package lnwire import ( "bytes" crand "crypto/rand" "encoding/binary" "encoding/hex" "fmt" "image/color" "io" "math" "math/rand" "net" "reflect" "testing" "testing/quick" "time" "github.com/btcsuite/btcd/btcec/v2" "github.com/btcsuite/btcd/btcec/v2/ecdsa" "github.com/btcsuite/btcd/btcutil" "github.com/btcsuite/btcd/chaincfg" "github.com/btcsuite/btcd/chaincfg/chainhash" "github.com/btcsuite/btcd/wire" "github.com/lightningnetwork/lnd/fn" "github.com/lightningnetwork/lnd/lnwallet/chainfee" "github.com/lightningnetwork/lnd/tlv" "github.com/lightningnetwork/lnd/tor" "github.com/stretchr/testify/assert" "github.com/stretchr/testify/require" ) var ( shaHash1Bytes, _ = hex.DecodeString("e3b0c44298fc1c149afbf4c8996fb" + "92427ae41e4649b934ca495991b7852b855") shaHash1, _ = chainhash.NewHash(shaHash1Bytes) outpoint1 = wire.NewOutPoint(shaHash1, 0) testRBytes, _ = hex.DecodeString("8ce2bc69281ce27da07e6683571" + "319d18e949ddfa2965fb6caa1bf0314f882d7") testSBytes, _ = hex.DecodeString("299105481d63e0f4bc2a" + "88121167221b6700d72a0ead154c03be696a292d24ae") testRScalar = new(btcec.ModNScalar) testSScalar = new(btcec.ModNScalar) _ = testRScalar.SetByteSlice(testRBytes) _ = testSScalar.SetByteSlice(testSBytes) testSig = ecdsa.NewSignature(testRScalar, testSScalar) testSchnorrSigStr, _ = hex.DecodeString("04E7F9037658A92AFEB4F2" + "5BAE5339E3DDCA81A353493827D26F16D92308E49E2A25E9220867" + "8A2DF86970DA91B03A8AF8815A8A60498B358DAF560B347AA557") testSchnorrSig, _ = NewSigFromSchnorrRawSignature(testSchnorrSigStr) ) const letterBytes = "abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ" func randLocalNonce(r *rand.Rand) Musig2Nonce { var nonce Musig2Nonce _, _ = io.ReadFull(r, nonce[:]) return nonce } func someLocalNonce[T tlv.TlvType]( r *rand.Rand) tlv.OptionalRecordT[T, Musig2Nonce] { return tlv.SomeRecordT(tlv.NewRecordT[T, Musig2Nonce]( randLocalNonce(r), )) } func randPartialSig(r *rand.Rand) (*PartialSig, error) { var sigBytes [32]byte if _, err := r.Read(sigBytes[:]); err != nil { return nil, fmt.Errorf("unable to generate sig: %w", err) } var s btcec.ModNScalar s.SetByteSlice(sigBytes[:]) return &PartialSig{ Sig: s, }, nil } func somePartialSig(t *testing.T, r *rand.Rand) tlv.OptionalRecordT[PartialSigType, PartialSig] { sig, err := randPartialSig(r) if err != nil { t.Fatal(err) } return tlv.SomeRecordT(tlv.NewRecordT[PartialSigType, PartialSig]( *sig, )) } func randPartialSigWithNonce(r *rand.Rand) (*PartialSigWithNonce, error) { var sigBytes [32]byte if _, err := r.Read(sigBytes[:]); err != nil { return nil, fmt.Errorf("unable to generate sig: %w", err) } var s btcec.ModNScalar s.SetByteSlice(sigBytes[:]) return &PartialSigWithNonce{ PartialSig: NewPartialSig(s), Nonce: randLocalNonce(r), }, nil } func somePartialSigWithNonce(t *testing.T, r *rand.Rand) OptPartialSigWithNonceTLV { sig, err := randPartialSigWithNonce(r) if err != nil { t.Fatal(err) } return tlv.SomeRecordT( tlv.NewRecordT[PartialSigWithNonceType, PartialSigWithNonce]( *sig, ), ) } func randAlias(r *rand.Rand) NodeAlias { var a NodeAlias for i := range a { a[i] = letterBytes[r.Intn(len(letterBytes))] } return a } func randPubKey() (*btcec.PublicKey, error) { priv, err := btcec.NewPrivateKey() if err != nil { return nil, err } return priv.PubKey(), nil } // pubkeyFromHex parses a Bitcoin public key from a hex encoded string. func pubkeyFromHex(keyHex string) (*btcec.PublicKey, error) { pubKeyBytes, err := hex.DecodeString(keyHex) if err != nil { return nil, err } return btcec.ParsePubKey(pubKeyBytes) } // generateRandomBytes returns a slice of n random bytes. func generateRandomBytes(n int) ([]byte, error) { b := make([]byte, n) _, err := crand.Read(b) if err != nil { return nil, err } return b, nil } func randRawKey(t *testing.T) [33]byte { var n [33]byte priv, err := btcec.NewPrivateKey() require.NoError(t, err) copy(n[:], priv.PubKey().SerializeCompressed()) return n } func randDeliveryAddress(r *rand.Rand) (DeliveryAddress, error) { // Generate size minimum one. Empty scripts should be tested specifically. size := r.Intn(deliveryAddressMaxSize) + 1 da := DeliveryAddress(make([]byte, size)) _, err := r.Read(da) return da, err } func randRawFeatureVector(r *rand.Rand) *RawFeatureVector { featureVec := NewRawFeatureVector() for i := 0; i < 10000; i++ { if r.Int31n(2) == 0 { featureVec.Set(FeatureBit(i)) } } return featureVec } func randTCP4Addr(r *rand.Rand) (*net.TCPAddr, error) { var ip [4]byte if _, err := r.Read(ip[:]); err != nil { return nil, err } var port [2]byte if _, err := r.Read(port[:]); err != nil { return nil, err } addrIP := net.IP(ip[:]) addrPort := int(binary.BigEndian.Uint16(port[:])) return &net.TCPAddr{IP: addrIP, Port: addrPort}, nil } func randTCP6Addr(r *rand.Rand) (*net.TCPAddr, error) { var ip [16]byte if _, err := r.Read(ip[:]); err != nil { return nil, err } var port [2]byte if _, err := r.Read(port[:]); err != nil { return nil, err } addrIP := net.IP(ip[:]) addrPort := int(binary.BigEndian.Uint16(port[:])) return &net.TCPAddr{IP: addrIP, Port: addrPort}, nil } func randV2OnionAddr(r *rand.Rand) (*tor.OnionAddr, error) { var serviceID [tor.V2DecodedLen]byte if _, err := r.Read(serviceID[:]); err != nil { return nil, err } var port [2]byte if _, err := r.Read(port[:]); err != nil { return nil, err } onionService := tor.Base32Encoding.EncodeToString(serviceID[:]) onionService += tor.OnionSuffix addrPort := int(binary.BigEndian.Uint16(port[:])) return &tor.OnionAddr{OnionService: onionService, Port: addrPort}, nil } func randV3OnionAddr(r *rand.Rand) (*tor.OnionAddr, error) { var serviceID [tor.V3DecodedLen]byte if _, err := r.Read(serviceID[:]); err != nil { return nil, err } var port [2]byte if _, err := r.Read(port[:]); err != nil { return nil, err } onionService := tor.Base32Encoding.EncodeToString(serviceID[:]) onionService += tor.OnionSuffix addrPort := int(binary.BigEndian.Uint16(port[:])) return &tor.OnionAddr{OnionService: onionService, Port: addrPort}, nil } func randOpaqueAddr(r *rand.Rand) (*OpaqueAddrs, error) { payloadLen := r.Int63n(64) + 1 payload := make([]byte, payloadLen) // The first byte is the address type. So set it to one that we // definitely don't know about. payload[0] = math.MaxUint8 // Generate random bytes for the rest of the payload. if _, err := r.Read(payload[1:]); err != nil { return nil, err } return &OpaqueAddrs{Payload: payload}, nil } func randAddrs(r *rand.Rand) ([]net.Addr, error) { tcp4Addr, err := randTCP4Addr(r) if err != nil { return nil, err } tcp6Addr, err := randTCP6Addr(r) if err != nil { return nil, err } v2OnionAddr, err := randV2OnionAddr(r) if err != nil { return nil, err } v3OnionAddr, err := randV3OnionAddr(r) if err != nil { return nil, err } opaqueAddrs, err := randOpaqueAddr(r) if err != nil { return nil, err } return []net.Addr{ tcp4Addr, tcp6Addr, v2OnionAddr, v3OnionAddr, opaqueAddrs, }, nil } // TestChanUpdateChanFlags ensures that converting the ChanUpdateChanFlags and // ChanUpdateMsgFlags bitfields to a string behaves as expected. func TestChanUpdateChanFlags(t *testing.T) { t.Parallel() testCases := []struct { flags uint8 expected string }{ { flags: 0, expected: "00000000", }, { flags: 1, expected: "00000001", }, { flags: 3, expected: "00000011", }, { flags: 255, expected: "11111111", }, } for _, test := range testCases { chanFlag := ChanUpdateChanFlags(test.flags) toStr := chanFlag.String() if toStr != test.expected { t.Fatalf("expected %v, got %v", test.expected, toStr) } msgFlag := ChanUpdateMsgFlags(test.flags) toStr = msgFlag.String() if toStr != test.expected { t.Fatalf("expected %v, got %v", test.expected, toStr) } } } // TestDecodeUnknownAddressType shows that an unknown address type is currently // incorrectly dealt with. func TestDecodeUnknownAddressType(t *testing.T) { // Add a normal, clearnet address. tcpAddr := &net.TCPAddr{ IP: net.IP{127, 0, 0, 1}, Port: 8080, } // Add an onion address. onionAddr := &tor.OnionAddr{ OnionService: "abcdefghijklmnop.onion", Port: 9065, } // Now add an address with an unknown type. var newAddrType addressType = math.MaxUint8 data := make([]byte, 0, 16) data = append(data, uint8(newAddrType)) opaqueAddrs := &OpaqueAddrs{ Payload: data, } buffer := bytes.NewBuffer(make([]byte, 0, MaxMsgBody)) err := WriteNetAddrs( buffer, []net.Addr{tcpAddr, onionAddr, opaqueAddrs}, ) require.NoError(t, err) // Now we attempt to parse the bytes and assert that we get an error. var addrs []net.Addr err = ReadElement(buffer, &addrs) require.NoError(t, err) require.Len(t, addrs, 3) require.Equal(t, tcpAddr.String(), addrs[0].String()) require.Equal(t, onionAddr.String(), addrs[1].String()) require.Equal(t, hex.EncodeToString(data), addrs[2].String()) } func TestMaxOutPointIndex(t *testing.T) { t.Parallel() op := wire.OutPoint{ Index: math.MaxUint32, } var b bytes.Buffer if err := WriteOutPoint(&b, op); err == nil { t.Fatalf("write of outPoint should fail, index exceeds 16-bits") } } func TestEmptyMessageUnknownType(t *testing.T) { t.Parallel() fakeType := CustomTypeStart - 1 if _, err := makeEmptyMessage(fakeType); err == nil { t.Fatalf("should not be able to make an empty message of an " + "unknown type") } } // randCustomRecords generates a random set of custom records for testing. func randCustomRecords(t *testing.T, r *rand.Rand) CustomRecords { var ( customRecords = CustomRecords{} // We'll generate a random number of records, between 1 and 10. numRecords = r.Intn(9) + 1 ) // For each record, we'll generate a random key and value. for i := 0; i < numRecords; i++ { // Keys must be equal to or greater than // MinCustomRecordsTlvType. keyOffset := uint64(r.Intn(100)) key := MinCustomRecordsTlvType + keyOffset // Values are byte slices of any length. value := make([]byte, r.Intn(10)) _, err := r.Read(value) require.NoError(t, err) customRecords[key] = value } // Validate the custom records as a sanity check. err := customRecords.Validate() require.NoError(t, err) return customRecords } // TestLightningWireProtocol uses the testing/quick package to create a series // of fuzz tests to attempt to break a primary scenario which is implemented as // property based testing scenario. func TestLightningWireProtocol(t *testing.T) { t.Parallel() // mainScenario is the primary test that will programmatically be // executed for all registered wire messages. The quick-checker within // testing/quick will attempt to find an input to this function, s.t // the function returns false, if so then we've found an input that // violates our model of the system. mainScenario := func(msg Message) bool { // Give a new message, we'll serialize the message into a new // bytes buffer. var b bytes.Buffer if _, err := WriteMessage(&b, msg, 0); err != nil { t.Fatalf("unable to write msg: %v", err) return false } // Next, we'll ensure that the serialized payload (subtracting // the 2 bytes for the message type) is _below_ the specified // max payload size for this message. payloadLen := uint32(b.Len()) - 2 if payloadLen > MaxMsgBody { t.Fatalf("msg payload constraint violated: %v > %v", payloadLen, MaxMsgBody) return false } // Finally, we'll deserialize the message from the written // buffer, and finally assert that the messages are equal. newMsg, err := ReadMessage(&b, 0) if err != nil { t.Fatalf("unable to read msg: %v", err) return false } if !assert.Equalf(t, msg, newMsg, "message mismatch") { return false } return true } // customTypeGen is a map of functions that are able to randomly // generate a given type. These functions are needed for types which // are too complex for the testing/quick package to automatically // generate. customTypeGen := map[MessageType]func([]reflect.Value, *rand.Rand){ MsgStfu: func(v []reflect.Value, r *rand.Rand) { req := Stfu{} if _, err := r.Read(req.ChanID[:]); err != nil { t.Fatalf("unable to generate ChanID: %v", err) } // 1/2 chance of being initiator req.Initiator = r.Intn(2) == 1 // 1/2 chance additional TLV data. if r.Intn(2) == 0 { req.ExtraData = []byte{0xfd, 0x00, 0xff, 0x00} } v[0] = reflect.ValueOf(req) }, MsgInit: func(v []reflect.Value, r *rand.Rand) { req := NewInitMessage( randRawFeatureVector(r), randRawFeatureVector(r), ) v[0] = reflect.ValueOf(*req) }, MsgOpenChannel: func(v []reflect.Value, r *rand.Rand) { req := OpenChannel{ FundingAmount: btcutil.Amount(r.Int63()), PushAmount: MilliSatoshi(r.Int63()), DustLimit: btcutil.Amount(r.Int63()), MaxValueInFlight: MilliSatoshi(r.Int63()), ChannelReserve: btcutil.Amount(r.Int63()), HtlcMinimum: MilliSatoshi(r.Int31()), FeePerKiloWeight: uint32(r.Int63()), CsvDelay: uint16(r.Int31()), MaxAcceptedHTLCs: uint16(r.Int31()), ChannelFlags: FundingFlag(uint8(r.Int31())), } if _, err := r.Read(req.ChainHash[:]); err != nil { t.Fatalf("unable to generate chain hash: %v", err) return } if _, err := r.Read(req.PendingChannelID[:]); err != nil { t.Fatalf("unable to generate pending chan id: %v", err) return } var err error req.FundingKey, err = randPubKey() if err != nil { t.Fatalf("unable to generate key: %v", err) return } req.RevocationPoint, err = randPubKey() if err != nil { t.Fatalf("unable to generate key: %v", err) return } req.PaymentPoint, err = randPubKey() if err != nil { t.Fatalf("unable to generate key: %v", err) return } req.DelayedPaymentPoint, err = randPubKey() if err != nil { t.Fatalf("unable to generate key: %v", err) return } req.HtlcPoint, err = randPubKey() if err != nil { t.Fatalf("unable to generate key: %v", err) return } req.FirstCommitmentPoint, err = randPubKey() if err != nil { t.Fatalf("unable to generate key: %v", err) return } // 1/2 chance empty TLV records. if r.Intn(2) == 0 { req.UpfrontShutdownScript, err = randDeliveryAddress(r) if err != nil { t.Fatalf("unable to generate delivery address: %v", err) return } req.ChannelType = new(ChannelType) *req.ChannelType = ChannelType(*randRawFeatureVector(r)) req.LeaseExpiry = new(LeaseExpiry) *req.LeaseExpiry = LeaseExpiry(1337) //nolint:lll req.LocalNonce = someLocalNonce[NonceRecordTypeT](r) } else { req.UpfrontShutdownScript = []byte{} } // 1/2 chance additional TLV data. if r.Intn(2) == 0 { req.ExtraData = []byte{0xfd, 0x00, 0xff, 0x00} } v[0] = reflect.ValueOf(req) }, MsgAcceptChannel: func(v []reflect.Value, r *rand.Rand) { req := AcceptChannel{ DustLimit: btcutil.Amount(r.Int63()), MaxValueInFlight: MilliSatoshi(r.Int63()), ChannelReserve: btcutil.Amount(r.Int63()), MinAcceptDepth: uint32(r.Int31()), HtlcMinimum: MilliSatoshi(r.Int31()), CsvDelay: uint16(r.Int31()), MaxAcceptedHTLCs: uint16(r.Int31()), } if _, err := r.Read(req.PendingChannelID[:]); err != nil { t.Fatalf("unable to generate pending chan id: %v", err) return } var err error req.FundingKey, err = randPubKey() if err != nil { t.Fatalf("unable to generate key: %v", err) return } req.RevocationPoint, err = randPubKey() if err != nil { t.Fatalf("unable to generate key: %v", err) return } req.PaymentPoint, err = randPubKey() if err != nil { t.Fatalf("unable to generate key: %v", err) return } req.DelayedPaymentPoint, err = randPubKey() if err != nil { t.Fatalf("unable to generate key: %v", err) return } req.HtlcPoint, err = randPubKey() if err != nil { t.Fatalf("unable to generate key: %v", err) return } req.FirstCommitmentPoint, err = randPubKey() if err != nil { t.Fatalf("unable to generate key: %v", err) return } // 1/2 chance empty TLV records. if r.Intn(2) == 0 { req.UpfrontShutdownScript, err = randDeliveryAddress(r) if err != nil { t.Fatalf("unable to generate delivery address: %v", err) return } req.ChannelType = new(ChannelType) *req.ChannelType = ChannelType(*randRawFeatureVector(r)) req.LeaseExpiry = new(LeaseExpiry) *req.LeaseExpiry = LeaseExpiry(1337) //nolint:lll req.LocalNonce = someLocalNonce[NonceRecordTypeT](r) } else { req.UpfrontShutdownScript = []byte{} } // 1/2 chance additional TLV data. if r.Intn(2) == 0 { req.ExtraData = []byte{0xfd, 0x00, 0xff, 0x00} } v[0] = reflect.ValueOf(req) }, MsgFundingCreated: func(v []reflect.Value, r *rand.Rand) { req := FundingCreated{ ExtraData: make([]byte, 0), } if _, err := r.Read(req.PendingChannelID[:]); err != nil { t.Fatalf("unable to generate pending chan id: %v", err) return } if _, err := r.Read(req.FundingPoint.Hash[:]); err != nil { t.Fatalf("unable to generate hash: %v", err) return } req.FundingPoint.Index = uint32(r.Int31()) % math.MaxUint16 var err error req.CommitSig, err = NewSigFromSignature(testSig) if err != nil { t.Fatalf("unable to parse sig: %v", err) return } // 1/2 chance to attach a partial sig. if r.Intn(2) == 0 { req.PartialSig = somePartialSigWithNonce(t, r) } v[0] = reflect.ValueOf(req) }, MsgFundingSigned: func(v []reflect.Value, r *rand.Rand) { var c [32]byte _, err := r.Read(c[:]) if err != nil { t.Fatalf("unable to generate chan id: %v", err) return } req := FundingSigned{ ChanID: ChannelID(c), ExtraData: make([]byte, 0), } req.CommitSig, err = NewSigFromSignature(testSig) if err != nil { t.Fatalf("unable to parse sig: %v", err) return } // 1/2 chance to attach a partial sig. if r.Intn(2) == 0 { req.PartialSig = somePartialSigWithNonce(t, r) } v[0] = reflect.ValueOf(req) }, MsgChannelReady: func(v []reflect.Value, r *rand.Rand) { var c [32]byte _, err := r.Read(c[:]) require.NoError(t, err) pubKey, err := randPubKey() require.NoError(t, err) req := NewChannelReady(c, pubKey) if r.Int31()%2 == 0 { scid := NewShortChanIDFromInt(uint64(r.Int63())) req.AliasScid = &scid //nolint:lll req.NextLocalNonce = someLocalNonce[NonceRecordTypeT](r) } if r.Int31()%2 == 0 { nodeNonce := tlv.ZeroRecordT[ tlv.TlvType0, Musig2Nonce, ]() nodeNonce.Val = randLocalNonce(r) req.AnnouncementNodeNonce = tlv.SomeRecordT( nodeNonce, ) btcNonce := tlv.ZeroRecordT[ tlv.TlvType2, Musig2Nonce, ]() btcNonce.Val = randLocalNonce(r) req.AnnouncementBitcoinNonce = tlv.SomeRecordT( btcNonce, ) } v[0] = reflect.ValueOf(*req) }, MsgShutdown: func(v []reflect.Value, r *rand.Rand) { var c [32]byte _, err := r.Read(c[:]) if err != nil { t.Fatalf("unable to generate chan id: %v", err) return } shutdownAddr, err := randDeliveryAddress(r) if err != nil { t.Fatalf("unable to generate delivery "+ "address: %v", err) return } req := Shutdown{ ChannelID: ChannelID(c), Address: shutdownAddr, } if r.Int31()%2 == 0 { //nolint:lll req.ShutdownNonce = someLocalNonce[ShutdownNonceType](r) } v[0] = reflect.ValueOf(req) }, MsgClosingSigned: func(v []reflect.Value, r *rand.Rand) { req := ClosingSigned{ FeeSatoshis: btcutil.Amount(r.Int63()), ExtraData: make([]byte, 0), } var err error req.Signature, err = NewSigFromSignature(testSig) if err != nil { t.Fatalf("unable to parse sig: %v", err) return } if _, err := r.Read(req.ChannelID[:]); err != nil { t.Fatalf("unable to generate chan id: %v", err) return } if r.Int31()%2 == 0 { req.PartialSig = somePartialSig(t, r) } v[0] = reflect.ValueOf(req) }, MsgDynPropose: func(v []reflect.Value, r *rand.Rand) { var dp DynPropose rand.Read(dp.ChanID[:]) if rand.Uint32()%2 == 0 { v := btcutil.Amount(rand.Uint32()) dp.DustLimit = fn.Some(v) } if rand.Uint32()%2 == 0 { v := MilliSatoshi(rand.Uint32()) dp.MaxValueInFlight = fn.Some(v) } if rand.Uint32()%2 == 0 { v := btcutil.Amount(rand.Uint32()) dp.ChannelReserve = fn.Some(v) } if rand.Uint32()%2 == 0 { v := uint16(rand.Uint32()) dp.CsvDelay = fn.Some(v) } if rand.Uint32()%2 == 0 { v := uint16(rand.Uint32()) dp.MaxAcceptedHTLCs = fn.Some(v) } if rand.Uint32()%2 == 0 { v, _ := btcec.NewPrivateKey() dp.FundingKey = fn.Some(*v.PubKey()) } if rand.Uint32()%2 == 0 { v := ChannelType(*NewRawFeatureVector()) dp.ChannelType = fn.Some(v) } if rand.Uint32()%2 == 0 { v := chainfee.SatPerKWeight(rand.Uint32()) dp.KickoffFeerate = fn.Some(v) } v[0] = reflect.ValueOf(dp) }, MsgDynReject: func(v []reflect.Value, r *rand.Rand) { var dr DynReject rand.Read(dr.ChanID[:]) features := NewRawFeatureVector() if rand.Uint32()%2 == 0 { features.Set(FeatureBit(DPDustLimitSatoshis)) } if rand.Uint32()%2 == 0 { features.Set( FeatureBit(DPMaxHtlcValueInFlightMsat), ) } if rand.Uint32()%2 == 0 { features.Set( FeatureBit(DPChannelReserveSatoshis), ) } if rand.Uint32()%2 == 0 { features.Set(FeatureBit(DPToSelfDelay)) } if rand.Uint32()%2 == 0 { features.Set(FeatureBit(DPMaxAcceptedHtlcs)) } if rand.Uint32()%2 == 0 { features.Set(FeatureBit(DPFundingPubkey)) } if rand.Uint32()%2 == 0 { features.Set(FeatureBit(DPChannelType)) } if rand.Uint32()%2 == 0 { features.Set(FeatureBit(DPKickoffFeerate)) } dr.UpdateRejections = *features v[0] = reflect.ValueOf(dr) }, MsgDynAck: func(v []reflect.Value, r *rand.Rand) { var da DynAck rand.Read(da.ChanID[:]) if rand.Uint32()%2 == 0 { var nonce Musig2Nonce rand.Read(nonce[:]) da.LocalNonce = fn.Some(nonce) } v[0] = reflect.ValueOf(da) }, MsgKickoffSig: func(v []reflect.Value, r *rand.Rand) { ks := KickoffSig{ ExtraData: make([]byte, 0), } rand.Read(ks.ChanID[:]) rand.Read(ks.Signature.bytes[:]) v[0] = reflect.ValueOf(ks) }, MsgCommitSig: func(v []reflect.Value, r *rand.Rand) { req := NewCommitSig() if _, err := r.Read(req.ChanID[:]); err != nil { t.Fatalf("unable to generate chan id: %v", err) return } var err error req.CommitSig, err = NewSigFromSignature(testSig) if err != nil { t.Fatalf("unable to parse sig: %v", err) return } // Only create the slice if there will be any signatures // in it to prevent false positive test failures due to // an empty slice versus a nil slice. numSigs := uint16(r.Int31n(500)) if numSigs > 0 { req.HtlcSigs = make([]Sig, numSigs) } for i := 0; i < int(numSigs); i++ { req.HtlcSigs[i], err = NewSigFromSignature( testSig, ) if err != nil { t.Fatalf("unable to parse sig: %v", err) return } } req.CustomRecords = randCustomRecords(t, r) // 50/50 chance to attach a partial sig. if r.Int31()%2 == 0 { req.PartialSig = somePartialSigWithNonce(t, r) } v[0] = reflect.ValueOf(*req) }, MsgRevokeAndAck: func(v []reflect.Value, r *rand.Rand) { req := NewRevokeAndAck() if _, err := r.Read(req.ChanID[:]); err != nil { t.Fatalf("unable to generate chan id: %v", err) return } if _, err := r.Read(req.Revocation[:]); err != nil { t.Fatalf("unable to generate bytes: %v", err) return } var err error req.NextRevocationKey, err = randPubKey() if err != nil { t.Fatalf("unable to generate key: %v", err) return } // 50/50 chance to attach a local nonce. if r.Int31()%2 == 0 { //nolint:lll req.LocalNonce = someLocalNonce[NonceRecordTypeT](r) } v[0] = reflect.ValueOf(*req) }, MsgChannelAnnouncement: func(v []reflect.Value, r *rand.Rand) { var err error req := ChannelAnnouncement1{ ShortChannelID: NewShortChanIDFromInt( uint64(r.Int63()), ), NodeID1: randRawKey(t), NodeID2: randRawKey(t), BitcoinKey1: randRawKey(t), BitcoinKey2: randRawKey(t), Features: randRawFeatureVector(r), ExtraOpaqueData: make([]byte, 0), } req.NodeSig1, err = NewSigFromSignature(testSig) if err != nil { t.Fatalf("unable to parse sig: %v", err) return } req.NodeSig2, err = NewSigFromSignature(testSig) if err != nil { t.Fatalf("unable to parse sig: %v", err) return } req.BitcoinSig1, err = NewSigFromSignature(testSig) if err != nil { t.Fatalf("unable to parse sig: %v", err) return } req.BitcoinSig2, err = NewSigFromSignature(testSig) if err != nil { t.Fatalf("unable to parse sig: %v", err) return } if _, err := r.Read(req.ChainHash[:]); err != nil { t.Fatalf("unable to generate chain hash: %v", err) return } numExtraBytes := r.Int31n(1000) if numExtraBytes > 0 { req.ExtraOpaqueData = make([]byte, numExtraBytes) _, err := r.Read(req.ExtraOpaqueData[:]) if err != nil { t.Fatalf("unable to generate opaque "+ "bytes: %v", err) return } } v[0] = reflect.ValueOf(req) }, MsgNodeAnnouncement: func(v []reflect.Value, r *rand.Rand) { var err error req := NodeAnnouncement{ NodeID: randRawKey(t), Features: randRawFeatureVector(r), Timestamp: uint32(r.Int31()), Alias: randAlias(r), RGBColor: color.RGBA{ R: uint8(r.Int31()), G: uint8(r.Int31()), B: uint8(r.Int31()), }, ExtraOpaqueData: make([]byte, 0), } req.Signature, err = NewSigFromSignature(testSig) if err != nil { t.Fatalf("unable to parse sig: %v", err) return } req.Addresses, err = randAddrs(r) if err != nil { t.Fatalf("unable to generate addresses: %v", err) } numExtraBytes := r.Int31n(1000) if numExtraBytes > 0 { req.ExtraOpaqueData = make([]byte, numExtraBytes) _, err := r.Read(req.ExtraOpaqueData[:]) if err != nil { t.Fatalf("unable to generate opaque "+ "bytes: %v", err) return } } v[0] = reflect.ValueOf(req) }, MsgChannelUpdate: func(v []reflect.Value, r *rand.Rand) { var err error msgFlags := ChanUpdateMsgFlags(r.Int31()) maxHtlc := MilliSatoshi(r.Int63()) // We make the max_htlc field zero if it is not flagged // as being part of the ChannelUpdate, to pass // serialization tests, as it will be ignored if the bit // is not set. if msgFlags&ChanUpdateRequiredMaxHtlc == 0 { maxHtlc = 0 } req := ChannelUpdate1{ ShortChannelID: NewShortChanIDFromInt( uint64(r.Int63()), ), Timestamp: uint32(r.Int31()), MessageFlags: msgFlags, ChannelFlags: ChanUpdateChanFlags(r.Int31()), TimeLockDelta: uint16(r.Int31()), HtlcMinimumMsat: MilliSatoshi(r.Int63()), HtlcMaximumMsat: maxHtlc, BaseFee: uint32(r.Int31()), FeeRate: uint32(r.Int31()), ExtraOpaqueData: make([]byte, 0), } req.Signature, err = NewSigFromSignature(testSig) if err != nil { t.Fatalf("unable to parse sig: %v", err) return } if _, err := r.Read(req.ChainHash[:]); err != nil { t.Fatalf("unable to generate chain hash: %v", err) return } numExtraBytes := r.Int31n(1000) if numExtraBytes > 0 { req.ExtraOpaqueData = make([]byte, numExtraBytes) _, err := r.Read(req.ExtraOpaqueData[:]) if err != nil { t.Fatalf("unable to generate opaque "+ "bytes: %v", err) return } } v[0] = reflect.ValueOf(req) }, MsgAnnounceSignatures: func(v []reflect.Value, r *rand.Rand) { var err error req := AnnounceSignatures1{ ShortChannelID: NewShortChanIDFromInt(uint64(r.Int63())), ExtraOpaqueData: make([]byte, 0), } req.NodeSignature, err = NewSigFromSignature(testSig) if err != nil { t.Fatalf("unable to parse sig: %v", err) return } req.BitcoinSignature, err = NewSigFromSignature(testSig) if err != nil { t.Fatalf("unable to parse sig: %v", err) return } if _, err := r.Read(req.ChannelID[:]); err != nil { t.Fatalf("unable to generate chan id: %v", err) return } numExtraBytes := r.Int31n(1000) if numExtraBytes > 0 { req.ExtraOpaqueData = make([]byte, numExtraBytes) _, err := r.Read(req.ExtraOpaqueData[:]) if err != nil { t.Fatalf("unable to generate opaque "+ "bytes: %v", err) return } } v[0] = reflect.ValueOf(req) }, MsgChannelReestablish: func(v []reflect.Value, r *rand.Rand) { req := ChannelReestablish{ NextLocalCommitHeight: uint64(r.Int63()), RemoteCommitTailHeight: uint64(r.Int63()), ExtraData: make([]byte, 0), } // With a 50/50 probability, we'll include the // additional fields so we can test our ability to // properly parse, and write out the optional fields. if r.Int()%2 == 0 { _, err := r.Read(req.LastRemoteCommitSecret[:]) if err != nil { t.Fatalf("unable to read commit secret: %v", err) return } req.LocalUnrevokedCommitPoint, err = randPubKey() if err != nil { t.Fatalf("unable to generate key: %v", err) return } //nolint:lll req.LocalNonce = someLocalNonce[NonceRecordTypeT](r) } v[0] = reflect.ValueOf(req) }, MsgGossipTimestampRange: func(v []reflect.Value, r *rand.Rand) { req := GossipTimestampRange{ FirstTimestamp: rand.Uint32(), TimestampRange: rand.Uint32(), ExtraData: make([]byte, 0), } _, err := rand.Read(req.ChainHash[:]) require.NoError(t, err) // Sometimes add a block range. if r.Int31()%2 == 0 { firstBlock := tlv.ZeroRecordT[ tlv.TlvType2, uint32, ]() firstBlock.Val = rand.Uint32() req.FirstBlockHeight = tlv.SomeRecordT( firstBlock, ) blockRange := tlv.ZeroRecordT[ tlv.TlvType4, uint32, ]() blockRange.Val = rand.Uint32() req.BlockRange = tlv.SomeRecordT(blockRange) } v[0] = reflect.ValueOf(req) }, MsgQueryShortChanIDs: func(v []reflect.Value, r *rand.Rand) { req := QueryShortChanIDs{ ExtraData: make([]byte, 0), } // With a 50/50 change, we'll either use zlib encoding, // or regular encoding. if r.Int31()%2 == 0 { req.EncodingType = EncodingSortedZlib } else { req.EncodingType = EncodingSortedPlain } if _, err := rand.Read(req.ChainHash[:]); err != nil { t.Fatalf("unable to read chain hash: %v", err) return } numChanIDs := rand.Int31n(5000) for i := int32(0); i < numChanIDs; i++ { req.ShortChanIDs = append(req.ShortChanIDs, NewShortChanIDFromInt(uint64(r.Int63()))) } v[0] = reflect.ValueOf(req) }, MsgReplyChannelRange: func(v []reflect.Value, r *rand.Rand) { req := ReplyChannelRange{ FirstBlockHeight: uint32(r.Int31()), NumBlocks: uint32(r.Int31()), ExtraData: make([]byte, 0), } if _, err := rand.Read(req.ChainHash[:]); err != nil { t.Fatalf("unable to read chain hash: %v", err) return } req.Complete = uint8(r.Int31n(2)) // With a 50/50 change, we'll either use zlib encoding, // or regular encoding. if r.Int31()%2 == 0 { req.EncodingType = EncodingSortedZlib } else { req.EncodingType = EncodingSortedPlain } numChanIDs := rand.Int31n(4000) for i := int32(0); i < numChanIDs; i++ { req.ShortChanIDs = append(req.ShortChanIDs, NewShortChanIDFromInt(uint64(r.Int63()))) } // With a 50/50 chance, add some timestamps. if r.Int31()%2 == 0 { for i := int32(0); i < numChanIDs; i++ { timestamps := ChanUpdateTimestamps{ Timestamp1: rand.Uint32(), Timestamp2: rand.Uint32(), } req.Timestamps = append( req.Timestamps, timestamps, ) } } v[0] = reflect.ValueOf(req) }, MsgQueryChannelRange: func(v []reflect.Value, r *rand.Rand) { req := QueryChannelRange{ FirstBlockHeight: uint32(r.Int31()), NumBlocks: uint32(r.Int31()), ExtraData: make([]byte, 0), } _, err := rand.Read(req.ChainHash[:]) require.NoError(t, err) // With a 50/50 change, we'll set a query option. if r.Int31()%2 == 0 { req.QueryOptions = NewTimestampQueryOption() } v[0] = reflect.ValueOf(req) }, MsgPing: func(v []reflect.Value, r *rand.Rand) { // We use a special message generator here to ensure we // don't generate ping messages that are too large, // which'll cause the test to fail. // // We'll allow the test to generate padding bytes up to // the max message limit, factoring in the 2 bytes for // the num pong bytes and 2 bytes for encoding the // length of the padding bytes. paddingBytes := make([]byte, rand.Intn(MaxMsgBody-3)) req := Ping{ NumPongBytes: uint16(r.Intn(MaxPongBytes + 1)), PaddingBytes: paddingBytes, } v[0] = reflect.ValueOf(req) }, MsgClosingComplete: func(v []reflect.Value, r *rand.Rand) { var c [32]byte _, err := r.Read(c[:]) if err != nil { t.Fatalf("unable to generate chan id: %v", err) return } req := ClosingComplete{ ChannelID: ChannelID(c), FeeSatoshis: btcutil.Amount(r.Int63()), Sequence: uint32(r.Int63()), ClosingSigs: ClosingSigs{}, } if r.Intn(2) == 0 { sig := req.CloserNoClosee.Zero() _, err := r.Read(sig.Val.bytes[:]) if err != nil { t.Fatalf("unable to generate sig: %v", err) return } req.CloserNoClosee = tlv.SomeRecordT(sig) } if r.Intn(2) == 0 { sig := req.NoCloserClosee.Zero() _, err := r.Read(sig.Val.bytes[:]) if err != nil { t.Fatalf("unable to generate sig: %v", err) return } req.NoCloserClosee = tlv.SomeRecordT(sig) } if r.Intn(2) == 0 { sig := req.CloserAndClosee.Zero() _, err := r.Read(sig.Val.bytes[:]) if err != nil { t.Fatalf("unable to generate sig: %v", err) return } req.CloserAndClosee = tlv.SomeRecordT(sig) } v[0] = reflect.ValueOf(req) }, MsgClosingSig: func(v []reflect.Value, r *rand.Rand) { var c [32]byte _, err := r.Read(c[:]) if err != nil { t.Fatalf("unable to generate chan id: %v", err) return } req := ClosingSig{ ChannelID: ChannelID(c), ClosingSigs: ClosingSigs{}, } if r.Intn(2) == 0 { sig := req.CloserNoClosee.Zero() _, err := r.Read(sig.Val.bytes[:]) if err != nil { t.Fatalf("unable to generate sig: %v", err) return } req.CloserNoClosee = tlv.SomeRecordT(sig) } if r.Intn(2) == 0 { sig := req.NoCloserClosee.Zero() _, err := r.Read(sig.Val.bytes[:]) if err != nil { t.Fatalf("unable to generate sig: %v", err) return } req.NoCloserClosee = tlv.SomeRecordT(sig) } if r.Intn(2) == 0 { sig := req.CloserAndClosee.Zero() _, err := r.Read(sig.Val.bytes[:]) if err != nil { t.Fatalf("unable to generate sig: %v", err) return } req.CloserAndClosee = tlv.SomeRecordT(sig) } v[0] = reflect.ValueOf(req) }, MsgUpdateAddHTLC: func(v []reflect.Value, r *rand.Rand) { req := &UpdateAddHTLC{ ID: r.Uint64(), Amount: MilliSatoshi(r.Uint64()), Expiry: r.Uint32(), } _, err := r.Read(req.ChanID[:]) require.NoError(t, err) _, err = r.Read(req.PaymentHash[:]) require.NoError(t, err) _, err = r.Read(req.OnionBlob[:]) require.NoError(t, err) req.CustomRecords = randCustomRecords(t, r) // Generate a blinding point 50% of the time, since not // all update adds will use route blinding. if r.Int31()%2 == 0 { pubkey, err := randPubKey() if err != nil { t.Fatalf("unable to generate key: %v", err) return } req.BlindingPoint = tlv.SomeRecordT( tlv.NewPrimitiveRecord[tlv.TlvType0]( pubkey, ), ) } v[0] = reflect.ValueOf(*req) }, MsgUpdateFulfillHTLC: func(v []reflect.Value, r *rand.Rand) { req := &UpdateFulfillHTLC{ ID: r.Uint64(), } _, err := r.Read(req.ChanID[:]) require.NoError(t, err) _, err = r.Read(req.PaymentPreimage[:]) require.NoError(t, err) req.CustomRecords = randCustomRecords(t, r) // Generate some random TLV records 50% of the time. if r.Int31()%2 == 0 { req.ExtraData = []byte{ 0x01, 0x03, 1, 2, 3, 0x02, 0x03, 4, 5, 6, } } v[0] = reflect.ValueOf(*req) }, MsgAnnounceSignatures2: func(v []reflect.Value, r *rand.Rand) { req := AnnounceSignatures2{ ShortChannelID: NewShortChanIDFromInt( uint64(r.Int63()), ), ExtraOpaqueData: make([]byte, 0), } _, err := r.Read(req.ChannelID[:]) require.NoError(t, err) partialSig, err := randPartialSig(r) require.NoError(t, err) req.PartialSignature = *partialSig numExtraBytes := r.Int31n(1000) if numExtraBytes > 0 { req.ExtraOpaqueData = make( []byte, numExtraBytes, ) _, err := r.Read(req.ExtraOpaqueData[:]) require.NoError(t, err) } v[0] = reflect.ValueOf(req) }, MsgChannelAnnouncement2: func(v []reflect.Value, r *rand.Rand) { req := ChannelAnnouncement2{ Signature: testSchnorrSig, ExtraOpaqueData: make([]byte, 0), } req.ShortChannelID.Val = NewShortChanIDFromInt( uint64(r.Int63()), ) req.Capacity.Val = rand.Uint64() req.Features.Val = *randRawFeatureVector(r) req.NodeID1.Val = randRawKey(t) req.NodeID2.Val = randRawKey(t) // Sometimes set chain hash to bitcoin mainnet genesis // hash. req.ChainHash.Val = *chaincfg.MainNetParams.GenesisHash if r.Int31()%2 == 0 { _, err := r.Read(req.ChainHash.Val[:]) require.NoError(t, err) } // Sometimes set the bitcoin keys. if r.Int31()%2 == 0 { btcKey1 := tlv.ZeroRecordT[ tlv.TlvType12, [33]byte, ]() btcKey1.Val = randRawKey(t) req.BitcoinKey1 = tlv.SomeRecordT(btcKey1) btcKey2 := tlv.ZeroRecordT[ tlv.TlvType14, [33]byte, ]() btcKey2.Val = randRawKey(t) req.BitcoinKey2 = tlv.SomeRecordT(btcKey2) // Occasionally also set the merkle root hash. if r.Int31()%2 == 0 { hash := tlv.ZeroRecordT[ tlv.TlvType16, [32]byte, ]() _, err := r.Read(hash.Val[:]) require.NoError(t, err) req.MerkleRootHash = tlv.SomeRecordT( hash, ) } } numExtraBytes := r.Int31n(1000) if numExtraBytes > 0 { req.ExtraOpaqueData = make( []byte, numExtraBytes, ) _, err := r.Read(req.ExtraOpaqueData[:]) require.NoError(t, err) } v[0] = reflect.ValueOf(req) }, MsgChannelUpdate2: func(v []reflect.Value, r *rand.Rand) { req := ChannelUpdate2{ Signature: testSchnorrSig, ExtraOpaqueData: make([]byte, 0), } req.ShortChannelID.Val = NewShortChanIDFromInt( uint64(r.Int63()), ) req.BlockHeight.Val = r.Uint32() req.HTLCMaximumMsat.Val = MilliSatoshi(r.Uint64()) // Sometimes set chain hash to bitcoin mainnet genesis // hash. req.ChainHash.Val = *chaincfg.MainNetParams.GenesisHash if r.Int31()%2 == 0 { _, err := r.Read(req.ChainHash.Val[:]) require.NoError(t, err) } // Sometimes use default htlc min msat. req.HTLCMinimumMsat.Val = defaultHtlcMinMsat if r.Int31()%2 == 0 { req.HTLCMinimumMsat.Val = MilliSatoshi( r.Uint64(), ) } // Sometimes set the cltv expiry delta to the default. req.CLTVExpiryDelta.Val = defaultCltvExpiryDelta if r.Int31()%2 == 0 { req.CLTVExpiryDelta.Val = uint16(r.Int31()) } // Sometimes use default fee base. req.FeeBaseMsat.Val = defaultFeeBaseMsat if r.Int31()%2 == 0 { req.FeeBaseMsat.Val = r.Uint32() } // Sometimes use default proportional fee. req.FeeProportionalMillionths.Val = defaultFeeProportionalMillionths if r.Int31()%2 == 0 { req.FeeProportionalMillionths.Val = r.Uint32() } // Alternate between the two direction possibilities. if r.Int31()%2 == 0 { req.SecondPeer = tlv.SomeRecordT( tlv.ZeroRecordT[tlv.TlvType8, TrueBoolean](), //nolint:lll ) } // Sometimes set the incoming disabled flag. if r.Int31()%2 == 0 { req.DisabledFlags.Val |= ChanUpdateDisableIncoming } // Sometimes set the outgoing disabled flag. if r.Int31()%2 == 0 { req.DisabledFlags.Val |= ChanUpdateDisableOutgoing } numExtraBytes := r.Int31n(1000) if numExtraBytes > 0 { req.ExtraOpaqueData = make( []byte, numExtraBytes, ) _, err := r.Read(req.ExtraOpaqueData[:]) require.NoError(t, err) } v[0] = reflect.ValueOf(req) }, } // With the above types defined, we'll now generate a slice of // scenarios to feed into quick.Check. The function scans in input // space of the target function under test, so we'll need to create a // series of wrapper functions to force it to iterate over the target // types, but re-use the mainScenario defined above. tests := []struct { msgType MessageType scenario interface{} }{ { msgType: MsgStfu, scenario: func(m Stfu) bool { return mainScenario(&m) }, }, { msgType: MsgInit, scenario: func(m Init) bool { return mainScenario(&m) }, }, { msgType: MsgWarning, scenario: func(m Warning) bool { return mainScenario(&m) }, }, { msgType: MsgError, scenario: func(m Error) bool { return mainScenario(&m) }, }, { msgType: MsgPing, scenario: func(m Ping) bool { return mainScenario(&m) }, }, { msgType: MsgPong, scenario: func(m Pong) bool { return mainScenario(&m) }, }, { msgType: MsgOpenChannel, scenario: func(m OpenChannel) bool { return mainScenario(&m) }, }, { msgType: MsgAcceptChannel, scenario: func(m AcceptChannel) bool { return mainScenario(&m) }, }, { msgType: MsgFundingCreated, scenario: func(m FundingCreated) bool { return mainScenario(&m) }, }, { msgType: MsgFundingSigned, scenario: func(m FundingSigned) bool { return mainScenario(&m) }, }, { msgType: MsgChannelReady, scenario: func(m ChannelReady) bool { return mainScenario(&m) }, }, { msgType: MsgShutdown, scenario: func(m Shutdown) bool { return mainScenario(&m) }, }, { msgType: MsgClosingSigned, scenario: func(m ClosingSigned) bool { return mainScenario(&m) }, }, { msgType: MsgDynPropose, scenario: func(m DynPropose) bool { return mainScenario(&m) }, }, { msgType: MsgDynReject, scenario: func(m DynReject) bool { return mainScenario(&m) }, }, { msgType: MsgDynAck, scenario: func(m DynAck) bool { return mainScenario(&m) }, }, { msgType: MsgKickoffSig, scenario: func(m KickoffSig) bool { return mainScenario(&m) }, }, { msgType: MsgUpdateAddHTLC, scenario: func(m UpdateAddHTLC) bool { return mainScenario(&m) }, }, { msgType: MsgUpdateFulfillHTLC, scenario: func(m UpdateFulfillHTLC) bool { return mainScenario(&m) }, }, { msgType: MsgUpdateFailHTLC, scenario: func(m UpdateFailHTLC) bool { return mainScenario(&m) }, }, { msgType: MsgCommitSig, scenario: func(m CommitSig) bool { return mainScenario(&m) }, }, { msgType: MsgRevokeAndAck, scenario: func(m RevokeAndAck) bool { return mainScenario(&m) }, }, { msgType: MsgUpdateFee, scenario: func(m UpdateFee) bool { return mainScenario(&m) }, }, { msgType: MsgUpdateFailMalformedHTLC, scenario: func(m UpdateFailMalformedHTLC) bool { return mainScenario(&m) }, }, { msgType: MsgChannelReestablish, scenario: func(m ChannelReestablish) bool { return mainScenario(&m) }, }, { msgType: MsgChannelAnnouncement, scenario: func(m ChannelAnnouncement1) bool { return mainScenario(&m) }, }, { msgType: MsgNodeAnnouncement, scenario: func(m NodeAnnouncement) bool { return mainScenario(&m) }, }, { msgType: MsgChannelUpdate, scenario: func(m ChannelUpdate1) bool { return mainScenario(&m) }, }, { msgType: MsgAnnounceSignatures, scenario: func(m AnnounceSignatures1) bool { return mainScenario(&m) }, }, { msgType: MsgGossipTimestampRange, scenario: func(m GossipTimestampRange) bool { return mainScenario(&m) }, }, { msgType: MsgQueryShortChanIDs, scenario: func(m QueryShortChanIDs) bool { return mainScenario(&m) }, }, { msgType: MsgReplyShortChanIDsEnd, scenario: func(m ReplyShortChanIDsEnd) bool { return mainScenario(&m) }, }, { msgType: MsgQueryChannelRange, scenario: func(m QueryChannelRange) bool { return mainScenario(&m) }, }, { msgType: MsgReplyChannelRange, scenario: func(m ReplyChannelRange) bool { return mainScenario(&m) }, }, { msgType: MsgClosingComplete, scenario: func(m ClosingComplete) bool { return mainScenario(&m) }, }, { msgType: MsgClosingSig, scenario: func(m ClosingSig) bool { return mainScenario(&m) }, }, { msgType: MsgAnnounceSignatures2, scenario: func(m AnnounceSignatures2) bool { return mainScenario(&m) }, }, { msgType: MsgChannelAnnouncement2, scenario: func(m ChannelAnnouncement2) bool { return mainScenario(&m) }, }, { msgType: MsgChannelUpdate2, scenario: func(m ChannelUpdate2) bool { return mainScenario(&m) }, }, } for _, test := range tests { t.Run(test.msgType.String(), func(t *testing.T) { var config *quick.Config // If the type defined is within the custom type gen // map above, then we'll modify the default config to // use this Value function that knows how to generate // the proper types. if valueGen, ok := customTypeGen[test.msgType]; ok { config = &quick.Config{ Values: valueGen, } } t.Logf("Running fuzz tests for msgType=%v", test.msgType) err := quick.Check(test.scenario, config) if err != nil { t.Fatalf("fuzz checks for msg=%v failed: %v", test.msgType, err) } }) } } func init() { rand.Seed(time.Now().Unix()) }