Frequently asked questions -- Debian mdadm ========================================== Also see /usr/share/doc/mdadm/README.recipes.gz . The latest version of this FAQ is available here: http://anonscm.debian.org/gitweb/?p=pkg-mdadm/mdadm.git;a=blob_plain;f=debian/FAQ;hb=HEAD 0. What does MD stand for? ~~~~~~~~~~~~~~~~~~~~~~~~~~ MD is an abbreviation for "multiple device" (also often called "multi- disk"). The Linux MD implementation implements various strategies for combining multiple (typically but not necessarily physical) block devices into single logical ones. The most common use case is commonly known as "Software RAID". Linux supports RAID levels 1, 4, 5, 6 and 10 as well as the "pseudo" RAID level 0. In addition, the MD implementation covers linear and multipath configurations. Most people refer to MD as RAID. Since the original name of the RAID configuration software is "md"adm, I chose to use MD consistently instead. 1. How do I overwrite ("zero") the superblock? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ mdadm --zero-superblock /dev/sdXY Note that this is a destructive operation. It does not actually delete any data, but the device will have lost its "authority". You cannot assemble the array with it anymore and if you add the device to another array, the synchronisation process *will* *overwrite* all data on the device. Nevertheless, sometimes it is necessary to zero the superblock: - If you want ot re-use a device (e.g. a HDD or SSD) that has been part of an array (with an different superblock version and/or location) in another one. In this case you zero the superblock before you assemble the array or add the device to a new array. - If you are trying to prevent a device from being recognised as part of an array. Say for instance you are trying to change an array spanning sd[ab]1 to sd[bc]1 (maybe because sda is failing or too slow), then automatic (scan) assembly will still recognise sda1 as a valid device. You can limit the devices to scan with the DEVICE keyword in the configuration file, but this may not be what you want. Instead, zeroing the superblock will (permanently) prevent a device from being considered as part of an array. WARNING: Depending on which superblock version you use, it won't work to just overwrite the first few MiBs of the block device with 0x0 (e.g. via dd), since the superblock may be at other locations (especially the end of the device). Therefore always use mdadm --zero-superblock . 2. How do I change the preferred minor of an MD array (RAID)? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ See item 12 in /usr/share/doc/mdadm/README.recipes.gz and read the mdadm(8) manpage (search for 'preferred'). 3. How does mdadm determine which /dev/mdX or /dev/md/X to use? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ The logic used by mdadm to determine the device node name in the mdadm --examine output (which is used to generate mdadm.conf) depends on several factors. Here's how mdadm determines it: It first checks the superblock version of a given array (or each array in turn when iterating all of them). Run mdadm --detail /dev/mdX | sed -ne 's,.*Version : ,,p' to determine the superblock version of a running array, or mdadm --examine /dev/sdXY | sed -ne 's,.*Version : ,,p' to determine the superblock version from a component device of an array. Version 0 superblocks (00.90.XX) '''''''''''''''''''''''''''''''' You need to know the preferred minor number stored in the superblock, so run either of mdadm --detail /dev/mdX | sed -ne 's,.*Preferred Minor : ,,p' mdadm --examine /dev/sdXY | sed -ne 's,.*Preferred Minor : ,,p' Let's call the resulting number MINOR. Also see FAQ 2 further up. Given MINOR, mdadm will output /dev/md if the device node /dev/md exists. Otherwise, it outputs /dev/md/ Version 1 superblocks (01.XX.XX) '''''''''''''''''''''''''''''''' Version 1 superblocks actually seem to ignore preferred minors and instead use the value of the name field in the superblock. Unless specified explicitly during creation (-N|--name) the name is determined from the device name used, using the following regexp: 's,/dev/md/?(.*),$1,', thus: /dev/md0 -> 0 /dev/md/0 -> 0 /dev/md_d0 -> _d0 (d0 in later versions) /dev/md/d0 -> d0 /dev/md/name -> name (/dev/name does not seem to work) mdadm will append the name to '/dev/md/', so it will always output device names under the /dev/md/ directory. Newer versions can create a symlink from /dev/mdX. See the symlinks option in mdadm.con(5) and mdadm(8). If you want to change the name, you can do so during assembly: mdadm -A -U name -N newname /dev/mdX /dev/sd[abc]X I know this all sounds inconsistent and upstream has some work to do. We're on it. 4. Which RAID level should I use? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Many people seem to prefer RAID4/5/6 because it makes more efficient use of space. For example, if you have devices of size X, then in order to get 2X storage, you need 3 devices for RAID5, but 4 if you use RAID10 or RAID1+ (or RAID6). This gain in usable space comes at a price: performance; RAID1/10 can be up to four times faster than RAID4/5/6. At the same time, however, RAID4/5/6 provide somewhat better redundancy in the event of two failing devices. In a RAID10 configuration, if one device is already dead, the RAID can only survive if any of the two devices in the other RAID1 array fails, but not if the second device in the degraded RAID1 array fails (see next item, 4b). A RAID6 across four devices can cope with any two devices failing. However, RAID6 is noticeably slower than RAID5. RAID5 and RAID4 do not differ much, but can only handle single-device failures. If you can afford the extra devices (storage *is* cheap these days), I suggest RAID1/10 over RAID4/5/6. If you don't care about performance but need as much space as possible, go with RAID4/5/6, but make sure to have backups. Heck, make sure to have backups whatever you do. Let it be said, however, that I thoroughly regret putting my primary workstation on RAID5. Anything device-intensive brings the system to its knees; I will have to migrate to RAID10 at one point. Please also consult /usr/share/doc/mdadm/RAID5_versus_RAID10.txt.gz, https://en.wikipedia.org/wiki/Standard_RAID_levels and perhaps even https://en.wikipedia.org/wiki/Non-standard_RAID_levels . 4b. Can a 4-device RAID10 survive two device failures? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ I am assuming that you are talking about a setup with two copies of each block, so --layout=near2/far2/offset2: In two thirds of the cases, yes[0], and it does not matter which layout you use. When you assemble 4 devices into a RAID10, you essentially stripe a RAID0 across two RAID1, so the four devices A,B,C,D become two pairs: A,B and C,D. If A fails, the RAID10 can only survive if the second failing device is either C or D; if B fails, your array is dead. Thus, if you see a device failing, replace it as soon as possible! If you need to handle two failing devices out of a set of four, you have to use RAID6, or store more than two copies of each block (see the --layout option in the mdadm(8) manpage). See also question 18 further down. [0] It's actually (n-2)/(n-1), where n is the number of devices. I am not a mathematician, see http://aput.net/~jheiss/raid10/, which gives the chance of *failure* as 1/(n-1), so the chance of success is 1-1/(n-1), or (n-2)/(n-1), or 2/3 in the four device example. (Thanks to Per Olofsson for clarifying this in #493577). 5. How to convert RAID5 to RAID10? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ To convert 3 device RAID5 to RAID10, you need a spare device (either a hot spare, fourth device in the array, or a new one). Then you remove the spare and one of the three devices from the RAID5, create a degraded RAID10 across them, create the filesystem and copy the data (or do a raw copy), then add the other two devices to the new RAID10. However, mdadm cannot assemble a RAID10 with 50% missing devices the way you might like it: mdadm --create -l 10 -n4 -pn2 /dev/md1 /dev/sd[cd] missing missing For reasons that may be answered by question 20 further down, mdadm actually cares about the order of devices you give it. If you intersperse the "missing" keywords with the physical devices, it should work: mdadm --create -l 10 -n4 -pn2 /dev/md1 /dev/sdc missing /dev/sdd missing or even mdadm --create -l 10 -n4 -pn2 /dev/md1 missing /dev/sd[cd] missing Also see item (4b) further up, and this thread: http://thread.gmane.org/gmane.linux.raid/13469/focus=13472 6. What is the difference between RAID1+0 and RAID10? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ RAID1+0 is a form of RAID in which a RAID0 is striped across two RAID1 arrays. To assemble it, you create two RAID1 arrays and then create a RAID0 array with the two md arrays. The Linux kernel provides the RAID10 level to do pretty much exactly the same for you, but with greater flexibility (and somewhat improved performance). While RAID1+0 makes sense with 4 devices, RAID10 can be configured to work with only 3 devices. Also, RAID10 has a little less overhead than RAID1+0, which has data pass the md layer twice. I prefer RAID10 over RAID1+0. 6b. What's the difference between RAID1+0 and RAID0+1? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ In short: RAID1+0 concatenates two mirrored arrays while RAID0+1 mirrors two concatenated arrays. However, the two are also often switched. The linux MD driver supports RAID10, which is equivalent to the above RAID1+0 definition. RAID1+0/10 has a greater chance to survive two device failures, its performance suffers less when in degraded state, and it resyncs faster after replacing a failed device. See http://aput.net/~jheiss/raid10/ for more details. 7. Which RAID10 layout scheme should I use ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ RAID10 gives you the choice between three ways of laying out chunks on the devices: near, far and offset. The examples below explain the chunk distribution for each of these layouts with 2 copies per chunk, using either an even number of devices (fewer than 4) or an odd number (fewer than 5). For simplicity we assume that the chunk size matches the block size of the underlying devices and also the RAID10 device exported by the kernel (e.g. /dev/md/name). The chunk numbers map therefore directly to the block addresses in the exported RAID10 device. The decimal numbers below (0, 1, 2, …) are the RAID10 chunks. Due to the foregoing assumption they are also the block addresses in the exported RAID10 device. Identical numbers refer to copies of a chunk or block, but on different underlying devices. The hexadecimal numbers (0x00, 0x01, 0x02, …) refer to the block addresses in the underlying devices. "near" layout with 2 copies per chunk (--layout=n2): ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ The chunk copies are placed "as close to each other as possible". With an even number of devices, they lie at the same offset on the each device. It is a classic RAID1+0 setup, i.e. two groups of mirrored devices, with both forming a striped RAID0. device1 device2 device3 device4 device1 device2 device3 device4 device5 ─────── ─────── ─────── ─────── ─────── ─────── ─────── ─────── ─────── 0 0 1 1 0x00 0 0 1 1 2 2 2 3 3 0x01 2 3 3 4 4 ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋮ ⋮ ⋮ ⋮ ⋮ ⋮ ⋮ ⋮ ⋮ ⋮ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ 254 254 255 255 0x80 317 318 318 319 319 ╰──────┬──────╯ ╰──────┬──────╯ RAID1 RAID1 ╰──────────────┬──────────────╯ RAID0 "far" layout with 2 copies per chunk (--layout=f2): ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ The chunk copies are placed "as far from each other as possible". Here, a complete sequence of chunks is striped over all devices. Then a second sequence of chunks is placed next to them. More copies are added as the number 2 goes up. It is undesirable, however, to place copies of the same chunks on the same devices. That is prevented by a cyclic permutation of each such stripe. device1 device2 device3 device4 device1 device2 device3 device4 device5 ─────── ─────── ─────── ─────── ─────── ─────── ─────── ─────── ─────── 0 1 2 3 0x00 0 1 2 3 4 ╮ 4 5 6 7 0x01 5 6 7 8 9 ├ ▒ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ┆ ⋮ ⋮ ⋮ ⋮ ⋮ ⋮ ⋮ ⋮ ⋮ ⋮ ┆ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ┆ 252 253 254 255 0x40 315 316 317 318 319 ╯ 3 0 1 2 0x41 4 0 1 2 3 ╮ 7 4 5 6 0x42 9 5 6 7 8 ├ ▒ₚ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ┆ ⋮ ⋮ ⋮ ⋮ ⋮ ⋮ ⋮ ⋮ ⋮ ⋮ ┆ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ┆ 255 252 253 254 0x80 319 315 316 317 318 ╯ Each ▒ in the diagram represents a complete sequence of chunks. ▒ₚ is a cyclic permutation. A major advantage of the "far" layout is that sequential reads can be spread out over different devices, which makes the setup similar to RAID0 in terms of speed. For writes, there is a cost of seeking. They are substantially slower. "offset" layout with 2 copies per chunk (--layout=o2): ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Here, a number of consecutive chunks are bundled on each device during the striping operation. The number of consecutive chunks equals the number of devices. Next, a copy of the same chunks is striped in a different pattern. More copies are added as the number 2 goes up. A cyclic permutation in the pattern prevents copies of the same chunks landing on the same devices. device1 device2 device3 device4 device1 device2 device3 device4 device5 ─────── ─────── ─────── ─────── ─────── ─────── ─────── ─────── ─────── 0 1 2 3 0x00 0 1 2 3 4 ) AA 3 0 1 2 0x01 4 0 1 2 3 ) AAₚ 4 5 6 7 0x02 5 6 7 8 9 ) AB 7 4 5 6 0x03 9 5 6 7 8 ) ABₚ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ) ⋯ ⋮ ⋮ ⋮ ⋮ ⋮ ⋮ ⋮ ⋮ ⋮ ⋮ ⋮ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ⋯ ) ⋯ 251 252 253 254 0x79 314 315 316 317 318 ) EX 254 251 252 253 0x80 318 314 315 316 317 ) EXₚ With AA, AB, …, AZ, BA, … being the sets of consecutive chunks and AAₚ, ABₚ, …, AZₚ, BAₚ, … their cyclic permutations. The read characteristics are probably similar to the "far" layout when a suitably large chunk size is chosen, but with less seeking for writes. Upstream and the Debian maintainer do not understand all the nuances and implications. The "offset" layout was only added because the Common RAID Data Disk Format (DDF) supports it, and standard compliance is our goal. See the md(4) manpage for more details. 8. (One of) my RAID arrays is busy and cannot be stopped. What gives? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ It is perfectly normal for mdadm to report the array with the root filesystem to be busy on shutdown. The reason for this is that the root filesystem must be mounted to be able to stop the array (or otherwise /sbin/mdadm does not exist), but to stop the array, the root filesystem cannot be mounted. Catch 22. The kernel actually stops the array just before halting, so it's all well. If mdadm cannot stop other arrays on your system, check that these arrays aren't used anymore. Common causes for busy/locked arrays are: * The array contains a mounted filesystem (check the `mount' output) * The array is used as a swap backend (check /proc/swaps) * The array is used by the device-mapper (check with `dmsetup') * LVM * dm-crypt * EVMS * The array contains a swap partition used for suspend-to-ram (check /etc/initramfs-tools/conf.d/resume) * The array is used by a process (check with `lsof') 9. Should I use RAID0 (or linear)? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ No. Unless you know what you're doing and keep backups, or use it for data that can be lost. 9b. Why not? ~~~~~~~~~~~~ RAID0 has zero redundancy. If you stripe a RAID0 across X devices, you increase the likelyhood of complete loss of the filesystem by a factor of X. The same applies to LVM by the way (when LVs are placed over X PVs). If you want/must used LVM or RAID0, stripe it across RAID1 arrays (RAID10/RAID1+0, or LVM on RAID1), and keep backups! 10. Can I cancel a running array check (checkarray)? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ See the -x option in the `/usr/share/mdadm/checkarray --help` output. 11. mdadm warns about duplicate/similar superblocks; what gives? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ In certain configurations, especially if your last partition extends all the way to the end of the device, mdadm may display a warning like: mdadm: WARNING /dev/sdXY and /dev/sdX appear to have very similar superblocks. If they are really different, please --zero the superblock on one. If they are the same or overlap, please remove one from the DEVICE list in mdadm.conf. There are two ways to solve this: (a) recreate the arrays with version-1 superblocks, which is not always an option -- you cannot yet upgrade version-0 to version-1 superblocks for existing arrays. (b) instead of 'DEVICE partitions', list exactly those devices that are components of MD arrays on your system. So istead of: DEVICE partitions for example: DEVICE /dev/sd[ab]* /dev/sdc[123] 12. mdadm -E / mkconf report different arrays with the same device name / minor number. What gives? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ In almost all cases, mdadm updates the super-minor field in an array's superblock when assembling the array. It does *not* do this for RAID0 arrays. Thus, you may end up seeing something like this when you run mdadm -E or mkconf: ARRAY /dev/md0 level=raid0 num-devices=2 UUID=abcd... ARRAY /dev/md0 level=raid1 num-devices=2 UUID=dcba... Note how the two arrays have different UUIDs but both appear as /dev/md0. The solution in this case is to explicitly tell mdadm to update the superblock of the RAID0 array. Assuming that the RAID0 array in the above example should really be /dev/md1: mdadm --stop /dev/md1 mdadm --assemble --update=super-minor --uuid=abcd... /dev/md1 See question 2 of this FAQ, and also http://bugs.debian.org/386315 and recipe #12 in README.recipes . 13. Can a MD array be partitioned? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Since kernel 2.6.28, MD arrays can be partitioned like any other block device. Prior to 2.6.28, for a MD array to be able to hold partitions, it must be created as a "partitionable array", using the configuration auto=part on the command line or in the configuration file, or by using the standard naming scheme (md_d* or md/d*) for partitionable arrays: mdadm --create --auto=yes ... /dev/md_d0 ... # see mdadm(8) manpage about the values of the --auto keyword 14. When would I partition an array? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ This answer by Doug Ledford is shamelessly adapted from [0] (with permission): First, not all MD types make sense to be split up, e.g. multipath. For those types, when a device fails, the *entire* device is considered to have failed, but with different arrays you won't switch over to the next path until each MD array has attempted to access the bad path. This can have obvious bad consequences for certain array types that do automatic failover from one port to another (you can end up getting the array in a loop of switching ports repeatedly to satisfy the fact that one array failed over during a path down, then the path came back up, and another array stayed on the old path because it didn't send any commands during the path down time period). Second, convenience. Assume you have a 6 device RAID5 array. If a device fails and you are using a partitioned MD array, then all the partitions on the device will already be handled without using that device. No need to manually fail any still active array members from other arrays. Third, safety. Again with the RAID5 array. If you use multiple arrays on a single device, and that device fails, but it only failed on one array, then you now need to manually fail that device from the other arrays before shutting down or hot swapping the device. Generally speaking, that's not a big deal, but people do occasionally have fat finger syndrome and this is a good opportunity for someone to accidentally fail the wrong device, and when you then go to remove the device you create a two device failure instead of one and now you are in real trouble. Forth, to respond to what you wrote about independent of each other -- part of the reason why you partition. I would argue that's not true. If your goal is to salvage as much use from a failing device as possible, then OK. But, generally speaking, people that have something of value on their devices don't want to salvage any part of a failing device, they want that device gone and replaced immediately. There simply is little to no value in an already malfunctioning device. They're too cheap and the data stored on them too valuable to risk loosing something in an effort to further utilize broken hardware. This of course is written with the understanding that the latest MD RAID code will do read error rewrites to compensate for minor device issues, so anything that will throw a device out of an array is more than just a minor sector glitch. [0] http://thread.gmane.org/gmane.linux.raid/13594/focus=13597 15. How can I start a dirty degraded array? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ A degraded array (e.g. a RAID5 with only two devices) that has not been properly stopped cannot be assembled just like that; mdadm will refuse and complain about a "dirty degraded array", for good reasons. The solution might be to force-assemble it, and then to start it. Please see recipes 4 and 4b of /usr/share/doc/mdadm/README.recipes.gz and make sure you know what you're doing. 16. How can I influence the speed with which an array is resynchronised? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ For each array, the MD subsystem exports parameters governing the synchronisation speed via sysfs. The values are in kB/sec. /sys/block/mdX/md/sync_speed -- the current speed /sys/block/mdX/md/sync_speed_max -- the maximum speed /sys/block/mdX/md/sync_speed_min -- the guaranteed minimum speed 17. When I create a new array, why does it resynchronise at first? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ See the mdadm(8) manpage: When creating a RAID5 array, mdadm will automatically create a degraded array with an extra spare drive. This is because building the spare into a degraded array is in general faster than resyncing the parity on a non-degraded, but not clean, array. This feature can be over-ridden with the --force option. This also applies to RAID levels 4 and 6. It does not make much sense for RAID levels 1 and 10 and can thus be overridden with the --force and --assume-clean options, but it is not recommended. Read the manpage. 18. How many failed devics can a RAID10 handle? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ (see also question 4b) The following table shows how many devices you can lose and still have an operational array. In some cases, you *can* lose more than the given number of devices, but there is no guarantee that the array survives. Thus, the following is the guaranteed number of failed devices a RAID10 array survives and the maximum number of failed devices the array can (but is not guaranteed to) handle, given the number of devices used and the number of data block copies. Note that 2 copies means original + 1 copy. Thus, if you only have one copy (the original), you cannot handle any failures. 1 2 3 4 (# of copies) 1 0/0 0/0 0/0 0/0 2 0/0 1/1 1/1 1/1 3 0/0 1/1 2/2 2/2 4 0/0 1/2 2/2 3/3 5 0/0 1/2 2/2 3/3 6 0/0 1/3 2/3 3/3 7 0/0 1/3 2/3 3/3 8 0/0 1/4 2/3 3/4 (# of devices) Note: I have not really verified the above information. Please don't count on it. If a device fails, replace it as soon as possible. Corrections welcome. 19. What should I do if a device fails? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Replace it as soon as possible. In case of physical devices with no hot-swap capabilities, for example via: mdadm --remove /dev/md0 /dev/sda1 poweroff mdadm --add /dev/md0 /dev/sda1 20. So how do I find out which other device(s) can fail without killing the array? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Did you read the previous question and its answer? For cases when you have two copies of each block, the question is easily answered by looking at the output of /proc/mdstat. For instance on a 4 device array: md3 : active raid10 sdg7[3] sde7[0] sdh7[2] sdf7[1] you know that sde7/sdf7 form one pair and sdg7/sgh7 the other. If sdh now fails, this will become md3 : active raid10 sdg7[3] sde7[0] sdh7[4](F) sdf7[1] So now the second pair is degraded; the array could take another failure in the first pair, but if sdg now also fails, you're history. Now go and read question 19. For cases with more copies per block, it becomes more complicated. Let's think of a 7 device array with three copies: md5 : active raid10 sdg7[6] sde7[4] sdb7[5] sdf7[2] sda7[3] sdc7[1] sdd7[0] Each mirror now has 7/3 = 2.33 devices to it, so in order to determine groups, you need to round up. Note how the devices are arranged in decreasing order of their indices (the number in brackes in /proc/mdstat): device: -sdd7- -sdc7- -sdf7- -sda7- -sde7- -sdb7- -sdg7- group: [ one ][ two ][ three ] Basically this means that after two devices failed, you need to make sure that the third failed device doesn't destroy all copies of any given block. And that's not always easy as it depends on the layout chosen: whether the blocks are near (same offset within each group), far (spread apart in a way to maximise the mean distance), or offset (offset by size/n within each block). I'll leave it up to you to figure things out. Now go read question 19. 21. Why does the kernel speak of 'resync' when using checkarray? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Please see README.checkarray and http://thread.gmane.org/gmane.linux.raid/11864 . In short: it's a bug. checkarray is actually not a resync, but the kernel does not distinguish between them. 22. Can I prioritise the sync process and sync certain arrays before others? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Upon start, md will resynchronise any unclean arrays, starting in somewhat random order. Sometimes it's desirable to sync e.g. /dev/md3 first (because it's the most important), but while /dev/md1 is synchronising, /dev/md3 will be DELAYED (see /proc/mdstat; only if they share the same physical components. It is possible to delay the synchronisation via /sys: echo idle >/sys/block/md1/md/sync_action This will cause md1 to go idle and MD to synchronise md3 (or whatever is queued next; repeat the above for other devices if necessary). MD will also realise that md1 is still not in sync and queue it for resynchronisation, so it will sync automatically when its turn has come. 23. mdadm's init script fails because it cannot find any arrays. What gives? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ This does not happen anymore, if no arrays present in config file, no arrays will be started. 24. What happened to mdrun? How do I replace it? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ mdrun used to be the sledgehammer approach to assembling arrays. It has accumulated several problems over the years (e.g. Debian bug #354705) and thus has been deprecated and removed with the 2.6.7-2 version of this package. If you are still using mdrun, please ensure that you have a valid /etc/mdadm/mdadm.conf file (run /usr/share/mdadm/mkconf --generate to get one), and run mdadm --assemble --scan --auto=yes instead of mdrun. 25. Why are my arrays marked auto-read-only in /proc/mdstat? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Arrays are kept read-only until the first write occurs. This allows md to skip lengthy resynchronisation for arrays that have not been properly shut down, but which also not have changed. 26. Why doesn't mdadm find arrays specified in the config file and causes the boot to fail? ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ My boot process dies at an early stage and drops me into the busybox shell. The last relevant output seems to be from mdadm and is something like "/dev/md2 does not exist" or "No devices listed in conf file found" Why does mdadm break my system? Short answer: It doesn't, the underlying devices aren't yet available yet when mdadm runs during the early boot process. Long answer: It doesn't, but the drivers of those devices incorrectly communicate to the kernel that the devices are ready, when in fact they are not. I consider this a bug in those drivers. Please consider reporting it. Workaround: there is nothing mdadm can or will do against this. Fortunately though, initramfs provides a method, documented at http://wiki.debian.org/InitramfsDebug. Please append rootdelay=10 (which sets a delay of 10 seconds before trying to mount the root filesystem) to the kernel command line and try if the boot now works. -- martin f. krafft Wed, 13 May 2009 09:59:53 +0200