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	# Copyright (C) Dnspython Contributors, see LICENSE for text of ISC license

	# Copyright (C) 2001-2017 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 Names.
	"""

	import copy
	import encodings.idna # type: ignore
	import functools
	import struct
	from typing import Any, Callable, Dict, Iterable, Optional, Tuple, Union

	import dns._features
	import dns.enum
	import dns.exception
	import dns.immutable
	import dns.wire

	if dns._features.have("idna"):
	import idna # type: ignore

	have_idna_2008 = True
	else: # pragma: no cover
	have_idna_2008 = False

	CompressType = Dict["Name", int]


	class NameRelation(dns.enum.IntEnum):
	"""Name relation result from fullcompare()."""

	# This is an IntEnum for backwards compatibility in case anyone
	# has hardwired the constants.

	#: The compared names have no relationship to each other.
	NONE = 0
	#: the first name is a superdomain of the second.
	SUPERDOMAIN = 1
	#: The first name is a subdomain of the second.
	SUBDOMAIN = 2
	#: The compared names are equal.
	EQUAL = 3
	#: The compared names have a common ancestor.
	COMMONANCESTOR = 4

	@classmethod
	def _maximum(cls):
	return cls.COMMONANCESTOR

	@classmethod
	def _short_name(cls):
	return cls.__name__


	# Backwards compatibility
	NAMERELN_NONE = NameRelation.NONE
	NAMERELN_SUPERDOMAIN = NameRelation.SUPERDOMAIN
	NAMERELN_SUBDOMAIN = NameRelation.SUBDOMAIN
	NAMERELN_EQUAL = NameRelation.EQUAL
	NAMERELN_COMMONANCESTOR = NameRelation.COMMONANCESTOR


	class EmptyLabel(dns.exception.SyntaxError):
	"""A DNS label is empty."""


	class BadEscape(dns.exception.SyntaxError):
	"""An escaped code in a text format of DNS name is invalid."""


	class BadPointer(dns.exception.FormError):
	"""A DNS compression pointer points forward instead of backward."""


	class BadLabelType(dns.exception.FormError):
	"""The label type in DNS name wire format is unknown."""


	class NeedAbsoluteNameOrOrigin(dns.exception.DNSException):
	"""An attempt was made to convert a non-absolute name to
	wire when there was also a non-absolute (or missing) origin."""


	class NameTooLong(dns.exception.FormError):
	"""A DNS name is > 255 octets long."""


	class LabelTooLong(dns.exception.SyntaxError):
	"""A DNS label is > 63 octets long."""


	class AbsoluteConcatenation(dns.exception.DNSException):
	"""An attempt was made to append anything other than the
	empty name to an absolute DNS name."""


	class NoParent(dns.exception.DNSException):
	"""An attempt was made to get the parent of the root name
	or the empty name."""


	class NoIDNA2008(dns.exception.DNSException):
	"""IDNA 2008 processing was requested but the idna module is not
	available."""


	class IDNAException(dns.exception.DNSException):
	"""IDNA processing raised an exception."""

	supp_kwargs = {"idna_exception"}
	fmt = "IDNA processing exception: {idna_exception}"

	# We do this as otherwise mypy complains about unexpected keyword argument
	# idna_exception
	def __init__(self, args, *kwargs):
	super().__init__(args, *kwargs)


	class NeedSubdomainOfOrigin(dns.exception.DNSException):
	"""An absolute name was provided that is not a subdomain of the specified origin."""


	_escaped = b'"().;\\@$'
	_escaped_text = '"().;\\@$'


	def _escapify(label: Union[bytes, str]) -> str:
	"""Escape the characters in label which need it.
	@returns: the escaped string
	@rtype: string"""
	if isinstance(label, bytes):
	# Ordinary DNS label mode. Escape special characters and values
	# < 0x20 or > 0x7f.
	text = ""
	for c in label:
	if c in _escaped:
	text += "\\" + chr(c)
	elif c > 0x20 and c < 0x7F:
	text += chr(c)
	else:
	text += "\\%03d" % c
	return text

	# Unicode label mode. Escape only special characters and values < 0x20
	text = ""
	for uc in label:
	if uc in _escaped_text:
	text += "\\" + uc
	elif uc <= "\x20":
	text += "\\%03d" % ord(uc)
	else:
	text += uc
	return text


	class IDNACodec:
	"""Abstract base class for IDNA encoder/decoders."""

	def __init__(self):
	pass

	def is_idna(self, label: bytes) -> bool:
	return label.lower().startswith(b"xn--")

	def encode(self, label: str) -> bytes:
	raise NotImplementedError # pragma: no cover

	def decode(self, label: bytes) -> str:
	# We do not apply any IDNA policy on decode.
	if self.is_idna(label):
	try:
	slabel = label[4:].decode("punycode")
	return _escapify(slabel)
	except Exception as e:
	raise IDNAException(idna_exception=e)
	else:
	return _escapify(label)


	class IDNA2003Codec(IDNACodec):
	"""IDNA 2003 encoder/decoder."""

	def __init__(self, strict_decode: bool = False):
	"""Initialize the IDNA 2003 encoder/decoder.

	strict_decode is a ``bool``. If `True`, then IDNA2003 checking
	is done when decoding. This can cause failures if the name
	was encoded with IDNA2008. The default is `False`.
	"""

	super().__init__()
	self.strict_decode = strict_decode

	def encode(self, label: str) -> bytes:
	"""Encode label."""

	if label == "":
	return b""
	try:
	return encodings.idna.ToASCII(label)
	except UnicodeError:
	raise LabelTooLong

	def decode(self, label: bytes) -> str:
	"""Decode label."""
	if not self.strict_decode:
	return super().decode(label)
	if label == b"":
	return ""
	try:
	return _escapify(encodings.idna.ToUnicode(label))
	except Exception as e:
	raise IDNAException(idna_exception=e)


	class IDNA2008Codec(IDNACodec):
	"""IDNA 2008 encoder/decoder."""

	def __init__(
	self,
	uts_46: bool = False,
	transitional: bool = False,
	allow_pure_ascii: bool = False,
	strict_decode: bool = False,
	):
	"""Initialize the IDNA 2008 encoder/decoder.

	uts_46 is a ``bool``. If True, apply Unicode IDNA
	compatibility processing as described in Unicode Technical
	Standard #46 (https://unicode.org/reports/tr46/).
	If False, do not apply the mapping. The default is False.

	transitional is a ``bool``: If True, use the
	"transitional" mode described in Unicode Technical Standard
	#46. The default is False.

	allow_pure_ascii is a ``bool``. If True, then a label which
	consists of only ASCII characters is allowed. This is less
	strict than regular IDNA 2008, but is also necessary for mixed
	names, e.g. a name with starting with "_sip._tcp." and ending
	in an IDN suffix which would otherwise be disallowed. The
	default is False.

	strict_decode is a ``bool``: If True, then IDNA2008 checking
	is done when decoding. This can cause failures if the name
	was encoded with IDNA2003. The default is False.
	"""
	super().__init__()
	self.uts_46 = uts_46
	self.transitional = transitional
	self.allow_pure_ascii = allow_pure_ascii
	self.strict_decode = strict_decode

	def encode(self, label: str) -> bytes:
	if label == "":
	return b""
	if self.allow_pure_ascii and is_all_ascii(label):
	encoded = label.encode("ascii")
	if len(encoded) > 63:
	raise LabelTooLong
	return encoded
	if not have_idna_2008:
	raise NoIDNA2008
	try:
	if self.uts_46:
	label = idna.uts46_remap(label, False, self.transitional)
	return idna.alabel(label)
	except idna.IDNAError as e:
	if e.args[0] == "Label too long":
	raise LabelTooLong
	else:
	raise IDNAException(idna_exception=e)

	def decode(self, label: bytes) -> str:
	if not self.strict_decode:
	return super().decode(label)
	if label == b"":
	return ""
	if not have_idna_2008:
	raise NoIDNA2008
	try:
	ulabel = idna.ulabel(label)
	if self.uts_46:
	ulabel = idna.uts46_remap(ulabel, False, self.transitional)
	return _escapify(ulabel)
	except (idna.IDNAError, UnicodeError) as e:
	raise IDNAException(idna_exception=e)


	IDNA_2003_Practical = IDNA2003Codec(False)
	IDNA_2003_Strict = IDNA2003Codec(True)
	IDNA_2003 = IDNA_2003_Practical
	IDNA_2008_Practical = IDNA2008Codec(True, False, True, False)
	IDNA_2008_UTS_46 = IDNA2008Codec(True, False, False, False)
	IDNA_2008_Strict = IDNA2008Codec(False, False, False, True)
	IDNA_2008_Transitional = IDNA2008Codec(True, True, False, False)
	IDNA_2008 = IDNA_2008_Practical


	def _validate_labels(labels: Tuple[bytes, ...]) -> None:
	"""Check for empty labels in the middle of a label sequence,
	labels that are too long, and for too many labels.

	Raises ``dns.name.NameTooLong`` if the name as a whole is too long.

	Raises ``dns.name.EmptyLabel`` if a label is empty (i.e. the root
	label) and appears in a position other than the end of the label
	sequence

	"""

	l = len(labels)
	total = 0
	i = -1
	j = 0
	for label in labels:
	ll = len(label)
	total += ll + 1
	if ll > 63:
	raise LabelTooLong
	if i < 0 and label == b"":
	i = j
	j += 1
	if total > 255:
	raise NameTooLong
	if i >= 0 and i != l - 1:
	raise EmptyLabel


	def _maybe_convert_to_binary(label: Union[bytes, str]) -> bytes:
	"""If label is ``str``, convert it to ``bytes``. If it is already
	``bytes`` just return it.

	"""

	if isinstance(label, bytes):
	return label
	if isinstance(label, str):
	return label.encode()
	raise ValueError # pragma: no cover


	@dns.immutable.immutable
	class Name:
	"""A DNS name.

	The dns.name.Name class represents a DNS name as a tuple of
	labels. Each label is a ``bytes`` in DNS wire format. Instances
	of the class are immutable.
	"""

	__slots__ = ["labels"]

	def __init__(self, labels: Iterable[Union[bytes, str]]):
	"""labels is any iterable whose values are ``str`` or ``bytes``."""

	blabels = [_maybe_convert_to_binary(x) for x in labels]
	self.labels = tuple(blabels)
	_validate_labels(self.labels)

	def __copy__(self):
	return Name(self.labels)

	def __deepcopy__(self, memo):
	return Name(copy.deepcopy(self.labels, memo))

	def __getstate__(self):
	# Names can be pickled
	return {"labels": self.labels}

	def __setstate__(self, state):
	super().__setattr__("labels", state["labels"])
	_validate_labels(self.labels)

	def is_absolute(self) -> bool:
	"""Is the most significant label of this name the root label?

	Returns a ``bool``.
	"""

	return len(self.labels) > 0 and self.labels[-1] == b""

	def is_wild(self) -> bool:
	"""Is this name wild? (I.e. Is the least significant label '*'?)

	Returns a ``bool``.
	"""

	return len(self.labels) > 0 and self.labels[0] == b"*"

	def __hash__(self) -> int:
	"""Return a case-insensitive hash of the name.

	Returns an ``int``.
	"""

	h = 0
	for label in self.labels:
	for c in label.lower():
	h += (h << 3) + c
	return h

	def fullcompare(self, other: "Name") -> Tuple[NameRelation, int, int]:
	"""Compare two names, returning a 3-tuple
	``(relation, order, nlabels)``.

	relation describes the relation ship between the names,
	and is one of: ``dns.name.NameRelation.NONE``,
	``dns.name.NameRelation.SUPERDOMAIN``, ``dns.name.NameRelation.SUBDOMAIN``,
	``dns.name.NameRelation.EQUAL``, or ``dns.name.NameRelation.COMMONANCESTOR``.

	order is < 0 if self < other, > 0 if self > other, and ==
	0 if self == other. A relative name is always less than an
	absolute name. If both names have the same relativity, then
	the DNSSEC order relation is used to order them.

	nlabels is the number of significant labels that the two names
	have in common.

	Here are some examples. Names ending in "." are absolute names,
	those not ending in "." are relative names.

	============= ============= =========== ===== =======
	self other relation order nlabels
	============= ============= =========== ===== =======
	www.example. www.example. equal 0 3
	www.example. example. subdomain > 0 2
	example. www.example. superdomain < 0 2
	example1.com. example2.com. common anc. < 0 2
	example1 example2. none < 0 0
	example1. example2 none > 0 0
	============= ============= =========== ===== =======
	"""

	sabs = self.is_absolute()
	oabs = other.is_absolute()
	if sabs != oabs:
	if sabs:
	return (NameRelation.NONE, 1, 0)
	else:
	return (NameRelation.NONE, -1, 0)
	l1 = len(self.labels)
	l2 = len(other.labels)
	ldiff = l1 - l2
	if ldiff < 0:
	l = l1
	else:
	l = l2

	order = 0
	nlabels = 0
	namereln = NameRelation.NONE
	while l > 0:
	l -= 1
	l1 -= 1
	l2 -= 1
	label1 = self.labels[l1].lower()
	label2 = other.labels[l2].lower()
	if label1 < label2:
	order = -1
	if nlabels > 0:
	namereln = NameRelation.COMMONANCESTOR
	return (namereln, order, nlabels)
	elif label1 > label2:
	order = 1
	if nlabels > 0:
	namereln = NameRelation.COMMONANCESTOR
	return (namereln, order, nlabels)
	nlabels += 1
	order = ldiff
	if ldiff < 0:
	namereln = NameRelation.SUPERDOMAIN
	elif ldiff > 0:
	namereln = NameRelation.SUBDOMAIN
	else:
	namereln = NameRelation.EQUAL
	return (namereln, order, nlabels)

	def is_subdomain(self, other: "Name") -> bool:
	"""Is self a subdomain of other?

	Note that the notion of subdomain includes equality, e.g.
	"dnspython.org" is a subdomain of itself.

	Returns a ``bool``.
	"""

	(nr, _, _) = self.fullcompare(other)
	if nr == NameRelation.SUBDOMAIN or nr == NameRelation.EQUAL:
	return True
	return False

	def is_superdomain(self, other: "Name") -> bool:
	"""Is self a superdomain of other?

	Note that the notion of superdomain includes equality, e.g.
	"dnspython.org" is a superdomain of itself.

	Returns a ``bool``.
	"""

	(nr, _, _) = self.fullcompare(other)
	if nr == NameRelation.SUPERDOMAIN or nr == NameRelation.EQUAL:
	return True
	return False

	def canonicalize(self) -> "Name":
	"""Return a name which is equal to the current name, but is in
	DNSSEC canonical form.
	"""

	return Name([x.lower() for x in self.labels])

	def __eq__(self, other):
	if isinstance(other, Name):
	return self.fullcompare(other)[1] == 0
	else:
	return False

	def __ne__(self, other):
	if isinstance(other, Name):
	return self.fullcompare(other)[1] != 0
	else:
	return True

	def __lt__(self, other):
	if isinstance(other, Name):
	return self.fullcompare(other)[1] < 0
	else:
	return NotImplemented

	def __le__(self, other):
	if isinstance(other, Name):
	return self.fullcompare(other)[1] <= 0
	else:
	return NotImplemented

	def __ge__(self, other):
	if isinstance(other, Name):
	return self.fullcompare(other)[1] >= 0
	else:
	return NotImplemented

	def __gt__(self, other):
	if isinstance(other, Name):
	return self.fullcompare(other)[1] > 0
	else:
	return NotImplemented

	def __repr__(self):
	return "<DNS name " + self.__str__() + ">"

	def __str__(self):
	return self.to_text(False)

	def to_text(self, omit_final_dot: bool = False) -> str:
	"""Convert name to DNS text format.

	omit_final_dot is a ``bool``. If True, don't emit the final
	dot (denoting the root label) for absolute names. The default
	is False.

	Returns a ``str``.
	"""

	if len(self.labels) == 0:
	return "@"
	if len(self.labels) == 1 and self.labels[0] == b"":
	return "."
	if omit_final_dot and self.is_absolute():
	l = self.labels[:-1]
	else:
	l = self.labels
	s = ".".join(map(_escapify, l))
	return s

	def to_unicode(
	self, omit_final_dot: bool = False, idna_codec: Optional[IDNACodec] = None
	) -> str:
	"""Convert name to Unicode text format.

	IDN ACE labels are converted to Unicode.

	omit_final_dot is a ``bool``. If True, don't emit the final
	dot (denoting the root label) for absolute names. The default
	is False.
	idna_codec specifies the IDNA encoder/decoder. If None, the
	dns.name.IDNA_2003_Practical encoder/decoder is used.
	The IDNA_2003_Practical decoder does
	not impose any policy, it just decodes punycode, so if you
	don't want checking for compliance, you can use this decoder
	for IDNA2008 as well.

	Returns a ``str``.
	"""

	if len(self.labels) == 0:
	return "@"
	if len(self.labels) == 1 and self.labels[0] == b"":
	return "."
	if omit_final_dot and self.is_absolute():
	l = self.labels[:-1]
	else:
	l = self.labels
	if idna_codec is None:
	idna_codec = IDNA_2003_Practical
	return ".".join([idna_codec.decode(x) for x in l])

	def to_digestable(self, origin: Optional["Name"] = None) -> bytes:
	"""Convert name to a format suitable for digesting in hashes.

	The name is canonicalized and converted to uncompressed wire
	format. All names in wire format are absolute. If the name
	is a relative name, then an origin must be supplied.

	origin is a ``dns.name.Name`` or ``None``. If the name is
	relative and origin is not ``None``, then origin will be appended
	to the name.

	Raises ``dns.name.NeedAbsoluteNameOrOrigin`` if the name is
	relative and no origin was provided.

	Returns a ``bytes``.
	"""

	digest = self.to_wire(origin=origin, canonicalize=True)
	assert digest is not None
	return digest

	def to_wire(
	self,
	file: Optional[Any] = None,
	compress: Optional[CompressType] = None,
	origin: Optional["Name"] = None,
	canonicalize: bool = False,
	) -> Optional[bytes]:
	"""Convert name to wire format, possibly compressing it.

	file is the file where the name is emitted (typically an
	io.BytesIO file). If ``None`` (the default), a ``bytes``
	containing the wire name will be returned.

	compress, a ``dict``, is the compression table to use. If
	``None`` (the default), names will not be compressed. Note that
	the compression code assumes that compression offset 0 is the
	start of file, and thus compression will not be correct
	if this is not the case.

	origin is a ``dns.name.Name`` or ``None``. If the name is
	relative and origin is not ``None``, then origin will be appended
	to it.

	canonicalize, a ``bool``, indicates whether the name should
	be canonicalized; that is, converted to a format suitable for
	digesting in hashes.

	Raises ``dns.name.NeedAbsoluteNameOrOrigin`` if the name is
	relative and no origin was provided.

	Returns a ``bytes`` or ``None``.
	"""

	if file is None:
	out = bytearray()
	for label in self.labels:
	out.append(len(label))
	if canonicalize:
	out += label.lower()
	else:
	out += label
	if not self.is_absolute():
	if origin is None or not origin.is_absolute():
	raise NeedAbsoluteNameOrOrigin
	for label in origin.labels:
	out.append(len(label))
	if canonicalize:
	out += label.lower()
	else:
	out += label
	return bytes(out)

	labels: Iterable[bytes]
	if not self.is_absolute():
	if origin is None or not origin.is_absolute():
	raise NeedAbsoluteNameOrOrigin
	labels = list(self.labels)
	labels.extend(list(origin.labels))
	else:
	labels = self.labels
	i = 0
	for label in labels:
	n = Name(labels[i:])
	i += 1
	if compress is not None:
	pos = compress.get(n)
	else:
	pos = None
	if pos is not None:
	value = 0xC000 + pos
	s = struct.pack("!H", value)
	file.write(s)
	break
	else:
	if compress is not None and len(n) > 1:
	pos = file.tell()
	if pos <= 0x3FFF:
	compress[n] = pos
	l = len(label)
	file.write(struct.pack("!B", l))
	if l > 0:
	if canonicalize:
	file.write(label.lower())
	else:
	file.write(label)
	return None

	def __len__(self) -> int:
	"""The length of the name (in labels).

	Returns an ``int``.
	"""

	return len(self.labels)

	def __getitem__(self, index):
	return self.labels[index]

	def __add__(self, other):
	return self.concatenate(other)

	def __sub__(self, other):
	return self.relativize(other)

	def split(self, depth: int) -> Tuple["Name", "Name"]:
	"""Split a name into a prefix and suffix names at the specified depth.

	depth is an ``int`` specifying the number of labels in the suffix

	Raises ``ValueError`` if depth was not >= 0 and <= the length of the
	name.

	Returns the tuple ``(prefix, suffix)``.
	"""

	l = len(self.labels)
	if depth == 0:
	return (self, dns.name.empty)
	elif depth == l:
	return (dns.name.empty, self)
	elif depth < 0 or depth > l:
	raise ValueError("depth must be >= 0 and <= the length of the name")
	return (Name(self[:-depth]), Name(self[-depth:]))

	def concatenate(self, other: "Name") -> "Name":
	"""Return a new name which is the concatenation of self and other.

	Raises ``dns.name.AbsoluteConcatenation`` if the name is
	absolute and other is not the empty name.

	Returns a ``dns.name.Name``.
	"""

	if self.is_absolute() and len(other) > 0:
	raise AbsoluteConcatenation
	labels = list(self.labels)
	labels.extend(list(other.labels))
	return Name(labels)

	def relativize(self, origin: "Name") -> "Name":
	"""If the name is a subdomain of origin, return a new name which is
	the name relative to origin. Otherwise return the name.

	For example, relativizing ``www.dnspython.org.`` to origin
	``dnspython.org.`` returns the name ``www``. Relativizing ``example.``
	to origin ``dnspython.org.`` returns ``example.``.

	Returns a ``dns.name.Name``.
	"""

	if origin is not None and self.is_subdomain(origin):
	return Name(self[: -len(origin)])
	else:
	return self

	def derelativize(self, origin: "Name") -> "Name":
	"""If the name is a relative name, return a new name which is the
	concatenation of the name and origin. Otherwise return the name.

	For example, derelativizing ``www`` to origin ``dnspython.org.``
	returns the name ``www.dnspython.org.``. Derelativizing ``example.``
	to origin ``dnspython.org.`` returns ``example.``.

	Returns a ``dns.name.Name``.
	"""

	if not self.is_absolute():
	return self.concatenate(origin)
	else:
	return self

	def choose_relativity(
	self, origin: Optional["Name"] = None, relativize: bool = True
	) -> "Name":
	"""Return a name with the relativity desired by the caller.

	If origin is ``None``, then the name is returned.
	Otherwise, if relativize is ``True`` the name is
	relativized, and if relativize is ``False`` the name is
	derelativized.

	Returns a ``dns.name.Name``.
	"""

	if origin:
	if relativize:
	return self.relativize(origin)
	else:
	return self.derelativize(origin)
	else:
	return self

	def parent(self) -> "Name":
	"""Return the parent of the name.

	For example, the parent of ``www.dnspython.org.`` is ``dnspython.org``.

	Raises ``dns.name.NoParent`` if the name is either the root name or the
	empty name, and thus has no parent.

	Returns a ``dns.name.Name``.
	"""

	if self == root or self == empty:
	raise NoParent
	return Name(self.labels[1:])

	def predecessor(self, origin: "Name", prefix_ok: bool = True) -> "Name":
	"""Return the maximal predecessor of name in the DNSSEC ordering in the zone
	whose origin is origin, or return the longest name under origin if the
	name is origin (i.e. wrap around to the longest name, which may still be
	origin due to length considerations.

	The relativity of the name is preserved, so if this name is relative
	then the method will return a relative name, and likewise if this name
	is absolute then the predecessor will be absolute.

	prefix_ok indicates if prefixing labels is allowed, and
	defaults to ``True``. Normally it is good to allow this, but if computing
	a maximal predecessor at a zone cut point then ``False`` must be specified.
	"""
	return _handle_relativity_and_call(
	_absolute_predecessor, self, origin, prefix_ok
	)

	def successor(self, origin: "Name", prefix_ok: bool = True) -> "Name":
	"""Return the minimal successor of name in the DNSSEC ordering in the zone
	whose origin is origin, or return origin if the successor cannot be
	computed due to name length limitations.

	Note that origin is returned in the "too long" cases because wrapping
	around to the origin is how NSEC records express "end of the zone".

	The relativity of the name is preserved, so if this name is relative
	then the method will return a relative name, and likewise if this name
	is absolute then the successor will be absolute.

	prefix_ok indicates if prefixing a new minimal label is allowed, and
	defaults to ``True``. Normally it is good to allow this, but if computing
	a minimal successor at a zone cut point then ``False`` must be specified.
	"""
	return _handle_relativity_and_call(_absolute_successor, self, origin, prefix_ok)


	#: The root name, '.'
	root = Name([b""])

	#: The empty name.
	empty = Name([])


	def from_unicode(
	text: str, origin: Optional[Name] = root, idna_codec: Optional[IDNACodec] = None
	) -> Name:
	"""Convert unicode text into a Name object.

	Labels are encoded in IDN ACE form according to rules specified by
	the IDNA codec.

	text, a ``str``, is the text to convert into a name.

	origin, a ``dns.name.Name``, specifies the origin to
	append to non-absolute names. The default is the root name.

	idna_codec, a ``dns.name.IDNACodec``, specifies the IDNA
	encoder/decoder. If ``None``, the default IDNA 2003 encoder/decoder
	is used.

	Returns a ``dns.name.Name``.
	"""

	if not isinstance(text, str):
	raise ValueError("input to from_unicode() must be a unicode string")
	if not (origin is None or isinstance(origin, Name)):
	raise ValueError("origin must be a Name or None")
	labels = []
	label = ""
	escaping = False
	edigits = 0
	total = 0
	if idna_codec is None:
	idna_codec = IDNA_2003
	if text == "@":
	text = ""
	if text:
	if text in [".", "\u3002", "\uff0e", "\uff61"]:
	return Name([b""]) # no Unicode "u" on this constant!
	for c in text:
	if escaping:
	if edigits == 0:
	if c.isdigit():
	total = int(c)
	edigits += 1
	else:
	label += c
	escaping = False
	else:
	if not c.isdigit():
	raise BadEscape
	total *= 10
	total += int(c)
	edigits += 1
	if edigits == 3:
	escaping = False
	label += chr(total)
	elif c in [".", "\u3002", "\uff0e", "\uff61"]:
	if len(label) == 0:
	raise EmptyLabel
	labels.append(idna_codec.encode(label))
	label = ""
	elif c == "\\":
	escaping = True
	edigits = 0
	total = 0
	else:
	label += c
	if escaping:
	raise BadEscape
	if len(label) > 0:
	labels.append(idna_codec.encode(label))
	else:
	labels.append(b"")

	if (len(labels) == 0 or labels[-1] != b"") and origin is not None:
	labels.extend(list(origin.labels))
	return Name(labels)


	def is_all_ascii(text: str) -> bool:
	for c in text:
	if ord(c) > 0x7F:
	return False
	return True


	def from_text(
	text: Union[bytes, str],
	origin: Optional[Name] = root,
	idna_codec: Optional[IDNACodec] = None,
	) -> Name:
	"""Convert text into a Name object.

	text, a ``bytes`` or ``str``, is the text to convert into a name.

	origin, a ``dns.name.Name``, specifies the origin to
	append to non-absolute names. The default is the root name.

	idna_codec, a ``dns.name.IDNACodec``, specifies the IDNA
	encoder/decoder. If ``None``, the default IDNA 2003 encoder/decoder
	is used.

	Returns a ``dns.name.Name``.
	"""

	if isinstance(text, str):
	if not is_all_ascii(text):
	# Some codepoint in the input text is > 127, so IDNA applies.
	return from_unicode(text, origin, idna_codec)
	# The input is all ASCII, so treat this like an ordinary non-IDNA
	# domain name. Note that "all ASCII" is about the input text,
	# not the codepoints in the domain name. E.g. if text has value
	#
	# r'\150\151\152\153\154\155\156\157\158\159'
	#
	# then it's still "all ASCII" even though the domain name has
	# codepoints > 127.
	text = text.encode("ascii")
	if not isinstance(text, bytes):
	raise ValueError("input to from_text() must be a string")
	if not (origin is None or isinstance(origin, Name)):
	raise ValueError("origin must be a Name or None")
	labels = []
	label = b""
	escaping = False
	edigits = 0
	total = 0
	if text == b"@":
	text = b""
	if text:
	if text == b".":
	return Name([b""])
	for c in text:
	byte_ = struct.pack("!B", c)
	if escaping:
	if edigits == 0:
	if byte_.isdigit():
	total = int(byte_)
	edigits += 1
	else:
	label += byte_
	escaping = False
	else:
	if not byte_.isdigit():
	raise BadEscape
	total *= 10
	total += int(byte_)
	edigits += 1
	if edigits == 3:
	escaping = False
	label += struct.pack("!B", total)
	elif byte_ == b".":
	if len(label) == 0:
	raise EmptyLabel
	labels.append(label)
	label = b""
	elif byte_ == b"\\":
	escaping = True
	edigits = 0
	total = 0
	else:
	label += byte_
	if escaping:
	raise BadEscape
	if len(label) > 0:
	labels.append(label)
	else:
	labels.append(b"")
	if (len(labels) == 0 or labels[-1] != b"") and origin is not None:
	labels.extend(list(origin.labels))
	return Name(labels)


	# we need 'dns.wire.Parser' quoted as dns.name and dns.wire depend on each other.


	def from_wire_parser(parser: "dns.wire.Parser") -> Name:
	"""Convert possibly compressed wire format into a Name.

	parser is a dns.wire.Parser.

	Raises ``dns.name.BadPointer`` if a compression pointer did not
	point backwards in the message.

	Raises ``dns.name.BadLabelType`` if an invalid label type was encountered.

	Returns a ``dns.name.Name``
	"""

	labels = []
	biggest_pointer = parser.current
	with parser.restore_furthest():
	count = parser.get_uint8()
	while count != 0:
	if count < 64:
	labels.append(parser.get_bytes(count))
	elif count >= 192:
	current = (count & 0x3F) * 256 + parser.get_uint8()
	if current >= biggest_pointer:
	raise BadPointer
	biggest_pointer = current
	parser.seek(current)
	else:
	raise BadLabelType
	count = parser.get_uint8()
	labels.append(b"")
	return Name(labels)


	def from_wire(message: bytes, current: int) -> Tuple[Name, int]:
	"""Convert possibly compressed wire format into a Name.

	message is a ``bytes`` containing an entire DNS message in DNS
	wire form.

	current, an ``int``, is the offset of the beginning of the name
	from the start of the message

	Raises ``dns.name.BadPointer`` if a compression pointer did not
	point backwards in the message.

	Raises ``dns.name.BadLabelType`` if an invalid label type was encountered.

	Returns a ``(dns.name.Name, int)`` tuple consisting of the name
	that was read and the number of bytes of the wire format message
	which were consumed reading it.
	"""

	if not isinstance(message, bytes):
	raise ValueError("input to from_wire() must be a byte string")
	parser = dns.wire.Parser(message, current)
	name = from_wire_parser(parser)
	return (name, parser.current - current)


	# RFC 4471 Support

	_MINIMAL_OCTET = b"\x00"
	_MINIMAL_OCTET_VALUE = ord(_MINIMAL_OCTET)
	_SUCCESSOR_PREFIX = Name([_MINIMAL_OCTET])
	_MAXIMAL_OCTET = b"\xff"
	_MAXIMAL_OCTET_VALUE = ord(_MAXIMAL_OCTET)
	_AT_SIGN_VALUE = ord("@")
	_LEFT_SQUARE_BRACKET_VALUE = ord("[")


	def _wire_length(labels):
	return functools.reduce(lambda v, x: v + len(x) + 1, labels, 0)


	def _pad_to_max_name(name):
	needed = 255 - _wire_length(name.labels)
	new_labels = []
	while needed > 64:
	new_labels.append(_MAXIMAL_OCTET * 63)
	needed -= 64
	if needed >= 2:
	new_labels.append(_MAXIMAL_OCTET * (needed - 1))
	# Note we're already maximal in the needed == 1 case as while we'd like
	# to add one more byte as a new label, we can't, as adding a new non-empty
	# label requires at least 2 bytes.
	new_labels = list(reversed(new_labels))
	new_labels.extend(name.labels)
	return Name(new_labels)


	def _pad_to_max_label(label, suffix_labels):
	length = len(label)
	# We have to subtract one here to account for the length byte of label.
	remaining = 255 - _wire_length(suffix_labels) - length - 1
	if remaining <= 0:
	# Shouldn't happen!
	return label
	needed = min(63 - length, remaining)
	return label + _MAXIMAL_OCTET * needed


	def _absolute_predecessor(name: Name, origin: Name, prefix_ok: bool) -> Name:
	# This is the RFC 4471 predecessor algorithm using the "absolute method" of section
	# 3.1.1.
	#
	# Our caller must ensure that the name and origin are absolute, and that name is a
	# subdomain of origin.
	if name == origin:
	return _pad_to_max_name(name)
	least_significant_label = name[0]
	if least_significant_label == _MINIMAL_OCTET:
	return name.parent()
	least_octet = least_significant_label[-1]
	suffix_labels = name.labels[1:]
	if least_octet == _MINIMAL_OCTET_VALUE:
	new_labels = [least_significant_label[:-1]]
	else:
	octets = bytearray(least_significant_label)
	octet = octets[-1]
	if octet == _LEFT_SQUARE_BRACKET_VALUE:
	octet = _AT_SIGN_VALUE
	else:
	octet -= 1
	octets[-1] = octet
	least_significant_label = bytes(octets)
	new_labels = [_pad_to_max_label(least_significant_label, suffix_labels)]
	new_labels.extend(suffix_labels)
	name = Name(new_labels)
	if prefix_ok:
	return _pad_to_max_name(name)
	else:
	return name


	def _absolute_successor(name: Name, origin: Name, prefix_ok: bool) -> Name:
	# This is the RFC 4471 successor algorithm using the "absolute method" of section
	# 3.1.2.
	#
	# Our caller must ensure that the name and origin are absolute, and that name is a
	# subdomain of origin.
	if prefix_ok:
	# Try prefixing \000 as new label
	try:
	return _SUCCESSOR_PREFIX.concatenate(name)
	except NameTooLong:
	pass
	while name != origin:
	# Try extending the least significant label.
	least_significant_label = name[0]
	if len(least_significant_label) < 63:
	# We may be able to extend the least label with a minimal additional byte.
	# This is only "may" because we could have a maximal length name even though
	# the least significant label isn't maximally long.
	new_labels = [least_significant_label + _MINIMAL_OCTET]
	new_labels.extend(name.labels[1:])
	try:
	return dns.name.Name(new_labels)
	except dns.name.NameTooLong:
	pass
	# We can't extend the label either, so we'll try to increment the least
	# signficant non-maximal byte in it.
	octets = bytearray(least_significant_label)
	# We do this reversed iteration with an explicit indexing variable because
	# if we find something to increment, we're going to want to truncate everything
	# to the right of it.
	for i in range(len(octets) - 1, -1, -1):
	octet = octets[i]
	if octet == _MAXIMAL_OCTET_VALUE:
	# We can't increment this, so keep looking.
	continue
	# Finally, something we can increment. We have to apply a special rule for
	# incrementing "@", sending it to "[", because RFC 4034 6.1 says that when
	# comparing names, uppercase letters compare as if they were their
	# lower-case equivalents. If we increment "@" to "A", then it would compare
	# as "a", which is after "[", "\", "]", "^", "_", and "`", so we would have
	# skipped the most minimal successor, namely "[".
	if octet == _AT_SIGN_VALUE:
	octet = _LEFT_SQUARE_BRACKET_VALUE
	else:
	octet += 1
	octets[i] = octet
	# We can now truncate all of the maximal values we skipped (if any)
	new_labels = [bytes(octets[: i + 1])]
	new_labels.extend(name.labels[1:])
	# We haven't changed the length of the name, so the Name constructor will
	# always work.
	return Name(new_labels)
	# We couldn't increment, so chop off the least significant label and try
	# again.
	name = name.parent()

	# We couldn't increment at all, so return the origin, as wrapping around is the
	# DNSSEC way.
	return origin


	def _handle_relativity_and_call(
	function: Callable[[Name, Name, bool], Name],
	name: Name,
	origin: Name,
	prefix_ok: bool,
	) -> Name:
	# Make "name" absolute if needed, ensure that the origin is absolute,
	# call function(), and then relativize the result if needed.
	if not origin.is_absolute():
	raise NeedAbsoluteNameOrOrigin
	relative = not name.is_absolute()
	if relative:
	name = name.derelativize(origin)
	elif not name.is_subdomain(origin):
	raise NeedSubdomainOfOrigin
	result_name = function(name, origin, prefix_ok)
	if relative:
	result_name = result_name.relativize(origin)
	return result_name