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# Copyright (C) Dnspython Contributors, see LICENSE for text of ISC license # Copyright (C) 2001-2007, 2009-2011 Nominum, Inc. # # Permission to use, copy, modify, and distribute this software and its # documentation for any purpose with or without fee is hereby granted, # provided that the above copyright notice and this permission notice # appear in all copies. # # THE SOFTWARE IS PROVIDED "AS IS" AND NOMINUM DISCLAIMS ALL WARRANTIES # WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF # MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL NOMINUM BE LIABLE FOR # ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES # WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN # ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT # OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. """DNS TSIG support.""" import base64 import hashlib import hmac import struct import dns.exception import dns.name import dns.rcode import dns.rdataclass class BadTime(dns.exception.DNSException): """The current time is not within the TSIG's validity time.""" class BadSignature(dns.exception.DNSException): """The TSIG signature fails to verify.""" class BadKey(dns.exception.DNSException): """The TSIG record owner name does not match the key.""" class BadAlgorithm(dns.exception.DNSException): """The TSIG algorithm does not match the key.""" class PeerError(dns.exception.DNSException): """Base class for all TSIG errors generated by the remote peer""" class PeerBadKey(PeerError): """The peer didn't know the key we used""" class PeerBadSignature(PeerError): """The peer didn't like the signature we sent""" class PeerBadTime(PeerError): """The peer didn't like the time we sent""" class PeerBadTruncation(PeerError): """The peer didn't like amount of truncation in the TSIG we sent""" # TSIG Algorithms HMAC_MD5 = dns.name.from_text("HMAC-MD5.SIG-ALG.REG.INT") HMAC_SHA1 = dns.name.from_text("hmac-sha1") HMAC_SHA224 = dns.name.from_text("hmac-sha224") HMAC_SHA256 = dns.name.from_text("hmac-sha256") HMAC_SHA256_128 = dns.name.from_text("hmac-sha256-128") HMAC_SHA384 = dns.name.from_text("hmac-sha384") HMAC_SHA384_192 = dns.name.from_text("hmac-sha384-192") HMAC_SHA512 = dns.name.from_text("hmac-sha512") HMAC_SHA512_256 = dns.name.from_text("hmac-sha512-256") GSS_TSIG = dns.name.from_text("gss-tsig") default_algorithm = HMAC_SHA256 mac_sizes = { HMAC_SHA1: 20, HMAC_SHA224: 28, HMAC_SHA256: 32, HMAC_SHA256_128: 16, HMAC_SHA384: 48, HMAC_SHA384_192: 24, HMAC_SHA512: 64, HMAC_SHA512_256: 32, HMAC_MD5: 16, GSS_TSIG: 128, # This is what we assume to be the worst case! } class GSSTSig: """ GSS-TSIG TSIG implementation. This uses the GSS-API context established in the TKEY message handshake to sign messages using GSS-API message integrity codes, per the RFC. In order to avoid a direct GSSAPI dependency, the keyring holds a ref to the GSSAPI object required, rather than the key itself. """ def __init__(self, gssapi_context): self.gssapi_context = gssapi_context self.data = b"" self.name = "gss-tsig" def update(self, data): self.data += data def sign(self): # defer to the GSSAPI function to sign return self.gssapi_context.get_signature(self.data) def verify(self, expected): try: # defer to the GSSAPI function to verify return self.gssapi_context.verify_signature(self.data, expected) except Exception: # note the usage of a bare exception raise BadSignature class GSSTSigAdapter: def __init__(self, keyring): self.keyring = keyring def __call__(self, message, keyname): if keyname in self.keyring: key = self.keyring[keyname] if isinstance(key, Key) and key.algorithm == GSS_TSIG: if message: GSSTSigAdapter.parse_tkey_and_step(key, message, keyname) return key else: return None @classmethod def parse_tkey_and_step(cls, key, message, keyname): # if the message is a TKEY type, absorb the key material # into the context using step(); this is used to allow the # client to complete the GSSAPI negotiation before attempting # to verify the signed response to a TKEY message exchange try: rrset = message.find_rrset( message.answer, keyname, dns.rdataclass.ANY, dns.rdatatype.TKEY ) if rrset: token = rrset[0].key gssapi_context = key.secret return gssapi_context.step(token) except KeyError: pass class HMACTSig: """ HMAC TSIG implementation. This uses the HMAC python module to handle the sign/verify operations. """ _hashes = { HMAC_SHA1: hashlib.sha1, HMAC_SHA224: hashlib.sha224, HMAC_SHA256: hashlib.sha256, HMAC_SHA256_128: (hashlib.sha256, 128), HMAC_SHA384: hashlib.sha384, HMAC_SHA384_192: (hashlib.sha384, 192), HMAC_SHA512: hashlib.sha512, HMAC_SHA512_256: (hashlib.sha512, 256), HMAC_MD5: hashlib.md5, } def __init__(self, key, algorithm): try: hashinfo = self._hashes[algorithm] except KeyError: raise NotImplementedError(f"TSIG algorithm {algorithm} is not supported") # create the HMAC context if isinstance(hashinfo, tuple): self.hmac_context = hmac.new(key, digestmod=hashinfo[0]) self.size = hashinfo[1] else: self.hmac_context = hmac.new(key, digestmod=hashinfo) self.size = None self.name = self.hmac_context.name if self.size: self.name += f"-{self.size}" def update(self, data): return self.hmac_context.update(data) def sign(self): # defer to the HMAC digest() function for that digestmod digest = self.hmac_context.digest() if self.size: digest = digest[: (self.size // 8)] return digest def verify(self, expected): # re-digest and compare the results mac = self.sign() if not hmac.compare_digest(mac, expected): raise BadSignature def _digest(wire, key, rdata, time=None, request_mac=None, ctx=None, multi=None): """Return a context containing the TSIG rdata for the input parameters @rtype: dns.tsig.HMACTSig or dns.tsig.GSSTSig object @raises ValueError: I{other_data} is too long @raises NotImplementedError: I{algorithm} is not supported """ first = not (ctx and multi) if first: ctx = get_context(key) if request_mac: ctx.update(struct.pack("!H", len(request_mac))) ctx.update(request_mac) ctx.update(struct.pack("!H", rdata.original_id)) ctx.update(wire[2:]) if first: ctx.update(key.name.to_digestable()) ctx.update(struct.pack("!H", dns.rdataclass.ANY)) ctx.update(struct.pack("!I", 0)) if time is None: time = rdata.time_signed upper_time = (time >> 32) & 0xFFFF lower_time = time & 0xFFFFFFFF time_encoded = struct.pack("!HIH", upper_time, lower_time, rdata.fudge) other_len = len(rdata.other) if other_len > 65535: raise ValueError("TSIG Other Data is > 65535 bytes") if first: ctx.update(key.algorithm.to_digestable() + time_encoded) ctx.update(struct.pack("!HH", rdata.error, other_len) + rdata.other) else: ctx.update(time_encoded) return ctx def _maybe_start_digest(key, mac, multi): """If this is the first message in a multi-message sequence, start a new context. @rtype: dns.tsig.HMACTSig or dns.tsig.GSSTSig object """ if multi: ctx = get_context(key) ctx.update(struct.pack("!H", len(mac))) ctx.update(mac) return ctx else: return None def sign(wire, key, rdata, time=None, request_mac=None, ctx=None, multi=False): """Return a (tsig_rdata, mac, ctx) tuple containing the HMAC TSIG rdata for the input parameters, the HMAC MAC calculated by applying the TSIG signature algorithm, and the TSIG digest context. @rtype: (string, dns.tsig.HMACTSig or dns.tsig.GSSTSig object) @raises ValueError: I{other_data} is too long @raises NotImplementedError: I{algorithm} is not supported """ ctx = _digest(wire, key, rdata, time, request_mac, ctx, multi) mac = ctx.sign() tsig = rdata.replace(time_signed=time, mac=mac) return (tsig, _maybe_start_digest(key, mac, multi)) def validate( wire, key, owner, rdata, now, request_mac, tsig_start, ctx=None, multi=False ): """Validate the specified TSIG rdata against the other input parameters. @raises FormError: The TSIG is badly formed. @raises BadTime: There is too much time skew between the client and the server. @raises BadSignature: The TSIG signature did not validate @rtype: dns.tsig.HMACTSig or dns.tsig.GSSTSig object""" (adcount,) = struct.unpack("!H", wire[10:12]) if adcount == 0: raise dns.exception.FormError adcount -= 1 new_wire = wire[0:10] + struct.pack("!H", adcount) + wire[12:tsig_start] if rdata.error != 0: if rdata.error == dns.rcode.BADSIG: raise PeerBadSignature elif rdata.error == dns.rcode.BADKEY: raise PeerBadKey elif rdata.error == dns.rcode.BADTIME: raise PeerBadTime elif rdata.error == dns.rcode.BADTRUNC: raise PeerBadTruncation else: raise PeerError("unknown TSIG error code %d" % rdata.error) if abs(rdata.time_signed - now) > rdata.fudge: raise BadTime if key.name != owner: raise BadKey if key.algorithm != rdata.algorithm: raise BadAlgorithm ctx = _digest(new_wire, key, rdata, None, request_mac, ctx, multi) ctx.verify(rdata.mac) return _maybe_start_digest(key, rdata.mac, multi) def get_context(key): """Returns an HMAC context for the specified key. @rtype: HMAC context @raises NotImplementedError: I{algorithm} is not supported """ if key.algorithm == GSS_TSIG: return GSSTSig(key.secret) else: return HMACTSig(key.secret, key.algorithm) class Key: def __init__(self, name, secret, algorithm=default_algorithm): if isinstance(name, str): name = dns.name.from_text(name) self.name = name if isinstance(secret, str): secret = base64.decodebytes(secret.encode()) self.secret = secret if isinstance(algorithm, str): algorithm = dns.name.from_text(algorithm) self.algorithm = algorithm def __eq__(self, other): return ( isinstance(other, Key) and self.name == other.name and self.secret == other.secret and self.algorithm == other.algorithm ) def __repr__(self): r = f"<DNS key name='{self.name}', " + f"algorithm='{self.algorithm}'" if self.algorithm != GSS_TSIG: r += f", secret='{base64.b64encode(self.secret).decode()}'" r += ">" return r