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412 lines
19 KiB
412 lines
19 KiB
#!/usr/bin/env python3
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# Copyright (c) 2017-2022 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 mempool acceptance of raw transactions."""
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from copy import deepcopy
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from decimal import Decimal
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import math
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from test_framework.test_framework import BitcoinTestFramework
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from test_framework.messages import (
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MAX_BIP125_RBF_SEQUENCE,
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COIN,
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COutPoint,
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CTransaction,
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CTxIn,
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CTxInWitness,
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CTxOut,
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MAX_BLOCK_WEIGHT,
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MAX_MONEY,
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SEQUENCE_FINAL,
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tx_from_hex,
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)
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from test_framework.script import (
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CScript,
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OP_0,
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OP_HASH160,
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OP_RETURN,
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OP_TRUE,
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SIGHASH_ALL,
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sign_input_legacy,
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)
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from test_framework.script_util import (
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DUMMY_MIN_OP_RETURN_SCRIPT,
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keys_to_multisig_script,
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MIN_PADDING,
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MIN_STANDARD_TX_NONWITNESS_SIZE,
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script_to_p2sh_script,
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script_to_p2wsh_script,
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)
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from test_framework.util import (
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assert_equal,
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assert_greater_than,
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assert_raises_rpc_error,
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)
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from test_framework.wallet import MiniWallet
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from test_framework.wallet_util import generate_keypair
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class MempoolAcceptanceTest(BitcoinTestFramework):
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def set_test_params(self):
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self.num_nodes = 1
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self.extra_args = [[
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'-txindex','-permitbaremultisig=0',
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]] * self.num_nodes
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self.supports_cli = False
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def check_mempool_result(self, result_expected, *args, **kwargs):
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"""Wrapper to check result of testmempoolaccept on node_0's mempool"""
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result_test = self.nodes[0].testmempoolaccept(*args, **kwargs)
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for r in result_test:
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# Skip these checks for now
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r.pop('wtxid')
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if "fees" in r:
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r["fees"].pop("effective-feerate")
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r["fees"].pop("effective-includes")
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assert_equal(result_expected, result_test)
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assert_equal(self.nodes[0].getmempoolinfo()['size'], self.mempool_size) # Must not change mempool state
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def run_test(self):
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node = self.nodes[0]
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self.wallet = MiniWallet(node)
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self.log.info('Start with empty mempool, and 200 blocks')
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self.mempool_size = 0
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assert_equal(node.getblockcount(), 200)
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assert_equal(node.getmempoolinfo()['size'], self.mempool_size)
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self.log.info('Should not accept garbage to testmempoolaccept')
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assert_raises_rpc_error(-3, 'JSON value of type string is not of expected type array', lambda: node.testmempoolaccept(rawtxs='ff00baar'))
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assert_raises_rpc_error(-8, 'Array must contain between 1 and 25 transactions.', lambda: node.testmempoolaccept(rawtxs=['ff22']*26))
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assert_raises_rpc_error(-8, 'Array must contain between 1 and 25 transactions.', lambda: node.testmempoolaccept(rawtxs=[]))
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assert_raises_rpc_error(-22, 'TX decode failed', lambda: node.testmempoolaccept(rawtxs=['ff00baar']))
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self.log.info('A transaction already in the blockchain')
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tx = self.wallet.create_self_transfer()['tx'] # Pick a random coin(base) to spend
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tx.vout.append(deepcopy(tx.vout[0]))
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tx.vout[0].nValue = int(0.3 * COIN)
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tx.vout[1].nValue = int(49 * COIN)
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raw_tx_in_block = tx.serialize().hex()
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txid_in_block = self.wallet.sendrawtransaction(from_node=node, tx_hex=raw_tx_in_block)
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self.generate(node, 1)
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self.mempool_size = 0
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# Also check feerate. 1BTC/kvB fails
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assert_raises_rpc_error(-8, "Fee rates larger than or equal to 1BTC/kvB are not accepted", lambda: self.check_mempool_result(
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result_expected=None,
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rawtxs=[raw_tx_in_block],
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maxfeerate=1,
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))
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# Check negative feerate
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assert_raises_rpc_error(-3, "Amount out of range", lambda: self.check_mempool_result(
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result_expected=None,
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rawtxs=[raw_tx_in_block],
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maxfeerate=-0.01,
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))
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# ... 0.99 passes
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self.check_mempool_result(
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result_expected=[{'txid': txid_in_block, 'allowed': False, 'reject-reason': 'txn-already-known'}],
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rawtxs=[raw_tx_in_block],
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maxfeerate=0.99,
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)
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self.log.info('A transaction not in the mempool')
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fee = Decimal('0.000007')
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utxo_to_spend = self.wallet.get_utxo(txid=txid_in_block) # use 0.3 BTC UTXO
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tx = self.wallet.create_self_transfer(utxo_to_spend=utxo_to_spend, sequence=MAX_BIP125_RBF_SEQUENCE)['tx']
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tx.vout[0].nValue = int((Decimal('0.3') - fee) * COIN)
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raw_tx_0 = tx.serialize().hex()
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txid_0 = tx.rehash()
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self.check_mempool_result(
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result_expected=[{'txid': txid_0, 'allowed': True, 'vsize': tx.get_vsize(), 'fees': {'base': fee}}],
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rawtxs=[raw_tx_0],
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)
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self.log.info('A final transaction not in the mempool')
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output_amount = Decimal('0.025')
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tx = self.wallet.create_self_transfer(
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sequence=SEQUENCE_FINAL,
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locktime=node.getblockcount() + 2000, # Can be anything
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)['tx']
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tx.vout[0].nValue = int(output_amount * COIN)
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raw_tx_final = tx.serialize().hex()
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tx = tx_from_hex(raw_tx_final)
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fee_expected = Decimal('50.0') - output_amount
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self.check_mempool_result(
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result_expected=[{'txid': tx.rehash(), 'allowed': True, 'vsize': tx.get_vsize(), 'fees': {'base': fee_expected}}],
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rawtxs=[tx.serialize().hex()],
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maxfeerate=0,
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)
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node.sendrawtransaction(hexstring=raw_tx_final, maxfeerate=0)
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self.mempool_size += 1
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self.log.info('A transaction in the mempool')
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node.sendrawtransaction(hexstring=raw_tx_0)
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self.mempool_size += 1
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self.check_mempool_result(
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result_expected=[{'txid': txid_0, 'allowed': False, 'reject-reason': 'txn-already-in-mempool'}],
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rawtxs=[raw_tx_0],
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)
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self.log.info('A transaction that replaces a mempool transaction')
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tx = tx_from_hex(raw_tx_0)
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tx.vout[0].nValue -= int(fee * COIN) # Double the fee
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tx.vin[0].nSequence = MAX_BIP125_RBF_SEQUENCE + 1 # Now, opt out of RBF
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raw_tx_0 = tx.serialize().hex()
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txid_0 = tx.rehash()
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self.check_mempool_result(
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result_expected=[{'txid': txid_0, 'allowed': True, 'vsize': tx.get_vsize(), 'fees': {'base': (2 * fee)}}],
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rawtxs=[raw_tx_0],
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)
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self.log.info('A transaction that conflicts with an unconfirmed tx')
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# Send the transaction that replaces the mempool transaction and opts out of replaceability
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node.sendrawtransaction(hexstring=tx.serialize().hex(), maxfeerate=0)
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# take original raw_tx_0
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tx = tx_from_hex(raw_tx_0)
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tx.vout[0].nValue -= int(4 * fee * COIN) # Set more fee
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self.check_mempool_result(
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result_expected=[{'txid': tx.rehash(), 'allowed': False, 'reject-reason': 'txn-mempool-conflict'}],
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rawtxs=[tx.serialize().hex()],
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maxfeerate=0,
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)
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self.log.info('A transaction with missing inputs, that never existed')
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tx = tx_from_hex(raw_tx_0)
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tx.vin[0].prevout = COutPoint(hash=int('ff' * 32, 16), n=14)
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self.check_mempool_result(
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result_expected=[{'txid': tx.rehash(), 'allowed': False, 'reject-reason': 'missing-inputs'}],
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rawtxs=[tx.serialize().hex()],
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)
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self.log.info('A transaction with missing inputs, that existed once in the past')
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tx = tx_from_hex(raw_tx_0)
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tx.vin[0].prevout.n = 1 # Set vout to 1, to spend the other outpoint (49 coins) of the in-chain-tx we want to double spend
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raw_tx_1 = tx.serialize().hex()
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txid_1 = node.sendrawtransaction(hexstring=raw_tx_1, maxfeerate=0)
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# Now spend both to "clearly hide" the outputs, ie. remove the coins from the utxo set by spending them
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tx = self.wallet.create_self_transfer()['tx']
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tx.vin.append(deepcopy(tx.vin[0]))
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tx.wit.vtxinwit.append(deepcopy(tx.wit.vtxinwit[0]))
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tx.vin[0].prevout = COutPoint(hash=int(txid_0, 16), n=0)
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tx.vin[1].prevout = COutPoint(hash=int(txid_1, 16), n=0)
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tx.vout[0].nValue = int(0.1 * COIN)
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raw_tx_spend_both = tx.serialize().hex()
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txid_spend_both = self.wallet.sendrawtransaction(from_node=node, tx_hex=raw_tx_spend_both)
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self.generate(node, 1)
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self.mempool_size = 0
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# Now see if we can add the coins back to the utxo set by sending the exact txs again
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self.check_mempool_result(
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result_expected=[{'txid': txid_0, 'allowed': False, 'reject-reason': 'missing-inputs'}],
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rawtxs=[raw_tx_0],
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)
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self.check_mempool_result(
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result_expected=[{'txid': txid_1, 'allowed': False, 'reject-reason': 'missing-inputs'}],
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rawtxs=[raw_tx_1],
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)
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self.log.info('Create a "reference" tx for later use')
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utxo_to_spend = self.wallet.get_utxo(txid=txid_spend_both)
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tx = self.wallet.create_self_transfer(utxo_to_spend=utxo_to_spend, sequence=SEQUENCE_FINAL)['tx']
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tx.vout[0].nValue = int(0.05 * COIN)
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raw_tx_reference = tx.serialize().hex()
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# Reference tx should be valid on itself
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self.check_mempool_result(
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result_expected=[{'txid': tx.rehash(), 'allowed': True, 'vsize': tx.get_vsize(), 'fees': { 'base': Decimal('0.1') - Decimal('0.05')}}],
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rawtxs=[tx.serialize().hex()],
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maxfeerate=0,
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)
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self.log.info('A transaction with no outputs')
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tx = tx_from_hex(raw_tx_reference)
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tx.vout = []
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self.check_mempool_result(
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result_expected=[{'txid': tx.rehash(), 'allowed': False, 'reject-reason': 'bad-txns-vout-empty'}],
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rawtxs=[tx.serialize().hex()],
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)
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self.log.info('A really large transaction')
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tx = tx_from_hex(raw_tx_reference)
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tx.vin = [tx.vin[0]] * math.ceil(MAX_BLOCK_WEIGHT // 4 / len(tx.vin[0].serialize()))
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self.check_mempool_result(
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result_expected=[{'txid': tx.rehash(), 'allowed': False, 'reject-reason': 'bad-txns-oversize'}],
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rawtxs=[tx.serialize().hex()],
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)
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self.log.info('A transaction with negative output value')
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tx = tx_from_hex(raw_tx_reference)
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tx.vout[0].nValue *= -1
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self.check_mempool_result(
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result_expected=[{'txid': tx.rehash(), 'allowed': False, 'reject-reason': 'bad-txns-vout-negative'}],
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rawtxs=[tx.serialize().hex()],
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)
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# The following two validations prevent overflow of the output amounts (see CVE-2010-5139).
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self.log.info('A transaction with too large output value')
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tx = tx_from_hex(raw_tx_reference)
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tx.vout[0].nValue = MAX_MONEY + 1
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self.check_mempool_result(
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result_expected=[{'txid': tx.rehash(), 'allowed': False, 'reject-reason': 'bad-txns-vout-toolarge'}],
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rawtxs=[tx.serialize().hex()],
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)
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self.log.info('A transaction with too large sum of output values')
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tx = tx_from_hex(raw_tx_reference)
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tx.vout = [tx.vout[0]] * 2
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tx.vout[0].nValue = MAX_MONEY
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self.check_mempool_result(
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result_expected=[{'txid': tx.rehash(), 'allowed': False, 'reject-reason': 'bad-txns-txouttotal-toolarge'}],
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rawtxs=[tx.serialize().hex()],
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)
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self.log.info('A transaction with duplicate inputs')
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tx = tx_from_hex(raw_tx_reference)
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tx.vin = [tx.vin[0]] * 2
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self.check_mempool_result(
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result_expected=[{'txid': tx.rehash(), 'allowed': False, 'reject-reason': 'bad-txns-inputs-duplicate'}],
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rawtxs=[tx.serialize().hex()],
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)
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self.log.info('A non-coinbase transaction with coinbase-like outpoint')
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tx = tx_from_hex(raw_tx_reference)
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tx.vin.append(CTxIn(COutPoint(hash=0, n=0xffffffff)))
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self.check_mempool_result(
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result_expected=[{'txid': tx.rehash(), 'allowed': False, 'reject-reason': 'bad-txns-prevout-null'}],
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rawtxs=[tx.serialize().hex()],
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)
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self.log.info('A coinbase transaction')
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# Pick the input of the first tx we created, so it has to be a coinbase tx
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raw_tx_coinbase_spent = node.getrawtransaction(txid=node.decoderawtransaction(hexstring=raw_tx_in_block)['vin'][0]['txid'])
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tx = tx_from_hex(raw_tx_coinbase_spent)
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self.check_mempool_result(
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result_expected=[{'txid': tx.rehash(), 'allowed': False, 'reject-reason': 'coinbase'}],
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rawtxs=[tx.serialize().hex()],
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)
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self.log.info('Some nonstandard transactions')
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tx = tx_from_hex(raw_tx_reference)
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tx.nVersion = 3 # A version currently non-standard
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self.check_mempool_result(
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result_expected=[{'txid': tx.rehash(), 'allowed': False, 'reject-reason': 'version'}],
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rawtxs=[tx.serialize().hex()],
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)
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tx = tx_from_hex(raw_tx_reference)
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tx.vout[0].scriptPubKey = CScript([OP_0]) # Some non-standard script
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self.check_mempool_result(
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result_expected=[{'txid': tx.rehash(), 'allowed': False, 'reject-reason': 'scriptpubkey'}],
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rawtxs=[tx.serialize().hex()],
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)
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tx = tx_from_hex(raw_tx_reference)
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_, pubkey = generate_keypair()
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tx.vout[0].scriptPubKey = keys_to_multisig_script([pubkey] * 3, k=2) # Some bare multisig script (2-of-3)
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self.check_mempool_result(
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result_expected=[{'txid': tx.rehash(), 'allowed': False, 'reject-reason': 'bare-multisig'}],
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rawtxs=[tx.serialize().hex()],
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)
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tx = tx_from_hex(raw_tx_reference)
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tx.vin[0].scriptSig = CScript([OP_HASH160]) # Some not-pushonly scriptSig
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self.check_mempool_result(
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result_expected=[{'txid': tx.rehash(), 'allowed': False, 'reject-reason': 'scriptsig-not-pushonly'}],
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rawtxs=[tx.serialize().hex()],
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)
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tx = tx_from_hex(raw_tx_reference)
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tx.vin[0].scriptSig = CScript([b'a' * 1648]) # Some too large scriptSig (>1650 bytes)
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self.check_mempool_result(
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result_expected=[{'txid': tx.rehash(), 'allowed': False, 'reject-reason': 'scriptsig-size'}],
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rawtxs=[tx.serialize().hex()],
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)
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tx = tx_from_hex(raw_tx_reference)
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output_p2sh_burn = CTxOut(nValue=540, scriptPubKey=script_to_p2sh_script(b'burn'))
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num_scripts = 100000 // len(output_p2sh_burn.serialize()) # Use enough outputs to make the tx too large for our policy
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tx.vout = [output_p2sh_burn] * num_scripts
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self.check_mempool_result(
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result_expected=[{'txid': tx.rehash(), 'allowed': False, 'reject-reason': 'tx-size'}],
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rawtxs=[tx.serialize().hex()],
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)
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tx = tx_from_hex(raw_tx_reference)
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tx.vout[0] = output_p2sh_burn
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tx.vout[0].nValue -= 1 # Make output smaller, such that it is dust for our policy
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self.check_mempool_result(
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result_expected=[{'txid': tx.rehash(), 'allowed': False, 'reject-reason': 'dust'}],
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rawtxs=[tx.serialize().hex()],
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)
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tx = tx_from_hex(raw_tx_reference)
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tx.vout[0].scriptPubKey = CScript([OP_RETURN, b'\xff'])
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tx.vout = [tx.vout[0]] * 2
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self.check_mempool_result(
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result_expected=[{'txid': tx.rehash(), 'allowed': False, 'reject-reason': 'multi-op-return'}],
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rawtxs=[tx.serialize().hex()],
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)
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self.log.info('A timelocked transaction')
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tx = tx_from_hex(raw_tx_reference)
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tx.vin[0].nSequence -= 1 # Should be non-max, so locktime is not ignored
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tx.nLockTime = node.getblockcount() + 1
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self.check_mempool_result(
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result_expected=[{'txid': tx.rehash(), 'allowed': False, 'reject-reason': 'non-final'}],
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rawtxs=[tx.serialize().hex()],
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)
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self.log.info('A transaction that is locked by BIP68 sequence logic')
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tx = tx_from_hex(raw_tx_reference)
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tx.vin[0].nSequence = 2 # We could include it in the second block mined from now, but not the very next one
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self.check_mempool_result(
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result_expected=[{'txid': tx.rehash(), 'allowed': False, 'reject-reason': 'non-BIP68-final'}],
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rawtxs=[tx.serialize().hex()],
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maxfeerate=0,
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)
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# Prep for tiny-tx tests with wsh(OP_TRUE) output
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seed_tx = self.wallet.send_to(from_node=node, scriptPubKey=script_to_p2wsh_script(CScript([OP_TRUE])), amount=COIN)
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self.generate(node, 1)
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self.log.info('A tiny transaction(in non-witness bytes) that is disallowed')
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tx = CTransaction()
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tx.vin.append(CTxIn(COutPoint(int(seed_tx["txid"], 16), seed_tx["sent_vout"]), b"", SEQUENCE_FINAL))
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tx.wit.vtxinwit = [CTxInWitness()]
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tx.wit.vtxinwit[0].scriptWitness.stack = [CScript([OP_TRUE])]
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tx.vout.append(CTxOut(0, CScript([OP_RETURN] + ([OP_0] * (MIN_PADDING - 2)))))
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# Note it's only non-witness size that matters!
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assert_equal(len(tx.serialize_without_witness()), 64)
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assert_equal(MIN_STANDARD_TX_NONWITNESS_SIZE - 1, 64)
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assert_greater_than(len(tx.serialize()), 64)
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self.check_mempool_result(
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result_expected=[{'txid': tx.rehash(), 'allowed': False, 'reject-reason': 'tx-size-small'}],
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rawtxs=[tx.serialize().hex()],
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maxfeerate=0,
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)
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self.log.info('Minimally-small transaction(in non-witness bytes) that is allowed')
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tx.vout[0] = CTxOut(COIN - 1000, DUMMY_MIN_OP_RETURN_SCRIPT)
|
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assert_equal(len(tx.serialize_without_witness()), MIN_STANDARD_TX_NONWITNESS_SIZE)
|
|
self.check_mempool_result(
|
|
result_expected=[{'txid': tx.rehash(), 'allowed': True, 'vsize': tx.get_vsize(), 'fees': { 'base': Decimal('0.00001000')}}],
|
|
rawtxs=[tx.serialize().hex()],
|
|
maxfeerate=0,
|
|
)
|
|
|
|
self.log.info('Spending a confirmed bare multisig is okay')
|
|
address = self.wallet.get_address()
|
|
tx = tx_from_hex(raw_tx_reference)
|
|
privkey, pubkey = generate_keypair()
|
|
tx.vout[0].scriptPubKey = keys_to_multisig_script([pubkey] * 3, k=1) # Some bare multisig script (1-of-3)
|
|
tx.rehash()
|
|
self.generateblock(node, address, [tx.serialize().hex()])
|
|
tx_spend = CTransaction()
|
|
tx_spend.vin.append(CTxIn(COutPoint(tx.sha256, 0), b""))
|
|
tx_spend.vout.append(CTxOut(tx.vout[0].nValue - int(fee*COIN), script_to_p2wsh_script(CScript([OP_TRUE]))))
|
|
tx_spend.rehash()
|
|
sign_input_legacy(tx_spend, 0, tx.vout[0].scriptPubKey, privkey, sighash_type=SIGHASH_ALL)
|
|
tx_spend.vin[0].scriptSig = bytes(CScript([OP_0])) + tx_spend.vin[0].scriptSig
|
|
self.check_mempool_result(
|
|
result_expected=[{'txid': tx_spend.rehash(), 'allowed': True, 'vsize': tx_spend.get_vsize(), 'fees': { 'base': Decimal('0.00000700')}}],
|
|
rawtxs=[tx_spend.serialize().hex()],
|
|
maxfeerate=0,
|
|
)
|
|
|
|
if __name__ == '__main__':
|
|
MempoolAcceptanceTest().main()
|