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# Net::CIDR # # Copyright 2001-2021 Sam Varshavchik. # # with contributions from David Cantrell. # # This program is free software; you can redistribute it # and/or modify it under the same terms as Perl itself. package Net::CIDR; require 5.000; #use strict; #use warnings; require Exporter; # use AutoLoader qw(AUTOLOAD); use Carp; @ISA = qw(Exporter); # Items to export into callers namespace by default. Note: do not export # names by default without a very good reason. Use EXPORT_OK instead. # Do not simply export all your public functions/methods/constants. # This allows declaration use Net::CIDR ':all'; # If you do not need this, moving things directly into @EXPORT or @EXPORT_OK # will save memory. %EXPORT_TAGS = ( 'all' => [ qw( range2cidr cidr2range cidr2octets cidradd cidrlookup cidrvalidate addr2cidr addrandmask2cidr ) ] ); @EXPORT_OK = ( qw( range2cidr cidr2range cidr2octets cidradd cidrlookup cidrvalidate addr2cidr addrandmask2cidr )); @EXPORT = qw( ); $VERSION = "0.21"; 1; =pod =head1 NAME Net::CIDR - Manipulate IPv4/IPv6 netblocks in CIDR notation =head1 SYNOPSIS use Net::CIDR; use Net::CIDR ':all'; my $var; if ($var = Net::CIDR::cidrvalidate($var)) { // ... do something } print join("\n", Net::CIDR::range2cidr("192.168.0.0-192.168.255.255", "10.0.0.0-10.3.255.255")) . "\n"; # # Output from above: # # 192.168.0.0/16 # 10.0.0.0/14 print join("\n", Net::CIDR::range2cidr( "dead:beef::-dead:beef:ffff:ffff:ffff:ffff:ffff:ffff")) . "\n"; # # Output from above: # # dead:beef::/32 print join("\n", Net::CIDR::range2cidr("192.168.1.0-192.168.2.255")) . "\n"; # # Output from above: # # 192.168.1.0/24 # 192.168.2.0/24 print join("\n", Net::CIDR::cidr2range("192.168.0.0/16")) . "\n"; # # Output from above: # # 192.168.0.0-192.168.255.255 print join("\n", Net::CIDR::cidr2range("dead::beef::/46")) . "\n"; # # Output from above: # # dead:beef::-dead:beef:3:ffff:ffff:ffff:ffff:ffff @list=("192.168.0.0/24"); @list=Net::CIDR::cidradd("192.168.1.0-192.168.1.255", @list); print join("\n", @list) . "\n"; # # Output from above: # # 192.168.0.0/23 print join("\n", Net::CIDR::cidr2octets("192.168.0.0/22")) . "\n"; # # Output from above: # # 192.168.0 # 192.168.1 # 192.168.2 # 192.168.3 print join("\n", Net::CIDR::cidr2octets("dead::beef::/46")) . "\n"; # # Output from above: # # dead:beef:0000 # dead:beef:0001 # dead:beef:0002 # dead:beef:0003 @list=("192.168.0.0/24"); print Net::CIDR::cidrlookup("192.168.0.12", @list); # # Output from above: # # 1 @list = Net::CIDR::addr2cidr("192.168.0.31"); print join("\n", @list); # # Output from above: # # 192.168.0.31/32 # 192.168.0.30/31 # 192.168.0.28/30 # 192.168.0.24/29 # 192.168.0.16/28 # 192.168.0.0/27 # 192.168.0.0/26 # 192.168.0.0/25 # 192.168.0.0/24 # 192.168.0.0/23 # [and so on] print Net::CIDR::addrandmask2cidr("195.149.50.61", "255.255.255.248")."\n"; # # Output from above: # # 195.149.50.56/29 =head1 DESCRIPTION The Net::CIDR package contains functions that manipulate lists of IP netblocks expressed in CIDR notation. The Net::CIDR functions handle both IPv4 and IPv6 addresses. The cidrvalidate() function, described below, checks that its argument is a single, valid IP address or a CIDR. The remaining functions expect that their parameters consist of validated IPs or CIDRs. See cidrvalidate() and BUGS, below, for more information. =head2 @cidr_list=Net::CIDR::range2cidr(@range_list); Each element in the @range_list is a string "start-finish", where "start" is the first IP address and "finish" is the last IP address. range2cidr() converts each range into an equivalent CIDR netblock. It returns a list of netblocks except in the case where it is given only one parameter and is called in scalar context. For example: @a=Net::CIDR::range2cidr("192.168.0.0-192.168.255.255"); The result is a one-element array, with $a[0] being "192.168.0.0/16". range2cidr() processes each "start-finish" element in @range_list separately. But if invoked like so: $a=Net::CIDR::range2cidr("192.168.0.0-192.168.255.255"); The result is a scalar "192.168.0.0/16". Where each element cannot be expressed as a single CIDR netblock range2cidr() will generate as many CIDR netblocks as are necessary to cover the full range of IP addresses. Example: @a=Net::CIDR::range2cidr("192.168.1.0-192.168.2.255"); The result is a two element array: ("192.168.1.0/24","192.168.2.0/24"); @a=Net::CIDR::range2cidr( "d08c:43::-d08c:43:ffff:ffff:ffff:ffff:ffff:ffff"); The result is an one element array: ("d08c:43::/32") that reflects this IPv6 netblock in CIDR notation. range2cidr() does not merge adjacent or overlapping netblocks in @range_list. =head2 @range_list=Net::CIDR::cidr2range(@cidr_list); The cidr2range() functions converts a netblock list in CIDR notation to a list of "start-finish" IP address ranges: @a=Net::CIDR::cidr2range("10.0.0.0/14", "192.168.0.0/24"); The result is a two-element array: ("10.0.0.0-10.3.255.255", "192.168.0.0-192.168.0.255"). @a=Net::CIDR::cidr2range("d08c:43::/32"); The result is a one-element array: ("d08c:43::-d08c:43:ffff:ffff:ffff:ffff:ffff:ffff"). cidr2range() does not merge adjacent or overlapping netblocks in @cidr_list. =head2 @netblock_list = Net::CIDR::addr2cidr($address); The addr2cidr function takes an IP address and returns a list of all the CIDR netblocks it might belong to: @a=Net::CIDR::addr2cidr('192.168.0.31'); The result is a thirtythree-element array: ('192.168.0.31/32', '192.168.0.30/31', '192.168.0.28/30', '192.168.0.24/29', [and so on]) consisting of all the possible subnets containing this address from 0.0.0.0/0 to address/32. Any addresses supplied to addr2cidr after the first will be ignored. It works similarly for IPv6 addresses, returning a list of one hundred and twenty nine elements. =head2 $cidr=Net::CIDR::addrandmask2cidr($address, $netmask); The addrandmask2cidr function takes an IP address and a netmask, and returns the CIDR range whose size fits the netmask and which contains the address. It is an error to supply one parameter in IPv4-ish format and the other in IPv6-ish format, and it is an error to supply a netmask which does not consist solely of 1 bits followed by 0 bits. For example, '255.255.248.192' is an invalid netmask, as is '255.255.255.32' because both contain 0 bits in between 1 bits. Technically speaking both of those *are* valid netmasks, but a) you'd have to be insane to use them, and b) there's no corresponding CIDR range. =cut # CIDR to start-finish sub cidr2range { my @cidr=@_; my @r; while ($#cidr >= 0) { my $cidr=shift @cidr; $cidr =~ s/\s//g; unless ($cidr =~ /(.*)\/(.*)/) { push @r, $cidr; next; } my ($ip, $pfix)=($1, $2); my $isipv6; my @ips=_iptoipa($ip); $isipv6=shift @ips; croak "$pfix, as in '$cidr', does not make sense" unless $pfix >= 0 && $pfix <= ($#ips+1) * 8 && $pfix =~ /^[0-9]+$/; my @rr=_cidr2iprange($pfix, @ips); while ($#rr >= 0) { my $a=shift @rr; my $b=shift @rr; $a =~ s/\.$//; $b =~ s/\.$//; if ($isipv6) { $a=_ipv4to6($a); $b=_ipv4to6($b); } push @r, "$a-$b"; } } return @r; } # # If the input is an IPv6-formatted address, convert it to an IPv4 decimal # format, since the other functions know how to deal with it. The hexadecimal # IPv6 address is represented in dotted-decimal form, like IPv4. # sub _ipv6to4 { my $ipv6=shift; return (undef, $ipv6) unless $ipv6 =~ /:/; croak "Syntax error: $ipv6" unless $ipv6 =~ /^[a-fA-F0-9:\.]+$/; my $ip4_suffix=""; ($ipv6, $ip4_suffix)=($1, $2) if $ipv6 =~ /^(.*:)([0-9]+\.[0-9\.]+)$/; $ipv6 =~ s/([a-fA-F0-9]+)/_h62d($1)/ge; my $ipv6_suffix=""; if ($ipv6 =~ /(.*)::(.*)/) { ($ipv6, $ipv6_suffix)=($1, $2); $ipv6_suffix .= ".$ip4_suffix"; } else { $ipv6 .= ".$ip4_suffix"; } my @p=grep (/./, split (/[^0-9]+/, $ipv6)); my @s=grep (/./, split (/[^0-9]+/, $ipv6_suffix)); push @p, 0 while $#p + $#s < 14; my $n=join(".", @p, @s); # return (undef, $1) # if $n =~ /^0\.0\.0\.0\.0\.0\.0\.0\.0\.0\.255\.255\.(.*)$/; return (1, $n); } # Let's go the other way around sub _ipv4to6 { my @octets=split(/[^0-9]+/, shift); croak "Internal error in _ipv4to6" unless $#octets == 15; my @dummy=@octets; return ("::ffff:" . join(".", $octets[12], $octets[13], $octets[14], $octets[15])) if join(".", splice(@dummy, 0, 12)) eq "0.0.0.0.0.0.0.0.0.0.255.255"; my @words; my $i; for ($i=0; $i < 8; $i++) { $words[$i]=sprintf("%x", $octets[$i*2] * 256 + $octets[$i*2+1]); } my $ind= -1; my $indlen= -1; for ($i=0; $i < 8; $i++) { next unless $words[$i] eq "0"; my $j; for ($j=$i; $j < 8; $j++) { last if $words[$j] ne "0"; } if ($j - $i > $indlen) { $indlen= $j-$i; $ind=$i; $i=$j-1; } } return "::" if $indlen == 8; return join(":", @words) if $ind < 0; my @s=splice (@words, $ind+$indlen); return join(":", splice (@words, 0, $ind)) . "::" . join(":", @s); } # An IP address to an octet list. # Returns a list. First element, flag: true if it was an IPv6 flag. Remaining # values are octets. sub _iptoipa { my $iparg=shift; my $isipv6; my $ip; ($isipv6, $ip)=_ipv6to4($iparg); my @ips= split (/\.+/, $ip); for( my $i = $#ips + 1 ; $i < 4 ; $i++ ) { $ips[$i] = 0; } grep { croak "$_, in $iparg, is not a byte" unless $_ >= 0 && $_ <= 255 && $_ =~ /^[0-9]+$/; } @ips; return ($isipv6, @ips); } sub _h62d { my $h=shift; $h=hex("0x$h"); return ( int($h / 256) . "." . ($h % 256)); } sub _cidr2iprange { my @ips=@_; my $pfix=shift @ips; if ($pfix == 0) { grep { $_=0 } @ips; my @ips2=@ips; grep { $_=255 } @ips2; return ( join(".", @ips), join(".", @ips2)); } if ($pfix >= 8) { my $octet=shift @ips; @ips=_cidr2iprange($pfix - 8, @ips); grep { $_="$octet.$_"; } @ips; return @ips; } my $octet=shift @ips; grep { $_=0 } @ips; my @ips2=@ips; grep { $_=255 } @ips2; my @r= _cidr2range8(($octet, $pfix)); $r[0] = join (".", ($r[0], @ips)); $r[1] = join (".", ($r[1], @ips2)); return @r; } # # ADDRESS to list of CIDR netblocks # sub addr2cidr { my @ips=_iptoipa(shift); my $isipv6=shift @ips; my $nbits; if ($isipv6) { croak "An IPv6 address is 16 bytes long" unless $#ips == 15; $nbits=128; } else { croak "An IPv4 address is 4 bytes long" unless $#ips == 3; $nbits=32; } my @blocks; foreach my $bits (reverse 0..$nbits) { my @ipcpy=@ips; my $n=$bits; while ($n < $nbits) { @ipcpy[$n / 8] &= (0xFF00 >> ($n % 8)); $n += 8; $n &= 0xF8; } my $s=join(".", @ipcpy); push @blocks, ($isipv6 ? _ipv4to6($s):$s) . "/$bits"; } return @blocks; } # Address and netmask to CIDR sub addrandmask2cidr { my $address = shift; my($a_isIPv6) = _ipv6to4($address); my($n_isIPv6, $netmask) = _ipv6to4(shift); die("Both address and netmask must be the same type") if( defined($a_isIPv6) && defined($n_isIPv6) && $a_isIPv6 != $n_isIPv6); my $bitsInNetmask = 0; my $previousNMoctet = 255; foreach my $octet (split/\./, $netmask) { die("Invalid netmask") if($previousNMoctet != 255 && $octet != 0); $previousNMoctet = $octet; $bitsInNetmask += ($octet == 255) ? 8 : ($octet == 254) ? 7 : ($octet == 252) ? 6 : ($octet == 248) ? 5 : ($octet == 240) ? 4 : ($octet == 224) ? 3 : ($octet == 192) ? 2 : ($octet == 128) ? 1 : ($octet == 0) ? 0 : die("Invalid netmask"); } return (grep { /\/$bitsInNetmask$/ } addr2cidr($address))[0]; } # # START-FINISH to CIDR list # sub range2cidr { my @r=@_; my $i; my @c; for ($i=0; $i <= $#r; $i++) { $r[$i] =~ s/\s//g; if ($r[$i] =~ /\//) { push @c, $r[$i]; next; } $r[$i]="$r[$i]-$r[$i]" unless $r[$i] =~ /(.*)-(.*)/; $r[$i] =~ /(.*)-(.*)/; my ($a,$b)=($1,$2); my $isipv6_1; my $isipv6_2; ($isipv6_1, $a)=_ipv6to4($a); ($isipv6_2, $b)=_ipv6to4($b); if ($isipv6_1 || $isipv6_2) { croak "Invalid netblock range: $r[$i]" unless $isipv6_1 && $isipv6_2; } my @a=split(/\.+/, $a); my @b=split(/\.+/, $b); croak unless $#a == $#b; my @cc=_range2cidr(\@a, \@b); while ($#cc >= 0) { $a=shift @cc; $b=shift @cc; $a=_ipv4to6($a) if $isipv6_1; push @c, "$a/$b"; } } return @c unless(1==@r && 1==@c && !wantarray()); return $c[0]; } sub _range2cidr { my $a=shift; my $b=shift; my @a=@$a; my @b=@$b; $a=shift @a; $b=shift @b; return _range2cidr8($a, $b) if $#a < 0; # Least significant octet pair. croak "Bad starting address\n" unless $a >= 0 && $a <= 255 && $a =~ /^[0-9]+$/; croak "Bad ending address\n" unless $b >= 0 && $b <= 255 && $b =~ /^[0-9]+$/ && $b >= $a; my @c; if ($a == $b) # Same start/end octet { my @cc= _range2cidr(\@a, \@b); while ($#cc >= 0) { my $c=shift @cc; push @c, "$a.$c"; $c=shift @cc; push @c, $c+8; } return @c; } my $start0=1; my $end255=1; grep { $start0=0 unless $_ == 0; } @a; grep { $end255=0 unless $_ == 255; } @b; if ( ! $start0 ) { my @bcopy=@b; grep { $_=255 } @bcopy; my @cc= _range2cidr(\@a, \@bcopy); while ($#cc >= 0) { my $c=shift @cc; push @c, "$a.$c"; $c=shift @cc; push @c, $c + 8; } ++$a; } if ( ! $end255 ) { my @acopy=@a; grep { $_=0 } @acopy; my @cc= _range2cidr(\@acopy, \@b); while ($#cc >= 0) { my $c=shift @cc; push @c, "$b.$c"; $c=shift @cc; push @c, $c + 8; } --$b; } if ($a <= $b) { grep { $_=0 } @a; my $pfix=join(".", @a); my @cc= _range2cidr8($a, $b); while ($#cc >= 0) { my $c=shift @cc; push @c, "$c.$pfix"; $c=shift @cc; push @c, $c; } } return @c; } sub _range2cidr8 { my @c; my @r=@_; while ($#r >= 0) { my $a=shift @r; my $b=shift @r; croak "Bad starting address\n" unless $a >= 0 && $a <= 255 && $a =~ /^[0-9]+$/; croak "Bad ending address\n" unless $b >= 0 && $b <= 255 && $b =~ /^[0-9]+$/ && $b >= $a; ++$b; while ($a < $b) { my $i=0; my $n=1; while ( ($n & $a) == 0) { ++$i; $n <<= 1; last if $i >= 8; } while ($i && $n + $a > $b) { --$i; $n >>= 1; } push @c, $a; push @c, 8-$i; $a += $n; } } return @c; } sub _cidr2range8 { my @c=@_; my @r; while ($#c >= 0) { my $a=shift @c; my $b=shift @c; croak "Bad starting address" unless $a >= 0 && $a <= 255 && $a =~ /^[0-9]+$/; croak "Bad ending address" unless $b >= 0 && $b <= 8 && $b =~ /^[0-9]+$/; my $n= 1 << (8-$b); $a &= ($n-1) ^ 255; push @r, $a; push @r, $a + ($n-1); } return @r; } sub _ipcmp { my $aa=shift; my $bb=shift; my $isipv6_1; my $isipv6_2; ($isipv6_1, $aa)=_ipv6to4($aa); ($isipv6_2, $bb)=_ipv6to4($bb); my @a=split (/\./, $aa); my @b=split (/\./, $bb); unshift @a, (0,0,0,0,0,0,0,0,0,0,255,255) unless $isipv6_1; unshift @b, (0,0,0,0,0,0,0,0,0,0,255,255) unless $isipv6_2; croak "Different number of octets in IP addresses" unless $#a == $#b; while ($#a >= 0 && $a[0] == $b[0]) { shift @a; shift @b; } return 0 if $#a < 0; return $a[0] <=> $b[0]; } =pod =head2 @octet_list=Net::CIDR::cidr2octets(@cidr_list); cidr2octets() takes @cidr_list and returns a list of leading octets representing those netblocks. Example: @octet_list=Net::CIDR::cidr2octets("10.0.0.0/14", "192.168.0.0/24"); The result is the following five-element array: ("10.0", "10.1", "10.2", "10.3", "192.168.0"). For IPv6 addresses, the hexadecimal words in the resulting list are zero-padded: @octet_list=Net::CIDR::cidr2octets("::dead:beef:0:0/110"); The result is a four-element array: ("0000:0000:0000:0000:dead:beef:0000", "0000:0000:0000:0000:dead:beef:0001", "0000:0000:0000:0000:dead:beef:0002", "0000:0000:0000:0000:dead:beef:0003"). Prefixes of IPv6 CIDR blocks should be even multiples of 16 bits, otherwise they can potentially expand out to a 32,768-element array, each! =cut sub cidr2octets { my @cidr=@_; my @r; while ($#cidr >= 0) { my $cidr=shift @cidr; $cidr =~ s/\s//g; croak "CIDR doesn't look like a CIDR\n" unless ($cidr =~ /(.*)\/(.*)/); my ($ip, $pfix)=($1, $2); my $isipv6; my @ips=_iptoipa($ip); $isipv6=shift @ips; croak "$pfix, as in '$cidr', does not make sense" unless $pfix >= 0 && $pfix <= ($#ips+1) * 8 && $pfix =~ /^[0-9]+$/; my $i; for ($i=0; $i <= $#ips; $i++) { last if $pfix - $i * 8 < 8; } my @msb=splice @ips, 0, $i; my $bitsleft= $pfix - $i * 8; if ($#ips < 0 || $bitsleft == 0) { if ($pfix == 0 && $bitsleft == 0) { foreach (0..255) { my @n=($_); if ($isipv6) { _push_ipv6_octets(\@r, \@n); } else { push @r, $n[0]; } } } elsif ($isipv6) { _push_ipv6_octets(\@r, \@msb); } else { push @r, join(".", @msb); } next; } my @rr=_cidr2range8(($ips[0], $bitsleft)); while ($#rr >= 0) { my $a=shift @rr; my $b=shift @rr; grep { if ($isipv6) { push @msb, $_; _push_ipv6_octets(\@r, \@msb); pop @msb; } else { push @r, join(".", (@msb, $_)); } } ($a .. $b); } } return @r; } sub _push_ipv6_octets { my $ary_ref=shift; my $octets=shift; if ( ($#{$octets} % 2) == 0) # Odd number of octets { foreach (0 .. 255) { push @$octets, $_; _push_ipv6_octets($ary_ref, $octets); pop @$octets; } return; } my $i; my $s=""; for ($i=0; $i <= $#{$octets}; $i += 2) { $s .= ":" if $s ne ""; $s .= sprintf("%02x%02x", $$octets[$i], $$octets[$i+1]); } push @$ary_ref, $s; } =pod =head2 @cidr_list=Net::CIDR::cidradd($block, @cidr_list); The cidradd() functions allows a CIDR list to be built one CIDR netblock at a time, merging adjacent and overlapping ranges. $block is a single netblock, expressed as either "start-finish", or "address/prefix". Example: @cidr_list=Net::CIDR::range2cidr("192.168.0.0-192.168.0.255"); @cidr_list=Net::CIDR::cidradd("10.0.0.0/8", @cidr_list); @cidr_list=Net::CIDR::cidradd("192.168.1.0-192.168.1.255", @cidr_list); The result is a two-element array: ("10.0.0.0/8", "192.168.0.0/23"). IPv6 addresses are handled in an analogous fashion. =cut sub cidradd { my @cidr=@_; my $ip=shift @cidr; $ip="$ip-$ip" unless $ip =~ /[-\/]/; unshift @cidr, $ip; @cidr=cidr2range(@cidr); my @a; my @b; grep { croak "This doesn't look like start-end\n" unless /(.*)-(.*)/; push @a, $1; push @b, $2; } @cidr; my $lo=shift @a; my $hi=shift @b; my $i; for ($i=0; $i <= $#a; $i++) { last if _ipcmp($lo, $hi) > 0; next if _ipcmp($b[$i], $lo) < 0; next if _ipcmp($hi, $a[$i]) < 0; if (_ipcmp($a[$i],$lo) <= 0 && _ipcmp($hi, $b[$i]) <= 0) { $lo=_add1($hi); last; } if (_ipcmp($a[$i],$lo) <= 0) { $lo=_add1($b[$i]); next; } if (_ipcmp($hi, $b[$i]) <= 0) { $hi=_sub1($a[$i]); next; } $a[$i]=undef; $b[$i]=undef; } unless ((! defined $lo) || (! defined $hi) || _ipcmp($lo, $hi) > 0) { push @a, $lo; push @b, $hi; } @cidr=(); @a=grep ( (defined $_), @a); @b=grep ( (defined $_), @b); for ($i=0; $i <= $#a; $i++) { push @cidr, "$a[$i]-$b[$i]"; } @cidr=sort { $a =~ /(.*)-/; my $c=$1; $b =~ /(.*)-/; my $d=$1; my $e=_ipcmp($c, $d); return $e; } @cidr; $i=0; while ($i < $#cidr) { $cidr[$i] =~ /(.*)-(.*)/; my ($k, $l)=($1, $2); $cidr[$i+1] =~ /(.*)-(.*)/; my ($m, $n)=($1, $2); if (_ipcmp( _add1($l), $m) == 0) { splice @cidr, $i, 2, "$k-$n"; next; } ++$i; } return range2cidr(@cidr); } sub _add1 { my $n=shift; my $isipv6; ($isipv6, $n)=_ipv6to4($n); my @ip=split(/\./, $n); my $i=$#ip; while ($i >= 0) { last if ++$ip[$i] < 256; $ip[$i]=0; --$i; } return undef if $i < 0; $i=join(".", @ip); $i=_ipv4to6($i) if $isipv6; return $i; } sub _sub1 { my $n=shift; my $isipv6; ($isipv6, $n)=_ipv6to4($n); my @ip=split(/\./, $n); my $i=$#ip; while ($i >= 0) { last if --$ip[$i] >= 0; $ip[$i]=255; --$i; } return undef if $i < 0; $i=join(".", @ip); $i=_ipv4to6($i) if $isipv6; return $i; } =pod =head2 $found=Net::CIDR::cidrlookup($ip, @cidr_list); Search for $ip in @cidr_list. $ip can be a single IP address, or a netblock in CIDR or start-finish notation. lookup() returns 1 if $ip overlaps any netblock in @cidr_list, 0 if not. =cut sub cidrlookup { my @cidr=@_; my $ip=shift @cidr; $ip="$ip-$ip" unless $ip =~ /[-\/]/; unshift @cidr, $ip; @cidr=cidr2range(@cidr); my @a; my @b; grep { croak "This doesn't look like start-end\n" unless /(.*)-(.*)/; push @a, $1; push @b, $2; } @cidr; my $lo=shift @a; my $hi=shift @b; my $i; for ($i=0; $i <= $#a; $i++) { next if _ipcmp($b[$i], $lo) < 0; next if _ipcmp($hi, $a[$i]) < 0; return 1; } return 0; } =pod =head2 $ip=Net::CIDR::cidrvalidate($ip); Validate whether $ip is a valid IPv4 or IPv6 address, or a CIDR. Returns its argument or undef. Spaces are removed, and IPv6 hexadecimal address are converted to lowercase. $ip with less than four octets gets filled out with additional octets, and the modified value gets returned. This turns "192.168/16" into a proper "192.168.0.0/16". If $ip contains a "/", it must be a valid CIDR, otherwise it must be a valid IPv4 or an IPv6 address. A technically invalid CIDR, such as "192.168.0.1/24" fails validation, returning undef. =cut sub cidrvalidate { my $v=shift; $v =~ s/\s//g; $v=lc($v); my $suffix; ($v, $suffix)=($1, $2) if $v =~ m@(.*)/(.*)@; if (defined $suffix) { return undef unless $suffix =~ /^\d+$/ && ($suffix eq "0" || $suffix =~ /^[123456789]/); } if ($v =~ /^([0-9\.]+)$/ || $v =~ /^::ffff:([0-9\.]+)$/ || $v =~ /^:([0-9\.]+)$/) { my $n=$1; return undef if $n =~ /^\./ || $n =~ /\.$/ || $n =~ /\.\./; my @o= split(/\./, $n); while ($#o < 3) { push @o, "0"; } $n=join(".", @o); return undef if $#o != 3; foreach (@o) { return undef if /^0./; return undef if $_ < 0 || $_ > 255; } if ($v =~ /^::ffff/) { $suffix=128 unless defined $suffix; return undef if $suffix < 128-32; $suffix -= 128-32; } else { $suffix=32 unless defined $suffix; } foreach (addr2cidr($n)) { return $_ if $_ eq "$n/$suffix"; } return undef; } return undef unless $v =~ /^[0-9a-f:]+$/; return undef if $v =~ /:::/ || $v =~ /^:[^:]/ || $v =~ /[^:]:$/ || $v =~ /::.*::/; my @o=grep (/./, split(/:/, $v)); return undef if ($#o >= 8 || ($#o<7 && $v !~ /::/)); foreach (@o) { return undef if length ($_) > 4; } $suffix=128 unless defined $suffix; $v =~ s/([0-9A-Fa-f]+)/_triml0($1)/ge; foreach (addr2cidr($v)) { return $_ if $_ eq "$v/$suffix"; } return undef; } sub _triml0 { my ($a) = @_; $a =~ s/^0+//g; $a = "0" if $a eq ''; return $a } =pod =head1 BUGS Garbage in, garbage out. Always use cidrvalidate() before doing anything with untrusted input. Otherwise, "slightly" invalid input will work (extraneous whitespace is generally OK), but the functions will croak if you're totally off the wall. =head1 AUTHOR Sam Varshavchik <sam@email-scan.com> With some contributions from David Cantrell <david@cantrell.org.uk> =cut __END__