| blob | 039eb1dfb6d7d0938a62f76f28aecd81280c7875 |
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 * Copyright 2009 Sun Microsystems, Inc. All rights reserved.
23 * Use is subject to license terms.
24 */
25 /*
26 * Copyright (c) 2009, Intel Corporation.
27 * All Rights Reserved.
28 */
30 /*
31 * CPU Device driver. The driver is not DDI-compliant.
32 *
33 * The driver supports following features:
34 * - Power management.
35 */
37 #include <sys/types.h>
38 #include <sys/param.h>
39 #include <sys/errno.h>
40 #include <sys/modctl.h>
41 #include <sys/kmem.h>
42 #include <sys/conf.h>
43 #include <sys/cmn_err.h>
44 #include <sys/stat.h>
45 #include <sys/debug.h>
46 #include <sys/systm.h>
47 #include <sys/ddi.h>
48 #include <sys/sunddi.h>
49 #include <sys/sdt.h>
50 #include <sys/epm.h>
51 #include <sys/machsystm.h>
52 #include <sys/x_call.h>
53 #include <sys/cpudrv_mach.h>
54 #include <sys/msacct.h>
56 /*
57 * CPU power management
58 *
59 * The supported power saving model is to slow down the CPU (on SPARC by
60 * dividing the CPU clock and on x86 by dropping down a P-state).
61 * Periodically we determine the amount of time the CPU is running
62 * idle thread and threads in user mode during the last quantum. If the idle
63 * thread was running less than its low water mark for current speed for
64 * number of consecutive sampling periods, or number of running threads in
65 * user mode are above its high water mark, we arrange to go to the higher
66 * speed. If the idle thread was running more than its high water mark without
67 * dropping a number of consecutive times below the mark, and number of threads
68 * running in user mode are below its low water mark, we arrange to go to the
69 * next lower speed. While going down, we go through all the speeds. While
70 * going up we go to the maximum speed to minimize impact on the user, but have
71 * provisions in the driver to go to other speeds.
72 *
73 * The driver does not have knowledge of a particular implementation of this
74 * scheme and will work with all CPUs supporting this model. On SPARC, the
75 * driver determines supported speeds by looking at 'clock-divisors' property
76 * created by OBP. On x86, the driver retrieves the supported speeds from
77 * ACPI.
78 */
80 /*
81 * Configuration function prototypes and data structures
82 */
100 };
106 };
111 NULL
112 };
114 /*
115 * Function prototypes
116 */
123 /*
124 * Driver global variables
125 */
137 /*
138 * cpudrv_direct_pm allows user applications to directly control the
139 * power state transitions (direct pm) without following the normal
140 * direct pm protocol. This is needed because the normal protocol
141 * requires that a device only be lowered when it is idle, and be
142 * brought up when it request to do so by calling pm_raise_power().
143 * Ignoring this protocol is harmless for CPU (other than speed).
144 * Moreover it might be the case that CPU is never idle or wants
145 * to be at higher speed because of the addition CPU cycles required
146 * to run the user application.
147 *
148 * The driver will still report idle/busy status to the framework. Although
149 * framework will ignore this information for direct pm devices and not
150 * try to bring them down when idle, user applications can still use this
151 * information if they wants.
152 *
153 * In the future, provide an ioctl to control setting of this mode. In
154 * that case, this variable should move to the state structure and
155 * be protected by the lock in the state structure.
156 */
159 /*
160 * Arranges for the handler function to be called at the interval suitable
161 * for current speed.
162 */
163 #define CPUDRV_MONITOR_INIT(cpudsp) { \
164 if (cpudrv_is_enabled(cpudsp)) { \
165 ASSERT(mutex_owned(&(cpudsp)->lock)); \
166 (cpudsp)->cpudrv_pm.timeout_id = \
167 timeout(cpudrv_monitor_disp, \
168 (cpudsp), (((cpudsp)->cpudrv_pm.cur_spd == NULL) ? \
169 CPUDRV_QUANT_CNT_OTHR : \
170 (cpudsp)->cpudrv_pm.cur_spd->quant_cnt)); \
171 } \
172 }
174 /*
175 * Arranges for the handler function not to be called back.
176 */
177 #define CPUDRV_MONITOR_FINI(cpudsp) { \
178 timeout_id_t tmp_tid; \
179 ASSERT(mutex_owned(&(cpudsp)->lock)); \
180 tmp_tid = (cpudsp)->cpudrv_pm.timeout_id; \
181 (cpudsp)->cpudrv_pm.timeout_id = 0; \
182 mutex_exit(&(cpudsp)->lock); \
183 if (tmp_tid != 0) { \
184 (void) untimeout(tmp_tid); \
185 mutex_enter(&(cpudsp)->cpudrv_pm.timeout_lock); \
186 while ((cpudsp)->cpudrv_pm.timeout_count != 0) \
187 cv_wait(&(cpudsp)->cpudrv_pm.timeout_cv, \
188 &(cpudsp)->cpudrv_pm.timeout_lock); \
189 mutex_exit(&(cpudsp)->cpudrv_pm.timeout_lock); \
190 } \
191 mutex_enter(&(cpudsp)->lock); \
192 }
194 int
196 {
203 }
207 }
209 /*
210 * Callbacks used by the PPM driver.
211 */
214 }
216 int
218 {
224 }
227 }
229 int
231 {
233 }
235 /*
236 * Driver attach(9e) entry point.
237 */
238 static int
240 {
253 DDI_SUCCESS) {
258 }
260 NULL) {
266 }
269 /*
270 * Find CPU number for this dev_info node.
271 */
278 }
287 }
293 }
300 }
302 /*
303 * Taskq is used to dispatch routine to monitor CPU
304 * activities.
305 */
315 /*
316 * Driver needs to assume that CPU is running at
317 * unknown speed at DDI_ATTACH and switch it to the
318 * needed speed. We assume that initial needed speed
319 * is full speed for us.
320 */
321 /*
322 * We need to take the lock because cpudrv_monitor()
323 * will start running in parallel with attach().
324 */
328 /*
329 * We don't call pm_raise_power() directly from attach
330 * because driver attach for a slave CPU node can
331 * happen before the CPU is even initialized. We just
332 * start the monitoring system which understands
333 * unknown speed and moves CPU to top speed when it
334 * has been initialized.
335 */
339 }
348 }
364 /*
365 * Nothing to do for resume, if not doing active PM.
366 */
371 /*
372 * Driver needs to assume that CPU is running at unknown speed
373 * at DDI_RESUME and switch it to the needed speed. We assume
374 * that the needed speed is full speed for us.
375 */
384 }
385 }
387 /*
388 * Driver detach(9e) entry point.
389 */
390 static int
392 {
404 #if defined(__x86)
408 /*
409 * Nothing to do for detach, if no doing active PM.
410 */
414 /*
415 * uninstall PPC/_TPC change notification handler
416 */
419 /*
420 * destruct platform specific resource
421 */
438 #else
439 /*
440 * If the only thing supported by the driver is power
441 * management, we can in future enhance the driver and
442 * framework that loads it to unload the driver when
443 * user has disabled CPU power management.
444 */
446 #endif
455 /*
456 * Nothing to do for suspend, if not doing active PM.
457 */
461 /*
462 * During a checkpoint-resume sequence, framework will
463 * stop interrupts to quiesce kernel activity. This will
464 * leave our monitoring system ineffective. Handle this
465 * by stopping our monitoring system and bringing CPU
466 * to full speed. In case we are in special direct pm
467 * mode, we leave the CPU at whatever speed it is. This
468 * is harmless other than speed.
469 */
490 "instance %d: can't busy CPU "
493 }
494 }
498 DDI_SUCCESS) {
504 instance,
509 }
513 }
517 }
518 }
520 /*
521 * Driver power(9e) entry point.
522 *
523 * Driver's notion of current power is set *only* in power(9e) entry point
524 * after actual power change operation has been successfully completed.
525 */
526 /* ARGSUSED */
527 static int
529 {
534 boolean_t is_ready;
546 }
548 /*
549 * We're not ready until we can get a cpu_t
550 */
556 /*
557 * In normal operation, we fail if we are busy and request is
558 * to lower the power level. We let this go through if the driver
559 * is in special direct pm mode. On x86, we also let this through
560 * if the change is due to a request to govern the max speed.
561 */
568 }
569 }
575 }
582 }
584 /*
585 * We currently refuse to power manage if the CPU is not ready to
586 * take cross calls (cross calls fail silently if CPU is not ready
587 * for it).
588 *
589 * Additionally, for x86 platforms we cannot power manage an instance,
590 * until it has been initialized.
591 */
600 instance));
601 }
602 }
607 }
609 /*
610 * Execute CPU specific routine on the requested CPU to
611 * change its speed to normal-speed/divisor.
612 */
618 }
620 /*
621 * Reset idle threshold time for the new power level.
622 */
626 DDI_SUCCESS) {
633 }
634 }
635 /*
636 * Reset various parameters because we are now running at new speed.
637 */
647 }
649 /*
650 * Initialize power management data.
651 */
652 static int
654 {
659 uint_t nspeeds;
666 /* Need at least two speeds to power manage */
669 }
672 /*
673 * Calculate the watermarks and other parameters based on the
674 * supplied speeds.
675 *
676 * One of the basic assumption is that for X amount of CPU work,
677 * if CPU is slowed down by a factor of N, the time it takes to
678 * do the same work will be N * X.
679 *
680 * The driver declares that a CPU is idle and ready for slowed down,
681 * if amount of idle thread is more than the current speed idle_hwm
682 * without dropping below idle_hwm a number of consecutive sampling
683 * intervals and number of running threads in user mode are below
684 * user_lwm. We want to set the current user_lwm such that if we
685 * just switched to the next slower speed with no change in real work
686 * load, the amount of user threads at the slower speed will be such
687 * that it falls below the slower speed's user_hwm. If we didn't do
688 * that then we will just come back to the higher speed as soon as we
689 * go down even with no change in work load.
690 * The user_hwm is a fixed precentage and not calculated dynamically.
691 *
692 * We bring the CPU up if idle thread at current speed is less than
693 * the current speed idle_lwm for a number of consecutive sampling
694 * intervals or user threads are above the user_hwm for the current
695 * speed.
696 */
706 /* can't speed anymore */
715 /*
716 * Let's assume CPU is considered idle at full speed
717 * when it is spending I% of time in running the idle
718 * thread. At full speed, CPU will be busy (100 - I) %
719 * of times. This % of busyness increases by factor of
720 * N as CPU slows down. CPU that is idle I% of times
721 * in full speed, it is idle (100 - ((100 - I) * N)) %
722 * of times in N speed. The idle_lwm is a fixed
723 * percentage. A large value of N may result in
724 * idle_hwm to go below idle_lwm. We need to make sure
725 * that there is at least a buffer zone seperation
726 * between the idle_lwm and idle_hwm values.
727 */
737 /*
738 * The lwm for user threads are determined such that
739 * if CPU slows down, the load of work in the
740 * new speed would still keep the CPU at or below the
741 * user_hwm in the new speed. This is to prevent
742 * the quick jump back up to higher speed.
743 */
750 }
752 }
753 /* Slowest speed. Can't slow down anymore */
756 #ifdef DEBUG
762 "down_spd spd %d, idle_hwm %d, user_lwm %d, "
763 "up_spd spd %d, idle_lwm %d, user_hwm %d, "
771 }
775 }
777 /*
778 * Free CPU power management data.
779 */
780 static void
782 {
791 }
793 }
795 /*
796 * Create pm-components property.
797 */
798 static int
800 {
807 uint_t comp_spd;
818 }
831 }
835 }
840 }
854 }
858 }
862 }
864 /*
865 * Mark a component idle.
866 */
867 #define CPUDRV_MONITOR_PM_IDLE_COMP(dip, cpupm) { \
868 if ((cpupm)->pm_busycnt >= 1) { \
869 if (pm_idle_component((dip), CPUDRV_COMP_NUM) == \
870 DDI_SUCCESS) { \
873 ddi_get_instance((dip)))); \
874 (cpupm)->pm_busycnt--; \
875 } else { \
878 ddi_get_instance((dip))); \
879 } \
880 } \
881 }
883 /*
884 * Marks a component busy in both PM framework and driver state structure.
885 */
886 #define CPUDRV_MONITOR_PM_BUSY_COMP(dip, cpupm) { \
887 if ((cpupm)->pm_busycnt < 1) { \
888 if (pm_busy_component((dip), CPUDRV_COMP_NUM) == \
889 DDI_SUCCESS) { \
892 ddi_get_instance((dip)))); \
893 (cpupm)->pm_busycnt++; \
894 } else { \
897 ddi_get_instance((dip))); \
898 } \
899 } \
900 }
902 /*
903 * Marks a component busy and calls pm_raise_power().
904 */
905 #define CPUDRV_MONITOR_PM_BUSY_AND_RAISE(dip, cpudsp, cpupm, new_spd) { \
906 int ret; \
907 /* \
908 * Mark driver and PM framework busy first so framework doesn't try \
909 * to bring CPU to lower speed when we need to be at higher speed. \
911 CPUDRV_MONITOR_PM_BUSY_COMP((dip), (cpupm)); \
912 mutex_exit(&(cpudsp)->lock); \
915 (new_spd->pm_level))); \
916 ret = pm_raise_power((dip), CPUDRV_COMP_NUM, (new_spd->pm_level)); \
917 if (ret != DDI_SUCCESS) { \
920 } \
921 mutex_enter(&(cpudsp)->lock); \
922 if (ret == DDI_SUCCESS && cpudsp->cpudrv_pm.cur_spd == NULL) { \
923 cpudsp->cpudrv_pm.cur_spd = new_spd; \
924 } \
925 }
927 /*
928 * In order to monitor a CPU, we need to hold cpu_lock to access CPU
929 * statistics. Holding cpu_lock is not allowed from a callout routine.
930 * We dispatch a taskq to do that job.
931 */
932 static void
934 {
937 /*
938 * We are here because the last task has scheduled a timeout.
939 * The queue should be empty at this time.
940 */
951 }
954 }
956 /*
957 * Monitors each CPU for the amount of time idle thread was running in the
958 * last quantum and arranges for the CPU to go to the lower or higher speed.
959 * Called at the time interval appropriate for the current speed. The
960 * time interval for normal speed is CPUDRV_QUANT_CNT_NORMAL. The time
961 * interval for other speeds (including unknown speed) is
962 * CPUDRV_QUANT_CNT_OTHR.
963 */
964 static void
966 {
973 uint_t tick_cnt;
975 boolean_t is_ready;
977 #define GET_CPU_MSTATE_CNT(state, cnt) \
978 msnsecs[state] = NSEC_TO_TICK(msnsecs[state]); \
979 if (cpupm->lastquan_mstate[state] > msnsecs[state]) \
980 msnsecs[state] = cpupm->lastquan_mstate[state]; \
981 cnt = msnsecs[state] - cpupm->lastquan_mstate[state]; \
982 cpupm->lastquan_mstate[state] = msnsecs[state]
984 /*
985 * We're not ready until we can get a cpu_t
986 */
994 }
998 /*
999 * We assume that a CPU is initialized and has a valid cpu_t
1000 * structure, if it is ready for cross calls. If this changes,
1001 * additional checks might be needed.
1002 *
1003 * Additionally, for x86 platforms we cannot power manage an
1004 * instance, until it has been initialized.
1005 */
1016 }
1017 }
1019 /*
1020 * Make sure that we are busy so that framework doesn't
1021 * try to bring us down in this situation.
1022 */
1027 }
1029 /*
1030 * Make sure that we are still not at unknown power level.
1031 */
1037 /*
1038 * We just changed the speed. Wait till at least next
1039 * call to this routine before proceeding ahead.
1040 */
1044 }
1049 }
1056 /*
1057 * We can't do anything when we have just switched to a state
1058 * because there is no valid timestamp.
1059 */
1065 }
1067 /*
1068 * Various watermarks are based on this routine being called back
1069 * exactly at the requested period. This is not guaranteed
1070 * because this routine is called from a taskq that is dispatched
1071 * from a timeout routine. Handle this by finding out how many
1072 * ticks have elapsed since the last call and adjusting
1073 * the idle_cnt based on the delay added to the requested period
1074 * by timeout and taskq.
1075 */
1081 /*
1082 * Time taken between recording the current counts and
1083 * arranging the next call of this routine is an error in our
1084 * calculation. We minimize the error by calling
1085 * CPUDRV_MONITOR_INIT() here instead of end of this routine.
1086 */
1089 "idle count %d, user count %d, system count %d, pm_level %d, "
1093 #ifdef DEBUG
1094 /*
1095 * Notify that timeout and taskq has caused delays and we need to
1096 * scale our parameters accordingly.
1097 *
1098 * To get accurate result, don't turn on other DPRINTFs with
1099 * the following DPRINTF. PROM calls generated by other
1100 * DPRINTFs changes the timing.
1101 */
1106 }
1109 /*
1110 * Adjust counts based on the delay added by timeout and taskq.
1111 */
1119 /*
1120 * In normal situation, arrange to go to next higher speed.
1121 * If we are running in special direct pm mode, we just stay
1122 * at the current speed.
1123 */
1129 new_spd);
1130 }
1135 /*
1136 * Arrange to go to next lower speed by informing our idle
1137 * status to the power management framework.
1138 */
1141 /*
1142 * If we are between the idle water marks and have not
1143 * been here enough consecutive times to be considered
1144 * busy, just increment the count and return.
1145 */
1153 }
1157 }
1158 /*
1159 * Arranges to stay at the current speed.
1160 */
1162 }
1164 do_return:
1170 }
1172 /*
1173 * get cpu_t structure for cpudrv_devstate_t
1174 */
1175 int
1177 {
1180 /*
1181 * return DDI_SUCCESS if cpudrv_devstate_t
1182 * already contains cpu_t structure
1183 */
1193 }
1199 }