identity/aidl/vts/TestCredentialTests.cpp - third_party/android/platform/hardware/interfaces - Git at Google

 /*
  * Copyright (C) 2020 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #define LOG_TAG "TestCredentialTests"

 #include <aidl/Gtest.h>
 #include <aidl/Vintf.h>
 #include <aidl/android/hardware/keymaster/HardwareAuthToken.h>
 #include <aidl/android/hardware/keymaster/VerificationToken.h>
 #include <android-base/logging.h>
 #include <android/hardware/identity/IIdentityCredentialStore.h>
 #include <android/hardware/identity/support/IdentityCredentialSupport.h>
 #include <binder/IServiceManager.h>
 #include <binder/ProcessState.h>
 #include <cppbor.h>
 #include <cppbor_parse.h>
 #include <gtest/gtest.h>
 #include <future>
 #include <map>
 #include <utility>

 #include "Util.h"

 namespace android::hardware::identity {

 using std::endl;
 using std::make_pair;
 using std::map;
 using std::optional;
 using std::pair;
 using std::string;
 using std::tie;
 using std::vector;

 using ::android::sp;
 using ::android::String16;
 using ::android::binder::Status;

 using ::android::hardware::keymaster::HardwareAuthToken;
 using ::android::hardware::keymaster::VerificationToken;

 class TestCredentialTests : public testing::TestWithParam<string> {
   public:
     virtual void SetUp() override {
         string halInstanceName = GetParam();
         credentialStore_ = android::waitForDeclaredService<IIdentityCredentialStore>(
                 String16(halInstanceName.c_str()));
         ASSERT_NE(credentialStore_, nullptr);
         halApiVersion_ = credentialStore_->getInterfaceVersion();
     }

     sp<IIdentityCredentialStore> credentialStore_;
     int halApiVersion_;
 };

 TEST_P(TestCredentialTests, testCredential) {
     string docType = "org.iso.18013-5.2019.mdl";
     sp<IWritableIdentityCredential> wc;
     ASSERT_TRUE(credentialStore_
                         ->createCredential(docType,
                                            true,  // testCredential
                                            &wc)
                         .isOk());

     vector<uint8_t> attestationApplicationId = {};
     vector<uint8_t> attestationChallenge = {1};
     vector<Certificate> certChain;
     ASSERT_TRUE(wc->getAttestationCertificate(attestationApplicationId, attestationChallenge,
                                               &certChain)
                         .isOk());

     optional<vector<uint8_t>> optCredentialPubKey =
             support::certificateChainGetTopMostKey(certChain[0].encodedCertificate);
     ASSERT_TRUE(optCredentialPubKey);
     vector<uint8_t> credentialPubKey;
     credentialPubKey = optCredentialPubKey.value();

     size_t proofOfProvisioningSize = 112;
     // Not in v1 HAL, may fail
     wc->setExpectedProofOfProvisioningSize(proofOfProvisioningSize);

     ASSERT_TRUE(wc->startPersonalization(1 /* numAccessControlProfiles */,
                                          {1} /* numDataElementsPerNamespace */)
                         .isOk());

     // Access control profile 0: open access - don't care about the returned SACP
     SecureAccessControlProfile sacp;
     ASSERT_TRUE(wc->addAccessControlProfile(1, {}, false, 0, 0, &sacp).isOk());

     // Single entry - don't care about the returned encrypted data
     vector<uint8_t> encryptedData;
     vector<uint8_t> tstrLastName = cppbor::Tstr("Turing").encode();
     ASSERT_TRUE(wc->beginAddEntry({1}, "ns", "Last name", tstrLastName.size()).isOk());
     ASSERT_TRUE(wc->addEntryValue(tstrLastName, &encryptedData).isOk());

     vector<uint8_t> proofOfProvisioningSignature;
     vector<uint8_t> credentialData;
     Status status = wc->finishAddingEntries(&credentialData, &proofOfProvisioningSignature);
     EXPECT_TRUE(status.isOk()) << status.exceptionCode() << ": " << status.exceptionMessage();

     optional<vector<uint8_t>> proofOfProvisioning =
             support::coseSignGetPayload(proofOfProvisioningSignature);
     ASSERT_TRUE(proofOfProvisioning);
     string cborPretty = cppbor::prettyPrint(proofOfProvisioning.value(), 32, {});
     EXPECT_EQ(
             "[\n"
             "  'ProofOfProvisioning',\n"
             "  'org.iso.18013-5.2019.mdl',\n"
             "  [\n"
             "    {\n"
             "      'id' : 1,\n"
             "    },\n"
             "  ],\n"
             "  {\n"
             "    'ns' : [\n"
             "      {\n"
             "        'name' : 'Last name',\n"
             "        'value' : 'Turing',\n"
             "        'accessControlProfiles' : [1, ],\n"
             "      },\n"
             "    ],\n"
             "  },\n"
             "  true,\n"
             "]",
             cborPretty);
     // Make sure it's signed by the CredentialKey in the returned cert chain.
     EXPECT_TRUE(support::coseCheckEcDsaSignature(proofOfProvisioningSignature,
                                                  {},  // Additional data
                                                  credentialPubKey));

     // Now analyze credentialData..
     auto [item, _, message] = cppbor::parse(credentialData);
     ASSERT_NE(item, nullptr);
     const cppbor::Array* arrayItem = item->asArray();
     ASSERT_NE(arrayItem, nullptr);
     ASSERT_EQ(arrayItem->size(), 3);
     const cppbor::Tstr* docTypeItem = (*arrayItem)[0]->asTstr();
     const cppbor::Bool* testCredentialItem =
             ((*arrayItem)[1]->asSimple() != nullptr ? ((*arrayItem)[1]->asSimple()->asBool())
                                                     : nullptr);
     EXPECT_EQ(docTypeItem->value(), docType);
     EXPECT_EQ(testCredentialItem->value(), true);

     vector<uint8_t> hardwareBoundKey = support::getTestHardwareBoundKey();
     const cppbor::Bstr* encryptedCredentialKeysItem = (*arrayItem)[2]->asBstr();
     const vector<uint8_t>& encryptedCredentialKeys = encryptedCredentialKeysItem->value();
     const vector<uint8_t> docTypeVec(docType.begin(), docType.end());
     optional<vector<uint8_t>> decryptedCredentialKeys =
             support::decryptAes128Gcm(hardwareBoundKey, encryptedCredentialKeys, docTypeVec);
     ASSERT_TRUE(decryptedCredentialKeys);
     auto [dckItem, dckPos, dckMessage] = cppbor::parse(decryptedCredentialKeys.value());
     ASSERT_NE(dckItem, nullptr) << dckMessage;
     const cppbor::Array* dckArrayItem = dckItem->asArray();
     ASSERT_NE(dckArrayItem, nullptr);
     // In HAL API version 1 and 2 this array has two items, in version 3 and later it has three.
     if (halApiVersion_ < 3) {
         ASSERT_EQ(dckArrayItem->size(), 2);
     } else {
         ASSERT_EQ(dckArrayItem->size(), 3);
     }
     const cppbor::Bstr* storageKeyItem = (*dckArrayItem)[0]->asBstr();
     const vector<uint8_t> storageKey = storageKeyItem->value();
     // const cppbor::Bstr* credentialPrivKeyItem = (*dckArrayItem)[1]->asBstr();
     // const vector<uint8_t> credentialPrivKey = credentialPrivKeyItem->value();

     // Check storageKey can be used to decrypt |encryptedData| to |tstrLastName|
     vector<uint8_t> additionalData = cppbor::Map()
                                              .add("Namespace", "ns")
                                              .add("Name", "Last name")
                                              .add("AccessControlProfileIds", cppbor::Array().add(1))
                                              .encode();
     optional<vector<uint8_t>> decryptedDataItemValue =
             support::decryptAes128Gcm(storageKey, encryptedData, additionalData);
     ASSERT_TRUE(decryptedDataItemValue);
     EXPECT_EQ(decryptedDataItemValue.value(), tstrLastName);

     // Check that SHA-256(ProofOfProvisioning) matches (only in HAL API version 3)
     if (halApiVersion_ >= 3) {
         const cppbor::Bstr* popSha256Item = (*dckArrayItem)[2]->asBstr();
         const vector<uint8_t> popSha256 = popSha256Item->value();
         ASSERT_EQ(popSha256, support::sha256(proofOfProvisioning.value()));
     }
 }

 GTEST_ALLOW_UNINSTANTIATED_PARAMETERIZED_TEST(TestCredentialTests);
 INSTANTIATE_TEST_SUITE_P(
         Identity, TestCredentialTests,
         testing::ValuesIn(android::getAidlHalInstanceNames(IIdentityCredentialStore::descriptor)),
         android::PrintInstanceNameToString);

 }  // namespace android::hardware::identity
	/*
	* Copyright (C) 2020 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#define LOG_TAG "TestCredentialTests"

	#include <aidl/Gtest.h>
	#include <aidl/Vintf.h>
	#include <aidl/android/hardware/keymaster/HardwareAuthToken.h>
	#include <aidl/android/hardware/keymaster/VerificationToken.h>
	#include <android-base/logging.h>
	#include <android/hardware/identity/IIdentityCredentialStore.h>
	#include <android/hardware/identity/support/IdentityCredentialSupport.h>
	#include <binder/IServiceManager.h>
	#include <binder/ProcessState.h>
	#include <cppbor.h>
	#include <cppbor_parse.h>
	#include <gtest/gtest.h>
	#include <future>
	#include <map>
	#include <utility>

	#include "Util.h"

	namespace android::hardware::identity {

	using std::endl;
	using std::make_pair;
	using std::map;
	using std::optional;
	using std::pair;
	using std::string;
	using std::tie;
	using std::vector;

	using ::android::sp;
	using ::android::String16;
	using ::android::binder::Status;

	using ::android::hardware::keymaster::HardwareAuthToken;
	using ::android::hardware::keymaster::VerificationToken;

	class TestCredentialTests : public testing::TestWithParam<string> {
	public:
	virtual void SetUp() override {
	string halInstanceName = GetParam();
	credentialStore_ = android::waitForDeclaredService<IIdentityCredentialStore>(
	String16(halInstanceName.c_str()));
	ASSERT_NE(credentialStore_, nullptr);
	halApiVersion_ = credentialStore_->getInterfaceVersion();
	}

	sp<IIdentityCredentialStore> credentialStore_;
	int halApiVersion_;
	};

	TEST_P(TestCredentialTests, testCredential) {
	string docType = "org.iso.18013-5.2019.mdl";
	sp<IWritableIdentityCredential> wc;
	ASSERT_TRUE(credentialStore_
	->createCredential(docType,
	true, // testCredential
	&wc)
	.isOk());

	vector<uint8_t> attestationApplicationId = {};
	vector<uint8_t> attestationChallenge = {1};
	vector<Certificate> certChain;
	ASSERT_TRUE(wc->getAttestationCertificate(attestationApplicationId, attestationChallenge,
	&certChain)
	.isOk());

	optional<vector<uint8_t>> optCredentialPubKey =
	support::certificateChainGetTopMostKey(certChain[0].encodedCertificate);
	ASSERT_TRUE(optCredentialPubKey);
	vector<uint8_t> credentialPubKey;
	credentialPubKey = optCredentialPubKey.value();

	size_t proofOfProvisioningSize = 112;
	// Not in v1 HAL, may fail
	wc->setExpectedProofOfProvisioningSize(proofOfProvisioningSize);

	ASSERT_TRUE(wc->startPersonalization(1 /* numAccessControlProfiles */,
	{1} /* numDataElementsPerNamespace */)
	.isOk());

	// Access control profile 0: open access - don't care about the returned SACP
	SecureAccessControlProfile sacp;
	ASSERT_TRUE(wc->addAccessControlProfile(1, {}, false, 0, 0, &sacp).isOk());

	// Single entry - don't care about the returned encrypted data
	vector<uint8_t> encryptedData;
	vector<uint8_t> tstrLastName = cppbor::Tstr("Turing").encode();
	ASSERT_TRUE(wc->beginAddEntry({1}, "ns", "Last name", tstrLastName.size()).isOk());
	ASSERT_TRUE(wc->addEntryValue(tstrLastName, &encryptedData).isOk());

	vector<uint8_t> proofOfProvisioningSignature;
	vector<uint8_t> credentialData;
	Status status = wc->finishAddingEntries(&credentialData, &proofOfProvisioningSignature);
	EXPECT_TRUE(status.isOk()) << status.exceptionCode() << ": " << status.exceptionMessage();

	optional<vector<uint8_t>> proofOfProvisioning =
	support::coseSignGetPayload(proofOfProvisioningSignature);
	ASSERT_TRUE(proofOfProvisioning);
	string cborPretty = cppbor::prettyPrint(proofOfProvisioning.value(), 32, {});
	EXPECT_EQ(
	"[\n"
	" 'ProofOfProvisioning',\n"
	" 'org.iso.18013-5.2019.mdl',\n"
	" [\n"
	" {\n"
	" 'id' : 1,\n"
	" },\n"
	" ],\n"
	" {\n"
	" 'ns' : [\n"
	" {\n"
	" 'name' : 'Last name',\n"
	" 'value' : 'Turing',\n"
	" 'accessControlProfiles' : [1, ],\n"
	" },\n"
	" ],\n"
	" },\n"
	" true,\n"
	"]",
	cborPretty);
	// Make sure it's signed by the CredentialKey in the returned cert chain.
	EXPECT_TRUE(support::coseCheckEcDsaSignature(proofOfProvisioningSignature,
	{}, // Additional data
	credentialPubKey));

	// Now analyze credentialData..
	auto [item, _, message] = cppbor::parse(credentialData);
	ASSERT_NE(item, nullptr);
	const cppbor::Array* arrayItem = item->asArray();
	ASSERT_NE(arrayItem, nullptr);
	ASSERT_EQ(arrayItem->size(), 3);
	const cppbor::Tstr* docTypeItem = (*arrayItem)[0]->asTstr();
	const cppbor::Bool* testCredentialItem =
	((arrayItem)[1]->asSimple() != nullptr ? ((arrayItem)[1]->asSimple()->asBool())
	: nullptr);
	EXPECT_EQ(docTypeItem->value(), docType);
	EXPECT_EQ(testCredentialItem->value(), true);

	vector<uint8_t> hardwareBoundKey = support::getTestHardwareBoundKey();
	const cppbor::Bstr* encryptedCredentialKeysItem = (*arrayItem)[2]->asBstr();
	const vector<uint8_t>& encryptedCredentialKeys = encryptedCredentialKeysItem->value();
	const vector<uint8_t> docTypeVec(docType.begin(), docType.end());
	optional<vector<uint8_t>> decryptedCredentialKeys =
	support::decryptAes128Gcm(hardwareBoundKey, encryptedCredentialKeys, docTypeVec);
	ASSERT_TRUE(decryptedCredentialKeys);
	auto [dckItem, dckPos, dckMessage] = cppbor::parse(decryptedCredentialKeys.value());
	ASSERT_NE(dckItem, nullptr) << dckMessage;
	const cppbor::Array* dckArrayItem = dckItem->asArray();
	ASSERT_NE(dckArrayItem, nullptr);
	// In HAL API version 1 and 2 this array has two items, in version 3 and later it has three.
	if (halApiVersion_ < 3) {
	ASSERT_EQ(dckArrayItem->size(), 2);
	} else {
	ASSERT_EQ(dckArrayItem->size(), 3);
	}
	const cppbor::Bstr* storageKeyItem = (*dckArrayItem)[0]->asBstr();
	const vector<uint8_t> storageKey = storageKeyItem->value();
	// const cppbor::Bstr* credentialPrivKeyItem = (*dckArrayItem)[1]->asBstr();
	// const vector<uint8_t> credentialPrivKey = credentialPrivKeyItem->value();

	// Check storageKey can be used to decrypt \|encryptedData\| to \|tstrLastName\|
	vector<uint8_t> additionalData = cppbor::Map()
	.add("Namespace", "ns")
	.add("Name", "Last name")
	.add("AccessControlProfileIds", cppbor::Array().add(1))
	.encode();
	optional<vector<uint8_t>> decryptedDataItemValue =
	support::decryptAes128Gcm(storageKey, encryptedData, additionalData);
	ASSERT_TRUE(decryptedDataItemValue);
	EXPECT_EQ(decryptedDataItemValue.value(), tstrLastName);

	// Check that SHA-256(ProofOfProvisioning) matches (only in HAL API version 3)
	if (halApiVersion_ >= 3) {
	const cppbor::Bstr* popSha256Item = (*dckArrayItem)[2]->asBstr();
	const vector<uint8_t> popSha256 = popSha256Item->value();
	ASSERT_EQ(popSha256, support::sha256(proofOfProvisioning.value()));
	}
	}

	GTEST_ALLOW_UNINSTANTIATED_PARAMETERIZED_TEST(TestCredentialTests);
	INSTANTIATE_TEST_SUITE_P(
	Identity, TestCredentialTests,
	testing::ValuesIn(android::getAidlHalInstanceNames(IIdentityCredentialStore::descriptor)),
	android::PrintInstanceNameToString);

	} // namespace android::hardware::identity