ipaddr.js is a small (1.9K minified and gzipped) library for manipulating IP addresses in JavaScript environments. It runs on both CommonJS runtimes (e.g. nodejs) and in a web browser.
ipaddr.js allows you to verify and parse string representation of an IP address, match it against a CIDR range or range list, determine if it falls into some reserved ranges (examples include loopback and private ranges), and convert between IPv4 and IPv4-mapped IPv6 addresses.
npm install ipaddr.js
or
bower install ipaddr.js
Use 2.x release for nodejs versions 10+. Use the 1.x release for versions of nodejs older than 10.
ipaddr.js defines one object in the global scope: ipaddr
. In CommonJS,
it is exported from the module:
const ipaddr = require('ipaddr.js');
The API consists of several global methods and two classes: ipaddr.IPv6 and ipaddr.IPv4.
There are three global methods defined: ipaddr.isValid
, ipaddr.parse
and
ipaddr.process
. All of them receive a string as a single parameter.
The ipaddr.isValid
method returns true
if the address is a valid IPv4 or
IPv6 address, and false
otherwise. It does not throw any exceptions.
The ipaddr.parse
method returns an object representing the IP address,
or throws an Error
if the passed string is not a valid representation of an
IP address.
The ipaddr.process
method works just like the ipaddr.parse
one, but it
automatically converts IPv4-mapped IPv6 addresses to their IPv4 counterparts
before returning. It is useful when you have a Node.js instance listening
on an IPv6 socket, and the net.ivp6.bindv6only
sysctl parameter (or its
equivalent on non-Linux OS) is set to 0. In this case, you can accept IPv4
connections on your IPv6-only socket, but the remote address will be mangled.
Use ipaddr.process
method to automatically demangle it.
Parsing methods return an object which descends from ipaddr.IPv6
or
ipaddr.IPv4
. These objects share some properties, but most of them differ.
One can determine the type of address by calling addr.kind()
. It will return
either "ipv6"
or "ipv4"
.
An address can be converted back to its string representation with addr.toString()
.
Note that this method:
- does not return the original string used to create the object (in fact, there is no way of getting that string)
- returns a compact representation (when it is applicable)
A match(range, bits)
method can be used to check if the address falls into a
certain CIDR range. Note that an address can be (obviously) matched only against an address of the same type.
For example:
const addr = ipaddr.parse('2001:db8:1234::1');
const range = ipaddr.parse('2001:db8::');
addr.match(range, 32); // => true
Alternatively, match
can also be called as match([range, bits])
. In this way, it can be used together with the parseCIDR(string)
method, which parses an IP address together with a CIDR range.
For example:
const addr = ipaddr.parse('2001:db8:1234::1');
addr.match(ipaddr.parseCIDR('2001:db8::/32')); // => true
A range()
method returns one of predefined names for several special ranges defined by IP protocols. The exact names (and their respective CIDR ranges) can be looked up in the source: IPv6 ranges and IPv4 ranges. Some common ones include "unicast"
(the default one) and "reserved"
.
You can match against your own range list by using
ipaddr.subnetMatch(address, rangeList, defaultName)
method. It can work with a mix of IPv6 or IPv4 addresses, and accepts a name-to-subnet map as the range list. For example:
const rangeList = {
documentationOnly: [ ipaddr.parse('2001:db8::'), 32 ],
tunnelProviders: [
[ ipaddr.parse('2001:470::'), 32 ], // he.net
[ ipaddr.parse('2001:5c0::'), 32 ] // freenet6
]
};
ipaddr.subnetMatch(ipaddr.parse('2001:470:8:66::1'), rangeList, 'unknown'); // => "tunnelProviders"
The addresses can be converted to their byte representation with toByteArray()
. (Actually, JavaScript mostly does not know about byte buffers. They are emulated with arrays of numbers, each in range of 0..255.)
const bytes = ipaddr.parse('2a00:1450:8007::68').toByteArray(); // ipv6.google.com
bytes // => [42, 0x00, 0x14, 0x50, 0x80, 0x07, 0x00, <zeroes...>, 0x00, 0x68 ]
The ipaddr.IPv4
and ipaddr.IPv6
objects have some methods defined, too. All of them have the same interface for both protocols, and are similar to global methods.
ipaddr.IPvX.isValid(string)
can be used to check if the string is a valid address for particular protocol, and ipaddr.IPvX.parse(string)
is the error-throwing parser.
ipaddr.IPvX.isValid(string)
uses the same format for parsing as the POSIX inet_ntoa
function, which accepts unusual formats like 0xc0.168.1.1
or 0x10000000
. The function ipaddr.IPv4.isValidFourPartDecimal(string)
validates the IPv4 address and also ensures that it is written in four-part decimal format.
Sometimes you will want to convert IPv6 not to a compact string representation (with the ::
substitution); the toNormalizedString()
method will return an address where all zeroes are explicit.
For example:
const addr = ipaddr.parse('2001:0db8::0001');
addr.toString(); // => '2001:db8::1'
addr.toNormalizedString(); // => '2001:db8:0:0:0:0:0:1'
The isIPv4MappedAddress()
method will return true
if this address is an IPv4-mapped
one, and toIPv4Address()
will return an IPv4 object address.
To access the underlying binary representation of the address, use addr.parts
.
const addr = ipaddr.parse('2001:db8:10::1234:DEAD');
addr.parts // => [0x2001, 0xdb8, 0x10, 0, 0, 0, 0x1234, 0xdead]
A IPv6 zone index can be accessed via addr.zoneId
:
const addr = ipaddr.parse('2001:db8::%eth0');
addr.zoneId // => 'eth0'
toIPv4MappedAddress()
will return a corresponding IPv4-mapped IPv6 address.
To access the underlying representation of the address, use addr.octets
.
const addr = ipaddr.parse('192.168.1.1');
addr.octets // => [192, 168, 1, 1]
prefixLengthFromSubnetMask()
will return a CIDR prefix length for a valid IPv4 netmask or
null if the netmask is not valid.
ipaddr.IPv4.parse('255.255.255.240').prefixLengthFromSubnetMask() == 28
ipaddr.IPv4.parse('255.192.164.0').prefixLengthFromSubnetMask() == null
subnetMaskFromPrefixLength()
will return an IPv4 netmask for a valid CIDR prefix length.
ipaddr.IPv4.subnetMaskFromPrefixLength(24) == '255.255.255.0'
ipaddr.IPv4.subnetMaskFromPrefixLength(29) == '255.255.255.248'
broadcastAddressFromCIDR()
will return the broadcast address for a given IPv4 interface and netmask in CIDR notation.
ipaddr.IPv4.broadcastAddressFromCIDR('172.0.0.1/24') == '172.0.0.255'
networkAddressFromCIDR()
will return the network address for a given IPv4 interface and netmask in CIDR notation.
ipaddr.IPv4.networkAddressFromCIDR('172.0.0.1/24') == '172.0.0.0'
IPv4 and IPv6 can be converted bidirectionally to and from network byte order (MSB) byte arrays.
The fromByteArray()
method will take an array and create an appropriate IPv4 or IPv6 object
if the input satisfies the requirements. For IPv4 it has to be an array of four 8-bit values,
while for IPv6 it has to be an array of sixteen 8-bit values.
For example:
const addr = ipaddr.fromByteArray([0x7f, 0, 0, 1]);
addr.toString(); // => '127.0.0.1'
or
const addr = ipaddr.fromByteArray([0x20, 1, 0xd, 0xb8, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1])
addr.toString(); // => '2001:db8::1'
Both objects also offer a toByteArray()
method, which returns an array in network byte order (MSB).
For example:
const addr = ipaddr.parse('127.0.0.1');
addr.toByteArray(); // => [0x7f, 0, 0, 1]
or
const addr = ipaddr.parse('2001:db8::1');
addr.toByteArray(); // => [0x20, 1, 0xd, 0xb8, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1]