APEX File Format

Android Pony EXpress (APEX) is a container format introduced in Android Q that is used in the install flow for lower-level system modules. This format facilitates the updates of system components that don't fit into the standard Android application model. Some example components are native services and libraries, hardware abstraction layers (HALs), runtime (ART), and class libraries.

The term "APEX" can also refer to an APEX file.

This document describes technical details of the APEX file format. If you are looking at how to build an APEX package, kindly refer to this how-to document.

Background

Although Android supports updates of modules that fit within the standard app model (for example, services, activities) via package installer apps (such as the Google Play Store app), using a similar model for lower-level OS components has the following drawbacks:

• APK-based modules can't be used early in the boot sequence. The package manager is the central repository of information about apps and can only be started from the activity manager, which becomes ready in a later stage of the boot procedure.
• The APK format (particularly the manifest) is designed for Android apps and system modules aren't always a good fit.

Design

This section describes the high-level design of the APEX file format and the APEX manager, which is a service that manages APEX files.

APEX format {#apex-format}

This is the format of an APEX file.

Figure 1. APEX file format

At the top level, an APEX file is a zip file in which files are stored uncompressed and located at 4 KB boundaries.

The four files in an APEX file are:

• apex_manifest.json
• AndroidManifest.xml
• apex_payload.img
• apex_pubkey

The apex_manifest.json file contains the package name and version, which identify an APEX file.

The AndroidManifest.xml file allows the APEX file to use APK-related tools and infrastructure such as ADB, PackageManager, and package installer apps (such as Play Store). For example, the APEX file can use an existing tool such as aapt to inspect basic metadata from the file. The file contains package name and version information. This information is generally also available in apex_manifest.json. AndroidManifest.xml might contain additional targeting information that can be used by the existing app publishing tools.

apex_manifest.json is recommended over AndroidManifest.xml for new code and systems that deal with APEX.

apex_payload.img is an ext4 file system image backed by dm-verity. The image is mounted at runtime via a loop device. Specifically, the hash tree and metadata block are created using libavb. The file system payload isn't parsed (because the image should be mountable in place). Regular files are included inside the apex_payload.img file.

apex_pubkey is the public key used to sign the file system image. At runtime, this key ensures that the downloaded APEX is signed with the same entity that signs the same APEX in the built-in partitions.

APEX manager

The APEX manager (or apexd) is a native daemon responsible for verifying, installing, and uninstalling APEX files. This process is launched and is ready early in the boot sequence. APEX files are normally pre-installed on the device under /system/apex. The APEX manager defaults to using these packages if no updates are available.

The update sequence of an APEX uses the PackageManager class and is as follows.

1. An APEX file is downloaded via a package installer app, ADB, or other source.

2. The package manager starts the installation procedure. Upon recognizing that the file is an APEX, the package manager transfers control to the APEX manager.

3. The APEX manager verifies the APEX file.

4. If the APEX file is verified, the internal database of the APEX manager is updated to reflect that the APEX file will be activated at next boot.

5. The requestor of the install receives a broadcast upon successful verification of the package.

6. To continue the installation, the system automatically reboots the device.

7. At reboot, the APEX manager starts, reads the internal database, and does the following for each APEX file listed:

   1. Verifies the APEX file.
   2. Creates a loop device from the APEX file.
   3. Creates a device mapper block device on top of the loop device.
   4. Mounts the device mapper block device onto a unique path (for example, /apex/name@ver).

When all APEX files listed in the internal database are mounted, the APEX manager provides a binder service for other system components to query information about the installed APEX files. For example, the other system components can query the list of APEX files installed in the device or query the exact path where a specific APEX is mounted, so the files can be accessed.

APEX files are APK files

APEX files are valid APK files because they are signed zip archives (using the APK signature scheme) containing an AndroidManifest.xml file. This allows APEX files to use the infrastructure for APK files, such as a package installer app, the signing utility, and the package manager.

The AndroidManifest.xml file inside an APEX file is minimal, consisting of the package name, versionCode, and optional targetSdkVersion, minSdkVersion, and maxSdkVersion for fine-grained targeting. This information allows APEX files to be delivered via existing channels such as package installer apps and ADB.

File types supported

The APEX format supports these file types:

• Native shared libs
• Native executables
• JAR files
• Data files
• Config files

The APEX format can only update some of these file types. Whether a file type can be updated depends on the platform and how stable the interfaces for the files types are defined.

Signing

APEX files are signed in two ways. First, the apex_payload.img (specifically, the vbmeta descriptor appended to apex_payload.img) file is signed with a key. Then, the entire APEX is signed using the APK signature scheme v3. Two different keys are used in this process.

On the device side, a public key corresponding to the private key used to sign the vbmeta descriptor is installed. The APEX manager uses the public key to verify APEXs that are requested to be installed. Each APEX must be signed with different keys and is enforced both at build time and runtime.

APEX in built-in partitions

APEX files can be located in built-in partitions such as /system. The partition is already over dm-verity, so the APEX files are mounted directly over the loop device.

If an APEX is present in a built-in partition, the APEX can be updated by providing an APEX package with the same package name and a higher version code. The new APEX is stored in /data and, similar to APKs, the newer version shadows the version already present in the built-in partition. But unlike APKs, the newer version of the APEX is only activated after reboot.

Kernel requirements

To support APEX mainline modules on an Android device, the following Linux kernel features are required: the loop driver and dm-verity. The loop driver mounts the file system image in an APEX module and dm-verity verifies the APEX module.

The performance of the loop driver and dm-verity is important in achieving good system performance when using APEX modules.

Supported kernel versions

APEX mainline modules are supported on devices using kernel versions 4.4 or higher. New devices launching with Android Q or higher must use kernel version 4.9 or higher to support APEX modules.

Required kernel patches

The required kernel patches for supporting APEX modules are included in the Android common tree. To get the patches to support APEX, use the latest version of the Android common tree.

Kernel version 4.4

This version is only supported for devices that are upgraded from Android 9 to Android Q and want to support APEX modules. To get the required patches, a down-merge from the android-4.4 branch is strongly recommended. The following is a list of the required individual patches for kernel version 4.4.

• UPSTREAM: loop: add ioctl for changing logical block size (4.4{: .external})
• BACKPORT: block/loop: set hw_sectors (4.4{: .external})
• UPSTREAM: loop: Add LOOP_SET_BLOCK_SIZE in compat ioctl (4.4{: .external})
• ANDROID: mnt: Fix next_descendent (4.4{: .external})
• ANDROID: mnt: remount should propagate to slaves of slaves (4.4{: .external})
• ANDROID: mnt: Propagate remount correctly (4.4{: .external})
• Revert "ANDROID: dm verity: add minimum prefetch size" (4.4{: .external})
• UPSTREAM: loop: drop caches if offset or block_size are changed (4.4{: .external})

Kernel versions 4.9/4.14/4.19

To get the required patches for kernel versions 4.9/4.14/4.19, down-merge from the android-common branch.

Required kernel configuration options

The following list shows the base configuration requirements for supporting APEX modules that were introduced in Android Q. The items with an asterisk (*) are existing requirements from Android 9 and lower.

(*) CONFIG_AIO=Y # AIO support (for direct I/O on loop devices)
CONFIG_BLK_DEV_LOOP=Y # for loop device support
CONFIG_BLK_DEV_LOOP_MIN_COUNT=16 # pre-create 16 loop devices
(*) CONFIG_CRYPTO_SHA1=Y # SHA1 hash for DM-verity
(*) CONFIG_CRYPTO_SHA256=Y # SHA256 hash for DM-verity
CONFIG_DM_VERITY=Y # DM-verity support

Kernel command line parameter requirements

To support APEX, make sure the kernel command line parameters meet the following requirements.

• loop.max_loop must NOT be set
• loop.max_part must be <= 7

Building an APEX

Note: Because the implementation details for APEX are still under development, the content in this section is subject to change.

This section describes how to build an APEX using the Android build system. The following is an example of Android.bp for an APEX named apex.test.

apex {
    name: "apex.test",
    manifest: "apex_manifest.json",
    file_contexts: "file_contexts",
    // libc.so and libcutils.so are included in the apex
    native_shared_libs: ["libc", "libcutils"],
    binaries: ["vold"],
    java_libs: ["core-all"],
    prebuilts: ["my_prebuilt"],
    compile_multilib: "both",
    key: "apex.test.key",
    certificate: "platform",
}

apex_manifest.json example:

{
  "name": "com.android.example.apex",
  "version": 1
}

file_contexts example:

(/.*)?           u:object_r:system_file:s0
/sub(/.*)?       u:object_r:sub_file:s0
/sub/file3       u:object_r:file3_file:s0

File types and locations in APEX

File type	Location in APEX
Shared libraries	/lib and /lib64 (/lib/arm for translated arm in x86)
Executables	/bin
Java libraries	/javalib
Prebuilts	/etc

Transitive dependencies

APEX files automatically include transitive dependencies of native shared libs or executables. For example, if libFoo depends on libBar, the two libs are included when only libFoo is listed in the native_shared_libs property.

Handling multiple ABIs

Install the native_shared_libs property for both primary and secondary application binary interfaces (ABIs) of the device. If an APEX targets devices with a single ABI (that is, 32 bit only or 64 bit only), only libraries with the corresponding ABI are installed.

Install the binaries property only for the primary ABI of the device as described below:

• If the device is 32 bit only, only the 32-bit variant of the binary is installed.
• If the device supports both 32/64 ABIs, but with TARGET_PREFER_32_BIT_EXECUTABLES=true, then only the 32-bit variant of the binary is installed.
• If the device is 64 bit only, then only the 64-bit variant of the binary is installed.
• If the device supports both 32/64 ABIs, but without TARGET_PREFER_32_BIT_EXECUTABLES=true, then only the 64-bit variant of the binary is installed.

To add fine-grained control over the ABIs of the native libraries and binaries, use the multilib.[first|lib32|lib64|prefer32|both].[native_shared_libs|binaries] properties.

• first: Matches the primary ABI of the device. This is the default for binaries.
• lib32: Matches the 32-bit ABI of the device, if supported.
• lib64: Matches the 64-bit ABI of the device, it supported.
• prefer32: Matches the 32-bit ABI of the device, if supported. If the 32-bit ABI isn't supported, matches the 64-bit ABI.
• both: Matches both ABIs. This is the default for native_shared_libraries.

The java, libraries, and prebuilts properties are ABI-agnostic.

This example is for a device that supports 32/64 and doesn't prefer 32:

apex {
    // other properties are omitted
    native_shared_libs: ["libFoo"], // installed for 32 and 64
    binaries: ["exec1"], // installed for 64, but not for 32
    multilib: {
        first: {
            native_shared_libs: ["libBar"], // installed for 64, but not for 32
            binaries: ["exec2"], // same as binaries without multilib.first
        },
        both: {
            native_shared_libs: ["libBaz"], // same as native_shared_libs without multilib
            binaries: ["exec3"], // installed for 32 and 64
        },
        prefer32: {
            native_shared_libs: ["libX"], // installed for 32, but not for 64
        },
        lib64: {
            native_shared_libs: ["libY"], // installed for 64, but not for 32
        },
    },
}

vbmeta signing

Sign each APEX with different keys. When a new key is required, create a public-private key pair and make an apex_key module. Use the key property to sign the APEX using the key. The public key is automatically included in the APEX with the name avb_pubkey.

Create an rsa key pair.

$ openssl genrsa -out foo.pem 4096

Extract the public key from the key pair.

$ avbtool extract_public_key --key foo.pem --output foo.avbpubkey

In Android.bp:

apex_key {
    name: "apex.test.key",
    public_key: "foo.avbpubkey",
    private_key: "foo.pem",
}

In the above example, the name of the public key (foo) becomes the ID of the key. The ID of the key used to sign an APEX is written in the APEX. At runtime, apexd verifies the APEX using a public key with the same ID in the device.

ZIP signing

Sign APEXs in the same way as APKs. Sign APEXs twice, once for the mini file system (apex_payload.img file) and once for the entire file.

To sign an APEX at the file-level, set the certificate property in one of these three ways:

• Not set: If no value is set, the APEX is signed with the certificate located at PRODUCT_DEFAULT_DEV_CERTIFICATE. If no flag is set, the path defaults to build/target/product/security/testkey.
• <name>: The APEX is signed with the <name> certificate in the same directory as PRODUCT_DEFAULT_DEV_CERTIFICATE.
• :<name>: The APEX is signed with the certificate that is defined by the Soong module named <name>. The certificate module can be defined as follows.

android_app_certificate {
    name: "my_key_name",
    certificate: "dir/cert",
    // this will use dir/cert.x509.pem (the cert) and dir/cert.pk8 (the private key)
}

Note: The key and certificate values do NOT need to be derived from the same public/private key pairs. APK signing (specified by certificate) is required because an APEX is an APK.

Installing an APEX

To install an APEX, use ADB.

$ adb install apex_file_name
$ adb reboot

Using an APEX

After reboot, the APEX is mounted at the /apex/<apex_name>@<version> directory. Multiple versions of the same APEX can be mounted at the same time. Among the mount paths, the one that corresponds to the latest version is bind-mounted at /apex/<apex_name>.

Clients can use the bind-mounted path to read or execute files from APEX.

APEXs are typically used as follows:

1. An OEM or ODM preloads an APEX under /system/apex when the device is shipped.
2. Files in the APEX are accessed via the /apex/<apex_name>/ path.
3. When an updated version of the APEX is installed in /data/apex, the path points to the new APEX after reboot.

Updating a service with an APEX

To update a service using an APEX:

1. Mark the service in the system partition as updatable. Add the option updatable to the service definition.

   /system/etc/init/myservice.rc:
   
   service myservice /system/bin/myservice
       class core
       user system
       ...
       updatable
   

2. Create a new .rc file for the updated service. Use the override option to redefine the existing service.

   /apex/my.apex@1/etc/init.rc:
   
   service myservice /apex/my.apex@1/bin/myservice
       class core
       user system
       ...
       override
   

Service definitions can only be defined in the .rc file of an APEX. Action triggers aren't supported in APEXs.

If a service marked as updatable starts before the APEXs are activated, the start is delayed until the activation of the APEXs is complete.

Configuring system to support APEX updates

Inherit updatable_apex.mk.

<device.mk>:

$(call inherit-product, $(SRC_TARGET_DIR)/product/updatable_apex.mk)

Compressed apexes {#compressed-apex}

APEX compression is a new feature introduced in Android S. Its main purpose is to reduce the storage impact of updatable APEX packages: after an update to an APEX is installed, its pre-installed version is not used anymore, and space that is taken by it effectively becomes a dead weight.

APEX compression minimizes the storage impact by using a highly-compressed set of APEX files on read-only partitions (e.g. /system). In Android S a DEFLATE zip compression is used.

Note: compression doesn't provide any optimization in the following scenarios:

• Bootstrap apexes that are required to be mounted very early in the boot sequence. List of bootstrap apexes is configured in kBootstrapApexes constant in system/apex/apexd/apexd.cpp.
• Non-updatable apexes. Compression is only beneficial in case an updated version of an apex is installed on /data partition. Full list of updatable apexes is available at https://source.android.com/devices/architecture/modular-system.
• Dynamic shared libs apexes. Since apexd will always activate both versions of such apexes (pre-installed and upgraded), compressing them doesn't provide any value.

Compressed APEX file format

This is the format of a compressed APEX file.

Figure 2. Compressed APEX file format

At the top level, a compressed APEX file is a zip file containing the original apex in deflated form with compression level of 9 and other files stored uncompressed.

The four files in an APEX file are:

• original_apex: deflated with compression level of 9
• apex_manifest.pb: stored only
• AndroidManifest.xml: stored only
• apex_pubkey: stored only

original_apex is the original uncompressed APEX file.

apex_manifest.pb AndroidManifest.xml apex_pubkey are copies of the corresponding files from original_apex.

Building compressed apex

Compressed apex can be built using apex_compression_tool.py located at system/apex/tools.

Note: the outer apk container of the produced compressed apex file won't be automatically signed. You will need to manually sign it with using the correct certificate. See Signing Builds for Release.

There are a few different parameters related to APEX compression available in the build system.

In Android.bp whether an apex is compressible is controlled by compressible property:

apex {
    name: "apex.test",
    manifest: "apex_manifest.json",
    file_contexts: "file_contexts",
    compressible: true,
}

Note: this only serves as a hint to build system that this apex can be compressed. Such property is required due to the fact that not all apexes are compressible as mentioned in the section above.

TODO(b/183208430): add docs on how this works for prebuilts.

A PRODUCT_COMPRESSED_APEX product flag is used to control whether a system image built from source should contain compressed apexes or not.

For local experimentation you can force a build to compress apexes by setting OVERRIDE_PRODUCT_COMPRESSED_APEX=true.

Compressed APEX files generated by the build system will have .capex extension. It makes it easier to distinguish between compressed and uncompressed versions of an APEX.

Supported compression algorithms

Android S only supports deflate zip compression.

Activating compressed apex during boot

Before activating a compressed APEX, original_apex inside it will be decompressed into /data/apex/decompressed directory. The resulting decompressed APEX will be hard linked to the /data/apex/active directory.

Note: because of the hard link step above, it's important that files under /data/apex/decompressed have the same SELinux label as files under /data/apex/active.

Consider following example as an illustration of the process described above.

Let's assume that /system/apex/com.android.foo.capex is a compressed APEX being activated, and it's versionCode is 37.

1. First original_apex inside /system/apex/com.android.foo.capex is decompressed into /data/apex/decompressed/[email protected].
2. After that restorecon /data/apex/decompressed/[email protected] is performed to make sure that it has a correct SELinux label.
3. Verification checks are performed on /data/apex/decompressed/[email protected] to ensure it's validity:
   • apexd checks that public key bundled in /data/apex/decompressed/[email protected] is equal to the one bundled in /system/apex/com.android.foo.capex
4. Next /data/apex/decompressed/[email protected] is hard linked to /data/apex/active/[email protected].
5. Finally, regular activation logic for uncompressed APEX files is performed for /data/apex/active/[email protected].

For more information see implementation of OnStart function in system/apex/apexd/apexd.cpp.

Interaction with OTA

Compressed APEX files have some implications on the OTA delivery and application. Since an OTA might contain a compressed APEX file with higher version compared to what is currently active on the device, some free space must be reserved before rebooting a device to apply an OTA.

To help OTA system, two new binder APIs are exposed by apexd:

• calculateSizeForCompressedApex - calculates size required for decompressing APEX files in OTA package. It can be used to check if device has enough space before downloading an OTA.
• reserveSpaceForCompressedApex - reserves space on the disk that in the future will be used by apexd for decompression of compressed APEX files inside the OTA package.

In case of A/B OTA, apexd will attempt decompression in the background as part of the postinstall OTA routine. If decompression fails, apexd will fallback to decompressing during the boot that applies the OTA.

Alternatives considered when developing APEX

Here are some options that we considered when designing the APEX file format, and why we included or excluded them.

Regular package management systems

Linux distributions have package management systems like dpkg and rpm, which are powerful, mature and robust. However, they weren't adopted for APEX because they can't protect the packages after installation. Verification is done only when packages are being installed. Attackers can break the integrity of the installed packages unnoticed. This is a regression for Android where all system components were stored in read-only file systems whose integrity is protected by dm-verity for every I/O. Any tampering to system components must be prohibited, or be detectable so that the device can refuse to boot if compromised.

dm-crypt for integrity

The files in an APEX container are from built-in partitions (for example, the /system partition) that are protected by dm-verity, where any modification to the files are prohibited even after the partitions are mounted. To provide the same level of security to the files, all files in an APEX are stored in a file system image that is paired with a hash tree and a vbmeta descriptor. Without dm-verity, an APEX in the /data partition is vulnerable to unintended modifications made after it's verified and installed.

In fact, the /data partition is also protected by encryption layers such as dm-crypt. Although this provides some level of protection against tampering, its primary purpose is privacy, not integrity. When an attacker gains access to the /data partition, there can be no further protection, and this again is a regression compared to every system component being in the /system partition. The hash tree inside an APEX file together with dm-verity provides the same level of content protection.

Redirecting paths from /system to /apex

System component files packaged in an APEX are accessible via new paths like /apex/<name>/lib/libfoo.so. When the files were part of the /system partition, they were accessible via paths such as /system/lib/libfoo.so. A client of an APEX file (other APEX files or the platform) should use the new paths. This change in paths might require updates to the existing code.

One way to avoid the path change is to overlay the file contents in an APEX file over the /system partition. However, we decided not to overlay files over the /system partition because we believed this would negatively affect performance as the number of files being overlayed (possibly even stacked one after another) increases.

Another option was to hijack file access functions such as open, stat, and readlink, so that paths that start with /system are redirected to their corresponding paths under /apex. We discarded this option because it's practically infeasible to change all functions that accept paths. For example, some apps statically link Bionic, which implements the functions. In that case, the redirection won't happen for the app.