3 ==========================
4 Short users guide for SLUB
5 ==========================
7 The basic philosophy of SLUB is very different from SLAB. SLAB
8 requires rebuilding the kernel to activate debug options for all
9 slab caches. SLUB always includes full debugging but it is off by default.
10 SLUB can enable debugging only for selected slabs in order to avoid
11 an impact on overall system performance which may make a bug more
14 In order to switch debugging on one can add an option ``slub_debug``
15 to the kernel command line. That will enable full debugging for
18 Typically one would then use the ``slabinfo`` command to get statistical
19 data and perform operation on the slabs. By default ``slabinfo`` only lists
20 slabs that have data in them. See "slabinfo -h" for more options when
21 running the command. ``slabinfo`` can be compiled with
24 gcc -o slabinfo tools/vm/slabinfo.c
26 Some of the modes of operation of ``slabinfo`` require that slub debugging
27 be enabled on the command line. F.e. no tracking information will be
28 available without debugging on and validation can only partially
29 be performed if debugging was not switched on.
31 Some more sophisticated uses of slub_debug:
32 -------------------------------------------
34 Parameters may be given to ``slub_debug``. If none is specified then full
35 debugging is enabled. Format:
37 slub_debug=<Debug-Options>
38 Enable options for all slabs
40 slub_debug=<Debug-Options>,<slab name1>,<slab name2>,...
41 Enable options only for select slabs (no spaces
44 Possible debug options are::
46 F Sanity checks on (enables SLAB_DEBUG_CONSISTENCY_CHECKS
47 Sorry SLAB legacy issues)
49 P Poisoning (object and padding)
50 U User tracking (free and alloc)
51 T Trace (please only use on single slabs)
52 A Toggle failslab filter mark for the cache
53 O Switch debugging off for caches that would have
54 caused higher minimum slab orders
55 - Switch all debugging off (useful if the kernel is
56 configured with CONFIG_SLUB_DEBUG_ON)
58 F.e. in order to boot just with sanity checks and red zoning one would specify::
62 Trying to find an issue in the dentry cache? Try::
66 to only enable debugging on the dentry cache. You may use an asterisk at the
67 end of the slab name, in order to cover all slabs with the same prefix. For
68 example, here's how you can poison the dentry cache as well as all kmalloc
71 slub_debug=P,kmalloc-*,dentry
73 Red zoning and tracking may realign the slab. We can just apply sanity checks
74 to the dentry cache with::
78 Debugging options may require the minimum possible slab order to increase as
79 a result of storing the metadata (for example, caches with PAGE_SIZE object
80 sizes). This has a higher liklihood of resulting in slab allocation errors
81 in low memory situations or if there's high fragmentation of memory. To
82 switch off debugging for such caches by default, use::
86 In case you forgot to enable debugging on the kernel command line: It is
87 possible to enable debugging manually when the kernel is up. Look at the
90 /sys/kernel/slab/<slab name>/
92 Look at the writable files. Writing 1 to them will enable the
93 corresponding debug option. All options can be set on a slab that does
94 not contain objects. If the slab already contains objects then sanity checks
95 and tracing may only be enabled. The other options may cause the realignment
98 Careful with tracing: It may spew out lots of information and never stop if
99 used on the wrong slab.
104 If no debug options are specified then SLUB may merge similar slabs together
105 in order to reduce overhead and increase cache hotness of objects.
106 ``slabinfo -a`` displays which slabs were merged together.
111 SLUB can validate all object if the kernel was booted with slub_debug. In
112 order to do so you must have the ``slabinfo`` tool. Then you can do
117 which will test all objects. Output will be generated to the syslog.
119 This also works in a more limited way if boot was without slab debug.
120 In that case ``slabinfo -v`` simply tests all reachable objects. Usually
121 these are in the cpu slabs and the partial slabs. Full slabs are not
122 tracked by SLUB in a non debug situation.
124 Getting more performance
125 ========================
127 To some degree SLUB's performance is limited by the need to take the
128 list_lock once in a while to deal with partial slabs. That overhead is
129 governed by the order of the allocation for each slab. The allocations
130 can be influenced by kernel parameters:
132 .. slub_min_objects=x (default 4)
133 .. slub_min_order=x (default 0)
134 .. slub_max_order=x (default 3 (PAGE_ALLOC_COSTLY_ORDER))
137 allows to specify how many objects must at least fit into one
138 slab in order for the allocation order to be acceptable. In
139 general slub will be able to perform this number of
140 allocations on a slab without consulting centralized resources
141 (list_lock) where contention may occur.
144 specifies a minim order of slabs. A similar effect like
145 ``slub_min_objects``.
148 specified the order at which ``slub_min_objects`` should no
149 longer be checked. This is useful to avoid SLUB trying to
150 generate super large order pages to fit ``slub_min_objects``
151 of a slab cache with large object sizes into one high order
152 page. Setting command line parameter
153 ``debug_guardpage_minorder=N`` (N > 0), forces setting
154 ``slub_max_order`` to 0, what cause minimum possible order of
160 Here is a sample of slub debug output::
162 ====================================================================
163 BUG kmalloc-8: Redzone overwritten
164 --------------------------------------------------------------------
166 INFO: 0xc90f6d28-0xc90f6d2b. First byte 0x00 instead of 0xcc
167 INFO: Slab 0xc528c530 flags=0x400000c3 inuse=61 fp=0xc90f6d58
168 INFO: Object 0xc90f6d20 @offset=3360 fp=0xc90f6d58
169 INFO: Allocated in get_modalias+0x61/0xf5 age=53 cpu=1 pid=554
171 Bytes b4 0xc90f6d10: 00 00 00 00 00 00 00 00 5a 5a 5a 5a 5a 5a 5a 5a ........ZZZZZZZZ
172 Object 0xc90f6d20: 31 30 31 39 2e 30 30 35 1019.005
173 Redzone 0xc90f6d28: 00 cc cc cc .
174 Padding 0xc90f6d50: 5a 5a 5a 5a 5a 5a 5a 5a ZZZZZZZZ
176 [<c010523d>] dump_trace+0x63/0x1eb
177 [<c01053df>] show_trace_log_lvl+0x1a/0x2f
178 [<c010601d>] show_trace+0x12/0x14
179 [<c0106035>] dump_stack+0x16/0x18
180 [<c017e0fa>] object_err+0x143/0x14b
181 [<c017e2cc>] check_object+0x66/0x234
182 [<c017eb43>] __slab_free+0x239/0x384
183 [<c017f446>] kfree+0xa6/0xc6
184 [<c02e2335>] get_modalias+0xb9/0xf5
185 [<c02e23b7>] dmi_dev_uevent+0x27/0x3c
186 [<c027866a>] dev_uevent+0x1ad/0x1da
187 [<c0205024>] kobject_uevent_env+0x20a/0x45b
188 [<c020527f>] kobject_uevent+0xa/0xf
189 [<c02779f1>] store_uevent+0x4f/0x58
190 [<c027758e>] dev_attr_store+0x29/0x2f
191 [<c01bec4f>] sysfs_write_file+0x16e/0x19c
192 [<c0183ba7>] vfs_write+0xd1/0x15a
193 [<c01841d7>] sys_write+0x3d/0x72
194 [<c0104112>] sysenter_past_esp+0x5f/0x99
195 [<b7f7b410>] 0xb7f7b410
196 =======================
198 FIX kmalloc-8: Restoring Redzone 0xc90f6d28-0xc90f6d2b=0xcc
200 If SLUB encounters a corrupted object (full detection requires the kernel
201 to be booted with slub_debug) then the following output will be dumped
204 1. Description of the problem encountered
206 This will be a message in the system log starting with::
208 ===============================================
209 BUG <slab cache affected>: <What went wrong>
210 -----------------------------------------------
212 INFO: <corruption start>-<corruption_end> <more info>
213 INFO: Slab <address> <slab information>
214 INFO: Object <address> <object information>
215 INFO: Allocated in <kernel function> age=<jiffies since alloc> cpu=<allocated by
216 cpu> pid=<pid of the process>
217 INFO: Freed in <kernel function> age=<jiffies since free> cpu=<freed by cpu>
218 pid=<pid of the process>
220 (Object allocation / free information is only available if SLAB_STORE_USER is
221 set for the slab. slub_debug sets that option)
223 2. The object contents if an object was involved.
225 Various types of lines can follow the BUG SLUB line:
227 Bytes b4 <address> : <bytes>
228 Shows a few bytes before the object where the problem was detected.
229 Can be useful if the corruption does not stop with the start of the
232 Object <address> : <bytes>
233 The bytes of the object. If the object is inactive then the bytes
234 typically contain poison values. Any non-poison value shows a
235 corruption by a write after free.
237 Redzone <address> : <bytes>
238 The Redzone following the object. The Redzone is used to detect
239 writes after the object. All bytes should always have the same
240 value. If there is any deviation then it is due to a write after
243 (Redzone information is only available if SLAB_RED_ZONE is set.
244 slub_debug sets that option)
246 Padding <address> : <bytes>
247 Unused data to fill up the space in order to get the next object
248 properly aligned. In the debug case we make sure that there are
249 at least 4 bytes of padding. This allows the detection of writes
254 The stackdump describes the location where the error was detected. The cause
255 of the corruption is may be more likely found by looking at the function that
256 allocated or freed the object.
258 4. Report on how the problem was dealt with in order to ensure the continued
259 operation of the system.
261 These are messages in the system log beginning with::
263 FIX <slab cache affected>: <corrective action taken>
265 In the above sample SLUB found that the Redzone of an active object has
266 been overwritten. Here a string of 8 characters was written into a slab that
267 has the length of 8 characters. However, a 8 character string needs a
268 terminating 0. That zero has overwritten the first byte of the Redzone field.
269 After reporting the details of the issue encountered the FIX SLUB message
270 tells us that SLUB has restored the Redzone to its proper value and then
271 system operations continue.
276 Minimal debugging (sanity checks alone) can be enabled by booting with::
280 This will be generally be enough to enable the resiliency features of slub
281 which will keep the system running even if a bad kernel component will
282 keep corrupting objects. This may be important for production systems.
283 Performance will be impacted by the sanity checks and there will be a
284 continual stream of error messages to the syslog but no additional memory
285 will be used (unlike full debugging).
287 No guarantees. The kernel component still needs to be fixed. Performance
288 may be optimized further by locating the slab that experiences corruption
289 and enabling debugging only for that cache
295 If the corruption occurs by writing after the end of the object then it
296 may be advisable to enable a Redzone to avoid corrupting the beginning
301 Extended slabinfo mode and plotting
302 ===================================
304 The ``slabinfo`` tool has a special 'extended' ('-X') mode that includes:
306 - Slabs sorted by size (up to -N <num> slabs, default 1)
307 - Slabs sorted by loss (up to -N <num> slabs, default 1)
309 Additionally, in this mode ``slabinfo`` does not dynamically scale
310 sizes (G/M/K) and reports everything in bytes (this functionality is
311 also available to other slabinfo modes via '-B' option) which makes
312 reporting more precise and accurate. Moreover, in some sense the `-X'
313 mode also simplifies the analysis of slabs' behaviour, because its
314 output can be plotted using the ``slabinfo-gnuplot.sh`` script. So it
315 pushes the analysis from looking through the numbers (tons of numbers)
316 to something easier -- visual analysis.
320 a) collect slabinfo extended records, for example::
322 while [ 1 ]; do slabinfo -X >> FOO_STATS; sleep 1; done
324 b) pass stats file(-s) to ``slabinfo-gnuplot.sh`` script::
326 slabinfo-gnuplot.sh FOO_STATS [FOO_STATS2 .. FOO_STATSN]
328 The ``slabinfo-gnuplot.sh`` script will pre-processes the collected records
329 and generates 3 png files (and 3 pre-processing cache files) per STATS
331 - Slabcache Totals: FOO_STATS-totals.png
332 - Slabs sorted by size: FOO_STATS-slabs-by-size.png
333 - Slabs sorted by loss: FOO_STATS-slabs-by-loss.png
335 Another use case, when ``slabinfo-gnuplot.sh`` can be useful, is when you
336 need to compare slabs' behaviour "prior to" and "after" some code
337 modification. To help you out there, ``slabinfo-gnuplot.sh`` script
338 can 'merge' the `Slabcache Totals` sections from different
339 measurements. To visually compare N plots:
341 a) Collect as many STATS1, STATS2, .. STATSN files as you need::
343 while [ 1 ]; do slabinfo -X >> STATS<X>; sleep 1; done
345 b) Pre-process those STATS files::
347 slabinfo-gnuplot.sh STATS1 STATS2 .. STATSN
349 c) Execute ``slabinfo-gnuplot.sh`` in '-t' mode, passing all of the
350 generated pre-processed \*-totals::
352 slabinfo-gnuplot.sh -t STATS1-totals STATS2-totals .. STATSN-totals
354 This will produce a single plot (png file).
356 Plots, expectedly, can be large so some fluctuations or small spikes
357 can go unnoticed. To deal with that, ``slabinfo-gnuplot.sh`` has two
358 options to 'zoom-in'/'zoom-out':
360 a) ``-s %d,%d`` -- overwrites the default image width and heigh
361 b) ``-r %d,%d`` -- specifies a range of samples to use (for example,
362 in ``slabinfo -X >> FOO_STATS; sleep 1;`` case, using a ``-r
363 40,60`` range will plot only samples collected between 40th and
366 Christoph Lameter, May 30, 2007
367 Sergey Senozhatsky, October 23, 2015