import json from time import sleep from riemann.tx import Tx from pisa import HOST, PORT from apps.cli import pisa_cli from apps.cli.blob import Blob from common.tools import compute_locator from common.appointment import Appointment from common.cryptographer import Cryptographer from pisa.utils.auth_proxy import JSONRPCException from test.pisa.e2e.conftest import END_TIME_DELTA, build_appointment_data, get_random_value_hex # We'll use pisa_cli to add appointments. The expected input format is a list of arguments with a json-encoded # appointment pisa_cli.pisa_api_server = HOST pisa_cli.pisa_api_port = PORT def broadcast_transaction_and_mine_block(bitcoin_cli, commitment_tx, addr): # Broadcast the commitment transaction and mine a block bitcoin_cli.sendrawtransaction(commitment_tx) bitcoin_cli.generatetoaddress(1, addr) def get_appointment_info(locator): # Check that the justice has been triggered (the appointment has moved from Watcher to Responder) sleep(1) # Let's add a bit of delay so the state can be updated return pisa_cli.get_appointment([locator]) def test_appointment_life_cycle(bitcoin_cli, create_txs): commitment_tx, penalty_tx = create_txs commitment_tx_id = bitcoin_cli.decoderawtransaction(commitment_tx).get("txid") appointment_data = build_appointment_data(bitcoin_cli, commitment_tx_id, penalty_tx) locator = compute_locator(appointment_data.get("tx_id")) assert pisa_cli.add_appointment([json.dumps(appointment_data)]) is True new_addr = bitcoin_cli.getnewaddress() broadcast_transaction_and_mine_block(bitcoin_cli, commitment_tx, new_addr) appointment_info = get_appointment_info(locator) assert appointment_info is not None assert len(appointment_info) == 1 assert appointment_info[0].get("status") == "dispute_responded" # It can be also checked by ensuring that the penalty transaction made it to the network penalty_tx_id = bitcoin_cli.decoderawtransaction(penalty_tx).get("txid") try: bitcoin_cli.getrawtransaction(penalty_tx_id) assert True except JSONRPCException: # If the transaction if not found. assert False # Now let's mine some blocks so the appointment reaches its end. # Since we are running all the nodes remotely data may take more time than normal, and some confirmations may be # missed, so we generate more than enough confirmations and add some delays. for _ in range(int(1.5 * END_TIME_DELTA)): sleep(1) bitcoin_cli.generatetoaddress(1, new_addr) appointment_info = get_appointment_info(locator) assert appointment_info[0].get("status") == "not_found" def test_appointment_malformed_penalty(bitcoin_cli, create_txs): # Lets start by creating two valid transaction commitment_tx, penalty_tx = create_txs # Now we can modify the penalty so it is invalid when broadcast mod_penalty_tx = Tx.from_hex(penalty_tx) tx_in = mod_penalty_tx.tx_ins[0].copy(redeem_script=b"") mod_penalty_tx = mod_penalty_tx.copy(tx_ins=[tx_in]) commitment_tx_id = bitcoin_cli.decoderawtransaction(commitment_tx).get("txid") appointment_data = build_appointment_data(bitcoin_cli, commitment_tx_id, mod_penalty_tx.hex()) locator = compute_locator(appointment_data.get("tx_id")) assert pisa_cli.add_appointment([json.dumps(appointment_data)]) is True # Broadcast the commitment transaction and mine a block new_addr = bitcoin_cli.getnewaddress() broadcast_transaction_and_mine_block(bitcoin_cli, commitment_tx, new_addr) # The appointment should have been removed since the penalty_tx was malformed. sleep(1) appointment_info = get_appointment_info(locator) assert appointment_info is not None assert len(appointment_info) == 1 assert appointment_info[0].get("status") == "not_found" def test_appointment_wrong_key(bitcoin_cli, create_txs): # This tests an appointment encrypted with a key that has not been derived from the same source as the locator. # Therefore the tower won't be able to decrypt the blob once the appointment is triggered. commitment_tx, penalty_tx = create_txs # The appointment data is built using a random 32-byte value. appointment_data = build_appointment_data(bitcoin_cli, get_random_value_hex(32), penalty_tx) # We can't use pisa_cli.add_appointment here since it computes the locator internally, so let's do it manually. # We will encrypt the blob using the random value and derive the locator from the commitment tx. appointment_data["locator"] = compute_locator(bitcoin_cli.decoderawtransaction(commitment_tx).get("txid")) appointment_data["encrypted_blob"] = Cryptographer.encrypt(Blob(penalty_tx), appointment_data.get("tx_id")) appointment = Appointment.from_dict(appointment_data) signature = pisa_cli.get_appointment_signature(appointment) hex_pk_der = pisa_cli.get_pk() data = {"appointment": appointment.to_dict(), "signature": signature, "public_key": hex_pk_der.decode("utf-8")} # Send appointment to the server. response_json = pisa_cli.post_data_to_add_appointment_endpoint(data) # Check that the server has accepted the appointment signature = response_json.get("signature") assert signature is not None assert pisa_cli.check_signature(signature, appointment) is True assert response_json.get("locator") == appointment.locator # Trigger the appointment new_addr = bitcoin_cli.getnewaddress() broadcast_transaction_and_mine_block(bitcoin_cli, commitment_tx, new_addr) # The appointment should have been removed since the decryption failed. sleep(1) appointment_info = get_appointment_info(appointment.locator) assert appointment_info is not None assert len(appointment_info) == 1 assert appointment_info[0].get("status") == "not_found"