As web developers, we usually enjoy the strong security net of the browser - the risks associated with the code we write are relatively small. Our websites are granted limited powers in a sandbox, and we trust that our users enjoy a browser built by a large team of engineers that is able to quickly respond to newly discovered security threats.
When working with Electron, it is important to understand that Electron is not a web browser. It allows you to build feature-rich desktop applications with familiar web technologies, but your code wields much greater power. JavaScript can access the filesystem, user shell, and more. This allows you to build high quality native applications, but the inherent security risks scale with the additional powers granted to your code.
With that in mind, be aware that displaying arbitrary content from untrusted sources poses a severe security risk that Electron is not intended to handle. In fact, the most popular Electron apps (Atom, Slack, Visual Studio Code, etc) display primarily local content (or trusted, secure remote content without Node integration) – if your application executes code from an online source, it is your responsibility to ensure that the code is not malicious.
For information on how to properly disclose an Electron vulnerability, see SECURITY.md
Electron keeps up to date with alternating Chromium releases. For more information, see the Electron Release Cadence blog post.
It is important to remember that the security of your Electron application is the result of the overall security of the framework foundation (Chromium, Node.js), Electron itself, all NPM dependencies and your code. As such, it is your responsibility to follow a few important best practices:
-
Keep your application up-to-date with the latest Electron framework release. When releasing your product, you’re also shipping a bundle composed of Electron, Chromium shared library and Node.js. Vulnerabilities affecting these components may impact the security of your application. By updating Electron to the latest version, you ensure that critical vulnerabilities (such as nodeIntegration bypasses) are already patched and cannot be exploited in your application. For more information, see "Use a current version of Electron".
-
Evaluate your dependencies. While NPM provides half a million reusable packages, it is your responsibility to choose trusted 3rd-party libraries. If you use outdated libraries affected by known vulnerabilities or rely on poorly maintained code, your application security could be in jeopardy.
-
Adopt secure coding practices. The first line of defense for your application is your own code. Common web vulnerabilities, such as Cross-Site Scripting (XSS), have a higher security impact on Electron applications hence it is highly recommended to adopt secure software development best practices and perform security testing.
A security issue exists whenever you receive code from an untrusted source (e.g.
a remote server) and execute it locally. As an example, consider a remote
website being displayed inside a default BrowserWindow
. If
an attacker somehow manages to change said content (either by attacking the
source directly, or by sitting between your app and the actual destination), they
will be able to execute native code on the user's machine.
⚠️ Under no circumstances should you load and execute remote code with Node.js integration enabled. Instead, use only local files (packaged together with your application) to execute Node.js code. To display remote content, use the<webview>
tag orBrowserView
, make sure to disable thenodeIntegration
and enablecontextIsolation
.
From Electron 2.0 on, developers will see warnings and recommendations printed to the developer console. They only show up when the binary's name is Electron, indicating that a developer is currently looking at the console.
You can force-enable or force-disable these warnings by setting
ELECTRON_ENABLE_SECURITY_WARNINGS
or ELECTRON_DISABLE_SECURITY_WARNINGS
on
either process.env
or the window
object.
You should at least follow these steps to improve the security of your application:
- Only load secure content
- Disable the Node.js integration in all renderers that display remote content
- Enable context isolation in all renderers that display remote content
- Use
ses.setPermissionRequestHandler()
in all sessions that load remote content - Do not disable
webSecurity
- Define a
Content-Security-Policy
and use restrictive rules (i.e.script-src 'self'
) - Do not set
allowRunningInsecureContent
totrue
- Do not enable experimental features
- Do not use
enableBlinkFeatures
<webview>
: Do not useallowpopups
<webview>
: Verify options and params- Disable or limit navigation
- Disable or limit creation of new windows
- Do not use
openExternal
with untrusted content - Disable the
remote
module - Filter the
remote
module - Use a current version of Electron
To automate the detection of misconfigurations and insecure patterns, it is possible to use electronegativity. For additional details on potential weaknesses and implementation bugs when developing applications using Electron, please refer to this guide for developers and auditors
Any resources not included with your application should be loaded using a
secure protocol like HTTPS
. In other words, do not use insecure protocols
like HTTP
. Similarly, we recommend the use of WSS
over WS
, FTPS
over
FTP
, and so on.
HTTPS
has three main benefits:
- It authenticates the remote server, ensuring your app connects to the correct host instead of an impersonator.
- It ensures data integrity, asserting that the data was not modified while in transit between your application and the host.
- It encrypts the traffic between your user and the destination host, making it more difficult to eavesdrop on the information sent between your app and the host.
// Bad
browserWindow.loadURL('http://example.com')
// Good
browserWindow.loadURL('https://example.com')
<!-- Bad -->
<script crossorigin src="http://example.com/react.js"></script>
<link rel="stylesheet" href="http://example.com/style.css">
<!-- Good -->
<script crossorigin src="https://example.com/react.js"></script>
<link rel="stylesheet" href="https://example.com/style.css">
This recommendation is the default behavior in Electron since 5.0.0.
It is paramount that you do not enable Node.js integration in any renderer
(BrowserWindow
, BrowserView
, or
<webview>
) that loads remote content. The goal is to limit the
powers you grant to remote content, thus making it dramatically more difficult
for an attacker to harm your users should they gain the ability to execute
JavaScript on your website.
After this, you can grant additional permissions for specific hosts. For example,
if you are opening a BrowserWindow pointed at https://example.com/
, you can
give that website exactly the abilities it needs, but no more.
A cross-site-scripting (XSS) attack is more dangerous if an attacker can jump out of the renderer process and execute code on the user's computer. Cross-site-scripting attacks are fairly common - and while an issue, their power is usually limited to messing with the website that they are executed on. Disabling Node.js integration helps prevent an XSS from being escalated into a so-called "Remote Code Execution" (RCE) attack.
// Bad
const mainWindow = new BrowserWindow({
webPreferences: {
nodeIntegration: true,
nodeIntegrationInWorker: true
}
})
mainWindow.loadURL('https://example.com')
// Good
const mainWindow = new BrowserWindow({
webPreferences: {
preload: path.join(app.getAppPath(), 'preload.js')
}
})
mainWindow.loadURL('https://example.com')
<!-- Bad -->
<webview nodeIntegration src="page.html"></webview>
<!-- Good -->
<webview src="page.html"></webview>
When disabling Node.js integration, you can still expose APIs to your website that
do consume Node.js modules or features. Preload scripts continue to have access
to require
and other Node.js features, allowing developers to expose a custom
API to remotely loaded content.
In the following example preload script, the later loaded website will have
access to a window.readConfig()
method, but no Node.js features.
const { readFileSync } = require('fs')
window.readConfig = function () {
const data = readFileSync('./config.json')
return data
}
Context isolation is an Electron feature that allows developers to run code
in preload scripts and in Electron APIs in a dedicated JavaScript context. In
practice, that means that global objects like Array.prototype.push
or
JSON.parse
cannot be modified by scripts running in the renderer process.
Electron uses the same technology as Chromium's Content Scripts to enable this behavior.
Even when you use nodeIntegration: false
to enforce strong isolation and
prevent the use of Node primitives, contextIsolation
must also be used.
Context isolation allows each of the scripts running in the renderer to make changes to its JavaScript environment without worrying about conflicting with the scripts in the Electron API or the preload script.
While still an experimental Electron feature, context isolation adds an additional layer of security. It creates a new JavaScript world for Electron APIs and preload scripts, which mitigates so-called "Prototype Pollution" attacks.
At the same time, preload scripts still have access to the document
and
window
objects. In other words, you're getting a decent return on a likely
very small investment.
// Main process
const mainWindow = new BrowserWindow({
webPreferences: {
contextIsolation: true,
preload: path.join(app.getAppPath(), 'preload.js')
}
})
// Preload script
// Set a variable in the page before it loads
webFrame.executeJavaScript('window.foo = "foo";')
// The loaded page will not be able to access this, it is only available
// in this context
window.bar = 'bar'
document.addEventListener('DOMContentLoaded', () => {
// Will log out 'undefined' since window.foo is only available in the main
// context
console.log(window.foo)
// Will log out 'bar' since window.bar is available in this context
console.log(window.bar)
})
You may have seen permission requests while using Chrome: They pop up whenever the website attempts to use a feature that the user has to manually approve ( like notifications).
The API is based on the Chromium permissions API and implements the same types of permissions.
By default, Electron will automatically approve all permission requests unless the developer has manually configured a custom handler. While a solid default, security-conscious developers might want to assume the very opposite.
const { session } = require('electron')
session
.fromPartition('some-partition')
.setPermissionRequestHandler((webContents, permission, callback) => {
const url = webContents.getURL()
if (permission === 'notifications') {
// Approves the permissions request
callback(true)
}
// Verify URL
if (!url.startsWith('https://example.com/')) {
// Denies the permissions request
return callback(false)
}
})
Recommendation is Electron's default
You may have already guessed that disabling the webSecurity
property on a
renderer process (BrowserWindow
,
BrowserView
, or <webview>
) disables crucial
security features.
Do not disable webSecurity
in production applications.
Disabling webSecurity
will disable the same-origin policy and set
allowRunningInsecureContent
property to true
. In other words, it allows
the execution of insecure code from different domains.
// Bad
const mainWindow = new BrowserWindow({
webPreferences: {
webSecurity: false
}
})
// Good
const mainWindow = new BrowserWindow()
<!-- Bad -->
<webview disablewebsecurity src="page.html"></webview>
<!-- Good -->
<webview src="page.html"></webview>
A Content Security Policy (CSP) is an additional layer of protection against cross-site-scripting attacks and data injection attacks. We recommend that they be enabled by any website you load inside Electron.
CSP allows the server serving content to restrict and control the resources
Electron can load for that given web page. https://example.com
should
be allowed to load scripts from the origins you defined while scripts from
https://evil.attacker.com
should not be allowed to run. Defining a CSP is an
easy way to improve your application's security.
The following CSP will allow Electron to execute scripts from the current
website and from apis.example.com
.
// Bad
Content-Security-Policy: '*'
// Good
Content-Security-Policy: script-src 'self' https://apis.example.com
Electron respects the Content-Security-Policy
HTTP header
which can be set using Electron's
webRequest.onHeadersReceived
handler:
const { session } = require('electron')
session.defaultSession.webRequest.onHeadersReceived((details, callback) => {
callback({
responseHeaders: {
...details.responseHeaders,
'Content-Security-Policy': ['default-src \'none\'']
}
})
})
CSP's preferred delivery mechanism is an HTTP header, however it is not possible
to use this method when loading a resource using the file://
protocol. It can
be useful in some cases, such as using the file://
protocol, to set a policy
on a page directly in the markup using a <meta>
tag:
<meta http-equiv="Content-Security-Policy" content="default-src 'none'">
Recommendation is Electron's default
By default, Electron will not allow websites loaded over HTTPS
to load and
execute scripts, CSS, or plugins from insecure sources (HTTP
). Setting the
property allowRunningInsecureContent
to true
disables that protection.
Loading the initial HTML of a website over HTTPS
and attempting to load
subsequent resources via HTTP
is also known as "mixed content".
Loading content over HTTPS
assures the authenticity and integrity
of the loaded resources while encrypting the traffic itself. See the section on
only displaying secure content for more details.
// Bad
const mainWindow = new BrowserWindow({
webPreferences: {
allowRunningInsecureContent: true
}
})
// Good
const mainWindow = new BrowserWindow({})
Recommendation is Electron's default
Advanced users of Electron can enable experimental Chromium features using the
experimentalFeatures
property.
Experimental features are, as the name suggests, experimental and have not been enabled for all Chromium users. Furthermore, their impact on Electron as a whole has likely not been tested.
Legitimate use cases exist, but unless you know what you are doing, you should not enable this property.
// Bad
const mainWindow = new BrowserWindow({
webPreferences: {
experimentalFeatures: true
}
})
// Good
const mainWindow = new BrowserWindow({})
Recommendation is Electron's default
Blink is the name of the rendering engine behind Chromium. As with
experimentalFeatures
, the enableBlinkFeatures
property allows developers to
enable features that have been disabled by default.
Generally speaking, there are likely good reasons if a feature was not enabled by default. Legitimate use cases for enabling specific features exist. As a developer, you should know exactly why you need to enable a feature, what the ramifications are, and how it impacts the security of your application. Under no circumstances should you enable features speculatively.
// Bad
const mainWindow = new BrowserWindow({
webPreferences: {
enableBlinkFeatures: 'ExecCommandInJavaScript'
}
})
// Good
const mainWindow = new BrowserWindow()
Recommendation is Electron's default
If you are using <webview>
, you might need the pages and scripts
loaded in your <webview>
tag to open new windows. The allowpopups
attribute
enables them to create new BrowserWindows
using the
window.open()
method. <webview>
tags are otherwise not allowed to create new
windows.
If you do not need popups, you are better off not allowing the creation of
new BrowserWindows
by default. This follows the principle
of minimally required access: Don't let a website create new popups unless
you know it needs that feature.
<!-- Bad -->
<webview allowpopups src="page.html"></webview>
<!-- Good -->
<webview src="page.html"></webview>
A WebView created in a renderer process that does not have Node.js integration
enabled will not be able to enable integration itself. However, a WebView will
always create an independent renderer process with its own webPreferences
.
It is a good idea to control the creation of new <webview>
tags
from the main process and to verify that their webPreferences do not disable
security features.
Since <webview>
live in the DOM, they can be created by a script running on your
website even if Node.js integration is otherwise disabled.
Electron enables developers to disable various security features that control
a renderer process. In most cases, developers do not need to disable any of
those features - and you should therefore not allow different configurations
for newly created <webview>
tags.
Before a <webview>
tag is attached, Electron will fire the
will-attach-webview
event on the hosting webContents
. Use the event to
prevent the creation of webViews
with possibly insecure options.
app.on('web-contents-created', (event, contents) => {
contents.on('will-attach-webview', (event, webPreferences, params) => {
// Strip away preload scripts if unused or verify their location is legitimate
delete webPreferences.preload
delete webPreferences.preloadURL
// Disable Node.js integration
webPreferences.nodeIntegration = false
// Verify URL being loaded
if (!params.src.startsWith('https://example.com/')) {
event.preventDefault()
}
})
})
Again, this list merely minimizes the risk, it does not remove it. If your goal is to display a website, a browser will be a more secure option.
If your app has no need to navigate or only needs to navigate to known pages, it is a good idea to limit navigation outright to that known scope, disallowing any other kinds of navigation.
Navigation is a common attack vector. If an attacker can convince your app to
navigate away from its current page, they can possibly force your app to open
web sites on the Internet. Even if your webContents
are configured to be more
secure (like having nodeIntegration
disabled or contextIsolation
enabled),
getting your app to open a random web site will make the work of exploiting your
app a lot easier.
A common attack pattern is that the attacker convinces your app's users to interact with the app in such a way that it navigates to one of the attacker's pages. This is usually done via links, plugins, or other user-generated content.
If your app has no need for navigation, you can call event.preventDefault()
in a will-navigate
handler. If you know which pages your app
might navigate to, check the URL in the event handler and only let navigation
occur if it matches the URLs you're expecting.
We recommend that you use Node's parser for URLs. Simple string comparisons can
sometimes be fooled - a startsWith('https://example.com')
test would let
https://example.com.attacker.com
through.
const URL = require('url').URL
app.on('web-contents-created', (event, contents) => {
contents.on('will-navigate', (event, navigationUrl) => {
const parsedUrl = new URL(navigationUrl)
if (parsedUrl.origin !== 'https://example.com') {
event.preventDefault()
}
})
})
If you have a known set of windows, it's a good idea to limit the creation of additional windows in your app.
Much like navigation, the creation of new webContents
is a common attack
vector. Attackers attempt to convince your app to create new windows, frames,
or other renderer processes with more privileges than they had before; or
with pages opened that they couldn't open before.
If you have no need to create windows in addition to the ones you know you'll
need to create, disabling the creation buys you a little bit of extra
security at no cost. This is commonly the case for apps that open one
BrowserWindow
and do not need to open an arbitrary number of additional
windows at runtime.
webContents
will emit the new-window
event
before creating new windows. That event will be passed, amongst other
parameters, the url
the window was requested to open and the options used to
create it. We recommend that you use the event to scrutinize the creation of
windows, limiting it to only what you need.
const { shell } = require('electron')
app.on('web-contents-created', (event, contents) => {
contents.on('new-window', async (event, navigationUrl) => {
// In this example, we'll ask the operating system
// to open this event's url in the default browser.
event.preventDefault()
await shell.openExternal(navigationUrl)
})
})
Shell's openExternal
allows opening a given protocol URI with
the desktop's native utilities. On macOS, for instance, this function is similar
to the open
terminal command utility and will open the specific application
based on the URI and filetype association.
Improper use of openExternal
can be leveraged to compromise
the user's host. When openExternal is used with untrusted content, it can be
leveraged to execute arbitrary commands.
// Bad
const { shell } = require('electron')
shell.openExternal(USER_CONTROLLED_DATA_HERE)
// Good
const { shell } = require('electron')
shell.openExternal('https://example.com/index.html')
The remote
module provides a way for the renderer processes to
access APIs normally only available in the main process. Using it, a
renderer can invoke methods of a main process object without explicitly sending
inter-process messages. If your desktop application does not run untrusted
content, this can be a useful way to have your renderer processes access and
work with modules that are only available to the main process, such as
GUI-related modules (dialogs, menus, etc.).
However, if your app can run untrusted content and even if you
sandbox your renderer processes accordingly, the remote
module
makes it easy for malicious code to escape the sandbox and have access to
system resources via the higher privileges of the main process. Therefore,
it should be disabled in such circumstances.
remote
uses an internal IPC channel to communicate with the main process.
"Prototype pollution" attacks can grant malicious code access to the internal
IPC channel, which can then be used to escape the sandbox by mimicking remote
IPC messages and getting access to main process modules running with higher
privileges.
Additionally, it's possible for preload scripts to accidentally leak modules to a
sandboxed renderer. Leaking remote
arms malicious code with a multitude
of main process modules with which to perform an attack.
Disabling the remote
module eliminates these attack vectors. Enabling
context isolation also prevents the "prototype pollution" attacks from
succeeding.
// Bad if the renderer can run untrusted content
const mainWindow = new BrowserWindow({})
// Good
const mainWindow = new BrowserWindow({
webPreferences: {
enableRemoteModule: false
}
})
<!-- Bad if the renderer can run untrusted content -->
<webview src="page.html"></webview>
<!-- Good -->
<webview enableremotemodule="false" src="page.html"></webview>
If you cannot disable the remote
module, you should filter the globals,
Node, and Electron modules (so-called built-ins) accessible via remote
that your application does not require. This can be done by blocking
certain modules entirely and by replacing others with proxies that
expose only the functionality that your app needs.
Due to the system access privileges of the main process, functionality provided by the main process modules may be dangerous in the hands of malicious code running in a compromised renderer process. By limiting the set of accessible modules to the minimum that your app needs and filtering out the others, you reduce the toolset that malicious code can use to attack the system.
Note that the safest option is to fully disable the remote module. If you choose to filter access rather than completely disable the module, you must be very careful to ensure that no escalation of privilege is possible through the modules you allow past the filter.
const readOnlyFsProxy = require(/* ... */) // exposes only file read functionality
const allowedModules = new Set(['crypto'])
const proxiedModules = new Map(['fs', readOnlyFsProxy])
const allowedElectronModules = new Set(['shell'])
const allowedGlobals = new Set()
app.on('remote-require', (event, webContents, moduleName) => {
if (proxiedModules.has(moduleName)) {
event.returnValue = proxiedModules.get(moduleName)
}
if (!allowedModules.has(moduleName)) {
event.preventDefault()
}
})
app.on('remote-get-builtin', (event, webContents, moduleName) => {
if (!allowedElectronModules.has(moduleName)) {
event.preventDefault()
}
})
app.on('remote-get-global', (event, webContents, globalName) => {
if (!allowedGlobals.has(globalName)) {
event.preventDefault()
}
})
app.on('remote-get-current-window', (event, webContents) => {
event.preventDefault()
})
app.on('remote-get-current-web-contents', (event, webContents) => {
event.preventDefault()
})
You should strive for always using the latest available version of Electron. Whenever a new major version is released, you should attempt to update your app as quickly as possible.
An application built with an older version of Electron, Chromium, and Node.js is an easier target than an application that is using more recent versions of those components. Generally speaking, security issues and exploits for older versions of Chromium and Node.js are more widely available.
Both Chromium and Node.js are impressive feats of engineering built by thousands of talented developers. Given their popularity, their security is carefully tested and analyzed by equally skilled security researchers. Many of those researchers disclose vulnerabilities responsibly, which generally means that researchers will give Chromium and Node.js some time to fix issues before publishing them. Your application will be more secure if it is running a recent version of Electron (and thus, Chromium and Node.js) for which potential security issues are not as widely known.