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🗺️ Our Best Practices

Last update: Feb 2024

This is a living document, expected to be updated regularly, with a broad overview of the history and how we prefer to do things on eigen. Here you can find links to the tools we use, examples, pull requests with interesting discussions & blog posts.

Please note: Links should point to specific commits, and not a branch (in case the branch or file is deleted, these links should always work). But it's possible that a file is outdated, that our understanding has moved on since it was linked to; in that case, please update this document.

Contents

Examples & Hacks

Check out our lists of examples and hacks.

History

The Artsy app was initially written in Objective-C and Swift and React Native was added in 2016. Some parts of the app are also written with Kotlin.

  • React Native is our preferred option for developing new features.

  • Objective-C and Java can be used for bridging code to react native (this is referring to native modules that need to talk to javascript, more info in the react native docs here: https://reactnative.dev/docs/native-modules-ios)

  • Swift and Kotlin are used for native functionality that can't be done in React Native (such as: an iOS Widget or a Push Notification Extension).

  • Why Artsy uses React Native

  • All React Native posts on Artsy's Engineering Blog

  • Some great React Native components:

    • Partner is a simple top-level component.
    • PartnerShows is a fragment container that uses FlatList to paginate through Relay data.
    • Search is a functional component that loads data in response to user input.

File Structure Organization

The React Native parts of the app live in src/ and most of our components on app/. Within this folder things can be a bit messy 👀 but we are working on improving that!

Files that export a JSX component end in .tsx and files that don't end in .ts by default.

We use PascalCase for Components and Component Folders, but keep everything else within the Component folder(eg. mutations, state, utils) camelCase. Test files follow the same pattern.

For example mutations, routes, state would be camelCase folders, while MyComponent.tsx would be a PascalCase file.

├── MyComponentFolder
│   ├── MyComponent.tsx
│   ├── MyComponent.tests.tsx
│   ├── mutations
│   |  ├── mutationFunction.ts
│   ├── state
│   |  ├── stateFunction.ts
│   ├── utils
│   |  ├── utilFunction.ts
│   |  ├── utilFunction.tests.ts
├── …

Another example is:

If we have a buttons folder which exports many button components, we keep it lowercase.

├── buttons
│   ├── RedButton.tsx
│   ├── GreenButton.tsx
│   ├── YellowButton.tsx
│   ├── buttons.tests.tsx
│   ├── buttons.stories.tsx
├── …

However, if we have a Button folder which exports only one button component, we write that with in PascalCase.

├── Button
│   ├── Button.tsx
│   ├── Button.tests.tsx
│   ├── Button.stories.tsx

Note: Updating capitalisation on folders can cause issues in git and locally so please refrain from renaming existing folders until we come up with a strategy about this. (TODO)

index.ts files

We try to avoid the use of index.ts files to prevent noise in the file structure and circular dependencies and make it easier to navigate between files.

When committing code

  • Use the semantic commit message format in the title of your PR (eg. feat, fix, style, test, refactor, docs)
  • When merging a PR, choose "Squash and merge" (unless you have good reason not to)
  • Do not use "Squash and merge" on a new version deployment PR

Frontend

Styling

@artsy/palette-mobile is our reusable component toolkit, which uses styled-system under the hood. Here you can see palette in action. Some of our most used elements are Flex, Box, Text. Separator and Spacer.

We want to move towards an atomic design and have all our UI elements in palette.

TypeScript

We use TypeScript to maximize runtime code safety & prevent runtime bugs.

In April 2020, we adopted TypeScript's strict mode.

This disables "implicit any" and requires strict null checks.

The change left comments like this throughout the codebase that we aim to gradually remove.

// @ts-expect-error STRICTNESS_MIGRATION --- 🚨 Unsafe legacy code 🚨 Please delete this and fix any type errors if you have time 🙏

Fetching data

We use Relay for network requests.

Artsy's GraphQL server is Metaphysics.

We prefer using Relay hooks over relay containers (Higher Order Components).

Refactoring components using HoCs in favour of hooks is encouraged.

➡️ Read more about how to fetch data here

Testing

Please read more about testing here.

Navigation

We use react-navigation for navigating between screens.

For adding a screen that corresponds to a page on artsy.net add a new route and use the navigate(<route-name>) function. Navigation will then be handled for you. And that's how it's done: (add links to code here).

See our documentation on adding a route for more details: Adding a new route and to create a new screen.

iOS Navigation

  • For native iOS code we use the ARScreenPresenterModule. Once the new app shell is finished (expected March 2022), we will be using react-navigation.

For the most part you don't have to worry about this.

Analytics and tracking

In React-native, we use react-tracking as a wrapper for the tracking events we send to Segment. You can read more about the implementation here.

VirtualizedList best practices

Smoothly rendering lists and animations is crucial for a positive user experience. However, performance issues can arise, causing lag, stuttering, and decreased responsiveness. Below are few tips to achieve that in Eigen:

Never nest ScrollViews.

If you feel like there is no other way, it's probably a better idea to talk to the designer to adjust the approach they're suggested instead. Our Screen wrappers from palette-mobile expose performant ScrollView based components such as Flatlist and Flashlist that can be used and would save you the nesting.

Always default to FlashList.

Think of FlashList as Flatlist on steroids. It's fast, performant and easy to use.

Code snippet
import { FlashList } from "@shopify/flash-list"

const App = () => {
  return (
   <FlashList
    renderItem={renderItem}
    estimatedItemSize={ESTIMATED_ITEM_SIZE}
    keyExtractor={keyExtractor}
  >
  )
}
``` ```

What if you followed all the above steps and still have performance issues?

Below are some tips to improve the performance further; don't follow them UNLESS you need to, as premature optimization will haunt you and can lead to issues that are non-trivial to debug (plus it's arguably not the best use of your time).

Use windowSize with caution

Use LazyFlatlist in order to define your own lazy loading logic.

Code snippet

Example of a PR implementing it: #9832

import { LazyFlatlist } from "@artsy/palette-mobile"

const App () => {
  return (
    <LazyFlatlist<NotificationT> keyExtractor={keyExtractor}>
      {(props) => {
        return (
          <FlatlistComponent
            ...
            renderItem={({ item }) => {
              return <ActivityItem notification={item} isVisible={props.hasSeenItem(item)} />
            }}
            onViewableItemsChanged={props.onViewableItemsChanged}
            viewabilityConfig={props.viewabilityConfig}
          />
        )
      }}
    </LazyFlatlist>
  )
}

Does your component contain animations?

If yes, consider moving all the animations to the native thread. How?

Example of a potentially problematic component implementing a fade in animation with Moti.

import { MotiView } from "moti"

const Image = () => {
  const [loading, setLoading] = useState(true) // 👈 executes on the JS thread
  return (
   <Flex>
    <FastImage ... onLoadEnd=(() => setLoading(false)) />
    <MotiView animate={{opacity: loading ? 0:1}} />
   <Flex>
  )
}

The above code runs the animation on the native thread thanks to Moti, However, it will only happens after loading is set to false , which happens on the js side! This is fine when not much is happening on the js thread, but when the JS thread is busy dealing with items complex logic, scrolling and calculating scroll position etc... it can lead to a bottleneck on the JS side leading and potentially breaking the scroll experience.

The solution here would be to follow RN threading models UI animations best practices and moving everything to the native thread like so.

import { MotiView } from "moti"

const Image = () => {
  const loading = useSharedValue(true) // 👈 executes on the JS thread

   const onLoadEnd = () => {
     "worklet"
     loading.set(() => false)
   }

  const animatedStyles = useAnimatedStyle(() => {
    return {
      opacity: withTiming(loading.get() ? 1 : 0, { duration: 200, easing: Easing.sin }),
    }

  return (
   <Flex>
    <FastImage ... onLoadEnd=(onLoadEnd) />
    <MotiView style={animatedStyles} />
   <Flex>
  )
}

More granular control on when updates happen can do magic sometimes! requestAnimationFrame, queueMicroTask and InteractionManager.runAfterInteractions can come to the rescue here!

Formik

We use Formik for handling forms. You can see an example that's also using form validation here

Miscellaneous

Parts of the app that are still being handled in native code (Objective-C and Swift) instead of react-native on iOS

The following parts of the iOS app are handled in native code:

  • Live Auctions Integration (LAI) view controller and networking.
  • Initializing the React Native runtime.
  • Analytics for Native UI.
  • View In Room (Augmented Reality)
  • City Guide Drawer Handling

The following parts of the iOS app are handled in native code, but will be managed by React Native once the new app shell is finished (expected March 2022):

  • ARScreenPresenterModule to navigate between view controllers.
  • The top-level tab bar, and each tab's navigation controller.
  • Deep-link and notification handling.