| blob | e01267f9918390f38424337140778c2c983bb7a4 |
1 /* SPDX-License-Identifier: GPL-2.0
2 *
3 * IO cost model based controller.
4 *
5 * Copyright (C) 2019 Tejun Heo <tj@kernel.org>
6 * Copyright (C) 2019 Andy Newell <newella@fb.com>
7 * Copyright (C) 2019 Facebook
8 *
9 * One challenge of controlling IO resources is the lack of trivially
10 * observable cost metric. This is distinguished from CPU and memory where
11 * wallclock time and the number of bytes can serve as accurate enough
12 * approximations.
13 *
14 * Bandwidth and iops are the most commonly used metrics for IO devices but
15 * depending on the type and specifics of the device, different IO patterns
16 * easily lead to multiple orders of magnitude variations rendering them
17 * useless for the purpose of IO capacity distribution. While on-device
18 * time, with a lot of clutches, could serve as a useful approximation for
19 * non-queued rotational devices, this is no longer viable with modern
20 * devices, even the rotational ones.
21 *
22 * While there is no cost metric we can trivially observe, it isn't a
23 * complete mystery. For example, on a rotational device, seek cost
24 * dominates while a contiguous transfer contributes a smaller amount
25 * proportional to the size. If we can characterize at least the relative
26 * costs of these different types of IOs, it should be possible to
27 * implement a reasonable work-conserving proportional IO resource
28 * distribution.
29 *
30 * 1. IO Cost Model
31 *
32 * IO cost model estimates the cost of an IO given its basic parameters and
33 * history (e.g. the end sector of the last IO). The cost is measured in
34 * device time. If a given IO is estimated to cost 10ms, the device should
35 * be able to process ~100 of those IOs in a second.
36 *
37 * Currently, there's only one builtin cost model - linear. Each IO is
38 * classified as sequential or random and given a base cost accordingly.
39 * On top of that, a size cost proportional to the length of the IO is
40 * added. While simple, this model captures the operational
41 * characteristics of a wide varienty of devices well enough. Default
42 * paramters for several different classes of devices are provided and the
43 * parameters can be configured from userspace via
44 * /sys/fs/cgroup/io.cost.model.
45 *
46 * If needed, tools/cgroup/iocost_coef_gen.py can be used to generate
47 * device-specific coefficients.
48 *
49 * If needed, tools/cgroup/iocost_coef_gen.py can be used to generate
50 * device-specific coefficients.
51 *
52 * 2. Control Strategy
53 *
54 * The device virtual time (vtime) is used as the primary control metric.
55 * The control strategy is composed of the following three parts.
56 *
57 * 2-1. Vtime Distribution
58 *
59 * When a cgroup becomes active in terms of IOs, its hierarchical share is
60 * calculated. Please consider the following hierarchy where the numbers
61 * inside parentheses denote the configured weights.
62 *
63 * root
64 * / \
65 * A (w:100) B (w:300)
66 * / \
67 * A0 (w:100) A1 (w:100)
68 *
69 * If B is idle and only A0 and A1 are actively issuing IOs, as the two are
70 * of equal weight, each gets 50% share. If then B starts issuing IOs, B
71 * gets 300/(100+300) or 75% share, and A0 and A1 equally splits the rest,
72 * 12.5% each. The distribution mechanism only cares about these flattened
73 * shares. They're called hweights (hierarchical weights) and always add
74 * upto 1 (HWEIGHT_WHOLE).
75 *
76 * A given cgroup's vtime runs slower in inverse proportion to its hweight.
77 * For example, with 12.5% weight, A0's time runs 8 times slower (100/12.5)
78 * against the device vtime - an IO which takes 10ms on the underlying
79 * device is considered to take 80ms on A0.
80 *
81 * This constitutes the basis of IO capacity distribution. Each cgroup's
82 * vtime is running at a rate determined by its hweight. A cgroup tracks
83 * the vtime consumed by past IOs and can issue a new IO iff doing so
84 * wouldn't outrun the current device vtime. Otherwise, the IO is
85 * suspended until the vtime has progressed enough to cover it.
86 *
87 * 2-2. Vrate Adjustment
88 *
89 * It's unrealistic to expect the cost model to be perfect. There are too
90 * many devices and even on the same device the overall performance
91 * fluctuates depending on numerous factors such as IO mixture and device
92 * internal garbage collection. The controller needs to adapt dynamically.
93 *
94 * This is achieved by adjusting the overall IO rate according to how busy
95 * the device is. If the device becomes overloaded, we're sending down too
96 * many IOs and should generally slow down. If there are waiting issuers
97 * but the device isn't saturated, we're issuing too few and should
98 * generally speed up.
99 *
100 * To slow down, we lower the vrate - the rate at which the device vtime
101 * passes compared to the wall clock. For example, if the vtime is running
102 * at the vrate of 75%, all cgroups added up would only be able to issue
103 * 750ms worth of IOs per second, and vice-versa for speeding up.
104 *
105 * Device business is determined using two criteria - rq wait and
106 * completion latencies.
107 *
108 * When a device gets saturated, the on-device and then the request queues
109 * fill up and a bio which is ready to be issued has to wait for a request
110 * to become available. When this delay becomes noticeable, it's a clear
111 * indication that the device is saturated and we lower the vrate. This
112 * saturation signal is fairly conservative as it only triggers when both
113 * hardware and software queues are filled up, and is used as the default
114 * busy signal.
115 *
116 * As devices can have deep queues and be unfair in how the queued commands
117 * are executed, soley depending on rq wait may not result in satisfactory
118 * control quality. For a better control quality, completion latency QoS
119 * parameters can be configured so that the device is considered saturated
120 * if N'th percentile completion latency rises above the set point.
121 *
122 * The completion latency requirements are a function of both the
123 * underlying device characteristics and the desired IO latency quality of
124 * service. There is an inherent trade-off - the tighter the latency QoS,
125 * the higher the bandwidth lossage. Latency QoS is disabled by default
126 * and can be set through /sys/fs/cgroup/io.cost.qos.
127 *
128 * 2-3. Work Conservation
129 *
130 * Imagine two cgroups A and B with equal weights. A is issuing a small IO
131 * periodically while B is sending out enough parallel IOs to saturate the
132 * device on its own. Let's say A's usage amounts to 100ms worth of IO
133 * cost per second, i.e., 10% of the device capacity. The naive
134 * distribution of half and half would lead to 60% utilization of the
135 * device, a significant reduction in the total amount of work done
136 * compared to free-for-all competition. This is too high a cost to pay
137 * for IO control.
138 *
139 * To conserve the total amount of work done, we keep track of how much
140 * each active cgroup is actually using and yield part of its weight if
141 * there are other cgroups which can make use of it. In the above case,
142 * A's weight will be lowered so that it hovers above the actual usage and
143 * B would be able to use the rest.
144 *
145 * As we don't want to penalize a cgroup for donating its weight, the
146 * surplus weight adjustment factors in a margin and has an immediate
147 * snapback mechanism in case the cgroup needs more IO vtime for itself.
148 *
149 * Note that adjusting down surplus weights has the same effects as
150 * accelerating vtime for other cgroups and work conservation can also be
151 * implemented by adjusting vrate dynamically. However, squaring who can
152 * donate and should take back how much requires hweight propagations
153 * anyway making it easier to implement and understand as a separate
154 * mechanism.
155 *
156 * 3. Monitoring
157 *
158 * Instead of debugfs or other clumsy monitoring mechanisms, this
159 * controller uses a drgn based monitoring script -
160 * tools/cgroup/iocost_monitor.py. For details on drgn, please see
161 * https://github.com/osandov/drgn. The ouput looks like the following.
162 *
163 * sdb RUN per=300ms cur_per=234.218:v203.695 busy= +1 vrate= 62.12%
164 * active weight hweight% inflt% dbt delay usages%
165 * test/a * 50/ 50 33.33/ 33.33 27.65 2 0*041 033:033:033
166 * test/b * 100/ 100 66.67/ 66.67 17.56 0 0*000 066:079:077
167 *
168 * - per : Timer period
169 * - cur_per : Internal wall and device vtime clock
170 * - vrate : Device virtual time rate against wall clock
171 * - weight : Surplus-adjusted and configured weights
172 * - hweight : Surplus-adjusted and configured hierarchical weights
173 * - inflt : The percentage of in-flight IO cost at the end of last period
174 * - del_ms : Deferred issuer delay induction level and duration
175 * - usages : Usage history
176 */
178 #include <linux/kernel.h>
179 #include <linux/module.h>
180 #include <linux/timer.h>
181 #include <linux/time64.h>
182 #include <linux/parser.h>
183 #include <linux/sched/signal.h>
184 #include <linux/blk-cgroup.h>
189 #ifdef CONFIG_TRACEPOINTS
191 /* copied from TRACE_CGROUP_PATH, see cgroup-internal.h */
192 #define TRACE_IOCG_PATH_LEN 1024
196 #define TRACE_IOCG_PATH(type, iocg, ...) \
197 do { \
198 unsigned long flags; \
199 if (trace_iocost_##type##_enabled()) { \
200 spin_lock_irqsave(&trace_iocg_path_lock, flags); \
201 cgroup_path(iocg_to_blkg(iocg)->blkcg->css.cgroup, \
202 trace_iocg_path, TRACE_IOCG_PATH_LEN); \
203 trace_iocost_##type(iocg, trace_iocg_path, \
204 ##__VA_ARGS__); \
205 spin_unlock_irqrestore(&trace_iocg_path_lock, flags); \
206 } \
207 } while (0)
210 #define TRACE_IOCG_PATH(type, iocg, ...) do { } while (0)
216 /* timer period is calculated from latency requirements, bound it */
220 /*
221 * A cgroup's vtime can run 50% behind the device vtime, which
222 * serves as its IO credit buffer. Surplus weight adjustment is
223 * immediately canceled if the vtime margin runs below 10%.
224 */
228 /* Have some play in waitq timer operations */
231 /*
232 * vtime can wrap well within a reasonable uptime when vrate is
233 * consistently raised. Don't trust recorded cgroup vtime if the
234 * period counter indicates that it's older than 5mins.
235 */
238 /*
239 * Remember the past three non-zero usages and use the max for
240 * surplus calculation. Three slots guarantee that we remember one
241 * full period usage from the last active stretch even after
242 * partial deactivation and re-activation periods. Don't start
243 * giving away weight before collecting two data points to prevent
244 * hweight adjustments based on one partial activation period.
245 */
249 /* 1/64k is granular enough and can easily be handled w/ u32 */
252 /*
253 * As vtime is used to calculate the cost of each IO, it needs to
254 * be fairly high precision. For example, it should be able to
255 * represent the cost of a single page worth of discard with
256 * suffificient accuracy. At the same time, it should be able to
257 * represent reasonably long enough durations to be useful and
258 * convenient during operation.
259 *
260 * 1s worth of vtime is 2^37. This gives us both sub-nanosecond
261 * granularity and days of wrap-around time even at extreme vrates.
262 */
267 /* bound vrate adjustments within two orders of magnitude */
274 /* if IOs end up waiting for requests, issue less */
277 /* unbusy hysterisis */
280 /* don't let cmds which take a very long time pin lagging for too long */
283 /*
284 * If usage% * 1.25 + 2% is lower than hweight% by more than 3%,
285 * donate the surplus.
286 */
291 /* switch iff the conditions are met for longer than this */
294 /*
295 * Count IO size in 4k pages. The 12bit shift helps keeping
296 * size-proportional components of cost calculation in closer
297 * numbers of digits to per-IO cost components.
298 */
303 /* if apart further than 16M, consider randio for linear model */
305 };
308 IOC_IDLE,
309 IOC_RUNNING,
310 IOC_STOP,
311 };
313 /* io.cost.qos controls including per-dev enable of the whole controller */
315 QOS_ENABLE,
316 QOS_CTRL,
317 NR_QOS_CTRL_PARAMS,
318 };
320 /* io.cost.qos params */
322 QOS_RPPM,
323 QOS_RLAT,
324 QOS_WPPM,
325 QOS_WLAT,
326 QOS_MIN,
327 QOS_MAX,
328 NR_QOS_PARAMS,
329 };
331 /* io.cost.model controls */
333 COST_CTRL,
334 COST_MODEL,
335 NR_COST_CTRL_PARAMS,
336 };
338 /* builtin linear cost model coefficients */
340 I_LCOEF_RBPS,
341 I_LCOEF_RSEQIOPS,
342 I_LCOEF_RRANDIOPS,
343 I_LCOEF_WBPS,
344 I_LCOEF_WSEQIOPS,
345 I_LCOEF_WRANDIOPS,
346 NR_I_LCOEFS,
347 };
350 LCOEF_RPAGE,
351 LCOEF_RSEQIO,
352 LCOEF_RRANDIO,
353 LCOEF_WPAGE,
354 LCOEF_WSEQIO,
355 LCOEF_WRANDIO,
356 NR_LCOEFS,
357 };
360 AUTOP_INVALID,
361 AUTOP_HDD,
362 AUTOP_SSD_QD1,
363 AUTOP_SSD_DFL,
364 AUTOP_SSD_FAST,
365 };
373 u32 too_fast_vrate_pct;
374 u32 too_slow_vrate_pct;
375 };
378 u32 nr_met;
379 u32 nr_missed;
380 u32 last_met;
381 u32 last_missed;
382 };
387 u64 rq_wait_ns;
388 u64 last_rq_wait_ns;
389 };
391 /* per device */
398 u32 period_us;
399 u32 margin_us;
400 u64 vrate_min;
401 u64 vrate_max;
403 spinlock_t lock;
409 atomic64_t vtime_rate;
411 seqcount_t period_seqcount;
418 u64 inuse_margin_vtime;
422 u64 autop_too_fast_at;
423 u64 autop_too_slow_at;
427 };
429 /* per device-cgroup pair */
434 /*
435 * A iocg can get its weight from two sources - an explicit
436 * per-device-cgroup configuration or the default weight of the
437 * cgroup. `cfg_weight` is the explicit per-device-cgroup
438 * configuration. `weight` is the effective considering both
439 * sources.
440 *
441 * When an idle cgroup becomes active its `active` goes from 0 to
442 * `weight`. `inuse` is the surplus adjusted active weight.
443 * `active` and `inuse` are used to calculate `hweight_active` and
444 * `hweight_inuse`.
445 *
446 * `last_inuse` remembers `inuse` while an iocg is idle to persist
447 * surplus adjustments.
448 */
449 u32 cfg_weight;
450 u32 weight;
451 u32 active;
452 u32 inuse;
453 u32 last_inuse;
457 /*
458 * `vtime` is this iocg's vtime cursor which progresses as IOs are
459 * issued. If lagging behind device vtime, the delta represents
460 * the currently available IO budget. If runnning ahead, the
461 * overage.
462 *
463 * `vtime_done` is the same but progressed on completion rather
464 * than issue. The delta behind `vtime` represents the cost of
465 * currently in-flight IOs.
466 *
467 * `last_vtime` is used to remember `vtime` at the end of the last
468 * period to calculate utilization.
469 */
470 atomic64_t vtime;
471 atomic64_t done_vtime;
472 atomic64_t abs_vdebt;
473 u64 last_vtime;
475 /*
476 * The period this iocg was last active in. Used for deactivation
477 * and invalidating `vtime`.
478 */
479 atomic64_t active_period;
482 /* see __propagate_active_weight() and current_hweight() for details */
483 u64 child_active_sum;
484 u64 child_inuse_sum;
486 u32 hweight_active;
487 u32 hweight_inuse;
494 /* usage is recorded as fractions of HWEIGHT_WHOLE */
498 /* this iocg's depth in the hierarchy and ancestors including self */
501 };
503 /* per cgroup */
507 };
510 u64 now_ns;
511 u32 now;
512 u64 vnow;
513 u64 vrate;
514 };
519 u64 abs_cost;
521 };
525 u32 hw_inuse;
526 s64 vbudget;
527 };
536 },
544 },
545 },
552 },
560 },
561 },
568 },
576 },
578 },
585 },
593 },
595 },
596 };
598 /*
599 * vrate adjust percentages indexed by ioc->busy_level. We adjust up on
600 * vtime credit shortage and down on device saturation.
601 */
610 /* accessors and helpers */
612 {
614 }
617 {
619 }
622 {
625 else
627 }
630 {
632 }
635 {
637 }
640 {
642 }
645 {
647 }
650 {
653 }
655 /*
656 * Scale @abs_cost to the inverse of @hw_inuse. The lower the hierarchical
657 * weight, the more expensive each IO. Must round up.
658 */
660 {
662 }
664 /*
665 * The inverse of abs_cost_to_cost(). Must round up.
666 */
668 {
670 }
673 {
676 }
678 #define CREATE_TRACE_POINTS
679 #include <trace/events/iocost.h>
681 /* latency Qos params changed, update period_us and all the dependent params */
683 {
688 /* pick the higher latency target */
695 }
697 /*
698 * We want the period to be long enough to contain a healthy number
699 * of IOs while short enough for granular control. Define it as a
700 * multiple of the latency target. Ideally, the multiplier should
701 * be scaled according to the percentile so that it would nominally
702 * contain a certain number of requests. Let's be simpler and
703 * scale it linearly so that it's 2x >= pct(90) and 10x at pct(50).
704 */
707 else
712 /* calculate dependent params */
717 }
720 {
723 u32 vrate_pct;
724 u64 now_ns;
726 /* rotational? */
730 /* handle SATA SSDs w/ broken NCQ */
734 /* use one of the normal ssd sets */
738 /* if user is overriding anything, maintain what was there */
742 /* step up/down based on the vrate */
744 VTIME_PER_USEC);
754 }
763 }
766 }
768 /*
769 * Take the followings as input
770 *
771 * @bps maximum sequential throughput
772 * @seqiops maximum sequential 4k iops
773 * @randiops maximum random 4k iops
774 *
775 * and calculate the linear model cost coefficients.
776 *
777 * *@page per-page cost 1s / (@bps / 4096)
778 * *@seqio base cost of a seq IO max((1s / @seqiops) - *@page, 0)
779 * @randiops base cost of a rand IO max((1s / @randiops) - *@page, 0)
780 */
783 {
784 u64 v;
796 }
802 }
803 }
806 {
814 }
817 {
850 }
852 /* take a snapshot of the current [v]time and vrate */
854 {
861 /*
862 * The current vtime is
863 *
864 * vtime at period start + (wallclock time since the start) * vrate
865 *
866 * As a consistent snapshot of `period_at_vtime` and `period_at` is
867 * needed, they're seqcount protected.
868 */
874 }
877 {
888 }
890 /*
891 * Update @iocg's `active` and `inuse` to @active and @inuse, update level
892 * weight sums and propagate upwards accordingly.
893 */
895 {
908 /* update the level sums */
911 /* apply the udpates */
915 /*
916 * The delta between inuse and active sums indicates that
917 * that much of weight is being given away. Parent's inuse
918 * and active should reflect the ratio.
919 */
925 }
927 /* do we need to keep walking up? */
934 }
937 }
940 {
944 /* paired with rmb in current_hweight(), see there */
948 }
949 }
952 {
955 }
958 {
964 /* hot path - if uptodate, use cached */
969 /*
970 * Paired with wmb in commit_active_weights(). If we saw the
971 * updated hweight_gen, all the weight updates from
972 * __propagate_active_weight() are visible too.
973 *
974 * We can race with weight updates during calculation and get it
975 * wrong. However, hweight_gen would have changed and a future
976 * reader will recalculate and we're guaranteed to discard the
977 * wrong result soon.
978 */
990 /* we can race with deactivations and either may read as zero */
999 }
1004 out:
1009 }
1012 {
1016 u32 weight;
1025 }
1028 {
1034 /*
1035 * If seem to be already active, just update the stamp to tell the
1036 * timer that we're still active. We don't mind occassional races.
1037 */
1044 }
1046 /* racy check on internal node IOs, treat as root level IOs */
1054 /* update period */
1059 /* already activated or breaking leaf-only constraint? */
1069 /*
1070 * vtime may wrap when vrate is raised substantially due to
1071 * underestimated IO costs. Look at the period and ignore its
1072 * vtime if the iocg has been idle for too long. Also, cap the
1073 * budget it can start with to the margin.
1074 */
1085 }
1087 /*
1088 * Activate, propagate weight and start period timer if not
1089 * running. Reset hweight_gen to avoid accidental match from
1090 * wrapping.
1091 */
1105 }
1107 succeed_unlock:
1111 fail_unlock:
1114 }
1118 {
1130 /*
1131 * autoremove_wake_function() removes the wait entry only when it
1132 * actually changed the task state. We want the wait always
1133 * removed. Remove explicitly and use default_wake_function().
1134 */
1140 }
1143 {
1149 s64 vbudget;
1150 u32 hw_inuse;
1157 /* pay off debt */
1163 abs_vdebt);
1170 }
1172 /*
1173 * Wake up the ones which are due and see how much vtime we'll need
1174 * for the next one.
1175 */
1184 /* determine next wakeup, add a quarter margin to guarantee chunking */
1190 /* if already active and close enough, don't bother */
1198 }
1201 {
1213 }
1216 {
1223 u32 hw_inuse;
1225 /* debt-adjust vtime */
1229 /* clear or maintain depending on the overage */
1233 }
1238 /* use delay */
1243 }
1249 /* if already active and close enough, don't bother */
1257 }
1260 {
1268 }
1271 {
1279 u64 this_rq_wait_ns;
1289 }
1294 }
1301 else
1303 }
1307 }
1309 /* was iocg idle this period? */
1311 {
1314 /* did something get issued this period? */
1319 /* is something in flight? */
1324 }
1326 /* returns usage with margin added if surplus is large enough */
1328 {
1329 /* add margin */
1333 /* don't bother if the surplus is too small */
1338 }
1341 {
1349 u64 period_vtime;
1352 /* how were the latencies during the period? */
1355 /* take care of active iocgs */
1364 }
1366 /*
1367 * Waiters determine the sleep durations based on the vrate they
1368 * saw at the time of sleep. If vrate has increased, some waiters
1369 * could be sleeping for too long. Wake up tardy waiters which
1370 * should have woken up in the last period and expire idle iocgs.
1371 */
1381 /* might be oversleeping vtime / hweight changes, kick */
1385 /* no waiter and idle, deactivate */
1389 }
1392 }
1395 /* calc usages and see whether some weights need to be moved around */
1400 /*
1401 * Collect unused and wind vtime closer to vnow to prevent
1402 * iocgs from accumulating a large amount of budget.
1403 */
1408 /*
1409 * Latency QoS detection doesn't account for IOs which are
1410 * in-flight for longer than a period. Detect them by
1411 * comparing vdone against period start. If lagging behind
1412 * IOs from past periods, don't increase vrate.
1413 */
1420 nr_lagging++;
1426 else
1430 /*
1431 * Factor in in-flight vtime into vusage to avoid
1432 * high-latency completions appearing as idle. This should
1433 * be done after the above ->last_time adjustment.
1434 */
1437 /* calculate hweight based usage ratio and record */
1440 period_vtime);
1445 }
1447 /* see whether there's surplus vtime */
1457 /* throw away surplus vtime */
1461 /* if usage is sufficiently low, maybe it can donate */
1464 nr_surpluses++;
1465 }
1469 /* was donating but might need to take back some */
1475 SURPLUS_SCALE_ABS);
1476 }
1479 hw_inuse);
1487 new_inuse);
1488 }
1490 /* genuninely out of vtime */
1491 nr_shortages++;
1492 }
1493 }
1498 /* there are both shortages and surpluses, transfer surpluses */
1506 /* base the decision on max historical usage */
1510 nr_valid++;
1511 }
1512 }
1522 hw_inuse);
1528 }
1529 }
1530 skip_surplus_transfers:
1533 /*
1534 * If q is getting clogged or we're missing too much, we're issuing
1535 * too much IO and should lower vtime rate. If we're not missing
1536 * and experiencing shortages but not surpluses, we're too stingy
1537 * and should increase vtime rate.
1538 */
1548 /* take action iff there is contention */
1551 /* redistribute surpluses first */
1554 }
1557 }
1565 /* rq_wait signal is always reliable, ignore user vrate_min */
1569 /*
1570 * If vrate is out of bounds, apply clamp gradually as the
1571 * bounds can change abruptly. Otherwise, apply busy_level
1572 * based adjustment.
1573 */
1589 else
1594 }
1598 nr_surpluses);
1607 }
1611 /*
1612 * This period is done. Move onto the next one. If nothing's
1613 * going on with the device, stop the timer.
1614 */
1623 }
1624 }
1627 }
1631 {
1651 }
1656 }
1663 }
1664 }
1666 out:
1668 }
1671 {
1672 u64 cost;
1676 }
1679 {
1688 /* bypass IOs if disabled or for root cgroup */
1692 /* always activate so that even 0 cost IOs get protected to some level */
1696 /* calculate the absolute vtime cost */
1714 }
1718 /*
1719 * If no one's waiting and within budget, issue right away. The
1720 * tests are racy but the races aren't systemic - we only miss once
1721 * in a while which is fine.
1722 */
1728 }
1730 /*
1731 * We're over budget. If @bio has to be issued regardless,
1732 * remember the abs_cost instead of advancing vtime.
1733 * iocg_kick_waitq() will pay off the debt before waking more IOs.
1734 * This way, the debt is continuously paid off each period with the
1735 * actual budget available to the cgroup. If we just wound vtime,
1736 * we would incorrectly use the current hw_inuse for the entire
1737 * amount which, for example, can lead to the cgroup staying
1738 * blocked for a long time even with substantially raised hw_inuse.
1739 */
1744 }
1746 /*
1747 * Append self to the waitq and schedule the wakeup timer if we're
1748 * the first waiter. The timer duration is calculated based on the
1749 * current vrate. vtime and hweight changes can make it too short
1750 * or too long. Each wait entry records the absolute cost it's
1751 * waiting for to allow re-evaluation using a custom wait entry.
1752 *
1753 * If too short, the timer simply reschedules itself. If too long,
1754 * the period timer will notice and trigger wakeups.
1755 *
1756 * All waiters are on iocg->waitq and the wait states are
1757 * synchronized using waitq.lock.
1758 */
1761 /*
1762 * We activated above but w/o any synchronization. Deactivation is
1763 * synchronized with waitq.lock and we won't get deactivated as
1764 * long as we're waiting, so we're good if we're activated here.
1765 * In the unlikely case that we are deactivated, just issue the IO.
1766 */
1771 }
1789 }
1791 /* waker already committed us, proceed */
1793 }
1797 {
1802 u32 hw_inuse;
1805 /* bypass if disabled or for root cgroup */
1817 /* update cursor if backmerging into the request at the cursor */
1822 /*
1823 * Charge if there's enough vtime budget and the existing request
1824 * has cost assigned. Otherwise, account it as debt. See debt
1825 * handling in ioc_rqos_throttle() for details.
1826 */
1830 else
1832 }
1835 {
1840 }
1843 {
1862 }
1869 else
1873 }
1876 {
1882 }
1885 {
1897 }
1906 };
1909 {
1922 }
1952 }
1954 }
1957 {
1966 }
1969 {
1971 }
1975 {
1985 }
1988 {
2018 }
2023 }
2026 {
2035 }
2040 }
2042 }
2046 {
2053 }
2057 {
2065 }
2069 {
2074 u32 v;
2095 }
2096 }
2100 }
2115 }
2125 einval:
2128 }
2132 {
2139 seq_printf(sf, "%s enable=%d ctrl=%s rpct=%u.%02u rlat=%u wpct=%u.%02u wlat=%u min=%u.%02u max=%u.%02u\n",
2152 }
2155 {
2161 }
2167 };
2177 };
2181 {
2199 }
2211 s64 v;
2227 else
2230 }
2265 }
2267 }
2280 }
2287 }
2294 einval:
2296 err:
2299 }
2303 {
2312 "rbps=%llu rseqiops=%llu rrandiops=%llu "
2318 }
2321 {
2327 }
2333 };
2343 };
2347 {
2365 }
2376 u64 v;
2388 else
2396 }
2405 }
2413 }
2420 einval:
2422 err:
2425 }
2428 {
2433 },
2434 {
2439 },
2440 {
2445 },
2446 {}
2447 };
2456 };
2459 {
2461 }
2464 {
2466 }