Jump to contentJump to page navigation: previous page [access key p]/next page [access key n]
Applies to SUSE Linux Enterprise Server 15

1 Overview of File Systems in Linux

SUSE Linux Enterprise Server ships with different file systems from which to choose, including Btrfs, Ext4, Ext3, Ext2 and XFS. Each file system has its own advantages and disadvantages. For a side-by-side feature comparison of the major operating systems in SUSE Linux Enterprise Server, see http://www.suse.com/products/server/technical-information/#FileSystem (File System Support and Sizes). This chapter contains an overview of how these file systems work and what advantages they offer.

With SUSE Linux Enterprise 12, Btrfs is the default file system for the operating system and XFS is the default for all other use cases. SUSE also continues to support the Ext family of file systems, and OCFS2. By default, the Btrfs file system will be set up with subvolumes. Snapshots will be automatically enabled for the root file system using the snapper infrastructure. For more information about snapper, refer to Chapter 7, System Recovery and Snapshot Management with Snapper.

Professional high-performance setups might require a highly available storage system. To meet the requirements of high-performance clustering scenarios, SUSE Linux Enterprise Server includes OCFS2 (Oracle Cluster File System 2) and the Distributed Replicated Block Device (DRBD) in the High Availability Extension add-on. These advanced storage systems are not covered in this guide. For information, see the SUSE Linux Enterprise High Availability Extension Administration Guide at http://www.suse.com/doc.

It is very important to remember that no file system best suits all kinds of applications. Each file system has its particular strengths and weaknesses, which must be taken into account. In addition, even the most sophisticated file system cannot replace a reasonable backup strategy.

The terms data integrity and data consistency, when used in this section, do not refer to the consistency of the user space data (the data your application writes to its files). Whether this data is consistent must be controlled by the application itself.

Unless stated otherwise in this section, all the steps required to set up or change partitions and file systems can be performed by using the YaST Partitioner (which is also strongly recommended). For information, see Capítulo 9, Particionador en modo experto.

1.1 Terminology


A data structure that is internal to the file system. It ensures that all of the on-disk data is properly organized and accessible. Almost every file system has its own structure of metadata, which is one reason the file systems show different performance characteristics. It is extremely important to maintain metadata intact, because otherwise all data on the file system could become inaccessible.


A data structure on a file system that contains a variety of information about a file, including size, number of links, pointers to the disk blocks where the file contents are actually stored, and date and time of creation, modification, and access.


In the context of a file system, a journal is an on-disk structure containing a type of log in which the file system stores what it is about to change in the file system’s metadata. Journaling greatly reduces the recovery time of a file system because it has no need for the lengthy search process that checks the entire file system at system start-up. Instead, only the journal is replayed.

1.2 Btrfs

Btrfs is a copy-on-write (COW) file system developed by Chris Mason. It is based on COW-friendly B-trees developed by Ohad Rodeh. Btrfs is a logging-style file system. Instead of journaling the block changes, it writes them in a new location, then links the change in. Until the last write, the new changes are not committed.

1.2.1 Key Features

Btrfs provides fault tolerance, repair, and easy management features, such as the following:

  • Writable snapshots that allow you to easily roll back your system if needed after applying updates, or to back up files.

  • Subvolume support: Btrfs creates a default subvolume in its assigned pool of space. It allows you to create additional subvolumes that act as individual file systems within the same pool of space. The number of subvolumes is limited only by the space allocated to the pool.

  • The online check and repair functionality scrub is available as part of the Btrfs command line tools. It verifies the integrity of data and metadata, assuming the tree structure is fine. You can run scrub periodically on a mounted file system; it runs as a background process during normal operation.

  • Different RAID levels for metadata and user data.

  • Different checksums for metadata and user data to improve error detection.

  • Integration with Linux Logical Volume Manager (LVM) storage objects.

  • Integration with the YaST Partitioner and AutoYaST on SUSE Linux Enterprise Server. This also includes creating a Btrfs file system on Multiple Devices (MD) and Device Mapper (DM) storage configurations.

  • Offline migration from existing Ext2, Ext3, and Ext4 file systems.

  • Boot loader support for /boot, allowing to boot from a Btrfs partition.

  • Multivolume Btrfs is supported in RAID0, RAID1, and RAID10 profiles in SUSE Linux Enterprise Server 15. Higher RAID levels are not supported yet, but might be enabled with a future service pack.

  • Use Btrfs commands to set up transparent compression.

1.2.2 The Root File System Setup on SUSE Linux Enterprise Server

By default, SUSE Linux Enterprise Server is set up using Btrfs and snapshots for the root partition. Snapshots allow you to easily roll back your system if needed after applying updates, or to back up files. Snapshots can easily be managed with the SUSE Snapper infrastructure as explained in Chapter 7, System Recovery and Snapshot Management with Snapper. For general information about the SUSE Snapper project, see the Snapper Portal wiki at OpenSUSE.org (http://snapper.io).

When using a snapshot to roll back the system, it must be ensured that data such as user's home directories, Web and FTP server contents or log files do not get lost or overwritten during a roll back. This is achieved by using Btrfs subvolumes on the root file system. Subvolumes can be excluded from snapshots. The default root file system setup on SUSE Linux Enterprise Server as proposed by YaST during the installation contains the following subvolumes. They are excluded from snapshots for the reasons given below.

/boot/grub2/i386-pc, /boot/grub2/x86_64-efi, /boot/grub2/powerpc-ieee1275, /boot/grub2/s390x-emu

No se admite la reversión de la configuración del cargador de arranque. Los directorios mostrados anteriormente son específicos de la arquitectura. Los dos primeros directorios están presentes en equipos AMD64/Intel 64, los dos últimos en IBM POWER e IBM Z, respectivamente.


Si /home no se encuentra en una partición independiente, se excluye para evitar la pérdida de datos cuando se produce una reversión.

/opt, /var/opt

Normalmente, los productos de otros fabricantes se instalan en /opt. Se excluye para evitar la desinstalación de estas aplicaciones cuando se produce una reversión.


Contiene datos de los servidores Web y FTP. Se excluye para evitar la pérdida de datos cuando se produce una reversión.

/tmp, /var/tmp, /var/cache, /var/crash

Todos los directorios que contienen archivos temporales y cachés se excluyen de las instantáneas.


Este directorio se usa cuando se instala manualmente el software. Se excluye para evitar la desinstalación de estas instalaciones cuando se produce una reversión.


La ubicación por defecto de las imágenes de máquina virtual gestionadas con libvirt. Se excluye para garantizar que las imágenes de máquina virtual no se sustituyen con las versiones anteriores durante una operación de reversión. Por defecto, este subvolumen se crea con la opción sin copia al escribir.

/var/lib/mailman, /var/spool

Para evitar la pérdida de correos después de una operación de reversión, los directorios que contienen mensajes de correo o colas de correo se excluyen.


Contiene datos de la zona para el servidor DNS. Se excluye de las instantáneas para garantizar que un servidor de nombres pueda funcionar tras una operación de reversión.

/var/lib/mariadb, /var/lib/mysql, /var/lib/pgqsl

Estos directorios contienen datos de la base de datos. Por defecto, estos subvolúmenes se crean con la opción sin copia al escribir.


Ubicación del archivo de registro. Se excluye de las instantáneas para permitir el análisis del archivo de registro después de la restauración de un sistema dañado.

Warning: Support for Rollbacks

Rollbacks are only supported by the SUSE support if you do not remove any of the preconfigured subvolumes. You may, however, add subvolumes using the YaST Partitioner. Mounting Compressed Btrfs File Systems

Note: GRUB 2 and LZO Compressed Root

GRUB 2 cannot read an lzo compressed root. You need a separate /boot partition to use compression.

Since SLE12 SP1, compression for Btrfs file systems is supported. Use the compress or compress-force option and select the compression algorithm, lzo or zlib (the default). The zlib compression has a higher compression ratio while lzo is faster and takes less CPU load.

For example:

root # mount -o compress /dev/sdx /mnt

In case you create a file, write to it, and the compressed result is greater or equal to the uncompressed size, Btrfs will skip compression for future write operations forever for this file. If you do not like this behavior, use the compress-force option. This can be useful for files that have some initial uncompressible data.

Note, compression takes effect for new files only. Files that were written without compression are not compressed when the file system is mounted with the compress or compress-force option. Furthermore, files with the nodatacow attribute never get their extents compressed:

root # chattr +C FILE
root # mount -o nodatacow  /dev/sdx /mnt

In regard to encryption, this is independent from any compression. After you have written some data to this partition, print the details:

root # btrfs filesystem show /mnt
btrfs filesystem show /mnt
Label: 'Test-Btrfs'  uuid: 62f0c378-e93e-4aa1-9532-93c6b780749d
        Total devices 1 FS bytes used 3.22MiB
      devid    1 size 2.00GiB used 240.62MiB path /dev/sdb1

If you want this to be permanent, add the compress or compress-force option into the /etc/fstab configuration file. For example:

UUID=1a2b3c4d /home btrfs subvol=@/home,compress 0 0 Mounting Subvolumes

A system rollback from a snapshot on SUSE Linux Enterprise Server is performed by booting from the snapshot first. This allows you to check the snapshot while running before doing the rollback. Being able to boot from snapshots is achieved by mounting the subvolumes (which would normally not be necessary).

In addition to the subvolumes listed in Section 1.2.2, “The Root File System Setup on SUSE Linux Enterprise Server a volume named @ exists. This is the default subvolume that will be mounted as the root partition (/). The other subvolumes will be mounted into this volume.

When booting from a snapshot, not the @ subvolume will be used, but rather the snapshot. The parts of the file system included in the snapshot will be mounted read-only as /. The other subvolumes will be mounted writable into the snapshot. This state is temporary by default: the previous configuration will be restored with the next reboot. To make it permanent, execute the snapper rollback command. This will make the snapshot that is currently booted the new default subvolume, which will be used after a reboot. Checking for Free Space

File system usage is usually checked by running the df command. On a Btrfs file system, the output of df can be misleading, because in addition to the space the raw data allocates, a Btrfs file system also allocates and uses space for metadata.

Consequently a Btrfs file system may report being out of space even though it seems that plenty of space is still available. In that case, all space allocated for the metadata is used up. Use the following commands to check for used and available space on a Btrfs file system:

btrfs filesystem show
tux > sudo btrfs filesystem show /
Label: 'ROOT'  uuid: 52011c5e-5711-42d8-8c50-718a005ec4b3
        Total devices 1 FS bytes used 10.02GiB
        devid    1 size 20.02GiB used 13.78GiB path /dev/sda3

Shows the total size of the file system and its usage. If these two values in the last line match, all space on the file system has been allocated.

btrfs filesystem df
tux > sudo btrfs filesystem df /
Data, single: total=13.00GiB, used=9.61GiB
System, single: total=32.00MiB, used=16.00KiB
Metadata, single: total=768.00MiB, used=421.36MiB
GlobalReserve, single: total=144.00MiB, used=0.00B

Shows values for allocated (total) and used space of the file system. If the values for total and used for the metadata are almost equal, all space for metadata has been allocated.

btrfs filesystem usage
tux > sudo btrfs filesystem usage /
    Device size:                  20.02GiB
    Device allocated:             13.78GiB
    Device unallocated:            6.24GiB
    Device missing:                  0.00B
    Used:                         10.02GiB
    Free (estimated):              9.63GiB      (min: 9.63GiB)
    Data ratio:                       1.00
    Metadata ratio:                   1.00
    Global reserve:              144.00MiB      (used: 0.00B)

             Data     Metadata  System
Id Path      single   single    single   Unallocated
-- --------- -------- --------- -------- -----------
 1 /dev/sda3 13.00GiB 768.00MiB 32.00MiB     6.24GiB
-- --------- -------- --------- -------- -----------
   Total     13.00GiB 768.00MiB 32.00MiB     6.24GiB
   Used       9.61GiB 421.36MiB 16.00KiB

Shows data similar to that of the two previous commands combined.

For more information refer to man 8 btrfs-filesystem and https://btrfs.wiki.kernel.org/index.php/FAQ.

1.2.3 Migration from ReiserFS and Ext File Systems to Btrfs

You can migrate data volumes from existing ReiserFS or Ext (Ext2, Ext3, or Ext4) to the Btrfs file system using the btrfs-convert tool. This allows you to do an in-place conversion of unmounted (offline) file systems, which may require a bootable install media with the btrfs-convert tool. The tool constructs a Btrfs file system within the free space of the original file system, directly linking to the data contained in it. There must be enough free space on the device to create the metadata or the conversion will fail. The original file system will be intact and no free space will be occupied by the Btrfs file system. The amount of space required is dependent on the content of the file system and can vary based on the number of file system objects (such as files, directories, extended attributes) contained in it. Since the data is directly referenced, the amount of data on the file system does not impact the space required for conversion, except for files that use tail packing and are larger than about 2 KiB in size.

To convert the original file system to the Btrfs file system, run:

root # btrfs-convert /path/to/device
Important: Check /etc/fstab

After the conversion, you need to ensure that any references to the original file system in /etc/fstab have been adjusted to indicate that the device contains a Btrfs file system.

When converted, the contents of the Btrfs file system will reflect the contents of the source file system. The source file system will be preserved until you remove the related read-only image created at fs_root/reiserfs_saved/image. The image file is effectively a 'snapshot' of the ReiserFS file system prior to conversion and will not be modified as the Btrfs file system is modified. To remove the image file, remove the reiserfs_saved subvolume:

root # btrfs subvolume delete fs_root/reiserfs_saved>

To revert the file system back to the original one, use the following command:

root # btrfs-convert -r /path/to/device
Warning: Lost Changes

Any changes you made to the file system while it was mounted as a Btrfs file system will be lost. A balance operation must not have been performed in the interim, or the file system will not be restored correctly.

1.2.4 Btrfs Administration

Btrfs is integrated in the YaST Partitioner and AutoYaST. It is available during the installation to allow you to set up a solution for the root file system. You can use the YaST Partitioner after the installation to view and manage Btrfs volumes.

Btrfs administration tools are provided in the btrfsprogs package. For information about using Btrfs commands, see the man 8 btrfs, man 8 btrfsck, and man 8 mkfs.btrfs commands. For information about Btrfs features, see the Btrfs wiki at http://btrfs.wiki.kernel.org.

1.2.5 Btrfs Quota Support for Subvolumes

The Btrfs root file system subvolumes /var/log, /var/crash and /var/cache can use all of the available disk space during normal operation, and cause a system malfunction. To help avoid this situation, SUSE Linux Enterprise Server now offers Btrfs quota support for subvolumes. If you set up the root file system by using the respective YaST proposal, it is prepared accordingly: quota groups (qgroup) for all subvolumes are already set up. To set a quota for a subvolume in the root file system, proceed as follows:

  1. Enable quota support:

    tux > sudo btrfs quota enable /
  2. Get a list of subvolumes:

    tux > sudo btrfs subvolume list /

    Quotas can only be set for existing subvolumes.

  3. Set a quota for one of the subvolumes that was listed in the previous step. A subvolume can either be identified by path (for example /var/tmp) or by 0/SUBVOLUME ID (for example 0/272). The following example sets a quota of 5 GB for /var/tmp.

    tux > sudo btrfs qgroup limit 5G /var/tmp

    The size can either be specified in bytes (5000000000), kilobytes (5000000K), megabytes (5000M), or gigabytes (5G). The resulting values in bytes slightly differ, since 1024 Bytes = 1 KiB, 1024 KiB = 1 MiB, etc.

  4. To list the existing quotas, use the following command. The column max_rfer shows the quota in bytes.

    tux > sudo btrfs qgroup show -r /
Tip: Nullifying a Quota

In case you want to nullify an existing quota, set a quota size of none:

tux > sudo btrfs qgroup limit none /var/tmp

To disable quota support for a partition and all its subvolumes, use btrfs quota disable:

tux > sudo btrfs quota disable /

See the man 8 btrfs-qgroup and man 8 btrfs-quota for more details. The UseCases page on the Btrfs wiki (https://btrfs.wiki.kernel.org/index.php/UseCases) also provides more information.

1.2.6 Btrfs send/receive

Btrfs allows to make snapshots to capture the state of the file system. Snapper, for example, uses this feature to create snapshots before and after system changes, allowing a rollback. However, together with the send/receive feature, snapshots can also be used to create and maintain copies of a file system in a remote location. This feature can, for example, be used to do incremental backups.

A btrfs send operation calculates the difference between two read-only snapshots from the same subvolume and sends it to a file or to STDOUT. A btrfs receive operation takes the result of the send command and applies it to a snapshot. Prerequisites

To use Btrfs's send/receive feature, the following requirements need to be met:

  • A Btrfs file system is required on the source side (send) and on the target side (receive).

  • Btrfs send/receive operates on snapshots, therefore the respective data needs to reside in a Btrfs subvolume.

  • Snapshots on the source side need to be read-only.

  • SUSE Linux Enterprise 12 SP2 or better. Earlier versions of SUSE Linux Enterprise do not support send/receive. Incremental Backups

The following procedure shows the basic usage of Btrfs send/receive using the example of creating incremental backups of /data (source side) in /backup/data (target side). /data needs to be a subvolume.

Procedure 1.1: Initial Setup
  1. Create the initial snapshot (called snapshot_0 in this example) on the source side and make sure it is written to the disk:

    tux > sudo btrfs subvolume snapshot -r /data /data/bkp_data

    A new subvolume /data/bkp_data is created. It will be used as the basis for the next incremental backup and should be kept as a reference.

  2. Send the initial snapshot to the target side. Since this is the initial send/receive operation, the complete snapshot needs to be sent:

    tux > sudo bash -c 'btrfs send /data/bkp_data | btrfs receive /backup'

    A new subvolume /backup/bkp_data is created on the target side.

When the initial setup has been finished, you can create incremental backups and send the differences between the current and previous snapshots to the target side. The procedure is always the same:

  1. Create a new snapshot on the source side.

  2. Send the differences to the target side.

  3. Optional: Rename and/or clean up snapshots on both sides.

Procedure 1.2: Performing an Incremental Backup
  1. Create a new snapshot on the source side and make sure it is written to the disk. In the following example the snapshot is named bkp_data_CURRENT_DATE:

    tux > sudo btrfs subvolume snapshot -r /data /data/bkp_data_$(date +%F)

    A new subvolume, for example /data/bkp_data_2016-07-07, is created.

  2. Send the difference between the previous snapshot and the one you have created to the target side. This is achieved by specifying the previous snapshot with the option -p SNAPSHOT.

    tux > sudo bash -c 'btrfs send -p /data/bkp_data /data/bkp_data_2016-07-07 \
    | btrfs receive /backup'

    A new subvolume /backup/bkp_data_2016-07-07 is created.

  3. As a result four snapshots, two on each side, exist:


    Now you have three options for how to proceed:

    • Keep all snapshots on both sides. With this option you can roll back to any snapshot on both sides while having all data duplicated at the same time. No further action is required. When doing the next incremental backup, keep in mind to use the next-to-last snapshot as parent for the send operation.

    • Only keep the last snapshot on the source side and all snapshots on the target side. Also allows to roll back to any snapshot on both sides—to do a rollback to a specific snapshot on the source side, perform a send/receive operation of a complete snapshot from the target side to the source side. Do a delete/move operation on the source side.

    • Only keep the last snapshot on both sides. This way you have a backup on the target side that represents the state of the last snapshot made on the source side. It is not possible to roll back to other snapshots. Do a delete/move operation on the source and the target side.

    1. To only keep the last snapshot on the source side, perform the following commands:

      tux > sudo btrfs subvolume delete /data/bkp_data
      tux > sudo mv /data/bkp_data_2016-07-07 /data/bkp_data

      The first command will delete the previous snapshot, the second command renames the current snapshot to /data/bkp_data. This ensures that the last snapshot that was backed up is always named /data/bkp_data. As a consequence, you can also always use this subvolume name as a parent for the incremental send operation.

    2. To only keep the last snapshot on the target side, perform the following commands:

      tux > sudo btrfs subvolume delete /backup/bkp_data
      tux > sudo mv /backup/bkp_data_2016-07-07 /backup/bkp_data

      The first command will delete the previous backup snapshot, the second command renames the current backup snapshot to /backup/bkp_data. This ensures that the latest backup snapshot is always named /backup/bkp_data.

Tip: Sending to a Remote Target Side

To send the snapshots to a remote machine, use SSH:

tux > btrfs send /data/bkp_data | ssh root@jupiter.example.com 'btrfs receive /backup'

1.2.7 Data Deduplication Support

Btrfs supports data deduplication by replacing identical blocks in the file system with logical links to a single copy of the block in a common storage location. SUSE Linux Enterprise Server provides the tool duperemove for scanning the file system for identical blocks. When used on a Btrfs file system, it can also be used to deduplicate these blocks. duperemove is not installed by default. To make it available, install the package duperemove .

Note: Use Cases

As of SUSE Linux Enterprise Server 15 duperemove is not suited to deduplicate the entire file system. It is intended to be used to deduplicate a set of 10 to 50 large files that possibly have lots of blocks in common, such as virtual machine images.

duperemove can either operate on a list of files or recursively scan a directory:

tux > sudo duperemove OPTIONS file1 file2 file3
tux > sudo duperemove -r OPTIONS directory

It operates in two modes: read-only and de-duping. When run in read-only mode (that is without the -d switch), it scans the given files or directories for duplicated blocks and prints them. This works on any file system.

Running duperemove in de-duping mode is only supported on Btrfs file systems. After having scanned the given files or directories, the duplicated blocks will be submitted for deduplication.

For more information see man 8 duperemove.

1.3 XFS

Originally intended as the file system for their IRIX OS, SGI started XFS development in the early 1990s. The idea behind XFS was to create a high-performance 64-bit journaling file system to meet extreme computing challenges. XFS is very good at manipulating large files and performs well on high-end hardware. XFS is the default file system for data partitions in SUSE Linux Enterprise Server.

A quick review of XFS’s key features explains why it might prove to be a strong competitor for other journaling file systems in high-end computing.

1.3.1 High Scalability by Using Allocation Groups

At the creation time of an XFS file system, the block device underlying the file system is divided into eight or more linear regions of equal size. Those are called allocation groups. Each allocation group manages its own inodes and free disk space. Practically, allocation groups can be seen as file systems in a file system. Because allocation groups are rather independent of each other, more than one of them can be addressed by the kernel simultaneously. This feature is the key to XFS’s great scalability. Naturally, the concept of independent allocation groups suits the needs of multiprocessor systems.

1.3.2 High Performance through Efficient Management of Disk Space

Free space and inodes are handled by B+ trees inside the allocation groups. The use of B+ trees greatly contributes to XFS’s performance and scalability. XFS uses delayed allocation, which handles allocation by breaking the process into two pieces. A pending transaction is stored in RAM and the appropriate amount of space is reserved. XFS still does not decide where exactly (in file system blocks) the data should be stored. This decision is delayed until the last possible moment. Some short-lived temporary data might never make its way to disk, because it is obsolete by the time XFS decides where actually to save it. In this way, XFS increases write performance and reduces file system fragmentation. Because delayed allocation results in less frequent write events than in other file systems, it is likely that data loss after a crash during a write is more severe.

1.3.3 Preallocation to Avoid File System Fragmentation

Before writing the data to the file system, XFS reserves (preallocates) the free space needed for a file. Thus, file system fragmentation is greatly reduced. Performance is increased because the contents of a file are not distributed all over the file system.

Note: The new XFS On-disk Format

Starting with version 12, SUSE Linux Enterprise Server supports the new on-disk format (v5) of the XFS file system. XFS file systems created by YaST will use this new format. The main advantages of this format are automatic checksums of all XFS metadata, file type support, and support for a larger number of access control lists for a file.

Note that this format is not supported by SUSE Linux Enterprise kernels older than version 3.12, by xfsprogs older than version 3.2.0, and GRUB 2 versions released before SUSE Linux Enterprise 12. This will be problematic if the file system should also be used from systems not meeting these prerequisites.

If you require interoperability of the XFS file system with older SUSE systems or other Linux distributions, format the file system manually using the mkfs.xfs command. This will create an XFS file system in the old format (unless you use the -m crc=1 option).

1.4 Ext2

The origins of Ext2 go back to the early days of Linux history. Its predecessor, the Extended File System, was implemented in April 1992 and integrated in Linux 0.96c. The Extended File System underwent several modifications and, as Ext2, became the most popular Linux file system for years. With the creation of journaling file systems and their short recovery times, Ext2 became less important.

A brief summary of Ext2’s strengths might help understand why it was—and in some areas still is—the favorite Linux file system of many Linux users.

Solidity and Speed

Being an old-timer, Ext2 underwent many improvements and was heavily tested. This might be the reason people often refer to it as rock-solid. After a system outage when the file system could not be cleanly unmounted, e2fsck starts to analyze the file system data. Metadata is brought into a consistent state and pending files or data blocks are written to a designated directory (called lost+found). In contrast to journaling file systems, e2fsck analyzes the entire file system and not only the recently modified bits of metadata. This takes significantly longer than checking the log data of a journaling file system. Depending on file system size, this procedure can take half an hour or more. Therefore, it is not desirable to choose Ext2 for any server that needs high availability. However, because Ext2 does not maintain a journal and uses less memory, it is sometimes faster than other file systems.

Easy Upgradability

Because Ext3 is based on the Ext2 code and shares its on-disk format and its metadata format, upgrades from Ext2 to Ext3 are very easy.

1.5 Ext3

Ext3 was designed by Stephen Tweedie. Unlike all other next-generation file systems, Ext3 does not follow a completely new design principle. It is based on Ext2. These two file systems are very closely related to each other. An Ext3 file system can be easily built on top of an Ext2 file system. The most important difference between Ext2 and Ext3 is that Ext3 supports journaling. In summary, Ext3 has three major advantages to offer:

1.5.1 Easy and Highly Reliable Upgrades from Ext2

The code for Ext2 is the strong foundation on which Ext3 could become a highly acclaimed next-generation file system. Its reliability and solidity are elegantly combined in Ext3 with the advantages of a journaling file system. Unlike transitions to other journaling file systems, such as XFS, which can be quite tedious (making backups of the entire file system and re-creating it from scratch), a transition to Ext3 is a matter of minutes. It is also very safe, because re-creating an entire file system from scratch might not work flawlessly. Considering the number of existing Ext2 systems that await an upgrade to a journaling file system, you can easily see why Ext3 might be of some importance to many system administrators. Downgrading from Ext3 to Ext2 is as easy as the upgrade. Perform a clean unmount of the Ext3 file system and remount it as an Ext2 file system.

1.5.2 Reliability and Performance

Some other journaling file systems follow the metadata-only journaling approach. This means your metadata is always kept in a consistent state, but this cannot be automatically guaranteed for the file system data itself. Ext3 is designed to take care of both metadata and data. The degree of care can be customized. Enabling Ext3 in the data=journal mode offers maximum security (data integrity), but can slow down the system because both metadata and data are journaled. A relatively new approach is to use the data=ordered mode, which ensures both data and metadata integrity, but uses journaling only for metadata. The file system driver collects all data blocks that correspond to one metadata update. These data blocks are written to disk before the metadata is updated. As a result, consistency is achieved for metadata and data without sacrificing performance. A third option to use is data=writeback, which allows data to be written to the main file system after its metadata has been committed to the journal. This option is often considered the best in performance. It can, however, allow old data to reappear in files after crash and recovery while internal file system integrity is maintained. Ext3 uses the data=ordered option as the default.

1.5.3 Converting an Ext2 File System into Ext3

To convert an Ext2 file system to Ext3:

  1. Create an Ext3 journal by running tune2fs -j as the root user.

    This creates an Ext3 journal with the default parameters.

    To specify how large the journal should be and on which device it should reside, run tune2fs -J instead together with the desired journal options size= and device=. More information about the tune2fs program is available in the tune2fs man page.

  2. Edit the file /etc/fstab as the root user to change the file system type specified for the corresponding partition from ext2 to ext3, then save the changes.

    This ensures that the Ext3 file system is recognized as such. The change takes effect after the next reboot.

  3. To boot a root file system that is set up as an Ext3 partition, add the modules ext3 and jbd in the initrd. Do so by

    1. adding the following line to /etc/dracut.conf.d/01-dist.conf:

      force_drivers+="ext3 jbd"
    2. and running the dracut -f command.

  4. Reboot the system.

1.5.4 Ext3 File System Inode Size and Number of Inodes

An inode stores information about the file and its block location in the file system. To allow space in the inode for extended attributes and ACLs, the default inode size for Ext3 was increased from 128 bytes on SLES 10 to 256 bytes on SLES 11. As compared to SLES 10, when you make a new Ext3 file system on SLES 11, the default amount of space preallocated for the same number of inodes is doubled, and the usable space for files in the file system is reduced by that amount. Thus, you must use larger partitions to accommodate the same number of inodes and files than were possible for an Ext3 file system on SLES 10.

When you create a new Ext3 file system, the space in the inode table is preallocated for the total number of inodes that can be created. The bytes-per-inode ratio and the size of the file system determine how many inodes are possible. When the file system is made, an inode is created for every bytes-per-inode bytes of space:

number of inodes = total size of the file system divided by the number of bytes per inode

The number of inodes controls the number of files you can have in the file system: one inode for each file. To address the increased inode size and reduced usable space available, the default for the bytes-per-inode ratio was increased from 8192 bytes on SLES 10 to 16384 bytes on SLES 11. The doubled ratio means that the number of files that can be created is one-half of the number of files possible for an Ext3 file system on SLES 10.

Important: Changing the Inode Size of an Existing Ext3 File System

After the inodes are allocated, you cannot change the settings for the inode size or bytes-per-inode ratio. No new inodes are possible without re-creating the file system with different settings, or unless the file system gets extended. When you exceed the maximum number of inodes, no new files can be created on the file system until some files are deleted.

When you make a new Ext3 file system, you can specify the inode size and bytes-per-inode ratio to control inode space usage and the number of files possible on the file system. If the blocks size, inode size, and bytes-per-inode ratio values are not specified, the default values in the /etc/mked2fs.conf file are applied. For information, see the mke2fs.conf(5) man page.

Use the following guidelines:

  • Inode size:  The default inode size is 256 bytes. Specify a value in bytes that is a power of 2 and equal to 128 or larger in bytes and up to the block size, such as 128, 256, 512, and so on. Use 128 bytes only if you do not use extended attributes or ACLs on your Ext3 file systems.

  • Bytes-per-inode ratio:  The default bytes-per-inode ratio is 16384 bytes. Valid bytes-per-inode ratio values must be a power of 2 equal to 1024 or greater in bytes, such as 1024, 2048, 4096, 8192, 16384, 32768, and so on. This value should not be smaller than the block size of the file system, because the block size is the smallest chunk of space used to store data. The default block size for the Ext3 file system is 4 KB.

    In addition, consider the number of files and the size of files you need to store. For example, if your file system will have many small files, you can specify a smaller bytes-per-inode ratio, which increases the number of inodes. If your file system will have very large files, you can specify a larger bytes-per-inode ratio, which reduces the number of possible inodes.

    Generally, it is better to have too many inodes than to run out of them. If you have too few inodes and very small files, you could reach the maximum number of files on a disk that is practically empty. If you have too many inodes and very large files, you might have free space reported but be unable to use it because you cannot create new files in space reserved for inodes.

If you do not use extended attributes or ACLs on your Ext3 file systems, you can restore the SLES 10 behavior specifying 128 bytes as the inode size and 8192 bytes as the bytes-per-inode ratio when you make the file system. Use any of the following methods to set the inode size and bytes-per-inode ratio:

  • Modifying the default settings for all new Ext3 files:  In a text editor, modify the defaults section of the /etc/mke2fs.conf file to set the inode_size and inode_ratio to the desired default values. The values apply to all new Ext3 file systems. For example:

    blocksize = 4096
    inode_size = 128
    inode_ratio = 8192
  • At the command line:  Pass the inode size (-I 128) and the bytes-per-inode ratio (-i 8192) to the mkfs.ext3(8) command or the mke2fs(8) command when you create a new Ext3 file system. For example, use either of the following commands:

    tux > sudo mkfs.ext3 -b 4096 -i 8092 -I 128 /dev/sda2
    tux > sudo mke2fs -t ext3 -b 4096 -i 8192 -I 128 /dev/sda2
  • During installation with YaST:  Pass the inode size and bytes-per-inode ratio values when you create a new Ext3 file system during the installation. In the YaST Partitioner on the Edit Partition page under Formatting Options, select Format partitionExt3, then click Options. In the File system options dialog, select the desired values from the Block Size in Bytes, Bytes-per-inode, and Inode Size drop-down box.

    For example, select 4096 for the Block Size in Bytes drop-down box, select 8192 from the Bytes per inode drop-down box, select 128 from the Inode Size drop-down box, then click OK.

  • During installation with AutoYaST:  In an AutoYaST profile, you can use the fs_options tag to set the opt_bytes_per_inode ratio value of 8192 for -i and the opt_inode_density value of 128 for -I:

    <partitioning config:type="list">
        <initialize config:type="boolean">true</initialize>
        <partitions config:type="list">
            <filesystem config:type="symbol">ext3</filesystem>
            <format config:type="boolean">true</format>
            <partition_id config:type="integer">131</partition_id>

For information, see http://www.suse.com/support/kb/doc.php?id=7009075 (SLES11 ext3 partitions can only store 50% of the files that can be stored on SLES10 [Technical Information Document 7009075]).

1.6 Ext4

In 2006, Ext4 started as a fork from Ext3. It eliminates some storage limitations of Ext3 by supporting volumes with a size of up to 1 exbibyte, files with a size of up to 16 tebibytes and an unlimited number of subdirectories. It also introduces several performance enhancements such as delayed block allocation and a much faster file system checking routine. Ext4 is also more reliable by supporting journal checksums and by providing time stamps measured in nanoseconds. Ext4 is fully backward compatible to Ext2 and Ext3—both file systems can be mounted as Ext4.

1.7 ReiserFS

ReiserFS support was completely removed with SUSE Linux Enterprise Server 15. To migrate your existing partitions to Btrfs, refer to Section 1.2.3, “Migration from ReiserFS and Ext File Systems to Btrfs”.

1.8 Other Supported File Systems

Table 1.1, “File System Types in Linux” summarizes some other file systems supported by Linux. They are supported mainly to ensure compatibility and interchange of data with different kinds of media or foreign operating systems.

Table 1.1: File System Types in Linux

File System Type



Compressed ROM file system: A compressed read-only file system for ROMs.


High Performance File System: The IBM OS/2 standard file system. Only supported in read-only mode.


Standard file system on CD-ROMs.


This file system originated from academic projects on operating systems and was the first file system used in Linux. Today, it is used as a file system for floppy disks.


fat, the file system originally used by DOS, is today used by various operating systems.


Network File System: Here, data can be stored on any machine in a network and access might be granted via a network.


Windows NT file system; read-only.


Server Message Block is used by products such as Windows to enable file access over a network.


Used on SCO Unix, Xenix, and Coherent (commercial Unix systems for PCs).


Used by BSD, SunOS, and NextStep. Only supported in read-only mode.


Unix on MS-DOS: Applied on top of a standard fat file system, achieves Unix functionality (permissions, links, long file names) by creating special files.


Virtual FAT: Extension of the fat file system (supports long file names).

1.9 Large File Support in Linux

Originally, Linux supported a maximum file size of 2 GiB (231 bytes). Unless a file system comes with large file support, the maximum file size on a 32-bit system is 2 GiB.

Currently, all of our standard file systems have LFS (large file support), which gives a maximum file size of 263 bytes in theory. Table 1.2, “Maximum Sizes of Files and File Systems (On-Disk Format, 4 KiB Block Size)” offers an overview of the current on-disk format limitations of Linux files and file systems. The numbers in the table assume that the file systems are using 4 KiB block size, which is a common standard. When using different block sizes, the results are different. The maximum file sizes in Table 1.2, “Maximum Sizes of Files and File Systems (On-Disk Format, 4 KiB Block Size)” can be larger than the file system's actual size when using sparse blocks.

Note: Binary Multiples

In this document: 1024 Bytes = 1 KiB; 1024 KiB = 1 MiB; 1024 MiB = 1 GiB; 1024 GiB = 1 TiB; 1024 TiB = 1 PiB; 1024 PiB = 1 EiB (see also NIST: Prefixes for Binary Multiples.

Table 1.2: Maximum Sizes of Files and File Systems (On-Disk Format, 4 KiB Block Size)

File System (4 KiB Block Size)

Maximum File System Size

Maximum File Size


16 EiB

16 EiB


16 TiB

2 TiB


1 EiB

16 TiB

OCFS2 (a cluster-aware file system available in the High Availability Extension)

16 TiB

1 EiB


8 EiB

8 EiB

NFSv2 (client side)

8 EiB

2 GiB

NFSv3/NFSv4 (client side)

8 EiB

8 EiB

Important: Limitations

Table 1.2, “Maximum Sizes of Files and File Systems (On-Disk Format, 4 KiB Block Size)” describes the limitations regarding the on-disk format. The Linux kernel imposes its own limits on the size of files and file systems handled by it. These are as follows:

File Size

On 32-bit systems, files cannot exceed 2 TiB (241 bytes).

File System Size

File systems can be up to 273 bytes in size. However, this limit is still out of reach for the currently available hardware.

1.10 Linux Kernel Storage Limitations

Table 1.3, “Storage Limitations” summarizes the kernel limits for storage associated with SUSE Linux Enterprise Server.

Table 1.3: Storage Limitations

Storage Feature


Maximum number of LUNs supported

16384 LUNs per target.

Maximum number of paths per single LUN

No limit by default. Each path is treated as a normal LUN.

The actual limit is given by the number of LUNs per target and the number of targets per HBA (16777215 for a Fibre Channel HBA).

Maximum number of HBAs

Unlimited. The actual limit is determined by the amount of PCI slots of the system.

Maximum number of paths with device-mapper-multipath (in total) per operating system

Approximately 1024. The actual number depends on the length of the device number strings for each multipath device. It is a compile-time variable within multipath-tools, which can be raised if this limit poses a problem.

Maximum size per block device

Up to 8 EiB.

1.11 Troubleshooting File Systems

This section describes some known issues and possible solutions for file systems.

1.11.1 Btrfs Error: No space is left on device

The root (/) partition using the Btrfs file system stops accepting data. You receive the error No space left on device.

See the following sections for information about possible causes and prevention of this issue. Disk Space Consumed by Snapper Snapshots

If Snapper is running for the Btrfs file system, the No space left on device problem is typically caused by having too much data stored as snapshots on your system.

You can remove some snapshots from Snapper, however, the snapshots are not deleted immediately and might not free up as much space as you need.

To delete files from Snapper:

  1. Open a terminal console.

  2. At the command prompt, enter btrfs filesystem show, for example:

    tux > sudo btrfs filesystem show
    Label: none uuid: 40123456-cb2c-4678-8b3d-d014d1c78c78
     Total devices 1 FS bytes used 20.00GB
     devid 1 size 20.00GB used 20.00GB path /dev/sda3
  3. Enter

    tux > sudo btrfs fi balance start MOUNTPOINT -dusage=5

    This command attempts to relocate data in empty or near-empty data chunks, allowing the space to be reclaimed and reassigned to metadata. This can take a while (many hours for 1 TB) although the system is otherwise usable during this time.

  4. List the snapshots in Snapper. Enter

    tux > sudo snapper -c root list
  5. Delete one or more snapshots from Snapper. Enter

    tux > sudo snapper -c root delete SNAPSHOT_NUMBER(S)

    Ensure that you delete the oldest snapshots first. The older a snapshot is, the more disk space it occupies.

To help prevent this problem, you can change the Snapper cleanup algorithms. See Section, “Cleanup-algorithms” for details. The configuration values controlling snapshot cleanup are EMPTY_*, NUMBER_*, and TIMELINE_*.

If you use Snapper with Btrfs on the file system disk, it is advisable to reserve twice the amount of disk space than the standard storage proposal. The YaST Partitioner automatically proposes twice the standard disk space in the Btrfs storage proposal for the root file system. Disk Space Consumed by Log, Crash, and Cache Files

If the system disk is filling up with data, you can try deleting files from /var/log, /var/crash, /var/lib/systemd/coredump and /var/cache.

The Btrfs root file system subvolumes /var/log, /var/crash and /var/cache can use all of the available disk space during normal operation, and cause a system malfunction. To help avoid this situation, SUSE Linux Enterprise Server offers Btrfs quota support for subvolumes. See Section 1.2.5, “Btrfs Quota Support for Subvolumes” for details.

On test and development machines, especially if you have frequent crashes of applications, you may also want to have a look at /var/lib/systemd/coredump where the coredumps are stored.

1.11.2 Freeing Unused File System Blocks

On solid-state drives (SSDs) and thinly provisioned volumes it is useful to trim blocks not in use by the file system. SUSE Linux Enterprise Server fully supports unmap or trim operations on all file systems supporting these methods.

The recommended way to trim a supported file system (except Btrfs) on SUSE Linux Enterprise Server is to run /sbin/wiper.sh. Make sure to read /usr/share/doc/packages/hdparm/README.wiper before running this script. For most desktop and server systems the sufficient trimming frequency is once a week. Mounting a file system with -o discard comes with a performance penalty and may negatively affect the lifetime of SSDs and is not recommended.

Warning: Do Not Use wiper.sh on Btrfs

The wiper.sh script trims read-write mounted Ext4 and XFS file systems, read-only mounted/unmounted Ext2, Ext3, Ext4, and XFS file systems. Do not use wiper.sh on the Btrfs file system as it may damage your data. Instead, use /usr/share/btrfsmaintenance/btrfs-trim.sh which is part of the btrfsmaintenance package.

1.11.3 No Defragmentation on SSDs

Linux file systems contain mechanisms to avoid data fragmentation and usually it is not necessary to defragment. However, there are use cases, where data fragmentation cannot be avoided and where defragmenting the hard disk significantly improves the performance.

This only applies to conventional hard disks. On solid state disks (SSDs) which use flash memory to store data, the firmware provides an algorithm that determines to which chips the data is written. Data is usually spread all over the device. Therefore defragmenting an SSD does not have the desired effect and will reduce the lifespan of an SSD by writing unnecessary data.

For the reasons mentioned above, SUSE explicitly recommends not to defragment SSDs. Some vendors also warn about defragmenting solid state disks. This includes, but it is not limited to the following:

  • HPE 3PAR StoreServ All-Flash

  • HPE 3PAR StoreServ Converged Flash

1.12 Additional Information

Each of the file system projects described above maintains its own home page on which to find mailing list information, further documentation, and FAQs:

A comprehensive multi-part tutorial about Linux file systems can be found at IBM developerWorks in the Advanced File System Implementor’s Guide (https://www.ibm.com/developerworks/linux/library/l-fs/).

An in-depth comparison of file systems (not only Linux file systems) is available from the Wikipedia project in Comparison of File Systems (http://en.wikipedia.org/wiki/Comparison_of_file_systems#Comparison).

Print this page