445 lines
20 KiB
Markdown
445 lines
20 KiB
Markdown
---
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title: Performance
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description: A set of guidelines for building performant Electron apps
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slug: performance
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hide_title: true
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toc_max_heading_level: 3
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---
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# Performance
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Developers frequently ask about strategies to optimize the performance of
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Electron applications. Software engineers, consumers, and framework developers
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do not always agree on one single definition of what "performance" means. This
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document outlines some of the Electron maintainers' favorite ways to reduce the
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amount of memory, CPU, and disk resources being used while ensuring that your
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app is responsive to user input and completes operations as quickly as
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possible. Furthermore, we want all performance strategies to maintain a high
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standard for your app's security.
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Wisdom and information about how to build performant websites with JavaScript
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generally applies to Electron apps, too. To a certain extent, resources
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discussing how to build performant Node.js applications also apply, but be
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careful to understand that the term "performance" means different things for
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a Node.js backend than it does for an application running on a client.
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This list is provided for your convenience – and is, much like our
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[security checklist][security] – not meant to exhaustive. It is probably possible
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to build a slow Electron app that follows all the steps outlined below. Electron
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is a powerful development platform that enables you, the developer, to do more
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or less whatever you want. All that freedom means that performance is largely
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your responsibility.
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## Measure, Measure, Measure
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The list below contains a number of steps that are fairly straightforward and
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easy to implement. However, building the most performant version of your app
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will require you to go beyond a number of steps. Instead, you will have to
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closely examine all the code running in your app by carefully profiling and
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measuring. Where are the bottlenecks? When the user clicks a button, what
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operations take up the brunt of the time? While the app is simply idling, which
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objects take up the most memory?
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Time and time again, we have seen that the most successful strategy for building
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a performant Electron app is to profile the running code, find the most
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resource-hungry piece of it, and to optimize it. Repeating this seemingly
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laborious process over and over again will dramatically increase your app's
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performance. Experience from working with major apps like Visual Studio Code or
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Slack has shown that this practice is by far the most reliable strategy to
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improve performance.
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To learn more about how to profile your app's code, familiarize yourself with
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the Chrome Developer Tools. For advanced analysis looking at multiple processes
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at once, consider the [Chrome Tracing](https://www.chromium.org/developers/how-tos/trace-event-profiling-tool) tool.
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### Recommended Reading
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* [Get Started With Analyzing Runtime Performance][chrome-devtools-tutorial]
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* [Talk: "Visual Studio Code - The First Second"][vscode-first-second]
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## Checklist: Performance recommendations
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Chances are that your app could be a little leaner, faster, and generally less
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resource-hungry if you attempt these steps.
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1. [Carelessly including modules](#1-carelessly-including-modules)
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2. [Loading and running code too soon](#2-loading-and-running-code-too-soon)
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3. [Blocking the main process](#3-blocking-the-main-process)
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4. [Blocking the renderer process](#4-blocking-the-renderer-process)
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5. [Unnecessary polyfills](#5-unnecessary-polyfills)
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6. [Unnecessary or blocking network requests](#6-unnecessary-or-blocking-network-requests)
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7. [Bundle your code](#7-bundle-your-code)
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### 1. Carelessly including modules
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Before adding a Node.js module to your application, examine said module. How
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many dependencies does that module include? What kind of resources does
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it need to simply be called in a `require()` statement? You might find
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that the module with the most downloads on the NPM package registry or the most stars on GitHub
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is not in fact the leanest or smallest one available.
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#### Why?
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The reasoning behind this recommendation is best illustrated with a real-world
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example. During the early days of Electron, reliable detection of network
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connectivity was a problem, resulting many apps to use a module that exposed a
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simple `isOnline()` method.
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That module detected your network connectivity by attempting to reach out to a
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number of well-known endpoints. For the list of those endpoints, it depended on
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a different module, which also contained a list of well-known ports. This
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dependency itself relied on a module containing information about ports, which
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came in the form of a JSON file with more than 100,000 lines of content.
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Whenever the module was loaded (usually in a `require('module')` statement),
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it would load all its dependencies and eventually read and parse this JSON
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file. Parsing many thousands lines of JSON is a very expensive operation. On
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a slow machine it can take up whole seconds of time.
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In many server contexts, startup time is virtually irrelevant. A Node.js server
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that requires information about all ports is likely actually "more performant"
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if it loads all required information into memory whenever the server boots at
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the benefit of serving requests faster. The module discussed in this example is
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not a "bad" module. Electron apps, however, should not be loading, parsing, and
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storing in memory information that it does not actually need.
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In short, a seemingly excellent module written primarily for Node.js servers
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running Linux might be bad news for your app's performance. In this particular
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example, the correct solution was to use no module at all, and to instead use
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connectivity checks included in later versions of Chromium.
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#### How?
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When considering a module, we recommend that you check:
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1. the size of dependencies included
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2. the resources required to load (`require()`) it
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3. the resources required to perform the action you're interested in
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Generating a CPU profile and a heap memory profile for loading a module can be done
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with a single command on the command line. In the example below, we're looking at
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the popular module `request`.
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```sh
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node --cpu-prof --heap-prof -e "require('request')"
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```
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Executing this command results in a `.cpuprofile` file and a `.heapprofile`
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file in the directory you executed it in. Both files can be analyzed using
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the Chrome Developer Tools, using the `Performance` and `Memory` tabs
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respectively.
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![Performance CPU Profile](../images/performance-cpu-prof.png)
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![Performance Heap Memory Profile](../images/performance-heap-prof.png)
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In this example, on the author's machine, we saw that loading `request` took
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almost half a second, whereas `node-fetch` took dramatically less memory
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and less than 50ms.
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### 2. Loading and running code too soon
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If you have expensive setup operations, consider deferring those. Inspect all
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the work being executed right after the application starts. Instead of firing
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off all operations right away, consider staggering them in a sequence more
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closely aligned with the user's journey.
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In traditional Node.js development, we're used to putting all our `require()`
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statements at the top. If you're currently writing your Electron application
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using the same strategy _and_ are using sizable modules that you do not
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immediately need, apply the same strategy and defer loading to a more
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opportune time.
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#### Why?
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Loading modules is a surprisingly expensive operation, especially on Windows.
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When your app starts, it should not make users wait for operations that are
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currently not necessary.
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This might seem obvious, but many applications tend to do a large amount of
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work immediately after the app has launched - like checking for updates,
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downloading content used in a later flow, or performing heavy disk I/O
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operations.
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Let's consider Visual Studio Code as an example. When you open a file, it will
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immediately display the file to you without any code highlighting, prioritizing
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your ability to interact with the text. Once it has done that work, it will
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move on to code highlighting.
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#### How?
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Let's consider an example and assume that your application is parsing files
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in the fictitious `.foo` format. In order to do that, it relies on the
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equally fictitious `foo-parser` module. In traditional Node.js development,
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you might write code that eagerly loads dependencies:
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```js title='parser.js'
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const fs = require('fs')
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const fooParser = require('foo-parser')
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class Parser {
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constructor () {
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this.files = fs.readdirSync('.')
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}
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getParsedFiles () {
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return fooParser.parse(this.files)
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}
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}
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const parser = new Parser()
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module.exports = { parser }
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```
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In the above example, we're doing a lot of work that's being executed as soon
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as the file is loaded. Do we need to get parsed files right away? Could we
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do this work a little later, when `getParsedFiles()` is actually called?
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```js title='parser.js'
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// "fs" is likely already being loaded, so the `require()` call is cheap
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const fs = require('fs')
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class Parser {
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async getFiles () {
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// Touch the disk as soon as `getFiles` is called, not sooner.
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// Also, ensure that we're not blocking other operations by using
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// the asynchronous version.
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this.files = this.files || await fs.readdir('.')
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return this.files
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}
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async getParsedFiles () {
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// Our fictitious foo-parser is a big and expensive module to load, so
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// defer that work until we actually need to parse files.
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// Since `require()` comes with a module cache, the `require()` call
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// will only be expensive once - subsequent calls of `getParsedFiles()`
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// will be faster.
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const fooParser = require('foo-parser')
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const files = await this.getFiles()
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return fooParser.parse(files)
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}
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}
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// This operation is now a lot cheaper than in our previous example
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const parser = new Parser()
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module.exports = { parser }
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```
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In short, allocate resources "just in time" rather than allocating them all
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when your app starts.
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### 3. Blocking the main process
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Electron's main process (sometimes called "browser process") is special: It is
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the parent process to all your app's other processes and the primary process
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the operating system interacts with. It handles windows, interactions, and the
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communication between various components inside your app. It also houses the
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UI thread.
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Under no circumstances should you block this process and the UI thread with
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long-running operations. Blocking the UI thread means that your entire app
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will freeze until the main process is ready to continue processing.
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#### Why?
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The main process and its UI thread are essentially the control tower for major
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operations inside your app. When the operating system tells your app about a
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mouse click, it'll go through the main process before it reaches your window.
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If your window is rendering a buttery-smooth animation, it'll need to talk to
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the GPU process about that – once again going through the main process.
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Electron and Chromium are careful to put heavy disk I/O and CPU-bound operations
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onto new threads to avoid blocking the UI thread. You should do the same.
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#### How?
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Electron's powerful multi-process architecture stands ready to assist you with
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your long-running tasks, but also includes a small number of performance traps.
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1. For long running CPU-heavy tasks, make use of
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[worker threads][worker-threads], consider moving them to the BrowserWindow, or
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(as a last resort) spawn a dedicated process.
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2. Avoid using the synchronous IPC and the `@electron/remote` module as much
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as possible. While there are legitimate use cases, it is far too easy to
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unknowingly block the UI thread.
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3. Avoid using blocking I/O operations in the main process. In short, whenever
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core Node.js modules (like `fs` or `child_process`) offer a synchronous or an
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asynchronous version, you should prefer the asynchronous and non-blocking
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variant.
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### 4. Blocking the renderer process
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Since Electron ships with a current version of Chrome, you can make use of the
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latest and greatest features the Web Platform offers to defer or offload heavy
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operations in a way that keeps your app smooth and responsive.
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#### Why?
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Your app probably has a lot of JavaScript to run in the renderer process. The
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trick is to execute operations as quickly as possible without taking away
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resources needed to keep scrolling smooth, respond to user input, or animations
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at 60fps.
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Orchestrating the flow of operations in your renderer's code is
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particularly useful if users complain about your app sometimes "stuttering".
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#### How?
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Generally speaking, all advice for building performant web apps for modern
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browsers apply to Electron's renderers, too. The two primary tools at your
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disposal are currently `requestIdleCallback()` for small operations and
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`Web Workers` for long-running operations.
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_`requestIdleCallback()`_ allows developers to queue up a function to be
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executed as soon as the process is entering an idle period. It enables you to
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perform low-priority or background work without impacting the user experience.
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For more information about how to use it,
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[check out its documentation on MDN][request-idle-callback].
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_Web Workers_ are a powerful tool to run code on a separate thread. There are
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some caveats to consider – consult Electron's
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[multithreading documentation][multithreading] and the
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[MDN documentation for Web Workers][web-workers]. They're an ideal solution
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for any operation that requires a lot of CPU power for an extended period of
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time.
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### 5. Unnecessary polyfills
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One of Electron's great benefits is that you know exactly which engine will
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parse your JavaScript, HTML, and CSS. If you're re-purposing code that was
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written for the web at large, make sure to not polyfill features included in
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Electron.
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#### Why?
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When building a web application for today's Internet, the oldest environments
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dictate what features you can and cannot use. Even though Electron supports
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well-performing CSS filters and animations, an older browser might not. Where
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you could use WebGL, your developers may have chosen a more resource-hungry
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solution to support older phones.
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When it comes to JavaScript, you may have included toolkit libraries like
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jQuery for DOM selectors or polyfills like the `regenerator-runtime` to support
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`async/await`.
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It is rare for a JavaScript-based polyfill to be faster than the equivalent
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native feature in Electron. Do not slow down your Electron app by shipping your
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own version of standard web platform features.
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#### How?
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Operate under the assumption that polyfills in current versions of Electron
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are unnecessary. If you have doubts, check [caniuse.com](https://caniuse.com/)
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and check if the [version of Chromium used in your Electron version](../api/process.md#processversionschrome-readonly)
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supports the feature you desire.
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In addition, carefully examine the libraries you use. Are they really necessary?
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`jQuery`, for example, was such a success that many of its features are now part
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of the [standard JavaScript feature set available][jquery-need].
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If you're using a transpiler/compiler like TypeScript, examine its configuration
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and ensure that you're targeting the latest ECMAScript version supported by
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Electron.
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### 6. Unnecessary or blocking network requests
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Avoid fetching rarely changing resources from the internet if they could easily
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be bundled with your application.
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#### Why?
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Many users of Electron start with an entirely web-based app that they're
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turning into a desktop application. As web developers, we are used to loading
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resources from a variety of content delivery networks. Now that you are
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shipping a proper desktop application, attempt to "cut the cord" where possible
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and avoid letting your users wait for resources that never change and could
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easily be included in your app.
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A typical example is Google Fonts. Many developers make use of Google's
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impressive collection of free fonts, which comes with a content delivery
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network. The pitch is straightforward: Include a few lines of CSS and Google
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will take care of the rest.
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When building an Electron app, your users are better served if you download
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the fonts and include them in your app's bundle.
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#### How?
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In an ideal world, your application wouldn't need the network to operate at
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all. To get there, you must understand what resources your app is downloading
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\- and how large those resources are.
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To do so, open up the developer tools. Navigate to the `Network` tab and check
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the `Disable cache` option. Then, reload your renderer. Unless your app
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prohibits such reloads, you can usually trigger a reload by hitting `Cmd + R`
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or `Ctrl + R` with the developer tools in focus.
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The tools will now meticulously record all network requests. In a first pass,
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take stock of all the resources being downloaded, focusing on the larger files
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first. Are any of them images, fonts, or media files that don't change and
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could be included with your bundle? If so, include them.
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As a next step, enable `Network Throttling`. Find the drop-down that currently
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reads `Online` and select a slower speed such as `Fast 3G`. Reload your
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renderer and see if there are any resources that your app is unnecessarily
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waiting for. In many cases, an app will wait for a network request to complete
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despite not actually needing the involved resource.
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As a tip, loading resources from the Internet that you might want to change
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without shipping an application update is a powerful strategy. For advanced
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control over how resources are being loaded, consider investing in
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[Service Workers][service-workers].
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### 7. Bundle your code
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As already pointed out in
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"[Loading and running code too soon](#2-loading-and-running-code-too-soon)",
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calling `require()` is an expensive operation. If you are able to do so,
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bundle your application's code into a single file.
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#### Why?
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Modern JavaScript development usually involves many files and modules. While
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that's perfectly fine for developing with Electron, we heavily recommend that
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you bundle all your code into one single file to ensure that the overhead
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included in calling `require()` is only paid once when your application loads.
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#### How?
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There are numerous JavaScript bundlers out there and we know better than to
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anger the community by recommending one tool over another. We do however
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recommend that you use a bundler that is able to handle Electron's unique
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environment that needs to handle both Node.js and browser environments.
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As of writing this article, the popular choices include [Webpack][webpack],
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[Parcel][parcel], and [rollup.js][rollup].
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### 8. Call `Menu.setApplicationMenu(null)` when you do not need a default menu
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Electron will set a default menu on startup with some standard entries. But there are reasons your application might want to change that and it will benefit startup performance.
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#### Why?
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If you build your own menu or use a frameless window without native menu, you should tell Electron early enough to not setup the default menu.
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#### How?
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Call `Menu.setApplicationMenu(null)` before `app.on("ready")`. This will prevent Electron from setting a default menu. See also https://github.com/electron/electron/issues/35512 for a related discussion.
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[security]: ./security.md
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[chrome-devtools-tutorial]: https://developers.google.com/web/tools/chrome-devtools/evaluate-performance/
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[worker-threads]: https://nodejs.org/api/worker_threads.html
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[web-workers]: https://developer.mozilla.org/en-US/docs/Web/API/Web_Workers_API/Using_web_workers
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[request-idle-callback]: https://developer.mozilla.org/en-US/docs/Web/API/Window/requestIdleCallback
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[multithreading]: ./multithreading.md
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[jquery-need]: https://youmightnotneedjquery.com/
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[service-workers]: https://developer.mozilla.org/en-US/docs/Web/API/Service_Worker_API
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[webpack]: https://webpack.js.org/
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[parcel]: https://parceljs.org/
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[rollup]: https://rollupjs.org/
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[vscode-first-second]: https://www.youtube.com/watch?v=r0OeHRUCCb4
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