package floodsub import ( "context" "encoding/binary" "fmt" "math/rand" "sync/atomic" "time" pb "github.com/libp2p/go-floodsub/pb" inet "gx/ipfs/QmQdLcvoy3JuSqhV6iwQ9T6Cv7hWLAdzob4jUZRPqFL67Z/go-libp2p-net" host "gx/ipfs/QmX9pw5dSUZ2FozbppcSDJiS7eEh1RFwJNwrbmyLoUMS9x/go-libp2p-host" timecache "gx/ipfs/QmYftoT56eEfUBTD3erR6heXuPSUhGRezSmhSU8LeczP8b/timecache" logging "gx/ipfs/QmZChCsSt8DctjceaL56Eibc29CVQq4dGKRXC5JRZ6Ppae/go-log" protocol "gx/ipfs/QmZNkThpqfVXs9GNbexPrfBbXSLNYeKrE7jwFM2oqHbyqN/go-libp2p-protocol" peer "gx/ipfs/QmbNepETomvmXfz1X5pHNFD2QuPqnqi47dTd94QJWSorQ3/go-libp2p-peer" ) const ( defaultValidateTimeout = 150 * time.Millisecond defaultValidateConcurrency = 100 defaultValidateThrottle = 8192 ) var log = logging.Logger("pubsub") type PubSub struct { // atomic counter for seqnos // NOTE: Must be declared at the top of the struct as we perform atomic // operations on this field. // // See: https://golang.org/pkg/sync/atomic/#pkg-note-BUG counter uint64 host host.Host rt PubSubRouter // incoming messages from other peers incoming chan *RPC // messages we are publishing out to our peers publish chan *Message // addSub is a control channel for us to add and remove subscriptions addSub chan *addSubReq // get list of topics we are subscribed to getTopics chan *topicReq // get chan of peers we are connected to getPeers chan *listPeerReq // send subscription here to cancel it cancelCh chan *Subscription // a notification channel for incoming streams from other peers newPeers chan inet.Stream // a notification channel for when our peers die peerDead chan peer.ID // The set of topics we are subscribed to myTopics map[string]map[*Subscription]struct{} // topics tracks which topics each of our peers are subscribed to topics map[string]map[peer.ID]struct{} // sendMsg handles messages that have been validated sendMsg chan *sendReq // addVal handles validator registration requests addVal chan *addValReq // rmVal handles validator unregistration requests rmVal chan *rmValReq // topicVals tracks per topic validators topicVals map[string]*topicVal // validateThrottle limits the number of active validation goroutines validateThrottle chan struct{} // eval thunk in event loop eval chan func() peers map[peer.ID]chan *RPC seenMessages *timecache.TimeCache ctx context.Context } // PubSubRouter is the message router component of PubSub type PubSubRouter interface { // Protocols returns the list of protocols supported by the router. Protocols() []protocol.ID // Attach is invoked by the PubSub constructor to attach the router to a // freshly initialized PubSub instance. Attach(*PubSub) // AddPeer notifies the router that a new peer has been connected. AddPeer(peer.ID, protocol.ID) // RemovePeer notifies the router that a peer has been disconnected. RemovePeer(peer.ID) // HandleRPC is invoked to process control messages in the RPC envelope. // It is invoked after subscriptions and payload messages have been processed. HandleRPC(*RPC) // Publish is invoked to forward a new message that has been validated. Publish(peer.ID, *pb.Message) // Join notifies the router that we want to receive and forward messages in a topic. // It is invoked after the subscription announcement. Join(topic string) // Leave notifies the router that we are no longer interested in a topic. // It is invoked after the unsubscription announcement. Leave(topic string) } type Message struct { *pb.Message } func (m *Message) GetFrom() peer.ID { return peer.ID(m.Message.GetFrom()) } type RPC struct { pb.RPC // unexported on purpose, not sending this over the wire from peer.ID } type Option func(*PubSub) error // NewPubSub returns a new PubSub management object func NewPubSub(ctx context.Context, h host.Host, rt PubSubRouter, opts ...Option) (*PubSub, error) { ps := &PubSub{ host: h, ctx: ctx, rt: rt, incoming: make(chan *RPC, 32), publish: make(chan *Message), newPeers: make(chan inet.Stream), peerDead: make(chan peer.ID), cancelCh: make(chan *Subscription), getPeers: make(chan *listPeerReq), addSub: make(chan *addSubReq), getTopics: make(chan *topicReq), sendMsg: make(chan *sendReq, 32), addVal: make(chan *addValReq), rmVal: make(chan *rmValReq), validateThrottle: make(chan struct{}, defaultValidateThrottle), eval: make(chan func()), myTopics: make(map[string]map[*Subscription]struct{}), topics: make(map[string]map[peer.ID]struct{}), peers: make(map[peer.ID]chan *RPC), topicVals: make(map[string]*topicVal), seenMessages: timecache.NewTimeCache(time.Second * 120), counter: uint64(time.Now().UnixNano()), } for _, opt := range opts { err := opt(ps) if err != nil { return nil, err } } rt.Attach(ps) for _, id := range rt.Protocols() { h.SetStreamHandler(id, ps.handleNewStream) } h.Network().Notify((*PubSubNotif)(ps)) go ps.processLoop(ctx) return ps, nil } func WithValidateThrottle(n int) Option { return func(ps *PubSub) error { ps.validateThrottle = make(chan struct{}, n) return nil } } // processLoop handles all inputs arriving on the channels func (p *PubSub) processLoop(ctx context.Context) { defer func() { // Clean up go routines. for _, ch := range p.peers { close(ch) } p.peers = nil p.topics = nil }() for { select { case s := <-p.newPeers: pid := s.Conn().RemotePeer() ch, ok := p.peers[pid] if ok { log.Error("already have connection to peer: ", pid) close(ch) } messages := make(chan *RPC, 32) go p.handleSendingMessages(ctx, s, messages) messages <- p.getHelloPacket() p.peers[pid] = messages p.rt.AddPeer(pid, s.Protocol()) case pid := <-p.peerDead: ch, ok := p.peers[pid] if ok { close(ch) } delete(p.peers, pid) for _, t := range p.topics { delete(t, pid) } p.rt.RemovePeer(pid) case treq := <-p.getTopics: var out []string for t := range p.myTopics { out = append(out, t) } treq.resp <- out case sub := <-p.cancelCh: p.handleRemoveSubscription(sub) case sub := <-p.addSub: p.handleAddSubscription(sub) case preq := <-p.getPeers: tmap, ok := p.topics[preq.topic] if preq.topic != "" && !ok { preq.resp <- nil continue } var peers []peer.ID for p := range p.peers { if preq.topic != "" { _, ok := tmap[p] if !ok { continue } } peers = append(peers, p) } preq.resp <- peers case rpc := <-p.incoming: p.handleIncomingRPC(rpc) case msg := <-p.publish: vals := p.getValidators(msg) p.pushMsg(vals, p.host.ID(), msg) case req := <-p.sendMsg: p.publishMessage(req.from, req.msg.Message) case req := <-p.addVal: p.addValidator(req) case req := <-p.rmVal: p.rmValidator(req) case thunk := <-p.eval: thunk() case <-ctx.Done(): log.Info("pubsub processloop shutting down") return } } } // handleRemoveSubscription removes Subscription sub from bookeeping. // If this was the last Subscription for a given topic, it will also announce // that this node is not subscribing to this topic anymore. // Only called from processLoop. func (p *PubSub) handleRemoveSubscription(sub *Subscription) { subs := p.myTopics[sub.topic] if subs == nil { return } sub.err = fmt.Errorf("subscription cancelled by calling sub.Cancel()") close(sub.ch) delete(subs, sub) if len(subs) == 0 { delete(p.myTopics, sub.topic) p.announce(sub.topic, false) p.rt.Leave(sub.topic) } } // handleAddSubscription adds a Subscription for a particular topic. If it is // the first Subscription for the topic, it will announce that this node // subscribes to the topic. // Only called from processLoop. func (p *PubSub) handleAddSubscription(req *addSubReq) { sub := req.sub subs := p.myTopics[sub.topic] // announce we want this topic if len(subs) == 0 { p.announce(sub.topic, true) p.rt.Join(sub.topic) } // make new if not there if subs == nil { p.myTopics[sub.topic] = make(map[*Subscription]struct{}) subs = p.myTopics[sub.topic] } sub.ch = make(chan *Message, 32) sub.cancelCh = p.cancelCh p.myTopics[sub.topic][sub] = struct{}{} req.resp <- sub } // announce announces whether or not this node is interested in a given topic // Only called from processLoop. func (p *PubSub) announce(topic string, sub bool) { subopt := &pb.RPC_SubOpts{ Topicid: &topic, Subscribe: &sub, } out := rpcWithSubs(subopt) for pid, peer := range p.peers { select { case peer <- out: default: log.Infof("Can't send announce message to peer %s: queue full; scheduling retry", pid) go p.announceRetry(topic, sub) } } } func (p *PubSub) announceRetry(topic string, sub bool) { time.Sleep(time.Duration(1+rand.Intn(1000)) * time.Millisecond) retry := func() { _, ok := p.myTopics[topic] if (ok && sub) || (!ok && !sub) { p.announce(topic, sub) } } select { case p.eval <- retry: case <-p.ctx.Done(): } } // notifySubs sends a given message to all corresponding subscribers. // Only called from processLoop. func (p *PubSub) notifySubs(msg *pb.Message) { for _, topic := range msg.GetTopicIDs() { subs := p.myTopics[topic] for f := range subs { select { case f.ch <- &Message{msg}: default: log.Infof("Can't deliver message to subscription for topic %s; subscriber too slow", topic) } } } } // seenMessage returns whether we already saw this message before func (p *PubSub) seenMessage(id string) bool { return p.seenMessages.Has(id) } // markSeen marks a message as seen such that seenMessage returns `true' for the given id func (p *PubSub) markSeen(id string) { p.seenMessages.Add(id) } // subscribedToMessage returns whether we are subscribed to one of the topics // of a given message func (p *PubSub) subscribedToMsg(msg *pb.Message) bool { if len(p.myTopics) == 0 { return false } for _, t := range msg.GetTopicIDs() { if _, ok := p.myTopics[t]; ok { return true } } return false } func (p *PubSub) handleIncomingRPC(rpc *RPC) { for _, subopt := range rpc.GetSubscriptions() { t := subopt.GetTopicid() if subopt.GetSubscribe() { tmap, ok := p.topics[t] if !ok { tmap = make(map[peer.ID]struct{}) p.topics[t] = tmap } tmap[rpc.from] = struct{}{} } else { tmap, ok := p.topics[t] if !ok { continue } delete(tmap, rpc.from) } } for _, pmsg := range rpc.GetPublish() { if !p.subscribedToMsg(pmsg) { log.Warning("received message we didn't subscribe to. Dropping.") continue } msg := &Message{pmsg} vals := p.getValidators(msg) p.pushMsg(vals, rpc.from, msg) } p.rt.HandleRPC(rpc) } // msgID returns a unique ID of the passed Message func msgID(pmsg *pb.Message) string { return string(pmsg.GetFrom()) + string(pmsg.GetSeqno()) } // pushMsg pushes a message performing validation as necessary func (p *PubSub) pushMsg(vals []*topicVal, src peer.ID, msg *Message) { id := msgID(msg.Message) if p.seenMessage(id) { return } p.markSeen(id) if len(vals) > 0 { // validation is asynchronous and globally throttled with the throttleValidate semaphore. // the purpose of the global throttle is to bound the goncurrency possible from incoming // network traffic; each validator also has an individual throttle to preclude // slow (or faulty) validators from starving other topics; see validate below. select { case p.validateThrottle <- struct{}{}: go func() { p.validate(vals, src, msg) <-p.validateThrottle }() default: log.Warningf("message validation throttled; dropping message from %s", src) } return } p.publishMessage(src, msg.Message) } // validate performs validation and only sends the message if all validators succeed func (p *PubSub) validate(vals []*topicVal, src peer.ID, msg *Message) { ctx, cancel := context.WithCancel(p.ctx) defer cancel() rch := make(chan bool, len(vals)) rcount := 0 throttle := false loop: for _, val := range vals { rcount++ select { case val.validateThrottle <- struct{}{}: go func(val *topicVal) { rch <- val.validateMsg(ctx, msg) <-val.validateThrottle }(val) default: log.Debugf("validation throttled for topic %s", val.topic) throttle = true break loop } } if throttle { log.Warningf("message validation throttled; dropping message from %s", src) return } for i := 0; i < rcount; i++ { valid := <-rch if !valid { log.Warningf("message validation failed; dropping message from %s", src) return } } // all validators were successful, send the message p.sendMsg <- &sendReq{ from: src, msg: msg, } } func (p *PubSub) publishMessage(from peer.ID, pmsg *pb.Message) { p.notifySubs(pmsg) p.rt.Publish(from, pmsg) } // getValidators returns all validators that apply to a given message func (p *PubSub) getValidators(msg *Message) []*topicVal { var vals []*topicVal for _, topic := range msg.GetTopicIDs() { val, ok := p.topicVals[topic] if !ok { continue } vals = append(vals, val) } return vals } type addSubReq struct { sub *Subscription resp chan *Subscription } type SubOpt func(sub *Subscription) error // Subscribe returns a new Subscription for the given topic func (p *PubSub) Subscribe(topic string, opts ...SubOpt) (*Subscription, error) { td := pb.TopicDescriptor{Name: &topic} return p.SubscribeByTopicDescriptor(&td, opts...) } // SubscribeByTopicDescriptor lets you subscribe a topic using a pb.TopicDescriptor func (p *PubSub) SubscribeByTopicDescriptor(td *pb.TopicDescriptor, opts ...SubOpt) (*Subscription, error) { if td.GetAuth().GetMode() != pb.TopicDescriptor_AuthOpts_NONE { return nil, fmt.Errorf("auth mode not yet supported") } if td.GetEnc().GetMode() != pb.TopicDescriptor_EncOpts_NONE { return nil, fmt.Errorf("encryption mode not yet supported") } sub := &Subscription{ topic: td.GetName(), } for _, opt := range opts { err := opt(sub) if err != nil { return nil, err } } out := make(chan *Subscription, 1) p.addSub <- &addSubReq{ sub: sub, resp: out, } return <-out, nil } type topicReq struct { resp chan []string } // GetTopics returns the topics this node is subscribed to func (p *PubSub) GetTopics() []string { out := make(chan []string, 1) p.getTopics <- &topicReq{resp: out} return <-out } // Publish publishes data under the given topic func (p *PubSub) Publish(topic string, data []byte) error { seqno := p.nextSeqno() p.publish <- &Message{ &pb.Message{ Data: data, TopicIDs: []string{topic}, From: []byte(p.host.ID()), Seqno: seqno, }, } return nil } func (p *PubSub) nextSeqno() []byte { seqno := make([]byte, 8) counter := atomic.AddUint64(&p.counter, 1) binary.BigEndian.PutUint64(seqno, counter) return seqno } type listPeerReq struct { resp chan []peer.ID topic string } // sendReq is a request to call publishMessage. // It is issued after message validation is done. type sendReq struct { from peer.ID msg *Message } // ListPeers returns a list of peers we are connected to. func (p *PubSub) ListPeers(topic string) []peer.ID { out := make(chan []peer.ID) p.getPeers <- &listPeerReq{ resp: out, topic: topic, } return <-out } // per topic validators type addValReq struct { topic string validate Validator timeout time.Duration throttle int resp chan error } type rmValReq struct { topic string resp chan error } type topicVal struct { topic string validate Validator validateTimeout time.Duration validateThrottle chan struct{} } // Validator is a function that validates a message type Validator func(context.Context, *Message) bool // ValidatorOpt is an option for RegisterTopicValidator type ValidatorOpt func(addVal *addValReq) error // WithValidatorTimeout is an option that sets the topic validator timeout func WithValidatorTimeout(timeout time.Duration) ValidatorOpt { return func(addVal *addValReq) error { addVal.timeout = timeout return nil } } // WithValidatorConcurrency is an option that sets topic validator throttle func WithValidatorConcurrency(n int) ValidatorOpt { return func(addVal *addValReq) error { addVal.throttle = n return nil } } // RegisterTopicValidator registers a validator for topic func (p *PubSub) RegisterTopicValidator(topic string, val Validator, opts ...ValidatorOpt) error { addVal := &addValReq{ topic: topic, validate: val, resp: make(chan error, 1), } for _, opt := range opts { err := opt(addVal) if err != nil { return err } } p.addVal <- addVal return <-addVal.resp } func (ps *PubSub) addValidator(req *addValReq) { topic := req.topic _, ok := ps.topicVals[topic] if ok { req.resp <- fmt.Errorf("Duplicate validator for topic %s", topic) return } val := &topicVal{ topic: topic, validate: req.validate, validateTimeout: defaultValidateTimeout, validateThrottle: make(chan struct{}, defaultValidateConcurrency), } if req.timeout > 0 { val.validateTimeout = req.timeout } if req.throttle > 0 { val.validateThrottle = make(chan struct{}, req.throttle) } ps.topicVals[topic] = val req.resp <- nil } // UnregisterTopicValidator removes a validator from a topic // returns an error if there was no validator registered with the topic func (p *PubSub) UnregisterTopicValidator(topic string) error { rmVal := &rmValReq{ topic: topic, resp: make(chan error, 1), } p.rmVal <- rmVal return <-rmVal.resp } func (ps *PubSub) rmValidator(req *rmValReq) { topic := req.topic _, ok := ps.topicVals[topic] if ok { delete(ps.topicVals, topic) req.resp <- nil } else { req.resp <- fmt.Errorf("No validator for topic %s", topic) } } func (val *topicVal) validateMsg(ctx context.Context, msg *Message) bool { vctx, cancel := context.WithTimeout(ctx, val.validateTimeout) defer cancel() valid := val.validate(vctx, msg) if !valid { log.Debugf("validation failed for topic %s", val.topic) } return valid }