dash/test/functional/p2p_invalid_tx.py
MarcoFalke e1497f67b2
Merge #13916: qa: wait_for_verack by default
fa5587fe71 qa: wait_for_verack by default (MarcoFalke)

Pull request description:

  This removes the need to do so manually every time a connection is added.

Tree-SHA512: a46c92cb4df41e30778b42b9fd3dcbd8d2d82aa7503d1213cb1c1165034f648d8caee01c292e2d87d05b0f71696996eef5be8a753f35ab49e5f66b0e3bf29f21
2021-07-06 20:29:31 +03:00

187 lines
8.3 KiB
Python
Executable File

#!/usr/bin/env python3
# Copyright (c) 2015-2016 The Bitcoin Core developers
# Distributed under the MIT software license, see the accompanying
# file COPYING or http://www.opensource.org/licenses/mit-license.php.
"""Test node responses to invalid transactions.
In this test we connect to one node over p2p, and test tx requests."""
from test_framework.blocktools import create_block, create_coinbase, create_transaction
from test_framework.mininode import (
COIN,
COutPoint,
CTransaction,
CTxIn,
CTxOut,
)
from test_framework.mininode import P2PDataStore
from test_framework.test_framework import BitcoinTestFramework
from test_framework.util import (
assert_equal,
wait_until,
)
class InvalidTxRequestTest(BitcoinTestFramework):
def set_test_params(self):
self.num_nodes = 1
self.setup_clean_chain = True
def bootstrap_p2p(self, *, num_connections=1):
"""Add a P2P connection to the node.
Helper to connect and wait for version handshake."""
for _ in range(num_connections):
self.nodes[0].add_p2p_connection(P2PDataStore())
def reconnect_p2p(self, **kwargs):
"""Tear down and bootstrap the P2P connection to the node.
The node gets disconnected several times in this test. This helper
method reconnects the p2p and restarts the network thread."""
self.nodes[0].disconnect_p2ps()
self.bootstrap_p2p(**kwargs)
def run_test(self):
node = self.nodes[0] # convenience reference to the node
self.bootstrap_p2p() # Add one p2p connection to the node
best_block = self.nodes[0].getbestblockhash()
tip = int(best_block, 16)
best_block_time = self.nodes[0].getblock(best_block)['time']
block_time = best_block_time + 1
self.log.info("Create a new block with an anyone-can-spend coinbase.")
height = 1
block = create_block(tip, create_coinbase(height), block_time)
block.solve()
# Save the coinbase for later
block1 = block
tip = block.sha256
# Create a second one to test orphan resolution via block receival
height += 1
block_time += 1
block = create_block(tip, create_coinbase(height), block_time)
block.solve()
# Save the coinbase for later
block2 = block
tip = block.sha256
node.p2p.send_blocks_and_test([block1, block2], node, success=True)
self.log.info("Mature the block.")
self.nodes[0].generate(100)
# b'\x64' is OP_NOTIF
# Transaction will be rejected with code 16 (REJECT_INVALID)
# and we get disconnected immediately
self.log.info('Test a transaction that is rejected')
tx1 = create_transaction(block1.vtx[0], 0, b'\x64' * 35, 50 * COIN)
node.p2p.send_txs_and_test([tx1], node, success=False, expect_disconnect=True)
# Make two p2p connections to provide the node with orphans
# * p2ps[0] will send valid orphan txs (one with low fee)
# * p2ps[1] will send an invalid orphan tx (and is later disconnected for that)
self.reconnect_p2p(num_connections=2)
self.log.info('Test orphan transaction handling ... ')
self.test_orphan_tx_handling(block1.vtx[0].sha256, False)
# restart node with sending BIP61 messages disabled, check that it disconnects without sending the reject message
self.log.info('Test a transaction that is rejected, with BIP61 disabled')
self.restart_node(0, ['-enablebip61=0', '-persistmempool=0'])
self.reconnect_p2p(num_connections=1)
with node.assert_debug_log(expected_msgs=[
"{} from peer=0 was not accepted: mandatory-script-verify-flag-failed (Invalid OP_IF construction) (code 16)".format(tx1.hash),
"disconnecting peer=0",
]):
node.p2p.send_txs_and_test([tx1], node, success=False, expect_disconnect=True)
# send_txs_and_test will have waited for disconnect, so we can safely check that no reject has been received
assert_equal(node.p2p.reject_code_received, None)
self.log.info('Test orphan transaction handling, resolve via block')
self.restart_node(0, ['-persistmempool=0'])
self.reconnect_p2p(num_connections=2)
self.test_orphan_tx_handling(block2.vtx[0].sha256, True)
def test_orphan_tx_handling(self, base_tx, resolve_via_block):
node = self.nodes[0] # convenience reference to the node
# Create a root transaction that we withold until all dependend transactions
# are sent out and in the orphan cache
SCRIPT_PUB_KEY_OP_TRUE = b'\x51\x75' * 15 + b'\x51'
tx_withhold = CTransaction()
tx_withhold.vin.append(CTxIn(outpoint=COutPoint(base_tx, 0)))
tx_withhold.vout.append(CTxOut(nValue=50 * COIN - 12000, scriptPubKey=SCRIPT_PUB_KEY_OP_TRUE))
tx_withhold.calc_sha256()
# Our first orphan tx with some outputs to create further orphan txs
tx_orphan_1 = CTransaction()
tx_orphan_1.vin.append(CTxIn(outpoint=COutPoint(tx_withhold.sha256, 0)))
tx_orphan_1.vout = [CTxOut(nValue=10 * COIN, scriptPubKey=SCRIPT_PUB_KEY_OP_TRUE)] * 3
tx_orphan_1.calc_sha256()
# A valid transaction with low fee
tx_orphan_2_no_fee = CTransaction()
tx_orphan_2_no_fee.vin.append(CTxIn(outpoint=COutPoint(tx_orphan_1.sha256, 0)))
tx_orphan_2_no_fee.vout.append(CTxOut(nValue=10 * COIN, scriptPubKey=SCRIPT_PUB_KEY_OP_TRUE))
# A valid transaction with sufficient fee
tx_orphan_2_valid = CTransaction()
tx_orphan_2_valid.vin.append(CTxIn(outpoint=COutPoint(tx_orphan_1.sha256, 1)))
tx_orphan_2_valid.vout.append(CTxOut(nValue=10 * COIN - 12000, scriptPubKey=SCRIPT_PUB_KEY_OP_TRUE))
tx_orphan_2_valid.calc_sha256()
# An invalid transaction with negative fee
tx_orphan_2_invalid = CTransaction()
tx_orphan_2_invalid.vin.append(CTxIn(outpoint=COutPoint(tx_orphan_1.sha256, 2)))
tx_orphan_2_invalid.vout.append(CTxOut(nValue=11 * COIN, scriptPubKey=SCRIPT_PUB_KEY_OP_TRUE))
self.log.info('Send the orphans ... ')
# Send valid orphan txs from p2ps[0]
node.p2p.send_txs_and_test([tx_orphan_1, tx_orphan_2_no_fee, tx_orphan_2_valid], node, success=False)
# Send invalid tx from p2ps[1]
node.p2ps[1].send_txs_and_test([tx_orphan_2_invalid], node, success=False)
assert_equal(0, node.getmempoolinfo()['size']) # Mempool should be empty
assert_equal(2, len(node.getpeerinfo())) # p2ps[1] is still connected
self.log.info('Send the withhold tx ... ')
if resolve_via_block:
# Test orphan handling/resolution by publishing the withhold TX via a mined block
prev_block = node.getblockheader(node.getbestblockhash())
block = create_block(int(prev_block['hash'], 16), create_coinbase(prev_block['height'] + 1), prev_block["time"] + 1)
block.vtx.append(tx_withhold)
block.hashMerkleRoot = block.calc_merkle_root()
block.solve()
node.p2p.send_blocks_and_test([block], node, success=True)
else:
# Test orphan handling/resolution by publishing the withhold TX via the mempool
node.p2p.send_txs_and_test([tx_withhold], node, success=True)
# Transactions that should end up in the mempool
expected_mempool = {
t.hash
for t in [
tx_withhold, # The transaction that is the root for all orphans
tx_orphan_1, # The orphan transaction that splits the coins
tx_orphan_2_valid, # The valid transaction (with sufficient fee)
]
}
# Transactions that do not end up in the mempool
# tx_orphan_no_fee, because it has too low fee (p2ps[0] is not disconnected for relaying that tx)
# tx_orphan_invaid, because it has negative fee (p2ps[1] is disconnected for relaying that tx)
if resolve_via_block:
# This TX has appeared in a block instead of being broadcasted via the mempool
expected_mempool.remove(tx_withhold.hash)
wait_until(lambda: 1 == len(node.getpeerinfo()), timeout=12) # p2ps[1] is no longer connected
assert_equal(expected_mempool, set(node.getrawmempool()))
if __name__ == '__main__':
InvalidTxRequestTest().main()