// Package dnsforward contains a DNS forwarding server. package dnsforward import ( "fmt" "net" "net/http" "runtime" "strings" "sync" "time" "github.com/AdguardTeam/AdGuardHome/internal/aghnet" "github.com/AdguardTeam/AdGuardHome/internal/dhcpd" "github.com/AdguardTeam/AdGuardHome/internal/filtering" "github.com/AdguardTeam/AdGuardHome/internal/querylog" "github.com/AdguardTeam/AdGuardHome/internal/stats" "github.com/AdguardTeam/dnsproxy/proxy" "github.com/AdguardTeam/dnsproxy/upstream" "github.com/AdguardTeam/golibs/cache" "github.com/AdguardTeam/golibs/errors" "github.com/AdguardTeam/golibs/log" "github.com/AdguardTeam/golibs/netutil" "github.com/AdguardTeam/golibs/stringutil" "github.com/miekg/dns" ) // DefaultTimeout is the default upstream timeout const DefaultTimeout = 10 * time.Second // defaultClientIDCacheCount is the default count of items in the LRU ClientID // cache. The assumption here is that there won't be more than this many // requests between the BeforeRequestHandler stage and the actual processing. const defaultClientIDCacheCount = 1024 var defaultDNS = []string{ "https://dns10.quad9.net/dns-query", } var defaultBootstrap = []string{"9.9.9.10", "149.112.112.10", "2620:fe::10", "2620:fe::fe:10"} // Often requested by all kinds of DNS probes var defaultBlockedHosts = []string{"version.bind", "id.server", "hostname.bind"} var webRegistered bool // hostToIPTable is an alias for the type of Server.tableHostToIP. type hostToIPTable = map[string]net.IP // Server is the main way to start a DNS server. // // Example: // s := dnsforward.Server{} // err := s.Start(nil) // will start a DNS server listening on default port 53, in a goroutine // err := s.Reconfigure(ServerConfig{UDPListenAddr: &net.UDPAddr{Port: 53535}}) // will reconfigure running DNS server to listen on UDP port 53535 // err := s.Stop() // will stop listening on port 53535 and cancel all goroutines // err := s.Start(nil) // will start listening again, on port 53535, in a goroutine // // The zero Server is empty and ready for use. type Server struct { dnsProxy *proxy.Proxy // DNS proxy instance dnsFilter *filtering.DNSFilter // DNS filter instance dhcpServer dhcpd.ServerInterface // DHCP server instance (optional) queryLog querylog.QueryLog // Query log instance stats stats.Interface access *accessCtx // localDomainSuffix is the suffix used to detect internal hosts. It // must be a valid domain name plus dots on each side. localDomainSuffix string ipset ipsetCtx privateNets netutil.SubnetSet localResolvers *proxy.Proxy sysResolvers aghnet.SystemResolvers recDetector *recursionDetector // anonymizer masks the client's IP addresses if needed. anonymizer *aghnet.IPMut tableHostToIP hostToIPTable tableHostToIPLock sync.Mutex tableIPToHost *netutil.IPMap tableIPToHostLock sync.Mutex // clientIDCache is a temporary storage for ClientIDs that were extracted // during the BeforeRequestHandler stage. clientIDCache cache.Cache // DNS proxy instance for internal usage // We don't Start() it and so no listen port is required. internalProxy *proxy.Proxy isRunning bool conf ServerConfig // serverLock protects Server. serverLock sync.RWMutex } // defaultLocalDomainSuffix is the default suffix used to detect internal hosts // when no suffix is provided. // // See the documentation for Server.localDomainSuffix. const defaultLocalDomainSuffix = "lan" // DNSCreateParams are parameters to create a new server. type DNSCreateParams struct { DNSFilter *filtering.DNSFilter Stats stats.Interface QueryLog querylog.QueryLog DHCPServer dhcpd.ServerInterface PrivateNets netutil.SubnetSet Anonymizer *aghnet.IPMut LocalDomain string } const ( // recursionTTL is the time recursive request is cached for. recursionTTL = 1 * time.Second // cachedRecurrentReqNum is the maximum number of cached recurrent // requests. cachedRecurrentReqNum = 1000 ) // NewServer creates a new instance of the dnsforward.Server // Note: this function must be called only once func NewServer(p DNSCreateParams) (s *Server, err error) { var localDomainSuffix string if p.LocalDomain == "" { localDomainSuffix = defaultLocalDomainSuffix } else { err = netutil.ValidateDomainName(p.LocalDomain) if err != nil { return nil, fmt.Errorf("local domain: %w", err) } localDomainSuffix = p.LocalDomain } if p.Anonymizer == nil { p.Anonymizer = aghnet.NewIPMut(nil) } s = &Server{ dnsFilter: p.DNSFilter, stats: p.Stats, queryLog: p.QueryLog, privateNets: p.PrivateNets, localDomainSuffix: localDomainSuffix, recDetector: newRecursionDetector(recursionTTL, cachedRecurrentReqNum), clientIDCache: cache.New(cache.Config{ EnableLRU: true, MaxCount: defaultClientIDCacheCount, }), anonymizer: p.Anonymizer, } // TODO(e.burkov): Enable the refresher after the actual implementation // passes the public testing. s.sysResolvers, err = aghnet.NewSystemResolvers(nil) if err != nil { return nil, fmt.Errorf("initializing system resolvers: %w", err) } if p.DHCPServer != nil { s.dhcpServer = p.DHCPServer s.dhcpServer.SetOnLeaseChanged(s.onDHCPLeaseChanged) s.onDHCPLeaseChanged(dhcpd.LeaseChangedAdded) } if runtime.GOARCH == "mips" || runtime.GOARCH == "mipsle" { // Use plain DNS on MIPS, encryption is too slow defaultDNS = defaultBootstrap } return s, nil } // NewCustomServer creates a new instance of *Server with custom internal proxy. func NewCustomServer(internalProxy *proxy.Proxy) *Server { s := &Server{ recDetector: newRecursionDetector(0, 1), } if internalProxy != nil { s.internalProxy = internalProxy } return s } // Close gracefully closes the server. It is safe for concurrent use. // // TODO(e.burkov): A better approach would be making Stop method waiting for all // its workers finished. But it would require the upstream.Upstream to have the // Close method to prevent from hanging while waiting for unresponsive server to // respond. func (s *Server) Close() { s.serverLock.Lock() defer s.serverLock.Unlock() s.dnsFilter = nil s.stats = nil s.queryLog = nil s.dnsProxy = nil if err := s.ipset.close(); err != nil { log.Error("closing ipset: %s", err) } } // WriteDiskConfig - write configuration func (s *Server) WriteDiskConfig(c *FilteringConfig) { s.serverLock.RLock() defer s.serverLock.RUnlock() sc := s.conf.FilteringConfig *c = sc c.RatelimitWhitelist = stringutil.CloneSlice(sc.RatelimitWhitelist) c.BootstrapDNS = stringutil.CloneSlice(sc.BootstrapDNS) c.AllowedClients = stringutil.CloneSlice(sc.AllowedClients) c.DisallowedClients = stringutil.CloneSlice(sc.DisallowedClients) c.BlockedHosts = stringutil.CloneSlice(sc.BlockedHosts) c.TrustedProxies = stringutil.CloneSlice(sc.TrustedProxies) c.UpstreamDNS = stringutil.CloneSlice(sc.UpstreamDNS) } // RDNSSettings returns the copy of actual RDNS configuration. func (s *Server) RDNSSettings() (localPTRResolvers []string, resolveClients, resolvePTR bool) { s.serverLock.RLock() defer s.serverLock.RUnlock() return stringutil.CloneSlice(s.conf.LocalPTRResolvers), s.conf.ResolveClients, s.conf.UsePrivateRDNS } // Resolve - get IP addresses by host name from an upstream server. // No request/response filtering is performed. // Query log and Stats are not updated. // This method may be called before Start(). func (s *Server) Resolve(host string) ([]net.IPAddr, error) { s.serverLock.RLock() defer s.serverLock.RUnlock() return s.internalProxy.LookupIPAddr(host) } // RDNSExchanger is a resolver for clients' addresses. type RDNSExchanger interface { // Exchange tries to resolve the ip in a suitable way, e.g. either as // local or as external. Exchange(ip net.IP) (host string, err error) // ResolvesPrivatePTR returns true if the RDNSExchanger is able to // resolve PTR requests for locally-served addresses. ResolvesPrivatePTR() (ok bool) } const ( // rDNSEmptyAnswerErr is returned by Exchange method when the answer // section of respond is empty. rDNSEmptyAnswerErr errors.Error = "the answer section is empty" // rDNSNotPTRErr is returned by Exchange method when the response is not // of PTR type. rDNSNotPTRErr errors.Error = "the response is not a ptr" ) // Exchange implements the RDNSExchanger interface for *Server. func (s *Server) Exchange(ip net.IP) (host string, err error) { s.serverLock.RLock() defer s.serverLock.RUnlock() if !s.conf.ResolveClients { return "", nil } arpa, err := netutil.IPToReversedAddr(ip) if err != nil { return "", fmt.Errorf("reversing ip: %w", err) } arpa = dns.Fqdn(arpa) req := &dns.Msg{ MsgHdr: dns.MsgHdr{ Id: dns.Id(), RecursionDesired: true, }, Compress: true, Question: []dns.Question{{ Name: arpa, Qtype: dns.TypePTR, Qclass: dns.ClassINET, }}, } ctx := &proxy.DNSContext{ Proto: "udp", Req: req, StartTime: time.Now(), } var resolver *proxy.Proxy if s.privateNets.Contains(ip) { if !s.conf.UsePrivateRDNS { return "", nil } resolver = s.localResolvers s.recDetector.add(*req) } else { resolver = s.internalProxy } if err = resolver.Resolve(ctx); err != nil { return "", err } resp := ctx.Res if len(resp.Answer) == 0 { return "", fmt.Errorf("lookup for %q: %w", arpa, rDNSEmptyAnswerErr) } ptr, ok := resp.Answer[0].(*dns.PTR) if !ok { return "", fmt.Errorf("type checking: %w", rDNSNotPTRErr) } return strings.TrimSuffix(ptr.Ptr, "."), nil } // ResolvesPrivatePTR implements the RDNSExchanger interface for *Server. func (s *Server) ResolvesPrivatePTR() (ok bool) { s.serverLock.RLock() defer s.serverLock.RUnlock() return s.conf.UsePrivateRDNS } // Start starts the DNS server. func (s *Server) Start() error { s.serverLock.Lock() defer s.serverLock.Unlock() return s.startLocked() } // startLocked starts the DNS server without locking. For internal use only. func (s *Server) startLocked() error { err := s.dnsProxy.Start() if err == nil { s.isRunning = true } return err } // defaultLocalTimeout is the default timeout for resolving addresses from // locally-served networks. It is assumed that local resolvers should work much // faster than ordinary upstreams. const defaultLocalTimeout = 1 * time.Second // collectDNSIPAddrs returns IP addresses the server is listening on without // port numbers. For internal use only. func (s *Server) collectDNSIPAddrs() (addrs []string, err error) { addrs = make([]string, len(s.conf.TCPListenAddrs)+len(s.conf.UDPListenAddrs)) var i int var ip net.IP for _, addr := range s.conf.TCPListenAddrs { if addr == nil { continue } if ip = addr.IP; ip.IsUnspecified() { return aghnet.CollectAllIfacesAddrs() } addrs[i] = ip.String() i++ } for _, addr := range s.conf.UDPListenAddrs { if addr == nil { continue } if ip = addr.IP; ip.IsUnspecified() { return aghnet.CollectAllIfacesAddrs() } addrs[i] = ip.String() i++ } return addrs[:i], nil } func (s *Server) filterOurDNSAddrs(addrs []string) (filtered []string, err error) { var ourAddrs []string ourAddrs, err = s.collectDNSIPAddrs() if err != nil { return nil, err } ourAddrsSet := stringutil.NewSet(ourAddrs...) // TODO(e.burkov): The approach of subtracting sets of strings is not // really applicable here since in case of listening on all network // interfaces we should check the whole interface's network to cut off // all the loopback addresses as well. return stringutil.FilterOut(addrs, ourAddrsSet.Has), nil } // setupResolvers initializes the resolvers for local addresses. For internal // use only. func (s *Server) setupResolvers(localAddrs []string) (err error) { bootstraps := s.conf.BootstrapDNS if len(localAddrs) == 0 { localAddrs = s.sysResolvers.Get() bootstraps = nil } localAddrs, err = s.filterOurDNSAddrs(localAddrs) if err != nil { return err } log.Debug("upstreams to resolve PTR for local addresses: %v", localAddrs) var upsConfig *proxy.UpstreamConfig upsConfig, err = proxy.ParseUpstreamsConfig( localAddrs, &upstream.Options{ Bootstrap: bootstraps, Timeout: defaultLocalTimeout, // TODO(e.burkov): Should we verify server's certificates? }, ) if err != nil { return fmt.Errorf("parsing upstreams: %w", err) } s.localResolvers = &proxy.Proxy{ Config: proxy.Config{ UpstreamConfig: upsConfig, }, } return nil } // Prepare the object func (s *Server) Prepare(config *ServerConfig) error { // Initialize the server configuration // -- if config != nil { s.conf = *config if s.conf.BlockingMode == "custom_ip" { if s.conf.BlockingIPv4 == nil || s.conf.BlockingIPv6 == nil { return fmt.Errorf("dns: invalid custom blocking IP address specified") } } } // Set default values in the case if nothing is configured // -- s.initDefaultSettings() // Initialize ipset configuration // -- err := s.ipset.init(s.conf.IpsetList) if err != nil { return err } log.Debug("inited ipset") // Prepare DNS servers settings // -- err = s.prepareUpstreamSettings() if err != nil { return err } // Create DNS proxy configuration // -- var proxyConfig proxy.Config proxyConfig, err = s.createProxyConfig() if err != nil { return err } // Prepare a DNS proxy instance that we use for internal DNS queries // -- s.prepareIntlProxy() s.access, err = newAccessCtx(s.conf.AllowedClients, s.conf.DisallowedClients, s.conf.BlockedHosts) if err != nil { return err } // Register web handlers if necessary // -- if !webRegistered && s.conf.HTTPRegister != nil { webRegistered = true s.registerHandlers() } // Create the main DNS proxy instance // -- s.dnsProxy = &proxy.Proxy{Config: proxyConfig} err = s.setupResolvers(s.conf.LocalPTRResolvers) if err != nil { return fmt.Errorf("setting up resolvers: %w", err) } s.recDetector.clear() return nil } // Stop stops the DNS server. func (s *Server) Stop() error { s.serverLock.Lock() defer s.serverLock.Unlock() return s.stopLocked() } // stopLocked stops the DNS server without locking. For internal use only. func (s *Server) stopLocked() error { if s.dnsProxy != nil { err := s.dnsProxy.Stop() if err != nil { return fmt.Errorf("could not stop the DNS server properly: %w", err) } } s.isRunning = false return nil } // IsRunning returns true if the DNS server is running. func (s *Server) IsRunning() bool { s.serverLock.RLock() defer s.serverLock.RUnlock() return s.isRunning } // srvClosedErr is returned when the method can't complete without inaccessible // data from the closing server. const srvClosedErr errors.Error = "server is closed" // proxy returns a pointer to the current DNS proxy instance. If p is nil, the // server is closing. // // See https://github.com/AdguardTeam/AdGuardHome/issues/3655. func (s *Server) proxy() (p *proxy.Proxy) { s.serverLock.RLock() defer s.serverLock.RUnlock() return s.dnsProxy } // Reconfigure applies the new configuration to the DNS server. func (s *Server) Reconfigure(config *ServerConfig) error { s.serverLock.Lock() defer s.serverLock.Unlock() log.Print("Start reconfiguring the server") err := s.stopLocked() if err != nil { return fmt.Errorf("could not reconfigure the server: %w", err) } // It seems that net.Listener.Close() doesn't close file descriptors right away. // We wait for some time and hope that this fd will be closed. time.Sleep(100 * time.Millisecond) err = s.Prepare(config) if err != nil { return fmt.Errorf("could not reconfigure the server: %w", err) } err = s.startLocked() if err != nil { return fmt.Errorf("could not reconfigure the server: %w", err) } return nil } // ServeHTTP is a HTTP handler method we use to provide DNS-over-HTTPS. func (s *Server) ServeHTTP(w http.ResponseWriter, r *http.Request) { if prx := s.proxy(); prx != nil { prx.ServeHTTP(w, r) } } // IsBlockedClient returns true if the client is blocked by the current access // settings. func (s *Server) IsBlockedClient(ip net.IP, clientID string) (blocked bool, rule string) { s.serverLock.RLock() defer s.serverLock.RUnlock() allowlistMode := s.access.allowlistMode() blockedByIP, rule := s.access.isBlockedIP(ip) blockedByClientID := s.access.isBlockedClientID(clientID) // Allow if at least one of the checks allows in allowlist mode, but // block if at least one of the checks blocks in blocklist mode. if allowlistMode && blockedByIP && blockedByClientID { log.Debug("client %s (id %q) is not in access allowlist", ip, clientID) // Return now without substituting the empty rule for the // clientID because the rule can't be empty here. return true, rule } else if !allowlistMode && (blockedByIP || blockedByClientID) { log.Debug("client %s (id %q) is in access blocklist", ip, clientID) blocked = true } if rule == "" { rule = clientID } return blocked, rule }