Huge News!Announcing our $40M Series B led by Abstract Ventures.Learn More
Socket
Sign inDemoInstall
Socket

jupyterlab-extension-builder

Package Overview
Dependencies
Maintainers
3
Versions
10
Alerts
File Explorer

Advanced tools

Socket logo

Install Socket

Detect and block malicious and high-risk dependencies

Install

jupyterlab-extension-builder

Tools for building JupyterLab extensions

  • 0.5.0
  • Source
  • npm
  • Socket score

Version published
Weekly downloads
0
decreased by-100%
Maintainers
3
Weekly downloads
 
Created
Source

JupyterLab Extension Builder

Tools for building JupyterLab extensions

A JupyterLab extension provides additional, optional functionality to JupyterLab's built-in capabilities. An extension is a module that provides one or more plugins to the JupyterLab application. To streamline third-party development of extensions, this library provides a build script for generating third party extension JavaScript bundles.

Simple extensions can be created by using the buildExtension function with the default options. More advanced extensions may require additional configuration such as custom loaders or WebPack plugins.

A video tutorial walkthrough for building JupyterLab extensions can be found on YouTube.

Package Install

Prerequisites

  • node
npm install --save jupyterlab-extension-builder

Source Build

Prerequisites

git clone https://github.com/jupyter/jupyterlab-extension-builder.git
cd jupyterlab-extension-builder
npm install
npm run build

Rebuild Source

npm run clean
npm run build

Usage

Three major usage steps include:

The full API docs can be found here.

Extension entry point

A simple extension entry point that exposes a single application plugin could look like:

module.exports = [{
    id: 'my-cool-extension',
    activate: function(app) {
       console.log(app.commands);
    }
}];

The extension entry point must be a CommonJS module where the default export is an array of plugin objects. If writing in ES6 format use the export default [ ... ]; syntax.

buildExtension

Build the above example using the following script:

var buildExtension = require('jupyterlab-extension-builder').buildExtension;

buildExtension({
    name: 'my-cool-extension',
    entry: './index.js',
    outputDir: './build'
});

The name is a string that will be used for the output filename. The entry is the module that exports a plugin definition or array of plugin definitions. The outputDir is the directory in which the generated plugin bundle, manifest, and related files will be stored.

Several optional arguments are also available; see the options at the bottom of the builder.ts file.

In this case the builder script will create the following files in the build directory:

my-cool-extension.bundle.js
my-cool-extension.js.manifest

jupyter labextension

Other extensions may produce additional files in the build directory depending on the complexity of extension. The two files above, my-cool-extension.js and my-cool-extension.js.manifest, are used by the JupyterLab server to determine the entry point file(s) and entry point module(s) for the extension. The extension must also be registered, using the command jupyter labextension, in order to be added to the JupyterLab application. See the documentation for labextension

Technical overview

The extension bundles are created using WebPack, and the modules produced by WebPack are modified to use JupyterLab's custom module registration and loading mechanism.

JupyterLab's custom module registration and loading mechanism uses a define function that registers modules by name, where the name contains the package name, version number, and the full path to the module. For example, 'phosphor@0.6.1/lib/ui/widget.js'. Within a define function, a required module is referenced by package name, semver range, and the full path to the module. For example, require('phosphor@^0.6.0/lib/ui/tabpanel.js').

By using a semver range, JupyterLab can perform client-side deduplication of modules, where the registered module that maximally satisfies a semver range is the one returned by the require function call. This also enables us to perform server-side deduplication of modules prior to serving the bundles, and the client-side lookup will still load the correct modules.

Reasons to deduplicate code include:

  • being able to use instanceof() on an object to determine if it is the same class (a technique used by phosphor's drag-drop mechanism)
  • sharing of module-private state between different consumers, such as a list of client-side running kernels in jupyter-js-services.

All client-side require() calls are synchronous, which means that the bundles containing the define() modules must be loaded prior to using any of the bundles' functions. The loader provides an ensureBundle() function to load a particular bundle or bundles prior to calling require() on a module.

Custom WebPack Configuration and JupyterLabPlugin

A completely custom WebPack configuration may be needed if there is a case where the buildExtension function is not sufficient to build the extension. If a custom WebPack configuration is needed, the JupyterLabPlugin must be used as part of the WebPack config to ensure proper handling of module definition and requires.

Keywords

FAQs

Package last updated on 21 Sep 2016

Did you know?

Socket

Socket for GitHub automatically highlights issues in each pull request and monitors the health of all your open source dependencies. Discover the contents of your packages and block harmful activity before you install or update your dependencies.

Install

Related posts

SocketSocket SOC 2 Logo

Product

  • Package Alerts
  • Integrations
  • Docs
  • Pricing
  • FAQ
  • Roadmap
  • Changelog

Packages

npm

Stay in touch

Get open source security insights delivered straight into your inbox.


  • Terms
  • Privacy
  • Security

Made with ⚡️ by Socket Inc