Example #1
0
// addrToKey converts known address types to an addrindex key.  An error is
// returned for unsupported types.
func addrToKey(addr btcutil.Address) ([addrKeySize]byte, error) {
	switch addr := addr.(type) {
	case *btcutil.AddressPubKeyHash:
		var result [addrKeySize]byte
		result[0] = addrKeyTypePubKeyHash
		copy(result[1:], addr.Hash160()[:])
		return result, nil

	case *btcutil.AddressScriptHash:
		var result [addrKeySize]byte
		result[0] = addrKeyTypeScriptHash
		copy(result[1:], addr.Hash160()[:])
		return result, nil

	case *btcutil.AddressPubKey:
		var result [addrKeySize]byte
		result[0] = addrKeyTypePubKeyHash
		copy(result[1:], addr.AddressPubKeyHash().Hash160()[:])
		return result, nil
	}

	return [addrKeySize]byte{}, errUnsupportedAddressType
}
Example #2
0
File: tx.go Project: dan-da/btcd
// FetchTxsForAddr looks up and returns all transactions which either
// spend from a previously created output of the passed address, or
// create a new output locked to the passed address. The, `limit` parameter
// should be the max number of transactions to be returned. Additionally, if the
// caller wishes to seek forward in the results some amount, the 'seek'
// represents how many results to skip.
func (db *LevelDb) FetchTxsForAddr(addr btcutil.Address, skip int,
	limit int, reverse bool) ([]*database.TxListReply, int, error) {
	db.dbLock.Lock()
	defer db.dbLock.Unlock()

	// Enforce constraints for skip and limit.
	if skip < 0 {
		return nil, 0, errors.New("offset for skip must be positive")
	}
	if limit < 0 {
		return nil, 0, errors.New("value for limit must be positive")
	}

	// Parse address type, bailing on an unknown type.
	var addrKey []byte
	switch addr := addr.(type) {
	case *btcutil.AddressPubKeyHash:
		hash160 := addr.Hash160()
		addrKey = hash160[:]
	case *btcutil.AddressScriptHash:
		hash160 := addr.Hash160()
		addrKey = hash160[:]
	case *btcutil.AddressPubKey:
		hash160 := addr.AddressPubKeyHash().Hash160()
		addrKey = hash160[:]
	default:
		return nil, 0, database.ErrUnsupportedAddressType
	}

	// Create the prefix for our search.
	addrPrefix := make([]byte, 23, 23)
	copy(addrPrefix[0:3], addrIndexKeyPrefix)
	copy(addrPrefix[3:23], addrKey)

	iter := db.lDb.NewIterator(bytesPrefix(addrPrefix), nil)
	skipped := 0

	if reverse {
		// Go to the last element if reverse iterating.
		iter.Last()
		// Skip "one past" the last element so the loops below don't
		// miss the last element due to Prev() being called first.
		// We can safely ignore iterator exhaustion since the loops
		// below will see there's no keys anyway.
		iter.Next()
	}

	for skip != 0 && advanceIterator(iter, reverse) {
		skip--
		skipped++
	}

	// Iterate through all address indexes that match the targeted prefix.
	var replies []*database.TxListReply
	var rawIndex [12]byte
	for advanceIterator(iter, reverse) && limit != 0 {
		copy(rawIndex[:], iter.Key()[23:35])
		addrIndex := unpackTxIndex(rawIndex)

		tx, blkSha, blkHeight, _, err := db.fetchTxDataByLoc(addrIndex.blkHeight,
			addrIndex.txoffset, addrIndex.txlen, []byte{})
		if err != nil {
			// Eat a possible error due to a potential re-org.
			continue
		}

		txSha := tx.TxSha()
		txReply := &database.TxListReply{Sha: &txSha, Tx: tx,
			BlkSha: blkSha, Height: blkHeight, TxSpent: []bool{}, Err: err}

		replies = append(replies, txReply)
		limit--
	}
	iter.Release()
	if err := iter.Error(); err != nil {
		return nil, 0, err
	}

	return replies, skipped, nil
}
Example #3
0
// FetchTxsForAddr looks up and returns all transactions which either
// spend from a previously created output of the passed address, or
// create a new output locked to the passed address. The, `limit` parameter
// should be the max number of transactions to be returned. Additionally, if the
// caller wishes to seek forward in the results some amount, the 'seek'
// represents how many results to skip.
func (db *LevelDb) FetchTxsForAddr(addr btcutil.Address, skip int,
	limit int) ([]*database.TxListReply, error) {
	db.dbLock.Lock()
	defer db.dbLock.Unlock()

	// Enforce constraints for skip and limit.
	if skip < 0 {
		return nil, errors.New("offset for skip must be positive")
	}
	if limit < 0 {
		return nil, errors.New("value for limit must be positive")
	}

	// Parse address type, bailing on an unknown type.
	var addrKey []byte
	switch addr := addr.(type) {
	case *btcutil.AddressPubKeyHash:
		hash160 := addr.Hash160()
		addrKey = hash160[:]
	case *btcutil.AddressScriptHash:
		hash160 := addr.Hash160()
		addrKey = hash160[:]
	case *btcutil.AddressPubKey:
		hash160 := addr.AddressPubKeyHash().Hash160()
		addrKey = hash160[:]
	default:
		return nil, database.ErrUnsupportedAddressType
	}

	// Create the prefix for our search.
	addrPrefix := make([]byte, 23, 23)
	copy(addrPrefix[0:3], addrIndexKeyPrefix)
	copy(addrPrefix[3:23], addrKey)

	iter := db.lDb.NewIterator(bytesPrefix(addrPrefix), nil)
	for skip != 0 && iter.Next() {
		skip--
	}

	// Iterate through all address indexes that match the targeted prefix.
	var replies []*database.TxListReply
	var rawIndex [12]byte
	for iter.Next() && limit != 0 {
		copy(rawIndex[:], iter.Key()[23:35])
		addrIndex := unpackTxIndex(rawIndex)

		tx, blkSha, blkHeight, _, err := db.fetchTxDataByLoc(addrIndex.blkHeight,
			addrIndex.txoffset, addrIndex.txlen, []byte{})
		if err != nil {
			// Eat a possible error due to a potential re-org.
			continue
		}

		txSha := tx.TxSha()
		txReply := &database.TxListReply{Sha: &txSha, Tx: tx,
			BlkSha: blkSha, Height: blkHeight, TxSpent: []bool{}, Err: err}

		replies = append(replies, txReply)
		limit--
	}
	iter.Release()
	if err := iter.Error(); err != nil {
		return nil, err
	}

	return replies, nil
}
Example #4
0
func (w *LibbitcoinWallet) Spend(amount int64, addr btc.Address, feeLevel bitcoin.FeeLevel) error {
	// Check for dust
	script, _ := txscript.PayToAddrScript(addr)
	if txrules.IsDustAmount(btc.Amount(amount), len(script), txrules.DefaultRelayFeePerKb) {
		return errors.New("Amount is below dust threshold")
	}

	var additionalPrevScripts map[wire.OutPoint][]byte
	var additionalKeysByAddress map[string]*btc.WIF

	// Create input source
	coinMap := w.gatherCoins()
	coins := make([]coinset.Coin, 0, len(coinMap))
	for k := range coinMap {
		coins = append(coins, k)
	}
	inputSource := func(target btc.Amount) (total btc.Amount, inputs []*wire.TxIn, scripts [][]byte, err error) {
		// TODO: maybe change the coin selection algorithm? We're using min coins right now because
		// TODO: we don't know the number of confirmations on each coin without querying the libbitcoin server.
		coinSelector := coinset.MinNumberCoinSelector{MaxInputs: 10000, MinChangeAmount: btc.Amount(10000)}
		coins, err := coinSelector.CoinSelect(target, coins)
		if err != nil {
			return total, inputs, scripts, errors.New("insuffient funds")
		}
		additionalPrevScripts = make(map[wire.OutPoint][]byte)
		additionalKeysByAddress = make(map[string]*btc.WIF)
		for _, c := range coins.Coins() {
			total += c.Value()
			outpoint := wire.NewOutPoint(c.Hash(), c.Index())
			in := wire.NewTxIn(outpoint, []byte{})
			in.Sequence = 0 // Opt-in RBF so we can bump fees
			inputs = append(inputs, in)
			additionalPrevScripts[*outpoint] = c.PkScript()
			key := coinMap[c]
			addr, _ := btc.NewAddressPubKey(key.PublicKey().Key, w.params)
			pk, _ := btcec.PrivKeyFromBytes(btcec.S256(), key.Key)
			wif, _ := btc.NewWIF(pk, w.params, true)
			additionalKeysByAddress[addr.AddressPubKeyHash().EncodeAddress()] = wif
		}
		return total, inputs, scripts, nil
	}

	// Get the fee per kilobyte
	feePerKB := int64(w.getFeePerByte(feeLevel)) * 1000

	// outputs
	out := wire.NewTxOut(amount, script)

	// Create change source
	changeSource := func() ([]byte, error) {
		addr := w.GetCurrentAddress(bitcoin.CHANGE)
		script, err := txscript.PayToAddrScript(addr)
		if err != nil {
			return []byte{}, err
		}
		return script, nil
	}

	authoredTx, err := txauthor.NewUnsignedTransaction([]*wire.TxOut{out}, btc.Amount(feePerKB), inputSource, changeSource)
	if err != nil {
		return err
	}

	// BIP 69 sorting
	txsort.InPlaceSort(authoredTx.Tx)

	// Sign tx
	getKey := txscript.KeyClosure(func(addr btc.Address) (
		*btcec.PrivateKey, bool, error) {
		addrStr := addr.EncodeAddress()
		wif := additionalKeysByAddress[addrStr]
		return wif.PrivKey, wif.CompressPubKey, nil
	})
	getScript := txscript.ScriptClosure(func(
		addr btc.Address) ([]byte, error) {
		return []byte{}, nil
	})
	for i, txIn := range authoredTx.Tx.TxIn {
		prevOutScript := additionalPrevScripts[txIn.PreviousOutPoint]
		script, err := txscript.SignTxOutput(w.params,
			authoredTx.Tx, i, prevOutScript, txscript.SigHashAll, getKey,
			getScript, txIn.SignatureScript)
		if err != nil {
			return errors.New("Failed to sign transaction")
		}
		txIn.SignatureScript = script
	}

	// Broadcast tx to bitcoin network
	serializedTx := new(bytes.Buffer)
	authoredTx.Tx.Serialize(serializedTx)
	w.Client.Broadcast(serializedTx.Bytes(), func(i interface{}, err error) {
		if err == nil {
			log.Infof("Broadcast tx %s to bitcoin network\n", authoredTx.Tx.TxSha().String())
		} else {
			log.Errorf("Failed to broadcast tx, reason: %s\n", err)
		}
	})

	// Update the db
	w.ProcessTransaction(btc.NewTx(authoredTx.Tx), 0)

	return nil
}