This is a Promise-based component encapsulation method. Designed to simplify the handling of asynchronous input and
output of components. Its design goal is to implement the software engineering concept
of High-cohesion and Low-coupling
Features
π₯ Promise-based invocation
Promise-based invocation allows us to flexibly control the asynchronous input and output flow of components. The
component will be invoked internally at the appropriate time
resolve or reject callback. This invocation follows a normalized pattern of asynchronous operation, making the use and
management of components more reliable and consistent.
π¦ Independence of calls
Each call to the component spawns a new, independent instance. They don't share call state, and they don't have issues
like state caching. Whether the same component is called multiple times in a single page, or multiple instances of the
same component are used in different pages, they are guaranteed to be independent of each other.
π Render on demand
Components are rendered only when they are needed. This rendering method can be triggered according to specific events
or external conditions, making the rendering logic more flexible and controllable. For example, we call a component when
a user clicks a button or when a condition is met. This on-demand rendering method can effectively improve page load
speed and performance, while also reducing unnecessary rendering and resource consumption.
β»οΈ Destroy after use
The result of a component's rendering is temporary and will be destroyed as soon as it is finished, similar to the
effect of burning. This feature is ideal for temporary and one-off scenarios, while also improving program performance.
Integrations
Example (React)
Let's implement a user list and include the ability to interactively add and edit user information using a dialog box.
Initialization
You need to use the shared rendering slot of the Promise component in the root component, which will provide a default
rendering location for the Promise components of the entire application and inheritance of the application context (such
as: store, theme, i18n...).
// App.tsx
import { SharedSlot } from '@promise-components/react'
function App () {
return (
<div>
...
<SharedSlot/>
</div>
)
}
export default App
Defining a Promise Component
// add-user.tsx
import { PromiseComponent, PromiseResolvers } from '@promise-components/react'
import { FormEvent, useState } from 'react'
interface UserItem {
name: string
age: number
id: number
}
/**
* π΄ The Props parameter must inherit from PromiseResolvers
*/
interface Props extends PromiseResolvers<UserItem> {
user?: UserItem
}
/**
* π΄ Create a PromiseComponent instance
*/
export const AddUser = new PromiseComponent((props: Props) => {
const [formData, setFormData] = useState(() => {
return {
name: '',
age: 0,
id: Math.random(),
...props.user, // If editing, fill in the default value
}
})
function handleSubmit () {
if (!formData.name) return alert('Please enter `Name`')
if (!formData.age) return alert('Please enter `Age`')
// π΄ Call resolve callback
props.resolve(formData)
}
function handleCancel () {
// π΄ Call reject callback
props.reject()
}
function handleInput (key: keyof UserItem) {
return (evt: FormEvent<HTMLInputElement>) => {
setFormData({
...formData,
[key]: evt.currentTarget.value
})
}
}
return (
<dialog open>
<form>
<p>
<span>Name: </span>
<input value={formData.name} onInput={handleInput('name')} type="text"/>
</p>
<p>
<span>Age: </span>
<input value={formData.age} onInput={handleInput('age')} type="number" min={0}/>
</p>
</form>
<p>
<button onClick={handleCancel}>Cancel</button>
<button onClick={handleSubmit}>Submit</button>
</p>
</dialog>
)
})
Using the Promise component
// user-list.tsx
import { useState } from 'react'
import { AddUser } from './add-user.tsx'
interface UserItem {
name: string
age: number
id: number
}
export function UserList () {
const [userList, setUserList] = useState<UserItem[]>([])
async function handleAdd () {
/**
* π΄ Using component
*/
const newUser = await AddUser.render()
setUserList((prevList) => [...prevList, newUser])
}
async function handleEdit (editIndex: number) {
/**
* π΄ Using component and providing parameters (Edit mode)
*/
const modifiedUser = await AddUser.render({
user: userList[editIndex],
})
setUserList((prevList) => {
return prevList.map((item, index) => {
return index === editIndex ? modifiedUser : item
})
})
}
return (
<div>
<ul>{
userList.map((item, index) => (
<li key={item.id}>
<span>Name: {item.name}, Age: {item.age}</span>
<button onClick={() => handleEdit(index)}>Edit</button>
</li>
))
}</ul>
<button onClick={handleAdd}>Add</button>
</div>
)
}
Well, we have happily completed the development of the user list function based on the Promise component.
Based on the above example, we can see some characteristics:
- There is no
ON/OFF
variable for modal - There is no event listener for modal
Cancel/Confirm
- There are no variables to distinguish between
Add/Edit
modes - When using the
Add/Edit
function, the program logic is independent and does not interfere with each other - The logic of the program is simple, clear and straightforward, and it is very readable and maintainable
Of course, you may think that this example is too simple, but in fact, the principle is the same, no matter how complex
the function, as long as it meets the asynchronous input and output scenarios, this mode can provide you with a more
user-friendly development experience and better program performance. We don't have to care about component rendering
state, we focus on business logic, that's it
The meaning of the Promise component.
Top comments (0)