This is an implementation of the OMRON FINS protocol using Node.js. This library allows for rapid development of network based services that need to communicate with FINS capable devices. Utilizing the awesome asynchronous abilities of Node.js communication with large numbers of devices is very fast.
Both UDP and TCP are supported however UDP is preferred because of its low overhead and performance advantages. Although UDP is connectionless this library makes use of software based timeouts and transaction identifiers (SID) to ensure request and response are matched up allowing for better reliability.
This adaption of the library utilises a sequence manager to coordinate callbacks with data responses, providing the ability to clearly understand who called for data when the request returns. All of the commands (listed below) can be called not only with a callback (or an options object with .callback), they also except a tag of any type (typically an object or key) permitting further routing in the users callback. If the options/callback is omitted, the appropriate reply/timeout/error is emitted instead.
When an options object is used in the command function, FINS routing and timeout can also be specified. See the Memory Area Read Command below for an example of using an options object and FINS routing.
This release (and possibly future releases up to V1.0.0) may have breaking changes.
Where possible, I make every attempt to keep things compatible, but sometimes, it becomes obvious a better way is worth the trouble - it happens (sorry) :)
Semantic Versioning 2.0.0 will be followed after V1 however for now, where you see V0.x.y...
x= major / minor changey= patch / bugfix
- CP
- CV
- CS
- CJ
- NJ
- NX NOTE: Not all NX PLCs have FINS support.
- Memory area read (Word and Bit)
- Memory area write (Word and Bit)
- Memory area fill
- Multiple Memory area read
- Memory area transfer
- Controller status read
- Run
- Stop
- CPU UNIT Data read
- CLOCK READ
- CLOCK WRITE
- Node.js (required) - Server side javascript runtime for Windows, Linux and Mac)
- Wireshark (optional) - This will allow you to see and monitor FINS communication
As an example we will be making a directory for our example code and installing the module there:
mkdir helloFins
cd helloFins
npm init
npm install omron-finsRequiring the library:
const fins = require('omron-fins');Create a FinsClient object and pass it:
port- FINS UDP port number as set on the PLCip- IP address of the PLCoptions- An object containing necessary parametersprotocol,timeout,DNA,DA1,DA2,SNA,SA1,SA2,autoConnectNOTE: ifautoConnectisfalse, the connection will not be made at the time of creation. Instead you can callconnect(with override options is desired). This permits an application to instantiate a FinsClient then later connect to PLC1 withtcpprotocol, disconnect, then change the connection to PLC2 withudpprotocol
const options = {timeout: 5000, SA1: 2, DA1: 1, protocol: "udp"}; //protocol can be "udp" or "tcp" only
const IP = '192.168.0.2';
const PORT = 9600;
const client = fins.FinsClient(PORT, IP, options);
// Connecting / disconnecting...
client.connect(); //connect to PLC with options set when the `FinsClient` was created
client.disconnect();
client.connect({"host": "plc_2", "port": 9700, "protocol": "tcp", "timeout": 3000, "DA1": 2}); //connect to different PLC with new options
//NOTE: Calling client.disconnect(); then client.connect(); will simply reconnect using the same connection options last used.Add a reply listener. The msg parameters content will vary depending on the command issued.
.sid- Transaction identifier. Use this to track specific command/ response pairs..request- An object containing values like the parsedaddressobject and the commandcommand.response- An object containing the parsed values from the FINS command including theremotehost,endCodeandendCodeDescription..error- This will normally befalse.Check msg.response.*iftrue.complete- true if the command has completed.values- if the command returns values, they will be here.stats- performance information.tag- the tag value you sent (if any) with the command..timeout- a boolean flag to indicate if a transaction timeout occurred
Example...
client.on('reply', msg){
console.log("Reply from : ", msg.response.remoteHost);
console.log("Sequence ID (SID) : ", msg.sid);
console.log("Requested command : ", msg.request.command);
console.log("Response code : ", msg.response.endCode);
console.log("Response desc : ", msg.response.endCodeDescription);
console.log("Data returned : ", msg.response.values || "");
console.log("Round trip time : ", msg.timeTaken + "ms");
console.log("Your tag : ", msg.tag);
});Finally, call any of the supported commands!
.read(address, count, callback, tag)
address- Memory area and the numerical start address e.g.D100orCIO50.0count- Number of registers to readoptions- Optional options object or a callback(err, msg) => {}(If an options object is provided then a callback can be added to the options object asoptions.callback)tag- Optional tag item that is sent back in the callback method
/* Read 10 registers starting from register 00000 in the DM Memory Area */
.read('D00000',10);
/* Same as above with callback */
client.read('D00000',10,function(err, msg) {
console.log("msg: ", msg);
});
/* Read D00000 from a remote PLC via the connected PLC (likely requires PLC routing table setup) */
const opts = {
timeout: 3000, //set an individual timeout for this transaction
DNA: 5, //remote network 5
DA1: 2, //remote node 2
callback: function(err, msg) {
if(err) console.error(err);
console.log("msg: ", msg);
}
}
client.read('D00000',10, opts, myTag);.write(address, dataToBeWritten, callback, tag)
address- Memory area and the numerical start address e.g.D100orCIO50.0data- An array of values or single valueoptions- Optional options object or a callback(err, msg) => {}(If an options object is provided then a callback can be added to the options object asoptions.callback)tag- Optional tag item that is sent back in the callback method
/* Writes single value of 1337 into DM register 00000 */
.write('D00000',1337)
/* Writes the values 12,34,56 into DM registers 00000 00001 000002 */
.write('D00000',[12,34,56]);
/* Writes 1 0 1 0 to DM0.4, DM0.5, DM0.6 & DM0.7 */
.write('D0.4',[true, false, 1, 0]);
/* Writes the values 12,34,56 into DM registers 00000 00001 000002 and calls back when done */
.write('D00000',[12,34,56], function(msg){
//check msg.timeout and msg.error
console.log(msg.response)
});
/* Same as above with callback */
.write('D00000',[12,34,56],function(err, msg) {
console.log("seq: ", msg);
});.fill(address, value, count, callback, tag)
address- Memory area and the numerical start address e.g.D100orCIO50value- Value to be filledcount- Number of registers to writeoptions- Optional options object or a callback(err, msg) => {}(If an options object is provided then a callback can be added to the options object asoptions.callback)tag- Optional tag item that is sent back in the callback method
/* Writes 1337 in 10 consecutive DM registers from 00100 to 00110 */
.fill('D00100',1337,10);
/* Same as above with callback */
.fill('D00100',1337,10,function(err, msg) {
console.log("msg: ", msg);
});
/* Writes 1111 in 4 consecutive CIO bit registers from CIO5.0 to CIO5.3 */
.fill('CIO5.0',true,4);.readMultiple(addresses, callback, tag)
addresses- Array or CSV of Memory addresses e.g."D10.15,CIO100,E0_100"or["CIO50.0", "D30", "W0.0"]options- Optional options object or a callback(err, msg) => {}(If an options object is provided then a callback can be added to the options object asoptions.callback)tag- Optional tag item that is sent back in the callback method
/* Reads D10.15, CIO100, E0_100 in one transmission*/
.readMultiple("D10.15,CIO100,E0_100");
/* Reads CIO50.0, D30, W0.0 in one transmission*/
.readMultiple(["CIO50.0","D30", "W0.0"],1337,10,function(err, msg) {
console.log("msg: ", msg);
});.transfer(srcAddress, dstAddress, count, callback, tag)
srcAddress- Source Memory address e.g.D100orCIO50dstAddress- Destination Memory address e.g.D200orCI100count- Number of registers to copyoptions- Optional options object or a callback(err, msg) => {}(If an options object is provided then a callback can be added to the options object asoptions.callback)tag- Optional tag item that is sent back in the callback method
/* Copies 10 values from D10 to CIO20*/
.transfer("D10", "CIO20", 10);
/* Copies values from D10 to CIO20 and calls callback with result*/
.transfer("D10", "CIO20", 10, function(err, msg) {
console.log("msg: ", msg);
});.run(callback, tag)
options- Optional options object or a callback(err, msg) => {}(If an options object is provided then a callback can be added to the options object asoptions.callback)tag- Optional tag item that is sent back in the callback method
/* Puts the PLC into Monitor mode */
.run(function(err, msg) {
console.log(err, msg)
});.stop(callback, tag)
options- Optional options object or a callback(err, msg) => {}(If an options object is provided then a callback can be added to the options object asoptions.callback)tag- Optional tag item that is sent back in the callback method
/* Stops program execution by putting the PLC into Program mode */
.stop(function(err, msg) {
console.log(err, msg)
});
.stop();.status(callback, tag)
options- Optional options object or a callback(err, msg) => {}(If an options object is provided then a callback can be added to the options object asoptions.callback)tag- Optional tag item that is sent back in the callback method
.status(function(err, msg) {
console.log(err, msg)
}, tag);
.status();.cpuUnitDataRead(callback, tag)
options- Optional options object or a callback(err, msg) => {}(If an options object is provided then a callback can be added to the options object asoptions.callback)tag- Optional tag item that is sent back in the callback method
.cpuUnitDataRead(function(err, msg) {
console.log(err, msg)
}, tag);
.cpuUnitDataRead();.clockRead(callback, tag)
options- Optional options object or a callback(err, msg) => {}(If an options object is provided then a callback can be added to the options object asoptions.callback)tag- Optional tag item that is sent back in the callback method
.clockRead(function(err, msg) {
console.log(err, msg)
}, tag);
.clockRead();.clockWrite(clock, callback, tag)
clock- An object containing{year,month,day,hour,minute,second,day_of_week}(second & day_of_week are optional)options- Optional options object or a callback(err, msg) => {}(If an options object is provided then a callback can be added to the options object asoptions.callback)tag- Optional tag item that is sent back in the callback method
const clock = {
year: 2021,
month: 12,
day: 25,
hour: 13,
minute: 0,
//second: 30, //optional
// day_of_week: 2, //optional
}
.clockWrite(clock, function(err, msg) {
console.log(err, msg)
}, tag);
.clockWrite(clock);======
A basic example that will demonstrate most of the features for a single client connection.
/* eslint-disable no-unused-vars */
const fins = require('../lib/index'); // << use this when running from src
//const fins = require('omron-fins'); // << use this when running from npm
// Connecting to remote FINS client on port 9600 with timeout of 2s.
// PLC is expected to be at 192.168.1.120 and this PC is expected to be fins node 36 (adjust as required)
//const client = fins.FinsClient(9700,'192.168.1.120', {protocol: "tcp", SA1:36, DA1:120, timeout: 2000});
const client = fins.FinsClient(9600, '192.168.1.120', { protocol: "udp", SA1: 36, DA1: 120, timeout: 2000 });
// Setting up our error listener
client.on('error', function (error, msg) {
console.log("Error: ", error, msg);
});
// Setting up our timeout listener
client.on('timeout', function (host, msg) {
console.log("Timeout: ", host, msg);
});
client.on('open', function (info) {
console.log("open: ", info);
// Setting up the general response listener showing a selection of properties from the `msg`
client.on('reply', function (msg) {
console.log("");
console.log("############# client.on('reply'...) #################");
console.log("Reply from : ", msg.response.remoteHost);
console.log("Sequence ID (SID) : ", msg.sid);
console.log("Requested command : ", msg.request.command);
console.log("Response code : ", msg.response.endCode);
console.log("Response desc : ", msg.response.endCodeDescription);
if (msg.request.command.name == 'cpu-unit-data-read') {
console.log("CPU model : ", msg.response.CPUUnitModel || "");
console.log("CPU version : ", msg.response.CPUUnitInternalSystemVersion || "");
} else {
console.log("Data returned : ", msg.response.values || "");
}
console.log("Round trip time : ", msg.timeTaken + "ms");
console.log("Your tag : ", msg.tag);
console.log("#####################################################");
console.log("");
});
console.log("Read CPU Unit Data ")
client.cpuUnitDataRead(null, { "tagdata": "Calling cpuUnitDataRead" });
// Read 10 registers starting at DM register 0
// a "reply" will be emitted - check general client reply on reply handler
console.log("Read 10 WD from D0")
client.read('D0', 10, null, { "tagdata": "I asked for 10 registers from D0" });
console.log("Read 32 bits from D0.0")
client.read('D0.0', 32, null, { "tagdata": "I asked for 32 bits from D0.0" });
// Read multiple registers using CSV as the address list
// a "reply" will be emitted - check general client reply on reply handler
console.log(`Read multiple addresses "D0,D0.0,D0.1,D0.2,D0.3,W10,D1.15"`)
client.readMultiple('D0,D0.0,D0.1,D0.2,D0.3,W10,D1.15', null, "readMultiple 'D0,D0.0,D0.1,D0.2,D0.3,W10,D1.15'");
// Read multiple registers using an array as the address list
// a "reply" will be emitted - check general client reply on reply handler
console.log(`Read multiple addresses ["D0","D0.0","D0.1","D0.2","W10","D1.15"]`)
client.readMultiple(["D0", "D0.0", "D0.1", "D0.2", "W10", "D1.15"], null, 'readMultiple ["D0","D0.0","D0.1","D0.2","W10","D1.15"]');
// direct callback is useful for getting direct responses to direct requests
var cb = function (err, msg) {
console.log("");
console.log("################ DIRECT CALLBACK ####################");
if (err)
console.error(err);
else
console.log("SID: " + msg.request.sid, msg.request.command.name, msg.request.command.desc, msg.request.command.descExtra, msg.tag || "", msg.response.endCodeDescription);
console.log("#####################################################");
console.log("");
};
//example fill D700~D704 with randomInt. Callback `cb` with the response
let randomInt = parseInt(Math.random() * 1000) + 1;
console.log(`Fill D700~D709 with random number '${randomInt}' - direct callback expected`)
client.fill('D700', randomInt, 10, cb, `set D700~D709 to '${randomInt}'`);
//example Transfer D700~D709 to D710~D719. Callback `cb` with the response
console.log("Transfer D700~D709 to D710~D719 - direct callback expected");
client.transfer('D700', 'D710', 10, cb, "Transfer D700~D709 to D710~D719");
//example Read D700~D719
console.log(`Read D700~D719 - expect ${randomInt}`)
client.read('D700', 20, null, `Read D700~D719 - expect all values to be '${randomInt}'`)
//example Read from other PLC on FINS network (routed to NET:2, NODE:11) D700~D719
console.log(`Read D700~D719 from DNA:2, DA1:11 with individual timeout setting`)
const readRemotePLC_options = {
timeout: 400,
DNA: 2,
DA1: 11,
callback: function (err, msg) {
if (err) {
console.error(err, msg, "Read D700~D719 from DNA: 2, DA1:11")
} else {
console.log(msg, "Read D700~D719 from DNA: 2, DA1:11")
}
}
}
client.read('D700', 20, readRemotePLC_options, `Read D700~D719 from DNA:2, DA1:11`);
//example write 1010 1111 0000 0101 to D700.0~D700.15 - response will be sent to client 'reply' handler
client.write('D700.0', [true, false, 1, 0, "true", true, 1, "1", "false", false, 0, "0", 0, 1, 0, 1], null, "write 1010 1111 0000 0101 to D700");
client.read('D700.0', 16, null, "read D700.0 ~ D700.15 - should contain 1010 1111 0000 0101");
//example tagged data for sending with a status request
const tag = { "source": "system-a", "sendto": "system-b" };
getStatus(tag);
function getStatus(_tag) {
console.log("Get PLC Status...")
client.status(function (err, msg) {
if (err) {
console.error(err, msg);
} else {
//use the tag for post reply routing or whatever you need
console.log("");
console.log("################ STATUS CALLBACK ####################");
console.log(msg.response.status, msg.response.mode, msg.response);
console.log("#####################################################");
console.log("");
}
}, _tag);
}
setTimeout(() => {
console.log("Request PLC change to STOP mode...")
client.stop((err, msg) => {
if (err) {
console.error(err)
} else {
console.log("* PLC should be stopped - check next STATUS CALLBACK")
setTimeout(() => {
getStatus();
}, 150);
}
})
}, 500);
setTimeout(() => {
console.log("Request PLC change to RUN mode...")
client.run((err, msg) => {
if (err) {
console.error(err)
} else {
console.log("* PLC should be running - check next STATUS CALLBACK")
setTimeout(() => {
getStatus();
}, 150);
}
})
}, 2000);
});TODO: Test and update this demo following v0.2.0 breaking changes
Example of instantiating multiple objects to allow for asynchronous communications. Because this code doesn't wait for a response from any client before sending/receiving packets it is incredibly fast. In this example we attempt to read a memory area from a list of remote hosts. Each command will either return with a response or timeout. Every transaction will be recorded to the responses array with the ip as a key and the msg.response.values as the associated value.
If a timeout occurs and you have provided a callback, the msg.timeout flag will be set.
If a timeout occurs and you have not provided a callback, to can get a response by listening for 'timeout' being emitted.
Once the size of the responses array is equal to the number of units we tried to communicate with we know we have gotten a response or timeout from every unit
/* ***************** UNTESTED ***************** */
const fins = require('omron-fins');
const debug = true;
const clients = [];
const responses = {};
/* List of remote hosts can be generated from local or remote resource */
const remoteHosts = [
{ KEY: "PLC1", IP:'192.168.0.1', OPTS: {DA1:1, SA1:99} },
{ KEY: "PLC2", IP:'192.168.0.2', OPTS: {DA1:2, SA1:99} },
{ KEY: "PLC3", IP:'192.168.0.3', OPTS: {DA1:3, SA1:99} },
];
/* Data is ready to be processed (sent to API,DB,etc) */
const finished = function(responses) {
console.log("All responses and or timeouts received");
console.log(responses);
};
const pollUnits = function() {
/* We use number of hosts to compare to the length of the response array */
const numberOfRemoteHosts = remoteHosts.length;
const options = {timeout:2000};
for (let remHost in remoteHosts) {
/* Add key value entry into responses array */
clients[remHost.KEY] = fins.FinsClient(9600,remHost.IP,remHost.OPTS);
clients[remHost.KEY].on('reply', function(err, msg) {
if(debug) console.log("Got reply from: ", msg.response.remotehost);
/* Add key value pair of [ipAddress] = values from read */
responses[msg.response.remotehost] = msg.response.values;
/* Check to see size of response array is equal to number of hosts */
if(Object.keys(responses).length == numberOfRemoteHosts){
finished(responses);
}
});
/* If timeout occurs log response for that IP as null */
clients[remHost.KEY].on('timeout',function(host, msg) {
responses[host] = null;
if(Object.keys(responses).length == numberOfRemoteHosts){
finished(responses);
};
if(debug) console.log("Got timeout from: ", host);
});
clients[remHost.KEY].on('error',function(err, msg) {
//depending where the error occurred, msg also may contain relevant info
console.error(err)
});
/* Read 10 registers starting at DM location 00000 */
clients[remHost.KEY].read('D00000',10);
};
};
console.log("Starting.....");
pollUnits();If you have Wireshark installed it is very simple to analyse OMRON FINS/UDP traffic:
Simply select your network interface and then hit "Start"
Once in Wireshark change your filter to "omron"
Now you can examine each FINS packet individually
