bionic (5) btrfs.5.gz

Provided by: btrfs-progs_4.15.1-1build1_amd64 bug

NAME

       btrfs-man5 - topics about the BTRFS filesystem (mount options, supported file attributes and other)

DESCRIPTION

       This document describes topics related to BTRFS that are not specific to the tools. Currently covers:

        1. mount options

        2. filesystem features

        3. file attributes

        4. control device

MOUNT OPTIONS

       This section describes mount options specific to BTRFS. For the generic mount options please refer to
       mount(8) manpage. The options are sorted alphabetically (discarding the no prefix).

           Note
           most mount options apply to the whole filesystem and only options in the first mounted subvolume will
           take effect. This is due to lack of implementation and may change in the future. This means that (for
           example) you can’t set per-subvolume nodatacow, nodatasum, or compress using mount options. This
           should eventually be fixed, but it has proved to be difficult to implement correctly within the Linux
           VFS framework.

       acl, noacl
           (default: on)

           Enable/disable support for Posix Access Control Lists (ACLs). See the acl(5) manual page for more
           information about ACLs.

           The support for ACL is build-time configurable (BTRFS_FS_POSIX_ACL) and mount fails if acl is
           requested but the feature is not compiled in.

       autodefrag, noautodefrag
           (since: 3.0, default: off)

           Enable automatic file defragmentation. When enabled, small random writes into files (in a range of
           tens of kilobytes, currently it’s 64K) are detected and queued up for the defragmentation process.
           Not well suited for large database workloads.

           The read latency may increase due to reading the adjacent blocks that make up the range for
           defragmentation, successive write will merge the blocks in the new location.

               Warning
               Defragmenting with Linux kernel versions < 3.9 or ≥ 3.14-rc2 as well as with Linux stable kernel
               versions ≥ 3.10.31, ≥ 3.12.12 or ≥ 3.13.4 will break up the reflinks of COW data (for example
               files copied with cp --reflink, snapshots or de-duplicated data). This may cause considerable
               increase of space usage depending on the broken up reflinks.

       barrier, nobarrier
           (default: on)

           Ensure that all IO write operations make it through the device cache and are stored permanently when
           the filesystem is at its consistency checkpoint. This typically means that a flush command is sent to
           the device that will synchronize all pending data and ordinary metadata blocks, then writes the
           superblock and issues another flush.

           The write flushes incur a slight hit and also prevent the IO block scheduler to reorder requests in a
           more effective way. Disabling barriers gets rid of that penalty but will most certainly lead to a
           corrupted filesystem in case of a crash or power loss. The ordinary metadata blocks could be yet
           unwritten at the time the new superblock is stored permanently, expecting that the block pointers to
           metadata were stored permanently before.

           On a device with a volatile battery-backed write-back cache, the nobarrier option will not lead to
           filesystem corruption as the pending blocks are supposed to make it to the permanent storage.

       check_int, check_int_data, check_int_print_mask=value
           (since: 3.0, default: off)

           These debugging options control the behavior of the integrity checking module (the
           BTRFS_FS_CHECK_INTEGRITY config option required). The main goal is to verify that all blocks from a
           given transaction period are properly linked.

           check_int enables the integrity checker module, which examines all block write requests to ensure
           on-disk consistency, at a large memory and CPU cost.

           check_int_data includes extent data in the integrity checks, and implies the check_int option.

           check_int_print_mask takes a bitmask of BTRFSIC_PRINT_MASK_* values as defined in
           fs/btrfs/check-integrity.c, to control the integrity checker module behavior.

           See comments at the top of fs/btrfs/check-integrity.c for more information.

       clear_cache
           Force clearing and rebuilding of the disk space cache if something has gone wrong. See also:
           space_cache.

       commit=seconds
           (since: 3.12, default: 30)

           Set the interval of periodic transaction commit when data are synchronized to permanent storage.
           Higher interval values lead to larger amount of unwritten data, which has obvious consequences when
           the system crashes. The upper bound is not forced, but a warning is printed if it’s more than 300
           seconds (5 minutes). Use with care.

       compress, compress=type, compress-force, compress-force=type
           (default: off)

           Control BTRFS file data compression. Type may be specified as zlib, lzo, zstd or no (for no
           compression, used for remounting). If no type is specified, zlib is used. If compress-force is
           specified, then compression will always be attempted, but the data may end up uncompressed if the
           compression would make them larger.

           Otherwise some simple heuristics are applied to detect an incompressible file. If the first blocks
           written to a file are not compressible, the whole file is permanently marked to skip compression. As
           this is too simple, the compress-force is a workaround that will compress most of the files at the
           cost of some wasted CPU cycles on failed attempts. The heuristics of compress will improve in the
           future so this will not be necessary.

               Note
               If compression is enabled, nodatacow and nodatasum are disabled.

       datacow, nodatacow
           (default: on)

           Enable data copy-on-write for newly created files.  Nodatacow implies nodatasum, and disables
           compression. All files created under nodatacow are also set the NOCOW file attribute (see chattr(1)).

               Note
               If nodatacow or nodatasum are enabled, compression is disabled.
           Updates in-place improve performance for workloads that do frequent overwrites, at the cost of
           potential partial writes, in case the write is interruted (system crash, device failure).

       datasum, nodatasum
           (default: on)

           Enable data checksumming for newly created files.  Datasum implies datacow, ie. the normal mode of
           operation. All files created under nodatasum inherit the "no checksums" property, however there’s no
           corresponding file attribute (see chattr(1)).

               Note
               If nodatacow or nodatasum are enabled, compression is disabled.
           There is a slight performance gain when checksums are turned off, the correspoinding metadata blocks
           holding the checksums do not need to updated. The cost of checksumming of the blocks in memory is
           much lower than the IO, modern CPUs feature hardware support of the checksumming algorithm.

       degraded
           (default: off)

           Allow mounts with less devices than the RAID profile constraints require. A read-write mount (or
           remount) may fail when there are too many devices missing, for example if a stripe member is
           completely missing from RAID0.

           Since 4.14, the constraint checks have been improved and are verified on the chunk level, not an the
           device level. This allows degraded mounts of filesystems with mixed RAID profiles for data and
           metadata, even if the device number constraints would not be satisfied for some of the prifles.

           Example: metadata — raid1, data — single, devices — /dev/sda, /dev/sdb

           Suppose the data are completely stored on sda, then missing sdb will not prevent the mount, even if 1
           missing device would normally prevent (any) single profile to mount. In case some of the data chunks
           are stored on sdb, then the constraint of single/data is not satisfied and the filesystem cannot be
           mounted.

       device=devicepath
           Specify a path to a device that will be scanned for BTRFS filesystem during mount. This is usually
           done automatically by a device manager (like udev) or using the btrfs device scan command (eg. run
           from the initial ramdisk). In cases where this is not possible the device mount option can help.

               Note
               booting eg. a RAID1 system may fail even if all filesystem’s device paths are provided as the
               actual device nodes may not be discovered by the system at that point.

       discard, nodiscard
           (default: off)

           Enable discarding of freed file blocks. This is useful for SSD devices, thinly provisioned LUNs, or
           virtual machine images; however, every storage layer must support discard for it to work. if the
           backing device does not support asynchronous queued TRIM, then this operation can severly degrade
           performance, because a synchronous TRIM operation will be attempted instead. Queued TRIM requires
           newer than SATA revision 3.1 chipsets and devices.

       If it is not necessary to immediately discard freed blocks, then the fstrim tool can be used to discard
       all free blocks in a batch. Scheduling a TRIM during a period of low system activity will prevent latent
       interference with the performance of other operations. Also, a device may ignore the TRIM command if the
       range is too small, so running a batch discard has a greater probability of actually discarding the
       blocks.

       If discarding is not necessary to be done at the block freeing time, there’s fstrim(8) tool that lets the
       filesystem discard all free blocks in a batch, possibly not much interfering with other operations. Also,
       the the device may ignore the TRIM command if the range is too small, so running the batch discard can
       actually discard the blocks.

       enospc_debug, noenospc_debug
           (default: off)

           Enable verbose output for some ENOSPC conditions. It’s safe to use but can be noisy if the system
           reaches near-full state.

       fatal_errors=action
           (since: 3.4, default: bug)

           Action to take when encountering a fatal error.

           bug
               BUG() on a fatal error, the system will stay in the crashed state and may be still partially
               usable, but reboot is required for full operation

           panic
               panic() on a fatal error, depending on other system configuration, this may be followed by a
               reboot. Please refer to the documentation of kernel boot parameters, eg.  panic, oops or
               crashkernel.

       flushoncommit, noflushoncommit
           (default: off)

           This option forces any data dirtied by a write in a prior transaction to commit as part of the
           current commit, effectively a full filesystem sync.

           This makes the committed state a fully consistent view of the file system from the application’s
           perspective (i.e. it includes all completed file system operations). This was previously the behavior
           only when a snapshot was created.

           When off, the filesystem is consistent but buffered writes may last more than one transaction commit.

       fragment=type
           (depends on compile-time option BTRFS_DEBUG, since: 4.4, default: off)

           A debugging helper to intentionally fragment given type of block groups. The type can be data,
           metadata or all. This mount option should not be used outside of debugging environments and is not
           recognized if the kernel config option BTRFS_DEBUG is not enabled.

       inode_cache, noinode_cache
           (since: 3.0, default: off)

           Enable free inode number caching. Not recommended to use unless files on your filesystem get assigned
           inode numbers that are approaching 264. Normally, new files in each subvolume get assigned
           incrementally (plus one from the last time) and are not reused. The mount option turns on caching of
           the existing inode numbers and reuse of inode numbers of deleted files.

           This option may slow down your system at first run, or after mounting without the option.

               Note
               Defaults to off due to a potential overflow problem when the free space checksums don’t fit
               inside a single page.
           Don’t use this option unless you really need it. The inode number limit on 64bit system is 264, which
           is practically enough for the whole filesystem lifetime. Due to implemention of linux VFS layer, the
           inode numbers on 32bit systems are only 32 bits wide. This lowers the limit significantly and makes
           it possible to reach it. In such case, this mount option will help. Alternatively, files with high
           inode numbers can be copied to a new subvolume which will effectively start the inode numbers from
           the beginning again.

       logreplay, nologreplay
           (default: on, even read-only)

           Enable/disable log replay at mount time. See also treelog.

               Warning
               currently, the tree log is replayed even with a read-only mount! To disable that behaviour, mount
               also with nologreplay.

       max_inline=bytes
           (default: min(2048, page size) )

           Specify the maximum amount of space, that can be inlined in a metadata B-tree leaf. The value is
           specified in bytes, optionally with a K suffix (case insensitive). In practice, this value is limited
           by the filesystem block size (named sectorsize at mkfs time), and memory page size of the system. In
           case of sectorsize limit, there’s some space unavailable due to leaf headers. For example, a 4k
           sectorsize, maximum size of inline data is about 3900 bytes.

           Inlining can be completely turned off by specifying 0. This will increase data block slack if file
           sizes are much smaller than block size but will reduce metadata consumption in return.

               Note
               the default value has changed to 2048 in kernel 4.6.

       metadata_ratio=value
           (default: 0, internal logic)

           Specifies that 1 metadata chunk should be allocated after every value data chunks. Default behaviour
           depends on internal logic, some percent of unused metadata space is attempted to be maintained but is
           not always possible if there’s not enough space left for chunk allocation. The option could be useful
           to override the internal logic in favor of the metadata allocation if the expected workload is
           supposed to be metadata intense (snapshots, reflinks, xattrs, inlined files).

       norecovery
           (since: 4.5, default: off)

           Do not attempt any data recovery at mount time. This will disable logreplay and avoids other write
           operations.

               Note
               The opposite option recovery used to have different meaning but was changed for consistency with
               other filesystems, where norecovery is used for skipping log replay. BTRFS does the same and in
               general will try to avoid any write operations.

       rescan_uuid_tree
           (since: 3.12, default: off)

           Force check and rebuild procedure of the UUID tree. This should not normally be needed.

       skip_balance
           (since: 3.3, default: off)

           Skip automatic resume of an interrupted balance operation. The operation can later be resumed with
           btrfs balance resume, or the paused state can be removed with btrfs balance cancel. The default
           behaviour is to resume an interrupted balance immediately after a volume is mounted.

       space_cache, space_cache=version, nospace_cache
           (nospace_cache since: 3.2, space_cache=v1 and space_cache=v2 since 4.5, default: space_cache=v1)

           Options to control the free space cache. The free space cache greatly improves performance when
           reading block group free space into memory. However, managing the space cache consumes some
           resources, including a small amount of disk space.

           There are two implementations of the free space cache. The original one, referred to as v1, is the
           safe default. The v1 space cache can be disabled at mount time with nospace_cache without clearing.

           On very large filesystems (many terabytes) and certain workloads, the performance of the v1 space
           cache may degrade drastically. The v2 implementation, which adds a new B-tree called the free space
           tree, addresses this issue. Once enabled, the v2 space cache will always be used and cannot be
           disabled unless it is cleared. Use clear_cache,space_cache=v1 or clear_cache,nospace_cache to do so.
           If v2 is enabled, kernels without v2 support will only be able to mount the filesystem in read-only
           mode. The btrfs(8) command currently only has read-only support for v2. A read-write command may be
           run on a v2 filesystem by clearing the cache, running the command, and then remounting with
           space_cache=v2.

           If a version is not explicitly specified, the default implementation will be chosen, which is v1.

       ssd, ssd_spread, nossd
           (default: SSD autodetected)

           Options to control SSD allocation schemes. By default, BTRFS will enable or disable SSD optimizations
           depending on status of a device with respect to rotational or non-rotational type. This is determined
           by the contents of /sys/block/DEV/queue/rotational). If it is 1, the ssd option is turned on. The
           option nossd will disable the autodetection.

           The optimizations make use of the absence of the seek penalty that’s inherent for the rotational
           devices. The blocks can be typically written faster and are not offloaded to separate threads.

               Note
               Since 4.14, the block layout optimizations have been dropped. This used to help with first
               generations of SSD devices. Their FTL (flash translation layer) was not effective and the
               optimization was supposed to improve the wear by better aligning blocks. This is no longer true
               with modern SSD devices and the optimization had no real benefit. Furthermore it caused increased
               fragmentation. The layout tuning has been kept intact for the option ssd_spread.
           The ssd_spread mount option attempts to allocate into bigger and aligned chunks of unused space, and
           may perform better on low-end SSDs.  ssd_spread implies ssd, enabling all other SSD heuristics as
           well. The option nossd will disable all SSD options.

       subvol=path
           Mount subvolume from path rather than the toplevel subvolume. The path is always treated as relative
           to the the toplevel subvolume. This mount option overrides the default subvolume set for the given
           filesystem.

       subvolid=subvolid
           Mount subvolume specified by a subvolid number rather than the toplevel subvolume. You can use btrfs
           subvolume list of btrfs subvolume show to see subvolume ID numbers. This mount option overrides the
           default subvolume set for the given filesystem.

               Note
               if both subvolid and subvol are specified, they must point at the same subvolume, otherwise the
               mount will fail.

       thread_pool=number
           (default: min(NRCPUS + 2, 8) )

           The number of worker threads to start. NRCPUS is number of on-line CPUs detected at the time of
           mount. Small number leads to less parallelism in processing data and metadata, higher numbers could
           lead to a performance hit due to increased locking contention, process scheduling, cache-line
           bouncing or costly data transfers between local CPU memories.

       treelog, notreelog
           (default: on)

           Enable the tree logging used for fsync and O_SYNC writes. The tree log stores changes without the
           need of a full filesystem sync. The log operations are flushed at sync and transaction commit. If the
           system crashes between two such syncs, the pending tree log operations are replayed during mount.

               Warning
               currently, the tree log is replayed even with a read-only mount! To disable that behaviour, also
               mount with nologreplay.
           The tree log could contain new files/directories, these would not exist on a mounted filesystem if
           the log is not replayed.

       usebackuproot, nousebackuproot
           (since: 4.6, default: off)

           Enable autorecovery attempts if a bad tree root is found at mount time. Currently this scans a backup
           list of several previous tree roots and tries to use the first readable. This can be used with
           read-only mounts as well.

               Note
               This option has replaced recovery.

       user_subvol_rm_allowed
           (default: off)

           Allow subvolumes to be deleted by their respective owner. Otherwise, only the root user can do that.

               Note
               historically, any user could create a snapshot even if he was not owner of the source subvolume,
               the subvolume deletion has been restricted for that reason. The subvolume creation has been
               restricted but this mount option is still required. This is a usability issue and will be
               addressed in the future.

   DEPRECATED MOUNT OPTIONS
       List of mount options that have been removed, kept for backward compatibility.

       alloc_start=bytes
           (default: 1M, minimum: 1M, deprecated since: 4.13)

           Debugging option to force all block allocations above a certain byte threshold on each block device.
           The value is specified in bytes, optionally with a K, M, or G suffix (case insensitive).

       recovery
           (since: 3.2, default: off, deprecated since: 4.5)

               Note
               this option has been replaced by usebackuproot and should not be used but will work on 4.5+
               kernels.

       subvolrootid=objectid
           (irrelevant since: 3.2, formally deprecated since: 3.10)

           A workaround option from times (pre 3.2) when it was not possible to mount a subvolume that did not
           reside directly under the toplevel subvolume.

   NOTES ON GENERIC MOUNT OPTIONS
       Some of the general mount options from mount(8) that affect BTRFS and are worth mentioning.

       noatime
           under read intensive work-loads, specifying noatime significantly improves performance because no new
           access time information needs to be written. Without this option, the default is relatime, which only
           reduces the number of inode atime updates in comparison to the traditional strictatime. The worst
           case for atime updates under relatime occurs when many files are read whose atime is older than 24 h
           and which are freshly snapshotted. In that case the atime is updated and COW happens - for each file
           - in bulk. See also https://lwn.net/Articles/499293/ - Atime and btrfs: a bad combination? (LWN,
           2012-05-31).

           Note that noatime may break applications that rely on atime uptimes like the venerable Mutt (unless
           you use maildir mailboxes).

FILESYSTEM FEATURES

       The basic set of filesystem features gets extended over time. The backward compatibility is maintained
       and the features are optional, need to be explicitly asked for so accidental use will not create
       incompatibilities.

       There are several classes and the respective tools to manage the features:

       at mkfs time only
           This is namely for core structures, like the b-tree nodesize, see mkfs.btrfs(8) for more details.

       after mkfs, on an unmounted filesystem
           Features that may optimize internal structures or add new structures to support new functionality,
           see btrfstune(8). The command btrfs inspect-internal dump-super device will dump a superblock, you
           can map the value of incompat_flags to the features listed below

       after mkfs, on a mounted filesystem
           The features of a filesystem (with a given UUID) are listed in /sys/fs/btrfs/UUID/features/, one file
           per feature. The status is stored inside the file. The value 1 is for enabled and active, while 0
           means the feature was enabled at mount time but turned off afterwards.

           Whether a particular feature can be turned on a mounted filesystem can be found in the directory
           /sys/fs/btrfs/features/, one file per feature. The value 1 means the feature can be enabled.

       List of features (see also mkfs.btrfs(8) section FILESYSTEM FEATURES):

       big_metadata
           (since: 3.4)

           the filesystem uses nodesize for metadata blocks, this can be bigger than the page size

       compress_lzo
           (since: 2.6.38)

           the lzo compression has been used on the filesystem, either as a mount option or via btrfs filesystem
           defrag.

       compress_zstd
           (since: 4.14)

           the zstd compression has been used on the filesystem, either as a mount option or via btrfs
           filesystem defrag.

       default_subvol
           (since: 2.6.34)

           the default subvolume has been set on the filesystem

       extended_iref
           (since: 3.7)

           increased hardlink limit per file in a directory to 65536, older kernels supported a varying number
           of hardlinks depending on the sum of all file name sizes that can be stored into one metadata block

       mixed_backref
           (since: 2.6.31)

           the last major disk format change, improved backreferences, now default

       mixed_groups
           (since: 2.6.37)

           mixed data and metadata block groups, ie. the data and metadata are not separated and occupy the same
           block groups, this mode is suitable for small volumes as there are no constraints how the remaining
           space should be used (compared to the split mode, where empty metadata space cannot be used for data
           and vice versa)

           on the other hand, the final layout is quite unpredictable and possibly highly fragmented, which
           means worse performance

       no_holes
           (since: 3.14)

           improved representation of file extents where holes are not explicitly stored as an extent, saves a
           few percent of metadata if sparse files are used

       raid56
           (since: 3.9)

           the filesystem contains or contained a raid56 profile of block groups

       skinny_metadata
           (since: 3.10)

           reduced-size metadata for extent references, saves a few percent of metadata

FILE ATTRIBUTES

       The btrfs filesystem supports setting the following file attributes using the chattr(1) utility:

       a
           append only, new writes are always written at the end of the file

       A
           no atime updates

       c
           compress data, all data written after this attribute is set will be compressed. Please note that
           compression is also affected by the mount options or the parent directory attributes.

           When set on a directory, all newly created files will inherit this attribute.

       C
           no copy-on-write, file modifications are done in-place

           When set on a directory, all newly created files will inherit this attribute.

               Note
               due to implementation limitations, this flag can be set/unset only on empty files.

       d
           no dump, makes sense with 3rd party tools like dump(8), on BTRFS the attribute can be set/unset but
           no other special handling is done

       D
           synchronous directory updates, for more details search open(2) for O_SYNC and O_DSYNC

       i
           immutable, no file data and metadata changes allowed even to the root user as long as this attribute
           is set (obviously the exception is unsetting the attribute)

       S
           synchronous updates, for more details search open(2) for O_SYNC and O_DSYNC

       X
           no compression, permanently turn off compression on the given file. Any compression mount options
           will not affect this file.

           When set on a directory, all newly created files will inherit this attribute.

       No other attributes are supported. For the complete list please refer to the chattr(1) manual page.

CONTROL DEVICE

       There’s a character special device /dev/btrfs-control with major and minor numbers 10 and 234 (the device
       can be found under the misc category).

           $ ls -l /dev/btrfs-control
           crw------- 1 root root 10, 234 Jan  1 12:00 /dev/btrfs-control

       The device accepts some ioctl calls that can perform following actions on the filesystem module:

       •   scan devices for btrfs filesystem (ie. to let multi-device filesystems mount automatically) and
           register them with the kernel module

       •   similar to scan, but also wait until the device scanning process is finished for a given filesystem

       •   get the supported features (can be also found under /sys/fs/btrfs/features)

       The device is usually created by a system device node manager (eg. udev), but can be created manually:

           # mknod --mode=600 c 10 234 /dev/btrfs-control

       The control device is not strictly required but the device scanning will not work and a workaround would
       need to be used to mount a multi-device filesystem. The mount option device can trigger the device
       scanning during mount.

SEE ALSO

       acl(5), btrfs(8), chattr(1), fstrim(8), ioctl(2), mkfs.btrfs(8), mount(8)