React Higher-order component for state management with Profunctor Optics

A simple and small (2.8KB!) approach to state management in React using functional lenses (a type of profunctor optics). A lens is made of two functions: get (like selectors in Redux, or computed values in MobX) and set (the opposite of a selector, creates new parent state). This way, parent state and child state are kept in sync, updating back and forth automatically.

npm install --save @staltz/with-profunctor-state

See also @staltz/use-profunctor-state.

Suppose your app handles temperatures in Fahrenheit, but one component works only with Celsius. You can create a conversion layer between those two with promap(get, set).

Open this also in a CodeSandbox.

const initialState = {fahrenheit: 70, other: {}}

function ProApp({state, setState, promap}) {
  const celsiusProf = promap(
    state => fToC(state.fahrenheit),
    (celsius, state) => ({ ...state, fahrenheit: cToF(celsius) })
  );

  return (
    <div>
      <div>Global app state: {JSON.stringify(state)}</div>
      <ProThermometer {...celsiusProf} />
    </div>
  );
}

const App = withProfunctorState(ProApp, initialState);

Because promap is composable, you can also split the conversion layer into multiple parts:

const celsiusProf = promap(
  state => state.fahrenheit,
  (f, state) => ({ ...state, fahrenheit: f })
)
.promap(fToC, cToF);

The ProThermometer component received props state, setState and promap from the spread of celsiusProf:

• state: in this case it's a number representing celsius
• setState: does what you think it does!
• promap: use this if ProThermometer would have children components

function ProThermometer({ state, setState, promap }) {
  const onColder = () => setState(prev => prev - 5);
  const onHotter = () => setState(prev => prev + 5);
  return (
    <div>
      <button onClick={onColder}>Colder</button>
      <button onClick={onHotter}>Hotter</button>
      <Thermometer value={state} max="100" steps="4" format="°C" />
    </div>
  );
}

• Global app state == Props == Local component state
• No actions, no reducers, no dispatch, no store
• Selector/unselector conversion layers in the component tree

• state and setState work just like you would assume
• Easy to migrate your apps to use profunctors

• Build the parent components like you build the smaller components
• Same pattern applies to all components, both Presentational and Container

• Every child component assumes nothing about its parent component
• Pro Components can be published to NPM as-is

• Lenses are composable and operate immutably, just like Redux selectors
• Chain .promap calls like you would chain .map calls
• Backed by mathematical theory

• Sprinkle React.memo() here and there to avoid full-app rerenders

Compared to Redux and similar (ngrx, Vuex):

• No actions means no support for Redux DevTools
• For preventing performance issues, better use React.memo (almost always?)
• This library itself is not used in production yet

Higher-order component that accepts as input a Pro Component (component that wants props state, setState, promap, see below for more info), an initial state object, and returns a new component that provides the initial state to the Pro Component.

A Pro Component is any component that expects all or some of these props {state, setState, promap}.

• state: the data, initially this will be initial
• setState: works just like React's traditional setState
  • setState(newState) or
  • setState(prev => ...)
• promap(get, set): creates a new profunctor state object based on the current one, given two functions:
  • get: parentState => childState
  • set: (newChild, oldParent) => newParent

Promap also alternatively supports a lens object, which is simply promap({get, set}) instead of promap(get, set). This is useful in case you want to publish a lens object elsewhere and simply pass it into the promap.

A Pro Component can put its local state in the state prop using setState. You can also think of this setState as setProps. Writing components in this style is familiar, because setState works just like the traditional API.

However, now we have the added benefit that Pro Components can be published as-is (they are just functions!) to NPM, and there is no need to import @staltz/with-profunctor-state as a dependency of a Pro Component. This way you get encapsulated and composable pieces of state management that can be shared across applications. Pro Components can either be presentational or logic-heavy container components.

By default, each child's setState will cause a top-level state update (up until withProfunctorState) which will rerender the entire hierarchy below. This is a bad thing, but it's not unlike Redux, where you need to carefully design shouldComponentUpdate. With profunctor state, just add React.memo to a Pro Component and that should do the same as shouldComponentUpdate, remember to also use the propsAreEqual argument too.

-const ProThermometer = ({ state, setState, promap }) => {
+const ProThermometer = React.memo(({ state, setState, promap }) => {
   const onColder = () => setState(prev => prev - 5);
   const onHotter = () => setState(prev => prev + 5);
   return (
     <div>
       <button onClick={onColder}>Colder</button>
       <button onClick={onHotter}>Hotter</button>
       <Thermometer value={state} max="100" steps="4" format="°C" />
     </div>
   );
-}
+}, (prev, next) => prev.state === prev.next);

Check this CodeSandbox with React.memo usage, where background colors change upon re-render.

Yes. With React Hooks (See @staltz/use-profunctor-state hook) it will be easy to add the useState into a function Pro Component, but before hooks become official in React, you'll have to rely on normal class components to use the traditional this.setState. Note that this may raise some confusion, as you'll have both this.props.setState (shared with the parent) and this.setState (internal local state). For instance:

 class ProThermometer extends Component {
+  state = {steps: 4};

   lessHeat = () => this.props.setState(prev => prev - 5);

   moreHeat = () => this.props.setState(prev => prev + 5);

   render() {
    return (
      <div>
        <button onClick={this.lessHeat}>Colder</button>
        <button onClick={this.moreHeat}>Hotter</button>
-        <Thermometer value={this.props.state} max="100" steps="4" format="°C" />
+        <Thermometer value={this.props.state} max="100" steps={this.state.steps} format="°C" />
      </div>
    );
   }
 }

Theoretically, yes, it was designed after Cycle State. The community has been using functional lenses in Cycle State (a.k.a. cycle-onionify) for at least a year, also in production. Lenses are also not new, they're in JS libraries like Ramda and Partial Lenses, but much more common in functional languages like Haskell.

In practice, this specific library has not been used in production, and you must be careful to handle performance issues correctly (read above). With such a small implementation, the risks associated with using this in production are lower.

First, I don't want to pollute the NPM registry. Second, I believe most people should author packages under their own scope (just like in GitHub!), so that forks can indicate who is maintaining the package, because I don't intend to maintain this package, although it's small and might not even need maintenance.

MIT