示例#1
0
 def parse_script(self, x):
     script = ''
     for word in x.split():
         if word[0:3] == 'OP_':
             opcode_int = opcodes[word]
             assert opcode_int < 256  # opcode is single-byte
             script += bitcoin.int_to_hex(opcode_int)
         else:
             bfh(word)  # to test it is hex data
             script += push_script(word)
     return script
示例#2
0
 def parse_script(self, x):
     from electrum_axe.transaction import opcodes, push_script
     script = ''
     for word in x.split():
         if word[0:3] == 'OP_':
             assert word in opcodes.lookup
             opcode_int = opcodes.lookup[word]
             assert opcode_int < 256  # opcode is single-byte
             script += bitcoin.int_to_hex(opcode_int)
         else:
             bfh(word)  # to test it is hex data
             script += push_script(word)
     return script
示例#3
0
    def sign_transaction(self, tx, password):
        if tx.is_complete():
            return
        client = self.get_client()
        self.signing = True
        inputs = []
        inputsPaths = []
        pubKeys = []
        chipInputs = []
        redeemScripts = []
        signatures = []
        preparedTrustedInputs = []
        changePath = ""
        changeAmount = None
        output = None
        outputAmount = None
        p2shTransaction = False
        pin = ""
        self.get_client(
        )  # prompt for the PIN before displaying the dialog if necessary

        # Fetch inputs of the transaction to sign
        derivations = self.get_tx_derivations(tx)
        for txin in tx.inputs():
            if txin['type'] == 'coinbase':
                self.give_error(
                    "Coinbase not supported")  # should never happen

            if txin['type'] in ['p2sh']:
                p2shTransaction = True

            pubkeys, x_pubkeys = tx.get_sorted_pubkeys(txin)
            for i, x_pubkey in enumerate(x_pubkeys):
                if x_pubkey in derivations:
                    signingPos = i
                    s = derivations.get(x_pubkey)
                    hwAddress = "%s/%d/%d" % (self.get_derivation()[2:], s[0],
                                              s[1])
                    break
            else:
                self.give_error("No matching x_key for sign_transaction"
                                )  # should never happen

            redeemScript = Transaction.get_preimage_script(txin)
            inputs.append([
                txin['prev_tx'].raw, txin['prevout_n'], redeemScript,
                txin['prevout_hash'], signingPos,
                txin.get('sequence', 0xffffffff - 1)
            ])
            inputsPaths.append(hwAddress)
            pubKeys.append(pubkeys)

        # Sanity check
        if p2shTransaction:
            for txin in tx.inputs():
                if txin['type'] != 'p2sh':
                    self.give_error(
                        "P2SH / regular input mixed in same transaction not supported"
                    )  # should never happen

        txOutput = var_int(len(tx.outputs()))
        for txout in tx.outputs():
            output_type, addr, amount = txout
            txOutput += int_to_hex(amount, 8)
            script = tx.pay_script(output_type, addr)
            txOutput += var_int(len(script) / 2)
            txOutput += script
        txOutput = txOutput.decode('hex')

        # Recognize outputs - only one output and one change is authorized
        if not p2shTransaction:
            if not self.get_client_electrum().supports_multi_output():
                if len(tx.outputs()) > 2:
                    self.give_error(
                        "Transaction with more than 2 outputs not supported")
            for _type, address, amount in tx.outputs():
                assert _type == TYPE_ADDRESS
                info = tx.output_info.get(address)
                if (info is not None) and (len(tx.outputs()) != 1):
                    index, xpubs, m = info
                    changePath = self.get_derivation()[2:] + "/%d/%d" % index
                    changeAmount = amount
                else:
                    output = address
                    if not self.get_client_electrum().canAlternateCoinVersions:
                        v, h = bc_address_to_hash_160(address)
                        if v == ADDRTYPE_P2PKH:
                            output = hash_160_to_bc_address(h, 0)
                    outputAmount = amount

        self.handler.show_message(
            _("Confirm Transaction on your Ledger device..."))
        try:
            # Get trusted inputs from the original transactions
            for utxo in inputs:
                sequence = int_to_hex(utxo[5], 4)
                if not p2shTransaction:
                    txtmp = bitcoinTransaction(bytearray(
                        utxo[0].decode('hex')))
                    trustedInput = self.get_client().getTrustedInput(
                        txtmp, utxo[1])
                    trustedInput['sequence'] = sequence
                    chipInputs.append(trustedInput)
                    redeemScripts.append(txtmp.outputs[utxo[1]].script)
                else:
                    tmp = utxo[3].decode('hex')[::-1].encode('hex')
                    tmp += int_to_hex(utxo[1], 4)
                    chipInputs.append({
                        'value': tmp.decode('hex'),
                        'sequence': sequence
                    })
                    redeemScripts.append(bytearray(utxo[2].decode('hex')))

            # Sign all inputs
            firstTransaction = True
            inputIndex = 0
            rawTx = tx.serialize()
            self.get_client().enableAlternate2fa(False)
            while inputIndex < len(inputs):
                self.get_client().startUntrustedTransaction(
                    firstTransaction, inputIndex, chipInputs,
                    redeemScripts[inputIndex])
                if not p2shTransaction:
                    outputData = self.get_client().finalizeInput(
                        output, format_satoshis_plain(outputAmount),
                        format_satoshis_plain(tx.get_fee()), changePath,
                        bytearray(rawTx.decode('hex')))
                else:
                    outputData = self.get_client().finalizeInputFull(txOutput)
                    outputData['outputData'] = txOutput

                if firstTransaction:
                    transactionOutput = outputData['outputData']
                if outputData['confirmationNeeded']:
                    outputData['address'] = output
                    self.handler.clear_dialog()
                    pin = self.handler.get_auth(
                        outputData
                    )  # does the authenticate dialog and returns pin
                    if not pin:
                        raise UserWarning()
                    if pin != 'paired':
                        self.handler.show_message(
                            _("Confirmed. Signing Transaction..."))
                else:
                    # Sign input with the provided PIN
                    inputSignature = self.get_client().untrustedHashSign(
                        inputsPaths[inputIndex], pin, lockTime=tx.locktime)
                    inputSignature[0] = 0x30  # force for 1.4.9+
                    signatures.append(inputSignature)
                    inputIndex = inputIndex + 1
                if pin != 'paired':
                    firstTransaction = False
        except UserWarning:
            self.handler.show_error(_('Cancelled by user'))
            return
        except BaseException as e:
            traceback.print_exc(file=sys.stdout)
            self.give_error(e, True)
        finally:
            self.handler.clear_dialog()

        for i, txin in enumerate(tx.inputs()):
            signingPos = inputs[i][4]
            txin['signatures'][signingPos] = str(signatures[i]).encode('hex')
        tx.raw = tx.serialize()
        self.signing = False
示例#4
0
    def sign_transaction(self, tx, password):
        if tx.is_complete():
            return
        client = self.get_client()
        inputs = []
        inputsPaths = []
        pubKeys = []
        chipInputs = []
        redeemScripts = []
        signatures = []
        preparedTrustedInputs = []
        changePath = ""
        output = None
        p2shTransaction = False
        pin = ""
        self.get_client(
        )  # prompt for the PIN before displaying the dialog if necessary

        # Fetch inputs of the transaction to sign
        derivations = self.get_tx_derivations(tx)
        for txin in tx.inputs():
            if txin['type'] == 'coinbase':
                self.give_error(
                    "Coinbase not supported")  # should never happen

            if txin['type'] in ['p2sh']:
                p2shTransaction = True

            pubkeys, x_pubkeys = tx.get_sorted_pubkeys(txin)
            for i, x_pubkey in enumerate(x_pubkeys):
                if x_pubkey in derivations:
                    signingPos = i
                    s = derivations.get(x_pubkey)
                    hwAddress = "%s/%d/%d" % (self.get_derivation()[2:], s[0],
                                              s[1])
                    break
            else:
                self.give_error("No matching x_key for sign_transaction"
                                )  # should never happen

            redeemScript = Transaction.get_preimage_script(txin)
            txin_prev_tx = txin.get('prev_tx')
            if txin_prev_tx is None:
                raise Exception(
                    _('Offline signing with {} is not supported for legacy inputs.'
                      ).format(self.device))
            txin_prev_tx_raw = txin_prev_tx.raw if txin_prev_tx else None
            inputs.append([
                txin_prev_tx_raw, txin['prevout_n'], redeemScript,
                txin['prevout_hash'], signingPos,
                txin.get('sequence', 0xffffffff - 1),
                txin.get('value')
            ])
            inputsPaths.append(hwAddress)
            pubKeys.append(pubkeys)

        # Sanity check
        if p2shTransaction:
            for txin in tx.inputs():
                if txin['type'] != 'p2sh':
                    self.give_error(
                        "P2SH / regular input mixed in same transaction not supported"
                    )  # should never happen

        txOutput = var_int(len(tx.outputs()))
        for txout in tx.outputs():
            output_type, addr, amount = txout
            txOutput += int_to_hex(amount, 8)
            script = tx.pay_script(output_type, addr)
            txOutput += var_int(len(script) // 2)
            txOutput += script
        txOutput = bfh(txOutput)

        # Recognize outputs
        # - only one output and one change is authorized (for hw.1 and nano)
        # - at most one output can bypass confirmation (~change) (for all)
        if not p2shTransaction:
            if not self.get_client_electrum().supports_multi_output():
                if len(tx.outputs()) > 2:
                    self.give_error(
                        "Transaction with more than 2 outputs not supported")
            has_change = False
            any_output_on_change_branch = is_any_tx_output_on_change_branch(tx)
            for o in tx.outputs():
                assert o.type == TYPE_ADDRESS
                info = tx.output_info.get(o.address)
                if (info is not None) and len(tx.outputs()) > 1 \
                        and not has_change:
                    index = info.address_index
                    on_change_branch = index[0] == 1
                    # prioritise hiding outputs on the 'change' branch from user
                    # because no more than one change address allowed
                    if on_change_branch == any_output_on_change_branch:
                        changePath = self.get_derivation(
                        )[2:] + "/%d/%d" % index
                        has_change = True
                    else:
                        output = o.address
                else:
                    output = o.address
                    if not self.get_client_electrum().canAlternateCoinVersions:
                        v, h = b58_address_to_hash160(address)
                        if v == constants.net.ADDRTYPE_P2PKH:
                            output = hash160_to_b58_address(h, 0)

        self.handler.show_message(
            _("Confirm Transaction on your Ledger device..."))
        try:
            # Get trusted inputs from the original transactions
            for utxo in inputs:
                sequence = int_to_hex(utxo[5], 4)
                if not p2shTransaction:
                    txtmp = bitcoinTransaction(bfh(utxo[0]))
                    trustedInput = self.get_client().getTrustedInput(
                        txtmp, utxo[1])
                    trustedInput['sequence'] = sequence
                    chipInputs.append(trustedInput)
                    redeemScripts.append(txtmp.outputs[utxo[1]].script)
                else:
                    tmp = bfh(utxo[3])[::-1]
                    tmp += bfh(int_to_hex(utxo[1], 4))
                    chipInputs.append({'value': tmp, 'sequence': sequence})
                    redeemScripts.append(bfh(utxo[2]))

            # Sign all inputs
            firstTransaction = True
            inputIndex = 0
            rawTx = tx.serialize_to_network()
            self.get_client().enableAlternate2fa(False)
            while inputIndex < len(inputs):
                self.get_client().startUntrustedTransaction(
                    firstTransaction, inputIndex, chipInputs,
                    redeemScripts[inputIndex])
                if changePath:
                    # we don't set meaningful outputAddress, amount and fees
                    # as we only care about the alternateEncoding==True branch
                    outputData = self.get_client().finalizeInput(
                        b'', 0, 0, changePath, bfh(rawTx))
                else:
                    outputData = self.get_client().finalizeInputFull(txOutput)
                outputData['outputData'] = txOutput
                if firstTransaction:
                    transactionOutput = outputData['outputData']
                if outputData['confirmationNeeded']:
                    outputData['address'] = output
                    self.handler.finished()
                    pin = self.handler.get_auth(
                        outputData
                    )  # does the authenticate dialog and returns pin
                    if not pin:
                        raise UserWarning()
                    if pin != 'paired':
                        self.handler.show_message(
                            _("Confirmed. Signing Transaction..."))
                else:
                    # Sign input with the provided PIN
                    inputSignature = self.get_client().untrustedHashSign(
                        inputsPaths[inputIndex], pin, lockTime=tx.locktime)
                    inputSignature[0] = 0x30  # force for 1.4.9+
                    signatures.append(inputSignature)
                    inputIndex = inputIndex + 1
                if pin != 'paired':
                    firstTransaction = False
        except UserWarning:
            self.handler.show_error(_('Cancelled by user'))
            return
        except BTChipException as e:
            if e.sw == 0x6985:  # cancelled by user
                return
            elif e.sw == 0x6982:
                raise  # pin lock. decorator will catch it
            else:
                traceback.print_exc(file=sys.stderr)
                self.give_error(e, True)
        except BaseException as e:
            traceback.print_exc(file=sys.stdout)
            self.give_error(e, True)
        finally:
            self.handler.finished()

        for i, txin in enumerate(tx.inputs()):
            signingPos = inputs[i][4]
            tx.add_signature_to_txin(i, signingPos, bh2u(signatures[i]))
        tx.raw = tx.serialize()
示例#5
0
 def test_int_to_hex(self):
     self.assertEqual('00', int_to_hex(0, 1))
     self.assertEqual('ff', int_to_hex(-1, 1))
     self.assertEqual('00000000', int_to_hex(0, 4))
     self.assertEqual('01000000', int_to_hex(1, 4))
     self.assertEqual('7f', int_to_hex(127, 1))
     self.assertEqual('7f00', int_to_hex(127, 2))
     self.assertEqual('80', int_to_hex(128, 1))
     self.assertEqual('80', int_to_hex(-128, 1))
     self.assertEqual('8000', int_to_hex(128, 2))
     self.assertEqual('ff', int_to_hex(255, 1))
     self.assertEqual('ff7f', int_to_hex(32767, 2))
     self.assertEqual('0080', int_to_hex(-32768, 2))
     self.assertEqual('ffff', int_to_hex(65535, 2))
     with self.assertRaises(OverflowError):
         int_to_hex(256, 1)
     with self.assertRaises(OverflowError):
         int_to_hex(-129, 1)
     with self.assertRaises(OverflowError):
         int_to_hex(-257, 1)
     with self.assertRaises(OverflowError):
         int_to_hex(65536, 2)
     with self.assertRaises(OverflowError):
         int_to_hex(-32769, 2)