1 /*
2 * CDDL HEADER START
3 *
4 * The contents of this file are subject to the terms of the
5 * Common Development and Distribution License (the "License").
6 * You may not use this file except in compliance with the License.
7 *
8 * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
9 * or http://www.opensolaris.org/os/licensing.
10 * See the License for the specific language governing permissions
11 * and limitations under the License.
12 *
13 * When distributing Covered Code, include this CDDL HEADER in each
14 * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
15 * If applicable, add the following below this CDDL HEADER, with the
16 * fields enclosed by brackets "[]" replaced with your own identifying
17 * information: Portions Copyright [yyyy] [name of copyright owner]
18 *
19 * CDDL HEADER END
20 */
21
22 /*
23 * Copyright 2018 Joyent, Inc.
24 * Copyright 2023 Oxide Computer Company
25 * Copyright 2021 OmniOS Community Edition (OmniOSce) Association.
26 */
27
28 /*
29 * Copyright 2009 Sun Microsystems, Inc. All rights reserved.
30 * Use is subject to license terms.
31 */
32
33 /* Copyright (c) 1984, 1986, 1987, 1988, 1989 AT&T */
34 /* All Rights Reserved */
35
36 /*
37 * University Copyright- Copyright (c) 1982, 1986, 1988
38 * The Regents of the University of California
39 * All Rights Reserved
40 *
41 * University Acknowledgment- Portions of this document are derived from
42 * software developed by the University of California, Berkeley, and its
43 * contributors.
44 */
45
46 #include <sys/types.h>
47 #include <sys/t_lock.h>
48 #include <sys/param.h>
49 #include <sys/buf.h>
50 #include <sys/uio.h>
51 #include <sys/proc.h>
52 #include <sys/systm.h>
53 #include <sys/mman.h>
54 #include <sys/cred.h>
55 #include <sys/vnode.h>
56 #include <sys/vm.h>
57 #include <sys/vmparam.h>
58 #include <sys/vtrace.h>
59 #include <sys/cmn_err.h>
60 #include <sys/cpuvar.h>
61 #include <sys/user.h>
62 #include <sys/kmem.h>
63 #include <sys/debug.h>
64 #include <sys/callb.h>
65 #include <sys/mem_cage.h>
66 #include <sys/time.h>
67 #include <sys/stdbool.h>
68
69 #include <vm/hat.h>
70 #include <vm/as.h>
71 #include <vm/seg.h>
72 #include <vm/page.h>
73 #include <vm/pvn.h>
74 #include <vm/seg_kmem.h>
75
76 /*
77 * FREE MEMORY MANAGEMENT
78 *
79 * Management of the pool of free pages is a tricky business. There are
80 * several critical threshold values which constrain our allocation of new
81 * pages and inform the rate of paging out of memory to swap. These threshold
82 * values, and the behaviour they induce, are described below in descending
83 * order of size -- and thus increasing order of severity!
84 *
85 * +---------------------------------------------------- physmem (all memory)
86 * |
87 * | Ordinarily there are no particular constraints placed on page
88 * v allocation. The page scanner is not running and page_create_va()
89 * | will effectively grant all page requests (whether from the kernel
90 * | or from user processes) without artificial delay.
91 * |
92 * +------------------------ lotsfree (1.56% of physmem, min. 16MB, max. 2GB)
93 * |
94 * | When we have less than "lotsfree" pages, pageout_scanner() is
95 * v signalled by schedpaging() to begin looking for pages that can
96 * | be evicted to disk to bring us back above lotsfree. At this
97 * | stage there is still no constraint on allocation of free pages.
98 * |
99 * | For small systems, we set a lower bound of 16MB for lotsfree;
100 * v this is the natural value for a system with 1GB memory. This is
101 * | to ensure that the pageout reserve pool contains at least 4MB
102 * | for use by ZFS.
103 * |
104 * | For systems with a large amount of memory, we constrain lotsfree
105 * | to be at most 2GB (with a pageout reserve of around 0.5GB), as
106 * v at some point the required slack relates more closely to the
107 * | rate at which paging can occur than to the total amount of memory.
108 * |
109 * +------------------- desfree (1/2 of lotsfree, 0.78% of physmem, min. 8MB)
110 * |
111 * | When we drop below desfree, a number of kernel facilities will
112 * v wait before allocating more memory, under the assumption that
113 * | pageout or reaping will make progress and free up some memory.
114 * | This behaviour is not especially coordinated; look for comparisons
115 * | of desfree and freemem.
116 * |
117 * | In addition to various attempts at advisory caution, clock()
118 * | will wake up the thread that is ordinarily parked in sched().
119 * | This routine is responsible for the heavy-handed swapping out
120 * v of entire processes in an attempt to arrest the slide of free
121 * | memory. See comments in sched.c for more details.
122 * |
123 * +----- minfree & throttlefree (3/4 of desfree, 0.59% of physmem, min. 6MB)
124 * |
125 * | These two separate tunables have, by default, the same value.
126 * v Various parts of the kernel use minfree to signal the need for
127 * | more aggressive reclamation of memory, and sched() is more
128 * | aggressive at swapping processes out.
129 * |
130 * | If free memory falls below throttlefree, page_create_va() will
131 * | use page_create_throttle() to begin holding most requests for
132 * | new pages while pageout and reaping free up memory. Sleeping
133 * v allocations (e.g., KM_SLEEP) are held here while we wait for
134 * | more memory. Non-sleeping allocations are generally allowed to
135 * | proceed, unless their priority is explicitly lowered with
136 * | KM_NORMALPRI (Note: KM_NOSLEEP_LAZY == (KM_NOSLEEP | KM_NORMALPRI).).
137 * |
138 * +------- pageout_reserve (3/4 of throttlefree, 0.44% of physmem, min. 4MB)
139 * |
140 * | When we hit throttlefree, the situation is already dire. The
141 * v system is generally paging out memory and swapping out entire
142 * | processes in order to free up memory for continued operation.
143 * |
144 * | Unfortunately, evicting memory to disk generally requires short
145 * | term use of additional memory; e.g., allocation of buffers for
146 * | storage drivers, updating maps of free and used blocks, etc.
147 * | As such, pageout_reserve is the number of pages that we keep in
148 * | special reserve for use by pageout() and sched() and by any
149 * v other parts of the kernel that need to be working for those to
150 * | make forward progress such as the ZFS I/O pipeline.
151 * |
152 * | When we are below pageout_reserve, we fail or hold any allocation
153 * | that has not explicitly requested access to the reserve pool.
154 * | Access to the reserve is generally granted via the KM_PUSHPAGE
155 * | flag, or by marking a thread T_PUSHPAGE such that all allocations
156 * | can implicitly tap the reserve. For more details, see the
157 * v NOMEMWAIT() macro, the T_PUSHPAGE thread flag, the KM_PUSHPAGE
158 * | and VM_PUSHPAGE allocation flags, and page_create_throttle().
159 * |
160 * +---------------------------------------------------------- no free memory
161 * |
162 * | If we have arrived here, things are very bad indeed. It is
163 * v surprisingly difficult to tell if this condition is even fatal,
164 * | as enough memory may have been granted to pageout() and to the
165 * | ZFS I/O pipeline that requests for eviction that have already been
166 * | made will complete and free up memory some time soon.
167 * |
168 * | If free memory does not materialise, the system generally remains
169 * | deadlocked. The pageout_deadman() below is run once per second
170 * | from clock(), seeking to limit the amount of time a single request
171 * v to page out can be blocked before the system panics to get a crash
172 * | dump and return to service.
173 * |
174 * +-------------------------------------------------------------------------
175 */
176
177 /*
178 * The following parameters control operation of the page replacement
179 * algorithm. They are initialized to 0, and then computed at boot time based
180 * on the size of the system; see setupclock(). If they are patched non-zero
181 * in a loaded vmunix they are left alone and may thus be changed per system
182 * using "mdb -kw" on the loaded system.
183 */
184 pgcnt_t slowscan = 0;
185 pgcnt_t fastscan = 0;
186
187 static pgcnt_t handspreadpages = 0;
188
189 /*
190 * looppages:
191 * Cached copy of the total number of pages in the system (total_pages).
192 *
193 * loopfraction:
194 * Divisor used to relate fastscan to looppages in setupclock().
195 */
196 static uint_t loopfraction = 2;
197 static pgcnt_t looppages;
198
199 static uint_t min_percent_cpu = 4;
200 static uint_t max_percent_cpu = 80;
201 static pgcnt_t maxfastscan = 0;
202 static pgcnt_t maxslowscan = 100;
203
204 #define MEGABYTES (1024ULL * 1024ULL)
205
206 /*
207 * pageout_threshold_style:
208 * set to 1 to use the previous default threshold size calculation;
209 * i.e., each threshold is half of the next largest value.
210 */
211 uint_t pageout_threshold_style = 0;
212
213 /*
214 * The operator may override these tunables to request a different minimum or
215 * maximum lotsfree value, or to change the divisor we use for automatic
216 * sizing.
217 *
218 * By default, we make lotsfree 1/64th of the total memory in the machine. The
219 * minimum and maximum are specified in bytes, rather than pages; a zero value
220 * means the default values (below) are used.
221 */
222 uint_t lotsfree_fraction = 64;
223 pgcnt_t lotsfree_min = 0;
224 pgcnt_t lotsfree_max = 0;
225
226 #define LOTSFREE_MIN_DEFAULT (16 * MEGABYTES)
227 #define LOTSFREE_MAX_DEFAULT (2048 * MEGABYTES)
228
229 /*
230 * If these tunables are set to non-zero values in /etc/system, and provided
231 * the value is not larger than the threshold above, the specified value will
232 * be used directly without any additional calculation or adjustment. The boot
233 * time value of these overrides is preserved in the "clockinit" struct. More
234 * detail is available in the comment at the top of the file.
235 */
236 pgcnt_t maxpgio = 0;
237 pgcnt_t minfree = 0;
238 pgcnt_t desfree = 0;
239 pgcnt_t lotsfree = 0;
240 pgcnt_t needfree = 0;
241 pgcnt_t throttlefree = 0;
242 pgcnt_t pageout_reserve = 0;
243
244 pgcnt_t deficit;
245 pgcnt_t nscan;
246 pgcnt_t desscan;
247
248 /* kstats */
249 uint64_t low_mem_scan;
250
251 /* The maximum supported number of page_scanner() threads */
252 #define MAX_PSCAN_THREADS 16
253
254 /*
255 * Values for min_pageout_nsec, max_pageout_nsec and pageout_nsec are the
256 * number of nanoseconds in each wakeup cycle that gives the equivalent of some
257 * underlying %CPU duty cycle.
258 *
259 * min_pageout_nsec:
260 * nanoseconds/wakeup equivalent of min_percent_cpu.
261 *
262 * max_pageout_nsec:
263 * nanoseconds/wakeup equivalent of max_percent_cpu.
264 *
265 * pageout_nsec:
266 * Number of nanoseconds budgeted for each wakeup cycle.
267 * Computed each time around by schedpaging().
268 * Varies between min_pageout_nsec and max_pageout_nsec,
269 * depending on memory pressure.
270 */
271 static hrtime_t min_pageout_nsec;
272 static hrtime_t max_pageout_nsec;
273 static hrtime_t pageout_nsec;
274
275 static bool reset_hands[MAX_PSCAN_THREADS];
276
277 #define PAGES_POLL_MASK 1023
278
279 /*
280 * Pageout scheduling.
281 *
282 * Schedpaging controls the rate at which the page out daemon runs by
283 * setting the global variables nscan and desscan SCHEDPAGING_HZ
284 * times a second. Nscan records the number of pages pageout has examined
285 * in its current pass; schedpaging() resets this value to zero each time
286 * it runs. Desscan records the number of pages pageout should examine
287 * in its next pass; schedpaging() sets this value based on the amount of
288 * currently available memory.
289 */
290 #define SCHEDPAGING_HZ 4
291
292 /*
293 * despagescanners:
294 * The desired number of page scanner threads. For testing purposes, this
295 * value can be set in /etc/system or tuned directly with mdb(1). The
296 * system will bring the actual number of threads into line with the
297 * desired number. If set to an invalid value, the system will correct the
298 * setting.
299 */
300 uint_t despagescanners = 0;
301
302 /*
303 * pageout_sample_lim:
304 * The limit on the number of samples needed to establish a value for new
305 * pageout parameters: fastscan, slowscan, pageout_new_spread, and
306 * handspreadpages.
307 *
308 * pageout_sample_cnt:
309 * Current sample number. Once the sample gets large enough, set new
310 * values for handspreadpages, pageout_new_spread, fastscan and slowscan.
311 *
312 * pageout_sample_pages:
313 * The accumulated number of pages scanned during sampling.
314 *
315 * pageout_sample_etime:
316 * The accumulated nanoseconds for the sample.
317 *
318 * pageout_sampling:
319 * True while sampling is still in progress.
320 *
321 * pageout_rate:
322 * Rate in pages/nanosecond, computed at the end of sampling.
323 *
324 * pageout_new_spread:
325 * Initially zero while the system scan rate is measured by
326 * pageout_scanner(), which then sets this value once per system boot after
327 * enough samples have been recorded (pageout_sample_cnt). Once set, this
328 * new value is used for fastscan and handspreadpages.
329 */
330 typedef hrtime_t hrrate_t;
331
332 static uint64_t pageout_sample_lim = 4;
333 static uint64_t pageout_sample_cnt = 0;
334 static pgcnt_t pageout_sample_pages = 0;
335 static hrtime_t pageout_sample_etime = 0;
336 static bool pageout_sampling = true;
337 static hrrate_t pageout_rate = 0;
338 static pgcnt_t pageout_new_spread = 0;
339
340 /* The current number of page scanner threads */
341 static uint_t n_page_scanners = 1;
342 /* The number of page scanner threads that are actively scanning. */
343 static uint_t pageouts_running;
344
345 /*
346 * Record number of times a pageout_scanner() wakeup cycle finished because it
347 * timed out (exceeded its CPU budget), rather than because it visited
348 * its budgeted number of pages.
349 */
350 uint64_t pageout_timeouts = 0;
351
352 #ifdef VM_STATS
353 static struct pageoutvmstats_str {
354 ulong_t checkpage[3];
355 } pageoutvmstats;
356 #endif /* VM_STATS */
357
358 /*
359 * Threads waiting for free memory use this condition variable and lock until
360 * memory becomes available.
361 */
362 kmutex_t memavail_lock;
363 kcondvar_t memavail_cv;
364
365 typedef enum pageout_hand {
366 POH_FRONT = 1,
367 POH_BACK,
368 } pageout_hand_t;
369
370 typedef enum {
371 CKP_INELIGIBLE,
372 CKP_NOT_FREED,
373 CKP_FREED,
374 } checkpage_result_t;
375
376 static checkpage_result_t checkpage(page_t *, pageout_hand_t);
377
378 static struct clockinit {
379 bool ci_init;
380 pgcnt_t ci_lotsfree_min;
381 pgcnt_t ci_lotsfree_max;
382 pgcnt_t ci_lotsfree;
383 pgcnt_t ci_desfree;
384 pgcnt_t ci_minfree;
385 pgcnt_t ci_throttlefree;
386 pgcnt_t ci_pageout_reserve;
387 pgcnt_t ci_maxpgio;
388 pgcnt_t ci_maxfastscan;
389 pgcnt_t ci_fastscan;
390 pgcnt_t ci_slowscan;
391 pgcnt_t ci_handspreadpages;
392 uint_t ci_despagescanners;
393 } clockinit = { .ci_init = false };
394
395 static inline pgcnt_t
clamp(pgcnt_t value,pgcnt_t minimum,pgcnt_t maximum)396 clamp(pgcnt_t value, pgcnt_t minimum, pgcnt_t maximum)
397 {
398 if (value < minimum)
399 return (minimum);
400 else if (value > maximum)
401 return (maximum);
402 else
403 return (value);
404 }
405
406 static pgcnt_t
tune(pgcnt_t initval,pgcnt_t initval_ceiling,pgcnt_t defval)407 tune(pgcnt_t initval, pgcnt_t initval_ceiling, pgcnt_t defval)
408 {
409 if (initval == 0 || initval >= initval_ceiling)
410 return (defval);
411 else
412 return (initval);
413 }
414
415 /*
416 * On large memory systems, multiple instances of the page scanner are run,
417 * each responsible for a separate region of memory. This speeds up page
418 * invalidation under low memory conditions.
419 *
420 * For testing purposes, despagescanners can be set in /etc/system or via
421 * mdb(1) and it will be used as a guide for how many page scanners to create;
422 * the value will be adjusted if it is not sensible. Otherwise, the number of
423 * page scanners is determined dynamically based on handspreadpages.
424 */
425 static void
recalc_pagescanners(void)426 recalc_pagescanners(void)
427 {
428 uint_t des;
429
430 /* If the initial calibration has not been done, take no action. */
431 if (pageout_new_spread == 0)
432 return;
433
434 /*
435 * If `clockinit.ci_despagescanners` is non-zero, then a value for
436 * `despagescanners` was set during initial boot. In this case, if
437 * `despagescanners` has been reset to 0 then we want to revert to
438 * that initial boot value.
439 */
440 if (despagescanners == 0)
441 despagescanners = clockinit.ci_despagescanners;
442
443 if (despagescanners != 0) {
444 /*
445 * We have a desired number of page scanners, either from
446 * /etc/system or set via mdb. Try and use it (it will be
447 * adjusted below if necessary).
448 */
449 des = despagescanners;
450 } else {
451 /*
452 * Calculate the number of desired scanners based on the
453 * system's memory size.
454 *
455 * A 64GiB region size is used as the basis for calculating how
456 * many scanner threads should be created. For systems with up
457 * to 64GiB of RAM, a single thread is used; for very large
458 * memory systems the threads are limited to MAX_PSCAN_THREADS.
459 */
460 des = (looppages - 1) / btop(64ULL << 30) + 1;
461 }
462
463 /*
464 * Clamp the number of scanners so that we have no more than
465 * MAX_PSCAN_THREADS and so that each scanner covers at least 10% more
466 * than handspreadpages.
467 */
468 pgcnt_t min_scanner_pages = handspreadpages + handspreadpages / 10;
469 pgcnt_t max_scanners = looppages / min_scanner_pages;
470 despagescanners = clamp(des, 1,
471 clamp(max_scanners, 1, MAX_PSCAN_THREADS));
472 }
473
474 /*
475 * Set up the paging constants for the clock algorithm used by
476 * pageout_scanner(), and by the virtual memory system overall. See the
477 * comments at the top of this file for more information about the threshold
478 * values and system responses to memory pressure.
479 *
480 * This routine is called once by main() at startup, after the initial size of
481 * physical memory is determined. It may be called again later if memory is
482 * added to or removed from the system, or if new measurements of the page scan
483 * rate become available.
484 */
485 void
setupclock(void)486 setupclock(void)
487 {
488 bool half = (pageout_threshold_style == 1);
489 bool recalc = true;
490
491 looppages = total_pages;
492
493 /*
494 * The operator may have provided specific values for some of the
495 * tunables via /etc/system. On our first call, we preserve those
496 * values so that they can be used for subsequent recalculations.
497 *
498 * A value of zero for any tunable means we will use the default
499 * sizing.
500 */
501 if (!clockinit.ci_init) {
502 clockinit.ci_init = true;
503
504 clockinit.ci_lotsfree_min = lotsfree_min;
505 clockinit.ci_lotsfree_max = lotsfree_max;
506 clockinit.ci_lotsfree = lotsfree;
507 clockinit.ci_desfree = desfree;
508 clockinit.ci_minfree = minfree;
509 clockinit.ci_throttlefree = throttlefree;
510 clockinit.ci_pageout_reserve = pageout_reserve;
511 clockinit.ci_maxpgio = maxpgio;
512 clockinit.ci_maxfastscan = maxfastscan;
513 clockinit.ci_fastscan = fastscan;
514 clockinit.ci_slowscan = slowscan;
515 clockinit.ci_handspreadpages = handspreadpages;
516 clockinit.ci_despagescanners = despagescanners;
517
518 /*
519 * The first call does not trigger a recalculation, only
520 * subsequent calls.
521 */
522 recalc = false;
523 }
524
525 /*
526 * Configure paging threshold values. For more details on what each
527 * threshold signifies, see the comments at the top of this file.
528 */
529 lotsfree_max = tune(clockinit.ci_lotsfree_max, looppages,
530 btop(LOTSFREE_MAX_DEFAULT));
531 lotsfree_min = tune(clockinit.ci_lotsfree_min, lotsfree_max,
532 btop(LOTSFREE_MIN_DEFAULT));
533
534 lotsfree = tune(clockinit.ci_lotsfree, looppages,
535 clamp(looppages / lotsfree_fraction, lotsfree_min, lotsfree_max));
536
537 desfree = tune(clockinit.ci_desfree, lotsfree,
538 lotsfree / 2);
539
540 minfree = tune(clockinit.ci_minfree, desfree,
541 half ? desfree / 2 : 3 * desfree / 4);
542
543 throttlefree = tune(clockinit.ci_throttlefree, desfree,
544 minfree);
545
546 pageout_reserve = tune(clockinit.ci_pageout_reserve, throttlefree,
547 half ? throttlefree / 2 : 3 * throttlefree / 4);
548
549 /*
550 * Maxpgio thresholds how much paging is acceptable.
551 * This figures that 2/3 busy on an arm is all that is
552 * tolerable for paging. We assume one operation per disk rev.
553 *
554 * XXX - Does not account for multiple swap devices.
555 */
556 if (clockinit.ci_maxpgio == 0) {
557 maxpgio = (DISKRPM * 2) / 3;
558 } else {
559 maxpgio = clockinit.ci_maxpgio;
560 }
561
562 /*
563 * The clock scan rate varies between fastscan and slowscan
564 * based on the amount of free memory available. Fastscan
565 * rate should be set based on the number pages that can be
566 * scanned per sec using ~10% of processor time. Since this
567 * value depends on the processor, MMU, Mhz etc., it is
568 * difficult to determine it in a generic manner for all
569 * architectures.
570 *
571 * Instead of trying to determine the number of pages scanned
572 * per sec for every processor, fastscan is set to be the smaller
573 * of 1/2 of memory or MAXHANDSPREADPAGES and the sampling
574 * time is limited to ~4% of processor time.
575 *
576 * Setting fastscan to be 1/2 of memory allows pageout to scan
577 * all of memory in ~2 secs. This implies that user pages not
578 * accessed within 1 sec (assuming, handspreadpages == fastscan)
579 * can be reclaimed when free memory is very low. Stealing pages
580 * not accessed within 1 sec seems reasonable and ensures that
581 * active user processes don't thrash.
582 *
583 * Smaller values of fastscan result in scanning fewer pages
584 * every second and consequently pageout may not be able to free
585 * sufficient memory to maintain the minimum threshold. Larger
586 * values of fastscan result in scanning a lot more pages which
587 * could lead to thrashing and higher CPU usage.
588 *
589 * Fastscan needs to be limited to a maximum value and should not
590 * scale with memory to prevent pageout from consuming too much
591 * time for scanning on slow CPU's and avoid thrashing, as a
592 * result of scanning too many pages, on faster CPU's.
593 * The value of 64 Meg was chosen for MAXHANDSPREADPAGES
594 * (the upper bound for fastscan) based on the average number
595 * of pages that can potentially be scanned in ~1 sec (using ~4%
596 * of the CPU) on some of the following machines that currently
597 * run Solaris 2.x:
598 *
599 * average memory scanned in ~1 sec
600 *
601 * 25 Mhz SS1+: 23 Meg
602 * LX: 37 Meg
603 * 50 Mhz SC2000: 68 Meg
604 *
605 * 40 Mhz 486: 26 Meg
606 * 66 Mhz 486: 42 Meg
607 *
608 * When free memory falls just below lotsfree, the scan rate
609 * goes from 0 to slowscan (i.e., pageout starts running). This
610 * transition needs to be smooth and is achieved by ensuring that
611 * pageout scans a small number of pages to satisfy the transient
612 * memory demand. This is set to not exceed 100 pages/sec (25 per
613 * wakeup) since scanning that many pages has no noticible impact
614 * on system performance.
615 *
616 * In addition to setting fastscan and slowscan, pageout is
617 * limited to using ~4% of the CPU. This results in increasing
618 * the time taken to scan all of memory, which in turn means that
619 * user processes have a better opportunity of preventing their
620 * pages from being stolen. This has a positive effect on
621 * interactive and overall system performance when memory demand
622 * is high.
623 *
624 * Thus, the rate at which pages are scanned for replacement will
625 * vary linearly between slowscan and the number of pages that
626 * can be scanned using ~4% of processor time instead of varying
627 * linearly between slowscan and fastscan.
628 *
629 * Also, the processor time used by pageout will vary from ~1%
630 * at slowscan to ~4% at fastscan instead of varying between
631 * ~1% at slowscan and ~10% at fastscan.
632 *
633 * The values chosen for the various VM parameters (fastscan,
634 * handspreadpages, etc) are not universally true for all machines,
635 * but appear to be a good rule of thumb for the machines we've
636 * tested. They have the following ranges:
637 *
638 * cpu speed: 20 to 70 Mhz
639 * page size: 4K to 8K
640 * memory size: 16M to 5G
641 * page scan rate: 4000 - 17400 4K pages per sec
642 *
643 * The values need to be re-examined for machines which don't
644 * fall into the various ranges (e.g., slower or faster CPUs,
645 * smaller or larger pagesizes etc) shown above.
646 *
647 * On an MP machine, pageout is often unable to maintain the
648 * minimum paging thresholds under heavy load. This is due to
649 * the fact that user processes running on other CPU's can be
650 * dirtying memory at a much faster pace than pageout can find
651 * pages to free. The memory demands could be met by enabling
652 * more than one CPU to run the clock algorithm in such a manner
653 * that the various clock hands don't overlap. This also makes
654 * it more difficult to determine the values for fastscan, slowscan
655 * and handspreadpages.
656 *
657 * The swapper is currently used to free up memory when pageout
658 * is unable to meet memory demands by swapping out processes.
659 * In addition to freeing up memory, swapping also reduces the
660 * demand for memory by preventing user processes from running
661 * and thereby consuming memory.
662 */
663 if (clockinit.ci_maxfastscan == 0) {
664 if (pageout_new_spread != 0) {
665 maxfastscan = pageout_new_spread;
666 } else {
667 maxfastscan = MAXHANDSPREADPAGES;
668 }
669 } else {
670 maxfastscan = clockinit.ci_maxfastscan;
671 }
672
673 if (clockinit.ci_fastscan == 0) {
674 fastscan = MIN(looppages / loopfraction, maxfastscan);
675 } else {
676 fastscan = clockinit.ci_fastscan;
677 }
678
679 if (fastscan > looppages / loopfraction) {
680 fastscan = looppages / loopfraction;
681 }
682
683 /*
684 * Set slow scan time to 1/10 the fast scan time, but
685 * not to exceed maxslowscan.
686 */
687 if (clockinit.ci_slowscan == 0) {
688 slowscan = MIN(fastscan / 10, maxslowscan);
689 } else {
690 slowscan = clockinit.ci_slowscan;
691 }
692
693 if (slowscan > fastscan / 2) {
694 slowscan = fastscan / 2;
695 }
696
697 /*
698 * Handspreadpages is the distance (in pages) between front and back
699 * pageout daemon hands. The amount of time to reclaim a page
700 * once pageout examines it increases with this distance and
701 * decreases as the scan rate rises. It must be < the amount
702 * of pageable memory.
703 *
704 * Since pageout is limited to ~4% of the CPU, setting handspreadpages
705 * to be "fastscan" results in the front hand being a few secs
706 * (varies based on the processor speed) ahead of the back hand
707 * at fastscan rates. This distance can be further reduced, if
708 * necessary, by increasing the processor time used by pageout
709 * to be more than ~4% and preferrably not more than ~10%.
710 *
711 * As a result, user processes have a much better chance of
712 * referencing their pages before the back hand examines them.
713 * This also significantly lowers the number of reclaims from
714 * the freelist since pageout does not end up freeing pages which
715 * may be referenced a sec later.
716 */
717 if (clockinit.ci_handspreadpages == 0) {
718 handspreadpages = fastscan;
719 } else {
720 handspreadpages = clockinit.ci_handspreadpages;
721 }
722
723 /*
724 * Make sure that back hand follows front hand by at least
725 * 1/SCHEDPAGING_HZ seconds. Without this test, it is possible for the
726 * back hand to look at a page during the same wakeup of the pageout
727 * daemon in which the front hand cleared its ref bit.
728 */
729 if (handspreadpages >= looppages) {
730 handspreadpages = looppages - 1;
731 }
732
733 /*
734 * Establish the minimum and maximum length of time to be spent
735 * scanning pages per wakeup, limiting the scanner duty cycle. The
736 * input percentage values (0-100) must be converted to a fraction of
737 * the number of nanoseconds in a second of wall time, then further
738 * scaled down by the number of scanner wakeups in a second.
739 */
740 min_pageout_nsec = MAX(1,
741 NANOSEC * min_percent_cpu / 100 / SCHEDPAGING_HZ);
742 max_pageout_nsec = MAX(min_pageout_nsec,
743 NANOSEC * max_percent_cpu / 100 / SCHEDPAGING_HZ);
744
745 /*
746 * If not called for recalculation, return and skip the remaining
747 * steps.
748 */
749 if (!recalc)
750 return;
751
752 /*
753 * Set a flag to re-evaluate the clock hand positions.
754 */
755 for (uint_t i = 0; i < MAX_PSCAN_THREADS; i++)
756 reset_hands[i] = true;
757
758 recalc_pagescanners();
759 }
760
761 static kmutex_t pageout_mutex;
762
763 /*
764 * Pool of available async pageout putpage requests.
765 */
766 static struct async_reqs *push_req;
767 static struct async_reqs *req_freelist; /* available req structs */
768 static struct async_reqs *push_list; /* pending reqs */
769 static kmutex_t push_lock; /* protects req pool */
770 static kcondvar_t push_cv;
771
772 /*
773 * If pageout() is stuck on a single push for this many seconds,
774 * pageout_deadman() will assume the system has hit a memory deadlock. If set
775 * to 0, the deadman will have no effect.
776 *
777 * Note that we are only looking for stalls in the calls that pageout() makes
778 * to VOP_PUTPAGE(). These calls are merely asynchronous requests for paging
779 * I/O, which should not take long unless the underlying strategy call blocks
780 * indefinitely for memory. The actual I/O request happens (or fails) later.
781 */
782 uint_t pageout_deadman_seconds = 90;
783
784 static uint_t pageout_stucktime = 0;
785 static bool pageout_pushing = false;
786 static uint64_t pageout_pushcount = 0;
787 static uint64_t pageout_pushcount_seen = 0;
788
789 int async_list_size = 8192;
790
791 static void pageout_scanner(void *);
792
793 /*
794 * If a page is being shared more than "po_share" times
795 * then leave it alone- don't page it out.
796 */
797 #define MIN_PO_SHARE (8)
798 #define MAX_PO_SHARE ((MIN_PO_SHARE) << 24)
799 ulong_t po_share = MIN_PO_SHARE;
800
801 /*
802 * Schedule rate for paging.
803 * Rate is linear interpolation between
804 * slowscan with lotsfree and fastscan when out of memory.
805 */
806 static void
schedpaging(void * arg)807 schedpaging(void *arg)
808 {
809 spgcnt_t vavail;
810
811 if (freemem < lotsfree + needfree + kmem_reapahead)
812 kmem_reap();
813
814 if (freemem < lotsfree + needfree)
815 seg_preap();
816
817 if (kcage_on && (kcage_freemem < kcage_desfree || kcage_needfree))
818 kcage_cageout_wakeup();
819
820 if (mutex_tryenter(&pageout_mutex)) {
821 if (pageouts_running != 0)
822 goto out;
823
824 /* No pageout scanner threads running. */
825 nscan = 0;
826 vavail = freemem - deficit;
827 if (pageout_new_spread != 0)
828 vavail -= needfree;
829 /* Note that vavail is signed so don't use clamp() here */
830 if (vavail < 0)
831 vavail = 0;
832 if (vavail > lotsfree)
833 vavail = lotsfree;
834
835 if (needfree > 0 && pageout_new_spread == 0) {
836 /*
837 * If we've not yet collected enough samples to
838 * calculate a spread, use the old logic of kicking
839 * into high gear anytime needfree is non-zero.
840 */
841 desscan = fastscan / SCHEDPAGING_HZ;
842 } else {
843 /*
844 * Once we've calculated a spread based on system
845 * memory and usage, just treat needfree as another
846 * form of deficit.
847 */
848 spgcnt_t faststmp, slowstmp, result;
849
850 slowstmp = slowscan * vavail;
851 faststmp = fastscan * (lotsfree - vavail);
852 result = (slowstmp + faststmp) /
853 nz(lotsfree) / SCHEDPAGING_HZ;
854 desscan = (pgcnt_t)result;
855 }
856
857 pageout_nsec = min_pageout_nsec + (lotsfree - vavail) *
858 (max_pageout_nsec - min_pageout_nsec) / nz(lotsfree);
859
860 DTRACE_PROBE2(schedpage__calc, pgcnt_t, desscan, hrtime_t,
861 pageout_nsec);
862
863 if (pageout_new_spread != 0 && despagescanners != 0 &&
864 despagescanners != n_page_scanners) {
865 /*
866 * We have finished the pagescan initialisation and the
867 * desired number of page scanners has changed, either
868 * because sampling just finished, because of a memory
869 * DR, or because despagescanners has been modified on
870 * the fly (e.g. via mdb(1)).
871 */
872 uint_t curr_nscan = n_page_scanners;
873 uint_t i;
874
875 /* Re-validate despagescanners */
876 recalc_pagescanners();
877
878 n_page_scanners = despagescanners;
879
880 for (i = 0; i < MAX_PSCAN_THREADS; i++)
881 reset_hands[i] = true;
882
883 /* If we need more scanners, start them now. */
884 for (i = curr_nscan; i < n_page_scanners; i++) {
885 (void) lwp_kernel_create(proc_pageout,
886 pageout_scanner, (void *)(uintptr_t)i,
887 TS_RUN, curthread->t_pri);
888 }
889
890 /*
891 * If the number of scanners has decreased, trigger a
892 * wakeup so that the excess threads will terminate.
893 */
894 if (n_page_scanners < curr_nscan) {
895 WAKE_PAGEOUT_SCANNER(reducing);
896 }
897 }
898
899 if (pageout_sampling) {
900 /*
901 * We still need to measure the rate at which the
902 * system is able to scan pages of memory. Each of
903 * these initial samples is a scan of as much system
904 * memory as practical, regardless of whether or not we
905 * are experiencing memory pressure.
906 */
907 desscan = total_pages;
908 pageout_nsec = max_pageout_nsec;
909
910 WAKE_PAGEOUT_SCANNER(sampling);
911 } else if (freemem < lotsfree + needfree) {
912 /*
913 * We need more memory.
914 */
915 low_mem_scan++;
916 WAKE_PAGEOUT_SCANNER(lowmem);
917 } else {
918 /*
919 * There are enough free pages, no need to
920 * kick the scanner threads. And next time
921 * around, keep more of the `highly shared'
922 * pages.
923 */
924 cv_signal_pageout();
925 if (po_share > MIN_PO_SHARE)
926 po_share >>= 1;
927 }
928 out:
929 mutex_exit(&pageout_mutex);
930 }
931
932 /*
933 * Signal threads waiting for available memory.
934 * NOTE: usually we need to grab memavail_lock before cv_broadcast, but
935 * in this case it is not needed - the waiters will be woken up during
936 * the next invocation of this function.
937 */
938 if (kmem_avail() > 0)
939 cv_broadcast(&memavail_cv);
940
941 (void) timeout(schedpaging, arg, hz / SCHEDPAGING_HZ);
942 }
943
944 pgcnt_t pushes;
945 ulong_t push_list_size; /* # of requests on pageout queue */
946
947 /*
948 * Paging out should always be enabled. This tunable exists to hold pageout
949 * for debugging purposes. If set to 0, pageout_scanner() will go back to
950 * sleep each time it is woken by schedpaging().
951 */
952 uint_t dopageout = 1;
953
954 /*
955 * The page out daemon, which runs as process 2.
956 *
957 * The daemon treats physical memory as a circular array of pages and scans
958 * the pages using a 'two-handed clock' algorithm. The front hand moves
959 * through the pages, clearing the reference bit. The back hand travels a
960 * distance (handspreadpages) behind the front hand, freeing the pages that
961 * have not been referenced in the time since the front hand passed. If
962 * modified, they are first written to their backing store before being
963 * freed.
964 *
965 * In order to make page invalidation more responsive on machines with
966 * larger memory, multiple pageout_scanner threads may be created. In this
967 * case, each thread is given a segment of the memory "clock face" so that
968 * memory can be reclaimed more quickly. As long as there are at least lotsfree
969 * pages, then pageout_scanner threads are not run.
970 *
971 * There are multiple threads that act on behalf of the pageout process. A
972 * set of threads scan pages (pageout_scanner) and frees them up if they
973 * don't require any VOP_PUTPAGE operation. If a page must be written back
974 * to its backing store, the request is put on a list and the other
975 * (pageout) thread is signaled. The pageout thread grabs VOP_PUTPAGE
976 * requests from the list, and processes them. Some filesystems may require
977 * resources for the VOP_PUTPAGE operations (like memory) and hence can
978 * block the pageout thread, but the scanner thread can still operate.
979 * There is still no guarantee that memory deadlocks cannot occur.
980 */
981 void
pageout()982 pageout()
983 {
984 struct async_reqs *arg;
985 pri_t pageout_pri;
986 int i;
987 pgcnt_t max_pushes;
988 callb_cpr_t cprinfo;
989
990 proc_pageout = ttoproc(curthread);
991 proc_pageout->p_cstime = 0;
992 proc_pageout->p_stime = 0;
993 proc_pageout->p_cutime = 0;
994 proc_pageout->p_utime = 0;
995 bcopy("pageout", PTOU(curproc)->u_psargs, 8);
996 bcopy("pageout", PTOU(curproc)->u_comm, 7);
997
998 mutex_init(&pageout_mutex, NULL, MUTEX_DEFAULT, NULL);
999 mutex_init(&push_lock, NULL, MUTEX_DEFAULT, NULL);
1000
1001 /*
1002 * Allocate and initialize the async request structures for pageout.
1003 */
1004 push_req = (struct async_reqs *)
1005 kmem_zalloc(async_list_size * sizeof (struct async_reqs), KM_SLEEP);
1006
1007 req_freelist = push_req;
1008 for (i = 0; i < async_list_size - 1; i++) {
1009 push_req[i].a_next = &push_req[i + 1];
1010 }
1011
1012 pageout_pri = curthread->t_pri;
1013
1014 /* Create the first pageout scanner thread. */
1015 (void) lwp_kernel_create(proc_pageout, pageout_scanner,
1016 (void *)0, /* this is instance 0, not NULL */
1017 TS_RUN, pageout_pri - 1);
1018
1019 /*
1020 * kick off the pageout scheduler.
1021 */
1022 schedpaging(NULL);
1023
1024 /*
1025 * Create kernel cage thread.
1026 * The kernel cage thread is started under the pageout process
1027 * to take advantage of the less restricted page allocation
1028 * in page_create_throttle().
1029 */
1030 kcage_cageout_init();
1031
1032 /*
1033 * Limit pushes to avoid saturating pageout devices.
1034 */
1035 max_pushes = maxpgio / SCHEDPAGING_HZ;
1036 CALLB_CPR_INIT(&cprinfo, &push_lock, callb_generic_cpr, "pageout");
1037
1038 for (;;) {
1039 mutex_enter(&push_lock);
1040
1041 while ((arg = push_list) == NULL || pushes > max_pushes) {
1042 CALLB_CPR_SAFE_BEGIN(&cprinfo);
1043 cv_wait(&push_cv, &push_lock);
1044 pushes = 0;
1045 CALLB_CPR_SAFE_END(&cprinfo, &push_lock);
1046 }
1047 push_list = arg->a_next;
1048 arg->a_next = NULL;
1049 pageout_pushing = true;
1050 mutex_exit(&push_lock);
1051
1052 DTRACE_PROBE(pageout__push);
1053
1054 if (VOP_PUTPAGE(arg->a_vp, (offset_t)arg->a_off,
1055 arg->a_len, arg->a_flags, arg->a_cred, NULL) == 0) {
1056 pushes++;
1057 }
1058
1059 /* vp held by checkpage() */
1060 VN_RELE(arg->a_vp);
1061
1062 mutex_enter(&push_lock);
1063 pageout_pushing = false;
1064 pageout_pushcount++;
1065 arg->a_next = req_freelist; /* back on freelist */
1066 req_freelist = arg;
1067 push_list_size--;
1068 mutex_exit(&push_lock);
1069 }
1070 }
1071
1072 static void
pageout_sample_add(pgcnt_t count,hrtime_t elapsed)1073 pageout_sample_add(pgcnt_t count, hrtime_t elapsed)
1074 {
1075 VERIFY(pageout_sampling);
1076
1077 /*
1078 * The global variables used below are only modified during initial
1079 * scanning when there is a single page scanner thread running.
1080 */
1081 pageout_sample_pages += count;
1082 pageout_sample_etime += elapsed;
1083 pageout_sample_cnt++;
1084
1085 if (pageout_sample_cnt >= pageout_sample_lim) {
1086 /*
1087 * We have enough samples, set the spread.
1088 */
1089 pageout_sampling = false;
1090 pageout_rate = (hrrate_t)pageout_sample_pages *
1091 (hrrate_t)(NANOSEC) / pageout_sample_etime;
1092 pageout_new_spread = pageout_rate / 10;
1093 }
1094 }
1095
1096 static inline page_t *
wrapping_page_next(page_t * cur,page_t * start,page_t * end)1097 wrapping_page_next(page_t *cur, page_t *start, page_t *end)
1098 {
1099 if (cur == end)
1100 return (start);
1101 return (page_nextn(cur, 1));
1102 }
1103
1104 /*
1105 * Kernel thread that scans pages looking for ones to free
1106 */
1107 static void
pageout_scanner(void * a)1108 pageout_scanner(void *a)
1109 {
1110 page_t *fhand, *bhand, *fhandstart;
1111 page_t *regionstart, *regionend;
1112 uint_t laps;
1113 callb_cpr_t cprinfo;
1114 pgcnt_t nscan_cnt;
1115 pgcnt_t pcount;
1116 hrtime_t sample_start, sample_end;
1117 uint_t inst = (uint_t)(uintptr_t)a;
1118
1119 VERIFY3U(inst, <, MAX_PSCAN_THREADS);
1120
1121 CALLB_CPR_INIT(&cprinfo, &pageout_mutex, callb_generic_cpr, "poscan");
1122 mutex_enter(&pageout_mutex);
1123
1124 /*
1125 * The restart case does not attempt to point the hands at roughly
1126 * the right point on the assumption that after one circuit things
1127 * will have settled down, and restarts shouldn't be that often.
1128 */
1129 reset_hands[inst] = true;
1130
1131 pageouts_running++;
1132 mutex_exit(&pageout_mutex);
1133
1134 loop:
1135 cv_signal_pageout();
1136
1137 mutex_enter(&pageout_mutex);
1138 pageouts_running--;
1139 CALLB_CPR_SAFE_BEGIN(&cprinfo);
1140 cv_wait(&proc_pageout->p_cv, &pageout_mutex);
1141 CALLB_CPR_SAFE_END(&cprinfo, &pageout_mutex);
1142 pageouts_running++;
1143 mutex_exit(&pageout_mutex);
1144
1145 /*
1146 * Check if pageout has been disabled for debugging purposes.
1147 */
1148 if (dopageout == 0)
1149 goto loop;
1150
1151 /*
1152 * One may reset the clock hands and scanned region for debugging
1153 * purposes. Hands will also be reset on first thread startup, if
1154 * the number of scanning threads (n_page_scanners) changes, or if
1155 * memory is added to, or removed from, the system.
1156 */
1157 if (reset_hands[inst]) {
1158 page_t *first;
1159
1160 reset_hands[inst] = false;
1161
1162 if (inst >= n_page_scanners) {
1163 /*
1164 * The desired number of page scanners has been
1165 * reduced and this instance is no longer wanted.
1166 * Exit the lwp.
1167 */
1168 VERIFY3U(inst, !=, 0);
1169 DTRACE_PROBE1(pageout__exit, uint_t, inst);
1170 mutex_enter(&pageout_mutex);
1171 pageouts_running--;
1172 mutex_exit(&pageout_mutex);
1173 mutex_enter(&curproc->p_lock);
1174 lwp_exit();
1175 /* NOTREACHED */
1176 }
1177
1178 first = page_first();
1179
1180 /*
1181 * Each scanner thread gets its own sector of the memory
1182 * clock face.
1183 */
1184 pgcnt_t span, offset;
1185
1186 span = looppages / n_page_scanners;
1187 VERIFY3U(span, >, handspreadpages);
1188
1189 offset = inst * span;
1190 regionstart = page_nextn(first, offset);
1191 if (inst == n_page_scanners - 1) {
1192 /* The last instance goes up to the last page */
1193 regionend = page_nextn(first, looppages - 1);
1194 } else {
1195 regionend = page_nextn(regionstart, span - 1);
1196 }
1197
1198 bhand = regionstart;
1199 fhand = page_nextn(bhand, handspreadpages);
1200
1201 DTRACE_PROBE4(pageout__reset, uint_t, inst,
1202 pgcnt_t, regionstart, pgcnt_t, regionend,
1203 pgcnt_t, fhand);
1204 }
1205
1206 /*
1207 * This CPU kstat is only incremented here and we're on this CPU, so no
1208 * lock.
1209 */
1210 CPU_STATS_ADDQ(CPU, vm, pgrrun, 1);
1211
1212 /*
1213 * Keep track of the number of times we have scanned all the way around
1214 * the loop on this wakeup.
1215 */
1216 laps = 0;
1217
1218 /*
1219 * Track the number of pages visited during this scan so that we can
1220 * periodically measure our duty cycle.
1221 */
1222 nscan_cnt = 0;
1223 pcount = 0;
1224
1225 DTRACE_PROBE5(pageout__start, uint_t, inst, pgcnt_t, desscan,
1226 hrtime_t, pageout_nsec, page_t *, bhand, page_t *, fhand);
1227
1228 /*
1229 * Record the initial position of the front hand for this cycle so
1230 * that we can detect when the hand wraps around.
1231 */
1232 fhandstart = fhand;
1233
1234 sample_start = gethrtime();
1235
1236 /*
1237 * Scan the appropriate number of pages for a single duty cycle.
1238 */
1239 while (nscan_cnt < desscan) {
1240 checkpage_result_t rvfront, rvback;
1241
1242 if (!pageout_sampling && freemem >= lotsfree + needfree) {
1243 /*
1244 * We are not sampling and enough memory has become
1245 * available that scanning is no longer required.
1246 */
1247 DTRACE_PROBE1(pageout__memfree, uint_t, inst);
1248 break;
1249 }
1250
1251 DTRACE_PROBE2(pageout__loop, uint_t, inst, pgcnt_t, pcount);
1252
1253 /*
1254 * Periodically check to see if we have exceeded the CPU duty
1255 * cycle for a single wakeup.
1256 */
1257 if ((pcount & PAGES_POLL_MASK) == PAGES_POLL_MASK) {
1258 hrtime_t pageout_cycle_nsec;
1259
1260 pageout_cycle_nsec = gethrtime() - sample_start;
1261 if (pageout_cycle_nsec >= pageout_nsec) {
1262 atomic_inc_64(&pageout_timeouts);
1263 DTRACE_PROBE1(pageout__timeout, uint_t, inst);
1264 break;
1265 }
1266 }
1267
1268 /*
1269 * If checkpage manages to add a page to the free list,
1270 * we give ourselves another couple of trips around the loop.
1271 */
1272 if ((rvfront = checkpage(fhand, POH_FRONT)) == CKP_FREED) {
1273 laps = 0;
1274 }
1275 if ((rvback = checkpage(bhand, POH_BACK)) == CKP_FREED) {
1276 laps = 0;
1277 }
1278
1279 ++pcount;
1280
1281 /*
1282 * This CPU kstat is only incremented here and we're on this
1283 * CPU, so no lock.
1284 */
1285 CPU_STATS_ADDQ(CPU, vm, scan, 1);
1286
1287 /*
1288 * Don't include ineligible pages in the number scanned.
1289 */
1290 if (rvfront != CKP_INELIGIBLE || rvback != CKP_INELIGIBLE)
1291 nscan_cnt++;
1292
1293 /*
1294 * Tick
1295 */
1296 bhand = wrapping_page_next(bhand, regionstart, regionend);
1297 fhand = wrapping_page_next(fhand, regionstart, regionend);
1298
1299 /*
1300 * The front hand has wrapped around during this wakeup.
1301 */
1302 if (fhand == fhandstart) {
1303 laps++;
1304 DTRACE_PROBE2(pageout__hand__wrap, uint_t, inst,
1305 uint_t, laps);
1306
1307 /*
1308 * This CPU kstat is only incremented here and we're
1309 * on this CPU, so no lock.
1310 */
1311 CPU_STATS_ADDQ(CPU, vm, rev, 1);
1312
1313 if (laps > 1) {
1314 /*
1315 * Extremely unlikely, but it happens.
1316 * We went around the loop at least once
1317 * and didn't get far enough.
1318 * If we are still skipping `highly shared'
1319 * pages, skip fewer of them. Otherwise,
1320 * give up till the next clock tick.
1321 */
1322 if (po_share < MAX_PO_SHARE) {
1323 po_share <<= 1;
1324 } else {
1325 break;
1326 }
1327 }
1328 }
1329 }
1330
1331 sample_end = gethrtime();
1332 atomic_add_long(&nscan, nscan_cnt);
1333
1334 DTRACE_PROBE4(pageout__end, uint_t, inst, uint_t, laps,
1335 pgcnt_t, nscan_cnt, pgcnt_t, pcount)
1336
1337 /*
1338 * Continue accumulating samples until we have enough to get a
1339 * reasonable value for average scan rate.
1340 */
1341 if (pageout_sampling) {
1342 VERIFY3U(inst, ==, 0);
1343 pageout_sample_add(pcount, sample_end - sample_start);
1344 /*
1345 * If, after the sample just added, we have finished sampling,
1346 * set up the paging constants.
1347 */
1348 if (!pageout_sampling)
1349 setupclock();
1350 }
1351
1352 goto loop;
1353 }
1354
1355 /*
1356 * The pageout deadman is run once per second by clock().
1357 */
1358 void
pageout_deadman(void)1359 pageout_deadman(void)
1360 {
1361 if (panicstr != NULL) {
1362 /*
1363 * There is no pageout after panic.
1364 */
1365 return;
1366 }
1367
1368 if (pageout_deadman_seconds == 0) {
1369 /*
1370 * The deadman is not enabled.
1371 */
1372 return;
1373 }
1374
1375 if (!pageout_pushing) {
1376 goto reset;
1377 }
1378
1379 /*
1380 * We are pushing a page. Check to see if it is the same call we saw
1381 * last time we looked:
1382 */
1383 if (pageout_pushcount != pageout_pushcount_seen) {
1384 /*
1385 * It is a different call from the last check, so we are not
1386 * stuck.
1387 */
1388 goto reset;
1389 }
1390
1391 if (++pageout_stucktime >= pageout_deadman_seconds) {
1392 panic("pageout_deadman: stuck pushing the same page for %d "
1393 "seconds (freemem is %lu)", pageout_deadman_seconds,
1394 freemem);
1395 }
1396
1397 return;
1398
1399 reset:
1400 /*
1401 * Reset our tracking state to reflect that we are not stuck:
1402 */
1403 pageout_stucktime = 0;
1404 pageout_pushcount_seen = pageout_pushcount;
1405 }
1406
1407 /*
1408 * Look at the page at hand. If it is locked (e.g., for physical i/o),
1409 * system (u., page table) or free, then leave it alone. Otherwise,
1410 * if we are running the front hand, turn off the page's reference bit.
1411 * If the proc is over maxrss, we take it. If running the back hand,
1412 * check whether the page has been reclaimed. If not, free the page,
1413 * pushing it to disk first if necessary.
1414 *
1415 * Return values:
1416 * CKP_INELIGIBLE if the page is not a candidate at all,
1417 * CKP_NOT_FREED if the page was not freed, or
1418 * CKP_FREED if we freed it.
1419 */
1420 static checkpage_result_t
checkpage(page_t * pp,pageout_hand_t whichhand)1421 checkpage(page_t *pp, pageout_hand_t whichhand)
1422 {
1423 int ppattr;
1424 int isfs = 0;
1425 int isexec = 0;
1426 int pagesync_flag;
1427
1428 /*
1429 * Skip pages:
1430 * - associated with the kernel vnode since
1431 * they are always "exclusively" locked.
1432 * - that are free
1433 * - that are shared more than po_share'd times
1434 * - its already locked
1435 *
1436 * NOTE: These optimizations assume that reads are atomic.
1437 */
1438
1439 if (PP_ISKAS(pp) || PAGE_LOCKED(pp) || PP_ISFREE(pp) ||
1440 pp->p_lckcnt != 0 || pp->p_cowcnt != 0 ||
1441 hat_page_checkshare(pp, po_share)) {
1442 return (CKP_INELIGIBLE);
1443 }
1444
1445 if (!page_trylock(pp, SE_EXCL)) {
1446 /*
1447 * Skip the page if we can't acquire the "exclusive" lock.
1448 */
1449 return (CKP_INELIGIBLE);
1450 } else if (PP_ISFREE(pp)) {
1451 /*
1452 * It became free between the above check and our actually
1453 * locking the page. Oh well, there will be other pages.
1454 */
1455 page_unlock(pp);
1456 return (CKP_INELIGIBLE);
1457 }
1458
1459 /*
1460 * Reject pages that cannot be freed. The page_struct_lock
1461 * need not be acquired to examine these
1462 * fields since the page has an "exclusive" lock.
1463 */
1464 if (pp->p_lckcnt != 0 || pp->p_cowcnt != 0) {
1465 page_unlock(pp);
1466 return (CKP_INELIGIBLE);
1467 }
1468
1469 /*
1470 * Maintain statistics for what we are freeing
1471 */
1472 if (pp->p_vnode != NULL) {
1473 if (pp->p_vnode->v_flag & VVMEXEC)
1474 isexec = 1;
1475
1476 if (!IS_SWAPFSVP(pp->p_vnode))
1477 isfs = 1;
1478 }
1479
1480 /*
1481 * Turn off REF and MOD bits with the front hand.
1482 * The back hand examines the REF bit and always considers
1483 * SHARED pages as referenced.
1484 */
1485 if (whichhand == POH_FRONT) {
1486 pagesync_flag = HAT_SYNC_ZERORM;
1487 } else {
1488 pagesync_flag = HAT_SYNC_DONTZERO | HAT_SYNC_STOPON_REF |
1489 HAT_SYNC_STOPON_SHARED;
1490 }
1491
1492 ppattr = hat_pagesync(pp, pagesync_flag);
1493
1494 recheck:
1495 /*
1496 * If page is referenced; make unreferenced but reclaimable.
1497 * If this page is not referenced, then it must be reclaimable
1498 * and we can add it to the free list.
1499 */
1500 if (ppattr & P_REF) {
1501 DTRACE_PROBE2(pageout__isref, page_t *, pp,
1502 pageout_hand_t, whichhand);
1503
1504 if (whichhand == POH_FRONT) {
1505 /*
1506 * Checking of rss or madvise flags needed here...
1507 *
1508 * If not "well-behaved", fall through into the code
1509 * for not referenced.
1510 */
1511 hat_clrref(pp);
1512 }
1513
1514 /*
1515 * Somebody referenced the page since the front
1516 * hand went by, so it's not a candidate for
1517 * freeing up.
1518 */
1519 page_unlock(pp);
1520 return (CKP_NOT_FREED);
1521 }
1522
1523 VM_STAT_ADD(pageoutvmstats.checkpage[0]);
1524
1525 /*
1526 * If large page, attempt to demote it. If successfully demoted,
1527 * retry the checkpage.
1528 */
1529 if (pp->p_szc != 0) {
1530 if (!page_try_demote_pages(pp)) {
1531 VM_STAT_ADD(pageoutvmstats.checkpage[1]);
1532 page_unlock(pp);
1533 return (CKP_INELIGIBLE);
1534 }
1535
1536 ASSERT(pp->p_szc == 0);
1537 VM_STAT_ADD(pageoutvmstats.checkpage[2]);
1538
1539 /*
1540 * Since page_try_demote_pages() could have unloaded some
1541 * mappings it makes sense to reload ppattr.
1542 */
1543 ppattr = hat_page_getattr(pp, P_MOD | P_REF);
1544 }
1545
1546 /*
1547 * If the page is currently dirty, we have to arrange to have it
1548 * cleaned before it can be freed.
1549 *
1550 * XXX - ASSERT(pp->p_vnode != NULL);
1551 */
1552 if ((ppattr & P_MOD) && pp->p_vnode != NULL) {
1553 struct vnode *vp = pp->p_vnode;
1554 u_offset_t offset = pp->p_offset;
1555
1556 /*
1557 * XXX - Test for process being swapped out or about to exit?
1558 * [Can't get back to process(es) using the page.]
1559 */
1560
1561 /*
1562 * Hold the vnode before releasing the page lock to
1563 * prevent it from being freed and re-used by some
1564 * other thread.
1565 */
1566 VN_HOLD(vp);
1567 page_unlock(pp);
1568
1569 /*
1570 * Queue I/O request for the pageout thread.
1571 */
1572 if (!queue_io_request(vp, offset)) {
1573 VN_RELE(vp);
1574 return (CKP_NOT_FREED);
1575 }
1576 return (CKP_FREED);
1577 }
1578
1579 /*
1580 * Now we unload all the translations and put the page back on to the
1581 * free list. If the page was used (referenced or modified) after the
1582 * pagesync but before it was unloaded we catch it and handle the page
1583 * properly.
1584 */
1585 DTRACE_PROBE2(pageout__free, page_t *, pp, pageout_hand_t, whichhand);
1586 (void) hat_pageunload(pp, HAT_FORCE_PGUNLOAD);
1587 ppattr = hat_page_getattr(pp, P_MOD | P_REF);
1588 if ((ppattr & P_REF) || ((ppattr & P_MOD) && pp->p_vnode != NULL)) {
1589 goto recheck;
1590 }
1591
1592 VN_DISPOSE(pp, B_FREE, 0, kcred);
1593
1594 CPU_STATS_ADD_K(vm, dfree, 1);
1595
1596 if (isfs) {
1597 if (isexec) {
1598 CPU_STATS_ADD_K(vm, execfree, 1);
1599 } else {
1600 CPU_STATS_ADD_K(vm, fsfree, 1);
1601 }
1602 } else {
1603 CPU_STATS_ADD_K(vm, anonfree, 1);
1604 }
1605
1606 return (CKP_FREED);
1607 }
1608
1609 /*
1610 * Queue async i/o request from pageout_scanner and segment swapout
1611 * routines on one common list. This ensures that pageout devices (swap)
1612 * are not saturated by pageout_scanner or swapout requests.
1613 * The pageout thread empties this list by initiating i/o operations.
1614 */
1615 int
queue_io_request(vnode_t * vp,u_offset_t off)1616 queue_io_request(vnode_t *vp, u_offset_t off)
1617 {
1618 struct async_reqs *arg;
1619
1620 /*
1621 * If we cannot allocate an async request struct,
1622 * skip this page.
1623 */
1624 mutex_enter(&push_lock);
1625 if ((arg = req_freelist) == NULL) {
1626 mutex_exit(&push_lock);
1627 return (0);
1628 }
1629 req_freelist = arg->a_next; /* adjust freelist */
1630 push_list_size++;
1631
1632 arg->a_vp = vp;
1633 arg->a_off = off;
1634 arg->a_len = PAGESIZE;
1635 arg->a_flags = B_ASYNC | B_FREE;
1636 arg->a_cred = kcred; /* always held */
1637
1638 /*
1639 * Add to list of pending write requests.
1640 */
1641 arg->a_next = push_list;
1642 push_list = arg;
1643
1644 if (req_freelist == NULL) {
1645 /*
1646 * No free async requests left. The lock is held so we
1647 * might as well signal the pusher thread now.
1648 */
1649 cv_signal(&push_cv);
1650 }
1651 mutex_exit(&push_lock);
1652 return (1);
1653 }
1654
1655 /*
1656 * Wake up pageout to initiate i/o if push_list is not empty.
1657 */
1658 void
cv_signal_pageout()1659 cv_signal_pageout()
1660 {
1661 if (push_list != NULL) {
1662 mutex_enter(&push_lock);
1663 cv_signal(&push_cv);
1664 mutex_exit(&push_lock);
1665 }
1666 }
1667