Beginners' Guide/Installation (한국어)
- 1 설치하기
- 1.1 Select an installation source
- 1.2 Set editor
- 1.3 Set clock
- 1.4 Prepare hard drive
- 1.4.1 Partitioning hard disks: General information
- 1.4.2 Creating filesystems: General information
- 1.4.3 Option 1: Auto prepare
- 1.4.4 Option 2: Manually partition hard drives
- 1.4.5 Option 3: Manually configure block devices, filesystems, and mountpoints
- 1.5 Select packages
- 1.6 Install packages
- 1.7 Configure the system
- 1.7.1 Can the installer handle this more automatically?
- 1.7.2 /etc/rc.conf
- 1.7.3 /etc/fstab
- 1.7.4 /etc/mkinitcpio.conf
- 1.7.5 /etc/modprobe.d/modprobe.conf
- 1.7.6 /etc/resolv.conf
- 1.7.7 /etc/hosts
- 1.7.8 /etc/locale.gen
- 1.7.9 /etc/pacman.conf
- 1.7.10 /etc/pacman.d/mirrorlist
- 1.7.11 Root password
- 1.7.12 Done
- 1.8 Install bootloader
- 1.9 Reboot
ftp_proxy의 환경변수를 설정해줘야만 할지 모릅니다.
export http_proxy=http://<http_proxy_address>:<proxy_port> export ftp_proxy=ftp://<ftp_proxy_address>:<proxy_port>}}
root 권한으로, tty1에서 설치도구 스크립트를 실행시킵니다:
여러분은 화면에 뜬 아치리눅스 프레임워크 스크린을 볼 것입니다.
Select an installation source
After a welcome screen, you will be prompted for an installation source.
The Select Source dialog will ask you to select the repositories you want to enable.
- If using a Netinstall image, you will be able to select only remote repositories.
- If you chose the Core installer and wish to use the packages on the CD, select core-local.
If you are not sure which to use, then select 'extra' and 'community' in addition to 'core'. If you are installing 64-bit Arch, you may also want 'multilib'. However, these settings will be made for the target system later in the installation process.
You will be given a list to select an additional FTP or HTTP mirror.
If you chose core-local as well as remote repositories, you will now be given the choice either to consult remote sources only for packages unavailable locally, or the converse.
At the next screen, select Yes to set up the network. You shall be prompted to load ethernet drivers manually, if desired. UDev is quite effective at loading the required modules, so you may assume it has already done so. You may verify this by pressing Template:Keypress and invoking
ip addr. When done, return to tty1 by pressing Template:Keypress.
Available interfaces will be presented. If an interface and HWaddr (HardWare address) is listed, then your module has already been loaded. If your interface is not listed, you may probe it from the installer, or manually do so from another virtual console. Select your interface to continue.
The installer will then ask if you wish to use DHCP. Choosing "Yes" will run
dhcpcd to discover an available gateway and request an IP address; choosing "No" will prompt you for your static IP address, netmask, broadcast (optional), gateway, DNS server, HTTP proxy (optional), and FTP proxy (optional).
Afterwards, you will be returned to the Main Menu
Setup ADSL bridging in the live environment (optional)
(If you have a modem or router in bridge mode to connect to your ISP)
Switch to another virtual console (Template:Keypress), login as root and invoke:
If everything is well configured in the end you can connect to your ISP with:
Setup wireless in the live environment (optional)
(If you need wireless connectivity during the installation process)
The wireless drivers and utilities are now available to you in the live environment of the installation media. A good knowledge of your wireless hardware will be of key importance to successful configuration. Note that the following quick-start procedure executed at this point in the installation will initialize your wireless hardware for use in the live environment of the installation media. These steps (or some other form of wireless management) must be repeated from the actual installed system after booting into it.
Also note that these steps are optional if wireless connectivity is unnecessary at this point in the installation; wireless functionality may always be established later.
The basic procedure will be:
- Switch to a free virtual console, e.g.: Template:Keypress
- Login as root
- (optional) Identify the wireless interface:
# lspci | grep -i net
- Ensure udev has loaded the driver, and that the driver has created a usable wireless kernel interface with
lo no wireless extensions. eth0 no wireless extensions. wlan0 unassociated ESSID:"" Mode:Managed Channel=0 Access Point: Not-Associated Bit Rate:0 kb/s Tx-Power=20 dBm Sensitivity=8/0 Retry limit:7 RTS thr:off Fragment thr:off Power Management:off Link Quality:0 Signal level:0 Noise level:0 Rx invalid nwid:0 Rx invalid crypt:0 Rx invalid frag:0 Tx excessive retries:0 Invalid misc:0 Missed beacon:0
wlan0 is the available wireless interface in this example.
- Bring the interface up with:
# ip link set wlan0 up
A small percentage of wireless chipsets also require firmware, in addition to a corresponding driver. If the wireless chipset requires firmware, you are likely to receive this error when bringing the interface up:
# ip link set wlan0 up
SIOCSIFFLAGS: No such file or directory
If unsure, invoke
/usr/bin/dmesg to query the kernel log for a firmware request from the wireless chipset. Example output from an Intel chipset which requires and has requested firmware from the kernel at boot:
$ dmesg | grep firmware
firmware: requesting iwlwifi-5000-1.ucode
If there is no output, it may be concluded that the system's wireless chipset does not require firmware.
- If the ESSID has been forgotten or is unknown, use
/sbin/iwlist <interface> scanto scan for nearby networks:
# iwlist wlan0 scan
Cell 01 - Address: 04:25:10:6B:7F:9D Channel:2 Frequency:2.417 GHz (Channel 2) Quality=31/70 Signal level=-79 dBm Encryption key:off ESSID:"dlink" Bit Rates:1 Mb/s; 2 Mb/s; 5.5 Mb/s; 11 Mb/s Bit Rates:6 Mb/s; 9 Mb/s; 12 Mb/s; 18 Mb/s; 24 Mb/s 36 Mb/s; 48 Mb/s; 54 Mb/s
- If using WPA encryption:
Using WPA encryption requires that the key be encrypted and stored in a file, along with the ESSID, to be used later for connection via
wpa_supplicant. Thus, a few extra steps are required:
For the purpose of simplifying and backup, rename the default
# mv /etc/wpa_supplicant.conf /etc/wpa_supplicant.conf.original
wpa_passphrase, provide your wireless network name and WPA key to be encrypted and written to
The following example encrypts the key "my_secret_passkey" of the "linksys" wireless network, generates a new configuration file (
/etc/wpa_supplicant.conf), and subsequently redirects the encrypted key, writing it to the file:
# wpa_passphrase linksys "my_secret_passkey" > /etc/wpa_supplicant.conf
Check WPA Supplicant for more information and troubleshooting.
- Associate your wireless device with the access point you want to use. Depending on the encryption (none, WEP, or WPA), the procedure may differ. You need to know the name of the chosen wireless network (ESSID).
|No Encryption|| |
|WEP w/ Hex Key|| |
|WEP w/ ASCII passphrase|| |
- After utilizing the appropriate association method outlined above, wait a few moments and confirm you have successfully associated to the access point before continuing, e.g.:
# iwconfig wlan0
Output should indicate the wireless network is associated with the interface.
- Request an IP address with
/sbin/dhcpcd <interface>, e.g.:
# dhcpcd wlan0
- Lastly, ensure you can route using
# ping -c 3 www.google.com
PING www.l.google.com (188.8.131.52) 56(84) bytes of data. 64 bytes from 184.108.40.206: icmp_req=1 ttl=49 time=87.7 ms 64 bytes from 220.127.116.11: icmp_req=2 ttl=49 time=87.0 ms 64 bytes from 18.104.22.168: icmp_req=3 ttl=49 time=94.6 ms --- www.l.google.com ping statistics --- 3 packets transmitted, 3 received, 0% packet loss, time 2002ms rtt min/avg/max/mdev = 87.052/89.812/94.634/3.430 ms
Hopefully you should have a working network connection. For troubleshooting, check the detailed Wireless Setup page.
Now you will be asked which text editor you want to use to modify configuration files. The choices are
vi. nano is generally considered easier for beginners because its behavior is more intuitive and resembles graphical word processors. The keyboard arrows, backspace, and delete keys, for example, operate as expected. A menu for the most common commands (eg. cut is Template:Keypress, paste is Template:Keypress, quit is Template:Keypress) is shown at the bottom of the nano terminal display. Please see the wiki pages Nano and Vi for detailed instructions.
Set region and timezone
Choose your region and timezone using the up and down arrows or skip to a section by typing the first letter, press enter to select.
Set time and date
Set the hardware clock mode. If this does not match the setting of your other operating systems, they will overwrite the time and cause clock shifts (which can cause time drift correction to be miscalibrated).
- UTC (recommended)
- localtime (discouraged) - Used by default in Windows. If time is set to localtime, DST shifts will not be made by Linux.
Setting time in a Windows dual boot setup
If you are setting up a dual-boot with Windows on your system, you have two options:
- Recommended: Set Arch Linux to UTC and make Windows use UTC too (a quick registry fix is needed, see this page for instructions). Also, be sure to prevent Windows from synchronizing the time with the Internet, as it will make the hardware clock use localtime again. If you want such functionality (NTP sync), you should use ntpd on your Arch Linux installation instead.
- Not recommended: Set Arch Linux to localtime and later (in Configure the system) remove
/etc/rc.conf(Windows will take care of hardware clock corrections).
Prepare hard drive
Verify current disk identities and layout by invoking
/sbin/fdisk with the
-l (lower-case L) switch.
Open another virtual console (Template:Keypress) and enter:
# fdisk -l
Take note of the disk(s) and/or partition(s) to utilize for the Arch installation.
Switch back to the installation script with Template:Keypress.
Select the menu entry "Prepare Hard Drive". A list of four options is presented:
- Option 1: Auto-Prepare
This will erase the ENTIRE hard drive and set up partitions automatically. Some customization is available.
- Option 2: Manually Partition Hard Drives
Recommended. This option uses the cfdisk utility and allows for the most robust and customized partitioning. After the partitions are setup, proceed to Option 3.
You can skip directly to this option if the hard drive has already been partitioned to your liking. Option 3 is also the next step of disk preparation that follows Option 2. The system will list what filesystems and mountpoints it has found and ask you if you wish to use them. You will be given a choice to select the desired method of identification, i.e. by dev, label, or uuid.
- Option 4: Rollback last filesystem changes
Reverts back to previous set of changes.
Options 1, 2, and 3 are explained in more detail below. To understand what is involved in these options, a short discussion on Linux partitions and filesystems is presented next. Advanced GNU/Linux users who are familiar and comfortable with manual partitioning may wish to skip down to Select packages below.
Partitioning hard disks: General information
Partitioning a hard disk drive defines specific memory storage areas. These are called partitions. Each partition behaves as a separate disk and is formatted with a specific filesystem type (see below).
There are 3 types of disk partitions:
Primary partitions can be bootable and are limited to four partitions per disk or RAID volume. If a partitioning scheme requires more than four partitions, an extended partition containing logical partitions is used. Extended partitions can be thought of as containers for logical partitions. A hard disk can contain no more than one extended partition. The extended partition is also counted as a primary partition so if the disk has an extended partition, only three additional primary partitions are possible (i.e. three primary partitions and one extended partition). The number of logical partitions residing in an extended partition is unlimited. A system that dual boots with Windows will require that Windows reside in a primary partition.
The customary numbering scheme is to create primary partitions
sda3 followed by an extended partition
sda4. The logical partitions on
sda4 are numbered
A swap partition is a place on the drive for virtual RAM. This allows the kernel to access disk space for data that does not fit into physical RAM.
Historically, the general rule for swap partition size was to allocate twice the amount of physical RAM. As computers have gained ever larger memory capacities, this rule has become deprecated. On machines with up to 512MB RAM, the 2x rule is usually adequate. If a sufficient amount of RAM (more than 1024MB) is available, it may be possible to have a smaller swap partition or even eliminate it. With more than 2 GB of physical RAM, one can generally expect good performance without a swap partition. There is always an option to create a swap file after the system is setup.
Selecting a partitioning scheme
There are no strict rules for partitioning a hard drive, although one may follow the general guidance given below. A disk partitioning scheme is determined by various issues such as desired flexibility, speed, security, as well as the limitations imposed by available disk space. It is essentially personal preference. Two simple possibilities are: i) one partition for root and one partition for swap or ii) just a single root partition without swap. Read through the following discussion and examples to understand the benefits and tradeoffs in making the decision. If you would like to dual boot Arch Linux and a Windows operating system please see Windows and Arch Dual Boot.
The following mountpoints are possible choices for separate partitions:
- The root directory is the top of the hierarchy, the point where the primary filesystem is mounted and from which all other filesystems stem. All files and directories appear under the root directory
/, even if they are stored on different physical devices. The contents of the root filesystem must be adequate to boot, restore, recover, and/or repair the system. Therefore, certain directories under
/are not candidates for separate partitions (See warning below).
- This directory contains the kernel and ramdisk images as well as the bootloader configuration file and bootloader stages. It also stores data that is used before the kernel begins executing user-space programs. This may include saved master boot sectors and sector map files. This directory is essential for booting, but is unique in that it may still be kept on its own optional partition.
- Provides subdirectories for each system user. It holds miscellaneous personal data as well as user-specific configuration files for applications.
- Directory for programs that require temporary storage of files such as
.lck, which can be used to prevent multiple instances of their respective program until a task is completed. Upon completion, the
.lckfile will be automatically removed. Programs must not assume that any files or directories in
/tmpare preserved between invocations of the program and files and directories located under
/tmpwill typically be deleted whenever the system is booted.
- Contains variable data such as spool directories and files, administrative and logging data, pacman's cache, the ABS tree, etc. It exists to make it possible to mount
/usras read-only. Everything that historically went into
/usrthat is written to during system operation (as opposed to installation and software maintenance) must reside under
There are several advantages for using discrete filesystems as opposed to placing everything in one partition:
- Security: Each filesystem may be configured in
/etc/fstabas 'nosuid', 'nodev', 'noexec', 'readonly', etc.
- Stability: A user, or malfunctioning program can completely fill a filesystem with garbage if they have write permissions for it. Critical programs residing on a different filesystem remain unaffected.
- Speed: A filesystem that gets re-written too frequently may become fragmented. Separate filesystems remain unaffected and each can be defragmented separately. Fragmentation can be avoided by ensuring that each filesystem is never in danger of filling up completely.
- Integrity: If one filesystem becomes corrupted, separate filesystems remain unharmed.
- Versatility: Sharing data across several systems becomes more expedient when independent filesystems are used. Separate filesystem types may also be chosen based upon the nature of data and usage.
How big should my partitions be?
The size of the partitions depends on personal preference, but the following information may be helpful:
- The root filesystem (
/) will contain the
/usrdirectory, which can grow significantly depending upon how much software is installed. 15-20 GB should be sufficient for most users with modern hard disks.
/varfilesystem will contain, among other data, the ABS tree and the pacman cache. Keeping cached packages is useful and versatile as it provides the ability to downgrade. As a result,
/vartends to grow in size. The pacman cache in particular will grow as the system is expanded and updated. It can, however, be safely cleared if space becomes an issue. If you are using an SSD, you may wish to locate your
/varon an HDD and keep the
/homepartitions on your SSD to avoid needless read/writes to the SSD. 8-12 GB on a desktop system should be sufficient for
/var, depending on how much software will be installed. Servers tend to have relatively larger
/homefilesystem is typically where user data, downloads, and multimedia reside. On a desktop system,
/homeis typically the largest filesystem on the drive by a large margin. If it becomes necessary to reinstall Arch, all the data on your
/homepartition will be retained if it is setup on its own partition.
/bootpartition requires only about 100MB.
- If available, an extra 25% of space added to each filesystem will provide a cushion for future expansion and help protect against fragmentation.
Creating filesystems: General information
Individual drive partitions can be setup using one of the many different available filesystems. Each has its own advantages, disadvantages, and unique idiosyncrasies. A brief overview of supported filesystems follows; the links are to wikipedia pages that provide much more information.
- ext2 Second Extended Filesystem is an established, mature GNU/Linux filesystem that is very stable. A drawback is that it does not have journaling support (see below) or barriers. Lack of journaling can result in data loss in the event of a power failure or system crash. It may also be inconvenient for root (
/homepartitions because file-system checks can take a long time. An ext2 filesystem can be converted to ext3.
- ext3 Third Extended Filesystem is essentially the ext2 system with journaling support and write barriers. It is backward compatible with ext2, well tested, and extremely stable.
- ext4 Fourth Extended Filesystem is a newer filesystem that is also compatible with ext2 and ext3. It provides support for volumes with sizes up to 1 exabyte (i.e. 1,048,576 terabytes) and files sizes up to 16 terabytes. It increases the 32,000 subdirectory limit in ext3 to 64,000. It also offers online defragmentation capability.
- ReiserFS (V3) Hans Reiser's high-performance journaling FS uses a very interesting method of data throughput based on an unconventional and creative algorithm. ReiserFS is touted as very fast, especially when dealing with many small files. ReiserFS is fast at formatting, yet comparatively slow at mounting. Quite mature and stable. ReiserFS (V3) is not being actively developed at this time. Generally regarded as a good choice for
- JFS IBM's Journaled File System was the first filesystem to offer journaling. It had many years of development in the IBM AIX® operating system before being ported to GNU/Linux. JFS makes the smallest demand on CPU resources of any GNU/Linux filesystem. It is very fast at formatting, mounting, and filesystem checks (fsck). JFS offers very good all-around performance especially in conjunction with the deadline I/O scheduler. It is not as widely supported as the ext series or ReiserFS, but still very mature and stable.
- XFS is another early journaling filesystem originally developed by Silicon Graphics for the IRIX operating system and ported to GNU/Linux. It provides very fast throughput on large files and filesystems and is very fast at formatting and mounting. Comparative benchmark testing has shown it to be slower when dealing with many small files. XFS is very mature and offers online defragmentation capability.
- vfat or Virtual File Allocation Table is technically simple and supported by virtually all existing operating systems. This makes it a useful format for solid-state memory cards and a convenient way to share data between operating systems. VFAT supports long file names.
- Btrfs Also known as "Better FS", Btrfs is a new filesystem with powerful features similar to Sun/Oracle's excellent ZFS. These include snapshots, multi-disk striping and mirroring (software RAID without mdadm), checksums, incremental backup, and on-the-fly compression that can give a significant performance boost as well as save space. As of January 2011, Btrfs is considered unstable although it has been merged into the mainline kernel with an experimental status. Btrfs appears to be the future of GNU/Linux filesystems and is offered as a root filesystem option in all major distribution installers.
- nilfs2 New Implementation of a Log-structured File System was developed by NTT. It records all data in a continuous log-like format that is only appended to and never overwritten. It is designed to reduce seek times and minimize the type of data loss that occurs after a crash with conventional Linux filesystems.
All the above filesystems with the exception of ext2 use journaling. Journaling provides fault-resilience by logging changes before they are committed to the filesystem. In the event of a system crash or power failure, such file systems are faster to bring back online and less likely to become corrupted. The logging takes place in a dedicated area of the filesystem.
Not all journaling techniques are the same. Only ext3 and ext4 offer data-mode journaling, which logs both data and meta-data. Data-mode journaling comes with a speed penalty and is not enabled by default. The other filesystems provide ordered-mode journaling, which only logs meta-data. While all journaling will return a filesystem to a valid state after a crash, data-mode journaling offers the greatest protection against corruption and data loss. There is a compromise in system performance, however, because data-mode journaling does two write operations: first to the journal and then to the disk. The trade-off between system speed and data safety should be a considered when choosing the filesystem type.
Option 1: Auto prepare
Auto-Prepare erases the entire drive and divides it into the following four partitions:
/bootpartition formatted ext2. The default size of 100MB can be changed.
/swappartition of default size of 256MB (adjustable).
/homepartitions with adjustable sizes and filesystems. Available filesystems include ext2, ext3, ext4, reiserfs, xfs, jfs, vfat, nilfs2 (experimental), and btrfs (experimental). Both
/homewill have the same filesystem type when using the Auto Prepare option.
Be warned that Auto-Prepare will completely format the entire hard drive. Read the warning presented by the installer very carefully and make sure the correct device is about to be partitioned.
If you do not wish to use the default configuration of Auto prepare, you can setup the partitions manually. This will be necessary if, for example, you are configuring a dual-boot system with an existing Windows partition. Manual partitioning can be accomplished with Option 2 (followed by Option 3) or by using a live media utility such as GParted.
Option 2: Manually partition hard drives
Choosing the target disk will open cfdisk for manual partitioning (if you have an SSD drive other choices like gdisk or GNU Parted may be preferable). Its operation can be understood with an example where four partitions are made on a 160 GB drive for root, var, swap, and home. Following the guidelines above, the example system will contain a 15GB root (
/) partition, a 10GB
/var partition, a 1GB swap partition, and a
/home partition for the remaining disk space. It is emphasized again that partitioning is a personal choice and this example is only for illustration.
Choose New -> 'Primary' and enter the desired size (15.44 GB in this example) for the root (
/) filesystem. The partition will be put at the beginning of the disk. Select the Type and designate it as
83 Linux. The created
/ partition will appear as
In a similar manner, create a second primary partition of size 10.256 GB for
/var, designating it as Type
83 Linux. The created
/var partition will appear as
Next, create a third partition for swap. Select an appropriate size (~1 GB here) and specify the Type as
82 (Linux swap / Solaris). The created swap partition will appear as
The remaining space is used to create a fourth partition for the
/home directory. Identify it as a primary partition and set the size. Select the Type as
83 Linux. The created
/home partition will appear as
This is how the example will look:
Name Flags Part Type FS Type [Label] Size (MB) ------------------------------------------------------------------------- sda1 Primary Linux 15440 #root sda2 Primary Linux 10256 #/var sda3 Primary Linux swap / Solaris 1024 #swap sda4 Primary Linux 133000 #/home
Choose Write and type
yes. Beware that this operation may destroy data on your disk. Choose Quit to leave the partitioner.
Familiarize yourself with the various filesystems discussed above and then proceed to Option 3.
Option 3: Manually configure block devices, filesystems, and mountpoints
This option requires the presence of existing partitions (generated in Option 2, for example) and is implemented as dev, label, or UUID. The list of recognized partitions will be shown. Each partition is identified with a number suffix. Example:
sda1 specifies the first partition of a drive while
sda designates the entire drive.
Format each partition with the desired filesystem and specify the mountpoints. You can choose a label and additional options for mkfs.
Return to the Main Menu.
All software packages available during installation are from the [core] repository. They are further divided into base (i686|x86_64), and base-devel (i686|x86_64) groups. Package information and brief descriptions for [core] are available here.
Now select the package category:
- base: Software packages from the [core] repo to provide the minimal base environment. Always select this and do not remove any packages from it, as all packages in Arch Linux assume that base is installed.
- base-devel: Extra tools from [core] such as
automake. Most beginners should choose to install it, as it will likely be needed to expand your new system. The base-devel group will be required to install software from the Arch User Repository.
After category selection, you will be presented with lists of available packages, allowing you to fine-tune your selections. Use the space bar to select and un-select. If you are uncertain about which additional packages to install at this point, you can skip this step and add them later using pacman.
After selecting the desired packages, leave the selection screen and continue to the next step, Install Packages.
Install Packages will install the selected packages to your new system. If you selected local sources, package versions from the CD-ROM/USB will be installed. If you opted for remote sources, the most currently available packages will be downloaded from the Internet and installed by pacman.
Configure the system
At this stage of the installation, you will configure the primary configuration files of your Arch Linux base system.
You will be presented with a menu including the main configuration files for your system.
Can the installer handle this more automatically?
Hiding the process of system configuration is in direct opposition to The Arch Way. While it is true that recent versions of the kernel and hardware probing tools offer excellent hardware support and auto-configuration, Arch presents the user all pertinent configuration files during installation for the purposes of transparency and system resource control. By the time you have finished modifying these files to your specifications, you will have learned the simple method of manual Arch Linux system configuration and become more familiar with the base structure, leaving you better prepared to use and maintain your new installation productively.
Arch Linux uses the file
/etc/rc.conf as the principal location for system configuration. This one file contains a wide range of configuration information such as timezone, keymap, kernel modules, networking, and startup daemons. It also contains settings that are sourced by the various
- This sets your location environment, which will be used by all i18n-aware applications and utilities. You can get a list of the available locales by running
locale -afrom the command line. This default is usually fine for US English users. If you experience problems such as alpha-numeric characters being replaced by squares you may want to replace "en_US.utf8" with "en_US".
- Set to yes to use the daemon locale with the environmental variable $LOCALE. Setting to no will use the C locale (default).
- Specifies whether the hardware clock, which is synchronized on boot and on shutdown, stores UTC time, or local time. See Set clock.
- Specify your time zone. (All available zones are under
- The available keymaps are in
/usr/share/kbd/keymaps. Please note that this setting is only valid for your TTYs, not any graphical window managers or X.
- Available alternate console fonts reside in
/usr/share/kbd/consolefonts/. The default (blank) is safe.
- Defines the console map to load with the setfont program at boot. Possible maps are found in
/usr/share/kbd/consoletrans, if needed. The default (blank) is safe.
- Select "yes" if you have a color monitor and wish to have colors in your consoles.
Example for LOCALIZATION:
LOCALE="en_US.utf8" DAEMON_LOCALE="no" HARDWARECLOCK="UTC" TIMEZONE="US/Eastern" KEYMAP="us" CONSOLEFONT= CONSOLEMAP= USECOLOR="yes"
- If you know a module is missing, it can be specified here. For example, if you will be using loopback filesystems, add "loop".
Example for HARDWARE:
# Scan hardware and load required modules at boot MODULES=()
- Set your hostname to your liking. This is the name of your computer. Whatever you put here, also put it in
- Specify the ethernet interface you want to be used for connecting to your local network.
- If you want to use a static IP for your computer, specify it here. Leave this blank for DHCP.
- Optional, defaults to 255.255.255.0. If you want to use a custom netmask, specify it here. Leave this blank for DHCP.
- Optional. If you want to use a custom broadcast address, specify it here. Leave this blank for DHCP.
- If you set a static IP in "address", enter the IP address of the default gateway (eg. your modem/router) here. Leave this blank for DHCP.
- Setting this to "yes" will enable graceful logouts if users are ssh'ed into the box and the box is being restarted or shutdown. This is required if the root device is on NFS.
- This is an optional setting to be enabled only if using the netcfg package with optional dialog package. Enable these netcfg profiles at boot-up. These are useful if you happen to need more advanced network features than the simple network service supports, such as multiple network configurations (ie, laptop users).
Example with Static IP:
HOSTNAME=arch interface=eth0 address=192.168.1.100 netmask=255.255.255.0 broadcast=192.168.1.255 gateway=192.168.1.1 #NETWORKS=(main)
Example with Dynamic IP (DHCP):
HOSTNAME=arch interface=eth0 address= netmask= broadcast= gateway= #NETWORKS=(main)
When using a static IP, modify
/etc/resolv.conf to specify the DNS servers of choice. Please see the section below regarding this file.
This array simply lists the names of those scripts contained in
/etc/rc.d/ which are to be started during the boot process, and the order in which they start. Asynchronous initialization by backgrounding is also supported and useful for speeding up boot:
DAEMONS=(network @syslog-ng netfs @crond)
- If a script name is prefixed with a bang (!), it is not executed.
- If a script is prefixed with an "at" symbol (@), it shall be executed in the background; the startup sequence will not wait for successful completion of each daemon before continuing to the next. (Useful for speeding up system boot). Do not background daemons that are needed by other daemons. For example "mpd" depends on "network", therefore backgrounding network may cause mpd to break.
- Edit this array whenever new system services are installed, if starting them automatically during boot is desired.
The daemons line need not be changed at this time, but it is useful to explain what daemons are, as they will be addressed later in this guide.
A daemon is a program that runs in the background, waiting for events to occur and offering services. A good example is a web server that waits for a request to deliver a page (e.g.: httpd) or an SSH server waiting for a user login (e.g.: sshd). While these are full-featured applications, there are also daemons whose work is not that visible. Examples are a daemon which writes messages into a log file (e.g. syslog, metalog), and a daemon which provides a graphical login (e.g.: gdm, kdm). All these programs can be added to the daemons line and will be started when the system boots. Useful daemons will be presented during this guide.
The fstab (for file systems table) is part of the system configuration listing all available disks and disk partitions, and indicating how they are to be initialized or otherwise integrated into the overall system's filesystem. The
/etc/fstab file is most commonly used by the mount command. The mount command takes a filesystem on a device, and adds it to the main system hierarchy that you see when you use your system. mount -a is called from
/etc/rc.sysinit, about 3/4 of the way through the boot process, and reads
/etc/fstab to determine which options should be used when mounting the specified devices therein. If noauto is appended to a filesystem in
/etc/fstab, mount -a will not mount it at boot.
An example of
# <file system> <dir> <type> <options> <dump> <pass> tmpfs /tmp tmpfs nodev,nosuid 0 0 UUID=0ddfbb25-9b00-4143-b458-bc0c45de47a0 / ext4 defaults 0 1 UUID=da6e64c6-f524-4978-971e-a3f5bd3c2c7b /var ext4 defaults 0 2 UUID=440b5c2d-9926-49ae-80fd-8d4b129f330b none swap defaults 0 0 UUID=95783956-c4c6-4fe7-9de6-1883a92c2cc8 /home ext4 defaults 0 2
- <file system>
- Describes the block device or remote filesystem to be mounted. For regular mounts, this field will contain a link to a block device node (as created by mknod which is called by udev at boot) for the device to be mounted; for instance,
- Describes the mount point for the filesystem. For swap partitions, this field should be specified as 'none'; (Swap partitions are not actually mounted.)
- Describes the type of the filesystem. The Linux kernel supports many filesystem types. (For the filesystems currently supported by the running kernel, see
/proc/filesystems). An entry 'swap' denotes a file or partition to be used for swapping. An entry 'ignore' causes the line to be ignored. This is useful to show disk partitions which are currently unused.
- Describes the mount options associated with the filesystem. It is formatted as a comma-separated list of options with no intervening spaces. It contains at least the type of mount plus any additional options appropriate to the filesystem type. For documentation on the available options for non-nfs file systems, see mount(8).
- Used by the dump(8) command to determine which filesystems are to be dumped. dump is a backup utility. If the fifth field is not present, a value of zero is returned and dump will assume that the filesystem does not need to be backed up. Note that dump is not installed by default.
- Used by the fsck(8) program to determine the order in which filesystem checks are done at boot time. The root filesystem should have the highest priority with <pass> of 1, and other filesystems you want to have checked should have a <pass> of 2. Filesystems with 0 <pass> will not be checked. Filesystems within a drive will be checked sequentially, but filesystems on different drives will be checked at the same time to utilize parallelism available in the hardware. If the sixth field is not present or zero, a value of zero is returned and fsck will assume that the filesystem does not need to be checked.
- For more information, see fstab.
This file allows further fine-tuning, through mkinitcpio, of the initial ram filesystem, or initramfs, (also historically referred to as the initial ramdisk or "initrd") for your system. The initramfs is a gzipped image that is read by the kernel during boot. The purpose of the initramfs is to bootstrap the system to the point where it can access the root filesystem. This means it has to load any modules that are required for devices like IDE, SCSI, or SATA drives (or USB/FW, if you are booting from a USB/FW drive). Once the initrramfs loads the proper modules, either manually or through udev, it passes control to the kernel and your boot continues. For this reason, the initramfs only needs to contain the modules necessary to access the root filesystem. It does not need to contain every module you would ever want to use. The majority of common kernel modules will be loaded later on by udev, during the init process.
mkinitcpio is the next generation of initramfs creation. It has many advantages over the old mkinitrd and mkinitramfs scripts.
- It uses glibc and busybox to provide a small and lightweight base for early userspace.
- It can use udev for hardware autodetection at runtime, thus preventing numerous unnecessary modules from being loaded.
- Its hook-based init script is easily extendable with custom hooks, which can easily be included in pacman packages without having to modifiy mkinitcpio itself.
- It already supports lvm2, dm-crypt for both legacy and luks volumes, raid, swsusp and TuxOnIce resuming and booting from usb mass storage devices.
- Many features can be configured from the kernel command line without having to rebuild the image.
- The mkinitcpio script makes it possible to include the image in a kernel, thus making a self-contained kernel image is possible.
- Its flexibility makes recompiling a kernel unnecessary in many cases.
If using RAID or LVM on the root filesystem, the appropriate HOOKS must be configured. See the wiki pages for LVM/RAID and Configuring mkinitcpio for more information. If using a non-US keyboard. add the
keymap hook to load your local keymap during boot. Add the
usbinput hook if using a USB keyboard (otherwise, if boot fails for some reason you will be asked to enter root's password for system maintenance but will be unable to do so). Remember to add the
usb hook when installing arch on an external hard drive, Comfact Flash, or SD card, which is connected via usb, e.g.:
HOOKS="base udev autodetect pata scsi sata usb filesystems keymap usbinput"
If you need support for booting from USB devices, FireWire devices, PCMCIA devices, NFS shares, software RAID arrays, LVM2 volumes, encrypted volumes, or DSDT support, configure your HOOKS accordingly.
This file can be used to set special configuration options for the kernel modules. It is unnecessary to configure this file in the example. The article on kernel modules has more information.
The resolver is a set of routines in the C library that provide access to the Internet Domain Name System (DNS). One of the main functions of DNS is to translate domain names into IP addresses, to make the Web a friendlier place. The resolver configuration file, or
/etc/resolv.conf, contains information that is read by the resolver routines the first time they are invoked by a process.
If you use a static IP, set your DNS servers in
/etc/resolv.conf (nameserver <ip-address>). You may have as many as you wish.
An example, using OpenDNS:
nameserver 22.214.171.124 nameserver 126.96.36.199
If you are using a router, you may specify your DNS servers in the router itself, and merely point to it from your
/etc/resolv.conf, using your router's IP (which is also your gateway from
If using DHCP, you may also specify your DNS servers in the router, or allow automatic assignment from your ISP, if your ISP is so equipped.
This file associates IP addresses with hostnames and aliases. Each host is represented by a single line.
<IP-address> <hostname> [aliases...]
Add your hostname, coinciding with the one specified in
/etc/rc.conf, as an alias, so that it looks like this:
127.0.0.1 localhost.localdomain localhost yourhostname
If you use a static IP, add another line using the syntax: <static-IP> <hostname.domainname.org> <hostname> e.g.:
192.168.1.100 yourhostname.domain.org yourhostname
/usr/sbin/locale-gen command reads from
/etc/locale.gen to generate specific locales. They can then be used by glibc and any other locale-aware program or library for rendering text, correctly displaying regional monetary values, time and date formats, alphabetic idiosyncrasies, and other locale-specific standards.
/etc/locale.gen is an empty file with commented documentation. Once edited, the file remains untouched.
locale-gen runs on every glibc upgrade, generating all the locales specified in
Choose the locale(s) you need by removing the # in front of the lines you want, e.g.:
en_US ISO-8859-1 en_US.UTF-8
The installer will now run the locale-gen script, which will generate the locales you specified. You may change your locale in the future by editing
/etc/locale.gen and subsequently running
locale-gen as root.
pacman will attempt to read
/etc/pacman.conf each time it is invoked. This configuration file is divided into sections, or repositories. Each section defines a package repository that pacman can use when searching for packages. The exception to this is the
options section, which defines global options.
Enable all desired repositories by removing the # in front of the 'Include =' and '[repository]' lines.
Mirror sites are Internet locations where exact copies of data reside. Multiple mirrors provide reliability, redundancy, and allow for faster data transfer depending on geographic location. Closer sites generally give faster data rates. Choose a mirror repository for
pacman by uncommenting the desired mirror locations in this file. Remember that ftp.archlinux.org is throttled, limiting downloads to 50 kB/s. Read the Mirrors wiki page for more details about setting up pacman mirrors. Note that the mirrors chosen here will carry over into your installation.
Finally, set a root password and make sure that you remember it later. Return to the Main Menu and continue with Installing Bootloader.
When you select "Done", the system will rebuild the images and put you back to the Main Menu. This may take some time.
Because we have no secondary operating system in our example, we will need a bootloader. GRUB (GRand Unified Bootloader) will be used in the following examples. Alternatively, you may choose LILO, Syslinux or GRUB2. Please see the related wiki and documentation pages if you choose to use a bootloader other than GRUB.
The provided GRUB configuration (
/boot/grub/menu.lst) should be sufficient, but verify its contents to ensure accuracy (specifically, ensure that the root (/) partition is specified by UUID on line 3). You may want to alter the resolution of the console by adding a vga=<number> kernel argument corresponding to your desired virtual console resolution. (A table of resolutions and the corresponding numbers is printed in the
- A printed menu selection. "Arch Linux (Main)" will be printed on the screen as a menu selection.
- GRUB's root; the drive and partition where the kernel (/boot) resides, according to system BIOS. (More accurately, where GRUB's stage2 file resides). NOT necessarily the root (/) file system, as they can reside on separate partitions. GRUB's numbering scheme starts at 0, and uses an hdx,x format regardless of IDE or SATA, and enclosed within parentheses. The example indicates that /boot is on the first partition of the first drive, according to the BIOS, so (hd0,0).
- This line specifies:
- The path and filename of the kernel relative to GRUB's root. In the example, /boot is merely a directory residing on the same partition as / and vmlinuz-linux is the kernel filename;
/boot/vmlinuz-linux. If /boot were on a separate partition, the path and filename would be simply
/vmlinuz-linux, being relative to GRUB's root.
root=argument to the kernel statement specifies the partition containing the root (/) directory in the booted system, (more accurately, the partition containing
/sbin/init). An easy way to distinguish the 2 appearances of "root" in
/boot/grub/menu.lstis to remember that the first root statement informs GRUB where the kernel resides, whereas the second
root=kernel argument tells the kernel where the root filesystem (/) resides.
- Kernel options: In our example, ro mounts the filesystem as read-only during startup, which is usually a safe default; you may wish to change this in case it causes problems booting. quiet sets the default kernel log level so that all messages during boot are suppressed except serious ones. Depending on hardware, rootdelay=8 may need to be added to the kernel options in order to be able to boot from an external usb hard drive.
- The path and filename of the kernel relative to GRUB's root. In the example, /boot is merely a directory residing on the same partition as / and vmlinuz-linux is the kernel filename;
- The path and filename of the initial RAM filesystem relative to GRUB's root. Again, in the example, /boot is merely a directory residing on the same partition as / and initramfs-linux.img is the initrd filename;
/boot/initramfs-linux.img. If /boot were on a separate partition, the path and filename would be simply /initramfs-linux.img, being relative to GRUB's root.
title Arch Linux (Main) root (hd0,0) kernel /boot/vmlinuz-linux root=/dev/sda1 ro quiet initrd /boot/initramfs-linux.img
Example for /boot on a separate partition:
title Arch Linux (Main) root (hd0,0) kernel /vmlinuz-linux root=/dev/sda3 ro quiet initrd /initramfs-linux.img
Install the GRUB bootloader to the Master Boot Record (/dev/sda in our example).
That is it; You have configured and installed your Arch Linux base system. Exit the install, and reboot:
# rebootTemplate:Beginners' Guide navigation