import logging.config import random import socket import struct import threading import os from coapthon import defines from coapthon.layers.blocklayer import BlockLayer from coapthon.layers.cachelayer import CacheLayer from coapthon.layers.forwardLayer import ForwardLayer from coapthon.layers.messagelayer import MessageLayer from coapthon.layers.observelayer import ObserveLayer from coapthon.layers.resourcelayer import ResourceLayer from coapthon.messages.message import Message from coapthon.messages.request import Request from coapthon.resources.resource import Resource from coapthon.serializer import Serializer from coapthon.utils import Tree __author__ = 'Giacomo Tanganelli' logger = logging.getLogger(__name__) class CoAP(object): """ Implementation of the Forward Proxy """ def __init__(self, server_address, multicast=False, starting_mid=None, cache=False, sock=None): """ Initialize the Forward Proxy. :param server_address: Server address for incoming connections :param multicast: if the ip is a multicast address :param starting_mid: used for testing purposes :param cache: if a cache must be used :param sock: if a socket has been created externally, it can be used directly """ self.stopped = threading.Event() self.stopped.clear() self.to_be_stopped = [] self.purge = threading.Thread(target=self.purge) self.purge.start() self.cache_enable = cache self._messageLayer = MessageLayer(starting_mid) self._blockLayer = BlockLayer() self._observeLayer = ObserveLayer() if self.cache_enable: self._cacheLayer = CacheLayer(defines.FORWARD_PROXY) else: self._cacheLayer = None self._forwardLayer = ForwardLayer(self) self.resourceLayer = ResourceLayer(self) # Resource directory root = Resource('root', self, visible=False, observable=False, allow_children=True) root.path = '/' self.root = Tree() self.root["/"] = root self._serializer = None self.server_address = server_address self.multicast = multicast addrinfo = socket.getaddrinfo(self.server_address[0], None)[0] if sock is not None: # Use given socket, could be a DTLS socket self._socket = sock elif self.multicast: # pragma: no cover # Create a socket # self._socket.setsockopt(socket.SOL_IP, socket.IP_MULTICAST_TTL, 255) # self._socket.setsockopt(socket.SOL_IP, socket.IP_MULTICAST_LOOP, 1) # Join group if addrinfo[0] == socket.AF_INET: # IPv4 self._socket = socket.socket(socket.AF_INET, socket.SOCK_DGRAM, socket.IPPROTO_UDP) # Allow multiple copies of this program on one machine # (not strictly needed) self._socket.setsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR, 1) self._socket.bind((defines.ALL_COAP_NODES, self.server_address[1])) mreq = struct.pack("4sl", socket.inet_aton(defines.ALL_COAP_NODES), socket.INADDR_ANY) self._socket.setsockopt(socket.IPPROTO_IP, socket.IP_ADD_MEMBERSHIP, mreq) self._unicast_socket = socket.socket(socket.AF_INET, socket.SOCK_DGRAM) self._unicast_socket.setsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR, 1) self._unicast_socket.bind(self.server_address) else: self._socket = socket.socket(socket.AF_INET6, socket.SOCK_DGRAM, socket.IPPROTO_UDP) # Allow multiple copies of this program on one machine # (not strictly needed) self._socket.setsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR, 1) self._socket.bind((defines.ALL_COAP_NODES_IPV6, self.server_address[1])) addrinfo_multicast = socket.getaddrinfo(defines.ALL_COAP_NODES_IPV6, 5683)[0] group_bin = socket.inet_pton(socket.AF_INET6, addrinfo_multicast[4][0]) mreq = group_bin + struct.pack('@I', 0) self._socket.setsockopt(socket.IPPROTO_IPV6, socket.IPV6_JOIN_GROUP, mreq) self._unicast_socket = socket.socket(socket.AF_INET6, socket.SOCK_DGRAM) self._unicast_socket.setsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR, 1) self._unicast_socket.bind(self.server_address) else: if addrinfo[0] == socket.AF_INET: # IPv4 self._socket = socket.socket(socket.AF_INET, socket.SOCK_DGRAM) self._socket.setsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR, 1) else: self._socket = socket.socket(socket.AF_INET6, socket.SOCK_DGRAM) self._socket.setsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR, 1) self._socket.bind(self.server_address) def purge(self): """ Clean old transactions """ while not self.stopped.isSet(): self.stopped.wait(timeout=defines.EXCHANGE_LIFETIME) self._messageLayer.purge() def listen(self, timeout=10): """ Listen for incoming messages. Timeout is used to check if the server must be switched off. :param timeout: Socket Timeout in seconds """ self._socket.settimeout(float(timeout)) while not self.stopped.isSet(): try: data, client_address = self._socket.recvfrom(4096) except socket.timeout: continue try: #Start a new thread not to block other requests args = ((data, client_address), ) t = threading.Thread(target=self.receive_datagram, args=args) t.daemon = True t.start() except RuntimeError: logging.exception("Exception with Executor") logging.debug("closing socket") self._socket.close() def close(self): """ Stop the server. """ logger.info("Stop server") self.stopped.set() for event in self.to_be_stopped: event.set() self._socket.close() def receive_datagram(self, args): """ Handle messages coming from the udp socket. :param args: (data, client_address) """ data, client_address = args logging.debug("receiving datagram") try: host, port = client_address except ValueError: host, port, tmp1, tmp2 = client_address client_address = (host, port) serializer = Serializer() message = serializer.deserialize(data, client_address) if isinstance(message, int): logger.error("receive_datagram - BAD REQUEST") rst = Message() rst.destination = client_address rst.type = defines.Types["RST"] rst.code = message self.send_datagram(rst) return logger.debug("receive_datagram - " + str(message)) if isinstance(message, Request): transaction = self._messageLayer.receive_request(message) if transaction.request.duplicated and transaction.completed: logger.debug("message duplicated,transaction completed") transaction = self._observeLayer.send_response(transaction) transaction = self._blockLayer.send_response(transaction) transaction = self._messageLayer.send_response(transaction) self.send_datagram(transaction.response) return elif transaction.request.duplicated and not transaction.completed: logger.debug("message duplicated,transaction NOT completed") self._send_ack(transaction) return transaction.separate_timer = self._start_separate_timer(transaction) transaction = self._blockLayer.receive_request(transaction) if transaction.block_transfer: self._stop_separate_timer(transaction.separate_timer) transaction = self._messageLayer.send_response(transaction) self.send_datagram(transaction.response) return transaction = self._observeLayer.receive_request(transaction) """ call to the cache layer to check if there's a cached response for the request if not, call the forward layer """ if self._cacheLayer is not None: transaction = self._cacheLayer.receive_request(transaction) if transaction.cacheHit is False: logging.debug(transaction.request) transaction = self._forwardLayer.receive_request(transaction) logging.debug(transaction.response) transaction = self._observeLayer.send_response(transaction) transaction = self._blockLayer.send_response(transaction) transaction = self._cacheLayer.send_response(transaction) else: transaction = self._forwardLayer.receive_request(transaction) transaction = self._observeLayer.send_response(transaction) transaction = self._blockLayer.send_response(transaction) self._stop_separate_timer(transaction.separate_timer) transaction = self._messageLayer.send_response(transaction) if transaction.response is not None: if transaction.response.type == defines.Types["CON"]: self._start_retransmission(transaction, transaction.response) self.send_datagram(transaction.response) elif isinstance(message, Message): transaction = self._messageLayer.receive_empty(message) if transaction is not None: transaction = self._blockLayer.receive_empty(message, transaction) self._observeLayer.receive_empty(message, transaction) else: # is Response logger.error("Received response from %s", message.source) def send_datagram(self, message): """ Send a message through the udp socket. :type message: Message :param message: the message to send """ if not self.stopped.isSet(): host, port = message.destination logger.debug("send_datagram - " + str(message)) serializer = Serializer() message = serializer.serialize(message) self._socket.sendto(message, (host, port)) def _start_retransmission(self, transaction, message): """ Start the retransmission task. :type transaction: Transaction :param transaction: the transaction that owns the message that needs retransmission :type message: Message :param message: the message that needs the retransmission task """ with transaction: if message.type == defines.Types['CON']: future_time = random.uniform(defines.ACK_TIMEOUT, (defines.ACK_TIMEOUT * defines.ACK_RANDOM_FACTOR)) transaction.retransmit_thread = threading.Thread(target=self._retransmit, args=(transaction, message, future_time, 0)) transaction.retransmit_stop = threading.Event() self.to_be_stopped.append(transaction.retransmit_stop) transaction.retransmit_thread.start() def _retransmit(self, transaction, message, future_time, retransmit_count): """ Thread function to retransmit the message in the future :param transaction: the transaction that owns the message that needs retransmission :param message: the message that needs the retransmission task :param future_time: the amount of time to wait before a new attempt :param retransmit_count: the number of retransmissions """ with transaction: while retransmit_count < defines.MAX_RETRANSMIT and (not message.acknowledged and not message.rejected) \ and not self.stopped.isSet(): transaction.retransmit_stop.wait(timeout=future_time) if not message.acknowledged and not message.rejected and not self.stopped.isSet(): retransmit_count += 1 future_time *= 2 self.send_datagram(message) if message.acknowledged or message.rejected: message.timeouted = False else: logger.warning("Give up on message {message}".format(message=message.line_print)) message.timeouted = True if message.observe is not None: self._observeLayer.remove_subscriber(message) try: self.to_be_stopped.remove(transaction.retransmit_stop) except ValueError: pass transaction.retransmit_stop = None transaction.retransmit_thread = None def _start_separate_timer(self, transaction): """ Start a thread to handle separate mode. :type transaction: Transaction :param transaction: the transaction that is in processing :rtype : the Timer object """ t = threading.Timer(defines.ACK_TIMEOUT, self._send_ack, (transaction,)) t.start() return t @staticmethod def _stop_separate_timer(timer): """ Stop the separate Thread if an answer has been already provided to the client. :param timer: The Timer object """ timer.cancel() def _send_ack(self, transaction): """ Sends an ACK message for the request. :param transaction: the transaction that owns the request """ ack = Message() ack.type = defines.Types['ACK'] if not transaction.request.acknowledged: ack = self._messageLayer.send_empty(transaction, transaction.request, ack) self.send_datagram(ack)