Functional Approach to Higher Order Components and Recompose

This is a continuation of our previous post where we talked about how Higher Order Components (HOC) help abstraction of logic. This in turn helps simplifying a React application.

Now let’s say we have a React Component on which we need to do certain tasks:

Omit certain props which parent component passes. In our case we will omit isDone prop. Conditionally check if we need to still show spinner based on certain props. In our case, if we have isLoading prop set to true then show a Component which renders a Preloader. That is show a preloader if isLoading prop is true and render the component if isLoading prop is false . Attach an event handler which does some preprocessing of data and then logs (on console) the data on clicking the button. (Since we cannot have event handlers in functional components, I particularly want to discuss how we can do this)

For this the usual way would be writing a HOC for each task separately and combine by using one on top of each other.

Now let’s look at an alternative way for achieving the same using functional programming. We described Higher Order Functions in our previous post as:

Functions that operate on other functions, either by taking them as arguments or by returning them, are called higher-order functions.

If we adopt functional programming, we need to think about composing existing functions as much as possible in order to create new functions. Currying is one major technique used to achieve this.

Currying is a method of constructing functions which facilitates the function to have all arguments passed to it returning a result or have partial arguments to be passed resulting a new function which expects remaining arguments. For example:

const fullName = firstName => lastName => { return firstName + lastName ; } ;

Now if we use fullName(‘Code’) it will return another function which expects a lastName . Its first name will be replaced as Code.

const partialName = fullName ( ‘Code’ ) ;

When we write

const finalName = partialName ( ‘brahma’ ) ;

finalName will be assigned with ‘Codebrahma’. This is a useful technique since it uses to create and compose multiple functions.

So considering the previously discussed task, first we will create a conversionFunction which can omit the ‘isDone’ prop.

import React from 'react' ; import omit from 'lodash/omit' ; const DummyComponent = props => ( < div > A simple dummy component </ div > ) ; const createFactory = Component => { return props => React . createElement ( Component , props , ) ; } const conversionFunction = anyFunction => Component => { const factory = createFactory ( Component ) ; const mapProps = props => factory ( anyFunction ( props ) ) ; return mapProps ; } ; export default conversionFunction ( props => omit ( props , [ 'isDone' ] ) ) ( DummyComponent ) ;

Now we can see that without adding an additional React Class we are able to write a HOC which omits the mentioned prop.

Now the second task is to show a Preloader if we have isLoading prop set to true. To achieve this the we need to change the conversion function like this.

const conversionFunction = anyFunction => Component => { const factory = createFactory ( Component ) ; const mapProps = props => ( props . isLoading ? < Preloader /> : factory ( anyFunction ( props ) ) ) ; return mapProps ; } ;

Now if we pass isLoading prop as true, it will always render a preloader. This gives control from the parent component to decide when to load the preloader and when to load the actual component

The third task is to attach an event handler to the functional component and console logging some data on clicking a button using that even handler. This is an extension to the above concept except that we will return one more React Component squashed inside.

import React from 'react' ; import omit from 'lodash/omit' ; import merge from 'lodash/merge' ; const Preloader = props => ( < div > Loading... </ div > ) ; const createFactory = Component => { return props => { return React . createElement ( Component , props , ) ; } } const DummyComponent = props => ( < div > A simple dummy component < button onClick = { ( ) => { props . handleButtonClick ( 1 ) } } > Click to Log </ button > </ div > ) ; const conversionFunction = ( { handlerName , handlerFunction } ) => anyFunction => Component => { const factory = createFactory ( Component ) ; return class ComponentWithHandler extends React . Component { constructor ( props ) { super ( props ) ; } render ( ) { return this . props . isLoading ? < Preloader /> : factory ( { ... this . props , [ handlerName ] : handlerFunction , } ) ; } } } const sampleHandlerFunction = { handlerName : 'handleButtonClick' , handlerFunction : ( data ) => { console . log ( ' logging data ' , data ) ; } } ; export default conversionFunction ( sampleHandlerFunction ) ( props => omit ( props , [ 'isDone' ] ) ) ( DummyComponent ) ;

We can see that we have used functional programming to achieve all the tasks mentioned above. conversionFunction is now a curried function which will work for any component that can do all the target tasks. Also we can ignore certain tasks as per the requirement.

The whole idea of doing this is functionality abstraction which results in components which depends only on props. The advantage of having more and more stateless components are

Clean code while avoiding bloated components.

Easy to understand and easy to test.

Better performance since there are no lifecycle methods.

Recompose (GitHub link) is a library which was developed based on the idea. It has list of utility functions which they claim as “Recompose is a React utility belt for function components and higher-order components. Think of it like lodash for React.” They have various cool functionalities abstracted through HOCs. From providing state through props for functional components to adding lifecycle events to functional components they have added functionalities which we feel is required most of the times while developing a React app.

Using these methods we can write really cool abstracting logic which we are regularly repeating among components.