// Copyright 2009 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. // Package x509 parses X.509-encoded keys and certificates. package x509 import ( "bytes" "crypto" "crypto/ecdsa" "crypto/ed25519" "crypto/elliptic" "crypto/rsa" "crypto/sha1" "crypto/x509/pkix" "encoding/asn1" "encoding/pem" "errors" "fmt" "io" "math/big" "net" "net/url" "strconv" "time" "unicode" // Explicitly import these for their crypto.RegisterHash init side-effects. // Keep these as blank imports, even if they're imported above. _ "crypto/sha1" _ "crypto/sha256" _ "crypto/sha512" "golang.org/x/crypto/cryptobyte" cryptobyte_asn1 "golang.org/x/crypto/cryptobyte/asn1" ) // pkixPublicKey reflects a PKIX public key structure. See SubjectPublicKeyInfo // in RFC 3280. type pkixPublicKey struct { Algo pkix.AlgorithmIdentifier BitString asn1.BitString } // ParsePKIXPublicKey parses a public key in PKIX, ASN.1 DER form. // The encoded public key is a SubjectPublicKeyInfo structure // (see RFC 5280, Section 4.1). // // It returns a *rsa.PublicKey, *dsa.PublicKey, *ecdsa.PublicKey, or // ed25519.PublicKey. More types might be supported in the future. // // This kind of key is commonly encoded in PEM blocks of type "PUBLIC KEY". func ParsePKIXPublicKey(derBytes []byte) (pub interface{}, err error) { var pki publicKeyInfo if rest, err := asn1.Unmarshal(derBytes, &pki); err != nil { if _, err := asn1.Unmarshal(derBytes, &pkcs1PublicKey{}); err == nil { return nil, errors.New("x509: failed to parse public key (use ParsePKCS1PublicKey instead for this key format)") } return nil, err } else if len(rest) != 0 { return nil, errors.New("x509: trailing data after ASN.1 of public-key") } algo := getPublicKeyAlgorithmFromOID(pki.Algorithm.Algorithm) if algo == UnknownPublicKeyAlgorithm { return nil, errors.New("x509: unknown public key algorithm") } return parsePublicKey(algo, &pki) } func marshalPublicKey(pub interface{}) (publicKeyBytes []byte, publicKeyAlgorithm pkix.AlgorithmIdentifier, err error) { switch pub := pub.(type) { case *rsa.PublicKey: publicKeyBytes, err = asn1.Marshal(pkcs1PublicKey{ N: pub.N, E: pub.E, }) if err != nil { return nil, pkix.AlgorithmIdentifier{}, err } publicKeyAlgorithm.Algorithm = oidPublicKeyRSA // This is a NULL parameters value which is required by // RFC 3279, Section 2.3.1. publicKeyAlgorithm.Parameters = asn1.NullRawValue case *ecdsa.PublicKey: publicKeyBytes = elliptic.Marshal(pub.Curve, pub.X, pub.Y) oid, ok := oidFromNamedCurve(pub.Curve) if !ok { return nil, pkix.AlgorithmIdentifier{}, errors.New("x509: unsupported elliptic curve") } publicKeyAlgorithm.Algorithm = oidPublicKeyECDSA var paramBytes []byte paramBytes, err = asn1.Marshal(oid) if err != nil { return } publicKeyAlgorithm.Parameters.FullBytes = paramBytes case ed25519.PublicKey: publicKeyBytes = pub publicKeyAlgorithm.Algorithm = oidPublicKeyEd25519 default: return nil, pkix.AlgorithmIdentifier{}, fmt.Errorf("x509: unsupported public key type: %T", pub) } return publicKeyBytes, publicKeyAlgorithm, nil } // MarshalPKIXPublicKey converts a public key to PKIX, ASN.1 DER form. // The encoded public key is a SubjectPublicKeyInfo structure // (see RFC 5280, Section 4.1). // // The following key types are currently supported: *rsa.PublicKey, *ecdsa.PublicKey // and ed25519.PublicKey. Unsupported key types result in an error. // // This kind of key is commonly encoded in PEM blocks of type "PUBLIC KEY". func MarshalPKIXPublicKey(pub interface{}) ([]byte, error) { var publicKeyBytes []byte var publicKeyAlgorithm pkix.AlgorithmIdentifier var err error if publicKeyBytes, publicKeyAlgorithm, err = marshalPublicKey(pub); err != nil { return nil, err } pkix := pkixPublicKey{ Algo: publicKeyAlgorithm, BitString: asn1.BitString{ Bytes: publicKeyBytes, BitLength: 8 * len(publicKeyBytes), }, } ret, _ := asn1.Marshal(pkix) return ret, nil } // These structures reflect the ASN.1 structure of X.509 certificates.: type certificate struct { Raw asn1.RawContent TBSCertificate tbsCertificate SignatureAlgorithm pkix.AlgorithmIdentifier SignatureValue asn1.BitString } type tbsCertificate struct { Raw asn1.RawContent Version int `asn1:"optional,explicit,default:0,tag:0"` SerialNumber *big.Int SignatureAlgorithm pkix.AlgorithmIdentifier Issuer asn1.RawValue Validity validity Subject asn1.RawValue PublicKey publicKeyInfo UniqueId asn1.BitString `asn1:"optional,tag:1"` SubjectUniqueId asn1.BitString `asn1:"optional,tag:2"` Extensions []pkix.Extension `asn1:"optional,explicit,tag:3"` } type dsaAlgorithmParameters struct { P, Q, G *big.Int } type validity struct { NotBefore, NotAfter time.Time } type publicKeyInfo struct { Raw asn1.RawContent Algorithm pkix.AlgorithmIdentifier PublicKey asn1.BitString } // RFC 5280, 4.2.1.1 type authKeyId struct { Id []byte `asn1:"optional,tag:0"` } type SignatureAlgorithm int const ( UnknownSignatureAlgorithm SignatureAlgorithm = iota MD2WithRSA // Unsupported. MD5WithRSA // Only supported for signing, not verification. SHA1WithRSA SHA256WithRSA SHA384WithRSA SHA512WithRSA DSAWithSHA1 // Unsupported. DSAWithSHA256 // Unsupported. ECDSAWithSHA1 ECDSAWithSHA256 ECDSAWithSHA384 ECDSAWithSHA512 SHA256WithRSAPSS SHA384WithRSAPSS SHA512WithRSAPSS PureEd25519 ) func (algo SignatureAlgorithm) isRSAPSS() bool { switch algo { case SHA256WithRSAPSS, SHA384WithRSAPSS, SHA512WithRSAPSS: return true default: return false } } func (algo SignatureAlgorithm) String() string { for _, details := range signatureAlgorithmDetails { if details.algo == algo { return details.name } } return strconv.Itoa(int(algo)) } type PublicKeyAlgorithm int const ( UnknownPublicKeyAlgorithm PublicKeyAlgorithm = iota RSA DSA // Unsupported. ECDSA Ed25519 ) var publicKeyAlgoName = [...]string{ RSA: "RSA", DSA: "DSA", ECDSA: "ECDSA", Ed25519: "Ed25519", } func (algo PublicKeyAlgorithm) String() string { if 0 < algo && int(algo) < len(publicKeyAlgoName) { return publicKeyAlgoName[algo] } return strconv.Itoa(int(algo)) } // OIDs for signature algorithms // // pkcs-1 OBJECT IDENTIFIER ::= { // iso(1) member-body(2) us(840) rsadsi(113549) pkcs(1) 1 } // // // RFC 3279 2.2.1 RSA Signature Algorithms // // md2WithRSAEncryption OBJECT IDENTIFIER ::= { pkcs-1 2 } // // md5WithRSAEncryption OBJECT IDENTIFIER ::= { pkcs-1 4 } // // sha-1WithRSAEncryption OBJECT IDENTIFIER ::= { pkcs-1 5 } // // dsaWithSha1 OBJECT IDENTIFIER ::= { // iso(1) member-body(2) us(840) x9-57(10040) x9cm(4) 3 } // // RFC 3279 2.2.3 ECDSA Signature Algorithm // // ecdsa-with-SHA1 OBJECT IDENTIFIER ::= { // iso(1) member-body(2) us(840) ansi-x962(10045) // signatures(4) ecdsa-with-SHA1(1)} // // // RFC 4055 5 PKCS #1 Version 1.5 // // sha256WithRSAEncryption OBJECT IDENTIFIER ::= { pkcs-1 11 } // // sha384WithRSAEncryption OBJECT IDENTIFIER ::= { pkcs-1 12 } // // sha512WithRSAEncryption OBJECT IDENTIFIER ::= { pkcs-1 13 } // // // RFC 5758 3.1 DSA Signature Algorithms // // dsaWithSha256 OBJECT IDENTIFIER ::= { // joint-iso-ccitt(2) country(16) us(840) organization(1) gov(101) // csor(3) algorithms(4) id-dsa-with-sha2(3) 2} // // RFC 5758 3.2 ECDSA Signature Algorithm // // ecdsa-with-SHA256 OBJECT IDENTIFIER ::= { iso(1) member-body(2) // us(840) ansi-X9-62(10045) signatures(4) ecdsa-with-SHA2(3) 2 } // // ecdsa-with-SHA384 OBJECT IDENTIFIER ::= { iso(1) member-body(2) // us(840) ansi-X9-62(10045) signatures(4) ecdsa-with-SHA2(3) 3 } // // ecdsa-with-SHA512 OBJECT IDENTIFIER ::= { iso(1) member-body(2) // us(840) ansi-X9-62(10045) signatures(4) ecdsa-with-SHA2(3) 4 } // // // RFC 8410 3 Curve25519 and Curve448 Algorithm Identifiers // // id-Ed25519 OBJECT IDENTIFIER ::= { 1 3 101 112 } var ( oidSignatureMD2WithRSA = asn1.ObjectIdentifier{1, 2, 840, 113549, 1, 1, 2} oidSignatureMD5WithRSA = asn1.ObjectIdentifier{1, 2, 840, 113549, 1, 1, 4} oidSignatureSHA1WithRSA = asn1.ObjectIdentifier{1, 2, 840, 113549, 1, 1, 5} oidSignatureSHA256WithRSA = asn1.ObjectIdentifier{1, 2, 840, 113549, 1, 1, 11} oidSignatureSHA384WithRSA = asn1.ObjectIdentifier{1, 2, 840, 113549, 1, 1, 12} oidSignatureSHA512WithRSA = asn1.ObjectIdentifier{1, 2, 840, 113549, 1, 1, 13} oidSignatureRSAPSS = asn1.ObjectIdentifier{1, 2, 840, 113549, 1, 1, 10} oidSignatureDSAWithSHA1 = asn1.ObjectIdentifier{1, 2, 840, 10040, 4, 3} oidSignatureDSAWithSHA256 = asn1.ObjectIdentifier{2, 16, 840, 1, 101, 3, 4, 3, 2} oidSignatureECDSAWithSHA1 = asn1.ObjectIdentifier{1, 2, 840, 10045, 4, 1} oidSignatureECDSAWithSHA256 = asn1.ObjectIdentifier{1, 2, 840, 10045, 4, 3, 2} oidSignatureECDSAWithSHA384 = asn1.ObjectIdentifier{1, 2, 840, 10045, 4, 3, 3} oidSignatureECDSAWithSHA512 = asn1.ObjectIdentifier{1, 2, 840, 10045, 4, 3, 4} oidSignatureEd25519 = asn1.ObjectIdentifier{1, 3, 101, 112} oidSHA256 = asn1.ObjectIdentifier{2, 16, 840, 1, 101, 3, 4, 2, 1} oidSHA384 = asn1.ObjectIdentifier{2, 16, 840, 1, 101, 3, 4, 2, 2} oidSHA512 = asn1.ObjectIdentifier{2, 16, 840, 1, 101, 3, 4, 2, 3} oidMGF1 = asn1.ObjectIdentifier{1, 2, 840, 113549, 1, 1, 8} // oidISOSignatureSHA1WithRSA means the same as oidSignatureSHA1WithRSA // but it's specified by ISO. Microsoft's makecert.exe has been known // to produce certificates with this OID. oidISOSignatureSHA1WithRSA = asn1.ObjectIdentifier{1, 3, 14, 3, 2, 29} ) var signatureAlgorithmDetails = []struct { algo SignatureAlgorithm name string oid asn1.ObjectIdentifier pubKeyAlgo PublicKeyAlgorithm hash crypto.Hash }{ {MD2WithRSA, "MD2-RSA", oidSignatureMD2WithRSA, RSA, crypto.Hash(0) /* no value for MD2 */}, {MD5WithRSA, "MD5-RSA", oidSignatureMD5WithRSA, RSA, crypto.MD5}, {SHA1WithRSA, "SHA1-RSA", oidSignatureSHA1WithRSA, RSA, crypto.SHA1}, {SHA1WithRSA, "SHA1-RSA", oidISOSignatureSHA1WithRSA, RSA, crypto.SHA1}, {SHA256WithRSA, "SHA256-RSA", oidSignatureSHA256WithRSA, RSA, crypto.SHA256}, {SHA384WithRSA, "SHA384-RSA", oidSignatureSHA384WithRSA, RSA, crypto.SHA384}, {SHA512WithRSA, "SHA512-RSA", oidSignatureSHA512WithRSA, RSA, crypto.SHA512}, {SHA256WithRSAPSS, "SHA256-RSAPSS", oidSignatureRSAPSS, RSA, crypto.SHA256}, {SHA384WithRSAPSS, "SHA384-RSAPSS", oidSignatureRSAPSS, RSA, crypto.SHA384}, {SHA512WithRSAPSS, "SHA512-RSAPSS", oidSignatureRSAPSS, RSA, crypto.SHA512}, {DSAWithSHA1, "DSA-SHA1", oidSignatureDSAWithSHA1, DSA, crypto.SHA1}, {DSAWithSHA256, "DSA-SHA256", oidSignatureDSAWithSHA256, DSA, crypto.SHA256}, {ECDSAWithSHA1, "ECDSA-SHA1", oidSignatureECDSAWithSHA1, ECDSA, crypto.SHA1}, {ECDSAWithSHA256, "ECDSA-SHA256", oidSignatureECDSAWithSHA256, ECDSA, crypto.SHA256}, {ECDSAWithSHA384, "ECDSA-SHA384", oidSignatureECDSAWithSHA384, ECDSA, crypto.SHA384}, {ECDSAWithSHA512, "ECDSA-SHA512", oidSignatureECDSAWithSHA512, ECDSA, crypto.SHA512}, {PureEd25519, "Ed25519", oidSignatureEd25519, Ed25519, crypto.Hash(0) /* no pre-hashing */}, } // hashToPSSParameters contains the DER encoded RSA PSS parameters for the // SHA256, SHA384, and SHA512 hashes as defined in RFC 3447, Appendix A.2.3. // The parameters contain the following values: // * hashAlgorithm contains the associated hash identifier with NULL parameters // * maskGenAlgorithm always contains the default mgf1SHA1 identifier // * saltLength contains the length of the associated hash // * trailerField always contains the default trailerFieldBC value var hashToPSSParameters = map[crypto.Hash]asn1.RawValue{ crypto.SHA256: asn1.RawValue{FullBytes: []byte{48, 52, 160, 15, 48, 13, 6, 9, 96, 134, 72, 1, 101, 3, 4, 2, 1, 5, 0, 161, 28, 48, 26, 6, 9, 42, 134, 72, 134, 247, 13, 1, 1, 8, 48, 13, 6, 9, 96, 134, 72, 1, 101, 3, 4, 2, 1, 5, 0, 162, 3, 2, 1, 32}}, crypto.SHA384: asn1.RawValue{FullBytes: []byte{48, 52, 160, 15, 48, 13, 6, 9, 96, 134, 72, 1, 101, 3, 4, 2, 2, 5, 0, 161, 28, 48, 26, 6, 9, 42, 134, 72, 134, 247, 13, 1, 1, 8, 48, 13, 6, 9, 96, 134, 72, 1, 101, 3, 4, 2, 2, 5, 0, 162, 3, 2, 1, 48}}, crypto.SHA512: asn1.RawValue{FullBytes: []byte{48, 52, 160, 15, 48, 13, 6, 9, 96, 134, 72, 1, 101, 3, 4, 2, 3, 5, 0, 161, 28, 48, 26, 6, 9, 42, 134, 72, 134, 247, 13, 1, 1, 8, 48, 13, 6, 9, 96, 134, 72, 1, 101, 3, 4, 2, 3, 5, 0, 162, 3, 2, 1, 64}}, } // pssParameters reflects the parameters in an AlgorithmIdentifier that // specifies RSA PSS. See RFC 3447, Appendix A.2.3. type pssParameters struct { // The following three fields are not marked as // optional because the default values specify SHA-1, // which is no longer suitable for use in signatures. Hash pkix.AlgorithmIdentifier `asn1:"explicit,tag:0"` MGF pkix.AlgorithmIdentifier `asn1:"explicit,tag:1"` SaltLength int `asn1:"explicit,tag:2"` TrailerField int `asn1:"optional,explicit,tag:3,default:1"` } func getSignatureAlgorithmFromAI(ai pkix.AlgorithmIdentifier) SignatureAlgorithm { if ai.Algorithm.Equal(oidSignatureEd25519) { // RFC 8410, Section 3 // > For all of the OIDs, the parameters MUST be absent. if len(ai.Parameters.FullBytes) != 0 { return UnknownSignatureAlgorithm } } if !ai.Algorithm.Equal(oidSignatureRSAPSS) { for _, details := range signatureAlgorithmDetails { if ai.Algorithm.Equal(details.oid) { return details.algo } } return UnknownSignatureAlgorithm } // RSA PSS is special because it encodes important parameters // in the Parameters. var params pssParameters if _, err := asn1.Unmarshal(ai.Parameters.FullBytes, ¶ms); err != nil { return UnknownSignatureAlgorithm } var mgf1HashFunc pkix.AlgorithmIdentifier if _, err := asn1.Unmarshal(params.MGF.Parameters.FullBytes, &mgf1HashFunc); err != nil { return UnknownSignatureAlgorithm } // PSS is greatly overburdened with options. This code forces them into // three buckets by requiring that the MGF1 hash function always match the // message hash function (as recommended in RFC 3447, Section 8.1), that the // salt length matches the hash length, and that the trailer field has the // default value. if (len(params.Hash.Parameters.FullBytes) != 0 && !bytes.Equal(params.Hash.Parameters.FullBytes, asn1.NullBytes)) || !params.MGF.Algorithm.Equal(oidMGF1) || !mgf1HashFunc.Algorithm.Equal(params.Hash.Algorithm) || (len(mgf1HashFunc.Parameters.FullBytes) != 0 && !bytes.Equal(mgf1HashFunc.Parameters.FullBytes, asn1.NullBytes)) || params.TrailerField != 1 { return UnknownSignatureAlgorithm } switch { case params.Hash.Algorithm.Equal(oidSHA256) && params.SaltLength == 32: return SHA256WithRSAPSS case params.Hash.Algorithm.Equal(oidSHA384) && params.SaltLength == 48: return SHA384WithRSAPSS case params.Hash.Algorithm.Equal(oidSHA512) && params.SaltLength == 64: return SHA512WithRSAPSS } return UnknownSignatureAlgorithm } // RFC 3279, 2.3 Public Key Algorithms // // pkcs-1 OBJECT IDENTIFIER ::== { iso(1) member-body(2) us(840) // rsadsi(113549) pkcs(1) 1 } // // rsaEncryption OBJECT IDENTIFIER ::== { pkcs1-1 1 } // // id-dsa OBJECT IDENTIFIER ::== { iso(1) member-body(2) us(840) // x9-57(10040) x9cm(4) 1 } // // RFC 5480, 2.1.1 Unrestricted Algorithm Identifier and Parameters // // id-ecPublicKey OBJECT IDENTIFIER ::= { // iso(1) member-body(2) us(840) ansi-X9-62(10045) keyType(2) 1 } var ( oidPublicKeyRSA = asn1.ObjectIdentifier{1, 2, 840, 113549, 1, 1, 1} oidPublicKeyDSA = asn1.ObjectIdentifier{1, 2, 840, 10040, 4, 1} oidPublicKeyECDSA = asn1.ObjectIdentifier{1, 2, 840, 10045, 2, 1} oidPublicKeyEd25519 = oidSignatureEd25519 ) func getPublicKeyAlgorithmFromOID(oid asn1.ObjectIdentifier) PublicKeyAlgorithm { switch { case oid.Equal(oidPublicKeyRSA): return RSA case oid.Equal(oidPublicKeyDSA): return DSA case oid.Equal(oidPublicKeyECDSA): return ECDSA case oid.Equal(oidPublicKeyEd25519): return Ed25519 } return UnknownPublicKeyAlgorithm } // RFC 5480, 2.1.1.1. Named Curve // // secp224r1 OBJECT IDENTIFIER ::= { // iso(1) identified-organization(3) certicom(132) curve(0) 33 } // // secp256r1 OBJECT IDENTIFIER ::= { // iso(1) member-body(2) us(840) ansi-X9-62(10045) curves(3) // prime(1) 7 } // // secp384r1 OBJECT IDENTIFIER ::= { // iso(1) identified-organization(3) certicom(132) curve(0) 34 } // // secp521r1 OBJECT IDENTIFIER ::= { // iso(1) identified-organization(3) certicom(132) curve(0) 35 } // // NB: secp256r1 is equivalent to prime256v1 var ( oidNamedCurveP224 = asn1.ObjectIdentifier{1, 3, 132, 0, 33} oidNamedCurveP256 = asn1.ObjectIdentifier{1, 2, 840, 10045, 3, 1, 7} oidNamedCurveP384 = asn1.ObjectIdentifier{1, 3, 132, 0, 34} oidNamedCurveP521 = asn1.ObjectIdentifier{1, 3, 132, 0, 35} ) func namedCurveFromOID(oid asn1.ObjectIdentifier) elliptic.Curve { switch { case oid.Equal(oidNamedCurveP224): return elliptic.P224() case oid.Equal(oidNamedCurveP256): return elliptic.P256() case oid.Equal(oidNamedCurveP384): return elliptic.P384() case oid.Equal(oidNamedCurveP521): return elliptic.P521() } return nil } func oidFromNamedCurve(curve elliptic.Curve) (asn1.ObjectIdentifier, bool) { switch curve { case elliptic.P224(): return oidNamedCurveP224, true case elliptic.P256(): return oidNamedCurveP256, true case elliptic.P384(): return oidNamedCurveP384, true case elliptic.P521(): return oidNamedCurveP521, true } return nil, false } // KeyUsage represents the set of actions that are valid for a given key. It's // a bitmap of the KeyUsage* constants. type KeyUsage int const ( KeyUsageDigitalSignature KeyUsage = 1 << iota KeyUsageContentCommitment KeyUsageKeyEncipherment KeyUsageDataEncipherment KeyUsageKeyAgreement KeyUsageCertSign KeyUsageCRLSign KeyUsageEncipherOnly KeyUsageDecipherOnly ) // RFC 5280, 4.2.1.12 Extended Key Usage // // anyExtendedKeyUsage OBJECT IDENTIFIER ::= { id-ce-extKeyUsage 0 } // // id-kp OBJECT IDENTIFIER ::= { id-pkix 3 } // // id-kp-serverAuth OBJECT IDENTIFIER ::= { id-kp 1 } // id-kp-clientAuth OBJECT IDENTIFIER ::= { id-kp 2 } // id-kp-codeSigning OBJECT IDENTIFIER ::= { id-kp 3 } // id-kp-emailProtection OBJECT IDENTIFIER ::= { id-kp 4 } // id-kp-timeStamping OBJECT IDENTIFIER ::= { id-kp 8 } // id-kp-OCSPSigning OBJECT IDENTIFIER ::= { id-kp 9 } var ( oidExtKeyUsageAny = asn1.ObjectIdentifier{2, 5, 29, 37, 0} oidExtKeyUsageServerAuth = asn1.ObjectIdentifier{1, 3, 6, 1, 5, 5, 7, 3, 1} oidExtKeyUsageClientAuth = asn1.ObjectIdentifier{1, 3, 6, 1, 5, 5, 7, 3, 2} oidExtKeyUsageCodeSigning = asn1.ObjectIdentifier{1, 3, 6, 1, 5, 5, 7, 3, 3} oidExtKeyUsageEmailProtection = asn1.ObjectIdentifier{1, 3, 6, 1, 5, 5, 7, 3, 4} oidExtKeyUsageIPSECEndSystem = asn1.ObjectIdentifier{1, 3, 6, 1, 5, 5, 7, 3, 5} oidExtKeyUsageIPSECTunnel = asn1.ObjectIdentifier{1, 3, 6, 1, 5, 5, 7, 3, 6} oidExtKeyUsageIPSECUser = asn1.ObjectIdentifier{1, 3, 6, 1, 5, 5, 7, 3, 7} oidExtKeyUsageTimeStamping = asn1.ObjectIdentifier{1, 3, 6, 1, 5, 5, 7, 3, 8} oidExtKeyUsageOCSPSigning = asn1.ObjectIdentifier{1, 3, 6, 1, 5, 5, 7, 3, 9} oidExtKeyUsageMicrosoftServerGatedCrypto = asn1.ObjectIdentifier{1, 3, 6, 1, 4, 1, 311, 10, 3, 3} oidExtKeyUsageNetscapeServerGatedCrypto = asn1.ObjectIdentifier{2, 16, 840, 1, 113730, 4, 1} oidExtKeyUsageMicrosoftCommercialCodeSigning = asn1.ObjectIdentifier{1, 3, 6, 1, 4, 1, 311, 2, 1, 22} oidExtKeyUsageMicrosoftKernelCodeSigning = asn1.ObjectIdentifier{1, 3, 6, 1, 4, 1, 311, 61, 1, 1} ) // ExtKeyUsage represents an extended set of actions that are valid for a given key. // Each of the ExtKeyUsage* constants define a unique action. type ExtKeyUsage int const ( ExtKeyUsageAny ExtKeyUsage = iota ExtKeyUsageServerAuth ExtKeyUsageClientAuth ExtKeyUsageCodeSigning ExtKeyUsageEmailProtection ExtKeyUsageIPSECEndSystem ExtKeyUsageIPSECTunnel ExtKeyUsageIPSECUser ExtKeyUsageTimeStamping ExtKeyUsageOCSPSigning ExtKeyUsageMicrosoftServerGatedCrypto ExtKeyUsageNetscapeServerGatedCrypto ExtKeyUsageMicrosoftCommercialCodeSigning ExtKeyUsageMicrosoftKernelCodeSigning ) // extKeyUsageOIDs contains the mapping between an ExtKeyUsage and its OID. var extKeyUsageOIDs = []struct { extKeyUsage ExtKeyUsage oid asn1.ObjectIdentifier }{ {ExtKeyUsageAny, oidExtKeyUsageAny}, {ExtKeyUsageServerAuth, oidExtKeyUsageServerAuth}, {ExtKeyUsageClientAuth, oidExtKeyUsageClientAuth}, {ExtKeyUsageCodeSigning, oidExtKeyUsageCodeSigning}, {ExtKeyUsageEmailProtection, oidExtKeyUsageEmailProtection}, {ExtKeyUsageIPSECEndSystem, oidExtKeyUsageIPSECEndSystem}, {ExtKeyUsageIPSECTunnel, oidExtKeyUsageIPSECTunnel}, {ExtKeyUsageIPSECUser, oidExtKeyUsageIPSECUser}, {ExtKeyUsageTimeStamping, oidExtKeyUsageTimeStamping}, {ExtKeyUsageOCSPSigning, oidExtKeyUsageOCSPSigning}, {ExtKeyUsageMicrosoftServerGatedCrypto, oidExtKeyUsageMicrosoftServerGatedCrypto}, {ExtKeyUsageNetscapeServerGatedCrypto, oidExtKeyUsageNetscapeServerGatedCrypto}, {ExtKeyUsageMicrosoftCommercialCodeSigning, oidExtKeyUsageMicrosoftCommercialCodeSigning}, {ExtKeyUsageMicrosoftKernelCodeSigning, oidExtKeyUsageMicrosoftKernelCodeSigning}, } func extKeyUsageFromOID(oid asn1.ObjectIdentifier) (eku ExtKeyUsage, ok bool) { for _, pair := range extKeyUsageOIDs { if oid.Equal(pair.oid) { return pair.extKeyUsage, true } } return } func oidFromExtKeyUsage(eku ExtKeyUsage) (oid asn1.ObjectIdentifier, ok bool) { for _, pair := range extKeyUsageOIDs { if eku == pair.extKeyUsage { return pair.oid, true } } return } // A Certificate represents an X.509 certificate. type Certificate struct { Raw []byte // Complete ASN.1 DER content (certificate, signature algorithm and signature). RawTBSCertificate []byte // Certificate part of raw ASN.1 DER content. RawSubjectPublicKeyInfo []byte // DER encoded SubjectPublicKeyInfo. RawSubject []byte // DER encoded Subject RawIssuer []byte // DER encoded Issuer Signature []byte SignatureAlgorithm SignatureAlgorithm PublicKeyAlgorithm PublicKeyAlgorithm PublicKey interface{} Version int SerialNumber *big.Int Issuer pkix.Name Subject pkix.Name NotBefore, NotAfter time.Time // Validity bounds. KeyUsage KeyUsage // Extensions contains raw X.509 extensions. When parsing certificates, // this can be used to extract non-critical extensions that are not // parsed by this package. When marshaling certificates, the Extensions // field is ignored, see ExtraExtensions. Extensions []pkix.Extension // ExtraExtensions contains extensions to be copied, raw, into any // marshaled certificates. Values override any extensions that would // otherwise be produced based on the other fields. The ExtraExtensions // field is not populated when parsing certificates, see Extensions. ExtraExtensions []pkix.Extension // UnhandledCriticalExtensions contains a list of extension IDs that // were not (fully) processed when parsing. Verify will fail if this // slice is non-empty, unless verification is delegated to an OS // library which understands all the critical extensions. // // Users can access these extensions using Extensions and can remove // elements from this slice if they believe that they have been // handled. UnhandledCriticalExtensions []asn1.ObjectIdentifier ExtKeyUsage []ExtKeyUsage // Sequence of extended key usages. UnknownExtKeyUsage []asn1.ObjectIdentifier // Encountered extended key usages unknown to this package. // BasicConstraintsValid indicates whether IsCA, MaxPathLen, // and MaxPathLenZero are valid. BasicConstraintsValid bool IsCA bool // MaxPathLen and MaxPathLenZero indicate the presence and // value of the BasicConstraints' "pathLenConstraint". // // When parsing a certificate, a positive non-zero MaxPathLen // means that the field was specified, -1 means it was unset, // and MaxPathLenZero being true mean that the field was // explicitly set to zero. The case of MaxPathLen==0 with MaxPathLenZero==false // should be treated equivalent to -1 (unset). // // When generating a certificate, an unset pathLenConstraint // can be requested with either MaxPathLen == -1 or using the // zero value for both MaxPathLen and MaxPathLenZero. MaxPathLen int // MaxPathLenZero indicates that BasicConstraintsValid==true // and MaxPathLen==0 should be interpreted as an actual // maximum path length of zero. Otherwise, that combination is // interpreted as MaxPathLen not being set. MaxPathLenZero bool SubjectKeyId []byte AuthorityKeyId []byte // RFC 5280, 4.2.2.1 (Authority Information Access) OCSPServer []string IssuingCertificateURL []string // Subject Alternate Name values. (Note that these values may not be valid // if invalid values were contained within a parsed certificate. For // example, an element of DNSNames may not be a valid DNS domain name.) DNSNames []string EmailAddresses []string IPAddresses []net.IP URIs []*url.URL // Name constraints PermittedDNSDomainsCritical bool // if true then the name constraints are marked critical. PermittedDNSDomains []string ExcludedDNSDomains []string PermittedIPRanges []*net.IPNet ExcludedIPRanges []*net.IPNet PermittedEmailAddresses []string ExcludedEmailAddresses []string PermittedURIDomains []string ExcludedURIDomains []string // CRL Distribution Points CRLDistributionPoints []string PolicyIdentifiers []asn1.ObjectIdentifier } // ErrUnsupportedAlgorithm results from attempting to perform an operation that // involves algorithms that are not currently implemented. var ErrUnsupportedAlgorithm = errors.New("x509: cannot verify signature: algorithm unimplemented") // An InsecureAlgorithmError type InsecureAlgorithmError SignatureAlgorithm func (e InsecureAlgorithmError) Error() string { return fmt.Sprintf("x509: cannot verify signature: insecure algorithm %v", SignatureAlgorithm(e)) } // ConstraintViolationError results when a requested usage is not permitted by // a certificate. For example: checking a signature when the public key isn't a // certificate signing key. type ConstraintViolationError struct{} func (ConstraintViolationError) Error() string { return "x509: invalid signature: parent certificate cannot sign this kind of certificate" } func (c *Certificate) Equal(other *Certificate) bool { if c == nil || other == nil { return c == other } return bytes.Equal(c.Raw, other.Raw) } func (c *Certificate) hasSANExtension() bool { return oidInExtensions(oidExtensionSubjectAltName, c.Extensions) } // CheckSignatureFrom verifies that the signature on c is a valid signature // from parent. func (c *Certificate) CheckSignatureFrom(parent *Certificate) error { // RFC 5280, 4.2.1.9: // "If the basic constraints extension is not present in a version 3 // certificate, or the extension is present but the cA boolean is not // asserted, then the certified public key MUST NOT be used to verify // certificate signatures." if parent.Version == 3 && !parent.BasicConstraintsValid || parent.BasicConstraintsValid && !parent.IsCA { return ConstraintViolationError{} } if parent.KeyUsage != 0 && parent.KeyUsage&KeyUsageCertSign == 0 { return ConstraintViolationError{} } if parent.PublicKeyAlgorithm == UnknownPublicKeyAlgorithm { return ErrUnsupportedAlgorithm } // TODO(agl): don't ignore the path length constraint. return parent.CheckSignature(c.SignatureAlgorithm, c.RawTBSCertificate, c.Signature) } // CheckSignature verifies that signature is a valid signature over signed from // c's public key. func (c *Certificate) CheckSignature(algo SignatureAlgorithm, signed, signature []byte) error { return checkSignature(algo, signed, signature, c.PublicKey) } func (c *Certificate) hasNameConstraints() bool { return oidInExtensions(oidExtensionNameConstraints, c.Extensions) } func (c *Certificate) getSANExtension() []byte { for _, e := range c.Extensions { if e.Id.Equal(oidExtensionSubjectAltName) { return e.Value } } return nil } func signaturePublicKeyAlgoMismatchError(expectedPubKeyAlgo PublicKeyAlgorithm, pubKey interface{}) error { return fmt.Errorf("x509: signature algorithm specifies an %s public key, but have public key of type %T", expectedPubKeyAlgo.String(), pubKey) } // CheckSignature verifies that signature is a valid signature over signed from // a crypto.PublicKey. func checkSignature(algo SignatureAlgorithm, signed, signature []byte, publicKey crypto.PublicKey) (err error) { var hashType crypto.Hash var pubKeyAlgo PublicKeyAlgorithm for _, details := range signatureAlgorithmDetails { if details.algo == algo { hashType = details.hash pubKeyAlgo = details.pubKeyAlgo } } switch hashType { case crypto.Hash(0): if pubKeyAlgo != Ed25519 { return ErrUnsupportedAlgorithm } case crypto.MD5: return InsecureAlgorithmError(algo) default: if !hashType.Available() { return ErrUnsupportedAlgorithm } h := hashType.New() h.Write(signed) signed = h.Sum(nil) } switch pub := publicKey.(type) { case *rsa.PublicKey: if pubKeyAlgo != RSA { return signaturePublicKeyAlgoMismatchError(pubKeyAlgo, pub) } if algo.isRSAPSS() { return rsa.VerifyPSS(pub, hashType, signed, signature, &rsa.PSSOptions{SaltLength: rsa.PSSSaltLengthEqualsHash}) } else { return rsa.VerifyPKCS1v15(pub, hashType, signed, signature) } case *ecdsa.PublicKey: if pubKeyAlgo != ECDSA { return signaturePublicKeyAlgoMismatchError(pubKeyAlgo, pub) } if !ecdsa.VerifyASN1(pub, signed, signature) { return errors.New("x509: ECDSA verification failure") } return case ed25519.PublicKey: if pubKeyAlgo != Ed25519 { return signaturePublicKeyAlgoMismatchError(pubKeyAlgo, pub) } if !ed25519.Verify(pub, signed, signature) { return errors.New("x509: Ed25519 verification failure") } return } return ErrUnsupportedAlgorithm } // CheckCRLSignature checks that the signature in crl is from c. func (c *Certificate) CheckCRLSignature(crl *pkix.CertificateList) error { algo := getSignatureAlgorithmFromAI(crl.SignatureAlgorithm) return c.CheckSignature(algo, crl.TBSCertList.Raw, crl.SignatureValue.RightAlign()) } type UnhandledCriticalExtension struct{} func (h UnhandledCriticalExtension) Error() string { return "x509: unhandled critical extension" } type basicConstraints struct { IsCA bool `asn1:"optional"` MaxPathLen int `asn1:"optional,default:-1"` } // RFC 5280 4.2.1.4 type policyInformation struct { Policy asn1.ObjectIdentifier // policyQualifiers omitted } const ( nameTypeEmail = 1 nameTypeDNS = 2 nameTypeURI = 6 nameTypeIP = 7 ) // RFC 5280, 4.2.2.1 type authorityInfoAccess struct { Method asn1.ObjectIdentifier Location asn1.RawValue } // RFC 5280, 4.2.1.14 type distributionPoint struct { DistributionPoint distributionPointName `asn1:"optional,tag:0"` Reason asn1.BitString `asn1:"optional,tag:1"` CRLIssuer asn1.RawValue `asn1:"optional,tag:2"` } type distributionPointName struct { FullName []asn1.RawValue `asn1:"optional,tag:0"` RelativeName pkix.RDNSequence `asn1:"optional,tag:1"` } func reverseBitsInAByte(in byte) byte { b1 := in>>4 | in<<4 b2 := b1>>2&0x33 | b1<<2&0xcc b3 := b2>>1&0x55 | b2<<1&0xaa return b3 } // asn1BitLength returns the bit-length of bitString by considering the // most-significant bit in a byte to be the "first" bit. This convention // matches ASN.1, but differs from almost everything else. func asn1BitLength(bitString []byte) int { bitLen := len(bitString) * 8 for i := range bitString { b := bitString[len(bitString)-i-1] for bit := uint(0); bit < 8; bit++ { if (b>>bit)&1 == 1 { return bitLen } bitLen-- } } return 0 } var ( oidExtensionSubjectKeyId = []int{2, 5, 29, 14} oidExtensionKeyUsage = []int{2, 5, 29, 15} oidExtensionExtendedKeyUsage = []int{2, 5, 29, 37} oidExtensionAuthorityKeyId = []int{2, 5, 29, 35} oidExtensionBasicConstraints = []int{2, 5, 29, 19} oidExtensionSubjectAltName = []int{2, 5, 29, 17} oidExtensionCertificatePolicies = []int{2, 5, 29, 32} oidExtensionNameConstraints = []int{2, 5, 29, 30} oidExtensionCRLDistributionPoints = []int{2, 5, 29, 31} oidExtensionAuthorityInfoAccess = []int{1, 3, 6, 1, 5, 5, 7, 1, 1} oidExtensionCRLNumber = []int{2, 5, 29, 20} ) var ( oidAuthorityInfoAccessOcsp = asn1.ObjectIdentifier{1, 3, 6, 1, 5, 5, 7, 48, 1} oidAuthorityInfoAccessIssuers = asn1.ObjectIdentifier{1, 3, 6, 1, 5, 5, 7, 48, 2} ) // oidNotInExtensions reports whether an extension with the given oid exists in // extensions. func oidInExtensions(oid asn1.ObjectIdentifier, extensions []pkix.Extension) bool { for _, e := range extensions { if e.Id.Equal(oid) { return true } } return false } // marshalSANs marshals a list of addresses into a the contents of an X.509 // SubjectAlternativeName extension. func marshalSANs(dnsNames, emailAddresses []string, ipAddresses []net.IP, uris []*url.URL) (derBytes []byte, err error) { var rawValues []asn1.RawValue for _, name := range dnsNames { if err := isIA5String(name); err != nil { return nil, err } rawValues = append(rawValues, asn1.RawValue{Tag: nameTypeDNS, Class: 2, Bytes: []byte(name)}) } for _, email := range emailAddresses { if err := isIA5String(email); err != nil { return nil, err } rawValues = append(rawValues, asn1.RawValue{Tag: nameTypeEmail, Class: 2, Bytes: []byte(email)}) } for _, rawIP := range ipAddresses { // If possible, we always want to encode IPv4 addresses in 4 bytes. ip := rawIP.To4() if ip == nil { ip = rawIP } rawValues = append(rawValues, asn1.RawValue{Tag: nameTypeIP, Class: 2, Bytes: ip}) } for _, uri := range uris { uriStr := uri.String() if err := isIA5String(uriStr); err != nil { return nil, err } rawValues = append(rawValues, asn1.RawValue{Tag: nameTypeURI, Class: 2, Bytes: []byte(uriStr)}) } return asn1.Marshal(rawValues) } func isIA5String(s string) error { for _, r := range s { // Per RFC5280 "IA5String is limited to the set of ASCII characters" if r > unicode.MaxASCII { return fmt.Errorf("x509: %q cannot be encoded as an IA5String", s) } } return nil } func buildCertExtensions(template *Certificate, subjectIsEmpty bool, authorityKeyId []byte, subjectKeyId []byte) (ret []pkix.Extension, err error) { ret = make([]pkix.Extension, 10 /* maximum number of elements. */) n := 0 if template.KeyUsage != 0 && !oidInExtensions(oidExtensionKeyUsage, template.ExtraExtensions) { ret[n], err = marshalKeyUsage(template.KeyUsage) if err != nil { return nil, err } n++ } if (len(template.ExtKeyUsage) > 0 || len(template.UnknownExtKeyUsage) > 0) && !oidInExtensions(oidExtensionExtendedKeyUsage, template.ExtraExtensions) { ret[n], err = marshalExtKeyUsage(template.ExtKeyUsage, template.UnknownExtKeyUsage) if err != nil { return nil, err } n++ } if template.BasicConstraintsValid && !oidInExtensions(oidExtensionBasicConstraints, template.ExtraExtensions) { ret[n], err = marshalBasicConstraints(template.IsCA, template.MaxPathLen, template.MaxPathLenZero) if err != nil { return nil, err } n++ } if len(subjectKeyId) > 0 && !oidInExtensions(oidExtensionSubjectKeyId, template.ExtraExtensions) { ret[n].Id = oidExtensionSubjectKeyId ret[n].Value, err = asn1.Marshal(subjectKeyId) if err != nil { return } n++ } if len(authorityKeyId) > 0 && !oidInExtensions(oidExtensionAuthorityKeyId, template.ExtraExtensions) { ret[n].Id = oidExtensionAuthorityKeyId ret[n].Value, err = asn1.Marshal(authKeyId{authorityKeyId}) if err != nil { return } n++ } if (len(template.OCSPServer) > 0 || len(template.IssuingCertificateURL) > 0) && !oidInExtensions(oidExtensionAuthorityInfoAccess, template.ExtraExtensions) { ret[n].Id = oidExtensionAuthorityInfoAccess var aiaValues []authorityInfoAccess for _, name := range template.OCSPServer { aiaValues = append(aiaValues, authorityInfoAccess{ Method: oidAuthorityInfoAccessOcsp, Location: asn1.RawValue{Tag: 6, Class: 2, Bytes: []byte(name)}, }) } for _, name := range template.IssuingCertificateURL { aiaValues = append(aiaValues, authorityInfoAccess{ Method: oidAuthorityInfoAccessIssuers, Location: asn1.RawValue{Tag: 6, Class: 2, Bytes: []byte(name)}, }) } ret[n].Value, err = asn1.Marshal(aiaValues) if err != nil { return } n++ } if (len(template.DNSNames) > 0 || len(template.EmailAddresses) > 0 || len(template.IPAddresses) > 0 || len(template.URIs) > 0) && !oidInExtensions(oidExtensionSubjectAltName, template.ExtraExtensions) { ret[n].Id = oidExtensionSubjectAltName // From RFC 5280, Section 4.2.1.6: // “If the subject field contains an empty sequence ... then // subjectAltName extension ... is marked as critical” ret[n].Critical = subjectIsEmpty ret[n].Value, err = marshalSANs(template.DNSNames, template.EmailAddresses, template.IPAddresses, template.URIs) if err != nil { return } n++ } if len(template.PolicyIdentifiers) > 0 && !oidInExtensions(oidExtensionCertificatePolicies, template.ExtraExtensions) { ret[n], err = marshalCertificatePolicies(template.PolicyIdentifiers) if err != nil { return nil, err } n++ } if (len(template.PermittedDNSDomains) > 0 || len(template.ExcludedDNSDomains) > 0 || len(template.PermittedIPRanges) > 0 || len(template.ExcludedIPRanges) > 0 || len(template.PermittedEmailAddresses) > 0 || len(template.ExcludedEmailAddresses) > 0 || len(template.PermittedURIDomains) > 0 || len(template.ExcludedURIDomains) > 0) && !oidInExtensions(oidExtensionNameConstraints, template.ExtraExtensions) { ret[n].Id = oidExtensionNameConstraints ret[n].Critical = template.PermittedDNSDomainsCritical ipAndMask := func(ipNet *net.IPNet) []byte { maskedIP := ipNet.IP.Mask(ipNet.Mask) ipAndMask := make([]byte, 0, len(maskedIP)+len(ipNet.Mask)) ipAndMask = append(ipAndMask, maskedIP...) ipAndMask = append(ipAndMask, ipNet.Mask...) return ipAndMask } serialiseConstraints := func(dns []string, ips []*net.IPNet, emails []string, uriDomains []string) (der []byte, err error) { var b cryptobyte.Builder for _, name := range dns { if err = isIA5String(name); err != nil { return nil, err } b.AddASN1(cryptobyte_asn1.SEQUENCE, func(b *cryptobyte.Builder) { b.AddASN1(cryptobyte_asn1.Tag(2).ContextSpecific(), func(b *cryptobyte.Builder) { b.AddBytes([]byte(name)) }) }) } for _, ipNet := range ips { b.AddASN1(cryptobyte_asn1.SEQUENCE, func(b *cryptobyte.Builder) { b.AddASN1(cryptobyte_asn1.Tag(7).ContextSpecific(), func(b *cryptobyte.Builder) { b.AddBytes(ipAndMask(ipNet)) }) }) } for _, email := range emails { if err = isIA5String(email); err != nil { return nil, err } b.AddASN1(cryptobyte_asn1.SEQUENCE, func(b *cryptobyte.Builder) { b.AddASN1(cryptobyte_asn1.Tag(1).ContextSpecific(), func(b *cryptobyte.Builder) { b.AddBytes([]byte(email)) }) }) } for _, uriDomain := range uriDomains { if err = isIA5String(uriDomain); err != nil { return nil, err } b.AddASN1(cryptobyte_asn1.SEQUENCE, func(b *cryptobyte.Builder) { b.AddASN1(cryptobyte_asn1.Tag(6).ContextSpecific(), func(b *cryptobyte.Builder) { b.AddBytes([]byte(uriDomain)) }) }) } return b.Bytes() } permitted, err := serialiseConstraints(template.PermittedDNSDomains, template.PermittedIPRanges, template.PermittedEmailAddresses, template.PermittedURIDomains) if err != nil { return nil, err } excluded, err := serialiseConstraints(template.ExcludedDNSDomains, template.ExcludedIPRanges, template.ExcludedEmailAddresses, template.ExcludedURIDomains) if err != nil { return nil, err } var b cryptobyte.Builder b.AddASN1(cryptobyte_asn1.SEQUENCE, func(b *cryptobyte.Builder) { if len(permitted) > 0 { b.AddASN1(cryptobyte_asn1.Tag(0).ContextSpecific().Constructed(), func(b *cryptobyte.Builder) { b.AddBytes(permitted) }) } if len(excluded) > 0 { b.AddASN1(cryptobyte_asn1.Tag(1).ContextSpecific().Constructed(), func(b *cryptobyte.Builder) { b.AddBytes(excluded) }) } }) ret[n].Value, err = b.Bytes() if err != nil { return nil, err } n++ } if len(template.CRLDistributionPoints) > 0 && !oidInExtensions(oidExtensionCRLDistributionPoints, template.ExtraExtensions) { ret[n].Id = oidExtensionCRLDistributionPoints var crlDp []distributionPoint for _, name := range template.CRLDistributionPoints { dp := distributionPoint{ DistributionPoint: distributionPointName{ FullName: []asn1.RawValue{ {Tag: 6, Class: 2, Bytes: []byte(name)}, }, }, } crlDp = append(crlDp, dp) } ret[n].Value, err = asn1.Marshal(crlDp) if err != nil { return } n++ } // Adding another extension here? Remember to update the maximum number // of elements in the make() at the top of the function and the list of // template fields used in CreateCertificate documentation. return append(ret[:n], template.ExtraExtensions...), nil } func marshalKeyUsage(ku KeyUsage) (pkix.Extension, error) { ext := pkix.Extension{Id: oidExtensionKeyUsage, Critical: true} var a [2]byte a[0] = reverseBitsInAByte(byte(ku)) a[1] = reverseBitsInAByte(byte(ku >> 8)) l := 1 if a[1] != 0 { l = 2 } bitString := a[:l] var err error ext.Value, err = asn1.Marshal(asn1.BitString{Bytes: bitString, BitLength: asn1BitLength(bitString)}) if err != nil { return ext, err } return ext, nil } func marshalExtKeyUsage(extUsages []ExtKeyUsage, unknownUsages []asn1.ObjectIdentifier) (pkix.Extension, error) { ext := pkix.Extension{Id: oidExtensionExtendedKeyUsage} oids := make([]asn1.ObjectIdentifier, len(extUsages)+len(unknownUsages)) for i, u := range extUsages { if oid, ok := oidFromExtKeyUsage(u); ok { oids[i] = oid } else { return ext, errors.New("x509: unknown extended key usage") } } copy(oids[len(extUsages):], unknownUsages) var err error ext.Value, err = asn1.Marshal(oids) if err != nil { return ext, err } return ext, nil } func marshalBasicConstraints(isCA bool, maxPathLen int, maxPathLenZero bool) (pkix.Extension, error) { ext := pkix.Extension{Id: oidExtensionBasicConstraints, Critical: true} // Leaving MaxPathLen as zero indicates that no maximum path // length is desired, unless MaxPathLenZero is set. A value of // -1 causes encoding/asn1 to omit the value as desired. if maxPathLen == 0 && !maxPathLenZero { maxPathLen = -1 } var err error ext.Value, err = asn1.Marshal(basicConstraints{isCA, maxPathLen}) if err != nil { return ext, nil } return ext, nil } func marshalCertificatePolicies(policyIdentifiers []asn1.ObjectIdentifier) (pkix.Extension, error) { ext := pkix.Extension{Id: oidExtensionCertificatePolicies} policies := make([]policyInformation, len(policyIdentifiers)) for i, policy := range policyIdentifiers { policies[i].Policy = policy } var err error ext.Value, err = asn1.Marshal(policies) if err != nil { return ext, err } return ext, nil } func buildCSRExtensions(template *CertificateRequest) ([]pkix.Extension, error) { var ret []pkix.Extension if (len(template.DNSNames) > 0 || len(template.EmailAddresses) > 0 || len(template.IPAddresses) > 0 || len(template.URIs) > 0) && !oidInExtensions(oidExtensionSubjectAltName, template.ExtraExtensions) { sanBytes, err := marshalSANs(template.DNSNames, template.EmailAddresses, template.IPAddresses, template.URIs) if err != nil { return nil, err } ret = append(ret, pkix.Extension{ Id: oidExtensionSubjectAltName, Value: sanBytes, }) } return append(ret, template.ExtraExtensions...), nil } func subjectBytes(cert *Certificate) ([]byte, error) { if len(cert.RawSubject) > 0 { return cert.RawSubject, nil } return asn1.Marshal(cert.Subject.ToRDNSequence()) } // signingParamsForPublicKey returns the parameters to use for signing with // priv. If requestedSigAlgo is not zero then it overrides the default // signature algorithm. func signingParamsForPublicKey(pub interface{}, requestedSigAlgo SignatureAlgorithm) (hashFunc crypto.Hash, sigAlgo pkix.AlgorithmIdentifier, err error) { var pubType PublicKeyAlgorithm switch pub := pub.(type) { case *rsa.PublicKey: pubType = RSA hashFunc = crypto.SHA256 sigAlgo.Algorithm = oidSignatureSHA256WithRSA sigAlgo.Parameters = asn1.NullRawValue case *ecdsa.PublicKey: pubType = ECDSA switch pub.Curve { case elliptic.P224(), elliptic.P256(): hashFunc = crypto.SHA256 sigAlgo.Algorithm = oidSignatureECDSAWithSHA256 case elliptic.P384(): hashFunc = crypto.SHA384 sigAlgo.Algorithm = oidSignatureECDSAWithSHA384 case elliptic.P521(): hashFunc = crypto.SHA512 sigAlgo.Algorithm = oidSignatureECDSAWithSHA512 default: err = errors.New("x509: unknown elliptic curve") } case ed25519.PublicKey: pubType = Ed25519 sigAlgo.Algorithm = oidSignatureEd25519 default: err = errors.New("x509: only RSA, ECDSA and Ed25519 keys supported") } if err != nil { return } if requestedSigAlgo == 0 { return } found := false for _, details := range signatureAlgorithmDetails { if details.algo == requestedSigAlgo { if details.pubKeyAlgo != pubType { err = errors.New("x509: requested SignatureAlgorithm does not match private key type") return } sigAlgo.Algorithm, hashFunc = details.oid, details.hash if hashFunc == 0 && pubType != Ed25519 { err = errors.New("x509: cannot sign with hash function requested") return } if requestedSigAlgo.isRSAPSS() { sigAlgo.Parameters = hashToPSSParameters[hashFunc] } found = true break } } if !found { err = errors.New("x509: unknown SignatureAlgorithm") } return } // emptyASN1Subject is the ASN.1 DER encoding of an empty Subject, which is // just an empty SEQUENCE. var emptyASN1Subject = []byte{0x30, 0} // CreateCertificate creates a new X.509 v3 certificate based on a template. // The following members of template are currently used: // // - AuthorityKeyId // - BasicConstraintsValid // - CRLDistributionPoints // - DNSNames // - EmailAddresses // - ExcludedDNSDomains // - ExcludedEmailAddresses // - ExcludedIPRanges // - ExcludedURIDomains // - ExtKeyUsage // - ExtraExtensions // - IPAddresses // - IsCA // - IssuingCertificateURL // - KeyUsage // - MaxPathLen // - MaxPathLenZero // - NotAfter // - NotBefore // - OCSPServer // - PermittedDNSDomains // - PermittedDNSDomainsCritical // - PermittedEmailAddresses // - PermittedIPRanges // - PermittedURIDomains // - PolicyIdentifiers // - SerialNumber // - SignatureAlgorithm // - Subject // - SubjectKeyId // - URIs // - UnknownExtKeyUsage // // The certificate is signed by parent. If parent is equal to template then the // certificate is self-signed. The parameter pub is the public key of the // certificate to be generated and priv is the private key of the signer. // // The returned slice is the certificate in DER encoding. // // The currently supported key types are *rsa.PublicKey, *ecdsa.PublicKey and // ed25519.PublicKey. pub must be a supported key type, and priv must be a // crypto.Signer with a supported public key. // // The AuthorityKeyId will be taken from the SubjectKeyId of parent, if any, // unless the resulting certificate is self-signed. Otherwise the value from // template will be used. // // If SubjectKeyId from template is empty and the template is a CA, SubjectKeyId // will be generated from the hash of the public key. func CreateCertificate(rand io.Reader, template, parent *Certificate, pub, priv interface{}) ([]byte, error) { key, ok := priv.(crypto.Signer) if !ok { return nil, errors.New("x509: certificate private key does not implement crypto.Signer") } if template.SerialNumber == nil { return nil, errors.New("x509: no SerialNumber given") } if template.BasicConstraintsValid && !template.IsCA && template.MaxPathLen != -1 && (template.MaxPathLen != 0 || template.MaxPathLenZero) { return nil, errors.New("x509: only CAs are allowed to specify MaxPathLen") } hashFunc, signatureAlgorithm, err := signingParamsForPublicKey(key.Public(), template.SignatureAlgorithm) if err != nil { return nil, err } publicKeyBytes, publicKeyAlgorithm, err := marshalPublicKey(pub) if err != nil { return nil, err } asn1Issuer, err := subjectBytes(parent) if err != nil { return nil, err } asn1Subject, err := subjectBytes(template) if err != nil { return nil, err } authorityKeyId := template.AuthorityKeyId if !bytes.Equal(asn1Issuer, asn1Subject) && len(parent.SubjectKeyId) > 0 { authorityKeyId = parent.SubjectKeyId } subjectKeyId := template.SubjectKeyId if len(subjectKeyId) == 0 && template.IsCA { // SubjectKeyId generated using method 1 in RFC 5280, Section 4.2.1.2: // (1) The keyIdentifier is composed of the 160-bit SHA-1 hash of the // value of the BIT STRING subjectPublicKey (excluding the tag, // length, and number of unused bits). h := sha1.Sum(publicKeyBytes) subjectKeyId = h[:] } // Check that the signer's public key matches the private key, if available. type privateKey interface { Equal(crypto.PublicKey) bool } if privPub, ok := key.Public().(privateKey); !ok { return nil, errors.New("x509: internal error: supported public key does not implement Equal") } else if parent.PublicKey != nil && !privPub.Equal(parent.PublicKey) { return nil, errors.New("x509: provided PrivateKey doesn't match parent's PublicKey") } extensions, err := buildCertExtensions(template, bytes.Equal(asn1Subject, emptyASN1Subject), authorityKeyId, subjectKeyId) if err != nil { return nil, err } encodedPublicKey := asn1.BitString{BitLength: len(publicKeyBytes) * 8, Bytes: publicKeyBytes} c := tbsCertificate{ Version: 2, SerialNumber: template.SerialNumber, SignatureAlgorithm: signatureAlgorithm, Issuer: asn1.RawValue{FullBytes: asn1Issuer}, Validity: validity{template.NotBefore.UTC(), template.NotAfter.UTC()}, Subject: asn1.RawValue{FullBytes: asn1Subject}, PublicKey: publicKeyInfo{nil, publicKeyAlgorithm, encodedPublicKey}, Extensions: extensions, } tbsCertContents, err := asn1.Marshal(c) if err != nil { return nil, err } c.Raw = tbsCertContents signed := tbsCertContents if hashFunc != 0 { h := hashFunc.New() h.Write(signed) signed = h.Sum(nil) } var signerOpts crypto.SignerOpts = hashFunc if template.SignatureAlgorithm != 0 && template.SignatureAlgorithm.isRSAPSS() { signerOpts = &rsa.PSSOptions{ SaltLength: rsa.PSSSaltLengthEqualsHash, Hash: hashFunc, } } var signature []byte signature, err = key.Sign(rand, signed, signerOpts) if err != nil { return nil, err } signedCert, err := asn1.Marshal(certificate{ nil, c, signatureAlgorithm, asn1.BitString{Bytes: signature, BitLength: len(signature) * 8}, }) if err != nil { return nil, err } // Check the signature to ensure the crypto.Signer behaved correctly. // We skip this check if the signature algorithm is MD5WithRSA as we // only support this algorithm for signing, and not verification. if sigAlg := getSignatureAlgorithmFromAI(signatureAlgorithm); sigAlg != MD5WithRSA { if err := checkSignature(sigAlg, c.Raw, signature, key.Public()); err != nil { return nil, fmt.Errorf("x509: signature over certificate returned by signer is invalid: %w", err) } } return signedCert, nil } // pemCRLPrefix is the magic string that indicates that we have a PEM encoded // CRL. var pemCRLPrefix = []byte("-----BEGIN X509 CRL") // pemType is the type of a PEM encoded CRL. var pemType = "X509 CRL" // ParseCRL parses a CRL from the given bytes. It's often the case that PEM // encoded CRLs will appear where they should be DER encoded, so this function // will transparently handle PEM encoding as long as there isn't any leading // garbage. func ParseCRL(crlBytes []byte) (*pkix.CertificateList, error) { if bytes.HasPrefix(crlBytes, pemCRLPrefix) { block, _ := pem.Decode(crlBytes) if block != nil && block.Type == pemType { crlBytes = block.Bytes } } return ParseDERCRL(crlBytes) } // ParseDERCRL parses a DER encoded CRL from the given bytes. func ParseDERCRL(derBytes []byte) (*pkix.CertificateList, error) { certList := new(pkix.CertificateList) if rest, err := asn1.Unmarshal(derBytes, certList); err != nil { return nil, err } else if len(rest) != 0 { return nil, errors.New("x509: trailing data after CRL") } return certList, nil } // CreateCRL returns a DER encoded CRL, signed by this Certificate, that // contains the given list of revoked certificates. // // Note: this method does not generate an RFC 5280 conformant X.509 v2 CRL. // To generate a standards compliant CRL, use CreateRevocationList instead. func (c *Certificate) CreateCRL(rand io.Reader, priv interface{}, revokedCerts []pkix.RevokedCertificate, now, expiry time.Time) (crlBytes []byte, err error) { key, ok := priv.(crypto.Signer) if !ok { return nil, errors.New("x509: certificate private key does not implement crypto.Signer") } hashFunc, signatureAlgorithm, err := signingParamsForPublicKey(key.Public(), 0) if err != nil { return nil, err } // Force revocation times to UTC per RFC 5280. revokedCertsUTC := make([]pkix.RevokedCertificate, len(revokedCerts)) for i, rc := range revokedCerts { rc.RevocationTime = rc.RevocationTime.UTC() revokedCertsUTC[i] = rc } tbsCertList := pkix.TBSCertificateList{ Version: 1, Signature: signatureAlgorithm, Issuer: c.Subject.ToRDNSequence(), ThisUpdate: now.UTC(), NextUpdate: expiry.UTC(), RevokedCertificates: revokedCertsUTC, } // Authority Key Id if len(c.SubjectKeyId) > 0 { var aki pkix.Extension aki.Id = oidExtensionAuthorityKeyId aki.Value, err = asn1.Marshal(authKeyId{Id: c.SubjectKeyId}) if err != nil { return } tbsCertList.Extensions = append(tbsCertList.Extensions, aki) } tbsCertListContents, err := asn1.Marshal(tbsCertList) if err != nil { return } signed := tbsCertListContents if hashFunc != 0 { h := hashFunc.New() h.Write(signed) signed = h.Sum(nil) } var signature []byte signature, err = key.Sign(rand, signed, hashFunc) if err != nil { return } return asn1.Marshal(pkix.CertificateList{ TBSCertList: tbsCertList, SignatureAlgorithm: signatureAlgorithm, SignatureValue: asn1.BitString{Bytes: signature, BitLength: len(signature) * 8}, }) } // CertificateRequest represents a PKCS #10, certificate signature request. type CertificateRequest struct { Raw []byte // Complete ASN.1 DER content (CSR, signature algorithm and signature). RawTBSCertificateRequest []byte // Certificate request info part of raw ASN.1 DER content. RawSubjectPublicKeyInfo []byte // DER encoded SubjectPublicKeyInfo. RawSubject []byte // DER encoded Subject. Version int Signature []byte SignatureAlgorithm SignatureAlgorithm PublicKeyAlgorithm PublicKeyAlgorithm PublicKey interface{} Subject pkix.Name // Attributes contains the CSR attributes that can parse as // pkix.AttributeTypeAndValueSET. // // Deprecated: Use Extensions and ExtraExtensions instead for parsing and // generating the requestedExtensions attribute. Attributes []pkix.AttributeTypeAndValueSET // Extensions contains all requested extensions, in raw form. When parsing // CSRs, this can be used to extract extensions that are not parsed by this // package. Extensions []pkix.Extension // ExtraExtensions contains extensions to be copied, raw, into any CSR // marshaled by CreateCertificateRequest. Values override any extensions // that would otherwise be produced based on the other fields but are // overridden by any extensions specified in Attributes. // // The ExtraExtensions field is not populated by ParseCertificateRequest, // see Extensions instead. ExtraExtensions []pkix.Extension // Subject Alternate Name values. DNSNames []string EmailAddresses []string IPAddresses []net.IP URIs []*url.URL } // These structures reflect the ASN.1 structure of X.509 certificate // signature requests (see RFC 2986): type tbsCertificateRequest struct { Raw asn1.RawContent Version int Subject asn1.RawValue PublicKey publicKeyInfo RawAttributes []asn1.RawValue `asn1:"tag:0"` } type certificateRequest struct { Raw asn1.RawContent TBSCSR tbsCertificateRequest SignatureAlgorithm pkix.AlgorithmIdentifier SignatureValue asn1.BitString } // oidExtensionRequest is a PKCS #9 OBJECT IDENTIFIER that indicates requested // extensions in a CSR. var oidExtensionRequest = asn1.ObjectIdentifier{1, 2, 840, 113549, 1, 9, 14} // newRawAttributes converts AttributeTypeAndValueSETs from a template // CertificateRequest's Attributes into tbsCertificateRequest RawAttributes. func newRawAttributes(attributes []pkix.AttributeTypeAndValueSET) ([]asn1.RawValue, error) { var rawAttributes []asn1.RawValue b, err := asn1.Marshal(attributes) if err != nil { return nil, err } rest, err := asn1.Unmarshal(b, &rawAttributes) if err != nil { return nil, err } if len(rest) != 0 { return nil, errors.New("x509: failed to unmarshal raw CSR Attributes") } return rawAttributes, nil } // parseRawAttributes Unmarshals RawAttributes into AttributeTypeAndValueSETs. func parseRawAttributes(rawAttributes []asn1.RawValue) []pkix.AttributeTypeAndValueSET { var attributes []pkix.AttributeTypeAndValueSET for _, rawAttr := range rawAttributes { var attr pkix.AttributeTypeAndValueSET rest, err := asn1.Unmarshal(rawAttr.FullBytes, &attr) // Ignore attributes that don't parse into pkix.AttributeTypeAndValueSET // (i.e.: challengePassword or unstructuredName). if err == nil && len(rest) == 0 { attributes = append(attributes, attr) } } return attributes } // parseCSRExtensions parses the attributes from a CSR and extracts any // requested extensions. func parseCSRExtensions(rawAttributes []asn1.RawValue) ([]pkix.Extension, error) { // pkcs10Attribute reflects the Attribute structure from RFC 2986, Section 4.1. type pkcs10Attribute struct { Id asn1.ObjectIdentifier Values []asn1.RawValue `asn1:"set"` } var ret []pkix.Extension for _, rawAttr := range rawAttributes { var attr pkcs10Attribute if rest, err := asn1.Unmarshal(rawAttr.FullBytes, &attr); err != nil || len(rest) != 0 || len(attr.Values) == 0 { // Ignore attributes that don't parse. continue } if !attr.Id.Equal(oidExtensionRequest) { continue } var extensions []pkix.Extension if _, err := asn1.Unmarshal(attr.Values[0].FullBytes, &extensions); err != nil { return nil, err } ret = append(ret, extensions...) } return ret, nil } // CreateCertificateRequest creates a new certificate request based on a // template. The following members of template are used: // // - SignatureAlgorithm // - Subject // - DNSNames // - EmailAddresses // - IPAddresses // - URIs // - ExtraExtensions // - Attributes (deprecated) // // priv is the private key to sign the CSR with, and the corresponding public // key will be included in the CSR. It must implement crypto.Signer and its // Public() method must return a *rsa.PublicKey or a *ecdsa.PublicKey or a // ed25519.PublicKey. (A *rsa.PrivateKey, *ecdsa.PrivateKey or // ed25519.PrivateKey satisfies this.) // // The returned slice is the certificate request in DER encoding. func CreateCertificateRequest(rand io.Reader, template *CertificateRequest, priv interface{}) (csr []byte, err error) { key, ok := priv.(crypto.Signer) if !ok { return nil, errors.New("x509: certificate private key does not implement crypto.Signer") } var hashFunc crypto.Hash var sigAlgo pkix.AlgorithmIdentifier hashFunc, sigAlgo, err = signingParamsForPublicKey(key.Public(), template.SignatureAlgorithm) if err != nil { return nil, err } var publicKeyBytes []byte var publicKeyAlgorithm pkix.AlgorithmIdentifier publicKeyBytes, publicKeyAlgorithm, err = marshalPublicKey(key.Public()) if err != nil { return nil, err } extensions, err := buildCSRExtensions(template) if err != nil { return nil, err } // Make a copy of template.Attributes because we may alter it below. attributes := make([]pkix.AttributeTypeAndValueSET, 0, len(template.Attributes)) for _, attr := range template.Attributes { values := make([][]pkix.AttributeTypeAndValue, len(attr.Value)) copy(values, attr.Value) attributes = append(attributes, pkix.AttributeTypeAndValueSET{ Type: attr.Type, Value: values, }) } extensionsAppended := false if len(extensions) > 0 { // Append the extensions to an existing attribute if possible. for _, atvSet := range attributes { if !atvSet.Type.Equal(oidExtensionRequest) || len(atvSet.Value) == 0 { continue } // specifiedExtensions contains all the extensions that we // found specified via template.Attributes. specifiedExtensions := make(map[string]bool) for _, atvs := range atvSet.Value { for _, atv := range atvs { specifiedExtensions[atv.Type.String()] = true } } newValue := make([]pkix.AttributeTypeAndValue, 0, len(atvSet.Value[0])+len(extensions)) newValue = append(newValue, atvSet.Value[0]...) for _, e := range extensions { if specifiedExtensions[e.Id.String()] { // Attributes already contained a value for // this extension and it takes priority. continue } newValue = append(newValue, pkix.AttributeTypeAndValue{ // There is no place for the critical // flag in an AttributeTypeAndValue. Type: e.Id, Value: e.Value, }) } atvSet.Value[0] = newValue extensionsAppended = true break } } rawAttributes, err := newRawAttributes(attributes) if err != nil { return } // If not included in attributes, add a new attribute for the // extensions. if len(extensions) > 0 && !extensionsAppended { attr := struct { Type asn1.ObjectIdentifier Value [][]pkix.Extension `asn1:"set"` }{ Type: oidExtensionRequest, Value: [][]pkix.Extension{extensions}, } b, err := asn1.Marshal(attr) if err != nil { return nil, errors.New("x509: failed to serialise extensions attribute: " + err.Error()) } var rawValue asn1.RawValue if _, err := asn1.Unmarshal(b, &rawValue); err != nil { return nil, err } rawAttributes = append(rawAttributes, rawValue) } asn1Subject := template.RawSubject if len(asn1Subject) == 0 { asn1Subject, err = asn1.Marshal(template.Subject.ToRDNSequence()) if err != nil { return nil, err } } tbsCSR := tbsCertificateRequest{ Version: 0, // PKCS #10, RFC 2986 Subject: asn1.RawValue{FullBytes: asn1Subject}, PublicKey: publicKeyInfo{ Algorithm: publicKeyAlgorithm, PublicKey: asn1.BitString{ Bytes: publicKeyBytes, BitLength: len(publicKeyBytes) * 8, }, }, RawAttributes: rawAttributes, } tbsCSRContents, err := asn1.Marshal(tbsCSR) if err != nil { return } tbsCSR.Raw = tbsCSRContents signed := tbsCSRContents if hashFunc != 0 { h := hashFunc.New() h.Write(signed) signed = h.Sum(nil) } var signature []byte signature, err = key.Sign(rand, signed, hashFunc) if err != nil { return } return asn1.Marshal(certificateRequest{ TBSCSR: tbsCSR, SignatureAlgorithm: sigAlgo, SignatureValue: asn1.BitString{ Bytes: signature, BitLength: len(signature) * 8, }, }) } // ParseCertificateRequest parses a single certificate request from the // given ASN.1 DER data. func ParseCertificateRequest(asn1Data []byte) (*CertificateRequest, error) { var csr certificateRequest rest, err := asn1.Unmarshal(asn1Data, &csr) if err != nil { return nil, err } else if len(rest) != 0 { return nil, asn1.SyntaxError{Msg: "trailing data"} } return parseCertificateRequest(&csr) } func parseCertificateRequest(in *certificateRequest) (*CertificateRequest, error) { out := &CertificateRequest{ Raw: in.Raw, RawTBSCertificateRequest: in.TBSCSR.Raw, RawSubjectPublicKeyInfo: in.TBSCSR.PublicKey.Raw, RawSubject: in.TBSCSR.Subject.FullBytes, Signature: in.SignatureValue.RightAlign(), SignatureAlgorithm: getSignatureAlgorithmFromAI(in.SignatureAlgorithm), PublicKeyAlgorithm: getPublicKeyAlgorithmFromOID(in.TBSCSR.PublicKey.Algorithm.Algorithm), Version: in.TBSCSR.Version, Attributes: parseRawAttributes(in.TBSCSR.RawAttributes), } var err error out.PublicKey, err = parsePublicKey(out.PublicKeyAlgorithm, &in.TBSCSR.PublicKey) if err != nil { return nil, err } var subject pkix.RDNSequence if rest, err := asn1.Unmarshal(in.TBSCSR.Subject.FullBytes, &subject); err != nil { return nil, err } else if len(rest) != 0 { return nil, errors.New("x509: trailing data after X.509 Subject") } out.Subject.FillFromRDNSequence(&subject) if out.Extensions, err = parseCSRExtensions(in.TBSCSR.RawAttributes); err != nil { return nil, err } for _, extension := range out.Extensions { switch { case extension.Id.Equal(oidExtensionSubjectAltName): out.DNSNames, out.EmailAddresses, out.IPAddresses, out.URIs, err = parseSANExtension(extension.Value) if err != nil { return nil, err } } } return out, nil } // CheckSignature reports whether the signature on c is valid. func (c *CertificateRequest) CheckSignature() error { return checkSignature(c.SignatureAlgorithm, c.RawTBSCertificateRequest, c.Signature, c.PublicKey) } // RevocationList contains the fields used to create an X.509 v2 Certificate // Revocation list with CreateRevocationList. type RevocationList struct { // SignatureAlgorithm is used to determine the signature algorithm to be // used when signing the CRL. If 0 the default algorithm for the signing // key will be used. SignatureAlgorithm SignatureAlgorithm // RevokedCertificates is used to populate the revokedCertificates // sequence in the CRL, it may be empty. RevokedCertificates may be nil, // in which case an empty CRL will be created. RevokedCertificates []pkix.RevokedCertificate // Number is used to populate the X.509 v2 cRLNumber extension in the CRL, // which should be a monotonically increasing sequence number for a given // CRL scope and CRL issuer. Number *big.Int // ThisUpdate is used to populate the thisUpdate field in the CRL, which // indicates the issuance date of the CRL. ThisUpdate time.Time // NextUpdate is used to populate the nextUpdate field in the CRL, which // indicates the date by which the next CRL will be issued. NextUpdate // must be greater than ThisUpdate. NextUpdate time.Time // ExtraExtensions contains any additional extensions to add directly to // the CRL. ExtraExtensions []pkix.Extension } // CreateRevocationList creates a new X.509 v2 Certificate Revocation List, // according to RFC 5280, based on template. // // The CRL is signed by priv which should be the private key associated with // the public key in the issuer certificate. // // The issuer may not be nil, and the crlSign bit must be set in KeyUsage in // order to use it as a CRL issuer. // // The issuer distinguished name CRL field and authority key identifier // extension are populated using the issuer certificate. issuer must have // SubjectKeyId set. func CreateRevocationList(rand io.Reader, template *RevocationList, issuer *Certificate, priv crypto.Signer) ([]byte, error) { if template == nil { return nil, errors.New("x509: template can not be nil") } if issuer == nil { return nil, errors.New("x509: issuer can not be nil") } if (issuer.KeyUsage & KeyUsageCRLSign) == 0 { return nil, errors.New("x509: issuer must have the crlSign key usage bit set") } if len(issuer.SubjectKeyId) == 0 { return nil, errors.New("x509: issuer certificate doesn't contain a subject key identifier") } if template.NextUpdate.Before(template.ThisUpdate) { return nil, errors.New("x509: template.ThisUpdate is after template.NextUpdate") } if template.Number == nil { return nil, errors.New("x509: template contains nil Number field") } hashFunc, signatureAlgorithm, err := signingParamsForPublicKey(priv.Public(), template.SignatureAlgorithm) if err != nil { return nil, err } // Force revocation times to UTC per RFC 5280. revokedCertsUTC := make([]pkix.RevokedCertificate, len(template.RevokedCertificates)) for i, rc := range template.RevokedCertificates { rc.RevocationTime = rc.RevocationTime.UTC() revokedCertsUTC[i] = rc } aki, err := asn1.Marshal(authKeyId{Id: issuer.SubjectKeyId}) if err != nil { return nil, err } crlNum, err := asn1.Marshal(template.Number) if err != nil { return nil, err } tbsCertList := pkix.TBSCertificateList{ Version: 1, // v2 Signature: signatureAlgorithm, Issuer: issuer.Subject.ToRDNSequence(), ThisUpdate: template.ThisUpdate.UTC(), NextUpdate: template.NextUpdate.UTC(), Extensions: []pkix.Extension{ { Id: oidExtensionAuthorityKeyId, Value: aki, }, { Id: oidExtensionCRLNumber, Value: crlNum, }, }, } if len(revokedCertsUTC) > 0 { tbsCertList.RevokedCertificates = revokedCertsUTC } if len(template.ExtraExtensions) > 0 { tbsCertList.Extensions = append(tbsCertList.Extensions, template.ExtraExtensions...) } tbsCertListContents, err := asn1.Marshal(tbsCertList) if err != nil { return nil, err } input := tbsCertListContents if hashFunc != 0 { h := hashFunc.New() h.Write(tbsCertListContents) input = h.Sum(nil) } var signerOpts crypto.SignerOpts = hashFunc if template.SignatureAlgorithm.isRSAPSS() { signerOpts = &rsa.PSSOptions{ SaltLength: rsa.PSSSaltLengthEqualsHash, Hash: hashFunc, } } signature, err := priv.Sign(rand, input, signerOpts) if err != nil { return nil, err } return asn1.Marshal(pkix.CertificateList{ TBSCertList: tbsCertList, SignatureAlgorithm: signatureAlgorithm, SignatureValue: asn1.BitString{Bytes: signature, BitLength: len(signature) * 8}, }) }