zolfa
/
tendermint


								package p2p


								import (

									"fmt"

									"io"

									"net"

									"time"


									"github.com/pkg/errors"


									crypto "github.com/tendermint/go-crypto"

									wire "github.com/tendermint/go-wire"

									cmn "github.com/tendermint/tmlibs/common"

									"github.com/tendermint/tmlibs/log"

								)


								// Peer is an interface representing a peer connected on a reactor.

								type Peer interface {

									cmn.Service


									Key() string

									IsOutbound() bool

									IsPersistent() bool

									NodeInfo() *NodeInfo

									Status() ConnectionStatus


									Send(byte, interface{}) bool

									TrySend(byte, interface{}) bool


									Set(string, interface{})

									Get(string) interface{}

								}


								// Peer could be marked as persistent, in which case you can use

								// Redial function to reconnect. Note that inbound peers can't be

								// made persistent. They should be made persistent on the other end.

								//

								// Before using a peer, you will need to perform a handshake on connection.

								type peer struct {

									cmn.BaseService


									outbound bool


									conn  net.Conn     // source connection

									mconn *MConnection // multiplex connection


									persistent bool

									config     *PeerConfig


									nodeInfo *NodeInfo

									key      string

									Data     *cmn.CMap // User data.

								}


								// PeerConfig is a Peer configuration.

								type PeerConfig struct {

									AuthEnc bool `mapstructure:"auth_enc"` // authenticated encryption


									// times are in seconds

									HandshakeTimeout time.Duration `mapstructure:"handshake_timeout"`

									DialTimeout      time.Duration `mapstructure:"dial_timeout"`


									MConfig *MConnConfig `mapstructure:"connection"`


									Fuzz       bool            `mapstructure:"fuzz"` // fuzz connection (for testing)

									FuzzConfig *FuzzConnConfig `mapstructure:"fuzz_config"`

								}


								// DefaultPeerConfig returns the default config.

								func DefaultPeerConfig() *PeerConfig {

									return &PeerConfig{

										AuthEnc:          true,

										HandshakeTimeout: 20, // * time.Second,

										DialTimeout:      3,  // * time.Second,

										MConfig:          DefaultMConnConfig(),

										Fuzz:             false,

										FuzzConfig:       DefaultFuzzConnConfig(),

									}

								}


								func newOutboundPeer(addr *NetAddress, reactorsByCh map[byte]Reactor, chDescs []*ChannelDescriptor,

									onPeerError func(Peer, interface{}), ourNodePrivKey crypto.PrivKeyEd25519, config *PeerConfig) (*peer, error) {


									conn, err := dial(addr, config)

									if err != nil {

										return nil, errors.Wrap(err, "Error creating peer")

									}


									peer, err := newPeerFromConnAndConfig(conn, true, reactorsByCh, chDescs, onPeerError, ourNodePrivKey, config)

									if err != nil {

										conn.Close()

										return nil, err

									}

									return peer, nil

								}


								func newInboundPeer(conn net.Conn, reactorsByCh map[byte]Reactor, chDescs []*ChannelDescriptor,

									onPeerError func(Peer, interface{}), ourNodePrivKey crypto.PrivKeyEd25519, config *PeerConfig) (*peer, error) {


									return newPeerFromConnAndConfig(conn, false, reactorsByCh, chDescs, onPeerError, ourNodePrivKey, config)

								}


								func newPeerFromConnAndConfig(rawConn net.Conn, outbound bool, reactorsByCh map[byte]Reactor, chDescs []*ChannelDescriptor,

									onPeerError func(Peer, interface{}), ourNodePrivKey crypto.PrivKeyEd25519, config *PeerConfig) (*peer, error) {


									conn := rawConn


									// Fuzz connection

									if config.Fuzz {

										// so we have time to do peer handshakes and get set up

										conn = FuzzConnAfterFromConfig(conn, 10*time.Second, config.FuzzConfig)

									}


									// Encrypt connection

									if config.AuthEnc {

										conn.SetDeadline(time.Now().Add(config.HandshakeTimeout * time.Second))


										var err error

										conn, err = MakeSecretConnection(conn, ourNodePrivKey)

										if err != nil {

											return nil, errors.Wrap(err, "Error creating peer")

										}

									}


									// Key and NodeInfo are set after Handshake

									p := &peer{

										outbound: outbound,

										conn:     conn,

										config:   config,

										Data:     cmn.NewCMap(),

									}


									p.mconn = createMConnection(conn, p, reactorsByCh, chDescs, onPeerError, config.MConfig)


									p.BaseService = *cmn.NewBaseService(nil, "Peer", p)


									return p, nil

								}


								func (p *peer) SetLogger(l log.Logger) {

									p.Logger = l

									p.mconn.SetLogger(l)

								}


								// CloseConn should be used when the peer was created, but never started.

								func (p *peer) CloseConn() {

									p.conn.Close()

								}


								// makePersistent marks the peer as persistent.

								func (p *peer) makePersistent() {

									if !p.outbound {

										panic("inbound peers can't be made persistent")

									}


									p.persistent = true

								}


								// IsPersistent returns true if the peer is persitent, false otherwise.

								func (p *peer) IsPersistent() bool {

									return p.persistent

								}


								// HandshakeTimeout performs a handshake between a given node and the peer.

								// NOTE: blocking

								func (p *peer) HandshakeTimeout(ourNodeInfo *NodeInfo, timeout time.Duration) error {

									// Set deadline for handshake so we don't block forever on conn.ReadFull

									p.conn.SetDeadline(time.Now().Add(timeout))


									var peerNodeInfo = new(NodeInfo)

									var err1 error

									var err2 error

									cmn.Parallel(

										func() {

											var n int

											wire.WriteBinary(ourNodeInfo, p.conn, &n, &err1)

										},

										func() {

											var n int

											wire.ReadBinary(peerNodeInfo, p.conn, maxNodeInfoSize, &n, &err2)

											p.Logger.Info("Peer handshake", "peerNodeInfo", peerNodeInfo)

										})

									if err1 != nil {

										return errors.Wrap(err1, "Error during handshake/write")

									}

									if err2 != nil {

										return errors.Wrap(err2, "Error during handshake/read")

									}


									if p.config.AuthEnc {

										// Check that the professed PubKey matches the sconn's.

										if !peerNodeInfo.PubKey.Equals(p.PubKey().Wrap()) {

											return fmt.Errorf("Ignoring connection with unmatching pubkey: %v vs %v",

												peerNodeInfo.PubKey, p.PubKey())

										}

									}


									// Remove deadline

									p.conn.SetDeadline(time.Time{})


									peerNodeInfo.RemoteAddr = p.Addr().String()


									p.nodeInfo = peerNodeInfo

									p.key = peerNodeInfo.PubKey.KeyString()


									return nil

								}


								// Addr returns peer's remote network address.

								func (p *peer) Addr() net.Addr {

									return p.conn.RemoteAddr()

								}


								// PubKey returns peer's public key.

								func (p *peer) PubKey() crypto.PubKeyEd25519 {

									if p.config.AuthEnc {

										return p.conn.(*SecretConnection).RemotePubKey()

									}

									if p.NodeInfo() == nil {

										panic("Attempt to get peer's PubKey before calling Handshake")

									}

									return p.PubKey()

								}


								// OnStart implements BaseService.

								func (p *peer) OnStart() error {

									p.BaseService.OnStart()

									_, err := p.mconn.Start()

									return err

								}


								// OnStop implements BaseService.

								func (p *peer) OnStop() {

									p.BaseService.OnStop()

									p.mconn.Stop()

								}


								// Connection returns underlying MConnection.

								func (p *peer) Connection() *MConnection {

									return p.mconn

								}


								// IsOutbound returns true if the connection is outbound, false otherwise.

								func (p *peer) IsOutbound() bool {

									return p.outbound

								}


								// Send msg 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, msg interface{}) 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

									}

									return p.mconn.Send(chID, msg)

								}


								// TrySend msg to the channel identified by chID byte. Immediately returns

								// false if the send queue is full.

								func (p *peer) TrySend(chID byte, msg interface{}) bool {

									if !p.IsRunning() {

										return false

									}

									return p.mconn.TrySend(chID, msg)

								}


								// 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)

								}


								// WriteTo writes the peer's public key to w.

								func (p *peer) WriteTo(w io.Writer) (int64, error) {

									var n int

									var err error

									wire.WriteString(p.key, w, &n, &err)

									return int64(n), err

								}


								// String representation.

								func (p *peer) String() string {

									if p.outbound {

										return fmt.Sprintf("Peer{%v %v out}", p.mconn, p.key[:12])

									}


									return fmt.Sprintf("Peer{%v %v in}", p.mconn, p.key[:12])

								}


								// Equals reports whenever 2 peers are actually represent the same node.

								func (p *peer) Equals(other Peer) bool {

									return p.key == other.Key()

								}


								// 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)

								}


								// Key returns the peer's id key.

								func (p *peer) Key() string {

									return p.key

								}


								// NodeInfo returns a copy of the peer's NodeInfo.

								func (p *peer) NodeInfo() *NodeInfo {

									if p.nodeInfo == nil {

										return nil

									}

									n := *p.nodeInfo // copy

									return &n

								}


								// Status returns the peer's ConnectionStatus.

								func (p *peer) Status() ConnectionStatus {

									return p.mconn.Status()

								}


								func dial(addr *NetAddress, config *PeerConfig) (net.Conn, error) {

									conn, err := addr.DialTimeout(config.DialTimeout * time.Second)

									if err != nil {

										return nil, err

									}

									return conn, nil

								}


								func createMConnection(conn net.Conn, p *peer, reactorsByCh map[byte]Reactor, chDescs []*ChannelDescriptor,

									onPeerError func(Peer, interface{}), config *MConnConfig) *MConnection {


									onReceive := func(chID byte, msgBytes []byte) {

										reactor := reactorsByCh[chID]

										if reactor == nil {

											cmn.PanicSanity(cmn.Fmt("Unknown channel %X", chID))

										}

										reactor.Receive(chID, p, msgBytes)

									}


									onError := func(r interface{}) {

										onPeerError(p, r)

									}


									return NewMConnectionWithConfig(conn, chDescs, onReceive, onError, config)

								}