Helix is a library which wraps React, a JavaScript library for building user interfaces.
The goals of Helix are:
Helix accomplishes this by providing a collection of macros for creating components and elements.
Years ago, the only way to build stateful React components was to define a
JavaScript class that extended React’s Component
class and implement various
lifecycle handlers. Most ClojureScript wrappers interop through this way of
building components. Since the release of React Hooks,
a modern component is a JavaScript function that takes in a props object, and
returns React Element objects.
function MyComponent(props) {
return React.createElement("div", null, "Hello, React");
}
React.createElement(MyComponent);
This is simple enough to translate to CLJS:
(defn my-component
[props]
(react/createElement “div” nil “Hello, CLJS!”))
(react/createElement my-component)
React Hooks are motivating because they vastly simplify both the code required to build components, and the mental model of how components work. Before, understanding React’s lifecycle methods and how they mapped to how and when your code would run was quite confusing. React Hooks mental model is smaller, and removes an amount of subtle bugs that hampered many React applications and libraries.
They also provide a migration path to being “safe” in Concurrent mode (e.g. your app will have less bugs when trying to migrate to Concurrent mode). Concurrent mode opens up a whole slew of fantastic UX and DX improvements that should not be ignored.
However, two issues appear quickly when attempting to write CLJS applications using the method above:
props
is always passed in as a native JS objectSo an example of a component that determines whether it’s “on” or “off” and changes its color would look like so:
(defn my-component
[props]
(let [on? (goog.object/get props “on?”)]
(react/createElement
“div”
#js {:style #js {:background (if on? “red” “black”)}}
“Hello, CLJS!”)))
(react/createElement my-component #js {:on? true})
This is mechanically tiresome, but consistent. Because of this, a wrapping library can help us easily handle converting to and from JS objects. Here’s how that component would look in helix:
(defnc my-component
[{:keys [on?]}]
(d/div
{:style {:background (if on? “red” “black”)}}
“Hello, CLJS!”))
($ my-component {:on? true})
The defnc macro does the work of coercing the props object into something that
can be destructured easily. The div
macro (d
here is an alias of helix.dom
)
creates the “div” element and $
macro creates a new my-component
element,
handling coercion of the map literal we pass in into a JS object in the most
performant way possible.
Semantically, the two are equivalent. Helix only makes reading and writing components in ClojureScript much easier.
The long term goal of helix is to build on these capabilities with additional features to help developers write performant, correct code. An example in helix today is an optional linter which will check your component for Hooks usage which violate the rules of hooks.
(defnc my-component
[]
{:helix/features {:check-invalid-hooks-usage true}}
(for [n (range 10)]
(let [[count set-count] (hooks/use-state 0)]
(d/button {:on-click #(set-count inc)} count))))
The above component will throw a compiler warning, saying that using a hook inside of a loop is invalid. It’s nice to find out about that at compile time, rather than at runtime!
Eventually, some of these features will be turned on by default. However, creating your own macro is easy, and in large applications suggested in order to enable/disable these experimental features, as well as add other compile-time processing of your components.
Some ideas of things you might want to build on top of helix’s component macro:
The world is vast! I hope helix can help remove some of the complexity from it.
Can you improve this documentation? These fine people already did:
Will Acton & WillEdit on GitHub
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