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<div class="mw-translate-fuzzy">
<languages/>
<languages/>
BTRFS  es un sistema de archivos basado en el principio copy-on-write (COW) que fue inicialmente diseñado en Oracle Corporation para  ser usado en  Linux. El desarrollo de BTRFS comenzó en 2007 y desde agosto de 2014 este sistema ha sido marcado como estable.
BTRFS  es un sistema de archivos basado en el principio copy-on-write (COW) que fue inicialmente diseñado en Oracle Corporation para  ser usado en  Linux. El desarrollo de BTRFS comenzó en 2007 y desde agosto de 2014 este sistema ha sido marcado como estable.
</div>


In 2015, Btrfs was adopted as the default filesystem for SUSE Linux Enterprise Server 12. SUSE reaffirmed its commitment to Btrfs in 2017 after RedHat announced to stop supporting Btrfs.
<div class="mw-translate-fuzzy">
En el año 2015, BTRFS  fue adoptado como el sistema de archivos oficial de SUSE Linux Enterprise Server 12. SUSE ratificó su compromiso con BTRFS  en 2017 después de que RedHat anunciara que dejaría de soportar este sistema de archivos.
</div>


Btrfs is intended to address the lack of pooling, snapshots, checksums, and integral multi-device spanning in Linux file systems.
BTRFS  fue diseñado para mejorar algunas de las deficiencias de los sistemas de archivos en Linux, entre ellas: almacenamiento de archivos basado Extensión, espacio eficiente de almacenamiento de archivos pequeños, espacio eficiente directorios indexados, asignación dinámica de inodos, instantáneas de escritura --de sólo lectura instantáneas, subvolúmenes ( raíces del sistema de archivos interno separadas), sumas de verificación sobre los datos y metadatos (CRC32C),  compresión (zlib y LZO) y soporte de múltiples dispositivos integrados.


It is easy to set up and use BTRFS. In this simple introduction, we're going to set up BTRFS under Funtoo Linux using an existing {{c|debian-sources}} or {{c|debian-sources-lts}} kernel, like the one that comes pre-built for you with Funtoo Linux, and we will also be using our BTRFS storage pool for storing data that isn't part of the Funtoo Linux installation itself. Funtoo Linux will boot from a non-BTRFS filesystem, and as part of the initialization process will initialize our BTRFS storage and mount it at the location of our choice.
<div class="mw-translate-fuzzy">
BTRFS es fácil configurar y utilizar. En esta breve introducción configuraremos BTRFS en Funtoo Linux, utilizando un núcleo {{c|debian-sources}} o {{c|debian-sources-lts}} similar al que viene integrado con Funtoo Linux y también usaremos nuestro grupo de almacenamiento BTRFS para almacenar datos que no forman parte de la instalación de Funtoo Linux. Funtoo Linux iniciará desde un sistema de archivos diferente a BTRFS y como parte del proceso de instalación, iniciará el grupo de almacenamiento en BTRFS y lo montará en la ruta que nosotros  deseemos.
</div>


== Installation ==
== Instalación ==


To install BTRFS no aditional steps are needed as it is part of Linux Kernel (in mainline Linux kernel since 2.6.29). Let's emerge the BTRFS userspace tools ({{c|btrfs-progs}}):
<div class="mw-translate-fuzzy">
Para instalar BTRFS no se necesitan pasos adicionales porque hace parte del núcleo (kernel) oficial de Linux desde la versión 2.6.29. Comencemos con instalar las herramientas para configurar BTRFS ({{c|btrfs-progs}}):
</div>


<div class="mw-translate-fuzzy">
{{console|body=
{{console|body=
# ##i##emerge btrfs-progs
# ##i##emerge btrfs-progs
}}
}}
</div>


BTRFS is now ready for use.
<div class="mw-translate-fuzzy">
Ahora,  está listo para ser usado.
</div>


== BTRFS Concepts ==
<div class="mw-translate-fuzzy">
=== Conceptos de BTRFS ===
</div>


BTRFS can be used to manage the physical disks that it uses, and physical disks are added to a BTRFS volume. Then, BTRFS can create subvolumes from the volume on which files can be stored.  
<div class="mw-translate-fuzzy">
BTRFS puede ser usado para manejar los discos físicos que el sistema de archivos use, así como discos físicos que sean incorporados a un volumen de almacenamiento de BTRFS. Después, BTRFS puede crear subvolúmenes de almacenamiento en donde los archivos pueden ser almacenados.
</div>


Unlike traditional Linux filesystems, BTRFS filesystems will allocate storage on-demand from the underlying volume.  
<div class="mw-translate-fuzzy">
A diferencia de los sistemas de archivos tradicionales en Linux, el sistema de archivo BTRFS puede disponer de almacenamiento por demanda desde el volumen de almacenamiento subyacente.
</div>


In the BTRFS world, the word volume corresponds to a storage pool (ZFS) or a volume group (LVM).
<div class="mw-translate-fuzzy">
En el mundo de BTRFS, la expresión "volumen de almacenamiento" corresponde a un espacio de almacenamiento tipo ZFS o a un gestor  de volumenes lógicos (LVM).
</div>


* ''devices'' - one or multiple underlying physical volumes.
* ''devices'' - one or multiple underlying physical volumes.
Line 33: Line 53:
== Creating a Volume ==
== Creating a Volume ==


To create a basic BTRFS volume, you will need an extra empty disk. Perform the following steps:
To create a basic btrfs volume, you will need an extra empty disk. Perform the following steps:


{{console|body=
{{console|body=
Line 68: Line 88:


{{console|body=
{{console|body=
# ##i## mkdir /mnt/btrfs-top-level
# ##i## mount /dev/sdxy /mnt/btrfs-top-level
# ##i## mount
...
/dev/sdxy on /mnt/btrfs-top-level type btrfs (rw,relatime,ssd,space_cache,subvolid=5,subvol=/)
}}
{{Important|It is recommended that nothing is stored directly on this top-level volume (ID 5) root directory.}}
== Creating Subvolumes ==
Btrfs has a concept of subvolumes. Subvolume is an independently mountable POSIX filetree (but not a block device). There are several basic schemas to layout subvolumes (including snapshots) as well as mixtures thereof.
Lets create children of the top level subvolume (ID 5). We will have:
* {{c|@data}} - it will serve as mountable {{c|/data}}
* {{c|.snapshots}} - here snapshots will be stored
{{console|body=
# ##i## cd /mnt/btrfs-top-level
# ##i## btrfs subvolume create @data
# ##i## btrfs subvolume create .snapshots
# ##i## btrfs subvolume list /mnt/btrfs-top-level
ID 256 gen 322338 top level 5 path @data
ID 257 gen 322275 top level 5 path .snapshots
}}
== The default Subvolume ==
{{Note|Changing the default subvolume with {{c|btrfs subvolume default}} will make the top level of the filesystem accessible only when {{c|subvol}} or {{c|subvolid}} mount options are specified}}
When btrfs block device is mounted without specifying a subvolume the default one is used. To check default subvolume run
{{console|body=
# ##i## btrfs subvolume get-default /mnt/btrfs-top-level
ID 5 (FS_TREE)
}}
For the convenience lets make {{c|@data}} subvolume as the default one. It's good to double check the subvolume ID first. Either {{c|btrfs subvolume list}} or {{c|btrfs subvolume show}} can be used for that
{{console|body=
# ##i## btrfs subvolume show /mnt/btrfs-top-level/@data
...
Subvolume ID: 256
}}
Now you can make this subvolume as a default one
{{console|body=
# ##i## btrfs subvolume set-default 256 /mnt/btrfs-top-level
# ##i## btrfs subvolume get-default /mnt/btrfs-top-level
ID 256 gen 322336 top level 5 path @data
}}
At this point you can stop working on the top level subvolume (ID 5) and instead mount directly {{c|@data}} subvolume.
{{console|body=
# ##i## cd /mnt
# ##i## umount /mnt/btrfs-top-level
# ##i## mkdir /data
# ##i## mkdir /data
# ##i## mount /dev/sdxy /data
# ##i## mount /dev/sdxy /data
# ##i## mount
...
/dev/sdxy on /data type btrfs (rw,relatime,ssd,space_cache,subvolid=5,subvol=/)
}}
}}


To automatically mount this volume after reboot you need to add a simple fstab entry:
== Nested Subvolumes ==
 
{{Note|Nested subvolumes are not going to be a part of snapshots created from their parent subvolume. So one typical reason is to exclude certain parts of the filesystem from being snapshot.}}
 
Lets create a separate nested subvolume for {{c|/data/independent}}.
 
{{console|body=
# ##i## btrfs subvolume create /data/independent
# ##i## btrfs subvolume list /data
ID 258 gen 161 top level 256 path independent
}}
 
Usually you will want to "split" areas which are "complete" and/or "consistent" in themselves. Examples for this more-fine grained partitioning could be {{c|/var/log}}, {{c|/var/www}} or {{c|/var/lib/postgresql}}.
 
== /etc/fstab ==
 
To automatically mount the {{c|@data}} subvolume after reboot you need to modify {{c|/etc/fstab}}
 
{{file|name=/etc/fstab|desc=fstab for btrfs|body=
/dev/sdxy /data btrfs subvolid=256,defaults 0 0
}}
 
{{Warning|According to [https://btrfs.readthedocs.io/en/latest/Administration.html#mount-options btrfs docs] most mount options apply to the whole filesystem and only options in the first mounted subvolume will take effect. This means that (for example) you can't set per-subvolume {{c|nodatacow}}, {{c|nodatasum}}, or {{c|compress}}.}}
 
Now lets verify if this changes were correct
{{console|body=
# ##i## cd /
# ##i## umount /data
# ##i## mount /data
# ##i## ls /data
independent
}}
 
Did you just notice that although we mounted our {{c|@data}} subvolume the nested subvolume {{c|@data/independent}} is also present?
 
== Snapshots ==
 
For the purpose of checking out this cool btrfs feature lets populate our filesystem with some example data first
 
{{console|body=
# ##i## echo 'btrfs' > /data/foo.txt
# ##i## echo 'fun' > /data/independent/bar.txt
}}
 
As you probably remember on the top level (next to {{c|@data}} subvolume) you've also created the {{c|.snapshots}} subvolume. You can mount it now to create some snapshots
{{console|body=
# ##i## mkdir /mnt/snapshots
# ##i## mount /dev/sdxy /mnt/snapshots -o subvolid=257
}}
 
A snapshot is a subvolume like any other, with given initial content. By default, snapshots are created read-write. File modifications in a snapshot do not affect the files in the original subvolume. Lets create a read-write snapshot for {{c|/data}} and read-only snapshot for {{c|/data/independent}}
 
{{console|body=
# ##i## btrfs subvolume snapshot /data /mnt/snapshots/data_$(date -u -Iseconds)
Create a snapshot of '/data' in '/mnt/snapshots/data_2022-08-30T22:04:57+00:00'
# ##i## btrfs subvolume snapshot -r /data/independent /mnt/snapshots/independent_$(date -u -Iseconds)
Create a readonly snapshot of '/data/independent' in '/mnt/snapshots/independent_2022-08-30T22:05:29+00:00'
}}
 
Once again, nested subvolumes are not going to be a part of snapshots created from their parent subvolume. So you shouldn't be surprised when you compare the contents of the {{c|/data}} vs the contents of the {{c|/mnt/snapshots}}
 
{{console|body=
# ##i## tree /data
/data
├── foo.txt
└── independent
    └── bar.txt
# ##i## tree /mnt/snapshots
/mnt/snapshots
├── data_2022-08-30T22:04:57+00:00
│   └── foo.txt
└── independent_2022-08-30T22:05:29+00:00
    └── bar.txt
}}
 
At this point you might be interested in [https://btrfs.readthedocs.io/en/latest/Send-receive.html send and receive btrfs features].
 
{{Note|According to [https://btrfs.readthedocs.io/en/latest/Subvolumes.html btrfs docs] a snapshot is not a backup: snapshots work by use of BTRFS copy-on-write behaviour. A snapshot and the original it was taken from initially share all of the same data blocks. If that data is damaged in some way (cosmic rays, bad disk sector, accident with dd to the disk), then the snapshot and the original will both be damaged.}}
 
== Wrap up ==
 
{{Important|It is recommended to run {{c|btrfs scrub}} once in a while. E.g. every month}}
 
Scrub is the online check and repair functionality that verifies the integrity of data and metadata, assuming the tree structure is fine. You can run it on a mounted file system; it runs as a background process during normal operation.
 
To start a (background) scrub on the filesystem which contains {{c|/data}} run
 
{{console|body=
# ##i## btrfs scrub start /data
scrub started on /data, fsid 40f8b94f-07ee-4f7e-beb1-8e686abc246d (pid=5525)
}}
 
To check the status of a running scrub


{{console|body=
{{console|body=
/dev/sdxy /data btrfs defaults 0 0
# ##i## btrfs scrub status /data
UUID:            40f8b94f-07ee-4f7e-beb1-8e686abc246d
Scrub started:    Tue Aug 30 00:38:54 2022
Status:          running
Duration:        0:00:15
Time left:        0:00:34
ETA:              Tue Aug 30 00:39:44 2022
Total to scrub:  149.06GiB
Bytes scrubbed:  44.79GiB  (30.04%)
Rate:            2.99GiB/s
Error summary:    no errors found
}}
}}


You should now be at the point where you can begin to use BTRFS for a variety of tasks. While there is a lot more to BTRFS than what is covered in this short introduction, you should now have a good understanding of the fundamental concepts on which BTRFS is based.
You should now be at the point where you can begin to use btrfs for a variety of tasks. While there is a lot more to btrfs than what is covered in this short introduction, you should now have a good understanding of the fundamental concepts on which btrfs is based.


[[Category:BTRFS]]
[[Category:Btrfs]]
[[Category:Filesystems]]
[[Category:Filesystems]]
[[Category:HOWTO]]
[[Category:HOWTO]]
[[Category:Official Documentation]]
[[Category:Official Documentation]]

Latest revision as of 18:14, September 4, 2022

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BTRFS es un sistema de archivos basado en el principio copy-on-write (COW) que fue inicialmente diseñado en Oracle Corporation para ser usado en Linux. El desarrollo de BTRFS comenzó en 2007 y desde agosto de 2014 este sistema ha sido marcado como estable.

En el año 2015, BTRFS fue adoptado como el sistema de archivos oficial de SUSE Linux Enterprise Server 12. SUSE ratificó su compromiso con BTRFS en 2017 después de que RedHat anunciara que dejaría de soportar este sistema de archivos.

BTRFS fue diseñado para mejorar algunas de las deficiencias de los sistemas de archivos en Linux, entre ellas: almacenamiento de archivos basado Extensión, espacio eficiente de almacenamiento de archivos pequeños, espacio eficiente directorios indexados, asignación dinámica de inodos, instantáneas de escritura --de sólo lectura instantáneas, subvolúmenes ( raíces del sistema de archivos interno separadas), sumas de verificación sobre los datos y metadatos (CRC32C), compresión (zlib y LZO) y soporte de múltiples dispositivos integrados.

BTRFS es fácil configurar y utilizar. En esta breve introducción configuraremos BTRFS en Funtoo Linux, utilizando un núcleo debian-sources o debian-sources-lts similar al que viene integrado con Funtoo Linux y también usaremos nuestro grupo de almacenamiento BTRFS para almacenar datos que no forman parte de la instalación de Funtoo Linux. Funtoo Linux iniciará desde un sistema de archivos diferente a BTRFS y como parte del proceso de instalación, iniciará el grupo de almacenamiento en BTRFS y lo montará en la ruta que nosotros deseemos.

Instalación

Para instalar BTRFS no se necesitan pasos adicionales porque hace parte del núcleo (kernel) oficial de Linux desde la versión 2.6.29. Comencemos con instalar las herramientas para configurar BTRFS (btrfs-progs): 

root # emerge btrfs-progs

Ahora, está listo para ser usado.

Conceptos de BTRFS

BTRFS puede ser usado para manejar los discos físicos que el sistema de archivos use, así como discos físicos que sean incorporados a un volumen de almacenamiento de BTRFS. Después, BTRFS puede crear subvolúmenes de almacenamiento en donde los archivos pueden ser almacenados.

A diferencia de los sistemas de archivos tradicionales en Linux, el sistema de archivo BTRFS puede disponer de almacenamiento por demanda desde el volumen de almacenamiento subyacente.

En el mundo de BTRFS, la expresión "volumen de almacenamiento" corresponde a un espacio de almacenamiento tipo ZFS o a un gestor de volumenes lógicos (LVM).

  • devices - one or multiple underlying physical volumes.
  • volume - one large storage pool comprised of all space of the devices and can support different redundancy levels
  • subvolumes - these are what get mounted and you store files in.
  • snapshots - a read-only copy of a subvolume at a given point in time and/or read-write copy of a subvolume in time (aka clone).

Creating a Volume

To create a basic btrfs volume, you will need an extra empty disk. Perform the following steps: 

root #  mkfs.btrfs /dev/sdxy
btrfs-progs v4.17.1 
See http://btrfs.wiki.kernel.org for more information.

Detected a SSD, turning off metadata duplication.  Mkfs with -m dup if you want to force metadata duplication.
Performing full device TRIM /dev/sdj (223.57GiB) ...
Label:              (null)
UUID:               d6bcba6e-8fd5-41fc-9bb4-79628c5c928c
Node size:          16384
Sector size:        4096
Filesystem size:    223.57GiB
Block group profiles:
  Data:             single            8.00MiB
  Metadata:         single            8.00MiB
  System:           single            4.00MiB
SSD detected:       yes
Incompat features:  extref, skinny-metadata
Number of devices:  1
Devices:
   ID        SIZE  PATH
    1   223.57GiB  /dev/sdxy

/dev/sdxy should be an unused disk. You may need to use the following command if this disk contains any pre-existing data on it: 

root #  mkfs.btrfs -f /dev/sdxy

Now you can mount the created volume as you would mount any other linux filesystem. 

root #  mkdir /mnt/btrfs-top-level
root #  mount /dev/sdxy /mnt/btrfs-top-level
root #  mount
...
/dev/sdxy on /mnt/btrfs-top-level type btrfs (rw,relatime,ssd,space_cache,subvolid=5,subvol=/)
   Important

It is recommended that nothing is stored directly on this top-level volume (ID 5) root directory.

Creating Subvolumes

Btrfs has a concept of subvolumes. Subvolume is an independently mountable POSIX filetree (but not a block device). There are several basic schemas to layout subvolumes (including snapshots) as well as mixtures thereof.

Lets create children of the top level subvolume (ID 5). We will have:

  • @data - it will serve as mountable /data
  • .snapshots - here snapshots will be stored
root #  cd /mnt/btrfs-top-level
root #  btrfs subvolume create @data
root #  btrfs subvolume create .snapshots
root #  btrfs subvolume list /mnt/btrfs-top-level
ID 256 gen 322338 top level 5 path @data
ID 257 gen 322275 top level 5 path .snapshots

The default Subvolume

   Note

Changing the default subvolume with btrfs subvolume default will make the top level of the filesystem accessible only when subvol or subvolid mount options are specified

When btrfs block device is mounted without specifying a subvolume the default one is used. To check default subvolume run 

root #  btrfs subvolume get-default /mnt/btrfs-top-level
ID 5 (FS_TREE)

For the convenience lets make @data subvolume as the default one. It's good to double check the subvolume ID first. Either btrfs subvolume list or btrfs subvolume show can be used for that 

root #  btrfs subvolume show /mnt/btrfs-top-level/@data
...
	Subvolume ID: 		256

Now you can make this subvolume as a default one 

root #  btrfs subvolume set-default 256 /mnt/btrfs-top-level
root #  btrfs subvolume get-default /mnt/btrfs-top-level
ID 256 gen 322336 top level 5 path @data

At this point you can stop working on the top level subvolume (ID 5) and instead mount directly @data subvolume. 

root #  cd /mnt
root #  umount /mnt/btrfs-top-level
root #  mkdir /data
root #  mount /dev/sdxy /data

Nested Subvolumes

   Note

Nested subvolumes are not going to be a part of snapshots created from their parent subvolume. So one typical reason is to exclude certain parts of the filesystem from being snapshot.

Lets create a separate nested subvolume for /data/independent. 

root #  btrfs subvolume create /data/independent
root #  btrfs subvolume list /data
ID 258 gen 161 top level 256 path independent

Usually you will want to "split" areas which are "complete" and/or "consistent" in themselves. Examples for this more-fine grained partitioning could be /var/log, /var/www or /var/lib/postgresql.

/etc/fstab

To automatically mount the @data subvolume after reboot you need to modify /etc/fstab

   /etc/fstab - fstab for btrfs
/dev/sdxy	/data	btrfs	subvolid=256,defaults	0 0
   Warning

According to btrfs docs most mount options apply to the whole filesystem and only options in the first mounted subvolume will take effect. This means that (for example) you can't set per-subvolume nodatacow, nodatasum, or compress.

Now lets verify if this changes were correct 

root #  cd /
root #  umount /data
root #  mount /data
root #  ls /data
independent

Did you just notice that although we mounted our @data subvolume the nested subvolume @data/independent is also present?

Snapshots

For the purpose of checking out this cool btrfs feature lets populate our filesystem with some example data first 

root #  echo 'btrfs' > /data/foo.txt
root #  echo 'fun' > /data/independent/bar.txt

As you probably remember on the top level (next to @data subvolume) you've also created the .snapshots subvolume. You can mount it now to create some snapshots 

root #  mkdir /mnt/snapshots
root #  mount /dev/sdxy /mnt/snapshots -o subvolid=257

A snapshot is a subvolume like any other, with given initial content. By default, snapshots are created read-write. File modifications in a snapshot do not affect the files in the original subvolume. Lets create a read-write snapshot for /data and read-only snapshot for /data/independent 

root #  btrfs subvolume snapshot /data /mnt/snapshots/data_$(date -u -Iseconds)
Create a snapshot of '/data' in '/mnt/snapshots/data_2022-08-30T22:04:57+00:00'
root #  btrfs subvolume snapshot -r /data/independent /mnt/snapshots/independent_$(date -u -Iseconds)
Create a readonly snapshot of '/data/independent' in '/mnt/snapshots/independent_2022-08-30T22:05:29+00:00'

Once again, nested subvolumes are not going to be a part of snapshots created from their parent subvolume. So you shouldn't be surprised when you compare the contents of the /data vs the contents of the /mnt/snapshots 

root #  tree /data
/data
├── foo.txt
└── independent
    └── bar.txt
root #  tree /mnt/snapshots
/mnt/snapshots
├── data_2022-08-30T22:04:57+00:00
│   └── foo.txt
└── independent_2022-08-30T22:05:29+00:00
    └── bar.txt

At this point you might be interested in send and receive btrfs features.

   Note

According to btrfs docs a snapshot is not a backup: snapshots work by use of BTRFS copy-on-write behaviour. A snapshot and the original it was taken from initially share all of the same data blocks. If that data is damaged in some way (cosmic rays, bad disk sector, accident with dd to the disk), then the snapshot and the original will both be damaged.

Wrap up

   Important

It is recommended to run btrfs scrub once in a while. E.g. every month

Scrub is the online check and repair functionality that verifies the integrity of data and metadata, assuming the tree structure is fine. You can run it on a mounted file system; it runs as a background process during normal operation.

To start a (background) scrub on the filesystem which contains /data run 

root #  btrfs scrub start /data
scrub started on /data, fsid 40f8b94f-07ee-4f7e-beb1-8e686abc246d (pid=5525)

To check the status of a running scrub 

root #  btrfs scrub status /data
UUID:             40f8b94f-07ee-4f7e-beb1-8e686abc246d
Scrub started:    Tue Aug 30 00:38:54 2022
Status:           running
Duration:         0:00:15
Time left:        0:00:34
ETA:              Tue Aug 30 00:39:44 2022
Total to scrub:   149.06GiB
Bytes scrubbed:   44.79GiB  (30.04%)
Rate:             2.99GiB/s
Error summary:    no errors found

You should now be at the point where you can begin to use btrfs for a variety of tasks. While there is a lot more to btrfs than what is covered in this short introduction, you should now have a good understanding of the fundamental concepts on which btrfs is based.

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