The latest Android and Google Play news for app and game developers.
Google Play Instant enables people to experience your game or app natively without having to go through a full installation process. Removing the friction of installing is a great way to increase engagement, conversions, and lifetime value of your users.
Today, we've made it easier to build instant games and apps by removing the URL requirement. Previously, in order to publish an instant game you had to create a web destination for it. The website also had to be connected to the instant game through intent filters and digital asset links verification.
Now, it is no longer required to add URL-based intent filters to your instant game. People will be able to access the instant experience through a 'Try Now' button in the Play Store or Play Games apps, via deep link API, and in the future through the app ads.
While being particularly helpful for games which often don't have a corresponding website, the new URL-less functionality is available to both game and app developers.
Game developers using Unity or the latest Cocos Creator can take advantage of URL-less instant games by simply leaving the URL fields blank in the setup process.
However, if you have your own game engine or have built your game from scratch in C++, check the AndroidManifest to make sure it has the following intent filter declaration:
<intent-filter> <action android:name="android.intent.action.MAIN" /> <category android:name="android.intent.category.LAUNCHER" /> </intent-filter>
Starting with Android Studio 3.2, you can create a new instant game, or convert your existing game, without associating a URL with it. In fact, this is now the default behavior. Here is a run through the process:
You should see an instant game on your attached device. Instant runtime found and launched the entry point activity in your game with the ACTION_MAIN and CATEGORY_LAUNCHER intent filter.
Once you are ready to publish the sample instant game:
Once you publish your instant game, people can access it via a 'Try Now' button in Play Store within 24 hours or sooner. You can also send traffic to your instant game using the deep link API:
market://details?id=MY.PACKAGE.NAME&launch=true&referrer=myreferrer
MY.PACKAGE.NAME refers to applicationId that you have replaced in app/build.gradle file.
MY.PACKAGE.NAME
With the launch of Android App Bundle we are excited to further simplify the developer experience for Google Play Instant. In the coming months we are making it possible to deliver your app's or game's dynamic features instantly from the same bundle as your installable app or game. Stay tuned!
Check out more information on Google Play Instant, or feel free to ask a question on Stack Overflow, or report an issue to our public tracker.
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Posted by Benjamin Baxter, Developer Advocate and Bacon Connoisseur
All TVs have the same problem with keyboard input: It is very cumbersome to hunt and peck for each letter using a D-pad with a remote. And if you make a mistake, trying to correct it compounds the problem.
APIs like Smart Lock and Autofill, can ease user's frustrations, but for certain types of input, like login, you need to collect complex input that is difficult for users using the on-screen keyboard.
With the Nearby Connections API, you can use a second screen to gather input from the user with less friction.
From the documentation:
"Nearby Connections is an offline peer-to-peer socket model for communication based on advertising and discovering devices in proximity.
Usage of the API falls into two phases: pre-connection, and post-connection.
In the pre-connection phase, Advertisers advertise themselves, while Discoverers discover nearby Advertisers and send connection requests. A connection request from a Discoverer to an Advertiser initiates a symmetric authentication flow that results in both sides independently accepting (or rejecting) the connection request.
After a connection request is accepted by both sides, the connection is established and the devices enter the post-connection phase, during which both sides can exchange data."
In most cases the TV is the advertiser and the phone is the discoverer. In the example below, the assumed second device is a phone. The API and patterns described in this article are not limited to a phone. For example, a tablet could also be the second screen device.
There are many times when keyboard input is required. Authenticating users and collecting billing information (like zip codes and name on card) are common cases. This example handles a login flow that uses a second screen to see how Nearby Connections can help reduce friction.
1. The user opens your app on her TV and needs to login. You can show a screen of options similar to the setup flow for a new TV.
2. After the user chooses to login with their phone, the TV should start advertising and send the user to the associated login app on their phone, which should start discovering.
There are a variety of solutions to open the app on the phone. As an example, Android TV's setup flow has the user open the corresponding app on their mobile device. Initiating the hand-off is a more a UX concern than a technology concern.
3. The phone app should display the advertising TV and prompt the user to initiate the connection. After the (encrypted -- see Security Considerations below for more on this) connection is established the TV can stop advertising and the phone can stop discovering.
"Advertising/Discovery using Nearby Connections for hours on end can affect a device's battery. While this is not usually an issue for a plugged-in TV, it can be for mobile devices, so be conscious about stopping advertising and discovery once they're no longer needed."
4. Next, the phone can start collecting the user's input. Once the user enters their login information, the phone should send it to the TV in a BYTES payload over the secure connection.
5. When the TV receives the message it should send an ACK (using a BYTES payload) back to the phone to confirm delivery.
6. When the phone receives the ACK, it can safely close the connection.
The following diagram summarizes the sequence of events:
Nearby Connections needs location permissions to be able to discover nearby devices. Be transparent with your users. Tell them why they need to grant the location permission on their phone.
Since the TV is advertising, it does not need location permissions.
After the user chooses to login on the phone, the TV should start advertising. This is a very simple process with the Nearby API.
override fun onGuidedActionClicked(action: GuidedAction?) { super.onGuidedActionClicked(action) if( action == loginAction ) { // Update the UI so the user knows to check their phone navigationFlowCallback.navigateToConnectionDialog() doStartAdvertising(requireContext()) { payload -> handlePayload(payload) } } }
When the user clicks a button, update the UI to tell them to look at their phone to continue. Be sure to offer a way to cancel the remote login and try manually with the cumbersome onscreen keyboard.
This example uses a GuidedStepFragment but the same UX pattern applies to whatever design you choose.
Advertising is straightforward. You need to supply a name, a service id (typically the package name), and a `ConnectionLifeCycleCallback`.
You also need to choose a strategy that both the TV and the phone use. Since it is possible that the users has multiple TVs (living room, bedroom, etc) the best strategy to use is P2P_CLUSTER.
Then start advertising. The onSuccessListener and onFailureListener tell you whether or not the device was able to start advertising, they do not indicate a device has been discovered.
fun doStartAdvertising(context: Context) { Nearby.getConnectionsClient(context).startAdvertising( context.getString(R.string.tv_name), context.packageName, connectionLifecycleCallback, AdvertisingOptions.Builder().setStrategy(Strategy.P2P_CLUSTER).build() ) .addOnSuccessListener { Log.d(LoginStepFragment.TAG, "We are advertising!") } .addOnFailureListener { Log.d(LoginStepFragment.TAG, "We cannot start advertising.") Toast.makeText( context, "We cannot start advertising.", Toast.LENGTH_LONG) .show() } }
The real magic happens in the `connectionLifecycleCallback` that is triggered when devices start to initiate a connection. The TV should accept the handshake from the phone (after performing the necessary authentication -- see Security Considerations below for more) and supply a payload listener.
val connectionLifecycleCallback = object : ConnectionLifecycleCallback() { override fun onConnectionInitiated( endpointId: String, connectionInfo: ConnectionInfo ) { Log.d(TAG, "Connection initialized to endpoint: $endpointId") // Make sure to authenticate using `connectionInfo.authenticationToken` // before accepting Nearby.getConnectionsClient(context) .acceptConnection(endpointId, payloadCallback) } override fun onConnectionResult( endpointId: String, connectionResolution: ConnectionResolution ) { Log.d(TAG, "Received result from connection: ${connectionResolution.status.statusCode}") doStopAdvertising() when (connectionResolution.status.statusCode) { ConnectionsStatusCodes.STATUS_OK -> { Log.d(TAG, "Connected to endpoint: $endpointId") otherDeviceEndpointId = endpointId } else -> { otherDeviceEndpointId = null } } } override fun onDisconnected(endpointId: String) { Log.d(TAG, "Disconnected from endpoint: $endpointId") otherDeviceEndpointId = null } }
The payloadCallback listens for the phone to send the login information needed. After receiving the login information, the connection is no longer needed. We go into more detail later in the Ending the Conversation section.
Nearby Connections does not require the user's consent. However, the location permission must be granted in order for discovery with Nearby Connections to work its magic. (It uses BLE scanning under the covers.) After opening the app on the phone, start by prompting the user for location permission if not already granted on devices running Marshmallow and higher.
Once the permission is granted, start discovering, confirm the connection, collect the credentials, and send a message to the TV app.
Discovering is as simple as advertising. You need a service id (typically the package name -- this should be the same on the Discoverer and Advertiser for them to see each other), a name, and a `EndpointDiscoveryCallback`. Similar to the TV code, the flow is triggered by callbacks based on the connection status.
Nearby.getConnectionsClient(context).startDiscovery( context.packageName, mobileEndpointDiscoveryCallback, DiscoveryOptions.Builder().setStrategy(Strategy.P2P_CLUSTER).build() ) .addOnSuccessListener { // We're discovering! Log.d(TAG, "We are discovering!") } .addOnFailureListener { // We were unable to start discovering. Log.d(TAG, "We cannot start discovering!") }
The Discoverer's listeners are similar to the Advertiser's success and failure listeners; they signal if the request to start discovery was successful or not.
Once you discover an advertiser, the `EndpointDiscoveryCallback` is triggered. You need to keep track of the other endpoint to know who to send the payload, e.g.: the user's credentials, to later.
val mobileEndpointDiscoveryCallback = object : EndpointDiscoveryCallback() { override fun onEndpointFound( endpointId: String, discoveredEndpointInfo: DiscoveredEndpointInfo ) { // An endpoint was found! Log.d(TAG, "An endpoint was found, ${discoveredEndpointInfo.endpointName}") Nearby.getConnectionsClient(context) .requestConnection( context.getString(R.string.phone_name), endpointId, connectionLifecycleCallback) } override fun onEndpointLost(endpointId: String) { // A previously discovered endpoint has gone away. Log.d(TAG, "An endpoint was lost, $endpointId") } }
One of the devices must initiate the connection. Since the Discoverer has a callback for endpoint discovery, it makes sense for the phone to request the connection to the TV.
The phone asks for a connection supplying a `connectionLifecycleCallback` which is symmetric to the callback in the TV code.
val connectionLifecycleCallback = object : ConnectionLifecycleCallback() { override fun onConnectionInitiated( endpointId: String, connectionInfo: ConnectionInfo ) { Log.d(TAG, "Connection initialized to endpoint: $endpointId") // Make sure to authenticate using `connectionInfo.authenticationToken` before accepting Nearby.getConnectionsClient(context) .acceptConnection(endpointId, payloadCallback) } override fun onConnectionResult( endpointId: String, connectionResolution: ConnectionResolution ) { Log.d(TAG, "Connection result from endpoint: $endpointId") when (connectionResolution.status.statusCode) { ConnectionsStatusCodes.STATUS_OK -> { Log.d(TAG, "Connected to endpoint: $endpointId") otherDeviceEndpointId = endpointId waitingIndicator.visibility = View.GONE emailInput.editText?.isEnabled = true passwordInput.editText?.isEnabled = true Nearby.getConnectionsClient(this).stopDiscovery() } else -> { otherDeviceEndpointId = null } } } override fun onDisconnected(endpointId: String) { Log.d(TAG, "Disconnected from endpoint: $endpointId") otherDeviceEndpointId = null } }
Once the connection is established, stop discovery to avoid keeping this battery-intensive operation running longer than needed. The example stops discovery after the connection is established, but it is possible for a user to leave the activity before that happens. Be sure to stop the discovery/advertising in onStop() on both the TV and phone.
override fun onStop() { super.onStop() Nearby.getConnectionsClient(this).stopDiscovery() }
Just like a TV app, when you accept the connection you supply a payload callback. The callback listens for messages from the TV app such as the ACK described above to clean up the connection.
After the devices are connected, the user can use the keyboard and send their authentication information to the TV by calling `sendPayload()`.
fun sendCreditials() { val email = emailInput.editText?.text.toString() val password = passwordInput.editText?.text.toString() val creds = "$email:$password" val payload = Payload.fromBytes(creds.toByteArray()) Log.d(TAG, "sending payload: $creds") if (otherDeviceEndpointId != null) { Nearby.getConnectionsClient(this) .sendPayload(otherDeviceEndpointId, payload) } }
After the phone sends the payload to the TV (and the login is successful), there is no reason for the devices to remain connected. The TV can initiate the disconnection with a simple shutdown protocol.
The TV should send an ACK to the phone after it receives the credential payload.
val payloadCallback = object : PayloadCallback() { override fun onPayloadReceived(endpointId: String, payload: Payload) { if (payload.type == Payload.Type.BYTES) { payload.asBytes()?.let { val body = String(it) Log.d(TAG, "A payload was received: $body") // Validate that this payload contains the login credentials, and process them. val ack = Payload.fromBytes(ACK_PAYLOAD.toByteArray()) Nearby.getConnectionsClient(context).sendPayload(endpointId, ack) } } } override fun onPayloadTransferUpdate( endpointId: String, update: PayloadTransferUpdate ) { } }
The phone should have a `PayloadCallback` that initiates a disconnection in response to the ACK. This is also a good time to reset the UI to show an authenticated state.
private val payloadCallback = object : PayloadCallback() { override fun onPayloadReceived(endpointId: String, payload: Payload) { if (payload.type == Payload.Type.BYTES) { payload.asBytes()?.let { val body = String(it) Log.d(TAG, "A payload was received: $body") if (body == ACK_PAYLOAD) { waitingIndicator.visibility = View.VISIBLE waitingIndicator.text = getString(R.string.login_successful) emailInput.editText?.isEnabled = false passwordInput.editText?.isEnabled = false loginButton.isEnabled = false Nearby.getConnectionsClient(this@MainActivity) .disconnectFromEndpoint(endpointId) } } } } override fun onPayloadTransferUpdate( endpointId: String, update: PayloadTransferUpdate ) { } }
For security (especially since we're sending over sensitive information like login credentials), it's strongly recommended that you authenticate the connection by showing a code and having the user confirm that the two devices being connected are the intended ones -- without this, the connection established by Nearby Connection is encrypted but not authenticated, and that's susceptible to Man-In-The-Middle attacks. The documentation goes into greater detail on how to authenticate a connection.
There are many times when a user needs to supply input to a TV app. The Nearby API provides a way to offload the hardships of an onscreen-dpad-driven keyboard to an easy and familiar phone keyboard.
What use cases do you have where a second screen would simplify your user's life? Leave a comment or send me (@benjamintravels) or Varun (@varunkapoor, Team Lead for Nearby Connections) a tweet to continue the discussion.
Posted by Seang Chau, Vice President, Engineering
According to the World Health Organization1, around 466 million people worldwide have disabling hearing loss. This number is expected to increase to 900 million people by the year 2050. Google is working with GN Hearing to create a new open specification for hearing aid streaming support on future versions of Android. Users with hearing loss will be able to connect, pair, and monitor their hearing aids so they can hear their phones loudly and clearly.
Hearing aid users expect a high quality, low latency experience with minimal impact on phone and hearing aid battery life. We've published a new hearing aid spec for Android smartphones: Audio Streaming for Hearing Aids (ASHA) on Bluetooth Low Energy Connection-Oriented Channels. ASHA is designed to have a minimal impact on battery life with low-latency while maintaining a high quality audio experience for users who rely on hearing aids. We look forward to continually evolving the spec to even better meet the needs of our users.
The spec details the pairing and connectivity, network topology, system architecture, and system requirements for implementing hearing aids using low energy connection-oriented channels. Any hearing aid manufacturer can now build native hearing aid support for Android.
The protocol specification is available here.
Posted by Hoi Lam, Lead Developer Advocate, Wear OS by Google
Today we are announcing a new initiative to improve Wear app quality and their presentation in the Google Play Store. The Wear app review process, which has been in place since the launch of Android Wear 2.0, is currently optional. It will become mandatory for apps to be listed on the Wear OS by Google version of the Google Play Store from the following dates:
The review process for mobile apps remains unchanged, and is independent of the Wear app review. Mobile app updates will not be blocked if they fail the Wear app review.
We hope this lightweight app review process will improve the quality of Wear app experiences across the wide range of devices available to your users. In addition, since screenshots are required for the Wear app review, this will improve the discovery and presentation of your Wear apps in the Google Play Store.
See a comprehensive list of review criteria here. The following are common issues we see during Wear app reviews:
We understand that some developers need to experiment with their Wear apps in the early stages of app development, and a Wear app review at this stage might not be appropriate. In this case, developers have two options:
Please note that the open test and closed test channels will be subject to Wear app review to help front-load the quality assurance process and to avoid leaving reviews to the last minute.
Thank you for your continuing support of Wear OS by Google.
Posted by Shailen Tuli, DPE
Today we're releasing the source code for the official Google I/O 2018 for Android app.
The 2018 version constitutes a comprehensive rewrite of the app. For many years, the app has used a ContentProvider + SyncAdapter architecture. This year, we rewrote the app using Architecture Components and brought the code in sync with the Android team's current recommendations for building modern apps.
We followed the recommendations laid out in the Guide to App Architecture for writing modular, testable and maintainable code when deciding on the architecture for the app. We kept logic away from Activities and Fragments and moved it to ViewModels. We observed data using LiveData and used the Data Binding Library to bind UI components in layouts to the app's data sources.
The overall architecture of the app can be summarized in this diagram:
We used a Repository layer for handling data operations. IOSched's data comes from a few different sources — user data is stored in Cloud Firestore (either remotely or in a local cache for offline use), user preferences and settings are stored in SharedPreferences, conference data is stored remotely and is fetched and stored in memory for the app to use — and the repository modules are responsible for handling all data operations and abstracting the data sources from the rest of the app. If we ever wanted to swap out the Firestore backend for a different data source in the future, our architecture allows us to do so in a clean way.
We implemented a lightweight domain layer, which sits between the data layer and the presentation layer, and handles discrete pieces of business logic off the UI thread. Examples.
We used Dagger2 for dependency injection and we heavily relied on dagger-android to abstract away boilerplate code.
We used Espresso for basic instrumentation tests and JUnit and Mockito for unit testing.
The use of Firebase technologies has grown in the app as the Firebase platform has matured. The 2018 version uses the following Firebase components:
We made an early decision to rewrite the app from scratch to bring it in line with modern Android architecture. Using Kotlin for the rewrite was an easy choice: we loved Kotlin's expressive, concise, and powerful syntax; we found that Kotlin's support for safety features including nullability and immutability made our code more resilient; and we leveraged the enhanced functionality provided by Android Ktx extensions.
At I/O 2018, the Material Design team announced Material Theming, giving apps much greater ability to customize Material Design to bring more of their product's brand. As we launched the app before Material Theming, we couldn't use all of the new components but we managed to sneak a couple in like the new Bottom App Bar with inset Floating Action Button and we were able to incorporate a lot of the conference's branding elements.
The rewrite of the app brings the code in sync with Android's opinionated recommendations about building apps, and it resulted in a cleaner, more maintainable codebase. We'll continue working on the app, incorporating JetPack components as they become available and finding opportunities to showcase platform features that are good fits for the app. Developers can follow changes to the code on GitHub.
Posted by Purnima Kochikar, Director, Google Play, Apps & Games
On Monday we released Android 9 Pie. As we continue to push the Android platform forward, we're always looking to provide new ways to distribute your apps efficiently, help people discover and engage with your work, and improve the overall security of our ecosystem. Google Play has had a busy year so far with some big milestones around helping you reach more users, including:
Google Play is dedicated to helping you build and grow quality app businesses, reach the more than 2 billion Android devices globally and provide your users with better experiences. Here are some of the important areas we're prioritizing this year:
We've added more testing tools to the popular Play Console to help developers de-risk app launches with internal and external test tracks and staged rollouts to get valuable early feedback. This year we've expanded the Start on Android program globally that provides developers new to Android additional guidance to optimize their apps before launch. Google Play Instant remains a huge bet to transform app discovery and improve conversions by letting users engage without the friction of installing. We're seeing great results from early adopters and are working on new places to surface instant experience, including ads, and making them easier to build throughout the year.
Google Play plays an important role helping developers understand and fix quality and performance issues. At I/O, we showcased how we expanded the battery, stability and rendering of Android vitals reporting to include app start time & permission denials, enabling developers to cut application not responding errors by up to 95%. We also expanded the functionality of automated device testing with the pre-launch report to enable games testing. Recently, we increased the importance of app quality in our search and discovery recommendations that has resulted in higher engagement and satisfaction with downloaded games.
Over the last year we've rolled out more editorial content and improved our machine learning to deliver personalized recommendations for apps and games that engage users. Since most game downloads come from browsing (as opposed to searching or deep linking into) the store, we've put particular focus on games discovery, with a new games home page, special sections for premium and new games, immersive video trailers and screenshots, and the ability to try games instantly. We've also introduced new programs to help drive app downloads through richer discovery. For example, since launching our app pre-registration program in 2016, we've seen nearly 250 million app pre-registrations. Going forward, we'll be expanding on these programs and others like LiveOps cards to help developers engage more deeply with their audience.
Google Play now collects payments in 150 markets via credit card, direct carrier billing (DCB), Paypal, and gift cards. Direct carrier billing is now enabled across 167 carriers in 64 markets. In 2018, we have focused on expanding our footprint in Africa and Latam with launches in Ghana, Kenya, Tanzania, Nigeria, Peru & Colombia. And users can now buy Google Play credit via gift cards or other means in more 800,000 retail locations around the world. This year, we also launched seller support in 18 new markets bringing the total markets with seller support to 98. Our subscription offering continues to improve with ML-powered fraud detection and even more control for subscribers and developers. Google Play's risk modeling automatically helps detect fraudulent transactions and purchase APIs help you better analyze your refund data to identify suspicious activity.
Google Play Protect and our other systems scan and analyze more than 50 billion apps a day to keep our ecosystem safe for users and developers. In fact, people who only download apps from Google Play are nine times less likely to download a potentially harmful app than those who download from other sources. We've made significant improvements in our ability to detect abuse—such as impersonation, inappropriate content, fraud, or malware—through new machine learning models and techniques. The result is that 99% of apps with abusive content are identified and rejected before anyone can install them. We're also continuing to run the Google Play Security Rewards Program through a collaboration with Hacker One to discover other vulnerabilities.
We are continually inspired by what developers build—check out #IMakeApps for incredible examples—and want every developer to have the tools needed to succeed. We can't wait to see what you do next!
Posted by Vineet Tanwar, Business Development Manager, Google Play
In June, we announced the Indie Games Accelerator, a new four month program to help indie game startups from India, Pakistan and Southeast Asia supercharge their growth on Android. We have been truly impressed by the overwhelming responses we have received, and the creativity that indie game developers from these regions have to offer.
We had a great time going through the applications and playing the games which were submitted for review. Now, it's finally time to announce the inaugural class of startups selected for the program who we will mentor and coach over the next few months. Here they are:
Congratulations to the selected participants and a huge thanks to everyone that applied! Find out more about the program or express your interest in joining next class of Indie Games Accelerator.
Play Console
