An abstraction layer over the modbus protocol
npm install modbusdb
// Create a KEYs for modbus register
// 1 - Discrete Inputs
// 2 - Coils
// 3 - Input Registers
// 4 - Holding Registers
// createRegisterKey(UnitAddress: 1-254, ModbusTable: 1-4, RegisterAddress: 1-65000, BitIndex: 0-15 (optional))
const temperature = createRegisterKey(1, 4, 10) // Unit=1, Table=Holding Registers, Address=10
const speed = createRegisterKey(1, 3, 500) // Unit=1, Table=Input Registers, Address=500
const mode = createRegisterKey(1, 4, 856) // Unit=1, Table=Holding Registers, Address=856
const db = new Modbusdb(...);
// Read multiple values from slave modbus device:
const result = await db.mget([
temperature,
speed,
mode
])
// Write values into modbus device:
const result = await db.mset(
[
[speed, 60],
[mode, 10],
]
)
// That`s it! As easy as possible and developer friendly:)
import { Modbusdb, ModbusSerialDriver, Datamap, createRegisterKey, TypeEnum, ScopeEnum } from "modbusdb";
import ModbusRTU from 'modbus-serial';
const bootstrap = async () => {
const client = new ModbusRTU();
// open connection to a serial port
// await client.connectRTUBuffered("/dev/ttyUSB0", { baudRate: 9600 });
await client.connectTcpRTUBuffered("127.0.0.1", { port: 8502 })
// .... or any possible way in `modbus-serial`
// connection issues are not handled by `modbusdb`
const units = [
{
address: 1,
forceWriteMany: true, // Use 15(0x0f) and 16(0x10) functions for single register, default: false
bigEndian: true, // You can use BigEndian for byte order, default: false
swapWords: false, // This is applicable only for multi-registers types such as int32, float etc, default: false
requestWithGaps: true, // If requesting address 10 and 13 allow to send one request to the device, default: true
maxRequestSize: 32, // How many registers to be requested in one round-trip with device, default: 1
}
];
// 1 -> ScopeEnum.PhysicalState -> Discrete Inputs
// 2 -> ScopeEnum.InternalState -> Coils
// 3 -> ScopeEnum.PhysicalRegister -> Input Registers
// 4 -> ScopeEnum.InternalRegister -> Holding Registers
// Define a schema for a database:
const schema = [
// Every data item has a unique int32 key (like ID), this key depends on unit,table,address...
{
key: createRegisterKey(1, ScopeEnum.InternalRegister, 10), // Encode [unit,table,address,bit index] into a single 32bit integer key
type: TypeEnum.Int16, // default: UInt16
scale: 2, // 123 int will become a float number 1.23, so it means multiply a register value by 10^-2, default: 0
freq: 12 // How often to poll this register, just remember "polling frequency" for now:), default: 0
},
{
key: createRegisterKey(1, ScopeEnum.InternalRegister, 11),
type: TypeEnum.Int32,
freq: 6
},
{
key: createRegisterKey(1, ScopeEnum.PhysicalRegister, 99)
},
{
key: createRegisterKey(1, ScopeEnum.InternalRegister, 15, 2), // Here is a SINGLE third-bit of the register (not coil and not discrete input)
type: TypeEnum.Bit
},
]
const db = new Modbusdb({
driver: new ModbusSerialDriver(client),
datamap: new Datamap(schema, units),
interval: 60, // 60 seconds
timeout: 15, // 15 seconds
roundSize: 12 // interval 60 divided by 12 is 5sec, so every 5 seconds modbusdb will poll for data
// when round size is 12 we can divide interval by 12, and we have six integer "chunks of time" in the given "interval"
// cause 12 has 6 Divisors (https://en.wikipedia.org/wiki/Table_of_divisors)
// ---> time --->
// 0sec |5sec |10sec |15sec|20sec|25sec|....
// |<- round=60sec ->|
// 1-----2-----3-----4-----5-----6-----7-----8-----9-----10-----11-----12
// X-----X-----X-----X-----X-----X-----X-----X-----X------X------X-----X <- polling frequency is 12
// X-----------X-----------X-----------X-----------X-------------X------ <- polling frequency is 6
// X-----------------X-----------------X------------------X------------- <- polling frequency is 4
// X-----------------------X-----------------------X-------------------- <- polling frequency is 3
// X-----------------------------------X-------------------------------- <- polling frequency is 2
// X-------------------------------------------------------------------- <- polling frequency is 1
// X this is when request are made
// so "polling frequency" means how many times request a register in a given "interval"
// this pattern repeats over time :)
})
db.on('tick', () => {
console.log('tick') // this is a round tick, triggered every [interval/roundSize] seconds
});
db.on('response', (t) => {
console.log('transaction', t)
});
db.on('data', (data) => {
console.log('data', data)
});
db.watch() // Start polling (if you wish to)
// request three registers: unit=1, table=HoldingRegister,InputRegister, address=10,11,99
const result = await db.mget([
createRegisterKey(1, ScopeEnum.InternalRegister, 10),
createRegisterKey(1, ScopeEnum.InternalRegister, 11),
createRegisterKey(1, ScopeEnum.PhysicalRegister, 99)
])
console.log('mget result', result)
}
// Start out app:
bootstrap();
- Create documentation
- Add unit tests
- Make more examples