# Copyright (c) 2012-2019 Roger Light and others # # All rights reserved. This program and the accompanying materials # are made available under the terms of the Eclipse Public License v1.0 # and Eclipse Distribution License v1.0 which accompany this distribution. # # The Eclipse Public License is available at # http://www.eclipse.org/legal/epl-v10.html # and the Eclipse Distribution License is available at # http://www.eclipse.org/org/documents/edl-v10.php. # # Contributors: # Roger Light - initial API and implementation # Ian Craggs - MQTT V5 support from .subscribeoptions import SubscribeOptions from .reasoncodes import ReasonCodes from .properties import Properties from .matcher import MQTTMatcher import logging import hashlib import string import base64 import uuid import time import threading import sys import struct """ This is an MQTT client module. MQTT is a lightweight pub/sub messaging protocol that is easy to implement and suitable for low powered devices. """ import collections import errno import os import platform import select import socket ssl = None try: import ssl except ImportError: pass socks = None try: import socks except ImportError: pass try: # Python 3 from urllib import request as urllib_dot_request from urllib import parse as urllib_dot_parse except ImportError: # Python 2 import urllib as urllib_dot_request import urlparse as urllib_dot_parse try: # Use monotonic clock if available time_func = time.monotonic except AttributeError: time_func = time.time try: import dns.resolver except ImportError: HAVE_DNS = False else: HAVE_DNS = True if platform.system() == 'Windows': EAGAIN = errno.WSAEWOULDBLOCK else: EAGAIN = errno.EAGAIN MQTTv31 = 3 MQTTv311 = 4 MQTTv5 = 5 if sys.version_info[0] >= 3: # define some alias for python2 compatibility unicode = str basestring = str # Message types CONNECT = 0x10 CONNACK = 0x20 PUBLISH = 0x30 PUBACK = 0x40 PUBREC = 0x50 PUBREL = 0x60 PUBCOMP = 0x70 SUBSCRIBE = 0x80 SUBACK = 0x90 UNSUBSCRIBE = 0xA0 UNSUBACK = 0xB0 PINGREQ = 0xC0 PINGRESP = 0xD0 DISCONNECT = 0xE0 AUTH = 0xF0 # Log levels MQTT_LOG_INFO = 0x01 MQTT_LOG_NOTICE = 0x02 MQTT_LOG_WARNING = 0x04 MQTT_LOG_ERR = 0x08 MQTT_LOG_DEBUG = 0x10 LOGGING_LEVEL = { MQTT_LOG_DEBUG: logging.DEBUG, MQTT_LOG_INFO: logging.INFO, MQTT_LOG_NOTICE: logging.INFO, # This has no direct equivalent level MQTT_LOG_WARNING: logging.WARNING, MQTT_LOG_ERR: logging.ERROR, } # CONNACK codes CONNACK_ACCEPTED = 0 CONNACK_REFUSED_PROTOCOL_VERSION = 1 CONNACK_REFUSED_IDENTIFIER_REJECTED = 2 CONNACK_REFUSED_SERVER_UNAVAILABLE = 3 CONNACK_REFUSED_BAD_USERNAME_PASSWORD = 4 CONNACK_REFUSED_NOT_AUTHORIZED = 5 # Connection state mqtt_cs_new = 0 mqtt_cs_connected = 1 mqtt_cs_disconnecting = 2 mqtt_cs_connect_async = 3 # Message state mqtt_ms_invalid = 0 mqtt_ms_publish = 1 mqtt_ms_wait_for_puback = 2 mqtt_ms_wait_for_pubrec = 3 mqtt_ms_resend_pubrel = 4 mqtt_ms_wait_for_pubrel = 5 mqtt_ms_resend_pubcomp = 6 mqtt_ms_wait_for_pubcomp = 7 mqtt_ms_send_pubrec = 8 mqtt_ms_queued = 9 # Error values MQTT_ERR_AGAIN = -1 MQTT_ERR_SUCCESS = 0 MQTT_ERR_NOMEM = 1 MQTT_ERR_PROTOCOL = 2 MQTT_ERR_INVAL = 3 MQTT_ERR_NO_CONN = 4 MQTT_ERR_CONN_REFUSED = 5 MQTT_ERR_NOT_FOUND = 6 MQTT_ERR_CONN_LOST = 7 MQTT_ERR_TLS = 8 MQTT_ERR_PAYLOAD_SIZE = 9 MQTT_ERR_NOT_SUPPORTED = 10 MQTT_ERR_AUTH = 11 MQTT_ERR_ACL_DENIED = 12 MQTT_ERR_UNKNOWN = 13 MQTT_ERR_ERRNO = 14 MQTT_ERR_QUEUE_SIZE = 15 MQTT_CLIENT = 0 MQTT_BRIDGE = 1 # For MQTT V5, use the clean start flag only on the first successful connect MQTT_CLEAN_START_FIRST_ONLY = 3 sockpair_data = b"0" class WebsocketConnectionError(ValueError): pass class WouldBlockError(Exception): pass def error_string(mqtt_errno): """Return the error string associated with an mqtt error number.""" if mqtt_errno == MQTT_ERR_SUCCESS: return "No error." elif mqtt_errno == MQTT_ERR_NOMEM: return "Out of memory." elif mqtt_errno == MQTT_ERR_PROTOCOL: return "A network protocol error occurred when communicating with the broker." elif mqtt_errno == MQTT_ERR_INVAL: return "Invalid function arguments provided." elif mqtt_errno == MQTT_ERR_NO_CONN: return "The client is not currently connected." elif mqtt_errno == MQTT_ERR_CONN_REFUSED: return "The connection was refused." elif mqtt_errno == MQTT_ERR_NOT_FOUND: return "Message not found (internal error)." elif mqtt_errno == MQTT_ERR_CONN_LOST: return "The connection was lost." elif mqtt_errno == MQTT_ERR_TLS: return "A TLS error occurred." elif mqtt_errno == MQTT_ERR_PAYLOAD_SIZE: return "Payload too large." elif mqtt_errno == MQTT_ERR_NOT_SUPPORTED: return "This feature is not supported." elif mqtt_errno == MQTT_ERR_AUTH: return "Authorisation failed." elif mqtt_errno == MQTT_ERR_ACL_DENIED: return "Access denied by ACL." elif mqtt_errno == MQTT_ERR_UNKNOWN: return "Unknown error." elif mqtt_errno == MQTT_ERR_ERRNO: return "Error defined by errno." elif mqtt_errno == MQTT_ERR_QUEUE_SIZE: return "Message queue full." else: return "Unknown error." def connack_string(connack_code): """Return the string associated with a CONNACK result.""" if connack_code == CONNACK_ACCEPTED: return "Connection Accepted." elif connack_code == CONNACK_REFUSED_PROTOCOL_VERSION: return "Connection Refused: unacceptable protocol version." elif connack_code == CONNACK_REFUSED_IDENTIFIER_REJECTED: return "Connection Refused: identifier rejected." elif connack_code == CONNACK_REFUSED_SERVER_UNAVAILABLE: return "Connection Refused: broker unavailable." elif connack_code == CONNACK_REFUSED_BAD_USERNAME_PASSWORD: return "Connection Refused: bad user name or password." elif connack_code == CONNACK_REFUSED_NOT_AUTHORIZED: return "Connection Refused: not authorised." else: return "Connection Refused: unknown reason." def base62(num, base=string.digits + string.ascii_letters, padding=1): """Convert a number to base-62 representation.""" assert num >= 0 digits = [] while num: num, rest = divmod(num, 62) digits.append(base[rest]) digits.extend(base[0] for _ in range(len(digits), padding)) return ''.join(reversed(digits)) def topic_matches_sub(sub, topic): """Check whether a topic matches a subscription. For example: foo/bar would match the subscription foo/# or +/bar non/matching would not match the subscription non/+/+ """ matcher = MQTTMatcher() matcher[sub] = True try: next(matcher.iter_match(topic)) return True except StopIteration: return False def _socketpair_compat(): """TCP/IP socketpair including Windows support""" listensock = socket.socket( socket.AF_INET, socket.SOCK_STREAM, socket.IPPROTO_IP) listensock.setsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR, 1) listensock.bind(("127.0.0.1", 0)) listensock.listen(1) iface, port = listensock.getsockname() sock1 = socket.socket( socket.AF_INET, socket.SOCK_STREAM, socket.IPPROTO_IP) sock1.setblocking(0) try: sock1.connect(("127.0.0.1", port)) except socket.error as err: if err.errno != errno.EINPROGRESS and err.errno != errno.EWOULDBLOCK and err.errno != EAGAIN: raise sock2, address = listensock.accept() sock2.setblocking(0) listensock.close() return (sock1, sock2) class MQTTMessageInfo(object): """This is a class returned from Client.publish() and can be used to find out the mid of the message that was published, and to determine whether the message has been published, and/or wait until it is published. """ __slots__ = 'mid', '_published', '_condition', 'rc', '_iterpos' def __init__(self, mid): self.mid = mid self._published = False self._condition = threading.Condition() self.rc = 0 self._iterpos = 0 def __str__(self): return str((self.rc, self.mid)) def __iter__(self): self._iterpos = 0 return self def __next__(self): return self.next() def next(self): if self._iterpos == 0: self._iterpos = 1 return self.rc elif self._iterpos == 1: self._iterpos = 2 return self.mid else: raise StopIteration def __getitem__(self, index): if index == 0: return self.rc elif index == 1: return self.mid else: raise IndexError("index out of range") def _set_as_published(self): with self._condition: self._published = True self._condition.notify() def wait_for_publish(self): """Block until the message associated with this object is published.""" if self.rc == MQTT_ERR_QUEUE_SIZE: raise ValueError('Message is not queued due to ERR_QUEUE_SIZE') with self._condition: while not self._published: self._condition.wait() def is_published(self): """Returns True if the message associated with this object has been published, else returns False.""" if self.rc == MQTT_ERR_QUEUE_SIZE: raise ValueError('Message is not queued due to ERR_QUEUE_SIZE') with self._condition: return self._published class MQTTMessage(object): """ This is a class that describes an incoming or outgoing message. It is passed to the on_message callback as the message parameter. Members: topic : String/bytes. topic that the message was published on. payload : String/bytes the message payload. qos : Integer. The message Quality of Service 0, 1 or 2. retain : Boolean. If true, the message is a retained message and not fresh. mid : Integer. The message id. properties: Properties class. In MQTT v5.0, the properties associated with the message. On Python 3, topic must be bytes. """ __slots__ = 'timestamp', 'state', 'dup', 'mid', '_topic', 'payload', 'qos', 'retain', 'info', 'properties' def __init__(self, mid=0, topic=b""): self.timestamp = 0 self.state = mqtt_ms_invalid self.dup = False self.mid = mid self._topic = topic self.payload = b"" self.qos = 0 self.retain = False self.info = MQTTMessageInfo(mid) def __eq__(self, other): """Override the default Equals behavior""" if isinstance(other, self.__class__): return self.mid == other.mid return False def __ne__(self, other): """Define a non-equality test""" return not self.__eq__(other) @property def topic(self): return self._topic.decode('utf-8') @topic.setter def topic(self, value): self._topic = value class Client(object): """MQTT version 3.1/3.1.1/5.0 client class. This is the main class for use communicating with an MQTT broker. General usage flow: * Use connect()/connect_async() to connect to a broker * Call loop() frequently to maintain network traffic flow with the broker * Or use loop_start() to set a thread running to call loop() for you. * Or use loop_forever() to handle calling loop() for you in a blocking * function. * Use subscribe() to subscribe to a topic and receive messages * Use publish() to send messages * Use disconnect() to disconnect from the broker Data returned from the broker is made available with the use of callback functions as described below. Callbacks ========= A number of callback functions are available to receive data back from the broker. To use a callback, define a function and then assign it to the client: def on_connect(client, userdata, flags, rc, properties=None): print("Connection returned " + str(rc)) client.on_connect = on_connect All of the callbacks as described below have a "client" and an "userdata" argument. "client" is the Client instance that is calling the callback. "userdata" is user data of any type and can be set when creating a new client instance or with user_data_set(userdata). If you wish to suppress exceptions within a callback, you should set `client.suppress_exceptions = True` The callbacks: on_connect(client, userdata, flags, rc, properties=None): called when the broker responds to our connection request. flags is a dict that contains response flags from the broker: flags['session present'] - this flag is useful for clients that are using clean session set to 0 only. If a client with clean session=0, that reconnects to a broker that it has previously connected to, this flag indicates whether the broker still has the session information for the client. If 1, the session still exists. The value of rc determines success or not: 0: Connection successful 1: Connection refused - incorrect protocol version 2: Connection refused - invalid client identifier 3: Connection refused - server unavailable 4: Connection refused - bad username or password 5: Connection refused - not authorised 6-255: Currently unused. on_disconnect(client, userdata, rc): called when the client disconnects from the broker. The rc parameter indicates the disconnection state. If MQTT_ERR_SUCCESS (0), the callback was called in response to a disconnect() call. If any other value the disconnection was unexpected, such as might be caused by a network error. on_disconnect(client, userdata, rc, properties): called when the MQTT V5 client disconnects from the broker. When using MQTT V5, the broker can send a disconnect message to the client. The message can contain a reason code and MQTT V5 properties. The properties parameter could be None if they do not exist in the disconnect message. on_message(client, userdata, message): called when a message has been received on a topic that the client subscribes to. The message variable is a MQTTMessage that describes all of the message parameters. on_publish(client, userdata, mid): called when a message that was to be sent using the publish() call has completed transmission to the broker. For messages with QoS levels 1 and 2, this means that the appropriate handshakes have completed. For QoS 0, this simply means that the message has left the client. The mid variable matches the mid variable returned from the corresponding publish() call, to allow outgoing messages to be tracked. This callback is important because even if the publish() call returns success, it does not always mean that the message has been sent. on_subscribe(client, userdata, mid, granted_qos, properties=None): called when the broker responds to a subscribe request. The mid variable matches the mid variable returned from the corresponding subscribe() call. The granted_qos variable is a list of integers that give the QoS level the broker has granted for each of the different subscription requests. on_unsubscribe(client, userdata, mid): called when the broker responds to an unsubscribe request. The mid variable matches the mid variable returned from the corresponding unsubscribe() call. on_log(client, userdata, level, buf): called when the client has log information. Define to allow debugging. The level variable gives the severity of the message and will be one of MQTT_LOG_INFO, MQTT_LOG_NOTICE, MQTT_LOG_WARNING, MQTT_LOG_ERR, and MQTT_LOG_DEBUG. The message itself is in buf. on_socket_open(client, userdata, sock): Called when the socket has been opened. Use this to register the socket with an external event loop for reading. on_socket_close(client, userdata, sock): Called when the socket is about to be closed. Use this to unregister a socket from an external event loop for reading. on_socket_register_write(client, userdata, sock): Called when a write operation to the socket failed because it would have blocked, e.g. output buffer full. Use this to register the socket with an external event loop for writing. on_socket_unregister_write(client, userdata, sock): Called when a write operation to the socket succeeded after it had previously failed. Use this to unregister the socket from an external event loop for writing. """ def __init__(self, client_id="", clean_session=None, userdata=None, protocol=MQTTv311, transport="tcp"): """client_id is the unique client id string used when connecting to the broker. If client_id is zero length or None, then the behaviour is defined by which protocol version is in use. If using MQTT v3.1.1, then a zero length client id will be sent to the broker and the broker will generate a random for the client. If using MQTT v3.1 then an id will be randomly generated. In both cases, clean_session must be True. If this is not the case a ValueError will be raised. clean_session is a boolean that determines the client type. If True, the broker will remove all information about this client when it disconnects. If False, the client is a persistent client and subscription information and queued messages will be retained when the client disconnects. Note that a client will never discard its own outgoing messages on disconnect. Calling connect() or reconnect() will cause the messages to be resent. Use reinitialise() to reset a client to its original state. The clean_session argument only applies to MQTT versions v3.1.1 and v3.1. It is not accepted if the MQTT version is v5.0 - use the clean_start argument on connect() instead. userdata is user defined data of any type that is passed as the "userdata" parameter to callbacks. It may be updated at a later point with the user_data_set() function. The protocol argument allows explicit setting of the MQTT version to use for this client. Can be paho.mqtt.client.MQTTv311 (v3.1.1), paho.mqtt.client.MQTTv31 (v3.1) or paho.mqtt.client.MQTTv5 (v5.0), with the default being v3.1.1. Set transport to "websockets" to use WebSockets as the transport mechanism. Set to "tcp" to use raw TCP, which is the default. """ if protocol == MQTTv5: if clean_session != None: raise ValueError('Clean session is not used for MQTT 5.0') else: if clean_session == None: clean_session = True if not clean_session and (client_id == "" or client_id is None): raise ValueError( 'A client id must be provided if clean session is False.') self._clean_session = clean_session if transport.lower() not in ('websockets', 'tcp'): raise ValueError( 'transport must be "websockets" or "tcp", not %s' % transport) self._transport = transport.lower() self._protocol = protocol self._userdata = userdata self._sock = None self._sockpairR, self._sockpairW = (None, None,) self._sockpairR, self._sockpairW = _socketpair_compat() self._keepalive = 60 self._message_retry = 20 self._last_retry_check = 0 self._client_mode = MQTT_CLIENT # [MQTT-3.1.3-4] Client Id must be UTF-8 encoded string. if client_id == "" or client_id is None: if protocol == MQTTv31: self._client_id = base62(uuid.uuid4().int, padding=22) else: self._client_id = b"" else: self._client_id = client_id if isinstance(self._client_id, unicode): self._client_id = self._client_id.encode('utf-8') self._username = None self._password = None self._in_packet = { "command": 0, "have_remaining": 0, "remaining_count": [], "remaining_mult": 1, "remaining_length": 0, "packet": b"", "to_process": 0, "pos": 0} self._out_packet = collections.deque() self._current_out_packet = None self._last_msg_in = time_func() self._last_msg_out = time_func() self._reconnect_min_delay = 1 self._reconnect_max_delay = 120 self._reconnect_delay = None self._ping_t = 0 self._last_mid = 0 self._state = mqtt_cs_new self._out_messages = collections.OrderedDict() self._in_messages = collections.OrderedDict() self._max_inflight_messages = 20 self._inflight_messages = 0 self._max_queued_messages = 0 self._connect_properties = None self._will_properties = None self._will = False self._will_topic = b"" self._will_payload = b"" self._will_qos = 0 self._will_retain = False self._on_message_filtered = MQTTMatcher() self._host = "" self._port = 1883 self._bind_address = "" self._bind_port = 0 self._proxy = {} self._in_callback_mutex = threading.Lock() self._callback_mutex = threading.RLock() self._out_packet_mutex = threading.Lock() self._current_out_packet_mutex = threading.RLock() self._msgtime_mutex = threading.Lock() self._out_message_mutex = threading.RLock() self._in_message_mutex = threading.Lock() self._reconnect_delay_mutex = threading.Lock() self._mid_generate_mutex = threading.Lock() self._thread = None self._thread_terminate = False self._ssl = False self._ssl_context = None # Only used when SSL context does not have check_hostname attribute self._tls_insecure = False self._logger = None self._registered_write = False # No default callbacks self._on_log = None self._on_connect = None self._on_subscribe = None self._on_message = None self._on_publish = None self._on_unsubscribe = None self._on_disconnect = None self._on_socket_open = None self._on_socket_close = None self._on_socket_register_write = None self._on_socket_unregister_write = None self._websocket_path = "/mqtt" self._websocket_extra_headers = None # for clean_start == MQTT_CLEAN_START_FIRST_ONLY self._mqttv5_first_connect = True self.suppress_exceptions = False # For callbacks def __del__(self): self._reset_sockets() def _sock_recv(self, bufsize): try: return self._sock.recv(bufsize) except socket.error as err: if self._ssl and err.errno == ssl.SSL_ERROR_WANT_READ: raise WouldBlockError() if self._ssl and err.errno == ssl.SSL_ERROR_WANT_WRITE: self._call_socket_register_write() raise WouldBlockError() if err.errno == EAGAIN: raise WouldBlockError() raise def _sock_send(self, buf): try: return self._sock.send(buf) except socket.error as err: if self._ssl and err.errno == ssl.SSL_ERROR_WANT_READ: raise WouldBlockError() if self._ssl and err.errno == ssl.SSL_ERROR_WANT_WRITE: self._call_socket_register_write() raise WouldBlockError() if err.errno == EAGAIN: self._call_socket_register_write() raise WouldBlockError() raise def _sock_close(self): """Close the connection to the server.""" if not self._sock: return try: sock = self._sock self._sock = None self._call_socket_unregister_write(sock) self._call_socket_close(sock) finally: # In case a callback fails, still close the socket to avoid leaking the file descriptor. sock.close() def _reset_sockets(self): self._sock_close() if self._sockpairR: self._sockpairR.close() self._sockpairR = None if self._sockpairW: self._sockpairW.close() self._sockpairW = None def reinitialise(self, client_id="", clean_session=True, userdata=None): self._reset_sockets() self.__init__(client_id, clean_session, userdata) def ws_set_options(self, path="/mqtt", headers=None): """ Set the path and headers for a websocket connection path is a string starting with / which should be the endpoint of the mqtt connection on the remote server headers can be either a dict or a callable object. If it is a dict then the extra items in the dict are added to the websocket headers. If it is a callable, then the default websocket headers are passed into this function and the result is used as the new headers. """ self._websocket_path = path if headers is not None: if isinstance(headers, dict) or callable(headers): self._websocket_extra_headers = headers else: raise ValueError( "'headers' option to ws_set_options has to be either a dictionary or callable") def tls_set_context(self, context=None): """Configure network encryption and authentication context. Enables SSL/TLS support. context : an ssl.SSLContext object. By default this is given by `ssl.create_default_context()`, if available. Must be called before connect() or connect_async().""" if self._ssl_context is not None: raise ValueError('SSL/TLS has already been configured.') # Assume that have SSL support, or at least that context input behaves like ssl.SSLContext # in current versions of Python if context is None: if hasattr(ssl, 'create_default_context'): context = ssl.create_default_context() else: raise ValueError('SSL/TLS context must be specified') self._ssl = True self._ssl_context = context # Ensure _tls_insecure is consistent with check_hostname attribute if hasattr(context, 'check_hostname'): self._tls_insecure = not context.check_hostname def tls_set(self, ca_certs=None, certfile=None, keyfile=None, cert_reqs=None, tls_version=None, ciphers=None): """Configure network encryption and authentication options. Enables SSL/TLS support. ca_certs : a string path to the Certificate Authority certificate files that are to be treated as trusted by this client. If this is the only option given then the client will operate in a similar manner to a web browser. That is to say it will require the broker to have a certificate signed by the Certificate Authorities in ca_certs and will communicate using TLS v1, but will not attempt any form of authentication. This provides basic network encryption but may not be sufficient depending on how the broker is configured. By default, on Python 2.7.9+ or 3.4+, the default certification authority of the system is used. On older Python version this parameter is mandatory. certfile and keyfile are strings pointing to the PEM encoded client certificate and private keys respectively. If these arguments are not None then they will be used as client information for TLS based authentication. Support for this feature is broker dependent. Note that if either of these files in encrypted and needs a password to decrypt it, Python will ask for the password at the command line. It is not currently possible to define a callback to provide the password. cert_reqs allows the certificate requirements that the client imposes on the broker to be changed. By default this is ssl.CERT_REQUIRED, which means that the broker must provide a certificate. See the ssl pydoc for more information on this parameter. tls_version allows the version of the SSL/TLS protocol used to be specified. By default TLS v1 is used. Previous versions (all versions beginning with SSL) are possible but not recommended due to possible security problems. ciphers is a string specifying which encryption ciphers are allowable for this connection, or None to use the defaults. See the ssl pydoc for more information. Must be called before connect() or connect_async().""" if ssl is None: raise ValueError('This platform has no SSL/TLS.') if not hasattr(ssl, 'SSLContext'): # Require Python version that has SSL context support in standard library raise ValueError( 'Python 2.7.9 and 3.2 are the minimum supported versions for TLS.') if ca_certs is None and not hasattr(ssl.SSLContext, 'load_default_certs'): raise ValueError('ca_certs must not be None.') # Create SSLContext object if tls_version is None: tls_version = ssl.PROTOCOL_TLSv1 # If the python version supports it, use highest TLS version automatically if hasattr(ssl, "PROTOCOL_TLS"): tls_version = ssl.PROTOCOL_TLS context = ssl.SSLContext(tls_version) # Configure context if certfile is not None: context.load_cert_chain(certfile, keyfile) if cert_reqs == ssl.CERT_NONE and hasattr(context, 'check_hostname'): context.check_hostname = False context.verify_mode = ssl.CERT_REQUIRED if cert_reqs is None else cert_reqs if ca_certs is not None: context.load_verify_locations(ca_certs) else: context.load_default_certs() if ciphers is not None: context.set_ciphers(ciphers) self.tls_set_context(context) if cert_reqs != ssl.CERT_NONE: # Default to secure, sets context.check_hostname attribute # if available self.tls_insecure_set(False) else: # But with ssl.CERT_NONE, we can not check_hostname self.tls_insecure_set(True) def tls_insecure_set(self, value): """Configure verification of the server hostname in the server certificate. If value is set to true, it is impossible to guarantee that the host you are connecting to is not impersonating your server. This can be useful in initial server testing, but makes it possible for a malicious third party to impersonate your server through DNS spoofing, for example. Do not use this function in a real system. Setting value to true means there is no point using encryption. Must be called before connect() and after either tls_set() or tls_set_context().""" if self._ssl_context is None: raise ValueError( 'Must configure SSL context before using tls_insecure_set.') self._tls_insecure = value # Ensure check_hostname is consistent with _tls_insecure attribute if hasattr(self._ssl_context, 'check_hostname'): # Rely on SSLContext to check host name # If verify_mode is CERT_NONE then the host name will never be checked self._ssl_context.check_hostname = not value def proxy_set(self, **proxy_args): """Configure proxying of MQTT connection. Enables support for SOCKS or HTTP proxies. Proxying is done through the PySocks library. Brief descriptions of the proxy_args parameters are below; see the PySocks docs for more info. (Required) proxy_type: One of {socks.HTTP, socks.SOCKS4, or socks.SOCKS5} proxy_addr: IP address or DNS name of proxy server (Optional) proxy_rdns: boolean indicating whether proxy lookup should be performed remotely (True, default) or locally (False) proxy_username: username for SOCKS5 proxy, or userid for SOCKS4 proxy proxy_password: password for SOCKS5 proxy Must be called before connect() or connect_async().""" if socks is None: raise ValueError("PySocks must be installed for proxy support.") elif not self._proxy_is_valid(proxy_args): raise ValueError("proxy_type and/or proxy_addr are invalid.") else: self._proxy = proxy_args def enable_logger(self, logger=None): """ Enables a logger to send log messages to """ if logger is None: if self._logger is not None: # Do not replace existing logger return logger = logging.getLogger(__name__) self._logger = logger def disable_logger(self): self._logger = None def connect(self, host, port=1883, keepalive=60, bind_address="", bind_port=0, clean_start=MQTT_CLEAN_START_FIRST_ONLY, properties=None): """Connect to a remote broker. host is the hostname or IP address of the remote broker. port is the network port of the server host to connect to. Defaults to 1883. Note that the default port for MQTT over SSL/TLS is 8883 so if you are using tls_set() the port may need providing. keepalive: Maximum period in seconds between communications with the broker. If no other messages are being exchanged, this controls the rate at which the client will send ping messages to the broker. clean_start: (MQTT v5.0 only) True, False or MQTT_CLEAN_START_FIRST_ONLY. Sets the MQTT v5.0 clean_start flag always, never or on the first successful connect only, respectively. MQTT session data (such as outstanding messages and subscriptions) is cleared on successful connect when the clean_start flag is set. properties: (MQTT v5.0 only) the MQTT v5.0 properties to be sent in the MQTT connect packet. """ if self._protocol == MQTTv5: self._mqttv5_first_connect = True else: if clean_start != MQTT_CLEAN_START_FIRST_ONLY: raise ValueError("Clean start only applies to MQTT V5") if properties != None: raise ValueError("Properties only apply to MQTT V5") self.connect_async(host, port, keepalive, bind_address, bind_port, clean_start, properties) return self.reconnect() def connect_srv(self, domain=None, keepalive=60, bind_address="", clean_start=MQTT_CLEAN_START_FIRST_ONLY, properties=None): """Connect to a remote broker. domain is the DNS domain to search for SRV records; if None, try to determine local domain name. keepalive, bind_address, clean_start and properties are as for connect() """ if HAVE_DNS is False: raise ValueError( 'No DNS resolver library found, try "pip install dnspython" or "pip3 install dnspython3".') if domain is None: domain = socket.getfqdn() domain = domain[domain.find('.') + 1:] try: rr = '_mqtt._tcp.%s' % domain if self._ssl: # IANA specifies secure-mqtt (not mqtts) for port 8883 rr = '_secure-mqtt._tcp.%s' % domain answers = [] for answer in dns.resolver.query(rr, dns.rdatatype.SRV): addr = answer.target.to_text()[:-1] answers.append( (addr, answer.port, answer.priority, answer.weight)) except (dns.resolver.NXDOMAIN, dns.resolver.NoAnswer, dns.resolver.NoNameservers): raise ValueError("No answer/NXDOMAIN for SRV in %s" % (domain)) # FIXME: doesn't account for weight for answer in answers: host, port, prio, weight = answer try: return self.connect(host, port, keepalive, bind_address, clean_start, properties) except Exception: pass raise ValueError("No SRV hosts responded") def connect_async(self, host, port=1883, keepalive=60, bind_address="", bind_port=0, clean_start=MQTT_CLEAN_START_FIRST_ONLY, properties=None): """Connect to a remote broker asynchronously. This is a non-blocking connect call that can be used with loop_start() to provide very quick start. host is the hostname or IP address of the remote broker. port is the network port of the server host to connect to. Defaults to 1883. Note that the default port for MQTT over SSL/TLS is 8883 so if you are using tls_set() the port may need providing. keepalive: Maximum period in seconds between communications with the broker. If no other messages are being exchanged, this controls the rate at which the client will send ping messages to the broker. clean_start: (MQTT v5.0 only) True, False or MQTT_CLEAN_START_FIRST_ONLY. Sets the MQTT v5.0 clean_start flag always, never or on the first successful connect only, respectively. MQTT session data (such as outstanding messages and subscriptions) is cleared on successful connect when the clean_start flag is set. properties: (MQTT v5.0 only) the MQTT v5.0 properties to be sent in the MQTT connect packet. Use the Properties class. """ if host is None or len(host) == 0: raise ValueError('Invalid host.') if port <= 0: raise ValueError('Invalid port number.') if keepalive < 0: raise ValueError('Keepalive must be >=0.') if bind_address != "" and bind_address is not None: if sys.version_info < (2, 7) or (3, 0) < sys.version_info < (3, 2): raise ValueError('bind_address requires Python 2.7 or 3.2.') if bind_port < 0: raise ValueError('Invalid bind port number.') self._host = host self._port = port self._keepalive = keepalive self._bind_address = bind_address self._bind_port = bind_port self._clean_start = clean_start self._connect_properties = properties self._state = mqtt_cs_connect_async def reconnect_delay_set(self, min_delay=1, max_delay=120): """ Configure the exponential reconnect delay When connection is lost, wait initially min_delay seconds and double this time every attempt. The wait is capped at max_delay. Once the client is fully connected (e.g. not only TCP socket, but received a success CONNACK), the wait timer is reset to min_delay. """ with self._reconnect_delay_mutex: self._reconnect_min_delay = min_delay self._reconnect_max_delay = max_delay self._reconnect_delay = None def reconnect(self): """Reconnect the client after a disconnect. Can only be called after connect()/connect_async().""" if len(self._host) == 0: raise ValueError('Invalid host.') if self._port <= 0: raise ValueError('Invalid port number.') self._in_packet = { "command": 0, "have_remaining": 0, "remaining_count": [], "remaining_mult": 1, "remaining_length": 0, "packet": b"", "to_process": 0, "pos": 0} with self._out_packet_mutex: self._out_packet = collections.deque() with self._current_out_packet_mutex: self._current_out_packet = None with self._msgtime_mutex: self._last_msg_in = time_func() self._last_msg_out = time_func() self._ping_t = 0 self._state = mqtt_cs_new self._sock_close() # Put messages in progress in a valid state. self._messages_reconnect_reset() sock = self._create_socket_connection() if self._ssl: # SSL is only supported when SSLContext is available (implies Python >= 2.7.9 or >= 3.2) verify_host = not self._tls_insecure try: # Try with server_hostname, even it's not supported in certain scenarios sock = self._ssl_context.wrap_socket( sock, server_hostname=self._host, do_handshake_on_connect=False, ) except ssl.CertificateError: # CertificateError is derived from ValueError raise except ValueError: # Python version requires SNI in order to handle server_hostname, but SNI is not available sock = self._ssl_context.wrap_socket( sock, do_handshake_on_connect=False, ) else: # If SSL context has already checked hostname, then don't need to do it again if (hasattr(self._ssl_context, 'check_hostname') and self._ssl_context.check_hostname): verify_host = False sock.settimeout(self._keepalive) sock.do_handshake() if verify_host: ssl.match_hostname(sock.getpeercert(), self._host) if self._transport == "websockets": sock.settimeout(self._keepalive) sock = WebsocketWrapper(sock, self._host, self._port, self._ssl, self._websocket_path, self._websocket_extra_headers) self._sock = sock self._sock.setblocking(0) self._registered_write = False self._call_socket_open() return self._send_connect(self._keepalive) def loop(self, timeout=1.0, max_packets=1): """Process network events. This function must be called regularly to ensure communication with the broker is carried out. It calls select() on the network socket to wait for network events. If incoming data is present it will then be processed. Outgoing commands, from e.g. publish(), are normally sent immediately that their function is called, but this is not always possible. loop() will also attempt to send any remaining outgoing messages, which also includes commands that are part of the flow for messages with QoS>0. timeout: The time in seconds to wait for incoming/outgoing network traffic before timing out and returning. max_packets: Not currently used. Returns MQTT_ERR_SUCCESS on success. Returns >0 on error. A ValueError will be raised if timeout < 0""" if timeout < 0.0: raise ValueError('Invalid timeout.') with self._current_out_packet_mutex: with self._out_packet_mutex: if self._current_out_packet is None and len(self._out_packet) > 0: self._current_out_packet = self._out_packet.popleft() if self._current_out_packet: wlist = [self._sock] else: wlist = [] # used to check if there are any bytes left in the (SSL) socket pending_bytes = 0 if hasattr(self._sock, 'pending'): pending_bytes = self._sock.pending() # if bytes are pending do not wait in select if pending_bytes > 0: timeout = 0.0 # sockpairR is used to break out of select() before the timeout, on a # call to publish() etc. rlist = [self._sock, self._sockpairR] try: socklist = select.select(rlist, wlist, [], timeout) except TypeError: # Socket isn't correct type, in likelihood connection is lost return MQTT_ERR_CONN_LOST except ValueError: # Can occur if we just reconnected but rlist/wlist contain a -1 for # some reason. return MQTT_ERR_CONN_LOST except Exception: # Note that KeyboardInterrupt, etc. can still terminate since they # are not derived from Exception return MQTT_ERR_UNKNOWN if self._sock in socklist[0] or pending_bytes > 0: rc = self.loop_read(max_packets) if rc or self._sock is None: return rc if self._sockpairR in socklist[0]: # Stimulate output write even though we didn't ask for it, because # at that point the publish or other command wasn't present. socklist[1].insert(0, self._sock) # Clear sockpairR - only ever a single byte written. try: self._sockpairR.recv(1) except socket.error as err: if err.errno != EAGAIN: raise if self._sock in socklist[1]: rc = self.loop_write(max_packets) if rc or self._sock is None: return rc return self.loop_misc() def publish(self, topic, payload=None, qos=0, retain=False, properties=None): """Publish a message on a topic. This causes a message to be sent to the broker and subsequently from the broker to any clients subscribing to matching topics. topic: The topic that the message should be published on. payload: The actual message to send. If not given, or set to None a zero length message will be used. Passing an int or float will result in the payload being converted to a string representing that number. If you wish to send a true int/float, use struct.pack() to create the payload you require. qos: The quality of service level to use. retain: If set to true, the message will be set as the "last known good"/retained message for the topic. properties: (MQTT v5.0 only) the MQTT v5.0 properties to be included. Use the Properties class. Returns a MQTTMessageInfo class, which can be used to determine whether the message has been delivered (using info.is_published()) or to block waiting for the message to be delivered (info.wait_for_publish()). The message ID and return code of the publish() call can be found at info.mid and info.rc. For backwards compatibility, the MQTTMessageInfo class is iterable so the old construct of (rc, mid) = client.publish(...) is still valid. rc is MQTT_ERR_SUCCESS to indicate success or MQTT_ERR_NO_CONN if the client is not currently connected. mid is the message ID for the publish request. The mid value can be used to track the publish request by checking against the mid argument in the on_publish() callback if it is defined. A ValueError will be raised if topic is None, has zero length or is invalid (contains a wildcard), except if the MQTT version used is v5.0. For v5.0, a zero length topic can be used when a Topic Alias has been set. A ValueError will be raised if qos is not one of 0, 1 or 2, or if the length of the payload is greater than 268435455 bytes.""" if self._protocol != MQTTv5: if topic is None or len(topic) == 0: raise ValueError('Invalid topic.') topic = topic.encode('utf-8') if self._topic_wildcard_len_check(topic) != MQTT_ERR_SUCCESS: raise ValueError('Publish topic cannot contain wildcards.') if qos < 0 or qos > 2: raise ValueError('Invalid QoS level.') if isinstance(payload, unicode): local_payload = payload.encode('utf-8') elif isinstance(payload, (bytes, bytearray)): local_payload = payload elif isinstance(payload, (int, float)): local_payload = str(payload).encode('ascii') elif payload is None: local_payload = b'' else: raise TypeError( 'payload must be a string, bytearray, int, float or None.') if len(local_payload) > 268435455: raise ValueError('Payload too large.') local_mid = self._mid_generate() if qos == 0: info = MQTTMessageInfo(local_mid) rc = self._send_publish( local_mid, topic, local_payload, qos, retain, False, info, properties) info.rc = rc return info else: message = MQTTMessage(local_mid, topic) message.timestamp = time_func() message.payload = local_payload message.qos = qos message.retain = retain message.dup = False message.properties = properties with self._out_message_mutex: if self._max_queued_messages > 0 and len(self._out_messages) >= self._max_queued_messages: message.info.rc = MQTT_ERR_QUEUE_SIZE return message.info if local_mid in self._out_messages: message.info.rc = MQTT_ERR_QUEUE_SIZE return message.info self._out_messages[message.mid] = message if self._max_inflight_messages == 0 or self._inflight_messages < self._max_inflight_messages: self._inflight_messages += 1 if qos == 1: message.state = mqtt_ms_wait_for_puback elif qos == 2: message.state = mqtt_ms_wait_for_pubrec rc = self._send_publish(message.mid, topic, message.payload, message.qos, message.retain, message.dup, message.info, message.properties) # remove from inflight messages so it will be send after a connection is made if rc is MQTT_ERR_NO_CONN: self._inflight_messages -= 1 message.state = mqtt_ms_publish message.info.rc = rc return message.info else: message.state = mqtt_ms_queued message.info.rc = MQTT_ERR_SUCCESS return message.info def username_pw_set(self, username, password=None): """Set a username and optionally a password for broker authentication. Must be called before connect() to have any effect. Requires a broker that supports MQTT v3.1. username: The username to authenticate with. Need have no relationship to the client id. Must be unicode [MQTT-3.1.3-11]. Set to None to reset client back to not using username/password for broker authentication. password: The password to authenticate with. Optional, set to None if not required. If it is unicode, then it will be encoded as UTF-8. """ # [MQTT-3.1.3-11] User name must be UTF-8 encoded string self._username = None if username is None else username.encode('utf-8') self._password = password if isinstance(self._password, unicode): self._password = self._password.encode('utf-8') def enable_bridge_mode(self): """Sets the client in a bridge mode instead of client mode. Must be called before connect() to have any effect. Requires brokers that support bridge mode. Under bridge mode, the broker will identify the client as a bridge and not send it's own messages back to it. Hence a subsciption of # is possible without message loops. This feature also correctly propagates the retain flag on the messages. Currently Mosquitto and RSMB support this feature. This feature can be used to create a bridge between multiple broker. """ self._client_mode = MQTT_BRIDGE def is_connected(self): """Returns the current status of the connection True if connection exists False if connection is closed """ return self._state == mqtt_cs_connected def disconnect(self, reasoncode=None, properties=None): """Disconnect a connected client from the broker. reasoncode: (MQTT v5.0 only) a ReasonCodes instance setting the MQTT v5.0 reasoncode to be sent with the disconnect. It is optional, the receiver then assuming that 0 (success) is the value. properties: (MQTT v5.0 only) a Properties instance setting the MQTT v5.0 properties to be included. Optional - if not set, no properties are sent. """ self._state = mqtt_cs_disconnecting if self._sock is None: return MQTT_ERR_NO_CONN return self._send_disconnect(reasoncode, properties) def subscribe(self, topic, qos=0, options=None, properties=None): """Subscribe the client to one or more topics. This function may be called in three different ways (and a further three for MQTT v5.0): Simple string and integer ------------------------- e.g. subscribe("my/topic", 2) topic: A string specifying the subscription topic to subscribe to. qos: The desired quality of service level for the subscription. Defaults to 0. options and properties: Not used. Simple string and subscribe options (MQTT v5.0 only) ---------------------------------------------------- e.g. subscribe("my/topic", options=SubscribeOptions(qos=2)) topic: A string specifying the subscription topic to subscribe to. qos: Not used. options: The MQTT v5.0 subscribe options. properties: a Properties instance setting the MQTT v5.0 properties to be included. Optional - if not set, no properties are sent. String and integer tuple ------------------------ e.g. subscribe(("my/topic", 1)) topic: A tuple of (topic, qos). Both topic and qos must be present in the tuple. qos and options: Not used. properties: Only used for MQTT v5.0. A Properties instance setting the MQTT v5.0 properties. Optional - if not set, no properties are sent. String and subscribe options tuple (MQTT v5.0 only) --------------------------------------------------- e.g. subscribe(("my/topic", SubscribeOptions(qos=1))) topic: A tuple of (topic, SubscribeOptions). Both topic and subscribe options must be present in the tuple. qos and options: Not used. properties: a Properties instance setting the MQTT v5.0 properties to be included. Optional - if not set, no properties are sent. List of string and integer tuples --------------------------------- e.g. subscribe([("my/topic", 0), ("another/topic", 2)]) This allows multiple topic subscriptions in a single SUBSCRIPTION command, which is more efficient than using multiple calls to subscribe(). topic: A list of tuple of format (topic, qos). Both topic and qos must be present in all of the tuples. qos, options and properties: Not used. List of string and subscribe option tuples (MQTT v5.0 only) ----------------------------------------------------------- e.g. subscribe([("my/topic", SubscribeOptions(qos=0), ("another/topic", SubscribeOptions(qos=2)]) This allows multiple topic subscriptions in a single SUBSCRIPTION command, which is more efficient than using multiple calls to subscribe(). topic: A list of tuple of format (topic, SubscribeOptions). Both topic and subscribe options must be present in all of the tuples. qos and options: Not used. properties: a Properties instance setting the MQTT v5.0 properties to be included. Optional - if not set, no properties are sent. The function returns a tuple (result, mid), where result is MQTT_ERR_SUCCESS to indicate success or (MQTT_ERR_NO_CONN, None) if the client is not currently connected. mid is the message ID for the subscribe request. The mid value can be used to track the subscribe request by checking against the mid argument in the on_subscribe() callback if it is defined. Raises a ValueError if qos is not 0, 1 or 2, or if topic is None or has zero string length, or if topic is not a string, tuple or list. """ topic_qos_list = None if isinstance(topic, tuple): if self._protocol == MQTTv5: topic, options = topic if not isinstance(options, SubscribeOptions): raise ValueError( 'Subscribe options must be instance of SubscribeOptions class.') else: topic, qos = topic if isinstance(topic, basestring): if qos < 0 or qos > 2: raise ValueError('Invalid QoS level.') if self._protocol == MQTTv5: if options == None: # if no options are provided, use the QoS passed instead options = SubscribeOptions(qos=qos) elif qos != 0: raise ValueError( 'Subscribe options and qos parameters cannot be combined.') if not isinstance(options, SubscribeOptions): raise ValueError( 'Subscribe options must be instance of SubscribeOptions class.') topic_qos_list = [(topic.encode('utf-8'), options)] else: if topic is None or len(topic) == 0: raise ValueError('Invalid topic.') topic_qos_list = [(topic.encode('utf-8'), qos)] elif isinstance(topic, list): topic_qos_list = [] if self._protocol == MQTTv5: for t, o in topic: if not isinstance(o, SubscribeOptions): # then the second value should be QoS if o < 0 or o > 2: raise ValueError('Invalid QoS level.') o = SubscribeOptions(qos=o) topic_qos_list.append((t.encode('utf-8'), o)) else: for t, q in topic: if q < 0 or q > 2: raise ValueError('Invalid QoS level.') if t is None or len(t) == 0 or not isinstance(t, basestring): raise ValueError('Invalid topic.') topic_qos_list.append((t.encode('utf-8'), q)) if topic_qos_list is None: raise ValueError("No topic specified, or incorrect topic type.") if any(self._filter_wildcard_len_check(topic) != MQTT_ERR_SUCCESS for topic, _ in topic_qos_list): raise ValueError('Invalid subscription filter.') if self._sock is None: return (MQTT_ERR_NO_CONN, None) return self._send_subscribe(False, topic_qos_list, properties) def unsubscribe(self, topic, properties=None): """Unsubscribe the client from one or more topics. topic: A single string, or list of strings that are the subscription topics to unsubscribe from. properties: (MQTT v5.0 only) a Properties instance setting the MQTT v5.0 properties to be included. Optional - if not set, no properties are sent. Returns a tuple (result, mid), where result is MQTT_ERR_SUCCESS to indicate success or (MQTT_ERR_NO_CONN, None) if the client is not currently connected. mid is the message ID for the unsubscribe request. The mid value can be used to track the unsubscribe request by checking against the mid argument in the on_unsubscribe() callback if it is defined. Raises a ValueError if topic is None or has zero string length, or is not a string or list. """ topic_list = None if topic is None: raise ValueError('Invalid topic.') if isinstance(topic, basestring): if len(topic) == 0: raise ValueError('Invalid topic.') topic_list = [topic.encode('utf-8')] elif isinstance(topic, list): topic_list = [] for t in topic: if len(t) == 0 or not isinstance(t, basestring): raise ValueError('Invalid topic.') topic_list.append(t.encode('utf-8')) if topic_list is None: raise ValueError("No topic specified, or incorrect topic type.") if self._sock is None: return (MQTT_ERR_NO_CONN, None) return self._send_unsubscribe(False, topic_list, properties) def loop_read(self, max_packets=1): """Process read network events. Use in place of calling loop() if you wish to handle your client reads as part of your own application. Use socket() to obtain the client socket to call select() or equivalent on. Do not use if you are using the threaded interface loop_start().""" if self._sock is None: return MQTT_ERR_NO_CONN max_packets = len(self._out_messages) + len(self._in_messages) if max_packets < 1: max_packets = 1 for _ in range(0, max_packets): if self._sock is None: return MQTT_ERR_NO_CONN rc = self._packet_read() if rc > 0: return self._loop_rc_handle(rc) elif rc == MQTT_ERR_AGAIN: return MQTT_ERR_SUCCESS return MQTT_ERR_SUCCESS def loop_write(self, max_packets=1): """Process write network events. Use in place of calling loop() if you wish to handle your client writes as part of your own application. Use socket() to obtain the client socket to call select() or equivalent on. Use want_write() to determine if there is data waiting to be written. Do not use if you are using the threaded interface loop_start().""" if self._sock is None: return MQTT_ERR_NO_CONN max_packets = len(self._out_packet) + 1 if max_packets < 1: max_packets = 1 try: for _ in range(0, max_packets): rc = self._packet_write() if rc > 0: return self._loop_rc_handle(rc) elif rc == MQTT_ERR_AGAIN: return MQTT_ERR_SUCCESS return MQTT_ERR_SUCCESS finally: if self.want_write(): self._call_socket_register_write() else: self._call_socket_unregister_write() def want_write(self): """Call to determine if there is network data waiting to be written. Useful if you are calling select() yourself rather than using loop(). """ if self._current_out_packet or len(self._out_packet) > 0: return True else: return False def loop_misc(self): """Process miscellaneous network events. Use in place of calling loop() if you wish to call select() or equivalent on. Do not use if you are using the threaded interface loop_start().""" if self._sock is None: return MQTT_ERR_NO_CONN now = time_func() self._check_keepalive() if self._last_retry_check + 1 < now: # Only check once a second at most self._message_retry_check() self._last_retry_check = now if self._ping_t > 0 and now - self._ping_t >= self._keepalive: # client->ping_t != 0 means we are waiting for a pingresp. # This hasn't happened in the keepalive time so we should disconnect. self._sock_close() if self._state == mqtt_cs_disconnecting: rc = MQTT_ERR_SUCCESS else: rc = 1 self._do_on_disconnect(rc) return MQTT_ERR_CONN_LOST return MQTT_ERR_SUCCESS def max_inflight_messages_set(self, inflight): """Set the maximum number of messages with QoS>0 that can be part way through their network flow at once. Defaults to 20.""" if inflight < 0: raise ValueError('Invalid inflight.') self._max_inflight_messages = inflight def max_queued_messages_set(self, queue_size): """Set the maximum number of messages in the outgoing message queue. 0 means unlimited.""" if queue_size < 0: raise ValueError('Invalid queue size.') if not isinstance(queue_size, int): raise ValueError('Invalid type of queue size.') self._max_queued_messages = queue_size return self def message_retry_set(self, retry): """Set the timeout in seconds before a message with QoS>0 is retried. 20 seconds by default.""" if retry < 0: raise ValueError('Invalid retry.') self._message_retry = retry def user_data_set(self, userdata): """Set the user data variable passed to callbacks. May be any data type.""" self._userdata = userdata def will_set(self, topic, payload=None, qos=0, retain=False, properties=None): """Set a Will to be sent by the broker in case the client disconnects unexpectedly. This must be called before connect() to have any effect. topic: The topic that the will message should be published on. payload: The message to send as a will. If not given, or set to None a zero length message will be used as the will. Passing an int or float will result in the payload being converted to a string representing that number. If you wish to send a true int/float, use struct.pack() to create the payload you require. qos: The quality of service level to use for the will. retain: If set to true, the will message will be set as the "last known good"/retained message for the topic. properties: (MQTT v5.0 only) a Properties instance setting the MQTT v5.0 properties to be included with the will message. Optional - if not set, no properties are sent. Raises a ValueError if qos is not 0, 1 or 2, or if topic is None or has zero string length. """ if topic is None or len(topic) == 0: raise ValueError('Invalid topic.') if qos < 0 or qos > 2: raise ValueError('Invalid QoS level.') if properties != None and not isinstance(properties, Properties): raise ValueError( "The properties argument must be an instance of the Properties class.") if isinstance(payload, unicode): self._will_payload = payload.encode('utf-8') elif isinstance(payload, (bytes, bytearray)): self._will_payload = payload elif isinstance(payload, (int, float)): self._will_payload = str(payload).encode('ascii') elif payload is None: self._will_payload = b"" else: raise TypeError( 'payload must be a string, bytearray, int, float or None.') self._will = True self._will_topic = topic.encode('utf-8') self._will_qos = qos self._will_retain = retain self._will_properties = properties def will_clear(self): """ Removes a will that was previously configured with will_set(). Must be called before connect() to have any effect.""" self._will = False self._will_topic = b"" self._will_payload = b"" self._will_qos = 0 self._will_retain = False def socket(self): """Return the socket or ssl object for this client.""" return self._sock def loop_forever(self, timeout=1.0, max_packets=1, retry_first_connection=False): """This function call loop() for you in an infinite blocking loop. It is useful for the case where you only want to run the MQTT client loop in your program. loop_forever() will handle reconnecting for you. If you call disconnect() in a callback it will return. timeout: The time in seconds to wait for incoming/outgoing network traffic before timing out and returning. max_packets: Not currently used. retry_first_connection: Should the first connection attempt be retried on failure. Raises socket.error on first connection failures unless retry_first_connection=True """ run = True while run: if self._thread_terminate is True: break if self._state == mqtt_cs_connect_async: try: self.reconnect() except (socket.error, OSError, WebsocketConnectionError): if not retry_first_connection: raise self._easy_log( MQTT_LOG_DEBUG, "Connection failed, retrying") self._reconnect_wait() else: break while run: rc = MQTT_ERR_SUCCESS while rc == MQTT_ERR_SUCCESS: rc = self.loop(timeout, max_packets) # We don't need to worry about locking here, because we've # either called loop_forever() when in single threaded mode, or # in multi threaded mode when loop_stop() has been called and # so no other threads can access _current_out_packet, # _out_packet or _messages. if (self._thread_terminate is True and self._current_out_packet is None and len(self._out_packet) == 0 and len(self._out_messages) == 0): rc = 1 run = False def should_exit(): return self._state == mqtt_cs_disconnecting or run is False or self._thread_terminate is True if should_exit(): run = False else: self._reconnect_wait() if should_exit(): run = False else: try: self.reconnect() except (socket.error, OSError, WebsocketConnectionError): self._easy_log( MQTT_LOG_DEBUG, "Connection failed, retrying") return rc def loop_start(self): """This is part of the threaded client interface. Call this once to start a new thread to process network traffic. This provides an alternative to repeatedly calling loop() yourself. """ if self._thread is not None: return MQTT_ERR_INVAL self._thread_terminate = False self._thread = threading.Thread(target=self._thread_main) self._thread.daemon = True self._thread.start() def loop_stop(self, force=False): """This is part of the threaded client interface. Call this once to stop the network thread previously created with loop_start(). This call will block until the network thread finishes. The force parameter is currently ignored. """ if self._thread is None: return MQTT_ERR_INVAL self._thread_terminate = True if threading.current_thread() != self._thread: self._thread.join() self._thread = None @property def on_log(self): """If implemented, called when the client has log information. Defined to allow debugging.""" return self._on_log @on_log.setter def on_log(self, func): """ Define the logging callback implementation. Expected signature is: log_callback(client, userdata, level, buf) client: the client instance for this callback userdata: the private user data as set in Client() or userdata_set() level: gives the severity of the message and will be one of MQTT_LOG_INFO, MQTT_LOG_NOTICE, MQTT_LOG_WARNING, MQTT_LOG_ERR, and MQTT_LOG_DEBUG. buf: the message itself """ self._on_log = func @property def on_connect(self): """If implemented, called when the broker responds to our connection request.""" return self._on_connect @on_connect.setter def on_connect(self, func): """ Define the connect callback implementation. Expected signature for MQTT v3.1 and v3.1.1 is: connect_callback(client, userdata, flags, rc, properties=None) and for MQTT v5.0: connect_callback(client, userdata, flags, reasonCode, properties) client: the client instance for this callback userdata: the private user data as set in Client() or userdata_set() flags: response flags sent by the broker rc: the connection result reasonCode: the MQTT v5.0 reason code: an instance of the ReasonCode class. ReasonCode may be compared to interger. properties: the MQTT v5.0 properties returned from the broker. An instance of the Properties class. For MQTT v3.1 and v3.1.1 properties is not provided but for compatibility with MQTT v5.0, we recommand adding properties=None. flags is a dict that contains response flags from the broker: flags['session present'] - this flag is useful for clients that are using clean session set to 0 only. If a client with clean session=0, that reconnects to a broker that it has previously connected to, this flag indicates whether the broker still has the session information for the client. If 1, the session still exists. The value of rc indicates success or not: 0: Connection successful 1: Connection refused - incorrect protocol version 2: Connection refused - invalid client identifier 3: Connection refused - server unavailable 4: Connection refused - bad username or password 5: Connection refused - not authorised 6-255: Currently unused. """ with self._callback_mutex: self._on_connect = func @property def on_subscribe(self): """If implemented, called when the broker responds to a subscribe request.""" return self._on_subscribe @on_subscribe.setter def on_subscribe(self, func): """ Define the suscribe callback implementation. Expected signature for MQTT v3.1.1 and v3.1 is: subscribe_callback(client, userdata, mid, granted_qos, properties=None) and for MQTT v5.0: subscribe_callback(client, userdata, mid, reasonCodes, properties) client: the client instance for this callback userdata: the private user data as set in Client() or userdata_set() mid: matches the mid variable returned from the corresponding subscribe() call. granted_qos: list of integers that give the QoS level the broker has granted for each of the different subscription requests. reasonCodes: the MQTT v5.0 reason codes received from the broker for each subscription. A list of ReasonCodes instances. properties: the MQTT v5.0 properties received from the broker. A list of Properties class instances. """ with self._callback_mutex: self._on_subscribe = func @property def on_message(self): """If implemented, called when a message has been received on a topic that the client subscribes to. This callback will be called for every message received. Use message_callback_add() to define multiple callbacks that will be called for specific topic filters.""" return self._on_message @on_message.setter def on_message(self, func): """ Define the message received callback implementation. Expected signature is: on_message_callback(client, userdata, message) client: the client instance for this callback userdata: the private user data as set in Client() or userdata_set() message: an instance of MQTTMessage. This is a class with members topic, payload, qos, retain. """ with self._callback_mutex: self._on_message = func @property def on_publish(self): """If implemented, called when a message that was to be sent using the publish() call has completed transmission to the broker. For messages with QoS levels 1 and 2, this means that the appropriate handshakes have completed. For QoS 0, this simply means that the message has left the client. This callback is important because even if the publish() call returns success, it does not always mean that the message has been sent.""" return self._on_publish @on_publish.setter def on_publish(self, func): """ Define the published message callback implementation. Expected signature is: on_publish_callback(client, userdata, mid) client: the client instance for this callback userdata: the private user data as set in Client() or userdata_set() mid: matches the mid variable returned from the corresponding publish() call, to allow outgoing messages to be tracked. """ with self._callback_mutex: self._on_publish = func @property def on_unsubscribe(self): """If implemented, called when the broker responds to an unsubscribe request.""" return self._on_unsubscribe @on_unsubscribe.setter def on_unsubscribe(self, func): """ Define the unsubscribe callback implementation. Expected signature for MQTT v3.1.1 and v3.1 is: unsubscribe_callback(client, userdata, mid) and for MQTT v5.0: unsubscribe_callback(client, userdata, mid, properties, reasonCodes) client: the client instance for this callback userdata: the private user data as set in Client() or userdata_set() mid: matches the mid variable returned from the corresponding unsubscribe() call. properties: the MQTT v5.0 properties received from the broker. A list of Properties class instances. reasonCodes: the MQTT v5.0 reason codes received from the broker for each unsubscribe topic. A list of ReasonCodes instances """ with self._callback_mutex: self._on_unsubscribe = func @property def on_disconnect(self): """If implemented, called when the client disconnects from the broker. """ return self._on_disconnect @on_disconnect.setter def on_disconnect(self, func): """ Define the disconnect callback implementation. Expected signature for MQTT v3.1.1 and v3.1 is: disconnect_callback(client, userdata, rc) and for MQTT v5.0: disconnect_callback(client, userdata, reasonCode, properties) client: the client instance for this callback userdata: the private user data as set in Client() or userdata_set() rc: the disconnection result The rc parameter indicates the disconnection state. If MQTT_ERR_SUCCESS (0), the callback was called in response to a disconnect() call. If any other value the disconnection was unexpected, such as might be caused by a network error. """ with self._callback_mutex: self._on_disconnect = func @property def on_socket_open(self): """If implemented, called just after the socket was opend.""" return self._on_socket_open @on_socket_open.setter def on_socket_open(self, func): """Define the socket_open callback implementation. This should be used to register the socket to an external event loop for reading. Expected signature is: socket_open_callback(client, userdata, socket) client: the client instance for this callback userdata: the private user data as set in Client() or userdata_set() sock: the socket which was just opened. """ with self._callback_mutex: self._on_socket_open = func def _call_socket_open(self): """Call the socket_open callback with the just-opened socket""" with self._callback_mutex: if self.on_socket_open: with self._in_callback_mutex: try: self.on_socket_open(self, self._userdata, self._sock) except Exception as err: self._easy_log( MQTT_LOG_ERR, 'Caught exception in on_socket_open: %s', err) if not self.suppress_exceptions: raise @property def on_socket_close(self): """If implemented, called just before the socket is closed.""" return self._on_socket_close @on_socket_close.setter def on_socket_close(self, func): """Define the socket_close callback implementation. This should be used to unregister the socket from an external event loop for reading. Expected signature is: socket_close_callback(client, userdata, socket) client: the client instance for this callback userdata: the private user data as set in Client() or userdata_set() sock: the socket which is about to be closed. """ with self._callback_mutex: self._on_socket_close = func def _call_socket_close(self, sock): """Call the socket_close callback with the about-to-be-closed socket""" with self._callback_mutex: if self.on_socket_close: with self._in_callback_mutex: try: self.on_socket_close(self, self._userdata, sock) except Exception as err: self._easy_log( MQTT_LOG_ERR, 'Caught exception in on_socket_close: %s', err) if not self.suppress_exceptions: raise @property def on_socket_register_write(self): """If implemented, called when the socket needs writing but can't.""" return self._on_socket_register_write @on_socket_register_write.setter def on_socket_register_write(self, func): """Define the socket_register_write callback implementation. This should be used to register the socket with an external event loop for writing. Expected signature is: socket_register_write_callback(client, userdata, socket) client: the client instance for this callback userdata: the private user data as set in Client() or userdata_set() sock: the socket which should be registered for writing """ with self._callback_mutex: self._on_socket_register_write = func def _call_socket_register_write(self): """Call the socket_register_write callback with the unwritable socket""" if not self._sock or self._registered_write: return self._registered_write = True with self._callback_mutex: if self.on_socket_register_write: try: self.on_socket_register_write( self, self._userdata, self._sock) except Exception as err: self._easy_log( MQTT_LOG_ERR, 'Caught exception in on_socket_register_write: %s', err) if not self.suppress_exceptions: raise @property def on_socket_unregister_write(self): """If implemented, called when the socket doesn't need writing anymore.""" return self._on_socket_unregister_write @on_socket_unregister_write.setter def on_socket_unregister_write(self, func): """Define the socket_unregister_write callback implementation. This should be used to unregister the socket from an external event loop for writing. Expected signature is: socket_unregister_write_callback(client, userdata, socket) client: the client instance for this callback userdata: the private user data as set in Client() or userdata_set() sock: the socket which should be unregistered for writing """ with self._callback_mutex: self._on_socket_unregister_write = func def _call_socket_unregister_write(self, sock=None): """Call the socket_unregister_write callback with the writable socket""" sock = sock or self._sock if not sock or not self._registered_write: return self._registered_write = False with self._callback_mutex: if self.on_socket_unregister_write: try: self.on_socket_unregister_write(self, self._userdata, sock) except Exception as err: self._easy_log( MQTT_LOG_ERR, 'Caught exception in on_socket_unregister_write: %s', err) if not self.suppress_exceptions: raise def message_callback_add(self, sub, callback): """Register a message callback for a specific topic. Messages that match 'sub' will be passed to 'callback'. Any non-matching messages will be passed to the default on_message callback. Call multiple times with different 'sub' to define multiple topic specific callbacks. Topic specific callbacks may be removed with message_callback_remove().""" if callback is None or sub is None: raise ValueError("sub and callback must both be defined.") with self._callback_mutex: self._on_message_filtered[sub] = callback def message_callback_remove(self, sub): """Remove a message callback previously registered with message_callback_add().""" if sub is None: raise ValueError("sub must defined.") with self._callback_mutex: try: del self._on_message_filtered[sub] except KeyError: # no such subscription pass # ============================================================ # Private functions # ============================================================ def _loop_rc_handle(self, rc, properties=None): if rc: self._sock_close() if self._state == mqtt_cs_disconnecting: rc = MQTT_ERR_SUCCESS self._do_on_disconnect(rc, properties) return rc def _packet_read(self): # This gets called if pselect() indicates that there is network data # available - ie. at least one byte. What we do depends on what data we # already have. # If we've not got a command, attempt to read one and save it. This should # always work because it's only a single byte. # Then try to read the remaining length. This may fail because it is may # be more than one byte - will need to save data pending next read if it # does fail. # Then try to read the remaining payload, where 'payload' here means the # combined variable header and actual payload. This is the most likely to # fail due to longer length, so save current data and current position. # After all data is read, send to _mqtt_handle_packet() to deal with. # Finally, free the memory and reset everything to starting conditions. if self._in_packet['command'] == 0: try: command = self._sock_recv(1) except WouldBlockError: return MQTT_ERR_AGAIN except socket.error as err: self._easy_log( MQTT_LOG_ERR, 'failed to receive on socket: %s', err) return 1 else: if len(command) == 0: return 1 command, = struct.unpack("!B", command) self._in_packet['command'] = command if self._in_packet['have_remaining'] == 0: # Read remaining # Algorithm for decoding taken from pseudo code at # http://publib.boulder.ibm.com/infocenter/wmbhelp/v6r0m0/topic/com.ibm.etools.mft.doc/ac10870_.htm while True: try: byte = self._sock_recv(1) except WouldBlockError: return MQTT_ERR_AGAIN except socket.error as err: self._easy_log( MQTT_LOG_ERR, 'failed to receive on socket: %s', err) return 1 else: if len(byte) == 0: return 1 byte, = struct.unpack("!B", byte) self._in_packet['remaining_count'].append(byte) # Max 4 bytes length for remaining length as defined by protocol. # Anything more likely means a broken/malicious client. if len(self._in_packet['remaining_count']) > 4: return MQTT_ERR_PROTOCOL self._in_packet['remaining_length'] += ( byte & 127) * self._in_packet['remaining_mult'] self._in_packet['remaining_mult'] = self._in_packet['remaining_mult'] * 128 if (byte & 128) == 0: break self._in_packet['have_remaining'] = 1 self._in_packet['to_process'] = self._in_packet['remaining_length'] while self._in_packet['to_process'] > 0: try: data = self._sock_recv(self._in_packet['to_process']) except WouldBlockError: return MQTT_ERR_AGAIN except socket.error as err: self._easy_log( MQTT_LOG_ERR, 'failed to receive on socket: %s', err) return 1 else: if len(data) == 0: return 1 self._in_packet['to_process'] -= len(data) self._in_packet['packet'] += data # All data for this packet is read. self._in_packet['pos'] = 0 rc = self._packet_handle() # Free data and reset values self._in_packet = { 'command': 0, 'have_remaining': 0, 'remaining_count': [], 'remaining_mult': 1, 'remaining_length': 0, 'packet': b"", 'to_process': 0, 'pos': 0} with self._msgtime_mutex: self._last_msg_in = time_func() return rc def _packet_write(self): self._current_out_packet_mutex.acquire() while self._current_out_packet: packet = self._current_out_packet try: write_length = self._sock_send( packet['packet'][packet['pos']:]) except (AttributeError, ValueError): self._current_out_packet_mutex.release() return MQTT_ERR_SUCCESS except WouldBlockError: self._current_out_packet_mutex.release() return MQTT_ERR_AGAIN except socket.error as err: self._current_out_packet_mutex.release() self._easy_log( MQTT_LOG_ERR, 'failed to receive on socket: %s', err) return 1 if write_length > 0: packet['to_process'] -= write_length packet['pos'] += write_length if packet['to_process'] == 0: if (packet['command'] & 0xF0) == PUBLISH and packet['qos'] == 0: with self._callback_mutex: if self.on_publish: with self._in_callback_mutex: try: self.on_publish( self, self._userdata, packet['mid']) except Exception as err: self._easy_log( MQTT_LOG_ERR, 'Caught exception in on_publish: %s', err) if not self.suppress_exceptions: raise packet['info']._set_as_published() if (packet['command'] & 0xF0) == DISCONNECT: self._current_out_packet_mutex.release() with self._msgtime_mutex: self._last_msg_out = time_func() self._do_on_disconnect(0) self._sock_close() return MQTT_ERR_SUCCESS with self._out_packet_mutex: if len(self._out_packet) > 0: self._current_out_packet = self._out_packet.popleft() else: self._current_out_packet = None else: break self._current_out_packet_mutex.release() with self._msgtime_mutex: self._last_msg_out = time_func() return MQTT_ERR_SUCCESS def _easy_log(self, level, fmt, *args): if self.on_log is not None: buf = fmt % args try: self.on_log(self, self._userdata, level, buf) except Exception: # Can't _easy_log this, as we'll recurse until we break pass # self._logger will pick this up, so we're fine if self._logger is not None: level_std = LOGGING_LEVEL[level] self._logger.log(level_std, fmt, *args) def _check_keepalive(self): if self._keepalive == 0: return MQTT_ERR_SUCCESS now = time_func() with self._msgtime_mutex: last_msg_out = self._last_msg_out last_msg_in = self._last_msg_in if self._sock is not None and (now - last_msg_out >= self._keepalive or now - last_msg_in >= self._keepalive): if self._state == mqtt_cs_connected and self._ping_t == 0: self._send_pingreq() with self._msgtime_mutex: self._last_msg_out = now self._last_msg_in = now else: self._sock_close() if self._state == mqtt_cs_disconnecting: rc = MQTT_ERR_SUCCESS else: rc = 1 self._do_on_disconnect(rc) def _mid_generate(self): with self._mid_generate_mutex: self._last_mid += 1 if self._last_mid == 65536: self._last_mid = 1 return self._last_mid @staticmethod def _topic_wildcard_len_check(topic): # Search for + or # in a topic. Return MQTT_ERR_INVAL if found. # Also returns MQTT_ERR_INVAL if the topic string is too long. # Returns MQTT_ERR_SUCCESS if everything is fine. if b'+' in topic or b'#' in topic or len(topic) > 65535: return MQTT_ERR_INVAL else: return MQTT_ERR_SUCCESS @staticmethod def _filter_wildcard_len_check(sub): if (len(sub) == 0 or len(sub) > 65535 or any(b'+' in p or b'#' in p for p in sub.split(b'/') if len(p) > 1) or b'#/' in sub): return MQTT_ERR_INVAL else: return MQTT_ERR_SUCCESS def _send_pingreq(self): self._easy_log(MQTT_LOG_DEBUG, "Sending PINGREQ") rc = self._send_simple_command(PINGREQ) if rc == MQTT_ERR_SUCCESS: self._ping_t = time_func() return rc def _send_pingresp(self): self._easy_log(MQTT_LOG_DEBUG, "Sending PINGRESP") return self._send_simple_command(PINGRESP) def _send_puback(self, mid): self._easy_log(MQTT_LOG_DEBUG, "Sending PUBACK (Mid: %d)", mid) return self._send_command_with_mid(PUBACK, mid, False) def _send_pubcomp(self, mid): self._easy_log(MQTT_LOG_DEBUG, "Sending PUBCOMP (Mid: %d)", mid) return self._send_command_with_mid(PUBCOMP, mid, False) def _pack_remaining_length(self, packet, remaining_length): remaining_bytes = [] while True: byte = remaining_length % 128 remaining_length = remaining_length // 128 # If there are more digits to encode, set the top bit of this digit if remaining_length > 0: byte |= 0x80 remaining_bytes.append(byte) packet.append(byte) if remaining_length == 0: # FIXME - this doesn't deal with incorrectly large payloads return packet def _pack_str16(self, packet, data): if isinstance(data, unicode): data = data.encode('utf-8') packet.extend(struct.pack("!H", len(data))) packet.extend(data) def _send_publish(self, mid, topic, payload=b'', qos=0, retain=False, dup=False, info=None, properties=None): # we assume that topic and payload are already properly encoded assert not isinstance(topic, unicode) and not isinstance( payload, unicode) and payload is not None if self._sock is None: return MQTT_ERR_NO_CONN command = PUBLISH | ((dup & 0x1) << 3) | (qos << 1) | retain packet = bytearray() packet.append(command) payloadlen = len(payload) remaining_length = 2 + len(topic) + payloadlen if payloadlen == 0: if self._protocol == MQTTv5: self._easy_log( MQTT_LOG_DEBUG, "Sending PUBLISH (d%d, q%d, r%d, m%d), '%s', properties=%s (NULL payload)", dup, qos, retain, mid, topic, properties ) else: self._easy_log( MQTT_LOG_DEBUG, "Sending PUBLISH (d%d, q%d, r%d, m%d), '%s' (NULL payload)", dup, qos, retain, mid, topic ) else: if self._protocol == MQTTv5: self._easy_log( MQTT_LOG_DEBUG, "Sending PUBLISH (d%d, q%d, r%d, m%d), '%s', properties=%s, ... (%d bytes)", dup, qos, retain, mid, topic, properties, payloadlen ) else: self._easy_log( MQTT_LOG_DEBUG, "Sending PUBLISH (d%d, q%d, r%d, m%d), '%s', ... (%d bytes)", dup, qos, retain, mid, topic, payloadlen ) if qos > 0: # For message id remaining_length += 2 if self._protocol == MQTTv5: if properties == None: packed_properties = b'\x00' else: packed_properties = properties.pack() remaining_length += len(packed_properties) self._pack_remaining_length(packet, remaining_length) self._pack_str16(packet, topic) if qos > 0: # For message id packet.extend(struct.pack("!H", mid)) if self._protocol == MQTTv5: packet.extend(packed_properties) packet.extend(payload) return self._packet_queue(PUBLISH, packet, mid, qos, info) def _send_pubrec(self, mid): self._easy_log(MQTT_LOG_DEBUG, "Sending PUBREC (Mid: %d)", mid) return self._send_command_with_mid(PUBREC, mid, False) def _send_pubrel(self, mid): self._easy_log(MQTT_LOG_DEBUG, "Sending PUBREL (Mid: %d)", mid) return self._send_command_with_mid(PUBREL | 2, mid, False) def _send_command_with_mid(self, command, mid, dup): # For PUBACK, PUBCOMP, PUBREC, and PUBREL if dup: command |= 0x8 remaining_length = 2 packet = struct.pack('!BBH', command, remaining_length, mid) return self._packet_queue(command, packet, mid, 1) def _send_simple_command(self, command): # For DISCONNECT, PINGREQ and PINGRESP remaining_length = 0 packet = struct.pack('!BB', command, remaining_length) return self._packet_queue(command, packet, 0, 0) def _send_connect(self, keepalive): proto_ver = self._protocol # hard-coded UTF-8 encoded string protocol = b"MQTT" if proto_ver >= MQTTv311 else b"MQIsdp" remaining_length = 2 + len(protocol) + 1 + \ 1 + 2 + 2 + len(self._client_id) connect_flags = 0 if self._protocol == MQTTv5: if self._clean_start == True: connect_flags |= 0x02 elif self._clean_start == MQTT_CLEAN_START_FIRST_ONLY and self._mqttv5_first_connect: connect_flags |= 0x02 elif self._clean_session: connect_flags |= 0x02 if self._will: remaining_length += 2 + \ len(self._will_topic) + 2 + len(self._will_payload) connect_flags |= 0x04 | ((self._will_qos & 0x03) << 3) | ( (self._will_retain & 0x01) << 5) if self._username is not None: remaining_length += 2 + len(self._username) connect_flags |= 0x80 if self._password is not None: connect_flags |= 0x40 remaining_length += 2 + len(self._password) if self._protocol == MQTTv5: if self._connect_properties == None: packed_connect_properties = b'\x00' else: packed_connect_properties = self._connect_properties.pack() remaining_length += len(packed_connect_properties) if self._will: if self._will_properties == None: packed_will_properties = b'\x00' else: packed_will_properties = self._will_properties.pack() remaining_length += len(packed_will_properties) command = CONNECT packet = bytearray() packet.append(command) # as per the mosquitto broker, if the MSB of this version is set # to 1, then it treats the connection as a bridge if self._client_mode == MQTT_BRIDGE: proto_ver |= 0x80 self._pack_remaining_length(packet, remaining_length) packet.extend(struct.pack("!H" + str(len(protocol)) + "sBBH", len(protocol), protocol, proto_ver, connect_flags, keepalive)) if self._protocol == MQTTv5: packet += packed_connect_properties self._pack_str16(packet, self._client_id) if self._will: if self._protocol == MQTTv5: packet += packed_will_properties self._pack_str16(packet, self._will_topic) self._pack_str16(packet, self._will_payload) if self._username is not None: self._pack_str16(packet, self._username) if self._password is not None: self._pack_str16(packet, self._password) self._keepalive = keepalive if self._protocol == MQTTv5: self._easy_log( MQTT_LOG_DEBUG, "Sending CONNECT (u%d, p%d, wr%d, wq%d, wf%d, c%d, k%d) client_id=%s properties=%s", (connect_flags & 0x80) >> 7, (connect_flags & 0x40) >> 6, (connect_flags & 0x20) >> 5, (connect_flags & 0x18) >> 3, (connect_flags & 0x4) >> 2, (connect_flags & 0x2) >> 1, keepalive, self._client_id, self._connect_properties ) else: self._easy_log( MQTT_LOG_DEBUG, "Sending CONNECT (u%d, p%d, wr%d, wq%d, wf%d, c%d, k%d) client_id=%s", (connect_flags & 0x80) >> 7, (connect_flags & 0x40) >> 6, (connect_flags & 0x20) >> 5, (connect_flags & 0x18) >> 3, (connect_flags & 0x4) >> 2, (connect_flags & 0x2) >> 1, keepalive, self._client_id ) return self._packet_queue(command, packet, 0, 0) def _send_disconnect(self, reasoncode=None, properties=None): if self._protocol == MQTTv5: self._easy_log(MQTT_LOG_DEBUG, "Sending DISCONNECT reasonCode=%s properties=%s", reasoncode, properties ) else: self._easy_log(MQTT_LOG_DEBUG, "Sending DISCONNECT") remaining_length = 0 command = DISCONNECT packet = bytearray() packet.append(command) if self._protocol == MQTTv5: if properties != None or reasoncode != None: if reasoncode == None: reasoncode = ReasonCodes(DISCONNECT >> 4, identifier=0) remaining_length += 1 if properties != None: packed_props = properties.pack() remaining_length += len(packed_props) self._pack_remaining_length(packet, remaining_length) if self._protocol == MQTTv5: if reasoncode != None: packet += reasoncode.pack() if properties != None: packet += packed_props return self._packet_queue(command, packet, 0, 0) def _send_subscribe(self, dup, topics, properties=None): remaining_length = 2 if self._protocol == MQTTv5: if properties == None: packed_subscribe_properties = b'\x00' else: packed_subscribe_properties = properties.pack() remaining_length += len(packed_subscribe_properties) for t, _ in topics: remaining_length += 2 + len(t) + 1 command = SUBSCRIBE | (dup << 3) | 0x2 packet = bytearray() packet.append(command) self._pack_remaining_length(packet, remaining_length) local_mid = self._mid_generate() packet.extend(struct.pack("!H", local_mid)) if self._protocol == MQTTv5: packet += packed_subscribe_properties for t, q in topics: self._pack_str16(packet, t) if self._protocol == MQTTv5: packet += q.pack() else: packet.append(q) self._easy_log( MQTT_LOG_DEBUG, "Sending SUBSCRIBE (d%d, m%d) %s", dup, local_mid, topics, ) return (self._packet_queue(command, packet, local_mid, 1), local_mid) def _send_unsubscribe(self, dup, topics, properties=None): remaining_length = 2 if self._protocol == MQTTv5: if properties == None: packed_unsubscribe_properties = b'\x00' else: packed_unsubscribe_properties = properties.pack() remaining_length += len(packed_unsubscribe_properties) for t in topics: remaining_length += 2 + len(t) command = UNSUBSCRIBE | (dup << 3) | 0x2 packet = bytearray() packet.append(command) self._pack_remaining_length(packet, remaining_length) local_mid = self._mid_generate() packet.extend(struct.pack("!H", local_mid)) if self._protocol == MQTTv5: packet += packed_unsubscribe_properties for t in topics: self._pack_str16(packet, t) # topics_repr = ", ".join("'"+topic.decode('utf8')+"'" for topic in topics) if self._protocol == MQTTv5: self._easy_log( MQTT_LOG_DEBUG, "Sending UNSUBSCRIBE (d%d, m%d) %s %s", dup, local_mid, properties, topics, ) else: self._easy_log( MQTT_LOG_DEBUG, "Sending UNSUBSCRIBE (d%d, m%d) %s", dup, local_mid, topics, ) return (self._packet_queue(command, packet, local_mid, 1), local_mid) def _message_retry_check_actual(self, messages, mutex): with mutex: now = time_func() for m in messages.values(): if m.timestamp + self._message_retry < now: if m.state == mqtt_ms_wait_for_puback or m.state == mqtt_ms_wait_for_pubrec: m.timestamp = now m.dup = True self._send_publish( m.mid, m.topic.encode('utf-8'), m.payload, m.qos, m.retain, m.dup, properties=m.properties, ) elif m.state == mqtt_ms_wait_for_pubrel: m.timestamp = now self._send_pubrec(m.mid) elif m.state == mqtt_ms_wait_for_pubcomp: m.timestamp = now self._send_pubrel(m.mid) def _message_retry_check(self): self._message_retry_check_actual( self._out_messages, self._out_message_mutex) self._message_retry_check_actual( self._in_messages, self._in_message_mutex) def _check_clean_session(self): if self._protocol == MQTTv5: if self._clean_start == MQTT_CLEAN_START_FIRST_ONLY: return self._mqttv5_first_connect else: return self._clean_start else: return self._clean_session def _messages_reconnect_reset_out(self): with self._out_message_mutex: self._inflight_messages = 0 for m in self._out_messages.values(): m.timestamp = 0 if self._max_inflight_messages == 0 or self._inflight_messages < self._max_inflight_messages: if m.qos == 0: m.state = mqtt_ms_publish elif m.qos == 1: # self._inflight_messages = self._inflight_messages + 1 if m.state == mqtt_ms_wait_for_puback: m.dup = True m.state = mqtt_ms_publish elif m.qos == 2: # self._inflight_messages = self._inflight_messages + 1 if self._check_clean_session(): if m.state != mqtt_ms_publish: m.dup = True m.state = mqtt_ms_publish else: if m.state == mqtt_ms_wait_for_pubcomp: m.state = mqtt_ms_resend_pubrel else: if m.state == mqtt_ms_wait_for_pubrec: m.dup = True m.state = mqtt_ms_publish else: m.state = mqtt_ms_queued def _messages_reconnect_reset_in(self): with self._in_message_mutex: if self._check_clean_session(): self._in_messages = collections.OrderedDict() return for m in self._in_messages.values(): m.timestamp = 0 if m.qos != 2: self._in_messages.pop(m.mid) else: # Preserve current state pass def _messages_reconnect_reset(self): self._messages_reconnect_reset_out() self._messages_reconnect_reset_in() def _packet_queue(self, command, packet, mid, qos, info=None): mpkt = { 'command': command, 'mid': mid, 'qos': qos, 'pos': 0, 'to_process': len(packet), 'packet': packet, 'info': info} with self._out_packet_mutex: self._out_packet.append(mpkt) if self._current_out_packet_mutex.acquire(False): if self._current_out_packet is None and len(self._out_packet) > 0: self._current_out_packet = self._out_packet.popleft() self._current_out_packet_mutex.release() # Write a single byte to sockpairW (connected to sockpairR) to break # out of select() if in threaded mode. try: self._sockpairW.send(sockpair_data) except socket.error as err: if err.errno != EAGAIN: raise if self._thread is None: if self._in_callback_mutex.acquire(False): self._in_callback_mutex.release() return self.loop_write() self._call_socket_register_write() return MQTT_ERR_SUCCESS def _packet_handle(self): cmd = self._in_packet['command'] & 0xF0 if cmd == PINGREQ: return self._handle_pingreq() elif cmd == PINGRESP: return self._handle_pingresp() elif cmd == PUBACK: return self._handle_pubackcomp("PUBACK") elif cmd == PUBCOMP: return self._handle_pubackcomp("PUBCOMP") elif cmd == PUBLISH: return self._handle_publish() elif cmd == PUBREC: return self._handle_pubrec() elif cmd == PUBREL: return self._handle_pubrel() elif cmd == CONNACK: return self._handle_connack() elif cmd == SUBACK: return self._handle_suback() elif cmd == UNSUBACK: return self._handle_unsuback() elif cmd == DISCONNECT and self._protocol == MQTTv5: # only allowed in MQTT 5.0 return self._handle_disconnect() else: # If we don't recognise the command, return an error straight away. self._easy_log(MQTT_LOG_ERR, "Error: Unrecognised command %s", cmd) return MQTT_ERR_PROTOCOL def _handle_pingreq(self): if self._in_packet['remaining_length'] != 0: return MQTT_ERR_PROTOCOL self._easy_log(MQTT_LOG_DEBUG, "Received PINGREQ") return self._send_pingresp() def _handle_pingresp(self): if self._in_packet['remaining_length'] != 0: return MQTT_ERR_PROTOCOL # No longer waiting for a PINGRESP. self._ping_t = 0 self._easy_log(MQTT_LOG_DEBUG, "Received PINGRESP") return MQTT_ERR_SUCCESS def _handle_connack(self): if self._protocol == MQTTv5: if self._in_packet['remaining_length'] < 2: return MQTT_ERR_PROTOCOL elif self._in_packet['remaining_length'] != 2: return MQTT_ERR_PROTOCOL if self._protocol == MQTTv5: (flags, result) = struct.unpack( "!BB", self._in_packet['packet'][:2]) reason = ReasonCodes(CONNACK >> 4, identifier=result) properties = Properties(CONNACK >> 4) properties.unpack(self._in_packet['packet'][2:]) else: (flags, result) = struct.unpack("!BB", self._in_packet['packet']) if self._protocol == MQTTv311: if result == CONNACK_REFUSED_PROTOCOL_VERSION: self._easy_log( MQTT_LOG_DEBUG, "Received CONNACK (%s, %s), attempting downgrade to MQTT v3.1.", flags, result ) # Downgrade to MQTT v3.1 self._protocol = MQTTv31 return self.reconnect() elif (result == CONNACK_REFUSED_IDENTIFIER_REJECTED and self._client_id == b''): self._easy_log( MQTT_LOG_DEBUG, "Received CONNACK (%s, %s), attempting to use non-empty CID", flags, result, ) self._client_id = base62(uuid.uuid4().int, padding=22) return self.reconnect() if result == 0: self._state = mqtt_cs_connected self._reconnect_delay = None if self._protocol == MQTTv5: self._easy_log( MQTT_LOG_DEBUG, "Received CONNACK (%s, %s) properties=%s", flags, reason, properties) else: self._easy_log( MQTT_LOG_DEBUG, "Received CONNACK (%s, %s)", flags, result) # it won't be the first successful connect any more self._mqttv5_first_connect = False with self._callback_mutex: if self.on_connect: flags_dict = {} flags_dict['session present'] = flags & 0x01 with self._in_callback_mutex: try: if self._protocol == MQTTv5: self.on_connect(self, self._userdata, flags_dict, reason, properties) else: self.on_connect( self, self._userdata, flags_dict, result) except Exception as err: self._easy_log( MQTT_LOG_ERR, 'Caught exception in on_connect: %s', err) if not self.suppress_exceptions: raise if result == 0: rc = 0 with self._out_message_mutex: for m in self._out_messages.values(): m.timestamp = time_func() if m.state == mqtt_ms_queued: self.loop_write() # Process outgoing messages that have just been queued up return MQTT_ERR_SUCCESS if m.qos == 0: with self._in_callback_mutex: # Don't call loop_write after _send_publish() rc = self._send_publish( m.mid, m.topic.encode('utf-8'), m.payload, m.qos, m.retain, m.dup, properties=m.properties ) if rc != 0: return rc elif m.qos == 1: if m.state == mqtt_ms_publish: self._inflight_messages += 1 m.state = mqtt_ms_wait_for_puback with self._in_callback_mutex: # Don't call loop_write after _send_publish() rc = self._send_publish( m.mid, m.topic.encode('utf-8'), m.payload, m.qos, m.retain, m.dup, properties=m.properties ) if rc != 0: return rc elif m.qos == 2: if m.state == mqtt_ms_publish: self._inflight_messages += 1 m.state = mqtt_ms_wait_for_pubrec with self._in_callback_mutex: # Don't call loop_write after _send_publish() rc = self._send_publish( m.mid, m.topic.encode('utf-8'), m.payload, m.qos, m.retain, m.dup, properties=m.properties ) if rc != 0: return rc elif m.state == mqtt_ms_resend_pubrel: self._inflight_messages += 1 m.state = mqtt_ms_wait_for_pubcomp with self._in_callback_mutex: # Don't call loop_write after _send_publish() rc = self._send_pubrel(m.mid) if rc != 0: return rc self.loop_write() # Process outgoing messages that have just been queued up return rc elif result > 0 and result < 6: return MQTT_ERR_CONN_REFUSED else: return MQTT_ERR_PROTOCOL def _handle_disconnect(self): packet_type = DISCONNECT >> 4 reasonCode = properties = None if self._in_packet['remaining_length'] > 2: reasonCode = ReasonCodes(packet_type) reasonCode.unpack(self._in_packet['packet']) if self._in_packet['remaining_length'] > 3: properties = Properties(packet_type) props, props_len = properties.unpack( self._in_packet['packet'][1:]) self._easy_log(MQTT_LOG_DEBUG, "Received DISCONNECT %s %s", reasonCode, properties ) self._loop_rc_handle(reasonCode, properties) return MQTT_ERR_SUCCESS def _handle_suback(self): self._easy_log(MQTT_LOG_DEBUG, "Received SUBACK") pack_format = "!H" + str(len(self._in_packet['packet']) - 2) + 's' (mid, packet) = struct.unpack(pack_format, self._in_packet['packet']) if self._protocol == MQTTv5: properties = Properties(SUBACK >> 4) props, props_len = properties.unpack(packet) reasoncodes = [] for c in packet[props_len:]: if sys.version_info[0] < 3: c = ord(c) reasoncodes.append(ReasonCodes(SUBACK >> 4, identifier=c)) else: pack_format = "!" + "B" * len(packet) granted_qos = struct.unpack(pack_format, packet) with self._callback_mutex: if self.on_subscribe: with self._in_callback_mutex: # Don't call loop_write after _send_publish() try: if self._protocol == MQTTv5: self.on_subscribe( self, self._userdata, mid, reasoncodes, properties) else: self.on_subscribe( self, self._userdata, mid, granted_qos) except Exception as err: self._easy_log( MQTT_LOG_ERR, 'Caught exception in on_subscribe: %s', err) if not self.suppress_exceptions: raise return MQTT_ERR_SUCCESS def _handle_publish(self): rc = 0 header = self._in_packet['command'] message = MQTTMessage() message.dup = (header & 0x08) >> 3 message.qos = (header & 0x06) >> 1 message.retain = (header & 0x01) pack_format = "!H" + str(len(self._in_packet['packet']) - 2) + 's' (slen, packet) = struct.unpack(pack_format, self._in_packet['packet']) pack_format = '!' + str(slen) + 's' + str(len(packet) - slen) + 's' (topic, packet) = struct.unpack(pack_format, packet) if self._protocol != MQTTv5 and len(topic) == 0: return MQTT_ERR_PROTOCOL # Handle topics with invalid UTF-8 # This replaces an invalid topic with a message and the hex # representation of the topic for logging. When the user attempts to # access message.topic in the callback, an exception will be raised. try: print_topic = topic.decode('utf-8') except UnicodeDecodeError: print_topic = "TOPIC WITH INVALID UTF-8: " + str(topic) message.topic = topic if message.qos > 0: pack_format = "!H" + str(len(packet) - 2) + 's' (message.mid, packet) = struct.unpack(pack_format, packet) if self._protocol == MQTTv5: message.properties = Properties(PUBLISH >> 4) props, props_len = message.properties.unpack(packet) packet = packet[props_len:] message.payload = packet if self._protocol == MQTTv5: self._easy_log( MQTT_LOG_DEBUG, "Received PUBLISH (d%d, q%d, r%d, m%d), '%s', properties=%s, ... (%d bytes)", message.dup, message.qos, message.retain, message.mid, print_topic, message.properties, len(message.payload) ) else: self._easy_log( MQTT_LOG_DEBUG, "Received PUBLISH (d%d, q%d, r%d, m%d), '%s', ... (%d bytes)", message.dup, message.qos, message.retain, message.mid, print_topic, len(message.payload) ) message.timestamp = time_func() if message.qos == 0: self._handle_on_message(message) return MQTT_ERR_SUCCESS elif message.qos == 1: rc = self._send_puback(message.mid) self._handle_on_message(message) return rc elif message.qos == 2: rc = self._send_pubrec(message.mid) message.state = mqtt_ms_wait_for_pubrel with self._in_message_mutex: self._in_messages[message.mid] = message return rc else: return MQTT_ERR_PROTOCOL def _handle_pubrel(self): if self._protocol == MQTTv5: if self._in_packet['remaining_length'] < 2: return MQTT_ERR_PROTOCOL elif self._in_packet['remaining_length'] != 2: return MQTT_ERR_PROTOCOL mid, = struct.unpack("!H", self._in_packet['packet']) self._easy_log(MQTT_LOG_DEBUG, "Received PUBREL (Mid: %d)", mid) with self._in_message_mutex: if mid in self._in_messages: # Only pass the message on if we have removed it from the queue - this # prevents multiple callbacks for the same message. message = self._in_messages.pop(mid) self._handle_on_message(message) self._inflight_messages -= 1 if self._max_inflight_messages > 0: with self._out_message_mutex: rc = self._update_inflight() if rc != MQTT_ERR_SUCCESS: return rc # FIXME: this should only be done if the message is known # If unknown it's a protocol error and we should close the connection. # But since we don't have (on disk) persistence for the session, it # is possible that we must known about this message. # Choose to acknwoledge this messsage (and thus losing a message) but # avoid hanging. See #284. return self._send_pubcomp(mid) def _update_inflight(self): # Dont lock message_mutex here for m in self._out_messages.values(): if self._inflight_messages < self._max_inflight_messages: if m.qos > 0 and m.state == mqtt_ms_queued: self._inflight_messages += 1 if m.qos == 1: m.state = mqtt_ms_wait_for_puback elif m.qos == 2: m.state = mqtt_ms_wait_for_pubrec rc = self._send_publish( m.mid, m.topic.encode('utf-8'), m.payload, m.qos, m.retain, m.dup, properties=m.properties, ) if rc != 0: return rc else: return MQTT_ERR_SUCCESS return MQTT_ERR_SUCCESS def _handle_pubrec(self): if self._protocol == MQTTv5: if self._in_packet['remaining_length'] < 2: return MQTT_ERR_PROTOCOL elif self._in_packet['remaining_length'] != 2: return MQTT_ERR_PROTOCOL mid, = struct.unpack("!H", self._in_packet['packet'][:2]) if self._protocol == MQTTv5: if self._in_packet['remaining_length'] > 2: reasonCode = ReasonCodes(PUBREC >> 4) reasonCode.unpack(self._in_packet['packet'][2:]) if self._in_packet['remaining_length'] > 3: properties = Properties(PUBREC >> 4) props, props_len = properties.unpack( self._in_packet['packet'][3:]) self._easy_log(MQTT_LOG_DEBUG, "Received PUBREC (Mid: %d)", mid) with self._out_message_mutex: if mid in self._out_messages: msg = self._out_messages[mid] msg.state = mqtt_ms_wait_for_pubcomp msg.timestamp = time_func() return self._send_pubrel(mid) return MQTT_ERR_SUCCESS def _handle_unsuback(self): if self._protocol == MQTTv5: if self._in_packet['remaining_length'] < 4: return MQTT_ERR_PROTOCOL elif self._in_packet['remaining_length'] != 2: return MQTT_ERR_PROTOCOL mid, = struct.unpack("!H", self._in_packet['packet'][:2]) if self._protocol == MQTTv5: packet = self._in_packet['packet'][2:] properties = Properties(UNSUBACK >> 4) props, props_len = properties.unpack(packet) reasoncodes = [] for c in packet[props_len:]: if sys.version_info[0] < 3: c = ord(c) reasoncodes.append(ReasonCodes(UNSUBACK >> 4, identifier=c)) if len(reasoncodes) == 1: reasoncodes = reasoncodes[0] self._easy_log(MQTT_LOG_DEBUG, "Received UNSUBACK (Mid: %d)", mid) with self._callback_mutex: if self.on_unsubscribe: with self._in_callback_mutex: try: if self._protocol == MQTTv5: self.on_unsubscribe( self, self._userdata, mid, properties, reasoncodes) else: self.on_unsubscribe(self, self._userdata, mid) except Exception as err: self._easy_log( MQTT_LOG_ERR, 'Caught exception in on_unsubscribe: %s', err) if not self.suppress_exceptions: raise return MQTT_ERR_SUCCESS def _do_on_disconnect(self, rc, properties=None): with self._callback_mutex: if self.on_disconnect: with self._in_callback_mutex: try: if properties: self.on_disconnect( self, self._userdata, rc, properties) else: self.on_disconnect(self, self._userdata, rc) except Exception as err: self._easy_log( MQTT_LOG_ERR, 'Caught exception in on_disconnect: %s', err) if not self.suppress_exceptions: raise def _do_on_publish(self, mid): with self._callback_mutex: if self.on_publish: with self._in_callback_mutex: try: self.on_publish(self, self._userdata, mid) except Exception as err: self._easy_log( MQTT_LOG_ERR, 'Caught exception in on_publish: %s', err) if not self.suppress_exceptions: raise msg = self._out_messages.pop(mid) msg.info._set_as_published() if msg.qos > 0: self._inflight_messages -= 1 if self._max_inflight_messages > 0: rc = self._update_inflight() if rc != MQTT_ERR_SUCCESS: return rc return MQTT_ERR_SUCCESS def _handle_pubackcomp(self, cmd): if self._protocol == MQTTv5: if self._in_packet['remaining_length'] < 2: return MQTT_ERR_PROTOCOL elif self._in_packet['remaining_length'] != 2: return MQTT_ERR_PROTOCOL packet_type = PUBACK if cmd == "PUBACK" else PUBCOMP packet_type = packet_type >> 4 mid, = struct.unpack("!H", self._in_packet['packet'][:2]) if self._protocol == MQTTv5: if self._in_packet['remaining_length'] > 2: reasonCode = ReasonCodes(packet_type) reasonCode.unpack(self._in_packet['packet'][2:]) if self._in_packet['remaining_length'] > 3: properties = Properties(packet_type) props, props_len = properties.unpack( self._in_packet['packet'][3:]) self._easy_log(MQTT_LOG_DEBUG, "Received %s (Mid: %d)", cmd, mid) with self._out_message_mutex: if mid in self._out_messages: # Only inform the client the message has been sent once. rc = self._do_on_publish(mid) return rc return MQTT_ERR_SUCCESS def _handle_on_message(self, message): matched = False with self._callback_mutex: try: topic = message.topic except UnicodeDecodeError: topic = None if topic is not None: for callback in self._on_message_filtered.iter_match(message.topic): with self._in_callback_mutex: try: callback(self, self._userdata, message) except Exception as err: self._easy_log( MQTT_LOG_ERR, 'Caught exception in user defined callback function %s: %s', callback.__name__, err ) if not self.suppress_exceptions: raise matched = True if matched == False and self.on_message: with self._in_callback_mutex: try: self.on_message(self, self._userdata, message) except Exception as err: self._easy_log( MQTT_LOG_ERR, 'Caught exception in on_message: %s', err) if not self.suppress_exceptions: raise def _thread_main(self): self.loop_forever(retry_first_connection=True) def _reconnect_wait(self): # See reconnect_delay_set for details now = time_func() with self._reconnect_delay_mutex: if self._reconnect_delay is None: self._reconnect_delay = self._reconnect_min_delay else: self._reconnect_delay = min( self._reconnect_delay * 2, self._reconnect_max_delay, ) target_time = now + self._reconnect_delay remaining = target_time - now while (self._state != mqtt_cs_disconnecting and not self._thread_terminate and remaining > 0): time.sleep(min(remaining, 1)) remaining = target_time - time_func() @staticmethod def _proxy_is_valid(p): def check(t, a): return (socks is not None and t in set([socks.HTTP, socks.SOCKS4, socks.SOCKS5]) and a) if isinstance(p, dict): return check(p.get("proxy_type"), p.get("proxy_addr")) elif isinstance(p, (list, tuple)): return len(p) == 6 and check(p[0], p[1]) else: return False def _get_proxy(self): if socks is None: return None # First, check if the user explicitly passed us a proxy to use if self._proxy_is_valid(self._proxy): return self._proxy # Next, check for an mqtt_proxy environment variable as long as the host # we're trying to connect to isn't listed under the no_proxy environment # variable (matches built-in module urllib's behavior) if not (hasattr(urllib_dot_request, "proxy_bypass") and urllib_dot_request.proxy_bypass(self._host)): env_proxies = urllib_dot_request.getproxies() if "mqtt" in env_proxies: parts = urllib_dot_parse.urlparse(env_proxies["mqtt"]) if parts.scheme == "http": proxy = { "proxy_type": socks.HTTP, "proxy_addr": parts.hostname, "proxy_port": parts.port } return proxy elif parts.scheme == "socks": proxy = { "proxy_type": socks.SOCKS5, "proxy_addr": parts.hostname, "proxy_port": parts.port } return proxy # Finally, check if the user has monkeypatched the PySocks library with # a default proxy socks_default = socks.get_default_proxy() if self._proxy_is_valid(socks_default): proxy_keys = ("proxy_type", "proxy_addr", "proxy_port", "proxy_rdns", "proxy_username", "proxy_password") return dict(zip(proxy_keys, socks_default)) # If we didn't find a proxy through any of the above methods, return # None to indicate that the connection should be handled normally return None def _create_socket_connection(self): proxy = self._get_proxy() addr = (self._host, self._port) source = (self._bind_address, self._bind_port) if sys.version_info < (2, 7) or (3, 0) < sys.version_info < (3, 2): # Have to short-circuit here because of unsupported source_address # param in earlier Python versions. return socket.create_connection(addr, timeout=self._keepalive) if proxy: return socks.create_connection(addr, source_address=source, timeout=self._keepalive, **proxy) else: return socket.create_connection(addr, source_address=source, timeout=self._keepalive) # Compatibility class for easy porting from mosquitto.py. class Mosquitto(Client): def __init__(self, client_id="", clean_session=True, userdata=None): super(Mosquitto, self).__init__(client_id, clean_session, userdata) class WebsocketWrapper(object): OPCODE_CONTINUATION = 0x0 OPCODE_TEXT = 0x1 OPCODE_BINARY = 0x2 OPCODE_CONNCLOSE = 0x8 OPCODE_PING = 0x9 OPCODE_PONG = 0xa def __init__(self, socket, host, port, is_ssl, path, extra_headers): self.connected = False self._ssl = is_ssl self._host = host self._port = port self._socket = socket self._path = path self._sendbuffer = bytearray() self._readbuffer = bytearray() self._requested_size = 0 self._payload_head = 0 self._readbuffer_head = 0 self._do_handshake(extra_headers) def __del__(self): self._sendbuffer = None self._readbuffer = None def _do_handshake(self, extra_headers): sec_websocket_key = uuid.uuid4().bytes sec_websocket_key = base64.b64encode(sec_websocket_key) websocket_headers = { "Host": "{self._host:s}:{self._port:d}".format(self=self), "Upgrade": "websocket", "Connection": "Upgrade", "Origin": "https://{self._host:s}:{self._port:d}".format(self=self), "Sec-WebSocket-Key": sec_websocket_key.decode("utf8"), "Sec-Websocket-Version": "13", "Sec-Websocket-Protocol": "mqtt", } # This is checked in ws_set_options so it will either be None, a # dictionary, or a callable if isinstance(extra_headers, dict): websocket_headers.update(extra_headers) elif callable(extra_headers): websocket_headers = extra_headers(websocket_headers) header = "\r\n".join([ "GET {self._path} HTTP/1.1".format(self=self), "\r\n".join("{}: {}".format(i, j) for i, j in websocket_headers.items()), "\r\n", ]).encode("utf8") self._socket.send(header) has_secret = False has_upgrade = False while True: # read HTTP response header as lines byte = self._socket.recv(1) self._readbuffer.extend(byte) # line end if byte == b"\n": if len(self._readbuffer) > 2: # check upgrade if b"connection" in str(self._readbuffer).lower().encode('utf-8'): if b"upgrade" not in str(self._readbuffer).lower().encode('utf-8'): raise WebsocketConnectionError( "WebSocket handshake error, connection not upgraded") else: has_upgrade = True # check key hash if b"sec-websocket-accept" in str(self._readbuffer).lower().encode('utf-8'): GUID = "258EAFA5-E914-47DA-95CA-C5AB0DC85B11" server_hash = self._readbuffer.decode( 'utf-8').split(": ", 1)[1] server_hash = server_hash.strip().encode('utf-8') client_hash = sec_websocket_key.decode('utf-8') + GUID client_hash = hashlib.sha1(client_hash.encode('utf-8')) client_hash = base64.b64encode(client_hash.digest()) if server_hash != client_hash: raise WebsocketConnectionError( "WebSocket handshake error, invalid secret key") else: has_secret = True else: # ending linebreak break # reset linebuffer self._readbuffer = bytearray() # connection reset elif not byte: raise WebsocketConnectionError("WebSocket handshake error") if not has_upgrade or not has_secret: raise WebsocketConnectionError("WebSocket handshake error") self._readbuffer = bytearray() self.connected = True def _create_frame(self, opcode, data, do_masking=1): header = bytearray() length = len(data) mask_key = bytearray(os.urandom(4)) mask_flag = do_masking # 1 << 7 is the final flag, we don't send continuated data header.append(1 << 7 | opcode) if length < 126: header.append(mask_flag << 7 | length) elif length < 65536: header.append(mask_flag << 7 | 126) header += struct.pack("!H", length) elif length < 0x8000000000000001: header.append(mask_flag << 7 | 127) header += struct.pack("!Q", length) else: raise ValueError("Maximum payload size is 2^63") if mask_flag == 1: for index in range(length): data[index] ^= mask_key[index % 4] data = mask_key + data return header + data def _buffered_read(self, length): # try to recv and strore needed bytes wanted_bytes = length - (len(self._readbuffer) - self._readbuffer_head) if wanted_bytes > 0: data = self._socket.recv(wanted_bytes) if not data: raise socket.error(errno.ECONNABORTED, 0) else: self._readbuffer.extend(data) if len(data) < wanted_bytes: raise socket.error(EAGAIN, 0) self._readbuffer_head += length return self._readbuffer[self._readbuffer_head - length:self._readbuffer_head] def _recv_impl(self, length): # try to decode websocket payload part from data try: self._readbuffer_head = 0 result = None chunk_startindex = self._payload_head chunk_endindex = self._payload_head + length header1 = self._buffered_read(1) header2 = self._buffered_read(1) opcode = (header1[0] & 0x0f) maskbit = (header2[0] & 0x80) == 0x80 lengthbits = (header2[0] & 0x7f) payload_length = lengthbits mask_key = None # read length if lengthbits == 0x7e: value = self._buffered_read(2) payload_length, = struct.unpack("!H", value) elif lengthbits == 0x7f: value = self._buffered_read(8) payload_length, = struct.unpack("!Q", value) # read mask if maskbit: mask_key = self._buffered_read(4) # if frame payload is shorter than the requested data, read only the possible part readindex = chunk_endindex if payload_length < readindex: readindex = payload_length if readindex > 0: # get payload chunk payload = self._buffered_read(readindex) # unmask only the needed part if maskbit: for index in range(chunk_startindex, readindex): payload[index] ^= mask_key[index % 4] result = payload[chunk_startindex:readindex] self._payload_head = readindex else: payload = bytearray() # check if full frame arrived and reset readbuffer and payloadhead if needed if readindex == payload_length: self._readbuffer = bytearray() self._payload_head = 0 # respond to non-binary opcodes, their arrival is not guaranteed beacause of non-blocking sockets if opcode == WebsocketWrapper.OPCODE_CONNCLOSE: frame = self._create_frame( WebsocketWrapper.OPCODE_CONNCLOSE, payload, 0) self._socket.send(frame) if opcode == WebsocketWrapper.OPCODE_PING: frame = self._create_frame( WebsocketWrapper.OPCODE_PONG, payload, 0) self._socket.send(frame) if opcode == WebsocketWrapper.OPCODE_BINARY and payload_length > 0: return result else: raise socket.error(EAGAIN, 0) except socket.error as err: if err.errno == errno.ECONNABORTED: self.connected = False return b'' else: # no more data raise def _send_impl(self, data): # if previous frame was sent successfully if len(self._sendbuffer) == 0: # create websocket frame frame = self._create_frame( WebsocketWrapper.OPCODE_BINARY, bytearray(data)) self._sendbuffer.extend(frame) self._requested_size = len(data) # try to write out as much as possible length = self._socket.send(self._sendbuffer) self._sendbuffer = self._sendbuffer[length:] if len(self._sendbuffer) == 0: # buffer sent out completely, return with payload's size return self._requested_size else: # couldn't send whole data, request the same data again with 0 as sent length return 0 def recv(self, length): return self._recv_impl(length) def read(self, length): return self._recv_impl(length) def send(self, data): return self._send_impl(data) def write(self, data): return self._send_impl(data) def close(self): self._socket.close() def fileno(self): return self._socket.fileno() def pending(self): # Fix for bug #131: a SSL socket may still have data available # for reading without select() being aware of it. if self._ssl: return self._socket.pending() else: # normal socket rely only on select() return 0 def setblocking(self, flag): self._socket.setblocking(flag)