Android 17 では、デベロッパー向けに優れた新しい機能と API が導入されました。以下のセクションでは、これらの機能の概要を説明し、関連する API を使い始めるうえで役立つ情報を提供します。
新しい API、変更された API、削除された API の一覧については、API 差分レポートをご覧ください。新しい API について詳しくは、Android API リファレンスをご覧ください。新しい API は、見つけやすいようにハイライト表示されています。
また、プラットフォームの変更がアプリに影響する可能性がある領域も確認する必要があります。詳細については、次のページをご覧ください。
コア機能
Android 17 では、Android のコア機能に関連する次の新機能が追加されています。
新しい ProfilingManager トリガー
Android 17 adds several new system triggers to ProfilingManager to
help you collect in-depth data to debug performance issues.
The new triggers are:
TRIGGER_TYPE_COLD_START: Trigger occurs during app cold start. It provides both a call stack sample and a system trace in the response.TRIGGER_TYPE_OOM: Trigger occurs when an app throws anOutOfMemoryErrorand provides a Java Heap Dump in response.TRIGGER_TYPE_KILL_EXCESSIVE_CPU_USAGE: Trigger occurs when an app is killed due to abnormal and excessive CPU usage and provides a call stack sample in response.
To understand how to set up the system trigger, see the documentation on trigger-based profiling and how to retrieve and analyze profiling data documentation.
JobDebugInfo API
Android 17 introduces new JobDebugInfo APIs to help developers debug
their JobScheduler jobs--why they aren't running, how long they ran for, and
other aggregated information.
The first method of the expanded JobDebugInfo APIs is
getPendingJobReasonStats(), which returns a map of reasons why the job was in
a pending execution state and their respective cumulative pending
durations. This method joins the getPendingJobReasonsHistory() and
getPendingJobReasons() methods to give you insight into why a scheduled
job is not running as expected, but simplifies information retrieval by making
both duration and job reason available in a single method.
For example, for a specified jobId, the method might return
PENDING_JOB_REASON_CONSTRAINT_CHARGING and a duration of 60000 ms, indicating
the job was pending for 60000ms due to the charging constraint not being
satisfied.
allow-while-idle アラームのリスナー サポートでウェイクロックを削減
Android 17
introduces a new variant of AlarmManager.setExactAndAllowWhileIdle that
accepts an OnAlarmListener instead of a PendingIntent. This new
callback-based mechanism is ideal for apps that currently rely on continuous
wakelocks to perform periodic tasks, such as messaging apps maintaining socket
connections.
プライバシー
Android 17 には、ユーザーのプライバシーを強化するための次の新機能が含まれています。
Android の連絡先選択ツール
The Android Contact Picker is a standardized, browsable interface for users to
share contacts with your app. Available on devices running
Android 17 (API level 37) or higher, the picker offers a privacy-preserving
alternative to the broad READ_CONTACTS permission. Instead of requesting
access to the user's entire address book, your app specifies the data fields it
needs, such as phone numbers or email addresses, and the user selects specific
contacts to share. This grants your app read access to only the selected data,
ensuring granular control while providing a consistent user experience with
built-in search, profile switching, and multi-selection capabilities without
having to build or maintain the UI.
For more information, see the contact picker documentation.
セキュリティ
Android 17 では、デバイスとアプリのセキュリティを強化するために、以下の新機能が追加されています。
Android の高度な保護機能モード(AAPM)
Android Advanced Protection Mode offers Android users a powerful new set of security features, marking a significant step in safeguarding users—particularly those at higher risk—from sophisticated attacks. Designed as an opt-in feature, AAPM is activated with a single configuration setting that users can turn on at any time to apply an opinionated set of security protections.
These core configurations include blocking app installation from unknown sources
(sideloading), restricting USB data signaling, and mandating Google Play Protect
scanning, which significantly reduces the device's attack surface area.
Developers can integrate with this feature using the
AdvancedProtectionManager API to detect the mode's status, enabling
applications to automatically adopt a hardened security posture or restrict
high-risk functionality when a user has opted in.
PQC APK 署名
Android now supports a hybrid APK signature scheme to future-proof your app's signing identity against the potential threat of attacks that make use of quantum computing. This feature introduces a new APK Signature Scheme, which lets you pair a classical signing key (such as RSA or EC) with a new post-quantum cryptography (PQC) algorithm (ML-DSA).
This hybrid approach ensures your app remains secure against future quantum attacks while maintaining full backward compatibility with older Android versions and devices that rely on classical signature verification.
Impact on developers
- Apps using Play App Signing: If you use Play App Signing, you can wait for Google Play to give you the option to upgrade a hybrid signature using a PQC key generated by Google Play, ensuring your app is protected without requiring manual key management.
- Apps using self-managed keys: Developers who manage their own signing keys can utilize updated Android build tools (like apksigner) to rotate to a hybrid identity, combining a PQC key with a new classical key. (You must create a new classical key, you cannot reuse the older one.)
接続
Android 17 では、デバイスとアプリの接続性を向上させるために次の機能が追加されています。
制約のある衛星ネットワーク
Implements optimizations to enable apps to function effectively over low-bandwidth satellite networks.
ユーザー エクスペリエンスとシステム UI
Android 17 には、ユーザー エクスペリエンスを改善するための以下の変更が含まれています。
アシスタント専用の音量ストリーム
Android 17 introduces a dedicated Assistant volume stream for Assistant apps,
for playback with USAGE_ASSISTANT. This change decouples Assistant audio
from the standard media stream, providing users with isolated control over both
volumes. This enables scenarios such as muting media playback while maintaining
audibility for Assistant responses, and the other way around.
Assistant apps with access to the new MODE_ASSISTANT_CONVERSATION audio
mode can further improve the volume control consistency. Assistant apps can use
this mode to provide a hint to the system about an active Assistant session,
ensuring the Assistant stream can be controlled outside of the active
USAGE_ASSISTANT playback or with connected Bluetooth peripherals.
ハンドオフ
Handoff is a new feature and API coming to Android 17 that app developers can integrate with to provide cross-device continuity for their users. It allows the user to start an app activity on one Android device and transition it to another Android device. Handoff runs in the background of a user's device and surfaces available activities from the user's other nearby devices through various entry points, like the launcher and taskbar, on the receiving device.
Apps can designate Handoff to launch the same native Android app, if it is installed and available on the receiving device. In this app-to-app flow, the user is deep-linked to the designated activity. Alternatively, app-to-web Handoff can be offered as a fallback option or directly implemented with URL Handoff.
Handoff support is implemented on a per-activity basis. To enable Handoff, call
the setHandoffEnabled() method for the activity. Additional data may need to
be passed along with the handoff so the recreated activity on the receiving
device can restore appropriate state. Implement the
onHandoffActivityRequested() callback to return a HandoffActivityData object
which contains details that specify how Handoff should handle and recreate
the activity on the receiving device.
ライブ アップデート - セマンティック カラー API
With Android 17, Live Update launches the Semantic Coloring APIs to support colors with universal meaning.
The following classes support semantic coloring:
NotificationNotification.MetricNotification.ProgressStyle.PointNotification.ProgressStyle.Segment
Coloring
- Green: Associated with safety. This color should be used for the case where it lets people know you are in the safe situation.
- Orange: For designating caution and marking physical hazards. This color should be used in the situation where users need to pay attention to set better protection setting.
- Red: Generally indicates danger, stop. It should be presented for the case where need people's attention urgently.
- Blue: Neutral color for content that is informational and should stand out from other content.
The following example shows how to apply semantic styles to text in a notification:
val ssb = SpannableStringBuilder()
.append("Colors: ")
.append("NONE", Notification.createSemanticStyleAnnotation(SEMANTIC_STYLE_UNSPECIFIED), 0)
.append(", ")
.append("INFO", Notification.createSemanticStyleAnnotation(SEMANTIC_STYLE_INFO), 0)
.append(", ")
.append("SAFE", Notification.createSemanticStyleAnnotation(SEMANTIC_STYLE_SAFE), 0)
.append(", ")
.append("CAUTION", Notification.createSemanticStyleAnnotation(SEMANTIC_STYLE_CAUTION), 0)
.append(", ")
.append("DANGER", Notification.createSemanticStyleAnnotation(SEMANTIC_STYLE_DANGER), 0)
Notification.Builder(context, channelId)
.setSmallIcon(R.drawable.ic_icon)
.setContentTitle("Hello World!")
.setContentText(ssb)
.setOngoing(true)
.setRequestPromotedOngoing(true)
Android 17 向け UWB ダウンリンク TDoA API
Downlink Time Difference of Arrival (DL-TDoA) ranging lets a device determine its position relative to multiple anchors by measuring the relative arrival times of signals.
The following snippet demonstrates how to initialize the Ranging Manager, verify device capabilities, and start a DL-TDoA session:
Kotlin
class RangingApp {
fun initDlTdoa(context: Context) {
// Initialize the Ranging Manager
val rangingManager = context.getSystemService(RangingManager::class.java)
// Register for device capabilities
val capabilitiesCallback = object : RangingManager.CapabilitiesCallback {
override fun onRangingCapabilities(capabilities: RangingCapabilities) {
// Make sure Dl-TDoA is supported before starting the session
if (capabilities.uwbCapabilities != null && capabilities.uwbCapabilities!!.isDlTdoaSupported) {
startDlTDoASession(context)
}
}
}
rangingManager.registerCapabilitiesCallback(Executors.newSingleThreadExecutor(), capabilitiesCallback)
}
fun startDlTDoASession(context: Context) {
// Initialize the Ranging Manager
val rangingManager = context.getSystemService(RangingManager::class.java)
// Create session and configure parameters
val executor = Executors.newSingleThreadExecutor()
val rangingSession = rangingManager.createRangingSession(executor, RangingSessionCallback())
val rangingRoundIndexes = intArrayOf(0)
val config: ByteArray = byteArrayOf() // OOB config data
val params = DlTdoaRangingParams.createFromFiraConfigPacket(config, rangingRoundIndexes)
val rangingDevice = RangingDevice.Builder().build()
val rawTagDevice = RawRangingDevice.Builder()
.setRangingDevice(rangingDevice)
.setDlTdoaRangingParams(params)
.build()
val dtTagConfig = RawDtTagRangingConfig.Builder(rawTagDevice).build()
val preference = RangingPreference.Builder(DEVICE_ROLE_DT_TAG, dtTagConfig)
.setSessionConfig(SessionConfig.Builder().build())
.build()
// Start the ranging session
rangingSession.start(preference)
}
}
private class RangingSessionCallback : RangingSession.Callback {
override fun onDlTdoaResults(peer: RangingDevice, measurement: DlTdoaMeasurement) {
// Process measurement results here
}
}
Java
public class RangingApp {
public void initDlTdoa(Context context) {
// Initialize the Ranging Manager
RangingManager rangingManager = context.getSystemService(RangingManager.class);
// Register for device capabilities
RangingManager.CapabilitiesCallback capabilitiesCallback = new RangingManager.CapabilitiesCallback() {
@Override
public void onRangingCapabilities(RangingCapabilities capabilities) {
// Make sure Dl-TDoA is supported before starting the session
if (capabilities.getUwbCapabilities() != null && capabilities.getUwbCapabilities().isDlTdoaSupported) {
startDlTDoASession(context);
}
}
};
rangingManager.registerCapabilitiesCallback(Executors.newSingleThreadExecutor(), capabilitiesCallback);
}
public void startDlTDoASession(Context context) {
RangingManager rangingManager = context.getSystemService(RangingManager.class);
// Create session and configure parameters
Executor executor = Executors.newSingleThreadExecutor();
RangingSession rangingSession = rangingManager.createRangingSession(executor, new RangingSessionCallback());
int[] rangingRoundIndexes = new int[] {0};
byte[] config = new byte[0]; // OOB config data
DlTdoaRangingParams params = DlTdoaRangingParams.createFromFiraConfigPacket(config, rangingRoundIndexes);
RangingDevice rangingDevice = new RangingDevice.Builder().build();
RawRangingDevice rawTagDevice = new RawRangingDevice.Builder()
.setRangingDevice(rangingDevice)
.setDlTdoaRangingParams(params)
.build();
RawDtTagRangingConfig dtTagConfig = new RawDtTagRangingConfig.Builder(rawTagDevice).build();
RangingPreference preference = new RangingPreference.Builder(DEVICE_ROLE_DT_TAG, dtTagConfig)
.setSessionConfig(new SessionConfig.Builder().build())
.build();
// Start the ranging session
rangingSession.start(preference);
}
private static class RangingSessionCallback implements RangingSession.Callback {
@Override
public void onDlTdoaResults(RangingDevice peer, DlTdoaMeasurement measurement) {
// Process measurement results here
}
}
}
Out-of-Band (OOB) Configurations
The following snippet provides an example of DL-TDoA OOB configuration data for Wi-Fi and BLE:
Java
// Wifi Configuration
byte[] wifiConfig = {
(byte) 0xDD, (byte) 0x2D, (byte) 0x5A, (byte) 0x18, (byte) 0xFF, // Header
(byte) 0x5F, (byte) 0x19, // FiRa Sub-Element
(byte) 0x02, (byte) 0x00, // Profile ID
(byte) 0x06, (byte) 0x02, (byte) 0x20, (byte) 0x08, // MAC Address
(byte) 0x14, (byte) 0x01, (byte) 0x0C, // Preamble Index
(byte) 0x27, (byte) 0x02, (byte) 0x08, (byte) 0x07, // Vendor ID
(byte) 0x28, (byte) 0x06, (byte) 0xCA, (byte) 0xC8, (byte) 0xA6, (byte) 0xF7, (byte) 0x6F, (byte) 0x08, // Static STS IV
(byte) 0x08, (byte) 0x02, (byte) 0x60, (byte) 0x09, // Slot Duration
(byte) 0x1B, (byte) 0x01, (byte) 0x0A, // Slots per RR
(byte) 0x09, (byte) 0x04, (byte) 0xE8, (byte) 0x03, (byte) 0x00, (byte) 0x00, // Duration
(byte) 0x9F, (byte) 0x04, (byte) 0x67, (byte) 0x45, (byte) 0x23, (byte) 0x01 // Session ID
};
// BLE Configuration
byte[] bleConfig = {
(byte) 0x2D, (byte) 0x16, (byte) 0xF4, (byte) 0xFF, // Header
(byte) 0x5F, (byte) 0x19, // FiRa Sub-Element
(byte) 0x02, (byte) 0x00, // Profile ID
(byte) 0x06, (byte) 0x02, (byte) 0x20, (byte) 0x08, // MAC Address
(byte) 0x14, (byte) 0x01, (byte) 0x0C, // Preamble Index
(byte) 0x27, (byte) 0x02, (byte) 0x08, (byte) 0x07, // Vendor ID
(byte) 0x28, (byte) 0x06, (byte) 0xCA, (byte) 0xC8, (byte) 0xA6, (byte) 0xF7, (byte) 0x6F, (byte) 0x08, // Static STS IV
(byte) 0x08, (byte) 0x02, (byte) 0x60, (byte) 0x09, // Slot Duration
(byte) 0x1B, (byte) 0x01, (byte) 0x0A, // Slots per RR
(byte) 0x09, (byte) 0x04, (byte) 0xE8, (byte) 0x03, (byte) 0x00, (byte) 0x00, // Duration
(byte) 0x9F, (byte) 0x04, (byte) 0x67, (byte) 0x45, (byte) 0x23, (byte) 0x01 // Session ID
};
If you can't use an OOB configuration because it is missing, or if you need to
change default values that aren't in the OOB config, you can build parameters
with DlTdoaRangingParams.Builder as shown in the following snippet. You can use
these parameters in place of DlTdoaRangingParams.createFromFiraConfigPacket():
Kotlin
val dlTdoaParams = DlTdoaRangingParams.Builder(1)
.setComplexChannel(UwbComplexChannel.Builder()
.setChannel(9).setPreambleIndex(10).build())
.setDeviceAddress(deviceAddress)
.setSessionKeyInfo(byteArrayOf(0x01, 0x02, 0x03, 0x04))
.setRangingIntervalMillis(240)
.setSlotDuration(UwbRangingParams.DURATION_2_MS)
.setSlotsPerRangingRound(20)
.setRangingRoundIndexes(byteArrayOf(0x01, 0x05))
.build()
Java
DlTdoaRangingParams dlTdoaParams = new DlTdoaRangingParams.Builder(1)
.setComplexChannel(new UwbComplexChannel.Builder()
.setChannel(9).setPreambleIndex(10).build())
.setDeviceAddress(deviceAddress)
.setSessionKeyInfo(new byte[]{0x01, 0x02, 0x03, 0x04})
.setRangingIntervalMillis(240)
.setSlotDuration(UwbRangingParams.DURATION_2_MS)
.setSlotsPerRangingRound(20)
.setRangingRoundIndexes(new byte[]{0x01, 0x05})
.build();