package swarm import ( "context" "errors" "fmt" "sync" "time" addrutil "github.com/libp2p/go-addr-util" iconn "github.com/libp2p/go-libp2p-interface-conn" lgbl "github.com/libp2p/go-libp2p-loggables" peer "github.com/libp2p/go-libp2p-peer" ma "github.com/multiformats/go-multiaddr" ) // Diagram of dial sync: // // many callers of Dial() synched w. dials many addrs results to callers // ----------------------\ dialsync use earliest /-------------- // -----------------------\ |----------\ /---------------- // ------------------------>------------<------- >---------<----------------- // -----------------------| \----x \---------------- // ----------------------| \-----x \--------------- // any may fail if no addr at end // retry dialAttempt x var ( // ErrDialBackoff is returned by the backoff code when a given peer has // been dialed too frequently ErrDialBackoff = errors.New("dial backoff") // ErrDialFailed is returned when connecting to a peer has ultimately failed ErrDialFailed = errors.New("dial attempt failed") // ErrDialToSelf is returned if we attempt to dial our own peer ErrDialToSelf = errors.New("dial to self attempted") ) // dialAttempts governs how many times a goroutine will try to dial a given peer. // Note: this is down to one, as we have _too many dials_ atm. To add back in, // add loop back in Dial(.) const dialAttempts = 1 // number of concurrent outbound dials over transports that consume file descriptors const concurrentFdDials = 160 // number of concurrent outbound dials to make per peer const defaultPerPeerRateLimit = 8 // DialTimeout is the amount of time each dial attempt has. We can think about making // this larger down the road, or putting more granular timeouts (i.e. within each // subcomponent of Dial) var DialTimeout = time.Second * 10 // dialbackoff is a struct used to avoid over-dialing the same, dead peers. // Whenever we totally time out on a peer (all three attempts), we add them // to dialbackoff. Then, whenevers goroutines would _wait_ (dialsync), they // check dialbackoff. If it's there, they don't wait and exit promptly with // an error. (the single goroutine that is actually dialing continues to // dial). If a dial is successful, the peer is removed from backoff. // Example: // // for { // if ok, wait := dialsync.Lock(p); !ok { // if backoff.Backoff(p) { // return errDialFailed // } // <-wait // continue // } // defer dialsync.Unlock(p) // c, err := actuallyDial(p) // if err != nil { // dialbackoff.AddBackoff(p) // continue // } // dialbackoff.Clear(p) // } // type dialbackoff struct { entries map[peer.ID]*backoffPeer lock sync.RWMutex } type backoffPeer struct { tries int until time.Time } func (db *dialbackoff) init() { if db.entries == nil { db.entries = make(map[peer.ID]*backoffPeer) } } // Backoff returns whether the client should backoff from dialing // peer p func (db *dialbackoff) Backoff(p peer.ID) (backoff bool) { db.lock.Lock() defer db.lock.Unlock() db.init() bp, found := db.entries[p] if found && time.Now().Before(bp.until) { return true } return false } const baseBackoffTime = time.Second * 5 const maxBackoffTime = time.Minute * 5 // AddBackoff lets other nodes know that we've entered backoff with // peer p, so dialers should not wait unnecessarily. We still will // attempt to dial with one goroutine, in case we get through. func (db *dialbackoff) AddBackoff(p peer.ID) { db.lock.Lock() defer db.lock.Unlock() db.init() bp, ok := db.entries[p] if !ok { db.entries[p] = &backoffPeer{ tries: 1, until: time.Now().Add(baseBackoffTime), } return } expTimeAdd := time.Second * time.Duration(bp.tries*bp.tries) if expTimeAdd > maxBackoffTime { expTimeAdd = maxBackoffTime } bp.until = time.Now().Add(baseBackoffTime + expTimeAdd) bp.tries++ } // Clear removes a backoff record. Clients should call this after a // successful Dial. func (db *dialbackoff) Clear(p peer.ID) { db.lock.Lock() defer db.lock.Unlock() db.init() delete(db.entries, p) } // Dial connects to a peer. // // The idea is that the client of Swarm does not need to know what network // the connection will happen over. Swarm can use whichever it choses. // This allows us to use various transport protocols, do NAT traversal/relay, // etc. to achive connection. func (s *Swarm) Dial(ctx context.Context, p peer.ID) (*Conn, error) { var logdial = lgbl.Dial("swarm", s.LocalPeer(), p, nil, nil) if p == s.local { log.Event(ctx, "swarmDialSelf", logdial) return nil, ErrDialToSelf } return s.gatedDialAttempt(ctx, p) } func (s *Swarm) bestConnectionToPeer(p peer.ID) *Conn { cs := s.ConnectionsToPeer(p) for _, conn := range cs { if conn != nil { // dump out the first one we find. (TODO pick better) return conn } } return nil } // gatedDialAttempt is an attempt to dial a node. It is gated by the swarm's // dial synchronization systems: dialsync and dialbackoff. func (s *Swarm) gatedDialAttempt(ctx context.Context, p peer.ID) (*Conn, error) { defer log.EventBegin(ctx, "swarmDialAttemptSync", p).Done() // check if we already have an open connection first conn := s.bestConnectionToPeer(p) if conn != nil { return conn, nil } // if this peer has been backed off, lets get out of here if s.backf.Backoff(p) { log.Event(ctx, "swarmDialBackoff", p) return nil, ErrDialBackoff } return s.dsync.DialLock(ctx, p) } // doDial is an ugly shim method to retain all the logging and backoff logic // of the old dialsync code func (s *Swarm) doDial(ctx context.Context, p peer.ID) (*Conn, error) { var logdial = lgbl.Dial("swarm", s.LocalPeer(), p, nil, nil) // ok, we have been charged to dial! let's do it. // if it succeeds, dial will add the conn to the swarm itself. defer log.EventBegin(ctx, "swarmDialAttemptStart", logdial).Done() ctxT, cancel := context.WithTimeout(ctx, s.dialT) conn, err := s.dial(ctxT, p) cancel() log.Debugf("dial end %s", conn) if err != nil { if err != context.Canceled { log.Event(ctx, "swarmDialBackoffAdd", logdial) s.backf.AddBackoff(p) // let others know to backoff } // ok, we failed. try again. (if loop is done, our error is output) return nil, fmt.Errorf("dial attempt failed: %s", err) } log.Event(ctx, "swarmDialBackoffClear", logdial) s.backf.Clear(p) // okay, no longer need to backoff return conn, nil } // dial is the actual swarm's dial logic, gated by Dial. func (s *Swarm) dial(ctx context.Context, p peer.ID) (*Conn, error) { var logdial = lgbl.Dial("swarm", s.LocalPeer(), p, nil, nil) if p == s.local { log.Event(ctx, "swarmDialDoDialSelf", logdial) return nil, ErrDialToSelf } defer log.EventBegin(ctx, "swarmDialDo", logdial).Done() logdial["dial"] = "failure" // start off with failure. set to "success" at the end. sk := s.peers.PrivKey(s.local) logdial["encrypted"] = (sk != nil) // log wether this will be an encrypted dial or not. if sk == nil { // fine for sk to be nil, just log. log.Debug("Dial not given PrivateKey, so WILL NOT SECURE conn.") } ila, _ := s.InterfaceListenAddresses() subtractFilter := addrutil.SubtractFilter(append(ila, s.peers.Addrs(s.local)...)...) // get live channel of addresses for peer, filtered by the given filters /* remoteAddrChan := s.peers.AddrsChan(ctx, p, addrutil.AddrUsableFilter, subtractFilter, s.Filters.AddrBlocked) */ ////// /* This code is temporary, the peerstore can currently provide a channel as an interface for receiving addresses, but more thought needs to be put into the execution. For now, this allows us to use the improved rate limiter, while maintaining the outward behaviour that we previously had (halting a dial when we run out of addrs) */ paddrs := s.peers.Addrs(p) goodAddrs := addrutil.FilterAddrs(paddrs, addrutil.AddrUsableFunc, subtractFilter, addrutil.FilterNeg(s.Filters.AddrBlocked), ) remoteAddrChan := make(chan ma.Multiaddr, len(goodAddrs)) for _, a := range goodAddrs { remoteAddrChan <- a } close(remoteAddrChan) ///////// // try to get a connection to any addr connC, err := s.dialAddrs(ctx, p, remoteAddrChan) if err != nil { logdial["error"] = err.Error() return nil, err } logdial["netconn"] = lgbl.NetConn(connC) // ok try to setup the new connection. defer log.EventBegin(ctx, "swarmDialDoSetup", logdial, lgbl.NetConn(connC)).Done() swarmC, err := dialConnSetup(ctx, s, connC) if err != nil { logdial["error"] = err.Error() connC.Close() // close the connection. didn't work out :( return nil, err } logdial["dial"] = "success" return swarmC, nil } func (s *Swarm) dialAddrs(ctx context.Context, p peer.ID, remoteAddrs <-chan ma.Multiaddr) (iconn.Conn, error) { log.Debugf("%s swarm dialing %s", s.local, p) ctx, cancel := context.WithCancel(ctx) defer cancel() // cancel work when we exit func // use a single response type instead of errs and conns, reduces complexity *a ton* respch := make(chan dialResult) defaultDialFail := fmt.Errorf("failed to dial %s (default failure)", p) exitErr := defaultDialFail var active int for { select { case addr, ok := <-remoteAddrs: if !ok { remoteAddrs = nil if active == 0 { return nil, exitErr } continue } s.limitedDial(ctx, p, addr, respch) active++ case <-ctx.Done(): if exitErr == defaultDialFail { exitErr = ctx.Err() } return nil, exitErr case resp := <-respch: active-- if resp.Err != nil { log.Infof("got error on dial to %s: %s", resp.Addr, resp.Err) // Errors are normal, lots of dials will fail exitErr = resp.Err if remoteAddrs == nil && active == 0 { return nil, exitErr } } else if resp.Conn != nil { return resp.Conn, nil } } } } // limitedDial will start a dial to the given peer when // it is able, respecting the various different types of rate // limiting that occur without using extra goroutines per addr func (s *Swarm) limitedDial(ctx context.Context, p peer.ID, a ma.Multiaddr, resp chan dialResult) { s.limiter.AddDialJob(&dialJob{ addr: a, peer: p, resp: resp, ctx: ctx, }) } func (s *Swarm) dialAddr(ctx context.Context, p peer.ID, addr ma.Multiaddr) (iconn.Conn, error) { log.Debugf("%s swarm dialing %s %s", s.local, p, addr) connC, err := s.dialer.Dial(ctx, addr, p) if err != nil { return nil, fmt.Errorf("%s --> %s dial attempt failed: %s", s.local, p, err) } // if the connection is not to whom we thought it would be... remotep := connC.RemotePeer() if remotep != p { connC.Close() _, err := connC.Read(nil) // should return any potential errors (ex: from secio) return nil, fmt.Errorf("misdial to %s through %s (got %s): %s", p, addr, remotep, err) } // if the connection is to ourselves... // this can happen TONS when Loopback addrs are advertized. // (this should be caught by two checks above, but let's just make sure.) if remotep == s.local { connC.Close() return nil, fmt.Errorf("misdial to %s through %s (got self)", p, addr) } // success! we got one! return connC, nil } var ConnSetupTimeout = time.Minute * 5 // dialConnSetup is the setup logic for a connection from the dial side. it // needs to add the Conn to the StreamSwarm, then run newConnSetup func dialConnSetup(ctx context.Context, s *Swarm, connC iconn.Conn) (*Conn, error) { deadline, ok := ctx.Deadline() if !ok { deadline = time.Now().Add(ConnSetupTimeout) } if err := connC.SetDeadline(deadline); err != nil { return nil, err } psC, err := s.swarm.AddConn(connC) if err != nil { // connC is closed by caller if we fail. return nil, fmt.Errorf("failed to add conn to ps.Swarm: %s", err) } // ok try to setup the new connection. (newConnSetup will add to group) swarmC, err := s.newConnSetup(ctx, psC) if err != nil { psC.Close() // we need to make sure psC is Closed. return nil, err } if err := connC.SetDeadline(time.Time{}); err != nil { log.Error("failed to reset connection deadline after setup: ", err) return nil, err } return swarmC, err }