BLFS does not have the essential packages to support Secure Boot. To set up the boot process with GRUB and UEFI in BLFS, Secure Boot must be turned off from the configuration interface of the firmware. Read the documentation provided by the manufacturer of your system to find out how.
Enable the following options in the kernel configuration and recompile the kernel if necessary:
Processor type and features ---> [*] EFI runtime service support [EFI] [*] EFI stub support [EFI_STUB] -*- Enable the block layer ---> [BLOCK] Partition Types ---> [ /*] Advanced partition selection [PARTITION_ADVANCED] [*] EFI GUID Partition support [EFI_PARTITION] Device Drivers ---> Firmware Drivers ---> [*] Mark VGA/VBE/EFI FB as generic system framebuffer [SYSFB_SIMPLEFB] Graphics support ---> <*> Direct Rendering Manager (XFree86 4.1.0 and higher DRI support) ---> ... [DRM] [*] Enable legacy fbdev support for your modesetting driver ... [DRM_FBDEV_EMULATION] <*> Simple framebuffer driver [DRM_SIMPLEDRM] Console display driver support ---> [*] Framebuffer Console support [FRAMEBUFFER_CONSOLE] File systems ---> DOS/FAT/EXFAT/NT Filesystems ---> <*/M> VFAT (Windows-95) fs support [VFAT_FS] Pseudo filesystems ---> <*/M> EFI Variable filesystem [EFIVAR_FS] -*- Native language support ---> [NLS] <*/M> Codepage 437 (United States, Canada) [NLS_CODEPAGE_437] <*/M> NLS ISO 8859-1 (Latin 1; Western European Languages) [NLS_ISO8859_1]
The meaning of the configuration options:
CONFIG_PARTITION_ADVANCED
If it's not enabled, CONFIG_EFI_PARTITION
will be
enabled automatically. But when it's enabled, you must set
CONFIG_EFI_PARTITION
to enabled as well.
CONFIG_SYSFB_SIMPLEFB
, CONFIG_DRM
, CONFIG_DRM_FBDEV_EMULATION
,
CONFIG_DRM_SIMPLEDRM
,
CONFIG_FB
, and
CONFIG_FRAMEBUFFER_CONSOLE
The combination of these options provides the Linux console support on top of the UEFI framebuffer. To allow the kernel to print debug messages at an early boot stage, they shouldn't be built as kernel modules unless an initramfs will be used.
Ensure that an emergency boot disk is ready to “rescue” the system in
case the system becomes un-bootable. To make an emergency boot disk
with GRUB for an EFI based system, find a spare USB flash drive and
create a vfat
file system on it.
Install dosfstools-4.2 first, then as the root
user:
The following command will erase all directories and files in the
partition. Make sure your USB flash drive contains no data which
will be needed, and change sdx1
to the device node
corresponding to the first partition of the USB flash drive. Be
careful not to overwrite your hard drive with a typo!
mkfs.vfat /dev/sdx1
Still as the root
user, use the
fdisk utility to set
the first partition of the USB flash drive to be an “EFI system” partition
(change sdx
to the
device node corresponding to your USB flash drive):
fdisk /dev/sdxWelcome to fdisk (util-linux 2.39.1). Changes will remain in memory only, until you decide to write them. Be careful before using the write command. Command (m for help):
tPartition number (1-9, default 9):
1Partition type or alias (type L to list all):
uefiChanged type of partition 'Linux filesystem' to 'EFI System'. Command (m for help):
wThe partition table has been altered. Syncing disks.
Still as the root
user, create a
mount point for the EFI partition on the USB flash drive and mount
it:
mount --mkdir -v -t vfat /dev/sdx1 -o codepage=437,iocharset=iso8859-1 \ /mnt/rescue
Install GRUB for EFI on the partition:
grub-install --target=x86_64-efi --removable \ --efi-directory=/mnt/rescue --boot-directory=/mnt/rescue
Unmount the partition:
umount /mnt/rescue
Now the USB flash drive can be used as an emergency boot disk on any x86-64 UEFI platform. It will boot the system and show the GRUB shell. Then you can type commands to boot your operating system from the hard drive. To learn how to select the boot device, read the manual of your motherboard or laptop.
On EFI based systems, the bootloaders are installed in a special
FAT32 partition called an EFI System
Partition (ESP). If your system supports EFI, and a
recent version of some Linux distribution or Windows is
pre-installed, it's likely that the ESP has already been created.
As the root
user, list all the
partitions on your hard drive (replace sda
with the device corresponding
to the appropriate hard drive):
fdisk -l /dev/sda
The “Type”
column of the ESP should be EFI
System
.
If the system or the hard drive is new, or it's the first
installation of a UEFI-booted OS on the system, the ESP may not
exist. In that case, install dosfstools-4.2 first. Then create a new
partition, make a vfat
file system
on it, and set the partition type to “EFI system”. See the
instructions for the emergency boot device above as a reference.
Some (old) UEFI implementations may require the ESP to be the first partition on the disk.
Now, as the root
user, create the
mount point for the ESP, and mount it (replace sda1
with the device node
corresponding to the ESP):
mount --mkdir -v -t vfat /dev/sda1 -o codepage=437,iocharset=iso8859-1 \ /boot/efi
If you want to mount the ESP automatically during system boot, as
the root
user, add an entry for the
ESP into /etc/fstab
:
cat >> /etc/fstab << EOF
/dev/sda1 /boot/efi vfat codepage=437,iocharset=iso8859-1 0 1
EOF
On UEFI based systems, GRUB works by installing an EFI application
(a special kind of executable) into the ESP. The EFI firmware will
search boot loaders in EFI applications from boot entries recorded
in EFI variables, and additionally a hardcoded path EFI/BOOT/BOOTX64.EFI
. Normally, a boot loader
should be installed into a custom path and the path should be
recorded in the EFI variables. The use of the hardcoded path should
be avoided if possible. However, in some cases we have to use the
hardcoded path:
The system is not booted with EFI yet, making EFI variables inaccessible.
The EFI firmware is 64-bit but the LFS system is 32-bit, making EFI variables inaccessible because the kernel cannot invoke EFI runtime services with a different virtual address length.
LFS is built for a Live USB, so we cannot rely on EFI variables, which are stored in NVRAM or EEPROM on the local machine.
You are unable or unwilling to install the efibootmgr for manipulating boot entries in EFI variables.
In these cases, follow these instructions to install the GRUB EFI application into the hardcoded path and make a minimal boot configuration. Otherwise it's better to skip ahead and set up the boot configuration normally.
To install GRUB with the EFI application in the hardcoded path
EFI/BOOT/BOOTX64.EFI
, first ensure
the boot partition is mounted at /boot
and the ESP is mounted at /boot/efi
. Then, as the root
user, run the command:
This command will overwrite /boot/efi/EFI/BOOT/BOOTX64.EFI
. It may break a
bootloader already installed there. Back it up if you are not
sure.
grub-install --target=x86_64-efi --removable
This command will install the GRUB EFI application into the
hardcoded path /boot/efi/EFI/BOOT/BOOTX64.EFI
, so the EFI
firmware can find and load it. The remaining GRUB files are
installed in the /boot/grub
directory
and will be loaded by BOOTX64.EFI
during system boot.
The EFI firmware usually prefers the EFI applications with a path stored in EFI variables to the EFI application at the hardcoded path. So you may need to invoke the boot selection menu or firmware setting interface to select the newly installed GRUB manually on the next boot. Read the manual of your motherboard or laptop to learn how.
If you've followed the instructions in this section and set up a minimal boot configuration, now skip ahead to “Creating the GRUB Configuration File”.
The installation of GRUB on a UEFI platform requires that the EFI
Variable file system, efivarfs
, is
mounted. As the root
user, mount it
if it's not already mounted:
mountpoint /sys/firmware/efi/efivars || mount -v -t efivarfs efivarfs /sys/firmware/efi/efivars
Now add an entry for the efivarfs
in /etc/fstab
so it will be mounted
automatically during system boot:
cat >> /etc/fstab << EOF
efivarfs /sys/firmware/efi/efivars efivarfs defaults 0 0
EOF
If the system is not booted with UEFI, the directory /sys/firmware/efi
will be missing. In this case
you should boot the system in UEFI mode with the emergency boot
disk or using a minimal boot configuration created as above, then
mount efivarfs
and continue.
On UEFI based systems, GRUB works by installing an EFI application
(a special kind of executable) into /boot/efi/EFI/[id]/grubx64.efi
, where
/boot/efi
is the mount point of the
ESP, and [id]
is replaced with an
identifier specified in the grub-install command line. GRUB
will create an entry in the EFI variables containing the path
EFI/[id]/grubx64.efi
so the EFI
firmware can find grubx64.efi
and
load it.
grubx64.efi
is very lightweight (136
KB with GRUB-2.06) so it will not use much space in the ESP. A
typical ESP size is 100 MB (for Windows boot manager, which uses
about 50 MB in the ESP). Once grubx64.efi
has been loaded by the firmware, it
will load GRUB modules from the boot partition. The default
location is /boot/grub
.
As the root
user, install the GRUB
files into /boot/efi/EFI/LFS/grubx64.efi
and /boot/grub
. Then set up the boot entry in the EFI
variables:
grub-install --bootloader-id=LFS --recheck
If the installation is successful, the output should be:
Installing for x86_64-efi platform.
Installation finished. No error reported.
Issue the efibootmgr | cut -f 1 command to recheck the EFI boot configuration. An example of the output is:
BootCurrent: 0000
Timeout: 1 seconds
BootOrder: 0005,0000,0002,0001,0003,0004
Boot0000* ARCH
Boot0001* UEFI:CD/DVD Drive
Boot0002* Windows Boot Manager
Boot0003* UEFI:Removable Device
Boot0004* UEFI:Network Device
Boot0005* LFS
Note that 0005
is the first in the
BootOrder
, and Boot0005
is LFS
. This
means that on the next boot, the version of GRUB installed by LFS
will be used to boot the system.
Generate /boot/grub/grub.cfg
to
configure the boot menu of GRUB:
cat > /boot/grub/grub.cfg << EOF
# Begin /boot/grub/grub.cfg
set default=0
set timeout=5
insmod part_gpt
insmod ext2
set root=(hd0,2)
insmod all_video
if loadfont /boot/grub/fonts/unicode.pf2; then
terminal_output gfxterm
fi
menuentry "GNU/Linux, Linux 6.7.4-lfs-12.1" {
linux /boot/vmlinuz-6.7.4-lfs-12.1 root=/dev/sda2 ro
}
menuentry "Firmware Setup" {
fwsetup
}
EOF
Refer to the LFS book
for the basic knowledge about the grub.cfg
file. (hd0,2)
, sda2
, and
6.4.10-lfs-12.0
must match your
configuration.
The insmod all_video directive loads various modules for video support. It's needed to initialize the EFI framebuffer for the kernel to print messages correctly before the kernel GPU driver initialization.
The terminal_output
gfxterm directive changes the display resolution of
the GRUB menu to match your display device. It will break the
rendering if the unicode.pf2
font
data file is not loaded, so it's guarded by a if directive.
From GRUB's perspective, the files are relative to the partitions
used. If you used a separate /boot partition, remove /boot from
the above paths (to kernel and to unicode.pf2
). You will also need to change the
"set root" line to point to the boot partition.
The Firmware Setup
entry can be used
to enter the configuration interface provided by the firmware
(sometimes called “BIOS
configuration”).
Add a menu entry for Windows into grub.cfg
:
cat >> /boot/grub/grub.cfg << EOF
# Begin Windows addition
menuentry "Windows 11" {
insmod fat
insmod chain
set root=(hd0,1)
chainloader /EFI/Microsoft/Boot/bootmgfw.efi
}
EOF
(hd0,1)
should be replaced with the
GRUB designated name for the ESP. The chainloader
directive can be used to tell GRUB to
run another EFI executable, in this case the Windows Boot Manager.
You may put more usable tools in EFI executable format (for
example, an EFI shell) into the ESP and create GRUB entries for
them, as well.