513 lines
19 KiB
Groff
513 lines
19 KiB
Groff
.\"
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.\" CDDL HEADER START
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.\"
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.\" The contents of this file are subject to the terms of the
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.\" Common Development and Distribution License (the "License").
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.\" You may not use this file except in compliance with the License.
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.\" You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
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.\" or http://www.opensolaris.org/os/licensing.
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.\" If applicable, add the following below this CDDL HEADER, with the
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.\" information: Portions Copyright [yyyy] [name of copyright owner]
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.\" CDDL HEADER END
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.\"
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.\" Copyright (c) 2007, Sun Microsystems, Inc. All Rights Reserved.
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.\" Copyright (c) 2012, 2018 by Delphix. All rights reserved.
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.\" Copyright (c) 2012 Cyril Plisko. All Rights Reserved.
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.\" Copyright (c) 2017 Datto Inc.
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.\" Copyright (c) 2018 George Melikov. All Rights Reserved.
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.\" Copyright 2017 Nexenta Systems, Inc.
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.\" Copyright (c) 2017 Open-E, Inc. All Rights Reserved.
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.\"
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.Dd June 2, 2021
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.Dt ZPOOLCONCEPTS 8
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.Os
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.
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.Sh NAME
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.Nm zpoolconcepts
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.Nd overview of ZFS storage pools
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.
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.Sh DESCRIPTION
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.Ss Virtual Devices (vdevs)
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A "virtual device" describes a single device or a collection of devices
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organized according to certain performance and fault characteristics.
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The following virtual devices are supported:
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.Bl -tag -width "special"
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.It Sy disk
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A block device, typically located under
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.Pa /dev .
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ZFS can use individual slices or partitions, though the recommended mode of
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operation is to use whole disks.
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A disk can be specified by a full path, or it can be a shorthand name
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.Po the relative portion of the path under
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.Pa /dev
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.Pc .
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A whole disk can be specified by omitting the slice or partition designation.
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For example,
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.Pa sda
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is equivalent to
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.Pa /dev/sda .
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When given a whole disk, ZFS automatically labels the disk, if necessary.
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.It Sy file
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A regular file.
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The use of files as a backing store is strongly discouraged.
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It is designed primarily for experimental purposes, as the fault tolerance of a
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file is only as good as the file system on which it resides.
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A file must be specified by a full path.
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.It Sy mirror
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A mirror of two or more devices.
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Data is replicated in an identical fashion across all components of a mirror.
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A mirror with
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.Em N No disks of size Em X No can hold Em X No bytes and can withstand Em N-1
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devices failing without losing data.
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.It Sy raidz , raidz1 , raidz2 , raidz3
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A variation on RAID-5 that allows for better distribution of parity and
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eliminates the RAID-5
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.Qq write hole
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.Pq in which data and parity become inconsistent after a power loss .
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Data and parity is striped across all disks within a raidz group.
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.Pp
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A raidz group can have single, double, or triple parity, meaning that the
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raidz group can sustain one, two, or three failures, respectively, without
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losing any data.
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The
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.Sy raidz1
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vdev type specifies a single-parity raidz group; the
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.Sy raidz2
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vdev type specifies a double-parity raidz group; and the
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.Sy raidz3
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vdev type specifies a triple-parity raidz group.
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The
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.Sy raidz
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vdev type is an alias for
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.Sy raidz1 .
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.Pp
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A raidz group with
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.Em N No disks of size Em X No with Em P No parity disks can hold approximately
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.Em (N-P)*X No bytes and can withstand Em P No devices failing without losing data.
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The minimum number of devices in a raidz group is one more than the number of
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parity disks.
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The recommended number is between 3 and 9 to help increase performance.
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.It Sy draid , draid1 , draid2 , draid3
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A variant of raidz that provides integrated distributed hot spares which
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allows for faster resilvering while retaining the benefits of raidz.
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A dRAID vdev is constructed from multiple internal raidz groups, each with
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.Em D No data devices and Em P No parity devices.
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These groups are distributed over all of the children in order to fully
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utilize the available disk performance.
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.Pp
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Unlike raidz, dRAID uses a fixed stripe width (padding as necessary with
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zeros) to allow fully sequential resilvering.
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This fixed stripe width significantly effects both usable capacity and IOPS.
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For example, with the default
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.Em D=8 No and Em 4kB No disk sectors the minimum allocation size is Em 32kB .
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If using compression, this relatively large allocation size can reduce the
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effective compression ratio.
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When using ZFS volumes and dRAID, the default of the
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.Sy volblocksize
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property is increased to account for the allocation size.
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If a dRAID pool will hold a significant amount of small blocks, it is
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recommended to also add a mirrored
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.Sy special
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vdev to store those blocks.
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.Pp
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In regards to I/O, performance is similar to raidz since for any read all
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.Em D No data disks must be accessed.
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Delivered random IOPS can be reasonably approximated as
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.Sy floor((N-S)/(D+P))*single_drive_IOPS .
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.Pp
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Like raidzm a dRAID can have single-, double-, or triple-parity.
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The
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.Sy draid1 ,
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.Sy draid2 ,
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and
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.Sy draid3
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types can be used to specify the parity level.
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The
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.Sy draid
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vdev type is an alias for
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.Sy draid1 .
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.Pp
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A dRAID with
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.Em N No disks of size Em X , D No data disks per redundancy group, Em P
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.No parity level, and Em S No distributed hot spares can hold approximately
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.Em (N-S)*(D/(D+P))*X No bytes and can withstand Em P
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devices failing without losing data.
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.It Sy draid Ns Oo Ar parity Oc Ns Oo Sy \&: Ns Ar data Ns Sy d Oc Ns Oo Sy \&: Ns Ar children Ns Sy c Oc Ns Oo Sy \&: Ns Ar spares Ns Sy s Oc
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A non-default dRAID configuration can be specified by appending one or more
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of the following optional arguments to the
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.Sy draid
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keyword:
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.Bl -tag -compact -width "children"
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.It Ar parity
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The parity level (1-3).
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.It Ar data
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The number of data devices per redundancy group.
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In general, a smaller value of
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.Em D No will increase IOPS, improve the compression ratio,
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and speed up resilvering at the expense of total usable capacity.
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Defaults to
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.Em 8 , No unless Em N-P-S No is less than Em 8 .
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.It Ar children
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The expected number of children.
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Useful as a cross-check when listing a large number of devices.
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An error is returned when the provided number of children differs.
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.It Ar spares
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The number of distributed hot spares.
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Defaults to zero.
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.El
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.It Sy spare
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A pseudo-vdev which keeps track of available hot spares for a pool.
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For more information, see the
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.Sx Hot Spares
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section.
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.It Sy log
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A separate intent log device.
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If more than one log device is specified, then writes are load-balanced between
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devices.
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Log devices can be mirrored.
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However, raidz vdev types are not supported for the intent log.
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For more information, see the
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.Sx Intent Log
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section.
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.It Sy dedup
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A device dedicated solely for deduplication tables.
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The redundancy of this device should match the redundancy of the other normal
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devices in the pool.
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If more than one dedup device is specified, then
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allocations are load-balanced between those devices.
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.It Sy special
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A device dedicated solely for allocating various kinds of internal metadata,
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and optionally small file blocks.
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The redundancy of this device should match the redundancy of the other normal
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devices in the pool.
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If more than one special device is specified, then
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allocations are load-balanced between those devices.
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.Pp
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For more information on special allocations, see the
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.Sx Special Allocation Class
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section.
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.It Sy cache
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A device used to cache storage pool data.
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A cache device cannot be configured as a mirror or raidz group.
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For more information, see the
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.Sx Cache Devices
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section.
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.El
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.Pp
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Virtual devices cannot be nested, so a mirror or raidz virtual device can only
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contain files or disks.
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Mirrors of mirrors
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.Pq or other combinations
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are not allowed.
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.Pp
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A pool can have any number of virtual devices at the top of the configuration
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.Po known as
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.Qq root vdevs
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.Pc .
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Data is dynamically distributed across all top-level devices to balance data
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among devices.
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As new virtual devices are added, ZFS automatically places data on the newly
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available devices.
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.Pp
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Virtual devices are specified one at a time on the command line,
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separated by whitespace.
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Keywords like
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.Sy mirror No and Sy raidz
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are used to distinguish where a group ends and another begins.
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For example, the following creates a pool with two root vdevs,
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each a mirror of two disks:
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.Dl # Nm zpool Cm create Ar mypool Sy mirror Ar sda sdb Sy mirror Ar sdc sdd
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.
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.Ss Device Failure and Recovery
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ZFS supports a rich set of mechanisms for handling device failure and data
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corruption.
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All metadata and data is checksummed, and ZFS automatically repairs bad data
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from a good copy when corruption is detected.
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.Pp
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In order to take advantage of these features, a pool must make use of some form
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of redundancy, using either mirrored or raidz groups.
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While ZFS supports running in a non-redundant configuration, where each root
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vdev is simply a disk or file, this is strongly discouraged.
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A single case of bit corruption can render some or all of your data unavailable.
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.Pp
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A pool's health status is described by one of three states:
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.Sy online , degraded , No or Sy faulted .
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An online pool has all devices operating normally.
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A degraded pool is one in which one or more devices have failed, but the data is
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still available due to a redundant configuration.
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A faulted pool has corrupted metadata, or one or more faulted devices, and
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insufficient replicas to continue functioning.
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.Pp
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The health of the top-level vdev, such as a mirror or raidz device,
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is potentially impacted by the state of its associated vdevs,
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or component devices.
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A top-level vdev or component device is in one of the following states:
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.Bl -tag -width "DEGRADED"
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.It Sy DEGRADED
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One or more top-level vdevs is in the degraded state because one or more
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component devices are offline.
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Sufficient replicas exist to continue functioning.
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.Pp
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One or more component devices is in the degraded or faulted state, but
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sufficient replicas exist to continue functioning.
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The underlying conditions are as follows:
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.Bl -bullet -compact
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.It
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The number of checksum errors exceeds acceptable levels and the device is
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degraded as an indication that something may be wrong.
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ZFS continues to use the device as necessary.
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.It
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The number of I/O errors exceeds acceptable levels.
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The device could not be marked as faulted because there are insufficient
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replicas to continue functioning.
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.El
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.It Sy FAULTED
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One or more top-level vdevs is in the faulted state because one or more
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component devices are offline.
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Insufficient replicas exist to continue functioning.
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.Pp
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One or more component devices is in the faulted state, and insufficient
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replicas exist to continue functioning.
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The underlying conditions are as follows:
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.Bl -bullet -compact
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.It
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The device could be opened, but the contents did not match expected values.
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.It
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The number of I/O errors exceeds acceptable levels and the device is faulted to
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prevent further use of the device.
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.El
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.It Sy OFFLINE
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The device was explicitly taken offline by the
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.Nm zpool Cm offline
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command.
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.It Sy ONLINE
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The device is online and functioning.
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.It Sy REMOVED
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The device was physically removed while the system was running.
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Device removal detection is hardware-dependent and may not be supported on all
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platforms.
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.It Sy UNAVAIL
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The device could not be opened.
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If a pool is imported when a device was unavailable, then the device will be
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identified by a unique identifier instead of its path since the path was never
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correct in the first place.
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.El
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.Pp
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Checksum errors represent events where a disk returned data that was expected
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to be correct, but was not.
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In other words, these are instances of silent data corruption.
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The checksum errors are reported in
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.Nm zpool Cm status
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and
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.Nm zpool Cm events .
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When a block is stored redundantly, a damaged block may be reconstructed
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(e.g. from raidz parity or a mirrored copy).
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In this case, ZFS reports the checksum error against the disks that contained
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damaged data.
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If a block is unable to be reconstructed (e.g. due to 3 disks being damaged
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in a raidz2 group), it is not possible to determine which disks were silently
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corrupted.
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In this case, checksum errors are reported for all disks on which the block
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is stored.
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.Pp
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If a device is removed and later re-attached to the system,
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ZFS attempts online the device automatically.
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Device attachment detection is hardware-dependent
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and might not be supported on all platforms.
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.
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.Ss Hot Spares
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ZFS allows devices to be associated with pools as
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.Qq hot spares .
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These devices are not actively used in the pool, but when an active device
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fails, it is automatically replaced by a hot spare.
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To create a pool with hot spares, specify a
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.Sy spare
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vdev with any number of devices.
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For example,
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.Dl # Nm zpool Cm create Ar pool Sy mirror Ar sda sdb Sy spare Ar sdc sdd
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.Pp
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Spares can be shared across multiple pools, and can be added with the
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.Nm zpool Cm add
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command and removed with the
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.Nm zpool Cm remove
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command.
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Once a spare replacement is initiated, a new
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.Sy spare
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vdev is created within the configuration that will remain there until the
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original device is replaced.
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At this point, the hot spare becomes available again if another device fails.
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.Pp
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If a pool has a shared spare that is currently being used, the pool can not be
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exported since other pools may use this shared spare, which may lead to
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potential data corruption.
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.Pp
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Shared spares add some risk.
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If the pools are imported on different hosts,
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and both pools suffer a device failure at the same time,
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both could attempt to use the spare at the same time.
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This may not be detected, resulting in data corruption.
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.Pp
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An in-progress spare replacement can be cancelled by detaching the hot spare.
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If the original faulted device is detached, then the hot spare assumes its
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place in the configuration, and is removed from the spare list of all active
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pools.
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.Pp
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The
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.Sy draid
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vdev type provides distributed hot spares.
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These hot spares are named after the dRAID vdev they're a part of
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.Po Sy draid1 Ns - Ns Ar 2 Ns - Ns Ar 3 No specifies spare Ar 3 No of vdev Ar 2 ,
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.No which is a single parity dRAID Pc
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and may only be used by that dRAID vdev.
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Otherwise, they behave the same as normal hot spares.
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.Pp
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Spares cannot replace log devices.
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.
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.Ss Intent Log
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The ZFS Intent Log (ZIL) satisfies POSIX requirements for synchronous
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transactions.
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For instance, databases often require their transactions to be on stable storage
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devices when returning from a system call.
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NFS and other applications can also use
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.Xr fsync 2
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to ensure data stability.
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By default, the intent log is allocated from blocks within the main pool.
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However, it might be possible to get better performance using separate intent
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log devices such as NVRAM or a dedicated disk.
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For example:
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.Dl # Nm zpool Cm create Ar pool sda sdb Sy log Ar sdc
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.Pp
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Multiple log devices can also be specified, and they can be mirrored.
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See the
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.Sx EXAMPLES
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section for an example of mirroring multiple log devices.
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.Pp
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Log devices can be added, replaced, attached, detached and removed.
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In addition, log devices are imported and exported as part of the pool
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that contains them.
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Mirrored devices can be removed by specifying the top-level mirror vdev.
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.
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.Ss Cache Devices
|
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Devices can be added to a storage pool as
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.Qq cache devices .
|
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These devices provide an additional layer of caching between main memory and
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disk.
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For read-heavy workloads, where the working set size is much larger than what
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can be cached in main memory, using cache devices allows much more of this
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working set to be served from low latency media.
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Using cache devices provides the greatest performance improvement for random
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read-workloads of mostly static content.
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.Pp
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To create a pool with cache devices, specify a
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.Sy cache
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vdev with any number of devices.
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For example:
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.Dl # Nm zpool Cm create Ar pool sda sdb Sy cache Ar sdc sdd
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.Pp
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Cache devices cannot be mirrored or part of a raidz configuration.
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If a read error is encountered on a cache device, that read I/O is reissued to
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the original storage pool device, which might be part of a mirrored or raidz
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configuration.
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.Pp
|
|
The content of the cache devices is persistent across reboots and restored
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asynchronously when importing the pool in L2ARC (persistent L2ARC).
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This can be disabled by setting
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.Sy l2arc_rebuild_enabled Ns = Ns Sy 0 .
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For cache devices smaller than
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.Em 1GB ,
|
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we do not write the metadata structures
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required for rebuilding the L2ARC in order not to waste space.
|
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This can be changed with
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.Sy l2arc_rebuild_blocks_min_l2size .
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The cache device header
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.Pq Em 512B
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is updated even if no metadata structures are written.
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Setting
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.Sy l2arc_headroom Ns = Ns Sy 0
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will result in scanning the full-length ARC lists for cacheable content to be
|
|
written in L2ARC (persistent ARC).
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|
If a cache device is added with
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.Nm zpool Cm add
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its label and header will be overwritten and its contents are not going to be
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restored in L2ARC, even if the device was previously part of the pool.
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If a cache device is onlined with
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.Nm zpool Cm online
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its contents will be restored in L2ARC.
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This is useful in case of memory pressure
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where the contents of the cache device are not fully restored in L2ARC.
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The user can off- and online the cache device when there is less memory pressure
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in order to fully restore its contents to L2ARC.
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.
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.Ss Pool checkpoint
|
|
Before starting critical procedures that include destructive actions
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.Pq like Nm zfs Cm destroy ,
|
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an administrator can checkpoint the pool's state and in the case of a
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mistake or failure, rewind the entire pool back to the checkpoint.
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Otherwise, the checkpoint can be discarded when the procedure has completed
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successfully.
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.Pp
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A pool checkpoint can be thought of as a pool-wide snapshot and should be used
|
|
with care as it contains every part of the pool's state, from properties to vdev
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configuration.
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Thus, certain operations are not allowed while a pool has a checkpoint.
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Specifically, vdev removal/attach/detach, mirror splitting, and
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changing the pool's GUID.
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Adding a new vdev is supported, but in the case of a rewind it will have to be
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added again.
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Finally, users of this feature should keep in mind that scrubs in a pool that
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has a checkpoint do not repair checkpointed data.
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.Pp
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|
To create a checkpoint for a pool:
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.Dl # Nm zpool Cm checkpoint Ar pool
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.Pp
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To later rewind to its checkpointed state, you need to first export it and
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then rewind it during import:
|
|
.Dl # Nm zpool Cm export Ar pool
|
|
.Dl # Nm zpool Cm import Fl -rewind-to-checkpoint Ar pool
|
|
.Pp
|
|
To discard the checkpoint from a pool:
|
|
.Dl # Nm zpool Cm checkpoint Fl d Ar pool
|
|
.Pp
|
|
Dataset reservations (controlled by the
|
|
.Sy reservation No and Sy refreservation
|
|
properties) may be unenforceable while a checkpoint exists, because the
|
|
checkpoint is allowed to consume the dataset's reservation.
|
|
Finally, data that is part of the checkpoint but has been freed in the
|
|
current state of the pool won't be scanned during a scrub.
|
|
.
|
|
.Ss Special Allocation Class
|
|
Allocations in the special class are dedicated to specific block types.
|
|
By default this includes all metadata, the indirect blocks of user data, and
|
|
any deduplication tables.
|
|
The class can also be provisioned to accept small file blocks.
|
|
.Pp
|
|
A pool must always have at least one normal
|
|
.Pq non- Ns Sy dedup Ns /- Ns Sy special
|
|
vdev before
|
|
other devices can be assigned to the special class.
|
|
If the
|
|
.Sy special
|
|
class becomes full, then allocations intended for it
|
|
will spill back into the normal class.
|
|
.Pp
|
|
Deduplication tables can be excluded from the special class by unsetting the
|
|
.Sy zfs_ddt_data_is_special
|
|
ZFS module parameter.
|
|
.Pp
|
|
Inclusion of small file blocks in the special class is opt-in.
|
|
Each dataset can control the size of small file blocks allowed
|
|
in the special class by setting the
|
|
.Sy special_small_blocks
|
|
property to nonzero.
|
|
See
|
|
.Xr zfsprops 8
|
|
for more info on this property.
|