXPECT_CALL(mock_tpm_utility_, SealToPCR0(_, _))
	.WillRepeatedly(Return(false));
	std::string key;
	std::string sealed_key;
	EXPECT_FALSE(crypto_utility_->CreateSealedKey(&key, &sealed_key));
	}

	TEST_F(CryptoUtilityImplTest, EncryptNoData) {
	std::string key(32, 0);
	std::string output;
	EXPECT_TRUE(crypto_utility_->EncryptData(std::string(), key, key, &output));
	}

	TEST_F(CryptoUtilityImplTest, EncryptInvalidKey) {
	std::string key(12, 0);
	std::string output;
	EXPECT_FALSE(crypto_utility_->EncryptData(std::string(), key, key, &output));
	}

	TEST_F(CryptoUtilityImplTest, UnsealInvalidData) {
	std::string output;
	EXPECT_FALSE(crypto_utility_->UnsealKey("invalid", &output, &output));
	}

	TEST_F(CryptoUtilityImplTest, UnsealError) {
	EXPECT_CALL(mock_tpm_utility_, Unseal(_, _)).WillRepeatedly(Return(false));
	std::string key(32, 0);
	std::string data;
	EXPECT_TRUE(crypto_utility_->EncryptData("data", key, key, &data));
	std::string output;
	EXPECT_FALSE(crypto_utility_->UnsealKey(data, &output, &output));
	}

	TEST_F(CryptoUtilityImplTest, DecryptInvalidKey) {
	std::string key(12, 0);
	std::string output;
	EXPECT_FALSE(crypto_utility_->DecryptData(std::string(), key, &output));
	}

	TEST_F(CryptoUtilityImplTest, DecryptInvalidData) {
	std::string key(32, 0);
	std::string output;
	EXPECT_FALSE(crypto_utility_->DecryptData("invalid", key, &output));
	}

	TEST_F(CryptoUtilityImplTest, DecryptInvalidData2) {
	std::string key(32, 0);
	std::string output;
	EncryptedData proto;
	std::string input;
	proto.SerializeToString(&input);
	EXPECT_FALSE(crypto_utility_->DecryptData(input, key, &output));
	}

	TEST_F(CryptoUtilityImplTest, GetRSASubjectPublicKeyInfo) {
	std::string public_key = HexDecode(kValidPublicKeyHex);
	std::string output;
	EXPECT_TRUE(crypto_utility_->GetRSASubjectPublicKeyInfo(public_key, &output));
	}

	TEST_F(CryptoUtilityImplTest, GetRSASubjectPublicKeyInfoBadInput) {
	std::string public_key = "bad_public_key";
	std::string output;
	EXPECT_FALSE(
	crypto_utility_->GetRSASubjectPublicKeyInfo(public_key, &output));
	}

	TEST_F(CryptoUtilityImplTest, GetRSASubjectPublicKeyInfoPairWise) {
	std::string public_key = HexDecode(kValidPublicKeyHex);
	std::string output;
	EXPECT_TRUE(crypto_utility_->GetRSASubjectPublicKeyInfo(public_key, &output));
	std::string public_key2;
	EXPECT_TRUE(crypto_utility_->GetRSAPublicKey(output, &public_key2));
	EXPECT_EQ(public_key, public_key2);
	}

	TEST_F(CryptoUtilityImplTest, EncryptIdentityCredential) {
	std::string public_key = HexDecode(kValidPublicKeyHex);
	EncryptedIdentityCredential output;
	EXPECT_TRUE(crypto_utility_->EncryptIdentityCredential(
	TPM_1_2, "credential", public_key, "aik", &output));
	EXPECT_TRUE(output.has_asym_ca_contents());
	EXPECT_TRUE(output.has_sym_ca_attestation());
	EXPECT_EQ(TPM_1_2, output.tpm_version());
	}

	TEST_F(CryptoUtilityImplTest, EncryptIdentityCredentialBadEK) {
	EncryptedIdentityCredential output;
	EXPECT_FALSE(crypto_utility_->EncryptIdentityCredential(
	TPM_1_2, "credential", "bad_ek", "aik", &output));
	}

	TEST_F(CryptoUtilityImplTest, EncryptIdentityCredentialTpm2) {
	std::string public_key = HexDecode(kValidPublicKeyHex);
	std::string public_key_info;
	EXPECT_TRUE(crypto_utility_->GetRSASubjectPublicKeyInfo(public_key,
	&public_key_info));
	EncryptedIdentityCredential output;
	EXPECT_TRUE(crypto_utility_->EncryptIdentityCredential(
	TPM_2_0, "credential", public_key_info, "aik", &output));
	EXPECT_FALSE(output.has_asym_ca_contents());
	EXPECT_FALSE(output.has_sym_ca_attestation());
	EXPECT_TRUE(output.has_encrypted_seed());
	EXPECT_TRUE(output.has_credential_mac());
	EXPECT_TRUE(output.has_wrapped_certificate());
	EXPECT_EQ(TPM_2_0, output.tpm_version());
	}

	TEST_F(CryptoUtilityImplTest, EncryptIdentityCredentialTpm2BadEK) {
	EncryptedIdentityCredential output;
	EXPECT_FALSE(crypto_utility_->EncryptIdentityCredential(
	TPM_2_0, "credential", "bad_ek", "aik", &output));
	}

	TEST_F(CryptoUtilityImplTest, DecryptIdentityCertificateForTpm2) {
	std::string credential(32, 'A');
	std::string certificate(10000, 'B');
	EncryptedData encrypted;
	ASSERT_TRUE(EncryptIdentityCertificate(credential, certificate, &encrypted));
	std::string decrypted_certificate;
	EXPECT_TRUE(crypto_utility_->DecryptIdentityCertificateForTpm2(
	credential, encrypted, &decrypted_certificate));
	EXPECT_EQ(certificate, decrypted_certificate);
	}

	TEST_F(CryptoUtilityImplTest, DecryptIdentityCertificateForTpm2BadInput) {
	std::string credential(32, 'A');
	std::string certificate(10000, 'B');
	EncryptedData encrypted;
	std::string decrypted_certificate;
	EXPECT_FALSE(crypto_utility_->DecryptIdentityCertificateForTpm2(
	credential, encrypted, &decrypted_certificate));
	}

	TEST_F(CryptoUtilityImplTest, EncryptForUnbind) {
	std::string public_key = HexDecode(kValidPublicKeyHex);
	std::string public_key_info;
	EXPECT_TRUE(crypto_utility_->GetRSASubjectPublicKeyInfo(public_key,
	&public_key_info));
	std::string output;
	EXPECT_TRUE(
	crypto_utility_->EncryptForUnbind(public_key_info, "input", &output));
	EXPECT_FALSE(output.empty());
	}

	TEST_F(CryptoUtilityImplTest, EncryptForUnbindBadKey) {
	std::string output;
	EXPECT_FALSE(crypto_utility_->EncryptForUnbind("bad_key", "input", &output));
	}

	TEST_F(CryptoUtilityImplTest, EncryptForUnbindLargeInput) {
	std::string public_key = HexDecode(kValidPublicKeyHex);
	std::string public_key_info;
	EXPECT_TRUE(crypto_utility_->GetRSASubjectPublicKeyInfo(public_key,
	&public_key_info));
	std::string input(1000, 'A');
	std::string output;
	EXPECT_FALSE(
	crypto_utility_->EncryptForUnbind(public_key_info, input, &output));
	}

	TEST_F(CryptoUtilityImplTest, VerifySignatureBadSignature) {
	std::string public_key = HexDecode(kValidPublicKeyHex);
	std::string public_key_info;
	EXPECT_TRUE(crypto_utility_->GetRSASubjectPublicKeyInfo(public_key,
	&public_key_info));
	std::string output;
	EXPECT_FALSE(crypto_utility_->VerifySignature(NID_sha256, public_key_info,
	"input", "signature"));
	}

	TEST_F(CryptoUtilityImplTest, VerifySignatureBadKey) {
	EXPECT_FALSE(
	crypto_utility_->VerifySignature(NID_sha256, "bad_key", "input", ""));
	}

	TEST_F(CryptoUtilityImplTest, VerifyCertificateWithSubjectPublicKey) {
	EXPECT_TRUE(crypto_utility_->VerifyCertificateWithSubjectPublicKey(
	HexDecode(kSelfSignedCertDerHex), kSelfSignedPublikKeyDerHex));
	}

	TEST_F(CryptoUtilityImplTest,
	VerifyCertificateWithSubjectPublicKeyPublicKeyHexDecodeFailure) {
	constexpr char kBadHexEncodedContent[] = "Not a hex-encoded content";
	EXPECT_FALSE(crypto_utility_->VerifyCertificateWithSubjectPublicKey(
	HexDecode(kSelfSignedCertDerHex), kBadHexEncodedContent));
	}

	TEST_F(CryptoUtilityImplTest,
	VerifyCertificateWithSubjectPublicKeyPublicKeyCertificateParseFailure) {
	constexpr char kBadCertificateDer[] = "A bad certificate";
	EXPECT_FALSE(crypto_utility_->VerifyCertificateWithSubjectPublicKey(
	kBadCertificateDer, kSelfSignedPublikKeyDerHex));
	}

	TEST_F(CryptoUtilityImplTest,
	VerifyCertificateWithSubjectPublicKeyPublicKeyDecodeFailure) {
	constexpr char kBadPublicKeyDerHex[] = "badbad";
	EXPECT_FALSE(crypto_utility_->VerifyCertificateWithSubjectPublicKey(
	HexDecode(kSelfSignedCertDerHex), kBadPublicKeyDerHex));
	}

	TEST_F(CryptoUtilityImplTest,
	VerifyCertificateWithSubjectPublicKeyVerifyFailure) {
	EXPECT_FALSE(crypto_utility_->VerifyCertificateWithSubjectPublicKey(
	HexDecode(kSelfSignedCertDerHex), kMismatchedPublicKeyDerHex));
	}

	TEST_F(CryptoUtilityImplTest, EncryptDataForGoogle) {
	std::string certificate(10000, 'C');
	EncryptedData encrypted;
	ASSERT_TRUE(crypto_utility_->EncryptDataForGoogle(
	certificate, kValidModulusHex, "ID", &encrypted));
	EXPECT_EQ("ID", encrypted.wrapping_key_id());
	EXPECT_TRUE(encrypted.has_iv());
	EXPECT_TRUE(encrypted.has_mac());
	EXPECT_TRUE(encrypted.has_encrypted_data());
	EXPECT_TRUE(encrypted.has_wrapped_key());
	}

	TEST_F(CryptoUtilityImplTest, EncryptDataForGoogleBadInput) {
	std::string certificate(10000, 'C');
	EncryptedData encrypted;
	EXPECT_FALSE(crypto_utility_->EncryptDataForGoogle(
	certificate, "bad_public_key", "ID", &encrypted));
	EXPECT_FALSE(encrypted.has_wrapping_key_id());
	EXPECT_FALSE(encrypted.has_iv());
	EXPECT_FALSE(encrypted.has_mac());
	EXPECT_FALSE(encrypted.has_encrypted_data());
	EXPECT_FALSE(encrypted.has_wrapped_key());
	}

	TEST_F(CryptoUtilityImplTest, KDFaKnownAnswerTest) {
	std::string key = HexDecode(
	"BF88BFC2D0FFA48025830745960EE0A53A66B31E7206321F8FC95B89FD63E8C3");
	std::string context = HexDecode(
	"000BEDB60C6A4E2470EF4804FDE7FA35B94A5338DB7D5B5A3A1DE0E7EB12152A1A95");
	std::string expected_output_256 = HexDecode(
	"C8307D1197CBD3A26E78D5519C26E08661C79D36B528A1089E6156627441ECCD");
	std::string expected_output_128 =
	HexDecode("9FD97E677A4538557783B3442EC41993");
	EXPECT_EQ(expected_output_256, KDFa(key, "STORAGE", context, 256));
	EXPECT_EQ(expected_output_128, KDFa(key, "STORAGE", context, 128));
	}

	TEST_F(CryptoUtilityImplTest, HmacSha256KnownAnswerTest) {
	std::string key = HexDecode(
	"3DE45E7AC03354DE42C3B02A8D370FBEE98AAEC3F333D1475EC3BB62D4690A07");
	std::string data = HexDecode("706C656173655F686D61635F74686973");
	std::string expected_output = HexDecode(
	"02E3A9D63DA50426AF92AA849FE20D5BA7DB656E8E35CC1E1562D7365F9D893E");

	EXPECT_EQ(expected_output, crypto_utility_->HmacSha256(key, data));
	}

	TEST_F(CryptoUtilityImplTest, HmacSha512KnownAnswerTest) {
	std::string key = HexDecode(
	"3DE45E7AC03354DE42C3B02A8D370FBEE98AAEC3F333D1475EC3BB62D4690A07");
	std::string data = HexDecode("706C656173655F686D61635F74686973");
	std::string expected_output = HexDecode(
	"573C0E7F8CE36935F5110363CCC240B30225919226730121DC0D1982ECB007CCE2D85C11"
	"15921E13AC8180B4BD9454B1463B897462F9FAD831066E117CF1D077");

	EXPECT_EQ(expected_output, crypto_utility_->HmacSha512(key, data));
	}

	} // namespace attestation