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ce881fc06d
a) since d73df887b6
("sched/fair: Add document for burstable CFS bandwidth")
[cpu.cfs_quota_us: the total available run-time within a period (in] shoud be removed,
let's delete it.
b) Add a period.
c) fix a build warning:
linux-next/Documentation/scheduler/sched-bwc.rst:243: WARNING: Inline emphasis
start-string without end-string.
Signed-off-by: Yanteng Si <siyanteng@loongson.cn>
Reviewed-by: Alex Shi <alexs@kernel.org>
Link: https://lore.kernel.org/r/163a4dde20b8c4b68d668977a668e281d18fcf92.1638517064.git.siyanteng@loongson.cn
Signed-off-by: Jonathan Corbet <corbet@lwn.net>
247 lines
11 KiB
ReStructuredText
247 lines
11 KiB
ReStructuredText
=====================
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CFS Bandwidth Control
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=====================
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.. note::
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This document only discusses CPU bandwidth control for SCHED_NORMAL.
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The SCHED_RT case is covered in Documentation/scheduler/sched-rt-group.rst
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CFS bandwidth control is a CONFIG_FAIR_GROUP_SCHED extension which allows the
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specification of the maximum CPU bandwidth available to a group or hierarchy.
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The bandwidth allowed for a group is specified using a quota and period. Within
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each given "period" (microseconds), a task group is allocated up to "quota"
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microseconds of CPU time. That quota is assigned to per-cpu run queues in
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slices as threads in the cgroup become runnable. Once all quota has been
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assigned any additional requests for quota will result in those threads being
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throttled. Throttled threads will not be able to run again until the next
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period when the quota is replenished.
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A group's unassigned quota is globally tracked, being refreshed back to
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cfs_quota units at each period boundary. As threads consume this bandwidth it
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is transferred to cpu-local "silos" on a demand basis. The amount transferred
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within each of these updates is tunable and described as the "slice".
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Burst feature
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-------------
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This feature borrows time now against our future underrun, at the cost of
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increased interference against the other system users. All nicely bounded.
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Traditional (UP-EDF) bandwidth control is something like:
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(U = \Sum u_i) <= 1
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This guaranteeds both that every deadline is met and that the system is
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stable. After all, if U were > 1, then for every second of walltime,
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we'd have to run more than a second of program time, and obviously miss
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our deadline, but the next deadline will be further out still, there is
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never time to catch up, unbounded fail.
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The burst feature observes that a workload doesn't always executes the full
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quota; this enables one to describe u_i as a statistical distribution.
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For example, have u_i = {x,e}_i, where x is the p(95) and x+e p(100)
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(the traditional WCET). This effectively allows u to be smaller,
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increasing the efficiency (we can pack more tasks in the system), but at
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the cost of missing deadlines when all the odds line up. However, it
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does maintain stability, since every overrun must be paired with an
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underrun as long as our x is above the average.
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That is, suppose we have 2 tasks, both specify a p(95) value, then we
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have a p(95)*p(95) = 90.25% chance both tasks are within their quota and
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everything is good. At the same time we have a p(5)p(5) = 0.25% chance
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both tasks will exceed their quota at the same time (guaranteed deadline
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fail). Somewhere in between there's a threshold where one exceeds and
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the other doesn't underrun enough to compensate; this depends on the
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specific CDFs.
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At the same time, we can say that the worst case deadline miss, will be
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\Sum e_i; that is, there is a bounded tardiness (under the assumption
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that x+e is indeed WCET).
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The interferenece when using burst is valued by the possibilities for
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missing the deadline and the average WCET. Test results showed that when
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there many cgroups or CPU is under utilized, the interference is
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limited. More details are shown in:
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https://lore.kernel.org/lkml/5371BD36-55AE-4F71-B9D7-B86DC32E3D2B@linux.alibaba.com/
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Management
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----------
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Quota, period and burst are managed within the cpu subsystem via cgroupfs.
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.. note::
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The cgroupfs files described in this section are only applicable
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to cgroup v1. For cgroup v2, see
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:ref:`Documentation/admin-guide/cgroup-v2.rst <cgroup-v2-cpu>`.
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- cpu.cfs_quota_us: run-time replenished within a period (in microseconds)
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- cpu.cfs_period_us: the length of a period (in microseconds)
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- cpu.stat: exports throttling statistics [explained further below]
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- cpu.cfs_burst_us: the maximum accumulated run-time (in microseconds)
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The default values are::
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cpu.cfs_period_us=100ms
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cpu.cfs_quota_us=-1
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cpu.cfs_burst_us=0
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A value of -1 for cpu.cfs_quota_us indicates that the group does not have any
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bandwidth restriction in place, such a group is described as an unconstrained
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bandwidth group. This represents the traditional work-conserving behavior for
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CFS.
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Writing any (valid) positive value(s) no smaller than cpu.cfs_burst_us will
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enact the specified bandwidth limit. The minimum quota allowed for the quota or
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period is 1ms. There is also an upper bound on the period length of 1s.
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Additional restrictions exist when bandwidth limits are used in a hierarchical
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fashion, these are explained in more detail below.
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Writing any negative value to cpu.cfs_quota_us will remove the bandwidth limit
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and return the group to an unconstrained state once more.
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A value of 0 for cpu.cfs_burst_us indicates that the group can not accumulate
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any unused bandwidth. It makes the traditional bandwidth control behavior for
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CFS unchanged. Writing any (valid) positive value(s) no larger than
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cpu.cfs_quota_us into cpu.cfs_burst_us will enact the cap on unused bandwidth
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accumulation.
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Any updates to a group's bandwidth specification will result in it becoming
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unthrottled if it is in a constrained state.
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System wide settings
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--------------------
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For efficiency run-time is transferred between the global pool and CPU local
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"silos" in a batch fashion. This greatly reduces global accounting pressure
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on large systems. The amount transferred each time such an update is required
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is described as the "slice".
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This is tunable via procfs::
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/proc/sys/kernel/sched_cfs_bandwidth_slice_us (default=5ms)
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Larger slice values will reduce transfer overheads, while smaller values allow
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for more fine-grained consumption.
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Statistics
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----------
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A group's bandwidth statistics are exported via 5 fields in cpu.stat.
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cpu.stat:
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- nr_periods: Number of enforcement intervals that have elapsed.
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- nr_throttled: Number of times the group has been throttled/limited.
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- throttled_time: The total time duration (in nanoseconds) for which entities
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of the group have been throttled.
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- nr_bursts: Number of periods burst occurs.
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- burst_time: Cumulative wall-time (in nanoseconds) that any CPUs has used
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above quota in respective periods.
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This interface is read-only.
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Hierarchical considerations
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---------------------------
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The interface enforces that an individual entity's bandwidth is always
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attainable, that is: max(c_i) <= C. However, over-subscription in the
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aggregate case is explicitly allowed to enable work-conserving semantics
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within a hierarchy:
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e.g. \Sum (c_i) may exceed C
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[ Where C is the parent's bandwidth, and c_i its children ]
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There are two ways in which a group may become throttled:
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a. it fully consumes its own quota within a period
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b. a parent's quota is fully consumed within its period
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In case b) above, even though the child may have runtime remaining it will not
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be allowed to until the parent's runtime is refreshed.
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CFS Bandwidth Quota Caveats
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---------------------------
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Once a slice is assigned to a cpu it does not expire. However all but 1ms of
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the slice may be returned to the global pool if all threads on that cpu become
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unrunnable. This is configured at compile time by the min_cfs_rq_runtime
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variable. This is a performance tweak that helps prevent added contention on
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the global lock.
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The fact that cpu-local slices do not expire results in some interesting corner
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cases that should be understood.
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For cgroup cpu constrained applications that are cpu limited this is a
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relatively moot point because they will naturally consume the entirety of their
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quota as well as the entirety of each cpu-local slice in each period. As a
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result it is expected that nr_periods roughly equal nr_throttled, and that
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cpuacct.usage will increase roughly equal to cfs_quota_us in each period.
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For highly-threaded, non-cpu bound applications this non-expiration nuance
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allows applications to briefly burst past their quota limits by the amount of
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unused slice on each cpu that the task group is running on (typically at most
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1ms per cpu or as defined by min_cfs_rq_runtime). This slight burst only
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applies if quota had been assigned to a cpu and then not fully used or returned
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in previous periods. This burst amount will not be transferred between cores.
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As a result, this mechanism still strictly limits the task group to quota
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average usage, albeit over a longer time window than a single period. This
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also limits the burst ability to no more than 1ms per cpu. This provides
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better more predictable user experience for highly threaded applications with
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small quota limits on high core count machines. It also eliminates the
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propensity to throttle these applications while simultanously using less than
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quota amounts of cpu. Another way to say this, is that by allowing the unused
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portion of a slice to remain valid across periods we have decreased the
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possibility of wastefully expiring quota on cpu-local silos that don't need a
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full slice's amount of cpu time.
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The interaction between cpu-bound and non-cpu-bound-interactive applications
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should also be considered, especially when single core usage hits 100%. If you
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gave each of these applications half of a cpu-core and they both got scheduled
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on the same CPU it is theoretically possible that the non-cpu bound application
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will use up to 1ms additional quota in some periods, thereby preventing the
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cpu-bound application from fully using its quota by that same amount. In these
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instances it will be up to the CFS algorithm (see sched-design-CFS.rst) to
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decide which application is chosen to run, as they will both be runnable and
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have remaining quota. This runtime discrepancy will be made up in the following
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periods when the interactive application idles.
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Examples
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--------
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1. Limit a group to 1 CPU worth of runtime::
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If period is 250ms and quota is also 250ms, the group will get
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1 CPU worth of runtime every 250ms.
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# echo 250000 > cpu.cfs_quota_us /* quota = 250ms */
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# echo 250000 > cpu.cfs_period_us /* period = 250ms */
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2. Limit a group to 2 CPUs worth of runtime on a multi-CPU machine
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With 500ms period and 1000ms quota, the group can get 2 CPUs worth of
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runtime every 500ms::
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# echo 1000000 > cpu.cfs_quota_us /* quota = 1000ms */
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# echo 500000 > cpu.cfs_period_us /* period = 500ms */
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The larger period here allows for increased burst capacity.
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3. Limit a group to 20% of 1 CPU.
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With 50ms period, 10ms quota will be equivalent to 20% of 1 CPU::
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# echo 10000 > cpu.cfs_quota_us /* quota = 10ms */
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# echo 50000 > cpu.cfs_period_us /* period = 50ms */
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By using a small period here we are ensuring a consistent latency
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response at the expense of burst capacity.
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4. Limit a group to 40% of 1 CPU, and allow accumulate up to 20% of 1 CPU
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additionally, in case accumulation has been done.
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With 50ms period, 20ms quota will be equivalent to 40% of 1 CPU.
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And 10ms burst will be equivalent to 20% of 1 CPU::
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# echo 20000 > cpu.cfs_quota_us /* quota = 20ms */
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# echo 50000 > cpu.cfs_period_us /* period = 50ms */
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# echo 10000 > cpu.cfs_burst_us /* burst = 10ms */
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Larger buffer setting (no larger than quota) allows greater burst capacity.
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