package zpay32 import ( "bytes" "encoding/binary" "errors" "fmt" "strings" "time" "github.com/btcsuite/btcd/btcec" "github.com/btcsuite/btcd/chaincfg" "github.com/btcsuite/btcd/chaincfg/chainhash" "github.com/btcsuite/btcutil" "github.com/btcsuite/btcutil/bech32" "github.com/lightningnetwork/lnd/lnwire" ) // Decode parses the provided encoded invoice and returns a decoded Invoice if // it is valid by BOLT-0011 and matches the provided active network. func Decode(invoice string, net *chaincfg.Params) (*Invoice, error) { decodedInvoice := Invoice{} // Before bech32 decoding the invoice, make sure that it is not too large. // This is done as an anti-DoS measure since bech32 decoding is expensive. if len(invoice) > maxInvoiceLength { return nil, ErrInvoiceTooLarge } // Decode the invoice using the modified bech32 decoder. hrp, data, err := decodeBech32(invoice) if err != nil { return nil, err } // We expect the human-readable part to at least have ln + one char // encoding the network. if len(hrp) < 3 { return nil, fmt.Errorf("hrp too short") } // First two characters of HRP should be "ln". if hrp[:2] != "ln" { return nil, fmt.Errorf("prefix should be \"ln\"") } // The next characters should be a valid prefix for a segwit BIP173 // address that match the active network except for signet where we add // an additional "s" to differentiate it from the older testnet3 (Core // devs decided to use the same hrp for signet as for testnet3 which is // not optimal for LN). See // https://github.com/lightningnetwork/lightning-rfc/pull/844 for more // information. expectedPrefix := net.Bech32HRPSegwit if net.Name == chaincfg.SigNetParams.Name { expectedPrefix = "tbs" } if !strings.HasPrefix(hrp[2:], expectedPrefix) { return nil, fmt.Errorf( "invoice not for current active network '%s'", net.Name) } decodedInvoice.Net = net // Optionally, if there's anything left of the HRP after ln + the segwit // prefix, we try to decode this as the payment amount. var netPrefixLength = len(expectedPrefix) + 2 if len(hrp) > netPrefixLength { amount, err := decodeAmount(hrp[netPrefixLength:]) if err != nil { return nil, err } decodedInvoice.MilliSat = &amount } // Everything except the last 520 bits of the data encodes the invoice's // timestamp and tagged fields. if len(data) < signatureBase32Len { return nil, errors.New("short invoice") } invoiceData := data[:len(data)-signatureBase32Len] // Parse the timestamp and tagged fields, and fill the Invoice struct. if err := parseData(&decodedInvoice, invoiceData, net); err != nil { return nil, err } // The last 520 bits (104 groups) make up the signature. sigBase32 := data[len(data)-signatureBase32Len:] sigBase256, err := bech32.ConvertBits(sigBase32, 5, 8, true) if err != nil { return nil, err } var sig lnwire.Sig copy(sig[:], sigBase256[:64]) recoveryID := sigBase256[64] // The signature is over the hrp + the data the invoice, encoded in // base 256. taggedDataBytes, err := bech32.ConvertBits(invoiceData, 5, 8, true) if err != nil { return nil, err } toSign := append([]byte(hrp), taggedDataBytes...) // We expect the signature to be over the single SHA-256 hash of that // data. hash := chainhash.HashB(toSign) // If the destination pubkey was provided as a tagged field, use that // to verify the signature, if not do public key recovery. if decodedInvoice.Destination != nil { signature, err := sig.ToSignature() if err != nil { return nil, fmt.Errorf("unable to deserialize "+ "signature: %v", err) } if !signature.Verify(hash, decodedInvoice.Destination) { return nil, fmt.Errorf("invalid invoice signature") } } else { headerByte := recoveryID + 27 + 4 compactSign := append([]byte{headerByte}, sig[:]...) pubkey, _, err := btcec.RecoverCompact(btcec.S256(), compactSign, hash) if err != nil { return nil, err } decodedInvoice.Destination = pubkey } // If no feature vector was decoded, populate an empty one. if decodedInvoice.Features == nil { decodedInvoice.Features = lnwire.NewFeatureVector( nil, lnwire.Features, ) } // Now that we have created the invoice, make sure it has the required // fields set. if err := validateInvoice(&decodedInvoice); err != nil { return nil, err } return &decodedInvoice, nil } // parseData parses the data part of the invoice. It expects base32 data // returned from the bech32.Decode method, except signature. func parseData(invoice *Invoice, data []byte, net *chaincfg.Params) error { // It must contain the timestamp, encoded using 35 bits (7 groups). if len(data) < timestampBase32Len { return fmt.Errorf("data too short: %d", len(data)) } t, err := parseTimestamp(data[:timestampBase32Len]) if err != nil { return err } invoice.Timestamp = time.Unix(int64(t), 0) // The rest are tagged parts. tagData := data[7:] return parseTaggedFields(invoice, tagData, net) } // parseTimestamp converts a 35-bit timestamp (encoded in base32) to uint64. func parseTimestamp(data []byte) (uint64, error) { if len(data) != timestampBase32Len { return 0, fmt.Errorf("timestamp must be 35 bits, was %d", len(data)*5) } return base32ToUint64(data) } // parseTaggedFields takes the base32 encoded tagged fields of the invoice, and // fills the Invoice struct accordingly. func parseTaggedFields(invoice *Invoice, fields []byte, net *chaincfg.Params) error { index := 0 for len(fields)-index > 0 { // If there are less than 3 groups to read, there cannot be more // interesting information, as we need the type (1 group) and // length (2 groups). // // This means the last tagged field is broken. if len(fields)-index < 3 { return ErrBrokenTaggedField } typ := fields[index] dataLength, err := parseFieldDataLength(fields[index+1 : index+3]) if err != nil { return err } // If we don't have enough field data left to read this length, // return error. if len(fields) < index+3+int(dataLength) { return ErrInvalidFieldLength } base32Data := fields[index+3 : index+3+int(dataLength)] // Advance the index in preparation for the next iteration. index += 3 + int(dataLength) switch typ { case fieldTypeP: if invoice.PaymentHash != nil { // We skip the field if we have already seen a // supported one. continue } invoice.PaymentHash, err = parse32Bytes(base32Data) case fieldTypeS: if invoice.PaymentAddr != nil { // We skip the field if we have already seen a // supported one. continue } invoice.PaymentAddr, err = parse32Bytes(base32Data) case fieldTypeD: if invoice.Description != nil { // We skip the field if we have already seen a // supported one. continue } invoice.Description, err = parseDescription(base32Data) case fieldTypeN: if invoice.Destination != nil { // We skip the field if we have already seen a // supported one. continue } invoice.Destination, err = parseDestination(base32Data) case fieldTypeH: if invoice.DescriptionHash != nil { // We skip the field if we have already seen a // supported one. continue } invoice.DescriptionHash, err = parse32Bytes(base32Data) case fieldTypeX: if invoice.expiry != nil { // We skip the field if we have already seen a // supported one. continue } invoice.expiry, err = parseExpiry(base32Data) case fieldTypeC: if invoice.minFinalCLTVExpiry != nil { // We skip the field if we have already seen a // supported one. continue } invoice.minFinalCLTVExpiry, err = parseMinFinalCLTVExpiry(base32Data) case fieldTypeF: if invoice.FallbackAddr != nil { // We skip the field if we have already seen a // supported one. continue } invoice.FallbackAddr, err = parseFallbackAddr(base32Data, net) case fieldTypeR: // An `r` field can be included in an invoice multiple // times, so we won't skip it if we have already seen // one. routeHint, err := parseRouteHint(base32Data) if err != nil { return err } invoice.RouteHints = append(invoice.RouteHints, routeHint) case fieldType9: if invoice.Features != nil { // We skip the field if we have already seen a // supported one. continue } invoice.Features, err = parseFeatures(base32Data) default: // Ignore unknown type. } // Check if there was an error from parsing any of the tagged // fields and return it. if err != nil { return err } } return nil } // parseFieldDataLength converts the two byte slice into a uint16. func parseFieldDataLength(data []byte) (uint16, error) { if len(data) != 2 { return 0, fmt.Errorf("data length must be 2 bytes, was %d", len(data)) } return uint16(data[0])<<5 | uint16(data[1]), nil } // parse32Bytes converts a 256-bit value (encoded in base32) to *[32]byte. This // can be used for payment hashes, description hashes, payment addresses, etc. func parse32Bytes(data []byte) (*[32]byte, error) { var paymentHash [32]byte // As BOLT-11 states, a reader must skip over the 32-byte fields if // it does not have a length of 52, so avoid returning an error. if len(data) != hashBase32Len { return nil, nil } hash, err := bech32.ConvertBits(data, 5, 8, false) if err != nil { return nil, err } copy(paymentHash[:], hash) return &paymentHash, nil } // parseDescription converts the data (encoded in base32) into a string to use // as the description. func parseDescription(data []byte) (*string, error) { base256Data, err := bech32.ConvertBits(data, 5, 8, false) if err != nil { return nil, err } description := string(base256Data) return &description, nil } // parseDestination converts the data (encoded in base32) into a 33-byte public // key of the payee node. func parseDestination(data []byte) (*btcec.PublicKey, error) { // As BOLT-11 states, a reader must skip over the destination field // if it does not have a length of 53, so avoid returning an error. if len(data) != pubKeyBase32Len { return nil, nil } base256Data, err := bech32.ConvertBits(data, 5, 8, false) if err != nil { return nil, err } return btcec.ParsePubKey(base256Data, btcec.S256()) } // parseExpiry converts the data (encoded in base32) into the expiry time. func parseExpiry(data []byte) (*time.Duration, error) { expiry, err := base32ToUint64(data) if err != nil { return nil, err } duration := time.Duration(expiry) * time.Second return &duration, nil } // parseMinFinalCLTVExpiry converts the data (encoded in base32) into a uint64 // to use as the minFinalCLTVExpiry. func parseMinFinalCLTVExpiry(data []byte) (*uint64, error) { expiry, err := base32ToUint64(data) if err != nil { return nil, err } return &expiry, nil } // parseFallbackAddr converts the data (encoded in base32) into a fallback // on-chain address. func parseFallbackAddr(data []byte, net *chaincfg.Params) (btcutil.Address, error) { // nolint:dupl // Checks if the data is empty or contains a version without an address. if len(data) < 2 { return nil, fmt.Errorf("empty fallback address field") } var addr btcutil.Address version := data[0] switch version { case 0: witness, err := bech32.ConvertBits(data[1:], 5, 8, false) if err != nil { return nil, err } switch len(witness) { case 20: addr, err = btcutil.NewAddressWitnessPubKeyHash(witness, net) case 32: addr, err = btcutil.NewAddressWitnessScriptHash(witness, net) default: return nil, fmt.Errorf("unknown witness program length %d", len(witness)) } if err != nil { return nil, err } case 17: pubKeyHash, err := bech32.ConvertBits(data[1:], 5, 8, false) if err != nil { return nil, err } addr, err = btcutil.NewAddressPubKeyHash(pubKeyHash, net) if err != nil { return nil, err } case 18: scriptHash, err := bech32.ConvertBits(data[1:], 5, 8, false) if err != nil { return nil, err } addr, err = btcutil.NewAddressScriptHashFromHash(scriptHash, net) if err != nil { return nil, err } default: // Ignore unknown version. } return addr, nil } // parseRouteHint converts the data (encoded in base32) into an array containing // one or more routing hop hints that represent a single route hint. func parseRouteHint(data []byte) ([]HopHint, error) { base256Data, err := bech32.ConvertBits(data, 5, 8, false) if err != nil { return nil, err } // Check that base256Data is a multiple of hopHintLen. if len(base256Data)%hopHintLen != 0 { return nil, fmt.Errorf("expected length multiple of %d bytes, "+ "got %d", hopHintLen, len(base256Data)) } var routeHint []HopHint for len(base256Data) > 0 { hopHint := HopHint{} hopHint.NodeID, err = btcec.ParsePubKey(base256Data[:33], btcec.S256()) if err != nil { return nil, err } hopHint.ChannelID = binary.BigEndian.Uint64(base256Data[33:41]) hopHint.FeeBaseMSat = binary.BigEndian.Uint32(base256Data[41:45]) hopHint.FeeProportionalMillionths = binary.BigEndian.Uint32(base256Data[45:49]) hopHint.CLTVExpiryDelta = binary.BigEndian.Uint16(base256Data[49:51]) routeHint = append(routeHint, hopHint) base256Data = base256Data[51:] } return routeHint, nil } // parseFeatures decodes any feature bits directly from the base32 // representation. func parseFeatures(data []byte) (*lnwire.FeatureVector, error) { rawFeatures := lnwire.NewRawFeatureVector() err := rawFeatures.DecodeBase32(bytes.NewReader(data), len(data)) if err != nil { return nil, err } return lnwire.NewFeatureVector(rawFeatures, lnwire.Features), nil } // base32ToUint64 converts a base32 encoded number to uint64. func base32ToUint64(data []byte) (uint64, error) { // Maximum that fits in uint64 is ceil(64 / 5) = 12 groups. if len(data) > 13 { return 0, fmt.Errorf("cannot parse data of length %d as uint64", len(data)) } val := uint64(0) for i := 0; i < len(data); i++ { val = val<<5 | uint64(data[i]) } return val, nil }