1 .. SPDX-License-Identifier: GPL-2.0
3 ========================
4 ext4 General Information
5 ========================
7 Ext4 is an advanced level of the ext3 filesystem which incorporates
8 scalability and reliability enhancements for supporting large filesystems
9 (64 bit) in keeping with increasing disk capacities and state-of-the-art
12 Mailing list: linux-ext4@vger.kernel.org
13 Web site: http://ext4.wiki.kernel.org
16 Quick usage instructions
17 ========================
19 Note: More extensive information for getting started with ext4 can be
20 found at the ext4 wiki site at the URL:
21 http://ext4.wiki.kernel.org/index.php/Ext4_Howto
23 - The latest version of e2fsprogs can be found at:
25 https://www.kernel.org/pub/linux/kernel/people/tytso/e2fsprogs/
29 http://sourceforge.net/project/showfiles.php?group_id=2406
31 or grab the latest git repository from:
33 https://git.kernel.org/pub/scm/fs/ext2/e2fsprogs.git
35 - Create a new filesystem using the ext4 filesystem type:
37 # mke2fs -t ext4 /dev/hda1
39 Or to configure an existing ext3 filesystem to support extents:
41 # tune2fs -O extents /dev/hda1
43 If the filesystem was created with 128 byte inodes, it can be
44 converted to use 256 byte for greater efficiency via:
46 # tune2fs -I 256 /dev/hda1
50 # mount -t ext4 /dev/hda1 /wherever
52 - When comparing performance with other filesystems, it's always
53 important to try multiple workloads; very often a subtle change in a
54 workload parameter can completely change the ranking of which
55 filesystems do well compared to others. When comparing versus ext3,
56 note that ext4 enables write barriers by default, while ext3 does
57 not enable write barriers by default. So it is useful to use
58 explicitly specify whether barriers are enabled or not when via the
59 '-o barriers=[0|1]' mount option for both ext3 and ext4 filesystems
60 for a fair comparison. When tuning ext3 for best benchmark numbers,
61 it is often worthwhile to try changing the data journaling mode; '-o
62 data=writeback' can be faster for some workloads. (Note however that
63 running mounted with data=writeback can potentially leave stale data
64 exposed in recently written files in case of an unclean shutdown,
65 which could be a security exposure in some situations.) Configuring
66 the filesystem with a large journal can also be helpful for
67 metadata-intensive workloads.
75 * ability to use filesystems > 16TB (e2fsprogs support not available yet)
76 * extent format reduces metadata overhead (RAM, IO for access, transactions)
77 * extent format more robust in face of on-disk corruption due to magics,
78 * internal redundancy in tree
79 * improved file allocation (multi-block alloc)
80 * lift 32000 subdirectory limit imposed by i_links_count[1]
81 * nsec timestamps for mtime, atime, ctime, create time
82 * inode version field on disk (NFSv4, Lustre)
83 * reduced e2fsck time via uninit_bg feature
84 * journal checksumming for robustness, performance
85 * persistent file preallocation (e.g for streaming media, databases)
86 * ability to pack bitmaps and inode tables into larger virtual groups via the
89 * inode allocation using large virtual block groups via flex_bg
91 * large block (up to pagesize) support
92 * efficient new ordered mode in JBD2 and ext4 (avoid using buffer head to force
94 * Case-insensitive file name lookups
95 * file-based encryption support (fscrypt)
96 * file-based verity support (fsverity)
98 [1] Filesystems with a block size of 1k may see a limit imposed by the
99 directory hash tree having a maximum depth of two.
101 case-insensitive file name lookups
102 ======================================================
104 The case-insensitive file name lookup feature is supported on a
105 per-directory basis, allowing the user to mix case-insensitive and
106 case-sensitive directories in the same filesystem. It is enabled by
107 flipping the +F inode attribute of an empty directory. The
108 case-insensitive string match operation is only defined when we know how
109 text in encoded in a byte sequence. For that reason, in order to enable
110 case-insensitive directories, the filesystem must have the
111 casefold feature, which stores the filesystem-wide encoding
112 model used. By default, the charset adopted is the latest version of
113 Unicode (12.1.0, by the time of this writing), encoded in the UTF-8
114 form. The comparison algorithm is implemented by normalizing the
115 strings to the Canonical decomposition form, as defined by Unicode,
116 followed by a byte per byte comparison.
118 The case-awareness is name-preserving on the disk, meaning that the file
119 name provided by userspace is a byte-per-byte match to what is actually
120 written in the disk. The Unicode normalization format used by the
121 kernel is thus an internal representation, and not exposed to the
122 userspace nor to the disk, with the important exception of disk hashes,
123 used on large case-insensitive directories with DX feature. On DX
124 directories, the hash must be calculated using the casefolded version of
125 the filename, meaning that the normalization format used actually has an
126 impact on where the directory entry is stored.
128 When we change from viewing filenames as opaque byte sequences to seeing
129 them as encoded strings we need to address what happens when a program
130 tries to create a file with an invalid name. The Unicode subsystem
131 within the kernel leaves the decision of what to do in this case to the
132 filesystem, which select its preferred behavior by enabling/disabling
133 the strict mode. When Ext4 encounters one of those strings and the
134 filesystem did not require strict mode, it falls back to considering the
135 entire string as an opaque byte sequence, which still allows the user to
136 operate on that file, but the case-insensitive lookups won't work.
141 When mounting an ext4 filesystem, the following option are accepted:
145 Mount filesystem read only. Note that ext4 will replay the journal (and
146 thus write to the partition) even when mounted "read only". The mount
147 options "ro,noload" can be used to prevent writes to the filesystem.
150 Enable checksumming of the journal transactions. This will allow the
151 recovery code in e2fsck and the kernel to detect corruption in the
152 kernel. It is a compatible change and will be ignored by older
156 Commit block can be written to disk without waiting for descriptor
157 blocks. If enabled older kernels cannot mount the device. This will
158 enable 'journal_checksum' internally.
160 journal_path=path, journal_dev=devnum
161 When the external journal device's major/minor numbers have changed,
162 these options allow the user to specify the new journal location. The
163 journal device is identified through either its new major/minor numbers
164 encoded in devnum, or via a path to the device.
167 Don't load the journal on mounting. Note that if the filesystem was
168 not unmounted cleanly, skipping the journal replay will lead to the
169 filesystem containing inconsistencies that can lead to any number of
173 All data are committed into the journal prior to being written into the
174 main file system. Enabling this mode will disable delayed allocation
175 and O_DIRECT support.
178 All data are forced directly out to the main file system prior to its
179 metadata being committed to the journal.
182 Data ordering is not preserved, data may be written into the main file
183 system after its metadata has been committed to the journal.
186 This setting limits the maximum age of the running transaction to
187 'nrsec' seconds. The default value is 5 seconds. This means that if
188 you lose your power, you will lose as much as the latest 5 seconds of
189 metadata changes (your filesystem will not be damaged though, thanks
190 to the journaling). This default value (or any low value) will hurt
191 performance, but it's good for data-safety. Setting it to 0 will have
192 the same effect as leaving it at the default (5 seconds). Setting it
193 to very large values will improve performance. Note that due to
194 delayed allocation even older data can be lost on power failure since
195 writeback of those data begins only after time set in
196 /proc/sys/vm/dirty_expire_centisecs.
198 barrier=<0|1(*)>, barrier(*), nobarrier
199 This enables/disables the use of write barriers in the jbd code.
200 barrier=0 disables, barrier=1 enables. This also requires an IO stack
201 which can support barriers, and if jbd gets an error on a barrier
202 write, it will disable again with a warning. Write barriers enforce
203 proper on-disk ordering of journal commits, making volatile disk write
204 caches safe to use, at some performance penalty. If your disks are
205 battery-backed in one way or another, disabling barriers may safely
206 improve performance. The mount options "barrier" and "nobarrier" can
207 also be used to enable or disable barriers, for consistency with other
210 inode_readahead_blks=n
211 This tuning parameter controls the maximum number of inode table blocks
212 that ext4's inode table readahead algorithm will pre-read into the
213 buffer cache. The default value is 32 blocks.
216 Disables Extended User Attributes. See the attr(5) manual page for
217 more information about extended attributes.
220 This option disables POSIX Access Control List support. If ACL support
221 is enabled in the kernel configuration (CONFIG_EXT4_FS_POSIX_ACL), ACL
222 is enabled by default on mount. See the acl(5) manual page for more
223 information about acl.
226 Make 'df' act like BSD.
229 Make 'df' act like Minix.
232 Extra debugging information is sent to syslog.
235 Simulate the effects of calling ext4_abort() for debugging purposes.
236 This is normally used while remounting a filesystem which is already
240 Remount the filesystem read-only on an error.
243 Keep going on a filesystem error.
246 Panic and halt the machine if an error occurs. (These mount options
247 override the errors behavior specified in the superblock, which can be
248 configured using tune2fs)
251 Just print an error message if an error occurs in a file data buffer in
254 Abort the journal if an error occurs in a file data buffer in ordered
258 New objects have the group ID of their parent.
260 nogrpid (*) | sysvgroups
261 New objects have the group ID of their creator.
264 The group ID which may use the reserved blocks.
267 The user ID which may use the reserved blocks.
270 Use alternate superblock at this location.
272 quota, noquota, grpquota, usrquota
273 These options are ignored by the filesystem. They are used only by
274 quota tools to recognize volumes where quota should be turned on. See
275 documentation in the quota-tools package for more details
276 (http://sourceforge.net/projects/linuxquota).
278 jqfmt=<quota type>, usrjquota=<file>, grpjquota=<file>
279 These options tell filesystem details about quota so that quota
280 information can be properly updated during journal replay. They replace
281 the above quota options. See documentation in the quota-tools package
282 for more details (http://sourceforge.net/projects/linuxquota).
285 Number of filesystem blocks that mballoc will try to use for allocation
286 size and alignment. For RAID5/6 systems this should be the number of
287 data disks * RAID chunk size in file system blocks.
290 Defer block allocation until just before ext4 writes out the block(s)
291 in question. This allows ext4 to better allocation decisions more
295 Disable delayed allocation. Blocks are allocated when the data is
296 copied from userspace to the page cache, either via the write(2) system
297 call or when an mmap'ed page which was previously unallocated is
298 written for the first time.
301 Maximum amount of time ext4 should wait for additional filesystem
302 operations to be batch together with a synchronous write operation.
303 Since a synchronous write operation is going to force a commit and then
304 a wait for the I/O complete, it doesn't cost much, and can be a huge
305 throughput win, we wait for a small amount of time to see if any other
306 transactions can piggyback on the synchronous write. The algorithm
307 used is designed to automatically tune for the speed of the disk, by
308 measuring the amount of time (on average) that it takes to finish
309 committing a transaction. Call this time the "commit time". If the
310 time that the transaction has been running is less than the commit
311 time, ext4 will try sleeping for the commit time to see if other
312 operations will join the transaction. The commit time is capped by
313 the max_batch_time, which defaults to 15000us (15ms). This
314 optimization can be turned off entirely by setting max_batch_time to 0.
317 This parameter sets the commit time (as described above) to be at least
318 min_batch_time. It defaults to zero microseconds. Increasing this
319 parameter may improve the throughput of multi-threaded, synchronous
320 workloads on very fast disks, at the cost of increasing latency.
323 The I/O priority (from 0 to 7, where 0 is the highest priority) which
324 should be used for I/O operations submitted by kjournald2 during a
325 commit operation. This defaults to 3, which is a slightly higher
326 priority than the default I/O priority.
328 auto_da_alloc(*), noauto_da_alloc
329 Many broken applications don't use fsync() when replacing existing
330 files via patterns such as fd = open("foo.new")/write(fd,..)/close(fd)/
331 rename("foo.new", "foo"), or worse yet, fd = open("foo",
332 O_TRUNC)/write(fd,..)/close(fd). If auto_da_alloc is enabled, ext4
333 will detect the replace-via-rename and replace-via-truncate patterns
334 and force that any delayed allocation blocks are allocated such that at
335 the next journal commit, in the default data=ordered mode, the data
336 blocks of the new file are forced to disk before the rename() operation
337 is committed. This provides roughly the same level of guarantees as
338 ext3, and avoids the "zero-length" problem that can happen when a
339 system crashes before the delayed allocation blocks are forced to disk.
342 Do not initialize any uninitialized inode table blocks in the
343 background. This feature may be used by installation CD's so that the
344 install process can complete as quickly as possible; the inode table
345 initialization process would then be deferred until the next time the
346 file system is unmounted.
349 The lazy itable init code will wait n times the number of milliseconds
350 it took to zero out the previous block group's inode table. This
351 minimizes the impact on the system performance while file system's
352 inode table is being initialized.
354 discard, nodiscard(*)
355 Controls whether ext4 should issue discard/TRIM commands to the
356 underlying block device when blocks are freed. This is useful for SSD
357 devices and sparse/thinly-provisioned LUNs, but it is off by default
358 until sufficient testing has been done.
361 Disables 32-bit UIDs and GIDs. This is for interoperability with
362 older kernels which only store and expect 16-bit values.
364 block_validity(*), noblock_validity
365 These options enable or disable the in-kernel facility for tracking
366 filesystem metadata blocks within internal data structures. This
367 allows multi- block allocator and other routines to notice bugs or
368 corrupted allocation bitmaps which cause blocks to be allocated which
369 overlap with filesystem metadata blocks.
371 dioread_lock, dioread_nolock
372 Controls whether or not ext4 should use the DIO read locking. If the
373 dioread_nolock option is specified ext4 will allocate uninitialized
374 extent before buffer write and convert the extent to initialized after
375 IO completes. This approach allows ext4 code to avoid using inode
376 mutex, which improves scalability on high speed storages. However this
377 does not work with data journaling and dioread_nolock option will be
378 ignored with kernel warning. Note that dioread_nolock code path is only
379 used for extent-based files. Because of the restrictions this options
380 comprises it is off by default (e.g. dioread_lock).
383 This limits the size of directories so that any attempt to expand them
384 beyond the specified limit in kilobytes will cause an ENOSPC error.
385 This is useful in memory constrained environments, where a very large
386 directory can cause severe performance problems or even provoke the Out
387 Of Memory killer. (For example, if there is only 512mb memory
388 available, a 176mb directory may seriously cramp the system's style.)
391 Enable 64-bit inode version support. This option is off by default.
394 Use direct access (no page cache). See
395 Documentation/filesystems/dax.txt. Note that this option is
396 incompatible with data=journal.
400 There are 3 different data modes:
404 In data=writeback mode, ext4 does not journal data at all. This mode provides
405 a similar level of journaling as that of XFS, JFS, and ReiserFS in its default
406 mode - metadata journaling. A crash+recovery can cause incorrect data to
407 appear in files which were written shortly before the crash. This mode will
408 typically provide the best ext4 performance.
412 In data=ordered mode, ext4 only officially journals metadata, but it logically
413 groups metadata information related to data changes with the data blocks into
414 a single unit called a transaction. When it's time to write the new metadata
415 out to disk, the associated data blocks are written first. In general, this
416 mode performs slightly slower than writeback but significantly faster than
421 data=journal mode provides full data and metadata journaling. All new data is
422 written to the journal first, and then to its final location. In the event of
423 a crash, the journal can be replayed, bringing both data and metadata into a
424 consistent state. This mode is the slowest except when data needs to be read
425 from and written to disk at the same time where it outperforms all others
426 modes. Enabling this mode will disable delayed allocation and O_DIRECT
432 Information about mounted ext4 file systems can be found in
433 /proc/fs/ext4. Each mounted filesystem will have a directory in
434 /proc/fs/ext4 based on its device name (i.e., /proc/fs/ext4/hdc or
435 /proc/fs/ext4/dm-0). The files in each per-device directory are shown
438 Files in /proc/fs/ext4/<devname>
441 details of multiblock allocator buddy cache of free blocks
446 Information about mounted ext4 file systems can be found in
447 /sys/fs/ext4. Each mounted filesystem will have a directory in
448 /sys/fs/ext4 based on its device name (i.e., /sys/fs/ext4/hdc or
449 /sys/fs/ext4/dm-0). The files in each per-device directory are shown
452 Files in /sys/fs/ext4/<devname>:
454 (see also Documentation/ABI/testing/sysfs-fs-ext4)
456 delayed_allocation_blocks
457 This file is read-only and shows the number of blocks that are dirty in
458 the page cache, but which do not have their location in the filesystem
462 Tuning parameter which (if non-zero) controls the goal inode used by
463 the inode allocator in preference to all other allocation heuristics.
464 This is intended for debugging use only, and should be 0 on production
468 Tuning parameter which controls the maximum number of inode table
469 blocks that ext4's inode table readahead algorithm will pre-read into
472 lifetime_write_kbytes
473 This file is read-only and shows the number of kilobytes of data that
474 have been written to this filesystem since it was created.
476 max_writeback_mb_bump
477 The maximum number of megabytes the writeback code will try to write
478 out before move on to another inode.
481 The multiblock allocator will round up allocation requests to a
482 multiple of this tuning parameter if the stripe size is not set in the
486 The maximum number of extents the multiblock allocator will search to
487 find the best extent.
490 The minimum number of extents the multiblock allocator will search to
491 find the best extent.
494 Tuning parameter which controls the minimum size for requests (as a
495 power of 2) where the buddy cache is used.
498 Controls whether the multiblock allocator should collect statistics,
499 which are shown during the unmount. 1 means to collect statistics, 0
500 means not to collect statistics.
503 Files which have fewer blocks than this tunable parameter will have
504 their blocks allocated out of a block group specific preallocation
505 pool, so that small files are packed closely together. Each large file
506 will have its blocks allocated out of its own unique preallocation
510 This file is read-only and shows the number of kilobytes of data that
511 have been written to this filesystem since it was mounted.
514 This is RW file and contains number of reserved clusters in the file
515 system which will be used in the specific situations to avoid costly
516 zeroout, unexpected ENOSPC, or possible data loss. The default is 2% or
517 4096 clusters, whichever is smaller and this can be changed however it
518 can never exceed number of clusters in the file system. If there is not
519 enough space for the reserved space when mounting the file mount will
525 There is some Ext4 specific functionality which can be accessed by applications
526 through the system call interfaces. The list of all Ext4 specific ioctls are
527 shown in the table below.
529 Table of Ext4 specific ioctls
532 Get additional attributes associated with inode. The ioctl argument is
533 an integer bitfield, with bit values described in ext4.h. This ioctl is
534 an alias for FS_IOC_GETFLAGS.
537 Set additional attributes associated with inode. The ioctl argument is
538 an integer bitfield, with bit values described in ext4.h. This ioctl is
539 an alias for FS_IOC_SETFLAGS.
541 EXT4_IOC_GETVERSION, EXT4_IOC_GETVERSION_OLD
542 Get the inode i_generation number stored for each inode. The
543 i_generation number is normally changed only when new inode is created
544 and it is particularly useful for network filesystems. The '_OLD'
545 version of this ioctl is an alias for FS_IOC_GETVERSION.
547 EXT4_IOC_SETVERSION, EXT4_IOC_SETVERSION_OLD
548 Set the inode i_generation number stored for each inode. The '_OLD'
549 version of this ioctl is an alias for FS_IOC_SETVERSION.
551 EXT4_IOC_GROUP_EXTEND
552 This ioctl has the same purpose as the resize mount option. It allows
553 to resize filesystem to the end of the last existing block group,
554 further resize has to be done with resize2fs, either online, or
555 offline. The argument points to the unsigned logn number representing
556 the filesystem new block count.
559 Move the block extents from orig_fd (the one this ioctl is pointing to)
560 to the donor_fd (the one specified in move_extent structure passed as
561 an argument to this ioctl). Then, exchange inode metadata between
562 orig_fd and donor_fd. This is especially useful for online
563 defragmentation, because the allocator has the opportunity to allocate
564 moved blocks better, ideally into one contiguous extent.
567 Add a new group descriptor to an existing or new group descriptor
568 block. The new group descriptor is described by ext4_new_group_input
569 structure, which is passed as an argument to this ioctl. This is
570 especially useful in conjunction with EXT4_IOC_GROUP_EXTEND, which
571 allows online resize of the filesystem to the end of the last existing
572 block group. Those two ioctls combined is used in userspace online
573 resize tool (e.g. resize2fs).
576 This ioctl operates on the filesystem itself. It converts (migrates)
577 ext3 indirect block mapped inode to ext4 extent mapped inode by walking
578 through indirect block mapping of the original inode and converting
579 contiguous block ranges into ext4 extents of the temporary inode. Then,
580 inodes are swapped. This ioctl might help, when migrating from ext3 to
581 ext4 filesystem, however suggestion is to create fresh ext4 filesystem
582 and copy data from the backup. Note, that filesystem has to support
583 extents for this ioctl to work.
585 EXT4_IOC_ALLOC_DA_BLKS
586 Force all of the delay allocated blocks to be allocated to preserve
587 application-expected ext3 behaviour. Note that this will also start
588 triggering a write of the data blocks, but this behaviour may change in
589 the future as it is not necessary and has been done this way only for
593 Resize the filesystem to a new size. The number of blocks of resized
594 filesystem is passed in via 64 bit integer argument. The kernel
595 allocates bitmaps and inode table, the userspace tool thus just passes
596 the new number of blocks.
599 Swap i_blocks and associated attributes (like i_blocks, i_size,
600 i_flags, ...) from the specified inode with inode EXT4_BOOT_LOADER_INO
601 (#5). This is typically used to store a boot loader in a secure part of
602 the filesystem, where it can't be changed by a normal user by accident.
603 The data blocks of the previous boot loader will be associated with the
609 kernel source: <file:fs/ext4/>
612 programs: http://e2fsprogs.sourceforge.net/
614 useful links: http://fedoraproject.org/wiki/ext3-devel
615 http://www.bullopensource.org/ext4/
616 http://ext4.wiki.kernel.org/index.php/Main_Page
617 http://fedoraproject.org/wiki/Features/Ext4