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What libs have you used for that? How compatible are they with one another? Or did you write your own parsing routine?

I'm particularly interested in mutually-compatible implementations for Java, C++, Python, and JavaScript, which support:

  • zero compression ("::")
  • IPv4-mapped addresses ("::ffff:123.45.67.89")
  • canonicalization (including to the short form, for human readability)
  • CIDR-style netmasks (like "/64" at the end)
share|improve this question

closed as too broad by Daniel A. White, gnat, amdixon, Nate Barbettini, jmoerdyk Dec 12 '15 at 0:10

There are either too many possible answers, or good answers would be too long for this format. Please add details to narrow the answer set or to isolate an issue that can be answered in a few paragraphs.If this question can be reworded to fit the rules in the help center, please edit the question.

11 Answers 11

up vote 6 down vote accepted

On POSIX systems you can use inet_pton and inet_ntop in combination to do canonicalization. You will still have to do your own CIDR parsing. Fortunately, I believe the only valid CIDR syntax for IPv6 is the /number_of_bits notation, so that's fairly easy.

The other issue you will run into is the lack of support for interface specifications. For link-local addresses, you will see things like %eth0 on the end to specify what link they are local too. getaddrinfo will parse that but inet_pton won't.

One strategy you could go for is using getaddrinfo to parse and inet_ntop to canonicalize.

getaddrinfo is available for Windows. inet_pton and inet_ntop aren't. Fortunately, it isn't too hard to write code to produce a canonical form IPv6 address. It will require two passes though because the rule for 0 compression is the biggest string of 0s that occurs first. Also IPv4 form (i.e. ::127.0.0.1) is only used for ::IPv4 or ::ffff:IPv4.

I have no Windows machine to test with, but from the documentation it appears that Python on Windows supports inet_pton and inet_ntop in its socket module.

Writing your own routine for producing a canonical form might not be a bad idea, since even if your canonical form isn't the same as everybody else's, as long as it's valid other people can parse it. But I would under no circumstances write a routine of your own to parse IPv6 addresses.

My advice above is good for Python, C, and C++. I know little or nothing about how to solve this problem in Java or Javascript.

EDIT: I have been examining getaddrinfo and its counterpart, getnameinfo. These are in almost all ways better than inet_pton and inet_ntop. They are thread safe, and you can pass them options (AI_NUMERICHOST in getaddrinfo's case, and NI_NUMERCHOST in getnameinfo's case) to keep them from doing any kind of DNS queries. Their interface is a little complex and reminds me of an ugly Windows interface in some respects, but it's fairly easy to figure out what options to pass to get what you want. I heartily recommend them both.

share|improve this answer
    
I would like to comment that after playing with getaddrinfo myself, the OSX 10.4 and glibc-2.10.1 versions both have interesting bugs. The OSX version has much worse bugs. – Omnifarious Sep 12 '09 at 2:33
    
Windows does support inet_pton and inet_ntop for Vista and later (see msdn.microsoft.com/en-us/library/cc805843%28VS.85%29.aspx). However, Python 2.6 and 3.0 does not (docs indicate Availability Unix). – Jason R. Coombs Oct 19 '09 at 23:27
1  
Watch out for speed in Windows. For some reason the Windows inet_pton and inet_ntop are horribly horribly slow. Or they were in my experience on Vista and Server 2008. – Zan Lynx Oct 20 '09 at 0:05
    
@Omnifarious, you wrote, "But I would under no circumstances write a routine of your own to parse IPv6 addresses." I did exactly that that fairly easily using RegEx, and it accepts all legal forms of IPv6 addressing (compressed, uncompressed, hybrid compressed, hybrid uncompressed, and upper or lower case versions of each, with or without the /<mask length>). The reverse routine will return the RFC 5259 "official" canonical representation of IPv6 addresses, including hybrid for /96 addresses. – Ron Maupin Oct 3 '15 at 2:41

In Java, You could use

InetAddress.getByName(IP)

and then check for exceptions thrown by this for validating IPv6 addresses

You could also use Sun Propreitary API if thats oK to you. THis will not perform a DNS lookup. ( They might change it/remove it without notice since its their propreitary API.This is a warning that will come when compiling a code using this )

boolean sun.net.util.IPAddressUtil.isIPv6LiteralAddress(String IP)
share|improve this answer
3  
Thanks for the idea. Unfortunately that method does a DNS lookup before throwing the exception. – ngn Sep 8 '09 at 8:01
    
Okie.. I looked into source code of InetAddress. Its using sun.net.util.IPAddressUtil class. Its a sun propreietary API. But if that's okie to you, you could use it. Use the static method isIPv6LiteralAddress(String IP). It returns true or false – vpram86 Sep 8 '09 at 8:43
    
IPAddressUtil works great. I guess I can cope with canonicalization too, via textToNumericFormatV*(String) and some custom formatting back to text. +1 and I wish I could accept more than one answer. – ngn Sep 11 '09 at 14:07
    
Wow. Glad i could help! :) No prob at all! – vpram86 Sep 11 '09 at 14:37
1  
You can use Guava's InetAddresses to avoid the lookup – Neil McGuigan Sep 27 '13 at 20:30

In Java, the Guava library has utility functions for validating IPv6 (and IPv4) in the com.google.common.net.InetAddresses class. http://goo.gl/RucRU

share|improve this answer

I wrote javascript-ipv6 for this very purpose. It currently powers v6decode.com.

Here's a short example of the API:

var address = new v6.Address("::ffff:7b2d:4359/64");

if (address.isValid()) {
   // Do something if the address is valid
}

console.log(address.correctForm());         // "::ffff:7b2d:4359"
console.log(address.canonicalForm());       // "0000:0000:0000:0000:0000:ffff:7b2d:4359"
console.log(address.v4Form());              // "::ffff:123.45.67.89"
console.log(address.subnetMask);            // "64"
console.log(address.possibleAddresses(96)); // "4,294,967,296"
share|improve this answer

I use a regular expression when os support may not be available - RE is available in most languages, including C/C++/Java/Python/Perl/bash/.... The following python code builds the RE at startup, the resulting RE source is a humdinger - but once compiled by the re engine is as fast as native code.

PAT_IP4 = r'\.'.join([r'(?:\d|[1-9]\d|1\d\d|2[0-4]\d|25[0-5])']*4)
RE_IP4 = re.compile(PAT_IP4+'$')
RE_IP6 = re.compile(                 '(?:%(hex4)s:){6}%(ls32)s$'
               '|::(?:%(hex4)s:){5}%(ls32)s$'
              '|(?:%(hex4)s)?::(?:%(hex4)s:){4}%(ls32)s$'
'|(?:(?:%(hex4)s:){0,1}%(hex4)s)?::(?:%(hex4)s:){3}%(ls32)s$'
'|(?:(?:%(hex4)s:){0,2}%(hex4)s)?::(?:%(hex4)s:){2}%(ls32)s$'
'|(?:(?:%(hex4)s:){0,3}%(hex4)s)?::%(hex4)s:%(ls32)s$'
'|(?:(?:%(hex4)s:){0,4}%(hex4)s)?::%(ls32)s$'
'|(?:(?:%(hex4)s:){0,5}%(hex4)s)?::%(hex4)s$'
'|(?:(?:%(hex4)s:){0,6}%(hex4)s)?::$'
  % {
'ls32': r'(?:[0-9a-f]{1,4}:[0-9a-f]{1,4}|%s)'%PAT_IP4,
'hex4': r'[0-9a-f]{1,4}'
}, re.IGNORECASE)
share|improve this answer

From what I can gather, you should use getaddrinfo() on systems that have it, i.e. Linux and POSIX places. There should be no need to write your own low-level parser.

Windows also provides getaddrinfo(), on XP and later.

share|improve this answer
    
I don't think getaddrinfo supports parsing subnet bit-slicing notation. It also doesn't support canonicalization. – Omnifarious Sep 7 '09 at 15:51

For Python, the best solution might be IPy (http://pypi.python.org/pypi/IPy/0.51)

share|improve this answer

getaddrinfo already returns the shortest textual form, so if you have the longer form you can canonicalize by running through getaddrinfo again. Example Python,

import sys, socket;
result = socket.getaddrinfo('0:0::0:1', None);
print "family:%i socktype:%i proto:%i canonname:%s sockaddr:%s"%result[0];

Outputs the following,

family:10 socktype:1 proto:6 canonname: sockaddr:('::1', 0, 0, 0)

IPv6 CIDR blocks don't appear to be well documented or defined so I wrote my own inet6_network implementation to handle that (C99).

share|improve this answer

i simply went through adhoc approach to check the validity of IPV4 and IPV6 both addressing scheme:here is my code ... corrections are always welcome in my code. and pardon me if my solution is wrong.

#include <cstdio>
#include <iostream>
#include <vector>
#include <stack>
#include <algorithm>
#include <sstream>
#include <utility>
#include <cmath>
#include <cstring>
#include <map>
#include <queue>
#include <limits.h>
using namespace std;
bool check6(string s)
{
    for(int i=0;i<s.length();i++)
    {
       if((s[i] < '0' || s[i] > '9') && (s[i] < 'a' || s[i]> 'f') && 
           (s[i] < 'A' || s[i] > 'F'))                       
          return false;
    }
    return true;
}
   bool check4(string s)
   {
      for(int i=0; i< s.length(); i++)
      {
       if(!(s[i]>= '0' && s[i] <= '9'))
          return false;
      }
     stringstream ss(s);
      int e;
      ss >> e;
     if( e < 0 || e > 255 )
      return false;
     else
      return true;
   }

int main()
{
  string s;
  cin>>s;
  vector<string> v;
  int i=0;
  int d=0;
  if((s.find(":")!=std::string::npos || 
         s.find("::")!=std::string::npos)&&  
     s.find(".")==std::string::npos)     
   {
      int x=0;
      while(i< s.length())
      {
          string s1 ="";
          while(i< s.length() && s[i]!= ':')
          {
             s1+= s[i];
             i++;
          }
         if(s1!="")
         v.push_back(s1);
         if((i+1)< s.length() && s[i]==':' && s[i+1]==':')
            x++;
         i++;
         if(i< s.length())
         d++;
     }
      if(x > 1 || d > 7 || v.size() > 8 || (x==1 && d >6))
      {
         cout<<"Not Valid"<<endl;
         return 0;
      }
      else if(d > 2 && v.size() ==0)
      {

         cout<<"Not Valid"<<endl;
         return 0;
      }
      else
      {
         for(int i=0;i< v.size();i++)
         {
             if((v[i]).length() > 4)
             {
                    cout<<"Not Valid"<<endl;
                 return 0;
              }
             else
             {
                if(!check6(v[i]))
                {

                    cout<<"Not Valid"<<endl;
                    return 0;
                }
            }
         }
         cout<<"Valid Ipv6"<<endl;
          return 0;
      }
   }
else if(s.find(":")==std::string::npos && s.find(".")!=std::string::npos)
{
    while(i< s.length())
    {
        string s1="";
        while( i< s.length() && s[i]!='.')
        {
            s1+=s[i];
            i++;
        }
        i++;
        if(i< s.length())
        d++;
        v.push_back(s1);
    }
    if(d > 4 || v.size()> 4)
    {
        cout<<"Not Valid"<<endl;
        return 0;
    }
    else
    {
        for(int i=0;i<v.size();i++)
        {
            if((v[i]).length() > 3)
            {
                cout<<"Not Valid"<<endl;
                return 0;
            }
            if(!check4(v[i]))
            {
                cout<<"Not Valid"<<endl;
                return 0;
            }
        }   
    }
    cout<<"Valid Ipv4"<<endl;
    return 0;
}

        cout<<"Not Valid"<<endl;

return 0;

}

share|improve this answer

It's too bad Python 3.1 lost the ipaddr lib.

It's still available as a third-party library: py-ipaddr available on PyPI.

Compression

>>> ipaddr.IPv6Address('0:0::0:1').compressed
'::1'

IPv4 mapping

>>> ipaddr.IPv6Address('::ffff:123.45.67.89').ipv4_mapped
IPv4Address('123.45.67.89')

CIDR

>>> ipaddr.IPv6Network('::ffff:123.45.67.89/128')
IPv6Network('::ffff:7b2d:4359/128')
share|improve this answer

For C#, I would recommend the use of IPNetwork Library https://github.com/lduchosal/ipnetwork. As of version 2, it supports IPv4 and IPv6 as well.

IPv6

  IPNetwork ipnetwork = IPNetwork.Parse("2001:0db8::/64");

  Console.WriteLine("Network : {0}", ipnetwork.Network);
  Console.WriteLine("Netmask : {0}", ipnetwork.Netmask);
  Console.WriteLine("Broadcast : {0}", ipnetwork.Broadcast);
  Console.WriteLine("FirstUsable : {0}", ipnetwork.FirstUsable);
  Console.WriteLine("LastUsable : {0}", ipnetwork.LastUsable);
  Console.WriteLine("Usable : {0}", ipnetwork.Usable);
  Console.WriteLine("Cidr : {0}", ipnetwork.Cidr);

Output

Network : 2001:db8::
Netmask : ffff:ffff:ffff:ffff::
Broadcast : 
FirstUsable : 2001:db8::
LastUsable : 2001:db8::ffff:ffff:ffff:ffff
Usable : 18446744073709551616
Cidr : 64

Have fun !

share|improve this answer
    
The output for first and last usable addresses is incorrect. IPv6, unlike IPv4, can use all the addresses in a subnet. A standard IPv6 subnet is /64 (a few special cases use other mask lengths), and the usable addresses are from <subnet>:: to <subnet>:ffff:ffff:ffff:ffff. There is no reservation for the subnet (<subnet>::), and IPv6 doesn't have the concept of broadcast, so no broadcast address exists at <subnet>:ffff:ffff:ffff:ffff. – Ron Maupin Aug 11 '15 at 16:56
    
Thanks Ron for pointing this out. – LukeSkywalker Aug 12 '15 at 14:20

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