EmbeddedPkg AndroidFastBoot - lersek/edk2 GitHub Wiki
Fastboot is a protocol designed as a mechanism to update Android platforms. This page describes an implementation of the device-side as part of UEFI. You can use it to download and flash images onto a target's storage, or to download and boot Linux kernels.
Android FastBoot support in UEFI has been added into SVN rev15317 (2014-03-05). The protocol is documented in the Android source tree in `system/core/fastboot/fastboot_protocol.txt`: https://android.googlesource.com/platform/system/core/+/master/fastboot/fastboot_protocol.txt
The Android FastBoot host tool is available from the Android ADT (Android Developer Tools) at http://developer.android.com/sdk/index.html
1. Build UEFI for Versatile Express TC2. See build instructions in this wiki page
2. Copy UEFI FastBoot Application into NOR Flash
cp Build/ArmVExpress-CTA15-A7/DEBUG_GCC48/ARM/AndroidFastbootApp.efi /media/ELBA/SOFTWARE/FastBoot.efi
3. Add FastBoot.efi to your /SITE1/HBI0249A/images.txt. Example:
(...) NOR6UPDATE: AUTO ;IMAGE UPDATE:NONE/AUTO/FORCE NOR6ADDRESS: 00000000 ;Image Flash Address NOR6NAME: fastboot.efi ;Image Flash Name NOR6FILE: \SOFTWARE\fastboot.efi ;Image File Name NOR6LOAD: 00000000 ;Image Load Address NOR6ENTRY: 00000000 ;Image Entry Point
On ARM Versatile Express, we assume the SD card would contain the Android Partitions that would be exposed by the Android FastBoot protocol.
Prepare an SD card with an Android build for VExpress according to Linaro's instructions: https://wiki.linaro.org/Platform/Android/ImageInstallation?action=show&redirect=Platform%2FAndroid%2FInstallImages
At time of writing, Linaro's android build uses the legacy MBR partition table, which is not supported by Fastboot on VExpress. We will now convert the SD card from MBR to GPT.
GPT requires a backup copy of the partition table at the end of the media. When converting from MBR to GPT, this poses a problem as the last partition extends to the end of the device, not leaving space for the backup GPT. To get around this, we will need to resize the last partition. Instructions follow to do so with GNU Parted. $DEV is the device name of your SD card - it will look like `/dev/sdc` (not /dev/sdc1).
1. Run `parted $DEV` as root.
2. Type `print` to show the partition table.
3. Identify the start and end of the last partition.
4. Subtract 2MB from the end of the partition, and type `resize $START $END`, where $START is the start of the partition and $END is the new end you calculated. Include the "MB" suffix in $START and $END.
5. Type `quit`.
6. Now use `gdisk` to convert from MBR to GPT.
7. Run `gdisk $DEV` as root.
You should see a warning stating that the media is partitioned with MBR, and that gdisk will convert to GPT.
Type `w` to write the partition table, converting to GPT, and quit.
In order for the VExpress Fastboot platform to identify partitions, we also need to set the Partition Name fields in the GPT. The reason for this is that flashing a partition will potentially change the filesystem's name, whereas the Partition Name is constant. We will now go through the partition table and populate these fields so that each partition's Partition Name is the same as the name of the filesystem on that partition.
8. Run `ls -l /dev/disk/by-label/` to see the filesystem labels for each partition. This directory contains symbolic links, named according to the name of the filesystem on the partition, to each partition's device file.
9. Run `gdisk $DEV` as root (again).
10. For each partition containing a filesystem with a name, type `c`, select the partition by number, then type the filesystem's name.
Type `w` to save the changes and quit.
(In the future, Linaro's Android builds will automatically use GPT and set the Partition Name field).
1. Plug your ARM Versatile Express to your host machine via USB (using the Mini-USB connection on the VExpress).
Insert the SD card into the ARM Versatile Express SD slot.
2. power up your Versatile Express.
3. Add and Start UEFI FastBoot Application to Boot entries:
[1] NorFlash [2] Linux from BootMonFs [3] Shell [4] Boot Manager Start: 4 [1] Add Boot Device Entry [2] Update Boot Device Entry [3] Remove Boot Device Entry [4] Update FDT path [5] Return to main menu Choice: 1 [1] NOR Flash (63 MB) [2] NOR Flash (63 MB) [3] VenHw(E7223039-5836-41E1-B542-D7EC736C5E59) [4] VenHw(02118005-9DA7-443A-92D5-781F022AEDBB) [5] VenHw(1F15DA3C-37FF-4070-B471-BB4AF12A724A) [6] VenHw(CC2CBF29-1498-4CDD-8171-F8B6B41D0909) [7] VenHw(09831032-6FA3-4484-AF4F-0A000A8D3A82) Select the Boot Device: 1 File path of the EFI Application or the kernel: fastboot.efi Is your application is an OS loader? [y/n] n Description for this new Entry: Android Fastboot [1] Add Boot Device Entry [2] Update Boot Device Entry [3] Remove Boot Device Entry [4] Update FDT path [5] Return to main menu Choice: 5 [1] NorFlash [2] Linux from BootMonFs [3] Android Fastboot [4] Shell [5] Boot Manager Start: 3 EDK2 USB Fastboot mode: this device reports 0xf00d for its device ID. If using the Android SDK fastboot host application, add '-i 0xf00d' to the command line arguments. Android Fastboot mode - version 0.4. Press any key to quit.
4. Your ARM Versatile Express should now be in Fastboot mode, and you should be able to run fastboot commands from the host. You will need to add `-i 0xf00d` to the fastboot command, and you will probably need to run it as root. Some example commands to try:
- `sudo fastboot -i 0xf00d boot zImage` (replace zImage with a Linux kernel supporting FDT) - this will download and boot the kernel.
- `sudo fastboot -i 0xf00d flash sdcard test_fs.dat` (replace test_fs.dat with a test FAT filesystem image) - this will flash the image onto the "sdcard" partition.
The implementation is distributed into several components:
- EmbeddedPkg/Application/AndroidFastbootApp is the platform-independent UEFI application that handles the core logic of a Fastboot session. It uses the FASTBOOT_TRANSPORT_PROTOCOL to communicate with the host and the FASTBOOT_PLATFORM_PROTOCOL to initiate platform-specific operations.
- EmbeddedPkg/Drivers/AndroidFastbootTransportUsbDxe is a driver implementing the FASTBOOT_TRANSPORT_PROTOCOL over USB by acting as a peripheral. This requires a USB peripheral or OTG controller and a UEFI driver for that controller. USB is the "default" transport system for Fastboot - the only one supported by the core AOSP.
- ArmPlatformPkg/ArmVExpressPkg/ArmVExpressFastBootDxe is an example of a FASTBOOT_PLATFORM_PROTOCOL implementation for ARM development platforms. It uses the SD card as the "flash memory".
To port UEFI Fastboot to your platform you will need implementations of the FASTBOOT_PLATFORM_PROTOCOL and the FASTBOOT_TRANSPORT_PROTOCOL. These UEFI protocols are documented in their respective header files under `EmbeddedPkg/Include/Protocol`.
The FASTBOOT_PLATFORM_PROTOCOL's main responsibility is to handle the mapping from Fastboot's notion of "partition names" to actual partitions on the platform's storage media. It also handles OEM-specific Fastboot commands.
The FASTBOOT_TRANSPORT_PROTOCOL provides an abstracted means for AndroidFastbootApp to communicate with the host.
In order to use Fastboot over USB on your platform, you will need to write a UEFI driver for the USB peripheral controller which exposes the USB_DEVICE_PROTOCOL defined in `EmbeddedPkg/Include/Protocol/UsbDevice.h`. At time of writing, this protocol consists of the bare minimum of functionality required to implement Fastboot. You can then use UsbFastbootTransportDxe, which will consume the USB_DEVICE_PROTOCOL and produce the FASTBOOT_TRANSPORT_PROTOCOL.