def test_multisig_one_at_a_time(self): N = 3 M = 3 keys = [Key(secret_exponent=i) for i in range(1, M + 2)] tx_in = TxIn.coinbase_tx_in(script=b'') script = ScriptMultisig(n=N, sec_keys=[key.sec() for key in keys[:M]]).script() tx_out = TxOut(1000000, script) tx1 = Tx(version=1, txs_in=[tx_in], txs_out=[tx_out]) tx2 = tx_utils.create_tx(tx1.tx_outs_as_spendable(), [keys[-1].address()]) ids = [ "403e5bfc59e097bb197bf77a692d158dd3a4f7affb4a1fa41072dafe7bec7058", "5931d9995e83721243dca24772d7012afcd4378996a8b953c458175f15a544db", "9bb4421088190bbbb5b42a9eaa9baed7ec7574a407c25f71992ba56ca43d9c44", "03a1dc2a63f93a5cf5a7cb668658eb3fc2eda88c06dc287b85ba3e6aff751771" ] for i in range(1, M + 1): self.assertEqual(tx2.bad_signature_count(), 1) self.assertEqual(tx2.id(), ids[i - 1]) hash160_lookup = build_hash160_lookup(key.secret_exponent() for key in keys[i - 1:i]) tx2.sign(hash160_lookup=hash160_lookup) self.assertEqual(tx2.id(), ids[i]) self.assertEqual(tx2.bad_signature_count(), 0)
def multisig_N_of_M(self, N, M, unsigned_id, signed_id): keys = [Key(secret_exponent=i) for i in range(1, M+2)] tx_in = TxIn.coinbase_tx_in(script=b'') script = ScriptMultisig(n=N, sec_keys=[key.sec() for key in keys[:M]]).script() tx_out = TxOut(1000000, script) tx1 = Tx(version=1, txs_in=[tx_in], txs_out=[tx_out]) tx2 = tx_utils.create_tx(tx1.tx_outs_as_spendable(), [keys[-1].address()]) self.assertEqual(tx2.id(), unsigned_id) self.assertEqual(tx2.bad_signature_count(), 1) hash160_lookup = build_hash160_lookup(key.secret_exponent() for key in keys) tx2.sign(hash160_lookup=hash160_lookup) self.assertEqual(tx2.id(), signed_id) self.assertEqual(tx2.bad_signature_count(), 0)
def multisig_M_of_N(self, M, N, unsigned_id, signed_id): keys = [Key(secret_exponent=i) for i in range(1, N+2)] tx_in = TxIn.coinbase_tx_in(script=b'') script = ScriptMultisig(m=M, sec_keys=[key.sec() for key in keys[:N]]).script() tx_out = TxOut(1000000, script) tx1 = Tx(version=1, txs_in=[tx_in], txs_out=[tx_out]) tx2 = tx_utils.create_tx(tx1.tx_outs_as_spendable(), [keys[-1].address()]) self.assertEqual(tx2.id(), unsigned_id) self.assertEqual(tx2.bad_signature_count(), 1) hash160_lookup = build_hash160_lookup(key.secret_exponent() for key in keys) tx2.sign(hash160_lookup=hash160_lookup) self.assertEqual(tx2.id(), signed_id) self.assertEqual(tx2.bad_signature_count(), 0)
def multisig_M_of_N_individually(self, M, N): keys = [Key(secret_exponent=i) for i in range(1, N+2)] tx_in = TxIn.coinbase_tx_in(script=b'') script = ScriptMultisig(n=M, sec_keys=[key.sec() for key in keys[:N]]).script() tx_out = TxOut(1000000, script) tx1 = Tx(version=1, txs_in=[tx_in], txs_out=[tx_out]) for partial_key_list in itertools.permutations(keys[:N], M): tx2 = tx_utils.create_tx(tx1.tx_outs_as_spendable(), [keys[-1].address()]) for key in partial_key_list: self.assertEqual(tx2.bad_signature_count(), 1) hash160_lookup = build_hash160_lookup([key.secret_exponent()]) tx2.sign(hash160_lookup=hash160_lookup) self.assertEqual(tx2.bad_signature_count(), 0)
def test_sign_pay_to_script_multisig(self): N, M = 3, 3 keys = [Key(secret_exponent=i) for i in range(1, M+2)] tx_in = TxIn.coinbase_tx_in(script=b'') underlying_script = ScriptMultisig(n=N, sec_keys=[key.sec() for key in keys[:M]]).script() address = address_for_pay_to_script(underlying_script) self.assertEqual(address, "39qEwuwyb2cAX38MFtrNzvq3KV9hSNov3q") script = standard_tx_out_script(address) tx_out = TxOut(1000000, script) tx1 = Tx(version=1, txs_in=[tx_in], txs_out=[tx_out]) tx2 = tx_utils.create_tx(tx1.tx_outs_as_spendable(), [address]) hash160_lookup = build_hash160_lookup(key.secret_exponent() for key in keys[:M]) p2sh_lookup = build_p2sh_lookup([underlying_script]) tx2.sign(hash160_lookup=hash160_lookup, p2sh_lookup=p2sh_lookup) self.assertEqual(tx2.bad_signature_count(), 0)
def test_sign_pay_to_script_multisig(self): M, N = 3, 3 keys = [Key(secret_exponent=i) for i in range(1, N+2)] tx_in = TxIn.coinbase_tx_in(script=b'') underlying_script = ScriptMultisig(m=M, sec_keys=[key.sec() for key in keys[:N]]).script() address = address_for_pay_to_script(underlying_script) self.assertEqual(address, "39qEwuwyb2cAX38MFtrNzvq3KV9hSNov3q") script = standard_tx_out_script(address) tx_out = TxOut(1000000, script) tx1 = Tx(version=1, txs_in=[tx_in], txs_out=[tx_out]) tx2 = tx_utils.create_tx(tx1.tx_outs_as_spendable(), [address]) hash160_lookup = build_hash160_lookup(key.secret_exponent() for key in keys[:N]) p2sh_lookup = build_p2sh_lookup([underlying_script]) tx2.sign(hash160_lookup=hash160_lookup, p2sh_lookup=p2sh_lookup) self.assertEqual(tx2.bad_signature_count(), 0)
def multisig_M_of_N_individually(self, M, N): keys = [Key(secret_exponent=i) for i in range(1, N + 2)] tx_in = TxIn.coinbase_tx_in(script=b'') script = ScriptMultisig(n=M, sec_keys=[key.sec() for key in keys[:N]]).script() tx_out = TxOut(1000000, script) tx1 = Tx(version=1, txs_in=[tx_in], txs_out=[tx_out]) for partial_key_list in itertools.permutations(keys[:N], M): tx2 = tx_utils.create_tx(tx1.tx_outs_as_spendable(), [keys[-1].address()]) for key in partial_key_list: self.assertEqual(tx2.bad_signature_count(), 1) hash160_lookup = build_hash160_lookup([key.secret_exponent()]) tx2.sign(hash160_lookup=hash160_lookup) self.assertEqual(tx2.bad_signature_count(), 0)
def test_multisig_one_at_a_time(self): N = 3 M = 3 keys = [Key(secret_exponent=i) for i in range(1, M+2)] tx_in = TxIn.coinbase_tx_in(script=b'') script = ScriptMultisig(n=N, sec_keys=[key.sec() for key in keys[:M]]).script() tx_out = TxOut(1000000, script) tx1 = Tx(version=1, txs_in=[tx_in], txs_out=[tx_out]) tx2 = tx_utils.create_tx(tx1.tx_outs_as_spendable(), [keys[-1].address()]) ids = ["403e5bfc59e097bb197bf77a692d158dd3a4f7affb4a1fa41072dafe7bec7058", "5931d9995e83721243dca24772d7012afcd4378996a8b953c458175f15a544db", "9bb4421088190bbbb5b42a9eaa9baed7ec7574a407c25f71992ba56ca43d9c44", "03a1dc2a63f93a5cf5a7cb668658eb3fc2eda88c06dc287b85ba3e6aff751771"] for i in range(1, M+1): self.assertEqual(tx2.bad_signature_count(), 1) self.assertEqual(tx2.id(), ids[i-1]) hash160_lookup = build_hash160_lookup(key.secret_exponent() for key in keys[i-1:i]) tx2.sign(hash160_lookup=hash160_lookup) self.assertEqual(tx2.id(), ids[i]) self.assertEqual(tx2.bad_signature_count(), 0)
def main(): parser = argparse.ArgumentParser( description="Manipulate bitcoin (or alt coin) transactions.", epilog=EPILOG) parser.add_argument('-t', "--transaction-version", type=int, help='Transaction version, either 1 (default) or 3 (not yet supported).') parser.add_argument('-l', "--lock-time", type=parse_locktime, help='Lock time; either a block' 'index, or a date/time (example: "2014-01-01T15:00:00"') parser.add_argument('-n', "--network", default="BTC", help='Define network code (M=Bitcoin mainnet, T=Bitcoin testnet).') parser.add_argument('-a', "--augment", action='store_true', help='augment tx by adding any missing spendable metadata by fetching' ' inputs from cache and/or web services') parser.add_argument("-i", "--fetch-spendables", metavar="address", action="append", help='Add all unspent spendables for the given bitcoin address. This information' ' is fetched from web services.') parser.add_argument('-f', "--private-key-file", metavar="path-to-private-keys", action="append", help='file containing WIF or BIP0032 private keys. If file name ends with .gpg, ' '"gpg -d" will be invoked automatically. File is read one line at a time, and if ' 'the file contains only one WIF per line, it will also be scanned for a bitcoin ' 'address, and any addresses found will be assumed to be public keys for the given' ' private key.', type=argparse.FileType('r')) parser.add_argument('-g', "--gpg-argument", help='argument to pass to gpg (besides -d).', default='') parser.add_argument("--remove-tx-in", metavar="tx_in_index_to_delete", action="append", type=int, help='remove a tx_in') parser.add_argument("--remove-tx-out", metavar="tx_out_index_to_delete", action="append", type=int, help='remove a tx_out') parser.add_argument('-F', "--fee", help='fee, in satoshis, to pay on transaction, or ' '"standard" to auto-calculate. This is only useful if the "split pool" ' 'is used; otherwise, the fee is automatically set to the unclaimed funds.', default="standard", metavar="transaction-fee", type=parse_fee) parser.add_argument('-C', "--cache", help='force the resultant transaction into the transaction cache.' ' Mostly for testing.', action='store_true'), parser.add_argument('-u', "--show-unspents", action='store_true', help='show TxOut items for this transaction in Spendable form.') parser.add_argument('-b', "--bitcoind-url", help='URL to bitcoind instance to validate against (http://user:pass@host:port).') parser.add_argument('-o', "--output-file", metavar="path-to-output-file", type=argparse.FileType('wb'), help='file to write transaction to. This supresses most other output.') parser.add_argument("argument", nargs="+", help='generic argument: can be a hex transaction id ' '(exactly 64 characters) to be fetched from cache or a web service;' ' a transaction as a hex string; a path name to a transaction to be loaded;' ' a spendable 4-tuple of the form tx_id/tx_out_idx/script_hex/satoshi_count ' 'to be added to TxIn list; an address/satoshi_count to be added to the TxOut ' 'list; an address to be added to the TxOut list and placed in the "split' ' pool".') args = parser.parse_args() # defaults txs = [] spendables = [] payables = [] key_iters = [] TX_ID_RE = re.compile(r"^[0-9a-fA-F]{64}$") # there are a few warnings we might optionally print out, but only if # they are relevant. We don't want to print them out multiple times, so we # collect them here and print them at the end if they ever kick in. warning_tx_cache = None warning_get_tx = None warning_spendables = None if args.private_key_file: wif_re = re.compile(r"[1-9a-km-zA-LMNP-Z]{51,111}") # address_re = re.compile(r"[1-9a-kmnp-zA-KMNP-Z]{27-31}") for f in args.private_key_file: if f.name.endswith(".gpg"): gpg_args = ["gpg", "-d"] if args.gpg_argument: gpg_args.extend(args.gpg_argument.split()) gpg_args.append(f.name) popen = subprocess.Popen(gpg_args, stdout=subprocess.PIPE) f = popen.stdout for line in f.readlines(): # decode if isinstance(line, bytes): line = line.decode("utf8") # look for WIFs possible_keys = wif_re.findall(line) def make_key(x): try: return Key.from_text(x) except Exception: return None keys = [make_key(x) for x in possible_keys] for key in keys: if key: key_iters.append((k.wif() for k in key.subkeys(""))) # if len(keys) == 1 and key.hierarchical_wallet() is None: # # we have exactly 1 WIF. Let's look for an address # potential_addresses = address_re.findall(line) # we create the tx_db lazily tx_db = None for arg in args.argument: # hex transaction id if TX_ID_RE.match(arg): if tx_db is None: warning_tx_cache = message_about_tx_cache_env() warning_get_tx = message_about_get_tx_env() tx_db = get_tx_db() tx = tx_db.get(h2b_rev(arg)) if not tx: for m in [warning_tx_cache, warning_get_tx, warning_spendables]: if m: print("warning: %s" % m, file=sys.stderr) parser.error("can't find Tx with id %s" % arg) txs.append(tx) continue # hex transaction data try: tx = Tx.tx_from_hex(arg) txs.append(tx) continue except Exception: pass try: key = Key.from_text(arg) # TODO: check network if key.wif() is None: payables.append((key.address(), 0)) continue # TODO: support paths to subkeys key_iters.append((k.wif() for k in key.subkeys(""))) continue except Exception: pass if os.path.exists(arg): try: with open(arg, "rb") as f: if f.name.endswith("hex"): f = io.BytesIO(codecs.getreader("hex_codec")(f).read()) tx = Tx.parse(f) txs.append(tx) try: tx.parse_unspents(f) except Exception as ex: pass continue except Exception: pass parts = arg.split("/") if len(parts) == 4: # spendable try: spendables.append(Spendable.from_text(arg)) continue except Exception: pass # TODO: fix allowable_prefixes allowable_prefixes = b'\0' if len(parts) == 2 and encoding.is_valid_bitcoin_address( parts[0], allowable_prefixes=allowable_prefixes): try: payables.append(parts) continue except ValueError: pass parser.error("can't parse %s" % arg) if args.fetch_spendables: warning_spendables = message_about_spendables_for_address_env() for address in args.fetch_spendables: spendables.extend(spendables_for_address(address)) for tx in txs: if tx.missing_unspents() and args.augment: if tx_db is None: warning_tx_cache = message_about_tx_cache_env() warning_get_tx = message_about_get_tx_env() tx_db = get_tx_db() tx.unspents_from_db(tx_db, ignore_missing=True) txs_in = [] txs_out = [] unspents = [] # we use a clever trick here to keep each tx_in corresponding with its tx_out for tx in txs: smaller = min(len(tx.txs_in), len(tx.txs_out)) txs_in.extend(tx.txs_in[:smaller]) txs_out.extend(tx.txs_out[:smaller]) unspents.extend(tx.unspents[:smaller]) for tx in txs: smaller = min(len(tx.txs_in), len(tx.txs_out)) txs_in.extend(tx.txs_in[smaller:]) txs_out.extend(tx.txs_out[smaller:]) unspents.extend(tx.unspents[smaller:]) for spendable in spendables: txs_in.append(spendable.tx_in()) unspents.append(spendable) for address, coin_value in payables: script = standard_tx_out_script(address) txs_out.append(TxOut(coin_value, script)) lock_time = args.lock_time version = args.transaction_version # if no lock_time is explicitly set, inherit from the first tx or use default if lock_time is None: if txs: lock_time = txs[0].lock_time else: lock_time = DEFAULT_LOCK_TIME # if no version is explicitly set, inherit from the first tx or use default if version is None: if txs: version = txs[0].version else: version = DEFAULT_VERSION if args.remove_tx_in: s = set(args.remove_tx_in) txs_in = [tx_in for idx, tx_in in enumerate(txs_in) if idx not in s] if args.remove_tx_out: s = set(args.remove_tx_out) txs_out = [tx_out for idx, tx_out in enumerate(txs_out) if idx not in s] tx = Tx(txs_in=txs_in, txs_out=txs_out, lock_time=lock_time, version=version, unspents=unspents) fee = args.fee try: distribute_from_split_pool(tx, fee) except ValueError as ex: print("warning: %s" % ex.args[0], file=sys.stderr) unsigned_before = tx.bad_signature_count() if unsigned_before > 0 and key_iters: def wif_iter(iters): while len(iters) > 0: for idx, iter in enumerate(iters): try: wif = next(iter) yield wif except StopIteration: iters = iters[:idx] + iters[idx+1:] break print("signing...", file=sys.stderr) sign_tx(tx, wif_iter(key_iters)) unsigned_after = tx.bad_signature_count() if unsigned_after > 0 and key_iters: print("warning: %d TxIn items still unsigned" % unsigned_after, file=sys.stderr) if len(tx.txs_in) == 0: print("warning: transaction has no inputs", file=sys.stderr) if len(tx.txs_out) == 0: print("warning: transaction has no outputs", file=sys.stderr) include_unspents = (unsigned_after > 0) tx_as_hex = tx.as_hex(include_unspents=include_unspents) if args.output_file: f = args.output_file if f.name.endswith(".hex"): f.write(tx_as_hex.encode("utf8")) else: tx.stream(f) if include_unspents: tx.stream_unspents(f) f.close() elif args.show_unspents: for spendable in tx.tx_outs_as_spendable(): print(spendable.as_text()) else: if not tx.missing_unspents(): check_fees(tx) dump_tx(tx, args.network) if include_unspents: print("including unspents in hex dump since transaction not fully signed") print(tx_as_hex) if args.cache: if tx_db is None: warning_tx_cache = message_about_tx_cache_env() warning_get_tx = message_about_get_tx_env() tx_db = get_tx_db() tx_db.put(tx) if args.bitcoind_url: if tx_db is None: warning_tx_cache = message_about_tx_cache_env() warning_get_tx = message_about_get_tx_env() tx_db = get_tx_db() validate_bitcoind(tx, tx_db, args.bitcoind_url) if tx.missing_unspents(): print("\n** can't validate transaction as source transactions missing", file=sys.stderr) else: try: if tx_db is None: warning_tx_cache = message_about_tx_cache_env() warning_get_tx = message_about_get_tx_env() tx_db = get_tx_db() tx.validate_unspents(tx_db) print('all incoming transaction values validated') except BadSpendableError as ex: print("\n**** ERROR: FEES INCORRECTLY STATED: %s" % ex.args[0], file=sys.stderr) except Exception as ex: print("\n*** can't validate source transactions as untampered: %s" % ex.args[0], file=sys.stderr) # print warnings for m in [warning_tx_cache, warning_get_tx, warning_spendables]: if m: print("warning: %s" % m, file=sys.stderr)
def main(): parser = create_parser() args = parser.parse_args() (txs, spendables, payables, key_iters, p2sh_lookup, tx_db, warning_tx_cache, warning_tx_for_tx_hash, warning_spendables) = parse_context(args, parser) txs_in = [] txs_out = [] unspents = [] # we use a clever trick here to keep each tx_in corresponding with its tx_out for tx in txs: smaller = min(len(tx.txs_in), len(tx.txs_out)) txs_in.extend(tx.txs_in[:smaller]) txs_out.extend(tx.txs_out[:smaller]) unspents.extend(tx.unspents[:smaller]) for tx in txs: smaller = min(len(tx.txs_in), len(tx.txs_out)) txs_in.extend(tx.txs_in[smaller:]) txs_out.extend(tx.txs_out[smaller:]) unspents.extend(tx.unspents[smaller:]) for spendable in spendables: txs_in.append(spendable.tx_in()) unspents.append(spendable) for address, coin_value in payables: script = standard_tx_out_script(address) txs_out.append(TxOut(coin_value, script)) lock_time = args.lock_time version = args.transaction_version # if no lock_time is explicitly set, inherit from the first tx or use default if lock_time is None: if txs: lock_time = txs[0].lock_time else: lock_time = DEFAULT_LOCK_TIME # if no version is explicitly set, inherit from the first tx or use default if version is None: if txs: version = txs[0].version else: version = DEFAULT_VERSION if args.remove_tx_in: s = set(args.remove_tx_in) txs_in = [tx_in for idx, tx_in in enumerate(txs_in) if idx not in s] if args.remove_tx_out: s = set(args.remove_tx_out) txs_out = [tx_out for idx, tx_out in enumerate(txs_out) if idx not in s] tx = Tx(txs_in=txs_in, txs_out=txs_out, lock_time=lock_time, version=version, unspents=unspents) fee = args.fee try: distribute_from_split_pool(tx, fee) except ValueError as ex: print("warning: %s" % ex.args[0], file=sys.stderr) unsigned_before = tx.bad_signature_count() unsigned_after = unsigned_before if unsigned_before > 0 and key_iters: def wif_iter(iters): while len(iters) > 0: for idx, iter in enumerate(iters): try: wif = next(iter) yield wif except StopIteration: iters = iters[:idx] + iters[idx+1:] break print("signing...", file=sys.stderr) sign_tx(tx, wif_iter(key_iters), p2sh_lookup=p2sh_lookup) unsigned_after = tx.bad_signature_count() if unsigned_after > 0: print("warning: %d TxIn items still unsigned" % unsigned_after, file=sys.stderr) if len(tx.txs_in) == 0: print("warning: transaction has no inputs", file=sys.stderr) if len(tx.txs_out) == 0: print("warning: transaction has no outputs", file=sys.stderr) include_unspents = (unsigned_after > 0) tx_as_hex = tx.as_hex(include_unspents=include_unspents) if args.output_file: f = args.output_file if f.name.endswith(".hex"): f.write(tx_as_hex.encode("utf8")) else: tx.stream(f) if include_unspents: tx.stream_unspents(f) f.close() elif args.show_unspents: for spendable in tx.tx_outs_as_spendable(): print(spendable.as_text()) else: if not tx.missing_unspents(): check_fees(tx) dump_tx(tx, args.network, args.verbose_signature, args.disassemble, args.trace, args.pdb) if include_unspents: print("including unspents in hex dump since transaction not fully signed") print(tx_as_hex) if args.cache: if tx_db is None: warning_tx_cache = message_about_tx_cache_env() warning_tx_for_tx_hash = message_about_tx_for_tx_hash_env(args.network) tx_db = get_tx_db(args.network) tx_db.put(tx) if args.bitcoind_url: if tx_db is None: warning_tx_cache = message_about_tx_cache_env() warning_tx_for_tx_hash = message_about_tx_for_tx_hash_env(args.network) tx_db = get_tx_db(args.network) validate_bitcoind(tx, tx_db, args.bitcoind_url) if tx.missing_unspents(): print("\n** can't validate transaction as source transactions missing", file=sys.stderr) else: try: if tx_db is None: warning_tx_cache = message_about_tx_cache_env() warning_tx_for_tx_hash = message_about_tx_for_tx_hash_env(args.network) tx_db = get_tx_db(args.network) tx.validate_unspents(tx_db) print('all incoming transaction values validated') except BadSpendableError as ex: print("\n**** ERROR: FEES INCORRECTLY STATED: %s" % ex.args[0], file=sys.stderr) except Exception as ex: print("\n*** can't validate source transactions as untampered: %s" % ex.args[0], file=sys.stderr) # print warnings for m in [warning_tx_cache, warning_tx_for_tx_hash, warning_spendables]: if m: print("warning: %s" % m, file=sys.stderr)
def main(): parser = create_parser() args = parser.parse_args() (txs, spendables, payables, key_iters, p2sh_lookup, tx_db, warning_tx_cache, warning_tx_for_tx_hash, warning_spendables) = parse_context(args, parser) txs_in = [] txs_out = [] unspents = [] # we use a clever trick here to keep each tx_in corresponding with its tx_out for tx in txs: smaller = min(len(tx.txs_in), len(tx.txs_out)) txs_in.extend(tx.txs_in[:smaller]) txs_out.extend(tx.txs_out[:smaller]) unspents.extend(tx.unspents[:smaller]) for tx in txs: smaller = min(len(tx.txs_in), len(tx.txs_out)) txs_in.extend(tx.txs_in[smaller:]) txs_out.extend(tx.txs_out[smaller:]) unspents.extend(tx.unspents[smaller:]) for spendable in spendables: txs_in.append(spendable.tx_in()) unspents.append(spendable) for address, coin_value in payables: script = standard_tx_out_script(address) txs_out.append(TxOut(coin_value, script)) lock_time = args.lock_time version = args.transaction_version # if no lock_time is explicitly set, inherit from the first tx or use default if lock_time is None: if txs: lock_time = txs[0].lock_time else: lock_time = DEFAULT_LOCK_TIME # if no version is explicitly set, inherit from the first tx or use default if version is None: if txs: version = txs[0].version else: version = DEFAULT_VERSION if args.remove_tx_in: s = set(args.remove_tx_in) txs_in = [tx_in for idx, tx_in in enumerate(txs_in) if idx not in s] if args.remove_tx_out: s = set(args.remove_tx_out) txs_out = [ tx_out for idx, tx_out in enumerate(txs_out) if idx not in s ] tx = Tx(txs_in=txs_in, txs_out=txs_out, lock_time=lock_time, version=version, unspents=unspents) fee = args.fee try: distribute_from_split_pool(tx, fee) except ValueError as ex: print("warning: %s" % ex.args[0], file=sys.stderr) unsigned_before = tx.bad_signature_count() unsigned_after = unsigned_before if unsigned_before > 0 and key_iters: def wif_iter(iters): while len(iters) > 0: for idx, iter in enumerate(iters): try: wif = next(iter) yield wif except StopIteration: iters = iters[:idx] + iters[idx + 1:] break print("signing...", file=sys.stderr) sign_tx(tx, wif_iter(key_iters), p2sh_lookup=p2sh_lookup) unsigned_after = tx.bad_signature_count() if unsigned_after > 0: print("warning: %d TxIn items still unsigned" % unsigned_after, file=sys.stderr) if len(tx.txs_in) == 0: print("warning: transaction has no inputs", file=sys.stderr) if len(tx.txs_out) == 0: print("warning: transaction has no outputs", file=sys.stderr) include_unspents = (unsigned_after > 0) tx_as_hex = tx.as_hex(include_unspents=include_unspents) if args.output_file: f = args.output_file if f.name.endswith(".hex"): f.write(tx_as_hex.encode("utf8")) else: tx.stream(f) if include_unspents: tx.stream_unspents(f) f.close() elif args.show_unspents: for spendable in tx.tx_outs_as_spendable(): print(spendable.as_text()) else: if not tx.missing_unspents(): check_fees(tx) dump_tx(tx, args.network, args.verbose_signature, args.disassemble, args.trace, args.pdb) if include_unspents: print( "including unspents in hex dump since transaction not fully signed" ) print(tx_as_hex) if args.cache: if tx_db is None: warning_tx_cache = message_about_tx_cache_env() warning_tx_for_tx_hash = message_about_tx_for_tx_hash_env( args.network) tx_db = get_tx_db(args.network) tx_db.put(tx) if args.bitcoind_url: if tx_db is None: warning_tx_cache = message_about_tx_cache_env() warning_tx_for_tx_hash = message_about_tx_for_tx_hash_env( args.network) tx_db = get_tx_db(args.network) validate_bitcoind(tx, tx_db, args.bitcoind_url) if tx.missing_unspents(): print("\n** can't validate transaction as source transactions missing", file=sys.stderr) else: try: if tx_db is None: warning_tx_cache = message_about_tx_cache_env() warning_tx_for_tx_hash = message_about_tx_for_tx_hash_env( args.network) tx_db = get_tx_db(args.network) tx.validate_unspents(tx_db) print('all incoming transaction values validated') except BadSpendableError as ex: print("\n**** ERROR: FEES INCORRECTLY STATED: %s" % ex.args[0], file=sys.stderr) except Exception as ex: print( "\n*** can't validate source transactions as untampered: %s" % ex.args[0], file=sys.stderr) # print warnings for m in [warning_tx_cache, warning_tx_for_tx_hash, warning_spendables]: if m: print("warning: %s" % m, file=sys.stderr)
# Very important part. When you move funds to a p2sh address you write a special scriptPubKey: # Instead of: OP_DUP OP_HASH160 <PubkeyHash> OP_EQUALVERIFY OP_CHECKSIG # your p2sh scriptPubKey will be: # OP_HASH160 <hash(redeemScript)> OP_EQUAL # standard_tx_out_script(address) gives the scriptPubKey for a given multisig address script = standard_tx_out_script(address) # Fake coinbase transaction to fill our p2sh address # It it is a coinbase transaction we put in a newly constructed block. tx_in = TxIn.coinbase_tx_in(script=b'') print("TxIn: %s" % tx_in.__str__()) tx_out = TxOut(1000000, script) print("TxOut: %s" % tx_out.__str__()) tx1 = Tx(version=1, txs_in=[tx_in], txs_out=[tx_out]) tx1.as_hex() # we now have an UTXO redeemable by supplying the script and the required sigs. # tx_utils.create_tx() allows to spend all the UTXO from the preavious tx to an arbitrary address. tx2 = tx_utils.create_tx(tx1.tx_outs_as_spendable(), [keys[-1].address()]) # to split the input in each of the generated addresses # tx2 = tx_utils.create_tx(tx1.tx_outs_as_spendable(), [keys[i].address() for i in range(len(keys))]) print("unsigned transaction:") print("bad signatures: %s" % tx2.bad_signature_count()) print(tx2.as_hex()) for i in range(1, N+1): print("signining with key number: %s" % i) hash160_lookup = build_hash160_lookup([keys[i].secret_exponent()]) p2sh_lookup = build_p2sh_lookup([underlying_script]) tx2.sign(hash160_lookup=hash160_lookup,p2sh_lookup=p2sh_lookup) print(tx2.as_hex()) print("This transactions have now : %s signature of %t necessary" % (i, N)) print("bad signatures: %s" % tx2.bad_signature_count())