package p2p import ( "context" "errors" "fmt" "io" "sync" "time" "github.com/gogo/protobuf/proto" "github.com/tendermint/tendermint/crypto" "github.com/tendermint/tendermint/libs/log" "github.com/tendermint/tendermint/libs/service" ) const queueBufferDefault = 4096 // ChannelID is an arbitrary channel ID. type ChannelID uint16 // Envelope contains a message with sender/receiver routing info. type Envelope struct { From NodeID // sender (empty if outbound) To NodeID // receiver (empty if inbound) Broadcast bool // send to all connected peers (ignores To) Message proto.Message // message payload // channelID is for internal Router use, set on outbound messages to inform // the sendPeer() goroutine which transport channel to use. // // FIXME: If we migrate the Transport API to a byte-oriented multi-stream // API, this will no longer be necessary since each channel will be mapped // onto a stream during channel/peer setup. See: // https://github.com/tendermint/spec/pull/227 channelID ChannelID } // PeerError is a peer error reported via Channel.Error. // // FIXME: This currently just disconnects the peer, which is too simplistic. // For example, some errors should be logged, some should cause disconnects, // and some should ban the peer. // // FIXME: This should probably be replaced by a more general PeerBehavior // concept that can mark good and bad behavior and contributes to peer scoring. // It should possibly also allow reactors to request explicit actions, e.g. // disconnection or banning, in addition to doing this based on aggregates. type PeerError struct { NodeID NodeID Err error } // Channel is a bidirectional channel to exchange Protobuf messages with peers, // wrapped in Envelope to specify routing info (i.e. sender/receiver). type Channel struct { ID ChannelID In <-chan Envelope // inbound messages (peers to reactors) Out chan<- Envelope // outbound messages (reactors to peers) Error chan<- PeerError // peer error reporting messageType proto.Message // the channel's message type, used for unmarshaling closeCh chan struct{} closeOnce sync.Once } // NewChannel creates a new channel. It is primarily for internal and test // use, reactors should use Router.OpenChannel(). func NewChannel( id ChannelID, messageType proto.Message, inCh <-chan Envelope, outCh chan<- Envelope, errCh chan<- PeerError, ) *Channel { return &Channel{ ID: id, messageType: messageType, In: inCh, Out: outCh, Error: errCh, closeCh: make(chan struct{}), } } // Close closes the channel. Future sends on Out and Error will panic. The In // channel remains open to avoid having to synchronize Router senders, which // should use Done() to detect channel closure instead. func (c *Channel) Close() { c.closeOnce.Do(func() { close(c.closeCh) close(c.Out) close(c.Error) }) } // Done returns a channel that's closed when Channel.Close() is called. func (c *Channel) Done() <-chan struct{} { return c.closeCh } // Wrapper is a Protobuf message that can contain a variety of inner messages // (e.g. via oneof fields). If a Channel's message type implements Wrapper, the // Router will automatically wrap outbound messages and unwrap inbound messages, // such that reactors do not have to do this themselves. type Wrapper interface { proto.Message // Wrap will take a message and wrap it in this one if possible. Wrap(proto.Message) error // Unwrap will unwrap the inner message contained in this message. Unwrap() (proto.Message, error) } // RouterOptions specifies options for a Router. type RouterOptions struct { // ResolveTimeout is the timeout for resolving NodeAddress URLs. // 0 means no timeout. ResolveTimeout time.Duration // DialTimeout is the timeout for dialing a peer. 0 means no timeout. DialTimeout time.Duration // HandshakeTimeout is the timeout for handshaking with a peer. 0 means // no timeout. HandshakeTimeout time.Duration // QueueType must be "wdrr" (Weighed Deficit Round Robin), // "priority", or FIFO. Defaults to FIFO. QueueType string } const ( queueTypeFifo = "fifo" queueTypePriority = "priority" queueTypeWDRR = "wdrr" ) // Validate validates router options. func (o *RouterOptions) Validate() error { switch o.QueueType { case "": o.QueueType = queueTypeFifo case queueTypeFifo, queueTypeWDRR, queueTypePriority: // pass default: return fmt.Errorf("queue type %q is not supported", o.QueueType) } return nil } // Router manages peer connections and routes messages between peers and reactor // channels. It takes a PeerManager for peer lifecycle management (e.g. which // peers to dial and when) and a set of Transports for connecting and // communicating with peers. // // On startup, three main goroutines are spawned to maintain peer connections: // // dialPeers(): in a loop, calls PeerManager.DialNext() to get the next peer // address to dial and spawns a goroutine that dials the peer, handshakes // with it, and begins to route messages if successful. // // acceptPeers(): in a loop, waits for an inbound connection via // Transport.Accept() and spawns a goroutine that handshakes with it and // begins to route messages if successful. // // evictPeers(): in a loop, calls PeerManager.EvictNext() to get the next // peer to evict, and disconnects it by closing its message queue. // // When a peer is connected, an outbound peer message queue is registered in // peerQueues, and routePeer() is called to spawn off two additional goroutines: // // sendPeer(): waits for an outbound message from the peerQueues queue, // marshals it, and passes it to the peer transport which delivers it. // // receivePeer(): waits for an inbound message from the peer transport, // unmarshals it, and passes it to the appropriate inbound channel queue // in channelQueues. // // When a reactor opens a channel via OpenChannel, an inbound channel message // queue is registered in channelQueues, and a channel goroutine is spawned: // // routeChannel(): waits for an outbound message from the channel, looks // up the recipient peer's outbound message queue in peerQueues, and submits // the message to it. // // All channel sends in the router are blocking. It is the responsibility of the // queue interface in peerQueues and channelQueues to prioritize and drop // messages as appropriate during contention to prevent stalls and ensure good // quality of service. type Router struct { *service.BaseService logger log.Logger metrics *Metrics options RouterOptions nodeInfo NodeInfo privKey crypto.PrivKey peerManager *PeerManager chDescs []ChannelDescriptor transports []Transport protocolTransports map[Protocol]Transport stopCh chan struct{} // signals Router shutdown peerMtx sync.RWMutex peerQueues map[NodeID]queue // outbound messages per peer for all channels queueFactory func(int) queue // FIXME: We don't strictly need to use a mutex for this if we seal the // channels on router start. This depends on whether we want to allow // dynamic channels in the future. channelMtx sync.RWMutex channelQueues map[ChannelID]queue // inbound messages from all peers to a single channel channelMessages map[ChannelID]proto.Message } // NewRouter creates a new Router. The given Transports must already be // listening on appropriate interfaces, and will be closed by the Router when it // stops. func NewRouter( logger log.Logger, metrics *Metrics, nodeInfo NodeInfo, privKey crypto.PrivKey, peerManager *PeerManager, transports []Transport, options RouterOptions, ) (*Router, error) { if err := options.Validate(); err != nil { return nil, err } router := &Router{ logger: logger, metrics: metrics, nodeInfo: nodeInfo, privKey: privKey, chDescs: make([]ChannelDescriptor, 0), transports: transports, protocolTransports: map[Protocol]Transport{}, peerManager: peerManager, options: options, stopCh: make(chan struct{}), channelQueues: map[ChannelID]queue{}, channelMessages: map[ChannelID]proto.Message{}, peerQueues: map[NodeID]queue{}, } router.BaseService = service.NewBaseService(logger, "router", router) qf, err := router.createQueueFactory() if err != nil { return nil, err } router.queueFactory = qf for _, transport := range transports { for _, protocol := range transport.Protocols() { if _, ok := router.protocolTransports[protocol]; !ok { router.protocolTransports[protocol] = transport } } } return router, nil } func (r *Router) createQueueFactory() (func(int) queue, error) { switch r.options.QueueType { case queueTypeFifo: return newFIFOQueue, nil case queueTypePriority: return func(size int) queue { if size%2 != 0 { size++ } q := newPQScheduler(r.logger, r.metrics, r.chDescs, uint(size)/2, uint(size)/2, defaultCapacity) q.start() return q }, nil case queueTypeWDRR: return func(size int) queue { if size%2 != 0 { size++ } q := newWDRRScheduler(r.logger, r.metrics, r.chDescs, uint(size)/2, uint(size)/2, defaultCapacity) q.start() return q }, nil default: return nil, fmt.Errorf("cannot construct queue of type %q", r.options.QueueType) } } // AddChannelDescriptors adds a set of ChannelDescriptors to the reactor. Note, // this should be called before the router is started and any connections are made. func (r *Router) AddChannelDescriptors(chDescs []*ChannelDescriptor) { for _, chDesc := range chDescs { r.chDescs = append(r.chDescs, *chDesc) } } // OpenChannel opens a new channel for the given message type. The caller must // close the channel when done, before stopping the Router. messageType is the // type of message passed through the channel (used for unmarshaling), which can // implement Wrapper to automatically (un)wrap multiple message types in a // wrapper message. The caller may provide a size to make the channel buffered, // which internally makes the inbound, outbound, and error channel buffered. func (r *Router) OpenChannel(id ChannelID, messageType proto.Message, size int) (*Channel, error) { if size == 0 { size = queueBufferDefault } r.channelMtx.Lock() defer r.channelMtx.Unlock() if _, ok := r.channelQueues[id]; ok { return nil, fmt.Errorf("channel %v already exists", id) } queue := r.queueFactory(size) outCh := make(chan Envelope, size) errCh := make(chan PeerError, size) channel := NewChannel(id, messageType, queue.dequeue(), outCh, errCh) var wrapper Wrapper if w, ok := messageType.(Wrapper); ok { wrapper = w } r.channelQueues[id] = queue r.channelMessages[id] = messageType go func() { defer func() { r.channelMtx.Lock() delete(r.channelQueues, id) delete(r.channelMessages, id) r.channelMtx.Unlock() queue.close() }() r.routeChannel(id, outCh, errCh, wrapper) }() return channel, nil } // routeChannel receives outbound channel messages and routes them to the // appropriate peer. It also receives peer errors and reports them to the peer // manager. It returns when either the outbound channel or error channel is // closed, or the Router is stopped. wrapper is an optional message wrapper // for messages, see Wrapper for details. func (r *Router) routeChannel( chID ChannelID, outCh <-chan Envelope, errCh <-chan PeerError, wrapper Wrapper, ) { for { select { case envelope, ok := <-outCh: if !ok { return } // Mark the envelope with the channel ID to allow sendPeer() to pass // it on to Transport.SendMessage(). envelope.channelID = chID // wrap the message in a wrapper message, if requested if wrapper != nil { msg := proto.Clone(wrapper) if err := msg.(Wrapper).Wrap(envelope.Message); err != nil { r.Logger.Error("failed to wrap message", "channel", chID, "err", err) continue } envelope.Message = msg } // collect peer queues to pass the message via var queues []queue if envelope.Broadcast { r.peerMtx.RLock() queues = make([]queue, 0, len(r.peerQueues)) for _, q := range r.peerQueues { queues = append(queues, q) } r.peerMtx.RUnlock() } else { r.peerMtx.RLock() q, ok := r.peerQueues[envelope.To] r.peerMtx.RUnlock() if !ok { r.logger.Debug("dropping message for unconnected peer", "peer", envelope.To, "channel", chID) continue } queues = []queue{q} } // send message to peers for _, q := range queues { start := time.Now().UTC() select { case q.enqueue() <- envelope: r.metrics.RouterPeerQueueSend.Observe(time.Since(start).Seconds()) case <-q.closed(): r.logger.Debug("dropping message for unconnected peer", "peer", envelope.To, "channel", chID) case <-r.stopCh: return } } case peerError, ok := <-errCh: if !ok { return } r.logger.Error("peer error, evicting", "peer", peerError.NodeID, "err", peerError.Err) if err := r.peerManager.Errored(peerError.NodeID, peerError.Err); err != nil { r.logger.Error("failed to report peer error", "peer", peerError.NodeID, "err", err) } case <-r.stopCh: return } } } // acceptPeers accepts inbound connections from peers on the given transport, // and spawns goroutines that route messages to/from them. func (r *Router) acceptPeers(transport Transport) { r.logger.Debug("starting accept routine", "transport", transport) ctx := r.stopCtx() for { // FIXME: We may need transports to enforce some sort of rate limiting // here (e.g. by IP address), or alternatively have PeerManager.Accepted() // do it for us. // // FIXME: Even though PeerManager enforces MaxConnected, we may want to // limit the maximum number of active connections here too, since e.g. // an adversary can open a ton of connections and then just hang during // the handshake, taking up TCP socket descriptors. // // FIXME: The old P2P stack rejected multiple connections for the same IP // unless P2PConfig.AllowDuplicateIP is true -- it's better to limit this // by peer ID rather than IP address, so this hasn't been implemented and // probably shouldn't (?). // // FIXME: The old P2P stack supported ABCI-based IP address filtering via // /p2p/filter/addr/ queries, do we want to implement this here as well? // Filtering by node ID is probably better. conn, err := transport.Accept() switch err { case nil: case io.EOF: r.logger.Debug("stopping accept routine", "transport", transport) return default: r.logger.Error("failed to accept connection", "transport", transport, "err", err) return } // Spawn a goroutine for the handshake, to avoid head-of-line blocking. go func() { defer conn.Close() // FIXME: The peer manager may reject the peer during Accepted() // after we've handshaked with the peer (to find out which peer it // is). However, because the handshake has no ack, the remote peer // will think the handshake was successful and start sending us // messages. // // This can cause problems in tests, where a disconnection can cause // the local node to immediately redial, while the remote node may // not have completed the disconnection yet and therefore reject the // reconnection attempt (since it thinks we're still connected from // before). // // The Router should do the handshake and have a final ack/fail // message to make sure both ends have accepted the connection, such // that it can be coordinated with the peer manager. peerInfo, _, err := r.handshakePeer(ctx, conn, "") switch { case errors.Is(err, context.Canceled): return case err != nil: r.logger.Error("peer handshake failed", "endpoint", conn, "err", err) return } if err := r.peerManager.Accepted(peerInfo.NodeID); err != nil { r.logger.Error("failed to accept connection", "peer", peerInfo.NodeID, "err", err) return } r.metrics.Peers.Add(1) queue := r.queueFactory(queueBufferDefault) r.peerMtx.Lock() r.peerQueues[peerInfo.NodeID] = queue r.peerMtx.Unlock() defer func() { r.peerMtx.Lock() delete(r.peerQueues, peerInfo.NodeID) r.peerMtx.Unlock() queue.close() if err := r.peerManager.Disconnected(peerInfo.NodeID); err != nil { r.logger.Error("failed to disconnect peer", "peer", peerInfo.NodeID, "err", err) } else { r.metrics.Peers.Add(-1) } }() if err := r.peerManager.Ready(peerInfo.NodeID); err != nil { r.logger.Error("failed to mark peer as ready", "peer", peerInfo.NodeID, "err", err) return } r.routePeer(peerInfo.NodeID, conn, queue) }() } } // dialPeers maintains outbound connections to peers by dialing them. func (r *Router) dialPeers() { r.logger.Debug("starting dial routine") ctx := r.stopCtx() for { address, err := r.peerManager.DialNext(ctx) switch { case errors.Is(err, context.Canceled): r.logger.Debug("stopping dial routine") return case err != nil: r.logger.Error("failed to find next peer to dial", "err", err) return } // Spawn off a goroutine to actually dial the peer, so that we can // dial multiple peers in parallel. go func() { conn, err := r.dialPeer(ctx, address) switch { case errors.Is(err, context.Canceled): return case err != nil: r.logger.Error("failed to dial peer", "peer", address, "err", err) if err = r.peerManager.DialFailed(address); err != nil { r.logger.Error("failed to report dial failure", "peer", address, "err", err) } return } defer conn.Close() peerID := address.NodeID _, _, err = r.handshakePeer(ctx, conn, peerID) switch { case errors.Is(err, context.Canceled): return case err != nil: r.logger.Error("failed to handshake with peer", "peer", address, "err", err) if err = r.peerManager.DialFailed(address); err != nil { r.logger.Error("failed to report dial failure", "peer", address, "err", err) } return } if err = r.peerManager.Dialed(address); err != nil { r.logger.Error("failed to dial peer", "peer", address, "err", err) return } r.metrics.Peers.Add(1) peerQueue := r.getOrMakeQueue(peerID) defer func() { r.peerMtx.Lock() delete(r.peerQueues, peerID) r.peerMtx.Unlock() peerQueue.close() if err := r.peerManager.Disconnected(peerID); err != nil { r.logger.Error("failed to disconnect peer", "peer", address, "err", err) } else { r.metrics.Peers.Add(-1) } }() if err := r.peerManager.Ready(peerID); err != nil { r.logger.Error("failed to mark peer as ready", "peer", address, "err", err) return } r.routePeer(peerID, conn, peerQueue) }() } } func (r *Router) getOrMakeQueue(peerID NodeID) queue { r.peerMtx.Lock() defer r.peerMtx.Unlock() if peerQueue, ok := r.peerQueues[peerID]; ok { return peerQueue } peerQueue := r.queueFactory(queueBufferDefault) r.peerQueues[peerID] = peerQueue return peerQueue } // dialPeer connects to a peer by dialing it. func (r *Router) dialPeer(ctx context.Context, address NodeAddress) (Connection, error) { resolveCtx := ctx if r.options.ResolveTimeout > 0 { var cancel context.CancelFunc resolveCtx, cancel = context.WithTimeout(resolveCtx, r.options.ResolveTimeout) defer cancel() } r.logger.Debug("resolving peer address", "peer", address) endpoints, err := address.Resolve(resolveCtx) switch { case err != nil: return nil, fmt.Errorf("failed to resolve address %q: %w", address, err) case len(endpoints) == 0: return nil, fmt.Errorf("address %q did not resolve to any endpoints", address) } for _, endpoint := range endpoints { transport, ok := r.protocolTransports[endpoint.Protocol] if !ok { r.logger.Error("no transport found for protocol", "endpoint", endpoint) continue } dialCtx := ctx if r.options.DialTimeout > 0 { var cancel context.CancelFunc dialCtx, cancel = context.WithTimeout(dialCtx, r.options.DialTimeout) defer cancel() } // FIXME: When we dial and handshake the peer, we should pass it // appropriate address(es) it can use to dial us back. It can't use our // remote endpoint, since TCP uses different port numbers for outbound // connections than it does for inbound. Also, we may need to vary this // by the peer's endpoint, since e.g. a peer on 192.168.0.0 can reach us // on a private address on this endpoint, but a peer on the public // Internet can't and needs a different public address. conn, err := transport.Dial(dialCtx, endpoint) if err != nil { r.logger.Error("failed to dial endpoint", "peer", address.NodeID, "endpoint", endpoint, "err", err) } else { r.logger.Debug("dialed peer", "peer", address.NodeID, "endpoint", endpoint) return conn, nil } } return nil, errors.New("all endpoints failed") } // handshakePeer handshakes with a peer, validating the peer's information. If // expectID is given, we check that the peer's info matches it. func (r *Router) handshakePeer(ctx context.Context, conn Connection, expectID NodeID) (NodeInfo, crypto.PubKey, error) { if r.options.HandshakeTimeout > 0 { var cancel context.CancelFunc ctx, cancel = context.WithTimeout(ctx, r.options.HandshakeTimeout) defer cancel() } peerInfo, peerKey, err := conn.Handshake(ctx, r.nodeInfo, r.privKey) if err != nil { return peerInfo, peerKey, err } if err = peerInfo.Validate(); err != nil { return peerInfo, peerKey, fmt.Errorf("invalid handshake NodeInfo: %w", err) } if NodeIDFromPubKey(peerKey) != peerInfo.NodeID { return peerInfo, peerKey, fmt.Errorf("peer's public key did not match its node ID %q (expected %q)", peerInfo.NodeID, NodeIDFromPubKey(peerKey)) } if expectID != "" && expectID != peerInfo.NodeID { return peerInfo, peerKey, fmt.Errorf("expected to connect with peer %q, got %q", expectID, peerInfo.NodeID) } return peerInfo, peerKey, nil } // routePeer routes inbound and outbound messages between a peer and the reactor // channels. It will close the given connection and send queue when done, or if // they are closed elsewhere it will cause this method to shut down and return. func (r *Router) routePeer(peerID NodeID, conn Connection, sendQueue queue) { r.logger.Info("peer connected", "peer", peerID, "endpoint", conn) errCh := make(chan error, 2) go func() { errCh <- r.receivePeer(peerID, conn) }() go func() { errCh <- r.sendPeer(peerID, conn, sendQueue) }() err := <-errCh _ = conn.Close() sendQueue.close() if e := <-errCh; err == nil { // The first err was nil, so we update it with the second err, which may // or may not be nil. err = e } switch err { case nil, io.EOF: r.logger.Info("peer disconnected", "peer", peerID, "endpoint", conn) default: r.logger.Error("peer failure", "peer", peerID, "endpoint", conn, "err", err) } } // receivePeer receives inbound messages from a peer, deserializes them and // passes them on to the appropriate channel. func (r *Router) receivePeer(peerID NodeID, conn Connection) error { for { chID, bz, err := conn.ReceiveMessage() if err != nil { return err } r.channelMtx.RLock() queue, ok := r.channelQueues[chID] messageType := r.channelMessages[chID] r.channelMtx.RUnlock() if !ok { r.logger.Debug("dropping message for unknown channel", "peer", peerID, "channel", chID) continue } msg := proto.Clone(messageType) if err := proto.Unmarshal(bz, msg); err != nil { r.logger.Error("message decoding failed, dropping message", "peer", peerID, "err", err) continue } if wrapper, ok := msg.(Wrapper); ok { msg, err = wrapper.Unwrap() if err != nil { r.logger.Error("failed to unwrap message", "err", err) continue } } start := time.Now().UTC() select { case queue.enqueue() <- Envelope{From: peerID, Message: msg}: r.metrics.PeerReceiveBytesTotal.With("peer_id", string(peerID)).Add(float64(proto.Size(msg))) r.metrics.RouterChannelQueueSend.Observe(time.Since(start).Seconds()) r.logger.Debug("received message", "peer", peerID, "message", msg) case <-queue.closed(): r.logger.Debug("channel closed, dropping message", "peer", peerID, "channel", chID) case <-r.stopCh: return nil } } } // sendPeer sends queued messages to a peer. func (r *Router) sendPeer(peerID NodeID, conn Connection, peerQueue queue) error { for { start := time.Now().UTC() select { case envelope := <-peerQueue.dequeue(): r.metrics.RouterPeerQueueRecv.Observe(time.Since(start).Seconds()) if envelope.Message == nil { r.logger.Error("dropping nil message", "peer", peerID) continue } bz, err := proto.Marshal(envelope.Message) if err != nil { r.logger.Error("failed to marshal message", "peer", peerID, "err", err) continue } _, err = conn.SendMessage(envelope.channelID, bz) if err != nil { return err } r.logger.Debug("sent message", "peer", envelope.To, "message", envelope.Message) case <-peerQueue.closed(): return nil case <-r.stopCh: return nil } } } // evictPeers evicts connected peers as requested by the peer manager. func (r *Router) evictPeers() { r.logger.Debug("starting evict routine") ctx := r.stopCtx() for { peerID, err := r.peerManager.EvictNext(ctx) switch { case errors.Is(err, context.Canceled): r.logger.Debug("stopping evict routine") return case err != nil: r.logger.Error("failed to find next peer to evict", "err", err) return } r.logger.Info("evicting peer", "peer", peerID) r.peerMtx.RLock() queue, ok := r.peerQueues[peerID] r.peerMtx.RUnlock() if ok { queue.close() } } } // OnStart implements service.Service. func (r *Router) OnStart() error { go r.dialPeers() go r.evictPeers() for _, transport := range r.transports { go r.acceptPeers(transport) } return nil } // OnStop implements service.Service. // // All channels must be closed by OpenChannel() callers before stopping the // router, to prevent blocked channel sends in reactors. Channels are not closed // here, since that would cause any reactor senders to panic, so it is the // sender's responsibility. func (r *Router) OnStop() { // Signal router shutdown. close(r.stopCh) // Close transport listeners (unblocks Accept calls). for _, transport := range r.transports { if err := transport.Close(); err != nil { r.logger.Error("failed to close transport", "transport", transport, "err", err) } } // Collect all remaining queues, and wait for them to close. queues := []queue{} r.channelMtx.RLock() for _, q := range r.channelQueues { queues = append(queues, q) } r.channelMtx.RUnlock() r.peerMtx.RLock() for _, q := range r.peerQueues { queues = append(queues, q) } r.peerMtx.RUnlock() for _, q := range queues { <-q.closed() } } // stopCtx returns a new context that is canceled when the router stops. func (r *Router) stopCtx() context.Context { ctx, cancel := context.WithCancel(context.Background()) go func() { <-r.stopCh cancel() }() return ctx }