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f4ba2bb769
The flag fDIP0001ActiveAtTip shows a status of activation of DIP0001 This flag is used currently only in net.cpp for setup block buffer size. Assume the bigger by default so far as DIP0001 is activated years ago
353 lines
16 KiB
Python
Executable File
353 lines
16 KiB
Python
Executable File
#!/usr/bin/env python3
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# Copyright (c) 2017-2020 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 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.key import ECKey
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from test_framework.messages import (
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BIP125_SEQUENCE_NUMBER,
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COIN,
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COutPoint,
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CTxIn,
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CTxOut,
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MAX_BLOCK_SIZE,
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MAX_MONEY,
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tx_from_hex,
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)
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from test_framework.script import (
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hash160,
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CScript,
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OP_0,
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OP_2,
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OP_3,
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OP_CHECKMULTISIG,
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OP_EQUAL,
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OP_HASH160,
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OP_RETURN,
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)
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from test_framework.util import (
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assert_equal,
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assert_raises_rpc_error,
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)
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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', '-testactivationheight=dip0001@2000',
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]] * self.num_nodes
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self.supports_cli = False
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def skip_test_if_missing_module(self):
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self.skip_if_no_wallet()
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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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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.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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coins = node.listunspent()
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self.log.info('Should not accept garbage to testmempoolaccept')
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assert_raises_rpc_error(-3, 'Expected type array, got string', 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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coin = coins.pop() # Pick a random coin(base) to spend
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raw_tx_in_block = node.signrawtransactionwithwallet(node.createrawtransaction(
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inputs=[{'txid': coin['txid'], 'vout': coin['vout']}],
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outputs=[{node.getnewaddress(): 0.3}, {node.getnewaddress(): 49}],
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))['hex']
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txid_in_block = node.sendrawtransaction(hexstring=raw_tx_in_block, maxfeerate=0)
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node.generate(1)
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self.mempool_size = 0
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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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)
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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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raw_tx_0 = node.signrawtransactionwithwallet(node.createrawtransaction(
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inputs=[{"txid": txid_in_block, "vout": 0, "sequence": BIP125_SEQUENCE_NUMBER}], # RBF is used later
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outputs=[{node.getnewaddress(): Decimal('0.3') - fee}],
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))['hex']
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tx = tx_from_hex(raw_tx_0)
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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': Decimal(str(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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coin = coins.pop() # Pick a random coin(base) to spend
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output_amount = 0.025
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raw_tx_final = node.signrawtransactionwithwallet(node.createrawtransaction(
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inputs=[{'txid': coin['txid'], 'vout': coin['vout'], "sequence": 0xffffffff}], # SEQUENCE_FINAL
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outputs=[{node.getnewaddress(): output_amount}],
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locktime=node.getblockcount() + 2000, # Can be anything
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))['hex']
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fee_expected = int(coin['amount']) - output_amount
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tx = tx_from_hex(raw_tx_final)
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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(str(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 = BIP125_SEQUENCE_NUMBER + 1 # Now, opt out of RBF
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raw_tx_0_reject = node.signrawtransactionwithwallet(tx.serialize().hex())['hex']
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tx = tx_from_hex(raw_tx_0_reject)
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txid_0_reject = tx.rehash()
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self.check_mempool_result(
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# No RBF in DASH
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result_expected=[{'txid': txid_0_reject, 'allowed': False, 'reject-reason': 'txn-mempool-conflict'}],
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rawtxs=[raw_tx_0_reject],
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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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# skip re-signing the tx
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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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# skip re-signing the tx
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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 = node.signrawtransactionwithwallet(tx.serialize().hex())['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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raw_tx_spend_both = node.signrawtransactionwithwallet(node.createrawtransaction(
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inputs=[
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{'txid': txid_0, 'vout': 0},
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{'txid': txid_1, 'vout': 0},
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],
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outputs=[{node.getnewaddress(): 0.1}]
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))['hex']
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txid_spend_both = node.sendrawtransaction(hexstring=raw_tx_spend_both, maxfeerate=0)
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node.generate(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 signed "reference" tx for later use')
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raw_tx_reference = node.signrawtransactionwithwallet(node.createrawtransaction(
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inputs=[{'txid': txid_spend_both, 'vout': 0}],
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outputs=[{node.getnewaddress(): 0.05}],
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))['hex']
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tx = tx_from_hex(raw_tx_reference)
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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(str(0.1 - 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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# Skip re-signing the transaction for context independent checks from now on
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# tx = tx_from_hex(node.signrawtransactionwithwallet(tx.serialize().hex())['hex'])
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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_SIZE / 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 signed, 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 = 4 # 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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key = ECKey()
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key.generate()
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pubkey = key.get_pubkey().get_bytes()
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tx.vout[0].scriptPubKey = CScript([OP_2, pubkey, pubkey, pubkey, OP_3, OP_CHECKMULTISIG]) # 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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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=CScript([OP_HASH160, hash160(b'burn'), OP_EQUAL]))
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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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# Can skip re-signing the tx because of early rejection
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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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if __name__ == '__main__':
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MempoolAcceptanceTest().main()
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