Using custom elements
One of the key features of web components is the ability to create custom elements: that is, HTML elements whose behavior is defined by the web developer, that extend the set of elements available in the browser.
This article introduces custom elements, and walks through some examples.
Types of custom element
There are two types of custom element:
-
Customized built-in elements inherit from standard HTML elements such as
HTMLImageElement
orHTMLParagraphElement
. Their implementation extends the behavior of select instances of the standard element.Note: Safari does not plan to support custom built-in elements. See the
is
attribute for more information. -
Autonomous custom elements inherit from the HTML element base class
HTMLElement
. You have to implement their behavior from scratch.
Implementing a custom element
A custom element is implemented as a class which extends HTMLElement
(in the case of autonomous elements) or the interface you want to customize (in the case of customized built-in elements).
Here's the implementation of a minimal custom element that customizes the <p>
element:
class WordCount extends HTMLParagraphElement {
constructor() {
super();
}
// Element functionality written in here
}
Here's the implementation of a minimal autonomous custom element:
class PopupInfo extends HTMLElement {
constructor() {
super();
}
// Element functionality written in here
}
In the class constructor, you can set up initial state and default values, register event listeners and perhaps create a shadow root. At this point, you should not inspect the element's attributes or children, or add new attributes or children. See Requirements for custom element constructors and reactions for the complete set of requirements.
Custom element lifecycle callbacks
Once your custom element is registered, the browser will call certain methods of your class when code in the page interacts with your custom element in certain ways. By providing an implementation of these methods, which the specification calls lifecycle callbacks, you can run code in response to these events.
Custom element lifecycle callbacks include:
connectedCallback()
: called each time the element is added to the document. The specification recommends that, as far as possible, developers should implement custom element setup in this callback rather than the constructor.disconnectedCallback()
: called each time the element is removed from the document.adoptedCallback()
: called each time the element is moved to a new document.attributeChangedCallback()
: called when attributes are changed, added, removed, or replaced. See Responding to attribute changes for more details about this callback.
Here's a minimal custom element that logs these lifecycle events:
// Create a class for the element
class MyCustomElement extends HTMLElement {
static observedAttributes = ["color", "size"];
constructor() {
// Always call super first in constructor
super();
}
connectedCallback() {
console.log("Custom element added to page.");
}
disconnectedCallback() {
console.log("Custom element removed from page.");
}
adoptedCallback() {
console.log("Custom element moved to new page.");
}
attributeChangedCallback(name, oldValue, newValue) {
console.log(`Attribute ${name} has changed.`);
}
}
customElements.define("my-custom-element", MyCustomElement);
Registering a custom element
To make a custom element available in a page, call the define()
method of Window.customElements
.
The define()
method takes the following arguments:
name
-
The name of the element. This must start with a lowercase letter, contain a hyphen, and satisfy certain other rules listed in the specification's definition of a valid name.
constructor
-
The custom element's constructor function.
options
-
Only included for customized built-in elements, this is an object containing a single property
extends
, which is a string naming the built-in element to extend.
For example, this code registers the WordCount
customized built-in element:
customElements.define("word-count", WordCount, { extends: "p" });
This code registers the PopupInfo
autonomous custom element:
customElements.define("popup-info", PopupInfo);
Using a custom element
Once you've defined and registered a custom element, you can use it in your code.
To use a customized built-in element, use the built-in element but with the custom name as the value of the is
attribute:
<p is="word-count"></p>
To use an autonomous custom element, use the custom name just like a built-in HTML element:
<popup-info>
<!-- content of the element -->
</popup-info>
Responding to attribute changes
Like built-in elements, custom elements can use HTML attributes to configure the element's behavior. To use attributes effectively, an element has to be able to respond to changes in an attribute's value. To do this, a custom element needs to add the following members to the class that implements the custom element:
- A static property named
observedAttributes
. This must be an array containing the names of all attributes for which the element needs change notifications. - An implementation of the
attributeChangedCallback()
lifecycle callback.
The attributeChangedCallback()
callback is then called whenever an attribute whose name is listed in the element's observedAttributes
property is added, modified, removed, or replaced.
The callback is passed three arguments:
- The name of the attribute which changed.
- The attribute's old value.
- The attribute's new value.
For example, this autonomous element will observe a size
attribute, and log the old and new values when they change:
// Create a class for the element
class MyCustomElement extends HTMLElement {
static observedAttributes = ["size"];
constructor() {
super();
}
attributeChangedCallback(name, oldValue, newValue) {
console.log(
`Attribute ${name} has changed from ${oldValue} to ${newValue}.`,
);
}
}
customElements.define("my-custom-element", MyCustomElement);
Note that if the element's HTML declaration includes an observed attribute, then attributeChangedCallback()
will be called after the attribute is initialized, when the element's declaration is parsed for the first time. So in the following example, attributeChangedCallback()
will be called when the DOM is parsed, even if the attribute is never changed again:
<my-custom-element size="100"></my-custom-element>
For a complete example showing the use of attributeChangedCallback()
, see Lifecycle callbacks in this page.
Custom states and custom state pseudo-class CSS selectors
Built in HTML elements can have different states, such as "hover", "disabled", and "read only". Some of these states can be set as attributes using HTML or JavaScript, while others are internal, and cannot. Whether external or internal, commonly these states have corresponding CSS pseudo-classes that can be used to select and style the element when it is in a particular state.
Autonomous custom elements (but not elements based on built-in elements) also allow you to define states and select against them using the :state()
pseudo-class function.
The code below shows how this works using the example of an autonomous custom element that has an internal state "collapsed"
.
The collapsed
state is represented as a boolean property (with setter and getter methods) that is not visible outside of the element.
To make this state selectable in CSS the custom element first calls HTMLElement.attachInternals()
in its constructor in order to attach an ElementInternals
object, which in turn provides access to a CustomStateSet
through the ElementInternals.states
property.
The setter for the (internal) collapsed state adds the identifier hidden
to the CustomStateSet
when the state is true
, and removes it when the state is false
.
The identifier is just a string: in this case we called it hidden
, but we could have just as easily called it collapsed
.
class MyCustomElement extends HTMLElement {
constructor() {
super();
this._internals = this.attachInternals();
}
get collapsed() {
return this._internals.states.has("hidden");
}
set collapsed(flag) {
if (flag) {
// Existence of identifier corresponds to "true"
this._internals.states.add("hidden");
} else {
// Absence of identifier corresponds to "false"
this._internals.states.delete("hidden");
}
}
}
// Register the custom element
customElements.define("my-custom-element", MyCustomElement);
We can use the identifier added to the custom element's CustomStateSet
(this._internals.states
) for matching the element's custom state.
This is matched by passing the identifier to the :state()
pseudo-class.
For example, below we select on the hidden
state being true (and hence the element's collapsed
state) using the :hidden
selector, and remove the border.
my-custom-element {
border: dashed red;
}
my-custom-element:state(hidden) {
border: none;
}
The :state()
pseudo-class can also be used within the :host()
pseudo-class function to match a custom state within a custom element's shadow DOM. Additionally, the :state()
pseudo-class can be used after the ::part()
pseudo-element to match the shadow parts of a custom element that is in a particular state.
There are several live examples in CustomStateSet
showing how this works.
Examples
In the rest of this guide we'll look at a few example custom elements. You can find the source for all these examples, and more, in the web-components-examples repository, and you can see them all live at https://mdn.github.io/web-components-examples/.
An autonomous custom element
First, we'll look at an autonomous custom element. The <popup-info>
custom element takes an image icon and a text string as attributes, and embeds the icon into the page. When the icon is focused, it displays the text in a pop up information box to provide further in-context information.
To begin with, the JavaScript file defines a class called PopupInfo
, which extends the HTMLElement
class.
// Create a class for the element
class PopupInfo extends HTMLElement {
constructor() {
// Always call super first in constructor
super();
}
connectedCallback() {
// Create a shadow root
const shadow = this.attachShadow({ mode: "open" });
// Create spans
const wrapper = document.createElement("span");
wrapper.setAttribute("class", "wrapper");
const icon = document.createElement("span");
icon.setAttribute("class", "icon");
icon.setAttribute("tabindex", 0);
const info = document.createElement("span");
info.setAttribute("class", "info");
// Take attribute content and put it inside the info span
const text = this.getAttribute("data-text");
info.textContent = text;
// Insert icon
let imgUrl;
if (this.hasAttribute("img")) {
imgUrl = this.getAttribute("img");
} else {
imgUrl = "img/default.png";
}
const img = document.createElement("img");
img.src = imgUrl;
icon.appendChild(img);
// Create some CSS to apply to the shadow dom
const style = document.createElement("style");
console.log(style.isConnected);
style.textContent = `
.wrapper {
position: relative;
}
.info {
font-size: 0.8rem;
width: 200px;
display: inline-block;
border: 1px solid black;
padding: 10px;
background: white;
border-radius: 10px;
opacity: 0;
transition: 0.6s all;
position: absolute;
bottom: 20px;
left: 10px;
z-index: 3;
}
img {
width: 1.2rem;
}
.icon:hover + .info, .icon:focus + .info {
opacity: 1;
}
`;
// Attach the created elements to the shadow dom
shadow.appendChild(style);
console.log(style.isConnected);
shadow.appendChild(wrapper);
wrapper.appendChild(icon);
wrapper.appendChild(info);
}
}
The class definition contains the constructor()
for the class, which always starts by calling super()
so that the correct prototype chain is established.
Inside the method connectedCallback()
, we define all the functionality the element will have when the element is connected to the DOM. In this case we attach a shadow root to the custom element, use some DOM manipulation to create the element's internal shadow DOM structure — which is then attached to the shadow root — and finally attach some CSS to the shadow root to style it. We don't do this work in the constructor because an element's attributes are unavailable until it is connected to the DOM.
Finally, we register our custom element in the CustomElementRegistry
using the define()
method we mentioned earlier — in the parameters we specify the element name, and then the class name that defines its functionality:
customElements.define("popup-info", PopupInfo);
It is now available to use on our page. Over in our HTML, we use it like so:
<popup-info
img="img/alt.png"
data-text="Your card validation code (CVC)
is an extra security feature — it is the last 3 or 4 numbers on the
back of your card."></popup-info>
Referencing external styles
In the above example we apply styles to the shadow DOM using a <style>
element, but you can reference an external stylesheet from a <link>
element instead. In this example we'll modify the <popup-info>
custom element to use an external stylesheet.
Here's the class definition:
// Create a class for the element
class PopupInfo extends HTMLElement {
constructor() {
// Always call super first in constructor
super();
}
connectedCallback() {
// Create a shadow root
const shadow = this.attachShadow({ mode: "open" });
// Create spans
const wrapper = document.createElement("span");
wrapper.setAttribute("class", "wrapper");
const icon = document.createElement("span");
icon.setAttribute("class", "icon");
icon.setAttribute("tabindex", 0);
const info = document.createElement("span");
info.setAttribute("class", "info");
// Take attribute content and put it inside the info span
const text = this.getAttribute("data-text");
info.textContent = text;
// Insert icon
let imgUrl;
if (this.hasAttribute("img")) {
imgUrl = this.getAttribute("img");
} else {
imgUrl = "img/default.png";
}
const img = document.createElement("img");
img.src = imgUrl;
icon.appendChild(img);
// Apply external styles to the shadow dom
const linkElem = document.createElement("link");
linkElem.setAttribute("rel", "stylesheet");
linkElem.setAttribute("href", "style.css");
// Attach the created elements to the shadow dom
shadow.appendChild(linkElem);
shadow.appendChild(wrapper);
wrapper.appendChild(icon);
wrapper.appendChild(info);
}
}
It's just like the original <popup-info>
example, except that we link to an external stylesheet using a <link>
element, which we add to the shadow DOM.
Note that <link>
elements do not block paint of the shadow root, so there may be a flash of unstyled content (FOUC) while the stylesheet loads.
Many modern browsers implement an optimization for <style>
tags either cloned from a common node or that have identical text, to allow them to share a single backing stylesheet. With this optimization the performance of external and internal styles should be similar.
Customized built-in elements
Now let's have a look at a customized built in element example. This example extends the built-in <ul>
element to support expanding and collapsing the list items.
Note:
Please see the is
attribute reference for caveats on implementation reality of custom built-in elements.
First of all, we define our element's class:
// Create a class for the element
class ExpandingList extends HTMLUListElement {
constructor() {
// Always call super first in constructor
// Return value from super() is a reference to this element
self = super();
}
connectedCallback() {
// Get ul and li elements that are a child of this custom ul element
// li elements can be containers if they have uls within them
const uls = Array.from(self.querySelectorAll("ul"));
const lis = Array.from(self.querySelectorAll("li"));
// Hide all child uls
// These lists will be shown when the user clicks a higher level container
uls.forEach((ul) => {
ul.style.display = "none";
});
// Look through each li element in the ul
lis.forEach((li) => {
// If this li has a ul as a child, decorate it and add a click handler
if (li.querySelectorAll("ul").length > 0) {
// Add an attribute which can be used by the style
// to show an open or closed icon
li.setAttribute("class", "closed");
// Wrap the li element's text in a new span element
// so we can assign style and event handlers to the span
const childText = li.childNodes[0];
const newSpan = document.createElement("span");
// Copy text from li to span, set cursor style
newSpan.textContent = childText.textContent;
newSpan.style.cursor = "pointer";
// Add click handler to this span
newSpan.addEventListener("click", (e) => {
// next sibling to the span should be the ul
const nextUl = e.target.nextElementSibling;
// Toggle visible state and update class attribute on ul
if (nextUl.style.display == "block") {
nextUl.style.display = "none";
nextUl.parentNode.setAttribute("class", "closed");
} else {
nextUl.style.display = "block";
nextUl.parentNode.setAttribute("class", "open");
}
});
// Add the span and remove the bare text node from the li
childText.parentNode.insertBefore(newSpan, childText);
childText.parentNode.removeChild(childText);
}
});
}
}
Note that this time we extend HTMLUListElement
, rather than HTMLElement
. This means that we get the default behavior of a list, and only have to implement our own customizations.
As before, most of the code is in the connectedCallback()
lifecycle callback.
Next, we register the element using the define()
method as before, except that this time it also includes an options object that details what element our custom element inherits from:
customElements.define("expanding-list", ExpandingList, { extends: "ul" });
Using the built-in element in a web document also looks somewhat different:
<ul is="expanding-list">
…
</ul>
You use a <ul>
element as normal, but specify the name of the custom element inside the is
attribute.
Note that in this case we must ensure that the script defining our custom element is executed after the DOM has been fully parsed, because connectedCallback()
is called as soon as the expanding list is added to the DOM, and at that point its children have not been added yet, so the querySelectorAll()
calls will not find any items. One way to ensure this is to add the defer attribute to the line that includes the script:
<script src="main.js" defer></script>
Lifecycle callbacks
So far we've seen only one lifecycle callback in action: connectedCallback()
. In the final example, <custom-square>
, we'll see some of the others. The <custom-square>
autonomous custom element draws a square whose size and color are determined by two attributes, named "size"
and "color"
.
In the class constructor, we attach a shadow DOM to the element, then attach empty <div>
and <style>
elements to the shadow root:
constructor() {
// Always call super first in constructor
super();
const shadow = this.attachShadow({ mode: "open" });
const div = document.createElement("div");
const style = document.createElement("style");
shadow.appendChild(style);
shadow.appendChild(div);
}
The key function in this example is updateStyle()
— this takes an element, gets its shadow root, finds its <style>
element, and adds width
, height
, and background-color
to the style.
function updateStyle(elem) {
const shadow = elem.shadowRoot;
shadow.querySelector("style").textContent = `
div {
width: ${elem.getAttribute("size")}px;
height: ${elem.getAttribute("size")}px;
background-color: ${elem.getAttribute("color")};
}
`;
}
The actual updates are all handled by the lifecycle callbacks. The connectedCallback()
runs each time the element is added to the DOM — here we run the updateStyle()
function to make sure the square is styled as defined in its attributes:
connectedCallback() {
console.log("Custom square element added to page.");
updateStyle(this);
}
The disconnectedCallback()
and adoptedCallback()
callbacks log messages to the console to inform us when the element is either removed from the DOM, or moved to a different page:
disconnectedCallback() {
console.log("Custom square element removed from page.");
}
adoptedCallback() {
console.log("Custom square element moved to new page.");
}
The attributeChangedCallback()
callback is run whenever one of the element's attributes is changed in some way. As you can see from its parameters, it is possible to act on attributes individually, looking at their name, and old and new attribute values. In this case however, we are just running the updateStyle()
function again to make sure that the square's style is updated as per the new values:
attributeChangedCallback(name, oldValue, newValue) {
console.log("Custom square element attributes changed.");
updateStyle(this);
}
Note that to get the attributeChangedCallback()
callback to fire when an attribute changes, you have to observe the attributes. This is done by specifying a static get observedAttributes()
method inside the custom element class - this should return an array containing the names of the attributes you want to observe:
static get observedAttributes() {
return ["color", "size"];
}