4 Copyright (C) 2004 BULL SA.
5 Written by Simon.Derr@bull.net
7 Portions Copyright (c) 2004-2006 Silicon Graphics, Inc.
8 Modified by Paul Jackson <pj@sgi.com>
9 Modified by Christoph Lameter <clameter@sgi.com>
10 Modified by Paul Menage <menage@google.com>
11 Modified by Hidetoshi Seto <seto.hidetoshi@jp.fujitsu.com>
17 1.1 What are cpusets ?
18 1.2 Why are cpusets needed ?
19 1.3 How are cpusets implemented ?
20 1.4 What are exclusive cpusets ?
21 1.5 What is memory_pressure ?
22 1.6 What is memory spread ?
23 1.7 What is sched_load_balance ?
24 1.8 What is sched_relax_domain_level ?
25 1.9 How do I use cpusets ?
26 2. Usage Examples and Syntax
28 2.2 Adding/removing cpus
30 2.4 Attaching processes
37 1.1 What are cpusets ?
38 ----------------------
40 Cpusets provide a mechanism for assigning a set of CPUs and Memory
41 Nodes to a set of tasks. In this document "Memory Node" refers to
42 an on-line node that contains memory.
44 Cpusets constrain the CPU and Memory placement of tasks to only
45 the resources within a tasks current cpuset. They form a nested
46 hierarchy visible in a virtual file system. These are the essential
47 hooks, beyond what is already present, required to manage dynamic
48 job placement on large systems.
50 Cpusets use the generic cgroup subsystem described in
51 Documentation/cgroups/cgroups.txt.
53 Requests by a task, using the sched_setaffinity(2) system call to
54 include CPUs in its CPU affinity mask, and using the mbind(2) and
55 set_mempolicy(2) system calls to include Memory Nodes in its memory
56 policy, are both filtered through that tasks cpuset, filtering out any
57 CPUs or Memory Nodes not in that cpuset. The scheduler will not
58 schedule a task on a CPU that is not allowed in its cpus_allowed
59 vector, and the kernel page allocator will not allocate a page on a
60 node that is not allowed in the requesting tasks mems_allowed vector.
62 User level code may create and destroy cpusets by name in the cgroup
63 virtual file system, manage the attributes and permissions of these
64 cpusets and which CPUs and Memory Nodes are assigned to each cpuset,
65 specify and query to which cpuset a task is assigned, and list the
66 task pids assigned to a cpuset.
69 1.2 Why are cpusets needed ?
70 ----------------------------
72 The management of large computer systems, with many processors (CPUs),
73 complex memory cache hierarchies and multiple Memory Nodes having
74 non-uniform access times (NUMA) presents additional challenges for
75 the efficient scheduling and memory placement of processes.
77 Frequently more modest sized systems can be operated with adequate
78 efficiency just by letting the operating system automatically share
79 the available CPU and Memory resources amongst the requesting tasks.
81 But larger systems, which benefit more from careful processor and
82 memory placement to reduce memory access times and contention,
83 and which typically represent a larger investment for the customer,
84 can benefit from explicitly placing jobs on properly sized subsets of
87 This can be especially valuable on:
89 * Web Servers running multiple instances of the same web application,
90 * Servers running different applications (for instance, a web server
92 * NUMA systems running large HPC applications with demanding
93 performance characteristics.
95 These subsets, or "soft partitions" must be able to be dynamically
96 adjusted, as the job mix changes, without impacting other concurrently
97 executing jobs. The location of the running jobs pages may also be moved
98 when the memory locations are changed.
100 The kernel cpuset patch provides the minimum essential kernel
101 mechanisms required to efficiently implement such subsets. It
102 leverages existing CPU and Memory Placement facilities in the Linux
103 kernel to avoid any additional impact on the critical scheduler or
104 memory allocator code.
107 1.3 How are cpusets implemented ?
108 ---------------------------------
110 Cpusets provide a Linux kernel mechanism to constrain which CPUs and
111 Memory Nodes are used by a process or set of processes.
113 The Linux kernel already has a pair of mechanisms to specify on which
114 CPUs a task may be scheduled (sched_setaffinity) and on which Memory
115 Nodes it may obtain memory (mbind, set_mempolicy).
117 Cpusets extends these two mechanisms as follows:
119 - Cpusets are sets of allowed CPUs and Memory Nodes, known to the
121 - Each task in the system is attached to a cpuset, via a pointer
122 in the task structure to a reference counted cgroup structure.
123 - Calls to sched_setaffinity are filtered to just those CPUs
124 allowed in that tasks cpuset.
125 - Calls to mbind and set_mempolicy are filtered to just
126 those Memory Nodes allowed in that tasks cpuset.
127 - The root cpuset contains all the systems CPUs and Memory
129 - For any cpuset, one can define child cpusets containing a subset
130 of the parents CPU and Memory Node resources.
131 - The hierarchy of cpusets can be mounted at /dev/cpuset, for
132 browsing and manipulation from user space.
133 - A cpuset may be marked exclusive, which ensures that no other
134 cpuset (except direct ancestors and descendents) may contain
135 any overlapping CPUs or Memory Nodes.
136 - You can list all the tasks (by pid) attached to any cpuset.
138 The implementation of cpusets requires a few, simple hooks
139 into the rest of the kernel, none in performance critical paths:
141 - in init/main.c, to initialize the root cpuset at system boot.
142 - in fork and exit, to attach and detach a task from its cpuset.
143 - in sched_setaffinity, to mask the requested CPUs by what's
144 allowed in that tasks cpuset.
145 - in sched.c migrate_live_tasks(), to keep migrating tasks within
146 the CPUs allowed by their cpuset, if possible.
147 - in the mbind and set_mempolicy system calls, to mask the requested
148 Memory Nodes by what's allowed in that tasks cpuset.
149 - in page_alloc.c, to restrict memory to allowed nodes.
150 - in vmscan.c, to restrict page recovery to the current cpuset.
152 You should mount the "cgroup" filesystem type in order to enable
153 browsing and modifying the cpusets presently known to the kernel. No
154 new system calls are added for cpusets - all support for querying and
155 modifying cpusets is via this cpuset file system.
157 The /proc/<pid>/status file for each task has four added lines,
158 displaying the tasks cpus_allowed (on which CPUs it may be scheduled)
159 and mems_allowed (on which Memory Nodes it may obtain memory),
160 in the two formats seen in the following example:
162 Cpus_allowed: ffffffff,ffffffff,ffffffff,ffffffff
163 Cpus_allowed_list: 0-127
164 Mems_allowed: ffffffff,ffffffff
165 Mems_allowed_list: 0-63
167 Each cpuset is represented by a directory in the cgroup file system
168 containing (on top of the standard cgroup files) the following
169 files describing that cpuset:
171 - cpus: list of CPUs in that cpuset
172 - mems: list of Memory Nodes in that cpuset
173 - memory_migrate flag: if set, move pages to cpusets nodes
174 - cpu_exclusive flag: is cpu placement exclusive?
175 - mem_exclusive flag: is memory placement exclusive?
176 - mem_hardwall flag: is memory allocation hardwalled
177 - memory_pressure: measure of how much paging pressure in cpuset
178 - memory_spread_page flag: if set, spread page cache evenly on allowed nodes
179 - memory_spread_slab flag: if set, spread slab cache evenly on allowed nodes
180 - sched_load_balance flag: if set, load balance within CPUs on that cpuset
181 - sched_relax_domain_level: the searching range when migrating tasks
183 In addition, the root cpuset only has the following file:
184 - memory_pressure_enabled flag: compute memory_pressure?
186 New cpusets are created using the mkdir system call or shell
187 command. The properties of a cpuset, such as its flags, allowed
188 CPUs and Memory Nodes, and attached tasks, are modified by writing
189 to the appropriate file in that cpusets directory, as listed above.
191 The named hierarchical structure of nested cpusets allows partitioning
192 a large system into nested, dynamically changeable, "soft-partitions".
194 The attachment of each task, automatically inherited at fork by any
195 children of that task, to a cpuset allows organizing the work load
196 on a system into related sets of tasks such that each set is constrained
197 to using the CPUs and Memory Nodes of a particular cpuset. A task
198 may be re-attached to any other cpuset, if allowed by the permissions
199 on the necessary cpuset file system directories.
201 Such management of a system "in the large" integrates smoothly with
202 the detailed placement done on individual tasks and memory regions
203 using the sched_setaffinity, mbind and set_mempolicy system calls.
205 The following rules apply to each cpuset:
207 - Its CPUs and Memory Nodes must be a subset of its parents.
208 - It can't be marked exclusive unless its parent is.
209 - If its cpu or memory is exclusive, they may not overlap any sibling.
211 These rules, and the natural hierarchy of cpusets, enable efficient
212 enforcement of the exclusive guarantee, without having to scan all
213 cpusets every time any of them change to ensure nothing overlaps a
214 exclusive cpuset. Also, the use of a Linux virtual file system (vfs)
215 to represent the cpuset hierarchy provides for a familiar permission
216 and name space for cpusets, with a minimum of additional kernel code.
218 The cpus and mems files in the root (top_cpuset) cpuset are
219 read-only. The cpus file automatically tracks the value of
220 cpu_online_map using a CPU hotplug notifier, and the mems file
221 automatically tracks the value of node_states[N_HIGH_MEMORY]--i.e.,
222 nodes with memory--using the cpuset_track_online_nodes() hook.
225 1.4 What are exclusive cpusets ?
226 --------------------------------
228 If a cpuset is cpu or mem exclusive, no other cpuset, other than
229 a direct ancestor or descendent, may share any of the same CPUs or
232 A cpuset that is mem_exclusive *or* mem_hardwall is "hardwalled",
233 i.e. it restricts kernel allocations for page, buffer and other data
234 commonly shared by the kernel across multiple users. All cpusets,
235 whether hardwalled or not, restrict allocations of memory for user
236 space. This enables configuring a system so that several independent
237 jobs can share common kernel data, such as file system pages, while
238 isolating each job's user allocation in its own cpuset. To do this,
239 construct a large mem_exclusive cpuset to hold all the jobs, and
240 construct child, non-mem_exclusive cpusets for each individual job.
241 Only a small amount of typical kernel memory, such as requests from
242 interrupt handlers, is allowed to be taken outside even a
243 mem_exclusive cpuset.
246 1.5 What is memory_pressure ?
247 -----------------------------
248 The memory_pressure of a cpuset provides a simple per-cpuset metric
249 of the rate that the tasks in a cpuset are attempting to free up in
250 use memory on the nodes of the cpuset to satisfy additional memory
253 This enables batch managers monitoring jobs running in dedicated
254 cpusets to efficiently detect what level of memory pressure that job
257 This is useful both on tightly managed systems running a wide mix of
258 submitted jobs, which may choose to terminate or re-prioritize jobs that
259 are trying to use more memory than allowed on the nodes assigned to them,
260 and with tightly coupled, long running, massively parallel scientific
261 computing jobs that will dramatically fail to meet required performance
262 goals if they start to use more memory than allowed to them.
264 This mechanism provides a very economical way for the batch manager
265 to monitor a cpuset for signs of memory pressure. It's up to the
266 batch manager or other user code to decide what to do about it and
269 ==> Unless this feature is enabled by writing "1" to the special file
270 /dev/cpuset/memory_pressure_enabled, the hook in the rebalance
271 code of __alloc_pages() for this metric reduces to simply noticing
272 that the cpuset_memory_pressure_enabled flag is zero. So only
273 systems that enable this feature will compute the metric.
275 Why a per-cpuset, running average:
277 Because this meter is per-cpuset, rather than per-task or mm,
278 the system load imposed by a batch scheduler monitoring this
279 metric is sharply reduced on large systems, because a scan of
280 the tasklist can be avoided on each set of queries.
282 Because this meter is a running average, instead of an accumulating
283 counter, a batch scheduler can detect memory pressure with a
284 single read, instead of having to read and accumulate results
285 for a period of time.
287 Because this meter is per-cpuset rather than per-task or mm,
288 the batch scheduler can obtain the key information, memory
289 pressure in a cpuset, with a single read, rather than having to
290 query and accumulate results over all the (dynamically changing)
291 set of tasks in the cpuset.
293 A per-cpuset simple digital filter (requires a spinlock and 3 words
294 of data per-cpuset) is kept, and updated by any task attached to that
295 cpuset, if it enters the synchronous (direct) page reclaim code.
297 A per-cpuset file provides an integer number representing the recent
298 (half-life of 10 seconds) rate of direct page reclaims caused by
299 the tasks in the cpuset, in units of reclaims attempted per second,
303 1.6 What is memory spread ?
304 ---------------------------
305 There are two boolean flag files per cpuset that control where the
306 kernel allocates pages for the file system buffers and related in
307 kernel data structures. They are called 'memory_spread_page' and
308 'memory_spread_slab'.
310 If the per-cpuset boolean flag file 'memory_spread_page' is set, then
311 the kernel will spread the file system buffers (page cache) evenly
312 over all the nodes that the faulting task is allowed to use, instead
313 of preferring to put those pages on the node where the task is running.
315 If the per-cpuset boolean flag file 'memory_spread_slab' is set,
316 then the kernel will spread some file system related slab caches,
317 such as for inodes and dentries evenly over all the nodes that the
318 faulting task is allowed to use, instead of preferring to put those
319 pages on the node where the task is running.
321 The setting of these flags does not affect anonymous data segment or
322 stack segment pages of a task.
324 By default, both kinds of memory spreading are off, and memory
325 pages are allocated on the node local to where the task is running,
326 except perhaps as modified by the tasks NUMA mempolicy or cpuset
327 configuration, so long as sufficient free memory pages are available.
329 When new cpusets are created, they inherit the memory spread settings
332 Setting memory spreading causes allocations for the affected page
333 or slab caches to ignore the tasks NUMA mempolicy and be spread
334 instead. Tasks using mbind() or set_mempolicy() calls to set NUMA
335 mempolicies will not notice any change in these calls as a result of
336 their containing tasks memory spread settings. If memory spreading
337 is turned off, then the currently specified NUMA mempolicy once again
338 applies to memory page allocations.
340 Both 'memory_spread_page' and 'memory_spread_slab' are boolean flag
341 files. By default they contain "0", meaning that the feature is off
342 for that cpuset. If a "1" is written to that file, then that turns
343 the named feature on.
345 The implementation is simple.
347 Setting the flag 'memory_spread_page' turns on a per-process flag
348 PF_SPREAD_PAGE for each task that is in that cpuset or subsequently
349 joins that cpuset. The page allocation calls for the page cache
350 is modified to perform an inline check for this PF_SPREAD_PAGE task
351 flag, and if set, a call to a new routine cpuset_mem_spread_node()
352 returns the node to prefer for the allocation.
354 Similarly, setting 'memory_spread_slab' turns on the flag
355 PF_SPREAD_SLAB, and appropriately marked slab caches will allocate
356 pages from the node returned by cpuset_mem_spread_node().
358 The cpuset_mem_spread_node() routine is also simple. It uses the
359 value of a per-task rotor cpuset_mem_spread_rotor to select the next
360 node in the current tasks mems_allowed to prefer for the allocation.
362 This memory placement policy is also known (in other contexts) as
363 round-robin or interleave.
365 This policy can provide substantial improvements for jobs that need
366 to place thread local data on the corresponding node, but that need
367 to access large file system data sets that need to be spread across
368 the several nodes in the jobs cpuset in order to fit. Without this
369 policy, especially for jobs that might have one thread reading in the
370 data set, the memory allocation across the nodes in the jobs cpuset
371 can become very uneven.
373 1.7 What is sched_load_balance ?
374 --------------------------------
376 The kernel scheduler (kernel/sched.c) automatically load balances
377 tasks. If one CPU is underutilized, kernel code running on that
378 CPU will look for tasks on other more overloaded CPUs and move those
379 tasks to itself, within the constraints of such placement mechanisms
380 as cpusets and sched_setaffinity.
382 The algorithmic cost of load balancing and its impact on key shared
383 kernel data structures such as the task list increases more than
384 linearly with the number of CPUs being balanced. So the scheduler
385 has support to partition the systems CPUs into a number of sched
386 domains such that it only load balances within each sched domain.
387 Each sched domain covers some subset of the CPUs in the system;
388 no two sched domains overlap; some CPUs might not be in any sched
389 domain and hence won't be load balanced.
391 Put simply, it costs less to balance between two smaller sched domains
392 than one big one, but doing so means that overloads in one of the
393 two domains won't be load balanced to the other one.
395 By default, there is one sched domain covering all CPUs, except those
396 marked isolated using the kernel boot time "isolcpus=" argument.
398 This default load balancing across all CPUs is not well suited for
399 the following two situations:
400 1) On large systems, load balancing across many CPUs is expensive.
401 If the system is managed using cpusets to place independent jobs
402 on separate sets of CPUs, full load balancing is unnecessary.
403 2) Systems supporting realtime on some CPUs need to minimize
404 system overhead on those CPUs, including avoiding task load
405 balancing if that is not needed.
407 When the per-cpuset flag "sched_load_balance" is enabled (the default
408 setting), it requests that all the CPUs in that cpusets allowed 'cpus'
409 be contained in a single sched domain, ensuring that load balancing
410 can move a task (not otherwised pinned, as by sched_setaffinity)
411 from any CPU in that cpuset to any other.
413 When the per-cpuset flag "sched_load_balance" is disabled, then the
414 scheduler will avoid load balancing across the CPUs in that cpuset,
415 --except-- in so far as is necessary because some overlapping cpuset
416 has "sched_load_balance" enabled.
418 So, for example, if the top cpuset has the flag "sched_load_balance"
419 enabled, then the scheduler will have one sched domain covering all
420 CPUs, and the setting of the "sched_load_balance" flag in any other
421 cpusets won't matter, as we're already fully load balancing.
423 Therefore in the above two situations, the top cpuset flag
424 "sched_load_balance" should be disabled, and only some of the smaller,
425 child cpusets have this flag enabled.
427 When doing this, you don't usually want to leave any unpinned tasks in
428 the top cpuset that might use non-trivial amounts of CPU, as such tasks
429 may be artificially constrained to some subset of CPUs, depending on
430 the particulars of this flag setting in descendent cpusets. Even if
431 such a task could use spare CPU cycles in some other CPUs, the kernel
432 scheduler might not consider the possibility of load balancing that
433 task to that underused CPU.
435 Of course, tasks pinned to a particular CPU can be left in a cpuset
436 that disables "sched_load_balance" as those tasks aren't going anywhere
439 There is an impedance mismatch here, between cpusets and sched domains.
440 Cpusets are hierarchical and nest. Sched domains are flat; they don't
441 overlap and each CPU is in at most one sched domain.
443 It is necessary for sched domains to be flat because load balancing
444 across partially overlapping sets of CPUs would risk unstable dynamics
445 that would be beyond our understanding. So if each of two partially
446 overlapping cpusets enables the flag 'sched_load_balance', then we
447 form a single sched domain that is a superset of both. We won't move
448 a task to a CPU outside it cpuset, but the scheduler load balancing
449 code might waste some compute cycles considering that possibility.
451 This mismatch is why there is not a simple one-to-one relation
452 between which cpusets have the flag "sched_load_balance" enabled,
453 and the sched domain configuration. If a cpuset enables the flag, it
454 will get balancing across all its CPUs, but if it disables the flag,
455 it will only be assured of no load balancing if no other overlapping
456 cpuset enables the flag.
458 If two cpusets have partially overlapping 'cpus' allowed, and only
459 one of them has this flag enabled, then the other may find its
460 tasks only partially load balanced, just on the overlapping CPUs.
461 This is just the general case of the top_cpuset example given a few
462 paragraphs above. In the general case, as in the top cpuset case,
463 don't leave tasks that might use non-trivial amounts of CPU in
464 such partially load balanced cpusets, as they may be artificially
465 constrained to some subset of the CPUs allowed to them, for lack of
466 load balancing to the other CPUs.
468 1.7.1 sched_load_balance implementation details.
469 ------------------------------------------------
471 The per-cpuset flag 'sched_load_balance' defaults to enabled (contrary
472 to most cpuset flags.) When enabled for a cpuset, the kernel will
473 ensure that it can load balance across all the CPUs in that cpuset
474 (makes sure that all the CPUs in the cpus_allowed of that cpuset are
475 in the same sched domain.)
477 If two overlapping cpusets both have 'sched_load_balance' enabled,
478 then they will be (must be) both in the same sched domain.
480 If, as is the default, the top cpuset has 'sched_load_balance' enabled,
481 then by the above that means there is a single sched domain covering
482 the whole system, regardless of any other cpuset settings.
484 The kernel commits to user space that it will avoid load balancing
485 where it can. It will pick as fine a granularity partition of sched
486 domains as it can while still providing load balancing for any set
487 of CPUs allowed to a cpuset having 'sched_load_balance' enabled.
489 The internal kernel cpuset to scheduler interface passes from the
490 cpuset code to the scheduler code a partition of the load balanced
491 CPUs in the system. This partition is a set of subsets (represented
492 as an array of struct cpumask) of CPUs, pairwise disjoint, that cover
493 all the CPUs that must be load balanced.
495 The cpuset code builds a new such partition and passes it to the
496 scheduler sched domain setup code, to have the sched domains rebuilt
497 as necessary, whenever:
498 - the 'sched_load_balance' flag of a cpuset with non-empty CPUs changes,
499 - or CPUs come or go from a cpuset with this flag enabled,
500 - or 'sched_relax_domain_level' value of a cpuset with non-empty CPUs
501 and with this flag enabled changes,
502 - or a cpuset with non-empty CPUs and with this flag enabled is removed,
503 - or a cpu is offlined/onlined.
505 This partition exactly defines what sched domains the scheduler should
506 setup - one sched domain for each element (struct cpumask) in the
509 The scheduler remembers the currently active sched domain partitions.
510 When the scheduler routine partition_sched_domains() is invoked from
511 the cpuset code to update these sched domains, it compares the new
512 partition requested with the current, and updates its sched domains,
513 removing the old and adding the new, for each change.
516 1.8 What is sched_relax_domain_level ?
517 --------------------------------------
519 In sched domain, the scheduler migrates tasks in 2 ways; periodic load
520 balance on tick, and at time of some schedule events.
522 When a task is woken up, scheduler try to move the task on idle CPU.
523 For example, if a task A running on CPU X activates another task B
524 on the same CPU X, and if CPU Y is X's sibling and performing idle,
525 then scheduler migrate task B to CPU Y so that task B can start on
526 CPU Y without waiting task A on CPU X.
528 And if a CPU run out of tasks in its runqueue, the CPU try to pull
529 extra tasks from other busy CPUs to help them before it is going to
532 Of course it takes some searching cost to find movable tasks and/or
533 idle CPUs, the scheduler might not search all CPUs in the domain
534 everytime. In fact, in some architectures, the searching ranges on
535 events are limited in the same socket or node where the CPU locates,
536 while the load balance on tick searchs all.
538 For example, assume CPU Z is relatively far from CPU X. Even if CPU Z
539 is idle while CPU X and the siblings are busy, scheduler can't migrate
540 woken task B from X to Z since it is out of its searching range.
541 As the result, task B on CPU X need to wait task A or wait load balance
542 on the next tick. For some applications in special situation, waiting
543 1 tick may be too long.
545 The 'sched_relax_domain_level' file allows you to request changing
546 this searching range as you like. This file takes int value which
547 indicates size of searching range in levels ideally as follows,
548 otherwise initial value -1 that indicates the cpuset has no request.
550 -1 : no request. use system default or follow request of others.
552 1 : search siblings (hyperthreads in a core).
553 2 : search cores in a package.
554 3 : search cpus in a node [= system wide on non-NUMA system]
555 ( 4 : search nodes in a chunk of node [on NUMA system] )
556 ( 5 : search system wide [on NUMA system] )
558 The system default is architecture dependent. The system default
559 can be changed using the relax_domain_level= boot parameter.
561 This file is per-cpuset and affect the sched domain where the cpuset
562 belongs to. Therefore if the flag 'sched_load_balance' of a cpuset
563 is disabled, then 'sched_relax_domain_level' have no effect since
564 there is no sched domain belonging the cpuset.
566 If multiple cpusets are overlapping and hence they form a single sched
567 domain, the largest value among those is used. Be careful, if one
568 requests 0 and others are -1 then 0 is used.
570 Note that modifying this file will have both good and bad effects,
571 and whether it is acceptable or not depends on your situation.
572 Don't modify this file if you are not sure.
574 If your situation is:
575 - The migration costs between each cpu can be assumed considerably
576 small(for you) due to your special application's behavior or
577 special hardware support for CPU cache etc.
578 - The searching cost doesn't have impact(for you) or you can make
579 the searching cost enough small by managing cpuset to compact etc.
580 - The latency is required even it sacrifices cache hit rate etc.
581 then increasing 'sched_relax_domain_level' would benefit you.
584 1.9 How do I use cpusets ?
585 --------------------------
587 In order to minimize the impact of cpusets on critical kernel
588 code, such as the scheduler, and due to the fact that the kernel
589 does not support one task updating the memory placement of another
590 task directly, the impact on a task of changing its cpuset CPU
591 or Memory Node placement, or of changing to which cpuset a task
592 is attached, is subtle.
594 If a cpuset has its Memory Nodes modified, then for each task attached
595 to that cpuset, the next time that the kernel attempts to allocate
596 a page of memory for that task, the kernel will notice the change
597 in the tasks cpuset, and update its per-task memory placement to
598 remain within the new cpusets memory placement. If the task was using
599 mempolicy MPOL_BIND, and the nodes to which it was bound overlap with
600 its new cpuset, then the task will continue to use whatever subset
601 of MPOL_BIND nodes are still allowed in the new cpuset. If the task
602 was using MPOL_BIND and now none of its MPOL_BIND nodes are allowed
603 in the new cpuset, then the task will be essentially treated as if it
604 was MPOL_BIND bound to the new cpuset (even though its numa placement,
605 as queried by get_mempolicy(), doesn't change). If a task is moved
606 from one cpuset to another, then the kernel will adjust the tasks
607 memory placement, as above, the next time that the kernel attempts
608 to allocate a page of memory for that task.
610 If a cpuset has its 'cpus' modified, then each task in that cpuset
611 will have its allowed CPU placement changed immediately. Similarly,
612 if a tasks pid is written to another cpusets 'tasks' file, then its
613 allowed CPU placement is changed immediately. If such a task had been
614 bound to some subset of its cpuset using the sched_setaffinity() call,
615 the task will be allowed to run on any CPU allowed in its new cpuset,
616 negating the effect of the prior sched_setaffinity() call.
618 In summary, the memory placement of a task whose cpuset is changed is
619 updated by the kernel, on the next allocation of a page for that task,
620 and the processor placement is updated immediately.
622 Normally, once a page is allocated (given a physical page
623 of main memory) then that page stays on whatever node it
624 was allocated, so long as it remains allocated, even if the
625 cpusets memory placement policy 'mems' subsequently changes.
626 If the cpuset flag file 'memory_migrate' is set true, then when
627 tasks are attached to that cpuset, any pages that task had
628 allocated to it on nodes in its previous cpuset are migrated
629 to the tasks new cpuset. The relative placement of the page within
630 the cpuset is preserved during these migration operations if possible.
631 For example if the page was on the second valid node of the prior cpuset
632 then the page will be placed on the second valid node of the new cpuset.
634 Also if 'memory_migrate' is set true, then if that cpusets
635 'mems' file is modified, pages allocated to tasks in that
636 cpuset, that were on nodes in the previous setting of 'mems',
637 will be moved to nodes in the new setting of 'mems.'
638 Pages that were not in the tasks prior cpuset, or in the cpusets
639 prior 'mems' setting, will not be moved.
641 There is an exception to the above. If hotplug functionality is used
642 to remove all the CPUs that are currently assigned to a cpuset,
643 then all the tasks in that cpuset will be moved to the nearest ancestor
644 with non-empty cpus. But the moving of some (or all) tasks might fail if
645 cpuset is bound with another cgroup subsystem which has some restrictions
646 on task attaching. In this failing case, those tasks will stay
647 in the original cpuset, and the kernel will automatically update
648 their cpus_allowed to allow all online CPUs. When memory hotplug
649 functionality for removing Memory Nodes is available, a similar exception
650 is expected to apply there as well. In general, the kernel prefers to
651 violate cpuset placement, over starving a task that has had all
652 its allowed CPUs or Memory Nodes taken offline.
654 There is a second exception to the above. GFP_ATOMIC requests are
655 kernel internal allocations that must be satisfied, immediately.
656 The kernel may drop some request, in rare cases even panic, if a
657 GFP_ATOMIC alloc fails. If the request cannot be satisfied within
658 the current tasks cpuset, then we relax the cpuset, and look for
659 memory anywhere we can find it. It's better to violate the cpuset
660 than stress the kernel.
662 To start a new job that is to be contained within a cpuset, the steps are:
665 2) mount -t cgroup -ocpuset cpuset /dev/cpuset
666 3) Create the new cpuset by doing mkdir's and write's (or echo's) in
667 the /dev/cpuset virtual file system.
668 4) Start a task that will be the "founding father" of the new job.
669 5) Attach that task to the new cpuset by writing its pid to the
670 /dev/cpuset tasks file for that cpuset.
671 6) fork, exec or clone the job tasks from this founding father task.
673 For example, the following sequence of commands will setup a cpuset
674 named "Charlie", containing just CPUs 2 and 3, and Memory Node 1,
675 and then start a subshell 'sh' in that cpuset:
677 mount -t cgroup -ocpuset cpuset /dev/cpuset
685 # The subshell 'sh' is now running in cpuset Charlie
686 # The next line should display '/Charlie'
687 cat /proc/self/cpuset
689 There are ways to query or modify cpusets:
690 - via the cpuset file system directly, using the various cd, mkdir, echo,
691 cat, rmdir commands from the shell, or their equivalent from C.
692 - via the C library libcpuset.
693 - via the C library libcgroup.
694 (http://sourceforge.net/proects/libcg/)
695 - via the python application cset.
696 (http://developer.novell.com/wiki/index.php/Cpuset)
698 The sched_setaffinity calls can also be done at the shell prompt using
699 SGI's runon or Robert Love's taskset. The mbind and set_mempolicy
700 calls can be done at the shell prompt using the numactl command
701 (part of Andi Kleen's numa package).
703 2. Usage Examples and Syntax
704 ============================
709 Creating, modifying, using the cpusets can be done through the cpuset
713 # mount -t cgroup -o cpuset cpuset /dev/cpuset
715 Then under /dev/cpuset you can find a tree that corresponds to the
716 tree of the cpusets in the system. For instance, /dev/cpuset
717 is the cpuset that holds the whole system.
719 If you want to create a new cpuset under /dev/cpuset:
723 Now you want to do something with this cpuset.
726 In this directory you can find several files:
728 cpu_exclusive memory_migrate mems tasks
729 cpus memory_pressure notify_on_release
730 mem_exclusive memory_spread_page sched_load_balance
731 mem_hardwall memory_spread_slab sched_relax_domain_level
733 Reading them will give you information about the state of this cpuset:
734 the CPUs and Memory Nodes it can use, the processes that are using
735 it, its properties. By writing to these files you can manipulate
739 # /bin/echo 1 > cpu_exclusive
742 # /bin/echo 0-7 > cpus
745 # /bin/echo 0-7 > mems
747 Now attach your shell to this cpuset:
748 # /bin/echo $$ > tasks
750 You can also create cpusets inside your cpuset by using mkdir in this
754 To remove a cpuset, just use rmdir:
756 This will fail if the cpuset is in use (has cpusets inside, or has
759 Note that for legacy reasons, the "cpuset" filesystem exists as a
760 wrapper around the cgroup filesystem.
764 mount -t cpuset X /dev/cpuset
768 mount -t cgroup -ocpuset,noprefix X /dev/cpuset
769 echo "/sbin/cpuset_release_agent" > /dev/cpuset/release_agent
771 2.2 Adding/removing cpus
772 ------------------------
774 This is the syntax to use when writing in the cpus or mems files
775 in cpuset directories:
777 # /bin/echo 1-4 > cpus -> set cpus list to cpus 1,2,3,4
778 # /bin/echo 1,2,3,4 > cpus -> set cpus list to cpus 1,2,3,4
783 The syntax is very simple:
785 # /bin/echo 1 > cpu_exclusive -> set flag 'cpu_exclusive'
786 # /bin/echo 0 > cpu_exclusive -> unset flag 'cpu_exclusive'
788 2.4 Attaching processes
789 -----------------------
791 # /bin/echo PID > tasks
793 Note that it is PID, not PIDs. You can only attach ONE task at a time.
794 If you have several tasks to attach, you have to do it one after another:
796 # /bin/echo PID1 > tasks
797 # /bin/echo PID2 > tasks
799 # /bin/echo PIDn > tasks
805 Q: what's up with this '/bin/echo' ?
806 A: bash's builtin 'echo' command does not check calls to write() against
807 errors. If you use it in the cpuset file system, you won't be
808 able to tell whether a command succeeded or failed.
810 Q: When I attach processes, only the first of the line gets really attached !
811 A: We can only return one error code per call to write(). So you should also
817 Web: http://www.bullopensource.org/cpuset