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Replace **bold** or ``quoted`` with :command:`line ...` that is supposed to be used verbatim. Signed-off-by: David Sterba <dsterba@suse.com>
334 lines
14 KiB
ReStructuredText
334 lines
14 KiB
ReStructuredText
Glossary
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========
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Terms in *italics* also appear in this glossary.
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allocator
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Usually *allocator* means the *block* allocator, i.e. the logic
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inside filesystem which decides where to place newly allocated blocks
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in order to maintain several constraints (like data locality, low
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fragmentation).
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In btrfs, allocator may also refer to *chunk* allocator, i.e. the
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logic behind placing chunks on devices.
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balance
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An operation that can be done to a btrfs filesystem, for example
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through :command:`btrfs fi balance /path`. A
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balance passes all data in the filesystem through the *allocator*
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again. It is primarily intended to rebalance the data in the filesystem
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across the *devices* when a device is added or removed. A balance
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will regenerate missing copies for the redundant *RAID* levels, if a
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device has failed. As of Linux kernel 3.3, a balance operation can be
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made selective about which parts of the filesystem are rewritten.
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barrier
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An instruction to the disk hardware to ensure that everything before
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the barrier is physically written to permanent storage before anything
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after it. Used in btrfs's *copy on write* approach to ensure
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filesystem consistency.
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block
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A single physically and logically contiguous piece of storage on a
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device, of size e.g. 4K.
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block group
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The unit of allocation of space in btrfs. A block group is laid out on
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the disk by the btrfs *allocator*, and will consist of one or more
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*chunks*, each stored on a different *device*. The number of chunks
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used in a block group will depend on its *RAID* level.
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B-tree
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The fundamental storage data structure used in btrfs. Except for the
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*superblocks*, all of btrfs *metadata* is stored in one of several
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B-trees on disk. B-trees store key/item pairs. While the same code is
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used to implement all of the B-trees, there are a few different
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categories of B-tree. The name *btrfs*
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refers to its use of B-trees.
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btrfsck
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Tool in *btrfs-progs* that checks a filesystem *offline* (i.e.
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unmounted), and reports on any errors in the filesystem structures it
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finds. By default the tool runs in read-only mode as fixing errors is
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potentially dangerous. See also *scrub*.
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btrfs-progs
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User mode tools to manage btrfs-specific features. Maintained at
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http://github.com/kdave/btrfs-progs.git . The main frontend to btrfs
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features is the standalone tool *btrfs*, although
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other tools such as *mkfs.btrfs* and *btrfstune* are also part of
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btrfs-progs.
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chunk
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A part of a *block group*. Chunks are either 1 GiB in size (for data)
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or 256 MiB (for *metadata*).
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chunk tree
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A layer that keeps information about mapping between physical and
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logical block addresses. It's stored within the *system* group.
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cleaner
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Usually referred to in context of deleted subvolumes. It's a background
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process that removes the actual data once a subvolume has been deleted.
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Cleaning can involve lots of IO and CPU activity depending on the
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fragmentation and amount of shared data with other subvolumes.
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copy-on-write
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Also known as *COW*. The method that btrfs uses for modifying data.
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Instead of directly overwriting data in place, btrfs takes a copy of
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the data, alters it, and then writes the modified data back to a
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different (free) location on the disk. It then updates the *metadata*
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to reflect the new location of the data. In order to update the
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metadata, the affected metadata blocks are also treated in the same
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way. In COW filesystems, files tend to fragment as they are modified.
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Copy-on-write is also used in the implementation of *snapshots* and
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*reflink copies*. A copy-on-write filesystem is, in theory,
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*always* consistent, provided the underlying hardware supports
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*barriers*.
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COW
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See *copy-on-write*.
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default subvolume
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The *subvolume* in a btrfs filesystem which is mounted when mounting
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the filesystem without using the ``subvol=`` mount option.
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device
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A Linux block device, e.g. a whole disk, partition, LVM logical volume,
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loopback device, or network block device. A btrfs filesystem can reside
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on one or more devices.
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df
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A standard Unix tool for reporting the amount of space used and free in
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a filesystem. The standard tool does not give accurate results, but the
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*btrfs* command from *btrfs-progs* has
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an implementation of *df* which shows space available in more detail. See
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the
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[[FAQ#Why_does_df_show_incorrect_free_space_for_my_RAID_volume.3F|FAQ]]
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for a more detailed explanation of btrfs free space accounting.
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DUP
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A form of "*RAID*" which stores two copies of each piece of data on
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the same *device*. This is similar to *RAID-1*, and protects
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against *block*-level errors on the device, but does not provide any
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guarantees if the entire device fails. By default, btrfs uses *DUP*
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profile for metadata on filesystems with one rotational device,
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*single* profile on filesystems with one non-rotational device, and
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*RAID1* profile on filesystems with more than one device.
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ENOSPC
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Error code returned by the OS to a user program when the filesystem
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cannot allocate enough data to fulfill the user requested. In most
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filesystems, it indicates there is no free space available in the
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filesystem. Due to the additional space requirements from btrfs's
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*COW* behaviour, btrfs can sometimes return ENOSPC when there is
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apparently (in terms of *df*) a large amount of space free. This is
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effectively a bug in btrfs, and (if it is repeatable), using the mount
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option ``enospc_debug`` may give a report
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that will help the btrfs developers. See the
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[[FAQ#if_your_device_is_large_.28.3E16GiB.29|FAQ entry]] on free space.
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extent
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Contiguous sequence of bytes on disk that holds file data.
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A file stored on disk with 3 extents means that it consists of three
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fragments of contiguous bytes. See *filefrag*. A file in one extent
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would mean it is not fragmented.
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Extent buffer
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An abstraction to allow access to *B-tree* blocks larger than a page size.
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fallocate
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Command line tool in util-linux, and a syscall, that reserves space in
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the filesystem for a file, without actually writing any file data to
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the filesystem. First data write will turn the preallocated extents
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into regular ones. See *fallocate(1)* and *fallocate(2)* manual pages
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for more details.
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filefrag
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A tool to show the number of extents in a file, and hence the amount of
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fragmentation in the file. It is usually part of the e2fsprogs package
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on most Linux distributions. While initially developed for the ext2
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filesystem, it works on Btrfs as well. It uses the *FIEMAP* ioctl.
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free space cache
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Btrfs doesn't track free space, it only tracks allocated space. Free
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space is by definition any holes in the allocated space, but finding
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these holes is actually fairly I/O intensive. The free space cache
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stores a condensed representation of what is free. It is updated on
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every *transaction* commit.
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fsync
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On Unix and Unix-like operating systems (of which Linux is the latter),
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the ``fsync()`` system call causes all buffered file
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descriptor related data changes to be flushed to the underlying block
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device. When a file is modified on a modern operating system the
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changes are generally not written to the disk immediately but rather
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those changes are buffered in memory for reasons of performance,
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calling ``fsync()`` causes any in-memory changes to be written
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to disk.
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generation
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An internal counter which updates for each *transaction*. When a
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*metadata* block is written (using *copy on write*), current
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generation is stored in the block, so that blocks which are too new
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(and hence possibly inconsistent) can be identified.
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key
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A fixed sized tuple used to identify and sort items in a *B-tree*.
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The key is broken up into 3 parts: *objectid*, *type*, and
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*offset*. The *type* field indicates how each of the other two
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fields should be used, and what to expect to find in the item.
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item
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A variable sized structure stored in B-tree leaves. Items hold
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different types of data depending on key type.
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log tree
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A b-tree that temporarily tracks ongoing metadata updates until a full
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transaction commit is done. It's a performance optimization of
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``fsync``. The log tracked in the tree are replayed if the filesystem
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is not unmounted cleanly.
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metadata
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Data about data. In btrfs, this includes all of the internal data
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structures of the filesystem, including directory structures,
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filenames, file permissions, checksums, and the location of each file's
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*extents*. All btrfs metadata is stored in *B-trees*.
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mkfs.btrfs
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The tool (from *btrfs-progs*) to create a btrfs filesystem.
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offline
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A filesystem which is not mounted is offline. Some tools (e.g.
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*btrfsck*) will only work on offline filesystems. Compare *online*.
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online
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A filesystem which is mounted is online. Most btrfs tools will only
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work on online filesystems. Compare *offline*.
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orphan
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A file that's still in use (opened by a running process) but all
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directory entries of that file have been removed.
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RAID
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A class of different methods for writing some additional redundant data
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across multiple *devices* so that if one device fails, the missing
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data can be reconstructed from the remaining ones. See *RAID-0*,
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*RAID-1*, *RAID-5*, *RAID-6*, *RAID-10*, *DUP* and
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*single*. Traditional RAID methods operate across multiple devices of
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equal size, whereas btrfs's RAID implementation works inside *block
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groups*.
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RAID-0
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A form of *RAID* which provides no form of error recovery, but
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stripes a single copy of data across multiple devices for performance
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purposes. The stripe size is fixed to 64KB for now.
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RAID-1
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A form of *RAID* which stores two complete copies of each piece of
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data. Each copy is stored on a different *device*. btrfs requires a
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minimum of two devices to use RAID-1. This is the default for btrfs's
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*metadata* on more than one device.
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RAID-5
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A form of *RAID* which stripes a single copy of data across multiple
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*devices*, including one device's worth of additional parity data.
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Can be used to recover from a single device failure.
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RAID-6
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A form of *RAID* which stripes a single copy of data across multiple
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*devices*, including two device's worth of additional parity data. Can
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be used to recover from the failure of two devices.
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RAID-10
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A form of *RAID* which stores two complete copies of each piece of
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data, and also stripes each copy across multiple devices for
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performance.
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reflink
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Parameter to :command:`cp`, allowing it to take advantage of the
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capabilities of *COW*-capable filesystems. Allows for files to be
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copied and modified, with only the modifications taking up additional
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storage space. May be considered as *snapshots* on a single file rather
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than a *subvolume*. Example: :command:`cp --reflink file1 file2`
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relocation
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The process of moving block groups within the filesystem while
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maintaining full filesystem integrity and consistency. This
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functionality is underlying *balance* and *device* removing features.
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scrub
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An *online* filesystem checking tool. Reads all the data and metadata
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on the filesystem, and uses *checksums* and the duplicate copies from
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*RAID* storage to identify and repair any corrupt data.
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seed device
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A readonly device can be used as a filesystem seed or template (e.g. a
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CD-ROM containing an OS image). Read/write devices can be added to
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store modifications (using *copy on write*), changes to the writable
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devices are persistent across reboots. The original device remains
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unchanged and can be removed at any time (after Btrfs has been
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instructed to copy over all missing blocks). Multiple read/write file
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systems can be built from the same seed.
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single
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A "*RAID*" level in btrfs, storing a single copy of each piece of data.
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The default for data (as opposed to *metadata*) in btrfs. Single is
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also default metadata profile for non-rotational (SSD, flash) devices.
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snapshot
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A *subvolume* which is a *copy on write* copy of another subvolume. The
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two subvolumes share all of their common (unmodified) data, which means
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that snapshots can be used to keep the historical state of a filesystem
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very cheaply. After the snapshot is made, the original subvolume and
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the snapshot are of equal status: the original does not "own" the
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snapshot, and either one can be deleted without affecting the other
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one.
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subvolume
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A tree of files and directories inside a btrfs that can be mounted as
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if it were an independent filesystem. A subvolume is created by taking
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a reference on the root of another subvolume. Each btrfs filesystem has
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at least one subvolume, the *top-level subvolume*, which contains
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everything else in the filesystem. Additional subvolumes can be created
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and deleted with the *btrfs<* tool. All subvolumes share the same pool
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of free space in the filesystem. See also *default subvolume*.
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superblock
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The *block* on the disk, at a fixed known location and of fixed size,
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which contains pointers to the disk blocks containing all the other
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filesystem *metadata* structures. btrfs stores multiple copies of the
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superblock on each *device* in the filesystem at offsets 64 KiB, 64
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MiB, 256 GiB, 1 TiB and PiB.
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system array
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Cryptic name of *superblock* metadata describing how to assemble a
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filesystem from multiple device. Prior to mount, the command *btrfs dev
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scan* has to be called, or all the devices have to be specified via
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mount option *device=/dev/ice*.
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top-level subvolume
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The *subvolume* at the very top of the filesystem. This is the only
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subvolume present in a newly-created btrfs filesystem, and internally has ID 5,
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otherwise could be referenced as 0 (e.g. within the *set-default* subcommand of
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*btrfs*).
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transaction
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A consistent set of changes. To avoid generating very large amounts of
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disk activity, btrfs caches changes in RAM for up to 30 seconds
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(sometimes more often if the filesystem is running short on space or
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doing a lot of *fsync*s), and then writes (commits) these changes out
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to disk in one go (using *copy on write* behaviour). This period of
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caching is called a transaction. Only one transaction is active on the
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filesystem at any one time.
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transid
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An alternative term for *generation*.
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writeback
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*Writeback* in the context of the Linux kernel can be defined as the
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process of writing "dirty" memory from the page cache to the disk,
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when certain conditions are met (timeout, number of dirty pages over a
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ratio).
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