#!/usr/bin/env python3 # Copyright (c) 2017-present 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 RPC calls related to net. Tests correspond to code in rpc/net.cpp. """ from decimal import Decimal from itertools import product import platform import time import test_framework.messages from test_framework.p2p import ( P2PInterface, P2P_SERVICES, ) from test_framework.test_framework import BitcoinTestFramework from test_framework.util import ( assert_approx, assert_equal, assert_greater_than, assert_raises_rpc_error, p2p_port, ) from test_framework.wallet import MiniWallet def assert_net_servicesnames(servicesflag, servicenames): """Utility that checks if all flags are correctly decoded in `getpeerinfo` and `getnetworkinfo`. :param servicesflag: The services as an integer. :param servicenames: The list of decoded services names, as strings. """ servicesflag_generated = 0 for servicename in servicenames: servicesflag_generated |= getattr(test_framework.messages, 'NODE_' + servicename) assert servicesflag_generated == servicesflag def seed_addrman(node): """ Populate the addrman with addresses from different networks. Here 2 ipv4, 2 ipv6, 1 cjdns, 2 onion and 1 i2p addresses are added. """ # These addresses currently don't collide with a deterministic addrman. # If the addrman positioning/bucketing is changed, these might collide # and adding them fails. success = { "success": True } assert_equal(node.addpeeraddress(address="1.2.3.4", tried=True, port=8333), success) assert_equal(node.addpeeraddress(address="2.0.0.0", port=8333), success) assert_equal(node.addpeeraddress(address="1233:3432:2434:2343:3234:2345:6546:4534", tried=True, port=8333), success) assert_equal(node.addpeeraddress(address="2803:0:1234:abcd::1", port=45324), success) assert_equal(node.addpeeraddress(address="fc00:1:2:3:4:5:6:7", port=8333), success) assert_equal(node.addpeeraddress(address="pg6mmjiyjmcrsslvykfwnntlaru7p5svn6y2ymmju6nubxndf4pscryd.onion", tried=True, port=8333), success) assert_equal(node.addpeeraddress(address="nrfj6inpyf73gpkyool35hcmne5zwfmse3jl3aw23vk7chdemalyaqad.onion", port=45324, tried=True), success) assert_equal(node.addpeeraddress(address="c4gfnttsuwqomiygupdqqqyy5y5emnk5c73hrfvatri67prd7vyq.b32.i2p", port=8333), success) class NetTest(BitcoinTestFramework): def set_test_params(self): self.num_nodes = 2 self.extra_args = [["-minrelaytxfee=0.00001000"], ["-minrelaytxfee=0.00000500"]] self.supports_cli = False def run_test(self): # We need miniwallet to make a transaction self.wallet = MiniWallet(self.nodes[0]) # By default, the test framework sets up an addnode connection from # node 1 --> node0. By connecting node0 --> node 1, we're left with # the two nodes being connected both ways. # Topology will look like: node0 <--> node1 self.connect_nodes(0, 1) self.sync_all() self.test_connection_count() self.test_getpeerinfo() self.test_getnettotals() self.test_getnetworkinfo() self.test_addnode_getaddednodeinfo() self.test_service_flags() self.test_getnodeaddresses() self.test_addpeeraddress() self.test_sendmsgtopeer() self.test_getaddrmaninfo() self.test_getrawaddrman() def test_connection_count(self): self.log.info("Test getconnectioncount") # After using `connect_nodes` to connect nodes 0 and 1 to each other. assert_equal(self.nodes[0].getconnectioncount(), 2) def test_getpeerinfo(self): self.log.info("Test getpeerinfo") # Create a few getpeerinfo last_block/last_transaction values. self.wallet.send_self_transfer(from_node=self.nodes[0]) # Make a transaction so we can see it in the getpeerinfo results self.generate(self.nodes[1], 1) time_now = int(time.time()) peer_info = [x.getpeerinfo() for x in self.nodes] # Verify last_block and last_transaction keys/values. for node, peer, field in product(range(self.num_nodes), range(2), ['last_block', 'last_transaction']): assert field in peer_info[node][peer].keys() if peer_info[node][peer][field] != 0: assert_approx(peer_info[node][peer][field], time_now, vspan=60) # check both sides of bidirectional connection between nodes # the address bound to on one side will be the source address for the other node assert_equal(peer_info[0][0]['addrbind'], peer_info[1][0]['addr']) assert_equal(peer_info[1][0]['addrbind'], peer_info[0][0]['addr']) assert_equal(peer_info[0][0]['minfeefilter'], Decimal("0.00000500")) assert_equal(peer_info[1][0]['minfeefilter'], Decimal("0.00001000")) # check the `servicesnames` field for info in peer_info: assert_net_servicesnames(int(info[0]["services"], 0x10), info[0]["servicesnames"]) assert_equal(peer_info[0][0]['connection_type'], 'inbound') assert_equal(peer_info[0][1]['connection_type'], 'manual') assert_equal(peer_info[1][0]['connection_type'], 'manual') assert_equal(peer_info[1][1]['connection_type'], 'inbound') # Check dynamically generated networks list in getpeerinfo help output. assert "(ipv4, ipv6, onion, i2p, cjdns, not_publicly_routable)" in self.nodes[0].help("getpeerinfo") self.log.info("Check getpeerinfo output before a version message was sent") no_version_peer_id = 2 no_version_peer_conntime = int(time.time()) self.nodes[0].setmocktime(no_version_peer_conntime) with self.nodes[0].wait_for_new_peer(): no_version_peer = self.nodes[0].add_p2p_connection(P2PInterface(), send_version=False, wait_for_verack=False) if self.options.v2transport: self.wait_until(lambda: self.nodes[0].getpeerinfo()[no_version_peer_id]["transport_protocol_type"] == "v2") self.nodes[0].setmocktime(0) peer_info = self.nodes[0].getpeerinfo()[no_version_peer_id] peer_info.pop("addr") peer_info.pop("addrbind") # The next two fields will vary for v2 connections because we send a rng-based number of decoy messages peer_info.pop("bytesrecv") peer_info.pop("bytessent") assert_equal( peer_info, { "addr_processed": 0, "addr_rate_limited": 0, "addr_relay_enabled": False, "bip152_hb_from": False, "bip152_hb_to": False, "bytesrecv_per_msg": {}, "bytessent_per_msg": {}, "connection_type": "inbound", "conntime": no_version_peer_conntime, "id": no_version_peer_id, "inbound": True, "inflight": [], "last_block": 0, "last_transaction": 0, "lastrecv": 0 if not self.options.v2transport else no_version_peer_conntime, "lastsend": 0 if not self.options.v2transport else no_version_peer_conntime, "minfeefilter": Decimal("0E-8"), "network": "not_publicly_routable", "permissions": [], "presynced_headers": -1, "relaytxes": False, "services": "0000000000000000", "servicesnames": [], "session_id": "" if not self.options.v2transport else no_version_peer.v2_state.peer['session_id'].hex(), "startingheight": -1, "subver": "", "synced_blocks": -1, "synced_headers": -1, "timeoffset": 0, "transport_protocol_type": "v1" if not self.options.v2transport else "v2", "version": 0, }, ) no_version_peer.peer_disconnect() self.wait_until(lambda: len(self.nodes[0].getpeerinfo()) == 2) def test_getnettotals(self): self.log.info("Test getnettotals") # Test getnettotals and getpeerinfo by doing a ping. The bytes # sent/received should increase by at least the size of one ping # and one pong. Both have a payload size of 8 bytes, but the total # size depends on the used p2p version: # - p2p v1: 24 bytes (header) + 8 bytes (payload) = 32 bytes # - p2p v2: 21 bytes (header/tag with short-id) + 8 bytes (payload) = 29 bytes ping_size = 32 if not self.options.v2transport else 29 net_totals_before = self.nodes[0].getnettotals() peer_info_before = self.nodes[0].getpeerinfo() self.nodes[0].ping() self.wait_until(lambda: (self.nodes[0].getnettotals()['totalbytessent'] >= net_totals_before['totalbytessent'] + ping_size * 2), timeout=1) self.wait_until(lambda: (self.nodes[0].getnettotals()['totalbytesrecv'] >= net_totals_before['totalbytesrecv'] + ping_size * 2), timeout=1) for peer_before in peer_info_before: peer_after = lambda: next(p for p in self.nodes[0].getpeerinfo() if p['id'] == peer_before['id']) self.wait_until(lambda: peer_after()['bytesrecv_per_msg'].get('pong', 0) >= peer_before['bytesrecv_per_msg'].get('pong', 0) + ping_size, timeout=1) self.wait_until(lambda: peer_after()['bytessent_per_msg'].get('ping', 0) >= peer_before['bytessent_per_msg'].get('ping', 0) + ping_size, timeout=1) def test_getnetworkinfo(self): self.log.info("Test getnetworkinfo") info = self.nodes[0].getnetworkinfo() assert_equal(info['networkactive'], True) assert_equal(info['connections'], 2) assert_equal(info['connections_in'], 1) assert_equal(info['connections_out'], 1) with self.nodes[0].assert_debug_log(expected_msgs=['SetNetworkActive: false\n']): self.nodes[0].setnetworkactive(state=False) assert_equal(self.nodes[0].getnetworkinfo()['networkactive'], False) # Wait a bit for all sockets to close for n in self.nodes: self.wait_until(lambda: n.getnetworkinfo()['connections'] == 0, timeout=3) with self.nodes[0].assert_debug_log(expected_msgs=['SetNetworkActive: true\n']): self.nodes[0].setnetworkactive(state=True) # Connect nodes both ways. self.connect_nodes(0, 1) self.connect_nodes(1, 0) info = self.nodes[0].getnetworkinfo() assert_equal(info['networkactive'], True) assert_equal(info['connections'], 2) assert_equal(info['connections_in'], 1) assert_equal(info['connections_out'], 1) # check the `servicesnames` field network_info = [node.getnetworkinfo() for node in self.nodes] for info in network_info: assert_net_servicesnames(int(info["localservices"], 0x10), info["localservicesnames"]) # Check dynamically generated networks list in getnetworkinfo help output. assert "(ipv4, ipv6, onion, i2p, cjdns)" in self.nodes[0].help("getnetworkinfo") def test_addnode_getaddednodeinfo(self): self.log.info("Test addnode and getaddednodeinfo") assert_equal(self.nodes[0].getaddednodeinfo(), []) self.log.info("Add a node (node2) to node0") ip_port = "127.0.0.1:{}".format(p2p_port(2)) self.nodes[0].addnode(node=ip_port, command='add') self.log.info("Try to add an equivalent ip and check it fails") self.log.debug("(note that OpenBSD doesn't support the IPv4 shorthand notation with omitted zero-bytes)") if platform.system() != "OpenBSD": ip_port2 = "127.1:{}".format(p2p_port(2)) assert_raises_rpc_error(-23, "Node already added", self.nodes[0].addnode, node=ip_port2, command='add') self.log.info("Check that the node has indeed been added") added_nodes = self.nodes[0].getaddednodeinfo() assert_equal(len(added_nodes), 1) assert_equal(added_nodes[0]['addednode'], ip_port) self.log.info("Check that filtering by node works") self.nodes[0].addnode(node="11.22.33.44", command='add') first_added_node = self.nodes[0].getaddednodeinfo(node=ip_port) assert_equal(added_nodes, first_added_node) assert_equal(len(self.nodes[0].getaddednodeinfo()), 2) self.log.info("Check that node cannot be added again") assert_raises_rpc_error(-23, "Node already added", self.nodes[0].addnode, node=ip_port, command='add') self.log.info("Check that node can be removed") self.nodes[0].addnode(node=ip_port, command='remove') added_nodes = self.nodes[0].getaddednodeinfo() assert_equal(len(added_nodes), 1) assert_equal(added_nodes[0]['addednode'], "11.22.33.44") self.log.info("Check that an invalid command returns an error") assert_raises_rpc_error(-1, 'addnode "node" "command"', self.nodes[0].addnode, node=ip_port, command='abc') self.log.info("Check that trying to remove the node again returns an error") assert_raises_rpc_error(-24, "Node could not be removed", self.nodes[0].addnode, node=ip_port, command='remove') self.log.info("Check that a non-existent node returns an error") assert_raises_rpc_error(-24, "Node has not been added", self.nodes[0].getaddednodeinfo, '1.1.1.1') def test_service_flags(self): self.log.info("Test service flags") self.nodes[0].add_p2p_connection(P2PInterface(), services=(1 << 4) | (1 << 63)) if self.options.v2transport: assert_equal(['UNKNOWN[2^4]', 'P2P_V2', 'UNKNOWN[2^63]'], self.nodes[0].getpeerinfo()[-1]['servicesnames']) else: assert_equal(['UNKNOWN[2^4]', 'UNKNOWN[2^63]'], self.nodes[0].getpeerinfo()[-1]['servicesnames']) self.nodes[0].disconnect_p2ps() def test_getnodeaddresses(self): self.log.info("Test getnodeaddresses") self.nodes[0].add_p2p_connection(P2PInterface()) # Add an IPv6 address to the address manager. ipv6_addr = "1233:3432:2434:2343:3234:2345:6546:4534" self.nodes[0].addpeeraddress(address=ipv6_addr, port=8333) # Add 10,000 IPv4 addresses to the address manager. Due to the way bucket # and bucket positions are calculated, some of these addresses will collide. imported_addrs = [] for i in range(10000): first_octet = i >> 8 second_octet = i % 256 a = f"{first_octet}.{second_octet}.1.1" imported_addrs.append(a) self.nodes[0].addpeeraddress(a, 8333) # Fetch the addresses via the RPC and test the results. assert_equal(len(self.nodes[0].getnodeaddresses()), 1) # default count is 1 assert_equal(len(self.nodes[0].getnodeaddresses(count=2)), 2) assert_equal(len(self.nodes[0].getnodeaddresses(network="ipv4", count=8)), 8) # Maximum possible addresses in AddrMan is 10000. The actual number will # usually be less due to bucket and bucket position collisions. node_addresses = self.nodes[0].getnodeaddresses(0, "ipv4") assert_greater_than(len(node_addresses), 5000) assert_greater_than(10000, len(node_addresses)) for a in node_addresses: assert_greater_than(a["time"], 1527811200) # 1st June 2018 assert_equal(a["services"], P2P_SERVICES) assert a["address"] in imported_addrs assert_equal(a["port"], 8333) assert_equal(a["network"], "ipv4") # Test the IPv6 address. res = self.nodes[0].getnodeaddresses(0, "ipv6") assert_equal(len(res), 1) assert_equal(res[0]["address"], ipv6_addr) assert_equal(res[0]["network"], "ipv6") assert_equal(res[0]["port"], 8333) assert_equal(res[0]["services"], P2P_SERVICES) # Test for the absence of onion, I2P and CJDNS addresses. for network in ["onion", "i2p", "cjdns"]: assert_equal(self.nodes[0].getnodeaddresses(0, network), []) # Test invalid arguments. assert_raises_rpc_error(-8, "Address count out of range", self.nodes[0].getnodeaddresses, -1) assert_raises_rpc_error(-8, "Network not recognized: Foo", self.nodes[0].getnodeaddresses, 1, "Foo") def test_addpeeraddress(self): self.log.info("Test addpeeraddress") # The node has an existing, non-deterministic addrman from a previous test. # Clear it to have a deterministic addrman. self.restart_node(1, ["-checkaddrman=1", "-test=addrman"], clear_addrman=True) node = self.nodes[1] self.log.debug("Test that addpeeraddress is a hidden RPC") # It is hidden from general help, but its detailed help may be called directly. assert "addpeeraddress" not in node.help() assert "unknown command: addpeeraddress" not in node.help("addpeeraddress") self.log.debug("Test that adding an empty address fails") assert_equal(node.addpeeraddress(address="", port=8333), {"success": False}) assert_equal(node.getnodeaddresses(count=0), []) self.log.debug("Test that non-bool tried fails") assert_raises_rpc_error(-3, "JSON value of type string is not of expected type bool", self.nodes[0].addpeeraddress, address="1.2.3.4", tried="True", port=1234) self.log.debug("Test that adding an address with invalid port fails") assert_raises_rpc_error(-1, "JSON integer out of range", self.nodes[0].addpeeraddress, address="1.2.3.4", port=-1) assert_raises_rpc_error(-1, "JSON integer out of range", self.nodes[0].addpeeraddress, address="1.2.3.4", port=65536) self.log.debug("Test that adding a valid address to the new table succeeds") assert_equal(node.addpeeraddress(address="1.0.0.0", tried=False, port=8333), {"success": True}) addrman = node.getrawaddrman() assert_equal(len(addrman["tried"]), 0) new_table = list(addrman["new"].values()) assert_equal(len(new_table), 1) assert_equal(new_table[0]["address"], "1.0.0.0") assert_equal(new_table[0]["port"], 8333) self.log.debug("Test that adding an already-present new address to the new and tried tables fails") for value in [True, False]: assert_equal(node.addpeeraddress(address="1.0.0.0", tried=value, port=8333), {"success": False, "error": "failed-adding-to-new"}) assert_equal(len(node.getnodeaddresses(count=0)), 1) self.log.debug("Test that adding a valid address to the tried table succeeds") assert_equal(node.addpeeraddress(address="1.2.3.4", tried=True, port=8333), {"success": True}) addrman = node.getrawaddrman() assert_equal(len(addrman["new"]), 1) tried_table = list(addrman["tried"].values()) assert_equal(len(tried_table), 1) assert_equal(tried_table[0]["address"], "1.2.3.4") assert_equal(tried_table[0]["port"], 8333) node.getnodeaddresses(count=0) # getnodeaddresses re-runs the addrman checks self.log.debug("Test that adding an already-present tried address to the new and tried tables fails") for value in [True, False]: assert_equal(node.addpeeraddress(address="1.2.3.4", tried=value, port=8333), {"success": False, "error": "failed-adding-to-new"}) assert_equal(len(node.getnodeaddresses(count=0)), 2) self.log.debug("Test that adding an address, which collides with the address in tried table, fails") colliding_address = "1.2.5.45" # grinded address that produces a tried-table collision assert_equal(node.addpeeraddress(address=colliding_address, tried=True, port=8333), {"success": False, "error": "failed-adding-to-tried"}) # When adding an address to the tried table, it's first added to the new table. # As we fail to move it to the tried table, it remains in the new table. addrman_info = node.getaddrmaninfo() assert_equal(addrman_info["all_networks"]["tried"], 1) assert_equal(addrman_info["all_networks"]["new"], 2) self.log.debug("Test that adding an another address to the new table succeeds") assert_equal(node.addpeeraddress(address="2.0.0.0", port=8333), {"success": True}) addrman_info = node.getaddrmaninfo() assert_equal(addrman_info["all_networks"]["tried"], 1) assert_equal(addrman_info["all_networks"]["new"], 3) node.getnodeaddresses(count=0) # getnodeaddresses re-runs the addrman checks def test_sendmsgtopeer(self): node = self.nodes[0] self.restart_node(0) # we want to use a p2p v1 connection here in order to ensure # a peer id of zero (a downgrade from v2 to v1 would lead # to an increase of the peer id) self.connect_nodes(0, 1, peer_advertises_v2=False) self.log.info("Test sendmsgtopeer") self.log.debug("Send a valid message") with self.nodes[1].assert_debug_log(expected_msgs=["received: addr"]): node.sendmsgtopeer(peer_id=0, msg_type="addr", msg="FFFFFF") self.log.debug("Test error for sending to non-existing peer") assert_raises_rpc_error(-1, "Error: Could not send message to peer", node.sendmsgtopeer, peer_id=100, msg_type="addr", msg="FF") self.log.debug("Test that zero-length msg_type is allowed") node.sendmsgtopeer(peer_id=0, msg_type="addr", msg="") self.log.debug("Test error for msg_type that is too long") assert_raises_rpc_error(-8, "Error: msg_type too long, max length is 12", node.sendmsgtopeer, peer_id=0, msg_type="long_msg_type", msg="FF") self.log.debug("Test that unknown msg_type is allowed") node.sendmsgtopeer(peer_id=0, msg_type="unknown", msg="FF") self.log.debug("Test that empty msg is allowed") node.sendmsgtopeer(peer_id=0, msg_type="addr", msg="FF") self.log.debug("Test that oversized messages are allowed, but get us disconnected") zero_byte_string = b'\x00' * 4000001 node.sendmsgtopeer(peer_id=0, msg_type="addr", msg=zero_byte_string.hex()) self.wait_until(lambda: len(self.nodes[0].getpeerinfo()) == 0, timeout=10) def test_getaddrmaninfo(self): self.log.info("Test getaddrmaninfo") self.restart_node(1, extra_args=["-cjdnsreachable", "-test=addrman"], clear_addrman=True) node = self.nodes[1] seed_addrman(node) expected_network_count = { 'all_networks': {'new': 4, 'tried': 4, 'total': 8}, 'ipv4': {'new': 1, 'tried': 1, 'total': 2}, 'ipv6': {'new': 1, 'tried': 1, 'total': 2}, 'onion': {'new': 0, 'tried': 2, 'total': 2}, 'i2p': {'new': 1, 'tried': 0, 'total': 1}, 'cjdns': {'new': 1, 'tried': 0, 'total': 1}, } self.log.debug("Test that count of addresses in addrman match expected values") res = node.getaddrmaninfo() for network, count in expected_network_count.items(): assert_equal(res[network]['new'], count['new']) assert_equal(res[network]['tried'], count['tried']) assert_equal(res[network]['total'], count['total']) def test_getrawaddrman(self): self.log.info("Test getrawaddrman") self.restart_node(1, extra_args=["-cjdnsreachable", "-test=addrman"], clear_addrman=True) node = self.nodes[1] self.addr_time = int(time.time()) node.setmocktime(self.addr_time) seed_addrman(node) self.log.debug("Test that getrawaddrman is a hidden RPC") # It is hidden from general help, but its detailed help may be called directly. assert "getrawaddrman" not in node.help() assert "unknown command: getrawaddrman" not in node.help("getrawaddrman") def check_addr_information(result, expected): """Utility to compare a getrawaddrman result entry with an expected entry""" assert_equal(result["address"], expected["address"]) assert_equal(result["port"], expected["port"]) assert_equal(result["services"], expected["services"]) assert_equal(result["network"], expected["network"]) assert_equal(result["source"], expected["source"]) assert_equal(result["source_network"], expected["source_network"]) assert_equal(result["time"], self.addr_time) def check_getrawaddrman_entries(expected): """Utility to compare a getrawaddrman result with expected addrman contents""" getrawaddrman = node.getrawaddrman() getaddrmaninfo = node.getaddrmaninfo() for (table_name, table_info) in expected.items(): assert_equal(len(getrawaddrman[table_name]), len(table_info)) assert_equal(len(getrawaddrman[table_name]), getaddrmaninfo["all_networks"][table_name]) for bucket_position in getrawaddrman[table_name].keys(): entry = getrawaddrman[table_name][bucket_position] expected_entry = list(filter(lambda e: e["address"] == entry["address"], table_info))[0] assert bucket_position == expected_entry["bucket_position"] check_addr_information(entry, expected_entry) # we expect 4 new and 4 tried table entries in the addrman which were added using seed_addrman() expected = { "new": [ { "bucket_position": "82/8", "address": "2.0.0.0", "port": 8333, "services": 9, "network": "ipv4", "source": "2.0.0.0", "source_network": "ipv4", }, { "bucket_position": "336/24", "address": "fc00:1:2:3:4:5:6:7", "port": 8333, "services": 9, "network": "cjdns", "source": "fc00:1:2:3:4:5:6:7", "source_network": "cjdns", }, { "bucket_position": "963/46", "address": "c4gfnttsuwqomiygupdqqqyy5y5emnk5c73hrfvatri67prd7vyq.b32.i2p", "port": 8333, "services": 9, "network": "i2p", "source": "c4gfnttsuwqomiygupdqqqyy5y5emnk5c73hrfvatri67prd7vyq.b32.i2p", "source_network": "i2p", }, { "bucket_position": "613/6", "address": "2803:0:1234:abcd::1", "services": 9, "network": "ipv6", "source": "2803:0:1234:abcd::1", "source_network": "ipv6", "port": 45324, } ], "tried": [ { "bucket_position": "6/33", "address": "1.2.3.4", "port": 8333, "services": 9, "network": "ipv4", "source": "1.2.3.4", "source_network": "ipv4", }, { "bucket_position": "197/34", "address": "1233:3432:2434:2343:3234:2345:6546:4534", "port": 8333, "services": 9, "network": "ipv6", "source": "1233:3432:2434:2343:3234:2345:6546:4534", "source_network": "ipv6", }, { "bucket_position": "72/61", "address": "pg6mmjiyjmcrsslvykfwnntlaru7p5svn6y2ymmju6nubxndf4pscryd.onion", "port": 8333, "services": 9, "network": "onion", "source": "pg6mmjiyjmcrsslvykfwnntlaru7p5svn6y2ymmju6nubxndf4pscryd.onion", "source_network": "onion" }, { "bucket_position": "139/46", "address": "nrfj6inpyf73gpkyool35hcmne5zwfmse3jl3aw23vk7chdemalyaqad.onion", "services": 9, "network": "onion", "source": "nrfj6inpyf73gpkyool35hcmne5zwfmse3jl3aw23vk7chdemalyaqad.onion", "source_network": "onion", "port": 45324, } ] } self.log.debug("Test that getrawaddrman contains information about newly added addresses in each addrman table") check_getrawaddrman_entries(expected) if __name__ == '__main__': NetTest().main()