use NetAddr::IP::Util qw( inet_aton inet_ntoa ipv6_aton ipv6_ntoa ipv6_n2x ipv6_n2d inet_any2n hasbits isIPv4 isNewIPv4 isAnyIPv4 inet_n2dx inet_n2ad inet_pton inet_ntop inet_4map6 ipv4to6 mask4to6 ipanyto6 maskanyto6 ipv6to4 packzeros shiftleft addconst add128 sub128 notcontiguous bin2bcd bcd2bin mode AF_INET AF_INET6 naip_gethostbyname ); use NetAddr::IP::Util qw(:all :inet :ipv4 :ipv6 :math) :inet => inet_aton, inet_ntoa, ipv6_aton ipv6_ntoa, ipv6_n2x, ipv6_n2d, inet_any2n, inet_n2dx, inet_n2ad, inet_pton, inet_ntop, inet_4map6, ipv4to6, mask4to6, ipanyto6, packzeros maskanyto6, ipv6to4, naip_gethostbyname :ipv4 => inet_aton, inet_ntoa :ipv6 => ipv6_aton, ipv6_ntoa, ipv6_n2x, ipv6_n2d, inet_any2n, inet_n2dx, inet_n2ad, inet_pton, inet_ntop, inet_4map6, ipv4to6, mask4to6, ipanyto6, maskanyto6, ipv6to4, packzeros, naip_gethostbyname :math => hasbits, isIPv4, isNewIPv4, isAnyIPv4, addconst, add128, sub128, notcontiguous, bin2bcd, bcd2bin, shiftleft $dotquad = inet_ntoa($netaddr); $netaddr = inet_aton($dotquad); $ipv6naddr = ipv6_aton($ipv6_text); $ipv6_text = ipvt_ntoa($ipv6naddr); $hex_text = ipv6_n2x($ipv6naddr); $dec_text = ipv6_n2d($ipv6naddr); $hex_text = packzeros($hex_text); $ipv6naddr = inet_any2n($dotquad or $ipv6_text); $ipv6naddr = inet_4map6($netaddr or $ipv6naddr); $rv = hasbits($bits128); $rv = isIPv4($bits128); $rv = isNewIPv4($bits128); $rv = isAnyIPv4($bits128); $dotquad or $hex_text = inet_n2dx($ipv6naddr); $dotquad or $dec_text = inet_n2ad($ipv6naddr); $netaddr = inet_pton($AF_family,$hex_text); $hex_text = inet_ntop($AF_family,$netaddr); $ipv6naddr = ipv4to6($netaddr); $ipv6naddr = mask4to6($netaddr); $ipv6naddr = ipanyto6($netaddr); $ipv6naddr = maskanyto6($netaddr); $netaddr = ipv6to4($pv6naddr); $bitsX2 = shiftleft($bits128,$n); $carry = addconst($ipv6naddr,$signed_32con); ($carry,$ipv6naddr)=addconst($ipv6naddr,$signed_32con); $carry = add128($ipv6naddr1,$ipv6naddr2); ($carry,$ipv6naddr)=add128($ipv6naddr1,$ipv6naddr2); $carry = sub128($ipv6naddr1,$ipv6naddr2); ($carry,$ipv6naddr)=sub128($ipv6naddr1,$ipv6naddr2); ($spurious,$cidr) = notcontiguous($mask128); $bcdtext = bin2bcd($bits128); $bits128 = bcd2bin($bcdtxt); $modetext = mode; ($name,$aliases,$addrtype,$length,@addrs)=naip_gethostbyname(NAME); $trueif = havegethostbyname2(); NetAddr::IP::Util::lower(); NetAddr::IP::Util::upper();
perl Makefile.PL make make test make install
NetAddr::IP::Util installs by default with its primary functions compiled using Perl's XS extensions to build a 'C' library. If you do not have a 'C' complier available or would like the slower Pure Perl version for some other reason, then type:
perl Makefile.PL -noxs make make test make install
and & or | xor ^ ~ compliment
in the same manner as 'vec' strings.
The IPv6 functions support all rfc1884 formats.
i.e. x:x:x:x:x:x:x:x:x x:x:x:x:x:x:x:d.d.d.d ::x:x:x ::x:d.d.d.d and so on...
Convert a packed IPv4 network address to a dot-quad IP address.
input: packed network address returns: IP address i.e. 10.4.12.123
Convert a dot-quad IP address into an IPv4 packed network address.
input: IP address i.e. 192.5.16.32 returns: packed network address
Takes an IPv6 address of the form described in rfc1884 and returns a 128 bit binary RDATA string.
input: ipv6 text returns: 128 bit RDATA string
Convert a 128 bit binary IPv6 address to compressed rfc 1884 text representation.
input: 128 bit RDATA string returns: ipv6 text
Takes an IPv6 RDATA string and returns an 8 segment IPv6 hex address
input: 128 bit RDATA string returns: x:x:x:x:x:x:x:x
Takes an IPv6 RDATA string and returns a mixed hex - decimal IPv6 address with the 6 uppermost chunks in hex and the lower 32 bits in dot-quad representation.
input: 128 bit RDATA string returns: x:x:x:x:x:x:d.d.d.d
This function converts a text IPv4 or IPv6 address in text format in any standard notation into a 128 bit IPv6 string address. It prefixes any dot-quad address (if found) with '::' and passes it to ipv6_aton.
input: dot-quad or rfc1844 address returns: 128 bit IPv6 string
This function returns true if there are one's present in the 128 bit string and false if all the bits are zero.
i.e. if (hasbits($bits128)) { &do_something; } or if (hasbits($bits128 & $mask128) { &do_something; }
This allows the implementation of logical functions of the form of:
if ($bits128 & $mask128) { ... input: 128 bit IPv6 string returns: true if any bits are present
This function returns an ipV6 network address with the first 80 bits set to zero and the next 16 bits set to one, while the last 32 bits are filled with the ipV4 address.
input: ipV4 netaddr or ipV6 netaddr returns: ipV6 netaddr returns: undef on error
An ipV6 network address must be in one of the two compatible ipV4 mapped address spaces. i.e.
::ffff::d.d.d.d or ::d.d.d.d
This function returns true if there are no on bits present in the IPv6 portion of the 128 bit string and false otherwise.
i.e. the address must be of the form - ::d.d.d.d
Note: this is an old and deprecated ipV4 compatible ipV6 address
This function return true if the IPv6 128 bit string is of the form
::ffff::d.d.d.d
This function return true if the IPv6 bit string is of the form
::d.d.d.d or ::ffff::d.d.d.d
This function does the right thing and returns the text for either a dot-quad IPv4 or a hex notation IPv6 address.
input: 128 bit IPv6 string returns: ddd.ddd.ddd.ddd or x:x:x:x:x:x:x:x
This function does the right thing and returns the text for either a dot-quad IPv4 or a hex::decimal notation IPv6 address.
input: 128 bit IPv6 string returns: ddd.ddd.ddd.ddd or x:x:x:x:x:x:ddd.ddd.ddd.dd
This function takes an IP address in IPv4 or IPv6 text format and converts it into binary format. The type of IP address conversion is controlled by the FAMILY argument.
This function takes and IP address in binary format and converts it into text format. The type of IP address conversion is controlled by the FAMILY argument.
NOTE: inet_ntop ALWAYS returns lowercase characters.
This function optimizes and rfc 1884 IPv6 hex address to reduce the number of long strings of zero bits as specified in rfc 1884, 2.2 (2) by substituting :: for the first occurence of the longest string of zeros in the address.
Convert an ipv4 network address into an IPv6 network address.
input: 32 bit network address returns: 128 bit network address
Convert an ipv4 network address/mask into an ipv6 network mask.
input: 32 bit network/mask address returns: 128 bit network/mask address
NOTE: returns the high 96 bits as one's
Similar to ipv4to6 except that this function takes either an IPv4 or IPv6 input and always returns a 128 bit IPv6 network address.
input: 32 or 128 bit network address returns: 128 bit network address
Similar to mask4to6 except that this function takes either an IPv4 or IPv6 netmask and always returns a 128 bit IPv6 netmask.
input: 32 or 128 bit network mask returns: 128 bit network mask
Truncate the upper 96 bits of a 128 bit address and return the lower 32 bits. Returns an IPv4 address as returned by inet_aton.
input: 128 bit network address returns: 32 bit inet_aton network address
input: 128 bit string variable, number of shifts [optional] returns: bits X n shifts NOTE: a single shift is performed if $n is not specified
Add a signed constant to a 128 bit string variable.
input: 128 bit IPv6 string, signed 32 bit integer returns: scalar carry array (carry, result)
Add two 128 bit string variables.
input: 128 bit string var1, 128 bit string var2 returns: scalar carry array (carry, result)
Subtract two 128 bit string variables.
input: 128 bit string var1, 128 bit string var2 returns: scalar carry array (carry, result)
Note: The carry from this operation is the result of adding the one's complement of ARG2 +1 to the ARG1. It is logically NOT borrow.
i.e. if ARG1 >= ARG2 then carry = 1 or if ARG1 < ARG2 then carry = 0
This function counts the bit positions remaining in the mask when the rightmost '0's are removed.
input: 128 bit netmask returns true if there are spurious zero bits remaining in the mask, false if the mask is contiguous one's, 128 bit cidr number
Convert a 128 bit binary string into binary coded decimal text digits.
input: 128 bit string variable returns: string of bcd text digits
Convert a bcd text string to 128 bit string variable
input: string of bcd text digits returns: 128 bit string variable
Returns the operating mode of this module.
input: none returns: "Pure Perl" or "CC XS"
Replacement for Perl's gethostbyname if Socket6 is available
In ARRAY context, returns a list of five elements, the hostname or NAME, a space separated list of C_NAMES, AF family, length of the address structure, and an array of one or more netaddr's
In SCALAR context, returns the first netaddr.
This function ALWAYS returns an IPv6 address, even on IPv4 only systems. IPv4 addresses are mapped into IPv6 space in the form:
::FFFF:FFFF:d.d.d.d
This is NOT the expected result from Perl's gethostbyname2. It is instead equivalent to:
On an IPv4 only system: $ipv6naddr = ipv4to6 scalar ( gethostbyname( name )); On a system with Socket6 and a working gethostbyname2: $ipv6naddr = gethostbyname2( name, AF_INET6 ); and if that fails, the IPv4 conversion above.
For a gethostbyname2 emulator that behave like Socket6, see: Net::DNS::Dig
This function returns TRUE if Socket6 has a functioning gethostbyname2, otherwise it returns FALSE. See the comments above about the behavior of naip_gethostbyname.
Return IPv6 strings in lowercase.
Return IPv6 strings in uppercase. This is the default.
# convert any textual IP address into a 128 bit vector # sub text2vec { my($anyIP,$anyMask) = @_; # not IPv4 bit mask my $notiv4 = ipv6_aton('FFFF:FFFF:FFFF:FFFF:FFFF:FFFF::'); my $vecip = inet_any2n($anyIP); my $mask = inet_any2n($anyMask); # extend mask bits for IPv4 my $bits = 128; # default unless (hasbits($mask & $notiv4)) { $mask |= $notiv4; $bits = 32; } return ($vecip, $mask, $bits); } ... alternate implementation, a little faster sub text2vec { my($anyIP,$anyMask) = @_; # not IPv4 bit mask my $notiv4 = ipv6_aton('FFFF:FFFF:FFFF:FFFF:FFFF:FFFF::'); my $vecip = inet_any2n($anyIP); my $mask = inet_any2n($anyMask); # extend mask bits for IPv4 my $bits = 128; # default if (isIPv4($mask)) { $mask |= $notiv4; $bits = 32; } return ($vecip, $mask, $bits); } ... elsewhere $nip = { addr => $vecip, mask => $mask, bits => $bits, }; # return network and broadcast addresses from IP and Mask # sub netbroad { my($nip) = shift; my $notmask = ~ $nip->{mask}; my $bcast = $nip->{addr} | $notmask; my $network = $nip->{addr} & $nip->{mask}; return ($network, $broadcast); } # check if address is within a network # sub within { my($nip,$net) = @_; my $addr = $nip->{addr} my($nw,$bc) = netbroad($net); # arg1 >= arg2, sub128 returns true return (sub128($addr,$nw) && sub128($bc,$addr)) ? 1 : 0; } # truely hard way to do $ip++ # add a constant, wrapping at netblock boundaries # to subtract the constant, negate it before calling # 'addwrap' since 'addconst' will extend the sign bits # sub addwrap { my($nip,$const) = @_; my $addr = $nip->{addr}; my $mask = $nip->{mask}; my $bits = $nip->{bits}; my $notmask = ~ $mask; my $hibits = $addr & $mask; $addr = addconst($addr,$const); my $wraponly = $addr & $notmask; my $newip = { addr => $hibits | $wraponly, mask => $mask, bits => $bits, }; # bless $newip as appropriate return $newip; } # something more useful # increment a /24 net to the NEXT net at the boundry my $nextnet = 256; # for /24 LOOP: while (...continuing) { your code.... ... my $lastip = $ip-copy(); $ip++; if ($ip < $lastip) { # host part wrapped? # discard carry (undef, $ip->{addr} = addconst($ip->{addr}, $nextnet); } next LOOP; }
inet_aton inet_ntoa ipv6_aton ipv6_ntoa ipv6_n2x ipv6_n2d inet_any2n hasbits isIPv4 isNewIPv4 isAnyIPv4 inet_n2dx inet_n2ad inet_pton inet_ntop inet_4map6 ipv4to6 mask4to6 ipanyto6 maskanyto6 ipv6to4 packzeros shiftleft addconst add128 sub128 notcontiguous bin2bcd bcd2bin mode naip_gethostbyname havegethostbyname2
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.