[mirror_ubuntu-bionic-kernel.git] / Documentation / filesystems / nilfs2.txt

NILFS2
------

NILFS2 is a log-structured file system (LFS) supporting continuous
snapshotting.  In addition to versioning capability of the entire file
system, users can even restore files mistakenly overwritten or
destroyed just a few seconds ago.  Since NILFS2 can keep consistency
like conventional LFS, it achieves quick recovery after system
crashes.

NILFS2 creates a number of checkpoints every few seconds or per
synchronous write basis (unless there is no change).  Users can select
significant versions among continuously created checkpoints, and can
change them into snapshots which will be preserved until they are
changed back to checkpoints.

There is no limit on the number of snapshots until the volume gets
full.  Each snapshot is mountable as a read-only file system
concurrently with its writable mount, and this feature is convenient
for online backup.

The userland tools are included in nilfs-utils package, which is
available from the following download page.  At least "mkfs.nilfs2",
"mount.nilfs2", "umount.nilfs2", and "nilfs_cleanerd" (so called
cleaner or garbage collector) are required.  Details on the tools are
described in the man pages included in the package.

Project web page:    http://www.nilfs.org/en/
Download page:       http://www.nilfs.org/en/download.html
Git tree web page:   http://www.nilfs.org/git/
List info:           http://vger.kernel.org/vger-lists.html#linux-nilfs

Caveats
=======

Features which NILFS2 does not support yet:

	- atime
	- extended attributes
	- POSIX ACLs
	- quotas
	- fsck
	- defragmentation

Mount options
=============

NILFS2 supports the following mount options:
(*) == default

barrier(*)		This enables/disables the use of write barriers.  This
nobarrier		requires an IO stack which can support barriers, and
			if nilfs gets an error on a barrier write, it will
			disable again with a warning.
errors=continue		Keep going on a filesystem error.
errors=remount-ro(*)	Remount the filesystem read-only on an error.
errors=panic		Panic and halt the machine if an error occurs.
cp=n			Specify the checkpoint-number of the snapshot to be
			mounted.  Checkpoints and snapshots are listed by lscp
			user command.  Only the checkpoints marked as snapshot
			are mountable with this option.  Snapshot is read-only,
			so a read-only mount option must be specified together.
order=relaxed(*)	Apply relaxed order semantics that allows modified data
			blocks to be written to disk without making a
			checkpoint if no metadata update is going.  This mode
			is equivalent to the ordered data mode of the ext3
			filesystem except for the updates on data blocks still
			conserve atomicity.  This will improve synchronous
			write performance for overwriting.
order=strict		Apply strict in-order semantics that preserves sequence
			of all file operations including overwriting of data
			blocks.  That means, it is guaranteed that no
			overtaking of events occurs in the recovered file
			system after a crash.
norecovery		Disable recovery of the filesystem on mount.
			This disables every write access on the device for
			read-only mounts or snapshots.  This option will fail
			for r/w mounts on an unclean volume.
discard			This enables/disables the use of discard/TRIM commands.
nodiscard(*)		The discard/TRIM commands are sent to the underlying
			block device when blocks are freed.  This is useful
			for SSD devices and sparse/thinly-provisioned LUNs.

NILFS2 usage
============

To use nilfs2 as a local file system, simply:

 # mkfs -t nilfs2 /dev/block_device
 # mount -t nilfs2 /dev/block_device /dir

This will also invoke the cleaner through the mount helper program
(mount.nilfs2).

Checkpoints and snapshots are managed by the following commands.
Their manpages are included in the nilfs-utils package above.

  lscp     list checkpoints or snapshots.
  mkcp     make a checkpoint or a snapshot.
  chcp     change an existing checkpoint to a snapshot or vice versa.
  rmcp     invalidate specified checkpoint(s).

To mount a snapshot,

 # mount -t nilfs2 -r -o cp=<cno> /dev/block_device /snap_dir

where <cno> is the checkpoint number of the snapshot.

To unmount the NILFS2 mount point or snapshot, simply:

 # umount /dir

Then, the cleaner daemon is automatically shut down by the umount
helper program (umount.nilfs2).

Disk format
===========

A nilfs2 volume is equally divided into a number of segments except
for the super block (SB) and segment #0.  A segment is the container
of logs.  Each log is composed of summary information blocks, payload
blocks, and an optional super root block (SR):

   ______________________________________________________
  | |SB| | Segment | Segment | Segment | ... | Segment | |
  |_|__|_|____0____|____1____|____2____|_____|____N____|_|
  0 +1K +4K       +8M       +16M      +24M  +(8MB x N)
       .             .            (Typical offsets for 4KB-block)
    .                  .
  .______________________.
  | log | log |... | log |
  |__1__|__2__|____|__m__|
        .       .
      .               .
    .                       .
  .______________________________.
  | Summary | Payload blocks  |SR|
  |_blocks__|_________________|__|

The payload blocks are organized per file, and each file consists of
data blocks and B-tree node blocks:

    |<---       File-A        --->|<---       File-B        --->|
   _______________________________________________________________
    | Data blocks | B-tree blocks | Data blocks | B-tree blocks | ...
   _|_____________|_______________|_____________|_______________|_


Since only the modified blocks are written in the log, it may have
files without data blocks or B-tree node blocks.

The organization of the blocks is recorded in the summary information
blocks, which contains a header structure (nilfs_segment_summary), per
file structures (nilfs_finfo), and per block structures (nilfs_binfo):

  _________________________________________________________________________
 | Summary | finfo | binfo | ... | binfo | finfo | binfo | ... | binfo |...
 |_blocks__|___A___|_(A,1)_|_____|(A,Na)_|___B___|_(B,1)_|_____|(B,Nb)_|___


The logs include regular files, directory files, symbolic link files
and several meta data files.  The mata data files are the files used
to maintain file system meta data.  The current version of NILFS2 uses
the following meta data files:

 1) Inode file (ifile)             -- Stores on-disk inodes
 2) Checkpoint file (cpfile)       -- Stores checkpoints
 3) Segment usage file (sufile)    -- Stores allocation state of segments
 4) Data address translation file  -- Maps virtual block numbers to usual
    (DAT)                             block numbers.  This file serves to
                                      make on-disk blocks relocatable.

The following figure shows a typical organization of the logs:

  _________________________________________________________________________
 | Summary | regular file | file  | ... | ifile | cpfile | sufile | DAT |SR|
 |_blocks__|_or_directory_|_______|_____|_______|________|________|_____|__|


To stride over segment boundaries, this sequence of files may be split
into multiple logs.  The sequence of logs that should be treated as
logically one log, is delimited with flags marked in the segment
summary.  The recovery code of nilfs2 looks this boundary information
to ensure atomicity of updates.

The super root block is inserted for every checkpoints.  It includes
three special inodes, inodes for the DAT, cpfile, and sufile.  Inodes
of regular files, directories, symlinks and other special files, are
included in the ifile.  The inode of ifile itself is included in the
corresponding checkpoint entry in the cpfile.  Thus, the hierarchy
among NILFS2 files can be depicted as follows:

  Super block (SB)
       |
       v
  Super root block (the latest cno=xx)
       |-- DAT
       |-- sufile
       `-- cpfile
              |-- ifile (cno=c1)
              |-- ifile (cno=c2) ---- file (ino=i1)
              :        :          |-- file (ino=i2)
              `-- ifile (cno=xx)  |-- file (ino=i3)
                                  :        :
                                  `-- file (ino=yy)
                                    ( regular file, directory, or symlink )

For detail on the format of each file, please see include/linux/nilfs2_fs.h.
Commit	Line	Data
962281a7 RK	1	NILFS2
	2	------
	3
	4	NILFS2 is a log-structured file system (LFS) supporting continuous
	5	snapshotting. In addition to versioning capability of the entire file
	6	system, users can even restore files mistakenly overwritten or
	7	destroyed just a few seconds ago. Since NILFS2 can keep consistency
	8	like conventional LFS, it achieves quick recovery after system
	9	crashes.
	10
	11	NILFS2 creates a number of checkpoints every few seconds or per
	12	synchronous write basis (unless there is no change). Users can select
	13	significant versions among continuously created checkpoints, and can
	14	change them into snapshots which will be preserved until they are
	15	changed back to checkpoints.
	16
	17	There is no limit on the number of snapshots until the volume gets
	18	full. Each snapshot is mountable as a read-only file system
	19	concurrently with its writable mount, and this feature is convenient
	20	for online backup.
	21
	22	The userland tools are included in nilfs-utils package, which is
	23	available from the following download page. At least "mkfs.nilfs2",
	24	"mount.nilfs2", "umount.nilfs2", and "nilfs_cleanerd" (so called
	25	cleaner or garbage collector) are required. Details on the tools are
	26	described in the man pages included in the package.
	27
	28	Project web page: http://www.nilfs.org/en/
	29	Download page: http://www.nilfs.org/en/download.html
	30	Git tree web page: http://www.nilfs.org/git/
6aff43f8	31	List info: http://vger.kernel.org/vger-lists.html#linux-nilfs
962281a7 RK	32
	33	Caveats
	34	=======
	35
	36	Features which NILFS2 does not support yet:
	37
	38	- atime
	39	- extended attributes
	40	- POSIX ACLs
	41	- quotas
fb6e7113	42	- fsck
962281a7 RK	43	- defragmentation
	44
	45	Mount options
	46	=============
	47
	48	NILFS2 supports the following mount options:
	49	(*) == default
	50
773bc4f3 RK	51	barrier(*) This enables/disables the use of write barriers. This
	52	nobarrier requires an IO stack which can support barriers, and
	53	if nilfs gets an error on a barrier write, it will
	54	disable again with a warning.
277a6a34 RK	55	errors=continue Keep going on a filesystem error.
277a6a34 RK	56	errors=remount-ro(*) Remount the filesystem read-only on an error.
962281a7 RK	57	errors=panic Panic and halt the machine if an error occurs.
	58	cp=n Specify the checkpoint-number of the snapshot to be
	59	mounted. Checkpoints and snapshots are listed by lscp
	60	user command. Only the checkpoints marked as snapshot
	61	are mountable with this option. Snapshot is read-only,
	62	so a read-only mount option must be specified together.
	63	order=relaxed(*) Apply relaxed order semantics that allows modified data
	64	blocks to be written to disk without making a
	65	checkpoint if no metadata update is going. This mode
	66	is equivalent to the ordered data mode of the ext3
	67	filesystem except for the updates on data blocks still
	68	conserve atomicity. This will improve synchronous
	69	write performance for overwriting.
	70	order=strict Apply strict in-order semantics that preserves sequence
	71	of all file operations including overwriting of data
	72	blocks. That means, it is guaranteed that no
	73	overtaking of events occurs in the recovered file
	74	system after a crash.
0234576d RK	75	norecovery Disable recovery of the filesystem on mount.
	76	This disables every write access on the device for
	77	read-only mounts or snapshots. This option will fail
	78	for r/w mounts on an unclean volume.
802d3177 RK	79	discard This enables/disables the use of discard/TRIM commands.
	80	nodiscard(*) The discard/TRIM commands are sent to the underlying
	81	block device when blocks are freed. This is useful
	82	for SSD devices and sparse/thinly-provisioned LUNs.
962281a7 RK	83
	84	NILFS2 usage
	85	============
	86
	87	To use nilfs2 as a local file system, simply:
	88
	89	# mkfs -t nilfs2 /dev/block_device
	90	# mount -t nilfs2 /dev/block_device /dir
	91
	92	This will also invoke the cleaner through the mount helper program
	93	(mount.nilfs2).
	94
	95	Checkpoints and snapshots are managed by the following commands.
	96	Their manpages are included in the nilfs-utils package above.
	97
	98	lscp list checkpoints or snapshots.
	99	mkcp make a checkpoint or a snapshot.
	100	chcp change an existing checkpoint to a snapshot or vice versa.
	101	rmcp invalidate specified checkpoint(s).
	102
	103	To mount a snapshot,
	104
	105	# mount -t nilfs2 -r -o cp=<cno> /dev/block_device /snap_dir
	106
	107	where <cno> is the checkpoint number of the snapshot.
	108
	109	To unmount the NILFS2 mount point or snapshot, simply:
	110
	111	# umount /dir
	112
	113	Then, the cleaner daemon is automatically shut down by the umount
	114	helper program (umount.nilfs2).
	115
	116	Disk format
	117	===========
	118
	119	A nilfs2 volume is equally divided into a number of segments except
	120	for the super block (SB) and segment #0. A segment is the container
	121	of logs. Each log is composed of summary information blocks, payload
	122	blocks, and an optional super root block (SR):
	123
	124	______________________________________________________
	125	\| \|SB\| \| Segment \| Segment \| Segment \| ... \| Segment \| \|
	126	\|_\|__\|_\|____0____\|____1____\|____2____\|_____\|____N____\|_\|
	127	0 +1K +4K +8M +16M +24M +(8MB x N)
	128	. . (Typical offsets for 4KB-block)
	129	. .
	130	.______________________.
	131	\| log \| log \|... \| log \|
	132	\|__1__\|__2__\|____\|__m__\|
	133	. .
	134	. .
	135	. .
	136	.______________________________.
	137	\| Summary \| Payload blocks \|SR\|
	138	\|_blocks__\|_________________\|__\|
	139
	140	The payload blocks are organized per file, and each file consists of
	141	data blocks and B-tree node blocks:
	142
	143	\|<--- File-A --->\|<--- File-B --->\|
	144	_______________________________________________________________
	145	\| Data blocks \| B-tree blocks \| Data blocks \| B-tree blocks \| ...
	146	_\|_____________\|_______________\|_____________\|_______________\|_
147
148
149	Since only the modified blocks are written in the log, it may have
150	files without data blocks or B-tree node blocks.
151
152	The organization of the blocks is recorded in the summary information
153	blocks, which contains a header structure (nilfs_segment_summary), per
154	file structures (nilfs_finfo), and per block structures (nilfs_binfo):
155
156	_________________________________________________________________________
157	\| Summary \| finfo \| binfo \| ... \| binfo \| finfo \| binfo \| ... \| binfo \|...
158	\|_blocks__\|___A___\|_(A,1)_\|_____\|(A,Na)_\|___B___\|_(B,1)_\|_____\|(B,Nb)_\|___
159
160
161	The logs include regular files, directory files, symbolic link files
162	and several meta data files. The mata data files are the files used
163	to maintain file system meta data. The current version of NILFS2 uses
164	the following meta data files:
165
166	1) Inode file (ifile) -- Stores on-disk inodes
167	2) Checkpoint file (cpfile) -- Stores checkpoints
168	3) Segment usage file (sufile) -- Stores allocation state of segments
169	4) Data address translation file -- Maps virtual block numbers to usual
170	(DAT) block numbers. This file serves to
171	make on-disk blocks relocatable.
962281a7 RK	172
	173	The following figure shows a typical organization of the logs:
	174
	175	_________________________________________________________________________
	176	\| Summary \| regular file \| file \| ... \| ifile \| cpfile \| sufile \| DAT \|SR\|
	177	\|_blocks__\|_or_directory_\|_______\|_____\|_______\|________\|________\|_____\|__\|
	178
	179
	180	To stride over segment boundaries, this sequence of files may be split
	181	into multiple logs. The sequence of logs that should be treated as
	182	logically one log, is delimited with flags marked in the segment
	183	summary. The recovery code of nilfs2 looks this boundary information
	184	to ensure atomicity of updates.
	185
	186	The super root block is inserted for every checkpoints. It includes
	187	three special inodes, inodes for the DAT, cpfile, and sufile. Inodes
	188	of regular files, directories, symlinks and other special files, are
	189	included in the ifile. The inode of ifile itself is included in the
	190	corresponding checkpoint entry in the cpfile. Thus, the hierarchy
	191	among NILFS2 files can be depicted as follows:
	192
	193	Super block (SB)
	194	\|
	195	v
	196	Super root block (the latest cno=xx)
	197	\|-- DAT
	198	\|-- sufile
	199	`-- cpfile
	200	\|-- ifile (cno=c1)
	201	\|-- ifile (cno=c2) ---- file (ino=i1)
	202	: : \|-- file (ino=i2)
	203	`-- ifile (cno=xx) \|-- file (ino=i3)
	204	: :
	205	`-- file (ino=yy)
	206	( regular file, directory, or symlink )
	207
	208	For detail on the format of each file, please see include/linux/nilfs2_fs.h.