Modbus Communication API

From SoftMC-Wiki
Revision as of 06:53, 2 May 2016 by Omri (talk | contribs) (Getting Started)
Jump to: navigation, search

Contents

Overview

Basic Overview

  • This describes how to set up Modbus communication for the softMC, and how to generate softMC scripts to handle Modbus communication.
  • It is assumed you are familiar with the principles of Modbus communication, although some of them will be described in this page.
  • It is also assumed your are familiar with the softMC, ControlStudio and MC-Basic programming.

Modbus Communication Background

  • A Motion Controller (MC) can act as a server (slave), a client (master) or both at the same time.
  • Each MC connection (TCP/RTU) can be used either as a server component (if the connection is used by the MC’s server-side) or as a client component (if the connection is used by the MC’s client-side).
  • Each component has its own parameters that defines it.
  • When the MC acts as a server, all server components share the same memory address space, thus acting as one server with multiple connections.
  • Each server (slave) on a Modbus network has its own deviceID, which is a number between 1 and 247.

The Modbus server registers

  • There are 4 types of registers in the Modbus Server address space:
    1. Bits (1-bit registers)
    2. Input Bits (1-bit READ-ONLY registers)
    3. Holding Registers (16-bit registers)
    4. Input Registers (16-bit READ-ONLY registers)
  • Servers can read and write their own address space.
  • Clients can read and write a remote server’s address space.

Getting Started

In order to get started in using the Modbus features:

  1. Download the required files, according to your system's type:
  2. Using the ControlStudio File Manager, Upload the following files to your MC:
    • mb_x86.O (for softMC7 ) / mb_armA9.O (for softMC3)
    • Modbus.lib
    • MB_Load.prg
    modbus;newAPI-upload.jpg
  3. Load MB_Load.prg by typing:
    Load MB_Load.prg
    This will load the mb_x86.O / mb_armA9.O, depending on your current system, along with the Modbus.LIB Library file.
  4. Alternatively, you can load the Object file and the Modbus library manually, by typing:
    Oload mb_x86.O
#: Loadglobal Modbus.LIB.

That's it! You're now ready to configure the Modbus system.

Initializing a Modbus Server

To initialize the Modbus server address space, call:

?init_multi_server([bits],[input_bits],[holding registers],[input_registers])
  • The function prints "success" and returns 0 on success, or return an error code on failure.
  • Notice: You can call this method only if there are no active server components.

Error codes:

Error Meaning
-1 Memory allocation failure.
-2 Some servers are still running and using an already mapped address space.
-3 Failed to create a modbus mapping.

Server Components

Adding server components

  • Each time you'll add a component, you will receive a handle, which is the component's identifier (for later use).
  • It is best to keep this handles in variables inside your program.

Creating a TCP server component

handle = mb_tcp_server_create([port],[deviceID])
  • This opens a TCP connection to the server on port [port] with deviceID [deviceID], and starts the created server immediately.
  • Returns a handle on success, or an error code on failure.

Error codes:

Error Meaning
-1 Server address spaces isn't initialized yet, please call "init_multi_server(...) and try again.
-2 Failed to create main socket.
-3 Failed to connect.
-4 Failed to create server thread.

Creating an RTU server component

handle = mb_rtu_server_create([type],[port],[baudrate],[data bits],[stop bits],[parity],[deviceID])
  • This opens an RTU connection with the given parameters, and starts the created server immediately.
  • Returns a handle on success, or an error code on failure.

Error codes:

Error Meaning
-1 Server address spaces isn't initialized yet, please call "init_multi_server(...) and try again.
-2 Invalid device string.
-3 Invalid parity.
-4 Failed opening RTU.
-5 Failed allocating query buffer memory.
-6 Failed to set RTU mode.
-7 Unable to connect.
-8 Failed to create server thread.
-9 The device is already in use by another system component.

Stopping Server Components

Stopping a specific server component

You can stop a specific server component by passing its handle to:

result = mb_server_stop([handle])
  • Given a handle, this will stop and free the memory of the appropriate server component.
  • Returns 0 on success, -1 on failure.

Stopping all server components

You can stop all server components with a single call to:

result = mb_server_stop_all

This function will:

  • Stop and free all server components.
  • Free the shared address space.
  • Return 0 on success, -1 on failure.

Client Components

Adding client components

  • Each time you'll add a component, you will receive a handle, which is the component's identifier (for later use).
  • It is best to keep this handles in variables inside your program.

Adding a TCP Client component

handle = mb_tcp_client_create([ip],[port])
  • This will opens a TCP connection to the client on the given ip and port, and start the client immediately.
  • Returns a handle on success, -1 on failure.

Adding an RTU Client component

handle = mb_rtu_client_create([type],[port],[baudrate],[data bits],[stop bits],[parity])
  • This will open an RTU connection to the client with the given parameters, and start the client immediately.
  • Returns a handle on success, -1 on failure.

Stopping client components

A specific client can be stopped by calling:

result = mb_client_stop([handle])
  • Given a handle, this will stop and free the memory of the appropriate client component.
  • Returns 0 on success, -1 on failure.

Reset the Modbus System

Sometimes, a user may wish to stop all server and client components at once, and reset the Modbus system (for example, when a user want to initialize a different Modbus system). To do that, call:

result = mb_reset

This function:

  • Stops all running servers and clients.
  • Frees their memory.
  • Frees the shared address space.
  • Reset the handle counter.
  • Returns 0 on success, -1 on failure.

Reading and Writing

  • Servers can read and write their own address space.
  • Clients can read and write a remote server’s address space.
  • Therefore, Servers and clients use different functions to read/write data from the address space.

Server Components


Reading

  • The following functions read variables from the different types of registers and return them.
  • When a read error occurs, the functions will write [function name] + "ERROR" + [error code] in the Message Log.
Reading from Holding registers
Val = MB_SERVER_READ_REG_LONG([index], [byte_swap], [word_swap])
Val = MB_SERVER_READ_REG_SHORT([index], [byte_swap])
Val = MB_SERVER_READ_REG_FLOAT([index], [byte_swap], [word_swap])
Val = MB_SERVER_READ_REG_DOUBLE([index], [byte_swap], [word_swap], [long swap])
Reading from Bits registers
val = MB_SERVER_READ_BIT([index])
Reading from Input registers
Val = MB_SERVER_READ_INREG_LONG([index], [byte_swap], [word_swap])
Val = MB_SERVER_READ_INREG_SHORT([index], [byte_swap])
Val = MB_SERVER_READ_INREG_FLOAT([index], [byte_swap], [word_swap])
Val = MB_SERVER_READ_INREG_DOUBLE([index], [byte_swap], [word_swap], [long swap])
Reading from Input Bits registers
 val = MB_SERVER_READ_INBIT([index])
Valid Parameters
Parameter Valid Input
Index From 0 to the number of registers available.
Byte_swap 1 or 0 (True/False)
Word_swap 1 or 0 (True/False)
Long_swap 1 or 0 (True/False)

Writing

  • The following functions write data into the different types of registers.
  • When a write error occurs, the functions will write [function name] + "ERROR" + [error code] in the Message Log.
Writing to holding registers
Val = MB_SERVER_WRITE_REG_LONG([index],[new value],[byte swap], [word swap])
Val = MB_SERVER_WRITE_REG_SHORT([index],[new value],[byte swap])
Val = MB_SERVER_WRITE_REG_FLOAT([index],[new value],[byte swap], [word swap])
Val = MB_SERVER_WRITE_REG_DOUBLE([index],[new value],[byte swap], [word swap], [long swap])
Writing to Bits registers
val = MB_SERVER_WRITE_BIT([index],[new value])
Writing to Input registers
Val = MB_SERVER_WRITE_INREG_LONG([index],[new value],[byte swap], [word swap])
Val = MB_SERVER_WRITE_INREG_SHORT([index],[new value],[byte swap])
Val = MB_SERVER_WRITE_INREG_FLOAT([index],[new value],[byte swap], [word swap])
Val = MB_SERVER_WRITE_INREG_DOUBLE([index],[new value],[byte swap], [word swap], [long swap])
Writing to Input Bits registers
val = MB_SERVER_WRITE_INBIT([index],[value])
Valid Parameters
Parameter Valid Input
Index From 0 to the number of registers available.
New value The value to write, must be from the appropriate type.
Byte_swap 1 or 0 (True/False)
Word_swap 1 or 0 (True/False)
Long_swap 1 or 0 (True/False)

Error codes

Error Meaning
-1 Invalid index.
-2 Local server's address space isn't mapped yet.
-3 Failed to catch the register mutex.
-4 Failed to release the register mutex.

Client Components


Reading

  • The following functions read variables from the different types of registers in a REMOTE modbus server.
  • The read value is inserted into an existing variable from the appropriate type (long/double).
  • The functions return 0 on success or an error code (not 0) on failure.
Reading from Holding registers
Val = MB_CLIENT_READ_REG_LONG([handle],[deviceID],[addr],[dest ptr])
Val = MB_CLIENT_READ_REG_SHORT([handle],[deviceID],[addr],[dest ptr])
Val = MB_CLIENT_READ_REG_FLOAT([handle],[deviceID],[addr],[dest ptr])
Val = MB_CLIENT_READ_REG_DOUBLE([handle],[deviceID],[addr],[dest ptr])
Reading from Bits registers
val = MB_CLIENT_READ_BITS ([handle],[deviceID],[addr],[num of bits],[dest arr ptr])
Reading from Input registers
Val = MB_CLIENT_READ_INREG_LONG ([handle],[deviceID],[addr],[dest ptr]) 
Val = MB_CLIENT_READ_INREG_SHORT([handle],[deviceID],[addr],[dest ptr])
Val = MB_CLIENT_READ_INREG_FLOAT([handle],[deviceID],[addr],[dest ptr])
Val = MB_CLIENT_READ_INREG_DOUBLE([handle],[deviceID],[addr],[dest ptr])
Reading from Input Bits registers
val = MB_CLIENT_READ_INBITS ([handle],[deviceID],[addr],[num of bits],[dest arr ptr])
Valid Parameters
Parameter Valid Input
Handle The client's unique identifier (received on client creation).
DeviceID The remote server(slave)'s device ID.
Addr The index of the register to read from.
Num of bits (Reading bits) The number of bits to read.
dest ptr / dest arr ptr The variable to store the read data. When reading bits, this must be an array of longs in the appropriate size (>= Num of bits).

Writing

  • The following functions write data from existing variables to the different types of registers in a REMOTE modbus server.
  • The functions return 0 on success or an error code (not 0) on failure.
Writing to Holding registers
Val = MB_CLIENT_WRITE_REG_LONG([handle],[deviceID],[addr],[src ptr])
Val = MB_CLIENT_WRITE_REG_SHORT([handle],[deviceID],[addr],[src ptr])
Val = MB_CLIENT_WRITE_REG_FLOAT([handle],[deviceID],[addr],[src ptr])
Val = MB_CLIENT_WRITE_REG_DOUBLE([handle],[deviceID],[addr],[src ptr])
Writing to Bits registers
val = MB_CLIENT_WRITE_BIT([handle],[deviceID],[addr],[src ptr])
Valid Parameters
Parameter Valid Input
Handle The client's unique identifier (received on client creation).
DeviceID The remote server(slave)'s device ID.
Addr The index of the register to start writing to.
src ptr The variable that stores the data to be written. This must be a variable from the appropriate type.

Reading and Writing Summary

modbus;newAPI-readwriteSummary.jpg


Modbus Configurator

Background

General

The Modbus Communication Scripts Generator (Modbus Configurator) is a tool that allows you to map your softMC application variables to Modbus tags.

Note: Tag access is defined from the HMI perspective. In other words:

  • Read Access variables are written by the softMC to the Modbus address space.
  • Write Access variables are read by the softMC from the Modbus address space.

You can define whether a variable has Read Access, or Write Access. Currently, it is not possible to define a variable as having both Read Access and Write Access. However, all Write Access variables can be written once by the softMC upon system startup by a special routine that is generated in HMIMBMAP.LIB (see section below).

The MCMBConfigurator creates three files:

  • HMIMBMAP.LIB and HMIMBMAP.PRG files are MC-Basic scripts that are used to start a softMC task. These are default file names, which you can change, but must retain the 8.3 format. This task cyclically and indefinitely reads/writes Modbus tags according to access type.
  • A .CSV format file that can be used by an HMI development environment, such as JMobile Studio or Indusoft, to automatically import Modbus tags. You define the HMI development environment by selecting various Python scripts that will generate the .csv file.

Mapping Variables

  • Variables destined to be mapped to Modbus tags must be defined as global variables by the common Shared declaration.
  • In order to map the variables, the program must be loaded in the softMC.

Getting Started

  1. Start the Modbus Configurator: from the ControlStudio toolbar, select Tools > Modbus Configurator. The Modbus Configurator tool will appear.
  2. From the top menu, Select Connection > Setting.
  3. Enter the MC's IP and port (default connection port is 5001), then click OK.
  4. From the top menu, Select Connection > Connect.
  5. Configure the Modbus Address Space
    1. From the top menu, Select Modbus Comm. Settings.
    2. In the General tab, Select the appropriate python script.
    3. In the Registers tab, enter the amount of registers needed per type, and the registers offset (Optional).
      • Notice: The maximum register number is 65536.
    4. In the Connections tab, add the server connections (TCP/RTU).
    5. Click OK.
  6. Map your variables
    • Once the Modbus Configurator is connected to softMC it gets updated with the complete list of all the global variables. Double-clicking on variables automatically maps them to Modbus tags in consecutive order. The automatic Modbus address and data type are displayed in the table, along with the Modbus address space area in which the data will be stored (Default: Holding Registers).
    • If a mapped variable is defined as CONST, its access type will automatically set to "Read". In such instances the access type cannot be changed. "Read Access variables are read only by the HMI; therefore the softMC only writes them to the Modbus address space.
    • If a mapped variable is not defined as CONST, it automatically appears with "Write" Access. Double-click on the access type to toggle the variable between Read Access and Write Access, and thus determine whether the variable will be read or written by softMC.

softMC Modbus HMI (4).png

Generating and Using Scripts

After you are done mapping variables and defining the access types, a snapshot of the current configuration must be saved in order to generate the Modbus-handling scripts.

1. Click Files, and then Save As.

The mapping is saved in an .mbas file.
If you makes changes after saving the .mbas file, the MBAS file indicator in the status bar will light up.

2. To generate the product files, click Generate.

The Log windows will display Success messages.
The product files were created in the target folder you chose when saving the .mbas file.
The files HMIMBMAP.LIB and HMIMBMAP.PRG will automatically open in ControlStudio.

softMC Modbus HMI (5).png


Using the Modbus-Handling Scripts

1. Using the ControlStudio File Manager, copy HMIMBMAP.LIB and HMIMBMAP.PRG to the softMC.

Note: Before these files can be loaded and used, your application must be loaded, and all mapped variables must exist in the softMC memory.

softMC Modbus HMI (6).png

1. Using the ControlStudio Terminal, load the library HMIMBMAP.LIB:

Load HMIMBMAP.LIB
Since HMIMBMAP.PRG imports this library it must not be loaded globally. This code can be executed wherever is convenient.

2. Verify that the library was loaded successfully:

?tasklist

3. Start the Modbus communication task by loading the program:

Load HMIMBMAP.PRG

HMIMBMAP.PRG is defined as Program Continue, therefore it starts automatically after it is loaded and it does not require an explicit StartTask command.

Of course, HMIMBMAP.PRG can be loaded and executed only after HMIMBMAP.LIB is loaded. Therefore, you should add the following code to AUTOEXEC.PRG or wherever is convenient:

Load HMIMBMAP.LIB
Load HMIMBMAP.PRG

HMIMBMAP.PRG Explained

The code:

import HMIMBMAP.LIB
Program Continue
	dim retVal as long = 0
	retVal = Init_Modbus
	while 1
		retVal = Read_Modbus_Registers
		retVal = Write_Modbus_Registers
		sleep 1
	end while
End Program

The functions Init_Modbus, Read_Modbus_Registers and Write_Modbus_Registers are implemented in HMIMBMAP.LIB, which is automatically generated by a Python script.

The function Init_Modbus starts the Modbus server and then writes to the Modbus address space all the Write Access Variables (i.e., all the variables read by the softMC from the Modbus address space). This feature allows you to setup the system to start with an initialized Modbus address space before the HMI/PLC connects to it. The HMI/PLC can read the address space and initialize itself accordingly.

The functions Read_Modbus_Registers and Write_Modbus_Registers are invoked cyclically and indefinitely. Read_Modbus_Registers reads all the tags that are written by the HMI/PLC and updates the Write Access variables with new values, while Write_Modbus_Registers does the opposite.

HMI IDEs and .CSV Files

Each line in the .csv file generated by the MCMBConfigurator file holds data about a single variable, such as Modbus address or data type.

This data can be used by an HMI IDE to import Modbus tags and associate them with HMI functionality.

Different manufacturer IDEs use different .csv formatting; therefore, various Python scripts are used to create the specific .csv files suitable for a particular manufacturer IDE.

JMobile Studio

Python script: JMobile_csv.py

Default target .csv file name: JMobile_HMI.csv (user-definable)

To import tags, perform the following procedure in JMobile Studio.

Define Protocol

1. In the ProjectView pane, select Protocols.

2. Click the blue + sign.

3. From the list, select Modbus TCP.

4. In the Modbus TCP configuration window, define:

IP Address: Set the IP address of your softMC.
PLC Models: Select Generic Modbus (0-based), meaning the softMC Modbus server starts addressing tags from 0.
Click OK.

softMC Modbus HMI (7).png

Import Tags

1. In the ProjectView pane, select Tags.

2. From the list, select Modbus TCP protocol defined previously.

softMC Modbus HMI (8).png

3. Click the Import Tags button.

4. Open the generated file JMobile_HMI.csv.

softMC Modbus HMI (9).png

5. Select the tags you want to add to your project, and click the Import tags button.

softMC Modbus HMI (10).png

AdvancedHMI

AdvancedHMI is an open source project (http://www.advancedhmi.com/), which is downloaded as a Visual Basic project. You can then open the project, add widgets, compile, and run it.

softMC Modbus HMI (11).png

1. Drag and drop ModbusTCPCom into MainForm.vb [Design].

2. The driver appears the bottom of the screen (circled in green).

Click the driver, and then use the Properties pane (circled in red) to setup the IP address of the Modbus server.
For example, drag and drop DigitalPanelMeter and MomentaryButton into MainForm.vb [Design].

softMC Modbus HMI (12).png

3. For both widgets, use the Properties pane to set the Modbus address that is associated with the variables from the softMC application.

softMC Modbus HMI (13).png

Note:

MC Modbus server addressing starts from 40000.
AdvancedHMI Modbus client addressing starts from 40001.
Prefix the address with the letter L.

4. Save the project (Ctrl+S).

5. Build the project (Ctrl+Shift+B).

6. Run the project (F5).