def test_invalid_same_peer_id(self):
manager3 = self.create_peer(self.network, peer_id=self.peer_id1)
conn = FakeConnection(self.manager1, manager3)
conn.run_one_step() # HELLO
conn.run_one_step() # PEER-ID
self._check_result_only_cmd(conn.peek_tr1_value(), b'ERROR')
self.assertTrue(conn.tr1.disconnecting)
def test_block_sync_new_blocks_and_txs(self):
self._add_new_blocks(25)
self._add_new_transactions(3)
self._add_new_blocks(4)
self._add_new_transactions(5)
manager2 = self.create_peer(self.network)
self.assertEqual(manager2.state, manager2.NodeState.READY)
conn = FakeConnection(self.manager1, manager2)
for _ in range(1000):
conn.run_one_step()
self.clock.advance(0.1)
# dot1 = self.manager1.tx_storage.graphviz(format='pdf')
# dot1.render('dot1')
# dot2 = manager2.tx_storage.graphviz(format='pdf')
# dot2.render('dot2')
node_sync = conn.proto1.state.sync_manager
self.assertEqual(self.manager1.tx_storage.latest_timestamp,
manager2.tx_storage.latest_timestamp)
self.assertEqual(node_sync.synced_timestamp, node_sync.peer_timestamp)
self.assertTipsEqual(self.manager1, manager2)
self.assertConsensusEqual(self.manager1, manager2)
self.assertConsensusValid(self.manager1)
self.assertConsensusValid(manager2)
def setUp(self):
super().setUp()
self.network = 'testnet'
self.peer_id1 = PeerId()
self.peer_id2 = PeerId()
self.manager1 = self.create_peer(self.network, peer_id=self.peer_id1)
self.manager2 = self.create_peer(self.network, peer_id=self.peer_id2)
self.conn = FakeConnection(self.manager1, self.manager2)
def _simulate_run(self, run_i, simulator):
# XXX: the following was adapted from test_new_syncing_peer, it doesn't matter too much, but has good coverage
# of different behaviors that can be affected by non-determinism on the fullnode implementation
self.log.debug(f'run{run_i}: simulator{run_i}')
nodes = []
miners = []
tx_generators = []
peer_id_pool = self.new_peer_id_pool()
manager = self.create_simulator_peer(simulator, peer_id_pool)
nodes.append(manager)
miner = simulator.create_miner(manager, hashpower=10e6)
miner.start()
miners.append(miner)
simulator.run(10)
for i, hashpower in enumerate([10e6, 8e6, 5e6]):
manager = self.create_simulator_peer(simulator, peer_id_pool)
for node in nodes:
conn = FakeConnection(manager, node, latency=0.085)
simulator.add_connection(conn)
nodes.append(manager)
miner = simulator.create_miner(manager, hashpower=hashpower)
miner.start()
miners.append(miner)
for i, rate in enumerate([5, 4, 3]):
tx_gen = simulator.create_tx_generator(nodes[i], rate=rate * 1 / 60., hashpower=1e6, ignore_no_funds=True)
tx_gen.start()
tx_generators.append(tx_gen)
simulator.run(10)
self.log.debug(f'run{run_i}: adding late node')
late_manager = self.create_simulator_peer(simulator, peer_id_pool)
for node in nodes:
conn = FakeConnection(late_manager, node, latency=0.300)
simulator.add_connection(conn)
nodes.append(late_manager)
simulator.run(10)
for tx_gen in tx_generators:
tx_gen.stop()
for miner in miners:
miner.stop()
simulator.run(10)
return nodes
def test_tx_propagation_nat_peers(self):
""" manager1 <- manager2 <- manager3
"""
self._add_new_blocks(25)
self.manager2 = self.create_peer(self.network)
self.conn1 = FakeConnection(self.manager1, self.manager2)
for _ in range(1000):
if self.conn1.is_empty():
break
self.conn1.run_one_step()
self.clock.advance(0.1)
self.assertTipsEqual(self.manager1, self.manager2)
self._add_new_blocks(1)
for _ in range(1000):
if self.conn1.is_empty():
break
self.conn1.run_one_step()
self.clock.advance(0.1)
self.assertTipsEqual(self.manager1, self.manager2)
self.manager3 = self.create_peer(self.network)
self.conn2 = FakeConnection(self.manager2, self.manager3)
for _ in range(1000):
if self.conn1.is_empty() and self.conn2.is_empty():
break
self.conn1.run_one_step()
self.conn2.run_one_step()
self.clock.advance(0.1)
self.assertTipsEqual(self.manager1, self.manager2)
self.assertTipsEqual(self.manager1, self.manager3)
self._add_new_transactions(1)
for _ in range(1000):
if self.conn1.is_empty() and self.conn2.is_empty():
break
self.conn1.run_one_step()
self.conn2.run_one_step()
self.clock.advance(0.1)
self.assertTipsEqual(self.manager1, self.manager2)
self.assertTipsEqual(self.manager1, self.manager3)
self.assertConsensusEqual(self.manager1, self.manager2)
self.assertConsensusEqual(self.manager1, self.manager3)
self.assertConsensusValid(self.manager1)
self.assertConsensusValid(self.manager2)
self.assertConsensusValid(self.manager3)
def test_new_syncing_peer(self):
nodes = []
miners = []
tx_generators = []
manager = self.create_peer()
nodes.append(manager)
miner = self.simulator.create_miner(manager, hashpower=10e6)
miner.start()
miners.append(miner)
self.simulator.run(600)
for hashpower in [10e6, 8e6, 5e6]:
manager = self.create_peer()
for node in nodes:
conn = FakeConnection(manager, node, latency=0.085)
self.simulator.add_connection(conn)
nodes.append(manager)
miner = self.simulator.create_miner(manager, hashpower=hashpower)
miner.start()
miners.append(miner)
for i, rate in enumerate([5, 4, 3]):
tx_gen = self.simulator.create_tx_generator(nodes[i], rate=rate * 1 / 60., hashpower=1e6,
ignore_no_funds=True)
tx_gen.start()
tx_generators.append(tx_gen)
self.simulator.run(600)
self.log.debug('adding late node')
late_manager = self.create_peer()
for node in nodes:
conn = FakeConnection(late_manager, node, latency=0.300)
self.simulator.add_connection(conn)
self.simulator.run(600)
for tx_gen in tx_generators:
tx_gen.stop()
for miner in miners:
miner.stop()
self.simulator.run_until_complete(600)
for idx, node in enumerate(nodes):
self.log.debug(f'checking node {idx}')
self.assertConsensusValid(node)
self.assertConsensusEqual(node, late_manager)
def test_capabilities(self):
network = 'testnet'
manager1 = self.create_peer(
network, capabilities=[settings.CAPABILITY_WHITELIST])
manager2 = self.create_peer(network, capabilities=[])
conn = FakeConnection(manager1, manager2)
# Run the p2p protocol.
for _ in range(100):
conn.run_one_step(debug=True)
self.clock.advance(0.1)
# Even if we don't have the capability we must connect because the whitelist url conf is None
self.assertEqual(conn._proto1.state.state_name, 'READY')
self.assertEqual(conn._proto2.state.state_name, 'READY')
manager3 = self.create_peer(
network, capabilities=[settings.CAPABILITY_WHITELIST])
manager4 = self.create_peer(
network, capabilities=[settings.CAPABILITY_WHITELIST])
conn2 = FakeConnection(manager3, manager4)
# Run the p2p protocol.
for _ in range(100):
conn2.run_one_step(debug=True)
self.clock.advance(0.1)
self.assertEqual(conn2._proto1.state.state_name, 'READY')
self.assertEqual(conn2._proto2.state.state_name, 'READY')
def test_many_miners_since_beginning(self):
nodes = []
miners = []
for hashpower in [10e6, 5e6, 1e6, 1e6, 1e6]:
manager = self.create_peer()
for node in nodes:
conn = FakeConnection(manager, node, latency=0.085)
self.simulator.add_connection(conn)
nodes.append(manager)
miner = self.simulator.create_miner(manager, hashpower=hashpower)
miner.start()
miners.append(miner)
self.simulator.run(600)
for miner in miners:
miner.stop()
self.simulator.run(15)
for node in nodes[1:]:
self.assertTipsEqual(nodes[0], node)
def test_two_nodes(self):
manager1 = self.create_peer()
manager2 = self.create_peer()
miner1 = self.simulator.create_miner(manager1, hashpower=10e6)
miner1.start()
self.simulator.run(10)
gen_tx1 = self.simulator.create_tx_generator(manager1, rate=3 / 60., hashpower=1e6, ignore_no_funds=True)
gen_tx1.start()
self.simulator.run(60)
conn12 = FakeConnection(manager1, manager2, latency=0.150)
self.simulator.add_connection(conn12)
self.simulator.run(60)
miner2 = self.simulator.create_miner(manager2, hashpower=100e6)
miner2.start()
self.simulator.run(120)
gen_tx2 = self.simulator.create_tx_generator(manager2, rate=10 / 60., hashpower=1e6, ignore_no_funds=True)
gen_tx2.start()
self.simulator.run(10 * 60)
miner1.stop()
miner2.stop()
gen_tx1.stop()
gen_tx2.stop()
self.simulator.run(5 * 60)
self.assertTrue(conn12.is_connected)
self.assertTipsEqual(manager1, manager2)
def test_invalid_different_network(self):
manager3 = self.create_peer(network='mainnet')
conn = FakeConnection(self.manager1, manager3)
conn.run_one_step() # HELLO
self._check_result_only_cmd(conn.peek_tr1_value(), b'ERROR')
self.assertTrue(conn.tr1.disconnecting)
conn.run_one_step() # ERROR
def test_block_sync_many_new_blocks(self):
self._add_new_blocks(150)
manager2 = self.create_peer(self.network)
self.assertEqual(manager2.state, manager2.NodeState.READY)
conn = FakeConnection(self.manager1, manager2)
while not conn.is_empty():
conn.run_one_step(debug=True)
self.clock.advance(0.1)
node_sync = conn.proto1.state.sync_manager
self.assertEqual(node_sync.synced_timestamp, node_sync.peer_timestamp)
self.assertTipsEqual(self.manager1, manager2)
self.assertConsensusEqual(self.manager1, manager2)
self.assertConsensusValid(self.manager1)
self.assertConsensusValid(manager2)
def test_mempool_basic(self):
# 10 blocks
self._add_new_blocks(2)
# N blocks to unlock the reward
add_blocks_unlock_reward(self.manager1)
# 5 transactions to be confirmed by the next blocks
self._add_new_transactions(5)
# 2 more blocks
self._add_new_blocks(2)
# 30 transactions in the mempool
self._add_new_transactions(30)
debug_pdf = False
if debug_pdf:
dot1 = GraphvizVisualizer(self.manager1.tx_storage,
include_verifications=True,
include_funds=True).dot()
dot1.render('mempool-test')
manager2 = self.create_peer(self.network, enable_sync_v1=True)
self.assertEqual(manager2.state, manager2.NodeState.READY)
conn = FakeConnection(self.manager1, manager2)
for _ in range(1000):
if conn.is_empty():
break
conn.run_one_step(debug=True)
self.clock.advance(1)
self.assertConsensusValid(self.manager1)
self.assertConsensusValid(manager2)
self.assertConsensusEqual(self.manager1, manager2)
# 3 genesis
# 25 blocks
# Unlock reward blocks
# 8 txs
self.assertEqual(len(manager2.tx_storage.indexes.mempool_tips.get()),
1)
self.assertEqual(
len(self.manager1.tx_storage.indexes.mempool_tips.get()), 1)
def test_match_peer_id(self):
network = 'testnet'
peer_id1 = PeerId()
peer_id2 = PeerId()
manager1 = self.create_peer(network, peer_id=peer_id1)
manager2 = self.create_peer(network, peer_id=peer_id2)
conn = FakeConnection(manager1, manager2)
self.assertTrue(conn.proto2.is_state(conn.proto2.PeerState.HELLO))
matcher = NetfilterMatchPeerId(str(peer_id1.id))
context = NetfilterContext(protocol=conn.proto2)
self.assertFalse(matcher.match(context))
conn.run_one_step()
self.assertTrue(conn.proto2.is_state(conn.proto2.PeerState.PEER_ID))
self.assertFalse(matcher.match(context))
# Success because the connection is ready and proto2 is connected to proto1.
conn.run_one_step()
conn.run_one_step()
self.assertTrue(conn.proto2.is_state(conn.proto2.PeerState.READY))
self.assertTrue(matcher.match(context))
# Fail because proto1 is connected to proto2, and the peer id cannot match.
context = NetfilterContext(protocol=conn.proto1)
self.assertFalse(matcher.match(context))
def test_block_sync_only_genesis(self):
manager2 = self.create_peer(self.network)
self.assertEqual(manager2.state, manager2.NodeState.READY)
conn = FakeConnection(self.manager1, manager2)
conn.run_one_step() # HELLO
conn.run_one_step() # PEER-ID
conn.run_one_step() # READY
node_sync = conn.proto1.state.sync_manager
self.assertEqual(node_sync.synced_timestamp, node_sync.peer_timestamp)
self.assertTipsEqual(self.manager1, manager2)
def test_two_connections(self):
self.conn.run_one_step() # HELLO
self.conn.run_one_step() # PEER-ID
self.conn.run_one_step() # READY
self.conn.run_one_step() # GET-PEERS
self.conn.run_one_step() # GET-TIPS
manager3 = self.create_peer(self.network)
conn = FakeConnection(self.manager1, manager3)
conn.run_one_step() # HELLO
conn.run_one_step() # PEER-ID
conn.run_one_step() # READY
conn.run_one_step() # GET-PEERS
self._check_result_only_cmd(self.conn.peek_tr1_value(), b'PEERS')
self.conn.run_one_step()
def test_split_brain(self):
debug_pdf = False
manager1 = self.create_peer()
manager1.allow_mining_without_peers()
manager2 = self.create_peer()
manager2.allow_mining_without_peers()
miner11 = self.simulator.create_miner(manager1, hashpower=10e6)
miner11.start()
gen_tx11 = self.simulator.create_tx_generator(manager1,
rate=10 / 60.,
hashpower=1e6,
ignore_no_funds=True)
gen_tx11.start()
gen_tx12 = self.simulator.create_tx_generator(manager1,
rate=10 / 60.,
hashpower=1e6,
ignore_no_funds=True)
gen_tx12.enable_double_spending()
gen_tx12.start()
miner21 = self.simulator.create_miner(manager2, hashpower=10e6)
miner21.start()
gen_tx21 = self.simulator.create_tx_generator(manager2,
rate=10 / 60.,
hashpower=1e6,
ignore_no_funds=True)
gen_tx21.start()
gen_tx22 = self.simulator.create_tx_generator(manager2,
rate=10 / 60.,
hashpower=1e6,
ignore_no_funds=True)
gen_tx22.enable_double_spending()
gen_tx22.start()
self.simulator.run(400)
if debug_pdf:
dot1 = GraphvizVisualizer(manager1.tx_storage,
include_verifications=True,
include_funds=True).dot()
dot1.render('dot1-pre')
dot2 = GraphvizVisualizer(manager2.tx_storage,
include_verifications=True,
include_funds=True).dot()
dot2.render('dot2-pre')
self.assertTipsNotEqual(manager1, manager2)
self.assertConsensusValid(manager1)
self.assertConsensusValid(manager2)
# input('Press enter to continue...')
miner11.stop()
gen_tx11.stop()
gen_tx12.stop()
miner21.stop()
gen_tx21.stop()
gen_tx22.stop()
conn12 = FakeConnection(manager1, manager2)
self.simulator.add_connection(conn12)
self.simulator.run(300)
if debug_pdf:
dot1 = GraphvizVisualizer(manager1.tx_storage,
include_verifications=True).dot()
dot1.render('dot1-post')
dot2 = GraphvizVisualizer(manager2.tx_storage,
include_verifications=True).dot()
dot2.render('dot2-post')
node_sync = conn12.proto1.state.sync_manager
self.assertEqual(node_sync.synced_timestamp, node_sync.peer_timestamp)
node_sync = conn12.proto2.state.sync_manager
self.assertEqual(node_sync.synced_timestamp, node_sync.peer_timestamp)
self.assertTipsEqual(manager1, manager2)
self.assertConsensusEqual(manager1, manager2)
self.assertConsensusValid(manager1)
self.assertConsensusValid(manager2)
def test_downloader(self):
from hathor.p2p.node_sync import NodeSyncTimestamp
blocks = self._add_new_blocks(3)
manager2 = self.create_peer(self.network)
self.assertEqual(manager2.state, manager2.NodeState.READY)
conn = FakeConnection(self.manager1, manager2)
# Get to PEER-ID state only because when it gets to READY it will automatically sync
conn.run_one_step()
self.assertTrue(isinstance(conn.proto1.state, PeerIdState))
self.assertTrue(isinstance(conn.proto2.state, PeerIdState))
downloader = conn.proto2.connections._sync_factories[
SyncVersion.V1].downloader
node_sync1 = NodeSyncTimestamp(conn.proto1,
downloader,
reactor=conn.proto1.node.reactor)
node_sync1.start()
node_sync2 = NodeSyncTimestamp(conn.proto2,
downloader,
reactor=conn.proto2.node.reactor)
node_sync2.start()
self.assertTrue(isinstance(conn.proto1.state, PeerIdState))
self.assertTrue(isinstance(conn.proto2.state, PeerIdState))
deferred1 = downloader.get_tx(blocks[0].hash, node_sync1)
deferred1.addCallback(node_sync1.on_tx_success)
self.assertEqual(len(downloader.pending_transactions), 1)
details = downloader.pending_transactions[blocks[0].hash]
self.assertEqual(len(details.connections), 1)
self.assertEqual(len(downloader.downloading_deque), 1)
deferred2 = downloader.get_tx(blocks[0].hash, node_sync2)
deferred2.addCallback(node_sync2.on_tx_success)
self.assertEqual(len(downloader.pending_transactions), 1)
self.assertEqual(
len(downloader.pending_transactions[blocks[0].hash].connections),
2)
self.assertEqual(len(downloader.downloading_deque), 1)
self.assertEqual(deferred1, deferred2)
details.downloading_deferred.callback(blocks[0])
self.assertEqual(len(downloader.downloading_deque), 0)
self.assertEqual(len(downloader.pending_transactions), 0)
# Getting tx already downloaded
downloader.get_tx(blocks[0].hash, node_sync1)
self.assertEqual(len(downloader.downloading_deque), 0)
# Adding fake tx_id to downloading deque
downloader.downloading_deque.append('1')
# Getting new tx
downloader.get_tx(blocks[1].hash, node_sync1)
self.assertEqual(len(downloader.pending_transactions), 1)
details = downloader.pending_transactions[blocks[1].hash]
self.assertEqual(len(details.connections), 1)
self.assertEqual(len(downloader.downloading_deque), 2)
details.downloading_deferred.callback(blocks[1])
# Still 2 elements because the first one is not downloaded yet
self.assertEqual(len(downloader.downloading_deque), 2)
# Remove it
downloader.downloading_deque.popleft()
# And try again
downloader.check_downloading_queue()
self.assertEqual(len(downloader.downloading_deque), 0)
def setUp(self):
super().setUp()
self.web = StubSite(StatusResource(self.manager))
self.manager2 = self.create_peer('testnet')
self.conn1 = FakeConnection(self.manager, self.manager2)
def test_determinism_interleaved(self):
# sanity assert as to not mess up with it on the setup
self.assertEqual(self.simulator1.seed, self.simulator2.seed)
# XXX: the following was adapted from test_new_syncing_peer, it doesn't matter too much, but has good coverage
# of different behaviors that can be affected by non-determinism on the fullnode implementation
nodes1 = []
nodes2 = []
miners1 = []
miners2 = []
tx_generators1 = []
tx_generators2 = []
peer_id_pool1 = self.new_peer_id_pool()
peer_id_pool2 = self.new_peer_id_pool()
self.log.debug('part1 simulator1')
manager1 = self.create_simulator_peer(self.simulator1, peer_id_pool1)
nodes1.append(manager1)
miner1 = self.simulator1.create_miner(manager1, hashpower=10e6)
miner1.start()
miners1.append(miner1)
self.log.debug('part1 simulator2')
manager2 = self.create_simulator_peer(self.simulator2, peer_id_pool2)
nodes2.append(manager2)
miner2 = self.simulator2.create_miner(manager2, hashpower=10e6)
miner2.start()
miners2.append(miner2)
for _ in range(3):
self.simulator1.run(10)
self.simulator2.run(10)
for idx, (node1, node2) in enumerate(zip(nodes1, nodes2)):
self.log.debug(f'checking node {idx}')
self.assertConsensusEqual(node1, node2)
for i, hashpower in enumerate([10e6, 8e6, 5e6]):
self.log.debug(f'part2.{i} simulator1')
manager1 = self.create_simulator_peer(self.simulator1, peer_id_pool1)
for node in nodes1:
conn = FakeConnection(manager1, node, latency=0.085)
self.simulator1.add_connection(conn)
nodes1.append(manager1)
miner1 = self.simulator1.create_miner(manager1, hashpower=hashpower)
miner1.start()
miners1.append(miner1)
self.log.debug(f'part2.{i} simulator2')
manager2 = self.create_simulator_peer(self.simulator2, peer_id_pool2)
for node in nodes2:
conn = FakeConnection(manager2, node, latency=0.085)
self.simulator2.add_connection(conn)
nodes2.append(manager2)
miner2 = self.simulator2.create_miner(manager2, hashpower=hashpower)
miner2.start()
miners2.append(miner2)
for i, rate in enumerate([5, 4, 3]):
self.log.debug(f'part3.{i} simulator1')
tx_gen1 = self.simulator1.create_tx_generator(nodes1[i], rate=rate * 1 / 60., hashpower=1e6,
ignore_no_funds=True)
tx_gen1.start()
tx_generators1.append(tx_gen1)
self.log.debug(f'part3.{i} simulator2')
tx_gen2 = self.simulator2.create_tx_generator(nodes2[i], rate=rate * 1 / 60., hashpower=1e6,
ignore_no_funds=True)
tx_gen2.start()
tx_generators2.append(tx_gen2)
for _ in range(3):
self.simulator1.run(10)
self.simulator2.run(10)
for idx, (node1, node2) in enumerate(zip(nodes1, nodes2)):
self.log.debug(f'checking node {idx}')
self.assertConsensusEqual(node1, node2)
self.log.debug('adding late node')
self.log.debug('part4 simulator1')
late_manager1 = self.create_simulator_peer(self.simulator1, peer_id_pool1)
for node in nodes1:
conn = FakeConnection(late_manager1, node, latency=0.300)
self.simulator1.add_connection(conn)
nodes1.append(late_manager1)
self.log.debug('part4 simulator2')
late_manager2 = self.create_simulator_peer(self.simulator2, peer_id_pool2)
for node in nodes2:
conn = FakeConnection(late_manager2, node, latency=0.300)
self.simulator2.add_connection(conn)
nodes2.append(late_manager2)
for _ in range(3):
self.simulator1.run(10)
self.simulator2.run(10)
for idx, (node1, node2) in enumerate(zip(nodes1, nodes2)):
self.log.debug(f'checking node {idx}')
self.assertConsensusEqual(node1, node2)
self.log.debug('part5 simulator1')
for tx_gen in tx_generators1:
tx_gen.stop()
for miner in miners1:
miner.stop()
self.log.debug('part5 simulator2')
for tx_gen in tx_generators2:
tx_gen.stop()
for miner in miners2:
miner.stop()
for _ in range(3):
self.simulator1.run(10)
self.simulator2.run(10)
for idx, (node1, node2) in enumerate(zip(nodes1, nodes2)):
self.log.debug(f'checking node {idx}')
self.assertConsensusEqual(node1, node2)
def test_soft_voided(self):
txA_hash = bytes.fromhex(
'4586c5428e8d666ea59684c1cd9286d2b9d9e89b4939207db47412eeaabc48b2')
soft_voided_tx_ids = set([
txA_hash,
])
manager1 = self.create_peer(soft_voided_tx_ids=soft_voided_tx_ids)
manager1.allow_mining_without_peers()
miner1 = self.simulator.create_miner(manager1, hashpower=5e6)
miner1.start()
self.simulator.run(60)
gen_tx1 = self.simulator.create_tx_generator(manager1,
rate=3 / 60.,
hashpower=1e6,
ignore_no_funds=True)
gen_tx1.start()
self.simulator.run(300)
manager2 = self.create_peer(soft_voided_tx_ids=soft_voided_tx_ids)
manager2.soft_voided_tx_ids = soft_voided_tx_ids
graphviz = GraphvizVisualizer(manager2.tx_storage,
include_verifications=True,
include_funds=True)
conn12 = FakeConnection(manager1, manager2, latency=0.001)
self.simulator.add_connection(conn12)
miner2 = self.simulator.create_miner(manager2, hashpower=10e6)
miner2.start()
gen_tx2 = self.simulator.create_tx_generator(manager2,
rate=10 / 60.,
hashpower=1e6,
ignore_no_funds=True)
gen_tx2.start()
self.simulator.run(900)
txA = manager2.tx_storage.get_transaction(txA_hash)
metaA = txA.get_metadata()
self.assertEqual({settings.SOFT_VOIDED_ID, txA.hash}, metaA.voided_by)
graphviz.labels[txA.hash] = 'txA'
txB = add_custom_tx(manager2, [(txA, 0)])
metaB = txB.get_metadata()
self.assertEqual({txA.hash}, metaB.voided_by)
graphviz.labels[txB.hash] = 'txB'
txD1 = add_custom_tx(manager2, [(txB, 0)])
metaD1 = txD1.get_metadata()
self.assertEqual({txA.hash}, metaD1.voided_by)
graphviz.labels[txD1.hash] = 'txD1'
txD2 = add_custom_tx(manager2, [(txB, 0)])
metaD2 = txD2.get_metadata()
self.assertEqual({txA.hash, txD2.hash}, metaD2.voided_by)
graphviz.labels[txD2.hash] = 'txD2'
metaD1 = txD1.get_metadata()
self.assertEqual({txA.hash, txD1.hash}, metaD1.voided_by)
address = manager2.wallet.get_unused_address(mark_as_used=False)
value = 1
txC = gen_new_tx(manager2, address, value)
txC.parents[0] = txA.hash
txC.timestamp = max(txC.timestamp, txA.timestamp + 1)
txC.weight = 25
txC.update_hash()
self.assertTrue(manager2.propagate_tx(txC, fails_silently=False))
metaC = txC.get_metadata()
self.assertIsNone(metaC.voided_by)
graphviz.labels[txC.hash] = 'txC'
blk1 = manager2.generate_mining_block()
self.assertNoParentsAreSoftVoided(blk1)
blk1.parents[1] = txA.hash
blk1.nonce = self.rng.getrandbits(32)
blk1.update_hash()
self.assertTrue(manager2.propagate_tx(blk1, fails_silently=False))
blk1meta = blk1.get_metadata()
self.assertIsNone(blk1meta.voided_by)
graphviz.labels[blk1.hash] = 'b1'
blk2 = manager2.generate_mining_block()
self.assertNoParentsAreSoftVoided(blk2)
if txD1.hash not in blk2.parents:
blk2.parents[1] = txD1.hash
blk2.nonce = self.rng.getrandbits(32)
blk2.update_hash()
self.assertTrue(manager2.propagate_tx(blk2, fails_silently=False))
blk2meta = blk2.get_metadata()
self.assertIsNone(blk2meta.voided_by)
graphviz.labels[blk2.hash] = 'b2'
blk3 = manager2.generate_mining_block()
self.assertNoParentsAreSoftVoided(blk3)
blk3.parents[1] = txD2.hash
blk3.nonce = self.rng.getrandbits(32)
blk3.update_hash()
self.assertTrue(manager2.propagate_tx(blk3, fails_silently=False))
blk3meta = blk3.get_metadata()
self.assertIsNone(blk3meta.voided_by)
graphviz.labels[blk3.hash] = 'b3'
for tx in manager1.tx_storage.get_all_transactions():
meta = tx.get_metadata()
voided_by = meta.voided_by or set()
if settings.SOFT_VOIDED_ID in voided_by:
self.assertTrue({settings.SOFT_VOIDED_ID,
tx.hash}.issubset(voided_by))
class BaseHathorSyncMethodsTestCase(unittest.TestCase):
__test__ = False
def setUp(self):
super().setUp()
# import sys
# from twisted.python import log
# log.startLogging(sys.stdout)
self.network = 'testnet'
self.manager1 = self.create_peer(self.network, unlock_wallet=True)
self.manager1.avg_time_between_blocks = 4
self.genesis = self.manager1.tx_storage.get_all_genesis()
self.genesis_blocks = [tx for tx in self.genesis if tx.is_block]
def _add_new_tx(self, address, value):
from hathor.transaction import Transaction
from hathor.wallet.base_wallet import WalletOutputInfo
outputs = []
outputs.append(
WalletOutputInfo(address=decode_address(address),
value=int(value),
timelock=None))
tx = self.manager1.wallet.prepare_transaction_compute_inputs(
Transaction, outputs, self.manager1.tx_storage)
tx.timestamp = int(self.clock.seconds())
tx.storage = self.manager1.tx_storage
tx.weight = 10
tx.parents = self.manager1.get_new_tx_parents()
tx.resolve()
tx.verify()
self.manager1.propagate_tx(tx)
self.clock.advance(10)
return tx
def _add_new_transactions(self, num_txs):
txs = []
for _ in range(num_txs):
address = self.get_address(0)
value = random.choice([5, 10, 50, 100, 120])
tx = self._add_new_tx(address, value)
txs.append(tx)
return txs
def _add_new_block(self, propagate=True):
block = self.manager1.generate_mining_block()
self.assertTrue(block.resolve())
block.verify()
self.manager1.on_new_tx(block, propagate_to_peers=propagate)
self.clock.advance(10)
return block
def _add_new_blocks(self, num_blocks, propagate=True):
blocks = []
for _ in range(num_blocks):
blocks.append(self._add_new_block(propagate=propagate))
return blocks
def test_get_blocks_before(self):
genesis_block = self.genesis_blocks[0]
result = self.manager1.tx_storage.get_blocks_before(genesis_block.hash)
self.assertEqual(0, len(result))
genesis_tx = [tx for tx in self.genesis if not tx.is_block][0]
with self.assertRaises(TransactionIsNotABlock):
self.manager1.tx_storage.get_blocks_before(genesis_tx.hash)
blocks = self._add_new_blocks(20)
num_blocks = 5
for i, block in enumerate(blocks):
result = self.manager1.tx_storage.get_blocks_before(
block.hash, num_blocks=num_blocks)
expected_result = [genesis_block] + blocks[:i]
expected_result = expected_result[-num_blocks:]
expected_result = expected_result[::-1]
self.assertEqual(result, expected_result)
def test_block_sync_only_genesis(self):
manager2 = self.create_peer(self.network)
self.assertEqual(manager2.state, manager2.NodeState.READY)
conn = FakeConnection(self.manager1, manager2)
conn.run_one_step() # HELLO
conn.run_one_step() # PEER-ID
conn.run_one_step() # READY
node_sync = conn.proto1.state.sync_manager
self.assertEqual(node_sync.synced_timestamp, node_sync.peer_timestamp)
self.assertTipsEqual(self.manager1, manager2)
def test_block_sync_new_blocks(self):
self._add_new_blocks(15)
manager2 = self.create_peer(self.network)
self.assertEqual(manager2.state, manager2.NodeState.READY)
conn = FakeConnection(self.manager1, manager2)
for _ in range(10000):
if conn.is_empty():
break
conn.run_one_step(debug=True)
self.clock.advance(0.1)
node_sync = conn.proto1.state.sync_manager
self.assertEqual(node_sync.synced_timestamp, node_sync.peer_timestamp)
self.assertTipsEqual(self.manager1, manager2)
self.assertConsensusEqual(self.manager1, manager2)
self.assertConsensusValid(self.manager1)
self.assertConsensusValid(manager2)
def test_block_sync_many_new_blocks(self):
self._add_new_blocks(150)
manager2 = self.create_peer(self.network)
self.assertEqual(manager2.state, manager2.NodeState.READY)
conn = FakeConnection(self.manager1, manager2)
while not conn.is_empty():
conn.run_one_step(debug=True)
self.clock.advance(0.1)
node_sync = conn.proto1.state.sync_manager
self.assertEqual(node_sync.synced_timestamp, node_sync.peer_timestamp)
self.assertTipsEqual(self.manager1, manager2)
self.assertConsensusEqual(self.manager1, manager2)
self.assertConsensusValid(self.manager1)
self.assertConsensusValid(manager2)
def test_block_sync_new_blocks_and_txs(self):
self._add_new_blocks(25)
self._add_new_transactions(3)
self._add_new_blocks(4)
self._add_new_transactions(5)
manager2 = self.create_peer(self.network)
self.assertEqual(manager2.state, manager2.NodeState.READY)
conn = FakeConnection(self.manager1, manager2)
for _ in range(1000):
conn.run_one_step()
self.clock.advance(0.1)
# dot1 = self.manager1.tx_storage.graphviz(format='pdf')
# dot1.render('dot1')
# dot2 = manager2.tx_storage.graphviz(format='pdf')
# dot2.render('dot2')
node_sync = conn.proto1.state.sync_manager
self.assertEqual(self.manager1.tx_storage.latest_timestamp,
manager2.tx_storage.latest_timestamp)
self.assertEqual(node_sync.synced_timestamp, node_sync.peer_timestamp)
self.assertTipsEqual(self.manager1, manager2)
self.assertConsensusEqual(self.manager1, manager2)
self.assertConsensusValid(self.manager1)
self.assertConsensusValid(manager2)
def test_tx_propagation_nat_peers(self):
""" manager1 <- manager2 <- manager3
"""
self._add_new_blocks(25)
self.manager2 = self.create_peer(self.network)
self.conn1 = FakeConnection(self.manager1, self.manager2)
for _ in range(1000):
if self.conn1.is_empty():
break
self.conn1.run_one_step()
self.clock.advance(0.1)
self.assertTipsEqual(self.manager1, self.manager2)
self._add_new_blocks(1)
for _ in range(1000):
if self.conn1.is_empty():
break
self.conn1.run_one_step()
self.clock.advance(0.1)
self.assertTipsEqual(self.manager1, self.manager2)
self.manager3 = self.create_peer(self.network)
self.conn2 = FakeConnection(self.manager2, self.manager3)
for _ in range(1000):
if self.conn1.is_empty() and self.conn2.is_empty():
break
self.conn1.run_one_step()
self.conn2.run_one_step()
self.clock.advance(0.1)
self.assertTipsEqual(self.manager1, self.manager2)
self.assertTipsEqual(self.manager1, self.manager3)
self._add_new_transactions(1)
for _ in range(1000):
if self.conn1.is_empty() and self.conn2.is_empty():
break
self.conn1.run_one_step()
self.conn2.run_one_step()
self.clock.advance(0.1)
self.assertTipsEqual(self.manager1, self.manager2)
self.assertTipsEqual(self.manager1, self.manager3)
self.assertConsensusEqual(self.manager1, self.manager2)
self.assertConsensusEqual(self.manager1, self.manager3)
self.assertConsensusValid(self.manager1)
self.assertConsensusValid(self.manager2)
self.assertConsensusValid(self.manager3)
def test_soft_voided(self):
txA_hash = bytes.fromhex(
'4586c5428e8d666ea59684c1cd9286d2b9d9e89b4939207db47412eeaabc48b2')
soft_voided_tx_ids = set([
txA_hash,
])
manager1 = self.create_peer(soft_voided_tx_ids=soft_voided_tx_ids)
manager1.allow_mining_without_peers()
miner1 = self.simulator.create_miner(manager1, hashpower=5e6)
miner1.start()
self.simulator.run(60)
gen_tx1 = self.simulator.create_tx_generator(manager1,
rate=3 / 60.,
hashpower=1e6,
ignore_no_funds=True)
gen_tx1.start()
self.simulator.run(300)
manager2 = self.create_peer(soft_voided_tx_ids=soft_voided_tx_ids)
manager2.soft_voided_tx_ids = soft_voided_tx_ids
conn12 = FakeConnection(manager1, manager2, latency=0.001)
self.simulator.add_connection(conn12)
miner2 = self.simulator.create_miner(manager2, hashpower=10e6)
miner2.start()
gen_tx2 = self.simulator.create_tx_generator(manager2,
rate=10 / 60.,
hashpower=1e6,
ignore_no_funds=True)
gen_tx2.start()
self.simulator.run(900)
miner2.stop()
gen_tx2.stop()
txA = manager2.tx_storage.get_transaction(txA_hash)
metaA = txA.get_metadata()
self.assertEqual({settings.SOFT_VOIDED_ID, txA.hash}, metaA.voided_by)
txB = add_custom_tx(manager2, [(txA, 0)])
metaB = txB.get_metadata()
self.assertEqual({txA.hash}, metaB.voided_by)
txD1 = add_custom_tx(manager2, [(txB, 0)])
metaD1 = txD1.get_metadata()
self.assertEqual({txA.hash}, metaD1.voided_by)
blk1 = manager2.generate_mining_block()
self.assertNoParentsAreSoftVoided(blk1)
if txD1.hash not in blk1.parents:
blk1.parents[1] = txD1.hash
blk1.timestamp = txD1.timestamp + 1
blk1.nonce = self.rng.getrandbits(32)
blk1.update_hash()
self.assertTrue(manager2.propagate_tx(blk1, fails_silently=False))
blk1meta = blk1.get_metadata()
self.assertIsNone(blk1meta.voided_by)
self.simulator.run(10)
address = manager2.wallet.get_unused_address(mark_as_used=True)
txC = gen_new_tx(manager2, address, 6400)
if txD1.hash not in txC.parents:
txC.parents[1] = txD1.hash
txC.weight = 25
txC.update_hash()
manager2.propagate_tx(txC, fails_silently=False)
metaC = txC.get_metadata()
self.assertIsNone(metaC.voided_by)
txD2 = gen_custom_tx(manager2, [(txB, 0)])
txD2.timestamp = txD1.timestamp + 2
txD2.update_hash()
manager2.propagate_tx(txD2, fails_silently=False)
blk1meta = blk1.get_metadata()
self.assertIsNone(blk1meta.voided_by)
metaC = txC.get_metadata()
self.assertIsNone(metaC.voided_by)
class BaseHathorProtocolTestCase(unittest.TestCase):
__test__ = False
def setUp(self):
super().setUp()
self.network = 'testnet'
self.peer_id1 = PeerId()
self.peer_id2 = PeerId()
self.manager1 = self.create_peer(self.network, peer_id=self.peer_id1)
self.manager2 = self.create_peer(self.network, peer_id=self.peer_id2)
self.conn = FakeConnection(self.manager1, self.manager2)
def assertIsConnected(self, conn=None):
if conn is None:
conn = self.conn
self.assertFalse(conn.tr1.disconnecting)
self.assertFalse(conn.tr2.disconnecting)
def assertIsNotConnected(self, conn=None):
if conn is None:
conn = self.conn
self.assertTrue(conn.tr1.disconnecting)
self.assertTrue(conn.tr2.disconnecting)
def _send_cmd(self, proto, cmd, payload=None):
if not payload:
line = '{}\r\n'.format(cmd)
else:
line = '{} {}\r\n'.format(cmd, payload)
if isinstance(line, str):
line = line.encode('utf-8')
return proto.dataReceived(line)
def _check_result_only_cmd(self, result, expected_cmd):
cmd_list = []
for line in result.split(b'\r\n'):
cmd, _, _ = line.partition(b' ')
cmd_list.append(cmd)
self.assertIn(expected_cmd, cmd_list)
def _check_cmd_and_value(self, result, expected):
result_list = []
for line in result.split(b'\r\n'):
cmd, _, data = line.partition(b' ')
result_list.append((cmd, data))
self.assertIn(expected, result_list)
def test_on_connect(self):
self._check_result_only_cmd(self.conn.peek_tr1_value(), b'HELLO')
def test_invalid_command(self):
self._send_cmd(self.conn.proto1, 'INVALID-CMD')
self.conn.proto1.state.handle_error('')
self.assertTrue(self.conn.tr1.disconnecting)
def test_rate_limit(self):
hits = 1
window = 60
self.conn.proto1.ratelimit.set_limit(
HathorProtocol.RateLimitKeys.GLOBAL, hits, window)
# first will be OK and reach the hits limit per window
self.conn.run_one_step() # HELLO
# second will fail and be throttled
self.conn.run_one_step() # PEER-ID
self._check_cmd_and_value(
self.conn.peek_tr1_value(),
(b'THROTTLE', 'global At most {} hits every {} seconds'.format(
hits, window).encode('utf-8')),
)
self.conn.proto1.state.handle_throttle(b'')
# Test empty disconnect
self.conn.proto1.state = None
self.conn.proto1.connections = None
self.conn.proto1.on_disconnect(Failure(Exception()))
def test_invalid_size(self):
self.conn.tr1.clear()
# Creating big payload
big_payload = '['
for x in range(65536):
big_payload = '{}{}'.format(big_payload, x)
big_payload = '{}]'.format(big_payload)
self._send_cmd(self.conn.proto1, 'HELLO', big_payload)
self.assertTrue(self.conn.tr1.disconnecting)
def test_invalid_payload(self):
self.conn.run_one_step() # HELLO
self.conn.run_one_step() # PEER-ID
self.conn.run_one_step() # READY
with self.assertRaises(json.decoder.JSONDecodeError):
self._send_cmd(self.conn.proto1, 'PEERS', 'abc')
def test_invalid_hello1(self):
self.conn.tr1.clear()
self._send_cmd(self.conn.proto1, 'HELLO')
self._check_result_only_cmd(self.conn.peek_tr1_value(), b'ERROR')
self.assertTrue(self.conn.tr1.disconnecting)
def test_invalid_hello2(self):
self.conn.tr1.clear()
self._send_cmd(self.conn.proto1, 'HELLO', 'invalid_payload')
self._check_result_only_cmd(self.conn.peek_tr1_value(), b'ERROR')
self.assertTrue(self.conn.tr1.disconnecting)
def test_invalid_hello3(self):
self.conn.tr1.clear()
self._send_cmd(self.conn.proto1, 'HELLO', '{}')
self._check_result_only_cmd(self.conn.peek_tr1_value(), b'ERROR')
self.assertTrue(self.conn.tr1.disconnecting)
def test_invalid_hello4(self):
self.conn.tr1.clear()
self._send_cmd(
self.conn.proto1, 'HELLO',
'{"app": 0, "remote_address": 1, "network": 2, "genesis_hash": "123", "settings_hash": "456"}'
)
self._check_result_only_cmd(self.conn.peek_tr1_value(), b'ERROR')
self.assertTrue(self.conn.tr1.disconnecting)
def test_invalid_hello5(self):
# hello with clocks too far apart
self.conn.tr1.clear()
data = self.conn.proto2.state._get_hello_data()
data['timestamp'] = data[
'timestamp'] + settings.MAX_FUTURE_TIMESTAMP_ALLOWED / 2 + 1
self._send_cmd(self.conn.proto1, 'HELLO', json.dumps(data))
self._check_result_only_cmd(self.conn.peek_tr1_value(), b'ERROR')
self.assertTrue(self.conn.tr1.disconnecting)
def test_valid_hello(self):
self.conn.run_one_step() # HELLO
self._check_result_only_cmd(self.conn.peek_tr1_value(), b'PEER-ID')
self._check_result_only_cmd(self.conn.peek_tr2_value(), b'PEER-ID')
self.assertFalse(self.conn.tr1.disconnecting)
self.assertFalse(self.conn.tr2.disconnecting)
@inlineCallbacks
def test_invalid_peer_id(self):
self.conn.run_one_step() # HELLO
self.conn.run_one_step() # PEER-ID
self.conn.run_one_step() # READY
self.conn.run_one_step() # GET-PEERS
self.conn.run_one_step() # GET-TIPS
self.conn.run_one_step() # PEERS
self.conn.run_one_step() # TIPS
invalid_payload = {
'id': '123',
'entrypoints': ['tcp://localhost:1234']
}
yield self._send_cmd(self.conn.proto1, 'PEER-ID',
json.dumps(invalid_payload))
self._check_result_only_cmd(self.conn.peek_tr1_value(), b'ERROR')
self.assertTrue(self.conn.tr1.disconnecting)
def test_invalid_same_peer_id(self):
manager3 = self.create_peer(self.network, peer_id=self.peer_id1)
conn = FakeConnection(self.manager1, manager3)
conn.run_one_step() # HELLO
conn.run_one_step() # PEER-ID
self._check_result_only_cmd(conn.peek_tr1_value(), b'ERROR')
self.assertTrue(conn.tr1.disconnecting)
def test_invalid_same_peer_id2(self):
"""
We connect nodes 1-2 and 1-3. Nodes 2 and 3 have the same peer_id. The connections
are established simultaneously, so we do not detect a peer id duplication in PEER_ID
state, only on READY state.
"""
# Disable idle timeout before creating any new peer because self.create_peer(...)
# runs the main loop.
self.conn.disable_idle_timeout()
# Create new peer and disable idle timeout.
manager3 = self.create_peer(self.network, peer_id=self.peer_id2)
conn = FakeConnection(manager3, self.manager1)
# Disable idle timeout.
conn.disable_idle_timeout()
# HELLO
self.assertEqual(self.conn.peek_tr1_value().split()[0], b'HELLO')
self.assertEqual(self.conn.peek_tr2_value().split()[0], b'HELLO')
self.assertEqual(conn.peek_tr1_value().split()[0], b'HELLO')
self.assertEqual(conn.peek_tr2_value().split()[0], b'HELLO')
self.conn.run_one_step()
conn.run_one_step()
# PEER-ID
self.assertEqual(self.conn.peek_tr1_value().split()[0], b'PEER-ID')
self.assertEqual(self.conn.peek_tr2_value().split()[0], b'PEER-ID')
self.assertEqual(conn.peek_tr1_value().split()[0], b'PEER-ID')
self.assertEqual(conn.peek_tr2_value().split()[0], b'PEER-ID')
self.conn.run_one_step()
conn.run_one_step()
# READY
self.assertEqual(self.conn.peek_tr1_value().split()[0], b'READY')
self.assertEqual(self.conn.peek_tr2_value().split()[0], b'READY')
self.assertEqual(conn.peek_tr1_value().split()[0], b'READY')
self.assertEqual(conn.peek_tr2_value().split()[0], b'READY')
self.conn.run_one_step()
conn.run_one_step()
# continue until messages stop
self.conn.run_until_complete()
conn.run_until_complete()
self.run_to_completion()
# one of the peers will close the connection. We don't know which on, as it depends
# on the peer ids
conn1_value = self.conn.peek_tr1_value() + self.conn.peek_tr2_value()
conn2_value = conn.peek_tr1_value() + conn.peek_tr2_value()
if b'ERROR' in conn1_value:
conn_dead = self.conn
conn_alive = conn
elif b'ERROR' in conn2_value:
conn_dead = conn
conn_alive = self.conn
else:
raise Exception('It should never happen.')
self._check_result_only_cmd(
conn_dead.peek_tr1_value() + conn_dead.peek_tr2_value(), b'ERROR')
# at this point, the connection must be closing as the error was detected on READY state
self.assertIn(
True, [conn_dead.tr1.disconnecting, conn_dead.tr2.disconnecting])
# check connected_peers
connected_peers = list(
self.manager1.connections.connected_peers.values())
self.assertEquals(1, len(connected_peers))
self.assertIn(connected_peers[0],
[conn_alive.proto1, conn_alive.proto2])
# connection is still up
self.assertIsConnected(conn_alive)
def test_invalid_different_network(self):
manager3 = self.create_peer(network='mainnet')
conn = FakeConnection(self.manager1, manager3)
conn.run_one_step() # HELLO
self._check_result_only_cmd(conn.peek_tr1_value(), b'ERROR')
self.assertTrue(conn.tr1.disconnecting)
conn.run_one_step() # ERROR
def test_valid_hello_and_peer_id(self):
self._check_result_only_cmd(self.conn.peek_tr1_value(), b'HELLO')
self._check_result_only_cmd(self.conn.peek_tr2_value(), b'HELLO')
self.conn.run_one_step() # HELLO
self._check_result_only_cmd(self.conn.peek_tr1_value(), b'PEER-ID')
self._check_result_only_cmd(self.conn.peek_tr2_value(), b'PEER-ID')
self.conn.run_one_step() # PEER-ID
self._check_result_only_cmd(self.conn.peek_tr1_value(), b'READY')
self._check_result_only_cmd(self.conn.peek_tr2_value(), b'READY')
self.conn.run_one_step() # READY
self._check_result_only_cmd(self.conn.peek_tr1_value(), b'GET-PEERS')
self._check_result_only_cmd(self.conn.peek_tr2_value(), b'GET-PEERS')
self.conn.run_one_step() # GET-PEERS
self._check_result_only_cmd(self.conn.peek_tr1_value(), b'GET-TIPS')
self._check_result_only_cmd(self.conn.peek_tr2_value(), b'GET-TIPS')
self.conn.run_one_step() # GET-TIPS
self.assertIsConnected()
self._check_result_only_cmd(self.conn.peek_tr1_value(), b'PEERS')
self._check_result_only_cmd(self.conn.peek_tr2_value(), b'PEERS')
self.conn.run_one_step() # PEERS
self._check_result_only_cmd(self.conn.peek_tr1_value(), b'TIPS')
self._check_result_only_cmd(self.conn.peek_tr2_value(), b'TIPS')
self.conn.run_one_step() # TIPS
self.assertIsConnected()
def test_send_ping(self):
self.conn.run_one_step() # HELLO
self.conn.run_one_step() # PEER-ID
self.conn.run_one_step() # READY
self.conn.run_one_step() # GET-PEERS
self.conn.run_one_step() # GET-TIPS
self.conn.run_one_step() # PEERS
self.conn.run_one_step() # TIPS
self.assertIsConnected()
self.clock.advance(5)
self.assertEqual(b'PING\r\n', self.conn.peek_tr1_value())
self.assertEqual(b'PING\r\n', self.conn.peek_tr2_value())
self.conn.run_one_step() # PING
self.conn.run_one_step() # GET-TIPS
self.assertEqual(b'PONG\r\n', self.conn.peek_tr1_value())
self.assertEqual(b'PONG\r\n', self.conn.peek_tr2_value())
while b'PONG\r\n' in self.conn.peek_tr1_value():
self.conn.run_one_step()
self.assertEqual(self.clock.seconds(), self.conn.proto1.last_message)
def test_send_invalid_unicode(self):
# \xff is an invalid unicode.
self.conn.proto1.dataReceived(b'\xff\r\n')
self.assertTrue(self.conn.tr1.disconnecting)
def test_on_disconnect(self):
self.assertIn(self.conn.proto1,
self.manager1.connections.handshaking_peers)
self.conn.disconnect(Failure(Exception('testing')))
self.assertNotIn(self.conn.proto1,
self.manager1.connections.handshaking_peers)
def test_on_disconnect_after_hello(self):
self.conn.run_one_step() # HELLO
self.assertIn(self.conn.proto1,
self.manager1.connections.handshaking_peers)
self.conn.disconnect(Failure(Exception('testing')))
self.assertNotIn(self.conn.proto1,
self.manager1.connections.handshaking_peers)
def test_on_disconnect_after_peer_id(self):
self.conn.run_one_step() # HELLO
self.assertIn(self.conn.proto1,
self.manager1.connections.handshaking_peers)
# No peer id in the peer_storage (known_peers)
self.assertNotIn(self.peer_id2.id,
self.manager1.connections.peer_storage)
# The peer READY now depends on a message exchange from both peers, so we need one more step
self.conn.run_one_step() # PEER-ID
self.conn.run_one_step() # READY
self.assertIn(self.conn.proto1,
self.manager1.connections.connected_peers.values())
# Peer id 2 in the peer_storage (known_peers) after connection
self.assertIn(self.peer_id2.id, self.manager1.connections.peer_storage)
self.assertNotIn(self.conn.proto1,
self.manager1.connections.handshaking_peers)
self.conn.disconnect(Failure(Exception('testing')))
# Peer id 2 in the peer_storage (known_peers) after disconnection but before looping call
self.assertIn(self.peer_id2.id, self.manager1.connections.peer_storage)
self.assertNotIn(self.conn.proto1,
self.manager1.connections.connected_peers.values())
self.clock.advance(10)
# Peer id 2 removed from peer_storage (known_peers) after disconnection and after looping call
self.assertNotIn(self.peer_id2.id,
self.manager1.connections.peer_storage)
def test_two_connections(self):
self.conn.run_one_step() # HELLO
self.conn.run_one_step() # PEER-ID
self.conn.run_one_step() # READY
self.conn.run_one_step() # GET-PEERS
self.conn.run_one_step() # GET-TIPS
manager3 = self.create_peer(self.network)
conn = FakeConnection(self.manager1, manager3)
conn.run_one_step() # HELLO
conn.run_one_step() # PEER-ID
conn.run_one_step() # READY
conn.run_one_step() # GET-PEERS
self._check_result_only_cmd(self.conn.peek_tr1_value(), b'PEERS')
self.conn.run_one_step()
def test_idle_connection(self):
self.clock.advance(settings.PEER_IDLE_TIMEOUT - 10)
self.assertIsConnected(self.conn)
self.clock.advance(15)
self.assertIsNotConnected(self.conn)
@inlineCallbacks
def test_get_data(self):
self.conn.run_one_step() # HELLO
self.conn.run_one_step() # PEER-ID
self.conn.run_one_step() # READY
self.conn.run_one_step() # GET-PEERS
self.conn.run_one_step() # GET-TIPS
self.conn.run_one_step() # PEERS
self.conn.run_one_step() # TIPS
self.assertIsConnected()
missing_tx = '00000000228dfcd5dec1c9c6263f6430a5b4316bb9e3decb9441a6414bfd8697'
yield self._send_cmd(self.conn.proto1, 'GET-DATA', missing_tx)
self._check_result_only_cmd(self.conn.peek_tr1_value(), b'NOT-FOUND')
self.conn.run_one_step()
def test_invalid_same_peer_id2(self):
"""
We connect nodes 1-2 and 1-3. Nodes 2 and 3 have the same peer_id. The connections
are established simultaneously, so we do not detect a peer id duplication in PEER_ID
state, only on READY state.
"""
# Disable idle timeout before creating any new peer because self.create_peer(...)
# runs the main loop.
self.conn.disable_idle_timeout()
# Create new peer and disable idle timeout.
manager3 = self.create_peer(self.network, peer_id=self.peer_id2)
conn = FakeConnection(manager3, self.manager1)
# Disable idle timeout.
conn.disable_idle_timeout()
# HELLO
self.assertEqual(self.conn.peek_tr1_value().split()[0], b'HELLO')
self.assertEqual(self.conn.peek_tr2_value().split()[0], b'HELLO')
self.assertEqual(conn.peek_tr1_value().split()[0], b'HELLO')
self.assertEqual(conn.peek_tr2_value().split()[0], b'HELLO')
self.conn.run_one_step()
conn.run_one_step()
# PEER-ID
self.assertEqual(self.conn.peek_tr1_value().split()[0], b'PEER-ID')
self.assertEqual(self.conn.peek_tr2_value().split()[0], b'PEER-ID')
self.assertEqual(conn.peek_tr1_value().split()[0], b'PEER-ID')
self.assertEqual(conn.peek_tr2_value().split()[0], b'PEER-ID')
self.conn.run_one_step()
conn.run_one_step()
# READY
self.assertEqual(self.conn.peek_tr1_value().split()[0], b'READY')
self.assertEqual(self.conn.peek_tr2_value().split()[0], b'READY')
self.assertEqual(conn.peek_tr1_value().split()[0], b'READY')
self.assertEqual(conn.peek_tr2_value().split()[0], b'READY')
self.conn.run_one_step()
conn.run_one_step()
# continue until messages stop
self.conn.run_until_complete()
conn.run_until_complete()
self.run_to_completion()
# one of the peers will close the connection. We don't know which on, as it depends
# on the peer ids
conn1_value = self.conn.peek_tr1_value() + self.conn.peek_tr2_value()
conn2_value = conn.peek_tr1_value() + conn.peek_tr2_value()
if b'ERROR' in conn1_value:
conn_dead = self.conn
conn_alive = conn
elif b'ERROR' in conn2_value:
conn_dead = conn
conn_alive = self.conn
else:
raise Exception('It should never happen.')
self._check_result_only_cmd(
conn_dead.peek_tr1_value() + conn_dead.peek_tr2_value(), b'ERROR')
# at this point, the connection must be closing as the error was detected on READY state
self.assertIn(
True, [conn_dead.tr1.disconnecting, conn_dead.tr2.disconnecting])
# check connected_peers
connected_peers = list(
self.manager1.connections.connected_peers.values())
self.assertEquals(1, len(connected_peers))
self.assertIn(connected_peers[0],
[conn_alive.proto1, conn_alive.proto2])
# connection is still up
self.assertIsConnected(conn_alive)
def test_soft_voided(self):
txA_hash = bytes.fromhex('4586c5428e8d666ea59684c1cd9286d2b9d9e89b4939207db47412eeaabc48b2')
txB_hash = bytes.fromhex('d19bee149abdce63bbfd523c90c3cf110563970a34100b2a62583a1eba48dfc8')
soft_voided_tx_ids = set([
txA_hash,
txB_hash,
])
manager1 = self.create_peer(soft_voided_tx_ids=soft_voided_tx_ids)
manager1.allow_mining_without_peers()
miner1 = self.simulator.create_miner(manager1, hashpower=5e6)
miner1.start()
self.simulator.run(60)
gen_tx1 = self.simulator.create_tx_generator(manager1, rate=3 / 60., hashpower=1e6, ignore_no_funds=True)
gen_tx1.start()
self.simulator.run(300)
manager2 = self.create_peer(soft_voided_tx_ids=soft_voided_tx_ids)
manager2.soft_voided_tx_ids = soft_voided_tx_ids
self.graphviz = GraphvizVisualizer(manager2.tx_storage, include_verifications=True, include_funds=True)
conn12 = FakeConnection(manager1, manager2, latency=0.001)
self.simulator.add_connection(conn12)
miner2 = self.simulator.create_miner(manager2, hashpower=10e6)
miner2.start()
gen_tx2 = self.simulator.create_tx_generator(manager2, rate=10 / 60., hashpower=1e6, ignore_no_funds=True)
gen_tx2.start()
self.simulator.run(900)
miner2.stop()
gen_tx2.stop()
txB = manager2.tx_storage.get_transaction(txB_hash)
# Get the tx confirmed by the soft voided that will be voided
tx_base = manager2.tx_storage.get_transaction(txB.parents[0])
txC = gen_new_double_spending(manager2, use_same_parents=False, tx=tx_base)
txC.weight = 25
txC.parents = tx_base.parents
txC.update_hash()
self.graphviz.labels[txC.hash] = 'txC'
self.assertTrue(manager2.propagate_tx(txC, fails_silently=False))
metaC = txC.get_metadata()
self.assertIsNone(metaC.voided_by)
meta_base = tx_base.get_metadata()
self.assertEqual(meta_base.voided_by, {tx_base.hash})
# Create 2 blocks confirming C in order to keep this voidance when we add
# the block confirming the soft voided tx
blk1 = manager2.generate_mining_block()
if txC.hash not in blk1.parents:
blk1.parents[1] = txC.hash
blk1.nonce = self.rng.getrandbits(32)
blk1.update_hash()
self.assertTrue(manager2.propagate_tx(blk1, fails_silently=False))
blk1meta = blk1.get_metadata()
self.assertIsNone(blk1meta.voided_by)
blk2 = manager2.generate_mining_block()
if txC.hash not in blk2.parents:
blk2.parents[1] = txC.hash
blk2.nonce = self.rng.getrandbits(32)
blk2.update_hash()
self.assertTrue(manager2.propagate_tx(blk2, fails_silently=False))
blk2meta = blk2.get_metadata()
self.assertIsNone(blk2meta.voided_by)
# Create block that confirms soft voided
blk3 = manager2.generate_mining_block()
if txB.hash not in blk3.parents:
blk3.parents[1] = txB.hash
blk3.nonce = self.rng.getrandbits(32)
blk3.update_hash()
self.assertTrue(manager2.propagate_tx(blk3, fails_silently=False))
blk3meta = blk3.get_metadata()
self.simulator.run(10)
txD = add_custom_tx(manager2, [(txC, 0)], base_parent=txB)
# dot = self.graphviz.dot()
# dot.render('dot0')
blk3meta = blk3.get_metadata()
self.assertEqual(blk3meta.voided_by, {tx_base.hash, blk3meta.hash})
metaD = txD.get_metadata()
self.assertEqual(metaD.voided_by, {tx_base.hash})
def test_split_brain(self):
debug_pdf = False
manager1 = self.create_peer(self.network, unlock_wallet=True)
manager1.avg_time_between_blocks = 3
manager2 = self.create_peer(self.network, unlock_wallet=True)
manager2.avg_time_between_blocks = 3
for _ in range(10):
add_new_block(manager1, advance_clock=1)
add_blocks_unlock_reward(manager1)
add_new_block(manager2, advance_clock=1)
add_blocks_unlock_reward(manager2)
self.clock.advance(10)
for _ in range(random.randint(3, 10)):
add_new_transactions(manager1, random.randint(2, 4), advance_clock=1)
add_new_transactions(manager2, random.randint(3, 7), advance_clock=1)
add_new_double_spending(manager1)
add_new_double_spending(manager2)
self.clock.advance(10)
self.clock.advance(20)
if debug_pdf:
dot1 = GraphvizVisualizer(manager1.tx_storage, include_verifications=True).dot()
dot1.render('dot1-pre')
self.assertTipsNotEqual(manager1, manager2)
self.assertConsensusValid(manager1)
self.assertConsensusValid(manager2)
# input('Press enter to continue...')
conn = FakeConnection(manager1, manager2)
conn.run_one_step() # HELLO
conn.run_one_step() # PEER-ID
conn.run_one_step() # READY
conn.run_one_step() # GET-PEERS
conn.run_one_step() # GET-TIPS
conn.run_one_step() # PEERS
conn.run_one_step() # TIPS
empty_counter = 0
for i in range(2000):
if conn.is_empty():
empty_counter += 1
if empty_counter > 10:
break
else:
empty_counter = 0
conn.run_one_step()
self.clock.advance(0.2)
if debug_pdf:
dot1 = GraphvizVisualizer(manager1.tx_storage, include_verifications=True).dot()
dot1.render('dot1-post')
dot2 = GraphvizVisualizer(manager2.tx_storage, include_verifications=True).dot()
dot2.render('dot2-post')
node_sync = conn.proto1.state.sync_manager
self.assertEqual(node_sync.synced_timestamp, node_sync.peer_timestamp)
self.assertTipsEqual(manager1, manager2)
self.assertConsensusEqual(manager1, manager2)
self.assertConsensusValid(manager1)
self.assertConsensusValid(manager2)
class BaseStatusTest(_BaseResourceTest._ResourceTest):
__test__ = False
def setUp(self):
super().setUp()
self.web = StubSite(StatusResource(self.manager))
self.manager2 = self.create_peer('testnet')
self.conn1 = FakeConnection(self.manager, self.manager2)
@inlineCallbacks
def test_get(self):
response = yield self.web.get("status")
data = response.json_value()
server_data = data.get('server')
self.assertEqual(server_data['app_version'],
'Hathor v{}'.format(hathor.__version__))
self.assertEqual(server_data['network'], 'testnet')
self.assertGreater(server_data['uptime'], 0)
@inlineCallbacks
def test_handshaking(self):
response = yield self.web.get("status")
data = response.json_value()
server_data = data.get('server')
known_peers = data.get('known_peers')
connections = data.get('connections')
self.assertEqual(server_data['app_version'],
'Hathor v{}'.format(hathor.__version__))
self.assertEqual(server_data['network'], 'testnet')
self.assertGreater(server_data['uptime'], 0)
handshake_peer = self.conn1.proto1.transport.getPeer()
handshake_address = '{}:{}'.format(handshake_peer.host,
handshake_peer.port)
self.assertEqual(len(known_peers), 0)
self.assertEqual(len(connections['connected_peers']), 0)
self.assertEqual(len(connections['handshaking_peers']), 1)
self.assertEqual(connections['handshaking_peers'][0]['address'],
handshake_address)
@inlineCallbacks
def test_get_with_one_peer(self):
self.conn1.run_one_step() # HELLO
self.conn1.run_one_step() # PEER-ID
self.conn1.run_one_step() # READY
self.conn1.run_one_step() # BOTH PEERS ARE READY NOW
response = yield self.web.get("status")
data = response.json_value()
server_data = data.get('server')
known_peers = data.get('known_peers')
connections = data.get('connections')
self.assertEqual(server_data['app_version'],
'Hathor v{}'.format(hathor.__version__))
self.assertEqual(server_data['network'], 'testnet')
self.assertGreater(server_data['uptime'], 0)
self.assertEqual(len(known_peers), 1)
self.assertEqual(known_peers[0]['id'], self.manager2.my_peer.id)
self.assertEqual(len(connections['connected_peers']), 1)
self.assertEqual(connections['connected_peers'][0]['id'],
self.manager2.my_peer.id)
@inlineCallbacks
def test_connecting_peers(self):
address = '192.168.1.1:54321'
endpoint = endpoints.clientFromString(self.manager.reactor,
'tcp:{}'.format(address))
deferred = endpoint.connect
self.manager.connections.connecting_peers[endpoint] = deferred
response = yield self.web.get("status")
data = response.json_value()
connecting = data['connections']['connecting_peers']
self.assertEqual(len(connecting), 1)
self.assertEqual(connecting[0]['address'], address)
self.assertIsNotNone(connecting[0]['deferred'])
