package reconnect import ( "io" "math/rand" "sync" "testing" "time" u "github.com/ipfs/go-ipfs/util" logging "github.com/ipfs/go-ipfs/vendor/go-log-v1.0.0" host "github.com/ipfs/go-libp2p/p2p/host" inet "github.com/ipfs/go-libp2p/p2p/net" swarm "github.com/ipfs/go-libp2p/p2p/net/swarm" protocol "github.com/ipfs/go-libp2p/p2p/protocol" testutil "github.com/ipfs/go-libp2p/p2p/test/util" ps "github.com/ipfs/go-ipfs/Godeps/_workspace/src/github.com/jbenet/go-peerstream" context "github.com/ipfs/go-ipfs/Godeps/_workspace/src/golang.org/x/net/context" ) func init() { // change the garbage collect timeout for testing. ps.GarbageCollectTimeout = 10 * time.Millisecond } var log = logging.Logger("reconnect") func EchoStreamHandler(stream inet.Stream) { c := stream.Conn() log.Debugf("%s echoing %s", c.LocalPeer(), c.RemotePeer()) go func() { defer stream.Close() io.Copy(stream, stream) }() } type sendChans struct { send chan struct{} sent chan struct{} read chan struct{} close_ chan struct{} closed chan struct{} } func newSendChans() sendChans { return sendChans{ send: make(chan struct{}), sent: make(chan struct{}), read: make(chan struct{}), close_: make(chan struct{}), closed: make(chan struct{}), } } func newSender() (chan sendChans, func(s inet.Stream)) { scc := make(chan sendChans) return scc, func(s inet.Stream) { sc := newSendChans() scc <- sc defer func() { s.Close() sc.closed <- struct{}{} }() buf := make([]byte, 65536) buf2 := make([]byte, 65536) u.NewTimeSeededRand().Read(buf) for { select { case <-sc.close_: return case <-sc.send: } // send a randomly sized subchunk from := rand.Intn(len(buf) / 2) to := rand.Intn(len(buf) / 2) sendbuf := buf[from : from+to] log.Debugf("sender sending %d bytes", len(sendbuf)) n, err := s.Write(sendbuf) if err != nil { log.Debug("sender error. exiting:", err) return } log.Debugf("sender wrote %d bytes", n) sc.sent <- struct{}{} if n, err = io.ReadFull(s, buf2[:len(sendbuf)]); err != nil { log.Debug("sender error. failed to read:", err) return } log.Debugf("sender read %d bytes", n) sc.read <- struct{}{} } } } // TestReconnect tests whether hosts are able to disconnect and reconnect. func TestReconnect2(t *testing.T) { ctx := context.Background() h1 := testutil.GenHostSwarm(t, ctx) h2 := testutil.GenHostSwarm(t, ctx) hosts := []host.Host{h1, h2} h1.SetStreamHandler(protocol.TestingID, EchoStreamHandler) h2.SetStreamHandler(protocol.TestingID, EchoStreamHandler) rounds := 8 if testing.Short() { rounds = 4 } for i := 0; i < rounds; i++ { log.Debugf("TestReconnect: %d/%d\n", i, rounds) SubtestConnSendDisc(t, hosts) } } // TestReconnect tests whether hosts are able to disconnect and reconnect. func TestReconnect5(t *testing.T) { ctx := context.Background() h1 := testutil.GenHostSwarm(t, ctx) h2 := testutil.GenHostSwarm(t, ctx) h3 := testutil.GenHostSwarm(t, ctx) h4 := testutil.GenHostSwarm(t, ctx) h5 := testutil.GenHostSwarm(t, ctx) hosts := []host.Host{h1, h2, h3, h4, h5} h1.SetStreamHandler(protocol.TestingID, EchoStreamHandler) h2.SetStreamHandler(protocol.TestingID, EchoStreamHandler) h3.SetStreamHandler(protocol.TestingID, EchoStreamHandler) h4.SetStreamHandler(protocol.TestingID, EchoStreamHandler) h5.SetStreamHandler(protocol.TestingID, EchoStreamHandler) rounds := 4 if testing.Short() { rounds = 2 } for i := 0; i < rounds; i++ { log.Debugf("TestReconnect: %d/%d\n", i, rounds) SubtestConnSendDisc(t, hosts) } } func SubtestConnSendDisc(t *testing.T, hosts []host.Host) { ctx := context.Background() numStreams := 3 * len(hosts) numMsgs := 10 if testing.Short() { numStreams = 5 * len(hosts) numMsgs = 4 } ss, sF := newSender() for _, h1 := range hosts { for _, h2 := range hosts { if h1.ID() >= h2.ID() { continue } h2pi := h2.Peerstore().PeerInfo(h2.ID()) log.Debugf("dialing %s", h2pi.Addrs) if err := h1.Connect(ctx, h2pi); err != nil { t.Fatalf("Failed to connect:", err) } } } var wg sync.WaitGroup for i := 0; i < numStreams; i++ { h1 := hosts[i%len(hosts)] h2 := hosts[(i+1)%len(hosts)] s, err := h1.NewStream(protocol.TestingID, h2.ID()) if err != nil { t.Error(err) } wg.Add(1) go func(j int) { defer wg.Done() go sF(s) log.Debugf("getting handle %d", j) sc := <-ss // wait to get handle. log.Debugf("spawning worker %d", j) for k := 0; k < numMsgs; k++ { sc.send <- struct{}{} <-sc.sent log.Debugf("%d sent %d", j, k) <-sc.read log.Debugf("%d read %d", j, k) } sc.close_ <- struct{}{} <-sc.closed log.Debugf("closed %d", j) }(i) } wg.Wait() for i, h1 := range hosts { log.Debugf("host %d has %d conns", i, len(h1.Network().Conns())) } for _, h1 := range hosts { // close connection cs := h1.Network().Conns() for _, c := range cs { sc := c.(*swarm.Conn) if sc.LocalPeer() > sc.RemotePeer() { continue // only close it on one side. } log.Debugf("closing: %s", sc.RawConn()) sc.Close() } } <-time.After(20 * time.Millisecond) for i, h := range hosts { if len(h.Network().Conns()) > 0 { t.Fatalf("host %d %s has %d conns! not zero.", i, h.ID(), len(h.Network().Conns())) } } }