package network import ( "sync" "time" "github.com/golang/protobuf/proto" "github.com/micro/go-micro/client" rtr "github.com/micro/go-micro/client/selector/router" "github.com/micro/go-micro/proxy" "github.com/micro/go-micro/router" pb "github.com/micro/go-micro/router/proto" "github.com/micro/go-micro/server" "github.com/micro/go-micro/transport" "github.com/micro/go-micro/tunnel" trn "github.com/micro/go-micro/tunnel/transport" "github.com/micro/go-micro/util/log" ) var ( // ControlChannel is the name of the tunnel channel for passing contron message ControlChannel = "control" // DefaultLink is default network link DefaultLink = "network" ) // network implements Network interface type network struct { // options configure the network options Options // rtr is network router router.Router // prx is network proxy proxy.Proxy // tun is network tunnel tunnel.Tunnel // server is network server server server.Server // client is network client client client.Client sync.RWMutex // connected marks the network as connected connected bool // closed closes the network closed chan bool } // newNetwork returns a new network node func newNetwork(opts ...Option) Network { options := DefaultOptions() for _, o := range opts { o(&options) } // init tunnel address to the network bind address options.Tunnel.Init( tunnel.Address(options.Address), ) // init router Id to the network id options.Router.Init( router.Id(options.Id), ) // create tunnel client with tunnel transport tunTransport := trn.NewTransport( trn.WithTunnel(options.Tunnel), ) // server is network server server := server.NewServer( server.Id(options.Id), server.Address(options.Address), server.Name(options.Name), server.Transport(tunTransport), ) // client is network client client := client.NewClient( client.Transport(tunTransport), client.Selector( rtr.NewSelector( rtr.WithRouter(options.Router), ), ), ) return &network{ options: options, Router: options.Router, Proxy: options.Proxy, Tunnel: options.Tunnel, server: server, client: client, } } // Name returns network name func (n *network) Name() string { return n.options.Name } // Address returns network bind address func (n *network) Address() string { return n.Tunnel.Address() } func (n *network) resolveNodes() ([]string, error) { // resolve the network address to network nodes records, err := n.options.Resolver.Resolve(n.options.Name) if err != nil { return nil, err } // collect network node addresses nodes := make([]string, len(records)) for i, record := range records { nodes[i] = record.Address } return nodes, nil } func (n *network) resolve() { resolve := time.NewTicker(ResolveTime) defer resolve.Stop() for { select { case <-n.closed: return case <-resolve.C: nodes, err := n.resolveNodes() if err != nil { log.Debugf("Network failed to resolve nodes: %v", err) continue } // initialize the tunnel n.Tunnel.Init( tunnel.Nodes(nodes...), ) } } } func (n *network) handleConn(conn tunnel.Conn, msg chan *transport.Message) { for { m := new(transport.Message) if err := conn.Recv(m); err != nil { // TODO: should we bail here? log.Debugf("Network tunnel advert receive error: %v", err) return } select { case msg <- m: case <-n.closed: return } } } func (n *network) process(l tunnel.Listener) { // receive control message queue recv := make(chan *transport.Message, 128) // accept a connection conn, err := l.Accept() if err != nil { // TODO: handle this log.Debugf("Network tunnel accept error: %v", err) return } go n.handleConn(conn, recv) for { select { case m := <-recv: // switch on type of message and take action switch m.Header["Micro-Method"] { case "advert": pbAdvert := &pb.Advert{} if err := proto.Unmarshal(m.Body, pbAdvert); err != nil { continue } var events []*router.Event for _, event := range pbAdvert.Events { route := router.Route{ Service: event.Route.Service, Address: event.Route.Address, Gateway: event.Route.Gateway, Network: event.Route.Network, Link: event.Route.Link, Metric: int(event.Route.Metric), } e := &router.Event{ Type: router.EventType(event.Type), Timestamp: time.Unix(0, pbAdvert.Timestamp), Route: route, } events = append(events, e) } advert := &router.Advert{ Id: pbAdvert.Id, Type: router.AdvertType(pbAdvert.Type), Timestamp: time.Unix(0, pbAdvert.Timestamp), TTL: time.Duration(pbAdvert.Ttl), Events: events, } if err := n.Router.Process(advert); err != nil { log.Debugf("Network failed to process advert %s: %v", advert.Id, err) continue } } case <-n.closed: return } } } // advertise advertises routes to the network func (n *network) advertise(client transport.Client, advertChan <-chan *router.Advert) { for { select { // process local adverts and randomly fire them at other nodes case advert := <-advertChan: // create a proto advert var events []*pb.Event for _, event := range advert.Events { // NOTE: we override the Gateway and Link fields here route := &pb.Route{ Service: event.Route.Service, Address: event.Route.Address, Gateway: n.options.Address, Network: event.Route.Network, Link: DefaultLink, Metric: int64(event.Route.Metric), } e := &pb.Event{ Type: pb.EventType(event.Type), Timestamp: event.Timestamp.UnixNano(), Route: route, } events = append(events, e) } pbAdvert := &pb.Advert{ Id: advert.Id, Type: pb.AdvertType(advert.Type), Timestamp: advert.Timestamp.UnixNano(), Events: events, } body, err := proto.Marshal(pbAdvert) if err != nil { // TODO: should we bail here? log.Debugf("Network failed to marshal message: %v", err) continue } // create transport message and chuck it down the pipe m := transport.Message{ Header: map[string]string{ "Micro-Method": "advert", }, Body: body, } if err := client.Send(&m); err != nil { log.Debugf("Network failed to send advert %s: %v", pbAdvert.Id, err) continue } case <-n.closed: return } } } // Connect connects the network func (n *network) Connect() error { n.Lock() defer n.Unlock() // return if already connected if n.connected { return nil } // try to resolve network nodes nodes, err := n.resolveNodes() if err != nil { log.Debugf("Network failed to resolve nodes: %v", err) } // connect network tunnel if err := n.Tunnel.Connect(); err != nil { return err } // initialize the tunnel to resolved nodes n.Tunnel.Init( tunnel.Nodes(nodes...), ) // dial into ControlChannel to send route adverts client, err := n.Tunnel.Dial(ControlChannel) if err != nil { return err } // listen on ControlChannel listener, err := n.Tunnel.Listen(ControlChannel) if err != nil { return err } // create closed channel n.closed = make(chan bool) // keep resolving network nodes go n.resolve() // start the router if err := n.options.Router.Start(); err != nil { return err } // start advertising routes advertChan, err := n.options.Router.Advertise() if err != nil { return err } // advertise routes go n.advertise(client, advertChan) // accept and process routes go n.process(listener) // start the server if err := n.server.Start(); err != nil { return err } // set connected to true n.connected = true return nil } func (n *network) close() error { // stop the server if err := n.server.Stop(); err != nil { return err } // stop the router if err := n.Router.Stop(); err != nil { return err } // close the tunnel if err := n.Tunnel.Close(); err != nil { return err } return nil } // Close closes network connection func (n *network) Close() error { n.Lock() defer n.Unlock() if !n.connected { return nil } select { case <-n.closed: return nil default: close(n.closed) // set connected to false n.connected = false } return n.close() } // Client returns network client func (n *network) Client() client.Client { return n.client } // Server returns network server func (n *network) Server() server.Server { return n.server }