package server import ( "context" "fmt" "io" "net" "runtime/debug" "sort" "strconv" "strings" "sync" "time" "github.com/micro/go-micro/broker" "github.com/micro/go-micro/codec" raw "github.com/micro/go-micro/codec/bytes" "github.com/micro/go-micro/metadata" "github.com/micro/go-micro/registry" "github.com/micro/go-micro/transport" "github.com/micro/go-micro/util/addr" log "github.com/micro/go-micro/util/log" mnet "github.com/micro/go-micro/util/net" "github.com/micro/go-micro/util/socket" ) type rpcServer struct { router *router exit chan chan error sync.RWMutex opts Options handlers map[string]Handler subscribers map[Subscriber][]broker.Subscriber // marks the serve as started started bool // used for first registration registered bool // subscribe to service name subscriber broker.Subscriber // graceful exit wg *sync.WaitGroup } func newRpcServer(opts ...Option) Server { options := newOptions(opts...) router := newRpcRouter() router.hdlrWrappers = options.HdlrWrappers router.subWrappers = options.SubWrappers return &rpcServer{ opts: options, router: router, handlers: make(map[string]Handler), subscribers: make(map[Subscriber][]broker.Subscriber), exit: make(chan chan error), wg: wait(options.Context), } } // HandleEvent handles inbound messages to the service directly // TODO: handle requests from an event. We won't send a response. func (s *rpcServer) HandleEvent(e broker.Event) error { // formatting horrible cruft msg := e.Message() if msg.Header == nil { // create empty map in case of headers empty to avoid panic later msg.Header = make(map[string]string) } // get codec ct := msg.Header["Content-Type"] // default content type if len(ct) == 0 { msg.Header["Content-Type"] = DefaultContentType ct = DefaultContentType } // get codec cf, err := s.newCodec(ct) if err != nil { return err } // copy headers hdr := make(map[string]string) for k, v := range msg.Header { hdr[k] = v } // create context ctx := metadata.NewContext(context.Background(), hdr) // TODO: inspect message header // Micro-Service means a request // Micro-Topic means a message rpcMsg := &rpcMessage{ topic: msg.Header["Micro-Topic"], contentType: ct, payload: &raw.Frame{Data: msg.Body}, codec: cf, header: msg.Header, body: msg.Body, } // existing router r := Router(s.router) // if the router is present then execute it if s.opts.Router != nil { // create a wrapped function handler := s.opts.Router.ProcessMessage // execute the wrapper for it for i := len(s.opts.SubWrappers); i > 0; i-- { handler = s.opts.SubWrappers[i-1](handler) } // set the router r = rpcRouter{m: handler} } return r.ProcessMessage(ctx, rpcMsg) } // ServeConn serves a single connection func (s *rpcServer) ServeConn(sock transport.Socket) { // global error tracking var gerr error // streams are multiplexed on Micro-Stream or Micro-Id header pool := socket.NewPool() // get global waitgroup s.Lock() gg := s.wg s.Unlock() // waitgroup to wait for processing to finish wg := &waitGroup{ gg: gg, } defer func() { // only wait if there's no error if gerr == nil { // wait till done wg.Wait() } // close all the sockets for this connection pool.Close() // close underlying socket sock.Close() // recover any panics if r := recover(); r != nil { log.Log("panic recovered: ", r) log.Log(string(debug.Stack())) } }() for { var msg transport.Message // process inbound messages one at a time if err := sock.Recv(&msg); err != nil { // set a global error and return // we're saying we essentially can't // use the socket anymore gerr = err return } // check the message header for // Micro-Service is a request // Micro-Topic is a message if t := msg.Header["Micro-Topic"]; len(t) > 0 { // process the event ev := newEvent(msg) // TODO: handle the error event if err := s.HandleEvent(ev); err != nil { msg.Header["Micro-Error"] = err.Error() } // write back some 200 if err := sock.Send(&transport.Message{ Header: msg.Header, }); err != nil { gerr = err break } // we're done continue } // business as usual // use Micro-Stream as the stream identifier // in the event its blank we'll always process // on the same socket id := msg.Header["Micro-Stream"] // if there's no stream id then its a standard request // use the Micro-Id if len(id) == 0 { id = msg.Header["Micro-Id"] } // check stream id var stream bool if v := getHeader("Micro-Stream", msg.Header); len(v) > 0 { stream = true } // check if we have an existing socket psock, ok := pool.Get(id) // if we don't have a socket and its a stream if !ok && stream { // check if its a last stream EOS error err := msg.Header["Micro-Error"] if err == lastStreamResponseError.Error() { pool.Release(psock) continue } } // got an existing socket already if ok { // we're starting processing wg.Add(1) // pass the message to that existing socket if err := psock.Accept(&msg); err != nil { // release the socket if there's an error pool.Release(psock) } // done waiting wg.Done() // continue to the next message continue } // no socket was found so its new // set the local and remote values psock.SetLocal(sock.Local()) psock.SetRemote(sock.Remote()) // load the socket with the current message psock.Accept(&msg) // now walk the usual path // we use this Timeout header to set a server deadline to := msg.Header["Timeout"] // we use this Content-Type header to identify the codec needed ct := msg.Header["Content-Type"] // copy the message headers hdr := make(map[string]string) for k, v := range msg.Header { hdr[k] = v } // set local/remote ips hdr["Local"] = sock.Local() hdr["Remote"] = sock.Remote() // create new context with the metadata ctx := metadata.NewContext(context.Background(), hdr) // set the timeout from the header if we have it if len(to) > 0 { if n, err := strconv.ParseUint(to, 10, 64); err == nil { var cancel context.CancelFunc ctx, cancel = context.WithTimeout(ctx, time.Duration(n)) defer cancel() } } // if there's no content type default it if len(ct) == 0 { msg.Header["Content-Type"] = DefaultContentType ct = DefaultContentType } // setup old protocol cf := setupProtocol(&msg) // no legacy codec needed if cf == nil { var err error // try get a new codec if cf, err = s.newCodec(ct); err != nil { // no codec found so send back an error if err := sock.Send(&transport.Message{ Header: map[string]string{ "Content-Type": "text/plain", }, Body: []byte(err.Error()), }); err != nil { gerr = err } // release the socket we just created pool.Release(psock) // now continue continue } } // create a new rpc codec based on the pseudo socket and codec rcodec := newRpcCodec(&msg, psock, cf) // check the protocol as well protocol := rcodec.String() // internal request request := &rpcRequest{ service: getHeader("Micro-Service", msg.Header), method: getHeader("Micro-Method", msg.Header), endpoint: getHeader("Micro-Endpoint", msg.Header), contentType: ct, codec: rcodec, header: msg.Header, body: msg.Body, socket: psock, stream: stream, } // internal response response := &rpcResponse{ header: make(map[string]string), socket: psock, codec: rcodec, } // set router r := Router(s.router) // if not nil use the router specified if s.opts.Router != nil { // create a wrapped function handler := func(ctx context.Context, req Request, rsp interface{}) error { return s.opts.Router.ServeRequest(ctx, req, rsp.(Response)) } // execute the wrapper for it for i := len(s.opts.HdlrWrappers); i > 0; i-- { handler = s.opts.HdlrWrappers[i-1](handler) } // set the router r = rpcRouter{h: handler} } // process the outbound messages from the socket go func(id string, psock *socket.Socket) { // wait for processing to exit wg.Add(1) defer func() { // TODO: don't hack this but if its grpc just break out of the stream // We do this because the underlying connection is h2 and its a stream switch protocol { case "grpc": sock.Close() } // release the socket pool.Release(psock) // signal we're done wg.Done() // recover any panics for outbound process if r := recover(); r != nil { log.Log("panic recovered: ", r) log.Log(string(debug.Stack())) } }() for { // get the message from our internal handler/stream m := new(transport.Message) if err := psock.Process(m); err != nil { return } // send the message back over the socket if err := sock.Send(m); err != nil { return } } }(id, psock) // serve the request in a go routine as this may be a stream go func(id string, psock *socket.Socket) { // add to the waitgroup wg.Add(1) defer func() { // release the socket pool.Release(psock) // signal we're done wg.Done() // recover any panics for call handler if r := recover(); r != nil { log.Log("panic recovered: ", r) log.Log(string(debug.Stack())) } }() // serve the actual request using the request router if serveRequestError := r.ServeRequest(ctx, request, response); serveRequestError != nil { // write an error response writeError := rcodec.Write(&codec.Message{ Header: msg.Header, Error: serveRequestError.Error(), Type: codec.Error, }, nil) // if the server request is an EOS error we let the socket know // sometimes the socket is already closed on the other side, so we can ignore that error alreadyClosed := serveRequestError == lastStreamResponseError && writeError == io.EOF // could not write error response if writeError != nil && !alreadyClosed { log.Debugf("rpc: unable to write error response: %v", writeError) } } }(id, psock) } } func (s *rpcServer) newCodec(contentType string) (codec.NewCodec, error) { if cf, ok := s.opts.Codecs[contentType]; ok { return cf, nil } if cf, ok := DefaultCodecs[contentType]; ok { return cf, nil } return nil, fmt.Errorf("Unsupported Content-Type: %s", contentType) } func (s *rpcServer) Options() Options { s.RLock() opts := s.opts s.RUnlock() return opts } func (s *rpcServer) Init(opts ...Option) error { s.Lock() for _, opt := range opts { opt(&s.opts) } // update router if its the default if s.opts.Router == nil { r := newRpcRouter() r.hdlrWrappers = s.opts.HdlrWrappers r.serviceMap = s.router.serviceMap r.subWrappers = s.opts.SubWrappers s.router = r } s.Unlock() return nil } func (s *rpcServer) NewHandler(h interface{}, opts ...HandlerOption) Handler { return s.router.NewHandler(h, opts...) } func (s *rpcServer) Handle(h Handler) error { s.Lock() defer s.Unlock() if err := s.router.Handle(h); err != nil { return err } s.handlers[h.Name()] = h return nil } func (s *rpcServer) NewSubscriber(topic string, sb interface{}, opts ...SubscriberOption) Subscriber { return s.router.NewSubscriber(topic, sb, opts...) } func (s *rpcServer) Subscribe(sb Subscriber) error { s.Lock() defer s.Unlock() if err := s.router.Subscribe(sb); err != nil { return err } s.subscribers[sb] = nil return nil } func (s *rpcServer) Register() error { var err error var advt, host, port string // parse address for host, port config := s.Options() // check the advertise address first // if it exists then use it, otherwise // use the address if len(config.Advertise) > 0 { advt = config.Advertise } else { advt = config.Address } if cnt := strings.Count(advt, ":"); cnt >= 1 { // ipv6 address in format [host]:port or ipv4 host:port host, port, err = net.SplitHostPort(advt) if err != nil { return err } } else { host = advt } addr, err := addr.Extract(host) if err != nil { return err } // make copy of metadata md := make(metadata.Metadata) for k, v := range config.Metadata { md[k] = v } // mq-rpc(eg. nats) doesn't need the port. its addr is queue name. if port != "" { addr = mnet.HostPort(addr, port) } // register service node := ®istry.Node{ Id: config.Name + "-" + config.Id, Address: addr, Metadata: md, } node.Metadata["transport"] = config.Transport.String() node.Metadata["broker"] = config.Broker.String() node.Metadata["server"] = s.String() node.Metadata["registry"] = config.Registry.String() node.Metadata["protocol"] = "mucp" s.RLock() // Maps are ordered randomly, sort the keys for consistency var handlerList []string for n, e := range s.handlers { // Only advertise non internal handlers if !e.Options().Internal { handlerList = append(handlerList, n) } } sort.Strings(handlerList) var subscriberList []Subscriber for e := range s.subscribers { // Only advertise non internal subscribers if !e.Options().Internal { subscriberList = append(subscriberList, e) } } sort.Slice(subscriberList, func(i, j int) bool { return subscriberList[i].Topic() > subscriberList[j].Topic() }) endpoints := make([]*registry.Endpoint, 0, len(handlerList)+len(subscriberList)) for _, n := range handlerList { endpoints = append(endpoints, s.handlers[n].Endpoints()...) } for _, e := range subscriberList { endpoints = append(endpoints, e.Endpoints()...) } service := ®istry.Service{ Name: config.Name, Version: config.Version, Nodes: []*registry.Node{node}, Endpoints: endpoints, } // get registered value registered := s.registered s.RUnlock() if !registered { log.Logf("Registry [%s] Registering node: %s", config.Registry.String(), node.Id) } // create registry options rOpts := []registry.RegisterOption{registry.RegisterTTL(config.RegisterTTL)} if err := config.Registry.Register(service, rOpts...); err != nil { return err } // already registered? don't need to register subscribers if registered { return nil } s.Lock() defer s.Unlock() s.registered = true // set what we're advertising s.opts.Advertise = addr // subscribe to the topic with own name sub, err := s.opts.Broker.Subscribe(config.Name, s.HandleEvent) if err != nil { return err } // save the subscriber s.subscriber = sub // subscribe for all of the subscribers for sb := range s.subscribers { var opts []broker.SubscribeOption if queue := sb.Options().Queue; len(queue) > 0 { opts = append(opts, broker.Queue(queue)) } if cx := sb.Options().Context; cx != nil { opts = append(opts, broker.SubscribeContext(cx)) } if !sb.Options().AutoAck { opts = append(opts, broker.DisableAutoAck()) } sub, err := config.Broker.Subscribe(sb.Topic(), s.HandleEvent, opts...) if err != nil { return err } log.Logf("Subscribing %s to topic: %s", node.Id, sub.Topic()) s.subscribers[sb] = []broker.Subscriber{sub} } return nil } func (s *rpcServer) Deregister() error { var err error var advt, host, port string config := s.Options() // check the advertise address first // if it exists then use it, otherwise // use the address if len(config.Advertise) > 0 { advt = config.Advertise } else { advt = config.Address } if cnt := strings.Count(advt, ":"); cnt >= 1 { // ipv6 address in format [host]:port or ipv4 host:port host, port, err = net.SplitHostPort(advt) if err != nil { return err } } else { host = advt } addr, err := addr.Extract(host) if err != nil { return err } // mq-rpc(eg. nats) doesn't need the port. its addr is queue name. if port != "" { addr = mnet.HostPort(addr, port) } node := ®istry.Node{ Id: config.Name + "-" + config.Id, Address: addr, } service := ®istry.Service{ Name: config.Name, Version: config.Version, Nodes: []*registry.Node{node}, } log.Logf("Registry [%s] Deregistering node: %s", config.Registry.String(), node.Id) if err := config.Registry.Deregister(service); err != nil { return err } s.Lock() if !s.registered { s.Unlock() return nil } s.registered = false // close the subscriber if s.subscriber != nil { s.subscriber.Unsubscribe() s.subscriber = nil } for sb, subs := range s.subscribers { for _, sub := range subs { log.Logf("Unsubscribing %s from topic: %s", node.Id, sub.Topic()) sub.Unsubscribe() } s.subscribers[sb] = nil } s.Unlock() return nil } func (s *rpcServer) Start() error { s.RLock() if s.started { s.RUnlock() return nil } s.RUnlock() config := s.Options() // start listening on the transport ts, err := config.Transport.Listen(config.Address) if err != nil { return err } log.Logf("Transport [%s] Listening on %s", config.Transport.String(), ts.Addr()) // swap address s.Lock() addr := s.opts.Address s.opts.Address = ts.Addr() s.Unlock() // connect to the broker if err := config.Broker.Connect(); err != nil { return err } bname := config.Broker.String() log.Logf("Broker [%s] Connected to %s", bname, config.Broker.Address()) // use RegisterCheck func before register if err = s.opts.RegisterCheck(s.opts.Context); err != nil { log.Logf("Server %s-%s register check error: %s", config.Name, config.Id, err) } else { // announce self to the world if err = s.Register(); err != nil { log.Logf("Server %s-%s register error: %s", config.Name, config.Id, err) } } exit := make(chan bool) go func() { for { // listen for connections err := ts.Accept(s.ServeConn) // TODO: listen for messages // msg := broker.Exchange(service).Consume() select { // check if we're supposed to exit case <-exit: return // check the error and backoff default: if err != nil { log.Logf("Accept error: %v", err) time.Sleep(time.Second) continue } } // no error just exit return } }() go func() { t := new(time.Ticker) // only process if it exists if s.opts.RegisterInterval > time.Duration(0) { // new ticker t = time.NewTicker(s.opts.RegisterInterval) } // return error chan var ch chan error Loop: for { select { // register self on interval case <-t.C: s.RLock() registered := s.registered s.RUnlock() rerr := s.opts.RegisterCheck(s.opts.Context) if rerr != nil && registered { log.Logf("Server %s-%s register check error: %s, deregister it", config.Name, config.Id, err) // deregister self in case of error if err := s.Deregister(); err != nil { log.Logf("Server %s-%s deregister error: %s", config.Name, config.Id, err) } } else if rerr != nil && !registered { log.Logf("Server %s-%s register check error: %s", config.Name, config.Id, err) continue } if err := s.Register(); err != nil { log.Logf("Server %s-%s register error: %s", config.Name, config.Id, err) } // wait for exit case ch = <-s.exit: t.Stop() close(exit) break Loop } } s.RLock() registered := s.registered s.RUnlock() if registered { // deregister self if err := s.Deregister(); err != nil { log.Logf("Server %s-%s deregister error: %s", config.Name, config.Id, err) } } s.Lock() swg := s.wg s.Unlock() // wait for requests to finish if swg != nil { swg.Wait() } // close transport listener ch <- ts.Close() // disconnect the broker config.Broker.Disconnect() // swap back address s.Lock() s.opts.Address = addr s.Unlock() }() // mark the server as started s.Lock() s.started = true s.Unlock() return nil } func (s *rpcServer) Stop() error { s.RLock() if !s.started { s.RUnlock() return nil } s.RUnlock() ch := make(chan error) s.exit <- ch err := <-ch s.Lock() s.started = false s.Unlock() return err } func (s *rpcServer) String() string { return "mucp" }