| blob | 517e3719027e619e5c7b565d1de9294dfffb5a3c |
1 /*
2 * Pressure stall information for CPU, memory and IO
3 *
4 * Copyright (c) 2018 Facebook, Inc.
5 * Author: Johannes Weiner <hannes@cmpxchg.org>
6 *
7 * Polling support by Suren Baghdasaryan <surenb@google.com>
8 * Copyright (c) 2018 Google, Inc.
9 *
10 * When CPU, memory and IO are contended, tasks experience delays that
11 * reduce throughput and introduce latencies into the workload. Memory
12 * and IO contention, in addition, can cause a full loss of forward
13 * progress in which the CPU goes idle.
14 *
15 * This code aggregates individual task delays into resource pressure
16 * metrics that indicate problems with both workload health and
17 * resource utilization.
18 *
19 * Model
20 *
21 * The time in which a task can execute on a CPU is our baseline for
22 * productivity. Pressure expresses the amount of time in which this
23 * potential cannot be realized due to resource contention.
24 *
25 * This concept of productivity has two components: the workload and
26 * the CPU. To measure the impact of pressure on both, we define two
27 * contention states for a resource: SOME and FULL.
28 *
29 * In the SOME state of a given resource, one or more tasks are
30 * delayed on that resource. This affects the workload's ability to
31 * perform work, but the CPU may still be executing other tasks.
32 *
33 * In the FULL state of a given resource, all non-idle tasks are
34 * delayed on that resource such that nobody is advancing and the CPU
35 * goes idle. This leaves both workload and CPU unproductive.
36 *
37 * (Naturally, the FULL state doesn't exist for the CPU resource.)
38 *
39 * SOME = nr_delayed_tasks != 0
40 * FULL = nr_delayed_tasks != 0 && nr_running_tasks == 0
41 *
42 * The percentage of wallclock time spent in those compound stall
43 * states gives pressure numbers between 0 and 100 for each resource,
44 * where the SOME percentage indicates workload slowdowns and the FULL
45 * percentage indicates reduced CPU utilization:
46 *
47 * %SOME = time(SOME) / period
48 * %FULL = time(FULL) / period
49 *
50 * Multiple CPUs
51 *
52 * The more tasks and available CPUs there are, the more work can be
53 * performed concurrently. This means that the potential that can go
54 * unrealized due to resource contention *also* scales with non-idle
55 * tasks and CPUs.
56 *
57 * Consider a scenario where 257 number crunching tasks are trying to
58 * run concurrently on 256 CPUs. If we simply aggregated the task
59 * states, we would have to conclude a CPU SOME pressure number of
60 * 100%, since *somebody* is waiting on a runqueue at all
61 * times. However, that is clearly not the amount of contention the
62 * workload is experiencing: only one out of 256 possible exceution
63 * threads will be contended at any given time, or about 0.4%.
64 *
65 * Conversely, consider a scenario of 4 tasks and 4 CPUs where at any
66 * given time *one* of the tasks is delayed due to a lack of memory.
67 * Again, looking purely at the task state would yield a memory FULL
68 * pressure number of 0%, since *somebody* is always making forward
69 * progress. But again this wouldn't capture the amount of execution
70 * potential lost, which is 1 out of 4 CPUs, or 25%.
71 *
72 * To calculate wasted potential (pressure) with multiple processors,
73 * we have to base our calculation on the number of non-idle tasks in
74 * conjunction with the number of available CPUs, which is the number
75 * of potential execution threads. SOME becomes then the proportion of
76 * delayed tasks to possibe threads, and FULL is the share of possible
77 * threads that are unproductive due to delays:
78 *
79 * threads = min(nr_nonidle_tasks, nr_cpus)
80 * SOME = min(nr_delayed_tasks / threads, 1)
81 * FULL = (threads - min(nr_running_tasks, threads)) / threads
82 *
83 * For the 257 number crunchers on 256 CPUs, this yields:
84 *
85 * threads = min(257, 256)
86 * SOME = min(1 / 256, 1) = 0.4%
87 * FULL = (256 - min(257, 256)) / 256 = 0%
88 *
89 * For the 1 out of 4 memory-delayed tasks, this yields:
90 *
91 * threads = min(4, 4)
92 * SOME = min(1 / 4, 1) = 25%
93 * FULL = (4 - min(3, 4)) / 4 = 25%
94 *
95 * [ Substitute nr_cpus with 1, and you can see that it's a natural
96 * extension of the single-CPU model. ]
97 *
98 * Implementation
99 *
100 * To assess the precise time spent in each such state, we would have
101 * to freeze the system on task changes and start/stop the state
102 * clocks accordingly. Obviously that doesn't scale in practice.
103 *
104 * Because the scheduler aims to distribute the compute load evenly
105 * among the available CPUs, we can track task state locally to each
106 * CPU and, at much lower frequency, extrapolate the global state for
107 * the cumulative stall times and the running averages.
108 *
109 * For each runqueue, we track:
110 *
111 * tSOME[cpu] = time(nr_delayed_tasks[cpu] != 0)
112 * tFULL[cpu] = time(nr_delayed_tasks[cpu] && !nr_running_tasks[cpu])
113 * tNONIDLE[cpu] = time(nr_nonidle_tasks[cpu] != 0)
114 *
115 * and then periodically aggregate:
116 *
117 * tNONIDLE = sum(tNONIDLE[i])
118 *
119 * tSOME = sum(tSOME[i] * tNONIDLE[i]) / tNONIDLE
120 * tFULL = sum(tFULL[i] * tNONIDLE[i]) / tNONIDLE
121 *
122 * %SOME = tSOME / period
123 * %FULL = tFULL / period
124 *
125 * This gives us an approximation of pressure that is practical
126 * cost-wise, yet way more sensitive and accurate than periodic
127 * sampling of the aggregate task states would be.
128 */
131 #include <linux/sched/loadavg.h>
132 #include <linux/seq_file.h>
133 #include <linux/proc_fs.h>
134 #include <linux/seqlock.h>
135 #include <linux/uaccess.h>
136 #include <linux/cgroup.h>
137 #include <linux/module.h>
138 #include <linux/sched.h>
139 #include <linux/ctype.h>
140 #include <linux/file.h>
141 #include <linux/poll.h>
142 #include <linux/psi.h>
149 #ifdef CONFIG_PSI_DEFAULT_DISABLED
151 #else
153 #endif
155 {
157 }
160 /* Running averages - we need to be higher-res than loadavg */
166 /* PSI trigger definitions */
171 /* Sampling frequency in nanoseconds */
174 /* System-level pressure and stall tracking */
178 };
183 {
191 /* Init trigger-related members */
202 }
205 {
209 }
213 }
216 {
233 }
234 }
239 {
244 u32 state_mask;
248 /* Snapshot a coherent view of the CPU state */
257 /* Calculate state time deltas against the previous snapshot */
259 u32 delta;
260 /*
261 * In addition to already concluded states, we also
262 * incorporate currently active states on the CPU,
263 * since states may last for many sampling periods.
264 *
265 * This way we keep our delta sampling buckets small
266 * (u32) and our reported pressure close to what's
267 * actually happening.
268 */
278 }
279 }
283 {
286 /* Fill in zeroes for periods of no activity */
291 }
293 /* Sample the most recent active period */
299 }
304 {
311 /*
312 * Collect the per-cpu time buckets and average them into a
313 * single time sample that is normalized to wallclock time.
314 *
315 * For averaging, each CPU is weighted by its non-idle time in
316 * the sampling period. This eliminates artifacts from uneven
317 * loading, or even entirely idle CPUs.
318 */
321 u32 nonidle;
322 u32 cpu_changed_states;
333 }
335 /*
336 * Integrate the sample into the running statistics that are
337 * reported to userspace: the cumulative stall times and the
338 * decaying averages.
339 *
340 * Pressure percentages are sampled at PSI_FREQ. We might be
341 * called more often when the user polls more frequently than
342 * that; we might be called less often when there is no task
343 * activity, thus no data, and clock ticks are sporadic. The
344 * below handles both.
345 */
347 /* total= */
354 }
357 {
360 u64 avg_next_update;
363 /* avgX= */
368 /*
369 * The periodic clock tick can get delayed for various
370 * reasons, especially on loaded systems. To avoid clock
371 * drift, we schedule the clock in fixed psi_period intervals.
372 * But the deltas we sample out of the per-cpu buckets above
373 * are based on the actual time elapsing between clock ticks.
374 */
380 u32 sample;
383 /*
384 * Due to the lockless sampling of the time buckets,
385 * recorded time deltas can slip into the next period,
386 * which under full pressure can result in samples in
387 * excess of the period length.
388 *
389 * We don't want to report non-sensical pressures in
390 * excess of 100%, nor do we want to drop such events
391 * on the floor. Instead we punt any overage into the
392 * future until pressure subsides. By doing this we
393 * don't underreport the occurring pressure curve, we
394 * just report it delayed by one period length.
395 *
396 * The error isn't cumulative. As soon as another
397 * delta slips from a period P to P+1, by definition
398 * it frees up its time T in P.
399 */
404 }
407 }
410 {
413 u32 changed_states;
415 u64 now;
426 /*
427 * If there is task activity, periodically fold the per-cpu
428 * times and feed samples into the running averages. If things
429 * are idle and there is no data to process, stop the clock.
430 * Once restarted, we'll catch up the running averages in one
431 * go - see calc_avgs() and missed_periods.
432 */
439 }
442 }
444 /* Trigger tracking window manupulations */
446 u64 prev_growth)
447 {
451 }
453 /*
454 * PSI growth tracking window update and growth calculation routine.
455 *
456 * This approximates a sliding tracking window by interpolating
457 * partially elapsed windows using historical growth data from the
458 * previous intervals. This minimizes memory requirements (by not storing
459 * all the intermediate values in the previous window) and simplifies
460 * the calculations. It works well because PSI signal changes only in
461 * positive direction and over relatively small window sizes the growth
462 * is close to linear.
463 */
465 {
466 u64 elapsed;
467 u64 growth;
471 /*
472 * After each tracking window passes win->start_value and
473 * win->start_time get reset and win->prev_growth stores
474 * the average per-window growth of the previous window.
475 * win->prev_growth is then used to interpolate additional
476 * growth from the previous window assuming it was linear.
477 */
481 u32 remaining;
485 }
488 }
491 {
500 }
503 {
508 /*
509 * On subsequent updates, calculate growth deltas and let
510 * watchers know when their specified thresholds are exceeded.
511 */
513 u64 growth;
515 /* Check for stall activity */
519 /*
520 * Multiple triggers might be looking at the same state,
521 * remember to update group->polling_total[] once we've
522 * been through all of them. Also remember to extend the
523 * polling time if we see new stall activity.
524 */
527 /* Calculate growth since last update */
532 /* Limit event signaling to once per window */
536 /* Generate an event */
540 }
547 }
549 /*
550 * Schedule polling if it's not already scheduled. It's safe to call even from
551 * hotpath because even though kthread_queue_delayed_work takes worker->lock
552 * spinlock that spinlock is never contended due to poll_scheduled atomic
553 * preventing such competition.
554 */
556 {
559 /* Do not reschedule if already scheduled */
566 /*
567 * kworker might be NULL in case psi_trigger_destroy races with
568 * psi_task_change (hotpath) which can't use locks
569 */
572 else
576 }
579 {
582 u32 changed_states;
583 u64 now;
597 /* Initialize trigger windows when entering polling mode */
601 /*
602 * Keep the monitor active for at least the duration of the
603 * minimum tracking window as long as monitor states are
604 * changing.
605 */
608 }
613 }
621 out:
623 }
627 {
628 u32 delta;
629 u64 now;
639 }
646 u32 sample;
647 /*
648 * Since we care about lost potential, a
649 * memstall is FULL when there are no other
650 * working tasks, but also when the CPU is
651 * actively reclaiming and nothing productive
652 * could run even if it were runnable.
653 *
654 * When the timer tick sees a reclaiming CPU,
655 * regardless of runnable tasks, sample a FULL
656 * tick (or less if it hasn't been a full tick
657 * since the last state change).
658 */
661 }
662 }
669 }
673 {
681 /*
682 * First we assess the aggregate resource states this CPU's
683 * tasks have been in since the last change, and account any
684 * SOME and FULL time these may have resulted in.
685 *
686 * Then we update the task counts according to the state
687 * change requested through the @clear and @set bits.
688 */
702 }
704 }
710 /* Calculate state mask representing active states */
714 }
720 }
723 {
724 #ifdef CONFIG_CGROUPS
731 else
737 }
738 #else
741 #endif
744 }
747 {
759 printk_deferred(KERN_ERR "psi: inconsistent task state! task=%d:%s cpu=%d psi_flags=%x clear=%x set=%x\n",
763 }
768 /*
769 * Periodic aggregation shuts off if there is a period of no
770 * task changes, so we wake it back up if necessary. However,
771 * don't do this if the task change is the aggregation worker
772 * itself going to sleep, or we'll ping-pong forever.
773 */
787 }
788 }
791 {
802 }
803 }
805 /**
806 * psi_memstall_enter - mark the beginning of a memory stall section
807 * @flags: flags to handle nested sections
808 *
809 * Marks the calling task as being stalled due to a lack of memory,
810 * such as waiting for a refault or performing reclaim.
811 */
813 {
823 /*
824 * PF_MEMSTALL setting & accounting needs to be atomic wrt
825 * changes to the task's scheduling state, otherwise we can
826 * race with CPU migration.
827 */
834 }
836 /**
837 * psi_memstall_leave - mark the end of an memory stall section
838 * @flags: flags to handle nested memdelay sections
839 *
840 * Marks the calling task as no longer stalled due to lack of memory.
841 */
843 {
852 /*
853 * PF_MEMSTALL clearing & accounting needs to be atomic wrt
854 * changes to the task's scheduling state, otherwise we could
855 * race with CPU migration.
856 */
863 }
865 #ifdef CONFIG_CGROUPS
867 {
876 }
879 {
885 /* All triggers must be removed by now */
887 }
889 /**
890 * cgroup_move_task - move task to a different cgroup
891 * @task: the task
892 * @to: the target css_set
893 *
894 * Move task to a new cgroup and safely migrate its associated stall
895 * state between the different groups.
896 *
897 * This function acquires the task's rq lock to lock out concurrent
898 * changes to the task's scheduling state and - in case the task is
899 * running - concurrent changes to its stall state.
900 */
902 {
908 /*
909 * Lame to do this here, but the scheduler cannot be locked
910 * from the outside, so we move cgroups from inside sched/.
911 */
914 }
929 /* See comment above */
936 }
940 {
942 u64 now;
947 /* Update averages before reporting them */
957 u64 total;
963 NSEC_PER_USEC);
970 total);
971 }
974 }
977 {
979 }
982 {
984 }
987 {
989 }
992 {
994 }
997 {
999 }
1002 {
1004 }
1008 {
1011 u32 threshold_us;
1012 u32 window_us;
1021 else
1031 /* Check threshold */
1055 };
1063 }
1066 psi_poll_work);
1068 }
1079 }
1082 {
1090 /*
1091 * Wakeup waiters to stop polling. Can happen if cgroup is deleted
1092 * from under a polling process.
1093 */
1106 /* reset min update period for the remaining triggers */
1109 UPDATES_PER_WINDOW));
1111 /* Destroy poll_kworker when the last trigger is destroyed */
1118 }
1119 }
1123 /*
1124 * Wait for both *trigger_ptr from psi_trigger_replace and
1125 * poll_kworker RCUs to complete their read-side critical sections
1126 * before destroying the trigger and optionally the poll_kworker
1127 */
1129 /*
1130 * Destroy the kworker after releasing trigger_lock to prevent a
1131 * deadlock while waiting for psi_poll_work to acquire trigger_lock
1132 */
1134 /*
1135 * After the RCU grace period has expired, the worker
1136 * can no longer be found through group->poll_kworker.
1137 * But it might have been already scheduled before
1138 * that - deschedule it cleanly before destroying it.
1139 */
1144 }
1146 }
1149 {
1158 }
1162 {
1175 }
1188 }
1192 {
1212 /* Take seq->lock to protect seq->private from concurrent writes */
1218 }
1222 {
1224 }
1228 {
1230 }
1234 {
1236 }
1239 {
1243 }
1246 {
1251 }
1260 };
1269 };
1278 };
1281 {
1287 }