jak podpisać bitcoin psbt z księgą?


11

Próbuję podpisać transakcję Psbt z bitcoinjs-lib zgodnie z tym, co tutaj znalazłem:

https://github.com/helperbit/helperbit-wallet/blob/master/app/components/dashboard.wallet/bitcoin.service/ledger.ts

Sprawdziłem, czy skompresowany publicKey zarówno z księgi głównej, jak i bitcoinjsLib zwrócił tę samą wartość.

Mógłbym podpisać go za pomocą ECPair bitcoinjs-lib, ale kiedy próbuję podpisać go za pomocą księgi rachunkowej, zawsze jest on nieprawidłowy.

Czy ktoś może mi pomóc wskazać, gdzie popełniłem błąd?

Zmienne te zostały już wspomniane w poniższym kodzie, ale dla jasności:

- mnemonics: 
abandon abandon abandon abandon abandon abandon abandon abandon abandon abandon abandon about

- previousTx:
02000000000101869362410c61a69ab9390b2167d08219662196e869626e8b0350f1a8e4075efb0100000017160014ef3fdddccdb6b53e6dd1f5a97299a6ba2e1c11c3ffffffff0240420f000000000017a914f748afee815f78f97672be5a9840056d8ed77f4887df9de6050000000017a9142ff4aa6ffa987335c7bdba58ef4cbfecbe9e49938702473044022061a01bf0fbac4650a9b3d035b3d9282255a5c6040aa1d04fd9b6b52ed9f4d20a022064e8e2739ef532e6b2cb461321dd20f5a5d63cf34da3056c428475d42c9aff870121025fb5240daab4cee5fa097eef475f3f2e004f7be702c421b6607d8afea1affa9b00000000

- paths:
["0'/0/0"]

- redeemScript: (non-multisig segwit)
00144328adace54072cd069abf108f97cf80420b212b

To mój minimalny odtwarzalny kod, jaki mam.

/* tslint:disable */
// @ts-check
require('regenerator-runtime');
const bip39 = require('bip39');
const { default: Transport } = require('@ledgerhq/hw-transport-node-hid');
const { default: AppBtc } = require('@ledgerhq/hw-app-btc');
const bitcoin = require('bitcoinjs-lib');
const mnemonics = 'abandon abandon abandon abandon abandon abandon abandon abandon abandon abandon abandon about';
const NETWORK = bitcoin.networks.regtest;

/**
 * @param {string} pk 
 * @returns {string}
 */
function compressPublicKey(pk) {
  const { publicKey } = bitcoin.ECPair.fromPublicKey(Buffer.from(pk, 'hex'));
  return publicKey.toString('hex');
}

/** @returns {Promise<any>} */
async function appBtc() {
  const transport = await Transport.create();
  const btc = new AppBtc(transport);
  return btc;
}

const signTransaction = async() => {
  const ledger = await appBtc();
  const paths = ["0'/0/0"];
  const [ path ] = paths;
  const previousTx = "02000000000101869362410c61a69ab9390b2167d08219662196e869626e8b0350f1a8e4075efb0100000017160014ef3fdddccdb6b53e6dd1f5a97299a6ba2e1c11c3ffffffff0240420f000000000017a914f748afee815f78f97672be5a9840056d8ed77f4887df9de6050000000017a9142ff4aa6ffa987335c7bdba58ef4cbfecbe9e49938702473044022061a01bf0fbac4650a9b3d035b3d9282255a5c6040aa1d04fd9b6b52ed9f4d20a022064e8e2739ef532e6b2cb461321dd20f5a5d63cf34da3056c428475d42c9aff870121025fb5240daab4cee5fa097eef475f3f2e004f7be702c421b6607d8afea1affa9b00000000"
  const utxo = bitcoin.Transaction.fromHex(previousTx);
  const segwit = utxo.hasWitnesses();
  const txIndex = 0;

  // ecpairs things.
  const seed = await bip39.mnemonicToSeed(mnemonics);
  const node = bitcoin.bip32.fromSeed(seed, NETWORK);

  const ecPrivate = node.derivePath(path);
  const ecPublic = bitcoin.ECPair.fromPublicKey(ecPrivate.publicKey, { network: NETWORK });
  const p2wpkh = bitcoin.payments.p2wpkh({ pubkey: ecPublic.publicKey, network: NETWORK });
  const p2sh = bitcoin.payments.p2sh({ redeem: p2wpkh, network: NETWORK });
  const redeemScript = p2sh.redeem.output;
  const fromLedger = await ledger.getWalletPublicKey(path, { format: 'p2sh' });
  const ledgerPublicKey = compressPublicKey(fromLedger.publicKey);
  const bitcoinJsPublicKey = ecPublic.publicKey.toString('hex');
  console.log({ ledgerPublicKey, bitcoinJsPublicKey, address: p2sh.address, segwit, fromLedger, redeemScript: redeemScript.toString('hex') });

  var tx1 = ledger.splitTransaction(previousTx, true);
  const psbt = new bitcoin.Psbt({ network: NETWORK });
  psbt.addInput({
    hash: utxo.getId(),
    index: txIndex,
    nonWitnessUtxo: Buffer.from(previousTx, 'hex'),
    redeemScript,
  });
  psbt.addOutput({
    address: 'mgWUuj1J1N882jmqFxtDepEC73Rr22E9GU',
    value: 5000,
  });
  psbt.setMaximumFeeRate(1000 * 1000 * 1000); // ignore maxFeeRate we're testnet anyway.
  psbt.setVersion(2);
  /** @type {string} */
  // @ts-ignore
  const newTx = psbt.__CACHE.__TX.toHex();
  console.log({ newTx });

  const splitNewTx = await ledger.splitTransaction(newTx, true);
  const outputScriptHex = await ledger.serializeTransactionOutputs(splitNewTx).toString("hex");
  const expectedOutscriptHex = '0188130000000000001976a9140ae1441568d0d293764a347b191025c51556cecd88ac';
  // stolen from: https://github.com/LedgerHQ/ledgerjs/blob/master/packages/hw-app-btc/tests/Btc.test.js
  console.log({ outputScriptHex, expectedOutscriptHex, eq: expectedOutscriptHex === outputScriptHex });

  const inputs = [ [tx1, 0, p2sh.redeem.output.toString('hex') /** ??? */] ];
  const ledgerSignatures = await ledger.signP2SHTransaction(
    inputs,
    paths,
    outputScriptHex,
    0, // lockTime,
    undefined, // sigHashType = SIGHASH_ALL ???
    utxo.hasWitnesses(),
    2, // version??,
  );

  const signer = {
    network: NETWORK,
    publicKey: ecPrivate.publicKey,
    /** @param {Buffer} $hash */
    sign: ($hash) => {
      const expectedSignature = ecPrivate.sign($hash); // just for comparison.
      const [ ledgerSignature0 ] = ledgerSignatures;
      const decodedLedgerSignature = bitcoin.script.signature.decode(Buffer.from(ledgerSignature0, 'hex'));
      console.log({
        $hash: $hash.toString('hex'),
        expectedSignature: expectedSignature.toString('hex'),
        actualSignature: decodedLedgerSignature.signature.toString('hex'),
      });
      // return signature;
      return decodedLedgerSignature.signature;
    },
  };
  psbt.signInput(0, signer);
  const validated = psbt.validateSignaturesOfInput(0);
  psbt.finalizeAllInputs();
  const hex = psbt.extractTransaction().toHex();
  console.log({ validated, hex });
};

if (process.argv[1] === __filename) {
  signTransaction().catch(console.error)
}

Odpowiedzi:


1

Ooof, wreszcie udało się.

Mój błąd polegał na tym, że próbowałem podpisać p2sh-p2ms, postępując zgodnie z instrukcją dotyczącą podpisywania p2sh-p2wsh-p2ms.

Poza tym brakujący ostatni 2 bit (01), który, jak sądzę, reprezentuje SIGHASH_ALL, spowodował błąd przy próbie odkodowania podpisu.

to jest mój sfinalizowany przykład działania.

// @ts-check
require('regenerator-runtime');
const bip39 = require('bip39');
const { default: Transport } = require('@ledgerhq/hw-transport-node-hid');
const { default: AppBtc } = require('@ledgerhq/hw-app-btc');
const serializer = require('@ledgerhq/hw-app-btc/lib/serializeTransaction');
const bitcoin = require('bitcoinjs-lib');
const mnemonics = 'abandon abandon abandon abandon abandon abandon abandon abandon abandon abandon abandon about';
const NETWORK = bitcoin.networks.regtest;
const DEFAULT_LOCK_TIME = 0;
const SIGHASH_ALL = 1;
const PATHS = ["m/49'/1'/0'/0/0", "m/49'/1'/0'/0/1"]; 

async function appBtc() {
  const transport = await Transport.create();
  const btc = new AppBtc(transport);
  return btc;
}

/**
 * @param {string} pk 
 * @returns {string}
 */
function compressPublicKey(pk) {
  const {
    publicKey
  } = bitcoin.ECPair.fromPublicKey(Buffer.from(pk, 'hex'));
  return publicKey.toString('hex');
}

/**
 * @param {AppBtc} ledger
 * @param {bitcoin.Transaction} tx
 */
function splitTransaction(ledger, tx) {
  return ledger.splitTransaction(tx.toHex(), tx.hasWitnesses());
}

const signTransaction = async() => {
  const seed = await bip39.mnemonicToSeed(mnemonics);
  const node = bitcoin.bip32.fromSeed(seed, NETWORK);
  const signers = PATHS.map((p) => node.derivePath(p));
  const publicKeys = signers.map((s) => s.publicKey);
  const p2ms = bitcoin.payments.p2ms({ pubkeys: publicKeys, network: NETWORK, m: 1 });
  const p2shP2ms = bitcoin.payments.p2sh({ redeem: p2ms, network: NETWORK });
  const previousTx = '02000000000101588e8fc89afea9adb79de2650f0cdba762f7d0880c29a1f20e7b468f97da9f850100000017160014345766130a8f8e83aef8621122ca14fff88e6d51ffffffff0240420f000000000017a914a0546d83e5f8876045d7025a230d87bf69db893287df9de6050000000017a9142ff4aa6ffa987335c7bdba58ef4cbfecbe9e49938702483045022100c654271a891af98e46ca4d82ede8cccb0503a430e50745f959274294c98030750220331b455fed13ff4286f6db699eca06aa0c1c37c45c9f3aed3a77a3b0187ff4ac0121037ebcf3cf122678b9dc89b339017c5b76bee9fedd068c7401f4a8eb1d7e841c3a00000000';
  const utxo = bitcoin.Transaction.fromHex(previousTx);
  const txIndex = 0;
  const destination = p2shP2ms;
  const redeemScript = destination.redeem.output;
  // const witnessScript = destination.redeem.redeem.output;
  const ledgerRedeemScript = redeemScript;
  // use witness script if the outgoing transaction was from a p2sh-p2wsh-p2ms instead of p2sh-p2ms
  const fee = 1000;
  /** @type {number} */
  // @ts-ignore
  const amount = utxo.outs[txIndex].value;
  const withdrawAmount = amount - fee;
  const psbt = new bitcoin.Psbt({ network: NETWORK });
  const version = 1;
  psbt.addInput({
    hash: utxo.getId(),
    index: txIndex,
    nonWitnessUtxo: utxo.toBuffer(),
    redeemScript,
  });
  psbt.addOutput({
    address: '2MsK2NdiVEPCjBMFWbjFvQ39mxWPMopp5vp',
    value: withdrawAmount
  });
  psbt.setVersion(version);
  /** @type {bitcoin.Transaction}  */
  // @ts-ignore
  const newTx = psbt.__CACHE.__TX;

  const ledger = await appBtc();
  const inLedgerTx = splitTransaction(ledger, utxo);
  const outLedgerTx = splitTransaction(ledger, newTx);
  const outputScriptHex = await serializer.serializeTransactionOutputs(outLedgerTx).toString('hex');

  /** @param {string} path */
  const signer = (path) => {
    const ecPrivate = node.derivePath(path);
    // actually only publicKey is needed, albeit ledger give an uncompressed one.
    // const { publicKey: uncompressedPublicKey } = await ledger.getWalletPublicKey(path);
    // const publicKey = compressPublicKey(publicKey);
    return {
      network: NETWORK,
      publicKey: ecPrivate.publicKey,
      /** @param {Buffer} $hash */
      sign: async ($hash) => {
        const ledgerTxSignatures = await ledger.signP2SHTransaction({
          inputs: [[inLedgerTx, txIndex, ledgerRedeemScript.toString('hex')]],
          associatedKeysets: [ path ],
          outputScriptHex,
          lockTime: DEFAULT_LOCK_TIME,
          segwit: newTx.hasWitnesses(),
          transactionVersion: version,
          sigHashType: SIGHASH_ALL,
        });
        const [ ledgerSignature ] = ledgerTxSignatures;
        const expectedSignature = ecPrivate.sign($hash);
        const finalSignature = (() => {
          if (newTx.hasWitnesses()) {
            return Buffer.from(ledgerSignature, 'hex');
          };
          return Buffer.concat([
            ledgerSignature,
            Buffer.from('01', 'hex'), // SIGHASH_ALL
          ]);
        })();
        console.log({
          expectedSignature: expectedSignature.toString('hex'),
          finalSignature: finalSignature.toString('hex'),
        });
        const { signature } = bitcoin.script.signature.decode(finalSignature);
        return signature;
      },
    };
  }
  await psbt.signInputAsync(0, signer(PATHS[0]));
  const validate = await psbt.validateSignaturesOfAllInputs();
  await psbt.finalizeAllInputs();
  const hex = psbt.extractTransaction().toHex();
  console.log({ validate, hex });
};

if (process.argv[1] === __filename) {
  signTransaction().catch(console.error)
}

0

Domyślam się, że masz spację w ciągu przekazaną do toByteArrayfunkcji. Ta funkcja nie przycina wejścia. Nie sprawdza również, czy długość wejściowa jest parzysta.


Hmm ... nie sądzę, że to jest problem, próbowałem użyć standardu Buffer.from, ale powyższy kod jest po prostu kopiowaniem kodu z odwołania, o którym wspomniałem powyżej, ponieważ wydaje się, że oryginalny kod powinien działać w przeglądarce.
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