AlkantarClanX12
Current Path : /opt/hc_python/lib/python3.8/site-packages/dns/dnssecalgs/ |
Current File : //opt/hc_python/lib/python3.8/site-packages/dns/dnssecalgs/dsa.py |
import struct from cryptography.hazmat.backends import default_backend from cryptography.hazmat.primitives import hashes from cryptography.hazmat.primitives.asymmetric import dsa, utils from dns.dnssecalgs.cryptography import CryptographyPrivateKey, CryptographyPublicKey from dns.dnssectypes import Algorithm from dns.rdtypes.ANY.DNSKEY import DNSKEY class PublicDSA(CryptographyPublicKey): key: dsa.DSAPublicKey key_cls = dsa.DSAPublicKey algorithm = Algorithm.DSA chosen_hash = hashes.SHA1() def verify(self, signature: bytes, data: bytes) -> None: sig_r = signature[1:21] sig_s = signature[21:] sig = utils.encode_dss_signature( int.from_bytes(sig_r, "big"), int.from_bytes(sig_s, "big") ) self.key.verify(sig, data, self.chosen_hash) def encode_key_bytes(self) -> bytes: """Encode a public key per RFC 2536, section 2.""" pn = self.key.public_numbers() dsa_t = (self.key.key_size // 8 - 64) // 8 if dsa_t > 8: raise ValueError("unsupported DSA key size") octets = 64 + dsa_t * 8 res = struct.pack("!B", dsa_t) res += pn.parameter_numbers.q.to_bytes(20, "big") res += pn.parameter_numbers.p.to_bytes(octets, "big") res += pn.parameter_numbers.g.to_bytes(octets, "big") res += pn.y.to_bytes(octets, "big") return res @classmethod def from_dnskey(cls, key: DNSKEY) -> "PublicDSA": cls._ensure_algorithm_key_combination(key) keyptr = key.key (t,) = struct.unpack("!B", keyptr[0:1]) keyptr = keyptr[1:] octets = 64 + t * 8 dsa_q = keyptr[0:20] keyptr = keyptr[20:] dsa_p = keyptr[0:octets] keyptr = keyptr[octets:] dsa_g = keyptr[0:octets] keyptr = keyptr[octets:] dsa_y = keyptr[0:octets] return cls( key=dsa.DSAPublicNumbers( # type: ignore int.from_bytes(dsa_y, "big"), dsa.DSAParameterNumbers( int.from_bytes(dsa_p, "big"), int.from_bytes(dsa_q, "big"), int.from_bytes(dsa_g, "big"), ), ).public_key(default_backend()), ) class PrivateDSA(CryptographyPrivateKey): key: dsa.DSAPrivateKey key_cls = dsa.DSAPrivateKey public_cls = PublicDSA def sign(self, data: bytes, verify: bool = False) -> bytes: """Sign using a private key per RFC 2536, section 3.""" public_dsa_key = self.key.public_key() if public_dsa_key.key_size > 1024: raise ValueError("DSA key size overflow") der_signature = self.key.sign(data, self.public_cls.chosen_hash) dsa_r, dsa_s = utils.decode_dss_signature(der_signature) dsa_t = (public_dsa_key.key_size // 8 - 64) // 8 octets = 20 signature = ( struct.pack("!B", dsa_t) + int.to_bytes(dsa_r, length=octets, byteorder="big") + int.to_bytes(dsa_s, length=octets, byteorder="big") ) if verify: self.public_key().verify(signature, data) return signature @classmethod def generate(cls, key_size: int) -> "PrivateDSA": return cls( key=dsa.generate_private_key(key_size=key_size), ) class PublicDSANSEC3SHA1(PublicDSA): algorithm = Algorithm.DSANSEC3SHA1 class PrivateDSANSEC3SHA1(PrivateDSA): public_cls = PublicDSANSEC3SHA1