def binary_message(self, bytes): """ Returns a :class:`ws4py.messaging.BinaryMessage` instance ready to be built. Convenience method so that the caller doesn't need to import the :class:`ws4py.messaging.BinaryMessage` class itself. """ return BinaryMessage(bytes)
def binary_message(self, bytes): """ Returns a messaging.BinaryMessage instance ready to be built. Convenience method so that the caller doesn't need to import the BinaryMessage class itself. @param text: data to be carried by the message """ return BinaryMessage(bytes)
def receiver(self): """ Parser that keeps trying to interpret bytes it is fed with as incoming frames part of a message. Control message are single frames only while data messages, like text and binary, may be fragmented accross frames. The way it works is by instanciating a framing.Frame object, then running its parser generator which yields how much bytes it requires to performs its task. The stream parser yields this value to its caller and feeds the frame parser. When the frame parser raises StopIteration, the stream parser tries to make sense of the parsed frame. It dispatches the frame's bytes to the most appropriate message type based on the frame's opcode. Overall this makes the stream parser totally agonstic to the data provider. """ running = True while running: frame = Frame() while True: try: bytes = (yield frame.parser.next()) if bytes is None: raise InvalidBytesError() frame.parser.send(bytes) except StopIteration: bytes = frame.body or '' if frame.masking_key and bytes: bytes = frame.unmask(bytes) if frame.opcode == OPCODE_TEXT: if self.message and not self.message.completed: # We got a text frame before we completed the previous one self.errors.append(CloseControlMessage(code=1002)) break try: m = TextMessage(bytes.decode("utf-8")) m.completed = (frame.fin == 1) self.message = m except UnicodeDecodeError: self.errors.append(CloseControlMessage(code=1007)) break elif frame.opcode == OPCODE_BINARY: m = BinaryMessage(bytes) m.completed = (frame.fin == 1) self.message = m elif frame.opcode == OPCODE_CONTINUATION: m = self.message if m is None: self.errors.append(CloseControlMessage(code=1002)) break m.completed = (frame.fin == 1) if m.opcode == OPCODE_TEXT: try: m.extend(bytes.decode("utf-8")) except UnicodeDecodeError: self.errors.append(CloseControlMessage(code=1007)) break else: m.extend(bytes) elif frame.opcode == OPCODE_CLOSE: self.closing = CloseControlMessage(reason=bytes.decode("utf-8", "replace")) elif frame.opcode == OPCODE_PING: self.pings.append(PingControlMessage(bytes)) elif frame.opcode == OPCODE_PONG: self.pongs.append(PongControlMessage(bytes)) else: self.errors.append(CloseControlMessage(code=1003)) # When the frame's payload is empty, we must yield # once more so that the caller is properly aligned if not bytes: yield 0 break except ProtocolException: self.errors.append(CloseControlMessage(code=1002)) except FrameTooLargeException: self.errors.append(CloseControlMessage(code=1004)) except StreamClosed: running = False break frame.parser.close()
def receiver(self): """ Parser that keeps trying to interpret bytes it is fed with as incoming frames part of a message. Control message are single frames only while data messages, like text and binary, may be fragmented accross frames. The way it works is by instanciating a :class:`wspy.framing.Frame` object, then running its parser generator which yields how much bytes it requires to performs its task. The stream parser yields this value to its caller and feeds the frame parser. When the frame parser raises :exc:`StopIteration`, the stream parser tries to make sense of the parsed frame. It dispatches the frame's bytes to the most appropriate message type based on the frame's opcode. Overall this makes the stream parser totally agonstic to the data provider. """ utf8validator = Utf8Validator() running = True frame = None while running: frame = Frame() while 1: try: some_bytes = (yield next(frame.parser)) frame.parser.send(some_bytes) except GeneratorExit: running = False break except StopIteration: frame._cleanup() some_bytes = frame.body # Let's avoid unmasking when there is no payload if some_bytes: if frame.masking_key and self.expect_masking: some_bytes = frame.unmask(some_bytes) elif not frame.masking_key and self.expect_masking: msg = CloseControlMessage( code=1002, reason='Missing masking when expected') self.errors.append(msg) break elif frame.masking_key and not self.expect_masking: msg = CloseControlMessage( code=1002, reason='Masked when not expected') self.errors.append(msg) break else: # If we reach this stage, it's because # the frame wasn't masked and we didn't expect # it anyway. Therefore, on py2k, the bytes # are actually a str object and can't be used # in the utf8 validator as we need integers # when we get each byte one by one. # Our only solution here is to convert our # string to a bytearray. some_bytes = bytearray(some_bytes) if frame.opcode == OPCODE_TEXT: if self.message and not self.message.completed: # We got a text frame before we completed the previous one msg = CloseControlMessage( code=1002, reason= 'Received a new message before completing previous' ) self.errors.append(msg) break m = TextMessage(some_bytes) m.completed = (frame.fin == 1) self.message = m if some_bytes: is_valid, end_on_code_point, _, _ = utf8validator.validate( some_bytes) if not is_valid or (m.completed and not end_on_code_point): self.errors.append( CloseControlMessage( code=1007, reason='Invalid UTF-8 bytes')) break elif frame.opcode == OPCODE_BINARY: if self.message and not self.message.completed: # We got a text frame before we completed the previous one msg = CloseControlMessage( code=1002, reason= 'Received a new message before completing previous' ) self.errors.append(msg) break m = BinaryMessage(some_bytes) m.completed = (frame.fin == 1) self.message = m elif frame.opcode == OPCODE_CONTINUATION: m = self.message if m is None: self.errors.append( CloseControlMessage( code=1002, reason='Message not started yet')) break m.extend(some_bytes) m.completed = (frame.fin == 1) if m.opcode == OPCODE_TEXT: if some_bytes: is_valid, end_on_code_point, _, _ = utf8validator.validate( some_bytes) if not is_valid or (m.completed and not end_on_code_point): self.errors.append( CloseControlMessage( code=1007, reason='Invalid UTF-8 bytes')) break elif frame.opcode == OPCODE_CLOSE: code = 1005 reason = "" if frame.payload_length == 0: self.closing = CloseControlMessage(code=1005) elif frame.payload_length == 1: self.closing = CloseControlMessage( code=1005, reason='Payload has invalid length') else: try: # at this stage, some_bytes have been unmasked # so actually are held in a bytearray code = int( unpack("!H", bytes(some_bytes[0:2]))[0]) except struct.error: reason = 'Failed at decoding closing code' else: # Those codes are reserved or plainly forbidden if code not in VALID_CLOSING_CODES and not ( 2999 < code < 5000): reason = 'Invalid Closing Frame Code: %d' % code code = 1005 elif frame.payload_length > 1: reason = some_bytes[ 2:] if frame.masking_key else frame.body[ 2:] if not py3k: reason = bytearray(reason) is_valid, end_on_code_point, _, _ = utf8validator.validate( reason) if not is_valid or not end_on_code_point: self.errors.append( CloseControlMessage( code=1007, reason='Invalid UTF-8 bytes')) break reason = bytes(reason) self.closing = CloseControlMessage(code=code, reason=reason) elif frame.opcode == OPCODE_PING: self.pings.append(PingControlMessage(some_bytes)) elif frame.opcode == OPCODE_PONG: self.pongs.append(PongControlMessage(some_bytes)) else: self.errors.append(CloseControlMessage(code=1003)) break except ProtocolException: self.errors.append(CloseControlMessage(code=1002)) break except FrameTooLargeException: self.errors.append( CloseControlMessage(code=1002, reason="Frame was too large")) break frame._cleanup() frame.body = None frame = None if self.message is not None and self.message.completed: utf8validator.reset() utf8validator.reset() utf8validator = None self._cleanup()
def test_receive_message_invalid(mocker): mocker.patch( 'autosubliminal.core.websocket.WebSocketHandler.handle_message') handler = WebSocketHandler(None) handler.received_message(BinaryMessage(b'')) handler.handle_message.assert_not_called()
def receiver(self): """ Parser that keeps trying to interpret bytes it is fed with as incoming frames part of a message. Control message are single frames only while data messages, like text and binary, may be fragmented accross frames. The way it works is by instanciating a framing.Frame object, then running its parser generator which yields how much bytes it requires to performs its task. The stream parser yields this value to its caller and feeds the frame parser. When the frame parser raises StopIteration, the stream parser tries to make sense of the parsed frame. It dispatches the frame's bytes to the most appropriate message type based on the frame's opcode. Overall this makes the stream parser totally agonstic to the data provider. """ utf8validator = Utf8Validator() running = True while running: frame = Frame() while True: try: bytes = (yield frame.parser.next()) if bytes is None: raise InvalidBytesError() frame.parser.send(bytes) except StopIteration: bytes = frame.body or '' if frame.masking_key and bytes: bytes = frame.unmask(bytes) if frame.opcode == OPCODE_TEXT: if self.message and not self.message.completed: # We got a text frame before we completed the previous one self.errors.append(CloseControlMessage(code=1002)) break is_valid, _, _, _ = utf8validator.validate(bytes) if is_valid or (not is_valid and frame.fin == 0): m = TextMessage(bytes) m.completed = (frame.fin == 1) self.message = m elif not is_valid and frame.fin == 1: self.errors.append(CloseControlMessage(code=1007)) elif frame.opcode == OPCODE_BINARY: m = BinaryMessage(bytes) m.completed = (frame.fin == 1) self.message = m elif frame.opcode == OPCODE_CONTINUATION: m = self.message if m is None: self.errors.append(CloseControlMessage(code=1002)) break m.completed = (frame.fin == 1) if m.opcode == OPCODE_TEXT: is_valid, _, _, _ = utf8validator.validate(bytes) if is_valid: m.extend(bytes) else: self.errors.append(CloseControlMessage(code=1007)) #except UnicodeDecodeError: # self.errors.append(CloseControlMessage(code=1007)) # break else: m.extend(bytes) elif frame.opcode == OPCODE_CLOSE: code = 1000 reason = "" if len(bytes) == 0: self.errors.append(CloseControlMessage(code=1000)) elif 1 < len(bytes) < 126: code = struct.unpack("!H", str(bytes[0:2]))[0] try: code = int(code) except TypeError: code = 1002 reason = 'Invalid Closing Frame Code Type' else: # Those codes are reserved or plainly forbidden if code < 1000 or code in [1004, 1005, 1006, 1012, 1013, 1014, 1015, 1016, 1100, 2000, 2999, 5000, 65536]: code = 1002 reason = 'Invalid Closing Frame Code' else: if len(bytes) > 2: try: reason = frame.body[2:].decode("utf-8") except UnicodeDecodeError: code = 1007 reason = '' self.closing = CloseControlMessage(code=code, reason=reason) else: self.errors.append(CloseControlMessage(code=1002)) elif frame.opcode == OPCODE_PING: self.pings.append(PingControlMessage(bytes)) elif frame.opcode == OPCODE_PONG: self.pongs.append(PongControlMessage(bytes)) else: self.errors.append(CloseControlMessage(code=1003)) # When the frame's payload is empty, we must yield # once more so that the caller is properly aligned if not bytes: yield 0 break except ProtocolException: self.errors.append(CloseControlMessage(code=1002)) except FrameTooLargeException: self.errors.append(CloseControlMessage(code=1002)) except StreamClosed: running = False break frame.parser.close() utf8validator.reset() utf8validator = None
def receiver(self): """ Parser that keeps trying to interpret bytes it is fed with as incoming frames part of a message. Control message are single frames only while data messages, like text and binary, may be fragmented accross frames. The way it works is by instanciating a :class:`wspy.framing.Frame` object, then running its parser generator which yields how much bytes it requires to performs its task. The stream parser yields this value to its caller and feeds the frame parser. When the frame parser raises :exc:`StopIteration`, the stream parser tries to make sense of the parsed frame. It dispatches the frame's bytes to the most appropriate message type based on the frame's opcode. Overall this makes the stream parser totally agonstic to the data provider. """ utf8validator = Utf8Validator() running = True frame = None while running: frame = Frame() while 1: try: bytes = (yield frame.parser.next()) frame.parser.send(bytes) except StopIteration: frame._cleanup() bytes = frame.body or '' # Let's avoid unmasking when there is no payload if bytes: if frame.masking_key and self.expect_masking: bytes = frame.unmask(bytes) elif not frame.masking_key and self.expect_masking: msg = CloseControlMessage( code=1002, reason='Missing masking when expected') self.errors.append(msg) break elif frame.masking_key and not self.expect_masking: msg = CloseControlMessage( code=1002, reason='Masked when not expected') self.errors.append(msg) break else: bytes = bytearray(bytes) if frame.opcode == OPCODE_TEXT: if self.message and not self.message.completed: # We got a text frame before we completed the previous one msg = CloseControlMessage( code=1002, reason= 'Received a new message before completing previous' ) self.errors.append(msg) break m = TextMessage(bytes) m.completed = (frame.fin == 1) self.message = m if bytes: is_valid, end_on_code_point, _, _ = utf8validator.validate( bytes) if not is_valid or (m.completed and not end_on_code_point): self.errors.append( CloseControlMessage( code=1007, reason='Invalid UTF-8 bytes')) break elif frame.opcode == OPCODE_BINARY: m = BinaryMessage(bytes) m.completed = (frame.fin == 1) self.message = m elif frame.opcode == OPCODE_CONTINUATION: m = self.message if m is None: self.errors.append( CloseControlMessage( code=1002, reason='Message not started yet')) break m.extend(bytes) m.completed = (frame.fin == 1) if m.opcode == OPCODE_TEXT: if bytes: is_valid, end_on_code_point, _, _ = utf8validator.validate( bytes) if not is_valid or (m.completed and not end_on_code_point): self.errors.append( CloseControlMessage( code=1007, reason='Invalid UTF-8 bytes')) break elif frame.opcode == OPCODE_CLOSE: code = 1000 reason = "" if frame.payload_length == 0: self.closing = CloseControlMessage(code=1000) elif frame.payload_length == 1: self.closing = CloseControlMessage( code=1002, reason='Payload has invalid length') else: try: code = int( struct.unpack("!H", str(bytes[0:2]))[0]) except TypeError: code = 1002 reason = 'Invalid Closing Frame Code Type' except struct.error, sr: code = 1002 reason = 'Failed at decoding closing code' else: # Those codes are reserved or plainly forbidden if code not in VALID_CLOSING_CODES and not ( 2999 < code < 5000): reason = 'Invalid Closing Frame Code: %d' % code code = 1002 elif frame.payload_length > 1: reason = bytes[ 2:] if frame.masking_key else bytearray( frame.body[2:]) is_valid, end_on_code_point, _, _ = utf8validator.validate( reason) if not is_valid or not end_on_code_point: self.errors.append( CloseControlMessage( code=1007, reason='Invalid UTF-8 bytes')) break self.closing = CloseControlMessage( code=code, reason=reason.decode('utf-8')) elif frame.opcode == OPCODE_PING: self.pings.append(PingControlMessage(bytes)) elif frame.opcode == OPCODE_PONG: self.pongs.append(PongControlMessage(bytes))
def opened(self): rospy.loginfo(">> Websocket Opened") for req in paramToRead: p = BinaryMessage(packet_tools.build_read_request("TX", req)) self.send(p)