1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
354
355
356
357
358
359
360
361
362
363
364
365
366
367
368
369
370
371
372
373
374
375
376
377
378
379
380
381
382
383
384
385
386
387
388
389
390
391
392
393
394
395
396
397
398
399
400
401
402
403
404
405
406
407
408
409
410
411
412
413
414
415
416
417
418
419
420
421
422
423
424
425
426
427
428
429
430
431
432
433
434
435
436
437
438
439
440
441
442
443
444
445
446
447
448
449
450
451
452
453
454
455
456
457
458
459
460
461
462
463
464
465
466
467
468
469
|
#Block device translator
Block device translator (BD xlator) is a translator added to GlusterFS which provides block backend for GlusterFS. This replaces the existing bd_map translator in GlusterFS that provided similar but very limited functionality. GlusterFS expects the underlying brick to be formatted with a POSIX compatible file system. BD xlator changes that and allows for having bricks that are raw block devices like LVM which needn’t have any file systems on them. Hence with BD xlator, it becomes possible to build a GlusterFS volume comprising of bricks that are logical volumes (LV).
##bd
BD xlator maps underlying LVs to files and hence the LVs appear as files to GlusterFS clients. Though BD volume externally appears very similar to the usual Posix volume, not all operations are supported or possible for the files on a BD volume. Only those operations that make sense for a block device are supported and the exact semantics are described in subsequent sections.
While Posix volume takes a file system directory as brick, BD volume needs a volume group (VG) as brick. In the usual use case of BD volume, a file created on BD volume will result in an LV being created in the brick VG. In addition to a VG, BD volume also needs a file system directory that should be specified at the volume creation time. This directory is necessary for supporting the notion of directories and directory hierarchy for the BD volume. Metadata about LVs (size, mapping info) is stored in this directory.
BD xlator was mainly developed to use block devices directly as VM images when GlusterFS is used as storage for KVM virtualization. Some of the salient points of BD xlator are
* Since BD supports file level snapshots and clones by leveraging the snapshot and clone capabilities of LVM, it can be used to fully off-load snapshot and cloning operations from QEMU to the storage (GlusterFS) itself.
* BD understands dm-thin LVs and hence can support files that are backed by thinly provisioned LVs. This capability of BD xlator translates to having thinly provisioned raw VM images.
* BD enables thin LVs from a thin pool to be used from multiple nodes that have visibility to GlusterFS BD volume. Thus thin pool can be used as a VM image repository allowing access/visibility to it from multiple nodes.
* BD supports true zerofill by using BLKZEROOUT ioctl on underlying block devices. Thus BD allows SCSI WRITESAME to be used on underlying block device if the device supports it.
Though BD xlator is primarily intended to be used with block devices, it does provide full Posix xlator compatibility for files that are created on BD volume but are not backed by or mapped to a block device. Such files which don’t have a block device mapping exist on the Posix directory that is specified during BD volume creation. BD xlator is available from GlusterFS-3.5 release.
###Compiling BD translator
BD xlator needs lvm2 development library. –enable-bd-xlator option can be used with `./configure` script to explicitly enable BD translator. The following snippet from the output of configure script shows that BD xlator is enabled for compilation.
#####GlusterFS configure summary
…
Block Device xlator : yes
###Creating a BD volume
BD supports hosting of both linear LV and thin LV within the same volume. However seperate examples are provided below. As noted above, the prerequisite for a BD volume is VG which is created from a loop device here, but it can be any other device too.
* Creating BD volume with linear LV backend
* Create a loop device
[root@node ~]# dd if=/dev/zero of=bd-loop count=1024 bs=1M
[root@node ~]# losetup /dev/loop0 bd-loop
* Prepare a brick by creating a VG
[root@node ~]# pvcreate /dev/loop0
[root@node ~]# vgcreate bd-vg /dev/loop0
* Create the BD volume
* Create a POSIX directory first
[root@node ~]# mkdir /bd-meta
It is recommended that this directory is created on an LV in the brick VG itself so that both data and metadata live together on the same device.
* Create and mount the volume
[root@node ~]# gluster volume create bd node:/bd-meta?bd-vg force
The general syntax for specifying the brick is `host:/posix-dir?volume-group-name` where “?” is the separator.
[root@node ~]# gluster volume start bd
[root@node ~]# gluster volume info bd
Volume Name: bd
Type: Distribute
Volume ID: cb042d2a-f435-4669-b886-55f5927a4d7f
Status: Started
Xlator 1: BD
Capability 1: offload_copy
Capability 2: offload_snapshot
Number of Bricks: 1
Transport-type: tcp
Bricks:
Brick1: node:/bd-meta
Brick1 VG: bd-vg
[root@node ~]# mount -t glusterfs node:/bd /mnt
* Create a file that is backed by an LV
[root@node ~]# ls /mnt
[root@node ~]#
Since the volume is empty now, so is the underlying VG.
[root@node ~]# lvdisplay bd-vg
[root@node ~]#
Creating a file that is mapped to an LV is a 2 step operation. First the file should be created on the mount point and a specific extended attribute should be set to map the file to LV.
[root@node ~]# touch /mnt/lv
[root@node ~]# setfattr -n “user.glusterfs.bd” -v “lv” /mnt/lv
Now an LV got created in the VG brick and the file /mnt/lv maps to this LV. Any read/write to this file ends up as read/write to the underlying LV.
[root@node ~]# lvdisplay bd-vg
— Logical volume —
LV Path /dev/bd-vg/6ff0f25f-2776-4d19-adfb-df1a3cab8287
LV Name 6ff0f25f-2776-4d19-adfb-df1a3cab8287
VG Name bd-vg
LV UUID PjMPcc-RkD5-RADz-6ixG-UYsk-oclz-vL0nv6
LV Write Access read/write
LV Creation host, time node, 2013-11-26 16:15:45 +0530
LV Status available
open 0
LV Size 4.00 MiB
Current LE 1
Segments 1
Allocation inherit
Read ahead sectors 0
Block device 253:6
The file gets created with default LV size which is 1 LE which is 4MB in this case.
[root@node ~]# ls -lh /mnt/lv
-rw-r–r–. 1 root root 4.0M Nov 26 16:15 /mnt/lv
truncate can be used to set the required file size.
[root@node ~]# truncate /mnt/lv -s 256M
[root@node ~]# lvdisplay bd-vg
— Logical volume —
LV Path /dev/bd-vg/6ff0f25f-2776-4d19-adfb-df1a3cab8287
LV Name 6ff0f25f-2776-4d19-adfb-df1a3cab8287
VG Name bd-vg
LV UUID PjMPcc-RkD5-RADz-6ixG-UYsk-oclz-vL0nv6
LV Write Access read/write
LV Creation host, time node, 2013-11-26 16:15:45 +0530
LV Status available
# open 0
LV Size 256.00 MiB
Current LE 64
Segments 1
Allocation inherit
Read ahead sectors 0
Block device 253:6
[root@node ~]# ls -lh /mnt/lv
-rw-r–r–. 1 root root 256M Nov 26 16:15 /mnt/lv
currently LV size has been set to 256
The size of the file/LV can be specified during creation/mapping time itself like this:
setfattr -n “user.glusterfs.bd” -v “lv:256MB” /mnt/lv
2. Creating BD volume with thin LV backend
* Create a loop device
[root@node ~]# dd if=/dev/zero of=bd-loop-thin count=1024 bs=1M
[root@node ~]# losetup /dev/loop0 bd-loop-thin
* Prepare a brick by creating a VG and thin pool
[root@node ~]# pvcreate /dev/loop0
[root@node ~]# vgcreate bd-vg-thin /dev/loop0
* Create a thin pool
[root@node ~]# lvcreate –thin bd-vg-thin -L 1000M
Rounding up size to full physical extent 4.00 MiB
Logical volume “lvol0″ created
lvdisplay shows the thin pool
[root@node ~]# lvdisplay bd-vg-thin
— Logical volume —
LV Name lvol0
VG Name bd-vg-thin
LV UUID HVa3EM-IVMS-QG2g-oqU6-1UxC-RgqS-g8zhVn
LV Write Access read/write
LV Creation host, time node, 2013-11-26 16:39:06 +0530
LV Pool transaction ID 0
LV Pool metadata lvol0_tmeta
LV Pool data lvol0_tdata
LV Pool chunk size 64.00 KiB
LV Zero new blocks yes
LV Status available
# open 0
LV Size 1000.00 MiB
Allocated pool data 0.00%
Allocated metadata 0.88%
Current LE 250
Segments 1
Allocation inherit
Read ahead sectors auto
Block device 253:9
* Create the BD volume
* Create a POSIX directory first
[root@node ~]# mkdir /bd-meta-thin
* Create and mount the volume
[root@node ~]# gluster volume create bd-thin node:/bd-meta-thin?bd-vg-thin force
[root@node ~]# gluster volume start bd-thin
[root@node ~]# gluster volume info bd-thin
Volume Name: bd-thin
Type: Distribute
Volume ID: 27aa7eb0-4ffa-497e-b639-7cbda0128793
Status: Started
Xlator 1: BD
Capability 1: thin
Capability 2: offload_copy
Capability 3: offload_snapshot
Number of Bricks: 1
Transport-type: tcp
Bricks:
Brick1: node:/bd-meta-thin
Brick1 VG: bd-vg-thin
[root@node ~]# mount -t glusterfs node:/bd-thin /mnt
* Create a file that is backed by a thin LV
[root@node ~]# ls /mnt
[root@node ~]#
Creating a file that is mapped to a thin LV is a 2 step operation. First the file should be created on the mount point and a specific extended attribute should be set to map the file to a thin LV.
[root@node ~]# touch /mnt/thin-lv
[root@node ~]# setfattr -n “user.glusterfs.bd” -v “thin:256MB” /mnt/thin-lv
Now /mnt/thin-lv is a thin provisioned file that is backed by a thin LV and size has been set to 256.
[root@node ~]# lvdisplay bd-vg-thin
— Logical volume —
LV Name lvol0
VG Name bd-vg-thin
LV UUID HVa3EM-IVMS-QG2g-oqU6-1UxC-RgqS-g8zhVn
LV Write Access read/write
LV Creation host, time node, 2013-11-26 16:39:06 +0530
LV Pool transaction ID 1
LV Pool metadata lvol0_tmeta
LV Pool data lvol0_tdata
LV Pool chunk size 64.00 KiB
LV Zero new blocks yes
LV Status available
# open 0
LV Size 000.00 MiB
Allocated pool data 0.00%
Allocated metadata 0.98%
Current LE 250
Segments 1
Allocation inherit
Read ahead sectors auto
Block device 253:9
— Logical volume —
LV Path dev/bd-vg-thin/081b01d1-1436-4306-9baf-41c7bf5a2c73
LV Name 081b01d1-1436-4306-9baf-41c7bf5a2c73
VG Name bd-vg-thin
LV UUID coxpTY-2UZl-9293-8H2X-eAZn-wSp6-csZIeB
LV Write Access read/write
LV Creation host, time node, 2013-11-26 16:43:19 +0530
LV Pool name lvol0
LV Status available
# open 0
LV Size 256.00 MiB
Mapped size 0.00%
Current LE 64
Segments 1
Allocation inherit
Read ahead sectors auto
Block device 253:10
As can be seen from above, creation of a file resulted in creation of a thin LV in the brick.
###Improvisation on BD translator:
First version of BD xlator ( block backend) had few limitations such as
* Creation of directories not supported
* Supports only single brick
* Does not use extended attributes (and client gfid) like posix xlator
* Creation of special files (symbolic links, device nodes etc) not
supported
Basic limitation of not allowing directory creation was blocking
oVirt/VDSM to consume BD xlator as part of Gluster domain since VDSM
creates multi-level directories when GlusterFS is used as storage
backend for storing VM images.
To overcome these limitations a new BD xlator with following
improvements are implemented.
* New hybrid BD xlator that handles both regular files and block device
files
* The volume will have both POSIX and BD bricks. Regular files are
created on POSIX bricks, block devices are created on the BD brick (VG)
* BD xlator leverages exiting POSIX xlator for most POSIX calls and
hence sits above the POSIX xlator
* Block device file is differentiated from regular file by an extended
attribute
* The xattr 'user.glusterfs.bd' (BD_XATTR) plays a role in mapping a
posix file to Logical Volume (LV).
* When a client sends a request to set BD_XATTR on a posix file, a new
LV is created and mapped to posix file. So every block device will
have a representative file in POSIX brick with 'user.glusterfs.bd'
(BD_XATTR) set.
* Here after all operations on this file results in LV related
operations.
For example, opening a file that has BD_XATTR set results in opening
the LV block device, reading results in reading the corresponding LV
block device.
When BD xlator gets request to set BD_XATTR via setxattr call, it
creates a LV and information about this LV is placed in the xattr of the
posix file. xattr "user.glusterfs.bd" used to identify that posix file
is mapped to BD.
Usage:
Server side:
[root@host1 ~]# gluster volume create bdvol host1:/storage/vg1_info?vg1 host2:/storage/vg2_info?vg2
It creates a distributed gluster volume 'bdvol' with Volume Group vg1
using posix brick /storage/vg1_info in host1 and Volume Group vg2 using
/storage/vg2_info in host2.
[root@host1 ~]# gluster volume start bdvol
Client side:
[root@node ~]# mount -t glusterfs host1:/bdvol /media
[root@node ~]# touch /media/posix
It creates regular posix file 'posix' in either host1:/vg1 or host2:/vg2 brick
[root@node ~]# mkdir /media/image
[root@node ~]# touch /media/image/lv1
It also creates regular posix file 'lv1' in either host1:/vg1 or
host2:/vg2 brick
[root@node ~]# setfattr -n "user.glusterfs.bd" -v "lv" /media/image/lv1
[root@node ~]#
Above setxattr results in creating a new LV in corresponding brick's VG
and it sets 'user.glusterfs.bd' with value 'lv:<default-extent-size''
[root@node ~]# truncate -s5G /media/image/lv1
It results in resizig LV 'lv1'to 5G
New BD xlator code is placed in `xlators/storage/bd` directory.
Also add volume-uuid to the VG so that same VG cannot be used for other
bricks/volumes. After deleting a gluster volume, one has to manually
remove the associated tag using vgchange <vg-name> --deltag
`<trusted.glusterfs.volume-id:<volume-id>>`
#### Exposing volume capabilities
With multiple storage translators (posix and bd) being supported in GlusterFS, it becomes
necessary to know the volume type so that user can issue appropriate calls that are relevant
only to the a given volume type. Hence there needs to be a way to expose the type of
the storage translator of the volume to the user.
BD xlator is capable of providing server offloaded file copy, server/storage offloaded
zeroing of a file etc. This capabilities should be visible to the client/user, so that these
features can be exploited.
BD xlator exports capability information through gluster volume info (and --xml) output. For eg:
`snip of gluster volume info output for a BD based volume`
Xlator 1: BD
Capability 1: thin
`snip of gluster volume info --xml output for a BD based volume`
<xlators>
<xlator>
<name>BD</name>
<capabilities>
<capability>thin</capability>
</capabilities>
</xlator>
</xlators>
But this capability information should also exposed through some other means so that a host
which is not part of Gluster peer could also avail this capabilities.
* Type
BD translator supports both regular files and block device, i,e., one can create files on
GlusterFS volume backed by BD translator and this file could end up as regular posix file or
a logical volume (block device) based on the user''s choice. User can do a setxattr on the
created file to convert it to a logical volume.
Users of BD backed volume like QEMU would like to know that it is working with BD type of volume
so that it can issue an additional setxattr call after creating a VM image on GlusterFS backend.
This is necessary to ensure that the created VM image is backed by LV instead of file.
There are different ways to expose this information (BD type of volume) to user.
One way is to export it via a `getxattr` call. That said, When a client issues getxattr("volume_type")
on a root gfid, bd xlator will return 1 implying its BD xlator. But posix xlator will return ENODATA
and client code can interpret this as posix xlator. Also capability list can be returned via
getxattr("caps") for root gfid.
* Capabilities
BD xlator supports new features such as server offloaded file copy, thin provisioned VM images etc.
There is no standard way of exploiting these features from client side (such as syscall
to exploit server offloaded copy). So these features need to be exported to the client so that
they can be used. BD xlator latest version exports these capabilities information through
gluster volume info (and --xml) output. But if a client is not part of GlusterFS peer
it can''t run volume info command to get the list of capabilities of a given GlusterFS volume.
For example, GlusterFS block driver in qemu need to get the capability list so that these features are used.
Parts of this documentation were originally published here
#http://raobharata.wordpress.com/2013/11/27/glusterfs-block-device-translator/
|