@node-wot/binding-modbus

Modbus Client Protocol Binding of node-wot

Overview

W3C Web of Things (WoT) Protocol Binding for Modbus TCP RFC. This package uses modbus-serial as a low-level client for Modbus TCP. W3C WoT Binding Template for Modbus can be found here.

Current Maintainer(s): @relu91 @fillobotto

Client Example

You can use a code like the following to use the binding. This specific code is interacting with one of the Eclipse Thingweb Test Things at https://github.com/eclipse-thingweb/test-things/tree/main/things/elevator.

// Protocols and Servient
Servient = require("@node-wot/core").Servient;
ModbusClientFactory = require("@node-wot/binding-modbus").ModbusClientFactory;

// create Servient and add Modbus binding
let servient = new Servient();
servient.addClientFactory(new ModbusClientFactory());

async function main() {
    let td = {}; // see https://github.com/eclipse-thingweb/test-things/blob/main/things/elevator/modbus/js/modbus-elevator.td.json

    const WoT = await servient.start();
    const thing = await WoT.consume(td);

    const readData1 = await thing.readProperty("lightSwitch"); // coil
    const readData2 = await thing.readProperty("floorNumber"); // register

    const readValue1 = await readData1.value();
    console.log(readValue1);

    const readValue2 = await readData2.value();
    console.log(readValue2);
}

main();

Binding Information

Protocol specifier

The protocol prefix handled by this binding is modbus+tcp://.

New Form Fields for the Modbus Binding

Note: for further details please refer to the documentation.

modv:function

Specifies which Modbus function should be issued in the requested command. The list of the available functions is the following:

Function ID	Label
1	readCoil
2	readDiscreteInput
3	readHoldingRegisters
4	readInputRegisters
5	writeSingleCoil
6	writeSingleHoldingRegister
15	writeMultipleCoils
16	writeMultipleHoldingRegisters

This list is from the Modbus Binding Template. Function IDs are used on the wire but the labels should be used in a TD as the values of modv:function property.

modv:entity

The Modbus resource the modv:function acts on. It can be filled with the following keywords: Coil, DiscreteInput, InputRegister, HoldingRegister. The client will then determine the right function code to be applied in the Modbus request. Furthermore, it can be used in multi-operation forms where modv:function cannot be used but the correct function is filled based on the default assumptions. See the [example].

Note that when used in conjunction with modv:function, the value of modv:entity property is ignored.

modv:unitID

The physical bus address of the unit targeted by the Modbus request.

modv:address

This property defines the starting address of registers or coils that are meant to be written.

modv:quantity

This property defines the total amount of registers or coils that should be written, beginning with the register specified with the property modv:address.

modv:pollingTime

The polling time used for subscriptions. The client will issue a reading command every modv:pollingTime milliseconds. Note that the reading request timeout can be still controlled using modv:timeout property.

modv:timeout

Timeout in milliseconds of the Modbus request. Default to 1000 milliseconds

URL format

The URL is used to transport all addressing information necessary to describe the MODBUS connection and register addresses. It has the following structure:

modbus+tcp:// <host> [ : <port> ] [/ <unitid> [ / <address> ] [&quantity=<quantity> ] ]

with the following meaning:

• <host> is the hostname or IP address of the MODBUS slave
• <port> is the optional TCP port number used to access the MODBUS slave. Default is 502
• <unitid> is the MODBUS unit id of the MODBUS slave; same as modv:unitID
• <address> is the starting address register number; see modv:address
• <quantity> is the optional number of registers to access. Default is 1; see modv:quantity

When specified URL values override the corresponding form parameter.

DataSchema

The MODBUS binding uses and provides plain binary data for reading and writing. Therefore in most cases, it will be associated with the content type application/octet-stream. Please refer to the description of this codec on how to decode and encode plain register values to/from JavaScript objects (See OctetstreamCodec). Note array and object schema are not supported.

Along with content type application/octet-stream, this protocol binding accepts also an optional byteSeq parameter. byteSeq specifies the endian-ness of the raw byte data being read/written by the MODBUS binding. It follows the notation application/octet-stream;byteSeq=value, where its value can be one of the following:

• BIG_ENDIAN, which is the default value
• LITTLE_ENDIAN
• BIG_ENDIAN_BYTE_SWAP
• LITTLE_ENDIAN_BYTE_SWAP

Note: the list above may be extended in the future.

In particular, the decimal numbers 9545 and 22880 will be encoded as follows:

• BIG_ENDIAN: 25 49 59 60
• LITTLE_ENDIAN: 60 59 49 25
• BIG_ENDIAN_BYTE_SWAP: 49 25 60 59
• LITTLE_ENDIAN_BYTE_SWAP: 59 60 25 49

For register resources, the payload is just the plain sequence of bytes read from or written to the registers. For coils and discrete inputs, the payload is a sequence of bytes, each corresponding to a single coil or discrete input. Each byte contains the value 0 or 1. So the encoder and decoder should work on this series of bytes and does not have to take care about handling the individual bits. Mapping each coil or discrete input to a single property of type boolean works just fine.

Another parameter that can be used in conjunction with application/octet-stream is length. This parameter specifies the length of the payload in bytes. This is useful to indicate the actual length of the payload when reading or writing a sequence of registers. For example, when reading a property using readHoldingRegisters, the payload length can be used to specify the number of registers to be read. Notice that the payload length must always be equal to the number of registers multiplied by the size of the register in bytes.

Security

The protocol does not support security.

Implementation notes

This implementation handles multiple requests to the same slave by serializing and combining them if possible. In the following, the terms request and transaction are used as follows to describe this:

• A request is a read or write request to a resource as issued by a user of the node-wot API.
• A transaction is a Modbus operation and may cover the data of multiple requests.

Combination

When two requests of the same type are issued and these requests cover neighbored registers, then they are combined into a single transaction reading or writing the combined register range. Note that this algorithm is currently rather simple: New requests are just checked if they can be prepended or appended to an existing transaction. If not, a new transaction is created. When a transaction completes, all requests contained in this transaction are completed.

Serialization

Multiple transactions to the same slave are serialized. This means that a new MODBUS transaction is only started when the previous transaction was finished. Transactions are held in a queue and executed in a first-come-first-serve manner.

Combination using the node-wot API

To help the MODBUS binding to perform combination a user of the API should create several requests for neighbor registers and resolve them all together in a single call to Promise.all(), e.g. as follows:

console.info("Creating promise vl1n");
let vl1n = pac3200Thing.readProperty("Voltage/L1N");
console.info("Creating promise vl2n");
let vl2n = pac3200Thing.readProperty("Voltage/L2N");
console.info("Creating promise vl3n");
let vl3n = pac3200Thing.readProperty("Voltage/L3N");

console.info("Resolving all promises");
Promise.all([vl1n, vl2n, vl3n])
    .then((values) => values.forEach((v) => console.info("Voltage = ", await v.value())))
    .catch((reason) => console.warn("Failed ", reason));

This procedure guarantees that the requests are all combined into a single transaction before this transaction is executed. A similar approach can also be used to write multiple properties in a single transaction.

Valid Form Examples

Base read function form

Reads the 8th input register of the unit 1

{
    "href": "modbus+tcp://127.0.0.1:60000/1/8",
    "contentType": "application/octet-stream;length=2",
    "op": ["readproperty"],
    "modv:function": "readInputRegister",
    "modv:timeout": 2000
}

Write/read function form

Read and write the 8th holding register of the unit 1

{
    "href": "modbus+tcp://127.0.0.1:60000/1/8",
    "contentType": "application/octet-stream;length=2",
    "op": ["readproperty", "writeproperty"],
    "modv:entity": "HoldingRegister"
}

Subscribe form

Polls the 8th holding register of the unit 1 every second.

{
    "href": "modbus+tcp://127.0.0.1:60000/1/8",
    "contentType": "application/octet-stream;length=2",
    "op": ["observeproperty"],
    "modv:entity": "HoldingRegister",
    "modv:pollingTime": 1000
}

TODOs

• TEST
• (Modbus Server Protocol Binding)
• Connection pooling
• More sophisticated algorithm for combining requests. Some ideas
  • Not only append or prepend requests to transactions, but also combine transactions which become neighboured later on
  • Impose some limit to the overall number of registers. The MODBUS protocol has such a limit and devices may define even lower values
• When a connection times out, re-connection does not work (see connectionTimeout in modbus-client.ts)
• When a Modbus device is not reachable, scripts using binding-modbus stop working - corresponding error handling is necessary

More Details

See https://github.com/eclipse-thingweb/node-wot/.