Bootdisk-HOWTO@linuxdoc.org
Copyright © 1995-2002 by Tom Fawcett
v4.5, January 2002
This document describes how to design and build boot/root diskettes for Linux. These disks can be used as rescue disks or to test new system components. You should be reasonably familiar with system administration tasks before attempting to build a bootdisk. If you just want a rescue disk to have for emergencies, see Appendix A.1.
This document may be outdated. If the date on the title page is more than six months ago, please check the Bootdisk-HOWTO homepage to see if a more recent version exists. |
Although this document should be legible in its text form, it looks much better in Postscript, PDF or HTML forms because of the typographical conventions used.
Graham Chapman wrote the original Bootdisk-HOWTO and supported it through version 3.1. Tom Fawcett started as co-author around the time kernel v2 was introduced, and he is the document's current maintainer. Chapman has disappeared from the Linux community and his whereabouts are currently unknown.
This information is intended for Linux on the Intel platform. Much of this information may be applicable to Linux on other processors, but I have no first-hand experience or information about this. If you have experience with bootdisks on other platforms, please contact me.
User-mode-linux ( http://user-mode-linux.sourceforge.net) seems like a great way to test out bootdisks without having to reboot your machine constantly. I haven't been able to get it to work. If anyone has been using this consistently with homemade bootdisks, please let me know.
Re-analyze distribution bootdisks and update the "How the Pros do it" section.
Figure out just how much of the init-getty-login sequence can be simplified, and rip it out. A few people have said that init can be linked directly to /bin/sh; if so, and if this imposes no great limitations, alter the instructions to do this. This would eliminate the need for getty, login, gettydefs, and maybe all that PAM and NSS stuff.
Go through the 2.4 kernel source code again and write a detailed explanation of how the boot process and ramdisk-loading process work, in detail. (If only so that I understand it better.) There are some issues about initrd and limitations of booting devices (eg flash memory) that I don't understand yet.
Delete section that describes how to upgrade existing distribution bootdisks. This is usually more trouble than it's worth.
Replace rdev commands with LILO keywords.
I welcome any feedback, good or bad, on the content of this document. I have done my best to ensure that the instructions and information herein are accurate and reliable, but I don't know everything and I don't keep up on kernel development. Please let me know if you find errors or omissions. When writing, please indicate the version number of the document you're referencing. Be nice.
We thank the many people who assisted with corrections and suggestions. Their contributions have made it far better than we could ever have done alone.
Send comments and corrections to the author at the email address above. Please read Section 7 before asking me questions. Do not email me disk images.
Copyright © 1995-2002 by Tom Fawcett and Graham Chapman. This document may be distributed under the terms set forth in the Linux Documentation Project License. Please contact the authors if you are unable to get the license.
This is free documentation. It is distributed in the hope that it will be useful, but without any warranty; without even the implied warranty of merchantability or fitness for a particular purpose.
Linux boot disks are useful in a number of situations, such as testing a new kernel, recovering from a disk failure (anything from a lost boot sector to a disk head crash), fixing a disabled system, or upgrading critical system files safely (such as libc.so).
There are several ways of obtaining boot disks:
Use one from a distribution such as Slackware. This will at least allow you to boot.
Use a rescue package to set up disks designed to be used as rescue disks.
Learn what is required for each of the types of disk to operate, then build your own.
This document assumes some basic familiarity with Linux system administration concepts. For example, you should know about directories, filesystems and floppy diskettes. You should know how to use mount and df. You should know what /etc/passwd and fstab files are for and what they look like. You should know that most of the commands in this HOWTO should be run as root.
Constructing a bootdisk from scratch can be complicated. If you haven't read the Linux FAQ and related documents, such as the Linux Installation HOWTO and the Linux Installation Guide, you should not be trying to build boot diskettes. If you just need a working bootdisk for emergencies, it is much easier to download a prefabricated one. See Appendix A.1, below, for where to find these.
A bootdisk is basically a miniature, self-contained Linux system on a diskette. It must perform many of the same functions that a complete full-size Linux system performs. Before trying to build one you should understand the basic Linux boot process. Here we present the basics, which are sufficient for understanding the rest of this document. Many details and alternative options have been omitted.
All PC systems start the boot process by executing code in ROM (specifically, the BIOS) to load the sector from sector 0, cylinder 0 of the boot drive. The boot drive is usually the first floppy drive (designated A: in DOS and /dev/fd0 in Linux). The BIOS then tries to execute this sector. On most bootable disks, sector 0, cylinder 0 contains either:
code from a boot loader such as LILO, which locates the kernel, loads it and executes it to start the boot proper; or
the start of an operating system kernel, such as Linux.
If a Linux kernel has been raw-copied to a diskette, the first sector of the disk will be the first sector of the Linux kernel itself. This first sector will continue the boot process by loading the rest of the kernel from the boot device.
When the kernel is completely loaded, it initializes device drivers and its internal data structures. Once it is completely initialized, it consults a special location in its image called the ramdisk word. This word tells it how and where to find its root filesystem. A root filesystem is simply a filesystem that will be mounted as ``/''. The kernel has to be told where to look for the root filesystem; if it cannot find a loadable image there, it halts.
In some boot situations — often when booting from a diskette — the root filesystem is loaded into a ramdisk, which is RAM accessed by the system as if it were a disk. RAM is several orders of magnitude faster than a floppy disk, so system operation is fast from a ramdisk. Also, the kernel can load a compressed filesystem from the floppy and uncompress it onto the ramdisk, allowing many more files to be squeezed onto the diskette.
Once the root filesystem is loaded and mounted, you see a message like:
VFS: Mounted root (ext2 filesystem) readonly. |
Once the system has loaded a root filesystem successfully, it tries to execute the init program (in /bin or /sbin). init reads its configuration file /etc/inittab, looks for a line designated sysinit, and executes the named script. The sysinit script is usually something like /etc/rc or /etc/init.d/boot. This script is a set of shell commands that set up basic system services, such as running fsck on hard disks, loading necessary kernel modules, initializing swapping, initializing the network, and mounting disks mentioned in /etc/fstab.
This script often invokes various other scripts to do modular initialization. For example, in the common SysVinit structure, the directory /etc/rc.d/ contains a complex structure of subdirectories whose files specify how to enable and shut down most system services. However, on a bootdisk the sysinit script is often very simple.
When the sysinit script finishes control returns to init, which then enters the default runlevel, specified in inittab with the initdefault keyword. The runlevel line usually specifies a program like getty, which is responsible for handling commununications through the console and ttys. It is the getty program which prints the familiar ``login:'' prompt. The getty program in turn invokes the login program to handle login validation and to set up user sessions.
Having reviewed the basic boot process, we can now define various kinds of disks involved. We classify disks into four types. The discussion here and throughout this document uses the term ``disk'' to refer to floppy diskettes unless otherwise specified, though most of the discussion could apply equally well to hard disks.
A disk containing a kernel which can be booted. The disk can be used to boot the kernel, which then may load a root file system on another disk. The kernel on a bootdisk usually must be told where to find its root filesystem.
Often a bootdisk loads a root filesystem from another diskette, but it is possible for a bootdisk to be set up to load a hard disk's root filesystem instead. This is commonly done when testing a new kernel (in fact, ``make zdisk'' will create such a bootdisk automatically from the kernel source code).
A disk with a filesystem containing files required to run a Linux system. Such a disk does not necessarily contain either a kernel or a boot loader.
A root disk can be used to run the system independently of any other disks, once the kernel has been booted. Usually the root disk is automatically copied to a ramdisk. This makes root disk accesses much faster, and frees up the disk drive for a utility disk.
A disk which contains both the kernel and a root filesystem. In other words, it contains everything necessary to boot and run a Linux system without a hard disk. The advantage of this type of disk is that is it compact — everything required is on a single disk. However, the gradually increasing size of everything means that it is increasingly difficult to fit everything on a single diskette, even with compression.
A disk which contains a filesystem, but is not intended to be mounted as a root file system. It is an additional data disk. You would use this type of disk to carry additional utilities where you have too much to fit on your root disk.
In general, when we talk about ``building a bootdisk'' we mean creating both the boot (kernel) and root (files) portions. They may be either together (a single boot/root disk) or separate (boot + root disks). The most flexible approach for rescue diskettes is probably to use separate boot and root diskettes, and one or more utility diskettes to handle the overflow.
Creating the root filesystem involves selecting files necessary for the system to run. In this section we describe how to build a compressed root filesystem. A less common option is to build an uncompressed filesystem on a diskette that is directly mounted as root; this alternative is described in Section 9.1.
A root filesystem must contain everything needed to support a full Linux system. To be able to do this, the disk must include the minimum requirements for a Linux system:
The basic file system structure,
Minimum set of directories: /dev, /proc, /bin, /etc, /lib, /usr, /tmp,
Basic set of utilities: sh, ls, cp, mv, etc.,
Minimum set of config files: rc, inittab, fstab, etc.,
Devices: /dev/hd*, /dev/tty*, /dev/fd0, etc.,
Runtime library to provide basic functions used by utilities.
Of course, any system only becomes useful when you can run something on it, and a root diskette usually only becomes useful when you can do something like:
Check a file system on another drive, for example to check your root file system on your hard drive, you need to be able to boot Linux from another drive, as you can with a root diskette system. Then you can run fsck on your original root drive while it is not mounted.
Restore all or part of your original root drive from backup using archive and compression utilities such as cpio, tar, gzip and ftape.
We describe how to build a compressed filesystem, so called because it is compressed on disk and, when booted, is uncompressed onto a ramdisk. With a compressed filesystem you can fit many files (approximately six megabytes) onto a standard 1440K diskette. Because the filesystem is much larger than a diskette, it cannot be built on the diskette. We have to build it elsewhere, compress it, then copy it to the diskette.
In order to build such a root filesystem, you need a spare device that is large enough to hold all the files before compression. You will need a device capable of holding about four megabytes. There are several choices:
Use a ramdisk (DEVICE = /dev/ram0). In this case, memory is used to simulate a disk drive. The ramdisk must be large enough to hold a filesystem of the appropriate size. If you use LILO, check your configuration file (/etc/lilo.conf) for a line like RAMDISK = nnn which determines the maximum RAM that can be allocated to a ramdisk. The default is 4096K, which should be sufficient. You should probably not try to use such a ramdisk on a machine with less than 8MB of RAM. Check to make sure you have a device like /dev/ram0, /dev/ram or /dev/ramdisk. If not, create /dev/ram0 with mknod (major number 1, minor 0).
If you have an unused hard disk partition that is large enough (several megabytes), this is acceptable.
Use a loopback device, which allows a disk file to be treated as a device. Using a loopback device you can create a three megabyte file on your hard disk and build the filesystem on it.
Type man losetup for instructions on using loopback devices. If you don't have losetup, you can get it along with compatible versions of mount and unmount from the util-linux package in the directory ftp://ftp.win.tue.nl/pub/linux/utils/util-linux/.
If you do not have a loop device (/dev/loop0, /dev/loop1, etc.) on your system, you will have to create one with ``mknod /dev/loop0 b 7 0''. Once you've installed these special mount and umount binaries, create a temporary file on a hard disk with enough capacity (eg, /tmp/fsfile). You can use a command like:
dd if=/dev/zero of=/tmp/fsfile bs=1k count=nnn |
Use the file name in place of DEVICE below. When you issue a mount command you must include the option -o loop to tell mount to use a loopback device.
After you've chosen one of these options, prepare the DEVICE with:
dd if=/dev/zero of=DEVICE bs=1k count=4096 |
This command zeroes out the device.
Zeroing the device is critical because the filesystem will be compressed later, so all unused portions should be filled with zeroes to achieve maximum compression. Keep this in mind whenever you move or delete files on the filesystem. The filesystem will correctly de-allocate the blocks, but it will not zero them out again. If you do a lot of deletions and copying, your compressed filesystem may end up much larger than necessary. |
Next, create the filesystem. The Linux kernel recognizes two file system types for root disks to be automatically copied to ramdisk. These are minix and ext2, of which ext2 is preferred. If using ext2, you may find it useful to use the -N option to specify more inodes than the default; -N 2000 is suggested so that you don't run out of inodes. Alternatively, you can save on inodes by removing lots of unnecessary /dev files. mke2fs will by default create 360 inodes on a 1.44Mb diskette. I find that 120 inodes is ample on my current rescue root diskette, but if you include all the devices in /dev you will easily exceed 360. Using a compressed root filesystem allows a larger filesystem, and hence more inodes by default, but you may still need to either reduce the number of files or increase the number of inodes.
So the command you use will look like:
mke2fs -m 0 -N 2000 DEVICE |
(If you're using a loopback device, the disk file you're using should be supplied in place of this DEVICE.)
The mke2fs command will automatically detect the space available and configure itself accordingly. The ``-m 0'' parameter prevents it from reserving space for root, and hence provides more usable space on the disk.
Next, mount the device:
mount -t ext2 DEVICE /mnt |
Here is a reasonable minimum set of directories for your root filesystem [1]:
/dev -- Device files, required to perform I/O
/proc -- Directory stub required by the proc filesystem
/etc -- System configuration files
/sbin -- Critical system binaries
/bin -- Essential binaries considered part of the system
/lib -- Shared libraries to provide run-time support
/mnt -- A mount point for maintenance on other disks
/usr -- Additional utilities and applications
Three of these directories will be empty on the root filesystem, so they only need to be created with mkdir. The /proc directory is basically a stub under which the proc filesystem is placed. The directories /mnt and /usr are only mount points for use after the boot/root system is running. Hence again, these directories only need to be created.
The remaining four directories are described in the following sections.
A /dev directory containing a special file for all devices to be used by the system is mandatory for any Linux system. The directory itself is a normal directory, and can be created with mkdir in the normal way. The device special files, however, must be created in a special way, using the mknod command.
There is a shortcut, though — copy devices files from your existing hard disk /dev directory. The only requirement is that you copy the device special files using -R option. This will copy the directory without attempting to copy the contents of the files. Be sure to use an upper case R. For example:
cp -dpR /dev/fd[01]* /mnt/dev cp -dpR /dev/tty[0-6] /mnt/dev |
If you want to do it the hard way, use ls -l to display the major and minor device numbers for the devices you want, and create them on the diskette using mknod.
However the devices files are created, check that any special devices you need have been placed on the rescue diskette. For example, ftape uses tape devices, so you will need to copy all of these if you intend to access your floppy tape drive from the bootdisk.
Note that one inode is required for each device special file, and inodes can at times be a scarce resource, especially on diskette filesystems. You'll need to be selective about the device files you include. For example, if you do not have SCSI disks you can safely ignore /dev/sd*; if you don't intend to use serial ports you can ignore /dev/ttyS*.
If, in building your root filesystem, you get the error No space left on device but a df command shows space still available, you have probably run out of inodes. A df -i will display inode usage.
Be sure to include the following files from this directory: console, kmem, mem, null, ram0 and tty1. |
The /etc directory contains configuration files. What it should contain depends on what programs you intend to run. On most systems, these can be divided into three groups:
Required at all times, e.g. rc, fstab, passwd.
May be required, but no one is too sure.
Junk that crept in.
ls -ltru |
On my root diskettes, I have the number of config files down to 15. This reduces my work to dealing with three sets of files:
The ones I must configure for a boot/root system:
rc.d/* -- system startup and run level change scripts
fstab -- list of file systems to be mounted
inittab -- parameters for the init process, the first process started at boot time.
gettydefs -- parameters for the init process, the first process started at boot time.
The ones I should tidy up for a boot/root system:
passwd -- Critical list of users, home directories, etc.
group -- user groups.
shadow -- passwords of users. You may not have this.
termcap -- the terminal capability database.
If security is important, passwd and shadow should be pruned to avoid copying user passwords off the system, and so that unwanted logins are rejected when you boot from diskette.
Be sure that passwd contains at least root. If you intend other users to login, be sure their home directories and shells exist.
termcap, the terminal database, is typically several hundred kilobytes. The version on your boot/root diskette should be pruned down to contain only the terminal(s) you use, which is usually just the linux or linux-console entry.
The rest. They work at the moment, so I leave them alone.
Out of this, I only really have to configure two files, and what they should contain is surprisingly small.
rc should contain:
#!/bin/sh /bin/mount -av /bin/hostname Kangaroo |
fstab should contain at least:
/dev/ram0 / ext2 defaults /dev/fd0 / ext2 defaults /proc /proc proc defaults |
Your inittab should be changed so that its sysinit line runs rc or whatever basic boot script will be used. Also, if you want to ensure that users on serial ports cannot login, comment out all the entries for getty which include a ttys or ttyS device at the end of the line. Leave in the tty ports so that you can login at the console.
A minimal inittab file looks like this:
id:2:initdefault: si::sysinit:/etc/rc 1:2345:respawn:/sbin/getty 9600 tty1 2:23:respawn:/sbin/getty 9600 tty2 |
Note that some programs cannot be moved elsewhere because other programs have hardcoded their locations. For example, on my system, /etc/shutdown has hardcoded in it /etc/reboot. If I move reboot to /bin/reboot, and then issue a shutdown command, it will fail because it cannot find the reboot file.
For the rest, just copy all the text files in your /etc directory, plus all the executables in your /etc directory that you cannot be sure you do not need. As a guide, consult the sample listing in Appendix C. Probably it will suffice to copy only those files, but systems differ a great deal, so you cannot be sure that the same set of files on your system is equivalent to the files in the list. The only sure method is to start with inittab and work out what is required.
Most systems now use an /etc/rc.d/ directory containing shell scripts for different run levels. The minimum is a single rc script, but it may be simpler just to copy inittab and the /etc/rc.d directory from your existing system, and prune the shell scripts in the rc.d directory to remove processing not relevent to a diskette system environment.
The /bin directory is a convenient place for extra utilities you need to perform basic operations, utilities such as ls, mv, cat and dd. See Appendix C for an example list of files that go in a /bin and /sbin directories. It does not include any of the utilities required to restore from backup, such as cpio, tar and gzip. That is because I place these on a separate utility diskette, to save space on the boot/root diskette. Once the boot/root diskette is booted, it is copied to the ramdisk leaving the diskette drive free to mount another diskette, the utility diskette. I usually mount this as /usr.
Creation of a utility diskette is described below in Section 9.2. It is probably desirable to maintain a copy of the same version of backup utilities used to write the backups so you don't waste time trying to install versions that cannot read your backup tapes.
Be sure to include the following programs: init, getty or equivalent, login, mount, some shell capable of running your rc scripts, a link from sh to the shell. |
In /lib you place necessary shared libraries and loaders. If the necessary libraries are not found in your /lib directory then the system will be unable to boot. If you're lucky you may see an error message telling you why.
Nearly every program requires at least the libc library, libc.so.N, where N is the current version number. Check your /lib directory. The file libc.so.N is usually a symlink to a filename with a complete version number:
% ls -l /lib/libc* -rwxr-xr-x 1 root root 4016683 Apr 16 18:48 libc-2.1.1.so* lrwxrwxrwx 1 root root 13 Apr 10 12:25 libc.so.6 -> libc-2.1.1.so* |
In this case, you want libc-2.1.1.so. To find other libraries you should go through all the binaries you plan to include and check their dependencies with ldd. For example:
% ldd /sbin/mke2fs libext2fs.so.2 => /lib/libext2fs.so.2 (0x40014000) libcom_err.so.2 => /lib/libcom_err.so.2 (0x40026000) libuuid.so.1 => /lib/libuuid.so.1 (0x40028000) libc.so.6 => /lib/libc.so.6 (0x4002c000) /lib/ld-linux.so.2 => /lib/ld-linux.so.2 (0x40000000) |
Note that some libraries are quite large and will not fit easily on your root filesystem. For example, the libc.so listed above is about 4 meg. You will probably need to strip libraries when copying them to your root filesystem. See Section 8 for instructions.
In /lib you must also include a loader for the libraries. The loader will be either ld.so (for A.OUT libraries, which are no longer common) or ld-linux.so (for ELF libraries). Newer versions of ldd tell you exactly which loader is needed, as in the example above, but older versions may not. If you're unsure which you need, run the file command on the library. For example:
% file /lib/libc.so.4.7.2 /lib/libc.so.5.4.33 /lib/libc-2.1.1.so /lib/libc.so.4.7.2: Linux/i386 demand-paged executable (QMAGIC), stripped /lib/libc.so.5.4.33: ELF 32-bit LSB shared object, Intel 80386, version 1, stripped /lib/libc-2.1.1.so: ELF 32-bit LSB shared object, Intel 80386, version 1, not stripped |
Copy the specific loader(s) you need to the root filesystem you're building. Libraries and loaders should be checked carefully against the included binaries. If the kernel cannot load a necessary library, the kernel may hang with no error message.
Your system may require dynamically loaded libraries that are not visible to ldd. If you don't provide for these, you may have trouble logging in or using your bootdisk.
If your system uses PAM (Pluggable Authentication Modules), you must make some provision for it on your bootdisk. Briefly, PAM is a sophisticated modular method for authenticating users and controlling their access to services. An easy way to determine if your system uses PAM is run ldd on your login executable; if the output includes libpam.so, you need PAM.
Fortunately, security is usually of no concern with bootdisks since anyone who has physical access to a machine can usually do anything they want anyway. Therefore, you can effectively disable PAM by creating a simple /etc/pam.conf file in your root filesystem that looks like this:
OTHER auth optional /lib/security/pam_permit.so OTHER account optional /lib/security/pam_permit.so OTHER password optional /lib/security/pam_permit.so OTHER session optional /lib/security/pam_permit.so |
This configuration allows anyone complete access to the files and services on your machine. If you care about security on your bootdisk for some reason, you'll have to copy some or all of your hard disk's PAM setup to your root filesystem. Be sure to read the PAM documentation carefully, and copy any libraries needed in /lib/security onto your root filesystem.
You must also include /lib/libpam.so on your bootdisk. But you already know this since you ran ldd on /bin/login, which showed this dependency.
If you are using glibc (aka libc6), you will have to make provisions for name services or you will not be able to login. The file /etc/nsswitch.conf controls database lookups for various servies. If you don't plan to access services from the network (eg, DNS or NIS lookups), you need only prepare a simple nsswitch.conf file that looks like this:
passwd: files shadow: files group: files hosts: files services: files networks: files protocols: files rpc: files ethers: files netmasks: files bootparams: files automount: files aliases: files netgroup: files publickey: files |
If you plan to access the network from your bootdisk, you may want to create a more elaborate nsswitch.conf file. See the nsswitch man page for details. You must include a file /lib/libnss_service.so.1 for each service you specify.
If you have a modular kernel, you must consider which modules you may want to load from your bootdisk after booting. You might want to include ftape and zftape modules if your backup tapes are on floppy tape, modules for SCSI devices if you have them, and possibly modules for PPP or SLIP support if you want to access the net in an emergency.
These modules may be placed in /lib/modules. You should also include insmod, rmmod and lsmod. Depending on whether you want to load modules automatically, you might also include modprobe, depmod and swapout. If you use kerneld, include it along with /etc/conf.modules.
However, the main advantage to using modules is that you can move non-critical modules to a utility disk and load them when needed, thus using less space on your root disk. If you may have to deal with many different devices, this approach is preferable to building one huge kernel with many drivers built in.
In order to boot a compressed ext2 filesystem, you must have ramdisk and ext2 support built-in. They cannot be supplied as modules. |
Some system programs, such as login, complain if the file /var/run/utmp and the directory /var/log do not exist. So:
mkdir -p /mnt/var/{log,run} touch /mnt/var/run/utmp |
Finally, after you have set up all the libraries you need, run ldconfig to remake /etc/ld.so.cache on the root filesystem. The cache tells the loader where to find the libraries. You can do this with:
ldconfig -r /mnt |
When you have finished constructing the root filesystem, unmount it, copy it to a file and compress it:
umount /mnt
dd if=DEVICE bs=1k | gzip -v9 > rootfs.gz |
At this point you have a complete compressed root filesystem. The next step is to build or select a kernel. In most cases it would be possible to copy your current kernel and boot the diskette from that. However, there may be cases where you wish to build a separate one.
One reason is size. If you are building a single boot/root diskette, the kernel will be one of the largest files on the diskette so you will have to reduce the size of the kernel as much as possible. To reduce kernel size, build it with the minumum set of facilities necessary to support the desired system. This means leaving out everything you don't need. Networking is a good thing to leave out, as well as support for any disk drives and other devices which you don't need when running your boot/root system. As stated before, your kernel must have ramdisk and ext2 support built into it.
Having worked out a minimum set of facilities to include in a kernel, you then need to work out what to add back in. Probably the most common uses for a boot/root diskette system would be to examine and restore a corrupted root file system, and to do this you may need kernel support. For example, if your backups are all held on tape using Ftape to access your tape drive, then, if you lose your current root drive and drives containing Ftape, then you will not be able to restore from your backup tapes. You will have to reinstall Linux, download and reinstall ftape, and then try to read your backups.
The point here is that, whatever I/O support you have added to your kernel to support backups should also be added into your boot/root kernel.
The procedure for actually building the kernel is described in the documentation that comes with the kernel. It is quite easy to follow, so start by looking in /usr/src/linux. If you have trouble building a kernel, you should probably not attempt to build boot/root systems anyway. Remember to compress the kernel with ``make zImage''.
At this point you have a kernel and a compressed root filesystem. If you are making a boot/root disk, check their sizes to make sure they will both fit on one disk. If you are making a two disk boot+root set, check the root filesystem to make sure it will fit on a single diskette.
You should decide whether to use LILO to boot the bootdisk kernel. The alternative is to copy the kernel directly to the diskette and boot without LILO. The advantage of using LILO is that it enables you to supply some parameters to the kernel which may be necessary to initialize your hardware (Check the file /etc/lilo.conf on your system. If it exists and has a line like ``append=...'', you probably need this feature). The disadvantage of using LILO is that building the bootdisk is more complicated and takes slightly more space. You will have to set up a small separate filesystem, which we shall call the kernel filesystem, where you transfer the kernel and a few other files that LILO needs.
If you are going to use LILO, read on; if you are going to transfer the kernel directly, skip ahead to Section 6.2.
First, make sure you have a recent version of LILO.
You must create a small configuration file for LILO. It should look like this:
boot =/dev/fd0 install =/boot/boot.b map =/boot/map read-write backup =/dev/null compact image = KERNEL label = Bootdisk root =/dev/fd0 |
Save this file as bdlilo.conf.
You now have to create a small filesystem, which we shall call a kernel filesystem, to distinguish it from the root filesystem.
First, figure out how large the filesystem should be. Take the size of your kernel in blocks (the size shown by ``ls -s KERNEL'') and add 50. Fifty blocks is approximately the space needed for inodes plus other files. You can calculate this number exactly if you want to, or just use 50. If you're creating a two-disk set, you may as well overestimate the space since the first disk is only used for the kernel anyway. Call this number KERNEL_BLOCKS.
Put a floppy diskette in the drive (for simplicity we'll assume /dev/fd0) and create an ext2 kernel filesystem on it:
mke2fs -N 24 -m 0 /dev/fd0 KERNEL_BLOCKS |
mount -o dev /dev/fd0 /mnt rm -rf /mnt/lost+found mkdir /mnt/{boot,dev} |
Next, create devices /dev/null and /dev/fd0. Instead of looking up the device numbers, you can just copy them from your hard disk using -R:
cp -R /dev/{null,fd0} /mnt/dev |
cp /boot/boot.b /mnt/boot |
cp bdlilo.conf KERNEL /mnt |
lilo -v -C bdlilo.conf -r /mnt |
total 361 1 –rw–r––r–– 1 root root 176 Jan 10 07:22 bdlilo.conf 1 drwxr–xr–x 2 root root 1024 Jan 10 07:23 boot/ 1 drwxr–xr–x 2 root root 1024 Jan 10 07:22 dev/ 358 –rw–r––r–– 1 root root 362707 Jan 10 07:23 vmlinuz boot: total 8 4 –rw–r––r–– 1 root root 3708 Jan 10 07:22 boot.b 4 –rw––––––– 1 root root 3584 Jan 10 07:23 map dev: total 0 0 brw–r––––– 1 root root 2, 0 Jan 10 07:22 fd0 0 crw–r––r–– 1 root root 1, 3 Jan 10 07:22 null |
Do not worry if the file sizes are slightly different from yours.
Now leave the diskette in the drive and go to Section 6.3.
If you are not using LILO, transfer the kernel to the bootdisk with dd:
% dd if=KERNEL of=/dev/fd0 bs=1k 353+1 records in 353+1 records out |
Finally, set the root device to be the diskette itself, then set the root to be loaded read/write:
rdev /dev/fd0 /dev/fd0 rdev -R /dev/fd0 0 |
Inside the kernel image is the ramdisk word that specifies where the root filesystem is to be found, along with other options. The word can be accessed and set via the rdev command, and its contents are interpreted as follows:
Bit field | Description |
---|---|
0-10 | Offset to start of ramdisk, in 1024 byte blocks |
11-13 | unused |
14 | Flag indicating that ramdisk is to be loaded |
15 | Flag indicating to prompt before loading rootfs |
If bit 15 is set, on boot-up you will be prompted to place a new floppy diskette in the drive. This is necessary for a two-disk boot set.
There are two cases, depending on whether you are building a single boot/root diskette or a double ``boot+root'' diskette set.
If you are building a single disk, the compressed root filesystem will be placed right after the kernel, so the offset will be the first free block (which should be the same as KERNEL_BLOCKS). Bit 14 will be set to 1, and bit 15 will be zero. For example, say you're building a single disk and the root filesystem will begin at block 253 (decimal). The ramdisk word value should be 253 (decimal) with bit 14 set to 1 and bit 15 set to 0. To calculate the value you can simply add the decimal values. 253 + (2^14) = 253 + 16384 = 16637. If you don't quite understand where this number comes from, plug it into a scientific calculator and convert it to binary,
If you are building a two-disk set, the root filesystem will begin at block zero of the second disk, so the offset will be zero. Bit 14 will be set to 1 and bit 15 will be 1. The decimal value will be 2^14 + 2^15 = 49152 in this case.
After carefully calculating the value for the ramdisk word, set it with rdev -r. Be sure to use the decimal value. If you used LILO, the argument to rdev here should be the mounted kernel path, e.g. /mnt/vmlinuz; if you copied the kernel with dd, instead use the floppy device name (e.g., /dev/fd0).
rdev -r KERNEL_OR_FLOPPY_DRIVE VALUE |
If you used LILO, unmount the diskette now.
Do not believe what the rdev/ramsize manpage says about ramdisk size. The manpage is obsolete. As of kernel 2.0 or so, the ramdisk word no longer determines the ramdisk size; the word is instead interpreted according to the table at the beginning of section Section 6.3. For a detailed explanation, see the documentation file ramdisk.txt or http://www.linuxhq.com/kernel/v2.4/doc/ramdisk.txt.html. |
The last step is to transfer the root filesystem.
If the root filesystem will be placed on the same disk as the kernel, transfer it using dd with the seek option, which specifies how many blocks to skip:
dd if=rootfs.gz of=/dev/fd0 bs=1k seek=KERNEL_BLOCKS |
If the root filesystem will be placed on a second disk, remove the first diskette, put the second diskette in the drive, then transfer the root filesystem to it:
dd if=rootfs.gz of=/dev/fd0 bs=1k |
Congratulations, you are done!
You should always test a bootdisk before putting it aside for an emergency. If it fails to boot, read on. |
When building bootdisks, the first few tries often will not boot. The general approach to building a root disk is to assemble components from your existing system, and try and get the diskette-based system to the point where it displays messages on the console. Once it starts talking to you, the battle is half over because you can see what it is complaining about, and you can fix individual problems until the system works smoothly. If the system just hangs with no explanation, finding the cause can be difficult. The recommended procedure for investigating the problem where the system will not talk to you is as follows:
You may see a message like this:
Kernel panic: VFS: Unable to mount root fs on XX:YY |
If you see many errors like:
end_request: I/O error, dev 01:00 (ramdisk), sector NNN |
Ramdisk driver initialized : 16 ramdisks of 4096K size |
Check that the root disk actually contains the directories you think it does. It is easy to copy at the wrong level so that you end up with something like /rootdisk/bin instead of /bin on your root diskette.
Check that there is a /lib/libc.so with the same link that appears in your /lib directory on your hard disk.
Check that any symbolic links in your /dev directory in your existing system also exist on your root diskette filesystem, where those links are to devices which you have included in your root diskette. In particular, /dev/console links are essential in many cases.
Check that you have included /dev/tty1, /dev/null, /dev/zero, /dev/mem, /dev/ram and /dev/kmem files.
Check your kernel configuration -- support for all resources required up to login point must be built in, not modules. So ramdisk and ext2 support must be built-in.
Check that your kernel root device and ramdisk settings are correct.
Once these general aspects have been covered, here are some more specific files to check:
Make sure init is included as /sbin/init or /bin/init. Make sure it is executable.
Run ldd init to check init's libraries. Usually this is just libc.so, but check anyway. Make sure you included the necessary libraries and loaders.
Make sure you have the right loader for your libraries -- ld.so for a.out or ld-linux.so for ELF.
Check the /etc/inittab on your bootdisk filesystem for the calls to getty (or some getty-like program, such as agetty, mgetty or getty_ps). Double-check these against your hard disk inittab. Check the man pages of the program you use to make sure these make sense. inittab is possibly the trickiest part because its syntax and content depend on the init program used and the nature of the system. The only way to tackle it is to read the man pages for init and inittab and work out exactly what your existing system is doing when it boots. Check to make sure /etc/inittab has a system initialisation entry. This should contain a command to execute the system initialization script, which must exist.
As with init, run ldd on your getty to see what it needs, and make sure the necessary library files and loaders were included in your root filesystem.
Be sure you have included a shell program (e.g., bash or ash) capable of running all of your rc scripts.
If you have a /etc/ld.so.cache file on your rescue disk, remake it.
If init starts, but you get a message like:
Id xxx respawning too fast: disabled for 5 minutes |
If you get a login prompt, and you enter a valid login name but the system prompts you for another login name immediately, the problem may be with PAM or NSS. See Section 4.4. The problem may also be that you use shadow passwords and didn't copy /etc/shadow to your bootdisk.
If you try to run some executable, such as df, which is on your rescue disk but you yields a message like: df: not found, check two things: (1) Make sure the directory containing the binary is in your PATH, and (2) make sure you have libraries (and loaders) the program needs.
One of the main problems with building bootdisks is getting everything to fit into one (or even two) diskettes. Even when files are compressed this can be very difficult, because Linux system components keep growing. Here are some common techniques used to make everything fit.
By default, floppy diskettes are formatted at 1440K, but higher density formats are possible. Whether you can boot from higher density disks depends mostly on your BIOS. fdformat will format disks for the following sizes: 1600K, 1680K, 1722K, 1743K, 1760K, 1840K, and 1920K. See the fdformat man page and /usr/src/linux/Documentation/devices.txt.
But what diskette densities/geometries will your machine support? Here are some (lightly edited) answers from Alain Knaff, the author of fdutils.
This is more an issue of the BIOS rather than the physical format of the disk. If the BIOS decides that any sector number greater than 18 is bad, then there is not much we can do. Indeed, short of disassembling the BIOS, trial and error seems to be the only way to find out. However, if the BIOS supports ED disks (extra density: 36 sectors/track and 2.88MB), there's a chance that 1722K disks are supported as well.
Superformatted disks with more than 21 sectors/track are likely not bootable: indeed, those use sectors of non-standard sizes (1024 bytes in a sector instead of 512, for example), and are likely not bootable. It should however be possible to write a special bootsector program to work around this. If I remember correctly, the DOS 2m utility has such a beast, as does OS/2's XDF utilities.
Some BIOSes artificially claim that any sector number greater than 18 must be in error. As 1722K disks use sector numbers up to 21, these would not be bootable. The best way to test would be to format a test DOS or syslinus disk as 1722K and make it bootable. If you use LILO, don't use the option linear (or else LILO would assume that the disk is the default 18 sectors/track, and the disk will fail to boot even if supported by the BIOS).
Much root filesystem space is consumed by common GNU system utilities such as cat, chmod, cp, dd, df, etc. The BusyBox project was designed to provide minimal replacements for these common system utilities. BusyBox supplies one single monolithic executable file, /bin/busybox, about 150K, which implements the functions of these utilities. You then create symlinks from different utilities to this executable; busybox sees how it was called and invokes the correct code. BusyBox even includes a basic shell. BusyBox is available in binary packages for many distributions, and source code is available from the BusyBox site.
Some of the popular shells for Linux, such as bash and tcsh, are large and require many libraries. If you don't use the BusyBox shell, you should still consider replacing your shell anyway. Some light-weight alternatives are ash, lsh, kiss and smash, which are much smaller and require few (or no) libraries. Most of these replacement shells are available from http://www.ibiblio.org/pub/Linux/system/shells/. Make sure any shell you use is capable of running commands in all the rc files you include on your bootdisk.
Many libraries and binaries are distributed with debugging information. Running file on these files will tell you ``not stripped'' if so. When copying binaries to your root filesystem, it is good practice to use:
objcopy --strip-all FROM TO |
When copying libraries, be sure to use strip-debug instead of strip-all. |
If some of your binaries are not needed immediately to boot or login, you can move them to a utility disk. See Section 9.2 for details. You may also consider moving modules to a utility disk as well.
Section 4 gave instructions for building a compressed root filesystem which is loaded to ramdisk when the system boots. This method has many advantages so it is commonly used. However, some systems with little memory cannot afford the RAM needed for this, and they must use root filesystems mounted directly from the diskette.
Such filesystems are actually easier to build than compressed root filesystems because they can be built on a diskette rather than on some other device, and they do not have to be compressed. We will outline the procedure as it differs from the instructions above. If you choose to do this, keep in mind that you will have much less space available.
Calculate how much space you will have available for root files. If you are building a single boot/root disk, you must fit all blocks for the kernel plus all blocks for the root filesystem on the one disk.
Using mke2fs, create a root filesystem on a diskette of the appropriate size.
Populate the filesystem as described above.
When done, unmount the filesystem and transfer it to a disk file but do not compress it.
Transfer the kernel to a floppy diskette, as described above. When calculating the ramdisk word, set bit 14 to zero, to indicate that the root filesystem is not to be loaded to ramdisk. Run the rdev's as described.
Transfer the root filesystem as before.
There are several shortcuts you can take. If you are building a two-disk set, you can build the complete root filesystem directly on the second disk and you need not transfer it to a hard disk file and then back. Also, if you are building a single boot/root disk and using LILO, you can build a single filesystem on the entire disk, containing the kernel, LILO files and root files, and simply run LILO as the last step.
Building a utility disk is relatively easy -- simply create a filesystem on a formatted disk and copy files to it. To use it with a bootdisk, mount it manually after the system is booted.
In the instructions above, we mentioned that the utility disk could be mounted as /usr. In this case, binaries could be placed into a /bin directory on your utility disk, so that placing /usr/bin in your path will access them. Additional libraries needed by the binaries are placed in /lib on the utility disk.
There are several important points to keep in mind when designing a utility disk:
Do not place critical system binaries or libraries onto the utility disk, since it will not be mountable until after the system has booted.
You cannot access a floppy diskette and a floppy tape drive simultaneously. This means that if you have a floppy tape drive, you will not be able to access it while your utility disk is mounted.
Access to files on the utility disk will be slow.
Appendix D shows a sample of files on a utility disk. Here are some ideas for files you may find useful: programs for examining and manipulating disks (format, fdisk) and filesystems (mke2fs, fsck, debugfs, isofs.o), a lightweight text editor (elvis, jove), compression and archive utilities (gzip, bzip, tar, cpio, afio), tape utilities (mt, ftmt, tob, taper), communications utilities (ppp.o, slip.o, minicom) and utilities for devices (setserial, mknod).
You may notice that the bootdisks used by major distributions such as Slackware, RedHat or Debian seem more sophisticated than what is described in this document. Professional distribution bootdisks are based on the same principles outlined here, but employ various tricks because their bootdisks have additional requirements. First, they must be able to work with a wide variety of hardware, so they must be able to interact with the user and load various device drivers. Second, they must be prepared to work with many different installation options, with varying degrees of automation. Finally, distribution bootdisks usually combine installation and rescue capabilities.
Some bootdisks use a feature called initrd (initial ramdisk). This feature was introduced around 2.0.x and allows a kernel to boot in two phases. When the kernel first boots, it loads an initial ramdisk image from the boot disk. This initial ramdisk is a root filesystem containing a program that runs before the real root fs is loaded. This program usually inspects the environment and/or asks the user to select various boot options, such as the device from which to load the real rootdisk. It typically loads additional modules not built in to the kernel. When this initial program exits, the kernel loads the real root image and booting continues normally. For further information on initrd, see your local file /usr/src/linux/Documentation/initrd.txt and ftp://elserv.ffm.fgan.de/pub/linux/loadlin-1.6/initrd-example.tgz
The following are summaries of how each distribution's installation disks seem to work, based on inspecting their filesystems and/or source code. We do not guarantee that this information is completely accurate, or that they have not changed since the versions noted.
Slackware (v.3.1) uses a straightforward LILO boot similar to what is described in Section 6.1. The Slackware bootdisk prints a bootup message (“Welcome to the Slackware Linux bootkernel disk!”) using LILO's message parameter. This instructs the user to enter a boot parameter line if necessary. After booting, a root filesystem is loaded from a second disk. The user invokes a setup script which starts the installation. Instead of using a modular kernel, Slackware provides many different kernels and depends upon the user to select the one matching his or her hardware requirements.
RedHat (v.4.0) also uses a LILO boot. It loads a compressed ramdisk on the first disk, which runs a custom init program. This program queries for drivers then loads additional files from a supplemental disk if necessary.
Debian (v.1.3) is probably the most sophisticated of the installation disk sets. It uses the SYSLINUX loader to arrange various load options, then uses an initrd image to guide the user through installation. It appears to use both a customized init and a customized shell.
This section was contributed by Rizwan Mohammed Darwe (rizwan AT clovertechnologies dot com) |
This section assumes that you are familiar with the process and workings of writing CDs in linux. Consider this to be a quick reference to include the ability to boot the CD which you will burn. The CD-Writing-HOWTO should give you an in-depth reference.
For the x86 platform, many BIOS's have begun to support bootable CDs. The patches for mkisofs is based on the standard called "El Torito". Simply put, El Torito is a specification that says how a cdrom should be formatted such that you can directly boot from it.
The "El Torito" spec says that any cdrom drive should work (SCSI or EIDE) as long as the BIOS supports El Torito. So far this has only been tested with EIDE drives because none of the SCSI controllers that has been tested so far appears to support El Torito. The motherboard definately has to support El Torito. How do you know if your motherboard supports "El Torito"? Well, the ones that support it let you choose booting from hard disk, Floppy, Network or CDROM.
The El Torito standard works by making the CD drive appear, through BIOS calls, to be a normal floppy drive. This way you simply put any floppy size image (exactly 1440k for a 1.44 meg floppy) somewhere in the ISO filesystem. In the headers of the ISO fs you place a pointer to this image. The BIOS will then grab this image from the CD and for all purposes it acts as if it were booting from the floppy drive. This allows a working LILO boot disk, for example, to simply be used as is.
Roughly speaking, the first 1.44 (or 2.88 if supported) Mbytes of the CD-ROM contains a floppy-disk image supplied by you. This image is treated like a floppy by the BIOS and booted from. (As a consequence, while booting from this virtual floppy, your original drive A: (/dev/fd0) may not be accessible, but you can try with /dev/fd1).
First create a file, say "boot.img", which is an exact image of the bootable floppy-disk which you want to boot via the CD-ROM. This must be an 1.44 MB bootable floppy-disk. The command below will do this
dd if=/dev/fd0 of=boot.img bs=10k count=144 |
Place this image somewhere in the hierarchy which will be the source for the iso9660 filesystem. It is a good idea to put all boot related files in their own directory ("boot/" under the root of the iso9660 fs, for example).
One caveat -- Your boot floppy must load any initial ramdisk via LILO, not the kernel ramdisk driver! This is because once the linux kernel starts up, the BIOS emulation of the CD as a floppy disk is circumvented and will fail. LILO will load the initial ramdisk using BIOS disk calls, so the emulation works as designed.
The El Torito specification requires a "boot catalog" to be created as well. This is a 2048 byte file which is of no interest except it is required. The patchwork done by the author of mkisofs will cause it to automatically create the boot catalog, but you must specify where the boot catalog will go in the iso9660 filesystem. Usually it is a good idea to put it in the same place as the boot image, and a name like boot.catalog seems appropriate.
So we have our boot image in the file boot.img, and we are going to put it in the directory boot/ under the root of the iso9660 filesystem. We will have the boot catalog go in the same directory with the name boot.catalog. The command to create the iso9660 fs in the file bootcd.iso is then:
mkisofs -r -b boot/boot.img -c boot/boot.catalog -o bootcd.iso . |
Now burn the CD with the usual cdrecord command and it is ready to boot.
The first step is to get hold of the bootable image used by the source CD. But you cannot simply mount the CD under linux and dd the first 1440k to a floppy disk or to a file like boot.img. Instead you simply boot with the source CD-ROM.
When you boot the Win98 CD you are dropped to A: prompt which is the actual ramdisk. And D: or Z: is where all the installables are residing. By using the diskcopy command of dos copy the A: image into the actual floppy drive which is now B: The command below will do this.
diskcopy A: B: |
A: See Section 7, above.
A: See Section 10, above.
Q: How do I use higher-density (> 1440K) diskettes? How do I figure out which densities will work with my diskette drive?
A: See Section Section 8, above, for the comments by Alain Knaff on this subject. His is the most authoritative answer I know of.
A: This probably should be explained better in the text, but I'll put an answer here for the time being.
First, do not attempt to use the rdev or ramsize commands to do this, no matter what their documentation says. The ramdisk word no longer determines the size of ramdisks.
Second, keep in mind that ramdisks are actually dynamic; when you set a ramdisk size you aren't allocating any memory, you're just setting the limit of how large it can grow. Don't be afraid to set these fairly large (eg, 8 or even 16 meg). The RAM space is not actually consumed until you need it. You can set these limits in one of several ways.
Use the ramdisk_size=NNN command line parameter. You can either enter this manually or use a command like append="ramdisk_size=NNN" with LILO.
If you're using LILO, you can use a kernel option like ramdisk=8192K in the lilo.conf file.
Change the kernel configuration option CONFIG_BLK_DEV_RAM_SIZE and recompile your kernel.
A: See section Section 11.
A: Since I don't have an LS-120 drive, the following information is summarized from information provided by Dave Cinege from the Linux Router Project.
The LS-120 is an IDE floppy drive. It is compatible with both standard 3.5" disks and the new 120MB disks. As of Linux v2.0.31 there is full support. To be able to boot from these you must have a BIOS that specifically allows the LS-120 to be treated as drive 0 (whereas IDE devices normally start at 80). If you do not have BIOS support, you can purchase a small IDE FloppyMAX card from Promise Technologies to overcome this deficiency.
The kernel boot loader does not like the LS-120, and instantly dies. Also 2m disks do not like it and will not boot. 1.44MB through 1.74MB disks will work fine. SYSLINUX works with the 120MB disks as of v1.32. You would better off partitioning the disk and using ext2 or minix, instead of SYSLINUX unless you need MS-DOS compatibility.
LILO does work fine with 120MB disks. Here is a sample lilo.conf:
boot=/dev/hda compact disk=/dev/hda bios=0 install=/floppy/boot.b map=/floppy/map image=/floppy/linux label=Linux append="load_ramdisk=1" initrd=/floppy/root.bin ramdisk=8192 |
A: The easiest way is to obtain a Slackware kernel from your nearest Slackware mirror site. Slackware kernels are generic kernels which atttempt to include drivers for as many devices as possible, so if you have a SCSI or IDE controller, chances are that a driver for it is included in the Slackware kernel.
Go to the a1 directory and select either IDE or SCSI kernel depending on the type of controller you have. Check the xxxxkern.cfg file for the selected kernel to see the drivers which have been included in that kernel. If the device you want is in that list, then the corresponding kernel should boot your computer. Download the xxxxkern.tgz file and copy it to your boot diskette as described above in the section on making boot disks.
You must then check the root device in the kernel, using the command rdev zImage. If this is not the same as the root device you want, use rdev to change it. For example, the kernel I tried was set to /dev/sda2, but my root SCSI partition is /dev/sda8. To use a root diskette, you would have to use the command rdev zImage /dev/fd0.
If you want to know how to set up a Slackware root disk as well, that's outside the scope of this HOWTO, so I suggest you check the Linux Install Guide or get the Slackware distribution. See the section in this HOWTO titled ``References''.
A: The easiest way is to copy the filesystem from the rootdisk back to the DEVICE you used (from Section 4.2, above). Then mount the filesystem and make the changes. You have to remember where your root filesystem started and how many blocks it occupied:
dd if=/dev/fd0 bs=1k skip=ROOTBEGIN count=BLOCKS | gunzip > DEVICE mount -t ext2 DEVICE /mnt |
A: This is not really a Bootdisk topic, but it is asked often. Within Linux, you can run:
/sbin/lilo -u |
You can also use the dd command to copy the backup saved by LILO to the boot sector. Refer to the LILO documentation if you wish to do this.
Within DOS and Windows you can use the DOS command:
FDISK /MBR |
A: If you don't have a boot disk standing by, probably the easiest method is to obtain a Slackware kernel for your disk controller type (IDE or SCSI) as described above for ``How do I make a boot disk with a XXX driver?''. You can then boot your computer using this kernel, then repair whatever damage there is.
The kernel you get may not have the root device set to the disk type and partition you want. For example, Slackware's generic SCSI kernel has the root device set to /dev/sda2, whereas my root Linux partition happens to be /dev/sda8. In this case the root device in the kernel will have to be changed.
You can still change the root device and ramdisk settings in the kernel even if all you have is a kernel, and some other operating system, such as DOS.
rdev changes kernel settings by changing the values at fixed offsets in the kernel file, so you can do the same if you have a hex editor available on whatever systems you do still have running -- for example, Norton Utilities Disk Editor under DOS. You then need to check and if necessary change the values in the kernel at the following offsets:
HEX DEC DESCRIPTION 0x01F8 504 Low byte of RAMDISK word 0x01F9 505 High byte of RAMDISK word 0x01FC 508 Root minor device number - see below 0X01FD 509 Root major device number - see below |
The interpretation of the ramdisk word was described in Section 6.3, above.
The major and minor device numbers must be set to the device you want to mount your root filesystem on. Some useful values to select from are:
DEVICE MAJOR MINOR /dev/fd0 2 0 1st floppy drive /dev/hda1 3 1 partition 1 on 1st IDE drive /dev/sda1 8 1 partition 1 on 1st SCSI drive /dev/sda8 8 8 partition 8 on 1st SCSI drive |
A: Because magnetic media may deteriorate over time, you should keep several copies of your rescue disk, in case the original is unreadable.
The easiest way of making copies of any diskettes, including bootable and utility diskettes, is to use the dd command to copy the contents of the original diskette to a file on your hard drive, and then use the same command to copy the file back to a new diskette. Note that you do not need to, and should not, mount the diskettes, because dd uses the raw device interface.
To copy the original, enter the command:
dd if=DEVICENAME of=FILENAME |
To copy the resulting file back to a new diskette, insert the new diskette and enter the reverse command:
dd if=FILENAME of=DEVICENAME |
Note that the above discussion assumes that you have only one diskette drive. If you have two of the same type, you can copy diskettes using a command like:
dd if=/dev/fd0 of=/dev/fd1 |
A: Where a disk device cannot be autodetected it is necessary to supply the kernel with a command device parameter string, such as:
aha152x=0x340,11,3,1 |
By entering it on the command line every time the system is booted via LILO. This is boring, though.
By using LILO's lock keyword to make it store the command line as the default command line, so that LILO will use the same options every time it boots.
By using the append= statement in the LILO config file. Note that the parameter string must be enclosed in quotes.
For example, a sample command line using the above parameter string would be:
zImage aha152x=0x340,11,3,1 root=/dev/sda1 lock |
This would pass the device parameter string through, and also ask the kernel to set the root device to /dev/sda1 and save the whole command line and reuse it for all future boots.
A sample APPEND statement is:
APPEND = “aha152x=0x340,11,3,1” |
Note that the parameter string must not be enclosed in quotes on the command line, but it must be enclosed in quotes in the APPEND statement.
Note also that for the parameter string to be acted on, the kernel must contain the driver for that disk type. If it does not, then there is nothing listening for the parameter string, and you will have to rebuild the kernel to include the required driver. For details on rebuilding the kernel, go to /usr/src/linux and read the README, and read the Linux FAQ and Installation HOWTO. Alternatively you could obtain a generic kernel for the disk type and install that.
Readers are strongly urged to read the LILO documentation before experimenting with LILO installation. Incautious use of the BOOT statement can damage partitions.
A: There are several cases of program names being hardcoded in various utilities. These cases do not occur everywhere, but they may explain why an executable apparently cannot be found on your system even though you can see that it is there. You can find out if a given program has the name of another hardcoded by using the strings command and piping the output through grep.
Known examples of hardcoding are:
shutdown in some versions has /etc/reboot hardcoded, so reboot must be placed in the /etc directory.
init has caused problems for at least one person, with the kernel being unable to find init.
To fix these problems, either move the programs to the correct directory, or change configuration files (e.g. inittab) to point to the correct directory. If in doubt, put programs in the same directories as they are on your hard disk, and use the same inittab and /etc/rc.d files as they appear on your hard disk.
A: Where this occurs, a kernel message like this will appear as the kernel is booting:
Ramdisk driver initialized : 16 ramdisks of 0K size |
This is probably because the size has been set to 0 by kernel parameters at boot time. This could possibly be because of an overlooked LILO configuration file parameter:
ramdisk= 0 |
This was included in sample LILO configuration files in some older distributions, and was put there to override any previous kernel setting. If you have such a line, remove it.
Note that if you attempt to use a ramdisk of 0 size, the behaviour can be unpredictable, and can result in kernel panics.
When retrieving a package, always get the latest version unless you have good reasons for not doing so.
These are sources for distribution bootdisks. Please use one of the mirror sites to reduce the load on these machines.
In addition to the distribution bootdisks, the following rescue disk images are available. Unless otherwise specified, these are available in the directory http://www.ibiblio.org/pub/Linux/system/recovery/!INDEX.html
RIP is a boot/rescue system which comes in several versions: one that fits on a 1.44M floppy diskette and one that fits on a CD-ROM. It has large file support and many utility programs for disk maintenance and rescue. It has support for ext2, ext3, iso9660, msdos, ntfs, reiserfs, ufs and vfat. RIP is available from http://www.tux.org/pub/people/kent-robotti/looplinux/rip/index.html
tomsrtbt, by Tom Oehser, is a single-disk boot/root disk based on kernel 2.0, with a large set of features and support programs. It supports IDE, SCSI, tape, network adaptors, PCMCIA and more. About 100 utility programs and tools are included for fixing and restoring disks. The package also includes scripts for disassembling and reconstructing the images so that new material can be added if necessary.
rescue02, by John Comyns, is a rescue disk based on kernel 1.3.84, with support for IDE and Adaptec 1542 and NCR53C7,8xx. It uses ELF binaries but it has enough commands so that it can be used on any system. There are modules that can be loaded after booting for all other SCSI cards. It probably won't work on systems with 4 mb of ram since it uses a 3 mb ram disk.
resque_disk-2.0.22, by Sergei Viznyuk, is a full-featured boot/root disk based on kernel 2.0.22 with built-in support for IDE, many difference SCSI controllers, and ELF/AOUT. Also includes many modules and useful utilities for repairing and restoring a hard disk.
cramdisk images, based on the 2.0.23 kernel, available for 4 meg and 8 meg machines. They include math emulation and networking (PPP and dialin script, NE2000, 3C509), or support for the parallel port ZIP drive. These diskette images will boot on a 386 with 4MB RAM. MSDOS support is included so you can download from the net to a DOS partition.
Several packages for creating rescue disks are available on www.ibiblio.org. With these packages you specify a set of files for inclusion and the software automates (to varying degrees) the creation of a bootdisk. See http://www.ibiblio.org/pub/Linux/system/recovery/!INDEX.html for more information. Check the file dates carefully. Some of these packages have not been updated in several years and will not support the creation of a compressed root filesystem loaded into ramdisk. To the best of our knowledge, Yard is the only package that will.
Written by Werner Almesberger. Excellent boot loader, and the documentation includes information on the boot sector contents and the early stages of the boot process.
Ftp from ftp://tsx-11.mit.edu/pub/linux/packages/lilo/. It is also available on Metalab and mirrors.
An excellent description of the how the ramdisk code works may be found with the documentation supplied with the Linux kernel. See /usr/src/linux/Documentation/ramdisk.txt. It is written by Paul Gortmaker and includes a section on creating a compressed ramdisk.
For more detail on the Linux boot process, here are some pointers:
The Linux System Administrators' Guide has a section on booting.
The LILO ``Technical overview'' has the definitive technical, low-level description of the boot process, up to where the kernel is started.
The source code is the ultimate guide. Below are some kernel files related to the boot process. If you have the Linux kernel source code, you can find these under /usr/src/linux on your machine; alternatively, Shigio Yamaguchi (shigio at tamacom.com) has a very nice hypertext kernel browser for reading kernel source files. Here are some relevant files to look at:
Contain assembly code for the bootsector itself.
Contains code for uncompressing the kernel.
Directory containing kernel initialization code. setup.c defines the ramdisk word.
Contains the ramdisk driver. The procedures rd_load and rd_load_image load blocks from a device into a ramdisk. The procedure identify_ramdisk_image determines what kind of filesystem is found and whether it is compressed.
Questions about these codes are asked so often on Usenet that we include them here as a public service. This summary is excerpted from Werner Almsberger's LILO User Documentation.
When LILO loads itself, it displays the word LILO. Each letter is printed before or after performing some specific action. If LILO fails at some point, the letters printed so far can be used to identify the problem.
Output | Problem |
---|---|
(nothing) | No part of LILO has been loaded. LILO either isn't installed or the partition on which its boot sector is located isn't active. |
L | The first stage boot loader has been loaded and started, but it can't load the second stage boot loader. The two-digit error codes indicate the type of problem. (See also section ``Disk error codes''.) This condition usually indicates a media failure or a geometry mismatch (e.g. bad disk parameters). |
LI | The first stage boot loader was able to load the second stage boot loader, but has failed to execute it. This can either be caused by a geometry mismatch or by moving /boot/boot.b without running the map installer. |
LIL | The second stage boot loader has been started, but it can't load the descriptor table from the map file. This is typically caused by a media failure or by a geometry mismatch. |
LIL? | The second stage boot loader has been loaded at an incorrect address. This is typically caused by a subtle geometry mismatch or by moving /boot/boot.b without running the map installer. |
LIL- | The descriptor table is corrupt. This can either be caused by a geometry mismatch or by moving /boot/map without running the map installer. |
LILO | All parts of LILO have been successfully loaded. |
If the BIOS signals an error when LILO is trying to load a boot image, the respective error code is displayed. These codes range from 0x00 through 0xbb. See the LILO User Guide for an explanation of these.
/: drwx––x––x 2 root root 1024 Nov 1 15:39 bin drwx––x––x 2 root root 4096 Nov 1 15:39 dev drwx––x––x 3 root root 1024 Nov 1 15:39 etc drwx––x––x 4 root root 1024 Nov 1 15:39 lib drwx––x––x 5 root root 1024 Nov 1 15:39 mnt drwx––x––x 2 root root 1024 Nov 1 15:39 proc drwx––x––x 2 root root 1024 Nov 1 15:39 root drwx––x––x 2 root root 1024 Nov 1 15:39 sbin drwx––x––x 2 root root 1024 Nov 1 15:39 tmp drwx––x––x 7 root root 1024 Nov 1 15:39 usr drwx––x––x 5 root root 1024 Nov 1 15:39 var /bin: -rwx––x––x 1 root root 62660 Nov 1 15:39 ash -rwx––x––x 1 root root 9032 Nov 1 15:39 cat -rwx––x––x 1 root root 10276 Nov 1 15:39 chmod -rwx––x––x 1 root root 9592 Nov 1 15:39 chown -rwx––x––x 1 root root 23124 Nov 1 15:39 cp -rwx––x––x 1 root root 23028 Nov 1 15:39 date -rwx––x––x 1 root root 14052 Nov 1 15:39 dd -rwx––x––x 1 root root 14144 Nov 1 15:39 df -rwx––x––x 1 root root 69444 Nov 1 15:39 egrep -rwx––x––x 1 root root 395 Nov 1 15:39 false -rwx––x––x 1 root root 69444 Nov 1 15:39 fgrep -rwx––x––x 1 root root 69444 Nov 1 15:39 grep -rwx––x––x 3 root root 45436 Nov 1 15:39 gunzip -rwx––x––x 3 root root 45436 Nov 1 15:39 gzip -rwx––x––x 1 root root 8008 Nov 1 15:39 hostname -rwx––x––x 1 root root 12736 Nov 1 15:39 ln -rws––x––x 1 root root 15284 Nov 1 15:39 login -rwx––x––x 1 root root 29308 Nov 1 15:39 ls -rwx––x––x 1 root root 8268 Nov 1 15:39 mkdir -rwx––x––x 1 root root 8920 Nov 1 15:39 mknod -rwx––x––x 1 root root 24836 Nov 1 15:39 more -rws––x––x 1 root root 37640 Nov 1 15:39 mount -rwx––x––x 1 root root 12240 Nov 1 15:39 mt -rwx––x––x 1 root root 12932 Nov 1 15:39 mv -r-x––x––x 1 root root 12324 Nov 1 15:39 ps -rwx––x––x 1 root root 5388 Nov 1 15:39 pwd -rwx––x––x 1 root root 10092 Nov 1 15:39 rm lrwxrwxrwx 1 root root 3 Nov 1 15:39 sh -> ash -rwx––x––x 1 root root 25296 Nov 1 15:39 stty -rws––x––x 1 root root 12648 Nov 1 15:39 su -rwx––x––x 1 root root 4444 Nov 1 15:39 sync -rwx––x––x 1 root root 19712 Nov 1 15:39 touch -rwx––x––x 1 root root 395 Nov 1 15:39 true -rws––x––x 1 root root 19084 Nov 1 15:39 umount -rwx––x––x 1 root root 5368 Nov 1 15:39 uname -rwx––x––x 3 root root 45436 Nov 1 15:39 zcat /dev: lrwxrwxrwx 1 root root 6 Nov 1 15:39 cdrom -> cdu31a brw–rw–r–– 1 root root 15, 0 May 5 1998 cdu31a crw––––––– 1 root root 4, 0 Nov 1 15:29 console crw–rw–rw– 1 root uucp 5, 64 Sep 9 19:46 cua0 crw–rw–rw– 1 root uucp 5, 65 May 5 1998 cua1 crw–rw–rw– 1 root uucp 5, 66 May 5 1998 cua2 crw–rw–rw– 1 root uucp 5, 67 May 5 1998 cua3 brw–rw–––– 1 root floppy 2, 0 Aug 8 13:54 fd0 brw–rw–––– 1 root floppy 2, 36 Aug 8 13:54 fd0CompaQ brw–rw–––– 1 root floppy 2, 84 Aug 8 13:55 fd0D1040 brw–rw–––– 1 root floppy 2, 88 Aug 8 13:55 fd0D1120 brw–rw–––– 1 root floppy 2, 12 Aug 8 13:54 fd0D360 brw–rw–––– 1 root floppy 2, 16 Aug 8 13:54 fd0D720 brw–rw–––– 1 root floppy 2, 120 Aug 8 13:55 fd0D800 brw–rw–––– 1 root floppy 2, 32 Aug 8 13:54 fd0E2880 brw–rw–––– 1 root floppy 2, 104 Aug 8 13:55 fd0E3200 brw–rw–––– 1 root floppy 2, 108 Aug 8 13:55 fd0E3520 brw–rw–––– 1 root floppy 2, 112 Aug 8 13:55 fd0E3840 brw–rw–––– 1 root floppy 2, 28 Aug 8 13:54 fd0H1440 brw–rw–––– 1 root floppy 2, 124 Aug 8 13:55 fd0H1600 brw–rw–––– 1 root floppy 2, 44 Aug 8 13:55 fd0H1680 brw–rw–––– 1 root floppy 2, 60 Aug 8 13:55 fd0H1722 brw–rw–––– 1 root floppy 2, 76 Aug 8 13:55 fd0H1743 brw–rw–––– 1 root floppy 2, 96 Aug 8 13:55 fd0H1760 brw–rw–––– 1 root floppy 2, 116 Aug 8 13:55 fd0H1840 brw–rw–––– 1 root floppy 2, 100 Aug 8 13:55 fd0H1920 lrwxrwxrwx 1 root root 7 Nov 1 15:39 fd0H360 –> fd0D360 lrwxrwxrwx 1 root root 7 Nov 1 15:39 fd0H720 –> fd0D720 brw–rw–––– 1 root floppy 2, 52 Aug 8 13:55 fd0H820 brw–rw–––– 1 root floppy 2, 68 Aug 8 13:55 fd0H830 brw–rw–––– 1 root floppy 2, 4 Aug 8 13:54 fd0d360 brw–rw–––– 1 root floppy 2, 8 Aug 8 13:54 fd0h1200 brw–rw–––– 1 root floppy 2, 40 Aug 8 13:54 fd0h1440 brw–rw–––– 1 root floppy 2, 56 Aug 8 13:55 fd0h1476 brw–rw–––– 1 root floppy 2, 72 Aug 8 13:55 fd0h1494 brw–rw–––– 1 root floppy 2, 92 Aug 8 13:55 fd0h1600 brw–rw–––– 1 root floppy 2, 20 Aug 8 13:54 fd0h360 brw–rw–––– 1 root floppy 2, 48 Aug 8 13:55 fd0h410 brw–rw–––– 1 root floppy 2, 64 Aug 8 13:55 fd0h420 brw–rw–––– 1 root floppy 2, 24 Aug 8 13:54 fd0h720 brw–rw–––– 1 root floppy 2, 80 Aug 8 13:55 fd0h880 brw–rw–––– 1 root disk 3, 0 May 5 1998 hda brw–rw–––– 1 root disk 3, 1 May 5 1998 hda1 brw–rw–––– 1 root disk 3, 2 May 5 1998 hda2 brw–rw–––– 1 root disk 3, 3 May 5 1998 hda3 brw–rw–––– 1 root disk 3, 4 May 5 1998 hda4 brw–rw–––– 1 root disk 3, 5 May 5 1998 hda5 brw–rw–––– 1 root disk 3, 6 May 5 1998 hda6 brw–rw–––– 1 root disk 3, 64 May 5 1998 hdb brw–rw–––– 1 root disk 3, 65 May 5 1998 hdb1 brw–rw–––– 1 root disk 3, 66 May 5 1998 hdb2 brw–rw–––– 1 root disk 3, 67 May 5 1998 hdb3 brw–rw–––– 1 root disk 3, 68 May 5 1998 hdb4 brw–rw–––– 1 root disk 3, 69 May 5 1998 hdb5 brw–rw–––– 1 root disk 3, 70 May 5 1998 hdb6 crw–r––––– 1 root kmem 1, 2 May 5 1998 kmem crw–r––––– 1 root kmem 1, 1 May 5 1998 mem lrwxrwxrwx 1 root root 12 Nov 1 15:39 modem –> ttyS1 lrwxrwxrwx 1 root root 12 Nov 1 15:39 mouse –> psaux crw–rw–rw– 1 root root 1, 3 May 5 1998 null crwxrwxrwx 1 root root 10, 1 Oct 5 20:22 psaux brw–r––––– 1 root disk 1, 1 May 5 1998 ram brw–rw–––– 1 root disk 1, 0 May 5 1998 ram0 brw–rw–––– 1 root disk 1, 1 May 5 1998 ram1 brw–rw–––– 1 root disk 1, 2 May 5 1998 ram2 brw–rw–––– 1 root disk 1, 3 May 5 1998 ram3 brw–rw–––– 1 root disk 1, 4 May 5 1998 ram4 brw–rw–––– 1 root disk 1, 5 May 5 1998 ram5 brw–rw–––– 1 root disk 1, 6 May 5 1998 ram6 brw–rw–––– 1 root disk 1, 7 May 5 1998 ram7 brw–rw–––– 1 root disk 1, 8 May 5 1998 ram8 brw–rw–––– 1 root disk 1, 9 May 5 1998 ram9 lrwxrwxrwx 1 root root 4 Nov 1 15:39 ramdisk –> ram0 *** I have only included devices for the IDE partitions I use. *** If you use SCSI, then use the /dev/sdXX devices instead. crw––––––– 1 root root 4, 0 May 5 1998 tty0 crw–w––––– 1 root tty 4, 1 Nov 1 15:39 tty1 crw––––––– 1 root root 4, 2 Nov 1 15:29 tty2 crw––––––– 1 root root 4, 3 Nov 1 15:29 tty3 crw––––––– 1 root root 4, 4 Nov 1 15:29 tty4 crw––––––– 1 root root 4, 5 Nov 1 15:29 tty5 crw––––––– 1 root root 4, 6 Nov 1 15:29 tty6 crw––––––– 1 root root 4, 7 May 5 1998 tty7 crw––––––– 1 root tty 4, 8 May 5 1998 tty8 crw––––––– 1 root tty 4, 9 May 8 12:57 tty9 crw–rw–rw– 1 root root 4, 65 Nov 1 12:17 ttyS1 crw–rw–rw– 1 root root 1, 5 May 5 1998 zero /etc: –rw––––––– 1 root root 164 Nov 1 15:39 conf.modules –rw––––––– 1 root root 668 Nov 1 15:39 fstab –rw––––––– 1 root root 71 Nov 1 15:39 gettydefs –rw––––––– 1 root root 389 Nov 1 15:39 group –rw––––––– 1 root root 413 Nov 1 15:39 inittab –rw––––––– 1 root root 65 Nov 1 15:39 issue –rw–r––r–– 1 root root 746 Nov 1 15:39 ld.so.cache –rw––––––– 1 root root 32 Nov 1 15:39 motd –rw––––––– 1 root root 949 Nov 1 15:39 nsswitch.conf drwx––x––x 2 root root 1024 Nov 1 15:39 pam.d –rw––––––– 1 root root 139 Nov 1 15:39 passwd –rw––––––– 1 root root 516 Nov 1 15:39 profile –rwx––x––x 1 root root 387 Nov 1 15:39 rc –rw––––––– 1 root root 55 Nov 1 15:39 shells –rw––––––– 1 root root 774 Nov 1 15:39 termcap –rw––––––– 1 root root 78 Nov 1 15:39 ttytype lrwxrwxrwx 1 root root 15 Nov 1 15:39 utmp –> ../var/run/utmp lrwxrwxrwx 1 root root 15 Nov 1 15:39 wtmp –> ../var/log/wtmp /etc/pam.d: –rw––––––– 1 root root 356 Nov 1 15:39 other /lib: –rwxr–xr–x 1 root root 45415 Nov 1 15:39 ld–2.0.7.so lrwxrwxrwx 1 root root 11 Nov 1 15:39 ld–linux.so.2 –> ld–2.0.7.so –rwxr–xr–x 1 root root 731548 Nov 1 15:39 libc–2.0.7.so lrwxrwxrwx 1 root root 13 Nov 1 15:39 libc.so.6 –> libc–2.0.7.so lrwxrwxrwx 1 root root 17 Nov 1 15:39 libcom_err.so.2 –> libcom_err.so.2.0 –rwxr–xr–x 1 root root 6209 Nov 1 15:39 libcom_err.so.2.0 –rwxr–xr–x 1 root root 153881 Nov 1 15:39 libcrypt–2.0.7.so lrwxrwxrwx 1 root root 17 Nov 1 15:39 libcrypt.so.1 –> libcrypt–2.0.7.so –rwxr–xr–x 1 root root 12962 Nov 1 15:39 libdl–2.0.7.so lrwxrwxrwx 1 root root 14 Nov 1 15:39 libdl.so.2 –> libdl–2.0.7.so lrwxrwxrwx 1 root root 16 Nov 1 15:39 libext2fs.so.2 –> libext2fs.so.2.4 –rwxr–xr–x 1 root root 81382 Nov 1 15:39 libext2fs.so.2.4 –rwxr–xr–x 1 root root 25222 Nov 1 15:39 libnsl–2.0.7.so lrwxrwxrwx 1 root root 15 Nov 1 15:39 libnsl.so.1 –> libnsl–2.0.7.so –rwx––x––x 1 root root 178336 Nov 1 15:39 libnss_files–2.0.7.so lrwxrwxrwx 1 root root 21 Nov 1 15:39 libnss_files.so.1 –> libnss_files–2.0.7.so lrwxrwxrwx 1 root root 14 Nov 1 15:39 libpam.so.0 –> libpam.so.0.64 –rwxr–xr–x 1 root root 26906 Nov 1 15:39 libpam.so.0.64 lrwxrwxrwx 1 root root 19 Nov 1 15:39 libpam_misc.so.0 –> libpam_misc.so.0.64 –rwxr–xr–x 1 root root 7086 Nov 1 15:39 libpam_misc.so.0.64 –r–xr–xr–x 1 root root 35615 Nov 1 15:39 libproc.so.1.2.6 lrwxrwxrwx 1 root root 15 Nov 1 15:39 libpwdb.so.0 –> libpwdb.so.0.54 –rw–r–r––– 1 root root 121899 Nov 1 15:39 libpwdb.so.0.54 lrwxrwxrwx 1 root root 19 Nov 1 15:39 libtermcap.so.2 –> libtermcap.so.2.0.8 –rwxr–xr–x 1 root root 12041 Nov 1 15:39 libtermcap.so.2.0.8 –rwxr–xr–x 1 root root 12874 Nov 1 15:39 libutil–2.0.7.so lrwxrwxrwx 1 root root 16 Nov 1 15:39 libutil.so.1 –> libutil–2.0.7.so lrwxrwxrwx 1 root root 14 Nov 1 15:39 libuuid.so.1 –> libuuid.so.1.1 –rwxr–xr–x 1 root root 8039 Nov 1 15:39 libuuid.so.1.1 drwx––x––x 3 root root 1024 Nov 1 15:39 modules drwx––x––x 2 root root 1024 Nov 1 15:39 security /lib/modules: drwx––x––x 4 root root 1024 Nov 1 15:39 2.0.35 /lib/modules/2.0.35: drwx––x––x 2 root root 1024 Nov 1 15:39 block drwx––x––x 2 root root 1024 Nov 1 15:39 cdrom /lib/modules/2.0.35/block: drwx–––––– 1 root root 7156 Nov 1 15:39 loop.o /lib/modules/2.0.35/cdrom: drwx–––––– 1 root root 24108 Nov 1 15:39 cdu31a.o /lib/security: –rwx––x––x 1 root root 8771 Nov 1 15:39 pam_permit.so *** Directory stubs for mounting /mnt: drwx––x––x 2 root root 1024 Nov 1 15:39 cdrom drwx––x––x 2 root root 1024 Nov 1 15:39 floppy /proc: /root: –rw––––––– 1 root root 176 Nov 1 15:39 .bashrc –rw––––––– 1 root root 182 Nov 1 15:39 .cshrc –rwx––x––x 1 root root 455 Nov 1 15:39 .profile –rw––––––– 1 root root 4014 Nov 1 15:39 .tcshrc /sbin: –rwx––x––x 1 root root 23976 Nov 1 15:39 depmod –rwx––x––x 2 root root 274600 Nov 1 15:39 e2fsck –rwx––x––x 1 root root 41268 Nov 1 15:39 fdisk –rwx––x––x 1 root root 9396 Nov 1 15:39 fsck –rwx––x––x 2 root root 274600 Nov 1 15:39 fsck.ext2 –rwx––x––x 1 root root 29556 Nov 1 15:39 getty –rwx––x––x 1 root root 6620 Nov 1 15:39 halt –rwx––x––x 1 root root 23116 Nov 1 15:39 init –rwx––x––x 1 root root 25612 Nov 1 15:39 insmod –rwx––x––x 1 root root 10368 Nov 1 15:39 kerneld –rwx––x––x 1 root root 110400 Nov 1 15:39 ldconfig –rwx––x––x 1 root root 6108 Nov 1 15:39 lsmod –rwx––x––x 2 root root 17400 Nov 1 15:39 mke2fs –rwx––x––x 1 root root 4072 Nov 1 15:39 mkfs –rwx––x––x 2 root root 17400 Nov 1 15:39 mkfs.ext2 –rwx––x––x 1 root root 5664 Nov 1 15:39 mkswap –rwx––x––x 1 root root 22032 Nov 1 15:39 modprobe lrwxrwxrwx 1 root root 4 Nov 1 15:39 reboot –> halt –rwx––x––x 1 root root 7492 Nov 1 15:39 rmmod –rwx––x––x 1 root root 12932 Nov 1 15:39 shutdown lrwxrwxrwx 1 root root 6 Nov 1 15:39 swapoff –> swapon –rwx––x––x 1 root root 5124 Nov 1 15:39 swapon lrwxrwxrwx 1 root root 4 Nov 1 15:39 telinit –> init –rwx––x––x 1 root root 6944 Nov 1 15:39 update /tmp: /usr: drwx––x––x 2 root root 1024 Nov 1 15:39 bin drwx––x––x 2 root root 1024 Nov 1 15:39 lib drwx––x––x 3 root root 1024 Nov 1 15:39 man drwx––x––x 2 root root 1024 Nov 1 15:39 sbin drwx––x––x 3 root root 1024 Nov 1 15:39 share lrwxrwxrwx 1 root root 10 Nov 1 15:39 tmp –> ../var/tmp /usr/bin: –rwx––x––x 1 root root 37164 Nov 1 15:39 afio –rwx––x––x 1 root root 5044 Nov 1 15:39 chroot –rwx––x––x 1 root root 10656 Nov 1 15:39 cut –rwx––x––x 1 root root 63652 Nov 1 15:39 diff –rwx––x––x 1 root root 12972 Nov 1 15:39 du –rwx––x––x 1 root root 56552 Nov 1 15:39 find –r–x––x––x 1 root root 6280 Nov 1 15:39 free –rwx––x––x 1 root root 7680 Nov 1 15:39 head –rwx––x––x 1 root root 8504 Nov 1 15:39 id –r–sr–xr–x 1 root bin 4200 Nov 1 15:39 passwd –rwx––x––x 1 root root 14856 Nov 1 15:39 tail –rwx––x––x 1 root root 19008 Nov 1 15:39 tr –rwx––x––x 1 root root 7160 Nov 1 15:39 wc –rwx––x––x 1 root root 4412 Nov 1 15:39 whoami /usr/lib: lrwxrwxrwx 1 root root 17 Nov 1 15:39 libncurses.so.4 –> libncurses.so.4.2 –rw–r–r––– 1 root root 260474 Nov 1 15:39 libncurses.so.4.2 /usr/sbin: –r–x––x––x 1 root root 13684 Nov 1 15:39 fuser –rwx––x––x 1 root root 3876 Nov 1 15:39 mklost+found /usr/share: drwx––x––x 4 root root 1024 Nov 1 15:39 terminfo /usr/share/terminfo: drwx––x––x 2 root root 1024 Nov 1 15:39 l drwx––x––x 2 root root 1024 Nov 1 15:39 v /usr/share/terminfo/l: –rw––––––– 1 root root 1552 Nov 1 15:39 linux –rw––––––– 1 root root 1516 Nov 1 15:39 linux–m –rw––––––– 1 root root 1583 Nov 1 15:39 linux–nic /usr/share/terminfo/v: –rw––––––– 2 root root 1143 Nov 1 15:39 vt100 –rw––––––– 2 root root 1143 Nov 1 15:39 vt100–am /var: drwx––x––x 2 root root 1024 Nov 1 15:39 log drwx––x––x 2 root root 1024 Nov 1 15:39 run drwx––x––x 2 root root 1024 Nov 1 15:39 tmp /var/log: –rw––––––– 1 root root 0 Nov 1 15:39 wtmp /var/run: –rw––––––– 1 root root 0 Nov 1 15:39 utmp /var/tmp: |
total 579 –rwxr–xr–x 1 root root 42333 Jul 28 19:05 cpio –rwxr–xr–x 1 root root 32844 Aug 28 19:50 debugfs –rwxr–xr–x 1 root root 103560 Jul 29 21:31 elvis –rwxr–xr–x 1 root root 29536 Jul 28 19:04 fdisk –rw–r–r––– 1 root root 128254 Jul 28 19:03 ftape.o –rwxr–xr–x 1 root root 17564 Jul 25 03:21 ftmt –rwxr–xr–x 1 root root 64161 Jul 29 20:47 grep –rwxr–xr–x 1 root root 45309 Jul 29 20:48 gzip –rwxr–xr–x 1 root root 23560 Jul 28 19:04 insmod –rwxr–xr–x 1 root root 118 Jul 28 19:04 lsmod lrwxrwxrwx 1 root root 5 Jul 28 19:04 mt –> mt–st –rwxr–xr–x 1 root root 9573 Jul 28 19:03 mt–st lrwxrwxrwx 1 root root 6 Jul 28 19:05 rmmod –> insmod –rwxr–xr–x 1 root root 104085 Jul 28 19:05 tar lrwxrwxrwx 1 root root 5 Jul 29 21:35 vi –> elvis |
[1] | The directory structure presented here is for root diskette use only. Real Linux systems have a more complex and disciplined set of policies, called the Filesystem Hierarchy Standard, for determining where files should go.) |