Posted by Alex Vanyo, Developer Relations Engineer
Watch faces are one of the most visible ways that people express themselves on their smartwatches, and they’re one of the best ways to display your brand to your users.
Watch Face Studio from Samsung is a great tool for creating watch faces without writing any code. For developers who want more fine-tuned control, we've recently launched the Jetpack Watch Face library written from the ground up in Kotlin.
The stable release of the Jetpack Watch Face library includes all functionality from the Wearable Support Library and many new features that make it easier to support customization on the smartwatch and on the system companion app on mobile, including:
If you are still using the Wearable Support Library, we strongly encourage migrating to the new Jetpack libraries to take advantage of the new APIs and upcoming features and bug fixes.
Below is an example of configuring a watch face from the phone with no code written on or for the phone.
Editing a watch face using the Galaxy Wearable mobile companion app
If you use the Jetpack Watch Face library to save your watch face configuration options, the values are synced with the mobile companion app. That is, all the cross-device communication is handled for you.
The mobile app will automatically present those options to the user in a simple, intuitive user interface where they change them to whatever works best for their style. It also includes previews that update in real time.
Let’s dive into the API with an overview of the most important components for creating a custom watch face!
A subclass of WatchFaceService forms the entry point of any Jetpack watch face. Implementing a WatchFaceService requires creating 3 objects: A UserStyleSchema, a ComplicationSlotsManager, and a WatchFace:
WatchFaceService
UserStyleSchema
ComplicationSlotsManager
WatchFace
Diagram showing the 3 main parts of a WatchFaceService
These 3 objects are specified by overriding 3 abstract methods from WatchFaceService:
class CustomWatchFaceService : WatchFaceService() { /** * The specification of settings the watch face supports. * This is similar to a database schema. */ override fun createUserStyleSchema(): UserStyleSchema = // ... /** * The complication slot configuration for the watchface. */ override fun createComplicationSlotsManager( currentUserStyleRepository: CurrentUserStyleRepository ): ComplicationSlotsManager = // ... /** * The watch face itself, which includes the renderer for drawing. */ override suspend fun createWatchFace( surfaceHolder: SurfaceHolder, watchState: WatchState, complicationSlotsManager: ComplicationSlotsManager, currentUserStyleRepository: CurrentUserStyleRepository ): WatchFace = // ... }
Let’s take a more detailed look at each one of these in turn, and some of the other classes that the library creates on your behalf.
The UserStyleSchema defines the primary information source for a Jetpack watch face. The UserStyleSchema should contain a list of all customization settings available to the user, as well as information about what those options do and what the default option is. These settings can be boolean flags, lists, ranges, and more.
By providing this schema, the library will automatically keep track of changes to settings by the user, either through the mobile companion app on a connected phone or via changes made on the smartwatch in a custom editor activity.
override fun createUserStyleSchema(): UserStyleSchema = UserStyleSchema( listOf( // Allows user to change the color styles of the watch face UserStyleSetting.ListUserStyleSetting( UserStyleSetting.Id(COLOR_STYLE_SETTING), // ... ), // Allows user to toggle on/off the hour pips (dashes around the outer edge of the watch UserStyleSetting.BooleanUserStyleSetting( UserStyleSetting.Id(DRAW_HOUR_PIPS_STYLE_SETTING), // ... ), // Allows user to change the length of the minute hand UserStyleSetting.DoubleRangeUserStyleSetting( UserStyleSetting.Id(WATCH_HAND_LENGTH_STYLE_SETTING), // ... ) ) )
The current user style can be observed via the CurrentUserStyleRepository, which is created by the library based on the UserStyleSchema.
CurrentUserStyleRepository
It gives you a UserStyle which is just a Map with keys based on the settings defined in the schema:
UserStyle
Map
Map<UserStyleSetting, UserStyleSetting.Option>
As the user’s preferences change, a MutableStateFlow of UserStyle will emit the latest selected options for all of the settings defined in the UserStyleSchema.
MutableStateFlow
currentUserStyleRepository.userStyle.collect { newUserStyle -> // Update configuration based on user style }
Complications allow a watch face to display additional information from other apps on the watch, such as events, health data, or the day.
The ComplicationSlotsManager defines how many complications a watch face supports, and where they are positioned on the screen. To support changing the location or number of complications, the ComplicationSlotsManager also uses the CurrentUserStyleRepository.
override fun createComplicationSlotsManager( currentUserStyleRepository: CurrentUserStyleRepository ): ComplicationSlotsManager { val defaultCanvasComplicationFactory = CanvasComplicationFactory { watchState, listener -> // ... } val leftComplicationSlot = ComplicationSlot.createRoundRectComplicationSlotBuilder( id = 100, canvasComplicationFactory = defaultCanvasComplicationFactory, // ... ) .setDefaultDataSourceType(ComplicationType.SHORT_TEXT) .build() val rightComplicationSlot = ComplicationSlot.createRoundRectComplicationSlotBuilder( id = 101, canvasComplicationFactory = defaultCanvasComplicationFactory, // ... ) .setDefaultDataSourceType(ComplicationType.SHORT_TEXT) .build() return ComplicationSlotsManager( listOf(leftComplicationSlot, rightComplicationSlot), currentUserStyleRepository ) }
The WatchFace describes the type of watch face and how to draw it.
A WatchFace can be specified as digital or analog and can optionally have a tap listener for when the user taps on the watch face.
Most importantly, a WatchFace specifies a Renderer, which actually renders the watch face:
Renderer
override suspend fun createWatchFace( surfaceHolder: SurfaceHolder, watchState: WatchState, complicationSlotsManager: ComplicationSlotsManager, currentUserStyleRepository: CurrentUserStyleRepository ): WatchFace = WatchFace( watchFaceType = WatchFaceType.ANALOG, renderer = // ... )
The prettiest part of a watch face! Every watch face will create a custom subclass of a renderer that implements everything needed to actually draw the watch face to a canvas.
The renderer is in charge of combining the UserStyle (the map from CurrentUserStyleRepository), the complication information from ComplicationSlotsManager, the current time, and other state information to render the watch face.
CurrentUserStyleRepository)
class CustomCanvasRenderer( private val context: Context, surfaceHolder: SurfaceHolder, watchState: WatchState, private val complicationSlotsManager: ComplicationSlotsManager, currentUserStyleRepository: CurrentUserStyleRepository, canvasType: Int ) : Renderer.CanvasRenderer( surfaceHolder = surfaceHolder, currentUserStyleRepository = currentUserStyleRepository, watchState = watchState, canvasType = canvasType, interactiveDrawModeUpdateDelayMillis = 16L ) { override fun render(canvas: Canvas, bounds: Rect, zonedDateTime: ZonedDateTime) { // Draw into the canvas! } override fun renderHighlightLayer(canvas: Canvas, bounds: Rect, zonedDateTime: ZonedDateTime) { // Draw into the canvas! } }
In addition to the system WYSIWYG editor on the phone, we strongly encourage supporting configuration on the smartwatch to allow the user to customize their watch face without requiring a companion device.
To support this, a watch face can provide a configuration Activity and allow the user to change settings using an EditorSession returned from EditorSession.createOnWatchEditorSession. As the user makes changes, calling EditorSession.renderWatchFaceToBitmap provides a live preview of the watch face in the editor Activity.
Activity
EditorSession
EditorSession.createOnWatchEditorSession
EditorSession.renderWatchFaceToBitmap
To see how the whole puzzle fits together to tell the time, check out the watchface sample on GitHub. To learn more about developing for Wear OS, check out the developer website.
Posted by Florina Muntenescu, Developer Relations Engineer
From updates to Jetpack libraries, more guidance on using Kotlin coroutines and Flow in your android app and new versions of Android Studio, here are the top 3 things you should know:
We’ve been working to add the features you’ve been asking us for in a lot of Jetpack libraries, here are a few highlights:
But if you want to deep dive, you should really check out: WorkManager - back to the foreground - where you’ll learn all about the latest APIs and features.
Coroutines are the recommended solution for asynchronous work and Kotlin Flow is the obvious choice for managing streams of data in Android apps. To learn how to use Flows in practice, check out this Android Dev Summit session:
The talk also covers important things like how to stop collecting from the UI when it’s not needed, using the newly stable lifecycle-aware coroutines APIs: repeatOnLifecycle and flowWithLifecycle.
In the Android Studio world, Arctic Fox is stable, Bumblebee is in Beta and Chipmunk is in Canary, all of them bringing a bunch of new features for Jetpack Compose and Material You, developer productivity and 12L and large screens.
The What’s new in Android Studio talk is a must see, especially the sneak peek demo of LiveEdit. LiveEdit is a generalization of live editing of literals, where you get to edit more general scenarios than just constants and strings: you can comment out parts of the UI, reorder composable calls and see the result on the phone in milliseconds. But, we want to make sure that this feature is really right before we include it in Android Studio, so stay tuned for it in the next releases.
You want more? Then sit back, relax and watch the full Modern Android Development playlist.
Posted by Clara Bayarri, Engineering Manager
This year’s Android Dev Summit brought a lot of updates related to Large Screen development for Android, the 12L feature drop on foldables and tablets - a set of features optimising Android 12 for large screens, better developer tools and updates to Google Play purpose-built for large screens. Here are the top 3 things you should know:
12L makes Android 12 even better on Large Screen devices, with a bunch of new refined UI across surfaces such as notifications and the lock screen. The most important announcements for developers included
To find out more about what’s new, check out the What’s new for large screens and foldables video and developer.android.com/12L .
Android has supported Large Screens for a long time, but we announced several new tools to help you scale up your app’s UI to larger form factors.
Learn more about all these items in the Building Android UIs for Any Screen Size and Design beautiful apps on foldables and large screens talks, and check out the latest Large Screen guide and Build adaptive layouts in Compose guide for more. You can also check out Best practices for video apps on foldable devices and Spotify Across Screens for examples on how apps are making this journey.
To help users find the best apps on tablets, foldables and ChromeOS devices, we’ve got new changes in Play to recommend apps optimized for the large screen. This includes new checks to assess app quality, so we can feature large screen optimized apps and update search rankings to show the best possible apps for these devices. We will also be introducing large screen specific app ratings, so users will be able to rate how your app works on their large screen devices.
You can find all of this year’s Android Dev Summit talks related to Large Screens in this playlist, and the full list of announcements for Large Screens in our blog post.
Posted by the Google and Facebook teams. Authored by Kateryna Semenova from the Google Android team and Tim Trueman, Steven Harris, Subramanian Ramaswamy from the Facebook team.
Improving app startup time is not a trivial task and requires a deep understanding of things that affect it. This year, the Google Android team and the Facebook app team have been working together on metrics and sharing approaches to improve app startup. Google Android’s public documentation has a lot of information on app startup optimization. In addition to that we want to share how it applies to the Facebook app and what helped them to improve app startup.
There are now more than 2.9 billion people using Facebook every month. Facebook helps give people the power to build community and bring the world closer together. It is a place for people to share life’s moments, discover and discuss what’s happening, connect and nurture relationships, and help work together to build economic opportunity.
Facebook app developers are committed to ensure that people have the best possible experience and that the app works seamlessly on every device, in any country, and within different network conditions. Working together, the Google Android team and Facebook team aligned on metrics definition for app startup and best practices and shared them in this article.
Start by measuring your startup times. This will let you know how good your user’s startup experience is, track any regressions, as well as how much to invest on improving it. At the end of the day, your startup times need to be tied to user satisfaction or engagement or user-base growth in order to prioritize your investments.
Android defines two metrics to measure app startup times: Time-To-Full-Display (TTFD) and Time-To-Initial-Display (TTID). While you can further split it into cold/warm startup times, this post will not disambiguate between them - Facebook's approach is to measure and optimize the startup time that’s experienced across all users interacting with the app (some of them will be cold, some warm).
TTFD captures the time when your app has completed rendering and is ready for user interaction and consumption, perhaps including content from disk or the network. This can take a while on slow networks and can depend on what surface your users land on. Thus, it may also be helpful to show something right away and let users see progress is still happening, which brings us to TTID…
TTID captures the time for your app to draw its background, navigation, any fast-loading local content, placeholders for slower local content or content coming from the network. TTID should be when users can navigate around and get to where they want to go.
Your users are coming to your app for content that might take a while to load, and you want to deliver that content to them as quickly as you can.
Facebook app developers focus on a metric based on Time To Full Display (TTFD), including all content and images, because that represents the full experience of what users came to the app for. If a network call for content or an image takes a long time or fails, developers want to know so that they can improve the entire start to finish startup experience.
Facebook’s startup metric is the percentage of app starts that they consider “bad,” which is any start that either has a TTFD longer than 2.5 seconds OR any part of startup that is unsuccessful (e.g. an image fails to load or the app crashes). Facebook focuses on driving this percentage of bad starts down either by improving successful starts that take longer than 2.5 seconds, or by fixing issues causing unsuccessful starts. 2.5 seconds was chosen based on research that showed this was meaningful to Facebook users (this also matches the Largest Contentful Paint (LCP) metric in the Web Vitals recommendations for web sites).
Including the full experience, especially of any network calls to fetch recent content, can make your TTFD startup metrics seem really slow compared to TTID. This is actually a good thing! It represents the real experience people have with your app. Improvements you make to this may drive increased usage and perception of your app’s performance for your users like it has at Facebook.
Measuring TTFD can be tricky depending on your app. If it’s too hard, it’s fine to start with Time To Initial Display (TTID). That may miss the performance of loading some of your content if you have placeholders or images, but it’s good to start somewhere even if it’s just a subset of what your users see interacting with your app every day.
In Android 4.4 (API level 19) and higher, logcat provides a “Displayed” value capturing the time elapsed between launching the process and the completion of drawing the first frame of the corresponding activity on the screen.
The reported log line looks similar to the following example:
ActivityManager: Displayed com.android.myexample/.StartupTiming: +3s534ms
To instrument TTFD, call reportFullyDrawn() in your Activity after all your content is on screen. Be sure to include any content that replaces placeholders, as well as any images you render (be sure to count when the image itself is displayed, not just its placeholder). Once you instrument calling reportFullyDrawn(), you can see it in logcat:
ActivityManager: Fully drawn {package}/.MainActivity: +1s54ms
Facebook app developers have been optimizing the app for billions of users across a multitude of devices, platforms and countries for many years. This section shares some of the key lessons that Facebook app developers applied to optimize their app startup.
Google Android team’s recommendations to measure and optimize app startup are available in the public docs: App startup time. This section summarizes some of the key points that ties into Facebook’s recommendations above that all Android app developers should consider.
This article captures some key measures of startup and best practices to improve startup experience that helps drive user engagement and adoption for the Facebook Android app. It also shares metrics, libraries and tools recommended by the Google Android team. Any Android app stands to benefit from applying some of the strategies described in the document. Measure and make your app startup delightful and fast for your users!
Posted by Nick Butcher Developer Relations Engineer
The Android Dev Summit last month brought a number of exciting updates to Jetpack Compose, including that Material You, Google's new design language, is now available in Compose. In case you missed it, here's a recap of all the announcements.
We released Jetpack Compose 1.1 beta. This means that new APIs in 1.1 are now stable, offering new functionality and performance improvements. 1.1 includes new features like improved focus handling & touch target sizing or `ImageVector` caching and support for Android 12 stretch overscroll. Compose 1.1 also graduates a number of previously experimental APIs to stable and supports newer versions of Kotlin. We've already updated our samples, codelabs and Accompanist library to work with Compose 1.1.
We released compose-material3. This is a brand new artifact for building Material You UIs with Jetpack Compose. It offers updated components and color system, including support for dynamic color, creating a personalized color palette from a user's wallpaper. This is our first alpha so we welcome your feedback as we continue to add features and iterate on the APIs. Check out the new m3.material.io website to learn more about Material Design 3 and find tools to help you design & build with dynamic color, like the Material Theme Builder.
We released a ton of talks about Jetpack Compose, providing deep dives into layout, animation and state, showed how to use Compose across Wear OS, homescreen widgets and Large Screens and held 3 code-alongs; live coding your first Compose app, migrating an existing app or using compose on Wear OS. Finally we held a panel discussion, answering your burning questions about Jetpack Compose and Material.
We also expanded the Compose documentation, including new guides on the Phases of Jetpack Compose, Building Adaptive Layouts and expanded theming guidance including guidance for Material 3.
At ADS, Android Studio Bumblebee entered Beta, bringing richer support for Jetpack Compose including:
Android Studio Chipmunk canaries also introduced a new template for Compose (and View based) Material 3 applications.
Lastly, we gave a sneak peak of some new tooling for design handoff, enabling you to export components designed in Figma to generate idiomatic Jetpack Compose code. You can iterate on the designs and pull in new changes, and safely edit the generated code. We're looking for a small group of teams to work directly with, so go sign up.
Jetpack Compose is stable and ready for production. We’ve been thrilled to see tens of thousands of apps start using Jetpack Compose in production and we continue to build our roadmap of features to enable you to use Compose to create excellent apps, across devices.
Sagar Kamdar, VP of Product Management
The app experiences that you as developers build help people around the world in ways we couldn’t have imagined, and at Android Dev Summit, happening over the next two days, we’ll talk about that spirit - focusing on the user, understanding their needs, and then building experiences to delight them. We just wrapped up the keynote, and over the next two days, we’ll focus on an important theme for Android: helping you build excellent apps, across devices. First on updates to our modern Android development offering to help you stay more productive so you can focus on building great applications, and then helping you extend those apps across devices to all form factors. And as a big part of this, we’re introducing the 12L feature drop on foldables and tablets - a set of features optimising Android 12 for large screens - read on to learn more!
When it comes to helping you build excellent apps, our expanding collection of development tools, APIs, language, and distribution technologies–Modern Android Development, MAD for short–are your partners to help you stay more productive. And we’ve got a number of new features across MAD to help you be productive and create better apps, starting with one of our biggest announcements: the introduction of Material You and its radical new design vision into Jetpack Compose, Android's modern toolkit for building native UI.
Material You, introduced in Android 12 earlier this year at Google I/O, focuses on delivering experiences that are personal for every style, accessible for every need, and adaptive for every screen. We’re releasing the first alpha of Compose Material 3, which offers Material Design 3 styled components and theme, enabling Material You personalization features like dynamic color. We’re also releasing the first beta version of Jetpack Compose 1.1 with features like stretch overscroll for Android 12, improved touch-target sizing, experimental lazy layout animations, and more. Jetpack Compose is stable and ready for use in production and we continue to add the features you need to make it fast and easy to build Android UI across all form factors, with new support for Wear OS and for building homescreen widgets.
Beyond Compose, Jetpack continues to add the features you’ve been asking us for. Navigation adds multiple backstacks support. WorkManager, our recommended solution for persistent work, makes it easier to handle Android 12 background restrictions, adding support for expedited jobs. Room adds auto-migration and multi-map relations. DataStore, our recommended replacement for SharedPreferences, has reached 1.0 and Macrobenchmark, a tool to measure and improve startup and frame performance, added simplified and more accurate frame timing, and compatibility back to Android M.
We also have updates to help you build across Android form factors. Learn more about how being available across different Android devices and form factors is helping Spotify achieve their mission of connecting billions of fans with millions of creators.
Large screens have seen some incredible momentum: a 92% Year-over-Year growth in Chrome OS, making it the fastest growing desktop OS in the world, a 20% growth in tablet sales in the last year and a 2.5x growth in foldables sales, the newest and most innovate form factor…altogether those represent over 250M active large screen Android devices - and Android is giving you an OS to match. And we’ve got some… *large* news to *unfold* here: a developer preview of an upcoming feature drop for Android 12, with updates added JUST for large screens; we call it 12L. With 12L we’ve optimised and polished the system UI for large screens, made multitasking more powerful and intuitive, and improved our compatibility support for apps so they look better right out of the box. You can try the new large-screen features today as part of the 12L developer preview. Check out what is in 12L and how we’re making it easier to build for large screens here.
Many developers have created helpful experiences for the latest version of Wear OS which launched earlier this year, and we're looking forward to richer, more immersive app experiences like what we’re seeing from Strava, Spotify, and Calm. Jetpack Compose makes building UIs so much faster and easier - so we’re bringing Compose support to Wear OS. Compose for Wear OS is now in developer preview, with new samples and documentation to help you get started. The Tiles API, now in Beta, provides predictable, glanceable access to information and quick actions. We’ve also partnered with Samsung to make it easier to design watch faces. Watch Face Studio, created by Samsung, allows you to produce your own watch faces without any coding, so watch you see..is watch you get. You can read more about all of the Wear OS news here.
We’ve invested in more ways to power your business growth on Google Play. To strengthen user trust, we’ve introduced the Data safety section to highlight your privacy practices and the Play Integrity API to make sure your app installs are always genuine. We’ve also invested in more tools and features to help boost your app quality and recently updated our programs so that 99% of developers qualify for a service fee of 15% or less. To learn more, check out our blog post or watch the full session.
We just dropped over 30 technical sessions, which you can watch here at your own pace. And over the next two days, we have a lot more live content for you to enjoy - including your opportunity to get your burning #AskAndroid questions answered by the team who built Android on topics like Modern Android Development, Large Screens, or Compose with Material You. Plus, we’ll also be hosting live Android Code-Alongs, where you can tune in to watch Android experts as they code, tackle programming challenges, and answer your questions live across Jetpack Compose and Compose for Wear OS. You can check out the full agenda with timings here. While we can’t wait for the opportunity to connect with you in person soon, we’re excited to engage with you remotely over the next two days. Enjoy your #AndroidDevSummit!
Posted by Dave Burke, VP of Engineering
There are over a quarter billion large screen devices running Android across tablets, foldables, and ChromeOS devices. In just the last 12 months we’ve seen nearly 100 million new Android tablet activations–a 20% year-over-year growth, while ChromeOS, now the fastest growing desktop platform, grew by 92%. We’ve also seen Foldable devices on the rise, with year on year growth of over 265%! All told, there are over 250 million active large screen devices running Android. With all of the momentum, we’re continuing to invest in making Android an even better OS on these devices, for users and developers.
So today at Android Dev Summit, we announced a feature drop for Android 12 that is purpose-built for large screens, we’re calling it 12L, along with new APIs, tools, and guidance to make it easier to build for large screens. We also talked about changes we’re making to Google Play to help users discover your large-screen optimized apps more easily. Read on to see what’s new for large screens on Android!
Today we're bringing you a developer preview of 12L, our upcoming feature drop that makes Android 12 even better on large screens. With the preview, you can try the new large screen features, optimize your apps, and let us know your feedback.
In 12L we’ve refined the UI on large screens across notifications, quick settings, lockscreen, overview, home screen, and more. For example, on screens above 600dp, the notification shade, lockscreen, and other system surfaces use a new two-column layout to take advantage of the screen area. System apps are also optimized.
Two-column layouts show more and are easier to use
We’ve also made multitasking more powerful and intuitive - 12L includes a new taskbar on large screens that lets users instantly switch to favorite apps on the fly. The taskbar also makes split-screen mode more discoverable than ever - just drag-and-drop from the taskbar to run an app in split-screen mode. To make split-screen mode a better experience in Android 12 and later, we’re helping users by automatically enabling all apps to enter split screen mode, regardless whether the apps are resizable.
Drag and drop apps into split-screen mode
Last, we’ve improved compatibility mode with visual and stability improvements to offer a better letterboxing experience for users and help apps look better by default. We’ve made letterboxing easily customizable by device manufacturers, who can now set custom letterbox colors or treatments, adjust the position of the inset window, apply custom rounded corners, and more.
We plan to release the 12L feature drop early next year, in time for the next wave of Android 12 tablets and foldables. We’re already working with our OEM partners to bring these features to their large screen devices - watch for the developer preview of 12L coming soon to the Lenovo P12 Pro. With the features coming to devices in the few months ahead, now is a great time to optimize your apps for large screens.
For developers, we highly recommend checking out how your apps work in split screen mode with windows of various sizes. If you haven’t optimized your app yet, see how it looks in different orientations and try the new compatibility mode changes if they apply. Along with the large screen features, 12L also includes a handful of new APIs for developers, along with a new API level. We’ve been careful not to introduce any breaking changes for your apps, so we won’t require apps to target 12L to meet Google Play requirements.
To get started with 12L, download the 12L Android Emulator system images and tools from the latest preview release of Android Studio. Review the features and changes to learn about areas to test in your apps, and see preview overview for the timeline and release details. You can report issues and requests here, and as always, we appreciate your feedback!
12L is for phones, too, but since most of the new features won’t be visible on smaller screens, for now we’re keeping the focus on tablets, foldables, and ChromeOS devices. Later in the preview we plan to open up Android Beta enrollments for Pixel devices. For details, visit developer.android.com/12L.
It's time to start designing fully adaptive apps to fit any screen, and now we're making it even easier. To help you get ready for these changes in the OS and Play, along with the developer preview we're releasing updates to our APIs, tools and guidance.
The first step to supporting adaptive UI is designing your app to behave nicely on both a small and a larger screen. We’ve been working on new Material Design guidance that will help you scale your app’s UI across all screens. The guidance covers common layout patterns prevalent in the ecosystem that will help inspire and kick-start your efforts.
Adaptive UI patterns in the Material Design guidelines
To provide the best possible navigation experience to your users, you should provide a navigation UI that is tailored to the Window Size Class of the user’s device. The recommended navigation patterns include using a navigation bar for compact screens and a navigation rail for medium-width device classes and larger (600dp+). For expanded-width devices, there are several ideas on larger screen layouts within our newly released Material Design guidance such as a List/Detail structure that can be implemented, using SlidingPaneLayout. Check out our guidance on how to implement navigation for adaptive UIs in Views and Compose.
While updating the navigation pattern and using a SlidingPaneLayout is a great way to apply a large screen optimized layout to an existing application with fragments, we know many of you have applications based on multiple activities. For those apps, the new activity embedding APIs released in Jetpack WindowManager 1.0 beta 03 make it easy to support new UI paradigms, such as a TwoPane view. We’re working on updating SlidingPaneLayout to support those APIs - look for an update in the coming months.
SlidingPaneLayout
Jetpack Compose makes it easier to build for large screens and diverse layouts. If you’re starting to adopt Compose, it’s a great time to optimize for large screens along the way.
Compose is a declarative UI toolkit; all UI is described in code, and it is easy to make decisions at runtime of how it should adapt to the available size. This makes Compose especially great for developing adaptive UI, as it is very easy to handle UI changes across different screen sizes or components. The Build adaptive layouts in Compose guide covers the basics of what you need to know.
The Jetpack WindowManger library provides a backward-compatible way to work with windows in your app and build responsive UI for all devices. Here’s what’s new.
Activity embedding
Activity embedding lets you take advantage of the extra display area of large screens by showing multiple activities at once, such as for the List-Detail pattern, and it requires little or no refactoring of your app. You determine how your app displays its activities—side by side or stacked—by creating an XML configuration file or making Jetpack WindowManager API calls. The system handles the rest, determining the presentation based on the configuration you’ve created.
Activity embedding works seamlessly on foldable devices, stacking and unstacking activities as the device folds and unfolds. If your app uses multiple activities, activity embedding can enhance your user experience on large screen devices. Try the activity embedding APIs in Jetpack WindowManager 1.0 Beta 03 and later releases. More here.
Activity embedding with Jetpack WindowManager
Use Window size classes to help detect the size of your window
Window Size Classes are a set of opinionated viewport breakpoints for you to design, develop and test resizable application layouts against. The Window Size Class breakpoints have been split into three categories: compact, medium, and expanded. They have been designed specifically to balance layout simplicity with the flexibility to optimize your app for the most unique use cases, while representing a large proportion of devices in the ecosystem. The WindowSizeClass APIs will be coming soon in Jetpack WindowManager 1.1 and will make it easier to build responsive UIs. More here.
Window Size Classes in Jetpack WindowManager
Make your app fold-aware
WindowManager also provides a common API surface for different window features, like folds and hinges. When your app is fold aware, the content in the window can be adapted to avoid folds and hinges, or to take advantage of them and use them as natural separators. Learn how you can make your app fold aware in this guide.
Reference Devices
Since Android apps should be built to respond and adapt to all devices and categories, we’re introducing Reference Devices across Android Studio in many tools where you design, develop and test UI and layout. The four reference devices represent phones, large foldable inner displays, tablets, and desktops. We’ve designed these after analyzing market data to represent either popular devices or rapidly growing segments. They also enable you to ensure your app works across popular breakpoint combinations with the new WindowSizeClass breakpoints, to ensure your app covers as many use cases as possible.
Reference Device definitions
Layout validation
If you’re not sure where to get started adapting your UI for large screens, the first thing you can do is use new tools to identify potential issues impacting large screen devices. In Android Studio Chipmunk, we’re working on a new visual linting tool to proactively surface UI warnings and suggestions in Layout Validation, including which reference devices are impacted.
Layout validation tool with Reference Device classes
Resizable emulator
To test your app at runtime, we can use the new resizable emulator configuration that comes with Android Studio Chipmunk. The resizable emulator lets you quickly toggle between the four reference devices - phone, foldable, tablet, and desktop. This makes it easier to validate your layout at design time and test the behavior at runtime, both using the same reference devices. To create a new Resizable emulator, use the Device Manager in Android Studio to create a new Virtual Device and select the Resizable device definition with the Android 12L (Sv2) system image.
Resizable Android Emulator
To make it easier for people to find the best app experiences on their tablets, foldables, and ChromeOS devices, we're making changes in Play to highlight apps that are optimized for their devices.
We’re adding new checks to assess each app’s quality against our large screen app quality guidelines to ensure that we surface the best possible apps on those devices. For apps that are not optimized for large screens, we’ll start warning large screen users with a notice on the app’s Play Store listing page.
We'll also be introducing large screen specific app ratings, as announced earlier this year, so users will be able to rate how your app works on their large screen devices. These changes are coming next year, so we're giving you advanced notice to get your apps ready!
Also, make sure to check out our post that highlights how we are evolving our business model to address developer needs in Google Play.
To help you get started with building for large screens and foldables, no matter whether you’re using Views or Compose, we’ve got you covered! We’re launching new and updated guidance on how to support different screen sizes both in a new and in an existing app, how to implement navigation for both Views and Compose, how to take advantage of foldable devices and more. Check them out in the large screens guides section for Views support or in the Compose guides section.
Nothing speaks louder than code - we updated the following samples to support responsive UIs:
For some hands-on work, check out our Support foldable and dual-screen devices with Jetpack WindowManager updated codelab.
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