How hooks might shape design systems built in React

If you use it regularly or play around with React to build stuff for the web, there's a slight chance you heard about a little thing called hooks.

OK, maybe you are already tired of hearing about them. But the hype is justified, hooks though not in their final form yet are already proving to be a nice pattern to extend capabilities for functional components.

This article doesn't serve the purposes of an introduction to hooks, if you don't know about them I suggest watching Dan Abramov presenting them or read the documentation available for it and come back later.

As someone who has been working in design systems over the past year and using React for it, I can already detect a lot of golden opportunities to simplify and unify the logic these codebases need to handle.

Let's go over some of these potential wins.

Stopping the class switcheroo

In the context of a design system repository, you won't (and shouldn't) find a lot of logic around components, as the purpose of it is to serve the view part for engineers.

Usually, the logic part comes as style calculation, covering backwards compatibility, and some minimal DOM manipulation.

Let's think of a dialog element as a functional component.

import React from 'react';

const Dialog = ({ isOpen, title, content }) => {
  return (
    isOpen && (
      <div className="dialog---overlay">
        <div className="dialog">
          <h2 className="dialog--title">{title}</h2>
          <p className="dialog--content">{content}</p>
        </div>
      </div>
    )
  );
};

Of course this is an oversimplified example on how it would look from the code perspective, and it will look different depending on the tooling your company is using to distribute styles.

So here our dialog will be displayed every time the isOpen prop changes to true and hide when it's false.

Now, think about the chance that we need to lock scrolling every time the dialog opens. There's no way today to do it without switching this to a class component.

import React from 'react';

class Dialog extends React.Component {
  render() {
    const { isOpen, title, content } = this.props;
    return (
      isOpen && (
        <div className="dialog---overlay">
          <div className="dialog">
            <h2 className="dialog--title">{title}</h2>
            <p className="dialog--content">{content}</p>
          </div>
        </div>
      )
    );
  }
}

Then we use the lifecycle hooks to toggle a class or a style on the body element of the document.

import React from 'react';

class Dialog extends React.Component {
  componentDidMount() {
    const { isOpen } = this.props;
    document.body.style.overflow = isOpen ? 'hidden' : 'visible';
  }

  componentDidUpdate() {
    const { isOpen } = this.props;
    document.body.style.overflow = isOpen ? 'hidden' : 'visible';
  }

  render() {
    const { isOpen, title, content } = this.props;
    return (
      isOpen && (
        <div className="dialog---overlay">
          <div className="dialog">
            <h2 className="dialog--title">{title}</h2>
            <p className="dialog--content">{content}</p>
          </div>
        </div>
      )
    );
  }
}

For something so little and trivial as this, we needed a whole refactor of our component. We also find ourselves writing basically the same code on two different lifecycle methods in the component.

We can avoid this by using useEffect.

import React, { useEffect } from 'react';

const Dialog = ({ isOpen, title, content }) => {
  useEffect(() => {
    document.body.style.overflow = isOpen ? 'hidden' : 'visible';
    return () => (document.body.style.overflow = 'visible');
  }, [isOpen]);

  return (
    isOpen && (
      <div className="dialog---overlay">
        <div className="dialog">
          <h2 className="dialog--title">{title}</h2>
          <p className="dialog--content">{content}</p>
        </div>
      </div>
    )
  );
};

Every time our Dialog instance changes the useEffect hook will be called. Inside of it, we are deciding what to do based on the isOpen value.

We are returning a function that will be executed in case the component gets unmounted, to make sure we clean the body styles.

Finally, as a second argument, we are passing an array with isOpen indicating we only want the effect to run if that property has been modified.

This way we avoid a whole rewrite of the component to a class.

Read about the useEffect hook here.

Distribution of simple behaviors

It happens a lot that these small details get repeated over and over again in a design system codebase.

There's a huge chance you will need this for a lot of other elements like overlays, drawers or modals. You can't share lifecycle methods between class components, but we can isolate hooks into their own files and import them wherever necessary.

Let's imagine the use case from above, isollated in a single file that can be consumed by any component from a project.

import { useEffect } from 'react';

function useLockBodyScroll(toggle) {
  useEffect(() => {
    document.body.style.overflow = toggle ? 'hidden' : 'visible';
    return () => (document.body.style.overflow = 'visible');
  }, [toggle]);
}

export default useLockBodyScroll;

Later we add the hook and pass the property that will toggle the style.

import React from 'react';
import useLockBodyScreen from './hooks/useLockBodyScreen';

const Dialog = ({ isOpen, title, content }) => {
  useLockBodyScreen(isOpen);

  return (
    isOpen && (
      <div className="dialog---overlay">
        <div className="dialog">
          <h2 className="dialog--title">{title}</h2>
          <p className="dialog--content">{content}</p>
        </div>
      </div>
    )
  );
};

Now, the behavior can be shared across the components of the system. This also has an impact in other parts of the repositories like the unit tests suite.

I need to make sure all components with lifecycles altering the body styles work properly, which means writing the same unit tests over and over again. With this pattern, we would only need to test the behavior once at the hook's level.

Read about building custom hooks here.

Goodbye dumb states

I don't think states themselves are dumb, but it is a little annoying how a lot of components are classes just because you need to conditionally render a part of its tree or not.

For example, menus and dropdowns.

import React from 'react';

class Menu extends React.Component {
  state = { open: false };

  toggleMenu = () => {
    this.setState({ open: !this.state.open });
  };

  render() {
    const { open } = this.state;
    const { options } = this.props;

    return (
      <div className="menu">
        <button onClick={this.toggleMenu}>Menu</button>
        {open && (
          <div className="menu--options">
            {options.map((item) => (
              <a href={item.href}>{item.text}</a>
            ))}
          </div>
        )}
      </div>
    );
  }
}

The only reason this component is a class in the code above is the need of a state to show or hide the options, but this can easily become a functional component with the useState hook.

You will notice how we deconstruct the return value of it into the state itself and the method to toggle its value.

import React, { useState } from 'react'

const Menu = ({ options }) => {
  const [open, setOpen] = useState(false)

  return (
    <div className='menu'>
      <button onClick={() => setOpen(!open))} >
        Menu
      </button>
      {open && (
        <div className='menu--options'>
          {options.map(item => (
            <a href={item.href}>{item.text}</a>
          ))}
        </div>
      )}
    </div>
  )
}

The value we pass to useState becomes the initial state, later each setOpen call will modify it, without the need of a class at all.

Read about the useState hook here.

Wrap up

Hooks enable new patterns by empowering functional components and removing the need of lifecycles and states for simple use cases.

The behavior inside hooks can be shared now within your design system, and less code to maintain could potentially translate into fewer bugs and avoid redundant unit tests.

Building our own hooks and distributing them across the project will help us concentrate more on what it is happening around the interface itself and less on the logic and little quirks needed for components to behave as expected out of the box. I can't wait to see how they reshape design systems.

Remember that hooks are not production ready, and there could be serious performance regressions and behavior changes in the future so keep their use as experimental.

Thanks Sara Vieira for proofreading this piece.