#!/usr/bin/env python3 # Copyright (c) 2014-2022 The Bitcoin Core developers # Distributed under the MIT software license, see the accompanying # file COPYING or http://www.opensource.org/licenses/mit-license.php. """Test wallet import RPCs. Test rescan behavior of importaddress, importpubkey, importprivkey, and importmulti RPCs with different types of keys and rescan options. In the first part of the test, node 0 creates an address for each type of import RPC call and sends BTC to it. Then other nodes import the addresses, and the test makes listtransactions and getbalance calls to confirm that the importing node either did or did not execute rescans picking up the send transactions. In the second part of the test, node 0 sends more BTC to each address, and the test makes more listtransactions and getbalance calls to confirm that the importing nodes pick up the new transactions regardless of whether rescans happened previously. """ from test_framework.test_framework import BitcoinTestFramework from test_framework.address import AddressType from test_framework.util import ( assert_equal, set_node_times, ) import collections from decimal import Decimal import enum import itertools import random Call = enum.Enum("Call", "single multiaddress multiscript") Data = enum.Enum("Data", "address pub priv") Rescan = enum.Enum("Rescan", "no yes late_timestamp") class Variant(collections.namedtuple("Variant", "call data address_type rescan prune")): """Helper for importing one key and verifying scanned transactions.""" def do_import(self, timestamp): """Call one key import RPC.""" rescan = self.rescan == Rescan.yes assert_equal(self.address["solvable"], True) assert_equal(self.address["isscript"], self.address_type == AddressType.p2sh_segwit) assert_equal(self.address["iswitness"], self.address_type == AddressType.bech32) if self.address["isscript"]: assert_equal(self.address["embedded"]["isscript"], False) assert_equal(self.address["embedded"]["iswitness"], True) if self.call == Call.single: if self.data == Data.address: response = self.node.importaddress(address=self.address["address"], label=self.label, rescan=rescan) elif self.data == Data.pub: response = self.node.importpubkey(pubkey=self.address["pubkey"], label=self.label, rescan=rescan) elif self.data == Data.priv: response = self.node.importprivkey(privkey=self.key, label=self.label, rescan=rescan) assert_equal(response, None) elif self.call in (Call.multiaddress, Call.multiscript): request = { "scriptPubKey": { "address": self.address["address"] } if self.call == Call.multiaddress else self.address["scriptPubKey"], "timestamp": timestamp + TIMESTAMP_WINDOW + (1 if self.rescan == Rescan.late_timestamp else 0), "pubkeys": [self.address["pubkey"]] if self.data == Data.pub else [], "keys": [self.key] if self.data == Data.priv else [], "label": self.label, "watchonly": self.data != Data.priv } if self.address_type == AddressType.p2sh_segwit and self.data != Data.address: # We need solving data when providing a pubkey or privkey as data request.update({"redeemscript": self.address['embedded']['scriptPubKey']}) response = self.node.importmulti( requests=[request], options={"rescan": self.rescan in (Rescan.yes, Rescan.late_timestamp)}, ) assert_equal(response, [{"success": True}]) def check(self, txid=None, amount=None, confirmation_height=None): """Verify that listtransactions/listreceivedbyaddress return expected values.""" txs = self.node.listtransactions(label=self.label, count=10000, include_watchonly=True) current_height = self.node.getblockcount() assert_equal(len(txs), self.expected_txs) addresses = self.node.listreceivedbyaddress(minconf=0, include_watchonly=True, address_filter=self.address['address']) if self.expected_txs: assert_equal(len(addresses[0]["txids"]), self.expected_txs) if txid is not None: tx, = [tx for tx in txs if tx["txid"] == txid] assert_equal(tx["label"], self.label) assert_equal(tx["address"], self.address["address"]) assert_equal(tx["amount"], amount) assert_equal(tx["category"], "receive") assert_equal(tx["label"], self.label) assert_equal(tx["txid"], txid) # If no confirmation height is given, the tx is still in the # mempool. confirmations = (1 + current_height - confirmation_height) if confirmation_height else 0 assert_equal(tx["confirmations"], confirmations) if confirmations: assert "trusted" not in tx address, = [ad for ad in addresses if txid in ad["txids"]] assert_equal(address["address"], self.address["address"]) assert_equal(address["amount"], self.expected_balance) assert_equal(address["confirmations"], confirmations) # Verify the transaction is correctly marked watchonly depending on # whether the transaction pays to an imported public key or # imported private key. The test setup ensures that transaction # inputs will not be from watchonly keys (important because # involvesWatchonly will be true if either the transaction output # or inputs are watchonly). if self.data != Data.priv: assert_equal(address["involvesWatchonly"], True) else: assert_equal("involvesWatchonly" not in address, True) # List of Variants for each way a key or address could be imported. IMPORT_VARIANTS = [Variant(*variants) for variants in itertools.product(Call, Data, AddressType, Rescan, (False, True))] # List of nodes to import keys to. Half the nodes will have pruning disabled, # half will have it enabled. Different nodes will be used for imports that are # expected to cause rescans, and imports that are not expected to cause # rescans, in order to prevent rescans during later imports picking up # transactions associated with earlier imports. This makes it easier to keep # track of expected balances and transactions. ImportNode = collections.namedtuple("ImportNode", "prune rescan") IMPORT_NODES = [ImportNode(*fields) for fields in itertools.product((False, True), repeat=2)] # Rescans start at the earliest block up to 2 hours before the key timestamp. TIMESTAMP_WINDOW = 2 * 60 * 60 AMOUNT_DUST = 0.00000546 def get_rand_amount(): r = random.uniform(AMOUNT_DUST, 1) return Decimal(str(round(r, 8))) class ImportRescanTest(BitcoinTestFramework): def add_options(self, parser): self.add_wallet_options(parser, descriptors=False) def set_test_params(self): self.num_nodes = 2 + len(IMPORT_NODES) self.supports_cli = False self.rpc_timeout = 120 def skip_test_if_missing_module(self): self.skip_if_no_wallet() def setup_network(self): self.extra_args = [[] for _ in range(self.num_nodes)] for i, import_node in enumerate(IMPORT_NODES, 2): if import_node.prune: self.extra_args[i] += ["-prune=1"] self.add_nodes(self.num_nodes, extra_args=self.extra_args) # Import keys with pruning disabled self.start_nodes(extra_args=[[]] * self.num_nodes) self.import_deterministic_coinbase_privkeys() self.stop_nodes() self.start_nodes(extra_args=[["-whitelist=noban@127.0.0.1"]] * self.num_nodes) for i in range(1, self.num_nodes): self.connect_nodes(i, 0) def run_test(self): # Create one transaction on node 0 with a unique amount for # each possible type of wallet import RPC. last_variants = [] for i, variant in enumerate(IMPORT_VARIANTS): if i % 10 == 0: blockhash = self.generate(self.nodes[0], 1)[0] conf_height = self.nodes[0].getblockcount() timestamp = self.nodes[0].getblockheader(blockhash)["time"] for var in last_variants: var.confirmation_height = conf_height var.timestamp = timestamp last_variants.clear() variant.label = "label {} {}".format(i, variant) variant.address = self.nodes[1].getaddressinfo(self.nodes[1].getnewaddress( label=variant.label, address_type=variant.address_type.value, )) variant.key = self.nodes[1].dumpprivkey(variant.address["address"]) variant.initial_amount = get_rand_amount() variant.initial_txid = self.nodes[0].sendtoaddress(variant.address["address"], variant.initial_amount) last_variants.append(variant) blockhash = self.generate(self.nodes[0], 1)[0] conf_height = self.nodes[0].getblockcount() timestamp = self.nodes[0].getblockheader(blockhash)["time"] for var in last_variants: var.confirmation_height = conf_height var.timestamp = timestamp last_variants.clear() # Generate a block further in the future (past the rescan window). assert_equal(self.nodes[0].getrawmempool(), []) set_node_times( self.nodes, self.nodes[0].getblockheader(self.nodes[0].getbestblockhash())["time"] + TIMESTAMP_WINDOW + 1, ) self.generate(self.nodes[0], 1) # For each variation of wallet key import, invoke the import RPC and # check the results from getbalance and listtransactions. for variant in IMPORT_VARIANTS: self.log.info('Run import for variant {}'.format(variant)) expect_rescan = variant.rescan == Rescan.yes variant.node = self.nodes[2 + IMPORT_NODES.index(ImportNode(variant.prune, expect_rescan))] variant.do_import(variant.timestamp) if expect_rescan: variant.expected_balance = variant.initial_amount variant.expected_txs = 1 variant.check(variant.initial_txid, variant.initial_amount, variant.confirmation_height) else: variant.expected_balance = 0 variant.expected_txs = 0 variant.check() # Create new transactions sending to each address. for i, variant in enumerate(IMPORT_VARIANTS): if i % 10 == 0: blockhash = self.generate(self.nodes[0], 1)[0] conf_height = self.nodes[0].getblockcount() + 1 variant.sent_amount = get_rand_amount() variant.sent_txid = self.nodes[0].sendtoaddress(variant.address["address"], variant.sent_amount) variant.confirmation_height = conf_height self.generate(self.nodes[0], 1) assert_equal(self.nodes[0].getrawmempool(), []) self.sync_all() # Check the latest results from getbalance and listtransactions. for variant in IMPORT_VARIANTS: self.log.info('Run check for variant {}'.format(variant)) variant.expected_balance += variant.sent_amount variant.expected_txs += 1 variant.check(variant.sent_txid, variant.sent_amount, variant.confirmation_height) self.log.info('Test that the mempool is rescanned as well if the rescan parameter is set to true') # The late timestamp and pruned variants are not necessary when testing mempool rescan mempool_variants = [variant for variant in IMPORT_VARIANTS if variant.rescan != Rescan.late_timestamp and not variant.prune] # No further blocks are mined so the timestamp will stay the same timestamp = self.nodes[0].getblockheader(self.nodes[0].getbestblockhash())["time"] # Create one transaction on node 0 with a unique amount for # each possible type of wallet import RPC. for i, variant in enumerate(mempool_variants): variant.label = "mempool label {} {}".format(i, variant) variant.address = self.nodes[1].getaddressinfo(self.nodes[1].getnewaddress( label=variant.label, address_type=variant.address_type.value, )) variant.key = self.nodes[1].dumpprivkey(variant.address["address"]) variant.initial_amount = get_rand_amount() variant.initial_txid = self.nodes[0].sendtoaddress(variant.address["address"], variant.initial_amount) variant.confirmation_height = 0 variant.timestamp = timestamp assert_equal(len(self.nodes[0].getrawmempool()), len(mempool_variants)) self.sync_mempools() # For each variation of wallet key import, invoke the import RPC and # check the results from getbalance and listtransactions. for variant in mempool_variants: self.log.info('Run import for mempool variant {}'.format(variant)) expect_rescan = variant.rescan == Rescan.yes variant.node = self.nodes[2 + IMPORT_NODES.index(ImportNode(variant.prune, expect_rescan))] variant.do_import(variant.timestamp) if expect_rescan: variant.expected_balance = variant.initial_amount variant.expected_txs = 1 variant.check(variant.initial_txid, variant.initial_amount) else: variant.expected_balance = 0 variant.expected_txs = 0 variant.check() if __name__ == "__main__": ImportRescanTest().main()