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fd45529d94
Warn about banning a single IPv6 address
221 lines
5.3 KiB
Go
221 lines
5.3 KiB
Go
// Copyright 2020 Shivaram Lingamneni <slingamn@cs.stanford.edu>
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// Copyright 2009 The Go Authors
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// Released under the MIT license
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package flatip
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import (
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"bytes"
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"errors"
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"net"
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)
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var (
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v4InV6Prefix = []byte{0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0xff, 0xff}
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IPv6loopback = IP{0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1}
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IPv6zero = IP{0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0}
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IPv4zero = IP{0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0xff, 0xff, 0, 0, 0, 0}
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ErrInvalidIPString = errors.New("String could not be interpreted as an IP address")
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)
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// packed versions of net.IP and net.IPNet; these are pure value types,
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// so they can be compared with == and used as map keys.
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// IP is a 128-bit representation of an IP address, using the 4-in-6 mapping
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// to represent IPv4 addresses.
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type IP [16]byte
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// IPNet is a IP network. In a valid value, all bits after PrefixLen are zeroes.
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type IPNet struct {
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IP
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PrefixLen uint8
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}
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// NetIP converts an IP into a net.IP.
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func (ip IP) NetIP() (result net.IP) {
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result = make(net.IP, 16)
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copy(result[:], ip[:])
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return
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}
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// FromNetIP converts a net.IP into an IP.
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func FromNetIP(ip net.IP) (result IP) {
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if len(ip) == 16 {
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copy(result[:], ip[:])
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} else {
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result[10] = 0xff
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result[11] = 0xff
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copy(result[12:], ip[:])
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}
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return
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}
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// IPv4 returns the IP address representation of a.b.c.d
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func IPv4(a, b, c, d byte) (result IP) {
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copy(result[:12], v4InV6Prefix)
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result[12] = a
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result[13] = b
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result[14] = c
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result[15] = d
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return
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}
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// ParseIP parses a string representation of an IP address into an IP.
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// Unlike net.ParseIP, it returns an error instead of a zero value on failure,
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// since the zero value of `IP` is a representation of a valid IP (::0, the
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// IPv6 "unspecified address").
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func ParseIP(ipstr string) (ip IP, err error) {
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// TODO reimplement this without net.ParseIP
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netip := net.ParseIP(ipstr)
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if netip == nil {
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err = ErrInvalidIPString
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return
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}
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netip = netip.To16()
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copy(ip[:], netip)
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return
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}
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// String returns the string representation of an IP
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func (ip IP) String() string {
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// TODO reimplement this without using (net.IP).String()
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return (net.IP)(ip[:]).String()
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}
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// IsIPv4 returns whether the IP is an IPv4 address.
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func (ip IP) IsIPv4() bool {
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return bytes.Equal(ip[:12], v4InV6Prefix)
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}
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// IsLoopback returns whether the IP is a loopback address.
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func (ip IP) IsLoopback() bool {
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if ip.IsIPv4() {
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return ip[12] == 127
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} else {
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return ip == IPv6loopback
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}
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}
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func (ip IP) IsUnspecified() bool {
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return ip == IPv4zero || ip == IPv6zero
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}
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func rawCidrMask(length int) (m IP) {
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n := uint(length)
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for i := 0; i < 16; i++ {
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if n >= 8 {
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m[i] = 0xff
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n -= 8
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continue
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}
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m[i] = ^byte(0xff >> n)
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return
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}
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return
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}
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func (ip IP) applyMask(mask IP) (result IP) {
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for i := 0; i < 16; i += 1 {
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result[i] = ip[i] & mask[i]
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}
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return
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}
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func cidrMask(ones, bits int) (result IP) {
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switch bits {
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case 32:
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return rawCidrMask(96 + ones)
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case 128:
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return rawCidrMask(ones)
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default:
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return
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}
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}
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// Mask returns the result of masking ip with the CIDR mask of
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// length 'ones', out of a total of 'bits' (which must be either
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// 32 for an IPv4 subnet or 128 for an IPv6 subnet).
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func (ip IP) Mask(ones, bits int) (result IP) {
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return ip.applyMask(cidrMask(ones, bits))
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}
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// ToNetIPNet converts an IPNet into a net.IPNet.
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func (cidr IPNet) ToNetIPNet() (result net.IPNet) {
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return net.IPNet{
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IP: cidr.IP.NetIP(),
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Mask: net.CIDRMask(int(cidr.PrefixLen), 128),
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}
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}
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// Contains retuns whether the network contains `ip`.
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func (cidr IPNet) Contains(ip IP) bool {
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maskedIP := ip.Mask(int(cidr.PrefixLen), 128)
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return cidr.IP == maskedIP
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}
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func (cidr IPNet) Size() (ones, bits int) {
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if cidr.IP.IsIPv4() {
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return int(cidr.PrefixLen) - 96, 32
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} else {
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return int(cidr.PrefixLen), 128
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}
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}
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// FromNetIPnet converts a net.IPNet into an IPNet.
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func FromNetIPNet(network net.IPNet) (result IPNet) {
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ones, _ := network.Mask.Size()
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if len(network.IP) == 16 {
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copy(result.IP[:], network.IP[:])
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} else {
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result.IP[10] = 0xff
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result.IP[11] = 0xff
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copy(result.IP[12:], network.IP[:])
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ones += 96
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}
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// perform masking so that equal CIDRs are ==
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result.IP = result.IP.Mask(ones, 128)
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result.PrefixLen = uint8(ones)
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return
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}
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// String returns a string representation of an IPNet.
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func (cidr IPNet) String() string {
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ip := make(net.IP, 16)
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copy(ip[:], cidr.IP[:])
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ipnet := net.IPNet{
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IP: ip,
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Mask: net.CIDRMask(int(cidr.PrefixLen), 128),
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}
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return ipnet.String()
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}
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// HumanReadableString returns a string representation of an IPNet;
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// if the network contains only a single IP address, it returns
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// a representation of that address.
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func (cidr IPNet) HumanReadableString() string {
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if cidr.PrefixLen == 128 {
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return cidr.IP.String()
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}
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return cidr.String()
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}
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// IsZero tests whether ipnet is the zero value of an IPNet, 0::0/0.
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// Although this is a valid subnet, it can still be used as a sentinel
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// value in some contexts.
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func (ipnet IPNet) IsZero() bool {
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return ipnet == IPNet{}
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}
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// ParseCIDR parses a string representation of an IP network in CIDR notation,
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// then returns it as an IPNet (along with the original, unmasked address).
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func ParseCIDR(netstr string) (ip IP, ipnet IPNet, err error) {
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// TODO reimplement this without net.ParseCIDR
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nip, nipnet, err := net.ParseCIDR(netstr)
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if err != nil {
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return
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}
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return FromNetIP(nip), FromNetIPNet(*nipnet), nil
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}
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