// TestFilterLoadMaxHashFuncsSize tests the MsgFilterLoad API maximum hash functions. func TestFilterLoadMaxHashFuncsSize(t *testing.T) { data := bytes.Repeat([]byte{0xff}, 10) msg := wire.NewMsgFilterLoad(data, 61, 0, 0) // Encode with latest protocol version. var buf bytes.Buffer err := msg.BtcEncode(&buf, wire.ProtocolVersion) if err == nil { t.Errorf("encode of MsgFilterLoad succeeded when it shouldn't have %v", msg) } newBuf := []byte{ 0x0a, // filter size 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, // filter 0x3d, 0x00, 0x00, 0x00, // max hash funcs 0x00, 0x00, 0x00, 0x00, // tweak 0x00, // update Type } // Decode with latest protocol version. readbuf := bytes.NewReader(newBuf) err = msg.BtcDecode(readbuf, wire.ProtocolVersion) if err == nil { t.Errorf("decode of MsgFilterLoad succeeded when it shouldn't have %v", msg) } }
// NewFilter creates a new bloom filter instance, mainly to be used by SPV // clients. The tweak parameter is a random value added to the seed value. // The false positive rate is the probability of a false positive where 1.0 is // "match everything" and zero is unachievable. Thus, providing any false // positive rates less than 0 or greater than 1 will be adjusted to the valid // range. // // For more information on what values to use for both elements and fprate, // see https://en.wikipedia.org/wiki/Bloom_filter. func NewFilter(elements, tweak uint32, fprate float64, flags wire.BloomUpdateType) *Filter { // Massage the false positive rate to sane values. if fprate > 1.0 { fprate = 1.0 } if fprate < 1e-9 { fprate = 1e-9 } // Calculate the size of the filter in bytes for the given number of // elements and false positive rate. // // Equivalent to m = -(n*ln(p) / ln(2)^2), where m is in bits. // Then clamp it to the maximum filter size and convert to bytes. dataLen := uint32(-1 * float64(elements) * math.Log(fprate) / ln2Squared) dataLen = minUint32(dataLen, wire.MaxFilterLoadFilterSize*8) / 8 // Calculate the number of hash functions based on the size of the // filter calculated above and the number of elements. // // Equivalent to k = (m/n) * ln(2) // Then clamp it to the maximum allowed hash funcs. hashFuncs := uint32(float64(dataLen*8) / float64(elements) * math.Ln2) hashFuncs = minUint32(hashFuncs, wire.MaxFilterLoadHashFuncs) data := make([]byte, dataLen) msg := wire.NewMsgFilterLoad(data, hashFuncs, tweak, flags) return &Filter{ msgFilterLoad: msg, } }
// TestFilterLoadMaxFilterSize tests the MsgFilterLoad API maximum filter size. func TestFilterLoadMaxFilterSize(t *testing.T) { data := bytes.Repeat([]byte{0xff}, 36001) msg := wire.NewMsgFilterLoad(data, 10, 0, 0) // Encode with latest protocol version. var buf bytes.Buffer err := msg.BtcEncode(&buf, wire.ProtocolVersion) if err == nil { t.Errorf("encode of MsgFilterLoad succeeded when it shouldn't "+ "have %v", msg) } // Decode with latest protocol version. readbuf := bytes.NewReader(data) err = msg.BtcDecode(readbuf, wire.ProtocolVersion) if err == nil { t.Errorf("decode of MsgFilterLoad succeeded when it shouldn't "+ "have %v", msg) } }
// TestFilterLoadCrossProtocol tests the MsgFilterLoad API when encoding with // the latest protocol version and decoding with BIP0031Version. func TestFilterLoadCrossProtocol(t *testing.T) { data := []byte{0x01, 0x02} msg := wire.NewMsgFilterLoad(data, 10, 0, 0) // Encode with latest protocol version. var buf bytes.Buffer err := msg.BtcEncode(&buf, wire.ProtocolVersion) if err != nil { t.Errorf("encode of NewMsgFilterLoad failed %v err <%v>", msg, err) } // Decode with old protocol version. var readmsg wire.MsgFilterLoad err = readmsg.BtcDecode(&buf, wire.BIP0031Version) if err == nil { t.Errorf("decode of MsgFilterLoad succeeded when it shouldn't have %v", msg) } }
// TestFilterCLearLatest tests the MsgFilterLoad API against the latest protocol // version. func TestFilterLoadLatest(t *testing.T) { pver := wire.ProtocolVersion data := []byte{0x01, 0x02} msg := wire.NewMsgFilterLoad(data, 10, 0, 0) // Ensure the command is expected value. wantCmd := "filterload" if cmd := msg.Command(); cmd != wantCmd { t.Errorf("NewMsgFilterLoad: wrong command - got %v want %v", cmd, wantCmd) } // Ensure max payload is expected value for latest protocol version. wantPayload := uint32(36012) maxPayload := msg.MaxPayloadLength(pver) if maxPayload != wantPayload { t.Errorf("MaxPayLoadLength: wrong max payload length for "+ "protocol version %d - got %v, want %v", pver, maxPayload, wantPayload) } // Test encode with latest protocol version. var buf bytes.Buffer err := msg.BtcEncode(&buf, pver) if err != nil { t.Errorf("encode of MsgFilterLoad failed %v err <%v>", msg, err) } // Test decode with latest protocol version. readmsg := wire.MsgFilterLoad{} err = readmsg.BtcDecode(&buf, pver) if err != nil { t.Errorf("decode of MsgFilterLoad failed [%v] err <%v>", buf, err) } return }
// TestPeerListeners tests that the peer listeners are called as expected. func TestPeerListeners(t *testing.T) { verack := make(chan struct{}, 1) ok := make(chan wire.Message, 20) peerCfg := &peer.Config{ Listeners: peer.MessageListeners{ OnGetAddr: func(p *peer.Peer, msg *wire.MsgGetAddr) { ok <- msg }, OnAddr: func(p *peer.Peer, msg *wire.MsgAddr) { ok <- msg }, OnPing: func(p *peer.Peer, msg *wire.MsgPing) { ok <- msg }, OnPong: func(p *peer.Peer, msg *wire.MsgPong) { ok <- msg }, OnAlert: func(p *peer.Peer, msg *wire.MsgAlert) { ok <- msg }, OnMemPool: func(p *peer.Peer, msg *wire.MsgMemPool) { ok <- msg }, OnTx: func(p *peer.Peer, msg *wire.MsgTx) { ok <- msg }, OnBlock: func(p *peer.Peer, msg *wire.MsgBlock, buf []byte) { ok <- msg }, OnInv: func(p *peer.Peer, msg *wire.MsgInv) { ok <- msg }, OnHeaders: func(p *peer.Peer, msg *wire.MsgHeaders) { ok <- msg }, OnNotFound: func(p *peer.Peer, msg *wire.MsgNotFound) { ok <- msg }, OnGetData: func(p *peer.Peer, msg *wire.MsgGetData) { ok <- msg }, OnGetBlocks: func(p *peer.Peer, msg *wire.MsgGetBlocks) { ok <- msg }, OnGetHeaders: func(p *peer.Peer, msg *wire.MsgGetHeaders) { ok <- msg }, OnFilterAdd: func(p *peer.Peer, msg *wire.MsgFilterAdd) { ok <- msg }, OnFilterClear: func(p *peer.Peer, msg *wire.MsgFilterClear) { ok <- msg }, OnFilterLoad: func(p *peer.Peer, msg *wire.MsgFilterLoad) { ok <- msg }, OnMerkleBlock: func(p *peer.Peer, msg *wire.MsgMerkleBlock) { ok <- msg }, OnVersion: func(p *peer.Peer, msg *wire.MsgVersion) { ok <- msg }, OnVerAck: func(p *peer.Peer, msg *wire.MsgVerAck) { verack <- struct{}{} }, OnReject: func(p *peer.Peer, msg *wire.MsgReject) { ok <- msg }, }, UserAgentName: "peer", UserAgentVersion: "1.0", ChainParams: &chaincfg.MainNetParams, Services: wire.SFNodeBloom, } inConn, outConn := pipe( &conn{raddr: "10.0.0.1:8333"}, &conn{raddr: "10.0.0.2:8333"}, ) inPeer := peer.NewInboundPeer(peerCfg) if err := inPeer.Connect(inConn); err != nil { t.Errorf("TestPeerListeners: unexpected err %v\n", err) return } peerCfg.Listeners = peer.MessageListeners{ OnVerAck: func(p *peer.Peer, msg *wire.MsgVerAck) { verack <- struct{}{} }, } outPeer, err := peer.NewOutboundPeer(peerCfg, "10.0.0.1:8333") if err != nil { t.Errorf("NewOutboundPeer: unexpected err %v\n", err) return } if err := outPeer.Connect(outConn); err != nil { t.Errorf("TestPeerListeners: unexpected err %v\n", err) return } for i := 0; i < 2; i++ { select { case <-verack: case <-time.After(time.Second * 1): t.Errorf("TestPeerListeners: verack timeout\n") return } } tests := []struct { listener string msg wire.Message }{ { "OnGetAddr", wire.NewMsgGetAddr(), }, { "OnAddr", wire.NewMsgAddr(), }, { "OnPing", wire.NewMsgPing(42), }, { "OnPong", wire.NewMsgPong(42), }, { "OnAlert", wire.NewMsgAlert([]byte("payload"), []byte("signature")), }, { "OnMemPool", wire.NewMsgMemPool(), }, { "OnTx", wire.NewMsgTx(), }, { "OnBlock", wire.NewMsgBlock(wire.NewBlockHeader(&wire.ShaHash{}, &wire.ShaHash{}, 1, 1)), }, { "OnInv", wire.NewMsgInv(), }, { "OnHeaders", wire.NewMsgHeaders(), }, { "OnNotFound", wire.NewMsgNotFound(), }, { "OnGetData", wire.NewMsgGetData(), }, { "OnGetBlocks", wire.NewMsgGetBlocks(&wire.ShaHash{}), }, { "OnGetHeaders", wire.NewMsgGetHeaders(), }, { "OnFilterAdd", wire.NewMsgFilterAdd([]byte{0x01}), }, { "OnFilterClear", wire.NewMsgFilterClear(), }, { "OnFilterLoad", wire.NewMsgFilterLoad([]byte{0x01}, 10, 0, wire.BloomUpdateNone), }, { "OnMerkleBlock", wire.NewMsgMerkleBlock(wire.NewBlockHeader(&wire.ShaHash{}, &wire.ShaHash{}, 1, 1)), }, // only one version message is allowed // only one verack message is allowed { "OnMsgReject", wire.NewMsgReject("block", wire.RejectDuplicate, "dupe block"), }, } t.Logf("Running %d tests", len(tests)) for _, test := range tests { // Queue the test message outPeer.QueueMessage(test.msg, nil) select { case <-ok: case <-time.After(time.Second * 1): t.Errorf("TestPeerListeners: %s timeout", test.listener) return } } inPeer.Disconnect() outPeer.Disconnect() }
// TestFilterLoadWireErrors performs negative tests against wire encode and decode // of MsgFilterLoad to confirm error paths work correctly. func TestFilterLoadWireErrors(t *testing.T) { pver := wire.ProtocolVersion pverNoFilterLoad := wire.BIP0037Version - 1 wireErr := &wire.MessageError{} baseFilter := []byte{0x01, 0x02, 0x03, 0x04} baseFilterLoad := wire.NewMsgFilterLoad(baseFilter, 10, 0, wire.BloomUpdateNone) baseFilterLoadEncoded := append([]byte{0x04}, baseFilter...) baseFilterLoadEncoded = append(baseFilterLoadEncoded, 0x00, 0x00, 0x00, 0x0a, // HashFuncs 0x00, 0x00, 0x00, 0x00, // Tweak 0x00) // Flags tests := []struct { in *wire.MsgFilterLoad // Value to encode buf []byte // Wire encoding pver uint32 // Protocol version for wire encoding max int // Max size of fixed buffer to induce errors writeErr error // Expected write error readErr error // Expected read error }{ // Latest protocol version with intentional read/write errors. // Force error in filter size. { baseFilterLoad, baseFilterLoadEncoded, pver, 0, io.ErrShortWrite, io.EOF, }, // Force error in filter. { baseFilterLoad, baseFilterLoadEncoded, pver, 1, io.ErrShortWrite, io.EOF, }, // Force error in hash funcs. { baseFilterLoad, baseFilterLoadEncoded, pver, 5, io.ErrShortWrite, io.EOF, }, // Force error in tweak. { baseFilterLoad, baseFilterLoadEncoded, pver, 9, io.ErrShortWrite, io.EOF, }, // Force error in flags. { baseFilterLoad, baseFilterLoadEncoded, pver, 13, io.ErrShortWrite, io.EOF, }, // Force error due to unsupported protocol version. { baseFilterLoad, baseFilterLoadEncoded, pverNoFilterLoad, 10, wireErr, wireErr, }, } t.Logf("Running %d tests", len(tests)) for i, test := range tests { // Encode to wire format. w := newFixedWriter(test.max) err := test.in.BtcEncode(w, test.pver) if reflect.TypeOf(err) != reflect.TypeOf(test.writeErr) { t.Errorf("BtcEncode #%d wrong error got: %v, want: %v", i, err, test.writeErr) continue } // For errors which are not of type wire.MessageError, check // them for equality. if _, ok := err.(*wire.MessageError); !ok { if err != test.writeErr { t.Errorf("BtcEncode #%d wrong error got: %v, "+ "want: %v", i, err, test.writeErr) continue } } // Decode from wire format. var msg wire.MsgFilterLoad r := newFixedReader(test.max, test.buf) err = msg.BtcDecode(r, test.pver) if reflect.TypeOf(err) != reflect.TypeOf(test.readErr) { t.Errorf("BtcDecode #%d wrong error got: %v, want: %v", i, err, test.readErr) continue } // For errors which are not of type wire.MessageError, check // them for equality. if _, ok := err.(*wire.MessageError); !ok { if err != test.readErr { t.Errorf("BtcDecode #%d wrong error got: %v, "+ "want: %v", i, err, test.readErr) continue } } } }
// TestMessage tests the Read/WriteMessage and Read/WriteMessageN API. func TestMessage(t *testing.T) { pver := wire.ProtocolVersion // Create the various types of messages to test. // MsgVersion. addrYou := &net.TCPAddr{IP: net.ParseIP("192.168.0.1"), Port: 8333} you, err := wire.NewNetAddress(addrYou, wire.SFNodeNetwork) if err != nil { t.Errorf("NewNetAddress: %v", err) } you.Timestamp = time.Time{} // Version message has zero value timestamp. addrMe := &net.TCPAddr{IP: net.ParseIP("127.0.0.1"), Port: 8333} me, err := wire.NewNetAddress(addrMe, wire.SFNodeNetwork) if err != nil { t.Errorf("NewNetAddress: %v", err) } me.Timestamp = time.Time{} // Version message has zero value timestamp. msgVersion := wire.NewMsgVersion(me, you, 123123, 0) msgVerack := wire.NewMsgVerAck() msgGetAddr := wire.NewMsgGetAddr() msgAddr := wire.NewMsgAddr() msgGetBlocks := wire.NewMsgGetBlocks(&wire.ShaHash{}) msgBlock := &blockOne msgInv := wire.NewMsgInv() msgGetData := wire.NewMsgGetData() msgNotFound := wire.NewMsgNotFound() msgTx := wire.NewMsgTx() msgPing := wire.NewMsgPing(123123) msgPong := wire.NewMsgPong(123123) msgGetHeaders := wire.NewMsgGetHeaders() msgHeaders := wire.NewMsgHeaders() msgAlert := wire.NewMsgAlert([]byte("payload"), []byte("signature")) msgMemPool := wire.NewMsgMemPool() msgFilterAdd := wire.NewMsgFilterAdd([]byte{0x01}) msgFilterClear := wire.NewMsgFilterClear() msgFilterLoad := wire.NewMsgFilterLoad([]byte{0x01}, 10, 0, wire.BloomUpdateNone) bh := wire.NewBlockHeader(&wire.ShaHash{}, &wire.ShaHash{}, 0, 0) msgMerkleBlock := wire.NewMsgMerkleBlock(bh) msgReject := wire.NewMsgReject("block", wire.RejectDuplicate, "duplicate block") tests := []struct { in wire.Message // Value to encode out wire.Message // Expected decoded value pver uint32 // Protocol version for wire encoding btcnet wire.BitcoinNet // Network to use for wire encoding bytes int // Expected num bytes read/written }{ {msgVersion, msgVersion, pver, wire.MainNet, 125}, {msgVerack, msgVerack, pver, wire.MainNet, 24}, {msgGetAddr, msgGetAddr, pver, wire.MainNet, 24}, {msgAddr, msgAddr, pver, wire.MainNet, 25}, {msgGetBlocks, msgGetBlocks, pver, wire.MainNet, 61}, {msgBlock, msgBlock, pver, wire.MainNet, 239}, {msgInv, msgInv, pver, wire.MainNet, 25}, {msgGetData, msgGetData, pver, wire.MainNet, 25}, {msgNotFound, msgNotFound, pver, wire.MainNet, 25}, {msgTx, msgTx, pver, wire.MainNet, 34}, {msgPing, msgPing, pver, wire.MainNet, 32}, {msgPong, msgPong, pver, wire.MainNet, 32}, {msgGetHeaders, msgGetHeaders, pver, wire.MainNet, 61}, {msgHeaders, msgHeaders, pver, wire.MainNet, 25}, {msgAlert, msgAlert, pver, wire.MainNet, 42}, {msgMemPool, msgMemPool, pver, wire.MainNet, 24}, {msgFilterAdd, msgFilterAdd, pver, wire.MainNet, 26}, {msgFilterClear, msgFilterClear, pver, wire.MainNet, 24}, {msgFilterLoad, msgFilterLoad, pver, wire.MainNet, 35}, {msgMerkleBlock, msgMerkleBlock, pver, wire.MainNet, 110}, {msgReject, msgReject, pver, wire.MainNet, 79}, } t.Logf("Running %d tests", len(tests)) for i, test := range tests { // Encode to wire format. var buf bytes.Buffer nw, err := wire.WriteMessageN(&buf, test.in, test.pver, test.btcnet) if err != nil { t.Errorf("WriteMessage #%d error %v", i, err) continue } // Ensure the number of bytes written match the expected value. if nw != test.bytes { t.Errorf("WriteMessage #%d unexpected num bytes "+ "written - got %d, want %d", i, nw, test.bytes) } // Decode from wire format. rbuf := bytes.NewReader(buf.Bytes()) nr, msg, _, err := wire.ReadMessageN(rbuf, test.pver, test.btcnet) if err != nil { t.Errorf("ReadMessage #%d error %v, msg %v", i, err, spew.Sdump(msg)) continue } if !reflect.DeepEqual(msg, test.out) { t.Errorf("ReadMessage #%d\n got: %v want: %v", i, spew.Sdump(msg), spew.Sdump(test.out)) continue } // Ensure the number of bytes read match the expected value. if nr != test.bytes { t.Errorf("ReadMessage #%d unexpected num bytes read - "+ "got %d, want %d", i, nr, test.bytes) } } // Do the same thing for Read/WriteMessage, but ignore the bytes since // they don't return them. t.Logf("Running %d tests", len(tests)) for i, test := range tests { // Encode to wire format. var buf bytes.Buffer err := wire.WriteMessage(&buf, test.in, test.pver, test.btcnet) if err != nil { t.Errorf("WriteMessage #%d error %v", i, err) continue } // Decode from wire format. rbuf := bytes.NewReader(buf.Bytes()) msg, _, err := wire.ReadMessage(rbuf, test.pver, test.btcnet) if err != nil { t.Errorf("ReadMessage #%d error %v, msg %v", i, err, spew.Sdump(msg)) continue } if !reflect.DeepEqual(msg, test.out) { t.Errorf("ReadMessage #%d\n got: %v want: %v", i, spew.Sdump(msg), spew.Sdump(test.out)) continue } } }