package discover import ( "bytes" "crypto/ecdsa" "errors" "fmt" "io" logpkg "log" "net" "os" "reflect" "runtime" "sync" "testing" "time" "github.com/ethereum/go-ethereum/crypto" "github.com/ethereum/go-ethereum/logger" "path/filepath" ) func init() { logger.AddLogSystem(logger.NewStdLogSystem(os.Stdout, logpkg.LstdFlags, logger.ErrorLevel)) } // shared test variables var ( futureExp = uint64(time.Now().Add(10 * time.Hour).Unix()) testTarget = NodeID{0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1} testRemote = rpcEndpoint{IP: net.ParseIP("1.1.1.1").To4(), UDP: 1, TCP: 2} testLocalAnnounced = rpcEndpoint{IP: net.ParseIP("2.2.2.2").To4(), UDP: 3, TCP: 4} testLocal = rpcEndpoint{IP: net.ParseIP("3.3.3.3").To4(), UDP: 5, TCP: 6} ) type udpTest struct { t *testing.T pipe *dgramPipe table *Table udp *udp sent [][]byte localkey, remotekey *ecdsa.PrivateKey remoteaddr *net.UDPAddr } func newUDPTest(t *testing.T) *udpTest { test := &udpTest{ t: t, pipe: newpipe(), localkey: newkey(), remotekey: newkey(), remoteaddr: &net.UDPAddr{IP: net.IP{1, 2, 3, 4}, Port: 30303}, } test.table, test.udp = newUDP(test.localkey, test.pipe, nil, "") return test } // handles a packet as if it had been sent to the transport. func (test *udpTest) packetIn(wantError error, ptype byte, data packet) error { enc, err := encodePacket(test.remotekey, ptype, data) if err != nil { return test.errorf("packet (%d) encode error: %v", err) } test.sent = append(test.sent, enc) if err = test.udp.handlePacket(test.remoteaddr, enc); err != wantError { return test.errorf("error mismatch: got %q, want %q", err, wantError) } return nil } // waits for a packet to be sent by the transport. // validate should have type func(*udpTest, X) error, where X is a packet type. func (test *udpTest) waitPacketOut(validate interface{}) error { dgram := test.pipe.waitPacketOut() p, _, _, err := decodePacket(dgram) if err != nil { return test.errorf("sent packet decode error: %v", err) } fn := reflect.ValueOf(validate) exptype := fn.Type().In(0) if reflect.TypeOf(p) != exptype { return test.errorf("sent packet type mismatch, got: %v, want: %v", reflect.TypeOf(p), exptype) } fn.Call([]reflect.Value{reflect.ValueOf(p)}) return nil } func (test *udpTest) errorf(format string, args ...interface{}) error { _, file, line, ok := runtime.Caller(2) // errorf + waitPacketOut if ok { file = filepath.Base(file) } else { file = "???" line = 1 } err := fmt.Errorf(format, args...) fmt.Printf("\t%s:%d: %v\n", file, line, err) test.t.Fail() return err } func TestUDP_packetErrors(t *testing.T) { test := newUDPTest(t) defer test.table.Close() test.packetIn(errExpired, pingPacket, &ping{From: testRemote, To: testLocalAnnounced, Version: Version}) test.packetIn(errBadVersion, pingPacket, &ping{From: testRemote, To: testLocalAnnounced, Version: 99, Expiration: futureExp}) test.packetIn(errUnsolicitedReply, pongPacket, &pong{ReplyTok: []byte{}, Expiration: futureExp}) test.packetIn(errUnknownNode, findnodePacket, &findnode{Expiration: futureExp}) test.packetIn(errUnsolicitedReply, neighborsPacket, &neighbors{Expiration: futureExp}) } func TestUDP_pingTimeout(t *testing.T) { t.Parallel() test := newUDPTest(t) defer test.table.Close() toaddr := &net.UDPAddr{IP: net.ParseIP("1.2.3.4"), Port: 2222} toid := NodeID{1, 2, 3, 4} if err := test.udp.ping(toid, toaddr); err != errTimeout { t.Error("expected timeout error, got", err) } } func TestUDP_findnodeTimeout(t *testing.T) { t.Parallel() test := newUDPTest(t) defer test.table.Close() toaddr := &net.UDPAddr{IP: net.ParseIP("1.2.3.4"), Port: 2222} toid := NodeID{1, 2, 3, 4} target := NodeID{4, 5, 6, 7} result, err := test.udp.findnode(toid, toaddr, target) if err != errTimeout { t.Error("expected timeout error, got", err) } if len(result) > 0 { t.Error("expected empty result, got", result) } } func TestUDP_findnode(t *testing.T) { test := newUDPTest(t) defer test.table.Close() // put a few nodes into the table. their exact // distribution shouldn't matter much, altough we need to // take care not to overflow any bucket. targetHash := crypto.Sha3Hash(testTarget[:]) nodes := &nodesByDistance{target: targetHash} for i := 0; i < bucketSize; i++ { nodes.push(nodeAtDistance(test.table.self.sha, i+2), bucketSize) } test.table.add(nodes.entries) // ensure there's a bond with the test node, // findnode won't be accepted otherwise. test.table.db.updateNode(newNode( PubkeyID(&test.remotekey.PublicKey), test.remoteaddr.IP, uint16(test.remoteaddr.Port), 99, )) // check that closest neighbors are returned. test.packetIn(nil, findnodePacket, &findnode{Target: testTarget, Expiration: futureExp}) test.waitPacketOut(func(p *neighbors) { expected := test.table.closest(targetHash, bucketSize) if len(p.Nodes) != bucketSize { t.Errorf("wrong number of results: got %d, want %d", len(p.Nodes), bucketSize) } for i := range p.Nodes { if p.Nodes[i].ID != expected.entries[i].ID { t.Errorf("result mismatch at %d:\n got: %v\n want: %v", i, p.Nodes[i], expected.entries[i]) } } }) } func TestUDP_findnodeMultiReply(t *testing.T) { test := newUDPTest(t) defer test.table.Close() // queue a pending findnode request resultc, errc := make(chan []*Node), make(chan error) go func() { rid := PubkeyID(&test.remotekey.PublicKey) ns, err := test.udp.findnode(rid, test.remoteaddr, testTarget) if err != nil && len(ns) == 0 { errc <- err } else { resultc <- ns } }() // wait for the findnode to be sent. // after it is sent, the transport is waiting for a reply test.waitPacketOut(func(p *findnode) { if p.Target != testTarget { t.Errorf("wrong target: got %v, want %v", p.Target, testTarget) } }) // send the reply as two packets. list := []*Node{ MustParseNode("enode://ba85011c70bcc5c04d8607d3a0ed29aa6179c092cbdda10d5d32684fb33ed01bd94f588ca8f91ac48318087dcb02eaf36773a7a453f0eedd6742af668097b29c@10.0.1.16:30303?discport=30304"), MustParseNode("enode://81fa361d25f157cd421c60dcc28d8dac5ef6a89476633339c5df30287474520caca09627da18543d9079b5b288698b542d56167aa5c09111e55acdbbdf2ef799@10.0.1.16:30303"), MustParseNode("enode://9bffefd833d53fac8e652415f4973bee289e8b1a5c6c4cbe70abf817ce8a64cee11b823b66a987f51aaa9fba0d6a91b3e6bf0d5a5d1042de8e9eeea057b217f8@10.0.1.36:30301?discport=17"), MustParseNode("enode://1b5b4aa662d7cb44a7221bfba67302590b643028197a7d5214790f3bac7aaa4a3241be9e83c09cf1f6c69d007c634faae3dc1b1221793e8446c0b3a09de65960@10.0.1.16:30303"), } rpclist := make([]rpcNode, len(list)) for i := range list { rpclist[i] = nodeToRPC(list[i]) } test.packetIn(nil, neighborsPacket, &neighbors{Expiration: futureExp, Nodes: rpclist[:2]}) test.packetIn(nil, neighborsPacket, &neighbors{Expiration: futureExp, Nodes: rpclist[2:]}) // check that the sent neighbors are all returned by findnode select { case result := <-resultc: if !reflect.DeepEqual(result, list) { t.Errorf("neighbors mismatch:\n got: %v\n want: %v", result, list) } case err := <-errc: t.Errorf("findnode error: %v", err) case <-time.After(5 * time.Second): t.Error("findnode did not return within 5 seconds") } } func TestUDP_successfulPing(t *testing.T) { test := newUDPTest(t) defer test.table.Close() done := make(chan struct{}) go func() { // The remote side sends a ping packet to initiate the exchange. test.packetIn(nil, pingPacket, &ping{From: testRemote, To: testLocalAnnounced, Version: Version, Expiration: futureExp}) close(done) }() // the ping is replied to. test.waitPacketOut(func(p *pong) { pinghash := test.sent[0][:macSize] if !bytes.Equal(p.ReplyTok, pinghash) { t.Errorf("got pong.ReplyTok %x, want %x", p.ReplyTok, pinghash) } wantTo := rpcEndpoint{ // The mirrored UDP address is the UDP packet sender IP: test.remoteaddr.IP, UDP: uint16(test.remoteaddr.Port), // The mirrored TCP port is the one from the ping packet TCP: testRemote.TCP, } if !reflect.DeepEqual(p.To, wantTo) { t.Errorf("got pong.To %v, want %v", p.To, wantTo) } }) // remote is unknown, the table pings back. test.waitPacketOut(func(p *ping) error { if !reflect.DeepEqual(p.From, test.udp.ourEndpoint) { t.Errorf("got ping.From %v, want %v", p.From, test.udp.ourEndpoint) } wantTo := rpcEndpoint{ // The mirrored UDP address is the UDP packet sender. IP: test.remoteaddr.IP, UDP: uint16(test.remoteaddr.Port), TCP: 0, } if !reflect.DeepEqual(p.To, wantTo) { t.Errorf("got ping.To %v, want %v", p.To, wantTo) } return nil }) test.packetIn(nil, pongPacket, &pong{Expiration: futureExp}) // ping should return shortly after getting the pong packet. <-done // check that the node was added. rid := PubkeyID(&test.remotekey.PublicKey) rnode := find(test.table, rid) if rnode == nil { t.Fatalf("node %v not found in table", rid) } if !bytes.Equal(rnode.IP, test.remoteaddr.IP) { t.Errorf("node has wrong IP: got %v, want: %v", rnode.IP, test.remoteaddr.IP) } if int(rnode.UDP) != test.remoteaddr.Port { t.Errorf("node has wrong UDP port: got %v, want: %v", rnode.UDP, test.remoteaddr.Port) } if rnode.TCP != testRemote.TCP { t.Errorf("node has wrong TCP port: got %v, want: %v", rnode.TCP, testRemote.TCP) } } func find(tab *Table, id NodeID) *Node { for _, b := range tab.buckets { for _, e := range b.entries { if e.ID == id { return e } } } return nil } // dgramPipe is a fake UDP socket. It queues all sent datagrams. type dgramPipe struct { mu *sync.Mutex cond *sync.Cond closing chan struct{} closed bool queue [][]byte } func newpipe() *dgramPipe { mu := new(sync.Mutex) return &dgramPipe{ closing: make(chan struct{}), cond: &sync.Cond{L: mu}, mu: mu, } } // WriteToUDP queues a datagram. func (c *dgramPipe) WriteToUDP(b []byte, to *net.UDPAddr) (n int, err error) { msg := make([]byte, len(b)) copy(msg, b) c.mu.Lock() defer c.mu.Unlock() if c.closed { return 0, errors.New("closed") } c.queue = append(c.queue, msg) c.cond.Signal() return len(b), nil } // ReadFromUDP just hangs until the pipe is closed. func (c *dgramPipe) ReadFromUDP(b []byte) (n int, addr *net.UDPAddr, err error) { <-c.closing return 0, nil, io.EOF } func (c *dgramPipe) Close() error { c.mu.Lock() defer c.mu.Unlock() if !c.closed { close(c.closing) c.closed = true } return nil } func (c *dgramPipe) LocalAddr() net.Addr { return &net.UDPAddr{IP: testLocal.IP, Port: int(testLocal.UDP)} } func (c *dgramPipe) waitPacketOut() []byte { c.mu.Lock() defer c.mu.Unlock() for len(c.queue) == 0 { c.cond.Wait() } p := c.queue[0] copy(c.queue, c.queue[1:]) c.queue = c.queue[:len(c.queue)-1] return p }