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lvm2/conf/example.conf.in

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# This is an example configuration file for the LVM2 system.
# It contains the default settings that would be used if there was no
# @DEFAULT_SYS_DIR@/lvm.conf file.
#
# Refer to 'man lvm.conf' for further information including the file layout.
#
# To put this file in a different directory and override @DEFAULT_SYS_DIR@ set
# the environment variable LVM_SYSTEM_DIR before running the tools.
#
# N.B. Take care that each setting only appears once if uncommenting
# example settings in this file.
# Configuration section config.
# How LVM configuration settings are handled.
config {
# Configuration option config/checks.
# If enabled, any LVM configuration mismatch is reported.
# This implies checking that the configuration key is understood
# by LVM and that the value of the key is the proper type.
# If disabled, any configuration mismatch is ignored and the default
# value is used without any warning (a message about the
# configuration key not being found is issued in verbose mode only).
checks = 1
# Configuration option config/abort_on_errors.
# Abort the LVM process if a configuration mismatch is found.
abort_on_errors = 0
# Configuration option config/profile_dir.
# Directory where LVM looks for configuration profiles.
profile_dir = "@DEFAULT_SYS_DIR@/@DEFAULT_PROFILE_SUBDIR@"
}
# Configuration section devices.
# How LVM uses block devices.
devices {
# Configuration option devices/dir.
# Directory in which to create volume group device nodes.
# Commands also accept this as a prefix on volume group names.
# This configuration option is advanced.
dir = "/dev"
# Configuration option devices/scan.
# Directories containing device nodes to use with LVM.
# This configuration option is advanced.
scan = [ "/dev" ]
# Configuration option devices/obtain_device_list_from_udev.
# Obtain the list of available devices from udev.
# This avoids opening or using any inapplicable non-block
# devices or subdirectories found in the udev directory.
# Any device node or symlink not managed by udev in the udev
# directory is ignored. This setting applies only to the
# udev-managed device directory; other directories will be
# scanned fully. LVM needs to be compiled with udev support
# for this setting to apply.
obtain_device_list_from_udev = 1
# Configuration option devices/external_device_info_source.
# Select an external device information source.
# Some information may already be available in the system and
# LVM can use this information to determine the exact type
# or use of devices it processes. Using an existing external
# device information source can speed up device processing
# as LVM does not need to run its own native routines to acquire
# this information. For example, this information is used to
# drive LVM filtering like MD component detection, multipath
# component detection, partition detection and others.
# Possible options are: none, udev.
# none - No external device information source is used.
# udev - Reuse existing udev database records. Applicable
# only if LVM is compiled with udev support.
external_device_info_source = "none"
# Configuration option devices/preferred_names.
# Select which path name to display for a block device.
# If multiple path names exist for a block device,
# and LVM needs to display a name for the device,
# the path names are matched against each item in
# this list of regular expressions. The first match is used.
# Try to avoid using undescriptive /dev/dm-N names, if present.
# If no preferred name matches, or if preferred_names are not
# defined, built-in rules are used until one produces a preference.
# Rule 1 checks path prefixes and gives preference in this order:
# /dev/mapper, /dev/disk, /dev/dm-*, /dev/block (/dev from devices/dev)
# Rule 2 prefers the path with the least slashes.
# Rule 3 prefers a symlink.
# Rule 4 prefers the path with least value in lexicographical order.
# Example:
# preferred_names = [ "^/dev/mpath/", "^/dev/mapper/mpath", "^/dev/[hs]d" ]
# This configuration option does not have a default value defined.
# preferred_names=[]
# Configuration option devices/filter.
# Limit the block devices that are used by LVM commands.
# This is a list of regular expressions used to accept or
# reject block device path names. Each regex is delimited
# by a vertical bar '|' (or any character) and is preceded
# by 'a' to accept the path, or by 'r' to reject the path.
# The first regex in the list to match the path is used,
# producing the 'a' or 'r' result for the device.
# When multiple path names exist for a block device, if any
# path name matches an 'a' pattern before an 'r' pattern,
# then the device is accepted. If all the path names match
# an 'r' pattern first, then the device is rejected.
# Unmatching path names do not affect the accept or reject
# decision. If no path names for a device match a pattern,
# then the device is accepted.
# Be careful mixing 'a' and 'r' patterns, as the combination
# might produce unexpected results (test any changes.)
# Run vgscan after changing the filter to regenerate the cache.
# See the use_lvmetad comment for a special case regarding filters.
# Example:
# Accept every block device.
# filter = [ "a|.*/|" ]
# Example:
# Reject the cdrom drive.
# filter = [ "r|/dev/cdrom|" ]
# Example:
# Work with just loopback devices, e.g. for testing.
# filter = [ "a|loop|", "r|.*|" ]
# Example:
# Accept all loop devices and ide drives except hdc.
# filter = [ "a|loop|", "r|/dev/hdc|", "a|/dev/ide|", "r|.*|" ]
# Example:
# Use anchors to be very specific.
# filter = [ "a|^/dev/hda8$|", "r|.*/|" ]
# This configuration option does not have a default value defined.
# filter = []
# Configuration option devices/global_filter.
# Limit the block devices that are used by LVM system components.
# Because devices/filter may be overridden from the command line,
# it is not suitable for system-wide device filtering, e.g. udev
# and lvmetad. Use global_filter to hide devices from these LVM
# system components. The syntax is the same as devices/filter.
# Devices rejected by global_filter are not opened by LVM.
# This configuration option does not have a default value defined.
# global_filter = []
# Configuration option devices/cache_dir.
# Directory in which to store the device cache file.
# The results of filtering are cached on disk to avoid
# rescanning dud devices (which can take a very long time).
# By default this cache is stored in a file named .cache.
# It is safe to delete this file; the tools regenerate it.
# If obtain_device_list_from_udev is enabled, the list of devices
# is obtained from udev and any existing .cache file is removed.
cache_dir = "@DEFAULT_SYS_DIR@/@DEFAULT_CACHE_SUBDIR@"
# Configuration option devices/cache_file_prefix.
# A prefix used before the .cache file name. See devices/cache_dir.
cache_file_prefix = ""
# Configuration option devices/write_cache_state.
# Enable/disable writing the cache file. See devices/cache_dir.
write_cache_state = 1
# Configuration option devices/types.
# List of additional acceptable block device types.
# These are of device type names from /proc/devices,
# followed by the maximum number of partitions.
# Example:
# types = [ "fd", 16 ]
# This configuration option is advanced.
# This configuration option does not have a default value defined.
# types = []
# Configuration option devices/sysfs_scan.
# Restrict device scanning to block devices appearing in sysfs.
# This is a quick way of filtering out block devices that are
# not present on the system. sysfs must be part of the kernel
# and mounted.)
sysfs_scan = 1
# Configuration option devices/multipath_component_detection.
# Ignore devices that are components of DM multipath devices.
multipath_component_detection = 1
# Configuration option devices/md_component_detection.
# Ignore devices that are components of software RAID (md) devices.
md_component_detection = 1
# Configuration option devices/fw_raid_component_detection.
# Ignore devices that are components of firmware RAID devices.
# LVM must use an external_device_info_source other than none
# for this detection to execute.
fw_raid_component_detection = 0
# Configuration option devices/md_chunk_alignment.
# Align PV data blocks with md device's stripe-width.
# This applies if a PV is placed directly on an md device.
md_chunk_alignment = 1
# Configuration option devices/default_data_alignment.
# Default alignment of the start of a PV data area in MB.
# If set to 0, a value of 64KB will be used.
# Set to 1 for 1MiB, 2 for 2MiB, etc.
# default_data_alignment = 1
# Configuration option devices/data_alignment_detection.
# Detect PV data alignment based on sysfs device information.
# The start of a PV data area will be a multiple of
# minimum_io_size or optimal_io_size exposed in sysfs.
# minimum_io_size is the smallest request the device can perform
# without incurring a read-modify-write penalty, e.g. MD chunk size.
# optimal_io_size is the device's preferred unit of receiving I/O,
# e.g. MD stripe width.
# minimum_io_size is used if optimal_io_size is undefined (0).
# If md_chunk_alignment is enabled, that detects the optimal_io_size.
# This setting takes precedence over md_chunk_alignment.
data_alignment_detection = 1
# Configuration option devices/data_alignment.
# Alignment of the start of a PV data area in KB.
# If a PV is placed directly on an md device and
# md_chunk_alignment or data_alignment_detection are enabled,
# then this setting is ignored. Otherwise, md_chunk_alignment
# and data_alignment_detection are disabled if this is set.
# Set to 0 to use the default alignment or the page size, if larger.
data_alignment = 0
# Configuration option devices/data_alignment_offset_detection.
# Detect PV data alignment offset based on sysfs device information.
# The start of a PV aligned data area will be shifted by the
# alignment_offset exposed in sysfs. This offset is often 0, but
# may be non-zero. Certain 4KB sector drives that compensate for
# windows partitioning will have an alignment_offset of 3584 bytes
# (sector 7 is the lowest aligned logical block, the 4KB sectors start
# at LBA -1, and consequently sector 63 is aligned on a 4KB boundary).
# pvcreate --dataalignmentoffset will skip this detection.
data_alignment_offset_detection = 1
# Configuration option devices/ignore_suspended_devices.
# Ignore DM devices that have I/O suspended while scanning devices.
# Otherwise, LVM waits for a suspended device to become accessible.
# This should only be needed in recovery situations.
ignore_suspended_devices = 0
# Configuration option devices/ignore_lvm_mirrors.
# Do not scan 'mirror' LVs to avoid possible deadlocks.
# This avoids possible deadlocks when using the 'mirror'
# segment type. This setting determines whether logical volumes
# using the 'mirror' segment type are scanned for LVM labels.
# This affects the ability of mirrors to be used as physical volumes.
# If this setting is enabled, it becomes impossible to create VGs
# on top of mirror LVs, i.e. to stack VGs on mirror LVs.
# If this setting is disabled, allowing mirror LVs to be scanned,
# it may cause LVM processes and I/O to the mirror to become blocked.
# This is due to the way that the mirror segment type handles failures.
# In order for the hang to occur, an LVM command must be run just after
# a failure and before the automatic LVM repair process takes place,
# or there must be failures in multiple mirrors in the same VG at the
# same time with write failures occurring moments before a scan of the
# mirror's labels.
# The 'mirror' scanning problems do not apply to LVM RAID types like
# 'raid1' which handle failures in a different way, making them a
# better choice for VG stacking.
ignore_lvm_mirrors = 1
# Configuration option devices/disable_after_error_count.
# Number of I/O errors after which a device is skipped.
# During each LVM operation, errors received from each device
# are counted. If the counter of a device exceeds the limit set
# here, no further I/O is sent to that device for the remainder
# of the operation.
# Setting this to 0 disables the counters altogether.
disable_after_error_count = 0
# Configuration option devices/require_restorefile_with_uuid.
# Allow use of pvcreate --uuid without requiring --restorefile.
require_restorefile_with_uuid = 1
# Configuration option devices/pv_min_size.
# Minimum size (in KB) of block devices which can be used as PVs.
# In a clustered environment all nodes must use the same value.
# Any value smaller than 512KB is ignored. The previous built-in
# value was 512.
pv_min_size = 2048
# Configuration option devices/issue_discards.
# Issue discards to PVs that are no longer used by an LV.
# Discards are sent to an LV's underlying physical volumes when
# the LV is no longer using the physical volumes' space, e.g.
# lvremove, lvreduce. Discards inform the storage that a region
# is no longer used. Storage that supports discards advertise
# the protocol-specific way discards should be issued by the
# kernel (TRIM, UNMAP, or WRITE SAME with UNMAP bit set).
# Not all storage will support or benefit from discards, but SSDs
# and thinly provisioned LUNs generally do. If enabled, discards
# will only be issued if both the storage and kernel provide support.
issue_discards = 0
}
# Configuration section allocation.
# How LVM selects free space for Logical Volumes.
allocation {
# Configuration option allocation/cling_tag_list.
# Advise LVM which PVs to use when searching for new space.
# When searching for free space to extend an LV, the 'cling'
# allocation policy will choose space on the same PVs as the last
# segment of the existing LV. If there is insufficient space and a
# list of tags is defined here, it will check whether any of them are
# attached to the PVs concerned and then seek to match those PV tags
# between existing extents and new extents.
# Example:
# Use the special tag "@*" as a wildcard to match any PV tag.
# cling_tag_list = [ "@*" ]
# Example:
# LVs are mirrored between two sites within a single VG.
# PVs are tagged with either @site1 or @site2 to indicate where
# they are situated.
# cling_tag_list = [ "@site1", "@site2" ]
# This configuration option does not have a default value defined.
# cling_tag_list = []
# Configuration option allocation/maximise_cling.
# Use a previous allocation algorithm.
# Changes made in version 2.02.85 extended the reach of the 'cling'
# policies to detect more situations where data can be grouped onto
# the same disks. This setting can be used to disable the changes
# and revert to the previous algorithm.
maximise_cling = 1
# Configuration option allocation/use_blkid_wiping.
# Use blkid to detect existing signatures on new PVs and LVs.
# The blkid library can detect more signatures than the
# native LVM detection code, but may take longer.
# LVM needs to be compiled with blkid wiping support for
# this setting to apply.
# LVM native detection code is currently able to recognize:
# MD device signatures, swap signature, and LUKS signatures.
# To see the list of signatures recognized by blkid, check the
# output of the 'blkid -k' command.
use_blkid_wiping = 1
# Configuration option allocation/wipe_signatures_when_zeroing_new_lvs.
# Look for and erase any signatures while zeroing a new LV.
# Zeroing is controlled by the -Z/--zero option, and if not
# specified, zeroing is used by default if possible.
# Zeroing simply overwrites the first 4 KiB of a new LV
# with zeroes and does no signature detection or wiping.
# Signature wiping goes beyond zeroing and detects exact
# types and positions of signatures within the whole LV.
# It provides a cleaner LV after creation as all known
# signatures are wiped. The LV is not claimed incorrectly
# by other tools because of old signatures from previous use.
# The number of signatures that LVM can detect depends on the
# detection code that is selected (see use_blkid_wiping.)
# Wiping each detected signature must be confirmed.
# The command line option -W/--wipesignatures takes precedence
# over this setting.
# When this setting is disabled, signatures on new LVs are
# not detected or erased unless the -W/--wipesignatures y
# option is used directly.
wipe_signatures_when_zeroing_new_lvs = 1
# Configuration option allocation/mirror_logs_require_separate_pvs.
# Mirror logs and images will always use different PVs.
# The default setting changed in version 2.02.85.
mirror_logs_require_separate_pvs = 0
# Configuration option allocation/cache_pool_metadata_require_separate_pvs.
# Cache pool metadata and data will always use different PVs.
cache_pool_metadata_require_separate_pvs = 0
# Configuration option allocation/cache_pool_cachemode.
# The default cache mode used for new cache pools.
# Possible options are: writethrough, writeback.
# writethrough - Data blocks are immediately written from
# the cache to disk.
# writeback - Data blocks are written from the cache back
# to disk after some delay to improve performance.
# cache_pool_cachemode = "writethrough"
# Configuration option allocation/cache_pool_chunk_size.
# The minimal chunk size (in kiB) for cache pool volumes.
# Using a chunk_size that is too large can result in wasteful
# use of the cache, where small reads and writes can cause
# large sections of an LV to be mapped into the cache. However,
# choosing a chunk_size that is too small can result in more
# overhead trying to manage the numerous chunks that become mapped
# into the cache. The former is more of a problem than the latter
# in most cases, so we default to a value that is on the smaller
# end of the spectrum. Supported values range from 32(kiB) to
# 1048576 in multiples of 32.
# This configuration option does not have a default value defined.
# cache_pool_chunk_size = 128
# Configuration option allocation/thin_pool_metadata_require_separate_pvs.
# Thin pool metdata and data will always use different PVs.
thin_pool_metadata_require_separate_pvs = 0
# Configuration option allocation/thin_pool_zero.
# Thin pool data chunks are zeroed before they are first used.
# Zeroing with a larger thin pool chunk size reduces performance.
# thin_pool_zero = 1
# Configuration option allocation/thin_pool_discards.
# The discards behaviour of thin pool volumes.
# Possible options are: ignore, nopassdown, passdown.
# thin_pool_discards = "passdown"
# Configuration option allocation/thin_pool_chunk_size_policy.
# The chunk size calculation policy for thin pool volumes.
# Possible options are: generic, performance.
# generic - If thin_pool_chunk_size is defined, use it.
# Otherwise, calculate the chunk size based on estimation and
# device hints exposed in sysfs - the minimum_io_size.
# The chunk size is always at least 64KiB.
# performance - If thin_pool_chunk_size is defined, use it.
# Otherwise, calculate the chunk size for performance based on
# device hints exposed in sysfs - the optimal_io_size.
# The chunk size is always at least 512KiB.
# thin_pool_chunk_size_policy = "generic"
# Configuration option allocation/thin_pool_chunk_size.
# The minimal chunk size (in KB) for thin pool volumes.
# Larger chunk sizes may improve performance for plain
# thin volumes, however using them for snapshot volumes
# is less efficient, as it consumes more space and takes
# extra time for copying. When unset, lvm tries to estimate
# chunk size starting from 64KB. Supported values are in
# the range 64 to 1048576.
# This configuration option does not have a default value defined.
# thin_pool_chunk_size = 128
# Configuration option allocation/physical_extent_size.
# Default physical extent size to use for new VGs (in KB).
# physical_extent_size = 4096
}
# Configuration section log.
# How LVM log information is reported.
log {
# Configuration option log/verbose.
# Controls the messages sent to stdout or stderr.
verbose = 0
# Configuration option log/silent.
# Suppress all non-essential messages from stdout.
# This has the same effect as -qq.
# When enabled, the following commands still produce output:
# dumpconfig, lvdisplay, lvmdiskscan, lvs, pvck, pvdisplay,
# pvs, version, vgcfgrestore -l, vgdisplay, vgs.
# Non-essential messages are shifted from log level 4 to log level 5
# for syslog and lvm2_log_fn purposes.
# Any 'yes' or 'no' questions not overridden by other arguments
# are suppressed and default to 'no'.
silent = 0
# Configuration option log/syslog.
# Send log messages through syslog.
syslog = 1
# Configuration option log/file.
# Write error and debug log messages to a file specified here.
# This configuration option does not have a default value defined.
# file = ""
# Configuration option log/overwrite.
# Overwrite the log file each time the program is run.
overwrite = 0
# Configuration option log/level.
# The level of log messages that are sent to the log file or syslog.
# There are 6 syslog-like log levels currently in use: 2 to 7 inclusive.
# 7 is the most verbose (LOG_DEBUG).
level = 0
# Configuration option log/indent.
# Indent messages according to their severity.
indent = 1
# Configuration option log/command_names.
# Display the command name on each line of output.
command_names = 0
# Configuration option log/prefix.
# A prefix to use before the log message text.
# (After the command name, if selected).
# Two spaces allows you to see/grep the severity of each message.
# To make the messages look similar to the original LVM tools use:
# indent = 0, command_names = 1, prefix = " -- "
prefix = " "
# Configuration option log/activation.
# Log messages during activation.
# Don't use this in low memory situations (can deadlock).
# activation = 0
# Configuration option log/debug_classes.
# Select log messages by class.
# Some debugging messages are assigned to a class
# and only appear in debug output if the class is
# listed here. Classes currently available:
# memory, devices, activation, allocation,
# lvmetad, metadata, cache, locking.
# Use "all" to see everything.
debug_classes = ["memory", "devices", "activation", "allocation",
"lvmetad", "metadata", "cache", "locking"]
}
# Configuration section backup.
# How LVM metadata is backed up and archived.
# In LVM, a 'backup' is a copy of the metadata for the
# current system, and an 'archive' contains old metadata
# configurations. They are stored in a human readable
# text format.
backup {
# Configuration option backup/backup.
# Maintain a backup of the current metadata configuration.
# Think very hard before turning this off!
backup = 1
# Configuration option backup/backup_dir.
# Location of the metadata backup files.
# Remember to back up this directory regularly!
backup_dir = "@DEFAULT_SYS_DIR@/@DEFAULT_BACKUP_SUBDIR@"
# Configuration option backup/archive.
# Maintain an archive of old metadata configurations.
# Think very hard before turning this off.
archive = 1
# Configuration option backup/archive_dir.
# Location of the metdata archive files.
# Remember to back up this directory regularly!
archive_dir = "@DEFAULT_SYS_DIR@/@DEFAULT_ARCHIVE_SUBDIR@"
# Configuration option backup/retain_min.
# Minimum number of archives to keep.
retain_min = 10
# Configuration option backup/retain_days.
# Minimum number of days to keep archive files.
retain_days = 30
}
# Configuration section shell.
# Settings for running LVM in shell (readline) mode.
shell {
# Configuration option shell/history_size.
# Number of lines of history to store in ~/.lvm_history.
history_size = 100
}
# Configuration section global.
# Miscellaneous global LVM settings.
global {
# Configuration option global/umask.
# The file creation mask for any files and directories created.
# Interpreted as octal if the first digit is zero.
umask = 077
# Configuration option global/test.
# No on-disk metadata changes will be made in test mode.
# Equivalent to having the -t option on every command.
test = 0
# Configuration option global/units.
# Default value for --units argument.
units = "h"
# Configuration option global/si_unit_consistency.
# Distinguish between powers of 1024 and 1000 bytes.
# The LVM commands distinguish between powers of 1024 bytes,
# e.g. KiB, MiB, GiB, and powers of 1000 bytes, e.g. KB, MB, GB.
# If scripts depend on the old behaviour, disable
# this setting temporarily until they are updated.
si_unit_consistency = 1
# Configuration option global/suffix.
# Display unit suffix for sizes.
# This setting has no effect if the units are in human-readable
# form (global/units = "h") in which case the suffix is always
# displayed.
suffix = 1
# Configuration option global/activation.
# Enable/disable communication with the kernel device-mapper.
# Disable to use the tools to manipulate LVM metadata without
# activating any logical volumes. If the device-mapper driver
# is not present in the kernel, disabling this should suppress
# the error messages.
activation = 1
# Configuration option global/fallback_to_lvm1.
# Try running LVM1 tools if LVM cannot communicate with DM.
# This option only applies to 2.4 kernels and is provided to
# help switch between device-mapper kernels and LVM1 kernels.
# The LVM1 tools need to be installed with .lvm1 suffices,
# e.g. vgscan.lvm1. They will stop working once the lvm2
# on-disk metadata format is used.
# fallback_to_lvm1 = 0
# Configuration option global/format.
# The default metadata format that commands should use.
# "lvm1" or "lvm2".
# The command line override is -M1 or -M2.
# format = "lvm2"
# Configuration option global/format_libraries.
# Shared libraries that process different metadata formats.
# If support for LVM1 metadata was compiled as a shared library use
# format_libraries = "liblvm2format1.so"
# This configuration option does not have a default value defined.
# format_libraries = []
# Configuration option global/segment_libraries.
# This configuration option does not have a default value defined.
# segment_libraries = []
# Configuration option global/proc.
# Location of proc filesystem.
# This configuration option is advanced.
proc = "/proc"
# Configuration option global/etc.
# Location of /etc system configuration directory.
etc = "@CONFDIR@"
# Configuration option global/locking_type.
# Type of locking to use.
# Type 0: turns off locking. Warning: this risks metadata
# corruption if commands run concurrently.
# Type 1: uses local file-based locking, the standard mode.
# Type 2: uses the external shared library locking_library.
# Type 3: uses built-in clustered locking with clvmd.
# This is incompatible with lvmetad. If use_lvmetad is enabled,
# lvm prints a warning and disables lvmetad use.
# Type 4: uses read-only locking which forbids any operations
# that might change metadata.
# Type 5: offers dummy locking for tools that do not need any locks.
# You should not need to set this directly; the tools will select
# when to use it instead of the configured locking_type.
# Do not use lvmetad or the kernel device-mapper driver with this
# locking type. It is used by the --readonly option that offers
# read-only access to Volume Group metadata that cannot be locked
# safely because it belongs to an inaccessible domain and might be
# in use, for example a virtual machine image or a disk that is
# shared by a clustered machine.
locking_type = 1
# Configuration option global/wait_for_locks.
# When disabled, fail if a lock request would block.
wait_for_locks = 1
# Configuration option global/fallback_to_clustered_locking.
# Attempt to use built-in cluster locking if locking_type 2 fails.
# If using external locking (type 2) and initialisation fails,
# with this enabled, an attempt will be made to use the built-in
# clustered locking.
# If you are using a customised locking_library you should disable this.
fallback_to_clustered_locking = 1
# Configuration option global/fallback_to_local_locking.
# Use locking_type 1 (local) if locking_type 2 or 3 fail.
# If an attempt to initialise type 2 or type 3 locking failed,
# perhaps because cluster components such as clvmd are not
# running, with this enabled, an attempt will be made to use
# local file-based locking (type 1). If this succeeds, only
# commands against local volume groups will proceed.
# Volume Groups marked as clustered will be ignored.
fallback_to_local_locking = 1
# Configuration option global/locking_dir.
# Directory to use for LVM command file locks.
# Local non-LV directory that holds file-based locks
# while commands are in progress. A directory like
# /tmp that may get wiped on reboot is OK.
locking_dir = "@DEFAULT_LOCK_DIR@"
# Configuration option global/prioritise_write_locks.
# Allow quicker VG write access during high volume read access.
# When there are competing read-only and read-write access
# requests for a volume group's metadata, instead of always
# granting the read-only requests immediately, delay them to
# allow the read-write requests to be serviced. Without this
# setting, write access may be stalled by a high volume of
# read-only requests.
# This option only affects locking_type 1 viz.
# local file-based locking.
prioritise_write_locks = 1
# Configuration option global/library_dir.
# Search this directory first for shared libraries.
# This configuration option does not have a default value defined.
# library_dir = ""
# Configuration option global/locking_library.
# The external locking library to use for locking_type 2.
# locking_library = "liblvm2clusterlock.so"
# Configuration option global/abort_on_internal_errors.
# Abort a command that encounters an internal error.
# Treat any internal errors as fatal errors, aborting
# the process that encountered the internal error.
# Please only enable for debugging.
abort_on_internal_errors = 0
# Configuration option global/detect_internal_vg_cache_corruption.
# Internal verification of VG structures.
# Check if CRC matches when a parsed VG is
# used multiple times. This is useful to catch
# unexpected changes to cached VG structures.
# Please only enable for debugging.
detect_internal_vg_cache_corruption = 0
# Configuration option global/metadata_read_only.
# No operations that change on-disk metadata are permitted.
# Additionally, read-only commands that encounter metadata
# in need of repair will still be allowed to proceed exactly
# as if the repair had been performed (except for the unchanged
# vg_seqno). Inappropriate use could mess up your system,
# so seek advice first!
metadata_read_only = 0
# Configuration option global/mirror_segtype_default.
# The segment type used by the short mirroring option -m.
# Possible options are: mirror, raid1.
# mirror - the original RAID1 implementation from LVM/DM.
# It is characterized by a flexible log solution (core,
# disk, mirrored), and by the necessity to block I/O while
# handling a failure.
# There is an inherent race in the dmeventd failure
# handling logic with snapshots of devices using this
# type of RAID1 that in the worst case could cause a
# deadlock. (Also see devices/ignore_lvm_mirrors.)
# raid1 - a newer RAID1 implementation using the MD RAID1
# personality through device-mapper. It is characterized
# by a lack of log options. (A log is always allocated for
# every device and they are placed on the same device as the
# image - no separate devices are required.) This mirror
# implementation does not require I/O to be blocked while
# handling a failure. This mirror implementation is not
# cluster-aware and cannot be used in a shared (active/active)
# fashion in a cluster.
# The '--type mirror|raid1' option overrides this setting.
mirror_segtype_default = "@DEFAULT_MIRROR_SEGTYPE@"
# Configuration option global/raid10_segtype_default.
# The segment type used by the -i -m combination.
# The --stripes/-i and --mirrors/-m options can both
# be specified during the creation of a logical volume
# to use both striping and mirroring for the LV.
# There are two different implementations.
# Possible options are: raid10, mirror.
# raid10 - LVM uses MD's RAID10 personality through DM.
# mirror - LVM layers the 'mirror' and 'stripe' segment types.
# The layering is done by creating a mirror LV on top of
# striped sub-LVs, effectively creating a RAID 0+1 array.
# The layering is suboptimal in terms of providing redundancy
# and performance. The 'raid10' option is perferred.
# The '--type raid10|mirror' option overrides this setting.
raid10_segtype_default = "@DEFAULT_RAID10_SEGTYPE@"
# Configuration option global/sparse_segtype_default.
# The segment type used by the -V -L combination.
# The combination of -V and -L options creates a
# sparse LV. There are two different implementations.
# Possible options are: snapshot, thin.
# snapshot - The original snapshot implementation from LVM/DM.
# It uses an old snapshot that mixes data and metadata within
# a single COW storage volume and performs poorly when the
# size of stored data passes hundreds of MB.
# thin - A newer implementation that uses thin provisioning.
# It has a bigger minimal chunk size (64KiB) and uses a separate
# volume for metadata. It has better performance, especially
# when more data is used. It also supports full snapshots.
# The '--type snapshot|thin' option overrides this setting.
sparse_segtype_default = "@DEFAULT_SPARSE_SEGTYPE@"
# Configuration option global/lvdisplay_shows_full_device_path.
# The default format for displaying LV names in lvdisplay was changed
# in version 2.02.89 to show the LV name and path separately.
# Previously this was always shown as /dev/vgname/lvname even when that
# was never a valid path in the /dev filesystem.
# Enable this option to reinstate the previous format.
# lvdisplay_shows_full_device_path = 0
# Configuration option global/use_lvmetad.
# Use lvmetad to cache metadata and reduce disk scanning.
# When enabled (and running), lvmetad provides LVM commands
# with VG metadata and PV state. LVM commands then avoid
# reading this information from disks which can be slow.
# When disabled (or not running), LVM commands fall back to
# scanning disks to obtain VG metadata.
# lvmetad is kept updated via udev rules which must be set
# up for LVM to work correctly. (The udev rules should be
# installed by default.) Without a proper udev setup, changes
# in the system's block device configuration will be unknown
# to LVM, and ignored until a manual 'pvscan --cache' is run.
# If lvmetad was running while use_lvmetad was disabled,
# it must be stopped, use_lvmetad enabled, and then started.
# When using lvmetad, LV activation is switched to an automatic,
# event-based mode. In this mode, LVs are activated based on
# incoming udev events that inform lvmetad when PVs appear on
# the system. When a VG is complete (all PVs present), it is
# auto-activated. The auto_activation_volume_list setting
# controls which LVs are auto-activated (all by default.)
# When lvmetad is updated (automatically by udev events, or
# directly by pvscan --cache), devices/filter is ignored and
# all devices are scanned by default. lvmetad always keeps
# unfiltered information which is provided to LVM commands.
# Each LVM command then filters based on devices/filter.
# This does not apply to other, non-regexp, filtering settings:
# component filters such as multipath and MD are checked
# during pvscan --cache.
# To filter a device and prevent scanning from the LVM system
# entirely, including lvmetad, use devices/global_filter.
# lvmetad is not compatible with locking_type 3 (clustering).
# LVM prints warnings and ignores lvmetad if this combination
# is seen.
use_lvmetad = 0
# Configuration option global/thin_check_executable.
# The full path to the thin_check command.
# LVM uses this command to check that a thin metadata
# device is in a usable state.
# When a thin pool is activated and after it is deactivated,
# this command is run. Activation will only proceed if the
# command has an exit status of 0.
# Set to "" to skip this check. (Not recommended.)
# Also see thin_check_options.
# The thin tools are available from the package
# device-mapper-persistent-data.
# thin_check_executable = "@THIN_CHECK_CMD@"
# Configuration option global/thin_dump_executable.
# The full path to the thin_dump command.
# LVM uses this command to dump thin pool metadata.
# (For thin tools, see thin_check_executable.)
# thin_dump_executable = "@THIN_DUMP_CMD@"
# Configuration option global/thin_repair_executable.
# The full path to the thin_repair command.
# LVM uses this command to repair a thin metadata device
# if it is in an unusable state.
# Also see thin_repair_options.
# (For thin tools, see thin_check_executable.)
# thin_repair_executable = "@THIN_REPAIR_CMD@"
# Configuration option global/thin_check_options.
# List of options passed to the thin_check command.
# With thin_check version 2.1 or newer you can add
# --ignore-non-fatal-errors to let it pass through
# ignorable errors and fix them later.
# With thin_check version 3.2 or newer you should add
# --clear-needs-check-flag.
# thin_check_options = ["-q", "--clear-needs-check-flag"]
# Configuration option global/thin_repair_options.
# List of options passed to the thin_repair command.
# This configuration option does not have a default value defined.
# thin_repair_options = ""
# Configuration option global/thin_disabled_features.
# Features to not use in the thin driver.
# This can be helpful for testing, or to avoid
# using a feature that is causing problems.
# Features: block_size, discards, discards_non_power_2,
# external_origin, metadata_resize, external_origin_extend,
# error_if_no_space.
# Example:
# thin_disabled_features = [ "discards", "block_size" ]
# This configuration option does not have a default value defined.
# thin_disabled_features = []
# Configuration option global/cache_check_executable.
# The full path to the cache_check command.
# LVM uses this command to check that a cache metadata
# device is in a usable state.
# When a cached LV is activated and after it is deactivated,
# this command is run. Activation will only proceed if the
# command has an exit status of 0.
# Set to "" to skip this check. (Not recommended.)
# Also see cache_check_options.
# The cache tools are available from the package
# device-mapper-persistent-data.
# cache_check_executable = "@CACHE_CHECK_CMD@"
# Configuration option global/cache_dump_executable.
# The full path to the cache_dump command.
# LVM uses this command to dump cache pool metadata.
# (For cache tools, see cache_check_executable.)
# cache_dump_executable = "@CACHE_DUMP_CMD@"
# Configuration option global/cache_repair_executable.
# The full path to the cache_repair command.
# LVM uses this command to repair a cache metadata device
# if it is in an unusable state.
# Also see cache_repair_options.
# (For cache tools, see cache_check_executable.)
# cache_repair_executable = "@CACHE_REPAIR_CMD@"
# Configuration option global/cache_check_options.
# List of options passed to the cache_check command.
# cache_check_options = "-q"
# Configuration option global/cache_repair_options.
# List of options passed to the cache_repair command.
# This configuration option does not have a default value defined.
# cache_repair_options = ""
# Configuration option global/system_id_source.
# The method LVM uses to set the local system ID.
# Volume Groups can also be given a system ID (by
# vgcreate, vgchange, or vgimport.)
# A VG on shared storage devices is accessible only
# to the host with a matching system ID.
# See 'man lvmsystemid' for information on limitations
# and correct usage.
# Possible options are: none, lvmlocal, uname, machineid, file.
# none - The host has no system ID.
# lvmlocal - Obtain the system ID from the system_id setting in the
# 'local' section of an lvm configuration file, e.g. lvmlocal.conf.
# uname - Set the system ID from the hostname (uname) of the system.
# System IDs beginning localhost are not permitted.
# machineid - Use the contents of the file /etc/machine-id to set the
# system ID. Some systems create this file at installation time.
# See 'man machine-id'.
# file - Use the contents of another file (system_id_file) to set
# the system ID.
# system_id_source = "none"
# Configuration option global/system_id_file.
# The full path to the file containing a system ID.
# This is used when system_id_source is set to 'file'.
# Comments starting with the character # are ignored.
# This configuration option does not have a default value defined.
# system_id_file = ""
# Indicates whether to use lvmpolld instead of classical polldaemon (a process
# forked off an initiating lvm command) or not. When set to 1 and native systemd
# service is installed in the system lvm starts using lvmpolld. lvmpolld gets
# auto-activated by systemd when a message lands on the respective lvmpolld socket.
# All commands that would require polling of in-progress operation are therefore
# spawned in lvmpolld's service cgroup.
#
# When set to 0 lvm falls back to classical polling.
use_lvmpolld = 0
}
# Configuration section activation.
activation {
# Configuration option activation/checks.
# Perform internal checks of libdevmapper operations.
# Useful for debugging problems with activation.
# Some of the checks may be expensive, so it's best to use
# this only when there seems to be a problem.
checks = 0
# Configuration option activation/udev_sync.
# Use udev notifications to synchronize udev and LVM.
# When disabled, LVM commands will not wait for notifications
# from udev, but continue irrespective of any possible udev
# processing in the background. Only use this if udev is not
# running or has rules that ignore the devices LVM creates.
# If enabled when udev is not running, and LVM processes
# are waiting for udev, run 'dmsetup udevcomplete_all' to
# wake them up.
# The '--nodevsync' option overrides this setting.
udev_sync = 1
# Configuration option activation/udev_rules.
# Use udev rules to manage LV device nodes and symlinks.
# When disabled, LVM will manage the device nodes and
# symlinks for active LVs itself.
# Manual intervention may be required if this setting is
# changed while LVs are active.
udev_rules = 1
# Configuration option activation/verify_udev_operations.
# Use extra checks in LVM to verify udev operations.
# This enables additional checks (and if necessary,
# repairs) on entries in the device directory after
# udev has completed processing its events.
# Useful for diagnosing problems with LVM/udev interactions.
verify_udev_operations = 0
# Configuration option activation/retry_deactivation.
# Retry failed LV deactivation.
# If LV deactivation fails, LVM will retry for a few
# seconds before failing. This may happen because a
# process run from a quick udev rule temporarily opened
# the device.
retry_deactivation = 1
# Configuration option activation/missing_stripe_filler.
# Method to fill missing stripes when activating an incomplete LV.
# Using 'error' will make inaccessible parts of the device return
# I/O errors on access. You can instead use a device path, in which
# case, that device will be used in place of missing stripes.
# Using anything other than 'error' with mirrored or snapshotted
# volumes is likely to result in data corruption.
# This configuration option is advanced.
missing_stripe_filler = "error"
# Configuration option activation/use_linear_target.
# Use the linear target to optimize single stripe LVs.
# When disabled, the striped target is used. The linear
# target is an optimised version of the striped target
# that only handles a single stripe.
use_linear_target = 1
# Configuration option activation/reserved_stack.
# Stack size in KB to reserve for use while devices are suspended.
# Insufficent reserve risks I/O deadlock during device suspension.
reserved_stack = 64
# Configuration option activation/reserved_memory.
# Memory size in KB to reserve for use while devices are suspended.
# Insufficent reserve risks I/O deadlock during device suspension.
reserved_memory = 8192
# Configuration option activation/process_priority.
# Nice value used while devices are suspended.
# Use a high priority so that LVs are suspended
# for the shortest possible time.
process_priority = -18
# Configuration option activation/volume_list.
# Only LVs selected by this list are activated.
# If this list is defined, an LV is only activated
# if it matches an entry in this list.
# If this list is undefined, it imposes no limits
# on LV activation (all are allowed).
# Possible options are: vgname, vgname/lvname, @tag, @*
# vgname is matched exactly and selects all LVs in the VG.
# vgname/lvname is matched exactly and selects the LV.
# @tag selects if tag matches a tag set on the LV or VG.
# @* selects if a tag defined on the host is also set on
# the LV or VG. See tags/hosttags.
# If any host tags exist but volume_list is not defined,
# a default single-entry list containing '@*' is assumed.
# Example:
# volume_list = [ "vg1", "vg2/lvol1", "@tag1", "@*" ]
# This configuration option does not have a default value defined.
# volume_list = []
# Configuration option activation/auto_activation_volume_list.
# Only LVs selected by this list are auto-activated.
# This list works like volume_list, but it is used
# only by auto-activation commands. It does not apply
# to direct activation commands.
# If this list is defined, an LV is only auto-activated
# if it matches an entry in this list.
# If this list is undefined, it imposes no limits
# on LV auto-activation (all are allowed.)
# If this list is defined and empty, i.e. "[]",
# then no LVs are selected for auto-activation.
# An LV that is selected by this list for
# auto-activation, must also be selected by
# volume_list (if defined) before it is activated.
# Auto-activation is an activation command that
# includes the 'a' argument: --activate ay or -a ay,
# e.g. vgchange -a ay, or lvchange -a ay vgname/lvname.
# The 'a' (auto) argument for auto-activation is
# meant to be used by activation commands that are
# run automatically by the system, as opposed to
# LVM commands run directly by a user. A user may
# also use the 'a' flag directly to perform auto-
# activation.
# An example of a system-generated auto-activation
# command is 'pvscan --cache -aay' which is generated
# when udev and lvmetad detect a new VG has appeared
# on the system, and want LVs in it to be auto-activated.
# Possible options are: vgname, vgname/lvname, @tag, @*
# See volume_list for how these options are matched to LVs.
# This configuration option does not have a default value defined.
# auto_activation_volume_list = []
# Configuration option activation/read_only_volume_list.
# LVs in this list are activated in read-only mode.
# If this list is defined, each LV that is to be activated
# is checked against this list, and if it matches, it is
# activated in read-only mode.
# This overrides the permission setting stored in the
# metadata, e.g. from --permission rw.
# Possible options are: vgname, vgname/lvname, @tag, @*
# See volume_list for how these options are matched to LVs.
# This configuration option does not have a default value defined.
# read_only_volume_list = []
# Configuration option activation/raid_region_size.
# Size in KiB of each raid or mirror synchronization region.
# For raid or mirror segment types, this is the amount of
# data that is copied at once when initializing, or moved
# at once by pvmove.
raid_region_size = 512
# Configuration option activation/error_when_full.
# Return errors if a thin pool runs out of space.
# When enabled, writes to thin LVs immediately return
# an error if the thin pool is out of data space.
# When disabled, writes to thin LVs are queued if the
# thin pool is out of space, and processed when the
# thin pool data space is extended.
# New thin pools are assigned the behavior defined here.
# The '--errorwhenfull y|n' option overrides this setting.
# error_when_full = 0
# Configuration option activation/readahead.
# Setting to use when there is no readahead setting in metadata.
# Possible options are: none, auto.
# none - Disable readahead.
# auto - Use default value chosen by kernel.
readahead = "auto"
# Configuration option activation/raid_fault_policy.
# Defines how a device failure in a RAID LV is handled.
# This includes LVs that have the following segment types:
# raid1, raid4, raid5*, and raid6*.
# If a device in the LV fails, the policy determines the
# steps perfomed by dmeventd automatically, and the steps
# perfomed by 'lvconvert --repair --use-policies' run manually.
# Automatic handling requires dmeventd to be monitoring the LV.
# Possible options are: warn, allocate.
# warn - Use the system log to warn the user that a device
# in the RAID LV has failed. It is left to the user to run
# 'lvconvert --repair' manually to remove or replace the failed
# device. As long as the number of failed devices does not
# exceed the redundancy of the logical volume (1 device for
# raid4/5, 2 for raid6, etc) the LV will remain usable.
# allocate - Attempt to use any extra physical volumes in the
# volume group as spares and replace faulty devices.
raid_fault_policy = "warn"
# Configuration option activation/mirror_image_fault_policy.
# Defines how a device failure in a 'mirror' LV is handled.
# An LV with the 'mirror' segment type is composed of mirror
# images (copies) and a mirror log.
# A disk log ensures that a mirror LV does not need to be
# re-synced (all copies made the same) every time a machine
# reboots or crashes.
# If a device in the LV fails, this policy determines the
# steps perfomed by dmeventd automatically, and the steps
# performed by 'lvconvert --repair --use-policies' run manually.
# Automatic handling requires dmeventd to be monitoring the LV.
# Possible options are: remove, allocate, allocate_anywhere.
# remove - Simply remove the faulty device and run without it.
# If the log device fails, the mirror would convert to using
# an in-memory log. This means the mirror will not
# remember its sync status across crashes/reboots and
# the entire mirror will be re-synced.
# If a mirror image fails, the mirror will convert to a
# non-mirrored device if there is only one remaining good copy.
# allocate - Remove the faulty device and try to allocate space
# on a new device to be a replacement for the failed device.
# Using this policy for the log is fast and maintains the
# ability to remember sync state through crashes/reboots.
# Using this policy for a mirror device is slow, as it
# requires the mirror to resynchronize the devices, but it
# will preserve the mirror characteristic of the device.
# This policy acts like 'remove' if no suitable device and
# space can be allocated for the replacement.
# allocate_anywhere - Not yet implemented. Useful to place
# the log device temporarily on the same physical volume as
# one of the mirror images. This policy is not recommended
# for mirror devices since it would break the redundant nature
# of the mirror. This policy acts like 'remove' if no suitable
# device and space can be allocated for the replacement.
mirror_image_fault_policy = "remove"
# Configuration option activation/mirror_log_fault_policy.
# Defines how a device failure in a 'mirror' log LV is handled.
# The mirror_image_fault_policy description for mirrored LVs
# also applies to mirrored log LVs.
mirror_log_fault_policy = "allocate"
# Configuration option activation/snapshot_autoextend_threshold.
# Auto-extend a snapshot when its usage exceeds this percent.
# Setting this to 100 disables automatic extension.
# The minimum value is 50 (a smaller value is treated as 50.)
# Also see snapshot_autoextend_percent.
# Automatic extension requires dmeventd to be monitoring the LV.
# Example:
# With snapshot_autoextend_threshold 70 and
# snapshot_autoextend_percent 20, whenever a snapshot
# exceeds 70% usage, it will be extended by another 20%.
# For a 1G snapshot, using 700M will trigger a resize to 1.2G.
# When the usage exceeds 840M, the snapshot will be extended
# to 1.44G, and so on.
snapshot_autoextend_threshold = 100
# Configuration option activation/snapshot_autoextend_percent.
# Auto-extending a snapshot adds this percent extra space.
# The amount of additional space added to a snapshot is this
# percent of its current size.
# Also see snapshot_autoextend_threshold.
snapshot_autoextend_percent = 20
# Configuration option activation/thin_pool_autoextend_threshold.
# Auto-extend a thin pool when its usage exceeds this percent.
# Setting this to 100 disables automatic extension.
# The minimum value is 50 (a smaller value is treated as 50.)
# Also see thin_pool_autoextend_percent.
# Automatic extension requires dmeventd to be monitoring the LV.
# Example:
# With thin_pool_autoextend_threshold 70 and
# thin_pool_autoextend_percent 20, whenever a thin pool
# exceeds 70% usage, it will be extended by another 20%.
# For a 1G thin pool, using up 700M will trigger a resize to 1.2G.
# When the usage exceeds 840M, the thin pool will be extended
# to 1.44G, and so on.
thin_pool_autoextend_threshold = 100
# Configuration option activation/thin_pool_autoextend_percent.
# Auto-extending a thin pool adds this percent extra space.
# The amount of additional space added to a thin pool is this
# percent of its current size.
thin_pool_autoextend_percent=20
# Configuration option activation/mlock_filter.
# Do not mlock these memory areas.
# While activating devices, I/O to devices being
# (re)configured is suspended. As a precaution against
# deadlocks, LVM pins memory it is using so it is not
# paged out, and will not require I/O to reread.
# Groups of pages that are known not to be accessed during
# activation do not need to be pinned into memory.
# Each string listed in this setting is compared against
# each line in /proc/self/maps, and the pages corresponding
# to lines that match are not pinned. On some systems,
# locale-archive was found to make up over 80% of the memory
# used by the process.
# Example:
# mlock_filter = [ "locale/locale-archive", "gconv/gconv-modules.cache" ]
# This configuration option is advanced.
# This configuration option does not have a default value defined.
# mlock_filter = []
# Configuration option activation/use_mlockall.
# Use the old behavior of mlockall to pin all memory.
# Prior to version 2.02.62, LVM used mlockall() to pin
# the whole process's memory while activating devices.
use_mlockall = 0
# Configuration option activation/monitoring.
# Monitor LVs that are activated.
# When enabled, LVM will ask dmeventd to monitor LVs
# that are activated.
# The '--ignoremonitoring' option overrides this setting.
monitoring = 1
# Configuration option activation/polling_interval.
# Check pvmove or lvconvert progress at this interval (seconds)
# When pvmove or lvconvert must wait for the kernel to finish
# synchronising or merging data, they check and report progress
# at intervals of this number of seconds.
# If this is set to 0 and there is only one thing to wait for,
# there are no progress reports, but the process is awoken
# immediately once the operation is complete.
polling_interval = 15
# Configuration option activation/auto_set_activation_skip.
# Set the activation skip flag on new thin snapshot LVs.
# An LV can have a persistent 'activation skip' flag.
# The flag causes the LV to be skipped during normal activation.
# The lvchange/vgchange -K option is required to activate LVs
# that have the activation skip flag set.
# When this setting is enabled, the activation skip flag is
# set on new thin snapshot LVs.
# The '--setactivationskip y|n' option overrides this setting.
# auto_set_activation_skip = 1
# Configuration option activation/activation_mode.
# How LVs with missing devices are activated.
# Possible options are: complete, degraded, partial.
# complete - Only allow activation of an LV if all of
# the Physical Volumes it uses are present. Other PVs
# in the Volume Group may be missing.
# degraded - Like complete, but additionally RAID LVs of
# segment type raid1, raid4, raid5, radid6 and raid10 will
# be activated if there is no data loss, i.e. they have
# sufficient redundancy to present the entire addressable
# range of the Logical Volume.
# partial - Allows the activation of any LV even if a
# missing or failed PV could cause data loss with a
# portion of the Logical Volume inaccessible.
# This setting should not normally be used, but may
# sometimes assist with data recovery.
# The '--activationmode' option overrides this setting.
activation_mode = "degraded"
}
# Configuration section metadata.
# metadata {
# Configuration option metadata/pvmetadatacopies.
# Number of copies of metadata to store on each PV.
# Possible options are: 0, 1, 2.
# If set to 2, two copies of the VG metadata are stored on
# the PV, one at the front of the PV, and one at the end.
# If set to 1, one copy is stored at the front of the PV.
# If set to 0, no copies are stored on the PV. This may
# be useful with VGs containing large numbers of PVs.
# The '--pvmetadatacopies' option overrides this setting.
# This configuration option is advanced.
# pvmetadatacopies = 1
# Configuration option metadata/vgmetadatacopies.
# Number of copies of metadata to maintain for each VG.
# If set to a non-zero value, LVM automatically chooses which of
# the available metadata areas to use to achieve the requested
# number of copies of the VG metadata. If you set a value larger
# than the the total number of metadata areas available, then
# metadata is stored in them all.
# The value 0 (unmanaged) disables this automatic management
# and allows you to control which metadata areas are used at
# the individual PV level using 'pvchange --metadataignore y|n'.
# The '--vgmetadatacopies' option overrides this setting.
# vgmetadatacopies = 0
# Configuration option metadata/pvmetadatasize.
# Approximate number of sectors to use for each metadata copy.
# VGs with large numbers of PVs or LVs, or VGs containing
# complex LV structures, may need additional space for VG
# metadata. The metadata areas are treated as circular buffers,
# so unused space becomes filled with an archive of the most
# recent previous versions of the metadata.
# pvmetadatasize = 255
# Configuration option metadata/pvmetadataignore.
# Ignore metadata areas on a new PV.
# If metadata areas on a PV are ignored, LVM will not store
# metadata in them.
# The '--metadataignore' option overrides this setting.
# This configuration option is advanced.
# pvmetadataignore = 0
# Configuration option metadata/stripesize.
# This configuration option is advanced.
# stripesize = 64
# Configuration option metadata/dirs.
# Directories holding live copies of text format metadata.
# These directories must not be on logical volumes!
# It's possible to use LVM with a couple of directories here,
# preferably on different (non-LV) filesystems, and with no other
# on-disk metadata (pvmetadatacopies = 0). Or this can be in
# addition to on-disk metadata areas.
# The feature was originally added to simplify testing and is not
# supported under low memory situations - the machine could lock up.
# Never edit any files in these directories by hand unless you
# you are absolutely sure you know what you are doing! Use
# the supplied toolset to make changes (e.g. vgcfgrestore).
# Example:
# dirs = [ "/etc/lvm/metadata", "/mnt/disk2/lvm/metadata2" ]
# This configuration option is advanced.
# This configuration option does not have a default value defined.
# dirs = []
# }
# Configuration section report.
# LVM report command output formatting.
# report {
# Configuration option report/compact_output.
# Do not print empty report fields.
# Fields that don't have a value set for any of the rows
# reported are skipped and not printed. Compact output is
# applicable only if report/buffered is enabled.
# compact_output = 0
# Configuration option report/aligned.
# Align columns in report output.
# aligned = 1
# Configuration option report/buffered.
# Buffer report output.
# When buffered reporting is used, the report's content is appended
# incrementally to include each object being reported until the report
# is flushed to output which normally happens at the end of command
# execution. Otherwise, if buffering is not used, each object is
# reported as soon as its processing is finished.
# buffered = 1
# Configuration option report/headings.
# Show headings for columns on report.
# headings = 1
# Configuration option report/separator.
# A separator to use on report after each field.
# separator = " "
# Configuration option report/list_item_separator.
# A separator to use for list items when reported.
# list_item_separator = ","
# Configuration option report/prefixes.
# Use a field name prefix for each field reported.
# prefixes = 0
# Configuration option report/quoted.
# Quote field values when using field name prefixes.
# quoted = 1
# Configuration option report/colums_as_rows.
# Output each column as a row.
# If set, this also implies report/prefixes = 1.
# colums_as_rows = 0
# Configuration option report/binary_values_as_numeric.
# Use binary values 0 or 1 instead of descriptive literal values.
# For columns that have exactly two valid values to report
# (not counting the 'unknown' value which denotes that the
# value could not be determined).
# binary_values_as_numeric = 0
# Configuration option report/devtypes_sort.
# List of columns to sort by when reporting 'lvm devtypes' command.
# See 'lvm devtypes -o help' for the list of possible fields.
# devtypes_sort = "devtype_name"
# Configuration option report/devtypes_cols.
# List of columns to report for 'lvm devtypes' command.
# See 'lvm devtypes -o help' for the list of possible fields.
# devtypes_cols = "devtype_name,devtype_max_partitions,devtype_description"
# Configuration option report/devtypes_cols_verbose.
# List of columns to report for 'lvm devtypes' command in verbose mode.
# See 'lvm devtypes -o help' for the list of possible fields.
# devtypes_cols_verbose = "devtype_name,devtype_max_partitions,devtype_description"
# Configuration option report/lvs_sort.
# List of columns to sort by when reporting 'lvs' command.
# See 'lvs -o help' for the list of possible fields.
# lvs_sort = "vg_name,lv_name"
# Configuration option report/lvs_cols.
# List of columns to report for 'lvs' command.
# See 'lvs -o help' for the list of possible fields.
# lvs_cols = "lv_name,vg_name,lv_attr,lv_size,pool_lv,origin,data_percent,metadata_percent,move_pv,mirror_log,copy_percent,convert_lv"
# Configuration option report/lvs_cols_verbose.
# List of columns to report for 'lvs' command in verbose mode.
# See 'lvs -o help' for the list of possible fields.
# lvs_cols_verbose = "lv_name,vg_name,seg_count,lv_attr,lv_size,lv_major,lv_minor,lv_kernel_major,lv_kernel_minor,pool_lv,origin,data_percent,metadata_percent,move_pv,copy_percent,mirror_log,convert_lv,lv_uuid,lv_profile"
# Configuration option report/vgs_sort.
# List of columns to sort by when reporting 'vgs' command.
# See 'vgs -o help' for the list of possible fields.
# vgs_sort = "vg_name"
# Configuration option report/vgs_cols.
# List of columns to report for 'vgs' command.
# See 'vgs -o help' for the list of possible fields.
# vgs_cols = "vg_name,pv_count,lv_count,snap_count,vg_attr,vg_size,vg_free"
# Configuration option report/vgs_cols_verbose.
# List of columns to report for 'vgs' command in verbose mode.
# See 'vgs -o help' for the list of possible fields.
# vgs_cols_verbose = "vg_name,vg_attr,vg_extent_size,pv_count,lv_count,snap_count,vg_size,vg_free,vg_uuid,vg_profile"
# Configuration option report/pvs_sort.
# List of columns to sort by when reporting 'pvs' command.
# See 'pvs -o help' for the list of possible fields.
# pvs_sort = "pv_name"
# Configuration option report/pvs_cols.
# List of columns to report for 'pvs' command.
# See 'pvs -o help' for the list of possible fields.
# pvs_cols = "pv_name,vg_name,pv_fmt,pv_attr,pv_size,pv_free"
# Configuration option report/pvs_cols_verbose.
# List of columns to report for 'pvs' command in verbose mode.
# See 'pvs -o help' for the list of possible fields.
# pvs_cols_verbose = "pv_name,vg_name,pv_fmt,pv_attr,pv_size,pv_free,dev_size,pv_uuid"
# Configuration option report/segs_sort.
# List of columns to sort by when reporting 'lvs --segments' command.
# See 'lvs --segments -o help' for the list of possible fields.
# segs_sort = "vg_name,lv_name,seg_start"
# Configuration option report/segs_cols.
# List of columns to report for 'lvs --segments' command.
# See 'lvs --segments -o help' for the list of possible fields.
# segs_cols = "lv_name,vg_name,lv_attr,stripes,segtype,seg_size"
# Configuration option report/segs_cols_verbose.
# List of columns to report for 'lvs --segments' command in verbose mode.
# See 'lvs --segments -o help' for the list of possible fields.
# segs_cols_verbose = "lv_name,vg_name,lv_attr,seg_start,seg_size,stripes,segtype,stripesize,chunksize"
# Configuration option report/pvsegs_sort.
# List of columns to sort by when reporting 'pvs --segments' command.
# See 'pvs --segments -o help' for the list of possible fields.
# pvsegs_sort = "pv_name,pvseg_start"
# Configuration option report/pvsegs_cols.
# List of columns to sort by when reporting 'pvs --segments' command.
# See 'pvs --segments -o help' for the list of possible fields.
# pvsegs_cols = "pv_name,vg_name,pv_fmt,pv_attr,pv_size,pv_free,pvseg_start,pvseg_size"
# Configuration option report/pvsegs_cols_verbose.
# List of columns to sort by when reporting 'pvs --segments' command in verbose mode.
# See 'pvs --segments -o help' for the list of possible fields.
# pvsegs_cols_verbose = "pv_name,vg_name,pv_fmt,pv_attr,pv_size,pv_free,pvseg_start,pvseg_size,lv_name,seg_start_pe,segtype,seg_pe_ranges"
# }
# Configuration section dmeventd.
# Settings for the LVM event daemon.
dmeventd {
# Configuration option dmeventd/mirror_library.
# The library dmeventd uses when monitoring a mirror device.
# libdevmapper-event-lvm2mirror.so attempts to recover from
# failures. It removes failed devices from a volume group and
# reconfigures a mirror as necessary. If no mirror library is
# provided, mirrors are not monitored through dmeventd.
mirror_library = "libdevmapper-event-lvm2mirror.so"
# Configuration option dmeventd/raid_library.
# raid_library = "libdevmapper-event-lvm2raid.so"
# Configuration option dmeventd/snapshot_library.
# The library dmeventd uses when monitoring a snapshot device.
# libdevmapper-event-lvm2snapshot.so monitors the filling of
# snapshots and emits a warning through syslog when the usage
# exceeds 80%. The warning is repeated when 85%, 90% and
# 95% of the snapshot is filled.
snapshot_library = "libdevmapper-event-lvm2snapshot.so"
# Configuration option dmeventd/thin_library.
# The library dmeventd uses when monitoring a thin device.
# libdevmapper-event-lvm2thin.so monitors the filling of
# a pool and emits a warning through syslog when the usage
# exceeds 80%. The warning is repeated when 85%, 90% and
# 95% of the pool is filled.
thin_library = "libdevmapper-event-lvm2thin.so"
# Configuration option dmeventd/executable.
# The full path to the dmeventd binary.
# executable = "@DMEVENTD_PATH@"
}
# Configuration section tags.
# Host tag settings.
# tags {
# Configuration option tags/hosttags.
# Create a host tag using the machine name.
# The machine name is nodename returned by uname(2).
# hosttags = 0
# Configuration section tags/<tag>.
# Replace this subsection name with a custom tag name.
# Multiple subsections like this can be created.
# The '@' prefix for tags is optional.
# This subsection can contain host_list, which is a
# list of machine names. If the name of the local
# machine is found in host_list, then the name of
# this subsection is used as a tag and is applied
# to the local machine as a 'host tag'.
# If this subsection is empty (has no host_list), then
# the subsection name is always applied as a 'host tag'.
# Example:
# The host tag foo is given to all hosts, and the host tag
# bar is given to the hosts named machine1 and machine2.
# tags { foo { } bar { host_list = [ "machine1", "machine2" ] } }
# This configuration section has variable name.
# This configuration section does not have a default value defined.
# tag {
# Configuration option tags/<tag>/host_list.
# A list of machine names.
# These machine names are compared to the nodename
# returned by uname(2). If the local machine name
# matches an entry in this list, the name of the
# subsection is applied to the machine as a 'host tag'.
# This configuration option does not have a default value defined.
# host_list = ""
# }
# }