ÿØÿà JFIF    ÿÛ „  ( %!1!%)+//.383,7(-.+  -%%-////---/-.+/--+------/------/--0+--/-/-----.-----ÿÀ  ¥2" ÿÄ     ÿÄ J    ! 1AQ"aq2‘#BR‚¡ÁÑ3br’¢±Âð$CSƒ²á4c“%DsÓñÿÄ   ÿÄ *  !1AQa‘"2q3±ð#b¡ÿÚ   ? ¼QxJQaÍuò¸Zö Úü8,ÐÚú "SSn<rçù–´âE—^ªBÖ9À\†¸ÔÁT­ÃÛ5 ëd´³Í#Ý;Þ38œî ¶H£M:wÎ3…³…âpÔF&‚FK¸9„â4àGEõªfÿ ‘ñ(ßw­pŽF|È¥ù®häðÍѶ¹‘[ÒinÙW¶ùñY˜Q{›K"išÒ[Ú8žë\F¹@-?v"ÔU”,ìöžkÿ {I‡£šÍ?e ríV .............................................................................................................................................................................. ............................................................................. ÿØÿà JFIF    ÿÛ „  ( %!1!%)+//.383,7(-.+  -%%-////---/-.+/--+------/------/--0+--/-/-----.-----ÿÀ  ¥2" ÿÄ     ÿÄ J    ! 1AQ"aq2‘#BR‚¡ÁÑ3br’¢±Âð$CSƒ²á4c“%DsÓñÿÄ   ÿÄ *  !1AQa‘"2q3±ð#b¡ÿÚ   ? ¼QxJQaÍuò¸Zö Úü8,ÐÚú "SSn<rçù–´âE—^ªBÖ9À\†¸ÔÁT­ÃÛ5 ëd´³Í#Ý;Þ38œî ¶H£M:wÎ3…³…âpÔF&‚FK¸9„â4àGEõªfÿ ‘ñ(ßw­pŽF|È¥ù®häðÍѶ¹‘[ÒinÙW¶ùñY˜Q{›K"išÒ[Ú8žë\F¹@-?v"ÔU”,ìöžkÿ {I‡£šÍ?e ríV .............................................................................................................................................................................. ............................................................................. from cryptography.hazmat.backends import default_backend from cryptography.hazmat.primitives import hashes from cryptography.hazmat.primitives.asymmetric import ec, utils from dns.dnssecalgs.cryptography import CryptographyPrivateKey, CryptographyPublicKey from dns.dnssectypes import Algorithm from dns.rdtypes.ANY.DNSKEY import DNSKEY class PublicECDSA(CryptographyPublicKey): key: ec.EllipticCurvePublicKey key_cls = ec.EllipticCurvePublicKey algorithm: Algorithm chosen_hash: hashes.HashAlgorithm curve: ec.EllipticCurve octets: int def verify(self, signature: bytes, data: bytes) -> None: sig_r = signature[0 : self.octets] sig_s = signature[self.octets :] sig = utils.encode_dss_signature( int.from_bytes(sig_r, "big"), int.from_bytes(sig_s, "big") ) self.key.verify(sig, data, ec.ECDSA(self.chosen_hash)) def encode_key_bytes(self) -> bytes: """Encode a public key per RFC 6605, section 4.""" pn = self.key.public_numbers() return pn.x.to_bytes(self.octets, "big") + pn.y.to_bytes(self.octets, "big") @classmethod def from_dnskey(cls, key: DNSKEY) -> "PublicECDSA": cls._ensure_algorithm_key_combination(key) ecdsa_x = key.key[0 : cls.octets] ecdsa_y = key.key[cls.octets : cls.octets * 2] return cls( key=ec.EllipticCurvePublicNumbers( curve=cls.curve, x=int.from_bytes(ecdsa_x, "big"), y=int.from_bytes(ecdsa_y, "big"), ).public_key(default_backend()), ) class PrivateECDSA(CryptographyPrivateKey): key: ec.EllipticCurvePrivateKey key_cls = ec.EllipticCurvePrivateKey public_cls = PublicECDSA def sign( self, data: bytes, verify: bool = False, deterministic: bool = True, ) -> bytes: """Sign using a private key per RFC 6605, section 4.""" algorithm = ec.ECDSA( self.public_cls.chosen_hash, deterministic_signing=deterministic ) der_signature = self.key.sign(data, algorithm) dsa_r, dsa_s = utils.decode_dss_signature(der_signature) signature = int.to_bytes( dsa_r, length=self.public_cls.octets, byteorder="big" ) + int.to_bytes(dsa_s, length=self.public_cls.octets, byteorder="big") if verify: self.public_key().verify(signature, data) return signature @classmethod def generate(cls) -> "PrivateECDSA": return cls( key=ec.generate_private_key( curve=cls.public_cls.curve, backend=default_backend() ), ) class PublicECDSAP256SHA256(PublicECDSA): algorithm = Algorithm.ECDSAP256SHA256 chosen_hash = hashes.SHA256() curve = ec.SECP256R1() octets = 32 class PrivateECDSAP256SHA256(PrivateECDSA): public_cls = PublicECDSAP256SHA256 class PublicECDSAP384SHA384(PublicECDSA): algorithm = Algorithm.ECDSAP384SHA384 chosen_hash = hashes.SHA384() curve = ec.SECP384R1() octets = 48 class PrivateECDSAP384SHA384(PrivateECDSA): public_cls = PublicECDSAP384SHA384