Custom Elements
The dist-custom-elements
output target is used to generate custom elements in a more optimized way for tree shaking, and its the recommended approach when using any frontend framework integrations. For example, if a component library has 100 components, but an external project only imported one component from the directory, then only the code used by that one component would be pulled into the project. This is due to Stencil's use of ES Modules and the compiler generating friendly code for bundlers to parse and understand.
outputTargets: [
{
type: 'dist-custom-elements',
},
];
Defining Exported Custom Elements
By default, the custom elements files will be written to
dist/components/
.
This directory can be configured using the output target's
dir
config. The
generated files will each export a component class and will already have the
styles bundled. However, this build does not define the custom elements or
apply any polyfills. Any dependencies of your imported component will need to
be loaded as well.
Below is an example of defining a custom element:
import { HelloWorld } from 'my-library/dist/components/hello-world';
customElements.define('hello-world', HelloWorld);
The output directory will also contain an
index.js
file which exports all of
your components and their respective
defineCustomElement
helper functions,
looking something like this:
export { setAssetPath, setPlatformOptions } from '@stencil/core/internal/client';
export { MyComponent, defineCustomElement as defineCustomElementMyComponent } from './my-component.js';
export {
MyOtherComponent,
defineCustomElement as defineCustomElementMyOtherComponent
} from './my-other-component.js';
This file can be used as the root module when distributing your component library, see below for more details.
Config
autoDefineCustomElements
By default, consumers of the
dist-custom-elements
output target need to
register each Stencil component that they want to use in the bundle manually.
Setting this flag to
true
will define a component automatically with the
CustomElementRegistry
when the component's module is imported. Note that this
will also automatically recursively define any child components as well.
This flag defaults to false
when omitted from a Stencil configuration file.
Note: At this time, components that do not use JSX cannot be automatically defined. This is a known limitation of Stencil that users should be aware of.
externalRuntime
When
true
, this flag results in the following behaviors:
- Minification will follow what is specified in the Stencil config.
- Filenames will not be hashed.
- All imports from packages under
@stencil/core/*
will be marked as external and therefore not included in the generated Rollup bundle.
This flag defaults to true
when omitted from a Stencil configuration file.
generateTypeDeclarations
By default, type declaration files (.d.ts
files) are only generated for the dist-custom-elements
output target when
the
dist
output target is also declared in a Stencil project's configuration. This behavior
isn't always desirable, as not all users need the files emitted by the
dist
output target. To generate type
declaration files for the
dist-custom-elements
, the experimental
generateTypeDeclarations
field can be set to
true
.
Setting this flag to true
will generate type declaration files for the
dist-custom-elements
output target. Type
declaration files will be placed in the
dist/types
directory in the root of a Stencil project. At this time, this
output destination is not able to be configured.
This flag defaults to false
when omitted from a Stencil configuration file.
Making Assets Available
For performance reasons, the generated bundle does not include
local assets built within the JavaScript output,
but instead it's recommended to keep static assets as external files. By keeping them external this ensures they can be requested on-demand, rather
than either welding their content into the JS file, or adding many URLs for the bundler to add to the output.
One method to ensure
assets are available to external builds and http servers is to set the asset path using
setAssetPath()
.
The setAssetPath()
function is used to manually set the base path where static assets can be found.
For the lazy-loaded output target the asset path is automatically set and assets copied to the correct
build directory. However, for custom elements builds, the
setAssetPath(path)
should be
used to customize the asset path depending on where they are found on the http server.
If the component's script is a type="module"
, it's recommended to use
import.meta.url
, such
as
setAssetPath(import.meta.url)
. Other options include
setAssetPath(document.currentScript.src)
, or using a bundler's replace plugin to
dynamically set the path at build time, such as
setAssetPath(process.env.ASSET_PATH)
.
import { setAssetPath } from 'my-library/dist/components';
setAssetPath(document.currentScript.src);
Make sure to copy the assets over to a public directory in your app. This configuration depends on how your script is bundled, or lack of bundling, and where your assets can be loaded from. How the files are copied to the production build directory depends on the bundler or tooling. The configs below provide examples of how to do this automatically with popular bundlers.
Distributing Custom Elements
Your component library can be distributed on NPM, just like
@ionic/core
. From there,
consumers of your library can decide how to import your library into their
project. For the
dist-custom-elements
output target, the default import
location would be
my-library/dist/components
, but this can get further
configured within the
package.json
file.
To make the custom elements index the entry module for a package, set the
module
property like so in your
package.json
:
{
"module": "dist/components/index.js",
"dependencies": {
"@stencil/core": "latest"
},
...
}
Be sure to set @stencil/core
as a dependency of the package as well.
Note: If you are distributing the output of both the
dist
anddist-custom-elements
targets, then it's up to you to choose which one of them should be available in themodule
entry.
Consumers of your library can then either import components from their individual files, like so:
import { MyComponent } from 'best-web-components/dist/components/my-component';
Or they can import directly from the index module (dist/components/index.js
),
like so:
import { MyComponent } from 'best-web-components';
Now you can publish your library to Node Package Manager
(NPM). For more information about setting up the
package.json
file, and publishing, see:
Publishing Component Library To
NPM.
Usage in Typescript
If you plan to support consuming your component library in Typescript you'll
need to set
generateTypeDeclarations: true
on the your output target in
stencil.config.ts
, like so:
outputTargets: [
{
type: 'dist-custom-elements',
generateTypeDeclarations: true,
},
];
Then you can set the types
property in
package.json
so that consumers of
your package can find the type definitions, like so:
{
"module": "dist/components/index.js",
"types": "dist/components/index.d.ts",
"dependencies": {
"@stencil/core": "latest"
},
...
}
Example Bundler Configs
Instructions for consuming the custom elements bundle vary depending on the bundler you're using. These examples will help your users consume your components with webpack and Rollup.
The following examples assume your component library is published to NPM as
my-library
. You should change this to the name you actually publish your library with.
Users will need to install your library before importing them.
npm install my-library
webpack.config.js
A webpack config will look something like the one below. Note how assets are copied from the library's
node_module
folder to dist/assets
via the
CopyPlugin
utility. This is important if your library includes
local assets.
const path = require('path');
const CopyPlugin = require('copy-webpack-plugin');
module.exports = {
entry: './src/index.js',
output: {
filename: 'main.js',
path: path.resolve(__dirname, 'dist'),
},
module: {
rules: [
{
test: /\.css$/i,
use: ['style-loader', 'css-loader'],
},
],
},
plugins: [
new CopyPlugin({
patterns: [
{
from: path.resolve(__dirname, 'node_modules/my-library/dist/my-library/assets'),
to: path.resolve(__dirname, 'dist/assets'),
},
],
}),
],
};
rollup.config.js
A Rollup config will look something like the one below. Note how assets are copied from the library's
node_module
folder to dist/assets
via the
rollup-copy-plugin
utility. This is important if your library includes
local assets.
import path from 'path';
import commonjs from '@rollup/plugin-commonjs';
import copy from 'rollup-plugin-copy';
import postcss from 'rollup-plugin-postcss';
import resolve from '@rollup/plugin-node-resolve';
export default {
input: 'src/index.js',
output: [{ dir: path.resolve('dist/'), format: 'es' }],
plugins: [
resolve(),
commonjs(),
postcss({
extensions: ['.css'],
}),
copy({
targets: [
{
src: path.resolve(__dirname, 'node_modules/my-library/dist/my-library/assets'),
dest: path.resolve(__dirname, 'dist'),
},
],
}),
],
};
How is this different from the "dist" and the "dist-custom-element-bundle" output targets?
The dist-custom-elements
builds each component as a stand-alone class that extends
HTMLElement
. The output is a standardized custom element with the styles already attached and without any of Stencil's lazy-loading. This may be preferred for projects that are already handling bundling, lazy-loading and defining the custom elements themselves.
The dist-custom-elements-bundle
output target is nearly the same as
dist-custom-elements
, and has been deprecated in
Stencil v2.12.0 in favor of dist-custom-elements
for its improved tree-shaking features. Stencil's React, Vue, and Angular output targets use the
dist-custom-elements
for this reason.
The dist
output target, on the other hand, is more for projects that want to allow components to lazy-load themselves, without having to setup bundling configurations to do so.
Luckily, all builds can be generated at the same time, using the same source code, and shipped in the same distribution. It would be up to the consumer of your component library to decide which build to use.
Browser Support
If the library is to be used on IE11 we recommend using the
dist
output target instead since it will only load the required polyfills on-demand. The
dist-custom-elements
is only recommended for modern browsers that already support Custom Elements, Shadow DOM, and CSS Variables (basically not IE11 or Edge 12-18). If this build is going to be used within legacy browsers then the project consuming these components will have to provide its own polyfills, and correctly downlevel the output to ES5.
Good news is that these are already widely supported for modern web development:
Contributors
Contents
Defining Exported Custom Elements Config autoDefineCustomElements externalRuntime generateTypeDeclarations Making Assets Available Distributing Custom Elements Usage in Typescript Example Bundler Configs webpack.config.js rollup.config.js How is this different from the "dist" and the "dist-custom-element-bundle" output targets? Browser Support
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