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673 lines
42 KiB
673 lines
42 KiB
#!/usr/bin/env python3 |
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# Copyright (c) 2016-2017 The Bitcoin Core developers |
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# Distributed under the MIT software license, see the accompanying |
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# file COPYING or http://www.opensource.org/licenses/mit-license.php. |
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"""Test the SegWit changeover logic.""" |
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from test_framework.test_framework import BitcoinTestFramework |
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from test_framework.util import * |
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from test_framework.mininode import sha256, CTransaction, CTxIn, COutPoint, CTxOut, COIN, ToHex, FromHex |
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from test_framework.address import script_to_p2sh, key_to_p2pkh, key_to_p2sh_p2wpkh, key_to_p2wpkh, script_to_p2sh_p2wsh, script_to_p2wsh, program_to_witness |
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from test_framework.script import CScript, OP_HASH160, OP_CHECKSIG, OP_0, hash160, OP_EQUAL, OP_DUP, OP_EQUALVERIFY, OP_1, OP_2, OP_CHECKMULTISIG, OP_TRUE |
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from io import BytesIO |
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NODE_0 = 0 |
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NODE_2 = 2 |
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WIT_V0 = 0 |
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WIT_V1 = 1 |
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# Create a scriptPubKey corresponding to either a P2WPKH output for the |
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# given pubkey, or a P2WSH output of a 1-of-1 multisig for the given |
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# pubkey. Returns the hex encoding of the scriptPubKey. |
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def witness_script(use_p2wsh, pubkey): |
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if (use_p2wsh == False): |
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# P2WPKH instead |
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pubkeyhash = hash160(hex_str_to_bytes(pubkey)) |
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pkscript = CScript([OP_0, pubkeyhash]) |
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else: |
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# 1-of-1 multisig |
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witness_program = CScript([OP_1, hex_str_to_bytes(pubkey), OP_1, OP_CHECKMULTISIG]) |
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scripthash = sha256(witness_program) |
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pkscript = CScript([OP_0, scripthash]) |
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return bytes_to_hex_str(pkscript) |
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# Return a transaction (in hex) that spends the given utxo to a segwit output, |
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# optionally wrapping the segwit output using P2SH. |
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def create_witness_tx(node, use_p2wsh, utxo, pubkey, encode_p2sh, amount): |
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if use_p2wsh: |
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program = CScript([OP_1, hex_str_to_bytes(pubkey), OP_1, OP_CHECKMULTISIG]) |
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addr = script_to_p2sh_p2wsh(program) if encode_p2sh else script_to_p2wsh(program) |
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else: |
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addr = key_to_p2sh_p2wpkh(pubkey) if encode_p2sh else key_to_p2wpkh(pubkey) |
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if not encode_p2sh: |
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assert_equal(node.validateaddress(addr)['scriptPubKey'], witness_script(use_p2wsh, pubkey)) |
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return node.createrawtransaction([utxo], {addr: amount}) |
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# Create a transaction spending a given utxo to a segwit output corresponding |
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# to the given pubkey: use_p2wsh determines whether to use P2WPKH or P2WSH; |
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# encode_p2sh determines whether to wrap in P2SH. |
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# sign=True will have the given node sign the transaction. |
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# insert_redeem_script will be added to the scriptSig, if given. |
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def send_to_witness(use_p2wsh, node, utxo, pubkey, encode_p2sh, amount, sign=True, insert_redeem_script=""): |
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tx_to_witness = create_witness_tx(node, use_p2wsh, utxo, pubkey, encode_p2sh, amount) |
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if (sign): |
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signed = node.signrawtransaction(tx_to_witness) |
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assert("errors" not in signed or len(["errors"]) == 0) |
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return node.sendrawtransaction(signed["hex"]) |
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else: |
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if (insert_redeem_script): |
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tx = FromHex(CTransaction(), tx_to_witness) |
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tx.vin[0].scriptSig += CScript([hex_str_to_bytes(insert_redeem_script)]) |
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tx_to_witness = ToHex(tx) |
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return node.sendrawtransaction(tx_to_witness) |
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def getutxo(txid): |
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utxo = {} |
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utxo["vout"] = 0 |
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utxo["txid"] = txid |
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return utxo |
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def find_unspent(node, min_value): |
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for utxo in node.listunspent(): |
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if utxo['amount'] >= min_value: |
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return utxo |
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class SegWitTest(BitcoinTestFramework): |
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def set_test_params(self): |
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self.setup_clean_chain = True |
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self.num_nodes = 3 |
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# This test tests SegWit both pre and post-activation, so use the normal BIP9 activation. |
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self.extra_args = [["-walletprematurewitness", "-rpcserialversion=0", "-vbparams=segwit:0:999999999999"], |
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["-blockversion=4", "-promiscuousmempoolflags=517", "-prematurewitness", "-walletprematurewitness", "-rpcserialversion=1", "-vbparams=segwit:0:999999999999"], |
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["-blockversion=536870915", "-promiscuousmempoolflags=517", "-prematurewitness", "-walletprematurewitness", "-vbparams=segwit:0:999999999999"]] |
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def setup_network(self): |
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super().setup_network() |
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connect_nodes(self.nodes[0], 2) |
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self.sync_all() |
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def success_mine(self, node, txid, sign, redeem_script=""): |
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send_to_witness(1, node, getutxo(txid), self.pubkey[0], False, Decimal("49.998"), sign, redeem_script) |
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block = node.generate(1) |
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assert_equal(len(node.getblock(block[0])["tx"]), 2) |
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sync_blocks(self.nodes) |
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def skip_mine(self, node, txid, sign, redeem_script=""): |
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send_to_witness(1, node, getutxo(txid), self.pubkey[0], False, Decimal("49.998"), sign, redeem_script) |
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block = node.generate(1) |
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assert_equal(len(node.getblock(block[0])["tx"]), 1) |
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sync_blocks(self.nodes) |
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def fail_accept(self, node, error_msg, txid, sign, redeem_script=""): |
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assert_raises_rpc_error(-26, error_msg, send_to_witness, 1, node, getutxo(txid), self.pubkey[0], False, Decimal("49.998"), sign, redeem_script) |
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def fail_mine(self, node, txid, sign, redeem_script=""): |
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send_to_witness(1, node, getutxo(txid), self.pubkey[0], False, Decimal("49.998"), sign, redeem_script) |
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assert_raises_rpc_error(-1, "CreateNewBlock: TestBlockValidity failed", node.generate, 1) |
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sync_blocks(self.nodes) |
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def run_test(self): |
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self.nodes[0].generate(161) #block 161 |
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self.log.info("Verify sigops are counted in GBT with pre-BIP141 rules before the fork") |
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txid = self.nodes[0].sendtoaddress(self.nodes[0].getnewaddress(), 1) |
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tmpl = self.nodes[0].getblocktemplate({}) |
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assert(tmpl['sizelimit'] == 1000000) |
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assert('weightlimit' not in tmpl) |
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assert(tmpl['sigoplimit'] == 20000) |
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assert(tmpl['transactions'][0]['hash'] == txid) |
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assert(tmpl['transactions'][0]['sigops'] == 2) |
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tmpl = self.nodes[0].getblocktemplate({'rules':['segwit']}) |
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assert(tmpl['sizelimit'] == 1000000) |
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assert('weightlimit' not in tmpl) |
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assert(tmpl['sigoplimit'] == 20000) |
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assert(tmpl['transactions'][0]['hash'] == txid) |
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assert(tmpl['transactions'][0]['sigops'] == 2) |
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self.nodes[0].generate(1) #block 162 |
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balance_presetup = self.nodes[0].getbalance() |
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self.pubkey = [] |
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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 |
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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 |
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for i in range(3): |
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newaddress = self.nodes[i].getnewaddress() |
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self.pubkey.append(self.nodes[i].validateaddress(newaddress)["pubkey"]) |
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multiaddress = self.nodes[i].addmultisigaddress(1, [self.pubkey[-1]]) |
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multiscript = CScript([OP_1, hex_str_to_bytes(self.pubkey[-1]), OP_1, OP_CHECKMULTISIG]) |
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p2sh_addr = self.nodes[i].addwitnessaddress(newaddress, True) |
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bip173_addr = self.nodes[i].addwitnessaddress(newaddress, False) |
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p2sh_ms_addr = self.nodes[i].addwitnessaddress(multiaddress, True) |
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bip173_ms_addr = self.nodes[i].addwitnessaddress(multiaddress, False) |
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assert_equal(p2sh_addr, key_to_p2sh_p2wpkh(self.pubkey[-1])) |
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assert_equal(bip173_addr, key_to_p2wpkh(self.pubkey[-1])) |
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assert_equal(p2sh_ms_addr, script_to_p2sh_p2wsh(multiscript)) |
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assert_equal(bip173_ms_addr, script_to_p2wsh(multiscript)) |
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p2sh_ids.append([]) |
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wit_ids.append([]) |
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for v in range(2): |
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p2sh_ids[i].append([]) |
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wit_ids[i].append([]) |
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for i in range(5): |
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for n in range(3): |
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for v in range(2): |
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wit_ids[n][v].append(send_to_witness(v, self.nodes[0], find_unspent(self.nodes[0], 50), self.pubkey[n], False, Decimal("49.999"))) |
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p2sh_ids[n][v].append(send_to_witness(v, self.nodes[0], find_unspent(self.nodes[0], 50), self.pubkey[n], True, Decimal("49.999"))) |
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self.nodes[0].generate(1) #block 163 |
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sync_blocks(self.nodes) |
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# Make sure all nodes recognize the transactions as theirs |
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assert_equal(self.nodes[0].getbalance(), balance_presetup - 60*50 + 20*Decimal("49.999") + 50) |
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assert_equal(self.nodes[1].getbalance(), 20*Decimal("49.999")) |
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assert_equal(self.nodes[2].getbalance(), 20*Decimal("49.999")) |
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self.nodes[0].generate(260) #block 423 |
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sync_blocks(self.nodes) |
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self.log.info("Verify default node can't accept any witness format txs before fork") |
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# unsigned, no scriptsig |
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self.fail_accept(self.nodes[0], "mandatory-script-verify-flag", wit_ids[NODE_0][WIT_V0][0], False) |
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self.fail_accept(self.nodes[0], "mandatory-script-verify-flag", wit_ids[NODE_0][WIT_V1][0], False) |
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self.fail_accept(self.nodes[0], "mandatory-script-verify-flag", p2sh_ids[NODE_0][WIT_V0][0], False) |
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self.fail_accept(self.nodes[0], "mandatory-script-verify-flag", p2sh_ids[NODE_0][WIT_V1][0], False) |
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# unsigned with redeem script |
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self.fail_accept(self.nodes[0], "mandatory-script-verify-flag", p2sh_ids[NODE_0][WIT_V0][0], False, witness_script(False, self.pubkey[0])) |
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self.fail_accept(self.nodes[0], "mandatory-script-verify-flag", p2sh_ids[NODE_0][WIT_V1][0], False, witness_script(True, self.pubkey[0])) |
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# signed |
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self.fail_accept(self.nodes[0], "no-witness-yet", wit_ids[NODE_0][WIT_V0][0], True) |
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self.fail_accept(self.nodes[0], "no-witness-yet", wit_ids[NODE_0][WIT_V1][0], True) |
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self.fail_accept(self.nodes[0], "no-witness-yet", p2sh_ids[NODE_0][WIT_V0][0], True) |
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self.fail_accept(self.nodes[0], "no-witness-yet", p2sh_ids[NODE_0][WIT_V1][0], True) |
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self.log.info("Verify witness txs are skipped for mining before the fork") |
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self.skip_mine(self.nodes[2], wit_ids[NODE_2][WIT_V0][0], True) #block 424 |
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self.skip_mine(self.nodes[2], wit_ids[NODE_2][WIT_V1][0], True) #block 425 |
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self.skip_mine(self.nodes[2], p2sh_ids[NODE_2][WIT_V0][0], True) #block 426 |
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self.skip_mine(self.nodes[2], p2sh_ids[NODE_2][WIT_V1][0], True) #block 427 |
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# TODO: An old node would see these txs without witnesses and be able to mine them |
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self.log.info("Verify unsigned bare witness txs in versionbits-setting blocks are valid before the fork") |
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self.success_mine(self.nodes[2], wit_ids[NODE_2][WIT_V0][1], False) #block 428 |
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self.success_mine(self.nodes[2], wit_ids[NODE_2][WIT_V1][1], False) #block 429 |
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self.log.info("Verify unsigned p2sh witness txs without a redeem script are invalid") |
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self.fail_accept(self.nodes[2], "mandatory-script-verify-flag", p2sh_ids[NODE_2][WIT_V0][1], False) |
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self.fail_accept(self.nodes[2], "mandatory-script-verify-flag", p2sh_ids[NODE_2][WIT_V1][1], False) |
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self.log.info("Verify unsigned p2sh witness txs with a redeem script in versionbits-settings blocks are valid before the fork") |
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self.success_mine(self.nodes[2], p2sh_ids[NODE_2][WIT_V0][1], False, witness_script(False, self.pubkey[2])) #block 430 |
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self.success_mine(self.nodes[2], p2sh_ids[NODE_2][WIT_V1][1], False, witness_script(True, self.pubkey[2])) #block 431 |
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self.log.info("Verify previous witness txs skipped for mining can now be mined") |
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assert_equal(len(self.nodes[2].getrawmempool()), 4) |
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block = self.nodes[2].generate(1) #block 432 (first block with new rules; 432 = 144 * 3) |
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sync_blocks(self.nodes) |
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assert_equal(len(self.nodes[2].getrawmempool()), 0) |
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segwit_tx_list = self.nodes[2].getblock(block[0])["tx"] |
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assert_equal(len(segwit_tx_list), 5) |
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self.log.info("Verify block and transaction serialization rpcs return differing serializations depending on rpc serialization flag") |
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assert(self.nodes[2].getblock(block[0], False) != self.nodes[0].getblock(block[0], False)) |
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assert(self.nodes[1].getblock(block[0], False) == self.nodes[2].getblock(block[0], False)) |
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for i in range(len(segwit_tx_list)): |
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tx = FromHex(CTransaction(), self.nodes[2].gettransaction(segwit_tx_list[i])["hex"]) |
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assert(self.nodes[2].getrawtransaction(segwit_tx_list[i]) != self.nodes[0].getrawtransaction(segwit_tx_list[i])) |
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assert(self.nodes[1].getrawtransaction(segwit_tx_list[i], 0) == self.nodes[2].getrawtransaction(segwit_tx_list[i])) |
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assert(self.nodes[0].getrawtransaction(segwit_tx_list[i]) != self.nodes[2].gettransaction(segwit_tx_list[i])["hex"]) |
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assert(self.nodes[1].getrawtransaction(segwit_tx_list[i]) == self.nodes[2].gettransaction(segwit_tx_list[i])["hex"]) |
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assert(self.nodes[0].getrawtransaction(segwit_tx_list[i]) == bytes_to_hex_str(tx.serialize_without_witness())) |
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self.log.info("Verify witness txs without witness data are invalid after the fork") |
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self.fail_mine(self.nodes[2], wit_ids[NODE_2][WIT_V0][2], False) |
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self.fail_mine(self.nodes[2], wit_ids[NODE_2][WIT_V1][2], False) |
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self.fail_mine(self.nodes[2], p2sh_ids[NODE_2][WIT_V0][2], False, witness_script(False, self.pubkey[2])) |
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self.fail_mine(self.nodes[2], p2sh_ids[NODE_2][WIT_V1][2], False, witness_script(True, self.pubkey[2])) |
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self.log.info("Verify default node can now use witness txs") |
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self.success_mine(self.nodes[0], wit_ids[NODE_0][WIT_V0][0], True) #block 432 |
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self.success_mine(self.nodes[0], wit_ids[NODE_0][WIT_V1][0], True) #block 433 |
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self.success_mine(self.nodes[0], p2sh_ids[NODE_0][WIT_V0][0], True) #block 434 |
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self.success_mine(self.nodes[0], p2sh_ids[NODE_0][WIT_V1][0], True) #block 435 |
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self.log.info("Verify sigops are counted in GBT with BIP141 rules after the fork") |
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txid = self.nodes[0].sendtoaddress(self.nodes[0].getnewaddress(), 1) |
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tmpl = self.nodes[0].getblocktemplate({'rules':['segwit']}) |
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assert(tmpl['sizelimit'] >= 3999577) # actual maximum size is lower due to minimum mandatory non-witness data |
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assert(tmpl['weightlimit'] == 4000000) |
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assert(tmpl['sigoplimit'] == 80000) |
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assert(tmpl['transactions'][0]['txid'] == txid) |
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assert(tmpl['transactions'][0]['sigops'] == 8) |
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self.nodes[0].generate(1) # Mine a block to clear the gbt cache |
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self.log.info("Non-segwit miners are able to use GBT response after activation.") |
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# Create a 3-tx chain: tx1 (non-segwit input, paying to a segwit output) -> |
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# tx2 (segwit input, paying to a non-segwit output) -> |
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# tx3 (non-segwit input, paying to a non-segwit output). |
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# tx1 is allowed to appear in the block, but no others. |
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txid1 = send_to_witness(1, self.nodes[0], find_unspent(self.nodes[0], 50), self.pubkey[0], False, Decimal("49.996")) |
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hex_tx = self.nodes[0].gettransaction(txid)['hex'] |
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tx = FromHex(CTransaction(), hex_tx) |
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assert(tx.wit.is_null()) # This should not be a segwit input |
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assert(txid1 in self.nodes[0].getrawmempool()) |
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# Now create tx2, which will spend from txid1. |
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tx = CTransaction() |
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tx.vin.append(CTxIn(COutPoint(int(txid1, 16), 0), b'')) |
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tx.vout.append(CTxOut(int(49.99*COIN), CScript([OP_TRUE]))) |
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tx2_hex = self.nodes[0].signrawtransaction(ToHex(tx))['hex'] |
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txid2 = self.nodes[0].sendrawtransaction(tx2_hex) |
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tx = FromHex(CTransaction(), tx2_hex) |
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assert(not tx.wit.is_null()) |
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# Now create tx3, which will spend from txid2 |
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tx = CTransaction() |
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tx.vin.append(CTxIn(COutPoint(int(txid2, 16), 0), b"")) |
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tx.vout.append(CTxOut(int(49.95*COIN), CScript([OP_TRUE]))) # Huge fee |
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tx.calc_sha256() |
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txid3 = self.nodes[0].sendrawtransaction(ToHex(tx)) |
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assert(tx.wit.is_null()) |
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assert(txid3 in self.nodes[0].getrawmempool()) |
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# Now try calling getblocktemplate() without segwit support. |
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template = self.nodes[0].getblocktemplate() |
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# Check that tx1 is the only transaction of the 3 in the template. |
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template_txids = [ t['txid'] for t in template['transactions'] ] |
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assert(txid2 not in template_txids and txid3 not in template_txids) |
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assert(txid1 in template_txids) |
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# Check that running with segwit support results in all 3 being included. |
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template = self.nodes[0].getblocktemplate({"rules": ["segwit"]}) |
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template_txids = [ t['txid'] for t in template['transactions'] ] |
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assert(txid1 in template_txids) |
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assert(txid2 in template_txids) |
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assert(txid3 in template_txids) |
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# Check that wtxid is properly reported in mempool entry |
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assert_equal(int(self.nodes[0].getmempoolentry(txid3)["wtxid"], 16), tx.calc_sha256(True)) |
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# Mine a block to clear the gbt cache again. |
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self.nodes[0].generate(1) |
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self.log.info("Verify behaviour of importaddress, addwitnessaddress and listunspent") |
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# Some public keys to be used later |
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pubkeys = [ |
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"0363D44AABD0F1699138239DF2F042C3282C0671CC7A76826A55C8203D90E39242", # cPiM8Ub4heR9NBYmgVzJQiUH1if44GSBGiqaeJySuL2BKxubvgwb |
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"02D3E626B3E616FC8662B489C123349FECBFC611E778E5BE739B257EAE4721E5BF", # cPpAdHaD6VoYbW78kveN2bsvb45Q7G5PhaPApVUGwvF8VQ9brD97 |
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"04A47F2CBCEFFA7B9BCDA184E7D5668D3DA6F9079AD41E422FA5FD7B2D458F2538A62F5BD8EC85C2477F39650BD391EA6250207065B2A81DA8B009FC891E898F0E", # 91zqCU5B9sdWxzMt1ca3VzbtVm2YM6Hi5Rxn4UDtxEaN9C9nzXV |
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"02A47F2CBCEFFA7B9BCDA184E7D5668D3DA6F9079AD41E422FA5FD7B2D458F2538", # cPQFjcVRpAUBG8BA9hzr2yEzHwKoMgLkJZBBtK9vJnvGJgMjzTbd |
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"036722F784214129FEB9E8129D626324F3F6716555B603FFE8300BBCB882151228", # cQGtcm34xiLjB1v7bkRa4V3aAc9tS2UTuBZ1UnZGeSeNy627fN66 |
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"0266A8396EE936BF6D99D17920DB21C6C7B1AB14C639D5CD72B300297E416FD2EC", # cTW5mR5M45vHxXkeChZdtSPozrFwFgmEvTNnanCW6wrqwaCZ1X7K |
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"0450A38BD7F0AC212FEBA77354A9B036A32E0F7C81FC4E0C5ADCA7C549C4505D2522458C2D9AE3CEFD684E039194B72C8A10F9CB9D4764AB26FCC2718D421D3B84", # 92h2XPssjBpsJN5CqSP7v9a7cf2kgDunBC6PDFwJHMACM1rrVBJ |
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] |
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# Import a compressed key and an uncompressed key, generate some multisig addresses |
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self.nodes[0].importprivkey("92e6XLo5jVAVwrQKPNTs93oQco8f8sDNBcpv73Dsrs397fQtFQn") |
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uncompressed_spendable_address = ["mvozP4UwyGD2mGZU4D2eMvMLPB9WkMmMQu"] |
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self.nodes[0].importprivkey("cNC8eQ5dg3mFAVePDX4ddmPYpPbw41r9bm2jd1nLJT77e6RrzTRR") |
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compressed_spendable_address = ["mmWQubrDomqpgSYekvsU7HWEVjLFHAakLe"] |
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assert ((self.nodes[0].validateaddress(uncompressed_spendable_address[0])['iscompressed'] == False)) |
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assert ((self.nodes[0].validateaddress(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]])) |
|
uncompressed_spendable_address.append(self.nodes[0].addmultisigaddress(2, [uncompressed_spendable_address[0], uncompressed_spendable_address[0]])) |
|
compressed_spendable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_spendable_address[0], compressed_spendable_address[0]])) |
|
uncompressed_solvable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_spendable_address[0], uncompressed_solvable_address[0]])) |
|
compressed_solvable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_spendable_address[0], compressed_solvable_address[0]])) |
|
compressed_solvable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_solvable_address[0], compressed_solvable_address[1]])) |
|
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]]) |
|
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].validateaddress(i) |
|
if (v['isscript']): |
|
[bare, p2sh, p2wsh, p2sh_p2wsh] = self.p2sh_address_to_script(v) |
|
# bare and p2sh multisig with compressed keys should always be spendable |
|
spendable_anytime.extend([bare, p2sh]) |
|
# 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, and witness with compressed keys are spendable after direct importaddress |
|
spendable_after_importaddress.extend([p2wpkh, p2sh_p2wpkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh]) |
|
|
|
for i in uncompressed_spendable_address: |
|
v = self.nodes[0].validateaddress(i) |
|
if (v['isscript']): |
|
[bare, p2sh, p2wsh, p2sh_p2wsh] = self.p2sh_address_to_script(v) |
|
# bare and p2sh multisig with uncompressed keys should always be spendable |
|
spendable_anytime.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 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 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].validateaddress(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 and P2PK with compressed keys should always be seen |
|
solvable_anytime.extend([p2pkh, p2pk]) |
|
# P2SH_P2PK, P2SH_P2PKH, and witness with compressed keys are seen after direct importaddress |
|
solvable_after_importaddress.extend([p2wpkh, p2sh_p2wpkh, p2sh_p2pk, p2sh_p2pkh, p2wsh_p2pk, p2wsh_p2pkh, p2sh_p2wsh_p2pk, p2sh_p2wsh_p2pkh]) |
|
|
|
for i in uncompressed_solvable_address: |
|
v = self.nodes[0].validateaddress(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 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].validateaddress(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 |
|
|
|
uncompressed_spendable_address.append(self.nodes[0].addmultisigaddress(2, [uncompressed_spendable_address[0], compressed_spendable_address[0]])) |
|
uncompressed_spendable_address.append(self.nodes[0].addmultisigaddress(2, [uncompressed_spendable_address[0], uncompressed_spendable_address[0]])) |
|
compressed_spendable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_spendable_address[0], compressed_spendable_address[0]])) |
|
uncompressed_solvable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_solvable_address[0], uncompressed_solvable_address[0]])) |
|
compressed_solvable_address.append(self.nodes[0].addmultisigaddress(2, [compressed_spendable_address[0], compressed_solvable_address[0]])) |
|
|
|
premature_witaddress = [] |
|
|
|
for i in compressed_spendable_address: |
|
v = self.nodes[0].validateaddress(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 spendable after addwitnessaddress |
|
spendable_after_addwitnessaddress.extend([p2wpkh, p2sh_p2wpkh]) |
|
premature_witaddress.append(script_to_p2sh(p2wpkh)) |
|
|
|
for i in uncompressed_spendable_address + uncompressed_solvable_address: |
|
v = self.nodes[0].validateaddress(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].validateaddress(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 seen after addwitnessaddress |
|
solvable_after_addwitnessaddress.extend([p2wpkh, p2sh_p2wpkh]) |
|
premature_witaddress.append(script_to_p2sh(p2wpkh)) |
|
|
|
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].validateaddress(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, 2)) |
|
solvable_txid.append(self.mine_and_test_listunspent(solvable_after_addwitnessaddress, 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" |
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transaction = "01000000000100e1f5050000000017a9142f8c469c2f0084c48e11f998ffbe7efa7549f26d8700000000" |
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|
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self.nodes[1].importaddress(scriptPubKey, "", False) |
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rawtxfund = self.nodes[1].fundrawtransaction(transaction)['hex'] |
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rawtxfund = self.nodes[1].signrawtransaction(rawtxfund)["hex"] |
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txid = self.nodes[1].sendrawtransaction(rawtxfund) |
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|
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assert_equal(self.nodes[1].gettransaction(txid, True)["txid"], txid) |
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assert_equal(self.nodes[1].listtransactions("*", 1, 0, True)[0]["txid"], txid) |
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|
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# Assert it is properly saved |
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self.stop_node(1) |
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self.start_node(1) |
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assert_equal(self.nodes[1].gettransaction(txid, True)["txid"], txid) |
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assert_equal(self.nodes[1].listtransactions("*", 1, 0, True)[0]["txid"], txid) |
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|
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def mine_and_test_listunspent(self, script_list, ismine): |
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utxo = find_unspent(self.nodes[0], 50) |
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tx = CTransaction() |
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tx.vin.append(CTxIn(COutPoint(int('0x'+utxo['txid'],0), utxo['vout']))) |
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for i in script_list: |
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tx.vout.append(CTxOut(10000000, i)) |
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tx.rehash() |
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signresults = self.nodes[0].signrawtransaction(bytes_to_hex_str(tx.serialize_without_witness()))['hex'] |
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txid = self.nodes[0].sendrawtransaction(signresults, True) |
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self.nodes[0].generate(1) |
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sync_blocks(self.nodes) |
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watchcount = 0 |
|
spendcount = 0 |
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for i in self.nodes[0].listunspent(): |
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if (i['txid'] == txid): |
|
watchcount += 1 |
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if (i['spendable'] == True): |
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spendcount += 1 |
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if (ismine == 2): |
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assert_equal(spendcount, len(script_list)) |
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elif (ismine == 1): |
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assert_equal(watchcount, len(script_list)) |
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assert_equal(spendcount, 0) |
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else: |
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assert_equal(watchcount, 0) |
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return txid |
|
|
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def p2sh_address_to_script(self,v): |
|
bare = CScript(hex_str_to_bytes(v['hex'])) |
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p2sh = CScript(hex_str_to_bytes(v['scriptPubKey'])) |
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p2wsh = CScript([OP_0, sha256(bare)]) |
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p2sh_p2wsh = CScript([OP_HASH160, hash160(p2wsh), OP_EQUAL]) |
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return([bare, p2sh, p2wsh, p2sh_p2wsh]) |
|
|
|
def p2pkh_address_to_script(self,v): |
|
pubkey = hex_str_to_bytes(v['pubkey']) |
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p2wpkh = CScript([OP_0, hash160(pubkey)]) |
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p2sh_p2wpkh = CScript([OP_HASH160, hash160(p2wpkh), OP_EQUAL]) |
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p2pk = CScript([pubkey, OP_CHECKSIG]) |
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p2pkh = CScript(hex_str_to_bytes(v['scriptPubKey'])) |
|
p2sh_p2pk = CScript([OP_HASH160, hash160(p2pk), OP_EQUAL]) |
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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 create_and_mine_tx_from_txids(self, txids, success = True): |
|
tx = CTransaction() |
|
for i in txids: |
|
txtmp = CTransaction() |
|
txraw = self.nodes[0].getrawtransaction(i) |
|
f = BytesIO(hex_str_to_bytes(txraw)) |
|
txtmp.deserialize(f) |
|
for j in range(len(txtmp.vout)): |
|
tx.vin.append(CTxIn(COutPoint(int('0x'+i,0), j))) |
|
tx.vout.append(CTxOut(0, CScript())) |
|
tx.rehash() |
|
signresults = self.nodes[0].signrawtransaction(bytes_to_hex_str(tx.serialize_without_witness()))['hex'] |
|
self.nodes[0].sendrawtransaction(signresults, True) |
|
self.nodes[0].generate(1) |
|
sync_blocks(self.nodes) |
|
|
|
|
|
if __name__ == '__main__': |
|
SegWitTest().main()
|
|
|