Definición de compatibilidad de Android (vista previa)

1. Introducción

Este documento enumera los requisitos que se deben cumplir para que los dispositivos sean compatibles con Android 15.

El uso de "DEBE", "NO DEBE", "REQUERIDO", "DEBE", "NO DEBE", "DEBE", "NO DEBE", "RECOMENDADO", "PUEDE" y "OPCIONAL" es según el IETF. estándar definido en RFC2119 .

Tal como se utiliza en este documento, un "implementador de dispositivo" o "implementador" es una persona u organización que desarrolla una solución de hardware/software que ejecuta Android 15. Una "implementación de dispositivo" o "implementación" es la solución de hardware/software así desarrollada.

Para ser considerada compatible con Android 15, las implementaciones de dispositivos DEBEN cumplir con los requisitos presentados en esta Definición de compatibilidad, incluido cualquier documento incorporado mediante referencia.

Cuando esta definición o las pruebas de software descritas en la sección 10 no dicen nada, son ambiguas o están incompletas, es responsabilidad del implementador del dispositivo garantizar la compatibilidad con las implementaciones existentes.

Por esta razón, el Proyecto de Código Abierto de Android es a la vez la implementación de referencia y preferida de Android. Se RECOMIENDA ENCARECIDAMENTE a los implementadores de dispositivos que basen sus implementaciones en la mayor medida posible en el código fuente "ascendente" disponible en el Proyecto de código abierto de Android. Si bien hipotéticamente algunos componentes pueden reemplazarse con implementaciones alternativas, se RECOMIENDA ENCARECIDAMENTE no seguir esta práctica, ya que pasar las pruebas de software será sustancialmente más difícil. Es responsabilidad del implementador garantizar la compatibilidad total del comportamiento con la implementación estándar de Android, incluido y más allá del Compatibility Test Suite. Finalmente, tenga en cuenta que este documento prohíbe explícitamente ciertas sustituciones y modificaciones de componentes.

Muchos de los recursos vinculados en este documento se derivan directa o indirectamente del SDK de Android y serán funcionalmente idénticos a la información contenida en la documentación de ese SDK. En cualquier caso en el que esta Definición de compatibilidad o el Conjunto de pruebas de compatibilidad no estén de acuerdo con la documentación del SDK, la documentación del SDK se considera autorizada. Cualquier detalle técnico proporcionado en los recursos vinculados a lo largo de este documento se considera por inclusión parte de esta Definición de compatibilidad.

1.1 Estructura del documento

1.1.1. Requisitos por tipo de dispositivo

La Sección 2 contiene todos los requisitos que se aplican a un tipo de dispositivo específico. Cada subsección de la Sección 2 está dedicada a un tipo de dispositivo específico.

Todos los demás requisitos, que se aplican universalmente a cualquier implementación de dispositivo Android, se enumeran en las secciones posteriores a la Sección 2 . Estos requisitos se denominan "Requisitos básicos" en este documento.

1.1.2. ID de requisito

El ID de requisito se asigna a los requisitos MUST.

  • La identificación se asigna únicamente para los requisitos MUST.
  • Los requisitos MUY RECOMENDADOS están marcados como [SR] pero no se asigna una ID.
  • La ID consta de: ID de tipo de dispositivo - ID de condición - ID de requisito (por ejemplo, C-0-1).

Cada ID se define de la siguiente manera:

  • ID de tipo de dispositivo (ver más en 2. Tipos de dispositivos )
    • C: Core (Requisitos que se aplican a todas las implementaciones de dispositivos Android)
    • H: dispositivo portátil Android
    • T: dispositivo de televisión Android
    • R: Implementación de Android Automotive
    • W: implementación de Android Watch
    • Pestaña: Implementación de tableta Android
  • ID de condición
    • Cuando el requisito es incondicional, este ID se establece en 0.
    • Cuando el requisito es condicional, se asigna 1 para la primera condición y el número aumenta en 1 dentro de la misma sección y el mismo tipo de dispositivo.
  • ID de requisito
    • Este ID comienza desde 1 y aumenta en 1 dentro de la misma sección y la misma condición.

1.1.3. ID de requisito en la Sección 2

Los ID de requisitos de la Sección 2 tienen dos partes. El primero corresponde a un ID de sección como se describe anteriormente. La segunda parte identifica el factor de forma y el requisito específico del factor de forma.

ID de sección seguido por el ID de requisito descrito anteriormente.

  • El ID de la Sección 2 consta de: ID de sección/ID de tipo de dispositivo - ID de condición - ID de requisito (por ejemplo, 7.4.3/A-0-1).

2. Tipos de dispositivos

El Proyecto de código abierto de Android proporciona una pila de software que se puede utilizar para una variedad de tipos de dispositivos y factores de forma. Para respaldar la seguridad en los dispositivos, se espera que la pila de software, incluido cualquier sistema operativo de reemplazo o una implementación de kernel alternativa, se ejecute en un entorno seguro como se describe en la sección 9 y en otras partes de este CDD. Hay algunos tipos de dispositivos que tienen un ecosistema de distribución de aplicaciones relativamente mejor establecido.

Esta sección describe esos tipos de dispositivos y los requisitos y recomendaciones adicionales aplicables a cada tipo de dispositivo.

Todas las implementaciones de dispositivos Android que no se ajusten a ninguno de los tipos de dispositivos descritos DEBEN cumplir todos los requisitos de las otras secciones de esta Definición de compatibilidad.

2.1 Configuraciones del dispositivo

Para conocer las principales diferencias en la configuración de hardware por tipo de dispositivo, consulte los requisitos específicos del dispositivo que aparecen a continuación en esta sección.

2.2. Requisitos de mano

Un dispositivo portátil Android se refiere a una implementación de dispositivo Android que normalmente se usa sosteniéndolo en la mano, como un reproductor de mp3, un teléfono o una tableta.

Las implementaciones de dispositivos Android se clasifican como dispositivos portátiles si cumplen con todos los criterios siguientes:

  • Contar con una fuente de energía que proporcione movilidad, como una batería.
  • Tener un tamaño de pantalla diagonal física en el rango de 4 a 8 pulgadas.
  • Tener una interfaz de entrada de pantalla táctil.

Los requisitos adicionales en el resto de esta sección son específicos de las implementaciones de dispositivos portátiles Android.

Nota: Los requisitos que no se aplican a los dispositivos Tablet Android están marcados con un *.

2.2.1. Hardware

Implementaciones de dispositivos portátiles:

  • [ 7.1 .1.1/H-0-1] DEBE tener al menos una pantalla compatible con Android que mida al menos 2,2" en el borde corto y 3,4" en el borde largo.
  • [ 7.1 .1.3/H-SR-1] Se RECOMIENDA ENCARECIDAMENTE para brindar a los usuarios la posibilidad de cambiar el tamaño de la pantalla (densidad de la pantalla).

  • [ 7.1 .1.1/H-0-2] DEBE admitir la composición de búferes gráficos de GPU al menos tan grande como la resolución más alta de cualquier pantalla integrada.

  • [ 7.1 .1.1/H-0-3]* DEBE asignar cada pantalla UI_MODE_NORMAL disponible para aplicaciones de terceros en un área de pantalla física sin obstáculos que tenga al menos 2,2" pulgadas en el borde corto y 3,4" pulgadas en el borde largo.

  • [ 7.1 .1.3/H-0-1]* DEBE establecer el valor de DENSITY_DEVICE_STABLE para que sea 92% o mayor que la densidad física real de la pantalla correspondiente.

Si las implementaciones de dispositivos portátiles afirman ser compatibles con pantallas de alto rango dinámico a través de Configuration.isScreenHdr() ,:

  • [ 7.1 .4.5/h-1-1] debe anunciar soporte para EGL_EXT_gl_colorspace_bt2020_pq , EGL_EXT_surface_SMPTE2086_metadata , EGL_EXT_surface_CTA861_3_metadata , VK_EXT_swapchain_colorspace y VK_EXT_hdr_metadata .

Implementaciones de dispositivos portátiles:

  • [ 7.1 .4.6/H-0-1] DEBE informar si el dispositivo admite la capacidad de creación de perfiles de GPU a través de una propiedad del sistema graphics.gpu.profiler.support .

Si las implementaciones de dispositivos portátiles declaran soporte a través de una propiedad del sistema graphics.gpu.profiler.support ,:

Implementaciones de dispositivos portátiles:

  • [ 7.1 .5/H-0-1] DEBE incluir soporte para el modo de compatibilidad de aplicaciones heredadas tal como lo implementa el código fuente abierto de Android. Es decir, las implementaciones de dispositivos NO DEBEN alterar los activadores o umbrales en los que se activa el modo de compatibilidad, y NO DEBEN alterar el comportamiento del modo de compatibilidad en sí.
  • [ 7.2 .1/H-0-1] DEBE incluir soporte para aplicaciones de editor de métodos de entrada (IME) de terceros.
  • [ 7.2 .3/H-0-2] DEBE enviar tanto el evento de pulsación normal como el de pulsación larga de la función Atrás ( KEYCODE_BACK ) a la aplicación de primer plano. Estos eventos NO DEBEN ser consumidos por el sistema y PUEDEN activarse desde fuera del dispositivo Android (por ejemplo, un teclado de hardware externo conectado al dispositivo Android).
  • [ 7.2 .3/H-0-3] DEBE proporcionar la función Inicio en todas las pantallas compatibles con Android que proporcionan la pantalla de inicio.
  • [ 7.2 .3/H-0-4] DEBE proporcionar la función Atrás en todas las pantallas compatibles con Android y la función Recientes en al menos una de las pantallas compatibles con Android.
  • [ 7.2 .4/H-0-1] DEBE admitir la entrada de pantalla táctil.
  • [ 7.2 .4/H-SR-1] Se RECOMIENDA ENCARECIDAMENTE iniciar la aplicación de asistencia seleccionada por el usuario, en otras palabras, la aplicación que implementa VoiceInteractionService, o una actividad que maneja ACTION_ASSIST al mantener presionada KEYCODE_MEDIA_PLAY_PAUSE o KEYCODE_HEADSETHOOK si la actividad en primer plano no maneja esos eventos de larga duración.
  • [ 7.3 .1/H-SR-1] Se RECOMIENDA ENCARECIDAMENTE incluir un acelerómetro de 3 ejes.

Si las implementaciones de dispositivos portátiles incluyen un acelerómetro de 3 ejes, estos:

  • [ 7.3 .1/H-1-1] DEBE poder informar eventos con una frecuencia de al menos 100 Hz.

Si las implementaciones de dispositivos portátiles incluyen un receptor GPS/GNSS e informan la capacidad a las aplicaciones a través del indicador de función android.hardware.location.gps , estas:

  • [ 7.3 .3/H-2-1] DEBE informar las mediciones GNSS tan pronto como se encuentren, incluso si aún no se informa una ubicación calculada a partir de GPS/GNSS.
  • [ 7.3 .3/H-2-2 ] DEBEN informar los pseudodistancias y velocidades de pseudodistancia GNSS que, en condiciones de cielo abierto después de determinar la ubicación, mientras están estacionarios o en movimiento con menos de 0,2 metros por segundo al cuadrado de aceleración, sean suficientes para calcular posición dentro de los 20 metros y velocidad dentro de los 0,2 metros por segundo, al menos el 95% del tiempo.

Si las implementaciones de dispositivos portátiles incluyen un giroscopio de 3 ejes, estos:

  • [ 7.3 .4/H-3-1] DEBE poder informar eventos con una frecuencia de al menos 100 Hz.
  • [ 7.3.4 /H-3-2] DEBE ser capaz de medir cambios de orientación de hasta 1000 grados por segundo.

Implementaciones de dispositivos portátiles que pueden realizar una llamada de voz e indicar cualquier valor distinto de PHONE_TYPE_NONE en getPhoneType :

  • [ 7.3 .8/H] DEBE incluir un sensor de proximidad.

Implementaciones de dispositivos portátiles:

  • [ 7.3 .11/H-SR-1] Se RECOMIENDA ENCARECIDAMENTE admitir el sensor de pose con 6 grados de libertad.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[7.4.3] (vista previa del 8 de abril de 2024)

  • [ 7.4 .3/H] DEBE incluir soporte para Bluetooth y Bluetooth LE.
  • [ 7.4 .3/H-0-1] DEBE incluir soporte para Bluetooth y Bluetooth LE.

Implementaciones de dispositivos portátiles que incluyen soporte para Bluetooth LE:

  • [ 7.4 .3/H-SR-1] Se RECOMIENDA ENCARECIDAMENTE que admitan la extensión de longitud de paquetes de datos Bluetooth LE.

Terminar con nuevos requisitos

[7.4.3] (vista previa del 26 de febrero de 2024)

  • [ 7.4 .3/H-0-1] DEBE incluir soporte para Bluetooth y Bluetooth LE.
  • [ 7.4 .3/H-0-2] DEBE ser compatible con Bluetooth 4.2.
  • [ 7.4 .3/H-SR-1] Se RECOMIENDA ENCARECIDAMENTE que admitan la extensión de longitud de paquetes de datos Bluetooth LE.

Terminar con nuevos requisitos

[7.4.3] (vista previa del 11 de diciembre de 2023)

  • [ 7.4 .3/H-0-1] DEBE incluir soporte para Bluetooth y Bluetooth LE.
  • [ 7.4 .3/H-0-2] DEBE admitir Bluetooth 4.2 y extensión de longitud de datos Bluetooth LE.
  • [ 7.4 .3/H-0-3] DEBE admitir GATT ATT_MTU de un mínimo de 247 bytes.
  • [ 7.4 .3/H-0-4] DEBE admitir el servicio BTP con 3 características C1, C2 y C3, como se define en la Especificación principal de Matter 1.0 .

Terminar con nuevos requisitos

Si los dispositivos admiten el protocolo WiFi Neighbor Awareness Networking (NAN) al declarar PackageManager.FEATURE_WIFI_AWARE y la ubicación de Wi-Fi (tiempo de ida y vuelta de Wi-Fi - RTT) al declarar PackageManager.FEATURE_WIFI_RTT , entonces:

  • [ 7.4 .2.5/H-1-1] DEBE informar el alcance con precisión dentro de +/-1 metro en un ancho de banda de 160 MHz en el percentil 68 (calculado con la función de distribución acumulativa), +/-2 metros en un ancho de banda de 80 MHz en el percentil 68, +/-4 metros con un ancho de banda de 40 MHz en el percentil 68 y +/-8 metros con un ancho de banda de 20 MHz en el percentil 68 a distancias de 10 cm, 1 m, 3 m y 5 m, como observado a través de la API de Android WifiRttManager#startRanging .

  • [ 7.4 .2.5/H-SR-1] Se RECOMIENDA ENCARECIDAMENTE informar el alcance con precisión dentro de +/-1 metro en un ancho de banda de 160 MHz en el percentil 90 (calculado con la función de distribución acumulativa), +/-2 metros en Ancho de banda de 80 MHz en el percentil 90, +/-4 metros con un ancho de banda de 40 MHz en el percentil 90 y +/-8 metros con un ancho de banda de 20 MHz en el percentil 90 a distancias de 10 cm, como se observa a través de WifiRttManager#startRanging Android API .

Se RECOMIENDA ENCARECIDAMENTE seguir los pasos de configuración de medición especificados en Calibración de presencia .

Si las implementaciones de dispositivos portátiles declaran FEATURE_BLUETOOTH_LE ,:

  • [ 7.4 .3/H-1-3] DEBE medir y compensar la compensación de Rx para garantizar que el RSSI BLE medio sea -50 dBm +/-15 dB a 1 m de distancia de un dispositivo de referencia que transmita a ADVERTISE_TX_POWER_HIGH .
  • [ 7.4 .3/H-1-4] DEBE medir y compensar la compensación de Tx para garantizar que el RSSI BLE medio sea -50 dBm +/-15 dB cuando se escanea desde un dispositivo de referencia ubicado a 1 m de distancia y se transmite a ADVERTISE_TX_POWER_HIGH .

Si las implementaciones de dispositivos portátiles incluyen una conexión medida,:

  • [ 7.4 .7/H-1-1] DEBE proporcionar el modo de ahorro de datos.

Si las implementaciones de dispositivos portátiles incluyen un dispositivo de cámara lógico que enumera las capacidades que utilizan CameraMetadata.REQUEST_AVAILABLE_CAPABILITIES_LOGICAL_MULTI_CAMERA ,:

  • [ 7.5 .4/H-1-1] DEBE tener un campo de visión normal (FOV) de forma predeterminada y DEBE estar entre 50 y grados.

Implementaciones de dispositivos portátiles:

  • [ 7.6 .1/H-0-1] DEBE tener al menos 4 GB de almacenamiento no volátil disponible para los datos privados de la aplicación (también conocida como partición "/data").
  • [ 7.6 .1/H-0-2] DEBE devolver "true" para ActivityManager.isLowRamDevice() cuando hay menos de 1 GB de memoria disponible para el kernel y el espacio de usuario.

Si las implementaciones de dispositivos portátiles declaran admitir solo una ABI de 32 bits:

  • [ 7.6 .1/H-1-1] La memoria disponible para el kernel y el espacio de usuario DEBE ser de al menos 416 MB si la pantalla predeterminada utiliza resoluciones de framebuffer de hasta qHD (por ejemplo, FWVGA).

  • [ 7.6 .1/H-2-1] La memoria disponible para el kernel y el espacio de usuario DEBE ser de al menos 592 MB si la pantalla predeterminada utiliza resoluciones de framebuffer hasta HD+ (por ejemplo, HD, WSVGA).

  • [ 7.6 .1/H-3-1] La memoria disponible para el kernel y el espacio de usuario DEBE ser de al menos 896 MB si la pantalla predeterminada utiliza resoluciones de framebuffer de hasta FHD (por ejemplo, WSXGA+).

  • [ 7.6 .1/H-4-1] La memoria disponible para el kernel y el espacio de usuario DEBE ser de al menos 1344 MB si la pantalla predeterminada utiliza resoluciones de framebuffer hasta QHD (por ejemplo, QWXGA).

Si las implementaciones de dispositivos portátiles declaran compatibilidad con cualquier ABI de 64 bits (con o sin ABI de 32 bits):

  • [ 7.6 .1/H-5-1] La memoria disponible para el kernel y el espacio de usuario DEBE ser de al menos 816 MB si la pantalla predeterminada utiliza resoluciones de framebuffer de hasta qHD (por ejemplo, FWVGA).

  • [ 7.6 .1/H-6-1] La memoria disponible para el kernel y el espacio de usuario DEBE ser de al menos 944 MB si la pantalla predeterminada utiliza resoluciones de framebuffer de hasta HD+ (por ejemplo, HD, WSVGA).

  • [ 7.6 .1/H-7-1] La memoria disponible para el kernel y el espacio de usuario DEBE ser de al menos 1280 MB si la pantalla predeterminada utiliza resoluciones de framebuffer de hasta FHD (por ejemplo, WSXGA+).

  • [ 7.6 .1/H-8-1] La memoria disponible para el kernel y el espacio de usuario DEBE ser de al menos 1824 MB si la pantalla predeterminada utiliza resoluciones de framebuffer hasta QHD (por ejemplo, QWXGA).

Tenga en cuenta que la "memoria disponible para el kernel y el espacio de usuario" anterior se refiere al espacio de memoria proporcionado además de cualquier memoria ya dedicada a componentes de hardware como radio, video, etc. que no están bajo el control del kernel en las implementaciones del dispositivo.

Si las implementaciones de dispositivos portátiles incluyen menos o igual a 1 GB de memoria disponible para el kernel y el espacio de usuario,:

  • [ 7.6 .1/H-9-1] DEBE declarar el indicador de función android.hardware.ram.low .
  • [ 7.6 .1/H-9-2] DEBE tener al menos 1,1 GB de almacenamiento no volátil para los datos privados de la aplicación (también conocida como partición "/data").

Si las implementaciones de dispositivos portátiles incluyen más de 1 GB de memoria disponible para el kernel y el espacio de usuario,:

  • [ 7.6 .1/H-10-1] DEBE tener al menos 4 GB de almacenamiento no volátil disponible para los datos privados de la aplicación (también conocida como partición "/data").
  • DEBE declarar el indicador de función android.hardware.ram.normal .

Si las implementaciones de dispositivos portátiles incluyen 2 GB o más y menos de 4 GB de memoria disponible para el kernel y el espacio de usuario,:

  • [7.6.1/H-SR-1] Se RECOMIENDA ENCARECIDAMENTE admitir solo espacio de usuario de 32 bits (tanto aplicaciones como código del sistema)

Si las implementaciones de dispositivos portátiles incluyen menos de 2 GB de memoria disponible para el kernel y el espacio de usuario,:

  • [7.6.1/H-1-1] DEBE admitir solo ABI de 32 bits.

Implementaciones de dispositivos portátiles:

  • [ 7.6 .2/H-0-1] NO DEBE proporcionar un almacenamiento compartido de aplicaciones de menos de 1 GiB.
  • [ 7.7 .1/H] DEBE incluir un puerto USB que admita el modo periférico.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[7.7.1/H-1-1] (vista previa del 11 de diciembre de 2023)

Si las implementaciones de dispositivos portátiles incluyen un puerto USB compatible con un controlador que funciona en modo periférico:

  • [ 7.7 .1/H-1-1] DEBE implementar la API del accesorio abierto de Android (AOA).

Terminar con nuevos requisitos

Si las implementaciones de dispositivos portátiles incluyen un puerto USB que admite el modo host:

  • [ 7.7 .2/H-1-1] DEBE implementar la clase de audio USB como se documenta en la documentación del SDK de Android.

Implementaciones de dispositivos portátiles:

  • [ 7.8 .1/H-0-1] DEBE incluir un micrófono.
  • [ 7.8 .2/H-0-1] DEBE tener una salida de audio y declarar android.hardware.audio.output .

Si las implementaciones de dispositivos portátiles son capaces de cumplir con todos los requisitos de rendimiento para admitir el modo VR e incluyen soporte para él,:

  • [ 7.9 .1/H-1-1] DEBE declarar el indicador de función android.hardware.vr.high_performance .
  • [ 7.9 .1/H-1-2] DEBE incluir una aplicación que implemente android.service.vr.VrListenerService que las aplicaciones de realidad virtual puedan habilitar a través de android.app.Activity#setVrModeEnabled .

Si las implementaciones de dispositivos portátiles incluyen uno o más puertos USB-C en modo host e implementan (clase de audio USB), además de los requisitos de la sección 7.7.2 ,:

  • [ 7.8 .2.2/H-1-1] DEBE proporcionar el siguiente mapeo de software de códigos HID:
Función Mapeos Contexto Comportamiento
A Página de uso de HID : 0x0C
Uso de HID : 0x0CD
Clave del núcleo : KEY_PLAYPAUSE
Clave de Android : KEYCODE_MEDIA_PLAY_PAUSE
Reproducción multimedia Entrada : pulsación corta
Salida : Reproducir o pausar
Entrada : pulsación larga
Salida : iniciar comando de voz
Envía : android.speech.action.VOICE_SEARCH_HANDS_FREE si el dispositivo está bloqueado o su pantalla está apagada. Envía android.speech.RecognizerIntent.ACTION_WEB_SEARCH de lo contrario
Llamada entrante Entrada : pulsación corta
Salida : Aceptar llamada
Entrada : pulsación larga
Salida : Rechazar llamada
llamada en curso Entrada : pulsación corta
Salida : Finalizar llamada
Entrada : pulsación larga
Salida : Silenciar o reactivar el micrófono
B Página de uso de HID : 0x0C
Uso de HID : 0x0E9
Clave del kernel : KEY_VOLUMEUP
Clave de Android : VOLUME_UP
Reproducción multimedia, llamada en curso Entrada : Pulsación corta o larga
Salida : aumenta el volumen del sistema o de los auriculares.
C Página de uso de HID : 0x0C
Uso de HID : 0x0EA
Clave del núcleo : KEY_VOLUMEDOWN
Clave de Android : VOLUME_DOWN
Reproducción multimedia, llamada en curso Entrada : Pulsación corta o larga
Salida : Disminuye el volumen del sistema o de los auriculares.
D Página de uso de HID : 0x0C
Uso de HID : 0x0CF
Clave del núcleo : KEY_VOICECOMMAND
Clave de Android : KEYCODE_VOICE_ASSIST
Todo. Puede activarse en cualquier caso. Entrada : Pulsación corta o larga
Salida : iniciar comando de voz
  • [ 7.8 .2.2/H-1-2] DEBE activar ACTION_HEADSET_PLUG al insertar un enchufe, pero solo después de que las interfaces de audio USB y los puntos finales se hayan enumerado correctamente para identificar el tipo de terminal conectado.

Cuando se detecta el terminal de audio USB tipo 0x0302,:

  • [ 7.8 .2.2/H-2-1] DEBE transmitir el Intent ACTION_HEADSET_PLUG con el "micrófono" adicional establecido en 0.

Cuando se detecta el terminal de audio USB tipo 0x0402,:

  • [ 7.8 .2.2/H-3-1] DEBE transmitir el Intent ACTION_HEADSET_PLUG con el "micrófono" adicional configurado en 1.

Cuando se llama a API AudioManager.getDevices() mientras el periférico USB está conectado:

  • [ 7.8 .2.2/H-4-1] DEBE enumerar un dispositivo de tipo AudioDeviceInfo.TYPE_USB_HEADSET y la función isSink() si el campo de tipo de terminal de audio USB es 0x0302.

  • [ 7.8 .2.2/H-4-2] DEBE enumerar un dispositivo de tipo AudioDeviceInfo.TYPE_USB_HEADSET y función isSink() si el campo de tipo de terminal de audio USB es 0x0402.

  • [ 7.8 .2.2/H-4-3] DEBE enumerar un dispositivo de tipo AudioDeviceInfo.TYPE_USB_HEADSET y la función isSource() si el campo de tipo de terminal de audio USB es 0x0402.

  • [ 7.8 .2.2/H-4-4] DEBE enumerar un dispositivo de tipo AudioDeviceInfo.TYPE_USB_DEVICE y la función isSink() si el campo de tipo de terminal de audio USB es 0x603.

  • [ 7.8 .2.2/H-4-5] DEBE enumerar un dispositivo de tipo AudioDeviceInfo.TYPE_USB_DEVICE y la función isSource() si el campo de tipo de terminal de audio USB es 0x604.

  • [ 7.8 .2.2/H-4-6] DEBE enumerar un dispositivo de tipo AudioDeviceInfo.TYPE_USB_DEVICE y la función isSink() si el campo de tipo de terminal de audio USB es 0x400.

  • [ 7.8 .2.2/H-4-7] DEBE enumerar un dispositivo de tipo AudioDeviceInfo.TYPE_USB_DEVICE y la función isSource() si el campo de tipo de terminal de audio USB es 0x400.

  • [ 7.8 .2.2/H-SR-1] Se RECOMIENDA ENCARECIDAMENTE al conectar un periférico de audio USB-C, para realizar una enumeración de descriptores USB, identificar tipos de terminales y transmitir Intent ACTION_HEADSET_PLUG en menos de 1000 milisegundos.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[5.6/H-1-1 y 5.6/H-1-2] (vista previa del 5 de febrero de 2024)

Si se trata de implementaciones de dispositivos portátiles que declaran android.hardware.audio.output y android.hardware.microphone , consulte los requisitos de RTL y TTL en la sección 5.6 .

  • [ 5.6 /H-1-1] DEBE tener una latencia media continua de ida y vuelta de 300 milisegundos o menos en 5 mediciones, con una desviación media absoluta inferior a 30 ms, en las siguientes rutas de datos: "altavoz a micrófono", 3,5 mm adaptador de bucle invertido (si es compatible), bucle invertido USB (si es compatible).

  • [ 5.6 /H-1-2] DEBE tener una latencia promedio de toque a tono de 300 milisegundos o menos en al menos 5 mediciones a través de la ruta de datos del altavoz al micrófono.

Terminar con nuevos requisitos

Un actuador resonante lineal (LRA) es un sistema de resorte de una sola masa que tiene una frecuencia resonante dominante donde la masa se traslada en la dirección del movimiento deseado.

Si las implementaciones de dispositivos portátiles incluyen al menos un actuador resonante lineal 7.10 de uso general, estos:

  • [ 7.10 /H] DEBE colocar el actuador cerca del lugar donde normalmente se sostiene o toca el dispositivo con las manos.

  • [ 7.10 /H] DEBE mover el actuador háptico en el eje X (izquierda-derecha) de la orientación natural del dispositivo.

Si las implementaciones de dispositivos portátiles tienen un actuador háptico de uso general que es un actuador resonante lineal (LRA) del eje X,:

  • [ 7.10 /H] DEBE tener la frecuencia de resonancia del LRA del eje X por debajo de 200 Hz.

Si las implementaciones de dispositivos portátiles siguen el mapeo de constantes hápticas,:

2.2.2. Multimedia

Las implementaciones de dispositivos portátiles DEBEN admitir los siguientes formatos de codificación y decodificación de audio y ponerlos a disposición de aplicaciones de terceros:

  • [ 5.1 /H-0-1] RAM-NB
  • [ 5.1 /H-0-2] AMR-WB
  • [ 5.1 /H-0-3] Perfil MPEG-4 AAC (AAC LC)
  • [ 5.1 /H-0-4] Perfil MPEG-4 HE AAC (AAC+)
  • [ 5.1 /H-0-5] AAC ELD (AAC de bajo retardo mejorado)

Las implementaciones de dispositivos portátiles DEBEN admitir los siguientes formatos de codificación de video y ponerlos a disposición de aplicaciones de terceros:

  • [ 5.2 /H-0-1] H.264 AVC
  • [ 5.2 /H-0-2] VP8
  • [ 5.2 /H-0-3] AV1

Las implementaciones de dispositivos portátiles DEBEN admitir los siguientes formatos de decodificación de video y ponerlos a disposición de aplicaciones de terceros:

  • [ 5.3 /H-0-1] H.264 AVC
  • [ 5.3 /H-0-2] H.265 HEVC
  • [ 5.3 /H-0-3] MPEG-4 SP
  • [ 5.3 /H-0-4] VP8
  • [ 5.3 /H-0-5] VP9
  • [ 5.3 /H-0-6] AV1

2.2.3. Software

Implementaciones de dispositivos portátiles:

  • [ 3.2.3.1 /H-0-1] DEBE tener una aplicación que maneje las intenciones ACTION_GET_CONTENT , ACTION_OPEN_DOCUMENT , ACTION_OPEN_DOCUMENT_TREE y ACTION_CREATE_DOCUMENT como se describe en los documentos del SDK, y proporcione al usuario la posibilidad de acceder a los datos del proveedor de documentos mediante la API DocumentsProvider .
  • [ 3.2.3.1 /H-0-2]* DEBE precargar una o más aplicaciones o componentes de servicio con un controlador de intenciones, para todos los patrones de filtro de intenciones públicas definidos por las siguientes intenciones de aplicación enumeradas aquí .
  • [ 3.2.3.1 /H-SR-1] Se RECOMIENDA ENCARECIDAMENTE precargar una aplicación de correo electrónico que pueda manejar ACTION_SENDTO o ACTION_SEND o ACTION_SEND_MULTIPLE intentos para enviar un correo electrónico.
  • [ 3.4 .1/H-0-1] DEBE proporcionar una implementación completa de la API android.webkit.Webview .
  • [ 3.4 .2/H-0-1] DEBE incluir una aplicación de navegador independiente para la navegación web del usuario general.
  • [ 3.8.1 /H-SR-1] Se RECOMIENDA ENCARECIDAMENTE implementar un iniciador predeterminado que admita la fijación de accesos directos, widgets y funciones de widgets en la aplicación.
  • [ 3.8 .1/H-SR-2] Se RECOMIENDA ENCARECIDAMENTE implementar un iniciador predeterminado que proporcione acceso rápido a los accesos directos adicionales proporcionados por aplicaciones de terceros a través de la API ShortcutManager .
  • [ 3.8 .1/H-SR-3] Se RECOMIENDA ENCARECIDAMENTE incluir una aplicación de inicio predeterminada que muestre insignias para los íconos de las aplicaciones.
  • [ 3.8 .2/H-SR-1] Se RECOMIENDA ENCARECIDAMENTE para admitir widgets de aplicaciones de terceros.
  • [ 3.8 .3/H-0-1] DEBE permitir que aplicaciones de terceros notifiquen a los usuarios sobre eventos notables a través de las clases API Notification y NotificationManager .
  • [ 3.8 .3/H-0-2] DEBE admitir notificaciones enriquecidas.
  • [ 3.8 .3/H-0-3] DEBE admitir notificaciones de aviso.
  • [ 3.8 .3/H-0-4] DEBE incluir un tono de notificación, que brinde al usuario la capacidad de controlar directamente (por ejemplo, responder, posponer, descartar, bloquear) las notificaciones a través de las posibilidades del usuario, como los botones de acción o el panel de control, según se implemente. en la AOSP.
  • [ 3.8 .3/H-0-5] DEBE mostrar las opciones proporcionadas a través de RemoteInput.Builder setChoices() en el tono de notificación.
  • [ 3.8 .3/H-SR-1] Se RECOMIENDA ENCARECIDAMENTE mostrar la primera opción proporcionada a través de RemoteInput.Builder setChoices() en el tono de notificación sin interacción adicional del usuario.
  • [ 3.8 .3/H-SR-2] Se RECOMIENDA ENCARECIDAMENTE mostrar todas las opciones proporcionadas a través de RemoteInput.Builder setChoices() en el tono de notificación cuando el usuario expande todas las notificaciones en el tono de notificación.
  • [ 3.8.3.1/H-SR-1 ] Se RECOMIENDA ENCARECIDAMENTE mostrar acciones para las cuales Notification.Action.Builder.setContextual está configurado como true en línea con las respuestas mostradas por Notification.Remoteinput.Builder.setChoices .
  • [ 3.8.4 /H-SR-1] Se RECOMIENDA ENCARECIDAMENTE implementar un asistente en el dispositivo para manejar la acción de asistencia .

Si las implementaciones de dispositivos portátiles admiten notificaciones MediaStyle :

  • [ 3.8 .3.1/H-SR-2] Se RECOMIENDA ENCARECIDAMENTE proporcionar una opción para el usuario (por ejemplo, un conmutador de salida) a la que se accede desde la interfaz de usuario del sistema y que permite a los usuarios cambiar entre las rutas de medios disponibles apropiadas (por ejemplo, dispositivos Bluetooth y rutas proporcionadas para MediaRouter2Manager ) cuando una aplicación publica una notificación MediaStyle con un token MediaSession .

Si las implementaciones del dispositivo, incluida la tecla de navegación de la función reciente, como se detalla en la sección 7.2.3, alteran la interfaz:

  • [ 3.8 .3/H-1-1] DEBE implementar el comportamiento de fijación de pantalla y proporcionar al usuario un menú de configuración para alternar la función.

Si las implementaciones de dispositivos portátiles admiten la acción de asistencia, estas:

  • [ 3.8.4 /H-SR-2] Se RECOMIENDA ENCARECIDAMENTE utilizar una pulsación prolongada de la tecla HOME como interacción designada para iniciar la aplicación de asistencia como se describe en la sección 7.2.3 . DEBE iniciar la aplicación de asistencia seleccionada por el usuario, en otras palabras, la aplicación que implementa VoiceInteractionService o una actividad que maneje la intención ACTION_ASSIST .

Si las implementaciones de dispositivos portátiles admiten conversation notifications y las agrupan en una sección separada de las alertas y las notificaciones silenciosas que no son de conversación,:

  • [ 3.8 .4/H-1-1]* DEBE mostrar las notificaciones de conversación antes que las notificaciones que no son de conversación, con la excepción de las notificaciones de servicio en primer plano en curso y las notificaciones de importancia: alta .

Si las implementaciones de dispositivos portátiles Android admiten una pantalla de bloqueo,:

  • [ 3.8 .10/H-1-1] DEBE mostrar las notificaciones de la pantalla de bloqueo, incluida la plantilla de notificación de medios.

Si las implementaciones de dispositivos portátiles admiten una pantalla de bloqueo segura,:

Si las implementaciones de dispositivos portátiles incluyen soporte para ControlsProviderService y Control API y permiten que aplicaciones de terceros publiquen controles de dispositivos , entonces:

  • [ 3.8 .16/H-1-1] DEBE declarar el indicador de función android.software.controls y establecerlo en true .
  • [ 3.8 .16/H-1-2] DEBE proporcionar al usuario la posibilidad de agregar, editar, seleccionar y operar los controles del dispositivo favorito del usuario desde los controles registrados por las aplicaciones de terceros a través de ControlsProviderService y las API Control . .
  • [ 3.8 .16/H-1-3] DEBE proporcionar acceso a esta posibilidad de usuario dentro de tres interacciones desde un iniciador predeterminado.
  • [ 3.8 .16/H-1-4] DEBE representar con precisión en esta prestación de usuario el nombre y el icono de cada aplicación de terceros que proporciona controles a través de la API ControlsProviderService , así como cualquier campo especificado proporcionado por las API Control .

  • [ 3.8 .16/H-1-5] DEBE proporcionar al usuario la posibilidad de optar por no participar en los controles de dispositivos triviales de autenticación designados por la aplicación de los controles registrados por las aplicaciones de terceros a través de ControlsProviderService y la API Control Control.isAuthRequired .

  • [ 3.8 .16/H-1-6] Las implementaciones de dispositivos DEBEN ofrecer con precisión las posibilidades del usuario de la siguiente manera:

    • Si el dispositivo ha configurado config_supportsMultiWindow=true y la aplicación declara los metadatos META_DATA_PANEL_ACTIVITY en la declaración ControlsProviderService , incluido el ComponentName de una actividad válida (según lo definido por la API), entonces la aplicación DEBE incorporar dicha actividad en esta posibilidad de usuario.
    • Si la aplicación no declara metadatos META_DATA_PANEL_ACTIVITY , DEBE representar los campos especificados proporcionados por la API ControlsProviderService , así como cualquier campo especificado proporcionado por las API de control .
  • [ 3.8 .16/H-1-7] Si la aplicación declara los metadatos META_DATA_PANEL_ACTIVITY , DEBE pasar el valor de la configuración definida en [3.8.16/H-1-5] usando EXTRA_LOCKSCREEN_ALLOW_TRIVIAL_CONTROLS al iniciar la actividad integrada.

Por el contrario, si las implementaciones de dispositivos portátiles no implementan dichos controles,:

Si las implementaciones de dispositivos portátiles no se ejecutan en modo de tarea de bloqueo , cuando el contenido se copia al portapapeles:

  • [3.8.17/H-1-1] DEBE presentar una confirmación al usuario de que los datos se han copiado al portapapeles (por ejemplo, una miniatura o alerta de "Contenido copiado"). Además, incluya aquí una indicación si los datos del portapapeles se sincronizarán entre dispositivos.

Implementaciones de dispositivos portátiles:

  • [ 3.10 /H-0-1] DEBE admitir servicios de accesibilidad de terceros.
  • [ 3.10 /H-SR-1] Se RECOMIENDA ENCARECIDAMENTE precargar servicios de accesibilidad en el dispositivo comparables o superiores a la funcionalidad de los servicios de accesibilidad Switch Access y TalkBack (para idiomas admitidos por el motor de texto a voz preinstalado) según lo dispuesto en el proyecto de código abierto talkback .
  • [ 3.11 /H-0-1] DEBE admitir la instalación de motores TTS de terceros.
  • [ 3.11 /H-SR-1] Se RECOMIENDA ENCARECIDAMENTE incluir un motor TTS que admita los idiomas disponibles en el dispositivo.
  • [ 3.13 /H-SR-1] Se RECOMIENDA ENCARECIDAMENTE incluir un componente de interfaz de usuario de Configuración rápida.

Si las implementaciones de dispositivos portátiles Android declaran compatibilidad FEATURE_BLUETOOTH o FEATURE_WIFI ,:

  • [ 3.16 /H-1-1] DEBE admitir la función de emparejamiento de dispositivos complementarios.

Si la función de navegación se proporciona como una acción en pantalla basada en gestos:

  • [ 7.2 .3/H] La zona de reconocimiento de gestos para la función Inicio no DEBE tener más de 32 dp de altura desde la parte inferior de la pantalla.

Si las implementaciones de dispositivos portátiles proporcionan una función de navegación como un gesto desde cualquier lugar de los bordes izquierdo y derecho de la pantalla:

  • [ 7.2 .3/H-0-1] El área de gestos de la función de navegación DEBE tener menos de 40 dp de ancho en cada lado. El área de gesto DEBE tener 24 dp de ancho de forma predeterminada.

Si las implementaciones de dispositivos portátiles admiten una pantalla de bloqueo segura y tienen 2 GB o más de memoria disponible para el kernel y el espacio de usuario,:

  • [3.9/H-1-2] DEBE declarar la compatibilidad con perfiles administrados a través del indicador de función android.software.managed_users .

Si las implementaciones de dispositivos portátiles Android declaran la compatibilidad con la cámara a través de android.hardware.camera.any :

Si la aplicación de configuración de implementación del dispositivo implementa una funcionalidad dividida mediante la incrustación de actividades, entonces:

Si las implementaciones de dispositivos permiten a los usuarios realizar llamadas de cualquier tipo,

2.2.4. Rendimiento y potencia

  • [ 8.1 /H-0-1] Latencia de fotogramas consistente . La latencia de fotogramas inconsistente o un retraso en la renderización de fotogramas NO DEBEN ocurrir con más frecuencia de 5 fotogramas por segundo, y DEBEN ser inferiores a 1 fotograma por segundo.
  • [ 8.1 /H-0-2] Latencia de la interfaz de usuario . Las implementaciones de dispositivos DEBEN garantizar una experiencia de usuario de baja latencia al desplazarse por una lista de 10.000 entradas de lista según lo definido por Android Compatibility Test Suite (CTS) en menos de 36 segundos.
  • [ 8.1 /H-0-3] Cambio de tarea . Cuando se han iniciado varias aplicaciones, volver a iniciar una aplicación que ya se está ejecutando después de haberla iniciado DEBE tomar menos de 1 segundo.

Implementaciones de dispositivos portátiles:

  • [ 8.2 /H-0-1] DEBE garantizar un rendimiento de escritura secuencial de al menos 5 MB/s.
  • [ 8.2 /H-0-2] DEBE garantizar un rendimiento de escritura aleatoria de al menos 0,5 MB/s.
  • [ 8.2 /H-0-3] DEBE garantizar un rendimiento de lectura secuencial de al menos 15 MB/s.
  • [ 8.2 /H-0-4] DEBE garantizar un rendimiento de lectura aleatoria de al menos 3,5 MB/s.

Si las implementaciones de dispositivos portátiles incluyen funciones para mejorar la administración de energía del dispositivo que se incluyen en AOSP o amplían las funciones que se incluyen en AOSP, estas:

  • [ 8.3 /H-1-1] DEBE proporcionar al usuario la posibilidad de habilitar y deshabilitar la función de ahorro de batería.
  • [ 8.3 /H-1-2] DEBE proporcionar al usuario la posibilidad de mostrar todas las aplicaciones que están exentas de los modos de ahorro de energía App Standby y Doze.

Implementaciones de dispositivos portátiles:

  • [ 8.4 /H-0-1] DEBE proporcionar un perfil de energía por componente que defina el valor de consumo actual para cada componente de hardware y el consumo aproximado de batería causado por los componentes a lo largo del tiempo, como se documenta en el sitio del Proyecto de código abierto de Android.
  • [ 8.4 /H-0-2] DEBE informar todos los valores de consumo de energía en miliamperios hora (mAh).
  • [ 8.4 /H-0-3] DEBE informar el consumo de energía de la CPU por el UID de cada proceso. El proyecto de código abierto de Android cumple con el requisito mediante la implementación del módulo del kernel uid_cputime .
  • [ 8.4 /H-0-4] DEBE hacer que este uso de energía esté disponible a través del comando adb shell dumpsys batterystats shell para el desarrollador de la aplicación.
  • [ 8.4 /H] DEBE atribuirse al propio componente de hardware si no se puede atribuir el uso de energía del componente de hardware a una aplicación.

Si las implementaciones de dispositivos portátiles incluyen una pantalla o salida de video,:

Implementaciones de dispositivos portátiles:

  • [ 8.5 /H-0-1] DEBE proporcionar al usuario la posibilidad de ver todas las aplicaciones con servicios en primer plano activos o trabajos iniciados por el usuario, incluida la duración de cada uno de estos servicios desde que se inició, como se describe en el documento SDK .

  • [ 8.5 /H-0-2]DEBE proporcionar al usuario la posibilidad de detener una aplicación que esté ejecutando un servicio en primer plano o un trabajo iniciado por el usuario.

2.2.5. Modelo de seguridad

Implementaciones de dispositivos portátiles:

  • [9/H-0-1] DEBE declarar la característica android.hardware.security.model.compatible .
  • [ 9.1 /H-0-1] DEBE permitir que aplicaciones de terceros accedan a las estadísticas de uso a través del permiso android.permission.PACKAGE_USAGE_STATS y proporcionar un mecanismo accesible para el usuario para otorgar o revocar el acceso a dichas aplicaciones en respuesta a android.settings.ACTION_USAGE_ACCESS_SETTINGS intención.

Si las implementaciones de dispositivos declaran compatibilidad con android.hardware.telephony ,:

  • [ 9.5 /H-1-1] NO DEBE establecer UserManager.isHeadlessSystemUserMode en true .

Implementaciones de dispositivos portátiles:

  • [ 9.11 /H-0-2] DEBE realizar una copia de seguridad de la implementación del almacén de claves con un entorno de ejecución aislado.
  • [ 9.11 /H-0-3] DEBE tener implementaciones de algoritmos criptográficos RSA, AES, ECDSA y HMAC y funciones hash de las familias MD5, SHA1 y SHA-2 para admitir adecuadamente los algoritmos admitidos del sistema Android Keystore en un área segura. aislado del código que se ejecuta en el kernel y superiores. El aislamiento seguro DEBE bloquear todos los mecanismos potenciales mediante los cuales el código del kernel o del espacio de usuario podría acceder al estado interno del entorno aislado, incluido DMA. El Proyecto de código abierto de Android (AOSP) cumple con este requisito mediante el uso de la implementación Trusty , pero otra solución basada en ARM TrustZone o una implementación segura revisada por terceros de un aislamiento adecuado basado en hipervisor son opciones alternativas.
  • [ 9.11 /H-0-4] DEBE realizar la autenticación de la pantalla de bloqueo en el entorno de ejecución aislada y solo cuando tenga éxito, permita que se utilicen las claves vinculadas a la autenticación. Las credenciales de la pantalla de bloqueo DEBEN almacenarse de manera que solo el entorno de ejecución aislado pueda realizar la autenticación de la pantalla de bloqueo. El proyecto de código abierto de Android proporciona la capa de abstracción de hardware Gatekeeper (HAL) y Trusty, que se pueden utilizar para satisfacer este requisito.
  • [ 9.11 /H-0-5] DEBE admitir la atestación de clave donde la clave de firma de atestación está protegida por hardware seguro y la firma se realiza en hardware seguro. Las claves de firma de certificación DEBEN compartirse entre una cantidad suficiente de dispositivos para evitar que se utilicen como identificadores de dispositivos. Una forma de cumplir este requisito es compartir la misma clave de certificación a menos que se produzcan al menos 100.000 unidades de un SKU determinado. Si se producen más de 100.000 unidades de un SKU, SE PUEDE utilizar una clave diferente por cada 100.000 unidades.

Tenga en cuenta que si la implementación de un dispositivo ya se lanzó en una versión anterior de Android, dicho dispositivo está exento del requisito de tener un almacén de claves respaldado por un entorno de ejecución aislado y admitir la atestación de claves, a menos que declare la característica android.hardware.fingerprint que requiere un almacén de claves respaldado por un entorno de ejecución aislado.

Cuando las implementaciones de dispositivos portátiles admiten una pantalla de bloqueo segura,:

  • [ 9.11 /H-1-1] DEBE permitir al usuario elegir el tiempo de espera más corto, es decir, un tiempo de transición del estado desbloqueado al estado bloqueado, de 15 segundos o menos.
  • [ 9.11 /H-1-2] DEBE brindar al usuario la posibilidad de ocultar notificaciones y deshabilitar todas las formas de autenticación, excepto la autenticación primaria descrita en 9.11.1 Pantalla de bloqueo seguro . El AOSP cumple con el requisito como modo de bloqueo.

Si las implementaciones de dispositivos tienen una pantalla de bloqueo segura e incluyen uno o más agentes de confianza, que implementan la API del sistema TrustAgentService , ellos:

  • [ 9.11.1 /H-1-1] DEBE solicitar al usuario uno de los métodos de autenticación principales recomendados (por ejemplo, PIN, patrón, contraseña) con más frecuencia que una vez cada 72 horas.

Si las implementaciones de dispositivos portátiles incluyen varios usuarios y no declaran el indicador de función android.hardware.telephony , estos:

  • [ 9.5 /H-2-1] DEBE admitir perfiles restringidos, una característica que permite a los propietarios de dispositivos administrar usuarios adicionales y sus capacidades en el dispositivo. Con perfiles restringidos, los propietarios de dispositivos pueden configurar rápidamente entornos separados para que trabajen usuarios adicionales, con la capacidad de administrar restricciones más detalladas en las aplicaciones que están disponibles en esos entornos.

Si las implementaciones de dispositivos portátiles incluyen varios usuarios y declaran la marca de función android.hardware.telephony , estos:

  • [ 9.5 /H-3-1] NO DEBE admitir perfiles restringidos, pero DEBE alinearse con la implementación de controles de AOSP para permitir o deshabilitar el acceso de otros usuarios a las llamadas de voz y SMS.

Si las implementaciones de dispositivos portátiles configuran UserManager.isHeadlessSystemUserMode en true ,

  • [ 9.5 /H-4-1] NO DEBE incluir soporte para eUICC ni para eSIM con capacidad de llamada.
  • [ 9.5 /H-4-2] NO DEBE declarar soporte para android.hardware.telephony .

Android, a través de la API del sistema VoiceInteractionService, admite un mecanismo para la detección segura de palabras activas siempre activas sin indicación de acceso al micrófono y la detección de consultas siempre activas, sin indicación de acceso al micrófono o a la cámara.

Si las implementaciones de dispositivos portátiles admiten System API HotwordDetectionService u otro mecanismo para la detección de palabras activas sin indicación de acceso al micrófono,:

  • [9.8/H-1-1] DEBE asegurarse de que el servicio de detección de palabras activas solo pueda transmitir datos al sistema, ContentCaptureService o al servicio de reconocimiento de voz en el dispositivo creado por SpeechRecognizer#createOnDeviceSpeechRecognizer() .
  • [9.8/H-1-2] DEBE asegurarse de que el servicio de detección de palabras activas solo pueda transmitir datos de audio del micrófono o datos derivados de él al servidor del sistema a través de la API HotwordDetectionService , o a ContentCaptureService a través de la API ContentCaptureManager .
  • [9.8/H-1-3] NO DEBE suministrar audio de micrófono que dure más de 30 segundos para una solicitud individual activada por hardware al servicio de detección de palabras activas.
  • [9.8/H-1-4] NO DEBE proporcionar audio de micrófono almacenado en búfer de más de 8 segundos para una solicitud individual al servicio de detección de palabras activas.
  • [9.8/H-1-5] NO DEBE suministrar audio de micrófono almacenado en buffer de más de 30 segundos al servicio de interacción de voz o entidad similar.
  • [9.8/H-1-6] NO DEBE permitir que se transmitan más de 100 bytes de datos (excluyendo secuencias de audio) fuera del servicio de detección de palabras activas en cada resultado exitoso de palabra activa.
  • [9.8/H-1-7] NO DEBE permitir que se transmitan más de 5 bits de datos fuera del servicio de detección de palabras activas en cada resultado negativo de palabra activa.
  • [9.8/H-1-8] DEBE permitir únicamente la transmisión de datos fuera del servicio de detección de palabras activas en una solicitud de validación de palabras activas del servidor del sistema.
  • [9.8/H-1-9] NO DEBE permitir que una aplicación instalable por el usuario proporcione el servicio de detección de palabras activas.
  • [9.8/H-1-10] NO DEBE aparecer en la interfaz de usuario datos cuantitativos sobre el uso del micrófono por parte del servicio de detección de palabras activas.
  • [9.8/H-1-11] DEBE registrar la cantidad de bytes incluidos en cada transmisión desde el servicio de detección de palabras activas para permitir la inspeccionabilidad por parte de los investigadores de seguridad.
  • [9.8/H-1-12] DEBE admitir un modo de depuración que registre el contenido sin procesar de cada transmisión desde el servicio de detección de palabras activas para permitir la inspeccionabilidad por parte de los investigadores de seguridad.
  • [9.8/H-1-14] DEBE mostrar el indicador del micrófono, como se describe en la sección 9.8.2 , cuando se transmite un resultado exitoso de una palabra activa al servicio de interacción de voz o entidad similar.

  • [9.8/H-1-15] DEBE garantizar que los flujos de audio proporcionados cuando se obtienen resultados exitosos de palabras activas se transmitan en un sentido desde el servicio de detección de palabras activas al servicio de interacción de voz.

  • [9.8/H-SR-1] Se RECOMIENDA ENCARECIDAMENTE notificar a los usuarios antes de configurar una aplicación como proveedor del servicio de detección de palabras activas.

  • [9.8/H-SR-2] Se RECOMIENDA ENCARECIDAMENTE no permitir la transmisión de datos no estructurados fuera del servicio de detección de palabras activas.

  • [9.8/H-SR-3] Se RECOMIENDA ENCARECIDAMENTE reiniciar el proceso que aloja el servicio de detección de palabras activas al menos una vez cada hora o cada 30 eventos de activación de hardware, lo que ocurra primero.

Si las implementaciones del dispositivo incluyen una aplicación que utiliza la API del sistema HotwordDetectionService o un mecanismo similar para la detección de palabras activas sin indicación de uso del micrófono, la aplicación:

  • [9.8/H-2-1] DEBE proporcionar un aviso explícito al usuario para cada frase de palabra activa admitida.
  • [9.8/H-2-2] NO DEBE conservar datos de audio sin procesar, ni datos derivados de ellos, a través del servicio de detección de palabras activas.
  • [9.8/H-2-3] NO DEBE transmitir desde el servicio de detección de palabras clave, datos de audio, datos que puedan usarse para reconstruir (total o parcialmente) el audio, o contenidos de audio no relacionados con la palabra clave en sí, excepto al ContentCaptureService o Servicio de reconocimiento de voz en el dispositivo.

Si las implementaciones de dispositivos portátiles admiten la API del sistema VisualQueryDetectionService u otro mecanismo para la detección de consultas sin indicación de acceso al micrófono o la cámara,:

  • [9.8/H-3-1] DEBE asegurarse de que el servicio de detección de consultas solo pueda transmitir datos al Sistema, o ContentCaptureService , o al servicio de reconocimiento de voz en el dispositivo (creado por SpeechRecognizer#createOnDeviceSpeechRecognizer() ).
  • [9.8/H-3-2] NO DEBE permitir que se transmita ninguna información de audio o video fuera de VisualQueryDetectionService , excepto a ContentCaptureService o al servicio de reconocimiento de voz en el dispositivo.
  • [9.8/H-3-3] DEBE mostrar un aviso de usuario en la interfaz de usuario del sistema cuando el dispositivo detecta la intención del usuario de interactuar con la aplicación de asistente digital (por ejemplo, detectando la presencia del usuario a través de la cámara).
  • [9.8/H-3-4] DEBE mostrar un indicador de micrófono y mostrar la consulta del usuario detectada en la interfaz de usuario inmediatamente después de que se detecta la consulta del usuario.
  • [9.8/H-3-5] NO DEBE permitir que una aplicación instalable por el usuario proporcione el servicio de detección visual de consultas.

Si las implementaciones de dispositivos portátiles declaran android.hardware.microphone ,:

  • [ 9.8.2 /H-4-1] DEBE mostrar el indicador del micrófono cuando una aplicación accede a datos de audio desde el micrófono, pero no cuando al micrófono solo accede HotwordDetectionService , SOURCE_HOTWORD , ContentCaptureService o aplicaciones que desempeñan los roles mencionados en la sección 9.1 con identificador CDD [C-4-X].
  • [ 9.8.2 /H-4-2] DEBE mostrar la lista de aplicaciones recientes y activas que usan el micrófono según lo devuelto por PermissionManager.getIndicatorAppOpUsageData() , junto con cualquier mensaje de atribución asociado con ellas.
  • [ 9.8.2 /H-4-3] No DEBE ocultar el indicador del micrófono para aplicaciones del sistema que tienen interfaces de usuario visibles o interacción directa con el usuario.
  • [ 9.8.2 /H-4-4] DEBE mostrar la lista de aplicaciones recientes y activas que usan el micrófono según lo devuelto por PermissionManager.getIndicatorAppOpUsageData() , junto con cualquier mensaje de atribución asociado con ellas.

Si las implementaciones de dispositivos portátiles declaran android.hardware.camera.any ,:

  • [ 9.8.2 /H-5-1] DEBE mostrar el indicador de la cámara cuando una aplicación accede a los datos de la cámara en vivo, pero no cuando solo acceden a la cámara las aplicaciones que desempeñan las funciones mencionadas en la sección 9.1 con el identificador CDD. [C-4-X].
  • [ 9.8.2 /H-5-2] DEBE mostrar las aplicaciones recientes y activas que usan la cámara tal como se devuelven desde PermissionManager.getIndicatorAppOpUsageData() , junto con cualquier mensaje de atribución asociado con ellas.
  • [ 9.8.2 /H-5-3] No DEBE ocultar el indicador de la cámara para aplicaciones del sistema que tienen interfaces de usuario visibles o interacción directa con el usuario.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[9.10/H–1–1] (vista previa del 26 de febrero de 2024)

El arranque verificado es una característica que garantiza la integridad del software del dispositivo. Si las implementaciones de dispositivos admiten la función,:

  • [ 9.10 /H–1–1] DEBE verificar todas las particiones de solo lectura cargadas durante la secuencia de inicio de Android.

Terminar con nuevos requisitos

2.2.6. Compatibilidad de opciones y herramientas de desarrollador

Implementaciones de dispositivos portátiles (* No aplicable para tableta):

  • [ 6.1 /H-0-1]* DEBE admitir el comando de shell cmd testharness .

Implementaciones de dispositivos portátiles (* No aplicable para tableta):

  • perfecto
    • [ 6.1 /H-0-2]* DEBE exponer un binario /system/bin/perfetto al usuario del shell cuyo cmdline cumpla con la documentación de perfetto .
    • [ 6.1 /H-0-3]* El binario perfetto DEBE aceptar como entrada una configuración de protobuf que cumpla con el esquema definido en la documentación de perfetto .
    • [ 6.1 /H-0-4]* El binario perfetto DEBE escribir como salida una traza de protobuf que cumpla con el esquema definido en la documentación de perfetto .
    • [ 6.1 /H-0-5]* DEBE proporcionar, a través del binario perfetto, al menos las fuentes de datos descritas en la documentación de perfetto .
    • [ 6.1 /H-0-6]* El demonio rastreado de perfetto DEBE estar habilitado de forma predeterminada (propiedad del sistema persist.traced.enable ).

2.2.7. Clase de rendimiento de medios portátiles

Consulte la Sección 7.11 para conocer la definición de clase de rendimiento del medio.

2.2.7.1. Medios de comunicación

Si las implementaciones de dispositivos portátiles devuelven android.os.Build.VERSION_CODES.U para android.os.Build.VERSION_CODES.MEDIA_PERFORMANCE_CLASS ,:

Comienzan nuevos requisitos para 15 (AOSP experimental)

Actualizaciones de clases de rendimiento multimedia para Android 15 (AOSP experimental) (vista previa del 5 de febrero de 2024)

Si las implementaciones de dispositivos portátiles devuelven android.os.Build.VERSION_CODES.V para android.os.Build.VERSION_CODES.MEDIA_PERFORMANCE_CLASS ,:

Terminar con nuevos requisitos

  • [5.1/H-1-1] DEBE anunciar el número máximo de sesiones de decodificador de video de hardware que se pueden ejecutar simultáneamente en cualquier combinación de códec a través de los métodos CodecCapabilities.getMaxSupportedInstances() y VideoCapabilities.getSupportedPerformancePoints() .

Comienzan nuevos requisitos para 15 (AOSP experimental)

5.1/H-1-2 (vista previa del 5 de febrero de 2024)

  • [5.1/H-1-2] DEBE admitir 6 instancias de sesiones de decodificador de video de hardware de 8 bits (SDR) (AVC, HEVC, VP9, ​​AV1 o posterior) en cualquier combinación de códec que se ejecute simultáneamente con 3 sesiones con una resolución de 1080p@30 fps y 3 sesiones a resolución 4k@30fps, a menos que AV1. Para todas las sesiones, NO DEBE perderse más de 1 fotograma por segundo. Los códecs AV1 solo son necesarios para admitir una resolución de 1080p, pero aún así deben admitir 6 instancias a 1080p30fps.

Terminar con nuevos requisitos

  • [5.1/H-1-3] DEBE anunciar el número máximo de sesiones de codificador de video de hardware que se pueden ejecutar simultáneamente en cualquier combinación de códec a través de los métodos CodecCapabilities.getMaxSupportedInstances() y VideoCapabilities.getSupportedPerformancePoints() .

Comienzan nuevos requisitos para 15 (AOSP experimental)

5.1/H-1-4 (vista previa del 5 de febrero de 2024)

  • [5.1/H-1-4] DEBE admitir 6 instancias de sesiones de codificador de video de hardware de 8 bits (SDR) (AVC, HEVC, VP9, ​​AV1 o posterior) en cualquier combinación de códec que se ejecute simultáneamente con 4 sesiones con una resolución de 1080p@30 fps y 2 sesiones a resolución 4k@30fps, a menos que AV1. Para todas las sesiones, NO DEBE perderse más de 1 fotograma por segundo. Los códecs AV1 solo son necesarios para admitir una resolución de 1080p, pero aún así deben admitir 6 instancias a 1080p30fps.

Terminar con nuevos requisitos

  • [5.1/H-1-5] DEBE anunciar el número máximo de sesiones de codificador y decodificador de video de hardware que se pueden ejecutar simultáneamente en cualquier combinación de códec a través de los métodos CodecCapabilities.getMaxSupportedInstances() y VideoCapabilities.getSupportedPerformancePoints() .

Comienzan nuevos requisitos para 15 (AOSP experimental)

5.1/H-1-6 (vista previa del 5 de febrero de 2024)

  • [5.1/H-1-6] DEBE admitir 6 instancias de sesiones de decodificador de video por hardware (SDR) y codificador de video por hardware (AVC, HEVC, VP9, ​​AV1 o posterior) en cualquier combinación de códec que se ejecute simultáneamente con 3 sesiones en Resolución 4K@30fps (a menos que AV1), de las cuales como máximo 2 son sesiones de codificador y 3 sesiones a resolución 1080p. Para todas las sesiones, NO DEBE perderse más de 1 fotograma por segundo. Los códecs AV1 solo son necesarios para admitir una resolución de 1080p, pero aún así deben admitir 6 instancias a 1080p30fps.

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

5.1/H-1-19 (vista previa del 5 de febrero de 2024)

  • [5.1/H-1-19] DEBE admitir 3 instancias de sesiones de decodificador de video por hardware (HDR) y codificador de video por hardware (AVC, HEVC, VP9, ​​AV1 o posterior) en cualquier combinación de códec que se ejecute simultáneamente a 4K a 30 fps. resolución (a menos que AV1) de la cual como máximo 1 es una sesión de codificador, que podría configurarse en formato de entrada RGBA_1010102 a través de una superficie GL. Para todas las sesiones, NO DEBE perderse más de 1 fotograma por segundo. No se requiere la generación de metadatos HDR por parte del codificador si se codifica desde la superficie GL. Las sesiones de códec AV1 solo son necesarias para admitir una resolución de 1080p, incluso cuando este requisito requiere 4K.

Terminar con nuevos requisitos

  • [5.1/H-1-7] DEBE tener una latencia de inicialización de códec de 40 ms o menos para una sesión de codificación de video de 1080p o menor para todos los codificadores de video de hardware cuando están bajo carga. La carga aquí se define como una sesión simultánea de transcodificación de video de 1080p a 720p únicamente utilizando códecs de video de hardware junto con la inicialización de grabación de audio y video de 1080p. Para el códec Dolby Vision, la latencia de inicialización del códec DEBE ser de 50 ms o menos.
  • [5.1/H-1-8] DEBE tener una latencia de inicialización de códec de 30 ms o menos para una sesión de codificación de audio con una velocidad de bits de 128 kbps o inferior para todos los codificadores de audio cuando están bajo carga. La carga aquí se define como una sesión simultánea de transcodificación de video de 1080p a 720p únicamente utilizando códecs de video de hardware junto con la inicialización de grabación de audio y video de 1080p.

Comienzan nuevos requisitos para 15 (AOSP experimental)

5.1/H-1-9 (vista previa del 5 de febrero de 2024)

  • [5.1/H-1-9] DEBE admitir 2 instancias de sesiones seguras de decodificador de video por hardware (AVC, HEVC, VP9, ​​AV1 o posterior) en cualquier combinación de códec que se ejecute simultáneamente con una resolución de 4k a 30 fps (a menos que AV1) para ambos 8 -bit (SDR) y contenido HDR de 10 bits. Para todas las sesiones, NO DEBE perderse más de 1 fotograma por segundo. Las sesiones de códec AV1 solo son necesarias para admitir una resolución de 1080p, incluso cuando este requisito requiere 4K.

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

5.1/H-1-10 (vista previa del 5 de febrero de 2024)

  • [5.1/H-1-10] DEBE admitir 3 instancias de sesiones de decodificador de video de hardware no seguro junto con 1 instancia de sesión de decodificador de video de hardware seguro (4 instancias en total) (AVC, HEVC, VP9, ​​AV1 o posterior) en cualquier combinación de códec que se ejecuta simultáneamente con 3 sesiones con resolución 4K a 30 fps (a menos que AV1) que incluye una sesión de decodificador seguro y 1 sesión nn-segura con resolución 1080p a 30 fps donde como máximo 2 sesiones pueden ser en HDR de 10 bits. Para todas las sesiones, NO DEBE perderse más de 1 fotograma por segundo. Las sesiones de códec AV1 solo son necesarias para admitir una resolución de 1080p, incluso cuando este requisito requiere 4K.

Terminar con nuevos requisitos

  • [5.1/H-1-11] DEBE admitir un decodificador seguro para cada decodificador de hardware AVC, HEVC, VP9 o AV1 en el dispositivo.
  • [5.1/H-1-12] DEBE tener una latencia de inicialización de códec de 40 ms o menos para una sesión de decodificación de video de 1080p o menor para todos los decodificadores de video de hardware cuando están bajo carga. La carga aquí se define como una sesión simultánea de transcodificación de solo video de 1080p a 720p utilizando códecs de video de hardware junto con la inicialización de reproducción de audio y video de 1080p. Para el códec Dolby Vision, la latencia de inicialización del códec DEBE ser de 50 ms o menos.
  • [5.1/H-1-13] DEBE tener una latencia de inicialización de códec de 30 ms o menos para una sesión de decodificación de audio con una velocidad de bits de 128 kbps o inferior para todos los decodificadores de audio cuando están bajo carga. La carga aquí se define como una sesión simultánea de transcodificación de solo video de 1080p a 720p utilizando códecs de video de hardware junto con la inicialización de reproducción de audio y video de 1080p.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[5.1/H-1-14] (vista previa del 5 de febrero de 2024)

  • [5.1/H-1-14] DEBE admitir el decodificador de hardware AV1 Main 10, nivel 4.1 y el grano de película con efecto de grano de película sobre la composición de GPU .

Terminar con nuevos requisitos

  • [5.1/H-1-15] DEBE tener al menos 1 decodificador de video de hardware compatible con 4K60.
  • [5.1/H-1-16] DEBE tener al menos 1 codificador de video de hardware compatible con 4K60.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[5.1/H-1-21] (vista previa del 5 de febrero de 2024)

  • [5.1/H-1-21] DEBE admitir FEATURE_DynamicColorAspect para todos los decodificadores de video de hardware (AVC, HEVC, VP9, ​​AV1 o posterior). Nota: Esto significa que las aplicaciones pueden actualizar los aspectos de color del contenido del video durante la sesión de decodificación. Los decodificadores que admiten contenido de 10 y 8 bits DEBEN admitir la conmutación dinámica entre contenido de 8 y 10 bits en modo Superficie. Los decodificadores que admiten la función de transferencia HDR DEBEN admitir el cambio dinámico entre contenido SDR y HDR.

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[5.1/H-1-22] (vista previa del 5 de febrero de 2024)

  • [5.1/H-1-22] DEBE admitir codificación, decodificación, edición de GPU y visualización de contenido de video en relación de aspecto vertical, independientemente de los metadatos de rotación para la resolución más grande admitida por la cámara o 4K, la que sea menor. Nota: esto incluye perfiles HDR si el códec admite HDR. Los códecs AV1 solo son necesarios para admitir una resolución de 1080p. Este requisito es sólo para códecs de hardware, GPU y DPU.

Terminar con nuevos requisitos

  • [5.3/H-1-1] NO DEBE perder más de 1 fotograma en 10 segundos (es decir, menos del 0,167 por ciento de pérdida de fotogramas) para una sesión de vídeo 4K a 60 fps bajo carga.
  • [5.3/H-1-2] NO DEBE perder más de 1 cuadro en 10 segundos durante un cambio de resolución de video en una sesión de video de 60 fps bajo carga para una sesión de 4K.
  • [5.6/H-1-1] DEBE tener una latencia de pulsación para tono de 80 milisegundos o menos utilizando la prueba de pulsación para tono de CTS Verifier.
  • [5.6/H-1-2] DEBE tener una latencia de audio de ida y vuelta de 80 milisegundos o menos en al menos una ruta de datos admitida.
  • [5.6/H-1-3] DEBE admitir >= audio de 24 bits para salida estéreo a través de conectores de audio de 3,5 mm si están presentes y a través de audio USB si es compatible con toda la ruta de datos para configuraciones de transmisión y baja latencia. Para la configuración de baja latencia, la aplicación debe utilizar AAudio en modo de devolución de llamada de baja latencia. Para la configuración de transmisión, la aplicación debe utilizar Java AudioTrack. Tanto en la configuración de baja latencia como en la de transmisión, el receptor de salida HAL debe aceptar AUDIO_FORMAT_PCM_24_BIT , AUDIO_FORMAT_PCM_24_BIT_PACKED , AUDIO_FORMAT_PCM_32_BIT o AUDIO_FORMAT_PCM_FLOAT para su formato de salida de destino.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[5.6/H-1-4] (vista previa del 5 de febrero de 2024)

  • [5.6/H-1-4] DEBE admitir >= dispositivos de audio USB de 4 canales. (Esto lo utilizan los controladores de DJ para obtener una vista previa de las canciones).

Terminar con nuevos requisitos

  • [5.6/H-1-5] DEBE admitir dispositivos MIDI compatibles con su clase y declarar el indicador de función MIDI.
  • [5.6/H-1-9] DEBE admitir al menos 12 canales de mezcla. Esto implica la capacidad de abrir una AudioTrack con máscara de canal 7.1.4 y espacializar o mezclar adecuadamente todos los canales a estéreo.
  • [5.6/H-SR] Se RECOMIENDA ENCARECIDAMENTE admitir mezcla de 24 canales con al menos soporte para máscaras de 9.1.6 y 22.2 canales.
  • [5.7/H-1-2] DEBE admitir MediaDrm.SECURITY_LEVEL_HW_SECURE_ALL con las siguientes capacidades de descifrado de contenido.
Tamaño mínimo de muestra 4 MB
Número mínimo de submuestras: H264 o HEVC 32
Número mínimo de submuestras - VP9 9
Número mínimo de submuestras - AV1 288
Tamaño mínimo del búfer de submuestra 1 MB
Tamaño mínimo del búfer criptográfico genérico 500 KiB
Número mínimo de sesiones simultáneas 30
Número mínimo de claves por sesión 20
Número total mínimo de claves (todas las sesiones) 80
Número total mínimo de claves DRM (todas las sesiones) 6
Tamaño del mensaje 16 KiB
Cuadros descifrados por segundo 60 fps
  • [5.1/H-1-17] DEBE tener al menos 1 decodificador de imágenes de hardware compatible con AVIF Baseline Profile.
  • [5.1/H-1-18] DEBE admitir el codificador AV1 que puede codificar una resolución de hasta 480p a 30 fps y 1 Mbps.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[5.1/H-1-20] (vista previa del 5 de febrero de 2024)

  • [5.1/H-1-20] DEBE admitir la función Feature_HdrEditing para todos los codificadores AV1 y HEVC de hardware presentes en el dispositivo con una resolución de 4K o la resolución más grande admitida por la cámara, la que sea menor.

Terminar con nuevos requisitos

  • Se recomienda encarecidamente [5.12/H-SR] para admitir la función Feature_HdrEditing para todos los codificadores AV1 y HEVC de hardware presentes en el dispositivo.
  • [5.12/H-1-2] DEBE admitir el formato de color RGBA_1010102 para todos los codificadores AV1 y HEVC de hardware presentes en el dispositivo.
  • [5.12/H-1-3] DEBE anunciar soporte para la extensión EXT_YUV_target para muestrear texturas YUV tanto en 8 como en 10 bits.
  • [7.1.4/H-1-1] DEBE tener al menos 6 superposiciones de hardware en el compositor de hardware (HWC) de la unidad de procesamiento de datos (DPU), y al menos 2 de ellas capaces de mostrar contenido de video de 10 bits.

Comienzan nuevos requisitos para 15 (AOSP experimental)

Actualizaciones de clases de rendimiento multimedia para Android 15 (AOSP experimental) (vista previa del 5 de febrero de 2024)

Si las implementaciones de dispositivos portátiles devuelven android.os.Build.VERSION_CODES.V para android.os.Build.VERSION_CODES.MEDIA_PERFORMANCE_CLASS e incluyen soporte para un codificador de hardware AVC o HEVC,:

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[5.2/H-2-2] [Retirado] (vista previa del 8 de abril de 2024)

  • [5.2/H-2-2]
    Este requisito se retira de Android 15 (AOSP experimental).

Terminar con nuevos requisitos

[5.2/H-2-2] (vista previa del 5 de febrero de 2024)

  • [5.2/H-2-2] DEBE renderizar el video de muestra usando el decodificador AV1 del software dav1d en 1080p a >= 60 FPS.

Terminar con nuevos requisitos

2.2.7.2. Cámara

Si las implementaciones de dispositivos portátiles devuelven android.os.Build.VERSION_CODES.U para android.os.Build.VERSION_CODES.MEDIA_PERFORMANCE_CLASS ,:

Comienzan nuevos requisitos para 15 (AOSP experimental)

Actualizaciones de clases de rendimiento multimedia para Android 15 (AOSP experimental) (vista previa del 5 de febrero de 2024)

Si las implementaciones de dispositivos portátiles devuelven android.os.Build.VERSION_CODES.V para android.os.Build.VERSION_CODES.MEDIA_PERFORMANCE_CLASS ,:

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[7.5/H-1-1] (vista previa del 26 de febrero de 2024)

  • [ 7.5 /H-1-1] DEBE tener una cámara trasera principal con una resolución de al menos 12 megapíxeles que admita captura de video a 4k@30fps , 1080p@60fps y 720p@60fps . La cámara trasera principal es la cámara trasera con el ID de cámara más bajo.

Terminar con nuevos requisitos

[7.5/H-1-1] (vista previa del 5 de febrero de 2024)

  • [ 7.5 /H-1-1] DEBE tener una cámara trasera principal con una resolución de al menos 12 megapíxeles que admita captura de video a 4k@30fps , 1080p@60fps y 720p@60fps. La tasa de caída de cuadros para estas tasas de captura no DEBE ser mayor que el X% (X está por determinarse para el primer trimestre de 2024). La cámara trasera principal es la cámara trasera con el ID de cámara más bajo.

Terminar con nuevos requisitos

  • [ 7.5 /H-1-2] DEBE tener una cámara frontal principal con una resolución de al menos 6 megapíxeles y admitir captura de video a 1080p@30fps. La cámara frontal principal es la cámara frontal con el ID de cámara más bajo.
  • [ 7.5 /H-1-3] DEBE admitir la propiedad android.info.supportedHardwareLevel como FULL o mejor para la cámara principal trasera y LIMITED o mejor para la cámara principal frontal.
  • [ 7.5 /H-1-4] DEBE admitir CameraMetadata.SENSOR_INFO_TIMESTAMP_SOURCE_REALTIME para ambas cámaras principales.
  • [ 7.5 /H-1-5] DEBE tener una latencia de captura JPEG de la cámara 2 < 1000 ms para una resolución de 1080p según lo medido por la prueba de rendimiento de la cámara CTS en condiciones de iluminación ITS (3000K) para ambas cámaras principales.
  • [ 7.5 /H-1-6] DEBE tener una latencia de inicio de la cámara 2 (cámara abierta al primer fotograma de vista previa) < 500 ms, según lo medido por la prueba de rendimiento de la cámara CTS en condiciones de iluminación ITS (3000 K) para ambas cámaras principales.
  • [ 7.5 /H-1-8] DEBE admitir CameraMetadata.REQUEST_AVAILABLE_CAPABILITIES_RAW y android.graphics.ImageFormat.RAW_SENSOR para la cámara trasera principal.
  • [ 7.5 /H-1-9] DEBE tener una cámara principal orientada hacia atrás que admita 720p o 1080p a 240 fps.
  • [ 7.5 /H-1-10] DEBE tener ZOOM_RATIO mínimo < 1.0 para las cámaras principales si hay una cámara RGB ultra ancha orientada en la misma dirección.
  • [ 7.5 /H-1-11] DEBE implementar transmisión simultánea de adelante hacia atrás en las cámaras principales.
  • [ 7.5 /H-1-12] DEBE admitir CONTROL_VIDEO_STABILIZATION_MODE_PREVIEW_STABILIZATION tanto para la cámara frontal principal como para la cámara trasera principal.
  • [ 7.5 /H-1-13] DEBE admitir la capacidad LOGICAL_MULTI_CAMERA para la cámara trasera principal si hay más de 1 cámara trasera RGB.
  • [ 7.5 /H-1-14] DEBE admitir la capacidad STREAM_USE_CASE tanto para la cámara frontal principal como para la trasera principal.
  • [ 7.5 /H-1-15] DEBE admitir extensiones de modo nocturno a través de las extensiones CameraX y Camera2 para las cámaras principales.
  • [ 7.5 /H-1-16] DEBE admitir la capacidad DYNAMIC_RANGE_TEN_BIT para las cámaras principales.
  • [ 7.5 /H-1-17] DEBE admitir CONTROL_SCENE_MODE_FACE_PRIORITY y detección de rostros ( STATISTICS_FACE_DETECT_MODE_SIMPLE o STATISTICS_FACE_DETECT_MODE_FULL ) para las cámaras principales.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[7.5/H-1-18] (vista previa del 5 de febrero de 2024)

  • [ 7.5 /H-1-18] DEBE admitir JPEG_R para las cámaras principal trasera y frontal principal.

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[7.5/H-1-19] (vista previa del 8 de abril de 2024)

  • [ 7.5 /H-1-19] DEBE admitir CONTROL_VIDEO_STABILIZATION_MODE_PREVIEW_STABILIZATION para una vista previa de 1080p HLG10 con una relación de aspecto de 16:9 de tamaño máximo y combinaciones de secuencias de secuencias de JPEG de una relación de aspecto de 16:9 de tamaño máximo para la cámara trasera principal.

Terminar con nuevos requisitos

[7.5/H-1-19] (vista previa del 26 de febrero de 2024)

  • [ 7.5 /H-1-19] DEBE admitir CONTROL_VIDEO_STABILIZATION_MODE_PREVIEW_STABILIZATION para una vista previa de 1080p HLG10 con JPEG de tamaño máximo y para una vista previa de 720p HLG10 con combinaciones de secuencias de JPEG de tamaño máximo para la cámara trasera principal.

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[7.5/H-1-20] (vista previa del 8 de abril de 2024)

  • [ 7.5 /H-1-20] DEBE generar de forma predeterminada JPEG_R para las cámaras trasera y frontal principal en la aplicación de cámara nativa.

Terminar con nuevos requisitos

2.2.7.3. Hardware

Si las implementaciones de dispositivos portátiles devuelven android.os.Build.VERSION_CODES.U para android.os.Build.VERSION_CODES.MEDIA_PERFORMANCE_CLASS ,:

Comienzan nuevos requisitos para 15 (AOSP experimental)

Actualizaciones de clases de rendimiento multimedia para Android 15 (AOSP experimental) (vista previa del 5 de febrero de 2024)

Si las implementaciones de dispositivos portátiles devuelven android.os.Build.VERSION_CODES.V para android.os.Build.VERSION_CODES.MEDIA_PERFORMANCE_CLASS ,:

Terminar con nuevos requisitos

  • [7.1.1.1/H-2-1] DEBE tener una resolución de pantalla de al menos 1080p.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[7.1.1.3/H-2-1] (vista previa del 5 de febrero de 2024)

  • [7.1.1.3/H-2-1] DEBE tener una densidad de pantalla de al menos 400 ppp si el ancho de la pantalla del dispositivo es <600 ppp .

Terminar con nuevos requisitos

  • [7.1.1.3/H-3-1] DEBE tener una pantalla HDR que admita al menos 1000 nits en promedio.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[7.6.1/H-2-1] (vista previa del 8 de abril de 2024)

Terminar con nuevos requisitos

2.2.7.4. Actuación

Si las implementaciones de dispositivos portátiles devuelven android.os.Build.VERSION_CODES.U para android.os.Build.VERSION_CODES.MEDIA_PERFORMANCE_CLASS ,:

Comienzan nuevos requisitos para 15 (AOSP experimental)

Actualizaciones de clases de rendimiento multimedia para Android 15 (AOSP experimental) (vista previa del 5 de febrero de 2024)

Si las implementaciones de dispositivos portátiles devuelven android.os.Build.VERSION_CODES.V para android.os.Build.VERSION_CODES.MEDIA_PERFORMANCE_CLASS ,:

Terminar con nuevos requisitos

  • [8.2/H-1-1] DEBE garantizar un rendimiento de escritura secuencial de al menos 150 MB/s.
  • [8.2/H-1-2] DEBE garantizar un rendimiento de escritura aleatoria de al menos 10 MB/s.
  • [8.2/H-1-3] DEBE garantizar un rendimiento de lectura secuencial de al menos 250 MB/s.
  • [8.2/H-1-4] DEBE garantizar un rendimiento de lectura aleatoria de al menos 100 MB/s.
  • [8.2/H-1-5] DEBE garantizar un rendimiento de lectura y escritura secuencial paralela con un rendimiento de lectura 2x y escritura 1x de al menos 50 MB/s.

Comienzan nuevos requisitos para 15 (AOSP experimental)

2.2.7.5. Gráficos

[2.2.7.5 Gráficos] (vista previa del 8 de abril de 2024)

Si las implementaciones de dispositivos portátiles devuelven android.os.Build.VERSION_CODES.V para android.os.Build.VERSION_CODES.MEDIA_PERFORMANCE_CLASS ,:

Terminar con nuevos requisitos

[2.2.7.5 Gráficos] (vista previa del 5 de febrero de 2024)
Si las implementaciones de dispositivos portátiles devuelven android.os.Build.VERSION_CODES.V para android.os.Build.VERSION_CODES.MEDIA_PERFORMANCE_CLASS ,:

Terminar con nuevos requisitos

2.3. Requisitos de televisión

Un dispositivo Android Television se refiere a una implementación de dispositivo Android que es una interfaz de entretenimiento para consumir medios digitales, películas, juegos, aplicaciones y/o TV en vivo para usuarios sentados a unos diez pies de distancia (un "usuario reclinado" o "usuario de 10 pies"). interfaz").

Las implementaciones de dispositivos Android se clasifican como Televisión si cumplen con todos los criterios siguientes:

  • Han proporcionado un mecanismo para controlar de forma remota la interfaz de usuario representada en la pantalla que podría estar a tres metros de distancia del usuario.
  • Tener una pantalla integrada con una longitud diagonal superior a 24 pulgadas O incluir un puerto de salida de video, como VGA, HDMI, DisplayPort o un puerto inalámbrico para visualización.

Los requisitos adicionales en el resto de esta sección son específicos de las implementaciones de dispositivos Android Television.

2.3.1. Hardware

Implementaciones de dispositivos de televisión:

  • [ 7.2 .2/T-0-1] DEBE admitir D-pad .
  • [ 7.2 .3/T-0-1] DEBE proporcionar las funciones Inicio y Atrás.
  • [ 7.2 .3/T-0-2] DEBE enviar tanto el evento de pulsación normal como el de pulsación larga de la función Atrás ( KEYCODE_BACK ) a la aplicación de primer plano.
  • [ 7.2 .6.1/T-0-1] DEBE incluir soporte para controladores de juegos y declarar el indicador de función android.hardware.gamepad .
  • [ 7.2.7 /T] DEBE proporcionar un control remoto desde el cual los usuarios puedan acceder a la navegación no táctil y a las entradas de las teclas de navegación principales .

Si las implementaciones de dispositivos de televisión incluyen un giroscopio de 3 ejes, estos:

  • [ 7.3 .4/T-1-1] DEBE poder informar eventos con una frecuencia de al menos 100 Hz.
  • [ 7.3.4 /T-1-2] DEBE ser capaz de medir cambios de orientación de hasta 1000 grados por segundo.

Implementaciones de dispositivos de televisión:

  • [ 7.4 .3/T-0-1] DEBE admitir Bluetooth y Bluetooth LE.
  • [ 7.6 .1/T-0-1] DEBE tener al menos 4 GB de almacenamiento no volátil disponible para los datos privados de la aplicación (también conocida como partición "/data").

Si las implementaciones de dispositivos de televisión incluyen un puerto USB que admite el modo host,:

  • [ 7.5 .3/T-1-1] DEBE incluir soporte para una cámara externa que se conecta a través de este puerto USB pero que no necesariamente está siempre conectada.

Si las implementaciones de dispositivos de TV son de 32 bits:

  • [ 7.6 .1/T-1-1] La memoria disponible para el kernel y el espacio de usuario DEBE ser de al menos 896 MB si se utiliza cualquiera de las siguientes densidades:

    • 400 ppp o más en pantallas pequeñas/normales
    • xhdpi o superior en pantallas grandes
    • tvdpi o superior en pantallas extra grandes

Si las implementaciones de dispositivos de TV son de 64 bits:

  • [ 7.6 .1/T-2-1] La memoria disponible para el kernel y el espacio de usuario DEBE ser de al menos 1280 MB si se utiliza cualquiera de las siguientes densidades:

    • 400 ppp o más en pantallas pequeñas/normales
    • xhdpi o superior en pantallas grandes
    • tvdpi o superior en pantallas extra grandes

Tenga en cuenta que la "memoria disponible para el kernel y el espacio de usuario" anterior se refiere al espacio de memoria proporcionado además de cualquier memoria ya dedicada a componentes de hardware como radio, video, etc. que no están bajo el control del kernel en las implementaciones del dispositivo.

Implementaciones de dispositivos de televisión:

  • [ 7.8 .1/T] DEBE incluir un micrófono.
  • [ 7.8 .2/T-0-1] DEBE tener una salida de audio y declarar android.hardware.audio.output .

2.3.2. Multimedia

Las implementaciones de dispositivos de televisión DEBEN admitir los siguientes formatos de codificación y decodificación de audio y ponerlos a disposición de aplicaciones de terceros:

  • [ 5.1 /T-0-1] Perfil MPEG-4 AAC (AAC LC)
  • [ 5.1 /T-0-2] Perfil MPEG-4 HE AAC (AAC+)
  • [ 5.1 /T-0-3] AAC ELD (AAC de bajo retardo mejorado)

Las implementaciones de dispositivos de televisión DEBEN admitir los siguientes formatos de codificación de video y ponerlos a disposición de aplicaciones de terceros:

  • [ 5.2 /T-0-1] H.264
  • [ 5.2 /T-0-2] VP8
  • [ 5.2 /T-0-3] AV1

Implementaciones de dispositivos de televisión:

  • [ 5.2 .2/T-SR-1] Se RECOMIENDA ENCARECIDAMENTE admitir la codificación H.264 de vídeos con resolución de 720p y 1080p a 30 fotogramas por segundo.

Las implementaciones de dispositivos de televisión DEBEN admitir los siguientes formatos de decodificación de video y ponerlos a disposición de aplicaciones de terceros:

Las implementaciones de dispositivos de televisión DEBEN admitir la decodificación MPEG-2, como se detalla en la Sección 5.3.1, a velocidades de cuadros de video estándar y resoluciones de hasta e incluyendo:

  • [ 5.3.1 /T-1-1] HD 1080p a 29,97 cuadros por segundo con perfil principal de alto nivel.
  • [ 5.3.1 /T-1-2] HD 1080i a 59,94 cuadros por segundo con perfil principal de alto nivel. DEBEN desentrelazar el vídeo MPEG-2 entrelazado y ponerlo a disposición de aplicaciones de terceros.

Las implementaciones de dispositivos de televisión DEBEN admitir la decodificación H.264, como se detalla en la Sección 5.3.4, a velocidades de cuadros de video estándar y resoluciones de hasta e incluyendo:

  • [ 5.3.4 /T-1-1] HD 1080p a 60 cuadros por segundo con Baseline Profile
  • [ 5.3.4 /T-1-2] HD 1080p a 60 fotogramas por segundo con perfil principal
  • [ 5.3.4 /T-1-3] HD 1080p a 60 cuadros por segundo con High Profile Level 4.2

Las implementaciones de dispositivos de televisión con decodificadores de hardware H.265 DEBEN admitir la decodificación H.265, como se detalla en la Sección 5.3.5, a velocidades de cuadros de video estándar y resoluciones de hasta e incluyendo:

  • [ 5.3.5 /T-1-1] HD 1080p a 60 fotogramas por segundo con perfil principal nivel 4.1

Si las implementaciones de dispositivos de televisión con decodificadores de hardware H.265 admiten la decodificación H.265 y el perfil de decodificación UHD,:

  • [ 5.3.5 /T-2-1] DEBE admitir el perfil de decodificación UHD a 60 cuadros por segundo con el perfil Main10 Nivel 5 Main Tier

Las implementaciones de dispositivos de televisión DEBEN admitir la decodificación VP8, como se detalla en la Sección 5.3.6, a velocidades de cuadros de video estándar y resoluciones de hasta e incluyendo:

  • [ 5.3.6 /T-1-1] Perfil de decodificación HD 1080p a 60 fotogramas por segundo

Las implementaciones de dispositivos de televisión con decodificadores de hardware VP9 DEBEN admitir la decodificación VP9, ​​como se detalla en la Sección 5.3.7, a velocidades de cuadros de video estándar y resoluciones de hasta e incluyendo:

  • [ 5.3.7 /T-1-1] HD 1080p a 60 fotogramas por segundo con perfil 0 (profundidad de color de 8 bits)

Si las implementaciones de dispositivos de televisión con decodificadores de hardware VP9 admiten la decodificación VP9 y el perfil de decodificación UHD,:

  • [ 5.3.7 /T-2-1] DEBE admitir el perfil de decodificación UHD a 60 fotogramas por segundo con el perfil 0 (profundidad de color de 8 bits).
  • [ 5.3.7 /T-SR1] Se RECOMIENDA ENCARECIDAMENTE admitir el perfil de decodificación UHD a 60 fotogramas por segundo con el perfil 2 (profundidad de color de 10 bits).

Implementaciones de dispositivos de televisión:

  • [ 5.5 /T-0-1] DEBE incluir soporte para el volumen maestro del sistema y la atenuación del volumen de salida de audio digital en las salidas admitidas, excepto para la salida de paso de audio comprimido (donde no se realiza ninguna decodificación de audio en el dispositivo).

Si las implementaciones de dispositivos de televisión no tienen una pantalla incorporada, pero admiten una pantalla externa conectada a través de HDMI,:

  • [ 5.8 /T-0-1] DEBE configurar el modo de salida HDMI en la resolución más alta para el formato de píxeles elegido que funcione con una frecuencia de actualización de 50 Hz o 60 Hz para la pantalla externa, dependiendo de la frecuencia de actualización de video para la región en la que se vende el dispositivo. en.
  • [ 5.8 /T-SR-1] Se RECOMIENDA ENCARECIDAMENTE proporcionar un selector de frecuencia de actualización HDMI configurable por el usuario.
  • [ 5.8 ] DEBE configurar la frecuencia de actualización del modo de salida HDMI en 50 Hz o 60 Hz, dependiendo de la frecuencia de actualización de video para la región en la que se vende el dispositivo.

Si las implementaciones de dispositivos de televisión no tienen una pantalla incorporada, pero admiten una pantalla externa conectada a través de HDMI,:

  • [ 5.8 /T-1-1] DEBE ser compatible con HDCP 2.2.

Si las implementaciones de dispositivos de televisión no admiten la decodificación UHD, pero admiten una pantalla externa conectada a través de HDMI,:

  • [ 5.8 /T-2-1] DEBE ser compatible con HDCP 1.4

2.3.3. Software

Implementaciones de dispositivos de televisión:

  • [ 3 /T-0-1] DEBE declarar las funciones android.software.leanback y android.hardware.type.television .
  • [ 3.2.3.1 /T-0-1] DEBE precargar una o más aplicaciones o componentes de servicio con un controlador de intenciones, para todos los patrones de filtro de intenciones públicas definidos por las siguientes intenciones de aplicación enumeradas aquí .
  • [ 3.4 .1/T-0-1] DEBE proporcionar una implementación completa de la API android.webkit.Webview .

Si las implementaciones de dispositivos Android Television admiten una pantalla de bloqueo,:

  • [ 3.8 .10/T-1-1] DEBE mostrar las notificaciones de la pantalla de bloqueo, incluida la plantilla de notificación de medios.

Implementaciones de dispositivos de televisión:

  • [ 3.8 .14/T-SR-1] Se RECOMIENDA ENCARECIDAMENTE admitir el modo de ventana múltiple de imagen en imagen (PIP).
  • [ 3.10 /T-0-1] DEBE admitir servicios de accesibilidad de terceros.
  • [ 3.10 /T-SR-1] Se RECOMIENDA ENCARECIDAMENTE precargar servicios de accesibilidad en el dispositivo comparables o superiores a la funcionalidad de los servicios de accesibilidad Switch Access y TalkBack (para idiomas admitidos por el motor de texto a voz preinstalado) según lo dispuesto en el proyecto de código abierto talkback .

Si las implementaciones de dispositivos de televisión informan la función android.hardware.audio.output ,:

  • [ 3.11 /T-SR-1] Se RECOMIENDA ENCARECIDAMENTE incluir un motor TTS que admita los idiomas disponibles en el dispositivo.
  • [ 3.11 /T-1-1] DEBE admitir la instalación de motores TTS de terceros.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[3.12/T-0-1] (vista previa del 26 de febrero de 2024)

Implementaciones de dispositivos de televisión:

  • [ 3.12 /T-0-1] DEBE admitir el marco de entrada de TV.

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[3/T-0-2, 3/T-0-3. 3/T-1-1] (vista previa del 26 de febrero de 2024)

Android Television Input Framework (TIF) simplifica la entrega de contenido en vivo a dispositivos Android Television. TIF proporciona una API estándar para crear módulos de entrada que controlan dispositivos Android Television.

Implementaciones de dispositivos de televisión:

  • [ 3 /T-0-2] DEBE declarar la característica de la plataforma android.software.live_tv .
  • [ 3 /T-0-3] DEBE admitir todas las API TIF, de modo que se pueda instalar y utilizar en el dispositivo una aplicación que utilice estas API y el servicio de entradas de terceros basado en TIF .

Android Television Tuner Framework (TF) [ENLACE TBD para el tercer trimestre de 2024] unifica el manejo de contenido en vivo desde Tuner con contenido de transmisión desde IP en dispositivos Android Television. Turner Framework proporciona una API estándar para crear servicios de entrada que utilizan Android Television Tuner.

Si las implementaciones de dispositivos admiten Tuner,:

  • [ 3 /T-1-1] DEBE admitir todas las API de Tuner Framework, de modo que una aplicación que utilice estas API pueda instalarse y usarse en el dispositivo.

Terminar con nuevos requisitos

2.3.4. Rendimiento y potencia

  • [ 8.1 /T-0-1] Latencia de fotogramas consistente . La latencia de fotogramas inconsistente o un retraso en la renderización de fotogramas NO DEBEN ocurrir con más frecuencia de 5 fotogramas por segundo, y DEBEN ser inferiores a 1 fotograma por segundo.
  • [ 8.2 /T-0-1] DEBE garantizar un rendimiento de escritura secuencial de al menos 5 MB/s.
  • [ 8.2 /T-0-2] DEBE garantizar un rendimiento de escritura aleatoria de al menos 0,5 MB/s.
  • [ 8.2 /T-0-3] DEBE garantizar un rendimiento de lectura secuencial de al menos 15 MB/s.
  • [ 8.2 /T-0-4] DEBE garantizar un rendimiento de lectura aleatoria de al menos 3,5 MB/s.

Si las implementaciones de dispositivos de televisión incluyen funciones para mejorar la administración de energía del dispositivo que se incluyen en AOSP o amplían las funciones que se incluyen en AOSP, estas:

  • [ 8.3 /T-1-1] DEBE proporcionar al usuario la posibilidad de habilitar y deshabilitar la función de ahorro de batería.

Si las implementaciones de dispositivos de televisión no tienen batería:

Si las implementaciones de dispositivos de televisión tienen batería:

  • [ 8.3 /T-1-3] DEBE proporcionar al usuario la posibilidad de mostrar todas las aplicaciones que están exentas de los modos de ahorro de energía App Standby y Doze.

Implementaciones de dispositivos de televisión:

  • [ 8.4 /T-0-1] DEBE proporcionar un perfil de energía por componente que defina el valor de consumo actual para cada componente de hardware y el consumo aproximado de batería causado por los componentes a lo largo del tiempo, como se documenta en el sitio del Proyecto de código abierto de Android.
  • [ 8.4 /T-0-2] DEBE informar todos los valores de consumo de energía en miliamperios hora (mAh).
  • [ 8.4 /T-0-3] DEBE informar el consumo de energía de la CPU por el UID de cada proceso. El proyecto de código abierto de Android cumple con el requisito mediante la implementación del módulo del kernel uid_cputime .
  • [ 8.4 /T] DEBE atribuirse al propio componente de hardware si no se puede atribuir el uso de energía del componente de hardware a una aplicación.
  • [ 8.4 /T-0-4] DEBE hacer que este uso de energía esté disponible a través del comando adb shell dumpsys batterystats shell para el desarrollador de la aplicación.

2.3.5. Modelo de seguridad

Implementaciones de dispositivos de televisión:

  • [9/T-0-1] DEBE declarar la característica android.hardware.security.model.compatible .
  • [ 9.11 /T-0-1] DEBE realizar una copia de seguridad de la implementación del almacén de claves con un entorno de ejecución aislado.
  • [ 9.11 /T-0-2] DEBE tener implementaciones de algoritmos criptográficos RSA, AES, ECDSA y HMAC y funciones hash de las familias MD5, SHA1 y SHA-2 para admitir adecuadamente los algoritmos admitidos del sistema Android Keystore en un área que esté aislada de forma segura. del código que se ejecuta en el kernel y superior. El aislamiento seguro DEBE bloquear todos los mecanismos potenciales mediante los cuales el código del kernel o del espacio de usuario podría acceder al estado interno del entorno aislado, incluido DMA. El Proyecto de código abierto de Android (AOSP) cumple con este requisito mediante el uso de la implementación Trusty , pero otra solución basada en ARM TrustZone o una implementación segura revisada por terceros de un aislamiento adecuado basado en hipervisor son opciones alternativas.
  • [ 9.11 /T-0-3] DEBE realizar la autenticación de la pantalla de bloqueo en el entorno de ejecución aislada y solo cuando tenga éxito, permita que se utilicen las claves vinculadas a la autenticación. Las credenciales de la pantalla de bloqueo DEBEN almacenarse de manera que solo el entorno de ejecución aislado pueda realizar la autenticación de la pantalla de bloqueo. El proyecto de código abierto de Android proporciona la capa de abstracción de hardware Gatekeeper (HAL) y Trusty, que se pueden utilizar para satisfacer este requisito.
  • [ 9.11 /T-0-4] DEBE admitir la atestación de clave donde la clave de firma de la atestación está protegida por hardware seguro y la firma se realiza en hardware seguro. Las claves de firma de certificación DEBEN compartirse entre una cantidad suficiente de dispositivos para evitar que se utilicen como identificadores de dispositivos. Una forma de cumplir este requisito es compartir la misma clave de certificación a menos que se produzcan al menos 100.000 unidades de un SKU determinado. Si se producen más de 100.000 unidades de un SKU, SE PUEDE utilizar una clave diferente por cada 100.000 unidades.

Tenga en cuenta que si la implementación de un dispositivo ya se lanzó en una versión anterior de Android, dicho dispositivo está exento del requisito de tener un almacén de claves respaldado por un entorno de ejecución aislado y admitir la atestación de claves, a menos que declare la característica android.hardware.fingerprint que requiere un almacén de claves respaldado por un entorno de ejecución aislado.

Si las implementaciones de dispositivos de televisión admiten una pantalla de bloqueo segura,:

  • [ 9.11 /T-1-1] DEBE permitir al usuario elegir el tiempo de espera para la transición del estado desbloqueado al estado bloqueado, con un tiempo de espera mínimo permitido de hasta 15 segundos o menos.

Si las implementaciones de dispositivos de televisión incluyen varios usuarios y no declaran la marca de función android.hardware.telephony , estos:

  • [ 9.5 /T-2-1] DEBE admitir perfiles restringidos, una característica que permite a los propietarios de dispositivos administrar usuarios adicionales y sus capacidades en el dispositivo. Con perfiles restringidos, los propietarios de dispositivos pueden configurar rápidamente entornos separados para que trabajen usuarios adicionales, con la capacidad de administrar restricciones más detalladas en las aplicaciones que están disponibles en esos entornos.

Si las implementaciones de dispositivos de televisión incluyen varios usuarios y declaran la marca de función android.hardware.telephony , estos:

  • [ 9.5 /T-3-1] NO DEBE admitir perfiles restringidos, pero DEBE alinearse con la implementación de controles de AOSP para permitir/deshabilitar el acceso de otros usuarios a las llamadas de voz y SMS.

Si las implementaciones de dispositivos de televisión declaran android.hardware.microphone ,:

  • [ 9.8.2 /T-4-1] DEBE mostrar el indicador del micrófono cuando una aplicación accede a datos de audio desde el micrófono, pero no cuando al micrófono solo accede HotwordDetectionService, SOURCE_HOTWORD, ContentCaptureService o aplicaciones que desempeñan los roles mencionados en Sección 9.1 Permisos con identificador CDD C-3-X].
  • [ 9.8.2 /T-4-2] No DEBE ocultar el indicador del micrófono para aplicaciones del sistema que tienen interfaces de usuario visibles o interacción directa con el usuario.

Si las implementaciones de dispositivos de televisión declaran android.hardware.camera.any ,:

  • [ 9.8.2 /T-5-1] DEBE mostrar el indicador de la cámara cuando una aplicación accede a los datos de la cámara en vivo, pero no cuando solo acceden a la cámara las aplicaciones que desempeñan las funciones mencionadas en la Sección 9.1 Permisos con CDD identificador [C-3-X].
  • [ 9.8.2 /T-5-2] No DEBE ocultar el indicador de la cámara para aplicaciones del sistema que tienen interfaces de usuario visibles o interacción directa con el usuario.

2.3.6. Compatibilidad de opciones y herramientas de desarrollador

Implementaciones de dispositivos de televisión:

2.4. Requisitos del reloj

Un dispositivo Android Watch se refiere a una implementación de dispositivo Android destinada a usarse en el cuerpo, tal vez en la muñeca.

Las implementaciones de dispositivos Android se clasifican como Watch si cumplen con todos los criterios siguientes:

  • Tener una pantalla con una longitud diagonal física en el rango de 1,1 a 2,5 pulgadas.
  • Disponer de un mecanismo para llevar en el cuerpo.

Los requisitos adicionales en el resto de esta sección son específicos de las implementaciones de dispositivos Android Watch.

2.4.1. Hardware

Ver implementaciones de dispositivos:

  • [ 7.1 .1.1/W-0-1] DEBE tener una pantalla con un tamaño diagonal físico en el rango de 1,1 a 2,5 pulgadas.

  • [ 7.2 .3/W-0-1] DEBE tener la función Inicio disponible para el usuario y la función Atrás excepto cuando está en UI_MODE_TYPE_WATCH .

  • [ 7.2 .4/W-0-1] DEBE admitir la entrada de pantalla táctil.

  • [ 7.3 .1/W-SR-1] Se RECOMIENDA ENCARECIDAMENTE incluir un acelerómetro de 3 ejes.

Si las implementaciones de dispositivos Watch incluyen un receptor GPS/GNSS e informan la capacidad a las aplicaciones a través del indicador de función android.hardware.location.gps , estas:

  • [ 7.3 .3/W-1-1] DEBE informar las mediciones GNSS tan pronto como se encuentren, incluso si aún no se informa una ubicación calculada a partir de GPS/GNSS.
  • [ 7.3 .3/W-1-2 ] DEBE informar los pseudodistancias y velocidades de pseudodistancia GNSS que, en condiciones de cielo abierto después de determinar la ubicación, mientras está estacionario o en movimiento con menos de 0,2 metros por segundo al cuadrado de aceleración, sean suficientes para calcular posición dentro de los 20 metros y velocidad dentro de los 0,2 metros por segundo, al menos el 95% del tiempo.

Si las implementaciones del dispositivo Watch incluyen un giroscopio de 3 ejes,:

  • [ 7.3.4 /W-2-1] DEBE ser capaz de medir cambios de orientación de hasta 1000 grados por segundo.

Ver implementaciones de dispositivos:

  • [ 7.4 .3/W-0-1] DEBE ser compatible con Bluetooth.

  • [ 7.6 .1/W-0-1] DEBE tener al menos 1 GB de almacenamiento no volátil disponible para los datos privados de la aplicación (también conocida como partición "/data").

  • [ 7.6 .1/W-0-2] DEBE tener al menos 416 MB de memoria disponible para el kernel y el espacio de usuario.

  • [ 7.8 .1/W-0-1] DEBE incluir un micrófono.

  • [ 7.8.2 /W] PUEDE tener salida de audio.

2.4.2. Multimedia

Sin requisitos adicionales.

2.4.3. Software

Ver implementaciones de dispositivos:

  • [ 3 /W-0-1] DEBE declarar la característica android.hardware.type.watch .
  • [ 3 /W-0-2] DEBE admitir uiMode = UI_MODE_TYPE_WATCH .
  • [ 3.2.3.1 /W-0-1] DEBE precargar una o más aplicaciones o componentes de servicio con un controlador de intenciones, para todos los patrones de filtro de intenciones públicas definidos por las siguientes intenciones de aplicación enumeradas aquí .

Ver implementaciones de dispositivos:

  • [ 3.8 .4/W-SR-1] Se RECOMIENDA ENCARECIDAMENTE implementar un asistente en el dispositivo para manejar la acción de asistencia .

Observe las implementaciones de dispositivos que declaran el indicador de función android.hardware.audio.output :

  • [ 3.10 /W-1-1] DEBE admitir servicios de accesibilidad de terceros.
  • [ 3.10 /W-SR-1] Se RECOMIENDA ENCARECIDAMENTE precargar servicios de accesibilidad en el dispositivo comparables o superiores a la funcionalidad de los servicios de accesibilidad Switch Access y TalkBack (para idiomas admitidos por el motor de texto a voz preinstalado) según lo dispuesto en el proyecto de código abierto talkback .

Si las implementaciones de dispositivos Watch informan la función android.hardware.audio.output,:

  • [ 3.11 /W-SR-1] Se RECOMIENDA ENCARECIDAMENTE incluir un motor TTS que admita los idiomas disponibles en el dispositivo.

  • [ 3.11 /W-0-1] DEBE admitir la instalación de motores TTS de terceros.

2.4.4. Rendimiento y potencia

Si las implementaciones de dispositivos Watch incluyen funciones para mejorar la administración de energía del dispositivo que se incluyen en AOSP o amplían las funciones que se incluyen en AOSP, estas:

  • [ 8.3 /W-SR-1] Se RECOMIENDA ENCARECIDAMENTE brindar al usuario la posibilidad de mostrar todas las aplicaciones que están exentas de los modos de ahorro de energía App Standby y Doze.
  • [ 8.3 /W-SR-2] Se RECOMIENDA ENCARECIDAMENTE brindar al usuario la posibilidad de habilitar y deshabilitar la función de ahorro de batería.

Ver implementaciones de dispositivos:

  • [ 8.4 /W-0-1] DEBE proporcionar un perfil de energía por componente que defina el valor de consumo actual para cada componente de hardware y el consumo aproximado de batería causado por los componentes a lo largo del tiempo, como se documenta en el sitio del Proyecto de código abierto de Android.
  • [ 8.4 /W-0-2] DEBE informar todos los valores de consumo de energía en miliamperios hora (mAh).
  • [ 8.4 /W-0-3] DEBE informar el consumo de energía de la CPU por el UID de cada proceso. El proyecto de código abierto de Android cumple con el requisito mediante la implementación del módulo del kernel uid_cputime .
  • [ 8.4 /W-0-4] DEBE hacer que este uso de energía esté disponible a través del comando adb shell dumpsys batterystats shell para el desarrollador de la aplicación.
  • [ 8.4 /W] DEBE atribuirse al propio componente de hardware si no se puede atribuir el uso de energía del componente de hardware a una aplicación.

2.4.5. Modelo de seguridad

Ver implementaciones de dispositivos:

  • [9/W-0-1] DEBE declarar la característica android.hardware.security.model.compatible .

Si las implementaciones de dispositivos Watch incluyen varios usuarios y no declaran el indicador de función android.hardware.telephony , estos:

  • [ 9.5 /W-1-1] DEBE admitir perfiles restringidos, una característica que permite a los propietarios de dispositivos administrar usuarios adicionales y sus capacidades en el dispositivo. Con perfiles restringidos, los propietarios de dispositivos pueden configurar rápidamente entornos separados para que trabajen usuarios adicionales, con la capacidad de administrar restricciones más detalladas en las aplicaciones que están disponibles en esos entornos.

Si las implementaciones de dispositivos Watch incluyen varios usuarios y declaran la marca de función android.hardware.telephony , estos:

  • [ 9.5 /W-2-1] NO DEBE admitir perfiles restringidos, pero DEBE alinearse con la implementación de controles de AOSP para permitir o deshabilitar el acceso de otros usuarios a las llamadas de voz y SMS.

Si las implementaciones de dispositivos tienen una pantalla de bloqueo segura e incluyen uno o más agentes de confianza, que implementan la API del sistema TrustAgentService , ellos:

  • [ 9.11.1 /W-1-1] DEBE solicitar al usuario uno de los métodos de autenticación principales recomendados (por ejemplo, PIN, patrón, contraseña) con más frecuencia que una vez cada 72 horas.

2.5. Requisitos automotrices

La implementación de Android Automotive se refiere a la unidad principal de un vehículo que ejecuta Android como sistema operativo para parte o la totalidad del sistema y/o la funcionalidad de infoentretenimiento.

Las implementaciones de dispositivos Android se clasifican como automotrices si declaran la característica android.hardware.type.automotive o cumplen con todos los criterios siguientes.

  • Están integrados como parte de un vehículo automotor o se pueden conectar a él.
  • Están utilizando una pantalla en la fila del asiento del conductor como pantalla principal.

Los requisitos adicionales en el resto de esta sección son específicos de las implementaciones de dispositivos Android Automotive.

2.5.1. Hardware

Implementaciones de dispositivos automotrices:

  • [ 7.1 .1.1/A-0-1] DEBE tener una pantalla de al menos 6 pulgadas de tamaño diagonal físico.
  • [ 7.1 .1.1/A-0-2] DEBE tener un diseño de tamaño de pantalla de al menos 750 dp x 480 dp.
  • [ 7.2 .3/A-0-1] DEBE proporcionar la función Inicio y PUEDE proporcionar funciones Atrás y Recientes.
  • [ 7.2 .3/A-0-2] DEBE enviar tanto el evento de pulsación normal como el de pulsación larga de la función Atrás ( KEYCODE_BACK ) a la aplicación de primer plano.
  • [ 7.3 /A-0-1] DEBE implementar e informar GEAR_SELECTION , NIGHT_MODE , PERF_VEHICLE_SPEED y PARKING_BRAKE_ON .
  • [ 7.3 /A-0-2] El valor del indicador NIGHT_MODE DEBE ser consistente con el modo día/noche del tablero y DEBE basarse en la entrada del sensor de luz ambiental. El sensor de luz ambiental subyacente PUEDE ser el mismo que el fotómetro .
  • [ 7.3 /A-0-3] DEBE proporcionar el campo de información adicional del sensor TYPE_SENSOR_PLACEMENT como parte de SensorAdditionalInfo para cada sensor proporcionado.
  • [ 7.3 /A-SR1] PUEDE ubicación por estima fusionando GPS/GNSS con sensores adicionales. Si la ubicación se considera predeterminada, se RECOMIENDA ENCARECIDAMENTE implementar e informar los tipos de sensores correspondientes y/o las identificaciones de propiedad del vehículo utilizadas.
  • [ 7.3 /A-0-4] La ubicación solicitada a través de LocationManager#requestLocationUpdates() NO DEBE coincidir con el mapa.

  • [ 7.3 .1/A-0-4] DEBE cumplir con el sistema de coordenadas del sensor del automóvil de Android.

  • [ 7.3 /A-SR-1] Se RECOMIENDA ENCARECIDAMENTE incluir un acelerómetro de 3 ejes y un giroscopio de 3 ejes.

  • [ 7.3 /A-SR-2] Está MUY_RECOMENDADO implementar e informar el sensor TYPE_HEADING .

Si las implementaciones de dispositivos automotrices son compatibles con OpenGL ES 3.1,:

  • [ 7.1 .4.1/A-0-1] DEBE declarar OpenGL ES 3.1 o superior.
  • [ 7.1 .4.1/A-0-2] DEBE ser compatible con Vulkan 1.1.
  • [ 7.1 .4.1/A-0-3] DEBE incluir el cargador Vulkan y exportar todos los símbolos.

Si las implementaciones de dispositivos automotrices incluyen un acelerómetro,:

  • [ 7.3 .1/A-1-1] DEBE poder informar eventos con una frecuencia de al menos 100 Hz.

Si las implementaciones de dispositivos incluyen un acelerómetro de 3 ejes,:

  • [ 7.3 .1/A-SR-1] Se RECOMIENDA ENCARECIDAMENTE implementar el sensor compuesto para acelerómetro de ejes limitados.

Si las implementaciones de dispositivos automotrices incluyen un acelerómetro con menos de 3 ejes, estos:

  • [ 7.3 .1/A-1-3] DEBE implementar e informar el sensor TYPE_ACCELEROMETER_LIMITED_AXES .
  • [ 7.3.1 /A-1-4] DEBE implementar e informar el sensor TYPE_ACCELEROMETER_LIMITED_AXES_UNCALIBRATED .

Si las implementaciones de dispositivos automotrices incluyen un giroscopio,:

  • [ 7.3 .4/A-2-1] DEBE poder informar eventos con una frecuencia de al menos 100 Hz.
  • [ 7.3.4 /A-2-3] DEBE ser capaz de medir cambios de orientación de hasta 250 grados por segundo.
  • [ 7.3 .4/A-SR-1] Se RECOMIENDA ENCARECIDAMENTE configurar el rango de medición del giroscopio en +/-250 dps para maximizar la resolución posible.

Si las implementaciones de dispositivos automotrices incluyen un giroscopio de 3 ejes,:

  • [ 7.3 .4/A-SR-2] Se RECOMIENDA ENCARECIDAMENTE implementar el sensor compuesto para giroscopio de ejes limitados.

Si las implementaciones de dispositivos automotrices incluyen un giroscopio con menos de 3 ejes, estos:

  • [ 7.3.4 /A-4-1] DEBE implementar e informar el sensor TYPE_GYROSCOPE_LIMITED_AXES .
  • [ 7.3.4 /A-4-2] DEBE implementar e informar el sensor TYPE_GYROSCOPE_LIMITED_AXES_UNCALIBRATED .

Si las implementaciones de dispositivos automotrices incluyen un receptor GPS/GNSS, pero no incluyen conectividad de datos basada en red celular,:

  • [ 7.3 .3/A-3-1] DEBE determinar la ubicación la primera vez que se enciende el receptor GPS/GNSS o después de más de 4 días dentro de 60 segundos.
  • [ 7.3 .3/A-3-2] DEBE cumplir con los criterios de tiempo para la primera localización como se describe en 7.3.3/C-1-2 y 7.3.3/C-1-6 para todas las demás solicitudes de ubicación ( es decir, solicitudes que no son la primera vez o después de más de 4 días). El requisito 7.3.3/C-1-2 normalmente se cumple en vehículos sin conectividad de datos basada en red celular, mediante el uso de predicciones de órbita GNSS calculadas en el receptor, o utilizando la última ubicación conocida del vehículo junto con la capacidad de estimar al menos al menos 60 segundos con una precisión de posición que satisfaga 7.3.3/C-1-3 , o una combinación de ambos.

Si las implementaciones de dispositivos automotrices incluyen un sensor TYPE_HEADING ,:

  • [ 7.3 .4/A-4-3] DEBE poder informar eventos con una frecuencia de al menos 1 Hz.
  • [ 7.3 .4/A-SR-3] MUY RECOMENDADO informar eventos con una frecuencia de al menos 10 Hz.
  • DEBE estar en referencia al norte verdadero.
  • DEBE estar disponible incluso cuando el vehículo esté quieto.
  • DEBE tener una resolución de al menos 1 grado.

Implementaciones de dispositivos automotrices:

  • [ 7.4 .3/A-0-1] DEBE admitir Bluetooth y DEBE admitir Bluetooth LE.
  • [ 7.4 .3/A-0-2] Las implementaciones de Android Automotive DEBEN admitir los siguientes perfiles de Bluetooth:
    • Llamadas telefónicas a través del perfil manos libres (HFP).
    • Reproducción de medios a través del perfil de distribución de audio (A2DP).
    • Control de reproducción multimedia a través del perfil de control remoto (AVRCP).
    • Compartir contactos mediante el perfil de acceso a la agenda telefónica (PBAP).
  • [ 7.4 .3/A-SR-1] Se RECOMIENDA ENCARECIDAMENTE admitir el perfil de acceso a mensajes (MAP).

  • [ 7.4.5 /A] DEBE incluir soporte para conectividad de datos basada en redes celulares.

  • [ 7.4.5 /A] PUEDE usar la constante API del sistema NetworkCapabilities#NET_CAPABILITY_OEM_PAID para redes que deberían estar disponibles para las aplicaciones del sistema.

Si las implementaciones de dispositivos incluyen soporte para transmisiones de radio AM/FM y exponen la funcionalidad a cualquier aplicación, estas:

  • [ 7.4 /A-0-1] DEBE declarar soporte para FEATURE_BROADCAST_RADIO .

Una cámara orientada hacia atrás significa una cámara orientada hacia el mundo que puede ubicarse en cualquier lugar del vehículo y está orientada hacia el exterior de la cabina del vehículo; es decir, capta escenas en el lado más alejado de la carrocería del vehículo, como la cámara de visión trasera.

Una cámara frontal significa una cámara orientada al usuario que puede ubicarse en cualquier lugar del vehículo y está orientada hacia el interior de la cabina del vehículo; es decir, imágenes del usuario, como para videoconferencias y aplicaciones similares.

Implementaciones de dispositivos automotrices:

  • [7.5/A-SR-1] Se RECOMIENDA ENCARECIDAMENTE incluir una o más cámaras orientadas al mundo.
  • PUEDE incluir una o más cámaras orientadas al usuario.
  • [7.5/A-SR-2] Se RECOMIENDAN ENCARECIDAMENTE para admitir la transmisión simultánea de varias cámaras.

Si las implementaciones de dispositivos automotrices incluyen al menos una cámara orientada al mundo, entonces, para dicha cámara:

  • [7.5/A-1-1] DEBE orientarse de modo que la dimensión larga de la cámara se alinee con el plano XY de los ejes de los sensores automotrices de Android.
  • [7.5/A-SR-3] Se RECOMIENDA ENCARECIDAMENTE tener hardware de enfoque fijo o EDOF (profundidad de campo extendida).
  • [7.5/A-1-2] DEBE tener la cámara principal orientada al mundo como la cámara orientada al mundo con el ID de cámara más bajo.

Si las implementaciones de dispositivos automotrices incluyen al menos una cámara que está orientada al usuario, entonces para dicha cámara:

  • [7.5/A-2-1] La cámara principal orientada al usuario debe ser la cámara orientada al usuario con la ID de cámara más baja.
  • Puede orientarse para que la dimensión larga de la cámara se alinee con el plano XY de los ejes del sensor automotriz de Android.

Si las implementaciones de dispositivos automotrices incluyen una cámara a la que se puede acceder a través de android.hardware.Camera o android.hardware.camera2 API, entonces ellos:

  • [7.5/A-3-1] debe cumplir con los requisitos de la cámara central en la Sección 7.5.

Si las implementaciones de dispositivos automotrices incluyen una cámara a la que no se puede acceder a través de android.hardware.Camera o android.hardware.camera2 API, entonces ellos:

  • [7.5/A-4-1] debe ser accesible a través del servicio del sistema de vista extendida.

Si las implementaciones de dispositivos automotrices incluyen una o más cámaras accesibles a través del servicio del sistema de vista extendida, para dicha cámara, ellos:

  • [7.5/A-5-1] no debe girar ni reflejar horizontalmente la vista previa de la cámara.
  • [7.5/A-SR-4] se recomienda encarecidamente tener una resolución de al menos 1.3 megapíxeles.

Si las implementaciones de dispositivos automotrices incluyen una o más cámaras a las que se puede acceder a través del servicio del sistema de vista extendida y android.hardware.Camera o android.hardware.Camera2 API Entonces, para dicha cámara, ellos:

  • [7.5/A-6-1] debe informar la misma identificación de la cámara.

Si las implementaciones de dispositivos automotrices proporcionan una API de cámara patentada, ellos:

  • [7.5/A-7-1] debe implementar dicha API de la cámara con android.hardware.camera2 API o API del sistema de vista extendida.

Implementaciones de dispositivos automotrices:

  • [ 7.6 .1/A-0-1] debe tener al menos 4 GB de almacenamiento no volátil disponible para la aplicación de datos privados (también conocido como partición "/datos").

  • [ 7.6 .1/A] debe formatear la partición de datos para ofrecer un rendimiento mejorado y la longevidad en el almacenamiento flash, por ejemplo, utilizando el sistema de archivos f2fs .

Si las implementaciones de dispositivos automotrices proporcionan almacenamiento externo compartido a través de una parte del almacenamiento interno no removible, ellos:

  • [ 7.6 .1/A-SR-1] se recomiendan encarecidamente para reducir la sobrecarga de E/S en las operaciones realizadas en el almacenamiento externo, por ejemplo, utilizando SDCardFS .

Si las implementaciones de dispositivos automotrices son de 64 bits:

  • [ 7.6 .1/A-2-1] La memoria disponible para el kernel y el espacio de usuario debe tener al menos 816 MB si se usa alguna de las siguientes densidades:

    • 280 dpi o más bajo en pantallas pequeñas/normales
    • LDPI o más bajo en pantallas extra grandes
    • MDPI o más bajo en pantallas grandes
  • [ 7.6 .1/A-2-2] La memoria disponible para el kernel y el espacio de usuario debe tener al menos 944 MB si se usa alguna de las siguientes densidades:

    • XHDPI o superior en pantallas pequeñas/normales
    • HDPI o superior en pantallas grandes
    • MDPI o superior en pantallas extra grandes
  • [ 7.6 .1/a-2-3] La memoria disponible para el núcleo y el espacio de usuario debe tener al menos 1280 MB si se usa alguna de las siguientes densidades:

    • 400dpi o más en pantallas pequeñas/normales
    • XHDPI o superior en pantallas grandes
    • TVDPI o superior en pantallas extra grandes
  • [ 7.6 .1/a-2-4] La memoria disponible para el núcleo y el espacio de usuario debe ser de al menos 1824 MB si se usa alguna de las siguientes densidades:

    • 560dpi o más en pantallas pequeñas/normales
    • 400 ppi o más en pantallas grandes
    • XHDPI o superior en pantallas extra grandes

Tenga en cuenta que la "memoria disponible para el kernel y el espacio de usuario" anterior se refiere al espacio de memoria proporcionado además de cualquier memoria ya dedicada a componentes de hardware como radio, video, etc. que no están bajo el control del kernel en las implementaciones del dispositivo.

Implementaciones de dispositivos automotrices:

  • [ 7.7 .1/a] debe incluir un puerto USB que admite el modo periférico.

Implementaciones de dispositivos automotrices:

  • [ 7.8 .1/A-0-1] debe incluir un micrófono.

Implementaciones de dispositivos automotrices:

  • [ 7.8 .2/A-0-1] debe tener una salida de audio y declarar android.hardware.audio.output .

2.5.2. Multimedia

Las implementaciones de dispositivos automotrices deben admitir los siguientes formatos de codificación y decodificación de audio y hacerlas a disposición de aplicaciones de terceros:

  • [ 5.1 /A-0-1] Perfil MPEG-4 AAC (AAC LC)
  • [ 5.1 /A-0-2] MPEG-4 He AAC Perfil (AAC+)
  • [ 5.1 /A-0-3] AAC ELD (AAC de baja retraso mejorado)

Las implementaciones de dispositivos automotrices deben admitir los siguientes formatos de codificación de video y ponerlos a disposición de aplicaciones de terceros:

  • [ 5.2 /A-0-1] H.264 AVC
  • [ 5.2 /A-0-2] VP8

Las implementaciones de dispositivos automotrices deben admitir los siguientes formatos de decodificación de video y ponerlos a disposición de aplicaciones de terceros:

  • [ 5.3 /A-0-1] H.264 AVC
  • [ 5.3 /A-0-2] MPEG-4 SP
  • [ 5.3 /A-0-3] VP8
  • [ 5.3 /A-0-4] VP9

Se recomiendan las implementaciones de dispositivos automotrices para admitir la siguiente decodificación de video:

  • [ 5.3 /A-SR-1] H.265 HEVC

2.5.3. Software

Implementaciones de dispositivos automotrices:

  • [ 3 /A-0-1] debe declarar la función android.hardware.type.automotive .

  • [ 3 /a-0-2] debe admitir uiMode = UI_MODE_TYPE_CAR .

  • [ 3 /A-0-3] Debe admitir todas las API públicas en el espacio de nombres android.car.*

Comienzan nuevos requisitos para 15 (AOSP experimental)

[3/A-0-4] [retirado] (8 de abril de 2024 Vista previa)
Este requisito se retira de Android 15 (AOSP experimental).

Terminar con nuevos requisitos

[3/A-0-4] (Vista previa del 11 de diciembre de 2023)

  • [ 3 /A-0-4] debe admitir la aplicación Adapt para las pantallas de automóviles.

Terminar con nuevos requisitos

Si las implementaciones de dispositivos automotrices proporcionan una API patentada utilizando android.car.CarPropertyManager con android.car.VehiclePropertyIds , ellos:

  • [ 3 /A-1-1] no debe adjuntar privilegios especiales al uso de estas propiedades de System Application, ni evitar que las aplicaciones de terceros usen estas propiedades.
  • [ 3 /A-1-2] no debe replicar una propiedad del vehículo que ya existe en el SDK .

Implementaciones de dispositivos automotrices:

  • [ 3.2 .1/A-0-1] debe apoyar y hacer cumplir todas las constantes de permisos según lo documente por la página de referencia de permiso automotriz .

  • [ 3.2.3.1 /a-0-1] debe precargar una o más aplicaciones o componentes de servicio con un controlador de intención, para todos los patrones de filtro de intención pública definidos por los siguientes intentos de aplicación enumerados aquí .

  • [ 3.4 .1/A-0-1] debe proporcionar una implementación completa de la API android.webkit.Webview .

  • [ 3.8 /A-0-1] no debe permitir que los usuarios secundarios completos que no son el usuario actual de primer plano inicien actividades y tengan acceso a la interfaz de usuario en cualquier pantalla.

  • [ 3.8 .3/A-0-1] debe mostrar notificaciones que usan la API Notification.CarExtender .

  • [ 3.8 .4/A-SR-1] se recomienda encarecidamente implementar un asistente en el dispositivo para manejar la acción de asistencia .

Si las implementaciones de dispositivos automotrices incluyen un botón Push-to Talk, ellos:

  • [ 3.8 .4/A-1-1] Debe usar una breve presión del botón Push-to-Talk como la interacción designada para iniciar la aplicación de asistencia seleccionada por el usuario, en otras palabras, la aplicación que implementa VoiceInteractionService .

Implementaciones de dispositivos automotrices:

  • [ 3.8.3.1 /a-0-1] debe representar correctamente los recursos como se describe en las Notifications on Automotive OS .
  • [ 3.8.3.1 /a-0-2] debe mostrar el juego y silenciar las acciones de notificación en el lugar de las proporcionadas a través de Notification.Builder.addAction()
  • [ 3.8.3.1 /a] debe restringir el uso de tareas de gestión ricas, como los controles de canal por notificación. Puede usar la intervención de la interfaz de usuario por aplicación para reducir los controles.

Si las implementaciones de dispositivos automotrices admiten las propiedades de usuario del usuario, ellos:

Implementaciones de dispositivos automotrices:

Si las implementaciones de dispositivos automotrices incluyen una aplicación de lanzador predeterminada, ellos:

Implementaciones de dispositivos automotrices:

Comienzan nuevos requisitos para 15 (AOSP experimental)

[3.14/A-0-8] (8 de abril de 2024 Vista previa)

Terminar con nuevos requisitos

  • [ 3.8 /a] puede restringir las solicitudes de aplicación para ingresar un modo de pantalla completa como se describe en immersive documentation .
  • [ 3.8 /a] puede mantener la barra de estado y la barra de navegación visible en todo momento.
  • [ 3.8 /a] puede restringir las solicitudes de aplicación para cambiar los colores detrás de los elementos de interfaz de usuario del sistema, para garantizar que esos elementos sean claramente visibles en todo momento.

2.5.4. Rendimiento y potencia

Implementaciones de dispositivos automotrices:

  • [ 8.2 /A-0-1] debe informar el número de bytes leídos y escritos en el almacenamiento no volátil según el UID de cada proceso para que las estadísticas estén disponibles para los desarrolladores a través de la API del sistema android.car.storagemonitoring.CarStorageMonitoringManager . El proyecto de código abierto de Android cumple con el requisito a través del módulo de núcleo uid_sys_stats .
  • [ 8.3 /A-1-3] debe admitir el modo de garaje .
  • [ 8.3 /a] debe estar en modo de garaje durante al menos 15 minutos después de cada unidad a menos que:
    • La batería está drenada.
    • No se programan trabajos inactivos.
    • El controlador sale del modo de garaje.
  • [ 8.4 /A-0-1] debe proporcionar un perfil de potencia por componente que define el valor de consumo actual para cada componente de hardware y el drenaje de la batería aproximado causado por los componentes con el tiempo como se documenta en el sitio del proyecto de código abierto de Android.
  • [ 8.4 /A-0-2] debe informar todos los valores de consumo de energía en las horas miliámicas (MAH).
  • [ 8.4 /A-0-3] debe informar el consumo de energía de la CPU según el UID de cada proceso. El proyecto de código abierto de Android cumple con el requisito mediante la implementación del módulo del kernel uid_cputime .
  • [ 8.4 /a] debe atribuirse al componente de hardware en sí mismo si no puede atribuir el uso del componente de hardware a una aplicación.
  • [ 8.4 /A-0-4] debe hacer que este uso de energía esté disponible a través del comando adb shell dumpsys batterystats Shell para el desarrollador de aplicaciones.

2.5.5. Modelo de seguridad

Si las implementaciones de dispositivos automotrices admiten múltiples usuarios, ellos:

Si las implementaciones de dispositivos automotrices declaran android.hardware.microphone , ellos:

  • [ 9.8.2 /a-1-1] debe mostrar el indicador del micrófono cuando una aplicación accede a los datos de audio desde el micrófono, pero no cuando el micrófono solo se accede por HotwordDetectionService , SOURCE_HOTWORD , ContentCaptureService o aplicaciones que contienen los roles que se califican en la sección 9.1 con identificador CDD [C-4-X].
  • [ 9.8.2 /a-1-2] no debe ocultar el indicador de micrófono para aplicaciones del sistema que tienen interfaces de usuario visibles o interacción directa del usuario.
  • [ 9.8.2 /a-1-3] debe proporcionar una posibilidad del usuario para alternar el micrófono en la aplicación Configuración.

Si las implementaciones de dispositivos automotrices declaran android.hardware.camera.any , entonces ellos:

  • [ 9.8.2 /A-2-1] debe mostrar el indicador de la cámara cuando una aplicación accede a los datos de la cámara en vivo, pero no cuando la cámara solo se accede por aplicaciones que contienen los roles como se define en la Sección 9.1 con CDD Identificador [C-4-X].
  • [ 9.8.2 /A-2-2] no debe ocultar el indicador de la cámara para aplicaciones del sistema que tienen interfaces de usuario visibles o interacción directa del usuario.
  • [ 9.8.2 /a-2-3] debe proporcionar una posibilidad del usuario para alternar la cámara en la aplicación Configuración.
  • [ 9.8.2 /a-2-4] debe mostrar aplicaciones recientes y activas que usan la cámara que se devuelve de PermissionManager.getIndicatorAppOpUsageData() , junto con cualquier mensaje de atribución asociado con ellos.

Implementaciones de dispositivos automotrices:

  • [9/A-0-1] debe declarar el android.hardware.security.model.compatible Function Patible.
  • [ 9.11 /A-0-1] debe hacer una copia de seguridad de la implementación del almacén de claves con un entorno de ejecución aislado.
  • [ 9.11 /a-0-2] debe tener implementaciones de algoritmos criptográficos y HMAC criptográficos y MD5, SHA1 y SHA-2 FAMILLA HASHMA para apoyar adecuadamente los algoritmos compatibles con el sistema de claves Android en un área que está aislada de forma segura desde el código que se ejecuta en el núcleo y superior. El aislamiento seguro DEBE bloquear todos los mecanismos potenciales mediante los cuales el código del kernel o del espacio de usuario podría acceder al estado interno del entorno aislado, incluido DMA. El Proyecto de código abierto de Android (AOSP) cumple con este requisito mediante el uso de la implementación Trusty , pero otra solución basada en ARM TrustZone o una implementación segura revisada por terceros de un aislamiento adecuado basado en hipervisor son opciones alternativas.
  • [ 9.11 /A-0-3] debe realizar la autenticación de la pantalla de bloqueo en el entorno de ejecución aislado y solo cuando exista, permita que se usen las claves unidas a la autenticación. Las credenciales de la pantalla de bloqueo DEBEN almacenarse de manera que solo el entorno de ejecución aislado pueda realizar la autenticación de la pantalla de bloqueo. El proyecto de código abierto de Android proporciona la capa de abstracción de hardware Gatekeeper (HAL) y Trusty, que se pueden utilizar para satisfacer este requisito.
  • [ 9.11 /A-0-4] debe admitir la certificación de la clave donde la clave de firma de certificación está protegida por hardware seguro y la firma se realiza en hardware seguro. Las claves de firma de certificación DEBEN compartirse entre una cantidad suficiente de dispositivos para evitar que se utilicen como identificadores de dispositivos. Una forma de cumplir este requisito es compartir la misma clave de certificación a menos que se produzcan al menos 100.000 unidades de un SKU determinado. Si se producen más de 100.000 unidades de un SKU, SE PUEDE utilizar una clave diferente por cada 100.000 unidades.

Tenga en cuenta que si la implementación de un dispositivo ya se lanzó en una versión anterior de Android, dicho dispositivo está exento del requisito de tener un almacén de claves respaldado por un entorno de ejecución aislado y admitir la atestación de claves, a menos que declare la característica android.hardware.fingerprint que requiere un almacén de claves respaldado por un entorno de ejecución aislado.

Implementaciones de dispositivos automotrices:

  • [ 9.14 /A-0-1] Debe hacer mensajes de Gatekeep de Android Framework Vehicle Subsistems, por ejemplo, la lista de mensajes permitidos y las fuentes de mensajes permitidos.
  • [ 9.14 /A-0-2] debe vigilar los ataques de denegación de servicios del marco de Android o aplicaciones de terceros. Esto protege contra el software malicioso que inundan la red de vehículos con tráfico, lo que puede conducir a los subsistemas de vehículos que no funcionan mal.

2.5.6. Compatibilidad de opciones y herramientas de desarrollador

Implementaciones de dispositivos automotrices:

2.6. Requisitos de tableta

Un dispositivo de tableta Android se refiere a una implementación de dispositivos Android que generalmente cumple con los siguientes criterios:

  • Utilizado por sosteniendo en ambas manos.
  • No tiene una cala o configuración convertible.
  • Implementaciones físicas de teclado utilizadas con el dispositivo Connect por medio de una conexión estándar (por ejemplo, USB, Bluetooth).
  • Tiene una fuente de energía que proporciona movilidad, como una batería.

  • Tiene un tamaño de pantalla de pantalla mayor de 7 "y menos de 18", medido en diagonal.

Las implementaciones de dispositivos de tabletas tienen requisitos similares a las implementaciones de dispositivos portátiles. Las excepciones están indicadas por un * en esa sección y se observan como referencia en esta sección.

2.6.1. Hardware

Giroscopio

Si las implementaciones de la tableta incluyen un giroscopio de 3 ejes, ellos:

  • [ 7.3 .4/TAB-1-1] debe ser capaz de medir los cambios de orientación hasta 1000 grados por segundo.

Memoria y almacenamiento mínimo (Sección 7.6.1)

Las densidades de pantalla enumeradas para pantallas pequeñas/normales en los requisitos portátiles no son aplicables a las tabletas.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[7.7.1/TAB] (11 de diciembre de 2023 Vista previa)

Modo periférico USB (Sección 7.7.1)

Si las implementaciones de la tableta incluyen un puerto USB que admite el modo periférico, ellos:

  • [ 7.7.1 /tab] puede implementar la API de accesorios abiertos de Android (AOA).

Terminar con nuevos requisitos

Modo de realidad virtual (Sección 7.9.1)

Realidad virtual Alto rendimiento (Sección 7.9.2)

Los requisitos de realidad virtual no son aplicables a las tabletas.

2.6.2. Modelo de seguridad

Claves y credenciales (Sección 9.11)

Consulte la sección [ 9.11 ].

Si las implementaciones de la tableta incluyen múltiples usuarios y no declaran el indicador de funciones android.hardware.telephony , ellos:

  • [ 9.5 /T-1-1] debe admitir perfiles restringidos, una característica que permite a los propietarios de dispositivos administrar usuarios adicionales y sus capacidades en el dispositivo. Con perfiles restringidos, los propietarios de dispositivos pueden configurar rápidamente entornos separados para que trabajen usuarios adicionales, con la capacidad de administrar restricciones más detalladas en las aplicaciones que están disponibles en esos entornos.

Si las implementaciones de la tableta incluyen múltiples usuarios y declaran el indicador de funciones android.hardware.telephony , ellos:

  • [ 9.5 /T-2-1] no debe admitir perfiles restringidos, sino que debe alinearse con la implementación de controles AOSP para habilitar /deshabilitar a otros usuarios acceder a las llamadas de voz y SMS.

2.6.2. Software

  • [ 3.2.3.1 /TAB-0-1] debe precargar una o más aplicaciones o componentes de servicio con un controlador de intención, para todos los patrones de filtro de intención pública definidos por los siguientes intentos de aplicación enumerados aquí .

3.software

3.1. Compatibilidad de API administrada

El entorno de ejecución de Bytecode Dalvik administrado es el vehículo principal para aplicaciones de Android. La interfaz de programación de aplicaciones Android (API) es el conjunto de interfaces de plataforma Android expuestas a aplicaciones que se ejecutan en el entorno de tiempo de ejecución administrado.

Implementaciones de dispositivos:

  • [C-0-1] debe proporcionar implementaciones completas, incluidos todos los comportamientos documentados, de cualquier API documentada expuesta por el SDK de Android o cualquier API decorada con el marcador "@Systemapi" en el código fuente de Android ascendente.

  • [C-0-2] debe admitir/preservar todas las clases, métodos y elementos asociados marcados por la anotación de Testapi (@Testapi).

  • [C-0-3] no debe omitir ninguna API administrada, alterar las interfaces o firmas de API, desviarse del comportamiento documentado, o incluir OPS, excepto cuando esta definición de compatibilidad permita específicamente.

  • [C-0-4] aún debe mantener las API presentes y comportarse de una manera razonable, incluso cuando se omiten algunas características de hardware para las cuales Android incluye API. Consulte la Sección 7 para ver los requisitos específicos para este escenario.

  • [C-0-5] no debe permitir que las aplicaciones de terceros usen interfaces que no son SDK, que se definen como métodos y campos en los paquetes de lenguaje Java que están en la clase de arranque en AOSP, y que no forman parte del SDK público. Esto incluye API decoradas con la anotación @hide pero no con un @SystemAPI , como se describe en los documentos SDK y los miembros de clase privada y privada de paquetes.

  • [C-0-6] debe enviarse con todas y cada una de la interfaz no SDK en las mismas listas restringidas que se proporcionan a través de la ruta provisional y denilista en la rama de nivel API adecuado en prebuilts/runtime/appcompat/hiddenapi-flags.csv el aosp.

  • [C-0-7] debe admitir el mecanismo de actualización dinámica de configuración firmada para eliminar las interfaces que no son SDK de una lista restringida integrando la configuración firmada en cualquier APK, utilizando las claves públicas existentes presentes en AOSP.

    Sin embargo, ellos:

    • Puede, si una API oculta está ausente o implementada de manera diferente en la implementación del dispositivo, mueva la API oculta al denylist u omitirla de todas las listas restringidas.
    • Puede, si una API oculta aún no existe en el AOSP, agregar la API oculta a cualquiera de las listas restringidas.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-0-8] (8 de abril de 2024 Vista previa)

  • [C-0-8] no debe admitir la instalación de aplicaciones dirigidas a un nivel de API inferior a 23 24 .

Terminar con nuevos requisitos

[C-0-8] (11 de diciembre de 2023 Vista previa)

  • [C-0-8] no debe admitir la instalación de aplicaciones dirigidas a un nivel de API inferior a 23 25 .

Terminar con nuevos requisitos

3.1.1. Extensiones de Android

Android admite extender la superficie API administrada de un nivel de API particular actualizando la versión de extensión para ese nivel de API. La API android.os.ext.SdkExtensions.getExtensionVersion(int apiLevel) devuelve la versión de extensión del apiLevel proporcionado, si hay extensiones para ese nivel de API.

Implementaciones del dispositivo Android:

  • [C-0-1] debe precargar la implementación de AOSP de la biblioteca compartida ExtShared y ExtServices de servicios con versiones mayores o iguales a las versiones mínimas permitidas por cada nivel de API. Por ejemplo, las implementaciones del dispositivo Android 7.0, la ejecución de API nivel 24 debe incluir al menos la versión 1.

  • [C-0-2] solo debe devolver el número de versión de extensión válido que ha sido definido por el AOSP.

  • [C-0-3] debe admitir todas las API definidas por las versiones de extensión devueltas por android.os.ext.SdkExtensions.getExtensionVersion(int apiLevel) de la misma manera que otras API administradas son compatibles, siguiendo los requisitos en la Sección 3.1 .

3.1.2. Biblioteca de Android

Debido a la deprecación del cliente apache http , implementaciones del dispositivo:

  • [C-0-1] no debe colocar la biblioteca org.apache.http.legacy en el BootClassPath.
  • [C-0-2] debe agregar la biblioteca org.apache.http.legacy a la aplicación de la aplicación solo cuando la aplicación satisface una de las siguientes condiciones:
    • Se dirige a API Nivel 28 o inferior.
    • Declara en su manifiesto que necesita la biblioteca estableciendo el atributo android:name de <uses-library> a org.apache.http.legacy .

La implementación de AOSP cumple con estos requisitos.

3.2. Compatibilidad de API suave

Además de las API administradas de la Sección 3.1 , Android también incluye una API "suave" de tiempo de ejecución significativa, en forma de cosas como intentos, permisos y aspectos similares de las aplicaciones de Android que no pueden aplicarse en el tiempo de compilación de aplicaciones.

3.2.1. Permisos

  • [C-0-1] Los implementadores del dispositivo deben admitir y hacer cumplir todas las constantes de permiso según lo documentado por la página de referencia de permiso . Tenga en cuenta que la Sección 9 enumera requisitos adicionales relacionados con el modelo de seguridad de Android.

3.2.2. Parámetros de construcción

Las API de Android incluyen una serie de constantes en la clase android.os.build que están destinadas a describir el dispositivo actual.

  • [C-0-1] Para proporcionar valores consistentes y significativos en las implementaciones del dispositivo, la siguiente tabla incluye restricciones adicionales en los formatos de estos valores a los que deben conformarse las implementaciones del dispositivo.
Parámetro Detalles
Version.lelease La versión del sistema Android actualmente ejecutivo, en formato legible por humanos. Este campo debe tener uno de los valores de cadena definidos en cadenas de versión permitidas para Android 15 .
Versión.sdk La versión del sistema Android que funciona actualmente, en un formato accesible para el código de aplicación de terceros. Para Android 15, este campo debe tener el valor entero 15_Int.
Versión.sdk_int La versión del sistema Android que funciona actualmente, en un formato accesible para el código de aplicación de terceros. Para Android 15, este campo debe tener el valor entero 15 int.
Versión. Un valor elegido por el implementador de dispositivos que designa la compilación específica del sistema Android que actualmente ejecutaba, en formato legible por humanos. Este valor no debe reutilizarse para diferentes compilaciones disponibles para los usuarios finales. Un uso típico de este campo es indicar qué número de compilación o identificador de cambio de control de origen se usó para generar la compilación. El valor de este campo debe ser codificable como ASCII de 7 bits imprimible y coincidir con la expresión regular ^[^ :\/~]+$ .
JUNTA Un valor elegido por el implementador del dispositivo que identifica el hardware interno específico utilizado por el dispositivo, en formato legible por humanos. Un posible uso de este campo es indicar la revisión específica de la placa que alimenta el dispositivo. El valor de este campo debe ser codificable como ASCII de 7 bits y coincidir con la expresión regular ^[a-zA-Z0-9 -]+$ .
MARCA Un valor que refleja la marca asociada con el dispositivo conocido por los usuarios finales. Debe estar en formato legible por humanos y debe representar al fabricante del dispositivo o la marca de la compañía bajo la cual se comercializa el dispositivo. El valor de este campo debe ser codificable como ASCII de 7 bits y coincidir con la expresión regular ^[a-zA-Z0-9_-]+$ .
Supported_abis El nombre del conjunto de instrucciones (Convención CPU Tipo + ABI) del código nativo. Ver Sección 3.3. Compatibilidad de API nativa .
Soported_32_bit_abis El nombre del conjunto de instrucciones (Convención CPU Tipo + ABI) del código nativo. Ver Sección 3.3. Compatibilidad de API nativa .
Soported_64_bit_abis El nombre del segundo conjunto de instrucciones (Convención CPU Tipo + ABI) del código nativo. Ver Sección 3.3. Compatibilidad de API nativa .
Cpu_abi El nombre del conjunto de instrucciones (Convención CPU Tipo + ABI) del código nativo. Ver Sección 3.3. Compatibilidad de API nativa .
CPU_ABI2 El nombre del segundo conjunto de instrucciones (Convención CPU Tipo + ABI) del código nativo. Ver Sección 3.3. Compatibilidad de API nativa .
DISPOSITIVO Un valor elegido por el implementador del dispositivo que contiene el nombre de desarrollo o el nombre de código que identifica la configuración de las características de hardware y el diseño industrial del dispositivo. El valor de este campo debe ser codificable como ASCII de 7 bits y coincidir con la expresión regular ^[a-zA-Z0-9 -]+$ . El nombre de este dispositivo no debe cambiar durante la vida útil del producto.
HUELLA DACTILAR Una cadena que identifica de manera única esta construcción. Debería ser razonablemente legible por humanos. Debe seguir esta plantilla:

$ (Marca)/$ (producto)/
$ (Dispositivo): $ (versión.release)/$ (id)/$ (versión.incremental): $ (type)/$ (etiquetas)

Por ejemplo:

acme/myproduct/
MyDevice: 15/lmyxx/3359: userDebug/test-keys

La huella digital no debe incluir personajes de espacios en blanco. El valor de este campo debe ser codificable como ASCII de 7 bits.

HARDWARE El nombre del hardware (desde la línea de comando del núcleo o /proc). Debería ser razonablemente legible por humanos. El valor de este campo debe ser codificable como ASCII de 7 bits y coincidir con la expresión regular ^[a-zA-Z0-9 -]+$ .
ANFITRIÓN Una cadena que identifica de manera única el host en el que se construyó la construcción, en formato legible por humanos. No hay requisitos en el formato específico de este campo, excepto que no debe ser nulo o la cadena vacía ("").
IDENTIFICACIÓN Un identificador elegido por el implementador del dispositivo para referirse a una versión específica, en formato legible por humanos. Este campo puede ser el mismo que Android.os.build.version.incremental, pero debe ser un valor suficientemente significativo para que los usuarios finales distinguen entre las compilaciones de software. El valor de este campo debe ser codificable como ASCII de 7 bits y coincidir con la expresión regular ^[a-zA-Z0-9._-]+$ .
FABRICANTE El nombre comercial del fabricante de equipos original (OEM) del producto. No hay requisitos en el formato específico de este campo, excepto que no debe ser nulo o la cadena vacía (""). Este campo no debe cambiar durante la vida útil del producto.
Soc_ Manufacturador El comercio del nombre del fabricante del sistema primario en ChIP (SOC) utilizado en el producto. Los dispositivos con el mismo fabricante de SOC deben usar el mismo valor constante. Pida al fabricante de SOC la constante correcta de usar. El valor de este campo debe ser codificable como ASCII de 7 bits, debe coincidir con la expresión regular ^([0-9A-Za-z ]+) , no debe comenzar ni terminar con Whitpace, y no debe ser igual a "desconocido" . Este campo no debe cambiar durante la vida útil del producto.
Modelo SOC El nombre del modelo del sistema primario en un chip (SOC) utilizado en el producto. Los dispositivos con el mismo modelo SOC deben usar el mismo valor constante. Pida al fabricante de SOC la constante correcta de usar. El valor de este campo debe ser codificable como ASCII de 7 bits y coincidir con la expresión regular ^([0-9A-Za-z . /+-]+)$ , no debe comenzar ni terminar con Whitespace, y no debe ser igual a "desconocido". Este campo no debe cambiar durante la vida útil del producto.
MODELO Un valor elegido por el implementador del dispositivo que contiene el nombre del dispositivo como conocido por el usuario final. Este debe ser el mismo nombre bajo el cual el dispositivo se comercializa y vende a los usuarios finales. No hay requisitos en el formato específico de este campo, excepto que no debe ser nulo o la cadena vacía (""). Este campo no debe cambiar durante la vida útil del producto.
PRODUCTO Un valor elegido por el implementador del dispositivo que contiene el nombre de desarrollo o el nombre de código del producto específico (SKU) que debe ser único dentro de la misma marca. Debe ser legible por humanos, pero no necesariamente está destinado a la vista por parte de los usuarios finales. El valor de este campo debe ser codificable como ASCII de 7 bits y coincidir con la expresión regular ^[a-zA-Z0-9_-]+$ . Este nombre del producto no debe cambiar durante la vida del producto.
ODM SKU Un valor opcional elegido por el implementador del dispositivo que contiene SKU (unidad de mantenimiento de stock) utilizado para rastrear configuraciones específicas del dispositivo, por ejemplo, cualquier periférico incluido con el dispositivo cuando se vende. El valor de este campo debe ser codificable como ASCII de 7 bits y coincidir con la expresión regular "[0-9-Za-Z.,-])"
DE SERIE Debe devolver "desconocido".
ETIQUETAS Una lista separada por comas de etiquetas elegidas por el implementador del dispositivo que distingue aún más la compilación. Las etiquetas deben ser codificables como ASCII de 7 bits y coincidir con la expresión regular ^[a-zA-Z0-9._-]+ y deben tener uno de los valores correspondientes a las tres configuraciones típicas de firma de la plataforma Android: KeeS-Keys, Dev-keys y test-keys.
TIEMPO Un valor que representa la marca de tiempo de cuándo ocurrió la construcción.
TIPO Un valor elegido por el implementador del dispositivo que especifica la configuración de tiempo de ejecución de la compilación. Este campo debe tener uno de los valores correspondientes a las tres configuraciones típicas de tiempo de ejecución de Android: User, UserDebug o Eng.
USUARIO Un nombre o ID de usuario del usuario (o usuario automatizado) que generó la compilación. No hay requisitos en el formato específico de este campo, excepto que no debe ser nulo o la cadena vacía ("").
Security_patch Un valor que indica el nivel de parche de seguridad de una compilación. Debe significar que la construcción no es de ninguna manera vulnerable a ninguno de los problemas descritos a través del boletín de seguridad público de Android designado. Debe estar en el formato [aaa yyy-mm-dd], que coincide con una cadena definida documentada en el boletín de seguridad pública de Android o en el aviso de seguridad de Android , por ejemplo "2015-11-01".
Sistema operativo base Un valor que representa el parámetro de huella digital de la compilación que de otra manera es idéntico a esta construcción, excepto los parches proporcionados en el Boletín de Seguridad Pública de Android. Debe informar el valor correcto y si dicha compilación no existe, informe una cadena vacía ("").
CARGADOR DE ARRANQUE Un valor elegido por el implementador del dispositivo que identifica la versión específica del cargador de arranque interno utilizado en el dispositivo, en formato legible por humanos. El valor de este campo debe ser codificable como ASCII de 7 bits y coincidir con la expresión regular ^[a-zA-Z0-9. -]+$ .
getRadioversion () Debe (be o return) un valor elegido por el implementador del dispositivo que identifica la versión específica de radio/módem interna utilizada en el dispositivo, en formato legible por humanos. Si un dispositivo no tiene ninguna radio/módem interno, debe devolver nulo. El valor de este campo debe ser codificable como ASCII de 7 bits y coincidir con la expresión regular ^[a-zA-Z0-9._-,]+$ .
getSerial () Debe (ser o devolver) un número de serie de hardware, que debe estar disponible y único en todos los dispositivos con el mismo modelo y fabricante. El valor de este campo debe ser codificable como ASCII de 7 bits y coincidir con la expresión regular ^[a-zA-Z0-9]+$ .

3.2.3. Compatibilidad de la intención

3.2.3.1. Intentos de aplicación comunes

Android Intents permite que los componentes de la aplicación soliciten la funcionalidad de otros componentes de Android. El proyecto Android Upstream incluye una lista de aplicaciones que implementan varios patrones de intención para realizar acciones comunes.

Implementaciones de dispositivos:

  • [C-SR-1] se recomienda encarecidamente precargar una o más aplicaciones o componentes de servicio con un controlador de intención, para todos los patrones de filtro de intención pública definidos por los siguientes intentos de aplicación enumerados aquí y proporcionar cumplimiento, es decir, reunirse con la expectativa del desarrollador para estos intentos de aplicación común como se describe en el SDK.

Consulte la Sección 2 para obtener intentos de aplicación obligatorios para cada tipo de dispositivo.

3.2.3.2. Resolución de intención
  • [C-0-1] Como Android es una plataforma extensible, las implementaciones de dispositivos deben permitir que cada patrón de intención hace referencia en la Sección 3.2.3.1 , a excepción de la configuración, se anule por aplicaciones de terceros. La implementación de código abierto de Android Upstream permite esto de forma predeterminada.

  • Los implementadores de dispositivos [C-0-2] no deben adjuntar privilegios especiales al uso de aplicaciones del sistema de estos patrones de intención, o evitar que las aplicaciones de terceros se vinculen y asuman el control de estos patrones. Esta prohibición incluye específicamente, pero no se limita a deshabilitar la interfaz de usuario "selector" que permite al usuario seleccionar entre múltiples aplicaciones que manejan el mismo patrón de intención.

  • [C-0-3] Las implementaciones de dispositivos deben proporcionar una interfaz de usuario para que los usuarios modifiquen la actividad predeterminada para intentos.

  • Sin embargo, las implementaciones de dispositivos pueden proporcionar actividades predeterminadas para patrones de URI específicos (por ejemplo, http://play.google.com) cuando la actividad predeterminada proporciona un atributo más específico para el URI de datos. Por ejemplo, un patrón de filtro de intención que especifica el URI de datos "http://www.android.com" es más específico que el patrón de intención central del navegador para "http: //".

Android también incluye un mecanismo para que las aplicaciones de terceros declaren una aplicación predeterminada autorizada que vincula el comportamiento para ciertos tipos de intentos de URI web. Cuando tales declaraciones autorizadas se definen en los patrones de filtro de intención de una aplicación, implementaciones de dispositivos:

  • [C-0-4] debe intentar validar cualquier filtros de intención realizando los pasos de validación definidos en la especificación de enlaces de activos digitales implementados por el administrador de paquetes en el proyecto de código abierto de Android ascendente.
  • [C-0-5] debe intentar la validación de los filtros de intención durante la instalación de la aplicación y establecer todos los filtros de intención de URI validados con éxito como controladores de aplicaciones predeterminados para sus URI.
  • Puede establecer filtros de intención de URI específicos como manejadores de aplicaciones predeterminados para sus URI, si se verifican con éxito, pero otros filtros de URI candidatos falla la verificación. Si una implementación de un dispositivo hace esto, debe proporcionar al usuario las anulaciones de patrones por URI apropiadas en el menú Configuración.
  • Debe proporcionar al usuario controles de enlaces de aplicación por APP en la configuración de la siguiente manera:
    • [C-0-6] The user MUST be able to override holistically the default app links behavior for an app to be: always open, always ask, or never open, which must apply to all candidate URI intent filters equally.
    • [C-0-7] The user MUST be able to see a list of the candidate URI intent filters.
    • The device implementation MAY provide the user with the ability to override specific candidate URI intent filters that were successfully verified, on a per-intent filter basis.
    • [C-0-8] The device implementation MUST provide users with the ability to view and override specific candidate URI intent filters if the device implementation lets some candidate URI intent filters succeed verification while some others can fail.
3.2.3.3. Intent Namespaces
  • [C-0-1] Device implementations MUST NOT include any Android component that honors any new intent or broadcast intent patterns using an ACTION, CATEGORY, or other key string in the android.* or com.android.* namespace.
  • [C-0-2] Device implementers MUST NOT include any Android components that honor any new intent or broadcast intent patterns using an ACTION, CATEGORY, or other key string in a package space belonging to another organization.
  • [C-0-3] Device implementers MUST NOT alter or extend any of the intent patterns listed in section 3.2.3.1 .
  • Device implementations MAY include intent patterns using namespaces clearly and obviously associated with their own organization. This prohibition is analogous to that specified for Java language classes in section 3.6 .
3.2.3.4. Broadcast Intents

Third-party applications rely on the platform to broadcast certain intents to notify them of changes in the hardware or software environment.

Device implementations:

  • [C-0-1] MUST broadcast the public broadcast intents listed here in response to appropriate system events as described in the SDK documentation. Note that this requirement is not conflicting with section 3.5 as the limitation for background applications are also described in the SDK documentation. Also certain broadcast intents are conditional upon hardware support, if the device supports the necessary hardware they MUST broadcast the intents and provide the behavior inline with SDK documentation.
3.2.3.5. Conditional Application Intents

Android includes settings that provide users an easy way to select their default applications, for example for Home screen or SMS.

Where it makes sense, device implementations MUST provide a similar settings menu and be compatible with the intent filter pattern and API methods described in the SDK documentation as below.

If device implementations report android.software.home_screen , they:

If device implementations report android.hardware.telephony.calling , they:

If device implementations report android.hardware.nfc.hce , they:

If device implementations report android.hardware.nfc , they:

If device implementations report android.hardware.bluetooth , they:

If device implementations support the DND feature, they:

  • [C-6-1] MUST implement an activity that would respond to the intent ACTION_NOTIFICATION_POLICY_ACCESS_SETTINGS , which for implementations with UI_MODE_TYPE_NORMAL it MUST be an activity where the user can grant or deny the app access to DND policy configurations.

If device implementations allow users to use third-party input methods on the device, they:

If device implementations support third-party accessibility services, they:

  • [C-8-1] MUST honor the android.settings.ACCESSIBILITY_SETTINGS intent to provide a user-accessible mechanism to enable and disable the third-party accessibility services alongside the preloaded accessibility services.

If device implementations include support for Wi-Fi Easy Connect and expose the functionality to third-party apps, they:

If device implementations provide the data saver mode, they: * [C-10-1] MUST provide a user interface in the settings, that handles the Settings.ACTION_IGNORE_BACKGROUND_DATA_RESTRICTIONS_SETTINGS intent, allowing users to add applications to or remove applications from the allow list.

If device implementations do not provide the data saver mode, they:

If device implementations declare support for the camera via android.hardware.camera.any , they:

If device implementations report android.software.device_admin , they:

If device implementations declare the android.software.autofill feature flag, they:

If device implementations include a pre-installed app or wish to allow third-party apps to access the usage statistics, they:

  • [C-SR-2] are STRONGLY RECOMMENDED provide user-accessible mechanism to grant or revoke access to the usage stats in response to the android.settings.ACTION_USAGE_ACCESS_SETTINGS intent for apps that declare the android.permission.PACKAGE_USAGE_STATS permission.

If device implementations intend to disallow any apps, including pre-installed apps, from accessing the usage statistics, they:

  • [C-15-1] MUST still have an activity that handles the android.settings.ACTION_USAGE_ACCESS_SETTINGS intent pattern but MUST implement it as a no-op, that is to have an equivalent behavior as when the user is declined for access.

If device implementations surface links to the activities specified by AutofillService_passwordsActivity in Settings or links to user passwords through a similar mechanism, they:

  • [C-16-1] MUST surface such links for all installed autofill services.

If device implementations support the VoiceInteractionService and have more than one application using this API installed at a time, they:

If device implementations report the feature android.hardware.audio.output , they:

  • [C-SR-3] Are STRONGLY RECOMMENDED to honor android.intent.action.TTS_SERVICE, android.speech.tts.engine.INSTALL_TTS_DATA & android.speech.tts.engine.GET_SAMPLE_TEXT intents have an activity to provide fulfillment for these intents as described in SDK here .

Android includes support for interactive screensavers, previously referred to as Dreams. Screen Savers allow users to interact with applications when a device connected to a power source is idle or docked in a desk dock. Device Implementations:

  • SHOULD include support for screen savers and provide a settings option for users to configure screen savers in response to the android.settings.DREAM_SETTINGS intent.

If device implementations report android.hardware.nfc.uicc or android.hardware.nfc.ese , they:

3.2.4. Activities on secondary/multiple displays

If device implementations allow launching normal Android Activities on more than one display, they:

  • [C-1-1] MUST set the android.software.activities_on_secondary_displays feature flag.
  • [C-1-2] MUST guarantee API compatibility similar to an activity running on the primary display.
  • [C-1-3] MUST land the new activity on the same display as the activity that launched it, when the new activity is launched without specifying a target display via the ActivityOptions.setLaunchDisplayId() API.
  • [C-1-4] MUST destroy all activities, when a display with the Display.FLAG_PRIVATE flag is removed.
  • [C-1-5] MUST securely hide content on all screens when the device is locked with a secure lock screen, unless the app opts in to show on top of lock screen using Activity#setShowWhenLocked() API.
  • SHOULD have android.content.res.Configuration which corresponds to that display in order to be displayed, operate correctly, and maintain compatibility if an activity is launched on secondary display.

If device implementations allow launching normal Android Activities on secondary displays and a secondary display has the android.view.Display.FLAG_PRIVATE flag:

  • [C-3-1] Only the owner of that display, system, and activities that are already on that display MUST be able to launch to it. Everyone can launch to a display that has android.view.Display.FLAG_PUBLIC flag.

3.3. Native API Compatibility

Native code compatibility is challenging. For this reason, device implementers are:

  • [C-SR-1] STRONGLY RECOMMENDED to use the implementations of the libraries listed below from the upstream Android Open Source Project.

3.3.1. Application Binary Interfaces

Managed Dalvik bytecode can call into native code provided in the application .apk file as an ELF .so file compiled for the appropriate device hardware architecture. As native code is highly dependent on the underlying processor technology, Android defines a number of Application Binary Interfaces (ABIs) in the Android NDK.

Device implementations:

  • [C-0-1] MUST be compatible with one or more defined Android NDK ABIs .
  • [C-0-2] MUST include support for code running in the managed environment to call into native code, using the standard Java Native Interface (JNI) semantics.
  • [C-0-3] MUST be source-compatible (ie header-compatible) and binary-compatible (for the ABI) with each required library in the list below.
  • [C-0-5] MUST accurately report the native Application Binary Interface (ABI) supported by the device, via the android.os.Build.SUPPORTED_ABIS , android.os.Build.SUPPORTED_32_BIT_ABIS , and android.os.Build.SUPPORTED_64_BIT_ABIS parameters, each a comma separated list of ABIs ordered from the most to the least preferred one.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-0-6] (February 26, 2024 preview)

  • [C-0-6] MUST report, via the above parameters, a subset of the following list of ABIs and MUST NOT report any ABI not on the list.

Terminar con nuevos requisitos

  • [C-0-7] MUST make all the following libraries, providing native APIs, available to apps that include native code:

    • libaaudio.so (AAudio native audio support)
    • libamidi.so (native MIDI support, if feature android.software.midi is claimed as described in Section 5.9)
    • libandroid.so (native Android activity support)
    • libc (C library)
    • libcamera2ndk.so
    • libdl (dynamic linker)
    • libEGL.so (native OpenGL surface management)
    • libGLESv1_CM.so (OpenGL ES 1.x)
    • libGLESv2.so (OpenGL ES 2.0)
    • libGLESv3.so (OpenGL ES 3.x)
    • libicui18n.so
    • libicuuc.so
    • libjnigraphics.so
    • liblog (Android logging)
    • libmediandk.so (native media APIs support)
    • libm (math library)
    • libneuralnetworks.so (Neural Networks API)
    • libOpenMAXAL.so (OpenMAX AL 1.0.1 support)
    • libOpenSLES.so (OpenSL ES 1.0.1 audio support)
    • libRS.so
    • libstdc++ (Minimal support for C++)
    • libvulkan.so (Vulkan)
    • libz (Zlib compression)
    • interfaz JNI
  • [C-0-8] MUST NOT add or remove the public functions for the native libraries listed above.

  • [C-0-9] MUST list additional non-AOSP libraries exposed directly to third-party apps in /vendor/etc/public.libraries.txt .

  • [C-0-10] MUST NOT expose any other native libraries, implemented and provided in AOSP as system libraries, to third-party apps targeting API level 24 or higher as they are reserved.

  • [C-0-11] MUST export all the OpenGL ES 3.1 and Android Extension Pack function symbols, as defined in the NDK, through the libGLESv3.so library. Note that while all the symbols MUST be present, section 7.1.4.1 describes in more detail the requirements for when the full implementation of each corresponding functions are expected.

  • [C-0-12] MUST export function symbols for the core Vulkan 1.1 function symbols, as well as the VK_KHR_surface , VK_KHR_android_surface , VK_KHR_swapchain , VK_KHR_maintenance1 , and VK_KHR_get_physical_device_properties2 extensions through the libvulkan.so library. Note that while all the symbols MUST be present, section 7.1.4.2 describes in more detail the requirements for when the full implementation of each corresponding functions are expected.

  • SHOULD be built using the source code and header files available in the upstream Android Open Source Project.

Note that future releases of Android may introduce support for additional ABIs.

3.3.2. 32-bit ARM Native Code Compatibility

If device implementations report the support of the armeabi ABI, they:

  • [C-3-1] MUST also support armeabi-v7a and report its support, as armeabi is only for backwards compatibility with older apps.

If device implementations report the support of the armeabi-v7a ABI, for apps using this ABI, they:

  • [C-2-1] MUST include the following lines in /proc/cpuinfo , and SHOULD NOT alter the values on the same device, even when they are read by other ABIs.

    • Features: , followed by a list of any optional ARMv7 CPU features supported by the device.
    • CPU architecture: , followed by an integer describing the device's highest supported ARM architecture (eg, "8" for ARMv8 devices).
  • [C-2-2] MUST always keep the following operations available, even in the case where the ABI is implemented on an ARMv8 architecture, either through native CPU support or through software emulation:

    • SWP and SWPB instructions.
    • CP15ISB, CP15DSB, and CP15DMB barrier operations.
  • [C-2-3] MUST include support for the Advanced SIMD (aka NEON) extension.

3.4. Compatibilidad web

3.4.1. WebView Compatibility

If device implementations provide a complete implementation of the android.webkit.Webview API, they:

  • [C-1-1] MUST report android.software.webview .
  • [C-1-2] MUST use the Chromium Project build from the upstream Android Open Source Project on the Android 15 branch for the implementation of the android.webkit.WebView API.
  • [C-1-3] The user agent string reported by the WebView MUST be in this format:

    Mozilla/5.0 (Linux; Android $(VERSION); [$(MODEL)] [Build/$(BUILD)]; wv) AppleWebKit/537.36 (KHTML, like Gecko) Version/4.0 $(CHROMIUM_VER) Mobile Safari/537.36

    • The value of the $(VERSION) string MUST be the same as the value for android.os.Build.VERSION.RELEASE.
    • The $(MODEL) string MAY be empty, but if it is not empty it MUST have the same value as android.os.Build.MODEL.
    • "Build/$(BUILD)" MAY be omitted, but if it is present the $(BUILD) string MUST be the same as the value for android.os.Build.ID.
    • The value of the $(CHROMIUM_VER) string MUST be the version of Chromium in the upstream Android Open Source Project.
    • Device implementations MAY omit Mobile in the user agent string.
  • The WebView component SHOULD include support for as many HTML5 features as possible and if it supports the feature SHOULD conform to the HTML5 specification .

  • [C-1-4] MUST render the provided content or remote URL content in a process that is distinct from the application that instantiates the WebView. Specifically the separate renderer process MUST hold lower privilege, run as a separate user ID, have no access to the app's data directory, have no direct network access, and only have access to the minimum-required system services over Binder. The AOSP implementation of WebView meets this requirement.

Note that if device implementations are 32-bit or declare the feature flag android.hardware.ram.low , they are exempted from C-1-3.

3.4.2. Compatibilidad del navegador

If device implementations include a standalone Browser application for general web browsing, they:

  • [C-1-1] MUST support each of these APIs associated with HTML5:
  • [C-1-2] MUST support the HTML5/W3C webstorage API and SHOULD support the HTML5/W3C IndexedDB API . Note that as the web development standards bodies are transitioning to favor IndexedDB over webstorage, IndexedDB is expected to become a required component in a future version of Android.
  • MAY ship a custom user agent string in the standalone Browser application.
  • SHOULD implement support for as much of HTML5 as possible on the standalone Browser application (whether based on the upstream WebKit Browser application or a third-party replacement).

However, If device implementations do not include a standalone Browser application, they:

  • [C-2-1] MUST still support the public intent patterns as described in section 3.2.3.1 .

3.5. API Behavioral Compatibility

Device implementations:

  • [C-0-9] MUST ensure that API behavioral compatibility is applied for all installed apps unless they are restricted as described in Section 3.5.1 .
  • [C-0-10] MUST NOT implement the allowlisting approach that ensures API behavioral compatibility only for apps that are selected by device implementers.

The behaviors of each of the API types (managed, soft, native, and web) must be consistent with the preferred implementation of the upstream Android Open Source Project . Some specific areas of compatibility are:

  • [C-0-1] Devices MUST NOT change the behavior or semantics of a standard intent.
  • [C-0-2] Devices MUST NOT alter the lifecycle or lifecycle semantics of a particular type of system component (such as Service, Activity, ContentProvider, etc.).
  • [C-0-3] Devices MUST NOT change the semantics of a standard permission.
  • Devices MUST NOT alter the limitations enforced on background applications. More specifically, for background apps:
    • [C-0-4] they MUST stop executing callbacks that are registered by the app to receive outputs from the GnssMeasurement and GnssNavigationMessage .
    • [C-0-5] they MUST rate-limit the frequency of updates that are provided to the app through the LocationManager API class or the WifiManager.startScan() method.
    • [C-0-6] if the app is targeting API level 25 or higher, they MUST NOT allow to register broadcast receivers for the implicit broadcasts of standard Android intents in the app's manifest, unless the broadcast intent requires a "signature" or "signatureOrSystem" protectionLevel permission or are on the exemption list .
    • [C-0-7] if the app is targeting API level 25 or higher, they MUST stop the app's background services, just as if the app had called the services' stopSelf() method, unless the app is placed on a temporary allowlist to handle a task that's visible to the user.
    • [C-0-8] if the app is targeting API level 25 or higher, they MUST release the wakelocks the app holds.
  • [C-0-11] Devices MUST return the following security providers as the first seven array values from the Security.getProviders() method, in the given order and with the given names (as returned by Provider.getName() ) and classes, unless the app has modified the list via insertProviderAt() or removeProvider() . Devices MAY return additional providers after the specified list of providers below.
    1. AndroidNSSP - android.security.net.config.NetworkSecurityConfigProvider
    2. AndroidOpenSSL - com.android.org.conscrypt.OpenSSLProvider
    3. CertPathProvider - sun.security.provider.CertPathProvider
    4. AndroidKeyStoreBCWorkaround - android.security.keystore.AndroidKeyStoreBCWorkaroundProvider
    5. BC - com.android.org.bouncycastle.jce.provider.BouncyCastleProvider
    6. HarmonyJSSE - com.android.org.conscrypt.JSSEProvider
    7. AndroidKeyStore - android.security.keystore.AndroidKeyStoreProvider

The above list is not comprehensive. The Compatibility Test Suite (CTS) tests significant portions of the platform for behavioral compatibility, but not all. It is the responsibility of the implementer to ensure behavioral compatibility with the Android Open Source Project. For this reason, device implementers SHOULD use the source code available via the Android Open Source Project where possible, rather than re-implement significant parts of the system.

3.5.1. Application Restriction

If device implementations implement a proprietary mechanism to restrict apps (eg changing or restricting API behaviors that are described in the SDK) and that mechanism is more restrictive than the Restricted App Standby Bucket , they:

  • [C-1-1] MUST allow the user to see the list of restricted apps.
  • [C-1-2] MUST provide user affordance to turn on / off all of these proprietary restrictions on each app.
  • [C-1-3] MUST not automatically apply these proprietary restrictions without evidence of poor system health behavior, but MAY apply the restrictions on apps upon detection of poor system health behavior like stuck wakelocks, long running services, and other criteria. The criteria MAY be determined by device implementers but MUST be related to the app's impact on the system health. Other criteria that are not purely related to the system health, such as the app's lack of popularity in the market, MUST NOT be used as criteria.

  • [C-1-4] MUST not automatically apply these proprietary restrictions for apps when a user has turned off app restrictions manually, and MAY suggest the user to apply these proprietary restrictions.

  • [C-1-5] MUST inform users if these proprietary restrictions are applied to an app automatically. Such information MUST be provided in the 24-hour period preceding the application of these proprietary restrictions.

  • [C-1-6] MUST return true for the ActivityManager.isBackgroundRestricted() method for any API calls from an app.

  • [C-1-7] MUST NOT restrict the top foreground app that is explicitly used by the user.

  • [C-1-8] MUST suspend these proprietary restrictions on an app whenever a user starts to explicitly use the app, making it the top foreground application.

  • [C-1-10] MUST provide a public and clear document or website that describes how proprietary restrictions are applied. This document or website MUST be linkable from the Android SDK documents and MUST include:

    • Triggering conditions for proprietary restrictions.
    • What and how an app can be restricted.
    • How an app can be exempted from such restrictions.
    • How an app can request an exemption from proprietary restrictions, if they support such an exemption for apps the user can install.

If an app is pre-installed on the device and has never been explicitly used by a user for more than 30 days, [C-1-3] [C-1-5] are exempted.

If device implementations extend the app restrictions that are implemented in AOSP, they:

  • [C-2-1]MUST follow the implementation described in this document .

3.5.2. Hibernación de aplicaciones

If device implementations include App Hibernation that is included in AOSP or extends the feature that is included in AOSP, then they:

  • [C-1-1] MUST meet all the requirements in section 3.5.1 except for [C-1-6] and [C-1-3].
  • [C-1-2] MUST only apply the restriction on the app for a user when there is evidence that the user has not used the app for some period of time. This duration is STRONGLY RECOMMENDED to be one month or longer. Usage MUST be defined by either explicit user interaction via the UsageStats#getLastTimeVisible() API or anything that would cause an app to leave the force-stopped state, including service bindings, content provider bindings, explicit broadcasts, etc., which will be tracked by a new API UsageStats#getLastTimeAnyComponentUsed().
  • [C-1-3] MUST only apply restrictions affecting all device users when there is evidence that the package has not been used by ANY user for some period of time. This duration is STRONGLY RECOMMENDED to be one month or longer.
  • [C-1-4] MUST NOT render the app unable to respond to activity intents, service bindings, content provider requests, or explicit broadcasts.

App Hibernation in AOSP meets the above requirements.

3.6. API Namespaces

Android follows the package and class namespace conventions defined by the Java programming language. To ensure compatibility with third-party applications, device implementers MUST NOT make any prohibited modifications (see below) to these package namespaces:

  • java.*
  • javax.*
  • sun.*
  • android.*
  • androidx.*
  • com.android.*

That is, they:

  • [C-0-1] MUST NOT modify the publicly exposed APIs on the Android platform by changing any method or class signatures, or by removing classes or class fields.
  • [C-0-2] MUST NOT add any publicly exposed elements (such as classes or interfaces, or fields or methods to existing classes or interfaces) or Test or System APIs to the APIs in the above namespaces. A "publicly exposed element" is any construct that is not decorated with the "@hide" marker as used in the upstream Android source code.

Device implementers MAY modify the underlying implementation of the APIs, but such modifications:

  • [C-0-3] MUST NOT impact the stated behavior and Java-language signature of any publicly exposed APIs.
  • [C-0-4] MUST NOT be advertised or otherwise exposed to developers.

However, device implementers MAY add custom APIs outside the standard Android namespace, but the custom APIs:

  • [C-0-5] MUST NOT be in a namespace owned by or referring to another organization. For instance, device implementers MUST NOT add APIs to the com.google.* or similar namespace: only Google may do so. Similarly, Google MUST NOT add APIs to other companies' namespaces.
  • [C-0-6] MUST be packaged in an Android shared library so that only apps that explicitly use them (via the <uses-library> mechanism) are affected by the increased memory usage of such APIs.

Device implementers MAY add custom APIs in native languages, outside of the NDK APIs, but the custom APIs:

  • [C-1-1] MUST NOT be in a NDK library or a library owned by another organization as described here .

If a device implementer proposes to improve one of the package namespaces above (such as by adding useful new functionality to an existing API, or adding a new API), the implementer SHOULD visit source.android.com and begin the process for contributing changes and code, according to the information on that site.

Note that the restrictions above correspond to standard conventions for naming APIs in the Java programming language; this section simply aims to reinforce those conventions and make them binding through inclusion in this Compatibility Definition.

3.7. Runtime Compatibility

Device implementations:

  • [C-0-1] MUST support the full Dalvik Executable (DEX) format and Dalvik bytecode specification and semantics .

  • [C-0-2] MUST configure Dalvik runtimes to allocate memory in accordance with the upstream Android platform, and as specified by the following table. (See section 7.1.1 for screen size and screen density definitions.)

  • SHOULD use Android RunTime (ART), the reference upstream implementation of the Dalvik Executable Format, and the reference implementation's package management system.

  • SHOULD run fuzz tests under various modes of execution and target architectures to assure the stability of the runtime. Refer to JFuzz and DexFuzz in the Android Open Source Project website.

Note that memory values specified below are considered minimum values and device implementations MAY allocate more memory per application.

Diseño de pantalla Densidad de la pantalla Minimum Application Memory
Android Watch 120 dpi (ldpi) 32MB
140 dpi (140dpi)
160 dpi (mdpi)
180 dpi (180dpi)
200 dpi (200dpi)
213 dpi (tvdpi)
220 dpi (220dpi) 36MB
240 dpi (hdpi)
280 dpi (280dpi)
320 dpi (xhdpi) 48MB
360 dpi (360dpi)
400 dpi (400dpi) 56MB
420 dpi (420dpi) 64MB
480 dpi (xxhdpi) 88MB
560 dpi (560dpi) 112MB
640 dpi (xxxhdpi) 154MB
small/normal 120 dpi (ldpi) 32MB
140 dpi (140dpi)
160 dpi (mdpi)
180 dpi (180dpi) 48MB
200 dpi (200dpi)
213 dpi (tvdpi)
220 dpi (220dpi)
240 dpi (hdpi)
280 dpi (280dpi)
320 dpi (xhdpi) 80MB
360 dpi (360dpi)
400 dpi (400dpi) 96MB
420 dpi (420dpi) 112MB
480 dpi (xxhdpi) 128MB
560 dpi (560dpi) 192MB
640 dpi (xxxhdpi) 256MB
grande 120 dpi (ldpi) 32MB
140 dpi (140dpi) 48MB
160 dpi (mdpi)
180 dpi (180dpi) 80MB
200 dpi (200dpi)
213 dpi (tvdpi)
220 dpi (220dpi)
240 dpi (hdpi)
280 dpi (280dpi) 96MB
320 dpi (xhdpi) 128MB
360 dpi (360dpi) 160MB
400 dpi (400dpi) 192MB
420 dpi (420dpi) 228MB
480 dpi (xxhdpi) 256MB
560 dpi (560dpi) 384MB
640 dpi (xxxhdpi) 512MB
extra grande 120 dpi (ldpi) 48MB
140 dpi (140dpi) 80MB
160 dpi (mdpi)
180 dpi (180dpi) 96MB
200 dpi (200dpi)
213 dpi (tvdpi)
220 dpi (220dpi)
240 dpi (hdpi)
280 dpi (280dpi) 144MB
320 dpi (xhdpi) 192MB
360 dpi (360dpi) 240MB
400 dpi (400dpi) 288MB
420 dpi (420dpi) 336MB
480 dpi (xxhdpi) 384MB
560 dpi (560dpi) 576MB
640 dpi (xxxhdpi) 768MB

3.8. User Interface Compatibility

3.8.1. Launcher (Home Screen)

Android includes a launcher application (home screen) and support for third-party applications to replace the device launcher (home screen).

If device implementations allow third-party applications to replace the device home screen, they:

  • [C-1-1] MUST declare the platform feature android.software.home_screen .
  • [C-1-2] MUST return the AdaptiveIconDrawable object when the third-party application use <adaptive-icon> tag to provide their icon, and the PackageManager methods to retrieve icons are called.

If device implementations include a default launcher that supports in-app pinning of shortcuts, they:

Conversely, if device implementations do not support in-app pinning of shortcuts, they:

If device implementations implement a default launcher that provides quick access to the additional shortcuts provided by third-party apps through the ShortcutManager API, they:

  • [C-4-1] MUST support all documented shortcut features (eg static and dynamic shortcuts, pinning shortcuts) and fully implement the APIs of the ShortcutManager API class.

If device implementations include a default launcher app that shows badges for the app icons, they:

  • [C-5-1] MUST respect the NotificationChannel.setShowBadge() API method. In other words, show a visual affordance associated with the app icon if the value is set as true , and do not show any app icon badging scheme when all of the app's notification channels have set the value as false .
  • MAY override the app icon badges with their proprietary badging scheme when third-party applications indicate support of the proprietary badging scheme through the use of proprietary APIs, but SHOULD use the resources and values provided through the notification badges APIs described in the SDK , such as the Notification.Builder.setNumber() and the Notification.Builder.setBadgeIconType() API.

If device implementations support monochrome icons, these icons:

  • [C-6-1] MUST be used only when a user explicitly enables them (eg via Settings or wallpaper picker menu).

3.8.2. widgets

Android supports third-party app widgets by defining a component type and corresponding API and lifecycle that allows applications to expose an "AppWidget" to the end user.

If device implementations support third-party app widgets, they:

  • [C-1-1] MUST declare support for platform feature android.software.app_widgets .
  • [C-1-2] MUST include built-in support for AppWidgets and expose user interface affordances to add, configure, view, and remove AppWidgets
  • [C-1-3] MUST be capable of rendering widgets that are 4 x 4 in the standard grid size. See the App Widget DesignGuidelines in the Android SDK documentation for details.
  • MAY support application widgets on the lock screen.

If device implementations support third-party app widgets and in-app pinning of shortcuts, they:

3.8.3. Notificaciones

Android includes Notification and NotificationManager APIs that allow third-party app developers to notify users of notable events and attract users' attention using the hardware components (eg sound, vibration and light) and software features (eg notification shade, system bar) of the device .

3.8.3.1. Presentación de Notificaciones

If device implementations allow third-party apps to notify users of notable events , they:

  • [C-1-1] MUST support notifications that use hardware features, as described in the SDK documentation, and to the extent possible with the device implementation hardware. For instance, if a device implementation includes a vibrator, it MUST correctly implement the vibration APIs. If a device implementation lacks hardware, the corresponding APIs MUST be implemented as no-ops. This behavior is further detailed in section 7 .
  • [C-1-2] MUST correctly render all resources (icons, animation files, etc.) provided for in the APIs, or in the Status/System Bar icon style guide , although they MAY provide an alternative user experience for notifications than that provided by the reference Android Open Source implementation.
  • [C-1-3] MUST honor and implement properly the behaviors described for the APIs to update, remove and group notifications.
  • [C-1-4] MUST provide the full behavior of the NotificationChannel API documented in the SDK.
  • [C-1-5] MUST provide a user affordance to block and modify a certain third-party app's notification per each channel and app package level.
  • [C-1-6] MUST also provide a user affordance to display deleted notification channels.
  • [C-1-7] MUST correctly render all resources (images, stickers, icons, etc.) provided through Notification.MessagingStyle alongside the notification text without additional user interaction. For example, MUST show all resources including icons provided through android.app.Person in a group conversation that is set through setGroupConversation .

  • [C-SR-1] Are STRONGLY RECOMMENDED to provide an affordance for the user to control the notifications that are exposed to apps that have been granted the Notification Listener permission. The granularity MUST be so that the user can control for each such notification listener what notification types are bridged to this listener. The types MUST include "conversations", "alerting", "silent", and "important ongoing" notifications.

  • [C-SR-2] Are STRONGLY RECOMMENDED provide an affordance for users to specify apps to exclude from notifying any specific notification listener.

  • [C-SR-3] Are STRONGLY RECOMMENDED to automatically surface a user affordance to block a certain third-party app's notification per each channel and app package level after the user dismisses that notification multiple times.

  • SHOULD support rich notifications.

  • SHOULD present some higher priority notifications as heads-up notifications.

  • SHOULD have a user affordance to snooze notifications.

  • MAY only manage the visibility and timing of when third-party apps can notify users of notable events to mitigate safety issues such as driver distraction.

Android 11 introduces support for conversation notifications, which are notifications that use MessagingStyle and provides a published People Shortcut ID.

Device implementations:

  • [C-SR-4] Are STRONGLY RECOMMENDED to group and display conversation notifications ahead of non conversation notifications with the exception of ongoing foreground service notifications and importance:high notifications.

If device implementations support conversation notifications and the app provides the required data for bubbles , they:

  • [C-SR-5] Are STRONGLY RECOMMENDED to display this conversation as a bubble. The AOSP implementation meets these requirements with the default System UI, Settings, and Launcher.

If device implementations support rich notifications, they:

  • [C-2-1] MUST use the exact resources as provided through the Notification.Style API class and its subclasses for the presented resource elements.
  • SHOULD present each and every resource element (eg icon, title and summary text) defined in the Notification.Style API class and its subclasses.

Heads up notifications are notifications that are presented to the user as they come in independently of the surface the user is on. If device implementations support heads-up notifications, then they:

  • [C-3-1] MUST use the heads-up notification view and resources as described in the Notification.Builder API class when heads-up notifications are presented.
  • [C-3-2] MUST display the actions provided through Notification.Builder.addAction() together with the notification content without additional user interaction as described in the SDK .
3.8.3.2. Notification Listener Service

Android includes the NotificationListenerService APIs that allow apps (once explicitly enabled by the user) to receive a copy of all notifications as they are posted or updated.

Device implementations:

  • [C-0-1] MUST correctly and promptly update notifications in their entirety to all such installed and user-enabled listener services, including any and all metadata attached to the Notification object.
  • [C-0-2] MUST respect the snoozeNotification() API call, and dismiss the notification and make a callback after the snooze duration that is set in the API call.

If device implementations have a user affordance to snooze notifications, they:

  • [C-1-1] MUST reflect the snoozed notification status properly through the standard APIs such as NotificationListenerService.getSnoozedNotifications() .
  • [C-1-2] MUST make this user affordance available to snooze notifications from each installed third-party app's, unless they are from persistent/foreground services.
3.8.3.3. DND (Do not Disturb) / Priority Mode

If device implementations support the DND feature (also called Priority Mode), they:

  • [C-1-1] MUST, for when the device implementation has provided a means for the user to grant or deny third-party apps to access the DND policy configuration, display Automatic DND rules created by applications alongside the user-created and pre-defined rules.
  • [C-1-3] MUST honor the suppressedVisualEffects values passed along the NotificationManager.Policy and if an app has set any of the SUPPRESSED_EFFECT_SCREEN_OFF or SUPPRESSED_EFFECT_SCREEN_ON flags, it SHOULD indicate to the user that the visual effects are suppressed in the DND settings menu.

Comienzan nuevos requisitos para 15 (AOSP experimental)

3.8.3.4. Sensitive Notification Protection

[3.8.3.4 Sensitive Notification Protection] (April 8, 2024 preview)

Device implementation:

  • [C-1-1] MUST include a Notification Assistant Service (NAS) that redacts sensitive information from notification content to notification listeners, unless the listener service is:

    • System signed apps with a uid < 10000
    • Interfaz de usuario del sistema
    • Caparazón
    • Designated Companion Device App (defined by CompanionDeviceManager )
    • SYSTEM_AUTOMOTIVE_PROJECTION role
    • SYSTEM_NOTIFICATION_INTELLIGENCE role
    • HOME role

The AOSP implementation of NotificationAssistantServices contained in ExtService meets these requirements.

Terminar con nuevos requisitos

[3.8.3.4 Sensitive Notification Protection] (February 26, 2024 preview)

Device implementation:

  • [C-1-1] MUST include a Notification Assistant Service (NAS) that redacts sensitive information from notification content to notification listeners, unless that service is:

    • System signed apps with a uid < 10000
    • SysUI
    • Caparazón
    • Designated Companion Device App (defined by CompanionDeviceManager )
    • SYSTEM_AUTOMOTIVE_PROJECTION role
    • SYSTEM_NOTIFICATION_INTELLIGENCE role
    • HOME role

The AOSP implementation of NotificationAssistantServices contained in ExtService meets these requirements.

Terminar con nuevos requisitos

[3.8.3.4 Sensitive Notification Protection] (February 5, 2024 preview)

Device implementation:

  • [C-1-1] MUST include a Notification Assistant Service (NAS) that redacts sensitive information from notification content to notification listeners, and MUST NOT send sensitive information to a non-exempt notification listener service unless that service is:

    • SysUI and system server app
    • Caparazón
    • Designated Companion Device App (as determined by the CompanionDeviceManager API)
    • SYSTEM_AUTOMOTIVE_PROJECTION role
    • SYSTEM_NOTIFICATION_INTELLIGENCE role
    • Notification being processed was sent by the same package as a particular NLS
    • HOME role

The AOSP implementation of NotificationAssistantServices contained in ExtService meets these requirements.

Terminar con nuevos requisitos

3.8.4. Assist APIs

Android includes the Assist APIs to allow applications to elect how much information of the current context is shared with the assistant on the device.

If device implementations support the Assist action, they:

  • [C-2-1] MUST indicate clearly to the end user when the context is shared, by either:
    • Each time the assist app accesses the context, displaying a white light around the edges of the screen that meet or exceed the duration and brightness of the Android Open Source Project implementation.
    • For the preinstalled assist app, providing a user affordance less than two navigations away from the default voice input and assistant app settings menu , and only sharing the context when the assist app is explicitly invoked by the user through a hotword or assist navigation key input.
  • [C-2-2] The designated interaction to launch the assist app as described in section 7.2.3 MUST launch the user-selected assist app, in other words the app that implements VoiceInteractionService , or an activity handling the ACTION_ASSIST intent.

3.8.5. Alerts and Toasts

Applications can use the Toast API to display short non-modal strings to the end user that disappear after a brief period of time, and use the TYPE_APPLICATION_OVERLAY window type API to display alert windows as an overlay over other apps.

If device implementations include a screen or video output, they:

  • [C-1-1] MUST provide a user affordance to block an app from displaying alert windows that use the TYPE_APPLICATION_OVERLAY . The AOSP implementation meets this requirement by having controls in the notification shade.

  • [C-1-2] MUST honor the Toast API and display Toasts from applications to end users in some highly visible manner.

3.8.6. Temas

Android provides "themes" as a mechanism for applications to apply styles across an entire Activity or application.

Android includes a "Holo" and "Material" theme family as a set of defined styles for application developers to use if they want to match the Holo theme look and feel as defined by the Android SDK.

If device implementations include a screen or video output, they:

  • [C-1-1] MUST NOT alter any of the Holo theme attributes exposed to applications.
  • [C-1-2] MUST support the "Material" theme family and MUST NOT alter any of the Material theme attributes or their assets exposed to applications.
  • [C-1-3] MUST either set the "sans-serif" font family to Roboto version 2.x for the languages that Roboto supports, or provide a user affordance to change the font used for the "sans-serif" font family to Roboto version 2.x for the languages that Roboto supports.

  • [C-1-4] MUST generate dynamic color tonal palettes as specified in the AOSP documentation of Settings.THEME_CUSTOMIZATION_OVERLAY_PACKAGES (see android.theme.customization.system_palette and android.theme.customization.theme_style ).

  • [C-1-5] MUST generate dynamic color tonal palettes using color theme styles enumerated in the Settings.THEME_CUSTOMIZATION_OVERLAY_PACKAGES documentation (see android.theme.customization.theme_styles ), namely TONAL_SPOT , VIBRANT , EXPRESSIVE , SPRITZ , RAINBOW , FRUIT_SALAD , and MONOCHROMATIC .

    "Source color" used to generate dynamic color tonal palettes when sent with android.theme.customization.system_palette (as documented in Settings.THEME_CUSTOMIZATION_OVERLAY_PACKAGES ).

  • [C-1-6] MUST have a CAM16 chroma value of 5 or larger.

    • SHOULD be derived from the wallpaper via com.android.systemui.monet.ColorScheme#getSeedColors , which provides multiple valid source colors to pick one from.

    • SHOULD use the value 0xFF1B6EF3 , if none of the provided colors meet the above source color requirement.

Android also includes a "Device Default" theme family as a set of defined styles for application developers to use if they want to match the look and feel of the device theme as defined by the device implementer.

Android supports a variant theme with translucent system bars, which allows application developers to fill the area behind the status and navigation bar with their app content. To enable a consistent developer experience in this configuration, it is important the status bar icon style is maintained across different device implementations.

If device implementations include a system status bar, they:

  • [C-2-1] MUST use white for system status icons (such as signal strength and battery level) and notifications issued by the system, unless the icon is indicating a problematic status or an app requests a light status bar using the WindowInsetsController#APPEARANCE_LIGHT_STATUS_BARS flag.
  • [C-2-2] Android device implementations MUST change the color of the system status icons to black (for details, refer to R.style ) when an app requests a light status bar.

3.8.7. Fondos de pantalla vivos

Android defines a component type and corresponding API and lifecycle that allows applications to expose one or more "Live Wallpapers" to the end user. Live wallpapers are animations, patterns, or similar images with limited input capabilities that display as a wallpaper, behind other applications.

Hardware is considered capable of reliably running live wallpapers if it can run all live wallpapers, with no limitations on functionality, at a reasonable frame rate with no adverse effects on other applications. If limitations in the hardware cause wallpapers and/or applications to crash, malfunction, consume excessive CPU or battery power, or run at unacceptably low frame rates, the hardware is considered incapable of running live wallpaper. As an example, some live wallpapers may use an OpenGL 2.0 or 3.x context to render their content. Live wallpaper will not run reliably on hardware that does not support multiple OpenGL contexts because the live wallpaper use of an OpenGL context may conflict with other applications that also use an OpenGL context.

  • Device implementations capable of running live wallpapers reliably as described above SHOULD implement live wallpapers.

If device implementations implement live wallpapers, they:

  • [C-1-1] MUST report the platform feature flag android.software.live_wallpaper.

3.8.8. Activity Switching

The upstream Android source code includes the overview screen , a system-level user interface for task switching and displaying recently accessed activities and tasks using a thumbnail image of the application's graphical state at the moment the user last left the application.

Device implementations including the recents function navigation key as detailed in section 7.2.3 MAY alter the interface.

Si las implementaciones del dispositivo, incluida la tecla de navegación de la función reciente, como se detalla en la sección 7.2.3, alteran la interfaz:

  • [C-1-1] MUST support at least up to 7 displayed activities.
  • SHOULD at least display the title of 4 activities at a time.
  • SHOULD display highlight color, icon, screen title in recents.
  • SHOULD display a closing affordance ("x") but MAY delay this until user interacts with screens.
  • SHOULD implement a shortcut to switch easily to the previous activity.
  • SHOULD trigger the fast-switch action between the two most recently used apps, when the recents function key is tapped twice.
  • SHOULD trigger the split-screen multiwindow-mode, if supported, when the recents functions key is long pressed.
  • MAY display affiliated recents as a group that moves together.
  • [C-SR-1] Are STRONGLY RECOMMENDED to use the upstream Android user interface (or a similar thumbnail-based interface) for the overview screen.

3.8.9. Input Management

Android includes support for Input Management and support for third-party input method editors.

If device implementations allow users to use third-party input methods on the device, they:

  • [C-1-1] MUST declare the platform feature android.software.input_methods and support IME APIs as defined in the Android SDK documentation.

3.8.10. Lock Screen Media Control

The Remote Control Client API is deprecated from Android 5.0 in favor of the Media Notification Template that allows media applications to integrate with playback controls that are displayed on the lock screen.

3.8.11. Screen savers (previously Dreams)

See section 3.2.3.5 for settings intent to congfigure screen savers.

3.8.12. Ubicación

If device implementations include a hardware sensor (eg GPS) that is capable of providing the location coordinates, they

3.8.13. Unicode and Font

Android includes support for the emoji characters defined in Unicode 10.0 .

If device implementations include a screen or video output, they:

  • [C-1-1] MUST be capable of rendering these emoji characters in color glyph.
  • [C-1-2] MUST include support for:
    • Roboto 2 font with different weights—sans-serif-thin, sans-serif-light, sans-serif-medium, sans-serif-black, sans-serif-condensed, sans-serif-condensed-light for the languages available on the dispositivo.
    • Full Unicode 7.0 coverage of Latin, Greek, and Cyrillic, including the Latin Extended A, B, C, and D ranges, and all glyphs in the currency symbols block of Unicode 7.0.
  • [C-1-3] MUST NOT remove or modify NotoColorEmoji.tff in the system image. (It is acceptable to add a new emoji font to override emoji in NotoColorEmoji.tff)
  • SHOULD support the skin tone and diverse family emojis as specified in the Unicode Technical Report #51 .

If device implementations include an IME, they:

  • SHOULD provide an input method to the user for these emoji characters.

Android includes support to render Myanmar fonts. Myanmar has several non-Unicode compliant fonts, commonly known as "Zawgyi," for rendering Myanmar languages.

If device implementations include support for Burmese, they:

  • [C-2-1] MUST render text with Unicode compliant font as default; non-Unicode compliant font MUST NOT be set as default font unless the user chooses it in the language picker.
  • [C-2-2] MUST support a Unicode font and a non-Unicode compliant font if a non-Unicode compliant font is supported on the device. Non-Unicode compliant font MUST NOT remove or overwrite the Unicode font.
  • [C-2-3] MUST render text with non-Unicode compliant font ONLY IF a language code with script code Qaag is specified (eg my-Qaag). No other ISO language or region codes (whether assigned, unassigned, or reserved) can be used to refer to non-Unicode compliant font for Myanmar. App developers and web page authors can specify my-Qaag as the designated language code as they would for any other language.

3.8.14. Ventanas múltiples

If device implementations have the capability to display multiple activities at the same time, they:

  • [C-1-1] MUST implement such multi-window mode(s) in accordance with the application behaviors and APIs described in the Android SDK multi-window mode support documentation and meet the following requirements:
  • [C-1-2] MUST honor android:resizeableActivity that is set by an app in the AndroidManifest.xml file as described in this SDK .
  • [C-1-3] MUST NOT offer split-screen or freeform mode if the screen height is less than 440 dp and the screen width is less than 440 dp.
  • [C-1-4] An activity MUST NOT be resized to a size smaller than 220dp in multi-window modes other than Picture-in-Picture.
  • Las implementaciones de dispositivos con tamaño de pantalla xlarge DEBEN admitir el modo de forma libre.

If device implementations support multi-window mode(s), and the split screen mode, they:

  • [C-2-2] MUST crop the docked activity of a split-screen multi-window but SHOULD show some content of it, if the Launcher app is the focused window.
  • [C-2-3] MUST honor the declared AndroidManifestLayout_minWidth and AndroidManifestLayout_minHeight values of the third-party launcher application and not override these values in the course of showing some content of the docked activity.

If device implementations support multi-window mode(s) and Picture-in-Picture multi-window mode, they:

  • [C-3-1] MUST launch activities in picture-in-picture multi-window mode when the app is: * Targeting API level 26 or higher and declares android:supportsPictureInPicture * Targeting API level 25 or lower and declares both android:resizeableActivity and android:supportsPictureInPicture .
  • [C-3-2] MUST expose the actions in their SystemUI as specified by the current PIP activity through the setActions() API.
  • [C-3-3] MUST support aspect ratios greater than or equal to 1:2.39 and less than or equal to 2.39:1, as specified by the PIP activity through the setAspectRatio() API.
  • [C-3-4] MUST use KeyEvent.KEYCODE_WINDOW to control the PIP window; if PIP mode is not implemented, the key MUST be available to the foreground activity.
  • [C-3-5] MUST provide a user affordance to block an app from displaying in PIP mode; the AOSP implementation meets this requirement by having controls in the notification shade.
  • [C-3-6] MUST allocate the following minimum width and height for the PIP window when an application does not declare any value for AndroidManifestLayout_minWidth and AndroidManifestLayout_minHeight :

    • Devices with the Configuration.uiMode that is set other than UI_MODE_TYPE_TELEVISION MUST allocate a minimum width and height of 108 dp.
    • Devices with the Configuration.uiMode that is set to UI_MODE_TYPE_TELEVISION MUST allocate a minimum width of 240 dp and a minimum height of 135 dp.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-4-1 and C-5-1] (February 5, 2024 preview)

If device implementations include one or more foldable Android-compatible display areas, or include a folding hinge between multiple Android-compatible display areas and make such areas available to applications, they:

  • [C-4-1] MUST support multi-window mode.

If device implementations support multi-window mode, they:

  • [C-5-1] MUST implement the correct version of the Window Manager Extensions API level as described in WindowManager Extensions .

Terminar con nuevos requisitos

3.8.15. Recorte de pantalla

Android supports a Display Cutout as described in the SDK document. The DisplayCutout API defines an area on the edge of the display that may not be functional for an application due to a display cutout or curved display on the edge(s).

If device implementations include display cutout(s), they:

  • [C-1-5] MUST NOT have cutout(s) if the device's aspect ratio is 1.0(1:1).
  • [C-1-2] MUST NOT have more than one cutout per edge.
  • [C-1-3] MUST honor the display cutout flags set by the app through the WindowManager.LayoutParams API as described in the SDK.
  • [C-1-4] MUST report correct values for all cutout metrics defined in the DisplayCutout API.

3.8.16. Controles del dispositivo

Android includes ControlsProviderService and Control APIs to allow third-party applications to publish device controls for quick status and action for users.

See Section 2_2_3 for device-specific requirements.

3.8.17. Portapapeles

Device implementations:

  • [C-0-1] MUST NOT send clipboard data to any component, activity, service, or across any network connection, without explicit user action (eg, pressing a button on the overlay), except for services mentioned in 9.8.6 Content Capture and App Search .

If device implementations generate a user-visible preview when content is copied to the clipboard for any ClipData item where ClipData.getDescription().getExtras() contains android.content.extra.IS_SENSITIVE , they:

  • [C-1-1] MUST redact the user visible preview

The AOSP reference implementation satisfies these clipboard requirements.

Comienzan nuevos requisitos para 15 (AOSP experimental)

3.8.18. Localization and Language Selection [Withdrawn]

3.8.18 [Withdrawn] (April 8, 2024 preview)

Este requisito se retira de Android 15 (AOSP experimental).

Terminar con nuevos requisitos

3.8.18 (February 5, 2024 preview)

If device implementations support multiple locales or languages, they:

Terminar con nuevos requisitos

3.9. Administración de dispositivos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[3.9/C-1-1 and C-1-2] (February 26, 2024 preview)

Android includes features that allow security-aware applications enable device policy controller applications to perform device administration functions at the system level, such as enforcing password policies or performing remote wipe, through the Android Device Administration API Device Policy Manager APIs .

If device implementations implement the full range of device administration policies defined in the Android SDK documentation, they:

  • [C-1-1] MUST declare android.software.device_admin .
  • [C-1-2] MUST support device owner provisioning as described in section 3.9.1 and section 3.9.1.1 .

Terminar con nuevos requisitos

3.9.1. Aprovisionamiento de dispositivos

3.9.1.1. Device owner provisioning

If device implementations declare android.software.device_admin , they:

  • [C-1-1] MUST support enrolling a Device Policy Client (DPC) as a Device Owner app as described below:
    • When the device implementation has neither users nor user data configured, it:
      • [C-1-5] MUST enroll the DPC application as the Device Owner app or enable the DPC app to choose whether to become a Device Owner or a Profile Owner, if the device declares Near-Field Communications (NFC) support via the feature flag android.hardware.nfc and receives an NFC message containing a record with MIME type MIME_TYPE_PROVISIONING_NFC .
      • [C-1-8] MUST send the ACTION_GET_PROVISIONING_MODE intent after device owner provisioning is triggered so that the DPC app can choose whether to become a Device Owner or a Profile Owner, depending on the values of android.app.extra.PROVISIONING_ALLOWED_PROVISIONING_MODES , unless it can be determined from context that there is only one valid option.
      • [C-1-9] MUST send the ACTION_ADMIN_POLICY_COMPLIANCE intent to the Device Owner app if a Device Owner is established during provisioning regardless of the provisioning method used. The user must not be able to proceed in the Setup Wizard until the Device Owner app finishes.
    • When the device implementation has users or user data, it:
      • [C-1-7] MUST not enroll any DPC application as the Device Owner App any more.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-2 through C-2-3] (February 26, 2024 preview)

  • [C-1-2] MUST show an appropriate disclosure notice (such as referenced in AOSP ) and obtain affirmative consent from the end user prior to an app being set as Device Owner, unless the device is programmatically configured for Retail Demo Mode prior to on-screen, end-user interaction. If device implementations declare android.software.device_admin , but also include a proprietary device management solution and provide a mechanism to promote an application configured in their solution as a "Device Owner equivalent" to the standard "Device Owner" as recognized by the standard Android DevicePolicyManager APIs, they:

  • [C-2-1] MUST have a process in place to verify that the specific app being promoted belongs to a legitimate enterprise device management solution and has been configured in the proprietary solution to have the rights equivalent as a "Device Owner".

  • [C-2-2] MUST show the same AOSP Device Owner consent disclosure as the flow initiated by android.app.action.PROVISION_MANAGED_DEVICE prior to enrolling the DPC application as "Device Owner".

  • [C-2-3] MUST NOT hard code the consent or prevent the use of other device owner apps.

Terminar con nuevos requisitos

3.9.1.2. Managed profile provisioning

If device implementations declare android.software.managed_users , they:

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-2] (February 26, 2024 preview)

  • [C-1-2] The managed profile provisioning process (the flow initiated by the DPC using the android.app.action.PROVISION_MANAGED_PROFILE ) or by the platform), consent screen and user experience MUST align with the AOSP implementation.

Terminar con nuevos requisitos

3.9.2. Managed Profile Support

If device implementations declare android.software.managed_users , they:

  • [C-1-1] MUST support managed profiles via the android.app.admin.DevicePolicyManager APIs.
  • [C-1-2] MUST allow one and only one managed profile to be created .
  • [C-1-3] MUST use an icon badge (similar to the AOSP upstream work badge) to represent the managed applications and widgets and other badged UI elements like Recents & Notifications.
  • [C-1-4] MUST display a notification icon (similar to the AOSP upstream work badge) to indicate when user is within a managed profile application.
  • [C-1-5] MUST display a toast indicating that the user is in the managed profile if and when the device wakes up (ACTION_USER_PRESENT) and the foreground application is within the managed profile.
  • [C-1-6] Where a managed profile exists, MUST show a visual affordance in the Intent 'Chooser' to allow the user to forward the intent from the managed profile to the primary user or vice versa, if enabled by the Device Policy Controlador.
  • [C-1-7] Where a managed profile exists, MUST expose the following user affordances for both the primary user and the managed profile:
    • Separate accounting for battery, location, mobile data and storage usage for the primary user and managed profile.
    • Independent management of VPN Applications installed within the primary user or managed profile.
    • Independent management of applications installed within the primary user or managed profile.
    • Independent management of accounts within the primary user or managed profile.
  • [C-1-8] MUST ensure the preinstalled dialer, contacts and messaging applications can search for and look up caller information from the managed profile (if one exists) alongside those from the primary profile, if the Device Policy Controller permits it.
  • [C-1-9] MUST ensure that it satisfies all the security requirements applicable for a device with multiple users enabled (see section 9.5 ), even though the managed profile is not counted as another user in addition to the primary user.
  • [C-1-10] MUST ensure that the screenshot data is saved in the work profile storage when a screenshot is captured with a topActivity window that has focus (the one the user interacted with last among all activities) and belongs to a work profile aplicación .
  • [C-1-11] MUST NOT capture any other screen content (system bar, notifications or any personal profile content) except for the work profile application window/windows when saving a screenshot to the work profile (to ensure that personal profile data is not saved in the work profile).

If device implementations declare android.software.managed_users and android.software.secure_lock_screen , they:

  • [C-2-1] MUST support the ability to specify a separate lock screen meeting the following requirements to grant access to apps running in a managed profile only.
  • When contacts from the managed profile are displayed in the preinstalled call log, in-call UI, in-progress and missed-call notifications, contacts and messaging apps they SHOULD be badged with the same badge used to indicate managed profile applications.

3.9.3. Managed User Support

If device implementations declare android.software.managed_users , they:

  • [C-1-1] MUST provide a user affordance to logout from the current user and switch back to the primary user in multiple-user session when isLogoutEnabled returns true . The user affordance MUST be accessible from the lockscreen without unlocking the device.

If device implementations declare android.software.device_admin and provide an on-device user affordance to add additional secondary Users , they:

  • [C-SR-1] Are STRONGLY RECOMMENDED show the same AOSP Device Owner consent disclosures that were shown in the flow initiated by android.app.action.PROVISION_MANAGED_DEVICE , prior to allowing accounts to be added in the new secondary User, so users understand that the device is managed.

3.9.4. Device Policy Management Role Requirements

If device implementations report android.software.device_admin or android.software.managed_users , then they:

  • [C-1-1] MUST support the device policy management role as defined in section 9.1 . The application that holds the device policy management role MAY be defined by setting config_devicePolicyManagement to the package name. The package name MUST be followed by : and the signing certificate unless the application is preloaded.

If a package name is not defined for config_devicePolicyManagement as described above:

If a package name is defined for config_devicePolicyManagement as described above:

  • [C-3-1] The application MUST be installed on all profiles for a user .
  • [C-3-2] Device implementations MAY define an application that updates the device policy management role holder before provisioning by setting config_devicePolicyManagementUpdater .

If a package name is defined for config_devicePolicyManagementUpdater as described above:

  • [C-4-1] The application MUST be preinstalled on the device.
  • [C-4-2] The application MUST implement an intent filter which resolves android.app.action.UPDATE_DEVICE_POLICY_MANAGEMENT_ROLE_HOLDER .

3.9.5. Device Policy Resolution Framework

If device implementations report android.software.device_admin or android.software.managed_users , then they:

3.10. Accesibilidad

Android provides an accessibility layer that helps users with disabilities to navigate their devices more easily. In addition, Android provides platform APIs that enable accessibility service implementations to receive callbacks for user and system events and generate alternate feedback mechanisms, such as text-to-speech, haptic feedback, and trackball/d-pad navigation.

If device implementations support third-party accessibility services, they:

  • [C-1-1] MUST provide an implementation of the Android accessibility framework as described in the accessibility APIs SDK documentation.
  • [C-1-2] MUST generate accessibility events and deliver the appropriate AccessibilityEvent to all registered AccessibilityService implementations as documented in the SDK.
  • [C-1-4] MUST provide a user affordance to control accessibility services that declare the AccessibilityServiceInfo.FLAG_REQUEST_ACCESSIBILITY_BUTTON . Note that for device implementations with a system navigation bar, they SHOULD allow the user to have the option for a button in the system's navigation bar to control these services.

If device implementations include preinstalled accessibility services, they:

  • [C-2-1] MUST implement these preinstalled accessibility services as Direct Boot Aware apps when the data storage is encrypted with File Based Encryption (FBE).
  • SHOULD provide a mechanism in the out-of-box setup flow for users to enable relevant accessibility services, as well as options to adjust the font size, display size and magnification gestures.

3.11. Texto a voz

Android includes APIs that allow applications to make use of text-to-speech (TTS) services and allows service providers to provide implementations of TTS services.

If device implementations reporting the feature android.hardware.audio.output, they:

If device implementations support installation of third-party TTS engines, they:

  • [C-2-1] MUST provide user affordance to allow the user to select a TTS engine for use at system level.

Comienzan nuevos requisitos para 15 (AOSP experimental)

3.12. TV Input Framework

[3.12] (February 26, 2024 preview)

El Android Television Input Framework (TIF) simplifica la entrega de contenido en vivo a dispositivos de televisión Android. TIF proporciona una API estándar para crear módulos de entrada que controlan los dispositivos de televisión Android.

If device implementations support TIF, they:

  • [C-1-1] MUST declare the platform feature android.software.live_tv .
  • [C-1-2] MUST support all TIF APIs such that an application which uses these APIs and the third-party TIF-based inputs service can be installed and used on the device.

Terminar con nuevos requisitos

3.13. Ajustes rápidos

Android provides a Quick Settings UI component that allows quick access to frequently used or urgently needed actions.

If device implementations include a Quick Settings UI component and support third-party Quick Settings, they:

  • [C-1-1] MUST allow the user to add or remove the tiles provided through the quicksettings APIs from a third-party app.
  • [C-1-2] MUST NOT automatically add a tile from a third-party app directly to the Quick Settings.
  • [C-1-3] MUST display all the user-added tiles from third-party apps alongside the system-provided quick setting tiles.

3.14. Media UI

If device implementations include non-voice-activated applications (the Apps) that interact with third-party applications through MediaBrowser or MediaSession , the Apps:

  • [C-1-2] MUST clearly display icons obtained via getIconBitmap() or getIconUri() and titles obtained via getTitle() as described in MediaDescription . May shorten titles to comply with safety regulations (eg driver distraction).

  • [C-1-3] MUST show the third-party application icon whenever displaying content provided by this third-party application.

  • [C-1-4] MUST allow the user to interact with the entire MediaBrowser hierarchy. MAY restrict the access to part of the hierarchy to comply with safety regulations (eg driver distraction), but MUST NOT give preferential treatment based on content or content provider.

  • [C-1-5] MUST consider double tap of KEYCODE_HEADSETHOOK or KEYCODE_MEDIA_PLAY_PAUSE as KEYCODE_MEDIA_NEXT for MediaSession.Callback#onMediaButtonEvent .

3.15. Aplicaciones instantáneas

If device implementations support Instant Apps, they MUST satisfy the following requirements:

  • [C-1-1] Instant Apps MUST only be granted permissions that have the android:protectionLevel set to "instant" .
  • [C-1-2] Instant Apps MUST NOT interact with installed apps via implicit intents unless one of the following is true:
    • The component's intent pattern filter is exposed and has CATEGORY_BROWSABLE
    • The action is one of ACTION_SEND, ACTION_SENDTO, ACTION_SEND_MULTIPLE
    • The target is explicitly exposed with android:visibleToInstantApps
  • [C-1-3] Instant Apps MUST NOT interact explicitly with installed apps unless the component is exposed via android:visibleToInstantApps.
  • [C-1-4] Installed Apps MUST NOT see details about Instant Apps on the device unless the Instant App explicitly connects to the installed application.
  • Device implementations MUST provide the following user affordances for interacting with Instant Apps. The AOSP meets the requirements with the default System UI, Settings, and Launcher. Device implementations:

    • [C-1-5] MUST provide a user affordance to view and delete Instant Apps locally cached for each individual app package.
    • [C-1-6] MUST provide a persistent user notification that can be collapsed while an Instant App is running in the foreground. This user notification MUST include that Instant Apps do not require installation and provide a user affordance that directs the user to the application info screen in Settings. For Instant Apps launched via web intents, as defined by using an intent with action set to Intent.ACTION_VIEW and with a scheme of "http" or "https", an additional user affordance SHOULD allow the user not to launch the Instant App and launch the associated link with the configured web browser, if a browser is available on the device.
    • [C-1-7] MUST allow running Instant Apps to be accessed from the Recents function if the Recents function is available on the device.
  • [C-1-8] MUST preload one or more applications or service components with an intent handler for the intents listed in the SDK here and make the intents visible for Instant Apps.

3.16. Companion Device Pairing

Android includes support for companion device pairing to more effectively manage association with companion devices and provides the CompanionDeviceManager API for apps to access this feature.

If device implementations support the companion device pairing feature, they:

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-3] (February 5, 2024 preview)

  • [C-1-3] MUST provide user affordances for the user to select/confirm a companion device is present and operational , which MUST use the same message as implemented in AOSP without addition or modification .

Terminar con nuevos requisitos

3.17. Aplicaciones pesadas

If device implementations declare the feature FEATURE_CANT_SAVE_STATE , then they:

  • [C-1-1] MUST have only one installed app that specifies cantSaveState running in the system at a time. If the user leaves such an app without explicitly exiting it (for example by pressing home while leaving an active activity the system, instead of pressing back with no remaining active activities in the system), then device implementations MUST prioritize that app in RAM as they do for other things that are expected to remain running, such as foreground services. While such an app is in the background, the system can still apply power management features to it, such as limiting CPU and network access.
  • [C-1-2] MUST provide a UI affordance to chose the app that won't participate in the normal state save/restore mechanism once the user launches a second app declared with cantSaveState attribute.
  • [C-1-3] MUST NOT apply other changes in policy to apps that specify cantSaveState , such as changing CPU performance or changing scheduling prioritization.

If device implementations don't declare the feature FEATURE_CANT_SAVE_STATE , then they:

  • [C-1-1] MUST ignore the cantSaveState attribute set by apps and MUST NOT change the app behavior based on that attribute.

3.18. Contactos

Android includes Contacts Provider APIs to allow applications to manage contact information stored on the device. Contact data that is entered directly into the device is typically synchronized with a web service, but the data MAY also only reside locally on the device. Contacts that are only stored on the device are referred to as local contacts.

RawContacts are "associated with" or "stored in" an Account when the ACCOUNT_NAME , and ACCOUNT_TYPE , columns for the raw contacts match the corresponding Account.name and Account.type fields of the account.

Default local account : an account for raw contacts that are only stored on the device and not associated with an Account in the AccountManager , which are created with null values for the ACCOUNT_NAME , and ACCOUNT_TYPE , columns.

Custom local account : an account for raw contacts that are only stored on the device and not associated with an Account in the AccountManager, which are created with at least one non-null value for the ACCOUNT_NAME , and ACCOUNT_TYPE , columns.

Device implementations:

  • [C-SR-1] Are STRONGLY RECOMMENDED to not create custom local accounts .

If device implementations use a custom local account :

  • [C-1-1] The ACCOUNT_NAME , of the custom local account MUST be returned by ContactsContract.RawContacts.getLocalAccountName
  • [C-1-2] The ACCOUNT_TYPE , of the custom local account MUST be returned by ContactsContract.RawContacts.getLocalAccountType
  • [C-1-3] Raw contacts that are inserted by third party applications with the default local account (ie by setting null values for ACCOUNT_NAME and ACCOUNT_TYPE ) MUST be inserted to the custom local account .
  • [C-1-4] Raw contacts inserted into the custom local account MUST not be removed when accounts are added or removed.
  • [C-1-5] Delete operations performed against the custom local account MUST result in raw contacts being purged immediately (as if the CALLER_IS_SYNCADAPTER param was set to true), even if the CALLER\_IS\_SYNCADAPTER param was set to false or not especificado.

Comienzan nuevos requisitos para 15 (AOSP experimental)

3.19. Ajustes de idioma

[3.19. Language Settings] (February 26, 2024 preview)

Device implementations:

  • [C-0-1] MUST NOT provide any user affordance to select gender-specific language treatment for languages that do not support gender specific translations. See grammatical resources for more information.

Terminar con nuevos requisitos

4. Application Packaging Compatibility

Devices implementations:

  • [C-0-1] MUST be capable of installing and running Android ".apk" files as generated by the "aapt" tool included in the official Android SDK .

    • As the above requirement may be challenging, device implementations are RECOMMENDED to use the AOSP reference implementation's package management system.
  • [C-0-2] MUST support verifying ".apk" files using the APK Signature Scheme v3.1, APK Signature Scheme v3 , APK Signature Scheme v2 and JAR signing .

  • [C-0-3] MUST NOT extend either the .apk , Android Manifest , Dalvik bytecode , or RenderScript bytecode formats in such a way that would prevent those files from installing and running correctly on other compatible devices.

  • [C-0-4] MUST NOT allow apps other than the current "installer of record" for the package to silently uninstall the app without any user confirmation, as documented in the SDK for the DELETE_PACKAGE permission. The only exceptions are the system package verifier app handling PACKAGE_NEEDS_VERIFICATION intent and the storage manager app handling ACTION_MANAGE_STORAGE intent.

  • [C-0-5] MUST have an activity that handles the android.settings.MANAGE_UNKNOWN_APP_SOURCES intent.

  • [C-0-6] MUST NOT install application packages from unknown sources, unless the app that requests the installation meets all the following requirements:

    • It MUST declare the REQUEST_INSTALL_PACKAGES permission or have the android:targetSdkVersion set at 24 or lower.
    • It MUST have been granted permission by the user to install apps from unknown sources.
  • SHOULD provide a user affordance to grant/revoke the permission to install apps from unknown sources per application, but MAY choose to implement this as a no-op and return RESULT_CANCELED for startActivityForResult() , if the device implementation does not want to allow users to have this choice. However, even in such cases, they SHOULD indicate to the user why there is no such choice presented.

  • [C-0-7] MUST display a warning dialog with the warning string that is provided through the system API PackageManager.setHarmfulAppWarning to the user before launching an activity in an application that has been marked by the same system API PackageManager.setHarmfulAppWarning as potentially dañino.

  • SHOULD provide a user affordance to choose to uninstall or launch an application on the warning dialog.

  • [C-0-8] MUST implement support for Incremental File System as documented here .

  • [C-0-9] MUST support verifying .apk files using the APK Signature Scheme v4 and APK Signature Scheme v4.1.

5. Multimedia Compatibility

Device implementations:

  • [C-0-1] MUST support the media formats, encoders, decoders, file types, and container formats defined in section 5.1 for each and every codec declared by MediaCodecList .
  • [C-0-2] MUST declare and report support of the encoders, decoders available to third-party applications via MediaCodecList .
  • [C-0-3] MUST be able to properly decode and make available to third-party apps all the formats it can encode. This includes all bitstreams that its encoders generate and the profiles reported in its CamcorderProfile .

Device implementations:

  • SHOULD aim for minimum codec latency, in others words, they
    • SHOULD NOT consume and store input buffers and return input buffers only once processed.
    • SHOULD NOT hold onto decoded buffers for longer than as specified by the standard (eg SPS).
    • SHOULD NOT hold onto encoded buffers longer than required by the GOP structure.

All of the codecs listed in the section below are provided as software implementations in the preferred Android implementation from the Android Open Source Project.

Please note that neither Google nor the Open Handset Alliance make any representation that these codecs are free from third-party patents. Those intending to use this source code in hardware or software products are advised that implementations of this code, including in open source software or shareware, may require patent licenses from the relevant patent holders.

5.1. Códecs multimedia

5.1.1. Codificación de audio

See more details in 5.1.3. Audio Codecs Details .

If device implementations declare android.hardware.microphone , they MUST support encoding the following audio formats and make them available to third-party apps:

  • [C-1-1] PCM/WAVE
  • [C-1-2] FLAC
  • [C-1-3] Opus

All audio encoders MUST support:

5.1.2. Decodificación de audio

See more details in 5.1.3. Audio Codecs Details .

If device implementations declare support for the android.hardware.audio.output feature, they must support decoding the following audio formats:

  • [C-1-1] MPEG-4 AAC Profile (AAC LC)
  • [C-1-2] MPEG-4 HE AAC Profile (AAC+)
  • [C-1-3] MPEG-4 HE AACv2 Profile (enhanced AAC+)
  • [C-1-4] AAC ELD (enhanced low delay AAC)
  • [C-1-11] xHE-AAC (ISO/IEC 23003-3 Extended HE AAC Profile, which includes the USAC Baseline Profile, and ISO/IEC 23003-4 Dynamic Range Control Profile)
  • [C-1-5] FLAC
  • [C-1-6] MP3
  • [C-1-7] MIDI
  • [C-1-8] Vorbis
  • [C-1-9] PCM/WAVE including high-resolution audio formats up to 24 bits, 192 kHz sample rate, and 8 channels. Note that this requirement is for decoding only, and that a device is permitted to downsample and downmix during the playback phase.
  • [C-1-10] Opus

If device implementations support the decoding of AAC input buffers of multichannel streams (ie more than two channels) to PCM through the default AAC audio decoder in the android.media.MediaCodec API, the following MUST be supported:

  • [C-2-1] Decoding MUST be performed without downmixing (eg a 5.0 AAC stream must be decoded to five channels of PCM, a 5.1 AAC stream must be decoded to six channels of PCM).
  • [C-2-2] Dynamic range metadata MUST be as defined in "Dynamic Range Control (DRC)" in ISO/IEC 14496-3, and the android.media.MediaFormat DRC keys to configure the dynamic range-related behaviors of the audio decoder. The AAC DRC keys were introduced in API 21, and are: KEY_AAC_DRC_ATTENUATION_FACTOR , KEY_AAC_DRC_BOOST_FACTOR , KEY_AAC_DRC_HEAVY_COMPRESSION , KEY_AAC_DRC_TARGET_REFERENCE_LEVEL and KEY_AAC_ENCODED_TARGET_LEVEL .
  • [C-SR-1] It is STRONGLY RECOMMENDED that requirements C-2-1 and C-2-2 above are satisfied by all AAC audio decoders.

When decoding USAC audio, MPEG-D (ISO/IEC 23003-4):

  • [C-3-1] Loudness and DRC metadata MUST be interpreted and applied according to MPEG-D DRC Dynamic Range Control Profile Level 1.
  • [C-3-2] The decoder MUST behave according to the configuration set with the following android.media.MediaFormat keys: KEY_AAC_DRC_TARGET_REFERENCE_LEVEL and KEY_AAC_DRC_EFFECT_TYPE .

MPEG-4 AAC, HE AAC, and HE AACv2 profile decoders:

  • MAY support loudness and dynamic range control using ISO/IEC 23003-4 Dynamic Range Control Profile.

If ISO/IEC 23003-4 is supported and if both ISO/IEC 23003-4 and ISO/IEC 14496-3 metadata are present in a decoded bitstream, then:

  • ISO/IEC 23003-4 metadata SHALL take precedence.

All audio decoders MUST support outputting:

If device implementations support the decoding of AAC input buffers of multichannel streams (ie more than two channels) to PCM through the default AAC audio decoder in the android.media.MediaCodec API, then the following MUST be supported:

  • [C-7-1] MUST be able to be configured by the application using the decoding with the key KEY_MAX_OUTPUT_CHANNEL_COUNT to control whether the content is downmixed to stereo (when using a value of 2) or is output using the native number of channels (when using a value equal or greater to that number). For instance a value of 6 or greater would configure a decoder to output 6 channels when fed 5.1 content.
  • [C-7-2] When decoding, the decoder MUST advertise the channel mask being used on the output format with the KEY_CHANNEL_MASK key, using the android.media.AudioFormat constants (example: CHANNEL_OUT_5POINT1 ).

If device implementations support audio decoders other than the default AAC audio decoder and are capable of outputting multi-channel audio (ie more than 2 channels) when fed compressed multi-channel content, then:

  • [C-SR-2] The decoder is STRONGLY RECOMMENDED to be able to be configured by the application using the decoding with the key KEY_MAX_OUTPUT_CHANNEL_COUNT to control whether the content is downmixed to stereo (when using a value of 2) or is output using the native number of channels (when using a value equal or greater to that number). For instance a value of 6 or greater would configure a decoder to output 6 channels when fed 5.1 content.
  • [C-SR-3] When decoding, the decoder is STRONGLY RECOMMENDED to advertise the channel mask being used on the output format with the KEY_CHANNEL_MASK key, using the android.media.AudioFormat constants (example: CHANNEL_OUT_5POINT1 ).

5.1.3. Audio Codecs Details

Format/Codec Detalles File Types/Container Formats to be supported
MPEG-4 AAC Profile
(AAC LC)
Compatibilidad con contenido mono/estéreo/5.0/5.1 con frecuencias de muestreo estándar de 8 a 48 kHz.
  • 3GPP (.3gp)
  • MPEG-4 (.mp4, .m4a)
  • ADTS raw AAC (.aac, ADIF not supported)
  • MPEG-TS (.ts, not seekable, decode only)
  • Matroska (.mkv, decode only)
MPEG-4 HE AAC Profile (AAC+) Compatibilidad con contenido mono/estéreo/5.0/5.1 con frecuencias de muestreo estándar de 16 a 48 kHz.
  • 3GPP (.3gp)
  • MPEG-4 (.mp4, .m4a)
MPEG-4 HE AACv2
Profile (enhanced AAC+)
Compatibilidad con contenido mono/estéreo/5.0/5.1 con frecuencias de muestreo estándar de 16 a 48 kHz.
  • 3GPP (.3gp)
  • MPEG-4 (.mp4, .m4a)
AAC ELD (enhanced low delay AAC) Soporte para contenido mono/estéreo con frecuencias de muestreo estándar de 16 a 48 kHz.
  • 3GPP (.3gp)
  • MPEG-4 (.mp4, .m4a)
USAC Soporte para contenido mono/estéreo con frecuencias de muestreo estándar de 7,35 a 48 kHz. MPEG-4 (.mp4, .m4a)
AMR-NB 4.75 to 12.2 kbps sampled @ 8 kHz 3GPP (.3gp)
AMR-WB 9 rates from 6.60 kbit/s to 23.85 kbit/s sampled @ 16 kHz, as defined at AMR-WB, Adaptive Multi-Rate - Wideband Speech Codec 3GPP (.3gp)
FLAC For both encoder and decoder: at least Mono and Stereo modes MUST be supported. Sample rates up to 192 kHz MUST be supported; 16-bit and 24-bit resolution MUST be supported. FLAC 24-bit audio data handling MUST be available with floating point audio configuration.
  • FLAC (.flac)
  • MPEG-4 (.mp4, .m4a, decode only)
  • Matroska (.mkv, decode only)
MP3 Mono/Stereo 8-320Kbps constant (CBR) or variable bitrate (VBR)
  • MP3 (.mp3)
  • MPEG-4 (.mp4, .m4a, decode only)
  • Matroska (.mkv, decode only)
midi MIDI Type 0 and 1. DLS Version 1 and 2. XMF and Mobile XMF. Support for ringtone formats RTTTL/RTX, OTA, and iMelody
  • Type 0 and 1 (.mid, .xmf, .mxmf)
  • RTTTL/RTX (.rtttl, .rtx)
  • iMelody (.imy)
Vorbis
  • Ogg (.ogg)
  • MPEG-4 (.mp4, .m4a, decode only)
  • Matroska (.mkv)
  • Webm (.webm)
PCM/WAVE PCM codec MUST support 16-bit linear PCM and 16-bit float. WAVE extractor must support 16-bit, 24-bit, 32-bit linear PCM and 32-bit float (rates up to limit of hardware). Sampling rates MUST be supported from 8 kHz to 192 kHz. WAVE (.wav)
Opus Decoding: Support for mono, stereo, 5.0 and 5.1 content with sampling rates of 8000, 12000, 16000, 24000, and 48000 Hz.
Encoding: Support for mono and stereo content with sampling rates of 8000, 12000, 16000, 24000, and 48000 Hz.
  • Ogg (.ogg)
  • MPEG-4 (.mp4, .m4a, decode only)
  • Matroska (.mkv)
  • Webm (.webm)

5.1.4. Image Encoding

See more details in 5.1.6. Image Codecs Details .

Device implementations MUST support encoding the following image encoding:

  • [C-0-1] JPEG
  • [C-0-2] PNG
  • [C-0-3] WebP
  • [C-0-4] AVIF
    • Devices must support BITRATE_MODE_CQ and Baseline Profile.

If device implementations support HEIC encoding via android.media.MediaCodec for media type MIMETYPE_IMAGE_ANDROID_HEIC , they:

5.1.5. Image Decoding

See more details in 5.1.6. Image Codecs Details .

Device implementations MUST support decoding the following image encoding:

  • [C-0-1] JPEG
  • [C-0-2] GIF
  • [C-0-3] PNG
  • [C-0-4] BMP
  • [C-0-5] WebP
  • [C-0-6] Raw
  • [C-0-7] AVIF (Baseline Profile)

If device implementations support HEVC video decoding, they: * [C-1-1] MUST support HEIF (HEIC) image decoding.

Image decoders that support a high bit-depth format (9+ bits per channel):

  • [C-2-1] MUST support outputting an 8-bit equivalent format if requested by the application, for example, via the ARGB_8888 config of android.graphics.Bitmap .

5.1.6. Image Codecs Details

Format/Codec Detalles Supported File Types/Container Formats
JPEG Base+progressive JPEG (.jpg)
GIF GIF (.gif)
PNG PNG (.png)
BMP BMP (.bmp)
WebP WebP (.webp)
Crudo ARW (.arw), CR2 (.cr2), DNG (.dng), NEF (.nef), NRW (.nrw), ORF (.orf), PEF (.pef), RAF (.raf), RW2 (.rw2), SRW (.srw)
HEIF Image, Image collection, Image sequence HEIF (.heif), HEIC (.heic)
AVIF (Baseline Profile) Image, Image collection, Image sequence Baseline Profile HEIF container (.avif)

Image encoder and decoders exposed through the MediaCodec API

  • [C-1-1] MUST support YUV420 8:8:8 flexible color format ( COLOR_FormatYUV420Flexible ) through CodecCapabilities .

  • [C-SR-1] STRONGLY RECOMMENDED to support RGB888 color format for input Surface mode.

  • [C-1-3] MUST support at least one of a planar or semiplanar YUV420 8:8:8 color format: COLOR_FormatYUV420PackedPlanar (equivalent to COLOR_FormatYUV420Planar ) or COLOR_FormatYUV420PackedSemiPlanar (equivalent to COLOR_FormatYUV420SemiPlanar ). They are STRONGLY RECOMMENDED to support both.

5.1.7. Códecs de vídeo

  • For acceptable quality of web video streaming and video-conference services, device implementations SHOULD use a hardware VP8 codec that meets the requirements .

If device implementations include a video decoder or encoder:

  • [C-1-1] Video codecs MUST support output and input bytebuffer sizes that accommodate the largest feasible compressed and uncompressed frame as dictated by the standard and configuration but also not overallocate.

  • [C-1-2] Video encoders and decoders MUST support YUV420 8:8:8 flexible color formats ( COLOR_FormatYUV420Flexible ) through CodecCapabilities .

  • [C-1-3] Video encoders and decoders MUST support at least one of a planar or semiplanar YUV420 8:8:8 color format: COLOR_FormatYUV420PackedPlanar (equivalent to COLOR_FormatYUV420Planar ) or COLOR_FormatYUV420PackedSemiPlanar (equivalent to COLOR_FormatYUV420SemiPlanar ). They are STRONGLY RECOMMENDED to support both.

  • [C-SR-1] Video encoders and decoders are STRONGLY RECOMMENDED to support at least one of a hardware optimized planar or semiplanar YUV420 8:8:8 color format (YV12, NV12, NV21 or equivalent vendor optimized format.)

  • [C-1-5] Video decoders that support a high bit-depth format (9+ bits per channel) MUST support outputting an 8-bit equivalent format if requested by the application. This MUST be reflected by supporting an YUV420 8:8:8 color format via android.media.MediaCodecInfo .

If device implementations advertise HDR profile support through Display.HdrCapabilities , they:

  • [C-2-1] MUST support HDR static metadata parsing and handling.

If device implementations advertise intra refresh support through FEATURE_IntraRefresh in the MediaCodecInfo.CodecCapabilities class, they:

  • [C-3-1] MUST support the refresh periods in the range of 10 - 60 frames and accurately operate within 20% of configured refresh period.

Unless the application specifies otherwise using the KEY_COLOR_FORMAT format key, video decoder implementations:

  • [C-4-1] MUST default to the color format optimized for hardware display if configured using Surface output.
  • [C-4-2] MUST default to a YUV420 8:8:8 color format optimized for CPU reading if configured to not use Surface output.

5.1.8. Video Codecs List

Format/Codec Detalles File Types/Container Formats to be supported
H.263
  • 3GPP (.3gp)
  • MPEG-4 (.mp4)
  • Matroska (.mkv, decode only)
H.264 AVC See section 5.2 and 5.3 for details
  • 3GPP (.3gp)
  • MPEG-4 (.mp4)
  • MPEG-2 TS (.ts, not seekable)
  • Matroska (.mkv, decode only)
H.265 HEVC See section 5.3 for details
  • MPEG-4 (.mp4)
  • Matroska (.mkv, decode only)
MPEG-2 Perfil principal
  • MPEG2-TS (.ts, not seekable)
  • MPEG-4 (.mp4, decode only)
  • Matroska (.mkv, decode only)
MPEG-4SP
  • 3GPP (.3gp)
  • MPEG-4 (.mp4)
  • Matroska (.mkv, decode only)
VP8 See section 5.2 and 5.3 for details
VP9 See section 5.3 for details
AV1 See section 5.2 and section 5.3 for details
  • MPEG-4 (.mp4)
  • Matroska (.mkv, decode only)

5.1.9. Media Codec Security

Device implementations MUST ensure compliance with media codec security features as described below.

Android includes support for OMX, a cross-platform multimedia acceleration API, as well as Codec 2.0, a low-overhead multimedia acceleration API.

If device implementations support multimedia, they:

  • [C-1-1] MUST provide support for media codecs either via OMX or Codec 2.0 APIs (or both) as in the Android Open Source Project and not disable or circumvent the security protections. This specifically does not mean that every codec MUST use either the OMX or Codec 2.0 API, only that support for at least one of these APIs MUST be available, and support for the available APIs MUST include the security protections present.
  • [C-SR-1] Are STRONGLY RECOMMENDED to include support for Codec 2.0 API.

If device implementations do not support the Codec 2.0 API, they:

  • [C-2-1] MUST include the corresponding OMX software codec from the Android Open Source Project (if it is available) for each media format and type (encoder or decoder) supported by the device.
  • [C-2-2] Codecs that have names starting with "OMX.google." MUST be based on their Android Open Source Project source code.
  • [C-SR-2] Are STRONGLY RECOMMENDED that the OMX software codecs run in a codec process that does not have access to hardware drivers other than memory mappers.

If device implementations support Codec 2.0 API, they:

  • [C-3-1] MUST include the corresponding Codec 2.0 software codec from the Android Open Source Project (if it is available) for each media format and type (encoder or decoder) supported by the device.
  • [C-3-2] MUST house the Codec 2.0 software codecs in the software codec process as provided in the Android Open Source Project to make it possible to more narrowly grant access to software codecs.
  • [C-3-3] Codecs that have names starting with "c2.android." MUST be based on their Android Open Source Project source code.

5.1.10. Media Codec Characterization

If device implementations support media codecs, they:

  • [C-1-1] MUST return correct values of media codec characterization via the MediaCodecInfo API.

En particular:

  • [C-1-2] Codecs with names starting with "OMX." MUST use the OMX APIs and have names that conform to OMX IL naming guidelines.
  • [C-1-3] Codecs with names starting with "c2." MUST use the Codec 2.0 API and have names that conform to Codec 2.0 naming guidelines for Android.
  • [C-1-4] Codecs with names starting with "OMX.google." or "c2.android." MUST NOT be characterized as vendor or as hardware-accelerated.
  • [C-1-5] Codecs that run in a codec process (vendor or system) that have access to hardware drivers other than memory allocators and mappers MUST NOT be characterized as software-only.
  • [C-1-6] Codecs not present in the Android Open Source Project or not based on the source code in that project MUST be characterized as vendor.
  • [C-1-7] Codecs that utilize hardware acceleration MUST be characterized as hardware accelerated.
  • [C-1-8] Codec names MUST NOT be misleading. For example, codecs named "decoders" MUST support decoding, and those named "encoders" MUST support encoding. Codecs with names containing media formats MUST support those formats.

If device implementations support video codecs:

  • [C-2-1] All video codecs MUST publish achievable frame rate data for the following sizes if supported by the codec:
SD (low quality) SD (high quality) alta definición 720p alta definición 1080p HD
Resolución de video
  • 176 x 144 px (H263, MPEG2, MPEG4)
  • 352 x 288 px (MPEG4 encoder, H263, MPEG2)
  • 320 x 180 px (VP8, VP8)
  • 320 x 240 px (other)
  • 704 x 576 px (H263)
  • 640 x 360 px (VP8, VP9)
  • 640 x 480 px (MPEG4 encoder)
  • 720 x 480 px (other, AV1)
  • 1408 x 1152 px (H263)
  • 1280 x 720 px (other, AV1)
1920 x 1080 px (other than MPEG4, AV1) 3840 x 2160 px (HEVC, VP9, AV1)
  • [C-2-2] Video codecs that are characterized as hardware accelerated MUST publish performance points information. They MUST each list all supported standard performance points (listed in PerformancePoint API), unless they are covered by another supported standard performance point.
  • Additionally they SHOULD publish extended performance points if they support sustained video performance other than one of the standard ones listed.

5.2. Codificación de vídeo

If device implementations support any video encoder and make it available to third-party apps, and set the
MediaFormat.KEY_BITRATE_MODE to BITRATE_MODE_VBR so that the encoder operates in Variable bitrate mode, then, as long as it does not impact the minimum quality floor , the encoded bitrate :

  • SHOULD NOT be, over one sliding window, more than 15% over the bitrate between intraframe (I-frame) intervals.
  • SHOULD NOT be more than 100% over the bitrate over a sliding window of 1 second.

If device implementations support any video encoder and make it available to third-party apps and set the MediaFormat.KEY_BITRATE_MODE to BITRATE_MODE_CBR so the encoder operates in constant bitrate mode, then the encoded bitrate:

  • [C-SR-2] is STRONGLY RECOMMENDED to NOT be more than 15% over the target bitrate over a sliding window of 1 second.

If device implementations include an embedded screen display with the diagonal length of at least 2.5 inches or include a video output port or declare the support of a camera via the android.hardware.camera.any feature flag, they:

  • [C-1-1] MUST include the support of at least one of the VP8 or H.264 video encoders, and make it available for third-party applications.
  • SHOULD support both VP8 and H.264 video encoders, and make it available for third-party applications.

If device implementations support any of the H.264, VP8, VP9 or HEVC video encoders and make it available to third-party applications, they:

  • [C-2-1] MUST support dynamically configurable bitrates.
  • SHOULD support variable frame rates, where video encoder SHOULD determine instantaneous frame duration based on the timestamps of input buffers, and allocate its bit bucket based on that frame duration.

If device implementations support the MPEG-4 SP video encoder and make it available to third-party apps, they:

  • SHOULD support dynamically configurable bitrates for the supported encoder.

If device implementations provide hardware accelerated video or image encoders, and support one or more attached or pluggable hardware camera(s) exposed through the android.camera APIs:

  • [C-4-1] all hardware accelerated video and image encoders MUST support encoding frames from the hardware camera(s).
  • SHOULD support encoding frames from the hardware camera(s) through all video or image encoders.

If device implementations provide HDR encoding, they:

  • [C-SR-1] are STRONGLY RECOMMENDED to provide a plugin for the seamless transcoding API to convert from HDR format to SDR format.

5.2.1. H.263

If device implementations support H.263 encoders and make it available to third-party apps, they:

  • [C-1-1] MUST support QCIF resolution (176 x 144) using Baseline Profile Level 45. SQCIF resolution is optional.

5.2.2. H.264

If device implementations support H.264 codec, they:

  • [C-1-1] MUST support Baseline Profile Level 3. However, support for ASO (Arbitrary Slice Ordering), FMO (Flexible Macroblock Ordering) and RS (Redundant Slices) is OPTIONAL. Moreover, to maintain compatibility with other Android devices, it is RECOMMENDED that ASO, FMO and RS are not used for Baseline Profile by encoders.
  • [C-1-2] MUST support the SD (Standard Definition) video encoding profiles in the following table.
  • SHOULD support Main Profile Level 4.
  • SHOULD support the HD (High Definition) video encoding profiles as indicated in the following table.

If device implementations report support of H.264 encoding for 720p or 1080p resolution videos through the media APIs, they:

  • [C-2-1] MUST support the encoding profiles in the following table.
SD (Low quality) SD (High quality) alta definición 720p alta definición 1080p
Resolución de video 320 x 240 px 720 x 480 px 1280 x 720 píxeles 1920 x 1080 px
Velocidad de fotogramas de vídeo 20 fps 30 fps 30 fps 30 fps
Bitrate de vídeo 384 Kbps 2Mbps 4Mbps 10Mbps

5.2.3. VP8

If device implementations support VP8 codec, they:

  • [C-1-1] MUST support the SD video encoding profiles.
  • SHOULD support the following HD (High Definition) video encoding profiles.
  • [C-1-2] MUST support writing Matroska WebM files.
  • SHOULD provide a hardware VP8 codec that meets the WebM project RTC hardware coding requirements , to ensure acceptable quality of web video streaming and video-conference services.

If device implementations report support of VP8 encoding for 720p or 1080p resolution videos through the media APIs, they:

  • [C-2-1] MUST support the encoding profiles in the following table.
SD (Low quality) SD (High quality) alta definición 720p alta definición 1080p
Resolución de video 320 x 180 px 640 x 360 px 1280 x 720 píxeles 1920 x 1080 px
Velocidad de fotogramas de vídeo 30 fps 30 fps 30 fps 30 fps
Bitrate de vídeo 800 Kbps 2Mbps 4Mbps 10Mbps

5.2.4. VP9

If device implementations support VP9 codec, they:

  • [C-1-2] MUST support Profile 0 Level 3.
  • [C-1-1] MUST support writing Matroska WebM files.
  • [C-1-3] MUST generate CodecPrivate data.
  • SHOULD support the HD decoding profiles as indicated in the following table.
  • [C-SR-1] are STRONGLY RECOMMENDED to support the HD decoding profiles as indicated in the following table if there is a hardware encoder.
Dakota del Sur alta definición 720p alta definición 1080p HD
Resolución de video 720 x 480 px 1280 x 720 píxeles 1920 x 1080 px 3840 x 2160 px
Velocidad de fotogramas de vídeo 30 fps 30 fps 30 fps 30 fps
Bitrate de vídeo 1.6 Mbps 4Mbps 5Mbps 20Mbps

If device implementations claim to support Profile 2 or Profile 3 through the Media APIs:

  • Support for 12-bit format is OPTIONAL.

5.2.5. H.265

If device implementations support H.265 codec, they:

  • [C-1-1] MUST support Main Profile Level 3 up to 512 x 512 resolution.
  • [C-SR-1] are STRONGLY RECOMMENDED to support the 720 x 480 SD profile and the HD encoding profiles as indicated in the following table if there is a hardware encoder.
Dakota del Sur alta definición 720p alta definición 1080p HD
Resolución de video 720 x 480 px 1280 x 720 píxeles 1920 x 1080 px 3840 x 2160 px
Velocidad de fotogramas de vídeo 30 fps 30 fps 30 fps 30 fps
Bitrate de vídeo 1.6 Mbps 4Mbps 5Mbps 20Mbps

5.2.6. AV1

If device implementations support AV1 codec then, they:

  • [C-1-1] MUST support Main Profile including 8-bit and 10-bit content.
  • [C-1-2] MUST publish performance data ie report performance data via the getSupportedFrameRatesFor() or getSupportedPerformancePoints() APIs for supported resolutions in the table below.

  • [C-1-3] MUST accept HDR metadata and output it to the bitstream

If AV1 encoder is hardware accelerated, then it:

  • [C-2-1] MUST support up to and including HD1080p encoding profile from the table below:
Dakota del Sur alta definición 720p alta definición 1080p HD
Resolución de video 720 x 480 px 1280 x 720 píxeles 1920 x 1080 px 3840 x 2160 px
Velocidad de fotogramas de vídeo 30 fps 30 fps 30 fps 30 fps
Bitrate de vídeo 5Mbps 8Mbps 16Mbps 50Mbps

5.3. Decodificación de vídeo

If device implementations support VP8, VP9, H.264, or H.265 codecs, they:

  • [C-1-1] MUST support dynamic video resolution and frame rate switching through the standard Android APIs within the same stream for all VP8, VP9, H.264, and H.265 codecs in real time and up to the maximum resolution supported by each codec on the device.

5.3.1. MPEG-2

If device implementations support MPEG-2 decoders, they:

  • [C-1-1] MUST support the Main Profile High Level.

5.3.2. H.263

If device implementations support H.263 decoders, they:

  • [C-1-1] MUST support Baseline Profile Level 30 (CIF, QCIF and SQCIF resolutions @ 30fps 384kbps) and Level 45 (QCIF and SQCIF resolutions @ 30fps 128kbps).

5.3.3. MPEG-4

If device implementations with MPEG-4 decoders, they:

  • [C-1-1] MUST support Simple Profile Level 3.

5.3.4. H.264

If device implementations support H.264 decoders, they:

  • [C-1-1] MUST support Main Profile Level 3.1 and Baseline Profile. Support for ASO (Arbitrary Slice Ordering), FMO (Flexible Macroblock Ordering) and RS (Redundant Slices) is OPTIONAL.
  • [C-1-2] MUST be capable of decoding videos with the SD (Standard Definition) profiles listed in the following table and encoded with the Baseline Profile and Main Profile Level 3.1 (including 720p30).
  • SHOULD be capable of decoding videos with the HD (High Definition) profiles as indicated in the following table.

If the height that is reported by the Display.getSupportedModes() method is equal or greater than the video resolution, device implementations:

  • [C-2-1] MUST support the HD 720p video decoding profiles in the following table.
  • [C-2-2] MUST support the HD 1080p video decoding profiles in the following table.
SD (Low quality) SD (High quality) alta definición 720p alta definición 1080p
Resolución de video 320 x 240 px 720 x 480 px 1280 x 720 píxeles 1920 x 1080 px
Velocidad de fotogramas de vídeo 30 fps 30 fps 60 fps 30 fps (60 fps Television )
Bitrate de vídeo 800 Kbps 2Mbps 8Mbps 20Mbps

5.3.5. H.265 (HEVC)

If device implementations support H.265 codec, they:

  • [C-1-1] MUST support the Main Profile Level 3 Main tier and the SD video decoding profiles as indicated in the following table.
  • SHOULD support the HD decoding profiles as indicated in the following table.
  • [C-1-2] MUST support the HD decoding profiles as indicated in the following table if there is a hardware decoder.

If the height that is reported by the Display.getSupportedModes() method is equal to or greater than the video resolution, then:

  • [C-2-1] Device implementations MUST support at least one of H.265 or VP9 decoding of 720, 1080 and UHD profiles.
SD (Low quality) SD (High quality) alta definición 720p alta definición 1080p HD
Resolución de video 352 x 288 px 720 x 480 px 1280 x 720 píxeles 1920 x 1080 px 3840 x 2160 px
Velocidad de fotogramas de vídeo 30 fps 30 fps 30 fps 30/60 fps (60 fps Television with H.265 hardware decoding ) 60 fps
Bitrate de vídeo 600 Kbps 1.6 Mbps 4Mbps 5Mbps 20Mbps

If device implementations claim to support an HDR Profile through the Media APIs:

  • [C-3-1] Device implementations MUST accept the required HDR metadata from the application, as well as support extracting and outputting the required HDR metadata from the bitstream and/or container.
  • [C-3-2] Device implementations MUST properly display HDR content on the device screen or on a standard video output port (eg, HDMI).

5.3.6. VP8

If device implementations support VP8 codec, they:

  • [C-1-1] MUST support the SD decoding profiles in the following table.
  • SHOULD use a hardware VP8 codec that meets the requirements .
  • SHOULD support the HD decoding profiles in the following table.

If the height as reported by the Display.getSupportedModes() method is equal or greater than the video resolution, then:

  • [C-2-1] Device implementations MUST support 720p profiles in the following table.
  • [C-2-2] Device implementations MUST support 1080p profiles in the following table.
SD (Low quality) SD (High quality) alta definición 720p alta definición 1080p
Resolución de video 320 x 180 px 640 x 360 px 1280 x 720 píxeles 1920 x 1080 px
Velocidad de fotogramas de vídeo 30 fps 30 fps 30 fps (60 fps Television ) 30 (60 fps Television )
Bitrate de vídeo 800 Kbps 2Mbps 8Mbps 20Mbps

5.3.7. VP9

If device implementations support VP9 codec, they:

  • [C-1-1] MUST support the SD video decoding profiles as indicated in the following table.
  • SHOULD support the HD decoding profiles as indicated in the following table.

If device implementations support VP9 codec and a hardware decoder:

  • [C-2-1] MUST support the HD decoding profiles as indicated in the following table.

If the height that is reported by the Display.getSupportedModes() method is equal to or greater than the video resolution, then:

  • [C-3-1] Device implementations MUST support at least one of VP9 or H.265 decoding of the 720, 1080 and UHD profiles.
SD (Low quality) SD (High quality) alta definición 720p alta definición 1080p HD
Resolución de video 320 x 180 px 640 x 360 px 1280 x 720 píxeles 1920 x 1080 px 3840 x 2160 px
Velocidad de fotogramas de vídeo 30 fps 30 fps 30 fps 30 fps (60 fps Television with VP9 hardware decoding ) 60 fps
Bitrate de vídeo 600 Kbps 1.6 Mbps 4Mbps 5Mbps 20Mbps

If device implementations claim to support VP9Profile2 or VP9Profile3 through the 'CodecProfileLevel' media APIs:

  • Support for 12-bit format is OPTIONAL.

If device implementations claim to support an HDR Profile ( VP9Profile2HDR , VP9Profile2HDR10Plus , VP9Profile3HDR , VP9Profile3HDR10Plus ) through the media APIs:

  • [C-4-1] Device implementations MUST accept the required HDR metadata ( KEY_HDR_STATIC_INFO for all HDR profiles, as well as 'KEY_HDR10_PLUS_INFO' for HDR10Plus profiles) from the application. They also MUST support extracting and outputting the required HDR metadata from the bitstream and/or container.
  • [C-4-2] Device implementations MUST properly display HDR content on the device screen or on a standard video output port (eg, HDMI).

5.3.8. Visión Dolby

If device implementations declare support for the Dolby Vision decoder through HDR_TYPE_DOLBY_VISION , they:

  • [C-1-1] MUST provide a Dolby Vision-capable extractor.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-2] (December 11, 2023 preview)

  • [C-1-2] MUST properly display Dolby Vision content either on the device screen or on an external display attached via a standard video output port (eg, HDMI).

Terminar con nuevos requisitos

  • [C-1-3] MUST set the track ID of backward-compatible base-layer(s) (if present) to be the same as the combined Dolby Vision layer's track ID.

5.3.9. AV1

If device implementations support AV1 codec and make it available to third-party applications, they:

  • [C-1-1] MUST support Main Profile including 8-bit and 10-bit content.

If device implementations provide support for AV1 codec with a hardware accelerated decoder then they:

  • [C-2-1] MUST be able to decode at least HD 720p video decoding profiles from the table below when the height reported by Display.getSupportedModes() method is equal or greater than 720p.
  • [C-2-2] MUST be able to decode at least HD 1080p video decoding profiles from the table below when the height reported by Display.getSupportedModes() method is equal or greater than 1080p.
Dakota del Sur alta definición 720p alta definición 1080p HD
Resolución de video 720 x 480 px 1280 x 720 píxeles 1920 x 1080 px 3840 x 2160 px
Velocidad de fotogramas de vídeo 30 fps 30 fps 30 fps 30 fps
Bitrate de vídeo 5Mbps 8Mbps 16Mbps 50Mbps

If device implementations support HDR Profile through the Media APIs, then they:

  • [C-3-1] MUST support extracting and outputting HDR metadata from the bitstream and/or container.
  • [C-3-2] MUST properly display HDR content on the device screen or on a standard video output port (for example, HDMI).

5.4. Grabación de audio

While some of the requirements outlined in this section are listed as SHOULD since Android 4.3, the Compatibility Definition for future versions are planned to change these to MUST. Existing and new Android devices are STRONGLY RECOMMENDED to meet these requirements that are listed as SHOULD, or they will not be able to attain Android compatibility when upgraded to the future version.

5.4.1. Raw Audio Capture and Microphone Information

If device implementations declare android.hardware.microphone , they:

  • [C-1-1] MUST allow capture of raw audio content for any AudioRecord or AAudio INPUT stream that is opened successfully. At a minimum, the following characteristics MUST be supported:

  • SHOULD allow capture of raw audio content with the following characteristics:

    • Format : Linear PCM, 16-bit and 24-bit
    • Sampling rates : 8000, 11025, 16000, 22050, 24000, 32000, 44100, 48000 Hz
    • Channels : As many channels as the number of microphones on the device
  • [C-1-2] MUST capture at above sample rates without up-sampling.

  • [C-1-3] MUST include an appropriate anti-aliasing filter when the sample rates given above are captured with down-sampling.

  • SHOULD allow AM radio and DVD quality capture of raw audio content, which means the following characteristics:

    • Format : Linear PCM, 16-bit
    • Sampling rates : 22050, 48000 Hz
    • Channels : Stereo
  • [C-1-4] MUST honor the MicrophoneInfo API and properly fill in information for the available microphones on device accessible to the third-party applications via the AudioManager.getMicrophones() API, for active AudioRecord using MediaRecorder.AudioSources DEFAULT , MIC , CAMCORDER , VOICE_RECOGNITION , VOICE_COMMUNICATION , UNPROCESSED , or VOICE_PERFORMANCE . If device implementations allow AM radio and DVD quality capture of raw audio content, they:

  • [C-2-1] MUST capture without up-sampling at any ratio higher than 16000:22050 or 44100:48000.

  • [C-2-2] MUST include an appropriate anti-aliasing filter for any up-sampling or down-sampling.

5.4.2. Capture for Voice Recognition

If device implementations declare android.hardware.microphone , they:

  • [C-1-1] MUST capture android.media.MediaRecorder.AudioSource.VOICE_RECOGNITION audio source at one of the sampling rates, 44100 and 48000.
  • [C-1-2] MUST, by default, disable any noise reduction audio processing when recording an audio stream from the AudioSource.VOICE_RECOGNITION audio source.
  • [C-1-3] MUST, by default, disable any automatic gain control when recording an audio stream from the AudioSource.VOICE_RECOGNITION audio source.

  • SHOULD exhibit approximately flat amplitude-versus-frequency characteristics in the mid-frequency range: specifically ±3dB from 100 Hz to 4000 Hz for each and every microphone used to record the voice recognition audio source.

  • [C-SR-1] are STRONGLY RECOMMENDED to exhibit amplitude levels in the low frequency range: specifically from ±20 dB from 30 Hz to 100 Hz compared to the mid-frequency range for each and every microphone used to record the voice recognition audio fuente.

  • [C-SR-2] are STRONGLY RECOMMENDED to exhibit amplitude levels in the high frequency range: specifically from ±30 dB from 4000 Hz to 22 KHz compared to the mid-frequency range for each and every microphone used to record the voice recognition audio fuente.

  • SHOULD set audio input sensitivity such that a 1000 Hz sinusoidal tone source played at 90 dB Sound Pressure Level (SPL) (measured next to the microphone) yields an ideal response of RMS 2500 within a range of 1770 and 3530 for 16 bit-samples (or -22.35 db ±3dB Full Scale for floating point/double precision samples) for each and every microphone used to record the voice recognition audio source.

  • SHOULD record the voice recognition audio stream so that the PCM amplitude levels linearly track input SPL changes over at least a 30 dB range from -18 dB to +12 dB re 90 dB SPL at the microphone.

  • SHOULD record the voice recognition audio stream with total harmonic distortion (THD) less than 1% for 1 kHz at 90 dB SPL input level at the microphone.

If device implementations declare android.hardware.microphone and noise suppression (reduction) technologies tuned for speech recognition, they:

  • [C-2-1] MUST allow this audio effect to be controllable with the android.media.audiofx.NoiseSuppressor API.
  • [C-2-2] MUST uniquely identify each noise suppression technology implementation via the AudioEffect.Descriptor.uuid field.

5.4.3. Capture for Rerouting of Playback

The android.media.MediaRecorder.AudioSource class includes the REMOTE_SUBMIX audio source.

If device implementations declare both android.hardware.audio.output and android.hardware.microphone , they:

  • [C-1-1] MUST properly implement the REMOTE_SUBMIX audio source so that when an application uses the android.media.AudioRecord API to record from this audio source, it captures a mix of all audio streams except for the following:

    • AudioManager.STREAM_RING
    • AudioManager.STREAM_ALARM
    • AudioManager.STREAM_NOTIFICATION

5.4.4. Acoustic Echo Canceler

If device implementations declare android.hardware.microphone , they:

  • SHOULD implement an Acoustic Echo Canceler (AEC) technology tuned for voice communication and applied to the capture path when capturing using AudioSource.VOICE_COMMUNICATION .

If device implementations provides an Acoustic Echo Canceler which is inserted in the capture audio path when AudioSource.VOICE_COMMUNICATION is selected, they:

5.4.5. Concurrent Capture

If device implementations declare android.hardware.microphone ,they MUST implement concurrent capture as described in this document . Específicamente:

  • [C-1-1] MUST allow concurrent access to microphone by an accessibility service capturing with AudioSource.VOICE_RECOGNITION and at least one application capturing with any AudioSource .
  • [C-1-2] MUST allow concurrent access to microphone by a pre-installed application that holds an Assistant role and at least one application capturing with any AudioSource except for AudioSource.VOICE_COMMUNICATION or AudioSource.CAMCORDER .
  • [C-1-3] MUST silence the audio capture for any other application, except for an accessibility service, while an application is capturing with AudioSource.VOICE_COMMUNICATION or AudioSource.CAMCORDER . However, when an app is capturing via AudioSource.VOICE_COMMUNICATION then another app can capture the voice call if it is a privileged (pre-installed) app with permission CAPTURE_AUDIO_OUTPUT .
  • [C-1-4] If two or more applications are capturing concurrently and if neither app has an UI on top, the one that started capture the most recently receives audio.

5.5. Reproducción de audio

Android includes the support to allow apps to playback audio through the audio output peripheral as defined in section 7.8.2.

5.5.1. Raw Audio Playback

If device implementations declare android.hardware.audio.output , they:

  • [C-1-1] MUST allow playback of raw audio content with the following characteristics:

    • Source formats : Linear PCM, 16-bit, 8-bit, float
    • Channels : Mono, Stereo, valid multichannel configurations with up to 8 channels
    • Sampling rates (in Hz) :
      • 8000, 11025, 16000, 22050, 24000, 32000, 44100, 48000 at the channel configurations listed above
      • 96000 in mono and stereo

5.5.2. Efectos de audio

Android provides an API for audio effects for device implementations.

If device implementations declare the feature android.hardware.audio.output , they:

  • [C-1-1] MUST support the EFFECT_TYPE_EQUALIZER and EFFECT_TYPE_LOUDNESS_ENHANCER implementations controllable through the AudioEffect subclasses Equalizer and LoudnessEnhancer .
  • [C-1-2] MUST support the visualizer API implementation, controllable through the Visualizer class.
  • [C-1-3] MUST support the EFFECT_TYPE_DYNAMICS_PROCESSING implementation controllable through the AudioEffect subclass DynamicsProcessing .

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-4] (February 5, 2024 preview)

  • [C-1-4] MUST support audio effects with floating-point input and output , when the effect results are returned to the framework audio pipeline. This refers to typical insert or aux effects such as the equalizer. Equivalent behavior is strongly recommended when the effect results are not visible by the framework audio pipeline (such as, post-processing or offloaded effects) .

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-5] (February 5, 2024 preview)

  • [C-1-5] MUST make sure that audio effects support multiple channels up to the mixer channel count also known as FCC_LIMIT , when the effect results are returned to the framework audio pipeline. This refers to typical insert or aux effects, but excludes special effects such as downmix, upmix, spatialization effects which change the channel count. Equivalent behavior is recommended when the effects are not visible by the framework audio pipeline (such as, post-processing or offloaded effects) .

Terminar con nuevos requisitos

  • SHOULD support the EFFECT_TYPE_BASS_BOOST , EFFECT_TYPE_ENV_REVERB , EFFECT_TYPE_PRESET_REVERB , and EFFECT_TYPE_VIRTUALIZER implementations controllable through the AudioEffect sub-classes BassBoost , EnvironmentalReverb , PresetReverb , and Virtualizer .
  • [C-SR-1] Are STRONGLY RECOMMENDED to support effects in floating-point and multichannel.

5.5.3. Audio Output Volume

Implementaciones de dispositivos automotrices:

  • SHOULD allow adjusting audio volume separately per each audio stream using the content type or usage as defined by AudioAttributes and car audio usage as publicly defined in android.car.CarAudioManager .

5.5.4. Audio Offload

If device implementations support audio offload playback , they:

  • [C-SR-1] Are STRONGLY RECOMMENDED to trim the played gapless audio content between two clips with the same format when specified by the AudioTrack gapless API and the media container for MediaPlayer.

5.6. Audio Latency

Audio latency is the time delay as an audio signal passes through a system. Many classes of applications rely on short latencies, to achieve real-time sound effects.

For the purposes of this section, use the following definitions:

  • output latency . The interval between when an application writes a frame of PCM-coded data and when the corresponding sound is presented to the environment at an on-device transducer or the signal leaves the device via a port and can be observed externally.
  • cold output latency . The time between starting an output stream and the presentation time of the first frame based on timestamps, when the audio output system has been idle and powered down prior to the request.
  • continuous output latency . The output latency for subsequent frames, after the device is playing audio.
  • input latency . The interval between when a sound is presented by environment to device at an on-device transducer or signal enters the device via a port and when an application reads the corresponding frame of PCM-coded data.
  • lost input . The initial portion of an input signal that is unusable or unavailable.
  • cold input latency . The time between starting the stream and when the first valid frame is received, when the audio input system has been idle and powered down prior to the request.
  • continuous input latency . The input latency for subsequent frames, while the device is capturing audio.
  • continuous round-trip latency . The sum of continuous input latency plus continuous output latency plus one buffer period. The buffer period allows time for the app to process the signal and time for the app to mitigate phase difference between input and output streams.
  • OpenSL ES PCM buffer queue API . The set of PCM-related OpenSL ES APIs within Android NDK .
  • AAudio native audio API . The set of AAudio APIs within Android NDK .
  • Timestamp . A pair consisting of a relative frame position within a stream and the estimated time when that frame enters or leaves the audio processing pipeline on the associated endpoint. See also AudioTimestamp .
  • falla . A temporary interruption or incorrect sample value in the audio signal, typically caused by a buffer underrun for output, buffer overrun for input, or any other source of digital or analog noise.
  • mean absolute deviation (MAD) . The average of the absolute value of the deviations from the mean for a set of values.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[TTL, RTL, MPC, and FEATURE_AUDIO_PRO definitions]

  • tap-to-tone latency (TTL) , as measured by CTS Verifier, is the time between when the screen is tapped and when a tone generated as a result of that tap is heard on the speaker. This is averaged over 5 measurements using the AAudio native audio API for output.

  • Round-Trip latency (RTL) , as measured by the CTS Verifier, is the Mean Continuous latency over 5 measurements, measured over a loopback path that feeds the output back to the input, using the AAudio native audio API. The loopback paths are:

    • Speaker/mic: Built-in speaker to built-in microphone.
    • Analog: 3.5mm analog jack and a loopback adapter.
    • USB: USB to 3.5mm adapter and a loopback adapter or a USB audio interface and loopback cables.
  • FEATURE_AUDIO_PRO . The android.hardware.audio.pro feature is declared.

  • MPC . Media Performance Class

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[head-tracking-latency definition] (February 26, 2024 preview)

  • head-tracking latency . The time it takes from the head motion captured by the inertial measurement unit (IMU) to the headphone transducers' detection of the change in sound caused by this motion.

Terminar con nuevos requisitos

If device implementations declare android.hardware.audio.output , they MUST meet or exceed the following requirements:

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-1] (February 5, 2024 preview)

  • [C-1-1] The output timestamp returned by AudioTrack.getTimestamp and AAudioStream_getTimestamp is accurate to +/- 2 ms.

Terminar con nuevos requisitos

  • [C-1-2] Cold output latency of 500 milliseconds or less.

  • [C-1-3] Opening an output stream using AAudioStreamBuilder_openStream() MUST take less than 1000 milliseconds.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-4] (February 5, 2024 preview)

  • [C-1-4] The calculated round-trip latencies based on input and output timestamps returned by AAudioStream_getTimestamp MUST be within 200 msec of the measured round trip latency for AAUDIO_PERFORMANCE_MODE_NONE and AAUDIO_PERFORMANCE_MODE_LOW_LATENCY for speakers, wired and wireless headsets.

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-SR-1, C-SR-2, C-SR-4] (February 5, 2024 preview)

If device implementations declare android.hardware.audio.output they are STRONGLY RECOMMENDED to meet or exceed the following requirements:

  • [C-SR-1] Cold output latency of 100 milliseconds or less over the speaker data path.

  • [C-SR-2] Tap-to-tone latency of 80 milliseconds or less.

  • [C-SR-4] The calculated round-trip latencies based on input and output timestamps returned by AAudioStream_getTimestamp are STRONGLY RECOMMENDED to be within 30 msec of the measured round trip latency for AAUDIO_PERFORMANCE_MODE_NONE and AAUDIO_PERFORMANCE_MODE_LOW_LATENCY for speakers, wired and wireless headsets.

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-SR-5, C-SR-6, C-SR-7] (February 5, 2024 preview)

If device implementations meet the above requirements, after any initial calibration, when using the AAudio native audio API, for continuous output latency and cold output latency over at least one supported audio output device, they are:

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-2-1] (February 5, 2024 preview)

If device implementations do not meet the requirements for low-latency audio via the AAudio native audio API, they:

  • [C-2-1] MUST NOT report support for low-latency audio.

Terminar con nuevos requisitos

If device implementations include android.hardware.microphone , they MUST meet these input audio requirements:

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-3-1] (February 5, 2024 preview)

  • [C-3-1] Limit the error in input timestamps, as returned by AudioRecord.getTimestamp or AAudioStream_getTimestamp , to +/- 2 ms. "Error" here means the deviation from the correct value.

Terminar con nuevos requisitos

  • [C-3-2] Cold input latency of 500 milliseconds or less.
  • [C-3-3] Opening an input stream using AAudioStreamBuilder_openStream() MUST take less than 1000 milliseconds.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-SR-8, C-SR-11] (February 5, 2024 preview)

If device implementations include android.hardware.microphone , they are STRONGLY RECOMMENDED to meet these input audio requirements:

  • [C-SR-8] Cold input latency of 100 milliseconds or less over the microphone data path.
  • [C-SR-11] Limit the error in input timestamps, as returned by AudioRecord.getTimestamp or AAudioStream_getTimestamp , to +/- 1 ms.

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-SR-12] (February 5, 2024 preview)

If device implementations declare android.hardware.audio.output and android.hardware.microphone , they:

  • [C-SR-12] Are STRONGLY RECOMMENDED to have a Mean Continuous Round-Trip Latency of 50 milliseconds or less over 5 measurements, with a Mean Absolute Deviation less than 10 msec, over at least one supported path.

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[RTL requirements] (February 5, 2024 preview)

The following table defines the requirements for RTL for Handheld device implementations as defined in 2.2.1 that declare android.hardware.audio.output and android.hardware.microphone .

Device and Declarations RTL (ms) MAD (ms) Loopback Paths
Mano 250 30 speaker/mic, analog 3.5mm (if supported), USB (if supported)
>= MPC_T (14) 80 15 at least one path
FEATURE_AUDIO_LOW_LATENCY 50 10 at least one path
FEATURE_AUDIO_PRO 25 5 at least one path
FEATURE_AUDIO_PRO 20 5 analog (if supported)
FEATURE_AUDIO_PRO 25 5 USB (if analog not supported)

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[TTL requirements] (February 5, 2024 preview)

The following table defines the requirements for TTL for Handheld device implementations as defined in 2.2.1 that declare android.hardware.audio.output and android.hardware.microphone .

Device and Declarations TTL (ms)
Mano 250
>= MPC_T (14) 80
MPC_S (13) 100
FEATURE_AUDIO_PRO 80

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-4-1] (February 26, 2024 preview)

If device implementations include support for spatial audio with head tracking and declare the PackageManager.FEATURE_AUDIO_SPATIAL_HEADTRACKING_LOW_LATENCY flag, they:

  • [C-4-1] MUST exhibit a maximum head-tracking to audio-update latency of 300ms.

Terminar con nuevos requisitos

5.7. Protocolos de red

Device implementations MUST support the media network protocols for audio and video playback as specified in the Android SDK documentation.

For each codec and container format that a device implementation is required to support, the device implementation:

  • [C-1-1] MUST support that codec or container over HTTP and HTTPS.

  • [C-1-2] MUST support the corresponding media segment formats as shown in the media segment formats table below over HTTP Live Streaming draft protocol, Version 7 .

  • [C-1-3] MUST support the corresponding RTSP payload formats as shown in the RTSP table below. For exceptions please see the table footnotes in section 5.1 .

Media Segment Formats

Segment formats Referencia(s) Required codec support
Flujo de transporte MPEG-2 ISO 13818 Códecs de vídeo:
  • H264 AVC
  • MPEG-4SP
  • MPEG-2
See section 5.1.8 for details on H264 AVC, MPEG2-4 SP,
and MPEG-2.

Códecs de audio:

  • CAA
See section 5.1.3 for details on AAC and its variants.
AAC with ADTS framing and ID3 tags ISO 13818-7 See section 5.1.1 for details on AAC and its variants
WebVTT WebVTT

RTSP (RTP, SDP)

Nombre de perfil Referencia(s) Required codec support
H264 AVC RFC 6184 See section 5.1.8 for details on H264 AVC
MP4A-LATM RFC 6416 See section 5.1.3 for details on AAC and its variants
H263-1998 RFC 3551
RFC 4629
RFC 2190
See section 5.1.8 for details on H263
H263-2000 RFC 4629 See section 5.1.8 for details on H263
RAM RFC 4867 See section 5.1.3 for details on AMR-NB
AMR-WB RFC 4867 See section 5.1.3 for details on AMR-WB
MP4V-ES RFC 6416 See section 5.1.8 for details on MPEG-4 SP
mpeg4-generic RFC 3640 See section 5.1.3 for details on AAC and its variants
MP2T RFC 2250 See MPEG-2 Transport Stream underneath HTTP Live Streaming for details

5.8. Medios seguros

If device implementations support secure video output and are capable of supporting secure surfaces, they:

  • [C-1-1] MUST declare support for Display.FLAG_SECURE .

If device implementations declare support for Display.FLAG_SECURE and support wireless display protocol, they:

  • [C-2-1] MUST secure the link with a cryptographically strong mechanism such as HDCP 2.x or higher for the displays connected through wireless protocols such as Miracast.

If device implementations declare support for Display.FLAG_SECURE and support wired external display, they:

  • [C-3-1] MUST support HDCP 1.2 or higher for all external displays connected via a user-accessible wired port.

5.9. Interfaz digital para instrumentos musicales (MIDI)

If device implementations report support for feature android.software.midi via the android.content.pm.PackageManager class, they:

  • [C-1-1] MUST support MIDI over all MIDI-capable hardware transports for which they provide generic non-MIDI connectivity, where such transports are:

  • [C-1-2] MUST support the inter-app MIDI software transport (virtual MIDI devices)

  • [C-1-3] MUST include libamidi.so (native MIDI support)

  • SHOULD support MIDI over USB peripheral mode, section 7.7

5.10. Audio profesional

If device implementations report support for feature android.hardware.audio.pro via the android.content.pm.PackageManager class, they:

  • [C-1-1] MUST report support for feature android.hardware.audio.low_latency .

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-2] (February 5, 2024 preview)

  • [C-1-2] MUST have the continuous round-trip audio latency , meet the latency requirements for FEATURE_AUDIO_PRO as defined in section 5.6 Audio Latency of 25 milliseconds or less over at least one supported path .

Terminar con nuevos requisitos

  • [C-1-3] MUST include a USB port(s) supporting USB host mode and USB peripheral mode.
  • [C-1-4] MUST report support for feature android.software.midi .

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-5] (February 5, 2024 preview)

  • [C-1-5] MUST meet latencies and USB audio latency requirements using the AAudio native audio API and AAUDIO_PERFORMANCE_MODE_LOW_LATENCY .

Terminar con nuevos requisitos

  • [C-1-6] MUST have Cold output latency of 200 milliseconds or less.
  • [C-1-7] MUST have Cold input latency of 200 milliseconds or less.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-8, C-SR-1, C-SR-2, C-SR-3] (February 5, 2024 preview)

  • [C-1-8] MUST have an average Tap-to-tone latency of 80 milliseconds or less over at least 5 measurements over the speaker to microphone data path.
  • [C-SR-1] Are STRONGLY RECOMMENDED to meet latencies as defined in section 5.6 Audio Latency , of 20 milliseconds or less, over 5 measurements with a Mean Absolute Deviation less than 5 milliseconds over the speaker to microphone path.
  • [C-SR-2] Are STRONGLY RECOMMENDED to meet the Pro Audio requirements for continuous round-trip audio latency, cold input latency and cold output latency and USB audio requirements using the AAudio native audio API over the MMAP path.
  • [C-SR-3] Are STRONGLY RECOMMENDED to provide a consistent level of CPU performance while audio is active and CPU load is varying. This should be tested using the Android app SynthMark . SynthMark uses a software synthesizer running on a simulated audio framework that measures system performance. See the SynthMark documentation for an explanation of the benchmarks. The SynthMark app needs to be run using the "Automated Test" option and achieve the following results:

    • voicemark.90 >= 32 voices
    • latencymark.fixed.little <= 15 msec
    • latencymark.dynamic.little <= 50 msec
  • SHOULD minimize audio clock inaccuracy and drift relative to standard time.

  • SHOULD minimize audio clock drift relative to the CPU CLOCK_MONOTONIC when both are active.

  • SHOULD minimize audio latency over on-device transducers.

  • SHOULD minimize audio latency over USB digital audio.

  • SHOULD document audio latency measurements over all paths.

  • SHOULD minimize jitter in audio buffer completion callback entry times, as this affects usable percentage of full CPU bandwidth by the callback.

  • SHOULD provide zero audio glitches under normal use at reported latency.

  • SHOULD provide zero inter-channel latency difference.

  • SHOULD minimize MIDI mean latency over all transports.

  • SHOULD minimize MIDI latency variability under load (jitter) over all transports.

  • SHOULD provide accurate MIDI timestamps over all transports.

  • SHOULD minimize audio signal noise over on-device transducers, including the period immediately after cold start.

  • SHOULD provide zero audio clock difference between the input and output sides of corresponding end-points, when both are active. Examples of corresponding end-points include the on-device microphone and speaker, or the audio jack input and output.

  • SHOULD handle audio buffer completion callbacks for the input and output sides of corresponding end-points on the same thread when both are active, and enter the output callback immediately after the return from the input callback. Or if it is not feasible to handle the callbacks on the same thread, then enter the output callback shortly after entering the input callback to permit the application to have a consistent timing of the input and output sides.

  • SHOULD minimize the phase difference between HAL audio buffering for the input and output sides of corresponding end-points.

  • SHOULD minimize touch latency.

  • SHOULD minimize touch latency variability under load (jitter).

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-SR-4] (February 5, 2024 preview)

If device implementations meet all of the above requirements, they:

Terminar con nuevos requisitos

If device implementations include a 4 conductor 3.5mm audio jack, they:

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-2-1] (February 5, 2024 preview)

  • [C-2-1] MUST have a mean Continuous Round-trip Audio Latency, as defined in section 5.6 Audio Latency , of 20 milliseconds or less, over 5 measurements with a Mean Absolute Deviation less than 5 milliseconds over the audio jack path using an Audio Loopback Dongle .

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-SR-5] (February 5, 2024 preview)

Terminar con nuevos requisitos

If device implementations omit a 4 conductor 3.5mm audio jack and include a USB port(s) supporting USB host mode, they:

  • [C-3-1] MUST implement the USB audio class.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-3-2, C-SR-6, C-SR-7] (February 5, 2024 preview)

  • [C-3-2] MUST have a mean Continuous Round-trip Audio Latency of 25 milliseconds or less, over 5 measurements with a Mean Absolute Deviation less than 5 milliseconds over the USB host mode port using USB audio class. (This can be measured using a USB-3.5mm adapter and an Audio Loopback Dongle, or using a USB audio interface with patch cables connecting the inputs to outputs).
  • [C-SR-6] Are STRONGLY RECOMMENDED to support simultaneous I/O up to 8 channels each direction, 96 kHz sample rate, and 24-bit or 32-bit depth, when used with USB audio peripherals that also support these requirements.
  • [C-SR-7] Are STRONGLY RECOMMENDED to meet this group of requirements using the AAudio native audio API over the MMAP path.

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[HDMI port requirement] (February 5, 2024 preview)

If device implementations include an HDMI port, they:

  • SHOULD support output in stereo and eight channels at 20-bit or 24-bit depth and 192 kHz without bit-depth loss or resampling, in at least one configuration.

Terminar con nuevos requisitos

5.11. Capture for Unprocessed

Android includes support for recording of unprocessed audio via the android.media.MediaRecorder.AudioSource.UNPROCESSED audio source. In OpenSL ES, it can be accessed with the record preset SL_ANDROID_RECORDING_PRESET_UNPROCESSED .

If device implementations intent to support unprocessed audio source and make it available to third-party apps, they:

  • [C-1-1] MUST report the support through the android.media.AudioManager property PROPERTY_SUPPORT_AUDIO_SOURCE_UNPROCESSED .

  • [C-1-2] MUST exhibit approximately flat amplitude-versus-frequency characteristics in the mid-frequency range: specifically ±10dB from 100 Hz to 7000 Hz for each and every microphone used to record the unprocessed audio source.

  • [C-1-3] MUST exhibit amplitude levels in the low frequency range: specifically from ±20 dB from 5 Hz to 100 Hz compared to the mid-frequency range for each and every microphone used to record the unprocessed audio source.

  • [C-1-4] MUST exhibit amplitude levels in the high frequency range: specifically from ±30 dB from 7000 Hz to 22 KHz compared to the mid-frequency range for each and every microphone used to record the unprocessed audio source.

  • [C-1-5] MUST set audio input sensitivity such that a 1000 Hz sinusoidal tone source played at 94 dB Sound Pressure Level (SPL) yields a response with RMS of 520 for 16 bit-samples (or -36 dB Full Scale for floating point/double precision samples) for each and every microphone used to record the unprocessed audio source.

  • [C-1-6] MUST have a signal-to-noise ratio (SNR) at 60 dB or higher for each and every microphone used to record the unprocessed audio source. (whereas the SNR is measured as the difference between 94 dB SPL and equivalent SPL of self noise, A-weighted).

  • [C-1-7] MUST have a total harmonic distortion (THD) less than be less than 1% for 1 kHZ at 90 dB SPL input level at each and every microphone used to record the unprocessed audio source.

  • [C-1-8] MUST not have any other signal processing (eg Automatic Gain Control, High Pass Filter, or Echo cancellation) in the path other than a level multiplier to bring the level to desired range. En otras palabras:

    • [C-1-9] If any signal processing is present in the architecture for any reason, it MUST be disabled and effectively introduce zero delay or extra latency to the signal path.
    • [C-1-10] The level multiplier, while allowed to be on the path, MUST NOT introduce delay or latency to the signal path.

All SPL measurements are made directly next to the microphone under test. For multiple microphone configurations, these requirements apply to each microphone.

If device implementations declare android.hardware.microphone but do not support unprocessed audio source, they:

  • [C-2-1] MUST return null for the AudioManager.getProperty(PROPERTY_SUPPORT_AUDIO_SOURCE_UNPROCESSED) API method, to properly indicate the lack of support.
  • [C-SR-1] are still STRONGLY RECOMMENDED to satisfy as many of the requirements for the signal path for the unprocessed recording source.

5.12. Vídeo HDR

Android 13 supports the HDR technologies as described in an upcoming document.

Pixel Format

If a video decoder advertises support for COLOR_FormatYUVP010, then:

  • [C-1-1] MUST support the P010 format for CPU-read (ImageReader, MediaImage, ByteBuffer). In Android 13, P010 is relaxed to allow arbitrary stride for the Y and UV planes.

  • [C-1-2] The P010 output buffer MUST be able to be sampled by the GPU (when allocated with GPU_SAMPLING usage). This enables GPU composition and custom tone mapping by apps.

If a video decoder advertises support for COLOR_Format32bitABGR2101010, it:

  • [C-2-1] MUST support the RGBA_1010102 format for output surface and CPU-readable (ByteBuffer output).

If a video encoder advertises support for COLOR_FormatYUVP010, it:

  • [C-3-1] MUST support the P010 format for input surface and CPU-writeable (ImageWriter, MediaImage, ByteBuffer) input.

If a video encoder advertises support for COLOR_Format32bitABGR2101010, it:

  • [C-4-1] MUST support RGBA_1010102 format for input surface and CPU-writeable (ImageWriter, ByteBuffer) input. Note: Converting between various transfer curves is NOT required for encoders.

HDR Capture Requirements

For all video encoders that support HDR profiles, device implementations:

  • [C-5-1] MUST NOT assume that the HDR metadata is precise. For example, the encoded frame could have pixels beyond the peak luminance level, or the histogram might not be representative of the frame.

  • SHOULD aggregate HDR dynamic metadata to generate appropriate HDR static metadata for encoded streams, and they should output it at the end of each encoding session.

If device implementations support HDR capture using the CamcorderProfile APIs then they:

  • [C-6-1] MUST support HDR capture through the Camera2 APIs as well.

  • [C-6-2] MUST support at least one hardware-accelerated video encoder for each HDR technology supported.

  • [C-6-3] MUST support (at the minimum) HLG capture.

  • [C-6-4] MUST support writing the HDR metadata (if applicable to the HDR technology) into the captured video file. For AV1, HEVC, and DolbyVision this means including the metadata into the encoded bitstream.

  • [C-6-5] MUST support P010 and COLOR_FormatYUVP010.

  • [C-6-6] MUST support HDR to SDR tone mapping in the default hardware-accelerated decoder for the captured profile. In other words, if a device can capture HDR10+ HEVC, the default HEVC decoder MUST be able to decode the captured stream in SDR.

HDR Editing Requirements

If device implementations include video encoders that support HDR editing, then they:

  • SHOULD use minimal latency for generating the HDR metadata when not present, and SHOULD gracefully handle situations where the metadata is present for some frames and not for others. This metadata SHOULD be precise (for example, represent the actual peak luminance and histogram of the frame).

If device implementation includes codecs that support FEATURE_HdrEditing, then those codecs:

  • [C-7-1] MUST support at least one HDR profile.

  • [C-7-2] MUST support FEATURE_HdrEditing for all HDR profiles advertised by that codec. In other words, they MUST support generating HDR metadata when not present for all HDR profiles supported that use HDR metadata.

  • [C-7-3] MUST support the following video encoder input formats that fully preserve the HDR decoded signal:

    • RGBA_1010102 (already in the target transfer curve) for both input surface and ByteBuffer and MUST advertise support for COLOR_Format32bitABGR2101010.

If device implementation includes codecs that support FEATURE_HdrEditing, then the device:

  • [C-7-4] MUST advertise support for EXT_YUV_target OpenGL extension.

6. Developer Tools and Options Compatibility

6.1. Herramientas de desarrollo

Device implementations:

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-0-2] (February 5, 2024 preview)

  • [C-0-2] MUST support adb as documented in the Android SDK and the shell commands provided in the AOSP, which can be used by app developers, including dumpsys , cmd stats , and Simpleperf .

Terminar con nuevos requisitos

  • [C-0-11] MUST support the shell command cmd testharness . Upgrading device implementations from an earlier Android version without a persistent data block MAY be exempted from C-0-11.
  • [C-0-3] MUST NOT alter the format or the contents of device system events (batterystats, diskstats, fingerprint, graphicsstats, netstats, notification, procstats) logged via the dumpsys command.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-0-10] (December 11, 2023 preview)

  • [C-0-10] MUST record, without omission, and make the following events accessible and available to the cmd stats shell command and the StatsManager System API class.
    • ActivityForegroundStateChanged
    • AnomalyDetected
    • AppBreadcrumbReported
    • AppCrashOccurred
    • AppStartOccurred
    • BatteryLevelChanged
    • BatterySaverModeStateChanged
    • BleScanResultReceived
    • BleScanStateChanged
    • ChargingStateChanged
    • DeviceIdleModeStateChanged
    • ForegroundServiceStateChanged
    • GpsScanStateChanged
    • InputDeviceUsageReported
    • JobStateChanged
    • KeyboardConfigured
    • KeyboardSystemsEventReported
    • PluggedStateChanged
    • ScheduledJobStateChanged
    • ScreenStateChanged
    • SyncStateChanged
    • SystemElapsedRealtime
    • TouchpadUsage
    • UidProcessStateChanged
    • WakelockStateChanged
    • WakeupAlarmOccurred
    • WifiLockStateChanged
    • WifiMulticastLockStateChanged
    • WifiScanStateChanged

Terminar con nuevos requisitos

  • [C-0-4] MUST have the device-side adb daemon be inactive by default and there MUST be a user-accessible mechanism to turn on the Android Debug Bridge.
  • [C-0-5] MUST support secure adb. Android includes support for secure adb. Secure adb enables adb on known authenticated hosts.
  • [C-0-6] MUST provide a mechanism allowing adb to be connected from a host machine. Específicamente:

If device implementations without a USB port support peripheral mode, they:

  • [C-3-1] MUST implement adb via local-area network (such as Ethernet or Wi-Fi).
  • [C-3-2] MUST provide drivers for Windows 7, 8 and 10, allowing developers to connect to the device using the adb protocol.

If device implementations support adb connections to a host machine via Wi-Fi or Ethernet, they:

  • [C-4-1] MUST have the AdbManager#isAdbWifiSupported() method return true .

If device implementations support adb connections to a host machine via Wi-Fi or Ethernet, and includes at least one camera, they:

  • [C-5-1] MUST have the AdbManager#isAdbWifiQrSupported() method return true .

  • Dalvik Debug Monitor Service (ddms)

    • [C-0-7] MUST support all ddms features as documented in the Android SDK. As ddms uses adb, support for ddms SHOULD be inactive by default, but MUST be supported whenever the user has activated the Android Debug Bridge, as above.
  • SysTrace

    • [C-0-9] MUST support the systrace tool as documented in the Android SDK. Systrace must be inactive by default and there MUST be a user-accessible mechanism to turn on Systrace.
  • perfecto

    • [C-SR-1] Are STRONGLY RECOMMENDED to expose a /system/bin/perfetto binary to the shell user which cmdline complies with the perfetto documentation .
    • [C-SR-2] The perfetto binary is STRONGLY RECOMMENDED to accept as input a protobuf config that complies with the schema defined in the perfetto documentation .
    • [C-SR-3] The perfetto binary is STRONGLY RECOMMENDED to write as output a protobuf trace that complies with the schema defined in the perfetto documentation .
    • [C-SR-4] Are STRONGLY RECOMMENDED to provide, through the perfetto binary, at least the data sources described in the perfetto documentation .
  • Low Memory Killer

    • [C-0-12] MUST write a LMK_KILL_OCCURRED_FIELD_NUMBER Atom to the statsd log when an app is terminated by the Low Memory Killer .
  • Test Harness Mode If device implementations support the shell command cmd testharness and run cmd testharness enable , they:

    • [C-2-1] MUST return true for ActivityManager.isRunningInUserTestHarness()
    • [C-2-2] MUST implement Test Harness Mode as described in Test Harness Mode documentation .
  • GPU work information

    Device implementations:

    • [C-0-13] MUST implement the shell command dumpsys gpu --gpuwork to display the aggregated GPU work data returned by the power/gpu_work_period kernel tracepoint, or display no data if the tracepoint is not supported. The AOSP implementation is frameworks/native/services/gpuservice/gpuwork/ .

If device implementations report the support of Vulkan 1.0 or higher via the android.hardware.vulkan.version feature flags, they:

  • [C-1-1] MUST provide an affordance for the app developer to enable/disable GPU debug layers.
  • [C-1-2] MUST, when the GPU debug layers are enabled, enumerate layers in libraries provided by external tools (ie not part of the platform or application package) found in debuggable applications' base directory to support vkEnumerateInstanceLayerProperties() and vkCreateInstance() API methods.

6.2. Opciones de desarrollador

Android includes support for developers to configure application development-related settings.

Device implementations MUST provide a consistent experience for Developer Options, they:

  • [C-0-1] MUST honor the android.settings.APPLICATION_DEVELOPMENT_SETTINGS intent to show application development-related settings. The upstream Android implementation hides the Developer Options menu by default and enables users to launch Developer Options after pressing seven (7) times on the Settings > About Device > Build Number menu item.
  • [C-0-2] MUST hide Developer Options by default.
  • [C-0-3] MUST provide a clear mechanism that does not give preferential treatment to one third-party app as opposed to another to enable Developer Options. MUST provide a public visible document or website that describes how to enable Developer Options. This document or website MUST be linkable from the Android SDK documents.
  • SHOULD have an ongoing visual notification to the user when Developer Options is enabled and the safety of the user is of concern.
  • MAY temporarily limit access to the Developer Options menu, by visually hiding or disabling the menu, to prevent distraction for scenarios where the safety of the user is of concern.

7. Hardware Compatibility

If a device includes a particular hardware component that has a corresponding API for third-party developers:

  • [C-0-1] The device implementation MUST implement that API as described in the Android SDK documentation.

If an API in the SDK interacts with a hardware component that is stated to be optional and the device implementation does not possess that component:

  • [C-0-2] Complete class definitions (as documented by the SDK) for the component APIs MUST still be presented.
  • [C-0-3] The API's behaviors MUST be implemented as no-ops in some reasonable fashion.
  • [C-0-4] API methods MUST return null values where permitted by the SDK documentation.
  • [C-0-5] API methods MUST return no-op implementations of classes where null values are not permitted by the SDK documentation.
  • [C-0-6] API methods MUST NOT throw exceptions not documented by the SDK documentation.
  • [C-0-7] Device implementations MUST consistently report accurate hardware configuration information via the getSystemAvailableFeatures() and hasSystemFeature(String) methods on the android.content.pm.PackageManager class for the same build fingerprint.

A typical example of a scenario where these requirements apply is the telephony API: Even on non-phone devices, these APIs must be implemented as reasonable no-ops.

7.1. Pantalla y gráficos

Android includes facilities that automatically adjust application assets and UI layouts appropriately for the device to ensure that third-party applications run well on a variety of hardware displays and configurations. An Android-compatible display is a display screen that implements all of the behaviors and APIs described in Android Developers - Screen compatibility overview , this section (7.1) and its subsections, as well as any additional device-type specific behaviors documented in section 2 of this CDD.

Device implementations:

  • [C-0-1] MUST, by default, render third party applications only onto Android-compatible displays.

The units referenced by the requirements in this section are defined as follows:

  • physical diagonal size . The distance in inches between two opposing corners of the illuminated portion of the display.
  • densidad . The number of pixels encompassed by a linear horizontal or vertical span of 1", expressed as pixels per inch (ppi or dpi). Where ppi and dpi values are listed, both horizontal and vertical dpi must fall within the listed range.
  • aspect ratio . The ratio of the pixels of the longer dimension to the shorter dimension of the screen. For example, a display of 480x854 pixels would be 854/480 = 1.779, or roughly "16:9".
  • density-independent pixel (dp) . A virtual pixel unit normalized to a screen density of 160. For some density d, and a number of pixels p, the number of density-independent pixels dp, is calculated as: dp = (160 / d) * p.

7.1.1. Configuración de pantalla

7.1.1.1. Screen Size and Shape

The Android UI framework supports a variety of different logical screen layout sizes, and allows applications to query the current configuration's screen layout size via Configuration.screenLayout with the SCREENLAYOUT_SIZE_MASK and Configuration.smallestScreenWidthDp .

Device implementations:

  • [C-0-1] MUST report the correct layout size for the Configuration.screenLayout as defined in the Android SDK documentation. Specifically, device implementations MUST report the correct logical density-independent pixel (dp) screen dimensions as below:

    • Devices with the Configuration.uiMode set as any value other than UI_MODE_TYPE_WATCH, and reporting a small size for the Configuration.screenLayout , MUST have at least 426 dp x 320 dp.
    • Devices reporting a normal size for the Configuration.screenLayout , MUST have at least 480 dp x 320 dp.
    • Devices reporting a large size for the Configuration.screenLayout , MUST have at least 640 dp x 480 dp.
    • Devices reporting a xlarge size for the Configuration.screenLayout , MUST have at least 960 dp x 720 dp.
  • [C-0-2] MUST correctly honor applications' stated support for screen sizes through the < supports-screens > attribute in the AndroidManifest.xml, as described in the Android SDK documentation.

  • MAY have the Android-compatible display(s) with rounded corners.

If device implementations support screens capable of the UI_MODE_TYPE_NORMAL size configuration and use physical display(s) with rounded corners to render these screens, they:

  • [C-1-1] MUST ensure that at least one of the following requirements is met for each such display:

    • The radius of the rounded corners is less than or equal to 38 dp.
    • When an 18 dp by 18 dp box is anchored at each corner of the logical display, at least one pixel of each box is visible on the screen.
  • SHOULD include user affordance to switch to the display mode with the rectangular corners.

If device implementations are only capable of NO_KEYS keyboard configuration, and intend to report support for the UI_MODE_TYPE_NORMAL ui mode configuration, they:

  • [C-4-1] MUST have a layout size, excluding any display cutouts, of at least 596 dp x 384 dp or greater.

For details on correctly implementing the sidecar or extension APIs refer to the public documentation of Window Manager Jetpack .

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-4-1] (February 5, 2024 preview)

If device implementations include one or more Android-compatible display areas that are foldable, or include a folding hinge between multiple Android-compatible display panel areas and make such display areas available to applications, they:

  • [C-4-1] MUST implement the correct version of the Window Manager Extensions API level as described in WindowManager Extensions .

Terminar con nuevos requisitos

7.1.1.2. Relación de aspecto de pantalla

This section was deleted in Android 14.

7.1.1.3. Densidad de la pantalla

The Android UI framework defines a set of standard logical densities to help application developers target application resources.

Device Implementations:

  • [C-0-1] MUST report one of the Android framework densities that are listed on DisplayMetrics through the DENSITY_DEVICE_STABLE API and this value must be a static value for each physical display. However the device MAY report a different DisplayMetrics.density according to the display configuration changes made by the user (for example, display size) set after initial boot.

  • SHOULD define the standard Android framework density that is numerically closest to the physical density of the screen, or a value that would map to the same equivalent angular field-of-view measurements of a handheld device.

If device implementations provide an affordance to change the display size of the device, they:

  • [C-1-1] MUST NOT scale the display larger than 1.5 times DENSITY_DEVICE_STABLE or produce an effective minimum screen dimension smaller than 320dp (equivalent to resource qualifier sw320dp), whichever comes first.
  • [C-1-2] MUST NOT scale the display smaller than 0.85 times the DENSITY_DEVICE_STABLE .
  • To ensure good usability and consistent font sizes, it is RECOMMENDED that the following scaling of Native Display options be provided (while complying with the limits specified above)
    • Small: 0.85x
    • Default: 1x (Native display scale)
    • Large: 1.15x
    • Larger: 1.3x
    • Largest 1.45x

Comienzan nuevos requisitos para 15 (AOSP experimental)

7.1.1.4. Display Overrides

[Withdrawn] 7.1.1.4 (February 26, 2024 preview)

These requirements are withdrawn from Android 15 (AOSP experimental).

Terminar con nuevos requisitos

7.1.1.4 (February 5, 2024 preview)

Device implementations MAY provide user affordance to override application-specific display settings via per-app override APIs or a proprietary mechanism.

If device implementations provide one or more user affordances to override the application-specific display settings (such as screenOrientation , Activity#setRequestedOrientation() , resizeableActivity , minAspectRatio , and maxAspectRatio ), they:

  • [C-1-1] MUST obtain user consent and provide an explicit indication that any override might result in unexpected application display or other user experience issues.
  • [C-1-2] MUST clearly indicate how to revert such overrides.
  • [C-1-3] MUST provide similarly accessible user affordances to revert such overrides.
  • [C-1-4] MUST NOT allow users to override apps in bulk actions.
  • [C-1-5] MUST respect APIs that disable overrides .

Terminar con nuevos requisitos

7.1.2. Display Metrics

If device implementations include the Android-compatible display(s) or video output to the Android-compatible display screen(s), they:

If device implementations does not include an embedded screen or video output, they:

  • [C-2-1] MUST report correct values of the Android-compatible display as defined in the android.util.DisplayMetrics API for the emulated default view.Display .

7.1.3. Orientación de la pantalla

Device implementations:

  • [C-0-1] MUST report which screen orientations they support ( android.hardware.screen.portrait and/or android.hardware.screen.landscape ) and MUST report at least one supported orientation. For example, a device with a fixed orientation landscape screen, such as a television or laptop, SHOULD only report android.hardware.screen.landscape .
  • [C-0-2] MUST report the correct value for the device's current orientation, whenever queried via the android.content.res.Configuration.orientation , android.view.Display.getOrientation() , or other APIs.

If device implementations support both screen orientations, they:

  • [C-1-1] MUST support dynamic orientation by applications to either portrait or landscape screen orientation. That is, the device must respect the application's request for a specific screen orientation.
  • [C-1-2] MUST NOT change the reported screen size or density when changing orientation.
  • MAY select either portrait or landscape orientation as the default.

7.1.4. 2D and 3D Graphics Acceleration

7.1.4.1. OpenGL ES

Device implementations:

  • [C-0-1] MUST correctly identify the supported OpenGL ES versions (1.1, 2.0, 3.0, 3.1, 3.2) through the managed APIs (such as via the GLES10.getString() method) and the native APIs.
  • [C-0-2] MUST include the support for all the corresponding managed APIs and native APIs for every OpenGL ES versions they identified to support.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[Moved] [C-0-3 and C-0-4] (February 26, 2024 preview)

These requirements are moved from CDD to GMS section 3.2.9 OpenGL ES (ANGLE) .

Terminar con nuevos requisitos

[C-0-3 and C-0-4] (February 5, 2024 preview)

If device implementations return false for ActivityManager.isLowRamDevice() , they:

  • [C-0-3] MUST include the ANGLE libraries libEGL_angle.so , libGLESv1_CM_angle.so , and libGLESv2_angle.so . Note: the AOSP reference code includes these binaries by default in the /system/${LIB} directories.
  • [C-0-4] MUST provide a developer option under Settings an affordance for application developers to enable and disable the ANGLE libraries as replacements for the native OpenGL ES driver. This provision is for developer testing purposes and can be This replacement setting MUST be disabled by default.

Terminar con nuevos requisitos

[C-0-3 and C-0-4] (December 11, 2023 preview)

  • [C-0-3] MUST include the ANGLE libraries libEGL_angle.so , libGLESv1_CM_angle.so , and libGLESv2_angle.so . Note: The AOSP reference code includes these binaries by default in the /system/${LIB} directories.
  • [C-0-4] MUST provide a developer option under Settings to enable and disable the ANGLE libraries as replacements for the native OpenGL ES driver. This provision is for developer testing purposes and can be disabled by default.

Terminar con nuevos requisitos

If device implementations include a screen or video output, they:

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-1] (December 11, 2023 preview)

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-SR-1] (December 11, 2023 preview)

  • [C-SR-1] Are STRONGLY RECOMMENDED to support OpenGL ES 3.1.

Terminar con nuevos requisitos

  • SHOULD support OpenGL ES 3.2.

The OpenGL ES dEQP tests are partitioned into a number of test lists, each with an associated date/version number. These are in the Android source tree at external/deqp/android/cts/main/glesXX-master-YYYY-MM-DD.txt . A device that supports OpenGL ES at a self-reported level indicates that it can pass the dEQP tests in all test lists from this level and earlier.

If device implementations support any of the OpenGL ES versions, they:

  • [C-2-1] MUST report via the OpenGL ES managed APIs and native APIs any other OpenGL ES extensions they have implemented, and conversely MUST NOT report extension strings that they do not support.
  • [C-2-2] MUST support the EGL_KHR_image , EGL_KHR_image_base , EGL_ANDROID_image_native_buffer , EGL_ANDROID_get_native_client_buffer , EGL_KHR_wait_sync , EGL_KHR_get_all_proc_addresses , EGL_ANDROID_presentation_time , EGL_KHR_swap_buffers_with_damage , EGL_ANDROID_recordable , and EGL_ANDROID_GLES_layers extensions.
  • [C-2-3] MUST report the maximum version of the OpenGL ES dEQP tests supported via the android.software.opengles.deqp.level feature flag.
  • [C-2-4] MUST at least support version 132383489 (from Mar 1st, 2020) as reported in the android.software.opengles.deqp.level feature flag.
  • [C-2-5] MUST pass all OpenGL ES dEQP Tests in the test lists between version 132383489 and the version specified in the android.software.opengles.deqp.level feature flag, for each supported OpenGL ES version.
  • [C-SR-2] Are STRONGLY RECOMMENDED to support the EGL_KHR_partial_update and OES_EGL_image_external extensions.
  • SHOULD accurately report via the getString() method, any texture compression format that they support, which is typically vendor-specific.

  • SHOULD support the EGL_IMG_context_priority and EGL_EXT_protected_content extensions.

If device implementations declare support for OpenGL ES 3.0, 3.1, or 3.2, they:

  • [C-3-1] MUST export the corresponding function symbols for these version in addition to the OpenGL ES 2.0 function symbols in the libGLESv2.so library.
  • [C-SR-3] Are STRONGLY RECOMMENDED to support the OES_EGL_image_external_essl3 extension.

If device implementations support OpenGL ES 3.2, they:

  • [C-4-1] MUST support the OpenGL ES Android Extension Pack in its entirety.

If device implementations support the OpenGL ES Android Extension Pack in its entirety, they:

  • [C-5-1] MUST identify the support through the android.hardware.opengles.aep feature flag.

If device implementations expose support for the EGL_KHR_mutable_render_buffer extension, they:

  • [C-6-1] MUST also support the EGL_ANDROID_front_buffer_auto_refresh extension.
7.1.4.2. vulcano

Android includes support for Vulkan , a low-overhead, cross-platform API for high-performance 3D graphics.

If device implementations support OpenGL ES 3.1, they:

  • [C-SR-1] Are STRONGLY RECOMMENDED to include support for Vulkan 1.3.
  • [C-4-1] MUST NOT support a Vulkan variant version (ie the variant part of the Vulkan core version MUST be zero).

If device implementations include a screen or video output, they:

  • [C-SR-2] Are STRONGLY RECOMMENDED to include support for Vulkan 1.3.

The Vulkan dEQP tests are partitioned into a number of test lists, each with an associated date/version. These are in the Android source tree at external/deqp/android/cts/main/vk-master-YYYY-MM-DD.txt . A device that supports Vulkan at a self-reported level indicates that it can pass the dEQP tests in all test lists from this level and earlier.

If device implementations include support for Vulkan, they:

  • [C-1-1] MUST report the correct integer value with the android.hardware.vulkan.level and android.hardware.vulkan.version feature flags.
  • [C-1-2] MUST enumerate, at least one VkPhysicalDevice for the Vulkan native API vkEnumeratePhysicalDevices() .
  • [C-1-3] MUST fully implement the Vulkan 1.1 APIs for each enumerated VkPhysicalDevice .
  • [C-1-4] MUST enumerate layers, contained in native libraries named as libVkLayer*.so in the application package's native library directory, through the Vulkan native APIs vkEnumerateInstanceLayerProperties() and vkEnumerateDeviceLayerProperties() .
  • [C-1-5] MUST NOT enumerate layers provided by libraries outside of the application package, or provide other ways of tracing or intercepting the Vulkan API, unless the application has the android:debuggable attribute set as true or the metadata com.android.graphics.injectLayers.enable set to true .
  • [C-1-6] MUST report all extension strings that they do support via the Vulkan native APIs , and conversely MUST NOT report extension strings that they do not correctly support.
  • [C-1-7] MUST support the VK_KHR_surface, VK_KHR_android_surface, VK_KHR_swapchain, and VK_KHR_incremental_present extensions.
  • [C-1-8] MUST report the maximum version of the Vulkan dEQP Tests supported via the android.software.vulkan.deqp.level feature flag.
  • [C-1-9] MUST at least support version 132317953 (from Mar 1st, 2019) as reported in the android.software.vulkan.deqp.level feature flag.
  • [C-1-10] MUST pass all Vulkan dEQP Tests in the test lists between version 132317953 and the version specified in the android.software.vulkan.deqp.level feature flag.
  • [C-1-11] MUST NOT enumerate support for the VK_KHR_video_queue, VK_KHR_video_decode_queue, or VK_KHR_video_encode_queue extensions.
  • [C-SR-3] Are STRONGLY RECOMMENDED to support the VK_KHR_driver_properties and VK_GOOGLE_display_timing extensions.
  • [C-1-12] MUST NOT enumerate support for the VK_KHR_performance_query extension.
  • [C-1-13] MUST satisfy the requirements specified by the Android Baseline 2021 profile .
  • [C-SR-4] Are STRONGLY RECOMMENDED to satisfy the requirements specified by the Android Baseline 2022 profile .
  • [C-SR-5] Are STRONGLY RECOMMENDED to support VkPhysicalDeviceProtectedMemoryFeatures.protectedMemory and VK_EXT_global_priority .
  • [C-SR-6] Are STRONGLY RECOMMENDED to use SkiaVk with HWUI.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-SR-8 and C-1-14] (December 11, 2023 preview)

If device implementations include support for Vulkan, then they:

  • [C-SR-8] Are STRONGLY RECOMMENDED to not modify the Vulkan loader.
  • [C-1-14] MUST NOT enumerate Vulkan Device extensions of type "KHR", "GOOGLE", or "ANDROID" unless these extensions are included in the android.software.vulkan.deqp.level feature flag.

Terminar con nuevos requisitos

If device implementations do not include support for Vulkan 1.0, they:

  • [C-2-1] MUST NOT declare any of the Vulkan feature flags (eg android.hardware.vulkan.level , android.hardware.vulkan.version ).
  • [C-2-2] MUST NOT enumerate any VkPhysicalDevice for the Vulkan native API vkEnumeratePhysicalDevices() .

If device implementations include support for Vulkan 1.1 and declare any of the Vulkan feature flags described here , they:

  • [C-3-1] MUST expose support for the SYNC_FD external semaphore and handle types and the VK_ANDROID_external_memory_android_hardware_buffer extension.

  • [C-SR-7] Are STRONGLY RECOMMENDED to make the VK_KHR_external_fence_fd extension available to third-party applications and enable the application to export fence payload to and import fence payload from POSIX file descriptors as described here .

7.1.4.3. renderizar script
  • [C-0-1] Device implementations MUST support Android RenderScript , as detailed in the Android SDK documentation.
7.1.4.4. 2D Graphics Acceleration

Android includes a mechanism for applications to declare that they want to enable hardware acceleration for 2D graphics at the Application, Activity, Window, or View level through the use of a manifest tag android:hardwareAccelerated or direct API calls.

Device implementations:

  • [C-0-1] MUST enable hardware acceleration by default, and MUST disable hardware acceleration if the developer so requests by setting android:hardwareAccelerated="false" or disabling hardware acceleration directly through the Android View APIs.
  • [C-0-2] MUST exhibit behavior consistent with the Android SDK documentation on hardware acceleration .

Android includes a TextureView object that lets developers directly integrate hardware-accelerated OpenGL ES textures as rendering targets in a UI hierarchy.

Device implementations:

  • [C-0-3] MUST support the TextureView API, and MUST exhibit consistent behavior with the upstream Android implementation.
7.1.4.5. Wide-gamut Displays

If device implementations claim support for wide-gamut displays through Configuration.isScreenWideColorGamut() , they:

  • [C-1-1] MUST have a color-calibrated display.
  • [C-1-2] MUST have a display whose gamut covers the sRGB color gamut entirely in CIE 1931 xyY space.
  • [C-1-3] MUST have a display whose gamut has an area of at least 90% of DCI-P3 in CIE 1931 xyY space.
  • [C-1-4] MUST support OpenGL ES 3.1 or 3.2 and report it properly.
  • [C-1-5] MUST advertise support for the EGL_KHR_no_config_context , EGL_EXT_pixel_format_float , EGL_KHR_gl_colorspace , EGL_EXT_gl_colorspace_scrgb , EGL_EXT_gl_colorspace_scrgb_linear , EGL_EXT_gl_colorspace_display_p3 , EGL_EXT_gl_colorspace_display_p3_linear , and EGL_EXT_gl_colorspace_display_p3_passthrough extensions.
  • [C-SR-1] Are STRONGLY RECOMMENDED to support GL_EXT_sRGB .

Conversely, if device implementations do not support wide-gamut displays, they:

  • [C-2-1] SHOULD cover 100% or more of sRGB in CIE 1931 xyY space, although the screen color gamut is undefined.

7.1.5. Legacy Application Compatibility Mode

Android specifies a "compatibility mode" in which the framework operates in a 'normal' screen size equivalent (320dp width) mode for the benefit of legacy applications not developed for old versions of Android that pre-date screen-size independence.

7.1.6. Tecnología de pantalla

The Android platform includes APIs that allow applications to render rich graphics to an Android-compatible display. Devices MUST support all of these APIs as defined by the Android SDK unless specifically allowed in this document.

All of a device implementation's Android-compatible displays:

  • [C-0-1] MUST be capable of rendering 16-bit color graphics.
  • SHOULD support displays capable of 24-bit color graphics.
  • [C-0-2] MUST be capable of rendering animations.
  • [C-0-3] MUST have a pixel aspect ratio (PAR) between 0.9 and 1.15. That is, the pixel aspect ratio MUST be near square (1.0) with a 10 ~ 15% tolerance.

7.1.7. Secondary Displays

Android includes support for secondary Android-compatible displays to enable media sharing capabilities and developer APIs for accessing external displays.

If device implementations support an external display either via a wired, wireless, or an embedded additional display connection, they:

  • [C-1-1] MUST implement the DisplayManager system service and API as described in the Android SDK documentation.

7.2. Los dispositivos de entrada

Device implementations:

7.2.1. Teclado

If device implementations include support for third-party Input Method Editor (IME) applications, they:

Device implementations:

  • [C-0-1] MUST NOT include a hardware keyboard that does not match one of the formats specified in android.content.res.Configuration.keyboard (QWERTY or 12-key).
  • SHOULD include additional soft keyboard implementations.
  • MAY include a hardware keyboard.

7.2.2. Non-touch Navigation

Android includes support for d-pad, trackball, and wheel as mechanisms for non-touch navigation.

Device implementations:

If device implementations lack non-touch navigations, they:

  • [C-1-1] MUST provide a reasonable alternative user interface mechanism for the selection and editing of text, compatible with Input Management Engines. The upstream Android open source implementation includes a selection mechanism suitable for use with devices that lack non-touch navigation inputs.

7.2.3. Teclas de navegación

The Home , Recents , and Back functions typically provided via an interaction with a dedicated physical button or a distinct portion of the touch screen, are essential to the Android navigation paradigm and therefore, device implementations:

  • [C-0-1] MUST provide a user affordance to launch installed applications that have an activity with the <intent-filter> set with ACTION=MAIN and CATEGORY=LAUNCHER or CATEGORY=LEANBACK_LAUNCHER for Television device implementations. The Home function SHOULD be the mechanism for this user affordance.
  • SHOULD provide buttons for the Recents and Back function.

If the Home, Recents, or Back functions are provided, they:

  • [C-1-1] MUST be accessible with a single action (eg tap, double-click or gesture) when any of them are accessible.
  • [C-1-2] MUST provide a clear indication of which single action would trigger each function. Having a visible icon imprinted on the button, showing a software icon on the navigation bar portion of the screen, or walking the user through a guided step-by-step demo flow during the out-of-box setup experience are examples of such an indicación.

Device implementations:

  • [C-SR-1] are STRONGLY RECOMMENDED to not provide the input mechanism for the Menu function as it is deprecated in favor of action bar since Android 4.0.

  • [C-SR-2] Are STRONGLY RECOMMENDED to provide all navigation functions as cancellable. 'Cancellable' is defined as the user's ability to prevent the navigation function from executing (eg going home, going back, etc.) if the swipe is not released past a certain threshold.

If device implementations provide the Menu function, they:

  • [C-2-1] MUST display the action overflow button whenever the action overflow menu popup is not empty and the action bar is visible.
  • [C-2-2] MUST NOT modify the position of the action overflow popup displayed by selecting the overflow button in the action bar, but MAY render the action overflow popup at a modified position on the screen when it is displayed by selecting the Menu función.

If device implementations do not provide the Menu function, for backwards compatibility, they: * [C-3-1] MUST make the Menu function available to applications when targetSdkVersion is less than 10, either by a physical button, a software key, or gestos. This Menu function should be accessible unless hidden together with other navigation functions.

If device implementations provide the Assist function , they:

  • [C-4-1] MUST make the Assist function accessible with a single action (eg tap, double-click or gesture) when other navigation keys are accessible.
  • [C-SR-3] STRONGLY RECOMMENDED to use long press on HOME function as this designated interaction.

If device implementations use a distinct portion of the screen to display the navigation keys, they:

  • [C-5-1] Navigation keys MUST use a distinct portion of the screen, not available to applications, and MUST NOT obscure or otherwise interfere with the portion of the screen available to applications.
  • [C-5-2] MUST make available a portion of the display to applications that meets the requirements defined in section 7.1.1 .
  • [C-5-3] MUST honor the flags set by the app through the View.setSystemUiVisibility() API method, so that this distinct portion of the screen (aka the navigation bar) is properly hidden away as documented in the SDK.

Si la función de navegación se proporciona como una acción en pantalla basada en gestos:

If a navigation function is provided from anywhere on the left and right edges of the current orientation of the screen:

  • [C-7-1] The navigation function MUST be Back and provided as a swipe from both left and right edges of the current orientation of the screen.
  • [C-7-2] If custom swipeable system panels are provided on the left or right edges, they MUST be placed within the top 1/3rd of the screen with a clear, persistent visual indication that dragging in would invoke the aforementioned panels, and hence not Back. A system panel MAY be configured by a user such that it lands below the top 1/3rd of the screen edge(s) but the system panel MUST NOT use longer than 1/3rd of the edge(s).
  • [C-7-3] When the foreground app has either the View.SYSTEM_UI_FLAG_IMMERSIVE, View.SYSTEM_UI_FLAG_IMMERSIVE_STICKY, WindowInsetsController.BEHAVIOR_DEFAULT, or WindowInsetsController.BEHAVIOR_SHOW_TRANSIENT_BARS_BY_SWIPE flags set, swiping from the edges MUST behave as implemented in AOSP, which is documented in the SDK .
  • [C-7-4] When the foreground app has either the View.SYSTEM_UI_FLAG_IMMERSIVE, View.SYSTEM_UI_FLAG_IMMERSIVE_STICKY, WindowInsetsController.BEHAVIOR_DEFAULT, or WindowInsetsController.BEHAVIOR_SHOW_TRANSIENT_BARS_BY_SWIPE flags set, custom swipeable system panels MUST be hidden until the user brings in or un-dims the system bars (aka navigation and status bar) as implemented in AOSP.

If the back navigation function is provided and the user cancels the Back gesture, then:

  • [C-8-1] OnBackInvokedCallback.onBackCancelled() MUST be called.
  • [C-8-2] OnBackInvokedCallback.onBackInvoked() MUST NOT be called.
  • [C-8-3] KEYCODE_BACK event MUST NOT be dispatched.

If the back navigation function is provided but the foreground application does NOT have an OnBackInvokedCallback registered, then:

  • The system SHOULD provide an animation for the foreground application that suggests that the user is going back, as provided in AOSP.

If device implementations provide support for the system API setNavBarMode to allow any system app with android.permission.STATUS_BAR permission to set the navigation bar mode, then they:

  • [C-9-1] MUST provide support for kid-friendly icons or button-based navigation as provided in the AOSP code.

7.2.4. Touchscreen Input

Android includes support for a variety of pointer input systems, such as touchscreens, touch pads, and fake touch input devices. Touchscreen-based device implementations are associated with a display such that the user has the impression of directly manipulating items on screen. Since the user is directly touching the screen, the system does not require any additional affordances to indicate the objects being manipulated.

Device implementations:

  • SHOULD have a pointer input system of some kind (either mouse-like or touch).
  • SHOULD support fully independently tracked pointers.

If device implementations include a touchscreen (single-touch or better) on a primary Android-compatible display, they:

  • [C-1-1] MUST report TOUCHSCREEN_FINGER for the Configuration.touchscreen API field.
  • [C-1-2] MUST report the android.hardware.touchscreen and android.hardware.faketouch feature flags.

If device implementations include a touchscreen that can track more than a single touch on a primary Android-compatible display, they:

  • [C-2-1] MUST report the appropriate feature flags android.hardware.touchscreen.multitouch , android.hardware.touchscreen.multitouch.distinct , android.hardware.touchscreen.multitouch.jazzhand corresponding to the type of the specific touchscreen on the dispositivo.

If device implementations rely on an external input device such as mouse or trackball (ie not directly touching the screen) for input on a primary Android-compatible display and meet the fake touch requirements in section 7.2.5 , they:

  • [C-3-1] MUST NOT report any feature flag starting with android.hardware.touchscreen .
  • [C-3-2] MUST report only android.hardware.faketouch .
  • [C-3-3] MUST report TOUCHSCREEN_NOTOUCH for the Configuration.touchscreen API field.

7.2.5. Fake Touch Input

Fake touch interface provides a user input system that approximates a subset of touchscreen capabilities. For example, a mouse or remote control that drives an on-screen cursor approximates touch, but requires the user to first point or focus then click. Numerous input devices like the mouse, trackpad, gyro-based air mouse, gyro-pointer, joystick, and multi-touch trackpad can support fake touch interactions. Android includes the feature constant android.hardware.faketouch, which corresponds to a high-fidelity non-touch (pointer-based) input device such as a mouse or trackpad that can adequately emulate touch-based input (including basic gesture support), and indicates that the device supports an emulated subset of touchscreen functionality.

If device implementations do not include a touchscreen but include another pointer input system which they want to make available, they:

  • SHOULD declare support for the android.hardware.faketouch feature flag.

If device implementations declare support for android.hardware.faketouch , they:

  • [C-1-1] MUST report the absolute X and Y screen positions of the pointer location and display a visual pointer on the screen.
  • [C-1-2] MUST report touch event with the action code that specifies the state change that occurs on the pointer going down or up on the screen .
  • [C-1-3] MUST support pointer down and up on an object on the screen, which allows users to emulate tap on an object on the screen.
  • [C-1-4] MUST support pointer down, pointer up, pointer down then pointer up in the same place on an object on the screen within a time threshold, which allows users to emulate double tap on an object on the screen.
  • [C-1-5] MUST support pointer down on an arbitrary point on the screen, pointer move to any other arbitrary point on the screen, followed by a pointer up, which allows users to emulate a touch drag.
  • [C-1-6] MUST support pointer down then allow users to quickly move the object to a different position on the screen and then pointer up on the screen, which allows users to fling an object on the screen.

If device implementations declare support for android.hardware.faketouch.multitouch.distinct , they:

  • [C-2-1] MUST declare support for android.hardware.faketouch .
  • [C-2-2] MUST support distinct tracking of two or more independent pointer inputs.

If device implementations declare support for android.hardware.faketouch.multitouch.jazzhand , they:

  • [C-3-1] MUST declare support for android.hardware.faketouch .
  • [C-3-2] MUST support distinct tracking of 5 (tracking a hand of fingers) or more pointer inputs fully independently.

7.2.6. Soporte de controlador de juego

7.2.6.1. Asignaciones de botones

Device implementations:

  • [C-1-1] MUST be capable to map HID events to the corresponding InputEvent constants as listed in the below tables. The upstream Android implementation satisfies this requirement.

If device implementations embed a controller or ship with a separate controller in the box that would provide means to input all the events listed in the below tables, they:

  • [C-2-1] MUST declare the feature flag android.hardware.gamepad
Botón HID Usage 2 Botón Android
un 1 0x09 0x0001 KEYCODE_BUTTON_A (96)
B 1 0x09 0x0002 KEYCODE_BUTTON_B (97)
X1 0x09 0x0004 KEYCODE_BUTTON_X (99)
Y 1 0x09 0x0005 KEYCODE_BUTTON_Y (100)
D-pad up 1
D-pad down 1
0x01 0x0039 3 AXIS_HAT_Y 4
D-pad left 1
D-pad right 1
0x01 0x0039 3 AXIS_HAT_X 4
Left shoulder button 1 0x09 0x0007 KEYCODE_BUTTON_L1 (102)
Right shoulder button 1 0x09 0x0008 KEYCODE_BUTTON_R1 (103)
Left stick click 1 0x09 0x000E KEYCODE_BUTTON_THUMBL (106)
Right stick click 1 0x09 0x000F KEYCODE_BUTTON_THUMBR (107)
Atrás 1 0x0c 0x0224 KEYCODE_BACK (4)

1 KeyEvent

2 The above HID usages must be declared within a Game pad CA (0x01 0x0005).

3 This usage must have a Logical Minimum of 0, a Logical Maximum of 7, a Physical Minimum of 0, a Physical Maximum of 315, Units in Degrees, and a Report Size of 4. The logical value is defined to be the clockwise rotation away from the vertical axis; for example, a logical value of 0 represents no rotation and the up button being pressed, while a logical value of 1 represents a rotation of 45 degrees and both the up and left keys being pressed.

4 MotionEvent

Analog Controls 1 HID Usage Botón Android
Gatillo izquierdo 0x02 0x00C5 AXIS_LTRIGGER
Gatillo derecho 0x02 0x00C4 AXIS_RTRIGGER
Palanca izquierda 0x01 0x0030
0x01 0x0031
AXIS_X
AXIS_Y
Palanca derecha 0x01 0x0032
0x01 0x0035
AXIS_Z
AXIS_RZ

1 MotionEvent

7.2.7. Control remoto

See Section 2.3.1 for device-specific requirements.

7.3. Sensores

If device implementations include a particular sensor type that has a corresponding API for third-party developers, the device implementation MUST implement that API as described in the Android SDK documentation and the Android Open Source documentation on sensors .

Device implementations:

  • [C-0-1] MUST accurately report the presence or absence of sensors per the android.content.pm.PackageManager class.
  • [C-0-2] MUST return an accurate list of supported sensors via the SensorManager.getSensorList() and similar methods.
  • [C-0-3] MUST behave reasonably for all other sensor APIs (for example, by returning true or false as appropriate when applications attempt to register listeners, not calling sensor listeners when the corresponding sensors are not present; etc.).

If device implementations include a particular sensor type that has a corresponding API for third-party developers, they:

  • [C-1-1] MUST report all sensor measurements using the relevant International System of Units (metric) values for each sensor type as defined in the Android SDK documentation.
  • [C-1-2] MUST report sensor data with a maximum latency of 100 milliseconds + 2 * sample_time for the case of a sensor stream with a maximum requested latency of 0 ms when the application processor is active. This delay does not include any filtering delays.
  • [C-1-3] MUST report the first sensor sample within 400 milliseconds + 2 * sample_time of the sensor being activated. It is acceptable for this sample to have an accuracy of 0.
  • [C-1-4] For any API indicated by the Android SDK documentation to be a continuous sensor , device implementations MUST continuously provide periodic data samples that SHOULD have a jitter below 3%, where jitter is defined as the standard deviation of the difference of the reported timestamp values between consecutive events.
  • [C-1-5] MUST ensure that the sensor event stream MUST NOT prevent the device CPU from entering a suspend state or waking up from a suspend state.
  • [C-1-6] MUST report the event time in nanoseconds as defined in the Android SDK documentation, representing the time the event happened and synchronized with the SystemClock.elapsedRealtimeNano() clock.
  • [C-SR-1] Are STRONGLY RECOMMENDED to have timestamp synchronization error below 100 milliseconds, and SHOULD have timestamp synchronization error below 1 millisecond.
  • When several sensors are activated, the power consumption SHOULD NOT exceed the sum of the individual sensor's reported power consumption.

The list above is not comprehensive; the documented behavior of the Android SDK and the Android Open Source Documentations on sensors is to be considered authoritative.

If device implementations include a particular sensor type that has a corresponding API for third-party developers, they:

  • [C-1-6] MUST set a non-zero resolution for all sensors, and report the value via the Sensor.getResolution() API method.

Some sensor types are composite, meaning they can be derived from data provided by one or more other sensors. (Examples include the orientation sensor and the linear acceleration sensor.)

Device implementations:

  • SHOULD implement these sensor types, when they include the prerequisite physical sensors as described in sensor types .

If device implementations include a composite sensor, they:

  • [C-2-1] MUST implement the sensor as described in the Android Open Source documentation on composite sensors .

If device implementations include a particular sensor type that has a corresponding API for third-party developers and the sensor only reports one value, then device implementations:

  • [C-3-1] MUST set the resolution to 1 for the sensor and report the value via the Sensor.getResolution() API method.

If device implementations include a particular sensor type which supports SensorAdditionalInfo#TYPE_VEC3_CALIBRATION and the sensor is exposed to third-party developers, they:

  • [C-4-1] MUST NOT include any fixed, factory-determined calibration parameters in the data provided.

If device implementations include a combination of 3-axis accelerometer, a 3-axis gyroscope sensor, or a magnetometer sensor, they are:

  • [C-SR-2] STRONGLY RECOMMENDED to ensure the accelerometer, gyroscope and magnetometer have a fixed relative position, such that if the device is transformable (eg foldable), the sensor axes remain aligned and consistent with the sensor coordinate system throughout all possible device transformation states.

7.3.1. Acelerómetro

Device implementations:

  • [C-SR-1] Are STRONGLY RECOMMENDED to include a 3-axis accelerometer.

If device implementations include an accelerometer, they:

  • [C-1-1] MUST be able to report events up to a frequency of at least 50 Hz.
  • [C-1-3] MUST comply with the Android sensor coordinate system as detailed in the Android APIs.
  • [C-1-4] MUST be capable of measuring from freefall up to four times the gravity(4g) or more on any axis.
  • [C-1-5] MUST have a resolution of at least 12-bits.
  • [C-1-6] MUST have a standard deviation no greater than 0.05 m/s^, where the standard deviation should be calculated on a per axis basis on samples collected over a period of at least 3 seconds at the fastest sampling rate.
  • SHOULD report events up to at least 200 Hz.
  • SHOULD have a resolution of at least 16-bits.
  • SHOULD be calibrated while in use if the characteristics changes over the life cycle and compensated, and preserve the compensation parameters between device reboots.
  • SHOULD be temperature compensated.

Si las implementaciones del dispositivo incluyen un acelerómetro de 3 ejes, ellos:

  • [C-2-1] MUST implement and report TYPE_ACCELEROMETER sensor.
  • [C-SR-4] Are STRONGLY RECOMMENDED to implement the TYPE_SIGNIFICANT_MOTION composite sensor.
  • [C-SR-5] Are STRONGLY RECOMMENDED to implement and report TYPE_ACCELEROMETER_UNCALIBRATED sensor. Android devices are STRONGLY RECOMMENDED to meet this requirement so they will be able to upgrade to the future platform release where this might become REQUIRED.
  • SHOULD implement the TYPE_SIGNIFICANT_MOTION , TYPE_TILT_DETECTOR , TYPE_STEP_DETECTOR , TYPE_STEP_COUNTER composite sensors as described in the Android SDK document.

If device implementations include an accelerometer with less than 3 axes, they:

  • [C-3-1] MUST implement and report TYPE_ACCELEROMETER_LIMITED_AXES sensor.
  • [C-SR-6] Are STRONGLY_RECOMMENDED to implement and report TYPE_ACCELEROMETER_LIMITED_AXES_UNCALIBRATED sensor.

If device implementations include a 3-axis accelerometer and any of the TYPE_SIGNIFICANT_MOTION , TYPE_TILT_DETECTOR , TYPE_STEP_DETECTOR , TYPE_STEP_COUNTER composite sensors are implemented:

  • [C-4-1] The sum of their power consumption MUST always be less than 4 mW.
  • SHOULD each be below 2 mW and 0.5 mW for when the device is in a dynamic or static condition.

If device implementations include a 3-axis accelerometer and a 3-axis gyroscope sensor, they:

  • [C-5-1] MUST implement the TYPE_GRAVITY and TYPE_LINEAR_ACCELERATION composite sensors.
  • [C-SR-7] Are STRONGLY RECOMMENDED to implement the TYPE_GAME_ROTATION_VECTOR composite sensor.

If device implementations include a 3-axis accelerometer, a 3-axis gyroscope sensor, and a magnetometer sensor, they:

  • [C-6-1] MUST implement a TYPE_ROTATION_VECTOR composite sensor.

7.3.2. Magnetómetro

Device implementations:

  • [C-SR-1] Are STRONGLY RECOMMENDED to include a 3-axis magnetometer (compass).

If device implementations include a 3-axis magnetometer, they:

  • [C-1-1] MUST implement the TYPE_MAGNETIC_FIELD sensor.
  • [C-1-2] MUST be able to report events up to a frequency of at least 10 Hz and SHOULD report events up to at least 50 Hz.
  • [C-1-3] MUST comply with the Android sensor coordinate system as detailed in the Android APIs.
  • [C-1-4] MUST be capable of measuring between -900 µT and +900 µT on each axis before saturating.
  • [C-1-5] MUST have a hard iron offset value less than 700 µT and SHOULD have a value below 200 µT, by placing the magnetometer far from dynamic (current-induced) and static (magnet-induced) magnetic fields.
  • [C-1-6] MUST have a resolution equal or denser than 0.6 µT.
  • [C-1-7] MUST support online calibration and compensation of the hard iron bias, and preserve the compensation parameters between device reboots.
  • [C-1-8] MUST have the soft iron compensation applied—the calibration can be done either while in use or during the production of the device.
  • [C-1-9] MUST have a standard deviation, calculated on a per axis basis on samples collected over a period of at least 3 seconds at the fastest sampling rate, no greater than 1.5 µT; SHOULD have a standard deviation no greater than 0.5 µT.
  • [C-1-10] MUST implement the TYPE_MAGNETIC_FIELD_UNCALIBRATED sensor.

If device implementations include a 3-axis magnetometer, an accelerometer sensor, and a 3-axis gyroscope sensor, they:

  • [C-2-1] MUST implement a TYPE_ROTATION_VECTOR composite sensor.

If device implementations include a 3-axis magnetometer, an accelerometer, they:

  • MAY implement the TYPE_GEOMAGNETIC_ROTATION_VECTOR sensor.

If device implementations include a 3-axis magnetometer, an accelerometer and TYPE_GEOMAGNETIC_ROTATION_VECTOR sensor, they:

  • [C-3-1] MUST consume less than 10 mW.
  • SHOULD consume less than 3 mW when the sensor is registered for batch mode at 10 Hz.

7.3.3. GPS

Device implementations:

  • [C-SR-1] Are STRONGLY RECOMMENDED to include a GPS/GNSS receiver.

If device implementations include a GPS/GNSS receiver and report the capability to applications through the android.hardware.location.gps feature flag, they:

  • [C-1-1] MUST support location outputs at a rate of at least 1 Hz when requested via LocationManager#requestLocationUpdate .
  • [C-1-2] MUST be able to determine the location in open-sky conditions (strong signals, negligible multipath, HDOP < 2) within 10 seconds (fast time to first fix), when connected to a 0.5 Mbps or faster data speed internet connection. This requirement is typically met by the use of some form of Assisted or Predicted GPS/GNSS technique to minimize GPS/GNSS lock-on time (Assistance data includes Reference Time, Reference Location and Satellite Ephemeris/Clock).
    • [C-1-6] After making such a location calculation, device implementations MUST determine its location, in open sky, within 5 seconds, when location requests are restarted, up to an hour after the initial location calculation, even when the subsequent request is made without a data connection, and/or after a power cycle.
  • In open sky conditions after determining the location, while stationary or moving with less than 1 meter per second squared of acceleration:

    • [C-1-3] MUST be able to determine location within 20 meters, and speed within 0.5 meters per second, at least 95% of the time.
    • [C-1-4] MUST simultaneously track and report via GnssStatus.Callback at least 8 satellites from one constellation.
    • SHOULD be able to simultaneously track at least 24 satellites, from multiple constellations (eg GPS + at least one of Glonass, Beidou, Galileo).
  • [C-SR-2] Are STRONGLY RECOMMENDED to continue to deliver normal GPS/GNSS location outputs through GNSS Location Provider API's during an emergency phone call.

  • [C-SR-3] Are STRONGLY RECOMMENDED to report GNSS measurements from all constellations tracked (as reported in GnssStatus messages), with the exception of SBAS.

  • [C-SR-4] Are STRONGLY RECOMMENDED to report AGC, and Frequency of GNSS measurement.

  • [C-SR-5] Are STRONGLY RECOMMENDED to report all accuracy estimates (including Bearing, Speed, and Vertical) as part of each GPS/GNSS location.

  • [C-SR-6] Are STRONGLY RECOMMENDED to report GNSS measurements, as soon as they are found, even if a location calculated from GPS/GNSS is not yet reported.

  • [C-SR-7] Are STRONGLY RECOMMENDED to report GNSS pseudoranges and pseudorange rates, that, in open-sky conditions after determining the location, while stationary or moving with less than 0.2 meter per second squared of acceleration, are sufficient to calculate position within 20 meters, and speed within 0.2 meters per second, at least 95% of the time.

7.3.4. Giroscopio

Device implementations:

  • [C-SR-1] Are STRONGLY RECOMMENDED to include a gyroscope sensor.

If device implementations include a gyroscope, they:

  • [C-1-1] MUST be able to report events up to a frequency of at least 50 Hz.
  • [C-1-4] MUST have a resolution of 12-bits or more.
  • [C-1-5] MUST be temperature compensated.
  • [C-1-6] MUST be calibrated and compensated while in use, and preserve the compensation parameters between device reboots.
  • [C-1-7] MUST have a variance no greater than 1e-7 rad^2 / s^2 per Hz (variance per Hz, or rad^2 / s). The variance is allowed to vary with the sampling rate, but MUST be constrained by this value. In other words, if you measure the variance of the gyro at 1 Hz sampling rate it SHOULD be no greater than 1e-7 rad^2/s^2.
  • [C-SR-2] Calibration error is STRONGLY RECOMMENDED to be less than 0.01 rad/s when device is stationary at room temperature.
  • [C-SR-3] Are STRONGLY RECOMMENDED to have a resolution of 16-bits or more.
  • SHOULD report events up to at least 200 Hz.

If device implementations include a 3-axis gyroscope, they:

If device implementations include a gyroscope with less than 3 axes, they:

  • [C-3-1] MUST implement and report TYPE_GYROSCOPE_LIMITED_AXES sensor.
  • [C-SR-5] Are STRONGLY_RECOMMENDED to implement and report TYPE_GYROSCOPE_LIMITED_AXES_UNCALIBRATED sensor.

If device implementations include a 3-axis gyroscope, an accelerometer sensor and a magnetometer sensor, they:

  • [C-4-1] MUST implement a TYPE_ROTATION_VECTOR composite sensor.

If device implementations include a 3-axis accelerometer and a 3-axis gyroscope sensor, they:

  • [C-5-1] MUST implement the TYPE_GRAVITY and TYPE_LINEAR_ACCELERATION composite sensors.
  • [C-SR-6] Are STRONGLY RECOMMENDED to implement the TYPE_GAME_ROTATION_VECTOR composite sensor.

7.3.5. Barómetro

Device implementations:

  • [C-SR-1] Are STRONGLY RECOMMENDED to include a barometer (ambient air pressure sensor).

If device implementations include a barometer, they:

  • [C-1-1] MUST implement and report TYPE_PRESSURE sensor.
  • [C-1-2] MUST be able to deliver events at 5 Hz or greater.
  • [C-1-3] MUST be temperature compensated.
  • [C-SR-2] STRONGLY RECOMMENDED to be able to report pressure measurements in the range 300hPa to 1100hPa.
  • SHOULD have an absolute accuracy of 1hPa.
  • SHOULD have a relative accuracy of 0.12hPa over 20hPa range (equivalent to ~1m accuracy over ~200m change at sea level).

7.3.6. Termómetro

If device implementations include an ambient thermometer (temperature sensor), they:

  • [C-1-1] MUST define SENSOR_TYPE_AMBIENT_TEMPERATURE for the ambient temperature sensor and the sensor MUST measure the ambient (room/vehicle cabin) temperature from where the user is interacting with the device in degrees Celsius.

If device implementations include a thermometer sensor that measures a temperature other than ambient temperature, such as CPU temperature, they:

If device implementations include a sensor for monitoring skin temperature, then they:

7.3.7. Fotómetro

  • Device implementations MAY include a photometer (ambient light sensor).

7.3.8. Sensor de proximidad

  • Device implementations MAY include a proximity sensor.

If device implementations include a proximity sensor and they report only a binary "near" or "far" reading, they:

  • [C-1-1] MUST measure the proximity of an object in the same direction as the screen. That is, the proximity sensor MUST be oriented to detect objects close to the screen, as the primary intent of this sensor type is to detect a phone in use by the user. If device implementations include a proximity sensor with any other orientation, it MUST NOT be accessible through this API.
  • [C-1-2] MUST have 1-bit of accuracy or more.
  • [C-1-3] MUST use 0 centimeters as the near reading and 5 centimeters as the far reading.
  • [C-1-4] MUST report a maximum range and resolution of 5.

7.3.9. High Fidelity Sensors

If device implementations include a set of higher quality sensors as defined in this section, and make available them to third-party apps, they:

  • [C-1-1] MUST identify the capability through the android.hardware.sensor.hifi_sensors feature flag.

If device implementations declare android.hardware.sensor.hifi_sensors , they:

  • [C-2-1] MUST have a TYPE_ACCELEROMETER sensor which:

    • MUST have a measurement range between at least -8g and +8g, and is STRONGLY RECOMMENDED to have a measurement range between at least -16g and +16g.
    • MUST have a measurement resolution of at least 2048 LSB/g.
    • MUST have a minimum measurement frequency of 12.5 Hz or lower.
    • MUST have a maximum measurement frequency of 400 Hz or higher; SHOULD support the SensorDirectChannel RATE_VERY_FAST .
    • MUST have a measurement noise not above 400 μg/√Hz.
    • MUST implement a non-wake-up form of this sensor with a buffering capability of at least 3000 sensor events.
    • MUST have a batching power consumption not worse than 3 mW.
    • [C-SR-1] Is STRONGLY RECOMMENDED to have 3dB measurement bandwidth of at least 80% of Nyquist frequency, and white noise spectrum within this bandwidth.
    • SHOULD have an acceleration random walk less than 30 μg √Hz tested at room temperature.
    • SHOULD have a bias change vs. temperature of ≤ +/- 1 mg/°C.
    • SHOULD have a best-fit line non-linearity of ≤ 0.5%, and sensitivity change vs. temperature of ≤ 0.03%/C°.
    • SHOULD have cross-axis sensitivity of < 2.5 % and variation of cross-axis sensitivity < 0.2% in device operation temperature range.
  • [C-2-2] MUST have a TYPE_ACCELEROMETER_UNCALIBRATED with the same quality requirements as TYPE_ACCELEROMETER .

  • [C-2-3] MUST have a TYPE_GYROSCOPE sensor which:

    • MUST have a measurement range between at least -1000 and +1000 dps.
    • MUST have a measurement resolution of at least 16 LSB/dps.
    • MUST have a minimum measurement frequency of 12.5 Hz or lower.
    • MUST have a maximum measurement frequency of 400 Hz or higher; SHOULD support the SensorDirectChannel RATE_VERY_FAST .
    • MUST have a measurement noise not above 0.014°/s/√Hz.
    • [C-SR-2] Is STRONGLY RECOMMENDED to have 3dB measurement bandwidth of at least 80% of Nyquist frequency, and white noise spectrum within this bandwidth.
    • SHOULD have a rate random walk less than 0.001 °/s √Hz tested at room temperature.
    • SHOULD have a bias change vs. temperature of ≤ +/- 0.05 °/ s / °C.
    • SHOULD have a sensitivity change vs. temperature of ≤ 0.02% / °C.
    • SHOULD have a best-fit line non-linearity of ≤ 0.2%.
    • SHOULD have a noise density of ≤ 0.007 °/s/√Hz.
    • SHOULD have calibration error less than 0.002 rad/s in temperature range 10 ~ 40 ℃ when device is stationary.
    • SHOULD have g-sensitivity less than 0.1°/s/g.
    • SHOULD have cross-axis sensitivity of < 4.0 % and cross-axis sensitivity variation < 0.3% in device operation temperature range.
  • [C-2-4] MUST have a TYPE_GYROSCOPE_UNCALIBRATED with the same quality requirements as TYPE_GYROSCOPE .

  • [C-2-5] MUST have a TYPE_GEOMAGNETIC_FIELD sensor which:

    • MUST have a measurement range between at least -900 and +900 μT.
    • MUST have a measurement resolution of at least 5 LSB/uT.
    • MUST have a minimum measurement frequency of 5 Hz or lower.
    • MUST have a maximum measurement frequency of 50 Hz or higher.
    • MUST have a measurement noise not above 0.5 uT.
  • [C-2-6] MUST have a TYPE_MAGNETIC_FIELD_UNCALIBRATED with the same quality requirements as TYPE_GEOMAGNETIC_FIELD and in addition:

    • MUST implement a non-wake-up form of this sensor with a buffering capability of at least 600 sensor events.
    • [C-SR-3] Is STRONGLY RECOMMENDED to have white noise spectrum from 1 Hz to at least 10 Hz when the report rate is 50 Hz or higher.
  • [C-2-7] MUST have a TYPE_PRESSURE sensor which:

    • MUST have a measurement range between at least 300 and 1100 hPa.
    • MUST have a measurement resolution of at least 80 LSB/hPa.
    • MUST have a minimum measurement frequency of 1 Hz or lower.
    • MUST have a maximum measurement frequency of 10 Hz or higher.
    • MUST have a measurement noise not above 2 Pa/√Hz.
    • MUST implement a non-wake-up form of this sensor with a buffering capability of at least 300 sensor events.
    • MUST have a batching power consumption not worse than 2 mW.
  • [C-2-8] MUST have a TYPE_GAME_ROTATION_VECTOR sensor.

  • [C-2-9] MUST have a TYPE_SIGNIFICANT_MOTION sensor which:

    • MUST have a power consumption not worse than 0.5 mW when device is static and 1.5 mW when device is moving.
  • [C-2-10] MUST have a TYPE_STEP_DETECTOR sensor which:

    • MUST implement a non-wake-up form of this sensor with a buffering capability of at least 100 sensor events.
    • MUST have a power consumption not worse than 0.5 mW when device is static and 1.5 mW when device is moving.
    • MUST have a batching power consumption not worse than 4 mW.
  • [C-2-11] MUST have a TYPE_STEP_COUNTER sensor which:

    • MUST have a power consumption not worse than 0.5 mW when device is static and 1.5 mW when device is moving.
  • [C-2-12] MUST have a TILT_DETECTOR sensor which:

    • MUST have a power consumption not worse than 0.5 mW when device is static and 1.5 mW when device is moving.
  • [C-2-13] The event timestamp of the same physical event reported by the Accelerometer, Gyroscope, and Magnetometer MUST be within 2.5 milliseconds of each other. The event timestamp of the same physical event reported by the Accelerometer and Gyroscope SHOULD be within 0.25 milliseconds of each other.

  • [C-2-14] MUST have Gyroscope sensor event timestamps on the same time base as the camera subsystem and within 1 milliseconds of error.

  • [C-2-15] MUST deliver samples to applications within 5 milliseconds from the time when the data is available on any of the above physical sensors to the application.

  • [C-2-16] MUST NOT have a power consumption higher than 0.5 mW when device is static and 2.0 mW when device is moving when any combination of the following sensors are enabled:

    • SENSOR_TYPE_SIGNIFICANT_MOTION
    • SENSOR_TYPE_STEP_DETECTOR
    • SENSOR_TYPE_STEP_COUNTER
    • SENSOR_TILT_DETECTORS
  • [C-2-17] MAY have a TYPE_PROXIMITY sensor, but if present MUST have a minimum buffer capability of 100 sensor events.

Note that all power consumption requirements in this section do not include the power consumption of the Application Processor. It is inclusive of the power drawn by the entire sensor chain—the sensor, any supporting circuitry, any dedicated sensor processing system, etc.

If device implementations include direct sensor support, they:

  • [C-3-1] MUST correctly declare support of direct channel types and direct report rates level through the isDirectChannelTypeSupported and getHighestDirectReportRateLevel API.
  • [C-3-2] MUST support at least one of the two sensor direct channel types for all sensors that declare support for sensor direct channel.
  • SHOULD support event reporting through sensor direct channel for primary sensor (non-wakeup variant) of the following types:
    • TYPE_ACCELEROMETER
    • TYPE_ACCELEROMETER_UNCALIBRATED
    • TYPE_GYROSCOPE
    • TYPE_GYROSCOPE_UNCALIBRATED
    • TYPE_MAGNETIC_FIELD
    • TYPE_MAGNETIC_FIELD_UNCALIBRATED

7.3.10. Sensores biométricos

For additional background on Measuring Biometric Unlock Security, please see Measuring Biometric Security documentation .

If device implementations include a secure lock screen, they:

  • SHOULD include a biometric sensor

Biometric sensors can be classified as Class 3 (formerly Strong ), Class 2 (formerly Weak ), or Class 1 (formerly Convenience ) based on their spoof and imposter acceptance rates, and on the security of the biometric pipeline. This classification determines the capabilities the biometric sensor has to interface with the platform and with third-party applications. Sensors need to meet additional requirements as detailed below if they wish to be classified as either Class 1 , Class 2 or Class 3 . Both Class 2 and Class 3 biometrics get additional capabilities as detailed below.

If device implementations make a biometric sensor available to third-party applications via android.hardware.biometrics.BiometricManager , android.hardware.biometrics.BiometricPrompt , and android.provider.Settings.ACTION_BIOMETRIC_ENROLL , they:

  • [C-4-1] MUST meet the requirements for Class 3 or Class 2 biometric as defined in this document.
  • [C-4-2] MUST recognize and honor each parameter name defined as a constant in the Authenticators class and any combinations thereof. Conversely, MUST NOT honor or recognize integer constants passed to the canAuthenticate(int) and setAllowedAuthenticators(int) methods other than those documented as public constants in Authenticators and any combinations thereof.
  • [C-4-3] MUST implement the ACTION_BIOMETRIC_ENROLL action on devices that have either Class 3 or Class 2 biometrics. This action MUST only present the enrollment entry points for Class 3 or Class 2 biometrics.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-4-4] (April 8, 2024 preview)

  • [C-4-4] MUST allow applications to add custom content to BiometricPrompt using the PromptContentView content display formats. The content display formats MUST NOT be extended to allow imagery, links, interactive content, or other forms of media that are not already part of the BiometricPrompt API. Stylistic adjustments that do not alter, obscure, or truncate this content can be made (such as changing position, padding, margins, and typography).

Terminar con nuevos requisitos

[C-4-4] (February 5, 2024 preview)

  • [C-4-4] MUST NOT fundamentally change the content display formats of the BiometricPrompt (title text, description text, content body templates, etc.) if they support custom BiometricPrompt UI. The content display formats MUST NOT be extended to allow imagery, links, interactive content, or other forms of media that are not already part of the BiometricPrompt API. Minor stylistic adjustments that do not significantly alter or obscure this content can be made (paddings, margins, position, etc.).

Terminar con nuevos requisitos

[C-4-4] (December 11, 2023 preview)

  • [C-4-4] MUST NOT fundamentally change the content display formats of the BiometricPrompt (title text, description text, content body templates, etc.) if they support custom BiometricPrompt UI. The content display formats cannot be extended to allow imagery, links, interactive content, or other forms of media that are not already part of the BiometricPrompt API. Minor stylistic adjustments that do not significantly alter or obscure this content (paddings, margins, position, etc.) MAY be allowed.

Terminar con nuevos requisitos

If device implementations support passive biometrics, they:

  • [C-5-1] MUST by default require an additional confirmation step (eg a button press).
  • [C-SR-1] Are STRONGLY RECOMMENDED to have a setting to allow users to override application preference and always require accompanying confirmation step.
  • [C-SR-2] Are STRONGLY RECOMMENDED to have the confirm action be secured such that an operating system or kernel compromise cannot spoof it. For example, this means that the confirm action based on a physical button is routed through an input-only general-purpose input/output (GPIO) pin of a secure element (SE) that cannot be driven by any other means than a physical button prensa.
  • [C-5-2] MUST additionally implement an implicit authentication flow (without confirmation step) corresponding to setConfirmationRequired(boolean) , which applications can set to utilize for sign-in flows.

If device implementations have multiple biometric sensors, they:

  • [C-7-1] MUST, when a biometric is in lockout (ie the biometric is disabled until the user unlocks with primary authentication) or time-bound lockout (ie the biometric is temporarily disabled until the user waits for a time interval) due to too many failed attempts, also lock out all other biometrics of a lower biometric class. In the case of time-bound lockout, the backoff time for biometric verification MUST be the maximum backoff time of all biometrics in time-bound lockout.

  • [C-SR-12] Are STRONGLY RECOMMENDED, when a biometric is in lockout (ie the biometric is disabled until the user unlocks with primary authentication) or time-bound lockout (ie the biometric is temporarily disabled until the user waits for a time interval) due to too many failed attempts, to also lock out all other biometrics of the same biometric class. In the case of time-bound lockout, the backoff time for biometric verification is STRONGLY RECOMMENDED to be the maximum backoff time of all biometrics in time-bound lockout.

  • [C-7-2] MUST challenge the user for the recommended primary authentication (eg: PIN, pattern, password) to reset the lockout counter for a biometric being locked out. Class 3 biometrics MAY be allowed to reset the lockout counter for a locked biometric of the same or lower class. Class 2 or Class 1 biometrics MUST NOT be allowed to complete a reset lockout operation for any biometrics.

  • [C-SR-3] Are STRONGLY RECOMMENDED to require only one biometric be confirmed per authentication (eg if both fingerprint and face sensors are available on the device, onAuthenticationSucceeded should be sent after any one of them is confirmed).

In order for device implementations to allow access to keystore keys to third-party applications, they:

  • [C-6-1] MUST meet the requirements for Class 3 as defined in this section below.
  • [C-6-2] MUST present only Class 3 biometrics when the authentication requires BIOMETRIC_STRONG , or the authentication is invoked with a CryptoObject .

If device implementations wish to treat a biometric sensor as Class 1 (formerly Convenience ), they:

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-1] (December 11, 2023 preview)

  • [C-1-1] MUST have a false acceptance rate less than 0.002% 0.001% .

Terminar con nuevos requisitos

  • [C-1-2] MUST disclose that this mode may be less secure than a strong PIN, pattern, or password and clearly enumerate the risks of enabling it, if the spoof and imposter acceptance rates are higher than 7% as measured by the Android Biometrics Test Protocols .
  • [C-1-9] MUST challenge the user for the recommended primary authentication (eg, PIN, pattern, password) after no more than twenty false trials and no less than ninety-second backoff time for biometric verification - where a false trial is one with an adequate capture quality (BIOMETRIC_ACQUIRED_GOOD) that does not match an enrolled biometric.
  • [C-SR-4] Are STRONGLY RECOMMENDED to lower the total number of false trials for biometric verification specified in [C-1-9] if the spoof and imposter acceptance rates are higher than 7% as measure by the Android Biometrics Test Protocols .
  • [C-1-3] MUST rate limit attempts for biometric verification - where a false trial is one with an adequate capture quality ( BIOMETRIC_ACQUIRED_GOOD ) that does not match an enrolled biometric.
  • [C-SR-5] Are STRONGLY RECOMMENDED to rate limit attempts for at least 30 seconds after five false trials for biometric verification for the maximum number of false trials per [C-1-9] - where a false trial is one with an adequate capture quality (BIOMETRIC_ACQUIRED_GOOD) that does not match an enrolled biometric.
  • [C-SR-6] Are STRONGLY RECOMMENDED to have all rate limiting logic in TEE.
  • [C-1-10] MUST disable biometrics once primary authentication backoff has first triggered as described in [C-0-2] of section 9.11.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-11] (December 11, 2023 preview)

  • [C-1-11] MUST have a spoof and imposter acceptance rate not higher than 30%, with (1) a spoof and imposter acceptance rate for Level A presentation attack instrument (PAI) species not higher than 30%, and (2) a spoof and imposter acceptance rate of Level B PAI species not higher than 40%, as measured by the Android Biometrics Test Protocols.

Terminar con nuevos requisitos

  • [C-1-4] MUST prevent adding new biometrics without first establishing a chain of trust by having the user confirm existing or add a new device credential (PIN/pattern/password) that's secured by TEE; the Android Open Source Project implementation provides the mechanism in the framework to do so.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-5] (December 11, 2023 preview)

  • [C-1-5] MUST completely remove all identifiable biometric data for a user when the user's account is removed (including via a factory reset) or when the recommended primary authentication (eg PIN, pattern, password) is removed .

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-7] (April 8, 2024 preview)

  • [C-1-7] MUST challenge the user for the recommended primary authentication (eg, PIN, pattern, password) once every 24 hours or less. Note: Upgrading devices launched on Android version 9 or earlier MUST challenge the user for the recommended primary authentication (eg, PIN, pattern, password) once every 72 hours or less.

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-8] (December 11, 2023 preview)

  • [C-1-8] MUST challenge the user for the recommended primary authentication (eg, PIN, pattern, password) or Class 3 (STRONG) biometric after one of the following:
    • a 4-hour idle timeout period, OR
    • 3 failed biometric authentication attempts.
    • The idle timeout period and the failed authentication count is reset after any successful confirmation of the device credentials. Note: Upgrading devices launched on Android version 9 or earlier MAY be exempted from C-1-8.

Terminar con nuevos requisitos

  • [C-SR-7] Are STRONGLY RECOMMENDED to use the logic in the framework provided by the Android Open Source Project to enforce constraints specified in [C-1-7] and [C-1-8] for new devices.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-14] (December 11, 2023 preview)

  • [ C-SR-8 C-1-14 ] Are STRONGLY RECOMMENDED to MUST have a false rejection rate of less than 10%, as measured on the device.

Terminar con nuevos requisitos

  • [C-SR-9] Are STRONGLY RECOMMENDED to have a latency below 1 second, measured from when the biometric is detected, until the screen is unlocked, for each enrolled biometric.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-12] (December 11, 2023 preview)

  • [C-1-12] MUST have a spoof and imposter acceptance rate not higher than 40% per presentation attack instrument (PAI) species , as measured by the Android Biometrics Test Protocols .

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-13] (December 11, 2023 preview)

  • [ C-SR-13 C-1-13 ] Are STRONGLY RECOMMENDED to MUST have a spoof and imposter acceptance rate not higher than 30% per presentation attack instrument (PAI) species , as measured by the Android Biometrics Test Protocols .

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-14] (April 8, 2024 preview)

  • [C-1-14] MUST have a false rejection rate of less than 10%, as measured on the device.

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-15] (December 11, 2023 preview)

  • [C-1-15] MUST allow users to remove single or multiple biometrics enrollments.

Terminar con nuevos requisitos

  • [C-SR-14] Are STRONGLY RECOMMENDED to disclose the biometric class of the biometric sensor and the corresponding risks of enabling it.

  • [C-SR-17] Are STRONGLY RECOMMENDED to implement the new AIDL interfaces (such as, IFace.aidl and IFingerprint.aidl ).

If device implementations wish to treat a biometric sensor as Class 2 (formerly Weak ), they:

  • [C-2-1] MUST meet all requirements for Class 1 above.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-2-2] (December 11, 2023 preview)

  • [C-2-2] MUST have a spoof and imposter acceptance rate not higher than 20%, with (1) a spoof and imposter acceptance rate for Level A presentation attack instrument (PAI) species not higher than 20%, and (2) a spoof and imposter acceptance rate of Level B PAI species not higher than 30%, as measured by the Android Biometrics Test Protocols .

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-2-10] (December 11, 2023 preview)

  • [ C-SR-15 C-2-10 ] Are STRONGLY RECOMMENDED to MUST have a spoof and imposter acceptance rate not higher than 20% per presentation attack instrument (PAI) species , as measured by the Android Biometrics Test Protocols .

Terminar con nuevos requisitos

  • [C-2-3] MUST perform the biometric matching in an isolated execution environment outside Android user or kernel space, such as the Trusted Execution Environment (TEE), on a chip with a secure channel to the isolated execution environment or on Protected Virtual Machine that meets requirements in Section 9.17.
  • [C-2-4] MUST have all identifiable data encrypted and cryptographically authenticated such that they cannot be acquired, read or altered outside of the isolated execution environment or a chip with a secure channel to the isolated execution environment as documented in the implementation guidelines on the Android Open Source Project site or a Protected Virtual Machine controlled by hypervisor that meets requirements in Section 9.17.
  • [C-2-5] For camera based biometrics, while biometric based authentication or enrollment is happening:
    • MUST operate the camera in a mode that prevents camera frames from being read or altered outside the isolated execution environment or a chip with a secure channel to the isolated execution environment or a Protected Virtual Machine controlled by hypervisor that meets requirements in Section 9.17.
    • For RGB single-camera solutions, the camera frames CAN be readable outside the isolated execution environment to support operations such as preview for enrollment, but MUST still NOT be alterable.
  • [C-2-6] MUST NOT enable third-party applications to distinguish between individual biometric enrollments.
  • [C-2-7] MUST NOT allow unencrypted access to identifiable biometric data or any data derived from it (such as embeddings) to the Application Processor outside the context of the TEE or the Protected Virtual Machine controlled by hypervisor that meets requirements in Section 9.17. Upgrading devices launched on Android version 9 or earlier are not exempted from C-2-7.
  • [C-2-8] MUST have a secure processing pipeline such that an operating system or kernel compromise cannot allow data to be directly injected to falsely authenticate as the user. Note: If device implementations are already launched on Android version 9 or earlier and cannot meet the requirement C-2-8 through a system software update, they MAY be exempted from the requirement.

  • [C-SR-10] Are STRONGLY RECOMMENDED to include liveness detection for all biometric modalities and attention detection for Face biometrics.

  • [C-2-9] MUST make the biometric sensor available to third-party applications.

If device implementations wish to treat a biometric sensor as Class 3 (formerly Strong ), they:

  • [C-3-1] MUST meet all the requirements of Class 2 above, except for [C-1-7] and [C-1-8].
  • [C-3-2] MUST have a hardware-backed keystore implementation.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-3-3] (December 11, 2023 preview)

  • [C-3-3] MUST have a spoof and imposter acceptance rate not higher than 7%, with (1) a spoof and imposter acceptance rate for Level A presentation attack instrument (PAI) species not higher than 7%, and (2) a spoof and imposter acceptance rate of Level B PAI species not higher than 20%, as measured by the Android Biometrics Test Protocols .

Terminar con nuevos requisitos

  • [C-3-4] MUST challenge the user for the recommended primary authentication (eg PIN, pattern, password) once every 72 hours or less.
  • [C-3-5] MUST re-generate Authenticator ID for all Class 3 biometrics supported on device if any of them is re-enrolled.
  • [C-3-6] Must enable biometric-backed keystore keys to third-party applications.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-3-7] (December 11, 2023 preview)

  • [ C-SR-16 C-3-7 ] Are STRONGLY RECOMMENDED to MUST have a spoof and imposter acceptance rate not higher than 7% per presentation attack instrument (PAI) species , as measured by the Android Biometrics Test Protocols .

Terminar con nuevos requisitos

If device implementations contain an under-display fingerprint sensor (UDFPS), they:

  • [C-SR-11] Are STRONGLY RECOMMENDED to prevent the touchable area of the UDFPS from interfering with 3-button navigation( which some users might require for accessibility purposes).

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-8-1 through C-8-6] [Withdrawn] (April 8, 2024 preview)

These requirements are withdrawn from Android 15 (AOSP experimental).

Terminar con nuevos requisitos

[C-8-1 through C-8-6] (December 11, 2023 preview)

If device implementations wish to allow a biometric sensor for binding (ie to be used as the primary user verification method bound for specific use cases), they:

  • [C-8-1] MUST meet the requirements for Class 3 as defined in this section. Class 3 biometrics MAY be excluded and not participate in binding if usability under certain circumstances is a concern due to the fallback requirement below.
  • [C-8-2] MUST NOT allow more than one bound biometric at a time. For example, if multiple biometric modalities are available and eligible, such as face and fingerprint, only one modality and only one enrollment of the modality (eg, only one enrolled fingerprint) can be bound at a time.
  • [C-8-3] MUST NOT allow fallback to device credential (PIN/pattern/password) when the bound biometric is requested.
  • [C-8-4] MUST require the presentation of a new or previously enrolled biometric to be added as a bound biometric, or the presentation of the currently bound biometric to change the bound biometric to a new or previously enrolled biometric.
  • [C-8-5] MUST implement setRequireBoundBiometric(boolean) which applications can utilize to request bound biometric for authentication flows.
  • [C-8-6] MUST treat a bound biometric as any other Class 3 biometric regardless of when it is requested (ie setRequireBoundBiometric(boolean )). For example, the bound biometric cannot be excluded when it is not requested or prevent applications from using a CryptoObject that would have otherwise been available.

Terminar con nuevos requisitos

7.3.11. Pose Sensor

Device implementations:

  • MAY support pose sensor with 6 degrees of freedom.

If device implementations support pose sensor with 6 degrees of freedom, they:

  • [C-1-1] MUST implement and report TYPE_POSE_6DOF sensor.
  • [C-1-2] MUST be more accurate than the rotation vector alone.

7.3.12. Hinge Angle Sensor

If device implementations support a hinge angle sensor, they:

7.3.13. IEEE 802.1.15.4 (UWB)

If device implementations include support for 802.1.15.4 and expose the functionality to a third-party application, they:

  • [C-1-2] MUST report the hardware feature flag android.hardware.uwb .
  • [C-1-3] MUST support all the following configuration sets (pre-defined combinations of FIRA UCI parameters) defined in the AOSP implementation.
    • CONFIG_ID_1 : FiRa-defined unicast STATIC STS DS-TWR ranging, deferred mode, ranging interval 240 ms.
    • CONFIG_ID_2 : FiRa-defined one-to-many STATIC STS DS-TWR ranging, deferred mode, ranging interval 200 ms. Typical use case: smart phone interacts with many smart devices.
    • CONFIG_ID_3 : Same as CONFIG_ID_1 , except Angle-of-arrival (AoA) data is not reported.
    • CONFIG_ID_4 : Same as CONFIG_ID_1 , except P-STS security mode is enabled.
    • CONFIG_ID_5 : Same as CONFIG_ID_2 , except P-STS security mode is enabled.
    • CONFIG_ID_6 : Same as CONFIG_ID_3 , except P-STS security mode is enabled.
    • CONFIG_ID_7 : Same as CONFIG_ID_2 , except P-STS individual controlee key mode is enabled.
  • [C-1-4] MUST provide a user affordance to allow the user to toggle the UWB radio on/off state.
  • [C-1-5] MUST enforce that apps using UWB radio hold the UWB_RANGING permission (under the NEARBY_DEVICES permission group).

Passing the relevant conformance and certification tests defined by standard organizations, including FIRA , CCC and CSA helps ensure 802.1.15.4 functions correctly.

7.4. Conectividad de datos

7.4.1. Telefonía

"Telephony" as used by the Android APIs and this document refers specifically to hardware related to placing voice calls and sending SMS messages, or establishing mobile data via a mobile (eg GSM, CDMA, LTE, NR)GSM or CDMA network. A device supporting "Telephony" may choose to offer some or all of the call, messaging and data services as fits the product.

  • Android MAY be used on devices that do not include telephony hardware. That is, Android is compatible with devices that are not phones.

If device implementations include GSM or CDMA telephony, they:

  • [C-1-1] MUST declare the android.hardware.telephony feature flag and other sub-feature flags according to the technology.
  • [C-1-2] MUST implement full support for the API for that technology.
  • SHOULD allow all available cellular service types (2G, 3G, 4G, 5G, etc.) during emergency calls (regardless of the network types set by SetAllowedNetworkTypeBitmap() ).

If device implementations do not include telephony hardware, they:

  • [C-2-1] MUST implement the full APIs as no-ops.

If device implementations support eUICCs or eSIMs/embedded SIMs and include a proprietary mechanism to make eSIM functionality available for third-party developers, they:

If device implementations don't set the system property ro.telephony.iwlan\_operation\_mode to 'legacy', then they:

If device implementations support a single IP Multimedia Subsystem (IMS) registration for both multimedia telephony service (MMTEL) and rich communication service (RCS) features and are expected to comply with cellular carrier requirements regarding using a single IMS registration for all IMS signalling traffic, ellos:

If device implementations report the android.hardware.telephony feature, then:

If the device implementations report the android.hardware.telephony feature and provide a system status bar, then:

  • [C-7-1] MUST select a representative active subscription for a given group UUID to display to the user in any affordances that provide SIM status information. Examples of such affordances include the status bar cellular signal icon or quick settings tile.
  • [C-SR-1] It is STRONGLY RECOMMENDED that the representative subscription is chosen to be the active data subscription unless the device is in a voice call, during which it is STRONGLY RECOMMENDED that the representative subscription is the active voice subscription.

If device implementations report the android.hardware.telephony feature, then:

  • [C-6-7] MUST be capable of opening and concurrently utilizing the maximum number of logical channels (20 in total) for each UICC per ETSI TS 102 221.
  • [C-6-8] MUST NOT apply any of the following behaviors to active carrier apps (as designated by TelephonyManager#getCarrierServicePackageName ) automatically or without explicit user confirmation:
    • Revoke or limit network access
    • Revocar permisos
    • Restrict background or foreground app execution beyond the existing power management features included in AOSP
    • Disable or uninstall the app

If device implementations report the android.hardware.telephony feature and all active, non-opportunistic subscriptions that share a group UUID are disabled, physically removed from the device, or marked opportunistic, then the device:

  • [C-8-1] MUST automatically disable all remaining active opportunistic subscriptions in the same group.

If device implementations include GSM telephony but not CDMA telephony, they:

If the device implementations support eUICCs with multiple ports and profiles, they:

7.4.1.1. Number Blocking Compatibility

If device implementations report the android.hardware.telephony.calling feature, they:

  • [C-1-1] MUST include number blocking support
  • [C-1-2] MUST fully implement BlockedNumberContract and the corresponding API as described in the SDK documentation.
  • [C-1-3] MUST block all calls and messages from a phone number in 'BlockedNumberProvider' without any interaction with apps. The only exception is when number blocking is temporarily lifted as described in the SDK documentation.

  • [C-1-4] MUST write to the platform call log provider for a blocked call and MUST filter calls with BLOCKED_TYPE out of the default call log view in the pre-installed dialer app.

  • [C-1-5] MUST NOT write to the Telephony provider for a blocked message.

  • [C-1-6] MUST implement a blocked numbers management UI, which is opened with the intent returned by TelecomManager.createManageBlockedNumbersIntent() method.

  • [C-1-7] MUST NOT allow secondary users to view or edit the blocked numbers on the device as the Android platform assumes the primary user to have full control of the telephony services, a single instance, on the device. All blocking related UI MUST be hidden for secondary users and the blocked list MUST still be respected.

  • SHOULD migrate the blocked numbers into the provider when a device updates to Android 7.0.

  • SHOULD provide a user affordance to show blocked calls in the pre-installed dialer app.

7.4.1.2. API de telecomunicaciones

If device implementations report android.hardware.telephony.calling , they:

  • [C-1-1] MUST support the ConnectionService APIs described in the SDK .
  • [C-1-2] MUST display a new incoming call and provide user affordance to accept or reject the incoming call when the user is on an ongoing call that is made by a third-party app that does not support the hold feature specified via CAPABILITY_SUPPORT_HOLD .
  • [C-1-3] MUST have an application that implements InCallService .
  • [C-SR-1] Are STRONGLY RECOMMENDED to notify the user that answering an incoming call will drop an ongoing call.

    The AOSP implementation meets these requirements by a heads-up notification which indicates to the user that answering an incoming call will cause the other call to be dropped.

  • [C-SR-2] Are STRONGLY RECOMMENDED to preload the default dialer app that shows a call log entry and the name of a third-party app in its call log when the third-party app sets the EXTRA_LOG_SELF_MANAGED_CALLS extras key on its PhoneAccount to true .

  • [C-SR-3] Are STRONGLY RECOMMENDED to handle the audio headset's KEYCODE_MEDIA_PLAY_PAUSE and KEYCODE_HEADSETHOOK events for the android.telecom APIs as below:

7.4.1.3. Cellular NAT-T Keepalive Offload

Device implementations:

  • SHOULD include support for Cellular keepalive offload.

If device implementations include support for Cellular keepalive offload and exposes the functionality to third-party apps, they:

  • [C-1-1] MUST support the SocketKeepAlive API.
  • [C-1-2] MUST support at least one concurrent keepalive slot over cellular.
  • [C-1-3] MUST support as many concurrent cellular keepalive slots as are supported by the Cellular Radio HAL.
  • [C-SR-1] Are STRONGLY RECOMMENDED to support at least three cellular keepalive slots per radio instance.

If device implementations do not include support for cellular keepalive offload, they:

  • [C-2-1] MUST return ERROR_UNSUPPORTED.

7.4.2. IEEE 802.11 (Wi-Fi)

Device implementations:

  • SHOULD include support for one or more forms of 802.11.

If device implementations include support for 802.11 and expose the functionality to a third-party application, they:

  • [C-1-1] MUST implement the corresponding Android API.
  • [C-1-2] MUST report the hardware feature flag android.hardware.wifi .
  • [C-1-3] MUST implement the multicast API as described in the SDK documentation.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-4] (December 11, 2023 preview)

  • [C-1-4] MUST support multicast DNS (mDNS) and MUST NOT filter mDNS packets (224.0.0.251 or ff02::fb) at any time of operation, including when the screen is not in an active state, unless dropping or filtering these packets is necessary to stay within power consumption ranges required by regulatory requirements applicable to the target market.

  • [C-1-4] MUST support mDNS and MUST NOT filter mDNS packets (224.0.0.251 or ff02::fb) at any time of operation, including when the screen is not in an active state, unless the multicast lock is not held and the packets are filtered by APF. The packets are not required to satisfy any mDNS operations currently requested by applications through the NsdManager APIs. However, the device MAY filter mDNS packets if doing so is necessary to stay within power consumption ranges required by regulatory requirements applicable to the target market.

Terminar con nuevos requisitos

  • [C-1-5] MUST NOT treat the WifiManager.enableNetwork() API method call as a sufficient indication to switch the currently active Network that is used by default for application traffic and is returned by ConnectivityManager API methods such as getActiveNetwork and registerDefaultNetworkCallback . In other words, they MAY only disable the Internet access provided by any other network provider (eg mobile data) if they successfully validate that the Wi-Fi network is providing Internet access.
  • [C-1-6] Are STRONGLY RECOMMENDED to, when the ConnectivityManager.reportNetworkConnectivity() API method is called, re-evaluate the Internet access on the Network and, once the evaluation determines that the current Network no longer provides Internet access, switch to any other available network (eg mobile data) that provides Internet access.
  • [C-1-7] MUST randomize the source MAC address and sequence number of probe request frames, once at the beginning of each scan, while STA is disconnected.
  • [C-1-8] MUST use one consistent MAC address (SHOULD NOT randomize MAC address halfway through a scan).
  • [C-1-9] MUST iterate probe request sequence number as normal (sequentially) between the probe requests in a scan.
  • [C-1-10] MUST randomize Probe request sequence number between the last probe request of a scan and the first probe request of the next scan.
  • [C-SR-1] Are STRONGLY RECOMMENDED to randomize the source MAC address used for all STA communication to an Access Point (AP) while associating and associated.
    • The device MUST use a different randomized MAC address for each SSID (FQDN for Passpoint) it communicates with.
    • The device MUST provide the user with an option to control the randomization per SSID (FQDN for Passpoint) with non randomized and randomized options, and MUST set the default mode for new Wi-Fi configurations to be randomized.
  • [C-SR-2] Are STRONGLY RECOMMENDED to use a random BSSID for any AP that they create.
    • The MAC address MUST be randomized and persisted per SSID used by the AP.
    • The DEVICE MAY provide the user with an option to disable this feature. If such an option is provided, randomization MUST be enabled by default.

If device implementations include support for Wi-Fi power save mode as defined in IEEE 802.11 standard, they:

  • SHOULD turn off Wi-Fi power save mode whenever an app acquires WIFI_MODE_FULL_HIGH_PERF lock or WIFI_MODE_FULL_LOW_LATENCY lock via WifiManager.createWifiLock() and WifiManager.WifiLock.acquire() APIs and the lock is active.
  • [C-3-2] The average round trip latency between the device and an access point while the device is in a Wi-Fi Low Latency Lock ( WIFI_MODE_FULL_LOW_LATENCY ) mode MUST be smaller than the latency during a Wi-Fi High Perf Lock ( WIFI_MODE_FULL_HIGH_PERF ) mode.
  • [C-SR-3] Are STRONGLY RECOMMENDED to minimize Wi-Fi round trip latency whenever a Low Latency Lock ( WIFI_MODE_FULL_LOW_LATENCY ) is acquired and takes effect.

If device implementations support Wi-Fi and use Wi-Fi for location scanning, they:

7.4.2.1. Wi-Fi directo

Device implementations:

  • SHOULD include support for Wi-Fi Direct (Wi-Fi peer-to-peer).

If device implementations include support for Wi-Fi Direct, they:

  • [C-1-1] MUST implement the corresponding Android API as described in the SDK documentation.
  • [C-1-2] MUST report the hardware feature android.hardware.wifi.direct .
  • [C-1-3] MUST support regular Wi-Fi operation.
  • [C-1-4] MUST support Wi-Fi and Wi-Fi Direct operations concurrently.
  • [C-SR-1] Are STRONGLY RECOMMENDED to randomize the source MAC address for all newly formed Wi-Fi Direct connections.

Device implementations:

If device implementations include support for TDLS and TDLS is enabled by the WiFiManager API, they:

  • [C-1-1] MUST declare support for TDLS through WifiManager.isTdlsSupported .
  • SHOULD use TDLS only when it is possible AND beneficial.
  • SHOULD have some heuristic and NOT use TDLS when its performance might be worse than going through the Wi-Fi access point.
7.4.2.3. Compatible con Wi-Fi

Device implementations:

If device implementations include support for Wi-Fi Aware and expose the functionality to third-party apps, then they:

  • [C-1-1] MUST implement the WifiAwareManager APIs as described in the SDK documentation .
  • [C-1-2] MUST declare the android.hardware.wifi.aware feature flag.
  • [C-1-3] MUST support Wi-Fi and Wi-Fi Aware operations concurrently.
  • [C-1-4] MUST randomize the Wi-Fi Aware management interface address at intervals no longer than 30 minutes and whenever Wi-Fi Aware is enabled unless an Aware ranging operation is ongoing or an Aware data-path is active (randomization is not expected for as long as the data-path is active).

If device implementations include support for Wi-Fi Aware and Wi-Fi Location as described in Section 7.4.2.5 and exposes these functionalities to third-party apps, then they:

7.4.2.4. Punto de acceso Wi-Fi

If device implementations include support for 802.11 (Wi-Fi) they:

  • [C-1-1] MUST include support for Wi-Fi Passpoint .
  • [C-1-2] MUST implement the Passpoint related WifiManager APIs as described in the SDK documentation .
  • [C-1-3] MUST support IEEE 802.11u standard, specifically related to Network Discovery and Selection, such as Generic Advertisement Service (GAS) and Access Network Query Protocol (ANQP).
  • [C-1-4] MUST declare android.hardware.wifi.passpoint feature flag.
  • [C-1-5] MUST follow the AOSP implementation to discover, match and associate to Passpoint networks.
  • [C-1-6] MUST support at least the following subset of device provisioning protocols as defined in the Wi-Fi Alliance Passpoint R2: EAP-TTLS authentication and SOAP-XML.
  • [C-1-7] MUST process the AAA server certificate as described in Hotspot 2.0 R3 specification.
  • [C-1-8] MUST support user control of provisioning through the Wi-Fi picker.
  • [C-1-9] MUST keep Passpoint configurations persistent across reboots.
  • [C-SR-1] Are STRONGLY RECOMMENDED to support the terms and conditions acceptance feature.
  • [C-SR-2] Are STRONGLY RECOMMENDED to support the Venue information feature.

If a global Passpoint disable user control switch is provided, implementations:

  • [C-3-1] MUST enable Passpoint by default.
7.4.2.5. Wi-Fi Location (Wi-Fi Round Trip Time - RTT)

Device implementations:

If device implementations include support for Wi-Fi Location and expose the functionality to third-party apps, then they:

  • [C-1-1] MUST implement the WifiRttManager APIs as described in the SDK documentation .
  • [C-1-2] MUST declare the android.hardware.wifi.rtt feature flag.
  • [C-1-3] MUST randomize the source MAC address for each RTT burst which is executed while the Wi-Fi interface on which the RTT is being executed is not associated to an Access Point.
  • [C-1-4] MUST be accurate to within 2 meters at 80 MHz bandwidth at the 68th percentile (as calculated with the Cumulative Distribution Function).
  • [C-SR-1] Are STRONGLY RECOMMENDED to report it accurately to within 1.5 meters at 80 MHz bandwidth at the 68th percentile (as calculated with the Cumulative Distribution Function).
7.4.2.6. Wi-Fi Keepalive Offload

Device implementations:

  • SHOULD include support for Wi-Fi keepalive offload.

If device implementations include support for Wi-Fi keepalive offload and expose the functionality to third-party apps, they:

  • [C-1-1] MUST support the SocketKeepAlive API.
  • [C-1-2] MUST support at least three concurrent keepalive slots over Wi-Fi

If device implementations do not include support for Wi-Fi keepalive offload, they:

7.4.2.7. Wi-Fi Easy Connect (Device Provisioning Protocol)

Device implementations:

If device implementations include support for Wi-Fi Easy Connect and expose the functionality to third-party apps, they:

7.4.2.8. Enterprise Wi-Fi Server Certificate Validation

If the Wi-Fi server certificate is not validated or the Wi-Fi server domain name is not set, device implementations:

  • [C-SR-1] Are STRONGLY RECOMMENDED not to provide the user an option to manually add Enterprise Wi-Fi network in the Settings app.
7.4.2.9. Trust On First Use (TOFU)

If device implementations support Trust on first usage (TOFU) and allow the user to define WPA/WPA2/WPA3-Enterprise configurations, then they:

  • [C-4-1] MUST provide the user an option to select to use TOFU.

7.4.3. Bluetooth

If device implementations support Bluetooth Audio profile, they:

  • SHOULD support Advanced Audio Codecs and Bluetooth Audio Codecs (eg LDAC)

If device implementations support HFP, A2DP and AVRCP, they:

  • SHOULD support at least 5 total connected devices.

If device implementations declare android.hardware.vr.high_performance feature, they:

  • [C-1-1] MUST support Bluetooth 4.2 and Bluetooth LE Data Length Extension.

Android includes support for Bluetooth and Bluetooth Low Energy .

If device implementations include support for Bluetooth and Bluetooth Low Energy, they:

  • [C-2-1] MUST declare the relevant platform features ( android.hardware.bluetooth and android.hardware.bluetooth_le respectively) and implement the platform APIs.
  • SHOULD implement relevant Bluetooth profiles such as A2DP, AVRCP, OBEX, HFP, etc. as appropriate for the device.

If device implementations include support for Bluetooth Low Energy (BLE), they:

  • [C-3-1] MUST declare the hardware feature android.hardware.bluetooth_le .
  • [C-3-2] MUST enable the GATT (generic attribute profile) based Bluetooth APIs as described in the SDK documentation and android.bluetooth .
  • [C-3-3] MUST report the correct value for BluetoothAdapter.isOffloadedFilteringSupported() to indicate whether the filtering logic for the ScanFilter API classes is implemented.
  • [C-3-4] MUST report the correct value for BluetoothAdapter.isMultipleAdvertisementSupported() to indicate whether Low Energy Advertising is supported.
  • [C-3-5] MUST implement a Resolvable Private Address (RPA) timeout no longer than 15 minutes and rotate the address at timeout to protect user privacy when device is actively using BLE for scanning or advertising. To prevent timing attacks, timeout intervals MUST also be randomized between 5 and 15 minutes.

  • SHOULD support offloading of the filtering logic to the bluetooth chipset when implementing the ScanFilter API .

  • SHOULD support offloading of the batched scanning to the bluetooth chipset.

  • SHOULD support multi advertisement with at least 4 slots.

If device implementations support Bluetooth LE and use Bluetooth LE for location scanning, they:

  • [C-4-1] MUST provide a user affordance to enable/disable the value read through the System API BluetoothAdapter.isBleScanAlwaysAvailable() .

If device implementations include support for Bluetooth LE and Hearing Aids Profile, as described in Hearing Aid Audio Support Using Bluetooth LE , they:

If device implementations include support for Bluetooth or Bluetooth Low Energy, they:

  • [C-6-1] MUST restrict access to any Bluetooth metadata (such as scan results) which could be used to derive the location of the device, unless the requesting app successfully passes an android.permission.ACCESS_FINE_LOCATION permission check based on its current foreground/background state.

If device implementations include support for Bluetooth or Bluetooth Low Energy and the app manifest does not include a declaration from the developer stating that they are not deriving location from Bluetooth, then, they:

If device implementations return true for the BluetoothAdapter.isLeAudioSupported() API, then they:

  • [C-7-1] MUST support unicast client.
  • [C-7-2] MUST support 2M PHY.
  • [C-7-3] MUST support LE Extended advertising.
  • [C-7-4] MUST support at least 2 CIS connections in a CIG.
  • [C-7-5] MUST enable BAP unicast client, CSIP set coordinator, MCP server, VCP controller, CCP server simultaneously.
  • [C-SR-1] Are STRONGLY RECOMMENDED to enable HAP unicast client.

If device implementations return true for the BluetoothAdapter.isLeAudioBroadcastSourceSupported() API, then they:

  • [C-8-1] MUST support at least 2 BIS links in a BIG.
  • [C-8-2] MUST enable BAP broadcast source, BAP broadcast assistant simultaneously.
  • [C-8-3] MUST support LE Periodic advertising.

If device implementations return true for the BluetoothAdapter.isLeAudioBroadcastAssistantSupported() API, then they:

  • [C-9-1] MUST support PAST (Periodic Advertising Sync Transfer).
  • [C-9-2] MUST support LE Periodic advertising.

If device implementations declare FEATURE_BLUETOOTH_LE , they:

  • [C-10-1] MUST have RSSI measurements be within +/-9dB for 95% of the measurements at 1m distance from a reference device transmitting at ADVERTISE_TX_POWER_HIGH in line of sight environment.
  • [C-10-2] MUST include Rx/Tx corrections to reduce per-channel deviations so that the measurements on each of the 3 channels, on each of the antennas (if multiple are used), are within +/-3dB of one another for 95% of the measurements.
  • [C-SR-2] Are STRONGLY RECOMMENDED to measure and compensate for Rx offset to ensure the median BLE RSSI is -60dBm +/-10 dB at 1m distance from a reference device transmitting at ADVERTISE_TX_POWER_HIGH , where devices are oriented such that they are on 'parallel planes' with screens facing the same direction.
  • [C-SR-3] Are STRONGLY RECOMMENDED to measure and compensate for Tx offset to ensure the median BLE RSSI is -60dBm +/-10 dB when scanning from a reference device positioned at 1m distance and transmitting at ADVERTISE_TX_POWER_HIGH , where devices are oriented such that they are on 'parallel planes' with screens facing the same direction.

It is STRONGLY RECOMMENDED to follow the measurement setup steps specified in Presence Calibration Requirements .

7.4.4. Near-Field Communications

Device implementations:

  • SHOULD include a transceiver and related hardware for Near-Field Communications (NFC).
  • [C-0-1] MUST implement android.nfc.NdefMessage and android.nfc.NdefRecord APIs even if they do not include support for NFC or declare the android.hardware.nfc feature as the classes represent a protocol-independent data representation format .

If device implementations include NFC hardware and plan to make it available to third-party apps, they:

  • [C-1-1] MUST report the android.hardware.nfc feature from the android.content.pm.PackageManager.hasSystemFeature() method .
  • MUST be capable of reading and writing NDEF messages via the following NFC standards as below:
  • [C-1-2] MUST be capable of acting as an NFC Forum reader/writer (as defined by the NFC Forum technical specification NFCForum-TS-DigitalProtocol-1.0) via the following NFC standards:
    • NfcA (ISO14443-3A)
    • NfcB (ISO14443-3B)
    • NfcF (JIS X 6319-4)
    • IsoDep (ISO 14443-4)
    • NFC Forum Tag Types 1, 2, 3, 4, 5 (defined by the NFC Forum)
  • [C-SR-1] STRONGLY RECOMMENDED to be capable of reading and writing NDEF messages as well as raw data via the following NFC standards. Note that while the NFC standards are stated as STRONGLY RECOMMENDED, the Compatibility Definition for a future version is planned to change these to MUST. These standards are optional in this version but will be required in future versions. Existing and new devices that run this version of Android are very strongly encouraged to meet these requirements now so they will be able to upgrade to the future platform releases.

  • [C-1-13] MUST poll for all supported technologies while in NFC discovery mode.

  • SHOULD be in NFC discovery mode while the device is awake with the screen active and the lock-screen unlocked.

  • SHOULD be capable of reading the barcode and URL (if encoded) of Thinfilm NFC Barcode products.

Note that publicly available links are not available for the JIS, ISO, and NFC Forum specifications cited above.

Android includes support for NFC Host Card Emulation (HCE) mode.

If device implementations include an NFC controller chipset capable of HCE (for NfcA and/or NfcB) and support Application ID (AID) routing, they:

  • [C-2-1] MUST report the android.hardware.nfc.hce feature constant.
  • [C-2-2] MUST support NFC HCE APIs as defined in the Android SDK.

If device implementations include an NFC controller chipset capable of HCE for NfcF, and implement the feature for third-party applications, they:

  • [C-3-1] MUST report the android.hardware.nfc.hcef feature constant.
  • [C-3-2] MUST implement the NfcF Card Emulation APIs as defined in the Android SDK.

If device implementations include general NFC support as described in this section and support MIFARE technologies (MIFARE Classic, MIFARE Ultralight, NDEF on MIFARE Classic) in the reader/writer role, they:

  • [C-4-1] MUST implement the corresponding Android APIs as documented by the Android SDK.
  • [C-4-2] MUST report the feature com.nxp.mifare from the android.content.pm.PackageManager.hasSystemFeature () method. Note that this is not a standard Android feature and as such does not appear as a constant in the android.content.pm.PackageManager class.

7.4.5. Networking protocols and APIs

7.4.5.1. Minimum Network Capability

Device implementations:

  • [C-0-1] MUST include support for one or more forms of data networking. Specifically, device implementations MUST include support for at least one data standard capable of 200 Kbit/sec or greater. Examples of technologies that satisfy this requirement include EDGE, HSPA, EV-DO, 802.11g, Ethernet and Bluetooth PAN.
  • SHOULD also include support for at least one common wireless data standard, such as 802.11 (Wi-Fi), when a physical networking standard (such as Ethernet) is the primary data connection.
  • MAY implement more than one form of data connectivity.
7.4.5.2. IPv6

Device implementations:

  • [C-0-2] MUST include an IPv6 networking stack and support IPv6 communication using the managed APIs, such as java.net.Socket and java.net.URLConnection , as well as the native APIs, such as AF_INET6 sockets.
  • [C-0-3] MUST enable IPv6 by default.
    • MUST ensure that IPv6 communication is as reliable as IPv4, for example:
      • [C-0-4] MUST maintain IPv6 connectivity in doze mode.
      • [C-0-5] Rate-limiting MUST NOT cause the device to lose IPv6 connectivity on any IPv6-compliant network that uses RA lifetimes of at least 180 seconds.
  • [C-0-6] MUST provide third-party applications with direct IPv6 connectivity to the network when connected to an IPv6 network, without any form of address or port translation happening locally on the device. Both managed APIs such as Socket#getLocalAddress or Socket#getLocalPort ) and NDK APIs such as getsockname() or IPV6_PKTINFO MUST return the IP address and port that is actually used to send and receive packets on the network and is visible as the source ip and port to internet (web) servers.

The required level of IPv6 support depends on the network type, as shown in the following requirements.

If device implementations support Wi-Fi, they:

  • [C-1-1] MUST support dual-stack and IPv6-only operation on Wi-Fi.

If device implementations support Ethernet, they:

  • [C-2-1] MUST support dual-stack and IPv6-only operation on Ethernet.

If device implementations support Cellular data, they:

  • [C-3-1] MUST support IPv6 operation (IPv6-only and possibly dual-stack) on cellular.

If device implementations support more than one network type (eg, Wi-Fi and cellular data), they:

  • [C-4-1] MUST simultaneously meet the above requirements on each network when the device is simultaneously connected to more than one network type.
7.4.5.3. Portales cautivos

A captive portal refers to a network that requires sign-in in order to obtain internet access.

If device implementations provide a complete implementation of the android.webkit.Webview API , they:

  • [C-1-1] MUST provide a captive portal application to handle the intent ACTION_CAPTIVE_PORTAL_SIGN_IN and display the captive portal login page, by sending that intent, on call to the System API ConnectivityManager#startCaptivePortalApp(Network, Bundle) .
  • [C-1-2] MUST perform detection of captive portals and support login through the captive portal application when the device is connected to any network type, including cellular/mobile network, WiFi, Ethernet or Bluetooth.
  • [C-1-3] MUST support logging in to captive portals using cleartext DNS when the device is configured to use private DNS strict mode.
  • [C-1-4] MUST use encrypted DNS as per the SDK documentation for android.net.LinkProperties.getPrivateDnsServerName and android.net.LinkProperties.isPrivateDnsActive for all network traffic that is not explicitly communicating with the captive portal.
  • [C-1-5] MUST ensure that, while the user is logging in to a captive portal, the default network used by applications (as returned by ConnectivityManager.getActiveNetwork , ConnectivityManager.registerDefaultNetworkCallback , and used by default by Java networking APIs such as java.net.Socket, and native APIs such as connect()) is any other available network that provides internet access, if available.

7.4.6. Configuración de sincronización

Device implementations:

7.4.7. Ahorro de datos

If device implementations include a metered connection, they are:

  • [C-SR-1] STRONGLY RECOMMENDED to provide the data saver mode.

If device implementations provide the data saver mode, they:

  • [C-1-1] MUST support all the APIs in the ConnectivityManager class as described in the SDK documentation

If device implementations do not provide the data saver mode, they:

7.4.8. Secure Elements

If device implementations support Open Mobile API -capable secure elements and make them available to third-party apps, they:

7.4.9. UWB

If device implementations include support for 802.1.15.4 and expose the functionality to a third-party application, then they:

  • [C-1-1] MUST implement the corresponding Android API in android.uwb.
  • [C-1-2] MUST report the hardware feature flag android.hardware.uwb.
  • [C-1-3] MUST support all the relevant UWB profiles defined in Android implementation.
  • [C-1-4] MUST provide a user affordance to allow the user to toggle the UWB radio on/off state.
  • [C-1-5] MUST enforce that apps using UWB radio hold UWB_RANGING permission (under NEARBY_DEVICES permission group).
  • [C-SR-1] Are STRONGLY RECOMMENDED to pass the relevant conformance and certification tests defined by standard organizations, including FIRA , CCC and CSA .
  • [C-1-6] MUST ensure the distance measurements are within +/-15 cm for 95% of the measurements in the line of sight environment at 1m distance in a non-reflective chamber.
  • [C-1-7] MUST ensure that the median of the distance measurements at 1m from the reference device is within [0.75m, 1.25m], where ground truth distance is measured from the top edge of the DUT.
  • [C-SR-2] Are STRONGLY RECOMMENDED to follow the measurement setup steps specified in Presence Calibration Requirements .

7.5. Cámaras

If device implementations include at least one camera, they:

  • [C-1-1] MUST declare the android.hardware.camera.any feature flag.
  • [C-1-2] MUST be possible for an application to simultaneously allocate 3 RGBA_8888 bitmaps equal to the size of the images produced by the largest-resolution camera sensor on the device, while camera is open for the purpose of basic preview and still captura.
  • [C-1-3] MUST ensure that the preinstalled default camera application handling intents MediaStore.ACTION_IMAGE_CAPTURE , MediaStore.ACTION_IMAGE_CAPTURE_SECURE , or MediaStore.ACTION_VIDEO_CAPTURE , is responsible for removing the user location in the image metadata before sending it to the receiving application when the receiving application does not have ACCESS_FINE_LOCATION .

If device implementations support HDR 10-bit output capability, then they:

  • [C-2-1] MUST support at least the HLG HDR profile for every camera device that supports 10-bit output.
  • [C-2-2] MUST support 10-bit output for either the primary rear-facing or the primary front-facing camera.
  • [C-SR-1] Are STRONGLY RECOMMENDED to support 10-bit output for both primary cameras.
  • [C-2-3] MUST support the same HDR profiles for all BACKWARD_COMPATIBLE-capable physical sub-cameras of a logical camera, and the logical camera itself.

For Logical camera devices which support 10-bit HDR that implement the android.hardware.camera2.CaptureRequest#CONTROL_ZOOM_RATIO API, they:

  • [C-3-1] MUST support switching between all the backwards-compatible physical cameras via the CONTROL_ZOOM_RATIO control on the logical camera.

7.5.1. Rear-Facing Camera

A rear-facing camera is a world-facing camera that images scenes on the far side of the device, like a traditional camera; on handheld devices, that is a camera located on the side of the device opposite the display.

Device implementations:

  • SHOULD include a rear-facing camera.

If device implementations include at least one rear-facing camera, they:

  • [C-1-1] MUST report the feature flag android.hardware.camera and android.hardware.camera.any .
  • [C-1-2] MUST have a resolution of at least 2 megapixels.
  • SHOULD have either hardware auto-focus or software auto-focus implemented in the camera driver (transparent to application software).
  • MAY have fixed-focus or EDOF (extended depth of field) hardware.
  • MAY include a flash.

If the camera includes a flash:

  • [C-2-1] the flash lamp MUST NOT be lit while an android.hardware.Camera.PreviewCallback instance has been registered on a Camera preview surface, unless the application has explicitly enabled the flash by enabling the FLASH_MODE_AUTO or FLASH_MODE_ON attributes of a Camera.Parameters object. Note that this constraint does not apply to the device's built-in system camera application, but only to third-party applications using Camera.PreviewCallback .

7.5.2. Cámara frontal

A front-facing camera is a user-facing camera that is typically used to image the user, such as for video conferencing and similar applications; on handheld devices, that is a camera located on the same side of the device as the display.

Device implementations:

  • MAY include a front-facing camera.

If device implementations include at least one front-facing camera, they:

  • [C-1-1] MUST report the feature flag android.hardware.camera.any and android.hardware.camera.front .
  • [C-1-2] MUST have a resolution of at least VGA (640x480 pixels).
  • [C-1-3] MUST NOT use a front-facing camera as the default for the Camera API and MUST NOT configure the API to treat a front-facing camera as the default rear-facing camera, even if it is the only camera en el dispositivo.
  • [C-1-4] The camera preview MUST be mirrored horizontally relative to the orientation specified by the application when the current application has explicitly requested that the Camera display be rotated via a call to the android.hardware.Camera.setDisplayOrientation() method . Conversely, the preview MUST be mirrored along the device's default horizontal axis when the current application does not explicitly request that the Camera display be rotated via a call to the android.hardware.Camera.setDisplayOrientation() method.
  • [C-1-5] MUST NOT mirror the final captured still image or video streams returned to application callbacks or committed to media storage.
  • [C-1-6] MUST mirror the image displayed by the postview in the same manner as the camera preview image stream.
  • MAY include features (such as auto-focus, flash, etc.) available to rear-facing cameras as described in section 7.5.1 .

If device implementations are capable of being rotated by user (such as automatically via an accelerometer or manually via user input):

  • [C-2-1] The camera preview MUST be mirrored horizontally relative to the device's current orientation.

7.5.3. Cámara externa

An external camera is a camera that can be physically attached or detached from the device implementation at any time and can face any direction; such as USB cameras.

Device implementations:

  • MAY include support for an external camera that is not necessarily always connected.

If device implementations include support for an external camera, they:

  • [C-1-1] MUST declare the platform feature flag android.hardware.camera.external and android.hardware camera.any .
  • [C-1-2] MUST support USB Video Class (UVC 1.0 or higher) if the external camera connects through the USB host port.
  • [C-1-3] MUST pass camera CTS tests with a physical external camera device connected. Details of camera CTS testing are available at source.android.com .
  • SHOULD support video compressions such as MJPEG to enable transfer of high-quality unencoded streams (ie raw or independently compressed picture streams).
  • MAY support multiple cameras.
  • MAY support camera-based video encoding.

If camera-based video encoding is supported:

  • [C-2-1] A simultaneous unencoded / MJPEG stream (QVGA or greater resolution) MUST be accessible to the device implementation.

7.5.4. Camera API Behavior

Android includes two API packages to access the camera, the newer android.hardware.camera2 API expose lower-level camera control to the app, including efficient zero-copy burst/streaming flows and per-frame controls of exposure, gain, white balance gains, color conversion, denoising, sharpening, and more.

The older API package, android.hardware.Camera , is marked as deprecated in Android 5.0 but as it should still be available for apps to use. Android device implementations MUST ensure the continued support of the API as described in this section and in the Android SDK.

All features that are common between the deprecated android.hardware.Camera class and the newer android.hardware.camera2 package MUST have equivalent performance and quality in both APIs. For example, with equivalent settings, autofocus speed and accuracy must be identical, and the quality of captured images must be the same. Features that depend on the different semantics of the two APIs are not required to have matching speed or quality, but SHOULD match as closely as possible.

Device implementations MUST implement the following behaviors for the camera-related APIs, for all available cameras. Device implementations:

  • [C-0-1] MUST use android.hardware.PixelFormat.YCbCr_420_SP for preview data provided to application callbacks when an application has never called android.hardware.Camera.Parameters.setPreviewFormat(int) .
  • [C-0-2] MUST further be in the NV21 encoding format when an application registers an android.hardware.Camera.PreviewCallback instance and the system calls the onPreviewFrame() method and the preview format is YCbCr_420_SP, the data in the byte[] passed into onPreviewFrame() . That is, NV21 MUST be the default.
  • [C-0-3] MUST support the YV12 format (as denoted by the android.graphics.ImageFormat.YV12 constant) for camera previews for both front- and rear-facing cameras for android.hardware.Camera . (The hardware video encoder and camera may use any native pixel format, but the device implementation MUST support conversion to YV12.)
  • [C-0-4] MUST support the android.hardware.ImageFormat.YUV_420_888 and android.hardware.ImageFormat.JPEG formats as outputs through the android.media.ImageReader API for android.hardware.camera2 devices that advertise REQUEST_AVAILABLE_CAPABILITIES_BACKWARD_COMPATIBLE capability in android.request.availableCapabilities .
  • [C-0-5] MUST still implement the full Camera API included in the Android SDK documentation, regardless of whether the device includes hardware autofocus or other capabilities. For instance, cameras that lack autofocus MUST still call any registered android.hardware.Camera.AutoFocusCallback instances (even though this has no relevance to a non-autofocus camera.) Note that this does apply to front-facing cameras; for instance, even though most front-facing cameras do not support autofocus, the API callbacks must still be "faked" as described.
  • [C-0-6] MUST recognize and honor each parameter name defined as a constant in the android.hardware.Camera.Parameters class and the android.hardware.camera2.CaptureRequest class. Conversely, device implementations MUST NOT honor or recognize string constants passed to the android.hardware.Camera.setParameters() method other than those documented as constants on the android.hardware.Camera.Parameters . That is, device implementations MUST support all standard Camera parameters if the hardware allows, and MUST NOT support custom Camera parameter types. For instance, device implementations that support image capture using high dynamic range (HDR) imaging techniques MUST support camera parameter Camera.SCENE_MODE_HDR .
  • [C-0-7] MUST report the proper level of support with the android.info.supportedHardwareLevel property as described in the Android SDK and report the appropriate framework feature flags .
  • [C-0-8] MUST also declare its individual camera capabilities of android.hardware.camera2 via the android.request.availableCapabilities property and declare the appropriate feature flags ; MUST define the feature flag if any of its attached camera devices supports the feature.
  • [C-0-9] MUST broadcast the Camera.ACTION_NEW_PICTURE intent whenever a new picture is taken by the camera and the entry of the picture has been added to the media store.
  • [C-0-10] MUST broadcast the Camera.ACTION_NEW_VIDEO intent whenever a new video is recorded by the camera and the entry of the picture has been added to the media store.
  • [C-0-11] MUST have all cameras accessible via the deprecated android.hardware.Camera API also accessible via the android.hardware.camera2 API.
  • [C-0-12] MUST ensure that the facial appearance is NOT altered, including but not limited to altering facial geometry, facial skin tone, or facial skin smoothening for any android.hardware.camera2 or android.hardware.Camera API.
  • [C-SR-1] For devices with multiple RGB cameras in close proximity and facing in the same direction, it is STRONGLY RECOMMENDED to support a logical camera device that lists capability CameraMetadata.REQUEST_AVAILABLE_CAPABILITIES_LOGICAL_MULTI_CAMERA , consisting of all of the RGB cameras facing that direction as physical sub-devices.

If device implementations provide a proprietary camera API to 3rd-party apps, they:

7.5.5. Camera Orientation

If device implementations have a front- or a rear-facing camera, such camera(s):

  • [C-1-1] MUST be oriented so that the long dimension of the camera aligns with the screen's long dimension. That is, when the device is held in the landscape orientation, cameras MUST capture images in the landscape orientation. This applies regardless of the device's natural orientation; that is, it applies to landscape-primary devices as well as portrait-primary devices.

Devices that fulfill all of the following criteria are exempt from the requirement above:

  • The device implements variable-geometry screens, such as foldable or hinged displays.
  • When the device's fold or hinge state changes, the device switches between portrait-primary to landscape-primary (or vice-versa) orientations.
  • Device implementations that are not capable of being rotated by the user such as automotive devices.

7.6. Memoria y almacenamiento

7.6.1. Minimum Memory and Storage

Device implementations:

  • [C-0-1] MUST include a Download Manager that applications MAY use to download data files and they MUST be capable of downloading individual files of at least 100MB in size to the default "cache" location.

7.6.2. Application Shared Storage

Device implementations:

  • [C-0-1] MUST offer storage to be shared by applications, also often referred as "shared external storage", "application shared storage" or by the Linux path "/sdcard" it is mounted on.
  • [C-0-2] MUST be configured with shared storage mounted by default, in other words "out of the box", regardless of whether the storage is implemented on an internal storage component or a removable storage medium (eg Secure Digital card slot ).
  • [C-0-3] MUST mount the application shared storage directly on the Linux path sdcard or include a Linux symbolic link from sdcard to the actual mount point.
  • [C-0-4] MUST enable scoped storage by default for all apps targeting API level 29 or above, except in the following situation:
    • When the app has requested android:requestLegacyExternalStorage="true" in their manifest.
  • [C-0-5] MUST redact location metadata, such as GPS Exif tags, stored in media files when those files are accessed through MediaStore , except when the calling app holds the ACCESS_MEDIA_LOCATION permission.

Device implementations MAY meet the above requirements using either of the following:

  • User-accessible removable storage, such as a Secure Digital (SD) card slot.
  • A portion of the internal (non-removable) storage as implemented in the Android Open Source Project (AOSP).

If device implementations use removable storage to satisfy the above requirements, they:

  • [C-1-1] MUST implement a toast or pop-up user interface warning the user when there is no storage medium inserted in the slot.
  • [C-1-2] MUST include a FAT-formatted storage medium (eg SD card) or show on the box and other material available at time of purchase that the storage medium has to be purchased separately.

If device implementations use a portion of the non-removable storage to satisfy the above requirements, they:

  • SHOULD use the AOSP implementation of the internal application shared storage.
  • MAY share the storage space with the application private data.

If device implementations have a USB port with USB peripheral mode support, they:

  • [C-3-1] MUST provide a mechanism to access the data on the application shared storage from a host computer.
  • SHOULD expose content from both storage paths transparently through Android's media scanner service and android.provider.MediaStore .
  • MAY use USB mass storage, but SHOULD use Media Transfer Protocol to satisfy this requirement.

If device implementations have a USB port with USB peripheral mode and support Media Transfer Protocol, they:

  • SHOULD be compatible with the reference Android MTP host, Android File Transfer .
  • SHOULD report a USB device class of 0x00.
  • SHOULD report a USB interface name of 'MTP'.

7.6.3. Almacenamiento adoptable

If the device is expected to be mobile in nature unlike Television, device implementations are:

  • [C-SR-1] STRONGLY RECOMMENDED to implement the adoptable storage in a long-term stable location, since accidentally disconnecting them can cause data loss/corruption.

If the removable storage device port is in a long-term stable location, such as within the battery compartment or other protective cover, device implementations are:

7.7. USB

If device implementations have a USB port, they:

  • SHOULD support USB peripheral mode and SHOULD support USB host mode.
  • SHOULD support disabling data signaling over USB.

7.7.1. USB peripheral mode

If device implementations include a USB port supporting peripheral mode:

  • [C-1-1] The port MUST be connectable to a USB host that has a standard type-A or type-C USB port.
  • [C-1-2] MUST report the correct value of iSerialNumber in USB standard device descriptor through android.os.Build.SERIAL .
  • [C-1-3] MUST detect 1.5A and 3.0A chargers per the Type-C resistor standard and MUST detect changes in the advertisement if they support Type-C USB.
  • [C-SR-1] The port SHOULD use micro-B, micro-AB or Type-C USB form factor. Existing and new Android devices are STRONGLY RECOMMENDED to meet these requirements so they will be able to upgrade to the future platform releases.
  • [C-SR-2] The port SHOULD be located on the bottom of the device (according to natural orientation) or enable software screen rotation for all apps (including home screen), so that the display draws correctly when the device is oriented with the port at bottom. Existing and new Android devices are STRONGLY RECOMMENDED to meet these requirements so they will be able to upgrade to future platform releases.
  • [C-SR-3] SHOULD implement support to draw 1.5 A current during HS chirp and traffic as specified in the USB Battery Charging specification, revision 1.2 . Existing and new Android devices are STRONGLY RECOMMENDED to meet these requirements so they will be able to upgrade to the future platform releases.
  • [C-SR-4] STRONGLY RECOMMENDED to not support proprietary charging methods that modify Vbus voltage beyond default levels, or alter sink/source roles as such may result in interoperability issues with the chargers or devices that support the standard USB Power Delivery methods. While this is called out as "STRONGLY RECOMMENDED", in future Android versions we might REQUIRE all type-C devices to support full interoperability with standard type-C chargers.
  • [C-SR-5] STRONGLY RECOMMENDED to support Power Delivery for data and power role swapping when they support Type-C USB and USB host mode.
  • SHOULD support Power Delivery for high-voltage charging and support for Alternate Modes such as display out.
  • SHOULD implement the Android Open Accessory (AOA) API and specification as documented in the Android SDK documentation.

If device implementations include a USB port and implement the AOA specification, they:

  • [C-2-1] MUST declare support for the hardware feature android.hardware.usb.accessory .
  • [C-2-2] The USB mass storage class MUST include the string "android" at the end of the interface description iInterface string of the USB mass storage
  • SHOULD NOT implement AOAv2 audio documented in the Android Open Accessory Protocol 2.0 documentation. AOAv2 audio is deprecated as of Android version 8.0 (API level 26).

7.7.2. USB host mode

If device implementations include a USB port supporting host mode, they:

  • [C-1-1] MUST implement the Android USB host API as documented in the Android SDK and MUST declare support for the hardware feature android.hardware.usb.host .
  • [C-1-2] MUST implement support to connect standard USB peripherals, in other words, they MUST either:
    • Have an on-device type C port or ship with cable(s) adapting an on-device proprietary port to a standard USB type-C port (USB Type-C device).
    • Have an on-device type A or ship with cable(s) adapting an on-device proprietary port to a standard USB type-A port.
    • Have an on-device micro-AB port, which SHOULD ship with a cable adapting to a standard type-A port.
  • [C-1-3] MUST NOT ship with an adapter converting from USB type A or micro-AB ports to a type-C port (receptacle).
  • [C-SR-1] Are STRONGLY RECOMMENDED to implement the USB audio class as documented in the Android SDK documentation.
  • SHOULD support charging the connected USB peripheral device while in host mode; advertising a source current of at least 1.5A as specified in the Termination Parameters section of the USB Type-C Cable and Connector Specification Revision 1.2 for USB Type-C connectors or using Charging Downstream Port(CDP) output current range as specified in the USB Battery Charging specifications, revision 1.2 for Micro-AB connectors.
  • SHOULD implement and support USB Type-C standards.

If device implementations include a USB port supporting host mode and the USB audio class, they:

  • [C-2-1] MUST support the USB HID class .
  • [C-2-2] MUST support the detection and mapping of the following HID data fields specified in the USB HID Usage Tables and the Voice Command Usage Request to the KeyEvent constants as below:
    • Usage Page (0xC) Usage ID (0x0CD): KEYCODE_MEDIA_PLAY_PAUSE
    • Usage Page (0xC) Usage ID (0x0E9): KEYCODE_VOLUME_UP
    • Usage Page (0xC) Usage ID (0x0EA): KEYCODE_VOLUME_DOWN
    • Usage Page (0xC) Usage ID (0x0CF): KEYCODE_VOICE_ASSIST

If device implementations include a USB port supporting host mode and the Storage Access Framework (SAF), they:

  • [C-3-1] MUST recognize any remotely connected MTP (Media Transfer Protocol) devices and make their contents accessible through the ACTION_GET_CONTENT , ACTION_OPEN_DOCUMENT , and ACTION_CREATE_DOCUMENT intents. .

If device implementations include a USB port supporting host mode and USB Type-C, they:

  • [C-4-1] MUST implement Dual Role Port functionality as defined by the USB Type-C specification (section 4.5.1.3.3). For Dual Role Ports, On devices that include a 3.5mm audio jack, the USB sink detection (host mode) MAY be off by default but it MUST be possible for the user to enable it.
  • [C-SR-2] STRONGLY RECOMMENDED to support DisplayPort, SHOULD support USB SuperSpeed Data Rates, and are STRONGLY RECOMMENDED to support Power Delivery for data and power role swapping.
  • [C-SR-3] STRONGLY RECOMMENDED to NOT support Audio Adapter Accessory Mode as described in the Appendix A of the USB Type-C Cable and Connector Specification Revision 1.2 .
  • SHOULD implement the Try.* model that is most appropriate for the device form factor. For example a handheld device SHOULD implement the Try.SNK model.

7.8. Audio

7.8.1. Micrófono

If device implementations include a microphone, they:

  • [C-1-1] MUST report the android.hardware.microphone feature constant.
  • [C-1-2] MUST meet the audio recording requirements in section 5.4 .
  • [C-1-3] MUST meet the audio latency requirements in section 5.6 .
  • [C-SR-1] Are STRONGLY RECOMMENDED to support near-ultrasound recording as described in section 7.8.3 .

If device implementations omit a microphone, they:

  • [C-2-1] MUST NOT report the android.hardware.microphone feature constant.
  • [C-2-2] MUST implement the audio recording API at least as no-ops, per section 7 .

7.8.2. Salida de audio

If device implementations include a speaker or an audio/multimedia output port for an audio output peripheral such as a 4 conductor 3.5mm audio jack or USB host mode port using USB audio class , they:

  • [C-1-1] MUST report the android.hardware.audio.output feature constant.
  • [C-1-2] MUST meet the audio playback requirements in section 5.5 .
  • [C-1-3] MUST meet the audio latency requirements in section 5.6 .
  • [C-SR-1] STRONGLY RECOMMENDED to support near-ultrasound playback as described in section 7.8.3 .

If device implementations do not include a speaker or audio output port, they:

  • [C-2-1] MUST NOT report the android.hardware.audio.output feature.
  • [C-2-2] MUST implement the Audio Output related APIs as no-ops at least.

For the purposes of this section, an "output port" is a physical interface such as a 3.5mm audio jack, HDMI, or USB host mode port with USB audio class. Support for audio output over radio-based protocols such as Bluetooth, WiFi, or cellular network does not qualify as including an "output port".

7.8.2.1. Analog Audio Ports

In order to be compatible with the headsets and other audio accessories using the 3.5mm audio plug across the Android ecosystem, if device implementations include one or more analog audio ports, they:

  • [C-SR-1] Are STRONGLY RECOMMENDED to include at least one of the audio port(s) to be a 4 conductor 3.5mm audio jack.

If device implementations have a 4 conductor 3.5mm audio jack, they:

  • [C-1-1] MUST support audio playback to stereo headphones and stereo headsets with a microphone.
  • [C-1-2] MUST support TRRS audio plugs with the CTIA pin-out order.
  • [C-1-3] MUST support the detection and mapping to the keycodes for the following 3 ranges of equivalent impedance between the microphone and ground conductors on the audio plug:
    • 70 ohm or less : KEYCODE_HEADSETHOOK
    • 210-290 ohm : KEYCODE_VOLUME_UP
    • 360-680 ohm : KEYCODE_VOLUME_DOWN
  • [C-1-4] MUST trigger ACTION_HEADSET_PLUG upon a plug insert, but only after all contacts on plug are touching their relevant segments on the jack.
  • [C-1-5] MUST be capable of driving at least 150mV ± 10% of output voltage on a 32 ohm speaker impedance.
  • [C-1-6] MUST have a microphone bias voltage between 1.8V ~ 2.9V.
  • [C-1-7] MUST detect and map to the keycode for the following range of equivalent impedance between the microphone and ground conductors on the audio plug:
    • 110-180 ohm: KEYCODE_VOICE_ASSIST
  • [C-SR-2] Are STRONGLY RECOMMENDED to support audio plugs with the OMTP pin-out order.
  • [C-SR-3] Are STRONGLY RECOMMENDED to support audio recording from stereo headsets with a microphone.

If device implementations have a 4 conductor 3.5mm audio jack and support a microphone, and broadcast the android.intent.action.HEADSET_PLUG with the extra value microphone set as 1, they:

  • [C-2-1] MUST support the detection of microphone on the plugged in audio accessory.
7.8.2.2. Digital Audio Ports

See Section 2.2.1 for device-specific requirements.

7.8.3. Near-Ultrasound

Near-Ultrasound audio is the 18.5 kHz to 20 kHz band.

Device implementations:

If PROPERTY_SUPPORT_MIC_NEAR_ULTRASOUND is "true", the following requirements MUST be met by the VOICE_RECOGNITION and UNPROCESSED audio sources:

  • [C-1-1] The microphone's mean power response in the 18.5 kHz to 20 kHz band MUST be no more than 15 dB below the response at 2 kHz.
  • [C-1-2] The microphone's unweighted signal to noise ratio over 18.5 kHz to 20 kHz for a 19 kHz tone at -26 dBFS MUST be no lower than 50 dB.

If PROPERTY_SUPPORT_SPEAKER_NEAR_ULTRASOUND is "true":

  • [C-2-1] The speaker's mean response in 18.5 kHz - 20 kHz MUST be no lower than 40 dB below the response at 2 kHz.

7.8.4. Integridad de la señal

Device implementations:

  • SHOULD provide a glitch-free audio signal path for both input and output streams on handheld devices, as defined by zero glitches measured during a test of one minute per path. Test using OboeTester "Automated Glitch Test".

The test requires an audio loopback dongle , used directly in a 3.5mm jack, and/or in combination with a USB-C to 3.5mm adapter. All audio output ports SHOULD be tested.

OboeTester currently supports AAudio paths, so the following combinations SHOULD be tested for glitches using AAudio:

Perf Mode Intercambio Out Sample Rate In Chans Out Chans
BAJA LATENCIA EXCLUSIVO NO ESPECIFICADO 1 2
BAJA LATENCIA EXCLUSIVO NO ESPECIFICADO 2 1
BAJA LATENCIA COMPARTIDO NO ESPECIFICADO 1 2
BAJA LATENCIA COMPARTIDO NO ESPECIFICADO 2 1
NINGUNO COMPARTIDO 48000 1 2
NINGUNO COMPARTIDO 48000 2 1
NINGUNO COMPARTIDO 44100 1 2
NINGUNO COMPARTIDO 44100 2 1
NINGUNO COMPARTIDO 16000 1 2
NINGUNO COMPARTIDO 16000 2 1

A reliable stream SHOULD meet the following criteria for Signal to Noise Ratio (SNR) and Total Harmonic Distortion (THD) for 2000 Hz sine.

transductor THD SNR
primary built-in speaker, measured using an external reference microphone < 3.0% >= 50 dB
primary built-in microphone, measured using an external reference speaker < 3.0% >= 50 dB
built-in analog 3.5 mm jacks, tested using loopback adapter < 1% >= 60 dB
USB adapters supplied with the phone, tested using loopback adapter < 1,0% >= 60 dB

7.9. Realidad virtual

Android includes APIs and facilities to build "Virtual Reality" (VR) applications including high quality mobile VR experiences. Device implementations MUST properly implement these APIs and behaviors, as detailed in this section.

7.9.1. Virtual Reality Mode

Android includes support for VR Mode , a feature which handles stereoscopic rendering of notifications and disables monocular system UI components while a VR application has user focus.

7.9.2. Virtual Reality Mode - High Performance

If device implementations support VR mode, they:

  • [C-1-1] MUST have at least 2 physical cores.
  • [C-1-2] MUST declare the android.hardware.vr.high_performance feature.
  • [C-1-3] MUST support sustained performance mode.
  • [C-1-4] MUST support OpenGL ES 3.2.
  • [C-1-5] MUST support android.hardware.vulkan.level 0.
  • SHOULD support android.hardware.vulkan.level 1 or higher.
  • [C-1-6] MUST implement EGL_KHR_mutable_render_buffer , EGL_ANDROID_front_buffer_auto_refresh , EGL_ANDROID_get_native_client_buffer , EGL_KHR_fence_sync , EGL_KHR_wait_sync , EGL_IMG_context_priority , EGL_EXT_protected_content , EGL_EXT_image_gl_colorspace , and expose the extensions in the list of available EGL extensions.
  • [C-1-8] MUST implement GL_EXT_multisampled_render_to_texture2 , GL_OVR_multiview , GL_OVR_multiview2 , GL_EXT_protected_textures , and expose the extensions in the list of available GL extensions.
  • [C-SR-1] Are STRONGLY RECOMMENDED to implement GL_EXT_external_buffer , GL_EXT_EGL_image_array , GL_OVR_multiview_multisampled_render_to_texture , and expose the extensions in the list of available GL extensions.
  • [C-SR-2] Are STRONGLY RECOMMENDED to support Vulkan 1.1.
  • [C-SR-3] Are STRONGLY RECOMMENDED to implement VK_ANDROID_external_memory_android_hardware_buffer , VK_GOOGLE_display_timing , VK_KHR_shared_presentable_image , and expose it in the list of available Vulkan extensions.
  • [C-SR-4] Are STRONGLY RECOMMENDED to expose at least one Vulkan queue family where flags contain both VK_QUEUE_GRAPHICS_BIT and VK_QUEUE_COMPUTE_BIT , and queueCount is at least 2.
  • [C-1-7] The GPU and display MUST be able to synchronize access to the shared front buffer such that alternating-eye rendering of VR content at 60fps with two render contexts will be displayed with no visible tearing artifacts.
  • [C-1-9] MUST implement support for AHardwareBuffer flags AHARDWAREBUFFER_USAGE_GPU_DATA_BUFFER , AHARDWAREBUFFER_USAGE_SENSOR_DIRECT_DATA and AHARDWAREBUFFER_USAGE_PROTECTED_CONTENT as described in the NDK.
  • [C-1-10] MUST implement support for AHardwareBuffer s with any combination of the usage flags AHARDWAREBUFFER_USAGE_GPU_COLOR_OUTPUT , AHARDWAREBUFFER_USAGE_GPU_SAMPLED_IMAGE , AHARDWAREBUFFER_USAGE_PROTECTED_CONTENT for at least the following formats: AHARDWAREBUFFER_FORMAT_R5G6B5_UNORM , AHARDWAREBUFFER_FORMAT_R8G8B8A8_UNORM , AHARDWAREBUFFER_FORMAT_R10G10B10A2_UNORM , AHARDWAREBUFFER_FORMAT_R16G16B16A16_FLOAT .
  • [C-SR-5] Are STRONGLY RECOMMENDED to support the allocation of AHardwareBuffer s with more than one layer and flags and formats specified in C-1-10.
  • [C-1-11] MUST support H.264 decoding at least 3840 x 2160 at 30fps, compressed to an average of 40Mbps (equivalent to 4 instances of 1920 x1080 at 30 fps-10 Mbps or 2 instances of 1920 x 1080 at 60 fps-20 Mbps).
  • [C-1-12] MUST support HEVC and VP9, MUST be capable of decoding at least 1920 x 1080 at 30 fps compressed to an average of 10 Mbps and SHOULD be capable of decoding 3840 x 2160 at 30 fps-20 Mbps (equivalent to 4 instances of 1920 x 1080 at 30 fps-5 Mbps).
  • [C-1-13] MUST support HardwarePropertiesManager.getDeviceTemperatures API and return accurate values for skin temperature.
  • [C-1-14] MUST have an embedded screen, and its resolution MUST be at least 1920 x 1080.
  • [C-SR-6] Are STRONGLY RECOMMENDED to have a display resolution of at least 2560 x 1440.
  • [C-1-15] The display MUST update at least 60 Hz while in VR Mode.
  • [C-1-17] The display MUST support a low-persistence mode with ≤ 5 milliseconds persistence, persistence being defined as the amount of time for which a pixel is emitting light.
  • [C-1-18] MUST support Bluetooth 4.2 and Bluetooth LE Data Length Extension section 7.4.3 .
  • [C-1-19] MUST support and properly report Direct Channel Type for all of the following default sensor types:
    • TYPE_ACCELEROMETER
    • TYPE_ACCELEROMETER_UNCALIBRATED
    • TYPE_GYROSCOPE
    • TYPE_GYROSCOPE_UNCALIBRATED
    • TYPE_MAGNETIC_FIELD
    • TYPE_MAGNETIC_FIELD_UNCALIBRATED
  • [C-SR-7] Are STRONGLY RECOMMENDED to support the TYPE_HARDWARE_BUFFER direct channel type for all Direct Channel Types listed above.
  • [C-1-21] MUST meet the gyroscope, accelerometer, and magnetometer related requirements for android.hardware.hifi_sensors , as specified in section 7.3.9 .
  • [C-SR-8] Are STRONGLY RECOMMENDED to support the android.hardware.sensor.hifi_sensors feature.
  • [C-1-22] MUST have end-to-end motion to photon latency not higher than 28 milliseconds.
  • [C-SR-9] Are STRONGLY RECOMMENDED to have end-to-end motion to photon latency not higher than 20 milliseconds.
  • [C-1-23] MUST have first-frame ratio, which is the ratio between the brightness of pixels on the first frame after a transition from black to white and the brightness of white pixels in steady state, of at least 85%.
  • [C-SR-10] Are STRONGLY RECOMMENDED to have first-frame ratio of at least 90%.
  • MAY provide an exclusive core to the foreground application and MAY support the Process.getExclusiveCores API to return the numbers of the cpu cores that are exclusive to the top foreground application.

If exclusive core is supported, then the core:

  • [C-2-1] MUST not allow any other userspace processes to run on it (except device drivers used by the application), but MAY allow some kernel processes to run as necessary.

7.10. hápticos

Devices intended to be hand-held or worn may include a general purpose haptic actuator, available to applications for purposes including getting attention through ringtones, alarms, notifications, as well as general touch feedback.

If device implementations DO NOT include such a general purpose haptic actuator, they:

  • [7.10/C] MUST return false for Vibrator.hasVibrator() .

If device implementations DO include at least one such general purpose haptic actuator, they:

If device implementations follow the haptic constants mapping, they:

7.11. Media Performance Class

The media performance class of the device implementation can be obtained from the android.os.Build.VERSION_CODES.MEDIA_PERFORMANCE_CLASS API. Requirements for media performance class are defined for each Android version starting with R (version 30). The special value of 0 designates that the device is not of a media performance class.

If device implementations return non-zero value for android.os.Build.VERSION_CODES.MEDIA_PERFORMANCE_CLASS , they:

  • [C-1-1] MUST return at least a value of android.os.Build.VERSION_CODES.R .

  • [C-1-2] MUST be a handheld device implementation.

  • [C-1-3] MUST meet all requirements for "Media Performance Class" described in section 2.2.7 .

In other words, media performance class in Android T is only defined for handheld devices at version T, S or R.

See section 2.2.7 for device-specific requirements.

8. Performance and Power

Some minimum performance and power criteria are critical to the user experience and impact the baseline assumptions developers would have when developing an app.

8.1. User Experience Consistency

A smooth user interface can be provided to the end user if there are certain minimum requirements to ensure a consistent frame rate and response times for applications and games. Device implementations, depending on the device type, MAY have measurable requirements for the user interface latency and task switching as described in section 2 .

8.2. File I/O Access Performance

Providing a common baseline for a consistent file access performance on the application private data storage ( /data partition) allows app developers to set a proper expectation that would help their software design. Device implementations, depending on the device type, MAY have certain requirements described in section 2 for the following read and write operations:

  • Sequential write performance . Measured by writing a 256MB file using 10MB write buffer.
  • Random write performance . Measured by writing a 256MB file using 4KB write buffer.
  • Sequential read performance . Measured by reading a 256MB file using 10MB write buffer.
  • Random read performance . Measured by reading a 256MB file using 4KB write buffer.

8.3. Power-Saving Modes

If device implementations include features to improve device power management that are included in AOSP (eg App Standby Bucket, Doze) or extend the features to apply stronger restrictions than the RESTRICTED App Standby Bucket , they:

  • [C-1-1] MUST NOT deviate from the AOSP implementation for the triggering, maintenance, wakeup algorithms and the use of global system settings or DeviceConfig of App Standby and Doze power-saving modes.
  • [C-1-2] MUST NOT deviate from the AOSP implementation for the use of global settings or DeviceConfig to manage the throttling of jobs, alarm and network for apps in each bucket for App standby.
  • [C-1-3] MUST NOT deviate from the AOSP implementation for the number of the App Standby Buckets used for App Standby.
  • [C-1-4] MUST implement App Standby Buckets and Doze as described in Power Management .
  • [C-1-5] MUST return true for PowerManager.isPowerSaveMode() when the device is on power save mode.
  • [C-1-6] MUST provide user affordance to display all apps that are exempted from App Standby and Doze power-saving modes or any battery optimizations and MUST implement the ACTION_REQUEST_IGNORE_BATTERY_OPTIMIZATIONS intent to ask the user to allow an app to ignore battery optimizations.
  • [C-SR-1] Are STRONGLY RECOMMENDED to provide user affordance to enable and disable the battery saver feature.
  • [C-SR-2] Are STRONGLY RECOMMENDED to provide user affordance to display all apps that are exempted from App Standby and Doze power-saving modes.

If device implementations extend power management features that are included in AOSP and that extension applies more stringent restrictions than the Rare App Standby Bucket , refer to section 3.5.1 .

In addition to the power-saving modes, Android device implementations MAY implement any or all of the 4 sleeping power states as defined by the Advanced Configuration and Power Interface (ACPI).

If device implementations implement S4 power states as defined by the ACPI, they:

  • [C-1-1] MUST enter this state only after the user has taken an explicit action to put the device in an inactive state (eg by closing a lid that is physically part of the device or turning off a vehicle or television) and before the user re-activates the device (eg by opening the lid or turning the vehicle or television back on).

If device implementations implement S3 power states as defined by the ACPI, they:

  • [C-2-1] MUST meet C-1-1 above, or, MUST enter S3 state only when third-party applications do not need the system resources (eg the screen, CPU).

    Conversely, MUST exit from S3 state when third-party applications need the system resources, as described on this SDK.

    For example, while the third-party applications request to keep the screen on through FLAG_KEEP_SCREEN_ON or keep CPU running through PARTIAL_WAKE_LOCK , the device MUST NOT enter S3 state unless, as described in C-1-1, the user has taken explicit action to put the device in an inactive state. Conversely, at a time when a task that third-party apps implement through JobScheduler is triggered or Firebase Cloud Messaging is delivered to third-party apps, the device MUST exit the S3 state unless the user has put the device in an inactive state. These are not comprehensive examples and AOSP implements extensive wake-up signals that trigger a wakeup from this state.

8.4. Power Consumption Accounting

A more accurate accounting and reporting of the power consumption provides the app developer both the incentives and the tools to optimize the power usage pattern of the application.

Device implementations:

  • [C-SR-1] STRONGLY RECOMMENDED to provide a per-component power profile that defines the current consumption value for each hardware component and the approximate battery drain caused by the components over time as documented in the Android Open Source Project site.
  • [C-SR-2] STRONGLY RECOMMENDED to report all power consumption values in milliampere hours (mAh).
  • [C-SR-3] STRONGLY RECOMMENDED to report CPU power consumption per each process's UID. El proyecto de código abierto de Android cumple con el requisito mediante la implementación del módulo del kernel uid_cputime .
  • [C-SR-4] STRONGLY RECOMMENDED to make this power usage available via the adb shell dumpsys batterystats shell command to the app developer.
  • SHOULD be attributed to the hardware component itself if unable to attribute hardware component power usage to an application.

8.5. Rendimiento consistente

Performance can fluctuate dramatically for high-performance long-running apps, either because of the other apps running in the background or the CPU throttling due to temperature limits. Android includes programmatic interfaces so that when the device is capable, the top foreground application can request that the system optimize the allocation of the resources to address such fluctuations.

Device implementations:

If device implementations report support of Sustained Performance Mode, they:

  • [C-1-1] MUST provide the top foreground application a consistent level of performance for at least 30 minutes, when the app requests it.
  • [C-1-2] MUST honor the Window.setSustainedPerformanceMode() API and other related APIs.

If device implementations include two or more CPU cores, they:

  • SHOULD provide at least one exclusive core that can be reserved by the top foreground application.

If device implementations support reserving one exclusive core for the top foreground application, they:

  • [C-2-1] MUST report through the Process.getExclusiveCores() API method the ID numbers of the exclusive cores that can be reserved by the top foreground application.
  • [C-2-2] MUST not allow any user space processes except the device drivers used by the application to run on the exclusive cores, but MAY allow some kernel processes to run as necessary.

If device implementations do not support an exclusive core, they:

9. Security Model Compatibility

Device implementations:

  • [C-0-1] MUST implement a security model consistent with the Android platform security model as defined in Security and Permissions reference document in the APIs in the Android developer documentation.

  • [C-0-2] MUST support installation of self-signed applications without requiring any additional permissions/certificates from any third parties/authorities.

If device implementations declare the android.hardware.security.model.compatible feature, they:

  • [C-1-1] MUST support the requirements listed in the following subsections.

9.1. Permisos

Device implementations:

  • [C-0-1] MUST support the Android permissions model and the Android Roles Model as defined in the Android developer documentation. Specifically, they MUST enforce each permission and role defined as described in the SDK documentation; no permissions and no roles may be omitted, altered, or ignored.

  • MAY add additional permissions, provided the new permission ID strings are not in the android.\* namespace.

  • [C-0-2] Permissions with a protectionLevel of PROTECTION_FLAG_PRIVILEGED MUST only be granted to apps preinstalled in the privileged path(s) of the system image (as well as APEX files ) and be within the subset of the explicitly allowlisted permissions for each aplicación. The AOSP implementation meets this requirement by reading and honoring the allowlisted permissions for each app from the files in the etc/permissions/ path and using the system/priv-app path as the privileged path.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-0-16] (February 5, 2024 preview)

  • [C-0-16] Permissions with a protectionLevel of PROTECTION_SIGNATURE MUST only be granted to either:

    • Apps preinstalled on the system image (as well as APEX files ).
    • Apps allowlisted with allowed permissions if they are not included in the system image.

    The AOSP implementation meets this requirement by reading and honoring the allowlisted permissions for each app from the files in the etc/permissions/ path.

Terminar con nuevos requisitos

Permissions with a protection level of dangerous are runtime permissions. Applications with targetSdkVersion > 22 request them at runtime.

Device implementations:

  • [C-0-3] MUST show a dedicated interface for the user to decide whether to grant the requested runtime permissions and also provide an interface for the user to manage runtime permissions.

  • [C-0-5] MUST NOT grant any runtime permissions to apps unless:

    • They are installed at time of device shipment, AND
    • The user's consent can be obtained before the application uses the permission,

      O

    • The runtime permissions are granted by the default permission grant policy or for holding a platform role .

  • [C-0-6] MUST grant the android.permission.RECOVER_KEYSTORE permission only to system apps that register a properly secured Recovery Agent. A properly secured Recovery Agent is defined as an on-device software agent that synchronizes with an off-device remote storage, that is equipped with secure hardware with protection equivalent or stronger than what is described in Google Cloud Key Vault Service to prevent brute-force attacks on the lockscreen knowledge factor.

Device implementations:

  • [C-0-7] MUST adhere to Android location permission properties when an app requests the location or physical activity data through standard Android API or proprietary mechanism. Such data includes but not limited to:

    • Device's location (eg latitude and longitude) as described in section 9.8.8 .
    • Information that can be used to determine or estimate the device's location (eg SSID, BSSID, Cell ID, or location of the network that the device is connected to).
    • User's physical activity or classification of the physical activity.

More specifically, device implementations:

  • [C-0-8] MUST obtain user consent to allow an app to access the location or physical activity data.
  • [C-0-9] MUST grant a runtime permission ONLY to the app that holds sufficient permission as described on SDK. For example, TelephonyManager#getServiceState requires android.permission.ACCESS_FINE_LOCATION ).

The only exceptions to the Android location permission properties above are for apps not accessing Location to derive or identify user location; específicamente:

  • When apps hold the RADIO_SCAN_WITHOUT_LOCATION permission.
  • For device configuration and setup purposes, where system apps hold the NETWORK_SETTINGS or NETWORK_SETUP_WIZARD permission.

Permissions can be marked as restricted altering their behavior.

  • [C-0-10] Permissions marked with the flag hardRestricted MUST NOT be granted to an app unless:

    • An app APK file is in the system partition.
    • The user assigns a role that is associated with the hardRestricted permissions to an app.
    • The installer grants the hardRestricted to an app.
    • An app is granted the hardRestricted on an earlier Android version.
  • [C-0-11] Apps holding a softRestricted permission MUST get only limited access and MUST NOT gain full access until allowlisted as described in the SDK, where full and limited access is defined for each softRestricted permission (for example, READ_EXTERNAL_STORAGE ).

  • [C-0-12] MUST NOT provide any custom functions or APIs to bypass the permission restrictions defined in setPermissionPolicy and setPermissionGrantState APIs.

  • [C-0-13] MUST use the AppOpsManager APIs to record and track each and every programmatic access of data protected by dangerous permissions from Android activities and services.

  • [C-0-14] MUST only assign roles to applications with functionalities that meet the role requirements.

  • [C-0-15] MUST not define roles that are duplicates or superset functionality of roles defined by the platform.

If devices report android.software.managed_users , they:

  • [C-1-1] MUST NOT have the following permissions silently granted by the admin:
    • Location (ACCESS_BACKGROUND_LOCATION, ACCESS_COARSE_LOCATION, ACCESS_FINE_LOCATION).
    • Camera (CAMERA)
    • Microphone (RECORD_AUDIO)
    • Body sensor (BODY_SENSORS)
    • Physical activity (ACTIVITY_RECOGNITION)

If device implementations provide a user affordance to choose which apps can draw on top of other apps with an activity that handles the ACTION_MANAGE_OVERLAY_PERMISSION intent, they:

  • [C-2-1] MUST ensure that all activities with intent filters for the ACTION_MANAGE_OVERLAY_PERMISSION intent have the same UI screen, regardless of the initiating app or any information it provides.

If device implementations report android.software.device_admin, they:

  • [C-3-1] MUST show a disclaimer during fully managed device setup (device owner setup) stating that the IT admin will have the ability to allow apps to control settings on the phone including microphone, camera and location, with options for user to continue setup or exit setup UNLESS the admin has opted out of control of permissions on the device.

If device implementations pre-install any packages that hold any of the System UI Intelligence , System Ambient Audio Intelligence , System Audio Intelligence , System Notification Intelligence , System Text Intelligence , or System Visual Intelligence roles, the packages:

  • [C-4-1] MUST fulfill all requirements outlined for device implementations in sections "9.8.6 OS-level and ambient data and 9.8.15 Sandboxed API implementations".

If device implementations include a default application to support the VoiceInteractionService they:

  • [C-5-1] MUST NOT grant ACCESS_FINE_LOCATION as the default for that application.

9.2. UID and Process Isolation

Device implementations:

  • [C-0-1] MUST support the Android application sandbox model, in which each application runs as a unique Unixstyle UID and in a separate process.
  • [C-0-2] MUST support running multiple applications as the same Linux user ID, provided that the applications are properly signed and constructed, as defined in the Security and Permissions reference .

9.3. Permisos del sistema de archivos

Device implementations:

9.4. Alternate Execution Environments

Device implementations MUST keep consistency of the Android security and permission model, even if they include runtime environments that execute applications using some other software or technology than the Dalvik Executable Format or native code. En otras palabras:

  • [C-0-1] Alternate runtimes MUST themselves be Android applications, and abide by the standard Android security model, as described elsewhere in section 9 .

  • [C-0-2] Alternate runtimes MUST NOT be granted access to resources protected by permissions not requested in the runtime's AndroidManifest.xml file via the < uses-permission > mechanism.

  • [C-0-3] Alternate runtimes MUST NOT permit applications to make use of features protected by Android permissions restricted to system applications.

  • [C-0-4] Alternate runtimes MUST abide by the Android sandbox model and installed applications using an alternate runtime MUST NOT reuse the sandbox of any other app installed on the device, except through the standard Android mechanisms of shared user ID and signing certificate .

  • [C-0-5] Alternate runtimes MUST NOT launch with, grant, or be granted access to the sandboxes corresponding to other Android applications.

  • [C-0-6] Alternate runtimes MUST NOT be launched with, be granted, or grant to other applications any privileges of the superuser (root), or of any other user ID.

  • [C-0-7] When the .apk files of alternate runtimes are included in the system image of device implementations, it MUST be signed with a key distinct from the key used to sign other applications included with the device implementations.

  • [C-0-8] When installing applications, alternate runtimes MUST obtain user consent for the Android permissions used by the application.

  • [C-0-9] When an application needs to make use of a device resource for which there is a corresponding Android permission (such as Camera, GPS, etc.), the alternate runtime MUST inform the user that the application will be able to access that resource.

  • [C-0-10] When the runtime environment does not record application capabilities in this manner, the runtime environment MUST list all permissions held by the runtime itself when installing any application using that runtime.

  • Alternate runtimes SHOULD install apps via the PackageManager into separate Android sandboxes (Linux user IDs, etc.).

  • Alternate runtimes MAY provide a single Android sandbox shared by all applications using the alternate runtime.

9.5. Soporte multiusuario

Android includes support for multiple users and provides support for full user isolation and clone user profiles with partial isolation(ie single additional user profile of type android.os.usertype.profile.CLONE ).

  • Device implementations MAY but SHOULD NOT enable multi-user if they use removable media for primary external storage.

If device implementations include support for multiple users, they:

  • [C-1-2] MUST, for each user, implement a security model consistent with the Android platform security model as defined in Security and Permissions reference document in the APIs.
  • [C-1-3] MUST have separate and isolated shared application storage (aka /sdcard ) directories for each user instance.
  • [C-1-4] MUST ensure that applications owned by and running on behalf a given user cannot list, read, or write to the files owned by any other user, even if the data of both users are stored on the same volume or filesystem.
  • [C-1-5] MUST encrypt the contents of the SD card when multiuser is enabled using a key stored only on non-removable media accessible only to the system if device implementations use removable media for the external storage APIs. As this will make the media unreadable by a host PC, device implementations will be required to switch to MTP or a similar system to provide host PCs with access to the current user's data.

If device implementations include support for multiple users, then for all users except users specifically created for running dual instances of the same app, they:

  • [C-2-1] MUST have separate and isolated shared application storage (aka /sdcard) directories for each user instance.
  • [C-2-2] MUST ensure that applications owned by and running on behalf of a given user cannot list, read, or write to the files owned by any other user, even if the data of both users are stored on the same volume or filesystem.

Device implementations MAY create a single additional user profile of type android.os.usertype.profile.CLONE against the primary user (and only against the primary user) for the purpose of running dual instances of the same app. These dual instances share partially isolated storage, are presented to the end user in the launcher at the same time and appear in the same recents view. For example, this could be used to support the user installing two separate instances of a single app on a dual-SIM device.

If device implementations create the additional user profile discussed above, then they:

  • [C-3-1] MUST only provide access to storage or data that is either already accessible to the parent user profile or is directly owned by this additional user profile.
  • [C-3-2] MUST NOT have this as a work profile.
  • [C-3-3] MUST have isolated private app data directories from the parent user account.
  • [C-3-4] MUST NOT allow the additional user profile to be created if there is a Device Owner provisioned (see section 3.9.1) or allow a Device Owner to be provisioned without removing the additional user profile first.

If device implementations create the additional user profile discussed above, then they:

  • [C-4-1] MUST allow the below intents originating from the additional profile to be handled by applications of the primary user on the device:

    • Intent.ACTION_VIEW
    • Intent.ACTION_SENDTO
    • Intent.ACTION_SEND
    • Intent.ACTION_EDIT
    • Intent.ACTION_INSERT
    • Intent.ACTION_INSERT_OR_EDIT
    • Intent.ACTION_SEND_MULTIPLE
    • Intent.ACTION_PICK
    • Intent.ACTION_GET_CONTENT
    • MediaStore.ACTION_IMAGE_CAPTURE
    • MediaStore.ACTION_VIDEO_CAPTURE
  • [C-4-2] MUST inherit all device policy user restrictions and selected non-user restrictions(list below) applied on the primary user of the device to this additional user profile.

  • [C-4-3] MUST only allow writing contacts from this additional profile via the following intents:

  • [C-4-4] MUST NOT have contact syncs running for applications running in this additional user profile.

  • [C-4-5] MUST only allow applications in the additional profile that have a launcher activity to access contacts that are already accessible to the parent user profile.

9.6. Premium SMS Warning

Android includes support for warning users of any outgoing premium SMS message . Premium SMS messages are text messages sent to a service registered with a carrier that may incur a charge to the user.

Si las implementaciones de dispositivos declaran compatibilidad con android.hardware.telephony ,:

  • [C-1-1] MUST warn users before sending a SMS message to numbers identified by regular expressions defined in /data/misc/sms/codes.xml file in the device. The upstream Android Open Source Project provides an implementation that satisfies this requirement.

9.7. Características de seguridad

Device implementations MUST ensure compliance with security features in both the kernel and platform as described below.

The Android Sandbox includes features that use the Security-Enhanced Linux (SELinux) mandatory access control (MAC) system, seccomp sandboxing, and other security features in the Linux kernel. Device implementations:

  • [C-0-1] MUST maintain compatibility with existing applications, even when SELinux or any other security features are implemented below the Android framework.
  • [C-0-2] MUST NOT have a visible user interface when a security violation is detected and successfully blocked by the security feature implemented below the Android framework, but MAY have a visible user interface when an unblocked security violation occurs resulting in a successful explotar.
  • [C-0-3] MUST NOT make SELinux or any other security features implemented below the Android framework configurable to the user or app developer.
  • [C-0-4] MUST NOT allow an application that can affect another application through an API (such as a Device Administration API) to configure a policy that breaks compatibility.
  • [C-0-5] MUST split the media framework into multiple processes so that it is possible to more narrowly grant access for each process as described in the Android Open Source Project site.
  • [C-0-6] MUST implement a kernel application sandboxing mechanism which allows filtering of system calls using a configurable policy from multithreaded programs. The upstream Android Open Source Project meets this requirement through enabling the seccomp-BPF with threadgroup synchronization (TSYNC) as described in the Kernel Configuration section of source.android.com .

Kernel integrity and self-protection features are integral to Android security. Device implementations:

  • [C-0-7] MUST implement kernel stack buffer overflow protection mechanisms. Examples of such mechanisms are CC_STACKPROTECTOR_REGULAR and CONFIG_CC_STACKPROTECTOR_STRONG .
  • [C-0-8] MUST implement strict kernel memory protections where executable code is read-only, read-only data is non-executable and non-writable, and writable data is non-executable (eg CONFIG_DEBUG_RODATA or CONFIG_STRICT_KERNEL_RWX ).
  • [C-0-9] MUST implement static and dynamic object size bounds checking of copies between user-space and kernel-space (eg CONFIG_HARDENED_USERCOPY ) on devices originally shipping with API level 28 or higher.
  • [C-0-10] MUST NOT execute user-space memory when executing in the kernel mode (eg hardware PXN, or emulated via CONFIG_CPU_SW_DOMAIN_PAN or CONFIG_ARM64_SW_TTBR0_PAN ) on devices originally shipping with API level 28 or higher.
  • [C-0-11] MUST NOT read or write user-space memory in the kernel outside of normal usercopy access APIs (eg hardware PAN, or emulated via CONFIG_CPU_SW_DOMAIN_PAN or CONFIG_ARM64_SW_TTBR0_PAN ) on devices originally shipping with API level 28 or higher.
  • [C-0-12] MUST implement kernel page table isolation if the hardware is vulnerable to CVE-2017-5754 on all devices originally shipping with API level 28 or higher (eg CONFIG_PAGE_TABLE_ISOLATION or CONFIG_UNMAP_KERNEL_AT_EL0 ).
  • [C-0-13] MUST implement branch prediction hardening if the hardware is vulnerable to CVE-2017-5715 on all devices originally shipping with API level 28 or higher (eg CONFIG_HARDEN_BRANCH_PREDICTOR ).

  • [C-SR-1] Are STRONGLY RECOMMENDED to enable stack initialization in the kernel to prevent uses of uninitialized local variables ( CONFIG_INIT_STACK_ALL or CONFIG_INIT_STACK_ALL_ZERO ). Also, device implementations SHOULD NOT assume the value used by the compiler to initialize the locals.

  • [C-SR-2] Are STRONGLY RECOMMENDED to keep kernel data which is written only during initialization marked read-only after initialization (eg __ro_after_init ).

  • [C-SR-3] Are STRONGLY RECOMMENDED to randomize the layout of the kernel code and memory, and to avoid exposures that would compromise the randomization (eg CONFIG_RANDOMIZE_BASE with bootloader entropy via the /chosen/kaslr-seed Device Tree node or EFI_RNG_PROTOCOL ) .

  • [C-SR-4] Are STRONGLY RECOMMENDED to enable control flow integrity (CFI) in the kernel to provide additional protection against code-reuse attacks (eg CONFIG_CFI_CLANG and CONFIG_SHADOW_CALL_STACK ).

  • [C-SR-5] Are STRONGLY RECOMMENDED not to disable Control-Flow Integrity (CFI), Shadow Call Stack (SCS) or Integer Overflow Sanitization (IntSan) on components that have it enabled.

  • [C-SR-6] Are STRONGLY RECOMMENDED to enable CFI, SCS, and IntSan for any additional security-sensitive userspace components as explained in CFI and IntSan .

  • [C-SR-7] Are STRONGLY RECOMMENDED to enable stack initialization in the kernel to prevent uses of uninitialized local variables ( CONFIG_INIT_STACK_ALL or CONFIG_INIT_STACK_ALL_ZERO ). Also, device implementations SHOULD NOT assume the value used by the compiler to initialize the locals.

  • [C-SR-8] Are STRONGLY RECOMMENDED to enable heap initialization in the kernel to prevent uses of uninitialized heap allocations ( CONFIG_INIT_ON_ALLOC_DEFAULT_ON ) and they SHOULD NOT assume the value used by the kernel to initialize those allocations.

If device implementations use a Linux kernel that is capable of supporting SELinux, they:

  • [C-1-1] MUST implement SELinux.
  • [C-1-2] MUST set SELinux to global enforcing mode.
  • [C-1-3] MUST configure all domains in enforcing mode. No permissive mode domains are allowed, including domains specific to a device/vendor.
  • [C-1-4] MUST NOT modify, omit, or replace the neverallow rules present within the system/sepolicy folder provided in the upstream Android Open Source Project (AOSP) and the policy MUST compile with all neverallow rules present, for both AOSP SELinux domains as well as device/vendor specific domains.
  • [C-1-5] MUST run third-party applications targeting API level 28 or higher in per-application SELinux sandboxes with per-app SELinux restrictions on each application's private data directory.
  • SHOULD retain the default SELinux policy provided in the system/sepolicy folder of the upstream Android Open Source Project and only further add to this policy for their own device-specific configuration.

If device implementations use kernel other than Linux or Linux without SELinux, they:

  • [C-2-1] MUST use a mandatory access control system that is equivalent to SELinux.

If device implementations use I/O devices capable of DMA, they:

  • [C-SR-9] Are STRONGLY RECOMMENDED to isolate each I/O device capable of DMA, using an IOMMU (egthe ARM SMMU).

Android contains multiple defense-in-depth features that are integral to device security. In addition, Android focuses on reducing key classes of common bugs that contribute to poor quality and security.

In order to reduce memory bugs, device implementations:

  • [C-SR-10] Are STRONGLY RECOMMENDED to be tested using userspace memory error detection tools like MTE for ARMv9 devices, HWASan for ARMv8+ devices or ASan for other device types.
  • [C-SR-11] Are STRONGLY RECOMMENDED to be tested using kernel memory error detection tools like KASAN (CONFIG_KASAN, CONFIG_KASAN_HW_TAGS for ARMv9 devices, CONFIG_KASAN_SW_TAGS for ARMv8 devices or CONFIG_KASAN_GENERIC for other device types).
  • [C-SR-12] Are STRONGLY RECOMMENDED to be using memory error detection tools in production like MTE, GWP-ASan and KFENCE.

If device implementations use an Arm TrustZone-based TEE, they:

  • [C-SR-13] Are STRONGLY RECOMMENDED to use a standard protocol for memory sharing, between Android and the TEE, like Arm Firmware Framework for Armv8-A (FF-A).
  • [C-SR-14] Are STRONGLY RECOMMENDED to restrict trusted applications to only accessing memory which has been explicitly shared with them via the above protocol. If the device has support for the Arm S-EL2 exception level, this should be enforced by the secure partition manager. Otherwise, this should be enforced by the TEE OS.

A Memory Safety technology is a technology that mitigates at least the following classes of bugs with a high (> 90%) probability in applications that use the android:memtagMode manifest option:

  • heap buffer overflow
  • use after free
  • double free
  • wild free (free of a non-malloc pointer)

Device implementations:

  • [C-SR-15] Are STRONGLY RECOMMENDED to set ro.arm64.memtag.bootctl_supported .

If device implementations set the system property ro.arm64.memtag.bootctl_supported to true, they:

  • [C-3-1] MUST allow the system property arm64.memtag.bootctl to accept a comma-separated list of the following values, with the desired effect applied on the next subsequent reboot:

    • memtag : a Memory Safety technology as defined above is enabled
    • memtag-once : a Memory Safety technology as defined above is transiently enabled, and is automatically disabled upon, next reboot
    • memtag-off : a Memory Safety technology as defined above is disabled
  • [C-3-2] MUST allow the shell user to set arm64.memtag.bootctl .

  • [C-3-3] MUST allow any process to read arm64.memtag.bootctl .

  • [C-3-4] MUST set arm64.memtag.bootctl to the currently requested state upon boot, it MUST also update the property, if the device implementation allows to modify the state without changing the system property.

  • [C-SR-16] Are STRONGLY RECOMMENDED to show a Developer Setting that sets memtag-once and reboots the device. With a compatible bootloader, the Android Open Source Project meets the above requirements through the MTE bootloader protocol .

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-SR-17 through C-SR-20] [Renumbered] (April 8, 2024 preview)

If a device declares android.hardware.telephony , supports the radio capability CAPABILITY_USES_ALLOWED_NETWORK_TYPES_BITMASK , and includes a cellular modem that supports 2G connections, the device implementation:

Terminar con nuevos requisitos

[C-4-1 through C-4-4] (December 11, 2023 preview)

If a device declares android.hardware.telephony , supports the radio capability CAPABILITY_USES_ALLOWED_NETWORK_TYPES_BITMASK , and includes a cellular modem that supports 2G connections, the device implementation:

Terminar con nuevos requisitos

9.8. Privacidad

9.8.1. Historial de uso

Android stores the history of the user's choices and manages such history by UsageStatsManager .

Device implementations:

  • [C-0-1] MUST keep a reasonable retention period of such user history.
  • [C-SR-1] Are STRONGLY RECOMMENDED to keep the 14 days retention period as configured by default in the AOSP implementation.

Android stores the system events using the StatsLog identifiers, and manages such history via the StatsManager and the IncidentManager System API.

Device implementations:

  • [C-0-2] MUST only include the fields marked with DEST_AUTOMATIC in the incident report created by the System API class IncidentManager .
  • [C-0-3] MUST not use the system event identifiers to log any other event than what is described in the StatsLog SDK documents. If additional system events are logged, they MAY use a different atom identifier in the range between 100,000 and 200,000.

9.8.2. Grabación

Device implementations:

  • [C-0-1] MUST NOT preload or distribute software components out-of-box that send the user's private information (eg keystrokes, text displayed on the screen, bugreport) off the device without the user's consent or clear ongoing notifications.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-0-2] [Reverted] (April 8, 2024 preview)

Terminar con nuevos requisitos

[C-0-2] (February 5, 2024 preview)

Terminar con nuevos requisitos

  • [C-0-3] MUST have an ongoing notification to the user while screen casting or screen recording is enabled. AOSP meets this requirement by showing an ongoing notification icon in the status bar.

  • [C-SR-1] Are STRONGLY RECOMMENDED to display a user warning which is exactly the same message as implemented in AOSP but CAN be altered as long as the message clearly warns the user that any sensitive information on the user's screen is captured.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-0-4] [Reverted] (April 8, 2024 preview)

Terminar con nuevos requisitos

[C-0-4] (February 5, 2024 preview)

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-0-5 and C-0-6] (April 8, 2024 preview)

Device implementations:

  • [C-0-5] MUST NOT alter an app's setting of FLAG_SECURE .

  • [C-0-6] MUST provide users an affordance to turn off the screen recording for sensitive notification protection feature via Developer Options menu.

Terminar con nuevos requisitos

If device implementations include functionality in the system that either captures the contents displayed on the screen and/or records the audio stream played on the device other than via the System API ContentCaptureService , or other proprietary means described in Section 9.8.6 OS-level and ambient data , they:

  • [C-1-1] MUST have an ongoing notification to the user whenever this functionality is enabled and actively capturing/recording.

If device implementations include a component enabled out-of-box, capable of recording ambient audio and/or record the audio played on the device to infer useful information about user's context, they:

  • [C-2-1] MUST NOT store in persistent on-device storage or transmit off the device the recorded raw audio or any format that can be converted back into the original audio or a near facsimile, except with explicit user consent.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-3-1 through C-3-3] (April 8, 2024 preview)

If screen recording is active and is not initiated through System UI or via OEM bug reporting app, device notification implementations:

  • [C-3-1] MUST display content when the notifications' visibility is VISIBILITY_PUBLIC or redacted notification content (no more than app icon and app name) on all surfaces where notification content is visible (including lock screen, heads up notifications, notification shade, bubbles, and Launcher dots) unless either of the following is true:

    • Partial screen is shared.
    • Notification content does not reveal any personal or sensitive user data such as when notification is a foreground service posted by the app recording the screen, or notification is from the Android system.
  • [C-3-2] MUST hide app windows which have posted notifications containing detected one-time passwords by calling WindowState.setSecureLocked(true) .

  • [C-3-3] MUST hide sensitive views or an app window when CONTENT_SENSITIVITY_SENSITIVE is visible or when the framework heuristic determines that the view contains any sensitive data as follows:

Terminar con nuevos requisitos

[C-3-1 through C-3-5] (February 26, 2024 preview)

If screen sharing recording is active, device implementations:

  • [C-3-1] MUST only display notification content when notifications' visibility is VISIBILITY_PUBLIC , or display redacted notification content (no more than app icon and app name) on all surfaces where notification content is visible (including lock screen, notification shade, bubbles, and Launcher dots), unless at least one of the following is true:

    • A foreground service notification is posted by the app recording the screen.
    • Screenshare is initiated by Bug report handler or System (including screen record from Quick Settings tile).
    • Partial screen sharing is in use.
  • [C-3-2] MUST hide app windows which have posted notifications containing detected one-time passwords by calling WindowState.setSecureLocked(true) .

  • [C-3-3] MUST hide sensitive views or app window when a sensitive view ( CONTENT_SENSITIVITY_SENSITIVE ) is visible.

  • [C-3-4] MUST NOT alter an app's setting of FLAG_SECURE .

  • [C-3-5] MUST provide an option for users an affordance to turn off the screen recording for sensitive notification protection feature via Developer Options menu.

Terminar con nuevos requisitos

[C-3-1 through C-3-3] (February 5, 2024 preview)

When screen sharing is active, a device implementation:

  • [C-3-1] MUST only display notification content when setVisibility() is set to public, or display redacted notification content (only app icon and app name) on all surfaces where notification content is visible (including lock screen, notification shade, bubbles, and Launcher dots), unless either:

    • Notification is Foreground Service notification of the screen share / record app; FGS notifications can be shown fully / unredacted.
    • Screenshare is initiated by:
      • Bug report handler
      • SysUI (including screen record from Quick Settings tile)
    • Partial screen sharing is in use.
  • [C-3-2] MUST hide app windows of apps that have posted notifications containing detected one-time passwords.

    • MUST be implemented by calling WindowState.setSecureLocked(true) on the app's windows.
      • Implementation SHOULD NOT interfere with apps setting FLAG_SECURE .
  • [C-3-3] MUST provide an option for users an affordance to turn off the feature via developer mode.

Terminar con nuevos requisitos

A "microphone indicator" refers to a view on screen, which is constantly visible to the user and cannot be obscured, which users understand as a microphone is in use(through unique text, color, icon, or some combination).

A "camera indicator" refers to a view on screen, which is constantly visible to the user and cannot be obscured, which users understand as a camera is in use (through unique text, color, icon, or some combination).

After the first one second displayed, an indicator can change visually, such as becoming smaller, and is not required to show as originally presented and understood.

The microphone indicator may be merged with an actively displayed camera indicator, provided that text, icons, or colors indicate to the user that microphone use has begun.

The camera indicator may be merged with an actively displayed microphone indicator, provided that text, icons, or colors indicate to the user that the camera use has begun.

If device implementations declare android.hardware.microphone , they:

  • [C-SR-1] Are STRONGLY RECOMMENDED to display microphone indicator when an app is accessing audio data from the microphone, but not when the microphone is only accessed by HotwordDetectionService , SOURCE_HOTWORD , ContentCaptureService , or app(s) holding the roles called out in Section 9.1 Permissions with CDD identifier [C-3-X]. .
  • [C-SR-2] Are STRONGLY RECOMMENDED to display the list of Recent and Active apps using microphone as returned from PermissionManager.getIndicatorAppOpUsageData() , along with any attribution messages associated with them.
  • [C-SR-3] Are STRONGLY RECOMMENDED to not hide the microphone indicator for system apps that have visible user interfaces or direct user interaction.

If device implementations declare android.hardware.camera.any , they:

  • [C-SR-4] Are STRONGLY RECOMMENDED to display camera indicator when an app is accessing live camera data, but not when the camera is only being accessed by app(s) holding the roles called out in Section 9.1 Permissions with CDD identifier [C-3-X].
  • [C-SR-5] Are STRONGLY RECOMMENDED to display Recent and Active apps using camera as returned from PermissionManager.getIndicatorAppOpUsageData() , along with any attribution messages associated with them.
  • [C-SR-6] Are STRONGLY RECOMMENDED to not hide the camera indicator for system apps that have visible user interfaces or direct user interaction.

9.8.3. Conectividad

If device implementations have a USB port with USB peripheral mode support, they:

  • [C-1-1] MUST present a user interface asking for the user's consent before allowing access to the contents of the shared storage over the USB port.

9.8.4. Tráfico de red

Device implementations:

  • [C-0-1] MUST preinstall the same root certificates for the system-trusted Certificate Authority (CA) store as provided in the upstream Android Open Source Project.
  • [C-0-2] MUST ship with an empty user root CA store.
  • [C-0-3] MUST display a warning to the user indicating the network traffic may be monitored, when a user root CA is added.

If device traffic is routed through a VPN, device implementations:

  • [C-1-1] MUST display a warning to the user indicating either:
    • That network traffic may be monitored.
    • That network traffic is being routed through the specific VPN application providing the VPN.

If device implementations have a mechanism, enabled out-of-box by default, that routes network data traffic through a proxy server or VPN gateway (for example, preloading a VPN service with android.permission.CONTROL_VPN granted), they:

  • [C-2-1] MUST ask for the user's consent before enabling that mechanism, unless that VPN is enabled by the Device Policy Controller via the DevicePolicyManager.setAlwaysOnVpnPackage() , in which case the user does not need to provide a separate consent, but MUST only be notified.

If device implementations implement a user affordance to toggle on the "always-on VPN" function of a 3rd-party VPN app, they:

  • [C-3-1] MUST disable this user affordance for apps that do not support always-on VPN service in the AndroidManifest.xml file via setting the SERVICE_META_DATA_SUPPORTS_ALWAYS_ON attribute to false .

9.8.5. Identificadores de dispositivos

Device implementations:

  • [C-0-1] MUST prevent access to the device serial number and, where applicable, IMEI/MEID, SIM serial number, and International Mobile Subscriber Identity (IMSI) from an app, unless it meets one of the following requirements:
    • is a signed carrier app that is verified by device manufacturers.
    • has been granted the READ_PRIVILEGED_PHONE_STATE permission.
    • has carrier privileges as defined in UICC Carrier Privileges .
    • is a device owner or profile owner that has been granted the READ_PHONE_STATE permission.
    • (For SIM serial number/ICCID only) has the local regulations requirement that the app detect changes in the subscriber's identity.

9.8.6. OS-level and ambient data

Android, through the System APIs, supports a mechanism for device implementations to capture the following sensitive data:

  • Text and graphics rendered on-screen, including but not limited to, notifications and assist data via AssistStructure API.
  • Media data, such as audio or video, recorded or played by the device.
  • Input events (eg key, mouse, gesture, voice, video, and accessibility).

  • Any screen or other data sent via the AugmentedAutofillService to the system.

  • Any screen or other data accessible via Content Capture APIs.

  • Any application data passed to the system via the AppSearchManager API and accessible via AppSearchGlobalManager.query .

  • Any text or other data sent via the TextClassifier API to the System TextClassifier ie to the system service to understand the meaning of text, as well as generating predicted next actions based on the text.

  • Data indexed by the platform AppSearch implementation, including but not limited to text, graphics, media data or other similar data.

  • Audio data obtained as a result of using SpeechRecognizer#onDeviceSpeechRecognizer() by the Speech Recognizer Implementation.

  • Audio data obtained in background (continuously) through AudioRecord , SoundTrigger or other Audio APIs, and not resulting in a user-visible indicator

  • Camera data obtained in background (continuously) through CameraManager or other Camera APIs, and not resulting in a user-visible indicator

If device implementations capture any of the data above, they:

  • [C-1-1] MUST encrypt all such data when stored in the device. This encryption MAY be carried out using Android File Based Encryption, or any of the ciphers listed as API version 26+ described in Cipher SDK .
  • [C-1-2] MUST NOT back up either raw or encrypted data using Android backup methods or any other back up methods.
  • [C-1-3] MUST only send all such data off the device using a privacy-preserving mechanism, except with explicit user consent every time the data is shared. The privacy-preserving mechanism is defined as "those which allow only analysis in aggregate and prevent matching of logged events or derived outcomes to individual users", to prevent any per-user data being introspectable (eg, implemented using a differential privacy technology such as RAPPOR ).
  • [C-1-4] MUST NOT associate such data with any user identity (such as Account ) on the device, except with explicit user consent each time the data is associated.
  • [C-1-5] MUST NOT share such data with other OS components that don't follow requirements outlined in the current section (9.8.6 OS-level and ambient data), except with explicit user consent every time it is shared. Unless such functionality is built as an Android SDK API ( AmbientContext , HotwordDetectionService ).
  • [C-1-6] MUST provide user affordance to erase such data that the implementation or the proprietary means collects when the data is stored in any form on the device. If the user chooses to erase the data, MUST remove all collected historical data.
  • [C-1-7] MUST provide a user affordance to opt-out of the data, collected via AppSearch or proprietary means from being shown in Android platform (eg launcher).

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-SR-1] (February 26, 2024 preview)

  • [C-SR-1] Are STRONGLY RECOMMENDED NOT to request the INTERNET permission.

Note: This is now the same as Android 14. Prior preview changes have been withdrawn.

Terminar con nuevos requisitos

[C-SR-1] (December 11, 2023 preview)

  • [C- SR-1 1-8 ] Are STRONGLY RECOMMENDED NOT to MUST not request the INTERNET permission.

Terminar con nuevos requisitos

  • [C-SR-2] Are STRONGLY RECOMMENDED to only access the internet through structured APIs backed by publicly available open-source implementations.
  • [C-SR-4] Are STRONGLY RECOMMENDED to be implemented with Android SDK API or a similar OEM-owned open-source repository; and / or be performed in a Sandboxed implementation (see 9.8.15 Sandboxed API implementations).

If device implementations include a service that implements the System API ContentCaptureService , AppSearchManager.index , or any proprietary service that captures the data as described as above, they:

  • [C-2-1] MUST NOT allow users to replace the services with a user-installable application or service and MUST only allow the preinstalled services to capture such data.
  • [C-2-2] MUST NOT allow any apps other than the preinstalled services mechanism to be able to capture such data.
  • [C-2-3] MUST provide user affordance to disable the services.
  • [C-2-4] MUST NOT omit user affordance to manage Android permissions that are held by the services and follow Android permissions model as described in Section 9.1. Permiso .

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-SR-3] (February 26, 2024 preview)

  • [C-SR-3] Are STRONGLY RECOMMENDED to keep the services separate from other system components (eg not binding the service or sharing process IDs) except for the following:
    • Telephony, Contacts, System UI, and Media

Note: This is now the same as Android 14. Prior preview changes have been withdrawn.

Terminar con nuevos requisitos

[C-SR-3] (December 11, 2023 preview)

  • [C- SR-3 1-5 ] Are STRONGLY RECOMMENDED to MUST keep the services separate from other system components (eg not binding the service or sharing process IDs) except for the following:

    • Telephony, Contacts, System UI, and Media

Terminar con nuevos requisitos

9.8.7. Clipboard Access

Device implementations:

  • [C-0-1] MUST NOT return a clipped data from the clipboard (eg via the ClipboardManager API) unless the 3rd-party app is the default IME or is the app that currently has focus.

  • [C-0-2] MUST clear clipboard data at most 60 minutes after it has last been placed in a clipboard or read from a clipboard.

9.8.8. Ubicación

Location includes information in the Android Location class( such as Latitude, Longitude, Altitude), as well as identifiers that can be converted to Location. Location can be as fine as DGPS (Differential Global Positioning System) or as coarse as country level locations (like the country code location - MCC - Mobile Country Code).

The following is a list of location types that either directly derive a user's location or can be converted to a user's location. This is not a comprehensive list, but should be used as an example on what Location can directly or indirectly be derived from:

  • GPS/GNSS/DGPS/PPP
    • Global Positioning Solution or Global Navigation Satellite System or Differential Global Positioning Solution
    • This also includes Raw GNSS Measurements and GNSS Status
      • Fine Location can be derived from the Raw GNSS Measurements
  • Wireless Technologies with unique identifiers such as:
    • Wi-Fi access points (MAC, BSSID, Name, or SSID)
    • Bluetooth/BLE (MAC, BSSID, Name, or SSID)
    • UWB (MAC, BSSID, Name, or SSID)
    • Cell Tower ID (3G, 4G, 5G… including all future Cellular Modem technologies that have unique identifiers)

As a primary point of reference, see the Android APIs which require ACCESS_FINE_Location or ACCESS_COARSE_Location permissions.

Device implementations:

  • [C-0-1] MUST NOT turn on/off device location setting and Wi-Fi/Bluetooth scanning settings without explicit user consent or user initiation.
  • [C-0-2] MUST provide the user affordance to access location related information including recent location requests, app level permissions and usage of Wi-Fi/Bluetooth scanning for determining location.
  • [C-0-3] MUST ensure that the application using Emergency Location Bypass API [LocationRequest.setLocationSettingsIgnored()] is a user initiated emergency session (eg dial 911 or text to 911). For Automotive however, a vehicle MAY initiate an emergency session without active user interaction in the case a crash/accident is detected (eg to satisfy eCall requirements).
  • [C-0-4] MUST preserve the Emergency Location Bypass API's ability to bypass device location settings without changing the settings.
  • [C-0-5] MUST schedule a notification that reminds the user after an app in the background has accessed their location using the [ ACCESS_BACKGROUND_LOCATION ] permission.

9.8.9. Aplicaciones instaladas

Android apps targeting API level 30 or above cannot see details about other installed apps by default (see Package visibility in the Android SDK documentation).

Device implementations:

  • [C-0-1] MUST NOT expose to any app targeting API level 30 or above details about any other installed app, unless the app is already able to see details about the other installed app through the managed APIs. This includes but is not limited to details exposed by any custom APIs added by the device implementer, or accessible via the filesystem.
  • [C-0-2] MUST NOT give to any app, read or write access to files in any other app's dedicated, app-specific directory within external storage. Las únicas excepciones son las siguientes:
    • The external storage provider authority (eg apps like DocumentsUI).
    • Download Provider which uses the "downloads" provider authority for downloading files to app storage.
    • Platform-signed media transfer protocol (MTP) apps which use the privileged permission ACCESS_MTP to enable transferring files to another device.
    • Apps which install other apps and have the permission INSTALL_PACKAGES can access only "obb" directories for the purpose of managing APK expansion files .

9.8.10. Connectivity Bug Report

If device implementations declare the android.hardware.telephony feature flag, they:

  • [C-1-1] MUST support generating connectivity bug reports via BUGREPORT_MODE_TELEPHONY with BugreportManager.
  • [C-1-2] MUST obtain user consent every time BUGREPORT_MODE_TELEPHONY is used to generate a report and MUST NOT prompt the user to consent to all future requests from the application.
  • [C-1-3] MUST NOT return the generated report to the requesting app without explicit user consent.
  • [C-1-4] Reports generated using BUGREPORT_MODE_TELEPHONY MUST contain at least the following information:
    • TelephonyDebugService dump
    • TelephonyRegistry dump
    • WifiService dump
    • ConnectivityService dump
    • A dump of the calling package's CarrierService instance (if bound)
    • Radio log buffer
    • SubscriptionManagerService dump
  • [C-1-5] MUST NOT include the following in the generated reports:
    • Any kind of information that isn't directly related to connectivity debugging.
    • Any kind of user-installed application traffic logs or detailed profiles of user-installed applications/packages (UIDs are okay, package names are not).
  • MAY include additional information that is not associated with any user identity. (eg vendor logs).

If device implementations include additional information (eg vendor logs) in bug reports and that information has privacy/security/battery/storage/memory impact, they:

  • [C-SR-1] Are STRONGLY RECOMMENDED to have a developer setting defaulted to disabled. The AOSP reference implementation meets this by providing the Enable verbose vendor logging option in developer settings to include additional device-specific vendor logs in the bug reports.

9.8.11. Data blobs sharing

Android, through BlobStoreManager allows apps to contribute data blobs to the System to be shared with a selected set of apps.

If device implementations support shared data blobs as described in the SDK documentation , they:

9.8.12. Reconocimiento de música

Android, through the System API MusicRecognitionManager, supports a mechanism for device implementations to request music recognition, given an audio record, and delegate the music recognition to a privileged app implementing the MusicRecognitionService API.

If device implementations include a service that implements the System API MusicRecognitionManager or any proprietary service that streams audio data as described as above, they:

  • [C-1-1] MUST enforce that the caller of MusicRecognitionManager holds the MANAGE_MUSIC_RECOGNITION permission
  • [C-1-2] MUST enforce that a single, pre-installed, music recognition application implements MusicRecognitionService.
  • [C-1-3] MUST NOT allow users to replace the MusicRecognitionManagerService or MusicRecognitionService with a user-installable application or service.
  • [C-1-4] MUST ensure that when MusicRecognitionManagerService accesses the audio record and forwards it to the application implementing the MusicRecognitionService, the audio access is tracked via invocations of AppOpsManager.noteOp / startOp .

If device implementations of MusicRecognitionManagerService or MusicRecognitionService store any audio data captured, they:

  • [C-2-1] MUST NOT store any raw audio or audio fingerprints on disk at all, or in memory for longer than 14 days.
  • [C-2-2] MUST NOT share such data beyond the MusicRecognitionService, except with explicit user consent every time it is shared.

9.8.13. Administrador de privacidad del sensor

If device implementations provide the user a software affordance to turn off the camera and/or microphone input for the device implementation, they:

  • [C-1-1] MUST accurately return 'true' for the relevant supportsSensorToggle() API method.
  • [C-1-2] MUST, when an app tries to access a blocked microphone or camera, present the user with a non-dismissable user affordance that clearly indicates that the sensor is blocked and requires a choice to continue blocking or unblock as per the AOSP implementation which meets this requirement.
  • [C-1-3] MUST only pass blank (or fake) camera and audio data to apps and not report an error code due to the user not turning on the camera nor microphone via the user affordance presented per [C-1-2 ] arriba.

9.8.14. Administrador de Credenciales

Comienzan nuevos requisitos para 15 (AOSP experimental)

9.8.14 (February 26, 2024 preview)

Removed in Android 14.

Device implementations MUST declare support for android.software.credentials and:

  • MUST honor the android.settings.CREDENTIAL_PROVIDER intent to allow selection of a preferred provider for the Credential Manager. This provider will be enabled for Autofill and will also be the default location to save new credentials entered through the Credential Manager.
  • MUST support at least 2 concurrent credential providers and provide a user affordance in the Setting app to enable or disable providers.

Terminar con nuevos requisitos

9.8.14 (February 5, 2024 preview)

Removed in Android 14.

Device implementations MUST declare support for android.software.credentials and:

  • MUST fully implement the Credential API and honor the android.settings.CREDENTIAL_PROVIDER intent to show a default app settings menu to enable and disable credential providers.
  • MUST provide a user affordance in the Setting app to select a preferred provider for Autofill & Credential Manager. This provider will be enabled for autofill and will be the default location to save new credentials via Credential Manager.
  • MUST support at least 2 concurrent credential providers and provide a user affordance in the Setting app to enable or disable providers.

Terminar con nuevos requisitos

9.8.15. Sandboxed API Implementations

Android, through a set of delegate APIs provides a mechanism to process secure OS-level and ambient data. Such processing can be delegated to a preinstalled apk with privileged access and reduced communication capabilities, known as a Sandboxed API Implementation.

Any Sandboxed API implementation:

  • [C-0-1] MUST NOT request the INTERNET permission.
  • [C-0-2] MUST only access the internet through structured APIs backed by publicly available open-source implementations using privacy-preserving mechanisms, or indirectly via Android SDK APIs. The privacy-preserving mechanism is defined as "those which allow only analysis in aggregate and prevent matching of logged events or derived outcomes to individual users", to prevent any per-user data being introspectable (eg, implemented using a differential privacy technology such as RAPPOR ).
  • [C-0-3] MUST keep the services separate from other system components (eg not binding the service or sharing process IDs) except for the following:
    • Telephony, Contacts, System UI, and Media
  • [C-0-4] MUST NOT allow users to replace the services with a user-installable application or service
  • [C-0-5] MUST only allow the preinstalled services to capture such data. Unless the replacement capability is built into AOSP (eg for Digital Assistant Apps).
  • [C-0-6] MUST NOT allow any apps other than the preinstalled services mechanism to be able to capture such data. Unless such capture capability is implemented with an Android SDK API.
  • [C-0-7] MUST provide user affordance to disable the services.
  • [C-0-8] MUST NOT omit user affordance to manage Android permissions that are held by the services and follow the Android permissions model as described in Section 9.1. Permiso .

9.8.16. Continuous Audio and Camera data

Comienzan nuevos requisitos para 15 (AOSP experimental)

9.8.16 (February 26, 2024 preview)

In addition to requirements outlined in 9.8.2 Recording, 9.8.6 OS-level and ambient data, and 9.8.15 Sandboxed API implementations, implementations that make use of Audio data obtained in background (continuously) through AudioRecord, SoundTrigger or other Audio APIs OR Camera data obtained in background (continuously) through CameraManager or other Camera APIs:

If device implementations capture any of the data as described in 9.8.2 or section 9.8.6, and if such implementations make use of Audio data obtained in background (continuously) through AudioRecord, SoundTrigger, or other Audio APIs OR Camera data obtained in background (continuously) through CameraManager or other Camera APIs, they:

Terminar con nuevos requisitos

  • [C-0-1] MUST enforce a corresponding indicator (camera and/or microphone as per section 9.8.2 Recording), unless:
  • [C-SR-1] Is STRONGLY RECOMMENDED to require user consent for every functionality utilizing such data, and be disabled by default.
  • [C-SR-2] STRONGLY RECOMMENDED to apply the same treatment (ie follow the restrictions outlined in 9.8.2 Recording, 9.8.6 OS-level and ambient data, 9.8.15 Sandboxed API implementations, and 9.8.16 Continuous Audio and Camera data) to Camera data coming from a remote wearable device.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-1] (February 26, 2024 preview)

If the Camera data is supplied from a remote wearable device and accessed in an unencrypted form outside Android OS, sandboxed implementation or a sandboxed functionality built by WearableSensingManager , then they:

If device implementations receive Camera or Microphone data from a remote wearable device and the data is accessed in an unencrypted form outside of Android OS, sandboxed implementation or a sandboxed functionality built by WearableSensingManager , they:

Terminar con nuevos requisitos

  • [C-1-1] MUST indicate to the remote wearable device to display an additional indicator there.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-2-1] (February 26, 2024 preview)

If devices provide capability to engage with a Digital Assistant Application without the assigned keyword (either handling generic user queries, or analyzing user presence through camera), they:

Terminar con nuevos requisitos

  • [C-2-1] MUST ensure such implementation is provided by a package holding the android.app.role.ASSISTANT role.
  • [C-2-2] MUST ensure such implementation utilizes HotwordDetectionService and/or VisualQueryDetectionService Android APIs.

9.8.17. Telemetria

Android stores system and app logs using StatsLog APIs. These logs are managed via StatsManager APIs which can be used by privileged system applications.

StatsManager also provides a way to collect data categorized as privacy sensitive from devices with a privacy preserving mechanism. In particular, StatsManager::query API provides the ability to query restricted metric categories defined in StatsLog .

Any implementation querying and collecting restricted metrics from StatsManager:

  • [C-0-1] MUST be the sole application/implementation on the device and hold the READ_RESTRICTED_STATS permission.
  • [C-0-2] MUST only send telemetry data and the log of the device using a privacy-preserving mechanism. The privacy-preserving mechanism is defined as "those which allow only analysis in aggregate and prevent matching of logged events or derived outcomes to individual users", to prevent any per-user data being introspectable (eg, implemented using a differential privacy technology such as RAPPOR ).
  • [C-0-3] MUST NOT associate such data with any user identity (such as Account ) on the device.
  • [C-0-4] MUST NOT share such data with other OS components that don't follow requirements outlined in the current section (9.8.17 Privacy-preserving Telemetry).
  • [C-0-5] MUST provide a user affordance to enable/disable privacy-preserving telemetry collection, use, and sharing.
  • [C-0-6] MUST provide user affordance to erase such data that the implementation collects if the data is stored in any form on the device. If the user chose to erase the data, MUST remove all data currently stored on the device.
  • [C-0-7] MUST disclose underlying privacy-preserving protocol implementation in an open source repository.
  • [C-0-8 ]MUST enforce data egress policies in this section to gate collection of data in restricted metric categories defined in StatsLog .

9.9. Data Storage Encryption

All devices MUST meet the requirements of section 9.9.1. Devices which launched on an API level earlier than that of this document are exempted from the requirements of sections 9.9.2 and 9.9.3; instead they MUST meet the requirements in section 9.9 of the Android Compatibility Definition document corresponding to the API level on which the device launched.

9.9.1. Direct Boot

Device implementations:

  • [C-0-1] MUST implement the Direct Boot mode APIs even if they do not support Storage Encryption.

  • [C-0-2] The ACTION_LOCKED_BOOT_COMPLETED and ACTION_USER_UNLOCKED Intents MUST still be broadcast to signal Direct Boot aware applications that Device Encrypted (DE) and Credential Encrypted (CE) storage locations are available for user.

9.9.2. Requisitos de cifrado

Device implementations:

  • [C-0-1] MUST encrypt the application private data ( /data partition), as well as the application shared storage partition ( /sdcard partition) if it is a permanent, non-removable part of the device.
  • [C-0-2] MUST enable the data storage encryption by default at the time the user has completed the out-of-box setup experience.
  • [C-0-3] MUST meet the above data storage encryption requirement by implementing one of the following two encryption methods:

9.9.3. Métodos de cifrado

If device implementations are encrypted, they:

  • [C-1-1] MUST boot up without challenging the user for credentials and allow Direct Boot aware apps to access to the Device Encrypted (DE) storage after the ACTION_LOCKED_BOOT_COMPLETED message is broadcasted.
  • [C-1-2] MUST only allow access to Credential Encrypted (CE) storage after the user has unlocked the device by supplying their credentials (eg. passcode, pin, pattern or fingerprint) and the ACTION_USER_UNLOCKED message is broadcasted.
  • [C-1-13] MUST NOT offer any method to unlock the CE protected storage without either the user-supplied credentials, a registered escrow key or a resume on reboot implementation meeting the requirements in section 9.9.4 .
  • [C-1-4] MUST use Verified Boot.
9.9.3.1. File Based Encryption with Metadata Encryption

If device implementations use File Based Encryption with Metadata Encryption, they:

  • [C-1-5] MUST encrypt file contents and filesystem metadata using AES-256-XTS or Adiantum. AES-256-XTS refers to the Advanced Encryption Standard with a 256-bit cipher key length, operated in XTS mode; the full length of the key is 512 bits. Adiantum refers to Adiantum-XChaCha12-AES, as specified at https://github.com/google/adiantum. Filesystem metadata is data such as file sizes, ownership, modes, and extended attributes (xattrs).
  • [C-1-6] MUST encrypt file names using AES-256-CBC-CTS, AES-256-HCTR2, or Adiantum.
  • [C-1-12] If the device has Advanced Encryption Standard (AES) instructions (such as ARMv8 Cryptography Extensions on ARM-based devices, or AES-NI on x86-based devices) then the AES-based options above for file name, file contents, and filesystem metadata encryption MUST be used, not Adiantum.
  • [C-1-13] MUST use a cryptographically strong and non-reversible key derivation function (eg HKDF-SHA512) to derive any needed subkeys (eg per-file keys) from the CE and DE keys. "Cryptographically strong and non-reversible" means that the key derivation function has a security strength of at least 256 bits and behaves as a pseudorandom function family over its inputs.
  • [C-1-14] MUST NOT use the same File Based Encryption (FBE) keys or subkeys for different cryptographic purposes (eg for both encryption and key derivation, or for two different encryption algorithms).
  • [C-1-15] MUST ensure that all non-deleted blocks of encrypted file contents on persistent storage were encrypted using combinations of encryption key and initialization vector (IV) that depend on both the file and the offset within the file. In addition, all such combinations MUST be distinct, except where the encryption is done using inline encryption hardware that only supports an IV length of 32 bits.
  • [C-1-16] MUST ensure that all non-deleted encrypted filenames on persistent storage in distinct directories were encrypted using distinct combinations of encryption key and initialization vector (IV).
  • [C-1-17] MUST ensure that all encrypted filesystem metadata blocks on persistent storage were encrypted using distinct combinations of encryption key and initialization vector (IV).

  • Keys protecting CE and DE storage areas and filesystem metadata:

    • [C-1-7] MUST be cryptographically bound to a hardware-backed Keystore. This keystore MUST be bound to Verified Boot and the device's hardware root of trust.
    • [C-1-8] CE keys MUST be bound to a user's lock screen credentials.
    • [C-1-9] CE keys MUST be bound to a default passcode when the user has not specified lock screen credentials.
    • [C-1-10] MUST be unique and distinct, in other words no user's CE or DE key matches any other user's CE or DE keys.
    • [C-1-11] MUST use the mandatorily supported ciphers, key lengths and modes.
    • [C-1-12] MUST be securely erased during bootloader unlock and lock as described here .
  • SHOULD make preinstalled essential apps (eg Alarm, Phone, Messenger) Direct Boot aware.

The upstream Android Open Source project provides a preferred implementation of File Based Encryption based on the Linux kernel "fscrypt" encryption feature, and of Metadata Encryption based on the Linux kernel "dm-default-key" feature.

9.9.3.2. Per-User Block-Level Encryption

If device implementations use per-user block-level encryption, they:

  • [C-1-1] MUST enable multi-user support as described in section 9.5.
  • [C-1-2] MUST provide per-user partitions, either using raw partitions or logical volumes.
  • [C-1-3] MUST use unique and distinct encryption keys per-user for encryption of the underlying block devices.
  • [C-1-4] MUST use AES-256-XTS for block-level encryption of the user partitions.

  • The keys protecting the per-user block-level encrypted devices:

    • [C-1-5] MUST be cryptographically bound to a hardware-backed Keystore. This keystore MUST be bound to Verified Boot and the device's hardware root of trust.
    • [C-1-6] MUST be bound to the corresponding user's lock screen credentials.

Per-user block-level encryption can be implemented using the Linux kernel "dm-crypt" feature over per-user partitions.

9.9.4. Resume on Reboot

Resume on Reboot allows unlocking the CE storage of all apps, including those that do not yet support Direct Boot, after a reboot initiated by an OTA. This feature enables users to receive notifications from installed apps after the reboot.

An implementation of Resume-on-Reboot must continue to ensure that when a device falls into an attacker's hands, it is extremely difficult for that attacker to recover the user's CE-encrypted data, even if the device is powered on, CE storage is unlocked, and the user has unlocked the device after receiving an OTA. For insider attack resistance, we also assume the attacker gains access to broadcast cryptographic signing keys.

Específicamente:

  • [C-0-1] CE storage MUST NOT be readable even for the attacker who physically has the device and then has these capabilities and limitations:

    • Can use the signing key of any vendor or company to sign arbitrary messages.
    • Can cause an OTA to be received by the device.
    • Can modify the operation of any hardware (AP, flash etc) except as detailed below, but such modification involves a delay of at least an hour and a power cycle that destroys RAM contents.
    • Cannot modify the operation of tamper-resistant hardware (eg Titan M).
    • Cannot read the RAM of the live device.
    • Cannot obtain the user's credential (PIN, pattern, password) or otherwise cause it to be entered.

By way of example, a device implementation that implements and complies with all of the descriptions found here will be compliant with [C-0-1].

9.10. Integridad del dispositivo

The following requirements ensure there is transparency to the status of the device integrity. Device implementations:

  • [C-0-1] MUST correctly report through the System API method PersistentDataBlockManager.getFlashLockState() whether their bootloader state permits flashing of the system image.

  • [C-0-2] MUST support Verified Boot for device integrity.

If device implementations are already launched without supporting Verified Boot on an earlier version of Android and cannot add support for this feature with a system software update, they MAY be exempted from the requirement.

El arranque verificado es una característica que garantiza la integridad del software del dispositivo. Si las implementaciones de dispositivos admiten la función,:

  • [C-1-1] MUST declare the platform feature flag android.software.verified_boot .
  • [C-1-2] MUST perform verification on every boot sequence.
  • [C-1-3] MUST start verification from an immutable hardware key that is the root of trust and go all the way up to the system partition.
  • [C-1-4] MUST implement each stage of verification to check the integrity and authenticity of all the bytes in the next stage before executing the code in the next stage.
  • [C-1-5] MUST use verification algorithms as strong as current recommendations from NIST for hashing algorithms (SHA-256) and public key sizes (RSA-2048).
  • [C-1-6] MUST NOT allow boot to complete when system verification fails, unless the user consents to attempt booting anyway, in which case the data from any non-verified storage blocks MUST not be used.
  • [C-1-7] MUST NOT allow verified partitions on the device to be modified unless the user has explicitly unlocked the bootloader.
  • [C-1-8] MUST use tamper-evident storage: for storing whether the bootloader is unlocked. Tamper-evident storage means that the bootloader can detect if the storage has been tampered with from inside Android.
  • [C-1-9] MUST prompt the user, while using the device, and require physical confirmation before allowing a transition from bootloader locked mode to bootloader unlocked mode.
  • [C-1-10] MUST implement rollback protection for partitions used by Android (eg boot, system partitions) and use tamper-evident storage for storing the metadata used for determining the minimum allowable OS version.
  • [C-1-11] MUST securely erase all user data during bootloader unlock and lock, as per '9.12. Data Deletion' (including the userdata partition and any NVRAM spaces).

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-12 through C-1-14] (February 26, 2024 preview)

  • [C-SR-1] If there are multiple discrete chips in the device (eg radio, specialized image processor), the boot process of each of those chips is STRONGLY RECOMMENDED to verify every stage upon booting.

  • [C-1-12] MUST verify every stage upon booting, with the boot process of each of the chips, if there are multiple discrete chips in the device (eg, radio, specialized image processor).

  • [C-1-14] MUST verify the signature at least once per boot for allow listed packages that are listed as require-strict-signature in system config.

Terminar con nuevos requisitos

[C-1-12 through C-1-14] (December 11, 2023 preview)

  • [C-SR-1] If there are multiple discrete chips in the device (eg radio, specialized image processor), the boot process of each of those chips is STRONGLY RECOMMENDED to verify every stage upon booting.

  • [C-1-12] MUST verify every stage upon booting, with the boot process of each of the chips, if there are multiple discrete chips in the device (eg radio, specialized image processor).

  • [C-1-13] MUST verify all immutable partitions loaded during the Android boot sequence, except for the partitions that are not part of standard partitions AND that do not contain privileged apps.

  • [C-1-14] MUST verify the signature at least once per boot for allow listed packages that are listed as require-strict-signature in system config.

Terminar con nuevos requisitos

  • [C-SR-2] Are STRONGLY RECOMMENDED to verify all privileged app APK files with a chain of trust rooted in partitions protected by Verified Boot.
  • [C-SR-3] Are STRONGLY RECOMMENDED to verify any executable artifacts loaded by a privileged app from outside its APK file (such as dynamically loaded code or compiled code) before executing them or STRONGLY RECOMMENDED not to execute them at all.
  • SHOULD implement rollback protection for any component with persistent firmware (eg modem, camera) and SHOULD use tamper-evident storage for storing the metadata used for determining the minimum allowable version.

Comienzan nuevos requisitos para 15 (AOSP experimental)

Note about C-1-8 to C-1-13 (February 26, 2024 preview)

If device implementations are already launched without supporting C-1-8 through C-1-11 on an earlier version of Android and cannot add support for these requirements with a system software update, they MAY be exempted from the requirements.

Terminar con nuevos requisitos

Note about C-1-8 to C-1-13 (November 13, 2023 preview)

If device implementations are already launched without supporting C-1-8 through C-1-11 C-1-13 on an earlier version of Android and cannot add support for these requirements with a system software update, they MAY be exempted from the requirements .

Terminar con nuevos requisitos

The upstream Android Open Source Project provides a preferred implementation of this feature in the external/avb/ repository, which can be integrated into the bootloader used for loading Android.

If device implementations have the ability to verify file content on the per-page basis, then they:

  • [C-2-1] support cryptographically verifying file content without reading the whole file.

  • [C-2-2] MUST NOT allow the read requests on a protected file to succeed when the read content is not verified per [C-2-1] above.

  • [C-2-4] MUST return file checksum in O(1) for enabled files.

If device implementations are already launched without the ability to verify file content against a trusted key on an earlier Android version and can not add support for this feature with a system software update, they MAY be exempted from the requirement. The upstream Android Open Source project provides a preferred implementation of this feature based on the Linux kernel fs-verity feature.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-SR-4], [C-3-1], [C-3-2], and [C-3-3] (February 5, 2024 preview)

Device implementations:

If device implementations support the Android Protected Confirmation API they:

  • [C-3-1] MUST report true for the ConfirmationPrompt.isSupported() API.

  • [C-3-2] MUST ensure that code running in the Android OS including its kernel, malicious or otherwise, cannot generate a positive response without user interaction.

  • [C-3-3] MUST ensure that the user has been able to review and approve the prompted message even in the event that the Android OS, including its kernel, is compromised.

Terminar con nuevos requisitos

9.11. Keys and Credentials

The Android Keystore System allows app developers to store cryptographic keys in a container and use them in cryptographic operations through the KeyChain API or the Keystore API . Device implementations:

  • [C-0-1] MUST allow at least 8,192 keys to be imported or generated.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-0-2] [Reverted] (April 8, 2024 preview)

  • [C-0-2] The lock screen authentication MUST implement a time interval between failed attempts. With n as the failed attempt count, the time interval MUST be at least 30 seconds for 9 < n < 30. For n > 29, the time interval value MUST be at least 30*2^floor((n-30)/10)) seconds or at least 24 hours, whichever is smaller.

Terminar con nuevos requisitos

[C-0-2] (December 11, 2023 preview)

  • [C-0-2] The lock screen authentication MUST implement a time interval between failed attempts. With n as the failed attempt count, the time interval MUST be at least 30 seconds for 9 < n < 30. For n > 29, the time interval value MUST be at least 30*2^floor((n-30)/10)) seconds or at least 24 hours, whichever is smaller for n > 4 the time interval value MUST be at least 60*3^(n-5) seconds. .

Terminar con nuevos requisitos

  • SHOULD not limit the number of keys that can be generated.

When the device implementation supports a secure lock screen, it:

  • [C-1-1] MUST back up the keystore implementation with an isolated execution environment.
  • [C-1-2] MUST have implementations of RSA, AES, ECDSA, ECDH (if IKeyMintDevice is supported), 3DES, and HMAC cryptographic algorithms and MD5, SHA1, and SHA-2 family hash functions to properly support the Android Keystore system's supported algorithms in an area that is securely isolated from the code running on the kernel and above. El aislamiento seguro DEBE bloquear todos los mecanismos potenciales mediante los cuales el código del kernel o del espacio de usuario podría acceder al estado interno del entorno aislado, incluido DMA. El Proyecto de código abierto de Android (AOSP) cumple con este requisito mediante el uso de la implementación Trusty , pero otra solución basada en ARM TrustZone o una implementación segura revisada por terceros de un aislamiento adecuado basado en hipervisor son opciones alternativas.
  • [C-1-3] MUST perform the lock screen authentication in the isolated execution environment and only when successful, allow the authentication-bound keys to be used. Las credenciales de la pantalla de bloqueo DEBEN almacenarse de manera que solo el entorno de ejecución aislado pueda realizar la autenticación de la pantalla de bloqueo. El proyecto de código abierto de Android proporciona la capa de abstracción de hardware Gatekeeper (HAL) y Trusty, que se pueden utilizar para satisfacer este requisito.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-4] (December 11, 2023 preview)

  • [C-1-4] MUST support key attestation where the attestation signing key is protected by secure hardware and signing is performed in secure hardware. The attestation signing keys MUST be shared across large enough number of devices to prevent the keys prevented from being used as permanent device identifiers.

Terminar con nuevos requisitos

Tenga en cuenta que si la implementación de un dispositivo ya se lanzó en una versión anterior de Android, dicho dispositivo está exento del requisito de tener un almacén de claves respaldado por un entorno de ejecución aislado y admitir la atestación de claves, a menos que declare la característica android.hardware.fingerprint que requiere un almacén de claves respaldado por un entorno de ejecución aislado.

  • [C-1-5] MUST allow the user to choose the Sleep timeout for transition from the unlocked to the locked state, with a minimum allowable timeout up to 15 seconds. Automotive devices, that lock the screen whenever the head unit is turned off or the user is switched, MAY NOT have the Sleep timeout configuration.
  • [C-1-6] MUST support IKeymasterDevice 4.0, IKeymasterDevice 4.1, IKeyMintDevice version 1 or IKeyMintDevice version 2.
  • [C-SR-1] Is STRONGLY RECOMMENDED to support IKeyMintDevice version 1.

9.11.1. Secure Lock Screen, Authentication and Virtual Devices

The AOSP implementation follows a tiered authentication model where a knowledge-factory based primary authentication can be backed by either a secondary strong biometric, or by weaker tertiary modalities.

Device implementations:

  • [C-SR-1] Are STRONGLY RECOMMENDED to set only one of the following as the primary authentication method:

    • A numerical PIN
    • An alphanumerical password
    • A swipe pattern on a grid of exactly 3x3 dots

      Note that the above authentication methods are referred as the recommended primary authentication methods in this document.

  • [C-0-1] MUST limit the number of failed primary authentication attempts.

  • [C-SR-5] Are STRONGLY RECOMMENDED to implement an upper bound of 20 failed primary authentication attempts and if users consent and opt-in the feature, perform a "Factory Data Reset" after exceeding the limit of failed primary authentication attempts.

If device implementations set a numerical PIN as the recommended primary authentication method, then:

  • [C-SR-6] A PIN is STRONGLY RECOMMENDED to have at least 6 digits, or equivalently a 20-bit entropy.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-SR-7] [Reverted] (April 8, 2024 preview)

  • [C-SR-7] A PIN of a length less than 6 digits is STRONGLY RECOMMENDED NOT to allow automatic entry without user interaction to avoid revealing the PIN length.

Terminar con nuevos requisitos

[C-14-1] (December 11, 2023 preview)

  • [ C-SR-7 C-14-1 ] A PIN of a length less than 6 digits is STRONGLY RECOMMENDED MUST NOT to allow automatic entry without user interaction to avoid revealing the PIN length.

Terminar con nuevos requisitos

If device implementations add or modify the recommended primary authentication methods and use a new authentication method as a secure way to lock the screen, the new authentication method:

If device implementations add or modify the authentication methods to unlock the lock screen if based on a known secret and use a new authentication method to be treated as a secure way to lock the screen:

  • [C-3-1] The entropy of the shortest allowed length of inputs MUST be greater than 10 bits.
  • [C-3-2] The maximum entropy of all possible inputs MUST be greater than 18 bits.
  • [C-3-3] The new authentication method MUST NOT replace any of the recommended primary authentication methods (ie PIN, pattern, password) implemented and provided in AOSP.
  • [C-3-4] The new authentication method MUST be disabled when the Device Policy Controller (DPC) application has set the password requirements policy via the DevicePolicyManager.setRequiredPasswordComplexity() with a more restrictive complexity constant than PASSWORD_COMPLEXITY_NONE or via the DevicePolicyManager.setPasswordQuality() method with a more restrictive constant than PASSWORD_QUALITY_BIOMETRIC_WEAK .
  • [C-3-5] New authentication methods MUST either fall back to the recommended primary authentication methods (ie PIN, pattern, password) once every 72 hours or less OR clearly disclose to the user that some data will not be backed up in order to preserve the privacy of their data.

If device implementations add or modify the recommended primary authentication methods to unlock the lock screen and use a new authentication method that is based on biometrics to be treated as a secure way to lock the screen, the new method:

  • [C-4-1] MUST meet all requirements described in section 7.3.10 for Class 1 (formerly Convenience ).
  • [C-4-2] MUST have a fall-back mechanism to use one of the recommended primary authentication methods which is based on a known secret.
  • [C-4-3] MUST be disabled and only allow the recommended primary authentication to unlock the screen when the Device Policy Controller (DPC) application has set the keyguard feature policy by calling the method DevicePolicyManager.setKeyguardDisabledFeatures() , with any of the associated biometric flags (ie KEYGUARD_DISABLE_BIOMETRICS , KEYGUARD_DISABLE_FINGERPRINT , KEYGUARD_DISABLE_FACE , or KEYGUARD_DISABLE_IRIS ).

If the biometric authentication methods do not meet the requirements for Class 3 (formerly Strong ) as described in section 7.3.10 :

  • [C-5-1] The methods MUST be disabled if the Device Policy Controller (DPC) application has set the password requirements quality policy via the DevicePolicyManager.setRequiredPasswordComplexity() with a more restrictive complexity bucket than PASSWORD_COMPLEXITY_LOW or using DevicePolicyManager.setPasswordQuality() method with a more restrictive quality constant than PASSWORD_QUALITY_BIOMETRIC_WEAK .
  • [C-5-2] The user MUST be challenged for the recommended primary authentication (eg: PIN, pattern, password) as described in [C-1-7] and [C-1-8] in section 7.3.10 .
  • [C-5-3] The methods MUST NOT be treated as a secure lock screen, and MUST meet the requirements that start with C-8 in this section below.

If device implementations add or modify the authentication methods to unlock the lock screen and a new authentication method is based on a physical token or the location:

  • [C-6-1] They MUST have a fall-back mechanism to use one of the recommended primary authentication methods which is based on a known secret and meet the requirements to be treated as a secure lock screen.
  • [C-6-2] The new method MUST be disabled and only allow one of the recommended primary authentication methods to unlock the screen when the Device Policy Controller (DPC) application has set the policy with either:
  • [C-6-3] The user MUST be challenged for one of the recommended primary authentication methods (egPIN, pattern, password) at least once every 4 hours or less. When a physical token meets the requirements for TrustAgent implementations in CX, timeout restrictions defined in C-9-5 apply instead.
  • [C-6-4] The new method MUST NOT be treated as a secure lock screen and MUST follow the constraints listed in C-8 below.

Si las implementaciones de dispositivos tienen una pantalla de bloqueo segura e incluyen uno o más agentes de confianza, que implementan la API del sistema TrustAgentService , ellos:

  • [C-7-1] MUST have clear indication in the settings menu and on the lock screen when device lock is deferred or can be unlocked by trust agent(s). For example, AOSP meets this requirement by showing a text description for the "Automatically lock setting" and "Power button instantly locks" in the settings menu and a distinguishable icon on the lock screen.
  • [C-7-2] MUST respect and fully implement all trust agent APIs in the DevicePolicyManager class, such as the KEYGUARD_DISABLE_TRUST_AGENTS constant.
  • [C-7-3] MUST NOT fully implement the TrustAgentService.addEscrowToken() function on a device that is used as a primary personal device (eg handheld) but MAY fully implement the function on device implementations that are typically shared (eg Android Television or Automotive device).
  • [C-7-4] MUST encrypt all stored tokens added by TrustAgentService.addEscrowToken() .
  • [C-7-5] MUST NOT store the encryption key or escrow token on the same device where the key is used. For example, it is allowed for a key stored on a phone to unlock a user account on a TV. For Automotive devices, it is not allowed for the escrow token to be stored on any part of the vehicle.
  • [C-7-6] MUST inform the user about the security implications before enabling the escrow token to decrypt the data storage.
  • [C-7-7] MUST have a fall-back mechanism to use one of the recommended primary authentication methods.
  • [C-7-9] The user MUST be challenged for one of the recommended primary authentication (eg: PIN, pattern, password) methods as described in [C-1-7] and [C-1-8] in section 7.3.10 , unless the safety of the user (eg driver distraction) is of concern.
  • [C-7-10] MUST NOT be treated as a secure lock screen and MUST follow the constraints listed in C-8 below.
  • [C-7-11] MUST NOT allow TrustAgents on primary personal devices (eg: handheld) to unlock the device, and can only use them to keep an already unlocked device in the unlocked state for up to a maximum of 4 hours. The default implementation of TrustManagerService in AOSP meets this requirement.
  • [C-7-12] MUST use a cryptographically secure (eg UKEY2) communication channel to pass the escrow token from the storage device to the target device.

If device implementations add or modify the authentication methods to unlock the lock screen that is not a secure lock screen as described above, and use a new authentication method to unlock the keyguard:

If device implementations allow applications to create secondary virtual displays and do not support associated input events, such as via VirtualDeviceManager , they:

  • [C-9-1] MUST lock these secondary virtual display(s) when the device's default display is locked, and unlock these secondary virtual display(s) when the device's default display is unlocked.

If device implementations allow applications to create secondary virtual displays and support associated input events, such as via VirtualDeviceManager , they:

  • [C-10-1] MUST support separate lock states per virtual device
  • [C-10-2] MUST disconnect all virtual devices upon idle timeout
  • [C-10-3] MUST have an idle timeout
  • [C-10-4] MUST lock all displays when the user initiates a lockdown , including via the lockdown user affordance required for handheld devices (see Section 2.2.5[9.11/H-1-2] )
  • [C-10-5] MUST have separate virtual device instances per user

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-10-6] (February 5, 2024 preview)

  • [C-10-6] MUST disable the creation of associated input events via VirtualDeviceManager when indicated by app streaming as indicated by DevicePolicyManager.setNearbyAppStreamingPolicy .

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-10-7] (February 5, 2024 preview)

  • [C-10-7] MUST either:
    • Disable clipboard usage
    • Enable a separate clipboard for each device that supports clipboards

  • [C-10-7] MUST use a separate clipboard solely for each virtual device (or disable the clipboard for virtual devices)

Terminar con nuevos requisitos

  • [C-10-11] MUST disable authentication UI on virtual devices, including knowledge factor entry and biometric prompt

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-10-12] [Removed] (February 5, 2024 preview)

  • [C-10-12] MUST restrict intents initiated from a virtual device to display only on the same virtual device

  • [C-10-12]
    This requirement is removed in Android 15 (AOSP experimental).

Terminar con nuevos requisitos

  • [C-10-13] MUST not use a virtual device lock state as user authentication authorization with the Android Keystore System. See KeyGenParameterSpec.Builder.setUserAuthentication* .

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-10-14 and C-10-15] (February 5, 2024 preview)

  • [C-10-14] MUST provide a user affordance to enable clipboard sharing between devices prior to sharing clipboard data between physical and virtual devices if the device is implementing a shared clipboard.
  • [C-10-15] MUST show notifications when clipboard data is accessed across devices, and MUST make content inaccessible after one minute measured from the initial sharing time.

Terminar con nuevos requisitos

When device implementations allow the user to transfer the primary authentication knowledge-factor from a source device to a target device, such as for initial setup of the target device, they:

  • [C-11-1] MUST encrypt the knowledge-factor with protection guarantees similar to those described in the Google Cloud Key Vault Service security whitepaper when transferring the knowledge-factor from the source device to the target device such that the knowledge-factor cannot be remotely decrypted or used to remotely unlock either device.
  • [C-11-2] MUST, on the source device , ask the user to confirm the knowledge-factor of the source device before transferring the knowledge-factor to the target device.
  • [C-11-3] MUST, on a target device lacking any set primary authentication knowledge-factor, ask the user to confirm a transferred knowledge-factor on the target device before setting that knowledge-factor as the primary authentication knowledge-factor for the target device and before making available any data transferred from a source device.

If device implementations have a secure lock screen and include one or more trust agents, which call the TrustAgentService.grantTrust() System API with the FLAG_GRANT_TRUST_TEMPORARY_AND_RENEWABLE flag they:

  • [C-12-1] MUST only call grantTrust() with the flag when connected to a proximate physical device with a lockscreen of its own, and when the user has authenticated their identity against that lockscreen. Proximate devices can use on-wrist or on-body detection mechanisms after a one-time user unlock to satisfy the user authentication requirement.
  • [C-12-2] MUST put the device implementation into the TrustState.TRUSTABLE state when the screen is turned off (such as via a button press or display time out) and the TrustAgent has not revoked trust. The AOSP satisfies this requirement.
  • [C-12-3] MUST only move the device from TrustState.TRUSTABLE to the TrustState.TRUSTED state if the TrustAgent is still granting trust based on the requirements in C-12-1.
  • [C-12-4] MUST call TrustManagerService.revokeTrust() after a maximum of 24 hours from granting trust, an 8 hour idle window, or when the underlying connection to the proximate physical device is lost.

If device implementations allow applications to create secondary virtual displays and support associated input events such as via VirtualDeviceManager and the displays are not marked with VIRTUAL_DISPLAY_FLAG_SECURE, they:

  • [C-13-8] MUST block activities with the attribute android:canDisplayOnRemoteDevices or the meta-data android.activity.can_display_on_remote_devices set to false from being started on the virtual device.

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-13-9] (February 5, 2024 preview)

  • [C-13-9] MUST block activities which do not explicitly enable streaming and which indicate they show sensitive content, including via SurfaceView#setSecure , and FLAG_SECURE , or SYSTEM_FLAG_HIDE_NON_SYSTEM_OVERLAY_WINDOWS, from being started on the virtual device.

Terminar con nuevos requisitos

If device implementations support separate display power states through DeviceStateManager AND support separate display lock states through KeyguardDisplayManager , they:

  • [C-SR-2] Are STRONGLY RECOMMENDED to utilize a credential meeting requirements defined in section 9.11.1 or a Biometric meeting at least Class 1 specifications defined in section 7.3.10 to allow independent unlocking from the default device display.
  • [C-SR-3] Are STRONGLY RECOMMENDED to constrain separate display unlock via a defined display timeout.
  • [C-SR-4] Are STRONGLY RECOMMENDED to allow user to globally lock all displays through lockdown from primary handheld device.

9.11.2. Caja fuerte

The Android Keystore System allows app developers to store cryptographic keys in a dedicated secure processor as well as the isolated execution environment described above. Such a dedicated secure processor is called "StrongBox". Requirements C-1-3 through C-1-11 below define the requirements a device must meet to qualify as a StrongBox.

Device implementations that have a dedicated secure processor:

  • [C-SR-1] Are STRONGLY RECOMMENDED to support StrongBox. StrongBox will likely become a requirement in a future release.

If device implementations support StrongBox, they:

  • [C-1-1] MUST declare FEATURE_STRONGBOX_KEYSTORE .

  • [C-1-2] MUST provide dedicated secure hardware that is used to back keystore and secure user authentication. The dedicated secure hardware may be used for other purposes as well.

  • [C-1-3] MUST have a discrete CPU that shares no cache, DRAM, coprocessors or other core resources with the application processor (AP).

  • [C-1-4] MUST ensure that any peripherals shared with the AP cannot alter StrongBox processing in any way, or obtain any information from the StrongBox. The AP MAY disable or block access to StrongBox.

  • [C-1-5] MUST have an internal clock with reasonable accuracy (+-10%) that is immune to manipulation by the AP.

  • [C-1-6] MUST have a true random number generator that produces uniformly-distributed and unpredictable output.

  • [C-1-7] MUST have tamper resistance, including resistance against physical penetration, and glitching.

  • [C-1-8] MUST have side-channel resistance, including resistance against leaking information via power, timing, electromagnetic radiation, and thermal radiation side channels.

  • [C-1-9] MUST have secure storage which ensures confidentiality, integrity, authenticity, consistency, and freshness of the contents. The storage MUST NOT be able to be read or altered, except as permitted by the StrongBox APIs.

  • To validate compliance with [C-1-3] through [C-1-9], device implementations:

Comienzan nuevos requisitos para 15 (AOSP experimental)

[C-1-10] (December 11, 2023 preview)

Terminar con nuevos requisitos

  • [C-1-11] MUST include the firmware that is evaluated by a nationally accredited testing laboratory incorporating High attack potential vulnerability assessment according to the Common Criteria Application of Attack Potential to Smartcards .
  • [C-SR-2] Are STRONGLY RECOMMENDED to include the hardware that is evaluated using a Security Target, Evaluation Assurance Level (EAL) 5, augmented by AVA_VAN.5. EAL 5 certification will likely become a requirement in a future release.
  • [C-SR-3] Are STRONGLY RECOMMENDED to provide insider attack resistance (IAR), which means that an insider with access to firmware signing keys cannot produce firmware that causes the StrongBox to leak secrets, to bypass functional security requirements or otherwise enable access to sensitive user data. The recommended way to implement IAR is to allow firmware updates only when the primary user password is provided via the IAuthSecret HAL.

9.11.3. Credencial de identidad

The Identity Credential System is defined and achieved by implementing all APIs in the android.security.identity.* package. These APIs allows app developers to store and retrieve user identity documents. Device implementations:

  • [C-SR-1] are STRONGLY RECOMMENDED to implement the Identity Credential System.

If device implementations implement the Identity Credential System, they:

  • [C-1-1] MUST return non-null for the IdentityCredentialStore#getInstance() method.

  • [C-1-2] MUST implement the Identity Credential System (eg the android.security.identity.* APIs) with code communicating with a trusted application in an area that is securely isolated from the code running on the kernel and above. El aislamiento seguro DEBE bloquear todos los mecanismos potenciales mediante los cuales el código del kernel o del espacio de usuario podría acceder al estado interno del entorno aislado, incluido DMA.

  • [C-1-3] The cryptographic operations needed to implement the Identity Credential System (eg the android.security.identity.* APIs) MUST be performed entirely in the trusted application and private key material MUST never leave the isolated execution environment unless specifically required by higher-level APIs (eg the createEphemeralKeyPair() method).

  • [C-1-4] The trusted application MUST be implemented in a way such that its security properties are not affected (eg credential data is not released unless access control conditions are satisfied, MACs can't be produced for arbitrary data) even if Android is misbehaving or compromised.

The upstream Android Open Source Project provides a reference implementation of a trusted application ( libeic ) that can be used to implement the Identity Credential system.

9.12. Eliminación de datos

All device implementations:

  • [C-0-1] MUST provide users a mechanism to perform a "Factory Data Reset".
  • [C-0-2] MUST delete all data on the userdata filesystem when performing a "Factory Data Reset".
  • [C-0-3] MUST delete the data in such a way that will satisfy relevant industry standards such as NIST SP800-88 when performing a "Factory Data Reset".
  • [C-0-4] MUST trigger the above "Factory Data Reset" process when the DevicePolicyManager.wipeData() API is called by the primary user's Device Policy Controller app.
  • MAY provide a fast data wipe option that conducts only a logical data erase.

9.13. Safe Boot Mode

Android provides Safe Boot Mode, which allows users to boot up into a mode where only preinstalled system apps are allowed to run and all third-party apps are disabled. This mode, known as "Safe Boot Mode", provides the user the capability to uninstall potentially harmful third-party apps.

Device implementations are:

  • [C-SR-1] STRONGLY RECOMMENDED to implement Safe Boot Mode.

If device implementations implement Safe Boot Mode, they:

  • [C-1-1] MUST provide the user an option to enter Safe Boot Mode in such a way that is uninterruptible from third-party apps installed on the device, except when the third-party app is a Device Policy Controller and has set the UserManager.DISALLOW_SAFE_BOOT flag as true.

  • [C-1-2] MUST provide the user the capability to uninstall any third-party apps within Safe Mode.

  • SHOULD provide the user an option to enter Safe Boot Mode from the boot menu using a workflow that is different from that of a normal boot.

9.14. Automotive Vehicle System Isolation

Android Automotive devices are expected to exchange data with critical vehicle subsystems by using the vehicle HAL to send and receive messages over vehicle networks such as CAN bus.

The data exchange can be secured by implementing security features below the Android framework layers to prevent malicious or unintentional interaction with these subsystems.

9.15. Planes de suscripción

"Subscription plans" refer to the billing relationship plan details provided by a mobile carrier through SubscriptionManager.setSubscriptionPlans() .

All device implementations:

  • [C-0-1] MUST return subscription plans only to the mobile carrier app that has originally provided them.
  • [C-0-2] MUST NOT remotely back up or upload subscription plans.
  • [C-0-3] MUST only allow overrides, such as SubscriptionManager.setSubscriptionOverrideCongested() , from the mobile carrier app currently providing valid subscription plans.

9.16. Application Data Migration

If device implementations include a capability to migrate data from a device to another device and do not limit the application data it copies to what is configured by the application developer in the manifest via android:fullBackupContent attribute, they:

  • [C-1-1] MUST NOT initiate transfers of application data from devices on which the user has not set a primary authentication as described in 9.11.1 Secure Lock Screen and Authentication .
  • [C-1-2] MUST securely confirm the primary authentication on the source device and confirm with the user intent to copy the data on the source device before any data is transferred.
  • [C-1-3] MUST use security key attestation to ensure that both the source device and the target device in the device-to-device migration are legitimate Android devices and have a locked bootloader.
  • [C-1-4] MUST only migrate application data to the same application on the target device, with the same package name AND signing certificate.
  • [C-1-5] MUST show an indication that the source device has had data migrated by a device-to-device data migration in the settings menu. A user SHOULD NOT be able to remove this indication.

Comienzan nuevos requisitos para 15 (AOSP experimental)

9.17. Android Virtualization Framework

[9.17] (February 26, 2024 preview)

The Android Virtualization Framework (AVF) APIs ( android.system.virtualmachine.* ) allows applications to create on-device virtual machines (VMs) that load and run native binaries as payloads.

If device implementations set FEATURE_VIRTUALIZATION_FRAMEWORK to true , they:

  • [C-1-6] MUST ensure that android.system.virtualmachine.VirtualMachineManager.getCapabilities() returns at least one of:
    • CAPABILITY_PROTECTED_VM
    • CAPABILITY_NON_PROTECTED_VM

Terminar con nuevos requisitos

[9.17] (December 11, 2023 preview)

The Android Virtualization Framework (AVF) APIs ( android.system.virtualmachine.* ) support both Protected Virtual Machines (pVMs) and Non-Protected Virtual Machines (non-pVMs) according to the following system properties:

If ro.boot.hypervisor.vm.supported is set to true then non-pVMs are supported.

If ro.boot.hypervisor.protected_vm.supported is set to true then pVMs are supported.

Device implementations:

  • [C-0-1] MUST support the Android Virtualization Framework APIs ( android.system.virtualmachine.* ) for pVMs, non-pVMs and the existence of both.

If the device implements support for the Android Virtualization Framework APIs ( android.system.virtualmachine.* ), The Android host:

  • [C-1-1] MUST support all the APIs defined by the android.system.virtualmachine package.

  • [C- 1-2 0-2 ] MUST NOT modify the Android SELinux and permission model for the management of Protected Virtual Machines( pVM both pVMs and non-pVMs ).
  • [C- 1-4 0-4 ] MUST only allow platform signed code & privileged apps pre-installed in read-only partition to create and run a pVM virtual machines . Note: This might change in future Android releases.
  • [C- 1-5 0-5 ] MUST only allow a non-debuggable pVM to execute code from the factory image or their platform updates which also includes any updates to privileged pre-installed apps.

If the device implements support for the Android Virtualization Framework APIs ( android.system.virtualmachine.* ), then Any pVM instance:

  • [C- 2-1 0-6 ] MUST be able to run all operating systems available in the virtualization APEX in a pVM.
  • [C- 2-2 0-7 ] MUST NOT allow a pVM to run an operating system that is not signed by the device implementor or OS vendor.
  • [C- 2-3 0-8 ] MUST NOT allow a pVM to execute data as code (eg SELinux neverallow execmem).
  • [C- 2-5 0-9 ] MUST implement pVM defense-in-depth mechanisms (eg SELinux for pVMs) even for non-Microdroid operating systems.
  • [C- 2-6 0-10 ] MUST ensure that the pVM fails to boot if images that the VM will run cannot be verified. The verification MUST be done inside the VM.
  • [C- 2-7 0-11 ] MUST ensure that the pVM fails to boot if the integrity of the instance.img is compromised.

If the device implements support for the Android Virtualization Framework APIs ( android.system.virtualmachine.* ), then The hypervisor:

  • [C- 3-1 0-12 ] MUST ensure that memory pages exclusively owned by a VM (either pVM or host VM guest or host pVM) or the hypervisor are accessible only to the virtual machine itself or the hypervisor, not by other virtual machines - either protected or non-protected.
  • [C- 3-2 0-13 ] MUST wipe a page after it is used by a pVM and before it is returned to the host (eg the pVM is destroyed).
  • [C- SR-1 0-14 ] Is STRONGLY RECOMMENDED to MUST ensure that that the pVM firmware is loaded and executed prior to any code in a pVM.
  • [C- 3-4 0-15 ] MUST ensure that each VM pVM derives a per-VM secret which means that (Boot Certificate Chain) (BCC) and Compound Device Identifier (CDIs) provided to a pVM instance can only be derived by that particular VM pVM instance and changes upon factory reset and OTA.

If the device implements support for the Android Virtualization Framework APIs, then across all areas:

  • [C-4-1] MUST NOT provide functionality to a pVM that allows bypassing the Android Security Model.

If the device implements support for the Android Virtualization Framework APIs, then:

  • [C-5-1] MUST be capable to support Isolated Compilation but may disable Isolated Compilation feature on the device shipment.

If the device implements support for the Android Virtualization Framework APIs, then for Key Management:

  • [C-SR-2] Is STRONGLY RECOMMENDED to use DICE as the per-VM secret derivation mechanism.

  • [C-0-16] MUST implement rollback protection for partitions used by protected VM (eg, boot, pVM firmware), either by using tamper-evident storage for storing the metadata used for determining the minimum allowable partition version or by including the security version of the partition in the respective DICE or equivalent certificate.

Terminar con nuevos requisitos

Comienzan nuevos requisitos para 15 (AOSP experimental)

9.18. Restricted Settings

[9.18] (December 11, 2023 preview)

Device implementations:

[C-0-1] MUST implement and enable support for Restricted Settings mode. Restricted Settings apply to all apps that are side-loaded and that declare the need for certain "restricted permissions". "Restricted permissions" are not necessarily permissions, but roles and other capabilities that are considered security sensitive. Specifically, the in-scope "permissions" for Restricted Settings are:

  • Accesibilidad
  • Oyente de notificaciones
  • Default Apps (Home, Phone, SMS)
  • Device Admin Apps
  • Display Over Other Apps
  • Usage Access
  • Media Projection
  • SMS
  • Llamar

An app is identified as side-loaded if it is installed from a downloaded or local file .

Terminar con nuevos requisitos

10. Software Compatibility Testing

Device implementations MUST pass all tests described in this section. However, note that no software test package is fully comprehensive. For this reason, device implementers are STRONGLY RECOMMENDED to make the minimum number of changes as possible to the reference and preferred implementation of Android available from the Android Open Source Project. This will minimize the risk of introducing bugs that create incompatibilities requiring rework and potential device updates.

10.1. Compatibility Test Suite

Device implementations:

  • [C-0-1] MUST pass the Android Compatibility Test Suite (CTS) available from the Android Open Source Project, using the final shipping software on the device.

  • [C-0-2] MUST ensure compatibility in cases of ambiguity in CTS and for any reimplementations of parts of the reference source code.

The CTS is designed to be run on an actual device. Like any software, the CTS may itself contain bugs. The CTS will be versioned independently of this Compatibility Definition, and multiple revisions of the CTS may be released for Android 15.

Device implementations:

  • [C-0-3] MUST pass the latest CTS version available at the time the device software is completed.

  • SHOULD use the reference implementation in the Android Open Source tree as much as possible.

10.2. CTS Verifier

The CTS Verifier is included with the Compatibility Test Suite, and is intended to be run by a human operator to test functionality that cannot be tested by an automated system, such as correct functioning of a camera and sensors.

Device implementations:

  • [C-0-1] MUST correctly execute all applicable cases in the CTS verifier.

The CTS Verifier has tests for many kinds of hardware, including some hardware that is optional.

Device implementations:

  • [C-0-2] MUST pass all tests for hardware that they possess; for instance, if a device possesses an accelerometer, it MUST correctly execute the Accelerometer test case in the CTS Verifier.

Test cases for features noted as optional by this Compatibility Definition Document MAY be skipped or omitted.

  • [C-0-2] Every device and every build MUST correctly run the CTS Verifier, as noted above. However, since many builds are very similar, device implementers are not expected to explicitly run the CTS Verifier on builds that differ only in trivial ways. Specifically, device implementations that differ from an implementation that has passed the CTS Verifier only by the set of included locales, branding, etc. MAY omit the CTS Verifier test.

11. Updatable Software

  • [C-0-1] Device implementations MUST include a mechanism to replace the entirety of the system software. The mechanism need not perform "live" upgrades—that is, a device restart MAY be required. Any method can be used, provided that it can replace the entirety of the software preinstalled on the device. For instance, any of the following approaches will satisfy this requirement:

    • "Over-the-air (OTA)" downloads with offline update via reboot.
    • "Tethered" updates over USB from a host PC.
    • "Offline" updates via a reboot and update from a file on removable storage.
  • [C-0-2] The update mechanism used MUST support updates without wiping user data. That is, the update mechanism MUST preserve application private data and application shared data. Note that the upstream Android software includes an update mechanism that satisfies this requirement.

  • [C-0-3] The entire update MUST be signed and the on-device update mechanism MUST verify the update and signature against a public key stored on device.

  • [C-SR-1] The signing mechanism is STRONGLY RECOMMENDED to hash the update with SHA-256 and validate the hash against the public key using ECDSA NIST P-256.

If the device implementations includes support for an unmetered data connection such as 802.11 or Bluetooth PAN (Personal Area Network) profile, then, they:

  • [C-1-1] MUST support OTA downloads with offline update via reboot.

Device implementations SHOULD verify that the system image is binary identical to the expected result following an OTA. The block-based OTA implementation in the upstream Android Open Source Project, added since Android 5.1, satisfies this requirement.

Also, device implementations SHOULD support A/B system updates . The AOSP implements this feature using the boot control HAL.

If an error is found in a device implementation after it has been released but within its reasonable product lifetime that is determined in consultation with the Android Compatibility Team to affect the compatibility of third-party applications, then:

  • [C-2-1] The device implementer MUST correct the error via a software update available that can be applied per the mechanism just described.

Android includes features that allow the Device Owner app (if present) to control the installation of system updates. If the system update subsystem for devices report android.software.device_admin then, they:

12. Document Changelog

For a summary of changes to the Compatibility Definition in this release:

13. Contáctenos

You can join the android-compatibility forum and ask for clarifications or bring up any issues that you think the document does not cover.