// Copyright 2015 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "net/cert/internal/parse_certificate.h" #include #include "base/strings/string_util.h" #include "net/cert/internal/cert_error_params.h" #include "net/cert/internal/cert_errors.h" #include "net/cert/internal/general_names.h" #include "net/der/input.h" #include "net/der/parse_values.h" #include "net/der/parser.h" namespace net { namespace { DEFINE_CERT_ERROR_ID(kCertificateNotSequence, "Failed parsing Certificate SEQUENCE"); DEFINE_CERT_ERROR_ID(kUnconsumedDataInsideCertificateSequence, "Unconsumed data inside Certificate SEQUENCE"); DEFINE_CERT_ERROR_ID(kUnconsumedDataAfterCertificateSequence, "Unconsumed data after Certificate SEQUENCE"); DEFINE_CERT_ERROR_ID(kTbsCertificateNotSequence, "Couldn't read tbsCertificate as SEQUENCE"); DEFINE_CERT_ERROR_ID( kSignatureAlgorithmNotSequence, "Couldn't read Certificate.signatureAlgorithm as SEQUENCE"); DEFINE_CERT_ERROR_ID(kSignatureValueNotBitString, "Couldn't read Certificate.signatureValue as BIT STRING"); DEFINE_CERT_ERROR_ID(kUnconsumedDataInsideTbsCertificateSequence, "Unconsumed data inside TBSCertificate"); DEFINE_CERT_ERROR_ID(kTbsNotSequence, "Failed parsing TBSCertificate SEQUENCE"); DEFINE_CERT_ERROR_ID(kFailedReadingVersion, "Failed reading version"); DEFINE_CERT_ERROR_ID(kFailedParsingVersion, "Failed parsing version"); DEFINE_CERT_ERROR_ID(kVersionExplicitlyV1, "Version explicitly V1 (should be omitted)"); DEFINE_CERT_ERROR_ID(kFailedReadingSerialNumber, "Failed reading serialNumber"); DEFINE_CERT_ERROR_ID(kFailedReadingSignatureValue, "Failed reading signature"); DEFINE_CERT_ERROR_ID(kFailedReadingIssuer, "Failed reading issuer"); DEFINE_CERT_ERROR_ID(kFailedReadingValidity, "Failed reading validity"); DEFINE_CERT_ERROR_ID(kFailedParsingValidity, "Failed parsing validity"); DEFINE_CERT_ERROR_ID(kFailedReadingSubject, "Failed reading subject"); DEFINE_CERT_ERROR_ID(kFailedReadingSpki, "Failed reading subjectPublicKeyInfo"); DEFINE_CERT_ERROR_ID(kFailedReadingIssuerUniqueId, "Failed reading issuerUniqueId"); DEFINE_CERT_ERROR_ID(kFailedParsingIssuerUniqueId, "Failed parsing issuerUniqueId"); DEFINE_CERT_ERROR_ID( kIssuerUniqueIdNotExpected, "Unexpected issuerUniqueId (must be V2 or V3 certificate)"); DEFINE_CERT_ERROR_ID(kFailedReadingSubjectUniqueId, "Failed reading subjectUniqueId"); DEFINE_CERT_ERROR_ID(kFailedParsingSubjectUniqueId, "Failed parsing subjectUniqueId"); DEFINE_CERT_ERROR_ID( kSubjectUniqueIdNotExpected, "Unexpected subjectUniqueId (must be V2 or V3 certificate)"); DEFINE_CERT_ERROR_ID(kFailedReadingExtensions, "Failed reading extensions SEQUENCE"); DEFINE_CERT_ERROR_ID(kUnexpectedExtensions, "Unexpected extensions (must be V3 certificate)"); DEFINE_CERT_ERROR_ID(kSerialNumberIsNegative, "Serial number is negative"); DEFINE_CERT_ERROR_ID(kSerialNumberIsZero, "Serial number is zero"); DEFINE_CERT_ERROR_ID(kSerialNumberLengthOver20, "Serial number is longer than 20 octets"); DEFINE_CERT_ERROR_ID(kSerialNumberNotValidInteger, "Serial number is not a valid INTEGER"); // Returns true if |input| is a SEQUENCE and nothing else. WARN_UNUSED_RESULT bool IsSequenceTLV(const der::Input& input) { der::Parser parser(input); der::Parser unused_sequence_parser; if (!parser.ReadSequence(&unused_sequence_parser)) return false; // Should by a single SEQUENCE by definition of the function. return !parser.HasMore(); } // Reads a SEQUENCE from |parser| and writes the full tag-length-value into // |out|. On failure |parser| may or may not have been advanced. WARN_UNUSED_RESULT bool ReadSequenceTLV(der::Parser* parser, der::Input* out) { return parser->ReadRawTLV(out) && IsSequenceTLV(*out); } // Parses a Version according to RFC 5280: // // Version ::= INTEGER { v1(0), v2(1), v3(2) } // // No value other that v1, v2, or v3 is allowed (and if given will fail). RFC // 5280 minimally requires the handling of v3 (and overwhelmingly these are the // certificate versions in use today): // // Implementations SHOULD be prepared to accept any version certificate. // At a minimum, conforming implementations MUST recognize version 3 // certificates. WARN_UNUSED_RESULT bool ParseVersion(const der::Input& in, CertificateVersion* version) { der::Parser parser(in); uint64_t version64; if (!parser.ReadUint64(&version64)) return false; switch (version64) { case 0: *version = CertificateVersion::V1; break; case 1: *version = CertificateVersion::V2; break; case 2: *version = CertificateVersion::V3; break; default: // Don't allow any other version identifier. return false; } // By definition the input to this function was a single INTEGER, so there // shouldn't be anything else after it. return !parser.HasMore(); } // Consumes a "Time" value (as defined by RFC 5280) from |parser|. On success // writes the result to |*out| and returns true. On failure no guarantees are // made about the state of |parser|. // // From RFC 5280: // // Time ::= CHOICE { // utcTime UTCTime, // generalTime GeneralizedTime } WARN_UNUSED_RESULT bool ReadTime(der::Parser* parser, der::GeneralizedTime* out) { der::Input value; der::Tag tag; if (!parser->ReadTagAndValue(&tag, &value)) return false; if (tag == der::kUtcTime) return der::ParseUTCTime(value, out); if (tag == der::kGeneralizedTime) return der::ParseGeneralizedTime(value, out); // Unrecognized tag. return false; } // Parses a DER-encoded "Validity" as specified by RFC 5280. Returns true on // success and sets the results in |not_before| and |not_after|: // // Validity ::= SEQUENCE { // notBefore Time, // notAfter Time } // // Note that upon success it is NOT guaranteed that |*not_before <= *not_after|. bool ParseValidity(const der::Input& validity_tlv, der::GeneralizedTime* not_before, der::GeneralizedTime* not_after) { der::Parser parser(validity_tlv); // Validity ::= SEQUENCE { der::Parser validity_parser; if (!parser.ReadSequence(&validity_parser)) return false; // notBefore Time, if (!ReadTime(&validity_parser, not_before)) return false; // notAfter Time } if (!ReadTime(&validity_parser, not_after)) return false; // By definition the input was a single Validity sequence, so there shouldn't // be unconsumed data. if (parser.HasMore()) return false; // The Validity type does not have an extension point. if (validity_parser.HasMore()) return false; // Note that RFC 5280 doesn't require notBefore to be <= // notAfter, so that will not be considered a "parsing" error here. Instead it // will be considered an expired certificate later when testing against the // current timestamp. return true; } // Returns true if every bit in |bits| is zero (including empty). WARN_UNUSED_RESULT bool BitStringIsAllZeros(const der::BitString& bits) { // Note that it is OK to read from the unused bits, since BitString parsing // guarantees they are all zero. for (size_t i = 0; i < bits.bytes().Length(); ++i) { if (bits.bytes().UnsafeData()[i] != 0) return false; } return true; } // Parses a DistributionPointName. // // Currently this implementation is only concerned with URIs encoded in // fullName and skips the rest (it does not fully parse the GeneralNames). // // URIs found in fullName are appended to |uris|. // // From RFC 5280: // // DistributionPointName ::= CHOICE { // fullName [0] GeneralNames, // nameRelativeToCRLIssuer [1] RelativeDistinguishedName } bool ParseDistributionPointName(const der::Input& dp_name, std::vector* uris) { bool has_full_name; der::Input der_full_name; if (!der::Parser(dp_name).ReadOptionalTag( der::kTagContextSpecific | der::kTagConstructed | 0, &der_full_name, &has_full_name)) { return false; } if (!has_full_name) { // Only process DistributionPoints which provide "fullName". return true; } // TODO(mattm): surface the CertErrors. CertErrors errors; std::unique_ptr full_name = GeneralNames::CreateFromValue(der_full_name, &errors); if (!full_name) return false; // This code is only interested in extracting the URIs from fullName. *uris = full_name->uniform_resource_identifiers; return true; } // RFC 5280, section 4.2.1.13. // // DistributionPoint ::= SEQUENCE { // distributionPoint [0] DistributionPointName OPTIONAL, // reasons [1] ReasonFlags OPTIONAL, // cRLIssuer [2] GeneralNames OPTIONAL } bool ParseAndAddDistributionPoint( der::Parser* parser, std::vector* distribution_points) { ParsedDistributionPoint distribution_point; // DistributionPoint ::= SEQUENCE { der::Parser distrib_point_parser; if (!parser->ReadSequence(&distrib_point_parser)) return false; // distributionPoint [0] DistributionPointName OPTIONAL, bool distribution_point_present; der::Input name; if (!distrib_point_parser.ReadOptionalTag( der::kTagContextSpecific | der::kTagConstructed | 0, &name, &distribution_point_present)) { return false; } if (!distribution_point_present) { // Only process DistributionPoints which provide a "distributionPoint". return true; } // reasons [1] ReasonFlags OPTIONAL, bool reasons_present; if (!distrib_point_parser.SkipOptionalTag(der::kTagContextSpecific | 1, &reasons_present)) { return false; } // If it contains a subset of reasons then we skip it. We aren't // interested in subsets of CRLs and the RFC states that there MUST be // a CRL that covers all reasons. if (reasons_present) { return true; } // Extract the URIs from the DistributionPointName. if (!ParseDistributionPointName(name, &distribution_point.uris)) return false; // cRLIssuer [2] GeneralNames OPTIONAL } bool crl_issuer_present; der::Input crl_issuer; if (!distrib_point_parser.ReadOptionalTag( der::kTagContextSpecific | der::kTagConstructed | 2, &crl_issuer, &crl_issuer_present)) { return false; } distribution_point.has_crl_issuer = crl_issuer_present; // TODO(eroman): Parse "cRLIssuer". if (distrib_point_parser.HasMore()) return false; distribution_points->push_back(std::move(distribution_point)); return true; } } // namespace ParsedTbsCertificate::ParsedTbsCertificate() = default; ParsedTbsCertificate::~ParsedTbsCertificate() = default; bool VerifySerialNumber(const der::Input& value, bool warnings_only, CertErrors* errors) { // If |warnings_only| was set to true, the exact same errors will be logged, // only they will be logged with a lower severity (warning rather than error). CertError::Severity error_severity = warnings_only ? CertError::SEVERITY_WARNING : CertError::SEVERITY_HIGH; bool negative; if (!der::IsValidInteger(value, &negative)) { errors->Add(error_severity, kSerialNumberNotValidInteger, nullptr); return false; } // RFC 5280 section 4.1.2.2: // // Note: Non-conforming CAs may issue certificates with serial numbers // that are negative or zero. Certificate users SHOULD be prepared to // gracefully handle such certificates. if (negative) errors->AddWarning(kSerialNumberIsNegative); if (value.Length() == 1 && value.UnsafeData()[0] == 0) errors->AddWarning(kSerialNumberIsZero); // RFC 5280 section 4.1.2.2: // // Certificate users MUST be able to handle serialNumber values up to 20 // octets. Conforming CAs MUST NOT use serialNumber values longer than 20 // octets. if (value.Length() > 20) { errors->Add(error_severity, kSerialNumberLengthOver20, CreateCertErrorParams1SizeT("length", value.Length())); return false; } return true; } bool ParseCertificate(const der::Input& certificate_tlv, der::Input* out_tbs_certificate_tlv, der::Input* out_signature_algorithm_tlv, der::BitString* out_signature_value, CertErrors* out_errors) { // |out_errors| is optional. But ensure it is non-null for the remainder of // this function. if (!out_errors) { CertErrors unused_errors; return ParseCertificate(certificate_tlv, out_tbs_certificate_tlv, out_signature_algorithm_tlv, out_signature_value, &unused_errors); } der::Parser parser(certificate_tlv); // Certificate ::= SEQUENCE { der::Parser certificate_parser; if (!parser.ReadSequence(&certificate_parser)) { out_errors->AddError(kCertificateNotSequence); return false; } // tbsCertificate TBSCertificate, if (!ReadSequenceTLV(&certificate_parser, out_tbs_certificate_tlv)) { out_errors->AddError(kTbsCertificateNotSequence); return false; } // signatureAlgorithm AlgorithmIdentifier, if (!ReadSequenceTLV(&certificate_parser, out_signature_algorithm_tlv)) { out_errors->AddError(kSignatureAlgorithmNotSequence); return false; } // signatureValue BIT STRING } if (!certificate_parser.ReadBitString(out_signature_value)) { out_errors->AddError(kSignatureValueNotBitString); return false; } // There isn't an extension point at the end of Certificate. if (certificate_parser.HasMore()) { out_errors->AddError(kUnconsumedDataInsideCertificateSequence); return false; } // By definition the input was a single Certificate, so there shouldn't be // unconsumed data. if (parser.HasMore()) { out_errors->AddError(kUnconsumedDataAfterCertificateSequence); return false; } return true; } // From RFC 5280 section 4.1: // // TBSCertificate ::= SEQUENCE { // version [0] EXPLICIT Version DEFAULT v1, // serialNumber CertificateSerialNumber, // signature AlgorithmIdentifier, // issuer Name, // validity Validity, // subject Name, // subjectPublicKeyInfo SubjectPublicKeyInfo, // issuerUniqueID [1] IMPLICIT UniqueIdentifier OPTIONAL, // -- If present, version MUST be v2 or v3 // subjectUniqueID [2] IMPLICIT UniqueIdentifier OPTIONAL, // -- If present, version MUST be v2 or v3 // extensions [3] EXPLICIT Extensions OPTIONAL // -- If present, version MUST be v3 // } bool ParseTbsCertificate(const der::Input& tbs_tlv, const ParseCertificateOptions& options, ParsedTbsCertificate* out, CertErrors* errors) { // The rest of this function assumes that |errors| is non-null. if (!errors) { CertErrors unused_errors; return ParseTbsCertificate(tbs_tlv, options, out, &unused_errors); } // TODO(crbug.com/634443): Add useful error information to |errors|. der::Parser parser(tbs_tlv); // TBSCertificate ::= SEQUENCE { der::Parser tbs_parser; if (!parser.ReadSequence(&tbs_parser)) { errors->AddError(kTbsNotSequence); return false; } // version [0] EXPLICIT Version DEFAULT v1, der::Input version; bool has_version; if (!tbs_parser.ReadOptionalTag(der::ContextSpecificConstructed(0), &version, &has_version)) { errors->AddError(kFailedReadingVersion); return false; } if (has_version) { if (!ParseVersion(version, &out->version)) { errors->AddError(kFailedParsingVersion); return false; } if (out->version == CertificateVersion::V1) { errors->AddError(kVersionExplicitlyV1); // The correct way to specify v1 is to omit the version field since v1 is // the DEFAULT. return false; } } else { out->version = CertificateVersion::V1; } // serialNumber CertificateSerialNumber, if (!tbs_parser.ReadTag(der::kInteger, &out->serial_number)) { errors->AddError(kFailedReadingSerialNumber); return false; } if (!VerifySerialNumber(out->serial_number, options.allow_invalid_serial_numbers, errors)) { // Invalid serial numbers are only considered fatal failures if // |!allow_invalid_serial_numbers|. if (!options.allow_invalid_serial_numbers) return false; } // signature AlgorithmIdentifier, if (!ReadSequenceTLV(&tbs_parser, &out->signature_algorithm_tlv)) { errors->AddError(kFailedReadingSignatureValue); return false; } // issuer Name, if (!ReadSequenceTLV(&tbs_parser, &out->issuer_tlv)) { errors->AddError(kFailedReadingIssuer); return false; } // validity Validity, der::Input validity_tlv; if (!tbs_parser.ReadRawTLV(&validity_tlv)) { errors->AddError(kFailedReadingValidity); return false; } if (!ParseValidity(validity_tlv, &out->validity_not_before, &out->validity_not_after)) { errors->AddError(kFailedParsingValidity); return false; } // subject Name, if (!ReadSequenceTLV(&tbs_parser, &out->subject_tlv)) { errors->AddError(kFailedReadingSubject); return false; } // subjectPublicKeyInfo SubjectPublicKeyInfo, if (!ReadSequenceTLV(&tbs_parser, &out->spki_tlv)) { errors->AddError(kFailedReadingSpki); return false; } // issuerUniqueID [1] IMPLICIT UniqueIdentifier OPTIONAL, // -- If present, version MUST be v2 or v3 der::Input issuer_unique_id; if (!tbs_parser.ReadOptionalTag(der::ContextSpecificPrimitive(1), &issuer_unique_id, &out->has_issuer_unique_id)) { errors->AddError(kFailedReadingIssuerUniqueId); return false; } if (out->has_issuer_unique_id) { if (!der::ParseBitString(issuer_unique_id, &out->issuer_unique_id)) { errors->AddError(kFailedParsingIssuerUniqueId); return false; } if (out->version != CertificateVersion::V2 && out->version != CertificateVersion::V3) { errors->AddError(kIssuerUniqueIdNotExpected); return false; } } // subjectUniqueID [2] IMPLICIT UniqueIdentifier OPTIONAL, // -- If present, version MUST be v2 or v3 der::Input subject_unique_id; if (!tbs_parser.ReadOptionalTag(der::ContextSpecificPrimitive(2), &subject_unique_id, &out->has_subject_unique_id)) { errors->AddError(kFailedReadingSubjectUniqueId); return false; } if (out->has_subject_unique_id) { if (!der::ParseBitString(subject_unique_id, &out->subject_unique_id)) { errors->AddError(kFailedParsingSubjectUniqueId); return false; } if (out->version != CertificateVersion::V2 && out->version != CertificateVersion::V3) { errors->AddError(kSubjectUniqueIdNotExpected); return false; } } // extensions [3] EXPLICIT Extensions OPTIONAL // -- If present, version MUST be v3 if (!tbs_parser.ReadOptionalTag(der::ContextSpecificConstructed(3), &out->extensions_tlv, &out->has_extensions)) { errors->AddError(kFailedReadingExtensions); return false; } if (out->has_extensions) { // extensions_tlv must be a single element. Also check that it is a // SEQUENCE. if (!IsSequenceTLV(out->extensions_tlv)) { errors->AddError(kFailedReadingExtensions); return false; } if (out->version != CertificateVersion::V3) { errors->AddError(kUnexpectedExtensions); return false; } } // Note that there IS an extension point at the end of TBSCertificate // (according to RFC 5912), so from that interpretation, unconsumed data would // be allowed in |tbs_parser|. // // However because only v1, v2, and v3 certificates are supported by the // parsing, there shouldn't be any subsequent data in those versions, so // reject. if (tbs_parser.HasMore()) { errors->AddError(kUnconsumedDataInsideTbsCertificateSequence); return false; } // By definition the input was a single TBSCertificate, so there shouldn't be // unconsumed data. if (parser.HasMore()) return false; return true; } // From RFC 5280: // // Extension ::= SEQUENCE { // extnID OBJECT IDENTIFIER, // critical BOOLEAN DEFAULT FALSE, // extnValue OCTET STRING // -- contains the DER encoding of an ASN.1 value // -- corresponding to the extension type identified // -- by extnID // } bool ParseExtension(const der::Input& extension_tlv, ParsedExtension* out) { der::Parser parser(extension_tlv); // Extension ::= SEQUENCE { der::Parser extension_parser; if (!parser.ReadSequence(&extension_parser)) return false; // extnID OBJECT IDENTIFIER, if (!extension_parser.ReadTag(der::kOid, &out->oid)) return false; // critical BOOLEAN DEFAULT FALSE, out->critical = false; bool has_critical; der::Input critical; if (!extension_parser.ReadOptionalTag(der::kBool, &critical, &has_critical)) return false; if (has_critical) { if (!der::ParseBool(critical, &out->critical)) return false; if (!out->critical) return false; // DER-encoding requires DEFAULT values be omitted. } // extnValue OCTET STRING if (!extension_parser.ReadTag(der::kOctetString, &out->value)) return false; // The Extension type does not have an extension point (everything goes in // extnValue). if (extension_parser.HasMore()) return false; // By definition the input was a single Extension sequence, so there shouldn't // be unconsumed data. if (parser.HasMore()) return false; return true; } der::Input KeyUsageOid() { // From RFC 5280: // // id-ce-keyUsage OBJECT IDENTIFIER ::= { id-ce 15 } // // In dotted notation: 2.5.29.15 static const uint8_t oid[] = {0x55, 0x1d, 0x0f}; return der::Input(oid); } der::Input SubjectAltNameOid() { // From RFC 5280: // // id-ce-subjectAltName OBJECT IDENTIFIER ::= { id-ce 17 } // // In dotted notation: 2.5.29.17 static const uint8_t oid[] = {0x55, 0x1d, 0x11}; return der::Input(oid); } der::Input BasicConstraintsOid() { // From RFC 5280: // // id-ce-basicConstraints OBJECT IDENTIFIER ::= { id-ce 19 } // // In dotted notation: 2.5.29.19 static const uint8_t oid[] = {0x55, 0x1d, 0x13}; return der::Input(oid); } der::Input NameConstraintsOid() { // From RFC 5280: // // id-ce-nameConstraints OBJECT IDENTIFIER ::= { id-ce 30 } // // In dotted notation: 2.5.29.30 static const uint8_t oid[] = {0x55, 0x1d, 0x1e}; return der::Input(oid); } der::Input CertificatePoliciesOid() { // From RFC 5280: // // id-ce-certificatePolicies OBJECT IDENTIFIER ::= { id-ce 32 } // // In dotted notation: 2.5.29.32 static const uint8_t oid[] = {0x55, 0x1d, 0x20}; return der::Input(oid); } der::Input PolicyConstraintsOid() { // From RFC 5280: // // id-ce-policyConstraints OBJECT IDENTIFIER ::= { id-ce 36 } // // In dotted notation: 2.5.29.36 static const uint8_t oid[] = {0x55, 0x1d, 0x24}; return der::Input(oid); } der::Input ExtKeyUsageOid() { // From RFC 5280: // // id-ce-extKeyUsage OBJECT IDENTIFIER ::= { id-ce 37 } // // In dotted notation: 2.5.29.37 static const uint8_t oid[] = {0x55, 0x1d, 0x25}; return der::Input(oid); } der::Input AuthorityInfoAccessOid() { // From RFC 5280: // // id-pe-authorityInfoAccess OBJECT IDENTIFIER ::= { id-pe 1 } // // In dotted notation: 1.3.6.1.5.5.7.1.1 static const uint8_t oid[] = {0x2B, 0x06, 0x01, 0x05, 0x05, 0x07, 0x01, 0x01}; return der::Input(oid); } der::Input AdCaIssuersOid() { // From RFC 5280: // // id-ad-caIssuers OBJECT IDENTIFIER ::= { id-ad 2 } // // In dotted notation: 1.3.6.1.5.5.7.48.2 static const uint8_t oid[] = {0x2B, 0x06, 0x01, 0x05, 0x05, 0x07, 0x30, 0x02}; return der::Input(oid); } der::Input AdOcspOid() { // From RFC 5280: // // id-ad-ocsp OBJECT IDENTIFIER ::= { id-ad 1 } // // In dotted notation: 1.3.6.1.5.5.7.48.1 static const uint8_t oid[] = {0x2B, 0x06, 0x01, 0x05, 0x05, 0x07, 0x30, 0x01}; return der::Input(oid); } der::Input CrlDistributionPointsOid() { // From RFC 5280: // // id-ce-cRLDistributionPoints OBJECT IDENTIFIER ::= { id-ce 31 } // // In dotted notation: 2.5.29.31 static const uint8_t oid[] = {0x55, 0x1d, 0x1f}; return der::Input(oid); } NET_EXPORT bool ParseExtensions( const der::Input& extensions_tlv, std::map* extensions) { der::Parser parser(extensions_tlv); // Extensions ::= SEQUENCE SIZE (1..MAX) OF Extension der::Parser extensions_parser; if (!parser.ReadSequence(&extensions_parser)) return false; // The Extensions SEQUENCE must contains at least 1 element (otherwise it // should have been omitted). if (!extensions_parser.HasMore()) return false; extensions->clear(); while (extensions_parser.HasMore()) { ParsedExtension extension; der::Input extension_tlv; if (!extensions_parser.ReadRawTLV(&extension_tlv)) return false; if (!ParseExtension(extension_tlv, &extension)) return false; bool is_duplicate = !extensions->insert(std::make_pair(extension.oid, extension)).second; // RFC 5280 says that an extension should not appear more than once. if (is_duplicate) return false; } // By definition the input was a single Extensions sequence, so there // shouldn't be unconsumed data. if (parser.HasMore()) return false; return true; } NET_EXPORT bool ConsumeExtension( const der::Input& oid, std::map* unconsumed_extensions, ParsedExtension* extension) { auto it = unconsumed_extensions->find(oid); if (it == unconsumed_extensions->end()) return false; *extension = it->second; unconsumed_extensions->erase(it); return true; } bool ParseBasicConstraints(const der::Input& basic_constraints_tlv, ParsedBasicConstraints* out) { der::Parser parser(basic_constraints_tlv); // BasicConstraints ::= SEQUENCE { der::Parser sequence_parser; if (!parser.ReadSequence(&sequence_parser)) return false; // cA BOOLEAN DEFAULT FALSE, out->is_ca = false; bool has_ca; der::Input ca; if (!sequence_parser.ReadOptionalTag(der::kBool, &ca, &has_ca)) return false; if (has_ca) { if (!der::ParseBool(ca, &out->is_ca)) return false; // TODO(eroman): Should reject if CA was set to false, since // DER-encoding requires DEFAULT values be omitted. In // practice however there are a lot of certificates that use // the broken encoding. } // pathLenConstraint INTEGER (0..MAX) OPTIONAL } der::Input encoded_path_len; if (!sequence_parser.ReadOptionalTag(der::kInteger, &encoded_path_len, &out->has_path_len)) { return false; } if (out->has_path_len) { // TODO(eroman): Surface reason for failure if length was longer than uint8. if (!der::ParseUint8(encoded_path_len, &out->path_len)) return false; } else { // Default initialize to 0 as a precaution. out->path_len = 0; } // There shouldn't be any unconsumed data in the extension. if (sequence_parser.HasMore()) return false; // By definition the input was a single BasicConstraints sequence, so there // shouldn't be unconsumed data. if (parser.HasMore()) return false; return true; } bool ParseKeyUsage(const der::Input& key_usage_tlv, der::BitString* key_usage) { der::Parser parser(key_usage_tlv); if (!parser.ReadBitString(key_usage)) return false; // By definition the input was a single BIT STRING. if (parser.HasMore()) return false; // RFC 5280 section 4.2.1.3: // // When the keyUsage extension appears in a certificate, at least // one of the bits MUST be set to 1. if (BitStringIsAllZeros(*key_usage)) return false; return true; } bool ParseAuthorityInfoAccess( const der::Input& authority_info_access_tlv, std::vector* out_ca_issuers_uris, std::vector* out_ocsp_uris) { der::Parser parser(authority_info_access_tlv); out_ca_issuers_uris->clear(); out_ocsp_uris->clear(); // AuthorityInfoAccessSyntax ::= // SEQUENCE SIZE (1..MAX) OF AccessDescription der::Parser sequence_parser; if (!parser.ReadSequence(&sequence_parser)) return false; if (!sequence_parser.HasMore()) return false; while (sequence_parser.HasMore()) { // AccessDescription ::= SEQUENCE { der::Parser access_description_sequence_parser; if (!sequence_parser.ReadSequence(&access_description_sequence_parser)) return false; // accessMethod OBJECT IDENTIFIER, der::Input access_method_oid; if (!access_description_sequence_parser.ReadTag(der::kOid, &access_method_oid)) return false; // accessLocation GeneralName } der::Tag access_location_tag; der::Input access_location_value; if (!access_description_sequence_parser.ReadTagAndValue( &access_location_tag, &access_location_value)) return false; // GeneralName ::= CHOICE { if (access_location_tag == der::ContextSpecificPrimitive(6)) { // uniformResourceIdentifier [6] IA5String, base::StringPiece uri = access_location_value.AsStringPiece(); if (!base::IsStringASCII(uri)) return false; if (access_method_oid == AdCaIssuersOid()) out_ca_issuers_uris->push_back(uri); else if (access_method_oid == AdOcspOid()) out_ocsp_uris->push_back(uri); } } return true; } ParsedDistributionPoint::ParsedDistributionPoint() = default; ParsedDistributionPoint::ParsedDistributionPoint( ParsedDistributionPoint&& other) = default; ParsedDistributionPoint::~ParsedDistributionPoint() = default; bool ParseCrlDistributionPoints( const der::Input& extension_value, std::vector* distribution_points) { distribution_points->clear(); // RFC 5280, section 4.2.1.13. // // CRLDistributionPoints ::= SEQUENCE SIZE (1..MAX) OF DistributionPoint der::Parser extension_value_parser(extension_value); der::Parser distribution_points_parser; if (!extension_value_parser.ReadSequence(&distribution_points_parser)) return false; if (extension_value_parser.HasMore()) return false; // Sequence must have a minimum of 1 item. if (!distribution_points_parser.HasMore()) return false; while (distribution_points_parser.HasMore()) { if (!ParseAndAddDistributionPoint(&distribution_points_parser, distribution_points)) return false; } return true; } } // namespace net