Handbuch:HPPA/Installation/Festplatten

Einführung in blockorientierte Geräte

Blockorientierte Geräte

Let's take a good look at disk-oriented aspects of Gentoo Linux and Linux in general, including Linux filesystems, partitions, and block devices. Once the ins and outs of disks and filesystems are understood, partitions and filesystems can be established for the Gentoo Linux installation.

To begin, let's look at block devices. The most famous block device is probably the one that represents the first drive in a Linux system, namely /dev/sda. SCSI and Serial ATA drives are both labeled /dev/sd*; even IDE drives are labeled /dev/sd* with the libata framework in the kernel. When using the old device framework, then the first IDE drive is /dev/hda.

The block devices above represent an abstract interface to the disk. User programs can use these block devices to interact with the disk without worrying about whether the drives are IDE, SCSI, or something else. The program can simply address the storage on the disk as a bunch of contiguous, randomly-accessible 512-byte blocks.

Partitionen und Slices

Obwohl es theoretisch möglich wäre die gesamte Festplatte für die Unterbringung eines Linux Systems zu nutzen, wird das in der Praxis selten gemacht. Statt dessen teilt man das gesamte Festplatten Block-Device in kleinere, besser verwaltbare Block Devices auf. Auf den meisten Systemen nennt man diese Partitionen. Andere Architekturen verwenden eine ähnliche Technik, genannt "Slices".

Entwurf Partitionsschema

How many partitions and how big?

The number of partitions is highly dependent on the environment. For instance, if there are lots of users, then it is advised to have /home/ separate as it increases security and makes backups easier. If Gentoo is being installed to perform as a mail server, then /var/ should be separate as all mails are stored inside /var/. A good choice of filesystem will then maximize the performance. Game servers will have a separate /opt/ as most gaming servers are installed there. The reason is similar for the /home/ directory: security and backups. In most situations, /usr/ is to be kept big: not only will it contain the majority of applications, it typically also hosts the Gentoo ebuild repository (by default located at /usr/portage) which already takes around 650 MiB. This disk space estimate excludes the packages/ and distfiles/ directories that are generally stored within this ebuild repository.

It very much depends on what the administrator wants to achieve. Separate partitions or volumes have the following advantages:

• Choose the best performing filesystem for each partition or volume.
• The entire system cannot run out of free space if one defunct tool is continuously writing files to a partition or volume.
• If necessary, file system checks are reduced in time, as multiple checks can be done in parallel (although this advantage is more with multiple disks than it is with multiple partitions).
• Security can be enhanced by mounting some partitions or volumes read-only, nosuid (setuid bits are ignored), noexec (executable bits are ignored) etc.

Jedoch haben viele Partitionen auch Nachteile. Wenn diese schlecht auf das System angepasst sind, hat dieses viel freien Speicherplatz auf einer Partition und keinen auf einer Anderen mehr übrig. Ein weiterer Nachteil besteht darin, dass separate Partitionen - vor allem für wichtige Mount-Pfade wie /usr/ oder /var/ - es notwendig ein initramfs während des Bootens zu benutzen, welches diese Partitionen vor der Ausführung anderer Bootskripte mountet.

Weiterhin gibt es ein Limit von maximal 15 Partitionen für SCSI und SATA Datenträger, es sei denn der Datenträger nutzt GPT-labels.

What about swap space?

Die perfekte Größe für eine Swap-Partition gibt es nicht. Der Zweck von Swap-Speicher es ist Festplattenspeicherplatz für den Kernel bereitzuhalten, wenn der interne Speicher (RAM) knapp wird. Der Swap-Speicher erlaubt dem Kernel Speicherseiten auf die vermutlich nicht bald zugegriffen wird auf die Platte auszulagern (Swap oder Page-Out) um Arbeitsspeicher freizumachen. Wird der Speicherinhalt plötzlich benötigt, müssen diese Speicherseiten (Pages) wieder zurück in den Arbeitsspeicher geladen werden (Page-In), dies dauert eine Weile (da Festplatten verglichen mit Arbeitsspeicher sehr langsam sind).

When the system is not going to run memory intensive applications or the system has lots of memory available, then it probably does not need much swap space. However, swap space is also used to store the entire memory in case of hibernation. If the system is going to need hibernation, then a bigger swap space is necessary, often at least the amount of memory installed in the system.

fdisk auf HPPA benutzen

Use fdisk to create the partitions needed:

HPPA machines use the PC standard DOS partition tables. To create a new DOS partition table press the o key.

Building a new DOS disklabel.

PALO (der HPPA Bootloader) benötigt eine besondere Partition, damit er funktioniert. Es muss eine mindestens 16 MB große Partition am Anfang der Festplatte für ihn erzeugt werden. Der Typ der Partition muss f0 (Linux/PA-RISC boot) sein.

/dev/sda2    /boot   ext2    noauto,noatime   1 1
/dev/sda3    none    swap    sw               0 0
/dev/sda4    /       ext4    noatime          0 0

In fdisk, such a partition layout looks like so:

Disk /dev/sda: 4294 MB, 4294816768 bytes
133 heads, 62 sectors/track, 1017 cylinders
Units = cylinders of 8246 * 512 = 4221952 bytes
  
   Device Boot      Start         End      Blocks   Id  System
/dev/sda1               1           8       32953   f0  Linux/PA-RISC boot
/dev/sda2               9          20       49476   83  Linux
/dev/sda3              21          70      206150   82  Linux swap
/dev/sda4              71        1017     3904481   83  Linux

Erstellung von Dateisystemen

Einleitung

Now that the partitions are created, it is time to place a filesystem on them. In the next section the various file systems that Linux supports are described. Readers that already know which filesystem to use can continue with Applying a filesystem to a partition. The others should read on to learn about the available filesystems...

Dateisysteme

Several filesystems are available. Some of them are found stable on the hppa architecture - it is advised to read up on the filesystems and their support state before selecting a more experimental one for important partitions.

btrfs

A next generation filesystem that provides many advanced features such as snapshotting, self-healing through checksums, transparent compression, subvolumes and integrated RAID. A few distributions have begun to ship it as an out-of-the-box option, but it is not production ready. Reports of filesystem corruption are common. Its developers urge people to run the latest kernel version for safety because the older ones have known problems. This has been the case for years and it is too early to tell if things have changed. Fixes for corruption issues are rarely backported to older kernels. Proceed with caution when using this filesystem!

ext2

This is the tried and true Linux filesystem but doesn't have metadata journaling, which means that routine ext2 filesystem checks at startup time can be quite time-consuming. There is now quite a selection of newer-generation journaled filesystems that can be checked for consistency very quickly and are thus generally preferred over their non-journaled counterparts. Journaled filesystems prevent long delays when the system is booted and the filesystem happens to be in an inconsistent state.

ext3

The journaled version of the ext2 filesystem, providing metadata journaling for fast recovery in addition to other enhanced journaling modes like full data and ordered data journaling. It uses an HTree index that enables high performance in almost all situations. In short, ext3 is a very good and reliable filesystem.

ext4

Initially created as a fork of ext3, ext4 brings new features, performance improvements, and removal of size limits with moderate changes to the on-disk format. It can span volumes up to 1 EB and with maximum file size of 16TB. Instead of the classic ext2/3 bitmap block allocation ext4 uses extents, which improve large file performance and reduce fragmentation. Ext4 also provides more sophisticated block allocation algorithms (delayed allocation and multiblock allocation) giving the filesystem driver more ways to optimize the layout of data on the disk. Ext4 is the recommended all-purpose all-platform filesystem.

f2fs

The Flash-Friendly File System was originally created by Samsung for the use with NAND flash memory. As of Q2, 2016, this filesystem is still considered immature, but it is a decent choice when installing Gentoo to microSD cards, USB drives, or other flash-based storage devices.

JFS

IBM's high-performance journaling filesystem. JFS is a light, fast and reliable B+tree-based filesystem with good performance in various conditions.

ReiserFS

A B+tree-based journaled filesystem that has good overall performance, especially when dealing with many tiny files at the cost of more CPU cycles. ReiserFS appears to be less maintained than other filesystems.

XFS

A filesystem with metadata journaling which comes with a robust feature-set and is optimized for scalability. XFS seems to be less forgiving to various hardware problems.

vfat

Also known as FAT32, is supported by Linux but does not support any permission settings. It is mostly used for interoperability with other operating systems (mainly Microsoft Windows) but is also a necessity for some system firmware (like UEFI).

NTFS

This "New Technology" filesystem is the flagship filesystem of Microsoft Windows. Similar to vfat above it does not store permission settings or extended attributes necessary for BSD or Linux to function properly, therefore it cannot be used as a root filesystem. It should only be used for interoperability with Microsoft Windows systems (note the emphasis on only).

When using ext2, ext3, or ext4 on a small partition (less than 8GB), then the file system must be created with the proper options to reserve enough inodes. The mke2fs (mkfs.ext2) application uses the "bytes-per-inode" setting to calculate how many inodes a file system should have. On smaller partitions, it is advised to increase the calculated number of inodes.

Bei ext2 kann dies mit dem folgenden Befehl erfolgen:

Bei ext3 und ext4 fügen Sie die Option -j hinzu um Journaling zu aktivieren:

Dies vervierfacht die Zahl der Inodes für ein angegebenes Dateisystem in der Regel, da es dessen "bytes-per-inode" (Bytes pro Inode) von 16 kB auf 4 kB pro Inode reduziert. Durch die Angabe des Verhältnisses kann dies sogar weiter optimiert werden:

Dateisystem auf Partition anlegen

To create a filesystem on a partition or volume, there are user space utilities available for each possible filesystem. Click the filesystem's name in the table below for additional information on each filesystem:

For instance, to have the boot partition (/dev/sda2) in ext2 and the root partition (/dev/sda4) in ext4 as used in the example partition structure, the following commands would be used:

Erzeugen Sie nun die Dateisysteme auf den zuvor erzeugten Partitionen (oder logischen Laufwerken).

Activating the swap partition

mkswap is the command that is used to initialize swap partitions:

To activate the swap partition, use swapon:

Erzeugen und aktivieren Sie jetzt die Swap-Partition mit den oben genannten Befehlen.

Einhängen

Now that the partitions are initialized and are housing a filesystem, it is time to mount those partitions. Use the mount command, but don't forget to create the necessary mount directories for every partition created. As an example we mount the root partition:

In der Anleitung wird später das Dateisystem proc (eine virtuelle Schnittstelle zum Kernel) zusammen mit anderen Kernel-Pseudodateisystemen eingehängt. Zunächst installieren wir jedoch die Gentoo Installationsdateien.