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pymelsec

A Python3 implementation of MELSEC Communication Protocol that allows you to interact with a Mitsubishi PLC. This library was inspired by pymcprotocol, but has been rewritten to have additional features and be more flexible.

Installation

pip3 install pymelsec

Protocol type

pymelsec natively supports MELSEC Communication 3E type. Type 4E is implemented but has not been fully tested.
Type 1C~4C is not supported.

Supported PLC series

  • Q Series
  • L Series
  • QnA Series
  • iQ-L Series
  • iQ-R Series

A and FX series are not supportted because they does not support 3E or 4E type.

How to use pymelsec

1. Set up PLC

You need to open PLC's port for MELSEC Communication by GxWorks2 or GxWorks3 software.

  1. Mitsubishi PLC manuals
    1. Set IP address for PLC.
    2. Set network port for PLC, but default port should be 5007.
Port Number Application
0x1388 (5000) For future extension (For Q series Ethernet modules, this port number is used for "Auto Open UDP Port".)
0x1389 (5001) For future extension (For Q series Ethernet modules, this port number is used for "over UDP/IP and Ethernet module".)
0x138A (5002) For future extension (For Q series Ethernet modules, this port number is used for "over TCP/IP and Ethernet module".)
0x138B (5003) to 0x138D (5005) For future extension
0x138E (5006) MELSOFT communication port (over UDP/IP and CPU module)
0x138F (5007) MELSOFT communication port (over TCP/IP and CPU module)
0x1390 (5008) MELSOFT direct connection port (over CPU module
0x1391 (5009) For future extension

2. Connect and Send Commands

from datetime import datetime
from pymelsec import Type3E, Type4E
from pymelsec.constants import DT
from pymelsec.tag import Tag


__READ_TAGS = [
    Tag(device="X0", type=DT.BIT),      # BIT
    Tag(device="X1", type=DT.BIT),      # BIT
    Tag(device="X2", type=DT.BIT),      # BIT
    Tag(device="X3", type=DT.BIT),      # BIT
    Tag(device="D200", type=DT.SWORD),  # WORD signed
    Tag(device="D201", type=DT.UWORD),  # WORD unsigned
    Tag(device="D202", type=DT.SDWORD), # DWORD signed
    Tag(device="D204", type=DT.UDWORD), # DWORD unsigned
    Tag(device="D206", type=DT.FLOAT),  # FLOAT
    Tag(device="D208", type=DT.DOUBLE), # DOUBLE
    Tag(device="D300", type=DT.SLWORD), # LWORD signed (unofficial)
    Tag(device="D304", type=DT.ULWORD), # LWORD unsigned (unofficial)
]

__WRITE_TAGS = [
    Tag(device="X0", value=0, type=DT.BIT),                     # BIT
    Tag(device="X1", value=1, type=DT.BIT),                     # BIT
    Tag(device="X2", value=0, type=DT.BIT),                     # BIT
    Tag(device="X3", value=1, type=DT.BIT),                     # BIT
    Tag(device="D200", value=-20000, type=DT.SWORD),            # WORD signed
    Tag(device="D201", value=20100, type=DT.UWORD),             # WORD unsigned
    Tag(device="D202", value=-20200000, type=DT.SDWORD),        # DWORD signed
    Tag(device="D204", value=20400000, type=DT.UDWORD),         # DWORD unsigned
    Tag(device="D206", value=-206.206206, type=DT.FLOAT),       # FLOAT
    Tag(device="D208", value=208.208208208208, type=DT.DOUBLE), # DOUBLE
    Tag(device="D300", value=-10000000, type=DT.SLWORD),        # LWORD signed (unofficial)
    Tag(device="D304", value=10000000, type=DT.ULWORD),         # LWORD unsigned (unofficial)
]

__HOST = '192.168.1.15' # REQUIRED
__PORT = 5007           # OPTIONAL: default is 5007
__PLC_TYPE = 'iQ-R'     # OPTIONAL: default is 'Q'
                        #   options: 'L', 'QnA', 'iQ-L', 'iQ-R'

with Type4E(host=__HOST, port=__PORT, plc_type=__PLC_TYPE) as plc:
    """
    Set communication access mode option
        example: read 5 contiguous words starting from "D0" to "D4"

    Args:
        comm_type(str)[Optional]: the communication access mode option
            example: comm_type="binary" (default)
                     comm_type="ascii"
    """
    plc.set_access_opt(comm_type="binary")



    """
    Write mixed devices
        example: write randomly mixed data types

    Args:
        devices(list[Tag])[Required]: list of data class Tag
            example: devices=__WRITE_TAGS
    Returns:
        result(list[Tag]): list of incorrectly defined Tag
            example:
                [
                    Tag(
                        device='X0',
                        value=1,
                        type='X',
                        error=DataTypeError('Data type "X" is not supported.')
                    )
                ]
    Notes:
        look at __WRITE_TAGS to understand named tuple setup
    """
    plc.write(devices=__WRITE_TAGS)



    """
    Read mixed devices
        example: read randomly mixed data types

    Args:
        devices(list[Tag])[Required]: list of data class Tag
            example: devices=__WRITE_TAGS
    Returns:
        result(list[Tag]): list of Tag
            example:
                [
                    Tag(device='X0',value=False,type='BIT',error=''),
                    ...
                    Tag(device='D208',value=208.208208208208,type='DOUBLE',error='')
                ]
    Notes:
        look at __READ_TAGS to understand named tuple setup
        error status shows error reason
            example:
                [
                    Tag(
                        device='X0',
                        value=None,
                        type='X',
                        error=DataTypeError('Data type "X" is not supported.')
                    )
                ]
        to access the fields of each entry in result
            for tag in read_result:
                print((f'device:{tag.device}, '
                        f'value:{tag.value}, '
                        f'data_type:{tag.type}, '
                        f'status:{tag.error}'))
    """
    read_result = plc.read(devices=__READ_TAGS)



    """
    Write a sequence of data types
        example: write 5 consecutive signed words starting at "D100"

    Args:
        ref_device(str)[Required]: the reference device
            example: ref_device="D100"
        read_size(int)[Required]: number of points to read
            example: read_size=5
        data_type(str)[Required]: data type
            example: data_type=DT.SWORD
    Notes:
        look at __READ_TAGS to understand named tuple setup
        error status shows error reason
            example:
                [
                    Tag(
                        device='X0',
                        value=None,
                        type='X',
                        error=DataTypeError('Data type "X" is not supported.')
                    )
                ]
        to access the fields of each entry in result
            for tag in read_result:
                print((f'device:{tag.device}, '
                        f'value:{tag.value}, '
                        f'data_type:{tag.type}, '
                        f'status:{tag.error}'))
    """
    plc.batch_write(
        ref_device="D100",
        values=[-100,100,-1000,1000,10000],
        data_type=DT.SWORD
    )
    # additional examples:
    plc.batch_write(
        ref_device="D100",
        values=[-100.0,100.1,-1000.2,1000.3,10000.4],
        data_type=DT.FLOAT
    )
    # any of these bit representation is valid
    plc.batch_write(
        ref_device="X0",
        values=[False,True,False,True,False],
        data_type=DT.BIT
    )
    plc.batch_write(
        ref_device="X0",
        values=[0,1,0,1,0],
        data_type=DT.BIT
    )
    plc.batch_write(
        ref_device="X0",
        values=[False,1,0,True,0],
        data_type=DT.BIT
    )


    """
    Read a sequence of data types
        example: read 5 consecutive signed words starting at "D100"

    Args:
        ref_device(str)[Required]: the reference device
            example: ref_device="D100"
        read_size(int)[Required]: number of points to read
            example: read_size=5
        data_type(str)[Required]: data type
            example: data_type=DT.SWORD
        bool_encode(bool): encode boolean value when reading bits
            example: bool_encode=False (default)
                     bool_encode=True
        decode(bool): decode data or keep as raw bytes
            example: decode=True (default)
                     decode=False
    Returns:
        result(list[Tag]): list of Tag
            example:
                [
                    Tag(device='D100',value=-100,type='SWORD',error=''),
                    ...
                    Tag(device='D104',value=10000,type='SWORD',error='')
                ]
    Notes:
        look at __READ_TAGS to understand named tuple setup
        error status shows error reason
            example:
                [
                    Tag(
                        device='X0',
                        value=None,
                        type='X',
                        error=DataTypeError('Data type "X" is not supported.')
                    )
                ]
        to access the fields of each entry in result
            for tag in read_result:
                print((f'device:{tag.device}, '
                        f'value:{tag.value}, '
                        f'data_type:{tag.type}, '
                        f'status:{tag.error}'))
    """
    read_result = plc.batch_read(
        ref_device="D100", 
        read_size=5, 
        data_type=DT.SWORD
    )
    # additional examples:
    # read raw bytes
    read_result = plc.batch_read(
        ref_device="D100", 
        read_size=5, 
        data_type=DT.SWORD, 
        decode=False
    )
    # read bits and return type boolean
    read_result = plc.batch_read(
        ref_device="X0", 
        read_size=5, 
        data_type=DT.BIT, 
        bool_encode=True
    )

4. Utility Functions

These commands are available if you connect via Ethernet communication module (E71 module).
If you connect to PLC directly, C059 error returns.

with Type4E(host=__HOST, port=__PORT, plc_type=__PLC_TYPE) as plc:
    """
    Unlock PLC

    Args:
        password(str):          password in clear text to be sent (unencrypted)
            example: password="1234"
        request_input(bool):    enter password interactively instead of hardcoded
            example: request_input=False (default)
                     request_input=True to enter password directly from user input
    Notes:
        Except iQ-R, password is 4 characters.
    """
    plc.remote_unlock(password="1234")
    plc.remote_unlock(password="", request_input=True)



    """
    Lock PLC

    Args:
        password(str)[Optional]:        password in clear text to be sent (unencrypted)
            example: password="1234"
        request_input(bool)[Optional]:  set password interactively instead of hardcoded
            example: request_input=False (default)
                     request_input=True to set password directly from user input
    Notes:
        Except iQ-R, password is 4 characters.
    """
    plc.remote_lock(password="1234")
    plc.remote_lock(request_input=True)



    """
    Set PLC to run

    Args:
        clear_mode(int): clear memory mode
            example: clear_mode=0 (default) do not clear
                     clear_mode=1 clear except latch device
                     clear_mode=2 clear all
        force_exec(bool): Force execution if controlled by other devices.
            example: force_exec=False (default)
                     force_exec=True
    """
    plc.remote_run(clear_mode=2, force_exec=True)



    """
    Set PLC to stop
    """
    plc.remote_stop()



    """
    Clear latched memory

    Notes:
        PLC must be stop when use this command.
    """
    plc.remote_latch_clear()



    """
    Set PLC to pause

    Args:
        force_exec(bool): boolean to signal force execution
    Notes:
        default is False
    """
    plc.remote_pause(force_exec=False)



    """
    Set PLC to be reset

    Notes:
        PLC must be stop when use this command.
    """
    plc.remote_reset()



    """
    Read CPU model

    Returns:
        CPUModel(named tuple): contains fields "name" and "code"
        example: CPUModel(name='R08ENCPU', code='4806')
    Notes:
        to access field name: cpu_model.name (e.g. 'R08ENCPU')
        to access field code: cpu_model.code (e.g. '4806')
    """
    cpu_model = plc.read_cpu_model()



    """
    Read PLC status

    Returns:
        CPUStatus(named tuple): contains fiels "status" and "cause"
        example: CPUStatus(status='Stop', cause='By Error')
    Notes:
        to access field status: cpu_state.status (e.g. 'Stop')
        to access field cause: cpu_state.cause (e.g. 'By Error')
    """
    cpu_state = plc.read_cpu_status()



    """
    Initialize LED display and error information of 
    buffer memory, and recover the supported device.
    """
    plc.error_led_off()



    """
    Turn off indicator error led

    Args:
       channel(int): the channel to control
           example: channel=1 (default) to turn off channel 1
                    channel=2 to turn off channel 2
                    channel=3 to turn off channel 1 & 2
    Notes:
        Channels are only applicable for Q/L series
    """
    plc.indicator_led_off(channel=1)



    """
    Read PLC physical switch status

    Returns:
        status(str): status of the switch
            example: "Run"
    """
    plc_switch_status = plc.read_switch_status()



    """
    Read PLC time

    Returns:
        datetime object
            example: 2022-08-23 00:07:34
    Notes:
        PLC only has precision at seconds level
    """
    plc_time = plc.read_plc_time()



    """
    Synchronize PLC time to PC

    Args:
        utc(bool):  flag to set to UTC time       
            exaple: utc=False   (default) to set to PC time
                    utc=True    to set to UTC time
    Returns:
        PLC time as a datetime object
            example: 2022-08-23 07:18:42.888054
    Notes:
        PLC only has precision at seconds level
    """
    synced_time = plc.sync_plc_time(utc=False)



    """
    Set PLC time

    Args:
        dt(datetime): datetime object
            example: dt=datetime.now()      to use current PC time
                     dt=datetime.utcnow()   to use UTC time
                     dt=datetime(2022, 8, 22, 10, 11, 12)
    Returns:
        The datetime object used
            example: 2022-08-23 07:18:42.888054
    Notes:
        PLC only has precision at seconds level
    """
    set_time = plc.set_plc_time(dt=datetime.now())



    """
    Request loopback test

    Args:
        echo_data(str): payload to be echo'd back.
            example: echo_data='testing'
    Returns:
        LoopbackTest(NamedTuple): the result and its length
            example: LoopbackTest(length=7, data='testing')
    Notes:
        echo_data only accepts ASCII chars
        to access data length: loopback_result.length (e.g. 7)
        to aaccess data string: loopback_result.data (e.g. 'testing')
    """
    loopback_result = plc.loopback_test(echo_data="testing")