import logging import socket import functools import hashlib import asyncio import typing import binascii from asyncio.protocols import DatagramProtocol from asyncio.transports import DatagramTransport from lbrynet.dht import constants from lbrynet.dht.serialization.datagram import decode_datagram, ErrorDatagram, ResponseDatagram, RequestDatagram from lbrynet.dht.serialization.datagram import RESPONSE_TYPE, ERROR_TYPE from lbrynet.dht.error import RemoteException, TransportNotConnected from lbrynet.dht.protocol.routing_table import TreeRoutingTable from lbrynet.dht.protocol.data_store import DictDataStore if typing.TYPE_CHECKING: from lbrynet.dht.peer import PeerManager, KademliaPeer log = logging.getLogger(__name__) old_protocol_errors = { "findNode() takes exactly 2 arguments (5 given)": "0.19.1", "findValue() takes exactly 2 arguments (5 given)": "0.19.1" } class KademliaRPC: def __init__(self, protocol: 'KademliaProtocol', loop: asyncio.BaseEventLoop, peer_port: int = 3333): self.protocol = protocol self.loop = loop self.peer_port = peer_port self.old_token_secret: bytes = None self.token_secret = constants.generate_id() def compact_address(self): compact_ip = functools.reduce(lambda buff, x: buff + bytearray([int(x)]), self.protocol.external_ip.split('.'), bytearray()) compact_port = self.peer_port.to_bytes(2, 'big') return compact_ip + compact_port + self.protocol.node_id @staticmethod def ping(): return b'pong' def store(self, rpc_contact: 'KademliaPeer', blob_hash: bytes, token: bytes, port: int, original_publisher_id: bytes, age: int) -> bytes: if original_publisher_id is None: original_publisher_id = rpc_contact.node_id rpc_contact.update_tcp_port(port) if self.loop.time() - self.protocol.started_listening_time < constants.token_secret_refresh_interval: pass elif not self.verify_token(token, rpc_contact.compact_ip()): raise ValueError("Invalid token") now = int(self.loop.time()) originally_published = now - age self.protocol.data_store.add_peer_to_blob( rpc_contact, blob_hash, rpc_contact.compact_address_tcp(), now, originally_published, original_publisher_id ) return b'OK' def find_node(self, rpc_contact: 'KademliaPeer', key: bytes) -> typing.List[typing.Tuple[bytes, str, int]]: if len(key) != constants.hash_length: raise ValueError("invalid contact node_id length: %i" % len(key)) contacts = self.protocol.routing_table.find_close_peers(key, sender_node_id=rpc_contact.node_id) contact_triples = [] for contact in contacts: contact_triples.append((contact.node_id, contact.address, contact.udp_port)) return contact_triples def find_value(self, rpc_contact: 'KademliaPeer', key: bytes): if len(key) != constants.hash_length: raise ValueError("invalid blob_exchange hash length: %i" % len(key)) response = { b'token': self.make_token(rpc_contact.compact_ip()), b'contacts': self.find_node(rpc_contact, key) } if self.protocol.protocol_version: response[b'protocolVersion'] = self.protocol.protocol_version # get peers we have stored for this blob_exchange peers = [ peer.compact_address_tcp() for peer in self.protocol.data_store.get_peers_for_blob(key) if not rpc_contact.tcp_port or peer.compact_address_tcp() != rpc_contact.compact_address_tcp() ] # if we don't have k storing peers to return and we have this hash locally, include our contact information if len(peers) < constants.k and binascii.hexlify(key).decode() in self.protocol.data_store.completed_blobs: peers.append(self.compact_address()) if peers: response[key] = peers return response def refresh_token(self): # TODO: this needs to be called periodically self.old_token_secret = self.token_secret self.token_secret = constants.generate_id() def make_token(self, compact_ip): h = hashlib.new('sha384') h.update(self.token_secret + compact_ip) return h.digest() def verify_token(self, token, compact_ip): h = hashlib.new('sha384') h.update(self.token_secret + compact_ip) if self.old_token_secret and not token == h.digest(): # TODO: why should we be accepting the previous token? h = hashlib.new('sha384') h.update(self.old_token_secret + compact_ip) if not token == h.digest(): return False return True class RemoteKademliaRPC: """ Encapsulates RPC calls to remote Peers """ def __init__(self, loop: asyncio.BaseEventLoop, peer_tracker: 'PeerManager', protocol: 'KademliaProtocol', peer: 'KademliaPeer'): self.loop = loop self.peer_tracker = peer_tracker self.protocol = protocol self.peer = peer async def ping(self) -> bytes: """ :return: b'pong' """ response = await self.protocol.send_request( self.peer, RequestDatagram.make_ping(self.protocol.node_id) ) return response.response async def store(self, blob_hash: bytes) -> bytes: """ :param blob_hash: blob hash as bytes :return: b'OK' """ if len(blob_hash) != constants.hash_bits // 8: raise ValueError(f"invalid length of blob hash: {len(blob_hash)}") if not self.protocol.peer_port or not 0 < self.protocol.peer_port < 65535: raise ValueError(f"invalid tcp port: {self.protocol.peer_port}") token = self.peer_tracker.get_node_token(self.peer.node_id) if not token: find_value_resp = await self.find_value(blob_hash) token = find_value_resp[b'token'] response = await self.protocol.send_request( self.peer, RequestDatagram.make_store(self.protocol.node_id, blob_hash, token, self.protocol.peer_port) ) return response.response async def find_node(self, key: bytes) -> typing.List[typing.Tuple[bytes, str, int]]: """ :return: [(node_id, address, udp_port), ...] """ if len(key) != constants.hash_bits // 8: raise ValueError(f"invalid length of find node key: {len(key)}") response = await self.protocol.send_request( self.peer, RequestDatagram.make_find_node(self.protocol.node_id, key) ) return [(node_id, address.decode(), udp_port) for node_id, address, udp_port in response.response] async def find_value(self, key: bytes) -> typing.Union[typing.Dict]: """ :return: { b'token': , b'contacts': [(node_id, address, udp_port), ...] : [= d] for k in scheduled: del self._pending_contacts[k] if k not in self._enqueued_contacts: self._enqueued_contacts.append(k) while self._enqueued_contacts: peer = self._enqueued_contacts.pop() tasks.append(self._loop.create_task(_ping(peer))) if tasks: await asyncio.wait(tasks, loop=self._loop) f = self._loop.create_future() self._loop.call_later(1.0, lambda: None if f.done() else f.set_result(None)) await f def start(self): assert not self._running self._running = True if not self._process_task: self._process_task = self._loop.create_task(self._process()) def stop(self): assert self._running self._running = False if self._process_task: self._process_task.cancel() self._process_task = None if self._next_task: self._next_task.cancel() self._next_task = None if self._next_timer: self._next_timer.cancel() self._next_timer = None class KademliaProtocol(DatagramProtocol): def __init__(self, loop: asyncio.BaseEventLoop, peer_manager: 'PeerManager', node_id: bytes, external_ip: str, udp_port: int, peer_port: int, rpc_timeout: float = 5.0): self.peer_manager = peer_manager self.loop = loop self.node_id = node_id self.external_ip = external_ip self.udp_port = udp_port self.peer_port = peer_port self.is_seed_node = False self.partial_messages: typing.Dict[bytes, typing.Dict[bytes, bytes]] = {} self.sent_messages: typing.Dict[bytes, typing.Tuple['KademliaPeer', asyncio.Future, RequestDatagram]] = {} self.protocol_version = constants.protocol_version self.started_listening_time = 0 self.transport: DatagramTransport = None self.old_token_secret = constants.generate_id() self.token_secret = constants.generate_id() self.routing_table = TreeRoutingTable(self.loop, self.peer_manager, self.node_id) self.data_store = DictDataStore(self.loop, self.peer_manager) self.ping_queue = PingQueue(self.loop, self) self.node_rpc = KademliaRPC(self, self.loop, self.peer_port) self.lock = asyncio.Lock(loop=self.loop) self.rpc_timeout = rpc_timeout self._split_lock = asyncio.Lock(loop=self.loop) def get_rpc_peer(self, peer: 'KademliaPeer') -> RemoteKademliaRPC: return RemoteKademliaRPC(self.loop, self.peer_manager, self, peer) def stop(self): if self.transport: self.disconnect() def disconnect(self): self.transport.close() def connection_made(self, transport: DatagramTransport): self.transport = transport def connection_lost(self, exc): self.stop() @staticmethod def _migrate_incoming_rpc_args(peer: 'KademliaPeer', method: bytes, *args) -> typing.Tuple[typing.Tuple, typing.Dict]: if method == b'store' and peer.protocol_version == 0: if isinstance(args[1], dict): blob_hash = args[0] token = args[1].pop(b'token', None) port = args[1].pop(b'port', -1) original_publisher_id = args[1].pop(b'lbryid', None) age = 0 return (blob_hash, token, port, original_publisher_id, age), {} return args, {} async def _add_peer(self, peer: 'KademliaPeer'): bucket_index = self.routing_table.kbucket_index(peer.node_id) if self.routing_table.buckets[bucket_index].add_peer(peer): return True # The bucket is full; see if it can be split (by checking if its range includes the host node's node_id) if self.routing_table.should_split(bucket_index, peer.node_id): self.routing_table.split_bucket(bucket_index) # Retry the insertion attempt result = await self._add_peer(peer) self.routing_table.join_buckets() return result else: # We can't split the k-bucket # # The 13 page kademlia paper specifies that the least recently contacted node in the bucket # shall be pinged. If it fails to reply it is replaced with the new contact. If the ping is successful # the new contact is ignored and not added to the bucket (sections 2.2 and 2.4). # # A reasonable extension to this is BEP 0005, which extends the above: # # Not all nodes that we learn about are equal. Some are "good" and some are not. # Many nodes using the DHT are able to send queries and receive responses, # but are not able to respond to queries from other nodes. It is important that # each node's routing table must contain only known good nodes. A good node is # a node has responded to one of our queries within the last 15 minutes. A node # is also good if it has ever responded to one of our queries and has sent us a # query within the last 15 minutes. After 15 minutes of inactivity, a node becomes # questionable. Nodes become bad when they fail to respond to multiple queries # in a row. Nodes that we know are good are given priority over nodes with unknown status. # # When there are bad or questionable nodes in the bucket, the least recent is selected for # potential replacement (BEP 0005). When all nodes in the bucket are fresh, the head (least recent) # contact is selected as described in section 2.2 of the kademlia paper. In both cases the new contact # is ignored if the pinged node replies. not_good_contacts = self.routing_table.buckets[bucket_index].get_bad_or_unknown_peers() not_recently_replied = [] for p in not_good_contacts: last_replied = self.peer_manager.get_last_replied(p.address, p.udp_port) if not last_replied or last_replied + 60 < self.loop.time(): not_recently_replied.append(p) if not_recently_replied: to_replace = not_recently_replied[0] else: to_replace = self.routing_table.buckets[bucket_index].peers[0] last_replied = self.peer_manager.get_last_replied(to_replace.address, to_replace.udp_port) if last_replied and last_replied + 60 > self.loop.time(): return False log.debug("pinging %s:%s", to_replace.address, to_replace.udp_port) try: to_replace_rpc = self.get_rpc_peer(to_replace) await to_replace_rpc.ping() return False except asyncio.TimeoutError: log.debug("Replacing dead contact in bucket %i: %s:%i with %s:%i ", bucket_index, to_replace.address, to_replace.udp_port, peer.address, peer.udp_port) if to_replace in self.routing_table.buckets[bucket_index]: self.routing_table.buckets[bucket_index].remove_peer(to_replace) return await self._add_peer(peer) async def add_peer(self, peer: 'KademliaPeer') -> bool: if peer.node_id == self.node_id: return False async with self._split_lock: return await self._add_peer(peer) async def _handle_rpc(self, sender_contact: 'KademliaPeer', message: RequestDatagram): assert sender_contact.node_id != self.node_id, (binascii.hexlify(sender_contact.node_id)[:8].decode(), binascii.hexlify(self.node_id)[:8].decode()) method = message.method if method not in [b'ping', b'store', b'findNode', b'findValue']: raise AttributeError('Invalid method: %s' % message.method.decode()) if message.args and isinstance(message.args[-1], dict) and b'protocolVersion' in message.args[-1]: # args don't need reformatting a, kw = tuple(message.args[:-1]), message.args[-1] else: a, kw = self._migrate_incoming_rpc_args(sender_contact, message.method, *message.args) log.debug("%s:%i RECV CALL %s %s:%i", self.external_ip, self.udp_port, message.method.decode(), sender_contact.address, sender_contact.udp_port) if method == b'ping': result = self.node_rpc.ping() elif method == b'store': blob_hash, token, port, original_publisher_id, age = a result = self.node_rpc.store(sender_contact, blob_hash, token, port, original_publisher_id, age) elif method == b'findNode': key, = a result = self.node_rpc.find_node(sender_contact, key) else: assert method == b'findValue' key, = a result = self.node_rpc.find_value(sender_contact, key) await self.send_response( sender_contact, ResponseDatagram(RESPONSE_TYPE, message.rpc_id, self.node_id, result), ) async def handle_request_datagram(self, address, request_datagram: RequestDatagram): # This is an RPC method request self.peer_manager.report_last_requested(address[0], address[1]) self.peer_manager.update_contact_triple(request_datagram.node_id, address[0], address[1]) # only add a requesting contact to the routing table if it has replied to one of our requests peer = self.peer_manager.get_kademlia_peer(request_datagram.node_id, address[0], address[1]) try: await self._handle_rpc(peer, request_datagram) # if the contact is not known to be bad (yet) and we haven't yet queried it, send it a ping so that it # will be added to our routing table if successful is_good = self.peer_manager.peer_is_good(peer) if is_good is None: await self.ping_queue.enqueue_maybe_ping(peer) elif is_good is True: await self.add_peer(peer) except Exception as err: log.warning("error raised handling %s request from %s:%i - %s(%s)", request_datagram.method, peer.address, peer.udp_port, str(type(err)), str(err)) await self.send_error( peer, ErrorDatagram(ERROR_TYPE, request_datagram.rpc_id, self.node_id, str(type(err)).encode(), str(err).encode()) ) async def handle_response_datagram(self, address: typing.Tuple[str, int], response_datagram: ResponseDatagram): # Find the message that triggered this response if response_datagram.rpc_id in self.sent_messages: peer, df, request = self.sent_messages[response_datagram.rpc_id] if peer.address != address[0]: df.set_exception(RemoteException( f"response from {address[0]}:{address[1]}, " f"expected {peer.address}:{peer.udp_port}") ) return peer.set_id(response_datagram.node_id) # We got a result from the RPC if peer.node_id == self.node_id: df.set_exception(RemoteException("node has our node id")) return elif response_datagram.node_id == self.node_id: df.set_exception(RemoteException("incoming message is from our node id")) return self.peer_manager.report_last_replied(address[0], address[1]) self.peer_manager.update_contact_triple(peer.node_id, address[0], address[1]) if not df.cancelled(): df.set_result(response_datagram) await self.add_peer(peer) else: log.warning("%s:%i replied, but after we cancelled the request attempt", peer.address, peer.udp_port) else: # If the original message isn't found, it must have timed out # TODO: we should probably do something with this... pass def handle_error_datagram(self, address, error_datagram: ErrorDatagram): # The RPC request raised a remote exception; raise it locally remote_exception = RemoteException(f"{error_datagram.exception_type}({error_datagram.response})") if error_datagram.rpc_id in self.sent_messages: peer, df, request = self.sent_messages.pop(error_datagram.rpc_id) error_msg = f"" \ f"Error sending '{request.method}' to {peer.address}:{peer.udp_port}\n" \ f"Args: {request.args}\n" \ f"Raised: {str(remote_exception)}" if error_datagram.response not in old_protocol_errors: log.warning(error_msg) else: log.warning("known dht protocol backwards compatibility error with %s:%i (lbrynet v%s)", peer.address, peer.udp_port, old_protocol_errors[error_datagram.response]) # reject replies coming from a different address than what we sent our request to if (peer.address, peer.udp_port) != address: log.error("node id mismatch in reply") remote_exception = TimeoutError(peer.node_id) df.set_exception(remote_exception) return else: if error_datagram.response not in old_protocol_errors: msg = f"Received error from {address[0]}:{address[1]}, but it isn't in response to a " \ f"pending request: {str(remote_exception)}" log.warning(msg) else: log.warning("known dht protocol backwards compatibility error with %s:%i (lbrynet v%s)", address[0], address[1], old_protocol_errors[error_datagram.response]) def datagram_received(self, datagram: bytes, address: typing.Tuple[str, int]) -> None: try: message = decode_datagram(datagram) except (ValueError, TypeError): self.peer_manager.report_failure(address[0], address[1]) log.warning("Couldn't decode dht datagram from %s: %s", address, binascii.hexlify(datagram).decode()) return if isinstance(message, RequestDatagram): self.loop.create_task(self.handle_request_datagram(address, message)) elif isinstance(message, ErrorDatagram): self.handle_error_datagram(address, message) else: assert isinstance(message, ResponseDatagram), "sanity" self.loop.create_task(self.handle_response_datagram(address, message)) async def send_request(self, peer: 'KademliaPeer', request: RequestDatagram) -> ResponseDatagram: await self._send(peer, request) response_fut = self.sent_messages[request.rpc_id][1] try: response = await asyncio.wait_for(response_fut, self.rpc_timeout) self.peer_manager.report_last_replied(peer.address, peer.udp_port) return response except (asyncio.TimeoutError, RemoteException): self.peer_manager.report_failure(peer.address, peer.udp_port) if self.peer_manager.peer_is_good(peer) is False: self.routing_table.remove_peer(peer) raise async def send_response(self, peer: 'KademliaPeer', response: ResponseDatagram): await self._send(peer, response) async def send_error(self, peer: 'KademliaPeer', error: ErrorDatagram): await self._send(peer, error) async def _send(self, peer: 'KademliaPeer', message: typing.Union[RequestDatagram, ResponseDatagram, ErrorDatagram]): if not self.transport: raise TransportNotConnected() data = message.bencode() if len(data) > constants.msg_size_limit: log.exception("unexpected: %i vs %i", len(data), constants.msg_size_limit) raise ValueError() if isinstance(message, (RequestDatagram, ResponseDatagram)): assert message.node_id == self.node_id, message if isinstance(message, RequestDatagram): assert self.node_id != peer.node_id def pop_from_sent_messages(_): if message.rpc_id in self.sent_messages: self.sent_messages.pop(message.rpc_id) async with self.lock: if isinstance(message, RequestDatagram): response_fut = self.loop.create_future() response_fut.add_done_callback(pop_from_sent_messages) self.sent_messages[message.rpc_id] = (peer, response_fut, message) try: self.transport.sendto(data, (peer.address, peer.udp_port)) except OSError as err: # TODO: handle ENETUNREACH if err.errno == socket.EWOULDBLOCK: # i'm scared this may swallow important errors, but i get a million of these # on Linux and it doesn't seem to affect anything -grin log.warning("Can't send data to dht: EWOULDBLOCK") else: log.error("DHT socket error sending %i bytes to %s:%i - %s (code %i)", len(data), peer.address, peer.udp_port, str(err), err.errno) if isinstance(message, RequestDatagram): self.sent_messages[message.rpc_id][1].set_exception(err) else: raise err if isinstance(message, RequestDatagram): self.peer_manager.report_last_sent(peer.address, peer.udp_port) elif isinstance(message, ErrorDatagram): self.peer_manager.report_failure(peer.address, peer.udp_port) def change_token(self): self.old_token_secret = self.token_secret self.token_secret = constants.generate_id() def make_token(self, compact_ip): return constants.digest(self.token_secret + compact_ip) def verify_token(self, token, compact_ip): h = constants.hash_class() h.update(self.token_secret + compact_ip) if self.old_token_secret and not token == h.digest(): # TODO: why should we be accepting the previous token? h = constants.hash_class() h.update(self.old_token_secret + compact_ip) if not token == h.digest(): return False return True async def store_to_peer(self, hash_value: bytes, peer: 'KademliaPeer') -> typing.Tuple[bytes, bool]: try: res = await self.get_rpc_peer(peer).store(hash_value) if res != b"OK": raise ValueError(res) log.debug("Stored %s to %s", binascii.hexlify(hash_value).decode()[:8], peer) return peer.node_id, True except asyncio.TimeoutError: log.debug("Timeout while storing blob_hash %s at %s", binascii.hexlify(hash_value).decode()[:8], peer) except ValueError as err: log.error("Unexpected response: %s" % err) except Exception as err: if 'Invalid token' in str(err): self.peer_manager.clear_token(peer.node_id) else: log.exception("Unexpected error while storing blob_hash") return peer.node_id, False def _write(self, data: bytes, address: typing.Tuple[str, int]): if self.transport: try: self.transport.sendto(data, address) except OSError as err: if err.errno == socket.EWOULDBLOCK: # i'm scared this may swallow important errors, but i get a million of these # on Linux and it doesn't seem to affect anything -grin log.warning("Can't send data to dht: EWOULDBLOCK") # elif err.errno == socket.ENETUNREACH: # # this should probably try to retransmit when the network connection is back # log.error("Network is unreachable") else: log.error("DHT socket error sending %i bytes to %s:%i - %s (code %i)", len(data), address[0], address[1], str(err), err.errno) raise err else: raise TransportNotConnected()