| blob | fa0787bb8251573ff3737e4a1ca034452f7b395f |
1 /*
2 * menu.c - the menu idle governor
3 *
4 * Copyright (C) 2006-2007 Adam Belay <abelay@novell.com>
5 * Copyright (C) 2009 Intel Corporation
6 * Author:
7 * Arjan van de Ven <arjan@linux.intel.com>
8 *
9 * This code is licenced under the GPL version 2 as described
10 * in the COPYING file that acompanies the Linux Kernel.
11 */
13 #include <linux/kernel.h>
14 #include <linux/cpuidle.h>
15 #include <linux/pm_qos_params.h>
16 #include <linux/time.h>
17 #include <linux/ktime.h>
18 #include <linux/hrtimer.h>
19 #include <linux/tick.h>
20 #include <linux/sched.h>
21 #include <linux/math64.h>
23 #define BUCKETS 12
24 #define INTERVALS 8
25 #define RESOLUTION 1024
26 #define DECAY 8
27 #define MAX_INTERESTING 50000
28 #define STDDEV_THRESH 400
31 /*
32 * Concepts and ideas behind the menu governor
33 *
34 * For the menu governor, there are 3 decision factors for picking a C
35 * state:
36 * 1) Energy break even point
37 * 2) Performance impact
38 * 3) Latency tolerance (from pmqos infrastructure)
39 * These these three factors are treated independently.
40 *
41 * Energy break even point
42 * -----------------------
43 * C state entry and exit have an energy cost, and a certain amount of time in
44 * the C state is required to actually break even on this cost. CPUIDLE
45 * provides us this duration in the "target_residency" field. So all that we
46 * need is a good prediction of how long we'll be idle. Like the traditional
47 * menu governor, we start with the actual known "next timer event" time.
48 *
49 * Since there are other source of wakeups (interrupts for example) than
50 * the next timer event, this estimation is rather optimistic. To get a
51 * more realistic estimate, a correction factor is applied to the estimate,
52 * that is based on historic behavior. For example, if in the past the actual
53 * duration always was 50% of the next timer tick, the correction factor will
54 * be 0.5.
55 *
56 * menu uses a running average for this correction factor, however it uses a
57 * set of factors, not just a single factor. This stems from the realization
58 * that the ratio is dependent on the order of magnitude of the expected
59 * duration; if we expect 500 milliseconds of idle time the likelihood of
60 * getting an interrupt very early is much higher than if we expect 50 micro
61 * seconds of idle time. A second independent factor that has big impact on
62 * the actual factor is if there is (disk) IO outstanding or not.
63 * (as a special twist, we consider every sleep longer than 50 milliseconds
64 * as perfect; there are no power gains for sleeping longer than this)
65 *
66 * For these two reasons we keep an array of 12 independent factors, that gets
67 * indexed based on the magnitude of the expected duration as well as the
68 * "is IO outstanding" property.
69 *
70 * Repeatable-interval-detector
71 * ----------------------------
72 * There are some cases where "next timer" is a completely unusable predictor:
73 * Those cases where the interval is fixed, for example due to hardware
74 * interrupt mitigation, but also due to fixed transfer rate devices such as
75 * mice.
76 * For this, we use a different predictor: We track the duration of the last 8
77 * intervals and if the stand deviation of these 8 intervals is below a
78 * threshold value, we use the average of these intervals as prediction.
79 *
80 * Limiting Performance Impact
81 * ---------------------------
82 * C states, especially those with large exit latencies, can have a real
83 * noticable impact on workloads, which is not acceptable for most sysadmins,
84 * and in addition, less performance has a power price of its own.
85 *
86 * As a general rule of thumb, menu assumes that the following heuristic
87 * holds:
88 * The busier the system, the less impact of C states is acceptable
89 *
90 * This rule-of-thumb is implemented using a performance-multiplier:
91 * If the exit latency times the performance multiplier is longer than
92 * the predicted duration, the C state is not considered a candidate
93 * for selection due to a too high performance impact. So the higher
94 * this multiplier is, the longer we need to be idle to pick a deep C
95 * state, and thus the less likely a busy CPU will hit such a deep
96 * C state.
97 *
98 * Two factors are used in determing this multiplier:
99 * a value of 10 is added for each point of "per cpu load average" we have.
100 * a value of 5 points is added for each process that is waiting for
101 * IO on this CPU.
102 * (these values are experimentally determined)
103 *
104 * The load average factor gives a longer term (few seconds) input to the
105 * decision, while the iowait value gives a cpu local instantanious input.
106 * The iowait factor may look low, but realize that this is also already
107 * represented in the system load average.
108 *
109 */
116 u64 predicted_us;
122 };
125 #define LOAD_INT(x) ((x) >> FSHIFT)
126 #define LOAD_FRAC(x) LOAD_INT(((x) & (FIXED_1-1)) * 100)
129 {
134 }
137 {
140 /*
141 * We keep two groups of stats; one with no
142 * IO pending, one without.
143 * This allows us to calculate
144 * E(duration)|iowait
145 */
160 }
162 /*
163 * Return a multiplier for the exit latency that is intended
164 * to take performance requirements into account.
165 * The more performance critical we estimate the system
166 * to be, the higher this multiplier, and thus the higher
167 * the barrier to go to an expensive C state.
168 */
170 {
173 /* for higher loadavg, we are more reluctant */
177 /* for IO wait tasks (per cpu!) we add 5x each */
181 }
187 /* This implements DIV_ROUND_CLOSEST but avoids 64 bit division */
189 {
191 }
193 /*
194 * Try detecting repeating patterns by keeping track of the last 8
195 * intervals, and checking if the standard deviation of that set
196 * of points is below a threshold. If it is... then use the
197 * average of these 8 points as the estimated value.
198 */
200 {
205 /* first calculate average and standard deviation of the past */
210 /* if the avg is beyond the known next tick, it's worthless */
220 /*
221 * now.. if stddev is small.. then assume we have a
222 * repeating pattern and predict we keep doing this.
223 */
227 }
229 /**
230 * menu_select - selects the next idle state to enter
231 * @dev: the CPU
232 */
234 {
244 }
249 /* Special case when user has set very strict latency requirement */
253 /* determine the expected residency time, round up */
263 /*
264 * if the correction factor is 0 (eg first time init or cpu hotplug
265 * etc), we actually want to start out with a unity factor.
266 */
270 /* Make sure to round up for half microseconds */
276 /*
277 * We want to default to C1 (hlt), not to busy polling
278 * unless the timer is happening really really soon.
279 */
284 /* find the deepest idle state that satisfies our constraints */
296 }
299 }
301 /**
302 * menu_reflect - records that data structures need update
303 * @dev: the CPU
304 *
305 * NOTE: it's important to be fast here because this operation will add to
306 * the overall exit latency.
307 */
309 {
312 }
314 /**
315 * menu_update - attempts to guess what happened after entry
316 * @dev: the CPU
317 */
319 {
325 u64 new_factor;
327 /*
328 * Ugh, this idle state doesn't support residency measurements, so we
329 * are basically lost in the dark. As a compromise, assume we slept
330 * for the whole expected time.
331 */
338 /*
339 * We correct for the exit latency; we are assuming here that the
340 * exit latency happens after the event that we're interested in.
341 */
346 /* update our correction ratio */
353 else
354 /*
355 * we were idle so long that we count it as a perfect
356 * prediction
357 */
360 /*
361 * We don't want 0 as factor; we always want at least
362 * a tiny bit of estimated time.
363 */
369 /* update the repeating-pattern data */
373 }
375 /**
376 * menu_enable_device - scans a CPU's states and does setup
377 * @dev: the CPU
378 */
380 {
386 }
395 };
397 /**
398 * init_menu - initializes the governor
399 */
401 {
403 }
405 /**
406 * exit_menu - exits the governor
407 */
409 {
411 }