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Commit acda97acb2
changes dax.txt to dax.rst.
Fix the references accordingly.
Cc: Igor Matheus Andrade Torrente <igormtorrente@gmail.com>
Signed-off-by: Kir Kolyshkin <kolyshkin@gmail.com>
Link: https://lore.kernel.org/r/20210611030044.1982911-4-kolyshkin@gmail.com
Signed-off-by: Jonathan Corbet <corbet@lwn.net>
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628 lines
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ReStructuredText
.. SPDX-License-Identifier: GPL-2.0
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========================
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ext4 General Information
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========================
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Ext4 is an advanced level of the ext3 filesystem which incorporates
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scalability and reliability enhancements for supporting large filesystems
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(64 bit) in keeping with increasing disk capacities and state-of-the-art
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feature requirements.
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Mailing list: linux-ext4@vger.kernel.org
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Web site: http://ext4.wiki.kernel.org
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Quick usage instructions
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========================
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Note: More extensive information for getting started with ext4 can be
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found at the ext4 wiki site at the URL:
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http://ext4.wiki.kernel.org/index.php/Ext4_Howto
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- The latest version of e2fsprogs can be found at:
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https://www.kernel.org/pub/linux/kernel/people/tytso/e2fsprogs/
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or
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http://sourceforge.net/project/showfiles.php?group_id=2406
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or grab the latest git repository from:
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https://git.kernel.org/pub/scm/fs/ext2/e2fsprogs.git
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- Create a new filesystem using the ext4 filesystem type:
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# mke2fs -t ext4 /dev/hda1
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Or to configure an existing ext3 filesystem to support extents:
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# tune2fs -O extents /dev/hda1
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If the filesystem was created with 128 byte inodes, it can be
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converted to use 256 byte for greater efficiency via:
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# tune2fs -I 256 /dev/hda1
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- Mounting:
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# mount -t ext4 /dev/hda1 /wherever
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- When comparing performance with other filesystems, it's always
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important to try multiple workloads; very often a subtle change in a
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workload parameter can completely change the ranking of which
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filesystems do well compared to others. When comparing versus ext3,
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note that ext4 enables write barriers by default, while ext3 does
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not enable write barriers by default. So it is useful to use
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explicitly specify whether barriers are enabled or not when via the
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'-o barriers=[0|1]' mount option for both ext3 and ext4 filesystems
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for a fair comparison. When tuning ext3 for best benchmark numbers,
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it is often worthwhile to try changing the data journaling mode; '-o
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data=writeback' can be faster for some workloads. (Note however that
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running mounted with data=writeback can potentially leave stale data
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exposed in recently written files in case of an unclean shutdown,
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which could be a security exposure in some situations.) Configuring
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the filesystem with a large journal can also be helpful for
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metadata-intensive workloads.
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Features
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========
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Currently Available
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-------------------
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* ability to use filesystems > 16TB (e2fsprogs support not available yet)
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* extent format reduces metadata overhead (RAM, IO for access, transactions)
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* extent format more robust in face of on-disk corruption due to magics,
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* internal redundancy in tree
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* improved file allocation (multi-block alloc)
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* lift 32000 subdirectory limit imposed by i_links_count[1]
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* nsec timestamps for mtime, atime, ctime, create time
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* inode version field on disk (NFSv4, Lustre)
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* reduced e2fsck time via uninit_bg feature
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* journal checksumming for robustness, performance
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* persistent file preallocation (e.g for streaming media, databases)
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* ability to pack bitmaps and inode tables into larger virtual groups via the
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flex_bg feature
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* large file support
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* inode allocation using large virtual block groups via flex_bg
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* delayed allocation
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* large block (up to pagesize) support
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* efficient new ordered mode in JBD2 and ext4 (avoid using buffer head to force
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the ordering)
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* Case-insensitive file name lookups
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* file-based encryption support (fscrypt)
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* file-based verity support (fsverity)
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[1] Filesystems with a block size of 1k may see a limit imposed by the
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directory hash tree having a maximum depth of two.
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case-insensitive file name lookups
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======================================================
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The case-insensitive file name lookup feature is supported on a
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per-directory basis, allowing the user to mix case-insensitive and
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case-sensitive directories in the same filesystem. It is enabled by
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flipping the +F inode attribute of an empty directory. The
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case-insensitive string match operation is only defined when we know how
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text in encoded in a byte sequence. For that reason, in order to enable
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case-insensitive directories, the filesystem must have the
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casefold feature, which stores the filesystem-wide encoding
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model used. By default, the charset adopted is the latest version of
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Unicode (12.1.0, by the time of this writing), encoded in the UTF-8
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form. The comparison algorithm is implemented by normalizing the
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strings to the Canonical decomposition form, as defined by Unicode,
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followed by a byte per byte comparison.
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The case-awareness is name-preserving on the disk, meaning that the file
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name provided by userspace is a byte-per-byte match to what is actually
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written in the disk. The Unicode normalization format used by the
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kernel is thus an internal representation, and not exposed to the
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userspace nor to the disk, with the important exception of disk hashes,
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used on large case-insensitive directories with DX feature. On DX
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directories, the hash must be calculated using the casefolded version of
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the filename, meaning that the normalization format used actually has an
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impact on where the directory entry is stored.
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When we change from viewing filenames as opaque byte sequences to seeing
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them as encoded strings we need to address what happens when a program
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tries to create a file with an invalid name. The Unicode subsystem
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within the kernel leaves the decision of what to do in this case to the
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filesystem, which select its preferred behavior by enabling/disabling
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the strict mode. When Ext4 encounters one of those strings and the
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filesystem did not require strict mode, it falls back to considering the
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entire string as an opaque byte sequence, which still allows the user to
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operate on that file, but the case-insensitive lookups won't work.
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Options
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=======
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When mounting an ext4 filesystem, the following option are accepted:
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(*) == default
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ro
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Mount filesystem read only. Note that ext4 will replay the journal (and
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thus write to the partition) even when mounted "read only". The mount
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options "ro,noload" can be used to prevent writes to the filesystem.
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journal_checksum
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Enable checksumming of the journal transactions. This will allow the
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recovery code in e2fsck and the kernel to detect corruption in the
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kernel. It is a compatible change and will be ignored by older
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kernels.
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journal_async_commit
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Commit block can be written to disk without waiting for descriptor
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blocks. If enabled older kernels cannot mount the device. This will
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enable 'journal_checksum' internally.
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journal_path=path, journal_dev=devnum
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When the external journal device's major/minor numbers have changed,
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these options allow the user to specify the new journal location. The
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journal device is identified through either its new major/minor numbers
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encoded in devnum, or via a path to the device.
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norecovery, noload
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Don't load the journal on mounting. Note that if the filesystem was
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not unmounted cleanly, skipping the journal replay will lead to the
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filesystem containing inconsistencies that can lead to any number of
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problems.
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data=journal
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All data are committed into the journal prior to being written into the
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main file system. Enabling this mode will disable delayed allocation
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and O_DIRECT support.
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data=ordered (*)
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All data are forced directly out to the main file system prior to its
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metadata being committed to the journal.
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data=writeback
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Data ordering is not preserved, data may be written into the main file
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system after its metadata has been committed to the journal.
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commit=nrsec (*)
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This setting limits the maximum age of the running transaction to
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'nrsec' seconds. The default value is 5 seconds. This means that if
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you lose your power, you will lose as much as the latest 5 seconds of
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metadata changes (your filesystem will not be damaged though, thanks
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to the journaling). This default value (or any low value) will hurt
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performance, but it's good for data-safety. Setting it to 0 will have
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the same effect as leaving it at the default (5 seconds). Setting it
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to very large values will improve performance. Note that due to
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delayed allocation even older data can be lost on power failure since
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writeback of those data begins only after time set in
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/proc/sys/vm/dirty_expire_centisecs.
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barrier=<0|1(*)>, barrier(*), nobarrier
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This enables/disables the use of write barriers in the jbd code.
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barrier=0 disables, barrier=1 enables. This also requires an IO stack
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which can support barriers, and if jbd gets an error on a barrier
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write, it will disable again with a warning. Write barriers enforce
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proper on-disk ordering of journal commits, making volatile disk write
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caches safe to use, at some performance penalty. If your disks are
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battery-backed in one way or another, disabling barriers may safely
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improve performance. The mount options "barrier" and "nobarrier" can
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also be used to enable or disable barriers, for consistency with other
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ext4 mount options.
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inode_readahead_blks=n
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This tuning parameter controls the maximum number of inode table blocks
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that ext4's inode table readahead algorithm will pre-read into the
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buffer cache. The default value is 32 blocks.
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nouser_xattr
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Disables Extended User Attributes. See the attr(5) manual page for
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more information about extended attributes.
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noacl
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This option disables POSIX Access Control List support. If ACL support
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is enabled in the kernel configuration (CONFIG_EXT4_FS_POSIX_ACL), ACL
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is enabled by default on mount. See the acl(5) manual page for more
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information about acl.
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bsddf (*)
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Make 'df' act like BSD.
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minixdf
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Make 'df' act like Minix.
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debug
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Extra debugging information is sent to syslog.
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abort
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Simulate the effects of calling ext4_abort() for debugging purposes.
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This is normally used while remounting a filesystem which is already
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mounted.
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errors=remount-ro
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Remount the filesystem read-only on an error.
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errors=continue
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Keep going on a filesystem error.
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errors=panic
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Panic and halt the machine if an error occurs. (These mount options
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override the errors behavior specified in the superblock, which can be
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configured using tune2fs)
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data_err=ignore(*)
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Just print an error message if an error occurs in a file data buffer in
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ordered mode.
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data_err=abort
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Abort the journal if an error occurs in a file data buffer in ordered
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mode.
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grpid | bsdgroups
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New objects have the group ID of their parent.
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nogrpid (*) | sysvgroups
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New objects have the group ID of their creator.
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resgid=n
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The group ID which may use the reserved blocks.
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resuid=n
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The user ID which may use the reserved blocks.
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sb=
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Use alternate superblock at this location.
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quota, noquota, grpquota, usrquota
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These options are ignored by the filesystem. They are used only by
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quota tools to recognize volumes where quota should be turned on. See
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documentation in the quota-tools package for more details
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(http://sourceforge.net/projects/linuxquota).
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jqfmt=<quota type>, usrjquota=<file>, grpjquota=<file>
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These options tell filesystem details about quota so that quota
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information can be properly updated during journal replay. They replace
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the above quota options. See documentation in the quota-tools package
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for more details (http://sourceforge.net/projects/linuxquota).
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stripe=n
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Number of filesystem blocks that mballoc will try to use for allocation
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size and alignment. For RAID5/6 systems this should be the number of
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data disks * RAID chunk size in file system blocks.
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delalloc (*)
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Defer block allocation until just before ext4 writes out the block(s)
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in question. This allows ext4 to better allocation decisions more
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efficiently.
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nodelalloc
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Disable delayed allocation. Blocks are allocated when the data is
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copied from userspace to the page cache, either via the write(2) system
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call or when an mmap'ed page which was previously unallocated is
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written for the first time.
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max_batch_time=usec
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Maximum amount of time ext4 should wait for additional filesystem
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operations to be batch together with a synchronous write operation.
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Since a synchronous write operation is going to force a commit and then
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a wait for the I/O complete, it doesn't cost much, and can be a huge
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throughput win, we wait for a small amount of time to see if any other
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transactions can piggyback on the synchronous write. The algorithm
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used is designed to automatically tune for the speed of the disk, by
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measuring the amount of time (on average) that it takes to finish
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committing a transaction. Call this time the "commit time". If the
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time that the transaction has been running is less than the commit
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time, ext4 will try sleeping for the commit time to see if other
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operations will join the transaction. The commit time is capped by
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the max_batch_time, which defaults to 15000us (15ms). This
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optimization can be turned off entirely by setting max_batch_time to 0.
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min_batch_time=usec
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This parameter sets the commit time (as described above) to be at least
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min_batch_time. It defaults to zero microseconds. Increasing this
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parameter may improve the throughput of multi-threaded, synchronous
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workloads on very fast disks, at the cost of increasing latency.
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journal_ioprio=prio
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The I/O priority (from 0 to 7, where 0 is the highest priority) which
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should be used for I/O operations submitted by kjournald2 during a
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commit operation. This defaults to 3, which is a slightly higher
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priority than the default I/O priority.
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auto_da_alloc(*), noauto_da_alloc
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Many broken applications don't use fsync() when replacing existing
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files via patterns such as fd = open("foo.new")/write(fd,..)/close(fd)/
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rename("foo.new", "foo"), or worse yet, fd = open("foo",
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O_TRUNC)/write(fd,..)/close(fd). If auto_da_alloc is enabled, ext4
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will detect the replace-via-rename and replace-via-truncate patterns
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and force that any delayed allocation blocks are allocated such that at
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the next journal commit, in the default data=ordered mode, the data
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blocks of the new file are forced to disk before the rename() operation
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is committed. This provides roughly the same level of guarantees as
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ext3, and avoids the "zero-length" problem that can happen when a
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system crashes before the delayed allocation blocks are forced to disk.
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noinit_itable
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Do not initialize any uninitialized inode table blocks in the
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background. This feature may be used by installation CD's so that the
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install process can complete as quickly as possible; the inode table
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initialization process would then be deferred until the next time the
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file system is unmounted.
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init_itable=n
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The lazy itable init code will wait n times the number of milliseconds
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it took to zero out the previous block group's inode table. This
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minimizes the impact on the system performance while file system's
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inode table is being initialized.
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discard, nodiscard(*)
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Controls whether ext4 should issue discard/TRIM commands to the
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underlying block device when blocks are freed. This is useful for SSD
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devices and sparse/thinly-provisioned LUNs, but it is off by default
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until sufficient testing has been done.
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nouid32
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Disables 32-bit UIDs and GIDs. This is for interoperability with
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older kernels which only store and expect 16-bit values.
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block_validity(*), noblock_validity
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These options enable or disable the in-kernel facility for tracking
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filesystem metadata blocks within internal data structures. This
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allows multi- block allocator and other routines to notice bugs or
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corrupted allocation bitmaps which cause blocks to be allocated which
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overlap with filesystem metadata blocks.
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dioread_lock, dioread_nolock
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Controls whether or not ext4 should use the DIO read locking. If the
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dioread_nolock option is specified ext4 will allocate uninitialized
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extent before buffer write and convert the extent to initialized after
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IO completes. This approach allows ext4 code to avoid using inode
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mutex, which improves scalability on high speed storages. However this
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does not work with data journaling and dioread_nolock option will be
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ignored with kernel warning. Note that dioread_nolock code path is only
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used for extent-based files. Because of the restrictions this options
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comprises it is off by default (e.g. dioread_lock).
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max_dir_size_kb=n
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This limits the size of directories so that any attempt to expand them
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beyond the specified limit in kilobytes will cause an ENOSPC error.
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This is useful in memory constrained environments, where a very large
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directory can cause severe performance problems or even provoke the Out
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Of Memory killer. (For example, if there is only 512mb memory
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available, a 176mb directory may seriously cramp the system's style.)
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i_version
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Enable 64-bit inode version support. This option is off by default.
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dax
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Use direct access (no page cache). See
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Documentation/filesystems/dax.rst. Note that this option is
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incompatible with data=journal.
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inlinecrypt
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When possible, encrypt/decrypt the contents of encrypted files using the
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blk-crypto framework rather than filesystem-layer encryption. This
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allows the use of inline encryption hardware. The on-disk format is
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unaffected. For more details, see
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Documentation/block/inline-encryption.rst.
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Data Mode
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=========
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There are 3 different data modes:
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* writeback mode
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In data=writeback mode, ext4 does not journal data at all. This mode provides
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a similar level of journaling as that of XFS, JFS, and ReiserFS in its default
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mode - metadata journaling. A crash+recovery can cause incorrect data to
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appear in files which were written shortly before the crash. This mode will
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typically provide the best ext4 performance.
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* ordered mode
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In data=ordered mode, ext4 only officially journals metadata, but it logically
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groups metadata information related to data changes with the data blocks into
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a single unit called a transaction. When it's time to write the new metadata
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out to disk, the associated data blocks are written first. In general, this
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mode performs slightly slower than writeback but significantly faster than
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journal mode.
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* journal mode
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data=journal mode provides full data and metadata journaling. All new data is
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written to the journal first, and then to its final location. In the event of
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a crash, the journal can be replayed, bringing both data and metadata into a
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consistent state. This mode is the slowest except when data needs to be read
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from and written to disk at the same time where it outperforms all others
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modes. Enabling this mode will disable delayed allocation and O_DIRECT
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support.
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/proc entries
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=============
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Information about mounted ext4 file systems can be found in
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/proc/fs/ext4. Each mounted filesystem will have a directory in
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/proc/fs/ext4 based on its device name (i.e., /proc/fs/ext4/hdc or
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/proc/fs/ext4/dm-0). The files in each per-device directory are shown
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in table below.
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Files in /proc/fs/ext4/<devname>
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mb_groups
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details of multiblock allocator buddy cache of free blocks
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/sys entries
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============
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Information about mounted ext4 file systems can be found in
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/sys/fs/ext4. Each mounted filesystem will have a directory in
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/sys/fs/ext4 based on its device name (i.e., /sys/fs/ext4/hdc or
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/sys/fs/ext4/dm-0). The files in each per-device directory are shown
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in table below.
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Files in /sys/fs/ext4/<devname>:
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(see also Documentation/ABI/testing/sysfs-fs-ext4)
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delayed_allocation_blocks
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This file is read-only and shows the number of blocks that are dirty in
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the page cache, but which do not have their location in the filesystem
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allocated yet.
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inode_goal
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Tuning parameter which (if non-zero) controls the goal inode used by
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the inode allocator in preference to all other allocation heuristics.
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This is intended for debugging use only, and should be 0 on production
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systems.
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|
|
inode_readahead_blks
|
|
Tuning parameter which controls the maximum number of inode table
|
|
blocks that ext4's inode table readahead algorithm will pre-read into
|
|
the buffer cache.
|
|
|
|
lifetime_write_kbytes
|
|
This file is read-only and shows the number of kilobytes of data that
|
|
have been written to this filesystem since it was created.
|
|
|
|
max_writeback_mb_bump
|
|
The maximum number of megabytes the writeback code will try to write
|
|
out before move on to another inode.
|
|
|
|
mb_group_prealloc
|
|
The multiblock allocator will round up allocation requests to a
|
|
multiple of this tuning parameter if the stripe size is not set in the
|
|
ext4 superblock
|
|
|
|
mb_max_inode_prealloc
|
|
The maximum length of per-inode ext4_prealloc_space list.
|
|
|
|
mb_max_to_scan
|
|
The maximum number of extents the multiblock allocator will search to
|
|
find the best extent.
|
|
|
|
mb_min_to_scan
|
|
The minimum number of extents the multiblock allocator will search to
|
|
find the best extent.
|
|
|
|
mb_order2_req
|
|
Tuning parameter which controls the minimum size for requests (as a
|
|
power of 2) where the buddy cache is used.
|
|
|
|
mb_stats
|
|
Controls whether the multiblock allocator should collect statistics,
|
|
which are shown during the unmount. 1 means to collect statistics, 0
|
|
means not to collect statistics.
|
|
|
|
mb_stream_req
|
|
Files which have fewer blocks than this tunable parameter will have
|
|
their blocks allocated out of a block group specific preallocation
|
|
pool, so that small files are packed closely together. Each large file
|
|
will have its blocks allocated out of its own unique preallocation
|
|
pool.
|
|
|
|
session_write_kbytes
|
|
This file is read-only and shows the number of kilobytes of data that
|
|
have been written to this filesystem since it was mounted.
|
|
|
|
reserved_clusters
|
|
This is RW file and contains number of reserved clusters in the file
|
|
system which will be used in the specific situations to avoid costly
|
|
zeroout, unexpected ENOSPC, or possible data loss. The default is 2% or
|
|
4096 clusters, whichever is smaller and this can be changed however it
|
|
can never exceed number of clusters in the file system. If there is not
|
|
enough space for the reserved space when mounting the file mount will
|
|
_not_ fail.
|
|
|
|
Ioctls
|
|
======
|
|
|
|
Ext4 implements various ioctls which can be used by applications to access
|
|
ext4-specific functionality. An incomplete list of these ioctls is shown in the
|
|
table below. This list includes truly ext4-specific ioctls (``EXT4_IOC_*``) as
|
|
well as ioctls that may have been ext4-specific originally but are now supported
|
|
by some other filesystem(s) too (``FS_IOC_*``).
|
|
|
|
Table of Ext4 ioctls
|
|
|
|
FS_IOC_GETFLAGS
|
|
Get additional attributes associated with inode. The ioctl argument is
|
|
an integer bitfield, with bit values described in ext4.h.
|
|
|
|
FS_IOC_SETFLAGS
|
|
Set additional attributes associated with inode. The ioctl argument is
|
|
an integer bitfield, with bit values described in ext4.h.
|
|
|
|
EXT4_IOC_GETVERSION, EXT4_IOC_GETVERSION_OLD
|
|
Get the inode i_generation number stored for each inode. The
|
|
i_generation number is normally changed only when new inode is created
|
|
and it is particularly useful for network filesystems. The '_OLD'
|
|
version of this ioctl is an alias for FS_IOC_GETVERSION.
|
|
|
|
EXT4_IOC_SETVERSION, EXT4_IOC_SETVERSION_OLD
|
|
Set the inode i_generation number stored for each inode. The '_OLD'
|
|
version of this ioctl is an alias for FS_IOC_SETVERSION.
|
|
|
|
EXT4_IOC_GROUP_EXTEND
|
|
This ioctl has the same purpose as the resize mount option. It allows
|
|
to resize filesystem to the end of the last existing block group,
|
|
further resize has to be done with resize2fs, either online, or
|
|
offline. The argument points to the unsigned logn number representing
|
|
the filesystem new block count.
|
|
|
|
EXT4_IOC_MOVE_EXT
|
|
Move the block extents from orig_fd (the one this ioctl is pointing to)
|
|
to the donor_fd (the one specified in move_extent structure passed as
|
|
an argument to this ioctl). Then, exchange inode metadata between
|
|
orig_fd and donor_fd. This is especially useful for online
|
|
defragmentation, because the allocator has the opportunity to allocate
|
|
moved blocks better, ideally into one contiguous extent.
|
|
|
|
EXT4_IOC_GROUP_ADD
|
|
Add a new group descriptor to an existing or new group descriptor
|
|
block. The new group descriptor is described by ext4_new_group_input
|
|
structure, which is passed as an argument to this ioctl. This is
|
|
especially useful in conjunction with EXT4_IOC_GROUP_EXTEND, which
|
|
allows online resize of the filesystem to the end of the last existing
|
|
block group. Those two ioctls combined is used in userspace online
|
|
resize tool (e.g. resize2fs).
|
|
|
|
EXT4_IOC_MIGRATE
|
|
This ioctl operates on the filesystem itself. It converts (migrates)
|
|
ext3 indirect block mapped inode to ext4 extent mapped inode by walking
|
|
through indirect block mapping of the original inode and converting
|
|
contiguous block ranges into ext4 extents of the temporary inode. Then,
|
|
inodes are swapped. This ioctl might help, when migrating from ext3 to
|
|
ext4 filesystem, however suggestion is to create fresh ext4 filesystem
|
|
and copy data from the backup. Note, that filesystem has to support
|
|
extents for this ioctl to work.
|
|
|
|
EXT4_IOC_ALLOC_DA_BLKS
|
|
Force all of the delay allocated blocks to be allocated to preserve
|
|
application-expected ext3 behaviour. Note that this will also start
|
|
triggering a write of the data blocks, but this behaviour may change in
|
|
the future as it is not necessary and has been done this way only for
|
|
sake of simplicity.
|
|
|
|
EXT4_IOC_RESIZE_FS
|
|
Resize the filesystem to a new size. The number of blocks of resized
|
|
filesystem is passed in via 64 bit integer argument. The kernel
|
|
allocates bitmaps and inode table, the userspace tool thus just passes
|
|
the new number of blocks.
|
|
|
|
EXT4_IOC_SWAP_BOOT
|
|
Swap i_blocks and associated attributes (like i_blocks, i_size,
|
|
i_flags, ...) from the specified inode with inode EXT4_BOOT_LOADER_INO
|
|
(#5). This is typically used to store a boot loader in a secure part of
|
|
the filesystem, where it can't be changed by a normal user by accident.
|
|
The data blocks of the previous boot loader will be associated with the
|
|
given inode.
|
|
|
|
References
|
|
==========
|
|
|
|
kernel source: <file:fs/ext4/>
|
|
<file:fs/jbd2/>
|
|
|
|
programs: http://e2fsprogs.sourceforge.net/
|
|
|
|
useful links: https://fedoraproject.org/wiki/ext3-devel
|
|
http://www.bullopensource.org/ext4/
|
|
http://ext4.wiki.kernel.org/index.php/Main_Page
|
|
https://fedoraproject.org/wiki/Features/Ext4
|