uncontrollable
Wrap a controlled react component, to allow specific prop/handler pairs to be omitted by Component consumers. Uncontrollable allows you to write React components, with minimal state, and then wrap them in a component that will manage state for prop/handlers if they are excluded.
Install
npm i -S uncontrollable
Usage
If you are a bit unsure on the why of this module read the next section first. If you just want to see some real-world examples, check out React Widgets which makes heavy use of this strategy.
import { uncontrollable } from 'uncontrollable';
API
useUncontrolledProp(value, defaultValue, onChange) => [value, onChange]
A React hook that can be used in place of the above Higher order Component. It
returns a complete set of props
which are safe to spread through to a child element.
import { useUncontrolledProp } from 'uncontrollable';
const UncontrolledCombobox = ({ value, defaultValue, onChange }) => {
const [controlledValue, onControlledChange] = useUncontrolledProp(
value,
defaultValue,
onChange
);
return <Checkbox {...controlledProps} />;
};
useUncontrolled(props, propsHandlerHash) => controlledProps
A React hook that can be used in place of the above Higher order Component. It
returns a complete set of props
which are safe to spread through to a child element.
import { useUncontrolled } from 'uncontrollable';
const UncontrolledCombobox = (props) => {
const controlledProps = useUncontrolled(props, {
value: 'onChange',
open: 'onToggle',
});
return <Checkbox {...controlledProps} />;
};
Use Case
One of the strengths of React is its extensibility model, enabled by a common practice of pushing component state as high up the tree as possible. While great for enabling extremely flexible and easy to reason about components, this can produce a lot of boilerplate to wire components up with every use. For simple components (like an input) this is usually a matter of tying the input value
prop to a parent state property via its onChange
handler. Here is an extremely common pattern:
render() {
return (
<input type='text'
value={this.state.value}
onChange={ e => this.setState({ value: e.target.value })}
/>
)
}
This pattern moves the responsibility of managing the value
from the input to its parent and mimics "two-way" databinding. Sometimes, however, there is no need for the parent to manage the input's state directly. In that case, all we want to do is set the initial value
of the input and let the input manage it from then on. React deals with this through "uncontrolled" inputs, where if you don't indicate that you want to control the state of the input externally via a value
prop it will just do the book-keeping for you.
This is a great pattern which we can make use of in our own Components. It is often best to build each component to be as stateless as possible, assuming that the parent will want to control everything that makes sense. Take a simple Dropdown component as an example
class SimpleDropdown extends React.Component {
static propTypes = {
value: React.PropTypes.string,
onChange: React.PropTypes.func,
open: React.PropTypes.bool,
onToggle: React.PropTypes.func,
};
render() {
return (
<div>
<input
value={this.props.value}
onChange={(e) => this.props.onChange(e.target.value)}
/>
<button onClick={(e) => this.props.onToggle(!this.props.open)}>
open
</button>
{this.props.open && (
<ul className="open">
<li>option 1</li>
<li>option 2</li>
</ul>
)}
</div>
);
}
}
Notice how we don't track any state in our simple dropdown? This is great because a consumer of our module will have the all the flexibility to decide what the behavior of the dropdown should be. Also notice our public API (propTypes), it consists of common pattern: a property we want set (value
, open
), and a set of handlers that indicate when we want them set (onChange
, onToggle
). It is up to the parent component to change the value
and open
props in response to the handlers.
While this pattern offers an excellent amount of flexibility to consumers, it also requires them to write a bunch of boilerplate code that probably won't change much from use to use. In all likelihood they will always want to set open
in response to onToggle
, and only in rare cases will want to override that behavior. This is where the controlled/uncontrolled pattern comes in.
We want to just handle the open/onToggle case ourselves if the consumer doesn't provide a open
prop (indicating that they want to control it). Rather than complicating our dropdown component with all that logic, obscuring the business logic of our dropdown, we can add it later, by taking our dropdown and wrapping it inside another component that handles that for us.
uncontrollable
allows you separate out the logic necessary to create controlled/uncontrolled inputs letting you focus on creating a completely controlled input and wrapping it later. This tends to be a lot simpler to reason about as well.
import { uncontrollable } from 'uncontrollable';
const UncontrollableDropdown = uncontrollable(SimpleDropdown, {
value: 'onChange',
open: 'onToggle'
})
<UncontrollableDropdown
value={this.state.val}
onChange={val => this.setState({ val })}
defaultOpen={true} />
Now we don't need to worry about the open onToggle! The returned component will track open
for us by assuming that it should just set open
to whatever onToggle
returns. If we do want to worry about it we can just provide open
and onToggle
props and the uncontrolled input will just pass them through.
The above is a contrived example but it allows you to wrap even more complex Components, giving you a lot of flexibility in the API you can offer a consumer of your Component. For every pair of prop/handlers you also get a defaultProp of the form "default[PropName]" so value
-> defaultValue
, and open
-> defaultOpen
, etc. React Widgets makes heavy use of this strategy, you can see it in action here: https://github.com/jquense/react-widgets/blob/5d1b530cb094cdc72f577fe01abe4a02dd265400/src/Multiselect.jsx#L521