core is a library to create powerful, composable user interface widgets.
- Reactive & unidirectional: Follows core reactive principles to ensure predictable, consistent behavior.
- Encapsulated Widgets: Create independent encapsulated widgets that can be wired together to create complex and beautiful user interfaces.
- DOM Abstractions: Provides API abstractions to avoid needing to access or manipulate the DOM outside of the reactive render life-cycle.
- I18n & Themes: Provides core mixins to enable internationalization and theming support for your widgets.
Dojo applications use the Virtual DOM (vdom) paradigm to represent what should be shown on the view. These vdom nodes are plain JavaScript objects that are more efficient to create from a performance perspective than browser DOM elements. Dojo uses these vdom elements to synchronize and update the browser DOM so that the application shows the expected view.
There are two types of vdom within Dojo. The first type provides a pure representation of DOM elements, the fundamental building blocks of all Dojo applications. These are called VNode
s and are created using the v()
function available from the @dojo/framework/core/d
module.
The following will create a VNode
that represents a simple div
DOM element, with a text node child: Hello, Dojo!
:
v('div', ['Hello, Dojo!']);
The second vdom type, WNode
, represent widgets. A widget is a class that extends WidgetBase
from @dojo/framework/core/WidgetBase
and implements a render
function that returns one of the Dojo vdom types (known as a DNode
). Widgets are used to represent reusable, independent sections of a Dojo application.
The following returns the VNode
example from above from the render
function:
class HelloDojo extends WidgetBase {
protected render() {
return v('div', ['Hello, Dojo!']);
}
}
To display your new component in the view you will to use the renderer
from the @dojo/framework/core/vdom
module. The renderer
function accepts function that returns your component using the w()
pragma and calling .mount()
on the returned API.
import renderer from '@dojo/framework/core/vdom';
import { w } from '@dojo/framework/core/vdom';
const r = renderer(() => w(HelloDojo, {}));
r.mount();
renderer#mount
accepts an optional argument of MountOptions
that controls configuration of the mount operation.
interface MountOptions {
sync: boolean; // (default `false`)
merge: boolean; // (default `true`)
domNode: HTMLElement; // (default `document.body)
transition: TransitionStrategy; // (default `cssTransitions`)
}
The renderer by default mounts to the document.body
in the DOM, but this can be overridden by passing the preferred target dom node to the .mount()
function.
Consider the following in your HTML file:
<div id="my-app"></div>
You can target this Element:
import renderer from '@dojo/framework/core/vdom';
import { w } from '@dojo/framework/core/vdom';
const root = document.getElementById('my-app');
const r = renderer(() => w(HelloDojo, {}));
r.mount({ domNode: root });
We have created a widget used to project our VNode
s into the DOM, however, widgets can be composed of other widgets and properties
which are used to determine if a widget needs to be re-rendered.
Properties are available on the widget instance, defined by an interface and passed as a generic
to the WidgetBase
class when creating your custom widget.
interface MyProperties {
name: string;
}
class Hello extends WidgetBase<MyProperties> {
protected render() {
const { name } = this.properties;
return v('div', [`Hello, ${name}`]);
}
}
Note: By default widgets have a key: string | number
property, when using a custom property interface the default property is still available, there is no need to extend WidgetProperties
.
New properties are compared with the previous properties to determine if a widget requires re-rendering. By default Dojo uses the auto
diffing strategy, that performs a shallow comparison for objects and arrays, ignores functions (except classes that extend WidgetBase
) and a reference comparison for all other values.
It is common for widgets to maintain internal state, that directly affects the results of the render output or passed as properties to child widgets. The most common pattern is that an action (often user initiated via an event) occurs which updates the internal state leaving the user to manually call this.invalidate()
to trigger a re-render.
For class properties that always need to trigger a re-render when they're updated, a property decorator, @watch
can be used, which implicitly calls this.invalidate
each time the property is set.
import WidgetBase from '@dojo/framework/core/WidgetBase';
import watch from '@dojo/framework/core/decorators/watch';
class Counter extends WidgetBase {
@watch()
private _count = 0;
private _increment() {
this._count = this._count + 1; // this automatically calls invalidate
}
protected render() {
return v('div', [
v('button', { onclick: this._increment }, [ 'Increment' ]),
`${this._count}`)
]);
}
}
As mentioned, often widgets are composed of other widgets in their render
output. This promotes widget reuse across an application (or multiple applications) and promotes widget best practices.
To compose widgets, we need to create WNode
s and we can do this using the w()
function from @dojo/framework/core/d
.
Consider the previous Hello
widget that we created:
class App extends WidgetBase {
protected render() {
return v('div', [
w(Hello, { name: 'Bill' }),
w(Hello, { name: 'Bob' }),
w(Hello, { name: 'Flower pot men' })
]);
}
}
We can now use App
with the renderer
to display the Hello
widgets.
const r = renderer(() => w(App, {}));
r.mount({ domNode: root });
Splitting widgets into multiple smaller widgets is easy and helps to add extended functionality and promotes reuse.
Consider the following List
widget, which has a simple property interface of an array of items consisting of content: string
and highlighted: boolean
.
interface ListProperties {
items: {
id: string;
content: string;
highlighted: boolean;
};
}
class List extends WidgetBase<ListProperties> {
protected render() {
const { items } = this.properties;
return v('ul', { classes: 'list' }, items.map((item) => {
const { id, highlighted, content } = item;
const classes = [ highlighted ? 'highlighted' : null ];
return v('li', { key: id, classes }, [ content ]);
});
}
}
The List
widget works as expected and displays the list in the browser but is difficult to reuse, modify, and/or extend.
Note: When working with children arrays with the same type of widget or Element, it is important to add a unique key
property or attribute so that Dojo can identify the correct node when updates are made.
To extend the List
API with an event that needs to be called when an item is clicked with the item's id
, we first update the properties interface:
interface ListProperties {
items: {
id: string;
content: string;
highlighted: boolean;
};
onItemClick: (id: string) => void;
}
If we try to use the onItemClick
function in the current List
widget, we would need to wrap it in another function in order to pass the item's id
.
This would mean a new function would be created every render but Dojo does not support changing listener functions after the first render and this would error.
To resolve this, the list item can be extracted into a separate widget:
import { WidgetBase } from '@dojo/framework/core/WidgetBase';
import { v, w } from '@dojo/framework/core/vdom';
interface ListItemProperties {
id: string;
content: string;
highlighted: boolean;
onItemClick(id: string): void;
}
export default class ListItem extends WidgetBase<ListItemProperties> {
protected onClick(event: MouseEvent) {
const { id } = this.properties;
this.properties.onItemClick(id);
}
protected render() {
const { id, content, highlighted } = this.properties;
const classes = [highlighted ? 'highlighted' : null];
return v('li', { key: id, classes, onclick: this.onClick }, [content]);
}
}
Using the ListItem
we can simplify the List
slightly and also add the onclick
functionality that we required:
interface Item {
id: string;
content: string;
highlighted: boolean;
}
interface ListProperties {
items: Item[];
onItemClick(id: string): void;
}
export default class List extends WidgetBase<ListProperties> {
protected render() {
const { onItemClick, items } = this.properties;
return v(
'ul',
{ classes: 'list' },
items.map(({ id, content, highlighted }) => {
return w(ListItem, { key: id, id, content, highlighted, onItemClick });
})
);
}
}
Additionally, the ListItem
is now reusable in other areas of our application(s).
Dojo makes use of mixins to decorate additional functionality and properties to existing widgets. Mixins provide a mechanism that allows loosely coupled design and composition of behaviors into existing widgets without having to change the base widget.
TypeScript supports mixins using a constructor type of new (...args: any[]) => any;
that enables a class to be passed as a function argument and extended to add new functionality.
Example mixin that adds method setState
and readonly
state
property:
// interface for the extended API
interface StateMixin {
readonly state: Readonly<any>;
setState(state: any): void;
}
// function that accepts a class that extends `WidgetBase` and returns the extended class with the `StateMixin`
// behavior
function StateMixin<T extends new (...args: any[]) => WidgetBase>(Base: T): T & (new (...args: any[]) => StateMixin) {
return class extends Base {
private _state: any;
public setState(state: any): void {
// shallow copy of the state
this._state = { ...this._state, ...state };
// invalidate the widget
this.invalidate();
}
public get state(): any {
return this._state;
}
};
}
Examples of Dojo mixins can be seen with ThemedMixin
and I18nMixin
that are described in Styling & Theming and Internationalization sections.
Dojo core provides a WebAnimation
meta to apply web animations to VNodes.
To specify the web animations pass an AnimationProperties
object to the WebAnimation
meta along with the key of the node you wish to animate. This can be a single animation or an array or animations.
Note: The Web Animations API is not currently available even in the latest browsers. To use the Web Animations API, a polyfill needs to be included. Dojo does not include the polyfill by default, so will need to be added as a script tag in your index.html or alternatively imported in the application’s main.ts using import 'web-animations-js/web-animations-next-lite.min';
after including the dependency in your source tree, or by importing @dojo/framework/shim/browser
.
export default class AnimatedWidget extends WidgetBase {
protected render() {
const animate = {
id: 'rootAnimation',
effects: [{ height: '10px' }, { height: '100px' }],
controls: {
play: true
}
};
this.meta(WebAnimation).animate('root', animate);
return v('div', {
key: 'root'
});
}
}
controls
and timing
are optional properties and are used to setup and control the animation. The timing
property can only be set once, but the controls
can be changed to apply stop, start, reverse, and other actions on the web animation.
Animations can be changed on each widget render in a reactive pattern, for example changing the animation from slideUp
to slideDown
on a title pane depending on the titlepane being open or not.
export default class AnimatedWidget extends WidgetBase {
private _open = false;
protected render() {
const animate = this._open
? {
id: 'upAnimation',
effects: [{ height: '100px' }, { height: '0px' }],
controls: {
play: true
}
}
: {
id: 'downAnimation',
effects: [{ height: '0px' }, { height: '100px' }],
controls: {
play: true
}
};
this.meta(WebAnimation).animate('root', animate);
return v('div', {
key: 'root'
});
}
}
An effects
function can be passed to the animation and evaluated at render time. This allows you to create programmatic effects such as those depending on measurements from the Dimensions
Meta
.
export default class AnimatedWidget extends WidgetBase {
private _getEffect() {
const { scroll } = this.meta(Dimensions).get('content');
return [{ height: '0px' }, { height: `${scroll.height}px` }];
}
protected render() {
const animate = {
id: 'upAnimation',
effects: this._getEffect(),
controls: {
play: true
}
};
this.meta(WebAnimation).animate('root', animate);
return v('div', {
key: 'root'
});
}
}
The WebAnimation
meta provides a get
function that can be used to retrieve information about an animation via its id
.
This info contains the currentTime, playState, playbackRate and startTime of the animation. If no animation is found or the animation has been cleared this will return undefined.
export default class AnimatedWidget extends WidgetBase {
protected render() {
const animate = {
id: 'rootAnimation',
effects: [{ height: '10px' }, { height: '100px' }],
controls: {
play: true
}
};
this.meta(WebAnimation).animate('root', animate);
const info = this.meta(WebAnimation).get('rootAnimation');
return v('div', {
key: 'root'
});
}
}
Dojo core provides ThemedMixin
to decorate a widget with theming functionality and a @theme
decorator to specify the classes available to the widget. Both ThemedMixin
and @theme
are provided by @dojo/framework/core/mixins/Themed
.
To specify the theme classes for a widget, an interface needs to be imported with named exports for each class and passed to the @theme
decorator. Importing the interface provides IntelliSense / auto-complete for the class names and passing this via the @theme
decorator informs the ThemedMixin
which classes can be themed.
Example CSS classes interface
export const classNameOne: string;
export const classNameTwo: string;
Important: at runtime, a JavaScript file is required to provide the processed CSS class names.
The ThemedMixin
provides a method available on the instance this.theme()
takes a single argument that is either a string
class name or an array of string
class names and returns the theme's equivalent class names as either a single string or array of strings.
However, it is not always desirable to allow consumers to override styling that may be required for a widget to function correctly. These classes can be added directly to the classes
array in VirtualDomProperties
.
The following example passes css.root
that will be themeable and css.rootFixed
that cannot be overridden.
import * as css from './styles/myWidget.m.css';
import { ThemedMixin, theme } from '@dojo/framework/core/mixins/Themed';
@theme(css)
export default class MyWidget extends ThemedMixin(WidgetBase) {
protected render() {
return v('div', { classes: [this.theme(css.root), css.rootFixed] });
}
}
If an array is passed to this.theme
then an array will be returned. For example, this.theme([ css.root, css.other ])
will return an array containing the theme's class names [ 'themedRoot', 'themedOther' ]
.
Themes are TypeScript modules that export an object that contains css-modules files keyed by a widgets CSS file name.
/* myTheme/styles/myWidget.m.css */
.root {
color: blue;
}
// myTheme/theme.ts
import * as myWidget from './styles/myWidget.m.css';
export default {
myWidget: myWidget
};
In the above example, the new root
class provided by the theme for myWidget
will replace the root
class that was provided by the original myWidget.m.css
. This means the myWidget
will now have its color set to blue, but will no longer receive the styles from the root
class in the original CSS.
To apply a theme to a widget, simply require it as a module and pass it to a widget via its properties. It is important to ensure that any child widgets created within your widget's render function are passed the theme
or they will not be themed.
// app.ts
import myTheme from './myTheme/theme';
// ...
render() {
return w(TabPanel, { theme: myTheme } });
}
The theming mechanism is great for consistently applying custom styles across every widget, but isn't flexible enough for individual cases when a user wants to apply additional styles for a specific widget or widgets.
To apply extra classes to a widget and any child widget that they leverage, the Themed
mixins adds an extra property, classes
to the widget API. This property can be used to pass extra classes that target specific classes used within a widget. It is the widget author's responsibility to explicitly pass the classes
property to all children widget as this is not injected or automatically passed to children.
Each set of classes is keyed by the widget key (the same structure as the Theme object) to identify the widget to which the classes get applied.
interface Classes {
[widgetKey: string]: {
[className: string]: string | null | undefined;
}
}
const myExtraClasses = {
'@dojo/widgets/icon': {
root: [css.extraRoot]
},
'@dojo/widgets/button': {
root: [css.extraRoot]
}
}
// example render method
render() {
return w(Button, { classes: myExtraClasses });
}
Note: The widget key is constructed by the package name from the package.json
and the widget name, i.e. the Icon
widget from @dojo/widgets
has a key of @dojo/widget/icon
or a widget called Spinner
from a package called all-the-dojo-spinners
would have a key of all-the-dojo-spinners/spinners
.
Please refer to the I18n reference guide for details on how to to internationalize Dojo widgets and applications.
These are some of the important principles to keep in mind when creating and using widgets:
- The widget's
__render__
,__setProperties__
,__setChildren__
functions should never be called or overridden.- These are the internal methods of the widget APIs and their behavior can change in the future, causing regressions in your application.
- You should never need to deal directly with widget instances
- The Dojo widget system manages all instances required including caching and destruction, trying to create and manage other widgets will cause issues and will not work as expected.
- Never update
properties
within a widget instance, they should be considered pure.- Properties are considered read-only and should not be updated within a widget instance, updating properties could cause unexpected behavior and introduce bugs in your application.
- Hyperscript should always be written using the
@dojo/framework/core/d#v()
function.- The core abstraction for Hyperscript is the only type of vdom that core can process for standard DOM elements, any other mechanism will not work properly or at all.
This section provides some details on more advanced Dojo functionality and configuration that may be required to build more complex widgets and applications.
Handling focus is an important aspect in any application and can be tricky to do correctly. To help with this issue, @dojo/framework/core
provides a primitive mechanism built into the Virtual DOM system that enables users to focus a Virtual DOM node once it has been appended to the DOM. This uses a special property called focus
on the VNodeProperties
interface that can be passed when using v()
. The focus
property is either a boolean
or a function that returns a boolean
.
When passing a function, focus will be called when true
is returned without comparing the value of the previous result. However, when passing a boolean
, focus will only be applied if the property is true
and the previous property value was not.
// Call focus for the node on the only first render
v('input', { type: 'text', focus: true });
// Call focus for the node on every render
v('input', { type: 'text', focus: () => true) })
This primitive is a base that enables further abstractions to be built to handle more complex behaviors. One of these is handling focus across the boundaries of encapsulated widgets. The FocusMixin
should be used by widgets to provide focus
to their children or to accept focus
from a parent widget.
The FocusMixin
adds focus
and shouldFocus
to a widget's API. shouldFocus
checks if the widget is in a state to perform a focus action and will only return true
once, until the widget's focus
method has been called again. This shouldFocus
method is designed to be passed to child widgets or nodes as the value of their focus
property.
When shouldFocus
is passed to a widget, it will be called as the properties are set on the child widget, meaning that any other usages of the parent's shouldFocus
method will result in a return value of false
.
An example usage controlling focus across child VNodes (DOM) and WNodes (widgets):
interface FocusInputChildProperties {
onFocus: () => void;
}
class FocusInputChild extends Focus(WidgetBase)<FocusInputChildProperties> {
protected render() {
// the child widget's `this.shouldFocus` is passed directly to the input node's focus property
return v('input', { onfocus: this.properties.onFocus, focus: this.shouldFocus });
}
}
class FocusParent extends Focus(WidgetBase) {
private _focusedInputKey = 0;
private _onFocus(key: number) {
this._focusedInputKey = key;
this.invalidate();
}
private _previous() {
if (this._focusedInputKey === 0) {
this._focusedInputKey = 4;
} else {
this._focusedInputKey--;
}
// calling focus resets the widget so that `this.shouldFocus`
// will return true on its next use
this.focus();
}
private _next() {
if (this._focusedInputKey === 4) {
this._focusedInputKey = 0;
} else {
this._focusedInputKey++;
}
// calling focus resets the widget so that `this.shouldFocus`
// will return true on its next use
this.focus();
}
protected render() {
return v('div', [
v('button', { onclick: this._previous }, ['Previous']),
v('button', { onclick: this._next }, ['Next']),
// `this.shouldFocus` is passed to the child that requires focus based on
// some widget logic. If the child is a widget it can then deal with that
// in whatever manner is necessary. The widget may also have internal
// logic and pass its own `this.shouldFocus` down further or it could apply
// directly to a VNode child.
w(FocusInputChild, {
key: 0,
focus: this._focusedInputKey === 0 ? this.shouldFocus : undefined,
onFocus: () => this._onFocus(0)
}),
w(FocusInputChild, {
key: 1,
focus: this._focusedInputKey === 1 ? this.shouldFocus : undefined,
onFocus: () => this._onFocus(1)
}),
w(FocusInputChild, {
key: 2,
focus: this._focusedInputKey === 2 ? this.shouldFocus : undefined,
onFocus: () => this._onFocus(2)
}),
w(FocusInputChild, {
key: 3,
focus: this._focusedInputKey === 3 ? this.shouldFocus : undefined,
onFocus: () => this._onFocus(3)
}),
v('input', {
key: 4,
focus: this._focusedInputKey === 4 ? this.shouldFocus : undefined,
onfocus: () => this._onFocus(4)
})
]);
}
}
Controlling the diffing strategy can be done at an individual property level using the diffProperty
decorator on a widget class.
core
provides a set of diffing strategy functions from @dojo/framework/core/diff.ts
that can be used. When these functions do not provide the required functionality a custom diffing function can be provided. Properties that have been configured with a specific diffing type will be excluded from the automatic diffing.
Diff Function | Description |
---|---|
always |
Always report a property as changed. |
auto |
Ignore functions (except classes that extend WidgetBase ), shallow compare objects, and reference compare all other values. |
ignore |
Never report a property as changed. |
reference |
Compare values by reference (old === new ) |
shallow |
Treat the values as objects and compare their immediate values by reference. |
Important: All diffing functions should be pure functions and are called WITHOUT any scope.
// using a diff function provided by core#diff
@diffProperty('title', reference)
class MyWidget extends WidgetBase<MyProperties> {}
//custom diff function; A pure function with no side effects.
function customDiff(previousProperty: string, newProperty: string): PropertyChangeRecord {
return {
changed: previousProperty !== newProperty,
value: newProperty
};
}
// using a custom diff function
@diffProperty('title', customDiff)
class MyWidget extends WidgetBase<MyProperties> {}
It can be necessary to perform some internal logic when one or more properties change, this can be done by registering a reaction callback.
A reaction function is registered using the diffProperty
decorator on a widget class method. This method will be called when the specified property has been detected as changed and receives both the old and new property values.
class MyWidget extends WidgetBase<MyProperties> {
@diffProperty('title', auto)
protected onTitleChange(previousProperties: any, newProperties: any): void {
this._previousTitle = previousProperties.title;
}
}
diffProperty
decorators can be stacked on a single class method and will be called if any of the specified properties are considered changed.
class MyWidget extends WidgetBase<MyProperties> {
@diffProperty('title', auto)
@diffProperty('subtitle', auto)
protected onTitleOrSubtitleChange(previousProperties: any, newProperties: any): void {
this._titlesUpdated = true;
}
}
For non-decorator environments (Either JavaScript/ES6 or a TypeScript project that does not have the experimental decorators configuration set to true in the tsconfig
), the functions need to be registered in the constructor using the addDecorator
API with diffProperty
as the key.
class MyWidget extends WidgetBase {
constructor() {
super();
diffProperty('foo', auto, this.diffFooReaction)(this);
}
diffFooReaction(previousProperty: any, newProperty: any) {
// do something to reaction to a diff of foo
}
}
The Registry
provides a mechanism to define widgets and injectors (see the Containers & Injectors
section), that can be dynamically/lazily loaded on request. Once the registry widget is loaded all widgets that need the newly loaded widget will be invalidated and re-rendered automatically.
A main registry can be provided to the renderer
, which will be automatically passed to all widgets within the tree (referred to as baseRegistry
). Each widget also gets access to a private Registry
instance that can be used to define registry items that are scoped to the widget. The locally defined registry items are considered a higher precedence than an item registered in the baseRegistry
.
import { Registry } from '@dojo/framework/core/Registry';
import { w } from '@dojo/framework/core/vdom';
import MyWidget from './MyWidget';
import MyAppContext from './MyAppContext';
import App from './App';
const registry = new Registry();
registry.define('my-widget', MyWidget);
registry.defineInjector('my-injector', (invalidator) => {
const appContext = new MyAppContext(invalidator);
return () => appContext;
});
const r = renderer(() => w(App, {}));
r.registry = registry;
In some scenarios, it might be desirable to allow the baseRegistry
to override an item defined in the local registry
. Use true as the second argument of the registry.get function to override the local item.
The Registry will automatically detect and handle widget constructors as default exports for imported esModules for you.
A registry decorator is provided to make adding widgets to a local registry easier. The decorator can be stacked to register multiple entries.
// single entry
@registry('loading', LoadingWidget)
class MyWidget extends WidgetBase {
render() {
if (this.properties) {
const LoadingWidget = this.registry.get('loading', true);
return w(LoadingWidget, {});
}
return w(MyActualChildWidget, {});
}
}
// multiple entries
@registry('loading', LoadingWidget)
@registry('heading', () => import('./HeadingWidget'))
class MyWidget extends WidgetBase {
render() {
if (this.properties) {
const LoadingWidget = this.registry.get('loading', true);
return w(LoadingWidget, {});
}
return w(MyActualChildWidget, {}, [w('heading', {})]);
}
}
The registry can handle the detection of imported esModules for you that have the widget constructor as the default export. This means that your callback function can simply return the import
call. If the widget constructor is not the default export you will need to pass it manually.
@registry('Button', () => import('./Button')) // default export
@registry('Table', async () => {
const module = await import('./HeadingWidget');
return module.table;
})
class MyWidget extends WidgetBase {}
Occasionally, in a mixin or a widget class, it may be required to provide logic that needs to be executed before properties are diffed using beforeProperties
, either side of a widget's render
call using beforeRender
& afterRender
or after a constructor using afterContructor
.
This functionality is provided by the beforeProperties
, beforeRender
, afterRender
and afterConstructor
decorators that can be found in the decorators
directory.
Note: All lifecycle functions are executed in the order that they are specified from the superclass up to the final class.
The beforeProperties
lifecycle hook is called immediately before property diffing is executed. Functions registered for beforeProperties
receive properties
and are required to return any updated, changed properties
that are mixed over (merged) the existing properties.
As the lifecycle is executed before the property diffing is completed, any new or updated properties will be included in the diffing phase.
An example that demonstrates adding an extra property based on the widgets current properties, using a function declared on the widget class myBeforeProperties
:
class MyClass extends WidgetBase<MyClassProperties> {
@beforeProperties()
protected myBeforeProperties(properties: MyClassProperties): MyClassProperties {
if (properties.type === 'myType') {
return { extraProperty: 'foo' };
}
return {};
}
}
The alwaysRender
decorator is used to force a widget to always render regardless of whether the widget's properties are considered different.
@alwaysRender()
class MyClass extends WidgetBase {}
The beforeRender
lifecycle hook receives the widget's render
function, properties
, and children
and is expected to return a function that satisfies the render
API. The properties
and children
are passed to enable them to be manipulated or decorated prior to render
being called.
Note: When properties
are changed during the beforeRender
lifecycle, they do not go through the standard property diffing provided by WidgetBase
. If the changes to the properties
need to go through diffing, consider using the beforeProperties
lifecycle hook.
class MyClass extends WidgetBase {
@beforeRender()
protected myBeforeRender(renderFunc: () => DNode, properties: any, children: DNode[]): () => DNode {
// decorate/manipulate properties or children.
properties.extraAttribute = 'foo';
// Return or replace the `render` function
return () => {
return v('my-replaced-attribute');
};
}
}
The afterRender
lifecycle hook receives the returned DNode
s from a widget's render
call so that the nodes can be decorated, manipulated or swapped completely.
class MyBaseClass extends WidgetBase {
@afterRender()
myAfterRender(result: DNode): DNode {
// do something with the result
return result;
}
}
These lifecycle hooks are used by overriding methods in a widget class. Currently, onAttach
and onDetach
are supported and provide callbacks for when a widget has been first attached and removed (destroyed) from the virtual dom.
onAttach
is called once when a widget is first rendered and attached to the DOM.
class MyClass extends WidgetBase {
onAttach() {
// do things when attached to the DOM
}
}
onDetach
is called when a widget is removed from the widget tree and therefore the DOM. onDetach
is called recursively down the tree to ensure that even if a widget at the top of the tree is removed all the child widgets onDetach
callbacks are fired.
class MyClass extends WidgetBase {
onDetach() {
// do things when removed from the DOM
}
}
There is built-in support for side-loading/injecting values into sections of the widget tree and mapping them to a widget's properties. This is achieved by registering an injector factory with a registry
and setting the registry on the application's renderer
to ensure the registry instance is available to your application.
Create a factory function for a function that returns the required payload
.
registry.defineInjector('my-injector', () => {
return () => ({ foo: 'bar' });
});
The injector factory gets passed an invalidator
function that can get called when something has changed that requires connected widgets to invalidate
.
registry.defineInjector('my-injector', (invalidator) => {
// This could be a store, but for this example it is simply an instance
// that accepts the `invalidator` and calls it when any of its internal
// state has changed.
const appContext = new AppContext(invalidator);
return () => appContext;
});
To connect the registered payload
to a widget, we can use the Container
HOC (higher order component) provided by core
. The Container
accepts a widget constructor
, injector
label, and getProperties
mapping function as arguments and returns a new class that returns the passed widget from its render
function.
getProperties
receives the payload
returned from the injector function and the properties
passed to the container HOC component. These are used to map into the wrapped widget's properties.
import { Container } from '@dojo/framework/core/Container';
import { MyWidget } from './MyWidget';
function getProperties(payload: any, properties: any) {
return {
foo: payload.foo
};
}
export const MyWidgetContainer = Container(MyWidget, 'my-injector', getProperties);
The returned class from Container
HOC is then used in place of the widget it wraps, the container assumes the properties type of the wrapped widget, however, they all considered optional.
// import { MyWidget } from './MyWidget';
import { MyWidgetContainer } from './MyWidgetContainer';
interface AppProperties {
foo: string;
}
class App extends WidgetBase<AppProperties> {
render() {
return v('div', {}, [
// w(MyWidget, { foo: 'bar' })
w(MyWidgetContainer, {})
]);
}
}
All decorators provided by core, can be used in non-decorator environments (Either JavaScript/ES6 or a TypeScript project that does not have the experimental decorators configuration set to true in the tsconfig
) programmatically by calling them directly, usually within a Widget class' constructor
.
Example usages:
constructor() {
beforeProperties(this.myBeforeProperties)(this);
beforeRender(myBeforeRender)(this);
afterRender(this.myAfterRender)(this);
diffProperty('myProperty', this.myPropertyDiff)(this);
}
Widget meta is used to access additional information about the widget, usually information only available through the rendered DOM element - for example, the dimensions of an HTML node. You can access and respond to metadata during a widget's render operation.
class TestWidget extends WidgetBase {
render() {
const dimensions = this.meta(Dimensions).get('root');
return v('div', {
key: 'root',
innerHTML: `Width: ${dimensions.width}`
});
}
}
If an HTML node is required to calculate the meta information, a sensible default will be returned and your widget will be automatically re-rendered to provide more accurate information.
The Dimensions
meta provides size/position information about a node.
const dimensions = this.meta(Dimensions).get('root');
In this simple snippet, dimensions
would be an object containing offset
, position
, scroll
, and size
objects.
The following fields are provided:
Property | Source |
---|---|
client.left |
node.clientLeft |
client.top |
node.clientTop |
client.width |
node.clientWidth |
client.height |
node.clientHeight |
position.bottom |
node.getBoundingClientRect().bottom |
position.left |
node.getBoundingClientRect().left |
position.right |
node.getBoundingClientRect().right |
position.top |
node.getBoundingClientRect().top |
size.width |
node.getBoundingClientRect().width |
size.height |
node.getBoundingClientRect().height |
scroll.left |
node.scrollLeft |
scroll.top |
node.scrollTop |
scroll.height |
node.scrollHeight |
scroll.width |
node.scrollWidth |
offset.left |
node.offsetLeft |
offset.top |
node.offsetTop |
offset.width |
node.offsetWidth |
offset.height |
node.offsetHeight |
If the node has not yet been rendered, all values will contain 0
. If you need more information about whether or not the node has been rendered you can use the has
method:
const hasRootBeenRendered = this.meta(Dimensions).has('root');
The Intersection Meta provides information on whether a Node is visible in the application's viewport using the Intersection Observer API.
Note: The Intersection Observer API is not available in all browsers. To use the Intersection Observer API in all browsers supported by Dojo, a polyfill needs to be included. Dojo does not include the polyfill by default, so will need to be added as a script tag in your index.html or alternatively imported in the application’s main.ts using import 'intersection-observer';
after including the dependency in your source tree, or by importing @dojo/framework/shim/browser
.
This example renders a list with images, the image src is only added when the item is in the viewport which prevents needlessly downloading images until the user scrolls to them:
import { WidgetBase } from '@dojo/framework/core/WidgetBase';
import { v, w } from '@dojo/framework/core/vdom';
import { DNode } from '@dojo/framework/core/interfaces';
import { Intersection } from '@dojo/framework/core/meta/Intersection';
// Add image URLs here to load
const images = [];
class Item extends WidgetBase<{ imageSrc: string }> {
protected render() {
const { imageSrc } = this.properties;
const { isIntersecting } = this.meta(Intersection).get('root');
let imageProperties: any = {
key: 'root',
styles: {
height: '200px',
width: '200px'
}
};
// Only adds the image source if the node is in the viewport
if (isIntersecting) {
imageProperties = { ...imageProperties, src: imageSrc };
}
return v('img', imageProperties);
}
}
class List extends WidgetBase {
protected render() {
let items: DNode[] = [];
for (let i = 0; i < images.length; i++) {
items.push(v('ul', { key: i }, [w(Item, { key: i, imageSrc: images[i] })]));
}
return v('div', items);
}
}
See the Animation section more information.
The Drag
meta allows a consuming widget to determine if its nodes are being dragged and by how much. The meta provider abstracts away the need for dealing with modeling specific mouse, pointer, and touch events to create a drag state.
const dragResult = this.meta(Drag).get('root');
The drag information returned contains the following properties:
Property | Description |
---|---|
delta |
An x /y position that contains the number of pixels the pointer has moved since the last read of the drag state. |
isDragging |
If the pointer is currently active in dragging the identified node. |
start |
A position object that contains x /y positions for client , offset , page , and screen that provides the start positions that the delta movement refers to. Note that offset and page are not supported by all browsers and the meta provider does nothing to normalize this data, it simply copies it from the underlying events. |
One common use case is to create a draggable node within a container:
interface ExampleWidget extends WidgetBaseProperties {
height: number;
top: number;
onScroll?(delta: number): void;
}
class VerticalScrollBar extends WidgetBase {
protected render() {
const { height, top, onScroll } = this.properties;
const dragResult = this.meta(Drag).get('slider');
onScroll && onScroll(dragResult.delta.y);
return v(
'div',
{
classes: [css.root, dragResult.isDragging ? css.dragging : null],
key: 'root'
},
[
v('div', {
classes: [css.slider],
key: 'slider',
styles: {
height: `${height}px`,
top: `${top}px`
}
})
]
);
}
}
class VerticalScrollBarController extends WidgetBase {
private _top: 0;
private _onScroll(delta: number) {
this._top += delta;
if (this._top < 0) {
this._top = 0;
}
this.invalidate();
}
protected render() {
return w(VerticalScrollBar, {
top: this._top,
width: 10,
onScroll: this._onScroll
});
}
}
As can be seen in the above code, the meta provider simply provides information which the widgets can react to. The implementation needs to react to these changes.
The Focus
meta determines whether a given node is focused or contains document focus. Calling this.meta(Focus).get(key)
returns the following results object:
Property | Description |
---|---|
active |
A boolean indicating whether the specified node itself is focused. |
containsFocus |
A boolean indicating whether one of the descendants of the specified node is currently focused. This will return true if active is true. |
An example usage that opens a tooltip if the trigger is focused might look like this:
class MyWidget extends WidgetBase {
// ...
render() {
// run your meta
const buttonFocus = this.meta(FocusMeta).get('button');
return v('div', {
w(Button, {
key: 'button'
}, [ 'Open Tooltip' ]),
w(Tooltip, {
content: 'Foo',
open: buttonFocus.active
}, [ 'modal content' ])
});
}
// ...
}
The Focus
meta also provides a set
method to call focus on a given node. This is most relevant when it is necessary to shift focus in response to a user action, e.g. when opening a modal or navigating to a new page. You can use it like this:
class MyWidget extends WidgetBase {
// ...
render() {
// run your meta
return v('div', {
w(Button, {
onClick: () => {
this.meta(Focus).set('modal');
}
}, [ 'Open Modal' ]),
v('div', {
key: 'modal',
tabIndex: -1
}, [ 'modal content' ])
});
}
// ...
}
The resize observer meta uses the latest ResizeObserver
within Dojo based widgets.
Note: The Resize Observer API is not available in all browsers. Native browser support is currently provided by Chrome 64+
, other Dojo supported browsers work via polyfill. To use the Resize Observer API in all browsers supported by Dojo, either added as a script tag in your index.html pointing to the polyfill, or alternatively import the polyfill in the application’s main.ts after including the dependency in your source tree.
This allows you to observe resize events at the component level. The meta
accepts an object of predicate
functions which receive ContentRect
dimensions and will be executed when a resize event has occured. The results are made available in a widget's render
function. This is an incredibly powerful tool for creating responsive components and layouts.
function isMediumWidthPredicate(contentRect: ContentRect) {
return contentRect.width < 500;
}
function isSmallHeightPredicate(contentRect: ContentRect) {
return contentRect.height < 300;
}
class TestWidget extends WidgetBase {
render() {
const { isMediumWidth, isSmallHeight } = this.meta(Resize).get('root', {
isMediumWidth: isMediumWidthPredicate,
isSmallHeight: isSmallHeightPredicate
});
return v('div', {
key: 'root'
classes: [
isMediumWidth ? css.medium : css.large,
isSmallHeight ? css.scroll : null
]
}, [
v('div', {
innerHTML: 'Hello World'
})
]);
}
}
You can create your own meta if you need access to DOM nodes.
import MetaBase from '@dojo/framework/core/meta/Base';
class HtmlMeta extends MetaBase {
get(key: string): string {
const node = this.getNode(key);
return node ? node.innerHTML : '';
}
}
And you can use it like:
class MyWidget extends WidgetBase {
// ...
render() {
// run your meta
const html = this.meta(HtmlMeta).get('comment');
return v('div', { key: 'comment', innerHTML: html });
}
// ...
}
Extending the base class found in meta/Base
will provide the following functionality:
has
- A method that accepts akey
and returns aboolean
to denote if the corresponding node exists in the rendered DOM.getNode
- A method that accepts akey
string to inform the widget it needs a rendered DOM element corresponding to that key. If one is available, it will be returned immediately. If not, a callback is created which will invalidate the widget when the node becomes available. This uses the underlyingnodeHandler
event system.invalidate
- A method that will invalidate the widget.afterRender
- This provides a hook into the widgetafterRender
lifecycle that can be used to clear up any resources that the meta has created. This is used, for instance, in theWebAnimation
meta to clear down unused animations.
Meta classes that require extra options should accept them in their methods.
import MetaBase from '@dojo/framework/core/meta/Base';
interface IsTallMetaOptions {
minHeight: number;
}
class IsTallMeta extends MetaBase {
isTall(key: string, { minHeight }: IsTallMetaOptions = { minHeight: 300 }): boolean {
const node = this.getNode(key);
if (node) {
return node.offsetHeight >= minHeight;
}
return false;
}
}
The dom()
function is used to wrap DOM that is created outside of Dojo. This is the only mechanism to integrate foreign DOM nodes into the virtual DOM system.
dom()
works much like v()
but instead of taking a tag
it accepts an existing DOM node and creates a VNode
that references the DOM node and the vdom system will reuse this node. Unlike v()
a diffType
can be passed that indicates the mode to use when determining if a property or attribute has changed and needs to be applied, the default is none
.
none
: This mode will always pass an empty object as the previousattributes
andproperties
so theprops
andattrs
passed todom()
will always be applied.dom
: This mode uses theattributes
andproperties
from the DOM node for the diff.vdom
: This mode will use the previousVNode
for the diff, this is the mode used normally during the vdom rendering.
Note: All modes use the events from the previous VNode to ensure that they are correctly removed and applied each render.
const node = document.createElement('div');
const vnode = dom({
node,
props: {
foo: 'foo',
bar: 1
},
attrs: {
baz: 'baz'
},
on: {
click: () => {
console.log('clicker');
}
},
diffType: 'none' | 'dom' | 'vdom'
});
To execute a function after the node has been appended to the DOM, there is an onAttach
property that will be executed immediately after the append has occurred.
const node = document.createElement('div');
const vnode = dom({
node,
onAttach: () => {
// do things after the node has been attached
}
});
In addition to creating widgets functionally using the v()
and w()
functions from @dojo/framework/core/d
, Dojo optionally supports the use of the jsx
syntax known as tsx
in TypeScript.
To start to use jsx
in your project, widgets need to be named with a .tsx
extension and some configuration is required in the project's tsconfig.json
:
Add the configuration options for jsx
:
"jsx": "react",
"jsxFactory": "tsx",
Include .tsx
files in the project:
"include": [
"./src/**/*.ts",
"./src/**/*.tsx"
]
Once the project is configured, tsx
can be used in a widget's render
function simply by importing the tsx
function as:
import { tsx } from '@dojo/framework/core/vdom';
class MyWidgetWithTsx extends Themed(WidgetBase)<MyProperties> {
protected render(): DNode {
const {
clear,
properties: { completed, count, activeCount, activeFilter }
} = this;
return (
<footer classes={this.theme(css.footer)}>
<span classes={this.theme(css.count)}>
<strong>{`${activeCount}`}</strong>
<span>{`${count}`}</span>
</span>
<TodoFilter activeFilter={activeFilter} />
{completed ? <button onclick={clear} /> : null}
</footer>
);
}
}
Widgets can be turned into Custom Elements with minimal extra effort.
The customElement
decorator can be used to annotate the widget class
that should be converted to a custom element,
interface MyWidgetProperties {
onClick: (event: Event) => void;
foo: string;
bar: string;
}
@customElement<MyWidgetProperties>({
tag: 'my-widget',
attributes: ['foo', 'bar'],
events: ['onClick']
})
class MyWidget extends WidgetBase<MyWidgetProperties> {
// ...
}
Note: The Custom Elements API is not available in all browsers. To use Custom Elements in all browsers supported by Dojo, a polyfill needs to be included such as webcomponents/custom-elements/master/custom-elements.min.js. Dojo does not include the polyfill by default, so will need to be added as a script tag in your index.html. Note that this polyfill cannot currently be ponyfilled like other polyfills used in Dojo, so it cannot be added with @dojo/framework/shim/browser or imported using ES modules.
No additional steps are required. The custom element can be used in your application automatically. The decorator can be provided with configuration options to modify the functionality of the custom element.
An array of attribute names that should be set as properties on the widget. The attribute name should be the same as the corresponding property on the widget.
An array of property names that will be accessible programmatically on the custom element but not as attributes. The property name must match the corresponding widget property.
Some widgets have function properties, like events, that need to be exposed to your element. You can use the
events
array to specify widget properties to map to DOM events.
{
events: ['onChange'];
}
This will add a property to onChange
that will emit the change
custom event. You can listen like any other
DOM event,
textWidget.addEventListener('change', function(event) {
// do something
});
The name of the event is determined by removing the 'on'
prefix from the name
and lower-casing the resulting name.
Your widget will be registered with the browser using the provided tag name. The tag name must have a -
in it.