4 This document describes a collection of device-mapper targets that
5 between them implement thin-provisioning and snapshots.
7 The main highlight of this implementation, compared to the previous
8 implementation of snapshots, is that it allows many virtual devices to
9 be stored on the same data volume. This simplifies administration and
10 allows the sharing of data between volumes, thus reducing disk usage.
12 Another significant feature is support for an arbitrary depth of
13 recursive snapshots (snapshots of snapshots of snapshots ...). The
14 previous implementation of snapshots did this by chaining together
15 lookup tables, and so performance was O(depth). This new
16 implementation uses a single data structure to avoid this degradation
17 with depth. Fragmentation may still be an issue, however, in some
20 Metadata is stored on a separate device from data, giving the
21 administrator some freedom, for example to:
23 - Improve metadata resilience by storing metadata on a mirrored volume
24 but data on a non-mirrored one.
26 - Improve performance by storing the metadata on SSD.
31 These targets are very much still in the EXPERIMENTAL state. Please
32 do not yet rely on them in production. But do experiment and offer us
33 feedback. Different use cases will have different performance
34 characteristics, for example due to fragmentation of the data volume.
36 If you find this software is not performing as expected please mail
37 dm-devel@redhat.com with details and we'll try our best to improve
40 Userspace tools for checking and repairing the metadata are under
46 This section describes some quick recipes for using thin provisioning.
47 They use the dmsetup program to control the device-mapper driver
48 directly. End users will be advised to use a higher-level volume
49 manager such as LVM2 once support has been added.
54 The pool device ties together the metadata volume and the data volume.
55 It maps I/O linearly to the data volume and updates the metadata via
58 - Function calls from the thin targets
60 - Device-mapper 'messages' from userspace which control the creation of new
61 virtual devices amongst other things.
63 Setting up a fresh pool device
64 ------------------------------
66 Setting up a pool device requires a valid metadata device, and a
67 data device. If you do not have an existing metadata device you can
68 make one by zeroing the first 4k to indicate empty metadata.
70 dd if=/dev/zero of=$metadata_dev bs=4096 count=1
72 The amount of metadata you need will vary according to how many blocks
73 are shared between thin devices (i.e. through snapshots). If you have
74 less sharing than average you'll need a larger-than-average metadata device.
76 As a guide, we suggest you calculate the number of bytes to use in the
77 metadata device as 48 * $data_dev_size / $data_block_size but round it up
78 to 2MB if the answer is smaller. If you're creating large numbers of
79 snapshots which are recording large amounts of change, you may find you
80 need to increase this.
82 The largest size supported is 16GB: If the device is larger,
83 a warning will be issued and the excess space will not be used.
85 Reloading a pool table
86 ----------------------
88 You may reload a pool's table, indeed this is how the pool is resized
89 if it runs out of space. (N.B. While specifying a different metadata
90 device when reloading is not forbidden at the moment, things will go
91 wrong if it does not route I/O to exactly the same on-disk location as
94 Using an existing pool device
95 -----------------------------
98 --table "0 20971520 thin-pool $metadata_dev $data_dev \
99 $data_block_size $low_water_mark"
101 $data_block_size gives the smallest unit of disk space that can be
102 allocated at a time expressed in units of 512-byte sectors.
103 $data_block_size must be between 128 (64KB) and 2097152 (1GB) and a
104 multiple of 128 (64KB). $data_block_size cannot be changed after the
105 thin-pool is created. People primarily interested in thin provisioning
106 may want to use a value such as 1024 (512KB). People doing lots of
107 snapshotting may want a smaller value such as 128 (64KB). If you are
108 not zeroing newly-allocated data, a larger $data_block_size in the
109 region of 256000 (128MB) is suggested.
111 $low_water_mark is expressed in blocks of size $data_block_size. If
112 free space on the data device drops below this level then a dm event
113 will be triggered which a userspace daemon should catch allowing it to
114 extend the pool device. Only one such event will be sent.
115 Resuming a device with a new table itself triggers an event so the
116 userspace daemon can use this to detect a situation where a new table
117 already exceeds the threshold.
119 A low water mark for the metadata device is maintained in the kernel and
120 will trigger a dm event if free space on the metadata device drops below
123 Updating on-disk metadata
124 -------------------------
126 On-disk metadata is committed every time a FLUSH or FUA bio is written.
127 If no such requests are made then commits will occur every second. This
128 means the thin-provisioning target behaves like a physical disk that has
129 a volatile write cache. If power is lost you may lose some recent
130 writes. The metadata should always be consistent in spite of any crash.
132 If data space is exhausted the pool will either error or queue IO
133 according to the configuration (see: error_if_no_space). If metadata
134 space is exhausted or a metadata operation fails: the pool will error IO
135 until the pool is taken offline and repair is performed to 1) fix any
136 potential inconsistencies and 2) clear the flag that imposes repair.
137 Once the pool's metadata device is repaired it may be resized, which
138 will allow the pool to return to normal operation. Note that if a pool
139 is flagged as needing repair, the pool's data and metadata devices
140 cannot be resized until repair is performed. It should also be noted
141 that when the pool's metadata space is exhausted the current metadata
142 transaction is aborted. Given that the pool will cache IO whose
143 completion may have already been acknowledged to upper IO layers
144 (e.g. filesystem) it is strongly suggested that consistency checks
145 (e.g. fsck) be performed on those layers when repair of the pool is
151 i) Creating a new thinly-provisioned volume.
153 To create a new thinly- provisioned volume you must send a message to an
154 active pool device, /dev/mapper/pool in this example.
156 dmsetup message /dev/mapper/pool 0 "create_thin 0"
158 Here '0' is an identifier for the volume, a 24-bit number. It's up
159 to the caller to allocate and manage these identifiers. If the
160 identifier is already in use, the message will fail with -EEXIST.
162 ii) Using a thinly-provisioned volume.
164 Thinly-provisioned volumes are activated using the 'thin' target:
166 dmsetup create thin --table "0 2097152 thin /dev/mapper/pool 0"
168 The last parameter is the identifier for the thinp device.
173 i) Creating an internal snapshot.
175 Snapshots are created with another message to the pool.
177 N.B. If the origin device that you wish to snapshot is active, you
178 must suspend it before creating the snapshot to avoid corruption.
179 This is NOT enforced at the moment, so please be careful!
181 dmsetup suspend /dev/mapper/thin
182 dmsetup message /dev/mapper/pool 0 "create_snap 1 0"
183 dmsetup resume /dev/mapper/thin
185 Here '1' is the identifier for the volume, a 24-bit number. '0' is the
186 identifier for the origin device.
188 ii) Using an internal snapshot.
190 Once created, the user doesn't have to worry about any connection
191 between the origin and the snapshot. Indeed the snapshot is no
192 different from any other thinly-provisioned device and can be
193 snapshotted itself via the same method. It's perfectly legal to
194 have only one of them active, and there's no ordering requirement on
195 activating or removing them both. (This differs from conventional
196 device-mapper snapshots.)
198 Activate it exactly the same way as any other thinly-provisioned volume:
200 dmsetup create snap --table "0 2097152 thin /dev/mapper/pool 1"
205 You can use an external _read only_ device as an origin for a
206 thinly-provisioned volume. Any read to an unprovisioned area of the
207 thin device will be passed through to the origin. Writes trigger
208 the allocation of new blocks as usual.
210 One use case for this is VM hosts that want to run guests on
211 thinly-provisioned volumes but have the base image on another device
212 (possibly shared between many VMs).
214 You must not write to the origin device if you use this technique!
215 Of course, you may write to the thin device and take internal snapshots
218 i) Creating a snapshot of an external device
220 This is the same as creating a thin device.
221 You don't mention the origin at this stage.
223 dmsetup message /dev/mapper/pool 0 "create_thin 0"
225 ii) Using a snapshot of an external device.
227 Append an extra parameter to the thin target specifying the origin:
229 dmsetup create snap --table "0 2097152 thin /dev/mapper/pool 0 /dev/image"
231 N.B. All descendants (internal snapshots) of this snapshot require the
232 same extra origin parameter.
237 All devices using a pool must be deactivated before the pool itself
252 thin-pool <metadata dev> <data dev> <data block size (sectors)> \
253 <low water mark (blocks)> [<number of feature args> [<arg>]*]
255 Optional feature arguments:
257 skip_block_zeroing: Skip the zeroing of newly-provisioned blocks.
259 ignore_discard: Disable discard support.
261 no_discard_passdown: Don't pass discards down to the underlying
262 data device, but just remove the mapping.
264 read_only: Don't allow any changes to be made to the pool
267 error_if_no_space: Error IOs, instead of queueing, if no space.
269 Data block size must be between 64KB (128 sectors) and 1GB
270 (2097152 sectors) inclusive.
275 <transaction id> <used metadata blocks>/<total metadata blocks>
276 <used data blocks>/<total data blocks> <held metadata root>
277 [no_]discard_passdown ro|rw
280 A 64-bit number used by userspace to help synchronise with metadata
281 from volume managers.
283 used data blocks / total data blocks
284 If the number of free blocks drops below the pool's low water mark a
285 dm event will be sent to userspace. This event is edge-triggered and
286 it will occur only once after each resume so volume manager writers
287 should register for the event and then check the target's status.
290 The location, in blocks, of the metadata root that has been
291 'held' for userspace read access. '-' indicates there is no
294 discard_passdown|no_discard_passdown
295 Whether or not discards are actually being passed down to the
296 underlying device. When this is enabled when loading the table,
297 it can get disabled if the underlying device doesn't support it.
299 ro|rw|out_of_data_space
300 If the pool encounters certain types of device failures it will
301 drop into a read-only metadata mode in which no changes to
302 the pool metadata (like allocating new blocks) are permitted.
304 In serious cases where even a read-only mode is deemed unsafe
305 no further I/O will be permitted and the status will just
306 contain the string 'Fail'. The userspace recovery tools
309 error_if_no_space|queue_if_no_space
310 If the pool runs out of data or metadata space, the pool will
311 either queue or error the IO destined to the data device. The
312 default is to queue the IO until more space is added or the
313 'no_space_timeout' expires. The 'no_space_timeout' dm-thin-pool
314 module parameter can be used to change this timeout -- it
315 defaults to 60 seconds but may be disabled using a value of 0.
318 A metadata operation has failed, resulting in the needs_check
319 flag being set in the metadata's superblock. The metadata
320 device must be deactivated and checked/repaired before the
321 thin-pool can be made fully operational again. '-' indicates
322 needs_check is not set.
328 Create a new thinly-provisioned device.
329 <dev id> is an arbitrary unique 24-bit identifier chosen by
332 create_snap <dev id> <origin id>
334 Create a new snapshot of another thinly-provisioned device.
335 <dev id> is an arbitrary unique 24-bit identifier chosen by
337 <origin id> is the identifier of the thinly-provisioned device
338 of which the new device will be a snapshot.
342 Deletes a thin device. Irreversible.
344 set_transaction_id <current id> <new id>
346 Userland volume managers, such as LVM, need a way to
347 synchronise their external metadata with the internal metadata of the
348 pool target. The thin-pool target offers to store an
349 arbitrary 64-bit transaction id and return it on the target's
350 status line. To avoid races you must provide what you think
351 the current transaction id is when you change it with this
352 compare-and-swap message.
354 reserve_metadata_snap
356 Reserve a copy of the data mapping btree for use by userland.
357 This allows userland to inspect the mappings as they were when
358 this message was executed. Use the pool's status command to
359 get the root block associated with the metadata snapshot.
361 release_metadata_snap
363 Release a previously reserved copy of the data mapping btree.
370 thin <pool dev> <dev id> [<external origin dev>]
373 the thin-pool device, e.g. /dev/mapper/my_pool or 253:0
376 the internal device identifier of the device to be
380 an optional block device outside the pool to be treated as a
381 read-only snapshot origin: reads to unprovisioned areas of the
382 thin target will be mapped to this device.
384 The pool doesn't store any size against the thin devices. If you
385 load a thin target that is smaller than you've been using previously,
386 then you'll have no access to blocks mapped beyond the end. If you
387 load a target that is bigger than before, then extra blocks will be
388 provisioned as and when needed.
392 <nr mapped sectors> <highest mapped sector>
394 If the pool has encountered device errors and failed, the status
395 will just contain the string 'Fail'. The userspace recovery
396 tools should then be used.