// Copyright (c) 2020 Tailscale Inc & AUTHORS All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. // Package resolver a DNS resolver. package resolver import ( "encoding/hex" "errors" "net" "strings" "sync" "time" dns "golang.org/x/net/dns/dnsmessage" "inet.af/netaddr" "tailscale.com/net/interfaces" "tailscale.com/types/logger" "tailscale.com/util/dnsname" "tailscale.com/wgengine/monitor" ) // maxResponseBytes is the maximum size of a response from a Resolver. const maxResponseBytes = 512 // queueSize is the maximal number of DNS requests that can await polling. // If EnqueueRequest is called when this many requests are already pending, // the request will be dropped to avoid blocking the caller. const queueSize = 64 // defaultTTL is the TTL of all responses from Resolver. const defaultTTL = 600 * time.Second // ErrClosed indicates that the resolver has been closed and readers should exit. var ErrClosed = errors.New("closed") var ( errFullQueue = errors.New("request queue full") errMapNotSet = errors.New("domain map not set") errNotImplemented = errors.New("query type not implemented") errNotQuery = errors.New("not a DNS query") errNotOurName = errors.New("not a Tailscale DNS name") ) type packet struct { bs []byte addr netaddr.IPPort // src for a request, dst for a response } // Resolver is a DNS resolver for nodes on the Tailscale network, // associating them with domain names of the form ... // If it is asked to resolve a domain that is not of that form, // it delegates to upstream nameservers if any are set. type Resolver struct { logf logger.Logf linkMon *monitor.Mon // or nil unregLinkMon func() // or nil // forwarder forwards requests to upstream nameservers. forwarder *forwarder // queue is a buffered channel holding DNS requests queued for resolution. queue chan packet // responses is an unbuffered channel to which responses are returned. responses chan packet // errors is an unbuffered channel to which errors are returned. errors chan error // closed signals all goroutines to stop. closed chan struct{} // wg signals when all goroutines have stopped. wg sync.WaitGroup // mu guards the following fields from being updated while used. mu sync.Mutex // dnsMap is the map most recently received from the control server. dnsMap *Map } // New returns a new resolver. // linkMon optionally specifies a link monitor to use for socket rebinding. func New(logf logger.Logf, linkMon *monitor.Mon) (*Resolver, error) { r := &Resolver{ logf: logger.WithPrefix(logf, "dns: "), linkMon: linkMon, queue: make(chan packet, queueSize), responses: make(chan packet), errors: make(chan error), closed: make(chan struct{}), } r.forwarder = newForwarder(r.logf, r.responses) if r.linkMon != nil { r.unregLinkMon = r.linkMon.RegisterChangeCallback(r.onLinkMonitorChange) } if err := r.forwarder.Start(); err != nil { return nil, err } r.wg.Add(1) go r.poll() return r, nil } // Close shuts down the resolver and ensures poll goroutines have exited. // The Resolver cannot be used again after Close is called. func (r *Resolver) Close() { select { case <-r.closed: return default: // continue } close(r.closed) if r.unregLinkMon != nil { r.unregLinkMon() } r.forwarder.Close() r.wg.Wait() } func (r *Resolver) onLinkMonitorChange(changed bool, state *interfaces.State) { if !changed { return } r.forwarder.rebindFromNetworkChange() } // SetMap sets the resolver's DNS map, taking ownership of it. func (r *Resolver) SetMap(m *Map) { r.mu.Lock() oldMap := r.dnsMap r.dnsMap = m r.mu.Unlock() r.logf("map diff:\n%s", m.PrettyDiffFrom(oldMap)) } // SetUpstreams sets the addresses of the resolver's // upstream nameservers, taking ownership of the argument. func (r *Resolver) SetUpstreams(upstreams []net.Addr) { r.forwarder.setUpstreams(upstreams) r.logf("set upstreams: %v", upstreams) } // EnqueueRequest places the given DNS request in the resolver's queue. // It takes ownership of the payload and does not block. // If the queue is full, the request will be dropped and an error will be returned. func (r *Resolver) EnqueueRequest(bs []byte, from netaddr.IPPort) error { select { case <-r.closed: return ErrClosed case r.queue <- packet{bs, from}: return nil default: return errFullQueue } } // NextResponse returns a DNS response to a previously enqueued request. // It blocks until a response is available and gives up ownership of the response payload. func (r *Resolver) NextResponse() (packet []byte, to netaddr.IPPort, err error) { select { case <-r.closed: return nil, netaddr.IPPort{}, ErrClosed case resp := <-r.responses: return resp.bs, resp.addr, nil case err := <-r.errors: return nil, netaddr.IPPort{}, err } } // resolve maps a given domain name to the IP address of the host that owns it, // if the IP address conforms to the DNS resource type given by tp (one of A, AAAA, ALL). // The domain name must be in canonical form (with a trailing period). func (r *Resolver) resolve(domain string, tp dns.Type) (netaddr.IP, dns.RCode, error) { r.mu.Lock() dnsMap := r.dnsMap r.mu.Unlock() if dnsMap == nil { return netaddr.IP{}, dns.RCodeServerFailure, errMapNotSet } // Reject .onion domains per RFC 7686. if dnsname.HasSuffix(domain, ".onion") { return netaddr.IP{}, dns.RCodeNameError, nil } anyHasSuffix := false for _, suffix := range dnsMap.rootDomains { if dnsname.HasSuffix(domain, suffix) { anyHasSuffix = true break } } addr, found := dnsMap.nameToIP[domain] if !found { if !anyHasSuffix { return netaddr.IP{}, dns.RCodeRefused, nil } return netaddr.IP{}, dns.RCodeNameError, nil } // Refactoring note: this must happen after we check suffixes, // otherwise we will respond with NOTIMP to requests that should be forwarded. switch tp { case dns.TypeA: if !addr.Is4() { return netaddr.IP{}, dns.RCodeSuccess, nil } return addr, dns.RCodeSuccess, nil case dns.TypeAAAA: if !addr.Is6() { return netaddr.IP{}, dns.RCodeSuccess, nil } return addr, dns.RCodeSuccess, nil case dns.TypeALL: // Answer with whatever we've got. // It could be IPv4, IPv6, or a zero addr. // TODO: Return all available resolutions (A and AAAA, if we have them). return addr, dns.RCodeSuccess, nil // Leave some some record types explicitly unimplemented. // These types relate to recursive resolution or special // DNS sematics and might be implemented in the future. case dns.TypeNS, dns.TypeSOA, dns.TypeAXFR, dns.TypeHINFO: return netaddr.IP{}, dns.RCodeNotImplemented, errNotImplemented // For everything except for the few types above that are explictly not implemented, return no records. // This is what other DNS systems do: always return NOERROR // without any records whenever the requested record type is unknown. // You can try this with: // dig -t TYPE9824 example.com // and note that NOERROR is returned, despite that record type being made up. default: // no records exist of this type return netaddr.IP{}, dns.RCodeSuccess, nil } } // resolveReverse returns the unique domain name that maps to the given address. // The returned domain name is in canonical form (with a trailing period). func (r *Resolver) resolveReverse(ip netaddr.IP) (string, dns.RCode, error) { r.mu.Lock() dnsMap := r.dnsMap r.mu.Unlock() if dnsMap == nil { return "", dns.RCodeServerFailure, errMapNotSet } name, found := dnsMap.ipToName[ip] if !found { return "", dns.RCodeNameError, nil } return name, dns.RCodeSuccess, nil } func (r *Resolver) poll() { defer r.wg.Done() var pkt packet for { select { case <-r.closed: return case pkt = <-r.queue: // continue } out, err := r.respond(pkt.bs) if err == errNotOurName { err = r.forwarder.forward(pkt) if err == nil { // forward will send response into r.responses, nothing to do. continue } } if err != nil { select { case <-r.closed: return case r.errors <- err: // continue } } else { pkt.bs = out select { case <-r.closed: return case r.responses <- pkt: // continue } } } } type response struct { Header dns.Header Question dns.Question // Name is the response to a PTR query. Name string // IP is the response to an A, AAAA, or ALL query. IP netaddr.IP } // parseQuery parses the query in given packet into a response struct. func parseQuery(query []byte, resp *response) error { var parser dns.Parser var err error resp.Header, err = parser.Start(query) if err != nil { return err } if resp.Header.Response { return errNotQuery } resp.Question, err = parser.Question() if err != nil { return err } return nil } // marshalARecord serializes an A record into an active builder. // The caller may continue using the builder following the call. func marshalARecord(name dns.Name, ip netaddr.IP, builder *dns.Builder) error { var answer dns.AResource answerHeader := dns.ResourceHeader{ Name: name, Type: dns.TypeA, Class: dns.ClassINET, TTL: uint32(defaultTTL / time.Second), } ipbytes := ip.As4() copy(answer.A[:], ipbytes[:]) return builder.AResource(answerHeader, answer) } // marshalAAAARecord serializes an AAAA record into an active builder. // The caller may continue using the builder following the call. func marshalAAAARecord(name dns.Name, ip netaddr.IP, builder *dns.Builder) error { var answer dns.AAAAResource answerHeader := dns.ResourceHeader{ Name: name, Type: dns.TypeAAAA, Class: dns.ClassINET, TTL: uint32(defaultTTL / time.Second), } ipbytes := ip.As16() copy(answer.AAAA[:], ipbytes[:]) return builder.AAAAResource(answerHeader, answer) } // marshalPTRRecord serializes a PTR record into an active builder. // The caller may continue using the builder following the call. func marshalPTRRecord(queryName dns.Name, name string, builder *dns.Builder) error { var answer dns.PTRResource var err error answerHeader := dns.ResourceHeader{ Name: queryName, Type: dns.TypePTR, Class: dns.ClassINET, TTL: uint32(defaultTTL / time.Second), } answer.PTR, err = dns.NewName(name) if err != nil { return err } return builder.PTRResource(answerHeader, answer) } // marshalResponse serializes the DNS response into a new buffer. func marshalResponse(resp *response) ([]byte, error) { resp.Header.Response = true resp.Header.Authoritative = true if resp.Header.RecursionDesired { resp.Header.RecursionAvailable = true } builder := dns.NewBuilder(nil, resp.Header) isSuccess := resp.Header.RCode == dns.RCodeSuccess if resp.Question.Type != 0 || isSuccess { err := builder.StartQuestions() if err != nil { return nil, err } err = builder.Question(resp.Question) if err != nil { return nil, err } } // Only successful responses contain answers. if !isSuccess { return builder.Finish() } err := builder.StartAnswers() if err != nil { return nil, err } switch resp.Question.Type { case dns.TypeA, dns.TypeAAAA, dns.TypeALL: if resp.IP.Is4() { err = marshalARecord(resp.Question.Name, resp.IP, &builder) } else if resp.IP.Is6() { err = marshalAAAARecord(resp.Question.Name, resp.IP, &builder) } case dns.TypePTR: err = marshalPTRRecord(resp.Question.Name, resp.Name, &builder) } if err != nil { return nil, err } return builder.Finish() } const ( rdnsv4Suffix = ".in-addr.arpa." rdnsv6Suffix = ".ip6.arpa." ) // hasRDNSBonjourPrefix reports whether name has a Bonjour Service Prefix.. // // https://tools.ietf.org/html/rfc6763 lists // "five special RR names" for Bonjour service discovery: // // b._dns-sd._udp.. // db._dns-sd._udp.. // r._dns-sd._udp.. // dr._dns-sd._udp.. // lb._dns-sd._udp.. func hasRDNSBonjourPrefix(s string) bool { // Even the shortest name containing a Bonjour prefix is long, // so check length (cheap) and bail early if possible. if len(s) < len("*._dns-sd._udp.0.0.0.0.in-addr.arpa.") { return false } dot := strings.IndexByte(s, '.') if dot == -1 { return false // shouldn't happen } switch s[:dot] { case "b", "db", "r", "dr", "lb": default: return false } return strings.HasPrefix(s[dot:], "._dns-sd._udp.") } // rawNameToLower converts a raw DNS name to a string, lowercasing it. func rawNameToLower(name []byte) string { var sb strings.Builder sb.Grow(len(name)) for _, b := range name { if 'A' <= b && b <= 'Z' { b = b - 'A' + 'a' } sb.WriteByte(b) } return sb.String() } // ptrNameToIPv4 transforms a PTR name representing an IPv4 address to said address. // Such names are IPv4 labels in reverse order followed by .in-addr.arpa. // For example, // 4.3.2.1.in-addr.arpa // is transformed to // 1.2.3.4 func rdnsNameToIPv4(name string) (ip netaddr.IP, ok bool) { name = strings.TrimSuffix(name, rdnsv4Suffix) ip, err := netaddr.ParseIP(string(name)) if err != nil { return netaddr.IP{}, false } if !ip.Is4() { return netaddr.IP{}, false } b := ip.As4() return netaddr.IPv4(b[3], b[2], b[1], b[0]), true } // ptrNameToIPv6 transforms a PTR name representing an IPv6 address to said address. // Such names are dot-separated nibbles in reverse order followed by .ip6.arpa. // For example, // b.a.9.8.7.6.5.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.0.8.b.d.0.1.0.0.2.ip6.arpa. // is transformed to // 2001:db8::567:89ab func rdnsNameToIPv6(name string) (ip netaddr.IP, ok bool) { var b [32]byte var ipb [16]byte name = strings.TrimSuffix(name, rdnsv6Suffix) // 32 nibbles and 31 dots between them. if len(name) != 63 { return netaddr.IP{}, false } // Dots and hex digits alternate. prevDot := true // i ranges over name backward; j ranges over b forward. for i, j := len(name)-1, 0; i >= 0; i-- { thisDot := (name[i] == '.') if prevDot == thisDot { return netaddr.IP{}, false } prevDot = thisDot if !thisDot { // This is safe assuming alternation. // We do not check that non-dots are hex digits: hex.Decode below will do that. b[j] = name[i] j++ } } _, err := hex.Decode(ipb[:], b[:]) if err != nil { return netaddr.IP{}, false } return netaddr.IPFrom16(ipb), true } // respondReverse returns a DNS response to a PTR query. // It is assumed that resp.Question is populated by respond before this is called. func (r *Resolver) respondReverse(query []byte, name string, resp *response) ([]byte, error) { if hasRDNSBonjourPrefix(name) { return nil, errNotOurName } var ip netaddr.IP var ok bool switch { case strings.HasSuffix(name, rdnsv4Suffix): ip, ok = rdnsNameToIPv4(name) case strings.HasSuffix(name, rdnsv6Suffix): ip, ok = rdnsNameToIPv6(name) default: return nil, errNotOurName } // It is more likely that we failed in parsing the name than that it is actually malformed. // To avoid frustrating users, just log and delegate. if !ok { r.logf("parsing rdns: malformed name: %s", name) return nil, errNotOurName } var err error resp.Name, resp.Header.RCode, err = r.resolveReverse(ip) if err != nil { r.logf("resolving rdns: %v", ip, err) } if resp.Header.RCode == dns.RCodeNameError { return nil, errNotOurName } return marshalResponse(resp) } // respond returns a DNS response to query if it can be resolved locally. // Otherwise, it returns errNotOurName. func (r *Resolver) respond(query []byte) ([]byte, error) { resp := new(response) // ParseQuery is sufficiently fast to run on every DNS packet. // This is considerably simpler than extracting the name by hand // to shave off microseconds in case of delegation. err := parseQuery(query, resp) // We will not return this error: it is the sender's fault. if err != nil { if errors.Is(err, dns.ErrSectionDone) { r.logf("parseQuery(%02x): no DNS questions", query) } else { r.logf("parseQuery(%02x): %v", query, err) } resp.Header.RCode = dns.RCodeFormatError return marshalResponse(resp) } rawName := resp.Question.Name.Data[:resp.Question.Name.Length] name := rawNameToLower(rawName) // Always try to handle reverse lookups; delegate inside when not found. // This way, queries for existent nodes do not leak, // but we behave gracefully if non-Tailscale nodes exist in CGNATRange. if resp.Question.Type == dns.TypePTR { return r.respondReverse(query, name, resp) } resp.IP, resp.Header.RCode, err = r.resolve(name, resp.Question.Type) // This return code is special: it requests forwarding. if resp.Header.RCode == dns.RCodeRefused { return nil, errNotOurName } // We will not return this error: it is the sender's fault. if err != nil { r.logf("resolving: %v", err) } return marshalResponse(resp) }