Posted by Adarsh Fernando, Product Manager
During these uncertain times, we’re humbled by the many developers around the world who are finding ways to keep doing what they do best—create amazing apps for Android. Whether you’re working from your kitchen table on a laptop or from a home office, you need tools that keep up with you. Android Studio 4.0 is the result of our drive to bring you new and improved tools for coding smarter, building faster, and designing the apps your users depend on, and it’s now available on the stable channel.
Some highlights of Android Studio 4.0 include a new Motion Editor to help bring your apps to life, a Build Analyzer to investigate causes for slower build times, and Java 8 language APIs you can use regardless of your app’s minimum API level. Based on your feedback, we’ve also overhauled the CPU Profiler user interface to provide a more intuitive workflow and easier side-by-side analysis of thread activity. And the improved Layout Inspector now provides live data of your app’s UI, so you can easily debug exactly what’s being shown on the device.
As always, this release wouldn’t be possible without the early feedback from our Preview users. So read on or watch below for further highlights and new features you can find in this stable version. If you’re ready to jump in and see for yourself, head over to the official website to download Android Studio 4.0 now.
The MotionLayout API extends the rich capabilities of ConstraintLayout to help Android developers manage complex motion and widget animation in their apps. In Android Studio 4.0, using this API is made easier with the new Motion Editor—a powerful interface for creating, editing, and previewing MotionLayout animations. You no longer have to create and modify complex XML files; the Motion Editor generates them for you, with support for editing constraint sets, transitions, keyframes, and view attributes. And if you do want to see the code the editor creates, it is one click away. And just as conveniently, for developers already using ConstraintLayout, the IDE can easily convert those to MotionLayout. Learn more
ConstraintLayout
MotionLayout
Create, edit, and preview animations in the Motion Editor
Have you ever wanted to investigate where a value for a particular attribute came from? Or see a live 3D representation of nested views to more easily inspect your view hierarchy? With the new Layout Inspector, debugging your UI is much more intuitive by giving you access to data that stays updated with your running app and providing insights on how resources are being resolved.
Debug your app’s UI in real-time with Live Layout Inspector
Use the live Layout Inspector by selecting View > Tool Windows > Layout Inspector from the main menu. If you are deploying to a device running API 29 level or higher, you have access to additional features, such as a dynamic layout hierarchy that updates as views change, detailed view attributes that also help you determine how resource values are resolved, and a live 3D model of your running app’s UI. Navigate, animate, and transition between views on your running app while always having the ability to debug your UI to pixel perfection. Learn more
Compare your UI across multiple screens with Layout Validation
When you’re developing for multiple form-factors, screen sizes, and resolutions, you need to verify that changes you make to your UI look great on every screen you support. With the Layout Validation window, you can preview layouts on different screens and configurations simultaneously, so you can easily ensure your app looks great across a range of devices. To get started, click on the Layout Validation tab in the top-right corner of the IDE.
The improved UI of the CPU Profiler
The CPU profiler is designed to provide a rich amount of information about your app’s thread activity and trace recordings. So, when you provided us feedback about how we can make the UI even more intuitive to navigate and the data easier to understand, we listened. In Android Studio 4.0, CPU recordings are now separated from the main profiler timeline and organized in groups to allow for easier analysis. You can move groups up and down, or drag-and-drop individual items within a group for additional customization.
Easier side-by-side analysis of thread activity
For easier side-by-side analysis, you can now view all thread activity in the Thread Activity timeline (including methods, functions, and events) and try new navigation shortcuts to easily move around the data—such as using W, A, S, and D keys for fine-grained zooming and panning. We’ve also redesigned the System Trace UI so Events are uniquely colored for better visual distinction, threads are sorted to surface the busier ones first, and you can now focus on seeing data for only the threads you select. Finally, we invested in the quality of the CPU profiler, and consequently we’ve seen a significant decrease in the user-reported error rates of recordings since Android Studio 3.6. There are even more improvements to try, so learn more.
Smart editor feature when writing rules for R8
R8 was introduced in Android Gradle plugin 3.4.0 to combine desugaring, shrinking, obfuscating, optimizing, and dexing all in one step—resulting in noticeable build performance improvements. When creating rules files for R8, Android Studio now provides smart editor features, such as syntax highlighting, completion, and error checking. The editor also integrates with your Android project to provide full symbol completion for all classes, methods, and fields, and includes quick navigation and refactoring.
The core Android Studio IDE has been updated with improvements from IntelliJ IDEA 2019.3 and 2019.3.3 releases. These improvements largely focus on quality and performance improvements across the IDE.
Live templates is a convenient IntelliJ feature that allows you to insert common constructs into your code by typing simple keywords. Android Studio now includes Android-specific live templates for your Kotlin code. For example, simply type toast and press the Tab key to quickly insert boilerplate code for a Toast. For a full list of available live templates, navigate to Editor > Live Templates in the Settings (or Preferences) dialog.
toast
For developers writing C++, we have switched to clangd as the primary language analysis engine for code navigation, completion, inspection, and showing code errors and warnings. We also now bundle clang-tidy with Android Studio. To configure Clangd or Clang-Tidy behavior, go to the IDE Settings (or Preferences) dialog, navigate to Languages & Frameworks > C/C++ > Clangd or Clang-Tidy, and configure the options.
Android Gradle plugin 4.0.0 includes support for Android Studio’s Build Analyzer by using Java 8 language APIs (regardless of your app’s minimum API level), and creating feature-on-feature dependencies between Dynamic Feature modules. For a full list of updates, read the Android Gradle plugin 4.0.0 release notes.
Address bottlenecks in your build performance with Build Analyzer
Android Developers rely on a variety of Gradle plugins and custom build logic to tailor the build system for their app. However, outdated or misconfigured tasks can cause longer build times that lead to frustration and lost productivity. The Build Analyzer helps you understand and address bottlenecks in your build by highlighting the plugins and tasks that are most responsible for your overall build time and by suggesting steps to mitigate regressions. Learn more
Previous versions of the Android Gradle plugin supported a variety of Java 8 language features for all API levels, such as lambda expressions and method references, through a process called desugaring. In Android Studio 4.0, the desugaring engine has been extended to support Java language APIs, regardless of your app’s minSdkVersion. This means that you can now use standard language APIs, which were previously available in only recent Android releases (such as java.util.stream, java.util.function and java.time). Learn more
Feature-on-feature dependencies
When using Android Gradle plugin 4.0.0 and higher, you can now specify that a Dynamic Feature module depends on another feature module. Being able to define this relationship ensures that your app has the required modules to unlock additional functionality, resulting in fewer requests and easier modularization of your app. For example, a :video feature can depend on the :camera feature. If a user wants to unlock the ability to record videos, your app automatically downloads the required :camera module when it requests :video. Learn more
:video
:camera
The Android Gradle plugin has built-in support for modern libraries, such as data binding and view binding, and build features, such as auto-generated BuildConfig classes. However, you might not need these libraries and features for every project. In version 4.0.0 of the plugin, you can now disable discrete build features, as shown below, which can help optimize build performance for larger projects. For the DSL and full list of features you can control, see the release notes.
android { // The default value for each feature is shown below. // You can change the value to override the default behavior. buildFeatures { // Determines whether to support View Binding. // Note that the viewBinding.enabled property is now deprecated. viewBinding = false // Determines whether to support Data Binding. // Note that the dataBinding.enabled property is now deprecated. dataBinding = false ... } }
Android Gradle plugin DSL for enabling or disabling build features
Android Studio 4.0 now has built-in support for Kotlin DSL build script files (*.kts), which means that Kotlin build scripts offer a full suite of quick fixes and are supported by the Project Structure dialog. While we are excited about the potential for using Kotlin to configure your build, we will continue to refine the Android Gradle Plugin’s DSL API throughout the next year, which may result in breaking API changes for Kotlin script users. Long term, these fixes will make for a more idiomatic, easy-to-use DSL for Kotlin script users.
When building your app using Android Gradle plugin 4.0.0 and higher, the plugin includes metadata that describes the library dependencies that are compiled into your app. When uploading your app, the Play Console inspects this metadata to provide alerts for known issues with SDKs and dependencies your app uses, and, in some cases, provide actionable feedback to resolve those issues.
The data is compressed, encrypted by a Google Play signing key, and stored in the signing block of your release app. If you’d rather not share this information, you can easily opt-out by including the following in your module’s build.gradle file:
build.gradle
android { dependenciesInfo { // Disables dependency metadata when building APKs. includeInApk = false // Disables dependency metadata when building Android App Bundles. includeInBundle = false } }
Disable dependency metadata for your APKs, app bundle, or both
To recap, Android Studio 4.0 includes these new enhancements & features:
Design
Develop & Profile
Build
For a full list of changes, read the official release notes.
Download Android Studio 4.0 from the download page. If you are using a previous release of Android Studio, you can simply update to the latest version of Android Studio.
As always, we appreciate any feedback on things you like, and issues or features you would like to see. If you find a bug or issue, please file an issue. Follow us -- the Android Studio development team ‐ on Twitter and on Medium.
Posted by The #Android11 team
In just under a week, we’ll kick off #Android11: The Beta Launch Show, your opportunity to find out what’s new in Android from the people who build Android. Join us on June 3, 11AM ET (8AM PT, 4PM BST, 8:30PM IST) as we unveil new features packed inside the next release, Android 11, as well as updates to help developers get the most out of modern Android development. You’ll be able to watch the show live on YouTube (don’t forget to set a reminder) or Twitter, and can sign-up for updates here.
Got a burning question? We’ve got experts ready to answer your #AskAndroid questions, and we’ll be wrapping up the show with a live Q&A session. All you have to do is share your question on Twitter using #AskAndroid, and we’ll be selecting questions for Android engineering and product leads Dave Burke and Stephanie Cuthbertson to answer live on-the-air.
Also on June 3, we’ll be sharing 12 talks on a range of topics from Jetpack to Android Studio and Google Play–talks that we had originally planned for Google I/O–to help you take advantage of the latest in Android development. We just posted the full list of talks on the event page.
We want to see your take on the show, so grab your best pens, markers, and paper, download the template, and get ready to show off your sketchnote skills during The Beta Launch Show. Don’t forget to share your work using the hashtag #Android11 for a chance to be featured.
We can’t wait to share with you the latest we’ve been working on with you in just over a week at #Android11: The Beta Launch Show!
Posted by Dom Elliott, Product Manager, Google Play
Google Play's first priority is to build a trusted, safe, and secure platform for billions of users and millions of developers for many years into the future. The sustainability and success of the ecosystem depends on this.
As part of this goal, almost two years ago, we announced app signing by Google Play. With app signing by Google Play, Google manages and protects your app's signing key for you and uses it to sign your APKs for distribution. It’s a secure way to store your app signing key that helps protect you if your key is ever lost or compromised. If you’re not enrolled in app signing and you lose your signing key, you’ll lose the ability to update your app.
App signing by Play also enables you to publish your app or game with the Android App Bundle, the recommended publishing format in use by over 500,000 apps in production on Google Play. The Android App Bundle reduces the size of your app, simplifies your releases, and unlocks next generation distribution features such as dynamic features and dynamic asset delivery.
Developers often have questions when enrolling in app signing for the first time so my colleague has written a Medium post with answers to some frequently asked questions. Read the post to find out more about the benefits of app signing, how we protect developer keys, and to learn about features like key upgrade for new installs and the new source stamp that bundletool will start adding to apps published with app bundles to give you more peace of mind about Play-signed apps.
Posted by Dave Burke, VP of Engineering
When we started planning Android 11, we didn’t expect the kinds of changes that would find their way to all of us, across nearly every region in the world. These have challenged us to stay flexible and find new ways to work together, especially with our developer community.
To help us meet those challenges we’re announcing an update to our release timeline. We’re bringing you a fourth Developer Preview today and moving Beta 1 to June 3. And to tell you all about the release and give you the technical resources you need, we’re hosting an online developer event that we’re calling #Android11: the Beta Launch Show.
While the circumstances prevent us from joining together with you in-person at Shoreline Amphitheatre for Google I/O, our annual developer conference, we’re organizing an online event where we can share with you all the best of what’s new in Android. We hope you’ll join us for #Android11: The Beta Launch Show, your opportunity to find out what’s new in Android from the people who build Android. Hosted by me, Dave Burke, we’ll be kicking off at 11AM ET on June 3. And we’ll be wrapping it up with a post-show live Q&A; tweet your #AskAndroid questions to get them answered live!
Later that day, we’ll be sharing a number of talks on a range of topics from Jetpack Compose to Android Studio and Google Play–talks that we had originally planned for Google I/O–to help you take advantage of the latest in Android development. You can sign-up to receive updates on this digital event at developer.android.com/android11.
Our industry moves really fast, and we know that many of our device-maker partners are counting on us to help them bring Android 11 to new consumer devices later this year. We also know that many of you have been working to prioritize early app and game testing on Android 11, based in part on our Platform Stability and other milestones. At the same time, all of us are collaborating remotely and prioritizing the well-being of our families, friends and colleagues.
So to help us meet the needs of the ecosystem while being mindful of the impacts on our developers and partners, we’ve decided to add a bit of extra time in the Android 11 release schedule. We’re moving out Beta 1 and all subsequent milestones by about a month, which gives everyone a bit more room but keeps us on track for final release later in Q3.
Here are some of the key changes in the new schedule:
By bringing you the final APIs on the original timeline while shifting the other dates, we’re giving you an extra month to compile and test with the final APIs, while also ensuring that you have the same amount of time between Platform Stability and the final release, planned for later in Q3. Here’s a look at the timeline.
You can read more about what the new timeline means to app developers in the preview program overview.
The schedule change adds some extra time for you to test your app for compatibility and identify any work you’ll need to do. We recommend releasing a compatible app update by Android 11 Beta on June 3rd to get feedback from the larger group of Android Beta users who will be getting the update.
With Beta 1 the SDK and NDK APIs will be final, and as we reach Platform Stability in July, the system behaviors and non-SDK greylists will also be finalized. At that time, plan on doing your final compatibility testing and releasing your fully compatible app, SDK, or library as soon as possible so that it is ready for the final Android 11 release. You can read more in the timeline for developers.
You can start compatibility testing today on a Pixel 2, 3, 3a, or 4 device, or you can use the Android Emulator. Just flash the latest build, install your current production app, and test the user flows. Make sure to review the behavior changes for areas where your app might be affected. There’s no need to change the app’s targetSdkVersion at this time, although we recommend evaluating the work since many changes apply once your app is targeting the new API level.
Today we're pushing a Developer Preview 4 with the latest bug fixes, API tweaks, and features to try in your apps. It’s available by manual download and flash for Pixel 2, 3, 3a, or 4 devices, and if you’re already running a Developer Preview build, you’ll get an over-the-air (OTA) update to today’s release.
For complete information on Android 11, visit the Android 11 developer site, and please continue to let us know what you think!
Posted by Ady Abraham, Software Engineer
For a long time, phones have had a display that refreshes at 60Hz. Application and game developers could just assume that the refresh rate is 60Hz, frame deadline is 16.6ms, and things would just work. This is no longer the case. New flagship devices are built with higher refresh rate displays, providing smoother animations, lower latency, and an overall nicer user experience. There are also devices that support multiple refresh rates, such as the Pixel 4, which supports both 60Hz and 90Hz.
A 60Hz display refreshes the display content every 16.6ms. This means that an image will be shown for the duration of a multiple of 16.6ms (16.6ms, 33.3ms, 50ms, etc.). A display that supports multiple refresh rates, provides more options to render at different speeds without jitter. For example, a game that cannot sustain 60fps rendering must drop all the way to 30fps on a 60Hz display to remain smooth and stutter free (since the display is limited to present images at a multiple of 16.6ms, the next framerate available is a frame every 33.3ms or 30fps). On a 90Hz device, the same game can drop to 45fps (22.2ms for each frame), providing a much smoother user experience. A device that supports 90Hz and 120Hz can smoothly present content at 120, 90, 60 (120/2), 45(90/2), 40(120/3), 30(90/3), 24(120/5), etc. frames per second.
The higher the rendering rate, the harder it is to sustain that frame rate, simply because there is less time available for the same amount of work. To render at 90Hz, applications only have 11.1ms to produce a frame as opposed to 16.6ms at 60Hz.
To demonstrate that, let’s take a look at the Android UI rendering pipeline. We can break frame rendering into roughly five pipeline stages:
The entire pipeline is controlled by the Android Choreographer. The Choreographer is based on the display vertical synchronization (vsync) events, which indicate the time the display starts to scanout the image and update the display pixels. The Choreographer is based on the vsync events but has different wakeup offsets for the application and for SurfaceFlinger. The diagram below illustrates the pipeline on a Pixel 4 device running at 60Hz, where the application is woken up 2ms after the vsync event and SurfaceFlinger is woken up 6ms after the vsync event. This gives 20ms for an app to produce a frame, and 10ms for SurfaceFlinger to compose the screen.
When running at 90Hz, the application is still woken up 2ms after the vsync event. However, SurfaceFlinger is woken up 1ms after the vsync event to have the same 10ms for composing the screen. The app, on the other hand, has just 10ms to render a frame, which is very short.
To mitigate that, the UI subsystem in Android is using “render ahead” (which delays a frame presentation while starting it at the same time) to deepen the pipeline and postpone frame presentation by one vsync. This gives the app 21ms to produce a frame, while keeping the throughput at 90Hz.
Some applications, including most games, have their own custom rendering pipelines. These pipelines might have more or fewer stages, depending on what they are trying to accomplish. In general, as the pipeline becomes deeper, more stages could be performed in parallel, which increases the overall throughput. On the other hand, this can increase the latency of a single frame (the latency will be number_of_pipeline_stages x longest_pipeline_stage). This tradeoff needs to be considered carefully.
As mentioned above, multiple refresh rates allow a broader range of available rendering rates to be used. This is especially useful for games which can control their rendering speed, and for video players which need to present content at a given rate. For example, to play a 24fps video on a 60Hz display, a 3:2 pulldown algorithm needs to be used, which creates jitter. However, if the device has a display that can present 24fps content natively (24/48/72/120Hz), it will eliminate the need for pulldown and the jitter associated with it.
The refresh rate that the device operates at is controlled by the Android platform. Applications and games can influence the refresh rate via various methods (explained below), but the ultimate decision is made by the platform. This is crucial when more than one app is present on the screen and the platform needs to satisfy all of them. A good example is a 24fps video player. 24Hz might be great for video playback, but it’s awful for responsive UI. A notification animating at only 24Hz feels janky. In situations like this, the platform will set the refresh rate to ensure that the content on the screen looks good.
For this reason, applications may need to know the current device refresh rate. This can be done in the following ways:
Applications can influence the device refresh rate by setting a frame rate on their Window or Surface. This is a new capability introduced in Android 11 and allows the platform to know the rendering intentions of the calling application. Applications can call one of the following methods:
Please refer to the frame rate guide on how to use these APIs.
The system will choose the most appropriate refresh rate based on the frame rate programmed on the Window or Surface.
On Older Android versions (before Android 11) where the setFrameRate API doesn’t exist, applications can still influence the refresh rate by directly setting WindowManager.LayoutParams.preferredDisplayModeId to one of the available modes from Display.getSupportedModes. This approach is discouraged starting with Android 11 since the platform doesn’t know the rendering intention of the app. For example, if a device supports 48Hz, 60Hz and 120Hz and there are two applications present on the screen that call setFrameRate(60, …) and setFrameRate(24, …) respectively, the platform can choose 120Hz and make both applications happy. On the other hand, if those applications used preferredDisplayModeId they would probably set the mode to 60Hz and 48Hz respectively, leaving the platform with no option to set 120Hz. The platform will choose either 60Hz or 48Hz, making one app unhappy.
Refresh rate is not always 60Hz - don’t assume 60Hz and don’t hardcode assumptions based on that historical artifact.
Refresh rate is not always constant - if you care about the refresh rate, you need to register a callback to find out when the refresh rate changes and update your internal data accordingly.
If you are not using the Android UI toolkit and have your own custom renderer, consider changing your rendering pipeline according to the current refresh rate. Deepening the pipeline can be done by setting a presentation timestamp using eglPresentationTimeANDROID on OpenGL or VkPresentTimesInfoGOOGLE on Vulkan. Setting a presentation timestamp indicates to SurfaceFlinger when to present the image. If it is set to a few frames in the future, it will deepen the pipeline by the number of frames it is set to. The Android UI in the example above is setting the present time to frameTimeNanos1 + 2 * vsyncPeriod2
frameTimeNanos
+ 2 * vsyncPeriod
Tell the platform your rendering intentions using the setFrameRate API. The platform will match different requests by selecting the appropriate refresh rate.
Use preferredDisplayModeId only when necessary, either when setFrameRate API is not available or when you need to use a very specific mode.
Lastly, familiarize yourself with the Android Frame Pacing library. This library handles proper frame pacing for your game and uses the methods described above to handle multiple refresh rates.
frameTimeNanos received from Choreographer ↩
frameTimeNanos received from Choreographer
vsyncPeriod received from Display.getRefreshRate()
Our teams, like all of you, continue getting used to a new normal. For many of us, that means working from living rooms, kitchens, backyards and bedrooms. So, from our homes to yours, we wanted to take a moment to share our most recent developer preview for Android 11. This update includes bug fixes and a set of productivity improvements for developers.
You can see some of the highlights below, and visit the Android 11 developer site for details on all of the new features in Android 11. Today’s release is for developers and not intended for daily or consumer use, so we’re making it available by manual download and flash for Pixel 2, 3, 3a, or 4 devices. If you’re already running a Developer Preview build, you’ll receive an over-the-air (OTA) update to today’s release soon. As always, let us know what you think, and thank you for the helpful feedback you’ve shared so far.
In today’s release there are a number of new features and changes for you to try, as well as the latest updates to existing features, APIs, and tools. Here are just a few:
App exit reasons updates - Apps can exit for a variety of reasons, from crash to system kill or user action. Across the many device types, memory configurations, and user scenarios that your app runs in, it’s important to understand why the app exited and what the state was at the time. Android 11 makes this easier with an exit reasons API that you can use to request details of the app’s recent exits. In DP3 we’ve updated the APIs based on your input, so please take a look. If you haven’t had a chance to check out this new API yet, we recommend giving it a try and please let us know what you think here.
GWP-ASan heap analysis - Android 11 uses a variety of tools to harden security-critical components in the platform and apps. In DP3, we’re adding GWP-ASan as another way to help developers find and fix memory safety issues. GWP-ASan is a sampling allocation tool that detects heap memory errors with minimal overhead or impact on performance. We’ve enabled GWP-ASan to run by default in platform binaries and system apps, and now you can now enable it for your apps as well. If your app uses native code or libraries, we recommend enabling GWP-ASan and testing as soon as possible. For details, see the documentation.
ADB Incremental - Installing very large APKs with ADB (Android Debug Bridge) during development can be slow and impact your productivity, especially those developers working on Android Games. With ADB Incremental in Android 11, installing large APKs (2GB+) from your development computer to an Android 11 device is up to 10x faster. To use this new developer tool, first sign your APK with the new APK signature scheme v4 format, and then install your APK with the updated ADB command line tool found in the Android 11 Preview SDK. This new feature is part of a broad suite of new tools we're investing in to make you more productive in building games on Android. Note that in DP3, ADB Incremental only works with Pixel 4 / 4XL devices due to a required file system change at the device level. All new devices launching with Android 11 will include this change and will support ADB Incremental. Learn more here.
Wireless Debugging - In Android 11, we’ve completely revamped the debugging experience using ADB over a Wi-Fi connection. With limited USB ports on laptops, and a myriad of USB cables & connections to manage, the Wireless Debugging feature in Android 11 can help you be more productive. Unlike the existing TCP/IP debugging workflow, Wireless Debugging on Android 11 does not need a cable to set up, remembers connections over time, and can utilize the full speed of the latest Wi-Fi standards. In DP3, use the pairing code workflow to get started with this developer feature. We plan to add an integrated experience for Wireless Debugging with QR code scanning in a future Android Studio release, but we want to get your early feedback on the command line tool offered in Android 11 DP3. For details, see the documentation.
Try the new wireless debugging feature in Developer Options.
Data access auditing updates - In DP3 we renamed several of the APIs for this Android 11 developer feature. If you are already using the APIs, make sure to check out the changes. If you aren’t familiar, data access auditing lets you instrument your app to better understand how it accesses user data and from which user flows. For example, It can help you identify any inadvertent access to private data in your own code or within any SDKs you might be using. Give data access auditing a try in your apps - you can read more here. Let us know your feedback here.
For details on everything that’s changed in Developer Preview 3, take a look at the DP3 diff report and read the release notes for details about known issues.
With Developer Preview 3, we’re well on the way to finalizing features and APIs and shifting our focus to polish and performance. If you haven’t already, now is the time to begin testing your app for compatibility and identify any work you’ll need to do. We recommend releasing a compatible app update by Android 11 Beta to get feedback from the larger group of Android Beta users.
When we reach Platform Stability, system behaviors, non-SDK greylists, and APIs are finalized. At that time, plan on doing your final compatibility testing and releasing your fully compatible app, SDK, or library as soon as possible so that it is ready for the final Android 11 release. You can read more in the timeline for developers.
To help you test, we’ve made many of the targetSdk changes toggleable, so you can force-enable or disable them individually from Developer options or ADB. Check out the details here. Also see the greylists of restricted non-SDK interfaces, which can also be enabled/disabled.
App compatibility toggles in Developer Options.
Developer Preview 3 has everything you need to try the latest Android 11 features, test your apps, and give us feedback. Just download and flash a device system image to a Pixel 2 / 2 XL, Pixel 3 / 3 XL, Pixel 3a / 3a XL, or Pixel 4 / 4 XL device, or set up the Android Emulator through Android Studio. Next, update your Android Studio environment with the latest Android 11 Preview SDK and tools, see the set up guide for details.
As always, your feedback is crucial, so please continue to let us know what you think — the sooner we hear from you, the more of your feedback we can integrate. When you find issues, please report them here.
For complete information on Android 11, visit the Android 11 developer site.
Since 2014, Android WebView has paved the way as an updateable system component, delivering stability and performance improvements, modern web platform features, and security patches to Android apps and users. However, updates can be a double edged sword: as much as we strive for stability and backward compatibility, new crashes and breaking changes occasionally slip through. To solve these issues faster, today we're announcing WebView DevTools, a new set of on-device debugging tools to diagnose WebView-caused crashes and misbehaving web platform features.
For your convenience, WebView DevTools comes included as part of WebView itself. The easiest way to launch WebView Devtools is to try out WebView Beta. WebView's beta program is a way for app developers to get WebView several weeks before they reach users, for extra lead time to report compatibility bugs to our team. Starting with today's release (M83), WebView Beta includes a launcher icon for WebView DevTools. Just look for the blue and gray WebView gear icon to get started debugging WebView in your app.
Inspecting a crash in WebView DevTools.
No software is bug-free and loading web content can be challenging, so it's no surprise WebView crashes are a pain point for apps. Worse yet, these crashes are difficult to debug because WebView's Java and C++ stack traces are obfuscated (to minimize APK size for Android users). To help make these crashes more actionable, we're exposing first-class access to WebView's built-in crash reporter. Just open WebView DevTools, tap on "crashes," and you'll see a list of recent WebView-caused crashes from apps on your device. You can use this tool to see if the crash report has been uploaded to our servers, force-upload it if necessary, and subsequently file a bug. This ensures our team has all the information we need to swiftly resolve these crashes and ensure a smoother user experience in your app.
Using flags to highlight WebView usage in Android apps.
However, not all bugs cause crashes. A handful of past WebView releases have broken Android apps due to behavior changes caused by new features. While our team's policy is to roll back features which break compatibility, the chromium team launches several features for WebView in each release, and we often need time to identify the offending feature. WebView DevTools can help here too. Inspired by Google Chrome's chrome://flags tool, which enables compatibility testing with web platform features, we're offering app developers similar controls for experimental features. To get started, open WebView DevTools, tap on "flags," enable or disable any available features, then kill and restart the WebView-based app you're testing. Using WebView DevTools will help us work together to pin down the culprit so we can roll it back. We've also included flags for features slated for upcoming releases, so you can test compatibility even earlier by enabling these features on your test device.
