boot/grub2/readme.txt - buildroot - Git at Google

 Notes on using Grub2 for BIOS-based platforms
 =============================================

 1. Create a disk image
    dd if=/dev/zero of=disk.img bs=1M count=32
 2. Partition it (either legacy or GPT style partitions work)
    cfdisk disk.img
     - Create one partition, type Linux, for the root
       filesystem. The only constraint is to make sure there
       is enough free space *before* the first partition to
       store Grub2. Leaving 1 MB of free space is safe.
 3. Setup loop device and loop partitions
    sudo losetup -f disk.img
    sudo partx -a /dev/loop0
 4. Prepare the root partition
    sudo mkfs.ext3 -L root /dev/loop0p1
    sudo mount /dev/loop0p1 /mnt
    sudo tar -C /mnt -xf output/images/rootfs.tar
    sudo umount /mnt
 5. Install Grub2
    sudo ./output/host/sbin/grub-bios-setup \
         -b ./output/host/lib/grub/i386-pc/boot.img \
         -c ./output/images/grub.img -d . /dev/loop0
 6. Cleanup loop device
    sudo partx -d /dev/loop0
    sudo losetup -d /dev/loop0
 7. Your disk.img is ready!

 Using genimage
 --------------

 If you use genimage to generate your complete image,
 installing Grub can be tricky. Here is how to achieve Grub's
 installation with genimage:

 partition boot {
     in-partition-table = "no"
     image = "path_to_boot.img"
     offset = 0
     size = 512
 }
 partition grub {
     in-partition-table = "no"
     image = "path_to_grub.img"
     offset = 512
 }

 The result is not byte to byte identical to what
 grub-bios-setup does but it works anyway.

 To test your BIOS image in Qemu
 -------------------------------

 qemu-system-{i386,x86-64} -hda disk.img

 Notes on using Grub2 for x86/x86_64 EFI-based platforms
 =======================================================

 1. Create a disk image
    dd if=/dev/zero of=disk.img bs=1M count=32
 2. Partition it with GPT partitions
    cgdisk disk.img
     - Create a first partition, type EF00, for the
       bootloader and kernel image
     - Create a second partition, type 8300, for the root
       filesystem.
 3. Setup loop device and loop partitions
    sudo losetup -f disk.img
    sudo partx -a /dev/loop0
 4. Prepare the boot partition
    sudo mkfs.vfat -n boot /dev/loop0p1
    sudo mount /dev/loop0p1 /mnt
    sudo cp -a output/images/efi-part/* /mnt/
    sudo cp output/images/bzImage /mnt/
    sudo umount /mnt
 5. Prepare the root partition
    sudo mkfs.ext3 -L root /dev/loop0p2
    sudo mount /dev/loop0p2 /mnt
    sudo tar -C /mnt -xf output/images/rootfs.tar
    sudo umount /mnt
 6  Cleanup loop device
    sudo partx -d /dev/loop0
    sudo losetup -d /dev/loop0
 7. Your disk.img is ready!

 To test your i386/x86-64 EFI image in Qemu
 ------------------------------------------

 1. Download the EFI BIOS for Qemu
    Version IA32 or X64 depending on the chosen Grub2
    platform (i386-efi vs. x86-64-efi)
    https://www.kraxel.org/repos/jenkins/edk2/
    (or use one provided by your distribution as OVMF)
 2. Extract, and rename OVMF.fd to bios.bin and
    CirrusLogic5446.rom to vgabios-cirrus.bin.
 3. qemu-system-{i386,x86-64} -L ovmf-dir/ -hda disk.img
 4. Make sure to pass pci=nocrs to the kernel command line,
    to workaround a bug in the EFI BIOS regarding the
    EFI framebuffer.

 Notes on using Grub2 for ARM u-boot-based platforms
 ===================================================

 The following steps show how to use the Grub2 arm-uboot platform
 support in the simplest way possible and with a single
 buildroot-generated filesystem.

  1. Load qemu_arm_vexpress_defconfig

  2. Enable u-boot with the vexpress_ca9x4 board name and with
     u-boot.elf image format.

  3. Enable grub2 for the arm-uboot platform.

  4. Enable "Install kernel image to /boot in target" in the kernel
     menu to populate a /boot directory with zImage in it.

  5. The upstream u-boot vexpress_ca9x4 doesn't have CONFIG_API enabled
     by default, which is required.

     Before building, patch u-boot (for example, make u-boot-extract to
     edit the source before building) file
     include/configs/vexpress_common.h to define:

     #define CONFIG_API
     #define CONFIG_SYS_MMC_MAX_DEVICE   1

  6. Create a custom grub2 config file with the following contents and
     set its path in BR2_TARGET_GRUB2_CFG:

     set default="0"
     set timeout="5"

     menuentry "Buildroot" {
         set root='(hd0)'
         linux /boot/zImage root=/dev/mmcblk0 console=ttyAMA0
         devicetree /boot/vexpress-v2p-ca9.dtb
     }

  7. Create a custom builtin config file with the following contents
     and set its path in BR2_TARGET_GRUB2_BUILTIN_CONFIG:

     set root=(hd0)
     set prefix=/boot/grub

  8. Create a custom post-build script which copies files from
     ${BINARIES_DIR}/boot-part to $(TARGET_DIR)/boot (set its path in
     BR2_ROOTFS_POST_BUILD_SCRIPT):

     #!/bin/sh
     cp -r ${BINARIES_DIR}/boot-part/* ${TARGET_DIR}/boot/

  9. make

 10. Run qemu with:

     qemu-system-arm -M vexpress-a9 -kernel output/images/u-boot -m 1024 \
     -nographic -sd output/images/rootfs.ext2

 11. In u-boot, stop at the prompt and run grub2 with:

   => ext2load mmc 0:0 ${loadaddr} /boot/grub/grub.img
   => bootm

 12. This should bring the grub2 menu, upon which selecting the "Buildroot"
     entry should boot Linux.


 Notes on using Grub2 for Aarch64 EFI-based platforms
 ====================================================

 The following steps show how to use the Grub2 arm64-efi platform,
 using qemu and EFI firmware built for qemu.

  1. Load aarch64_efi_defconfig

  2. make

  3. Download the EFI firmware for qemu aarch64
     https://www.kraxel.org/repos/jenkins/edk2/
     (or use one provided by your distribution as OVMF-aarch64 or AAVMF)

  4. Run qemu with:

     qemu-system-aarch64 -M virt -cpu cortex-a57 -m 512 -nographic \
     -bios <path/to/EDK2>/QEMU_EFI.fd -hda output/images/disk.img \
     -netdev user,id=eth0 -device virtio-net-device,netdev=eth0

  5. This should bring the grub2 menu, upon which selecting the
     "Buildroot" entry should boot Linux.
	Notes on using Grub2 for BIOS-based platforms
	=============================================

	1. Create a disk image
	dd if=/dev/zero of=disk.img bs=1M count=32
	2. Partition it (either legacy or GPT style partitions work)
	cfdisk disk.img
	- Create one partition, type Linux, for the root
	filesystem. The only constraint is to make sure there
	is enough free space before the first partition to
	store Grub2. Leaving 1 MB of free space is safe.
	3. Setup loop device and loop partitions
	sudo losetup -f disk.img
	sudo partx -a /dev/loop0
	4. Prepare the root partition
	sudo mkfs.ext3 -L root /dev/loop0p1
	sudo mount /dev/loop0p1 /mnt
	sudo tar -C /mnt -xf output/images/rootfs.tar
	sudo umount /mnt
	5. Install Grub2
	sudo ./output/host/sbin/grub-bios-setup \
	-b ./output/host/lib/grub/i386-pc/boot.img \
	-c ./output/images/grub.img -d . /dev/loop0
	6. Cleanup loop device
	sudo partx -d /dev/loop0
	sudo losetup -d /dev/loop0
	7. Your disk.img is ready!

	Using genimage
	--------------

	If you use genimage to generate your complete image,
	installing Grub can be tricky. Here is how to achieve Grub's
	installation with genimage:

	partition boot {
	in-partition-table = "no"
	image = "path_to_boot.img"
	offset = 0
	size = 512
	}
	partition grub {
	in-partition-table = "no"
	image = "path_to_grub.img"
	offset = 512
	}

	The result is not byte to byte identical to what
	grub-bios-setup does but it works anyway.

	To test your BIOS image in Qemu
	-------------------------------

	qemu-system-{i386,x86-64} -hda disk.img

	Notes on using Grub2 for x86/x86_64 EFI-based platforms
	=======================================================

	1. Create a disk image
	dd if=/dev/zero of=disk.img bs=1M count=32
	2. Partition it with GPT partitions
	cgdisk disk.img
	- Create a first partition, type EF00, for the
	bootloader and kernel image
	- Create a second partition, type 8300, for the root
	filesystem.
	3. Setup loop device and loop partitions
	sudo losetup -f disk.img
	sudo partx -a /dev/loop0
	4. Prepare the boot partition
	sudo mkfs.vfat -n boot /dev/loop0p1
	sudo mount /dev/loop0p1 /mnt
	sudo cp -a output/images/efi-part/* /mnt/
	sudo cp output/images/bzImage /mnt/
	sudo umount /mnt
	5. Prepare the root partition
	sudo mkfs.ext3 -L root /dev/loop0p2
	sudo mount /dev/loop0p2 /mnt
	sudo tar -C /mnt -xf output/images/rootfs.tar
	sudo umount /mnt
	6 Cleanup loop device
	sudo partx -d /dev/loop0
	sudo losetup -d /dev/loop0
	7. Your disk.img is ready!

	To test your i386/x86-64 EFI image in Qemu
	------------------------------------------

	1. Download the EFI BIOS for Qemu
	Version IA32 or X64 depending on the chosen Grub2
	platform (i386-efi vs. x86-64-efi)
	https://www.kraxel.org/repos/jenkins/edk2/
	(or use one provided by your distribution as OVMF)
	2. Extract, and rename OVMF.fd to bios.bin and
	CirrusLogic5446.rom to vgabios-cirrus.bin.
	3. qemu-system-{i386,x86-64} -L ovmf-dir/ -hda disk.img
	4. Make sure to pass pci=nocrs to the kernel command line,
	to workaround a bug in the EFI BIOS regarding the
	EFI framebuffer.

	Notes on using Grub2 for ARM u-boot-based platforms
	===================================================

	The following steps show how to use the Grub2 arm-uboot platform
	support in the simplest way possible and with a single
	buildroot-generated filesystem.

	1. Load qemu_arm_vexpress_defconfig

	2. Enable u-boot with the vexpress_ca9x4 board name and with
	u-boot.elf image format.

	3. Enable grub2 for the arm-uboot platform.

	4. Enable "Install kernel image to /boot in target" in the kernel
	menu to populate a /boot directory with zImage in it.

	5. The upstream u-boot vexpress_ca9x4 doesn't have CONFIG_API enabled
	by default, which is required.

	Before building, patch u-boot (for example, make u-boot-extract to
	edit the source before building) file
	include/configs/vexpress_common.h to define:

	#define CONFIG_API
	#define CONFIG_SYS_MMC_MAX_DEVICE 1

	6. Create a custom grub2 config file with the following contents and
	set its path in BR2_TARGET_GRUB2_CFG:

	set default="0"
	set timeout="5"

	menuentry "Buildroot" {
	set root='(hd0)'
	linux /boot/zImage root=/dev/mmcblk0 console=ttyAMA0
	devicetree /boot/vexpress-v2p-ca9.dtb
	}

	7. Create a custom builtin config file with the following contents
	and set its path in BR2_TARGET_GRUB2_BUILTIN_CONFIG:

	set root=(hd0)
	set prefix=/boot/grub

	8. Create a custom post-build script which copies files from
	${BINARIES_DIR}/boot-part to $(TARGET_DIR)/boot (set its path in
	BR2_ROOTFS_POST_BUILD_SCRIPT):

	#!/bin/sh
	cp -r ${BINARIES_DIR}/boot-part/* ${TARGET_DIR}/boot/

	9. make

	10. Run qemu with:

	qemu-system-arm -M vexpress-a9 -kernel output/images/u-boot -m 1024 \
	-nographic -sd output/images/rootfs.ext2

	11. In u-boot, stop at the prompt and run grub2 with:

	=> ext2load mmc 0:0 ${loadaddr} /boot/grub/grub.img
	=> bootm

	12. This should bring the grub2 menu, upon which selecting the "Buildroot"
	entry should boot Linux.


	Notes on using Grub2 for Aarch64 EFI-based platforms
	====================================================

	The following steps show how to use the Grub2 arm64-efi platform,
	using qemu and EFI firmware built for qemu.

	1. Load aarch64_efi_defconfig

	2. make

	3. Download the EFI firmware for qemu aarch64
	https://www.kraxel.org/repos/jenkins/edk2/
	(or use one provided by your distribution as OVMF-aarch64 or AAVMF)

	4. Run qemu with:

	qemu-system-aarch64 -M virt -cpu cortex-a57 -m 512 -nographic \
	-bios <path/to/EDK2>/QEMU_EFI.fd -hda output/images/disk.img \
	-netdev user,id=eth0 -device virtio-net-device,netdev=eth0

	5. This should bring the grub2 menu, upon which selecting the
	"Buildroot" entry should boot Linux.