SpoofDPI/dns/addrselect/addrselect.go
Ledorub 15163ca5fe
feat: add IPv6 support (#161)
* Add support for IPv6 lookups.

* Refactor DNSResolver.

* Make listener support IPv6.
2024-08-18 13:34:09 +09:00

378 lines
9.7 KiB
Go

package addrselect
import (
"net"
"net/netip"
"sort"
)
// Copyright 2015 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
// Minimal RFC 6724 address selection.
func SortByRFC6724(addrs []net.IPAddr) {
if len(addrs) < 2 {
return
}
sortByRFC6724withSrcs(addrs, srcAddrs(addrs))
}
func sortByRFC6724withSrcs(addrs []net.IPAddr, srcs []netip.Addr) {
if len(addrs) != len(srcs) {
panic("internal error")
}
addrAttr := make([]ipAttr, len(addrs))
srcAttr := make([]ipAttr, len(srcs))
for i, v := range addrs {
addrAttrIP, _ := netip.AddrFromSlice(v.IP)
addrAttr[i] = ipAttrOf(addrAttrIP)
srcAttr[i] = ipAttrOf(srcs[i])
}
sort.Stable(&byRFC6724{
addrs: addrs,
addrAttr: addrAttr,
srcs: srcs,
srcAttr: srcAttr,
})
}
// srcAddrs tries to UDP-connect to each address to see if it has a
// route. (This doesn't send any packets). The destination port
// number is irrelevant.
func srcAddrs(addrs []net.IPAddr) []netip.Addr {
srcs := make([]netip.Addr, len(addrs))
dst := net.UDPAddr{Port: 9}
for i := range addrs {
dst.IP = addrs[i].IP
dst.Zone = addrs[i].Zone
c, err := net.DialUDP("udp", nil, &dst)
if err == nil {
if src, ok := c.LocalAddr().(*net.UDPAddr); ok {
srcs[i], _ = netip.AddrFromSlice(src.IP)
}
c.Close()
}
}
return srcs
}
type ipAttr struct {
Scope scope
Precedence uint8
Label uint8
}
func ipAttrOf(ip netip.Addr) ipAttr {
if !ip.IsValid() {
return ipAttr{}
}
match := rfc6724policyTable.Classify(ip)
return ipAttr{
Scope: classifyScope(ip),
Precedence: match.Precedence,
Label: match.Label,
}
}
type byRFC6724 struct {
addrs []net.IPAddr // addrs to sort
addrAttr []ipAttr
srcs []netip.Addr // or not valid addr if unreachable
srcAttr []ipAttr
}
func (s *byRFC6724) Len() int { return len(s.addrs) }
func (s *byRFC6724) Swap(i, j int) {
s.addrs[i], s.addrs[j] = s.addrs[j], s.addrs[i]
s.srcs[i], s.srcs[j] = s.srcs[j], s.srcs[i]
s.addrAttr[i], s.addrAttr[j] = s.addrAttr[j], s.addrAttr[i]
s.srcAttr[i], s.srcAttr[j] = s.srcAttr[j], s.srcAttr[i]
}
// Less reports whether i is a better destination address for this
// host than j.
//
// The algorithm and variable names comes from RFC 6724 section 6.
func (s *byRFC6724) Less(i, j int) bool {
DA := s.addrs[i].IP
DB := s.addrs[j].IP
SourceDA := s.srcs[i]
SourceDB := s.srcs[j]
attrDA := &s.addrAttr[i]
attrDB := &s.addrAttr[j]
attrSourceDA := &s.srcAttr[i]
attrSourceDB := &s.srcAttr[j]
const preferDA = true
const preferDB = false
// Rule 1: Avoid unusable destinations.
// If DB is known to be unreachable or if Source(DB) is undefined, then
// prefer DA. Similarly, if DA is known to be unreachable or if
// Source(DA) is undefined, then prefer DB.
if !SourceDA.IsValid() && !SourceDB.IsValid() {
return false // "equal"
}
if !SourceDB.IsValid() {
return preferDA
}
if !SourceDA.IsValid() {
return preferDB
}
// Rule 2: Prefer matching scope.
// If Scope(DA) = Scope(Source(DA)) and Scope(DB) <> Scope(Source(DB)),
// then prefer DA. Similarly, if Scope(DA) <> Scope(Source(DA)) and
// Scope(DB) = Scope(Source(DB)), then prefer DB.
if attrDA.Scope == attrSourceDA.Scope && attrDB.Scope != attrSourceDB.Scope {
return preferDA
}
if attrDA.Scope != attrSourceDA.Scope && attrDB.Scope == attrSourceDB.Scope {
return preferDB
}
// Rule 3: Avoid deprecated addresses.
// If Source(DA) is deprecated and Source(DB) is not, then prefer DB.
// Similarly, if Source(DA) is not deprecated and Source(DB) is
// deprecated, then prefer DA.
// TODO(bradfitz): implement? low priority for now.
// Rule 4: Prefer home addresses.
// If Source(DA) is simultaneously a home address and care-of address
// and Source(DB) is not, then prefer DA. Similarly, if Source(DB) is
// simultaneously a home address and care-of address and Source(DA) is
// not, then prefer DB.
// TODO(bradfitz): implement? low priority for now.
// Rule 5: Prefer matching label.
// If Label(Source(DA)) = Label(DA) and Label(Source(DB)) <> Label(DB),
// then prefer DA. Similarly, if Label(Source(DA)) <> Label(DA) and
// Label(Source(DB)) = Label(DB), then prefer DB.
if attrSourceDA.Label == attrDA.Label &&
attrSourceDB.Label != attrDB.Label {
return preferDA
}
if attrSourceDA.Label != attrDA.Label &&
attrSourceDB.Label == attrDB.Label {
return preferDB
}
// Rule 6: Prefer higher precedence.
// If Precedence(DA) > Precedence(DB), then prefer DA. Similarly, if
// Precedence(DA) < Precedence(DB), then prefer DB.
if attrDA.Precedence > attrDB.Precedence {
return preferDA
}
if attrDA.Precedence < attrDB.Precedence {
return preferDB
}
// Rule 7: Prefer native transport.
// If DA is reached via an encapsulating transition mechanism (e.g.,
// IPv6 in IPv4) and DB is not, then prefer DB. Similarly, if DB is
// reached via encapsulation and DA is not, then prefer DA.
// TODO(bradfitz): implement? low priority for now.
// Rule 8: Prefer smaller scope.
// If Scope(DA) < Scope(DB), then prefer DA. Similarly, if Scope(DA) >
// Scope(DB), then prefer DB.
if attrDA.Scope < attrDB.Scope {
return preferDA
}
if attrDA.Scope > attrDB.Scope {
return preferDB
}
// Rule 9: Use the longest matching prefix.
// When DA and DB belong to the same address family (both are IPv6 or
// both are IPv4 [but see below]): If CommonPrefixLen(Source(DA), DA) >
// CommonPrefixLen(Source(DB), DB), then prefer DA. Similarly, if
// CommonPrefixLen(Source(DA), DA) < CommonPrefixLen(Source(DB), DB),
// then prefer DB.
//
// However, applying this rule to IPv4 addresses causes
// problems (see issues 13283 and 18518), so limit to IPv6.
if DA.To4() == nil && DB.To4() == nil {
commonA := commonPrefixLen(SourceDA, DA)
commonB := commonPrefixLen(SourceDB, DB)
if commonA > commonB {
return preferDA
}
if commonA < commonB {
return preferDB
}
}
// Rule 10: Otherwise, leave the order unchanged.
// If DA preceded DB in the original list, prefer DA.
// Otherwise, prefer DB.
return false // "equal"
}
type policyTableEntry struct {
Prefix netip.Prefix
Precedence uint8
Label uint8
}
type policyTable []policyTableEntry
// RFC 6724 section 2.1.
// Items are sorted by the size of their Prefix.Mask.Size,
var rfc6724policyTable = policyTable{
{
// "::1/128"
Prefix: netip.PrefixFrom(netip.AddrFrom16([16]byte{0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x01}), 128),
Precedence: 50,
Label: 0,
},
{
// "::ffff:0:0/96"
// IPv4-compatible, etc.
Prefix: netip.PrefixFrom(netip.AddrFrom16([16]byte{0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0xff, 0xff}), 96),
Precedence: 35,
Label: 4,
},
{
// "::/96"
Prefix: netip.PrefixFrom(netip.AddrFrom16([16]byte{}), 96),
Precedence: 1,
Label: 3,
},
{
// "2001::/32"
// Teredo
Prefix: netip.PrefixFrom(netip.AddrFrom16([16]byte{0x20, 0x01}), 32),
Precedence: 5,
Label: 5,
},
{
// "2002::/16"
// 6to4
Prefix: netip.PrefixFrom(netip.AddrFrom16([16]byte{0x20, 0x02}), 16),
Precedence: 30,
Label: 2,
},
{
// "3ffe::/16"
Prefix: netip.PrefixFrom(netip.AddrFrom16([16]byte{0x3f, 0xfe}), 16),
Precedence: 1,
Label: 12,
},
{
// "fec0::/10"
Prefix: netip.PrefixFrom(netip.AddrFrom16([16]byte{0xfe, 0xc0}), 10),
Precedence: 1,
Label: 11,
},
{
// "fc00::/7"
Prefix: netip.PrefixFrom(netip.AddrFrom16([16]byte{0xfc}), 7),
Precedence: 3,
Label: 13,
},
{
// "::/0"
Prefix: netip.PrefixFrom(netip.AddrFrom16([16]byte{}), 0),
Precedence: 40,
Label: 1,
},
}
// Classify returns the policyTableEntry of the entry with the longest
// matching prefix that contains ip.
// The table t must be sorted from largest mask size to smallest.
func (t policyTable) Classify(ip netip.Addr) policyTableEntry {
// Prefix.Contains() will not match an IPv6 prefix for an IPv4 address.
if ip.Is4() {
ip = netip.AddrFrom16(ip.As16())
}
for _, ent := range t {
if ent.Prefix.Contains(ip) {
return ent
}
}
return policyTableEntry{}
}
// RFC 6724 section 3.1.
type scope uint8
const (
scopeInterfaceLocal scope = 0x1
scopeLinkLocal scope = 0x2
scopeAdminLocal scope = 0x4
scopeSiteLocal scope = 0x5
scopeOrgLocal scope = 0x8
scopeGlobal scope = 0xe
)
func classifyScope(ip netip.Addr) scope {
if ip.IsLoopback() || ip.IsLinkLocalUnicast() {
return scopeLinkLocal
}
ipv6 := ip.Is6() && !ip.Is4In6()
ipv6AsBytes := ip.As16()
if ipv6 && ip.IsMulticast() {
return scope(ipv6AsBytes[1] & 0xf)
}
// Site-local addresses are defined in RFC 3513 section 2.5.6
// (and deprecated in RFC 3879).
if ipv6 && ipv6AsBytes[0] == 0xfe && ipv6AsBytes[1]&0xc0 == 0xc0 {
return scopeSiteLocal
}
return scopeGlobal
}
// commonPrefixLen reports the length of the longest prefix (looking
// at the most significant, or leftmost, bits) that the
// two addresses have in common, up to the length of a's prefix (i.e.,
// the portion of the address not including the interface ID).
//
// If a or b is an IPv4 address as an IPv6 address, the IPv4 addresses
// are compared (with max common prefix length of 32).
// If a and b are different IP versions, 0 is returned.
//
// See https://tools.ietf.org/html/rfc6724#section-2.2
func commonPrefixLen(a netip.Addr, b net.IP) (cpl int) {
if b4 := b.To4(); b4 != nil {
b = b4
}
aAsSlice := a.AsSlice()
if len(aAsSlice) != len(b) {
return 0
}
// If IPv6, only up to the prefix (first 64 bits)
if len(aAsSlice) > 8 {
aAsSlice = aAsSlice[:8]
b = b[:8]
}
for len(aAsSlice) > 0 {
if aAsSlice[0] == b[0] {
cpl += 8
aAsSlice = aAsSlice[1:]
b = b[1:]
continue
}
bits := 8
ab, bb := aAsSlice[0], b[0]
for {
ab >>= 1
bb >>= 1
bits--
if ab == bb {
cpl += bits
return
}
}
}
return
}