core-lightning/tests/test_closing.py
Rusty Russell 3b8c0a7397 sendpsbt: just reserve (maybe bump) inputs on send, don't mark spent.
Marking spent means if the transaction doesn't confirm for some
reason, the user will need to force a rescan to find the funds.  Now
we have timed reservations, reserving for (an additional) 12 hours
should be sufficient.

We also take this opportunity (now we have our own callback path)
to record the tx in the wallet only on success.

Signed-off-by: Rusty Russell <rusty@rustcorp.com.au>
2020-09-08 10:14:42 +09:30

2337 lines
96 KiB
Python

from fixtures import * # noqa: F401,F403
from flaky import flaky
from pyln.client import RpcError
from shutil import copyfile
from utils import (
only_one, sync_blockheight, wait_for, DEVELOPER, TIMEOUT,
account_balance, first_channel_id, basic_fee
)
import os
import queue
import pytest
import re
import threading
import unittest
@unittest.skipIf(not DEVELOPER, "Too slow without --dev-bitcoind-poll")
def test_closing(node_factory, bitcoind, chainparams):
l1, l2 = node_factory.line_graph(2)
chan = l1.get_channel_scid(l2)
fee = basic_fee(7500) if not chainparams['elements'] else 8955
l1.pay(l2, 200000000)
assert bitcoind.rpc.getmempoolinfo()['size'] == 0
billboard = only_one(l1.rpc.listpeers(l2.info['id'])['peers'][0]['channels'])['status']
assert billboard == ['CHANNELD_NORMAL:Funding transaction locked.']
billboard = only_one(l2.rpc.listpeers(l1.info['id'])['peers'][0]['channels'])['status']
assert billboard == ['CHANNELD_NORMAL:Funding transaction locked.']
bitcoind.generate_block(5)
# Only wait for the channels to activate with DEVELOPER=1,
# otherwise it's going to take too long because of the missing
# --dev-fast-gossip
if DEVELOPER:
wait_for(lambda: len(l1.getactivechannels()) == 2)
wait_for(lambda: len(l2.getactivechannels()) == 2)
billboard = only_one(l1.rpc.listpeers(l2.info['id'])['peers'][0]['channels'])['status']
# This may either be from a local_update or an announce, so just
# check for the substring
assert 'CHANNELD_NORMAL:Funding transaction locked.' in billboard[0]
l1.rpc.close(chan)
l1.daemon.wait_for_log(' to CHANNELD_SHUTTING_DOWN')
l2.daemon.wait_for_log(' to CHANNELD_SHUTTING_DOWN')
l1.daemon.wait_for_log(' to CLOSINGD_SIGEXCHANGE')
l2.daemon.wait_for_log(' to CLOSINGD_SIGEXCHANGE')
# And should put closing into mempool.
l1.daemon.wait_for_log('sendrawtx exit 0')
l2.daemon.wait_for_log('sendrawtx exit 0')
# Both nodes should have disabled the channel in their view
wait_for(lambda: len(l1.getactivechannels()) == 0)
wait_for(lambda: len(l2.getactivechannels()) == 0)
assert bitcoind.rpc.getmempoolinfo()['size'] == 1
# Now grab the close transaction
closetxid = only_one(bitcoind.rpc.getrawmempool(False))
billboard = only_one(l1.rpc.listpeers(l2.info['id'])['peers'][0]['channels'])['status']
assert billboard == [
'CLOSINGD_SIGEXCHANGE:We agreed on a closing fee of {} satoshi for tx:{}'.format(fee, closetxid),
]
bitcoind.generate_block(1)
l1.daemon.wait_for_log(r'Owning output.* \(SEGWIT\).* txid %s.* CONFIRMED' % closetxid)
l2.daemon.wait_for_log(r'Owning output.* \(SEGWIT\).* txid %s.* CONFIRMED' % closetxid)
# Make sure both nodes have grabbed their close tx funds
assert closetxid in set([o['txid'] for o in l1.rpc.listfunds()['outputs']])
assert closetxid in set([o['txid'] for o in l2.rpc.listfunds()['outputs']])
wait_for(lambda: only_one(l1.rpc.listpeers(l2.info['id'])['peers'][0]['channels'])['status'] == [
'CLOSINGD_SIGEXCHANGE:We agreed on a closing fee of {} satoshi for tx:{}'.format(fee, closetxid),
'ONCHAIN:Tracking mutual close transaction',
'ONCHAIN:All outputs resolved: waiting 99 more blocks before forgetting channel'
])
bitcoind.generate_block(9)
wait_for(lambda: only_one(l1.rpc.listpeers(l2.info['id'])['peers'][0]['channels'])['status'] == [
'CLOSINGD_SIGEXCHANGE:We agreed on a closing fee of {} satoshi for tx:{}'.format(fee, closetxid),
'ONCHAIN:Tracking mutual close transaction',
'ONCHAIN:All outputs resolved: waiting 90 more blocks before forgetting channel'
])
# Make sure both have forgotten about it
bitcoind.generate_block(90)
wait_for(lambda: len(l1.rpc.listchannels()['channels']) == 0)
wait_for(lambda: len(l2.rpc.listchannels()['channels']) == 0)
# The entry in the channels table should still be there
assert l1.db_query("SELECT count(*) as c FROM channels;")[0]['c'] == 1
assert l2.db_query("SELECT count(*) as c FROM channels;")[0]['c'] == 1
def test_closing_while_disconnected(node_factory, bitcoind, executor):
l1, l2 = node_factory.line_graph(2, opts={'may_reconnect': True})
chan = l1.get_channel_scid(l2)
l1.pay(l2, 200000000)
l2.stop()
# The close should still be triggered afterwards.
fut = executor.submit(l1.rpc.close, chan, 0)
l1.daemon.wait_for_log(' to CHANNELD_SHUTTING_DOWN')
l2.start()
fut.result(TIMEOUT)
l1.daemon.wait_for_log(' to CLOSINGD_SIGEXCHANGE')
l2.daemon.wait_for_log(' to CLOSINGD_SIGEXCHANGE')
# And should put closing into mempool.
l1.daemon.wait_for_log('sendrawtx exit 0')
l2.daemon.wait_for_log('sendrawtx exit 0')
bitcoind.generate_block(101)
wait_for(lambda: len(l1.rpc.listchannels()['channels']) == 0)
wait_for(lambda: len(l2.rpc.listchannels()['channels']) == 0)
def test_closing_id(node_factory):
"""Test closing using peer ID and full channel ID
"""
l1, l2 = node_factory.get_nodes(2)
# Close by full channel ID.
l1.rpc.connect(l2.info['id'], 'localhost', l2.port)
l1.fund_channel(l2, 10**6)
cid = l2.rpc.listpeers()['peers'][0]['channels'][0]['channel_id']
l2.rpc.close(cid)
wait_for(lambda: not only_one(l1.rpc.listpeers(l2.info['id'])['peers'])['connected'])
wait_for(lambda: not only_one(l2.rpc.listpeers(l1.info['id'])['peers'])['connected'])
# Close by peer ID.
l2.rpc.connect(l1.info['id'], 'localhost', l1.port)
l1.daemon.wait_for_log("Handed peer, entering loop")
l2.fund_channel(l1, 10**6)
pid = l1.info['id']
l2.rpc.close(pid)
wait_for(lambda: not only_one(l1.rpc.listpeers(l2.info['id'])['peers'])['connected'])
wait_for(lambda: not only_one(l2.rpc.listpeers(l1.info['id'])['peers'])['connected'])
@pytest.mark.slow_test
def test_closing_torture(node_factory, executor, bitcoind):
# We set up a fully-connected mesh of N nodes, then try
# closing them all at once.
amount = 10**6
num_nodes = 10 # => 45 channels (36 seconds on my laptop)
if node_factory.valgrind:
num_nodes -= 4 # => 15 (135 seconds)
nodes = node_factory.get_nodes(num_nodes)
# Make sure bitcoind has plenty of utxos
bitcoind.generate_block(num_nodes)
# Give them all plenty of UTXOs, make sure they see them
for i in range(len(nodes)):
for j in range(i + 1, len(nodes)):
addr = nodes[i].rpc.newaddr()['bech32']
bitcoind.rpc.sendtoaddress(addr, (amount + 1000000) / 10**8)
bitcoind.generate_block(1)
sync_blockheight(bitcoind, nodes)
txs = []
for i in range(len(nodes)):
for j in range(i + 1, len(nodes)):
nodes[i].rpc.connect(nodes[j].info['id'], 'localhost', nodes[j].port)
txs.append(nodes[i].rpc.fundchannel(nodes[j].info['id'], amount)['txid'])
# Make sure they're all in, then lock them in.
bitcoind.generate_block(1, wait_for_mempool=txs)
# Wait for them all to be CHANNELD_NORMAL
for n in nodes:
wait_for(lambda: all(p['channels'][0]['state'] == 'CHANNELD_NORMAL' for p in n.rpc.listpeers()['peers']))
# Start closers: can take a long time under valgrind!
futures = []
for i in range(len(nodes)):
for j in range(i + 1, len(nodes)):
futures.append(executor.submit(nodes[i].rpc.close, nodes[j].info['id']))
futures.append(executor.submit(nodes[j].rpc.close, nodes[i].info['id']))
# Wait for close to finish
close_txs = set()
for f in futures:
# If one side completes closing, we'll get an error here 'Peer has no active channel'
try:
close_txs.add(f.result(TIMEOUT)['txid'])
except RpcError as err:
assert err.error['message'] == 'Peer has no active channel'
# Should have one close for each open.
assert len(close_txs) == len(txs)
# Get closes confirmed
bitcoind.generate_block(100, wait_for_mempool=list(close_txs))
# And make sure they hangup.
for n in nodes:
wait_for(lambda: n.rpc.listpeers()['peers'] == [])
@pytest.mark.slow_test
def test_closing_different_fees(node_factory, bitcoind, executor):
l1 = node_factory.get_node()
# Default feerate = 15000/11000/7500/1000
# It will start at the second number, accepting anything above the first.
feerates = [[20000, 11000, 15000, 7400], [8000, 6000, 1001, 100]]
amounts = [0, 545999, 546000]
num_peers = len(feerates) * len(amounts)
addr = l1.rpc.newaddr()['bech32']
bitcoind.rpc.sendtoaddress(addr, 1)
numfunds = len(l1.rpc.listfunds()['outputs'])
bitcoind.generate_block(1)
wait_for(lambda: len(l1.rpc.listfunds()['outputs']) > numfunds)
# Create them in a batch, for speed!
peers = []
for feerate in feerates:
for amount in amounts:
p = node_factory.get_node(feerates=feerate)
p.feerate = feerate
p.amount = amount
l1.rpc.connect(p.info['id'], 'localhost', p.port)
peers.append(p)
for p in peers:
p.channel = l1.rpc.fundchannel(p.info['id'], 10**6, minconf=0)['channel_id']
# Technically, this is async to fundchannel returning.
l1.daemon.wait_for_log('sendrawtx exit 0')
bitcoind.generate_block(6)
# Now wait for them all to hit normal state, do payments
l1.daemon.wait_for_logs(['update for channel .* now ACTIVE'] * num_peers
+ ['to CHANNELD_NORMAL'] * num_peers)
for p in peers:
if p.amount != 0:
l1.pay(p, 100000000)
# Now close all channels (not unilaterally!)
closes = [executor.submit(l1.rpc.close, p.channel, 0) for p in peers]
for c in closes:
c.result(90)
# close does *not* wait for the sendrawtransaction, so do that!
# Note that since they disagree on the ideal fee, they may conflict
# (first one in will win), so we cannot look at logs, we need to
# wait for mempool.
wait_for(lambda: bitcoind.rpc.getmempoolinfo()['size'] == num_peers)
bitcoind.generate_block(1)
for p in peers:
p.daemon.wait_for_log(' to ONCHAIN')
wait_for(lambda: 'ONCHAIN:Tracking mutual close transaction' in only_one(p.rpc.listpeers(l1.info['id'])['peers'][0]['channels'])['status'])
l1.daemon.wait_for_logs([' to ONCHAIN'] * num_peers)
@unittest.skipIf(not DEVELOPER, "needs DEVELOPER=1")
def test_closing_negotiation_reconnect(node_factory, bitcoind):
disconnects = ['-WIRE_CLOSING_SIGNED',
'@WIRE_CLOSING_SIGNED',
'+WIRE_CLOSING_SIGNED']
l1, l2 = node_factory.line_graph(2, opts=[{'disconnect': disconnects,
'may_reconnect': True},
{'may_reconnect': True}])
l1.pay(l2, 200000000)
assert bitcoind.rpc.getmempoolinfo()['size'] == 0
l1.rpc.close(l2.info['id'])
l1.daemon.wait_for_log(' to CHANNELD_SHUTTING_DOWN')
l2.daemon.wait_for_log(' to CHANNELD_SHUTTING_DOWN')
l1.daemon.wait_for_log(' to CLOSINGD_SIGEXCHANGE')
l2.daemon.wait_for_log(' to CLOSINGD_SIGEXCHANGE')
# And should put closing into mempool (happens async, so
# CLOSINGD_COMPLETE may come first).
l1.daemon.wait_for_logs(['sendrawtx exit 0', ' to CLOSINGD_COMPLETE'])
l2.daemon.wait_for_logs(['sendrawtx exit 0', ' to CLOSINGD_COMPLETE'])
assert bitcoind.rpc.getmempoolinfo()['size'] == 1
@unittest.skipIf(not DEVELOPER, "needs DEVELOPER=1")
def test_closing_specified_destination(node_factory, bitcoind, chainparams):
l1, l2, l3, l4 = node_factory.get_nodes(4)
l1.rpc.connect(l2.info['id'], 'localhost', l2.port)
l1.rpc.connect(l3.info['id'], 'localhost', l3.port)
l1.rpc.connect(l4.info['id'], 'localhost', l4.port)
chan12 = l1.fund_channel(l2, 10**6)
chan13 = l1.fund_channel(l3, 10**6)
chan14 = l1.fund_channel(l4, 10**6)
l1.pay(l2, 100000000)
l1.pay(l3, 100000000)
l1.pay(l4, 100000000)
bitcoind.generate_block(5)
addr = chainparams['example_addr']
l1.rpc.close(chan12, None, addr)
l1.rpc.call('close', {'id': chan13, 'destination': addr})
l1.rpc.call('close', [chan14, None, addr])
l1.daemon.wait_for_logs([' to CLOSINGD_SIGEXCHANGE'] * 3)
# Both nodes should have disabled the channel in their view
wait_for(lambda: len(l1.getactivechannels()) == 0)
wait_for(lambda: bitcoind.rpc.getmempoolinfo()['size'] == 3)
# Now grab the close transaction
closetxs = {}
for i, n in enumerate([l2, l3, l4]):
billboard = only_one(l1.rpc.listpeers(n.info['id'])['peers'][0]['channels'])['status'][0]
m = re.search(r'CLOSINGD_SIGEXCHANGE.* tx:([a-f0-9]{64})', billboard)
closetxs[n] = m.group(1)
bitcoind.generate_block(1)
sync_blockheight(bitcoind, [l1, l2, l3, l4])
# l1 can't spent the output to addr.
for txid in closetxs.values():
assert not l1.daemon.is_in_log(r'Owning output.* \(SEGWIT\).* txid {}.* CONFIRMED'.format(txid))
# Check the txid has at least 1 confirmation
for n, txid in closetxs.items():
n.daemon.wait_for_log(r'Owning output.* \(SEGWIT\).* txid {}.* CONFIRMED'.format(txid))
for n in [l2, l3, l4]:
# Make sure both nodes have grabbed their close tx funds
closetx = closetxs[n]
outputs = n.rpc.listfunds()['outputs']
assert closetx in set([o['txid'] for o in outputs])
output_num2 = [o for o in outputs if o['txid'] == closetx][0]['output']
output_num1 = 0 if output_num2 == 1 else 1
# Check the another address is addr
assert addr == bitcoind.rpc.gettxout(closetx, output_num1)['scriptPubKey']['addresses'][0]
assert 1 == bitcoind.rpc.gettxout(closetx, output_num1)['confirmations']
def closing_negotiation_step(node_factory, bitcoind, chainparams, opts):
def feerate_for(target, minimum=0, maximum=10000000):
"""Binary search to find feerate"""
assert minimum != maximum
mid = (minimum + maximum) // 2
mid_fee = basic_fee(mid)
if mid_fee > target:
return feerate_for(target, minimum, mid)
elif mid_fee < target:
return feerate_for(target, mid, maximum)
else:
return mid
orate = feerate_for(21000) # closing fee negotiation starts at 21000
prate = feerate_for(20000) # closing fee negotiation starts at 20000
opener, peer = node_factory.line_graph(2, opts=[{'feerates': (orate, orate, orate, orate)},
{'feerates': (prate, prate, prate, prate)}])
opener_id = opener.info['id']
peer_id = peer.info['id']
assert bitcoind.rpc.getmempoolinfo()['size'] == 0
if opts['close_initiated_by'] == 'opener':
opener.rpc.close(peer_id=peer_id, fee_negotiation_step=opts['fee_negotiation_step'])
else:
assert opts['close_initiated_by'] == 'peer'
peer.rpc.close(peer_id=opener_id, fee_negotiation_step=opts['fee_negotiation_step'])
# Get the proclaimed closing fee from the two nodes' statuses
status_agreed_regex = re.compile("agreed on a closing fee of ([0-9]+) satoshi")
# [fee_from_opener_status, fee_from_peer_status]
fees_from_status = [None, None]
def get_fee_from_status(node, peer_id, i):
nonlocal fees_from_status
status = only_one(only_one(node.rpc.listpeers(peer_id)['peers'][0]['channels'])['status'])
m = status_agreed_regex.search(status)
if not m:
return False
fees_from_status[i] = int(m.group(1))
return True
wait_for(lambda: get_fee_from_status(opener, peer_id, 0))
wait_for(lambda: get_fee_from_status(peer, opener_id, 1))
assert opts['expected_close_fee'] == fees_from_status[0]
assert opts['expected_close_fee'] == fees_from_status[1]
# Get the closing transaction from the bitcoind mempool and get its fee
mempool = None
mempool_tx_ids = None
def get_mempool_when_size_1():
nonlocal mempool, mempool_tx_ids
mempool = bitcoind.rpc.getrawmempool(True)
mempool_tx_ids = list(mempool.keys())
return len(mempool_tx_ids) == 1
wait_for(get_mempool_when_size_1)
close_tx_id = mempool_tx_ids[0]
fee_mempool = round(mempool[close_tx_id]['fee'] * 10**8)
assert opts['expected_close_fee'] == fee_mempool
def test_closing_negotiation_step_30pct(node_factory, bitcoind, chainparams):
"""Test that the closing fee negotiation step works, 30%"""
opts = {}
opts['fee_negotiation_step'] = '30%'
opts['close_initiated_by'] = 'opener'
opts['expected_close_fee'] = 20537 if not chainparams['elements'] else 33870
closing_negotiation_step(node_factory, bitcoind, chainparams, opts)
opts['close_initiated_by'] = 'peer'
opts['expected_close_fee'] = 20233 if not chainparams['elements'] else 33366
closing_negotiation_step(node_factory, bitcoind, chainparams, opts)
def test_closing_negotiation_step_50pct(node_factory, bitcoind, chainparams):
"""Test that the closing fee negotiation step works, 50%, the default"""
opts = {}
opts['fee_negotiation_step'] = '50%'
opts['close_initiated_by'] = 'opener'
opts['expected_close_fee'] = 20334 if not chainparams['elements'] else 33533
closing_negotiation_step(node_factory, bitcoind, chainparams, opts)
opts['close_initiated_by'] = 'peer'
opts['expected_close_fee'] = 20334 if not chainparams['elements'] else 33533
closing_negotiation_step(node_factory, bitcoind, chainparams, opts)
def test_closing_negotiation_step_100pct(node_factory, bitcoind, chainparams):
"""Test that the closing fee negotiation step works, 100%"""
opts = {}
opts['fee_negotiation_step'] = '100%'
opts['close_initiated_by'] = 'opener'
opts['expected_close_fee'] = 20001 if not chainparams['elements'] else 32985
closing_negotiation_step(node_factory, bitcoind, chainparams, opts)
# The close fee of 20499 looks strange in this case - one would expect
# to have a number close to 21000. This is because
# * the range is initially set to [20000 (peer), 21000 (opener)]
# * the opener is always first to propose, he uses 50% step, so he proposes 20500
# * the range is narrowed to [20001, 20499] and the peer proposes 20499
opts['close_initiated_by'] = 'peer'
opts['expected_close_fee'] = 20499 if not chainparams['elements'] else 33808
closing_negotiation_step(node_factory, bitcoind, chainparams, opts)
def test_closing_negotiation_step_1sat(node_factory, bitcoind, chainparams):
"""Test that the closing fee negotiation step works, 1sat"""
opts = {}
opts['fee_negotiation_step'] = '1'
opts['close_initiated_by'] = 'opener'
opts['expected_close_fee'] = 20989 if not chainparams['elements'] else 34621
closing_negotiation_step(node_factory, bitcoind, chainparams, opts)
opts['close_initiated_by'] = 'peer'
opts['expected_close_fee'] = 20010 if not chainparams['elements'] else 32995
closing_negotiation_step(node_factory, bitcoind, chainparams, opts)
def test_closing_negotiation_step_700sat(node_factory, bitcoind, chainparams):
"""Test that the closing fee negotiation step works, 700sat"""
opts = {}
opts['fee_negotiation_step'] = '700'
opts['close_initiated_by'] = 'opener'
opts['expected_close_fee'] = 20151 if not chainparams['elements'] else 33459
closing_negotiation_step(node_factory, bitcoind, chainparams, opts)
opts['close_initiated_by'] = 'peer'
opts['expected_close_fee'] = 20499 if not chainparams['elements'] else 33746
closing_negotiation_step(node_factory, bitcoind, chainparams, opts)
@unittest.skipIf(not DEVELOPER, "needs DEVELOPER=1")
def test_penalty_inhtlc(node_factory, bitcoind, executor, chainparams):
"""Test penalty transaction with an incoming HTLC"""
# We track channel balances, to verify that accounting is ok.
coin_mvt_plugin = os.path.join(os.getcwd(), 'tests/plugins/coin_movements.py')
# We suppress each one after first commit; HTLC gets added not fulfilled.
# Feerates identical so we don't get gratuitous commit to update them
l1, l2 = node_factory.line_graph(2, opts=[{'disconnect': ['=WIRE_COMMITMENT_SIGNED-nocommit'],
'may_fail': True,
'feerates': (7500, 7500, 7500, 7500),
'allow_broken_log': True,
'plugin': coin_mvt_plugin},
{'disconnect': ['=WIRE_COMMITMENT_SIGNED-nocommit'],
'plugin': coin_mvt_plugin}])
channel_id = first_channel_id(l1, l2)
# Now, this will get stuck due to l1 commit being disabled..
t = executor.submit(l1.pay, l2, 100000000)
assert len(l1.getactivechannels()) == 2
assert len(l2.getactivechannels()) == 2
# They should both have commitments blocked now.
l1.daemon.wait_for_log('=WIRE_COMMITMENT_SIGNED-nocommit')
l2.daemon.wait_for_log('=WIRE_COMMITMENT_SIGNED-nocommit')
# Make sure l1 got l2's commitment to the HTLC, and sent to master.
l1.daemon.wait_for_log('got commitsig')
# Take our snapshot.
tx = l1.rpc.dev_sign_last_tx(l2.info['id'])['tx']
# Let them continue
l1.rpc.dev_reenable_commit(l2.info['id'])
l2.rpc.dev_reenable_commit(l1.info['id'])
# Should fulfill.
l1.daemon.wait_for_log('peer_in WIRE_UPDATE_FULFILL_HTLC')
l1.daemon.wait_for_log('peer_out WIRE_REVOKE_AND_ACK')
l2.daemon.wait_for_log('peer_out WIRE_UPDATE_FULFILL_HTLC')
l1.daemon.wait_for_log('peer_in WIRE_REVOKE_AND_ACK')
# Payment should now complete.
t.result(timeout=10)
# Now we really mess things up!
bitcoind.rpc.sendrawtransaction(tx)
bitcoind.generate_block(1)
l2.daemon.wait_for_log(' to ONCHAIN')
# FIXME: l1 should try to stumble along!
wait_for(lambda: len(l2.getactivechannels()) == 0)
# l2 should spend all of the outputs (except to-us).
# Could happen in any order, depending on commitment tx.
needle = l2.daemon.logsearch_start
l2.wait_for_onchaind_broadcast('OUR_PENALTY_TX',
'THEIR_REVOKED_UNILATERAL/DELAYED_CHEAT_OUTPUT_TO_THEM')
l2.daemon.logsearch_start = needle
l2.wait_for_onchaind_broadcast('OUR_PENALTY_TX',
'THEIR_REVOKED_UNILATERAL/THEIR_HTLC')
# FIXME: test HTLC tx race!
bitcoind.generate_block(100)
sync_blockheight(bitcoind, [l2])
wait_for(lambda: len(l2.rpc.listpeers()['peers']) == 0)
# Do one last pass over the logs to extract the reactions l2 sent
l2.daemon.logsearch_start = needle
needles = [
# The first needle will match, but since we don't have a direct output
# for l2 it won't result in an output, hence the comment:
# r'Resolved FUNDING_TRANSACTION/FUNDING_OUTPUT by THEIR_REVOKED_UNILATERAL .([a-f0-9]{64}).',
r'Resolved THEIR_REVOKED_UNILATERAL/DELAYED_CHEAT_OUTPUT_TO_THEM by our proposal OUR_PENALTY_TX .([a-f0-9]{64}).',
r'Resolved THEIR_REVOKED_UNILATERAL/THEIR_HTLC by our proposal OUR_PENALTY_TX .([a-f0-9]{64}).',
]
matches = list(map(l2.daemon.is_in_log, needles))
# Now extract the txids for these responses
txids = set([re.search(r'\(([0-9a-f]{64})\)', m).group(1) for m in matches])
# We should have one confirmed output for each of the above reactions in
# the list of funds we own.
outputs = l2.rpc.listfunds()['outputs']
assert [o['status'] for o in outputs] == ['confirmed'] * 2
assert set([o['txid'] for o in outputs]) == txids
assert account_balance(l2, channel_id) == 0
@unittest.skipIf(not DEVELOPER, "needs DEVELOPER=1")
def test_penalty_outhtlc(node_factory, bitcoind, executor, chainparams):
"""Test penalty transaction with an outgoing HTLC"""
# We track channel balances, to verify that accounting is ok.
coin_mvt_plugin = os.path.join(os.getcwd(), 'tests/plugins/coin_movements.py')
# First we need to get funds to l2, so suppress after second.
# Feerates identical so we don't get gratuitous commit to update them
l1, l2 = node_factory.line_graph(2,
opts=[{'disconnect': ['=WIRE_COMMITMENT_SIGNED*3-nocommit'],
'may_fail': True,
'feerates': (7500, 7500, 7500, 7500),
'allow_broken_log': True,
'plugin': coin_mvt_plugin},
{'disconnect': ['=WIRE_COMMITMENT_SIGNED*3-nocommit'],
'plugin': coin_mvt_plugin}])
channel_id = first_channel_id(l1, l2)
# Move some across to l2.
l1.pay(l2, 200000000)
assert not l1.daemon.is_in_log('=WIRE_COMMITMENT_SIGNED')
assert not l2.daemon.is_in_log('=WIRE_COMMITMENT_SIGNED')
# Now, this will get stuck due to l1 commit being disabled..
t = executor.submit(l2.pay, l1, 100000000)
# Make sure we get signature from them.
l1.daemon.wait_for_log('peer_in WIRE_UPDATE_ADD_HTLC')
l1.daemon.wait_for_log('peer_in WIRE_COMMITMENT_SIGNED')
# They should both have commitments blocked now.
l1.daemon.wait_for_log('dev_disconnect: =WIRE_COMMITMENT_SIGNED')
l2.daemon.wait_for_log('dev_disconnect: =WIRE_COMMITMENT_SIGNED')
# Make sure both sides got revoke_and_ack for that commitment.
l1.daemon.wait_for_log('peer_in WIRE_REVOKE_AND_ACK')
l2.daemon.wait_for_log('peer_in WIRE_REVOKE_AND_ACK')
# Take our snapshot.
tx = l1.rpc.dev_sign_last_tx(l2.info['id'])['tx']
# Let them continue
l1.rpc.dev_reenable_commit(l2.info['id'])
l2.rpc.dev_reenable_commit(l1.info['id'])
# Thread should complete.
t.result(timeout=10)
# Make sure both sides got revoke_and_ack for final.
l1.daemon.wait_for_log('peer_in WIRE_REVOKE_AND_ACK')
l2.daemon.wait_for_log('peer_in WIRE_REVOKE_AND_ACK')
# Now we really mess things up!
bitcoind.rpc.sendrawtransaction(tx)
bitcoind.generate_block(1)
l2.daemon.wait_for_log(' to ONCHAIN')
# FIXME: l1 should try to stumble along!
# l2 should spend all of the outputs (except to-us).
# Could happen in any order, depending on commitment tx.
needle = l2.daemon.logsearch_start
l2.wait_for_onchaind_broadcast('OUR_PENALTY_TX',
'THEIR_REVOKED_UNILATERAL/DELAYED_CHEAT_OUTPUT_TO_THEM')
l2.daemon.logsearch_start = needle
l2.wait_for_onchaind_broadcast('OUR_PENALTY_TX',
'THEIR_REVOKED_UNILATERAL/OUR_HTLC')
l2.daemon.logsearch_start = needle
l2.daemon.wait_for_log('Ignoring output.*: THEIR_REVOKED_UNILATERAL/OUTPUT_TO_US')
# FIXME: test HTLC tx race!
# 100 blocks later, all resolved.
bitcoind.generate_block(100)
sync_blockheight(bitcoind, [l2])
wait_for(lambda: len(l2.rpc.listpeers()['peers']) == 0)
# Do one last pass over the logs to extract the reactions l2 sent
l2.daemon.logsearch_start = needle
needles = [
r'Resolved FUNDING_TRANSACTION/FUNDING_OUTPUT by THEIR_REVOKED_UNILATERAL .([a-f0-9]{64}).',
r'Resolved THEIR_REVOKED_UNILATERAL/DELAYED_CHEAT_OUTPUT_TO_THEM by our proposal OUR_PENALTY_TX .([a-f0-9]{64}).',
r'Resolved THEIR_REVOKED_UNILATERAL/OUR_HTLC by our proposal OUR_PENALTY_TX .([a-f0-9]{64}).',
]
matches = list(map(l2.daemon.is_in_log, needles))
# Now extract the txids for these responses
txids = set([re.search(r'\(([0-9a-f]{64})\)', m).group(1) for m in matches])
# We should have one confirmed output for each of the above reactions in
# the list of funds we own.
outputs = l2.rpc.listfunds()['outputs']
assert [o['status'] for o in outputs] == ['confirmed'] * 3
assert set([o['txid'] for o in outputs]) == txids
assert account_balance(l2, channel_id) == 0
@unittest.skipIf(not DEVELOPER, "needs DEVELOPER=1")
@unittest.skipIf(os.getenv('TEST_DB_PROVIDER', 'sqlite3') != 'sqlite3', "Makes use of the sqlite3 db")
@pytest.mark.slow_test
def test_penalty_htlc_tx_fulfill(node_factory, bitcoind, chainparams):
""" Test that the penalizing node claims any published
HTLC transactions
Node topology:
l1 <-> l2 <-> l3 <-> l4
l4 pushes money to l1, who doesn't fulfill (freezing htlc across l2-l3)
we snapshot l2
l2 pushes money to l3 (updating state)
l2 + l3 go offline; l2 is backed up from snapshot
l1 fails the channel with l2, fulfilling the stranded htlc onchain
l2 comes back online, force closes channel with l3
block chain advances, l2 broadcasts their htlc fulfill tx
l3 comes back online, sees l2's cheat. takes funds from htlc fulfill tx.
some blocks are mined. the dust settles.
we check the accounting.
"""
# We track channel balances, to verify that accounting is ok.
coin_mvt_plugin = os.path.join(os.getcwd(), 'tests/plugins/coin_movements.py')
l1, l2, l3, l4 = node_factory.line_graph(4,
opts=[{'disconnect': ['-WIRE_UPDATE_FULFILL_HTLC'],
'may_reconnect': True,
'dev-no-reconnect': None},
{'plugin': coin_mvt_plugin,
'disable-mpp': None,
'dev-no-reconnect': None,
'may_reconnect': True,
'allow_broken_log': True},
{'plugin': coin_mvt_plugin,
'dev-no-reconnect': None,
'may_reconnect': True,
'allow_broken_log': True},
{'dev-no-reconnect': None,
'may_reconnect': True}],
wait_for_announce=True)
channel_id = first_channel_id(l2, l3)
# push some money so that 1 + 4 can both send htlcs
inv = l2.rpc.invoice(10**9 // 2, '1', 'balancer')
l1.rpc.pay(inv['bolt11'])
l1.rpc.waitsendpay(inv['payment_hash'])
inv = l4.rpc.invoice(10**9 // 2, '1', 'balancer')
l2.rpc.pay(inv['bolt11'])
l2.rpc.waitsendpay(inv['payment_hash'])
# now we send one 'sticky' htlc: l4->l1
amt = 10**8 // 2
sticky_inv = l1.rpc.invoice(amt, '2', 'sticky')
route = l4.rpc.getroute(l1.info['id'], amt, 1)['route']
l4.rpc.sendpay(route, sticky_inv['payment_hash'])
l1.daemon.wait_for_log('dev_disconnect: -WIRE_UPDATE_FULFILL_HTLC')
wait_for(lambda: len(l2.rpc.listpeers(l3.info['id'])['peers'][0]['channels'][0]['htlcs']) == 1)
# make database snapshot of l2
l2.stop()
l2_db_path = os.path.join(l2.daemon.lightning_dir, chainparams['name'], 'lightningd.sqlite3')
l2_db_path_bak = os.path.join(l2.daemon.lightning_dir, chainparams['name'], 'lightningd.sqlite3.bak')
copyfile(l2_db_path, l2_db_path_bak)
l2.start()
sync_blockheight(bitcoind, [l2])
# push some money from l3->l2, so that the commit counter advances
l2.rpc.connect(l3.info['id'], 'localhost', l3.port)
inv = l3.rpc.invoice(10**4, '1', 'push')
# Make sure gossipd in l2 knows it's active
wait_for(lambda: [c['active'] for c in l2.rpc.listchannels(l2.get_channel_scid(l3))['channels']] == [True, True])
l2.rpc.pay(inv['bolt11'])
# stop both nodes, roll back l2's database
l2.stop()
l3.stop()
copyfile(l2_db_path_bak, l2_db_path)
# start l2 and force close channel with l3 while l3 is still offline
l2.start()
sync_blockheight(bitcoind, [l2])
l2.rpc.close(l3.info['id'], 1)
l2.daemon.wait_for_log('sendrawtx exit 0')
# reconnect with l1, which will fulfill the payment
l2.rpc.connect(l1.info['id'], 'localhost', l1.port)
l2.daemon.wait_for_log('got commitsig .*: feerate 15000, 0 added, 1 fulfilled, 0 failed, 0 changed')
l2.daemon.wait_for_log('coins payment_hash: {}'.format(sticky_inv['payment_hash']))
# l2 moves on for closed l3
bitcoind.generate_block(1)
l2.daemon.wait_for_log('to ONCHAIN')
l2.daemon.wait_for_logs(['Propose handling OUR_UNILATERAL/DELAYED_OUTPUT_TO_US by OUR_DELAYED_RETURN_TO_WALLET .* after 5 blocks',
'Propose handling OUR_UNILATERAL/THEIR_HTLC by OUR_HTLC_SUCCESS_TX .* after 0 blocks'])
l2.wait_for_onchaind_broadcast('OUR_HTLC_SUCCESS_TX',
'OUR_UNILATERAL/THEIR_HTLC')
bitcoind.generate_block(1)
l2.daemon.wait_for_log('Propose handling OUR_HTLC_SUCCESS_TX/DELAYED_OUTPUT_TO_US by OUR_DELAYED_RETURN_TO_WALLET .* after 5 blocks')
# l3 comes back up, sees cheat, penalizes l2 (revokes the htlc they've offered;
# notes that they've successfully claimed to_local and the fulfilled htlc)
l3.start()
sync_blockheight(bitcoind, [l3])
l3.daemon.wait_for_logs(['Propose handling THEIR_REVOKED_UNILATERAL/OUR_HTLC by OUR_PENALTY_TX',
'Propose handling THEIR_REVOKED_UNILATERAL/DELAYED_CHEAT_OUTPUT_TO_THEM '
'by OUR_PENALTY_TX',
'Resolved THEIR_REVOKED_UNILATERAL/OUR_HTLC by OUR_HTLC_FULFILL_TO_THEM',
'Propose handling OUR_HTLC_FULFILL_TO_THEM/DELAYED_CHEAT_OUTPUT_TO_THEM'
' by OUR_PENALTY_TX'])
l3.wait_for_onchaind_broadcast('OUR_PENALTY_TX',
'OUR_HTLC_FULFILL_TO_THEM/DELAYED_CHEAT_OUTPUT_TO_THEM')
bitcoind.generate_block(1)
l3.daemon.wait_for_log('Resolved OUR_HTLC_FULFILL_TO_THEM/DELAYED_CHEAT_OUTPUT_TO_THEM '
'by our proposal OUR_PENALTY_TX')
l2.daemon.wait_for_log('Unknown spend of OUR_HTLC_SUCCESS_TX/DELAYED_OUTPUT_TO_US')
# 100 blocks later, l3+l2 are both done
bitcoind.generate_block(100)
l3.daemon.wait_for_log('{}.*: onchaind complete, forgetting peer'.format(l2.info['id']))
l2.daemon.wait_for_log('{}.*: onchaind complete, forgetting peer'.format(l3.info['id']))
assert account_balance(l3, channel_id) == 0
assert account_balance(l2, channel_id) == 0
@unittest.skipIf(not DEVELOPER, "needs DEVELOPER=1")
@unittest.skipIf(os.getenv('TEST_DB_PROVIDER', 'sqlite3') != 'sqlite3', "Makes use of the sqlite3 db")
@pytest.mark.slow_test
def test_penalty_htlc_tx_timeout(node_factory, bitcoind, chainparams):
""" Test that the penalizing node claims any published
HTLC transactions
Node topology:
l1 <-> l2 <-> l3 <-> l4
^---> l5
l1 pushes money to l5, who doesn't fulfill (freezing htlc across l2-l3)
l4 pushes money to l1, who doesn't fulfill (freezing htlc across l2-l3)
we snapshot l2
l2 pushes money to l3 (updating state)
l2 + l3 go offline; l2 is backed up from snapshot
l1 fails the channel with l2, fulfilling the stranded htlc onchain
l2 comes back online, force closes channel with l3
block chain advances, l2 broadcasts the timeout htlc_tx + fulfill htlc_tx
both of which have a delay. l2 goes ahead and 'steals back' their
output + the htlc they fulfill
l3 comes back online, sees l2's cheat. takes funds from htlc timeout tx
some blocks are mined. the dust settles.
we check the accounting.
"""
# We track channel balances, to verify that accounting is ok.
coin_mvt_plugin = os.path.join(os.getcwd(), 'tests/plugins/coin_movements.py')
l1, l2, l3, l4, l5 = node_factory.get_nodes(5,
opts=[{'disconnect': ['-WIRE_UPDATE_FULFILL_HTLC'],
'may_reconnect': True,
'dev-no-reconnect': None},
{'plugin': coin_mvt_plugin,
'dev-no-reconnect': None,
'may_reconnect': True,
'allow_broken_log': True},
{'plugin': coin_mvt_plugin,
'dev-no-reconnect': None,
'may_reconnect': True,
'allow_broken_log': True},
{'dev-no-reconnect': None},
{'disconnect': ['-WIRE_UPDATE_FULFILL_HTLC'],
'may_reconnect': True,
'dev-no-reconnect': None}])
node_factory.join_nodes([l1, l2, l3, l4], wait_for_announce=True)
node_factory.join_nodes([l3, l5], wait_for_announce=True)
channel_id = first_channel_id(l2, l3)
# push some money so that 1 + 4 can both send htlcs
inv = l2.rpc.invoice(10**9 // 2, '1', 'balancer')
l1.rpc.pay(inv['bolt11'])
inv = l4.rpc.invoice(10**9 // 2, '1', 'balancer')
l2.rpc.pay(inv['bolt11'])
# now we send two 'sticky' htlcs, l1->l5 + l4->l1
amt = 10**8 // 2
sticky_inv_1 = l5.rpc.invoice(amt, '2', 'sticky')
route = l1.rpc.getroute(l5.info['id'], amt, 1)['route']
l1.rpc.sendpay(route, sticky_inv_1['payment_hash'])
l5.daemon.wait_for_log('dev_disconnect: -WIRE_UPDATE_FULFILL_HTLC')
sticky_inv_2 = l1.rpc.invoice(amt, '2', 'sticky')
route = l4.rpc.getroute(l1.info['id'], amt, 1)['route']
l4.rpc.sendpay(route, sticky_inv_2['payment_hash'])
l1.daemon.wait_for_log('dev_disconnect: -WIRE_UPDATE_FULFILL_HTLC')
wait_for(lambda: len(l2.rpc.listpeers(l3.info['id'])['peers'][0]['channels'][0]['htlcs']) == 2)
# make database snapshot of l2
l2.stop()
l2_db_path = os.path.join(l2.daemon.lightning_dir, chainparams['name'], 'lightningd.sqlite3')
l2_db_path_bak = os.path.join(l2.daemon.lightning_dir, chainparams['name'], 'lightningd.sqlite3.bak')
copyfile(l2_db_path, l2_db_path_bak)
l2.start()
sync_blockheight(bitcoind, [l2])
# push some money from l3->l2, so that the commit counter advances
l2.rpc.connect(l3.info['id'], 'localhost', l3.port)
inv = l3.rpc.invoice(10**4, '1', 'push')
# Make sure gossipd in l2 knows it's active
wait_for(lambda: [c['active'] for c in l2.rpc.listchannels(l2.get_channel_scid(l3))['channels']] == [True, True])
l2.rpc.pay(inv['bolt11'])
# stop both nodes, roll back l2's database
l2.stop()
l3.stop()
copyfile(l2_db_path_bak, l2_db_path)
# start l2, now back a bit. force close channel with l3 while l3 is still offline
l2.start()
sync_blockheight(bitcoind, [l2])
l2.rpc.close(l3.info['id'], 1)
l2.daemon.wait_for_log('sendrawtx exit 0')
# reconnect with l1, which will fulfill the payment
l2.rpc.connect(l1.info['id'], 'localhost', l1.port)
l2.daemon.wait_for_log('got commitsig .*: feerate 15000, 0 added, 1 fulfilled, 0 failed, 0 changed')
l2.daemon.wait_for_log('coins payment_hash: {}'.format(sticky_inv_2['payment_hash']))
# l2 moves on for closed l3
bitcoind.generate_block(1)
l2.daemon.wait_for_log('to ONCHAIN')
l2.daemon.wait_for_logs(['Propose handling OUR_UNILATERAL/OUR_HTLC by OUR_HTLC_TIMEOUT_TX .* after 16 blocks',
'Propose handling OUR_UNILATERAL/DELAYED_OUTPUT_TO_US by OUR_DELAYED_RETURN_TO_WALLET .* after 5 blocks',
'Propose handling OUR_UNILATERAL/THEIR_HTLC by OUR_HTLC_SUCCESS_TX .* after 0 blocks'])
l2.wait_for_onchaind_broadcast('OUR_HTLC_SUCCESS_TX',
'OUR_UNILATERAL/THEIR_HTLC')
bitcoind.generate_block(1)
l2.daemon.wait_for_log('Propose handling OUR_HTLC_SUCCESS_TX/DELAYED_OUTPUT_TO_US by OUR_DELAYED_RETURN_TO_WALLET .* after 5 blocks')
# after 5 blocks, l2 reclaims both their DELAYED_OUTPUT_TO_US and their delayed output
bitcoind.generate_block(5)
sync_blockheight(bitcoind, [l2])
l2.daemon.wait_for_logs(['Broadcasting OUR_DELAYED_RETURN_TO_WALLET .* to resolve OUR_HTLC_SUCCESS_TX/DELAYED_OUTPUT_TO_US',
'Broadcasting OUR_DELAYED_RETURN_TO_WALLET .* to resolve OUR_UNILATERAL/DELAYED_OUTPUT_TO_US'])
bitcoind.generate_block(10)
l2.wait_for_onchaind_broadcast('OUR_HTLC_TIMEOUT_TX',
'OUR_UNILATERAL/OUR_HTLC')
bitcoind.generate_block(1)
l2.daemon.wait_for_log('Propose handling OUR_HTLC_TIMEOUT_TX/DELAYED_OUTPUT_TO_US by OUR_DELAYED_RETURN_TO_WALLET .* after 5 blocks')
# l3 comes back up, sees cheat, penalizes l2 (revokes the htlc they've offered;
# notes that they've successfully claimed to_local and the fulfilled htlc)
l3.start()
sync_blockheight(bitcoind, [l3])
l3.daemon.wait_for_logs(['Propose handling THEIR_REVOKED_UNILATERAL/OUR_HTLC by OUR_PENALTY_TX',
'Propose handling THEIR_REVOKED_UNILATERAL/THEIR_HTLC by OUR_PENALTY_TX',
'Propose handling THEIR_REVOKED_UNILATERAL/DELAYED_CHEAT_OUTPUT_TO_THEM '
'by OUR_PENALTY_TX',
'Resolved THEIR_REVOKED_UNILATERAL/OUR_HTLC by OUR_HTLC_FULFILL_TO_THEM',
'Propose handling OUR_HTLC_FULFILL_TO_THEM/DELAYED_CHEAT_OUTPUT_TO_THEM'
' by OUR_PENALTY_TX',
'Resolved OUR_HTLC_FULFILL_TO_THEM/DELAYED_CHEAT_OUTPUT_TO_THEM '
'by THEIR_DELAYED_CHEAT',
'Resolved THEIR_REVOKED_UNILATERAL/DELAYED_CHEAT_OUTPUT_TO_THEM '
'by THEIR_DELAYED_CHEAT',
'Resolved THEIR_REVOKED_UNILATERAL/THEIR_HTLC by THEIR_HTLC_TIMEOUT_TO_THEM',
'Propose handling THEIR_HTLC_TIMEOUT_TO_THEM/DELAYED_CHEAT_OUTPUT_TO_THEM by OUR_PENALTY_TX'])
bitcoind.generate_block(1)
l3.daemon.wait_for_log('Resolved THEIR_HTLC_TIMEOUT_TO_THEM/DELAYED_CHEAT_OUTPUT_TO_THEM '
'by our proposal OUR_PENALTY_TX')
l2.daemon.wait_for_log('Unknown spend of OUR_HTLC_TIMEOUT_TX/DELAYED_OUTPUT_TO_US')
# 100 blocks later, l3+l2 are both done
bitcoind.generate_block(100)
l3.daemon.wait_for_log('{}.*: onchaind complete, forgetting peer'.format(l2.info['id']))
l2.daemon.wait_for_log('{}.*: onchaind complete, forgetting peer'.format(l3.info['id']))
assert account_balance(l3, channel_id) == 0
assert account_balance(l2, channel_id) == 0
@unittest.skipIf(not DEVELOPER, "needs DEVELOPER=1")
def test_onchain_first_commit(node_factory, bitcoind):
"""Onchain handling where opener immediately drops to chain"""
# We track channel balances, to verify that accounting is ok.
coin_mvt_plugin = os.path.join(os.getcwd(), 'tests/plugins/coin_movements.py')
# HTLC 1->2, 1 fails just after funding.
disconnects = ['+WIRE_FUNDING_LOCKED', 'permfail']
# Make locktime different, as we once had them reversed!
l1, l2 = node_factory.line_graph(2, opts=[{'disconnect': disconnects,
'plugin': coin_mvt_plugin},
{'watchtime-blocks': 10,
'plugin': coin_mvt_plugin}],
fundchannel=False)
l1.fundwallet(10**7)
l1.rpc.fundchannel(l2.info['id'], 10**6)
l1.daemon.wait_for_log('sendrawtx exit 0')
bitcoind.generate_block(1)
# l1 will drop to chain.
l1.daemon.wait_for_log('permfail')
l1.daemon.wait_for_log('sendrawtx exit 0')
bitcoind.generate_block(1)
l1.daemon.wait_for_log(' to ONCHAIN')
l2.daemon.wait_for_log(' to ONCHAIN')
# 10 later, l1 should collect its to-self payment.
bitcoind.generate_block(10)
l1.wait_for_onchaind_broadcast('OUR_DELAYED_RETURN_TO_WALLET',
'OUR_UNILATERAL/DELAYED_OUTPUT_TO_US')
# 94 later, l2 is done.
bitcoind.generate_block(94)
l2.daemon.wait_for_log('onchaind complete, forgetting peer')
# Now, 100 blocks and l1 should be done.
bitcoind.generate_block(6)
l1.daemon.wait_for_log('onchaind complete, forgetting peer')
@unittest.skipIf(not DEVELOPER, "needs DEVELOPER=1")
def test_onchain_unwatch(node_factory, bitcoind):
"""Onchaind should not watch random spends"""
# We track channel balances, to verify that accounting is ok.
coin_mvt_plugin = os.path.join(os.getcwd(), 'tests/plugins/coin_movements.py')
l1, l2 = node_factory.line_graph(2, opts={'plugin': coin_mvt_plugin})
channel_id = first_channel_id(l1, l2)
l1.pay(l2, 200000000)
l1.rpc.dev_fail(l2.info['id'])
l1.daemon.wait_for_log('Failing due to dev-fail command')
l1.wait_for_channel_onchain(l2.info['id'])
l1.bitcoin.generate_block(1)
l1.daemon.wait_for_log(' to ONCHAIN')
l2.daemon.wait_for_log(' to ONCHAIN')
# 10 later, l1 should collect its to-self payment.
bitcoind.generate_block(10)
l1.wait_for_onchaind_broadcast('OUR_DELAYED_RETURN_TO_WALLET',
'OUR_UNILATERAL/DELAYED_OUTPUT_TO_US')
# First time it sees it, onchaind cares.
bitcoind.generate_block(1)
l1.daemon.wait_for_log('Resolved OUR_UNILATERAL/DELAYED_OUTPUT_TO_US by our proposal '
'OUR_DELAYED_RETURN_TO_WALLET')
# Now test unrelated onchain churn.
# Daemon gets told about wallet; says it doesn't care.
l1.rpc.withdraw(l1.rpc.newaddr()['bech32'], 'all')
bitcoind.generate_block(1)
l1.daemon.wait_for_log("but we don't care")
# And lightningd should respect that!
assert not l1.daemon.is_in_log("Can't unwatch txid")
# So these should not generate further messages
for i in range(5):
l1.rpc.withdraw(l1.rpc.newaddr()['bech32'], 'all')
bitcoind.generate_block(1)
# Make sure it digests the block
sync_blockheight(bitcoind, [l1])
# We won't see this again.
assert not l1.daemon.is_in_log("but we don't care",
start=l1.daemon.logsearch_start)
assert account_balance(l1, channel_id) == 0
assert account_balance(l2, channel_id) == 0
# Note: for this test we leave onchaind running, so we can detect
# any leaks!
@unittest.skipIf(not DEVELOPER, "needs DEVELOPER=1")
def test_onchaind_replay(node_factory, bitcoind):
disconnects = ['+WIRE_REVOKE_AND_ACK', 'permfail']
# Feerates identical so we don't get gratuitous commit to update them
l1, l2 = node_factory.line_graph(2, opts=[{'watchtime-blocks': 201, 'cltv-delta': 101,
'disconnect': disconnects,
'feerates': (7500, 7500, 7500, 7500)},
{'watchtime-blocks': 201, 'cltv-delta': 101}])
rhash = l2.rpc.invoice(10**8, 'onchaind_replay', 'desc')['payment_hash']
routestep = {
'msatoshi': 10**8 - 1,
'id': l2.info['id'],
'delay': 101,
'channel': '1x1x1'
}
l1.rpc.sendpay([routestep], rhash)
l1.daemon.wait_for_log('sendrawtx exit 0')
bitcoind.generate_block(1, wait_for_mempool=1)
# Wait for nodes to notice the failure, this seach needle is after the
# DB commit so we're sure the tx entries in onchaindtxs have been added
l1.daemon.wait_for_log("Deleting channel .* due to the funding outpoint being spent")
l2.daemon.wait_for_log("Deleting channel .* due to the funding outpoint being spent")
# We should at least have the init tx now
assert len(l1.db_query("SELECT * FROM channeltxs;")) > 0
assert len(l2.db_query("SELECT * FROM channeltxs;")) > 0
# Generate some blocks so we restart the onchaind from DB (we rescan
# last_height - 100)
bitcoind.generate_block(100)
sync_blockheight(bitcoind, [l1, l2])
# l1 should still have a running onchaind
assert len(l1.db_query("SELECT * FROM channeltxs;")) > 0
l2.rpc.stop()
l1.restart()
# Can't wait for it, it's after the "Server started" wait in restart()
assert l1.daemon.is_in_log(r'Restarting onchaind for channel')
# l1 should still notice that the funding was spent and that we should react to it
l1.daemon.wait_for_log("Propose handling OUR_UNILATERAL/DELAYED_OUTPUT_TO_US by OUR_DELAYED_RETURN_TO_WALLET")
sync_blockheight(bitcoind, [l1])
bitcoind.generate_block(10)
sync_blockheight(bitcoind, [l1])
@unittest.skipIf(not DEVELOPER, "needs DEVELOPER=1")
def test_onchain_dust_out(node_factory, bitcoind, executor):
"""Onchain handling of outgoing dust htlcs (they should fail)"""
# We track channel balances, to verify that accounting is ok.
coin_mvt_plugin = os.path.join(os.getcwd(), 'tests/plugins/coin_movements.py')
# HTLC 1->2, 1 fails after it's irrevocably committed
disconnects = ['@WIRE_REVOKE_AND_ACK', 'permfail']
# Feerates identical so we don't get gratuitous commit to update them
l1, l2 = node_factory.line_graph(2,
opts=[{'disconnect': disconnects,
'feerates': (7500, 7500, 7500, 7500),
'plugin': coin_mvt_plugin},
{'plugin': coin_mvt_plugin}])
channel_id = first_channel_id(l1, l2)
# Must be dust!
rhash = l2.rpc.invoice(1, 'onchain_dust_out', 'desc')['payment_hash']
routestep = {
'msatoshi': 1,
'id': l2.info['id'],
'delay': 5,
'channel': '1x1x1'
}
l1.rpc.sendpay([routestep], rhash)
payfuture = executor.submit(l1.rpc.waitsendpay, rhash)
# l1 will drop to chain.
l1.daemon.wait_for_log('permfail')
l1.wait_for_channel_onchain(l2.info['id'])
l1.bitcoin.generate_block(1)
l1.daemon.wait_for_log(' to ONCHAIN')
l2.daemon.wait_for_log(' to ONCHAIN')
# We use 3 blocks for "reasonable depth"
bitcoind.generate_block(3)
# It should fail.
with pytest.raises(RpcError, match=r'WIRE_PERMANENT_CHANNEL_FAILURE: missing in commitment tx'):
payfuture.result(5)
# Retry payment, this should fail (and, as a side-effect, tickle a
# bug).
with pytest.raises(RpcError, match=r'WIRE_UNKNOWN_NEXT_PEER'):
l1.rpc.sendpay([routestep], rhash)
# 6 later, l1 should collect its to-self payment.
bitcoind.generate_block(6)
l1.wait_for_onchaind_broadcast('OUR_DELAYED_RETURN_TO_WALLET',
'OUR_UNILATERAL/DELAYED_OUTPUT_TO_US')
# 94 later, l2 is done.
bitcoind.generate_block(94)
l2.daemon.wait_for_log('onchaind complete, forgetting peer')
# Restart l1, it should not crash!
l1.restart()
# Now, 100 blocks and l1 should be done.
bitcoind.generate_block(6)
l1.daemon.wait_for_log('onchaind complete, forgetting peer')
# Payment failed, BTW
assert only_one(l2.rpc.listinvoices('onchain_dust_out')['invoices'])['status'] == 'unpaid'
assert account_balance(l1, channel_id) == 0
assert account_balance(l2, channel_id) == 0
@unittest.skipIf(not DEVELOPER, "needs DEVELOPER=1")
def test_onchain_timeout(node_factory, bitcoind, executor):
"""Onchain handling of outgoing failed htlcs"""
# We track channel balances, to verify that accounting is ok.
coin_mvt_plugin = os.path.join(os.getcwd(), 'tests/plugins/coin_movements.py')
# HTLC 1->2, 1 fails just after it's irrevocably committed
disconnects = ['+WIRE_REVOKE_AND_ACK*3', 'permfail']
# Feerates identical so we don't get gratuitous commit to update them
l1, l2 = node_factory.line_graph(2,
opts=[{'disconnect': disconnects,
'feerates': (7500, 7500, 7500, 7500),
'plugin': coin_mvt_plugin},
{'plugin': coin_mvt_plugin}])
channel_id = first_channel_id(l1, l2)
rhash = l2.rpc.invoice(10**8, 'onchain_timeout', 'desc')['payment_hash']
# We underpay, so it fails.
routestep = {
'msatoshi': 10**8 - 1,
'id': l2.info['id'],
'delay': 5,
'channel': '1x1x1'
}
l1.rpc.sendpay([routestep], rhash)
with pytest.raises(RpcError):
l1.rpc.waitsendpay(rhash)
# Make sure CLTVs are different, in case it confuses onchaind.
bitcoind.generate_block(1)
sync_blockheight(bitcoind, [l1])
# Second one will cause drop to chain.
l1.rpc.sendpay([routestep], rhash)
payfuture = executor.submit(l1.rpc.waitsendpay, rhash)
# l1 will drop to chain.
l1.daemon.wait_for_log('permfail')
l1.wait_for_channel_onchain(l2.info['id'])
l1.bitcoin.generate_block(1)
l1.daemon.wait_for_log(' to ONCHAIN')
l2.daemon.wait_for_log(' to ONCHAIN')
# Wait for timeout.
l1.daemon.wait_for_logs(['Propose handling OUR_UNILATERAL/DELAYED_OUTPUT_TO_US by OUR_DELAYED_RETURN_TO_WALLET .* after 5 blocks',
'Propose handling OUR_UNILATERAL/OUR_HTLC by OUR_HTLC_TIMEOUT_TX .* after 6 blocks'])
bitcoind.generate_block(4)
l1.wait_for_onchaind_broadcast('OUR_DELAYED_RETURN_TO_WALLET',
'OUR_UNILATERAL/DELAYED_OUTPUT_TO_US')
bitcoind.generate_block(1)
l1.wait_for_onchaind_broadcast('OUR_HTLC_TIMEOUT_TX',
'OUR_UNILATERAL/OUR_HTLC')
# We use 3 blocks for "reasonable depth"
bitcoind.generate_block(3)
# It should fail.
with pytest.raises(RpcError, match=r'WIRE_PERMANENT_CHANNEL_FAILURE: timed out'):
payfuture.result(5)
# 2 later, l1 spends HTLC (5 blocks total).
bitcoind.generate_block(2)
l1.wait_for_onchaind_broadcast('OUR_DELAYED_RETURN_TO_WALLET',
'OUR_HTLC_TIMEOUT_TX/DELAYED_OUTPUT_TO_US')
# 89 later, l2 is done.
bitcoind.generate_block(89)
l2.daemon.wait_for_log('onchaind complete, forgetting peer')
# Now, 100 blocks and l1 should be done.
bitcoind.generate_block(10)
sync_blockheight(bitcoind, [l1])
assert not l1.daemon.is_in_log('onchaind complete, forgetting peer')
bitcoind.generate_block(1)
l1.daemon.wait_for_log('onchaind complete, forgetting peer')
# Payment failed, BTW
assert only_one(l2.rpc.listinvoices('onchain_timeout')['invoices'])['status'] == 'unpaid'
assert account_balance(l1, channel_id) == 0
assert account_balance(l2, channel_id) == 0
@unittest.skipIf(not DEVELOPER, "needs DEVELOPER=1")
def test_onchain_middleman(node_factory, bitcoind):
# We track channel balances, to verify that accounting is ok.
coin_mvt_plugin = os.path.join(os.getcwd(), 'tests/plugins/coin_movements.py')
# HTLC 1->2->3, 1->2 goes down after 2 gets preimage from 3.
disconnects = ['-WIRE_UPDATE_FULFILL_HTLC', 'permfail']
l1, l2, l3 = node_factory.get_nodes(3, opts=[{'plugin': coin_mvt_plugin},
{'plugin': coin_mvt_plugin,
'disconnect': disconnects},
{}])
# l2 connects to both, so l1 can't reconnect and thus l2 drops to chain
l2.rpc.connect(l1.info['id'], 'localhost', l1.port)
l2.rpc.connect(l3.info['id'], 'localhost', l3.port)
l2.fund_channel(l1, 10**6)
c23 = l2.fund_channel(l3, 10**6)
channel_id = first_channel_id(l1, l2)
# Make sure routes finalized.
bitcoind.generate_block(5)
l1.wait_channel_active(c23)
# Give l1 some money to play with.
l2.pay(l1, 2 * 10**8)
# Must be bigger than dust!
rhash = l3.rpc.invoice(10**8, 'middleman', 'desc')['payment_hash']
route = l1.rpc.getroute(l3.info['id'], 10**8, 1)["route"]
assert len(route) == 2
q = queue.Queue()
def try_pay():
try:
l1.rpc.sendpay(route, rhash)
l1.rpc.waitsendpay(rhash)
q.put(None)
except Exception as err:
q.put(err)
t = threading.Thread(target=try_pay)
t.daemon = True
t.start()
# l2 will drop to chain.
l2.daemon.wait_for_log('sendrawtx exit 0')
l1.bitcoin.generate_block(1, wait_for_mempool=1)
l2.daemon.wait_for_log(' to ONCHAIN')
l1.daemon.wait_for_log(' to ONCHAIN')
l2.daemon.wait_for_log('OUR_UNILATERAL/THEIR_HTLC')
# l2 should fulfill HTLC onchain, and spend to-us (any order)
l2.wait_for_onchaind_broadcast('OUR_HTLC_SUCCESS_TX',
'OUR_UNILATERAL/THEIR_HTLC')
# Payment should succeed.
l1.bitcoin.generate_block(1)
l1.daemon.wait_for_log('THEIR_UNILATERAL/OUR_HTLC gave us preimage')
err = q.get(timeout=10)
if err:
print("Got err from sendpay thread")
raise err
t.join(timeout=1)
assert not t.is_alive()
# Three more, l2 can spend to-us.
bitcoind.generate_block(3)
l2.wait_for_onchaind_broadcast('OUR_DELAYED_RETURN_TO_WALLET',
'OUR_UNILATERAL/DELAYED_OUTPUT_TO_US')
# One more block, HTLC tx is now spendable.
l1.bitcoin.generate_block(1)
l2.wait_for_onchaind_broadcast('OUR_DELAYED_RETURN_TO_WALLET',
'OUR_HTLC_SUCCESS_TX/DELAYED_OUTPUT_TO_US')
# 100 blocks after last spend, l2 should be done.
l1.bitcoin.generate_block(100)
l2.daemon.wait_for_log('onchaind complete, forgetting peer')
# Verify accounting for l1 & l2
assert account_balance(l1, channel_id) == 0
assert account_balance(l2, channel_id) == 0
@unittest.skipIf(not DEVELOPER, "needs DEVELOPER=1")
def test_onchain_middleman_their_unilateral_in(node_factory, bitcoind):
""" This is the same as test_onchain_middleman, except that
node l1 drops to chain, not l2, reversing the unilateral
handling logic """
# We track channel balances, to verify that accounting is ok.
coin_mvt_plugin = os.path.join(os.getcwd(), 'tests/plugins/coin_movements.py')
l1_disconnects = ['=WIRE_UPDATE_FULFILL_HTLC', 'permfail']
l2_disconnects = ['-WIRE_UPDATE_FULFILL_HTLC']
l1, l2, l3 = node_factory.get_nodes(3, opts=[{'plugin': coin_mvt_plugin,
'disconnect': l1_disconnects},
{'plugin': coin_mvt_plugin,
'disconnect': l2_disconnects},
{}])
l2.rpc.connect(l1.info['id'], 'localhost', l1.port)
l2.rpc.connect(l3.info['id'], 'localhost', l3.port)
l2.fund_channel(l1, 10**6)
c23 = l2.fund_channel(l3, 10**6)
channel_id = first_channel_id(l1, l2)
# Make sure routes finalized.
bitcoind.generate_block(5)
l1.wait_channel_active(c23)
# Give l1 some money to play with.
l2.pay(l1, 2 * 10**8)
# Must be bigger than dust!
rhash = l3.rpc.invoice(10**8, 'middleman', 'desc')['payment_hash']
route = l1.rpc.getroute(l3.info['id'], 10**8, 1)["route"]
assert len(route) == 2
q = queue.Queue()
def try_pay():
try:
l1.rpc.sendpay(route, rhash)
l1.rpc.waitsendpay(rhash)
q.put(None)
except Exception as err:
q.put(err)
t = threading.Thread(target=try_pay)
t.daemon = True
t.start()
# l1 will drop to chain.
l1.daemon.wait_for_log('sendrawtx exit 0')
l1.bitcoin.generate_block(1)
l2.daemon.wait_for_log(' to ONCHAIN')
l1.daemon.wait_for_log(' to ONCHAIN')
l2.daemon.wait_for_log('THEIR_UNILATERAL/THEIR_HTLC')
# l2 should fulfill HTLC onchain, immediately
l2.wait_for_onchaind_broadcast('THEIR_HTLC_FULFILL_TO_US',
'THEIR_UNILATERAL/THEIR_HTLC')
# Payment should succeed.
l1.bitcoin.generate_block(1)
l1.daemon.wait_for_log('OUR_UNILATERAL/OUR_HTLC gave us preimage')
err = q.get(timeout=10)
if err:
print("Got err from sendpay thread")
raise err
t.join(timeout=1)
assert not t.is_alive()
l1.bitcoin.generate_block(6)
l1.wait_for_onchaind_broadcast('OUR_DELAYED_RETURN_TO_WALLET',
'OUR_UNILATERAL/DELAYED_OUTPUT_TO_US')
# 100 blocks after last spend, l1 should be done.
l1.bitcoin.generate_block(100)
l2.daemon.wait_for_log('onchaind complete, forgetting peer')
l1.daemon.wait_for_log('onchaind complete, forgetting peer')
# Verify accounting for l1 & l2
assert account_balance(l1, channel_id) == 0
assert account_balance(l2, channel_id) == 0
@unittest.skipIf(not DEVELOPER, "needs DEVELOPER=1")
def test_onchain_their_unilateral_out(node_factory, bitcoind):
""" Very similar to the test_onchain_middleman, except there's no
middleman, we simply want to check that our offered htlc
on their unilateral returns to us (and is accounted
for correctly) """
# We track channel balances, to verify that accounting is ok.
coin_mvt_plugin = os.path.join(os.getcwd(), 'tests/plugins/coin_movements.py')
disconnects = ['-WIRE_UPDATE_FAIL_HTLC', 'permfail']
l1, l2 = node_factory.line_graph(2, opts=[{'plugin': coin_mvt_plugin},
{'disconnect': disconnects,
'plugin': coin_mvt_plugin}])
channel_id = first_channel_id(l1, l2)
route = l1.rpc.getroute(l2.info['id'], 10**8, 1)["route"]
assert len(route) == 1
q = queue.Queue()
def try_pay():
try:
# rhash is fake
rhash = 'B1' * 32
l1.rpc.sendpay(route, rhash)
q.put(None)
except Exception as err:
q.put(err)
t = threading.Thread(target=try_pay)
t.daemon = True
t.start()
# l2 will drop to chain.
l2.daemon.wait_for_log('sendrawtx exit 0')
l2.bitcoin.generate_block(1)
l1.daemon.wait_for_log(' to ONCHAIN')
l2.daemon.wait_for_log(' to ONCHAIN')
l1.daemon.wait_for_log('THEIR_UNILATERAL/OUR_HTLC')
# l1 should wait til to_self_delay (10), then fulfill onchain
l2.bitcoin.generate_block(9)
l1.wait_for_onchaind_broadcast('OUR_HTLC_TIMEOUT_TO_US',
'THEIR_UNILATERAL/OUR_HTLC')
err = q.get(timeout=10)
if err:
print("Got err from sendpay thread")
raise err
t.join(timeout=1)
assert not t.is_alive()
# 100 blocks after last spend, l1+l2 should be done.
l2.bitcoin.generate_block(100)
l1.daemon.wait_for_log('onchaind complete, forgetting peer')
l2.daemon.wait_for_log('onchaind complete, forgetting peer')
# Verify accounting for l1 & l2
assert account_balance(l2, channel_id) == 0
assert account_balance(l1, channel_id) == 0
def test_listfunds_after_their_unilateral(node_factory, bitcoind):
"""We keep spending info around for their unilateral closes.
Make sure we show the address.
"""
coin_mvt_plugin = os.path.join(os.getcwd(), 'tests/plugins/coin_movements.py')
l1, l2 = node_factory.line_graph(2, opts={'plugin': coin_mvt_plugin})
channel_id = first_channel_id(l1, l2)
# listfunds will show 1 output change, and channels.
assert len([o for o in l1.rpc.listfunds()['outputs'] if not o['reserved']]) == 1
l1.stop()
l2.rpc.close(l1.info['id'], unilateraltimeout=1)
l2.wait_for_channel_onchain(l1.info['id'])
bitcoind.generate_block(100)
l1.start()
l2.daemon.wait_for_log('onchaind complete, forgetting peer')
l1.daemon.wait_for_log('onchaind complete, forgetting peer')
wait_for(lambda: len(l1.rpc.listfunds()['outputs']) == 2)
assert all(['address' in o for o in l1.rpc.listfunds()['outputs']])
# Verify accounting for l1 & l2
assert account_balance(l1, channel_id) == 0
assert account_balance(l2, channel_id) == 0
@unittest.skipIf(not DEVELOPER, "needs DEVELOPER=1")
def test_onchain_feechange(node_factory, bitcoind, executor):
"""Onchain handling when we restart with different fees"""
# HTLC 1->2, 2 fails just after they're both irrevocably committed
# We need 2 to drop to chain, because then 1's HTLC timeout tx
# is generated on-the-fly, and is thus feerate sensitive.
disconnects = ['-WIRE_UPDATE_FAIL_HTLC', 'permfail']
l1, l2 = node_factory.line_graph(2, opts=[{'may_reconnect': True},
{'may_reconnect': True,
'disconnect': disconnects}])
rhash = l2.rpc.invoice(10**8, 'onchain_timeout', 'desc')['payment_hash']
# We underpay, so it fails.
routestep = {
'msatoshi': 10**8 - 1,
'id': l2.info['id'],
'delay': 5,
'channel': '1x1x1'
}
executor.submit(l1.rpc.sendpay, [routestep], rhash)
# l2 will drop to chain.
l2.daemon.wait_for_log('permfail')
l2.wait_for_channel_onchain(l1.info['id'])
bitcoind.generate_block(1)
l1.daemon.wait_for_log(' to ONCHAIN')
l2.daemon.wait_for_log(' to ONCHAIN')
# Wait for timeout.
l1.daemon.wait_for_log('Propose handling THEIR_UNILATERAL/OUR_HTLC by OUR_HTLC_TIMEOUT_TO_US .* after 6 blocks')
bitcoind.generate_block(6)
l1.wait_for_onchaind_broadcast('OUR_HTLC_TIMEOUT_TO_US',
'THEIR_UNILATERAL/OUR_HTLC')
# Make sure that gets included.
bitcoind.generate_block(1)
# Now we restart with different feerates.
l1.stop()
l1.daemon.cmd_line.append('--override-fee-rates=20000/9000/2000')
l1.start()
# We recognize different proposal as ours.
l1.daemon.wait_for_log('Resolved THEIR_UNILATERAL/OUR_HTLC by our proposal OUR_HTLC_TIMEOUT_TO_US')
# We use 3 blocks for "reasonable depth", so add two more
bitcoind.generate_block(2)
# Note that the very similar test_onchain_timeout looks for a
# different string: that's because it sees the JSONRPC response,
# and due to the l1 restart, there is none here.
l1.daemon.wait_for_log('WIRE_PERMANENT_CHANNEL_FAILURE')
# 90 later, l2 is done
bitcoind.generate_block(89)
sync_blockheight(bitcoind, [l2])
assert not l2.daemon.is_in_log('onchaind complete, forgetting peer')
bitcoind.generate_block(1)
l2.daemon.wait_for_log('onchaind complete, forgetting peer')
# Now, 7 blocks and l1 should be done.
bitcoind.generate_block(6)
sync_blockheight(bitcoind, [l1])
assert not l1.daemon.is_in_log('onchaind complete, forgetting peer')
bitcoind.generate_block(1)
l1.daemon.wait_for_log('onchaind complete, forgetting peer')
# Payment failed, BTW
assert only_one(l2.rpc.listinvoices('onchain_timeout')['invoices'])['status'] == 'unpaid'
@unittest.skipIf(not DEVELOPER, "needs DEVELOPER=1 for dev-set-fees")
def test_onchain_all_dust(node_factory, bitcoind, executor):
"""Onchain handling when we reduce output to all dust"""
# We track channel balances, to verify that accounting is ok.
coin_mvt_plugin = os.path.join(os.getcwd(), 'tests/plugins/coin_movements.py')
# HTLC 1->2, 2 fails just after they're both irrevocably committed
# We need 2 to drop to chain, because then 1's HTLC timeout tx
# is generated on-the-fly, and is thus feerate sensitive.
disconnects = ['-WIRE_UPDATE_FAIL_HTLC', 'permfail']
# Feerates identical so we don't get gratuitous commit to update them
l1 = node_factory.get_node(options={'dev-no-reconnect': None,
'plugin': coin_mvt_plugin},
feerates=(7500, 7500, 7500, 7500))
l2 = node_factory.get_node(disconnect=disconnects, options={'plugin': coin_mvt_plugin})
l1.rpc.connect(l2.info['id'], 'localhost', l2.port)
l1.fund_channel(l2, 10**6)
channel_id = first_channel_id(l1, l2)
rhash = l2.rpc.invoice(10**8, 'onchain_timeout', 'desc')['payment_hash']
# We underpay, so it fails.
routestep = {
'msatoshi': 10**7 - 1,
'id': l2.info['id'],
'delay': 5,
'channel': '1x1x1'
}
executor.submit(l1.rpc.sendpay, [routestep], rhash)
# l2 will drop to chain.
l2.daemon.wait_for_log('permfail')
l2.wait_for_channel_onchain(l1.info['id'])
# Make l1's fees really high (and wait for it to exceed 50000)
l1.set_feerates((100000, 100000, 100000, 100000))
l1.daemon.wait_for_log('Feerate estimate for unilateral_close set to [56789][0-9]{4}')
bitcoind.generate_block(1)
l1.daemon.wait_for_log(' to ONCHAIN')
l2.daemon.wait_for_log(' to ONCHAIN')
# Wait for timeout.
l1.daemon.wait_for_log('Propose handling THEIR_UNILATERAL/OUR_HTLC by IGNORING_TINY_PAYMENT .* after 6 blocks')
bitcoind.generate_block(5)
l1.wait_for_onchaind_broadcast('IGNORING_TINY_PAYMENT',
'THEIR_UNILATERAL/OUR_HTLC')
l1.daemon.wait_for_log('Ignoring output .* of .*: THEIR_UNILATERAL/OUR_HTLC')
# 100 deep and l2 forgets.
bitcoind.generate_block(93)
sync_blockheight(bitcoind, [l1, l2])
assert not l2.daemon.is_in_log('onchaind complete, forgetting peer')
assert not l1.daemon.is_in_log('onchaind complete, forgetting peer')
bitcoind.generate_block(1)
l2.daemon.wait_for_log('onchaind complete, forgetting peer')
# l1 does not wait for ignored payment.
l1.daemon.wait_for_log('onchaind complete, forgetting peer')
assert account_balance(l1, channel_id) == 0
assert account_balance(l2, channel_id) == 0
@unittest.skipIf(not DEVELOPER, "needs DEVELOPER=1 for dev_fail")
def test_onchain_different_fees(node_factory, bitcoind, executor):
"""Onchain handling when we've had a range of fees"""
l1, l2 = node_factory.line_graph(2, fundchannel=True, fundamount=10**7,
opts={'may_reconnect': True})
l2.rpc.dev_ignore_htlcs(id=l1.info['id'], ignore=True)
p1 = executor.submit(l1.pay, l2, 1000000000)
l2.daemon.wait_for_log('htlc 0: SENT_ADD_ACK_COMMIT->RCVD_ADD_ACK_REVOCATION')
l1.set_feerates((16000, 11000, 7500, 3750))
p2 = executor.submit(l1.pay, l2, 900000000)
l2.daemon.wait_for_log('htlc 1: SENT_ADD_ACK_COMMIT->RCVD_ADD_ACK_REVOCATION')
# Restart with different feerate for second HTLC.
l1.set_feerates((5000, 5000, 5000, 3750))
l1.restart()
l1.daemon.wait_for_log('peer_out WIRE_UPDATE_FEE')
p3 = executor.submit(l1.pay, l2, 800000000)
l2.daemon.wait_for_log('htlc 2: SENT_ADD_ACK_COMMIT->RCVD_ADD_ACK_REVOCATION')
# Drop to chain
l1.rpc.dev_fail(l2.info['id'])
l1.wait_for_channel_onchain(l2.info['id'])
bitcoind.generate_block(1)
l1.daemon.wait_for_log(' to ONCHAIN')
l2.daemon.wait_for_log(' to ONCHAIN')
# Both sides should have correct feerate
assert l1.db_query('SELECT min_possible_feerate, max_possible_feerate FROM channels;') == [{
'min_possible_feerate': 5000,
'max_possible_feerate': 16000
}]
assert l2.db_query('SELECT min_possible_feerate, max_possible_feerate FROM channels;') == [{
'min_possible_feerate': 5000,
'max_possible_feerate': 16000
}]
bitcoind.generate_block(5)
# Three HTLCs, and one for the to-us output.
l1.daemon.wait_for_logs(['sendrawtx exit 0'] * 4)
# We use 3 blocks for "reasonable depth"
bitcoind.generate_block(3)
with pytest.raises(Exception):
p1.result(10)
with pytest.raises(Exception):
p2.result(10)
with pytest.raises(Exception):
p3.result(10)
# Two more for HTLC timeout tx to be spent.
bitcoind.generate_block(2)
l1.daemon.wait_for_logs(['sendrawtx exit 0'] * 3)
# Now, 100 blocks it should be done.
bitcoind.generate_block(100)
wait_for(lambda: l1.rpc.listpeers()['peers'] == [])
wait_for(lambda: l2.rpc.listpeers()['peers'] == [])
@unittest.skipIf(not DEVELOPER, "needs DEVELOPER=1")
def test_permfail_new_commit(node_factory, bitcoind, executor):
# Test case where we have two possible commits: it will use new one.
disconnects = ['-WIRE_REVOKE_AND_ACK', 'permfail']
# Feerates identical so we don't get gratuitous commit to update them
l1 = node_factory.get_node(options={'dev-no-reconnect': None},
feerates=(7500, 7500, 7500, 7500))
l2 = node_factory.get_node(disconnect=disconnects)
l1.rpc.connect(l2.info['id'], 'localhost', l2.port)
l1.fund_channel(l2, 10**6)
# This will fail at l2's end.
t = executor.submit(l1.pay, l2, 200000000)
l2.daemon.wait_for_log('dev_disconnect permfail')
l2.wait_for_channel_onchain(l1.info['id'])
bitcoind.generate_block(1)
l1.daemon.wait_for_log('Their unilateral tx, new commit point')
l1.daemon.wait_for_log(' to ONCHAIN')
l2.daemon.wait_for_log(' to ONCHAIN')
l2.daemon.wait_for_log('Propose handling OUR_UNILATERAL/THEIR_HTLC by THEIR_HTLC_TIMEOUT_TO_THEM \\(IGNORING\\) after 6 blocks')
l1.daemon.wait_for_log('Propose handling THEIR_UNILATERAL/OUR_HTLC by OUR_HTLC_TIMEOUT_TO_US (.*) after 6 blocks')
# OK, time out HTLC.
bitcoind.generate_block(5)
l1.wait_for_onchaind_broadcast('OUR_HTLC_TIMEOUT_TO_US',
'THEIR_UNILATERAL/OUR_HTLC')
bitcoind.generate_block(1)
l1.daemon.wait_for_log('Resolved THEIR_UNILATERAL/OUR_HTLC by our proposal OUR_HTLC_TIMEOUT_TO_US')
l2.daemon.wait_for_log('Ignoring output.*: OUR_UNILATERAL/THEIR_HTLC')
t.cancel()
# Now, 100 blocks it should be done.
bitcoind.generate_block(100)
wait_for(lambda: l1.rpc.listpeers()['peers'] == [])
wait_for(lambda: l2.rpc.listpeers()['peers'] == [])
def setup_multihtlc_test(node_factory, bitcoind):
# l1 -> l2 -> l3 -> l4 -> l5 -> l6 -> l7
# l1 and l7 ignore and HTLCs they're sent.
# For each direction, we create these HTLCs with same payment_hash:
# 1 failed (CLTV1)
# 1 failed (CLTV2)
# 2 live (CLTV2)
# 1 live (CLTV3)
nodes = node_factory.line_graph(7, wait_for_announce=True,
opts={'dev-no-reconnect': None,
'may_reconnect': True})
# Balance by pushing half the funds.
b11 = nodes[-1].rpc.invoice(10**9 // 2, '1', 'balancer')['bolt11']
nodes[0].rpc.pay(b11)
nodes[0].rpc.dev_ignore_htlcs(id=nodes[1].info['id'], ignore=True)
nodes[-1].rpc.dev_ignore_htlcs(id=nodes[-2].info['id'], ignore=True)
preimage = "0" * 64
h = nodes[0].rpc.invoice(msatoshi=10**8, label='x', description='desc',
preimage=preimage)['payment_hash']
nodes[-1].rpc.invoice(msatoshi=10**8, label='x', description='desc',
preimage=preimage)['payment_hash']
# First, the failed attempts (paying wrong node). CLTV1
r = nodes[0].rpc.getroute(nodes[-2].info['id'], 10**8, 1)["route"]
nodes[0].rpc.sendpay(r, h)
with pytest.raises(RpcError, match=r'INCORRECT_OR_UNKNOWN_PAYMENT_DETAILS'):
nodes[0].rpc.waitsendpay(h)
r = nodes[-1].rpc.getroute(nodes[1].info['id'], 10**8, 1)["route"]
nodes[-1].rpc.sendpay(r, h)
with pytest.raises(RpcError, match=r'INCORRECT_OR_UNKNOWN_PAYMENT_DETAILS'):
nodes[-1].rpc.waitsendpay(h)
# Now increment CLTV -> CLTV2
bitcoind.generate_block(1)
sync_blockheight(bitcoind, nodes)
# Now, the live attempts with CLTV2 (blackholed by end nodes)
r = nodes[0].rpc.getroute(nodes[-1].info['id'], 10**8, 1)["route"]
nodes[0].rpc.sendpay(r, h)
r = nodes[-1].rpc.getroute(nodes[0].info['id'], 10**8, 1)["route"]
nodes[-1].rpc.sendpay(r, h)
# We send second HTLC from different node, since they refuse to send
# multiple with same hash.
r = nodes[1].rpc.getroute(nodes[-1].info['id'], 10**8, 1)["route"]
nodes[1].rpc.sendpay(r, h)
r = nodes[-2].rpc.getroute(nodes[0].info['id'], 10**8, 1)["route"]
nodes[-2].rpc.sendpay(r, h)
# Now increment CLTV -> CLTV3.
bitcoind.generate_block(1)
sync_blockheight(bitcoind, nodes)
r = nodes[2].rpc.getroute(nodes[-1].info['id'], 10**8, 1)["route"]
nodes[2].rpc.sendpay(r, h)
r = nodes[-3].rpc.getroute(nodes[0].info['id'], 10**8, 1)["route"]
nodes[-3].rpc.sendpay(r, h)
# Make sure HTLCs have reached the end.
nodes[0].daemon.wait_for_logs(['peer_in WIRE_UPDATE_ADD_HTLC'] * 3)
nodes[-1].daemon.wait_for_logs(['peer_in WIRE_UPDATE_ADD_HTLC'] * 3)
return h, nodes
@unittest.skipIf(not DEVELOPER, "needs DEVELOPER=1 for dev_ignore_htlcs")
@pytest.mark.slow_test
def test_onchain_multihtlc_our_unilateral(node_factory, bitcoind):
"""Node pushes a channel onchain with multiple HTLCs with same payment_hash """
h, nodes = setup_multihtlc_test(node_factory, bitcoind)
mid = len(nodes) // 2
for i in range(len(nodes) - 1):
assert only_one(nodes[i].rpc.listpeers(nodes[i + 1].info['id'])['peers'])['connected']
# Now midnode goes onchain with n+1 channel.
nodes[mid].rpc.dev_fail(nodes[mid + 1].info['id'])
nodes[mid].wait_for_channel_onchain(nodes[mid + 1].info['id'])
bitcoind.generate_block(1)
nodes[mid].daemon.wait_for_log(' to ONCHAIN')
nodes[mid + 1].daemon.wait_for_log(' to ONCHAIN')
# Now, restart and manually reconnect end nodes (so they don't ignore HTLCs)
# In fact, they'll fail them with WIRE_TEMPORARY_NODE_FAILURE.
# TODO Remove our reliance on HTLCs failing on startup and the need for
# this plugin
nodes[0].daemon.opts['plugin'] = os.path.join(os.getcwd(), 'tests/plugins/fail_htlcs.py')
nodes[-1].daemon.opts['plugin'] = os.path.join(os.getcwd(), 'tests/plugins/fail_htlcs.py')
nodes[0].restart()
nodes[-1].restart()
# We disabled auto-reconnect so we'd detect breakage, so manually reconnect.
nodes[0].rpc.connect(nodes[1].info['id'], 'localhost', nodes[1].port)
nodes[-1].rpc.connect(nodes[-2].info['id'], 'localhost', nodes[-2].port)
# Wait for HTLCs to stabilize.
nodes[0].daemon.wait_for_logs(['peer_out WIRE_UPDATE_FAIL_HTLC'] * 3)
nodes[0].daemon.wait_for_log('peer_out WIRE_COMMITMENT_SIGNED')
nodes[0].daemon.wait_for_log('peer_out WIRE_REVOKE_AND_ACK')
nodes[-1].daemon.wait_for_logs(['peer_out WIRE_UPDATE_FAIL_HTLC'] * 3)
nodes[-1].daemon.wait_for_log('peer_out WIRE_COMMITMENT_SIGNED')
nodes[-1].daemon.wait_for_log('peer_out WIRE_REVOKE_AND_ACK')
# After at depth 5, midnode will spend its own to-self output.
bitcoind.generate_block(4)
nodes[mid].wait_for_onchaind_broadcast('OUR_DELAYED_RETURN_TO_WALLET',
'OUR_UNILATERAL/DELAYED_OUTPUT_TO_US')
# The three outgoing HTLCs time out at 21, 21 and 22 blocks.
bitcoind.generate_block(16)
nodes[mid].wait_for_onchaind_broadcast('OUR_HTLC_TIMEOUT_TX',
'OUR_UNILATERAL/OUR_HTLC')
nodes[mid].wait_for_onchaind_broadcast('OUR_HTLC_TIMEOUT_TX',
'OUR_UNILATERAL/OUR_HTLC')
bitcoind.generate_block(1)
nodes[mid].wait_for_onchaind_broadcast('OUR_HTLC_TIMEOUT_TX',
'OUR_UNILATERAL/OUR_HTLC')
# And three more for us to consider them all settled.
bitcoind.generate_block(3)
# Now, those nodes should have correctly failed the HTLCs
for n in nodes[:mid - 1]:
with pytest.raises(RpcError, match=r'WIRE_PERMANENT_CHANNEL_FAILURE'):
n.rpc.waitsendpay(h, TIMEOUT)
# Other timeouts are 27,27,28 blocks.
bitcoind.generate_block(2)
nodes[mid].daemon.wait_for_logs(['Ignoring output.*: OUR_UNILATERAL/THEIR_HTLC'] * 2)
for _ in range(2):
nodes[mid + 1].wait_for_onchaind_broadcast('OUR_HTLC_TIMEOUT_TO_US',
'THEIR_UNILATERAL/OUR_HTLC')
bitcoind.generate_block(1)
nodes[mid].daemon.wait_for_log('Ignoring output.*: OUR_UNILATERAL/THEIR_HTLC')
nodes[mid + 1].wait_for_onchaind_broadcast('OUR_HTLC_TIMEOUT_TO_US',
'THEIR_UNILATERAL/OUR_HTLC')
# Depth 3 to consider it settled.
bitcoind.generate_block(3)
for n in nodes[mid + 1:]:
with pytest.raises(RpcError, match=r'WIRE_PERMANENT_CHANNEL_FAILURE'):
n.rpc.waitsendpay(h, TIMEOUT)
# At depth 100 it's all done (we didn't bother waiting for mid+1's
# spends, so that might still be going)
bitcoind.generate_block(97)
nodes[mid].daemon.wait_for_logs(['onchaind complete, forgetting peer'])
# No other channels should have failed.
for i in range(len(nodes) - 1):
if i != mid:
assert only_one(nodes[i].rpc.listpeers(nodes[i + 1].info['id'])['peers'])['connected']
@unittest.skipIf(not DEVELOPER, "needs DEVELOPER=1 for dev_ignore_htlcs")
@pytest.mark.slow_test
def test_onchain_multihtlc_their_unilateral(node_factory, bitcoind):
"""Node pushes a channel onchain with multiple HTLCs with same payment_hash """
h, nodes = setup_multihtlc_test(node_factory, bitcoind)
mid = len(nodes) // 2
for i in range(len(nodes) - 1):
assert only_one(nodes[i].rpc.listpeers(nodes[i + 1].info['id'])['peers'])['connected']
# Now midnode+1 goes onchain with midnode channel.
nodes[mid + 1].rpc.dev_fail(nodes[mid].info['id'])
nodes[mid + 1].wait_for_channel_onchain(nodes[mid].info['id'])
bitcoind.generate_block(1)
nodes[mid].daemon.wait_for_log(' to ONCHAIN')
nodes[mid + 1].daemon.wait_for_log(' to ONCHAIN')
# Now, restart and manually reconnect end nodes (so they don't ignore HTLCs)
# In fact, they'll fail them with WIRE_TEMPORARY_NODE_FAILURE.
# TODO Remove our reliance on HTLCs failing on startup and the need for
# this plugin
nodes[0].daemon.opts['plugin'] = os.path.join(os.getcwd(), 'tests/plugins/fail_htlcs.py')
nodes[-1].daemon.opts['plugin'] = os.path.join(os.getcwd(), 'tests/plugins/fail_htlcs.py')
nodes[0].restart()
nodes[-1].restart()
# We disabled auto-reconnect so we'd detect breakage, so manually reconnect.
nodes[0].rpc.connect(nodes[1].info['id'], 'localhost', nodes[1].port)
nodes[-1].rpc.connect(nodes[-2].info['id'], 'localhost', nodes[-2].port)
# Wait for HTLCs to stabilize.
nodes[0].daemon.wait_for_logs(['peer_out WIRE_UPDATE_FAIL_HTLC'] * 3)
nodes[0].daemon.wait_for_log('peer_out WIRE_COMMITMENT_SIGNED')
nodes[0].daemon.wait_for_log('peer_out WIRE_REVOKE_AND_ACK')
nodes[-1].daemon.wait_for_logs(['peer_out WIRE_UPDATE_FAIL_HTLC'] * 3)
nodes[-1].daemon.wait_for_log('peer_out WIRE_COMMITMENT_SIGNED')
nodes[-1].daemon.wait_for_log('peer_out WIRE_REVOKE_AND_ACK')
# At depth 5, midnode+1 will spend its own to-self output.
bitcoind.generate_block(4)
nodes[mid + 1].wait_for_onchaind_broadcast('OUR_DELAYED_RETURN_TO_WALLET')
# The three outgoing HTLCs time out at depth 21, 21 and 22 blocks.
bitcoind.generate_block(16)
nodes[mid].wait_for_onchaind_broadcast('OUR_HTLC_TIMEOUT_TO_US',
'THEIR_UNILATERAL/OUR_HTLC')
nodes[mid].wait_for_onchaind_broadcast('OUR_HTLC_TIMEOUT_TO_US',
'THEIR_UNILATERAL/OUR_HTLC')
bitcoind.generate_block(1)
nodes[mid].wait_for_onchaind_broadcast('OUR_HTLC_TIMEOUT_TO_US',
'THEIR_UNILATERAL/OUR_HTLC')
# At depth 3 we consider them all settled.
bitcoind.generate_block(3)
# Now, those nodes should have correctly failed the HTLCs
for n in nodes[:mid - 1]:
with pytest.raises(RpcError, match=r'WIRE_PERMANENT_CHANNEL_FAILURE'):
n.rpc.waitsendpay(h, TIMEOUT)
# Other timeouts are at depths 27,27,28 blocks.
bitcoind.generate_block(2)
nodes[mid].daemon.wait_for_logs(['Ignoring output.*: THEIR_UNILATERAL/THEIR_HTLC'] * 2)
for _ in range(2):
nodes[mid + 1].wait_for_onchaind_broadcast('OUR_HTLC_TIMEOUT_TX',
'OUR_UNILATERAL/OUR_HTLC')
bitcoind.generate_block(1)
nodes[mid].daemon.wait_for_log('Ignoring output.*: THEIR_UNILATERAL/THEIR_HTLC')
nodes[mid + 1].wait_for_onchaind_broadcast('OUR_HTLC_TIMEOUT_TX',
'OUR_UNILATERAL/OUR_HTLC')
# At depth 3 we consider them all settled.
bitcoind.generate_block(3)
for n in nodes[mid + 1:]:
with pytest.raises(RpcError, match=r'WIRE_PERMANENT_CHANNEL_FAILURE'):
n.rpc.waitsendpay(h, TIMEOUT)
# At depth 5, mid+1 can spend HTLC_TIMEOUT_TX output.
bitcoind.generate_block(1)
for _ in range(2):
nodes[mid + 1].wait_for_onchaind_broadcast('OUR_DELAYED_RETURN_TO_WALLET',
'OUR_HTLC_TIMEOUT_TX/DELAYED_OUTPUT_TO_US')
bitcoind.generate_block(1)
nodes[mid + 1].wait_for_onchaind_broadcast('OUR_DELAYED_RETURN_TO_WALLET',
'OUR_HTLC_TIMEOUT_TX/DELAYED_OUTPUT_TO_US')
# At depth 100 they're all done.
bitcoind.generate_block(100)
nodes[mid].daemon.wait_for_logs(['onchaind complete, forgetting peer'])
nodes[mid + 1].daemon.wait_for_logs(['onchaind complete, forgetting peer'])
# No other channels should have failed.
for i in range(len(nodes) - 1):
if i != mid:
assert only_one(nodes[i].rpc.listpeers(nodes[i + 1].info['id'])['peers'])['connected']
@unittest.skipIf(not DEVELOPER, "needs DEVELOPER=1")
def test_permfail_htlc_in(node_factory, bitcoind, executor):
# Test case where we fail with unsettled incoming HTLC.
disconnects = ['-WIRE_UPDATE_FULFILL_HTLC', 'permfail']
# Feerates identical so we don't get gratuitous commit to update them
l1 = node_factory.get_node(options={'dev-no-reconnect': None},
feerates=(7500, 7500, 7500, 7500))
l2 = node_factory.get_node(disconnect=disconnects)
l1.rpc.connect(l2.info['id'], 'localhost', l2.port)
l1.fund_channel(l2, 10**6)
# This will fail at l2's end.
t = executor.submit(l1.pay, l2, 200000000)
l2.daemon.wait_for_log('dev_disconnect permfail')
l2.wait_for_channel_onchain(l1.info['id'])
bitcoind.generate_block(1)
l1.daemon.wait_for_log('Their unilateral tx, old commit point')
l1.daemon.wait_for_log(' to ONCHAIN')
l2.daemon.wait_for_log(' to ONCHAIN')
l2.daemon.wait_for_log('Propose handling OUR_UNILATERAL/THEIR_HTLC by THEIR_HTLC_TIMEOUT_TO_THEM \\(IGNORING\\) after 6 blocks')
l1.daemon.wait_for_log('Propose handling THEIR_UNILATERAL/OUR_HTLC by OUR_HTLC_TIMEOUT_TO_US (.*) after 6 blocks')
# l2 then gets preimage, uses it instead of ignoring
l2.wait_for_onchaind_broadcast('OUR_HTLC_SUCCESS_TX',
'OUR_UNILATERAL/THEIR_HTLC')
bitcoind.generate_block(1)
# OK, l1 sees l2 fulfill htlc.
l1.daemon.wait_for_log('THEIR_UNILATERAL/OUR_HTLC gave us preimage')
l2.daemon.wait_for_log('Propose handling OUR_HTLC_SUCCESS_TX/DELAYED_OUTPUT_TO_US by OUR_DELAYED_RETURN_TO_WALLET .* after 5 blocks')
bitcoind.generate_block(5)
l2.wait_for_onchaind_broadcast('OUR_DELAYED_RETURN_TO_WALLET',
'OUR_HTLC_SUCCESS_TX/DELAYED_OUTPUT_TO_US')
t.cancel()
# Now, 100 blocks it should be done.
bitcoind.generate_block(95)
l1.daemon.wait_for_log('onchaind complete, forgetting peer')
assert not l2.daemon.is_in_log('onchaind complete, forgetting peer')
bitcoind.generate_block(5)
l2.daemon.wait_for_log('onchaind complete, forgetting peer')
@unittest.skipIf(not DEVELOPER, "needs DEVELOPER=1")
def test_permfail_htlc_out(node_factory, bitcoind, executor):
# Test case where we fail with unsettled outgoing HTLC.
disconnects = ['+WIRE_REVOKE_AND_ACK', 'permfail']
l1 = node_factory.get_node(options={'dev-no-reconnect': None})
# Feerates identical so we don't get gratuitous commit to update them
l2 = node_factory.get_node(disconnect=disconnects,
feerates=(7500, 7500, 7500, 7500))
l1.rpc.connect(l2.info['id'], 'localhost', l2.port)
l2.daemon.wait_for_log('openingd-chan#1: Handed peer, entering loop'.format(l1.info['id']))
l2.fund_channel(l1, 10**6)
# This will fail at l2's end.
t = executor.submit(l2.pay, l1, 200000000)
l2.daemon.wait_for_log('dev_disconnect permfail')
l2.wait_for_channel_onchain(l1.info['id'])
bitcoind.generate_block(1)
l1.daemon.wait_for_log('Their unilateral tx, old commit point')
l1.daemon.wait_for_log(' to ONCHAIN')
l2.daemon.wait_for_log(' to ONCHAIN')
l2.daemon.wait_for_logs([
'Propose handling OUR_UNILATERAL/OUR_HTLC by OUR_HTLC_TIMEOUT_TX \\(.*\\) after 6 blocks',
'Propose handling OUR_UNILATERAL/DELAYED_OUTPUT_TO_US by OUR_DELAYED_RETURN_TO_WALLET .* after 5 blocks'
])
l1.daemon.wait_for_log('Propose handling THEIR_UNILATERAL/THEIR_HTLC by THEIR_HTLC_TIMEOUT_TO_THEM \\(IGNORING\\) after 6 blocks')
# l1 then gets preimage, uses it instead of ignoring
l1.wait_for_onchaind_broadcast('THEIR_HTLC_FULFILL_TO_US',
'THEIR_UNILATERAL/THEIR_HTLC')
# l2 sees l1 fulfill tx.
bitcoind.generate_block(1)
l2.daemon.wait_for_log('OUR_UNILATERAL/OUR_HTLC gave us preimage')
t.cancel()
# l2 can send OUR_DELAYED_RETURN_TO_WALLET after 3 more blocks.
bitcoind.generate_block(3)
l2.wait_for_onchaind_broadcast('OUR_DELAYED_RETURN_TO_WALLET',
'OUR_UNILATERAL/DELAYED_OUTPUT_TO_US')
# Now, 100 blocks they should be done.
bitcoind.generate_block(95)
sync_blockheight(bitcoind, [l1, l2])
assert not l1.daemon.is_in_log('onchaind complete, forgetting peer')
assert not l2.daemon.is_in_log('onchaind complete, forgetting peer')
bitcoind.generate_block(1)
l1.daemon.wait_for_log('onchaind complete, forgetting peer')
sync_blockheight(bitcoind, [l2])
assert not l2.daemon.is_in_log('onchaind complete, forgetting peer')
bitcoind.generate_block(3)
sync_blockheight(bitcoind, [l2])
assert not l2.daemon.is_in_log('onchaind complete, forgetting peer')
bitcoind.generate_block(1)
wait_for(lambda: l2.rpc.listpeers()['peers'] == [])
@unittest.skipIf(not DEVELOPER, "needs DEVELOPER=1")
def test_permfail(node_factory, bitcoind):
l1, l2 = node_factory.line_graph(2)
# The funding change should be confirmed and our only output
assert [o['status'] for o in l1.rpc.listfunds()['outputs']] == ['confirmed']
l1.pay(l2, 200000000)
# Make sure l2 has received sig with 0 htlcs!
l2.daemon.wait_for_log('Received commit_sig with 1 htlc sigs')
l2.daemon.wait_for_log('Received commit_sig with 0 htlc sigs')
# Make sure l1 has final revocation.
l1.daemon.wait_for_log('Sending commit_sig with 1 htlc sigs')
l1.daemon.wait_for_log('Sending commit_sig with 0 htlc sigs')
l1.daemon.wait_for_log('peer_in WIRE_REVOKE_AND_ACK')
# We fail l2, so l1 will reconnect to it.
l2.rpc.dev_fail(l1.info['id'])
l2.daemon.wait_for_log('Failing due to dev-fail command')
l2.wait_for_channel_onchain(l1.info['id'])
assert l1.bitcoin.rpc.getmempoolinfo()['size'] == 1
# Now grab the close transaction
closetxid = only_one(l1.bitcoin.rpc.getrawmempool(False))
# l2 will send out tx (l1 considers it a transient error)
bitcoind.generate_block(1)
l1.daemon.wait_for_log('Their unilateral tx, old commit point')
l1.daemon.wait_for_log(' to ONCHAIN')
l2.daemon.wait_for_log(' to ONCHAIN')
l2.daemon.wait_for_log('Propose handling OUR_UNILATERAL/DELAYED_OUTPUT_TO_US by OUR_DELAYED_RETURN_TO_WALLET (.*) after 5 blocks')
wait_for(lambda: only_one(l1.rpc.listpeers(l2.info['id'])['peers'][0]['channels'])['status']
== ['ONCHAIN:Tracking their unilateral close',
'ONCHAIN:All outputs resolved: waiting 99 more blocks before forgetting channel'])
def check_billboard():
billboard = only_one(l2.rpc.listpeers(l1.info['id'])['peers'][0]['channels'])['status']
return (
len(billboard) == 2
and billboard[0] == 'ONCHAIN:Tracking our own unilateral close'
and re.fullmatch(r'ONCHAIN:.* outputs unresolved: in 4 blocks will spend DELAYED_OUTPUT_TO_US \(.*:.*\) using OUR_DELAYED_RETURN_TO_WALLET', billboard[1])
)
wait_for(check_billboard)
# Now, mine 4 blocks so it sends out the spending tx.
bitcoind.generate_block(4)
# onchaind notes to-local payment immediately.
assert (closetxid, "confirmed") in set([(o['txid'], o['status']) for o in l1.rpc.listfunds()['outputs']])
# Restart, should still be confirmed (fails: unwinding blocks erases
# the confirmation, and we don't re-make it).
l1.restart()
wait_for(lambda: (closetxid, "confirmed") in set([(o['txid'], o['status']) for o in l1.rpc.listfunds()['outputs']]))
# It should send the to-wallet tx.
l2.wait_for_onchaind_broadcast('OUR_DELAYED_RETURN_TO_WALLET',
'OUR_UNILATERAL/DELAYED_OUTPUT_TO_US')
# 100 after l1 sees tx, it should be done.
bitcoind.generate_block(95)
wait_for(lambda: l1.rpc.listpeers()['peers'] == [])
wait_for(lambda: only_one(l2.rpc.listpeers(l1.info['id'])['peers'][0]['channels'])['status'] == [
'ONCHAIN:Tracking our own unilateral close',
'ONCHAIN:All outputs resolved: waiting 5 more blocks before forgetting channel'
])
# Now, 100 blocks l2 should be done.
bitcoind.generate_block(5)
wait_for(lambda: l2.rpc.listpeers()['peers'] == [])
# Only l1 has a direct output since all of l2's outputs are respent (it
# failed). Also the output should now be listed as confirmed since we
# generated some more blocks.
assert (closetxid, "confirmed") in set([(o['txid'], o['status']) for o in l1.rpc.listfunds()['outputs']])
# Check that the all the addresses match what we generated ourselves:
for o in l1.rpc.listfunds()['outputs']:
txout = bitcoind.rpc.gettxout(o['txid'], o['output'])
addr = txout['scriptPubKey']['addresses'][0]
assert(addr == o['address'])
addr = l1.bitcoin.getnewaddress()
l1.rpc.withdraw(addr, "all")
@unittest.skipIf(not DEVELOPER, "needs DEVELOPER=1")
def test_shutdown(node_factory):
# Fail, in that it will exit before cleanup.
l1 = node_factory.get_node(may_fail=True)
if not node_factory.valgrind:
leaks = l1.rpc.dev_memleak()['leaks']
if len(leaks):
raise Exception("Node {} has memory leaks: {}"
.format(l1.daemon.lightning_dir, leaks))
l1.rpc.stop()
@flaky
@unittest.skipIf(not DEVELOPER, "needs to set upfront_shutdown_script")
def test_option_upfront_shutdown_script(node_factory, bitcoind, executor):
l1 = node_factory.get_node(start=False)
# Insist on upfront script we're not going to match.
l1.daemon.env["DEV_OPENINGD_UPFRONT_SHUTDOWN_SCRIPT"] = "76a91404b61f7dc1ea0dc99424464cc4064dc564d91e8988ac"
l1.start()
l2 = node_factory.get_node()
l1.rpc.connect(l2.info['id'], 'localhost', l2.port)
l1.fund_channel(l2, 1000000, False)
# This will block, as l12 will send an error but l2 will retry.
fut = executor.submit(l1.rpc.close, l2.info['id'])
# l2 will close unilaterally when it dislikes shutdown script.
l1.daemon.wait_for_log(r'scriptpubkey .* is not as agreed upfront \(76a91404b61f7dc1ea0dc99424464cc4064dc564d91e8988ac\)')
# Clear channel.
wait_for(lambda: len(bitcoind.rpc.getrawmempool()) != 0)
bitcoind.generate_block(1)
fut.result(TIMEOUT)
wait_for(lambda: [c['state'] for c in only_one(l1.rpc.listpeers()['peers'])['channels']] == ['ONCHAIN'])
wait_for(lambda: [c['state'] for c in only_one(l2.rpc.listpeers()['peers'])['channels']] == ['ONCHAIN'])
# Works when l2 closes channel, too.
l1.rpc.connect(l2.info['id'], 'localhost', l2.port)
l1.fund_channel(l2, 1000000, False)
l2.rpc.close(l1.info['id'])
# l2 will close unilaterally when it dislikes shutdown script.
l1.daemon.wait_for_log(r'scriptpubkey .* is not as agreed upfront \(76a91404b61f7dc1ea0dc99424464cc4064dc564d91e8988ac\)')
# Clear channel.
wait_for(lambda: len(bitcoind.rpc.getrawmempool()) != 0)
bitcoind.generate_block(1)
wait_for(lambda: [c['state'] for c in only_one(l1.rpc.listpeers()['peers'])['channels']] == ['ONCHAIN', 'ONCHAIN'])
wait_for(lambda: [c['state'] for c in only_one(l2.rpc.listpeers()['peers'])['channels']] == ['ONCHAIN', 'ONCHAIN'])
# Figure out what address it will try to use.
keyidx = int(l1.db_query("SELECT intval FROM vars WHERE name='bip32_max_index';")[0]['intval'])
# Expect 1 for change address, 1 for the channel final address,
# which are discarded as the 'scratch' tx that the fundchannel
# plugin makes, plus 1 for the funding address of the actual
# funding tx.
addr = l1.rpc.call('dev-listaddrs', [keyidx + 3])['addresses'][-1]
# Now, if we specify upfront and it's OK, all good.
l1.stop()
# We need to prepend the segwit version (0) and push opcode (14).
l1.daemon.env["DEV_OPENINGD_UPFRONT_SHUTDOWN_SCRIPT"] = '0014' + addr['bech32_redeemscript']
l1.start()
l1.rpc.connect(l2.info['id'], 'localhost', l2.port)
l1.rpc.fundchannel(l2.info['id'], 1000000)
l1.rpc.close(l2.info['id'])
wait_for(lambda: sorted([c['state'] for c in only_one(l1.rpc.listpeers()['peers'])['channels']]) == ['CLOSINGD_COMPLETE', 'ONCHAIN', 'ONCHAIN'])