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# Copyright (C) Dnspython Contributors, see LICENSE for text of ISC license # Copyright (C) 2003-2007, 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 Zones.""" import contextlib import io import os import struct from typing import ( Any, Callable, Iterable, Iterator, List, MutableMapping, Optional, Set, Tuple, Union, ) import dns.exception import dns.grange import dns.immutable import dns.name import dns.node import dns.rdata import dns.rdataclass import dns.rdataset import dns.rdatatype import dns.rdtypes.ANY.SOA import dns.rdtypes.ANY.ZONEMD import dns.rrset import dns.tokenizer import dns.transaction import dns.ttl import dns.zonefile from dns.zonetypes import DigestHashAlgorithm, DigestScheme, _digest_hashers class BadZone(dns.exception.DNSException): """The DNS zone is malformed.""" class NoSOA(BadZone): """The DNS zone has no SOA RR at its origin.""" class NoNS(BadZone): """The DNS zone has no NS RRset at its origin.""" class UnknownOrigin(BadZone): """The DNS zone's origin is unknown.""" class UnsupportedDigestScheme(dns.exception.DNSException): """The zone digest's scheme is unsupported.""" class UnsupportedDigestHashAlgorithm(dns.exception.DNSException): """The zone digest's origin is unsupported.""" class NoDigest(dns.exception.DNSException): """The DNS zone has no ZONEMD RRset at its origin.""" class DigestVerificationFailure(dns.exception.DNSException): """The ZONEMD digest failed to verify.""" def _validate_name( name: dns.name.Name, origin: Optional[dns.name.Name], relativize: bool, ) -> dns.name.Name: # This name validation code is shared by Zone and Version if origin is None: # This should probably never happen as other code (e.g. # _rr_line) will notice the lack of an origin before us, but # we check just in case! raise KeyError("no zone origin is defined") if name.is_absolute(): if not name.is_subdomain(origin): raise KeyError("name parameter must be a subdomain of the zone origin") if relativize: name = name.relativize(origin) else: # We have a relative name. Make sure that the derelativized name is # not too long. try: abs_name = name.derelativize(origin) except dns.name.NameTooLong: # We map dns.name.NameTooLong to KeyError to be consistent with # the other exceptions above. raise KeyError("relative name too long for zone") if not relativize: # We have a relative name in a non-relative zone, so use the # derelativized name. name = abs_name return name class Zone(dns.transaction.TransactionManager): """A DNS zone. A ``Zone`` is a mapping from names to nodes. The zone object may be treated like a Python dictionary, e.g. ``zone[name]`` will retrieve the node associated with that name. The *name* may be a ``dns.name.Name object``, or it may be a string. In either case, if the name is relative it is treated as relative to the origin of the zone. """ node_factory: Callable[[], dns.node.Node] = dns.node.Node map_factory: Callable[[], MutableMapping[dns.name.Name, dns.node.Node]] = dict writable_version_factory: Optional[Callable[[], "WritableVersion"]] = None immutable_version_factory: Optional[Callable[[], "ImmutableVersion"]] = None __slots__ = ["rdclass", "origin", "nodes", "relativize"] def __init__( self, origin: Optional[Union[dns.name.Name, str]], rdclass: dns.rdataclass.RdataClass = dns.rdataclass.IN, relativize: bool = True, ): """Initialize a zone object. *origin* is the origin of the zone. It may be a ``dns.name.Name``, a ``str``, or ``None``. If ``None``, then the zone's origin will be set by the first ``$ORIGIN`` line in a zone file. *rdclass*, an ``int``, the zone's rdata class; the default is class IN. *relativize*, a ``bool``, determine's whether domain names are relativized to the zone's origin. The default is ``True``. """ if origin is not None: if isinstance(origin, str): origin = dns.name.from_text(origin) elif not isinstance(origin, dns.name.Name): raise ValueError("origin parameter must be convertible to a DNS name") if not origin.is_absolute(): raise ValueError("origin parameter must be an absolute name") self.origin = origin self.rdclass = rdclass self.nodes: MutableMapping[dns.name.Name, dns.node.Node] = self.map_factory() self.relativize = relativize def __eq__(self, other): """Two zones are equal if they have the same origin, class, and nodes. Returns a ``bool``. """ if not isinstance(other, Zone): return False if ( self.rdclass != other.rdclass or self.origin != other.origin or self.nodes != other.nodes ): return False return True def __ne__(self, other): """Are two zones not equal? Returns a ``bool``. """ return not self.__eq__(other) def _validate_name(self, name: Union[dns.name.Name, str]) -> dns.name.Name: # Note that any changes in this method should have corresponding changes # made in the Version _validate_name() method. if isinstance(name, str): name = dns.name.from_text(name, None) elif not isinstance(name, dns.name.Name): raise KeyError("name parameter must be convertible to a DNS name") return _validate_name(name, self.origin, self.relativize) def __getitem__(self, key): key = self._validate_name(key) return self.nodes[key] def __setitem__(self, key, value): key = self._validate_name(key) self.nodes[key] = value def __delitem__(self, key): key = self._validate_name(key) del self.nodes[key] def __iter__(self): return self.nodes.__iter__() def keys(self): return self.nodes.keys() def values(self): return self.nodes.values() def items(self): return self.nodes.items() def get(self, key): key = self._validate_name(key) return self.nodes.get(key) def __contains__(self, key): key = self._validate_name(key) return key in self.nodes def find_node( self, name: Union[dns.name.Name, str], create: bool = False ) -> dns.node.Node: """Find a node in the zone, possibly creating it. *name*: the name of the node to find. The value may be a ``dns.name.Name`` or a ``str``. If absolute, the name must be a subdomain of the zone's origin. If ``zone.relativize`` is ``True``, then the name will be relativized. *create*, a ``bool``. If true, the node will be created if it does not exist. Raises ``KeyError`` if the name is not known and create was not specified, or if the name was not a subdomain of the origin. Returns a ``dns.node.Node``. """ name = self._validate_name(name) node = self.nodes.get(name) if node is None: if not create: raise KeyError node = self.node_factory() self.nodes[name] = node return node def get_node( self, name: Union[dns.name.Name, str], create: bool = False ) -> Optional[dns.node.Node]: """Get a node in the zone, possibly creating it. This method is like ``find_node()``, except it returns None instead of raising an exception if the node does not exist and creation has not been requested. *name*: the name of the node to find. The value may be a ``dns.name.Name`` or a ``str``. If absolute, the name must be a subdomain of the zone's origin. If ``zone.relativize`` is ``True``, then the name will be relativized. *create*, a ``bool``. If true, the node will be created if it does not exist. Returns a ``dns.node.Node`` or ``None``. """ try: node = self.find_node(name, create) except KeyError: node = None return node def delete_node(self, name: Union[dns.name.Name, str]) -> None: """Delete the specified node if it exists. *name*: the name of the node to find. The value may be a ``dns.name.Name`` or a ``str``. If absolute, the name must be a subdomain of the zone's origin. If ``zone.relativize`` is ``True``, then the name will be relativized. It is not an error if the node does not exist. """ name = self._validate_name(name) if name in self.nodes: del self.nodes[name] def find_rdataset( self, name: Union[dns.name.Name, str], rdtype: Union[dns.rdatatype.RdataType, str], covers: Union[dns.rdatatype.RdataType, str] = dns.rdatatype.NONE, create: bool = False, ) -> dns.rdataset.Rdataset: """Look for an rdataset with the specified name and type in the zone, and return an rdataset encapsulating it. The rdataset returned is not a copy; changes to it will change the zone. KeyError is raised if the name or type are not found. *name*: the name of the node to find. The value may be a ``dns.name.Name`` or a ``str``. If absolute, the name must be a subdomain of the zone's origin. If ``zone.relativize`` is ``True``, then the name will be relativized. *rdtype*, a ``dns.rdatatype.RdataType`` or ``str``, the rdata type desired. *covers*, a ``dns.rdatatype.RdataType`` or ``str`` the covered type. Usually this value is ``dns.rdatatype.NONE``, but if the rdtype is ``dns.rdatatype.SIG`` or ``dns.rdatatype.RRSIG``, then the covers value will be the rdata type the SIG/RRSIG covers. The library treats the SIG and RRSIG types as if they were a family of types, e.g. RRSIG(A), RRSIG(NS), RRSIG(SOA). This makes RRSIGs much easier to work with than if RRSIGs covering different rdata types were aggregated into a single RRSIG rdataset. *create*, a ``bool``. If true, the node will be created if it does not exist. Raises ``KeyError`` if the name is not known and create was not specified, or if the name was not a subdomain of the origin. Returns a ``dns.rdataset.Rdataset``. """ name = self._validate_name(name) rdtype = dns.rdatatype.RdataType.make(rdtype) covers = dns.rdatatype.RdataType.make(covers) node = self.find_node(name, create) return node.find_rdataset(self.rdclass, rdtype, covers, create) def get_rdataset( self, name: Union[dns.name.Name, str], rdtype: Union[dns.rdatatype.RdataType, str], covers: Union[dns.rdatatype.RdataType, str] = dns.rdatatype.NONE, create: bool = False, ) -> Optional[dns.rdataset.Rdataset]: """Look for an rdataset with the specified name and type in the zone. This method is like ``find_rdataset()``, except it returns None instead of raising an exception if the rdataset does not exist and creation has not been requested. The rdataset returned is not a copy; changes to it will change the zone. *name*: the name of the node to find. The value may be a ``dns.name.Name`` or a ``str``. If absolute, the name must be a subdomain of the zone's origin. If ``zone.relativize`` is ``True``, then the name will be relativized. *rdtype*, a ``dns.rdatatype.RdataType`` or ``str``, the rdata type desired. *covers*, a ``dns.rdatatype.RdataType`` or ``str``, the covered type. Usually this value is ``dns.rdatatype.NONE``, but if the rdtype is ``dns.rdatatype.SIG`` or ``dns.rdatatype.RRSIG``, then the covers value will be the rdata type the SIG/RRSIG covers. The library treats the SIG and RRSIG types as if they were a family of types, e.g. RRSIG(A), RRSIG(NS), RRSIG(SOA). This makes RRSIGs much easier to work with than if RRSIGs covering different rdata types were aggregated into a single RRSIG rdataset. *create*, a ``bool``. If true, the node will be created if it does not exist. Raises ``KeyError`` if the name is not known and create was not specified, or if the name was not a subdomain of the origin. Returns a ``dns.rdataset.Rdataset`` or ``None``. """ try: rdataset = self.find_rdataset(name, rdtype, covers, create) except KeyError: rdataset = None return rdataset def delete_rdataset( self, name: Union[dns.name.Name, str], rdtype: Union[dns.rdatatype.RdataType, str], covers: Union[dns.rdatatype.RdataType, str] = dns.rdatatype.NONE, ) -> None: """Delete the rdataset matching *rdtype* and *covers*, if it exists at the node specified by *name*. It is not an error if the node does not exist, or if there is no matching rdataset at the node. If the node has no rdatasets after the deletion, it will itself be deleted. *name*: the name of the node to find. The value may be a ``dns.name.Name`` or a ``str``. If absolute, the name must be a subdomain of the zone's origin. If ``zone.relativize`` is ``True``, then the name will be relativized. *rdtype*, a ``dns.rdatatype.RdataType`` or ``str``, the rdata type desired. *covers*, a ``dns.rdatatype.RdataType`` or ``str`` or ``None``, the covered type. Usually this value is ``dns.rdatatype.NONE``, but if the rdtype is ``dns.rdatatype.SIG`` or ``dns.rdatatype.RRSIG``, then the covers value will be the rdata type the SIG/RRSIG covers. The library treats the SIG and RRSIG types as if they were a family of types, e.g. RRSIG(A), RRSIG(NS), RRSIG(SOA). This makes RRSIGs much easier to work with than if RRSIGs covering different rdata types were aggregated into a single RRSIG rdataset. """ name = self._validate_name(name) rdtype = dns.rdatatype.RdataType.make(rdtype) covers = dns.rdatatype.RdataType.make(covers) node = self.get_node(name) if node is not None: node.delete_rdataset(self.rdclass, rdtype, covers) if len(node) == 0: self.delete_node(name) def replace_rdataset( self, name: Union[dns.name.Name, str], replacement: dns.rdataset.Rdataset ) -> None: """Replace an rdataset at name. It is not an error if there is no rdataset matching I{replacement}. Ownership of the *replacement* object is transferred to the zone; in other words, this method does not store a copy of *replacement* at the node, it stores *replacement* itself. If the node does not exist, it is created. *name*: the name of the node to find. The value may be a ``dns.name.Name`` or a ``str``. If absolute, the name must be a subdomain of the zone's origin. If ``zone.relativize`` is ``True``, then the name will be relativized. *replacement*, a ``dns.rdataset.Rdataset``, the replacement rdataset. """ if replacement.rdclass != self.rdclass: raise ValueError("replacement.rdclass != zone.rdclass") node = self.find_node(name, True) node.replace_rdataset(replacement) def find_rrset( self, name: Union[dns.name.Name, str], rdtype: Union[dns.rdatatype.RdataType, str], covers: Union[dns.rdatatype.RdataType, str] = dns.rdatatype.NONE, ) -> dns.rrset.RRset: """Look for an rdataset with the specified name and type in the zone, and return an RRset encapsulating it. This method is less efficient than the similar ``find_rdataset()`` because it creates an RRset instead of returning the matching rdataset. It may be more convenient for some uses since it returns an object which binds the owner name to the rdataset. This method may not be used to create new nodes or rdatasets; use ``find_rdataset`` instead. *name*: the name of the node to find. The value may be a ``dns.name.Name`` or a ``str``. If absolute, the name must be a subdomain of the zone's origin. If ``zone.relativize`` is ``True``, then the name will be relativized. *rdtype*, a ``dns.rdatatype.RdataType`` or ``str``, the rdata type desired. *covers*, a ``dns.rdatatype.RdataType`` or ``str``, the covered type. Usually this value is ``dns.rdatatype.NONE``, but if the rdtype is ``dns.rdatatype.SIG`` or ``dns.rdatatype.RRSIG``, then the covers value will be the rdata type the SIG/RRSIG covers. The library treats the SIG and RRSIG types as if they were a family of types, e.g. RRSIG(A), RRSIG(NS), RRSIG(SOA). This makes RRSIGs much easier to work with than if RRSIGs covering different rdata types were aggregated into a single RRSIG rdataset. *create*, a ``bool``. If true, the node will be created if it does not exist. Raises ``KeyError`` if the name is not known and create was not specified, or if the name was not a subdomain of the origin. Returns a ``dns.rrset.RRset`` or ``None``. """ vname = self._validate_name(name) rdtype = dns.rdatatype.RdataType.make(rdtype) covers = dns.rdatatype.RdataType.make(covers) rdataset = self.nodes[vname].find_rdataset(self.rdclass, rdtype, covers) rrset = dns.rrset.RRset(vname, self.rdclass, rdtype, covers) rrset.update(rdataset) return rrset def get_rrset( self, name: Union[dns.name.Name, str], rdtype: Union[dns.rdatatype.RdataType, str], covers: Union[dns.rdatatype.RdataType, str] = dns.rdatatype.NONE, ) -> Optional[dns.rrset.RRset]: """Look for an rdataset with the specified name and type in the zone, and return an RRset encapsulating it. This method is less efficient than the similar ``get_rdataset()`` because it creates an RRset instead of returning the matching rdataset. It may be more convenient for some uses since it returns an object which binds the owner name to the rdataset. This method may not be used to create new nodes or rdatasets; use ``get_rdataset()`` instead. *name*: the name of the node to find. The value may be a ``dns.name.Name`` or a ``str``. If absolute, the name must be a subdomain of the zone's origin. If ``zone.relativize`` is ``True``, then the name will be relativized. *rdtype*, a ``dns.rdataset.Rdataset`` or ``str``, the rdata type desired. *covers*, a ``dns.rdataset.Rdataset`` or ``str``, the covered type. Usually this value is ``dns.rdatatype.NONE``, but if the rdtype is ``dns.rdatatype.SIG`` or ``dns.rdatatype.RRSIG``, then the covers value will be the rdata type the SIG/RRSIG covers. The library treats the SIG and RRSIG types as if they were a family of types, e.g. RRSIG(A), RRSIG(NS), RRSIG(SOA). This makes RRSIGs much easier to work with than if RRSIGs covering different rdata types were aggregated into a single RRSIG rdataset. *create*, a ``bool``. If true, the node will be created if it does not exist. Returns a ``dns.rrset.RRset`` or ``None``. """ try: rrset = self.find_rrset(name, rdtype, covers) except KeyError: rrset = None return rrset def iterate_rdatasets( self, rdtype: Union[dns.rdatatype.RdataType, str] = dns.rdatatype.ANY, covers: Union[dns.rdatatype.RdataType, str] = dns.rdatatype.NONE, ) -> Iterator[Tuple[dns.name.Name, dns.rdataset.Rdataset]]: """Return a generator which yields (name, rdataset) tuples for all rdatasets in the zone which have the specified *rdtype* and *covers*. If *rdtype* is ``dns.rdatatype.ANY``, the default, then all rdatasets will be matched. *rdtype*, a ``dns.rdataset.Rdataset`` or ``str``, the rdata type desired. *covers*, a ``dns.rdataset.Rdataset`` or ``str``, the covered type. Usually this value is ``dns.rdatatype.NONE``, but if the rdtype is ``dns.rdatatype.SIG`` or ``dns.rdatatype.RRSIG``, then the covers value will be the rdata type the SIG/RRSIG covers. The library treats the SIG and RRSIG types as if they were a family of types, e.g. RRSIG(A), RRSIG(NS), RRSIG(SOA). This makes RRSIGs much easier to work with than if RRSIGs covering different rdata types were aggregated into a single RRSIG rdataset. """ rdtype = dns.rdatatype.RdataType.make(rdtype) covers = dns.rdatatype.RdataType.make(covers) for name, node in self.items(): for rds in node: if rdtype == dns.rdatatype.ANY or ( rds.rdtype == rdtype and rds.covers == covers ): yield (name, rds) def iterate_rdatas( self, rdtype: Union[dns.rdatatype.RdataType, str] = dns.rdatatype.ANY, covers: Union[dns.rdatatype.RdataType, str] = dns.rdatatype.NONE, ) -> Iterator[Tuple[dns.name.Name, int, dns.rdata.Rdata]]: """Return a generator which yields (name, ttl, rdata) tuples for all rdatas in the zone which have the specified *rdtype* and *covers*. If *rdtype* is ``dns.rdatatype.ANY``, the default, then all rdatas will be matched. *rdtype*, a ``dns.rdataset.Rdataset`` or ``str``, the rdata type desired. *covers*, a ``dns.rdataset.Rdataset`` or ``str``, the covered type. Usually this value is ``dns.rdatatype.NONE``, but if the rdtype is ``dns.rdatatype.SIG`` or ``dns.rdatatype.RRSIG``, then the covers value will be the rdata type the SIG/RRSIG covers. The library treats the SIG and RRSIG types as if they were a family of types, e.g. RRSIG(A), RRSIG(NS), RRSIG(SOA). This makes RRSIGs much easier to work with than if RRSIGs covering different rdata types were aggregated into a single RRSIG rdataset. """ rdtype = dns.rdatatype.RdataType.make(rdtype) covers = dns.rdatatype.RdataType.make(covers) for name, node in self.items(): for rds in node: if rdtype == dns.rdatatype.ANY or ( rds.rdtype == rdtype and rds.covers == covers ): for rdata in rds: yield (name, rds.ttl, rdata) def to_file( self, f: Any, sorted: bool = True, relativize: bool = True, nl: Optional[str] = None, want_comments: bool = False, want_origin: bool = False, ) -> None: """Write a zone to a file. *f*, a file or `str`. If *f* is a string, it is treated as the name of a file to open. *sorted*, a ``bool``. If True, the default, then the file will be written with the names sorted in DNSSEC order from least to greatest. Otherwise the names will be written in whatever order they happen to have in the zone's dictionary. *relativize*, a ``bool``. If True, the default, then domain names in the output will be relativized to the zone's origin if possible. *nl*, a ``str`` or None. The end of line string. If not ``None``, the output will use the platform's native end-of-line marker (i.e. LF on POSIX, CRLF on Windows). *want_comments*, a ``bool``. If ``True``, emit end-of-line comments as part of writing the file. If ``False``, the default, do not emit them. *want_origin*, a ``bool``. If ``True``, emit a $ORIGIN line at the start of the file. If ``False``, the default, do not emit one. """ if isinstance(f, str): cm: contextlib.AbstractContextManager = open(f, "wb") else: cm = contextlib.nullcontext(f) with cm as f: # must be in this way, f.encoding may contain None, or even # attribute may not be there file_enc = getattr(f, "encoding", None) if file_enc is None: file_enc = "utf-8" if nl is None: # binary mode, '\n' is not enough nl_b = os.linesep.encode(file_enc) nl = "\n" elif isinstance(nl, str): nl_b = nl.encode(file_enc) else: nl_b = nl nl = nl.decode() if want_origin: assert self.origin is not None l = "$ORIGIN " + self.origin.to_text() l_b = l.encode(file_enc) try: f.write(l_b) f.write(nl_b) except TypeError: # textual mode f.write(l) f.write(nl) if sorted: names = list(self.keys()) names.sort() else: names = self.keys() for n in names: l = self[n].to_text( n, origin=self.origin, relativize=relativize, want_comments=want_comments, ) l_b = l.encode(file_enc) try: f.write(l_b) f.write(nl_b) except TypeError: # textual mode f.write(l) f.write(nl) def to_text( self, sorted: bool = True, relativize: bool = True, nl: Optional[str] = None, want_comments: bool = False, want_origin: bool = False, ) -> str: """Return a zone's text as though it were written to a file. *sorted*, a ``bool``. If True, the default, then the file will be written with the names sorted in DNSSEC order from least to greatest. Otherwise the names will be written in whatever order they happen to have in the zone's dictionary. *relativize*, a ``bool``. If True, the default, then domain names in the output will be relativized to the zone's origin if possible. *nl*, a ``str`` or None. The end of line string. If not ``None``, the output will use the platform's native end-of-line marker (i.e. LF on POSIX, CRLF on Windows). *want_comments*, a ``bool``. If ``True``, emit end-of-line comments as part of writing the file. If ``False``, the default, do not emit them. *want_origin*, a ``bool``. If ``True``, emit a $ORIGIN line at the start of the output. If ``False``, the default, do not emit one. Returns a ``str``. """ temp_buffer = io.StringIO() self.to_file(temp_buffer, sorted, relativize, nl, want_comments, want_origin) return_value = temp_buffer.getvalue() temp_buffer.close() return return_value def check_origin(self) -> None: """Do some simple checking of the zone's origin. Raises ``dns.zone.NoSOA`` if there is no SOA RRset. Raises ``dns.zone.NoNS`` if there is no NS RRset. Raises ``KeyError`` if there is no origin node. """ if self.relativize: name = dns.name.empty else: assert self.origin is not None name = self.origin if self.get_rdataset(name, dns.rdatatype.SOA) is None: raise NoSOA if self.get_rdataset(name, dns.rdatatype.NS) is None: raise NoNS def get_soa( self, txn: Optional[dns.transaction.Transaction] = None ) -> dns.rdtypes.ANY.SOA.SOA: """Get the zone SOA rdata. Raises ``dns.zone.NoSOA`` if there is no SOA RRset. Returns a ``dns.rdtypes.ANY.SOA.SOA`` Rdata. """ if self.relativize: origin_name = dns.name.empty else: if self.origin is None: # get_soa() has been called very early, and there must not be # an SOA if there is no origin. raise NoSOA origin_name = self.origin soa: Optional[dns.rdataset.Rdataset] if txn: soa = txn.get(origin_name, dns.rdatatype.SOA) else: soa = self.get_rdataset(origin_name, dns.rdatatype.SOA) if soa is None: raise NoSOA return soa[0] def _compute_digest( self, hash_algorithm: DigestHashAlgorithm, scheme: DigestScheme = DigestScheme.SIMPLE, ) -> bytes: hashinfo = _digest_hashers.get(hash_algorithm) if not hashinfo: raise UnsupportedDigestHashAlgorithm if scheme != DigestScheme.SIMPLE: raise UnsupportedDigestScheme if self.relativize: origin_name = dns.name.empty else: assert self.origin is not None origin_name = self.origin hasher = hashinfo() for name, node in sorted(self.items()): rrnamebuf = name.to_digestable(self.origin) for rdataset in sorted(node, key=lambda rds: (rds.rdtype, rds.covers)): if name == origin_name and dns.rdatatype.ZONEMD in ( rdataset.rdtype, rdataset.covers, ): continue rrfixed = struct.pack( "!HHI", rdataset.rdtype, rdataset.rdclass, rdataset.ttl ) rdatas = [rdata.to_digestable(self.origin) for rdata in rdataset] for rdata in sorted(rdatas): rrlen = struct.pack("!H", len(rdata)) hasher.update(rrnamebuf + rrfixed + rrlen + rdata) return hasher.digest() def compute_digest( self, hash_algorithm: DigestHashAlgorithm, scheme: DigestScheme = DigestScheme.SIMPLE, ) -> dns.rdtypes.ANY.ZONEMD.ZONEMD: serial = self.get_soa().serial digest = self._compute_digest(hash_algorithm, scheme) return dns.rdtypes.ANY.ZONEMD.ZONEMD( self.rdclass, dns.rdatatype.ZONEMD, serial, scheme, hash_algorithm, digest ) def verify_digest( self, zonemd: Optional[dns.rdtypes.ANY.ZONEMD.ZONEMD] = None ) -> None: digests: Union[dns.rdataset.Rdataset, List[dns.rdtypes.ANY.ZONEMD.ZONEMD]] if zonemd: digests = [zonemd] else: assert self.origin is not None rds = self.get_rdataset(self.origin, dns.rdatatype.ZONEMD) if rds is None: raise NoDigest digests = rds for digest in digests: try: computed = self._compute_digest(digest.hash_algorithm, digest.scheme) if computed == digest.digest: return except Exception: pass raise DigestVerificationFailure # TransactionManager methods def reader(self) -> "Transaction": return Transaction(self, False, Version(self, 1, self.nodes, self.origin)) def writer(self, replacement: bool = False) -> "Transaction": txn = Transaction(self, replacement) txn._setup_version() return txn def origin_information( self, ) -> Tuple[Optional[dns.name.Name], bool, Optional[dns.name.Name]]: effective: Optional[dns.name.Name] if self.relativize: effective = dns.name.empty else: effective = self.origin return (self.origin, self.relativize, effective) def get_class(self): return self.rdclass # Transaction methods def _end_read(self, txn): pass def _end_write(self, txn): pass def _commit_version(self, _, version, origin): self.nodes = version.nodes if self.origin is None: self.origin = origin def _get_next_version_id(self): # Versions are ephemeral and all have id 1 return 1 # These classes used to be in dns.versioned, but have moved here so we can use # the copy-on-write transaction mechanism for both kinds of zones. In a # regular zone, the version only exists during the transaction, and the nodes # are regular dns.node.Nodes. # A node with a version id. class VersionedNode(dns.node.Node): # lgtm[py/missing-equals] __slots__ = ["id"] def __init__(self): super().__init__() # A proper id will get set by the Version self.id = 0 @dns.immutable.immutable class ImmutableVersionedNode(VersionedNode): def __init__(self, node): super().__init__() self.id = node.id self.rdatasets = tuple( [dns.rdataset.ImmutableRdataset(rds) for rds in node.rdatasets] ) def find_rdataset( self, rdclass: dns.rdataclass.RdataClass, rdtype: dns.rdatatype.RdataType, covers: dns.rdatatype.RdataType = dns.rdatatype.NONE, create: bool = False, ) -> dns.rdataset.Rdataset: if create: raise TypeError("immutable") return super().find_rdataset(rdclass, rdtype, covers, False) def get_rdataset( self, rdclass: dns.rdataclass.RdataClass, rdtype: dns.rdatatype.RdataType, covers: dns.rdatatype.RdataType = dns.rdatatype.NONE, create: bool = False, ) -> Optional[dns.rdataset.Rdataset]: if create: raise TypeError("immutable") return super().get_rdataset(rdclass, rdtype, covers, False) def delete_rdataset( self, rdclass: dns.rdataclass.RdataClass, rdtype: dns.rdatatype.RdataType, covers: dns.rdatatype.RdataType = dns.rdatatype.NONE, ) -> None: raise TypeError("immutable") def replace_rdataset(self, replacement: dns.rdataset.Rdataset) -> None: raise TypeError("immutable") def is_immutable(self) -> bool: return True class Version: def __init__( self, zone: Zone, id: int, nodes: Optional[MutableMapping[dns.name.Name, dns.node.Node]] = None, origin: Optional[dns.name.Name] = None, ): self.zone = zone self.id = id if nodes is not None: self.nodes = nodes else: self.nodes = zone.map_factory() self.origin = origin def _validate_name(self, name: dns.name.Name) -> dns.name.Name: return _validate_name(name, self.origin, self.zone.relativize) def get_node(self, name: dns.name.Name) -> Optional[dns.node.Node]: name = self._validate_name(name) return self.nodes.get(name) def get_rdataset( self, name: dns.name.Name, rdtype: dns.rdatatype.RdataType, covers: dns.rdatatype.RdataType, ) -> Optional[dns.rdataset.Rdataset]: node = self.get_node(name) if node is None: return None return node.get_rdataset(self.zone.rdclass, rdtype, covers) def keys(self): return self.nodes.keys() def items(self): return self.nodes.items() class WritableVersion(Version): def __init__(self, zone: Zone, replacement: bool = False): # The zone._versions_lock must be held by our caller in a versioned # zone. id = zone._get_next_version_id() super().__init__(zone, id) if not replacement: # We copy the map, because that gives us a simple and thread-safe # way of doing versions, and we have a garbage collector to help # us. We only make new node objects if we actually change the # node. self.nodes.update(zone.nodes) # We have to copy the zone origin as it may be None in the first # version, and we don't want to mutate the zone until we commit. self.origin = zone.origin self.changed: Set[dns.name.Name] = set() def _maybe_cow(self, name: dns.name.Name) -> dns.node.Node: name = self._validate_name(name) node = self.nodes.get(name) if node is None or name not in self.changed: new_node = self.zone.node_factory() if hasattr(new_node, "id"): # We keep doing this for backwards compatibility, as earlier # code used new_node.id != self.id for the "do we need to CoW?" # test. Now we use the changed set as this works with both # regular zones and versioned zones. # # We ignore the mypy error as this is safe but it doesn't see it. new_node.id = self.id # type: ignore if node is not None: # moo! copy on write! new_node.rdatasets.extend(node.rdatasets) self.nodes[name] = new_node self.changed.add(name) return new_node else: return node def delete_node(self, name: dns.name.Name) -> None: name = self._validate_name(name) if name in self.nodes: del self.nodes[name] self.changed.add(name) def put_rdataset( self, name: dns.name.Name, rdataset: dns.rdataset.Rdataset ) -> None: node = self._maybe_cow(name) node.replace_rdataset(rdataset) def delete_rdataset( self, name: dns.name.Name, rdtype: dns.rdatatype.RdataType, covers: dns.rdatatype.RdataType, ) -> None: node = self._maybe_cow(name) node.delete_rdataset(self.zone.rdclass, rdtype, covers) if len(node) == 0: del self.nodes[name] @dns.immutable.immutable class ImmutableVersion(Version): def __init__(self, version: WritableVersion): # We tell super() that it's a replacement as we don't want it # to copy the nodes, as we're about to do that with an # immutable Dict. super().__init__(version.zone, True) # set the right id! self.id = version.id # keep the origin self.origin = version.origin # Make changed nodes immutable for name in version.changed: node = version.nodes.get(name) # it might not exist if we deleted it in the version if node: version.nodes[name] = ImmutableVersionedNode(node) # We're changing the type of the nodes dictionary here on purpose, so # we ignore the mypy error. self.nodes = dns.immutable.Dict( version.nodes, True, self.zone.map_factory ) # type: ignore class Transaction(dns.transaction.Transaction): def __init__(self, zone, replacement, version=None, make_immutable=False): read_only = version is not None super().__init__(zone, replacement, read_only) self.version = version self.make_immutable = make_immutable @property def zone(self): return self.manager def _setup_version(self): assert self.version is None factory = self.manager.writable_version_factory if factory is None: factory = WritableVersion self.version = factory(self.zone, self.replacement) def _get_rdataset(self, name, rdtype, covers): return self.version.get_rdataset(name, rdtype, covers) def _put_rdataset(self, name, rdataset): assert not self.read_only self.version.put_rdataset(name, rdataset) def _delete_name(self, name): assert not self.read_only self.version.delete_node(name) def _delete_rdataset(self, name, rdtype, covers): assert not self.read_only self.version.delete_rdataset(name, rdtype, covers) def _name_exists(self, name): return self.version.get_node(name) is not None def _changed(self): if self.read_only: return False else: return len(self.version.changed) > 0 def _end_transaction(self, commit): if self.read_only: self.zone._end_read(self) elif commit and len(self.version.changed) > 0: if self.make_immutable: factory = self.manager.immutable_version_factory if factory is None: factory = ImmutableVersion version = factory(self.version) else: version = self.version self.zone._commit_version(self, version, self.version.origin) else: # rollback self.zone._end_write(self) def _set_origin(self, origin): if self.version.origin is None: self.version.origin = origin def _iterate_rdatasets(self): for name, node in self.version.items(): for rdataset in node: yield (name, rdataset) def _iterate_names(self): return self.version.keys() def _get_node(self, name): return self.version.get_node(name) def _origin_information(self): (absolute, relativize, effective) = self.manager.origin_information() if absolute is None and self.version.origin is not None: # No origin has been committed yet, but we've learned one as part of # this txn. Use it. absolute = self.version.origin if relativize: effective = dns.name.empty else: effective = absolute return (absolute, relativize, effective) def _from_text( text: Any, origin: Optional[Union[dns.name.Name, str]] = None, rdclass: dns.rdataclass.RdataClass = dns.rdataclass.IN, relativize: bool = True, zone_factory: Any = Zone, filename: Optional[str] = None, allow_include: bool = False, check_origin: bool = True, idna_codec: Optional[dns.name.IDNACodec] = None, allow_directives: Union[bool, Iterable[str]] = True, ) -> Zone: # See the comments for the public APIs from_text() and from_file() for # details. # 'text' can also be a file, but we don't publish that fact # since it's an implementation detail. The official file # interface is from_file(). if filename is None: filename = "<string>" zone = zone_factory(origin, rdclass, relativize=relativize) with zone.writer(True) as txn: tok = dns.tokenizer.Tokenizer(text, filename, idna_codec=idna_codec) reader = dns.zonefile.Reader( tok, rdclass, txn, allow_include=allow_include, allow_directives=allow_directives, ) try: reader.read() except dns.zonefile.UnknownOrigin: # for backwards compatibility raise dns.zone.UnknownOrigin # Now that we're done reading, do some basic checking of the zone. if check_origin: zone.check_origin() return zone def from_text( text: str, origin: Optional[Union[dns.name.Name, str]] = None, rdclass: dns.rdataclass.RdataClass = dns.rdataclass.IN, relativize: bool = True, zone_factory: Any = Zone, filename: Optional[str] = None, allow_include: bool = False, check_origin: bool = True, idna_codec: Optional[dns.name.IDNACodec] = None, allow_directives: Union[bool, Iterable[str]] = True, ) -> Zone: """Build a zone object from a zone file format string. *text*, a ``str``, the zone file format input. *origin*, a ``dns.name.Name``, a ``str``, or ``None``. The origin of the zone; if not specified, the first ``$ORIGIN`` statement in the zone file will determine the origin of the zone. *rdclass*, a ``dns.rdataclass.RdataClass``, the zone's rdata class; the default is class IN. *relativize*, a ``bool``, determine's whether domain names are relativized to the zone's origin. The default is ``True``. *zone_factory*, the zone factory to use or ``None``. If ``None``, then ``dns.zone.Zone`` will be used. The value may be any class or callable that returns a subclass of ``dns.zone.Zone``. *filename*, a ``str`` or ``None``, the filename to emit when describing where an error occurred; the default is ``'<string>'``. *allow_include*, a ``bool``. If ``True``, the default, then ``$INCLUDE`` directives are permitted. If ``False``, then encoutering a ``$INCLUDE`` will raise a ``SyntaxError`` exception. *check_origin*, a ``bool``. If ``True``, the default, then sanity checks of the origin node will be made by calling the zone's ``check_origin()`` method. *idna_codec*, a ``dns.name.IDNACodec``, specifies the IDNA encoder/decoder. If ``None``, the default IDNA 2003 encoder/decoder is used. *allow_directives*, a ``bool`` or an iterable of `str`. If ``True``, the default, then directives are permitted, and the *allow_include* parameter controls whether ``$INCLUDE`` is permitted. If ``False`` or an empty iterable, then no directive processing is done and any directive-like text will be treated as a regular owner name. If a non-empty iterable, then only the listed directives (including the ``$``) are allowed. Raises ``dns.zone.NoSOA`` if there is no SOA RRset. Raises ``dns.zone.NoNS`` if there is no NS RRset. Raises ``KeyError`` if there is no origin node. Returns a subclass of ``dns.zone.Zone``. """ return _from_text( text, origin, rdclass, relativize, zone_factory, filename, allow_include, check_origin, idna_codec, allow_directives, ) def from_file( f: Any, origin: Optional[Union[dns.name.Name, str]] = None, rdclass: dns.rdataclass.RdataClass = dns.rdataclass.IN, relativize: bool = True, zone_factory: Any = Zone, filename: Optional[str] = None, allow_include: bool = True, check_origin: bool = True, idna_codec: Optional[dns.name.IDNACodec] = None, allow_directives: Union[bool, Iterable[str]] = True, ) -> Zone: """Read a zone file and build a zone object. *f*, a file or ``str``. If *f* is a string, it is treated as the name of a file to open. *origin*, a ``dns.name.Name``, a ``str``, or ``None``. The origin of the zone; if not specified, the first ``$ORIGIN`` statement in the zone file will determine the origin of the zone. *rdclass*, an ``int``, the zone's rdata class; the default is class IN. *relativize*, a ``bool``, determine's whether domain names are relativized to the zone's origin. The default is ``True``. *zone_factory*, the zone factory to use or ``None``. If ``None``, then ``dns.zone.Zone`` will be used. The value may be any class or callable that returns a subclass of ``dns.zone.Zone``. *filename*, a ``str`` or ``None``, the filename to emit when describing where an error occurred; the default is ``'<string>'``. *allow_include*, a ``bool``. If ``True``, the default, then ``$INCLUDE`` directives are permitted. If ``False``, then encoutering a ``$INCLUDE`` will raise a ``SyntaxError`` exception. *check_origin*, a ``bool``. If ``True``, the default, then sanity checks of the origin node will be made by calling the zone's ``check_origin()`` method. *idna_codec*, a ``dns.name.IDNACodec``, specifies the IDNA encoder/decoder. If ``None``, the default IDNA 2003 encoder/decoder is used. *allow_directives*, a ``bool`` or an iterable of `str`. If ``True``, the default, then directives are permitted, and the *allow_include* parameter controls whether ``$INCLUDE`` is permitted. If ``False`` or an empty iterable, then no directive processing is done and any directive-like text will be treated as a regular owner name. If a non-empty iterable, then only the listed directives (including the ``$``) are allowed. Raises ``dns.zone.NoSOA`` if there is no SOA RRset. Raises ``dns.zone.NoNS`` if there is no NS RRset. Raises ``KeyError`` if there is no origin node. Returns a subclass of ``dns.zone.Zone``. """ if isinstance(f, str): if filename is None: filename = f cm: contextlib.AbstractContextManager = open(f) else: cm = contextlib.nullcontext(f) with cm as f: return _from_text( f, origin, rdclass, relativize, zone_factory, filename, allow_include, check_origin, idna_codec, allow_directives, ) assert False # make mypy happy lgtm[py/unreachable-statement] def from_xfr( xfr: Any, zone_factory: Any = Zone, relativize: bool = True, check_origin: bool = True, ) -> Zone: """Convert the output of a zone transfer generator into a zone object. *xfr*, a generator of ``dns.message.Message`` objects, typically ``dns.query.xfr()``. *relativize*, a ``bool``, determine's whether domain names are relativized to the zone's origin. The default is ``True``. It is essential that the relativize setting matches the one specified to the generator. *check_origin*, a ``bool``. If ``True``, the default, then sanity checks of the origin node will be made by calling the zone's ``check_origin()`` method. Raises ``dns.zone.NoSOA`` if there is no SOA RRset. Raises ``dns.zone.NoNS`` if there is no NS RRset. Raises ``KeyError`` if there is no origin node. Raises ``ValueError`` if no messages are yielded by the generator. Returns a subclass of ``dns.zone.Zone``. """ z = None for r in xfr: if z is None: if relativize: origin = r.origin else: origin = r.answer[0].name rdclass = r.answer[0].rdclass z = zone_factory(origin, rdclass, relativize=relativize) for rrset in r.answer: znode = z.nodes.get(rrset.name) if not znode: znode = z.node_factory() z.nodes[rrset.name] = znode zrds = znode.find_rdataset(rrset.rdclass, rrset.rdtype, rrset.covers, True) zrds.update_ttl(rrset.ttl) for rd in rrset: zrds.add(rd) if z is None: raise ValueError("empty transfer") if check_origin: z.check_origin() return z