dash/test/functional/interface_zmq_dash.py
UdjinM6 687aece098
Harden DIP0008 activation (#3889)
* Harden DIP0008 activation

* Update src/llmq/quorums_instantsend.cpp

Co-authored-by: dustinface <35775977+xdustinface@users.noreply.github.com>

* Update test/functional/test_framework/test_framework.py

Co-authored-by: PastaPastaPasta <6443210+PastaPastaPasta@users.noreply.github.com>

Co-authored-by: dustinface <35775977+xdustinface@users.noreply.github.com>
Co-authored-by: PastaPastaPasta <6443210+PastaPastaPasta@users.noreply.github.com>
2020-12-28 12:21:01 +01:00

388 lines
18 KiB
Python
Executable File

#!/usr/bin/env python3
# Copyright (c) 2018-2020 The Dash Core developers
# Distributed under the MIT software license, see the accompanying
# file COPYING or http://www.opensource.org/licenses/mit-license.php.
"""Test the dash specific ZMQ notification interfaces."""
import configparser
from enum import Enum
import io
import json
import random
import struct
import time
try:
import zmq
finally:
pass
from test_framework.test_framework import (
DashTestFramework, skip_if_no_bitcoind_zmq, skip_if_no_py3_zmq)
from test_framework.mininode import P2PInterface, network_thread_start
from test_framework.util import assert_equal, assert_raises_rpc_error, bytes_to_hex_str
from test_framework.messages import (
CBlock,
CGovernanceObject,
CGovernanceVote,
CInv,
COutPoint,
CRecoveredSig,
CTransaction,
FromHex,
hash256,
msg_clsig,
msg_inv,
msg_islock,
msg_tx,
ser_string,
uint256_from_str,
uint256_to_string
)
class ZMQPublisher(Enum):
hash_chain_lock = "hashchainlock"
hash_tx_lock = "hashtxlock"
hash_governance_vote = "hashgovernancevote"
hash_governance_object = "hashgovernanceobject"
hash_instantsend_doublespend = "hashinstantsenddoublespend"
hash_recovered_sig = "hashrecoveredsig"
raw_chain_lock = "rawchainlock"
raw_chain_lock_sig = "rawchainlocksig"
raw_tx_lock = "rawtxlock"
raw_tx_lock_sig = "rawtxlocksig"
raw_governance_vote = "rawgovernancevote"
raw_governance_object = "rawgovernanceobject"
raw_instantsend_doublespend = "rawinstantsenddoublespend"
raw_recovered_sig = "rawrecoveredsig"
class TestP2PConn(P2PInterface):
def __init__(self):
super().__init__()
self.islocks = {}
self.txes = {}
def send_islock(self, islock):
hash = uint256_from_str(hash256(islock.serialize()))
self.islocks[hash] = islock
inv = msg_inv([CInv(30, hash)])
self.send_message(inv)
def send_tx(self, tx):
hash = uint256_from_str(hash256(tx.serialize()))
self.txes[hash] = tx
inv = msg_inv([CInv(30, hash)])
self.send_message(inv)
def on_getdata(self, message):
for inv in message.inv:
if inv.hash in self.islocks:
self.send_message(self.islocks[inv.hash])
if inv.hash in self.txes:
self.send_message(self.txes[inv.hash])
class DashZMQTest (DashTestFramework):
def set_test_params(self):
# That's where the zmq publisher will listen for subscriber
self.address = "tcp://127.0.0.1:28333"
# node0 creates all available ZMQ publisher
node0_extra_args = ["-zmqpub%s=%s" % (pub.value, self.address) for pub in ZMQPublisher]
node0_extra_args.append("-whitelist=127.0.0.1")
self.set_dash_test_params(4, 3, fast_dip3_enforcement=True, extra_args=[node0_extra_args, [], [], []])
def run_test(self):
# Check that dashd has been built with ZMQ enabled.
config = configparser.ConfigParser()
config.read_file(open(self.options.configfile))
skip_if_no_py3_zmq()
skip_if_no_bitcoind_zmq(self)
try:
# Setup the ZMQ subscriber socket
self.zmq_context = zmq.Context()
self.socket = self.zmq_context.socket(zmq.SUB)
self.socket.connect(self.address)
# Initialize the network
self.activate_dip8()
self.nodes[0].spork("SPORK_17_QUORUM_DKG_ENABLED", 0)
self.wait_for_sporks_same()
# Create an LLMQ for testing
self.quorum_type = 100 # llmq_test
self.quorum_hash = self.mine_quorum()
self.sync_blocks()
self.wait_for_chainlocked_block_all_nodes(self.nodes[0].getbestblockhash())
# Wait a moment to avoid subscribing to recovered sig in the test before the one from the chainlock
# has been sent which leads to test failure.
time.sleep(1)
# Test all dash related ZMQ publisher
self.test_recovered_signature_publishers()
self.test_chainlock_publishers()
self.test_instantsend_publishers()
self.test_governance_publishers()
finally:
# Destroy the ZMQ context.
self.log.debug("Destroying ZMQ context")
self.zmq_context.destroy(linger=None)
def subscribe(self, publishers):
# Subscribe to a list of ZMQPublishers
for pub in publishers:
self.socket.subscribe(pub.value)
def unsubscribe(self, publishers):
# Unsubscribe from a list of ZMQPublishers
for pub in publishers:
self.socket.unsubscribe(pub.value)
def receive(self, publisher, flags=0):
# Receive a ZMQ message and validate it's sent from the correct ZMQPublisher
topic, body, seq = self.socket.recv_multipart(flags)
# Topic should match the publisher value
assert_equal(topic.decode(), publisher.value)
return io.BytesIO(body)
def test_recovered_signature_publishers(self):
def validate_recovered_sig(request_id, msg_hash):
# Make sure the recovered sig exists by RPC
rpc_recovered_sig = self.get_recovered_sig(request_id, msg_hash)
# Validate hashrecoveredsig
zmq_recovered_sig_hash = bytes_to_hex_str(self.receive(ZMQPublisher.hash_recovered_sig).read(32))
assert_equal(zmq_recovered_sig_hash, msg_hash)
# Validate rawrecoveredsig
zmq_recovered_sig_raw = CRecoveredSig()
zmq_recovered_sig_raw.deserialize(self.receive(ZMQPublisher.raw_recovered_sig))
assert_equal(zmq_recovered_sig_raw.llmqType, rpc_recovered_sig['llmqType'])
assert_equal(uint256_to_string(zmq_recovered_sig_raw.quorumHash), rpc_recovered_sig['quorumHash'])
assert_equal(uint256_to_string(zmq_recovered_sig_raw.id), rpc_recovered_sig['id'])
assert_equal(uint256_to_string(zmq_recovered_sig_raw.msgHash), rpc_recovered_sig['msgHash'])
assert_equal(bytes_to_hex_str(zmq_recovered_sig_raw.sig), rpc_recovered_sig['sig'])
recovered_sig_publishers = [
ZMQPublisher.hash_recovered_sig,
ZMQPublisher.raw_recovered_sig
]
self.log.info("Testing %d recovered signature publishers" % len(recovered_sig_publishers))
# Subscribe to recovered signature messages
self.subscribe(recovered_sig_publishers)
# Generate a ChainLock and make sure this leads to valid recovered sig ZMQ messages
rpc_last_block_hash = self.nodes[0].generate(1)[0]
self.wait_for_chainlocked_block_all_nodes(rpc_last_block_hash)
height = self.nodes[0].getblockcount()
rpc_request_id = hash256(ser_string(b"clsig") + struct.pack("<I", height))[::-1].hex()
validate_recovered_sig(rpc_request_id, rpc_last_block_hash)
# Sign an arbitrary and make sure this leads to valid recovered sig ZMQ messages
sign_id = uint256_to_string(random.getrandbits(256))
sign_msg_hash = uint256_to_string(random.getrandbits(256))
for mn in self.get_quorum_masternodes(self.quorum_hash):
mn.node.quorum("sign", self.quorum_type, sign_id, sign_msg_hash)
validate_recovered_sig(sign_id, sign_msg_hash)
# Unsubscribe from recovered signature messages
self.unsubscribe(recovered_sig_publishers)
def test_chainlock_publishers(self):
chain_lock_publishers = [
ZMQPublisher.hash_chain_lock,
ZMQPublisher.raw_chain_lock,
ZMQPublisher.raw_chain_lock_sig
]
self.log.info("Testing %d ChainLock publishers" % len(chain_lock_publishers))
# Subscribe to ChainLock messages
self.subscribe(chain_lock_publishers)
# Generate ChainLock
generated_hash = self.nodes[0].generate(1)[0]
self.wait_for_chainlocked_block_all_nodes(generated_hash)
rpc_best_chain_lock = self.nodes[0].getbestchainlock()
rpc_best_chain_lock_hash = rpc_best_chain_lock["blockhash"]
rpc_best_chain_lock_sig = rpc_best_chain_lock["signature"]
assert_equal(generated_hash, rpc_best_chain_lock_hash)
rpc_chain_locked_block = self.nodes[0].getblock(rpc_best_chain_lock_hash)
rpc_chain_lock_height = rpc_chain_locked_block["height"]
rpc_chain_lock_hash = rpc_chain_locked_block["hash"]
assert_equal(generated_hash, rpc_chain_lock_hash)
# Validate hashchainlock
zmq_chain_lock_hash = bytes_to_hex_str(self.receive(ZMQPublisher.hash_chain_lock).read(32))
assert_equal(zmq_chain_lock_hash, rpc_best_chain_lock_hash)
# Validate rawchainlock
zmq_chain_locked_block = CBlock()
zmq_chain_locked_block.deserialize(self.receive(ZMQPublisher.raw_chain_lock))
assert(zmq_chain_locked_block.is_valid())
assert_equal(zmq_chain_locked_block.hash, rpc_chain_lock_hash)
# Validate rawchainlocksig
zmq_chain_lock_sig_stream = self.receive(ZMQPublisher.raw_chain_lock_sig)
zmq_chain_locked_block = CBlock()
zmq_chain_locked_block.deserialize(zmq_chain_lock_sig_stream)
assert(zmq_chain_locked_block.is_valid())
zmq_chain_lock = msg_clsig()
zmq_chain_lock.deserialize(zmq_chain_lock_sig_stream)
assert_equal(zmq_chain_lock.height, rpc_chain_lock_height)
assert_equal(uint256_to_string(zmq_chain_lock.blockHash), rpc_chain_lock_hash)
assert_equal(zmq_chain_locked_block.hash, rpc_chain_lock_hash)
assert_equal(bytes_to_hex_str(zmq_chain_lock.sig), rpc_best_chain_lock_sig)
# Unsubscribe from ChainLock messages
self.unsubscribe(chain_lock_publishers)
def test_instantsend_publishers(self):
instantsend_publishers = [
ZMQPublisher.hash_tx_lock,
ZMQPublisher.raw_tx_lock,
ZMQPublisher.raw_tx_lock_sig,
ZMQPublisher.hash_instantsend_doublespend,
ZMQPublisher.raw_instantsend_doublespend
]
self.log.info("Testing %d InstantSend publishers" % len(instantsend_publishers))
# Subscribe to InstantSend messages
self.subscribe(instantsend_publishers)
# Initialize test node
self.test_node = self.nodes[0].add_p2p_connection(TestP2PConn())
network_thread_start()
self.nodes[0].p2p.wait_for_verack()
# Make sure all nodes agree
self.wait_for_chainlocked_block_all_nodes(self.nodes[0].getbestblockhash())
# Create two raw TXs, they will conflict with each other
rpc_raw_tx_1 = self.create_raw_tx(self.nodes[0], self.nodes[0], 1, 1, 100)
rpc_raw_tx_2 = self.create_raw_tx(self.nodes[0], self.nodes[0], 1, 1, 100)
# Send the first transaction and wait for the InstantLock
rpc_raw_tx_1_hash = self.nodes[0].sendrawtransaction(rpc_raw_tx_1['hex'])
self.wait_for_instantlock(rpc_raw_tx_1_hash, self.nodes[0])
# Validate hashtxlock
zmq_tx_lock_hash = bytes_to_hex_str(self.receive(ZMQPublisher.hash_tx_lock).read(32))
assert_equal(zmq_tx_lock_hash, rpc_raw_tx_1['txid'])
# Validate rawtxlock
zmq_tx_lock_raw = CTransaction()
zmq_tx_lock_raw.deserialize(self.receive(ZMQPublisher.raw_tx_lock))
assert(zmq_tx_lock_raw.is_valid())
assert_equal(zmq_tx_lock_raw.hash, rpc_raw_tx_1['txid'])
# Validate rawtxlocksig
zmq_tx_lock_sig_stream = self.receive(ZMQPublisher.raw_tx_lock_sig)
zmq_tx_lock_tx = CTransaction()
zmq_tx_lock_tx.deserialize(zmq_tx_lock_sig_stream)
assert(zmq_tx_lock_tx.is_valid())
assert_equal(zmq_tx_lock_tx.hash, rpc_raw_tx_1['txid'])
zmq_tx_lock = msg_islock()
zmq_tx_lock.deserialize(zmq_tx_lock_sig_stream)
assert_equal(uint256_to_string(zmq_tx_lock.txid), rpc_raw_tx_1['txid'])
# Try to send the second transaction. This must throw an RPC error because it conflicts with rpc_raw_tx_1
# which already got the InstantSend lock.
assert_raises_rpc_error(-26, "tx-txlock-conflict", self.nodes[0].sendrawtransaction, rpc_raw_tx_2['hex'])
# Validate hashinstantsenddoublespend
zmq_double_spend_hash2 = bytes_to_hex_str(self.receive(ZMQPublisher.hash_instantsend_doublespend).read(32))
zmq_double_spend_hash1 = bytes_to_hex_str(self.receive(ZMQPublisher.hash_instantsend_doublespend).read(32))
assert_equal(zmq_double_spend_hash2, rpc_raw_tx_2['txid'])
assert_equal(zmq_double_spend_hash1, rpc_raw_tx_1['txid'])
# Validate rawinstantsenddoublespend
zmq_double_spend_tx_2 = CTransaction()
zmq_double_spend_tx_2.deserialize(self.receive(ZMQPublisher.raw_instantsend_doublespend))
assert (zmq_double_spend_tx_2.is_valid())
assert_equal(zmq_double_spend_tx_2.hash, rpc_raw_tx_2['txid'])
zmq_double_spend_tx_1 = CTransaction()
zmq_double_spend_tx_1.deserialize(self.receive(ZMQPublisher.raw_instantsend_doublespend))
assert(zmq_double_spend_tx_1.is_valid())
assert_equal(zmq_double_spend_tx_1.hash, rpc_raw_tx_1['txid'])
# No islock notifications when tx is not received yet
self.nodes[0].generate(1)
rpc_raw_tx_3 = self.create_raw_tx(self.nodes[0], self.nodes[0], 1, 1, 100)
islock = self.create_islock(rpc_raw_tx_3['hex'])
self.test_node.send_islock(islock)
# Validate NO hashtxlock
time.sleep(1)
try:
self.receive(ZMQPublisher.hash_tx_lock, zmq.NOBLOCK)
assert(False)
except zmq.ZMQError:
# this is expected
pass
# Now send the tx itself
self.test_node.send_tx(FromHex(msg_tx(), rpc_raw_tx_3['hex']))
self.wait_for_instantlock(rpc_raw_tx_3['txid'], self.nodes[0])
# Validate hashtxlock
zmq_tx_lock_hash = bytes_to_hex_str(self.receive(ZMQPublisher.hash_tx_lock).read(32))
assert_equal(zmq_tx_lock_hash, rpc_raw_tx_3['txid'])
# Drop test node connection
self.nodes[0].disconnect_p2ps()
# Unsubscribe from InstantSend messages
self.unsubscribe(instantsend_publishers)
def test_governance_publishers(self):
governance_publishers = [
ZMQPublisher.hash_governance_object,
ZMQPublisher.raw_governance_object,
ZMQPublisher.hash_governance_vote,
ZMQPublisher.raw_governance_vote
]
self.log.info("Testing %d governance publishers" % len(governance_publishers))
# Subscribe to governance messages
self.subscribe(governance_publishers)
# Create a proposal and submit it to the network
proposal_rev = 1
proposal_time = int(time.time())
proposal_data = {
"type": 1, # GOVERNANCE_OBJECT_PROPOSAL
"name": "Test",
"start_epoch": proposal_time,
"end_epoch": proposal_time + 60,
"payment_amount": 5,
"payment_address": self.nodes[0].getnewaddress(),
"url": "https://dash.org"
}
proposal_hex = ''.join(format(x, '02x') for x in json.dumps(proposal_data).encode())
collateral = self.nodes[0].gobject("prepare", "0", proposal_rev, proposal_time, proposal_hex)
self.wait_for_instantlock(collateral, self.nodes[0])
self.nodes[0].generate(6)
self.sync_blocks()
rpc_proposal_hash = self.nodes[0].gobject("submit", "0", proposal_rev, proposal_time, proposal_hex, collateral)
# Validate hashgovernanceobject
zmq_governance_object_hash = bytes_to_hex_str(self.receive(ZMQPublisher.hash_governance_object).read(32))
assert_equal(zmq_governance_object_hash, rpc_proposal_hash)
zmq_governance_object_raw = CGovernanceObject()
zmq_governance_object_raw.deserialize(self.receive(ZMQPublisher.raw_governance_object))
assert_equal(zmq_governance_object_raw.nHashParent, 0)
assert_equal(zmq_governance_object_raw.nRevision, proposal_rev)
assert_equal(zmq_governance_object_raw.nTime, proposal_time)
assert_equal(json.loads(zmq_governance_object_raw.vchData.decode()), proposal_data)
assert_equal(zmq_governance_object_raw.nObjectType, proposal_data["type"])
assert_equal(zmq_governance_object_raw.masternodeOutpoint.hash, COutPoint().hash)
assert_equal(zmq_governance_object_raw.masternodeOutpoint.n, COutPoint().n)
# Vote for the proposal and validate the governance vote message
map_vote_outcomes = {
0: "none",
1: "yes",
2: "no",
3: "abstain"
}
map_vote_signals = {
0: "none",
1: "funding",
2: "valid",
3: "delete",
4: "endorsed"
}
self.nodes[0].gobject("vote-many", rpc_proposal_hash, map_vote_signals[1], map_vote_outcomes[1])
rpc_proposal_votes = self.nodes[0].gobject('getcurrentvotes', rpc_proposal_hash)
# Validate hashgovernancevote
zmq_governance_vote_hash = bytes_to_hex_str(self.receive(ZMQPublisher.hash_governance_vote).read(32))
assert(zmq_governance_vote_hash in rpc_proposal_votes)
# Validate rawgovernancevote
zmq_governance_vote_raw = CGovernanceVote()
zmq_governance_vote_raw.deserialize(self.receive(ZMQPublisher.raw_governance_vote))
assert_equal(uint256_to_string(zmq_governance_vote_raw.nParentHash), rpc_proposal_hash)
rpc_vote_parts = rpc_proposal_votes[zmq_governance_vote_hash].split(':')
rpc_outpoint_parts = rpc_vote_parts[0].split('-')
assert_equal(uint256_to_string(zmq_governance_vote_raw.masternodeOutpoint.hash), rpc_outpoint_parts[0])
assert_equal(zmq_governance_vote_raw.masternodeOutpoint.n, int(rpc_outpoint_parts[1]))
assert_equal(zmq_governance_vote_raw.nTime, int(rpc_vote_parts[1]))
assert_equal(map_vote_outcomes[zmq_governance_vote_raw.nVoteOutcome], rpc_vote_parts[2])
assert_equal(map_vote_signals[zmq_governance_vote_raw.nVoteSignal], rpc_vote_parts[3])
# Unsubscribe from governance messages
self.unsubscribe(governance_publishers)
if __name__ == '__main__':
DashZMQTest().main()