#!/usr/bin/env python # -*- encoding: utf-8 -*- from __future__ import with_statement import struct import threading import re from utils.modbus import LOGGER from utils.modbus import defines from utils.modbus.exceptions import ( ModbusError, ModbusFunctionNotSupportedError, DuplicatedKeyError, MissingKeyError, InvalidModbusBlockError, InvalidArgumentError, OverlapModbusBlockError, OutOfModbusBlockError, ModbusInvalidResponseError, ModbusInvalidRequestError ) from utils.modbus.hooks import call_hooks from utils.modbus.utils import threadsafe_function, get_log_buffer class Query(object): def __init__(self): pass def build_request(self, pdu, slave): raise NotImplementedError() def parse_response(self, response): raise NotImplementedError() def parse_request(self, request): raise NotImplementedError() def build_response(self, response_pdu): raise NotImplementedError() class Master(object): def __init__(self, timeout_in_sec, hooks=None): self._timeout = timeout_in_sec self._verbose = False self._is_opened = False def __del__(self): self.close() def set_verbose(self, verbose): self._verbose = verbose def open(self): if not self._is_opened: self._do_open() self._is_opened = True def close(self): if self._is_opened: ret = self._do_close() if ret: self._is_opened = False def _do_open(self): raise NotImplementedError() def _do_close(self): raise NotImplementedError() def _send(self, buf): raise NotImplementedError() def _recv(self, expected_length): raise NotImplementedError() def _make_query(self): raise NotImplementedError() @threadsafe_function def execute( self, slave, function_code, starting_address, quantity_of_x=0, output_value=0, data_format="", expected_length=-1, write_starting_address_fc23=0, number_file=None, pdu="" ): """ Execute a modbus query and returns the data part of the answer as a tuple The returned tuple depends on the query function code. see modbus protocol specification for details data_format makes possible to extract the data like defined in the struct python module documentation For function Read_File_Record starting_address, quantity_of_x, number_file must be tuple () of one long (by the number of requested sub_seq) the result will be ((sub _ seq_0 _ data), (sub_seq_1_data),... (sub_seq_N_data)). """ is_read_function = False nb_of_digits = 0 if number_file is None: number_file = tuple() # open the connection if it is not already done self.open() # Build the modbus pdu and the format of the expected data. # It depends of function code. see modbus specifications for details. if function_code == defines.READ_COILS or function_code == defines.READ_DISCRETE_INPUTS: is_read_function = True pdu = struct.pack(">BHH", function_code, starting_address, quantity_of_x) byte_count = quantity_of_x // 8 if (quantity_of_x % 8) > 0: byte_count += 1 nb_of_digits = quantity_of_x if not data_format: data_format = ">" + (byte_count * "B") if expected_length < 0: # No length was specified and calculated length can be used: # slave + func + bytcodeLen + bytecode + crc1 + crc2 expected_length = byte_count + 5 elif function_code == defines.READ_INPUT_REGISTERS or function_code == defines.READ_HOLDING_REGISTERS: is_read_function = True pdu = struct.pack(">BHH", function_code, starting_address, quantity_of_x) if not data_format: data_format = ">" + (quantity_of_x * "H") if expected_length < 0: # No length was specified and calculated length can be used: # slave + func + bytcodeLen + bytecode x 2 + crc1 + crc2 expected_length = 2 * quantity_of_x + 5 elif function_code == defines.READ_FILE_RECORD: is_read_function = True if ( isinstance(number_file, tuple) and isinstance(starting_address, tuple) and isinstance(quantity_of_x, tuple) and len(number_file) == len(starting_address) == len(quantity_of_x) > 0 ): count_seq = len(number_file) else: raise ModbusInvalidRequestError( 'For function READ_FILE_RECORD param' 'starting_address, quantity_of_x, number_file must be tuple()' 'of one length > 0 (by the number of requested sub_seq)' ) pdu = struct.pack(">BB", function_code, count_seq * 7) + b''.join(map(lambda zip_param: struct.pack(">BHHH", *zip_param), zip(count_seq * (6, ), number_file, starting_address, quantity_of_x))) if not data_format: data_format = ">BB" + 'BB'.join(map(lambda x: x * 'H', quantity_of_x)) if expected_length < 0: # No length was specified and calculated length can be used: # slave + func + bytcodeLen + (byteLenSubReq+byteref+bytecode[] x 2)*countSubReq + crc1 + crc2 expected_length = 2 * sum(quantity_of_x) + 2 * count_seq + 5 elif (function_code == defines.WRITE_SINGLE_COIL) or (function_code == defines.WRITE_SINGLE_REGISTER): if function_code == defines.WRITE_SINGLE_COIL: if output_value != 0: output_value = 0xff00 fmt = ">BHH" else: fmt = ">BH" + ("H" if output_value >= 0 else "h") pdu = struct.pack(fmt, function_code, starting_address, output_value) if not data_format: data_format = ">HH" if expected_length < 0: # No length was specified and calculated length can be used: # slave + func + adress1 + adress2 + value1+value2 + crc1 + crc2 expected_length = 8 elif function_code == defines.WRITE_MULTIPLE_COILS: byte_count = len(output_value) // 8 if (len(output_value) % 8) > 0: byte_count += 1 pdu = struct.pack(">BHHB", function_code, starting_address, len(output_value), byte_count) i, byte_value = 0, 0 for j in output_value: if j > 0: byte_value += pow(2, i) if i == 7: pdu += struct.pack(">B", byte_value) i, byte_value = 0, 0 else: i += 1 if i > 0: pdu += struct.pack(">B", byte_value) if not data_format: data_format = ">HH" if expected_length < 0: # No length was specified and calculated length can be used: # slave + func + adress1 + adress2 + outputQuant1 + outputQuant2 + crc1 + crc2 expected_length = 8 elif function_code == defines.WRITE_MULTIPLE_REGISTERS: if output_value and data_format: byte_count = struct.calcsize(data_format) else: byte_count = 2 * len(output_value) pdu = struct.pack(">BHHB", function_code, starting_address, byte_count // 2, byte_count) if output_value and data_format: pdu += struct.pack(data_format, *output_value) else: for j in output_value: fmt = "H" if j >= 0 else "h" pdu += struct.pack(">" + fmt, j) # data_format is now used to process response which is always 2 registers: # 1) data address of first register, 2) number of registers written data_format = ">HH" if expected_length < 0: # No length was specified and calculated length can be used: # slave + func + adress1 + adress2 + outputQuant1 + outputQuant2 + crc1 + crc2 expected_length = 8 elif function_code == defines.READ_EXCEPTION_STATUS: pdu = struct.pack(">B", function_code) data_format = ">B" if expected_length < 0: # No length was specified and calculated length can be used: expected_length = 5 elif function_code == defines.DIAGNOSTIC: # SubFuncCode are in starting_address pdu = struct.pack(">BH", function_code, starting_address) if len(output_value) > 0: for j in output_value: # copy data in pdu pdu += struct.pack(">B", j) if not data_format: data_format = ">" + (len(output_value) * "B") if expected_length < 0: # No length was specified and calculated length can be used: # slave + func + SubFunc1 + SubFunc2 + Data + crc1 + crc2 expected_length = len(output_value) + 6 elif function_code == defines.READ_WRITE_MULTIPLE_REGISTERS: is_read_function = True byte_count = 2 * len(output_value) pdu = struct.pack( ">BHHHHB", function_code, starting_address, quantity_of_x, write_starting_address_fc23, len(output_value), byte_count ) for j in output_value: fmt = "H" if j >= 0 else "h" # copy data in pdu pdu += struct.pack(">" + fmt, j) if not data_format: data_format = ">" + (quantity_of_x * "H") if expected_length < 0: # No length was specified and calculated length can be used: # slave + func + bytcodeLen + bytecode x 2 + crc1 + crc2 expected_length = 2 * quantity_of_x + 5 elif function_code == defines.RAW: # caller has to set arguments "pdu", "expected_length", and "data_format" pass elif function_code == defines.DEVICE_INFO: # is_read_function = True mei_type = 0x0E pdu = struct.pack( ">BBBB", # function_code = 43 (0x2B) # MEI Type = 0x0E (Read Device Identification) # output_value[0] = Read Device ID code # output_value[1] = Object Id function_code, mei_type, output_value[0], output_value[1] ) else: raise ModbusFunctionNotSupportedError("The {0} function code is not supported. ".format(function_code)) # instantiate a query which implements the MAC (TCP or RTU) part of the protocol query = self._make_query() # add the mac part of the protocol to the request request = query.build_request(pdu, slave) # send the request to the slave retval = call_hooks("modbus.Master.before_send", (self, request)) if retval is not None: request = retval if self._verbose: LOGGER.debug(get_log_buffer("-> ", request)) self._send(request) call_hooks("modbus.Master.after_send", (self, )) if slave != 0: # receive the data from the slave response = self._recv(expected_length) retval = call_hooks("modbus.Master.after_recv", (self, response)) if retval is not None: response = retval if self._verbose: LOGGER.debug(get_log_buffer("<- ", response)) # extract the pdu part of the response response_pdu = query.parse_response(response) # analyze the received data (return_code, byte_2) = struct.unpack(">BB", response_pdu[0:2]) if return_code > 0x80: # the slave has returned an error exception_code = byte_2 raise ModbusError(exception_code) else: if is_read_function: # get the values returned by the reading function byte_count = byte_2 data = response_pdu[2:] if byte_count != len(data): # the byte count in the pdu is invalid raise ModbusInvalidResponseError( "Byte count is {0} while actual number of bytes is {1}. ".format(byte_count, len(data)) ) elif function_code == defines.DEVICE_INFO: data = response_pdu[1:] data_format = ">" + (len(data) * "B") else: # returns what is returned by the slave after a writing function data = response_pdu[1:] # returns the data as a tuple according to the data_format # (calculated based on the function or user-defined) if (re.match("[>]?[sp]?", data_format)): # result = data.decode() result = data else: result = struct.unpack(data_format, data) if nb_of_digits > 0: digits = [] for byte_val in result: for i in range(8): if len(digits) >= nb_of_digits: break digits.append(byte_val % 2) byte_val = byte_val >> 1 result = tuple(digits) if function_code == defines.READ_FILE_RECORD: sub_seq = list() ptr = 0 while ptr < len(result): sub_seq += ((ptr + 2, ptr + 2 + result[ptr] // 2), ) ptr += result[ptr] // 2 + 2 result = tuple(map(lambda sub_seq_x: result[sub_seq_x[0]:sub_seq_x[1]], sub_seq)) return result def set_timeout(self, timeout_in_sec): """Defines a timeout on the MAC layer""" self._timeout = timeout_in_sec def get_timeout(self): """Gets the current value of the MAC layer timeout""" return self._timeout class ModbusBlock(object): def __init__(self, starting_address, size, name=''): self.starting_address = starting_address self._data = [0] * size self.size = len(self._data) def is_in(self, starting_address, size): if starting_address > self.starting_address: return (self.starting_address + self.size) > starting_address elif starting_address < self.starting_address: return (starting_address + size) > self.starting_address return True def __getitem__(self, item): return self._data.__getitem__(item) def __setitem__(self, item, value): call_hooks("modbus.ModbusBlock.setitem", (self, item, value)) return self._data.__setitem__(item, value) class Slave(object): def __init__(self, slave_id, unsigned=True, memory=None): self._id = slave_id self.unsigned = unsigned self._blocks = {} if memory is None: self._memory = { defines.COILS: [], defines.DISCRETE_INPUTS: [], defines.HOLDING_REGISTERS: [], defines.ANALOG_INPUTS: [], } else: self._memory = memory self._data_lock = threading.RLock() self._fn_code_map = { defines.READ_COILS: self._read_coils, defines.READ_DISCRETE_INPUTS: self._read_discrete_inputs, defines.READ_INPUT_REGISTERS: self._read_input_registers, defines.READ_HOLDING_REGISTERS: self._read_holding_registers, defines.READ_EXCEPTION_STATUS: self._read_exception_status, defines.WRITE_SINGLE_COIL: self._write_single_coil, defines.WRITE_SINGLE_REGISTER: self._write_single_register, defines.WRITE_MULTIPLE_COILS: self._write_multiple_coils, defines.WRITE_MULTIPLE_REGISTERS: self._write_multiple_registers, defines.READ_WRITE_MULTIPLE_REGISTERS: self._read_write_multiple_registers, } def _get_block_and_offset(self, block_type, address, length): for block in self._memory[block_type]: if address >= block.starting_address: offset = address - block.starting_address if block.size >= offset + length: return block, offset raise ModbusError(defines.ILLEGAL_DATA_ADDRESS) def _read_digital(self, block_type, request_pdu): (starting_address, quantity_of_x) = struct.unpack(">HH", request_pdu[1:5]) if (quantity_of_x <= 0) or (quantity_of_x > 2000): # maximum allowed size is 2000 bits in one reading raise ModbusError(defines.ILLEGAL_DATA_VALUE) block, offset = self._get_block_and_offset(block_type, starting_address, quantity_of_x) values = block[offset: offset + quantity_of_x] # pack bits in bytes byte_count = quantity_of_x // 8 if (quantity_of_x % 8) > 0: byte_count += 1 # write the response header response = struct.pack(">B", byte_count) i, byte_value = 0, 0 for coil in values: if coil: byte_value += (1 << i) if i >= 7: # write the values of 8 bits in a byte response += struct.pack(">B", byte_value) # reset the counters i, byte_value = 0, 0 else: i += 1 # if there is remaining bits: add one more byte with their values if i > 0: fmt = "B" if self.unsigned else "b" response += struct.pack(">" + fmt, byte_value) return response def _read_coils(self, request_pdu): """handle read coils modbus function""" call_hooks("modbus.Slave.handle_read_coils_request", (self, request_pdu)) return self._read_digital(defines.COILS, request_pdu) def _read_discrete_inputs(self, request_pdu): """handle read discrete inputs modbus function""" call_hooks("modbus.Slave.handle_read_discrete_inputs_request", (self, request_pdu)) return self._read_digital(defines.DISCRETE_INPUTS, request_pdu) def _read_registers(self, block_type, request_pdu): """read the value of holding and input registers""" (starting_address, quantity_of_x) = struct.unpack(">HH", request_pdu[1:5]) if (quantity_of_x <= 0) or (quantity_of_x > 125): # maximum allowed size is 125 registers in one reading LOGGER.debug("quantity_of_x is %d", quantity_of_x) raise ModbusError(defines.ILLEGAL_DATA_VALUE) # look for the block corresponding to the request block, offset = self._get_block_and_offset(block_type, starting_address, quantity_of_x) # get the values values = block[offset: offset + quantity_of_x] # write the response header response = struct.pack(">B", 2 * quantity_of_x) # add the values of every register on 2 bytes for reg in values: fmt = "H" if self.unsigned else "h" response += struct.pack(">" + fmt, reg) return response def _read_holding_registers(self, request_pdu): """handle read coils modbus function""" call_hooks("modbus.Slave.handle_read_holding_registers_request", (self, request_pdu)) return self._read_registers(defines.HOLDING_REGISTERS, request_pdu) def _read_input_registers(self, request_pdu): """handle read coils modbus function""" call_hooks("modbus.Slave.handle_read_input_registers_request", (self, request_pdu)) return self._read_registers(defines.ANALOG_INPUTS, request_pdu) def _read_exception_status(self, request_pdu): """handle read exception status modbus function""" call_hooks("modbus.Slave.handle_read_exception_status_request", (self, request_pdu)) response = struct.pack(">B", 0) return response def _read_write_multiple_registers(self, request_pdu): """execute modbus function 23""" call_hooks("modbus.Slave.handle_read_write_multiple_registers_request", (self, request_pdu)) # get the starting address and the number of items from the request pdu (starting_read_address, quantity_of_x_to_read, starting_write_address, quantity_of_x_to_write, byte_count_to_write) = struct.unpack(">HHHHB", request_pdu[1:10]) # read part if (quantity_of_x_to_read <= 0) or (quantity_of_x_to_read > 125): # maximum allowed size is 125 registers in one reading LOGGER.debug("quantity_of_x_to_read is %d", quantity_of_x_to_read) raise ModbusError(defines.ILLEGAL_DATA_VALUE) # look for the block corresponding to the request block, offset = self._get_block_and_offset(defines.HOLDING_REGISTERS, starting_read_address, quantity_of_x_to_read) # get the values values = block[offset: offset + quantity_of_x_to_read] # write the response header response = struct.pack(">B", 2 * quantity_of_x_to_read) # add the values of every register on 2 bytes for reg in values: fmt = "H" if self.unsigned else "h" response += struct.pack(">" + fmt, reg) # write part if (quantity_of_x_to_write <= 0) or (quantity_of_x_to_write > 123) or (byte_count_to_write != (quantity_of_x_to_write * 2)): # maximum allowed size is 123 registers in one reading raise ModbusError(defines.ILLEGAL_DATA_VALUE) # look for the block corresponding to the request block, offset = self._get_block_and_offset(defines.HOLDING_REGISTERS, starting_write_address, quantity_of_x_to_write) count = 0 for i in range(quantity_of_x_to_write): count += 1 fmt = "H" if self.unsigned else "h" block[offset + i] = struct.unpack(">" + fmt, request_pdu[10 + 2 * i:12 + 2 * i])[0] return response def _write_multiple_registers(self, request_pdu): """execute modbus function 16""" call_hooks("modbus.Slave.handle_write_multiple_registers_request", (self, request_pdu)) # get the starting address and the number of items from the request pdu (starting_address, quantity_of_x, byte_count) = struct.unpack(">HHB", request_pdu[1:6]) if (quantity_of_x <= 0) or (quantity_of_x > 123) or (byte_count != (quantity_of_x * 2)): # maximum allowed size is 123 registers in one reading raise ModbusError(defines.ILLEGAL_DATA_VALUE) # look for the block corresponding to the request block, offset = self._get_block_and_offset(defines.HOLDING_REGISTERS, starting_address, quantity_of_x) count = 0 for i in range(quantity_of_x): count += 1 fmt = "H" if self.unsigned else "h" block[offset + i] = struct.unpack(">" + fmt, request_pdu[6 + 2 * i: 8 + 2 * i])[0] return struct.pack(">HH", starting_address, count) def _write_multiple_coils(self, request_pdu): """execute modbus function 15""" call_hooks("modbus.Slave.handle_write_multiple_coils_request", (self, request_pdu)) # get the starting address and the number of items from the request pdu (starting_address, quantity_of_x, byte_count) = struct.unpack(">HHB", request_pdu[1:6]) expected_byte_count = quantity_of_x // 8 if (quantity_of_x % 8) > 0: expected_byte_count += 1 if (quantity_of_x <= 0) or (quantity_of_x > 1968) or (byte_count != expected_byte_count): # maximum allowed size is 1968 coils raise ModbusError(defines.ILLEGAL_DATA_VALUE) # look for the block corresponding to the request block, offset = self._get_block_and_offset(defines.COILS, starting_address, quantity_of_x) count = 0 for i in range(byte_count): if count >= quantity_of_x: break fmt = "B" if self.unsigned else "b" (byte_value, ) = struct.unpack(">" + fmt, request_pdu[6 + i: 7 + i]) for j in range(8): if count >= quantity_of_x: break if byte_value & (1 << j): block[offset + i * 8 + j] = 1 else: block[offset + i * 8 + j] = 0 count += 1 return struct.pack(">HH", starting_address, count) def _write_single_register(self, request_pdu): """execute modbus function 6""" call_hooks("modbus.Slave.handle_write_single_register_request", (self, request_pdu)) fmt = "H" if self.unsigned else "h" (data_address, value) = struct.unpack(">H" + fmt, request_pdu[1:5]) block, offset = self._get_block_and_offset(defines.HOLDING_REGISTERS, data_address, 1) block[offset] = value # returns echo of the command return request_pdu[1:] def _write_single_coil(self, request_pdu): """execute modbus function 5""" call_hooks("modbus.Slave.handle_write_single_coil_request", (self, request_pdu)) (data_address, value) = struct.unpack(">HH", request_pdu[1:5]) block, offset = self._get_block_and_offset(defines.COILS, data_address, 1) if value == 0: block[offset] = 0 elif value == 0xff00: block[offset] = 1 else: raise ModbusError(defines.ILLEGAL_DATA_VALUE) # returns echo of the command return request_pdu[1:] def handle_request(self, request_pdu, broadcast=False): """ parse the request pdu, makes the corresponding action and returns the response pdu """ # thread-safe with self._data_lock: try: retval = call_hooks("modbus.Slave.handle_request", (self, request_pdu)) if retval is not None: return retval # get the function code (function_code, ) = struct.unpack(">B", request_pdu[0:1]) # check if the function code is valid. If not returns error response if function_code not in self._fn_code_map: raise ModbusError(defines.ILLEGAL_FUNCTION) # if read query is broadcasted raises an error cant_be_broadcasted = ( defines.READ_COILS, defines.READ_DISCRETE_INPUTS, defines.READ_INPUT_REGISTERS, defines.READ_HOLDING_REGISTERS ) if broadcast and (function_code in cant_be_broadcasted): raise ModbusInvalidRequestError("Function %d can not be broadcasted" % function_code) # execute the corresponding function response_pdu = self._fn_code_map[function_code](request_pdu) if response_pdu: if broadcast: call_hooks("modbus.Slave.on_handle_broadcast", (self, response_pdu)) LOGGER.debug("broadcast: %s", get_log_buffer("!!", response_pdu)) return "" else: return struct.pack(">B", function_code) + response_pdu raise Exception("No response for function %d" % function_code) except ModbusError as excpt: LOGGER.debug(str(excpt)) call_hooks("modbus.Slave.on_exception", (self, function_code, excpt)) return struct.pack(">BB", function_code + 128, excpt.get_exception_code()) def add_block(self, block_name, block_type, starting_address, size): """Add a new block identified by its name""" # thread-safe with self._data_lock: if size <= 0: raise InvalidArgumentError("size must be a positive number") if starting_address < 0: raise InvalidArgumentError("starting address must be zero or positive number") if block_name in self._blocks: raise DuplicatedKeyError("Block {0} already exists. ".format(block_name)) if block_type not in self._memory: raise InvalidModbusBlockError("Invalid block type {0}".format(block_type)) # check that the new block doesn't overlap an existing block # it means that only 1 block per type must correspond to a given address # for example: it must not have 2 holding registers at address 100 index = 0 for i in range(len(self._memory[block_type])): block = self._memory[block_type][i] if block.is_in(starting_address, size): raise OverlapModbusBlockError( "Overlap block at {0} size {1}".format(block.starting_address, block.size) ) if block.starting_address > starting_address: index = i break # if the block is ok: register it self._blocks[block_name] = (block_type, starting_address) # add it in the 'per type' shortcut self._memory[block_type].insert(index, ModbusBlock(starting_address, size, block_name)) def remove_block(self, block_name): """ Remove the block with the given name. Raise an exception if not found """ # thread safe with self._data_lock: block = self._get_block(block_name) # the block has been found: remove it from the shortcut block_type = self._blocks.pop(block_name)[0] self._memory[block_type].remove(block) def remove_all_blocks(self): """ Remove all the blocks """ # thread safe with self._data_lock: self._blocks.clear() for key in self._memory: self._memory[key] = [] def _get_block(self, block_name): """Find a block by its name and raise and exception if not found""" if block_name not in self._blocks: raise MissingKeyError("block {0} not found".format(block_name)) (block_type, starting_address) = self._blocks[block_name] for block in self._memory[block_type]: if block.starting_address == starting_address: return block raise Exception("Bug?: the block {0} is not registered properly in memory".format(block_name)) def set_values(self, block_name, address, values): """ Set the values of the items at the given address If values is a list or a tuple, the value of every item is written If values is a number, only one value is written """ # thread safe with self._data_lock: block = self._get_block(block_name) # the block has been found # check that it doesn't write out of the block offset = address - block.starting_address size = 1 if isinstance(values, list) or isinstance(values, tuple): size = len(values) if (offset < 0) or ((offset + size) > block.size): raise OutOfModbusBlockError( "address {0} size {1} is out of block {2}".format(address, size, block_name) ) # if Ok: write the values if isinstance(values, list) or isinstance(values, tuple): block[offset: offset + len(values)] = values else: block[offset] = values def get_values(self, block_name, address, size=1): """ return the values of n items at the given address of the given block """ # thread safe with self._data_lock: block = self._get_block(block_name) # the block has been found # check that it doesn't write out of the block offset = address - block.starting_address if (offset < 0) or ((offset + size) > block.size): raise OutOfModbusBlockError( "address {0} size {1} is out of block {2}".format(address, size, block_name) ) # returns the values if size == 1: return tuple([block[offset], ]) else: return tuple(block[offset: offset + size]) class Databank(object): """A databank is a shared place containing the data of all slaves""" def __init__(self, error_on_missing_slave=True): """Constructor""" # the map of slaves by ids self._slaves = {} # protect access to the map of slaves self._lock = threading.RLock() self.error_on_missing_slave = error_on_missing_slave def add_slave(self, slave_id, unsigned=True, memory=None): """Add a new slave with the given id""" with self._lock: if (slave_id <= 0) or (slave_id > 255): raise Exception("Invalid slave id {0}".format(slave_id)) if slave_id not in self._slaves: self._slaves[slave_id] = Slave(slave_id, unsigned, memory) return self._slaves[slave_id] else: raise DuplicatedKeyError("Slave {0} already exists".format(slave_id)) def get_slave(self, slave_id): """Get the slave with the given id""" with self._lock: if slave_id in self._slaves: return self._slaves[slave_id] else: raise MissingKeyError("Slave {0} doesn't exist".format(slave_id)) def remove_slave(self, slave_id): """Remove the slave with the given id""" with self._lock: if slave_id in self._slaves: self._slaves.pop(slave_id) else: raise MissingKeyError("Slave {0} already exists".format(slave_id)) def remove_all_slaves(self): """clean the list of slaves""" with self._lock: self._slaves.clear() def handle_request(self, query, request): """ when a request is received, handle it and returns the response pdu """ request_pdu = "" try: # extract the pdu and the slave id (slave_id, request_pdu) = query.parse_request(request) # get the slave and let him executes the action if slave_id == 0: # broadcast for key in self._slaves: self._slaves[key].handle_request(request_pdu, broadcast=True) return else: try: slave = self.get_slave(slave_id) except MissingKeyError: if self.error_on_missing_slave: raise else: return "" response_pdu = slave.handle_request(request_pdu) # make the full response response = query.build_response(response_pdu) return response except ModbusInvalidRequestError as excpt: # Request is invalid, do not send any response LOGGER.error("invalid request: " + str(excpt)) return "" except MissingKeyError as excpt: # No slave with this ID in server, do not send any response LOGGER.error("handle request failed: " + str(excpt)) return "" except Exception as excpt: call_hooks("modbus.Databank.on_error", (self, excpt, request_pdu)) LOGGER.error("handle request failed: " + str(excpt)) # If the request was not handled correctly, return a server error response func_code = 1 if len(request_pdu) > 0: (func_code, ) = struct.unpack(">B", request_pdu[0:1]) return struct.pack(">BB", func_code + 0x80, defines.SLAVE_DEVICE_FAILURE) class Server(object): """ This class owns several slaves and defines an interface to be implemented for a TCP or RTU server """ def __init__(self, databank=None): """Constructor""" # never use a mutable type as default argument self._databank = databank if databank else Databank() self._verbose = False self._thread = None self._go = None self._make_thread() def _do_init(self): """executed before the server starts: to be overridden""" pass def _do_exit(self): """executed after the server stops: to be overridden""" pass def _do_run(self): """main function of the server: to be overridden""" pass def _make_thread(self): """create the main thread of the server""" self._thread = threading.Thread(target=Server._run_server, args=(self,)) self._go = threading.Event() def set_verbose(self, verbose): """if verbose is true the sent and received packets will be logged""" self._verbose = verbose def get_db(self): """returns the databank""" return self._databank def add_slave(self, slave_id, unsigned=True, memory=None): """add slave to the server""" return self._databank.add_slave(slave_id, unsigned, memory) def get_slave(self, slave_id): """get the slave with the given id""" return self._databank.get_slave(slave_id) def remove_slave(self, slave_id): """remove the slave with the given id""" self._databank.remove_slave(slave_id) def remove_all_slaves(self): """remove the slave with the given id""" self._databank.remove_all_slaves() def _make_query(self): """ Returns an instance of a Query subclass implementing the MAC layer protocol """ raise NotImplementedError() def start(self): """Start the server. It will handle request""" self._go.set() self._thread.start() def stop(self): """stop the server. It doesn't handle request anymore""" if self._thread.is_alive(): self._go.clear() self._thread.join() def _run_server(self): """main function of the main thread""" try: self._do_init() while self._go.isSet(): self._do_run() LOGGER.debug("%s has stopped", self.__class__) self._do_exit() except Exception as excpt: LOGGER.error("server error: %s", str(excpt)) call_hooks("modbus.Server.on_exception", (self, excpt)) # make possible to rerun in future self._make_thread() def _handle(self, request): """handle a received sentence""" if self._verbose: LOGGER.debug(get_log_buffer("-->", request)) # gets a query for analyzing the request query = self._make_query() retval = call_hooks("modbus.Server.before_handle_request", (self, request)) if retval: request = retval response = self._databank.handle_request(query, request) retval = call_hooks("modbus.Server.after_handle_request", (self, response)) if retval: response = retval if response and self._verbose: LOGGER.debug(get_log_buffer("<--", response)) return response