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# -*- test-case-name: twisted.names.test.test_dns -*-
# Copyright (c) Twisted Matrix Laboratories.
# See LICENSE for details.

"""
DNS protocol implementation.

Future Plans:
    - Get rid of some toplevels, maybe.
"""
from __future__ import annotations

# System imports
import inspect
import random
import socket
import struct
from io import BytesIO
from itertools import chain
from typing import Optional, Sequence, SupportsInt, Union, overload

from zope.interface import Attribute, Interface, implementer

# Twisted imports
from twisted.internet import defer, protocol
from twisted.internet.error import CannotListenError
from twisted.python import failure, log, randbytes, util as tputil
from twisted.python.compat import cmp, comparable, nativeString

__all__ = [
    "IEncodable",
    "IRecord",
    "IEncodableRecord",
    "A",
    "A6",
    "AAAA",
    "AFSDB",
    "CNAME",
    "DNAME",
    "HINFO",
    "MAILA",
    "MAILB",
    "MB",
    "MD",
    "MF",
    "MG",
    "MINFO",
    "MR",
    "MX",
    "NAPTR",
    "NS",
    "NULL",
    "OPT",
    "PTR",
    "RP",
    "SOA",
    "SPF",
    "SRV",
    "TXT",
    "SSHFP",
    "TSIG",
    "WKS",
    "ANY",
    "CH",
    "CS",
    "HS",
    "IN",
    "ALL_RECORDS",
    "AXFR",
    "IXFR",
    "EFORMAT",
    "ENAME",
    "ENOTIMP",
    "EREFUSED",
    "ESERVER",
    "EBADVERSION",
    "EBADSIG",
    "EBADKEY",
    "EBADTIME",
    "Record_A",
    "Record_A6",
    "Record_AAAA",
    "Record_AFSDB",
    "Record_CNAME",
    "Record_DNAME",
    "Record_HINFO",
    "Record_MB",
    "Record_MD",
    "Record_MF",
    "Record_MG",
    "Record_MINFO",
    "Record_MR",
    "Record_MX",
    "Record_NAPTR",
    "Record_NS",
    "Record_NULL",
    "Record_PTR",
    "Record_RP",
    "Record_SOA",
    "Record_SPF",
    "Record_SRV",
    "Record_SSHFP",
    "Record_TSIG",
    "Record_TXT",
    "Record_WKS",
    "UnknownRecord",
    "QUERY_CLASSES",
    "QUERY_TYPES",
    "REV_CLASSES",
    "REV_TYPES",
    "EXT_QUERIES",
    "Charstr",
    "Message",
    "Name",
    "Query",
    "RRHeader",
    "SimpleRecord",
    "DNSDatagramProtocol",
    "DNSMixin",
    "DNSProtocol",
    "OK",
    "OP_INVERSE",
    "OP_NOTIFY",
    "OP_QUERY",
    "OP_STATUS",
    "OP_UPDATE",
    "PORT",
    "AuthoritativeDomainError",
    "DNSQueryTimeoutError",
    "DomainError",
]


AF_INET6 = socket.AF_INET6


def _ord2bytes(ordinal):
    """
    Construct a bytes object representing a single byte with the given
    ordinal value.

    @type ordinal: L{int}
    @rtype: L{bytes}
    """
    return bytes([ordinal])


def _nicebytes(bytes):
    """
    Represent a mostly textful bytes object in a way suitable for
    presentation to an end user.

    @param bytes: The bytes to represent.
    @rtype: L{str}
    """
    return repr(bytes)[1:]


def _nicebyteslist(list):
    """
    Represent a list of mostly textful bytes objects in a way suitable for
    presentation to an end user.

    @param list: The list of bytes to represent.
    @rtype: L{str}
    """
    return "[{}]".format(", ".join([_nicebytes(b) for b in list]))


def randomSource():
    """
    Wrapper around L{twisted.python.randbytes.RandomFactory.secureRandom} to
    return 2 random bytes.

    @rtype: L{bytes}
    """
    return struct.unpack("H", randbytes.secureRandom(2, fallback=True))[0]


PORT = 53

(
    A,
    NS,
    MD,
    MF,
    CNAME,
    SOA,
    MB,
    MG,
    MR,
    NULL,
    WKS,
    PTR,
    HINFO,
    MINFO,
    MX,
    TXT,
    RP,
    AFSDB,
) = range(1, 19)
AAAA = 28
SRV = 33
NAPTR = 35
A6 = 38
DNAME = 39
OPT = 41
SSHFP = 44
SPF = 99

# These record types do not exist in zones, but are transferred in
# messages the same way normal RRs are.
TKEY = 249
TSIG = 250

QUERY_TYPES = {
    A: "A",
    NS: "NS",
    MD: "MD",
    MF: "MF",
    CNAME: "CNAME",
    SOA: "SOA",
    MB: "MB",
    MG: "MG",
    MR: "MR",
    NULL: "NULL",
    WKS: "WKS",
    PTR: "PTR",
    HINFO: "HINFO",
    MINFO: "MINFO",
    MX: "MX",
    TXT: "TXT",
    RP: "RP",
    AFSDB: "AFSDB",
    # 19 through 27?  Eh, I'll get to 'em.
    AAAA: "AAAA",
    SRV: "SRV",
    NAPTR: "NAPTR",
    A6: "A6",
    DNAME: "DNAME",
    OPT: "OPT",
    SSHFP: "SSHFP",
    SPF: "SPF",
    TKEY: "TKEY",
    TSIG: "TSIG",
}

IXFR, AXFR, MAILB, MAILA, ALL_RECORDS = range(251, 256)

# "Extended" queries (Hey, half of these are deprecated, good job)
EXT_QUERIES = {
    IXFR: "IXFR",
    AXFR: "AXFR",
    MAILB: "MAILB",
    MAILA: "MAILA",
    ALL_RECORDS: "ALL_RECORDS",
}

REV_TYPES = {v: k for (k, v) in chain(QUERY_TYPES.items(), EXT_QUERIES.items())}

IN, CS, CH, HS = range(1, 5)
ANY = 255

QUERY_CLASSES = {IN: "IN", CS: "CS", CH: "CH", HS: "HS", ANY: "ANY"}
REV_CLASSES = {v: k for (k, v) in QUERY_CLASSES.items()}


# Opcodes
OP_QUERY, OP_INVERSE, OP_STATUS = range(3)
OP_NOTIFY = 4  # RFC 1996
OP_UPDATE = 5  # RFC 2136


# Response Codes
OK, EFORMAT, ESERVER, ENAME, ENOTIMP, EREFUSED = range(6)
# https://tools.ietf.org/html/rfc6891#section-9
EBADVERSION = 16
# RFC 2845
EBADSIG, EBADKEY, EBADTIME = range(16, 19)


class IRecord(Interface):
    """
    A single entry in a zone of authority.
    """

    TYPE = Attribute("An indicator of what kind of record this is.")


# Backwards compatibility aliases - these should be deprecated or something I
# suppose. -exarkun
from twisted.names.error import (
    AuthoritativeDomainError,
    DNSQueryTimeoutError,
    DomainError,
)


def _nameToLabels(name):
    """
    Split a domain name into its constituent labels.

    @type name: L{bytes}
    @param name: A fully qualified domain name (with or without a
        trailing dot).

    @return: A L{list} of labels ending with an empty label
        representing the DNS root zone.
    @rtype: L{list} of L{bytes}
    """
    if name in (b"", b"."):
        return [b""]
    labels = name.split(b".")
    if labels[-1] != b"":
        labels.append(b"")
    return labels


def domainString(domain: str | bytes) -> bytes:
    """
    Coerce a domain name string to bytes.

    L{twisted.names} represents domain names as L{bytes}, but many interfaces
    accept L{bytes} or a text string (L{unicode} on Python 2, L{str} on Python
    3). This function coerces text strings using IDNA encoding --- see
    L{encodings.idna}.

    Note that DNS is I{case insensitive} but I{case preserving}. This function
    doesn't normalize case, so you'll still need to do that whenever comparing
    the strings it returns.

    @param domain: A domain name.  If passed as a text string it will be
        C{idna} encoded.
    @type domain: L{bytes} or L{str}

    @returns: L{bytes} suitable for network transmission.
    @rtype: L{bytes}

    @since: Twisted 20.3.0
    """
    if isinstance(domain, str):
        domain = domain.encode("idna")
    if not isinstance(domain, bytes):
        raise TypeError(
            "Expected {} or {} but found {!r} of type {}".format(
                bytes.__name__, str.__name__, domain, type(domain)
            )
        )
    return domain


def _isSubdomainOf(descendantName, ancestorName):
    """
    Test whether C{descendantName} is equal to or is a I{subdomain} of
    C{ancestorName}.

    The names are compared case-insensitively.

    The names are treated as byte strings containing one or more
    DNS labels separated by B{.}.

    C{descendantName} is considered equal if its sequence of labels
    exactly matches the labels of C{ancestorName}.

    C{descendantName} is considered a I{subdomain} if its sequence of
    labels ends with the labels of C{ancestorName}.

    @type descendantName: L{bytes}
    @param descendantName: The DNS subdomain name.

    @type ancestorName: L{bytes}
    @param ancestorName: The DNS parent or ancestor domain name.

    @return: C{True} if C{descendantName} is equal to or if it is a
        subdomain of C{ancestorName}. Otherwise returns C{False}.
    """
    descendantLabels = _nameToLabels(descendantName.lower())
    ancestorLabels = _nameToLabels(ancestorName.lower())
    return descendantLabels[-len(ancestorLabels) :] == ancestorLabels


def _str2time(s: str) -> int:
    """
    mypy doesn't like type-punning str | bytes | int | None into a str so we have this helper function.
    """
    suffixes = (
        ("S", 1),
        ("M", 60),
        ("H", 60 * 60),
        ("D", 60 * 60 * 24),
        ("W", 60 * 60 * 24 * 7),
        ("Y", 60 * 60 * 24 * 365),
    )
    s = s.upper().strip()
    for suff, mult in suffixes:
        if s.endswith(suff):
            return int(float(s[:-1]) * mult)
    try:
        return int(s)
    except ValueError:
        raise ValueError("Invalid time interval specifier: " + s)


@overload
def str2time(s: Union[str, bytes, int]) -> int:
    ...


@overload
def str2time(s: None) -> None:
    ...


def str2time(s: Union[str, bytes, int, None]) -> Union[int, None]:
    """
    Parse a string description of an interval into an integer number of seconds.

    @param s: An interval definition constructed as an interval duration
        followed by an interval unit.  An interval duration is a base ten
        representation of an integer.  An interval unit is one of the following
        letters: S (seconds), M (minutes), H (hours), D (days), W (weeks), or Y
        (years).  For example: C{"3S"} indicates an interval of three seconds;
        C{"5D"} indicates an interval of five days.  Alternatively, C{s} may be
        any non-string and it will be returned unmodified.
    @type s: text string (L{bytes} or L{str}) for parsing; anything else
        for passthrough.

    @return: an L{int} giving the interval represented by the string C{s}, or
        whatever C{s} is if it is not a string.
    """
    if isinstance(s, bytes):
        return _str2time(s.decode("ascii"))

    if isinstance(s, str):
        return _str2time(s)

    return s


def readPrecisely(file, l):
    buff = file.read(l)
    if len(buff) < l:
        raise EOFError
    return buff


class IEncodable(Interface):
    """
    Interface for something which can be encoded to and decoded
    to the DNS wire format.

    A binary-mode file object (such as L{io.BytesIO}) is used as a buffer when
    encoding or decoding.
    """

    def encode(strio, compDict=None):
        """
        Write a representation of this object to the given
        file object.

        @type strio: File-like object
        @param strio: The buffer to write to. It must have a C{tell()} method.

        @type compDict: L{dict} of L{bytes} to L{int} r L{None}
        @param compDict: A mapping of names to byte offsets that have already
        been written to the buffer, which may be used for compression (see RFC
        1035 section 4.1.4). When L{None}, encode without compression.
        """

    def decode(strio, length=None):
        """
        Reconstruct an object from data read from the given
        file object.

        @type strio: File-like object
        @param strio: A seekable buffer from which bytes may be read.

        @type length: L{int} or L{None}
        @param length: The number of bytes in this RDATA field.  Most
        implementations can ignore this value.  Only in the case of
        records similar to TXT where the total length is in no way
        encoded in the data is it necessary.
        """


class IEncodableRecord(IEncodable, IRecord):
    """
    Interface for DNS records that can be encoded and decoded.

    @since: Twisted 21.2.0
    """


@implementer(IEncodable)
class Charstr:
    def __init__(self, string: bytes = b""):
        if not isinstance(string, bytes):
            raise ValueError(f"{string!r} is not a byte string")
        self.string = string

    def encode(self, strio, compDict=None):
        """
        Encode this Character string into the appropriate byte format.

        @type strio: file
        @param strio: The byte representation of this Charstr will be written
            to this file.
        """
        string = self.string
        ind = len(string)
        strio.write(_ord2bytes(ind))
        strio.write(string)

    def decode(self, strio, length=None):
        """
        Decode a byte string into this Charstr.

        @type strio: file
        @param strio: Bytes will be read from this file until the full string
            is decoded.

        @raise EOFError: Raised when there are not enough bytes available from
            C{strio}.
        """
        self.string = b""
        l = ord(readPrecisely(strio, 1))
        self.string = readPrecisely(strio, l)

    def __eq__(self, other: object) -> bool:
        if isinstance(other, Charstr):
            return self.string == other.string
        return NotImplemented

    def __hash__(self):
        return hash(self.string)

    def __str__(self) -> str:
        """
        Represent this L{Charstr} instance by its string value.
        """
        return nativeString(self.string)


@implementer(IEncodable)
class Name:
    """
    A name in the domain name system, made up of multiple labels.  For example,
    I{twistedmatrix.com}.

    @ivar name: A byte string giving the name.
    @type name: L{bytes}
    """

    def __init__(self, name: bytes | str = b""):
        """
        @param name: A name.
        @type name: L{bytes} or L{str}
        """
        self.name = domainString(name)

    def encode(self, strio, compDict=None):
        """
        Encode this Name into the appropriate byte format.

        @type strio: file
        @param strio: The byte representation of this Name will be written to
        this file.

        @type compDict: dict
        @param compDict: dictionary of Names that have already been encoded
        and whose addresses may be backreferenced by this Name (for the purpose
        of reducing the message size).
        """
        name = self.name
        while name:
            if compDict is not None:
                if name in compDict:
                    strio.write(struct.pack("!H", 0xC000 | compDict[name]))
                    return
                else:
                    compDict[name] = strio.tell() + Message.headerSize
            ind = name.find(b".")
            if ind > 0:
                label, name = name[:ind], name[ind + 1 :]
            else:
                # This is the last label, end the loop after handling it.
                label = name
                name = None
                ind = len(label)
            strio.write(_ord2bytes(ind))
            strio.write(label)
        strio.write(b"\x00")

    def decode(self, strio, length=None):
        """
        Decode a byte string into this Name.

        @type strio: file
        @param strio: Bytes will be read from this file until the full Name
        is decoded.

        @raise EOFError: Raised when there are not enough bytes available
        from C{strio}.

        @raise ValueError: Raised when the name cannot be decoded (for example,
            because it contains a loop).
        """
        visited = set()
        self.name = b""
        off = 0
        while 1:
            l = ord(readPrecisely(strio, 1))
            if l == 0:
                if off > 0:
                    strio.seek(off)
                return
            if (l >> 6) == 3:
                new_off = (l & 63) << 8 | ord(readPrecisely(strio, 1))
                if new_off in visited:
                    raise ValueError("Compression loop in encoded name")
                visited.add(new_off)
                if off == 0:
                    off = strio.tell()
                strio.seek(new_off)
                continue
            label = readPrecisely(strio, l)
            if self.name == b"":
                self.name = label
            else:
                self.name = self.name + b"." + label

    def __eq__(self, other: object) -> bool:
        if isinstance(other, Name):
            return self.name.lower() == other.name.lower()
        return NotImplemented

    def __hash__(self):
        return hash(self.name)

    def __str__(self) -> str:
        """
        Represent this L{Name} instance by its string name.
        """
        return nativeString(self.name)


@comparable
@implementer(IEncodable)
class Query:
    """
    Represent a single DNS query.

    @ivar name: The name about which this query is requesting information.
    @type name: L{Name}

    @ivar type: The query type.
    @type type: L{int}

    @ivar cls: The query class.
    @type cls: L{int}
    """

    def __init__(self, name: Union[bytes, str] = b"", type: int = A, cls: int = IN):
        """
        @type name: L{bytes} or L{str}
        @param name: See L{Query.name}

        @type type: L{int}
        @param type: The query type.

        @type cls: L{int}
        @param cls: The query class.
        """
        self.name = Name(name)
        self.type = type
        self.cls = cls

    def encode(self, strio, compDict=None):
        self.name.encode(strio, compDict)
        strio.write(struct.pack("!HH", self.type, self.cls))

    def decode(self, strio, length=None):
        self.name.decode(strio)
        buff = readPrecisely(strio, 4)
        self.type, self.cls = struct.unpack("!HH", buff)

    def __hash__(self):
        return hash((self.name.name.lower(), self.type, self.cls))

    def __cmp__(self, other):
        if isinstance(other, Query):
            return cmp(
                (self.name.name.lower(), self.type, self.cls),
                (other.name.name.lower(), other.type, other.cls),
            )
        return NotImplemented

    def __str__(self) -> str:
        t = QUERY_TYPES.get(
            self.type, EXT_QUERIES.get(self.type, "UNKNOWN (%d)" % self.type)
        )
        c = QUERY_CLASSES.get(self.cls, "UNKNOWN (%d)" % self.cls)
        return f"<Query {self.name} {t} {c}>"

    def __repr__(self) -> str:
        return f"Query({self.name.name!r}, {self.type!r}, {self.cls!r})"


@implementer(IEncodable)
class _OPTHeader(tputil.FancyStrMixin, tputil.FancyEqMixin):
    """
    An OPT record header.

    @ivar name: The DNS name associated with this record. Since this
        is a pseudo record, the name is always an L{Name} instance
        with value b'', which represents the DNS root zone. This
        attribute is a readonly property.

    @ivar type: The DNS record type. This is a fixed value of 41
        C{dns.OPT} for OPT Record. This attribute is a readonly
        property.

    @see: L{_OPTHeader.__init__} for documentation of other public
        instance attributes.

    @see: U{https://tools.ietf.org/html/rfc6891#section-6.1.2}

    @since: 13.2
    """

    showAttributes = (
        ("name", lambda n: nativeString(n.name)),
        "type",
        "udpPayloadSize",
        "extendedRCODE",
        "version",
        "dnssecOK",
        "options",
    )

    compareAttributes = (
        "name",
        "type",
        "udpPayloadSize",
        "extendedRCODE",
        "version",
        "dnssecOK",
        "options",
    )

    def __init__(
        self,
        udpPayloadSize=4096,
        extendedRCODE=0,
        version=0,
        dnssecOK=False,
        options=None,
    ):
        """
        @type udpPayloadSize: L{int}
        @param udpPayloadSize: The number of octets of the largest UDP
            payload that can be reassembled and delivered in the
            requestor's network stack.

        @type extendedRCODE: L{int}
        @param extendedRCODE: Forms the upper 8 bits of extended
            12-bit RCODE (together with the 4 bits defined in
            [RFC1035].  Note that EXTENDED-RCODE value 0 indicates
            that an unextended RCODE is in use (values 0 through 15).

        @type version: L{int}
        @param version: Indicates the implementation level of the
            setter.  Full conformance with this specification is
            indicated by version C{0}.

        @type dnssecOK: L{bool}
        @param dnssecOK: DNSSEC OK bit as defined by [RFC3225].

        @type options: L{list}
        @param options: A L{list} of 0 or more L{_OPTVariableOption}
            instances.
        """
        self.udpPayloadSize = udpPayloadSize
        self.extendedRCODE = extendedRCODE
        self.version = version
        self.dnssecOK = dnssecOK

        if options is None:
            options = []
        self.options = options

    @property
    def name(self):
        """
        A readonly property for accessing the C{name} attribute of
        this record.

        @return: The DNS name associated with this record. Since this
            is a pseudo record, the name is always an L{Name} instance
            with value b'', which represents the DNS root zone.
        """
        return Name(b"")

    @property
    def type(self):
        """
        A readonly property for accessing the C{type} attribute of
        this record.

        @return: The DNS record type. This is a fixed value of 41
            (C{dns.OPT} for OPT Record.
        """
        return OPT

    def encode(self, strio, compDict=None):
        """
        Encode this L{_OPTHeader} instance to bytes.

        @type strio: file
        @param strio: the byte representation of this L{_OPTHeader}
            will be written to this file.

        @type compDict: L{dict} or L{None}
        @param compDict: A dictionary of backreference addresses that
            have already been written to this stream and that may
            be used for DNS name compression.
        """
        b = BytesIO()
        for o in self.options:
            o.encode(b)
        optionBytes = b.getvalue()

        RRHeader(
            name=self.name.name,
            type=self.type,
            cls=self.udpPayloadSize,
            ttl=(self.extendedRCODE << 24 | self.version << 16 | self.dnssecOK << 15),
            payload=UnknownRecord(optionBytes),
        ).encode(strio, compDict)

    def decode(self, strio, length=None):
        """
        Decode bytes into an L{_OPTHeader} instance.

        @type strio: file
        @param strio: Bytes will be read from this file until the full
            L{_OPTHeader} is decoded.

        @type length: L{int} or L{None}
        @param length: Not used.
        """

        h = RRHeader()
        h.decode(strio, length)
        h.payload = UnknownRecord(readPrecisely(strio, h.rdlength))

        newOptHeader = self.fromRRHeader(h)

        for attrName in self.compareAttributes:
            if attrName not in ("name", "type"):
                setattr(self, attrName, getattr(newOptHeader, attrName))

    @classmethod
    def fromRRHeader(cls, rrHeader):
        """
        A classmethod for constructing a new L{_OPTHeader} from the
        attributes and payload of an existing L{RRHeader} instance.

        @type rrHeader: L{RRHeader}
        @param rrHeader: An L{RRHeader} instance containing an
            L{UnknownRecord} payload.

        @return: An instance of L{_OPTHeader}.
        @rtype: L{_OPTHeader}
        """
        options = None
        if rrHeader.payload is not None:
            options = []
            optionsBytes = BytesIO(rrHeader.payload.data)
            optionsBytesLength = len(rrHeader.payload.data)
            while optionsBytes.tell() < optionsBytesLength:
                o = _OPTVariableOption()
                o.decode(optionsBytes)
                options.append(o)

        # Decode variable options if present
        return cls(
            udpPayloadSize=rrHeader.cls,
            extendedRCODE=rrHeader.ttl >> 24,
            version=rrHeader.ttl >> 16 & 0xFF,
            dnssecOK=(rrHeader.ttl & 0xFFFF) >> 15,
            options=options,
        )


@implementer(IEncodable)
class _OPTVariableOption(tputil.FancyStrMixin, tputil.FancyEqMixin):
    """
    A class to represent OPT record variable options.

    @see: L{_OPTVariableOption.__init__} for documentation of public
        instance attributes.

    @see: U{https://tools.ietf.org/html/rfc6891#section-6.1.2}

    @since: 13.2
    """

    showAttributes = ("code", ("data", nativeString))
    compareAttributes = ("code", "data")

    _fmt = "!HH"

    def __init__(self, code=0, data=b""):
        """
        @type code: L{int}
        @param code: The option code

        @type data: L{bytes}
        @param data: The option data
        """
        self.code = code
        self.data = data

    def encode(self, strio, compDict=None):
        """
        Encode this L{_OPTVariableOption} to bytes.

        @type strio: file
        @param strio: the byte representation of this
            L{_OPTVariableOption} will be written to this file.

        @type compDict: L{dict} or L{None}
        @param compDict: A dictionary of backreference addresses that
            have already been written to this stream and that may
            be used for DNS name compression.
        """
        strio.write(struct.pack(self._fmt, self.code, len(self.data)) + self.data)

    def decode(self, strio, length=None):
        """
        Decode bytes into an L{_OPTVariableOption} instance.

        @type strio: file
        @param strio: Bytes will be read from this file until the full
            L{_OPTVariableOption} is decoded.

        @type length: L{int} or L{None}
        @param length: Not used.
        """
        l = struct.calcsize(self._fmt)
        buff = readPrecisely(strio, l)
        self.code, length = struct.unpack(self._fmt, buff)
        self.data = readPrecisely(strio, length)


@implementer(IEncodable)
class RRHeader(tputil.FancyEqMixin):
    """
    A resource record header.

    @cvar fmt: L{str} specifying the byte format of an RR.

    @ivar name: The name about which this reply contains information.
    @type name: L{Name}

    @ivar type: The query type of the original request.
    @type type: L{int}

    @ivar cls: The query class of the original request.

    @ivar ttl: The time-to-live for this record.
    @type ttl: L{int}

    @ivar payload: The record described by this header.
    @type payload: L{IEncodableRecord} or L{None}

    @ivar auth: A L{bool} indicating whether this C{RRHeader} was parsed from
        an authoritative message.
    """

    compareAttributes = ("name", "type", "cls", "ttl", "payload", "auth")

    fmt = "!HHIH"

    rdlength = None

    cachedResponse = None

    def __init__(
        self,
        name: Union[bytes, str] = b"",
        type: int = A,
        cls: int = IN,
        ttl: SupportsInt = 0,
        payload: Optional[IEncodableRecord] = None,
        auth: bool = False,
    ):
        """
        @type name: L{bytes} or L{str}
        @param name: See L{RRHeader.name}

        @type type: L{int}
        @param type: The query type.

        @type cls: L{int}
        @param cls: The query class.

        @type ttl: L{int}
        @param ttl: Time to live for this record.  This will be
            converted to an L{int}.

        @type payload: L{IEncodableRecord} or L{None}
        @param payload: An optional Query Type specific data object.

        @raises TypeError: if the ttl cannot be converted to an L{int}.
        @raises ValueError: if the ttl is negative.
        @raises ValueError: if the payload type is not equal to the C{type}
                            argument.
        """
        payloadType = None if payload is None else payload.TYPE
        if payloadType is not None and payloadType != type:
            raise ValueError(
                "Payload type (%s) does not match given type (%s)"
                % (
                    QUERY_TYPES.get(payloadType, payloadType),
                    QUERY_TYPES.get(type, type),
                )
            )

        integralTTL = int(ttl)

        if integralTTL < 0:
            raise ValueError("TTL cannot be negative")

        self.name = Name(name)
        self.type = type
        self.cls = cls
        self.ttl = integralTTL
        self.payload = payload
        self.auth = auth

    def encode(self, strio, compDict=None):
        self.name.encode(strio, compDict)
        strio.write(struct.pack(self.fmt, self.type, self.cls, self.ttl, 0))
        if self.payload:
            prefix = strio.tell()
            self.payload.encode(strio, compDict)
            aft = strio.tell()
            strio.seek(prefix - 2, 0)
            strio.write(struct.pack("!H", aft - prefix))
            strio.seek(aft, 0)

    def decode(self, strio, length=None):
        self.name.decode(strio)
        l = struct.calcsize(self.fmt)
        buff = readPrecisely(strio, l)
        r = struct.unpack(self.fmt, buff)
        self.type, self.cls, self.ttl, self.rdlength = r

    def isAuthoritative(self):
        return self.auth

    def __str__(self) -> str:
        t = QUERY_TYPES.get(
            self.type, EXT_QUERIES.get(self.type, "UNKNOWN (%d)" % self.type)
        )
        c = QUERY_CLASSES.get(self.cls, "UNKNOWN (%d)" % self.cls)
        return "<RR name=%s type=%s class=%s ttl=%ds auth=%s>" % (
            self.name,
            t,
            c,
            self.ttl,
            self.auth and "True" or "False",
        )

    __repr__ = __str__


@implementer(IEncodableRecord)
class SimpleRecord(tputil.FancyStrMixin, tputil.FancyEqMixin):
    """
    A Resource Record which consists of a single RFC 1035 domain-name.

    @type name: L{Name}
    @ivar name: The name associated with this record.

    @type ttl: L{int}
    @ivar ttl: The maximum number of seconds which this record should be
        cached.
    """

    showAttributes = (("name", "name", "%s"), "ttl")
    compareAttributes = ("name", "ttl")

    TYPE: Optional[int] = None
    name = None

    def __init__(self, name=b"", ttl=None):
        """
        @param name: See L{SimpleRecord.name}
        @type name: L{bytes} or L{str}
        """
        self.name = Name(name)
        self.ttl = str2time(ttl)

    def encode(self, strio, compDict=None):
        self.name.encode(strio, compDict)

    def decode(self, strio, length=None):
        self.name = Name()
        self.name.decode(strio)

    def __hash__(self):
        return hash(self.name)


# Kinds of RRs - oh my!
class Record_NS(SimpleRecord):
    """
    An authoritative nameserver.
    """

    TYPE = NS
    fancybasename = "NS"


class Record_MD(SimpleRecord):
    """
    A mail destination.

    This record type is obsolete.

    @see: L{Record_MX}
    """

    TYPE = MD
    fancybasename = "MD"


class Record_MF(SimpleRecord):
    """
    A mail forwarder.

    This record type is obsolete.

    @see: L{Record_MX}
    """

    TYPE = MF
    fancybasename = "MF"


class Record_CNAME(SimpleRecord):
    """
    The canonical name for an alias.
    """

    TYPE = CNAME
    fancybasename = "CNAME"


class Record_MB(SimpleRecord):
    """
    A mailbox domain name.

    This is an experimental record type.
    """

    TYPE = MB
    fancybasename = "MB"


class Record_MG(SimpleRecord):
    """
    A mail group member.

    This is an experimental record type.
    """

    TYPE = MG
    fancybasename = "MG"


class Record_MR(SimpleRecord):
    """
    A mail rename domain name.

    This is an experimental record type.
    """

    TYPE = MR
    fancybasename = "MR"


class Record_PTR(SimpleRecord):
    """
    A domain name pointer.
    """

    TYPE = PTR
    fancybasename = "PTR"


class Record_DNAME(SimpleRecord):
    """
    A non-terminal DNS name redirection.

    This record type provides the capability to map an entire subtree of the
    DNS name space to another domain.  It differs from the CNAME record which
    maps a single node of the name space.

    @see: U{http://www.faqs.org/rfcs/rfc2672.html}
    @see: U{http://www.faqs.org/rfcs/rfc3363.html}
    """

    TYPE = DNAME
    fancybasename = "DNAME"


@implementer(IEncodableRecord)
class Record_A(tputil.FancyEqMixin):
    """
    An IPv4 host address.

    @type address: L{bytes}
    @ivar address: The packed network-order representation of the IPv4 address
        associated with this record.

    @type ttl: L{int}
    @ivar ttl: The maximum number of seconds which this record should be
        cached.
    """

    compareAttributes = ("address", "ttl")

    TYPE = A
    address = None

    def __init__(self, address="0.0.0.0", ttl=None):
        """
        @type address: L{bytes} or L{str}
        @param address: The IPv4 address associated with this record, in
            quad-dotted notation.
        """
        if isinstance(address, bytes):
            address = address.decode("ascii")

        address = socket.inet_aton(address)
        self.address = address
        self.ttl = str2time(ttl)

    def encode(self, strio, compDict=None):
        strio.write(self.address)

    def decode(self, strio, length=None):
        self.address = readPrecisely(strio, 4)

    def __hash__(self):
        return hash(self.address)

    def __str__(self) -> str:
        return f"<A address={self.dottedQuad()} ttl={self.ttl}>"

    __repr__ = __str__

    def dottedQuad(self):
        return socket.inet_ntoa(self.address)


@implementer(IEncodableRecord)
class Record_SOA(tputil.FancyEqMixin, tputil.FancyStrMixin):
    """
    Marks the start of a zone of authority.

    This record describes parameters which are shared by all records within a
    particular zone.

    @type mname: L{Name}
    @ivar mname: The domain-name of the name server that was the original or
        primary source of data for this zone.

    @type rname: L{Name}
    @ivar rname: A domain-name which specifies the mailbox of the person
        responsible for this zone.

    @type serial: L{int}
    @ivar serial: The unsigned 32 bit version number of the original copy of
        the zone.  Zone transfers preserve this value.  This value wraps and
        should be compared using sequence space arithmetic.

    @type refresh: L{int}
    @ivar refresh: A 32 bit time interval before the zone should be refreshed.

    @type minimum: L{int}
    @ivar minimum: The unsigned 32 bit minimum TTL field that should be
        exported with any RR from this zone.

    @type expire: L{int}
    @ivar expire: A 32 bit time value that specifies the upper limit on the
        time interval that can elapse before the zone is no longer
        authoritative.

    @type retry: L{int}
    @ivar retry: A 32 bit time interval that should elapse before a failed
        refresh should be retried.

    @type ttl: L{int}
    @ivar ttl: The default TTL to use for records served from this zone.
    """

    fancybasename = "SOA"
    compareAttributes = (
        "serial",
        "mname",
        "rname",
        "refresh",
        "expire",
        "retry",
        "minimum",
        "ttl",
    )
    showAttributes = (
        ("mname", "mname", "%s"),
        ("rname", "rname", "%s"),
        "serial",
        "refresh",
        "retry",
        "expire",
        "minimum",
        "ttl",
    )

    TYPE = SOA

    def __init__(
        self,
        mname=b"",
        rname=b"",
        serial=0,
        refresh=0,
        retry=0,
        expire=0,
        minimum=0,
        ttl=None,
    ):
        """
        @param mname: See L{Record_SOA.mname}
        @type mname: L{bytes} or L{str}

        @param rname: See L{Record_SOA.rname}
        @type rname: L{bytes} or L{str}
        """
        self.mname, self.rname = Name(mname), Name(rname)
        self.serial, self.refresh = str2time(serial), str2time(refresh)
        self.minimum, self.expire = str2time(minimum), str2time(expire)
        self.retry = str2time(retry)
        self.ttl = str2time(ttl)

    def encode(self, strio, compDict=None):
        self.mname.encode(strio, compDict)
        self.rname.encode(strio, compDict)
        strio.write(
            struct.pack(
                "!LlllL",
                self.serial,
                self.refresh,
                self.retry,
                self.expire,
                self.minimum,
            )
        )

    def decode(self, strio, length=None):
        self.mname, self.rname = Name(), Name()
        self.mname.decode(strio)
        self.rname.decode(strio)
        r = struct.unpack("!LlllL", readPrecisely(strio, 20))
        self.serial, self.refresh, self.retry, self.expire, self.minimum = r

    def __hash__(self):
        return hash(
            (self.serial, self.mname, self.rname, self.refresh, self.expire, self.retry)
        )


@implementer(IEncodableRecord)
class Record_NULL(tputil.FancyStrMixin, tputil.FancyEqMixin):
    """
    A null record.

    This is an experimental record type.

    @type ttl: L{int}
    @ivar ttl: The maximum number of seconds which this record should be
        cached.
    """

    fancybasename = "NULL"
    showAttributes = (("payload", _nicebytes), "ttl")
    compareAttributes = ("payload", "ttl")

    TYPE = NULL

    def __init__(self, payload=None, ttl=None):
        self.payload = payload
        self.ttl = str2time(ttl)

    def encode(self, strio, compDict=None):
        strio.write(self.payload)

    def decode(self, strio, length=None):
        self.payload = readPrecisely(strio, length)

    def __hash__(self):
        return hash(self.payload)


@implementer(IEncodableRecord)
class Record_WKS(tputil.FancyEqMixin, tputil.FancyStrMixin):
    """
    A well known service description.

    This record type is obsolete.  See L{Record_SRV}.

    @type address: L{bytes}
    @ivar address: The packed network-order representation of the IPv4 address
        associated with this record.

    @type protocol: L{int}
    @ivar protocol: The 8 bit IP protocol number for which this service map is
        relevant.

    @type map: L{bytes}
    @ivar map: A bitvector indicating the services available at the specified
        address.

    @type ttl: L{int}
    @ivar ttl: The maximum number of seconds which this record should be
        cached.
    """

    fancybasename = "WKS"
    compareAttributes = ("address", "protocol", "map", "ttl")
    showAttributes = [("_address", "address", "%s"), "protocol", "ttl"]

    TYPE = WKS

    @property
    def _address(self):
        return socket.inet_ntoa(self.address)

    def __init__(self, address="0.0.0.0", protocol=0, map=b"", ttl=None):
        """
        @type address: L{bytes} or L{str}
        @param address: The IPv4 address associated with this record, in
            quad-dotted notation.
        """
        if isinstance(address, bytes):
            address = address.decode("idna")

        self.address = socket.inet_aton(address)
        self.protocol, self.map = protocol, map
        self.ttl = str2time(ttl)

    def encode(self, strio, compDict=None):
        strio.write(self.address)
        strio.write(struct.pack("!B", self.protocol))
        strio.write(self.map)

    def decode(self, strio, length=None):
        self.address = readPrecisely(strio, 4)
        self.protocol = struct.unpack("!B", readPrecisely(strio, 1))[0]
        self.map = readPrecisely(strio, length - 5)

    def __hash__(self):
        return hash((self.address, self.protocol, self.map))


@implementer(IEncodableRecord)
class Record_AAAA(tputil.FancyEqMixin, tputil.FancyStrMixin):
    """
    An IPv6 host address.

    @type address: L{bytes}
    @ivar address: The packed network-order representation of the IPv6 address
        associated with this record.

    @type ttl: L{int}
    @ivar ttl: The maximum number of seconds which this record should be
        cached.

    @see: U{http://www.faqs.org/rfcs/rfc1886.html}
    """

    TYPE = AAAA

    fancybasename = "AAAA"
    showAttributes = (("_address", "address", "%s"), "ttl")
    compareAttributes = ("address", "ttl")

    @property
    def _address(self):
        return socket.inet_ntop(AF_INET6, self.address)

    def __init__(self, address="::", ttl=None):
        """
        @type address: L{bytes} or L{str}
        @param address: The IPv6 address for this host, in RFC 2373 format.
        """
        if isinstance(address, bytes):
            address = address.decode("idna")

        self.address = socket.inet_pton(AF_INET6, address)
        self.ttl = str2time(ttl)

    def encode(self, strio, compDict=None):
        strio.write(self.address)

    def decode(self, strio, length=None):
        self.address = readPrecisely(strio, 16)

    def __hash__(self):
        return hash(self.address)


@implementer(IEncodableRecord)
class Record_A6(tputil.FancyStrMixin, tputil.FancyEqMixin):
    """
    An IPv6 address.

    This is an experimental record type.

    @type prefixLen: L{int}
    @ivar prefixLen: The length of the suffix.

    @type suffix: L{bytes}
    @ivar suffix: An IPv6 address suffix in network order.

    @type prefix: L{Name}
    @ivar prefix: If specified, a name which will be used as a prefix for other
        A6 records.

    @type bytes: L{int}
    @ivar bytes: The length of the prefix.

    @type ttl: L{int}
    @ivar ttl: The maximum number of seconds which this record should be
        cached.

    @see: U{http://www.faqs.org/rfcs/rfc2874.html}
    @see: U{http://www.faqs.org/rfcs/rfc3363.html}
    @see: U{http://www.faqs.org/rfcs/rfc3364.html}
    """

    TYPE = A6

    fancybasename = "A6"
    showAttributes = (("_suffix", "suffix", "%s"), ("prefix", "prefix", "%s"), "ttl")
    compareAttributes = ("prefixLen", "prefix", "suffix", "ttl")

    @property
    def _suffix(self):
        return socket.inet_ntop(AF_INET6, self.suffix)

    def __init__(
        self,
        prefixLen: int = 0,
        suffix: bytes | str = "::",
        prefix: bytes | str = b"",
        ttl: Union[str, bytes, int, None] = None,
    ):
        """
        @param suffix: An IPv6 address suffix in in RFC 2373 format.
        @type suffix: L{bytes} or L{str}

        @param prefix: An IPv6 address prefix for other A6 records.
        @type prefix: L{bytes} or L{str}
        """
        if isinstance(suffix, bytes):
            suffix = suffix.decode("idna")

        self.prefixLen = prefixLen
        self.suffix = socket.inet_pton(AF_INET6, suffix)
        self.prefix = Name(prefix)
        self.bytes = int((128 - self.prefixLen) / 8.0)
        self.ttl = str2time(ttl)

    def encode(self, strio, compDict=None):
        strio.write(struct.pack("!B", self.prefixLen))
        if self.bytes:
            strio.write(self.suffix[-self.bytes :])
        if self.prefixLen:
            # This may not be compressed
            self.prefix.encode(strio, None)

    def decode(self, strio, length=None):
        self.prefixLen = struct.unpack("!B", readPrecisely(strio, 1))[0]
        self.bytes = int((128 - self.prefixLen) / 8.0)
        if self.bytes:
            self.suffix = b"\x00" * (16 - self.bytes) + readPrecisely(strio, self.bytes)
        if self.prefixLen:
            self.prefix.decode(strio)

    def __eq__(self, other: object) -> bool:
        if isinstance(other, Record_A6):
            return (
                self.prefixLen == other.prefixLen
                and self.suffix[-self.bytes :] == other.suffix[-self.bytes :]
                and self.prefix == other.prefix
                and self.ttl == other.ttl
            )
        return NotImplemented

    def __hash__(self):
        return hash((self.prefixLen, self.suffix[-self.bytes :], self.prefix))

    def __str__(self) -> str:
        return "<A6 %s %s (%d) ttl=%s>" % (
            self.prefix,
            socket.inet_ntop(AF_INET6, self.suffix),
            self.prefixLen,
            self.ttl,
        )


@implementer(IEncodableRecord)
class Record_SRV(tputil.FancyEqMixin, tputil.FancyStrMixin):
    """
    The location of the server(s) for a specific protocol and domain.

    This is an experimental record type.

    @type priority: L{int}
    @ivar priority: The priority of this target host.  A client MUST attempt to
        contact the target host with the lowest-numbered priority it can reach;
        target hosts with the same priority SHOULD be tried in an order defined
        by the weight field.

    @type weight: L{int}
    @ivar weight: Specifies a relative weight for entries with the same
        priority. Larger weights SHOULD be given a proportionately higher
        probability of being selected.

    @type port: L{int}
    @ivar port: The port on this target host of this service.

    @type target: L{Name}
    @ivar target: The domain name of the target host.  There MUST be one or
        more address records for this name, the name MUST NOT be an alias (in
        the sense of RFC 1034 or RFC 2181).  Implementors are urged, but not
        required, to return the address record(s) in the Additional Data
        section.  Unless and until permitted by future standards action, name
        compression is not to be used for this field.

    @type ttl: L{int}
    @ivar ttl: The maximum number of seconds which this record should be
        cached.

    @see: U{http://www.faqs.org/rfcs/rfc2782.html}
    """

    TYPE = SRV

    fancybasename = "SRV"
    compareAttributes = ("priority", "weight", "target", "port", "ttl")
    showAttributes = ("priority", "weight", ("target", "target", "%s"), "port", "ttl")

    def __init__(self, priority=0, weight=0, port=0, target=b"", ttl=None):
        """
        @param target: See L{Record_SRV.target}
        @type target: L{bytes} or L{str}
        """
        self.priority = int(priority)
        self.weight = int(weight)
        self.port = int(port)
        self.target = Name(target)
        self.ttl = str2time(ttl)

    def encode(self, strio, compDict=None):
        strio.write(struct.pack("!HHH", self.priority, self.weight, self.port))
        # This can't be compressed
        self.target.encode(strio, None)

    def decode(self, strio, length=None):
        r = struct.unpack("!HHH", readPrecisely(strio, struct.calcsize("!HHH")))
        self.priority, self.weight, self.port = r
        self.target = Name()
        self.target.decode(strio)

    def __hash__(self):
        return hash((self.priority, self.weight, self.port, self.target))


@implementer(IEncodableRecord)
class Record_NAPTR(tputil.FancyEqMixin, tputil.FancyStrMixin):
    """
    The location of the server(s) for a specific protocol and domain.

    @type order: L{int}
    @ivar order: An integer specifying the order in which the NAPTR records
        MUST be processed to ensure the correct ordering of rules.  Low numbers
        are processed before high numbers.

    @type preference: L{int}
    @ivar preference: An integer that specifies the order in which NAPTR
        records with equal "order" values SHOULD be processed, low numbers
        being processed before high numbers.

    @type flag: L{Charstr}
    @ivar flag: A <character-string> containing flags to control aspects of the
        rewriting and interpretation of the fields in the record.  Flags
        are single characters from the set [A-Z0-9].  The case of the alphabetic
        characters is not significant.

        At this time only four flags, "S", "A", "U", and "P", are defined.

    @type service: L{Charstr}
    @ivar service: Specifies the service(s) available down this rewrite path.
        It may also specify the particular protocol that is used to talk with a
        service.  A protocol MUST be specified if the flags field states that
        the NAPTR is terminal.

    @type regexp: L{Charstr}
    @ivar regexp: A STRING containing a substitution expression that is applied
        to the original string held by the client in order to construct the
        next domain name to lookup.

    @type replacement: L{Name}
    @ivar replacement: The next NAME to query for NAPTR, SRV, or address
        records depending on the value of the flags field.  This MUST be a
        fully qualified domain-name.

    @type ttl: L{int}
    @ivar ttl: The maximum number of seconds which this record should be
        cached.

    @see: U{http://www.faqs.org/rfcs/rfc2915.html}
    """

    TYPE = NAPTR

    compareAttributes = (
        "order",
        "preference",
        "flags",
        "service",
        "regexp",
        "replacement",
    )
    fancybasename = "NAPTR"

    showAttributes = (
        "order",
        "preference",
        ("flags", "flags", "%s"),
        ("service", "service", "%s"),
        ("regexp", "regexp", "%s"),
        ("replacement", "replacement", "%s"),
        "ttl",
    )

    def __init__(
        self,
        order=0,
        preference=0,
        flags=b"",
        service=b"",
        regexp=b"",
        replacement=b"",
        ttl=None,
    ):
        """
        @param replacement: See L{Record_NAPTR.replacement}
        @type replacement: L{bytes} or L{str}
        """
        self.order = int(order)
        self.preference = int(preference)
        self.flags = Charstr(flags)
        self.service = Charstr(service)
        self.regexp = Charstr(regexp)
        self.replacement = Name(replacement)
        self.ttl = str2time(ttl)

    def encode(self, strio, compDict=None):
        strio.write(struct.pack("!HH", self.order, self.preference))
        # This can't be compressed
        self.flags.encode(strio, None)
        self.service.encode(strio, None)
        self.regexp.encode(strio, None)
        self.replacement.encode(strio, None)

    def decode(self, strio, length=None):
        r = struct.unpack("!HH", readPrecisely(strio, struct.calcsize("!HH")))
        self.order, self.preference = r
        self.flags = Charstr()
        self.service = Charstr()
        self.regexp = Charstr()
        self.replacement = Name()
        self.flags.decode(strio)
        self.service.decode(strio)
        self.regexp.decode(strio)
        self.replacement.decode(strio)

    def __hash__(self):
        return hash(
            (
                self.order,
                self.preference,
                self.flags,
                self.service,
                self.regexp,
                self.replacement,
            )
        )


@implementer(IEncodableRecord)
class Record_AFSDB(tputil.FancyStrMixin, tputil.FancyEqMixin):
    """
    Map from a domain name to the name of an AFS cell database server.

    @type subtype: L{int}
    @ivar subtype: In the case of subtype 1, the host has an AFS version 3.0
        Volume Location Server for the named AFS cell.  In the case of subtype
        2, the host has an authenticated name server holding the cell-root
        directory node for the named DCE/NCA cell.

    @type hostname: L{Name}
    @ivar hostname: The domain name of a host that has a server for the cell
        named by this record.

    @type ttl: L{int}
    @ivar ttl: The maximum number of seconds which this record should be
        cached.

    @see: U{http://www.faqs.org/rfcs/rfc1183.html}
    """

    TYPE = AFSDB

    fancybasename = "AFSDB"
    compareAttributes = ("subtype", "hostname", "ttl")
    showAttributes = ("subtype", ("hostname", "hostname", "%s"), "ttl")

    def __init__(self, subtype=0, hostname=b"", ttl=None):
        """
        @param hostname: See L{Record_AFSDB.hostname}
        @type hostname: L{bytes} or L{str}
        """
        self.subtype = int(subtype)
        self.hostname = Name(hostname)
        self.ttl = str2time(ttl)

    def encode(self, strio, compDict=None):
        strio.write(struct.pack("!H", self.subtype))
        self.hostname.encode(strio, compDict)

    def decode(self, strio, length=None):
        r = struct.unpack("!H", readPrecisely(strio, struct.calcsize("!H")))
        (self.subtype,) = r
        self.hostname.decode(strio)

    def __hash__(self):
        return hash((self.subtype, self.hostname))


@implementer(IEncodableRecord)
class Record_RP(tputil.FancyEqMixin, tputil.FancyStrMixin):
    """
    The responsible person for a domain.

    @type mbox: L{Name}
    @ivar mbox: A domain name that specifies the mailbox for the responsible
        person.

    @type txt: L{Name}
    @ivar txt: A domain name for which TXT RR's exist (indirection through
        which allows information sharing about the contents of this RP record).

    @type ttl: L{int}
    @ivar ttl: The maximum number of seconds which this record should be
        cached.

    @see: U{http://www.faqs.org/rfcs/rfc1183.html}
    """

    TYPE = RP

    fancybasename = "RP"
    compareAttributes = ("mbox", "txt", "ttl")
    showAttributes = (("mbox", "mbox", "%s"), ("txt", "txt", "%s"), "ttl")

    def __init__(self, mbox=b"", txt=b"", ttl=None):
        """
        @param mbox: See L{Record_RP.mbox}.
        @type mbox: L{bytes} or L{str}

        @param txt: See L{Record_RP.txt}
        @type txt: L{bytes} or L{str}
        """
        self.mbox = Name(mbox)
        self.txt = Name(txt)
        self.ttl = str2time(ttl)

    def encode(self, strio, compDict=None):
        self.mbox.encode(strio, compDict)
        self.txt.encode(strio, compDict)

    def decode(self, strio, length=None):
        self.mbox = Name()
        self.txt = Name()
        self.mbox.decode(strio)
        self.txt.decode(strio)

    def __hash__(self):
        return hash((self.mbox, self.txt))


@implementer(IEncodableRecord)
class Record_HINFO(tputil.FancyStrMixin, tputil.FancyEqMixin):
    """
    Host information.

    @type cpu: L{bytes}
    @ivar cpu: Specifies the CPU type.

    @type os: L{bytes}
    @ivar os: Specifies the OS.

    @type ttl: L{int}
    @ivar ttl: The maximum number of seconds which this record should be
        cached.
    """

    TYPE = HINFO

    fancybasename = "HINFO"
    showAttributes = (("cpu", _nicebytes), ("os", _nicebytes), "ttl")
    compareAttributes = ("cpu", "os", "ttl")

    def __init__(
        self,
        cpu: bytes = b"",
        os: bytes = b"",
        ttl: Union[str, bytes, int, None] = None,
    ):
        self.cpu, self.os = cpu, os
        self.ttl = str2time(ttl)

    def encode(self, strio, compDict=None):
        strio.write(struct.pack("!B", len(self.cpu)) + self.cpu)
        strio.write(struct.pack("!B", len(self.os)) + self.os)

    def decode(self, strio, length=None):
        cpu = struct.unpack("!B", readPrecisely(strio, 1))[0]
        self.cpu = readPrecisely(strio, cpu)
        os = struct.unpack("!B", readPrecisely(strio, 1))[0]
        self.os = readPrecisely(strio, os)

    def __eq__(self, other: object) -> bool:
        if isinstance(other, Record_HINFO):
            return (
                self.os.lower() == other.os.lower()
                and self.cpu.lower() == other.cpu.lower()
                and self.ttl == other.ttl
            )
        return NotImplemented

    def __hash__(self):
        return hash((self.os.lower(), self.cpu.lower()))


@implementer(IEncodableRecord)
class Record_MINFO(tputil.FancyEqMixin, tputil.FancyStrMixin):
    """
    Mailbox or mail list information.

    This is an experimental record type.

    @type rmailbx: L{Name}
    @ivar rmailbx: A domain-name which specifies a mailbox which is responsible
        for the mailing list or mailbox.  If this domain name names the root,
        the owner of the MINFO RR is responsible for itself.

    @type emailbx: L{Name}
    @ivar emailbx: A domain-name which specifies a mailbox which is to receive
        error messages related to the mailing list or mailbox specified by the
        owner of the MINFO record.  If this domain name names the root, errors
        should be returned to the sender of the message.

    @type ttl: L{int}
    @ivar ttl: The maximum number of seconds which this record should be
        cached.
    """

    TYPE = MINFO

    rmailbx = None
    emailbx = None

    fancybasename = "MINFO"
    compareAttributes = ("rmailbx", "emailbx", "ttl")
    showAttributes = (
        ("rmailbx", "responsibility", "%s"),
        ("emailbx", "errors", "%s"),
        "ttl",
    )

    def __init__(self, rmailbx=b"", emailbx=b"", ttl=None):
        """
        @param rmailbx: See L{Record_MINFO.rmailbx}.
        @type rmailbx: L{bytes} or L{str}

        @param emailbx: See L{Record_MINFO.rmailbx}.
        @type emailbx: L{bytes} or L{str}
        """
        self.rmailbx, self.emailbx = Name(rmailbx), Name(emailbx)
        self.ttl = str2time(ttl)

    def encode(self, strio, compDict=None):
        self.rmailbx.encode(strio, compDict)
        self.emailbx.encode(strio, compDict)

    def decode(self, strio, length=None):
        self.rmailbx, self.emailbx = Name(), Name()
        self.rmailbx.decode(strio)
        self.emailbx.decode(strio)

    def __hash__(self):
        return hash((self.rmailbx, self.emailbx))


@implementer(IEncodableRecord)
class Record_MX(tputil.FancyStrMixin, tputil.FancyEqMixin):
    """
    Mail exchange.

    @type preference: L{int}
    @ivar preference: Specifies the preference given to this RR among others at
        the same owner.  Lower values are preferred.

    @type name: L{Name}
    @ivar name: A domain-name which specifies a host willing to act as a mail
        exchange.

    @type ttl: L{int}
    @ivar ttl: The maximum number of seconds which this record should be
        cached.
    """

    TYPE = MX

    fancybasename = "MX"
    compareAttributes = ("preference", "name", "ttl")
    showAttributes = ("preference", ("name", "name", "%s"), "ttl")

    def __init__(self, preference=0, name=b"", ttl=None, **kwargs):
        """
        @param name: See L{Record_MX.name}.
        @type name: L{bytes} or L{str}
        """
        self.preference = int(preference)
        self.name = Name(kwargs.get("exchange", name))
        self.ttl = str2time(ttl)

    def encode(self, strio, compDict=None):
        strio.write(struct.pack("!H", self.preference))
        self.name.encode(strio, compDict)

    def decode(self, strio, length=None):
        self.preference = struct.unpack("!H", readPrecisely(strio, 2))[0]
        self.name = Name()
        self.name.decode(strio)

    def __hash__(self):
        return hash((self.preference, self.name))


@implementer(IEncodableRecord)
class Record_SSHFP(tputil.FancyEqMixin, tputil.FancyStrMixin):
    """
    A record containing the fingerprint of an SSH key.

    @type algorithm: L{int}
    @ivar algorithm: The SSH key's algorithm, such as L{ALGORITHM_RSA}.
        Note that the numbering used for SSH key algorithms is specific
        to the SSHFP record, and is not the same as the numbering
        used for KEY or SIG records.

    @type fingerprintType: L{int}
    @ivar fingerprintType: The fingerprint type,
        such as L{FINGERPRINT_TYPE_SHA256}.

    @type fingerprint: L{bytes}
    @ivar fingerprint: The key's fingerprint, e.g. a 32-byte SHA-256 digest.

    @cvar ALGORITHM_RSA: The algorithm value for C{ssh-rsa} keys.
    @cvar ALGORITHM_DSS: The algorithm value for C{ssh-dss} keys.
    @cvar ALGORITHM_ECDSA: The algorithm value for C{ecdsa-sha2-*} keys.
    @cvar ALGORITHM_Ed25519: The algorithm value for C{ed25519} keys.

    @cvar FINGERPRINT_TYPE_SHA1: The type for SHA-1 fingerprints.
    @cvar FINGERPRINT_TYPE_SHA256: The type for SHA-256 fingerprints.

    @see: U{RFC 4255 <https://tools.ietf.org/html/rfc4255>}
          and
          U{RFC 6594 <https://tools.ietf.org/html/rfc6594>}
    """

    fancybasename = "SSHFP"
    compareAttributes = ("algorithm", "fingerprintType", "fingerprint", "ttl")
    showAttributes = ("algorithm", "fingerprintType", "fingerprint")

    TYPE = SSHFP

    ALGORITHM_RSA = 1
    ALGORITHM_DSS = 2
    ALGORITHM_ECDSA = 3
    ALGORITHM_Ed25519 = 4

    FINGERPRINT_TYPE_SHA1 = 1
    FINGERPRINT_TYPE_SHA256 = 2

    def __init__(self, algorithm=0, fingerprintType=0, fingerprint=b"", ttl=0):
        self.algorithm = algorithm
        self.fingerprintType = fingerprintType
        self.fingerprint = fingerprint
        self.ttl = ttl

    def encode(self, strio, compDict=None):
        strio.write(struct.pack("!BB", self.algorithm, self.fingerprintType))
        strio.write(self.fingerprint)

    def decode(self, strio, length=None):
        r = struct.unpack("!BB", readPrecisely(strio, 2))
        (self.algorithm, self.fingerprintType) = r
        self.fingerprint = readPrecisely(strio, length - 2)

    def __hash__(self):
        return hash((self.algorithm, self.fingerprintType, self.fingerprint))


@implementer(IEncodableRecord)
class Record_TXT(tputil.FancyEqMixin, tputil.FancyStrMixin):
    """
    Freeform text.

    @type data: L{list} of L{bytes}
    @ivar data: Freeform text which makes up this record.

    @type ttl: L{int}
    @ivar ttl: The maximum number of seconds which this record should be cached.
    """

    TYPE = TXT

    fancybasename = "TXT"
    showAttributes = (("data", _nicebyteslist), "ttl")
    compareAttributes = ("data", "ttl")

    def __init__(self, *data, **kw):
        self.data = list(data)
        # arg man python sucks so bad
        self.ttl = str2time(kw.get("ttl", None))

    def encode(self, strio, compDict=None):
        for d in self.data:
            strio.write(struct.pack("!B", len(d)) + d)

    def decode(self, strio, length=None):
        soFar = 0
        self.data = []
        while soFar < length:
            L = struct.unpack("!B", readPrecisely(strio, 1))[0]
            self.data.append(readPrecisely(strio, L))
            soFar += L + 1
        if soFar != length:
            log.msg(
                "Decoded %d bytes in %s record, but rdlength is %d"
                % (soFar, self.fancybasename, length)
            )

    def __hash__(self):
        return hash(tuple(self.data))


@implementer(IEncodableRecord)
class UnknownRecord(tputil.FancyEqMixin, tputil.FancyStrMixin):
    """
    Encapsulate the wire data for unknown record types so that they can
    pass through the system unchanged.

    @type data: L{bytes}
    @ivar data: Wire data which makes up this record.

    @type ttl: L{int}
    @ivar ttl: The maximum number of seconds which this record should be cached.

    @since: 11.1
    """

    TYPE = None

    fancybasename = "UNKNOWN"
    compareAttributes = ("data", "ttl")
    showAttributes = (("data", _nicebytes), "ttl")

    def __init__(self, data=b"", ttl=None):
        self.data = data
        self.ttl = str2time(ttl)

    def encode(self, strio, compDict=None):
        """
        Write the raw bytes corresponding to this record's payload to the
        stream.
        """
        strio.write(self.data)

    def decode(self, strio, length=None):
        """
        Load the bytes which are part of this record from the stream and store
        them unparsed and unmodified.
        """
        if length is None:
            raise Exception("must know length for unknown record types")
        self.data = readPrecisely(strio, length)

    def __hash__(self):
        return hash((self.data, self.ttl))


class Record_SPF(Record_TXT):
    """
    Structurally, freeform text. Semantically, a policy definition, formatted
    as defined in U{rfc 4408<http://www.faqs.org/rfcs/rfc4408.html>}.

    @type data: L{list} of L{bytes}
    @ivar data: Freeform text which makes up this record.

    @type ttl: L{int}
    @ivar ttl: The maximum number of seconds
               which this record should be cached.
    """

    TYPE = SPF
    fancybasename = "SPF"


@implementer(IEncodableRecord)
class Record_TSIG(tputil.FancyEqMixin, tputil.FancyStrMixin):
    """
    A transaction signature, encapsulated in a RR, as described
    in U{RFC 2845 <https://tools.ietf.org/html/rfc2845>}.

    @type algorithm: L{Name}
    @ivar algorithm: The name of the signature or MAC algorithm.

    @type timeSigned: L{int}
    @ivar timeSigned: Signing time, as seconds from the POSIX epoch.

    @type fudge: L{int}
    @ivar fudge: Allowable time skew, in seconds.

    @type MAC: L{bytes}
    @ivar MAC: The message digest or signature.

    @type originalID: L{int}
    @ivar originalID: A message ID.

    @type error: L{int}
    @ivar error: An error code (extended C{RCODE}) carried
          in exceptional cases.

    @type otherData: L{bytes}
    @ivar otherData: Other data carried in exceptional cases.

    """

    fancybasename = "TSIG"
    compareAttributes = (
        "algorithm",
        "timeSigned",
        "fudge",
        "MAC",
        "originalID",
        "error",
        "otherData",
        "ttl",
    )
    showAttributes = ["algorithm", "timeSigned", "MAC", "error", "otherData"]

    TYPE = TSIG

    def __init__(
        self,
        algorithm=None,
        timeSigned=None,
        fudge=5,
        MAC=None,
        originalID=0,
        error=OK,
        otherData=b"",
        ttl=0,
    ):
        # All of our init arguments have to have defaults, because of
        # the way IEncodable and Message.parseRecords() work, but for
        # some of our arguments there is no reasonable default; we use
        # invalid values here to prevent a user of this class from
        # relying on what's really an internal implementation detail.
        self.algorithm = None if algorithm is None else Name(algorithm)
        self.timeSigned = timeSigned
        self.fudge = str2time(fudge)
        self.MAC = MAC
        self.originalID = originalID
        self.error = error
        self.otherData = otherData
        self.ttl = ttl

    def encode(self, strio, compDict=None):
        self.algorithm.encode(strio, compDict)
        strio.write(struct.pack("!Q", self.timeSigned)[2:])  # 48-bit number
        strio.write(struct.pack("!HH", self.fudge, len(self.MAC)))
        strio.write(self.MAC)
        strio.write(
            struct.pack("!HHH", self.originalID, self.error, len(self.otherData))
        )
        strio.write(self.otherData)

    def decode(self, strio, length=None):
        algorithm = Name()
        algorithm.decode(strio)
        self.algorithm = algorithm
        fields = struct.unpack("!QHH", b"\x00\x00" + readPrecisely(strio, 10))
        self.timeSigned, self.fudge, macLength = fields
        self.MAC = readPrecisely(strio, macLength)
        fields = struct.unpack("!HHH", readPrecisely(strio, 6))
        self.originalID, self.error, otherLength = fields
        self.otherData = readPrecisely(strio, otherLength)

    def __hash__(self):
        return hash((self.algorithm, self.timeSigned, self.MAC, self.originalID))


def _responseFromMessage(responseConstructor, message, **kwargs):
    """
    Generate a L{Message} like instance suitable for use as the response to
    C{message}.

    The C{queries}, C{id} attributes will be copied from C{message} and the
    C{answer} flag will be set to L{True}.

    @param responseConstructor: A response message constructor with an
         initializer signature matching L{dns.Message.__init__}.
    @type responseConstructor: C{callable}

    @param message: A request message.
    @type message: L{Message}

    @param kwargs: Keyword arguments which will be passed to the initialiser
        of the response message.
    @type kwargs: L{dict}

    @return: A L{Message} like response instance.
    @rtype: C{responseConstructor}
    """
    response = responseConstructor(id=message.id, answer=True, **kwargs)
    response.queries = message.queries[:]
    return response


def _getDisplayableArguments(obj, alwaysShow, fieldNames):
    """
    Inspect the function signature of C{obj}'s constructor,
    and get a list of which arguments should be displayed.
    This is a helper function for C{_compactRepr}.

    @param obj: The instance whose repr is being generated.
    @param alwaysShow: A L{list} of field names which should always be shown.
    @param fieldNames: A L{list} of field attribute names which should be shown
        if they have non-default values.
    @return: A L{list} of displayable arguments.
    """
    displayableArgs = []
    # Get the argument names and values from the constructor.
    signature = inspect.signature(obj.__class__.__init__)
    for name in fieldNames:
        defaultValue = signature.parameters[name].default
        fieldValue = getattr(obj, name, defaultValue)
        if (name in alwaysShow) or (fieldValue != defaultValue):
            displayableArgs.append(f" {name}={fieldValue!r}")

    return displayableArgs


def _compactRepr(
    obj: object,
    alwaysShow: Sequence[str] | None = None,
    flagNames: Sequence[str] | None = None,
    fieldNames: Sequence[str] | None = None,
    sectionNames: Sequence[str] | None = None,
) -> str:
    """
    Return a L{str} representation of C{obj} which only shows fields with
    non-default values, flags which are True and sections which have been
    explicitly set.

    @param obj: The instance whose repr is being generated.
    @param alwaysShow: A L{list} of field names which should always be shown.
    @param flagNames: A L{list} of flag attribute names which should be shown if
        they are L{True}.
    @param fieldNames: A L{list} of field attribute names which should be shown
        if they have non-default values.
    @param sectionNames: A L{list} of section attribute names which should be
        shown if they have been assigned a value.

    @return: A L{str} representation of C{obj}.
    """
    if alwaysShow is None:
        alwaysShow = []

    if flagNames is None:
        flagNames = []

    if fieldNames is None:
        fieldNames = []

    if sectionNames is None:
        sectionNames = []

    setFlags = []
    for name in flagNames:
        if name in alwaysShow or getattr(obj, name, False) == True:
            setFlags.append(name)

    displayableArgs = _getDisplayableArguments(obj, alwaysShow, fieldNames)
    out = ["<", obj.__class__.__name__] + displayableArgs

    if setFlags:
        out.append(" flags={}".format(",".join(setFlags)))

    for name in sectionNames:
        section = getattr(obj, name, [])
        if section:
            out.append(f" {name}={section!r}")

    out.append(">")

    return "".join(out)


class Message(tputil.FancyEqMixin):
    """
    L{Message} contains all the information represented by a single
    DNS request or response.

    @ivar id: See L{__init__}
    @ivar answer: See L{__init__}
    @ivar opCode: See L{__init__}
    @ivar recDes: See L{__init__}
    @ivar recAv: See L{__init__}
    @ivar auth: See L{__init__}
    @ivar rCode: See L{__init__}
    @ivar trunc: See L{__init__}
    @ivar maxSize: See L{__init__}
    @ivar authenticData: See L{__init__}
    @ivar checkingDisabled: See L{__init__}

    @ivar queries: The queries which are being asked of or answered by
        DNS server.
    @type queries: L{list} of L{Query}

    @ivar answers: Records containing the answers to C{queries} if
        this is a response message.
    @type answers: L{list} of L{RRHeader}

    @ivar authority: Records containing information about the
        authoritative DNS servers for the names in C{queries}.
    @type authority: L{list} of L{RRHeader}

    @ivar additional: Records containing IP addresses of host names
        in C{answers} and C{authority}.
    @type additional: L{list} of L{RRHeader}

    @ivar _flagNames: The names of attributes representing the flag header
        fields.
    @ivar _fieldNames: The names of attributes representing non-flag fixed
        header fields.
    @ivar _sectionNames: The names of attributes representing the record
        sections of this message.
    """

    compareAttributes = (
        "id",
        "answer",
        "opCode",
        "recDes",
        "recAv",
        "auth",
        "rCode",
        "trunc",
        "maxSize",
        "authenticData",
        "checkingDisabled",
        "queries",
        "answers",
        "authority",
        "additional",
    )

    headerFmt = "!H2B4H"
    headerSize = struct.calcsize(headerFmt)

    # Question, answer, additional, and nameserver lists
    queries = answers = add = ns = None

    def __init__(
        self,
        id=0,
        answer=0,
        opCode=0,
        recDes=0,
        recAv=0,
        auth=0,
        rCode=OK,
        trunc=0,
        maxSize=512,
        authenticData=0,
        checkingDisabled=0,
    ):
        """
        @param id: A 16 bit identifier assigned by the program that
            generates any kind of query.  This identifier is copied to
            the corresponding reply and can be used by the requester
            to match up replies to outstanding queries.
        @type id: L{int}

        @param answer: A one bit field that specifies whether this
            message is a query (0), or a response (1).
        @type answer: L{int}

        @param opCode: A four bit field that specifies kind of query in
            this message.  This value is set by the originator of a query
            and copied into the response.
        @type opCode: L{int}

        @param recDes: Recursion Desired - this bit may be set in a
            query and is copied into the response.  If RD is set, it
            directs the name server to pursue the query recursively.
            Recursive query support is optional.
        @type recDes: L{int}

        @param recAv: Recursion Available - this bit is set or cleared
            in a response and denotes whether recursive query support
            is available in the name server.
        @type recAv: L{int}

        @param auth: Authoritative Answer - this bit is valid in
            responses and specifies that the responding name server
            is an authority for the domain name in question section.
        @type auth: L{int}

        @ivar rCode: A response code, used to indicate success or failure in a
            message which is a response from a server to a client request.
        @type rCode: C{0 <= int < 16}

        @param trunc: A flag indicating that this message was
            truncated due to length greater than that permitted on the
            transmission channel.
        @type trunc: L{int}

        @param maxSize: The requestor's UDP payload size is the number
            of octets of the largest UDP payload that can be
            reassembled and delivered in the requestor's network
            stack.
        @type maxSize: L{int}

        @param authenticData: A flag indicating in a response that all
            the data included in the answer and authority portion of
            the response has been authenticated by the server
            according to the policies of that server.
            See U{RFC2535 section-6.1<https://tools.ietf.org/html/rfc2535#section-6.1>}.
        @type authenticData: L{int}

        @param checkingDisabled: A flag indicating in a query that
            pending (non-authenticated) data is acceptable to the
            resolver sending the query.
            See U{RFC2535 section-6.1<https://tools.ietf.org/html/rfc2535#section-6.1>}.
        @type authenticData: L{int}
        """
        self.maxSize = maxSize
        self.id = id
        self.answer = answer
        self.opCode = opCode
        self.auth = auth
        self.trunc = trunc
        self.recDes = recDes
        self.recAv = recAv
        self.rCode = rCode
        self.authenticData = authenticData
        self.checkingDisabled = checkingDisabled

        self.queries = []
        self.answers = []
        self.authority = []
        self.additional = []

    def __repr__(self) -> str:
        """
        Generate a repr of this L{Message}.

        Only includes the non-default fields and sections and only includes
        flags which are set. The C{id} is always shown.

        @return: The native string repr.
        """
        return _compactRepr(
            self,
            flagNames=(
                "answer",
                "auth",
                "trunc",
                "recDes",
                "recAv",
                "authenticData",
                "checkingDisabled",
            ),
            fieldNames=("id", "opCode", "rCode", "maxSize"),
            sectionNames=("queries", "answers", "authority", "additional"),
            alwaysShow=("id",),
        )

    def addQuery(self, name, type=ALL_RECORDS, cls=IN):
        """
        Add another query to this Message.

        @type name: L{bytes}
        @param name: The name to query.

        @type type: L{int}
        @param type: Query type

        @type cls: L{int}
        @param cls: Query class
        """
        self.queries.append(Query(name, type, cls))

    def encode(self, strio):
        compDict = {}
        body_tmp = BytesIO()
        for q in self.queries:
            q.encode(body_tmp, compDict)
        for q in self.answers:
            q.encode(body_tmp, compDict)
        for q in self.authority:
            q.encode(body_tmp, compDict)
        for q in self.additional:
            q.encode(body_tmp, compDict)
        body = body_tmp.getvalue()
        size = len(body) + self.headerSize
        if self.maxSize and size > self.maxSize:
            self.trunc = 1
            body = body[: self.maxSize - self.headerSize]
        byte3 = (
            ((self.answer & 1) << 7)
            | ((self.opCode & 0xF) << 3)
            | ((self.auth & 1) << 2)
            | ((self.trunc & 1) << 1)
            | (self.recDes & 1)
        )
        byte4 = (
            ((self.recAv & 1) << 7)
            | ((self.authenticData & 1) << 5)
            | ((self.checkingDisabled & 1) << 4)
            | (self.rCode & 0xF)
        )

        strio.write(
            struct.pack(
                self.headerFmt,
                self.id,
                byte3,
                byte4,
                len(self.queries),
                len(self.answers),
                len(self.authority),
                len(self.additional),
            )
        )
        strio.write(body)

    def decode(self, strio, length=None):
        self.maxSize = 0
        header = readPrecisely(strio, self.headerSize)
        r = struct.unpack(self.headerFmt, header)
        self.id, byte3, byte4, nqueries, nans, nns, nadd = r
        self.answer = (byte3 >> 7) & 1
        self.opCode = (byte3 >> 3) & 0xF
        self.auth = (byte3 >> 2) & 1
        self.trunc = (byte3 >> 1) & 1
        self.recDes = byte3 & 1
        self.recAv = (byte4 >> 7) & 1
        self.authenticData = (byte4 >> 5) & 1
        self.checkingDisabled = (byte4 >> 4) & 1
        self.rCode = byte4 & 0xF

        self.queries = []
        for i in range(nqueries):
            q = Query()
            try:
                q.decode(strio)
            except EOFError:
                return
            self.queries.append(q)

        items = ((self.answers, nans), (self.authority, nns), (self.additional, nadd))

        for l, n in items:
            self.parseRecords(l, n, strio)

    def parseRecords(self, list, num, strio):
        for i in range(num):
            header = RRHeader(auth=self.auth)
            try:
                header.decode(strio)
            except EOFError:
                return
            t = self.lookupRecordType(header.type)
            if not t:
                continue
            header.payload = t(ttl=header.ttl)
            try:
                header.payload.decode(strio, header.rdlength)
            except EOFError:
                return
            list.append(header)

    # Create a mapping from record types to their corresponding Record_*
    # classes.  This relies on the global state which has been created so
    # far in initializing this module (so don't define Record classes after
    # this).
    _recordTypes = {}
    for name in globals():
        if name.startswith("Record_"):
            _recordTypes[globals()[name].TYPE] = globals()[name]

    # Clear the iteration variable out of the class namespace so it
    # doesn't become an attribute.
    del name

    def lookupRecordType(self, type):
        """
        Retrieve the L{IRecord} implementation for the given record type.

        @param type: A record type, such as C{A} or L{NS}.
        @type type: L{int}

        @return: An object which implements L{IRecord} or L{None} if none
            can be found for the given type.
        @rtype: C{Type[IRecord]}
        """
        return self._recordTypes.get(type, UnknownRecord)

    def toStr(self):
        """
        Encode this L{Message} into a byte string in the format described by RFC
        1035.

        @rtype: L{bytes}
        """
        strio = BytesIO()
        self.encode(strio)
        return strio.getvalue()

    def fromStr(self, str):
        """
        Decode a byte string in the format described by RFC 1035 into this
        L{Message}.

        @param str: L{bytes}
        """
        strio = BytesIO(str)
        self.decode(strio)


class _EDNSMessage(tputil.FancyEqMixin):
    """
    An I{EDNS} message.

    Designed for compatibility with L{Message} but with a narrower public
    interface.

    Most importantly, L{_EDNSMessage.fromStr} will interpret and remove I{OPT}
    records that are present in the additional records section.

    The I{OPT} records are used to populate certain I{EDNS} specific attributes.

    L{_EDNSMessage.toStr} will add suitable I{OPT} records to the additional
    section to represent the extended EDNS information.

    @see: U{https://tools.ietf.org/html/rfc6891}

    @ivar id: See L{__init__}
    @ivar answer: See L{__init__}
    @ivar opCode: See L{__init__}
    @ivar auth: See L{__init__}
    @ivar trunc: See L{__init__}
    @ivar recDes: See L{__init__}
    @ivar recAv: See L{__init__}
    @ivar rCode: See L{__init__}
    @ivar ednsVersion: See L{__init__}
    @ivar dnssecOK: See L{__init__}
    @ivar authenticData: See L{__init__}
    @ivar checkingDisabled: See L{__init__}
    @ivar maxSize: See L{__init__}

    @ivar queries: See L{__init__}
    @ivar answers: See L{__init__}
    @ivar authority: See L{__init__}
    @ivar additional: See L{__init__}

    @ivar _messageFactory: A constructor of L{Message} instances. Called by
        C{_toMessage} and C{_fromMessage}.
    """

    compareAttributes = (
        "id",
        "answer",
        "opCode",
        "auth",
        "trunc",
        "recDes",
        "recAv",
        "rCode",
        "ednsVersion",
        "dnssecOK",
        "authenticData",
        "checkingDisabled",
        "maxSize",
        "queries",
        "answers",
        "authority",
        "additional",
    )

    _messageFactory = Message

    def __init__(
        self,
        id=0,
        answer=False,
        opCode=OP_QUERY,
        auth=False,
        trunc=False,
        recDes=False,
        recAv=False,
        rCode=0,
        ednsVersion=0,
        dnssecOK=False,
        authenticData=False,
        checkingDisabled=False,
        maxSize=512,
        queries=None,
        answers=None,
        authority=None,
        additional=None,
    ):
        """
        Construct a new L{_EDNSMessage}

        @see: U{RFC1035 section-4.1.1<https://tools.ietf.org/html/rfc1035#section-4.1.1>}
        @see: U{RFC2535 section-6.1<https://tools.ietf.org/html/rfc2535#section-6.1>}
        @see: U{RFC3225 section-3<https://tools.ietf.org/html/rfc3225#section-3>}
        @see: U{RFC6891 section-6.1.3<https://tools.ietf.org/html/rfc6891#section-6.1.3>}

        @param id: A 16 bit identifier assigned by the program that generates
            any kind of query.  This identifier is copied the corresponding
            reply and can be used by the requester to match up replies to
            outstanding queries.
        @type id: L{int}

        @param answer: A one bit field that specifies whether this message is a
            query (0), or a response (1).
        @type answer: L{bool}

        @param opCode: A four bit field that specifies kind of query in this
            message.  This value is set by the originator of a query and copied
            into the response.
        @type opCode: L{int}

        @param auth: Authoritative Answer - this bit is valid in responses, and
            specifies that the responding name server is an authority for the
            domain name in question section.
        @type auth: L{bool}

        @param trunc: Truncation - specifies that this message was truncated due
            to length greater than that permitted on the transmission channel.
        @type trunc: L{bool}

        @param recDes: Recursion Desired - this bit may be set in a query and is
            copied into the response.  If set, it directs the name server to
            pursue the query recursively. Recursive query support is optional.
        @type recDes: L{bool}

        @param recAv: Recursion Available - this bit is set or cleared in a
            response, and denotes whether recursive query support is available
            in the name server.
        @type recAv: L{bool}

        @param rCode: Extended 12-bit RCODE. Derived from the 4 bits defined in
            U{RFC1035 4.1.1<https://tools.ietf.org/html/rfc1035#section-4.1.1>}
            and the upper 8bits defined in U{RFC6891
            6.1.3<https://tools.ietf.org/html/rfc6891#section-6.1.3>}.
        @type rCode: L{int}

        @param ednsVersion: Indicates the EDNS implementation level. Set to
            L{None} to prevent any EDNS attributes and options being added to
            the encoded byte string.
        @type ednsVersion: L{int} or L{None}

        @param dnssecOK: DNSSEC OK bit as defined by
            U{RFC3225 3<https://tools.ietf.org/html/rfc3225#section-3>}.
        @type dnssecOK: L{bool}

        @param authenticData: A flag indicating in a response that all the data
            included in the answer and authority portion of the response has
            been authenticated by the server according to the policies of that
            server.
            See U{RFC2535 section-6.1<https://tools.ietf.org/html/rfc2535#section-6.1>}.
        @type authenticData: L{bool}

        @param checkingDisabled: A flag indicating in a query that pending
            (non-authenticated) data is acceptable to the resolver sending the
            query.
            See U{RFC2535 section-6.1<https://tools.ietf.org/html/rfc2535#section-6.1>}.
        @type authenticData: L{bool}

        @param maxSize: The requestor's UDP payload size is the number of octets
            of the largest UDP payload that can be reassembled and delivered in
            the requestor's network stack.
        @type maxSize: L{int}

        @param queries: The L{list} of L{Query} associated with this message.
        @type queries: L{list} of L{Query}

        @param answers: The L{list} of answers associated with this message.
        @type answers: L{list} of L{RRHeader}

        @param authority: The L{list} of authority records associated with this
            message.
        @type authority: L{list} of L{RRHeader}

        @param additional: The L{list} of additional records associated with
            this message.
        @type additional: L{list} of L{RRHeader}
        """
        self.id = id
        self.answer = answer
        self.opCode = opCode
        self.auth = auth
        self.trunc = trunc
        self.recDes = recDes
        self.recAv = recAv
        self.rCode = rCode
        self.ednsVersion = ednsVersion
        self.dnssecOK = dnssecOK
        self.authenticData = authenticData
        self.checkingDisabled = checkingDisabled
        self.maxSize = maxSize

        if queries is None:
            queries = []
        self.queries = queries

        if answers is None:
            answers = []
        self.answers = answers

        if authority is None:
            authority = []
        self.authority = authority

        if additional is None:
            additional = []
        self.additional = additional

    def __repr__(self) -> str:
        return _compactRepr(
            self,
            flagNames=(
                "answer",
                "auth",
                "trunc",
                "recDes",
                "recAv",
                "authenticData",
                "checkingDisabled",
                "dnssecOK",
            ),
            fieldNames=("id", "opCode", "rCode", "maxSize", "ednsVersion"),
            sectionNames=("queries", "answers", "authority", "additional"),
            alwaysShow=("id",),
        )

    def _toMessage(self):
        """
        Convert to a standard L{dns.Message}.

        If C{ednsVersion} is not None, an L{_OPTHeader} instance containing all
        the I{EDNS} specific attributes and options will be appended to the list
        of C{additional} records.

        @return: A L{dns.Message}
        @rtype: L{dns.Message}
        """
        m = self._messageFactory(
            id=self.id,
            answer=self.answer,
            opCode=self.opCode,
            auth=self.auth,
            trunc=self.trunc,
            recDes=self.recDes,
            recAv=self.recAv,
            # Assign the lower 4 bits to the message
            rCode=self.rCode & 0xF,
            authenticData=self.authenticData,
            checkingDisabled=self.checkingDisabled,
        )

        m.queries = self.queries[:]
        m.answers = self.answers[:]
        m.authority = self.authority[:]
        m.additional = self.additional[:]

        if self.ednsVersion is not None:
            o = _OPTHeader(
                version=self.ednsVersion,
                dnssecOK=self.dnssecOK,
                udpPayloadSize=self.maxSize,
                # Assign the upper 8 bits to the OPT record
                extendedRCODE=self.rCode >> 4,
            )
            m.additional.append(o)

        return m

    def toStr(self):
        """
        Encode to wire format by first converting to a standard L{dns.Message}.

        @return: A L{bytes} string.
        """
        return self._toMessage().toStr()

    @classmethod
    def _fromMessage(cls, message):
        """
        Construct and return a new L{_EDNSMessage} whose attributes and records
        are derived from the attributes and records of C{message} (a L{Message}
        instance).

        If present, an C{OPT} record will be extracted from the C{additional}
        section and its attributes and options will be used to set the EDNS
        specific attributes C{extendedRCODE}, C{ednsVersion}, C{dnssecOK},
        C{ednsOptions}.

        The C{extendedRCODE} will be combined with C{message.rCode} and assigned
        to C{self.rCode}.

        @param message: The source L{Message}.
        @type message: L{Message}

        @return: A new L{_EDNSMessage}
        @rtype: L{_EDNSMessage}
        """
        additional = []
        optRecords = []
        for r in message.additional:
            if r.type == OPT:
                optRecords.append(_OPTHeader.fromRRHeader(r))
            else:
                additional.append(r)

        newMessage = cls(
            id=message.id,
            answer=message.answer,
            opCode=message.opCode,
            auth=message.auth,
            trunc=message.trunc,
            recDes=message.recDes,
            recAv=message.recAv,
            rCode=message.rCode,
            authenticData=message.authenticData,
            checkingDisabled=message.checkingDisabled,
            # Default to None, it will be updated later when the OPT records are
            # parsed.
            ednsVersion=None,
            dnssecOK=False,
            queries=message.queries[:],
            answers=message.answers[:],
            authority=message.authority[:],
            additional=additional,
        )

        if len(optRecords) == 1:
            # XXX: If multiple OPT records are received, an EDNS server should
            # respond with FORMERR. See ticket:5669#comment:1.
            opt = optRecords[0]
            newMessage.ednsVersion = opt.version
            newMessage.dnssecOK = opt.dnssecOK
            newMessage.maxSize = opt.udpPayloadSize
            newMessage.rCode = opt.extendedRCODE << 4 | message.rCode

        return newMessage

    def fromStr(self, bytes):
        """
        Decode from wire format, saving flags, values and records to this
        L{_EDNSMessage} instance in place.

        @param bytes: The full byte string to be decoded.
        @type bytes: L{bytes}
        """
        m = self._messageFactory()
        m.fromStr(bytes)

        ednsMessage = self._fromMessage(m)
        for attrName in self.compareAttributes:
            setattr(self, attrName, getattr(ednsMessage, attrName))


class DNSMixin:
    """
    DNS protocol mixin shared by UDP and TCP implementations.

    @ivar _reactor: A L{IReactorTime} and L{IReactorUDP} provider which will
        be used to issue DNS queries and manage request timeouts.
    """

    id = None
    liveMessages = None

    def __init__(self, controller, reactor=None):
        self.controller = controller
        self.id = random.randrange(2**10, 2**15)
        if reactor is None:
            from twisted.internet import reactor
        self._reactor = reactor

    def pickID(self):
        """
        Return a unique ID for queries.
        """
        while True:
            id = randomSource()
            if id not in self.liveMessages:
                return id

    def callLater(self, period, func, *args):
        """
        Wrapper around reactor.callLater, mainly for test purpose.
        """
        return self._reactor.callLater(period, func, *args)

    def _query(self, queries, timeout, id, writeMessage):
        """
        Send out a message with the given queries.

        @type queries: L{list} of C{Query} instances
        @param queries: The queries to transmit

        @type timeout: L{int} or C{float}
        @param timeout: How long to wait before giving up

        @type id: L{int}
        @param id: Unique key for this request

        @type writeMessage: C{callable}
        @param writeMessage: One-parameter callback which writes the message

        @rtype: C{Deferred}
        @return: a C{Deferred} which will be fired with the result of the
            query, or errbacked with any errors that could happen (exceptions
            during writing of the query, timeout errors, ...).
        """
        m = Message(id, recDes=1)
        m.queries = queries

        try:
            writeMessage(m)
        except BaseException:
            return defer.fail()

        resultDeferred = defer.Deferred()
        cancelCall = self.callLater(timeout, self._clearFailed, resultDeferred, id)
        self.liveMessages[id] = (resultDeferred, cancelCall)

        return resultDeferred

    def _clearFailed(self, deferred, id):
        """
        Clean the Deferred after a timeout.
        """
        try:
            del self.liveMessages[id]
        except KeyError:
            pass
        deferred.errback(failure.Failure(DNSQueryTimeoutError(id)))


class DNSDatagramProtocol(DNSMixin, protocol.DatagramProtocol):
    """
    DNS protocol over UDP.
    """

    resends = None

    def stopProtocol(self):
        """
        Stop protocol: reset state variables.
        """
        self.liveMessages = {}
        self.resends = {}
        self.transport = None

    def startProtocol(self):
        """
        Upon start, reset internal state.
        """
        self.liveMessages = {}
        self.resends = {}

    def writeMessage(self, message, address):
        """
        Send a message holding DNS queries.

        @type message: L{Message}
        """
        self.transport.write(message.toStr(), address)

    def startListening(self):
        self._reactor.listenUDP(0, self, maxPacketSize=512)

    def datagramReceived(self, data, addr):
        """
        Read a datagram, extract the message in it and trigger the associated
        Deferred.
        """
        m = Message()
        try:
            m.fromStr(data)
        except EOFError:
            log.msg("Truncated packet (%d bytes) from %s" % (len(data), addr))
            return
        except ValueError as ex:
            log.msg(f"Invalid packet ({ex}) from {addr}")
            return
        except BaseException:
            # Nothing should trigger this, but since we're potentially
            # invoking a lot of different decoding methods, we might as well
            # be extra cautious.  Anything that triggers this is itself
            # buggy.
            log.err(failure.Failure(), "Unexpected decoding error")
            return

        if m.id in self.liveMessages:
            d, canceller = self.liveMessages[m.id]
            del self.liveMessages[m.id]
            canceller.cancel()
            # XXX we shouldn't need this hack of catching exception on callback()
            try:
                d.callback(m)
            except BaseException:
                log.err()
        else:
            if m.id not in self.resends:
                self.controller.messageReceived(m, self, addr)

    def removeResend(self, id):
        """
        Mark message ID as no longer having duplication suppression.
        """
        try:
            del self.resends[id]
        except KeyError:
            pass

    def query(self, address, queries, timeout=10, id=None):
        """
        Send out a message with the given queries.

        @type address: L{tuple} of L{str} and L{int}
        @param address: The address to which to send the query

        @type queries: L{list} of C{Query} instances
        @param queries: The queries to transmit

        @rtype: C{Deferred}
        """
        if not self.transport:
            # XXX transport might not get created automatically, use callLater?
            try:
                self.startListening()
            except CannotListenError:
                return defer.fail()

        if id is None:
            id = self.pickID()
        else:
            self.resends[id] = 1

        def writeMessage(m):
            self.writeMessage(m, address)

        return self._query(queries, timeout, id, writeMessage)


class DNSProtocol(DNSMixin, protocol.Protocol):
    """
    DNS protocol over TCP.
    """

    length = None
    buffer = b""

    def writeMessage(self, message):
        """
        Send a message holding DNS queries.

        @type message: L{Message}
        """
        s = message.toStr()
        self.transport.write(struct.pack("!H", len(s)) + s)

    def connectionMade(self):
        """
        Connection is made: reset internal state, and notify the controller.
        """
        self.liveMessages = {}
        self.controller.connectionMade(self)

    def connectionLost(self, reason):
        """
        Notify the controller that this protocol is no longer
        connected.
        """
        self.controller.connectionLost(self)

    def dataReceived(self, data):
        self.buffer += data

        while self.buffer:
            if self.length is None and len(self.buffer) >= 2:
                self.length = struct.unpack("!H", self.buffer[:2])[0]
                self.buffer = self.buffer[2:]

            if len(self.buffer) >= self.length:
                myChunk = self.buffer[: self.length]
                m = Message()
                m.fromStr(myChunk)

                try:
                    d, canceller = self.liveMessages[m.id]
                except KeyError:
                    self.controller.messageReceived(m, self)
                else:
                    del self.liveMessages[m.id]
                    canceller.cancel()
                    # XXX we shouldn't need this hack
                    try:
                        d.callback(m)
                    except BaseException:
                        log.err()

                self.buffer = self.buffer[self.length :]
                self.length = None
            else:
                break

    def query(self, queries, timeout=60):
        """
        Send out a message with the given queries.

        @type queries: L{list} of C{Query} instances
        @param queries: The queries to transmit

        @rtype: C{Deferred}
        """
        id = self.pickID()
        return self._query(queries, timeout, id, self.writeMessage)

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