Características y API

Android 17 incluye excelentes funciones y APIs para desarrolladores. En las siguientes secciones, se resumen estas funciones para ayudarte a comenzar a usar las APIs relacionadas.

Para obtener una lista detallada de las APIs nuevas, modificadas y quitadas, consulta el informe de diferencias de la API. Para obtener detalles sobre las nuevas APIs, consulta la referencia de la API de Android. Las nuevas APIs están destacadas para que sea más fácil identificarlas.

También debes revisar las áreas en las que los cambios en la plataforma podrían afectar tus apps. Para obtener más información, consulta las siguientes páginas:

• Cambios de comportamiento que afectan a las apps cuando se segmentan para Android 17
• Cambios de comportamiento que afectan a todas las apps, independientemente de targetSdkVersion.

Funcionalidad principal

Android 17 agrega las siguientes funciones nuevas relacionadas con la funcionalidad principal de Android.

Nuevos activadores de ProfilingManager

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 an OutOfMemoryError and 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.

APIs de JobDebugInfo

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.

Privacidad

Android 17 incluye las siguientes funciones nuevas para mejorar la privacidad del usuario.

Selector de contactos de Android

The Android Contact Picker is a standardized, browsable interface for users to share contacts with your app. Available on devices running Android 17 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.

Seguridad

Android 17 agrega las siguientes funciones nuevas para mejorar la seguridad de los dispositivos y las apps.

Modo de Protección avanzada de Android (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.

Conectividad

Android 17 agrega las siguientes funciones para mejorar la conectividad de dispositivos y apps.

Redes satelitales restringidas

Se implementaron optimizaciones para permitir que las apps funcionen de manera eficaz en redes satelitales con ancho de banda bajo.

Experiencia del usuario y la IU del sistema

Android 17 incluye los siguientes cambios para mejorar la experiencia del usuario.

Handoff

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.

Actualización en vivo: API de color semántico

Con Android 17, Live Update lanza las APIs de Semantic Coloring para admitir colores con significado universal.

Las siguientes clases admiten el color semántico:

• Notification
• Notification.Metric
• Notification.ProgressStyle.Point
• Notification.ProgressStyle.Segment

Colorear

• Verde: Se asocia con la seguridad. Este color se debe usar en el caso en que se les informa a las personas que estás en una situación segura.
• Naranja: Para designar precaución y marcar peligros físicos Este color se debe usar en situaciones en las que los usuarios deben prestar atención para establecer una mejor configuración de protección.
• Rojo: Por lo general, indica peligro o detención. Se debe presentar en el caso en que se necesite la atención de las personas con urgencia.
• Azul: Color neutro para el contenido informativo que debe destacarse del resto.

En el siguiente ejemplo, se muestra cómo aplicar estilos semánticos al texto de una notificación:

  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)

API de UWB Downlink-TDoA para Android 17

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:

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
    }
}

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:

// 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():

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()

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();