zolfa
/
tendermint

package p2p
import (	"fmt"	"math"	"sync"	"time"
	"github.com/tendermint/tendermint/config"	cmn "github.com/tendermint/tendermint/libs/common"	"github.com/tendermint/tendermint/p2p/conn")
const (	// wait a random amount of time from this interval
	// before dialing peers or reconnecting to help prevent DoS
	dialRandomizerIntervalMilliseconds = 3000
	// repeatedly try to reconnect for a few minutes
	// ie. 5 * 20 = 100s
	reconnectAttempts = 20	reconnectInterval = 5 * time.Second
	// then move into exponential backoff mode for ~1day
	// ie. 3**10 = 16hrs
	reconnectBackOffAttempts    = 10	reconnectBackOffBaseSeconds = 3)
//-----------------------------------------------------------------------------

// An AddrBook represents an address book from the pex package, which is used
// to store peer addresses.
type AddrBook interface {	AddAddress(addr *NetAddress, src *NetAddress) error	AddOurAddress(*NetAddress)	OurAddress(*NetAddress) bool	MarkGood(*NetAddress)	RemoveAddress(*NetAddress)	HasAddress(*NetAddress) bool	Save()}
// PeerFilterFunc to be implemented by filter hooks after a new Peer has been
// fully setup.
type PeerFilterFunc func(IPeerSet, Peer) error
//-----------------------------------------------------------------------------

// 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 {	cmn.BaseService
	config       *config.P2PConfig	reactors     map[string]Reactor	chDescs      []*conn.ChannelDescriptor	reactorsByCh map[byte]Reactor	peers        *PeerSet	dialing      *cmn.CMap	reconnecting *cmn.CMap	nodeInfo     NodeInfo // our node info
	nodeKey      *NodeKey // our node privkey
	addrBook     AddrBook
	transport Transport
	filterTimeout time.Duration	peerFilters   []PeerFilterFunc
	mConfig conn.MConnConfig
	rng *cmn.Rand // seed for randomizing dial times and orders

	metrics *Metrics}
// SwitchOption sets an optional parameter on the Switch.
type SwitchOption func(*Switch)
// NewSwitch creates a new Switch with the given config.
func NewSwitch(	cfg *config.P2PConfig,	transport Transport,	options ...SwitchOption,) *Switch {	sw := &Switch{		config:        cfg,		reactors:      make(map[string]Reactor),		chDescs:       make([]*conn.ChannelDescriptor, 0),		reactorsByCh:  make(map[byte]Reactor),		peers:         NewPeerSet(),		dialing:       cmn.NewCMap(),		reconnecting:  cmn.NewCMap(),		metrics:       NopMetrics(),		transport:     transport,		filterTimeout: defaultFilterTimeout,	}
	// Ensure we have a completely undeterministic PRNG.
	sw.rng = cmn.NewRand()
	mConfig := conn.DefaultMConnConfig()	mConfig.FlushThrottle = time.Duration(cfg.FlushThrottleTimeout) * time.Millisecond	mConfig.SendRate = cfg.SendRate	mConfig.RecvRate = cfg.RecvRate	mConfig.MaxPacketMsgPayloadSize = cfg.MaxPacketMsgPayloadSize
	sw.mConfig = mConfig
	sw.BaseService = *cmn.NewBaseService(nil, "P2P Switch", sw)
	for _, option := range options {		option(sw)	}
	return sw}
// SwitchFilterTimeout sets the timeout used for peer filters.
func SwitchFilterTimeout(timeout time.Duration) SwitchOption {	return func(sw *Switch) { sw.filterTimeout = timeout }}
// SwitchPeerFilters sets the filters for rejection of new peers.
func SwitchPeerFilters(filters ...PeerFilterFunc) SwitchOption {	return func(sw *Switch) { sw.peerFilters = filters }}
// WithMetrics sets the metrics.
func WithMetrics(metrics *Metrics) SwitchOption {	return func(sw *Switch) { sw.metrics = metrics }}
//---------------------------------------------------------------------
// Switch setup

// AddReactor adds the given reactor to the switch.
// NOTE: 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 {			cmn.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}
// Reactors returns a map of reactors registered on the switch.
// NOTE: Not goroutine safe.
func (sw *Switch) Reactors() map[string]Reactor {	return sw.reactors}
// Reactor returns the reactor with the given name.
// NOTE: Not goroutine safe.
func (sw *Switch) Reactor(name string) Reactor {	return sw.reactors[name]}
// SetNodeInfo sets the switch's NodeInfo for checking compatibility and handshaking with other nodes.
// NOTE: Not goroutine safe.
func (sw *Switch) SetNodeInfo(nodeInfo NodeInfo) {	sw.nodeInfo = nodeInfo}
// NodeInfo returns the switch's NodeInfo.
// NOTE: Not goroutine safe.
func (sw *Switch) NodeInfo() NodeInfo {	return sw.nodeInfo}
// SetNodeKey sets the switch's private key for authenticated encryption.
// NOTE: Not goroutine safe.
func (sw *Switch) SetNodeKey(nodeKey *NodeKey) {	sw.nodeKey = nodeKey}
//---------------------------------------------------------------------
// Service start/stop

// OnStart implements BaseService. It starts all the reactors and peers.
func (sw *Switch) OnStart() error {	// Start reactors
	for _, reactor := range sw.reactors {		err := reactor.Start()		if err != nil {			return cmn.ErrorWrap(err, "failed to start %v", reactor)		}	}
	// Start accepting Peers.
	go sw.acceptRoutine()
	return nil}
// OnStop implements BaseService. It stops all peers and reactors.
func (sw *Switch) OnStop() {	// Stop peers
	for _, p := range sw.peers.List() {		p.Stop()		sw.peers.Remove(p)	}
	// Stop reactors
	sw.Logger.Debug("Switch: Stopping reactors")	for _, reactor := range sw.reactors {		reactor.Stop()	}}
//---------------------------------------------------------------------
// Peers

// 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). Channel will be
// closed once msg bytes are sent to all peers (or time out).
//
// NOTE: Broadcast uses goroutines, so order of broadcast may not be preserved.
func (sw *Switch) Broadcast(chID byte, msgBytes []byte) chan bool {	successChan := make(chan bool, len(sw.peers.List()))	sw.Logger.Debug("Broadcast", "channel", chID, "msgBytes", fmt.Sprintf("%X", msgBytes))	var wg sync.WaitGroup	for _, peer := range sw.peers.List() {		wg.Add(1)		go func(peer Peer) {			defer wg.Done()			success := peer.Send(chID, msgBytes)			successChan <- success		}(peer)	}	go func() {		wg.Wait()		close(successChan)	}()	return successChan}
// NumPeers 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.IsOutbound() {			outbound++		} else {			inbound++		}	}	dialing = sw.dialing.Size()	return}
// MaxNumOutboundPeers returns a maximum number of outbound peers.
func (sw *Switch) MaxNumOutboundPeers() int {	return sw.config.MaxNumOutboundPeers}
// Peers returns the set of peers that are connected to the switch.
func (sw *Switch) Peers() IPeerSet {	return sw.peers}
// StopPeerForError disconnects from a peer due to external error.
// If the peer is persistent, it will attempt to reconnect.
// TODO: make record depending on reason.
func (sw *Switch) StopPeerForError(peer Peer, reason interface{}) {	sw.Logger.Error("Stopping peer for error", "peer", peer, "err", reason)	sw.stopAndRemovePeer(peer, reason)
	if peer.IsPersistent() {		addr := peer.OriginalAddr()		if addr == nil {			// FIXME: persistent peers can't be inbound right now.
			// self-reported address for inbound persistent peers
			addr = peer.NodeInfo().NetAddress()		}		go sw.reconnectToPeer(addr)	}}
// StopPeerGracefully disconnects from a peer gracefully.
// TODO: handle graceful disconnects.
func (sw *Switch) StopPeerGracefully(peer Peer) {	sw.Logger.Info("Stopping peer gracefully")	sw.stopAndRemovePeer(peer, nil)}
func (sw *Switch) stopAndRemovePeer(peer Peer, reason interface{}) {	sw.peers.Remove(peer)	sw.metrics.Peers.Add(float64(-1))	peer.Stop()	for _, reactor := range sw.reactors {		reactor.RemovePeer(peer, reason)	}}
// reconnectToPeer tries to reconnect to the addr, first repeatedly
// with a fixed interval, then with exponential backoff.
// If no success after all that, it stops trying, and leaves it
// to the PEX/Addrbook to find the peer with the addr again
// NOTE: this will keep trying even if the handshake or auth fails.
// TODO: be more explicit with error types so we only retry on certain failures
//  - ie. if we're getting ErrDuplicatePeer we can stop
//  	because the addrbook got us the peer back already
func (sw *Switch) reconnectToPeer(addr *NetAddress) {	if sw.reconnecting.Has(string(addr.ID)) {		return	}	sw.reconnecting.Set(string(addr.ID), addr)	defer sw.reconnecting.Delete(string(addr.ID))
	start := time.Now()	sw.Logger.Info("Reconnecting to peer", "addr", addr)	for i := 0; i < reconnectAttempts; i++ {		if !sw.IsRunning() {			return		}
		err := sw.DialPeerWithAddress(addr, true)		if err == nil {			return // success
		}
		sw.Logger.Info("Error reconnecting to peer. Trying again", "tries", i, "err", err, "addr", addr)		// sleep a set amount
		sw.randomSleep(reconnectInterval)		continue	}
	sw.Logger.Error("Failed to reconnect to peer. Beginning exponential backoff",		"addr", addr, "elapsed", time.Since(start))	for i := 0; i < reconnectBackOffAttempts; i++ {		if !sw.IsRunning() {			return		}
		// sleep an exponentially increasing amount
		sleepIntervalSeconds := math.Pow(reconnectBackOffBaseSeconds, float64(i))		sw.randomSleep(time.Duration(sleepIntervalSeconds) * time.Second)		err := sw.DialPeerWithAddress(addr, true)		if err == nil {			return // success
		}		sw.Logger.Info("Error reconnecting to peer. Trying again", "tries", i, "err", err, "addr", addr)	}	sw.Logger.Error("Failed to reconnect to peer. Giving up", "addr", addr, "elapsed", time.Since(start))}
// SetAddrBook allows to set address book on Switch.
func (sw *Switch) SetAddrBook(addrBook AddrBook) {	sw.addrBook = addrBook}
// MarkPeerAsGood marks the given peer as good when it did something useful
// like contributed to consensus.
func (sw *Switch) MarkPeerAsGood(peer Peer) {	if sw.addrBook != nil {		sw.addrBook.MarkGood(peer.NodeInfo().NetAddress())	}}
//---------------------------------------------------------------------
// Dialing

// DialPeersAsync dials a list of peers asynchronously in random order (optionally, making them persistent).
// Used to dial peers from config on startup or from unsafe-RPC (trusted sources).
// TODO: remove addrBook arg since it's now set on the switch
func (sw *Switch) DialPeersAsync(addrBook AddrBook, peers []string, persistent bool) error {	netAddrs, errs := NewNetAddressStrings(peers)	// only log errors, dial correct addresses
	for _, err := range errs {		sw.Logger.Error("Error in peer's address", "err", err)	}
	ourAddr := sw.nodeInfo.NetAddress()
	// TODO: this code feels like it's in the wrong place.
	// The integration tests depend on the addrBook being saved
	// right away but maybe we can change that. Recall that
	// the addrBook is only written to disk every 2min
	if addrBook != nil {		// add peers to `addrBook`
		for _, netAddr := range netAddrs {			// do not add our address or ID
			if !netAddr.Same(ourAddr) {				if err := addrBook.AddAddress(netAddr, ourAddr); err != nil {					sw.Logger.Error("Can't add peer's address to addrbook", "err", err)				}			}		}		// Persist some peers to disk right away.
		// NOTE: integration tests depend on this
		addrBook.Save()	}
	// permute the list, dial them in random order.
	perm := sw.rng.Perm(len(netAddrs))	for i := 0; i < len(perm); i++ {		go func(i int) {			j := perm[i]			addr := netAddrs[j]
			if addr.Same(ourAddr) {				sw.Logger.Debug("Ignore attempt to connect to ourselves", "addr", addr, "ourAddr", ourAddr)				return			} else if sw.IsDialingOrExistingAddress(addr) {				sw.Logger.Debug("Ignore attempt to connect to an existing peer", "addr", addr)				return			}
			sw.randomSleep(0)			err := sw.DialPeerWithAddress(addr, persistent)			if err != nil {				switch err.(type) {				case ErrSwitchConnectToSelf, ErrSwitchDuplicatePeerID:					sw.Logger.Debug("Error dialing peer", "err", err)				default:					sw.Logger.Error("Error dialing peer", "err", err)				}			}		}(i)	}	return nil}
// DialPeerWithAddress dials the given peer and runs sw.addPeer if it connects and authenticates successfully.
// If `persistent == true`, the switch will always try to reconnect to this peer if the connection ever fails.
func (sw *Switch) DialPeerWithAddress(addr *NetAddress, persistent bool) error {	sw.dialing.Set(string(addr.ID), addr)	defer sw.dialing.Delete(string(addr.ID))	return sw.addOutboundPeerWithConfig(addr, sw.config, persistent)}
// sleep for interval plus some random amount of ms on [0, dialRandomizerIntervalMilliseconds]
func (sw *Switch) randomSleep(interval time.Duration) {	r := time.Duration(sw.rng.Int63n(dialRandomizerIntervalMilliseconds)) * time.Millisecond	time.Sleep(r + interval)}
// IsDialingOrExistingAddress returns true if switch has a peer with the given
// address or dialing it at the moment.
func (sw *Switch) IsDialingOrExistingAddress(addr *NetAddress) bool {	return sw.dialing.Has(string(addr.ID)) ||		sw.peers.Has(addr.ID) ||		(!sw.config.AllowDuplicateIP && sw.peers.HasIP(addr.IP))}
func (sw *Switch) acceptRoutine() {	for {		p, err := sw.transport.Accept(peerConfig{			chDescs:      sw.chDescs,			onPeerError:  sw.StopPeerForError,			reactorsByCh: sw.reactorsByCh,		})		if err != nil {			switch err.(type) {			case ErrRejected:				rErr := err.(ErrRejected)
				if rErr.IsSelf() {					// Remove the given address from the address book and add to our addresses
					// to avoid dialing in the future.
					addr := rErr.Addr()					sw.addrBook.RemoveAddress(&addr)					sw.addrBook.AddOurAddress(&addr)				}
				sw.Logger.Info(					"Inbound Peer rejected",					"err", err,					"numPeers", sw.peers.Size(),				)
				continue			case *ErrTransportClosed:				sw.Logger.Error(					"Stopped accept routine, as transport is closed",					"numPeers", sw.peers.Size(),				)			default:				sw.Logger.Error(					"Accept on transport errored",					"err", err,					"numPeers", sw.peers.Size(),				)			}
			break		}
		// Ignore connection if we already have enough peers.
		_, in, _ := sw.NumPeers()		if in >= sw.config.MaxNumInboundPeers {			sw.Logger.Info(				"Ignoring inbound connection: already have enough inbound peers",				"address", p.NodeInfo().NetAddress().String(),				"have", in,				"max", sw.config.MaxNumInboundPeers,			)
			_ = p.Stop()
			continue		}
		if err := sw.addPeer(p); err != nil {			_ = p.Stop()			sw.Logger.Info(				"Ignoring inbound connection: error while adding peer",				"err", err,				"id", p.ID(),			)		}	}}
// dial the peer; make secret connection; authenticate against the dialed ID;
// add the peer.
// if dialing fails, start the reconnect loop. If handhsake fails, its over.
// If peer is started succesffuly, reconnectLoop will start when
// StopPeerForError is called
func (sw *Switch) addOutboundPeerWithConfig(	addr *NetAddress,	cfg *config.P2PConfig,	persistent bool,) error {	sw.Logger.Info("Dialing peer", "address", addr)
	// XXX(xla): Remove the leakage of test concerns in implementation.
	if cfg.TestDialFail {		go sw.reconnectToPeer(addr)		return fmt.Errorf("dial err (peerConfig.DialFail == true)")	}
	p, err := sw.transport.Dial(*addr, peerConfig{		chDescs:      sw.chDescs,		onPeerError:  sw.StopPeerForError,		persistent:   persistent,		reactorsByCh: sw.reactorsByCh,	})	if err != nil {		switch e := err.(type) {		case ErrRejected:			if e.IsSelf() {				// Remove the given address from the address book and add to our addresses
				// to avoid dialing in the future.
				sw.addrBook.RemoveAddress(addr)				sw.addrBook.AddOurAddress(addr)			}		}
		if persistent {			go sw.reconnectToPeer(addr)		}
		return err	}
	if err := sw.addPeer(p); err != nil {		_ = p.Stop()		return err	}
	return nil}
func (sw *Switch) filterPeer(p Peer) error {	// Avoid duplicate
	if sw.peers.Has(p.ID()) {		return ErrRejected{id: p.ID(), isDuplicate: true}	}
	errc := make(chan error, len(sw.peerFilters))
	for _, f := range sw.peerFilters {		go func(f PeerFilterFunc, p Peer, errc chan<- error) {			errc <- f(sw.peers, p)		}(f, p, errc)	}
	for i := 0; i < cap(errc); i++ {		select {		case err := <-errc:			if err != nil {				return ErrRejected{id: p.ID(), err: err, isFiltered: true}			}		case <-time.After(sw.filterTimeout):			return ErrFilterTimeout{}		}	}
	return nil}
// addPeer starts up the Peer and adds it to the Switch.
func (sw *Switch) addPeer(p Peer) error {	if err := sw.filterPeer(p); err != nil {		return err	}
	p.SetLogger(sw.Logger.With("peer", p.NodeInfo().NetAddress().String))
	// All good. Start peer
	if sw.IsRunning() {		if err := sw.startInitPeer(p); err != nil {			return err		}	}
	// Add the peer to .peers.
	// We start it first so that a peer in the list is safe to Stop.
	// It should not err since we already checked peers.Has().
	if err := sw.peers.Add(p); err != nil {		return err	}
	sw.Logger.Info("Added peer", "peer", p)	sw.metrics.Peers.Add(float64(1))
	return nil}
func (sw *Switch) startInitPeer(p Peer) error {	err := p.Start() // spawn send/recv routines
	if err != nil {		// Should never happen
		sw.Logger.Error(			"Error starting peer",			"err", err,			"peer", p,		)		return err	}
	for _, reactor := range sw.reactors {		reactor.AddPeer(p)	}
	return nil}