# Authors: # Rob Crittenden # # Copyright (C) 2010 Red Hat # see file 'COPYING' for use and warranty information # # This program is free software; you can redistribute it and/or modify # it under the terms of the GNU General Public License as published by # the Free Software Foundation, either version 3 of the License, or # (at your option) any later version. # # This program is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the # GNU General Public License for more details. # # You should have received a copy of the GNU General Public License # along with this program. If not, see . # Certificates should be stored internally DER-encoded. We can be passed # a certificate several ways: read if from LDAP, read it from a 3rd party # app (dogtag, candlepin, etc) or as user input. The normalize_certificate() # function will convert an incoming certificate to DER-encoding. # Conventions # # Where possible the following naming conventions are used: # # cert: the certificate is a PEM-encoded certificate # dercert: the certificate is DER-encoded # rawcert: the cert is in an unknown format from __future__ import print_function import binascii import datetime import ipaddress import base64 import re from cryptography.hazmat.backends import default_backend import cryptography.x509 from pyasn1.type import univ, char, namedtype, tag from pyasn1.codec.der import decoder, encoder from pyasn1_modules import rfc2315, rfc2459 import six from ipalib import api from ipalib import util from ipalib import errors from ipapython.dn import DN if six.PY3: unicode = str PEM = 0 DER = 1 PEM_REGEX = re.compile( r'-----BEGIN CERTIFICATE-----.*?-----END CERTIFICATE-----', re.DOTALL) EKU_SERVER_AUTH = '1.3.6.1.5.5.7.3.1' EKU_CLIENT_AUTH = '1.3.6.1.5.5.7.3.2' EKU_CODE_SIGNING = '1.3.6.1.5.5.7.3.3' EKU_EMAIL_PROTECTION = '1.3.6.1.5.5.7.3.4' EKU_ANY = '2.5.29.37.0' EKU_PLACEHOLDER = '1.3.6.1.4.1.3319.6.10.16' SAN_UPN = '1.3.6.1.4.1.311.20.2.3' SAN_KRB5PRINCIPALNAME = '1.3.6.1.5.2.2' _subject_base = None def subject_base(): global _subject_base if _subject_base is None: config = api.Command['config_show']()['result'] _subject_base = DN(config['ipacertificatesubjectbase'][0]) return _subject_base def strip_header(pem): """ Remove the header and footer from a certificate. """ regexp = ( u"^-----BEGIN CERTIFICATE-----(.*?)-----END CERTIFICATE-----" ) if isinstance(pem, bytes): regexp = regexp.encode('ascii') s = re.search(regexp, pem, re.MULTILINE | re.DOTALL) if s is not None: return s.group(1) else: return pem def load_certificate(data, datatype=PEM): """ Load an X.509 certificate. :param datatype: PEM for base64-encoded data (with or without header), or DER :return: a python-cryptography ``CertificateSigningRequest`` object. :raises: ``ValueError`` if unable to load the certificate. """ if type(data) in (tuple, list): data = data[0] if (datatype == PEM): data = strip_header(data) data = base64.b64decode(data) return cryptography.x509.load_der_x509_certificate(data, default_backend()) def load_certificate_from_file(filename, dbdir=None): """ Load a certificate from a PEM file. Returns a python-cryptography ``Certificate`` object. """ with open(filename, mode='rb') as f: return load_certificate(f.read(), PEM) def load_certificate_list(data): """ Load a certificate list from a sequence of concatenated PEMs. Return a list of python-cryptography ``Certificate`` objects. """ certs = PEM_REGEX.findall(data) certs = [load_certificate(cert, PEM) for cert in certs] return certs def load_certificate_list_from_file(filename): """ Load a certificate list from a PEM file. Return a list of python-cryptography ``Certificate`` objects. """ with open(filename) as f: return load_certificate_list(f.read()) def pkcs7_to_pems(data, datatype=PEM): """ Extract certificates from a PKCS #7 object. Return a ``list`` of X.509 PEM strings. """ if datatype == PEM: match = re.match( r'-----BEGIN PKCS7-----(.*?)-----END PKCS7-----', data, re.DOTALL) if not match: raise ValueError("not a valid PKCS#7 PEM") data = base64.b64decode(match.group(1)) content_info, tail = decoder.decode(data, rfc2315.ContentInfo()) if tail: raise ValueError("not a valid PKCS#7 message") if content_info['contentType'] != rfc2315.signedData: raise ValueError("not a PKCS#7 signed data message") signed_data, tail = decoder.decode(bytes(content_info['content']), rfc2315.SignedData()) if tail: raise ValueError("not a valid PKCS#7 signed data message") result = [] for certificate in signed_data['certificates']: certificate = encoder.encode(certificate) certificate = base64.b64encode(certificate) certificate = make_pem(certificate) result.append(certificate) return result def is_self_signed(certificate, datatype=PEM): cert = load_certificate(certificate, datatype) return cert.issuer == cert.subject def _get_der_field(cert, datatype, dbdir, field): cert = normalize_certificate(cert) cert = decoder.decode(cert, rfc2459.Certificate())[0] field = cert['tbsCertificate'][field] field = encoder.encode(field) return field def get_der_subject(cert, datatype=PEM, dbdir=None): return _get_der_field(cert, datatype, dbdir, 'subject') def get_der_issuer(cert, datatype=PEM, dbdir=None): return _get_der_field(cert, datatype, dbdir, 'issuer') def get_der_serial_number(cert, datatype=PEM, dbdir=None): return _get_der_field(cert, datatype, dbdir, 'serialNumber') def get_der_public_key_info(cert, datatype=PEM, dbdir=None): return _get_der_field(cert, datatype, dbdir, 'subjectPublicKeyInfo') def get_ext_key_usage(certificate, datatype=PEM): cert = load_certificate(certificate, datatype) try: eku = cert.extensions.get_extension_for_oid( cryptography.x509.oid.ExtensionOID.EXTENDED_KEY_USAGE).value except cryptography.x509.ExtensionNotFound: return None return set(oid.dotted_string for oid in eku) def make_pem(data): """ Convert a raw base64-encoded blob into something that looks like a PE file with lines split to 64 characters and proper headers. """ if isinstance(data, bytes): data = data.decode('ascii') pemcert = '\r\n'.join([data[x:x+64] for x in range(0, len(data), 64)]) return '-----BEGIN CERTIFICATE-----\n' + \ pemcert + \ '\n-----END CERTIFICATE-----' def normalize_certificate(rawcert): """ Incoming certificates should be DER-encoded. If not it is converted to DER-format. Note that this can't be a normalizer on a Param because only unicode variables are normalized. """ if not rawcert: return None rawcert = strip_header(rawcert) try: if isinstance(rawcert, bytes): # base64 must work with utf-8, otherwise it is raw bin certificate decoded_cert = rawcert.decode('utf-8') else: decoded_cert = rawcert except UnicodeDecodeError: dercert = rawcert else: if util.isvalid_base64(decoded_cert): try: dercert = base64.b64decode(decoded_cert) except Exception as e: raise errors.Base64DecodeError(reason=str(e)) else: dercert = rawcert # At this point we should have a DER certificate. # Attempt to decode it. validate_certificate(dercert, datatype=DER) return dercert def validate_certificate(cert, datatype=PEM): """ Perform cert validation by trying to load it via python-cryptography. """ try: load_certificate(cert, datatype=datatype) except ValueError as e: raise errors.CertificateFormatError(error=str(e)) def write_certificate(rawcert, filename): """ Write the certificate to a file in PEM format. The cert value can be either DER or PEM-encoded, it will be normalized to DER regardless, then back out to PEM. """ dercert = normalize_certificate(rawcert) try: fp = open(filename, 'w') fp.write(make_pem(base64.b64encode(dercert))) fp.close() except (IOError, OSError) as e: raise errors.FileError(reason=str(e)) def write_certificate_list(rawcerts, filename): """ Write a list of certificates to a file in PEM format. The cert values can be either DER or PEM-encoded, they will be normalized to DER regardless, then back out to PEM. """ dercerts = [normalize_certificate(rawcert) for rawcert in rawcerts] try: with open(filename, 'w') as f: for cert in dercerts: cert = base64.b64encode(cert) cert = make_pem(cert) f.write(cert + '\n') except (IOError, OSError) as e: raise errors.FileError(reason=str(e)) def _encode_extension(oid, critical, value): ext = rfc2459.Extension() ext['extnID'] = univ.ObjectIdentifier(oid) ext['critical'] = univ.Boolean(critical) ext['extnValue'] = univ.Any(encoder.encode(univ.OctetString(value))) ext = encoder.encode(ext) return ext def encode_ext_key_usage(ext_key_usage): eku = rfc2459.ExtKeyUsageSyntax() for i, oid in enumerate(ext_key_usage): eku[i] = univ.ObjectIdentifier(oid) eku = encoder.encode(eku) return _encode_extension('2.5.29.37', EKU_ANY not in ext_key_usage, eku) class _PrincipalName(univ.Sequence): componentType = namedtype.NamedTypes( namedtype.NamedType('name-type', univ.Integer().subtype( explicitTag=tag.Tag(tag.tagClassContext, tag.tagFormatSimple, 0)) ), namedtype.NamedType('name-string', univ.SequenceOf(char.GeneralString()).subtype( explicitTag=tag.Tag(tag.tagClassContext, tag.tagFormatSimple, 1)) ), ) class _KRB5PrincipalName(univ.Sequence): componentType = namedtype.NamedTypes( namedtype.NamedType('realm', char.GeneralString().subtype( explicitTag=tag.Tag(tag.tagClassContext, tag.tagFormatSimple, 0)) ), namedtype.NamedType('principalName', _PrincipalName().subtype( explicitTag=tag.Tag(tag.tagClassContext, tag.tagFormatSimple, 1)) ), ) def _decode_krb5principalname(data): principal = decoder.decode(data, asn1Spec=_KRB5PrincipalName())[0] realm = (unicode(principal['realm']).replace('\\', '\\\\') .replace('@', '\\@')) name = principal['principalName']['name-string'] name = u'/'.join(unicode(n).replace('\\', '\\\\') .replace('/', '\\/') .replace('@', '\\@') for n in name) name = u'%s@%s' % (name, realm) return name class KRB5PrincipalName(cryptography.x509.general_name.OtherName): def __init__(self, type_id, value): super(KRB5PrincipalName, self).__init__(type_id, value) self.name = _decode_krb5principalname(value) class UPN(cryptography.x509.general_name.OtherName): def __init__(self, type_id, value): super(UPN, self).__init__(type_id, value) self.name = unicode( decoder.decode(value, asn1Spec=char.UTF8String())[0]) OTHERNAME_CLASS_MAP = { SAN_KRB5PRINCIPALNAME: KRB5PrincipalName, SAN_UPN: UPN, } def process_othernames(gns): """ Process python-cryptography GeneralName values, yielding OtherName values of more specific type if type is known. """ for gn in gns: if isinstance(gn, cryptography.x509.general_name.OtherName): cls = OTHERNAME_CLASS_MAP.get( gn.type_id.dotted_string, cryptography.x509.general_name.OtherName) yield cls(gn.type_id, gn.value) else: yield gn def get_san_general_names(cert): """ Return SAN general names from a python-cryptography certificate object. If the SAN extension is not present, return an empty sequence. Because python-cryptography does not yet provide a way to handle unrecognised critical extensions (which may occur), we must parse the certificate and extract the General Names. For uniformity with other code, we manually construct values of python-crytography GeneralName subtypes. python-cryptography does not yet provide types for ediPartyName or x400Address, so we drop these name types. otherNames are NOT instantiated to more specific types where the type is known. Use ``process_othernames`` to do that. When python-cryptography can handle certs with unrecognised critical extensions and implements ediPartyName and x400Address, this function (and helpers) will be redundant and should go away. """ tbs = decoder.decode( cert.tbs_certificate_bytes, asn1Spec=rfc2459.TBSCertificate() )[0] OID_SAN = univ.ObjectIdentifier('2.5.29.17') # One would expect KeyError or empty iterable when the key ('extensions' # in this particular case) is not pressent in the certificate but pyasn1 # returns None here extensions = tbs['extensions'] or [] gns = [] for ext in extensions: if ext['extnID'] == OID_SAN: der = decoder.decode( ext['extnValue'], asn1Spec=univ.OctetString())[0] gns = decoder.decode(der, asn1Spec=rfc2459.SubjectAltName())[0] break GENERAL_NAME_CONSTRUCTORS = { 'rfc822Name': lambda x: cryptography.x509.RFC822Name(unicode(x)), 'dNSName': lambda x: cryptography.x509.DNSName(unicode(x)), 'directoryName': _pyasn1_to_cryptography_directoryname, 'registeredID': _pyasn1_to_cryptography_registeredid, 'iPAddress': _pyasn1_to_cryptography_ipaddress, 'uniformResourceIdentifier': lambda x: cryptography.x509.UniformResourceIdentifier(unicode(x)), 'otherName': _pyasn1_to_cryptography_othername, } result = [] for gn in gns: gn_type = gn.getName() if gn_type in GENERAL_NAME_CONSTRUCTORS: result.append( GENERAL_NAME_CONSTRUCTORS[gn_type](gn.getComponent())) return result def _pyasn1_to_cryptography_directoryname(dn): attrs = [] # Name is CHOICE { RDNSequence } (only one possibility) for rdn in dn.getComponent(): for ava in rdn: attr = cryptography.x509.NameAttribute( _pyasn1_to_cryptography_oid(ava['type']), unicode(decoder.decode(ava['value'])[0]) ) attrs.append(attr) return cryptography.x509.DirectoryName(cryptography.x509.Name(attrs)) def _pyasn1_to_cryptography_registeredid(oid): return cryptography.x509.RegisteredID(_pyasn1_to_cryptography_oid(oid)) def _pyasn1_to_cryptography_ipaddress(octet_string): return cryptography.x509.IPAddress( ipaddress.ip_address(bytes(octet_string))) def _pyasn1_to_cryptography_othername(on): return cryptography.x509.OtherName( _pyasn1_to_cryptography_oid(on['type-id']), bytes(on['value']) ) def _pyasn1_to_cryptography_oid(oid): return cryptography.x509.ObjectIdentifier(str(oid)) def chunk(size, s): """Yield chunks of the specified size from the given string. The input must be a multiple of the chunk size (otherwise trailing characters are dropped). Works on character strings only. """ return (u''.join(span) for span in six.moves.zip(*[iter(s)] * size)) def add_colons(s): """Add colons between each nibble pair in a hex string.""" return u':'.join(chunk(2, s)) def to_hex_with_colons(bs): """Convert bytes to a hex string with colons.""" return add_colons(binascii.hexlify(bs).decode('utf-8')) class UTC(datetime.tzinfo): ZERO = datetime.timedelta(0) def tzname(self, dt): return "UTC" def utcoffset(self, dt): return self.ZERO def dst(self, dt): return self.ZERO def format_datetime(t): if t.tzinfo is None: t = t.replace(tzinfo=UTC()) return unicode(t.strftime("%a %b %d %H:%M:%S %Y %Z"))