noflo-nodejs

Command-line tool for running NoFlo programs on Node.js =================================

Usage no npm install needed!

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  import nofloNodejs from 'https://cdn.skypack.dev/noflo-nodejs';
</script>

README

Command-line tool for running NoFlo programs on Node.js

This tool is designed to be used together with the Flowhub development environment for running NoFlo networks on Node.js. This tool runs your NoFlo programs, and provides a FBP Protocol interface over either WebSockets or WebRTC to tools like Flowhub and fbp-spec.

This enables inspection of the state of the running NoFlo program, as well as live editing of the graph and components of your project.

Prepare a project folder

Start by setting up a local NoFlo Node.js project. For example:

$ mkdir my-project
$ cd my-project
$ npm init
$ npm install noflo --save
$ npm install noflo-nodejs --save

Continue by installing whatever NoFlo component libraries you need, for example:

$ npm install noflo-core --save

If you want, this is a great time to push your project to GitHub.

Starting the runtime

Once you have installed the runtime, it is time to start it:

$ npx noflo-nodejs

This will start a WebSocket-based NoFlo Runtime server. When started, it will output an URL with the connection details needed by Flowhub.

Copy paste this URL into the browser. The Flowhub IDE will open, and automatically connect to your runtime. To make changes hit 'Edit as Project'. You should be able to see available components and build up your system.

Starting an existing graph

If you want to run an existing graph, you can use the --graph option.

noflo-nodejs --graph graphs/MyMainGraph.json

If you want the process to exit when the network stops, you can pass --batch.

Typical project setup

In most Node.js projects there will be three different setups you might want to have with NoFlo: development, testing, and production. Each of these can be easily expressed via NPM scripts in package.json:

{
  "name": "my-project",
  "scripts": {
    "dev": "noflo-nodejs --host localhost --auto-save --graph ./graphs/MyGraph.json",
    "test": "fbp-spec --secret test --address ws://localhost:3333 --command 'noflo-nodejs --port 3333 --capture-output --secret test --open false' spec/",
    "start": "noflo-nodejs --protocol webrtc --graph ./graphs/MyGraph.json"
  },
  "dependencies": {
    ...
  },
  ...
}

With this setup you get the following:

  • By running npm run dev, noflo-nodejs will start your projects' main graph and open the Flowhub IDE in your browser. Any changes you make in Flowhub will be persisted on your local hard drive
  • By running npm test, fbp-spec will start a noflo-nodejs instance, connect to it, and run all of your local fbp-spec tests
  • By running npm start, noflo-nodejs starts your program, enabling remote debugging via the WebRTC protocol

Host address autodetection for WebSockets

By default noflo-nodejs will attempt to autodetect the public hostname/IP of your system. If this fails, you can specify --host myhostname manually.

Securing the WebSocket connection

The noflo-nodejs runtime can be secured using TLS. Place the key and certificate files somewhere that noflo-nodejs can read, and then start the runtime with the --tls-key and --tls-cert` options.

For example, to use self-signed keys, you could do the following:

$ openssl genrsa -out localhost.key 2048
$ openssl req -new -x509 -key localhost.key -out localhost.cert -days 3650 -subj /CN=localhost
$ noflo-nodejs --tls-key=localhost.key --tls-cert=localhost.cert

Note: browsers may refuse to connect to a WebSocket with a self-signed certificate by default. You can visit the runtime URL with your browser first to accept the certificate before connecting to it in the IDE.

Peer-to-peer WebRTC connections

If you want to use a peer-to-peer WebRTC connection instead of WebSockets, start noflo-nodejs with the argument --protocol webrtc.

While slightly more complex and slower to start, WebRTC has some advantages over WebSockets:

  • Peer-to-peer connections can (sometimes) work through firewalls
  • No need for setting up TLS to secure communications between the runtime and the client

By default noflo-nodejs uses Flowhub's signalling server for negotiating the connection details between runtime and clients. You can supply a different RTC Switchboard instance with the --signaller option.

Debugging

noflo-nodejs supports flowtrace allows to trace & store the execution of the FBP program, so you can debug any issues that would occur. Specify --trace to enable tracing.

$ noflo-nodejs --graph graphs/MyMainGraph.json --trace

If you are running in --batch mode, the file will be dumped to disk when the program terminates. Otherwise you can send the SIGUSR2 to trigger dumping the file to disk.

$ kill -SIGUSR2 $PID_OF_PROCESS
... Wrote flowtrace to: .flowtrace/1151020-12063-ami5vq.json

You can now use various flowtrace tools to introspect the data. For instance, you can get a human readable log using flowtrace-show

$ npx flowtrace-show .flowtrace/1151020-12063-ami5vq.json

-> IN repeat CONN
-> IN repeat DATA hello world
-> IN stdout CONN
-> IN stdout DATA hello world
-> IN repeat DISC
-> IN stdout DISC

Signalling aliveness

noflo-nodejs will ping Flowhub registry periodically to signal aliveness to IDE users. To disable this behavior, set --registry-ping 0.

Persistent runtime configuration

Settings can be loaded from a flowhub.json file. By default the configuration will be read from the current working directory, but you can change this by setting the PROJECT_HOME environment variable.

This file will be automatically saved when you run noflo-nodejs, meaning that settings like runtime ID and secret will be persisted between runs.

Environment variables and command-line options will override settings specified in config file.

Since the values are often machine and/or user specific, you usually don't want to add this file to version control.

Embedding runtime in an existing service

In addition to running noflo-nodejs as a command-line program that starts and runs your NoFlo graphs, you can embed it into an existing Node.js application. Here is a quick example how to do it:

const runtime = require('noflo-nodejs');

// This function returns a Promise that resolves when the NoFlo runtime has started up
startRuntime(graphPath, options = {}) {
  // Configure noflo-nodejs. Options here map roughly to the standard command-line arguments
  const settings = {
    id: '9f1432b1-a259-454a-bb67-e9d91525cc63', // Set an unique UUID for your application instance
    label: 'My cool app',
    baseDir: __dirname,
    host: 'localhost',
    port: 3569,
    ...options,
  };
  return runtime(graphPath, settings);
}