This is the documentation of GNU GRUB, the GRand Unified Bootloader, a flexible and powerful boot loader program for pcs.
This edition documents version 0.97.
Briefly, a boot loader is the first software program that runs when a computer starts. It is responsible for loading and transferring control to an operating system kernel software (such as Linux or GNU Mach). The kernel, in turn, initializes the rest of the operating system (e.g. a GNU system).
GNU GRUB is a very powerful boot loader, which can load a wide variety of free operating systems, as well as proprietary operating systems with chain-loading1. GRUB is designed to address the complexity of booting a personal computer; both the program and this manual are tightly bound to that computer platform, although porting to other platforms may be addressed in the future.
One of the important features in GRUB is flexibility; GRUB understands filesystems and kernel executable formats, so you can load an arbitrary operating system the way you like, without recording the physical position of your kernel on the disk. Thus you can load the kernel just by specifying its file name and the drive and partition where the kernel resides.
When booting with GRUB, you can use either a command-line interface (see Command-line interface), or a menu interface (see Menu interface). Using the command-line interface, you type the drive specification and file name of the kernel manually. In the menu interface, you just select an OS using the arrow keys. The menu is based on a configuration file which you prepare beforehand (see Configuration). While in the menu, you can switch to the command-line mode, and vice-versa. You can even edit menu entries before using them.
In the following chapters, you will learn how to specify a drive, a partition, and a file name (see Naming convention) to GRUB, how to install GRUB on your drive (see Installation), and how to boot your OSes (see Booting), step by step.
Besides the GRUB boot loader itself, there is a grub shell grub (see Invoking the grub shell) which can be run when you are in your operating system. It emulates the boot loader and can be used for installing the boot loader.
GRUB originated in 1995 when Erich Boleyn was trying to boot the GNU Hurd with the University of Utah's Mach 4 microkernel (now known as GNU Mach). Erich and Brian Ford designed the Multiboot Specification (see Multiboot Specification), because they were determined not to add to the large number of mutually-incompatible PC boot methods.
Erich then began modifying the FreeBSD boot loader so that it would understand Multiboot. He soon realized that it would be a lot easier to write his own boot loader from scratch than to keep working on the FreeBSD boot loader, and so GRUB was born.
Erich added many features to GRUB, but other priorities prevented him from keeping up with the demands of its quickly-expanding user base. In 1999, Gordon Matzigkeit and Yoshinori K. Okuji adopted GRUB as an official GNU package, and opened its development by making the latest sources available via anonymous CVS. See Obtaining and Building GRUB, for more information.
The primary requirement for GRUB is that it be compliant with the Multiboot Specification, which is described in Multiboot Specification.
The other goals, listed in approximate order of importance, are:
Except for specific compatibility modes (chain-loading and the Linux piggyback format), all kernels will be started in much the same state as in the Multiboot Specification. Only kernels loaded at 1 megabyte or above are presently supported. Any attempt to load below that boundary will simply result in immediate failure and an error message reporting the problem.
In addition to the requirements above, GRUB has the following features (note that the Multiboot Specification doesn't require all the features that GRUB supports):
The list of commands (see Commands) are a subset of those supported
for configuration files. Editing commands closely resembles the Bash
command-line (see Bash), with <TAB>-completion of commands,
devices, partitions, and files in a directory depending on context.
It is conceivable that some kernel modules should be loaded in a
compressed state, so a different module-loading command can be specified
to avoid uncompressing the modules.
The following is a quotation from Gordon Matzigkeit, a GRUB fanatic:
Some people like to acknowledge both the operating system and kernel when they talk about their computers, so they might say they use “GNU/Linux” or “GNU/Hurd”. Other people seem to think that the kernel is the most important part of the system, so they like to call their GNU operating systems “Linux systems.”
I, personally, believe that this is a grave injustice, because the boot loader is the most important software of all. I used to refer to the above systems as either “LILO”3 or “GRUB” systems.
Unfortunately, nobody ever understood what I was talking about; now I just use the word “GNU” as a pseudonym for GRUB.
So, if you ever hear people talking about their alleged “GNU” systems, remember that they are actually paying homage to the best boot loader around... GRUB!
We, the GRUB maintainers, do not (usually) encourage Gordon's level of fanaticism, but it helps to remember that boot loaders deserve recognition. We hope that you enjoy using GNU GRUB as much as we did writing it.
The device syntax used in GRUB is a wee bit different from what you may have seen before in your operating system(s), and you need to know it so that you can specify a drive/partition.
Look at the following examples and explanations:
First of all, GRUB requires that the device name be enclosed with `(' and `)'. The `fd' part means that it is a floppy disk. The number `0' is the drive number, which is counted from zero. This expression means that GRUB will use the whole floppy disk.
Here, `hd' means it is a hard disk drive. The first integer `0' indicates the drive number, that is, the first hard disk, while the second integer, `1', indicates the partition number (or the pc slice number in the BSD terminology). Once again, please note that the partition numbers are counted from zero, not from one. This expression means the second partition of the first hard disk drive. In this case, GRUB uses one partition of the disk, instead of the whole disk.
This specifies the first extended partition of the first hard disk drive. Note that the partition numbers for extended partitions are counted from `4', regardless of the actual number of primary partitions on your hard disk.
This means the BSD `a' partition of the second hard disk. If you need to specify which pc slice number should be used, use something like this: `(hd1,0,a)'. If the pc slice number is omitted, GRUB searches for the first pc slice which has a BSD `a' partition.
Of course, to actually access the disks or partitions with GRUB, you need to use the device specification in a command, like `root (fd0)' or `unhide (hd0,2)'. To help you find out which number specifies a partition you want, the GRUB command-line (see Command-line interface) options have argument completion. This means that, for example, you only need to type
followed by a <TAB>, and GRUB will display the list of drives, partitions, or file names. So it should be quite easy to determine the name of your target partition, even with minimal knowledge of the syntax.
Note that GRUB does not distinguish IDE from SCSI - it simply counts the drive numbers from zero, regardless of their type. Normally, any IDE drive number is less than any SCSI drive number, although that is not true if you change the boot sequence by swapping IDE and SCSI drives in your BIOS.
Now the question is, how to specify a file? Again, consider an example:
This specifies the file named `vmlinuz', found on the first partition of the first hard disk drive. Note that the argument completion works with file names, too.
That was easy, admit it. Now read the next chapter, to find out how to actually install GRUB on your drive.
In order to install GRUB as your boot loader, you need to first install the GRUB system and utilities under your UNIX-like operating system (see Obtaining and Building GRUB). You can do this either from the source tarball, or as a package for your OS.
After you have done that, you need to install the boot loader on a drive (floppy or hard disk). There are two ways of doing that - either using the utility grub-install (see Invoking grub-install) on a UNIX-like OS, or by running GRUB itself from a floppy. These are quite similar, however the utility might probe a wrong BIOS drive, so you should be careful.
Also, if you install GRUB on a UNIX-like OS, please make sure that you have an emergency boot disk ready, so that you can rescue your computer if, by any chance, your hard drive becomes unusable (unbootable).
GRUB comes with boot images, which are normally put in the directory /usr/lib/grub/i386-pc. If you do not use grub-install, then you need to copy the files stage1, stage2, and *stage1_5 to the directory /boot/grub, and run the grub-set-default (see Invoking grub-set-default) if you intend to use `default saved' (see default) in your configuration file. Hereafter, the directory where GRUB images are initially placed (normally /usr/lib/grub/i386-pc) will be called the image directory, and the directory where the boot loader needs to find them (usually /boot/grub) will be called the boot directory.
To create a GRUB boot floppy, you need to take the files stage1 and stage2 from the image directory, and write them to the first and the second block of the floppy disk, respectively.
Caution: This procedure will destroy any data currently stored on the floppy.
On a UNIX-like operating system, that is done with the following commands:
# cd /usr/lib/grub/i386-pc # dd if=stage1 of=/dev/fd0 bs=512 count=1 1+0 records in 1+0 records out # dd if=stage2 of=/dev/fd0 bs=512 seek=1 153+1 records in 153+1 records out #
The device file name may be different. Consult the manual for your OS.
Caution: Installing GRUB's stage1 in this manner will erase the normal boot-sector used by an OS.
GRUB can currently boot GNU Mach, Linux, FreeBSD, NetBSD, and OpenBSD directly, so using it on a boot sector (the first sector of a partition) should be okay. But generally, it would be a good idea to back up the first sector of the partition on which you are installing GRUB's stage1. This isn't as important if you are installing GRUB on the first sector of a hard disk, since it's easy to reinitialize it (e.g. by running `FDISK /MBR' from DOS).
If you decide to install GRUB in the native environment, which is definitely desirable, you'll need to create a GRUB boot disk, and reboot your computer with it. Otherwise, see Installing GRUB using grub-install.
Once started, GRUB will show the command-line interface (see Command-line interface). First, set the GRUB's root device4 to the partition containing the boot directory, like this:
grub> root (hd0,0)
If you are not sure which partition actually holds this directory, use the command find (see find), like this:
grub> find /boot/grub/stage1
This will search for the file name /boot/grub/stage1 and show the devices which contain the file.
Once you've set the root device correctly, run the command setup (see setup):
grub> setup (hd0)
This command will install the GRUB boot loader on the Master Boot Record (MBR) of the first drive. If you want to put GRUB into the boot sector of a partition instead of putting it in the MBR, specify the partition into which you want to install GRUB:
grub> setup (hd0,0)
If you install GRUB into a partition or a drive other than the first one, you must chain-load GRUB from another boot loader. Refer to the manual for the boot loader to know how to chain-load GRUB.
After using the setup command, you will boot into GRUB without the GRUB floppy. See the chapter Booting to find out how to boot your operating systems from GRUB.
Caution: This procedure is definitely less safe, because there are several ways in which your computer can become unbootable. For example, most operating systems don't tell GRUB how to map BIOS drives to OS devices correctly—GRUB merely guesses the mapping. This will succeed in most cases, but not always. Therefore, GRUB provides you with a map file called the device map, which you must fix if it is wrong. See Device map, for more details.
If you still do want to install GRUB under a UNIX-like OS (such as gnu), invoke the program grub-install (see Invoking grub-install) as the superuser (root).
The usage is basically very simple. You only need to specify one argument to the program, namely, where to install the boot loader. The argument can be either a device file (like `/dev/hda') or a partition specified in GRUB's notation. For example, under Linux the following will install GRUB into the MBR of the first IDE disk:
# grub-install /dev/hda
Likewise, under GNU/Hurd, this has the same effect:
# grub-install /dev/hd0
If it is the first BIOS drive, this is the same as well:
# grub-install '(hd0)'
Or you can omit the parentheses:
# grub-install hd0
But all the above examples assume that GRUB should use images under the root directory. If you want GRUB to use images under a directory other than the root directory, you need to specify the option --root-directory. The typical usage is that you create a GRUB boot floppy with a filesystem. Here is an example:
# mke2fs /dev/fd0 # mount -t ext2 /dev/fd0 /mnt # grub-install --root-directory=/mnt fd0 # umount /mnt
Another example is when you have a separate boot partition which is mounted at /boot. Since GRUB is a boot loader, it doesn't know anything about mountpoints at all. Thus, you need to run grub-install like this:
# grub-install --root-directory=/boot /dev/hda
By the way, as noted above, it is quite difficult to guess BIOS drives correctly under a UNIX-like OS. Thus, grub-install will prompt you to check if it could really guess the correct mappings, after the installation. The format is defined in Device map. Please be quite careful. If the output is wrong, it is unlikely that your computer will be able to boot with no problem.
Note that grub-install is actually just a shell script and the real task is done by the grub shell grub (see Invoking the grub shell). Therefore, you may run grub directly to install GRUB, without using grub-install. Don't do that, however, unless you are very familiar with the internals of GRUB. Installing a boot loader on a running OS may be extremely dangerous.
GRUB supports the no emulation mode in the El Torito specification5. This means that you can use the whole CD-ROM from GRUB and you don't have to make a floppy or hard disk image file, which can cause compatibility problems.
For booting from a CD-ROM, GRUB uses a special Stage 2 called stage2_eltorito. The only GRUB files you need to have in your bootable CD-ROM are this stage2_eltorito and optionally a config file menu.lst. You don't need to use stage1 or stage2, because El Torito is quite different from the standard boot process.
Here is an example of procedures to make a bootable CD-ROM image. First, make a top directory for the bootable image, say, `iso':
$ mkdir iso
Make a directory for GRUB:
$ mkdir -p iso/boot/grub
Copy the file stage2_eltorito:
$ cp /usr/lib/grub/i386-pc/stage2_eltorito iso/boot/grub
If desired, make the config file menu.lst under iso/boot/grub (see Configuration), and copy any files and directories for the disc to the directory iso/.
Finally, make a ISO9660 image file like this:
$ mkisofs -R -b boot/grub/stage2_eltorito -no-emul-boot \ -boot-load-size 4 -boot-info-table -o grub.iso iso
This produces a file named grub.iso, which then can be burned into a CD (or a DVD). mkisofs has already set up the disc to boot from the boot/grub/stage2_eltorito file, so there is no need to setup GRUB on the disc. (Note that the -boot-load-size 4 bit is required for compatibility with the BIOS on many older machines.)
You can use the device `(cd)' to access a CD-ROM in your config file. This is not required; GRUB automatically sets the root device to `(cd)' when booted from a CD-ROM. It is only necessary to refer to `(cd)' if you want to access other drives as well.
GRUB can load Multiboot-compliant kernels in a consistent way, but for some free operating systems you need to use some OS-specific magic.
GRUB has two distinct boot methods. One of the two is to load an operating system directly, and the other is to chain-load another boot loader which then will load an operating system actually. Generally speaking, the former is more desirable, because you don't need to install or maintain other boot loaders and GRUB is flexible enough to load an operating system from an arbitrary disk/partition. However, the latter is sometimes required, since GRUB doesn't support all the existing operating systems natively.
Multiboot (see Multiboot Specification) is the native format supported by GRUB. For the sake of convenience, there is also support for Linux, FreeBSD, NetBSD and OpenBSD. If you want to boot other operating systems, you will have to chain-load them (see Chain-loading).
Generally, GRUB can boot any Multiboot-compliant OS in the following steps:
Linux, FreeBSD, NetBSD and OpenBSD can be booted in a similar manner. You load a kernel image with the command kernel and then run the command boot. If the kernel requires some parameters, just append the parameters to kernel, after the file name of the kernel. Also, please refer to OS-specific notes, for information on your OS-specific issues.
If you want to boot an unsupported operating system (e.g. Windows 95), chain-load a boot loader for the operating system. Normally, the boot loader is embedded in the boot sector of the partition on which the operating system is installed.
grub> rootnoverify (hd0,0)
grub> chainloader +1
`+1' indicates that GRUB should read one sector from the start of the partition. The complete description about this syntax can be found in Block list syntax.
However, DOS and Windows have some deficiencies, so you might have to use more complicated instructions. See DOS/Windows, for more information.
Here, we describe some caveats on several operating systems.
Since GNU/Hurd is Multiboot-compliant, it is easy to boot it; there is nothing special about it. But do not forget that you have to specify a root partition to the kernel.
find /boot/gnumachor similar can help you (see find).
grub> kernel /boot/gnumach root=hd0s1 grub> module /boot/serverboot
It is relatively easy to boot GNU/Linux from GRUB, because it somewhat resembles to boot a Multiboot-compliant OS.
find /vmlinuzor similar can help you (see find).
grub> kernel /vmlinuz root=/dev/hda1
If you need to specify some kernel parameters, just append them to the command. For example, to set vga to `ext', do this:
grub> kernel /vmlinuz root=/dev/hda1 vga=ext
See the documentation in the Linux source tree for complete information on the available options.
grub> initrd /initrd
Caution: If you use an initrd and specify the `mem=' option to the kernel to let it use less than actual memory size, you will also have to specify the same memory size to GRUB. To let GRUB know the size, run the command uppermem before loading the kernel. See uppermem, for more information.
GRUB can load the kernel directly, either in ELF or a.out format. But this is not recommended, since FreeBSD's bootstrap interface sometimes changes heavily, so GRUB can't guarantee to pass kernel parameters correctly.
Thus, we'd recommend loading the very flexible loader /boot/loader instead. See this example:
grub> root (hd0,a) grub> kernel /boot/loader grub> boot
GRUB can load NetBSD a.out and ELF directly, follow these steps:
grub> kernel --type=netbsd /netbsd-elf
For now, however, GRUB doesn't allow you to pass kernel parameters, so it may be better to chain-load it instead. For more information, please see Chain-loading.
The booting instruction is exactly the same as for NetBSD (see NetBSD).
GRUB cannot boot DOS or Windows directly, so you must chain-load them (see Chain-loading). However, their boot loaders have some critical deficiencies, so it may not work to just chain-load them. To overcome the problems, GRUB provides you with two helper functions.
If you have installed DOS (or Windows) on a non-first hard disk, you have to use the disk swapping technique, because that OS cannot boot from any disks but the first one. The workaround used in GRUB is the command map (see map), like this:
grub> map (hd0) (hd1) grub> map (hd1) (hd0)
This performs a virtual swap between your first and second hard drive.
Caution: This is effective only if DOS (or Windows) uses BIOS to access the swapped disks. If that OS uses a special driver for the disks, this probably won't work.
Another problem arises if you installed more than one set of DOS/Windows onto one disk, because they could be confused if there are more than one primary partitions for DOS/Windows. Certainly you should avoid doing this, but there is a solution if you do want to do so. Use the partition hiding/unhiding technique.
If GRUB hides a DOS (or Windows) partition (see hide), DOS (or Windows) will ignore the partition. If GRUB unhides a DOS (or Windows) partition (see unhide), DOS (or Windows) will detect the partition. Thus, if you have installed DOS (or Windows) on the first and the second partition of the first hard disk, and you want to boot the copy on the first partition, do the following:
grub> unhide (hd0,0) grub> hide (hd0,1) grub> rootnoverify (hd0,0) grub> chainloader +1 grub> makeactive grub> boot
It is known that the signature in the boot loader for SCO UnixWare is wrong, so you will have to specify the option --force to chainloader (see chainloader), like this:
grub> rootnoverify (hd1,0) grub> chainloader --force +1 grub> makeactive grub> boot
QNX seems to use a bigger boot loader, so you need to boot it up, like this:
grub> rootnoverify (hd1,1) grub> chainloader +4 grub> boot
When you test a new kernel or a new OS, it is important to make sure that your computer can boot even if the new system is unbootable. This is crucial especially if you maintain servers or remote systems. To accomplish this goal, you need to set up two things:
The former requirement is very specific to each OS, so this documentation does not cover that topic. It is better to consult some backup tools.
So let's see the GRUB part. There are two possibilities: one of them is quite simple but not very robust, and the other is a bit complex to set up but probably the best solution to make sure that your system can start as long as GRUB itself is bootable.
You can teach GRUB to boot an entry only at next boot time. Suppose that your have an old kernel old_kernel and a new kernel new_kernel. You know that old_kernel can boot your system correctly, and you want to test new_kernel.
To ensure that your system will go back to the old kernel even if the new kernel fails (e.g. it panics), you can specify that GRUB should try the new kernel only once and boot the old kernel after that.
First, modify your configuration file. Here is an example:
default saved # This is important!!! timeout 10 title the old kernel root (hd0,0) kernel /old_kernel savedefault title the new kernel root (hd0,0) kernel /new_kernel savedefault 0 # This is important!!!
Note that this configuration file uses `default saved' (see default) at the head and `savedefault 0' (see savedefault) in the entry for the new kernel. This means that GRUB boots a saved entry by default, and booting the entry for the new kernel saves `0' as the saved entry.
With this configuration file, after all, GRUB always tries to boot the
old kernel after it booted the new one, because `0' is the entry
the old kernel.
The next step is to tell GRUB to boot the new kernel at next boot time. For this, execute grub-set-default (see Invoking grub-set-default):
# grub-set-default 1
This command sets the saved entry to `1', that is, to the new kernel.
This method is useful, but still not very robust, because GRUB stops booting, if there is any error in the boot entry, such that the new kernel has an invalid executable format. Thus, it it even better to use the fallback mechanism of GRUB. Look at next subsection for this feature.
GRUB supports a fallback mechanism of booting one or more other entries if a default boot entry fails. You can specify multiple fallback entries if you wish.
Suppose that you have three systems, `A', `B' and `C'. `A' is a system which you want to boot by default. `B' is a backup system which is supposed to boot safely. `C' is another backup system which is used in case where `B' is broken.
Then you may want GRUB to boot the first system which is bootable among `A', `B' and `C'. A configuration file can be written in this way:
default saved # This is important!!! timeout 10 fallback 1 2 # This is important!!! title A root (hd0,0) kernel /kernel savedefault fallback # This is important!!! title B root (hd1,0) kernel /kernel savedefault fallback # This is important!!! title C root (hd2,0) kernel /kernel savedefault
Note that `default saved' (see default), `fallback 1 2' and `savedefault fallback' are used. GRUB will boot a saved entry by default and save a fallback entry as next boot entry with this configuration.
When GRUB tries to boot `A', GRUB saves `1' as next boot entry, because the command fallback specifies that `1' is the first fallback entry. The entry `1' is `B', so GRUB will try to boot `B' at next boot time.
Likewise, when GRUB tries to boot `B', GRUB saves `2' as next boot entry, because fallback specifies `2' as next fallback entry. This makes sure that GRUB will boot `C' after booting `B'.
It is noteworthy that GRUB uses fallback entries both when GRUB itself fails in booting an entry and when `A' or `B' fails in starting up your system. So this solution ensures that your system is started even if GRUB cannot find your kernel or if your kernel panics.
However, you need to run grub-set-default (see Invoking grub-set-default) when `A' starts correctly or you fix `A' after it crashes, since GRUB always sets next boot entry to a fallback entry. You should run this command in a startup script such as rc.local to boot `A' by default:
# grub-set-default 0
where `0' is the number of the boot entry for the system `A'.
If you want to see what is current default entry, you can look at the file /boot/grub/default (or /grub/default in some systems). Because this file is plain-text, you can just cat this file. But it is strongly recommended not to modify this file directly, because GRUB may fail in saving a default entry in this file, if you change this file in an unintended manner. Therefore, you should use grub-set-default when you need to change the default entry.
You've probably noticed that you need to type several commands to boot your OS. There's a solution to that - GRUB provides a menu interface (see Menu interface) from which you can select an item (using arrow keys) that will do everything to boot an OS.
To enable the menu, you need a configuration file, menu.lst under the boot directory. We'll analyze an example file.
The file first contains some general settings, the menu interface related options. You can put these commands (see Menu-specific commands) before any of the items (starting with title (see title)).
# # Sample boot menu configuration file #
As you may have guessed, these lines are comments. Lines starting with a hash character (`#'), and blank lines, are ignored by GRUB.
# By default, boot the first entry. default 0
The first entry (here, counting starts with number zero, not one!) will be the default choice.
# Boot automatically after 30 secs. timeout 30
As the comment says, GRUB will boot automatically in 30 seconds, unless interrupted with a keypress.
# Fallback to the second entry. fallback 1
If, for any reason, the default entry doesn't work, fall back to the second one (this is rarely used, for obvious reasons).
Note that the complete descriptions of these commands, which are menu interface specific, can be found in Menu-specific commands. Other descriptions can be found in Commands.
Now, on to the actual OS definitions. You will see that each entry begins with a special command, title (see title), and the action is described after it. Note that there is no command boot (see boot) at the end of each item. That is because GRUB automatically executes boot if it loads other commands successfully.
The argument for the command title is used to display a short title/description of the entry in the menu. Since title displays the argument as is, you can write basically anything there.
# For booting GNU/Hurd title GNU/Hurd root (hd0,0) kernel /boot/gnumach.gz root=hd0s1 module /boot/serverboot.gz
This boots GNU/Hurd from the first hard disk.
# For booting GNU/Linux title GNU/Linux kernel (hd1,0)/vmlinuz root=/dev/hdb1
This boots GNU/Linux, but from the second hard disk.
# For booting Mach (getting kernel from floppy) title Utah Mach4 multiboot root (hd0,2) pause Insert the diskette now^G!! kernel (fd0)/boot/kernel root=hd0s3 module (fd0)/boot/bootstrap
This boots Mach with a kernel on a floppy, but the root filesystem at hd0s3. It also contains a pause line (see pause), which will cause GRUB to display a prompt and delay, before actually executing the rest of the commands and booting.
# For booting FreeBSD title FreeBSD root (hd0,2,a) kernel /boot/loader
This item will boot FreeBSD kernel loaded from the `a' partition of the third pc slice of the first hard disk.
# For booting OS/2 title OS/2 root (hd0,1) makeactive # chainload OS/2 bootloader from the first sector chainloader +1 # This is similar to "chainload", but loads a specific file #chainloader /boot/chain.os2
This will boot OS/2, using a chain-loader (see Chain-loading).
# For booting Windows NT or Windows95 title Windows NT / Windows 95 boot menu root (hd0,0) makeactive chainloader +1 # For loading DOS if Windows NT is installed # chainload /bootsect.dos
The same as the above, but for Windows.
# For installing GRUB into the hard disk title Install GRUB into the hard disk root (hd0,0) setup (hd0)
This will just (re)install GRUB onto the hard disk.
# Change the colors. title Change the colors color light-green/brown blink-red/blue
In the last entry, the command color is used (see color), to change the menu colors (try it!). This command is somewhat special, because it can be used both in the command-line and in the menu. GRUB has several such commands, see General commands.
We hope that you now understand how to use the basic features of GRUB. To learn more about GRUB, see the following chapters.
Although GRUB is a disk-based boot loader, it does provide network support. To use the network support, you need to enable at least one network driver in the GRUB build process. For more information please see netboot/README.netboot in the source distribution.
GRUB requires a file server and optionally a server that will assign an IP address to the machine on which GRUB is running. For the former, only TFTP is supported at the moment. The latter is either BOOTP, DHCP or a RARP server7. It is not necessary to run both the servers on one computer. How to configure these servers is beyond the scope of this document, so please refer to the manuals specific to those protocols/servers.
If you decided to use a server to assign an IP address, set up the server and run bootp (see bootp), dhcp (see dhcp) or rarp (see rarp) for BOOTP, DHCP or RARP, respectively. Each command will show an assigned IP address, a netmask, an IP address for your TFTP server and a gateway. If any of the addresses is wrong or it causes an error, probably the configuration of your servers isn't set up properly.
Otherwise, run ifconfig, like this:
grub> ifconfig --address=192.168.110.23 --server=192.168.110.14
You can also use ifconfig in conjuction with bootp, dhcp or rarp (e.g. to reassign the server address manually). See ifconfig, for more details.
Finally, download your OS images from your network. The network can be accessed using the network drive `(nd)'. Everything else is very similar to the normal instructions (see Booting).
Here is an example:
grub> bootp Probing... [NE*000] NE2000 base ... Address: 192.168.110.23 Netmask: 255.255.255.0 Server: 192.168.110.14 Gateway: 192.168.110.1 grub> root (nd) grub> kernel /tftproot/gnumach.gz root=sd0s1 grub> module /tftproot/serverboot.gz grub> boot
It is sometimes very useful to boot from a network, especially when you use a machine which has no local disk. In this case, you need to obtain a kind of Net Boot rom, such as a PXE rom or a free software package like Etherboot. Such a Boot rom first boots the machine, sets up the network card installed into the machine, and downloads a second stage boot image from the network. Then, the second image will try to boot an operating system actually from the network.
GRUB provides two second stage images, nbgrub and pxegrub (see Images). These images are the same as the normal Stage 2, except that they set up a network automatically, and try to load a configuration file from the network, if specified. The usage is very simple: If the machine has a PXE rom, use pxegrub. If the machine has an NBI loader such as Etherboot, use nbgrub. There is no difference between them except their formats. Since the way to load a second stage image you want to use should be described in the manual on your Net Boot rom, please refer to the manual, for more information.
However, there is one thing specific to GRUB. Namely, how to specify a configuration file in a BOOTP/DHCP server. For now, GRUB uses the tag `150', to get the name of a configuration file. The following is an example with a BOOTP configuration:
.allhost:hd=/tmp:bf=null:\ :ds=22.214.171.124 126.96.36.199:\ :sm=255.255.254.0:\ :gw=188.8.131.52:\ :sa=184.108.40.206: foo:ht=1:ha=63655d0334a7:ip=220.127.116.11:\ :bf=/nbgrub:\ :tc=.allhost:\ :T150="(nd)/tftpboot/menu.lst.foo":
Note that you should specify the drive name
(nd) in the name of
the configuration file. This is because you might change the root drive
before downloading the configuration from the TFTP server when the
preset menu feature is used (see Preset Menu).
See the manual of your BOOTP/DHCP server for more information. The exact syntax should differ a little from the example.
This chapter describes how to use the serial terminal support in GRUB.
If you have many computers or computers with no display/keyboard, it could be very useful to control the computers through serial communications. To connect one computer with another via a serial line, you need to prepare a null-modem (cross) serial cable, and you may need to have multiport serial boards, if your computer doesn't have extra serial ports. In addition, a terminal emulator is also required, such as minicom. Refer to a manual of your operating system, for more information.
As for GRUB, the instruction to set up a serial terminal is quite simple. First of all, make sure that you haven't specified the option --disable-serial to the configure script when you built your GRUB images. If you get them in binary form, probably they have serial terminal support already.
Then, initialize your serial terminal after GRUB starts up. Here is an example:
grub> serial --unit=0 --speed=9600 grub> terminal serial
The command serial initializes the serial unit 0 with the speed 9600bps. The serial unit 0 is usually called `COM1', so, if you want to use COM2, you must specify `--unit=1' instead. This command accepts many other options, so please refer to serial, for more details.
The command terminal (see terminal) chooses which type of
terminal you want to use. In the case above, the terminal will be a
serial terminal, but you can also pass
console to the command,
as `terminal serial console'. In this case, a terminal in which
you press any key will be selected as a GRUB terminal.
However, note that GRUB assumes that your terminal emulator is compatible with VT100 by default. This is true for most terminal emulators nowadays, but you should pass the option --dumb to the command if your terminal emulator is not VT100-compatible or implements few VT100 escape sequences. If you specify this option then GRUB provides you with an alternative menu interface, because the normal menu requires several fancy features of your terminal.
GRUB supports a preset menu which is to be always loaded before starting. The preset menu feature is useful, for example, when your computer has no console but a serial cable. In this case, it is critical to set up the serial terminal as soon as possible, since you cannot see any message until the serial terminal begins to work. So it is good to run the commands serial (see serial) and terminal (see terminal) before anything else at the start-up time.
How the preset menu works is slightly complicated:
To enable the preset menu feature, you must rebuild GRUB specifying a file to the configure script with the option --enable-preset-menu. The file has the same semantics as normal configuration files (see Configuration).
Another point you should take care is that the diskless support (see Diskless) diverts the preset menu. Diskless images embed a preset menu to execute the command bootp (see bootp) automatically, unless you specify your own preset menu to the configure script. This means that you must put commands to initialize a network in the preset menu yourself, because diskless images don't set it up implicitly, when you use the preset menu explicitly.
Therefore, a typical preset menu used with diskless support would be like this:
# Set up the serial terminal, first of all. serial --unit=0 --speed=19200 terminal --timeout=0 serial # Initialize the network. dhcp
You may be interested in how to prevent ordinary users from doing whatever they like, if you share your computer with other people. So this chapter describes how to improve the security of GRUB.
One thing which could be a security hole is that the user can do too many things with GRUB, because GRUB allows one to modify its configuration and run arbitrary commands at run-time. For example, the user can even read /etc/passwd in the command-line interface by the command cat (see cat). So it is necessary to disable all the interactive operations.
Thus, GRUB provides a password feature, so that only administrators can start the interactive operations (i.e. editing menu entries and entering the command-line interface). To use this feature, you need to run the command password in your configuration file (see password), like this:
password --md5 PASSWORD
If this is specified, GRUB disallows any interactive control, until you press the key <p> and enter a correct password. The option --md5 tells GRUB that `PASSWORD' is in MD5 format. If it is omitted, GRUB assumes the `PASSWORD' is in clear text.
You can encrypt your password with the command md5crypt (see md5crypt). For example, run the grub shell (see Invoking the grub shell), and enter your password:
grub> md5crypt Password: ********** Encrypted: $1$U$JK7xFegdxWH6VuppCUSIb.
Then, cut and paste the encrypted password to your configuration file.
Also, you can specify an optional argument to password. See this example:
password PASSWORD /boot/grub/menu-admin.lst
In this case, GRUB will load /boot/grub/menu-admin.lst as a configuration file when you enter the valid password.
Another thing which may be dangerous is that any user can choose any menu entry. Usually, this wouldn't be problematic, but you might want to permit only administrators to run some of your menu entries, such as an entry for booting an insecure OS like DOS.
GRUB provides the command lock (see lock). This command always fails until you enter the valid password, so you can use it, like this:
title Boot DOS lock rootnoverify (hd0,1) makeactive chainload +1
You should insert lock right after title, because any user can execute commands in an entry until GRUB encounters lock.
You can also use the command password instead of lock. In this case the boot process will ask for the password and stop if it was entered incorrectly. Since the password takes its own PASSWORD argument this is useful if you want different passwords for different entries.
GRUB consists of several images: two essential stages, optional stages called Stage 1.5, one image for bootable CD-ROM, and two network boot images. Here is a short overview of them. See Internals, for more details.
All stage1 must do is to load Stage 2 or Stage 1.5 from a local
disk. Because of the size restriction, stage1 encodes the
location of Stage 2 (or Stage 1.5) in a block list format, so it never
understand any filesystem structure.
While Stage 2 cannot generally be embedded in a fixed area as the size
is so large, Stage 1.5 can be installed into the area right after an MBR,
or the boot loader area of a ReiserFS or a FFS.
GRUB uses a special syntax for specifying disk drives which can be accessed by BIOS. Because of BIOS limitations, GRUB cannot distinguish between IDE, ESDI, SCSI, or others. You must know yourself which BIOS device is equivalent to which OS device. Normally, that will be clear if you see the files in a device or use the command find (see find).
The device syntax is like this:
`' means the parameter is optional. device should be either `fd' or `hd' followed by a digit, like `fd0'. But you can also set device to a hexadecimal or a decimal number which is a BIOS drive number, so the following are equivalent:
(hd0) (0x80) (128)
part-num represents the partition number of device, starting from zero for primary partitions and from four for extended partitions, and bsd-subpart-letter represents the BSD disklabel subpartition, such as `a' or `e'.
A shortcut for specifying BSD subpartitions is
), in this case, GRUB
searches for the first PC partition containing a BSD disklabel, then
finds the subpartition bsd-subpart-letter. Here is an example:
The syntax `(hd0)' represents using the entire disk (or the MBR when installing GRUB), while the syntax `(hd0,0)' represents using the first partition of the disk (or the boot sector of the partition when installing GRUB).
If you enabled the network support, the special drive, `(nd)', is also available. Before using the network drive, you must initialize the network. See Network, for more information.
If you boot GRUB from a CD-ROM, `(cd)' is available. See Making a GRUB bootable CD-ROM, for details.
There are two ways to specify files, by absolute file name and by block list.
An absolute file name resembles a Unix absolute file name, using
`/' for the directory separator (not `\' as in DOS). One
example is `(hd0,0)/boot/grub/menu.lst'. This means the file
/boot/grub/menu.lst in the first partition of the first hard
disk. If you omit the device name in an absolute file name, GRUB uses
GRUB's root device implicitly. So if you set the root device to,
say, `(hd1,0)' by the command root (see root), then
/boot/kernel is the same as
A block list is used for specifying a file that doesn't appear in the
filesystem, like a chainloader. The syntax is
Here is an example:
This represents that GRUB should read blocks 0 through 99, block 200, and blocks 300 through 599. If you omit an offset, then GRUB assumes the offset is zero.
Like the file name syntax (see File name syntax), if a blocklist
does not contain a device name, then GRUB uses GRUB's root
(hd0,1)+1 is the same as
+1 when the root
device is `(hd0,1)'.
GRUB has both a simple menu interface for choosing preset entries from a configuration file, and a highly flexible command-line for performing any desired combination of boot commands.
GRUB looks for its configuration file as soon as it is loaded. If one is found, then the full menu interface is activated using whatever entries were found in the file. If you choose the command-line menu option, or if the configuration file was not found, then GRUB drops to the command-line interface.
The command-line interface provides a prompt and after it an editable text area much like a command-line in Unix or DOS. Each command is immediately executed after it is entered8. The commands (see Command-line and menu entry commands) are a subset of those available in the configuration file, used with exactly the same syntax.
Cursor movement and editing of the text on the line can be done via a subset of the functions available in the Bash shell:
When typing commands interactively, if the cursor is within or before the first word in the command-line, pressing the <TAB> key (or <C-i>) will display a listing of the available commands, and if the cursor is after the first word, the <TAB> will provide a completion listing of disks, partitions, and file names depending on the context. Note that to obtain a list of drives, one must open a parenthesis, as root (.
Note that you cannot use the completion functionality in the TFTP filesystem. This is because TFTP doesn't support file name listing for the security.
The menu interface is quite easy to use. Its commands are both reasonably intuitive and described on screen.
Basically, the menu interface provides a list of boot entries to the user to choose from. Use the arrow keys to select the entry of choice, then press <RET> to run it. An optional timeout is available to boot the default entry (the first one if not set), which is aborted by pressing any key.
Commands are available to enter a bare command-line by pressing <c> (which operates exactly like the non-config-file version of GRUB, but allows one to return to the menu if desired by pressing <ESC>) or to edit any of the boot entries by pressing <e>.
If you protect the menu interface with a password (see Security), all you can do is choose an entry by pressing <RET>, or press <p> to enter the password.
The menu entry editor looks much like the main menu interface, but the lines in the menu are individual commands in the selected entry instead of entry names.
If an <ESC> is pressed in the editor, it aborts all the changes made to the configuration entry and returns to the main menu interface.
When a particular line is selected, the editor places the user in a special version of the GRUB command-line to edit that line. When the user hits <RET>, GRUB replaces the line in question in the boot entry with the changes (unless it was aborted via <ESC>, in which case the changes are thrown away).
If you want to add a new line to the menu entry, press <o> if adding a line after the current line or press <O> if before the current line.
To delete a line, hit the key <d>. Although GRUB unfortunately does not support undo, you can do almost the same thing by just returning to the main menu.
When your terminal is dumb or you request GRUB to hide the menu interface explicitly with the command hiddenmenu (see hiddenmenu), GRUB doesn't show the menu interface (see Menu interface) and automatically boots the default entry, unless interrupted by pressing <ESC>.
When you interrupt the timeout and your terminal is dumb, GRUB falls back to the command-line interface (see Command-line interface).
In this chapter, we list all commands that are available in GRUB.
Commands belong to different groups. A few can only be used in the global section of the configuration file (or “menu”); most of them can be entered on the command-line and can be used either anywhere in the menu or specifically in the menu entries.
The semantics used in parsing the configuration file are the following:
These commands can only be used in the menu:
Set the default entry to the entry number num. Numbering starts from 0, and the entry number 0 is the default if the command is not used.
You can specify `saved' instead of a number. In this case, the default entry is the entry saved with the command savedefault. See savedefault, for more information.
Go into unattended boot mode: if the default boot entry has any errors, instead of waiting for the user to do something, immediately start over using the num entry (same numbering as the
defaultcommand (see default)). This obviously won't help if the machine was rebooted by a kernel that GRUB loaded. You can specify multiple fallback entry numbers.
Don't display the menu. If the command is used, no menu will be displayed on the control terminal, and the default entry will be booted after the timeout expired. The user can still request the menu to be displayed by pressing <ESC> before the timeout expires. See also Hidden menu interface.
Set a timeout, in sec seconds, before automatically booting the default entry (normally the first entry defined).
Start a new boot entry, and set its name to the contents of the rest of the line, starting with the first non-space character.
Commands usable anywhere in the menu and in the command-line.
Initialize a network device via the BOOTP protocol. This command is only available if GRUB is compiled with netboot support. See also Network.
If you specify --with-configfile to this command, GRUB will fetch and load a configuration file specified by your BOOTP server with the vendor tag `150'.
Change the menu colors. The color normal is used for most lines in the menu (see Menu interface), and the color highlight is used to highlight the line where the cursor points. If you omit highlight, then the inverted color of normal is used for the highlighted line. The format of a color is foreground
/background. foreground and background are symbolic color names. A symbolic color name must be one of these:
These below can be specified only for the foreground.
But only the first eight names can be used for background. You can prefix
blink-to foreground if you want a blinking foreground color.
This command can be used in the configuration file and on the command line, so you may write something like this in your configuration file:# Set default colors. color light-gray/blue black/light-gray # Change the colors. title OS-BS like color magenta/blue black/magenta
In the grub shell, specify the file file as the actual drive for a bios drive drive. You can use this command to create a disk image, and/or to fix the drives guessed by GRUB when GRUB fails to determine them correctly, like this:grub> device (fd0) /floppy-image grub> device (hd0) /dev/sd0
This command can be used only in the grub shell (see Invoking the grub shell).
Initialize a network device via the DHCP protocol. Currently, this command is just an alias for bootp, since the two protocols are very similar. This command is only available if GRUB is compiled with netboot support. See also Network.
If you specify --with-configfile to this command, GRUB will fetch and load a configuration file specified by your DHCP server with the vendor tag `150'.
Hide the partition partition by setting the hidden bit in its partition type code. This is useful only when booting DOS or Windows and multiple primary FAT partitions exist in one disk. See also DOS/Windows.
Configure the IP address, the netmask, the gateway, and the server address of a network device manually. The values must be in dotted decimal format, like `192.168.11.178'. The order of the options is not important. This command shows current network configuration, if no option is specified. See also Network.
Toggle or set the state of the internal pager. If flag is `on', the internal pager is enabled. If flag is `off', it is disabled. If no argument is given, the state is toggled.
Create a new primary partition. part is a partition specification in GRUB syntax (see Naming convention); type is the partition type and must be a number in the range
0-0xff; from is the starting address and len is the length, both in sector units.
Change the type of an existing partition. part is a partition specification in GRUB syntax (see Naming convention); type is the new partition type and must be a number in the range 0-0xff.
If used in the first section of a menu file, disable all interactive editing control (menu entry editor and command-line) and entries protected by the command lock. If the password passwd is entered, it loads the new-config-file as a new config file and restarts the GRUB Stage 2, if new-config-file is specified. Otherwise, GRUB will just unlock the privileged instructions. You can also use this command in the script section, in which case it will ask for the password, before continuing. The option --md5 tells GRUB that passwd is encrypted with md5crypt (see md5crypt).
Initialize a network device via the RARP protocol. This command is only available if GRUB is compiled with netboot support. See also Network.
Initialize a serial device. unit is a number in the range 0-3 specifying which serial port to use; default is 0, which corresponds to the port often called COM1. port is the I/O port where the UART is to be found; if specified it takes precedence over unit. speed is the transmission speed; default is 9600. word and stop are the number of data bits and stop bits. Data bits must be in the range 5-8 and stop bits must be 1 or 2. Default is 8 data bits and one stop bit. parity is one of `no', `odd', `even' and defaults to `no'. The option --device can only be used in the grub shell and is used to specify the tty device to be used in the host operating system (see Invoking the grub shell).
The serial port is not used as a communication channel unless the terminal command is used (see terminal).
This command is only available if GRUB is compiled with serial support. See also Serial terminal.
Change the keyboard map. The key from_key is mapped to the key to_key. If no argument is specified, reset key mappings. Note that this command does not exchange the keys. If you want to exchange the keys, run this command again with the arguments exchanged, like this:grub> setkey capslock control grub> setkey control capslock
A key must be an alphabet letter, a digit, or one of these symbols: `escape', `exclam', `at', `numbersign', `dollar', `percent', `caret', `ampersand', `asterisk', `parenleft', `parenright', `minus', `underscore', `equal', `plus', `backspace', `tab', `bracketleft', `braceleft', `bracketright', `braceright', `enter', `control', `semicolon', `colon', `quote', `doublequote', `backquote', `tilde', `shift', `backslash', `bar', `comma', `less', `period', `greater', `slash', `question', `alt', `space', `capslock', `FX' (`X' is a digit), and `delete'. This table describes to which character each of the symbols corresponds:
- ` '
Select a terminal for user interaction. The terminal is assumed to be VT100-compatible unless --dumb is specified. If both console and serial are specified, then GRUB will use the one where a key is entered first or the first when the timeout expires. If neither are specified, the current setting is reported. This command is only available if GRUB is compiled with serial support. See also Serial terminal.
This may not make sense for most users, but GRUB supports Hercules console as well. Hercules console is usable like the ordinary console, and the usage is quite similar to that for serial terminals: specify hercules as the argument.
The option --lines defines the number of lines in your terminal, and it is used for the internal pager function. If you don't specify this option, the number is assumed as 24.
The option --silent suppresses the message to prompt you to hit any key. This might be useful if your system has no terminal device.
The option --no-echo has GRUB not to echo back input characters. This implies the option --no-edit.
The option --no-edit disables the BASH-like editing feature.
Define the capabilities of your terminal. Use this command to define escape sequences, if it is not vt100-compatible. You may use `\e' for <ESC> and `^X' for a control character.
You can use the utility grub-terminfo to generate appropriate arguments to this command. See Invoking grub-terminfo.
If no option is specified, the current settings are printed.
Caution: This command exists only for backward compatibility. Use ifconfig (see ifconfig) instead.
Override a TFTP server address returned by a BOOTP/DHCP/RARP server. The argument ipaddr must be in dotted decimal format, like `192.168.0.15'. This command is only available if GRUB is compiled with netboot support. See also Network.
Unhide the partition partition by clearing the hidden bit in its partition type code. This is useful only when booting DOS or Windows and multiple primary partitions exist on one disk. See also DOS/Windows.
These commands are usable in the command-line and in menu entries. If you forget a command, you can run the command help (see help).
Print the block list notation of the file file. See Block list syntax.
Boot the OS or chain-loader which has been loaded. Only necessary if running the fully interactive command-line (it is implicit at the end of a menu entry).
Display the contents of the file file. This command may be useful to remind you of your OS's root partition:grub> cat /etc/fstab
Load file as a chain-loader. Like any other file loaded by the filesystem code, it can use the blocklist notation to grab the first sector of the current partition with `+1'. If you specify the option --force, then load file forcibly, whether it has a correct signature or not. This is required when you want to load a defective boot loader, such as SCO UnixWare 7.1 (see SCO UnixWare).
Compare the file file1 with the file file2. If they differ in size, print the sizes like this:Differ in size: 0x1234 [foo], 0x4321 [bar]
If the sizes are equal but the bytes at an offset differ, then print the bytes like this:Differ at the offset 777: 0xbe [foo], 0xef [bar]
If they are completely identical, nothing will be printed.
Toggle debug mode (by default it is off). When debug mode is on, some extra messages are printed to show disk activity. This global debug flag is mainly useful for GRUB developers when testing new code.
Display what GRUB thinks the system address space map of the machine is, including all regions of physical ram installed. GRUB's upper/lower memory display uses the standard BIOS interface for the available memory in the first megabyte, or lower memory, and a synthesized number from various BIOS interfaces of the memory starting at 1MB and going up to the first chipset hole for upper memory (the standard PC upper memory interface is limited to reporting a maximum of 64MB).
Search for the file name filename in all mountable partitions and print the list of the devices which contain the file. The file name filename should be an absolute file name like
Toggle filesystem test mode. Filesystem test mode, when turned on, prints out data corresponding to all the device reads and what values are being sent to the low-level routines. The format is `<partition-offset-sector, byte-offset, byte-length>' for high-level reads inside a partition, and `[disk-offset-sector]' for low-level sector requests from the disk. Filesystem test mode is turned off by any use of the install (see install) or testload (see testload) commands.
Print the information for the drive drive. In the grub shell, you can set the geometry of the drive arbitrarily. The number of cylinders, the number of heads, the number of sectors and the number of total sectors are set to CYLINDER, HEAD, SECTOR and TOTAL_SECTOR, respectively. If you omit TOTAL_SECTOR, then it will be calculated based on the C/H/S values automatically.
The command halts the computer. If the --no-apm option is specified, no APM BIOS call is performed. Otherwise, the computer is shut down using APM.
Display helpful information about builtin commands. If you do not specify pattern, this command shows short descriptions of most of available commands. If you specify the option --all to this command, short descriptions of rarely used commands (such as testload) are displayed as well.
If you specify any patterns, it displays longer information about each of the commands which match those patterns.
Probe the Intel Multiprocessor Specification 1.1 or 1.4 configuration table and boot the various CPUs which are found into a tight loop. This command can be used only in the Stage 2, but not in the grub shell.
Load an initial ramdisk for a Linux format boot image and set the appropriate parameters in the Linux setup area in memory. See also GNU/Linux.
This command is fairly complex, and you should not use this command unless you are familiar with GRUB. Use setup (see setup) instead.
In short, it will perform a full install presuming the Stage 2 or Stage 1.510 is in its final install location.
In slightly more detail, it will load stage1_file, validate that it is a GRUB Stage 1 of the right version number, install in it a blocklist for loading stage2_file as a Stage 2. If the option d is present, the Stage 1 will always look for the actual disk stage2_file was installed on, rather than using the booting drive. The Stage 2 will be loaded at address addr, which must be `0x8000' for a true Stage 2, and `0x2000' for a Stage 1.5. If addr is not present, GRUB will determine the address automatically. It then writes the completed Stage 1 to the first block of the device dest_dev. If the options p or config_file are present, then it reads the first block of stage2, modifies it with the values of the partition stage2_file was found on (for p) or places the string config_file into the area telling the stage2 where to look for a configuration file at boot time. Likewise, if real_config_file is present and stage2_file is a Stage 1.5, then the Stage 2 config_file is patched with the configuration file name real_config_file. This command preserves the DOS BPB (and for hard disks, the partition table) of the sector the Stage 1 is to be installed into.
Caution: Several buggy BIOSes don't pass a booting drive properly when booting from a hard disk drive. Therefore, you will unfortunately have to specify the option d, whether your Stage2 resides at the booting drive or not, if you have such a BIOS. We know these are defective in this way:
- Fujitsu LifeBook 400 BIOS version 31J0103A
- HP Vectra XU 6/200 BIOS version GG.06.11
Caution2: A number of BIOSes don't return a correct LBA support bitmap even if they do have the support. So GRUB provides a solution to ignore the wrong bitmap, that is, the option --force-lba. Don't use this option if you know that your BIOS doesn't have LBA support.
Caution3: You must specify the option --stage2 in the grub shell, if you cannot unmount the filesystem where your stage2 file resides. The argument should be the file name in your operating system.
Probe I/O ports used for the drive drive. This command will list the I/O ports on the screen. For technical information, See Internals.
Attempt to load the primary boot image (Multiboot a.out or elf, Linux zImage or bzImage, FreeBSD a.out, NetBSD a.out, etc.) from file. The rest of the line is passed verbatim as the kernel command-line. Any modules must be reloaded after using this command.
This command also accepts the option --type so that you can specify the kernel type of file explicitly. The argument type must be one of these: `netbsd', `freebsd', `openbsd', `linux', `biglinux', and `multiboot'. However, you need to specify it only if you want to load a NetBSD elf kernel, because GRUB can automatically determine a kernel type in the other cases, quite safely.
The option --no-mem-option is effective only for Linux. If the option is specified, GRUB doesn't pass the option mem= to the kernel. This option is implied for Linux kernels 2.4.18 and newer.
Prevent normal users from executing arbitrary menu entries. You must use the command password if you really want this command to be useful (see password).
This command is used in a menu, as shown in this example:title This entry is too dangerous to be executed by normal users lock root (hd0,a) kernel /no-security-os
See also Security.
Set the active partition on the root disk to GRUB's root device. This command is limited to primary PC partitions on a hard disk.
Map the drive from_drive to the drive to_drive. This is necessary when you chain-load some operating systems, such as DOS, if such an OS resides at a non-first drive. Here is an example:grub> map (hd0) (hd1) grub> map (hd1) (hd0)
The example exchanges the order between the first hard disk and the second hard disk. See also DOS/Windows.
Load a boot module file for a Multiboot format boot image (no interpretation of the file contents are made, so the user of this command must know what the kernel in question expects). The rest of the line is passed as the module command-line, like the kernel command. You must load a Multiboot kernel image before loading any module. See also modulenounzip.
The same as module (see module), except that automatic decompression is disabled.
Print the message, then wait until a key is pressed. Note that placing <^G> (ASCII code 7) in the message will cause the speaker to emit the standard beep sound, which is useful when prompting the user to change floppies.
Exit from the grub shell grub (see Invoking the grub shell). This command can be used only in the grub shell.
Set the current root device to the device device, then attempt to mount it to get the partition size (for passing the partition descriptor in
ES:ESI, used by some chain-loaded boot loaders), the BSD drive-type (for booting BSD kernels using their native boot format), and correctly determine the PC partition where a BSD sub-partition is located. The optional hdbias parameter is a number to tell a BSD kernel how many BIOS drive numbers are on controllers before the current one. For example, if there is an IDE disk and a SCSI disk, and your FreeBSD root partition is on the SCSI disk, then use a `1' for hdbias.
See also rootnoverify.
Similar to root (see root), but don't attempt to mount the partition. This is useful for when an OS is outside of the area of the disk that GRUB can read, but setting the correct root device is still desired. Note that the items mentioned in root above which derived from attempting the mount will not work correctly.
Save the current menu entry or num if specified as a default entry. Here is an example:default saved timeout 10 title GNU/Linux root (hd0,0) kernel /boot/vmlinuz root=/dev/sda1 vga=ext initrd /boot/initrd savedefault title FreeBSD root (hd0,a) kernel /boot/loader savedefault
With this configuration, GRUB will choose the entry booted previously as the default entry.
You can specify `fallback' instead of a number. Then, next fallback entry is saved. Next fallback entry is chosen from fallback entries. Normally, this will be the first entry in fallback ones.
Set up the installation of GRUB automatically. This command uses the more flexible command install (see install) in the backend and installs GRUB into the device install_device. If image_device is specified, then find the GRUB images (see Images) in the device image_device, otherwise use the current root device, which can be set by the command root. If install_device is a hard disk, then embed a Stage 1.5 in the disk if possible.
The option --prefix specifies the directory under which GRUB images are put. If it is not specified, GRUB automatically searches them in /boot/grub and /grub.
The options --force-lba and --stage2 are just passed to install if specified. See install, for more information.
Read the entire contents of file in several different ways and compare them, to test the filesystem code. The output is somewhat cryptic, but if no errors are reported and the final `i=X, filepos=Y' reading has X and Y equal, then it is definitely consistent, and very likely works correctly subject to a consistent offset error. If this test succeeds, then a good next step is to try loading a kernel.
Test the VESA BIOS EXTENSION mode mode. This command will switch your video card to the graphics mode, and show an endless animation. Hit any key to return. See also vbeprobe.
Force GRUB to assume that only kbytes kilobytes of upper memory are installed. Any system address range maps are discarded.
Caution: This should be used with great caution, and should only be necessary on some old machines. GRUB's BIOS probe can pick up all ram on all new machines the author has ever heard of. It can also be used for debugging purposes to lie to an OS.
Probe VESA BIOS EXTENSION information. If the mode mode is specified, show only the information about mode. Otherwise, this command lists up available VBE modes on the screen. See also testvbe.
This chapter describes error messages reported by GRUB when you encounter trouble. See Invoking the grub shell, if your problem is specific to the grub shell.
The general way that the Stage 1 handles errors is to print an error string and then halt. Pressing <CTRL>-<ALT>-<DEL> will reboot.
The following is a comprehensive list of error messages for the Stage 1:
The general way that the Stage 1.5 handles errors is to print an error
number in the form
Error num and then halt. Pressing
<CTRL>-<ALT>-<DEL> will reboot.
The error numbers correspond to the errors reported by Stage 2. See Stage2 errors.
The general way that the Stage 2 handles errors is to abort the operation in question, print an error string, then (if possible) either continue based on the fact that an error occurred or wait for the user to deal with the error.
The following is a comprehensive list of error messages for the Stage 2 (error numbers for the Stage 1.5 are listed before the colon in each description):
This chapter documents the grub shell grub. Note that the grub shell is an emulator; it doesn't run under the native environment, so it sometimes does something wrong. Therefore, you shouldn't trust it too much. If there is anything wrong with it, don't hesitate to try the native GRUB environment, especially when it guesses a wrong map between BIOS drives and OS devices.
You can use the command grub for installing GRUB under your operating systems and for a testbed when you add a new feature into GRUB or when fixing a bug. grub is almost the same as the Stage 2, and, in fact, it shares the source code with the Stage 2 and you can use the same commands (see Commands) in grub. It is emulated by replacing BIOS calls with UNIX system calls and libc functions.
The command grub accepts the following options:
The installation procedure is the same as under the native Stage 2. See Installation, for more information. The command grub-specific information is described here.
What you should be careful about is buffer cache. grub makes use of raw devices instead of filesystems that your operating systems serve, so there exists a potential problem that some cache inconsistency may corrupt your filesystems. What we recommend is:
In addition, enter the command quit when you finish the installation. That is very important because quit makes the buffer cache consistent. Do not push <C-c>.
If you want to install GRUB non-interactively, specify `--batch' option in the command-line. This is a simple example:
#!/bin/sh # Use /usr/sbin/grub if you are on an older system. /sbin/grub --batch <<EOT 1>/dev/null 2>/dev/null root (hd0,0) setup (hd0) quit EOT
When you specify the option --device-map (see Basic usage), the grub shell creates the device map file automatically unless it already exists. The file name /boot/grub/device.map is preferred.
If the device map file exists, the grub shell reads it to map BIOS drives to OS devices. This file consists of lines like this:
device is a drive specified in the GRUB syntax (see Device syntax), and file is an OS file, which is normally a device file.
The reason why the grub shell gives you the device map file is that it cannot guess the map between BIOS drives and OS devices correctly in some environments. For example, if you exchange the boot sequence between IDE and SCSI in your BIOS, it gets the order wrong.
Thus, edit the file if the grub shell makes a mistake. You can put any comments in the file if needed, as the grub shell assumes that a line is just a comment if the first character is `#'.
The program grub-install installs GRUB on your drive using the grub shell (see Invoking the grub shell). You must specify the device name on which you want to install GRUB, like this:
The device name install_device is an OS device name or a GRUB device name.
grub-install accepts the following options:
grub-install --root-directory=/boot hd0
grub-install --grub-shell="grub --read-only" /dev/fd0
The program grub-md5-crypt encrypts a password in MD5 format. This is just a frontend of the grub shell (see Invoking the grub shell). Passwords encrypted by this program can be used with the command password (see password).
grub-md5-crypt accepts the following options:
The program grub-terminfo generates a terminfo command from a terminfo name (see terminfo). The result can be used in the configuration file, to define escape sequences. Because GRUB assumes that your terminal is vt100-compatible by default, this would be useful only if your terminal is uncommon (such as vt52).
grub-terminfo accepts the following options:
You must specify one argument to this command. For example:
The program grub-set-default sets the default boot entry for GRUB. This automatically creates a file named default under your GRUB directory (i.e. /boot/grub), if it is not present. This file is used to determine the default boot entry when GRUB boots up your system when you use `default saved' in your configuration file (see default), and to save next default boot entry when you use `savedefault' in a boot entry (see savedefault).
grub-set-default accepts the following options:
You must specify a single argument to grub-set-default. This argument is normally the number of a default boot entry. For example, if you have this configuration file:
default saved timeout 10 title GNU/Hurd root (hd0,0) ... title GNU/Linux root (hd0,1) ...
and if you want to set the next default boot entry to GNU/Linux, you may execute this command:
Because the entry for GNU/Linux is `1'. Note that entries are counted from zero. So, if you want to specify GNU/Hurd here, then you should specify `0'.
This feature is very useful if you want to test a new kernel or to make your system quite robust. See Making your system robust, for more hints about how to set up a robust system.
The program mbchk checks for the format of a Multiboot kernel. We recommend using this program before booting your own kernel by GRUB.
mbchk accepts the following options:
Caution: GRUB requires binutils-18.104.22.168.23 or later because the GNU assembler has been changed so that it can produce real 16bits machine code between 2.9.1 and 22.214.171.124.x. See http://sources.redhat.com/binutils/, to obtain information on how to get the latest version.
GRUB is available from the GNU alpha archive site ftp://alpha.gnu.org/gnu/grub or any of its mirrors. The file will be named grub-version.tar.gz. The current version is 0.97, so the file you should grab is:
To unbundle GRUB use the instruction:
zcat grub-0.97.tar.gz | tar xvf -
which will create a directory called grub-0.97 with all the sources. You can look at the file INSTALL for detailed instructions on how to build and install GRUB, but you should be able to just do:
cd grub-0.97 ./configure make install
This will install the grub shell grub (see Invoking the grub shell), the Multiboot checker mbchk (see Invoking mbchk), and the GRUB images. This will also install the GRUB manual.
Also, the latest version is available from the CVS. See http://savannah.gnu.org/cvs/?group=grub for more information.
These are the guideline for how to report bugs. Take a look at this list below before you submit bugs:
The information on your hardware is also essential. These are especially important: the geometries and the partition tables of your hard disk drives and your BIOS.
When you attach a patch, make the patch in unified diff format, and write ChangeLog entries. But, even when you make a patch, don't forget to explain the problem, so that we can understand what your patch is for.
If you follow the guideline above, submit a report to the Bug Tracking System. Alternatively, you can submit a report via electronic mail to firstname.lastname@example.org, but we strongly recommend that you use the Bug Tracking System, because e-mail can be passed over easily.
Once we get your report, we will try to fix the bugs.
We started the next generation of GRUB, GRUB 2. This will include internationalization, dynamic module loading, real memory management, multiple architecture support, a scripting language, and many other nice feature. If you are interested in the development of GRUB 2, take a look at the homepage.
This chapter documents the user-invisible aspect of GRUB.
As a general rule of software development, it is impossible to keep the descriptions of the internals up-to-date, and it is quite hard to document everything. So refer to the source code, whenever you are not satisfied with this documentation. Please assume that this gives just hints to you.
GRUB consists of two distinct components, called stages, which are loaded at different times in the boot process. Because they run mutual-exclusively, sometimes a memory area overlaps with another memory area. And, even in one stage, a single memory area can be used for various purposes, because their usages are mutually exclusive.
Here is the memory map of the various components:
See the file stage2/shared.h, for more information.
Stage 1 and Stage 2 have embedded variables whose locations are well-defined, so that the installation can patch the binary file directly without recompilation of the stages.
In Stage 1, these are defined:
See the file stage1/stage1.S, for more information.
In the first sector of Stage 1.5 and Stage 2, the block lists are
lastlist. The address of
lastlist is determined when assembling the file
The trick here is that it is actually read backward, and the first 8-byte block list is not read here, but after the pointer is decremented 8 bytes, then after reading it, it decrements again, reads, and so on, until it is finished. The terminating condition is when the number of sectors to be read in the next block list is zero.
The format of a block list can be seen from the example in the code just
firstlist label. Note that it is always from the
beginning of the disk, but not relative to the partition
In the second sector of Stage 1.5 and Stage 2, these are defined:
0x12+ the length of the version string
See the file stage2/asm.S, for more information.
For any particular partition, it is presumed that only one of the normal filesystems such as FAT, FFS, or ext2fs can be used, so there is a switch table managed by the functions in disk_io.c. The notation is that you can only mount one at a time.
The block list filesystem has a special place in the system. In addition to the normal filesystem (or even without one mounted), you can access disk blocks directly (in the indicated partition) via the block list notation. Using the block list filesystem doesn't effect any other filesystem mounts.
The variables which can be read by the filesystem backend are:
dirfunction should print the possible completions of a file, and false when it should try to actually open a file of that name.
The variables which need to be written by a filesystem backend are:
Caution: the value of filepos can be changed out from
under the filesystem code in the current implementation. Don't depend on
it being the same for later calls into the backend code!
NULLat all other times (it will be
NULLby default). If this isn't done correctly, then the testload and install commands won't work correctly.
The functions expected to be used by the filesystem backend are:
grub_readcan be used, after setting block_file to 1.
print_a_completionfor each possible file name. Otherwise, the file name completion won't work.
The functions expected to be defined by the filesystem backend are described at least moderately in the file filesys.h. Their usage is fairly evident from their use in the functions in disk_io.c, look for the use of the fsys_table array.
Caution: The semantics are such that then `mount'ing the
filesystem, presume the filesystem buffer
FSYS_BUF is corrupted,
and (re-)load all important contents. When opening and reading a file,
presume that the data from the `mount' is available, and doesn't
get corrupted by the open/read (i.e. multiple opens and/or reads will be
done with only one mount if in the same filesystem).
GRUB built-in commands are defined in a uniformal interface, whether they are menu-specific or can be used anywhere. The definition of a builtin command consists of two parts: the code itself and the table of the information.
The code must be a function which takes two arguments, a command-line string and flags, and returns an `int' value. The flags argument specifies how the function is called, using a bit mask. The return value must be zero if successful, otherwise non-zero. So it is normally enough to return errnum.
The table of the information is represented by the structure
struct builtin, which contains the name of the command, a pointer
to the function, flags, a short description of the command and a long
description of the command. Since the descriptions are used only for
help messages interactively, you don't have to define them, if the
command may not be called interactively (such as title).
The table is finally registered in the table builtin_table, so
enter_cmdline can find the
command. See the files cmdline.c and builtins.c, for more
The disk space can be used in a boot loader is very restricted because a MBR (see MBR) is only 512 bytes but it also contains a partition table (see Partition table) and a BPB. So the question is how to make a boot loader code enough small to be fit in a MBR.
However, GRUB is a very large program, so we break GRUB into 2 (or 3) distinct components, Stage 1 and Stage 2 (and optionally Stage 1.5). See Memory map, for more information.
We embed Stage 1 in a MBR or in the boot sector of a partition, and place Stage 2 in a filesystem. The optional Stage 1.5 can be installed in a filesystem, in the boot loader area in a FFS or a ReiserFS, and in the sectors right after a MBR, because Stage 1.5 is enough small and the sectors right after a MBR is normally an unused region. The size of this region is the number of sectors per head minus 1.
Thus, all Stage1 must do is just load Stage2 or Stage1.5. But even if Stage 1 needs not to support the user interface or the filesystem interface, it is impossible to make Stage 1 less than 400 bytes, because GRUB should support both the CHS mode and the LBA mode (see Low-level disk I/O).
The solution used by GRUB is that Stage 1 loads only the first sector of Stage 2 (or Stage 1.5) and Stage 2 itself loads the rest. The flow of Stage 1 is:
The flow of Stage 2 (and Stage 1.5) is:
Note that Stage 2 (or Stage 1.5) does not probe the geometry or the accessing mode of the loading drive, since Stage 1 has already probed them.
FIXME: I will write this chapter after implementing the new technique.
FIXME: I doubt if Erich didn't write this chapter only himself wholly, so I will rewrite this chapter.
FIXME: I'm not sure where some part of the original chapter is derived, so I will rewrite this chapter.
FIXME: Probably the original chapter is derived from "How It Works", so I will rewrite this chapter.
When you write patches for GRUB, please send them to the mailing list email@example.com. Here is the list of items of which you should take care:
current_drive: Filesystem interface
current_partition: Filesystem interface
current_slice: Filesystem interface
devread: Filesystem interface
disk_read_func: Filesystem interface
filemax: Filesystem interface
filepos: Filesystem interface
FSYS_BUF: Filesystem interface
grub_read: Filesystem interface
part_length: Filesystem interface
part_start: Filesystem interface
print_a_completion: Filesystem interface
print_possibilities: Filesystem interface
saved_drive: Filesystem interface
saved_partition: Filesystem interface
 chain-load is the mechanism for loading unsupported operating systems by loading another boot loader. It is typically used for loading DOS or Windows.
 There are a few pathological cases where loading a very badly organized ELF kernel might take longer, but in practice this never happen.
 The LInux LOader, a boot loader that everybody uses, but nobody likes.
 Note that GRUB's root device doesn't necessarily mean your OS's root partition; if you need to specify a root partition for your OS, add the argument into the command kernel.
 El Torito is a specification for bootable CD using BIOS functions.
 This is not necessary for most of the modern operating systems.
 RARP is not advised, since it cannot serve much information
 However, this behavior will be changed in the future version, in a user-invisible way.
 The latter feature has not been implemented yet.
 They're loaded the same way, so we will refer to the Stage 1.5 as a Stage 2 from now on.