Modbus Communication API
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:
- Bits (1-bit registers)
- Input Bits (1-bit READ-ONLY registers)
- Holding Registers (16-bit registers)
- 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:
- Download the required files, according to your system's type:
- Required files for modbus_X86.ZIP.
- Required files for ARM systems.
- Using the ControlStudio File Manager, Upload the following files to your MC:
- mb_x86.O (for X86 Systems) / mb_armA9.O (for ARM Systems)
- Modbus.lib
- Load the files to memory, by typing (in the Terminal):
- Oload mb_x86.O
- loadglobal Modbus.lib
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:
- This is NOT required when softMC does not run a modbus server.
- You can call this method only if no servers are running.
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.
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.
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
Reading from Holding registers
Val = MB_SERVER_READ_REG_LONG(…) Val = MB_SERVER_READ_REG_SHORT(…) Val = MB_SERVER_READ_REG_FLOAT(…) Val = MB_SERVER_READ_REG_DOUBLE(…)
Reading from Bits registers
val = MB_SERVER_READ_BIT([addr])
Reading from Input registers
Val = MB_SERVER_READ_INREG_LONG(…) Val = MB_SERVER_READ_INREG_SHORT(…) Val = MB_SERVER_READ_INREG_FLOAT(…) Val = MB_SERVER_READ_INREG_DOUBLE(…)
Reading from Input Bits registers
val = MB_SERVER_READ_INBIT([addr])
Writing
Writing to holding registers
Val = MB_SERVER_WRITE_REG_LONG(…) Val = MB_SERVER_WRITE_REG_SHORT(…) Val = MB_SERVER_WRITE_REG_FLOAT(…) Val = MB_SERVER_WRITE_REG_DOUBLE(…)
Writing to Bits registers
val = MB_SERVER_WRITE_BIT([addr],[value])
Writing to Input registers
Val = MB_SERVER_WRITE_INREG_LONG(…) Val = MB_SERVER_WRITE_INREG_SHORT(…) Val = MB_SERVER_WRITE_INREG_FLOAT(…) Val = MB_SERVER_WRITE_INREG_DOUBLE(…)
Writing to Input Bits registers
val = MB_SERVER_WRITE_INBIT([addr],[value])
Client Components
Reading
Reading from Holding registers
Val = MB_CLIENT_READ_REG_LONG([handle],[deviceID],[addr],[dest ptr]) Val = MB_CLIENT_READ_REG_SHORT(…) Val = MB_CLIENT_READ_REG_FLOAT(…) Val = MB_CLIENT_READ_REG_DOUBLE(…)
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(…) Val = MB_CLIENT_READ_INREG_FLOAT(…) Val = MB_CLIENT_READ_INREG_DOUBLE(…)
Reading from Input Bits registers
val = MB_CLIENT_READ_INBITS ([handle],[deviceID],[addr],[num of bits],[dest arr ptr])
Writing
Writing to Holding registers
Val = MB_CLIENT_WRITE_REG_LONG([addr],[val ptr],[deviceID]) Val = MB_CLIENT_WRITE_REG_SHORT(…) Val = MB_CLIENT_WRITE_REG_FLOAT(…) Val = MB_CLIENT_WRITE_REG_DOUBLE(…)
Writing to Bits registers
val = MB_CLIENT_WRITE_BIT([addr],[val ptr],[deviceID])