1.2. A Detailed Look at the Boot Process
The beginning of the boot process varies depending on the hardware
platform being used. However, once the kernel is found and loaded by the
boot loader, the default boot process is identical across all
architectures. This chapter focuses on the x86 architecture.
1.2.1. The BIOS
When an x86 computer is booted, the processor looks at the end of
system memory for the Basic Input/Output System
or BIOS program and runs it. The BIOS controls
not only the first step of the boot process, but also provides the
lowest level interface to peripheral devices. For this reason it is
written into read-only, permanent memory and is always available for
use.
Other platforms use different programs to perform low-level tasks
roughly equivalent to those of the BIOS on an x86 system. For
instance, Itanium-based computers use the Extensible
Firmware Interface (EFI)
Shell, while Alpha systems use the
SRM console.
Once loaded, the BIOS tests the system, looks for and checks
peripherals, and then locates a valid device with which to boot the
system. Usually, it checks any diskette drives and CD-ROM drives
present for bootable media, then, failing that, looks to the system's
hard drives. In most cases, the order of the drives searched while
booting is controlled with a setting in BIOS, and it looks on the
master IDE device on the primary IDE bus. The BIOS then loads into
memory whatever program is residing in the first sector of this
device, called the Master Boot Record or
MBR. The MBR is only 512 bytes in size and
contains machine code instructions for booting the machine, called a
boot loader, along with the partition table. Once the BIOS finds and
loads the boot loader program into memory, it yields control of the
boot process to it.
1.2.2. The Boot Loader
This section looks at the boot loaders for the x86 platform. Depending
on the system's architecture, the boot process may differ slightly.
Please see Section 1.2.2.1 Boot Loaders for Other Architectures
for a brief overview of non-x86 boot loaders.
Under Red Hat Linux two boot loaders are available:
GRUB or LILO. GRUB is
the default boot loader, but LILO is available for those who require
or prefer it. For more information about configuring and using GRUB or
LILO, see Chapter 2 Boot Loaders.
Both boot loaders for the x86 platform are broken into at least two
stages. The first stage is a small machine code binary on the MBR. Its
sole job is to locate the second stage boot loader and load the first
part of it into memory.
GRUB is the newer boot loader and has the advantage of being able read
ext2 and ext3
[1] partitions and load its configuration file —
/boot/grub/grub.conf — at boot time. See
Section 2.7 GRUB Menu Configuration File for information on how to edit
this file.
With LILO, the second stage boot loader uses information on the MBR to
determine the boot options available to the user. This means that any
time a configuration change is made or kernel is manually upgraded,
the /sbin/lilo -v -v command must be executed to
write the appropriate information to the MBR. For details on doing
this, see Section 2.8 LILO.
 | Tip |
|---|
| | If upgrading the kernel using the Red Hat Update Agent,
the boot loader configuration file is updated automatically. More
information on Red Hat Network can be found online at the following URL:
https://rhn.redhat.com.
|
Once the second stage boot loader is in memory, it presents the user
with the Red Hat Linux initial, graphical screen showing the different
operating systems or kernels it has been configured to boot. On this
screen a user can use the arrow keys to choose which operating system
or kernel they wish to boot and press [Enter]. If no
key is pressed, the boot loader will load the default selection after
a configurable period of time has passed.
 | Note |
|---|
| | If Symmetric Multi-Processor (SMP) kernel support is installed,
there will be more than one option present the first time the system
is booted. In this situation, LILO will display
linux, which is the SMP kernel, and
linux-up, which is for single
processors. GRUB displays Red Hat Linux
(<kernel-version>-smp),
which is the SMP kernel, and Red Hat Linux
(<kernel-version>),
which is for single processors.
If any problems occur using the SMP kernel, try selecting the a
non-SMP kernel upon rebooting.
|
Once the second stage boot loader has determined which kernel to boot,
it locates the corresponding kernel binary in the
/boot/ directory. The kernel binary is named
using the following format —
/boot/vmlinuz-<kernel-version>
file (where
<kernel-version>
corresponds to the kernel version specified in the boot loader's
settings).
For instructions on using the boot loader to supply command line
arguments to the kernel, see Chapter 2 Boot Loaders. For information
on changing the runlevel at the GRUB or LILO prompt, see Section 2.10 Changing Runlevels at Boot Time.
The boot loader then places the appropriate initial RAM
disk image, called an initrd, into
memory. The initrd is used by the kernel to
load drivers necessary to boot the system. This is particularly
important if SCSI hard drives are present or if the systems uses the
ext3 file system
[2].
 | Warning |
|---|
| | Do not remove the /initrd/ directory from the
file system for any reason. Removing this directory will cause the
system to fail with a kernel panic error message at boot time.
|
Once the kernel and the initrd image are loaded
into memory, the boot loader hands control of the boot process to
the kernel.
For a more detailed overview of the GRUB and LILO boot loaders, see
Chapter 2 Boot Loaders.
1.2.2.1. Boot Loaders for Other Architectures
Once the Red Hat Linux kernel loads and hands off the boot process to the
init command, the same sequence of events occurs on
every architecture. So the main difference between each architecture's boot
process is in the application used to find and load the kernel.
For example, the Alpha architecture uses the aboot
boot loader, while the Itanium architecture uses the ELILO boot loader.
Consult the Red Hat Linux Installation Guide specific to these
platforms for information on configuring their boot loaders.
1.2.3. The Kernel
When the kernel is loaded, it immediately initializes and configures
the computer's memory and configures the various hardware attached to
the system, including all processors, I/O subsystems, and storage
devices. It then looks for the compressed initrd
image in a predetermined location in memory, decompresses it, mounts
it, and loads all necessary drivers. Next, it initializes virtual
devices related to the file system, such as LVM or software RAID
before unmounting the initrd disk image and
freeing up all the memory the disk image once occupied.
The kernel then creates a root device, mounts the root partition
read-only, and frees any unused memory.
At this point, the kernel is loaded into memory and operational.
However, since there are no user applications that allow meaningful
input to the system, not much can be done with it.
In order to set up the user environment, the kernel executes the
/sbin/init program.
1.2.4. The /sbin/init Program
The /sbin/init program (also called
init) coordinates the rest of the boot process and
configures the environment for the user.
When the init command starts, it becomes the parent
or grandparent of all of the processes that start up automatically on
a Red Hat Linux system. First, it runs the
/etc/rc.d/rc.sysinit script, which sets the
environment path, starts swap, checks the file systems, and takes care
of everything the system needs to have done at system
initialization. For example, most systems use a clock, so on them
rc.sysinit reads the
/etc/sysconfig/clock configuration file to
initialize the hardware clock. Another example is if there are special
serial port processes which must be initialized,
rc.sysinit will execute the
/etc/rc.serial file.
The init command then runs the
/etc/inittab script, which describes how the
system should be set up in each SysV init
runlevel
[3]. Among other things, the
/etc/inittab sets the default runlevel and
dictates that /sbin/update should be run whenever
it starts a given runlevel
[4].
Next, the init command sets the source function
library, /etc/rc.d/init.d/functions, for the
system. This spells out how to start or kill a program and how to
determine the PID of a program.
The init program starts all of the background
processes by looking in the appropriate rc
directory for the runlevel specified as default in
/etc/inittab. The rc
directories are numbered to corresponds to the runlevel they
represent. For instance, /etc/rc.d/rc5.d/ is the
directory for runlevel 5.
When booting to runlevel 5, the init program looks
in the /etc/rc.d/rc5.d/ directory to determine
which processes to start and stop.
Below is an example listing of the
/etc/rc.d/rc5.d/ directory:
K05innd -> ../init.d/innd
K05saslauthd -> ../init.d/saslauthd
K10psacct -> ../init.d/psacct
K12cWnn -> ../init.d/cWnn
K12FreeWnn -> ../init.d/FreeWnn
K12kWnn -> ../init.d/kWnn
K12mysqld -> ../init.d/mysqld
K12tWnn -> ../init.d/tWnn
K15httpd -> ../init.d/httpd
K15postgresql -> ../init.d/postgresql
K16rarpd -> ../init.d/rarpd
K20bootparamd -> ../init.d/bootparamd
K20iscsi -> ../init.d/iscsi
K20netdump-server -> ../init.d/netdump-server
K20nfs -> ../init.d/nfs
K20rstatd -> ../init.d/rstatd
K20rusersd -> ../init.d/rusersd
K20rwalld -> ../init.d/rwalld
K20rwhod -> ../init.d/rwhod
K24irda -> ../init.d/irda
K25squid -> ../init.d/squid
K28amd -> ../init.d/amd
K34dhcrelay -> ../init.d/dhcrelay
K34yppasswdd -> ../init.d/yppasswdd
K35atalk -> ../init.d/atalk
K35dhcpd -> ../init.d/dhcpd
K35smb -> ../init.d/smb
K35vncserver -> ../init.d/vncserver
K35winbind -> ../init.d/winbind
K40mars-nwe -> ../init.d/mars-nwe
K45arpwatch -> ../init.d/arpwatch
K45named -> ../init.d/named
K45smartd -> ../init.d/smartd
K46radvd -> ../init.d/radvd
K50netdump -> ../init.d/netdump
K50snmpd -> ../init.d/snmpd
K50snmptrapd -> ../init.d/snmptrapd
K50tux -> ../init.d/tux
K54pxe -> ../init.d/pxe
K55routed -> ../init.d/routed
K61ldap -> ../init.d/ldap
K65identd -> ../init.d/identd
K65kadmin -> ../init.d/kadmin
K65kprop -> ../init.d/kprop
K65krb524 -> ../init.d/krb524
K65krb5kdc -> ../init.d/krb5kdc
K70aep1000 -> ../init.d/aep1000
K70bcm5820 -> ../init.d/bcm5820
K74ntpd -> ../init.d/ntpd
K74ups -> ../init.d/ups
K74ypserv -> ../init.d/ypserv
K74ypxfrd -> ../init.d/ypxfrd
K84bgpd -> ../init.d/bgpd
K84ospf6d -> ../init.d/ospf6d
K84ospfd -> ../init.d/ospfd
K84ripd -> ../init.d/ripd
K84ripngd -> ../init.d/ripngd
K85zebra -> ../init.d/zebra
K90isicom -> ../init.d/isicom
K92ipvsadm -> ../init.d/ipvsadm
K95firstboot -> ../init.d/firstboot
S00microcode_ctl -> ../init.d/microcode_ctl
S05kudzu -> ../init.d/kudzu
S08ip6tables -> ../init.d/ip6tables
S08ipchains -> ../init.d/ipchains
S08iptables -> ../init.d/iptables
S09isdn -> ../init.d/isdn
S10network -> ../init.d/network
S12syslog -> ../init.d/syslog
S13portmap -> ../init.d/portmap
S14nfslock -> ../init.d/nfslock
S17keytable -> ../init.d/keytable
S20random -> ../init.d/random
S24pcmcia -> ../init.d/pcmcia
S25netfs -> ../init.d/netfs
S26apmd -> ../init.d/apmd
S28autofs -> ../init.d/autofs
S44acpid -> ../init.d/acpid
S55sshd -> ../init.d/sshd
S56rawdevices -> ../init.d/rawdevices
S56xinetd -> ../init.d/xinetd
S80sendmail -> ../init.d/sendmail
S80spamassassin -> ../init.d/spamassassin
S84privoxy -> ../init.d/privoxy
S85gpm -> ../init.d/gpm
S90canna -> ../init.d/canna
S90crond -> ../init.d/crond
S90cups -> ../init.d/cups
S90xfs -> ../init.d/xfs
S95anacron -> ../init.d/anacron
S95atd -> ../init.d/atd
S97rhnsd -> ../init.d/rhnsd
S99local -> ../rc.local
S99mdmonitor -> ../init.d/mdmonitor |
As illustrated in this listing, none of the scripts that actually
start and stop the services are located in the
/etc/rc.d/rc5.d/ directory. Rather, all of the
files in /etc/rc.d/rc5.d/ are symbolic
links pointing to scripts located in the
/etc/rc.d/init.d/ directory. Symbolic links are
used in each of the rc directories so that the
runlevels can be reconfigured by creating, modifying, and deleting the
symbolic links without affecting the actual scripts they reference.
The name of each symbolic link begin with either a
K or an
S. The
K links are processes that are killed
on that runlevel, while those beginning with an
S are started.
The init command first stops all of the
K symbolic links in the directory by
issuing the
/etc/rc.d/init.d/<command>
stop command, where
<command> is the process to be
killed. It then starts all of the S
symbolic links by issuing
/etc/rc.d/init.d/<command>
start.
| Tip |
|---|
| | After the system is finished booting, it is possible to log in as
root and execute these same scripts to start and stop services. For
instance, the command /etc/rc.d/init.d/httpd stop
will stop the Apache Web server.
|
Each of the symbolic links are numbered to dictate start order. The
order in which the services are started or stopped can be altered by
changing this number. The lower the number, the earlier it is
started. Those symbolic links with the same number are started
alphabetically.
After the init command has progressed through the
appropriate rc directory for the runlevel, the
/etc/inittab script forks a
/sbin/mingetty process for each virtual console (login
prompts) allocated to the runlevel. Runlevels 2 through 5 get all six
virtual consoles, while runlevel 1 (single user mode) gets only one
and runlevels 0 and 6 get none. The /sbin/mingetty process
opens communication pathways to tty devices
[5], sets their modes, prints the login prompt, gets the user
name, and initiates the login process for the user.
In runlevel 5, the /etc/inittab runs a script
called /etc/X11/prefdm. The
prefdm script executes the preferred X display
manager — gdm, kdm, or
xdm, depending on the contents of the
/etc/sysconfig/desktop file.
At this point, the system is operating on runlevel 5 and
displaying a login screen.
