#!/usr/bin/perl package NetAddr::IP::Lite; use Carp; use strict; #use diagnostics; #use warnings; use NetAddr::IP::InetBase qw( inet_any2n isIPv4 inet_n2dx inet_aton ipv6_aton ipv6_n2x fillIPv4 ); use NetAddr::IP::Util qw( addconst sub128 ipv6to4 notcontiguous shiftleft hasbits bin2bcd bcd2bin mask4to6 ipv4to6 naip_gethostbyname havegethostbyname2 ); use vars qw(@ISA @EXPORT_OK $VERSION $Accept_Binary_IP $Old_nth $NoFQDN $AUTOLOAD *Zero); $VERSION = do { my @r = (q$Revision: 1.57 $ =~ /\d+/g); sprintf "%d."."%02d" x $#r, @r }; require Exporter; @ISA = qw(Exporter); @EXPORT_OK = qw(Zeros Zero Ones V4mask V4net); # Set to true, to enable recognizing of ipV4 && ipV6 binary notation IP # addresses. Thanks to Steve Snodgrass for reporting. This can be done # at the time of use-ing the module. See docs for details. $Accept_Binary_IP = 0; $Old_nth = 0; *Zero = \&Zeros; =pod =encoding UTF-8 =head1 NAME NetAddr::IP::Lite - Manages IPv4 and IPv6 addresses and subnets =head1 SYNOPSIS use NetAddr::IP::Lite qw( Zeros Ones V4mask V4net :aton DEPRECATED ! :old_nth :upper :lower :nofqdn ); my $ip = new NetAddr::IP::Lite '127.0.0.1'; or if your prefer my $ip = NetAddr::IP::Lite->new('127.0.0.1); or from a packed IPv4 address my $ip = new_from_aton NetAddr::IP::Lite (inet_aton('127.0.0.1')); or from an octal filtered IPv4 address my $ip = new_no NetAddr::IP::Lite '127.012.0.0'; print "The address is ", $ip->addr, " with mask ", $ip->mask, "\n" ; if ($ip->within(new NetAddr::IP::Lite "127.0.0.0", "255.0.0.0")) { print "Is a loopback address\n"; } # This prints 127.0.0.1/32 print "You can also say $ip...\n"; The following four functions return ipV6 representations of: :: = Zeros(); FFFF:FFFF:FFFF:FFFF:FFFF:FFFF:FFFF:FFFF = Ones(); FFFF:FFFF:FFFF:FFFF:FFFF:FFFF:: = V4mask(); ::FFFF:FFFF = V4net(); Will also return an ipV4 or ipV6 representation of a resolvable Fully Qualified Domanin Name (FQDN). =head1 INSTALLATION Un-tar the distribution in an appropriate directory and type: perl Makefile.PL make make test make install B depends on B which installs by default with its primary functions compiled using Perl's XS extensions to build a 'C' library. If you do not have a 'C' complier available or would like the slower Pure Perl version for some other reason, then type: perl Makefile.PL -noxs make make test make install =head1 DESCRIPTION This module provides an object-oriented abstraction on top of IP addresses or IP subnets, that allows for easy manipulations. Most of the operations of NetAddr::IP are supported. This module will work with older versions of Perl and is compatible with Math::BigInt. * By default B functions and methods return string IPv6 addresses in uppercase. To change that to lowercase: NOTE: the AUGUST 2010 RFC5952 states: 4.3. Lowercase The characters "a", "b", "c", "d", "e", and "f" in an IPv6 address MUST be represented in lowercase. It is recommended that all NEW applications using NetAddr::IP::Lite be invoked as shown on the next line. use NetAddr::IP::Lite qw(:lower); * To ensure the current IPv6 string case behavior even if the default changes: use NetAddr::IP::Lite qw(:upper); The internal representation of all IP objects is in 128 bit IPv6 notation. IPv4 and IPv6 objects may be freely mixed. The supported operations are described below: =cut # in the off chance that NetAddr::IP::Lite objects are created # and the caller later loads NetAddr::IP and expects to use # those objects, let the AUTOLOAD routine find and redirect # NetAddr::IP::Lite method and subroutine calls to NetAddr::IP. # my $parent = 'NetAddr::IP'; # test function # # input: subroutine name in NetAddr::IP # output: t/f if sub name exists in NetAddr::IP namespace # #sub sub_exists { # my $other = $parent .'::'; # return exists ${$other}{$_[0]}; #} sub DESTROY {}; sub AUTOLOAD { no strict; my ($pkg,$func) = ($AUTOLOAD =~ /(.*)::([^:]+)$/); my $other = $parent .'::'; if ($pkg =~ /^$other/o && exists ${$other}{$func}) { $other .= $func; goto &{$other}; } my @stack = caller(0); if ( $pkg eq ref $_[0] ) { $other = qq|Can't locate object method "$func" via|; } else { $other = qq|Undefined subroutine \&$AUTOLOAD not found in|; } die $other . qq| package "$parent" or "$pkg" (did you forgot to load a module?) at $stack[1] line $stack[2].\n|; } =head2 Overloaded Operators =cut # these really should be packed in Network Long order but since they are # symmetrical, that extra internal processing can be skipped my $_v4zero = pack('L',0); my $_zero = pack('L4',0,0,0,0); my $_ones = ~$_zero; my $_v4mask = pack('L4',0xffffffff,0xffffffff,0xffffffff,0); my $_v4net = ~ $_v4mask; my $_ipv4FFFF = pack('N4',0,0,0xffff,0); sub Zeros() { return $_zero; } sub Ones() { return $_ones; } sub V4mask() { return $_v4mask; } sub V4net() { return $_v4net; } ############################################# # These are the overload methods, placed here # for convenience. ############################################# use overload '+' => \&plus, '-' => \&minus, '++' => \&plusplus, '--' => \&minusminus, "=" => \©, '""' => sub { $_[0]->cidr(); }, 'eq' => sub { my $a = (UNIVERSAL::isa($_[0],__PACKAGE__)) ? $_[0]->cidr : $_[0]; my $b = (UNIVERSAL::isa($_[1],__PACKAGE__)) ? $_[1]->cidr : $_[1]; $a eq $b; }, 'ne' => sub { my $a = (UNIVERSAL::isa($_[0],__PACKAGE__)) ? $_[0]->cidr : $_[0]; my $b = (UNIVERSAL::isa($_[1],__PACKAGE__)) ? $_[1]->cidr : $_[1]; $a ne $b; }, '==' => sub { return 0 unless UNIVERSAL::isa($_[0],__PACKAGE__) && UNIVERSAL::isa($_[1],__PACKAGE__); $_[0]->cidr eq $_[1]->cidr; }, '!=' => sub { return 1 unless UNIVERSAL::isa($_[0],__PACKAGE__) && UNIVERSAL::isa($_[1],__PACKAGE__); $_[0]->cidr ne $_[1]->cidr; }, '>' => sub { return &comp_addr_mask > 0 ? 1 : 0; }, '<' => sub { return &comp_addr_mask < 0 ? 1 : 0; }, '>=' => sub { return &comp_addr_mask < 0 ? 0 : 1; }, '<=' => sub { return &comp_addr_mask > 0 ? 0 : 1; }, '<=>' => \&comp_addr_mask, 'cmp' => \&comp_addr_mask; sub comp_addr_mask { my($c,$rv) = sub128($_[0]->{addr},$_[1]->{addr}); return -1 unless $c; return 1 if hasbits($rv); ($c,$rv) = sub128($_[0]->{mask},$_[1]->{mask}); return -1 unless $c; return hasbits($rv) ? 1 : 0; } #sub comp_addr { # my($c,$rv) = sub128($_[0]->{addr},$_[1]->{addr}); # return -1 unless $c; # return hasbits($rv) ? 1 : 0; #} =pod =over =item B)> Has been optimized to copy one NetAddr::IP::Lite object to another very quickly. =item Bcopy()>> The B)> operation is only put in to operation when the copied object is further mutated by another overloaded operation. See L B for details. Bcopy()>> actually creates a new object when called. =cut sub copy { return _new($_[0],$_[0]->{addr}, $_[0]->{mask}); } =item B An object can be used just as a string. For instance, the following code my $ip = new NetAddr::IP::Lite '192.168.1.123'; print "$ip\n"; Will print the string 192.168.1.123/32. my $ip = new6 NetAddr::IP::Lite '192.168.1.123'; print "$ip\n"; Will print the string 0:0:0:0:0:0:C0A8:17B/128 =item B You can test for equality with either C, C, C<==> or C. C, C allows the comparison with arbitrary strings as well as NetAddr::IP::Lite objects. The following example: if (NetAddr::IP::Lite->new('127.0.0.1','255.0.0.0') eq '127.0.0.1/8') { print "Yes\n"; } Will print out "Yes". Comparison with C<==> and C requires both operands to be NetAddr::IP::Lite objects. =item B, E, E=, E=, E=E and C> Internally, all network objects are represented in 128 bit format. The numeric representation of the network is compared through the corresponding operation. Comparisons are tried first on the address portion of the object and if that is equal then the NUMERIC cidr portion of the masks are compared. This leads to the counterintuitive result that /24 > /16 Comparison should not be done on netaddr objects with different CIDR as this may produce indeterminate - unexpected results, rather the determination of which netblock is larger or smaller should be done by comparing $ip1->masklen <=> $ip2->masklen =item B)> Add a 32 bit signed constant to the address part of a NetAddr object. This operation changes the address part to point so many hosts above the current objects start address. For instance, this code: print NetAddr::IP::Lite->new('127.0.0.1/8') + 5; will output 127.0.0.6/8. The address will wrap around at the broadcast back to the network address. This code: print NetAddr::IP::Lite->new('10.0.0.1/24') + 255; outputs 10.0.0.0/24. Returns the the unchanged object when the constant is missing or out of range. 2147483647 <= constant >= -2147483648 =cut sub plus { my $ip = shift; my $const = shift; return $ip unless $const && $const < 2147483648 && $const > -2147483649; my $a = $ip->{addr}; my $m = $ip->{mask}; my $lo = $a & ~$m; my $hi = $a & $m; my $new = ((addconst($lo,$const))[1] & ~$m) | $hi; return _new($ip,$new,$m); } =item B)> The complement of the addition of a constant. =item B)> Returns the difference between the address parts of two NetAddr::IP::Lite objects address parts as a 32 bit signed number. Returns B if the difference is out of range. =cut my $_smsk = pack('L3N',0xffffffff,0xffffffff,0xffffffff,0x80000000); sub minus { my $ip = shift; my $arg = shift; unless (ref $arg) { return plus($ip, -$arg); } my($carry,$dif) = sub128($ip->{addr},$arg->{addr}); if ($carry) { # value is positive return undef if hasbits($dif & $_smsk); # all sign bits should be 0's return (unpack('L3N',$dif))[3]; } else { return undef if hasbits(($dif & $_smsk) ^ $_smsk); # sign is 1's return (unpack('L3N',$dif))[3] - 4294967296; } } # Auto-increment an object =item B Auto-incrementing a NetAddr::IP::Lite object causes the address part to be adjusted to the next host address within the subnet. It will wrap at the broadcast address and start again from the network address. =cut sub plusplus { my $ip = shift; my $a = $ip->{addr}; my $m = $ip->{mask}; my $lo = $a & ~ $m; my $hi = $a & $m; $ip->{addr} = ((addconst($lo,1))[1] & ~ $m) | $hi; return $ip; } =item B Auto-decrementing a NetAddr::IP::Lite object performs exactly the opposite of auto-incrementing it, as you would expect. =cut sub minusminus { my $ip = shift; my $a = $ip->{addr}; my $m = $ip->{mask}; my $lo = $a & ~$m; my $hi = $a & $m; $ip->{addr} = ((addconst($lo,-1))[1] & ~$m) | $hi; return $ip; } ############################################# # End of the overload methods. ############################################# # Preloaded methods go here. # This is a variant to ->new() that # creates and blesses a new object # without the fancy parsing of # IP formats and shorthands. # return a blessed IP object without parsing # input: prototype, naddr, nmask # returns: blessed IP object # sub _new ($$$) { my $proto = shift; my $class = ref($proto) || die "reference required"; $proto = $proto->{isv6}; my $self = { addr => $_[0], mask => $_[1], isv6 => $proto, }; return bless $self, $class; } =pod =back =head2 Methods =over =item C<-Enew([$addr, [ $mask|IPv6 ]])> =item C<-Enew6([$addr, [ $mask]])> =item C<-Enew6FFFF([$addr, [ $mask]])> =item C<-Enew_no([$addr, [ $mask]])> =item C<-Enew_from_aton($netaddr)> =item new_cis and new_cis6 are DEPRECATED =item C<-Enew_cis("$addr $mask)> =item C<-Enew_cis6("$addr $mask)> The first three methods create a new address with the supplied address in C<$addr> and an optional netmask C<$mask>, which can be omitted to get a /32 or /128 netmask for IPv4 / IPv6 addresses respectively. new6FFFF specifically returns an IPv4 address in IPv6 format according to RFC4291 new6 ::xxxx:xxxx new6FFFF ::FFFF:xxxx:xxxx The third method C is exclusively for IPv4 addresses and filters improperly formatted dot quad strings for leading 0's that would normally be interpreted as octal format by NetAddr per the specifications for inet_aton. B takes a packed IPv4 address and assumes a /32 mask. This function replaces the DEPRECATED :aton functionality which is fundamentally broken. The last two methods B and B differ from B and B only in that they except the common Cisco address notation for address/mask pairs with a B as a separator instead of a slash (/) These methods are DEPRECATED because the functionality is now included in the other "new" methods i.e. ->new_cis('1.2.3.0 24') or ->new_cis6('::1.2.3.0 120') C<-Enew6> and C<-Enew_cis6> mark the address as being in ipV6 address space even if the format would suggest otherwise. i.e. ->new6('1.2.3.4') will result in ::102:304 addresses submitted to ->new in ipV6 notation will remain in that notation permanently. i.e. ->new('::1.2.3.4') will result in ::102:304 whereas new('1.2.3.4') would print out as 1.2.3.4 See "STRINGIFICATION" below. C<$addr> can be almost anything that can be resolved to an IP address in all the notations I have seen over time. It can optionally contain the mask in CIDR notation. If the OPTIONAL perl module Socket6 is available in the local library it will autoload and ipV6 host6 names will be resolved as well as ipV4 hostnames. B notation is understood, with the limitation that the range specified by the prefix must match with a valid subnet. Addresses in the same format returned by C or C can also be understood, although no mask can be specified for them. The default is to not attempt to recognize this format, as it seems to be seldom used. ###### DEPRECATED, will be remove in version 5 ############ To accept addresses in that format, invoke the module as in use NetAddr::IP::Lite ':aton' ###### USE new_from_aton instead ########################## If called with no arguments, 'default' is assumed. If called with an empty string as the argument, returns 'undef' C<$addr> can be any of the following and possibly more... n.n n.n/mm n.n mm n.n.n n.n.n/mm n.n.n mm n.n.n.n n.n.n.n/mm 32 bit cidr notation n.n.n.n mm n.n.n.n/m.m.m.m n.n.n.n m.m.m.m loopback, localhost, broadcast, any, default x.x.x.x/host 0xABCDEF, 0b111111000101011110, (or a bcd number) a netaddr as returned by 'inet_aton' Any RFC1884 notation ::n.n.n.n ::n.n.n.n/mmm 128 bit cidr notation ::n.n.n.n/::m.m.m.m ::x:x ::x:x/mmm x:x:x:x:x:x:x:x x:x:x:x:x:x:x:x/mmm x:x:x:x:x:x:x:x/m:m:m:m:m:m:m:m any RFC1884 notation loopback, localhost, unspecified, any, default ::x:x/host 0xABCDEF, 0b111111000101011110 within the limits of perl's number resolution 123456789012 a 'big' bcd number (bigger than perl likes) and Math::BigInt A Fully Qualified Domain Name which returns an ipV4 address or an ipV6 address, embodied in that order. This previously undocumented feature may be disabled with: use NetAddr::IP::Lite ':nofqdn'; If called with no arguments, 'default' is assumed. If called with and empty string as the argument, 'undef' is returned; =cut my $lbmask = inet_aton('255.0.0.0'); my $_p4broad = inet_any2n('255.255.255.255'); my $_p4loop = inet_any2n('127.0.0.1'); my $_p4mloop = inet_aton('255.0.0.0'); $_p4mloop = mask4to6($_p4mloop); my $_p6loop = inet_any2n('::1'); my %fip4 = ( default => Zeros, any => Zeros, broadcast => $_p4broad, loopback => $_p4loop, unspecified => undef, ); my %fip4m = ( default => Zeros, any => Zeros, broadcast => Ones, loopback => $_p4mloop, unspecified => undef, # not applicable for ipV4 host => Ones, ); my %fip6 = ( default => Zeros, any => Zeros, broadcast => undef, # not applicable for ipV6 loopback => $_p6loop, unspecified => Zeros, ); my %fip6m = ( default => Zeros, any => Zeros, broadcast => undef, # not applicable for ipV6 loopback => Ones, unspecified => Ones, host => Ones, ); my $ff000000 = pack('L3N',0xffffffff,0xffffffff,0xffffffff,0xFF000000); my $ffff0000 = pack('L3N',0xffffffff,0xffffffff,0xffffffff,0xFFFF0000); my $ffffff00 = pack('L3N',0xffffffff,0xffffffff,0xffffffff,0xFFFFFF00); sub _obits ($$) { my($lo,$hi) = @_; return 0xFF if $lo == $hi; return (~ ($hi ^ $lo)) & 0xFF; } sub new_no($;$$) { unshift @_, -1; goto &_xnew; } sub new($;$$) { unshift @_, 0; goto &_xnew; } sub new_from_aton($$) { my $proto = shift; my $class = ref $proto || $proto || __PACKAGE__; my $ip = shift; return undef unless defined $ip; my $addrlen = length($ip); return undef unless $addrlen == 4; my $self = { addr => ipv4to6($ip), mask => &Ones, isv6 => 0, }; return bless $self, $class; } sub new6($;$$) { unshift @_, 1; goto &_xnew; } sub new6FFFF($;$$) { my $ip = _xnew(1,@_); $ip->{addr} |= $_ipv4FFFF; return $ip; } sub new_cis($;$$) { my @in = @_; if ( $in[1] && $in[1] =~ m!^(.+)\s+(.+)$! ) { $in[1] = $1 .'/'. $2; } @_ = (0,@in); goto &_xnew; } sub new_cis6($;$$) { my @in = @_; if ( $in[1] && $in[1] =~ m!^(.+)\s+(.+)$! ) { $in[1] = $1 .'/'. $2; } @_ = (1,@in); goto &_xnew; } sub _no_octal { # $_[0] =~ m/^(\d+)\.(\d+)\.(\d+)\.(\d+)$/; # return sprintf("%d.%d.%d.%d",$1,$2,$3,$4); (my $rv = $_[0]) =~ s#\b0*([1-9]\d*/?|0/?)#$1#g; # suppress leading zeros $rv; } sub _xnew($$;$$) { my $noctal = 0; my $isV6 = shift; if ($isV6 < 0) { # flag for no octal? $isV6 = 0; $noctal = 1; } my $proto = shift; my $class = ref $proto || $proto || __PACKAGE__; my $ip = shift; if ($ip && $noctal && $ip !~ m|(?:[^\s0123456789/. -])|) { # octal suppression required if not an IPv4 address $ip = _no_octal($ip); } # fix for bug #75976 return undef if defined $ip && $ip eq ''; $ip = 'default' unless defined $ip; $ip = _retMBIstring($ip) # treat as big bcd string if ref $ip && ref $ip eq 'Math::BigInt'; # can /CIDR notation my $hasmask = 1; my($mask,$tmp); # IP to lower case AFTER ref test for Math::BigInt. 'lc' strips blessing $ip = lc $ip; while (1) { # process IP's with no CIDR or that have the CIDR as part of the IP argument string unless (@_) { # if ($ip =~ m!^(.+)/(.+)$!) { if ($ip !~ /\D/) { # binary number notation $ip = bcd2bin($ip); $mask = Ones; last; } elsif ($ip =~ m!^([a-z0-9.:-]+)(?:/|\s+)([a-z0-9.:-]+)$! || $ip =~ m!^[\[]{1}([a-z0-9.:-]+)(?:/|\s+)([a-z0-9.:-]+)[\]]{1}$!) { $ip = $1; $mask = $2; } elsif (grep($ip eq $_,(qw(default any broadcast loopback unspecified)))) { $isV6 = 1 if $ip eq 'unspecified'; if ($isV6) { $mask = $fip6m{$ip}; return undef unless defined ($ip = $fip6{$ip}); } else { $mask = $fip4m{$ip}; return undef unless defined ($ip = $fip4{$ip}); } last; } } # process "ipv6" token and default IP's elsif (defined $_[0]) { if ($_[0] =~ /ipv6/i || $isV6) { if (grep($ip eq $_,(qw(default any loopback unspecified)))) { $mask = $fip6m{$ip}; $ip = $fip6{$ip}; last; } else { return undef unless $isV6; # add for ipv6 notation "12345, 1" } # $mask = lc $_[0]; # } else { # $mask = lc $_[0]; } # extract mask $mask = $_[0]; } ### ### process mask unless (defined $mask) { $hasmask = 0; $mask = 'host'; } # two kinds of IP's can turn on the isV6 flag # 1) big digits that are over the IPv4 boundry # 2) IPv6 IP syntax # # check these conditions and set isV6 as appropriate # my $try; $isV6 = 1 if # check big bcd and IPv6 rfc1884 ( $ip !~ /\D/ && # ip is all decimal (length($ip) > 3 || $ip > 255) && # exclude a single digit in the range of zero to 255, could be funny IPv4 ($try = bcd2bin($ip)) && ! isIPv4($try)) || # precedence so $try is not corrupted (index($ip,':') >= 0 && ($try = ipv6_aton($ip))); # fails if not an rfc1884 address # if either of the above conditions is true, $try contains the NetAddr 128 bit address # checkfor Math::BigInt mask $mask = _retMBIstring($mask) # treat as big bcd string if ref $mask && ref $mask eq 'Math::BigInt'; # MASK to lower case AFTER ref test for Math::BigInt, 'lc' strips blessing $mask = lc $mask; if ($mask !~ /\D/) { # bcd or CIDR notation my $isCIDR = length($mask) < 4 && $mask < 129; if ($isV6) { if ($isCIDR) { my($dq1,$dq2,$dq3,$dq4); if ($ip =~ /^(\d+)(?:|\.(\d+)(?:|\.(\d+)(?:|\.(\d+))))$/ && do {$dq1 = $1; $dq2 = $2 || 0; $dq3 = $3 || 0; $dq4 = $4 || 0; 1; } && $dq1 >= 0 && $dq1 < 256 && $dq2 >= 0 && $dq2 < 256 && $dq3 >= 0 && $dq3 < 256 && $dq4 >= 0 && $dq4 < 256 ) { # corner condition of IPv4 with isV6 $ip = join('.',$dq1,$dq2,$dq3,$dq4); $try = ipv4to6(inet_aton($ip)); if ($mask < 32) { $mask = shiftleft(Ones,32 -$mask); } elsif ($mask == 32) { $mask = Ones; } else { return undef; # undoubtably an error } } elsif ($mask < 128) { $mask = shiftleft(Ones,128 -$mask); # small cidr } else { $mask = Ones(); } } else { $mask = bcd2bin($mask); } } elsif ($isCIDR && $mask < 33) { # is V4 # if ($ip && $noctal && $ip !~ m|(?:[^\s0123456789.])|) { # octal suppression required if not an IPv4 address # $mask = _no_octal($mask); # } if ($mask < 32) { $mask = shiftleft(Ones,32 -$mask); } elsif ( $mask == 32) { $mask = Ones; } else { $mask = bcd2bin($mask); $mask |= $_v4mask; # v4 always } } else { # also V4 $mask = bcd2bin($mask); $mask |= $_v4mask; } if ($try) { # is a big number $ip = $try; last; } } elsif ($mask =~ m/^\d+\.\d+\.\d+\.\d+$/) { # ipv4 form of mask $mask = _no_octal($mask) if $noctal; # filter for octal return undef unless defined ($mask = inet_aton($mask)); $mask = mask4to6($mask); } elsif (grep($mask eq $_,qw(default any broadcast loopback unspecified host))) { if (index($ip,':') < 0 && ! $isV6) { return undef unless defined ($mask = $fip4m{$mask}); } else { return undef unless defined ($mask = $fip6m{$mask}); } } else { return undef unless defined ($mask = ipv6_aton($mask)); # try ipv6 form of mask } # process remaining IP's if (index($ip,':') < 0) { # ipv4 address if ($ip =~ m/^(\d+)\.(\d+)\.(\d+)\.(\d+)$/) { ; # the common case } elsif (grep($ip eq $_,(qw(default any broadcast loopback)))) { return undef unless defined ($ip = $fip4{$ip}); last; } elsif ($ip =~ m/^(\d+)\.(\d+)$/) { $ip = ($hasmask) ? "${1}.${2}.0.0" : "${1}.0.0.${2}"; } elsif ($ip =~ m/^(\d+)\.(\d+)\.(\d+)$/) { $ip = ($hasmask) ? "${1}.${2}.${3}.0" : "${1}.${2}.0.${3}"; } elsif ($ip =~ /^(\d+)$/ && $hasmask && $1 >= 0 and $1 < 256) { # pure numeric $ip = sprintf("%d.0.0.0",$1); } # elsif ($ip =~ /^\d+$/ && !$hasmask) { # a big integer elsif ($ip =~ /^\d+$/ ) { # a big integer $ip = bcd2bin($ip); last; } # these next three might be broken??? but they have been in the code a long time and no one has complained elsif ($ip =~ /^0[xb]\d+$/ && $hasmask && (($tmp = eval "$ip") || 1) && $tmp >= 0 && $tmp < 256) { $ip = sprintf("%d.0.0.0",$tmp); } elsif ($ip =~ /^-?\d+$/) { $ip += 2 ** 32 if $ip < 0; $ip = pack('L3N',0,0,0,$ip); last; } elsif ($ip =~ /^-?0[xb]\d+$/) { $ip = eval "$ip"; $ip = pack('L3N',0,0,0,$ip); last; } # notations below include an implicit mask specification elsif ($ip =~ m/^(\d+)\.$/) { $ip = "${1}.0.0.0"; $mask = $ff000000; } elsif ($ip =~ m/^(\d+)\.(\d+)-(\d+)\.?$/ && $2 <= $3 && $3 < 256) { $ip = "${1}.${2}.0.0"; $mask = pack('L3C4',0xffffffff,0xffffffff,0xffffffff,255,_obits($2,$3),0,0); } elsif ($ip =~ m/^(\d+)-(\d+)\.?$/ and $1 <= $2 && $2 < 256) { $ip = "${1}.0.0.0"; $mask = pack('L3C4',0xffffffff,0xffffffff,0xffffffff,_obits($1,$2),0,0,0) } elsif ($ip =~ m/^(\d+)\.(\d+)\.$/) { $ip = "${1}.${2}.0.0"; $mask = $ffff0000; } elsif ($ip =~ m/^(\d+)\.(\d+)\.(\d+)-(\d+)\.?$/ && $3 <= $4 && $4 < 256) { $ip = "${1}.${2}.${3}.0"; $mask = pack('L3C4',0xffffffff,0xffffffff,0xffffffff,255,255,_obits($3,$4),0); } elsif ($ip =~ m/^(\d+)\.(\d+)\.(\d+)\.$/) { $ip = "${1}.${2}.${3}.0"; $mask = $ffffff00; } elsif ($ip =~ m/^(\d+)\.(\d+)\.(\d+)\.(\d+)-(\d+)$/ && $4 <= $5 && $5 < 256) { $ip = "${1}.${2}.${3}.${4}"; $mask = pack('L3C4',0xffffffff,0xffffffff,0xffffffff,255,255,255,_obits($4,$5)); } elsif ($ip =~ m/^(\d+\.\d+\.\d+\.\d+) \s*-\s*(\d+\.\d+\.\d+\.\d+)$/x) { # if ($noctal) { # return undef unless ($ip = inet_aton(_no_octal($1))); # return undef unless ($tmp = inet_aton(_no_octal($2))); # } else { return undef unless ($ip = inet_aton($1)); return undef unless ($tmp = inet_aton($2)); # } # check for left side greater than right side # save numeric difference in $mask return undef if ($tmp = unpack('N',$tmp) - unpack('N',$ip)) < 0; $ip = ipv4to6($ip); $tmp = pack('L3N',0,0,0,$tmp); $mask = ~$tmp; return undef if notcontiguous($mask); # check for non-aligned left side return undef if hasbits($ip & $tmp); last; } # check for resolvable IPv4 hosts elsif (! $NoFQDN && $ip !~ /[^a-zA-Z0-9\._-]/ && ($tmp = gethostbyname(fillIPv4($ip))) && $tmp ne $_v4zero && $tmp ne $_zero ) { $ip = ipv4to6($tmp); last; } # check for resolvable IPv6 hosts elsif (! $NoFQDN && $ip !~ /[^a-zA-Z0-9\._-]/ && havegethostbyname2() && ($tmp = naip_gethostbyname($ip))) { $ip = $tmp; $isV6 = 1; last; } elsif ($Accept_Binary_IP && ! $hasmask) { if (length($ip) == 4) { $ip = ipv4to6($ip); } elsif (length($ip) == 16) { $isV6 = 1; } else { return undef; } last; } else { return undef; } return undef unless defined ($ip = inet_aton($ip)); $ip = ipv4to6($ip); last; } ########## continuing else { # ipv6 address $isV6 = 1; $ip = $1 if $ip =~ /\[([^\]]+)\]/; # transform URI notation if (defined ($tmp = ipv6_aton($ip))) { $ip = $tmp; last; } last if grep($ip eq $_,(qw(default any loopback unspecified))) && defined ($ip = $fip6{$ip}); return undef; } } # end while (1) return undef if notcontiguous($mask); # invalid if not contiguous my $self = { addr => $ip, mask => $mask, isv6 => $isV6, }; return bless $self, $class; } =item C<-Ebroadcast()> Returns a new object referring to the broadcast address of a given subnet. The broadcast address has all ones in all the bit positions where the netmask has zero bits. This is normally used to address all the hosts in a given subnet. =cut sub broadcast ($) { my $ip = _new($_[0],$_[0]->{addr} | ~$_[0]->{mask},$_[0]->{mask}); $ip->{addr} &= V4net unless $ip->{isv6}; return $ip; } =item C<-Enetwork()> Returns a new object referring to the network address of a given subnet. A network address has all zero bits where the bits of the netmask are zero. Normally this is used to refer to a subnet. =cut sub network ($) { return _new($_[0],$_[0]->{addr} & $_[0]->{mask},$_[0]->{mask}); } =item C<-Eaddr()> Returns a scalar with the address part of the object as an IPv4 or IPv6 text string as appropriate. This is useful for printing or for passing the address part of the NetAddr::IP::Lite object to other components that expect an IP address. If the object is an ipV6 address or was created using ->new6($ip) it will be reported in ipV6 hex format otherwise it will be reported in dot quad format only if it resides in ipV4 address space. =cut sub addr ($) { return ($_[0]->{isv6}) ? ipv6_n2x($_[0]->{addr}) : inet_n2dx($_[0]->{addr}); } =item C<-Emask()> Returns a scalar with the mask as an IPv4 or IPv6 text string as described above. =cut sub mask ($) { return ipv6_n2x($_[0]->{mask}) if $_[0]->{isv6}; my $mask = isIPv4($_[0]->{addr}) ? $_[0]->{mask} & V4net : $_[0]->{mask}; return inet_n2dx($mask); } =item C<-Emasklen()> Returns a scalar the number of one bits in the mask. =cut sub masklen ($) { my $len = (notcontiguous($_[0]->{mask}))[1]; return 0 unless $len; return $len if $_[0]->{isv6}; return isIPv4($_[0]->{addr}) ? $len -96 : $len; } =item C<-Ebits()> Returns the width of the address in bits. Normally 32 for v4 and 128 for v6. =cut sub bits { return $_[0]->{isv6} ? 128 : 32; } =item C<-Eversion()> Returns the version of the address or subnet. Currently this can be either 4 or 6. =cut sub version { my $self = shift; return $self->{isv6} ? 6 : 4; } =item C<-Ecidr()> Returns a scalar with the address and mask in CIDR notation. A NetAddr::IP::Lite object I to the result of this function. (see comments about ->new6() and ->addr() for output formats) =cut sub cidr ($) { return $_[0]->addr . '/' . $_[0]->masklen; } =item C<-Eaton()> Returns the address part of the NetAddr::IP::Lite object in the same format as the C or C function respectively. If the object was created using ->new6($ip), the address returned will always be in ipV6 format, even for addresses in ipV4 address space. =cut sub aton { return $_[0]->{addr} if $_[0]->{isv6}; return isIPv4($_[0]->{addr}) ? ipv6to4($_[0]->{addr}) : $_[0]->{addr}; } =item C<-Erange()> Returns a scalar with the base address and the broadcast address separated by a dash and spaces. This is called range notation. =cut sub range ($) { return $_[0]->network->addr . ' - ' . $_[0]->broadcast->addr; } =item C<-Enumeric()> When called in a scalar context, will return a numeric representation of the address part of the IP address. When called in an array context, it returns a list of two elements. The first element is as described, the second element is the numeric representation of the netmask. This method is essential for serializing the representation of a subnet. =cut sub numeric ($) { if (wantarray) { if (! $_[0]->{isv6} && isIPv4($_[0]->{addr})) { return ( sprintf("%u",unpack('N',ipv6to4($_[0]->{addr}))), sprintf("%u",unpack('N',ipv6to4($_[0]->{mask})))); } else { return ( bin2bcd($_[0]->{addr}), bin2bcd($_[0]->{mask})); } } return (! $_[0]->{isv6} && isIPv4($_[0]->{addr})) ? sprintf("%u",unpack('N',ipv6to4($_[0]->{addr}))) : bin2bcd($_[0]->{addr}); } =item C<-Ebigint()> When called in a scalar context, will return a Math::BigInt representation of the address part of the IP address. When called in an array contest, it returns a list of two elements. The first element is as described, the second element is the Math::BigInt representation of the netmask. =cut my $biloaded; my $bi2strng; my $no_mbi_emu = 1; # function to force into test development mode # sub _force_bi_emu { undef $biloaded; undef $bi2strng; $no_mbi_emu = 0; print STDERR "\n\n\tWARNING: test development mode, this \tmessage SHOULD NEVER BE SEEN IN PRODUCTION! set my \$no_mbi_emu = 1 in t/bigint.t to remove this warning\n\n"; } # function to stringify various flavors of Math::BigInt objects # tests to see if the object is a hash or a signed scalar sub _bi_stfy { "$_[0]" =~ /(\d+)/; # stringify and remove '+' if present $1; } sub _fakebi2strg { ${$_[0]} =~ /(\d+)/; $1; } # fake new from bi string Math::BigInt 0.01 # sub _bi_fake { bless \('+'. $_[1]), 'Math::BigInt'; } # as of this writing there are three known flavors of Math::BigInt # v0.01 MBI::new returns a scalar ref # v1.?? - 1.69 CALC::_new takes a reference to a scalar, returns an array, MBI returns a hash ref # v1.70 and up CALC::_new takes a scalar, returns and array, MBI returns a hash ref sub _loadMBI { # load Math::BigInt on demand if (eval {$no_mbi_emu && require Math::BigInt}) { # any version should work, three known import Math::BigInt; $biloaded = \&Math::BigInt::new; $bi2strng = \&_bi_stfy; } else { $biloaded = \&_bi_fake; $bi2strng = \&_fakebi2strg; } } sub _retMBIstring { _loadMBI unless $biloaded; # load Math::BigInt on demand $bi2strng->(@_); } sub _biRef { _loadMBI unless $biloaded; # load Math::BigInt on demand $biloaded->('Math::BigInt',$_[0]); } sub bigint($) { my($addr,$mask); if (wantarray) { if (! $_[0]->{isv6} && isIPv4($_[0]->{addr})) { $addr = $_[0]->{addr} ? sprintf("%u",unpack('N',ipv6to4($_[0]->{addr}))) : 0; $mask = $_[0]->{mask} ? sprintf("%u",unpack('N',ipv6to4($_[0]->{mask}))) : 0; } else { $addr = $_[0]->{addr} ? bin2bcd($_[0]->{addr}) : 0; $mask = $_[0]->{mask} ? bin2bcd($_[0]->{mask}) : 0; } (_biRef($addr),_biRef($mask)); } else { # not wantarray if (! $_[0]->{isv6} && isIPv4($_[0]->{addr})) { $addr = $_[0]->{addr} ? sprintf("%u",unpack('N',ipv6to4($_[0]->{addr}))) : 0; } else { $addr = $_[0]->{addr} ? bin2bcd($_[0]->{addr}) : 0; } _biRef($addr); } } =item C<$me-Econtains($other)> Returns true when C<$me> completely contains C<$other>. False is returned otherwise and C is returned if C<$me> and C<$other> are not both C objects. =cut sub contains ($$) { return within(@_[1,0]); } =item C<$me-Ewithin($other)> The complement of C<-Econtains()>. Returns true when C<$me> is completely contained within C<$other>, undef if C<$me> and C<$other> are not both C objects. =cut sub within ($$) { return 1 unless hasbits($_[1]->{mask}); # 0x0 contains everything my $netme = $_[0]->{addr} & $_[0]->{mask}; my $brdme = $_[0]->{addr} | ~ $_[0]->{mask}; my $neto = $_[1]->{addr} & $_[1]->{mask}; my $brdo = $_[1]->{addr} | ~ $_[1]->{mask}; return (sub128($netme,$neto) && sub128($brdo,$brdme)) ? 1 : 0; } =item C-Eis_rfc1918()> Returns true when C<$me> is an RFC 1918 address. 10.0.0.0 - 10.255.255.255 (10/8 prefix) 172.16.0.0 - 172.31.255.255 (172.16/12 prefix) 192.168.0.0 - 192.168.255.255 (192.168/16 prefix) =cut my $ip_10 = NetAddr::IP::Lite->new('10.0.0.0/8'); my $ip_10n = $ip_10->{addr}; # already the right value my $ip_10b = $ip_10n | ~ $ip_10->{mask}; my $ip_172 = NetAddr::IP::Lite->new('172.16.0.0/12'); my $ip_172n = $ip_172->{addr}; # already the right value my $ip_172b = $ip_172n | ~ $ip_172->{mask}; my $ip_192 = NetAddr::IP::Lite->new('192.168.0.0/16'); my $ip_192n = $ip_192->{addr}; # already the right value my $ip_192b = $ip_192n | ~ $ip_192->{mask}; sub is_rfc1918 ($) { my $netme = $_[0]->{addr} & $_[0]->{mask}; my $brdme = $_[0]->{addr} | ~ $_[0]->{mask}; return 1 if (sub128($netme,$ip_10n) && sub128($ip_10b,$brdme)); return 1 if (sub128($netme,$ip_192n) && sub128($ip_192b,$brdme)); return (sub128($netme,$ip_172n) && sub128($ip_172b,$brdme)) ? 1 : 0; } =item C<-Eis_local()> Returns true when C<$me> is a local network address. i.e. ipV4 127.0.0.0 - 127.255.255.255 or ipV6 === ::1 =cut my $_lclhost6 = NetAddr::IP::Lite->new('::1'); my $_lclnet = NetAddr::IP::Lite->new('127/8'); sub is_local ($) { return ($_[0]->{isv6}) ? $_[0] == $_lclhost6 : $_[0]->within($_lclnet); } =item C<-Efirst()> Returns a new object representing the first usable IP address within the subnet (ie, the first host address). =cut my $_cidr127 = pack('N4',0xffffffff,0xffffffff,0xffffffff,0xfffffffe); sub first ($) { if (hasbits($_[0]->{mask} ^ $_cidr127)) { return $_[0]->network + 1; } else { return $_[0]->network; } # return $_[0]->network + 1; } =item C<-Elast()> Returns a new object representing the last usable IP address within the subnet (ie, one less than the broadcast address). =cut sub last ($) { if (hasbits($_[0]->{mask} ^ $_cidr127)) { return $_[0]->broadcast - 1; } else { return $_[0]->broadcast; } # return $_[0]->broadcast - 1; } =item C<-Enth($index)> Returns a new object representing the I-th usable IP address within the subnet (ie, the I-th host address). If no address is available (for example, when the network is too small for C<$index> hosts), C is returned. Version 4.00 of NetAddr::IP and version 1.00 of NetAddr::IP::Lite implements C<-Enth($index)> and C<-Enum()> exactly as the documentation states. Previous versions behaved slightly differently and not in a consistent manner. To use the old behavior for C<-Enth($index)> and C<-Enum()>: use NetAddr::IP::Lite qw(:old_nth); old behavior: NetAddr::IP->new('10/32')->nth(0) == undef NetAddr::IP->new('10/32')->nth(1) == undef NetAddr::IP->new('10/31')->nth(0) == undef NetAddr::IP->new('10/31')->nth(1) == 10.0.0.1/31 NetAddr::IP->new('10/30')->nth(0) == undef NetAddr::IP->new('10/30')->nth(1) == 10.0.0.1/30 NetAddr::IP->new('10/30')->nth(2) == 10.0.0.2/30 NetAddr::IP->new('10/30')->nth(3) == 10.0.0.3/30 Note that in each case, the broadcast address is represented in the output set and that the 'zero'th index is alway undef except for a point-to-point /31 or /127 network where there are exactly two addresses in the network. new behavior: NetAddr::IP->new('10/32')->nth(0) == 10.0.0.0/32 NetAddr::IP->new('10.1/32'->nth(0) == 10.0.0.1/32 NetAddr::IP->new('10/31')->nth(0) == 10.0.0.0/32 NetAddr::IP->new('10/31')->nth(1) == 10.0.0.1/32 NetAddr::IP->new('10/30')->nth(0) == 10.0.0.1/30 NetAddr::IP->new('10/30')->nth(1) == 10.0.0.2/30 NetAddr::IP->new('10/30')->nth(2) == undef Note that a /32 net always has 1 usable address while a /31 has exactly two usable addresses for point-to-point addressing. The first index (0) returns the address immediately following the network address except for a /31 or /127 when it return the network address. =cut sub nth ($$) { my $self = shift; my $count = shift; my $slash31 = ! hasbits($self->{mask} ^ $_cidr127); if ($Old_nth) { return undef if $slash31 && $count != 1; return undef if ($count < 1 or $count > $self->num ()); } elsif ($slash31) { return undef if ($count && $count != 1); # only index 0, 1 allowed for /31 } else { ++$count; return undef if ($count < 1 or $count > $self->num ()); } return $self->network + $count; } =item C<-Enum()> As of version 4.42 of NetAddr::IP and version 1.27 of NetAddr::IP::Lite a /31 and /127 with return a net B value of 2 instead of 0 (zero) for point-to-point networks. Version 4.00 of NetAddr::IP and version 1.00 of NetAddr::IP::Lite return the number of usable IP addresses within the subnet, not counting the broadcast or network address. Previous versions worked only for ipV4 addresses, returned a maximum span of 2**32 and returned the number of IP addresses not counting the broadcast address. (one greater than the new behavior) To use the old behavior for C<-Enth($index)> and C<-Enum()>: use NetAddr::IP::Lite qw(:old_nth); WARNING: NetAddr::IP will calculate and return a numeric string for network ranges as large as 2**128. These values are TEXT strings and perl can treat them as integers for numeric calculations. Perl on 32 bit platforms only handles integer numbers up to 2**32 and on 64 bit platforms to 2**64. If you wish to manipulate numeric strings returned by NetAddr::IP that are larger than 2**32 or 2**64, respectively, you must load additional modules such as Math::BigInt, bignum or some similar package to do the integer math. =cut sub num ($) { if ($Old_nth) { my @net = unpack('L3N',$_[0]->{mask} ^ Ones); # number of ip's less broadcast return 0xfffffffe if $net[0] || $net[1] || $net[2]; # 2**32 -1 return $net[3] if $net[3]; } else { # returns 1 for /32 /128, 2 for /31 /127 else n-2 up to 2**32 (undef, my $net) = addconst($_[0]->{mask},1); return 1 unless hasbits($net); # ipV4/32 or ipV6/128 $net = $net ^ Ones; return 2 unless hasbits($net); # ipV4/31 or ipV6/127 $net &= $_v4net unless $_[0]->{isv6}; return bin2bcd($net); } } # deprecated #sub num ($) { # my @net = unpack('L3N',$_[0]->{mask} ^ Ones); # if ($Old_nth) { ## number of ip's less broadcast # return 0xfffffffe if $net[0] || $net[1] || $net[2]; # 2**32 -1 # return $net[3] if $net[3]; # } else { # returns 1 for /32 /128, 0 for /31 /127 else n-2 up to 2**32 ## number of usable IP's === number of ip's less broadcast & network addys # return 0xfffffffd if $net[0] || $net[1] || $net[2]; # 2**32 -2 # return 1 unless $net[3]; # $net[3]--; # } # return $net[3]; #} =pod =back =cut sub import { if (grep { $_ eq ':aton' } @_) { $Accept_Binary_IP = 1; @_ = grep { $_ ne ':aton' } @_; } if (grep { $_ eq ':old_nth' } @_) { $Old_nth = 1; @_ = grep { $_ ne ':old_nth' } @_; } if (grep { $_ eq ':lower' } @_) { NetAddr::IP::Util::lower(); @_ = grep { $_ ne ':lower' } @_; } if (grep { $_ eq ':upper' } @_) { NetAddr::IP::Util::upper(); @_ = grep { $_ ne ':upper' } @_; } if (grep { $_ eq ':nofqdn' } @_) { $NoFQDN = 1; @_ = grep { $_ ne ':nofqdn' } @_; } NetAddr::IP::Lite->export_to_level(1, @_); } =head1 EXPORT_OK Zeros Ones V4mask V4net :aton DEPRECATED :old_nth :upper :lower :nofqdn =head1 AUTHORS Luis E. Muñoz Eluismunoz@cpan.orgE, Michael Robinton Emichael@bizsystems.comE =head1 WARRANTY This software comes with the same warranty as perl itself (ie, none), so by using it you accept any and all the liability. =head1 COPYRIGHT This software is (c) Luis E. Muñoz, 1999 - 2005 and (c) Michael Robinton, 2006 - 2014. All rights reserved. This program is free software; you can redistribute it and/or modify it under the terms of either: a) the GNU General Public License as published by the Free Software Foundation; either version 2, or (at your option) any later version, or b) the "Artistic License" which comes with this distribution. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See either the GNU General Public License or the Artistic License for more details. You should have received a copy of the Artistic License with this distribution, in the file named "Artistic". If not, I'll be glad to provide one. You should also have received a copy of the GNU General Public License along with this program in the file named "Copying". If not, write to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor Boston, MA 02110-1301 USA or visit their web page on the internet at: http://www.gnu.org/copyleft/gpl.html. =head1 SEE ALSO NetAddr::IP(3), NetAddr::IP::Util(3), NetAddr::IP::InetBase(3) =cut 1;