ZFS administration is divided between two
main utilities. The zpool
utility controls
the operation of the pool and deals with adding, removing,
replacing, and managing disks. The
zfs
utility
deals with creating, destroying, and managing datasets,
both file systems and
volumes.
Creating a ZFS storage pool (zpool) involves making a number of decisions that are relatively permanent because the structure of the pool cannot be changed after the pool has been created. The most important decision is what types of vdevs into which to group the physical disks. See the list of vdev types for details about the possible options. After the pool has been created, most vdev types do not allow additional disks to be added to the vdev. The exceptions are mirrors, which allow additional disks to be added to the vdev, and stripes, which can be upgraded to mirrors by attaching an additional disk to the vdev. Although additional vdevs can be added to expand a pool, the layout of the pool cannot be changed after pool creation. Instead, the data must be backed up and the pool destroyed and recreated.
Create a simple mirror pool:
#
zpool create
mypool
mirror/dev/ada1
/dev/ada2
#
zpool status
pool: mypool state: ONLINE scan: none requested config: NAME STATE READ WRITE CKSUM mypool ONLINE 0 0 0 mirror-0 ONLINE 0 0 0 ada1 ONLINE 0 0 0 ada2 ONLINE 0 0 0 errors: No known data errors
Multiple vdevs can be created at once. Specify multiple
groups of disks separated by the vdev type keyword,
mirror
in this example:
#
zpool create
pool: mypool state: ONLINE scan: none requested config: NAME STATE READ WRITE CKSUM mypool ONLINE 0 0 0 mirror-0 ONLINE 0 0 0 ada1 ONLINE 0 0 0 ada2 ONLINE 0 0 0 mirror-1 ONLINE 0 0 0 ada3 ONLINE 0 0 0 ada4 ONLINE 0 0 0 errors: No known data errorsmypool
mirror/dev/ada1
/dev/ada2
mirror/dev/ada3
/dev/ada4
Pools can also be constructed using partitions rather than whole disks. Putting ZFS in a separate partition allows the same disk to have other partitions for other purposes. In particular, partitions with bootcode and file systems needed for booting can be added. This allows booting from disks that are also members of a pool. There is no performance penalty on FreeBSD when using a partition rather than a whole disk. Using partitions also allows the administrator to under-provision the disks, using less than the full capacity. If a future replacement disk of the same nominal size as the original actually has a slightly smaller capacity, the smaller partition will still fit, and the replacement disk can still be used.
Create a RAID-Z2 pool using partitions:
#
zpool create
mypool
raidz2/dev/ada0p3
/dev/ada1p3
/dev/ada2p3
/dev/ada3p3
/dev/ada4p3
/dev/ada5p3
#
zpool status
pool: mypool state: ONLINE scan: none requested config: NAME STATE READ WRITE CKSUM mypool ONLINE 0 0 0 raidz2-0 ONLINE 0 0 0 ada0p3 ONLINE 0 0 0 ada1p3 ONLINE 0 0 0 ada2p3 ONLINE 0 0 0 ada3p3 ONLINE 0 0 0 ada4p3 ONLINE 0 0 0 ada5p3 ONLINE 0 0 0 errors: No known data errors
A pool that is no longer needed can be destroyed so that
the disks can be reused. Destroying a pool involves first
unmounting all of the datasets in that pool. If the datasets
are in use, the unmount operation will fail and the pool will
not be destroyed. The destruction of the pool can be forced
with -f
, but this can cause undefined
behavior in applications which had open files on those
datasets.
There are two cases for adding disks to a zpool: attaching
a disk to an existing vdev with
zpool attach
, or adding vdevs to the pool
with zpool add
. Only some
vdev types allow disks to
be added to the vdev after creation.
A pool created with a single disk lacks redundancy.
Corruption can be detected but
not repaired, because there is no other copy of the data.
The copies property may
be able to recover from a small failure such as a bad sector,
but does not provide the same level of protection as mirroring
or RAID-Z. Starting with a pool consisting
of a single disk vdev, zpool attach
can be
used to add an additional disk to the vdev, creating a mirror.
zpool attach
can also be used to add
additional disks to a mirror group, increasing redundancy and
read performance. If the disks being used for the pool are
partitioned, replicate the layout of the first disk on to the
second, gpart backup
and
gpart restore
can be used to make this
process easier.
Upgrade the single disk (stripe) vdev
ada0p3
to a mirror by attaching
ada1p3
:
#
zpool status
pool: mypool state: ONLINE scan: none requested config: NAME STATE READ WRITE CKSUM mypool ONLINE 0 0 0 ada0p3 ONLINE 0 0 0 errors: No known data errors#
zpool attach
Make sure to wait until resilver is done before rebooting. If you boot from pool 'mypool', you may need to update boot code on newly attached disk 'ada1p3'. Assuming you use GPT partitioning and 'da0' is your new boot disk you may use the following command: gpart bootcode -b /boot/pmbr -p /boot/gptzfsboot -i 1 da0mypool
ada0p3
ada1p3
#
gpart bootcode -b /boot/pmbr -p /boot/gptzfsboot -i 1
bootcode written to ada1ada1
#
zpool status
pool: mypool state: ONLINE status: One or more devices is currently being resilvered. The pool will continue to function, possibly in a degraded state. action: Wait for the resilver to complete. scan: resilver in progress since Fri May 30 08:19:19 2014 527M scanned out of 781M at 47.9M/s, 0h0m to go 527M resilvered, 67.53% done config: NAME STATE READ WRITE CKSUM mypool ONLINE 0 0 0 mirror-0 ONLINE 0 0 0 ada0p3 ONLINE 0 0 0 ada1p3 ONLINE 0 0 0 (resilvering) errors: No known data errors#
zpool status
pool: mypool state: ONLINE scan: resilvered 781M in 0h0m with 0 errors on Fri May 30 08:15:58 2014 config: NAME STATE READ WRITE CKSUM mypool ONLINE 0 0 0 mirror-0 ONLINE 0 0 0 ada0p3 ONLINE 0 0 0 ada1p3 ONLINE 0 0 0 errors: No known data errors
When adding disks to the existing vdev is not an option,
as for RAID-Z, an alternative method is to
add another vdev to the pool. Additional vdevs provide higher
performance, distributing writes across the vdevs. Each vdev
is responsible for providing its own redundancy. It is
possible, but discouraged, to mix vdev types, like
mirror
and RAID-Z
.
Adding a non-redundant vdev to a pool containing mirror or
RAID-Z vdevs risks the data on the entire
pool. Writes are distributed, so the failure of the
non-redundant disk will result in the loss of a fraction of
every block that has been written to the pool.
Data is striped across each of the vdevs. For example, with two mirror vdevs, this is effectively a RAID 10 that stripes writes across two sets of mirrors. Space is allocated so that each vdev reaches 100% full at the same time. There is a performance penalty if the vdevs have different amounts of free space, as a disproportionate amount of the data is written to the less full vdev.
When attaching additional devices to a boot pool, remember to update the bootcode.
Attach a second mirror group (ada2p3
and ada3p3
) to the existing
mirror:
#
zpool status
pool: mypool state: ONLINE scan: resilvered 781M in 0h0m with 0 errors on Fri May 30 08:19:35 2014 config: NAME STATE READ WRITE CKSUM mypool ONLINE 0 0 0 mirror-0 ONLINE 0 0 0 ada0p3 ONLINE 0 0 0 ada1p3 ONLINE 0 0 0 errors: No known data errors#
zpool add
mypool
mirrorada2p3
ada3p3
#
gpart bootcode -b /boot/pmbr -p /boot/gptzfsboot -i 1
bootcode written to ada2ada2
#
gpart bootcode -b /boot/pmbr -p /boot/gptzfsboot -i 1
bootcode written to ada3ada3
#
zpool status
pool: mypool state: ONLINE scan: scrub repaired 0 in 0h0m with 0 errors on Fri May 30 08:29:51 2014 config: NAME STATE READ WRITE CKSUM mypool ONLINE 0 0 0 mirror-0 ONLINE 0 0 0 ada0p3 ONLINE 0 0 0 ada1p3 ONLINE 0 0 0 mirror-1 ONLINE 0 0 0 ada2p3 ONLINE 0 0 0 ada3p3 ONLINE 0 0 0 errors: No known data errors
Currently, vdevs cannot be removed from a pool, and disks can only be removed from a mirror if there is enough remaining redundancy. If only one disk in a mirror group remains, it ceases to be a mirror and reverts to being a stripe, risking the entire pool if that remaining disk fails.
Remove a disk from a three-way mirror group:
#
zpool status
pool: mypool state: ONLINE scan: scrub repaired 0 in 0h0m with 0 errors on Fri May 30 08:29:51 2014 config: NAME STATE READ WRITE CKSUM mypool ONLINE 0 0 0 mirror-0 ONLINE 0 0 0 ada0p3 ONLINE 0 0 0 ada1p3 ONLINE 0 0 0 ada2p3 ONLINE 0 0 0 errors: No known data errors#
zpool detach
mypool
ada2p3
#
zpool status
pool: mypool state: ONLINE scan: scrub repaired 0 in 0h0m with 0 errors on Fri May 30 08:29:51 2014 config: NAME STATE READ WRITE CKSUM mypool ONLINE 0 0 0 mirror-0 ONLINE 0 0 0 ada0p3 ONLINE 0 0 0 ada1p3 ONLINE 0 0 0 errors: No known data errors
Pool status is important. If a drive goes offline or a
read, write, or checksum error is detected, the corresponding
error count increases. The status
output
shows the configuration and status of each device in the pool
and the status of the entire pool. Actions that need to be
taken and details about the last scrub
are also shown.
#
zpool status
pool: mypool state: ONLINE scan: scrub repaired 0 in 2h25m with 0 errors on Sat Sep 14 04:25:50 2013 config: NAME STATE READ WRITE CKSUM mypool ONLINE 0 0 0 raidz2-0 ONLINE 0 0 0 ada0p3 ONLINE 0 0 0 ada1p3 ONLINE 0 0 0 ada2p3 ONLINE 0 0 0 ada3p3 ONLINE 0 0 0 ada4p3 ONLINE 0 0 0 ada5p3 ONLINE 0 0 0 errors: No known data errors
When an error is detected, the read, write, or checksum
counts are incremented. The error message can be cleared and
the counts reset with zpool clear
. Clearing the
error state can be important for automated scripts that alert
the administrator when the pool encounters an error. Further
errors may not be reported if the old errors are not
cleared.mypool
There are a number of situations where it may be
desirable to replace one disk with a different disk. When
replacing a working disk, the process keeps the old disk
online during the replacement. The pool never enters a
degraded state,
reducing the risk of data loss.
zpool replace
copies all of the data from
the old disk to the new one. After the operation completes,
the old disk is disconnected from the vdev. If the new disk
is larger than the old disk, it may be possible to grow the
zpool, using the new space. See Growing a Pool.
Replace a functioning device in the pool:
#
zpool status
pool: mypool state: ONLINE scan: none requested config: NAME STATE READ WRITE CKSUM mypool ONLINE 0 0 0 mirror-0 ONLINE 0 0 0 ada0p3 ONLINE 0 0 0 ada1p3 ONLINE 0 0 0 errors: No known data errors#
zpool replace
Make sure to wait until resilver is done before rebooting. If you boot from pool 'zroot', you may need to update boot code on newly attached disk 'ada2p3'. Assuming you use GPT partitioning and 'da0' is your new boot disk you may use the following command: gpart bootcode -b /boot/pmbr -p /boot/gptzfsboot -i 1 da0mypool
ada1p3
ada2p3
#
gpart bootcode -b /boot/pmbr -p /boot/gptzfsboot -i 1
ada2
#
zpool status
pool: mypool state: ONLINE status: One or more devices is currently being resilvered. The pool will continue to function, possibly in a degraded state. action: Wait for the resilver to complete. scan: resilver in progress since Mon Jun 2 14:21:35 2014 604M scanned out of 781M at 46.5M/s, 0h0m to go 604M resilvered, 77.39% done config: NAME STATE READ WRITE CKSUM mypool ONLINE 0 0 0 mirror-0 ONLINE 0 0 0 ada0p3 ONLINE 0 0 0 replacing-1 ONLINE 0 0 0 ada1p3 ONLINE 0 0 0 ada2p3 ONLINE 0 0 0 (resilvering) errors: No known data errors#
zpool status
pool: mypool state: ONLINE scan: resilvered 781M in 0h0m with 0 errors on Mon Jun 2 14:21:52 2014 config: NAME STATE READ WRITE CKSUM mypool ONLINE 0 0 0 mirror-0 ONLINE 0 0 0 ada0p3 ONLINE 0 0 0 ada2p3 ONLINE 0 0 0 errors: No known data errors
When a disk in a pool fails, the vdev to which the disk belongs enters the degraded state. All of the data is still available, but performance may be reduced because missing data must be calculated from the available redundancy. To restore the vdev to a fully functional state, the failed physical device must be replaced. ZFS is then instructed to begin the resilver operation. Data that was on the failed device is recalculated from available redundancy and written to the replacement device. After completion, the vdev returns to online status.
If the vdev does not have any redundancy, or if multiple devices have failed and there is not enough redundancy to compensate, the pool enters the faulted state. If a sufficient number of devices cannot be reconnected to the pool, the pool becomes inoperative and data must be restored from backups.
When replacing a failed disk, the name of the failed disk
is replaced with the GUID of the device.
A new device name parameter for
zpool replace
is not required if the
replacement device has the same device name.
Replace a failed disk using
zpool replace
:
#
zpool status
pool: mypool state: DEGRADED status: One or more devices could not be opened. Sufficient replicas exist for the pool to continue functioning in a degraded state. action: Attach the missing device and online it using 'zpool online'. see: http://illumos.org/msg/ZFS-8000-2Q scan: none requested config: NAME STATE READ WRITE CKSUM mypool DEGRADED 0 0 0 mirror-0 DEGRADED 0 0 0 ada0p3 ONLINE 0 0 0 316502962686821739 UNAVAIL 0 0 0 was /dev/ada1p3 errors: No known data errors#
zpool replace
mypool
316502962686821739
ada2p3
#
zpool status
pool: mypool state: DEGRADED status: One or more devices is currently being resilvered. The pool will continue to function, possibly in a degraded state. action: Wait for the resilver to complete. scan: resilver in progress since Mon Jun 2 14:52:21 2014 641M scanned out of 781M at 49.3M/s, 0h0m to go 640M resilvered, 82.04% done config: NAME STATE READ WRITE CKSUM mypool DEGRADED 0 0 0 mirror-0 DEGRADED 0 0 0 ada0p3 ONLINE 0 0 0 replacing-1 UNAVAIL 0 0 0 15732067398082357289 UNAVAIL 0 0 0 was /dev/ada1p3/old ada2p3 ONLINE 0 0 0 (resilvering) errors: No known data errors#
zpool status
pool: mypool state: ONLINE scan: resilvered 781M in 0h0m with 0 errors on Mon Jun 2 14:52:38 2014 config: NAME STATE READ WRITE CKSUM mypool ONLINE 0 0 0 mirror-0 ONLINE 0 0 0 ada0p3 ONLINE 0 0 0 ada2p3 ONLINE 0 0 0 errors: No known data errors
It is recommended that pools be
scrubbed regularly,
ideally at least once every month. The
scrub
operation is very disk-intensive and
will reduce performance while running. Avoid high-demand
periods when scheduling scrub
or use vfs.zfs.scrub_delay
to adjust the relative priority of the
scrub
to prevent it interfering with other
workloads.
#
zpool scrub
mypool
#
zpool status
pool: mypool state: ONLINE scan: scrub in progress since Wed Feb 19 20:52:54 2014 116G scanned out of 8.60T at 649M/s, 3h48m to go 0 repaired, 1.32% done config: NAME STATE READ WRITE CKSUM mypool ONLINE 0 0 0 raidz2-0 ONLINE 0 0 0 ada0p3 ONLINE 0 0 0 ada1p3 ONLINE 0 0 0 ada2p3 ONLINE 0 0 0 ada3p3 ONLINE 0 0 0 ada4p3 ONLINE 0 0 0 ada5p3 ONLINE 0 0 0 errors: No known data errors
In the event that a scrub operation needs to be cancelled,
issue zpool scrub -s
.mypool
The checksums stored with data blocks enable the file system to self-heal. This feature will automatically repair data whose checksum does not match the one recorded on another device that is part of the storage pool. For example, a mirror with two disks where one drive is starting to malfunction and cannot properly store the data any more. This is even worse when the data has not been accessed for a long time, as with long term archive storage. Traditional file systems need to run algorithms that check and repair the data like fsck(8). These commands take time, and in severe cases, an administrator has to manually decide which repair operation must be performed. When ZFS detects a data block with a checksum that does not match, it tries to read the data from the mirror disk. If that disk can provide the correct data, it will not only give that data to the application requesting it, but also correct the wrong data on the disk that had the bad checksum. This happens without any interaction from a system administrator during normal pool operation.
The next example demonstrates this self-healing behavior.
A mirrored pool of disks /dev/ada0
and
/dev/ada1
is created.
#
zpool create
healer
mirror/dev/ada0
/dev/ada1
#
zpool status
pool: healer state: ONLINE scan: none requested config: NAME STATE READ WRITE CKSUM healer ONLINE 0 0 0 mirror-0 ONLINE 0 0 0 ada0 ONLINE 0 0 0 ada1 ONLINE 0 0 0 errors: No known data errorshealer
#
zpool list
NAME SIZE ALLOC FREE CAP DEDUP HEALTH ALTROOT healer 960M 92.5K 960M 0% 1.00x ONLINE -
Some important data that to be protected from data errors using the self-healing feature is copied to the pool. A checksum of the pool is created for later comparison.
#
cp /some/important/data /healer
#
zfs list
NAME SIZE ALLOC FREE CAP DEDUP HEALTH ALTROOT healer 960M 67.7M 892M 7% 1.00x ONLINE -#
sha1 /healer > checksum.txt
#
cat checksum.txt
SHA1 (/healer) = 2753eff56d77d9a536ece6694bf0a82740344d1f
Data corruption is simulated by writing random data to the beginning of one of the disks in the mirror. To prevent ZFS from healing the data as soon as it is detected, the pool is exported before the corruption and imported again afterwards.
This is a dangerous operation that can destroy vital data. It is shown here for demonstrational purposes only and should not be attempted during normal operation of a storage pool. Nor should this intentional corruption example be run on any disk with a different file system on it. Do not use any other disk device names other than the ones that are part of the pool. Make certain that proper backups of the pool are created before running the command!
#
zpool export
healer
#
dd if=/dev/random of=/dev/ada1 bs=1m count=200
200+0 records in 200+0 records out 209715200 bytes transferred in 62.992162 secs (3329227 bytes/sec)#
zpool import healer
The pool status shows that one device has experienced an
error. Note that applications reading data from the pool did
not receive any incorrect data. ZFS
provided data from the ada0
device with
the correct checksums. The device with the wrong checksum can
be found easily as the CKSUM
column
contains a nonzero value.
#
zpool status
pool: healer state: ONLINE status: One or more devices has experienced an unrecoverable error. An attempt was made to correct the error. Applications are unaffected. action: Determine if the device needs to be replaced, and clear the errors using 'zpool clear' or replace the device with 'zpool replace'. see: http://www.sun.com/msg/ZFS-8000-9P scan: none requested config: NAME STATE READ WRITE CKSUM healer ONLINE 0 0 0 mirror-0 ONLINE 0 0 0 ada0 ONLINE 0 0 0 ada1 ONLINE 0 0 1 errors: No known data errorshealer
The error was detected and handled by using the redundancy
present in the unaffected ada0
mirror
disk. A checksum comparison with the original one will reveal
whether the pool is consistent again.
#
sha1 /healer >> checksum.txt
#
cat checksum.txt
SHA1 (/healer) = 2753eff56d77d9a536ece6694bf0a82740344d1f SHA1 (/healer) = 2753eff56d77d9a536ece6694bf0a82740344d1f
The two checksums that were generated before and after the
intentional tampering with the pool data still match. This
shows how ZFS is capable of detecting and
correcting any errors automatically when the checksums differ.
Note that this is only possible when there is enough
redundancy present in the pool. A pool consisting of a single
device has no self-healing capabilities. That is also the
reason why checksums are so important in
ZFS and should not be disabled for any
reason. No fsck(8) or similar file system consistency
check program is required to detect and correct this and the
pool was still available during the time there was a problem.
A scrub operation is now required to overwrite the corrupted
data on ada1
.
#
zpool scrub
healer
#
zpool status
pool: healer state: ONLINE status: One or more devices has experienced an unrecoverable error. An attempt was made to correct the error. Applications are unaffected. action: Determine if the device needs to be replaced, and clear the errors using 'zpool clear' or replace the device with 'zpool replace'. see: http://www.sun.com/msg/ZFS-8000-9P scan: scrub in progress since Mon Dec 10 12:23:30 2012 10.4M scanned out of 67.0M at 267K/s, 0h3m to go 9.63M repaired, 15.56% done config: NAME STATE READ WRITE CKSUM healer ONLINE 0 0 0 mirror-0 ONLINE 0 0 0 ada0 ONLINE 0 0 0 ada1 ONLINE 0 0 627 (repairing) errors: No known data errorshealer
The scrub operation reads data from
ada0
and rewrites any data with an
incorrect checksum on ada1
. This is
indicated by the (repairing)
output from
zpool status
. After the operation is
complete, the pool status changes to:
#
zpool status
pool: healer state: ONLINE status: One or more devices has experienced an unrecoverable error. An attempt was made to correct the error. Applications are unaffected. action: Determine if the device needs to be replaced, and clear the errors using 'zpool clear' or replace the device with 'zpool replace'. see: http://www.sun.com/msg/ZFS-8000-9P scan: scrub repaired 66.5M in 0h2m with 0 errors on Mon Dec 10 12:26:25 2012 config: NAME STATE READ WRITE CKSUM healer ONLINE 0 0 0 mirror-0 ONLINE 0 0 0 ada0 ONLINE 0 0 0 ada1 ONLINE 0 0 2.72K errors: No known data errorshealer
After the scrub operation completes and all the data
has been synchronized from ada0
to
ada1
, the error messages can be
cleared from the pool
status by running zpool clear
.
#
zpool clear
healer
#
zpool status
pool: healer state: ONLINE scan: scrub repaired 66.5M in 0h2m with 0 errors on Mon Dec 10 12:26:25 2012 config: NAME STATE READ WRITE CKSUM healer ONLINE 0 0 0 mirror-0 ONLINE 0 0 0 ada0 ONLINE 0 0 0 ada1 ONLINE 0 0 0 errors: No known data errorshealer
The pool is now back to a fully working state and all the errors have been cleared.
The usable size of a redundant pool is limited by the capacity of the smallest device in each vdev. The smallest device can be replaced with a larger device. After completing a replace or resilver operation, the pool can grow to use the capacity of the new device. For example, consider a mirror of a 1 TB drive and a 2 TB drive. The usable space is 1 TB. When the 1 TB drive is replaced with another 2 TB drive, the resilvering process copies the existing data onto the new drive. Because both of the devices now have 2 TB capacity, the mirror's available space can be grown to 2 TB.
Expansion is triggered by using
zpool online -e
on each device. After
expansion of all devices, the additional space becomes
available to the pool.
Pools are exported before moving them
to another system. All datasets are unmounted, and each
device is marked as exported but still locked so it cannot be
used by other disk subsystems. This allows pools to be
imported on other machines, other
operating systems that support ZFS, and
even different hardware architectures (with some caveats, see
zpool(8)). When a dataset has open files,
zpool export -f
can be used to force the
export of a pool. Use this with caution. The datasets are
forcibly unmounted, potentially resulting in unexpected
behavior by the applications which had open files on those
datasets.
Export a pool that is not in use:
#
zpool export mypool
Importing a pool automatically mounts the datasets. This
may not be the desired behavior, and can be prevented with
zpool import -N
.
zpool import -o
sets temporary properties
for this import only.
zpool import altroot=
allows importing a
pool with a base mount point instead of the root of the file
system. If the pool was last used on a different system and
was not properly exported, an import might have to be forced
with zpool import -f
.
zpool import -a
imports all pools that do
not appear to be in use by another system.
List all available pools for import:
#
zpool import
pool: mypool id: 9930174748043525076 state: ONLINE action: The pool can be imported using its name or numeric identifier. config: mypool ONLINE ada2p3 ONLINE
Import the pool with an alternative root directory:
#
zpool import -o altroot=
/mnt
mypool
#
zfs list
zfs list NAME USED AVAIL REFER MOUNTPOINT mypool 110K 47.0G 31K /mnt/mypool
After upgrading FreeBSD, or if a pool has been imported from a system using an older version of ZFS, the pool can be manually upgraded to the latest version of ZFS to support newer features. Consider whether the pool may ever need to be imported on an older system before upgrading. Upgrading is a one-way process. Older pools can be upgraded, but pools with newer features cannot be downgraded.
Upgrade a v28 pool to support
Feature Flags
:
#
zpool status
pool: mypool state: ONLINE status: The pool is formatted using a legacy on-disk format. The pool can still be used, but some features are unavailable. action: Upgrade the pool using 'zpool upgrade'. Once this is done, the pool will no longer be accessible on software that does not support feat flags. scan: none requested config: NAME STATE READ WRITE CKSUM mypool ONLINE 0 0 0 mirror-0 ONLINE 0 0 0 ada0 ONLINE 0 0 0 ada1 ONLINE 0 0 0 errors: No known data errors#
zpool upgrade
This system supports ZFS pool feature flags. The following pools are formatted with legacy version numbers and can be upgraded to use feature flags. After being upgraded, these pools will no longer be accessible by software that does not support feature flags. VER POOL --- ------------ 28 mypool Use 'zpool upgrade -v' for a list of available legacy versions. Every feature flags pool has all supported features enabled.#
zpool upgrade mypool
This system supports ZFS pool feature flags. Successfully upgraded 'mypool' from version 28 to feature flags. Enabled the following features on 'mypool': async_destroy empty_bpobj lz4_compress multi_vdev_crash_dump
The newer features of ZFS will not be
available until zpool upgrade
has
completed. zpool upgrade -v
can be used to
see what new features will be provided by upgrading, as well
as which features are already supported.
Upgrade a pool to support additional feature flags:
#
zpool status
pool: mypool state: ONLINE status: Some supported features are not enabled on the pool. The pool can still be used, but some features are unavailable. action: Enable all features using 'zpool upgrade'. Once this is done, the pool may no longer be accessible by software that does not support the features. See zpool-features(7) for details. scan: none requested config: NAME STATE READ WRITE CKSUM mypool ONLINE 0 0 0 mirror-0 ONLINE 0 0 0 ada0 ONLINE 0 0 0 ada1 ONLINE 0 0 0 errors: No known data errors#
zpool upgrade
This system supports ZFS pool feature flags. All pools are formatted using feature flags. Some supported features are not enabled on the following pools. Once a feature is enabled the pool may become incompatible with software that does not support the feature. See zpool-features(7) for details. POOL FEATURE --------------- zstore multi_vdev_crash_dump spacemap_histogram enabled_txg hole_birth extensible_dataset bookmarks filesystem_limits#
zpool upgrade mypool
This system supports ZFS pool feature flags. Enabled the following features on 'mypool': spacemap_histogram enabled_txg hole_birth extensible_dataset bookmarks filesystem_limits
The boot code on systems that boot from a pool must be
updated to support the new pool version. Use
gpart bootcode
on the partition that
contains the boot code. See gpart(8) for more
information.
Commands that modify the pool are recorded. Recorded
actions include the creation of datasets, changing properties,
or replacement of a disk. This history is useful for
reviewing how a pool was created and which user performed a
specific action and when. History is not kept in a log file,
but is part of the pool itself. The command to review this
history is aptly named
zpool history
:
#
zpool history
History for 'tank': 2013-02-26.23:02:35 zpool create tank mirror /dev/ada0 /dev/ada1 2013-02-27.18:50:58 zfs set atime=off tank 2013-02-27.18:51:09 zfs set checksum=fletcher4 tank 2013-02-27.18:51:18 zfs create tank/backup
The output shows zpool
and
zfs
commands that were executed on the pool
along with a timestamp. Only commands that alter the pool in
some way are recorded. Commands like
zfs list
are not included. When no pool
name is specified, the history of all pools is
displayed.
zpool history
can show even more
information when the options -i
or
-l
are provided. -i
displays user-initiated events as well as internally logged
ZFS events.
#
zpool history -i
History for 'tank': 2013-02-26.23:02:35 [internal pool create txg:5] pool spa 28; zfs spa 28; zpl 5;uts 9.1-RELEASE 901000 amd64 2013-02-27.18:50:53 [internal property set txg:50] atime=0 dataset = 21 2013-02-27.18:50:58 zfs set atime=off tank 2013-02-27.18:51:04 [internal property set txg:53] checksum=7 dataset = 21 2013-02-27.18:51:09 zfs set checksum=fletcher4 tank 2013-02-27.18:51:13 [internal create txg:55] dataset = 39 2013-02-27.18:51:18 zfs create tank/backup
More details can be shown by adding -l
.
History records are shown in a long format, including
information like the name of the user who issued the command
and the hostname on which the change was made.
#
zpool history -l
History for 'tank': 2013-02-26.23:02:35 zpool create tank mirror /dev/ada0 /dev/ada1 [user 0 (root) on :global] 2013-02-27.18:50:58 zfs set atime=off tank [user 0 (root) on myzfsbox:global] 2013-02-27.18:51:09 zfs set checksum=fletcher4 tank [user 0 (root) on myzfsbox:global] 2013-02-27.18:51:18 zfs create tank/backup [user 0 (root) on myzfsbox:global]
The output shows that the
root
user created
the mirrored pool with disks
/dev/ada0
and
/dev/ada1
. The hostname
myzfsbox
is also
shown in the commands after the pool's creation. The hostname
display becomes important when the pool is exported from one
system and imported on another. The commands that are issued
on the other system can clearly be distinguished by the
hostname that is recorded for each command.
Both options to zpool history
can be
combined to give the most detailed information possible for
any given pool. Pool history provides valuable information
when tracking down the actions that were performed or when
more detailed output is needed for debugging.
A built-in monitoring system can display pool I/O statistics in real time. It shows the amount of free and used space on the pool, how many read and write operations are being performed per second, and how much I/O bandwidth is currently being utilized. By default, all pools in the system are monitored and displayed. A pool name can be provided to limit monitoring to just that pool. A basic example:
#
zpool iostat
capacity operations bandwidth pool alloc free read write read write ---------- ----- ----- ----- ----- ----- ----- data 288G 1.53T 2 11 11.3K 57.1K
To continuously monitor I/O activity, a number can be specified as the last parameter, indicating a interval in seconds to wait between updates. The next statistic line is printed after each interval. Press Ctrl+C to stop this continuous monitoring. Alternatively, give a second number on the command line after the interval to specify the total number of statistics to display.
Even more detailed I/O statistics can
be displayed with -v
. Each device in the
pool is shown with a statistics line. This is useful in
seeing how many read and write operations are being performed
on each device, and can help determine if any individual
device is slowing down the pool. This example shows a
mirrored pool with two devices:
#
zpool iostat -v
capacity operations bandwidth pool alloc free read write read write ----------------------- ----- ----- ----- ----- ----- ----- data 288G 1.53T 2 12 9.23K 61.5K mirror 288G 1.53T 2 12 9.23K 61.5K ada1 - - 0 4 5.61K 61.7K ada2 - - 1 4 5.04K 61.7K ----------------------- ----- ----- ----- ----- ----- -----
A pool consisting of one or more mirror vdevs can be split
into two pools. Unless otherwise specified, the last member
of each mirror is detached and used to create a new pool
containing the same data. The operation should first be
attempted with -n
. The details of the
proposed operation are displayed without it actually being
performed. This helps confirm that the operation will do what
the user intends.
All FreeBSD documents are available for download at http://ftp.FreeBSD.org/pub/FreeBSD/doc/
Questions that are not answered by the
documentation may be
sent to <[email protected]>.
Send questions about this document to <[email protected]>.