The latest Android and Google Play news for app and game developers.
Posted by Patricia Correa, Platforms & Ecosystems
Earlier this year we highlighted some of Google Play's milestones and commitments in supporting the 1M+ developers on the Play Store, as well as those of you working on Android apps and games and looking to launch and grow your business on our platforms. We have been inspired and humbled by the achievements of app and game developers, building experiences that delight and help people everywhere, as some stories highlighted in #IMakeApps.
We continue to focus on helping you grow thriving businesses and building tools and resources to help you reach and engage more users in more places, whilst ensuring a safe and secure ecosystem. Looking to 2019, we are excited about all the things to come and seeing more developers adopt new features and update to Android P.
In the meantime let's share some of the 2018 highlights on Google Play and Android:
Building for the future
Along with Android P we have continued to help the Android developer ecosystem, launching Android Jetpack, the latest Android Studio, and Kotlin support. Developers are also now able to add rich and dynamic UI templates with Slices in places such as Google Search and Assistant, APIs for new screens support, and much more. Discover the latest from Android 9, API Level 28.
Smaller apps have higher conversion rates and our research shows that a large app size is a key driver of uninstalls. At I/O we launched a new publishing format, the Android App Bundle, helping developers to deliver smaller and more efficient apps with a simplified release process, and with features on demand - saving on average 35% in download size! On devices using Android M and above, app bundles can reduce app size even further, by automatically supporting uncompressed native libraries, thereby eliminating duplication on devices.
You can build app bundles in the Android Studio 3.2 stable release and in Unity 2018.3 beta, and upload larger bundles with installed APK sizes of up to 500MB without using expansion files, through an early access feature soon to be available to all developers.
Richer experiences and discovery
Discovery of your apps and games is important, so we launched Google Play Instant and increased the size limit to 10MB to enable TRY NOW on the Play Store, and removed the URL requirement for Instant apps. Android Studio 3.3 beta release, lets you publish a single app bundle and classify it or a particular module to be instant enabled (without maintaining separate code).
For game developers, Unity introduced the Google Play Instant plug-in and instant app support is built into the new Cocos Creator. Our app pre-registration program, has seen nearly 250 million app pre-registrations, helping drive app downloads through richer discovery.
Optimizing for quality and performance
Android vitals are now more actionable, with a dashboard highlighting core vitals, peer benchmarks, start-up time and permission denials vitals, anomaly detection and alerts, and linking pre-launch reports - all so that you can better optimize and prioritize issues for improved quality and performance.
There are more opportunities to get feedback and fix issues before launch. The Google Play Console expanded the functionality of automated device testing with a pre-launch report for games, and the launch of the internal and closed test tracks lets you push your app to up to 100 internal testers, before releasing them to production.
Insights for your business, now and in the long term
Metrics are critical to optimize your business and we've added new customizable tools in the Play Console, with downloadable reports to help you evaluate core metrics. Including cumulative data, 30-day rolling averages, and roll-ups for different time periods to better match the cadence of your business.
You can now configure the statistics report to show how your instant apps are performing, analyze different dimensions and identify how many install the final app on their device. The acquisition report shows users discovery journey through to conversion - with average revenue per user and retention benchmarks against similar apps. You can also find the best performing search terms for your store listing with organic breakdown - helping to optimize efforts to grow and retain a valuable audience.
Increasingly developers are adopting subscriptions as their core monetization model. The dedicated new subscriptions center means you can easily change subscription prices, offer partial refunds for in-app products and subscriptions, and also make plan changes in Play Billing Library version 1.2. Learn how to keep subscribers engaged; users can pause plans, giving you more control with order management and the cancellation survey.
Discover how to use all the new features and best practices on the Academy for App Success, our interactive free e-learning platform, offering bite-sized courses that help you make the most of Play Console and improve your app quality.
Make sure you follow @googleplaydev and sign up to our newsletter to stay ahead of all our updates in 2019! We hope these features and tools will enable us to continue a successful partnership with you in the New Year - follow our countdown for a daily highlight. From all of us at Google Play - happy holidays.
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Posted by Fei Ye, Software Engineer and Kazushi Nagayama, Ninja Spamologist
Google Play ratings and reviews are extremely important in helping users decide which apps to install. Unfortunately, fake and misleading reviews can undermine users' trust in those ratings. User trust is a top priority for us at Google Play, and we are continuously working to make sure that the ratings and reviews shown in our store are not being manipulated.
There are various ways in which ratings and reviews may violate our developer guidelines:
When we see these, we take action on the app itself, as well as the review or rating in question.
In 2018, the Google Play Trust & Safety teams deployed a system that combines human intelligence with machine learning to detect and enforce policy violations in ratings and reviews. A team of engineers and analysts closely monitor and study suspicious activities in Play's ratings and reviews, and improve the model's precision and recall on a regular basis. We also regularly ask skilled reviewers to check the decisions made by our models for quality assurance.
It's a big job. To give you a sense of the volume we manage, here are some numbers from a recent week:
Our team can do a lot, but we need your help to keep Google Play a safe and trusted place for apps and games.
If you're a developer, you can help us by doing the following:
Example of a violation: incentivized ratings is not allowed
If you're a user, you can follow these simple guidelines as well:
Finally, if you find bad ratings and reviews on Google Play, help us improve by sending your feedback! Users can mark the review as "Spam" and developers can submit feedback through the Play Console.
Tooltip to flag the review as Spam.
Thanks for helping us keep Google Play a safe and trusted place to discover some of the world's best apps and games.
★ ★ ★ ★ ★
Posted by Jeff Bailey, AOSP Team
AOSP has been around for more than 10 years and visibility into the project has often been restricted to the Android Team and Partners. A lot of that has been rooted in business needs: we want to have fun things to show off at launches and the code wasn't factored in a way that let us do more in the open.
At the Android Developer Summit last month, we demoed GSI running on a number of partner devices, enabled through Project Treble. The work done to make that happen has provided the separation needed, and has also made it easier to work with our partners to upstream fixes for Android into AOSP. As a result of this, more than 40% of the commits to our git repository came in through our open source tree in Q3 of this year.
In order to support the developers working directly in AOSP and our partners upstreaming changes, we have enabled more than 8000 tests in presubmit -- tests that are run before the code is checked in -- and are working to add other continuous testing like the Compatibility Test Suite which ensures that our AOSP trees are in a continuously releasable state. Today we are excited to open this up for you through https://ci.android.com/.
On this dashboard, across the top are the targets that we are building, down the left are the revisions. As we add more targets (such as GSI), they will appear here. Each square in the table provides access to the build artifacts. An anchor on the left provides a permanent URL for that revision. Find out more at https://source.android.com/setup/build/dashboard.
Our DroidCop team (similar to Chromium's Tree Sherrifs) watches this dashboard and works with developers to ensure the health of the tree. This is just the start for us and we are building on this tool to add more in the coming months.
I'd like to thank the Android Engineering Productivity Team for embracing this and I'm excited for us to take this step! I'd love to hear how you use this. Contact me at @jeffbaileyaosp on Twitter, jeffbailey+aosp@google.com, or tag /u/jeffbailey in a post to reddit.com/r/androiddev.
This blogpost is a collaboration between Google and Twitter. Authored by Jingwei Hao with support from César Puerta, Fred Lohner from Twitter, and developed with Jingyu Shi from Google.
Push notifications are an important way to keep Twitter users informed about what's happening. However, they can be a significant and often overlooked source of battery drain. For example: high priority notifications can wake a phone from Doze, and fetching data upon push notification delivery via the network can drain the battery quickly.
As app developers at Twitter, we know that battery life is an important aspect of the mobile experience for our users. Over time we've taken several steps to optimize our app to work with the power saving features, particularly around push notifications. In this article, we'll share what we did to save battery life on our users' devices in the hope this will help other developers optimize their apps as well.
Earlier this year, we upgraded our notifications messaging library to the next evolution of GCM: Firebase Cloud Messaging (FCM). This gave us the ability to use the latest APIs and get access to the additional features Firebase has to offer.
This was a very unique migration for us for multiple reasons:
We mitigated the risks by thoroughly testing across dogfood, alpha, and beta users for both migration and rollback paths, with real time metrics monitoring, and a staged app roll out. During the migration, we were pleased to find that replacing GCM with FCM worked smoothly in all our use cases.
Migrating to FCM proved valuable to us when testing against the power saving features on Android. With APIs like: getPriority() and getOriginalPriority(), FCM gave us insight into if the priority of FCM messages are downgraded.
On the backend at Twitter, we always try to make sure that notifications are assigned with the appropriate priority, making sure that high priority FCM messages are only used to generate a user visible notification. In fact, a very small fraction of notifications we send are classified as high priority.
App Standby Buckets was introduced in Android 9 Pie, this feature impose restrictions on the number of high priority messages the app will receive based on which bucket the app belongs to. As a result, high priority messages should be reserved for the notifications users are more likely to interact with. Using high priority FCM messages for actions which do not involve user interactions can lead to negative consequences, for example: once an app exhausts its app standby bucket quota, the following genuinely urgent FCM messages will be downgraded to normal priority and delayed when device is in Doze.
To understand how our app performs with App Standby Buckets, we gathered statistics on the notification priorities at both send and delivery time for the Twitter App:
This was very encouraging to see, as it means all users would receive the important notifications without any delay, and this is true no matter the app is considered active or not by the Android system. This also confirms that we are correctly categorizing high priority FCM messages based on our users usage engagement patterns.
Prefetching data is a popular practice to enrich the user experience around notifications. This entails including a piece of metadata within the payload of a notification. When the notification is delivered, the app leverages the payload data to start one or multiple network calls to download more data before the rendering of the notification. FCM payload has a 4KB max limit, and when more data is needed to create rich notifications, this prefetch practice is used. But doing this has a trade-off, and will increase both device power consumption and notification latency. At Twitter, among all the types of notifications we push to our users, there's only one type which does prefetching which makes up to less than 1% of the volume. In addition, in the cases where data prefetching for notification is unavoidable, it should be scheduled with JobScheduler or WorkManager tasks in order to avoid issues with the background execution limits in Oreo+.
In addition, Notification Channels were introduced in the Android 8 Oreo release. We designed the importance level of the channels with multiple factors in mind, user experience being the most important and power-saving being another. Currently, Twitter for Android has nine notification channels, among which only direct messaging, emergency, and security are designed as high importance, leaving most of the channels with a lower importance level, making it less intrusive.
We set out to improve our user experience by migrating to FCM, prioritizing notifications cautiously, limiting prefetching, and carefully designing notification channels. We were glad to find that these changes had a positive impact on battery performance and enabled our app to take advantage of the power-saving features introduced in recent versions of Android.
Designing for power optimization in a large evolving application is a complex and ongoing process, particularly as the Android platform grows and provides more granular controls. At Twitter we strongly believe in continuous refinement to improve application performance and resource consumption. We hope this discussion is useful in your own quest to optimize your app's performance and use of resources 💙
Posted by Lilian Young and Shawn Willden, Android Security; and Frank Salim, Google Pay
The Android Keystore provides application developers with a set of cryptographic tools that are designed to secure their users' data. Keystore moves the cryptographic primitives available in software libraries out of the Android OS and into secure hardware. Keys are protected and used only within the secure hardware to protect application secrets from various forms of attacks. Keystore gives applications the ability to specify restrictions on how and when the keys can be used.
Android Pie introduces new capabilities to Keystore. We will be discussing two of these new capabilities in this post. The first enables restrictions on key use so as to protect sensitive information. The second facilitates secure key use while protecting key material from the application or operating system.
There are times when a mobile application receives data but doesn't need to immediately access it if the user is not currently using the device. Sensitive information sent to an application while the device screen is locked must remain secure until the user wants access to it. Android Pie addresses this by introducing keyguard-bound cryptographic keys. When the screen is locked, these keys can be used in encryption or verification operations, but are unavailable for decryption or signing. If the device is currently locked with a PIN, pattern, or password, any attempt to use these keys will result in an invalid operation. Keyguard-bound keys protect the user's data while the device is locked, and only available when the user needs it.
Keyguard binding and authentication binding both function in similar ways, except with one important difference. Keyguard binding ties the availability of keys directly to the screen lock state while authentication binding uses a constant timeout. With keyguard binding, the keys become unavailable as soon as the device is locked and are only made available again when the user unlocks the device.
It is worth noting that keyguard binding is enforced by the operating system, not the secure hardware. This is because the secure hardware has no way to know when the screen is locked. Hardware-enforced Android Keystore protection features like authentication binding, can be combined with keyguard binding for a higher level of security. Furthermore, since keyguard binding is an operating system feature, it's available to any device running Android Pie.
Keys for any algorithm supported by the device can be keyguard-bound. To generate or import a key as keyguard-bound, call setUnlockedDeviceRequired(true) on the KeyGenParameterSpec or KeyProtection builder object at key generation or import.
Secure Key Import is a new feature in Android Pie that allows applications to provision existing keys into Keystore in a more secure manner. The origin of the key, a remote server that could be sitting in an on-premise data center or in the cloud, encrypts the secure key using a public wrapping key from the user's device. The encrypted key in the SecureKeyWrapper format, which also contains a description of the ways the imported key is allowed to be used, can only be decrypted in the Keystore hardware belonging to the specific device that generated the wrapping key. Keys are encrypted in transit and remain opaque to the application and operating system, meaning they're only available inside the secure hardware into which they are imported.
Secure Key Import is useful in scenarios where an application intends to share a secret key with an Android device, but wants to prevent the key from being intercepted or from leaving the device. Google Pay uses Secure Key Import to provision some keys on Pixel 3 phones, to prevent the keys from being intercepted or extracted from memory. There are also a variety of enterprise use cases such as S/MIME encryption keys being recovered from a Certificate Authorities escrow so that the same key can be used to decrypt emails on multiple devices.
To take advantage of this feature, please review this training article. Please note that Secure Key Import is a secure hardware feature, and is therefore only available on select Android Pie devices. To find out if the device supports it, applications can generate a KeyPair with PURPOSE_WRAP_KEY.
Posted by Keith Smyth
This is the fourth in a series of blog posts in which outline strategies and guidance in Android with regard to power.
Android is a mobile operating system designed to work with constrained memory and battery. For this reason, a typical Android application can have its process killed by the system to recover memory. The process being killed is chosen based on a ranking system of how important that process is to the user at the time. Here, in descending order, is the ranking of each class of process. The higher the rank, the less likely that process is to be killed.
There is nothing wrong with becoming a cached app: Sharing the user's device is part of the lifecycle that every app developer must accept to keep a happy ecosystem. On a device with a dead battery, 100% of the apps go unused. And an app blamed for killing the battery could even be uninstalled.
However, there are valid scenarios to promote your app to the foreground: The prerequisites for using a foreground service are that your app is executing a task that is immediate, important (must complete), is perceptible to the user (most often because it was started by the user), and must have a well defined start and finish. If a task in your app meets these criteria, then it can be promoted to the foreground until the task is complete.
There are some guidelines around creating and managing foreground services. For all API levels, a persistent notification with at least PRIORITY_LOW must be shown while the service is created. When targeting API 26+ you will also need to set the notification channel to at least IMPORTANCE_LOW. The notification must have a way for the user to cancel the work, this cancellation can be tied to the action itself: for example, stopping a music track can also stop the music-playback service. Last, the title and description of the foreground service notification must show an accurate description of what the foreground service is doing.
To read more about foreground services, including several important updates in recent releases, see Running a service in the foreground
Some good example usages of foreground services are playing music, completing a purchase transaction, high-accuracy location tracking for exercise, and logging sensor data for sleep. The user will initiate all of these activities, they must happen immediately, have an explicit beginning and end, and all can be cancelled by the user at any time.
Another good use case for a foreground service is to ensure that critical, immediate tasks (e.g. saving a photo, sending a message, processing a purchase) are completed if the user switches away from the application and starts a new one. If the device is under high memory pressure it could kill the previous app while it is still processing causing data loss or unexpected behavior. An elegantly written app will detect being backgrounded and respond by promoting its short, critical task to the foreground to complete.
If you feel you need your foreground service to stay alive permanently, then this is an indicator that a foreground service is not the right answer. Many alternatives exist to both meet the requirements of your use case, and be the most efficient with power.
Passive location tracking is a bad use case for foreground services. If the user has consented to being tracked, use the FusedLocationProvider API to receive bundled location updates at longer intervals, or use the geofencing API to be efficiently notified when a user enters or leaves a specified area. Read more about how to optimize location for battery.
If you wish to pair with a Bluetooth companion device, use CompanionDeviceManager. For reconnecting to the device, BluetoothLeScanner has a startScan method that takes a PendingIntent that will fire when a narrow filter is met.
If your app has work that must be done, but does not have to happen immediately: WorkManager or JobScheduler will schedule the work for the best time for the entire system. If the work must be started immediately, but then can stop if the user stops using the app, we recommend ThreadPools or Kotlin Coroutines.
DownloadManager facilitates handling long running downloads in the background. It will even handle retries over poor connections and system reboots for you.
If you believe you have a use case that isn't handled let us know!
Used correctly, the foreground service is a great way to tell Android that your app is doing something important to the user. Making the right decision on which tool to use remains the best way to provide a premium experience on Android for all users. Use the community and Google to help with these important decisions, and always respect the user first.
Posted by Sam Spencer, Technical Program Manager, Google Play
The Android Ice Cream Sandwich (ICS) platform is seven years old and the active device count has been below 1% for some time. Consequently, we are deprecating support for ICS in future releases of Google Play services. For devices running ICS, the Google Play Store will no longer update Play Services APK beyond version 14.7.99.
What does this mean as an Application developer:
The Google Play services SDK contains the interfaces to the functionality provided by the Google Play services APK, running as background services. The functionality required by the current, released SDK versions is already present on ICS devices with Google Play services and will continue to work without change.
With the SDK version changes earlier this year, each library can be independently released and may update its own minSdkVersion. Individual libraries are not required to change based on this deprecation. Newer SDK components may continue to support API levels 14 and 15 but many will update to require the higher API level. For applications that support API level 16 or greater, you will not need to make any changes to your build. For applications that support API levels 14 or 15, you may continue to build and publish your app to devices running ICS, but you will encounter build errors when updating to newer SDK versions. The error will look like this:
Error:Execution failed for task ':app:processDebugManifest'. > Manifest merger failed : uses-sdk:minSdkVersion 14 cannot be smaller than version 16 declared in library [com.google.android.gms:play-services-FOO:16.X.YY] Suggestion: use tools:overrideLibrary="com.google.android.gms:play_services" to force usage
Unfortunately, the stated suggestion will not help you successfully run your app on older devices. In order to use the newer SDK, you will need to use one of the following options:
1. Target API level 16 as the minimum supported API level.
This is the recommended course of action. To discontinue support for API levels that will no longer receive Google Play services updates, simply increase the minSdkVersion value in your app's build.gradle to at least 16. If you update your app in this way and publish it to the Play Store, users of devices with less than that level of support will not be able to see or download the update. However, they will still be able to download and use the most recently published version of the app that does target their device.
A very small percentage of all Android devices are using API levels less than 16. You can read more about the current distribution of Android devices. We believe that many of these old devices are not actively being used.
If your app still has a significant number of users on older devices, you can use multiple APK support in Google Play to deliver an APK that uses Google Play services 14.7.99. This is described below.
2. Build multiple APKs to support devices with an API level less than 16.
Along with some configuration and code management, you can build multiple APKs that support different minimum API levels, with different versions of Google Play services. You can accomplish this with build variants in Gradle. First, define build flavors for legacy and newer versions of your app. For example, in your build.gradle, define two different product flavors, with two different compile dependencies for the stand-in example play-services-FOO component:
productFlavors { legacy { minSdkVersion 14 versionCode 1401 // Min API level 14, v01 } current { minSdkVersion 16 versionCode 1601 // Min API level 16, v01 } } dependencies { legacyCompile 'com.google.android.gms:play-services-FOO:16.0.0' currentCompile 'com.google.android.gms:play-services-FOO:17.0.0' }
In the above situation, there are two product flavors being built against two different versions of play-services-FOO. This will work fine if only APIs are called that are available in the 16.0.0 library. If you need to call newer APIs made available with 17.0.0, you will have to create your own compatibility library for the newer API calls so that they are only built into the version of the application that can use them:
After building a release APK for each flavor, you then publish them both to the Play Store, and the device will update with the most appropriate version for that device. Read more about multiple APK support in the Play Store.
Play Console
