Exemplo n.º 1
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// CreateTxChain creates a chain of zero-fee transactions (each subsequent
// transaction spends the entire amount from the previous one) with the first
// one spending the provided outpoint.  Each transaction spends the entire
// amount of the previous one and as such does not include any fees.
func (p *poolHarness) CreateTxChain(firstOutput spendableOutput, numTxns uint32) ([]*btcutil.Tx, error) {
	txChain := make([]*btcutil.Tx, 0, numTxns)
	prevOutPoint := firstOutput.outPoint
	spendableAmount := firstOutput.amount
	for i := uint32(0); i < numTxns; i++ {
		// Create the transaction using the previous transaction output
		// and paying the full amount to the payment address associated
		// with the harness.
		tx := wire.NewMsgTx(wire.TxVersion)
		tx.AddTxIn(&wire.TxIn{
			PreviousOutPoint: prevOutPoint,
			SignatureScript:  nil,
			Sequence:         wire.MaxTxInSequenceNum,
		})
		tx.AddTxOut(&wire.TxOut{
			PkScript: p.payScript,
			Value:    int64(spendableAmount),
		})

		// Sign the new transaction.
		sigScript, err := txscript.SignatureScript(tx, 0, p.payScript,
			txscript.SigHashAll, p.signKey, true)
		if err != nil {
			return nil, err
		}
		tx.TxIn[0].SignatureScript = sigScript

		txChain = append(txChain, btcutil.NewTx(tx))

		// Next transaction uses outputs from this one.
		prevOutPoint = wire.OutPoint{Hash: tx.TxHash(), Index: 0}
	}

	return txChain, nil
}
Exemplo n.º 2
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// CreateTransaction returns a fully signed transaction paying to the specified
// outputs while observing the desired fee rate. The passed fee rate should be
// expressed in satoshis-per-byte.
//
// This function is safe for concurrent access.
func (m *memWallet) CreateTransaction(outputs []*wire.TxOut, feeRate btcutil.Amount) (*wire.MsgTx, error) {
	m.Lock()
	defer m.Unlock()

	tx := wire.NewMsgTx()

	// Tally up the total amount to be sent in order to perform coin
	// selection shortly below.
	var outputAmt btcutil.Amount
	for _, output := range outputs {
		outputAmt += btcutil.Amount(output.Value)
		tx.AddTxOut(output)
	}

	// Attempt to fund the transaction with spendable utxos.
	if err := m.fundTx(tx, outputAmt, btcutil.Amount(feeRate)); err != nil {
		return nil, err
	}

	// Populate all the selected inputs with valid sigScript for spending.
	// Along the way record all outputs being spent in order to avoid a
	// potential double spend.
	spentOutputs := make([]*utxo, 0, len(tx.TxIn))
	for i, txIn := range tx.TxIn {
		outPoint := txIn.PreviousOutPoint
		utxo := m.utxos[outPoint]

		extendedKey, err := m.hdRoot.Child(utxo.keyIndex)
		if err != nil {
			return nil, err
		}

		privKey, err := extendedKey.ECPrivKey()
		if err != nil {
			return nil, err
		}

		sigScript, err := txscript.SignatureScript(tx, i, utxo.pkScript,
			txscript.SigHashAll, privKey, true)
		if err != nil {
			return nil, err
		}

		txIn.SignatureScript = sigScript

		spentOutputs = append(spentOutputs, utxo)
	}

	// As these outputs are now being spent by this newly created
	// transaction, mark the outputs are "locked". This action ensures
	// these outputs won't be double spent by any subsequent transactions.
	// These locked outputs can be freed via a call to UnlockOutputs.
	for _, utxo := range spentOutputs {
		utxo.isLocked = true
	}

	return tx, nil
}
Exemplo n.º 3
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// generateSig requires a transaction, a private key, and the bytes of the raw
// scriptPubKey. It will then generate a signature over all of the outputs of
// the provided tx. This is the last step of creating a valid transaction.
func generateSig(tx *wire.MsgTx, privkey *btcec.PrivateKey, scriptPubKey []byte) []byte {

	// The all important signature. Each input is documented below.
	scriptSig, err := txscript.SignatureScript(
		tx,                  // The tx to be signed.
		0,                   // The index of the txin the signature is for.
		scriptPubKey,        // The other half of the script from the PubKeyHash.
		txscript.SigHashAll, // The signature flags that indicate what the sig covers.
		privkey,             // The key to generate the signature with.
		true,                // The compress sig flag. This saves space on the blockchain.
	)
	if err != nil {
		log.Fatal(err)
	}

	return scriptSig
}
Exemplo n.º 4
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func (t *TxStore) SignThis(tx *wire.MsgTx) error {
	fmt.Printf("-= SignThis =-\n")

	// sort tx before signing.
	txsort.InPlaceSort(tx)

	sigs := make([][]byte, len(tx.TxIn))
	// first iterate over each input
	for j, in := range tx.TxIn {
		for k := uint32(0); k < uint32(len(t.Adrs)); k++ {
			child, err := t.rootPrivKey.Child(k + hdkeychain.HardenedKeyStart)
			if err != nil {
				return err
			}
			myadr, err := child.Address(t.Param)
			if err != nil {
				return err
			}
			adrScript, err := txscript.PayToAddrScript(myadr)
			if err != nil {
				return err
			}
			if bytes.Equal(adrScript, in.SignatureScript) {
				fmt.Printf("Hit; key %d matches input %d. Signing.\n", k, j)
				priv, err := child.ECPrivKey()
				if err != nil {
					return err
				}
				sigs[j], err = txscript.SignatureScript(
					tx, j, in.SignatureScript, txscript.SigHashAll, priv, true)
				if err != nil {
					return err
				}
				break
			}
		}
	}
	for i, s := range sigs {
		if s != nil {
			tx.TxIn[i].SignatureScript = s
		}
	}
	return nil
}
Exemplo n.º 5
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// CreateSignedTx creates a new signed transaction that consumes the provided
// inputs and generates the provided number of outputs by evenly splitting the
// total input amount.  All outputs will be to the payment script associated
// with the harness and all inputs are assumed to do the same.
func (p *poolHarness) CreateSignedTx(inputs []spendableOutput, numOutputs uint32) (*btcutil.Tx, error) {
	// Calculate the total input amount and split it amongst the requested
	// number of outputs.
	var totalInput btcutil.Amount
	for _, input := range inputs {
		totalInput += input.amount
	}
	amountPerOutput := int64(totalInput) / int64(numOutputs)
	remainder := int64(totalInput) - amountPerOutput*int64(numOutputs)

	tx := wire.NewMsgTx(wire.TxVersion)
	for _, input := range inputs {
		tx.AddTxIn(&wire.TxIn{
			PreviousOutPoint: input.outPoint,
			SignatureScript:  nil,
			Sequence:         wire.MaxTxInSequenceNum,
		})
	}
	for i := uint32(0); i < numOutputs; i++ {
		// Ensure the final output accounts for any remainder that might
		// be left from splitting the input amount.
		amount := amountPerOutput
		if i == numOutputs-1 {
			amount = amountPerOutput + remainder
		}
		tx.AddTxOut(&wire.TxOut{
			PkScript: p.payScript,
			Value:    amount,
		})
	}

	// Sign the new transaction.
	for i := range tx.TxIn {
		sigScript, err := txscript.SignatureScript(tx, i, p.payScript,
			txscript.SigHashAll, p.signKey, true)
		if err != nil {
			return nil, err
		}
		tx.TxIn[i].SignatureScript = sigScript
	}

	return btcutil.NewTx(tx), nil
}
Exemplo n.º 6
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// signRawTransaction requires a transaction, a private key, and the bytes of the raw
// scriptPubKey. It will then generate a signature over all of the outputs of
// the provided tx. This is the last step of creating a valid transaction.
func signRawTx(tx *Transaction, index int, wifPrivKey string, scriptPubKey []byte) ([]byte, error) {
	wif, err := btcutil.DecodeWIF(wifPrivKey)
	if err != nil {
		return []byte{}, err
	}

	// The all important signature. Each input is documented below.
	scriptSig, err := txscript.SignatureScript(
		&tx.MsgTx,           // The tx to be signed.
		index,               // The index of the txin the signature is for.
		scriptPubKey,        // The other half of the script from the PubKeyHash.
		txscript.SigHashAll, // The signature flags that indicate what the sig covers.
		wif.PrivKey,         // The key to generate the signature with.
		true,                // The compress sig flag. This saves space on the blockchain.
	)
	if err != nil {
		return []byte{}, err
	}
	return scriptSig, nil
}
Exemplo n.º 7
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// signMsgTx sets the SignatureScript for every item in msgtx.TxIn.
// It must be called every time a msgtx is changed.
// Only P2PKH outputs are supported at this point.
func signMsgTx(msgtx *wire.MsgTx, prevOutputs []wtxmgr.Credit, mgr *waddrmgr.Manager, chainParams *chaincfg.Params) error {
	if len(prevOutputs) != len(msgtx.TxIn) {
		return fmt.Errorf(
			"Number of prevOutputs (%d) does not match number of tx inputs (%d)",
			len(prevOutputs), len(msgtx.TxIn))
	}
	for i, output := range prevOutputs {
		// Errors don't matter here, as we only consider the
		// case where len(addrs) == 1.
		_, addrs, _, _ := txscript.ExtractPkScriptAddrs(output.PkScript,
			chainParams)
		if len(addrs) != 1 {
			continue
		}
		apkh, ok := addrs[0].(*btcutil.AddressPubKeyHash)
		if !ok {
			return ErrUnsupportedTransactionType
		}

		ai, err := mgr.Address(apkh)
		if err != nil {
			return fmt.Errorf("cannot get address info: %v", err)
		}

		pka := ai.(waddrmgr.ManagedPubKeyAddress)
		privkey, err := pka.PrivKey()
		if err != nil {
			return fmt.Errorf("cannot get private key: %v", err)
		}

		sigscript, err := txscript.SignatureScript(msgtx, i,
			output.PkScript, txscript.SigHashAll, privkey,
			ai.Compressed())
		if err != nil {
			return fmt.Errorf("cannot create sigscript: %s", err)
		}
		msgtx.TxIn[i].SignatureScript = sigscript
	}

	return nil
}
Exemplo n.º 8
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// signFundingTx generates signatures for all the inputs in the funding tx
// belonging to Bob.
// NOTE: This generates the full sig-script.
func (b *bobNode) signFundingTx(fundingTx *wire.MsgTx) ([][]byte, error) {
	bobSigs := make([][]byte, 0, len(b.availableOutputs))
	bobPkScript := b.changeOutputs[0].PkScript
	for i, _ := range fundingTx.TxIn {
		// Alice has already signed this input
		if fundingTx.TxIn[i].SignatureScript != nil {
			continue
		}

		sigScript, err := txscript.SignatureScript(fundingTx, i,
			bobPkScript, txscript.SigHashAll, b.privKey,
			true)
		if err != nil {
			return nil, err
		}

		bobSigs = append(bobSigs, sigScript)
	}

	return bobSigs, nil
}
Exemplo n.º 9
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// Test the sigscript generation for valid and invalid inputs, all
// hashTypes, and with and without compression.  This test creates
// sigscripts to spend fake coinbase inputs, as sigscripts cannot be
// created for the MsgTxs in txTests, since they come from the blockchain
// and we don't have the private keys.
func TestSignatureScript(t *testing.T) {
	t.Parallel()

	privKey, _ := btcec.PrivKeyFromBytes(btcec.S256(), privKeyD)

nexttest:
	for i := range sigScriptTests {
		tx := wire.NewMsgTx()

		output := wire.NewTxOut(500, []byte{txscript.OP_RETURN})
		tx.AddTxOut(output)

		for range sigScriptTests[i].inputs {
			txin := wire.NewTxIn(coinbaseOutPoint, nil)
			tx.AddTxIn(txin)
		}

		var script []byte
		var err error
		for j := range tx.TxIn {
			var idx int
			if sigScriptTests[i].inputs[j].indexOutOfRange {
				t.Errorf("at test %v", sigScriptTests[i].name)
				idx = len(sigScriptTests[i].inputs)
			} else {
				idx = j
			}
			script, err = txscript.SignatureScript(tx, idx,
				sigScriptTests[i].inputs[j].txout.PkScript,
				sigScriptTests[i].hashType, privKey,
				sigScriptTests[i].compress)

			if (err == nil) != sigScriptTests[i].inputs[j].sigscriptGenerates {
				if err == nil {
					t.Errorf("passed test '%v' incorrectly",
						sigScriptTests[i].name)
				} else {
					t.Errorf("failed test '%v': %v",
						sigScriptTests[i].name, err)
				}
				continue nexttest
			}
			if !sigScriptTests[i].inputs[j].sigscriptGenerates {
				// done with this test
				continue nexttest
			}

			tx.TxIn[j].SignatureScript = script
		}

		// If testing using a correct sigscript but for an incorrect
		// index, use last input script for first input.  Requires > 0
		// inputs for test.
		if sigScriptTests[i].scriptAtWrongIndex {
			tx.TxIn[0].SignatureScript = script
			sigScriptTests[i].inputs[0].inputValidates = false
		}

		// Validate tx input scripts
		scriptFlags := txscript.ScriptBip16 | txscript.ScriptVerifyDERSignatures
		for j := range tx.TxIn {
			vm, err := txscript.NewEngine(sigScriptTests[i].
				inputs[j].txout.PkScript, tx, j, scriptFlags, nil)
			if err != nil {
				t.Errorf("cannot create script vm for test %v: %v",
					sigScriptTests[i].name, err)
				continue nexttest
			}
			err = vm.Execute()
			if (err == nil) != sigScriptTests[i].inputs[j].inputValidates {
				if err == nil {
					t.Errorf("passed test '%v' validation incorrectly: %v",
						sigScriptTests[i].name, err)
				} else {
					t.Errorf("failed test '%v' validation: %v",
						sigScriptTests[i].name, err)
				}
				continue nexttest
			}
		}
	}
}
Exemplo n.º 10
0
Arquivo: wallet.go Projeto: mkl-/lnd
// handleFundingCounterPartyFunds processes the second workflow step for the
// lifetime of a channel reservation. Upon completion, the reservation will
// carry a completed funding transaction (minus the counterparty's input
// signatures), both versions of the commitment transaction, and our signature
// for their version of the commitment transaction.
func (l *LightningWallet) handleContributionMsg(req *addContributionMsg) {
	l.limboMtx.Lock()
	pendingReservation, ok := l.fundingLimbo[req.pendingFundingID]
	l.limboMtx.Unlock()
	if !ok {
		req.err <- fmt.Errorf("attempted to update non-existant funding state")
		return
	}

	// Grab the mutex on the ChannelReservation to ensure thead-safety
	pendingReservation.Lock()
	defer pendingReservation.Unlock()

	// Create a blank, fresh transaction. Soon to be a complete funding
	// transaction which will allow opening a lightning channel.
	pendingReservation.partialState.FundingTx = wire.NewMsgTx()
	fundingTx := pendingReservation.partialState.FundingTx

	// Some temporary variables to cut down on the resolution verbosity.
	pendingReservation.theirContribution = req.contribution
	theirContribution := req.contribution
	ourContribution := pendingReservation.ourContribution

	// First, add all multi-party inputs to the transaction
	// TODO(roasbeef); handle case that tx doesn't exist, fake input
	// TODO(roasbeef): validate SPV proof from other side if in SPV mode.
	//  * actually, pure SPV would need fraud proofs right? must prove input
	//    is unspent
	//  * or, something like getutxo?
	for _, ourInput := range ourContribution.Inputs {
		fundingTx.AddTxIn(ourInput)
	}
	for _, theirInput := range theirContribution.Inputs {
		fundingTx.AddTxIn(theirInput)
	}

	// Next, add all multi-party outputs to the transaction. This includes
	// change outputs for both side.
	for _, ourChangeOutput := range ourContribution.ChangeOutputs {
		fundingTx.AddTxOut(ourChangeOutput)
	}
	for _, theirChangeOutput := range theirContribution.ChangeOutputs {
		fundingTx.AddTxOut(theirChangeOutput)
	}

	ourKey := pendingReservation.partialState.MultiSigKey
	theirKey := theirContribution.MultiSigKey

	// Finally, add the 2-of-2 multi-sig output which will set up the lightning
	// channel.
	channelCapacity := int64(pendingReservation.partialState.Capacity)
	redeemScript, multiSigOut, err := fundMultiSigOut(ourKey.PubKey().SerializeCompressed(),
		theirKey.SerializeCompressed(), channelCapacity)
	if err != nil {
		req.err <- err
		return
	}

	// Register intent for notifications related to the funding output.
	// This'll allow us to properly track the number of confirmations the
	// funding tx has once it has been broadcasted.
	lastBlock := l.Manager.SyncedTo()
	scriptAddr, err := l.Manager.ImportScript(redeemScript, &lastBlock)
	if err != nil {
		req.err <- err
		return
	}
	if err := l.rpc.NotifyReceived([]btcutil.Address{scriptAddr.Address()}); err != nil {
		req.err <- err
		return
	}

	pendingReservation.partialState.FundingRedeemScript = redeemScript
	fundingTx.AddTxOut(multiSigOut)

	// Sort the transaction. Since both side agree to a cannonical
	// ordering, by sorting we no longer need to send the entire
	// transaction. Only signatures will be exchanged.
	txsort.InPlaceSort(pendingReservation.partialState.FundingTx)

	// Next, sign all inputs that are ours, collecting the signatures in
	// order of the inputs.
	pendingReservation.ourFundingSigs = make([][]byte, 0, len(ourContribution.Inputs))
	for i, txIn := range fundingTx.TxIn {
		// Does the wallet know about the txin?
		txDetail, _ := l.TxStore.TxDetails(&txIn.PreviousOutPoint.Hash)
		if txDetail == nil {
			continue
		}

		// Is this our txin? TODO(roasbeef): assumes all inputs are P2PKH...
		prevIndex := txIn.PreviousOutPoint.Index
		prevOut := txDetail.TxRecord.MsgTx.TxOut[prevIndex]
		_, addrs, _, _ := txscript.ExtractPkScriptAddrs(prevOut.PkScript, ActiveNetParams)
		apkh, ok := addrs[0].(*btcutil.AddressPubKeyHash)
		if !ok {
			req.err <- btcwallet.ErrUnsupportedTransactionType
			return
		}

		ai, err := l.Manager.Address(apkh)
		if err != nil {
			req.err <- fmt.Errorf("cannot get address info: %v", err)
			return
		}
		pka := ai.(waddrmgr.ManagedPubKeyAddress)
		privkey, err := pka.PrivKey()
		if err != nil {
			req.err <- fmt.Errorf("cannot get private key: %v", err)
			return
		}

		sigscript, err := txscript.SignatureScript(pendingReservation.partialState.FundingTx, i,
			prevOut.PkScript, txscript.SigHashAll, privkey,
			ai.Compressed())
		if err != nil {
			req.err <- fmt.Errorf("cannot create sigscript: %s", err)
			return
		}

		fundingTx.TxIn[i].SignatureScript = sigscript
		pendingReservation.ourFundingSigs = append(pendingReservation.ourFundingSigs, sigscript)
	}

	// Initialize an empty sha-chain for them, tracking the current pending
	// revocation hash (we don't yet know the pre-image so we can't add it
	// to the chain).
	pendingReservation.partialState.TheirShaChain = shachain.New()
	pendingReservation.partialState.TheirCurrentRevocation = theirContribution.RevocationHash

	// Grab the hash of the current pre-image in our chain, this is needed
	// for our commitment tx.
	// TODO(roasbeef): grab partial state above to avoid long attr chain
	ourCurrentRevokeHash := pendingReservation.ourContribution.RevocationHash

	// Create the txIn to our commitment transaction. In the process, we
	// need to locate the index of the multi-sig output on the funding tx
	// since the outputs are cannonically sorted.
	fundingNTxid := fundingTx.TxSha() // NOTE: assumes testnet-L
	_, multiSigIndex := findScriptOutputIndex(fundingTx, multiSigOut.PkScript)
	fundingTxIn := wire.NewTxIn(wire.NewOutPoint(&fundingNTxid, multiSigIndex), nil)

	// With the funding tx complete, create both commitment transactions.
	initialBalance := ourContribution.FundingAmount
	pendingReservation.fundingLockTime = theirContribution.CsvDelay
	ourCommitKey := ourContribution.CommitKey
	theirCommitKey := theirContribution.CommitKey
	ourCommitTx, err := createCommitTx(fundingTxIn, ourCommitKey, theirCommitKey,
		ourCurrentRevokeHash[:], theirContribution.CsvDelay,
		initialBalance, initialBalance)
	if err != nil {
		req.err <- err
		return
	}
	theirCommitTx, err := createCommitTx(fundingTxIn, theirCommitKey, ourCommitKey,
		theirContribution.RevocationHash[:], theirContribution.CsvDelay,
		initialBalance, initialBalance)
	if err != nil {
		req.err <- err
		return
	}

	// Sort both transactions according to the agreed upon cannonical
	// ordering. This lets us skip sending the entire transaction over,
	// instead we'll just send signatures.
	txsort.InPlaceSort(ourCommitTx)
	txsort.InPlaceSort(theirCommitTx)

	// Record newly available information witin the open channel state.
	pendingReservation.partialState.CsvDelay = theirContribution.CsvDelay
	pendingReservation.partialState.TheirDeliveryAddress = theirContribution.DeliveryAddress
	pendingReservation.partialState.ChanID = fundingNTxid
	pendingReservation.partialState.TheirCommitKey = theirCommitKey
	pendingReservation.partialState.TheirCommitTx = theirCommitTx
	pendingReservation.partialState.OurCommitTx = ourCommitTx

	// Generate a signature for their version of the initial commitment
	// transaction.
	sigTheirCommit, err := txscript.RawTxInSignature(theirCommitTx, 0, redeemScript,
		txscript.SigHashAll, ourKey)
	if err != nil {
		req.err <- err
		return
	}
	pendingReservation.ourCommitmentSig = sigTheirCommit

	req.err <- nil
}