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package p2p
import (
"errors"
"fmt"
"math/rand"
"net"
"time"
. "github.com/tendermint/go-common"
cfg "github.com/tendermint/go-config"
"github.com/tendermint/go-crypto"
"github.com/tendermint/log15"
)
type Reactor interface {
Service // Start, Stop
SetSwitch(*Switch)
GetChannels() []*ChannelDescriptor
AddPeer(peer *Peer)
RemovePeer(peer *Peer, reason interface{})
Receive(chID byte, peer *Peer, msgBytes []byte)
}
//--------------------------------------
type BaseReactor struct {
QuitService // Provides Start, Stop, .Quit
Switch *Switch
}
func NewBaseReactor(log log15.Logger, name string, impl Reactor) *BaseReactor {
return &BaseReactor{
QuitService: *NewQuitService(log, name, impl),
Switch: nil,
}
}
func (br *BaseReactor) SetSwitch(sw *Switch) {
br.Switch = sw
}
func (_ *BaseReactor) GetChannels() []*ChannelDescriptor { return nil }
func (_ *BaseReactor) AddPeer(peer *Peer) {}
func (_ *BaseReactor) RemovePeer(peer *Peer, reason interface{}) {}
func (_ *BaseReactor) Receive(chID byte, peer *Peer, msgBytes []byte) {}
//-----------------------------------------------------------------------------
/*
The `Switch` handles peer connections and exposes an API to receive incoming messages
on `Reactors`. Each `Reactor` is responsible for handling incoming messages of one
or more `Channels`. So while sending outgoing messages is typically performed on the peer,
incoming messages are received on the reactor.
*/
type Switch struct {
BaseService
config cfg.Config
listeners []Listener
reactors map[string]Reactor
chDescs []*ChannelDescriptor
reactorsByCh map[byte]Reactor
peers *PeerSet
dialing *CMap
nodeInfo *NodeInfo // our node info
nodePrivKey crypto.PrivKeyEd25519 // our node privkey
}
var (
ErrSwitchDuplicatePeer = errors.New("Duplicate peer")
ErrSwitchMaxPeersPerIPRange = errors.New("IP range has too many peers")
)
func NewSwitch(config cfg.Config) *Switch {
setConfigDefaults(config)
sw := &Switch{
config: config,
reactors: make(map[string]Reactor),
chDescs: make([]*ChannelDescriptor, 0),
reactorsByCh: make(map[byte]Reactor),
peers: NewPeerSet(),
dialing: NewCMap(),
nodeInfo: nil,
}
sw.BaseService = *NewBaseService(log, "P2P Switch", sw)
return sw
}
// Not goroutine safe.
func (sw *Switch) AddReactor(name string, reactor Reactor) Reactor {
// Validate the reactor.
// No two reactors can share the same channel.
reactorChannels := reactor.GetChannels()
for _, chDesc := range reactorChannels {
chID := chDesc.ID
if sw.reactorsByCh[chID] != nil {
PanicSanity(fmt.Sprintf("Channel %X has multiple reactors %v & %v", chID, sw.reactorsByCh[chID], reactor))
}
sw.chDescs = append(sw.chDescs, chDesc)
sw.reactorsByCh[chID] = reactor
}
sw.reactors[name] = reactor
reactor.SetSwitch(sw)
return reactor
}
// Not goroutine safe.
func (sw *Switch) Reactors() map[string]Reactor {
return sw.reactors
}
// Not goroutine safe.
func (sw *Switch) Reactor(name string) Reactor {
return sw.reactors[name]
}
// Not goroutine safe.
func (sw *Switch) AddListener(l Listener) {
sw.listeners = append(sw.listeners, l)
}
// Not goroutine safe.
func (sw *Switch) Listeners() []Listener {
return sw.listeners
}
// Not goroutine safe.
func (sw *Switch) IsListening() bool {
return len(sw.listeners) > 0
}
// Not goroutine safe.
func (sw *Switch) SetNodeInfo(nodeInfo *NodeInfo) {
sw.nodeInfo = nodeInfo
}
// Not goroutine safe.
func (sw *Switch) NodeInfo() *NodeInfo {
return sw.nodeInfo
}
// Not goroutine safe.
// NOTE: Overwrites sw.nodeInfo.PubKey
func (sw *Switch) SetNodePrivKey(nodePrivKey crypto.PrivKeyEd25519) {
sw.nodePrivKey = nodePrivKey
if sw.nodeInfo != nil {
sw.nodeInfo.PubKey = nodePrivKey.PubKey().(crypto.PubKeyEd25519)
}
}
// Switch.Start() starts all the reactors, peers, and listeners.
func (sw *Switch) OnStart() error {
sw.BaseService.OnStart()
// Start reactors
for _, reactor := range sw.reactors {
_, err := reactor.Start()
if err != nil {
return err
}
}
// Start peers
for _, peer := range sw.peers.List() {
sw.startInitPeer(peer)
}
// Start listeners
for _, listener := range sw.listeners {
go sw.listenerRoutine(listener)
}
return nil
}
func (sw *Switch) OnStop() {
sw.BaseService.OnStop()
// Stop listeners
for _, listener := range sw.listeners {
listener.Stop()
}
sw.listeners = nil
// Stop peers
for _, peer := range sw.peers.List() {
peer.Stop()
sw.peers.Remove(peer)
}
// Stop reactors
for _, reactor := range sw.reactors {
reactor.Stop()
}
}
// NOTE: This performs a blocking handshake before the peer is added.
// CONTRACT: Iff error is returned, peer is nil, and conn is immediately closed.
func (sw *Switch) AddPeerWithConnection(conn net.Conn, outbound bool) (*Peer, error) {
// Set deadline for handshake so we don't block forever on conn.ReadFull
conn.SetDeadline(time.Now().Add(
time.Duration(sw.config.GetInt(configKeyHandshakeTimeoutSeconds)) * time.Second))
// First, encrypt the connection.
var sconn net.Conn = conn
if sw.config.GetBool(configKeyAuthEnc) {
var err error
sconn, err = MakeSecretConnection(conn, sw.nodePrivKey)
if err != nil {
conn.Close()
return nil, err
}
}
// Then, perform node handshake
peerNodeInfo, err := peerHandshake(sconn, sw.nodeInfo)
if err != nil {
sconn.Close()
return nil, err
}
if sw.config.GetBool(configKeyAuthEnc) {
// Check that the professed PubKey matches the sconn's.
if !peerNodeInfo.PubKey.Equals(sconn.(*SecretConnection).RemotePubKey()) {
sconn.Close()
return nil, fmt.Errorf("Ignoring connection with unmatching pubkey: %v vs %v",
peerNodeInfo.PubKey, sconn.(*SecretConnection).RemotePubKey())
}
}
// Avoid self
if peerNodeInfo.PubKey.Equals(sw.nodeInfo.PubKey) {
sconn.Close()
return nil, fmt.Errorf("Ignoring connection from self")
}
// Check version, chain id
if err := sw.nodeInfo.CompatibleWith(peerNodeInfo); err != nil {
sconn.Close()
return nil, err
}
peer := newPeer(sw.config, sconn, peerNodeInfo, outbound, sw.reactorsByCh, sw.chDescs, sw.StopPeerForError)
// Add the peer to .peers
// ignore if duplicate or if we already have too many for that IP range
if err := sw.peers.Add(peer); err != nil {
log.Notice("Ignoring peer", "error", err, "peer", peer)
peer.Stop()
return nil, err
}
// remove deadline and start peer
conn.SetDeadline(time.Time{})
if sw.IsRunning() {
sw.startInitPeer(peer)
}
log.Notice("Added peer", "peer", peer)
return peer, nil
}
func (sw *Switch) startInitPeer(peer *Peer) {
peer.Start() // spawn send/recv routines
sw.addPeerToReactors(peer) // run AddPeer on each reactor
}
// Dial a list of seeds in random order
// Spawns a go routine for each dial
func (sw *Switch) DialSeeds(seeds []string) {
// permute the list, dial them in random order.
perm := rand.Perm(len(seeds))
for i := 0; i < len(perm); i++ {
go func(i int) {
time.Sleep(time.Duration(rand.Int63n(3000)) * time.Millisecond)
j := perm[i]
addr := NewNetAddressString(seeds[j])
sw.dialSeed(addr)
}(i)
}
}
func (sw *Switch) dialSeed(addr *NetAddress) {
peer, err := sw.DialPeerWithAddress(addr)
if err != nil {
log.Error("Error dialing seed", "error", err)
return
} else {
log.Notice("Connected to seed", "peer", peer)
}
}
func (sw *Switch) DialPeerWithAddress(addr *NetAddress) (*Peer, error) {
log.Info("Dialing address", "address", addr)
sw.dialing.Set(addr.IP.String(), addr)
conn, err := addr.DialTimeout(time.Duration(
sw.config.GetInt(configKeyDialTimeoutSeconds)) * time.Second)
sw.dialing.Delete(addr.IP.String())
if err != nil {
log.Info("Failed dialing address", "address", addr, "error", err)
return nil, err
}
if sw.config.GetBool(configFuzzEnable) {
conn = FuzzConn(sw.config, conn)
}
peer, err := sw.AddPeerWithConnection(conn, true)
if err != nil {
log.Info("Failed adding peer", "address", addr, "conn", conn, "error", err)
return nil, err
}
log.Notice("Dialed and added peer", "address", addr, "peer", peer)
return peer, nil
}
func (sw *Switch) IsDialing(addr *NetAddress) bool {
return sw.dialing.Has(addr.IP.String())
}
// Broadcast runs a go routine for each attempted send, which will block
// trying to send for defaultSendTimeoutSeconds. Returns a channel
// which receives success values for each attempted send (false if times out)
// NOTE: Broadcast uses goroutines, so order of broadcast may not be preserved.
func (sw *Switch) Broadcast(chID byte, msg interface{}) chan bool {
successChan := make(chan bool, len(sw.peers.List()))
log.Debug("Broadcast", "channel", chID, "msg", msg)
for _, peer := range sw.peers.List() {
go func(peer *Peer) {
success := peer.Send(chID, msg)
successChan <- success
}(peer)
}
return successChan
}
// Returns the count of outbound/inbound and outbound-dialing peers.
func (sw *Switch) NumPeers() (outbound, inbound, dialing int) {
peers := sw.peers.List()
for _, peer := range peers {
if peer.outbound {
outbound++
} else {
inbound++
}
}
dialing = sw.dialing.Size()
return
}
func (sw *Switch) Peers() IPeerSet {
return sw.peers
}
// Disconnect from a peer due to external error.
// TODO: make record depending on reason.
func (sw *Switch) StopPeerForError(peer *Peer, reason interface{}) {
log.Notice("Stopping peer for error", "peer", peer, "error", reason)
sw.peers.Remove(peer)
peer.Stop()
sw.removePeerFromReactors(peer, reason)
}
// Disconnect from a peer gracefully.
// TODO: handle graceful disconnects.
func (sw *Switch) StopPeerGracefully(peer *Peer) {
log.Notice("Stopping peer gracefully")
sw.peers.Remove(peer)
peer.Stop()
sw.removePeerFromReactors(peer, nil)
}
func (sw *Switch) addPeerToReactors(peer *Peer) {
for _, reactor := range sw.reactors {
reactor.AddPeer(peer)
}
}
func (sw *Switch) removePeerFromReactors(peer *Peer, reason interface{}) {
for _, reactor := range sw.reactors {
reactor.RemovePeer(peer, reason)
}
}
func (sw *Switch) listenerRoutine(l Listener) {
for {
inConn, ok := <-l.Connections()
if !ok {
break
}
// ignore connection if we already have enough
maxPeers := sw.config.GetInt(configKeyMaxNumPeers)
if maxPeers <= sw.peers.Size() {
log.Info("Ignoring inbound connection: already have enough peers", "address", inConn.RemoteAddr().String(), "numPeers", sw.peers.Size(), "max", maxPeers)
continue
}
if sw.config.GetBool(configFuzzEnable) {
inConn = FuzzConn(sw.config, inConn)
}
// New inbound connection!
_, err := sw.AddPeerWithConnection(inConn, false)
if err != nil {
log.Notice("Ignoring inbound connection: error on AddPeerWithConnection", "address", inConn.RemoteAddr().String(), "error", err)
continue
}
// NOTE: We don't yet have the listening port of the
// remote (if they have a listener at all).
// The peerHandshake will handle that
}
// cleanup
}
//-----------------------------------------------------------------------------
type SwitchEventNewPeer struct {
Peer *Peer
}
type SwitchEventDonePeer struct {
Peer *Peer
Error interface{}
}
//------------------------------------------------------------------
// Switches connected via arbitrary net.Conn; useful for testing
// Returns n fully connected switches.
// initSwitch defines how the ith switch should be initialized (ie. with what reactors).
func MakeConnectedSwitches(n int, initSwitch func(int, *Switch) *Switch, connPipe func() (net.Conn, net.Conn)) []*Switch {
switches := make([]*Switch, n)
for i := 0; i < n; i++ {
switches[i] = makeSwitch(i, "testing", "123.123.123", initSwitch)
}
for i := 0; i < n; i++ {
switchI := switches[i]
for j := i; j < n; j++ {
switchJ := switches[j]
c1, c2 := connPipe()
go switchI.AddPeerWithConnection(c1, false) // AddPeer is blocking, requires handshake.
go switchJ.AddPeerWithConnection(c2, true)
}
}
// Wait for things to happen, peers to get added...
time.Sleep(100 * time.Millisecond * time.Duration(n*n))
return switches
}
func makeSwitch(i int, network, version string, initSwitch func(int, *Switch) *Switch) *Switch {
privKey := crypto.GenPrivKeyEd25519()
// new switch, add reactors
// TODO: let the config be passed in?
s := initSwitch(i, NewSwitch(cfg.NewMapConfig(nil)))
s.SetNodeInfo(&NodeInfo{
PubKey: privKey.PubKey().(crypto.PubKeyEd25519),
Moniker: Fmt("switch%d", i),
Network: network,
Version: version,
})
s.SetNodePrivKey(privKey)
s.Start() // start switch and reactors
return s
}