How to setup boot loaders

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Revision as of 04:12, 1 October 2005 by Wyrfel (Talk | contribs) (Using the NT Boot Loader to boot Linux)
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This page (hopefully) will explain everything you should know about the major bootloaders so that you can configure them to your liking.

General information about boot processes

From the moment you switch on your computer to the moment you can login into your installed operating system, a lot of things happen that can be devided into several major stages.

The BIOS stage

When you switch on your computer, the first thing that's run is the BIOS, a program embedded into a chip within your computer that represents the lowest layer between all running software and the hardware. During startup the BIOS has several tasks to do, like i.e. analyzing and checking hardware as well as the current system state. The last of it's tasks is to find a bootable device and boot into that.

To do so, the BIOS program keeps a list of bootable drives as well as a boot order list which you can adjust via the BIOS settings menu - or on ThinkPads directly through hitting F12 during bootup. In the order of that list it checks which of the drives it knows about actually contains bootable media. The first bootable media found will be booted. That means that the code at the very first sector of that media is loaded an run.

The Boot Sectors

This first sector is called the boot sector. For different types of media different kinds of boot sectors are required, and since booting the harddrive is what we are concerned about here, we'll look into that specifically. Now, a harddrive is usually devided into partitions. Even if you only have one partition covering your whole drive, the internal structure is still the same. The first sector of your harddrive is the Master Boot Record (MBR), which includes the harddrives boot code as well as the hard drives partition table. The partition table contains information about the partition layout of your harddisk. The MBR typically is 512 KB in size, as is the size of every sector on an x86 machines harddisk. Now, every partitions first sector is called the boot sector of that partition, because it actually is reserved especially to serve that purpose. To summarize, a harddisk will always contain boot code in the MBR, and can contain further boot code in one or several boot sectors, belonging each to one partition.

The Boot Loader stage

This stage starts with running the code inside the boot sector. As stated above, the first peace of code that's run on a harddisk is always the MBR. So, what happens next is already depending on what is written to the MBR and hence on which program wrote the boot code into the MBR. Typically, when you get your ThinkPad, the MBRs boot code will originate from Windows. In that case it picks the primary partition that is flagged with the bootable (or active) flag from the partition table and runs the boot sector of that partition, similar to how the BIOS launched the code in the MBR before. What happens next, depends on what code is in the partitions boot sector and at this point we should have a look to the most common boot loaders around.

LILO, GRUB and NT Boot Loader

Comparison Table
LILO GRUB NT Boot Loader
occupies MBR or boot sector MBR or boot sector MBR and boot sector
boot selector
  • line input
  • text menu
  • graphical menu
  • line input
  • text menu
  • text menu
OS support GNU/Linux FreeBSD, NetBSD, OpenBSD, GNU/Linux can chainload other bootsectors
Windows Support via chain-loading via chain-loading WinNT, Win2K, WinXP
supported filesystems block offset based BSD FFS, FAT16, FAT32, Minix fs, ext2fs, ReiserFS, JFS, XFS, VSTa FAT16, FAT32, NTFS
Partition designation example
(second partion on first harddisk)
/dev/hda2 (hd0,1) multi(0)disk(0)rdisk(0)partition(2)

LILO

LILO (LInux LOader) is one of the oldest linux and multiboot boot loaders. It is feature rich, dependable and widely used. Since LILO is configured through a human readable, easy to understand configuration file it is easy to setup.

LILOs classical way of behaving is to offer a single input line on boot, enabling you to type the label of the system to be booted and provide additional boot parameters. It can also print a message, or - in newer versions - it can be configured to show a menu (even a graphical one) so that you can pick your system more comfortably.

Creating a LILO bootdisk

As a fallback it is always good to create a simple LILO bootdisk. We are creating a simple LILO bootdisk here, not a Linux bootdisk, which is a different thing and would require more comprehensive steps.

  • You need to configure LILO beforehand, so edit lilo.conf to fit your configuration.
  • Insert a formatted floppy disk to your floppy drive, but do not mount it.
  • Now do a # lilo -v -b /dev/fd0. This overrides the boot=... line in the config file and writes the configured boot sector to the floppy.

That's it. You can use this floppy as long as your system layout is the same (as long as you don't need to modify /etc/lilo.conf). Whenever you modify LILOs configuration, you should recreate the bootdisk using the command above.

Installation of a LILO boot loader

The # lilo command is used to install the LILO boot loader. It reads the configuration file, calculates the block offset of the configured kernel images and writes the necessary data to the boot sector.

  • LILO is configured by editing /etc/lilo.conf.
    The format is explained in {{{2}}} man lilo.conf.
A simple example configuration could look like this:
boot=/dev/hda
map=/boot/map
install=/boot/boot.b
prompt
timeout=100
compact
default=Linux
image=/boot/vmlinuz
       label=Linux
       root=/dev/hda2
       read-only
other=/dev/hda1
       label=Windows
  • Run the # lilo command to write lilo to the MBR.
  • Reboot your machine.
NOTE!
Since LILO doesn't know about file systems and saves the kernel images positions based on a block count, you will have to rerun the lilo command everytime you did modifications to your kernel image. This includes recompiling or reinstalling the kernel as well as moving it to somewhere else or defragmenting the file system.

If you do not rerun lilo after such operations, you will render your system unbootable.

GRUB

GNU GRUB (GRand Unified Bootloader) is surely the most powerful of the bootloaders listed here. Besides featuring a nice and comfortable boot menu and a human readable easy to understand configuration file, it offers an interactive console which can be the perfect tool for recovering boot problems.

Creating a GRUB bootdisk

As a fallback it is always good to create a GRUB bootdisk, especially because for GRUB this is very quick and simple.

  • Insert a formatted floppy disk to your floppy drive, but do not mount it.
  • Execute the following commands to create the boot disk (you may need to change /usr/share to /usr/lib):
# dd if=/usr/share/grub/i386-pc/stage1 of=/dev/fd0 bs=512 count=1
# dd if=/usr/share/grub/i386-pc/stage2 of=/dev/fd0 bs=512 seek=1

That's it. The created disk will boot directly into the interactive GRUB console. Use help there to get a list of available commands.

Hint:
You can get partition and file listings within GRUBs console through TAB completion.

Installation of a GRUB boot loader

  • Usually the files needed for GRUB should reside in /boot/grub.
  • Copy over the necessary stage files from /usr/share/grub/i386-pc/ or /usr/lib/grub/i386-pc. You will need stage1, stage2 and usually one or more stage 1.5 files matching your filesystem. Usually these are e2fs_stage1_5, reiserfs_stage1_5 or iso9660_stage1_5. Look into the directory for support of other filesystems.
  • To get the comfortable GRUB boot menu you will have to create the file /boot/grub/menu.lst. The format of it is explained in GRUBs info page ({{{2}}} info grub).
  • Once everything is setup in /boot/grub, launch the GRUB console by running # grub.
  • Within the console select the partition on which your /boot/grub directory resides using the root command, i.e. for the second partion on the first harddisk (/dev/hda2), enter
root (hd0,1)
  • After that is successfully done, install the bootloader to the MBR using
setup (hd0)
  • Reboot your machine to try if it works.

NT Boot Loader

The Windows 2000/XP boot loader is a bit hard to tweak if you want something else than use it to choose between your Windows installations.

The NT Boot Loader generally works like this:

  • The booted partitions (i.e. the active one) boot sector looks for ntldr.exe on the active partitions filesystem. NTLDR is the actual boot loader and control is given to it if it's found. Else the boot process will fail.
  • NTLDR looks for the boot.ini file on the active partition to read it's configuration. If more than one operating systems are configured in the file and the delay parameter is not 0, then the NT boot menu is displayed.
  • When the user chooses a system, the delay time runs out or there is only one given system, NTLDR will start that system.
NOTE!
You can always boot older Windows NT like systems from the boot loader of newer ones, but trying the other way around will fail. Microsoft made changes to the boot loader and the NTFS file system throughout the releases of WinNT, Win2K and WinXP. An older NT Boot Loader will not know about these changes in a newer system.

Installation of the NT Boot Loader

The NT Boot Loader gets installed by the Windows installation routines. However, there are cases when you manually want to install the NT Boot Loader to a partition. The easiest way to do so is as follows:

  1. Boot your Windows system.
  2. Use the Disk Management Administration Console or a partitioning tool to set the partition that the boot sector should be installed to as active (bootable).
  3. Right-click on 'My Computer', select properties and go to the Startup Settings in the Advanced tab. Make some sensible changes, lowering or raising the delay time would be enough. Confirm with OK. This should write the boot sector to the active partition.

Using the NT Boot Loader to boot Linux

The NT boot loader is not able to boot anything else than NT type Windows systems. However, other systems boot sectors can be stored in a file on the same disk that the NTLDR files reside on and can be chainloaded from there.

Hence, the procedure to integrate Linux into your NT boot menu is outlines like this (we assume that the NT boot loader is properly installed already):

  • Install a Linux boot loader (LILO or GRUB) into the boot sector of your Linux partition.
  • Copy this boot sector into a file.
  • Copy that file to the root level of the Windows partition.
  • Add an entry to chainload that file to the NT boot menu.

Installing LILO to a partitions boot sector

Using LILO or GRUB to boot Windows

When you want to configure a linux boot manager to boot Windows, there are some aspects to care about.

  • First of all, do not install LILO or GRUB to the Windows partitions boot sector. This would overwrite the Windows boot loader and Windows would not be bootable anymore. In fact it is always a good idea to install the linux bootloader to the MBR.
  • Take care that at least at the time of booting, your Windows partition is the active one. As long as the LILO/GRUB is installed to the MBR, the Linux boot process doesn't depend on the active partition flag. So in most cases you can just set it on the Windows partition (using i.e. # fdisk /dev/hda) and leave it. However, there are cases requiring a more dynamic handling. GRUBs makeactive command can help you here.

LILO configuration

Given that /dev/hda2 would be your Windows partition, a typical /etc/lilo.conf section for booting it with LILO would be:

other=/dev/hda2
label=win

GRUB configuration

Given that /dev/hda2 would be your Windows partition, a typical /boot/grub/menu.lst section for booting it with GRUB would be:

title Windows
rootnoverify (hd0,1)
makeactive
chainloader +1

External Sources