package p2p import ( "bytes" "sync" "testing" "time" "github.com/tendermint/tendermint/binary" . "github.com/tendermint/tendermint/common" "github.com/tendermint/tendermint/types" ) type PeerMessage struct { PeerKey string Bytes []byte Counter int } type TestReactor struct { mtx sync.Mutex channels []*ChannelDescriptor peersAdded []*Peer peersRemoved []*Peer logMessages bool msgsCounter int msgsReceived map[byte][]PeerMessage } func NewTestReactor(channels []*ChannelDescriptor, logMessages bool) *TestReactor { return &TestReactor{ channels: channels, logMessages: logMessages, msgsReceived: make(map[byte][]PeerMessage), } } func (tr *TestReactor) Start(sw *Switch) { } func (tr *TestReactor) Stop() { } func (tr *TestReactor) GetChannels() []*ChannelDescriptor { return tr.channels } func (tr *TestReactor) AddPeer(peer *Peer) { tr.mtx.Lock() defer tr.mtx.Unlock() tr.peersAdded = append(tr.peersAdded, peer) } func (tr *TestReactor) RemovePeer(peer *Peer, reason interface{}) { tr.mtx.Lock() defer tr.mtx.Unlock() tr.peersRemoved = append(tr.peersRemoved, peer) } func (tr *TestReactor) Receive(chId byte, peer *Peer, msgBytes []byte) { if tr.logMessages { tr.mtx.Lock() defer tr.mtx.Unlock() //fmt.Printf("Received: %X, %X\n", chId, msgBytes) tr.msgsReceived[chId] = append(tr.msgsReceived[chId], PeerMessage{peer.Key, msgBytes, tr.msgsCounter}) tr.msgsCounter++ } } //----------------------------------------------------------------------------- // convenience method for creating two switches connected to each other. func makeSwitchPair(t testing.TB, initSwitch func(*Switch) *Switch) (*Switch, *Switch) { // Create two switches that will be interconnected. s1 := initSwitch(NewSwitch()) s1.SetNodeInfo(&types.NodeInfo{ Moniker: "switch1", Network: "testing", }) s2 := initSwitch(NewSwitch()) s2.SetNodeInfo(&types.NodeInfo{ Moniker: "switch2", Network: "testing", }) // Start switches s1.Start() s2.Start() // Create a listener for s1 l := NewDefaultListener("tcp", ":8001", true) // Dial the listener & add the connection to s2. lAddr := l.ExternalAddress() connOut, err := lAddr.Dial() if err != nil { t.Fatalf("Could not connect to listener address %v", lAddr) } else { t.Logf("Created a connection to listener address %v", lAddr) } connIn, ok := <-l.Connections() if !ok { t.Fatalf("Could not get inbound connection from listener") } go s1.AddPeerWithConnection(connIn, false) // AddPeer is blocking, requires handshake. s2.AddPeerWithConnection(connOut, true) // Wait for things to happen, peers to get added... time.Sleep(100 * time.Millisecond) // Close the server, no longer needed. l.Stop() return s1, s2 } func TestSwitches(t *testing.T) { s1, s2 := makeSwitchPair(t, func(sw *Switch) *Switch { // Make two reactors of two channels each sw.AddReactor("foo", NewTestReactor([]*ChannelDescriptor{ &ChannelDescriptor{Id: byte(0x00), Priority: 10}, &ChannelDescriptor{Id: byte(0x01), Priority: 10}, }, true)).Start(sw) // Start the reactor sw.AddReactor("bar", NewTestReactor([]*ChannelDescriptor{ &ChannelDescriptor{Id: byte(0x02), Priority: 10}, &ChannelDescriptor{Id: byte(0x03), Priority: 10}, }, true)).Start(sw) // Start the reactor return sw }) defer s1.Stop() defer s2.Stop() // Lets send a message from s1 to s2. if s1.Peers().Size() != 1 { t.Errorf("Expected exactly 1 peer in s1, got %v", s1.Peers().Size()) } if s2.Peers().Size() != 1 { t.Errorf("Expected exactly 1 peer in s2, got %v", s2.Peers().Size()) } ch0Msg := "channel zero" ch1Msg := "channel foo" ch2Msg := "channel bar" s1.Broadcast(byte(0x00), ch0Msg) s1.Broadcast(byte(0x01), ch1Msg) s1.Broadcast(byte(0x02), ch2Msg) // Wait for things to settle... time.Sleep(5000 * time.Millisecond) // Check message on ch0 ch0Msgs := s2.Reactor("foo").(*TestReactor).msgsReceived[byte(0x00)] if len(ch0Msgs) != 1 { t.Errorf("Expected to have received 1 message in ch0") } if !bytes.Equal(ch0Msgs[0].Bytes, binary.BinaryBytes(ch0Msg)) { t.Errorf("Unexpected message bytes. Wanted: %X, Got: %X", binary.BinaryBytes(ch0Msg), ch0Msgs[0].Bytes) } // Check message on ch1 ch1Msgs := s2.Reactor("foo").(*TestReactor).msgsReceived[byte(0x01)] if len(ch1Msgs) != 1 { t.Errorf("Expected to have received 1 message in ch1") } if !bytes.Equal(ch1Msgs[0].Bytes, binary.BinaryBytes(ch1Msg)) { t.Errorf("Unexpected message bytes. Wanted: %X, Got: %X", binary.BinaryBytes(ch1Msg), ch1Msgs[0].Bytes) } // Check message on ch2 ch2Msgs := s2.Reactor("bar").(*TestReactor).msgsReceived[byte(0x02)] if len(ch2Msgs) != 1 { t.Errorf("Expected to have received 1 message in ch2") } if !bytes.Equal(ch2Msgs[0].Bytes, binary.BinaryBytes(ch2Msg)) { t.Errorf("Unexpected message bytes. Wanted: %X, Got: %X", binary.BinaryBytes(ch2Msg), ch2Msgs[0].Bytes) } } func BenchmarkSwitches(b *testing.B) { b.StopTimer() s1, s2 := makeSwitchPair(b, func(sw *Switch) *Switch { // Make bar reactors of bar channels each sw.AddReactor("foo", NewTestReactor([]*ChannelDescriptor{ &ChannelDescriptor{Id: byte(0x00), Priority: 10}, &ChannelDescriptor{Id: byte(0x01), Priority: 10}, }, false)) sw.AddReactor("bar", NewTestReactor([]*ChannelDescriptor{ &ChannelDescriptor{Id: byte(0x02), Priority: 10}, &ChannelDescriptor{Id: byte(0x03), Priority: 10}, }, false)) return sw }) defer s1.Stop() defer s2.Stop() // Allow time for goroutines to boot up time.Sleep(1000 * time.Millisecond) b.StartTimer() numSuccess, numFailure := 0, 0 // Send random message from foo channel to another for i := 0; i < b.N; i++ { chId := byte(i % 4) successChan := s1.Broadcast(chId, "test data") for s := range successChan { if s { numSuccess += 1 } else { numFailure += 1 } } } log.Warn(Fmt("success: %v, failure: %v", numSuccess, numFailure)) // Allow everything to flush before stopping switches & closing connections. b.StopTimer() time.Sleep(1000 * time.Millisecond) }