kumquat-buildroot/boot/grub2
Fabrice Fontaine 7e64a050fb boot/grub2: Fix GRUB i386-pc build with Ubuntu gcc
Backport a patch from upstream to fix the build on certain versions of
gsc, notably:

    Ubuntu 19.10 with gcc (Ubuntu 8.3.0-26ubuntu1~19.10) 8.3.0
    Ubuntu 19.10 with gcc (Ubuntu 9.2.1-9ubuntu2) 9.2.1 20191008

The upstream patch is simply a change in the gentpl.py script, which is
used to generate parts of the automake machinery, so if we just backport
the upstream patch, we need to call the script to regenerate those files.

However, the modified script is a python script, so we would need to add
a dependency on host-python (2 or 3), which is not so nice.

Furthermore, calling the script is not enough: it needs a specific set
of optionss for each file it is to generate. That set of options is not
static; it is constructed in the convoluted autogen.sh. Calling
autogen.sh is usally not so good an idea in the Buildroot context, and
indeed this fails becasue it calls to autoreconf, but without our
carefuly crafted options and environment variables.

There was a little light in the tunnel, in that autogen.sh can be told
not to run autoreconf, by setting the environemnt variable
FROM_BOOTSTRAP to an non-=empty string, but this is fraught with various
other side-effects, as in that cause, autogen.sh expects to be valled by
an upper sciopt, bootstrap, which is not provided in the tarball
distribution...

So, between all those issues, autogen, bootstrap, and a host-python (2
or 3) dependency, we choose another route: path the script *and* the one
generated file affected by the change. Since that patched file is a .am
file, we also patch the corresponding .in file

However, we're faced with another issue: the other generated file is
now older than the script, so the automake machinery will now want to
re-run autoconf et al during the build step, which is still not a good
idea for us. So we touch the other generated file so it is mopre recent
than the script.

This is still not sufficient, because the patched file also has a
dependency on the generated file, so we need to touch as well.

Fixes:
 - https://bugs.buildroot.org/show_bug.cgi?id=12946

Signed-off-by: Fabrice Fontaine <fontaine.fabrice@gmail.com>
[yann.morin.1998@free.fr:
  - keep the hunk about patching gentpl.py
  - make it a git-formatted patch
  - add the touch
  - drastically expand the commit log
]
Signed-off-by: Yann E. MORIN <yann.morin.1998@free.fr>
2020-06-05 00:03:30 +02:00
..
0001-build-Fix-GRUB-i386-pc-build-with-Ubuntu-gcc.patch boot/grub2: Fix GRUB i386-pc build with Ubuntu gcc 2020-06-05 00:03:30 +02:00
Config.in
grub2.hash
grub2.mk boot/grub2: Fix GRUB i386-pc build with Ubuntu gcc 2020-06-05 00:03:30 +02:00
grub.cfg
readme.txt

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.