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package Net::DNS::Packet; use strict; use warnings; our $VERSION = (qw$Id: Packet.pm 1891 2022-12-28 13:09:27Z willem $)[2]; =head1 NAME Net::DNS::Packet - DNS protocol packet =head1 SYNOPSIS use Net::DNS::Packet; $query = Net::DNS::Packet->new( 'example.com', 'MX', 'IN' ); $reply = $resolver->send( $query ); =head1 DESCRIPTION A Net::DNS::Packet object represents a DNS protocol packet. =cut use integer; use Carp; use Net::DNS::Parameters qw(:dsotype); use constant UDPSZ => 512; BEGIN { require Net::DNS::Header; require Net::DNS::Question; require Net::DNS::RR; } =head1 METHODS =head2 new $packet = Net::DNS::Packet->new( 'example.com' ); $packet = Net::DNS::Packet->new( 'example.com', 'MX', 'IN' ); $packet = Net::DNS::Packet->new(); If passed a domain, type, and class, new() creates a Net::DNS::Packet object which is suitable for making a DNS query for the specified information. The type and class may be omitted; they default to A and IN. If called with an empty argument list, new() creates an empty packet. =cut sub new { return &decode if ref $_[1]; my $class = shift; my $self = bless { status => 0, question => [], answer => [], authority => [], additional => [], }, $class; $self->{question} = [Net::DNS::Question->new(@_)] if scalar @_; return $self; } #=head2 decode =pod $packet = Net::DNS::Packet->decode( \$data ); $packet = Net::DNS::Packet->decode( \$data, 1 ); # debug $packet = Net::DNS::Packet->new( \$data ... ); If passed a reference to a scalar containing DNS packet data, a new packet object is created by decoding the data. The optional second boolean argument enables debugging output. Returns undef if unable to create a packet object. Decoding errors, including data corruption and truncation, are collected in the $@ ($EVAL_ERROR) variable. ( $packet, $length ) = Net::DNS::Packet->decode( \$data ); If called in array context, returns a packet object and the number of octets successfully decoded. Note that the number of RRs in each section of the packet may differ from the corresponding header value if the data has been truncated or corrupted during transmission. =cut use constant HEADER_LENGTH => length pack 'n6', (0) x 6; sub decode { my $class = shift; # uncoverable pod my $data = shift; my $debug = shift || 0; my $offset = 0; my $self; eval { local $SIG{__DIE__}; my $length = length $$data; die 'corrupt wire-format data' if $length < HEADER_LENGTH; # header section my ( $id, $status, @count ) = unpack 'n6', $$data; my ( $qd, $an, $ns, $ar ) = @count; $self = bless { id => $id, status => $status, count => [@count], question => [], answer => [], authority => [], additional => [], replysize => $length }, $class; # question/zone section my $hash = {}; my $record; $offset = HEADER_LENGTH; while ( $qd-- ) { ( $record, $offset ) = Net::DNS::Question->decode( $data, $offset, $hash ); CORE::push( @{$self->{question}}, $record ); } # RR sections while ( $an-- ) { ( $record, $offset ) = Net::DNS::RR->decode( $data, $offset, $hash ); CORE::push( @{$self->{answer}}, $record ); } while ( $ns-- ) { ( $record, $offset ) = Net::DNS::RR->decode( $data, $offset, $hash ); CORE::push( @{$self->{authority}}, $record ); } while ( $ar-- ) { ( $record, $offset ) = Net::DNS::RR->decode( $data, $offset, $hash ); CORE::push( @{$self->{additional}}, $record ); } return unless $offset == HEADER_LENGTH; return unless $self->header->opcode eq 'DSO'; $self->{dso} = []; my $limit = $length - 4; while ( $offset < $limit ) { my ( $t, $l, $v ) = unpack "\@$offset n2a*", $$data; CORE::push( @{$self->{dso}}, [$t, substr( $v, 0, $l )] ); $offset += ( $l + 4 ); } }; if ($debug) { local $@ = $@; print $@ if $@; eval { $self->print }; } return wantarray ? ( $self, $offset ) : $self; } =head2 data $data = $packet->data; $data = $packet->data( $size ); Returns the packet data in binary format, suitable for sending as a query or update request to a nameserver. Truncation may be specified using a non-zero optional size argument. =cut sub data { return &encode; } sub encode { my ( $self, $size ) = @_; # uncoverable pod my $edns = $self->edns; # EDNS support my @addl = grep { !$_->isa('Net::DNS::RR::OPT') } @{$self->{additional}}; $self->{additional} = [$edns, @addl] if $edns->_specified; return $self->truncate($size) if $size; my @part = qw(question answer authority additional); my @size = map { scalar @{$self->{$_}} } @part; my $data = pack 'n6', $self->header->id, $self->{status}, @size; $self->{count} = []; my $hash = {}; # packet body foreach my $component ( map { @{$self->{$_}} } @part ) { $data .= $component->encode( length $data, $hash, $self ); } return $data; } =head2 header $header = $packet->header; Constructor method which returns a Net::DNS::Header object which represents the header section of the packet. =cut sub header { my $self = shift; return bless \$self, q(Net::DNS::Header); } =head2 edns $edns = $packet->edns; $version = $edns->version; $UDPsize = $edns->size; Auxiliary function which provides access to the EDNS protocol extension OPT RR. =cut sub edns { my $self = shift; my $link = \$self->{xedns}; ($$link) = grep { $_->isa(qw(Net::DNS::RR::OPT)) } @{$self->{additional}} unless $$link; $$link = Net::DNS::RR->new( type => 'OPT' ) unless $$link; return $$link; } =head2 reply $reply = $query->reply( $UDPmax ); Constructor method which returns a new reply packet. The optional UDPsize argument is the maximum UDP packet size which can be reassembled by the local network stack, and is advertised in response to an EDNS query. =cut sub reply { my $query = shift; my $UDPmax = shift; my $qheadr = $query->header; croak 'erroneous qr flag in query packet' if $qheadr->qr; my $reply = Net::DNS::Packet->new(); my $header = $reply->header; $header->qr(1); # reply with same id, opcode and question $header->id( $qheadr->id ); $header->opcode( $qheadr->opcode ); my @question = $query->question; $reply->{question} = [@question]; $header->rcode('FORMERR'); # no RCODE considered sinful! $header->rd( $qheadr->rd ); # copy these flags into reply $header->cd( $qheadr->cd ); return $reply unless grep { $_->isa('Net::DNS::RR::OPT') } @{$query->{additional}}; my $edns = $reply->edns(); CORE::push( @{$reply->{additional}}, $edns ); $edns->size($UDPmax); return $reply; } =head2 question, zone @question = $packet->question; Returns a list of Net::DNS::Question objects representing the question section of the packet. In dynamic update packets, this section is known as zone() and specifies the DNS zone to be updated. =cut sub question { my @qr = @{shift->{question}}; return @qr; } sub zone { return &question } =head2 answer, pre, prerequisite @answer = $packet->answer; Returns a list of Net::DNS::RR objects representing the answer section of the packet. In dynamic update packets, this section is known as pre() or prerequisite() and specifies the RRs or RRsets which must or must not preexist. =cut sub answer { my @rr = @{shift->{answer}}; return @rr; } sub pre { return &answer } sub prerequisite { return &answer } =head2 authority, update @authority = $packet->authority; Returns a list of Net::DNS::RR objects representing the authority section of the packet. In dynamic update packets, this section is known as update() and specifies the RRs or RRsets to be added or deleted. =cut sub authority { my @rr = @{shift->{authority}}; return @rr; } sub update { return &authority } =head2 additional @additional = $packet->additional; Returns a list of Net::DNS::RR objects representing the additional section of the packet. =cut sub additional { my @rr = @{shift->{additional}}; return @rr; } =head2 print $packet->print; Prints the entire packet to the currently selected output filehandle using the master file format mandated by RFC1035. =cut sub print { print &string; return; } =head2 string print $packet->string; Returns a string representation of the packet. =cut sub string { my $self = shift; my $header = $self->header; my $opcode = $header->opcode; my $server = $self->{replyfrom}; my $length = $self->{replysize}; my $origin = $server ? ";; Response received from $server ($length octets)\n" : ""; my @record = ( "$origin;; HEADER SECTION", $header->string ); my $edns = $self->edns; CORE::push( @record, $edns->string ) if $edns->_specified; if ( $opcode eq 'DSO' ) { CORE::push( @record, ";; DSO SECTION" ); foreach ( @{$self->{dso}} ) { my ( $t, $v ) = @$_; CORE::push( @record, pack 'a* A18 a*', ";;\t", dsotypebyval($t), unpack( 'H*', $v ) ); } return join "\n", @record, "\n"; } my @section = $opcode eq 'UPDATE' ? qw(ZONE PREREQUISITE UPDATE) : qw(QUESTION ANSWER AUTHORITY); my @question = $self->question; my $qdcount = scalar @question; my $qds = $qdcount != 1 ? 's' : ''; CORE::push( @record, ";; $section[0] SECTION ($qdcount record$qds)", map { ';; ' . $_->string } @question ); my @answer = $self->answer; my $ancount = scalar @answer; my $ans = $ancount != 1 ? 's' : ''; CORE::push( @record, "\n;; $section[1] SECTION ($ancount record$ans)", map { $_->string } @answer ); my @authority = $self->authority; my $nscount = scalar @authority; my $nss = $nscount != 1 ? 's' : ''; CORE::push( @record, "\n;; $section[2] SECTION ($nscount record$nss)", map { $_->string } @authority ); my @additional = $self->additional; my $arcount = scalar @additional; my $ars = $arcount != 1 ? 's' : ''; my $EDNSmarker = join ' ', qq[;; {\t"EDNS-VERSION":], $edns->version, qq[}\n]; CORE::push( @record, "\n;; ADDITIONAL SECTION ($arcount record$ars)" ); CORE::push( @record, map { ( $_ eq $edns ) ? $EDNSmarker : $_->string } @additional ); return join "\n", @record, "\n"; } =head2 from print "packet received from ", $packet->from, "\n"; Returns the IP address from which this packet was received. This method will return undef for user-created packets. =cut sub from { my $self = shift; $self->{replyfrom} = shift if scalar @_; return $self->{replyfrom}; } sub answerfrom { return &from; } # uncoverable pod =head2 size print "packet size: ", $packet->size, " octets\n"; Returns the size of the packet in octets as it was received from a nameserver. This method will return undef for user-created packets (use length($packet->data) instead). =cut sub size { return shift->{replysize}; } sub answersize { return &size; } # uncoverable pod =head2 push $ancount = $packet->push( prereq => $rr ); $nscount = $packet->push( update => $rr ); $arcount = $packet->push( additional => $rr ); $nscount = $packet->push( update => $rr1, $rr2, $rr3 ); $nscount = $packet->push( update => @rr ); Adds RRs to the specified section of the packet. Returns the number of resource records in the specified section. Section names may be abbreviated to the first three characters. =cut sub push { my $self = shift; my $list = $self->_section(shift); return CORE::push( @$list, grep { ref($_) } @_ ); } =head2 unique_push $ancount = $packet->unique_push( prereq => $rr ); $nscount = $packet->unique_push( update => $rr ); $arcount = $packet->unique_push( additional => $rr ); $nscount = $packet->unique_push( update => $rr1, $rr2, $rr3 ); $nscount = $packet->unique_push( update => @rr ); Adds RRs to the specified section of the packet provided that the RRs are not already present in the same section. Returns the number of resource records in the specified section. Section names may be abbreviated to the first three characters. =cut sub unique_push { my $self = shift; my $list = $self->_section(shift); my @rr = grep { ref($_) } @_; my %unique = map { ( bless( {%$_, ttl => 0}, ref $_ )->canonical => $_ ) } @rr, @$list; return scalar( @$list = values %unique ); } =head2 pop my $rr = $packet->pop( 'pre' ); my $rr = $packet->pop( 'update' ); my $rr = $packet->pop( 'additional' ); Removes a single RR from the specified section of the packet. =cut sub pop { my $self = shift; my $list = $self->_section(shift); return CORE::pop(@$list); } my %_section = ( ## section name abbreviation table 'ans' => 'answer', 'pre' => 'answer', 'aut' => 'authority', 'upd' => 'authority', 'add' => 'additional' ); sub _section { ## returns array reference for section my $self = shift; my $name = shift; my $list = $_section{unpack 'a3', $name} || $name; return $self->{$list} ||= []; } =head2 sign_tsig $query = Net::DNS::Packet->new( 'www.example.com', 'A' ); $query->sign_tsig( $keyfile, fudge => 60 ); $reply = $res->send( $query ); $reply->verify( $query ) || die $reply->verifyerr; Attaches a TSIG resource record object, which will be used to sign the packet (see RFC 2845). The TSIG record can be customised by optional additional arguments to sign_tsig() or by calling the appropriate Net::DNS::RR::TSIG methods. If you wish to create a TSIG record using a non-standard algorithm, you will have to create it yourself. In all cases, the TSIG name must uniquely identify the key shared between the parties, and the algorithm name must identify the signing function to be used with the specified key. $tsig = Net::DNS::RR->new( name => 'tsig.example', type => 'TSIG', algorithm => 'custom-algorithm', key => '<base64 key text>', sig_function => sub { my ($key, $data) = @_; ... } ); $query->sign_tsig( $tsig ); The response to an inbound request is signed by presenting the request in place of the key parameter. $response = $request->reply; $response->sign_tsig( $request, @options ); Multi-packet transactions are signed by chaining the sign_tsig() calls together as follows: $opaque = $packet1->sign_tsig( 'Kexample.+165+13281.private' ); $opaque = $packet2->sign_tsig( $opaque ); $packet3->sign_tsig( $opaque ); The opaque intermediate object references returned during multi-packet signing are not intended to be accessed by the end-user application. Any such access is expressly forbidden. Note that a TSIG record is added to every packet; this implementation does not support the suppressed signature scheme described in RFC2845. =cut sub sign_tsig { my $self = shift; return eval { local $SIG{__DIE__}; require Net::DNS::RR::TSIG; my $tsig = Net::DNS::RR::TSIG->create(@_); $self->push( 'additional' => $tsig ); return $tsig; } || return croak "$@\nTSIG: unable to sign packet"; } =head2 verify and verifyerr $packet->verify() || die $packet->verifyerr; $reply->verify( $query ) || die $reply->verifyerr; Verify TSIG signature of packet or reply to the corresponding query. $opaque = $packet1->verify( $query ) || die $packet1->verifyerr; $opaque = $packet2->verify( $opaque ); $verifed = $packet3->verify( $opaque ) || die $packet3->verifyerr; The opaque intermediate object references returned during multi-packet verify() will be undefined (Boolean false) if verification fails. Access to the object itself, if it exists, is expressly forbidden. Testing at every stage may be omitted, which results in a BADSIG error on the final packet in the absence of more specific information. =cut sub verify { my $self = shift; my $sig = $self->sigrr; return $sig ? $sig->verify( $self, @_ ) : shift; } sub verifyerr { my $self = shift; my $sig = $self->sigrr; return $sig ? $sig->vrfyerrstr : 'not signed'; } =head2 sign_sig0 SIG0 support is provided through the Net::DNS::RR::SIG class. The requisite cryptographic components are not integrated into Net::DNS but reside in the Net::DNS::SEC distribution available from CPAN. $update = Net::DNS::Update->new('example.com'); $update->push( update => rr_add('foo.example.com A 10.1.2.3')); $update->sign_sig0('Kexample.com+003+25317.private'); Execution will be terminated if Net::DNS::SEC is not available. =head2 verify SIG0 $packet->verify( $keyrr ) || die $packet->verifyerr; $packet->verify( [$keyrr, ...] ) || die $packet->verifyerr; Verify SIG0 packet signature against one or more specified KEY RRs. =cut sub sign_sig0 { my $self = shift; my $karg = shift; return eval { local $SIG{__DIE__}; my $sig0; if ( ref($karg) eq 'Net::DNS::RR::SIG' ) { $sig0 = $karg; } else { require Net::DNS::RR::SIG; $sig0 = Net::DNS::RR::SIG->create( '', $karg ); } $self->push( 'additional' => $sig0 ); return $sig0; } || return croak "$@\nSIG0: unable to sign packet"; } =head2 sigrr $sigrr = $packet->sigrr() || die 'unsigned packet'; The sigrr method returns the signature RR from a signed packet or undefined if the signature is absent. =cut sub sigrr { my $self = shift; my ($sig) = reverse $self->additional; return unless $sig; return $sig if $sig->type eq 'TSIG'; return $sig if $sig->type eq 'SIG'; return; } ######################################## =head2 truncate The truncate method takes a maximum length as argument and then tries to truncate the packet and set the TC bit according to the rules of RFC2181 Section 9. The smallest length limit that is honoured is 512 octets. =cut # From RFC2181: # # 9. The TC (truncated) header bit # # The TC bit should be set in responses only when an RRSet is required # as a part of the response, but could not be included in its entirety. # The TC bit should not be set merely because some extra information # could have been included, for which there was insufficient room. This # includes the results of additional section processing. In such cases # the entire RRSet that will not fit in the response should be omitted, # and the reply sent as is, with the TC bit clear. If the recipient of # the reply needs the omitted data, it can construct a query for that # data and send that separately. # # Where TC is set, the partial RRSet that would not completely fit may # be left in the response. When a DNS client receives a reply with TC # set, it should ignore that response, and query again, using a # mechanism, such as a TCP connection, that will permit larger replies. # Code developed from a contribution by Aaron Crane via rt.cpan.org 33547 sub truncate { my $self = shift; my $size = shift || UDPSZ; my $sigrr = $self->sigrr; $size = UDPSZ unless $size > UDPSZ; $size -= $sigrr->_size if $sigrr; my $data = pack 'x' x HEADER_LENGTH; # header placeholder $self->{count} = []; my $tc; my $hash = {}; foreach my $section ( map { $self->{$_} } qw(question answer authority) ) { my @list; foreach my $item (@$section) { my $component = $item->encode( length $data, $hash ); last if length($data) + length($component) > $size; last if $tc; $data .= $component; CORE::push @list, $item; } $tc++ if scalar(@list) < scalar(@$section); @$section = @list; } $self->header->tc(1) if $tc; # only set if truncated here my %rrset; my @order; foreach my $item ( grep { ref($_) ne ref($sigrr) } $self->additional ) { my $name = $item->{owner}->canonical; my $class = $item->{class} || 0; my $key = pack 'nna*', $class, $item->{type}, $name; CORE::push @order, $key unless $rrset{$key}; CORE::push @{$rrset{$key}}, $item; } my @list; foreach my $key (@order) { my $component = ''; my @item = @{$rrset{$key}}; foreach my $item (@item) { $component .= $item->encode( length $data, $hash ); } last if length($data) + length($component) > $size; $data .= $component; CORE::push @list, @item; } if ($sigrr) { $data .= $sigrr->encode( length $data, $hash, $self ); CORE::push @list, $sigrr; } $self->{'additional'} = \@list; my @part = qw(question answer authority additional); my @size = map { scalar @{$self->{$_}} } @part; return pack 'n6 a*', $self->header->id, $self->{status}, @size, substr( $data, HEADER_LENGTH ); } ######################################## sub dump { ## print internal data structure require Data::Dumper; # uncoverable pod local $Data::Dumper::Maxdepth = $Data::Dumper::Maxdepth || 3; local $Data::Dumper::Sortkeys = $Data::Dumper::Sortkeys || 1; local $Data::Dumper::Useqq = $Data::Dumper::Useqq || 1; print Data::Dumper::Dumper(@_); return; } 1; __END__ =head1 COPYRIGHT Copyright (c)1997-2000 Michael Fuhr. Portions Copyright (c)2002-2004 Chris Reinhardt. Portions Copyright (c)2002-2009 Olaf Kolkman Portions Copyright (c)2007-2019 Dick Franks All rights reserved. =head1 LICENSE Permission to use, copy, modify, and distribute this software and its documentation for any purpose and without fee is hereby granted, provided that the original copyright notices appear in all copies and that both copyright notice and this permission notice appear in supporting documentation, and that the name of the author not be used in advertising or publicity pertaining to distribution of the software without specific prior written permission. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. =head1 SEE ALSO L<perl>, L<Net::DNS>, L<Net::DNS::Update>, L<Net::DNS::Header>, L<Net::DNS::Question>, L<Net::DNS::RR>, L<Net::DNS::RR::TSIG>, RFC1035 Section 4.1, RFC2136 Section 2, RFC2845 =cut