@Test public void oneTx() throws Exception { // Check basic tx serialization. Coin v1 = COIN; Transaction t1 = createFakeTx(params, v1, myAddress); t1.getConfidence().markBroadcastBy(new PeerAddress(InetAddress.getByName("1.2.3.4"))); t1.getConfidence().markBroadcastBy(new PeerAddress(InetAddress.getByName("5.6.7.8"))); t1.getConfidence().setSource(TransactionConfidence.Source.NETWORK); myWallet.receivePending(t1, null); Wallet wallet1 = roundTrip(myWallet); assertEquals(1, wallet1.getTransactions(true).size()); assertEquals(v1, wallet1.getBalance(Wallet.BalanceType.ESTIMATED)); Transaction t1copy = wallet1.getTransaction(t1.getHash()); assertArrayEquals(t1.bitcoinSerialize(), t1copy.bitcoinSerialize()); assertEquals(2, t1copy.getConfidence().numBroadcastPeers()); assertEquals(TransactionConfidence.Source.NETWORK, t1copy.getConfidence().getSource()); Protos.Wallet walletProto = new WalletProtobufSerializer().walletToProto(myWallet); assertEquals(Protos.Key.Type.ORIGINAL, walletProto.getKey(0).getType()); assertEquals(0, walletProto.getExtensionCount()); assertEquals(1, walletProto.getTransactionCount()); assertEquals(6, walletProto.getKeyCount()); Protos.Transaction t1p = walletProto.getTransaction(0); assertEquals(0, t1p.getBlockHashCount()); assertArrayEquals(t1.getHash().getBytes(), t1p.getHash().toByteArray()); assertEquals(Protos.Transaction.Pool.PENDING, t1p.getPool()); assertFalse(t1p.hasLockTime()); assertFalse(t1p.getTransactionInput(0).hasSequence()); assertArrayEquals( t1.getInputs().get(0).getOutpoint().getHash().getBytes(), t1p.getTransactionInput(0).getTransactionOutPointHash().toByteArray()); assertEquals(0, t1p.getTransactionInput(0).getTransactionOutPointIndex()); assertEquals(t1p.getTransactionOutput(0).getValue(), v1.value); }
private WalletTransaction connectTransactionOutputs( org.bitcoinj.wallet.Protos.Transaction txProto) throws UnreadableWalletException { Transaction tx = txMap.get(txProto.getHash()); final WalletTransaction.Pool pool; switch (txProto.getPool()) { case DEAD: pool = WalletTransaction.Pool.DEAD; break; case PENDING: pool = WalletTransaction.Pool.PENDING; break; case SPENT: pool = WalletTransaction.Pool.SPENT; break; case UNSPENT: pool = WalletTransaction.Pool.UNSPENT; break; // Upgrade old wallets: inactive pool has been merged with the pending pool. // Remove this some time after 0.9 is old and everyone has upgraded. // There should not be any spent outputs in this tx as old wallets would not allow them to // be spent // in this state. case INACTIVE: case PENDING_INACTIVE: pool = WalletTransaction.Pool.PENDING; break; default: throw new UnreadableWalletException("Unknown transaction pool: " + txProto.getPool()); } for (int i = 0; i < tx.getOutputs().size(); i++) { TransactionOutput output = tx.getOutputs().get(i); final Protos.TransactionOutput transactionOutput = txProto.getTransactionOutput(i); if (transactionOutput.hasSpentByTransactionHash()) { final ByteString spentByTransactionHash = transactionOutput.getSpentByTransactionHash(); Transaction spendingTx = txMap.get(spentByTransactionHash); if (spendingTx == null) { throw new UnreadableWalletException( String.format( "Could not connect %s to %s", tx.getHashAsString(), byteStringToHash(spentByTransactionHash))); } final int spendingIndex = transactionOutput.getSpentByTransactionIndex(); TransactionInput input = checkNotNull(spendingTx.getInput(spendingIndex)); input.connect(output); } } if (txProto.hasConfidence()) { Protos.TransactionConfidence confidenceProto = txProto.getConfidence(); TransactionConfidence confidence = tx.getConfidence(); readConfidence(tx, confidenceProto, confidence); } return new WalletTransaction(pool, tx); }
public static boolean isSelectable(Transaction tx) { // Only pick chain-included transactions, or transactions that are ours and pending. TransactionConfidence confidence = tx.getConfidence(); TransactionConfidence.ConfidenceType type = confidence.getConfidenceType(); return type.equals(TransactionConfidence.ConfidenceType.BUILDING) || type.equals(TransactionConfidence.ConfidenceType.PENDING) && confidence.getSource().equals(TransactionConfidence.Source.SELF) && // In regtest mode we expect to have only one peer, so we won't see transactions // propagate. // TODO: The value 1 below dates from a time when transactions we broadcast *to* were // counted, set to 0 (confidence.numBroadcastPeers() > 1 || tx.getParams().getId().equals(NetworkParameters.ID_REGTEST)); }
@Test public void doubleSpend() throws Exception { // Check that we can serialize double spends correctly, as this is a slightly tricky case. FakeTxBuilder.DoubleSpends doubleSpends = FakeTxBuilder.createFakeDoubleSpendTxns(params, myAddress); // t1 spends to our wallet. myWallet.receivePending(doubleSpends.t1, null); // t2 rolls back t1 and spends somewhere else. myWallet.receiveFromBlock(doubleSpends.t2, null, BlockChain.NewBlockType.BEST_CHAIN, 0); Wallet wallet1 = roundTrip(myWallet); assertEquals(1, wallet1.getTransactions(true).size()); Transaction t1 = wallet1.getTransaction(doubleSpends.t1.getHash()); assertEquals(ConfidenceType.DEAD, t1.getConfidence().getConfidenceType()); assertEquals(Coin.ZERO, wallet1.getBalance()); // TODO: Wallet should store overriding transactions even if they are not wallet-relevant. // assertEquals(doubleSpends.t2, t1.getConfidence().getOverridingTransaction()); }
@Override public void deserializeWalletExtension(Wallet containingWallet, byte[] data) throws Exception { lock.lock(); try { checkState(this.containingWallet == null || this.containingWallet == containingWallet); this.containingWallet = containingWallet; NetworkParameters params = containingWallet.getParams(); ClientState.StoredClientPaymentChannels states = ClientState.StoredClientPaymentChannels.parseFrom(data); for (ClientState.StoredClientPaymentChannel storedState : states.getChannelsList()) { Transaction refundTransaction = params .getDefaultSerializer() .makeTransaction(storedState.getRefundTransaction().toByteArray()); refundTransaction.getConfidence().setSource(TransactionConfidence.Source.SELF); ECKey myKey = (storedState.getMyKey().isEmpty()) ? containingWallet.findKeyFromPubKey(storedState.getMyPublicKey().toByteArray()) : ECKey.fromPrivate(storedState.getMyKey().toByteArray()); StoredClientChannel channel = new StoredClientChannel( Sha256Hash.wrap(storedState.getId().toByteArray()), params .getDefaultSerializer() .makeTransaction(storedState.getContractTransaction().toByteArray()), refundTransaction, myKey, Coin.valueOf(storedState.getValueToMe()), Coin.valueOf(storedState.getRefundFees()), false); if (storedState.hasCloseTransactionHash()) { Sha256Hash closeTxHash = Sha256Hash.wrap(storedState.getCloseTransactionHash().toByteArray()); channel.close = containingWallet.getTransaction(closeTxHash); } putChannel(channel, false); } } finally { lock.unlock(); } }
/** * Called when the client provides us with a new signature and wishes to increment total payment * by size. Verifies the provided signature and only updates values if everything checks out. If * the new refundSize is not the lowest we have seen, it is simply ignored. * * @param refundSize How many satoshis of the original contract are refunded to the client (the * rest are ours) * @param signatureBytes The new signature spending the multi-sig contract to a new payment * transaction * @throws VerificationException If the signature does not verify or size is out of range (incl * being rejected by the network as dust). * @return true if there is more value left on the channel, false if it is now fully used up. */ public synchronized boolean incrementPayment(Coin refundSize, byte[] signatureBytes) throws VerificationException, ValueOutOfRangeException, InsufficientMoneyException { checkState(state == State.READY); checkNotNull(refundSize); checkNotNull(signatureBytes); TransactionSignature signature = TransactionSignature.decodeFromBitcoin(signatureBytes, true); // We allow snapping to zero for the payment amount because it's treated specially later, but // not less than // the dust level because that would prevent the transaction from being relayed/mined. final boolean fullyUsedUp = refundSize.equals(Coin.ZERO); if (refundSize.compareTo(clientOutput.getMinNonDustValue()) < 0 && !fullyUsedUp) throw new ValueOutOfRangeException( "Attempt to refund negative value or value too small to be accepted by the network"); Coin newValueToMe = totalValue.subtract(refundSize); if (newValueToMe.signum() < 0) throw new ValueOutOfRangeException("Attempt to refund more than the contract allows."); if (newValueToMe.compareTo(bestValueToMe) < 0) throw new ValueOutOfRangeException("Attempt to roll back payment on the channel."); // Get the wallet's copy of the multisigContract (ie with confidence information), if this is // null, the wallet // was not connected to the peergroup when the contract was broadcast (which may cause issues // down the road, and // disables our double-spend check next) Transaction walletContract = wallet.getTransaction(multisigContract.getHash()); checkNotNull( walletContract, "Wallet did not contain multisig contract {} after state was marked READY", multisigContract.getHash()); // Note that we check for DEAD state here, but this test is essentially useless in production // because we will // miss most double-spends due to bloom filtering right now anyway. This will eventually fixed // by network-wide // double-spend notifications, so we just wait instead of attempting to add all dependant // outpoints to our bloom // filters (and probably missing lots of edge-cases). if (walletContract.getConfidence().getConfidenceType() == TransactionConfidence.ConfidenceType.DEAD) { close(); throw new VerificationException("Multisig contract was double-spent"); } Transaction.SigHash mode; // If the client doesn't want anything back, they shouldn't sign any outputs at all. if (fullyUsedUp) mode = Transaction.SigHash.NONE; else mode = Transaction.SigHash.SINGLE; if (signature.sigHashMode() != mode || !signature.anyoneCanPay()) throw new VerificationException( "New payment signature was not signed with the right SIGHASH flags."); Wallet.SendRequest req = makeUnsignedChannelContract(newValueToMe); // Now check the signature is correct. // Note that the client must sign with SIGHASH_{SINGLE/NONE} | SIGHASH_ANYONECANPAY to allow us // to add additional // inputs (in case we need to add significant fee, or something...) and any outputs we want to // pay to. Sha256Hash sighash = req.tx.hashForSignature(0, multisigScript, mode, true); if (!clientKey.verify(sighash, signature)) throw new VerificationException("Signature does not verify on tx\n" + req.tx); bestValueToMe = newValueToMe; bestValueSignature = signatureBytes; updateChannelInWallet(); return !fullyUsedUp; }
/** * function that updates debit/credit/balance/price in fiat and Transaction History table * * @param services */ private void updateWalletsSummary(List<WalletService> services) { Coin totalDebit = Coin.ZERO; Coin totalCredit = Coin.ZERO; Coin totalBalance = Coin.ZERO; double priceInFiat = 0.00d; String confidence = ""; // update debit/credit/balance and price in fiat List<TransactionWrapper> transactions = new ArrayList<>(); for (WalletService service : services) { try { Wallet wallet = service.getWallet(); totalBalance = totalBalance.add(wallet.getBalance()); for (Transaction trx : wallet.getTransactionsByTime()) { if (trx.getConfidence().equals(TransactionConfidence.ConfidenceType.DEAD)) continue; Coin amount = trx.getValue(wallet); if (amount.isPositive()) { totalCredit = totalCredit.add(amount); } else { totalDebit = totalDebit.add(amount); } transactions.add(new TransactionWrapper(trx, wallet, amount)); } } catch (Exception e) { logger.error("Unable to update wallet details"); } } pnlDashboardStats.setTotalBalance(MonetaryFormat.BTC.noCode().format(totalBalance).toString()); // pnlDashboardStats.setTotalDebit(MonetaryFormat.BTC.noCode().format(totalDebit).toString()); // pnlDashboardStats.setTotalCredit(MonetaryFormat.BTC.noCode().format(totalCredit).toString()); priceInFiat = Double.valueOf(MonetaryFormat.BTC.noCode().format(totalBalance).toString()); priceInFiat *= BitcoinCurrencyRateApi.get().getCurrentRateValue(); pnlDashboardStats.setPriceInFiat( String.format("%.2f", priceInFiat), "", ConfigManager.config().getSelectedCurrency()); pnlDashboardStats.setExchangeRate( ConfigManager.config().getSelectedCurrency(), String.format("%.2f", BitcoinCurrencyRateApi.get().getCurrentRateValue())); Collections.sort( transactions, new Comparator<TransactionWrapper>() { @Override public int compare(TransactionWrapper o1, TransactionWrapper o2) { return o2.getTransaction() .getUpdateTime() .compareTo(o1.getTransaction().getUpdateTime()); } }); // update Transaction History table DefaultTableModel model = (DefaultTableModel) tblTransactions.getModel(); model.setRowCount(0); for (TransactionWrapper wrapper : transactions) { Transaction transaction = wrapper.getTransaction(); if (transaction.getConfidence().getDepthInBlocks() > 6) confidence = "<html>6<sup>+</sup></html>"; else confidence = transaction.getConfidence().getDepthInBlocks() + ""; Coin amount = wrapper.getAmount(); Coin fee = transaction.getFee(); String amountString = MonetaryFormat.BTC.noCode().format(amount).toString(); String feeString = fee != null ? MonetaryFormat.BTC.noCode().format(fee).toString() : "0.00"; Address from = transaction.getInput(0).getFromAddress(); Address to = transaction .getOutput(0) .getAddressFromP2PKHScript(wrapper.getWallet().getNetworkParameters()); boolean credit = amount.isPositive(); model.addRow( new Object[] { Utils.formatTransactionDate(transaction.getUpdateTime()), from, to, credit ? "Credit" : "Debit", amountString, feeString, "", confidence }); } Coin balanceAfter = Coin.ZERO; for (int index = transactions.size() - 1; index >= 0; index--) { balanceAfter = balanceAfter.add(Coin.parseCoin((String) model.getValueAt(index, 4))); model.setValueAt(MonetaryFormat.BTC.noCode().format(balanceAfter).toString(), index, 6); } }
private static Protos.Transaction makeTxProto(WalletTransaction wtx) { Transaction tx = wtx.getTransaction(); Protos.Transaction.Builder txBuilder = Protos.Transaction.newBuilder(); txBuilder .setPool(getProtoPool(wtx)) .setHash(hashToByteString(tx.getHash())) .setVersion((int) tx.getVersion()); if (tx.getUpdateTime() != null) { txBuilder.setUpdatedAt(tx.getUpdateTime().getTime()); } if (tx.getLockTime() > 0) { txBuilder.setLockTime((int) tx.getLockTime()); } // Handle inputs. for (TransactionInput input : tx.getInputs()) { Protos.TransactionInput.Builder inputBuilder = Protos.TransactionInput.newBuilder() .setScriptBytes(ByteString.copyFrom(input.getScriptBytes())) .setTransactionOutPointHash(hashToByteString(input.getOutpoint().getHash())) .setTransactionOutPointIndex((int) input.getOutpoint().getIndex()); if (input.hasSequence()) inputBuilder.setSequence((int) input.getSequenceNumber()); if (input.getValue() != null) inputBuilder.setValue(input.getValue().value); txBuilder.addTransactionInput(inputBuilder); } // Handle outputs. for (TransactionOutput output : tx.getOutputs()) { Protos.TransactionOutput.Builder outputBuilder = Protos.TransactionOutput.newBuilder() .setScriptBytes(ByteString.copyFrom(output.getScriptBytes())) .setValue(output.getValue().value); final TransactionInput spentBy = output.getSpentBy(); if (spentBy != null) { Sha256Hash spendingHash = spentBy.getParentTransaction().getHash(); int spentByTransactionIndex = spentBy.getParentTransaction().getInputs().indexOf(spentBy); outputBuilder .setSpentByTransactionHash(hashToByteString(spendingHash)) .setSpentByTransactionIndex(spentByTransactionIndex); } txBuilder.addTransactionOutput(outputBuilder); } // Handle which blocks tx was seen in. final Map<Sha256Hash, Integer> appearsInHashes = tx.getAppearsInHashes(); if (appearsInHashes != null) { for (Map.Entry<Sha256Hash, Integer> entry : appearsInHashes.entrySet()) { txBuilder.addBlockHash(hashToByteString(entry.getKey())); txBuilder.addBlockRelativityOffsets(entry.getValue()); } } if (tx.hasConfidence()) { TransactionConfidence confidence = tx.getConfidence(); Protos.TransactionConfidence.Builder confidenceBuilder = Protos.TransactionConfidence.newBuilder(); writeConfidence(txBuilder, confidence, confidenceBuilder); } Protos.Transaction.Purpose purpose; switch (tx.getPurpose()) { case UNKNOWN: purpose = Protos.Transaction.Purpose.UNKNOWN; break; case USER_PAYMENT: purpose = Protos.Transaction.Purpose.USER_PAYMENT; break; case KEY_ROTATION: purpose = Protos.Transaction.Purpose.KEY_ROTATION; break; case ASSURANCE_CONTRACT_CLAIM: purpose = Protos.Transaction.Purpose.ASSURANCE_CONTRACT_CLAIM; break; case ASSURANCE_CONTRACT_PLEDGE: purpose = Protos.Transaction.Purpose.ASSURANCE_CONTRACT_PLEDGE; break; case ASSURANCE_CONTRACT_STUB: purpose = Protos.Transaction.Purpose.ASSURANCE_CONTRACT_STUB; break; default: throw new RuntimeException("New tx purpose serialization not implemented."); } txBuilder.setPurpose(purpose); ExchangeRate exchangeRate = tx.getExchangeRate(); if (exchangeRate != null) { Protos.ExchangeRate.Builder exchangeRateBuilder = Protos.ExchangeRate.newBuilder() .setCoinValue(exchangeRate.coin.value) .setFiatValue(exchangeRate.fiat.value) .setFiatCurrencyCode(exchangeRate.fiat.currencyCode); txBuilder.setExchangeRate(exchangeRateBuilder); } if (tx.getMemo() != null) txBuilder.setMemo(tx.getMemo()); return txBuilder.build(); }
@Test public void testAppearedAtChainHeightDepthAndWorkDone() throws Exception { // Test the TransactionConfidence appearedAtChainHeight, depth and workDone field are stored. BlockChain chain = new BlockChain(params, myWallet, new MemoryBlockStore(params)); final ArrayList<Transaction> txns = new ArrayList<Transaction>(2); myWallet.addEventListener( new AbstractWalletEventListener() { @Override public void onCoinsReceived( Wallet wallet, Transaction tx, Coin prevBalance, Coin newBalance) { txns.add(tx); } }); // Start by building two blocks on top of the genesis block. Block b1 = params.getGenesisBlock().createNextBlock(myAddress); BigInteger work1 = b1.getWork(); assertTrue(work1.signum() > 0); Block b2 = b1.createNextBlock(myAddress); BigInteger work2 = b2.getWork(); assertTrue(work2.signum() > 0); assertTrue(chain.add(b1)); assertTrue(chain.add(b2)); // We now have the following chain: // genesis -> b1 -> b2 // Check the transaction confidence levels are correct before wallet roundtrip. Threading.waitForUserCode(); assertEquals(2, txns.size()); TransactionConfidence confidence0 = txns.get(0).getConfidence(); TransactionConfidence confidence1 = txns.get(1).getConfidence(); assertEquals(1, confidence0.getAppearedAtChainHeight()); assertEquals(2, confidence1.getAppearedAtChainHeight()); assertEquals(2, confidence0.getDepthInBlocks()); assertEquals(1, confidence1.getDepthInBlocks()); // Roundtrip the wallet and check it has stored the depth and workDone. Wallet rebornWallet = roundTrip(myWallet); Set<Transaction> rebornTxns = rebornWallet.getTransactions(false); assertEquals(2, rebornTxns.size()); // The transactions are not guaranteed to be in the same order so sort them to be in chain // height order if required. Iterator<Transaction> it = rebornTxns.iterator(); Transaction txA = it.next(); Transaction txB = it.next(); Transaction rebornTx0, rebornTx1; if (txA.getConfidence().getAppearedAtChainHeight() == 1) { rebornTx0 = txA; rebornTx1 = txB; } else { rebornTx0 = txB; rebornTx1 = txA; } TransactionConfidence rebornConfidence0 = rebornTx0.getConfidence(); TransactionConfidence rebornConfidence1 = rebornTx1.getConfidence(); assertEquals(1, rebornConfidence0.getAppearedAtChainHeight()); assertEquals(2, rebornConfidence1.getAppearedAtChainHeight()); assertEquals(2, rebornConfidence0.getDepthInBlocks()); assertEquals(1, rebornConfidence1.getDepthInBlocks()); }