// Copyright 2012 The Chromium Authors // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "net/cert/x509_certificate.h" #include #include #include #include "base/files/file_path.h" #include "base/files/file_util.h" #include "base/hash/sha1.h" #include "base/pickle.h" #include "base/strings/strcat.h" #include "base/strings/string_number_conversions.h" #include "base/strings/string_split.h" #include "base/strings/string_util.h" #include "base/time/time.h" #include "crypto/rsa_private_key.h" #include "net/base/net_errors.h" #include "net/cert/asn1_util.h" #include "net/cert/x509_util.h" #include "net/test/cert_builder.h" #include "net/test/cert_test_util.h" #include "net/test/test_certificate_data.h" #include "net/test/test_data_directory.h" #include "testing/gtest/include/gtest/gtest.h" #include "third_party/boringssl/src/pki/parse_certificate.h" #include "third_party/boringssl/src/pki/pem.h" using base::HexEncode; using base::Time; namespace net { namespace { // Certificates for test data. They're obtained with: // // $ openssl s_client -connect [host]:443 -showcerts > /tmp/host.pem < /dev/null // $ openssl x509 -inform PEM -outform DER < /tmp/host.pem > /tmp/host.der // // For fingerprint // $ openssl x509 -inform DER -fingerprint -noout < /tmp/host.der // For valid_start, valid_expiry // $ openssl x509 -inform DER -text -noout < /tmp/host.der | // grep -A 2 Validity // $ date +%s -d '' // Google's cert. SHA256HashValue google_fingerprint = { {0x21, 0xaf, 0x58, 0x74, 0xea, 0x6b, 0xad, 0xbd, 0xe4, 0xb3, 0xb1, 0xaa, 0x53, 0x32, 0x80, 0x8f, 0xbf, 0x8a, 0x24, 0x7d, 0x98, 0xec, 0x7f, 0x77, 0x49, 0x38, 0x42, 0x81, 0x26, 0x7f, 0xed, 0x38}}; // The fingerprint of the Google certificate used in the parsing tests, // which is newer than the one included in the x509_certificate_data.h SHA256HashValue google_parse_fingerprint = { {0xf6, 0x41, 0xc3, 0x6c, 0xfe, 0xf4, 0x9b, 0xc0, 0x71, 0x35, 0x9e, 0xcf, 0x88, 0xee, 0xd9, 0x31, 0x7b, 0x73, 0x8b, 0x59, 0x89, 0x41, 0x6a, 0xd4, 0x01, 0x72, 0x0c, 0x0a, 0x4e, 0x2e, 0x63, 0x52}}; // The fingerprint for the Thawte SGC certificate SHA256HashValue thawte_parse_fingerprint = { {0x10, 0x85, 0xa6, 0xf4, 0x54, 0xd0, 0xc9, 0x11, 0x98, 0xfd, 0xda, 0xb1, 0x1a, 0x31, 0xc7, 0x16, 0xd5, 0xdc, 0xd6, 0x8d, 0xf9, 0x1c, 0x03, 0x9c, 0xe1, 0x8d, 0xca, 0x9b, 0xeb, 0x3c, 0xde, 0x3d}}; // Dec 18 00:00:00 2009 GMT const double kGoogleParseValidFrom = 1261094400; // Dec 18 23:59:59 2011 GMT const double kGoogleParseValidTo = 1324252799; void CheckGoogleCert(const scoped_refptr& google_cert, const SHA256HashValue& expected_fingerprint, double valid_from, double valid_to) { ASSERT_NE(static_cast(nullptr), google_cert.get()); const CertPrincipal& subject = google_cert->subject(); EXPECT_EQ("www.google.com", subject.common_name); EXPECT_EQ("Mountain View", subject.locality_name); EXPECT_EQ("California", subject.state_or_province_name); EXPECT_EQ("US", subject.country_name); ASSERT_EQ(1U, subject.organization_names.size()); EXPECT_EQ("Google Inc", subject.organization_names[0]); EXPECT_EQ(0U, subject.organization_unit_names.size()); const CertPrincipal& issuer = google_cert->issuer(); EXPECT_EQ("Thawte SGC CA", issuer.common_name); EXPECT_EQ("", issuer.locality_name); EXPECT_EQ("", issuer.state_or_province_name); EXPECT_EQ("ZA", issuer.country_name); ASSERT_EQ(1U, issuer.organization_names.size()); EXPECT_EQ("Thawte Consulting (Pty) Ltd.", issuer.organization_names[0]); EXPECT_EQ(0U, issuer.organization_unit_names.size()); // Use DoubleT because its epoch is the same on all platforms const Time& valid_start = google_cert->valid_start(); EXPECT_EQ(valid_from, valid_start.InSecondsFSinceUnixEpoch()); const Time& valid_expiry = google_cert->valid_expiry(); EXPECT_EQ(valid_to, valid_expiry.InSecondsFSinceUnixEpoch()); EXPECT_EQ(expected_fingerprint, X509Certificate::CalculateFingerprint256( google_cert->cert_buffer())); } void ExpectX509CertificateMembersEqual( const scoped_refptr& a, const scoped_refptr& b) { EXPECT_TRUE(a->subject().EqualsForTesting(b->subject())); EXPECT_TRUE(a->issuer().EqualsForTesting(b->issuer())); EXPECT_EQ(a->valid_start(), b->valid_start()); EXPECT_EQ(a->valid_expiry(), b->valid_expiry()); EXPECT_EQ(a->serial_number(), b->serial_number()); } } // namespace TEST(X509CertificateTest, GoogleCertParsing) { scoped_refptr google_cert( X509Certificate::CreateFromBytes(google_der)); CheckGoogleCert(google_cert, google_fingerprint, 1238192407, // Mar 27 22:20:07 2009 GMT 1269728407); // Mar 27 22:20:07 2010 GMT } TEST(X509CertificateTest, WebkitCertParsing) { scoped_refptr webkit_cert( X509Certificate::CreateFromBytes(webkit_der)); ASSERT_NE(static_cast(nullptr), webkit_cert.get()); const CertPrincipal& subject = webkit_cert->subject(); EXPECT_EQ("Cupertino", subject.locality_name); EXPECT_EQ("California", subject.state_or_province_name); EXPECT_EQ("US", subject.country_name); ASSERT_EQ(1U, subject.organization_names.size()); EXPECT_EQ("Apple Inc.", subject.organization_names[0]); ASSERT_EQ(1U, subject.organization_unit_names.size()); EXPECT_EQ("Mac OS Forge", subject.organization_unit_names[0]); const CertPrincipal& issuer = webkit_cert->issuer(); EXPECT_EQ("Go Daddy Secure Certification Authority", issuer.common_name); EXPECT_EQ("Scottsdale", issuer.locality_name); EXPECT_EQ("Arizona", issuer.state_or_province_name); EXPECT_EQ("US", issuer.country_name); ASSERT_EQ(1U, issuer.organization_names.size()); EXPECT_EQ("GoDaddy.com, Inc.", issuer.organization_names[0]); ASSERT_EQ(1U, issuer.organization_unit_names.size()); EXPECT_EQ("http://certificates.godaddy.com/repository", issuer.organization_unit_names[0]); // Use DoubleT because its epoch is the same on all platforms const Time& valid_start = webkit_cert->valid_start(); EXPECT_EQ( 1205883319, valid_start.InSecondsFSinceUnixEpoch()); // Mar 18 23:35:19 2008 GMT const Time& valid_expiry = webkit_cert->valid_expiry(); EXPECT_EQ( 1300491319, valid_expiry.InSecondsFSinceUnixEpoch()); // Mar 18 23:35:19 2011 GMT std::vector dns_names; EXPECT_TRUE(webkit_cert->GetSubjectAltName(&dns_names, nullptr)); ASSERT_EQ(2U, dns_names.size()); EXPECT_EQ("*.webkit.org", dns_names[0]); EXPECT_EQ("webkit.org", dns_names[1]); // Test that the wildcard cert matches properly. EXPECT_TRUE(webkit_cert->VerifyNameMatch("www.webkit.org")); EXPECT_TRUE(webkit_cert->VerifyNameMatch("foo.webkit.org")); EXPECT_TRUE(webkit_cert->VerifyNameMatch("webkit.org")); EXPECT_FALSE(webkit_cert->VerifyNameMatch("www.webkit.com")); EXPECT_FALSE(webkit_cert->VerifyNameMatch("www.foo.webkit.com")); } TEST(X509CertificateTest, ThawteCertParsing) { scoped_refptr thawte_cert( X509Certificate::CreateFromBytes(thawte_der)); ASSERT_NE(static_cast(nullptr), thawte_cert.get()); const CertPrincipal& subject = thawte_cert->subject(); EXPECT_EQ("www.thawte.com", subject.common_name); EXPECT_EQ("Mountain View", subject.locality_name); EXPECT_EQ("California", subject.state_or_province_name); EXPECT_EQ("US", subject.country_name); ASSERT_EQ(1U, subject.organization_names.size()); EXPECT_EQ("Thawte Inc", subject.organization_names[0]); EXPECT_EQ(0U, subject.organization_unit_names.size()); const CertPrincipal& issuer = thawte_cert->issuer(); EXPECT_EQ("thawte Extended Validation SSL CA", issuer.common_name); EXPECT_EQ("", issuer.locality_name); EXPECT_EQ("", issuer.state_or_province_name); EXPECT_EQ("US", issuer.country_name); ASSERT_EQ(1U, issuer.organization_names.size()); EXPECT_EQ("thawte, Inc.", issuer.organization_names[0]); ASSERT_EQ(1U, issuer.organization_unit_names.size()); EXPECT_EQ("Terms of use at https://www.thawte.com/cps (c)06", issuer.organization_unit_names[0]); // Use DoubleT because its epoch is the same on all platforms const Time& valid_start = thawte_cert->valid_start(); EXPECT_EQ( 1227052800, valid_start.InSecondsFSinceUnixEpoch()); // Nov 19 00:00:00 2008 GMT const Time& valid_expiry = thawte_cert->valid_expiry(); EXPECT_EQ( 1263772799, valid_expiry.InSecondsFSinceUnixEpoch()); // Jan 17 23:59:59 2010 GMT } // Test that all desired AttributeAndValue pairs can be extracted when only // a single bssl::RelativeDistinguishedName is present. "Normally" there is only // one AVA per RDN, but some CAs place all AVAs within a single RDN. // This is a regression test for http://crbug.com/101009 TEST(X509CertificateTest, MultivalueRDN) { base::FilePath certs_dir = GetTestCertsDirectory(); scoped_refptr multivalue_rdn_cert = ImportCertFromFile(certs_dir, "multivalue_rdn.pem"); ASSERT_NE(static_cast(nullptr), multivalue_rdn_cert.get()); const CertPrincipal& subject = multivalue_rdn_cert->subject(); EXPECT_EQ("Multivalue RDN Test", subject.common_name); EXPECT_EQ("", subject.locality_name); EXPECT_EQ("", subject.state_or_province_name); EXPECT_EQ("US", subject.country_name); ASSERT_EQ(1U, subject.organization_names.size()); EXPECT_EQ("Chromium", subject.organization_names[0]); ASSERT_EQ(1U, subject.organization_unit_names.size()); EXPECT_EQ("Chromium net_unittests", subject.organization_unit_names[0]); } // Test that characters which would normally be escaped in the string form, // such as '=' or '"', are not escaped when parsed as individual components. // This is a regression test for http://crbug.com/102839 TEST(X509CertificateTest, UnescapedSpecialCharacters) { base::FilePath certs_dir = GetTestCertsDirectory(); scoped_refptr unescaped_cert = ImportCertFromFile(certs_dir, "unescaped.pem"); ASSERT_NE(static_cast(nullptr), unescaped_cert.get()); const CertPrincipal& subject = unescaped_cert->subject(); EXPECT_EQ("127.0.0.1", subject.common_name); EXPECT_EQ("Mountain View", subject.locality_name); EXPECT_EQ("California", subject.state_or_province_name); EXPECT_EQ("US", subject.country_name); ASSERT_EQ(1U, subject.organization_names.size()); EXPECT_EQ("Chromium = \"net_unittests\"", subject.organization_names[0]); ASSERT_EQ(2U, subject.organization_unit_names.size()); EXPECT_EQ("net_unittests", subject.organization_unit_names[0]); EXPECT_EQ("Chromium", subject.organization_unit_names[1]); } TEST(X509CertificateTest, InvalidPrintableStringIsUtf8) { base::FilePath certs_dir = GetTestNetDataDirectory().AppendASCII("parse_certificate_unittest"); std::string file_data; ASSERT_TRUE(base::ReadFileToString( certs_dir.AppendASCII( "subject_printable_string_containing_utf8_client_cert.pem"), &file_data)); bssl::PEMTokenizer pem_tokenizer(file_data, {"CERTIFICATE"}); ASSERT_TRUE(pem_tokenizer.GetNext()); std::string cert_der(pem_tokenizer.data()); ASSERT_FALSE(pem_tokenizer.GetNext()); bssl::UniquePtr cert_handle = x509_util::CreateCryptoBuffer(cert_der); ASSERT_TRUE(cert_handle); EXPECT_FALSE( X509Certificate::CreateFromBuffer(bssl::UpRef(cert_handle.get()), {})); X509Certificate::UnsafeCreateOptions options; options.printable_string_is_utf8 = true; scoped_refptr cert = X509Certificate::CreateFromBufferUnsafeOptions( bssl::UpRef(cert_handle.get()), {}, options); const CertPrincipal& subject = cert->subject(); EXPECT_EQ("Foo@#_ Clïênt Cërt", subject.common_name); } TEST(X509CertificateTest, TeletexStringIsLatin1) { base::FilePath certs_dir = GetTestNetDataDirectory().AppendASCII("parse_certificate_unittest"); scoped_refptr cert = ImportCertFromFile(certs_dir, "subject_t61string.pem"); ASSERT_TRUE(cert); const CertPrincipal& subject = cert->subject(); EXPECT_EQ( " !\"#$%&'()*+,-./" "0123456789:;<=>?@ABCDEFGHIJKLMNOPQRSTUVWXYZ[\\]^_`" "abcdefghijklmnopqrstuvwxyz{|}~" " ¡¢£¤¥¦§¨©ª«¬®¯°±²³´µ¶·¸¹º»¼½¾¿ÀÁÂÃÄÅÆÇÈÉÊËÌÍÎÏÐÑÒÓÔÕÖ×ØÙÚÛÜÝÞßàáâãäåæç" "èéêëìíîïðñòóôõö÷øùúûüýþÿ", subject.organization_names[0]); } TEST(X509CertificateTest, TeletexStringControlChars) { base::FilePath certs_dir = GetTestNetDataDirectory().AppendASCII("parse_certificate_unittest"); scoped_refptr cert = ImportCertFromFile(certs_dir, "subject_t61string_1-32.pem"); ASSERT_TRUE(cert); const CertPrincipal& subject = cert->subject(); EXPECT_EQ( "\x01\x02\x03\x04\x05\x06\x07\x08\x09\x0a\x0b\x0c\x0d\x0e\x0f\x10\x11\x12" "\x13\x14\x15\x16\x17\x18\x19\x1a\x1b\x1c\x1d\x1e\x1f\x20", subject.organization_names[0]); } TEST(X509CertificateTest, TeletexStringIsLatin1NotCp1252) { base::FilePath certs_dir = GetTestNetDataDirectory().AppendASCII("parse_certificate_unittest"); scoped_refptr cert = ImportCertFromFile(certs_dir, "subject_t61string_126-160.pem"); ASSERT_TRUE(cert); const CertPrincipal& subject = cert->subject(); // TeletexString is decoded as latin1, so 127-160 get decoded to equivalent // unicode control chars. EXPECT_EQ( "~\x7F\xC2\x80\xC2\x81\xC2\x82\xC2\x83\xC2\x84\xC2\x85\xC2\x86\xC2\x87" "\xC2\x88\xC2\x89\xC2\x8A\xC2\x8B\xC2\x8C\xC2\x8D\xC2\x8E\xC2\x8F\xC2\x90" "\xC2\x91\xC2\x92\xC2\x93\xC2\x94\xC2\x95\xC2\x96\xC2\x97\xC2\x98\xC2\x99" "\xC2\x9A\xC2\x9B\xC2\x9C\xC2\x9D\xC2\x9E\xC2\x9F\xC2\xA0", subject.organization_names[0]); } TEST(X509CertificateTest, TeletexStringIsNotARealT61String) { base::FilePath certs_dir = GetTestNetDataDirectory().AppendASCII("parse_certificate_unittest"); scoped_refptr cert = ImportCertFromFile(certs_dir, "subject_t61string_actual.pem"); ASSERT_TRUE(cert); const CertPrincipal& subject = cert->subject(); // If TeletexStrings were actually parsed according to T.61, this would be // "あ". (Probably. Not verified against a real implementation.) EXPECT_EQ("\x1B$@$\"", subject.organization_names[0]); } TEST(X509CertificateTest, SerialNumbers) { scoped_refptr google_cert( X509Certificate::CreateFromBytes(google_der)); ASSERT_TRUE(google_cert); static const uint8_t google_serial[16] = { 0x01,0x2a,0x39,0x76,0x0d,0x3f,0x4f,0xc9, 0x0b,0xe7,0xbd,0x2b,0xcf,0x95,0x2e,0x7a, }; ASSERT_EQ(sizeof(google_serial), google_cert->serial_number().size()); EXPECT_TRUE(memcmp(google_cert->serial_number().data(), google_serial, sizeof(google_serial)) == 0); } TEST(X509CertificateTest, SerialNumberZeroPadded) { base::FilePath certs_dir = GetTestNetDataDirectory().AppendASCII("parse_certificate_unittest"); scoped_refptr cert = ImportCertFromFile(certs_dir, "serial_zero_padded.pem"); ASSERT_TRUE(cert); // Check a serial number where the first byte is >= 0x80, the DER returned by // serial() should contain the leading 0 padding byte. static const uint8_t expected_serial[3] = {0x00, 0x80, 0x01}; ASSERT_EQ(sizeof(expected_serial), cert->serial_number().size()); EXPECT_TRUE(memcmp(cert->serial_number().data(), expected_serial, sizeof(expected_serial)) == 0); } TEST(X509CertificateTest, SerialNumberZeroPadded21BytesLong) { base::FilePath certs_dir = GetTestNetDataDirectory().AppendASCII("parse_certificate_unittest"); scoped_refptr cert = ImportCertFromFile(certs_dir, "serial_zero_padded_21_bytes.pem"); ASSERT_TRUE(cert); // Check a serial number where the first byte is >= 0x80, causing the encoded // length to be 21 bytes long. This should be an error, but serial number // parsing is currently permissive. static const uint8_t expected_serial[21] = { 0x00, 0x80, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f, 0x10, 0x11, 0x12, 0x13}; ASSERT_EQ(sizeof(expected_serial), cert->serial_number().size()); EXPECT_TRUE(memcmp(cert->serial_number().data(), expected_serial, sizeof(expected_serial)) == 0); } TEST(X509CertificateTest, SerialNumberNegative) { base::FilePath certs_dir = GetTestNetDataDirectory().AppendASCII("parse_certificate_unittest"); scoped_refptr cert = ImportCertFromFile(certs_dir, "serial_negative.pem"); ASSERT_TRUE(cert); // RFC 5280 does not allow serial numbers to be negative, but serial number // parsing is currently permissive, so this does not cause an error. static const uint8_t expected_serial[2] = {0x80, 0x01}; ASSERT_EQ(sizeof(expected_serial), cert->serial_number().size()); EXPECT_TRUE(memcmp(cert->serial_number().data(), expected_serial, sizeof(expected_serial)) == 0); } TEST(X509CertificateTest, SerialNumber37BytesLong) { base::FilePath certs_dir = GetTestNetDataDirectory().AppendASCII("parse_certificate_unittest"); scoped_refptr cert = ImportCertFromFile(certs_dir, "serial_37_bytes.pem"); ASSERT_TRUE(cert); // Check a serial number which is very long. This should be an error, but // serial number parsing is currently permissive. static const uint8_t expected_serial[37] = { 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f, 0x10, 0x11, 0x12, 0x13, 0x14, 0x15, 0x16, 0x17, 0x18, 0x19, 0x1a, 0x1b, 0x1c, 0x1d, 0x1e, 0x1f, 0x20, 0x21, 0x22, 0x23, 0x24, 0x25}; ASSERT_EQ(sizeof(expected_serial), cert->serial_number().size()); EXPECT_TRUE(memcmp(cert->serial_number().data(), expected_serial, sizeof(expected_serial)) == 0); } TEST(X509CertificateTest, SHA256FingerprintsCorrectly) { scoped_refptr google_cert( X509Certificate::CreateFromBytes(google_der)); ASSERT_TRUE(google_cert); const SHA256HashValue google_sha256_fingerprint = { {0x21, 0xaf, 0x58, 0x74, 0xea, 0x6b, 0xad, 0xbd, 0xe4, 0xb3, 0xb1, 0xaa, 0x53, 0x32, 0x80, 0x8f, 0xbf, 0x8a, 0x24, 0x7d, 0x98, 0xec, 0x7f, 0x77, 0x49, 0x38, 0x42, 0x81, 0x26, 0x7f, 0xed, 0x38}}; EXPECT_EQ(google_sha256_fingerprint, X509Certificate::CalculateFingerprint256( google_cert->cert_buffer())); } TEST(X509CertificateTest, CAFingerprints) { base::FilePath certs_dir = GetTestCertsDirectory(); scoped_refptr server_cert = ImportCertFromFile(certs_dir, "salesforce_com_test.pem"); ASSERT_NE(static_cast(nullptr), server_cert.get()); scoped_refptr intermediate_cert1 = ImportCertFromFile(certs_dir, "verisign_intermediate_ca_2011.pem"); ASSERT_NE(static_cast(nullptr), intermediate_cert1.get()); scoped_refptr intermediate_cert2 = ImportCertFromFile(certs_dir, "verisign_intermediate_ca_2016.pem"); ASSERT_NE(static_cast(nullptr), intermediate_cert2.get()); std::vector> intermediates; intermediates.push_back(bssl::UpRef(intermediate_cert1->cert_buffer())); scoped_refptr cert_chain1 = X509Certificate::CreateFromBuffer(bssl::UpRef(server_cert->cert_buffer()), std::move(intermediates)); ASSERT_TRUE(cert_chain1); intermediates.clear(); intermediates.push_back(bssl::UpRef(intermediate_cert2->cert_buffer())); scoped_refptr cert_chain2 = X509Certificate::CreateFromBuffer(bssl::UpRef(server_cert->cert_buffer()), std::move(intermediates)); ASSERT_TRUE(cert_chain2); // No intermediate CA certicates. intermediates.clear(); scoped_refptr cert_chain3 = X509Certificate::CreateFromBuffer(bssl::UpRef(server_cert->cert_buffer()), std::move(intermediates)); ASSERT_TRUE(cert_chain3); SHA256HashValue cert_chain1_chain_fingerprint_256 = { {0xac, 0xff, 0xcc, 0x63, 0x0d, 0xd0, 0xa7, 0x19, 0x78, 0xb5, 0x8a, 0x47, 0x8b, 0x67, 0x97, 0xcb, 0x8d, 0xe1, 0x6a, 0x8a, 0x57, 0x70, 0xda, 0x9a, 0x53, 0x72, 0xe2, 0xa0, 0x08, 0xab, 0xcc, 0x8f}}; SHA256HashValue cert_chain2_chain_fingerprint_256 = { {0x67, 0x3a, 0x11, 0x20, 0xd6, 0x94, 0x14, 0xe4, 0x16, 0x9f, 0x58, 0xe2, 0x8b, 0xf7, 0x27, 0xed, 0xbb, 0xe8, 0xa7, 0xff, 0x1c, 0x8c, 0x0f, 0x21, 0x38, 0x16, 0x7c, 0xad, 0x1f, 0x22, 0x6f, 0x9b}}; SHA256HashValue cert_chain3_chain_fingerprint_256 = { {0x16, 0x7a, 0xbd, 0xb4, 0x57, 0x04, 0x65, 0x3c, 0x3b, 0xef, 0x6e, 0x6a, 0xa6, 0x02, 0x73, 0x30, 0x3e, 0x34, 0x1b, 0x43, 0xc2, 0x7c, 0x98, 0x52, 0x9f, 0x34, 0x7f, 0x55, 0x97, 0xe9, 0x1a, 0x10}}; EXPECT_EQ(cert_chain1_chain_fingerprint_256, cert_chain1->CalculateChainFingerprint256()); EXPECT_EQ(cert_chain2_chain_fingerprint_256, cert_chain2->CalculateChainFingerprint256()); EXPECT_EQ(cert_chain3_chain_fingerprint_256, cert_chain3->CalculateChainFingerprint256()); } TEST(X509CertificateTest, ParseSubjectAltNames) { base::FilePath certs_dir = GetTestCertsDirectory(); scoped_refptr san_cert = ImportCertFromFile(certs_dir, "subjectAltName_sanity_check.pem"); ASSERT_NE(static_cast(nullptr), san_cert.get()); // Ensure that testing for SAN without using it is accepted. EXPECT_TRUE(san_cert->GetSubjectAltName(nullptr, nullptr)); // Ensure that it's possible to get just dNSNames. std::vector dns_names; EXPECT_TRUE(san_cert->GetSubjectAltName(&dns_names, nullptr)); // Ensure that it's possible to get just iPAddresses. std::vector ip_addresses; EXPECT_TRUE(san_cert->GetSubjectAltName(nullptr, &ip_addresses)); // Ensure that DNS names are correctly parsed. ASSERT_EQ(1U, dns_names.size()); EXPECT_EQ("test.example", dns_names[0]); // Ensure that both IPv4 and IPv6 addresses are correctly parsed. ASSERT_EQ(2U, ip_addresses.size()); static const uint8_t kIPv4Address[] = { 0x7F, 0x00, 0x00, 0x02 }; ASSERT_EQ(std::size(kIPv4Address), ip_addresses[0].size()); EXPECT_EQ( 0, memcmp(ip_addresses[0].data(), kIPv4Address, std::size(kIPv4Address))); static const uint8_t kIPv6Address[] = { 0xFE, 0x80, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x01 }; ASSERT_EQ(std::size(kIPv6Address), ip_addresses[1].size()); EXPECT_EQ( 0, memcmp(ip_addresses[1].data(), kIPv6Address, std::size(kIPv6Address))); // Ensure the subjectAltName dirName has not influenced the handling of // the subject commonName. EXPECT_EQ("127.0.0.1", san_cert->subject().common_name); scoped_refptr no_san_cert = ImportCertFromFile(certs_dir, "salesforce_com_test.pem"); ASSERT_NE(static_cast(nullptr), no_san_cert.get()); EXPECT_NE(0u, dns_names.size()); EXPECT_NE(0u, ip_addresses.size()); EXPECT_FALSE(no_san_cert->GetSubjectAltName(&dns_names, &ip_addresses)); EXPECT_EQ(0u, dns_names.size()); EXPECT_EQ(0u, ip_addresses.size()); } TEST(X509CertificateTest, ExtractSPKIFromDERCert) { base::FilePath certs_dir = GetTestCertsDirectory(); scoped_refptr cert = ImportCertFromFile(certs_dir, "nist.der"); ASSERT_NE(static_cast(nullptr), cert.get()); std::string_view spkiBytes; EXPECT_TRUE(asn1::ExtractSPKIFromDERCert( x509_util::CryptoBufferAsStringPiece(cert->cert_buffer()), &spkiBytes)); uint8_t hash[base::kSHA1Length]; base::SHA1HashBytes(reinterpret_cast(spkiBytes.data()), spkiBytes.size(), hash); EXPECT_EQ(0, memcmp(hash, kNistSPKIHash, sizeof(hash))); } TEST(X509CertificateTest, HasCanSignHttpExchangesDraftExtension) { base::FilePath certs_dir = GetTestCertsDirectory(); scoped_refptr cert = ImportCertFromFile( certs_dir, "can_sign_http_exchanges_draft_extension.pem"); ASSERT_NE(static_cast(nullptr), cert.get()); EXPECT_TRUE(asn1::HasCanSignHttpExchangesDraftExtension( x509_util::CryptoBufferAsStringPiece(cert->cert_buffer()))); } TEST(X509CertificateTest, HasCanSignHttpExchangesDraftExtensionInvalid) { base::FilePath certs_dir = GetTestCertsDirectory(); scoped_refptr cert = ImportCertFromFile( certs_dir, "can_sign_http_exchanges_draft_extension_invalid.pem"); ASSERT_NE(static_cast(nullptr), cert.get()); EXPECT_FALSE(asn1::HasCanSignHttpExchangesDraftExtension( x509_util::CryptoBufferAsStringPiece(cert->cert_buffer()))); } TEST(X509CertificateTest, DoesNotHaveCanSignHttpExchangesDraftExtension) { base::FilePath certs_dir = GetTestCertsDirectory(); scoped_refptr cert = ImportCertFromFile(certs_dir, "ok_cert.pem"); ASSERT_NE(static_cast(nullptr), cert.get()); EXPECT_FALSE(asn1::HasCanSignHttpExchangesDraftExtension( x509_util::CryptoBufferAsStringPiece(cert->cert_buffer()))); } TEST(X509CertificateTest, ExtractExtension) { base::FilePath certs_dir = GetTestCertsDirectory(); scoped_refptr cert = ImportCertFromFile(certs_dir, "ok_cert.pem"); ASSERT_TRUE(cert); bool present, critical; std::string_view contents; ASSERT_TRUE(asn1::ExtractExtensionFromDERCert( x509_util::CryptoBufferAsStringPiece(cert->cert_buffer()), bssl::der::Input(bssl::kBasicConstraintsOid).AsStringView(), &present, &critical, &contents)); EXPECT_TRUE(present); EXPECT_TRUE(critical); ASSERT_EQ(std::string_view("\x30\x00", 2), contents); static constexpr uint8_t kNonsenseOID[] = {0x56, 0x1d, 0x13}; ASSERT_TRUE(asn1::ExtractExtensionFromDERCert( x509_util::CryptoBufferAsStringPiece(cert->cert_buffer()), std::string_view(reinterpret_cast(kNonsenseOID), sizeof(kNonsenseOID)), &present, &critical, &contents)); ASSERT_FALSE(present); scoped_refptr uid_cert = ImportCertFromFile(certs_dir, "ct-test-embedded-with-uids.pem"); ASSERT_TRUE(uid_cert); ASSERT_TRUE(asn1::ExtractExtensionFromDERCert( x509_util::CryptoBufferAsStringPiece(uid_cert->cert_buffer()), bssl::der::Input(bssl::kBasicConstraintsOid).AsStringView(), &present, &critical, &contents)); EXPECT_TRUE(present); EXPECT_FALSE(critical); ASSERT_EQ(std::string_view("\x30\x00", 2), contents); } // Tests CRYPTO_BUFFER deduping via X509Certificate::CreateFromBuffer. We // call X509Certificate::CreateFromBuffer several times and observe whether // it returns a cached or new CRYPTO_BUFFER. TEST(X509CertificateTest, Cache) { bssl::UniquePtr google_cert_handle; bssl::UniquePtr thawte_cert_handle; // Add a single certificate to the certificate cache. google_cert_handle = x509_util::CreateCryptoBuffer(google_der); ASSERT_TRUE(google_cert_handle); scoped_refptr cert1( X509Certificate::CreateFromBuffer(std::move(google_cert_handle), {})); ASSERT_TRUE(cert1); // Add the same certificate, but as a new handle. google_cert_handle = x509_util::CreateCryptoBuffer(google_der); ASSERT_TRUE(google_cert_handle); scoped_refptr cert2( X509Certificate::CreateFromBuffer(std::move(google_cert_handle), {})); ASSERT_TRUE(cert2); // A new X509Certificate should be returned. EXPECT_NE(cert1.get(), cert2.get()); // But both instances should share the underlying OS certificate handle. EXPECT_EQ(cert1->cert_buffer(), cert2->cert_buffer()); EXPECT_EQ(0u, cert1->intermediate_buffers().size()); EXPECT_EQ(0u, cert2->intermediate_buffers().size()); // Add the same certificate, but this time with an intermediate. This // should result in the intermediate being cached. Note that this is not // a legitimate chain, but is suitable for testing. google_cert_handle = x509_util::CreateCryptoBuffer(google_der); thawte_cert_handle = x509_util::CreateCryptoBuffer(thawte_der); ASSERT_TRUE(google_cert_handle); ASSERT_TRUE(thawte_cert_handle); std::vector> intermediates; intermediates.push_back(std::move(thawte_cert_handle)); scoped_refptr cert3(X509Certificate::CreateFromBuffer( std::move(google_cert_handle), std::move(intermediates))); ASSERT_TRUE(cert3); // Test that the new certificate, even with intermediates, results in the // same underlying handle being used. EXPECT_EQ(cert1->cert_buffer(), cert3->cert_buffer()); // Though they use the same OS handle, the intermediates should be different. EXPECT_NE(cert1->intermediate_buffers().size(), cert3->intermediate_buffers().size()); } TEST(X509CertificateTest, CloneWithDifferentIntermediates) { CertificateList certs = CreateCertificateListFromFile( GetTestCertsDirectory(), "multi-root-chain1.pem", X509Certificate::FORMAT_PEM_CERT_SEQUENCE); ASSERT_EQ(4u, certs.size()); auto leaf_with_no_intermediates = certs[0]; { auto cloned = leaf_with_no_intermediates->CloneWithDifferentIntermediates({}); // Intermediates are equal, so should return a reference to the same object. EXPECT_EQ(leaf_with_no_intermediates.get(), cloned.get()); } { std::vector> intermediates; intermediates.push_back(bssl::UpRef(certs[1]->cert_buffer())); intermediates.push_back(bssl::UpRef(certs[2]->cert_buffer())); auto cloned = leaf_with_no_intermediates->CloneWithDifferentIntermediates( std::move(intermediates)); ASSERT_TRUE(cloned); EXPECT_NE(leaf_with_no_intermediates.get(), cloned.get()); EXPECT_EQ(leaf_with_no_intermediates->cert_buffer(), cloned->cert_buffer()); ExpectX509CertificateMembersEqual(leaf_with_no_intermediates, cloned); ASSERT_EQ(2u, cloned->intermediate_buffers().size()); EXPECT_TRUE(x509_util::CryptoBufferEqual( certs[1]->cert_buffer(), cloned->intermediate_buffers()[0].get())); EXPECT_TRUE(x509_util::CryptoBufferEqual( certs[2]->cert_buffer(), cloned->intermediate_buffers()[1].get())); } std::vector> leaf_intermediates; leaf_intermediates.push_back(bssl::UpRef(certs[1]->cert_buffer())); leaf_intermediates.push_back(bssl::UpRef(certs[2]->cert_buffer())); auto leaf_with_intermediates = X509Certificate::CreateFromBuffer( bssl::UpRef(certs[0]->cert_buffer()), std::move(leaf_intermediates)); ASSERT_TRUE(leaf_with_intermediates); { auto cloned = leaf_with_intermediates->CloneWithDifferentIntermediates({}); EXPECT_NE(leaf_with_intermediates.get(), cloned.get()); EXPECT_EQ(leaf_with_intermediates->cert_buffer(), cloned->cert_buffer()); ExpectX509CertificateMembersEqual(leaf_with_intermediates, cloned); ASSERT_EQ(0u, cloned->intermediate_buffers().size()); } { std::vector> intermediates; intermediates.push_back(bssl::UpRef(certs[1]->cert_buffer())); intermediates.push_back(bssl::UpRef(certs[2]->cert_buffer())); auto cloned = leaf_with_intermediates->CloneWithDifferentIntermediates( std::move(intermediates)); // Intermediates are equal, so should return a reference to the same object. EXPECT_EQ(leaf_with_intermediates.get(), cloned.get()); } { std::vector> intermediates; intermediates.push_back(bssl::UpRef(certs[2]->cert_buffer())); intermediates.push_back(bssl::UpRef(certs[1]->cert_buffer())); auto cloned = leaf_with_intermediates->CloneWithDifferentIntermediates( std::move(intermediates)); // Intermediates are different (same buffers but in different order). ASSERT_TRUE(cloned); EXPECT_NE(leaf_with_intermediates.get(), cloned.get()); EXPECT_EQ(leaf_with_intermediates->cert_buffer(), cloned->cert_buffer()); ExpectX509CertificateMembersEqual(leaf_with_intermediates, cloned); ASSERT_EQ(2u, cloned->intermediate_buffers().size()); EXPECT_TRUE(x509_util::CryptoBufferEqual( certs[2]->cert_buffer(), cloned->intermediate_buffers()[0].get())); EXPECT_TRUE(x509_util::CryptoBufferEqual( certs[1]->cert_buffer(), cloned->intermediate_buffers()[1].get())); } } TEST(X509CertificateTest, Pickle) { bssl::UniquePtr google_cert_handle = x509_util::CreateCryptoBuffer(google_der); ASSERT_TRUE(google_cert_handle); bssl::UniquePtr thawte_cert_handle = x509_util::CreateCryptoBuffer(thawte_der); ASSERT_TRUE(thawte_cert_handle); std::vector> intermediates; intermediates.push_back(std::move(thawte_cert_handle)); scoped_refptr cert = X509Certificate::CreateFromBuffer( std::move(google_cert_handle), std::move(intermediates)); ASSERT_TRUE(cert); base::Pickle pickle; cert->Persist(&pickle); base::PickleIterator iter(pickle); scoped_refptr cert_from_pickle = X509Certificate::CreateFromPickle(&iter); ASSERT_TRUE(cert_from_pickle); EXPECT_TRUE(x509_util::CryptoBufferEqual(cert->cert_buffer(), cert_from_pickle->cert_buffer())); const auto& cert_intermediates = cert->intermediate_buffers(); const auto& pickle_intermediates = cert_from_pickle->intermediate_buffers(); ASSERT_EQ(cert_intermediates.size(), pickle_intermediates.size()); for (size_t i = 0; i < cert_intermediates.size(); ++i) { EXPECT_TRUE(x509_util::CryptoBufferEqual(cert_intermediates[i].get(), pickle_intermediates[i].get())); } } TEST(X509CertificateTest, IntermediateCertificates) { scoped_refptr webkit_cert( X509Certificate::CreateFromBytes(webkit_der)); ASSERT_TRUE(webkit_cert); scoped_refptr thawte_cert( X509Certificate::CreateFromBytes(thawte_der)); ASSERT_TRUE(thawte_cert); bssl::UniquePtr google_handle; // Create object with no intermediates: google_handle = x509_util::CreateCryptoBuffer(google_der); scoped_refptr cert1; cert1 = X509Certificate::CreateFromBuffer(bssl::UpRef(google_handle.get()), {}); ASSERT_TRUE(cert1); EXPECT_EQ(0u, cert1->intermediate_buffers().size()); // Create object with 2 intermediates: std::vector> intermediates2; intermediates2.push_back(bssl::UpRef(webkit_cert->cert_buffer())); intermediates2.push_back(bssl::UpRef(thawte_cert->cert_buffer())); scoped_refptr cert2 = X509Certificate::CreateFromBuffer( std::move(google_handle), std::move(intermediates2)); ASSERT_TRUE(cert2); // Verify it has all the intermediates: const auto& cert2_intermediates = cert2->intermediate_buffers(); ASSERT_EQ(2u, cert2_intermediates.size()); EXPECT_TRUE(x509_util::CryptoBufferEqual(cert2_intermediates[0].get(), webkit_cert->cert_buffer())); EXPECT_TRUE(x509_util::CryptoBufferEqual(cert2_intermediates[1].get(), thawte_cert->cert_buffer())); } TEST(X509CertificateTest, Equals) { CertificateList certs = CreateCertificateListFromFile( GetTestCertsDirectory(), "multi-root-chain1.pem", X509Certificate::FORMAT_PEM_CERT_SEQUENCE); ASSERT_EQ(4u, certs.size()); // Comparing X509Certificates with no intermediates. EXPECT_TRUE(certs[0]->EqualsExcludingChain(certs[0].get())); EXPECT_FALSE(certs[1]->EqualsExcludingChain(certs[0].get())); EXPECT_FALSE(certs[0]->EqualsExcludingChain(certs[1].get())); EXPECT_TRUE(certs[0]->EqualsIncludingChain(certs[0].get())); EXPECT_FALSE(certs[1]->EqualsIncludingChain(certs[0].get())); EXPECT_FALSE(certs[0]->EqualsIncludingChain(certs[1].get())); std::vector> intermediates1; intermediates1.push_back(bssl::UpRef(certs[1]->cert_buffer())); scoped_refptr cert0_with_intermediate = X509Certificate::CreateFromBuffer(bssl::UpRef(certs[0]->cert_buffer()), std::move(intermediates1)); ASSERT_TRUE(cert0_with_intermediate); // Comparing X509Certificate with one intermediate to X509Certificate with no // intermediates. EXPECT_TRUE(certs[0]->EqualsExcludingChain(cert0_with_intermediate.get())); EXPECT_TRUE(cert0_with_intermediate->EqualsExcludingChain(certs[0].get())); EXPECT_FALSE(certs[0]->EqualsIncludingChain(cert0_with_intermediate.get())); EXPECT_FALSE(cert0_with_intermediate->EqualsIncludingChain(certs[0].get())); std::vector> intermediates2; intermediates2.push_back(bssl::UpRef(certs[2]->cert_buffer())); scoped_refptr cert0_with_intermediate2 = X509Certificate::CreateFromBuffer(bssl::UpRef(certs[0]->cert_buffer()), std::move(intermediates2)); ASSERT_TRUE(cert0_with_intermediate2); // Comparing X509Certificate with one intermediate to X509Certificate with // one different intermediate. EXPECT_TRUE(cert0_with_intermediate2->EqualsExcludingChain( cert0_with_intermediate.get())); EXPECT_TRUE(cert0_with_intermediate->EqualsExcludingChain( cert0_with_intermediate2.get())); EXPECT_FALSE(cert0_with_intermediate2->EqualsIncludingChain( cert0_with_intermediate.get())); EXPECT_FALSE(cert0_with_intermediate->EqualsIncludingChain( cert0_with_intermediate2.get())); std::vector> intermediates12; intermediates12.push_back(bssl::UpRef(certs[1]->cert_buffer())); intermediates12.push_back(bssl::UpRef(certs[2]->cert_buffer())); scoped_refptr cert0_with_intermediates12 = X509Certificate::CreateFromBuffer(bssl::UpRef(certs[0]->cert_buffer()), std::move(intermediates12)); ASSERT_TRUE(cert0_with_intermediates12); std::vector> intermediates21; intermediates21.push_back(bssl::UpRef(certs[2]->cert_buffer())); intermediates21.push_back(bssl::UpRef(certs[1]->cert_buffer())); scoped_refptr cert0_with_intermediates21 = X509Certificate::CreateFromBuffer(bssl::UpRef(certs[0]->cert_buffer()), std::move(intermediates21)); ASSERT_TRUE(cert0_with_intermediates21); // Comparing X509Certificate with two intermediates to X509Certificate with // same two intermediates but in reverse order EXPECT_TRUE(cert0_with_intermediates21->EqualsExcludingChain( cert0_with_intermediates12.get())); EXPECT_TRUE(cert0_with_intermediates12->EqualsExcludingChain( cert0_with_intermediates21.get())); EXPECT_FALSE(cert0_with_intermediates21->EqualsIncludingChain( cert0_with_intermediates12.get())); EXPECT_FALSE(cert0_with_intermediates12->EqualsIncludingChain( cert0_with_intermediates21.get())); std::vector> intermediates12b; intermediates12b.push_back(bssl::UpRef(certs[1]->cert_buffer())); intermediates12b.push_back(bssl::UpRef(certs[2]->cert_buffer())); scoped_refptr cert0_with_intermediates12b = X509Certificate::CreateFromBuffer(bssl::UpRef(certs[0]->cert_buffer()), std::move(intermediates12b)); ASSERT_TRUE(cert0_with_intermediates12b); // Comparing X509Certificate with two intermediates to X509Certificate with // same two intermediates in same order. EXPECT_TRUE(cert0_with_intermediates12->EqualsExcludingChain( cert0_with_intermediates12b.get())); EXPECT_TRUE(cert0_with_intermediates12b->EqualsExcludingChain( cert0_with_intermediates12.get())); EXPECT_TRUE(cert0_with_intermediates12->EqualsIncludingChain( cert0_with_intermediates12b.get())); EXPECT_TRUE(cert0_with_intermediates12b->EqualsIncludingChain( cert0_with_intermediates12.get())); } TEST(X509CertificateTest, IsIssuedByEncoded) { base::FilePath certs_dir = GetTestCertsDirectory(); // Test a client certificate from MIT. scoped_refptr mit_davidben_cert( ImportCertFromFile(certs_dir, "mit.davidben.der")); ASSERT_NE(static_cast(nullptr), mit_davidben_cert.get()); std::string mit_issuer(reinterpret_cast(MITDN), sizeof(MITDN)); // Test a certificate from Google, issued by Thawte scoped_refptr google_cert( ImportCertFromFile(certs_dir, "google.single.der")); ASSERT_NE(static_cast(nullptr), google_cert.get()); std::string thawte_issuer(reinterpret_cast(ThawteDN), sizeof(ThawteDN)); // Check that the David Ben certificate is issued by MIT, but not // by Thawte. std::vector issuers; issuers.clear(); issuers.push_back(mit_issuer); EXPECT_TRUE(mit_davidben_cert->IsIssuedByEncoded(issuers)); EXPECT_FALSE(google_cert->IsIssuedByEncoded(issuers)); // Check that the Google certificate is issued by Thawte and not // by MIT. issuers.clear(); issuers.push_back(thawte_issuer); EXPECT_FALSE(mit_davidben_cert->IsIssuedByEncoded(issuers)); EXPECT_TRUE(google_cert->IsIssuedByEncoded(issuers)); // Check that they both pass when given a list of the two issuers. issuers.clear(); issuers.push_back(mit_issuer); issuers.push_back(thawte_issuer); EXPECT_TRUE(mit_davidben_cert->IsIssuedByEncoded(issuers)); EXPECT_TRUE(google_cert->IsIssuedByEncoded(issuers)); } TEST(X509CertificateTest, IsSelfSigned) { base::FilePath certs_dir = GetTestCertsDirectory(); scoped_refptr cert( ImportCertFromFile(certs_dir, "mit.davidben.der")); ASSERT_NE(static_cast(nullptr), cert.get()); EXPECT_FALSE(X509Certificate::IsSelfSigned(cert->cert_buffer())); scoped_refptr self_signed( ImportCertFromFile(certs_dir, "root_ca_cert.pem")); ASSERT_NE(static_cast(nullptr), self_signed.get()); EXPECT_TRUE(X509Certificate::IsSelfSigned(self_signed->cert_buffer())); scoped_refptr bad_name( ImportCertFromFile(certs_dir, "self-signed-invalid-name.pem")); ASSERT_NE(static_cast(nullptr), bad_name.get()); EXPECT_FALSE(X509Certificate::IsSelfSigned(bad_name->cert_buffer())); scoped_refptr bad_sig( ImportCertFromFile(certs_dir, "self-signed-invalid-sig.pem")); ASSERT_NE(static_cast(nullptr), bad_sig.get()); EXPECT_FALSE(X509Certificate::IsSelfSigned(bad_sig->cert_buffer())); constexpr char invalid_cert_data[] = "this is not a certificate"; bssl::UniquePtr invalid_cert_handle = x509_util::CreateCryptoBuffer(std::string_view(invalid_cert_data)); ASSERT_TRUE(invalid_cert_handle); EXPECT_FALSE(X509Certificate::IsSelfSigned(invalid_cert_handle.get())); } TEST(X509CertificateTest, IsIssuedByEncodedWithIntermediates) { auto [leaf, intermediate, root] = CertBuilder::CreateSimpleChain3(); std::string intermediate_dn = intermediate->GetSubject(); std::string root_dn = root->GetSubject(); // Create an X509Certificate object containing the leaf and the intermediate // but not the root. scoped_refptr cert_chain = leaf->GetX509CertificateChain(); ASSERT_TRUE(cert_chain); // Check that the chain is issued by the intermediate. EXPECT_TRUE(cert_chain->IsIssuedByEncoded({intermediate_dn})); // Check that the chain is also issued by the root. EXPECT_TRUE(cert_chain->IsIssuedByEncoded({root_dn})); // Check that the chain is issued by either the intermediate or the root. EXPECT_TRUE(cert_chain->IsIssuedByEncoded({intermediate_dn, root_dn})); // Check that an empty issuers list returns false. EXPECT_FALSE(cert_chain->IsIssuedByEncoded({})); // Check that the chain is not issued by Verisign std::string verisign_issuer(reinterpret_cast(VerisignDN), sizeof(VerisignDN)); EXPECT_FALSE(cert_chain->IsIssuedByEncoded({verisign_issuer})); // Check that the chain is issued by root, though the extraneous Verisign // name is also given. EXPECT_TRUE(cert_chain->IsIssuedByEncoded({verisign_issuer, root_dn})); } const struct CertificateFormatTestData { const char* file_name; X509Certificate::Format format; SHA256HashValue* chain_fingerprints[3]; } kFormatTestData[] = { // DER Parsing - single certificate, DER encoded {"google.single.der", X509Certificate::FORMAT_SINGLE_CERTIFICATE, { &google_parse_fingerprint, nullptr, }}, // DER parsing - single certificate, PEM encoded {"google.single.pem", X509Certificate::FORMAT_SINGLE_CERTIFICATE, { &google_parse_fingerprint, nullptr, }}, // PEM parsing - single certificate, PEM encoded with a PEB of // "CERTIFICATE" {"google.single.pem", X509Certificate::FORMAT_PEM_CERT_SEQUENCE, { &google_parse_fingerprint, nullptr, }}, // PEM parsing - sequence of certificates, PEM encoded with a PEB of // "CERTIFICATE" {"google.chain.pem", X509Certificate::FORMAT_PEM_CERT_SEQUENCE, { &google_parse_fingerprint, &thawte_parse_fingerprint, nullptr, }}, // PKCS#7 parsing - "degenerate" SignedData collection of certificates, DER // encoding {"google.binary.p7b", X509Certificate::FORMAT_PKCS7, { &google_parse_fingerprint, &thawte_parse_fingerprint, nullptr, }}, // PKCS#7 parsing - "degenerate" SignedData collection of certificates, PEM // encoded with a PEM PEB of "CERTIFICATE" {"google.pem_cert.p7b", X509Certificate::FORMAT_PKCS7, { &google_parse_fingerprint, &thawte_parse_fingerprint, nullptr, }}, // PKCS#7 parsing - "degenerate" SignedData collection of certificates, PEM // encoded with a PEM PEB of "PKCS7" {"google.pem_pkcs7.p7b", X509Certificate::FORMAT_PKCS7, { &google_parse_fingerprint, &thawte_parse_fingerprint, nullptr, }}, // All of the above, this time using auto-detection {"google.single.der", X509Certificate::FORMAT_AUTO, { &google_parse_fingerprint, nullptr, }}, {"google.single.pem", X509Certificate::FORMAT_AUTO, { &google_parse_fingerprint, nullptr, }}, {"google.chain.pem", X509Certificate::FORMAT_AUTO, { &google_parse_fingerprint, &thawte_parse_fingerprint, nullptr, }}, {"google.binary.p7b", X509Certificate::FORMAT_AUTO, { &google_parse_fingerprint, &thawte_parse_fingerprint, nullptr, }}, {"google.pem_cert.p7b", X509Certificate::FORMAT_AUTO, { &google_parse_fingerprint, &thawte_parse_fingerprint, nullptr, }}, {"google.pem_pkcs7.p7b", X509Certificate::FORMAT_AUTO, { &google_parse_fingerprint, &thawte_parse_fingerprint, nullptr, }}, }; class X509CertificateParseTest : public testing::TestWithParam { public: ~X509CertificateParseTest() override = default; void SetUp() override { test_data_ = GetParam(); } void TearDown() override {} protected: CertificateFormatTestData test_data_; }; TEST_P(X509CertificateParseTest, CanParseFormat) { base::FilePath certs_dir = GetTestCertsDirectory(); CertificateList certs = CreateCertificateListFromFile( certs_dir, test_data_.file_name, test_data_.format); ASSERT_FALSE(certs.empty()); ASSERT_LE(certs.size(), std::size(test_data_.chain_fingerprints)); CheckGoogleCert(certs.front(), google_parse_fingerprint, kGoogleParseValidFrom, kGoogleParseValidTo); for (size_t i = 0; i < std::size(test_data_.chain_fingerprints); ++i) { if (!test_data_.chain_fingerprints[i]) { // No more test certificates expected - make sure no more were // returned before marking this test a success. EXPECT_EQ(i, certs.size()); break; } // A cert is expected - make sure that one was parsed. ASSERT_LT(i, certs.size()); ASSERT_TRUE(certs[i]); // Compare the parsed certificate with the expected certificate, by // comparing fingerprints. EXPECT_EQ( *test_data_.chain_fingerprints[i], X509Certificate::CalculateFingerprint256(certs[i]->cert_buffer())); } } INSTANTIATE_TEST_SUITE_P(All, X509CertificateParseTest, testing::ValuesIn(kFormatTestData)); struct CertificateNameVerifyTestData { // true iff we expect hostname to match an entry in cert_names. bool expected; // The hostname to match. const char* hostname; // Comma separated list of certificate names to match against. Any occurrence // of '#' will be replaced with a null character before processing. const char* dns_names; // Comma separated list of certificate IP Addresses to match against. Each // address is x prefixed 16 byte hex code for v6 or dotted-decimals for v4. const char* ip_addrs; }; // GTest 'magic' pretty-printer, so that if/when a test fails, it knows how // to output the parameter that was passed. Without this, it will simply // attempt to print out the first twenty bytes of the object, which depending // on platform and alignment, may result in an invalid read. void PrintTo(const CertificateNameVerifyTestData& data, std::ostream* os) { ASSERT_TRUE(data.hostname); ASSERT_TRUE(data.dns_names || data.ip_addrs); *os << " expected: " << data.expected << "; hostname: " << data.hostname << "; dns_names: " << (data.dns_names ? data.dns_names : "") << "; ip_addrs: " << (data.ip_addrs ? data.ip_addrs : ""); } const CertificateNameVerifyTestData kNameVerifyTestData[] = { {true, "foo.com", "foo.com"}, {true, "f", "f"}, {false, "h", "i"}, {true, "bar.foo.com", "*.foo.com"}, {true, "www.test.fr", "*.test.com,*.test.co.uk,*.test.de,*.test.fr"}, {true, "wwW.tESt.fr", ",*.*,*.test.de,*.test.FR,www"}, {false, "f.uk", ".uk"}, {false, "w.bar.foo.com", "?.bar.foo.com"}, {false, "www.foo.com", "(www|ftp).foo.com"}, {false, "www.foo.com", "www.foo.com#"}, // # = null char. {false, "www.foo.com", "www.foo.com#*.foo.com,#,#"}, {false, "www.house.example", "ww.house.example"}, {false, "test.org", "www.test.org,*.test.org,*.org"}, {false, "w.bar.foo.com", "w*.bar.foo.com"}, {false, "www.bar.foo.com", "ww*ww.bar.foo.com"}, {false, "wwww.bar.foo.com", "ww*ww.bar.foo.com"}, {false, "wwww.bar.foo.com", "w*w.bar.foo.com"}, {false, "wwww.bar.foo.com", "w*w.bar.foo.c0m"}, {false, "WALLY.bar.foo.com", "wa*.bar.foo.com"}, {false, "wally.bar.foo.com", "*Ly.bar.foo.com"}, // Hostname escaping tests {true, "ww%57.foo.com", "www.foo.com"}, {true, "www%2Efoo.com", "www.foo.com"}, {false, "www%00.foo.com", "www,foo.com,www.foo.com"}, {false, "www%0D.foo.com", "www.foo.com,www\r.foo.com"}, {false, "www%40foo.com", "www@foo.com"}, {false, "www%2E%2Efoo.com", "www.foo.com,www..foo.com"}, {false, "www%252Efoo.com", "www.foo.com"}, // IDN tests {true, "xn--poema-9qae5a.com.br", "xn--poema-9qae5a.com.br"}, {true, "www.xn--poema-9qae5a.com.br", "*.xn--poema-9qae5a.com.br"}, {false, "xn--poema-9qae5a.com.br", "*.xn--poema-9qae5a.com.br," "xn--poema-*.com.br," "xn--*-9qae5a.com.br," "*--poema-9qae5a.com.br"}, // The following are adapted from the examples quoted from // http://tools.ietf.org/html/rfc6125#section-6.4.3 // (e.g., *.example.com would match foo.example.com but // not bar.foo.example.com or example.com). {true, "foo.example.com", "*.example.com"}, {false, "bar.foo.example.com", "*.example.com"}, {false, "example.com", "*.example.com"}, // Partial wildcards are disallowed, though RFC 2818 rules allow them. // That is, forms such as baz*.example.net, *baz.example.net, and // b*z.example.net should NOT match domains. Instead, the wildcard must // always be the left-most label, and only a single label. {false, "baz1.example.net", "baz*.example.net"}, {false, "foobaz.example.net", "*baz.example.net"}, {false, "buzz.example.net", "b*z.example.net"}, {false, "www.test.example.net", "www.*.example.net"}, // Wildcards should not be valid for public registry controlled domains, // and unknown/unrecognized domains, at least three domain components must // be present. {true, "www.test.example", "*.test.example"}, {true, "test.example.co.uk", "*.example.co.uk"}, {false, "test.example", "*.example"}, {false, "example.co.uk", "*.co.uk"}, {false, "foo.com", "*.com"}, {false, "foo.us", "*.us"}, {false, "foo", "*"}, // IDN variants of wildcards and registry controlled domains. {true, "www.xn--poema-9qae5a.com.br", "*.xn--poema-9qae5a.com.br"}, {true, "test.example.xn--mgbaam7a8h", "*.example.xn--mgbaam7a8h"}, {false, "xn--poema-9qae5a.com.br", "*.com.br"}, {false, "example.xn--mgbaam7a8h", "*.xn--mgbaam7a8h"}, // Wildcards should be permissible for 'private' registry controlled // domains. {true, "www.appspot.com", "*.appspot.com"}, {true, "foo.s3.amazonaws.com", "*.s3.amazonaws.com"}, // Multiple wildcards are not valid. {false, "foo.example.com", "*.*.com"}, {false, "foo.bar.example.com", "*.bar.*.com"}, // Absolute vs relative DNS name tests. Although not explicitly specified // in RFC 6125, absolute reference names (those ending in a .) should // match either absolute or relative presented names. {true, "foo.com", "foo.com."}, {true, "foo.com.", "foo.com"}, {true, "foo.com.", "foo.com."}, {true, "f", "f."}, {true, "f.", "f"}, {true, "f.", "f."}, {true, "www-3.bar.foo.com", "*.bar.foo.com."}, {true, "www-3.bar.foo.com.", "*.bar.foo.com"}, {true, "www-3.bar.foo.com.", "*.bar.foo.com."}, {false, ".", "."}, {false, "example.com", "*.com."}, {false, "example.com.", "*.com"}, {false, "example.com.", "*.com."}, {false, "foo.", "*."}, {false, "foo", "*."}, {false, "foo.co.uk", "*.co.uk."}, {false, "foo.co.uk.", "*.co.uk."}, // IP addresses in subject alternative name {true, "10.1.2.3", "", "10.1.2.3"}, {true, "14.15", "", "14.0.0.15"}, {false, "10.1.2.7", "", "10.1.2.6,10.1.2.8"}, {false, "10.1.2.8", "foo"}, {true, "::4.5.6.7", "", "x00000000000000000000000004050607"}, {false, "::6.7.8.9", "::6.7.8.9", "x00000000000000000000000006070808,x0000000000000000000000000607080a," "xff000000000000000000000006070809,6.7.8.9"}, {true, "FE80::200:f8ff:fe21:67cf", "", "x00000000000000000000000006070808,xfe800000000000000200f8fffe2167cf," "xff0000000000000000000000060708ff,10.0.0.1"}, // Invalid hostnames with final numeric component. {false, "121.2.3.512", "1*1.2.3.512,*1.2.3.512,1*.2.3.512,*.2.3.512", "121.2.3.0"}, {false, "1.2.3.4.5.6", "*.2.3.4.5.6"}, {false, "1.2.3.4.5", "1.2.3.4.5"}, {false, "a.0.0.1", "*.0.0.1"}, // IP addresses in dNSName should not match commonName {false, "127.0.0.1", "127.0.0.1"}, {false, "127.0.0.1", "*.0.0.1"}, // Invalid host names. {false, ".", ""}, {false, ".", "."}, {false, "1.2.3.4..", "", "1.2.3.4"}, {false, "www..domain.example", "www.domain.example"}, {false, "www^domain.example", "www^domain.example"}, {false, "www%20.domain.example", "www .domain.example"}, {false, "www%2520.domain.example", "www .domain.example"}, {false, "www%5E.domain.example", "www^domain.example"}, {false, "www,domain.example", "www,domain.example"}, {false, "0x000000002200037955161..", "0x000000002200037955161"}, {false, "junk)(£)$*!@~#", "junk)(£)$*!@~#"}, {false, "www.*.com", "www.*.com"}, {false, "w$w.f.com", "w$w.f.com"}, {false, "nocolonallowed:example", "nocolonallowed:example"}, {false, "www-1.[::FFFF:129.144.52.38]", "*.[::FFFF:129.144.52.38]"}, {false, "[::4.5.6.9]", "", "x00000000000000000000000004050609"}, }; class X509CertificateNameVerifyTest : public testing::TestWithParam { }; TEST_P(X509CertificateNameVerifyTest, VerifyHostname) { CertificateNameVerifyTestData test_data = GetParam(); std::vector dns_names, ip_addressses; if (test_data.dns_names) { // Build up the certificate DNS names list. std::string dns_name_line(test_data.dns_names); std::replace(dns_name_line.begin(), dns_name_line.end(), '#', '\0'); dns_names = base::SplitString(dns_name_line, ",", base::TRIM_WHITESPACE, base::SPLIT_WANT_ALL); } if (test_data.ip_addrs) { // Build up the certificate IP address list. std::string ip_addrs_line(test_data.ip_addrs); std::vector ip_addressses_ascii = base::SplitString( ip_addrs_line, ",", base::TRIM_WHITESPACE, base::SPLIT_WANT_ALL); for (size_t i = 0; i < ip_addressses_ascii.size(); ++i) { std::string& addr_ascii = ip_addressses_ascii[i]; ASSERT_NE(0U, addr_ascii.length()); if (addr_ascii[0] == 'x') { // Hex encoded address addr_ascii.erase(0, 1); std::string bytes; EXPECT_TRUE(base::HexStringToString(addr_ascii, &bytes)) << "Could not parse hex address " << addr_ascii << " i = " << i; ip_addressses.push_back(std::move(bytes)); ASSERT_EQ(16U, ip_addressses.back().size()) << i; } else { // Decimal groups std::vector decimals_ascii_list = base::SplitString( addr_ascii, ".", base::TRIM_WHITESPACE, base::SPLIT_WANT_ALL); EXPECT_EQ(4U, decimals_ascii_list.size()) << i; std::string addr_bytes; for (const auto& decimals_ascii : decimals_ascii_list) { int decimal_value; EXPECT_TRUE(base::StringToInt(decimals_ascii, &decimal_value)); EXPECT_GE(decimal_value, 0); EXPECT_LE(decimal_value, 255); addr_bytes.push_back(static_cast(decimal_value)); } ip_addressses.push_back(addr_bytes); ASSERT_EQ(4U, ip_addressses.back().size()) << i; } } } EXPECT_EQ(test_data.expected, X509Certificate::VerifyHostname(test_data.hostname, dns_names, ip_addressses)); } INSTANTIATE_TEST_SUITE_P(All, X509CertificateNameVerifyTest, testing::ValuesIn(kNameVerifyTestData)); const struct PublicKeyInfoTestData { const char* file_name; size_t expected_bits; X509Certificate::PublicKeyType expected_type; } kPublicKeyInfoTestData[] = { {"rsa-768", 768, X509Certificate::kPublicKeyTypeRSA}, {"rsa-1024", 1024, X509Certificate::kPublicKeyTypeRSA}, {"rsa-2048", 2048, X509Certificate::kPublicKeyTypeRSA}, {"rsa-8200", 8200, X509Certificate::kPublicKeyTypeRSA}, {"ec-prime256v1", 256, X509Certificate::kPublicKeyTypeECDSA}, }; class X509CertificatePublicKeyInfoTest : public testing::TestWithParam { }; TEST_P(X509CertificatePublicKeyInfoTest, GetPublicKeyInfo) { PublicKeyInfoTestData data = GetParam(); auto [leaf, root] = CertBuilder::CreateSimpleChain2(); ASSERT_TRUE(leaf->UseKeyFromFile(GetTestCertsDirectory().AppendASCII( base::StrCat({data.file_name, "-1.key"})))); size_t actual_bits = 0; X509Certificate::PublicKeyType actual_type = X509Certificate::kPublicKeyTypeUnknown; X509Certificate::GetPublicKeyInfo(leaf->GetCertBuffer(), &actual_bits, &actual_type); EXPECT_EQ(data.expected_bits, actual_bits); EXPECT_EQ(data.expected_type, actual_type); } INSTANTIATE_TEST_SUITE_P(All, X509CertificatePublicKeyInfoTest, testing::ValuesIn(kPublicKeyInfoTestData)); } // namespace net