1 Tools that manage md devices can be found at
2 http://www.<country>.kernel.org/pub/linux/utils/raid/....
5 Boot time assembly of RAID arrays
6 ---------------------------------
8 You can boot with your md device with the following kernel command
11 for old raid arrays without persistent superblocks:
12 md=<md device no.>,<raid level>,<chunk size factor>,<fault level>,dev0,dev1,...,devn
14 for raid arrays with persistent superblocks
15 md=<md device no.>,dev0,dev1,...,devn
16 or, to assemble a partitionable array:
17 md=d<md device no.>,dev0,dev1,...,devn
19 md device no. = the number of the md device ...
26 raid level = -1 linear mode
28 other modes are only supported with persistent super blocks
30 chunk size factor = (raid-0 and raid-1 only)
31 Set the chunk size as 4k << n.
33 fault level = totally ignored
35 dev0-devn: e.g. /dev/hda1,/dev/hdc1,/dev/sda1,/dev/sdb1
37 A possible loadlin line (Harald Hoyer <HarryH@Royal.Net>) looks like this:
39 e:\loadlin\loadlin e:\zimage root=/dev/md0 md=0,0,4,0,/dev/hdb2,/dev/hdc3 ro
42 Boot time autodetection of RAID arrays
43 --------------------------------------
45 When md is compiled into the kernel (not as module), partitions of
46 type 0xfd are scanned and automatically assembled into RAID arrays.
47 This autodetection may be suppressed with the kernel parameter
48 "raid=noautodetect". As of kernel 2.6.9, only drives with a type 0
49 superblock can be autodetected and run at boot time.
51 The kernel parameter "raid=partitionable" (or "raid=part") means
52 that all auto-detected arrays are assembled as partitionable.
54 Boot time assembly of degraded/dirty arrays
55 -------------------------------------------
57 If a raid5 or raid6 array is both dirty and degraded, it could have
58 undetectable data corruption. This is because the fact that it is
59 'dirty' means that the parity cannot be trusted, and the fact that it
60 is degraded means that some datablocks are missing and cannot reliably
61 be reconstructed (due to no parity).
63 For this reason, md will normally refuse to start such an array. This
64 requires the sysadmin to take action to explicitly start the array
65 desipite possible corruption. This is normally done with
66 mdadm --assemble --force ....
68 This option is not really available if the array has the root
69 filesystem on it. In order to support this booting from such an
70 array, md supports a module parameter "start_dirty_degraded" which,
71 when set to 1, bypassed the checks and will allows dirty degraded
74 So, to boot with a root filesystem of a dirty degraded raid[56], use
76 md-mod.start_dirty_degraded=1
82 The md driver can support a variety of different superblock formats.
83 Currently, it supports superblock formats "0.90.0" and the "md-1" format
84 introduced in the 2.5 development series.
86 The kernel will autodetect which format superblock is being used.
88 Superblock format '0' is treated differently to others for legacy
89 reasons - it is the original superblock format.
92 General Rules - apply for all superblock formats
93 ------------------------------------------------
95 An array is 'created' by writing appropriate superblocks to all
98 It is 'assembled' by associating each of these devices with an
99 particular md virtual device. Once it is completely assembled, it can
102 An array should be created by a user-space tool. This will write
103 superblocks to all devices. It will usually mark the array as
104 'unclean', or with some devices missing so that the kernel md driver
105 can create appropriate redundancy (copying in raid1, parity
106 calculation in raid4/5).
108 When an array is assembled, it is first initialized with the
109 SET_ARRAY_INFO ioctl. This contains, in particular, a major and minor
110 version number. The major version number selects which superblock
111 format is to be used. The minor number might be used to tune handling
112 of the format, such as suggesting where on each device to look for the
115 Then each device is added using the ADD_NEW_DISK ioctl. This
116 provides, in particular, a major and minor number identifying the
119 The array is started with the RUN_ARRAY ioctl.
121 Once started, new devices can be added. They should have an
122 appropriate superblock written to them, and then passed be in with
125 Devices that have failed or are not yet active can be detached from an
126 array using HOT_REMOVE_DISK.
129 Specific Rules that apply to format-0 super block arrays, and
130 arrays with no superblock (non-persistent).
131 -------------------------------------------------------------
133 An array can be 'created' by describing the array (level, chunksize
134 etc) in a SET_ARRAY_INFO ioctl. This must has major_version==0 and
137 Then uninitialized devices can be added with ADD_NEW_DISK. The
138 structure passed to ADD_NEW_DISK must specify the state of the device
139 and it's role in the array.
141 Once started with RUN_ARRAY, uninitialized spares can be added with
148 md devices appear in sysfs (/sys) as regular block devices,
152 Each 'md' device will contain a subdirectory called 'md' which
153 contains further md-specific information about the device.
155 All md devices contain:
157 a text file indicating the 'raid level'. e.g. raid0, raid1,
158 raid5, linear, multipath, faulty.
159 If no raid level has been set yet (array is still being
160 assembled), the value will reflect whatever has been written
161 to it, which may be a name like the above, or may be a number
162 such as '0', '5', etc.
165 a text file with a simple number indicating the number of devices
166 in a fully functional array. If this is not yet known, the file
167 will be empty. If an array is being resized (not currently
168 possible) this will contain the larger of the old and new sizes.
169 Some raid level (RAID1) allow this value to be set while the
170 array is active. This will reconfigure the array. Otherwise
171 it can only be set while assembling an array.
174 This is the size if bytes for 'chunks' and is only relevant to
175 raid levels that involve striping (1,4,5,6,10). The address space
176 of the array is conceptually divided into chunks and consecutive
177 chunks are striped onto neighbouring devices.
178 The size should be atleast PAGE_SIZE (4k) and should be a power
179 of 2. This can only be set while assembling an array
182 For arrays with data redundancy (i.e. not raid0, linear, faulty,
183 multipath), all components must be the same size - or at least
184 there must a size that they all provide space for. This is a key
185 part or the geometry of the array. It is measured in sectors
186 and can be read from here. Writing to this value may resize
187 the array if the personality supports it (raid1, raid5, raid6),
188 and if the component drives are large enough.
191 This indicates the format that is being used to record metadata
192 about the array. It can be 0.90 (traditional format), 1.0, 1.1,
193 1.2 (newer format in varying locations) or "none" indicating that
194 the kernel isn't managing metadata at all.
197 The "layout" for the array for the particular level. This is
198 simply a number that is interpretted differently by different
199 levels. It can be written while assembling an array.
202 The point at which resync should start. If no resync is needed,
203 this will be a very large number. At array creation it will
204 default to 0, though starting the array as 'clean' will
208 This file can be written but not read. The value written should
209 be a block device number as major:minor. e.g. 8:0
210 This will cause that device to be attached to the array, if it is
211 available. It will then appear at md/dev-XXX (depending on the
212 name of the device) and further configuration is then possible.
215 When an md array has seen no write requests for a certain period
216 of time, it will be marked as 'clean'. When another write
217 request arrive, the array is marked as 'dirty' before the write
218 commenses. This is known as 'safe_mode'.
219 The 'certain period' is controlled by this file which stores the
220 period as a number of seconds. The default is 200msec (0.200).
221 Writing a value of 0 disables safemode.
224 This file contains a single word which describes the current
225 state of the array. In many cases, the state can be set by
226 writing the word for the desired state, however some states
227 cannot be explicitly set, and some transitions are not allowed.
230 No devices, no size, no level
231 Writing is equivalent to STOP_ARRAY ioctl
233 May have some settings, but array is not active
234 all IO results in error
235 When written, doesn't tear down array, but just stops it
236 suspended (not supported yet)
237 All IO requests will block. The array can be reconfigured.
238 Writing this, if accepted, will block until array is quiessent
240 no resync can happen. no superblocks get written.
243 like readonly, but behaves like 'clean' on a write request.
245 clean - no pending writes, but otherwise active.
246 When written to inactive array, starts without resync
247 If a write request arrives then
248 if metadata is known, mark 'dirty' and switch to 'active'.
249 if not known, block and switch to write-pending
250 If written to an active array that has pending writes, then fails.
252 fully active: IO and resync can be happening.
253 When written to inactive array, starts with resync
256 clean, but writes are blocked waiting for 'active' to be written.
259 like active, but no writes have been seen for a while (safe_mode_delay).
264 This are similar to /proc/sys/dev/raid/speed_limit_{min,max}
265 however they only apply to the particular array.
266 If no value has been written to these, of if the word 'system'
267 is written, then the system-wide value is used. If a value,
268 in kibibytes-per-second is written, then it is used.
269 When the files are read, they show the currently active value
270 followed by "(local)" or "(system)" depending on whether it is
271 a locally set or system-wide value.
274 This shows the number of sectors that have been completed of
275 whatever the current sync_action is, followed by the number of
276 sectors in total that could need to be processed. The two
277 numbers are separated by a '/' thus effectively showing one
278 value, a fraction of the process that is complete.
281 This shows the current actual speed, in K/sec, of the current
282 sync_action. It is averaged over the last 30 seconds.
285 As component devices are added to an md array, they appear in the 'md'
286 directory as new directories named
288 where XXX is a name that the kernel knows for the device, e.g. hdb1.
289 Each directory contains:
292 a symlink to the block device in /sys/block, e.g.
293 /sys/block/md0/md/dev-hdb1/block -> ../../../../block/hdb/hdb1
296 A file containing an image of the superblock read from, or
297 written to, that device.
300 A file recording the current state of the device in the array
301 which can be a comma separated list of
302 faulty - device has been kicked from active use due to
304 in_sync - device is a fully in-sync member of the array
305 writemostly - device will only be subject to read
306 requests if there are no other options.
307 This applies only to raid1 arrays.
308 spare - device is working, but not a full member.
309 This includes spares that are in the process
310 of being recoverred to
311 This list make grow in future.
312 This can be written to.
313 Writing "faulty" simulates a failure on the device.
314 Writing "remove" removes the device from the array.
315 Writing "writemostly" sets the writemostly flag.
316 Writing "-writemostly" clears the writemostly flag.
319 An approximate count of read errors that have been detected on
320 this device but have not caused the device to be evicted from
321 the array (either because they were corrected or because they
322 happened while the array was read-only). When using version-1
323 metadata, this value persists across restarts of the array.
325 This value can be written while assembling an array thus
326 providing an ongoing count for arrays with metadata managed by
330 This gives the role that the device has in the array. It will
331 either be 'none' if the device is not active in the array
332 (i.e. is a spare or has failed) or an integer less than the
333 'raid_disks' number for the array indicating which possition
334 it currently fills. This can only be set while assembling an
335 array. A device for which this is set is assumed to be working.
338 This gives the location in the device (in sectors from the
339 start) where data from the array will be stored. Any part of
340 the device before this offset us not touched, unless it is
341 used for storing metadata (Formats 1.1 and 1.2).
344 The amount of the device, after the offset, that can be used
345 for storage of data. This will normally be the same as the
346 component_size. This can be written while assembling an
347 array. If a value less than the current component_size is
348 written, component_size will be reduced to this value.
351 An active md device will also contain and entry for each active device
352 in the array. These are named
356 where 'NN' is the possition in the array, starting from 0.
357 So for a 3 drive array there will be rd0, rd1, rd2.
358 These are symbolic links to the appropriate 'dev-XXX' entry.
360 cat /sys/block/md*/md/rd*/state
361 will show 'in_sync' on every line.
365 Active md devices for levels that support data redundancy (1,4,5,6)
369 a text file that can be used to monitor and control the rebuild
370 process. It contains one word which can be one of:
371 resync - redundancy is being recalculated after unclean
373 recover - a hot spare is being built to replace a
374 failed/missing device
375 idle - nothing is happening
376 check - A full check of redundancy was requested and is
377 happening. This reads all block and checks
378 them. A repair may also happen for some raid
380 repair - A full check and repair is happening. This is
381 similar to 'resync', but was requested by the
382 user, and the write-intent bitmap is NOT used to
383 optimise the process.
385 This file is writable, and each of the strings that could be
386 read are meaningful for writing.
388 'idle' will stop an active resync/recovery etc. There is no
389 guarantee that another resync/recovery may not be automatically
390 started again, though some event will be needed to trigger
392 'resync' or 'recovery' can be used to restart the
393 corresponding operation if it was stopped with 'idle'.
394 'check' and 'repair' will start the appropriate process
395 providing the current state is 'idle'.
398 When performing 'check' and 'repair', and possibly when
399 performing 'resync', md will count the number of errors that are
400 found. The count in 'mismatch_cnt' is the number of sectors
401 that were re-written, or (for 'check') would have been
402 re-written. As most raid levels work in units of pages rather
403 than sectors, this my be larger than the number of actual errors
404 by a factor of the number of sectors in a page.
407 If the array has a write-intent bitmap, then writing to this
408 attribute can set bits in the bitmap, indicating that a resync
409 would need to check the corresponding blocks. Either individual
410 numbers or start-end pairs can be written. Multiple numbers
411 can be separated by a space.
412 Note that the numbers are 'bit' numbers, not 'block' numbers.
413 They should be scaled by the bitmap_chunksize.
415 Each active md device may also have attributes specific to the
416 personality module that manages it.
417 These are specific to the implementation of the module and could
418 change substantially if the implementation changes.
420 These currently include
422 stripe_cache_size (currently raid5 only)
423 number of entries in the stripe cache. This is writable, but
424 there are upper and lower limits (32768, 16). Default is 128.
425 strip_cache_active (currently raid5 only)
426 number of active entries in the stripe cache