def _on_data(self): """Try to read P2P messages from the recv buffer. This method reads data from the buffer in a loop. It deserializes, parses and verifies the P2P header, then passes the P2P payload to the on_message callback for processing.""" try: while True: if len(self.recvbuf) < 4: return if self.recvbuf[:4] != self.magic_bytes: raise ValueError("magic bytes mismatch: {} != {}".format(repr(self.magic_bytes), repr(self.recvbuf))) if len(self.recvbuf) < 4 + 12 + 4 + 4: return command = self.recvbuf[4:4+12].split(b"\x00", 1)[0] msglen = struct.unpack("<i", self.recvbuf[4+12:4+12+4])[0] checksum = self.recvbuf[4+12+4:4+12+4+4] if len(self.recvbuf) < 4 + 12 + 4 + 4 + msglen: return msg = self.recvbuf[4+12+4+4:4+12+4+4+msglen] th = sha256(msg) h = sha256(th) if checksum != h[:4]: raise ValueError("got bad checksum " + repr(self.recvbuf)) self.recvbuf = self.recvbuf[4+12+4+4+msglen:] if command not in MESSAGEMAP: raise ValueError("Received unknown command from %s:%d: '%s' %s" % (self.dstaddr, self.dstport, command, repr(msg))) f = BytesIO(msg) t = MESSAGEMAP[command]() t.deserialize(f) self._log_message("receive", t) self.on_message(t) except Exception as e: logger.exception('Error reading message:', repr(e)) raise
def p2pkh_address_to_script(self,v): pubkey = hex_str_to_bytes(v['pubkey']) p2wpkh = CScript([OP_0, hash160(pubkey)]) p2sh_p2wpkh = CScript([OP_HASH160, hash160(p2wpkh), OP_EQUAL]) p2pk = CScript([pubkey, OP_CHECKSIG]) p2pkh = CScript(hex_str_to_bytes(v['scriptPubKey'])) p2sh_p2pk = CScript([OP_HASH160, hash160(p2pk), OP_EQUAL]) p2sh_p2pkh = CScript([OP_HASH160, hash160(p2pkh), OP_EQUAL]) p2wsh_p2pk = CScript([OP_0, sha256(p2pk)]) p2wsh_p2pkh = CScript([OP_0, sha256(p2pkh)]) p2sh_p2wsh_p2pk = CScript([OP_HASH160, hash160(p2wsh_p2pk), OP_EQUAL]) p2sh_p2wsh_p2pkh = CScript([OP_HASH160, hash160(p2wsh_p2pkh), OP_EQUAL]) return [p2wpkh, p2sh_p2wpkh, p2pk, p2pkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh]
def build_message(self, message): """Build a serialized P2P message""" command = message.command data = message.serialize() tmsg = self.magic_bytes tmsg += command tmsg += b"\x00" * (12 - len(command)) tmsg += struct.pack("<I", len(data)) th = sha256(data) h = sha256(th) tmsg += h[:4] tmsg += data return tmsg
def _build_message(self, message): """Build a serialized P2P message""" command = message.command data = message.serialize() tmsg = MAGIC_BYTES[self.network] tmsg += command tmsg += b"\x00" * (12 - len(command)) tmsg += struct.pack("<I", len(data)) th = sha256(data) h = sha256(th) tmsg += h[:4] tmsg += data return tmsg
def witness_script_test(self): # Now test signing transaction to P2SH-P2WSH addresses without wallet # Create a new P2SH-P2WSH 1-of-1 multisig address: embedded_address = self.nodes[1].getaddressinfo(self.nodes[1].getnewaddress()) embedded_privkey = self.nodes[1].dumpprivkey(embedded_address["address"]) p2sh_p2wsh_address = self.nodes[1].addmultisigaddress(1, [embedded_address["pubkey"]], "", "p2sh-segwit") # send transaction to P2SH-P2WSH 1-of-1 multisig address self.nodes[0].generate(101) self.nodes[0].sendtoaddress(p2sh_p2wsh_address["address"], 49.999) self.nodes[0].generate(1) self.sync_all() # Find the UTXO for the transaction node[1] should have received, check witnessScript matches unspent_output = self.nodes[1].listunspent(0, 999999, [p2sh_p2wsh_address["address"]])[0] assert_equal(unspent_output["witnessScript"], p2sh_p2wsh_address["redeemScript"]) p2sh_redeemScript = CScript([OP_0, sha256(hex_str_to_bytes(p2sh_p2wsh_address["redeemScript"]))]) assert_equal(unspent_output["redeemScript"], p2sh_redeemScript.hex()) # Now create and sign a transaction spending that output on node[0], which doesn't know the scripts or keys spending_tx = self.nodes[0].createrawtransaction([unspent_output], {self.nodes[1].getnewaddress(): Decimal("49.998")}) spending_tx_signed = self.nodes[0].signrawtransactionwithkey(spending_tx, [embedded_privkey], [unspent_output]) # Check the signing completed successfully assert 'complete' in spending_tx_signed assert_equal(spending_tx_signed['complete'], True)
def p2sh_address_to_script(self, v): bare = CScript(hex_str_to_bytes(v['hex'])) p2sh = CScript(hex_str_to_bytes(v['scriptPubKey'])) p2wsh = CScript([OP_0, sha256(bare)]) p2sh_p2wsh = CScript([OP_HASH160, hash160(p2wsh), OP_EQUAL]) return([bare, p2sh, p2wsh, p2sh_p2wsh])
def decodescript_script_pub_key(self): public_key = '03b0da749730dc9b4b1f4a14d6902877a92541f5368778853d9c4a0cb7802dcfb2' push_public_key = '21' + public_key public_key_hash = '5dd1d3a048119c27b28293056724d9522f26d945' push_public_key_hash = '14' + public_key_hash uncompressed_public_key = '04b0da749730dc9b4b1f4a14d6902877a92541f5368778853d9c4a0cb7802dcfb25e01fc8fde47c96c98a4f3a8123e33a38a50cf9025cc8c4494a518f991792bb7' push_uncompressed_public_key = '41' + uncompressed_public_key p2wsh_p2pk_script_hash = 'd8590cf8ea0674cf3d49fd7ca249b85ef7485dea62c138468bddeb20cd6519f7' # below are test cases for all of the standard transaction types # 1) P2PK scriptPubKey # <pubkey> OP_CHECKSIG rpc_result = self.nodes[0].decodescript(push_public_key + 'ac') assert_equal(public_key + ' OP_CHECKSIG', rpc_result['asm']) # P2PK is translated to P2WPKH assert_equal('0 ' + public_key_hash, rpc_result['segwit']['asm']) # 2) P2PKH scriptPubKey # OP_DUP OP_HASH160 <PubKeyHash> OP_EQUALVERIFY OP_CHECKSIG rpc_result = self.nodes[0].decodescript('76a9' + push_public_key_hash + '88ac') assert_equal('OP_DUP OP_HASH160 ' + public_key_hash + ' OP_EQUALVERIFY OP_CHECKSIG', rpc_result['asm']) # P2PKH is translated to P2WPKH assert_equal('0 ' + public_key_hash, rpc_result['segwit']['asm']) # 3) multisig scriptPubKey # <m> <A pubkey> <B pubkey> <C pubkey> <n> OP_CHECKMULTISIG # just imagine that the pub keys used below are different. # for our purposes here it does not matter that they are the same even though it is unrealistic. multisig_script = '52' + push_public_key + push_public_key + push_public_key + '53ae' rpc_result = self.nodes[0].decodescript(multisig_script) assert_equal('2 ' + public_key + ' ' + public_key + ' ' + public_key + ' 3 OP_CHECKMULTISIG', rpc_result['asm']) # multisig in P2WSH multisig_script_hash = sha256(hex_str_to_bytes(multisig_script)).hex() assert_equal('0 ' + multisig_script_hash, rpc_result['segwit']['asm']) # 4) P2SH scriptPubKey # OP_HASH160 <Hash160(redeemScript)> OP_EQUAL. # push_public_key_hash here should actually be the hash of a redeem script. # but this works the same for purposes of this test. rpc_result = self.nodes[0].decodescript('a9' + push_public_key_hash + '87') assert_equal('OP_HASH160 ' + public_key_hash + ' OP_EQUAL', rpc_result['asm']) # P2SH does not work in segwit secripts. decodescript should not return a result for it. assert 'segwit' not in rpc_result # 5) null data scriptPubKey # use a signature look-alike here to make sure that we do not decode random data as a signature. # this matters if/when signature sighash decoding comes along. # would want to make sure that no such decoding takes place in this case. signature_imposter = '48304502207fa7a6d1e0ee81132a269ad84e68d695483745cde8b541e3bf630749894e342a022100c1f7ab20e13e22fb95281a870f3dcf38d782e53023ee313d741ad0cfbc0c509001' # OP_RETURN <data> rpc_result = self.nodes[0].decodescript('6a' + signature_imposter) assert_equal('OP_RETURN ' + signature_imposter[2:], rpc_result['asm']) # 6) a CLTV redeem script. redeem scripts are in-effect scriptPubKey scripts, so adding a test here. # OP_NOP2 is also known as OP_CHECKLOCKTIMEVERIFY. # just imagine that the pub keys used below are different. # for our purposes here it does not matter that they are the same even though it is unrealistic. # # OP_IF # <receiver-pubkey> OP_CHECKSIGVERIFY # OP_ELSE # <lock-until> OP_CHECKLOCKTIMEVERIFY OP_DROP # OP_ENDIF # <sender-pubkey> OP_CHECKSIG # # lock until block 500,000 cltv_script = '63' + push_public_key + 'ad670320a107b17568' + push_public_key + 'ac' rpc_result = self.nodes[0].decodescript(cltv_script) assert_equal('OP_IF ' + public_key + ' OP_CHECKSIGVERIFY OP_ELSE 500000 OP_CHECKLOCKTIMEVERIFY OP_DROP OP_ENDIF ' + public_key + ' OP_CHECKSIG', rpc_result['asm']) # CLTV script in P2WSH cltv_script_hash = sha256(hex_str_to_bytes(cltv_script)).hex() assert_equal('0 ' + cltv_script_hash, rpc_result['segwit']['asm']) # 7) P2PK scriptPubKey # <pubkey> OP_CHECKSIG rpc_result = self.nodes[0].decodescript(push_uncompressed_public_key + 'ac') assert_equal(uncompressed_public_key + ' OP_CHECKSIG', rpc_result['asm']) # uncompressed pubkeys are invalid for checksigs in segwit scripts. # decodescript should not return a P2WPKH equivalent. assert 'segwit' not in rpc_result # 8) multisig scriptPubKey with an uncompressed pubkey # <m> <A pubkey> <B pubkey> <n> OP_CHECKMULTISIG # just imagine that the pub keys used below are different. # the purpose of this test is to check that a segwit script is not returned for bare multisig scripts # with an uncompressed pubkey in them. rpc_result = self.nodes[0].decodescript('52' + push_public_key + push_uncompressed_public_key +'52ae') assert_equal('2 ' + public_key + ' ' + uncompressed_public_key + ' 2 OP_CHECKMULTISIG', rpc_result['asm']) # uncompressed pubkeys are invalid for checksigs in segwit scripts. # decodescript should not return a P2WPKH equivalent. assert 'segwit' not in rpc_result # 9) P2WPKH scriptpubkey # 0 <PubKeyHash> rpc_result = self.nodes[0].decodescript('00' + push_public_key_hash) assert_equal('0 ' + public_key_hash, rpc_result['asm']) # segwit scripts do not work nested into each other. # a nested segwit script should not be returned in the results. assert 'segwit' not in rpc_result # 10) P2WSH scriptpubkey # 0 <ScriptHash> # even though this hash is of a P2PK script which is better used as bare P2WPKH, it should not matter # for the purpose of this test. rpc_result = self.nodes[0].decodescript('0020' + p2wsh_p2pk_script_hash) assert_equal('0 ' + p2wsh_p2pk_script_hash, rpc_result['asm']) # segwit scripts do not work nested into each other. # a nested segwit script should not be returned in the results. assert 'segwit' not in rpc_result
def run_test(self): self.nodes[0].generate(161) # block 161 self.log.info("Verify sigops are counted in GBT with pre-BIP141 rules before the fork") txid = self.nodes[0].sendtoaddress(self.nodes[0].getnewaddress(), 1) tmpl = self.nodes[0].getblocktemplate({'rules': ['segwit']}) assert tmpl['sizelimit'] == 100000 assert 'weightlimit' not in tmpl assert tmpl['sigoplimit'] == 2000 assert tmpl['transactions'][0]['hash'] == txid assert tmpl['transactions'][0]['sigops'] == 2 tmpl = self.nodes[0].getblocktemplate({'rules': ['segwit']}) assert tmpl['sizelimit'] == 100000 assert 'weightlimit' not in tmpl assert tmpl['sigoplimit'] == 2000 assert tmpl['transactions'][0]['hash'] == txid assert tmpl['transactions'][0]['sigops'] == 2 self.nodes[0].generate(1) # block 162 balance_presetup = self.nodes[0].getbalance() self.pubkey = [] p2sh_ids = [] # p2sh_ids[NODE][VER] is an array of txids that spend to a witness version VER pkscript to an address for NODE embedded in p2sh wit_ids = [] # wit_ids[NODE][VER] is an array of txids that spend to a witness version VER pkscript to an address for NODE via bare witness for i in range(3): newaddress = self.nodes[i].getnewaddress() self.pubkey.append(self.nodes[i].getaddressinfo(newaddress)["pubkey"]) multiscript = CScript([OP_1, hex_str_to_bytes(self.pubkey[-1]), OP_1, OP_CHECKMULTISIG]) p2sh_ms_addr = self.nodes[i].addmultisigaddress(1, [self.pubkey[-1]], '', 'p2sh-segwit')['address'] bip173_ms_addr = self.nodes[i].addmultisigaddress(1, [self.pubkey[-1]], '', 'bech32')['address'] assert_equal(p2sh_ms_addr, script_to_p2sh_p2wsh(multiscript)) assert_equal(bip173_ms_addr, script_to_p2wsh(multiscript)) p2sh_ids.append([]) wit_ids.append([]) for v in range(2): p2sh_ids[i].append([]) wit_ids[i].append([]) for i in range(5): for n in range(3): for v in range(2): wit_ids[n][v].append(send_to_witness(v, self.nodes[0], find_spendable_utxo(self.nodes[0], 50), self.pubkey[n], False, Decimal("49.999"))) p2sh_ids[n][v].append(send_to_witness(v, self.nodes[0], find_spendable_utxo(self.nodes[0], 50), self.pubkey[n], True, Decimal("49.999"))) self.nodes[0].generate(1) # block 163 self.sync_blocks() # Make sure all nodes recognize the transactions as theirs assert_equal(self.nodes[0].getbalance(), balance_presetup - 60 * 50 + 20 * Decimal("49.999") + 50) assert_equal(self.nodes[1].getbalance(), 20 * Decimal("49.999")) assert_equal(self.nodes[2].getbalance(), 20 * Decimal("49.999")) self.nodes[0].generate(260) # block 423 self.sync_blocks() self.log.info("Verify witness txs are skipped for mining before the fork") self.skip_mine(self.nodes[2], wit_ids[NODE_2][WIT_V0][0], True) # block 424 self.skip_mine(self.nodes[2], wit_ids[NODE_2][WIT_V1][0], True) # block 425 self.skip_mine(self.nodes[2], p2sh_ids[NODE_2][WIT_V0][0], True) # block 426 self.skip_mine(self.nodes[2], p2sh_ids[NODE_2][WIT_V1][0], True) # block 427 self.log.info("Verify unsigned p2sh witness txs without a redeem script are invalid") self.fail_accept(self.nodes[2], "mandatory-script-verify-flag", p2sh_ids[NODE_2][WIT_V0][1], False) self.fail_accept(self.nodes[2], "mandatory-script-verify-flag", p2sh_ids[NODE_2][WIT_V1][1], False) self.nodes[2].generate(4) # blocks 428-431 self.log.info("Verify previous witness txs skipped for mining can now be mined") assert_equal(len(self.nodes[2].getrawmempool()), 4) blockhash = self.nodes[2].generate(1)[0] # block 432 (first block with new rules; 432 = 144 * 3) self.sync_blocks() assert_equal(len(self.nodes[2].getrawmempool()), 0) segwit_tx_list = self.nodes[2].getblock(blockhash)["tx"] assert_equal(len(segwit_tx_list), 5) self.log.info("Verify default node can't accept txs with missing witness") # unsigned, no scriptsig self.fail_accept(self.nodes[0], "mandatory-script-verify-flag", wit_ids[NODE_0][WIT_V0][0], False) self.fail_accept(self.nodes[0], "mandatory-script-verify-flag", wit_ids[NODE_0][WIT_V1][0], False) self.fail_accept(self.nodes[0], "mandatory-script-verify-flag", p2sh_ids[NODE_0][WIT_V0][0], False) self.fail_accept(self.nodes[0], "mandatory-script-verify-flag", p2sh_ids[NODE_0][WIT_V1][0], False) # unsigned with redeem script self.fail_accept(self.nodes[0], "mandatory-script-verify-flag", p2sh_ids[NODE_0][WIT_V0][0], False, witness_script(False, self.pubkey[0])) self.fail_accept(self.nodes[0], "mandatory-script-verify-flag", p2sh_ids[NODE_0][WIT_V1][0], False, witness_script(True, self.pubkey[0])) self.log.info("Verify block and transaction serialization rpcs return differing serializations depending on rpc serialization flag") assert self.nodes[2].getblock(blockhash, False) != self.nodes[0].getblock(blockhash, False) assert self.nodes[1].getblock(blockhash, False) == self.nodes[2].getblock(blockhash, False) for tx_id in segwit_tx_list: tx = FromHex(CTransaction(), self.nodes[2].gettransaction(tx_id)["hex"]) assert self.nodes[2].getrawtransaction(tx_id, False, blockhash) != self.nodes[0].getrawtransaction(tx_id, False, blockhash) assert self.nodes[1].getrawtransaction(tx_id, False, blockhash) == self.nodes[2].getrawtransaction(tx_id, False, blockhash) assert self.nodes[0].getrawtransaction(tx_id, False, blockhash) != self.nodes[2].gettransaction(tx_id)["hex"] assert self.nodes[1].getrawtransaction(tx_id, False, blockhash) == self.nodes[2].gettransaction(tx_id)["hex"] assert self.nodes[0].getrawtransaction(tx_id, False, blockhash) == tx.serialize_without_witness().hex() self.log.info("Verify witness txs without witness data are invalid after the fork") self.fail_accept(self.nodes[2], 'non-mandatory-script-verify-flag (Witness program hash mismatch) (code 64)', wit_ids[NODE_2][WIT_V0][2], sign=False) self.fail_accept(self.nodes[2], 'non-mandatory-script-verify-flag (Witness program was passed an empty witness) (code 64)', wit_ids[NODE_2][WIT_V1][2], sign=False) self.fail_accept(self.nodes[2], 'non-mandatory-script-verify-flag (Witness program hash mismatch) (code 64)', p2sh_ids[NODE_2][WIT_V0][2], sign=False, redeem_script=witness_script(False, self.pubkey[2])) self.fail_accept(self.nodes[2], 'non-mandatory-script-verify-flag (Witness program was passed an empty witness) (code 64)', p2sh_ids[NODE_2][WIT_V1][2], sign=False, redeem_script=witness_script(True, self.pubkey[2])) self.log.info("Verify default node can now use witness txs") self.success_mine(self.nodes[0], wit_ids[NODE_0][WIT_V0][0], True) # block 432 self.success_mine(self.nodes[0], wit_ids[NODE_0][WIT_V1][0], True) # block 433 self.success_mine(self.nodes[0], p2sh_ids[NODE_0][WIT_V0][0], True) # block 434 self.success_mine(self.nodes[0], p2sh_ids[NODE_0][WIT_V1][0], True) # block 435 self.log.info("Verify sigops are counted in GBT with BIP141 rules after the fork") txid = self.nodes[0].sendtoaddress(self.nodes[0].getnewaddress(), 1) tmpl = self.nodes[0].getblocktemplate({'rules': ['segwit']}) assert tmpl['sizelimit'] >= 390000 # actual maximum size is lower due to minimum mandatory non-witness data assert tmpl['weightlimit'] == 400000 assert tmpl['sigoplimit'] == 8000 assert tmpl['transactions'][0]['txid'] == txid assert tmpl['transactions'][0]['sigops'] == 8 self.nodes[0].generate(1) # Mine a block to clear the gbt cache self.log.info("Non-segwit miners are able to use GBT response after activation.") # Create a 3-tx chain: tx1 (non-segwit input, paying to a segwit output) -> # tx2 (segwit input, paying to a non-segwit output) -> # tx3 (non-segwit input, paying to a non-segwit output). # tx1 is allowed to appear in the block, but no others. txid1 = send_to_witness(1, self.nodes[0], find_spendable_utxo(self.nodes[0], 50), self.pubkey[0], False, Decimal("49.996")) hex_tx = self.nodes[0].gettransaction(txid)['hex'] tx = FromHex(CTransaction(), hex_tx) assert tx.wit.is_null() # This should not be a segwit input assert txid1 in self.nodes[0].getrawmempool() # Now create tx2, which will spend from txid1. tx = CTransaction() tx.vin.append(CTxIn(COutPoint(int(txid1, 16), 0), b'')) tx.vout.append(CTxOut(int(49.99 * COIN), CScript([OP_TRUE, OP_DROP] * 15 + [OP_TRUE]))) tx2_hex = self.nodes[0].signrawtransactionwithwallet(ToHex(tx))['hex'] txid2 = self.nodes[0].sendrawtransaction(tx2_hex) tx = FromHex(CTransaction(), tx2_hex) assert not tx.wit.is_null() # Now create tx3, which will spend from txid2 tx = CTransaction() tx.vin.append(CTxIn(COutPoint(int(txid2, 16), 0), b"")) tx.vout.append(CTxOut(int(49.95 * COIN), CScript([OP_TRUE, OP_DROP] * 15 + [OP_TRUE]))) # Huge fee tx.calc_sha256() txid3 = self.nodes[0].sendrawtransaction(ToHex(tx)) assert tx.wit.is_null() assert txid3 in self.nodes[0].getrawmempool() # Check that getblocktemplate includes all transactions. template = self.nodes[0].getblocktemplate({"rules": ["segwit"]}) template_txids = [t['txid'] for t in template['transactions']] assert txid1 in template_txids assert txid2 in template_txids assert txid3 in template_txids # Check that wtxid is properly reported in mempool entry assert_equal(int(self.nodes[0].getmempoolentry(txid3)["wtxid"], 16), tx.calc_sha256(True)) # Mine a block to clear the gbt cache again. self.nodes[0].generate(1) self.log.info("Verify behaviour of importaddress and listunspent") # Some public keys to be used later pubkeys = [ "0363D44AABD0F1699138239DF2F042C3282C0671CC7A76826A55C8203D90E39242", # b4Vfz2Ly8GAubXRrhpSGF9ctmorBYVzdokEQcDrbV2EmnzB5LonH "02D3E626B3E616FC8662B489C123349FECBFC611E778E5BE739B257EAE4721E5BF", # b4bVUqL7X7ZJpqzDnF6Ks32YM9GXbVdrEbmznQMRXcTixRM1AbGA "04A47F2CBCEFFA7B9BCDA184E7D5668D3DA6F9079AD41E422FA5FD7B2D458F2538A62F5BD8EC85C2477F39650BD391EA6250207065B2A81DA8B009FC891E898F0E", # 8iW8cP2tV3YUkc8XrPz3v7CvFjV5VkhpzgKos82q1LWshZEooJo "02A47F2CBCEFFA7B9BCDA184E7D5668D3DA6F9079AD41E422FA5FD7B2D458F2538", # b4BabAFLEnDwVU4FB2SosQPc42WvquuCqaa1rE34tV8rmhbQbjQv "036722F784214129FEB9E8129D626324F3F6716555B603FFE8300BBCB882151228", # b54DUJnyPL6VQMoCd4sXtvCBvhM1vG2vSCwqShSRE8ryS7Cuu9H1 "0266A8396EE936BF6D99D17920DB21C6C7B1AB14C639D5CD72B300297E416FD2EC", # b8HQcxqFUhg4BsdjE21bisYRkwT4jvKhTUmcYh5ege5SQbLsmrAz "0450A38BD7F0AC212FEBA77354A9B036A32E0F7C81FC4E0C5ADCA7C549C4505D2522458C2D9AE3CEFD684E039194B72C8A10F9CB9D4764AB26FCC2718D421D3B84", # 92h2XPssjBpsJN5CqSP7v9a7cf2kgDunBC6PDFwJHMACM1rrVBJ ] # Import a compressed key and an uncompressed key, generate some multisig addresses self.nodes[0].importprivkey("8j9PwFko4f5TjUAyE9ssZAQSNmbCHXdV6sBwuh2ouxyeg41E8Vu") uncompressed_spendable_address = ["cg37jZdKe7YsxJMUVZNKD36EuaDpPdbZqe"] self.nodes[0].importprivkey("b2yTVwqY6fX1PqXUEqWbUCYAaUo4YFQc8nRZavfUt9Ki77ewQaDr") compressed_spendable_address = ["cWjYG6zbUdBfsULfCHD8xQF928QYxcy4ZZ"] assert not self.nodes[0].getaddressinfo(uncompressed_spendable_address[0])['iscompressed'] assert self.nodes[0].getaddressinfo(compressed_spendable_address[0])['iscompressed'] self.nodes[0].importpubkey(pubkeys[0]) compressed_solvable_address = [key_to_p2pkh(pubkeys[0])] self.nodes[0].importpubkey(pubkeys[1]) compressed_solvable_address.append(key_to_p2pkh(pubkeys[1])) self.nodes[0].importpubkey(pubkeys[2]) uncompressed_solvable_address = [key_to_p2pkh(pubkeys[2])] spendable_anytime = [] # These outputs should be seen anytime after importprivkey and addmultisigaddress spendable_after_importaddress = [] # These outputs should be seen after importaddress solvable_after_importaddress = [] # These outputs should be seen after importaddress but not spendable unsolvable_after_importaddress = [] # These outputs should be unsolvable after importaddress solvable_anytime = [] # These outputs should be solvable after importpubkey unseen_anytime = [] # These outputs should never be seen uncompressed_spendable_address.append(self.nodes[0].addmultisigaddress(2, [uncompressed_spendable_address[0], compressed_spendable_address[0]])['address']) uncompressed_spendable_address.append(self.nodes[0].addmultisigaddress(2, [uncompressed_spendable_address[0], uncompressed_spendable_address[0]])['address']) compressed_spendable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_spendable_address[0], compressed_spendable_address[0]])['address']) uncompressed_solvable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_spendable_address[0], uncompressed_solvable_address[0]])['address']) compressed_solvable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_spendable_address[0], compressed_solvable_address[0]])['address']) compressed_solvable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_solvable_address[0], compressed_solvable_address[1]])['address']) # Test multisig_without_privkey # We have 2 public keys without private keys, use addmultisigaddress to add to wallet. # Money sent to P2SH of multisig of this should only be seen after importaddress with the BASE58 P2SH address. multisig_without_privkey_address = self.nodes[0].addmultisigaddress(2, [pubkeys[3], pubkeys[4]])['address'] script = CScript([OP_2, hex_str_to_bytes(pubkeys[3]), hex_str_to_bytes(pubkeys[4]), OP_2, OP_CHECKMULTISIG]) solvable_after_importaddress.append(CScript([OP_HASH160, hash160(script), OP_EQUAL])) for i in compressed_spendable_address: v = self.nodes[0].getaddressinfo(i) if (v['isscript']): [bare, p2sh, p2wsh, p2sh_p2wsh] = self.p2sh_address_to_script(v) # p2sh multisig with compressed keys should always be spendable spendable_anytime.extend([p2sh]) # bare multisig can be watched and signed, but is not treated as ours solvable_after_importaddress.extend([bare]) # P2WSH and P2SH(P2WSH) multisig with compressed keys are spendable after direct importaddress spendable_after_importaddress.extend([p2wsh, p2sh_p2wsh]) else: [p2wpkh, p2sh_p2wpkh, p2pk, p2pkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh] = self.p2pkh_address_to_script(v) # normal P2PKH and P2PK with compressed keys should always be spendable spendable_anytime.extend([p2pkh, p2pk]) # P2SH_P2PK, P2SH_P2PKH with compressed keys are spendable after direct importaddress spendable_after_importaddress.extend([p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh]) # P2WPKH and P2SH_P2WPKH with compressed keys should always be spendable spendable_anytime.extend([p2wpkh, p2sh_p2wpkh]) for i in uncompressed_spendable_address: v = self.nodes[0].getaddressinfo(i) if (v['isscript']): [bare, p2sh, p2wsh, p2sh_p2wsh] = self.p2sh_address_to_script(v) # p2sh multisig with uncompressed keys should always be spendable spendable_anytime.extend([p2sh]) # bare multisig can be watched and signed, but is not treated as ours solvable_after_importaddress.extend([bare]) # P2WSH and P2SH(P2WSH) multisig with uncompressed keys are never seen unseen_anytime.extend([p2wsh, p2sh_p2wsh]) else: [p2wpkh, p2sh_p2wpkh, p2pk, p2pkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh] = self.p2pkh_address_to_script(v) # normal P2PKH and P2PK with uncompressed keys should always be spendable spendable_anytime.extend([p2pkh, p2pk]) # P2SH_P2PK and P2SH_P2PKH are spendable after direct importaddress spendable_after_importaddress.extend([p2sh_p2pk, p2sh_p2pkh]) # Witness output types with uncompressed keys are never seen unseen_anytime.extend([p2wpkh, p2sh_p2wpkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh]) for i in compressed_solvable_address: v = self.nodes[0].getaddressinfo(i) if (v['isscript']): # Multisig without private is not seen after addmultisigaddress, but seen after importaddress [bare, p2sh, p2wsh, p2sh_p2wsh] = self.p2sh_address_to_script(v) solvable_after_importaddress.extend([bare, p2sh, p2wsh, p2sh_p2wsh]) else: [p2wpkh, p2sh_p2wpkh, p2pk, p2pkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh] = self.p2pkh_address_to_script(v) # normal P2PKH, P2PK, P2WPKH and P2SH_P2WPKH with compressed keys should always be seen solvable_anytime.extend([p2pkh, p2pk, p2wpkh, p2sh_p2wpkh]) # P2SH_P2PK, P2SH_P2PKH with compressed keys are seen after direct importaddress solvable_after_importaddress.extend([p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh]) for i in uncompressed_solvable_address: v = self.nodes[0].getaddressinfo(i) if (v['isscript']): [bare, p2sh, p2wsh, p2sh_p2wsh] = self.p2sh_address_to_script(v) # Base uncompressed multisig without private is not seen after addmultisigaddress, but seen after importaddress solvable_after_importaddress.extend([bare, p2sh]) # P2WSH and P2SH(P2WSH) multisig with uncompressed keys are never seen unseen_anytime.extend([p2wsh, p2sh_p2wsh]) else: [p2wpkh, p2sh_p2wpkh, p2pk, p2pkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh] = self.p2pkh_address_to_script(v) # normal P2PKH and P2PK with uncompressed keys should always be seen solvable_anytime.extend([p2pkh, p2pk]) # P2SH_P2PK, P2SH_P2PKH with uncompressed keys are seen after direct importaddress solvable_after_importaddress.extend([p2sh_p2pk, p2sh_p2pkh]) # Witness output types with uncompressed keys are never seen unseen_anytime.extend([p2wpkh, p2sh_p2wpkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh]) op1 = CScript([OP_1]) op0 = CScript([OP_0]) # dTXLAVZMSwCLfWDF4us6U6F1FWbyWyBYwK is the P2SH(P2PKH) version of cV2MQNbEFyXpjGihDYNqf4s1RQGbS94jVC unsolvable_address_key = hex_str_to_bytes("02341AEC7587A51CDE5279E0630A531AEA2615A9F80B17E8D9376327BAEAA59E3D") unsolvablep2pkh = CScript([OP_DUP, OP_HASH160, hash160(unsolvable_address_key), OP_EQUALVERIFY, OP_CHECKSIG]) unsolvablep2wshp2pkh = CScript([OP_0, sha256(unsolvablep2pkh)]) p2shop0 = CScript([OP_HASH160, hash160(op0), OP_EQUAL]) p2wshop1 = CScript([OP_0, sha256(op1)]) unsolvable_after_importaddress.append(unsolvablep2pkh) unsolvable_after_importaddress.append(unsolvablep2wshp2pkh) unsolvable_after_importaddress.append(op1) # OP_1 will be imported as script unsolvable_after_importaddress.append(p2wshop1) unseen_anytime.append(op0) # OP_0 will be imported as P2SH address with no script provided unsolvable_after_importaddress.append(p2shop0) spendable_txid = [] solvable_txid = [] spendable_txid.append(self.mine_and_test_listunspent(spendable_anytime, 2)) solvable_txid.append(self.mine_and_test_listunspent(solvable_anytime, 1)) self.mine_and_test_listunspent(spendable_after_importaddress + solvable_after_importaddress + unseen_anytime + unsolvable_after_importaddress, 0) importlist = [] for i in compressed_spendable_address + uncompressed_spendable_address + compressed_solvable_address + uncompressed_solvable_address: v = self.nodes[0].getaddressinfo(i) if (v['isscript']): bare = hex_str_to_bytes(v['hex']) importlist.append(bare.hex()) importlist.append(CScript([OP_0, sha256(bare)]).hex()) else: pubkey = hex_str_to_bytes(v['pubkey']) p2pk = CScript([pubkey, OP_CHECKSIG]) p2pkh = CScript([OP_DUP, OP_HASH160, hash160(pubkey), OP_EQUALVERIFY, OP_CHECKSIG]) importlist.append(p2pk.hex()) importlist.append(p2pkh.hex()) importlist.append(CScript([OP_0, hash160(pubkey)]).hex()) importlist.append(CScript([OP_0, sha256(p2pk)]).hex()) importlist.append(CScript([OP_0, sha256(p2pkh)]).hex()) importlist.append(unsolvablep2pkh.hex()) importlist.append(unsolvablep2wshp2pkh.hex()) importlist.append(op1.hex()) importlist.append(p2wshop1.hex()) for i in importlist: # import all generated addresses. The wallet already has the private keys for some of these, so catch JSON RPC # exceptions and continue. try_rpc(-4, "The wallet already contains the private key for this address or script", self.nodes[0].importaddress, i, "", False, True) self.nodes[0].importaddress(script_to_p2sh(op0)) # import OP_0 as address only self.nodes[0].importaddress(multisig_without_privkey_address) # Test multisig_without_privkey spendable_txid.append(self.mine_and_test_listunspent(spendable_anytime + spendable_after_importaddress, 2)) solvable_txid.append(self.mine_and_test_listunspent(solvable_anytime + solvable_after_importaddress, 1)) self.mine_and_test_listunspent(unsolvable_after_importaddress, 1) self.mine_and_test_listunspent(unseen_anytime, 0) spendable_txid.append(self.mine_and_test_listunspent(spendable_anytime + spendable_after_importaddress, 2)) solvable_txid.append(self.mine_and_test_listunspent(solvable_anytime + solvable_after_importaddress, 1)) self.mine_and_test_listunspent(unsolvable_after_importaddress, 1) self.mine_and_test_listunspent(unseen_anytime, 0) # Repeat some tests. This time we don't add witness scripts with importaddress # Import a compressed key and an uncompressed key, generate some multisig addresses self.nodes[0].importprivkey("8id8M1PDTjZimEZBfxp2iYgp9xFZ865PHcVqdksDhja21H3kuZC") uncompressed_spendable_address = ["cS8VPRWos5pYHt6ay9WAnenT6LeDpfdtVP"] self.nodes[0].importprivkey("b2QBP8LNcftKZAW4zx7DdZYa3FvxMmuAAuCvkgmKcvEptAiiFsvU") compressed_spendable_address = ["ckhW8KuyAKe1AvKYy5FXcP8JZrWA9n6u3g"] self.nodes[0].importpubkey(pubkeys[5]) compressed_solvable_address = [key_to_p2pkh(pubkeys[5])] self.nodes[0].importpubkey(pubkeys[6]) uncompressed_solvable_address = [key_to_p2pkh(pubkeys[6])] unseen_anytime = [] # These outputs should never be seen solvable_anytime = [] # These outputs should be solvable after importpubkey unseen_anytime = [] # These outputs should never be seen uncompressed_spendable_address.append(self.nodes[0].addmultisigaddress(2, [uncompressed_spendable_address[0], compressed_spendable_address[0]])['address']) uncompressed_spendable_address.append(self.nodes[0].addmultisigaddress(2, [uncompressed_spendable_address[0], uncompressed_spendable_address[0]])['address']) compressed_spendable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_spendable_address[0], compressed_spendable_address[0]])['address']) uncompressed_solvable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_solvable_address[0], uncompressed_solvable_address[0]])['address']) compressed_solvable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_spendable_address[0], compressed_solvable_address[0]])['address']) premature_witaddress = [] for i in compressed_spendable_address: v = self.nodes[0].getaddressinfo(i) if (v['isscript']): [bare, p2sh, p2wsh, p2sh_p2wsh] = self.p2sh_address_to_script(v) premature_witaddress.append(script_to_p2sh(p2wsh)) else: [p2wpkh, p2sh_p2wpkh, p2pk, p2pkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh] = self.p2pkh_address_to_script(v) # P2WPKH, P2SH_P2WPKH are always spendable spendable_anytime.extend([p2wpkh, p2sh_p2wpkh]) for i in uncompressed_spendable_address + uncompressed_solvable_address: v = self.nodes[0].getaddressinfo(i) if (v['isscript']): [bare, p2sh, p2wsh, p2sh_p2wsh] = self.p2sh_address_to_script(v) # P2WSH and P2SH(P2WSH) multisig with uncompressed keys are never seen unseen_anytime.extend([p2wsh, p2sh_p2wsh]) else: [p2wpkh, p2sh_p2wpkh, p2pk, p2pkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh] = self.p2pkh_address_to_script(v) # P2WPKH, P2SH_P2WPKH with uncompressed keys are never seen unseen_anytime.extend([p2wpkh, p2sh_p2wpkh]) for i in compressed_solvable_address: v = self.nodes[0].getaddressinfo(i) if (v['isscript']): [bare, p2sh, p2wsh, p2sh_p2wsh] = self.p2sh_address_to_script(v) premature_witaddress.append(script_to_p2sh(p2wsh)) else: [p2wpkh, p2sh_p2wpkh, p2pk, p2pkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh] = self.p2pkh_address_to_script(v) # P2SH_P2PK, P2SH_P2PKH with compressed keys are always solvable solvable_anytime.extend([p2wpkh, p2sh_p2wpkh]) self.mine_and_test_listunspent(spendable_anytime, 2) self.mine_and_test_listunspent(solvable_anytime, 1) self.mine_and_test_listunspent(unseen_anytime, 0) # Check that createrawtransaction/decoderawtransaction with non-v0 Bech32 works v1_addr = program_to_witness(1, [3, 5]) v1_tx = self.nodes[0].createrawtransaction([getutxo(spendable_txid[0])], {v1_addr: 1}) v1_decoded = self.nodes[1].decoderawtransaction(v1_tx) assert_equal(v1_decoded['vout'][0]['scriptPubKey']['addresses'][0], v1_addr) assert_equal(v1_decoded['vout'][0]['scriptPubKey']['hex'], "51020305") # Check that spendable outputs are really spendable self.create_and_mine_tx_from_txids(spendable_txid) # import all the private keys so solvable addresses become spendable self.nodes[0].importprivkey("b4Vfz2Ly8GAubXRrhpSGF9ctmorBYVzdokEQcDrbV2EmnzB5LonH") self.nodes[0].importprivkey("b4bVUqL7X7ZJpqzDnF6Ks32YM9GXbVdrEbmznQMRXcTixRM1AbGA") self.nodes[0].importprivkey("8iW8cP2tV3YUkc8XrPz3v7CvFjV5VkhpzgKos82q1LWshZEooJo") self.nodes[0].importprivkey("b4BabAFLEnDwVU4FB2SosQPc42WvquuCqaa1rE34tV8rmhbQbjQv") self.nodes[0].importprivkey("b54DUJnyPL6VQMoCd4sXtvCBvhM1vG2vSCwqShSRE8ryS7Cuu9H1") self.nodes[0].importprivkey("b8HQcxqFUhg4BsdjE21bisYRkwT4jvKhTUmcYh5ege5SQbLsmrAz") self.create_and_mine_tx_from_txids(solvable_txid) # Test that importing native P2WPKH/P2WSH scripts works for use_p2wsh in [False, True]: if use_p2wsh: scriptPubKey = "00203a59f3f56b713fdcf5d1a57357f02c44342cbf306ffe0c4741046837bf90561a" transaction = "01000000000100e1f505000000002200203a59f3f56b713fdcf5d1a57357f02c44342cbf306ffe0c4741046837bf90561a00000000" else: scriptPubKey = "a9142f8c469c2f0084c48e11f998ffbe7efa7549f26d87" transaction = "01000000000100e1f5050000000017a9142f8c469c2f0084c48e11f998ffbe7efa7549f26d8700000000" self.nodes[1].importaddress(scriptPubKey, "", False) rawtxfund = self.nodes[1].fundrawtransaction(transaction)['hex'] rawtxfund = self.nodes[1].signrawtransactionwithwallet(rawtxfund)["hex"] txid = self.nodes[1].sendrawtransaction(rawtxfund) assert_equal(self.nodes[1].gettransaction(txid, True)["txid"], txid) assert_equal(self.nodes[1].listtransactions("*", 1, 0, True)[0]["txid"], txid) # Assert it is properly saved self.stop_node(1) self.start_node(1) assert_equal(self.nodes[1].gettransaction(txid, True)["txid"], txid) assert_equal(self.nodes[1].listtransactions("*", 1, 0, True)[0]["txid"], txid)
def decodescript_script_pub_key(self): public_key = '03b0da749730dc9b4b1f4a14d6902877a92541f5368778853d9c4a0cb7802dcfb2' push_public_key = '21' + public_key public_key_hash = '5dd1d3a048119c27b28293056724d9522f26d945' push_public_key_hash = '14' + public_key_hash uncompressed_public_key = '04b0da749730dc9b4b1f4a14d6902877a92541f5368778853d9c4a0cb7802dcfb25e01fc8fde47c96c98a4f3a8123e33a38a50cf9025cc8c4494a518f991792bb7' push_uncompressed_public_key = '41' + uncompressed_public_key p2wsh_p2pk_script_hash = 'd8590cf8ea0674cf3d49fd7ca249b85ef7485dea62c138468bddeb20cd6519f7' # below are test cases for all of the standard transaction types # 1) P2PK scriptPubKey # <pubkey> OP_CHECKSIG rpc_result = self.nodes[0].decodescript(push_public_key + 'ac') assert_equal(public_key + ' OP_CHECKSIG', rpc_result['asm']) # P2PK is translated to P2WPKH assert_equal('0 ' + public_key_hash, rpc_result['segwit']['asm']) # 2) P2PKH scriptPubKey # OP_DUP OP_HASH160 <PubKeyHash> OP_EQUALVERIFY OP_CHECKSIG rpc_result = self.nodes[0].decodescript('76a9' + push_public_key_hash + '88ac') assert_equal( 'OP_DUP OP_HASH160 ' + public_key_hash + ' OP_EQUALVERIFY OP_CHECKSIG', rpc_result['asm']) # P2PKH is translated to P2WPKH assert_equal('0 ' + public_key_hash, rpc_result['segwit']['asm']) # 3) multisig scriptPubKey # <m> <A pubkey> <B pubkey> <C pubkey> <n> OP_CHECKMULTISIG # just imagine that the pub keys used below are different. # for our purposes here it does not matter that they are the same even though it is unrealistic. multisig_script = '52' + push_public_key + push_public_key + push_public_key + '53ae' rpc_result = self.nodes[0].decodescript(multisig_script) assert_equal( '2 ' + public_key + ' ' + public_key + ' ' + public_key + ' 3 OP_CHECKMULTISIG', rpc_result['asm']) # multisig in P2WSH multisig_script_hash = sha256(hex_str_to_bytes(multisig_script)).hex() assert_equal('0 ' + multisig_script_hash, rpc_result['segwit']['asm']) # 4) P2SH scriptPubKey # OP_HASH160 <Hash160(redeemScript)> OP_EQUAL. # push_public_key_hash here should actually be the hash of a redeem script. # but this works the same for purposes of this test. rpc_result = self.nodes[0].decodescript('a9' + push_public_key_hash + '87') assert_equal('OP_HASH160 ' + public_key_hash + ' OP_EQUAL', rpc_result['asm']) # P2SH does not work in segwit secripts. decodescript should not return a result for it. assert 'segwit' not in rpc_result # 5) null data scriptPubKey # use a signature look-alike here to make sure that we do not decode random data as a signature. # this matters if/when signature sighash decoding comes along. # would want to make sure that no such decoding takes place in this case. signature_imposter = '48304502207fa7a6d1e0ee81132a269ad84e68d695483745cde8b541e3bf630749894e342a022100c1f7ab20e13e22fb95281a870f3dcf38d782e53023ee313d741ad0cfbc0c509001' # OP_RETURN <data> rpc_result = self.nodes[0].decodescript('6a' + signature_imposter) assert_equal('OP_RETURN ' + signature_imposter[2:], rpc_result['asm']) # 6) a CLTV redeem script. redeem scripts are in-effect scriptPubKey scripts, so adding a test here. # OP_NOP2 is also known as OP_CHECKLOCKTIMEVERIFY. # just imagine that the pub keys used below are different. # for our purposes here it does not matter that they are the same even though it is unrealistic. # # OP_IF # <receiver-pubkey> OP_CHECKSIGVERIFY # OP_ELSE # <lock-until> OP_CHECKLOCKTIMEVERIFY OP_DROP # OP_ENDIF # <sender-pubkey> OP_CHECKSIG # # lock until block 500,000 cltv_script = '63' + push_public_key + 'ad670320a107b17568' + push_public_key + 'ac' rpc_result = self.nodes[0].decodescript(cltv_script) assert_equal( 'OP_IF ' + public_key + ' OP_CHECKSIGVERIFY OP_ELSE 500000 OP_CHECKLOCKTIMEVERIFY OP_DROP OP_ENDIF ' + public_key + ' OP_CHECKSIG', rpc_result['asm']) # CLTV script in P2WSH cltv_script_hash = sha256(hex_str_to_bytes(cltv_script)).hex() assert_equal('0 ' + cltv_script_hash, rpc_result['segwit']['asm']) # 7) P2PK scriptPubKey # <pubkey> OP_CHECKSIG rpc_result = self.nodes[0].decodescript(push_uncompressed_public_key + 'ac') assert_equal(uncompressed_public_key + ' OP_CHECKSIG', rpc_result['asm']) # uncompressed pubkeys are invalid for checksigs in segwit scripts. # decodescript should not return a P2WPKH equivalent. assert 'segwit' not in rpc_result # 8) multisig scriptPubKey with an uncompressed pubkey # <m> <A pubkey> <B pubkey> <n> OP_CHECKMULTISIG # just imagine that the pub keys used below are different. # the purpose of this test is to check that a segwit script is not returned for bare multisig scripts # with an uncompressed pubkey in them. rpc_result = self.nodes[0].decodescript('52' + push_public_key + push_uncompressed_public_key + '52ae') assert_equal( '2 ' + public_key + ' ' + uncompressed_public_key + ' 2 OP_CHECKMULTISIG', rpc_result['asm']) # uncompressed pubkeys are invalid for checksigs in segwit scripts. # decodescript should not return a P2WPKH equivalent. assert 'segwit' not in rpc_result # 9) P2WPKH scriptpubkey # 0 <PubKeyHash> rpc_result = self.nodes[0].decodescript('00' + push_public_key_hash) assert_equal('0 ' + public_key_hash, rpc_result['asm']) # segwit scripts do not work nested into each other. # a nested segwit script should not be returned in the results. assert 'segwit' not in rpc_result # 10) P2WSH scriptpubkey # 0 <ScriptHash> # even though this hash is of a P2PK script which is better used as bare P2WPKH, it should not matter # for the purpose of this test. rpc_result = self.nodes[0].decodescript('0020' + p2wsh_p2pk_script_hash) assert_equal('0 ' + p2wsh_p2pk_script_hash, rpc_result['asm']) # segwit scripts do not work nested into each other. # a nested segwit script should not be returned in the results. assert 'segwit' not in rpc_result
def run_test(self): self.nodes[0].generate(161) #block 161 self.log.info("Verify sigops are counted in GBT with pre-BIP141 rules before the fork") txid = self.nodes[0].sendtoaddress(self.nodes[0].getnewaddress(), 1) tmpl = self.nodes[0].getblocktemplate({}) assert(tmpl['sizelimit'] == 1000000) assert('weightlimit' not in tmpl) assert(tmpl['sigoplimit'] == 20000) assert(tmpl['transactions'][0]['hash'] == txid) assert(tmpl['transactions'][0]['sigops'] == 2) tmpl = self.nodes[0].getblocktemplate({'rules':['segwit']}) assert(tmpl['sizelimit'] == 1000000) assert('weightlimit' not in tmpl) assert(tmpl['sigoplimit'] == 20000) assert(tmpl['transactions'][0]['hash'] == txid) assert(tmpl['transactions'][0]['sigops'] == 2) self.nodes[0].generate(1) #block 162 balance_presetup = self.nodes[0].getbalance() self.pubkey = [] p2sh_ids = [] # p2sh_ids[NODE][VER] is an array of txids that spend to a witness version VER pkscript to an address for NODE embedded in p2sh wit_ids = [] # wit_ids[NODE][VER] is an array of txids that spend to a witness version VER pkscript to an address for NODE via bare witness for i in range(3): newaddress = self.nodes[i].getnewaddress() self.pubkey.append(self.nodes[i].getaddressinfo(newaddress)["pubkey"]) multiscript = CScript([OP_1, hex_str_to_bytes(self.pubkey[-1]), OP_1, OP_CHECKMULTISIG]) p2sh_addr = self.nodes[i].addwitnessaddress(newaddress) bip173_addr = self.nodes[i].addwitnessaddress(newaddress, False) p2sh_ms_addr = self.nodes[i].addmultisigaddress(1, [self.pubkey[-1]], '', 'p2sh-segwit')['address'] bip173_ms_addr = self.nodes[i].addmultisigaddress(1, [self.pubkey[-1]], '', 'bech32')['address'] assert_equal(p2sh_addr, key_to_p2sh_p2wpkh(self.pubkey[-1])) assert_equal(bip173_addr, key_to_p2wpkh(self.pubkey[-1])) assert_equal(p2sh_ms_addr, script_to_p2sh_p2wsh(multiscript)) assert_equal(bip173_ms_addr, script_to_p2wsh(multiscript)) p2sh_ids.append([]) wit_ids.append([]) for v in range(2): p2sh_ids[i].append([]) wit_ids[i].append([]) for i in range(5): for n in range(3): for v in range(2): wit_ids[n][v].append(send_to_witness(v, self.nodes[0], find_spendable_utxo(self.nodes[0], 50), self.pubkey[n], False, Decimal("49.999"))) p2sh_ids[n][v].append(send_to_witness(v, self.nodes[0], find_spendable_utxo(self.nodes[0], 50), self.pubkey[n], True, Decimal("49.999"))) self.nodes[0].generate(1) #block 163 sync_blocks(self.nodes) # Make sure all nodes recognize the transactions as theirs assert_equal(self.nodes[0].getbalance(), balance_presetup - 60*50 + 20*Decimal("49.999") + 50) assert_equal(self.nodes[1].getbalance(), 20*Decimal("49.999")) assert_equal(self.nodes[2].getbalance(), 20*Decimal("49.999")) self.nodes[0].generate(260) #block 423 sync_blocks(self.nodes) self.log.info("Verify witness txs are skipped for mining before the fork") self.skip_mine(self.nodes[2], wit_ids[NODE_2][WIT_V0][0], True) #block 424 self.skip_mine(self.nodes[2], wit_ids[NODE_2][WIT_V1][0], True) #block 425 self.skip_mine(self.nodes[2], p2sh_ids[NODE_2][WIT_V0][0], True) #block 426 self.skip_mine(self.nodes[2], p2sh_ids[NODE_2][WIT_V1][0], True) #block 427 self.log.info("Verify unsigned p2sh witness txs without a redeem script are invalid") self.fail_accept(self.nodes[2], "mandatory-script-verify-flag", p2sh_ids[NODE_2][WIT_V0][1], False) self.fail_accept(self.nodes[2], "mandatory-script-verify-flag", p2sh_ids[NODE_2][WIT_V1][1], False) self.nodes[2].generate(4) # blocks 428-431 self.log.info("Verify previous witness txs skipped for mining can now be mined") assert_equal(len(self.nodes[2].getrawmempool()), 4) block = self.nodes[2].generate(1) #block 432 (first block with new rules; 432 = 144 * 3) sync_blocks(self.nodes) assert_equal(len(self.nodes[2].getrawmempool()), 0) segwit_tx_list = self.nodes[2].getblock(block[0])["tx"] assert_equal(len(segwit_tx_list), 5) self.log.info("Verify default node can't accept txs with missing witness") # unsigned, no scriptsig self.fail_accept(self.nodes[0], "mandatory-script-verify-flag", wit_ids[NODE_0][WIT_V0][0], False) self.fail_accept(self.nodes[0], "mandatory-script-verify-flag", wit_ids[NODE_0][WIT_V1][0], False) self.fail_accept(self.nodes[0], "mandatory-script-verify-flag", p2sh_ids[NODE_0][WIT_V0][0], False) self.fail_accept(self.nodes[0], "mandatory-script-verify-flag", p2sh_ids[NODE_0][WIT_V1][0], False) # unsigned with redeem script self.fail_accept(self.nodes[0], "mandatory-script-verify-flag", p2sh_ids[NODE_0][WIT_V0][0], False, witness_script(False, self.pubkey[0])) self.fail_accept(self.nodes[0], "mandatory-script-verify-flag", p2sh_ids[NODE_0][WIT_V1][0], False, witness_script(True, self.pubkey[0])) self.log.info("Verify block and transaction serialization rpcs return differing serializations depending on rpc serialization flag") assert(self.nodes[2].getblock(block[0], False) != self.nodes[0].getblock(block[0], False)) assert(self.nodes[1].getblock(block[0], False) == self.nodes[2].getblock(block[0], False)) for i in range(len(segwit_tx_list)): tx = FromHex(CTransaction(), self.nodes[2].gettransaction(segwit_tx_list[i])["hex"]) assert(self.nodes[2].getrawtransaction(segwit_tx_list[i]) != self.nodes[0].getrawtransaction(segwit_tx_list[i])) assert(self.nodes[1].getrawtransaction(segwit_tx_list[i], 0) == self.nodes[2].getrawtransaction(segwit_tx_list[i])) assert(self.nodes[0].getrawtransaction(segwit_tx_list[i]) != self.nodes[2].gettransaction(segwit_tx_list[i])["hex"]) assert(self.nodes[1].getrawtransaction(segwit_tx_list[i]) == self.nodes[2].gettransaction(segwit_tx_list[i])["hex"]) assert(self.nodes[0].getrawtransaction(segwit_tx_list[i]) == bytes_to_hex_str(tx.serialize_without_witness())) self.log.info("Verify witness txs without witness data are invalid after the fork") self.fail_accept(self.nodes[2], 'non-mandatory-script-verify-flag (Witness program hash mismatch) (code 64)', wit_ids[NODE_2][WIT_V0][2], sign=False) self.fail_accept(self.nodes[2], 'non-mandatory-script-verify-flag (Witness program was passed an empty witness) (code 64)', wit_ids[NODE_2][WIT_V1][2], sign=False) self.fail_accept(self.nodes[2], 'non-mandatory-script-verify-flag (Witness program hash mismatch) (code 64)', p2sh_ids[NODE_2][WIT_V0][2], sign=False, redeem_script=witness_script(False, self.pubkey[2])) self.fail_accept(self.nodes[2], 'non-mandatory-script-verify-flag (Witness program was passed an empty witness) (code 64)', p2sh_ids[NODE_2][WIT_V1][2], sign=False, redeem_script=witness_script(True, self.pubkey[2])) self.log.info("Verify default node can now use witness txs") self.success_mine(self.nodes[0], wit_ids[NODE_0][WIT_V0][0], True) #block 432 self.success_mine(self.nodes[0], wit_ids[NODE_0][WIT_V1][0], True) #block 433 self.success_mine(self.nodes[0], p2sh_ids[NODE_0][WIT_V0][0], True) #block 434 self.success_mine(self.nodes[0], p2sh_ids[NODE_0][WIT_V1][0], True) #block 435 self.log.info("Verify sigops are counted in GBT with BIP141 rules after the fork") txid = self.nodes[0].sendtoaddress(self.nodes[0].getnewaddress(), 1) tmpl = self.nodes[0].getblocktemplate({'rules':['segwit']}) assert(tmpl['sizelimit'] >= 3999577) # actual maximum size is lower due to minimum mandatory non-witness data assert(tmpl['weightlimit'] == 4000000) assert(tmpl['sigoplimit'] == 80000) assert(tmpl['transactions'][0]['txid'] == txid) assert(tmpl['transactions'][0]['sigops'] == 8) self.nodes[0].generate(1) # Mine a block to clear the gbt cache self.log.info("Non-segwit miners are able to use GBT response after activation.") # Create a 3-tx chain: tx1 (non-segwit input, paying to a segwit output) -> # tx2 (segwit input, paying to a non-segwit output) -> # tx3 (non-segwit input, paying to a non-segwit output). # tx1 is allowed to appear in the block, but no others. txid1 = send_to_witness(1, self.nodes[0], find_spendable_utxo(self.nodes[0], 50), self.pubkey[0], False, Decimal("49.996")) hex_tx = self.nodes[0].gettransaction(txid)['hex'] tx = FromHex(CTransaction(), hex_tx) assert(tx.wit.is_null()) # This should not be a segwit input assert(txid1 in self.nodes[0].getrawmempool()) # Now create tx2, which will spend from txid1. tx = CTransaction() tx.vin.append(CTxIn(COutPoint(int(txid1, 16), 0), b'')) tx.vout.append(CTxOut(int(49.99 * COIN), CScript([OP_TRUE, OP_DROP] * 15 + [OP_TRUE]))) tx2_hex = self.nodes[0].signrawtransactionwithwallet(ToHex(tx))['hex'] txid2 = self.nodes[0].sendrawtransaction(tx2_hex) tx = FromHex(CTransaction(), tx2_hex) assert(not tx.wit.is_null()) # Now create tx3, which will spend from txid2 tx = CTransaction() tx.vin.append(CTxIn(COutPoint(int(txid2, 16), 0), b"")) tx.vout.append(CTxOut(int(49.95 * COIN), CScript([OP_TRUE, OP_DROP] * 15 + [OP_TRUE]))) # Huge fee tx.calc_sha256() txid3 = self.nodes[0].sendrawtransaction(ToHex(tx)) assert(tx.wit.is_null()) assert(txid3 in self.nodes[0].getrawmempool()) # Now try calling getblocktemplate() without segwit support. template = self.nodes[0].getblocktemplate() # Check that tx1 is the only transaction of the 3 in the template. template_txids = [ t['txid'] for t in template['transactions'] ] assert(txid2 not in template_txids and txid3 not in template_txids) assert(txid1 in template_txids) # Check that running with segwit support results in all 3 being included. template = self.nodes[0].getblocktemplate({"rules": ["segwit"]}) template_txids = [ t['txid'] for t in template['transactions'] ] assert(txid1 in template_txids) assert(txid2 in template_txids) assert(txid3 in template_txids) # Check that wtxid is properly reported in mempool entry assert_equal(int(self.nodes[0].getmempoolentry(txid3)["wtxid"], 16), tx.calc_sha256(True)) # Mine a block to clear the gbt cache again. self.nodes[0].generate(1) self.log.info("Verify behaviour of importaddress, addwitnessaddress and listunspent") # Some public keys to be used later pubkeys = [ "0363D44AABD0F1699138239DF2F042C3282C0671CC7A76826A55C8203D90E39242", # cPiM8Ub4heR9NBYmgVzJQiUH1if44GSBGiqaeJySuL2BKxubvgwb "02D3E626B3E616FC8662B489C123349FECBFC611E778E5BE739B257EAE4721E5BF", # cPpAdHaD6VoYbW78kveN2bsvb45Q7G5PhaPApVUGwvF8VQ9brD97 "04A47F2CBCEFFA7B9BCDA184E7D5668D3DA6F9079AD41E422FA5FD7B2D458F2538A62F5BD8EC85C2477F39650BD391EA6250207065B2A81DA8B009FC891E898F0E", # 91zqCU5B9sdWxzMt1ca3VzbtVm2YM6Hi5Rxn4UDtxEaN9C9nzXV "02A47F2CBCEFFA7B9BCDA184E7D5668D3DA6F9079AD41E422FA5FD7B2D458F2538", # cPQFjcVRpAUBG8BA9hzr2yEzHwKoMgLkJZBBtK9vJnvGJgMjzTbd "036722F784214129FEB9E8129D626324F3F6716555B603FFE8300BBCB882151228", # cQGtcm34xiLjB1v7bkRa4V3aAc9tS2UTuBZ1UnZGeSeNy627fN66 "0266A8396EE936BF6D99D17920DB21C6C7B1AB14C639D5CD72B300297E416FD2EC", # cTW5mR5M45vHxXkeChZdtSPozrFwFgmEvTNnanCW6wrqwaCZ1X7K "0450A38BD7F0AC212FEBA77354A9B036A32E0F7C81FC4E0C5ADCA7C549C4505D2522458C2D9AE3CEFD684E039194B72C8A10F9CB9D4764AB26FCC2718D421D3B84", # 92h2XPssjBpsJN5CqSP7v9a7cf2kgDunBC6PDFwJHMACM1rrVBJ ] # Import a compressed key and an uncompressed key, generate some multisig addresses self.nodes[0].importprivkey("92e6XLo5jVAVwrQKPNTs93oQco8f8sDNBcpv73Dsrs397fQtFQn") uncompressed_spendable_address = ["mvozP4UwyGD2mGZU4D2eMvMLPB9WkMmMQu"] self.nodes[0].importprivkey("cNC8eQ5dg3mFAVePDX4ddmPYpPbw41r9bm2jd1nLJT77e6RrzTRR") compressed_spendable_address = ["mmWQubrDomqpgSYekvsU7HWEVjLFHAakLe"] assert ((self.nodes[0].getaddressinfo(uncompressed_spendable_address[0])['iscompressed'] == False)) assert ((self.nodes[0].getaddressinfo(compressed_spendable_address[0])['iscompressed'] == True)) self.nodes[0].importpubkey(pubkeys[0]) compressed_solvable_address = [key_to_p2pkh(pubkeys[0])] self.nodes[0].importpubkey(pubkeys[1]) compressed_solvable_address.append(key_to_p2pkh(pubkeys[1])) self.nodes[0].importpubkey(pubkeys[2]) uncompressed_solvable_address = [key_to_p2pkh(pubkeys[2])] spendable_anytime = [] # These outputs should be seen anytime after importprivkey and addmultisigaddress spendable_after_importaddress = [] # These outputs should be seen after importaddress solvable_after_importaddress = [] # These outputs should be seen after importaddress but not spendable unsolvable_after_importaddress = [] # These outputs should be unsolvable after importaddress solvable_anytime = [] # These outputs should be solvable after importpubkey unseen_anytime = [] # These outputs should never be seen uncompressed_spendable_address.append(self.nodes[0].addmultisigaddress(2, [uncompressed_spendable_address[0], compressed_spendable_address[0]])['address']) uncompressed_spendable_address.append(self.nodes[0].addmultisigaddress(2, [uncompressed_spendable_address[0], uncompressed_spendable_address[0]])['address']) compressed_spendable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_spendable_address[0], compressed_spendable_address[0]])['address']) uncompressed_solvable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_spendable_address[0], uncompressed_solvable_address[0]])['address']) compressed_solvable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_spendable_address[0], compressed_solvable_address[0]])['address']) compressed_solvable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_solvable_address[0], compressed_solvable_address[1]])['address']) unknown_address = ["mtKKyoHabkk6e4ppT7NaM7THqPUt7AzPrT", "2NDP3jLWAFT8NDAiUa9qiE6oBt2awmMq7Dx"] # Test multisig_without_privkey # We have 2 public keys without private keys, use addmultisigaddress to add to wallet. # Money sent to P2SH of multisig of this should only be seen after importaddress with the BASE58 P2SH address. multisig_without_privkey_address = self.nodes[0].addmultisigaddress(2, [pubkeys[3], pubkeys[4]])['address'] script = CScript([OP_2, hex_str_to_bytes(pubkeys[3]), hex_str_to_bytes(pubkeys[4]), OP_2, OP_CHECKMULTISIG]) solvable_after_importaddress.append(CScript([OP_HASH160, hash160(script), OP_EQUAL])) for i in compressed_spendable_address: v = self.nodes[0].getaddressinfo(i) if (v['isscript']): [bare, p2sh, p2wsh, p2sh_p2wsh] = self.p2sh_address_to_script(v) # p2sh multisig with compressed keys should always be spendable spendable_anytime.extend([p2sh]) # bare multisig can be watched and signed, but is not treated as ours solvable_after_importaddress.extend([bare]) # P2WSH and P2SH(P2WSH) multisig with compressed keys are spendable after direct importaddress spendable_after_importaddress.extend([p2wsh, p2sh_p2wsh]) else: [p2wpkh, p2sh_p2wpkh, p2pk, p2pkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh] = self.p2pkh_address_to_script(v) # normal P2PKH and P2PK with compressed keys should always be spendable spendable_anytime.extend([p2pkh, p2pk]) # P2SH_P2PK, P2SH_P2PKH with compressed keys are spendable after direct importaddress spendable_after_importaddress.extend([p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh]) # P2WPKH and P2SH_P2WPKH with compressed keys should always be spendable spendable_anytime.extend([p2wpkh, p2sh_p2wpkh]) for i in uncompressed_spendable_address: v = self.nodes[0].getaddressinfo(i) if (v['isscript']): [bare, p2sh, p2wsh, p2sh_p2wsh] = self.p2sh_address_to_script(v) # p2sh multisig with uncompressed keys should always be spendable spendable_anytime.extend([p2sh]) # bare multisig can be watched and signed, but is not treated as ours solvable_after_importaddress.extend([bare]) # P2WSH and P2SH(P2WSH) multisig with uncompressed keys are never seen unseen_anytime.extend([p2wsh, p2sh_p2wsh]) else: [p2wpkh, p2sh_p2wpkh, p2pk, p2pkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh] = self.p2pkh_address_to_script(v) # normal P2PKH and P2PK with uncompressed keys should always be spendable spendable_anytime.extend([p2pkh, p2pk]) # P2SH_P2PK and P2SH_P2PKH are spendable after direct importaddress spendable_after_importaddress.extend([p2sh_p2pk, p2sh_p2pkh]) # Witness output types with uncompressed keys are never seen unseen_anytime.extend([p2wpkh, p2sh_p2wpkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh]) for i in compressed_solvable_address: v = self.nodes[0].getaddressinfo(i) if (v['isscript']): # Multisig without private is not seen after addmultisigaddress, but seen after importaddress [bare, p2sh, p2wsh, p2sh_p2wsh] = self.p2sh_address_to_script(v) solvable_after_importaddress.extend([bare, p2sh, p2wsh, p2sh_p2wsh]) else: [p2wpkh, p2sh_p2wpkh, p2pk, p2pkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh] = self.p2pkh_address_to_script(v) # normal P2PKH, P2PK, P2WPKH and P2SH_P2WPKH with compressed keys should always be seen solvable_anytime.extend([p2pkh, p2pk, p2wpkh, p2sh_p2wpkh]) # P2SH_P2PK, P2SH_P2PKH with compressed keys are seen after direct importaddress solvable_after_importaddress.extend([p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh]) for i in uncompressed_solvable_address: v = self.nodes[0].getaddressinfo(i) if (v['isscript']): [bare, p2sh, p2wsh, p2sh_p2wsh] = self.p2sh_address_to_script(v) # Base uncompressed multisig without private is not seen after addmultisigaddress, but seen after importaddress solvable_after_importaddress.extend([bare, p2sh]) # P2WSH and P2SH(P2WSH) multisig with uncompressed keys are never seen unseen_anytime.extend([p2wsh, p2sh_p2wsh]) else: [p2wpkh, p2sh_p2wpkh, p2pk, p2pkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh] = self.p2pkh_address_to_script(v) # normal P2PKH and P2PK with uncompressed keys should always be seen solvable_anytime.extend([p2pkh, p2pk]) # P2SH_P2PK, P2SH_P2PKH with uncompressed keys are seen after direct importaddress solvable_after_importaddress.extend([p2sh_p2pk, p2sh_p2pkh]) # Witness output types with uncompressed keys are never seen unseen_anytime.extend([p2wpkh, p2sh_p2wpkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh]) op1 = CScript([OP_1]) op0 = CScript([OP_0]) # 2N7MGY19ti4KDMSzRfPAssP6Pxyuxoi6jLe is the P2SH(P2PKH) version of mjoE3sSrb8ByYEvgnC3Aox86u1CHnfJA4V unsolvable_address = ["mjoE3sSrb8ByYEvgnC3Aox86u1CHnfJA4V", "2N7MGY19ti4KDMSzRfPAssP6Pxyuxoi6jLe", script_to_p2sh(op1), script_to_p2sh(op0)] unsolvable_address_key = hex_str_to_bytes("02341AEC7587A51CDE5279E0630A531AEA2615A9F80B17E8D9376327BAEAA59E3D") unsolvablep2pkh = CScript([OP_DUP, OP_HASH160, hash160(unsolvable_address_key), OP_EQUALVERIFY, OP_CHECKSIG]) unsolvablep2wshp2pkh = CScript([OP_0, sha256(unsolvablep2pkh)]) p2shop0 = CScript([OP_HASH160, hash160(op0), OP_EQUAL]) p2wshop1 = CScript([OP_0, sha256(op1)]) unsolvable_after_importaddress.append(unsolvablep2pkh) unsolvable_after_importaddress.append(unsolvablep2wshp2pkh) unsolvable_after_importaddress.append(op1) # OP_1 will be imported as script unsolvable_after_importaddress.append(p2wshop1) unseen_anytime.append(op0) # OP_0 will be imported as P2SH address with no script provided unsolvable_after_importaddress.append(p2shop0) spendable_txid = [] solvable_txid = [] spendable_txid.append(self.mine_and_test_listunspent(spendable_anytime, 2)) solvable_txid.append(self.mine_and_test_listunspent(solvable_anytime, 1)) self.mine_and_test_listunspent(spendable_after_importaddress + solvable_after_importaddress + unseen_anytime + unsolvable_after_importaddress, 0) importlist = [] for i in compressed_spendable_address + uncompressed_spendable_address + compressed_solvable_address + uncompressed_solvable_address: v = self.nodes[0].getaddressinfo(i) if (v['isscript']): bare = hex_str_to_bytes(v['hex']) importlist.append(bytes_to_hex_str(bare)) importlist.append(bytes_to_hex_str(CScript([OP_0, sha256(bare)]))) else: pubkey = hex_str_to_bytes(v['pubkey']) p2pk = CScript([pubkey, OP_CHECKSIG]) p2pkh = CScript([OP_DUP, OP_HASH160, hash160(pubkey), OP_EQUALVERIFY, OP_CHECKSIG]) importlist.append(bytes_to_hex_str(p2pk)) importlist.append(bytes_to_hex_str(p2pkh)) importlist.append(bytes_to_hex_str(CScript([OP_0, hash160(pubkey)]))) importlist.append(bytes_to_hex_str(CScript([OP_0, sha256(p2pk)]))) importlist.append(bytes_to_hex_str(CScript([OP_0, sha256(p2pkh)]))) importlist.append(bytes_to_hex_str(unsolvablep2pkh)) importlist.append(bytes_to_hex_str(unsolvablep2wshp2pkh)) importlist.append(bytes_to_hex_str(op1)) importlist.append(bytes_to_hex_str(p2wshop1)) for i in importlist: # import all generated addresses. The wallet already has the private keys for some of these, so catch JSON RPC # exceptions and continue. try_rpc(-4, "The wallet already contains the private key for this address or script", self.nodes[0].importaddress, i, "", False, True) self.nodes[0].importaddress(script_to_p2sh(op0)) # import OP_0 as address only self.nodes[0].importaddress(multisig_without_privkey_address) # Test multisig_without_privkey spendable_txid.append(self.mine_and_test_listunspent(spendable_anytime + spendable_after_importaddress, 2)) solvable_txid.append(self.mine_and_test_listunspent(solvable_anytime + solvable_after_importaddress, 1)) self.mine_and_test_listunspent(unsolvable_after_importaddress, 1) self.mine_and_test_listunspent(unseen_anytime, 0) # addwitnessaddress should refuse to return a witness address if an uncompressed key is used # note that no witness address should be returned by unsolvable addresses for i in uncompressed_spendable_address + uncompressed_solvable_address + unknown_address + unsolvable_address: assert_raises_rpc_error(-4, "Public key or redeemscript not known to wallet, or the key is uncompressed", self.nodes[0].addwitnessaddress, i) # addwitnessaddress should return a witness addresses even if keys are not in the wallet self.nodes[0].addwitnessaddress(multisig_without_privkey_address) for i in compressed_spendable_address + compressed_solvable_address: witaddress = self.nodes[0].addwitnessaddress(i) # addwitnessaddress should return the same address if it is a known P2SH-witness address assert_equal(witaddress, self.nodes[0].addwitnessaddress(witaddress)) spendable_txid.append(self.mine_and_test_listunspent(spendable_anytime + spendable_after_importaddress, 2)) solvable_txid.append(self.mine_and_test_listunspent(solvable_anytime + solvable_after_importaddress, 1)) self.mine_and_test_listunspent(unsolvable_after_importaddress, 1) self.mine_and_test_listunspent(unseen_anytime, 0) # Repeat some tests. This time we don't add witness scripts with importaddress # Import a compressed key and an uncompressed key, generate some multisig addresses self.nodes[0].importprivkey("927pw6RW8ZekycnXqBQ2JS5nPyo1yRfGNN8oq74HeddWSpafDJH") uncompressed_spendable_address = ["mguN2vNSCEUh6rJaXoAVwY3YZwZvEmf5xi"] self.nodes[0].importprivkey("cMcrXaaUC48ZKpcyydfFo8PxHAjpsYLhdsp6nmtB3E2ER9UUHWnw") compressed_spendable_address = ["n1UNmpmbVUJ9ytXYXiurmGPQ3TRrXqPWKL"] self.nodes[0].importpubkey(pubkeys[5]) compressed_solvable_address = [key_to_p2pkh(pubkeys[5])] self.nodes[0].importpubkey(pubkeys[6]) uncompressed_solvable_address = [key_to_p2pkh(pubkeys[6])] spendable_after_addwitnessaddress = [] # These outputs should be seen after importaddress solvable_after_addwitnessaddress=[] # These outputs should be seen after importaddress but not spendable unseen_anytime = [] # These outputs should never be seen solvable_anytime = [] # These outputs should be solvable after importpubkey unseen_anytime = [] # These outputs should never be seen uncompressed_spendable_address.append(self.nodes[0].addmultisigaddress(2, [uncompressed_spendable_address[0], compressed_spendable_address[0]])['address']) uncompressed_spendable_address.append(self.nodes[0].addmultisigaddress(2, [uncompressed_spendable_address[0], uncompressed_spendable_address[0]])['address']) compressed_spendable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_spendable_address[0], compressed_spendable_address[0]])['address']) uncompressed_solvable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_solvable_address[0], uncompressed_solvable_address[0]])['address']) compressed_solvable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_spendable_address[0], compressed_solvable_address[0]])['address']) premature_witaddress = [] for i in compressed_spendable_address: v = self.nodes[0].getaddressinfo(i) if (v['isscript']): [bare, p2sh, p2wsh, p2sh_p2wsh] = self.p2sh_address_to_script(v) # P2WSH and P2SH(P2WSH) multisig with compressed keys are spendable after addwitnessaddress spendable_after_addwitnessaddress.extend([p2wsh, p2sh_p2wsh]) premature_witaddress.append(script_to_p2sh(p2wsh)) else: [p2wpkh, p2sh_p2wpkh, p2pk, p2pkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh] = self.p2pkh_address_to_script(v) # P2WPKH, P2SH_P2WPKH are always spendable spendable_anytime.extend([p2wpkh, p2sh_p2wpkh]) for i in uncompressed_spendable_address + uncompressed_solvable_address: v = self.nodes[0].getaddressinfo(i) if (v['isscript']): [bare, p2sh, p2wsh, p2sh_p2wsh] = self.p2sh_address_to_script(v) # P2WSH and P2SH(P2WSH) multisig with uncompressed keys are never seen unseen_anytime.extend([p2wsh, p2sh_p2wsh]) else: [p2wpkh, p2sh_p2wpkh, p2pk, p2pkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh] = self.p2pkh_address_to_script(v) # P2WPKH, P2SH_P2WPKH with uncompressed keys are never seen unseen_anytime.extend([p2wpkh, p2sh_p2wpkh]) for i in compressed_solvable_address: v = self.nodes[0].getaddressinfo(i) if (v['isscript']): # P2WSH multisig without private key are seen after addwitnessaddress [bare, p2sh, p2wsh, p2sh_p2wsh] = self.p2sh_address_to_script(v) solvable_after_addwitnessaddress.extend([p2wsh, p2sh_p2wsh]) premature_witaddress.append(script_to_p2sh(p2wsh)) else: [p2wpkh, p2sh_p2wpkh, p2pk, p2pkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh] = self.p2pkh_address_to_script(v) # P2SH_P2PK, P2SH_P2PKH with compressed keys are always solvable solvable_anytime.extend([p2wpkh, p2sh_p2wpkh]) self.mine_and_test_listunspent(spendable_anytime, 2) self.mine_and_test_listunspent(solvable_anytime, 1) self.mine_and_test_listunspent(spendable_after_addwitnessaddress + solvable_after_addwitnessaddress + unseen_anytime, 0) # addwitnessaddress should refuse to return a witness address if an uncompressed key is used # note that a multisig address returned by addmultisigaddress is not solvable until it is added with importaddress # premature_witaddress are not accepted until the script is added with addwitnessaddress first for i in uncompressed_spendable_address + uncompressed_solvable_address + premature_witaddress: # This will raise an exception assert_raises_rpc_error(-4, "Public key or redeemscript not known to wallet, or the key is uncompressed", self.nodes[0].addwitnessaddress, i) # after importaddress it should pass addwitnessaddress v = self.nodes[0].getaddressinfo(compressed_solvable_address[1]) self.nodes[0].importaddress(v['hex'],"",False,True) for i in compressed_spendable_address + compressed_solvable_address + premature_witaddress: witaddress = self.nodes[0].addwitnessaddress(i) assert_equal(witaddress, self.nodes[0].addwitnessaddress(witaddress)) spendable_txid.append(self.mine_and_test_listunspent(spendable_after_addwitnessaddress + spendable_anytime, 2)) solvable_txid.append(self.mine_and_test_listunspent(solvable_after_addwitnessaddress + solvable_anytime, 1)) self.mine_and_test_listunspent(unseen_anytime, 0) # Check that createrawtransaction/decoderawtransaction with non-v0 Bech32 works v1_addr = program_to_witness(1, [3,5]) v1_tx = self.nodes[0].createrawtransaction([getutxo(spendable_txid[0])],{v1_addr: 1}) v1_decoded = self.nodes[1].decoderawtransaction(v1_tx) assert_equal(v1_decoded['vout'][0]['scriptPubKey']['addresses'][0], v1_addr) assert_equal(v1_decoded['vout'][0]['scriptPubKey']['hex'], "51020305") # Check that spendable outputs are really spendable self.create_and_mine_tx_from_txids(spendable_txid) # import all the private keys so solvable addresses become spendable self.nodes[0].importprivkey("cPiM8Ub4heR9NBYmgVzJQiUH1if44GSBGiqaeJySuL2BKxubvgwb") self.nodes[0].importprivkey("cPpAdHaD6VoYbW78kveN2bsvb45Q7G5PhaPApVUGwvF8VQ9brD97") self.nodes[0].importprivkey("91zqCU5B9sdWxzMt1ca3VzbtVm2YM6Hi5Rxn4UDtxEaN9C9nzXV") self.nodes[0].importprivkey("cPQFjcVRpAUBG8BA9hzr2yEzHwKoMgLkJZBBtK9vJnvGJgMjzTbd") self.nodes[0].importprivkey("cQGtcm34xiLjB1v7bkRa4V3aAc9tS2UTuBZ1UnZGeSeNy627fN66") self.nodes[0].importprivkey("cTW5mR5M45vHxXkeChZdtSPozrFwFgmEvTNnanCW6wrqwaCZ1X7K") self.create_and_mine_tx_from_txids(solvable_txid) # Test that importing native P2WPKH/P2WSH scripts works for use_p2wsh in [False, True]: if use_p2wsh: scriptPubKey = "00203a59f3f56b713fdcf5d1a57357f02c44342cbf306ffe0c4741046837bf90561a" transaction = "01000000000100e1f505000000002200203a59f3f56b713fdcf5d1a57357f02c44342cbf306ffe0c4741046837bf90561a00000000" else: scriptPubKey = "a9142f8c469c2f0084c48e11f998ffbe7efa7549f26d87" transaction = "01000000000100e1f5050000000017a9142f8c469c2f0084c48e11f998ffbe7efa7549f26d8700000000" self.nodes[1].importaddress(scriptPubKey, "", False) rawtxfund = self.nodes[1].fundrawtransaction(transaction)['hex'] rawtxfund = self.nodes[1].signrawtransactionwithwallet(rawtxfund)["hex"] txid = self.nodes[1].sendrawtransaction(rawtxfund) assert_equal(self.nodes[1].gettransaction(txid, True)["txid"], txid) assert_equal(self.nodes[1].listtransactions("*", 1, 0, True)[0]["txid"], txid) # Assert it is properly saved self.stop_node(1) self.start_node(1) assert_equal(self.nodes[1].gettransaction(txid, True)["txid"], txid) assert_equal(self.nodes[1].listtransactions("*", 1, 0, True)[0]["txid"], txid)
def test_standardtx(self): nodes = self.nodes addrA_0 = nodes[0].getnewaddress() # party A addrB_0 = nodes[1].getnewaddress() # party B # Initiate A -> B # A has address (addrB_0) of B amountA = 5.0 amountB = 5.0 pkh0_0 = b58decode(addrA_0)[1:-4] pkh1_0 = b58decode(addrB_0)[1:-4] secretA = os.urandom(32) secretAHash = sha256(secretA) lockTime = int(time.time()) + 10000 # future locktime scriptInitiate = CreateAtomicSwapScript(payTo=pkh1_0, refundTo=pkh0_0, lockTime=lockTime, secretHash=secretAHash) p2sh_initiate = script_to_p2sh_part(scriptInitiate) rawtxInitiate = nodes[0].createrawtransaction([], {p2sh_initiate: amountA}) rawtxInitiate = nodes[0].fundrawtransaction(rawtxInitiate)['hex'] ro = nodes[0].signrawtransactionwithwallet(rawtxInitiate) assert (ro['complete'] == True) rawtxInitiate = ro['hex'] rawtx1refund = createRefundTx(nodes[0], rawtxInitiate, scriptInitiate, lockTime, addrA_0, addrA_0) nodes[0].sendrawtransaction(rawtxInitiate) self.stakeBlocks(1) ro = nodes[0].getblockchaininfo() assert (ro['mediantime'] < lockTime) try: txnidrefund = nodes[0].sendrawtransaction(rawtx1refund) assert (False) except JSONRPCException as e: assert ('non-final' in e.error['message']) # Party A sends B rawtxInitiate/txnid1 and script # auditcontract # Party B extracts the secrethash and verifies the txn: assert (len(scriptInitiate) == 97) extractedSecretAHash = scriptInitiate[7:7 + 32] assert (extractedSecretAHash == secretAHash) tx1 = nodes[1].decoderawtransaction(rawtxInitiate) self.log.info("Verify txn " + tx1['txid']) # TODO # Participate B -> A # needs address from A, amount and secretAHash lockTimeP = int(time.time()) + 10000 # future locktime scriptParticipate = CreateAtomicSwapScript(payTo=pkh0_0, refundTo=pkh1_0, lockTime=lockTimeP, secretHash=secretAHash) p2sh_participate = script_to_p2sh_part(scriptParticipate) rawtx_p = nodes[1].createrawtransaction([], {p2sh_participate: amountB}) rawtx_p = nodes[1].fundrawtransaction(rawtx_p)['hex'] ro = nodes[1].signrawtransactionwithwallet(rawtx_p) assert (ro['complete'] == True) rawtx_p = ro['hex'] rawtxRefundP = createRefundTx(nodes[1], rawtx_p, scriptParticipate, lockTimeP, addrB_0, addrB_0) txnidParticipate = nodes[1].sendrawtransaction(rawtx_p) self.sync_all() self.stakeBlocks(1) assert (txnidParticipate in nodes[0].getblock(nodes[0].getblockhash( nodes[0].getblockcount()))['tx']) ro = nodes[0].getblockchaininfo() assert (ro['mediantime'] < lockTimeP) try: txnidrefund = nodes[1].sendrawtransaction(rawtxRefundP) assert (False) except JSONRPCException as e: assert ('non-final' in e.error['message']) # auditcontract # Party A verifies the participate txn from B # Party A Redeem/Claim from participate txn # Party A spends the funds from the participate txn, and to do so must reveal secretA rawtxclaimA = createClaimTx(nodes[0], rawtx_p, scriptParticipate, secretA, addrA_0, addrA_0) txnidAClaim = nodes[0].sendrawtransaction(rawtxclaimA) # Party B Redeem/Claim from initiate txn # Get secret from txnidAClaim #ro = nodes[1].getrawtransaction(txnidAClaim, True) #print('ro', json.dumps(ro, indent=4, default=jsonDecimal)) rawtxclaimB = createClaimTx(nodes[1], rawtxInitiate, scriptInitiate, secretA, addrB_0, addrB_0) txnidBClaim = nodes[0].sendrawtransaction( rawtxclaimB) # send from staking node to avoid syncing self.stakeBlocks(1) last_block_txns = nodes[0].getblock(nodes[0].getblockhash( nodes[0].getblockcount()))['tx'] assert (txnidAClaim in last_block_txns) assert (txnidBClaim in last_block_txns) ftxB = nodes[1].filtertransactions() assert (ftxB[0]['confirmations'] == 1) assert (ftxB[0]['outputs'][0]['amount'] < 5.0 and ftxB[-1]['outputs'][0]['amount'] > 4.9) assert (isclose(ftxB[1]['outputs'][0]['amount'], -5.0)) # Test Refund expired initiate tx lockTime = int(time.time()) - 100000 # past locktime scriptInitiate2 = CreateAtomicSwapScript(payTo=pkh1_0, refundTo=pkh0_0, lockTime=lockTime, secretHash=secretAHash) p2sh_initiate = script_to_p2sh_part(scriptInitiate2) rawtxInitiate = nodes[0].createrawtransaction([], {p2sh_initiate: 6.0}) rawtxInitiate = nodes[0].fundrawtransaction(rawtxInitiate)['hex'] ro = nodes[0].signrawtransactionwithwallet(rawtxInitiate) assert (ro['complete'] == True) rawtxInitiate = ro['hex'] rawtx2refund = createRefundTx(nodes[0], rawtxInitiate, scriptInitiate2, lockTime, addrA_0, addrA_0) txnid2 = nodes[0].sendrawtransaction(rawtxInitiate) self.stakeBlocks(1) ro = nodes[0].getblockchaininfo() assert (ro['mediantime'] > lockTime) txnidrefund = nodes[0].sendrawtransaction(rawtx2refund) ftxA = nodes[0].filtertransactions() n = getIndexAtProperty(ftxA, 'txid', txnidrefund) assert (n > -1) assert (ftxA[n]['outputs'][0]['amount'] > 5.9 and ftxA[n]['outputs'][0]['amount'] < 6.0)
def colorIdReissuable(script): return b'\xc1' + sha256(script)
def colorIdNonReissuable(utxo): return b'\xc2'+ sha256(utxo)
def witness_script_test(self): # Now test signing transaction to P2SH-P2WSH addresses without wallet # Create a new P2SH-P2WSH 1-of-1 multisig address: embedded_address = self.nodes[1].getaddressinfo( self.nodes[1].getnewaddress()) embedded_privkey = self.nodes[1].dumpprivkey( embedded_address["address"]) p2sh_p2wsh_address = self.nodes[1].addmultisigaddress( 1, [embedded_address["pubkey"]], "", "p2sh-segwit") # send transaction to P2SH-P2WSH 1-of-1 multisig address self.nodes[0].generate(101) self.nodes[0].sendtoaddress(p2sh_p2wsh_address["address"], 49.999) self.nodes[0].generate(1) self.sync_all() # Find the UTXO for the transaction node[1] should have received, check witnessScript matches unspent_output = self.nodes[1].listunspent( 0, 999999, [p2sh_p2wsh_address["address"]])[0] assert_equal(unspent_output["witnessScript"], p2sh_p2wsh_address["redeemScript"]) p2sh_redeemScript = CScript([ OP_0, sha256(hex_str_to_bytes(p2sh_p2wsh_address["redeemScript"])) ]) assert_equal(unspent_output["redeemScript"], p2sh_redeemScript.hex()) # Now create and sign a transaction spending that output on node[0], which doesn't know the scripts or keys spending_tx = self.nodes[0].createrawtransaction( [unspent_output], {self.nodes[1].getnewaddress(): Decimal("49.998")}) spending_tx_signed = self.nodes[0].signrawtransactionwithkey( spending_tx, [embedded_privkey], [unspent_output]) # Check the signing completed successfully assert 'complete' in spending_tx_signed assert_equal(spending_tx_signed['complete'], True) self.log.info('Try with a P2PKH script as the witnessScript') embedded_addr_info = self.nodes[1].getaddressinfo( self.nodes[1].getnewaddress('', 'legacy')) embedded_privkey = self.nodes[1].dumpprivkey( embedded_addr_info['address']) witness_script = embedded_addr_info['scriptPubKey'] redeem_script = CScript([OP_0, sha256(check_script(witness_script))]).hex() addr = script_to_p2sh(redeem_script) script_pub_key = self.nodes[1].validateaddress(addr)['scriptPubKey'] # Fund that address txid = self.nodes[0].sendtoaddress(addr, 10) vout = find_vout_for_address(self.nodes[0], txid, addr) self.nodes[0].generate(1) # Now create and sign a transaction spending that output on node[0], which doesn't know the scripts or keys spending_tx = self.nodes[0].createrawtransaction( [{ 'txid': txid, 'vout': vout }], {self.nodes[1].getnewaddress(): Decimal("9.999")}) spending_tx_signed = self.nodes[0].signrawtransactionwithkey( spending_tx, [embedded_privkey], [{ 'txid': txid, 'vout': vout, 'scriptPubKey': script_pub_key, 'redeemScript': redeem_script, 'witnessScript': witness_script, 'amount': 10 }]) # Check the signing completed successfully assert 'complete' in spending_tx_signed assert_equal(spending_tx_signed['complete'], True) self.nodes[0].sendrawtransaction(spending_tx_signed['hex']) self.log.info('Try with a P2PK script as the witnessScript') embedded_addr_info = self.nodes[1].getaddressinfo( self.nodes[1].getnewaddress('', 'legacy')) embedded_privkey = self.nodes[1].dumpprivkey( embedded_addr_info['address']) witness_script = CScript( [hex_str_to_bytes(embedded_addr_info['pubkey']), OP_CHECKSIG]).hex() redeem_script = CScript([OP_0, sha256(check_script(witness_script))]).hex() addr = script_to_p2sh(redeem_script) script_pub_key = self.nodes[1].validateaddress(addr)['scriptPubKey'] # Fund that address txid = self.nodes[0].sendtoaddress(addr, 10) vout = find_vout_for_address(self.nodes[0], txid, addr) self.nodes[0].generate(1) # Now create and sign a transaction spending that output on node[0], which doesn't know the scripts or keys spending_tx = self.nodes[0].createrawtransaction( [{ 'txid': txid, 'vout': vout }], {self.nodes[1].getnewaddress(): Decimal("9.999")}) spending_tx_signed = self.nodes[0].signrawtransactionwithkey( spending_tx, [embedded_privkey], [{ 'txid': txid, 'vout': vout, 'scriptPubKey': script_pub_key, 'redeemScript': redeem_script, 'witnessScript': witness_script, 'amount': 10 }]) # Check the signing completed successfully assert 'complete' in spending_tx_signed assert_equal(spending_tx_signed['complete'], True) self.nodes[0].sendrawtransaction(spending_tx_signed['hex']) script_pub_key = self.nodes[1].validateaddress(addr)['scriptPubKey'] # Fund that address txid = self.nodes[0].sendtoaddress(addr, 10) vout = find_vout_for_address(self.nodes[0], txid, addr) self.nodes[0].generate(1) # Now create and sign a transaction spending that output on node[0], which doesn't know the scripts or keys spending_tx = self.nodes[0].createrawtransaction( [{ 'txid': txid, 'vout': vout }], {self.nodes[1].getnewaddress(): Decimal("9.999")}) spending_tx_signed = self.nodes[0].signrawtransactionwithkey( spending_tx, [embedded_privkey], [{ 'txid': txid, 'vout': vout, 'scriptPubKey': script_pub_key, 'redeemScript': redeem_script, 'witnessScript': witness_script, 'amount': 10 }]) # Check the signing completed successfully assert 'complete' in spending_tx_signed assert_equal(spending_tx_signed['complete'], True) self.nodes[0].sendrawtransaction(spending_tx_signed['hex'])
def run_test(self): node = self.nodes[0] self.log.info('Start with empty mempool and 101 blocks') # The last 100 coinbase transactions are premature blockhash = self.generate(node, 101)[0] txid = node.getblock(blockhash=blockhash, verbosity=2)["tx"][0]["txid"] assert_equal(node.getmempoolinfo()['size'], 0) self.log.info("Submit parent with multiple script branches to mempool") hashlock = hash160(b'Preimage') witness_script = CScript([ OP_IF, OP_HASH160, hashlock, OP_EQUAL, OP_ELSE, OP_TRUE, OP_ENDIF ]) witness_program = sha256(witness_script) script_pubkey = CScript([OP_0, witness_program]) parent = CTransaction() parent.vin.append(CTxIn(COutPoint(int(txid, 16), 0), b"")) parent.vout.append(CTxOut(int(9.99998 * COIN), script_pubkey)) parent.rehash() privkeys = [node.get_deterministic_priv_key().key] raw_parent = node.signrawtransactionwithkey( hexstring=parent.serialize().hex(), privkeys=privkeys)['hex'] parent_txid = node.sendrawtransaction(hexstring=raw_parent, maxfeerate=0) self.generate(node, 1) peer_wtxid_relay = node.add_p2p_connection(P2PTxInvStore()) # Create a new transaction with witness solving first branch child_witness_script = CScript([OP_TRUE]) child_witness_program = sha256(child_witness_script) child_script_pubkey = CScript([OP_0, child_witness_program]) child_one = CTransaction() child_one.vin.append(CTxIn(COutPoint(int(parent_txid, 16), 0), b"")) child_one.vout.append(CTxOut(int(9.99996 * COIN), child_script_pubkey)) child_one.wit.vtxinwit.append(CTxInWitness()) child_one.wit.vtxinwit[0].scriptWitness.stack = [ b'Preimage', b'\x01', witness_script ] child_one_wtxid = child_one.getwtxid() child_one_txid = child_one.rehash() # Create another identical transaction with witness solving second branch child_two = deepcopy(child_one) child_two.wit.vtxinwit[0].scriptWitness.stack = [b'', witness_script] child_two_wtxid = child_two.getwtxid() child_two_txid = child_two.rehash() assert_equal(child_one_txid, child_two_txid) assert child_one_wtxid != child_two_wtxid self.log.info("Submit child_one to the mempool") txid_submitted = node.sendrawtransaction(child_one.serialize().hex()) assert_equal( node.getmempoolentry(txid_submitted)['wtxid'], child_one_wtxid) peer_wtxid_relay.wait_for_broadcast([child_one_wtxid]) assert_equal(node.getmempoolinfo()["unbroadcastcount"], 0) # testmempoolaccept reports the "already in mempool" error assert_equal(node.testmempoolaccept([child_one.serialize().hex()]), [{ "txid": child_one_txid, "wtxid": child_one_wtxid, "allowed": False, "reject-reason": "txn-already-in-mempool" }]) assert_equal( node.testmempoolaccept([child_two.serialize().hex()])[0], { "txid": child_two_txid, "wtxid": child_two_wtxid, "allowed": False, "reject-reason": "txn-same-nonwitness-data-in-mempool" }) # sendrawtransaction will not throw but quits early when the exact same transaction is already in mempool node.sendrawtransaction(child_one.serialize().hex()) self.log.info("Connect another peer that hasn't seen child_one before") peer_wtxid_relay_2 = node.add_p2p_connection(P2PTxInvStore()) self.log.info("Submit child_two to the mempool") # sendrawtransaction will not throw but quits early when a transaction with the same non-witness data is already in mempool node.sendrawtransaction(child_two.serialize().hex()) # The node should rebroadcast the transaction using the wtxid of the correct transaction # (child_one, which is in its mempool). peer_wtxid_relay_2.wait_for_broadcast([child_one_wtxid]) assert_equal(node.getmempoolinfo()["unbroadcastcount"], 0)
def test_cttx(self): nodes = self.nodes # Test confidential transactions addrA_sx = nodes[0].getnewstealthaddress() # party A addrB_sx = nodes[1].getnewstealthaddress() # party B outputs = [ { 'address': addrA_sx, 'type': 'blind', 'amount': 100, }, { 'address': addrB_sx, 'type': 'blind', 'amount': 100, }, ] ro = nodes[0].createrawparttransaction([], outputs) ro = nodes[0].fundrawtransactionfrom('standard', ro['hex'], {}, ro['amounts']) rawtx = ro['hex'] ro = nodes[0].signrawtransactionwithwallet(rawtx) assert (ro['complete'] == True) ro = nodes[0].sendrawtransaction(ro['hex']) txnid = ro self.stakeBlocks(1) ro = nodes[0].getwalletinfo() assert (isclose(ro['blind_balance'], 100.0)) ro = nodes[0].filtertransactions() n = getIndexAtProperty(ro, 'txid', txnid) assert (n > -1) assert (isclose(ro[n]['amount'], -100.00203200)) ro = nodes[1].getwalletinfo() assert (isclose(ro['blind_balance'], 100.0)) ro = nodes[1].filtertransactions() n = getIndexAtProperty(ro, 'txid', txnid) assert (n > -1) assert (isclose(ro[n]['amount'], 100.0)) # Initiate A -> B # A has address (addrB_sx) of B amountA = 7.0 amountB = 7.0 secretA = os.urandom(32) secretAHash = sha256(secretA) lockTime = int(time.time()) + 10000 # future locktime destA = nodes[0].derivefromstealthaddress(addrA_sx) pkh0_0 = b58decode(destA['address'])[1:-4] ro = nodes[0].derivefromstealthaddress(addrA_sx, destA['ephemeral_pubkey']) privKeyA = ro['privatekey'] pubKeyA = ro['pubkey'] destB = nodes[0].derivefromstealthaddress(addrB_sx) pkh1_0 = b58decode(destB['address'])[1:-4] ro = nodes[1].derivefromstealthaddress(addrB_sx, destB['ephemeral_pubkey']) privKeyB = ro['privatekey'] pubKeyB = ro['pubkey'] scriptInitiate = CreateAtomicSwapScript(payTo=pkh1_0, refundTo=pkh0_0, lockTime=lockTime, secretHash=secretAHash) p2sh_initiate = script_to_p2sh_part(scriptInitiate) outputs = [ { 'address': p2sh_initiate, 'pubkey': destB['pubkey'], 'type': 'blind', 'amount': amountA, }, ] ro = nodes[0].createrawparttransaction([], outputs) ro = nodes[0].fundrawtransactionfrom('blind', ro['hex'], {}, ro['amounts']) output_amounts_i = ro['output_amounts'] ro = nodes[0].signrawtransactionwithwallet(ro['hex']) assert (ro['complete'] == True) rawtx_i = ro['hex'] rawtx_i_refund = createRefundTxCT(nodes[0], rawtx_i, output_amounts_i, scriptInitiate, lockTime, privKeyA, pubKeyA, addrA_sx) ro = nodes[0].testmempoolaccept([ rawtx_i_refund, ]) assert ('64: non-final' in ro[0]['reject-reason']) txnid1 = nodes[0].sendrawtransaction(rawtx_i) self.stakeBlocks(1) # Party A sends B rawtx_i/txnid1, script and output_amounts_i # auditcontract # Party B extracts the secrethash and verifies the txn: ro = nodes[1].decoderawtransaction(rawtx_i) n = getOutputByAddr(ro, p2sh_initiate) valueCommitment = ro['vout'][n]['valueCommitment'] amount = output_amounts_i[str(n)]['value'] blind = output_amounts_i[str(n)]['blind'] assert (nodes[1].verifycommitment(valueCommitment, blind, amount)['result'] == True) # Participate B -> A # needs address and publickey from A, amount and secretAHash lockTimeP = int(time.time()) + 10000 # future locktime scriptParticipate = CreateAtomicSwapScript(payTo=pkh0_0, refundTo=pkh1_0, lockTime=lockTimeP, secretHash=secretAHash) p2sh_participate = script_to_p2sh_part(scriptParticipate) outputs = [ { 'address': p2sh_participate, 'pubkey': destA['pubkey'], 'type': 'blind', 'amount': amountB, }, ] ro = nodes[1].createrawparttransaction([], outputs) ro = nodes[1].fundrawtransactionfrom('blind', ro['hex'], {}, ro['amounts']) output_amounts_p = ro['output_amounts'] ro = nodes[1].signrawtransactionwithwallet(ro['hex']) rawtx_p = ro['hex'] rawtx_p_refund = createRefundTxCT(nodes[1], rawtx_p, output_amounts_p, scriptParticipate, lockTime, privKeyB, pubKeyB, addrB_sx) ro = nodes[1].testmempoolaccept([ rawtx_p_refund, ]) assert ('64: non-final' in ro[0]['reject-reason']) txnid_p = nodes[0].sendrawtransaction(rawtx_p) self.stakeBlocks(1) assert (txnid_p in nodes[0].getblock(nodes[0].getblockhash( nodes[0].getblockcount()))['tx']) # B sends output_amounts to A # Party A Redeem/Claim from participate txn # Party A spends the funds from the participate txn, and to do so must reveal secretA rawtxclaimA = createClaimTxCT(nodes[0], rawtx_p, output_amounts_p, scriptParticipate, secretA, privKeyA, pubKeyA, addrA_sx) txnidAClaim = nodes[0].sendrawtransaction(rawtxclaimA) # Party B claims from initiate txn # Get secret from txnidAClaim #ro = nodes[1].getrawtransaction(txnidAClaim, True) #print('ro', json.dumps(ro, indent=4, default=jsonDecimal)) rawtxclaimB = createClaimTxCT(nodes[1], rawtx_i, output_amounts_i, scriptInitiate, secretA, privKeyB, pubKeyB, addrB_sx) txnidBClaim = nodes[0].sendrawtransaction(rawtxclaimB) nodes[0].getmempoolentry(txnidAClaim) nodes[0].getmempoolentry(txnidBClaim) # Test Refund expired initiate tx secretA = os.urandom(32) secretAHash = sha256(secretA) lockTime = int(time.time()) - 100000 # past locktime amountA = 7.1 scriptInitiate = CreateAtomicSwapScript(payTo=pkh1_0, refundTo=pkh0_0, lockTime=lockTime, secretHash=secretAHash) p2sh_initiate = script_to_p2sh_part(scriptInitiate) outputs = [ { 'address': p2sh_initiate, 'pubkey': destB['pubkey'], 'type': 'blind', 'amount': amountA, }, ] ro = nodes[0].createrawparttransaction([], outputs) ro = nodes[0].fundrawtransactionfrom('blind', ro['hex'], {}, ro['amounts']) r2 = nodes[0].verifyrawtransaction(ro['hex']) assert (r2['complete'] == False) output_amounts_i = ro['output_amounts'] ro = nodes[0].signrawtransactionwithwallet(ro['hex']) assert (ro['complete'] == True) rawtx_i = ro['hex'] r2 = nodes[0].verifyrawtransaction(rawtx_i) assert (r2['complete'] == True) rawtx_i_refund = createRefundTxCT(nodes[0], rawtx_i, output_amounts_i, scriptInitiate, lockTime, privKeyA, pubKeyA, addrA_sx) ro = nodes[0].testmempoolaccept([ rawtx_i_refund, ]) assert ('missing-inputs' in ro[0]['reject-reason']) txnid1 = nodes[0].sendrawtransaction(rawtx_i) ro = nodes[0].getwalletinfo() assert (ro['unconfirmed_blind'] > 6.0 and ro['unconfirmed_blind'] < 7.0) txnidRefund = nodes[0].sendrawtransaction(rawtx_i_refund) nodes[0].getmempoolentry(txnidRefund) ro = nodes[0].getwalletinfo() assert (ro['unconfirmed_blind'] > 14.0 and ro['unconfirmed_blind'] < 14.1)
def p2sh_address_to_script(self,v): bare = CScript(hex_str_to_bytes(v['hex'])) p2sh = CScript(hex_str_to_bytes(v['scriptPubKey'])) p2wsh = CScript([OP_0, sha256(bare)]) p2sh_p2wsh = CScript([OP_HASH160, hash160(p2wsh), OP_EQUAL]) return([bare, p2sh, p2wsh, p2sh_p2wsh])
def run_test(self): nodes = self.nodes ro = nodes[0].extkeyimportmaster( 'abandon baby cabbage dad eager fabric gadget habit ice kangaroo lab absorb' ) assert (ro['account_id'] == 'aaaZf2qnNr5T7PWRmqgmusuu5ACnBcX2ev') assert (nodes[0].getwalletinfo()['total_balance'] == 100000) txnHashes = [] nodes[1].extkeyimportmaster( 'drip fog service village program equip minute dentist series hawk crop sphere olympic lazy garbage segment fox library good alley steak jazz force inmate' ) sxAddrTo1_1 = nodes[1].getnewstealthaddress('lblsx11') assert ( sxAddrTo1_1 == 'TetbYTGv5LiqyFiUD3a5HHbpSinQ9KiRYDGAMvRzPfz4RnHMbKGAwDr1fjLGJ5Eqg1XDwpeGyqWMiwdK3qM3zKWjzHNpaatdoHVzzA' ) nodes[2].extkeyimportmaster(nodes[2].mnemonic('new')['master']) sxAddrTo0_1 = nodes[0].getnewstealthaddress('lblsx01') txnHashes.append(nodes[0].sendtypeto('part', 'anon', [ { 'address': sxAddrTo1_1, 'amount': 1, 'narr': 'node0 -> node1 p->a' }, ])) txnHashes.append(nodes[0].sendtypeto('part', 'blind', [ { 'address': sxAddrTo0_1, 'amount': 1000, 'narr': 'node0 -> node0 p->b' }, ])) txnHashes.append(nodes[0].sendtypeto('blind', 'anon', [ { 'address': sxAddrTo1_1, 'amount': 100, 'narr': 'node0 -> node1 b->a 1' }, ])) txnHashes.append(nodes[0].sendtypeto('blind', 'anon', [ { 'address': sxAddrTo1_1, 'amount': 100, 'narr': 'node0 -> node1 b->a 2' }, ])) txnHashes.append(nodes[0].sendtypeto('blind', 'anon', [ { 'address': sxAddrTo1_1, 'amount': 100, 'narr': 'node0 -> node1 b->a 3' }, ])) txnHashes.append(nodes[0].sendtypeto('blind', 'anon', [ { 'address': sxAddrTo1_1, 'amount': 10, 'narr': 'node0 -> node1 b->a 4' }, ])) for k in range(5): txnHashes.append(nodes[0].sendtypeto('part', 'anon', [ { 'address': sxAddrTo1_1, 'amount': 10, 'narr': 'node0 -> node1 p->a' }, ])) for k in range(10): txnHashes.append(nodes[0].sendtypeto('blind', 'anon', [ { 'address': sxAddrTo1_1, 'amount': 10, 'narr': 'node0 -> node1 b->a' }, ])) for h in txnHashes: assert (self.wait_for_mempool(nodes[1], h)) assert ('node0 -> node1 b->a 4' in self.dumpj(nodes[1].listtransactions('*', 100))) assert ('node0 -> node1 b->a 4' in self.dumpj(nodes[0].listtransactions('*', 100))) self.stakeBlocks(2) block1_hash = nodes[1].getblockhash(1) ro = nodes[1].getblock(block1_hash) for txnHash in txnHashes: assert (txnHash in ro['tx']) txnHash = nodes[1].sendtypeto('anon', 'anon', [ { 'address': sxAddrTo0_1, 'amount': 1, 'narr': 'node1 -> node0 a->a' }, ]) txnHashes = [ txnHash, ] assert (self.wait_for_mempool(nodes[0], txnHash)) self.stakeBlocks(1) ro = nodes[1].getblock(nodes[1].getblockhash(3)) for txnHash in txnHashes: assert (txnHash in ro['tx']) assert (nodes[1].anonoutput()['lastindex'] == 28) txnHashes.clear() txnHashes.append(nodes[1].sendtypeto('anon', 'anon', [ { 'address': sxAddrTo0_1, 'amount': 101, 'narr': 'node1 -> node0 a->a' }, ], '', '', 5, 1)) txnHashes.append(nodes[1].sendtypeto('anon', 'anon', [ { 'address': sxAddrTo0_1, 'amount': 0.1 }, ], '', '', 5, 2)) assert (nodes[1].getwalletinfo()['anon_balance'] > 10) outputs = [ { 'address': sxAddrTo0_1, 'amount': 10, 'subfee': True }, ] ro = nodes[1].sendtypeto('anon', 'part', outputs, 'comment_to', 'comment_from', 4, 32, True) assert (ro['bytes'] > 0) txnHashes.append(nodes[1].sendtypeto('anon', 'part', outputs)) for txhash in txnHashes: assert (self.wait_for_mempool(nodes[0], txhash)) self.log.info('Test filtertransactions with type filter') ro = nodes[1].filtertransactions({'type': 'anon', 'count': 20}) assert (len(ro) > 2) for t in ro: foundA = False for o in t['outputs']: if 'type' in o and o['type'] == 'anon': foundA = True break assert ((foundA is True) or (t['type_in'] == 'anon')) self.log.info('Test unspent with address filter') unspent_filtered = nodes[1].listunspentanon(1, 9999, [sxAddrTo1_1]) assert (unspent_filtered[0]['label'] == 'lblsx11') self.log.info('Test permanent lockunspent') unspent = nodes[1].listunspentanon() assert (nodes[1].lockunspent(False, [unspent[0]], True) == True) assert (nodes[1].lockunspent(False, [unspent[1]], True) == True) assert (len(nodes[1].listlockunspent()) == 2) # Restart node self.sync_all() self.stop_node(1) self.start_node(1, self.extra_args[1] + [ '-wallet=default_wallet', ]) self.connect_nodes_bi(0, 1) assert (len(nodes[1].listlockunspent()) == 2) assert (len(nodes[1].listunspentanon()) < len(unspent)) assert (nodes[1].lockunspent(True, [unspent[0]]) == True) assert_raises_rpc_error(-8, 'Invalid parameter, expected locked output', nodes[1].lockunspent, True, [unspent[0]]) assert (len(nodes[1].listunspentanon()) == len(unspent) - 1) assert (nodes[1].lockunspent(True) == True) assert (len(nodes[1].listunspentanon()) == len(unspent)) assert (nodes[1].lockunspent(True) == True) ro = nodes[2].getblockstats(nodes[2].getblockchaininfo()['blocks']) assert (ro['height'] == 3) self.log.info('Test recover from mnemonic') # Txns currently in the mempool will be reprocessed in the next block self.stakeBlocks(1) wi_1 = nodes[1].getwalletinfo() nodes[1].createwallet('test_import') w1_2 = nodes[1].get_wallet_rpc('test_import') w1_2.extkeyimportmaster( 'drip fog service village program equip minute dentist series hawk crop sphere olympic lazy garbage segment fox library good alley steak jazz force inmate' ) w1_2.getnewstealthaddress('lblsx11') w1_2.rescanblockchain(0) wi_1_2 = w1_2.getwalletinfo() assert (wi_1_2['anon_balance'] == wi_1['anon_balance']) nodes[1].createwallet('test_import_locked') w1_3 = nodes[1].get_wallet_rpc('test_import_locked') w1_3.encryptwallet('test') w1_3.walletpassphrase('test', 30) # Skip initial rescan by passing -1 as scan_chain_from w1_3.extkeyimportmaster( 'drip fog service village program equip minute dentist series hawk crop sphere olympic lazy garbage segment fox library good alley steak jazz force inmate', '', False, 'imported key', 'imported acc', -1) w1_3.getnewstealthaddress('lblsx11') w1_3.walletsettings('other', {'onlyinstance': False}) w1_3.walletlock() assert (w1_3.getwalletinfo()['encryptionstatus'] == 'Locked') w1_3.rescanblockchain(0) w1_3.walletpassphrase('test', 30) wi_1_3 = w1_3.getwalletinfo() assert (wi_1_3['anon_balance'] == wi_1['anon_balance']) self.log.info('Test sendtypeto coincontrol') w1_inputs = w1_2.listunspentanon() assert (len(w1_inputs) > 1) use_input = w1_inputs[random.randint(0, len(w1_inputs) - 1)] coincontrol = { 'inputs': [{ 'tx': use_input['txid'], 'n': use_input['vout'] }] } txid = w1_2.sendtypeto('anon', 'anon', [ { 'address': sxAddrTo0_1, 'amount': 0.01 }, ], '', '', 7, 1, False, coincontrol) w1_inputs_after = w1_2.listunspentanon() for txin in w1_inputs_after: if txin['txid'] == use_input['txid'] and txin['vout'] == use_input[ 'vout']: raise ValueError('Output should be spent') assert (self.wait_for_mempool(nodes[1], txid)) raw_tx = w1_2.getrawtransaction(txid, True) possible_inputs = raw_tx['vin'][0]['ring_row_0'].split(', ') possible_inputs_txids = [] for pi in possible_inputs: anonoutput = w1_2.anonoutput(pi) possible_inputs_txids.append(anonoutput['txnhash'] + '.' + str(anonoutput['n'])) assert (use_input['txid'] + '.' + str(use_input['vout']) in possible_inputs_txids) num_tries = 20 for i in range(num_tries): if nodes[0].getbalances()['mine']['anon_immature'] == 0.0: break self.stakeBlocks(1) if i >= num_tries - 1: raise ValueError('anon balance immature') assert (nodes[0].getbalances()['mine']['anon_trusted'] > 100.0) self.log.info('Test crafting anon transactions.') sxAddr2_1 = nodes[2].getnewstealthaddress('lblsx01') ephem = nodes[0].derivefromstealthaddress(sxAddr2_1) blind = bytes(random.getrandbits(8) for i in range(32)).hex() outputs = [ { 'address': sxAddr2_1, 'type': 'anon', 'amount': 10.0, 'blindingfactor': blind, 'ephemeral_key': ephem['ephemeral_privatekey'], }, ] tx = nodes[0].createrawparttransaction([], outputs) options = {'sign_tx': True} tx_signed = nodes[0].fundrawtransactionfrom('anon', tx['hex'], {}, tx['amounts'], options) txid = nodes[0].sendrawtransaction(tx_signed['hex']) self.stakeBlocks(1) sx_privkey = nodes[2].dumpprivkey(sxAddr2_1) assert ('scan_secret' in sx_privkey) assert ('spend_secret' in sx_privkey) sx_pubkey = nodes[2].getaddressinfo(sxAddr2_1) assert ('scan_public_key' in sx_pubkey) assert ('spend_public_key' in sx_pubkey) stealth_key = nodes[2].derivefromstealthaddress( sxAddr2_1, ephem['ephemeral_pubkey']) prevtx = nodes[2].decoderawtransaction(tx_signed['hex']) found_output = -1 for vout in prevtx['vout']: if vout['type'] != 'anon': continue try: ro = nodes[2].verifycommitment(vout['valueCommitment'], blind, 10.0) assert (ro['result'] is True) ro = nodes[2].rewindrangeproof(vout['rangeproof'], vout['valueCommitment'], stealth_key['privatekey'], ephem['ephemeral_pubkey']) assert (ro['amount'] == 10.0) found_output = vout['n'] except Exception as e: print(e) assert (found_output > -1) key_bytes = base58_to_byte(stealth_key['privatekey'])[0][0:32] epk = ECPubKey() epk.set(bytes.fromhex(ephem['ephemeral_pubkey'])) self.log.info('Test rewindrangeproof with final nonce') # ECDH P = SECP256K1.affine(epk.p) M = SECP256K1.affine( SECP256K1.mul([((P[0], P[1], P[2]), int.from_bytes(key_bytes, 'big'))])) eM = bytes([0x02 + (M[1] & 1)]) + M[0].to_bytes(32, 'big') hM = sha256(eM) hhM = sha256(hM) # Reverse, SetHex is LE hhM = hhM[::-1] vout = prevtx['vout'][found_output] ro = nodes[2].rewindrangeproof(vout['rangeproof'], vout['valueCommitment'], hhM.hex()) assert (ro['amount'] == 10.0) self.log.info( 'Test signing for unowned anon input' ) # Input not in wallet, must be in chain for pubkey index prev_tx_signed = nodes[0].decoderawtransaction(tx_signed['hex']) prev_commitment = prev_tx_signed['vout'][found_output][ 'valueCommitment'] prev_public_key = prev_tx_signed['vout'][found_output]['pubkey'] assert (prev_public_key == stealth_key['pubkey']) outputs = [ { 'address': sxAddr2_1, 'type': 'anon', 'amount': 10.0, }, ] tx = nodes[0].createrawparttransaction([], outputs) options = { 'subtractFeeFromOutputs': [ 0, ], 'inputs': [{ 'tx': txid, 'n': found_output, 'type': 'anon', 'value': 10.0, 'commitment': prev_commitment, 'pubkey': prev_public_key, 'privkey': stealth_key['privatekey'], 'blind': blind, }], 'feeRate': 0.001, 'sign_tx': True, } input_amounts = {} tx_signed = nodes[0].fundrawtransactionfrom('anon', tx['hex'], input_amounts, tx['amounts'], options) num_tries = 20 for i in range(num_tries): try: txid = nodes[0].sendrawtransaction(tx_signed['hex']) break except Exception: self.stakeBlocks(1) if i >= num_tries - 1: raise ValueError('Can\'t submit txn') assert (self.wait_for_mempool(nodes[2], txid)) self.stakeBlocks(1) w2b = nodes[2].getbalances() assert (w2b['mine']['anon_immature'] < 10 and w2b['mine']['anon_immature'] > 9)
def colorIdNFT(utxo): return b'\xc3'+ sha256(utxo)
else: [p2wpkh, p2sh_p2wpkh, p2pk, p2pkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh] = self.p2pkh_address_to_script(v) # normal P2PKH and P2PK with uncompressed keys should always be seen solvable_anytime.extend([p2pkh, p2pk]) # P2SH_P2PK, P2SH_P2PKH with uncompressed keys are seen after direct importaddress solvable_after_importaddress.extend([p2sh_p2pk, p2sh_p2pkh]) # Witness output types with uncompressed keys are never seen unseen_anytime.extend([p2wpkh, p2sh_p2wpkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh]) op1 = CScript([OP_1]) op0 = CScript([OP_0]) # 2N7MGY19ti4KDMSzRfPAssP6Pxyuxoi6jLe is the P2SH(P2PKH) version of mjoE3sSrb8ByYEvgnC3Aox86u1CHnfJA4V unsolvable_address = ["mjoE3sSrb8ByYEvgnC3Aox86u1CHnfJA4V", "2N7MGY19ti4KDMSzRfPAssP6Pxyuxoi6jLe", script_to_p2sh(op1), script_to_p2sh(op0)] unsolvable_address_key = hex_str_to_bytes("02341AEC7587A51CDE5279E0630A531AEA2615A9F80B17E8D9376327BAEAA59E3D") unsolvablep2pkh = CScript([OP_DUP, OP_HASH160, hash160(unsolvable_address_key), OP_EQUALVERIFY, OP_CHECKSIG]) unsolvablep2wshp2pkh = CScript([OP_0, sha256(unsolvablep2pkh)]) p2shop0 = CScript([OP_HASH160, hash160(op0), OP_EQUAL]) p2wshop1 = CScript([OP_0, sha256(op1)]) unsolvable_after_importaddress.append(unsolvablep2pkh) unsolvable_after_importaddress.append(unsolvablep2wshp2pkh) unsolvable_after_importaddress.append(op1) # OP_1 will be imported as script unsolvable_after_importaddress.append(p2wshop1) unseen_anytime.append(op0) # OP_0 will be imported as P2SH address with no script provided unsolvable_after_importaddress.append(p2shop0) spendable_txid = [] solvable_txid = [] spendable_txid.append(self.mine_and_test_listunspent(spendable_anytime, 2)) solvable_txid.append(self.mine_and_test_listunspent(solvable_anytime, 1)) self.mine_and_test_listunspent(spendable_after_importaddress + solvable_after_importaddress + unseen_anytime + unsolvable_after_importaddress, 0)
def run_test (self): self.log.info("Mining blocks...") self.nodes[0].generate(1) self.nodes[1].generate(1) timestamp = self.nodes[1].getblock(self.nodes[1].getbestblockhash())['mediantime'] node0_address1 = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) #Check only one address assert_equal(node0_address1['ismine'], True) #Node 1 sync test assert_equal(self.nodes[1].getblockcount(),1) #Address Test - before import address_info = self.nodes[1].getaddressinfo(node0_address1['address']) assert_equal(address_info['iswatchonly'], False) assert_equal(address_info['ismine'], False) # RPC importmulti ----------------------------------------------- # Bitcoin Address (implicit non-internal) self.log.info("Should import an address") address = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) result = self.nodes[1].importmulti([{ "scriptPubKey": { "address": address['address'] }, "timestamp": "now", }]) assert_equal(result[0]['success'], True) address_assert = self.nodes[1].getaddressinfo(address['address']) assert_equal(address_assert['iswatchonly'], True) assert_equal(address_assert['ismine'], False) assert_equal(address_assert['timestamp'], timestamp) assert_equal(address_assert['ischange'], False) watchonly_address = address['address'] watchonly_timestamp = timestamp self.log.info("Should not import an invalid address") result = self.nodes[1].importmulti([{ "scriptPubKey": { "address": "not valid address", }, "timestamp": "now", }]) assert_equal(result[0]['success'], False) assert_equal(result[0]['error']['code'], -5) assert_equal(result[0]['error']['message'], 'Invalid address') # ScriptPubKey + internal self.log.info("Should import a scriptPubKey with internal flag") address = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) result = self.nodes[1].importmulti([{ "scriptPubKey": address['scriptPubKey'], "timestamp": "now", "internal": True }]) assert_equal(result[0]['success'], True) address_assert = self.nodes[1].getaddressinfo(address['address']) assert_equal(address_assert['iswatchonly'], True) assert_equal(address_assert['ismine'], False) assert_equal(address_assert['timestamp'], timestamp) assert_equal(address_assert['ischange'], True) # ScriptPubKey + internal + label self.log.info("Should not allow a label to be specified when internal is true") address = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) result = self.nodes[1].importmulti([{ "scriptPubKey": address['scriptPubKey'], "timestamp": "now", "internal": True, "label": "Example label" }]) assert_equal(result[0]['success'], False) assert_equal(result[0]['error']['code'], -8) assert_equal(result[0]['error']['message'], 'Internal addresses should not have a label') # Nonstandard scriptPubKey + !internal self.log.info("Should not import a nonstandard scriptPubKey without internal flag") nonstandardScriptPubKey = address['scriptPubKey'] + bytes_to_hex_str(script.CScript([script.OP_NOP])) address = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) result = self.nodes[1].importmulti([{ "scriptPubKey": nonstandardScriptPubKey, "timestamp": "now", }]) assert_equal(result[0]['success'], False) assert_equal(result[0]['error']['code'], -8) assert_equal(result[0]['error']['message'], 'Internal must be set to true for nonstandard scriptPubKey imports.') address_assert = self.nodes[1].getaddressinfo(address['address']) assert_equal(address_assert['iswatchonly'], False) assert_equal(address_assert['ismine'], False) assert_equal('timestamp' in address_assert, False) # Address + Public key + !Internal(explicit) self.log.info("Should import an address with public key") address = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) result = self.nodes[1].importmulti([{ "scriptPubKey": { "address": address['address'] }, "timestamp": "now", "pubkeys": [ address['pubkey'] ], "internal": False }]) assert_equal(result[0]['success'], True) address_assert = self.nodes[1].getaddressinfo(address['address']) assert_equal(address_assert['iswatchonly'], True) assert_equal(address_assert['ismine'], False) assert_equal(address_assert['timestamp'], timestamp) # ScriptPubKey + Public key + internal self.log.info("Should import a scriptPubKey with internal and with public key") address = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) request = [{ "scriptPubKey": address['scriptPubKey'], "timestamp": "now", "pubkeys": [ address['pubkey'] ], "internal": True }] result = self.nodes[1].importmulti(requests=request) assert_equal(result[0]['success'], True) address_assert = self.nodes[1].getaddressinfo(address['address']) assert_equal(address_assert['iswatchonly'], True) assert_equal(address_assert['ismine'], False) assert_equal(address_assert['timestamp'], timestamp) # Nonstandard scriptPubKey + Public key + !internal self.log.info("Should not import a nonstandard scriptPubKey without internal and with public key") address = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) request = [{ "scriptPubKey": nonstandardScriptPubKey, "timestamp": "now", "pubkeys": [ address['pubkey'] ] }] result = self.nodes[1].importmulti(requests=request) assert_equal(result[0]['success'], False) assert_equal(result[0]['error']['code'], -8) assert_equal(result[0]['error']['message'], 'Internal must be set to true for nonstandard scriptPubKey imports.') address_assert = self.nodes[1].getaddressinfo(address['address']) assert_equal(address_assert['iswatchonly'], False) assert_equal(address_assert['ismine'], False) assert_equal('timestamp' in address_assert, False) # Address + Private key + !watchonly self.log.info("Should import an address with private key") address = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) result = self.nodes[1].importmulti([{ "scriptPubKey": { "address": address['address'] }, "timestamp": "now", "keys": [ self.nodes[0].dumpprivkey(address['address']) ] }]) assert_equal(result[0]['success'], True) address_assert = self.nodes[1].getaddressinfo(address['address']) assert_equal(address_assert['iswatchonly'], False) assert_equal(address_assert['ismine'], True) assert_equal(address_assert['timestamp'], timestamp) self.log.info("Should not import an address with private key if is already imported") result = self.nodes[1].importmulti([{ "scriptPubKey": { "address": address['address'] }, "timestamp": "now", "keys": [ self.nodes[0].dumpprivkey(address['address']) ] }]) assert_equal(result[0]['success'], False) assert_equal(result[0]['error']['code'], -4) assert_equal(result[0]['error']['message'], 'The wallet already contains the private key for this address or script') # Address + Private key + watchonly self.log.info("Should not import an address with private key and with watchonly") address = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) result = self.nodes[1].importmulti([{ "scriptPubKey": { "address": address['address'] }, "timestamp": "now", "keys": [ self.nodes[0].dumpprivkey(address['address']) ], "watchonly": True }]) assert_equal(result[0]['success'], False) assert_equal(result[0]['error']['code'], -8) assert_equal(result[0]['error']['message'], 'Watch-only addresses should not include private keys') address_assert = self.nodes[1].getaddressinfo(address['address']) assert_equal(address_assert['iswatchonly'], False) assert_equal(address_assert['ismine'], False) assert_equal('timestamp' in address_assert, False) # ScriptPubKey + Private key + internal self.log.info("Should import a scriptPubKey with internal and with private key") address = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) result = self.nodes[1].importmulti([{ "scriptPubKey": address['scriptPubKey'], "timestamp": "now", "keys": [ self.nodes[0].dumpprivkey(address['address']) ], "internal": True }]) assert_equal(result[0]['success'], True) address_assert = self.nodes[1].getaddressinfo(address['address']) assert_equal(address_assert['iswatchonly'], False) assert_equal(address_assert['ismine'], True) assert_equal(address_assert['timestamp'], timestamp) # Nonstandard scriptPubKey + Private key + !internal self.log.info("Should not import a nonstandard scriptPubKey without internal and with private key") address = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) result = self.nodes[1].importmulti([{ "scriptPubKey": nonstandardScriptPubKey, "timestamp": "now", "keys": [ self.nodes[0].dumpprivkey(address['address']) ] }]) assert_equal(result[0]['success'], False) assert_equal(result[0]['error']['code'], -8) assert_equal(result[0]['error']['message'], 'Internal must be set to true for nonstandard scriptPubKey imports.') address_assert = self.nodes[1].getaddressinfo(address['address']) assert_equal(address_assert['iswatchonly'], False) assert_equal(address_assert['ismine'], False) assert_equal('timestamp' in address_assert, False) # P2SH address sig_address_1 = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) sig_address_2 = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) sig_address_3 = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) multi_sig_script = self.nodes[0].createmultisig(2, [sig_address_1['pubkey'], sig_address_2['pubkey'], sig_address_3['pubkey']]) self.nodes[1].generate(100) self.nodes[1].sendtoaddress(multi_sig_script['address'], 10.00) self.nodes[1].generate(1) timestamp = self.nodes[1].getblock(self.nodes[1].getbestblockhash())['mediantime'] self.log.info("Should import a p2sh") result = self.nodes[1].importmulti([{ "scriptPubKey": { "address": multi_sig_script['address'] }, "timestamp": "now", }]) assert_equal(result[0]['success'], True) address_assert = self.nodes[1].getaddressinfo(multi_sig_script['address']) assert_equal(address_assert['isscript'], True) assert_equal(address_assert['iswatchonly'], True) assert_equal(address_assert['timestamp'], timestamp) p2shunspent = self.nodes[1].listunspent(0,999999, [multi_sig_script['address']])[0] assert_equal(p2shunspent['spendable'], False) assert_equal(p2shunspent['solvable'], False) # P2SH + Redeem script sig_address_1 = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) sig_address_2 = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) sig_address_3 = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) multi_sig_script = self.nodes[0].createmultisig(2, [sig_address_1['pubkey'], sig_address_2['pubkey'], sig_address_3['pubkey']]) self.nodes[1].generate(100) self.nodes[1].sendtoaddress(multi_sig_script['address'], 10.00) self.nodes[1].generate(1) timestamp = self.nodes[1].getblock(self.nodes[1].getbestblockhash())['mediantime'] self.log.info("Should import a p2sh with respective redeem script") result = self.nodes[1].importmulti([{ "scriptPubKey": { "address": multi_sig_script['address'] }, "timestamp": "now", "redeemscript": multi_sig_script['redeemScript'] }]) assert_equal(result[0]['success'], True) address_assert = self.nodes[1].getaddressinfo(multi_sig_script['address']) assert_equal(address_assert['timestamp'], timestamp) p2shunspent = self.nodes[1].listunspent(0,999999, [multi_sig_script['address']])[0] assert_equal(p2shunspent['spendable'], False) assert_equal(p2shunspent['solvable'], True) # P2SH + Redeem script + Private Keys + !Watchonly sig_address_1 = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) sig_address_2 = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) sig_address_3 = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) multi_sig_script = self.nodes[0].createmultisig(2, [sig_address_1['pubkey'], sig_address_2['pubkey'], sig_address_3['pubkey']]) self.nodes[1].generate(100) self.nodes[1].sendtoaddress(multi_sig_script['address'], 10.00) self.nodes[1].generate(1) timestamp = self.nodes[1].getblock(self.nodes[1].getbestblockhash())['mediantime'] self.log.info("Should import a p2sh with respective redeem script and private keys") result = self.nodes[1].importmulti([{ "scriptPubKey": { "address": multi_sig_script['address'] }, "timestamp": "now", "redeemscript": multi_sig_script['redeemScript'], "keys": [ self.nodes[0].dumpprivkey(sig_address_1['address']), self.nodes[0].dumpprivkey(sig_address_2['address'])] }]) assert_equal(result[0]['success'], True) address_assert = self.nodes[1].getaddressinfo(multi_sig_script['address']) assert_equal(address_assert['timestamp'], timestamp) p2shunspent = self.nodes[1].listunspent(0,999999, [multi_sig_script['address']])[0] assert_equal(p2shunspent['spendable'], False) assert_equal(p2shunspent['solvable'], True) # P2SH + Redeem script + Private Keys + Watchonly sig_address_1 = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) sig_address_2 = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) sig_address_3 = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) multi_sig_script = self.nodes[0].createmultisig(2, [sig_address_1['pubkey'], sig_address_2['pubkey'], sig_address_3['pubkey']]) self.nodes[1].generate(100) self.nodes[1].sendtoaddress(multi_sig_script['address'], 10.00) self.nodes[1].generate(1) timestamp = self.nodes[1].getblock(self.nodes[1].getbestblockhash())['mediantime'] self.log.info("Should import a p2sh with respective redeem script and private keys") result = self.nodes[1].importmulti([{ "scriptPubKey": { "address": multi_sig_script['address'] }, "timestamp": "now", "redeemscript": multi_sig_script['redeemScript'], "keys": [ self.nodes[0].dumpprivkey(sig_address_1['address']), self.nodes[0].dumpprivkey(sig_address_2['address'])], "watchonly": True }]) assert_equal(result[0]['success'], False) assert_equal(result[0]['error']['code'], -8) assert_equal(result[0]['error']['message'], 'Watch-only addresses should not include private keys') # Address + Public key + !Internal + Wrong pubkey self.log.info("Should not import an address with a wrong public key") address = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) address2 = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) result = self.nodes[1].importmulti([{ "scriptPubKey": { "address": address['address'] }, "timestamp": "now", "pubkeys": [ address2['pubkey'] ] }]) assert_equal(result[0]['success'], False) assert_equal(result[0]['error']['code'], -5) assert_equal(result[0]['error']['message'], 'Key does not match address destination') address_assert = self.nodes[1].getaddressinfo(address['address']) assert_equal(address_assert['iswatchonly'], False) assert_equal(address_assert['ismine'], False) assert_equal('timestamp' in address_assert, False) # ScriptPubKey + Public key + internal + Wrong pubkey self.log.info("Should not import a scriptPubKey with internal and with a wrong public key") address = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) address2 = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) request = [{ "scriptPubKey": address['scriptPubKey'], "timestamp": "now", "pubkeys": [ address2['pubkey'] ], "internal": True }] result = self.nodes[1].importmulti(request) assert_equal(result[0]['success'], False) assert_equal(result[0]['error']['code'], -5) assert_equal(result[0]['error']['message'], 'Key does not match address destination') address_assert = self.nodes[1].getaddressinfo(address['address']) assert_equal(address_assert['iswatchonly'], False) assert_equal(address_assert['ismine'], False) assert_equal('timestamp' in address_assert, False) # Address + Private key + !watchonly + Wrong private key self.log.info("Should not import an address with a wrong private key") address = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) address2 = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) result = self.nodes[1].importmulti([{ "scriptPubKey": { "address": address['address'] }, "timestamp": "now", "keys": [ self.nodes[0].dumpprivkey(address2['address']) ] }]) assert_equal(result[0]['success'], False) assert_equal(result[0]['error']['code'], -5) assert_equal(result[0]['error']['message'], 'Key does not match address destination') address_assert = self.nodes[1].getaddressinfo(address['address']) assert_equal(address_assert['iswatchonly'], False) assert_equal(address_assert['ismine'], False) assert_equal('timestamp' in address_assert, False) # ScriptPubKey + Private key + internal + Wrong private key self.log.info("Should not import a scriptPubKey with internal and with a wrong private key") address = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) address2 = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) result = self.nodes[1].importmulti([{ "scriptPubKey": address['scriptPubKey'], "timestamp": "now", "keys": [ self.nodes[0].dumpprivkey(address2['address']) ], "internal": True }]) assert_equal(result[0]['success'], False) assert_equal(result[0]['error']['code'], -5) assert_equal(result[0]['error']['message'], 'Key does not match address destination') address_assert = self.nodes[1].getaddressinfo(address['address']) assert_equal(address_assert['iswatchonly'], False) assert_equal(address_assert['ismine'], False) assert_equal('timestamp' in address_assert, False) # Importing existing watch only address with new timestamp should replace saved timestamp. assert_greater_than(timestamp, watchonly_timestamp) self.log.info("Should replace previously saved watch only timestamp.") result = self.nodes[1].importmulti([{ "scriptPubKey": { "address": watchonly_address, }, "timestamp": "now", }]) assert_equal(result[0]['success'], True) address_assert = self.nodes[1].getaddressinfo(watchonly_address) assert_equal(address_assert['iswatchonly'], True) assert_equal(address_assert['ismine'], False) assert_equal(address_assert['timestamp'], timestamp) watchonly_timestamp = timestamp # restart nodes to check for proper serialization/deserialization of watch only address self.stop_nodes() self.start_nodes() address_assert = self.nodes[1].getaddressinfo(watchonly_address) assert_equal(address_assert['iswatchonly'], True) assert_equal(address_assert['ismine'], False) assert_equal(address_assert['timestamp'], watchonly_timestamp) # Bad or missing timestamps self.log.info("Should throw on invalid or missing timestamp values") assert_raises_rpc_error(-3, 'Missing required timestamp field for key', self.nodes[1].importmulti, [{ "scriptPubKey": address['scriptPubKey'], }]) assert_raises_rpc_error(-3, 'Expected number or "now" timestamp value for key. got type string', self.nodes[1].importmulti, [{ "scriptPubKey": address['scriptPubKey'], "timestamp": "", }]) # Import P2WPKH address as watch only self.log.info("Should import a P2WPKH address as watch only") address = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress(address_type="bech32")) result = self.nodes[1].importmulti([{ "scriptPubKey": { "address": address['address'] }, "timestamp": "now", }]) assert_equal(result[0]['success'], True) address_assert = self.nodes[1].getaddressinfo(address['address']) assert_equal(address_assert['iswatchonly'], True) assert_equal(address_assert['solvable'], False) # Import P2WPKH address with public key but no private key self.log.info("Should import a P2WPKH address and public key as solvable but not spendable") address = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress(address_type="bech32")) result = self.nodes[1].importmulti([{ "scriptPubKey": { "address": address['address'] }, "timestamp": "now", "pubkeys": [ address['pubkey'] ] }]) assert_equal(result[0]['success'], True) address_assert = self.nodes[1].getaddressinfo(address['address']) assert_equal(address_assert['ismine'], False) assert_equal(address_assert['solvable'], True) # Import P2WPKH address with key and check it is spendable self.log.info("Should import a P2WPKH address with key") address = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress(address_type="bech32")) result = self.nodes[1].importmulti([{ "scriptPubKey": { "address": address['address'] }, "timestamp": "now", "keys": [self.nodes[0].dumpprivkey(address['address'])] }]) assert_equal(result[0]['success'], True) address_assert = self.nodes[1].getaddressinfo(address['address']) assert_equal(address_assert['iswatchonly'], False) assert_equal(address_assert['ismine'], True) # P2WSH multisig address without scripts or keys sig_address_1 = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) sig_address_2 = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) multi_sig_script = self.nodes[0].addmultisigaddress(2, [sig_address_1['pubkey'], sig_address_2['pubkey']], "", "bech32") self.log.info("Should import a p2wsh multisig as watch only without respective redeem script and private keys") result = self.nodes[1].importmulti([{ "scriptPubKey": { "address": multi_sig_script['address'] }, "timestamp": "now" }]) assert_equal(result[0]['success'], True) address_assert = self.nodes[1].getaddressinfo(multi_sig_script['address']) assert_equal(address_assert['solvable'], False) # Same P2WSH multisig address as above, but now with witnessscript + private keys self.log.info("Should import a p2wsh with respective redeem script and private keys") result = self.nodes[1].importmulti([{ "scriptPubKey": { "address": multi_sig_script['address'] }, "timestamp": "now", "witnessscript": multi_sig_script['redeemScript'], "keys": [ self.nodes[0].dumpprivkey(sig_address_1['address']), self.nodes[0].dumpprivkey(sig_address_2['address']) ] }]) assert_equal(result[0]['success'], True) address_assert = self.nodes[1].getaddressinfo(multi_sig_script['address']) assert_equal(address_assert['solvable'], True) assert_equal(address_assert['ismine'], True) assert_equal(address_assert['sigsrequired'], 2) # P2SH-P2WPKH address with no redeemscript or public or private key sig_address_1 = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress(address_type="p2sh-segwit")) pubkeyhash = hash160(hex_str_to_bytes(sig_address_1['pubkey'])) pkscript = CScript([OP_0, pubkeyhash]) self.log.info("Should import a p2sh-p2wpkh without redeem script or keys") result = self.nodes[1].importmulti([{ "scriptPubKey": { "address": sig_address_1['address'] }, "timestamp": "now" }]) assert_equal(result[0]['success'], True) address_assert = self.nodes[1].getaddressinfo(sig_address_1['address']) assert_equal(address_assert['solvable'], False) assert_equal(address_assert['ismine'], False) # P2SH-P2WPKH address + redeemscript + public key with no private key self.log.info("Should import a p2sh-p2wpkh with respective redeem script and pubkey as solvable") result = self.nodes[1].importmulti([{ "scriptPubKey": { "address": sig_address_1['address'] }, "timestamp": "now", "redeemscript": bytes_to_hex_str(pkscript), "pubkeys": [ sig_address_1['pubkey'] ] }]) assert_equal(result[0]['success'], True) address_assert = self.nodes[1].getaddressinfo(sig_address_1['address']) assert_equal(address_assert['solvable'], True) assert_equal(address_assert['ismine'], False) # P2SH-P2WPKH address + redeemscript + private key sig_address_1 = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress(address_type="p2sh-segwit")) pubkeyhash = hash160(hex_str_to_bytes(sig_address_1['pubkey'])) pkscript = CScript([OP_0, pubkeyhash]) self.log.info("Should import a p2sh-p2wpkh with respective redeem script and private keys") result = self.nodes[1].importmulti([{ "scriptPubKey": { "address": sig_address_1['address'] }, "timestamp": "now", "redeemscript": bytes_to_hex_str(pkscript), "keys": [ self.nodes[0].dumpprivkey(sig_address_1['address'])] }]) assert_equal(result[0]['success'], True) address_assert = self.nodes[1].getaddressinfo(sig_address_1['address']) assert_equal(address_assert['solvable'], True) assert_equal(address_assert['ismine'], True) # P2SH-P2WSH 1-of-1 multisig + redeemscript with no private key sig_address_1 = self.nodes[0].getaddressinfo(self.nodes[0].getnewaddress()) multi_sig_script = self.nodes[0].addmultisigaddress(1, [sig_address_1['pubkey']], "", "p2sh-segwit") scripthash = sha256(hex_str_to_bytes(multi_sig_script['redeemScript'])) redeem_script = CScript([OP_0, scripthash]) self.log.info("Should import a p2sh-p2wsh with respective redeem script but no private key") result = self.nodes[1].importmulti([{ "scriptPubKey": { "address": multi_sig_script['address'] }, "timestamp": "now", "redeemscript": bytes_to_hex_str(redeem_script), "witnessscript": multi_sig_script['redeemScript'] }]) assert_equal(result[0]['success'], True) address_assert = self.nodes[1].getaddressinfo(multi_sig_script['address']) assert_equal(address_assert['solvable'], True)
def run_test(self): nodes = self.nodes # Stop staking for i in range(len(nodes)): nodes[i].reservebalance(True, 10000000) nodes[0].extkeyimportmaster( 'abandon baby cabbage dad eager fabric gadget habit ice kangaroo lab absorb' ) assert (nodes[0].getwalletinfo()['total_balance'] == 100000) ro = nodes[1].extkeyimportmaster( 'pact mammal barrel matrix local final lecture chunk wasp survey bid various book strong spread fall ozone daring like topple door fatigue limb olympic', '', 'true') ro = nodes[1].getnewextaddress('lblExtTest') ro = nodes[1].rescanblockchain() assert (nodes[1].getwalletinfo()['total_balance'] == 25000) addrA_0 = nodes[0].getnewaddress() # party A addrB_0 = nodes[1].getnewaddress() # party B # Initiate A -> B # A has address (addrB_0) of B amountA = 5.0 amountB = 5.0 pkh0_0 = b58decode(addrA_0)[1:-4] pkh1_0 = b58decode(addrB_0)[1:-4] secretA = os.urandom(32) secretAHash = sha256(secretA) lockTime = int(time.time()) + 10000 # future locktime scriptInitiate = CreateAtomicSwapScript(payTo=pkh1_0, refundTo=pkh0_0, lockTime=lockTime, secretHash=secretAHash) p2sh_initiate = script_to_p2sh(scriptInitiate) rawtxInitiate = nodes[0].createrawtransaction([], {p2sh_initiate: 5.0}) rawtxInitiate = nodes[0].fundrawtransaction(rawtxInitiate)['hex'] ro = nodes[0].signrawtransaction(rawtxInitiate) assert (ro['complete'] == True) rawtxInitiate = ro['hex'] rawtx1refund = createRefundTx(nodes[0], rawtxInitiate, scriptInitiate, lockTime, addrA_0, addrA_0) txnid1 = nodes[0].sendrawtransaction(rawtxInitiate) self.stakeBlocks(1) ro = nodes[0].getblockchaininfo() assert (ro['mediantime'] < lockTime) try: txnidrefund = nodes[0].sendrawtransaction(rawtx1refund) assert (False) except JSONRPCException as e: assert ('non-final' in e.error['message']) # Party A sends B rawtxInitiate/txnid1 and script # auditcontract # Party B extracts the secrethash and verifies the txn: assert (len(scriptInitiate) == 97) extractedSecretAHash = scriptInitiate[7:7 + 32] assert (extractedSecretAHash == secretAHash) tx1 = nodes[1].decoderawtransaction(rawtxInitiate) # Participate B -> A # needs address from A, amount and secretAHash lockTimeP = int(time.time()) + 10000 # future locktime scriptParticipate = CreateAtomicSwapScript(payTo=pkh0_0, refundTo=pkh1_0, lockTime=lockTimeP, secretHash=secretAHash) p2sh_participate = script_to_p2sh(scriptParticipate) rawtx_p = nodes[1].createrawtransaction([], {p2sh_participate: 5.0}) rawtx_p = nodes[1].fundrawtransaction(rawtx_p)['hex'] ro = nodes[1].signrawtransaction(rawtx_p) assert (ro['complete'] == True) rawtx_p = ro['hex'] rawtxRefundP = createRefundTx(nodes[1], rawtx_p, scriptParticipate, lockTimeP, addrB_0, addrB_0) txnidParticipate = nodes[1].sendrawtransaction(rawtx_p) self.stakeBlocks(1) ro = nodes[0].getblockchaininfo() assert (ro['mediantime'] < lockTimeP) try: txnidrefund = nodes[1].sendrawtransaction(rawtxRefundP) assert (False) except JSONRPCException as e: assert ('non-final' in e.error['message']) # auditcontract # Party A verifies the participate txn from B # Party A Redeem/Claim from participate txn # Party A spends the funds from the participate txn, and to do so must reveal secretA rawtxclaimA = createClaimTx(nodes[0], rawtx_p, scriptParticipate, lockTimeP, secretA, addrA_0, addrA_0) txnidAClaim = nodes[0].sendrawtransaction(rawtxclaimA) # Party B Redeem/Claim from initiate txn # Get secret from txnidAClaim #ro = nodes[1].getrawtransaction(txnidAClaim, True) #print('ro', json.dumps(ro, indent=4, default=jsonDecimal)) rawtxclaimB = createClaimTx(nodes[1], rawtxInitiate, scriptInitiate, lockTime, secretA, addrB_0, addrB_0) txnidBClaim = nodes[0].sendrawtransaction(rawtxclaimB) self.stakeBlocks(1) ftxB = nodes[1].filtertransactions() assert (ftxB[0]['confirmations'] == 1) assert (ftxB[0]['outputs'][0]['amount'] < 5.0 and ftxB[-1]['outputs'][0]['amount'] > 4.9) assert (isclose(ftxB[1]['outputs'][0]['amount'], -5.0)) # Test Refund expired initiate tx lockTime = int(time.time()) - 100000 # past locktime scriptInitiate2 = CreateAtomicSwapScript(payTo=pkh1_0, refundTo=pkh0_0, lockTime=lockTime, secretHash=secretAHash) p2sh_initiate = script_to_p2sh(scriptInitiate2) rawtxInitiate = nodes[0].createrawtransaction([], {p2sh_initiate: 6.0}) rawtxInitiate = nodes[0].fundrawtransaction(rawtxInitiate)['hex'] ro = nodes[0].signrawtransaction(rawtxInitiate) assert (ro['complete'] == True) rawtxInitiate = ro['hex'] rawtx2refund = createRefundTx(nodes[0], rawtxInitiate, scriptInitiate2, lockTime, addrA_0, addrA_0) txnid2 = nodes[0].sendrawtransaction(rawtxInitiate) self.stakeBlocks(1) ro = nodes[0].getblockchaininfo() assert (ro['mediantime'] > lockTime) txnidrefund = nodes[0].sendrawtransaction(rawtx2refund) ftxA = nodes[0].filtertransactions() n = getIndexAtProperty(ftxA, 'txid', txnidrefund) assert (n > -1) assert (ftxA[n]['outputs'][0]['amount'] > 5.9 and ftxA[n]['outputs'][0]['amount'] < 6.0) addrA_sx = nodes[0].getnewstealthaddress() # party A addrB_sx = nodes[1].getnewstealthaddress() # party B
def run_test(self): self.nodes[0].generate(161) # block 161 self.log.info("Verify sigops are counted in GBT with pre-BIP141 rules before the fork") txid = self.nodes[0].sendtoaddress(self.nodes[0].getnewaddress(), 1) tmpl = self.nodes[0].getblocktemplate({'rules': ['segwit']}) assert(tmpl['sizelimit'] == 1000000) assert('weightlimit' not in tmpl) assert(tmpl['sigoplimit'] == 20000) assert(tmpl['transactions'][0]['hash'] == txid) assert(tmpl['transactions'][0]['sigops'] == 2) tmpl = self.nodes[0].getblocktemplate({'rules': ['segwit']}) assert(tmpl['sizelimit'] == 1000000) assert('weightlimit' not in tmpl) assert(tmpl['sigoplimit'] == 20000) assert(tmpl['transactions'][0]['hash'] == txid) assert(tmpl['transactions'][0]['sigops'] == 2) self.nodes[0].generate(1) # block 162 balance_presetup = self.nodes[0].getbalance() self.pubkey = [] p2sh_ids = [] # p2sh_ids[NODE][VER] is an array of txids that spend to a witness version VER pkscript to an address for NODE embedded in p2sh wit_ids = [] # wit_ids[NODE][VER] is an array of txids that spend to a witness version VER pkscript to an address for NODE via bare witness for i in range(3): newaddress = self.nodes[i].getnewaddress() self.pubkey.append(self.nodes[i].getaddressinfo(newaddress)["pubkey"]) multiscript = CScript([OP_1, hex_str_to_bytes(self.pubkey[-1]), OP_1, OP_CHECKMULTISIG]) p2sh_ms_addr = self.nodes[i].addmultisigaddress(1, [self.pubkey[-1]], '', 'p2sh-segwit')['address'] bip173_ms_addr = self.nodes[i].addmultisigaddress(1, [self.pubkey[-1]], '', 'bech32')['address'] assert_equal(p2sh_ms_addr, script_to_p2sh_p2wsh(multiscript)) assert_equal(bip173_ms_addr, script_to_p2wsh(multiscript)) p2sh_ids.append([]) wit_ids.append([]) for v in range(2): p2sh_ids[i].append([]) wit_ids[i].append([]) for i in range(5): for n in range(3): for v in range(2): wit_ids[n][v].append(send_to_witness(v, self.nodes[0], find_spendable_utxo(self.nodes[0], 50), self.pubkey[n], False, Decimal("49.999"))) p2sh_ids[n][v].append(send_to_witness(v, self.nodes[0], find_spendable_utxo(self.nodes[0], 50), self.pubkey[n], True, Decimal("49.999"))) self.nodes[0].generate(1) # block 163 sync_blocks(self.nodes) # Make sure all nodes recognize the transactions as theirs assert_equal(self.nodes[0].getbalance(), balance_presetup - 60 * 50 + 20 * Decimal("49.999") + 50) assert_equal(self.nodes[1].getbalance(), 20 * Decimal("49.999")) assert_equal(self.nodes[2].getbalance(), 20 * Decimal("49.999")) self.nodes[0].generate(260) # block 423 sync_blocks(self.nodes) self.log.info("Verify witness txs are skipped for mining before the fork") self.skip_mine(self.nodes[2], wit_ids[NODE_2][WIT_V0][0], True) # block 424 self.skip_mine(self.nodes[2], wit_ids[NODE_2][WIT_V1][0], True) # block 425 self.skip_mine(self.nodes[2], p2sh_ids[NODE_2][WIT_V0][0], True) # block 426 self.skip_mine(self.nodes[2], p2sh_ids[NODE_2][WIT_V1][0], True) # block 427 self.log.info("Verify unsigned p2sh witness txs without a redeem script are invalid") self.fail_accept(self.nodes[2], "mandatory-script-verify-flag", p2sh_ids[NODE_2][WIT_V0][1], False) self.fail_accept(self.nodes[2], "mandatory-script-verify-flag", p2sh_ids[NODE_2][WIT_V1][1], False) self.nodes[2].generate(4) # blocks 428-431 self.log.info("Verify previous witness txs skipped for mining can now be mined") assert_equal(len(self.nodes[2].getrawmempool()), 4) blockhash = self.nodes[2].generate(1)[0] # block 432 (first block with new rules; 432 = 144 * 3) sync_blocks(self.nodes) assert_equal(len(self.nodes[2].getrawmempool()), 0) segwit_tx_list = self.nodes[2].getblock(blockhash)["tx"] assert_equal(len(segwit_tx_list), 5) self.log.info("Verify default node can't accept txs with missing witness") # unsigned, no scriptsig self.fail_accept(self.nodes[0], "mandatory-script-verify-flag", wit_ids[NODE_0][WIT_V0][0], False) self.fail_accept(self.nodes[0], "mandatory-script-verify-flag", wit_ids[NODE_0][WIT_V1][0], False) self.fail_accept(self.nodes[0], "mandatory-script-verify-flag", p2sh_ids[NODE_0][WIT_V0][0], False) self.fail_accept(self.nodes[0], "mandatory-script-verify-flag", p2sh_ids[NODE_0][WIT_V1][0], False) # unsigned with redeem script self.fail_accept(self.nodes[0], "mandatory-script-verify-flag", p2sh_ids[NODE_0][WIT_V0][0], False, witness_script(False, self.pubkey[0])) self.fail_accept(self.nodes[0], "mandatory-script-verify-flag", p2sh_ids[NODE_0][WIT_V1][0], False, witness_script(True, self.pubkey[0])) self.log.info("Verify block and transaction serialization rpcs return differing serializations depending on rpc serialization flag") assert(self.nodes[2].getblock(blockhash, False) != self.nodes[0].getblock(blockhash, False)) assert(self.nodes[1].getblock(blockhash, False) == self.nodes[2].getblock(blockhash, False)) for tx_id in segwit_tx_list: tx = FromHex(CTransaction(), self.nodes[2].gettransaction(tx_id)["hex"]) assert(self.nodes[2].getrawtransaction(tx_id, False, blockhash) != self.nodes[0].getrawtransaction(tx_id, False, blockhash)) assert(self.nodes[1].getrawtransaction(tx_id, False, blockhash) == self.nodes[2].getrawtransaction(tx_id, False, blockhash)) assert(self.nodes[0].getrawtransaction(tx_id, False, blockhash) != self.nodes[2].gettransaction(tx_id)["hex"]) assert(self.nodes[1].getrawtransaction(tx_id, False, blockhash) == self.nodes[2].gettransaction(tx_id)["hex"]) assert(self.nodes[0].getrawtransaction(tx_id, False, blockhash) == bytes_to_hex_str(tx.serialize_without_witness())) self.log.info("Verify witness txs without witness data are invalid after the fork") self.fail_accept(self.nodes[2], 'non-mandatory-script-verify-flag (Witness program hash mismatch) (code 64)', wit_ids[NODE_2][WIT_V0][2], sign=False) self.fail_accept(self.nodes[2], 'non-mandatory-script-verify-flag (Witness program was passed an empty witness) (code 64)', wit_ids[NODE_2][WIT_V1][2], sign=False) self.fail_accept(self.nodes[2], 'non-mandatory-script-verify-flag (Witness program hash mismatch) (code 64)', p2sh_ids[NODE_2][WIT_V0][2], sign=False, redeem_script=witness_script(False, self.pubkey[2])) self.fail_accept(self.nodes[2], 'non-mandatory-script-verify-flag (Witness program was passed an empty witness) (code 64)', p2sh_ids[NODE_2][WIT_V1][2], sign=False, redeem_script=witness_script(True, self.pubkey[2])) self.log.info("Verify default node can now use witness txs") self.success_mine(self.nodes[0], wit_ids[NODE_0][WIT_V0][0], True) # block 432 self.success_mine(self.nodes[0], wit_ids[NODE_0][WIT_V1][0], True) # block 433 self.success_mine(self.nodes[0], p2sh_ids[NODE_0][WIT_V0][0], True) # block 434 self.success_mine(self.nodes[0], p2sh_ids[NODE_0][WIT_V1][0], True) # block 435 self.log.info("Verify sigops are counted in GBT with BIP141 rules after the fork") txid = self.nodes[0].sendtoaddress(self.nodes[0].getnewaddress(), 1) tmpl = self.nodes[0].getblocktemplate({'rules': ['segwit']}) assert(tmpl['sizelimit'] >= 3999577) # actual maximum size is lower due to minimum mandatory non-witness data assert(tmpl['weightlimit'] == 4000000) assert(tmpl['sigoplimit'] == 80000) assert(tmpl['transactions'][0]['txid'] == txid) assert(tmpl['transactions'][0]['sigops'] == 8) self.nodes[0].generate(1) # Mine a block to clear the gbt cache self.log.info("Non-segwit miners are able to use GBT response after activation.") # Create a 3-tx chain: tx1 (non-segwit input, paying to a segwit output) -> # tx2 (segwit input, paying to a non-segwit output) -> # tx3 (non-segwit input, paying to a non-segwit output). # tx1 is allowed to appear in the block, but no others. txid1 = send_to_witness(1, self.nodes[0], find_spendable_utxo(self.nodes[0], 50), self.pubkey[0], False, Decimal("49.996")) hex_tx = self.nodes[0].gettransaction(txid)['hex'] tx = FromHex(CTransaction(), hex_tx) assert(tx.wit.is_null()) # This should not be a segwit input assert(txid1 in self.nodes[0].getrawmempool()) # Now create tx2, which will spend from txid1. tx = CTransaction() tx.vin.append(CTxIn(COutPoint(int(txid1, 16), 0), b'')) tx.vout.append(CTxOut(int(49.99 * COIN), CScript([OP_TRUE, OP_DROP] * 15 + [OP_TRUE]))) tx2_hex = self.nodes[0].signrawtransactionwithwallet(ToHex(tx))['hex'] txid2 = self.nodes[0].sendrawtransaction(tx2_hex) tx = FromHex(CTransaction(), tx2_hex) assert(not tx.wit.is_null()) # Now create tx3, which will spend from txid2 tx = CTransaction() tx.vin.append(CTxIn(COutPoint(int(txid2, 16), 0), b"")) tx.vout.append(CTxOut(int(49.95 * COIN), CScript([OP_TRUE, OP_DROP] * 15 + [OP_TRUE]))) # Huge fee tx.calc_sha256() txid3 = self.nodes[0].sendrawtransaction(ToHex(tx)) assert(tx.wit.is_null()) assert(txid3 in self.nodes[0].getrawmempool()) # Check that getblocktemplate includes all transactions. template = self.nodes[0].getblocktemplate({"rules": ["segwit"]}) template_txids = [t['txid'] for t in template['transactions']] assert(txid1 in template_txids) assert(txid2 in template_txids) assert(txid3 in template_txids) # Check that wtxid is properly reported in mempool entry assert_equal(int(self.nodes[0].getmempoolentry(txid3)["wtxid"], 16), tx.calc_sha256(True)) # Mine a block to clear the gbt cache again. self.nodes[0].generate(1) self.log.info("Verify behaviour of importaddress and listunspent") # Some public keys to be used later pubkeys = [ "0363D44AABD0F1699138239DF2F042C3282C0671CC7A76826A55C8203D90E39242", # cPiM8Ub4heR9NBYmgVzJQiUH1if44GSBGiqaeJySuL2BKxubvgwb "02D3E626B3E616FC8662B489C123349FECBFC611E778E5BE739B257EAE4721E5BF", # cPpAdHaD6VoYbW78kveN2bsvb45Q7G5PhaPApVUGwvF8VQ9brD97 "04A47F2CBCEFFA7B9BCDA184E7D5668D3DA6F9079AD41E422FA5FD7B2D458F2538A62F5BD8EC85C2477F39650BD391EA6250207065B2A81DA8B009FC891E898F0E", # 91zqCU5B9sdWxzMt1ca3VzbtVm2YM6Hi5Rxn4UDtxEaN9C9nzXV "02A47F2CBCEFFA7B9BCDA184E7D5668D3DA6F9079AD41E422FA5FD7B2D458F2538", # cPQFjcVRpAUBG8BA9hzr2yEzHwKoMgLkJZBBtK9vJnvGJgMjzTbd "036722F784214129FEB9E8129D626324F3F6716555B603FFE8300BBCB882151228", # cQGtcm34xiLjB1v7bkRa4V3aAc9tS2UTuBZ1UnZGeSeNy627fN66 "0266A8396EE936BF6D99D17920DB21C6C7B1AB14C639D5CD72B300297E416FD2EC", # cTW5mR5M45vHxXkeChZdtSPozrFwFgmEvTNnanCW6wrqwaCZ1X7K "0450A38BD7F0AC212FEBA77354A9B036A32E0F7C81FC4E0C5ADCA7C549C4505D2522458C2D9AE3CEFD684E039194B72C8A10F9CB9D4764AB26FCC2718D421D3B84", # 92h2XPssjBpsJN5CqSP7v9a7cf2kgDunBC6PDFwJHMACM1rrVBJ ] # Import a compressed key and an uncompressed key, generate some multisig addresses self.nodes[0].importprivkey("92e6XLo5jVAVwrQKPNTs93oQco8f8sDNBcpv73Dsrs397fQtFQn") uncompressed_spendable_address = ["mvozP4UwyGD2mGZU4D2eMvMLPB9WkMmMQu"] self.nodes[0].importprivkey("cNC8eQ5dg3mFAVePDX4ddmPYpPbw41r9bm2jd1nLJT77e6RrzTRR") compressed_spendable_address = ["mmWQubrDomqpgSYekvsU7HWEVjLFHAakLe"] assert not self.nodes[0].getaddressinfo(uncompressed_spendable_address[0])['iscompressed'] assert self.nodes[0].getaddressinfo(compressed_spendable_address[0])['iscompressed'] self.nodes[0].importpubkey(pubkeys[0]) compressed_solvable_address = [key_to_p2pkh(pubkeys[0])] self.nodes[0].importpubkey(pubkeys[1]) compressed_solvable_address.append(key_to_p2pkh(pubkeys[1])) self.nodes[0].importpubkey(pubkeys[2]) uncompressed_solvable_address = [key_to_p2pkh(pubkeys[2])] spendable_anytime = [] # These outputs should be seen anytime after importprivkey and addmultisigaddress spendable_after_importaddress = [] # These outputs should be seen after importaddress solvable_after_importaddress = [] # These outputs should be seen after importaddress but not spendable unsolvable_after_importaddress = [] # These outputs should be unsolvable after importaddress solvable_anytime = [] # These outputs should be solvable after importpubkey unseen_anytime = [] # These outputs should never be seen uncompressed_spendable_address.append(self.nodes[0].addmultisigaddress(2, [uncompressed_spendable_address[0], compressed_spendable_address[0]])['address']) uncompressed_spendable_address.append(self.nodes[0].addmultisigaddress(2, [uncompressed_spendable_address[0], uncompressed_spendable_address[0]])['address']) compressed_spendable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_spendable_address[0], compressed_spendable_address[0]])['address']) uncompressed_solvable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_spendable_address[0], uncompressed_solvable_address[0]])['address']) compressed_solvable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_spendable_address[0], compressed_solvable_address[0]])['address']) compressed_solvable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_solvable_address[0], compressed_solvable_address[1]])['address']) # Test multisig_without_privkey # We have 2 public keys without private keys, use addmultisigaddress to add to wallet. # Money sent to P2SH of multisig of this should only be seen after importaddress with the BASE58 P2SH address. multisig_without_privkey_address = self.nodes[0].addmultisigaddress(2, [pubkeys[3], pubkeys[4]])['address'] script = CScript([OP_2, hex_str_to_bytes(pubkeys[3]), hex_str_to_bytes(pubkeys[4]), OP_2, OP_CHECKMULTISIG]) solvable_after_importaddress.append(CScript([OP_HASH160, hash160(script), OP_EQUAL])) for i in compressed_spendable_address: v = self.nodes[0].getaddressinfo(i) if (v['isscript']): [bare, p2sh, p2wsh, p2sh_p2wsh] = self.p2sh_address_to_script(v) # p2sh multisig with compressed keys should always be spendable spendable_anytime.extend([p2sh]) # bare multisig can be watched and signed, but is not treated as ours solvable_after_importaddress.extend([bare]) # P2WSH and P2SH(P2WSH) multisig with compressed keys are spendable after direct importaddress spendable_after_importaddress.extend([p2wsh, p2sh_p2wsh]) else: [p2wpkh, p2sh_p2wpkh, p2pk, p2pkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh] = self.p2pkh_address_to_script(v) # normal P2PKH and P2PK with compressed keys should always be spendable spendable_anytime.extend([p2pkh, p2pk]) # P2SH_P2PK, P2SH_P2PKH with compressed keys are spendable after direct importaddress spendable_after_importaddress.extend([p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh]) # P2WPKH and P2SH_P2WPKH with compressed keys should always be spendable spendable_anytime.extend([p2wpkh, p2sh_p2wpkh]) for i in uncompressed_spendable_address: v = self.nodes[0].getaddressinfo(i) if (v['isscript']): [bare, p2sh, p2wsh, p2sh_p2wsh] = self.p2sh_address_to_script(v) # p2sh multisig with uncompressed keys should always be spendable spendable_anytime.extend([p2sh]) # bare multisig can be watched and signed, but is not treated as ours solvable_after_importaddress.extend([bare]) # P2WSH and P2SH(P2WSH) multisig with uncompressed keys are never seen unseen_anytime.extend([p2wsh, p2sh_p2wsh]) else: [p2wpkh, p2sh_p2wpkh, p2pk, p2pkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh] = self.p2pkh_address_to_script(v) # normal P2PKH and P2PK with uncompressed keys should always be spendable spendable_anytime.extend([p2pkh, p2pk]) # P2SH_P2PK and P2SH_P2PKH are spendable after direct importaddress spendable_after_importaddress.extend([p2sh_p2pk, p2sh_p2pkh]) # Witness output types with uncompressed keys are never seen unseen_anytime.extend([p2wpkh, p2sh_p2wpkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh]) for i in compressed_solvable_address: v = self.nodes[0].getaddressinfo(i) if (v['isscript']): # Multisig without private is not seen after addmultisigaddress, but seen after importaddress [bare, p2sh, p2wsh, p2sh_p2wsh] = self.p2sh_address_to_script(v) solvable_after_importaddress.extend([bare, p2sh, p2wsh, p2sh_p2wsh]) else: [p2wpkh, p2sh_p2wpkh, p2pk, p2pkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh] = self.p2pkh_address_to_script(v) # normal P2PKH, P2PK, P2WPKH and P2SH_P2WPKH with compressed keys should always be seen solvable_anytime.extend([p2pkh, p2pk, p2wpkh, p2sh_p2wpkh]) # P2SH_P2PK, P2SH_P2PKH with compressed keys are seen after direct importaddress solvable_after_importaddress.extend([p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh]) for i in uncompressed_solvable_address: v = self.nodes[0].getaddressinfo(i) if (v['isscript']): [bare, p2sh, p2wsh, p2sh_p2wsh] = self.p2sh_address_to_script(v) # Base uncompressed multisig without private is not seen after addmultisigaddress, but seen after importaddress solvable_after_importaddress.extend([bare, p2sh]) # P2WSH and P2SH(P2WSH) multisig with uncompressed keys are never seen unseen_anytime.extend([p2wsh, p2sh_p2wsh]) else: [p2wpkh, p2sh_p2wpkh, p2pk, p2pkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh] = self.p2pkh_address_to_script(v) # normal P2PKH and P2PK with uncompressed keys should always be seen solvable_anytime.extend([p2pkh, p2pk]) # P2SH_P2PK, P2SH_P2PKH with uncompressed keys are seen after direct importaddress solvable_after_importaddress.extend([p2sh_p2pk, p2sh_p2pkh]) # Witness output types with uncompressed keys are never seen unseen_anytime.extend([p2wpkh, p2sh_p2wpkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh]) op1 = CScript([OP_1]) op0 = CScript([OP_0]) # 2N7MGY19ti4KDMSzRfPAssP6Pxyuxoi6jLe is the P2SH(P2PKH) version of mjoE3sSrb8ByYEvgnC3Aox86u1CHnfJA4V unsolvable_address_key = hex_str_to_bytes("02341AEC7587A51CDE5279E0630A531AEA2615A9F80B17E8D9376327BAEAA59E3D") unsolvablep2pkh = CScript([OP_DUP, OP_HASH160, hash160(unsolvable_address_key), OP_EQUALVERIFY, OP_CHECKSIG]) unsolvablep2wshp2pkh = CScript([OP_0, sha256(unsolvablep2pkh)]) p2shop0 = CScript([OP_HASH160, hash160(op0), OP_EQUAL]) p2wshop1 = CScript([OP_0, sha256(op1)]) unsolvable_after_importaddress.append(unsolvablep2pkh) unsolvable_after_importaddress.append(unsolvablep2wshp2pkh) unsolvable_after_importaddress.append(op1) # OP_1 will be imported as script unsolvable_after_importaddress.append(p2wshop1) unseen_anytime.append(op0) # OP_0 will be imported as P2SH address with no script provided unsolvable_after_importaddress.append(p2shop0) spendable_txid = [] solvable_txid = [] spendable_txid.append(self.mine_and_test_listunspent(spendable_anytime, 2)) solvable_txid.append(self.mine_and_test_listunspent(solvable_anytime, 1)) self.mine_and_test_listunspent(spendable_after_importaddress + solvable_after_importaddress + unseen_anytime + unsolvable_after_importaddress, 0) importlist = [] for i in compressed_spendable_address + uncompressed_spendable_address + compressed_solvable_address + uncompressed_solvable_address: v = self.nodes[0].getaddressinfo(i) if (v['isscript']): bare = hex_str_to_bytes(v['hex']) importlist.append(bytes_to_hex_str(bare)) importlist.append(bytes_to_hex_str(CScript([OP_0, sha256(bare)]))) else: pubkey = hex_str_to_bytes(v['pubkey']) p2pk = CScript([pubkey, OP_CHECKSIG]) p2pkh = CScript([OP_DUP, OP_HASH160, hash160(pubkey), OP_EQUALVERIFY, OP_CHECKSIG]) importlist.append(bytes_to_hex_str(p2pk)) importlist.append(bytes_to_hex_str(p2pkh)) importlist.append(bytes_to_hex_str(CScript([OP_0, hash160(pubkey)]))) importlist.append(bytes_to_hex_str(CScript([OP_0, sha256(p2pk)]))) importlist.append(bytes_to_hex_str(CScript([OP_0, sha256(p2pkh)]))) importlist.append(bytes_to_hex_str(unsolvablep2pkh)) importlist.append(bytes_to_hex_str(unsolvablep2wshp2pkh)) importlist.append(bytes_to_hex_str(op1)) importlist.append(bytes_to_hex_str(p2wshop1)) for i in importlist: # import all generated addresses. The wallet already has the private keys for some of these, so catch JSON RPC # exceptions and continue. try_rpc(-4, "The wallet already contains the private key for this address or script", self.nodes[0].importaddress, i, "", False, True) self.nodes[0].importaddress(script_to_p2sh(op0)) # import OP_0 as address only self.nodes[0].importaddress(multisig_without_privkey_address) # Test multisig_without_privkey spendable_txid.append(self.mine_and_test_listunspent(spendable_anytime + spendable_after_importaddress, 2)) solvable_txid.append(self.mine_and_test_listunspent(solvable_anytime + solvable_after_importaddress, 1)) self.mine_and_test_listunspent(unsolvable_after_importaddress, 1) self.mine_and_test_listunspent(unseen_anytime, 0) spendable_txid.append(self.mine_and_test_listunspent(spendable_anytime + spendable_after_importaddress, 2)) solvable_txid.append(self.mine_and_test_listunspent(solvable_anytime + solvable_after_importaddress, 1)) self.mine_and_test_listunspent(unsolvable_after_importaddress, 1) self.mine_and_test_listunspent(unseen_anytime, 0) # Repeat some tests. This time we don't add witness scripts with importaddress # Import a compressed key and an uncompressed key, generate some multisig addresses self.nodes[0].importprivkey("927pw6RW8ZekycnXqBQ2JS5nPyo1yRfGNN8oq74HeddWSpafDJH") uncompressed_spendable_address = ["mguN2vNSCEUh6rJaXoAVwY3YZwZvEmf5xi"] self.nodes[0].importprivkey("cMcrXaaUC48ZKpcyydfFo8PxHAjpsYLhdsp6nmtB3E2ER9UUHWnw") compressed_spendable_address = ["n1UNmpmbVUJ9ytXYXiurmGPQ3TRrXqPWKL"] self.nodes[0].importpubkey(pubkeys[5]) compressed_solvable_address = [key_to_p2pkh(pubkeys[5])] self.nodes[0].importpubkey(pubkeys[6]) uncompressed_solvable_address = [key_to_p2pkh(pubkeys[6])] unseen_anytime = [] # These outputs should never be seen solvable_anytime = [] # These outputs should be solvable after importpubkey unseen_anytime = [] # These outputs should never be seen uncompressed_spendable_address.append(self.nodes[0].addmultisigaddress(2, [uncompressed_spendable_address[0], compressed_spendable_address[0]])['address']) uncompressed_spendable_address.append(self.nodes[0].addmultisigaddress(2, [uncompressed_spendable_address[0], uncompressed_spendable_address[0]])['address']) compressed_spendable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_spendable_address[0], compressed_spendable_address[0]])['address']) uncompressed_solvable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_solvable_address[0], uncompressed_solvable_address[0]])['address']) compressed_solvable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_spendable_address[0], compressed_solvable_address[0]])['address']) premature_witaddress = [] for i in compressed_spendable_address: v = self.nodes[0].getaddressinfo(i) if (v['isscript']): [bare, p2sh, p2wsh, p2sh_p2wsh] = self.p2sh_address_to_script(v) premature_witaddress.append(script_to_p2sh(p2wsh)) else: [p2wpkh, p2sh_p2wpkh, p2pk, p2pkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh] = self.p2pkh_address_to_script(v) # P2WPKH, P2SH_P2WPKH are always spendable spendable_anytime.extend([p2wpkh, p2sh_p2wpkh]) for i in uncompressed_spendable_address + uncompressed_solvable_address: v = self.nodes[0].getaddressinfo(i) if (v['isscript']): [bare, p2sh, p2wsh, p2sh_p2wsh] = self.p2sh_address_to_script(v) # P2WSH and P2SH(P2WSH) multisig with uncompressed keys are never seen unseen_anytime.extend([p2wsh, p2sh_p2wsh]) else: [p2wpkh, p2sh_p2wpkh, p2pk, p2pkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh] = self.p2pkh_address_to_script(v) # P2WPKH, P2SH_P2WPKH with uncompressed keys are never seen unseen_anytime.extend([p2wpkh, p2sh_p2wpkh]) for i in compressed_solvable_address: v = self.nodes[0].getaddressinfo(i) if (v['isscript']): [bare, p2sh, p2wsh, p2sh_p2wsh] = self.p2sh_address_to_script(v) premature_witaddress.append(script_to_p2sh(p2wsh)) else: [p2wpkh, p2sh_p2wpkh, p2pk, p2pkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh] = self.p2pkh_address_to_script(v) # P2SH_P2PK, P2SH_P2PKH with compressed keys are always solvable solvable_anytime.extend([p2wpkh, p2sh_p2wpkh]) self.mine_and_test_listunspent(spendable_anytime, 2) self.mine_and_test_listunspent(solvable_anytime, 1) self.mine_and_test_listunspent(unseen_anytime, 0) # Check that createrawtransaction/decoderawtransaction with non-v0 Bech32 works v1_addr = program_to_witness(1, [3, 5]) v1_tx = self.nodes[0].createrawtransaction([getutxo(spendable_txid[0])], {v1_addr: 1}) v1_decoded = self.nodes[1].decoderawtransaction(v1_tx) assert_equal(v1_decoded['vout'][0]['scriptPubKey']['addresses'][0], v1_addr) assert_equal(v1_decoded['vout'][0]['scriptPubKey']['hex'], "51020305") # Check that spendable outputs are really spendable self.create_and_mine_tx_from_txids(spendable_txid) # import all the private keys so solvable addresses become spendable self.nodes[0].importprivkey("cPiM8Ub4heR9NBYmgVzJQiUH1if44GSBGiqaeJySuL2BKxubvgwb") self.nodes[0].importprivkey("cPpAdHaD6VoYbW78kveN2bsvb45Q7G5PhaPApVUGwvF8VQ9brD97") self.nodes[0].importprivkey("91zqCU5B9sdWxzMt1ca3VzbtVm2YM6Hi5Rxn4UDtxEaN9C9nzXV") self.nodes[0].importprivkey("cPQFjcVRpAUBG8BA9hzr2yEzHwKoMgLkJZBBtK9vJnvGJgMjzTbd") self.nodes[0].importprivkey("cQGtcm34xiLjB1v7bkRa4V3aAc9tS2UTuBZ1UnZGeSeNy627fN66") self.nodes[0].importprivkey("cTW5mR5M45vHxXkeChZdtSPozrFwFgmEvTNnanCW6wrqwaCZ1X7K") self.create_and_mine_tx_from_txids(solvable_txid) # Test that importing native P2WPKH/P2WSH scripts works for use_p2wsh in [False, True]: if use_p2wsh: scriptPubKey = "00203a59f3f56b713fdcf5d1a57357f02c44342cbf306ffe0c4741046837bf90561a" transaction = "01000000000100e1f505000000002200203a59f3f56b713fdcf5d1a57357f02c44342cbf306ffe0c4741046837bf90561a00000000" else: scriptPubKey = "a9142f8c469c2f0084c48e11f998ffbe7efa7549f26d87" transaction = "01000000000100e1f5050000000017a9142f8c469c2f0084c48e11f998ffbe7efa7549f26d8700000000" self.nodes[1].importaddress(scriptPubKey, "", False) rawtxfund = self.nodes[1].fundrawtransaction(transaction)['hex'] rawtxfund = self.nodes[1].signrawtransactionwithwallet(rawtxfund)["hex"] txid = self.nodes[1].sendrawtransaction(rawtxfund) assert_equal(self.nodes[1].gettransaction(txid, True)["txid"], txid) assert_equal(self.nodes[1].listtransactions("*", 1, 0, True)[0]["txid"], txid) # Assert it is properly saved self.stop_node(1) self.start_node(1) assert_equal(self.nodes[1].gettransaction(txid, True)["txid"], txid) assert_equal(self.nodes[1].listtransactions("*", 1, 0, True)[0]["txid"], txid)
def test_witness_block_size(self): # TODO: Test that non-witness carrying blocks can't exceed 1MB # Skipping this test for now; this is covered in p2p-fullblocktest.py # Test that witness-bearing blocks are limited at ceil(base + wit/4) <= 1MB. block = self.build_next_block() assert len(self.utxo) > 0 # Create a P2WSH transaction. # The witness program will be a bunch of OP_2DROP's, followed by OP_TRUE. # This should give us plenty of room to tweak the spending tx's # virtual size. NUM_DROPS = 200 # 201 max ops per script! NUM_OUTPUTS = 50 witness_program = CScript([OP_2DROP] * NUM_DROPS + [OP_TRUE]) witness_hash = uint256_from_str(sha256(witness_program)) script_pubkey = CScript([OP_0, ser_uint256(witness_hash)]) prevout = COutPoint(self.utxo[0].sha256, self.utxo[0].n) value = self.utxo[0].nValue parent_tx = CTransaction() parent_tx.vin.append(CTxIn(prevout, b"")) child_value = int(value / NUM_OUTPUTS) for i in range(NUM_OUTPUTS): parent_tx.vout.append(CTxOut(child_value, script_pubkey)) parent_tx.vout[0].nValue -= 50000 assert parent_tx.vout[0].nValue > 0 parent_tx.rehash() filler_size = 3150 child_tx = CTransaction() for i in range(NUM_OUTPUTS): child_tx.vin.append(CTxIn(COutPoint(parent_tx.sha256, i), b"")) child_tx.vout = [CTxOut(value - 100000, CScript([OP_TRUE]))] for i in range(NUM_OUTPUTS): child_tx.wit.vtxinwit.append(CTxInWitness()) child_tx.wit.vtxinwit[-1].scriptWitness.stack = [ b'a' * filler_size ] * (2 * NUM_DROPS) + [witness_program] child_tx.rehash() self.update_witness_block_with_transactions(block, [parent_tx, child_tx]) vsize = get_virtual_size(block) assert_greater_than(MAX_BLOCK_BASE_SIZE, vsize) additional_bytes = (MAX_BLOCK_BASE_SIZE - vsize) * 4 i = 0 while additional_bytes > 0: # Add some more bytes to each input until we hit MAX_BLOCK_BASE_SIZE+1 extra_bytes = min(additional_bytes + 1, 55) block.vtx[-1].wit.vtxinwit[int( i / (2 * NUM_DROPS))].scriptWitness.stack[ i % (2 * NUM_DROPS)] = b'a' * (filler_size + extra_bytes) additional_bytes -= extra_bytes i += 1 block.vtx[0].vout.pop() # Remove old commitment add_witness_commitment(block) block.solve() vsize = get_virtual_size(block) assert_equal(vsize, MAX_BLOCK_BASE_SIZE + 1) # Make sure that our test case would exceed the old max-network-message # limit assert len(block.serialize()) > 2 * 1024 * 1024 test_witness_block(self.nodes[0], self.test_node, block, accepted=False) # Now resize the second transaction to make the block fit. cur_length = len(block.vtx[-1].wit.vtxinwit[0].scriptWitness.stack[0]) block.vtx[-1].wit.vtxinwit[0].scriptWitness.stack[0] = b'a' * ( cur_length - 1) block.vtx[0].vout.pop() add_witness_commitment(block) block.solve() assert get_virtual_size(block) == MAX_BLOCK_BASE_SIZE test_witness_block(self.nodes[0], self.test_node, block, accepted=True) # Update available utxo's self.utxo.pop(0) self.utxo.append( UTXO(block.vtx[-1].sha256, 0, block.vtx[-1].vout[0].nValue))