package network import ( "bytes" "errors" "fmt" "io" "net" "github.com/CityOfZion/neo-go/pkg/network/payload" "github.com/CityOfZion/neo-go/pkg/util" ) func listenTCP(s *Server, port int) error { ln, err := net.Listen("tcp", fmt.Sprintf(":%d", port)) if err != nil { return err } s.listener = ln for { conn, err := ln.Accept() if err != nil { return err } go handleConnection(s, conn) } } func connectToRemoteNode(s *Server, address string) { conn, err := net.Dial("tcp", address) if err != nil { s.logger.Printf("failed to connect to remote node %s", address) if conn != nil { conn.Close() } return } go handleConnection(s, conn) } func connectToSeeds(s *Server, addrs []string) { for _, addr := range addrs { go connectToRemoteNode(s, addr) } } func handleConnection(s *Server, conn net.Conn) { peer := NewTCPPeer(conn, s) s.register <- peer // remove the peer from connected peers and cleanup the connection. defer func() { peer.disconnect() }() // Start a goroutine that will handle all outgoing messages. go peer.writeLoop() // Start a goroutine that will handle all incomming messages. go handleMessage(s, peer) // Read from the connection and decode it into a Message ready for processing. buf := make([]byte, 1024) for { _, err := conn.Read(buf) if err == io.EOF { return } if err != nil { s.logger.Printf("conn read error: %s", err) return } msg := &Message{} if err := msg.decode(bytes.NewReader(buf)); err != nil { s.logger.Printf("decode error %s", err) return } peer.receive <- msg } } // handleMessage hands the message received from a TCP connection over to the server. func handleMessage(s *Server, p *TCPPeer) { var err error // Disconnect the peer when we break out of the loop. defer func() { p.disconnect() }() for { msg := <-p.receive command := msg.commandType() s.logger.Printf("IN :: %d :: %s :: %v", p.id(), command, msg) switch command { case cmdVersion: if err = s.handleVersionCmd(msg, p); err != nil { return } p.nonce = msg.Payload.(*payload.Version).Nonce // When a node receives a connection request, it declares its version immediately. // There will be no other communication until both sides are getting versions of each other. // When a node receives the version message, it replies to a verack as a response immediately. // NOTE: The current official NEO nodes dont mimic this behaviour. There is small chance that the // official nodes will not respond directly with a verack after we sended our version. // is this a bug? - anthdm 02/02/2018 msgVerack := <-p.receive if msgVerack.commandType() != cmdVerack { s.logger.Printf("expected verack after sended out version") return } // start the protocol go s.sendLoop(p) case cmdAddr: err = s.handleAddrCmd(msg, p) case cmdGetAddr: err = s.handleGetaddrCmd(msg, p) case cmdInv: err = s.handleInvCmd(msg, p) case cmdBlock: err = s.handleBlockCmd(msg, p) case cmdConsensus: case cmdTX: case cmdVerack: // If we receive a verack here we disconnect. We already handled the verack // when we sended our version. err = errors.New("received verack twice") case cmdGetHeaders: case cmdGetBlocks: case cmdGetData: case cmdHeaders: } // catch all errors here and disconnect. if err != nil { s.logger.Printf("processing message failed: %s", err) return } } } type sendTuple struct { msg *Message err chan error } // TCPPeer represents a remote node, backed by TCP transport. type TCPPeer struct { s *Server // nonce (id) of the peer. nonce uint32 // underlying TCP connection conn net.Conn // host and port information about this peer. endpoint util.Endpoint // channel to coordinate messages writen back to the connection. send chan sendTuple // channel to receive from underlying connection. receive chan *Message } // NewTCPPeer returns a pointer to a TCP Peer. func NewTCPPeer(conn net.Conn, s *Server) *TCPPeer { e, _ := util.EndpointFromString(conn.RemoteAddr().String()) return &TCPPeer{ conn: conn, send: make(chan sendTuple), receive: make(chan *Message), endpoint: e, s: s, } } func (p *TCPPeer) callVersion(msg *Message) error { t := sendTuple{ msg: msg, err: make(chan error), } p.send <- t return <-t.err } // id implements the peer interface func (p *TCPPeer) id() uint32 { return p.nonce } // endpoint implements the peer interface func (p *TCPPeer) addr() util.Endpoint { return p.endpoint } // callGetaddr will send the "getaddr" command to the remote. func (p *TCPPeer) callGetaddr(msg *Message) error { t := sendTuple{ msg: msg, err: make(chan error), } p.send <- t return <-t.err } func (p *TCPPeer) callVerack(msg *Message) error { t := sendTuple{ msg: msg, err: make(chan error), } p.send <- t return <-t.err } func (p *TCPPeer) callGetdata(msg *Message) error { t := sendTuple{ msg: msg, err: make(chan error), } p.send <- t return <-t.err } // disconnect disconnects the peer, cleaning up all its resources. // 3 goroutines needs to be cleanup (writeLoop, handleConnection and handleMessage) func (p *TCPPeer) disconnect() { select { case <-p.send: case <-p.receive: default: close(p.send) close(p.receive) p.s.unregister <- p p.conn.Close() } } // writeLoop writes messages to the underlying TCP connection. // A goroutine writeLoop is started for each connection. // There should be at most one writer to a connection executing // all writes from this goroutine. func (p *TCPPeer) writeLoop() { // clean up the connection. defer func() { p.disconnect() }() for { t := <-p.send if t.msg == nil { return } p.s.logger.Printf("OUT :: %s :: %+v", t.msg.commandType(), t.msg.Payload) t.err <- t.msg.encode(p.conn) } }