Fedora 11

Installation Guide

Installing Fedora 11 on x86, AMD64, and Intel® 64 architectures

Edition 1.0

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Fedora Documentation Project


Legal Notice

Copyright © 2009 Red Hat, Inc. and others.
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Abstract
Provides documentation for the installation process.

Preface
1. Document Conventions
1.1. Typographic Conventions
1.2. Pull-quote Conventions
1.3. Notes and Warnings
2. We Need Feedback!
Introduction
1. Background
1.1. About Fedora
1.2. Getting Additional Help
2. About This Document
2.1. Goals
2.2. Audience
1. Quick Start for Experts
1.1. Overview
1.2. Download Files
1.3. Prepare for Installation
1.4. Install Fedora
1.5. Perform Post-installation Steps
2. New Users
2.1. How Do I Download Installation Files?
2.1.1. From a Mirror
2.1.2. From BitTorrent
2.2. Which Architecture Is My Computer?
2.3. Which Files Do I Download?
2.4. How Do I Make Fedora Media?
2.4.1. Making CD or DVD Discs
2.4.2. Making USB Media
2.5. What If I Cannot Download Fedora?
2.6. How Do I Start the Installation Program?
I. Before you begin
3. Steps to Get You Started
3.1. Upgrade or Install?
3.2. Is Your Hardware Compatible?
3.3. Do You Have Enough Disk Space?
3.4. Can You Install Using the CD-ROM or DVD?
3.4.1. Alternative Boot Methods
3.4.2. Making an Installation Boot CD-ROM
3.5. Preparing for a Network Installation
3.5.1. Preparing for FTP and HTTP installation
3.5.2. Preparing for an NFS install
3.6. Preparing for a Hard Drive Installation
4. System Specifications List
5. Driver Media for Intel and AMD Systems
5.1. Why Do I Need Driver Media?
5.2. So What Is Driver Media Anyway?
5.3. How Do I Obtain Driver Media?
5.3.1. Creating a Driver Diskette from an Image File
5.4. Using a Driver Image During Installation
II. The installation process
6. Beginning the Installation
6.1. The Boot Menu
6.2. Installing from a Different Source
6.3. Verifying Media
6.3.1. Verifying the Live CD
6.3.2. Verifying the DVD
6.4. Booting from the Network using PXE
6.5. Graphical and Text Interfaces
7. Installing on Intel and AMD Systems
7.1. The Graphical Installation Program User Interface
7.1.1. A Note about Virtual Consoles
7.2. The Text Mode Installation Program User Interface
7.2.1. Using the Keyboard to Navigate
7.3. Starting the Installation Program
7.3.1. Booting the Installation Program on x86, AMD64, and Intel 64 Systems
7.3.2. Additional Boot Options
7.4. Selecting an Installation Method
7.5. Installing from DVD/CD-ROM
7.5.1. What If the IDE CD-ROM Was Not Found?
7.6. Installing from a Hard Drive
7.7. Performing a Network Installation
7.8. Installing via NFS
7.9. Installing via FTP or HTTP
7.10. Welcome to Fedora
7.11. Language Selection
7.12. Keyboard Configuration
7.13. Initializing the Hard Disk
7.14. Upgrading an Existing System
7.14.1. Upgrade Examine
7.14.2. Upgrading Using the Installer
7.14.3. Upgrading Boot Loader Configuration
7.15. Network Configuration
7.15.1. Manual configuration
7.16. Time Zone Configuration
7.17. Set the Root Password
7.18. Disk Partitioning Setup
7.18.1. RAID and Other Disk Devices
7.19. Advanced Storage Options
7.20. Create Default Layout
7.21. Partitioning Your System
7.21.1. Graphical Display of Hard Drive(s)
7.21.2. The partitioning screen
7.21.3. Partition Fields
7.21.4. Recommended Partitioning Scheme
7.21.5. Adding Partitions
7.21.6. Editing Partitions
7.21.7. Deleting a Partition
7.22. x86, AMD64, and Intel 64 Boot Loader Configuration
7.22.1. Advanced Boot Loader Configuration
7.22.2. Rescue Mode
7.22.3. Alternative Boot Loaders
7.23. Package Group Selection
7.23.1. Installing from Additional Repositories
7.23.2. Customizing the Software Selection
7.24. Preparing to Install
7.24.1. Prepare to Install
7.25. Installing Packages
7.26. Installation Complete
8. Troubleshooting Installation on an Intel or AMD System
8.1. You are unable to boot Fedora
8.1.1. Are You Unable to Boot With Your RAID Card?
8.1.2. Is Your System Displaying Signal 11 Errors?
8.2. Trouble Beginning the Installation
8.2.1. Problems with Booting into the Graphical Installation
8.3. Trouble During the Installation
8.3.1. No devices found to install Fedora Error Message
8.3.2. Saving traceback messages without removeable media
8.3.3. Trouble with Partition Tables
8.3.4. Using Remaining Space
8.3.5. Other Partitioning Problems
8.3.6. Are You Seeing Python Errors?
8.4. Problems After Installation
8.4.1. Trouble With the Graphical GRUB Screen on an x86-based System?
8.4.2. Booting into a Graphical Environment
8.4.3. Problems with the X Window System (GUI)
8.4.4. Problems with the X Server Crashing and Non-Root Users
8.4.5. Problems When You Try to Log In
8.4.6. Is Your RAM Not Being Recognized?
8.4.7. Your Printer Does Not Work
8.4.8. Problems with Sound Configuration
8.4.9. Apache-based httpd service/Sendmail Hangs During Startup
III. Advanced installation options
9. Boot Options
9.1. Configuring the Installation System at the Boot Menu
9.1.1. Specifying the Language
9.1.2. Configuring the Interface
9.1.3. Updating anaconda
9.1.4. Specifying the Installation Method
9.1.5. Manually Configuring the Network Settings
9.2. Enabling Remote Access to the Installation System
9.2.1. Enabling Remote Access with VNC
9.2.2. Connecting the Installation System to a VNC Listener
9.2.3. Enabling Remote Access with Telnet
9.3. Logging to a Remote System During the Installation
9.3.1. Configuring a Log Server
9.4. Automating the Installation with Kickstart
9.5. Enhancing Hardware Support
9.5.1. Adding Hardware Support with Driver Disks
9.5.2. Overriding Automatic Hardware Detection
9.6. Using the Maintenance Boot Modes
9.6.1. Loading the Memory (RAM) Testing Mode
9.6.2. Verifying boot media
9.6.3. Booting Your Computer with the Rescue Mode
9.6.4. Upgrading your computer
10. Installing Without Media
10.1. Retrieving Boot Files
10.2. Editing the GRUB Configuration
10.3. Booting to Installation
11. Setting Up an Installation Server
11.1. Setting Up cobbler
11.2. Setting Up the Distribution
11.3. Mirroring a Network Location
11.4. Importing the Distribution
11.5. Manually configure a PXE server
11.5.1. Setting up the Network Server
11.5.2. PXE Boot Configuration
11.5.3. Adding PXE Hosts
11.5.4. TFTPD
11.5.5. Configuring the DHCP Server
11.5.6. Adding a Custom Boot Message
11.5.7. Performing the PXE Installation
12. Installing Through VNC
12.1. VNC Viewer
12.2. VNC Modes in Anaconda
12.2.1. Direct Mode
12.2.2. Connect Mode
12.3. Installation Using VNC
12.3.1. Installation Example
12.3.2. Kickstart Considerations
12.3.3. Firewall Considerations
12.4. References
13. Kickstart Installations
13.1. What are Kickstart Installations?
13.2. How Do You Perform a Kickstart Installation?
13.3. Creating the Kickstart File
13.4. Kickstart Options
13.4.1. Advanced Partitioning Example
13.5. Package Selection
13.6. Pre-installation Script
13.6.1. Example
13.7. Post-installation Script
13.7.1. Examples
13.8. Making the Kickstart File Available
13.8.1. Creating Kickstart Boot Media
13.8.2. Making the Kickstart File Available on the Network
13.9. Making the Installation Tree Available
13.10. Starting a Kickstart Installation
14. Kickstart Configurator
14.1. Basic Configuration
14.2. Installation Method
14.3. Boot Loader Options
14.4. Partition Information
14.4.1. Creating Partitions
14.5. Network Configuration
14.6. Authentication
14.7. Firewall Configuration
14.7.1. SELinux Configuration
14.8. Display Configuration
14.9. Package Selection
14.10. Pre-Installation Script
14.11. Post-Installation Script
14.11.1. Chroot Environment
14.11.2. Use an Interpreter
14.12. Saving the File
IV. After installation
15. Firstboot
15.1. License Agreement
15.2. System User
15.3. Date and Time
15.4. Hardware Profile
16. Your Next Steps
16.1. Updating Your System
16.2. Finishing an Upgrade
16.3. Switching to a Graphical Login
16.4. Subscribing to Fedora Announcements and News
16.5. Finding Documentation and Support
16.6. Joining the Fedora Community
17. Basic System Recovery
17.1. Common Problems
17.1.1. Unable to Boot into Fedora
17.1.2. Hardware/Software Problems
17.1.3. Root Password
17.2. Booting into Rescue Mode
17.2.1. Reinstalling the Boot Loader
17.3. Booting into Single-User Mode
17.4. Booting into Emergency Mode
18. Upgrading Your Current System
18.1. Determining Whether to Upgrade or Re-Install
18.2. Upgrading Your System
19. Removing Fedora
19.1. Fedora is the only operating system on the computer
19.2. Your computer dual-boots Fedora and another operating system
19.2.1. Your computer dual-boots Fedora and a Microsoft Windows operating system
19.2.2. Your computer dual-boots Fedora and Mac OS X
19.2.3. Your computer dual-boots Fedora and a different Linux distribution
19.3. Replacing Fedora with MS-DOS or legacy versions of Microsoft Windows
V. Technical appendixes
A. An Introduction to Disk Partitions
A.1. Hard Disk Basic Concepts
A.1.1. It is Not What You Write, it is How You Write It
A.1.2. Partitions: Turning One Drive Into Many
A.1.3. Partitions within Partitions — An Overview of Extended Partitions
A.1.4. Making Room For Fedora
A.1.5. Partition Naming Scheme
A.1.6. Disk Partitions and Other Operating Systems
A.1.7. Disk Partitions and Mount Points
A.1.8. How Many Partitions?
B. ISCSI disks
B.1. iSCSI disks in anaconda
B.2. iSCSI disks during start up
C. Disk Encryption Guide
C.1. What is block device encryption?
C.2. Encrypting block devices using dm-crypt/LUKS
C.2.1. Overview of LUKS
C.2.2. How will I access the encrypted devices after installation? (System Startup)
C.2.3. Choosing a Good Passphrase
C.3. Creating Encrypted Block Devices in Anaconda
C.3.1. What Kinds of Block Devices Can Be Encrypted?
C.3.2. Limitations of Anaconda's Block Device Encryption Support
C.4. Creating Encrypted Block Devices on the Installed System After Installation
C.4.1. Create the block devices
C.4.2. Optional: Fill the device with random data
C.4.3. Format the device as a dm-crypt/LUKS encrypted device
C.4.4. Create a mapping to allow access to the device's decrypted contents
C.4.5. Create filesystems on the mapped device, or continue to build complex storage structures using the mapped device
C.4.6. Add the mapping information to /etc/crypttab
C.4.7. Add an entry to /etc/fstab
C.5. Common Post-Installation Tasks
C.5.1. Set a randomly generated key as an additional way to access an encrypted block device
C.5.2. Add a new passphrase to an existing device
C.5.3. Remove a passphrase or key from a device
D. Understanding LVM
E. The GRUB Boot Loader
E.1. GRUB
E.1.1. GRUB and the x86 Boot Process
E.1.2. Features of GRUB
E.2. Installing GRUB
E.3. GRUB Terminology
E.3.1. Device Names
E.3.2. File Names and Blocklists
E.3.3. The Root File System and GRUB
E.4. GRUB Interfaces
E.4.1. Interfaces Load Order
E.5. GRUB Commands
E.6. GRUB Menu Configuration File
E.6.1. Configuration File Structure
E.6.2. Configuration File Directives
E.7. Changing Runlevels at Boot Time
E.8. Additional Resources
E.8.1. Installed Documentation
E.8.2. Useful Websites
E.8.3. Related Books
F. Boot Process, Init, and Shutdown
F.1. The Boot Process
F.2. A Detailed Look at the Boot Process
F.2.1. The BIOS
F.2.2. The Boot Loader
F.2.3. The Kernel
F.2.4. The /sbin/init Program
F.3. Running Additional Programs at Boot Time
F.4. SysV Init Runlevels
F.4.1. Runlevels
F.4.2. Runlevel Utilities
F.5. Shutting Down
G. Other Technical Documentation
H. Contributors and production methods
H.1. Contributors
H.2. Production methods
I. Revision History
Index

Preface

1. Document Conventions

This manual uses several conventions to highlight certain words and phrases and draw attention to specific pieces of information.
In PDF and paper editions, this manual uses typefaces drawn from the Liberation Fonts set. The Liberation Fonts set is also used in HTML editions if the set is installed on your system. If not, alternative but equivalent typefaces are displayed. Note: Red Hat Enterprise Linux 5 and later includes the Liberation Fonts set by default.

1.1. Typographic Conventions

Four typographic conventions are used to call attention to specific words and phrases. These conventions, and the circumstances they apply to, are as follows.
Mono-spaced Bold
Used to highlight system input, including shell commands, file names and paths. Also used to highlight key caps and key-combinations. For example:
To see the contents of the file my_next_bestselling_novel in your current working directory, enter the cat my_next_bestselling_novel command at the shell prompt and press Enter to execute the command.
The above includes a file name, a shell command and a key cap, all presented in Mono-spaced Bold and all distinguishable thanks to context.
Key-combinations can be distinguished from key caps by the hyphen connecting each part of a key-combination. For example:
Press Enter to execute the command.
Press Ctrl+Alt+F1 to switch to the first virtual terminal. Press Ctrl+Alt+F7 to return to your X-Windows session.
The first sentence highlights the particular key cap to press. The second highlights two sets of three key caps, each set pressed simultaneously.
If source code is discussed, class names, methods, functions, variable names and returned values mentioned within a paragraph will be presented as above, in Mono-spaced Bold. For example:
File-related classes include filesystem for file systems, file for files, and dir for directories. Each class has its own associated set of permissions.
Proportional Bold
This denotes words or phrases encountered on a system, including application names; dialogue box text; labelled buttons; check-box and radio button labels; menu titles and sub-menu titles. For example:
Choose System > Preferences > Mouse from the main menu bar to launch Mouse Preferences. In the Buttons tab, click the Left-handed mouse check box and click Close to switch the primary mouse button from the left to the right (making the mouse suitable for use in the left hand).
To insert a special character into a gedit file, choose Applications > Accessories > Character Map from the main menu bar. Next, choose Search > Find… from the Character Map menu bar, type the name of the character in the Search field and click Next. The character you sought will be highlighted in the Character Table. Double-click this highlighted character to place it in the Text to copy field and then click the Copy button. Now switch back to your document and choose Edit > Paste from the gedit menu bar.
The above text includes application names; system-wide menu names and items; application-specific menu names; and buttons and text found within a GUI interface, all presented in Proportional Bold and all distinguishable by context.
Note the > shorthand used to indicate traversal through a menu and its sub-menus. This is to avoid the difficult-to-follow 'Select Mouse from the Preferences sub-menu in the System menu of the main menu bar' approach.
Mono-spaced Bold Italic or Proportional Bold Italic
Whether Mono-spaced Bold or Proportional Bold, the addition of Italics indicates replaceable or variable text. Italics denotes text you do not input literally or displayed text that changes depending on circumstance. For example:
To connect to a remote machine using ssh, type ssh username@domain.name at a shell prompt. If the remote machine is example.com and your username on that machine is john, type ssh john@example.com.
The mount -o remount file-system command remounts the named file system. For example, to remount the /home file system, the command is mount -o remount /home.
To see the version of a currently installed package, use the rpm -q package command. It will return a result as follows: package-version-release.
Note the words in bold italics above — username, domain.name, file-system, package, version and release. Each word is a placeholder, either for text you enter when issuing a command or for text displayed by the system.
Aside from standard usage for presenting the title of a work, italics denotes the first use of a new and important term. For example:
When the Apache HTTP Server accepts requests, it dispatches child processes or threads to handle them. This group of child processes or threads is known as a server-pool. Under Apache HTTP Server 2.0, the responsibility for creating and maintaining these server-pools has been abstracted to a group of modules called Multi-Processing Modules (MPMs). Unlike other modules, only one module from the MPM group can be loaded by the Apache HTTP Server.

1.2. Pull-quote Conventions

Two, commonly multi-line, data types are set off visually from the surrounding text.
Output sent to a terminal is set in Mono-spaced Roman and presented thus:
books        Desktop   documentation  drafts  mss    photos   stuff  svn
books_tests  Desktop1  downloads      images  notes  scripts  svgs
Source-code listings are also set in Mono-spaced Roman but are presented and highlighted as follows:
package org.jboss.book.jca.ex1;

import javax.naming.InitialContext;

public class ExClient
{
   public static void main(String args[]) 
       throws Exception
   {
      InitialContext iniCtx = new InitialContext();
      Object         ref    = iniCtx.lookup("EchoBean");
      EchoHome       home   = (EchoHome) ref;
      Echo           echo   = home.create();

      System.out.println("Created Echo");

      System.out.println("Echo.echo('Hello') = " + echo.echo("Hello"));
   }
   
}

1.3. Notes and Warnings

Finally, we use three visual styles to draw attention to information that might otherwise be overlooked.

Note

A Note is a tip or shortcut or alternative approach to the task at hand. Ignoring a note should have no negative consequences, but you might miss out on a trick that makes your life easier.

Important

Important boxes detail things that are easily missed: configuration changes that only apply to the current session, or services that need restarting before an update will apply. Ignoring Important boxes won't cause data loss but may cause irritation and frustration.

Warning

A Warning should not be ignored. Ignoring warnings will most likely cause data loss.

2. We Need Feedback!

When submitting a bug report, be sure to mention the manual's identifier: Installation_Guide
If you have a suggestion for improving the documentation, try to be as specific as possible when describing it. If you have found an error, please include the section number and some of the surrounding text so we can find it easily.

Introduction

This guide covers installation of Fedora, a Linux distribution built on free and open source software. This manual helps you install Fedora on desktops, laptops, and servers. The installation system is easy to use even if you lack previous knowledge of Linux or computer networks. If you select default options, Fedora provides a complete desktop operating system, including productivity applications, Internet utilities, and desktop tools.
This document does not detail all of the features of the installation system.

1. Background

1.1. About Fedora

To find out more about Fedora, refer to http://fedoraproject.org/. To read other documentation on Fedora related topics, refer to http://docs.fedoraproject.org/.

1.2. Getting Additional Help

For information on additional help resources for Fedora, visit http://fedoraproject.org/wiki/Communicate.

2. About This Document

2.1. Goals

This guide helps a reader:
  1. Understand how to locate the Fedora distribution online
  2. Create configuration data that allows a computer to boot Fedora
  3. Understand and interact with the Fedora installation program
  4. Complete basic post-installation configuration of a Fedora system

Other Sources of Documentation

This guide does not cover use of Fedora. To learn how to use an installed Fedora system, refer to http://docs.fedoraproject.org/ for other documentation.

2.2. Audience

This guide is intended for new and intermediate Fedora users. Advanced Fedora users with questions about detailed operation of expert installation features should consult the Anaconda development mailing list at http://www.redhat.com/archives/anaconda-devel-list/.

Chapter 1. Quick Start for Experts

This section offers a very brief overview of installation tasks for experienced readers who are eager to get started. Note that many explanatory notes and helpful hints appear in the following chapters of this guide. If an issue arises during the installation process, consult the appropriate chapters in the full guide for help.

Experts Only

This section is intended only for experts. Other readers may not be familiar with some of the terms in this section, and should move on to Chapter 2, New Users instead.

1.1. Overview

The installation procedure is fairly simple, and consists of only a few steps:
  1. Download files to make media or another bootable configuration.
  2. Prepare system for installation.
  3. Boot the computer and run the installation process.
  4. Reboot and perform post-installation configuration.

1.2. Download Files

Do any one of the following:

Verify your downloads

Downloads may fail for any number of reasons. Always verify the sha1sum of the downloaded files.

1.4. Install Fedora

Boot from the desired media, with any options appropriate for your hardware and installation mode. Refer to Chapter 9, Boot Options for more information about boot options. If you boot from the Live CD, select the "Install to Hard Disk" option from the desktop to run the installation program. If you boot from minimal media or a downloaded kernel, select a network or hard disk resource from which to install.
Proceed through all the steps of the installation program. The installation program does not change your system until you make a final confirmation to proceed. When installation is finished, reboot your system.

1.5. Perform Post-installation Steps

After the system reboots, it displays additional configuration options. Make appropriate changes to your system and proceed to the login prompt.

Chapter 2. New Users

This chapter explains how to get the files you need to install and run Fedora on your computer. Concepts in this chapter may be new, especially if this is your first free and open source operating system. If you have any trouble with this chapter, find help by visiting the Fedora Forums at http://www.fedoraforum.org/.

Download Links

To follow a Web-based guide to downloading, visit http://get.fedoraproject.org/. For guidance on which architecture to download, refer to Section 2.2, “Which Architecture Is My Computer?”.

2.1. How Do I Download Installation Files?

The Fedora Project distributes Fedora in many ways, mostly free of cost and downloaded over the Internet. The most common distribution method is CD and DVD media. There are several types of CD and DVD media available, including:
  • A full set of the software on DVD media
  • Live images you can use to try Fedora, and then install to your system if you so choose
  • Reduced-size bootable CD and USB flash disk images you can use to install over an Internet connection
  • Source code on DVD media
Most users want the Fedora Live image or the full set of installable software on DVD or CDs. The reduced bootable images are suitable for use with a fast Internet connection and install Fedora on one computer. Source code discs are not used for installing Fedora, but are resources for experienced users and software developers.
Fedora software is available for download at no cost in a variety of ways.

2.1.1. From a Mirror

Mirrors publish Fedora software under a well-organized hierarchy of folders. For example, the Fedora 11 distribution normally appears in the directory fedora/linux/releases/11/. This directory contains a folder for each architecture supported by that release of Fedora. CD and DVD media files appear inside that folder, in a folder called iso/. For example, you can find the file for the DVD distribution of Fedora 11 for x86_64 at fedora/linux/releases/11/Fedora/x86_64/iso/Fedora-11-x86_64-DVD.iso.

2.1.2. From BitTorrent

BitTorrent is a way to download information in cooperation with other computers. Each computer cooperating in the group downloads pieces of the information in a particular torrent from other peers in the group. Computers that have finished downloading all the data in a torrent remain in the swarm to seed, or provide data to other peers. If you download using BitTorrent, as a courtesy you should seed the torrent at least until you have uploaded the same amount of data you downloaded.
If your computer does not have software installed for BitTorrent, visit the BitTorrent home page at http://www.bittorrent.com/download/ to download it. BitTorrent client software is available for Windows, Mac OS, Linux, and many other operating systems.
You do not need to find a special mirror for BitTorrent files. The BitTorrent protocol ensures that your computer participates in a nearby group. To download and use the Fedora BitTorrent files, visit http://torrent.fedoraproject.org/.

Minimal Boot Images

Minimal boot CD and USB flash disk images are not available through BitTorrent.

2.3. Which Files Do I Download?

You have several options to download Fedora. Read the options below to decide the best one for you.
Each file available for download in a Fedora distribution includes the architecture type in the file name. For example, the file for the DVD distribution of Fedora 11 for x86_64 is named Fedora-11-x86_64-DVD.iso. Refer to Section 2.2, “Which Architecture Is My Computer?” if you are unsure of your computer's architecture.
  1. Full Distribution on DVD
    If you have plenty of time, a fast Internet connection, and wish a broader choice of software on the install media, download the full DVD version. Once burned to DVD, the media is bootable and includes an installation program. The DVD version contains a mode to perform rescue operations on your Fedora system in an emergency. You can download the DVD version directly from a mirror, or via BitTorrent.
  2. Live Image
    If you want to try Fedora before you install it on your computer, download the Live image version. If your computer supports booting from CD or USB, you can boot the operating system without making any changes to your hard disk. The Live image also provides an Install to Hard Disk desktop shortcut. If you decide you like what you see, and want to install it, simply activate the selection to copy Fedora to your hard disk. You can download the Live image directly from a mirror, or using BitTorrent.
  3. Minimal Boot Media
    If you have a fast Internet connection but do not want to download the entire distribution, you can download a small boot image. Fedora offers images for a minimal boot environment on CD. Once you boot your system with the minimal media, you can install Fedora directly over the Internet. Although this method still involves downloading a significant amount of data over the Internet, it is almost always much less than the size of the full distribution media. Once you have finished installation, you can add or remove software to your system as desired.

    Download Size

    Installing the default software for Fedora over the Internet requires more time than the Live image, but less time than the entire DVD distribution. Actual results depend on the software you select and network traffic conditions.
The following table explains where to find the desired files on a mirror site. Replace arch with the architecture of the computer being installed.
Media type File locations
Full distribution on DVD fedora/linux/releases/11/Fedora/arch/iso/Fedora-11-arch-DVD.iso
Live image fedora/linux/releases/11/Live/arch/iso/Fedora-11-arch-Live.iso, fedora/linux/releases/11/Live/arch/iso/Fedora-11-KDE-arch-Live.iso
Minimal CD boot media fedora/linux/releases/11/Fedora/arch/os/images/boot.iso
Table 2.2. Locating files

2.4. How Do I Make Fedora Media?

A Fedora ISO file can be turned into either CD or DVD discs. You can turn Fedora Live ISO files into bootable USB media, as well as a CD or DVD.

2.4.1. Making CD or DVD Discs

To learn how to turn ISO images into CD or DVD media, refer to http://docs.fedoraproject.org/readme-burning-isos/.

2.4.2. Making USB Media

To make bootable USB media, use a Fedora Live image. Use either a Windows or Linux system to make the bootable USB media.

USB Image Writing is Nondestructive

Writing the Live image to the USB media is nondestructive. Any existing data on the media is not harmed.
It is always a good idea to back up important data before performing sensitive disk operations.
To begin, make sure there is sufficient free space available on the USB media. There is no need to repartition or reformat your media. It is always a good idea to back up important data before performing sensitive disk operations.

2.4.2.1. USB Image Creation from Windows

  1. Download a Live ISO file as explained in Section 2.3, “Which Files Do I Download?”.
  2. Download the Windows liveusb-creator program at http://fedorahosted.org/liveusb-creator.
  3. Follow the instructions given at the site and in the liveusb-creator program to create the bootable USB media.

2.4.2.2. USB Image Creation in Linux

USB media often comes in the form of flash devices sometimes called pen drives, thumb disks, or keys; or as an externally connected hard disk device. Almost all media of this type is formatted as a vfat file system. You can create bootable USB media on media formatted as ext2, ext3, or vfat.

ext4 and Btrfs

The GRUB bootloader does not support the ext4 or Btrfs file systems. You cannot create bootable USB media on media formatted as ext4 or Btrfs.

Unusual USB Media

In a few cases with oddly formatted or partitioned USB media, the image writing may fail.
  1. Download a Live ISO file as shown in Section 2.3, “Which Files Do I Download?”.
  2. Install the livecd-tools package on your system. For Fedora systems, use the following command:
    su -c 'yum -y install livecd-tools'
    
  3. Plug in your USB media.
  4. Find the device name for your USB media. If the media has a volume name, look up the name in /dev/disk/by-label, or use the findfs:
    su -c 'findfs LABEL="MyLabel"'
    
    If the media does not have a volume name, or you do not know it, consult the /var/log/messages log for details:
    su -c 'less /var/log/messages'
    
  5. Use the livecd-iso-to-disk command to write the ISO image to the media:
    su -c 'livecd-iso-to-disk the_image.iso /dev/sdX1'
    
    Replace sdX1 with the device name for the partition on the USB media. Most flash drives and external hard disks use only one partition. If you have changed this behavior or have oddly partitioned media, you may need to consult other sources of help.

2.5. What If I Cannot Download Fedora?

If you do not have a fast Internet connection, or if you have a problem creating boot media, downloading may not be an option. Fedora DVD and CD distribution media is available from a number of online sources around the world at a minimal cost. Use your favorite Web search engine to locate a vendor, or refer to http://fedoraproject.org/wiki/Distribution.

2.6. How Do I Start the Installation Program?

To start the installation program from minimal boot media, a Live image, or the distribution DVD, follow this procedure:
You may need to press a specific key or combination of keys to boot from the media, or configure your system's Basic Input/Output System, or BIOS, to boot from the media. On most computers you must select the boot or BIOS option promptly after turning on the computer. Most Windows-compatible computer systems use a special key such as F1, F2, F12, or Del to start the BIOS configuration menu. On Apple computers, the C key boots the system from the DVD drive. On older Apple hardware you may need to press Cmd +Opt+Shift+Del to boot from DVD drive.

Configuring the BIOS

If you are not sure what capabilities your computer has, or how to configure the BIOS, consult the documentation provided by the manufacturer. Detailed information on hardware specifications and configuration is beyond the scope of this document.

Part I. Before you begin

This part of the Fedora Installation Guide covers decisions that you should make and resources that you should gather before installing Fedora, including:
  • the decision whether to upgrade an existing installation of Fedora or install a new copy.
  • hardware considerations, and hardware details that you may need during installation.
  • preparing to install Fedora over a network.
  • preparing driver media.

Chapter 3. Steps to Get You Started

3.1. Upgrade or Install?

For information to help you determine whether to perform an upgrade or an installation refer to Chapter 18, Upgrading Your Current System.

3.3. Do You Have Enough Disk Space?

The disk space used by Fedora must be separate from the disk space used by other OSes you may have installed on your system, such as Windows, OS/2, or even a different version of Linux. For x86, AMD64, and Intel® 64 systems, at least two partitions (/ and swap) must be dedicated to Fedora.
Before you start the installation process, you must
  • have enough unpartitioned[1] disk space for the installation of Fedora, or
  • have one or more partitions that may be deleted, thereby freeing up enough disk space to install Fedora.
To gain a better sense of how much space you really need, refer to the recommended partitioning sizes discussed in Section 7.21.4, “Recommended Partitioning Scheme”.
If you are not sure that you meet these conditions, or if you want to know how to create free disk space for your Fedora installation, refer to Appendix A, An Introduction to Disk Partitions.

3.4. Can You Install Using the CD-ROM or DVD?

There are several methods that can be used to install Fedora.
Installing from a CD-ROM or DVD requires that you have a Fedora 11 CD-ROM or DVD, and you have a DVD/CD-ROM drive on a system that supports booting from it.

3.5. Preparing for a Network Installation

Note

Make sure an installation CD (or any other type of CD) is not in your system's CD/DVD drive if you are performing a network-based installation. Having a CD in the drive may cause unexpected errors.
The Fedora installation media must be available for either a network installation (via NFS, FTP, or HTTP) or installation via local storage. Use the following steps if you are performing an NFS, FTP, or HTTP installation.
The NFS, FTP, or HTTP server to be used for installation over the network must be a separate machine which can provide the complete contents of the installation DVD-ROM or the installation CD-ROMs.

Note

The Fedora installation program has the ability to test the integrity of the installation media. It works with the CD / DVD, hard drive ISO, and NFS ISO installation methods. We recommend that you test all installation media before starting the installation process, and before reporting any installation-related bugs (many of the bugs reported are actually due to improperly-burned CDs). To use this test, type the following command at the boot: prompt:
linux mediacheck

Note

In the following examples, the directory on the installation staging server that will contain the installation files will be specified as /location/of/disk/space. The directory that will be made publicly available via FTP, NFS, or HTTP will be specified as /publicly/available/directory. For example, /location/of/disk/space may be a directory you create called /var/isos. /publicly/available/directory might be /var/www/html/f11, for an HTTP install.
To copy the files from the installation DVD or CD-ROMs to a Linux machine which acts as an installation staging server, perform the following steps:
  • Create an iso image from the installation disk(s) using the following command (for DVDs):
    dd if=/dev/dvd of=/location/of/disk/space/f11.iso
    where dvd refers to your DVD drive device.
    For instructions on how to prepare a network installation using CD-ROMs, refer to the instructions on the README-en file in disk1.

3.5.1. Preparing for FTP and HTTP installation

Extract the files from the iso image of the installation DVD or the iso images of the installation CDs and place them in a directory that is shared over FTP or HTTP.
Next, make sure that the directory is shared via FTP or HTTP, and verify client access. You can check to see whether the directory is accessible from the server itself, and then from another machine on the same subnet that you will be installing to.

3.5.2. Preparing for an NFS install

For NFS installation it is not necessary to mount the iso image. It is sufficient to make the iso image itself available via NFS. You can do this by moving the iso image or images to the NFS exported directory:
  • For DVD:
    mv /location/of/disk/space/f11.iso /publicly/available/directory/
  • For CDROMs:
    mv /location/of/disk/space/f11-disk*.iso /publicly/available/directory/
Ensure that the /publicly/available/directory directory is exported via NFS via an entry in /etc/exports.
To export to a specific system:
/publicly/available/directory client.ip.address(ro,no_root_squash)
To export to all systems use an entry such as:
/publicly/available/directory *(ro,no_root_squash)
Start the NFS daemon (on a Fedora system, use /sbin/service nfs start). If NFS is already running, reload the configuration file (on a Fedora system use /sbin/service nfs reload).
Hard drive installations require the use of the ISO (or DVD/CD-ROM) images. An ISO image is a file containing an exact copy of a DVD/CD-ROM image. After placing the required ISO images (the binary Fedora DVD/CD-ROMs) in a directory, choose to install from the hard drive. You can then point the installation program at that directory to perform the installation.
To prepare your system for a hard drive installation, you must set the system up in one of the following ways:
  • Using a set of CD-ROMs, or a DVD — Create ISO image files from each installation CD-ROM, or from the DVD. For each CD-ROM (once for the DVD), execute the following command on a Linux system:
    dd if=/dev/cdrom of=/tmp/file-name.iso
    
  • Using ISO images — transfer these images to the system to be installed.
    Verifying that ISO images are intact before you attempt an installation, helps to avoid problems. To verify the ISO images are intact prior to performing an installation, use an md5sum program (many md5sum programs are available for various operating systems). An md5sum program should be available on the same Linux machine as the ISO images.

Note

The Fedora installation program has the ability to test the integrity of the installation media. It works with the CD / DVD, hard drive ISO, and NFS ISO installation methods. We recommend that you test all installation media before starting the installation process, and before reporting any installation-related bugs (many of the bugs reported are actually due to improperly-burned CDs). To use this test, type the following command at the boot: prompt:
linux mediacheck
Additionally, if a file called updates.img exists in the location from which you install, it is used for updates to anaconda, the installation program. Refer to the file install-methods.txt in the anaconda RPM package for detailed information on the various ways to install Fedora, as well as how to apply the installation program updates.


[1] Unpartitioned disk space means that available disk space on the hard drive(s) you are installing to has not been divided into sections for data. When you partition a disk, each partition behaves like a separate disk drive.

Chapter 4. System Specifications List

However, when performing certain types of installation, some specific details might be useful or even essential.
  • If you plan to use a customized partition layout, record:
    • The model numbers, sizes, types, and interfaces of the hard drives attached to the system. For example, Seagate ST3320613AS 320 GB on SATA0, Western Digital WD7500AAKS 750 GB on SATA1. This will allow you to identify specific hard drives during the partitioning process.
  • If you are installing Fedora as an additional operating system on an existing system, record:
    • The mount points of the existing partitions on the system. For example, /boot on sda1, / on sda2, and /home on sdb1. This will allow you to identify specific partitions during the partitioning process.
  • If you plan to install from an image on a local hard drive:
  • If you plan to install from a network location, or install on an iSCSI target:
    • The make and model numbers of the network adapters on your system. For example, Netgear GA311. This will allow you to identify adapters when manually configuring the network.
    • IP, DHCP, and BOOTP addresses
    • Netmask
    • Gateway IP address
    • One or more name server IP addresses (DNS)
    If any of these networking requirements or terms are unfamiliar to you, contact your network administrator for assistance.
  • If you plan to install from a network location:
  • If you plan to install on an iSCSI target:
  • If your computer is part of a domain:
    • You should verify that the domain name will be supplied by the DHCP server. If not, you will need to input the domain name manually during installation.

Chapter 5. Driver Media for Intel® and AMD Systems

5.1. Why Do I Need Driver Media?

While the Fedora installation program is loading, a screen may appear asking you for driver media. The driver media screen is most often seen in the following scenarios:
  • There is no driver available for a piece of hardware that is necessary for installation to proceed.
  • If you run the installation program by entering linux dd at the installation boot prompt.

5.2. So What Is Driver Media Anyway?

Driver media can add support for hardware that may or may not be supported by the installation program. Driver media could include a driver diskette or image produced by Red Hat, it could be a diskette or CD-ROM you make yourself from driver images found on the Internet, or it could be a diskette or CD-ROM that a hardware vendor includes with a piece of hardware.
Driver media is used if you need access to a particular device to install Fedora. Drivers can be used for non-standard, very new, or uncommon devices.

Note

If an unsupported device is not needed to install Fedora on your system, continue with the installation and add support for the new piece of hardware once the installation is complete.

Part II. The installation process

This part of the Fedora Installation Guide details the installation process itself, from various methods of booting the installer up to the point where the computer must restart to finalize the installation. This part of the manual also includes a chapter on troubleshooting problems with the installation process.

Table of Contents

6. Beginning the Installation
6.1. The Boot Menu
6.2. Installing from a Different Source
6.3. Verifying Media
6.3.1. Verifying the Live CD
6.3.2. Verifying the DVD
6.4. Booting from the Network using PXE
6.5. Graphical and Text Interfaces
7. Installing on Intel and AMD Systems
7.1. The Graphical Installation Program User Interface
7.1.1. A Note about Virtual Consoles
7.2. The Text Mode Installation Program User Interface
7.2.1. Using the Keyboard to Navigate
7.3. Starting the Installation Program
7.3.1. Booting the Installation Program on x86, AMD64, and Intel 64 Systems
7.3.2. Additional Boot Options
7.4. Selecting an Installation Method
7.5. Installing from DVD/CD-ROM
7.5.1. What If the IDE CD-ROM Was Not Found?
7.6. Installing from a Hard Drive
7.7. Performing a Network Installation
7.8. Installing via NFS
7.9. Installing via FTP or HTTP
7.10. Welcome to Fedora
7.11. Language Selection
7.12. Keyboard Configuration
7.13. Initializing the Hard Disk
7.14. Upgrading an Existing System
7.14.1. Upgrade Examine
7.14.2. Upgrading Using the Installer
7.14.3. Upgrading Boot Loader Configuration
7.15. Network Configuration
7.15.1. Manual configuration
7.16. Time Zone Configuration
7.17. Set the Root Password
7.18. Disk Partitioning Setup
7.18.1. RAID and Other Disk Devices
7.19. Advanced Storage Options
7.20. Create Default Layout
7.21. Partitioning Your System
7.21.1. Graphical Display of Hard Drive(s)
7.21.2. The partitioning screen
7.21.3. Partition Fields
7.21.4. Recommended Partitioning Scheme
7.21.5. Adding Partitions
7.21.6. Editing Partitions
7.21.7. Deleting a Partition
7.22. x86, AMD64, and Intel 64 Boot Loader Configuration
7.22.1. Advanced Boot Loader Configuration
7.22.2. Rescue Mode
7.22.3. Alternative Boot Loaders
7.23. Package Group Selection
7.23.1. Installing from Additional Repositories
7.23.2. Customizing the Software Selection
7.24. Preparing to Install
7.24.1. Prepare to Install
7.25. Installing Packages
7.26. Installation Complete
8. Troubleshooting Installation on an Intel or AMD System
8.1. You are unable to boot Fedora
8.1.1. Are You Unable to Boot With Your RAID Card?
8.1.2. Is Your System Displaying Signal 11 Errors?
8.2. Trouble Beginning the Installation
8.2.1. Problems with Booting into the Graphical Installation
8.3. Trouble During the Installation
8.3.1. No devices found to install Fedora Error Message
8.3.2. Saving traceback messages without removeable media
8.3.3. Trouble with Partition Tables
8.3.4. Using Remaining Space
8.3.5. Other Partitioning Problems
8.3.6. Are You Seeing Python Errors?
8.4. Problems After Installation
8.4.1. Trouble With the Graphical GRUB Screen on an x86-based System?
8.4.2. Booting into a Graphical Environment
8.4.3. Problems with the X Window System (GUI)
8.4.4. Problems with the X Server Crashing and Non-Root Users
8.4.5. Problems When You Try to Log In
8.4.6. Is Your RAM Not Being Recognized?
8.4.7. Your Printer Does Not Work
8.4.8. Problems with Sound Configuration
8.4.9. Apache-based httpd service/Sendmail Hangs During Startup

Chapter 6. Beginning the Installation

Aborting the Installation

To abort the installation, either press Ctrl +Alt+Del or power off your computer with the power switch. You may abort the installation process without consequence at any time prior to selecting Write changes to disk on the Write partitioning to disk screen. Fedora makes no permanent changes to your computer until that point. Please be aware that stopping the installation after partitioning has begun can leave your computer unusable.

6.1. The Boot Menu

The boot media displays a graphical boot menu with several options. If no key is hit within 60 seconds, the default boot option runs. To choose the default, either wait for the timer to run out or hit Enter on the keyboard. To select a different option than the default, use the arrow keys on your keyboard, and hit Enter when the correct option is highlighted. If you want to customize the boot options for a particular option, hit the Tab key.

Using Boot Options

For a listing and explanation of common boot options, refer to Chapter 9, Boot Options.
When using Fedora Live media, press any key during the initial boot countdown to bring up the Boot Options menu. The boot options include:
  • Boot
    This option is the default. If you select this option, only the kernel and startup programs load into memory. This option takes less time to load. As you use programs, they are loaded from the disc, which takes more time. This mode can be used on machines with less total memory.
  • Verify and Boot
    This option lets you verify the disc before you run the Live CD environment. Refer to Section 6.3, “Verifying Media” for more information on the verification process.
  • Memory Test
    This option runs an exhaustive test on the memory on your system. For more information, refer to Section 9.6.1, “Loading the Memory (RAM) Testing Mode”.
  • Boot from local drive
    This option boots the system from the first installed disk. If you booted this disc accidentally, use this option to boot from the hard disk immediately without starting the installer.
If you boot the DVD, rescue CD, or minimal boot media, the boot menu options include:
  • Install or upgrade an existing system
    This option is the default. Choose this option to install Fedora onto your computer system using the graphical installation program.
  • Install system with basic video driver
    This option allows you to install Fedora in graphical mode even if the installation program is unable to load the correct driver for your video card. If your screen appears distorted or goes blank when using the the Install or upgrade an existing system option, restart your computer and try this option instead.
  • Rescue installed system
    Choose this option to repair a problem with your installed Fedora system that prevents you from booting normally. Although Fedora is an exceptionally stable computing platform, it is still possible for occasional problems to occur that prevent booting. The rescue environment contains utility programs that allow you fix a wide variety of these problems.
  • Boot from local drive
    (as for Live CD)
  • Memory Test
    (as for Live CD)

6.2. Installing from a Different Source

All boot media except the distribution DVD present a menu that allows you to choose the installation source, such as the network or a hard disk. If you are booting the distribution DVD and do not want to install from the DVD, hit Tab at the boot menu. Add a space and the option linux askmethod to the end of the line that appears below the menu.
You can install Fedora from the ISO images stored on hard disk, or from a network using NFS, FTP, or HTTP methods. Experienced users frequently use one of these methods because it is often faster to read data from a hard disk or network server than from a CD or DVD.
The following table summarizes the different boot methods and recommended installation methods to use with each:
Boot method Installation method
DVD DVD, network, or hard disk
Minimal boot CD or USB, rescue CD Network or hard disk
Live CD or USB Install to Hard Disk application
Table 6.1. Boot methods and installation methods

Section 7.4, “Selecting an Installation Method” contains detailed information about installing from alternate locations.

6.3. Verifying Media

The distribution DVD media and the Live CD media offer an option to verify the integrity of the media. Recording errors sometimes occur while producing CD or DVD media in home computer equipment. An error in the data for package chosen in the installation program can cause the installation to abort. To minimize the chances of data errors affecting the installation, verify the media before installing.

6.3.1. Verifying the Live CD

If you boot from the Live CD, choose Verify and Boot from the boot menu. The verification process runs automatically during the boot process, and if it succeeds, the Live CD continues loading. If the verification fails, create a new Live CD using the ISO image you downloaded earlier.

6.3.2. Verifying the DVD

If you boot from the Fedora distribution DVD, the option to verify the media appears after you choose to install Fedora. If the verification succeeds, the installation process proceeds normally. If the process fails, create a new DVD using the ISO image you downloaded earlier.

6.4. Booting from the Network using PXE

Configure the computer to boot from the network interface. This option is in the BIOS, and may be labeled Network Boot or Boot Services. Once you properly configure PXE booting, the computer can boot the Fedora installation system without any other media.
To boot a computer from a PXE server:
  1. Ensure that the network cable is attached. The link indicator light on the network socket should be lit, even if the computer is not switched on.
  2. Switch on the computer.
  3. A menu screen appears. Press the number key that corresponds to the desired option.

PXE Troubleshooting

If your PC does not boot from the netboot server, ensure that the BIOS is configured to boot first from the correct network interface. Some BIOS systems specify the network interface as a possible boot device, but do not support the PXE standard. Refer to your hardware documentation for more information.

Multiple NICs and PXE installation

Some servers with multiple network interfaces may not assign eth0 to the first network interface as BIOS knows it, which can cause the installer to try using a different network interface than was used by PXE. To change this behavior, use the following in pxelinux.cfg/* config files:
IPAPPEND 2
APPEND ksdevice=bootif
The configuration options above causes the installer to use the same network interface as BIOS and PXE use. You can also use the following option:
ksdevice=link
This option causes the installer to use the first network device it finds that is linked to a network switch.

6.5. Graphical and Text Interfaces

Fedora 11 supports graphical and text-based installations. However, the installer image must either fit in RAM or appear on local storage, such as the installation DVD or Live Media. Therefore, only systems with more than 192 MB of RAM or that boot from the installation DVD or Live Media can use the graphical installer. Systems with 192 MB RAM or less automatically scale back to using the text-based installer. Note that you must still have a minimum of 64 MB of RAM for installation to proceed in text mode. If you prefer to use the text-based installer, type linux text at the boot: prompt.
If one of the following situations occurs, the installation program uses a text mode:
  • The installation system fails to identify the display hardware on your computer
  • Your computer has less than 192 MB of RAM
  • You choose the text mode installation from the boot menu
The text screens provide most of the same functions as the standard screens, although disk partitioning is simplified, and bootloader configuration and package selection are handled automatically in text mode. If you choose to install Fedora in text mode, you can still configure your system to use a graphical interface after installation.

Graphical Interface Usage

Installing in text mode does not prevent you from using a graphical interface on your system once it is installed. If you have trouble configuring your system for graphical interface use, consult other sources for troubleshooting help as shown in Section 1.2, “Getting Additional Help”.

Installation requires at least 64 MB of RAM

If your system has less than 64 MB of RAM, installation will not continue.

Chapter 7. Installing on Intel® and AMD Systems

7.1. The Graphical Installation Program User Interface
7.1.1. A Note about Virtual Consoles
7.2. The Text Mode Installation Program User Interface
7.2.1. Using the Keyboard to Navigate
7.3. Starting the Installation Program
7.3.1. Booting the Installation Program on x86, AMD64, and Intel 64 Systems
7.3.2. Additional Boot Options
7.4. Selecting an Installation Method
7.5. Installing from DVD/CD-ROM
7.5.1. What If the IDE CD-ROM Was Not Found?
7.6. Installing from a Hard Drive
7.7. Performing a Network Installation
7.8. Installing via NFS
7.9. Installing via FTP or HTTP
7.10. Welcome to Fedora
7.11. Language Selection
7.12. Keyboard Configuration
7.13. Initializing the Hard Disk
7.14. Upgrading an Existing System
7.14.1. Upgrade Examine
7.14.2. Upgrading Using the Installer
7.14.3. Upgrading Boot Loader Configuration
7.15. Network Configuration
7.15.1. Manual configuration
7.16. Time Zone Configuration
7.17. Set the Root Password
7.18. Disk Partitioning Setup
7.18.1. RAID and Other Disk Devices
7.19. Advanced Storage Options
7.20. Create Default Layout
7.21. Partitioning Your System
7.21.1. Graphical Display of Hard Drive(s)
7.21.2. The partitioning screen
7.21.3. Partition Fields
7.21.4. Recommended Partitioning Scheme
7.21.5. Adding Partitions
7.21.6. Editing Partitions
7.21.7. Deleting a Partition
7.22. x86, AMD64, and Intel 64 Boot Loader Configuration
7.22.1. Advanced Boot Loader Configuration
7.22.2. Rescue Mode
7.22.3. Alternative Boot Loaders
7.23. Package Group Selection
7.23.1. Installing from Additional Repositories
7.23.2. Customizing the Software Selection
7.24. Preparing to Install
7.24.1. Prepare to Install
7.25. Installing Packages
7.26. Installation Complete
This chapter explains how to perform a Fedora installation from the DVD/CD-ROM, using the graphical, mouse-based installation program. The following topics are discussed:
  • Becoming familiar with the installation program's user interface
  • Starting the installation program
  • Selecting an installation method
  • Configuration steps during the installation (language, keyboard, mouse, partitioning, etc.)
  • Finishing the installation

7.1. The Graphical Installation Program User Interface

If you have used a graphical user interface (GUI) before, you are already familiar with this process; use your mouse to navigate the screens, click buttons, or enter text fields.
You can also navigate through the installation using the keyboard. The Tab key allows you to move around the screen, the Up and Down arrow keys to scroll through lists, + and - keys expand and collapse lists, while Space and Enter selects or removes from selection a highlighted item. You can also use the Alt+X key command combination as a way of clicking on buttons or making other screen selections, where X is replaced with any underlined letter appearing within that screen.

Note

If you are using an x86, AMD64, or Intel® 64 system, and you do not wish to use the GUI installation program, the text mode installation program is also available. To start the text mode installation program, press the Esc key while the Fedora boot menu is displayed, then use the following command at the boot: prompt:
linux text
Refer to Section 6.1, “The Boot Menu” for a description of the Fedora boot menu and to Section 7.2, “The Text Mode Installation Program User Interface” for a brief overview of text mode installation instructions.
It is highly recommended that installs be performed using the GUI installation program. The GUI installation program offers the full functionality of the Fedora installation program, including LVM configuration which is not available during a text mode installation.
Users who must use the text mode installation program can follow the GUI installation instructions and obtain all needed information.

7.1.1. A Note about Virtual Consoles

The Fedora installation program offers more than the dialog boxes of the installation process. Several kinds of diagnostic messages are available to you, as well as a way to enter commands from a shell prompt. The installation program displays these messages on five virtual consoles, among which you can switch using a single keystroke combination.
A virtual console is a shell prompt in a non-graphical environment, accessed from the physical machine, not remotely. Multiple virtual consoles can be accessed simultaneously.
Generally, there is no reason to leave the default console (virtual console #6) for graphical installations unless you are attempting to diagnose installation problems.
console keystrokes contents
1 ctrl+alt+f1 installation dialog
2 ctrl+alt+f2 shell prompt
3 ctrl+alt+f3 install log (messages from installation program)
4 ctrl+alt+f4 system-related messages
5 ctrl+alt+f5 other messages
6 ctrl+alt+f6 graphical display
Table 7.1. Console, Keystrokes, and Contents

7.2. The Text Mode Installation Program User Interface

The Fedora text mode installation program uses a screen-based interface that includes most of the on-screen widgets commonly found on graphical user interfaces. Figure 7.1, “Installation Program Widgets as seen in Boot Loader Configuration”, and Figure 7.2, “Installation Program Widgets as seen in the partitioning screen”, illustrate the screens that appear during the installation process.
The cursor is used to select (and interact with) a particular widget. As the cursor is moved from widget to widget, it may cause the widget to change color, or the cursor itself may only appear positioned in or next to the widget.

Note

While text mode installations are not explicitly documented, those using the text mode installation program can easily follow the GUI installation instructions. However, because text mode presents you with a simpler, more streamlined insatallation process, certain options that are available in graphical mode are not also available in text mode. These differences are noted in the description of the installation process in this guide, and include:
  • customizing the partition layout.
  • customizing the bootloader configuration.
  • selecting packages during installation.
Note also that manipulation of LVM (Logical Volume Management) disk volumes is only possible in graphical mode. In text mode it is only possible to view and accept the default LVM setup.

Note

Not every language supported in graphical installation mode is also supported in text mode. Specifically, languages written with a character set other than the Latin or Cyrillic alphabets are not available in text mode. If you choose a language written with a character set that is not supported in text mode, the installation program will present you with the English versions of the screens.
Installation Program Widgets as seen in Boot Loader Configuration
Installation Program Widgets as seen in Boot Loader Configuration
Figure 7.1. Installation Program Widgets as seen in Boot Loader Configuration

Legend
  1. Window — Windows (usually referred to as dialogs in this manual) appear on your screen throughout the installation process. At times, one window may overlay another; in these cases, you can only interact with the window on top. When you are finished in that window, it disappears, allowing you to continue working in the window underneath.
  2. Checkbox — Checkboxes allow you to select or deselect a feature. The box displays either an asterisk (selected) or a space (unselected). When the cursor is within a checkbox, press Space to select or deselect a feature.
  3. Text Input — Text input lines are regions where you can enter information required by the installation program. When the cursor rests on a text input line, you may enter and/or edit information on that line.
Installation Program Widgets as seen in the partitioning screen
Installation Program Widgets as seen in the partitioning screen
Figure 7.2. Installation Program Widgets as seen in the partitioning screen

Legend
  1. Text Widget — Text widgets are regions of the screen for the display of text. At times, text widgets may also contain other widgets, such as checkboxes. If a text widget contains more information than can be displayed in the space reserved for it, a scroll bar appears; if you position the cursor within the text widget, you can then use the Up and Down arrow keys to scroll through all the information available. Your current position is shown on the scroll bar by a # character, which moves up and down the scroll bar as you scroll.
  2. Scroll Bar — Scroll bars appear on the side or bottom of a window to control which part of a list or document is currently in the window's frame. The scroll bar makes it easy to move to any part of a file.
  3. Button Widget — Button widgets are the primary method of interacting with the installation program. You progress through the windows of the installation program by navigating these buttons, using the Tab and Enter keys. Buttons can be selected when they are highlighted.
To start, first make sure that you have all necessary resources for the installation. If you have already read through Chapter 3, Steps to Get You Started, and followed the instructions, you should be ready to start the installation process. When you have verified that you are ready to begin, boot the installation program using the Fedora DVD or CD-ROM #1 or any boot media that you have created.

7.3.1. Booting the Installation Program on x86, AMD64, and Intel® 64 Systems

You can boot the installation program using any one of the following media (depending upon what your system can support):
To create a boot CD-ROM or to prepare your USB pen drive for installation, refer to Section 3.4.2, “Making an Installation Boot CD-ROM”.
Insert the boot media and reboot the system. Your BIOS settings may need to be changed to allow you to boot from the CD-ROM or USB device.

Note

To change your BIOS settings on an x86, AMD64, or Intel® 64 system, watch the instructions provided on your display when your computer first boots. A line of text appears, telling you which key to press to enter the BIOS settings.
Once you have entered your BIOS setup program, find the section where you can alter your boot sequence. The default is often C, A or A, C (depending on whether you boot from your hard drive [C] or a diskette drive [A]). Change this sequence so that the CD-ROM is first in your boot order and that C or A (whichever is your typical boot default) is second. This instructs the computer to first look at the CD-ROM drive for bootable media; if it does not find bootable media on the CD-ROM drive, it then checks your hard drive or diskette drive.
Save your changes before exiting the BIOS. For more information, refer to the documentation that came with your system.
After a short delay, a screen containing the boot: prompt should appear. The screen contains information on a variety of boot options. Each boot option also has one or more help screens associated with it. To access a help screen, press the appropriate function key as listed in the line at the bottom of the screen.
As you boot the installation program, be aware of two issues:
  • Once the boot: prompt appears, the installation program automatically begins if you take no action within the first minute. To disable this feature, press one of the help screen function keys.
  • If you press a help screen function key, there is a slight delay while the help screen is read from the boot media.
Normally, you only need to press Enter to boot. Be sure to watch the boot messages to review if the Linux kernel detects your hardware. If your hardware is properly detected, continue to the next section. If it does not properly detect your hardware, you may need to restart the installation and use one of the boot options provided in Chapter 9, Boot Options.

7.3.2. Additional Boot Options

While it is easiest to boot using a CD-ROM or DVD and perform a graphical installation, sometimes there are installation scenarios where booting in a different manner may be needed. This section discusses additional boot options available for Fedora.
To pass options to the boot loader on an x86, AMD64, or Intel® 64 system, use the instructions as provided in the boot loader option samples below.

Note

Refer to Chapter 9, Boot Options for additional boot options not covered in this section.

7.4. Selecting an Installation Method

What type of installation method do you wish to use? The following installation methods are available:
If you booted the distribution DVD and did not use the alternate installation source option askmethod, the next stage loads automatically from the DVD. Proceed to Section 7.10, “Welcome to Fedora”.

CD/DVD Activity

If you boot any Fedora installation media, the installation program loads its next stage from that disc. This happens regardless of which installation method you choose, unless you eject the disc before you proceed. The installation program still downloads package data from the source you choose.

7.5. Installing from DVD/CD-ROM

To install Fedora from a DVD/CD-ROM, place the DVD or CD #1 in your DVD/CD-ROM drive and boot your system from the DVD/CD-ROM. Even if you booted from alternative media, you can still install Fedora from CD or DVD media.
The installation program then probes your system and attempts to identify your CD-ROM drive. It starts by looking for an IDE (also known as an ATAPI) CD-ROM drive.
If your CD-ROM drive is not detected, and it is a SCSI CD-ROM, the installation program prompts you to choose a SCSI driver. Choose the driver that most closely resembles your adapter. You may specify options for the driver if necessary; however, most drivers detect your SCSI adapter automatically.
The Select Partition screen applies only if you are installing from a disk partition (that is, if you selected Hard Drive in the Installation Method dialog). This dialog allows you to name the disk partition and directory from which you are installing Fedora.
The ISO files must be located on a hard drive that is either internal to the computer, or attached to the machine by USB. In addition the install.img file from within the ISO files must be copied to a directory named images Use this option to install Fedora on computers that are without a network connection or CD/DVD drives.
To extract the install.img from the ISO follow the procedure:
  mount -t iso9660 /path/to/Fedora11.iso /mnt/point -o loop,ro
  cp -pr /mnt/point/images /path/images/
  umount /mnt/point
Before you begin installation from a hard drive, check the partition type to ensure that Fedora can read it. To check a partition's file system under Windows, use the Disk Management tool. To check a partition's file system under Linux, use the fdisk utility.

Cannot Install from LVM Partitions

You cannot use ISO files on partitions controlled by LVM (Logical Volume Management).
Selecting Partition Dialog for Hard Drive Installation
Selecting partition dialog for a hard drive installation.
Figure 7.3. Selecting Partition Dialog for Hard Drive Installation

Select the partition containing the ISO files from the list of available partitions. Internal IDE, SATA, SCSI, and USB drive device names begin with /dev/sd. Each individual drive has its own letter, for example /dev/sda. Each partition on a drive is numbered, for example /dev/sda1.
Also specify the Directory holding images. Enter the full directory path from the drive that contains the ISO image files. The following table shows some examples of how to enter this information:
Partition type Volume Original path to files Directory to use
VFAT D:\ D:\Downloads\F11 /Downloads/F11
ext2, ext3, ext4 /home /home/user1/F11 /user1/F11
Table 7.2. Location of ISO images for different partition types

If the ISO images are in the root (top-level) directory of a partition, enter a /. If the ISO images are located in a subdirectory of a mounted partition, enter the name of the directory holding the ISO images within that partition. For example, if the partition on which the ISO images is normally mounted as /home/, and the images are in /home/new/, you would enter /new/.

Use a leading slash

An entry without a leading slash may cause the installation to fail.

7.7. Performing a Network Installation

The installation program is network-aware and can use network settings for a number of functions. For instance, you can install Fedora from a network server using FTP, HTTP, or NFS protocols. You can also instruct the installation program to consult additional software repositories later in the process.
If you are performing a network installation, the Configure TCP/IP dialog appears. This dialog asks for your IP and other network addresses. You can choose to configure the IP address and Netmask of the device via DHCP or manually.
By default, the installation program uses DHCP to automatically provide network settings. If you use a cable or DSL modem, router, firewall, or other network hardware to communicate with the Internet, DHCP is a suitable option. If your network has no DHCP server, clear the check box labeled Use dynamic IP configuration (DHCP).
Enter the IP address you are using during installation and press Enter.
TCP/IP Configuration
Configure the network device address(es) for installation.
Figure 7.4. TCP/IP Configuration

When the installation process completes, it will transfer these settings to your system.
You can install from a Web, FTP, or NFS server either on your local network or, if you are connected, on the Internet. You may install Fedora from your own private mirror, or use one of the public mirrors maintained by members of the community. To ensure that the connection is as fast and reliable as possible, use a server that is close to your own geographical location.
The Fedora Project maintains a list of Web and FTP public mirrors, sorted by region, at http://fedoraproject.org/wiki/Mirrors. To determine the complete directory path for the installation files, add /11/Fedora/architecture/os/ to the path shown on the web page. A correct mirror location for an i386 system resembles the URL http://mirror.example.com/pub/fedora/linux/releases/11/Fedora/i386/os.

7.8. Installing via NFS

The NFS dialog applies only if you are installing from an NFS server (if you selected NFS Image in the Installation Method dialog).
Enter the domain name or IP address of your NFS server. For example, if you are installing from a host named eastcoast in the domain example.com, enter eastcoast.example.com in the NFS Server field.
If the NFS server is exporting a mirror of the Fedora installation tree, enter the directory which contains the root of the installation tree. You will enter an Installation Key later on in the process which will determine which subdirectories are used to install from. If everything was specified properly, a message appears indicating that the installation program for Fedora is running.
NFS Setup Dialog
NFS setup dialog.
Figure 7.5. NFS Setup Dialog

If the NFS server is exporting the ISO images of the Fedora CD-ROMs, enter the directory which contains the ISO images.
Next, the Welcome dialog appears.
The language you select here will become the default language for the operating system once it is installed. Selecting the appropriate language also helps target your time zone configuration later in the installation. The installation program tries to define the appropriate time zone based on what you specify on this screen.
To add support for additional languages, customize the installation at the package selection stage. For more information, refer to Section 7.23.2.2, “Additional Language Support”.
Language Selection
Language selection screen.
Figure 7.7. Language Selection

Once you select the appropriate language, click Next to continue.
If you choose to upgrade your system using the installation program, any software not provided by Fedora that conflicts with Fedora software is overwritten. Before you begin an upgrade this way, make a list of your system's current packages for later reference:
rpm -qa --qf '%{NAME} %{VERSION}-%{RELEASE} %{ARCH}\n' > ~/old-pkglist.txt
After installation, consult this list to discover which packages you may need to rebuild or retrieve from non-Fedora software repositories.
Next, make a backup of any system configuration data:
su -c 'tar czf /tmp/etc-`date +%F`.tar.gz /etc' su -c 'mv /tmp/etc-*.tar.gz /home'
Make a complete backup of any important data before performing an upgrade. Important data may include the contents of your entire /home directory as well as content from services such as an Apache, FTP, or SQL server, or a source code management system. Although upgrades are not destructive, if you perform one improperly there is a small possibility of data loss.

Storing Backups

Note that the above examples store backup materials in a /home directory. If your /home directory is not a separate partition, you should not follow these examples verbatim! Store your backups on another device such as CD or DVD discs or an external hard disk.
For more information on completing the upgrade process later, refer to Section 16.2, “Finishing an Upgrade”.

7.14.3. Upgrading Boot Loader Configuration

If the existing boot loader was installed by a Linux distribution, the installation system can modify it to load the new Fedora system. To update the existing Linux boot loader, select Update boot loader configuration. This is the default behavior when you upgrade an existing Fedora or Red Hat Linux installation.
GRUB is the standard boot loader for Fedora. If your machine uses another boot loader, such as BootMagic™, System Commander™, or the loader installed by Microsoft Windows, then the Fedora installation system cannot update it. In this case, select Skip boot loader updating. When the installation process completes, refer to the documentation for your product for assistance.
Install a new boot loader as part of an upgrade process only if you are certain you want to replace the existing boot loader. If you install a new boot loader, you may not be able to boot other operating systems on the same machine until you have configured the new boot loader. Select Create new boot loader configuration to remove the existing boot loader and install GRUB.
After you make your selection, click Next to continue.

7.15. Network Configuration

Fedora contains support for both IPv4 and IPv6. However, by default, the installation program configures network interfaces on your computer for IPv4, and to use DHCP via NetworkManager. Currently NetworkManager does not support IPv6. If your network only supports IPv6 you should use system-config-network after installation to configure your network interfaces.
Setup prompts you to supply a host name and domain name for this computer, in the format hostname.domainname. Many networks have a DHCP (Dynamic Host Configuration Protocol) service that automatically supplies connected systems with a domain name, leaving the user to enter a hostname.
Setting the hostname
Setting the hostname
Figure 7.11. Setting the hostname

To set up a network that is behind an Internet firewall or router, you may want to use hostname.localdomain for your Fedora system. If you have more than one computer on this network, you should give each one a separate host name in this domain.

Valid Hostnames

You may give your system any name provided that the full hostname is unique. The hostname may include letters, numbers and hyphens.
Specify a time zone even if you plan to use NTP (Network Time Protocol) to maintain the accuracy of the system clock.
Set your time zone by selecting the city closest to your computer's physical location. Click on the map to zoom in to a particular geographical region of the world.
Specify a time zone even if you plan to use NTP (Network Time Protocol) to maintain the accuracy of the system clock.
From here there are two ways for you to select your time zone:
  • Using your mouse, click on the interactive map to select a specific city (represented by a yellow dot). A red X appears indicating your selection.
  • You can also scroll through the list at the bottom of the screen to select your time zone. Using your mouse, click on a location to highlight your selection.
Configuring the Time Zone
Time zone configuration screen.
Figure 7.13. Configuring the Time Zone

If Fedora is the only operating system on your computer, select System clock uses UTC. The system clock is a piece of hardware on your computer system. Fedora uses the timezone setting to determine the offset between the local time and UTC on the system clock. This behavior is standard for UNIX-like operating systems.

Windows and the System Clock

Do not enable the System clock uses UTC option if your machine also runs Microsoft Windows. Microsoft operating systems change the BIOS clock to match local time rather than UTC. This may cause unexpected behavior under Fedora.

Note

To change your time zone configuration after you have completed the installation, use the Time and Date Properties Tool.
Type the system-config-date command in a shell prompt to launch the Time and Date Properties Tool. If you are not root, it prompts you for the root password to continue.
To run the Time and Date Properties Tool as a text-based application, use the command timeconfig.
Select Next to proceed.
Setting up a root account and password is one of the most important steps during your installation. Your root account is similar to the administrator account used on Microsoft Windows machines. The root account is used to install packages, upgrade RPMs, and perform most system maintenance. Logging in as root gives you complete control over your system.

Note

The root user (also known as the superuser) has complete access to the entire system; for this reason, logging in as the root user is best done only to perform system maintenance or administration.
Root Password
Setting your root password.
Figure 7.14. Root Password

Use the root account only for system administration. Create a non-root account for your general use and su - to root when you need to fix something quickly. These basic rules minimize the chances of a typo or an incorrect command doing damage to your system.

Note

To become root, type su - at the shell prompt in a terminal window and then press Enter. Then, enter the root password and press Enter.
The installation program prompts you to set a root password[2] for your system. You cannot proceed to the next stage of the installation process without entering a root password.
The root password must be at least six characters long; the password you type is not echoed to the screen. You must enter the password twice; if the two passwords do not match, the installation program asks you to enter them again.
You should make the root password something you can remember, but not something that is easy for someone else to guess. Your name, your phone number, qwerty, password, root, 123456, and anteater are all examples of bad passwords. Good passwords mix numerals with upper and lower case letters and do not contain dictionary words: Aard387vark or 420BMttNT, for example. Remember that the password is case-sensitive. If you write down your password, keep it in a secure place. However, it is recommended that you do not write down this or any password you create.

Note

Do not use one of the example passwords offered in this manual. Using one of these passwords could be considered a security risk.

Note

To change your root password after you have completed the installation, use the Root Password Tool.
Type the system-config-rootpassword command in a shell prompt to launch the Root Password Tool. If you are not root, it prompts you for the root password to continue.
Enter the root password into the Root Password field. Fedora displays the characters as asterisks for security. Type the same password into the Confirm field to ensure it is set correctly. After you set the root password, select Next to proceed.

7.18. Disk Partitioning Setup

On this screen you can choose to create the default layout or choose to manual partition using the Create custom layout option.
The first three options allow you to perform an automated installation without having to partition your drive(s) yourself. If you do not feel comfortable with partitioning your system, it is recommended that you do not choose to create a custom layout and instead let the installation program partition for you.
You can configure an iSCSI target for installation, or disable a dmraid device from this screen by clicking on the 'Advanced storage configuration' button. For more information refer to Section 7.19, “ Advanced Storage Options ”.

Warning

The PackageKit update software downloads updated packages to /var/cache/yum/ by default. If you partition the system manually, and create a separate /var/ partition, be sure to create the partition large enough (3.0 GB or more) to download package updates.
Disk Partitioning Setup
Choose automatic partitioning or manual partitioning.
Figure 7.15. Disk Partitioning Setup

If you choose to create a custom layout, refer to Section 7.21, “Partitioning Your System”.

Warning

If you receive an error after the Disk Partitioning Setup phase of the installation saying something similar to:
"The partition table on device hda was unreadable. To create new partitions it must be initialized, causing the loss of ALL DATA on this drive."
you may not have a partition table on that drive or the partition table on the drive may not be recognizable by the partitioning software used in the installation program.
Users who have used programs such as EZ-BIOS have experienced similar problems, causing data to be lost (assuming the data was not backed up before the installation began).
No matter what type of installation you are performing, backups of the existing data on your systems should always be made.

7.19.  Advanced Storage Options

Advanced Storage Options
Advanced Storage Options.
Figure 7.16. Advanced Storage Options

To configure an ISCSI target invoke the 'Configure ISCSI Parameters' dialog by selecting 'Add ISCSI target' and clicking on the 'Add Drive' button. Fill in the details for the ISCSI target IP and provide a unique ISCSI initiator name to identify this system. If the ISCSI target uses CHAP (Challenge Handshake Authentication Protocol) for authentication, enter the CHAP username and password. If your enviroment uses 2-way CHAP (also called "Mutual CHAP"), also enter the reverse CHAP username and password. Click the 'Add target' button to attempt connection to the ISCSI target using this information.
Configure ISCSI Parameters
Configure ISCSI Parameters.
Figure 7.17. Configure ISCSI Parameters

Please note that you will be able to reattempt with a different ISCSI target IP should you enter it incorrectly, but in order to change the ISCSI initiator name you will need to restart the installation.

7.20. Create Default Layout

Create default layout allows you to have some control concerning what data is removed (if any) from your system. Your options are:
  • Remove all partitions on selected drives and create default layout — select this option to remove all partitions on your hard drive(s) (this includes partitions created by other operating systems such as Windows VFAT or NTFS partitions).

    Warning

    If you select this option, all data on the selected hard drive(s) is removed by the installation program. Do not select this option if you have information that you want to keep on the hard drive(s) where you are installing Fedora.
  • Remove Linux partitions on selected drives and create default layout — select this option to remove only Linux partitions (partitions created from a previous Linux installation). This does not remove other partitions you may have on your hard drive(s) (such as VFAT or FAT32 partitions).
  • Use free space on selected drives and create default layout — select this option to retain your current data and partitions, assuming you have enough free space available on your hard drive(s).
Create Default Layout
Automatic partitioning.
Figure 7.18. Create Default Layout

Using your mouse, choose the storage drive(s) on which you want Fedora to be installed. If you have two or more drives, you can choose which drive(s) should contain this installation. Unselected drives, and any data on them, are not touched.

Warning

It is always a good idea to back up any data that you have on your systems. For example, if you are upgrading or creating a dual-boot system, you should back up any data you wish to keep on your drive(s). Mistakes do happen and can result in the loss of all your data.

Note

If you have a RAID card, be aware that some BIOSes do not support booting from the RAID card. In cases such as these, the /boot/ partition must be created on a partition outside of the RAID array, such as on a separate hard drive. An internal hard drive is necessary to use for partition creation with problematic RAID cards.
A /boot/ partition is also necessary for software RAID setups.
If you have chosen to automatically partition your system, you should select Review and manually edit your /boot/ partition.
Select Encrypt system to encrypt all partitions except the /boot partition.
Use the Advanced storage options option if:
  • You want to install Fedora to a drive connected through the iSCSI protocol. Select Advanced storage options, then select Add iSCSI target, then select Add drive. Provide an IP address and the iSCSI initiator name, and select Add drive.
  • You want to disable a dmraid device that was detected at boot time.
To review and make any necessary changes to the partitions created by automatic partitioning, select the Review option. After selecting Review and clicking Next to move forward, the partitions created for you by anaconda appear. You can make modifications to these partitions if they do not meet your needs.

Installing in text mode

If you install Fedora in text mode, you can only use the default partitioning schemes described in this section. Therefore, although you can choose to use a whole drive, to remove existing Linux partitions, or to use the free space on the drive, you cannot customize the partition layout. That is, you cannot add or remove partitions or file systems beyond those that the installer automatically adds or removes. If you require a customized layout at installation time, you should perform a graphical installation over a VNC connection or a kickstart installation.
Furthermore, advanced options such as LVM, encrypted filesystems, and resizable filesystems are available only in graphical mode and kickstart.
Click Next once you have made your selections to proceed.
If you chose one of the automatic partitioning options and selected Review, you can either accept the current partition settings (click Next), or modify the setup manually in the partitioning screen.

Note

Please note that in the text mode installation it is not possible to work with LVM (Logical Volumes) beyond viewing the existing setup. LVM can only be set up during graphical installation.
If you chose to create a custom layout, you must tell the installation program where to install Fedora. This is done by defining mount points for one or more disk partitions in which Fedora is installed. You may also need to create and/or delete partitions at this time.

Note

If you have not yet planned how to set up your partitions, refer to Appendix A, An Introduction to Disk Partitions and Section 7.21.4, “Recommended Partitioning Scheme”. At a bare minimum, you need an appropriately-sized root partition, and a swap partition equal to twice the amount of RAM you have on the system. Itanium system users should have a /boot/efi/ partition of approximately 100 MB and of type FAT (VFAT), a swap partition of at least 512 MB, and an appropriately-sized root (/) partition.
Partitioning on x86, AMD64, and Intel 64 Systems
The main partitioning screen.
Figure 7.19. Partitioning on x86, AMD64, and Intel® 64 Systems

With the exception of certain esoteric situations, anaconda can handle the partitioning requirements for a typical installation.

7.21.1. Graphical Display of Hard Drive(s)

The partitioning screen offers a graphical representation of your hard drive(s).
Using your mouse, click once to highlight a particular field in the graphical display. Double-click to edit an existing partition or to create a partition out of existing free space.
Above the display, you can review the Drive name (such as /dev/hda), the Geom (which shows the hard disk's geometry and consists of three numbers representing the number of cylinders, heads, and sectors as reported by the hard disk), and the Model of the hard drive as detected by the installation program.

7.21.2. The partitioning screen

These buttons are used to change the attributes of a partition (for example the file system type and mount point) and also to create RAID devices. Buttons on this screen are also used to accept the changes you have made, or to exit the partitioning screen. For further explanation, take a look at each button in order:

7.21.3. Partition Fields

Above the partition hierarchy are labels which present information about the partitions you are creating. The labels are defined as follows:
  • Device: This field displays the partition's device name.
  • Mount Point/RAID/Volume: A mount point is the location within the directory hierarchy at which a volume exists; the volume is "mounted" at this location. This field indicates where the partition is mounted. If a partition exists, but is not set, then you need to define its mount point. Double-click on the partition or click the Edit button.
  • Type: This field shows the partition's file system type (for example, ext2, ext3, ext4, or vfat).
  • Format: This field shows if the partition being created will be formatted.
  • Size (MB): This field shows the partition's size (in MB).
  • Start: This field shows the cylinder on your hard drive where the partition begins.
  • End: This field shows the cylinder on your hard drive where the partition ends.
Hide RAID device/LVM Volume Group members: Select this option if you do not want to view any RAID device or LVM Volume Group members that have been created.

7.21.4. Recommended Partitioning Scheme

7.21.4.1. x86, AMD64, and Intel® 64 systems

Unless you have a reason for doing otherwise, we recommend that you create the following partitions for x86, AMD64, and Intel® 64 systems:
  • A swap partition
  • A /boot partition
  • A / partition
  • A swap partition (at least 256 MB)
    Swap partitions are used to support virtual memory. In other words, data is written to a swap partition when there is not enough RAM to store the data your system is processing. In addition, certain power management features store all of the memory for a suspended system in the available swap partitions.
    If you are unsure about what size swap partition to create, make it twice the amount of RAM on your machine. It must be of type swap.
    Creation of the proper amount of swap space varies depending on a number of factors including the following (in descending order of importance):
    • The applications running on the machine.
    • The amount of physical RAM installed on the machine.
    • The version of the OS.
    Swap should equal 2x physical RAM for up to 2 GB of physical RAM, and then an additional 1x physical RAM for any amount above 2 GB, but never less than 32 MB.
    So, if:
    M = Amount of RAM in GB, and S = Amount of swap in GB, then
    If M < 2
    	S = M *2
    Else
    	S = M + 2
    
    Using this formula, a system with 2 GB of physical RAM would have 4 GB of swap, while one with 3 GB of physical RAM would have 5 GB of swap. Creating a large swap space partition can be especially helpful if you plan to upgrade your RAM at a later time.
    For systems with really large amounts of RAM (more than 32 GB) you can likely get away with a smaller swap partition (around 1x, or less, of physical RAM).
  • A /boot/ partition (100 MB)
    The partition mounted on /boot/ contains the operating system kernel (which allows your system to boot Fedora), along with files used during the bootstrap process. Due to limitations, creating a native ext3 partition to hold these files is required. For most users, a 100 MB boot partition is sufficient.

    ext4 and Btrfs

    The GRUB bootloader does not support the ext4 or Btrfs file systems. You cannot use an ext4 or Btrfs partition for /boot/.

    Note

    If your hard drive is more than 1024 cylinders (and your system was manufactured more than two years ago), you may need to create a /boot/ partition if you want the / (root) partition to use all of the remaining space on your hard drive.

    Note

    If you have a RAID card, be aware that some BIOSes do not support booting from the RAID card. In cases such as these, the /boot/ partition must be created on a partition outside of the RAID array, such as on a separate hard drive.
  • A root partition (3.0 GB - 5.0 GB)
    This is where "/" (the root directory) is located. In this setup, all files (except those stored in /boot) are on the root partition.
    A 3.0 GB partition allows you to install a minimal installation, while a 5.0 GB root partition lets you perform a full installation, choosing all package groups.

    Root and /root

    The / (or root) partition is the top of the directory structure. The /root directory/root (sometimes pronounced "slash-root") directory is the home directory of the user account for system administration.
If you create many partitions instead of one large / partition, upgrades become easier. Refer to the description the Edit option in Section 7.21.2, “The partitioning screen” for more information.
The following table summarizes minimum partition sizes for the partitions containing the listed directories. You do not have to make a separate partition for each of these directories. For instance, if the partition containing /foo must be at least 500 MB, and you do not make a separate /foo partition, then the / (root) partition must be at least 500 MB.
Directory Minimum size
/ 250 MB
/usr 250 MB, but avoid placing this on a separate partition
/tmp 50 MB
/var 384 MB
/home 100 MB
/boot 75 MB
Table 7.3. Minimum partition sizes

Leave Excess Capacity Unallocated

Only assign storage capacity to those partitions you require immediately. You may allocate free space at any time, to meet needs as they occur. To learn about a more flexible method for storage management, refer to Appendix D, Understanding LVM.
If you are not sure how best to configure the partitions for your computer, accept the default partition layout.
7.21.4.1.1. Advice on Partitions
Optimal partition setup depends on the usage for the Linux system in question. The following tips may help you decide how to allocate your disk space.
  • If you expect that you or other users will store data on the system, create a separate partition for the /home directory within a volume group. With a separate /home partition, you may upgrade or reinstall Fedora without erasing user data files.
  • Each kernel installed on your system requires approximately 10 MB on the /boot partition. Unless you plan to install a great many kernels, the default partition size of 100 MB for /boot should suffice.

    ext4 and Btrfs

    The GRUB bootloader does not support the ext4 or Btrfs file systems. You cannot use an ext4 or btrfs partition for /boot.
  • The /var directory holds content for a number of applications, including the Apache web server. It also is used to store downloaded update packages on a temporary basis. Ensure that the partition containing the /var directory has enough space to download pending updates and hold your other content.

    Pending Updates

    Because Fedora is a rapidly progressing collection of software, many updates may be available late in a release cycle. You can add an update repository to the sources for installation later to minimize this issue. Refer to Section 7.23.1, “Installing from Additional Repositories” for more information.
  • The /usr directory holds the majority of software content on a Fedora system. For an installation of the default set of software, allocate at least 4 GB of space. If you are a software developer or plan to use your Fedora system to learn software development skills, you may want to at least double this allocation.

    Do not place /usr on a separate partition

    If /usr is on a separate partition from /, the boot process becomes much more complex, and in some situations (like installations on iSCSI drives), might not work at all.
  • Consider leaving a portion of the space in an LVM volume group unallocated. This unallocated space gives you flexibility if your space requirements change but you do not wish to remove data from other partitions to reallocate storage.
  • If you separate subdirectories into partitions, you can retain content in those subdirectories if you decide to install a new version of Fedora over your current system. For instance, if you intend to run a MySQL database in /var/lib/mysql, make a separate partition for that directory in case you need to reinstall later.
The following table is a possible partition setup for a system with a single, new 80 GB hard disk and 1 GB of RAM. Note that approximately 10 GB of the volume group is unallocated to allow for future growth.

Example Usage

This setup is not optimal for all use cases.
Partition Size and type
/boot 100 MB ext3 partition
swap 2 GB swap
LVM physical volume Remaining space, as one LVM volume group
Table 7.4. Example partition setup

The physical volume is assigned to the default volume group and divided into the following logical volumes:
Partition Size and type
/ 13 GB ext4
/var 4 GB ext4
/home 50 GB ext4
Table 7.5. Example partition setup: LVM physical volume

Example 7.1. Example partition setup

7.21.5. Adding Partitions

Note

You must dedicate at least one partition for this installation, and optionally more. For more information, refer to Appendix A, An Introduction to Disk Partitions.
Creating a New Partition
Creating a new partition.
Figure 7.24. Creating a New Partition

  • Mount Point: Enter the partition's mount point. For example, if this partition should be the root partition, enter /; enter /boot for the /boot partition, and so on. You can also use the pull-down menu to choose the correct mount point for your partition. For a swap partition the mount point should not be set - setting the filesystem type to swap is sufficient.
  • File System Type: Using the pull-down menu, select the appropriate file system type for this partition. For more information on file system types, refer to Section 7.21.5.1, “File System Types”.
  • Allowable Drives: This field contains a list of the hard disks installed on your system. If a hard disk's box is highlighted, then a desired partition can be created on that hard disk. If the box is not checked, then the partition will never be created on that hard disk. By using different checkbox settings, you can have anaconda place partitions where you need them, or let anaconda decide where partitions should go.
  • Size (MB): Enter the size (in megabytes) of the partition. Note, this field starts with 100 MB; unless changed, only a 100 MB partition will be created.
  • Additional Size Options: Choose whether to keep this partition at a fixed size, to allow it to "grow" (fill up the available hard drive space) to a certain point, or to allow it to grow to fill any remaining hard drive space available.
    If you choose Fill all space up to (MB), you must give size constraints in the field to the right of this option. This allows you to keep a certain amount of space free on your hard drive for future use.
  • Force to be a primary partition: Select whether the partition you are creating should be one of the first four partitions on the hard drive. If unselected, the partition is created as a logical partition. Refer to Section A.1.3, “Partitions within Partitions — An Overview of Extended Partitions”, for more information.
  • OK: Select OK once you are satisfied with the settings and wish to create the partition.
  • Cancel: Select Cancel if you do not want to create the partition.

7.21.5.1. File System Types

Fedora allows you to create different partition types, based on the file system they will use. The following is a brief description of the different file systems available, and how they can be utilized.

7.22. x86, AMD64, and Intel® 64 Boot Loader Configuration

To boot the system without boot media, you usually need to install a boot loader. A boot loader is the first software program that runs when a computer starts. It is responsible for loading and transferring control to the operating system kernel software. The kernel, in turn, initializes the rest of the operating system.

Installing in text mode

If you install Fedora in text mode, the installer configures the bootloader automatically and you cannot customize bootloader settings during the installation process.
GRUB (GRand Unified Bootloader), which is installed by default, is a very powerful boot loader. GRUB can load a variety of free operating systems, as well as proprietary operating systems with chain-loading (the mechanism for loading unsupported operating systems, such as DOS or Windows, by loading another boot loader).

The GRUB boot menu

The GRUB menu defaults to being hidden, except on dual-boot systems. To show the GRUB menu during system boot, press and hold the Shift key before the kernel is loaded. (Any other key works as well but the Shift key is the safest to use.)
Boot Loader Configuration
Configure how you would like to boot the system.
Figure 7.25. Boot Loader Configuration

You may have a boot loader installed on your system already. An operating system may install its own preferred boot loader, or you may have installed a third-party boot loader.If your boot loader does not recognize Linux partitions, you may not be able to boot Fedora. Use GRUB as your boot loader to boot Linux and most other operating systems. Follow the directions in this chapter to install GRUB.

Installing GRUB

If you install GRUB, it may overwrite your existing boot loader.
By default, the installation program installs GRUB in the master boot record or MBR, of the device for the root file system. To decline installation of a new boot loader, unselect Install boot loader on /dev/sda.

Warning

If you choose not to install GRUB for any reason, you will not be able to boot the system directly, and you must use another boot method (such as a commercial boot loader application). Use this option only if you are sure you have another way of booting the system!
If you have other operating systems already installed, Fedora attempts to automatically detect and configure GRUB to boot them. You may manually configure any additional operating systems if GRUB does not detect them.
To add, remove, or change the detected operating system settings, use the options provided.
Add
Select Add to include an additional operating system in GRUB.
Select the disk partition which contains the bootable operating system from the drop-down list and give the entry a label. GRUB displays this label in its boot menu.
Edit
To change an entry in the GRUB boot menu, select the entry and then select Edit.
Delete
To remove an entry from the GRUB boot menu, select the entry and then select Delete.
Select Default beside the preferred boot partition to choose your default bootable OS. You cannot move forward in the installation unless you choose a default boot image.

Note

The Label column lists what you must enter at the boot prompt, in non-graphical boot loaders, in order to boot the desired operating system.
Once you have loaded the GRUB boot screen, use the arrow keys to choose a boot label or type e for edit. You are presented with a list of items in the configuration file for the boot label you have selected.
Boot loader passwords provide a security mechanism in an environment where physical access to your server is available.
If you are installing a boot loader, you should create a password to protect your system. Without a boot loader password, users with access to your system can pass options to the kernel which can compromise your system security. With a boot loader password in place, the password must first be entered before selecting any non-standard boot options. However, it is still possible for someone with physical access to the machine to boot from a diskette, CD-ROM, or USB media if the BIOS supports it. Security plans which include boot loader passwords should also address alternate boot methods.

GRUB Passwords Not Required

You may not require a GRUB password if your system only has trusted operators, or is physically secured with controlled console access. However, if an untrusted person can get physical access to your computer's keyboard and monitor, that person can reboot the system and access GRUB. A password is helpful in this case.
If you choose to use a boot loader password to enhance your system security, be sure to select the checkbox labeled Use a boot loader password.
Once selected, enter a password and confirm it.
GRUB stores the password in encrypted form, so it cannot be read or recovered. If you forget the boot password, boot the system normally and then change the password entry in the /boot/grub/grub.conf file. If you cannot boot, you may be able to use the "rescue" mode on the first Fedora installation disc to reset the GRUB password.
If you do need to change the GRUB password, use the grub-md5-crypt utility. For information on using this utility, use the command man grub-md5-crypt in a terminal window to read the manual pages.
To configure more advanced boot loader options, such as changing the drive order or passing options to the kernel, be sure Configure advanced boot loader options is selected before clicking Next.

7.22.1. Advanced Boot Loader Configuration

Now that you have chosen which boot loader to install, you can also determine where you want the boot loader to be installed. You may install the boot loader in one of two places:

Note

If you have a RAID card, be aware that some BIOSes do not support booting from the RAID card. In cases such as these, the boot loader should not be installed on the MBR of the RAID array. Rather, the boot loader should be installed on the MBR of the same drive as the /boot/ partition was created.
If your system only uses Fedora, you should choose the MBR.
Click the Change Drive Order button if you would like to rearrange the drive order or if your BIOS does not return the correct drive order. Changing the drive order may be useful if you have multiple SCSI adapters, or both SCSI and IDE adapters, and you want to boot from the SCSI device.
Now that you have made most of the choices for your installation, you are ready to confirm the default package selection or customize packages for your system.
The Package Installation Defaults screen appears and details the default package set for your Fedora installation. This screen varies depending on the version of Fedora you are installing.

Installing from a Live Image

If you install from a Fedora Live image, you cannot make package selections. This installation method transfers a copy of the Live image rather than installing packages from a repository. To change the package selection, complete the installation, then use the Add/Remove Software application to make desired changes.

Installing in text mode

If you install Fedora in text mode, you cannot make package selections. The installer automatically selects packages only from the base and core groups. These packages are sufficient to ensure that the system is operational at the end of the installation process, ready to install updates and new packages. To change the package selection, complete the installation, then use the Add/Remove Software application to make desired changes.
Package Group Selection
Choose which package groups you want to install.
Figure 7.27. Package Group Selection

By default, the Fedora installation process loads a selection of software that is suitable for a desktop system. To include or remove software for common tasks, select the relevant items from the list:
Office and Productivity
This option provides the OpenOffice.org productivity suite, the Planner project management application, graphical tools such as the GIMP, and multimedia applications.
Software Development
This option provides the necessary tools to compile software on your Fedora system.
Web server
This option provides the Apache Web server.
To select a component, click on the checkbox beside it (refer to Figure 7.27, “Package Group Selection”).
To customize your package set further, select the Customize now option on the screen. Clicking Next takes you to the Package Group Selection screen.

7.23.1. Installing from Additional Repositories

You can define additional repositories to increase the software available to your system during installation. A repository is a network location that stores software packages along with metadata that describes them. Many of the software packages used in Fedora require other software to be installed. The installer uses the metadata to ensure that these requirements are met for every piece of software you select for installation.
The basic options are:
  • The Installation Repo repository is automatically selected for you. This represents the collection of software available on your installation CD or DVD.
  • The Fedora 11 - i386 repository contains the complete collection of software that was released as Fedora 11, with the various pieces of software in their versions that were current at the time of release. If you are installing from the Fedora 11 DVD or set of CDs, this option does not offer you anything extra. However, if you are installing from a Fedora Live CD, this option provides access to far more software than is included on the disk. Note that the computer must have access to the internet to use this option.
  • The Fedora 11 - i386 - Updates repository contains the complete collection of software that was released as Fedora 11, with the various pieces of software in their most current stable versions. This option not only installs the software that you select, but makes sure that it is fully updated as well. Note that the computer must have access to the internet to use this option.
Adding a software repository
Enter the details of additional software repositories.
Figure 7.28. Adding a software repository

To include software from repositories other than the Fedora package collection, select Add additional software repositories. You may provide the location of a repository of third-party software. Depending on the configuration of that repository, you may be able to select non-Fedora software during installation.
To edit an existing software repository location, select the repository in the list and then select Modify repository.

Network Access Required

If you change the repository information during a non-network installation, such as from a Fedora DVD, the installer prompts you for network configuration information.
If you select Add additional software repositories, the Edit repository dialog appears. Provide a Repository name and the Repository URL for its location.

Fedora Software Mirrors

To find a Fedora software mirror near you, refer to http://fedoraproject.org/wiki/Mirrors.
Once you have located a mirror, to determine the URL to use, find the directory on the mirror that contains a directory named repodata. For instance, the "Everything" repository for Fedora is typically located in a directory tree releases/11/Everything/arch/os, where arch is a system architecture name.
Once you provide information for an additional repository, the installer reads the package metadata over the network. Software that is specially marked is then included in the package group selection system. See Section 7.23.2, “Customizing the Software Selection” for more information on selecting packages.

Backtracking Removes Repository Metadata

If you choose Back from the package selection screen, any extra repository data you may have entered is lost. This allows you to effectively cancel extra repositories. Currently there is no way to cancel only a single repository once entered.

7.23.2. Customizing the Software Selection

Select Customize now to specify the software packages for your final system in more detail. This option causes the installation process to display an additional customization screen when you select Next.

Installing Support for Additional Languages

Select Customize now to install support for additional languages. Refer to Section 7.23.2.2, “Additional Language Support” for more information on configuring language support.
Package Group Details
Choose to add or remove optional packages from this package group.
Figure 7.29. Package Group Details



[2] A root password is the administrative password for your Fedora system. You should only log in as root when needed for system maintenance. The root account does not operate within the restrictions placed on normal user accounts, so changes made as root can have implications for your entire system.

[3] The fsck application is used to check the file system for metadata consistency and optionally repair one or more Linux file systems.

Chapter 8. Troubleshooting Installation on an Intel® or AMD System

This appendix discusses some common installation problems and their solutions.

8.1. You are unable to boot Fedora

A signal 11 error, commonly know as a segmentation fault, means that the program accessed a memory location that was not assigned to it. A signal 11 error may be due to a bug in one of the software programs that is installed, or faulty hardware.
If you receive a fatal signal 11 error during your installation, it is probably due to a hardware error in memory on your system's bus. Like other operating systems, Fedora places its own demands on your system's hardware. Some of this hardware may not be able to meet those demands, even if they work properly under another OS.
Ensure that you have the latest installation updates and images. Review the online errata to see if newer versions are available. If the latest images still fail, it may be due to a problem with your hardware. Commonly, these errors are in your memory or CPU-cache. A possible solution for this error is turning off the CPU-cache in the BIOS, if your system supports this. You could also try to swap your memory around in the motherboard slots to check if the problem is either slot or memory related.
Another option is to perform a media check on your installation CD-ROMs. Anaconda, the installation program, has the ability to test the integrity of the installation media. It works with the CD, DVD, hard drive ISO, and NFS ISO installation methods. Red Hat recommends that you test all installation media before starting the installation process, and before reporting any installation-related bugs (many of the bugs reported are actually due to improperly-burned CDs). To use this test, type the following command at the boot: prompt:
	linux mediacheck
For more information concerning signal 11 errors, refer to:
	http://www.bitwizard.nl/sig11/

8.3. Trouble During the Installation

The partition table on device hda was unreadable. To create new partitions it must be initialized, causing the loss of ALL DATA on this drive.
you may not have a partition table on that drive or the partition table on the drive may not be recognizable by the partitioning software used in the installation program.
Users who have used programs such as EZ-BIOS have experienced similar problems, causing data to be lost (assuming the data was not backed up before the installation began) that could not be recovered.
No matter what type of installation you are performing, backups of the existing data on your systems should always be made.
During some upgrades or installations of Fedora, the installation program (also known as anaconda) may fail with a Python or traceback error. This error may occur after the selection of individual packages or while trying to save the upgrade log in the /tmp/directory. The error may look similar to:
Traceback (innermost last):
File "/var/tmp/anaconda-7.1//usr/lib/anaconda/iw/progress_gui.py", line 20, in run
rc = self.todo.doInstall ()    
File "/var/tmp/anaconda-7.1//usr/lib/anaconda/todo.py", line 1468, in doInstall 
self.fstab.savePartitions ()    
File "fstab.py", line 221, in savePartitions      
sys.exit(0)  
SystemExit: 0   
Local variables in innermost frame:  
self: <fstab.GuiFstab instance at 8446fe0>  
sys: <module 'sys' (built-in)>  
ToDo object:  (itodo  ToDo  p1  (dp2  S'method'  p3  (iimage  CdromInstallMethod  
p4  (dp5  S'progressWindow'  p6   <failed>
This error occurs in some systems where links to /tmp/ are symbolic to other locations or have been changed since creation. These symbolic or changed links are invalid during the installation process, so the installation program cannot write information and fails.
If you experience such an error, first try to download any available updates for anaconda. Updates for anaconda and instructions for using them can be found at:
http://fedoraproject.org/wiki/Anaconda/Updates
The anaconda website may also be a useful reference and can be found online at:
http://fedoraproject.org/wiki/Anaconda
You can also search for bug reports related to this problem. To search Red Hat's bug tracking system, go to:
http://bugzilla.redhat.com/bugzilla/

8.4. Problems After Installation

If you have installed the X Window System but are not seeing a graphical desktop environment once you log into your system, you can start the X Window System graphical interface using the command startx.
Once you enter this command and press Enter, the graphical desktop environment is displayed.
Note, however, that this is just a one-time fix and does not change the log in process for future log ins.
To set up your system so that you can log in at a graphical login screen, you must edit one file, /etc/inittab, by changing just one number in the runlevel section. When you are finished, reboot the computer. The next time you log in, you are presented with a graphical login prompt.
Open a shell prompt. If you are in your user account, become root by typing the su command.
Now, type gedit /etc/inittab to edit the file with gedit. The file /etc/inittab opens. Within the first screen, a section of the file which looks like the following appears:
# Default runlevel. The runlevels used are: 
#   0 - halt (Do NOT set initdefault to this) 
#   1 - Single user mode 
#   2 - Multiuser, without NFS (The same as 3, if you do not have networking) 
#   3 - Full multiuser mode 
#   4 - unused 
#   5 - X11 
#   6 - reboot (Do NOT set initdefault to this) 
#  id:3:initdefault:
To change from a console to a graphical login, you should change the number in the line id:3:initdefault: from a 3 to a 5.

Warning

Change only the number of the default runlevel from 3 to 5.
Your changed line should look like the following:
	 id:5:initdefault: 
When you are satisfied with your change, save and exit the file using the Ctrl+Q keys. A window appears and asks if you would like to save the changes. Click Save.
The next time you log in after rebooting your system, you are presented with a graphical login prompt.

8.4.6. Is Your RAM Not Being Recognized?

Sometimes, the kernel does not recognize all of your memory (RAM). You can check this with the cat /proc/meminfo command.
Verify that the displayed quantity is the same as the known amount of RAM in your system. If they are not equal, add the following line to the /boot/grub/grub.conf:
mem=xxM
Replace xx with the amount of RAM you have in megabytes.
In /boot/grub/grub.conf, the above example would look similar to the following:
# NOTICE: You have a /boot partition. This means that 
#  all kernel paths are relative to /boot/ 
default=0 
timeout=30 
splashimage=(hd0,0)/grub/splash.xpm.gz 
 title Fedora (2.6.27.19-170.2.35.fc10.i686)
root (hd0,1)
kernel /vmlinuz-2.6.27.19-170.2.35.fc10.i686 ro root=UUID=04a07c13-e6bf-6d5a-b207-002689545705 mem=1024M
initrd /initrd-2.6.27.19-170.2.35.fc10.i686.img
Once you reboot, the changes made to grub.conf are reflected on your system.
Once you have loaded the GRUB boot screen, type e for edit. You are presented with a list of items in the configuration file for the boot label you have selected.
Choose the line that starts with kernel and type e to edit this boot entry.
At the end of the kernel line, add
mem=xxM
where xx equals the amount of RAM in your system.
Press Enter to exit edit mode.
Once the boot loader screen has returned, type b to boot the system.
Itanium users must enter boot commands with elilo followed by the boot command.
Remember to replace xx with the amount of RAM in your system. Press Enter to boot.

Table of Contents

9. Boot Options
9.1. Configuring the Installation System at the Boot Menu
9.1.1. Specifying the Language
9.1.2. Configuring the Interface
9.1.3. Updating anaconda
9.1.4. Specifying the Installation Method
9.1.5. Manually Configuring the Network Settings
9.2. Enabling Remote Access to the Installation System
9.2.1. Enabling Remote Access with VNC
9.2.2. Connecting the Installation System to a VNC Listener
9.2.3. Enabling Remote Access with Telnet
9.3. Logging to a Remote System During the Installation
9.3.1. Configuring a Log Server
9.4. Automating the Installation with Kickstart
9.5. Enhancing Hardware Support
9.5.1. Adding Hardware Support with Driver Disks
9.5.2. Overriding Automatic Hardware Detection
9.6. Using the Maintenance Boot Modes
9.6.1. Loading the Memory (RAM) Testing Mode
9.6.2. Verifying boot media
9.6.3. Booting Your Computer with the Rescue Mode
9.6.4. Upgrading your computer
10. Installing Without Media
10.1. Retrieving Boot Files
10.2. Editing the GRUB Configuration
10.3. Booting to Installation
11. Setting Up an Installation Server
11.1. Setting Up cobbler
11.2. Setting Up the Distribution
11.3. Mirroring a Network Location
11.4. Importing the Distribution
11.5. Manually configure a PXE server
11.5.1. Setting up the Network Server
11.5.2. PXE Boot Configuration
11.5.3. Adding PXE Hosts
11.5.4. TFTPD
11.5.5. Configuring the DHCP Server
11.5.6. Adding a Custom Boot Message
11.5.7. Performing the PXE Installation
12. Installing Through VNC
12.1. VNC Viewer
12.2. VNC Modes in Anaconda
12.2.1. Direct Mode
12.2.2. Connect Mode
12.3. Installation Using VNC
12.3.1. Installation Example
12.3.2. Kickstart Considerations
12.3.3. Firewall Considerations
12.4. References
13. Kickstart Installations
13.1. What are Kickstart Installations?
13.2. How Do You Perform a Kickstart Installation?
13.3. Creating the Kickstart File
13.4. Kickstart Options
13.4.1. Advanced Partitioning Example
13.5. Package Selection
13.6. Pre-installation Script
13.6.1. Example
13.7. Post-installation Script
13.7.1. Examples
13.8. Making the Kickstart File Available
13.8.1. Creating Kickstart Boot Media
13.8.2. Making the Kickstart File Available on the Network
13.9. Making the Installation Tree Available
13.10. Starting a Kickstart Installation
14. Kickstart Configurator
14.1. Basic Configuration
14.2. Installation Method
14.3. Boot Loader Options
14.4. Partition Information
14.4.1. Creating Partitions
14.5. Network Configuration
14.6. Authentication
14.7. Firewall Configuration
14.7.1. SELinux Configuration
14.8. Display Configuration
14.9. Package Selection
14.10. Pre-Installation Script
14.11. Post-Installation Script
14.11.1. Chroot Environment
14.11.2. Use an Interpreter
14.12. Saving the File

Chapter 9. Boot Options

The Fedora installation system includes a range of functions and options for administrators. To use boot options, enter linux option at the boot: prompt.
If you specify more than one option, separate each of the options by a single space. For example:
linux option1 option2 option3

Anaconda Boot Options

The anaconda installer has many boot options, most are listed on the wiki http://fedoraproject.org/wiki/Anaconda/Options.

Kernel Boot Options

The http://fedoraproject.org/wiki/KernelCommonProblems page lists many common kernel boot options. The full list of kernel options is in the file /usr/share/doc/kernel-doc-version/Documentation/kernel-parameters.txt, which is installed with the kernel-doc package.

Rescue Mode

The Fedora installation and rescue discs may either boot with rescue mode, or load the installation system. For more information on rescue discs and rescue mode, refer to Section 9.6.3, “Booting Your Computer with the Rescue Mode”.

9.1. Configuring the Installation System at the Boot Menu

You can use the boot menu to specify a number of settings for the installation system, including:
  • language
  • display resolution
  • interface type
  • Installation method
  • network settings

9.1.1. Specifying the Language

To set the language for both the installation process and the final system, specify the ISO code for that language with the lang option. Use the keymap option to configure the correct keyboard layout.
For example, the ISO codes el_GR and gr identify the Greek language and the Greek keyboard layout:
linux lang=el_GR keymap=gr
Installation method Option format
CD or DVD drive method=cdrom
Hard Drive method=hd://device/
HTTP Server method=http://server.mydomain.com/directory/
FTP Server method=ftp://server.mydomain.com/directory/
NFS Server method=nfs:server.mydomain.com:/directory/
Table 9.1. Installation methods

9.1.5. Manually Configuring the Network Settings

By default, the installation system uses DHCP to automatically obtain the correct network settings. To manually configure the network settings yourself, either enter them in the Configure TCP/IP screen, or at the boot: prompt. You may specify the ip address, netmask, gateway, and dns server settings for the installation system at the prompt. If you specify the network configuration at the boot: prompt, these settings are used for the installation process, and the Configure TCP/IP screen does not appear.
This example configures the network settings for an installation system that uses the IP address 192.168.1.10:
linux ip=192.168.1.10 netmask=255.255.255.0 gateway=192.168.1.1 dns=192.168.1.2,192.168.1.3

Configuring the Installed System

Use the Network Configuration screen to specify the network settings for the new system. Refer to Section 7.15.1, “Manual configuration” for more information on configuring the network settings for the installed system.

9.2. Enabling Remote Access to the Installation System

You may access either graphical or text interfaces for the installation system from any other system. Access to a text mode display requires telnet, which is installed by default on Fedora systems. To remotely access the graphical display of an installation system, use client software that supports the VNC (Virtual Network Computing) display protocol. A number of providers offer VNC clients for Microsoft Windows and Mac OS, as well as UNIX-based systems.
linux syslog=192.168.1.20:514
 linux ks=location/kickstart-file.cfg
Kickstart source Option format
CD or DVD drive ks=cdrom:/directory/ks.cfg
Hard Drive ks=hd:/device/directory/ks.cfg
Other Device ks=file:/device/directory/ks.cfg
HTTP Server ks=http://server.mydomain.com/directory/ks.cfg
FTP Server ks=ftp://server.mydomain.com/directory/ks.cfg
NFS Server ks=nfs:server.mydomain.com:/directory/ks.cfg
Table 9.2. Kickstart sources

To obtain a Kickstart file from a script or application on a Web server, specify the URL of the application with the ks= option. If you add the option kssendmac, the request also sends HTTP headers to the Web application. Your application can use these headers to identify the computer. This line sends a request with headers to the application http://server.mydomain.com/kickstart.cgi:
linux ks=http://server.mydomain.com/kickstart.cgi kssendmac

9.5. Enhancing Hardware Support

By default, Fedora attempts to automatically detect and configure support for all of the components of your computer. Fedora supports the majority of hardware in common use with the software drivers that are included with the operating system. To support other devices you may supply additional drivers during the installation process, or at a later time.

9.5.1. Adding Hardware Support with Driver Disks

The installation system can load drivers from disks, pen drives, or network servers to configure support for new devices. After the installation is complete, remove any driver disks and store them for later use.
 dd if=drivers.img of=/dev/fd0
 linux dd
Image source Option format
Select a drive or device dd
HTTP Server dd=http://server.mydomain.com/directory/drivers.img
FTP Server dd=ftp://server.mydomain.com/directory/drivers.img
NFS Server dd=nfs:server.mydomain.com:/directory/drivers.img
Table 9.3. Driver disk image sources

9.5.2. Overriding Automatic Hardware Detection

For some models of device automatic hardware configuration may fail, or cause instability. In these cases, you may need to disable automatic configuration for that type of device, and take additional steps to manually configure the device after the installation process is complete.

Check the Release Notes

Refer to the Release Notes for information on known issues with specific devices.
To override the automatic hardware detection, use one or more of the following options:
Compatibility Option
Disable all hardware detection noprobe
Disable graphics, keyboard, and mouse detection headless
Disable passing keyboard and mouse information to stage 2 of the installation program nopass
Use basic VESA driver for video xdriver=vesa
Disable shell access on virtual console 2 during installation noshell
Disable advanced configuration and power interface (ACPI) acpi=off
Disable machine check exception (MCE) CPU self-diagnosis. nomce
Disable non-uniform menory access on the AMD64 architecture numa-off
Force kernel to detect a specific amount of memory, where xxx is a value in megabytes mem=xxxm
Enable DMA only for IDE and SATA drives libata.dma=1
Disable BIOS-assisted RAID nodmraid
Disable Firewire device detection nofirewire
Disable parallel port detection noparport
Disable PC Card (PCMCIA) device detection nopcmcia
Disable USB storage device detection nousbstorage
Disable all USB device detection nousb
Disable all probing of network hardware nonet
Table 9.4. Hardware Options

Additional Screen

The isa option causes the system to display an additional text screen at the beginning of the installation process. Use this screen to configure the ISA devices on your computer.

Important

Other kernel boot options have no particular meaning for anaconda and do not affect the installation process. However, if you use these options to boot the installation system, anaconda will preserve them in the bootloader configuration.

9.6. Using the Maintenance Boot Modes

9.6.1. Loading the Memory (RAM) Testing Mode

Faults in memory modules may cause your system to freeze or crash unpredictably. In some cases, memory faults may only cause errors with particular combinations of software. For this reason, you should test the memory of a computer before you install Fedora for the first time, even if it has previously run other operating systems.
This section discusses how to install Fedora to your system without making any additional physical media. Instead, you can use your existing GRUB boot loader to start the installation program.

Linux Required

This procedure assumes you are already using Fedora or another relatively modern Linux distribution, and the GRUB boot loader. It also assumes you are a somewhat experienced Linux user.

10.1. Retrieving Boot Files

To perform an installation without media or a PXE server, your system must have two files stored locally, a kernel and an initial RAM disk.
  1. Download a Live image or DVD distribution, or to locate an installation mirror, visit http://mirrors.fedoraproject.org/publiclist/Fedora/11/.
  2. Locate the isolinux/ folder using one of the following methods:
    • If you chose to download an image, open it with the appropriate desktop tool. If you are using Fedora, double-click the file to open it with the Archive Manager. Open the isolinux/ folder.
    • If you chose not to download a whole image because you wish to install via the network, locate the desired release. In general, once you find a suitable mirror, browse to the releases/11/Fedora/arch/os/isolinux/ folder.

    Installation Types Available

    If you download an image, you may then choose a hard disk-based installation or a network installation. If you only download selected files from a mirror, you may only perform a network installation.
  3. Copy the vmlinuz and initrd.img files from the chosen source to the /boot/ directory, renaming them to vmlinuz-install and initrd.img-installYou must have root privileges to write files into the /boot/ directory.

10.2. Editing the GRUB Configuration

The GRUB boot loader uses the configuration file /boot/grub/grub.conf. To configure GRUB to boot from the new files, add a boot stanza to /boot/grub/grub.confthat refers to them.
A minimal boot stanza looks like the following listing:
title Installation
        root (hd0,0)
        kernel /vmlinuz-install
        initrd /initrd.img-install
You may wish to add options to the end of the kernel line of the boot stanza. These options set preliminary options in Anaconda which the user normally sets interactively. For a list of available installer boot options, refer to Chapter 9, Boot Options.
The following options are generally useful for medialess installations:
  • ip=
  • method=
  • lang=
  • keymap=
  • ksdevice= (if installation requires an interface other than eth0)
  • vnc and vncpassword= for a remote installation
When you are finished, change the default option in /boot/grub/grub.conf to point to the new first stanza you added:
default 0

10.3. Booting to Installation

Reboot the system. GRUB boots the installation kernel and RAM disk, including any options you set. You may now refer to the appropriate chapter in this guide for the next step. If you chose to install remotely using VNC, refer to Section 9.2, “Enabling Remote Access to the Installation System” for assistance in connecting to the remote system.

Chapter 11. Setting Up an Installation Server

Experience Required

This appendix is intended for users with previous Linux experience. If you are a new user, you may want to install using minimal boot media or the distribution DVD instead.

Warning

The instructions in this appendix configures an automated install server. The default configuration includes destruction of all existing data on all disks for hosts that install using this method. This is often different from other network install server configurations which may provide for an interactive installation experience.
Fedora allows for installation over a network using the NFS, FTP, or HTTP protocols. A network installation can be started from a boot CD-ROM, a bootable flash memory drive, or by using the askmethod boot option with the Fedora CD #1 or DVD. Alternatively, if the system to be installed contains a network interface card (NIC) with Pre-Execution Environment (PXE) support, it can be configured to boot from files on another networked system rather than local media such as a CD-ROM.
For a PXE network installation, the client's NIC with PXE support sends out a broadcast request for DHCP information. The DHCP server provides the client with an IP address, other network information such as name server, the IP address or hostname of the tftp server (which provides the files necessary to start the installation program), and the location of the files on the tftp server. This is possible because of PXELINUX, which is part of the syslinux package.
In the past, administrators needed to perform a great deal of manual configuration to produce an installation server. However, if you have a Red Hat Enterprise Linux, CentOS, or Fedora server on your local network, you can use cobbler to perform these tasks. To configure a PXE server manually, see Section 11.5, “Manually configure a PXE server”.
To perform the tasks in this section, switch to the root account with the command su -. As an alternative, you can run a command with the -c option, using the form su -c 'command'.

11.1. Setting Up cobbler

To install cobbler use the following command:
yum -y install cobbler
The cobbler command can check its own settings for validity and report the results. Run the following command to check the settings:
cobbler check
Change the settings in the /var/lib/cobbler/settings file to reflect the IP address information for the server. You must change at least the server and next_server options, although these options may point to the same IP address.
If you are not already running a DHCP server, you should also change the manage_dhcp option to 1. If you are running a DHCP server, configure it according to the instructions found in the syslinux package documentation. For more information, refer to your local files /usr/share/doc/syslinux-version/syslinux.doc and /usr/share/doc/syslinux-version/pxelinux.doc.

11.2. Setting Up the Distribution

To set up a distribution from a full Fedora DVD or ISO image, use this procedure.

Network Locations

To create a local mirror from an existing network source, skip this section and refer instead to Section 11.3, “Mirroring a Network Location”.
  1. If you are using a DVD disc or ISO image, Create a directory mount point:
    mkdir /mnt/dvd
    
    To mount a physical DVD disc, use the following command:
    mount -o context=system_u:object_r:httpd_sys_content_t:s0 /dev/dvd /mnt/dvd
    
    To mount a DVD ISO image, use the following command:
    mount -ro loop,context=system_u:object_r:httpd_sys_content_t:s0 /path/to/image.iso /mnt/dvd
    
  2. To support NFS installation, create a file /etc/exports and add the following line to it:
    /mnt/dvd *(ro,async)
    
    Start the NFS server using the following commands:
    /sbin/service rpcbind start /sbin/service nfs start
    
  3. To support HTTP installation, use yum to install the Apache web server if it is not already installed:
    yum -y install httpd
    
    Make a link to the mounted disc in the Apache public content area:
    ln -s /mnt/dvd /var/www/html/distro
    

11.3. Mirroring a Network Location

If you do not have discs or ISO images for a distribution, you can use cobbler to create an installation server. The cobbler command can fetch the distribution over the network as part of the import process.
Locate the distribution on the network. The location may be on the local network or reached at a remote site via FTP, HTTP, or rsync protocols. Note the URI, which will be in one of the following forms:
  • http://mirror.example.com/pub/fedora/linux/releases/11/Fedora/arch/os
  • ftp://mirror.example.com/pub/fedora/linux/releases/11/Fedora/arch/os
  • rsync://mirror.example.com/fedora/linux/releases/11/Fedora/arch/os

11.4. Importing the Distribution

To offer a distribution through more than one installation method, perform additional cobbler import tasks using a different name for each method. For best results, use the installation method as part of the name, so it appears in the client's boot menu.
  1. To import the DVD disc or ISO distribution into cobbler, run this command:
    cobbler import --path=/mnt/dvd --name=distro_name
    
    For distro_name, substitute a meaningful name for the distribution.
    To import a local or remote network distribution into cobbler, run this command. Replace network_URI with the URI you found in Section 11.3, “Mirroring a Network Location”, and distro_name as above:
    cobbler import --mirror=network_URI --name=distro_name
    

    Importing a Source

    When cobbler imports a distribution with the commands above, it copies all the files to the server's local storage, which may take some time.
    If you do not want to make local copies of the distribution because clients can already reach its location, use the --available-as option.
    cobbler import --path=/mnt/dvd --name=distro_name --available-as=network_URI
    cobbler import --mirror=network_URI --name=distro_name --available-as=network_URI
    
    For nework_URI, substitute the appropriate network location of the distribution. This URI indicates how the server makes the distribution available to its clients. The examples above assume that your cobbler server reaches the mirror location at the same URI as the clients. If not, substitute an appropriate URI for the --mirror option. The following examples are URI locations that work if you have been following the procedures in this section, and your server's IP address is 192.168.1.1:
    • nfs://192.168.1.1:/mnt/dvd
    • http://192.168.1.1:/distro
    If necessary, replace 192.168.1.1 with the IP address for your cobbler server.
  2. Run the command cobbler sync to apply the changes. To check that your cobbler server is listening on the correct ports, use the netstat -lp command.

    Firewall Considerations

    Depending on your server's configuration, you may need to use the system-config-securitylevel command to permit access to some or all of these network services:
    • 67 or bootps, for the DHCP/BOOTP server
    • 69 or tftp, for providing the PXE loader
    • 80 or http, if the cobbler server is to provide HTTP installation service
    • 20 and 21 or ftp, if the cobbler server is to provide FTP installation service
    • 111 or sunrpc, if the cobbler server is to provide NFS installation service

11.5. Manually configure a PXE server

The following steps must be performed to prepare for a PXE installation:
  1. Configure the network (NFS, FTP, HTTP) server to export the installation tree.
  2. Configure the files on the tftp server necessary for PXE booting.
  3. Configure which hosts are allowed to boot from the PXE configuration.
  4. Start the tftp service.
  5. Configure DHCP.
  6. Boot the client, and start the installation.
Add Hosts
Add Hosts
Figure 11.1. Add Hosts

The next step is to configure which hosts are allowed to connect to the PXE boot server.
To add hosts, click the New button.
Add a Host
Add a Host
Figure 11.2. Add a Host

Enter the following information:
  • Hostname or IP Address/Subnet — The IP address, fully qualified hostname, or a subnet of systems that should be allowed to connect to the PXE server for installations.
  • Operating System — The operating system identifier to install on this client. The list is populated from the network install instances created from the Network Installation Dialog.
  • Serial Console — This option allows use of a serial console.
  • Kickstart File — The location of a kickstart file to use, such as http://server.example.com/kickstart/ks.cfg. This file can be created with the Kickstart Configurator. Refer to Chapter 14, Kickstart Configurator for details.
Ignore the Snapshot name and Ethernet options. They are only used for diskless environments.

Chapter 12. Installing Through VNC

The Red Hat Enterprise Linux and Fedora installer (anaconda) offers you two interactive modes of operation. The original mode is a text-based interface. The newer mode uses GTK+ and runs in the X Window environment. This chapter explains how you can use the graphical installation mode in environments where the system lacks a proper display and input devices typically associated with a workstation. This scenario is typical of systems in datacenters, which are often installed in a rack environment and do not have a display, keyboard, or mouse. Additionally, a lot of these systems even lack the ability to connect a graphical display. Given that enterprise hardware rarely needs that ability at the physical system, this hardware configuration is acceptable.
Even in these environments, however, the graphical installer remains the recommended method of installation. The text mode environment lacks a lot of capabilities found in the graphical mode. Many users still feel that the text mode interface provides them with additional power or configuration ability not found in the graphical version. The opposite is true. Much less development effort is put in to the text-mode environment and specific things (for example, LVM configuration, partition layout, package selection, and bootloader configuration) are deliberately left out of the text mode environment. The reasons for this are:
  • Less screen real estate for creating user interfaces similar to those found in the graphical mode.
  • Difficult internationalization support.
  • Desire to maintain a single interactive installation code path.
Anaconda therefore includes a Virtual Network Computing (VNC) mode that allows the graphical mode of the installer to run locally, but display on a system connected to the network. Installing in VNC mode provides you with the full range of installation options, even in situations where the system lacks a display or input devices.

12.1. VNC Viewer

Performing a VNC installation requires a VNC viewer running on your workstation or other terminal computer. Locations where you might want a VNC viewer installed:
  • Your workstation
  • Laptop on a datacenter crash cart
VNC is open source software licensed under the GNU General Public License. Versions exist for Linux, Windows, and MacOS X. Here are some recommended VNC viewers:
  • vncviewer is available on Red Hat Enterprise Linux and Fedora Linux by installing the vnc package:
    # yum install vnc
    
  • TightVNC is available for Windows at http://www.tightvnc.com/
  • MacOS X includes built-in VNC support as of version 10.5. In the Finder, click the Go menu and choose Connect to Server. In the server address field, you can type vnc://SERVER:DISPLAY, where SERVER is the IP address or DNS host name of the VNC server you wish to connect to and DISPLAY is the VNC display number (usually 1), and click Connect.
Once you have verified you have a VNC viewer available, it's time to start the installation.

12.2. VNC Modes in Anaconda

Anaconda offers two modes for VNC installation. The mode you select will depend on the network configuration in your environment.

12.2.1. Direct Mode

Direct mode VNC in anaconda is when the client initiates a connection to the VNC server running in anaconda. Anaconda will tell you when to initiate this connection in the VNC viewer. Direct mode can be activated by either of the following commands:
  • Specify vnc as a boot argument.
  • Specify the vnc command in the kickstart file used for installation.
When you activate VNC mode, anaconda will complete the first stage of the installer and then start VNC to run the graphical installer. The installer will display a message on the console in the following format:
Running anaconda VERSION, the PRODUCT system installer - please wait...
Anaconda will also tell you the IP address and display number to use in your VNC viewer. At this point, you need to start the VNC viewer and connect to the target system to continue the installation. The VNC viewer will present anaconda to you in graphical mode.
There are some disadvantages to direct mode, including:
  • Requires visual access to the system console to see the IP address and port to connect the VNC viewer to.
  • Requires interactive access to the system console to complete the first stage of the installer.
If either of these disadvantages would prevent you from using direct mode VNC in anaconda, then connect mode is probably more suited to your environment.

12.2.2. Connect Mode

Certain firewall configurations or instances where the target system is configured to obtain a dynamic IP address may cause trouble with the direct VNC mode in anaconda. In addition, if you lack a console on the target system to see the message that tells you the IP address to connect to, then you will not be able to continue the installation.
The VNC connect mode changes how VNC is started. Rather than anaconda starting up and waiting for you to connect, the VNC connect mode allows anaconda to automatically connect to your view. You won't need to know the IP address of the target system in this case.
To activate the VNC connect mode, pass the vncconnect boot parameter:
boot: linux vncconnect=HOST
Replace HOST with your VNC viewer's IP address or DNS host name. Before starting the installation process on the target system, start up your VNC viewer and have it wait for an incoming connection.
Start the installation and when your VNC viewer displays the graphical installer, you are ready to go.

12.3. Installation Using VNC

Now that you have installed a VNC viewer application and selected a VNC mode for use in anaconda, you are ready to begin the installation.

12.3.1. Installation Example

The easiest way to perform an installation using VNC is to connect another computer directly to the network port on the target system. The laptop on a datacenter crash cart usually fills this role. If you are performing your installation this way, make sure you follow these steps:
  1. Connect the laptop or other workstation to the target system using a crossover cable. If you are using regular patch cables, make sure you connect the two systems using a small hub or switch. Most recent Ethernet interfaces will automatically detect if they need to be crossover or not, so it may be possible to connect the two systems directly using a regular patch cable.
  2. Configure the VNC viewer system to use a RFC 1918 address with no gateway. This private network connection will only be used for the purpose of installation. Configure the VNC viewer system to be 192.168.100.1/24. If that address is in use, just pick something else in the RFC 1918 address space that is available to you.
  3. Start the installation on the target system.
    1. Booting the installation DVD or CD.
      If booting the installation media (CD or DVD), make sure vnc is passed as a boot parameter. To add the vnc parameter, you will need a console attached to the target system that allows you to interact with the boot process. Enter the following at the prompt:
      boot: linux vnc
      
    2. Boot over the network.
      If the target system is configured with a static IP address, add the vnc command to the kickstart file. If the target system is using DHCP, add vncconnect=HOST to the boot arguments for the target system. HOST is the IP address or DNS host name of the VNC viewer system. Enter the following at the prompt:
      boot: linux vncconnect=HOST
      
  4. When prompted for the network configuration on the target system, assign it an available RFC 1918 address in the same network you used for the VNC viewer system. For example, 192.168.100.2/24.

    Note

    This IP address is only used during installation. You will have an opportunity to configure the final network settings, if any, later in the installer.
  5. Once the installer indicates it is starting anaconda, you will be instructed to connect to the system using the VNC viewer. Connect to the viewer and follow the graphical installation mode instructions found in the product documentation.

12.3.2. Kickstart Considerations

If your target system will be booting over the network, VNC is still available. Just add the vnc command to the kickstart file for the system. You will be able to connect to the target system using your VNC viewer and monitor the installation progress. The address to use is the one the system is configured with via the kickstart file.
If you are using DHCP for the target system, the reverse vncconnect method may work better for you. Rather than adding the vnc boot parameter to the kickstart file, add the vncconnect=HOST parameter to the list of boot arguments for the target system. For HOST, put the IP address or DNS host name of the VNC viewer system. See the next section for more details on using the vncconnect mode.

12.3.3. Firewall Considerations

If you are performing the installation where the VNC viewer system is a workstation on a different subnet from the target system, you may run in to network routing problems. VNC works fine so long as your viewer system has a route to the target system and ports 5900 and 5901 are open. If your environment has a firewall, make sure ports 5900 and 5901 are open between your workstation and the target system.
In addition to passing the vnc boot parameter, you may also want to pass the vncpassword parameter in these scenarios. While the password is sent in plain text over the network, it does provide an extra step before a viewer can connect to a system. Once the viewer connects to the target system over VNC, no other connections are permitted. These limitations are usually sufficient for installation purposes.

Important

Be sure to use a temporary password for the vncpassword option. It should not be a password you use on any systems, especially a real root password.
If you continue to have trouble, consider using the vncconnect parameter. In this mode of operation, you start the viewer on your system first telling it to listen for an incoming connection. Pass vncconnect=HOST at the boot prompt and the installer will attempt to connect to the specified HOST (either a hostname or IP address).

12.4. References

Chapter 13. Kickstart Installations

13.1. What are Kickstart Installations?

Many system administrators would prefer to use an automated installation method to install Fedora on their machines. To answer this need, Red Hat created the kickstart installation method. Using kickstart, a system administrator can create a single file containing the answers to all the questions that would normally be asked during a typical installation.
Kickstart files can be kept on a single server system and read by individual computers during the installation. This installation method can support the use of a single kickstart file to install Fedora on multiple machines, making it ideal for network and system administrators.
Kickstart provides a way for users to automate a Fedora installation.

13.2. How Do You Perform a Kickstart Installation?

Kickstart installations can be performed using a local CD-ROM, a local hard drive, or via NFS, FTP, or HTTP.
To use kickstart, you must:
  1. Create a kickstart file.
  2. Create a boot media with the kickstart file or make the kickstart file available on the network.
  3. Make the installation tree available.
  4. Start the kickstart installation.
This chapter explains these steps in detail.

13.3. Creating the Kickstart File

The kickstart file is a simple text file, containing a list of items, each identified by a keyword. You can create it by using the Kickstart Configurator application, or writing it from scratch. The Fedora installation program also creates a sample kickstart file based on the options that you selected during installation. It is written to the file /root/anaconda-ks.cfg. You should be able to edit it with any text editor or word processor that can save files as ASCII text.
First, be aware of the following issues when you are creating your kickstart file:

13.4. Kickstart Options

Note

If the option is followed by an equals mark (=), a value must be specified after it. In the example commands, options in brackets ([]) are optional arguments for the command.
autopart (optional)
ignoredisk (optional)
ignoredisk --drives=drive1,drive2,...
autostep (optional)
auth or authconfig (required)
bootloader (required)
clearpart (optional)
cmdline (optional)
device (optional)
device <type> <moduleName> --opts=<options>
driverdisk (optional)
driverdisk <partition> [--type=<fstype>]
driverdisk --source=ftp://path/to/dd.img
driverdisk --source=http://path/to/dd.img
driverdisk --source=nfs:host:/path/to/img
firewall (optional)
firewall --enabled|--disabled [--trust=] <device> [--port=]
firstboot (optional)
halt (optional)
graphical (optional)
install (optional)
  • cdrom — Install from the first CD-ROM drive on the system.
  • harddrive — Install from a Red Hat installation tree on a local drive, which must be either vfat or ext2.
    • --biospart=
      BIOS partition to install from (such as 82).
    • --partition=
      Partition to install from (such as sdb2).
    • --dir=
      Directory containing the variant directory of the installation tree.
    For example:
    harddrive --partition=hdb2 --dir=/tmp/install-tree
    
  • nfs — Install from the NFS server specified.
    • --server=
      Server from which to install (hostname or IP).
    • --dir=
      Directory containing the variant directory of the installation tree.
    • --opts=
      Mount options to use for mounting the NFS export. (optional)
    For example:
    nfs --server=nfsserver.example.com --dir=/tmp/install-tree
    
  • url — Install from an installation tree on a remote server via FTP or HTTP.
    For example:
    url --url http://<server>/<dir>
    
    or:
    url --url ftp://<username>:<password>@<server>/<dir>
    
interactive (optional)
iscsi (optional)
key (optional)
keyboard (required)
be-latin1, bg, br-abnt2, cf, cz-lat2, cz-us-qwertz, de, de-latin1, 
de-latin1-nodeadkeys, dk, dk-latin1, dvorak, es, et, fi, fi-latin1, 
fr, fr-latin0, fr-latin1, fr-pc, fr_CH, fr_CH-latin1, gr, hu, hu101, 
is-latin1, it, it-ibm, it2, jp106, la-latin1, mk-utf, no, no-latin1, 
pl, pt-latin1, ro_win, ru, ru-cp1251, ru-ms, ru1, ru2,  ru_win, 
se-latin1, sg, sg-latin1, sk-qwerty, slovene, speakup,  speakup-lt, 
sv-latin1, sg, sg-latin1, sk-querty, slovene, trq, ua,  uk, us, us-acentos
lang (required)
lang en_US
langsupport (deprecated)
@french-support
logvol (optional)
logvol <mntpoint> --vgname=<name> --size=<size> --name=<name> <options>
part pv.01 --size 3000 
volgroup myvg pv.01
logvol / --vgname=myvg --size=2000 --name=rootvol
logging (optional)
mediacheck (optional)
monitor (optional)
mouse (deprecated)
network (optional)
multipath (optional)
part or partition (required for installs, ignored for upgrades)
  • <mntpoint> — The <mntpoint> is where the partition is mounted and must be of one of the following forms:
    • /<path>
      For example, /, /usr, /home
    • swap
      The partition is used as swap space.
      To determine the size of the swap partition automatically, use the --recommended option:
      swap --recommended
      
      The recommended maximum swap size for machines with less than 2GB of RAM is twice the amount of RAM. For machines with 2GB or more, this recommendation changes to 2GB plus the amount of RAM.
    • raid.<id>
      The partition is used for software RAID (refer to raid).
    • pv.<id>
      The partition is used for LVM (refer to logvol).
  • --size= — The minimum partition size in megabytes. Specify an integer value here such as 500. Do not append the number with MB.
  • --grow — Tells the partition to grow to fill available space (if any), or up to the maximum size setting.

    Note

    If you use --grow= without setting --maxsize= on a swap partition, Anaconda will limit the maximum size of the swap partition. For systems that have less than 2GB of physical memory, the imposed limit is twice the amount of physical memory. For systems with more than 2GB, the imposed limit is the size of physical memory plus 2GB.
  • --maxsize= — The maximum partition size in megabytes when the partition is set to grow. Specify an integer value here, and do not append the number with MB.
  • --noformat — Tells the installation program not to format the partition, for use with the --onpart command.
  • --onpart= or --usepart= — Put the partition on the already existing device. For example:
    partition /home --onpart=hda1
    
    puts /home on /dev/hda1, which must already exist.
  • --ondisk= or --ondrive= — Forces the partition to be created on a particular disk. For example, --ondisk=sdb puts the partition on the second SCSI disk on the system.
  • --asprimary — Forces automatic allocation of the partition as a primary partition, or the partitioning fails.
  • --type= (replaced by fstype) — This option is no longer available. Use fstype.
  • --fstype= — Sets the file system type for the partition. Valid values are xfs, ext2, ext3, ext4, swap, vfat, and hfs.
  • --start= — Specifies the starting cylinder for the partition. It requires that a drive be specified with --ondisk= or ondrive=. It also requires that the ending cylinder be specified with --end= or the partition size be specified with --size=.
  • --end= — Specifies the ending cylinder for the partition. It requires that the starting cylinder be specified with --start=.
  • --bytes-per-inode= — Specifies the size of inodes on the filesystem to be made on the partition. Not all filesystems support this option, so it is silently ignored for those cases.
  • --recommended — Determine the size of the partition automatically.
  • --onbiosdisk — Forces the partition to be created on a particular disk as discovered by the BIOS.
  • --encrypted — Specifies that this partition should be encrypted.
  • --passphrase= — Specifies the passphrase to use when encrypting this partition. Without the above --encrypted option, this option does nothing. If no passphrase is specified, the default system-wide one is used, or the installer will stop and prompt if there is no default.

Note

If partitioning fails for any reason, diagnostic messages appear on virtual console 3.
poweroff (optional)
raid (optional)
raid <mntpoint> --level=<level> --device=<mddevice> <partitions*>
part raid.01 --size=60 --ondisk=sda
part raid.02 --size=60 --ondisk=sdb 
part raid.03 --size=60 --ondisk=sdc
part swap --size=128 --ondisk=sda  
part swap --size=128 --ondisk=sdb  
part swap --size=128 --ondisk=sdc
part raid.11 --size=1 --grow --ondisk=sda  
part raid.12 --size=1 --grow --ondisk=sdb  
part raid.13 --size=1 --grow --ondisk=sdc
raid / --level=1 --device=md0 raid.01 raid.02 raid.03  
raid /usr --level=5 --device=md1 raid.11 raid.12 raid.13
reboot (optional)
repo (optional)
repo --name=<repoid> [--baseurl=<url>| --mirrorlist=<url>]
rootpw (required)
rootpw [--iscrypted] <password>
selinux (optional)
selinux [--disabled|--enforcing|--permissive]
services (optional)
shutdown (optional)
skipx (optional)
text (optional)
timezone (required)
timezone [--utc] <timezone>
upgrade (optional)
user (optional)
user --name=<username> [--groups=<list>] [--homedir=<homedir>] [--password=<password>] [--iscrypted] [--shell=<shell>] [--uid=<uid>]
vnc (optional)
vnc [--host=<hostname>] [--port=<port>] [--password=<password>]
volgroup (optional)
volgroup <name> <partition> <options>
part pv.01 --size 3000 
volgroup myvg pv.01 
logvol / --vgname=myvg --size=2000 --name=rootvol
xconfig (optional)
zerombr (optional)
zfcp (optional)
%include (optional)
Use the %packages command to begin a kickstart file section that lists the packages you would like to install (this is for installations only, as package selection during upgrades is not supported).
Packages can be specified by group or by individual package name, including with globs using the asterisk. The installation program defines several groups that contain related packages. Refer to the variant/repodata/comps-*.xml file on the first Fedora CD-ROM for a list of groups. Each group has an id, user visibility value, name, description, and package list. In the package list, the packages marked as mandatory are always installed if the group is selected, the packages marked default are selected by default if the group is selected, and the packages marked optional must be specifically selected even if the group is selected to be installed.
In most cases, it is only necessary to list the desired groups and not individual packages. Note that the Core and Base groups are always selected by default, so it is not necessary to specify them in the %packages section.
Here is an example %packages selection:
%packages 
@ X Window System 
@ GNOME Desktop Environment 
@ Graphical Internet 
@ Sound and Video dhcp
As you can see, groups are specified, one to a line, starting with an @ symbol, a space, and then the full group name as given in the comps.xml file. Groups can also be specified using the id for the group, such as gnome-desktop. Specify individual packages with no additional characters (the dhcp line in the example above is an individual package).
You can also specify which packages not to install from the default package list:
-autofs
The following options are available for the %packages option:
--nobase
Do not install the @Base group. Use this option if you are trying to create a very small system.
--resolvedeps
The --resolvedeps option has been deprecated. Dependencies are resolved automatically every time now.
--ignoredeps
The --ignoredeps option has been deprecated. Dependencies are resolved automatically every time now.
--ignoremissing
Ignore the missing packages and groups instead of halting the installation to ask if the installation should be aborted or continued. For example:
%packages --ignoremissing
You can add commands to run on the system immediately after the ks.cfg has been parsed. This section must be at the end of the kickstart file (after the commands) and must start with the %pre command. You can access the network in the %pre section; however, name service has not been configured at this point, so only IP addresses work.

Note

Note that the pre-install script is not run in the change root environment.
--interpreter /usr/bin/python
Allows you to specify a different scripting language, such as Python. Replace /usr/bin/python with the scripting language of your choice.

13.6.1. Example

Here is an example %pre section:
%pre  
#!/bin/sh  
hds="" 
mymedia=""  
for file in /proc/ide/h* do   
	mymedia=`cat $file/media`   
	if [ $mymedia == "disk" ] ; then       
		hds="$hds `basename $file`"   
	fi 
done  
set $hds 
numhd=`echo $#`  
drive1=`echo $hds | cut -d' ' -f1` 
drive2=`echo $hds | cut -d' ' -f2`  
#Write out partition scheme based on whether there are 1 or 2 hard drives  
if [ $numhd == "2" ] ; then   
	#2 drives   
	echo "#partitioning scheme generated in %pre for 2 drives" > /tmp/part-include   
	echo "clearpart --all" >> /tmp/part-include   
	echo "part /boot --fstype ext3 --size 75 --ondisk hda" >> /tmp/part-include   
	echo "part / --fstype ext3 --size 1 --grow --ondisk hda" >> /tmp/part-include   
	echo "part swap --recommended --ondisk $drive1" >> /tmp/part-include   
	echo "part /home --fstype ext3 --size 1 --grow --ondisk hdb" >> /tmp/part-include 
else   
	#1 drive   
	echo "#partitioning scheme generated in %pre for 1 drive" > /tmp/part-include   
	echo "clearpart --all" >> /tmp/part-include   
	echo "part /boot --fstype ext3 --size 75" >> /tmp/part-includ   
	echo "part swap --recommended" >> /tmp/part-include   
	echo "part / --fstype ext3 --size 2048" >> /tmp/part-include   
	echo "part /home --fstype ext3 --size 2048 --grow" >> /tmp/part-include 
fi
This script determines the number of hard drives in the system and writes a text file with a different partitioning scheme depending on whether it has one or two drives. Instead of having a set of partitioning commands in the kickstart file, include the line:
%include /tmp/part-include
The partitioning commands selected in the script are used.

Note

The pre-installation script section of kickstart cannot manage multiple install trees or source media. This information must be included for each created ks.cfg file, as the pre-installation script occurs during the second stage of the installation process.
You have the option of adding commands to run on the system once the installation is complete. This section must be at the end of the kickstart file and must start with the %post command. This section is useful for functions such as installing additional software and configuring an additional nameserver.

Note

If you configured the network with static IP information, including a nameserver, you can access the network and resolve IP addresses in the %post section. If you configured the network for DHCP, the /etc/resolv.conf file has not been completed when the installation executes the %post section. You can access the network, but you can not resolve IP addresses. Thus, if you are using DHCP, you must specify IP addresses in the %post section.

Note

The post-install script is run in a chroot environment; therefore, performing tasks such as copying scripts or RPMs from the installation media do not work.
--nochroot
Allows you to specify commands that you would like to run outside of the chroot environment.
The following example copies the file /etc/resolv.conf to the file system that was just installed.
%post --nochroot cp /etc/resolv.conf /mnt/sysimage/etc/resolv.conf
--interpreter /usr/bin/python
Allows you to specify a different scripting language, such as Python. Replace /usr/bin/python with the scripting language of your choice.

13.7.1. Examples

Register the system to a Red Hat Network Satellite:
%post
( # Note that in this example we run the entire %post section as a subshell for logging.
wget -O- http://proxy-or-sat.example.com/pub/bootstrap_script | /bin/bash
/usr/sbin/rhnreg_ks --activationkey=<activationkey>
# End the subshell and capture any output to a post-install log file.
) 1>/root/post_install.log 2>&1
Run a script named runme from an NFS share:
mkdir /mnt/temp 
mount -o nolock 10.10.0.2:/usr/new-machines /mnt/temp open -s -w -- 
/mnt/temp/runme 
umount /mnt/temp

Note

NFS file locking is not supported while in kickstart mode, therefore -o nolock is required when mounting an NFS mount.
A kickstart file must be placed in one of the following locations:
  • On a boot diskette
  • On a boot CD-ROM
  • On a network
Normally a kickstart file is copied to the boot diskette, or made available on the network. The network-based approach is most commonly used, as most kickstart installations tend to be performed on networked computers.
Let us take a more in-depth look at where the kickstart file may be placed.
Network installations using kickstart are quite common, because system administrators can easily automate the installation on many networked computers quickly and painlessly. In general, the approach most commonly used is for the administrator to have both a BOOTP/DHCP server and an NFS server on the local network. The BOOTP/DHCP server is used to give the client system its networking information, while the actual files used during the installation are served by the NFS server. Often, these two servers run on the same physical machine, but they are not required to.
To perform a network-based kickstart installation, you must have a BOOTP/DHCP server on your network, and it must include configuration information for the machine on which you are attempting to install Fedora. The BOOTP/DHCP server provides the client with its networking information as well as the location of the kickstart file.
If a kickstart file is specified by the BOOTP/DHCP server, the client system attempts an NFS mount of the file's path, and copies the specified file to the client, using it as the kickstart file. The exact settings required vary depending on the BOOTP/DHCP server you use.
Here is an example of a line from the dhcpd.conf file for the DHCP server:
filename "/usr/new-machine/kickstart/"; next-server blarg.redhat.com;
Note that you should replace the value after filename with the name of the kickstart file (or the directory in which the kickstart file resides) and the value after next-server with the NFS server name.
If the file name returned by the BOOTP/DHCP server ends with a slash ("/"), then it is interpreted as a path only. In this case, the client system mounts that path using NFS, and searches for a particular file. The file name the client searches for is:
<ip-addr>-kickstart
The <ip-addr> section of the file name should be replaced with the client's IP address in dotted decimal notation. For example, the file name for a computer with an IP address of 10.10.0.1 would be 10.10.0.1-kickstart.
Note that if you do not specify a server name, then the client system attempts to use the server that answered the BOOTP/DHCP request as its NFS server. If you do not specify a path or file name, the client system tries to mount /kickstart from the BOOTP/DHCP server and tries to find the kickstart file using the same <ip-addr>-kickstart file name as described above.

13.10. Starting a Kickstart Installation

To begin a kickstart installation, you must boot the system from boot media you have made or the Fedora CD-ROM #1, and enter a special boot command at the boot prompt. The installation program looks for a kickstart file if the ks command line argument is passed to the kernel.
Other options to start a kickstart installation are as follows:
askmethod
Do not automatically use the CD-ROM as the install source if we detect a Fedora CD in your CD-ROM drive.
autostep
Make kickstart non-interactive.
debug
Start up pdb immediately.
dd
Use a driver disk.
dhcpclass=<class>
Sends a custom DHCP vendor class identifier. ISC's dhcpcd can inspect this value using "option vendor-class-identifier".
dns=<dns>
Comma separated list of nameservers to use for a network installation.
driverdisk
Same as 'dd'.
expert
Turns on special features:
  • allows partitioning of removable media
  • prompts for a driver disk
gateway=<gw>
Gateway to use for a network installation.
graphical
Force graphical install. Required to have ftp/http use GUI.
isa
Prompt user for ISA devices configuration.
ip=<ip>
IP to use for a network installation, use 'dhcp' for DHCP.
keymap=<keymap>
Keyboard layout to use. Valid values are those which can be used for the 'keyboard' kickstart command.
ks=nfs:<server>:/<path>
The installation program looks for the kickstart file on the NFS server <server>, as file <path>. The installation program uses DHCP to configure the Ethernet card. For example, if your NFS server is server.example.com and the kickstart file is in the NFS share /mydir/ks.cfg, the correct boot command would be ks=nfs:server.example.com:/mydir/ks.cfg.
ks=http://<server>/<path>
The installation program looks for the kickstart file on the HTTP server <server>, as file <path>. The installation program uses DHCP to configure the Ethernet card. For example, if your HTTP server is server.example.com and the kickstart file is in the HTTP directory /mydir/ks.cfg, the correct boot command would be ks=http://server.example.com/mydir/ks.cfg.
ks=floppy
The installation program looks for the file ks.cfg on a vfat or ext2 file system on the diskette in /dev/fd0.
ks=floppy:/<path>
The installation program looks for the kickstart file on the diskette in /dev/fd0, as file <path>.
ks=hd:<device>:/<file>
The installation program mounts the file system on <device> (which must be vfat or ext2), and look for the kickstart configuration file as <file> in that file system (for example, ks=hd:sda3:/mydir/ks.cfg).
ks=file:/<file>
The installation program tries to read the file <file> from the file system; no mounts are done. This is normally used if the kickstart file is already on the initrd image.
ks=cdrom:/<path>
The installation program looks for the kickstart file on CD-ROM, as file <path>.
ks
If ks is used alone, the installation program configures the Ethernet card to use DHCP. The kickstart file is read from the "bootServer" from the DHCP response as if it is an NFS server sharing the kickstart file. By default, the bootServer is the same as the DHCP server. The name of the kickstart file is one of the following:
  • If DHCP is specified and the boot file begins with a /, the boot file provided by DHCP is looked for on the NFS server.
  • If DHCP is specified and the boot file begins with something other than a /, the boot file provided by DHCP is looked for in the /kickstart directory on the NFS server.
  • If DHCP did not specify a boot file, then the installation program tries to read the file /kickstart/1.2.3.4-kickstart, where 1.2.3.4 is the numeric IP address of the machine being installed.
ksdevice=<device>
The installation program uses this network device to connect to the network. For example, consider a system connected to an NFS server through the eth1 device. To perform a kickstart installation on this system using a kickstart file from the NFS server, you would use the command ks=nfs:<server>:/<path> ksdevice=eth1 at the boot: prompt.
kssendmac
Adds HTTP headers to ks=http:// request that can be helpful for provisioning systems. Includes MAC address of all nics in CGI environment variables of the form: "X-RHN-Provisioning-MAC-0: eth0 01:23:45:67:89:ab".
lang=<lang>
Language to use for the installation. This should be a language which is valid to be used with the 'lang' kickstart command.
loglevel=<level>
Set the minimum level required for messages to be logged. Values for <level> are debug, info, warning, error, and critical. The default value is info.
lowres
Force GUI installer to run at 640x480.
mediacheck
Activates loader code to give user option of testing integrity of install source (if an ISO-based method).
method=cdrom
Do a CDROM based installation.
method=ftp://<path>
Use <path> for an FTP installation.
method=hd:<dev>:<path>
Use <path> on <dev> for a hard drive installation.
method=http://<path>
Use <path> for an HTTP installation.
method=nfs:<path>
Use <path> for an NFS installation.
netmask=<nm>
Netmask to use for a network installation.
nofallback
If GUI fails exit.
nofb
Do not load the VGA16 framebuffer required for doing text-mode installation in some languages.
nofirewire
Do not load support for firewire devices.
noipv6
Disable IPv6 networking during installation.
nokill
A debugging option that prevents anaconda from terminating all running programs when a fatal error occurs.
nomount
Don't automatically mount any installed Linux partitions in rescue mode.
nonet
Do not auto-probe network devices.
noparport
Do not attempt to load support for parallel ports.
nopass
Don't pass keyboard/mouse info to stage 2 installer, good for testing keyboard and mouse config screens in stage2 installer during network installs.
nopcmcia
Ignore PCMCIA controller in system.
noprobe
Do not attempt to detect hw, prompts user instead.
noshell
Do not put a shell on tty2 during install.
nostorage
Do not auto-probe storage devices (SCSI, IDE, RAID).
nousb
Do not load USB support (helps if install hangs early sometimes).
nousbstorage
Do not load usbstorage module in loader. May help with device ordering on SCSI systems.
rescue
Run rescue environment.
resolution=<mode>
Run installer in mode specified, '1024x768' for example.
serial
Turns on serial console support.
skipddc
Skips DDC probe of monitor, may help if it's hanging system.
syslog=<host>[:<port>]
Once installation is up and running, send log messages to the syslog process on <host>, and optionally, on port <port>. Requires the remote syslog process to accept connections (the -r option).
text
Force text mode install.

Important

If you select text mode for a kickstart installation, make sure that you specify choices for the partitioning, bootloader, and package selection options. These steps are automated in text mode, and anaconda cannot prompt you for missing information. If you do not provide choices for these options, anaconda will stop the installation process.
updates
Prompt for floppy containing updates (bug fixes).
updates=ftp://<path>
Image containing updates over FTP.
updates=http://<path>
Image containing updates over HTTP.
upgradeany
Don't require an /etc/redhat-release that matches the expected syntax to upgrade.
vnc
Enable vnc-based installation. You will need to connect to the machine using a vnc client application.
vncconnect=<host>[:<port>]
Once installation is up and running, connect to the vnc client named <host>, and optionally use port <port>.
Requires 'vnc' option to be specified as well.
vncpassword=<password>
Enable a password for the vnc connection. This will prevent someone from inadvertently connecting to the vnc-based installation.
Requires 'vnc' option to be specified as well.

Chapter 14. Kickstart Configurator

Kickstart Configurator allows you to create or modify a kickstart file using a graphical user interface, so that you do not have to remember the correct syntax of the file.
To use Kickstart Configurator, you must be running the X Window System. To start Kickstart Configurator, select Applications (the main menu on the panel) => System Tools => Kickstart, or type the command /usr/sbin/system-config-kickstart.
As you are creating a kickstart file, you can select File => Preview at any time to review your current selections.
To start with an existing kickstart file, select File => Open and select the existing file.

14.1. Basic Configuration

Basic Configuration
Basic Configuration
Figure 14.1. Basic Configuration

Choose the language to use during the installation and as the default language to be used after installation from the Default Language menu.
Select the system keyboard type from the Keyboard menu.
From the Time Zone menu, choose the time zone to use for the system. To configure the system to use UTC, select Use UTC clock.
Enter the desired root password for the system in the Root Password text entry box. Type the same password in the Confirm Password text box. The second field is to make sure you do not mistype the password and then realize you do not know what it is after you have completed the installation. To save the password as an encrypted password in the file, select Encrypt root password. If the encryption option is selected, when the file is saved, the plain text password that you typed is encrypted and written to the kickstart file. Do not type an already encrypted password and select to encrypt it. Because a kickstart file is a plain text file that can be easily read, it is recommended that an encrypted password be used.
Choosing Target Architecture specifies which specific hardware architecture distribution is used during installation.
Choosing Reboot system after installation reboots your system automatically after the installation is finished.
Kickstart installations are performed in graphical mode by default. To override this default and use text mode instead, select the Perform installation in text mode option.
You can perform a kickstart installation in interactive mode. This means that the installation program uses all the options pre-configured in the kickstart file, but it allows you to preview the options in each screen before continuing to the next screen. To continue to the next screen, click the Next button after you have approved the settings or change them before continuing the installation. To select this type of installation, select the Perform installation in interactive mode option.
Installation Method
Kickstart Installation Method
Figure 14.2. Installation Method

The Installation Method screen allows you to choose whether to perform a new installation or an upgrade. If you choose upgrade, the Partition Information and Package Selection options are disabled. They are not supported for kickstart upgrades.
Choose the type of kickstart installation or upgrade from the following options:

14.3. Boot Loader Options


Please note that this screen will be disabled if you have specified a target architecture other than x86 / x86_64.
GRUB is the default boot loader for Fedora on x86 / x86_64 architectures. If you do not want to install a boot loader, select Do not install a boot loader. If you choose not to install a boot loader, make sure you create a boot diskette or have another way to boot your system, such as a third-party boot loader.
You must choose where to install the boot loader (the Master Boot Record or the first sector of the /boot partition). Install the boot loader on the MBR if you plan to use it as your boot loader.
To pass any special parameters to the kernel to be used when the system boots, enter them in the Kernel parameters text field. For example, if you have an IDE CD-ROM Writer, you can tell the kernel to use the SCSI emulation driver that must be loaded before using cdrecord by configuring hdd=ide-scsi as a kernel parameter (where hdd is the CD-ROM device).
You can password protect the GRUB boot loader by configuring a GRUB password. Select Use GRUB password, and enter a password in the Password field. Type the same password in the Confirm Password text field. To save the password as an encrypted password in the file, select Encrypt GRUB password. If the encryption option is selected, when the file is saved, the plain text password that you typed is encrypted and written to the kickstart file. If the password you typed was already encrypted, unselect the encryption option.
If Upgrade an existing installation is selected on the Installation Method page, select Upgrade existing boot loader to upgrade the existing boot loader configuration, while preserving the old entries.
Partition Information
Kickstart Partition Information
Figure 14.4. Partition Information

Select whether or not to clear the Master Boot Record (MBR). Choose to remove all existing partitions, remove all existing Linux partitions, or preserve existing partitions.
To initialize the disk label to the default for the architecture of the system (for example, msdos for x86 and gpt for Itanium), select Initialize the disk label if you are installing on a brand new hard drive.

Note

Although anaconda and kickstart support Logical Volume Management (LVM), at present there is no mechanism for configuring this using the Kickstart Configurator.

14.4.1. Creating Partitions

To create a partition, click the Add button. The Partition Options window shown in Figure 14.5, “Creating Partitions” appears. Choose the mount point, file system type, and partition size for the new partition. Optionally, you can also choose from the following:
  • In the Additional Size Options section, choose to make the partition a fixed size, up to a chosen size, or fill the remaining space on the hard drive. If you selected swap as the file system type, you can select to have the installation program create the swap partition with the recommended size instead of specifying a size.
  • Force the partition to be created as a primary partition.
  • Create the partition on a specific hard drive. For example, to make the partition on the first IDE hard disk (/dev/hda), specify hda as the drive. Do not include /dev in the drive name.
  • Use an existing partition. For example, to make the partition on the first partition on the first IDE hard disk (/dev/hda1), specify hda1 as the partition. Do not include /dev in the partition name.
  • Format the partition as the chosen file system type.
Creating Partitions
Creating Partitions for Kickstart
Figure 14.5. Creating Partitions

To edit an existing partition, select the partition from the list and click the Edit button. The same Partition Options window appears as when you chose to add a partition as shown in Figure 14.5, “Creating Partitions”, except it reflects the values for the selected partition. Modify the partition options and click OK.
To delete an existing partition, select the partition from the list and click the Delete button.
The Firewall Configuration window is similar to the screen in the installation program and the Security Level Configuration Tool.
Firewall Configuration
Firewall Configuration for Kickstart
Figure 14.10. Firewall Configuration

If Disable firewall is selected, the system allows complete access to any active services and ports. No connections to the system are refused or denied.
Selecting Enable firewall configures the system to reject incoming connections that are not in response to outbound requests, such as DNS replies or DHCP requests. If access to services running on this machine is required, you can choose to allow specific services through the firewall.
Only devices configured in the Network Configuration section are listed as available Trusted devices. Connections from any devices selected in the list are accepted by the system. For example, if eth1 only receives connections from internal system, you might want to allow connections from it.
If a service is selected in the Trusted services list, connections for the service are accepted and processed by the system.
In the Other ports text field, list any additional ports that should be opened for remote access. Use the following format: port:protocol. For example, to allow IMAP access through the firewall, specify imap:tcp. Numeric ports can also be specified explicitly; to allow UDP packets on port 1234 through the firewall, enter 1234:udp. To specify multiple ports, separate them with commas.
X Configuration
X Configuration for Kickstart
Figure 14.11. X Configuration

Also select whether to start the Setup Agent the first time the system is rebooted. It is disabled by default, but the setting can be changed to enabled or enabled in reconfiguration mode. Reconfiguration mode enables the language, mouse, keyboard, root password, security level, time zone, and networking configuration options in addition to the default ones.

14.10. Pre-Installation Script

Pre-Installation Script
Pre-Installation Script for Kickstart
Figure 14.13. Pre-Installation Script

You can add commands to run on the system immediately after the kickstart file has been parsed and before the installation begins. If you have configured the network in the kickstart file, the network is enabled before this section is processed. To include a pre-installation script, type it in the text area.
To specify a scripting language to use to execute the script, select the Use an interpreter option and enter the interpreter in the text box beside it. For example, /usr/bin/python2.4 can be specified for a Python script. This option corresponds to using %pre --interpreter /usr/bin/python2.4 in your kickstart file.
Many of the commands that are available in the pre-installation environment are provided by a version of busybox called busybox-anaconda. Busybox-supplied commands do not provide all features, but supply only the most commonly used features. The following list of available commands include commands provided by busybox:
addgroup, adduser, adjtimex, ar, arping, ash, awk, basename, bbconfig, bunzip2, busybox, bzcat, cal, cat, catv, chattr, chgrp, chmod, chown, chroot, chvt, cksum, clear, cmp, comm, cp, cpio, crond, crontab, cut, date, dc, dd, deallocvt, delgroup, deluser, devfsd, df, diff, dirname, dmesg, dnsd, dos2unix, dpkg, dpkg-deb, du, dumpkmap, dumpleases, e2fsck, e2label, echo, ed, egrep, eject, env, ether-wake, expr, fakeidentd, false, fbset, fdflush, fdformat, fdisk, fgrep, find, findfs, fold, free, freeramdisk, fsck, fsck.ext2, fsck.ext3, fsck.ext4, fsck.minix, ftpget, ftpput, fuser, getopt, getty, grep, gunzip, gzip, hdparm, head, hexdump, hostid, hostname, httpd, hush, hwclock, id, ifconfig, ifdown, ifup, inetd, insmod, install, ip, ipaddr, ipcalc, ipcrm, ipcs, iplink, iproute, iptunnel, kill, killall, lash, last, length, less, linux32, linux64, ln, load_policy, loadfont, loadkmap, login, logname, losetup, ls, lsattr, lsmod, lzmacat, makedevs, md5sum, mdev, mesg, mkdir, mke2fs, mkfifo, mkfs.ext2, mkfs.ext3, mkfs.ext4, mkfs.minix, mknod, mkswap, mktemp, modprobe, more, mount, mountpoint, msh, mt, mv, nameif, nc, netstat, nice, nohup, nslookup, od, openvt, passwd, patch, pidof, ping, ping6, pipe_progress, pivot_root, printenv, printf, ps, pwd, rdate, readlink, readprofile, realpath, renice, reset, rm, rmdir, rmmod, route, rpm, rpm2cpio, run-parts, runlevel, rx, sed, seq, setarch, setconsole, setkeycodes, setlogcons, setsid, sh, sha1sum, sleep, sort, start-stop-daemon, stat, strings, stty, su, sulogin, sum, swapoff, swapon, switch_root, sync, sysctl, tail, tar, tee, telnet, telnetd, test, tftp, time, top, touch, tr, traceroute, true, tty, tune2fs, udhcpc, udhcpd, umount, uname, uncompress, uniq, unix2dos, unlzma, unzip, uptime, usleep, uudecode, uuencode, vconfig, vi, vlock, watch, watchdog, wc, wget, which, who, whoami, xargs, yes, zcat, zcip
For a description of any of these commands, run:
busybox command --help
In addition to the aforementioned commands, the following commands are provided in their full featured versions:
anaconda, bash, bzip2, jmacs, ftp, head, joe, kudzu-probe, list-harddrives, loadkeys, mtools, mbchk, mtools, mini-wm, mtools, jpico, pump, python, python2.4, raidstart, raidstop, rcp, rlogin, rsync, setxkbmap, sftp, shred, ssh, syslinux, syslogd, tac, termidx, vncconfig, vncpasswd, xkbcomp, Xorg, Xvnc, zcat

Warning

Do not include the %pre command. It is added for you.

Note

The pre-installation script is run after the source media is mounted and stage 2 of the bootloader has been loaded. For this reason it is not possible to change the source media in the pre-installation script.
Post-Installation Script
Post-Installation Script for Kickstart
Figure 14.14. Post-Installation Script

You can also add commands to execute on the system after the installation is completed. If the network is properly configured in the kickstart file, the network is enabled, and the script can include commands to access resources on the network. To include a post-installation script, type it in the text area.

Warning

Do not include the %post command. It is added for you.
For example, to change the message of the day for the newly installed system, add the following command to the %post section:
echo "Hackers will be punished!" > /etc/motd

14.11.1. Chroot Environment

To run the post-installation script outside of the chroot environment, click the checkbox next to this option on the top of the Post-Installation window. This is equivalent to using the --nochroot option in the %post section.
To make changes to the newly installed file system, within the post-installation section, but outside of the chroot environment, you must prepend the directory name with /mnt/sysimage/.
For example, if you select Run outside of the chroot environment, the previous example must be changed to the following:
echo "Hackers will be punished!" > /mnt/sysimage/etc/motd

14.11.2. Use an Interpreter

To specify a scripting language to use to execute the script, select the Use an interpreter option and enter the interpreter in the text box beside it. For example, /usr/bin/python2.2 can be specified for a Python script. This option corresponds to using %post --interpreter /usr/bin/python2.2 in your kickstart file.

Part IV. After installation

This part of the Fedora Installation Guide covers finalizing the installation, as well as some installation-related tasks that you might perform at some time in the future. These include:
  • using a Fedora installation disk to rescue a damaged system.
  • upgrading to a new version of Fedora.
  • removing Fedora from your computer.

Chapter 15. Firstboot

Firstboot launches the first time that you start a new Fedora system. Use Firstboot to configure the system for use before you log in.
Firstboot welcome screen
Firstboot welcome screen
Figure 15.1. Firstboot welcome screen

Select Forward to start the Firstboot.

Graphical Interface Required

Firstboot requires a graphical interface. If you did not install one, or if Fedora has trouble starting it, you may see a slightly different setup screen.

15.2. System User

Create a user account for yourself with this screen. Always use this account to log in to your Fedora system, rather than using the root account.
Firstboot create user screen
Firstboot create user screen
Figure 15.3. Firstboot create user screen

Enter a user name and your full name, and then enter your chosen password. Type your password once more in the Confirm Password box to ensure that it is correct. Refer to Section 7.17, “Set the Root Password” for guidelines on selecting a secure password.

Creating Extra User Accounts

To add additional user accounts to your system after the installation is complete, choose SystemAdministrationUsers & Groups.
To configure Fedora to use network services for authentication or user information, select Use Network Login....

15.3. Date and Time

If your system does not have Internet access or a network time server, manually set the date and time for your system on this screen. Otherwise, use NTP (Network Time Protocol) servers to maintain the accuracy of the clock. NTP provides time synchronization service to computers on the same network. The Internet contains many computers that offer public NTP services.

Select the Network Time Protocol tab to configure your system to use NTP servers instead.

Setting the Clock

To change these settings later, choose SystemAdministrationDate & Time.
To configure your system to use network time servers, select the Enable Network Time Protocol option. This option disables the settings on the Date and Time tab and enables the other settings on this screen.
Firstboot Network Time Protocol screen
Firstboot Network Time Protocol screen
Figure 15.5. Firstboot Network Time Protocol screen

By default, Fedora is configured to use three separate groups, or pools, of time servers. Time server pools create redundancy, so if one time server is unavailable, your system synchronizes with another server.
To use an additional time server, select Add, and type the DNS name of the server into the box. To remove a server or server pool from the list, select the name and click Delete.
If your machine is always connected to the Internet through a wired connection, select the Synchronize system clock before starting service option. This option may cause a short delay during startup but ensures accurate time on your system even if the clock is significantly wrong at boot time.

Laptops and NTP

Do not use this option with laptop computers that sometimes use wireless networks.
If the hardware clock in your computer is highly inaccurate, you may turn off your local time source entirely. To turn off the local time source, select Show advanced options and then deselect the Use Local Time Source option. If you turn off your local time source, the NTP servers take priority over the internal clock.
If you enable the Enable NTP Broadcast advanced option, Fedora attempts to automatically locate time servers on the network.
Firstboot hardware profile screen
Firstboot hardware profile screen
Figure 15.6. Firstboot hardware profile screen

To opt in to this important work, select Send Profile. If you choose not to submit any profile data, do not change the default. Select Finish to continue to the login screen.

Update Your System

To ensure the security of your system, run a package update after the installation completes. Chapter 16, Your Next Steps explains how to update your Fedora system.

Chapter 16. Your Next Steps

Fedora provides you with a complete operating system with a vast range of capabilities, supported by a large community.

16.1. Updating Your System

The Fedora Project releases updated software packages for Fedora throughout the support period of each version. Updated packages add new features, improve reliability, resolve bugs, or remove security vulnerabilities. To ensure the security of your system, update regularly, and as soon as possible after a security announcement is issued. Refer to Section 16.4, “Subscribing to Fedora Announcements and News” for information on the Fedora announcements services.
An update applet reminds you of updates when they are available. This applet is installed by default in Fedora. It checks for software updates from all configured repositories, and runs as a background service. It generates a notification message on the desktop if updates are found, and you can click the message to update your system's software.
To update your system with the latest packages manually, use Update System:

su -c 'yum update'
Refer to http://docs.fedoraproject.org/yum/ for more information on yum.

Network Connection Required

Ensure that your system has an active network connection before you run the Update Software tool, or the yum utility. The update process downloads information and packages from a network of servers.
If your Fedora system has a permanent network connection, you may choose to enable daily system updates. To enable automatic updates, follow the instructions on the webpage http://docs.fedoraproject.org/yum/sn-updating-your-system.html.

16.2. Finishing an Upgrade

System Updates Recommended

Once you have rebooted your system after performing an upgrade, you should also perform a manual system update. Consult Section 16.1, “Updating Your System” for more information.
If you chose to upgrade your system from a previous release rather than perform a fresh installation, you may want to examine the differences in the package set. Section 7.14.2, “Upgrading Using the Installer” advised you to create a package listing for your original system. You can now use that listing to determine how to bring your new system close to the original system state.
Most software repository configurations are stored in packages that end with the term release. Check the old package list for the repositories that were installed:
awk '{print $1}' ~/old-pkglist.txt | grep 'release$'
If necessary, retrieve and install these software repository packages from their original sources on the Internet. Follow the instructions at the originating site to install the repository configuration packages for use by yum and other software management tools on your Fedora system.
Then run the following commands to make a list of other missing software packages:
awk '{print $1}' ~/old-pkglist.txt | sort | uniq > ~/old-pkgnames.txt
rpm -qa --qf '%{NAME}\n' | sort | uniq > ~/new-pkgnames.txt
diff -u ~/old-pkgnames.txt ~/new-pkgnames.txt | grep '^-' | sed 's/^-//' > /tmp/pkgs-to-install.txt
Now use the file /tmp/pkgs-to-install.txt with the yum command to restore most or all of your old software:
su -c 'yum install `cat /tmp/pkgs-to-install.txt`'

Missing Software

Due to changes in package complements between Fedora releases, it is possible this method may not restore all the software on your system. You can use the routines above to again compare the software on your system, and remedy any problems you find.

16.3. Switching to a Graphical Login

If you installed using a text login and wish to switch to a graphical login, follow this procedure.
  1. Switch users to the root account:
    su -
    
    Provide the administrator password when prompted.
  2. If you have not already done so, install one of the graphical desktop environments. For instance, to install the GNOME desktop environment, use this command:
    yum groupinstall "GNOME Desktop Environment"
    
    This step may take some time as your Fedora system downloads and installs additional software. You may be asked to provide the installation media depending on your original installation source.
  3. Run the following command to edit the /etc/inittab file:
    nano /etc/inittab
    
  4. Find the line that includes the text initdefault. Change the numeral 3 to 5.
  5. Hit Ctrl+O to write the file to disk, and then hit Ctrl+X to exit the program.
  6. Type exit to logout of the administrator account.
If desired, you can reboot the system using the reboot command. Your system will restart and present a graphical login.
If you encounter any problems with the graphical login, consult one of the help sources listed in Section 1.2, “Getting Additional Help”.

16.4. Subscribing to Fedora Announcements and News

To receive information about package updates, subscribe to either the announcements mailing list, or the RSS feeds.
Fedora Project announcements mailing list
Fedora Project RSS feeds
The announcements mailing list also provides you with news on the Fedora Project, and the Fedora community.

Security Announcements

Announcements with the keyword [SECURITY] in the title identify package updates that resolve security vulnerabilities.

16.5. Finding Documentation and Support

Members of the Fedora community provide support through mailing lists, Web forums and Linux User Groups (LUGs) across the world.
The Web site for the formally endorsed forums is http://forums.fedoraforum.org/.
The following resources provide information on many aspects of Fedora:
Many other organizations and individuals also provide tutorials and HOWTOs for Fedora on their Web sites. You can locate information on any topic by using Google's Linux search site, located at http://www.google.com/linux.

16.6. Joining the Fedora Community

The Fedora Project is driven by the individuals that contribute to it. Community members provide support and documentation to other users, help to improve the software included in Fedora by testing, and develop new software alongside the programmers employed by Red Hat. The results of this work are available to all.
To make a difference, start here:

Chapter 17. Basic System Recovery

When things go wrong, there are ways to fix problems. However, these methods require that you understand the system well. This chapter describes how to boot into rescue mode, single-user mode, and emergency mode, where you can use your own knowledge to repair the system.

17.1. Common Problems

You might need to boot into one of these recovery modes for any of the following reasons:
  • You are unable to boot normally into Fedora (runlevel 3 or 5).
  • You are having hardware or software problems, and you want to get a few important files off of your system's hard drive.
  • You forgot the root password.
Rescue mode provides the ability to boot a small Fedora environment entirely from CD-ROM, or some other boot method, instead of the system's hard drive.
As the name implies, rescue mode is provided to rescue you from something. During normal operation, your Fedora system uses files located on your system's hard drive to do everything — run programs, store your files, and more.
However, there may be times when you are unable to get Fedora running completely enough to access files on your system's hard drive. Using rescue mode, you can access the files stored on your system's hard drive, even if you cannot actually run Fedora from that hard drive.
  • By booting the system from an installation boot CD-ROM or DVD.
  • By booting the system from other installation boot media, such as USB flash devices.
  • By booting the system from the Fedora CD-ROM #1 or DVD.
Once you have booted using one of the described methods, add the keyword rescue as a kernel parameter. For example, for an x86 system, type the following command at the installation boot prompt:
linux rescue
You are prompted to answer a few basic questions, including which language to use. It also prompts you to select where a valid rescue image is located. Select from Local CD-ROM, Hard Drive, NFS image, FTP, or HTTP. The location selected must contain a valid installation tree, and the installation tree must be for the same version of Fedora as the Fedora disk from which you booted. If you used a boot CD-ROM or other media to start rescue mode, the installation tree must be from the same tree from which the media was created. For more information about how to setup an installation tree on a hard drive, NFS server, FTP server, or HTTP server, refer to the earlier section of this guide.
If you select a rescue image that does not require a network connection, you are asked whether or not you want to establish a network connection. A network connection is useful if you need to backup files to a different computer or install some RPM packages from a shared network location, for example.
The following message is displayed:
The rescue environment will now attempt to find your Linux installation and mount it under the directory /mnt/sysimage. You can then make any changes required to your system. If you want to proceed with this step choose 'Continue'. You can also choose to mount your file systems read-only instead of read-write by choosing 'Read-only'. If for some reason this process fails you can choose 'Skip' and this step will be skipped and you will go directly to a command shell.
If you select Continue, it attempts to mount your file system under the directory /mnt/sysimage/. If it fails to mount a partition, it notifies you. If you select Read-Only, it attempts to mount your file system under the directory /mnt/sysimage/, but in read-only mode. If you select Skip, your file system is not mounted. Choose Skip if you think your file system is corrupted.
Once you have your system in rescue mode, a prompt appears on VC (virtual console) 1 and VC 2 (use the Ctrl-Alt-F1 key combination to access VC 1 and Ctrl-Alt-F2 to access VC 2):
sh-3.00b#
If you selected Continue to mount your partitions automatically and they were mounted successfully, you are in single-user mode.
Even if your file system is mounted, the default root partition while in rescue mode is a temporary root partition, not the root partition of the file system used during normal user mode (runlevel 3 or 5). If you selected to mount your file system and it mounted successfully, you can change the root partition of the rescue mode environment to the root partition of your file system by executing the following command:
chroot /mnt/sysimage
This is useful if you need to run commands such as rpm that require your root partition to be mounted as /. To exit the chroot environment, type exit to return to the prompt.
If you selected Skip, you can still try to mount a partition or LVM2 logical volume manually inside rescue mode by creating a directory such as /foo, and typing the following command:
mount -t ext4 /dev/mapper/VolGroup00-LogVol02 /foo
In the above command, /foo is a directory that you have created and /dev/mapper/VolGroup00-LogVol02 is the LVM2 logical volume you want to mount. If the partition is of type ext2 or ext3 replace ext4 with ext2 or ext3 respectively.
If you do not know the names of all physical partitions, use the following command to list them:
fdisk -l
If you do not know the names of all LVM2 physical volumes, volume groups, or logical volumes, use the following commands to list them:
pvdisplay
vgdisplay
lvdisplay
From the prompt, you can run many useful commands, such as:
  • ssh, scp, and ping if the network is started
  • dump and restore for users with tape drives
  • parted and fdisk for managing partitions
  • rpm for installing or upgrading software
  • joe for editing configuration files

    Note

    If you try to start other popular editors such as emacs, pico, or vi, the joe editor is started.


[4] Refer to the earlier sections of this guide for more details.

Chapter 18. Upgrading Your Current System

This chapter explains the various methods available for upgrading your Fedora system.

18.1. Determining Whether to Upgrade or Re-Install

While upgrading from Fedora 10 is supported, you are more likely to have a consistent experience by backing up your data and then installing this release of Fedora 11 over your previous Fedora installation.
To upgrade from Fedora 10 you should bring your system up to date before performing the upgrade.

Important

It is not possible to upgrade directly from Fedora 9 to Fedora 11. To upgrade Fedora 9 to Fedora 11, upgrade to Fedora 10 first.
This recommended reinstallation method helps to ensure the best system stability possible.
If you currently use Fedora 10, you can perform a traditional, installation program-based upgrade.
However, before you chose to upgrade your system, there are a few things you should keep in mind:
  • Individual package configuration files may or may not work after performing an upgrade due to changes in various configuration file formats or layouts.
  • If you have one of Red Hat's layered products (such as the Cluster Suite) installed, it may need to be manually upgraded after the upgrade has been completed.
  • Third party or ISV applications may not work correctly following the upgrade.
Upgrading your system installs updated versions of the packages which are currently installed on your system.
The upgrade process preserves existing configuration files by renaming them with an .rpmsave extension (for example, sendmail.cf.rpmsave). The upgrade process also creates a log of its actions in /root/upgrade.log.

Warning

As software evolves, configuration file formats can change. It is very important to carefully compare your original configuration files to the new files before integrating your changes.

Note

It is always a good idea to back up any data that you have on your systems. For example, if you are upgrading or creating a dual-boot system, you should back up any data you wish to keep on your hard drive(s). Mistakes do happen and can result in the loss of all of your data.
Some upgraded packages may require the installation of other packages for proper operation. If you choose to customize your packages to upgrade, you may be required to resolve dependency problems. Otherwise, the upgrade procedure takes care of these dependencies, but it may need to install additional packages which are not on your system.
Depending on how you have partitioned your system, the upgrade program may prompt you to add an additional swap file. If the upgrade program does not detect a swap file that equals twice your RAM, it asks you if you would like to add a new swap file. If your system does not have a lot of RAM (less than 256 MB), it is recommended that you add this swap file.

Chapter 19. Removing Fedora

We respect your freedom to choose an operating system for your computer. This section explains how to uninstall Fedora.

These instructions may destroy data!

If you have data from Fedora that you want to keep, back it up before you proceed. Write your data to CD, DVD, external hard disk, or other storage device.
As a precaution, also back up data from any other operating systems that are installed on the same computer. Mistakes do happen and can result in the loss of all your data.
If you back up data from Fedora to be used later in another operating system, make sure that the storage medium or device is readable by that other operating system. For example, without extra third-party software, Microsoft Windows cannot read an external hard drive that you have formatted with Fedora to use the ext2, ext3, or ext4 file system.
To uninstall Fedora from your x86-based system, you must remove the Fedora boot loader information from your master boot record (MBR) and remove any partitions that contain the operating system. The method for removing Fedora from your computer varies, depending on whether Fedora is the only operating system installed on the computer, or whether the computer is configured to dual-boot Fedora and another operating system.

Legacy versions of Microsoft operating systems

Fdisk, the disk partitioning tool provided with MS-DOS and Microsoft Windows, is unable to remove the file systems used by Fedora. MS-DOS and versions of Windows prior to Windows XP (except for Windows 2000) have no other means of removing or modifying partitions. Refer to Section 19.3, “Replacing Fedora with MS-DOS or legacy versions of Microsoft Windows” for alternative removal methods for use with MS-DOS and these versions of Windows.

19.1. Fedora is the only operating system on the computer

If Fedora is the only operating system on your computer, use the installation media for the replacement operating system to remove Fedora. Examples of installation media include the Windows XP installation CD, Windows Vista installation DVD, Mac OS X installation CDs or DVD, or the installation CD, CDs, or DVD of another Linux distribution.
Note that some manufacturers of factory-built computers pre-installed with Microsoft Windows do not supply the Windows installation CD or DVD with the computer. The manufacturer may instead have supplied their own "system restore disk", or have included software with the computer that allowed you to create your own "system restore disk" when you first started the computer. In some cases, the system restore software is stored on a separate partition on the system's hard drive. If you cannot identify the installation media for an operating system that was pre-installed on your computer, consult the documentation supplied with the machine, or contact the manufacturer.
When you have located the installation media for your chosen operating system:
  1. Back up any data that you want to keep.
  2. Shut down the computer.
  3. Boot your computer with the installation disk for the replacement operating system.
  4. Follow the prompts presented during the installation process. Windows, OS X, and most Linux installation disks allow you to manually partition your hard drive during the installation process, or will offer you the option to remove all partitions and start with a fresh partition scheme. At this point, remove any existing partitions that the installation software detects or allow the installer to remove the partitions automatically. "System restore" media for computers pre-installed with Microsoft Windows might create a default partition layout automatically without input from you.

    Warning

    If your computer has system restore software stored on a partition on a hard drive, take care when removing partitions while installing an operating system from other media. Under these circumstances, you could destroy the partition holding the system restore software.

19.2. Your computer dual-boots Fedora and another operating system

If your computer is configured to dual-boot Fedora and another operating system, removing Fedora without removing the partitions containing the other operating system and its data is more complicated. Specific instructions for a number of operating systems are set out below. To keep neither Fedora nor the other operating system, follow the steps described for a computer with only Fedora installed: Section 19.1, “Fedora is the only operating system on the computer”

19.2.1. Your computer dual-boots Fedora and a Microsoft Windows operating system

19.2.1.1. Windows 2000, Windows Server 2000, Windows XP, and Windows Server 2003

Warning

Once you commence this process, your computer may be left in an unbootable state until you complete the entire set of instructions. Carefully read the steps below before beginning the removal process. Consider opening these instructions on another computer or printing them so that you have access to them at all times during the process.
This procedure relies on the Windows Recovery Console that loads from the Windows installation disk, so you will not be able to complete the procedure without access to this disk. If you start this procedure and do not complete it, you could leave your computer in a condition where you cannot boot it. The "system restore disk" supplied with some factory-built computers that are sold with Windows pre-installed on them might not include the Windows Recovery Console.
During the process outlined in these instructions, the Windows Recovery Console will prompt you for the Administrator password for your Windows system. Do not follow these instructions unless you know the Administrator password for your system or are certain that an Administrator password has never been created, even by the computer manufacturer.
  1. Remove the Fedora partitions
    1. Boot your computer into your Microsoft Windows environment.
    2. Click Start>Run..., type diskmgmt.msc and press Enter. The Disk Management tool opens.
      The tool displays a graphical representation of your disk, with bars representing each partition. The first partition is usually labeled NTFS and corresponds to your C: drive. At least two Fedora partitions will be visible. Windows will not display a file system type for these partitions, but may allocate drive letters to some of them.
    3. Right-click on one of the Fedora partitions, then click Delete Partition and click Yes to confirm the deletion. Repeat this process for the other Fedora partitions on your system. As you delete partitions, Windows labels the space on the hard drive previously occupied by those partitions as unallocated.
  2. Enable Windows to use the space on your hard drive vacated by Fedora (optional)

    Note

    This step is not required to remove Fedora from your computer. However, if you skip this step, you will leave part of your hard drive's storage capacity unusable by Windows. Depending on your configuration, this might be a a significant portion of the storage capacity of the drive.
    Decide whether to extend an existing Windows partition to use the extra space, or create a new Windows partition in that space. If you create new a Windows partition, Windows will allocate a new drive letter to it and will interact with it as if it is a separate hard drive.
    Extending an existing Windows partition

    Note

    The diskpart tool used in this step is installed as part of the Windows XP and Windows 2003 operating systems. If you are performing this step on a computer running Windows 2000 or Windows Server 2000, you can download a version of diskpart for your operating system from the Microsoft website.
    1. Click Start>Run..., type diskpart and press Enter. A command window appears.
    2. Type list volume and press Enter. Diskpart displays a list of the partitions on your system with a volume number, its drive letter, volume label, filesystem type, and size. Identify the Windows partition that you would like to use to occupy the space vacated on your hard drive by Fedora and take note of its volume number (for example, your Windows C: drive might be "Volume 0").
    3. Type select volume N (where N is the volume number for the Windows partition that you want to extend) and press Enter. Now type extend and press Enter. Diskpart now extends your chosen partition to fill the remaining space on your hard drive. It will notify you when the operation is complete.
    Adding a new Windows partition
    1. In the the Disk Management window, right-click on disk space that Windows labels as unallocated and select New Partition from the menu. The New Partition Wizard starts.
    2. Follow the prompts presented by the New Partition Wizard. If you accept the default options, the tool will create a new partition that fills all available space on the hard drive, assigns it the next available drive letter, and formats it with the NTFS file system.
  3. Restore the Windows bootloader
    1. Insert the Windows installation disk and restart your computer. As your computer starts, the following message will appear on the screen for a few seconds:
      Press any key to boot from CD
      
      Press any key while the message is still showing and the Windows installation software will load.
    2. When the Welcome to Setup screen appears, you can start the Windows Recovery Console. The procedure is slightly different on different versions of Windows:
      • On Windows 2000 and Windows Server 2000, press the R key, then the C key.
      • On Windows XP and Windows Server 2003, press the R key.
    3. The Windows Recovery Console scans your hard drives for Windows installations, and assigns a number to each one. It displays a list of Windows installations and prompts you to select one. Type the number corresponding to the Windows installation that you want to restore.
    4. The Windows Recovery Console prompts you for the Administrator password for your Windows installation. Type the Administrator password and press the Enter key. If there is no administrator password for this system, press only the Enter key.
    5. At the prompt, type the command fixmbr and press the Enter. The fixmbr tool now restores the Master Boot Record for the system.
    6. When the prompt reappears, type exit and press the Enter key.
    7. Your computer will restart and boot your Windows operating system.

19.2.1.2. Windows Vista and Windows Server 2008

Warning

Once you commence this process, your computer may be left in an unbootable state until you complete the entire set of instructions. Carefully read the steps below before beginning the removal process. Consider opening these instructions on another computer or printing them so that you have access to them at all times during the process.
This procedure relies on the Windows Recovery Environment that loads from the Windows installation disk and you will not be able to complete the procedure without access to this disk. If you start this procedure and do not complete it, you could leave your computer in a condition where you cannot boot it. The "system restore disk" supplied with some factory-built computers that are sold with Windows pre-installed on them might not include the Windows Recovery Environment.
  1. Remove the Fedora partitions
    1. Boot your computer into your Microsoft Windows environment.
    2. Click Start then type diskmgmt.msc into the Start Search box and press Enter. The Disk Management tool opens.
      The tool displays a graphical representation of your disk, with bars representing each partition. The first partition is usually labeled NTFS and corresponds to your C: drive. At least two Fedora partitions will be visible. Windows will not display a file system type for these partitions, but may allocate drive letters to some of them.
    3. Right-click on one of the Fedora partitions, then click Delete Partition and click Yes to confirm the deletion. Repeat this process for the other Fedora partitions on your system. As you delete partitions, Windows labels the space on the hard drive previously occupied by those partitions as unallocated.
  2. Enable Windows to use the space on your hard drive vacated by Fedora (optional)

    Note

    This step is not required to remove Fedora from your computer. However, if you skip this step, you will leave part of your hard drive's storage capacity unusable by Windows. Depending on your configuration, this might be a a significant portion of the storage capacity of the drive.
    Decide whether to extend an existing Windows partition to use the extra space, or create a new Windows partition in that space. If you create new a Windows partition, Windows will allocate a new drive letter to it and will interact with it as if it is a separate hard drive.
    Extending an existing Windows partition
    1. In the Disk Management window, right-click on the Windows partition that you want to extend and select Extend Volume from the menu. The Extend Volume Wizard opens.
    2. Follow the prompts presented by the Extend Volume Wizard. If you accept the defaults that it offers you, the tool will extend the selected volume to fill all available space on the hard drive.
    Adding a new Windows partition
    1. In the Disk Management window, right-click on disk space that Windows labels as unallocated and select New Simple Volume from the menu. The New Simple Volume Wizard starts.
    2. Follow the prompts presented by the New Simple Volume Wizard. If you accept the default options, the tool will create a new partition that fills all available space on the hard drive, assigns it the next available drive letter, and formats it with the NTFS file system.
  3. Restore the Windows bootloader
    1. Insert the Windows installation disk and restart your computer. As your computer starts, the following message will appear on the screen for a few seconds:
      Press any key to boot from CD or DVD
      
      Press any key while the message is still showing and the Windows installation software will load.
    2. In the Install Windows dialog, select a language, time and currency format, and keyboard type. Click Next
    3. Click Repair your computer.
    4. The Windows Recovery Environment (WRE) shows you the Windows installations that it can detect on your system. Select the installation that you want to restore, then click Next.
    5. Click Command prompt. A command window will open.
    6. Type bootrec /fixmbr and press Enter.
    7. When the prompt reappears, close the command window, then click Restart.
    8. Your computer will restart and boot your Windows operating system.

19.2.2. Your computer dual-boots Fedora and Mac OS X

The procedure to remove Fedora from a system that dual-boots Fedora and Mac OS X varies depending on whether you have installed Boot Camp on your computer:
You are not using Boot Camp on your computer
  1. Open the Disk Utility in /Applications/Utilities.
  2. Select the entry on the left for the disk volume containing Fedora.
  3. Click the Partition tab on the right side of the dialog.
  4. Select the Fedora partitions and click the minus button below the partition layout diagram.
  5. Resize your OS X partition to include the newly freed space.
You are using Boot Camp on your computer
  1. Open the Boot Camp Assistant in /Applications/Utilities.
  2. Select Create or remove a Windows partition and click Next.
  3. If your computer has a single internal disk, click Restore.
  4. If your computer has multiple internal disks, select the Linux disk, and then select Restore to a single Mac OS partition. Click Continue.

19.2.3. Your computer dual-boots Fedora and a different Linux distribution

Note

Because of the differences between the many different Linux distributions, these instructions are a general guide only. Specific details will vary according to your chosen distribution and the configuration of your particular computer. This example uses GParted as a partition editor and gedit as a text editor, but many other tools are available to perform these tasks. To follow these instructions exactly as written, install GParted and gedit.
  1. Remove Fedora partitions
    1. Boot the Linux version that you want to keep on your computer.
    2. Open GParted, either from a desktop menu or by typing gparted at the command line and pressing Enter.
    3. GParted displays the partitions that it detects on your computer, both as a graph and as a table.
      Right-click the Fedora partitions, then select Delete.
  2. Remove Fedora entries from your bootloader

    Example only

    These instructions assume that your system uses the GRUB bootloader. If you use a different bootloader (such as LILO) consult the documentation for that software to identify and remove Fedora entries from its list of boot targets and to ensure that your default operating system is correctly specified.
    1. At the command line, type su - and press Enter. When the system prompts you for the root password, type the password and press Enter.
    2. Type gedit /boot/grub/grub.conf and press Enter. This opens the grub.conf file in the gedit text editor.
    3. A typical Fedora entry in the grub.conf file consists of four lines:
      title Fedora (2.6.27.19-170.2.35.fc10.i686)
      root (hd0,1)
      kernel /vmlinuz-2.6.27.19-170.2.35.fc10.i686 ro root=UUID=04a07c13-e6bf-6d5a-b207-002689545705 rhgb quiet
      initrd /initrd-2.6.27.19-170.2.35.fc10.i686.img
      Example 19.1. Example Fedora entry in grub.conf

      Depending on the configuration of your system, there may be multiple Fedora entries in grub.conf, each corresponding to a different version of the Linux kernel. Delete each of the Fedora entries from the file.
    4. Grub.conf contains a line that specifies the default operating system to boot, in the format default=N where N is a number equal to or greater than 0. If N is set to 0, GRUB will boot the first operating system in the list. If N is set to 1, it will boot the second operating system, and so forth.
      Identify the entry for the operating system that you want GRUB to boot by default and note its place in the order within the list.
      Make sure that the default= line contains the number one below the number of your chosen default operating system in the list.
      Save the updated grub.conf file and close gedit
  3. Make space available to your operating system

    Note

    This step is not required to remove Fedora from your computer. However, if you skip this step, you will leave part of your hard drive's storage capacity unusable by your other Linux operating system. Depending on your configuration, this might be a a significant portion of the storage capacity of the drive.

    Note

    To carry out this step, you require live media for a Linux distribution, for example, the Fedora Live CD or the Knoppix DVD.
    The method to make the space freed by removing the Fedora partitions available to your other Linux operating system differs, depending on whether your chosen operating system is installed on disk partitions configured to use Logical Volume Management (LVM) or not.
    • If you do not use LVM
      1. Boot your computer from Linux live media, and install gparted if it is not already present.
      2. Open GParted, either from a desktop menu or by typing gparted at the command line and pressing Enter.
      3. GParted displays the partitions on your system both as a graph and as a table. Click on the partition that you want to extend to use the space freed by removing Fedora, and click the Resize/Move button.
      4. A new dialog opens, allowing you to specify a new size for the partition by entering it as numbers, or by dragging the sides of the graphical representation of the partition so that it fills the available space. Click the Resize/Move button in this dialog to confirm your choice.
      5. Back in the main GParted window, click Apply. Take note of the name of the partition that you just resized, for example, /dev/sda3.
      6. When GParted finishes resizing the partition, type e2fsck partition at a command line and press Enter, where partition is the partition that you just resized. For example, if you just resized /dev/sda3, you would type e2fsck /dev/sda3.
        Linux now checks the file system of the newly-resized partition.
      7. When the file system check finishes, type resize2fs partition at a command line and press Enter, where partition is the partition that you just resized. For example, if you just resized /dev/sda3, you would type resize2fs /dev/sda3.
        Linux now resizes your file system to fill the newly-resized partition.
      8. Restart your computer. The extra space is now available to your Linux installation.
    • If you use LVM
      1. Boot your computer from Linux live media and install gparted and lvm2 if they are not already present.
      2. Create a new partition in the free space on the disk
        1. Open GParted, either from a desktop menu or by typing gparted at the command line and pressing Enter.
        2. GParted displays the partitions on your system both as a graph and as a table. The space freed by removing Fedora is labeled unallocated. Right-click on the unallocated space and select New. Accept the defaults and GParted will create a new partition that fills the space available on the drive.
        3. Click Apply. GParted writes the changes to your hard drive. Take note of the name of the partition that you just created, and the name of the device that holds the partition. For example, you may have created /dev/sda3 on device /dev/sda.
      3. Change the partition type identifier
        1. Fdisk is a partitioning tool capable of preparing partitions for LVM. At a command line, type fdisk device and press Enter, where device is the name of the device on which you just created a partition. For example, fdisk /dev/sda.
        2. At the prompt Command (m for help):, press T and Enter to use fdisk to change a partition type.
        3. At the prompt Partition number (1-4):, type the number of the partition that you just created. For example, if you just created partition /dev/sda3, type the number 3 and press Enter. This identifies the partition whose type fdisk will change.
        4. At the prompt Hex code (type L to list codes):, type the code 8e and press Enter. This is the code for a Linux LVM partition.
        5. At the prompt Command (m for help):, press W and Enter. Fdisk writes the new type code to the partition and exits.
      4. Expand the volume group
        1. At the command prompt, type lvm and press Enter to start the lvm2 tool.
        2. At the lvm> prompt, type pvcreate partition and press Enter, where partition is the partition that you recently created. For example, pvcreate /dev/sda3. This creates /dev/sda3 as a physical volume in LVM.
        3. At the lvm> prompt, type vgextend VolumeGroup partition and press Enter, where VolumeGroup is the LVM volume group on which Linux is installed and partition is the partition that you recently created. For example, if Linux is installed on /dev/VolumeGroup00, you would type vgextend /dev/VolumeGroup00 /dev/sda3 to extend that volume group to include the physical volume at /dev/sda3.
        4. At the lvm> prompt, type lvextend -l +100%FREE LogVol and press Enter, where LogVol is the logical volume that contains your Linux filesystem. For example, to extend LogVol00 to fill the newly-available space in its volume group, VolGroup00, type lvextend -l +100%FREE /dev/VolGroup00/LogVol00.
        5. At the lvm> prompt, type exit and press Enter to exit lvm2
      5. Type e2fsck LogVol at the command line and press Enter, where LogVol is the logical volume that you just resized. For example, if you just resized /dev/VolumeGroup00/LogVol00, you would type e2fsck /dev/VolumeGroup00/LogVol00.
        Linux now checks the file system of the newly-resized logical volume.
      6. When the file system check finishes, type resize2fs LogVol at a command line and press Enter, where LogVol is the partition that you just resized. For example, if you just resized /dev/VolumeGroup00/LogVol00, you would type resize2fs /dev/VolumeGroup00/LogVol00.
        Linux now resizes your file system to fill the newly-resized logical volume.
      7. Restart your computer. The extra space is now available to your Linux installation.

19.3. Replacing Fedora with MS-DOS or legacy versions of Microsoft Windows

In DOS and Windows, use the Windows fdisk utility to create a new MBR with the undocumented flag /mbr. This ONLY rewrites the MBR to boot the primary DOS partition. The command should look like the following:
fdisk /mbr
If you need to remove Linux from a hard drive and have attempted to do this with the default DOS (Windows) fdisk, you will experience the Partitions exist but they do not exist problem. The best way to remove non-DOS partitions is with a tool that understands partitions other than DOS.
To begin, insert the Fedora CD #1 and boot your system. Once you have booted off the CD, a boot prompt appears. At the boot prompt, type: linux rescue. This starts the rescue mode program.
You are prompted for your keyboard and language requirements. Enter these values as you would during the installation of Fedora.
Next, a screen appears telling you that the program attempts to find a Fedora install to rescue. Select Skip on this screen.
After selecting Skip, you are given a command prompt where you can access the partitions you would like to remove.
First, type the command list-harddrives. This command lists all hard drives on your system that are recognizable by the installation program, as well as their sizes in megabytes.

Warning

Be careful to remove only the necessary Fedora partitions. Removing other partitions could result in data loss or a corrupted system environment.
To remove partitions, use the partitioning utility parted. Start parted, where /dev/hda is the device on which to remove the partition:
parted /dev/hda
Using the print command, view the current partition table to determine the minor number of the partition to remove:
print
The print command also displays the partition's type (such as linux-swap, ext2, ext3, ext4 and so on). Knowing the type of the partition helps you in determining whether to remove the partition.
Remove the partition with the command rm. For example, to remove the partition with minor number 3:
rm 3

Important

The changes start taking place as soon as you press [Enter], so review the command before committing to it.
After removing the partition, use the print command to confirm that it is removed from the partition table.
Once you have removed the Linux partitions and made all of the changes you need to make, type quit to quit parted.
After quitting parted, type exit at the boot prompt to exit rescue mode and reboot your system, instead of continuing with the installation. The system should reboot automatically. If it does not, you can reboot your computer using Control+Alt+Delete .

Part V. Technical appendixes

The appendixes in this section do not contain instructions that tell you how to install Fedora. Instead, they provide technical background that you might find helpful to understand the options that Fedora offers you at various points in the installation process.

Table of Contents

A. An Introduction to Disk Partitions
A.1. Hard Disk Basic Concepts
A.1.1. It is Not What You Write, it is How You Write It
A.1.2. Partitions: Turning One Drive Into Many
A.1.3. Partitions within Partitions — An Overview of Extended Partitions
A.1.4. Making Room For Fedora
A.1.5. Partition Naming Scheme
A.1.6. Disk Partitions and Other Operating Systems
A.1.7. Disk Partitions and Mount Points
A.1.8. How Many Partitions?
B. ISCSI disks
B.1. iSCSI disks in anaconda
B.2. iSCSI disks during start up
C. Disk Encryption Guide
C.1. What is block device encryption?
C.2. Encrypting block devices using dm-crypt/LUKS
C.2.1. Overview of LUKS
C.2.2. How will I access the encrypted devices after installation? (System Startup)
C.2.3. Choosing a Good Passphrase
C.3. Creating Encrypted Block Devices in Anaconda
C.3.1. What Kinds of Block Devices Can Be Encrypted?
C.3.2. Limitations of Anaconda's Block Device Encryption Support
C.4. Creating Encrypted Block Devices on the Installed System After Installation
C.4.1. Create the block devices
C.4.2. Optional: Fill the device with random data
C.4.3. Format the device as a dm-crypt/LUKS encrypted device
C.4.4. Create a mapping to allow access to the device's decrypted contents
C.4.5. Create filesystems on the mapped device, or continue to build complex storage structures using the mapped device
C.4.6. Add the mapping information to /etc/crypttab
C.4.7. Add an entry to /etc/fstab
C.5. Common Post-Installation Tasks
C.5.1. Set a randomly generated key as an additional way to access an encrypted block device
C.5.2. Add a new passphrase to an existing device
C.5.3. Remove a passphrase or key from a device
D. Understanding LVM
E. The GRUB Boot Loader
E.1. GRUB
E.1.1. GRUB and the x86 Boot Process
E.1.2. Features of GRUB
E.2. Installing GRUB
E.3. GRUB Terminology
E.3.1. Device Names
E.3.2. File Names and Blocklists
E.3.3. The Root File System and GRUB
E.4. GRUB Interfaces
E.4.1. Interfaces Load Order
E.5. GRUB Commands
E.6. GRUB Menu Configuration File
E.6.1. Configuration File Structure
E.6.2. Configuration File Directives
E.7. Changing Runlevels at Boot Time
E.8. Additional Resources
E.8.1. Installed Documentation
E.8.2. Useful Websites
E.8.3. Related Books
F. Boot Process, Init, and Shutdown
F.1. The Boot Process
F.2. A Detailed Look at the Boot Process
F.2.1. The BIOS
F.2.2. The Boot Loader
F.2.3. The Kernel
F.2.4. The /sbin/init Program
F.3. Running Additional Programs at Boot Time
F.4. SysV Init Runlevels
F.4.1. Runlevels
F.4.2. Runlevel Utilities
F.5. Shutting Down
G. Other Technical Documentation

An Introduction to Disk Partitions

Note

This appendix is not necessarily applicable to non-x86-based architectures. However, the general concepts mentioned here may apply.
This appendix is not necessarily applicable to non-x86-based architectures. However, the general concepts mentioned here may apply.
If you are reasonably comfortable with disk partitions, you could skip ahead to Section A.1.4, “Making Room For Fedora”, for more information on the process of freeing up disk space to prepare for a Fedora installation. This section also discusses the partition naming scheme used by Linux systems, sharing disk space with other operating systems, and related topics.

A.1. Hard Disk Basic Concepts

Hard disks perform a very simple function — they store data and reliably retrieve it on command.
An Unused Disk Drive
Image of an unused disk drive.
Figure A.1. An Unused Disk Drive

Not much to look at, is it? But if we are talking about disk drives on a basic level, it is adequate. Say that we would like to store some data on this drive. As things stand now, it will not work. There is something we need to do first.

A.1.1. It is Not What You Write, it is How You Write It

Experienced computer users probably got this one on the first try. We need to format the drive. Formatting (usually known as "making a file system") writes information to the drive, creating order out of the empty space in an unformatted drive.
Disk Drive with a File System
Image of a formatted disk drive.
Figure A.2. Disk Drive with a File System

As Figure A.2, “Disk Drive with a File System”, implies, the order imposed by a file system involves some trade-offs:
  • A small percentage of the drive's available space is used to store file system-related data and can be considered as overhead.
  • A file system splits the remaining space into small, consistently-sized segments. For Linux, these segments are known as blocks. [5]
Given that file systems make things like directories and files possible, these trade-offs are usually seen as a small price to pay.
It is also worth noting that there is no single, universal file system. As Figure A.3, “Disk Drive with a Different File System”, shows, a disk drive may have one of many different file systems written on it. As you might guess, different file systems tend to be incompatible; that is, an operating system that supports one file system (or a handful of related file system types) may not support another. This last statement is not a hard-and-fast rule, however. For example, Fedora supports a wide variety of file systems (including many commonly used by other operating systems), making data interchange between different file systems easy.
Disk Drive with a Different File System
Image of a disk drive with a different file system.
Figure A.3. Disk Drive with a Different File System

Of course, writing a file system to disk is only the beginning. The goal of this process is to actually store and retrieve data. Let us take a look at our drive after some files have been written to it.
Disk Drive with Data Written to It
Image of a disk drive with data written to it.
Figure A.4. Disk Drive with Data Written to It

As Figure A.4, “Disk Drive with Data Written to It”, shows, some of the previously-empty blocks are now holding data. However, by just looking at this picture, we cannot determine exactly how many files reside on this drive. There may only be one file or many, as all files use at least one block and some files use multiple blocks. Another important point to note is that the used blocks do not have to form a contiguous region; used and unused blocks may be interspersed. This is known as fragmentation. Fragmentation can play a part when attempting to resize an existing partition.
As with most computer-related technologies, disk drives changed over time after their introduction. In particular, they got bigger. Not larger in physical size, but bigger in their capacity to store information. And, this additional capacity drove a fundamental change in the way disk drives were used.

A.1.2. Partitions: Turning One Drive Into Many

As disk drive capacities soared, some people began to wonder if having all of that formatted space in one big chunk was such a great idea. This line of thinking was driven by several issues, some philosophical, some technical. On the philosophical side, above a certain size, it seemed that the additional space provided by a larger drive created more clutter. On the technical side, some file systems were never designed to support anything above a certain capacity. Or the file systems could support larger drives with a greater capacity, but the overhead imposed by the file system to track files became excessive.
The solution to this problem was to divide disks into partitions. Each partition can be accessed as if it was a separate disk. This is done through the addition of a partition table.

Note

While the diagrams in this chapter show the partition table as being separate from the actual disk drive, this is not entirely accurate. In reality, the partition table is stored at the very start of the disk, before any file system or user data. But for clarity, they are separate in our diagrams.
Disk Drive with Partition Table
Image of an unused disk drive with a partition table.
Figure A.5. Disk Drive with Partition Table

As Figure A.5, “Disk Drive with Partition Table” shows, the partition table is divided into four sections or four primary partitions. A primary partition is a partition on a hard drive that can contain only one logical drive (or section). Each section can hold the information necessary to define a single partition, meaning that the partition table can define no more than four partitions.
Each partition table entry contains several important characteristics of the partition:
  • The points on the disk where the partition starts and ends
  • Whether the partition is "active"
  • The partition's type
Let us take a closer look at each of these characteristics. The starting and ending points actually define the partition's size and location on the disk. The "active" flag is used by some operating systems' boot loaders. In other words, the operating system in the partition that is marked "active" is booted.
The partition's type can be a bit confusing. The type is a number that identifies the partition's anticipated usage. If that statement sounds a bit vague, that is because the meaning of the partition type is a bit vague. Some operating systems use the partition type to denote a specific file system type, to flag the partition as being associated with a particular operating system, to indicate that the partition contains a bootable operating system, or some combination of the three.
By this point, you might be wondering how all this additional complexity is normally used. Refer to Figure A.6, “Disk Drive With Single Partition”, for an example.
Disk Drive With Single Partition
Image of a disk drive with a single partition.
Figure A.6. Disk Drive With Single Partition

In many cases, there is only a single partition spanning the entire disk, essentially duplicating the method used before partitions. The partition table has only one entry used, and it points to the start of the partition.
We have labeled this partition as being of the "DOS" type. Although it is only one of several possible partition types listed in Table A.1, “Partition Types”, it is adequate for the purposes of this discussion.
Table A.1, “Partition Types”, contains a listing of some popular (and obscure) partition types, along with their hexadecimal numeric values.
Partition Type Value Partition Type Value
Empty 00 Novell Netware 386 65
DOS 12-bit FAT 01 PIC/IX 75
XENIX root 02 Old MINIX 80
XENIX usr 03 Linux/MINUX 81
DOS 16-bit <=32M 04 Linux swap 82
Extended 05 Linux native 83
DOS 16-bit >=32 06 Linux extended 85
OS/2 HPFS 07 Amoeba 93
AIX 08 Amoeba BBT 94
AIX bootable 09 BSD/386 a5
OS/2 Boot Manager 0a OpenBSD a6
Win95 FAT32 0b NEXTSTEP a7
Win95 FAT32 (LBA) 0c BSDI fs b7
Win95 FAT16 (LBA) 0e BSDI swap b8
Win95 Extended (LBA) 0f Syrinx c7
Venix 80286 40 CP/M db
Novell 51 DOS access e1
PPC PReP Boot 41 DOS R/O e3
GNU HURD 63 DOS secondary f2
Novell Netware 286 64 BBT ff
Table A.1. Partition Types

Of course, over time it became obvious that four partitions would not be enough. As disk drives continued to grow, it became more and more likely that a person could configure four reasonably-sized partitions and still have disk space left over. There needed to be some way of creating more partitions.
Enter the extended partition. As you may have noticed in Table A.1, “Partition Types”, there is an "Extended" partition type. It is this partition type that is at the heart of extended partitions.
When a partition is created and its type is set to "Extended," an extended partition table is created. In essence, the extended partition is like a disk drive in its own right — it has a partition table that points to one or more partitions (now called logical partitions, as opposed to the four primary partitions) contained entirely within the extended partition itself. Figure A.7, “Disk Drive With Extended Partition”, shows a disk drive with one primary partition and one extended partition containing two logical partitions (along with some unpartitioned free space).
Disk Drive With Extended Partition
Image of a disk drive with an extended partition.
Figure A.7. Disk Drive With Extended Partition

As this figure implies, there is a difference between primary and logical partitions — there can only be four primary partitions, but there is no fixed limit to the number of logical partitions that can exist. However, due to the way in which partitions are accessed in Linux, you should avoid defining more than 12 logical partitions on a single disk drive.
Now that we have discussed partitions in general, let us review how to use this knowledge to install Fedora.

A.1.4. Making Room For Fedora

The following list presents some possible scenarios you may face when attempting to repartition your hard disk:
  • Unpartitioned free space is available
  • An unused partition is available
  • Free space in an actively used partition is available
Let us look at each scenario in order.

Note

Keep in mind that the following illustrations are simplified in the interest of clarity and do not reflect the exact partition layout that you encounter when actually installing Fedora.

A.1.4.1. Using Unpartitioned Free Space

Disk Drive with Unpartitioned Free Space
Image of a disk drive with unpartitioned free space, where 1 represents an undefined partition with unallocated space and 2 represents a defined partition with allocated space.
Figure A.8. Disk Drive with Unpartitioned Free Space

In Figure A.8, “Disk Drive with Unpartitioned Free Space”, 1 represents an undefined partition with unallocated space and 2 represents a defined partition with allocated space.
If you think about it, an unused hard disk also falls into this category. The only difference is that all the space is not part of any defined partition.
In any case, you can create the necessary partitions from the unused space. Unfortunately, this scenario, although very simple, is not very likely (unless you have just purchased a new disk just for Fedora). Most pre-installed operating systems are configured to take up all available space on a disk drive (refer to Section A.1.4.3, “Using Free Space from an Active Partition”).
Next, we will discuss a slightly more common situation.

A.1.4.2. Using Space from an Unused Partition

Disk Drive With an Unused Partition
Image of a disk drive with an unused partition, where 1 represents an unused partition and 2 represents reallocating an unused partition for Linux.
Figure A.9. Disk Drive With an Unused Partition

In Figure A.9, “Disk Drive With an Unused Partition”, 1 represents an unused partition and 2 represents reallocating an unused partition for Linux.
If you find yourself in this situation, you can use the space allocated to the unused partition. You first must delete the partition and then create the appropriate Linux partition(s) in its place. You can delete the unused partition and manually create new partitions during the installation process.

A.1.4.3. Using Free Space from an Active Partition

This is the most common situation. It is also, unfortunately, the hardest to handle. The main problem is that, even if you have enough free space, it is presently allocated to a partition that is already in use. If you purchased a computer with pre-installed software, the hard disk most likely has one massive partition holding the operating system and data.
Aside from adding a new hard drive to your system, you have two choices:
Destructive Repartitioning
Disk Drive Being Destructively Repartitioned
Image of a disk drive being destructively repartitioned, where 1 represents before and 2 represents after.
Figure A.10. Disk Drive Being Destructively Repartitioned

In Figure A.10, “Disk Drive Being Destructively Repartitioned”, 1 represents before and 2 represents after.

Warning

As Figure A.10, “Disk Drive Being Destructively Repartitioned”, shows, any data present in the original partition is lost without proper backup!
Non-Destructive Repartitioning
As Figure A.11, “Disk Drive Being Compressed”, shows, the first step is to compress the data in your existing partition. The reason for doing this is to rearrange the data such that it maximizes the available free space at the "end" of the partition.
Disk Drive Being Compressed
Image of a disk drive being compressed, where 1 represents before and 2 represents after.
Figure A.11. Disk Drive Being Compressed

In Figure A.11, “Disk Drive Being Compressed”, 1 represents before and 2 represents after.
This step is crucial. Without it, the location of your data could prevent the partition from being resized to the extent desired. Note also that, for one reason or another, some data cannot be moved. If this is the case (and it severely restricts the size of your new partition(s)), you may be forced to destructively repartition your disk.
A.1.4.3.2. Resize the existing partition
Figure A.12, “Disk Drive with Partition Resized”, shows the actual resizing process. While the actual result of the resizing operation varies depending on the software used, in most cases the newly freed space is used to create an unformatted partition of the same type as the original partition.
Disk Drive with Partition Resized
Image of a disk drive with a resized partition, where 1 represents before and 2 represents after.
Figure A.12. Disk Drive with Partition Resized

In Figure A.12, “Disk Drive with Partition Resized”, 1 represents before and 2 represents after.
It is important to understand what the resizing software you use does with the newly freed space, so that you can take the appropriate steps. In the case we have illustrated, it would be best to delete the new DOS partition and create the appropriate Linux partition(s).
A.1.4.3.3. Create new partition(s)
As the previous step implied, it may or may not be necessary to create new partitions. However, unless your resizing software is Linux-aware, it is likely that you must delete the partition that was created during the resizing process. Figure A.13, “Disk Drive with Final Partition Configuration”, shows this being done.
Disk Drive with Final Partition Configuration
Image of a disk drive with final partition configuration, where 1 represents before and 2 represents after.
Figure A.13. Disk Drive with Final Partition Configuration

In Figure A.13, “Disk Drive with Final Partition Configuration”, 1 represents before and 2 represents after.

Note

The following information is specific to x86-based computers only.
As a convenience to our customers, we provide the parted utility. This is a freely available program that can resize partitions.
If you decide to repartition your hard drive with parted, it is important that you be familiar with disk storage and that you perform a backup of your computer data. You should make two copies of all the important data on your computer. These copies should be to removable media (such as tape, CD-ROM, or diskettes), and you should make sure they are readable before proceeding.
Should you decide to use parted, be aware that after parted runs you are left with two partitions: the one you resized, and the one parted created out of the newly freed space. If your goal is to use that space to install Fedora, you should delete the newly created partition, either by using the partitioning utility under your current operating system or while setting up partitions during installation.
Linux refers to disk partitions using a combination of letters and numbers which may be confusing, particularly if you are used to the "C drive" way of referring to hard disks and their partitions. In the DOS/Windows world, partitions are named using the following method:
  • Each partition's type is checked to determine if it can be read by DOS/Windows.
  • If the partition's type is compatible, it is assigned a "drive letter." The drive letters start with a "C" and move on to the following letters, depending on the number of partitions to be labeled.
  • The drive letter can then be used to refer to that partition as well as the file system contained on that partition.
Fedora uses a naming scheme that is more flexible and conveys more information than the approach used by other operating systems. The naming scheme is file-based, with file names in the form of /dev/xxyN.
Here is how to decipher the partition naming scheme:
/dev/
This is the name of the directory in which all device files reside. Since partitions reside on hard disks, and hard disks are devices, the files representing all possible partitions reside in /dev/.
xx
The first two letters of the partition name indicate the type of device on which the partition resides, usually either hd (for IDE disks) or sd (for SCSI disks).
y
This letter indicates which device the partition is on. For example, /dev/hda (the first IDE hard disk) or /dev/sdb (the second SCSI disk).
N
The final number denotes the partition. The first four (primary or extended) partitions are numbered 1 through 4. Logical partitions start at 5. So, for example, /dev/hda3 is the third primary or extended partition on the first IDE hard disk, and /dev/sdb6 is the second logical partition on the second SCSI hard disk.

Note

There is no part of this naming convention that is based on partition type; unlike DOS/Windows, all partitions can be identified under Fedora. Of course, this does not mean that Fedora can access data on every type of partition, but in many cases it is possible to access data on a partition dedicated to another operating system.
Keep this information in mind; it makes things easier to understand when you are setting up the partitions Fedora requires.


[5] Blocks really are consistently sized, unlike our illustrations. Keep in mind, also, that an average disk drive contains thousands of blocks. But for the purposes of this discussion, please ignore these minor discrepancies.

ISCSI disks

Internet Small Computer System Interface (iSCSI) is a protocol that allows computers to communicate with storage devices by SCSI requests and responses carried over TCP/IP. Because iSCSI is based on the standard SCSI protocols, it uses some terminology from SCSI. The device on the SCSI bus to which requests get sent (and which answers these requests) is known as the target and the device issuing requests is known as the initiator. In other words, an iSCSI disk is a target and the iSCSI software equivalent of a SCSI controller or SCSI Host Bus Adapter (HBA) is called an initiator. This appendix only covers Linux as an iSCSI initiator: how Linux uses iSCSI disks, but not how Linux hosts iSCSI disks.
Linux has a software iSCSI initiator in the kernel that takes the place and form of a SCSI HBA driver and therefore allows Linux to use iSCSI disks. However, as iSCSI is a fully network-based protocol, iSCSI initiator support needs more than just the ability to send SCSI packets over the network. Before Linux can use an iSCSI target, Linux must find the target on the network and make a connection to it. In some cases, Linux must send authentication information to gain access to the target. Linux must also detect any failure of the network connection and must establish a new connection, including logging in again if necessary.
The discovery, connection, and logging in is handled in userspace by the iscsiadm utility, and the error handling is also handled in userspace by iscsid.
Both iscsiadm and iscsid are part of the iscsi-initiator-utils package under Fedora.

B.1. iSCSI disks in anaconda

Anaconda can discover (and then log in to) iSCSI disks in two ways:
  1. When anaconda starts, it checks if the BIOS or add-on boot ROMs of the system support iSCSI Boot Firmware Table (iBFT), a BIOS extension for systems which can boot from iSCSI. If the BIOS supports iBFT, anaconda will read the iSCSI target information for the configured boot disk from the BIOS and log in to this target, making it available as an installation target.
  2. The initial partitioning screen presents you with an Advanced storage configuration button that allows you to add iSCSI target information like the discovery IP-address. Anaconda will probe the given IP-address and log in to any targets that it finds. See Section 7.19, “ Advanced Storage Options ” for the details that you can specify for iSCSI targets.
While anaconda uses iscsiadm to find and log into iSCSI targets, iscsiadm automatically stores any information about these targets iscsiadm iSCSI database. Anaconda then copies this database to the installed system and marks any iSCSI targets not used for / so that the system will automatically log in to them when it starts. If / is placed on an iSCSI target, initrd will log into this target and anaconda does not include this target in start up scripts to avoid multiple attempts to log into the same target.
If / is placed on an iSCSI target, anaconda sets NetworkManager to ignore any network interfaces that were active during the installation process. These interfaces will also be configured by initrd when the system starts. If NetworkManager were to reconfigure these interfaces, the system would lose its connection to /.

B.2. iSCSI disks during start up

ISCSI-related events might occur at a number of points while the system starts:
  1. The init script in the initrd will log in to iSCSI targets used for / (if any). This is done using the iscsistart utility (which can do this without requiring iscsid to run).
  2. When the root filesystem has been mounted and the various service initscripts get run, the iscsid initscript will get called. This script will then start iscsid if any iSCSI targets are used for /, or if any targets in the iSCSI database are marked to be logged in to automatically.
  3. After the classic network service script has been run (or would have been run if enabled) the iscsi initscript will run. If the network is accessible, this will log in to any targets in the iSCSI database which are marked to be logged in to automatically. If the network is not accessible, this script will exit quietly.
  4. When using NetworkManager to access the network (instead of the classic network service script), NetworkManager will call the iscsi initscript. See: /etc/NetworkManager/dispatcher.d/04-iscsi

    Important

    Because NetworkManager is installed in /usr, you cannot use it to configure network access if /usr is on network-attached storage such as an iSCSI target.
If iscsid is not needed as the system starts, it will not start automatically. If you start iscsiadm, iscsiadm will start iscsid in turn.

Disk Encryption Guide

C.1. What is block device encryption?

Block device encryption protects the data on a block device by encrypting it. To access the device's decrypted contents, a user must provide a passphrase or key as authentication. This provides additional security beyond existing OS security mechanisms in that it protects the device's contents even if it has been physically removed from the system.

C.2. Encrypting block devices using dm-crypt/LUKS

LUKS (Linux Unified Key Setup) is a specification for block device encryption. It establishes an on-disk format for the data, as well as a passphrase/key management policy.
LUKS uses the kernel device mapper subsystem via the dm-crypt module. This arrangement provides a low-level mapping that handles encryption and decryption of the device's data. User-level operations, such as creating and accessing encrypted devices, are accomplished through the use of the cryptsetup utility.

C.2.1. Overview of LUKS

  • What LUKS does:
    • LUKS encrypts entire block devices
      • LUKS is thereby well-suited for protecting the contents of mobile devices such as:
        • Removable storage media
        • Laptop disk drives
    • The underlying contents of the encrypted block device are arbitrary.
      • This makes it useful for encrypting swap devices.
      • This can also be useful with certain databases that use specially formatted block devices for data storage.
    • LUKS uses the existing device mapper kernel subsystem.
      • This is the same subsystem used by LVM, so it is well tested.
    • LUKS provides passphrase strengthening.
      • This protects against dictionary attacks.
    • LUKS devices contain multiple key slots.
      • This allows users to add backup keys/passphrases.
  • What LUKS does not do:
    • LUKS is not well-suited for applications requiring many (more than eight) users to have distinct access keys to the same device.
    • LUKS is not well-suited for applications requiring file-level encryption.

C.2.2. How will I access the encrypted devices after installation? (System Startup)

During system startup you will be presented with a passphrase prompt. After the correct passphrase has been provided the system will continue to boot normally. If you used different passphrases for multiple encypted devices you may need to enter more than one passphrase during the startup.

Tip

Consider using the same passphrase for all encrypted block devices in a given system. This will simplify system startup and you will have fewer passphrases to remember. Just make sure you choose a good passphrase!

C.2.3. Choosing a Good Passphrase

While dm-crypt/LUKS supports both keys and passphrases, the anaconda installer only supports the use of passphrases for creating and accessing encrypted block devices during installation.
LUKS does provide passphrase strengthening but it is still a good idea to choose a good (meaning "difficult to guess") passphrase. Note the use of the term "passphrase", as opposed to the term "password". This is intentional. Providing a phrase containing multiple words to increase the security of your data is important.

C.3. Creating Encrypted Block Devices in Anaconda

You can create encrypted devices during system installation. This allows you to easily configure a system with encrypted partitions.
To enable block device encryption, check the "Encrypt System" checkbox when selecting automatic partitioning or the "Encrypt" checkbox when creating an individual partition, software RAID array, or logical volume. After you finish partitioning, you will be prompted for an encryption passphrase. This passphrase will be required to access the encrypted devices. If you have pre-existing LUKS devices and provided correct passphrases for them earlier in the install process the passphrase entry dialog will also contain a checkbox. Checking this checkbox indicates that you would like the new passphrase to be added to an available slot in each of the pre-existing encrypted block devices.

Tip

Checking the "Encrypt System" checkbox on the "Automatic Partitioning" screen and then choosing "Create custom layout" does not cause any block devices to be encrypted automatically.

Tip

You can use kickstart to set a separate passphrase for each new encrypted block device.

C.3.1. What Kinds of Block Devices Can Be Encrypted?

Most types of block devices can be encrypted using LUKS. From anaconda you can encrypt partitions, LVM physical volumes, LVM logical volumes, and software RAID arrays.

C.3.2. Limitations of Anaconda's Block Device Encryption Support

This section is about Anaconda's Block Device Encryption Support

C.4. Creating Encrypted Block Devices on the Installed System After Installation

Encrypted block devices can be created and configured after installation.

C.4.1. Create the block devices

Create the block devices you want to encrypt by using parted, pvcreate, lvcreate and mdadm.

C.4.2. Optional: Fill the device with random data

Filling <device> (eg: /dev/sda3) with random data before encrypting it greatly increases the strength of the encryption. The downside is that it can take a very long time.

Warning

The commands below will destroy any existing data on the device.
  • The best way, which provides high quality random data but takes a long time (several minutes per gigabyte on most systems):
    dd if=/dev/urandom of=<device>
    
  • Fastest way, which provides lower quality random data:
    badblocks -c 10240 -s -w -t random -v <device>
    

C.4.3. Format the device as a dm-crypt/LUKS encrypted device

Warning

The command below will destroy any existing data on the device.
cryptsetup luksFormat <device>

Tip

For more information, read the cryptsetup(8) man page.
After supplying the passphrase twice the device will be formatted for use. To verify, use the following command:
cryptsetup isLuks <device> && echo Success
To see a summary of the encryption information for the device, use the following command:
cryptsetup luksDump <device>

C.4.4. Create a mapping to allow access to the device's decrypted contents

To access the device's decrypted contents, a mapping must be established using the kernel device-mapper.
It is useful to choose a meaningful name for this mapping. LUKS provides a UUID (Universally Unique Identifier) for each device. This, unlike the device name (eg: /dev/sda3), is guaranteed to remain constant as long as the LUKS header remains intact. To find a LUKS device's UUID, run the following command:
cryptsetup luksUUID <device>
An example of a reliable, informative and unique mapping name would be luks-<uuid>, where <uuid> is replaced with the device's LUKS UUID (eg: luks-50ec957a-5b5a-47ee-85e6-f8085bbc97a8). This naming convention might seem unwieldy but is it not necessary to type it often.
cryptsetup luksOpen <device> <name>
There should now be a device node, /dev/mapper/<name>, which represents the decrypted device. This block device can be read from and written to like any other unencrypted block device.
To see some information about the mapped device, use the following command:
dmsetup info <name>

Tip

For more information, read the dmsetup(8) man page.

C.4.5. Create filesystems on the mapped device, or continue to build complex storage structures using the mapped device

Use the mapped device node (/dev/mapper/<name>) as any other block device. To create an ext2 filesystem on the mapped device, use the following command:
mke2fs /dev/mapper/<name>
To mount this filesystem on /mnt/test, use the following command:

Important

The directory /mnt/test must exist before executing this command.
mount /dev/mapper/<name> /mnt/test

C.4.6. Add the mapping information to /etc/crypttab

In order for the system to set up a mapping for the device, an entry must be present in the /etc/crypttab file. If the file doesn't exist, create it and change the owner and group to root (root:root) and change the mode to 0744. Add a line to the file with the following format:
<name>  <device>  none
The <device> field should be given in the form "UUID=<luks_uuid>", where <luks_uuid> is the LUKS uuid as given by the command cryptsetup luksUUID <device>. This ensures the correct device will be identified and used even if the device node (eg: /dev/sda5) changes.

Tip

For details on the format of the /etc/crypttab file, read the crypttab(5) man page.

C.4.7. Add an entry to /etc/fstab

Add an entry to /etc/fstab. This is only necessary if you want to establish a persistent association between the device and a mountpoint. Use the decrypted device, /dev/mapper/<name> in the /etc/fstab file.
In many cases it is desirable to list devices in /etc/fstab by UUID or by a filesystem label. The main purpose of this is to provide a constant identifier in the event that the device name (eg: /dev/sda4) changes. LUKS device names in the form of /dev/mapper/luks-<luks_uuid> are based only on the device's LUKS UUID, and are therefore guaranteed to remain constant. This fact makes them suitable for use in /etc/fstab.

Title

For details on the format of the /etc/fstab file, read the fstab(5) man page.

C.5. Common Post-Installation Tasks

The following sections are about common post-installation tasks.

C.5.1. Set a randomly generated key as an additional way to access an encrypted block device

These sections are about generating keys and adding keys.

C.5.1.1. Generate a key

This will generate a 256-bit key in the file $HOME/keyfile.
		dd if=/dev/urandom of=$HOME/keyfile bs=32 count=1
		chmod 600 $HOME/keyfile

C.5.1.2. Add the key to an available keyslot on the encrypted device

cryptsetup luksAddKey <device> ~/keyfile

C.5.2. Add a new passphrase to an existing device

cryptsetup luksAddKey <device>
After being prompted for any one of the existing passprases for authentication, you will be prompted to enter the new passphrase.

C.5.3. Remove a passphrase or key from a device

cryptsetup luksRemoveKey <device>
You will be prompted for the passphrase you wish to remove and then for any one of the remaining passphrases for authentication.

Understanding LVM

When a computer running Linux is turned on, the operating system is loaded into memory by a special program called a boot loader. A boot loader usually exists on the system's primary hard drive (or other media device) and has the sole responsibility of loading the Linux kernel with its required files or (in some cases) other operating systems into memory.
This appendix discusses commands and configuration options for the GRUB boot loader included with Fedora for the x86 architecture.

E.1. GRUB

The GNU GRand Unified Boot loader (GRUB) is a program which enables the selection of the installed operating system or kernel to be loaded at system boot time. It also allows the user to pass arguments to the kernel.

E.1.1. GRUB and the x86 Boot Process

GRUB loads itself into memory in the following stages:
  1. The Stage 1 or primary boot loader is read into memory by the BIOS from the MBR [6]. The primary boot loader exists on less than 512 bytes of disk space within the MBR and is capable of loading either the Stage 1.5 or Stage 2 boot loader.
  2. The Stage 1.5 boot loader is read into memory by the Stage 1 boot loader, if necessary. Some hardware requires an intermediate step to get to the Stage 2 boot loader. This is sometimes true when the /boot/ partition is above the 1024 cylinder head of the hard drive or when using LBA mode. The Stage 1.5 boot loader is found either on the /boot/ partition or on a small part of the MBR and the /boot/ partition.
  3. The Stage 2 or secondary boot loader is read into memory. The secondary boot loader displays the GRUB menu and command environment. This interface allows the user to select which kernel or operating system to boot, pass arguments to the kernel, or look at system parameters.
  4. The secondary boot loader reads the operating system or kernel as well as the contents of /boot/sysroot/ into memory. Once GRUB determines which operating system or kernel to start, it loads it into memory and transfers control of the machine to that operating system.
The method used to boot Linux is called direct loading because the boot loader loads the operating system directly. There is no intermediary between the boot loader and the kernel.
The boot process used by other operating systems may differ. For example, the Microsoft® Windows® operating system, as well as other operating systems, are loaded using chain loading. Under this method, the MBR points to the first sector of the partition holding the operating system, where it finds the files necessary to actually boot that operating system.
GRUB supports both direct and chain loading boot methods, allowing it to boot almost any operating system.

Warning

During installation, Microsoft's DOS and Windows installation programs completely overwrite the MBR, destroying any existing boot loaders. If creating a dual-boot system, it is best to install the Microsoft operating system first.

E.1.2. Features of GRUB

GRUB contains several features that make it preferable to other boot loaders available for the x86 architecture. Below is a partial list of some of the more important features:
One of the most important things to understand before using GRUB is how the program refers to devices, such as hard drives and partitions. This information is particularly important when configuring GRUB to boot multiple operating systems.

E.3.1. Device Names

When referring to a specific device with GRUB, do so using the following format (note that the parentheses and comma are very important syntactically):
(<type-of-device><bios-device-number>,<partition-number>)
The <bios-device-number> is the BIOS device number. The primary IDE hard drive is numbered 0 and a secondary IDE hard drive is numbered 1. This syntax is roughly equivalent to that used for devices by the kernel. For example, the a in hda for the kernel is analogous to the 0 in hd0 for GRUB, the b in hdb is analogous to the 1 in hd1, and so on.
The <partition-number> specifies the number of a partition on a device. Like the <bios-device-number>, most types of partitions are numbered starting at 0. However, BSD partitions are specified using letters, with a corresponding to 0, b corresponding to 1, and so on.

Note

The numbering system for devices under GRUB always begins with 0, not 1. Failing to make this distinction is one of the most common mistakes made by new users.
To give an example, if a system has more than one hard drive, GRUB refers to the first hard drive as (hd0) and the second as (hd1). Likewise, GRUB refers to the first partition on the first drive as (hd0,0) and the third partition on the second hard drive as (hd1,2).
In general the following rules apply when naming devices and partitions under GRUB:
  • It does not matter if system hard drives are IDE or SCSI, all hard drives begin with the letters hd. The letters fd are used to specify 3.5 diskettes.
  • To specify an entire device without respect to partitions, leave off the comma and the partition number. This is important when telling GRUB to configure the MBR for a particular disk. For example, (hd0) specifies the MBR on the first device and (hd3) specifies the MBR on the fourth device.
  • If a system has multiple drive devices, it is very important to know how the drive boot order is set in the BIOS. This is a simple task if a system has only IDE or SCSI drives, but if there is a mix of devices, it becomes critical that the type of drive with the boot partition be accessed first.

E.3.2. File Names and Blocklists

When typing commands to GRUB that reference a file, such as a menu list, it is necessary to specify an absolute file path immediately after the device and partition numbers.
The following illustrates the structure of such a command:
(<device-type><device-number>,<partition-number>)</path/to/file>
In this example, replace <device-type> with hd, fd, or nd. Replace <device-number> with the integer for the device. Replace </path/to/file> with an absolute path relative to the top-level of the device.
It is also possible to specify files to GRUB that do not actually appear in the file system, such as a chain loader that appears in the first few blocks of a partition. To load such files, provide a blocklist that specifies block by block where the file is located in the partition. Since a file is often comprised of several different sets of blocks, blocklists use a special syntax. Each block containing the file is specified by an offset number of blocks, followed by the number of blocks from that offset point. Block offsets are listed sequentially in a comma-delimited list.
The following is a sample blocklist:
0+50,100+25,200+1
This sample blocklist specifies a file that starts at the first block on the partition and uses blocks 0 through 49, 100 through 124, and 200.
Knowing how to write blocklists is useful when using GRUB to load operating systems which require chain loading. It is possible to leave off the offset number of blocks if starting at block 0. As an example, the chain loading file in the first partition of the first hard drive would have the following name:
(hd0,0)+1
The following shows the chainloader command with a similar blocklist designation at the GRUB command line after setting the correct device and partition as root:
chainloader +1

E.4. GRUB Interfaces

GRUB features three interfaces which provide different levels of functionality. Each of these interfaces allows users to boot the Linux kernel or another operating system.
The interfaces are as follows:

Note

The following GRUB interfaces can only be accessed by pressing any key within the three seconds of the GRUB menu bypass screen.
Menu Interface
This is the default interface shown when GRUB is configured by the installation program. A menu of operating systems or preconfigured kernels are displayed as a list, ordered by name. Use the arrow keys to select an operating system or kernel version and press the Enter key to boot it. If you do nothing on this screen, then after the time out period expires GRUB will load the default option.
Press the e key to enter the entry editor interface or the c key to load a command line interface.
Refer to Section E.6, “GRUB Menu Configuration File” for more information on configuring this interface.
Menu Entry Editor Interface
To access the menu entry editor, press the e key from the boot loader menu. The GRUB commands for that entry are displayed here, and users may alter these command lines before booting the operating system by adding a command line (o inserts a new line after the current line and O inserts a new line before it), editing one (e), or deleting one (d).
After all changes are made, the b key executes the commands and boots the operating system. The Esc key discards any changes and reloads the standard menu interface. The c key loads the command line interface.

Note

For information about changing runlevels using the GRUB menu entry editor, refer to Section E.7, “Changing Runlevels at Boot Time”.
Command Line Interface
The command line interface is the most basic GRUB interface, but it is also the one that grants the most control. The command line makes it possible to type any relevant GRUB commands followed by the Enter key to execute them. This interface features some advanced shell-like features, including Tab key completion based on context, and Ctrl key combinations when typing commands, such as Ctrl+a to move to the beginning of a line and Ctrl+e to move to the end of a line. In addition, the arrow, Home, End, and Delete keys work as they do in the bash shell.
Refer to Section E.5, “GRUB Commands” for a list of common commands.
GRUB allows a number of useful commands in its command line interface. Some of the commands accept options after their name; these options should be separated from the command and other options on that line by space characters.
The following is a list of useful commands:
  • boot — Boots the operating system or chain loader that was last loaded.
  • chainloader </path/to/file> — Loads the specified file as a chain loader. If the file is located on the first sector of the specified partition, use the blocklist notation, +1, instead of the file name.
    The following is an example chainloader command:
    chainloader +1
    
  • displaymem — Displays the current use of memory, based on information from the BIOS. This is useful to determine how much RAM a system has prior to booting it.
  • initrd </path/to/initrd> — Enables users to specify an initial RAM disk to use when booting. An initrd is necessary when the kernel needs certain modules in order to boot properly, such as when the root partition is formatted with the ext3 or ext4 file system.
    The following is an example initrd command:
    initrd /initrd-2.6.8-1.523.img
    
  • install <stage-1> <install-disk> <stage-2> p config-file — Installs GRUB to the system MBR.
    • <stage-1> — Signifies a device, partition, and file where the first boot loader image can be found, such as (hd0,0)/grub/stage1.
    • <install-disk> — Specifies the disk where the stage 1 boot loader should be installed, such as (hd0).
    • <stage-2> — Passes the stage 2 boot loader location to the stage 1 boot loader, such as (hd0,0)/grub/stage2.
    • p <config-file> — This option tells the install command to look for the menu configuration file specified by <config-file>, such as (hd0,0)/grub/grub.conf.

    Warning

    The install command overwrites any information already located on the MBR.
  • kernel </path/to/kernel> <option-1> <option-N> ... — Specifies the kernel file to load when booting the operating system. Replace </path/to/kernel> with an absolute path from the partition specified by the root command. Replace <option-1> with options for the Linux kernel, such as root=/dev/VolGroup00/LogVol00 to specify the device on which the root partition for the system is located. Multiple options can be passed to the kernel in a space separated list.
    The following is an example kernel command:
    kernel /vmlinuz-2.6.8-1.523 ro root=/dev/VolGroup00/LogVol00
    
    The option in the previous example specifies that the root file system for Linux is located on the hda5 partition.
  • root (<device-type><device-number>,<partition>) — Configures the root partition for GRUB, such as (hd0,0), and mounts the partition.
    The following is an example root command:
    root (hd0,0)
    
  • rootnoverify (<device-type><device-number>,<partition>) — Configures the root partition for GRUB, just like the root command, but does not mount the partition.

E.6. GRUB Menu Configuration File

E.6.2. Configuration File Directives

The following are directives commonly used in the GRUB menu configuration file:
  • chainloader </path/to/file> — Loads the specified file as a chain loader. Replace </path/to/file> with the absolute path to the chain loader. If the file is located on the first sector of the specified partition, use the blocklist notation, +1.
  • color <normal-color> <selected-color> — Allows specific colors to be used in the menu, where two colors are configured as the foreground and background. Use simple color names such as red/black. For example:
    color red/black green/blue
    
  • default=<integer> — Replace <integer> with the default entry title number to be loaded if the menu interface times out.
  • fallback=<integer> — Replace <integer> with the entry title number to try if the first attempt fails.
  • hiddenmenu — Prevents the GRUB menu interface from being displayed, loading the default entry when the timeout period expires. The user can see the standard GRUB menu by pressing the Esc key.
  • initrd </path/to/initrd> — Enables users to specify an initial RAM disk to use when booting. Replace </path/to/initrd> with the absolute path to the initial RAM disk.
  • kernel </path/to/kernel> <option-1> <option-N> — Specifies the kernel file to load when booting the operating system. Replace </path/to/kernel> with an absolute path from the partition specified by the root directive. Multiple options can be passed to the kernel when it is loaded.
  • password=<password> — Prevents a user who does not know the password from editing the entries for this menu option.
    Optionally, it is possible to specify an alternate menu configuration file after the password=<password> directive. In this case, GRUB restarts the second stage boot loader and uses the specified alternate configuration file to build the menu. If an alternate menu configuration file is left out of the command, a user who knows the password is allowed to edit the current configuration file.
    For more information about securing GRUB, refer to the chapter titled Workstation Security in the Red Hat Enterprise Linux Deployment Guide.
  • root (<device-type><device-number>,<partition>) — Configures the root partition for GRUB, such as (hd0,0), and mounts the partition.
  • rootnoverify (<device-type><device-number>,<partition>) — Configures the root partition for GRUB, just like the root command, but does not mount the partition.
  • timeout=<integer> — Specifies the interval, in seconds, that GRUB waits before loading the entry designated in the default command.
  • splashimage=<path-to-image> — Specifies the location of the splash screen image to be used when GRUB boots.
  • title group-title — Specifies a title to be used with a particular group of commands used to load a kernel or operating system.
To add human-readable comments to the menu configuration file, begin the line with the hash mark character (#).


[6] For more on the system BIOS and the MBR, refer to Section F.2.1, “The BIOS”.

Boot Process, Init, and Shutdown

An important and powerful aspect of Fedora is the open, user-configurable method it uses for starting the operating system. Users are free to configure many aspects of the boot process, including specifying the programs launched at boot-time. Similarly, system shutdown gracefully terminates processes in an organized and configurable way, although customization of this process is rarely required.
Understanding how the boot and shutdown processes work not only allows customization, but also makes it easier to troubleshoot problems related to starting or shutting down the system.
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 primarily on the x86 architecture.
A boot loader for the x86 platform is 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 has the advantage of being able to read ext2 and ext3 [7] partitions and load its configuration file — /boot/grub/grub.conf — at boot time. Refer to Section E.6, “GRUB Menu Configuration File” for information on how to edit this file.

ext4 and Btrfs

The GRUB bootloader does not support the ext4 or Btrfs file systems.

Note

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 a 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 loads the default selection after a configurable period of time has passed.
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, refer to Appendix E, The GRUB Boot Loader. For information on changing the runlevel at the boot loader prompt, refer Section E.7, “Changing Runlevels at Boot Time”.
The boot loader then places one or more appropriate initramfs images into memory. Next, the kernel decompresses these images from memory to /sysroot/, a RAM-based virtual file system, via cpio. The initramfs is used by the kernel to load drivers and modules necessary to boot the system. This is particularly important if SCSI hard drives are present or if the systems use the ext3 or ext4 file system.
Once the kernel and the initramfs image(s) are loaded into memory, the boot loader hands control of the boot process to the kernel.
For a more detailed overview of the GRUB boot loader, refer to Appendix E, The GRUB Boot Loader.
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 the system. First, it runs the /etc/rc.d/rc.sysinit script, which sets the environment path, starts swap, checks the file systems, and executes all other steps required for system initialization. For example, most systems use a clock, so 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 executes the /etc/rc.serial file.
Next, the init command sets the source function library, /etc/rc.d/init.d/functions, for the system, which configures how to start, kill, and 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 the default in /etc/inittab. The rc directories are numbered to correspond 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 
K10dc_server -> ../init.d/dc_server 
K10psacct -> ../init.d/psacct 
K10radiusd -> ../init.d/radiusd 
K12dc_client -> ../init.d/dc_client 
K12FreeWnn -> ../init.d/FreeWnn 
K12mailman -> ../init.d/mailman 
K12mysqld -> ../init.d/mysqld 
K15httpd -> ../init.d/httpd 
K20netdump-server -> ../init.d/netdump-server 
K20rstatd -> ../init.d/rstatd 
K20rusersd -> ../init.d/rusersd 
K20rwhod -> ../init.d/rwhod 
K24irda -> ../init.d/irda 
K25squid -> ../init.d/squid 
K28amd -> ../init.d/amd 
K30spamassassin -> ../init.d/spamassassin 
K34dhcrelay -> ../init.d/dhcrelay 
K34yppasswdd -> ../init.d/yppasswdd 
K35dhcpd -> ../init.d/dhcpd 
K35smb -> ../init.d/smb 
K35vncserver -> ../init.d/vncserver 
K36lisa -> ../init.d/lisa 
K45arpwatch -> ../init.d/arpwatch 
K45named -> ../init.d/named 
K46radvd -> ../init.d/radvd 
K50netdump -> ../init.d/netdump 
K50snmpd -> ../init.d/snmpd 
K50snmptrapd -> ../init.d/snmptrapd 
K50tux -> ../init.d/tux 
K50vsftpd -> ../init.d/vsftpd 
K54dovecot -> ../init.d/dovecot 
K61ldap -> ../init.d/ldap 
K65kadmin -> ../init.d/kadmin 
K65kprop -> ../init.d/kprop 
K65krb524 -> ../init.d/krb524 
K65krb5kdc -> ../init.d/krb5kdc 
K70aep1000 -> ../init.d/aep1000 
K70bcm5820 -> ../init.d/bcm5820 
K74ypserv -> ../init.d/ypserv 
K74ypxfrd -> ../init.d/ypxfrd 
K85mdmpd -> ../init.d/mdmpd 
K89netplugd -> ../init.d/netplugd 
K99microcode_ctl -> ../init.d/microcode_ctl 
S04readahead_early -> ../init.d/readahead_early 
S05kudzu -> ../init.d/kudzu 
S06cpuspeed -> ../init.d/cpuspeed 
S08ip6tables -> ../init.d/ip6tables 
S08iptables -> ../init.d/iptables 
S09isdn -> ../init.d/isdn 
S10network -> ../init.d/network 
S12syslog -> ../init.d/syslog 
S13irqbalance -> ../init.d/irqbalance 
S13portmap -> ../init.d/portmap 
S15mdmonitor -> ../init.d/mdmonitor 
S15zebra -> ../init.d/zebra 
S16bgpd -> ../init.d/bgpd 
S16ospf6d -> ../init.d/ospf6d 
S16ospfd -> ../init.d/ospfd 
S16ripd -> ../init.d/ripd 
S16ripngd -> ../init.d/ripngd 
S20random -> ../init.d/random 
S24pcmcia -> ../init.d/pcmcia 
S25netfs -> ../init.d/netfs 
S26apmd -> ../init.d/apmd 
S27ypbind -> ../init.d/ypbind 
S28autofs -> ../init.d/autofs 
S40smartd -> ../init.d/smartd 
S44acpid -> ../init.d/acpid 
S54hpoj -> ../init.d/hpoj 
S55cups -> ../init.d/cups 
S55sshd -> ../init.d/sshd 
S56rawdevices -> ../init.d/rawdevices 
S56xinetd -> ../init.d/xinetd 
S58ntpd -> ../init.d/ntpd 
S75postgresql -> ../init.d/postgresql 
S80sendmail -> ../init.d/sendmail 
S85gpm -> ../init.d/gpm 
S87iiim -> ../init.d/iiim 
S90canna -> ../init.d/canna 
S90crond -> ../init.d/crond 
S90xfs -> ../init.d/xfs 
S95atd -> ../init.d/atd 
S96readahead -> ../init.d/readahead 
S97messagebus -> ../init.d/messagebus 
S97rhnsd -> ../init.d/rhnsd 
S99local -> ../rc.local
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 begins 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.

Note

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 stops the Apache HTTP 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. Symbolic links with the same number are started alphabetically.

Note

One of the last things the init program executes is the /etc/rc.d/rc.local file. This file is useful for system customization. Refer to Section F.3, “Running Additional Programs at Boot Time” for more information about using the rc.local file.
After the init command has progressed through the appropriate rc directory for the runlevel, the /etc/inittab script forks an /sbin/mingetty process for each virtual console (login prompt) allocated to the runlevel. Runlevels 2 through 5 have all six virtual consoles, while runlevel 1 (single user mode) has one, and runlevels 0 and 6 have none. The /sbin/mingetty process opens communication pathways to tty devices[8], sets their modes, prints the login prompt, accepts the user's username and password, and initiates the login process.
In runlevel 5, the /etc/inittab runs a script called /etc/X11/prefdm. The prefdm script executes the preferred X display manager[9]gdm, kdm, or xdm, depending on the contents of the /etc/sysconfig/desktop file.
Once finished, the system operates on runlevel 5 and displays a login screen.
The SysV init runlevel system provides a standard process for controlling which programs init launches or halts when initializing a runlevel. SysV init was chosen because it is easier to use and more flexible than the traditional BSD-style init process.
The configuration files for SysV init are located in the /etc/rc.d/ directory. Within this directory, are the rc, rc.local, rc.sysinit, and, optionally, the rc.serial scripts as well as the following directories:
init.d/ rc0.d/ rc1.d/ rc2.d/ rc3.d/ rc4.d/ rc5.d/ rc6.d/
The init.d/ directory contains the scripts used by the /sbin/init command when controlling services. Each of the numbered directories represent the six runlevels configured by default under Fedora.

F.4.1. Runlevels

The idea behind SysV init runlevels revolves around the idea that different systems can be used in different ways. For example, a server runs more efficiently without the drag on system resources created by the X Window System. Or there may be times when a system administrator may need to operate the system at a lower runlevel to perform diagnostic tasks, like fixing disk corruption in runlevel 1.
The characteristics of a given runlevel determine which services are halted and started by init. For instance, runlevel 1 (single user mode) halts any network services, while runlevel 3 starts these services. By assigning specific services to be halted or started on a given runlevel, init can quickly change the mode of the machine without the user manually stopping and starting services.
The following runlevels are defined by default under Fedora:
  • 0 — Halt
  • 1 — Single-user text mode
  • 2 — Not used (user-definable)
  • 3 — Full multi-user text mode
  • 4 — Not used (user-definable)
  • 5 — Full multi-user graphical mode (with an X-based login screen)
  • 6 — Reboot
In general, users operate Fedora at runlevel 3 or runlevel 5 — both full multi-user modes. Users sometimes customize runlevels 2 and 4 to meet specific needs, since they are not used.
The default runlevel for the system is listed in /etc/inittab. To find out the default runlevel for a system, look for the line similar to the following near the top of /etc/inittab:
id:5:initdefault:
The default runlevel listed in this example is five, as the number after the first colon indicates. To change it, edit /etc/inittab as root.

Warning

Be very careful when editing /etc/inittab. Simple typos can cause the system to become unbootable. If this happens, either use a boot diskette, enter single-user mode, or enter rescue mode to boot the computer and repair the file.
For more information on single-user and rescue mode, refer to the chapter titled Basic System Recovery in the Red Hat Enterprise Linux Deployment Guide.


[7] GRUB reads ext3 file systems as ext2, disregarding the journal file. Refer to the chapter titled The ext3 File System in the Red Hat Enterprise Linux Deployment Guide for more information on the ext3 file system.

[8] Refer to the Red Hat Enterprise Linux Deployment Guide for more information about tty devices.

[9] Refer to the Red Hat Enterprise Linux Deployment Guide for more information about display managers.

Other Technical Documentation

This document provides a reference for using the Fedora installation software, known as anaconda. To learn more about anaconda, visit the project Web page: http://www.fedoraproject.org/wiki/Anaconda.
Both anaconda and Fedora systems use a common set of software components. For detailed information on key technologies, refer to the Web sites listed below:
Boot Loader
Disk Partitioning
Fedora uses parted to partition disks. Refer to http://www.gnu.org/software/parted/ for more information.
Storage Management
Audio Support
Graphics System
Remote Displays
Command-line Interface
By default, Fedora uses the GNU bash shell to provide a command-line interface. The GNU Core Utilities complete the command-line environment. Refer to http://www.gnu.org/software/bash/bash.html for more information on bash. To learn more about the GNU Core Utilities, refer to http://www.gnu.org/software/coreutils/.
Remote System Access
Access Control
Firewall
Software Installation
Virtualization

Contributors and production methods

H.1. Contributors

  • Fabian Affolter (translator - German)
  • Amanpreet Singh Alam (translator - Punjabi)
  • Jean-Paul Aubry (translator - French)
  • David Barzilay (translator - Brazilian Portuguese)
  • Domingo Becker (translator - Spanish)
  • Subhransu Behera (translator - Oriya)
  • Michał Bentkowski (translator - Polish)
  • Rahul Bhalerao (translator - Marathi)
  • Runa Bhattacharjee (translator - Bengali (India))
  • Teta Bilianou (translator - Greek)
  • Lucas Brausch (translator - German)
  • Hector Daniel Cabrera (translator - Spanish)
  • David Cantrell (writer - VNC installation)
  • Guido Caruso (translator - Italian)
  • Guillaume Chardin (translator - French)
  • Nikos Charonitakis (translator - Greek)
  • Chester Cheng (translator - Chinese (Traditional))
  • Glaucia Cintra (translator - Brazilian Portuguese)
  • Fabien Decroux (translator - French)
  • Hans De Goede (writer - iSCSI)
  • Claudio Rodrigo Pereyra Diaz (translator - Spanish)
  • Piotr Drąg (translator - Polish)
  • Damien Durand (translator - French)
  • Stuart Ellis (writer, editor)
  • Ali Fakoor (translator - Persian)
  • Felix I (translator - Tamil)
  • Tony Fu (translator - Chinese (Simplified))
  • Paul W. Frields (writer, editor)
  • Paul Gampe (translator - Japanese)
  • Sree Ganesh (translator - Telugu)
  • Dimitris Glezos (translator - Greek)
  • Guillermo Gómez (translator - Spanish)
  • Rui Gouveia (translator - Portuguese)
  • Kiyoto James Hashida (translator - Japanese)
  • Severin Heiniger (translator - German)
  • Xi Huang (translator - Chinese (Simplified))
  • Ryuichi Hyugabaru (translator - Japanese)
  • Jayaradha N (translator - Tamil)
  • Chris Johnson (writer)
  • Eunju Kim (translator - Korean)
  • Michelle J Kim (translator - Korean)
  • Miloš Komarčević (translator - Serbian)
  • Alexey Kostyuk (translator - Russian)
  • Daniela Kugelmann (translator - German)
  • Rüdiger Landmann (writer, editor)
  • Magnus Larsson (translator - Swedish)
  • Christopherus Laurentius (translator - Indonesian)
  • Florent Le Coz (translator - French)
  • Erick Lemon (writer)
  • Andy Liu (translator - Chinese (Traditional))
  • Wei Liu (translator - Chinese (Simplified))
  • Yelitza Louze (translator - Spanish)
  • Gan Lu (translator - Chinese (Simplified))
  • Igor Miletić (translator - Serbian)
  • Noriko Mizumoto (translator - Japanese)
  • Jeremy W. Mooney (writer)
  • Enikő Nagy (translator - Hungarian)
  • Igor Nestorović (translator - Serbian)
  • David Nalley (writer, editor)
  • John Nguyen (writer)
  • Manuel Ospina (translator - Spanish)
  • Janis Ozolins (translator - Latvian)
  • Ankit Patel (translator - Gujarati)
  • Davidson Paulo (translator - Brazilian Portuguese)
  • Ani Peter (translator - Malayalam)
  • Amitakhya Phukan (translator - Assamese)
  • Silvio Pierro (translator - Italian)
  • Micha Pietsch (translator - German)
  • José Nuno Pires (translator - Portuguese)
  • Piotr Podgórski (translator - Polish)
  • Yulia Poyarkova (translator - Russian)
  • Shankar Prasad (translator - Kannada)
  • Rajesh Ranjan (translator - Hindi)
  • Tim Richert (translator - German)
  • Dominik Sandjaja (translator - German)
  • Sharuzzaman Ahmat Raslan (translator - Malay)
  • Mohsen Saeedi (translator - Persian)
  • Tian Shixiong (translator - Chinese (Simplified))
  • Audrey Simons (translator - French)
  • Keld Simonsen (translator - Danish)
  • Jared K. Smith (writer, editor)
  • Espen Stefansen (translator - Norwegian Bokmål)
  • Sulyok Péter (translator - Hungarian)
  • Sümegi Zoltán (translator - Hungarian)
  • Francesco Tombolini (translator - Italian)
  • Timo Trinks (translator - German)
  • Dimitris Typaldos (translator - Greek)
  • Göran Uddeborg (translator - Swedish)
  • Michaël Ughetto (translator - French)
  • Francesco Valente (translator - Italian)
  • Karsten Wade (writer, editor, publisher)
  • Sarah Saiying Wang (translator - Chinese (Simplified))
  • Geert Warrink (translator - Dutch)
  • Elizabeth Ann West (editor)
  • Tyronne Wickramarathne (translator - Sinhalese)
  • Ben Wu (translator - Chinese (Traditional))
  • Xiaofan Yang (translator - Chinese (Simplified))
  • Yuan Yijun (translator - Chinese (Simplified))
  • Diego Búrigo Zacarão (translator - Brazilian Portuguese)
  • Izaac Zavaleta (translator - Spanish)

H.2. Production methods

Writers produce the Install Guide directly in DocBook XML in a revision control repository. They collaborate with other subject matter experts during the beta release phase of Fedora to explain the installation process. The editorial team ensures consistency and quality of the finished guide. At this point, the team of translators produces other language versions of the release notes, and then they become available to the general public as part of Fedora. The publication team also makes the guide, and subsequent errata, available via the Web.

Revision History

Revision History
Revision 11.0.0Wed Apr 01 2009Hans De Goede, Paul W. Frields, Ruediger Landmann, David Nalley, The anaconda team, Red Hat Engineering Content Services
Major update, incorporating material from the Red Hat Enterprise Linux Installation Guide and elsewhere, plus fixes for numerous bugs
Revision 10.0.1Mon Feb 16 2009Ruediger Landmann
Convert to build in Publican
Revision 10.0.0Mon Nov 24 2008Karsten Wade
Build and publish Fedora 10 version
Revision 9.9.2Sat Oct 18 2008Jared K. Smith
Prepare for release of Fedora 10
Revision 9.0.2Fri Jul 25 2008Paul W. Frields
Fix incorrect livecd-tools instructions
Revision 9.0.1Sat Jun 28 2008Paul W. Frields
Lots of bug fixes
Revision 9.0.0Tue May 13 2008Paul W. Frields
Add information on upgrading a distribution

Index

Symbols

/boot/ partition
recommended partitioning, Recommended Partitioning Scheme
/root/install.log
install log file location, Prepare to Install
/var/ partition
recommended partitioning, Recommended Partitioning Scheme

A

adding partitions, Adding Partitions
file system type, File System Types
Anaconda, Other Technical Documentation
architecture, Which Architecture Is My Computer?
determining, Which Architecture Is My Computer?
array (see RAID)
ATAPI CD-ROM
unrecognized, problems with, What If the IDE CD-ROM Was Not Found?
automatic partitioning, Disk Partitioning Setup, Create Default Layout

B

Basic Input/Output System (see BIOS)
BIOS
definition of, The BIOS
(see also boot process)
BIOS (Basic Input/Output System), How Do I Start the Installation Program?
BitTorrent, From BitTorrent
seeding, From BitTorrent
boot CD-ROM, Alternative Boot Methods
creating, Making an Installation Boot CD-ROM
boot loader, Upgrading Boot Loader Configuration, x86, AMD64, and Intel 64 Boot Loader Configuration
(see also GRUB)
configuration, x86, AMD64, and Intel 64 Boot Loader Configuration
GRUB, x86, AMD64, and Intel 64 Boot Loader Configuration
installing on boot partition, Advanced Boot Loader Configuration
MBR, Advanced Boot Loader Configuration
password, x86, AMD64, and Intel 64 Boot Loader Configuration
upgrading, Upgrading Boot Loader Configuration
boot loader password, x86, AMD64, and Intel 64 Boot Loader Configuration
boot loaders, GRUB
(see also GRUB)
definition of, The GRUB Boot Loader
boot methods
boot CD-ROM, Alternative Boot Methods
USB pen drive, Alternative Boot Methods
boot options, Additional Boot Options
boot.iso, Additional Boot Options
linux mediacheck, Preparing for a Hard Drive Installation
mediacheck, Additional Boot Options
serial mode, Additional Boot Options
UTF-8, Additional Boot Options
text mode, Additional Boot Options
boot process, Boot Process, Init, and Shutdown, A Detailed Look at the Boot Process
(see also boot loaders)
chain loading, GRUB and the x86 Boot Process
direct loading, GRUB and the x86 Boot Process
for x86, A Detailed Look at the Boot Process
stages of, The Boot Process, A Detailed Look at the Boot Process
/sbin/init command, The /sbin/init Program
BIOS, The BIOS
boot loader, The Boot Loader
EFI shell, The BIOS
kernel, The Kernel
boot.iso, Making an Installation Boot CD-ROM, Additional Boot Options
booting
emergency mode, Booting into Emergency Mode
installation program
x86, AMD64 and Intel 64, Booting the Installation Program on x86, AMD64, and Intel 64 Systems
rescue mode, Booting into Rescue Mode
single-user mode, Booting into Single-User Mode

D

DHCP
diskless environment, Configuring the DHCP Server
PXE installations, Configuring the DHCP Server
DHCP (Dynamic Host Configuration Protocol), Network Configuration
Disk Partitioner
adding partitions, Adding Partitions
disk partitioning, Disk Partitioning Setup
disk space, Do You Have Enough Disk Space?
diskette
media, Driver Media for Intel and AMD Systems
diskless environment
DHCP configuration, Configuring the DHCP Server
dmraid
installation, Advanced Storage Options
domain name, Network Configuration
driver diskette, Starting the Installation Program
driver disks, Adding Hardware Support with Driver Disks
driver media, Driver Media for Intel and AMD Systems
creating diskette from image, Creating a Driver Diskette from an Image File
produced by others, How Do I Obtain Driver Media?
produced by Red Hat, How Do I Obtain Driver Media?
using a driver image, Using a Driver Image During Installation

E

EFI shell
definition of, The BIOS
(see also boot process)
emergency mode, Booting into Emergency Mode
ext2 (see file systems)
ext3 (see file systems)
ext4 (see file systems)
extended partitions, Partitions within Partitions — An Overview of Extended Partitions
Extensible Firmware Interface shell (see EFI shell)

F

feedback
contact information for this manual, We Need Feedback!
file system
formats, overview of, It is Not What You Write, it is How You Write It
file system types, File System Types
file systems
ext2, Installing from a Hard Drive
ext3, Installing from a Hard Drive
ext4, Installing from a Hard Drive
vfat, Installing from a Hard Drive
firewall
documentation, Other Technical Documentation
Firstboot, Firstboot
FTP
installation, Preparing for a Network Installation

G

GRUB, x86, AMD64, and Intel 64 Boot Loader Configuration, The Boot Loader
(see also boot loaders)
additional resources, Additional Resources
installed documentation, Installed Documentation
related books, Related Books
useful websites, Useful Websites
alternatives to, Alternative Boot Loaders
boot process, GRUB and the x86 Boot Process
Changing Runlevels at Boot Time, Changing Runlevels at Boot Time
changing runlevels with, GRUB Interfaces
commands, GRUB Commands
configuration, x86, AMD64, and Intel 64 Boot Loader Configuration
configuration file
/boot/grub/grub.conf, Configuration File Structure
structure, Configuration File Structure
definition of, GRUB
documentation, Other Technical Documentation
features, Features of GRUB
installing, Installing GRUB
interfaces, GRUB Interfaces
command line, GRUB Interfaces
menu, GRUB Interfaces
menu entry editor, GRUB Interfaces
order of, Interfaces Load Order
menu configuration file, GRUB Menu Configuration File
directives, Configuration File Directives
role in boot process, The Boot Loader
terminology, GRUB Terminology
devices, Device Names
files, File Names and Blocklists
root file system, The Root File System and GRUB
grub.conf, Configuration File Structure
(see also GRUB)

I

IDE CD-ROM
unrecognized, problems with, What If the IDE CD-ROM Was Not Found?
init command, The /sbin/init Program
(see also boot process)
configuration files
/etc/inittab, SysV Init Runlevels
role in boot process, The /sbin/init Program
(see also boot process)
runlevels
directories for, SysV Init Runlevels
runlevels accessed by, Runlevels
SysV init
definition of, SysV Init Runlevels
install log file
/root/install.log, Prepare to Install
installation
aborting, Installing from DVD/CD-ROM
can you install with a CD-ROM or DVD, Can You Install Using the CD-ROM or DVD?
CD-ROM, Installing from DVD/CD-ROM
disk space, Do You Have Enough Disk Space?
FTP, Preparing for a Network Installation
GUI
CD-ROM, Installing on Intel and AMD Systems
hard drive, Preparing for a Hard Drive Installation, Installing from a Hard Drive
HTTP, Preparing for a Network Installation, Installing via FTP or HTTP
keyboard navigation, Using the Keyboard to Navigate
kickstart (see kickstart installations)
mediacheck, Additional Boot Options
method
CD-ROM, Selecting an Installation Method
hard drive, Selecting an Installation Method
NFS image, Selecting an Installation Method
selecting, Selecting an Installation Method
URL, Selecting an Installation Method
network, Preparing for a Network Installation
NFS, Preparing for a Network Installation, Installing via NFS
server information, Installing via NFS
partitioning, Partitioning Your System
problems
IDE CD-ROM related, What If the IDE CD-ROM Was Not Found?
program
graphical user interface, The Graphical Installation Program User Interface
starting, Starting the Installation Program
text mode user interface, The Text Mode Installation Program User Interface
virtual consoles, A Note about Virtual Consoles
serial mode, Additional Boot Options
UTF-8, Additional Boot Options
starting, Installing from DVD/CD-ROM
text mode, Additional Boot Options
installation media
testing, Preparing for a Hard Drive Installation
installation program
x86, AMD64 and Intel 64
booting, Booting the Installation Program on x86, AMD64, and Intel 64 Systems
installing packages, Package Group Selection
IPv4, Network Configuration
iscsi
installation, Advanced Storage Options
ISO images
downloading, Download Files, How Do I Download Installation Files?

K

kernel
role in boot process, The Kernel
kernel options, Kernel Options
keyboard
configuration, Keyboard Configuration
navigating the installation program using, Using the Keyboard to Navigate
keymap
selecting type of keyboard, Keyboard Configuration
Kickstart, Automating the Installation with Kickstart
kickstart
how the file is found, Starting a Kickstart Installation
Kickstart Configurator, Kickstart Configurator
%post script, Post-Installation Script
%pre script, Pre-Installation Script
authentication options, Authentication
basic options, Basic Configuration
boot loader, Boot Loader Options
boot loader options, Boot Loader Options
Display configuration, Display Configuration
firewall configuration, Firewall Configuration
installation method selection, Installation Method
interactive, Basic Configuration
keyboard, Basic Configuration
language, Basic Configuration
network configuration, Network Configuration
package selection, Package Selection
partitioning, Partition Information
software RAID, Creating Software RAID Partitions
preview, Kickstart Configurator
reboot, Basic Configuration
root password, Basic Configuration
encrypt, Basic Configuration
saving, Saving the File
SELinux configuration, SELinux Configuration
text mode installation, Basic Configuration
time zone, Basic Configuration
kickstart file
%include, Kickstart Options
%post, Post-installation Script
%pre, Pre-installation Script
auth, Kickstart Options
authconfig, Kickstart Options
autopart, Kickstart Options
autostep, Kickstart Options
bootloader, Kickstart Options
CD-ROM-based, Creating Kickstart Boot Media
clearpart, Kickstart Options
cmdline, Kickstart Options
creating, Kickstart Options
device, Kickstart Options
diskette-based, Creating Kickstart Boot Media
driverdisk, Kickstart Options
firewall, Kickstart Options
firstboot, Kickstart Options
flash-based, Creating Kickstart Boot Media
format of, Creating the Kickstart File
graphical, Kickstart Options
halt, Kickstart Options
ignoredisk, Kickstart Options
include contents of another file, Kickstart Options
install, Kickstart Options
installation methods, Kickstart Options
interactive, Kickstart Options
iscsi, Kickstart Options
key, Kickstart Options
keyboard, Kickstart Options
lang, Kickstart Options
langsupport, Kickstart Options
logging, Kickstart Options
logvol, Kickstart Options
mediacheck, Kickstart Options
mouse, Kickstart Options
multipath, Kickstart Options
network, Kickstart Options
network-based, Making the Kickstart File Available on the Network, Making the Installation Tree Available
options, Kickstart Options
partitioning examples, Advanced Partitioning Example
package selection specification, Package Selection
part, Kickstart Options
partition, Kickstart Options
post-installation configuration, Post-installation Script
poweroff, Kickstart Options
pre-installation configuration, Pre-installation Script
raid, Kickstart Options
reboot, Kickstart Options
rootpw, Kickstart Options
selinux, Kickstart Options
services, Kickstart Options
shutdown, Kickstart Options
skipx, Kickstart Options
text, Kickstart Options
timezone, Kickstart Options
upgrade, Kickstart Options
user, Kickstart Options
vnc, Kickstart Options
volgroup, Kickstart Options
what it looks like, Creating the Kickstart File
xconfig, Kickstart Options
zerombr, Kickstart Options
zfcp, Kickstart Options
kickstart installations, Kickstart Installations
CD-ROM-based, Creating Kickstart Boot Media
diskette-based, Creating Kickstart Boot Media
file format, Creating the Kickstart File
file locations, Making the Kickstart File Available
flash-based, Creating Kickstart Boot Media
installation tree, Making the Installation Tree Available
LVM, Kickstart Options
network-based, Making the Kickstart File Available on the Network, Making the Installation Tree Available
starting, Starting a Kickstart Installation
from a boot CD-ROM, Starting a Kickstart Installation
from CD-ROM #1 with a diskette, Starting a Kickstart Installation

L

language
selecting, Language Selection
LILO, The Boot Loader
(see also boot loaders)
role in boot process, The Boot Loader
LVM
documentation, Other Technical Documentation
logical volume, Understanding LVM
physical volume, Understanding LVM
understanding, Understanding LVM
volume group, Understanding LVM
with kickstart, Kickstart Options

M

master boot record, x86, AMD64, and Intel 64 Boot Loader Configuration
Master Boot Record, Unable to Boot into Fedora (see MBR)
reinstalling, Reinstalling the Boot Loader
MBR
definition of, A Detailed Look at the Boot Process, The BIOS
(see also boot loaders)
(see also boot process)
installing boot loader on, Advanced Boot Loader Configuration
memory testing mode, Loading the Memory (RAM) Testing Mode
mirror, From a Mirror
modem, Network Configuration
mount points
partitions and, Disk Partitions and Mount Points

N

network
installations
HTTP, Installing via FTP or HTTP
NFS, Installing via NFS
network installation
performing, Performing a Network Installation
preparing for, Preparing for a Network Installation
NFS
installation, Preparing for a Network Installation, Installing via NFS
NFS (Network File System)
install from, Performing a Network Installation
NTFS partitions
resizing, Prepare for Installation
NTP (Network Time Protocol), Time Zone Configuration, Date and Time
ntsysv, Runlevel Utilities
(see also services)

O

OpenSSH, Other Technical Documentation
(see also SSH)
OS/2 boot manager, Advanced Boot Loader Configuration

P

package groups, Customizing the Software Selection
packages
groups, Package Group Selection
selecting, Package Group Selection
installing, Package Group Selection
selecting, Package Group Selection
parted partitioning utility, Create new partition(s)
partition
extended, Partitions within Partitions — An Overview of Extended Partitions
illegal, The partitioning screen
root, The partitioning screen
partitioning, Partitioning Your System
automatic, Create Default Layout
basic concepts, An Introduction to Disk Partitions
creating new, Adding Partitions
file system type, File System Types
deleting, Deleting a Partition
destructive, Using Free Space from an Active Partition
editing, Editing Partitions
extended partitions, Partitions within Partitions — An Overview of Extended Partitions
how many partitions, Partitions: Turning One Drive Into Many, How Many Partitions?
introduction to, Partitions: Turning One Drive Into Many
making room for partitions, Making Room For Fedora
mount points and, Disk Partitions and Mount Points
naming partitions, Partition Naming Scheme
non-destructive, Using Free Space from an Active Partition
numbering partitions, Partition Naming Scheme
other operating systems, Disk Partitions and Other Operating Systems
primary partitions, Partitions: Turning One Drive Into Many
recommended, Recommended Partitioning Scheme
types of partitions, Partitions: Turning One Drive Into Many
using free space, Using Unpartitioned Free Space
using in-use partition, Using Free Space from an Active Partition
using unused partition, Using Space from an Unused Partition
Partitioning, Partitioning Your System
adding partitions
file system type, File System Types
buttons, The partitioning screen
deleting partitions, Deleting a Partition
editing partitions, Editing Partitions
password
boot loader, x86, AMD64, and Intel 64 Boot Loader Configuration
setting root, Set the Root Password
programs
running at boot time, Running Additional Programs at Boot Time
PulseAudio, Other Technical Documentation
PXE (Pre-boot eXecution Environment), Booting from the Network using PXE
PXE installations
adding hosts, Adding PXE Hosts
boot message, custom, Adding a Custom Boot Message
configuration, PXE Boot Configuration
DHCP configuration, Configuring the DHCP Server
overview, Manually configure a PXE server
performing, Performing the PXE Installation
setting up the network server, Setting up the Network Server

R

RAID
creating a software RAID, The partitioning screen
hardware, RAID and Other Disk Devices
kickstart installations, Kickstart Options
Kickstart Configurator, Creating Software RAID Partitions
partitioning a RAID, The partitioning screen
software, RAID and Other Disk Devices
system unbootable after disk failure, Installing GRUB
trouble booting from drive attached to RAID card, Are You Unable to Boot With Your RAID Card?
rc.local
modifying, Running Additional Programs at Boot Time
rc.serial, Running Additional Programs at Boot Time
(see also setserial command)
re-installation, Determining Whether to Upgrade or Re-Install
removing
Fedora, Removing Fedora
rescue discs, Booting Your Computer with the Rescue Mode
rescue mode, Rescue Mode, Booting Your Computer with the Rescue Mode
definition of, Booting into Rescue Mode
utilities available, Booting into Rescue Mode
root / partition
recommended partitioning, Recommended Partitioning Scheme
root password, Set the Root Password
runlevel 1, Booting into Single-User Mode
runlevels (see init command)
changing with GRUB, GRUB Interfaces
configuration of, Runlevel Utilities
(see also services)

S

scp, Other Technical Documentation
(see also SSH)
selecting
packages, Package Group Selection
SELinux
documentation, Other Technical Documentation
serial console, Configuring the Interface
serial ports (see setserial command)
services
configuring with chkconfig, Runlevel Utilities
configuring with ntsysv, Runlevel Utilities
configuring with Services Configuration Tool, Runlevel Utilities
Services Configuration Tool, Runlevel Utilities
(see also services)
setserial command
configuring, Running Additional Programs at Boot Time
Setup Agent
via Kickstart, Kickstart Options
shutdown, Shutting Down
(see also halt)
single-user mode, Booting into Single-User Mode
SSH (Secure SHell)
documentation, Other Technical Documentation
starting
installation, Starting the Installation Program, Installing from DVD/CD-ROM
steps
disk space, Do You Have Enough Disk Space?
hardware compatibility, Is Your Hardware Compatible?
installing with CD-ROM or DVD, Can You Install Using the CD-ROM or DVD?
swap file
upgrade, Determining Whether to Upgrade or Re-Install
swap partition
recommended partitioning, Recommended Partitioning Scheme
syslog, Logging to a Remote System During the Installation
system recovery, Basic System Recovery
common problems, Common Problems
forgetting the root password, Root Password
hardware/software problems, Hardware/Software Problems
reinstalling the boot loader, Reinstalling the Boot Loader
unable to boot into Fedora, Unable to Boot into Fedora
system-config-kickstart (see Kickstart Configurator)
SysV init (see init command)

T

TCP/IP configuration, Performing a Network Installation
Telnet, Enabling Remote Access with Telnet
text interface, Configuring the Interface
tftp, Starting the tftp Server
time zone
configuration, Time Zone Configuration
traceback messages
saving traceback messages without removeable media, Saving traceback messages without removeable media
troubleshooting, Troubleshooting Installation on an Intel or AMD System
after the installation, Problems After Installation
Apache-based httpd service hangs during startup, Apache-based httpd service/Sendmail Hangs During Startup
booting into a graphical environment, Booting into a Graphical Environment
booting into GNOME or KDE, Booting into a Graphical Environment
booting into the X Window System, Booting into a Graphical Environment
graphical GRUB screen, Trouble With the Graphical GRUB Screen on an x86-based System?
logging in, Problems When You Try to Log In
printers, Your Printer Does Not Work
RAM not recognized, Is Your RAM Not Being Recognized?
Sendmail hangs during startup, Apache-based httpd service/Sendmail Hangs During Startup
sound configuration, Problems with Sound Configuration
X (X Window System), Problems with the X Window System (GUI)
X server crashes, Problems with the X Server Crashing and Non-Root Users
beginning the installation, Trouble Beginning the Installation
frame buffer, disabling, Problems with Booting into the Graphical Installation
GUI installation method unavailable, Problems with Booting into the Graphical Installation
booting, You are unable to boot Fedora
RAID cards, Are You Unable to Boot With Your RAID Card?
signal 11 error, Is Your System Displaying Signal 11 Errors?
CD-ROM failure
CD-ROM verification, Preparing for a Hard Drive Installation, Additional Boot Options
during the installation, Trouble During the Installation
completing partitions, Other Partitioning Problems
No devices found to install Fedora error message, No devices found to install Fedora Error Message
partition tables, Trouble with Partition Tables
Python errors, Are You Seeing Python Errors?
saving traceback messages without removeable media, Saving traceback messages without removeable media
using remaining hard drive space, Using Remaining Space