Simple, scalable state management.
Documentation can be found at mobx.js.org.
MobX is made possible by the generosity of the sponsors below, and many other individual backers. Sponsoring directly impacts the longevity of this project.
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Anything that can be derived from the application state, should be. Automatically.
MobX is a signal based, battle-tested library that makes state management simple and scalable by transparently applying functional reactive programming. The philosophy behind MobX is simple:
Write minimalistic, boilerplate-free code that captures your intent. Trying to update a record field? Simply use a normal JavaScript assignment — the reactivity system will detect all your changes and propagate them out to where they are being used. No special tools are required when updating data in an asynchronous process.
All changes to and uses of your data are tracked at runtime, building a dependency tree that captures all relations between state and output. This guarantees that computations that depend on your state, like React components, run only when strictly needed. There is no need to manually optimize components with error-prone and sub-optimal techniques like memoization and selectors.
MobX is unopinionated and allows you to manage your application state outside of any UI framework. This makes your code decoupled, portable, and above all, easily testable.
So what does code that uses MobX look like?
import React from "react"
import ReactDOM from "react-dom"
import { makeAutoObservable } from "mobx"
import { observer } from "mobx-react-lite"
// Model the application state.
function createTimer() {
return makeAutoObservable({
secondsPassed: 0,
increase() {
this.secondsPassed += 1
},
reset() {
this.secondsPassed = 0
}
})
}
const myTimer = createTimer()
// Build a "user interface" that uses the observable state.
const TimerView = observer(({ timer }) => (
<button onClick={() => timer.reset()}>Seconds passed: {timer.secondsPassed}</button>
))
ReactDOM.render(<TimerView timer={myTimer} />, document.body)
// Update the 'Seconds passed: X' text every second.
setInterval(() => {
myTimer.increase()
}, 1000)
The observer
wrapper around the TimerView
React component will automatically detect that rendering
depends on the timer.secondsPassed
observable, even though this relationship is not explicitly defined. The reactivity system will take care of re-rendering the component when precisely that field is updated in the future.
Every event (onClick
/ setInterval
) invokes an action (myTimer.increase
/ myTimer.reset
) that updates observable state (myTimer.secondsPassed
).
Changes in the observable state are propagated precisely to all computations and side effects (TimerView
) that depend on the changes being made.
This conceptual picture can be applied to the above example, or any other application using MobX.
To learn about the core concepts of MobX using a larger example, check out The gist of MobX page, or take the 10 minute interactive introduction to MobX and React. The philosophy and benefits of the mental model provided by MobX are also described in great detail in the blog posts UI as an afterthought and How to decouple state and UI (a.k.a. you don’t need componentWillMount).
The MobX Quick Start Guide ($24.99) by Pavan Podila and Michel Weststrate is available as an ebook, paperback, and on the O'Reilly platform (see preview).
MobX is inspired by reactive programming principles, which are for example used in spreadsheets. It is inspired by model–view–viewmodel frameworks like MeteorJS's Tracker, Knockout and Vue.js, but MobX brings transparent functional reactive programming (TFRP, a concept which is further explained in the MobX book) to the next level and provides a standalone implementation. It implements TFRP in a glitch-free, synchronous, predictable and efficient manner.
A ton of credit goes to Mendix, for providing the flexibility and support to maintain MobX and the chance to prove the philosophy of MobX in a real, complex, performance critical applications.