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ATTENTION version 2.0.0 is a breaking change from previous versions for handling IPv6 addresses (functions for IPv4 are unchanged). Calls that result in arithmatic operations against IPv6 now use uint128.Uint128 instead of *big.Int. Until now this library restricted itself to using the standard library, but math/big is sloooooooooow and the performance gains from switching were too large to ignore:

Benchmark*big.Intuint128.Uint128
Benchmark_DeltaIP679.27 ns/op2.809 ns/op
BenchmarkDecrementIP6By50.54 ns/op13.88 ns/op
BenchmarkIncrementIP6By50.48 ns/op13.92 ns/op
BenchmarkNet_Count6122.2 ns/op11.26 ns/op

It would be fantastic to remove this external dependency in some future v3 that switched to a native uint128 but for that to happen this proposal (or something similar) would need to be adopted.

Okay you can stop paying attention now

I really enjoy Python's ipaddress library and Ruby's ipaddr, I think you can write a lot of neat software if some of the little problems around manipulating IP addresses and netblocks are taken care of for you, so I set out to write something like them for my language of choice, Go. This is what I've come up with.

IPLib is a hopefully useful, aspirationally full-featured library built around and on top of the address primitives found in the net package, it seeks to make them more accessible and easier to manipulate.

It includes:

net.IP tools

Some simple tools for performing common tasks against IP objects:

iplib.Net

An enhancement of net.IPNet, iplib.Net is an interface with two, version- specific implementations providing features such as:

Net4 and Net6 implementations of Net

The two address versions behave differently in both large and subtle ways, and the version-specific implementations seek to account for this. For example the Net4 implementation omits the network and broadcast addresses from consideration during enumeration; while the Net6 implementation introduces the concept of a HostMask, which blocks usable addresses off from the right in the same way that a netmask constrains them from the left

Additional version-specific considerations described in the Net4 and Net6 sections below.

Sub-modules

Installing

go get -u github.com/c-robinson/iplib/v2

Using iplib

There are a series of functions for working with v4 or v6 net.IP objects:

package main

import (
	"fmt"
	"net"
	"sort"
	
	"github.com/c-robinson/iplib/v2"
)


func main() {
	ipa := net.ParseIP("192.168.1.1")
	ipb := iplib.IncrementIPBy(ipa, 15)      // ipb is 192.168.1.16
	ipc := iplib.NextIP(ipa)                 // ipc is 192.168.1.2

	fmt.Println(iplib.CompareIPs(ipa, ipb))  // -1
    
	fmt.Println(iplib.DeltaIP(ipa, ipb))     // 15
    
	fmt.Println(iplib.IPToHexString(ipc))    // "c0a80102"

	iplist := []net.IP{ ipb, ipc, ipa }
	sort.Sort(iplib.ByIP(iplist))            // []net.IP{ipa, ipc, ipb}

	fmt.Println(iplib.IP4ToUint32(ipa))      // 3232235777
	fmt.Println(iplib.IPToBinaryString(ipa)) // 11000000.10101000.00000001.00000001
	fmt.Println(iplib.IP4ToARPA(ipa))        // 1.1.168.192.in-addr.arpa
}

Addresses that require or return a count default to using uint32, which is sufficient for working with the entire IPv4 space. As a rule these functions are just lowest-common wrappers around IPv4- or IPv6-specific functions. The IPv6-specific variants use uint128.Uint128 so they can access the entire v6 space.

The iplib.Net interface

Net describes an iplib.Net object, the exposed functions are those that are required for comparison, sorting, generic initialization and for ancillary functions such as those found in this package's submodules.

Using iplib.Net4

Net4 represents an IPv4 network. Since the first and last addresses of a v4 network are typically not allocated for use these will be omitted by Enumerate(), NextIP() and PreviousIP(); they wont show up in Count(); and FirstAddress() and LastAddress() show the 2nd and 2nd-to-the-last addresses respectively. The v4-specific method NetworkAddress() returns the first address, while BroadcastAddress() returns the last. There is an exception made for Net4 networks defined with a 31-bit netmask, since these are assumed to be for RFC3021 point-to-point links.

Additionally Net4 contains a Wildcard() method which will return the network's wildcard address.

n := iplib.NewNet4(net.ParseIP("192.168.0.0"), 16)
fmt.Println(n.Count())            // 65534 (note: not 65536)
fmt.Println(n.Enumerate(2, 1024)) // [192.168.4.1 192.168.4.2]
fmt.Println(n.IP())               // 192.168.0.0
fmt.Println(n.FirstAddress())     // 192.168.0.1
fmt.Println(n.LastAddress())      // 192.168.255.254
fmt.Println(n.BroadcastAddress()) // 192.168.255.255
fmt.Println(n.Wildcard())         // 0000ffff
fmt.Println(n.Subnet(0))          // [192.168.0.0/17 192.168.128.0/17] <nil>
fmt.Println(n.Supernet(0))        // 192.168.0.0/15 <nil>

Using iplib.Net6

Net6 represents an IPv6 network. In some ways v6 is simpler than v4, as it does away with the special behavior of addresses at the front and back of the netblock. For IPv6 the primary problem is the sheer size of the thing: there are 2^128th addresses in IPv6, which translates to 340 undecillion!

n := iplib.NewNet6(net.ParseIP("2001:db8::"), 56, 0)
fmt.Println(n.Count())                  // 4722366482869645213696
fmt.Println(n.Enumerate(2, 1024))       // [2001:db8::400 2001:db8::401]
fmt.Println(n.FirstAddress())           // 2001:db8::
fmt.Println(n.NextIP(n.FirstAddress())) // 2001:db8::1 <nil>
fmt.Println(n.LastAddress())            // 2001:db8:0:ff:ffff:ffff:ffff:ffff
fmt.Println(n.Subnet(0, 0))             // [2001:db8::/57 2001:db8:0:80::/57] <nil>
fmt.Println(n.Supernet(0, 0))           // 2001:db8::/55 <nil>

HostMasks with Net6

To manage the address space, Net6 introduces HostMask. This optional constraint can be used to block addresses on the right-side of a netblock somewhat like Netmasks do on the left. Hostmask must be specified at initialization time and, if set, will affect the behavior of Count(), Enumerate(), LastAddress(), NextIP() and PreviousIP(). Subnet() and Supernet() generate objects that inherit the hostmask of their parent, while a hostmask must be specified for NextNet() and PreviousNet().

// this is the same as the previous example, except with a hostmask set
n := NewNet6(net.ParseIP("2001:db8::"), 56, 60)
fmt.Println(n.Count())                  // 4096
fmt.Println(n.Enumerate(2, 1024))       // [2001:db8:0:40:: 2001:db8:0:40:100::]
fmt.Println(n.FirstAddress())           // 2001:db8::
fmt.Println(n.NextIP(n.FirstAddress())) // 2001:db8:0:0:100:: <nil>
fmt.Println(n.LastAddress())            // 2001:db8:0:ff:f00::
fmt.Println(n.Mask().String())          // ffffffffffffff000000000000000000
fmt.Println(n.Hostmask.String())        // 0000000000000000f0ffffffffffffff
fmt.Println(n.Subnet(0, 60))            // [2001:db8::/57 2001:db8:0:80::/57] <nil>
fmt.Println(n.Supernet(0, 60))          // 2001:db8::/55 <nil>

Test driving

IPfool is a simple command-line tool that I wrote to test many of the features within this library and might be useful in evaluating it.