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d413850bd7
$ tailscale debug via 0xb 10.2.0.0/16
fd7a:115c:a1e0:b1a:0🅱️a02:0/112
$ tailscale debug via fd7a:115c:a1e0:b1a:0🅱️a02:0/112
site 11 (0xb), 10.2.0.0/16
Previously: 3ae701f0eb
This adds a little debug tool to do CIDR math to make converting between
those ranges easier for now.
Updates #3616
Change-Id: I98302e95d17765bfaced3ecbb71cbd43e84bff46
Signed-off-by: Brad Fitzpatrick <bradfitz@tailscale.com>
299 lines
8.7 KiB
Go
299 lines
8.7 KiB
Go
// Copyright (c) 2020 Tailscale Inc & AUTHORS All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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// Package tsaddr handles Tailscale-specific IPs and ranges.
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package tsaddr
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import (
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"encoding/binary"
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"errors"
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"sync"
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"inet.af/netaddr"
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)
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// ChromeOSVMRange returns the subset of the CGNAT IPv4 range used by
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// ChromeOS to interconnect the host OS to containers and VMs. We
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// avoid allocating Tailscale IPs from it, to avoid conflicts.
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func ChromeOSVMRange() netaddr.IPPrefix {
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chromeOSRange.Do(func() { mustPrefix(&chromeOSRange.v, "100.115.92.0/23") })
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return chromeOSRange.v
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}
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var chromeOSRange oncePrefix
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// CGNATRange returns the Carrier Grade NAT address range that
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// is the superset range that Tailscale assigns out of.
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// See https://tailscale.com/kb/1015/100.x-addresses.
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// Note that Tailscale does not assign out of the ChromeOSVMRange.
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func CGNATRange() netaddr.IPPrefix {
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cgnatRange.Do(func() { mustPrefix(&cgnatRange.v, "100.64.0.0/10") })
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return cgnatRange.v
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}
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var (
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cgnatRange oncePrefix
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ulaRange oncePrefix
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tsUlaRange oncePrefix
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tsViaRange oncePrefix
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ula4To6Range oncePrefix
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ulaEph6Range oncePrefix
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serviceIPv6 oncePrefix
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)
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// TailscaleServiceIP returns the IPv4 listen address of services
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// provided by Tailscale itself such as the MagicDNS proxy.
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//
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// For IPv6, use TailscaleServiceIPv6.
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func TailscaleServiceIP() netaddr.IP {
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return netaddr.IPv4(100, 100, 100, 100) // "100.100.100.100" for those grepping
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}
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// TailscaleServiceIPv6 returns the IPv6 listen address of the services
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// provided by Tailscale itself such as the MagicDNS proxy.
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//
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// For IPv4, use TailscaleServiceIP.
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func TailscaleServiceIPv6() netaddr.IP {
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serviceIPv6.Do(func() { mustPrefix(&serviceIPv6.v, "fd7a:115c:a1e0::53/128") })
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return serviceIPv6.v.IP()
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}
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// IsTailscaleIP reports whether ip is an IP address in a range that
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// Tailscale assigns from.
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func IsTailscaleIP(ip netaddr.IP) bool {
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if ip.Is4() {
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return CGNATRange().Contains(ip) && !ChromeOSVMRange().Contains(ip)
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}
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return TailscaleULARange().Contains(ip)
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}
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// TailscaleULARange returns the IPv6 Unique Local Address range that
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// is the superset range that Tailscale assigns out of.
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func TailscaleULARange() netaddr.IPPrefix {
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tsUlaRange.Do(func() { mustPrefix(&tsUlaRange.v, "fd7a:115c:a1e0::/48") })
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return tsUlaRange.v
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}
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// TailscaleViaRange returns the IPv6 Unique Local Address subset range
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// TailscaleULARange that's used for IPv4 tunneling via IPv6.
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func TailscaleViaRange() netaddr.IPPrefix {
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// Mnemonic: "b1a" sounds like "via".
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tsViaRange.Do(func() { mustPrefix(&tsViaRange.v, "fd7a:115c:a1e0:b1a::/64") })
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return tsViaRange.v
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}
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// Tailscale4To6Range returns the subset of TailscaleULARange used for
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// auto-translated Tailscale ipv4 addresses.
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func Tailscale4To6Range() netaddr.IPPrefix {
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// This IP range has no significance, beyond being a subset of
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// TailscaleULARange. The bits from /48 to /104 were picked at
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// random.
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ula4To6Range.Do(func() { mustPrefix(&ula4To6Range.v, "fd7a:115c:a1e0:ab12:4843:cd96:6200::/104") })
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return ula4To6Range.v
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}
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// TailscaleEphemeral6Range returns the subset of TailscaleULARange
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// used for ephemeral IPv6-only Tailscale nodes.
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func TailscaleEphemeral6Range() netaddr.IPPrefix {
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// This IP range has no significance, beyond being a subset of
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// TailscaleULARange. The bits from /48 to /64 were picked at
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// random, with the only criterion being to not be the conflict
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// with the Tailscale4To6Range above.
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ulaEph6Range.Do(func() { mustPrefix(&ulaEph6Range.v, "fd7a:115c:a1e0:efe3::/64") })
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return ulaEph6Range.v
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}
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// Tailscale4To6Placeholder returns an IP address that can be used as
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// a source IP when one is required, but a netmap didn't provide
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// any. This address never gets allocated by the 4-to-6 algorithm in
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// control.
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//
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// Currently used to work around a Windows limitation when programming
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// IPv6 routes in corner cases.
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func Tailscale4To6Placeholder() netaddr.IP {
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return Tailscale4To6Range().IP()
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}
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// Tailscale4To6 returns a Tailscale IPv6 address that maps 1:1 to the
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// given Tailscale IPv4 address. Returns a zero IP if ipv4 isn't a
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// Tailscale IPv4 address.
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func Tailscale4To6(ipv4 netaddr.IP) netaddr.IP {
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if !ipv4.Is4() || !IsTailscaleIP(ipv4) {
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return netaddr.IP{}
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}
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ret := Tailscale4To6Range().IP().As16()
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v4 := ipv4.As4()
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copy(ret[13:], v4[1:])
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return netaddr.IPFrom16(ret)
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}
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func mustPrefix(v *netaddr.IPPrefix, prefix string) {
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var err error
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*v, err = netaddr.ParseIPPrefix(prefix)
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if err != nil {
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panic(err)
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}
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}
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type oncePrefix struct {
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sync.Once
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v netaddr.IPPrefix
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}
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// NewContainsIPFunc returns a func that reports whether ip is in addrs.
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//
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// It's optimized for the cases of addrs being empty and addrs
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// containing 1 or 2 single-IP prefixes (such as one IPv4 address and
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// one IPv6 address).
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//
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// Otherwise the implementation is somewhat slow.
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func NewContainsIPFunc(addrs []netaddr.IPPrefix) func(ip netaddr.IP) bool {
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// Specialize the three common cases: no address, just IPv4
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// (or just IPv6), and both IPv4 and IPv6.
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if len(addrs) == 0 {
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return func(netaddr.IP) bool { return false }
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}
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// If any addr is more than a single IP, then just do the slow
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// linear thing until
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// https://github.com/inetaf/netaddr/issues/139 is done.
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for _, a := range addrs {
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if a.IsSingleIP() {
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continue
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}
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acopy := append([]netaddr.IPPrefix(nil), addrs...)
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return func(ip netaddr.IP) bool {
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for _, a := range acopy {
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if a.Contains(ip) {
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return true
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}
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}
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return false
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}
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}
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// Fast paths for 1 and 2 IPs:
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if len(addrs) == 1 {
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a := addrs[0]
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return func(ip netaddr.IP) bool { return ip == a.IP() }
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}
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if len(addrs) == 2 {
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a, b := addrs[0], addrs[1]
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return func(ip netaddr.IP) bool { return ip == a.IP() || ip == b.IP() }
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}
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// General case:
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m := map[netaddr.IP]bool{}
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for _, a := range addrs {
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m[a.IP()] = true
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}
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return func(ip netaddr.IP) bool { return m[ip] }
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}
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// PrefixesContainsFunc reports whether f is true for any IPPrefix in
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// ipp.
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func PrefixesContainsFunc(ipp []netaddr.IPPrefix, f func(netaddr.IPPrefix) bool) bool {
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for _, v := range ipp {
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if f(v) {
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return true
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}
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}
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return false
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}
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// PrefixesContainsIP reports whether any prefix in ipp contains ip.
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func PrefixesContainsIP(ipp []netaddr.IPPrefix, ip netaddr.IP) bool {
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for _, r := range ipp {
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if r.Contains(ip) {
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return true
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}
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}
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return false
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}
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// IPsContainsFunc reports whether f is true for any IP in ips.
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func IPsContainsFunc(ips []netaddr.IP, f func(netaddr.IP) bool) bool {
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for _, v := range ips {
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if f(v) {
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return true
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}
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}
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return false
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}
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// PrefixIs4 reports whether p is an IPv4 prefix.
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func PrefixIs4(p netaddr.IPPrefix) bool { return p.IP().Is4() }
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// PrefixIs6 reports whether p is an IPv6 prefix.
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func PrefixIs6(p netaddr.IPPrefix) bool { return p.IP().Is6() }
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// ContainsExitRoutes reports whether rr contains both the IPv4 and
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// IPv6 /0 route.
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func ContainsExitRoutes(rr []netaddr.IPPrefix) bool {
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var v4, v6 bool
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for _, r := range rr {
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if r == allIPv4 {
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v4 = true
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} else if r == allIPv6 {
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v6 = true
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}
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}
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return v4 && v6
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}
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var (
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allIPv4 = netaddr.MustParseIPPrefix("0.0.0.0/0")
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allIPv6 = netaddr.MustParseIPPrefix("::/0")
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)
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// AllIPv4 returns 0.0.0.0/0.
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func AllIPv4() netaddr.IPPrefix { return allIPv4 }
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// AllIPv6 returns ::/0.
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func AllIPv6() netaddr.IPPrefix { return allIPv6 }
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// ExitRoutes returns a slice containing AllIPv4 and AllIPv6.
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func ExitRoutes() []netaddr.IPPrefix { return []netaddr.IPPrefix{allIPv4, allIPv6} }
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// FilterPrefixes returns a new slice, not aliasing in, containing elements of
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// in that match f.
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func FilterPrefixesCopy(in []netaddr.IPPrefix, f func(netaddr.IPPrefix) bool) []netaddr.IPPrefix {
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var out []netaddr.IPPrefix
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for _, v := range in {
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if f(v) {
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out = append(out, v)
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}
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}
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return out
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}
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// IsViaPrefix reports whether p is a CIDR in the Tailscale "via" range.
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// See TailscaleViaRange.
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func IsViaPrefix(p netaddr.IPPrefix) bool {
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return TailscaleViaRange().Contains(p.IP())
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}
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// UnmapVia returns the IPv4 address that corresponds to the provided Tailscale
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// "via" IPv4-in-IPv6 address.
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//
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// If ip is not a via address, it returns ip unchanged.
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func UnmapVia(ip netaddr.IP) netaddr.IP {
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if TailscaleViaRange().Contains(ip) {
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a := ip.As16()
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return netaddr.IPFrom4(*(*[4]byte)(a[12:16]))
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}
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return ip
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}
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// MapVia returns an IPv6 "via" route for an IPv4 CIDR in a given siteID.
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func MapVia(siteID uint32, v4 netaddr.IPPrefix) (via netaddr.IPPrefix, err error) {
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if !v4.IP().Is4() {
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return via, errors.New("want IPv4 CIDR with a site ID")
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}
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viaRange16 := TailscaleViaRange().IP().As16()
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var a [16]byte
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copy(a[:], viaRange16[:8])
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binary.BigEndian.PutUint32(a[8:], siteID)
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ip4a := v4.IP().As4()
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copy(a[12:], ip4a[:])
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return netaddr.IPPrefixFrom(netaddr.IPFrom16(a), v4.Bits()+64+32), nil
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}
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