package p2p import ( "fmt" "net" "sync/atomic" "time" cmn "github.com/tendermint/tendermint/libs/common" "github.com/tendermint/tendermint/libs/log" "github.com/tendermint/tendermint/config" tmconn "github.com/tendermint/tendermint/p2p/conn" ) var testIPSuffix uint32 // Peer is an interface representing a peer connected on a reactor. type Peer interface { cmn.Service ID() ID // peer's cryptographic ID RemoteIP() net.IP // remote IP of the connection IsOutbound() bool // did we dial the peer IsPersistent() bool // do we redial this peer when we disconnect NodeInfo() NodeInfo // peer's info Status() tmconn.ConnectionStatus OriginalAddr() *NetAddress Send(byte, []byte) bool TrySend(byte, []byte) bool Set(string, interface{}) Get(string) interface{} } //---------------------------------------------------------- // peerConn contains the raw connection and its config. type peerConn struct { outbound bool persistent bool config *config.P2PConfig conn net.Conn // source connection ip net.IP originalAddr *NetAddress // nil for inbound connections } // ID only exists for SecretConnection. // NOTE: Will panic if conn is not *SecretConnection. func (pc peerConn) ID() ID { return PubKeyToID(pc.conn.(*tmconn.SecretConnection).RemotePubKey()) } // Return the IP from the connection RemoteAddr func (pc peerConn) RemoteIP() net.IP { if pc.ip != nil { return pc.ip } // In test cases a conn could not be present at all or be an in-memory // implementation where we want to return a fake ip. if pc.conn == nil || pc.conn.RemoteAddr().String() == "pipe" { pc.ip = net.IP{172, 16, 0, byte(atomic.AddUint32(&testIPSuffix, 1))} return pc.ip } host, _, err := net.SplitHostPort(pc.conn.RemoteAddr().String()) if err != nil { panic(err) } ips, err := net.LookupIP(host) if err != nil { panic(err) } pc.ip = ips[0] return pc.ip } // peer implements Peer. // // Before using a peer, you will need to perform a handshake on connection. type peer struct { cmn.BaseService // raw peerConn and the multiplex connection peerConn mconn *tmconn.MConnection // peer's node info and the channel it knows about // channels = nodeInfo.Channels // cached to avoid copying nodeInfo in hasChannel nodeInfo NodeInfo channels []byte // User data Data *cmn.CMap } func newPeer( pc peerConn, mConfig tmconn.MConnConfig, nodeInfo NodeInfo, reactorsByCh map[byte]Reactor, chDescs []*tmconn.ChannelDescriptor, onPeerError func(Peer, interface{}), ) *peer { p := &peer{ peerConn: pc, nodeInfo: nodeInfo, channels: nodeInfo.Channels, Data: cmn.NewCMap(), } p.mconn = createMConnection( pc.conn, p, reactorsByCh, chDescs, onPeerError, mConfig, ) p.BaseService = *cmn.NewBaseService(nil, "Peer", p) return p } //--------------------------------------------------- // Implements cmn.Service // SetLogger implements BaseService. func (p *peer) SetLogger(l log.Logger) { p.Logger = l p.mconn.SetLogger(l) } // OnStart implements BaseService. func (p *peer) OnStart() error { if err := p.BaseService.OnStart(); err != nil { return err } err := p.mconn.Start() return err } // OnStop implements BaseService. func (p *peer) OnStop() { p.BaseService.OnStop() p.mconn.Stop() // stop everything and close the conn } //--------------------------------------------------- // Implements Peer // ID returns the peer's ID - the hex encoded hash of its pubkey. func (p *peer) ID() ID { return p.nodeInfo.ID } // IsOutbound returns true if the connection is outbound, false otherwise. func (p *peer) IsOutbound() bool { return p.peerConn.outbound } // IsPersistent returns true if the peer is persitent, false otherwise. func (p *peer) IsPersistent() bool { return p.peerConn.persistent } // NodeInfo returns a copy of the peer's NodeInfo. func (p *peer) NodeInfo() NodeInfo { return p.nodeInfo } // OriginalAddr returns the original address, which was used to connect with // the peer. Returns nil for inbound peers. func (p *peer) OriginalAddr() *NetAddress { if p.peerConn.outbound { return p.peerConn.originalAddr } return nil } // Status returns the peer's ConnectionStatus. func (p *peer) Status() tmconn.ConnectionStatus { return p.mconn.Status() } // Send msg bytes to the channel identified by chID byte. Returns false if the // send queue is full after timeout, specified by MConnection. func (p *peer) Send(chID byte, msgBytes []byte) bool { if !p.IsRunning() { // see Switch#Broadcast, where we fetch the list of peers and loop over // them - while we're looping, one peer may be removed and stopped. return false } else if !p.hasChannel(chID) { return false } return p.mconn.Send(chID, msgBytes) } // TrySend msg bytes to the channel identified by chID byte. Immediately returns // false if the send queue is full. func (p *peer) TrySend(chID byte, msgBytes []byte) bool { if !p.IsRunning() { return false } else if !p.hasChannel(chID) { return false } return p.mconn.TrySend(chID, msgBytes) } // Get the data for a given key. func (p *peer) Get(key string) interface{} { return p.Data.Get(key) } // Set sets the data for the given key. func (p *peer) Set(key string, data interface{}) { p.Data.Set(key, data) } // hasChannel returns true if the peer reported // knowing about the given chID. func (p *peer) hasChannel(chID byte) bool { for _, ch := range p.channels { if ch == chID { return true } } // NOTE: probably will want to remove this // but could be helpful while the feature is new p.Logger.Debug( "Unknown channel for peer", "channel", chID, "channels", p.channels, ) return false } //--------------------------------------------------- // methods used by the Switch // CloseConn should be called by the Switch if the peer was created but never // started. func (pc *peerConn) CloseConn() { pc.conn.Close() // nolint: errcheck } // HandshakeTimeout performs the Tendermint P2P handshake between a given node // and the peer by exchanging their NodeInfo. It sets the received nodeInfo on // the peer. // NOTE: blocking func (pc *peerConn) HandshakeTimeout( ourNodeInfo NodeInfo, timeout time.Duration, ) (peerNodeInfo NodeInfo, err error) { // Set deadline for handshake so we don't block forever on conn.ReadFull if err := pc.conn.SetDeadline(time.Now().Add(timeout)); err != nil { return peerNodeInfo, cmn.ErrorWrap(err, "Error setting deadline") } var trs, _ = cmn.Parallel( func(_ int) (val interface{}, err error, abort bool) { _, err = cdc.MarshalBinaryWriter(pc.conn, ourNodeInfo) return }, func(_ int) (val interface{}, err error, abort bool) { _, err = cdc.UnmarshalBinaryReader( pc.conn, &peerNodeInfo, int64(MaxNodeInfoSize()), ) return }, ) if err := trs.FirstError(); err != nil { return peerNodeInfo, cmn.ErrorWrap(err, "Error during handshake") } // Remove deadline if err := pc.conn.SetDeadline(time.Time{}); err != nil { return peerNodeInfo, cmn.ErrorWrap(err, "Error removing deadline") } return peerNodeInfo, nil } // Addr returns peer's remote network address. func (p *peer) Addr() net.Addr { return p.peerConn.conn.RemoteAddr() } // CanSend returns true if the send queue is not full, false otherwise. func (p *peer) CanSend(chID byte) bool { if !p.IsRunning() { return false } return p.mconn.CanSend(chID) } // String representation. func (p *peer) String() string { if p.outbound { return fmt.Sprintf("Peer{%v %v out}", p.mconn, p.ID()) } return fmt.Sprintf("Peer{%v %v in}", p.mconn, p.ID()) } //------------------------------------------------------------------ // helper funcs func createMConnection( conn net.Conn, p *peer, reactorsByCh map[byte]Reactor, chDescs []*tmconn.ChannelDescriptor, onPeerError func(Peer, interface{}), config tmconn.MConnConfig, ) *tmconn.MConnection { onReceive := func(chID byte, msgBytes []byte) { reactor := reactorsByCh[chID] if reactor == nil { // Note that its ok to panic here as it's caught in the conn._recover, // which does onPeerError. panic(fmt.Sprintf("Unknown channel %X", chID)) } reactor.Receive(chID, p, msgBytes) } onError := func(r interface{}) { onPeerError(p, r) } return tmconn.NewMConnectionWithConfig( conn, chDescs, onReceive, onError, config, ) }