| blob | d93c70857e03ce4645a267634f8ee5e18059594e |
1 /******************************************************************************
2 * Xen selfballoon driver (and optional frontswap self-shrinking driver)
3 *
4 * Copyright (c) 2009-2011, Dan Magenheimer, Oracle Corp.
5 *
6 * This code complements the cleancache and frontswap patchsets to optimize
7 * support for Xen Transcendent Memory ("tmem"). The policy it implements
8 * is rudimentary and will likely improve over time, but it does work well
9 * enough today.
10 *
11 * Two functionalities are implemented here which both use "control theory"
12 * (feedback) to optimize memory utilization. In a virtualized environment
13 * such as Xen, RAM is often a scarce resource and we would like to ensure
14 * that each of a possibly large number of virtual machines is using RAM
15 * efficiently, i.e. using as little as possible when under light load
16 * and obtaining as much as possible when memory demands are high.
17 * Since RAM needs vary highly dynamically and sometimes dramatically,
18 * "hysteresis" is used, that is, memory target is determined not just
19 * on current data but also on past data stored in the system.
20 *
21 * "Selfballooning" creates memory pressure by managing the Xen balloon
22 * driver to decrease and increase available kernel memory, driven
23 * largely by the target value of "Committed_AS" (see /proc/meminfo).
24 * Since Committed_AS does not account for clean mapped pages (i.e. pages
25 * in RAM that are identical to pages on disk), selfballooning has the
26 * affect of pushing less frequently used clean pagecache pages out of
27 * kernel RAM and, presumably using cleancache, into Xen tmem where
28 * Xen can more efficiently optimize RAM utilization for such pages.
29 *
30 * When kernel memory demand unexpectedly increases faster than Xen, via
31 * the selfballoon driver, is able to (or chooses to) provide usable RAM,
32 * the kernel may invoke swapping. In most cases, frontswap is able
33 * to absorb this swapping into Xen tmem. However, due to the fact
34 * that the kernel swap subsystem assumes swapping occurs to a disk,
35 * swapped pages may sit on the disk for a very long time; even if
36 * the kernel knows the page will never be used again. This is because
37 * the disk space costs very little and can be overwritten when
38 * necessary. When such stale pages are in frontswap, however, they
39 * are taking up valuable real estate. "Frontswap selfshrinking" works
40 * to resolve this: When frontswap activity is otherwise stable
41 * and the guest kernel is not under memory pressure, the "frontswap
42 * selfshrinking" accounts for this by providing pressure to remove some
43 * pages from frontswap and return them to kernel memory.
44 *
45 * For both "selfballooning" and "frontswap-selfshrinking", a worker
46 * thread is used and sysfs tunables are provided to adjust the frequency
47 * and rate of adjustments to achieve the goal, as well as to disable one
48 * or both functions independently.
49 *
50 * While some argue that this functionality can and should be implemented
51 * in userspace, it has been observed that bad things happen (e.g. OOMs).
52 *
53 * System configuration note: Selfballooning should not be enabled on
54 * systems without a sufficiently large swap device configured; for best
55 * results, it is recommended that total swap be increased by the size
56 * of the guest memory. Also, while technically not required to be
57 * configured, it is highly recommended that frontswap also be configured
58 * and enabled when selfballooning is running. So, selfballooning
59 * is disabled by default if frontswap is not configured and can only
60 * be enabled with the "selfballooning" kernel boot option; similarly
61 * selfballooning is enabled by default if frontswap is configured and
62 * can be disabled with the "noselfballooning" kernel boot option. Finally,
63 * when frontswap is configured, frontswap-selfshrinking can be disabled
64 * with the "noselfshrink" kernel boot option.
65 *
66 * Selfballooning is disallowed in domain0 and force-disabled.
67 *
68 */
70 #include <linux/kernel.h>
71 #include <linux/bootmem.h>
72 #include <linux/swap.h>
73 #include <linux/mm.h>
74 #include <linux/mman.h>
75 #include <linux/module.h>
76 #include <linux/workqueue.h>
77 #include <xen/balloon.h>
78 #include <xen/tmem.h>
79 #include <xen/xen.h>
81 /* Enable/disable with sysfs. */
84 /*
85 * Controls rate at which memory target (this iteration) approaches
86 * ultimate goal when memory need is increasing (up-hysteresis) or
87 * decreasing (down-hysteresis). Higher values of hysteresis cause
88 * slower increases/decreases. The default values for the various
89 * parameters were deemed reasonable by experimentation, may be
90 * workload-dependent, and can all be adjusted via sysfs.
91 */
95 /* In HZ, controls frequency of worker invocation. */
98 /*
99 * Minimum usable RAM in MB for selfballooning target for balloon.
100 * If non-zero, it is added to totalreserve_pages and self-ballooning
101 * will not balloon below the sum. If zero, a piecewise linear function
102 * is calculated as a minimum and added to totalreserve_pages. Note that
103 * setting this value indiscriminately may cause OOMs and crashes.
104 */
110 #ifdef CONFIG_FRONTSWAP
111 #include <linux/frontswap.h>
113 /* Enable/disable with sysfs. */
116 /* Enable/disable with kernel boot option. */
119 /*
120 * The default values for the following parameters were deemed reasonable
121 * by experimentation, may be workload-dependent, and can all be
122 * adjusted via sysfs.
123 */
125 /* Control rate for frontswap shrinking. Higher hysteresis is slower. */
128 /*
129 * Number of selfballoon worker invocations to wait before observing that
130 * frontswap selfshrinking should commence. Note that selfshrinking does
131 * not use a separate worker thread.
132 */
135 /* Countdown to next invocation of frontswap_shrink() */
138 /*
139 * Invoked by the selfballoon worker thread, uses current number of pages
140 * in frontswap (frontswap_curr_pages()), previous status, and control
141 * values (hysteresis and inertia) to determine if frontswap should be
142 * shrunk and what the new frontswap size should be. Note that
143 * frontswap_shrink is essentially a partial swapoff that immediately
144 * transfers pages from the "swap device" (frontswap) back into kernel
145 * RAM; despite the name, frontswap "shrinking" is very different from
146 * the "shrinker" interface used by the kernel MM subsystem to reclaim
147 * memory.
148 */
150 {
161 }
166 else
170 }
173 {
176 }
180 /* Disable with kernel boot option. */
184 {
187 }
191 /* Enable with kernel boot option. */
195 {
198 }
203 #define MB2PAGES(mb) ((mb) << (20 - PAGE_SHIFT))
205 /*
206 * Use current balloon size, the goal (vm_committed_as), and hysteresis
207 * parameters to set a new target balloon size
208 */
210 {
219 totalreserve_pages;
220 #ifdef CONFIG_FRONTSWAP
221 /* allow space for frontswap pages to be repatriated */
224 #endif
228 selfballoon_downhysteresis);
232 selfballoon_uphysteresis);
233 /* else if cur_pages == goal_pages, no change */
238 /* piecewise linear function ending in ~3% slope */
255 }
256 #ifdef CONFIG_FRONTSWAP
260 }
261 #endif
265 }
267 #ifdef CONFIG_SYSFS
269 #include <linux/sysdev.h>
270 #include <linux/capability.h>
272 #define SELFBALLOON_SHOW(name, format, args...) \
273 static ssize_t show_##name(struct sys_device *dev, \
274 struct sysdev_attribute *attr, \
275 char *buf) \
276 { \
277 return sprintf(buf, format, ##args); \
278 }
286 {
304 }
315 {
326 }
337 {
348 }
360 {
371 }
377 selfballoon_min_usable_mb);
383 {
394 }
397 show_selfballoon_min_usable_mb,
398 store_selfballoon_min_usable_mb);
401 #ifdef CONFIG_FRONTSWAP
408 {
420 frontswap_selfshrinking)
425 }
436 {
448 }
459 {
470 }
483 #ifdef CONFIG_FRONTSWAP
487 #endif
488 NULL
489 };
494 };
495 #endif
498 {
501 #ifdef CONFIG_SYSFS
503 #endif
505 }
509 {
519 }
526 }
527 #ifdef CONFIG_FRONTSWAP
533 }
534 #endif
541 }