# This is an example configuration file for the LVM2 system. # It contains the default settings that would be used if there was no # /etc/lvm/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 /etc/lvm 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. # This section allows you to set the way the configuration settings are handled. config { # If enabled, any LVM2 configuration mismatch is reported. # This implies checking that the configuration key is understood # by LVM2 and that the value of the key is of a proper type. # If disabled, any configuration mismatch is ignored and default # value is used instead without any warning (a message about the # configuration key not being found is issued in verbose mode only). checks = 1 # If enabled, any configuration mismatch aborts the LVM2 process. abort_on_errors = 0 # Directory where LVM looks for configuration profiles. profile_dir = "/etc/lvm/profile" } # This section allows you to configure which block devices should # be used by the LVM system. devices { # Where do you want your volume groups to appear ? dir = "/dev" # An array of directories that contain the device nodes you wish # to use with LVM2. scan = [ "/dev" ] # If set, the cache of block device nodes with all associated symlinks # will be constructed out of the existing udev database content. # This avoids using and opening any inapplicable non-block devices or # subdirectories found in the device directory. This setting is applied # to udev-managed device directory only, other directories will be scanned # fully. LVM2 needs to be compiled with udev support for this setting to # take effect. N.B. Any device node or symlink not managed by udev in # udev directory will be ignored with this setting on. obtain_device_list_from_udev = 1 # If several entries in the scanned directories correspond to the # same block device and the tools need to display a name for device, # all the pathnames are matched against each item in the following # list of regular expressions in turn and the first match is used. # By default no preferred names are defined. # preferred_names = [ ] # Try to avoid using undescriptive /dev/dm-N names, if present. # preferred_names = [ "^/dev/mpath/", "^/dev/mapper/mpath", "^/dev/[hs]d" ] # In case no prefererred name matches or if preferred_names are not # defined at all, builtin rules are used to determine the preference. # # The first builtin rule checks path prefixes and it gives preference # based on this ordering (where "dev" depends on devices/dev setting): # /dev/mapper > /dev/disk > /dev/dm-* > /dev/block # # If the ordering above cannot be applied, the path with fewer slashes # gets preference then. # # If the number of slashes is the same, a symlink gets preference. # # Finally, if all the rules mentioned above are not applicable, # lexicographical order is used over paths and the smallest one # of all gets preference. # A filter that tells LVM2 to only use a restricted set of devices. # The filter consists of an array of regular expressions. These # expressions can be delimited by a character of your choice, and # prefixed with either an 'a' (for accept) or 'r' (for reject). # The first expression found to match a device name determines if # the device will be accepted or rejected (ignored). Devices that # don't match any patterns are accepted. # Be careful if there there are symbolic links or multiple filesystem # entries for the same device as each name is checked separately against # the list of patterns. The effect is that if the first pattern in the # list to match a name is an 'a' pattern for any of the names, the device # is accepted; otherwise if the first pattern in the list to match a name # is an 'r' pattern for any of the names it is rejected; otherwise it is # accepted. # By default we accept every block device except udev names, floppy and cdrom drives: filter = [ "r|/dev/.*/by-path/.*|", "r|/dev/.*/by-id/.*|", "r|/dev/fd.*|", "r|/dev/cdrom|", "a/.*/" ] # Exclude the cdrom drive # filter = [ "r|/dev/cdrom|" ] # When testing I like to work with just loopback devices: # filter = [ "a/loop/", "r/.*/" ] # Or maybe all loops and ide drives except hdc: # filter =[ "a|loop|", "r|/dev/hdc|", "a|/dev/ide|", "r|.*|" ] # Use anchors if you want to be really specific # filter = [ "a|^/dev/hda8$|", "r/.*/" ] # Since "filter" is often overridden from command line, it is not suitable # for system-wide device filtering (udev rules, lvmetad). To hide devices # from LVM-specific udev processing and/or from lvmetad, you need to set # global_filter. The syntax is the same as for normal "filter" # above. Devices that fail the global_filter are not even opened by LVM. # global_filter = [] # The results of the filtering are cached on disk to avoid # rescanning dud devices (which can take a very long time). # By default this cache is stored in the /etc/lvm/cache directory # in a file called '.cache'. # It is safe to delete the contents: the tools regenerate it. # (The old setting 'cache' is still respected if neither of # these new ones is present.) # N.B. If obtain_device_list_from_udev is set to 1 the list of # devices is instead obtained from udev and any existing .cache # file is removed. cache_dir = "/etc/lvm/cache" cache_file_prefix = "" # You can turn off writing this cache file by setting this to 0. write_cache_state = 1 # Advanced settings. # List of pairs of additional acceptable block device types found # in /proc/devices with maximum (non-zero) number of partitions. # types = [ "fd", 16 ] # If sysfs is mounted (2.6 kernels) restrict device scanning to # the block devices it believes are valid. # 1 enables; 0 disables. sysfs_scan = 1 # By default, LVM2 will ignore devices used as component paths # of device-mapper multipath devices. # 1 enables; 0 disables. multipath_component_detection = 1 # By default, LVM2 will ignore devices used as components of # software RAID (md) devices by looking for md superblocks. # 1 enables; 0 disables. md_component_detection = 1 # By default, if a PV is placed directly upon an md device, LVM2 # will align its data blocks with the md device's stripe-width. # 1 enables; 0 disables. md_chunk_alignment = 1 # Default alignment of the start of a 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 # By default, the start of a PV's data area will be a multiple of # the 'minimum_io_size' or 'optimal_io_size' exposed in sysfs. # - minimum_io_size - the smallest request the device can perform # w/o incurring a read-modify-write penalty (e.g. MD's chunk size) # - optimal_io_size - the device's preferred unit of receiving I/O # (e.g. MD's 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. # 1 enables; 0 disables. data_alignment_detection = 1 # Alignment (in KB) of start of data area when creating a new PV. # md_chunk_alignment and data_alignment_detection are disabled if set. # Set to 0 for the default alignment (see: data_alignment_default) # or page size, if larger. data_alignment = 0 # By default, the start of the PV's aligned data area will be shifted by # the 'alignment_offset' exposed in sysfs. This offset is often 0 but # may be non-zero; e.g.: 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). # But note that pvcreate --dataalignmentoffset will skip this detection. # 1 enables; 0 disables. data_alignment_offset_detection = 1 # If, while scanning the system for PVs, LVM2 encounters a device-mapper # device that has its I/O suspended, it waits for it to become accessible. # Set this to 1 to skip such devices. This should only be needed # in recovery situations. ignore_suspended_devices = 0 # ignore_lvm_mirrors: Introduced in version 2.02.104 # This setting determines whether logical volumes of "mirror" segment # type are scanned for LVM labels. This affects the ability of # mirrors to be used as physical volumes. If 'ignore_lvm_mirrors' # is set to '1', it becomes impossible to create volume groups on top # of mirror logical volumes - i.e. to stack volume groups on mirrors. # # Allowing mirror logical volumes to be scanned (setting the value to '0') # can potentially 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 manifest itself, 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 # volume group at the same time with write failures occurring moments # before a scan of the mirror's labels. # # Note that these scanning limitations do not apply to the LVM RAID # types, like "raid1". The RAID segment types handle failures in a # different way and are not subject to possible process or I/O blocking. # # It is encouraged that users set 'ignore_lvm_mirrors' to 1 if they # are using the "mirror" segment type. Users that require volume group # stacking on mirrored logical volumes should consider using the "raid1" # segment type. The "raid1" segment type is not available for # active/active clustered volume groups. # # Set to 1 to disallow stacking and thereby avoid a possible deadlock. ignore_lvm_mirrors = 1 # During each LVM operation errors received from each device are counted. # If the counter of a particular device exceeds the limit set here, no # further I/O is sent to that device for the remainder of the respective # operation. Setting the parameter to 0 disables the counters altogether. disable_after_error_count = 0 # Allow use of pvcreate --uuid without requiring --restorefile. require_restorefile_with_uuid = 1 # 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. # Ignore devices smaller than 2MB such as floppy drives. pv_min_size = 2048 # The original built-in setting was 512 up to and including version 2.02.84. # pv_min_size = 512 # Issue discards to a logical volumes's underlying physical volume(s) when # the logical volume is no longer using the physical volumes' space (e.g. # lvremove, lvreduce, etc). Discards inform the storage that a region is # no longer in use. 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 set # to 1, discards will only be issued if both the storage and kernel provide # support. # 1 enables; 0 disables. issue_discards = 0 } # This section allows you to configure the way in which LVM selects # free space for its Logical Volumes. allocation { # 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. # Use the special tag "@*" as a wildcard to match any PV tag. # 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" ] # cling_tag_list = [ "@*" ] # 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. Set this to 0 to revert to the previous # algorithm. maximise_cling = 1 # Whether to use blkid library instead of native LVM2 code to detect # any existing signatures while creating new Physical Volumes and # Logical Volumes. LVM2 needs to be compiled with blkid wiping support # for this setting to take effect. # # LVM2 native detection code is currently able to recognize these signatures: # - MD device signature # - swap signature # - LUKS signature # To see the list of signatures recognized by blkid, check the output # of 'blkid -k' command. The blkid can recognize more signatures than # LVM2 native detection code, but due to this higher number of signatures # to be recognized, it can take more time to complete the signature scan. use_blkid_wiping = 1 # Set to 1 to wipe any signatures found on newly-created Logical Volumes # automatically in addition to zeroing of the first KB on the LV # (controlled by the -Z/--zero y option). # The command line option -W/--wipesignatures takes precedence over this # setting. # The default is to wipe signatures when zeroing. # wipe_signatures_when_zeroing_new_lvs = 1 # Set to 1 to guarantee that mirror logs will always be placed on # different PVs from the mirror images. This was the default # until version 2.02.85. mirror_logs_require_separate_pvs = 0 # Set to 1 to guarantee that cache_pool metadata will always be # placed on different PVs from the cache_pool data. cache_pool_metadata_require_separate_pvs = 0 # Specify 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. # cache_pool_chunk_size = 64 # Set to 1 to guarantee that thin pool metadata will always # be placed on different PVs from the pool data. thin_pool_metadata_require_separate_pvs = 0 # Specify chunk size calculation policy for thin pool volumes. # Possible options are: # "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" # Specify the minimal chunk size (in KB) for thin pool volumes. # Use of the larger chunk size 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 range from 64 to 1048576. # thin_pool_chunk_size = 64 # Specify discards behaviour of the thin pool volume. # Select one of "ignore", "nopassdown", "passdown" # thin_pool_discards = "passdown" # Set to 0, to disable zeroing of thin pool data chunks before their # first use. # N.B. zeroing larger thin pool chunk size degrades performance. # thin_pool_zero = 1 } # This section that allows you to configure the nature of the # information that LVM2 reports. log { # Controls the messages sent to stdout or stderr. # There are three levels of verbosity, 3 being the most verbose. verbose = 0 # Set to 1 to suppress all non-essential messages from stdout. # This has the same effect as -qq. # When this is set, 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 # Should we send log messages through syslog? # 1 is yes; 0 is no. syslog = 1 # Should we log error and debug messages to a file? # By default there is no log file. #file = "/var/log/lvm2.log" # Should we overwrite the log file each time the program is run? # By default we append. overwrite = 0 # What level of log messages should we send to the log file and/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 # Format of output messages # Whether or not (1 or 0) to indent messages according to their severity indent = 1 # Whether or not (1 or 0) to display the command name on each line output command_names = 0 # A prefix to use before the message text (but after the command name, # if selected). Default is two spaces, so you can see/grep the severity # of each message. prefix = " " # To make the messages look similar to the original LVM tools use: # indent = 0 # command_names = 1 # prefix = " -- " # Set this if you want log messages during activation. # Don't use this in low memory situations (can deadlock). # activation = 0 # 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 of metadata backups and archiving. In LVM2 when we # talk about a 'backup' we mean making a copy of the metadata for the # *current* system. The 'archive' contains old metadata configurations. # Backups are stored in a human readable text format. backup { # Should we maintain a backup of the current metadata configuration ? # Use 1 for Yes; 0 for No. # Think very hard before turning this off! backup = 1 # Where shall we keep it ? # Remember to back up this directory regularly! backup_dir = "/etc/lvm/backup" # Should we maintain an archive of old metadata configurations. # Use 1 for Yes; 0 for No. # On by default. Think very hard before turning this off. archive = 1 # Where should archived files go ? # Remember to back up this directory regularly! archive_dir = "/etc/lvm/archive" # What is the minimum number of archive files you wish to keep ? retain_min = 10 # What is the minimum time you wish to keep an archive file for ? retain_days = 30 } # Settings for the running LVM2 in shell (readline) mode. shell { # Number of lines of history to store in ~/.lvm_history history_size = 100 } # Miscellaneous global LVM2 settings global { # The file creation mask for any files and directories created. # Interpreted as octal if the first digit is zero. umask = 077 # Allow other users to read the files #umask = 022 # Enabling test mode means that no changes to the on disk metadata # will be made. Equivalent to having the -t option on every # command. Defaults to off. test = 0 # Default value for --units argument units = "h" # Since version 2.02.54, the tools distinguish between powers of # 1024 bytes (e.g. KiB, MiB, GiB) and powers of 1000 bytes (e.g. # KB, MB, GB). # If you have scripts that depend on the old behaviour, set this to 0 # temporarily until you update them. si_unit_consistency = 1 # Whether or not to 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 # Whether or not to communicate with the kernel device-mapper. # Set to 0 if you want to use the tools to manipulate LVM metadata # without activating any logical volumes. # If the device-mapper kernel driver is not present in your kernel # setting this to 0 should suppress the error messages. activation = 1 # If we can't communicate with device-mapper, should we try running # the LVM1 tools? # This option only applies to 2.4 kernels and is provided to help you # switch between device-mapper kernels and LVM1 kernels. # The LVM1 tools need to be installed with .lvm1 suffices # e.g. vgscan.lvm1 and they will stop working after you start using # the new lvm2 on-disk metadata format. # The default value is set when the tools are built. # fallback_to_lvm1 = 0 # The default metadata format that commands should use - "lvm1" or "lvm2". # The command line override is -M1 or -M2. # Defaults to "lvm2". # format = "lvm2" # Location of proc filesystem proc = "/proc" # Type of locking to use. Defaults to local file-based locking (1). # Turn locking off by setting to 0 (dangerous: risks metadata corruption # if LVM2 commands get run concurrently). # Type 2 uses the external shared library locking_library. # Type 3 uses built-in clustered locking. # 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. # # N.B. Don't use lvmetad with locking type 3 as lvmetad is not yet # supported in clustered environment. If use_lvmetad=1 and locking_type=3 # is set at the same time, LVM always issues a warning message about this # and then it automatically disables lvmetad use. locking_type = 1 # Set to 0 to fail when a lock request cannot be satisfied immediately. wait_for_locks = 1 # If using external locking (type 2) and initialisation fails, # with this set to 1 an attempt will be made to use the built-in # clustered locking. # If you are using a customised locking_library you should set this to 0. fallback_to_clustered_locking = 1 # If an attempt to initialise type 2 or type 3 locking failed, perhaps # because cluster components such as clvmd are not running, with this set # to 1 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 # 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 = "/run/lvm/lock" # Whenever 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. # NB. This option only affects locking_type = 1 viz. local file-based # locking. prioritise_write_locks = 1 # Other entries can go here to allow you to load shared libraries # e.g. if support for LVM1 metadata was compiled as a shared library use # format_libraries = "liblvm2format1.so" # Full pathnames can be given. # Search this directory first for shared libraries. # library_dir = "/lib" # The external locking library to load if locking_type is set to 2. # locking_library = "liblvm2clusterlock.so" # 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 # Check whether CRC is matching when parsed VG is used multiple times. # This is useful to catch unexpected internal cached volume group # structure modification. Please only enable for debugging. detect_internal_vg_cache_corruption = 0 # If set to 1, no operations that change on-disk metadata will be 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 # 'mirror_segtype_default' defines which segtype will be used when the # shorthand '-m' option is used for mirroring. The possible options are: # # "mirror" - The original RAID1 implementation provided by LVM2/DM. It is # characterized by a flexible log solution (core, disk, mirrored) # and by the necessity to block I/O while reconfiguring in the # event of 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. # Ref: https://bugzilla.redhat.com/show_bug.cgi?id=817130#c10 # # "raid1" - This implementation leverages MD's 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 in the kernel in the event of a failure. # This mirror implementation is not cluster-aware and cannot be # used in a shared (active/active) fashion in a cluster. # # Specify the '--type ' option to override this default # setting. mirror_segtype_default = "raid1" # 'raid10_segtype_default' determines the segment types used by default # when the '--stripes/-i' and '--mirrors/-m' arguments are both specified # during the creation of a logical volume. # Possible settings include: # # "raid10" - This implementation leverages MD's RAID10 personality through # device-mapper. # # "mirror" - LVM will layer the 'mirror' and 'stripe' segment types. It # will do this by creating a mirror on top of striped sub-LVs; # effectively creating a RAID 0+1 array. This is suboptimal # in terms of providing redundancy and performance. Changing to # this setting is not advised. # Specify the '--type ' option to override this default # setting. raid10_segtype_default = "mirror" # 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. # Set to 1 to reinstate the previous format. # # lvdisplay_shows_full_device_path = 0 # Whether to use (trust) a running instance of lvmetad. If this is set to # 0, all commands fall back to the usual scanning mechanisms. When set to 1 # *and* when lvmetad is running (automatically instantiated by making use of # systemd's socket-based service activation or run as an initscripts service # or run manually), the volume group metadata and PV state flags are obtained # from the lvmetad instance and no scanning is done by the individual # commands. In a setup with lvmetad, lvmetad udev rules *must* be set up for # LVM to work correctly. Without proper udev rules, all changes in block # device configuration will be *ignored* until a manual 'pvscan --cache' # is performed. These rules are installed by default. # # If lvmetad has been running while use_lvmetad was 0, it MUST be stopped # before changing use_lvmetad to 1 and started again afterwards. # # If using lvmetad, the volume activation is also switched to automatic # event-based mode. In this mode, the volumes are activated based on # incoming udev events that automatically inform lvmetad about new PVs # that appear in the system. Once the VG is complete (all the PVs are # present), it is auto-activated. The activation/auto_activation_volume_list # setting controls which volumes are auto-activated (all by default). # # A note about device filtering while lvmetad is used: # When lvmetad is updated (either automatically based on udev events # or directly by pvscan --cache call), the devices/filter # is ignored and all devices are scanned by default. The lvmetad always # keeps unfiltered information which is then provided to LVM commands # and then each LVM command does the filtering based on devices/filter # setting itself. # To prevent scanning devices completely, even when using lvmetad, # the devices/global_filter must be used. # N.B. Don't use lvmetad with locking type 3 as lvmetad is not yet # supported in clustered environment. If use_lvmetad=1 and locking_type=3 # is set at the same time, LVM always issues a warning message about this # and then it automatically disables lvmetad use. # If use_lvmetad set to 1, please make sure lvm2-lvmetad.socket is started use_lvmetad = 1 # Full path of the utility called to check that a thin metadata device # is in a state that allows it to be used. # Each time a thin pool needs to be activated or after it is deactivated # this utility is executed. The activation will only proceed if the utility # has an exit status of 0. # Set to "" to skip this check. (Not recommended.) # The thin tools are available as part of the device-mapper-persistent-data # package from https://github.com/jthornber/thin-provisioning-tools. # # thin_check_executable = "/usr/sbin/thin_check" # Array of string options passed with thin_check command. By default, # option "-q" is for quiet output. # 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" ] # Full path of the utility called to repair a thin metadata device # is in a state that allows it to be used. # Each time a thin pool needs repair this utility is executed. # See thin_check_executable how to obtain binaries. # # thin_repair_executable = "/usr/sbin/thin_repair" # Array of extra string options passed with thin_repair command. # thin_repair_options = [ "" ] # Full path of the utility called to dump thin metadata content. # See thin_check_executable how to obtain binaries. # # thin_dump_executable = "/usr/sbin/thin_dump" # If set, given features are not used by thin driver. # This can be helpful not just for testing, but i.e. allows to avoid # using problematic implementation of some thin feature. # Features: # block_size # discards # discards_non_power_2 # external_origin # metadata_resize # external_origin_extend # # thin_disabled_features = [ "discards", "block_size" ] # Full path of the utility called to check that a cache metadata device # is in a state that allows it to be used. # Each time a cached LV needs to be used or after it is deactivated # this utility is executed. The activation will only proceed if the utility # has an exit status of 0. # Set to "" to skip this check. (Not recommended.) # The cache tools are available as part of the device-mapper-persistent-data # package from https://github.com/jthornber/thin-provisioning-tools. # # cache_check_executable = "autodetect" # Array of string options passed with cache_check command. By default, # option "-q" is for quiet output. # # cache_check_options = [ "-q" ] # Full path of the utility called to repair a cache metadata device. # Each time a cache metadata needs repair this utility is executed. # See cache_check_executable how to obtain binaries. # # cache_repair_executable = "autodetect" # Array of extra string options passed with cache_repair command. # cache_repair_options = [ "" ] # Full path of the utility called to dump cache metadata content. # See cache_check_executable how to obtain binaries. # # cache_dump_executable = "autodetect" } activation { # Set to 1 to perform internal checks on the operations issued to # libdevmapper. 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 # Set to 0 to disable udev synchronisation (if compiled into the binaries). # Processes will not wait for notification from udev. # They will continue irrespective of any possible udev processing # in the background. You should only use this if udev is not running # or has rules that ignore the devices LVM2 creates. # The command line argument --nodevsync takes precedence over this setting. # If set to 1 when udev is not running, and there are LVM2 processes # waiting for udev, run 'dmsetup udevcomplete_all' manually to wake them up. udev_sync = 1 # Set to 0 to disable the udev rules installed by LVM2 (if built with # --enable-udev_rules). LVM2 will then manage the /dev nodes and symlinks # for active logical volumes directly itself. # N.B. Manual intervention may be required if this setting is changed # while any logical volumes are active. udev_rules = 1 # Set to 1 for LVM2 to verify operations performed by udev. This turns on # additional checks (and if necessary, repairs) on entries in the device # directory after udev has completed processing its events. # Useful for diagnosing problems with LVM2/udev interactions. verify_udev_operations = 0 # If set to 1 and if deactivation of an LV fails, perhaps because # a process run from a quick udev rule temporarily opened the device, # retry the operation for a few seconds before failing. retry_deactivation = 1 # How to fill in missing stripes if activating an incomplete volume. # 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 to in place of missing stripes. # But note that using anything other than "error" with mirrored # or snapshotted volumes is likely to result in data corruption. missing_stripe_filler = "error" # The linear target is an optimised version of the striped target # that only handles a single stripe. Set this to 0 to disable this # optimisation and always use the striped target. use_linear_target = 1 # How much stack (in KB) to reserve for use while devices suspended # Prior to version 2.02.89 this used to be set to 256KB reserved_stack = 64 # How much memory (in KB) to reserve for use while devices suspended reserved_memory = 8192 # Nice value used while devices suspended process_priority = -18 # If volume_list is defined, each LV is only activated if there is a # match against the list. # # "vgname" and "vgname/lvname" are matched exactly. # "@tag" matches any tag set in the LV or VG. # "@*" matches if any tag defined on the host is also set in the LV or VG # # If any host tags exist but volume_list is not defined, a default # single-entry list containing "@*" is assumed. # # volume_list = [ "vg1", "vg2/lvol1", "@tag1", "@*" ] # If auto_activation_volume_list is defined, each LV that is to be # activated with the autoactivation option (--activate ay/-a ay) is # first checked against the list. There are two scenarios in which # the autoactivation option is used: # # - automatic activation of volumes based on incoming PVs. If all the # PVs making up a VG are present in the system, the autoactivation # is triggered. This requires lvmetad (global/use_lvmetad=1) and udev # to be running. In this case, "pvscan --cache -aay" is called # automatically without any user intervention while processing # udev events. Please, make sure you define auto_activation_volume_list # properly so only the volumes you want and expect are autoactivated. # # - direct activation on command line with the autoactivation option. # In this case, the user calls "vgchange --activate ay/-a ay" or # "lvchange --activate ay/-a ay" directly. # # By default, the auto_activation_volume_list is not defined and all # volumes will be activated either automatically or by using --activate ay/-a ay. # # N.B. The "activation/volume_list" is still honoured in all cases so even # if the VG/LV passes the auto_activation_volume_list, it still needs to # pass the volume_list for it to be activated in the end. # If auto_activation_volume_list is defined but empty, no volumes will be # activated automatically and --activate ay/-a ay will do nothing. # # auto_activation_volume_list = [] # If auto_activation_volume_list is defined and it's not empty, only matching # volumes will be activated either automatically or by using --activate ay/-a ay. # # "vgname" and "vgname/lvname" are matched exactly. # "@tag" matches any tag set in the LV or VG. # "@*" matches if any tag defined on the host is also set in the LV or VG # # auto_activation_volume_list = [ "vg1", "vg2/lvol1", "@tag1", "@*" ] # If read_only_volume_list is defined, each LV that is to be activated # is checked against the list, and if it matches, it as activated # in read-only mode. (This overrides '--permission rw' stored in the # metadata.) # # "vgname" and "vgname/lvname" are matched exactly. # "@tag" matches any tag set in the LV or VG. # "@*" matches if any tag defined on the host is also set in the LV or VG # # read_only_volume_list = [ "vg1", "vg2/lvol1", "@tag1", "@*" ] # Each LV can have an 'activation skip' flag stored persistently against it. # During activation, this flag is used to decide whether such an LV is skipped. # The 'activation skip' flag can be set during LV creation and by default it # is automatically set for thin snapshot LVs. The 'auto_set_activation_skip' # enables or disables this automatic setting of the flag while LVs are created. # auto_set_activation_skip = 1 # For RAID or 'mirror' segment types, 'raid_region_size' is the # size (in KiB) of each: # - synchronization operation when initializing # - each copy operation when performing a 'pvmove' (using 'mirror' segtype) # This setting has replaced 'mirror_region_size' since version 2.02.99 raid_region_size = 512 # Setting to use when there is no readahead value stored in the metadata. # # "none" - Disable readahead. # "auto" - Use default value chosen by kernel. readahead = "auto" # 'raid_fault_policy' defines how a device failure in a RAID logical # volume is handled. This includes logical volumes that have the following # segment types: raid1, raid4, raid5*, and raid6*. # # In the event of a failure, the following policies will determine what # actions are performed during the automated response to failures (when # dmeventd is monitoring the RAID logical volume) and when 'lvconvert' is # called manually with the options '--repair' and '--use-policies'. # # "warn" - Use the system log to warn the user that a device in the RAID # logical volume 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 logical volume 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" # 'mirror_image_fault_policy' and 'mirror_log_fault_policy' define # how a device failure affecting a mirror (of "mirror" segment type) is # handled. A mirror is composed of mirror images (copies) and a log. # A disk log ensures that a mirror does not need to be re-synced # (all copies made the same) every time a machine reboots or crashes. # # In the event of a failure, the specified policy will be used to determine # what happens. This applies to automatic repairs (when the mirror is being # monitored by dmeventd) and to manual lvconvert --repair when # --use-policies is given. # # "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 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_log_fault_policy = "allocate" mirror_image_fault_policy = "remove" # 'snapshot_autoextend_threshold' and 'snapshot_autoextend_percent' define # how to handle automatic snapshot extension. The former defines when the # snapshot should be extended: when its space usage exceeds this many # percent. The latter defines how much extra space should be allocated for # the snapshot, in percent of its current size. # # For example, if you set snapshot_autoextend_threshold to 70 and # snapshot_autoextend_percent to 20, whenever a snapshot exceeds 70% usage, # it will be extended by another 20%. For a 1G snapshot, using up 700M will # trigger a resize to 1.2G. When the usage exceeds 840M, the snapshot will # be extended to 1.44G, and so on. # # Setting snapshot_autoextend_threshold to 100 disables automatic # extensions. The minimum value is 50 (A setting below 50 will be treated # as 50). snapshot_autoextend_threshold = 100 snapshot_autoextend_percent = 20 # 'thin_pool_autoextend_threshold' and 'thin_pool_autoextend_percent' define # how to handle automatic pool extension. The former defines when the # pool should be extended: when its space usage exceeds this many # percent. The latter defines how much extra space should be allocated for # the pool, in percent of its current size. # # For example, if you set thin_pool_autoextend_threshold to 70 and # thin_pool_autoextend_percent to 20, whenever a pool exceeds 70% usage, # it will be extended by another 20%. For a 1G pool, using up 700M will # trigger a resize to 1.2G. When the usage exceeds 840M, the pool will # be extended to 1.44G, and so on. # # Setting thin_pool_autoextend_threshold to 100 disables automatic # extensions. The minimum value is 50 (A setting below 50 will be treated # as 50). thin_pool_autoextend_threshold = 100 thin_pool_autoextend_percent = 20 # While activating devices, I/O to devices being (re)configured is # suspended, and as a precaution against deadlocks, LVM2 needs to pin # any memory it is using so it is not paged out. Groups of pages that # are known not to be accessed during activation need not be pinned # into memory. Each string listed in this setting is compared against # each line in /proc/self/maps, and the pages corresponding to any # 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. # mlock_filter = [ "locale/locale-archive", "gconv/gconv-modules.cache" ] # Set to 1 to revert to the default behaviour prior to version 2.02.62 # which used mlockall() to pin the whole process's memory while activating # devices. use_mlockall = 0 # Monitoring is enabled by default when activating logical volumes. # Set to 0 to disable monitoring or use the --ignoremonitoring option. monitoring = 1 # 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. The default is 15 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 the # operation is complete. polling_interval = 15 # 'activation_mode' determines how Logical Volumes are activated if # any devices are missing. Possible settings are: # # "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 Logical Volumes 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 Logical Volume 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. # # This setting was introduced in LVM version 2.02.108. It corresponds # with the '--activationmode' option for lvchange and vgchange. activation_mode = "degraded" } # Report settings. # # report { # Align columns on report output. # aligned=1 # 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 # Show headings for columns on report. # headings=1 # A separator to use on report after each field. # separator=" " # A separator to use for list items when reported. # list_item_separator="," # Use a field name prefix for each field reported. # prefixes=0 # Quote field values when using field name prefixes. # quoted=1 # Output each column as a row. If set, this also implies report/prefixes=1. # colums_as_rows=0 # 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 # Comma separated 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" # Comma separated 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" # Comma separated 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" # Comma separated 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" # Comma separated 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" # Comma separated 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 # Comma separated list of columns to sort by when reporting 'vgs' command. # See 'vgs -o help' for the list of possible fields. # vgs_sort="vg_name" # Comma separated 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" # Comma separated 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" # Comma separated list of columns to sort by when reporting 'pvs' command. # See 'pvs -o help' for the list of possible fields. # pvs_sort="pv_name" # Comma separated 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" # Comma separated 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" # Comma separated 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" # Comma separated 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" # Comma separated 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" # Comma separated 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" # Comma separated 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" # Comma separated 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" #} #################### # Advanced section # #################### # Metadata settings # # metadata { # Default number of copies of metadata to hold on each PV. 0, 1 or 2. # You might want to override it from the command line with 0 # when running pvcreate on new PVs which are to be added to large VGs. # pvmetadatacopies = 1 # Default 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 default value of 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'. # vgmetadatacopies = 0 # Approximate default size of on-disk metadata areas in sectors. # You should increase this if you have large volume groups or # you want to retain a large on-disk history of your metadata changes. # pvmetadatasize = 255 # List of directories holding live copies of text format metadata. # These directories must not be on logical volumes! # It's possible to use LVM2 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). # dirs = [ "/etc/lvm/metadata", "/mnt/disk2/lvm/metadata2" ] #} # Event daemon # dmeventd { # mirror_library is the library used 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" # snapshot_library is the library used when monitoring a snapshot device. # # "libdevmapper-event-lvm2snapshot.so" monitors the filling of # snapshots and emits a warning through syslog when the use of # the snapshot exceeds 80%. The warning is repeated when 85%, 90% and # 95% of the snapshot is filled. snapshot_library = "libdevmapper-event-lvm2snapshot.so" # thin_library is the library used when monitoring a thin device. # # "libdevmapper-event-lvm2thin.so" monitors the filling of # pool and emits a warning through syslog when the use of # the pool exceeds 80%. The warning is repeated when 85%, 90% and # 95% of the pool is filled. thin_library = "libdevmapper-event-lvm2thin.so" # Full path of the dmeventd binary. # # executable = "" }