#!/usr/bin/env python # # This Source Code Form is subject to the terms of the Mozilla Public # License, v. 2.0. If a copy of the MPL was not distributed with this # file, You can obtain one at http://mozilla.org/MPL/2.0/. """ Reads a certificate specification from stdin or a file and outputs a signed x509 certificate with the desired properties. The input format is as follows: issuer: subject: [version:{1,2,3,4}] [validity:] [issuerKey:] [subjectKey:] [signature:{sha256WithRSAEncryption,sha1WithRSAEncryption, md5WithRSAEncryption,ecdsaWithSHA256,ecdsaWithSHA384, ecdsaWithSHA512}] [serialNumber:] [extension:>] [...] Known extensions are: basicConstraints:[cA],[pathLenConstraint] keyUsage:[digitalSignature,nonRepudiation,keyEncipherment, dataEncipherment,keyAgreement,keyCertSign,cRLSign] extKeyUsage:[serverAuth,clientAuth,codeSigning,emailProtection nsSGC, # Netscape Server Gated Crypto OCSPSigning,timeStamping] subjectAlternativeName:[,...] authorityInformationAccess: certificatePolicies:[,...] nameConstraints:{permitted,excluded}:[,...] nsCertType:sslServer TLSFeature:[,...] embeddedSCTList:[:,...] delegationUsage: Where: [] indicates an optional field or component of a field <> indicates a required component of a field {} indicates a choice of exactly one value among a set of values [a,b,c] indicates a list of potential values, of which zero or more may be used For instance, the version field is optional. However, if it is specified, it must have exactly one value from the set {1,2,3,4}. Most fields have reasonable default values. By default one shared RSA key is used for all signatures and subject public key information fields. Using "issuerKey:" or "subjectKey:" causes a different key be used for signing or as the subject public key information field, respectively. See pykey.py for the list of available specifications. The signature algorithm is sha256WithRSAEncryption by default. The validity period may be specified as either concrete notBefore and notAfter values or as a validity period centered around 'now'. For the latter, this will result in a notBefore of 'now' - duration/2 and a notAfter of 'now' + duration/2. Issuer and subject distinguished name specifications are of the form '[stringEncoding]/C=XX/O=Example/CN=example.com'. C (country name), ST (state or province name), L (locality name), O (organization name), OU (organizational unit name), CN (common name) and emailAddress (email address) are currently supported. The optional stringEncoding field may be 'utf8String' or 'printableString'. If the given string does not contain a '/', it is assumed to represent a common name. If an empty string is provided, then an empty distinguished name is returned. DirectoryNames also use this format. When specifying a directoryName in a nameConstraints extension, the implicit form may not be used. If an extension name has '[critical]' after it, it will be marked as critical. Otherwise (by default), it will not be marked as critical. TLSFeature values can either consist of a named value (currently only 'OCSPMustStaple' which corresponds to status_request) or a numeric TLS feature value (see rfc7633 for more information). If a serial number is not explicitly specified, it is automatically generated based on the contents of the certificate. """ import base64 import datetime import hashlib import re import socket import sys from struct import pack import pyct import pykey import six from pyasn1.codec.der import decoder, encoder from pyasn1.type import constraint, tag, univ, useful from pyasn1_modules import rfc2459 class Error(Exception): """Base class for exceptions in this module.""" pass class UnknownBaseError(Error): """Base class for handling unexpected input in this module.""" def __init__(self, value): super(UnknownBaseError, self).__init__() self.value = value self.category = "input" def __str__(self): return 'Unknown %s type "%s"' % (self.category, repr(self.value)) class UnknownAlgorithmTypeError(UnknownBaseError): """Helper exception type to handle unknown algorithm types.""" def __init__(self, value): UnknownBaseError.__init__(self, value) self.category = "algorithm" class UnknownParameterTypeError(UnknownBaseError): """Helper exception type to handle unknown input parameters.""" def __init__(self, value): UnknownBaseError.__init__(self, value) self.category = "parameter" class UnknownExtensionTypeError(UnknownBaseError): """Helper exception type to handle unknown input extensions.""" def __init__(self, value): UnknownBaseError.__init__(self, value) self.category = "extension" class UnknownKeyPurposeTypeError(UnknownBaseError): """Helper exception type to handle unknown key purposes.""" def __init__(self, value): UnknownBaseError.__init__(self, value) self.category = "keyPurpose" class UnknownKeyTargetError(UnknownBaseError): """Helper exception type to handle unknown key targets.""" def __init__(self, value): UnknownBaseError.__init__(self, value) self.category = "key target" class UnknownVersionError(UnknownBaseError): """Helper exception type to handle unknown specified versions.""" def __init__(self, value): UnknownBaseError.__init__(self, value) self.category = "version" class UnknownNameConstraintsSpecificationError(UnknownBaseError): """Helper exception type to handle unknown specified nameConstraints.""" def __init__(self, value): UnknownBaseError.__init__(self, value) self.category = "nameConstraints specification" class UnknownDNTypeError(UnknownBaseError): """Helper exception type to handle unknown DN types.""" def __init__(self, value): UnknownBaseError.__init__(self, value) self.category = "DN" class UnknownNSCertTypeError(UnknownBaseError): """Helper exception type to handle unknown nsCertType types.""" def __init__(self, value): UnknownBaseError.__init__(self, value) self.category = "nsCertType" class UnknownTLSFeature(UnknownBaseError): """Helper exception type to handle unknown TLS Features.""" def __init__(self, value): UnknownBaseError.__init__(self, value) self.category = "TLSFeature" class UnknownDelegatedCredentialError(UnknownBaseError): """Helper exception type to handle unknown Delegated Credential args.""" def __init__(self, value): UnknownBaseError.__init__(self, value) self.category = "delegatedCredential" class InvalidSCTSpecification(Error): """Helper exception type to handle invalid SCT specifications.""" def __init__(self, value): super(InvalidSCTSpecification, self).__init__() self.value = value def __str__(self): return repr('invalid SCT specification "{}"' % self.value) class InvalidSerialNumber(Error): """Exception type to handle invalid serial numbers.""" def __init__(self, value): super(InvalidSerialNumber, self).__init__() self.value = value def __str__(self): return repr(self.value) def getASN1Tag(asn1Type): """Helper function for returning the base tag value of a given type from the pyasn1 package""" return asn1Type.tagSet.baseTag.tagId def stringToAccessDescription(string): """Helper function that takes a string representing a URI presumably identifying an OCSP authority information access location. Returns an AccessDescription usable by pyasn1.""" accessMethod = rfc2459.id_ad_ocsp accessLocation = rfc2459.GeneralName() accessLocation["uniformResourceIdentifier"] = string sequence = univ.Sequence() sequence.setComponentByPosition(0, accessMethod) sequence.setComponentByPosition(1, accessLocation) return sequence def stringToDN(string, tag=None): """Takes a string representing a distinguished name or directory name and returns a Name for use by pyasn1. See the documentation for the issuer and subject fields for more details. Takes an optional implicit tag in cases where the Name needs to be tagged differently.""" if string and "/" not in string: string = "/CN=%s" % string rdns = rfc2459.RDNSequence() pattern = "/(C|ST|L|O|OU|CN|emailAddress)=" split = re.split(pattern, string) # split should now be [[encoding], , , , , ...] if split[0]: encoding = split[0] else: encoding = "utf8String" for pos, (nameType, value) in enumerate(zip(split[1::2], split[2::2])): ava = rfc2459.AttributeTypeAndValue() if nameType == "C": ava["type"] = rfc2459.id_at_countryName nameComponent = rfc2459.X520countryName(value) elif nameType == "ST": ava["type"] = rfc2459.id_at_stateOrProvinceName nameComponent = rfc2459.X520StateOrProvinceName() elif nameType == "L": ava["type"] = rfc2459.id_at_localityName nameComponent = rfc2459.X520LocalityName() elif nameType == "O": ava["type"] = rfc2459.id_at_organizationName nameComponent = rfc2459.X520OrganizationName() elif nameType == "OU": ava["type"] = rfc2459.id_at_organizationalUnitName nameComponent = rfc2459.X520OrganizationalUnitName() elif nameType == "CN": ava["type"] = rfc2459.id_at_commonName nameComponent = rfc2459.X520CommonName() elif nameType == "emailAddress": ava["type"] = rfc2459.emailAddress nameComponent = rfc2459.Pkcs9email(value) else: raise UnknownDNTypeError(nameType) if not nameType == "C" and not nameType == "emailAddress": # The value may have things like '\0' (i.e. a slash followed by # the number zero) that have to be decoded into the resulting # '\x00' (i.e. a byte with value zero). nameComponent[encoding] = six.ensure_binary(value).decode( encoding="unicode_escape" ) ava["value"] = nameComponent rdn = rfc2459.RelativeDistinguishedName() rdn.setComponentByPosition(0, ava) rdns.setComponentByPosition(pos, rdn) if tag: name = rfc2459.Name().subtype(implicitTag=tag) else: name = rfc2459.Name() name.setComponentByPosition(0, rdns) return name def stringToAlgorithmIdentifiers(string): """Helper function that converts a description of an algorithm to a representation usable by the pyasn1 package and a hash algorithm constant for use by pykey.""" algorithmIdentifier = rfc2459.AlgorithmIdentifier() algorithmType = None algorithm = None # We add Null parameters for RSA only addParameters = False if string == "sha1WithRSAEncryption": algorithmType = pykey.HASH_SHA1 algorithm = rfc2459.sha1WithRSAEncryption addParameters = True elif string == "sha256WithRSAEncryption": algorithmType = pykey.HASH_SHA256 algorithm = univ.ObjectIdentifier("1.2.840.113549.1.1.11") addParameters = True elif string == "md5WithRSAEncryption": algorithmType = pykey.HASH_MD5 algorithm = rfc2459.md5WithRSAEncryption addParameters = True elif string == "ecdsaWithSHA256": algorithmType = pykey.HASH_SHA256 algorithm = univ.ObjectIdentifier("1.2.840.10045.4.3.2") elif string == "ecdsaWithSHA384": algorithmType = pykey.HASH_SHA384 algorithm = univ.ObjectIdentifier("1.2.840.10045.4.3.3") elif string == "ecdsaWithSHA512": algorithmType = pykey.HASH_SHA512 algorithm = univ.ObjectIdentifier("1.2.840.10045.4.3.4") else: raise UnknownAlgorithmTypeError(string) algorithmIdentifier["algorithm"] = algorithm if addParameters: # Directly setting parameters to univ.Null doesn't currently work. nullEncapsulated = encoder.encode(univ.Null()) algorithmIdentifier["parameters"] = univ.Any(nullEncapsulated) return (algorithmIdentifier, algorithmType) def datetimeToTime(dt): """Takes a datetime object and returns an rfc2459.Time object with that time as its value as a GeneralizedTime""" time = rfc2459.Time() time["generalTime"] = useful.GeneralizedTime(dt.strftime("%Y%m%d%H%M%SZ")) return time def serialBytesToString(serialBytes): """Takes a list of integers in the interval [0, 255] and returns the corresponding serial number string.""" serialBytesLen = len(serialBytes) if serialBytesLen > 127: raise InvalidSerialNumber("{} bytes is too long".format(serialBytesLen)) # Prepend the ASN.1 INTEGER tag and length bytes. stringBytes = [getASN1Tag(univ.Integer), serialBytesLen] + serialBytes return bytes(stringBytes) class Certificate(object): """Utility class for reading a certificate specification and generating a signed x509 certificate""" def __init__(self, paramStream): self.versionValue = 2 # a value of 2 is X509v3 self.signature = "sha256WithRSAEncryption" self.issuer = "Default Issuer" actualNow = datetime.datetime.utcnow() self.now = datetime.datetime.strptime(str(actualNow.year), "%Y") aYearAndAWhile = datetime.timedelta(days=400) self.notBefore = self.now - aYearAndAWhile self.notAfter = self.now + aYearAndAWhile self.subject = "Default Subject" self.extensions = None # The serial number can be automatically generated from the # certificate specification. We need this value to depend in # part of what extensions are present. self.extensions are # pyasn1 objects. Depending on the string representation of # these objects can cause the resulting serial number to change # unexpectedly, so instead we depend on the original string # representation of the extensions as specified. self.extensionLines = None self.savedEmbeddedSCTListData = None self.subjectKey = pykey.keyFromSpecification("default") self.issuerKey = pykey.keyFromSpecification("default") self.serialNumber = None self.decodeParams(paramStream) # If a serial number wasn't specified, generate one based on # the certificate contents. if not self.serialNumber: self.serialNumber = self.generateSerialNumber() # This has to be last because the SCT signature depends on the # contents of the certificate. if self.savedEmbeddedSCTListData: self.addEmbeddedSCTListData() def generateSerialNumber(self): """Generates a serial number for this certificate based on its contents. Intended to be reproducible for compatibility with the build system on OS X (see the comment above main, later in this file).""" hasher = hashlib.sha256() hasher.update(six.ensure_binary(str(self.versionValue))) hasher.update(six.ensure_binary(self.signature)) hasher.update(six.ensure_binary(self.issuer)) hasher.update(six.ensure_binary(str(self.notBefore))) hasher.update(six.ensure_binary(str(self.notAfter))) hasher.update(six.ensure_binary(self.subject)) if self.extensionLines: for extensionLine in self.extensionLines: hasher.update(six.ensure_binary(extensionLine)) if self.savedEmbeddedSCTListData: # savedEmbeddedSCTListData is # (embeddedSCTListSpecification, critical), where |critical| # may be None hasher.update(six.ensure_binary(self.savedEmbeddedSCTListData[0])) if self.savedEmbeddedSCTListData[1]: hasher.update(six.ensure_binary(self.savedEmbeddedSCTListData[1])) serialBytes = [c for c in hasher.digest()[:20]] # Ensure that the most significant bit isn't set (which would # indicate a negative number, which isn't valid for serial # numbers). serialBytes[0] &= 0x7F # Also ensure that the least significant bit on the most # significant byte is set (to prevent a leading zero byte, # which also wouldn't be valid). serialBytes[0] |= 0x01 return serialBytesToString(serialBytes) def decodeParams(self, paramStream): for line in paramStream.readlines(): self.decodeParam(line.strip()) def decodeParam(self, line): param = line.split(":")[0] value = ":".join(line.split(":")[1:]) if param == "version": self.setVersion(value) elif param == "subject": self.subject = value elif param == "issuer": self.issuer = value elif param == "validity": self.decodeValidity(value) elif param == "extension": self.decodeExtension(value) elif param == "issuerKey": self.setupKey("issuer", value) elif param == "subjectKey": self.setupKey("subject", value) elif param == "signature": self.signature = value elif param == "serialNumber": serialNumber = int(value) # Ensure only serial numbers that conform to the rules listed in # generateSerialNumber() are permitted. if serialNumber < 1 or serialNumber > 127: raise InvalidSerialNumber(value) self.serialNumber = serialBytesToString([serialNumber]) else: raise UnknownParameterTypeError(param) def setVersion(self, version): intVersion = int(version) if intVersion >= 1 and intVersion <= 4: self.versionValue = intVersion - 1 else: raise UnknownVersionError(version) def decodeValidity(self, duration): match = re.search("([0-9]{8})-([0-9]{8})", duration) if match: self.notBefore = datetime.datetime.strptime(match.group(1), "%Y%m%d") self.notAfter = datetime.datetime.strptime(match.group(2), "%Y%m%d") else: delta = datetime.timedelta(days=(int(duration) / 2)) self.notBefore = self.now - delta self.notAfter = self.now + delta def decodeExtension(self, extension): match = re.search(r"([a-zA-Z]+)(\[critical\])?:(.*)", extension) if not match: raise UnknownExtensionTypeError(extension) extensionType = match.group(1) critical = match.group(2) value = match.group(3) if extensionType == "basicConstraints": self.addBasicConstraints(value, critical) elif extensionType == "keyUsage": self.addKeyUsage(value, critical) elif extensionType == "extKeyUsage": self.addExtKeyUsage(value, critical) elif extensionType == "subjectAlternativeName": self.addSubjectAlternativeName(value, critical) elif extensionType == "authorityInformationAccess": self.addAuthorityInformationAccess(value, critical) elif extensionType == "certificatePolicies": self.addCertificatePolicies(value, critical) elif extensionType == "nameConstraints": self.addNameConstraints(value, critical) elif extensionType == "nsCertType": self.addNSCertType(value, critical) elif extensionType == "TLSFeature": self.addTLSFeature(value, critical) elif extensionType == "embeddedSCTList": self.savedEmbeddedSCTListData = (value, critical) elif extensionType == "delegationUsage": self.addDelegationUsage(critical) else: raise UnknownExtensionTypeError(extensionType) if extensionType != "embeddedSCTList": if not self.extensionLines: self.extensionLines = [] self.extensionLines.append(extension) def setupKey(self, subjectOrIssuer, value): if subjectOrIssuer == "subject": self.subjectKey = pykey.keyFromSpecification(value) elif subjectOrIssuer == "issuer": self.issuerKey = pykey.keyFromSpecification(value) else: raise UnknownKeyTargetError(subjectOrIssuer) def addExtension(self, extensionType, extensionValue, critical): if not self.extensions: self.extensions = [] encapsulated = univ.OctetString(encoder.encode(extensionValue)) extension = rfc2459.Extension() extension["extnID"] = extensionType # critical is either the string '[critical]' or None. # We only care whether or not it is truthy. if critical: extension["critical"] = True extension["extnValue"] = encapsulated self.extensions.append(extension) def addBasicConstraints(self, basicConstraints, critical): cA = basicConstraints.split(",")[0] pathLenConstraint = basicConstraints.split(",")[1] basicConstraintsExtension = rfc2459.BasicConstraints() basicConstraintsExtension["cA"] = cA == "cA" if pathLenConstraint: pathLenConstraintValue = univ.Integer(int(pathLenConstraint)).subtype( subtypeSpec=constraint.ValueRangeConstraint(0, float("inf")) ) basicConstraintsExtension["pathLenConstraint"] = pathLenConstraintValue self.addExtension( rfc2459.id_ce_basicConstraints, basicConstraintsExtension, critical ) def addKeyUsage(self, keyUsage, critical): keyUsageExtension = rfc2459.KeyUsage(keyUsage) self.addExtension(rfc2459.id_ce_keyUsage, keyUsageExtension, critical) def keyPurposeToOID(self, keyPurpose): if keyPurpose == "serverAuth": return rfc2459.id_kp_serverAuth if keyPurpose == "clientAuth": return rfc2459.id_kp_clientAuth if keyPurpose == "codeSigning": return rfc2459.id_kp_codeSigning if keyPurpose == "emailProtection": return rfc2459.id_kp_emailProtection if keyPurpose == "nsSGC": return univ.ObjectIdentifier("2.16.840.1.113730.4.1") if keyPurpose == "OCSPSigning": return univ.ObjectIdentifier("1.3.6.1.5.5.7.3.9") if keyPurpose == "timeStamping": return rfc2459.id_kp_timeStamping raise UnknownKeyPurposeTypeError(keyPurpose) def addExtKeyUsage(self, extKeyUsage, critical): extKeyUsageExtension = rfc2459.ExtKeyUsageSyntax() for count, keyPurpose in enumerate(extKeyUsage.split(",")): extKeyUsageExtension.setComponentByPosition( count, self.keyPurposeToOID(keyPurpose) ) self.addExtension(rfc2459.id_ce_extKeyUsage, extKeyUsageExtension, critical) def addSubjectAlternativeName(self, names, critical): IPV4_PREFIX = "ip4:" subjectAlternativeName = rfc2459.SubjectAltName() for count, name in enumerate(names.split(",")): generalName = rfc2459.GeneralName() if "/" in name: directoryName = stringToDN( name, tag.Tag(tag.tagClassContext, tag.tagFormatSimple, 4) ) generalName["directoryName"] = directoryName elif "@" in name: generalName["rfc822Name"] = name elif name.startswith(IPV4_PREFIX): generalName["iPAddress"] = socket.inet_pton( socket.AF_INET, name[len(IPV4_PREFIX) :] ) else: # The string may have things like '\0' (i.e. a slash # followed by the number zero) that have to be decoded into # the resulting '\x00' (i.e. a byte with value zero). generalName["dNSName"] = six.ensure_binary(name).decode( "unicode_escape" ) subjectAlternativeName.setComponentByPosition(count, generalName) self.addExtension( rfc2459.id_ce_subjectAltName, subjectAlternativeName, critical ) def addAuthorityInformationAccess(self, ocspURI, critical): sequence = univ.Sequence() accessDescription = stringToAccessDescription(ocspURI) sequence.setComponentByPosition(0, accessDescription) self.addExtension(rfc2459.id_pe_authorityInfoAccess, sequence, critical) def addCertificatePolicies(self, policyOIDs, critical): policies = rfc2459.CertificatePolicies() for pos, policyOID in enumerate(policyOIDs.split(",")): if policyOID == "any": policyOID = "2.5.29.32.0" policy = rfc2459.PolicyInformation() policyIdentifier = rfc2459.CertPolicyId(policyOID) policy["policyIdentifier"] = policyIdentifier policies.setComponentByPosition(pos, policy) self.addExtension(rfc2459.id_ce_certificatePolicies, policies, critical) def addNameConstraints(self, constraints, critical): nameConstraints = rfc2459.NameConstraints() if constraints.startswith("permitted:"): (subtreesType, subtreesTag) = ("permittedSubtrees", 0) elif constraints.startswith("excluded:"): (subtreesType, subtreesTag) = ("excludedSubtrees", 1) else: raise UnknownNameConstraintsSpecificationError(constraints) generalSubtrees = rfc2459.GeneralSubtrees().subtype( implicitTag=tag.Tag( tag.tagClassContext, tag.tagFormatConstructed, subtreesTag ) ) subtrees = constraints[(constraints.find(":") + 1) :] for pos, name in enumerate(subtrees.split(",")): generalName = rfc2459.GeneralName() if "/" in name: directoryName = stringToDN( name, tag.Tag(tag.tagClassContext, tag.tagFormatSimple, 4) ) generalName["directoryName"] = directoryName else: generalName["dNSName"] = name generalSubtree = rfc2459.GeneralSubtree() generalSubtree["base"] = generalName generalSubtrees.setComponentByPosition(pos, generalSubtree) nameConstraints[subtreesType] = generalSubtrees self.addExtension(rfc2459.id_ce_nameConstraints, nameConstraints, critical) def addNSCertType(self, certType, critical): if certType != "sslServer": raise UnknownNSCertTypeError(certType) self.addExtension( univ.ObjectIdentifier("2.16.840.1.113730.1.1"), univ.BitString("'01'B"), critical, ) def addDelegationUsage(self, critical): if critical: raise UnknownDelegatedCredentialError(critical) self.addExtension( univ.ObjectIdentifier("1.3.6.1.4.1.44363.44"), univ.Null(), critical ) def addTLSFeature(self, features, critical): namedFeatures = {"OCSPMustStaple": 5} featureList = [f.strip() for f in features.split(",")] sequence = univ.Sequence() for pos, feature in enumerate(featureList): featureValue = 0 try: featureValue = int(feature) except ValueError: try: featureValue = namedFeatures[feature] except Exception: raise UnknownTLSFeature(feature) sequence.setComponentByPosition(pos, univ.Integer(featureValue)) self.addExtension( univ.ObjectIdentifier("1.3.6.1.5.5.7.1.24"), sequence, critical ) def addEmbeddedSCTListData(self): (scts, critical) = self.savedEmbeddedSCTListData encodedSCTs = [] for sctSpec in scts.split(","): match = re.search(r"(\w+):(\d{8})", sctSpec) if not match: raise InvalidSCTSpecification(sctSpec) keySpec = match.group(1) key = pykey.keyFromSpecification(keySpec) time = datetime.datetime.strptime(match.group(2), "%Y%m%d") tbsCertificate = self.getTBSCertificate() tbsDER = encoder.encode(tbsCertificate) sct = pyct.SCT(key, time, tbsDER, self.issuerKey) signed = sct.signAndEncode() lengthPrefix = pack("!H", len(signed)) encodedSCTs.append(lengthPrefix + signed) encodedSCTBytes = b"".join(encodedSCTs) lengthPrefix = pack("!H", len(encodedSCTBytes)) extensionBytes = lengthPrefix + encodedSCTBytes self.addExtension( univ.ObjectIdentifier("1.3.6.1.4.1.11129.2.4.2"), univ.OctetString(extensionBytes), critical, ) def getVersion(self): return rfc2459.Version(self.versionValue).subtype( explicitTag=tag.Tag(tag.tagClassContext, tag.tagFormatSimple, 0) ) def getSerialNumber(self): return decoder.decode(self.serialNumber)[0] def getIssuer(self): return stringToDN(self.issuer) def getValidity(self): validity = rfc2459.Validity() validity["notBefore"] = self.getNotBefore() validity["notAfter"] = self.getNotAfter() return validity def getNotBefore(self): return datetimeToTime(self.notBefore) def getNotAfter(self): return datetimeToTime(self.notAfter) def getSubject(self): return stringToDN(self.subject) def getTBSCertificate(self): (signatureOID, _) = stringToAlgorithmIdentifiers(self.signature) tbsCertificate = rfc2459.TBSCertificate() tbsCertificate["version"] = self.getVersion() tbsCertificate["serialNumber"] = self.getSerialNumber() tbsCertificate["signature"] = signatureOID tbsCertificate["issuer"] = self.getIssuer() tbsCertificate["validity"] = self.getValidity() tbsCertificate["subject"] = self.getSubject() tbsCertificate[ "subjectPublicKeyInfo" ] = self.subjectKey.asSubjectPublicKeyInfo() if self.extensions: extensions = rfc2459.Extensions().subtype( explicitTag=tag.Tag(tag.tagClassContext, tag.tagFormatSimple, 3) ) for count, extension in enumerate(self.extensions): extensions.setComponentByPosition(count, extension) tbsCertificate["extensions"] = extensions return tbsCertificate def toDER(self): (signatureOID, hashAlgorithm) = stringToAlgorithmIdentifiers(self.signature) certificate = rfc2459.Certificate() tbsCertificate = self.getTBSCertificate() certificate["tbsCertificate"] = tbsCertificate certificate["signatureAlgorithm"] = signatureOID tbsDER = encoder.encode(tbsCertificate) certificate["signatureValue"] = self.issuerKey.sign(tbsDER, hashAlgorithm) return encoder.encode(certificate) def toPEM(self): output = "-----BEGIN CERTIFICATE-----" der = self.toDER() b64 = six.ensure_text(base64.b64encode(der)) while b64: output += "\n" + b64[:64] b64 = b64[64:] output += "\n-----END CERTIFICATE-----" return output # The build harness will call this function with an output # file-like object and a path to a file containing a # specification. This will read the specification and output # the certificate as PEM. def main(output, inputPath): with open(inputPath) as configStream: output.write(Certificate(configStream).toPEM() + "\n") # When run as a standalone program, this will read a specification from # stdin and output the certificate as PEM to stdout. if __name__ == "__main__": print(Certificate(sys.stdin).toPEM())