import random import asyncio from ast import literal_eval from .pb import rpc_pb2 from .pubsub_router_interface import IPubsubRouter from .mcache import MessageCache class GossipSub(IPubsubRouter): # pylint: disable=no-member # pylint: disable=too-many-instance-attributes # pylint: disable=too-many-public-methods def __init__(self, protocols, degree, degree_low, degree_high, time_to_live, gossip_window=3, gossip_history=5, heartbeat_interval=120): # pylint: disable=too-many-arguments self.protocols = protocols self.pubsub = None # Store target degree, upper degree bound, and lower degree bound self.degree = degree self.degree_high = degree_high self.degree_low = degree_low # Store time to live (for topics in fanout) self.time_to_live = time_to_live # Create topic --> list of peers mappings self.mesh = {} self.fanout = {} # Create topic --> time since last publish map self.time_since_last_publish = {} self.peers_gossipsub = [] self.peers_floodsub = [] # Create message cache self.mcache = MessageCache(gossip_window, gossip_history) # Create heartbeat timer self.heartbeat_interval = heartbeat_interval # Interface functions def get_protocols(self): """ :return: the list of protocols supported by the router """ return self.protocols def attach(self, pubsub): """ Attach is invoked by the PubSub constructor to attach the router to a freshly initialized PubSub instance. :param pubsub: pubsub instance to attach to """ self.pubsub = pubsub # Start heartbeat now that we have a pubsub instance # TODO: Start after delay asyncio.ensure_future(self.heartbeat()) def add_peer(self, peer_id, protocol_id): """ Notifies the router that a new peer has been connected :param peer_id: id of peer to add """ # Add peer to the correct peer list peer_type = GossipSub.get_peer_type(protocol_id) peer_id_str = str(peer_id) if peer_type == "gossip": self.peers_gossipsub.append(peer_id_str) elif peer_type == "flood": self.peers_floodsub.append(peer_id_str) def remove_peer(self, peer_id): """ Notifies the router that a peer has been disconnected :param peer_id: id of peer to remove """ peer_id_str = str(peer_id) self.peers_to_protocol.remove(peer_id_str) async def handle_rpc(self, rpc, sender_peer_id): """ Invoked to process control messages in the RPC envelope. It is invoked after subscriptions and payload messages have been processed :param rpc: rpc message """ control_message = rpc.control # Relay each rpc control to the appropriate handler if control_message.ihave: for ihave in control_message.ihave: await self.handle_ihave(ihave, sender_peer_id) if control_message.iwant: for iwant in control_message.iwant: await self.handle_iwant(iwant, sender_peer_id) if control_message.graft: for graft in control_message.graft: await self.handle_graft(graft, sender_peer_id) if control_message.prune: for prune in control_message.prune: await self.handle_prune(prune, sender_peer_id) async def publish(self, sender_peer_id, rpc_message): # pylint: disable=too-many-locals """ Invoked to forward a new message that has been validated. """ packet = rpc_pb2.RPC() packet.ParseFromString(rpc_message) msg_sender = str(sender_peer_id) # Deliver to self if self was origin # Note: handle_talk checks if self is subscribed to topics in message for message in packet.publish: # Add RPC message to cache self.mcache.put(message) decoded_from_id = message.from_id.decode('utf-8') new_packet = rpc_pb2.RPC() new_packet.publish.extend([message]) new_packet_serialized = new_packet.SerializeToString() # Deliver to self if needed if msg_sender == decoded_from_id and msg_sender == str(self.pubsub.host.get_id()): id_in_seen_msgs = (message.seqno, message.from_id) if id_in_seen_msgs not in self.pubsub.seen_messages: self.pubsub.seen_messages[id_in_seen_msgs] = 1 await self.pubsub.handle_talk(message) # Deliver to peers for topic in message.topicIDs: # If topic has floodsub peers, deliver to floodsub peers # TODO: This can be done more efficiently. Do it more efficiently. floodsub_peers_in_topic = [] if topic in self.pubsub.peer_topics: for peer in self.pubsub.peer_topics[topic]: if str(peer) in self.peers_floodsub: floodsub_peers_in_topic.append(peer) await self.deliver_messages_to_peers(floodsub_peers_in_topic, msg_sender, decoded_from_id, new_packet_serialized) # If you are subscribed to topic, send to mesh, otherwise send to fanout if topic in self.pubsub.my_topics and topic in self.mesh: await self.deliver_messages_to_peers(self.mesh[topic], msg_sender, decoded_from_id, new_packet_serialized) else: # Send to fanout peers if topic not in self.fanout: # If no peers in fanout, choose some peers from gossipsub peers in topic gossipsub_peers_in_topic = [peer for peer in self.pubsub.peer_topics[topic] if peer in self.peers_gossipsub] selected = \ GossipSub.select_from_minus(self.degree, gossipsub_peers_in_topic, []) self.fanout[topic] = selected # TODO: Is topic DEFINITELY supposed to be in fanout if we are not subscribed? # I assume there could be short periods between heartbeats where topic may not # be but we should check that this path gets hit appropriately await self.deliver_messages_to_peers(self.fanout[topic], msg_sender, decoded_from_id, new_packet_serialized) async def join(self, topic): # Note: the comments here are the near-exact algorithm description from the spec """ Join notifies the router that we want to receive and forward messages in a topic. It is invoked after the subscription announcement :param topic: topic to join """ if topic in self.mesh: return # Create mesh[topic] if it does not yet exist self.mesh[topic] = [] topic_in_fanout = topic in self.fanout fanout_peers = self.fanout[topic] if topic_in_fanout else [] fanout_size = len(fanout_peers) if not topic_in_fanout or (topic_in_fanout and fanout_size < self.degree): # There are less than D peers (let this number be x) # in the fanout for a topic (or the topic is not in the fanout). # Selects the remaining number of peers (D-x) from peers.gossipsub[topic]. if topic in self.pubsub.peer_topics: gossipsub_peers_in_topic = [peer for peer in self.pubsub.peer_topics[topic] if peer in self.peers_gossipsub] selected_peers = \ GossipSub.select_from_minus(self.degree - fanout_size, gossipsub_peers_in_topic, fanout_peers) # Combine fanout peers with selected peers fanout_peers += selected_peers # Add fanout peers to mesh and notifies them with a GRAFT(topic) control message. for peer in fanout_peers: if peer not in self.mesh[topic]: self.mesh[topic].append(peer) await self.emit_graft(topic, peer) if topic_in_fanout: del self.fanout[topic] async def leave(self, topic): # Note: the comments here are the near-exact algorithm description from the spec """ Leave notifies the router that we are no longer interested in a topic. It is invoked after the unsubscription announcement. :param topic: topic to leave """ if topic not in self.mesh: return # Notify the peers in mesh[topic] with a PRUNE(topic) message for peer in self.mesh[topic]: await self.emit_prune(topic, peer) # Forget mesh[topic] self.mesh.pop(topic, None) # Interface Helper Functions @staticmethod def get_peer_type(protocol_id): # TODO: Do this in a better, more efficient way if "gossipsub" in protocol_id: return "gossip" if "floodsub" in protocol_id: return "flood" return "unknown" async def deliver_messages_to_peers(self, peers, msg_sender, origin_id, serialized_packet): for peer_id_in_topic in peers: # Forward to all peers that are not the # message sender and are not the message origin if peer_id_in_topic not in (msg_sender, origin_id): stream = self.pubsub.peers[peer_id_in_topic] # Publish the packet await stream.write(serialized_packet) # Heartbeat async def heartbeat(self): """ Call individual heartbeats. Note: the heartbeats are called with awaits because each heartbeat depends on the state changes in the preceding heartbeat """ while True: await self.mesh_heartbeat() await self.fanout_heartbeat() await self.gossip_heartbeat() await asyncio.sleep(self.heartbeat_interval) async def mesh_heartbeat(self): # Note: the comments here are the exact pseudocode from the spec for topic in self.mesh: # Skip if no peers have subscribed to the topic if topic not in self.pubsub.peer_topics: continue num_mesh_peers_in_topic = len(self.mesh[topic]) if num_mesh_peers_in_topic < self.degree_low: gossipsub_peers_in_topic = [peer for peer in self.pubsub.peer_topics[topic] if peer in self.peers_gossipsub] # Select D - |mesh[topic]| peers from peers.gossipsub[topic] - mesh[topic] selected_peers = GossipSub.select_from_minus( self.degree - num_mesh_peers_in_topic, gossipsub_peers_in_topic, self.mesh[topic] ) fanout_peers_not_in_mesh = [ peer for peer in selected_peers if peer not in self.mesh[topic] ] for peer in fanout_peers_not_in_mesh: # Add peer to mesh[topic] self.mesh[topic].append(peer) # Emit GRAFT(topic) control message to peer await self.emit_graft(topic, peer) if num_mesh_peers_in_topic > self.degree_high: # Select |mesh[topic]| - D peers from mesh[topic] selected_peers = GossipSub.select_from_minus(num_mesh_peers_in_topic - self.degree, self.mesh[topic], []) for peer in selected_peers: # Remove peer from mesh[topic] self.mesh[topic].remove(peer) # Emit PRUNE(topic) control message to peer await self.emit_prune(topic, peer) async def fanout_heartbeat(self): # Note: the comments here are the exact pseudocode from the spec for topic in self.fanout: # If time since last published > ttl # TODO: there's no way time_since_last_publish gets set anywhere yet if self.time_since_last_publish[topic] > self.time_to_live: # Remove topic from fanout del self.fanout[topic] self.time_since_last_publish.remove(topic) else: num_fanout_peers_in_topic = len(self.fanout[topic]) # If |fanout[topic]| < D if num_fanout_peers_in_topic < self.degree: # Select D - |fanout[topic]| peers from peers.gossipsub[topic] - fanout[topic] gossipsub_peers_in_topic = [peer for peer in self.pubsub.peer_topics[topic] if peer in self.peers_gossipsub] selected_peers = \ GossipSub.select_from_minus(self.degree - num_fanout_peers_in_topic, gossipsub_peers_in_topic, self.fanout[topic]) # Add the peers to fanout[topic] self.fanout[topic].extend(selected_peers) async def gossip_heartbeat(self): # pylint: disable=too-many-nested-blocks for topic in self.mesh: msg_ids = self.mcache.window(topic) if msg_ids: # TODO: Make more efficient, possibly using a generator? # Get all pubsub peers in a topic and only add them if they are gossipsub peers too if topic in self.pubsub.peer_topics: gossipsub_peers_in_topic = [peer for peer in self.pubsub.peer_topics[topic] if peer in self.peers_gossipsub] # Select D peers from peers.gossipsub[topic] peers_to_emit_ihave_to = \ GossipSub.select_from_minus(self.degree, gossipsub_peers_in_topic, []) for peer in peers_to_emit_ihave_to: # TODO: this line is a monster, can hopefully be simplified if (topic not in self.mesh or (peer not in self.mesh[topic]))\ and (topic not in self.fanout or (peer not in self.fanout[topic])): msg_ids = [str(msg) for msg in msg_ids] await self.emit_ihave(topic, msg_ids, peer) # Do the same for fanout, for all topics not already hit in mesh for topic in self.fanout: if topic not in self.mesh: msg_ids = self.mcache.window(topic) if msg_ids: # TODO: Make more efficient, possibly using a generator? # Get all pubsub peers in topic and only add if they are gossipsub peers also if topic in self.pubsub.peer_topics: gossipsub_peers_in_topic = [peer for peer in self.pubsub.peer_topics[topic] if peer in self.peers_gossipsub] # Select D peers from peers.gossipsub[topic] peers_to_emit_ihave_to = \ GossipSub.select_from_minus(self.degree, gossipsub_peers_in_topic, []) for peer in peers_to_emit_ihave_to: if peer not in self.mesh[topic] and peer not in self.fanout[topic]: msg_ids = [str(msg) for msg in msg_ids] await self.emit_ihave(topic, msg_ids, peer) self.mcache.shift() @staticmethod def select_from_minus(num_to_select, pool, minus): """ Select at most num_to_select subset of elements from the set (pool - minus) randomly. :param num_to_select: number of elements to randomly select :param pool: list of items to select from (excluding elements in minus) :param minus: elements to be excluded from selection pool :return: list of selected elements """ # Create selection pool, which is selection_pool = pool - minus if minus: # Create a new selection pool by removing elements of minus selection_pool = [x for x in pool if x not in minus] else: # Don't create a new selection_pool if we are not subbing anything selection_pool = pool # If num_to_select > size(selection_pool), then return selection_pool (which has the most # possible elements s.t. the number of elements is less than num_to_select) if num_to_select > len(selection_pool): return selection_pool # Random selection selection = random.sample(selection_pool, num_to_select) return selection # RPC handlers async def handle_ihave(self, ihave_msg, sender_peer_id): """ Checks the seen set and requests unknown messages with an IWANT message. """ # from_id_bytes = ihave_msg.from_id from_id_str = sender_peer_id # Get list of all seen (seqnos, from) from the (seqno, from) tuples in seen_messages cache seen_seqnos_and_peers = [seqno_and_from for seqno_and_from in self.pubsub.seen_messages.keys()] # Add all unknown message ids (ids that appear in ihave_msg but not in seen_seqnos) to list # of messages we want to request msg_ids_wanted = [msg_id for msg_id in ihave_msg.messageIDs if literal_eval(msg_id) not in seen_seqnos_and_peers] # Request messages with IWANT message if msg_ids_wanted: await self.emit_iwant(msg_ids_wanted, from_id_str) async def handle_iwant(self, iwant_msg, sender_peer_id): """ Forwards all request messages that are present in mcache to the requesting peer. """ from_id_str = sender_peer_id msg_ids = [literal_eval(msg) for msg in iwant_msg.messageIDs] msgs_to_forward = [] for msg_id_iwant in msg_ids: # Check if the wanted message ID is present in mcache msg = self.mcache.get(msg_id_iwant) # Cache hit if msg: # Add message to list of messages to forward to requesting peers msgs_to_forward.append(msg) # Forward messages to requesting peer # Should this just be publishing? No # because then the message will forwarded to peers in the topics contained in the messages. # We should # 1) Package these messages into a single packet packet = rpc_pb2.RPC() packet.publish.extend(msgs_to_forward) # 2) Serialize that packet rpc_msg = packet.SerializeToString() # 3) Get the stream to this peer # TODO: Should we pass in from_id or from_id_str here? peer_stream = self.pubsub.peers[from_id_str] # 4) And write the packet to the stream await peer_stream.write(rpc_msg) async def handle_graft(self, graft_msg, sender_peer_id): topic = graft_msg.topicID from_id_str = sender_peer_id # Add peer to mesh for topic if topic in self.mesh: if from_id_str not in self.mesh[topic]: self.mesh[topic].append(from_id_str) else: # Respond with PRUNE if not subscribed to the topic await self.emit_prune(topic, sender_peer_id) async def handle_prune(self, prune_msg, sender_peer_id): topic = prune_msg.topicID from_id_str = sender_peer_id # Remove peer from mesh for topic, if peer is in topic if topic in self.mesh and from_id_str in self.mesh[topic]: self.mesh[topic].remove(from_id_str) # RPC emitters async def emit_ihave(self, topic, msg_ids, to_peer): """ Emit ihave message, sent to to_peer, for topic and msg_ids """ ihave_msg = rpc_pb2.ControlIHave() ihave_msg.messageIDs.extend(msg_ids) ihave_msg.topicID = topic control_msg = rpc_pb2.ControlMessage() control_msg.ihave.extend([ihave_msg]) await self.emit_control_message(control_msg, to_peer) async def emit_iwant(self, msg_ids, to_peer): """ Emit iwant message, sent to to_peer, for msg_ids """ iwant_msg = rpc_pb2.ControlIWant() iwant_msg.messageIDs.extend(msg_ids) control_msg = rpc_pb2.ControlMessage() control_msg.iwant.extend([iwant_msg]) await self.emit_control_message(control_msg, to_peer) async def emit_graft(self, topic, to_peer): """ Emit graft message, sent to to_peer, for topic """ graft_msg = rpc_pb2.ControlGraft() graft_msg.topicID = topic control_msg = rpc_pb2.ControlMessage() control_msg.graft.extend([graft_msg]) await self.emit_control_message(control_msg, to_peer) async def emit_prune(self, topic, to_peer): """ Emit graft message, sent to to_peer, for topic """ prune_msg = rpc_pb2.ControlPrune() prune_msg.topicID = topic control_msg = rpc_pb2.ControlMessage() control_msg.prune.extend([prune_msg]) await self.emit_control_message(control_msg, to_peer) async def emit_control_message(self, control_msg, to_peer): # Add control message to packet packet = rpc_pb2.RPC() packet.control.CopyFrom(control_msg) rpc_msg = packet.SerializeToString() # Get stream for peer from pubsub peer_stream = self.pubsub.peers[to_peer] # Write rpc to stream await peer_stream.write(rpc_msg)