422 lines
13 KiB
Go
422 lines
13 KiB
Go
// Copyright (c) 2018 The btcsuite developers
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// Use of this source code is governed by an ISC
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// license that can be found in the LICENSE file.
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package psbt
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import (
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"bytes"
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"encoding/binary"
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"errors"
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"fmt"
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"io"
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"sort"
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"github.com/lbryio/lbcd/txscript"
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"github.com/lbryio/lbcd/wire"
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)
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// WriteTxWitness is a utility function due to non-exported witness
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// serialization (writeTxWitness encodes the bitcoin protocol encoding for a
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// transaction input's witness into w).
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func WriteTxWitness(w io.Writer, wit [][]byte) error {
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if err := wire.WriteVarInt(w, 0, uint64(len(wit))); err != nil {
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return err
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}
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for _, item := range wit {
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err := wire.WriteVarBytes(w, 0, item)
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if err != nil {
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return err
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}
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}
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return nil
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}
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// writePKHWitness writes a witness for a p2wkh spending input
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func writePKHWitness(sig []byte, pub []byte) ([]byte, error) {
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var (
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buf bytes.Buffer
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witnessItems = [][]byte{sig, pub}
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)
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if err := WriteTxWitness(&buf, witnessItems); err != nil {
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return nil, err
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}
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return buf.Bytes(), nil
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}
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// checkIsMultisigScript is a utility function to check whether a given
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// redeemscript fits the standard multisig template used in all P2SH based
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// multisig, given a set of pubkeys for redemption.
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func checkIsMultiSigScript(pubKeys [][]byte, sigs [][]byte,
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script []byte) bool {
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// First insist that the script type is multisig.
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if txscript.GetScriptClass(script) != txscript.MultiSigTy {
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return false
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}
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// Inspect the script to ensure that the number of sigs and pubkeys is
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// correct
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_, numSigs, err := txscript.CalcMultiSigStats(script)
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if err != nil {
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return false
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}
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// If the number of sigs provided, doesn't match the number of required
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// pubkeys, then we can't proceed as we're not yet final.
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if numSigs != len(pubKeys) || numSigs != len(sigs) {
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return false
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}
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return true
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}
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// extractKeyOrderFromScript is a utility function to extract an ordered list
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// of signatures, given a serialized script (redeemscript or witness script), a
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// list of pubkeys and the signatures corresponding to those pubkeys. This
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// function is used to ensure that the signatures will be embedded in the final
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// scriptSig or scriptWitness in the correct order.
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func extractKeyOrderFromScript(script []byte, expectedPubkeys [][]byte,
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sigs [][]byte) ([][]byte, error) {
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// If this isn't a proper finalized multi-sig script, then we can't
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// proceed.
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if !checkIsMultiSigScript(expectedPubkeys, sigs, script) {
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return nil, ErrUnsupportedScriptType
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}
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// Arrange the pubkeys and sigs into a slice of format:
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// * [[pub,sig], [pub,sig],..]
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type sigWithPub struct {
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pubKey []byte
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sig []byte
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}
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var pubsSigs []sigWithPub
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for i, pub := range expectedPubkeys {
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pubsSigs = append(pubsSigs, sigWithPub{
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pubKey: pub,
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sig: sigs[i],
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})
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}
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// Now that we have the set of (pubkey, sig) pairs, we'll construct a
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// position map that we can use to swap the order in the slice above to
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// match how things are laid out in the script.
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type positionEntry struct {
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index int
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value sigWithPub
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}
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var positionMap []positionEntry
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// For each pubkey in our pubsSigs slice, we'll now construct a proper
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// positionMap entry, based on _where_ in the script the pubkey first
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// appears.
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for _, p := range pubsSigs {
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pos := bytes.Index(script, p.pubKey)
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if pos < 0 {
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return nil, errors.New("script does not contain pubkeys")
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}
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positionMap = append(positionMap, positionEntry{
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index: pos,
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value: p,
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})
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}
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// Now that we have the position map full populated, we'll use the
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// index data to properly sort the entries in the map based on where
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// they appear in the script.
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sort.Slice(positionMap, func(i, j int) bool {
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return positionMap[i].index < positionMap[j].index
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})
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// Finally, we can simply iterate through the position map in order to
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// extract the proper signature ordering.
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sortedSigs := make([][]byte, 0, len(positionMap))
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for _, x := range positionMap {
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sortedSigs = append(sortedSigs, x.value.sig)
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}
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return sortedSigs, nil
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}
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// getMultisigScriptWitness creates a full psbt serialized Witness field for
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// the transaction, given the public keys and signatures to be appended. This
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// function will only accept witnessScripts of the type M of N multisig. This
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// is used for both p2wsh and nested p2wsh multisig cases.
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func getMultisigScriptWitness(witnessScript []byte, pubKeys [][]byte,
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sigs [][]byte) ([]byte, error) {
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// First using the script as a guide, we'll properly order the sigs
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// according to how their corresponding pubkeys appear in the
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// witnessScript.
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orderedSigs, err := extractKeyOrderFromScript(
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witnessScript, pubKeys, sigs,
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)
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if err != nil {
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return nil, err
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}
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// Now that we know the proper order, we'll append each of the
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// signatures into a new witness stack, then top it off with the
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// witness script at the end, prepending the nil as we need the extra
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// pop..
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witnessElements := make(wire.TxWitness, 0, len(sigs)+2)
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witnessElements = append(witnessElements, nil)
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for _, os := range orderedSigs {
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witnessElements = append(witnessElements, os)
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}
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witnessElements = append(witnessElements, witnessScript)
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// Now that we have the full witness stack, we'll serialize it in the
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// expected format, and return the final bytes.
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var buf bytes.Buffer
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if err = WriteTxWitness(&buf, witnessElements); err != nil {
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return nil, err
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}
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return buf.Bytes(), nil
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}
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// checkSigHashFlags compares the sighash flag byte on a signature with the
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// value expected according to any PsbtInSighashType field in this section of
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// the PSBT, and returns true if they match, false otherwise.
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// If no SighashType field exists, it is assumed to be SIGHASH_ALL.
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//
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// TODO(waxwing): sighash type not restricted to one byte in future?
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func checkSigHashFlags(sig []byte, input *PInput) bool {
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expectedSighashType := txscript.SigHashAll
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if input.SighashType != 0 {
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expectedSighashType = input.SighashType
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}
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return expectedSighashType == txscript.SigHashType(sig[len(sig)-1])
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}
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// serializeKVpair writes out a kv pair using a varbyte prefix for each.
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func serializeKVpair(w io.Writer, key []byte, value []byte) error {
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if err := wire.WriteVarBytes(w, 0, key); err != nil {
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return err
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}
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return wire.WriteVarBytes(w, 0, value)
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}
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// serializeKVPairWithType writes out to the passed writer a type coupled with
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// a key.
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func serializeKVPairWithType(w io.Writer, kt uint8, keydata []byte,
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value []byte) error {
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// If the key has no data, then we write a blank slice.
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if keydata == nil {
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keydata = []byte{}
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}
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// The final key to be written is: {type} || {keyData}
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serializedKey := append([]byte{kt}, keydata...)
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return serializeKVpair(w, serializedKey, value)
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}
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// getKey retrieves a single key - both the key type and the keydata (if
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// present) from the stream and returns the key type as an integer, or -1 if
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// the key was of zero length. This integer is is used to indicate the presence
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// of a separator byte which indicates the end of a given key-value pair list,
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// and the keydata as a byte slice or nil if none is present.
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func getKey(r io.Reader) (int, []byte, error) {
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// For the key, we read the varint separately, instead of using the
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// available ReadVarBytes, because we have a specific treatment of 0x00
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// here:
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count, err := wire.ReadVarInt(r, 0)
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if err != nil {
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return -1, nil, ErrInvalidPsbtFormat
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}
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if count == 0 {
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// A separator indicates end of key-value pair list.
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return -1, nil, nil
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}
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// Check that we don't attempt to decode a dangerously large key.
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if count > MaxPsbtKeyLength {
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return -1, nil, ErrInvalidKeydata
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}
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// Next, we ready out the designated number of bytes, which may include
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// a type, key, and optional data.
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keyTypeAndData := make([]byte, count)
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if _, err := io.ReadFull(r, keyTypeAndData[:]); err != nil {
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return -1, nil, err
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}
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keyType := int(string(keyTypeAndData)[0])
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// Note that the second return value will usually be empty, since most
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// keys contain no more than the key type byte.
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if len(keyTypeAndData) == 1 {
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return keyType, nil, nil
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}
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// Otherwise, we return the key, along with any data that it may
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// contain.
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return keyType, keyTypeAndData[1:], nil
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}
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// readTxOut is a limited version of wire.ReadTxOut, because the latter is not
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// exported.
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func readTxOut(txout []byte) (*wire.TxOut, error) {
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if len(txout) < 10 {
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return nil, ErrInvalidPsbtFormat
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}
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valueSer := binary.LittleEndian.Uint64(txout[:8])
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scriptPubKey := txout[9:]
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return wire.NewTxOut(int64(valueSer), scriptPubKey), nil
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}
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// SumUtxoInputValues tries to extract the sum of all inputs specified in the
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// UTXO fields of the PSBT. An error is returned if an input is specified that
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// does not contain any UTXO information.
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func SumUtxoInputValues(packet *Packet) (int64, error) {
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// We take the TX ins of the unsigned TX as the truth for how many
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// inputs there should be, as the fields in the extra data part of the
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// PSBT can be empty.
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if len(packet.UnsignedTx.TxIn) != len(packet.Inputs) {
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return 0, fmt.Errorf("TX input length doesn't match PSBT " +
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"input length")
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}
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inputSum := int64(0)
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for idx, in := range packet.Inputs {
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switch {
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case in.WitnessUtxo != nil:
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// Witness UTXOs only need to reference the TxOut.
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inputSum += in.WitnessUtxo.Value
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case in.NonWitnessUtxo != nil:
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// Non-witness UTXOs reference to the whole transaction
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// the UTXO resides in.
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utxOuts := in.NonWitnessUtxo.TxOut
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txIn := packet.UnsignedTx.TxIn[idx]
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// Check that utxOuts actually has enough space to
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// contain the previous outpoint's index.
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opIdx := txIn.PreviousOutPoint.Index
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if opIdx >= uint32(len(utxOuts)) {
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return 0, fmt.Errorf("input %d has malformed "+
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"TxOut field", idx)
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}
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inputSum += utxOuts[txIn.PreviousOutPoint.Index].Value
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default:
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return 0, fmt.Errorf("input %d has no UTXO information",
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idx)
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}
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}
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return inputSum, nil
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}
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// TxOutsEqual returns true if two transaction outputs are equal.
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func TxOutsEqual(out1, out2 *wire.TxOut) bool {
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if out1 == nil || out2 == nil {
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return out1 == out2
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}
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return out1.Value == out2.Value &&
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bytes.Equal(out1.PkScript, out2.PkScript)
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}
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// VerifyOutputsEqual verifies that the two slices of transaction outputs are
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// deep equal to each other. We do the length check and manual loop to provide
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// better error messages to the user than just returning "not equal".
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func VerifyOutputsEqual(outs1, outs2 []*wire.TxOut) error {
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if len(outs1) != len(outs2) {
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return fmt.Errorf("number of outputs are different")
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}
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for idx, out := range outs1 {
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// There is a byte slice in the output so we can't use the
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// equality operator.
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if !TxOutsEqual(out, outs2[idx]) {
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return fmt.Errorf("output %d is different", idx)
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}
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}
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return nil
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}
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// VerifyInputPrevOutpointsEqual verifies that the previous outpoints of the
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// two slices of transaction inputs are deep equal to each other. We do the
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// length check and manual loop to provide better error messages to the user
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// than just returning "not equal".
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func VerifyInputPrevOutpointsEqual(ins1, ins2 []*wire.TxIn) error {
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if len(ins1) != len(ins2) {
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return fmt.Errorf("number of inputs are different")
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}
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for idx, in := range ins1 {
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if in.PreviousOutPoint != ins2[idx].PreviousOutPoint {
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return fmt.Errorf("previous outpoint of input %d is "+
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"different", idx)
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}
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}
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return nil
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}
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// VerifyInputOutputLen makes sure a packet is non-nil, contains a non-nil wire
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// transaction and that the wire input/output lengths match the partial input/
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// output lengths. A caller also can specify if they expect any inputs and/or
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// outputs to be contained in the packet.
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func VerifyInputOutputLen(packet *Packet, needInputs, needOutputs bool) error {
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if packet == nil || packet.UnsignedTx == nil {
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return fmt.Errorf("PSBT packet cannot be nil")
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}
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if len(packet.UnsignedTx.TxIn) != len(packet.Inputs) {
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return fmt.Errorf("invalid PSBT, wire inputs don't match " +
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"partial inputs")
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}
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if len(packet.UnsignedTx.TxOut) != len(packet.Outputs) {
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return fmt.Errorf("invalid PSBT, wire outputs don't match " +
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"partial outputs")
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}
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if needInputs && len(packet.UnsignedTx.TxIn) == 0 {
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return fmt.Errorf("PSBT packet must contain at least one " +
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"input")
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}
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if needOutputs && len(packet.UnsignedTx.TxOut) == 0 {
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return fmt.Errorf("PSBT packet must contain at least one " +
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"output")
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}
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return nil
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}
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// NewFromSignedTx is a utility function to create a packet from an
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// already-signed transaction. Returned are: an unsigned transaction
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// serialization, a list of scriptSigs, one per input, and a list of witnesses,
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// one per input.
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func NewFromSignedTx(tx *wire.MsgTx) (*Packet, [][]byte,
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[]wire.TxWitness, error) {
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scriptSigs := make([][]byte, 0, len(tx.TxIn))
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witnesses := make([]wire.TxWitness, 0, len(tx.TxIn))
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tx2 := tx.Copy()
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// Blank out signature info in inputs
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for i, tin := range tx2.TxIn {
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tin.SignatureScript = nil
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scriptSigs = append(scriptSigs, tx.TxIn[i].SignatureScript)
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tin.Witness = nil
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witnesses = append(witnesses, tx.TxIn[i].Witness)
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}
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// Outputs always contain: (value, scriptPubkey) so don't need
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// amending. Now tx2 is tx with all signing data stripped out
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unsignedPsbt, err := NewFromUnsignedTx(tx2)
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if err != nil {
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return nil, nil, nil, err
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}
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return unsignedPsbt, scriptSigs, witnesses, nil
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}
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