| blob | 28f80d22752858a2b1fcdfefb5f079469ec480ee |
1 /*
2 * Block rq-qos base io controller
3 *
4 * This works similar to wbt with a few exceptions
5 *
6 * - It's bio based, so the latency covers the whole block layer in addition to
7 * the actual io.
8 * - We will throttle all IO that comes in here if we need to.
9 * - We use the mean latency over the 100ms window. This is because writes can
10 * be particularly fast, which could give us a false sense of the impact of
11 * other workloads on our protected workload.
12 * - By default there's no throttling, we set the queue_depth to UINT_MAX so
13 * that we can have as many outstanding bio's as we're allowed to. Only at
14 * throttle time do we pay attention to the actual queue depth.
15 *
16 * The hierarchy works like the cpu controller does, we track the latency at
17 * every configured node, and each configured node has it's own independent
18 * queue depth. This means that we only care about our latency targets at the
19 * peer level. Some group at the bottom of the hierarchy isn't going to affect
20 * a group at the end of some other path if we're only configred at leaf level.
21 *
22 * Consider the following
23 *
24 * root blkg
25 * / \
26 * fast (target=5ms) slow (target=10ms)
27 * / \ / \
28 * a b normal(15ms) unloved
29 *
30 * "a" and "b" have no target, but their combined io under "fast" cannot exceed
31 * an average latency of 5ms. If it does then we will throttle the "slow"
32 * group. In the case of "normal", if it exceeds its 15ms target, we will
33 * throttle "unloved", but nobody else.
34 *
35 * In this example "fast", "slow", and "normal" will be the only groups actually
36 * accounting their io latencies. We have to walk up the heirarchy to the root
37 * on every submit and complete so we can do the appropriate stat recording and
38 * adjust the queue depth of ourselves if needed.
39 *
40 * There are 2 ways we throttle IO.
41 *
42 * 1) Queue depth throttling. As we throttle down we will adjust the maximum
43 * number of IO's we're allowed to have in flight. This starts at (u64)-1 down
44 * to 1. If the group is only ever submitting IO for itself then this is the
45 * only way we throttle.
46 *
47 * 2) Induced delay throttling. This is for the case that a group is generating
48 * IO that has to be issued by the root cg to avoid priority inversion. So think
49 * REQ_META or REQ_SWAP. If we are already at qd == 1 and we're getting a lot
50 * of work done for us on behalf of the root cg and are being asked to scale
51 * down more then we induce a latency at userspace return. We accumulate the
52 * total amount of time we need to be punished by doing
53 *
54 * total_time += min_lat_nsec - actual_io_completion
55 *
56 * and then at throttle time will do
57 *
58 * throttle_time = min(total_time, NSEC_PER_SEC)
59 *
60 * This induced delay will throttle back the activity that is generating the
61 * root cg issued io's, wethere that's some metadata intensive operation or the
62 * group is using so much memory that it is pushing us into swap.
63 *
64 * Copyright (C) 2018 Josef Bacik
65 */
66 #include <linux/kernel.h>
67 #include <linux/blk_types.h>
68 #include <linux/backing-dev.h>
69 #include <linux/module.h>
70 #include <linux/timer.h>
71 #include <linux/memcontrol.h>
72 #include <linux/sched/loadavg.h>
73 #include <linux/sched/signal.h>
74 #include <trace/events/block.h>
78 #define DEFAULT_SCALE_COOKIE 1000000U
86 atomic_t enabled;
87 };
90 {
92 }
95 {
97 }
100 spinlock_t lock;
102 /* Last time we adjusted the scale of everybody. */
103 u64 last_scale_event;
105 /* The latency that we missed. */
106 u64 scale_lat;
108 /* Total io's from all of our children for the last summation. */
109 u64 nr_samples;
111 /* The guy who actually changed the latency numbers. */
114 /* Cookie to tell if we need to scale up or down. */
115 atomic_t scale_cookie;
116 };
119 u64 total;
120 u64 missed;
121 };
127 };
128 };
137 atomic64_t window_start;
138 atomic_t scale_cookie;
139 u64 min_lat_nsec;
140 u64 cur_win_nsec;
142 /* total running average of our io latency. */
143 u64 lat_avg;
145 /* Our current number of IO's for the last summation. */
146 u64 nr_samples;
150 };
152 #define BLKIOLATENCY_MIN_WIN_SIZE (100 * NSEC_PER_MSEC)
153 #define BLKIOLATENCY_MAX_WIN_SIZE NSEC_PER_SEC
154 /*
155 * These are the constants used to fake the fixed-point moving average
156 * calculation just like load average. The call to calc_load() folds
157 * (FIXED_1 (2048) - exp_factor) * new_sample into lat_avg. The sampling
158 * window size is bucketed to try to approximately calculate average
159 * latency such that 1/exp (decay rate) is [1 min, 2.5 min) when windows
160 * elapse immediately. Note, windows only elapse with IO activity. Idle
161 * periods extend the most recent window.
162 */
163 #define BLKIOLATENCY_NR_EXP_FACTORS 5
164 #define BLKIOLATENCY_EXP_BUCKET_SIZE (BLKIOLATENCY_MAX_WIN_SIZE / \
165 (BLKIOLATENCY_NR_EXP_FACTORS - 1))
172 };
175 {
177 }
180 {
182 }
185 {
187 }
191 {
197 }
202 {
208 }
211 u64 req_time)
212 {
221 }
225 {
230 }
232 }
236 {
240 }
244 {
250 /*
251 * calc_load() takes in a number stored in fixed point representation.
252 * Because we are using this for IO time in ns, the values stored
253 * are significantly larger than the FIXED_1 denominator (2048).
254 * Therefore, rounding errors in the calculation are negligible and
255 * can be ignored.
256 */
259 BLKIOLATENCY_EXP_BUCKET_SIZE));
263 }
268 {
275 }
283 {
292 /*
293 * To avoid priority inversions we want to just take a slot if we are
294 * issuing as root. If we're being killed off there's no point in
295 * delaying things, we may have been killed by OOM so throttling may
296 * make recovery take even longer, so just let the IO's through so the
297 * task can go away.
298 */
302 }
309 TASK_UNINTERRUPTIBLE);
321 }
325 }
327 #define SCALE_DOWN_FACTOR 2
328 #define SCALE_UP_FACTOR 4
331 {
333 }
335 /*
336 * We scale the qd down faster than we scale up, so we need to use this helper
337 * to adjust the scale_cookie accordingly so we don't prematurely get
338 * scale_cookie at DEFAULT_SCALE_COOKIE and unthrottle too much.
339 *
340 * Each group has their own local copy of the last scale cookie they saw, so if
341 * the global scale cookie goes up or down they know which way they need to go
342 * based on their last knowledge of it.
343 */
347 {
360 DEFAULT_SCALE_COOKIE);
363 else
366 /*
367 * We don't want to dig a hole so deep that it takes us hours to
368 * dig out of it. Just enough that we don't throttle/unthrottle
369 * with jagged workloads but can still unthrottle once pressure
370 * has sufficiently dissipated.
371 */
377 }
378 }
379 }
381 /*
382 * Change the queue depth of the iolatency_grp. We add/subtract 1/16th of the
383 * queue depth at a time so we don't get wild swings and hopefully dial in to
384 * fairer distribution of the overall queue depth.
385 */
387 {
404 }
408 }
409 }
411 /* Check our parent and see if the scale cookie has changed. */
413 {
418 u64 scale_lat;
437 else
442 /* Somebody beat us to the punch, just bail. */
447 u64 samples_thresh;
452 /*
453 * Sometimes high priority groups are their own worst enemy, so
454 * instead of taking it out on some poor other group that did 5%
455 * or less of the IO's for the last summation just skip this
456 * scale down event.
457 */
462 }
464 /* We're as low as we can go. */
468 }
470 /* We're back to the default cookie, unthrottle all the things. */
476 }
479 }
483 {
496 }
502 }
505 }
510 {
512 u64 req_time;
514 /*
515 * Have to do this so we are truncated to the correct time that our
516 * issue is truncated to.
517 */
525 /*
526 * We don't want to count issue_as_root bio's in the cgroups latency
527 * statistics as it could skew the numbers downwards.
528 */
534 }
537 }
539 #define BLKIOLATENCY_MIN_ADJUST_TIME (500 * NSEC_PER_MSEC)
540 #define BLKIOLATENCY_MIN_GOOD_SAMPLES 5
543 {
558 }
569 /* Everything is ok and we don't need to adjust the scale. */
574 /* Somebody beat us to the punch, just bail. */
589 BLKIOLATENCY_MIN_GOOD_SAMPLES)
594 }
602 }
604 }
606 out:
608 }
611 {
615 u64 window_start;
634 }
641 issue_as_root);
648 }
649 next:
652 }
653 }
656 {
671 next:
673 }
674 }
677 {
683 }
690 };
693 {
705 u64 cookie;
707 /*
708 * We could be exiting, don't access the pd unless we have a
709 * ref on the blkg.
710 */
728 /*
729 * We scaled down but don't have a scale_grp, scale up and carry
730 * on.
731 */
735 }
737 /*
738 * It's been 5 seconds since our last scale event, clear the
739 * scale grp in case the group that needed the scale down isn't
740 * doing any IO currently.
741 */
745 next_lock:
747 next:
749 }
751 }
754 {
775 }
780 }
783 {
791 BLKIOLATENCY_MAX_WIN_SIZE);
797 }
800 {
814 }
815 }
819 {
826 u64 oldval;
845 u64 v;
851 else
855 }
856 }
858 /* Walk up the tree to see if our new val is lower than it should be. */
865 }
868 out:
871 }
875 {
884 }
887 {
889 iolatency_prfill_limit,
892 }
896 {
906 }
917 }
921 {
937 }
941 {
952 }
954 }
957 {
967 else
974 }
986 /*
987 * We init things in list order, so the pd for the parent may not be
988 * init'ed yet for whatever reason.
989 */
996 }
999 }
1002 {
1008 }
1011 {
1015 }
1018 {
1023 },
1024 {}
1025 };
1034 };
1037 {
1039 }
1042 {
1044 }