package swarm import ( "errors" "fmt" "math/rand" "net" "sync" "time" conn "github.com/jbenet/go-ipfs/p2p/net/conn" addrutil "github.com/jbenet/go-ipfs/p2p/net/swarm/addr" peer "github.com/jbenet/go-ipfs/p2p/peer" lgbl "github.com/jbenet/go-ipfs/util/eventlog/loggables" ma "github.com/jbenet/go-ipfs/Godeps/_workspace/src/github.com/jbenet/go-multiaddr" manet "github.com/jbenet/go-ipfs/Godeps/_workspace/src/github.com/jbenet/go-multiaddr-net" process "github.com/jbenet/go-ipfs/Godeps/_workspace/src/github.com/jbenet/goprocess" ratelimit "github.com/jbenet/go-ipfs/Godeps/_workspace/src/github.com/jbenet/goprocess/ratelimit" context "github.com/jbenet/go-ipfs/Godeps/_workspace/src/golang.org/x/net/context" ) // 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 = errors.New("dial backoff") ErrDialFailed = errors.New("dial attempt failed") 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 // 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.Duration = time.Second * 10 // dialsync is a small object that helps manage ongoing dials. // this way, if we receive many simultaneous dial requests, one // can do its thing, while the rest wait. // // this interface is so would-be dialers can just: // // for { // c := findConnectionToPeer(peer) // if c != nil { // return c // } // // // ok, no connections. should we dial? // if ok, wait := dialsync.Lock(peer); !ok { // <-wait // can optionally wait // continue // } // defer dialsync.Unlock(peer) // // c := actuallyDial(peer) // return c // } // type dialsync struct { // ongoing is a map of tickets for the current peers being dialed. // this way, we dont kick off N dials simultaneously. ongoing map[peer.ID]chan struct{} lock sync.Mutex } // Lock governs the beginning of a dial attempt. // If there are no ongoing dials, it returns true, and the client is now // scheduled to dial. Every other goroutine that calls startDial -- with //the same dst -- will block until client is done. The client MUST call // ds.Unlock(p) when it is done, to unblock the other callers. // The client is not reponsible for achieving a successful dial, only for // reporting the end of the attempt (calling ds.Unlock(p)). // // see the example below `dialsync` func (ds *dialsync) Lock(dst peer.ID) (bool, chan struct{}) { ds.lock.Lock() if ds.ongoing == nil { // init if not ready ds.ongoing = make(map[peer.ID]chan struct{}) } wait, found := ds.ongoing[dst] if !found { ds.ongoing[dst] = make(chan struct{}) } ds.lock.Unlock() if found { return false, wait } // ok! you're signed up to dial! return true, nil } // Unlock releases waiters to a dial attempt. see Lock. // if Unlock(p) is called without calling Lock(p) first, Unlock panics. func (ds *dialsync) Unlock(dst peer.ID) { ds.lock.Lock() wait, found := ds.ongoing[dst] if !found { panic("called dialDone with no ongoing dials to peer: " + dst.Pretty()) } delete(ds.ongoing, dst) // remove ongoing dial close(wait) // release everyone else ds.lock.Unlock() } // 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]struct{} lock sync.RWMutex } func (db *dialbackoff) init() { if db.entries == nil { db.entries = make(map[peer.ID]struct{}) } } // Backoff returns whether the client should backoff from dialing // peeer p func (db *dialbackoff) Backoff(p peer.ID) bool { db.lock.Lock() db.init() _, found := db.entries[p] db.lock.Unlock() return found } // 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() db.init() db.entries[p] = struct{}{} db.lock.Unlock() } // Clear removes a backoff record. Clients should call this after a // successful Dial. func (db *dialbackoff) Clear(p peer.ID) { db.lock.Lock() db.init() delete(db.entries, p) db.lock.Unlock() } // 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) { var logdial = lgbl.Dial("swarm", s.LocalPeer(), p, nil, nil) defer log.EventBegin(ctx, "swarmDialAttemptSync", logdial).Done() // check if we already have an open connection first conn := s.bestConnectionToPeer(p) if conn != nil { return conn, nil } // check if there's an ongoing dial to this peer if ok, wait := s.dsync.Lock(p); ok { // 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() s.dsync.Unlock(p) log.Debugf("dial end %s", conn) if err != nil { log.Event(ctx, "swarmDialBackoffAdd", logdial) s.backf.AddBackoff(p) // let others know to backoff return nil, ErrDialFailed // ok, we failed. try again. (if loop is done, our error is output) } log.Event(ctx, "swarmDialBackoffClear", logdial) s.backf.Clear(p) // okay, no longer need to backoff return conn, nil } else { // we did not dial. we must wait for someone else to dial. // check whether we should backoff first... if s.backf.Backoff(p) { log.Event(ctx, "swarmDialBackoff", logdial) return nil, ErrDialBackoff } defer log.EventBegin(ctx, "swarmDialWait", logdial).Done() select { case <-wait: // wait for that other dial to finish. // see if it worked, OR we got an incoming dial in the meantime... conn := s.bestConnectionToPeer(p) if conn != nil { return conn, nil } return nil, ErrDialFailed case <-ctx.Done(): // or we may have to bail... return nil, ctx.Err() } } } // 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.") } // get our own addrs. try dialing out from our listener addresses (reusing ports) // Note that using our peerstore's addresses here is incorrect, as that would // include observed addresses. TODO: make peerstore's address book smarter. localAddrs := s.ListenAddresses() if len(localAddrs) == 0 { log.Debug("Dialing out with no local addresses.") } // get remote peer addrs remoteAddrs := s.peers.Addrs(p) // make sure we can use the addresses. remoteAddrs = addrutil.FilterUsableAddrs(remoteAddrs) // drop out any addrs that would just dial ourselves. use ListenAddresses // as that is a more authoritative view than localAddrs. ila, _ := s.InterfaceListenAddresses() remoteAddrs = addrutil.Subtract(remoteAddrs, ila) remoteAddrs = addrutil.Subtract(remoteAddrs, s.peers.Addrs(s.local)) log.Debugf("%s swarm dialing %s -- local:%s remote:%s", s.local, p, s.ListenAddresses(), remoteAddrs) if len(remoteAddrs) == 0 { err := errors.New("peer has no addresses") logdial["error"] = err return nil, err } // open connection to peer d := &conn.Dialer{ Dialer: manet.Dialer{ Dialer: net.Dialer{ Timeout: s.dialT, }, }, LocalPeer: s.local, LocalAddrs: localAddrs, PrivateKey: sk, } // try to get a connection to any addr connC, err := s.dialAddrs(ctx, d, p, remoteAddrs) if err != nil { logdial["error"] = err 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 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, d *conn.Dialer, p peer.ID, remoteAddrs []ma.Multiaddr) (conn.Conn, error) { // try to connect to one of the peer's known addresses. // we dial concurrently to each of the addresses, which: // * makes the process faster overall // * attempts to get the fastest connection available. // * mitigates the waste of trying bad addresses log.Debugf("%s swarm dialing %s %s", s.local, p, remoteAddrs) ctx, cancel := context.WithCancel(ctx) defer cancel() // cancel work when we exit func foundConn := make(chan struct{}) conns := make(chan conn.Conn, len(remoteAddrs)) errs := make(chan error, len(remoteAddrs)) // dialSingleAddr is used in the rate-limited async thing below. dialSingleAddr := func(addr ma.Multiaddr) { connC, err := s.dialAddr(ctx, d, p, addr) // check parent still wants our results select { case <-foundConn: if connC != nil { connC.Close() } return default: } if err != nil { errs <- err } else if connC == nil { errs <- fmt.Errorf("failed to dial %s %s", p, addr) } else { conns <- connC } } // this whole thing is in a goroutine so we can use foundConn // to end early. go func() { // rate limiting just in case. at most 10 addrs at once. limiter := ratelimit.NewRateLimiter(process.Background(), 10) limiter.Go(func(worker process.Process) { // permute addrs so we try different sets first each time. for _, i := range rand.Perm(len(remoteAddrs)) { select { case <-foundConn: // if one of them succeeded already break case <-worker.Closing(): // our context was cancelled break default: } workerAddr := remoteAddrs[i] // shadow variable to avoid race limiter.LimitedGo(func(worker process.Process) { dialSingleAddr(workerAddr) }) } }) <-ctx.Done() limiter.Close() }() // wair fot the results. exitErr := fmt.Errorf("failed to dial %s", p) for i := 0; i < len(remoteAddrs); i++ { select { case exitErr = <-errs: // log.Debug(exitErr) case connC := <-conns: // take the first + return asap close(foundConn) return connC, nil } } return nil, exitErr } func (s *Swarm) dialAddr(ctx context.Context, d *conn.Dialer, p peer.ID, addr ma.Multiaddr) (conn.Conn, error) { log.Debugf("%s swarm dialing %s %s", s.local, p, addr) connC, err := d.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() return nil, fmt.Errorf("misdial to %s through %s (got %s)", p, addr, remotep) } // 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 } // 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 conn.Conn) (*Conn, error) { 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 } return swarmC, err }