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[apple/xnu.git] / osfmk / kern / sfi.c
1 /*
2 * Copyright (c) 2013 Apple Inc. All rights reserved.
3 *
4 * @APPLE_OSREFERENCE_LICENSE_HEADER_START@
5 *
6 * This file contains Original Code and/or Modifications of Original Code
7 * as defined in and that are subject to the Apple Public Source License
8 * Version 2.0 (the 'License'). You may not use this file except in
9 * compliance with the License. The rights granted to you under the License
10 * may not be used to create, or enable the creation or redistribution of,
11 * unlawful or unlicensed copies of an Apple operating system, or to
12 * circumvent, violate, or enable the circumvention or violation of, any
13 * terms of an Apple operating system software license agreement.
14 *
15 * Please obtain a copy of the License at
16 * http://www.opensource.apple.com/apsl/ and read it before using this file.
17 *
18 * The Original Code and all software distributed under the License are
19 * distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER
20 * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
21 * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY,
22 * FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT.
23 * Please see the License for the specific language governing rights and
24 * limitations under the License.
25 *
26 * @APPLE_OSREFERENCE_LICENSE_HEADER_END@
27 */
28 #include <mach/mach_types.h>
29 #include <kern/assert.h>
30 #include <kern/clock.h>
31 #include <kern/coalition.h>
32 #include <kern/debug.h>
33 #include <kern/host.h>
34 #include <kern/kalloc.h>
35 #include <kern/kern_types.h>
36 #include <kern/machine.h>
37 #include <kern/simple_lock.h>
38 #include <kern/misc_protos.h>
39 #include <kern/sched.h>
40 #include <kern/sched_prim.h>
41 #include <kern/sfi.h>
42 #include <kern/timer_call.h>
43 #include <kern/waitq.h>
44 #include <kern/ledger.h>
45 #include <pexpert/pexpert.h>
46
47 #include <libkern/kernel_mach_header.h>
48
49 #include <sys/kdebug.h>
50
51 #if CONFIG_SCHED_SFI
52
53 #define SFI_DEBUG 0
54
55 #if SFI_DEBUG
56 #define dprintf(...) kprintf(__VA_ARGS__)
57 #else
58 #define dprintf(...) do { } while(0)
59 #endif
60
61 #ifdef MACH_BSD
62 extern sched_call_t workqueue_get_sched_callback(void);
63 #endif /* MACH_BSD */
64
65 /*
66 * SFI (Selective Forced Idle) operates by enabling a global
67 * timer on the SFI window interval. When it fires, all processors
68 * running a thread that should be SFI-ed are sent an AST.
69 * As threads become runnable while in their "off phase", they
70 * are placed on a deferred ready queue. When a per-class
71 * "on timer" fires, the ready threads for that class are
72 * re-enqueued for running. As an optimization to avoid spurious
73 * wakeups, the timer may be lazily programmed.
74 */
75
76 /*
77 * The "sfi_lock" simple lock guards access to static configuration
78 * parameters (as specified by userspace), dynamic state changes
79 * (as updated by the timer event routine), and timer data structures.
80 * Since it can be taken with interrupts disabled in some cases, all
81 * uses should be taken with interrupts disabled at splsched(). The
82 * "sfi_lock" also guards the "sfi_wait_class" field of thread_t, and
83 * must only be accessed with it held.
84 *
85 * When an "on timer" fires, we must deterministically be able to drain
86 * the wait queue, since if any threads are added to the queue afterwards,
87 * they may never get woken out of SFI wait. So sfi_lock must be
88 * taken before the wait queue's own spinlock.
89 *
90 * The wait queue will take the thread's scheduling lock. We may also take
91 * the thread_lock directly to update the "sfi_class" field and determine
92 * if the thread should block in the wait queue, but the lock will be
93 * released before doing so.
94 *
95 * The pset lock may also be taken, but not while any other locks are held.
96 *
97 * splsched ---> sfi_lock ---> waitq ---> thread_lock
98 * \ \ \__ thread_lock (*)
99 * \ \__ pset_lock
100 * \
101 * \__ thread_lock
102 */
103
104 decl_simple_lock_data(static,sfi_lock);
105 static timer_call_data_t sfi_timer_call_entry;
106 volatile boolean_t sfi_is_enabled;
107
108 boolean_t sfi_window_is_set;
109 uint64_t sfi_window_usecs;
110 uint64_t sfi_window_interval;
111 uint64_t sfi_next_off_deadline;
112
113 typedef struct {
114 sfi_class_id_t class_id;
115 thread_continue_t class_continuation;
116 const char * class_name;
117 const char * class_ledger_name;
118 } sfi_class_registration_t;
119
120 /*
121 * To add a new SFI class:
122 *
123 * 1) Raise MAX_SFI_CLASS_ID in mach/sfi_class.h
124 * 2) Add a #define for it to mach/sfi_class.h. It need not be inserted in order of restrictiveness.
125 * 3) Add a call to SFI_CLASS_REGISTER below
126 * 4) Augment sfi_thread_classify to categorize threads as early as possible for as restrictive as possible.
127 * 5) Modify thermald to use the SFI class
128 */
129
130 static inline void _sfi_wait_cleanup(sched_call_t callback);
131
132 #define SFI_CLASS_REGISTER(class_id, ledger_name) \
133 extern char compile_time_assert_ ## class_id[SFI_CLASS_ ## class_id < MAX_SFI_CLASS_ID ? 1 : -1]; \
134 void __attribute__((noinline,noreturn)) SFI_ ## class_id ## _THREAD_IS_WAITING(void *callback, wait_result_t wret __unused); \
135 void SFI_ ## class_id ## _THREAD_IS_WAITING(void *callback, wait_result_t wret __unused) \
136 { \
137 _sfi_wait_cleanup(callback); \
138 thread_exception_return(); \
139 } \
140 \
141 sfi_class_registration_t SFI_ ## class_id ## _registration __attribute__((section("__DATA,__sfi_class_reg"),used)) = { SFI_CLASS_ ## class_id, SFI_ ## class_id ## _THREAD_IS_WAITING, "SFI_CLASS_" # class_id, "SFI_CLASS_" # ledger_name };
142
143 /* SFI_CLASS_UNSPECIFIED not included here */
144 SFI_CLASS_REGISTER(MAINTENANCE, MAINTENANCE)
145 SFI_CLASS_REGISTER(DARWIN_BG, DARWIN_BG)
146 SFI_CLASS_REGISTER(APP_NAP, APP_NAP)
147 SFI_CLASS_REGISTER(MANAGED_FOCAL, MANAGED)
148 SFI_CLASS_REGISTER(MANAGED_NONFOCAL, MANAGED)
149 SFI_CLASS_REGISTER(UTILITY, UTILITY)
150 SFI_CLASS_REGISTER(DEFAULT_FOCAL, DEFAULT)
151 SFI_CLASS_REGISTER(DEFAULT_NONFOCAL, DEFAULT)
152 SFI_CLASS_REGISTER(LEGACY_FOCAL, LEGACY)
153 SFI_CLASS_REGISTER(LEGACY_NONFOCAL, LEGACY)
154 SFI_CLASS_REGISTER(USER_INITIATED_FOCAL, USER_INITIATED)
155 SFI_CLASS_REGISTER(USER_INITIATED_NONFOCAL, USER_INITIATED)
156 SFI_CLASS_REGISTER(USER_INTERACTIVE_FOCAL, USER_INTERACTIVE)
157 SFI_CLASS_REGISTER(USER_INTERACTIVE_NONFOCAL, USER_INTERACTIVE)
158 SFI_CLASS_REGISTER(KERNEL, OPTED_OUT)
159 SFI_CLASS_REGISTER(OPTED_OUT, OPTED_OUT)
160
161 struct sfi_class_state {
162 uint64_t off_time_usecs;
163 uint64_t off_time_interval;
164
165 timer_call_data_t on_timer;
166 uint64_t on_timer_deadline;
167 boolean_t on_timer_programmed;
168
169 boolean_t class_sfi_is_enabled;
170 volatile boolean_t class_in_on_phase;
171
172 struct waitq waitq; /* threads in ready state */
173 thread_continue_t continuation;
174
175 const char * class_name;
176 const char * class_ledger_name;
177 };
178
179 /* Static configuration performed in sfi_early_init() */
180 struct sfi_class_state sfi_classes[MAX_SFI_CLASS_ID];
181
182 int sfi_enabled_class_count;
183
184 static void sfi_timer_global_off(
185 timer_call_param_t param0,
186 timer_call_param_t param1);
187
188 static void sfi_timer_per_class_on(
189 timer_call_param_t param0,
190 timer_call_param_t param1);
191
192 static sfi_class_registration_t *
193 sfi_get_registration_data(unsigned long *count)
194 {
195 unsigned long sectlen = 0;
196 void *sectdata;
197
198 sectdata = getsectdatafromheader(&_mh_execute_header, "__DATA", "__sfi_class_reg", &sectlen);
199 if (sectdata) {
200
201 if (sectlen % sizeof(sfi_class_registration_t) != 0) {
202 /* corrupt data? */
203 panic("__sfi_class_reg section has invalid size %lu", sectlen);
204 __builtin_unreachable();
205 }
206
207 *count = sectlen / sizeof(sfi_class_registration_t);
208 return (sfi_class_registration_t *)sectdata;
209 } else {
210 panic("__sfi_class_reg section not found");
211 __builtin_unreachable();
212 }
213 }
214
215 /* Called early in boot, when kernel is single-threaded */
216 void sfi_early_init(void)
217 {
218 unsigned long i, count;
219 sfi_class_registration_t *registrations;
220
221 registrations = sfi_get_registration_data(&count);
222 for (i=0; i < count; i++) {
223 sfi_class_id_t class_id = registrations[i].class_id;
224
225 assert(class_id < MAX_SFI_CLASS_ID); /* should be caught at compile-time */
226 if (class_id < MAX_SFI_CLASS_ID) {
227 if (sfi_classes[class_id].continuation != NULL) {
228 panic("Duplicate SFI registration for class 0x%x", class_id);
229 }
230 sfi_classes[class_id].class_sfi_is_enabled = FALSE;
231 sfi_classes[class_id].class_in_on_phase = TRUE;
232 sfi_classes[class_id].continuation = registrations[i].class_continuation;
233 sfi_classes[class_id].class_name = registrations[i].class_name;
234 sfi_classes[class_id].class_ledger_name = registrations[i].class_ledger_name;
235 }
236 }
237 }
238
239 void sfi_init(void)
240 {
241 sfi_class_id_t i;
242 kern_return_t kret;
243
244 simple_lock_init(&sfi_lock, 0);
245 timer_call_setup(&sfi_timer_call_entry, sfi_timer_global_off, NULL);
246 sfi_window_is_set = FALSE;
247 sfi_enabled_class_count = 0;
248 sfi_is_enabled = FALSE;
249
250 for (i = 0; i < MAX_SFI_CLASS_ID; i++) {
251 /* If the class was set up in sfi_early_init(), initialize remaining fields */
252 if (sfi_classes[i].continuation) {
253 timer_call_setup(&sfi_classes[i].on_timer, sfi_timer_per_class_on, (void *)(uintptr_t)i);
254 sfi_classes[i].on_timer_programmed = FALSE;
255
256 kret = waitq_init(&sfi_classes[i].waitq, SYNC_POLICY_FIFO|SYNC_POLICY_DISABLE_IRQ);
257 assert(kret == KERN_SUCCESS);
258 } else {
259 /* The only allowed gap is for SFI_CLASS_UNSPECIFIED */
260 if(i != SFI_CLASS_UNSPECIFIED) {
261 panic("Gap in registered SFI classes");
262 }
263 }
264 }
265 }
266
267 /* Can be called before sfi_init() by task initialization, but after sfi_early_init() */
268 sfi_class_id_t
269 sfi_get_ledger_alias_for_class(sfi_class_id_t class_id)
270 {
271 sfi_class_id_t i;
272 const char *ledger_name = NULL;
273
274 ledger_name = sfi_classes[class_id].class_ledger_name;
275
276 /* Find the first class in the registration table with this ledger name */
277 if (ledger_name) {
278 for (i = SFI_CLASS_UNSPECIFIED + 1; i < class_id; i++) {
279 if (0 == strcmp(sfi_classes[i].class_ledger_name, ledger_name)) {
280 dprintf("sfi_get_ledger_alias_for_class(0x%x) -> 0x%x\n", class_id, i);
281 return i;
282 }
283 }
284
285 /* This class is the primary one for the ledger, so there is no alias */
286 dprintf("sfi_get_ledger_alias_for_class(0x%x) -> 0x%x\n", class_id, SFI_CLASS_UNSPECIFIED);
287 return SFI_CLASS_UNSPECIFIED;
288 }
289
290 /* We are permissive on SFI class lookup failures. In sfi_init(), we assert more */
291 return SFI_CLASS_UNSPECIFIED;
292 }
293
294 int
295 sfi_ledger_entry_add(ledger_template_t template, sfi_class_id_t class_id)
296 {
297 const char *ledger_name = NULL;
298
299 ledger_name = sfi_classes[class_id].class_ledger_name;
300
301 dprintf("sfi_ledger_entry_add(%p, 0x%x) -> %s\n", template, class_id, ledger_name);
302 return ledger_entry_add(template, ledger_name, "sfi", "MATUs");
303 }
304
305 static void sfi_timer_global_off(
306 timer_call_param_t param0 __unused,
307 timer_call_param_t param1 __unused)
308 {
309 uint64_t now = mach_absolute_time();
310 sfi_class_id_t i;
311 processor_set_t pset, nset;
312 processor_t processor;
313 uint32_t needs_cause_ast_mask = 0x0;
314 spl_t s;
315
316 s = splsched();
317
318 simple_lock(&sfi_lock);
319 if (!sfi_is_enabled) {
320 /* If SFI has been disabled, let all "on" timers drain naturally */
321 KERNEL_DEBUG_CONSTANT(MACHDBG_CODE(DBG_MACH_SFI, SFI_OFF_TIMER) | DBG_FUNC_NONE, 1, 0, 0, 0, 0);
322
323 simple_unlock(&sfi_lock);
324 splx(s);
325 return;
326 }
327
328 KERNEL_DEBUG_CONSTANT(MACHDBG_CODE(DBG_MACH_SFI, SFI_OFF_TIMER) | DBG_FUNC_START, 0, 0, 0, 0, 0);
329
330 /* First set all configured classes into the off state, and program their "on" timer */
331 for (i = 0; i < MAX_SFI_CLASS_ID; i++) {
332 if (sfi_classes[i].class_sfi_is_enabled) {
333 uint64_t on_timer_deadline;
334
335 sfi_classes[i].class_in_on_phase = FALSE;
336 sfi_classes[i].on_timer_programmed = TRUE;
337
338 /* Push out on-timer */
339 on_timer_deadline = now + sfi_classes[i].off_time_interval;
340 sfi_classes[i].on_timer_deadline = on_timer_deadline;
341
342 timer_call_enter1(&sfi_classes[i].on_timer, NULL, on_timer_deadline, TIMER_CALL_SYS_CRITICAL);
343 } else {
344 /* If this class no longer needs SFI, make sure the timer is cancelled */
345 sfi_classes[i].class_in_on_phase = TRUE;
346 if (sfi_classes[i].on_timer_programmed) {
347 sfi_classes[i].on_timer_programmed = FALSE;
348 sfi_classes[i].on_timer_deadline = ~0ULL;
349 timer_call_cancel(&sfi_classes[i].on_timer);
350 }
351 }
352 }
353 simple_unlock(&sfi_lock);
354
355 /* Iterate over processors, call cause_ast_check() on ones running a thread that should be in an off phase */
356 processor = processor_list;
357 pset = processor->processor_set;
358
359 pset_lock(pset);
360
361 do {
362 nset = processor->processor_set;
363 if (nset != pset) {
364 pset_unlock(pset);
365 pset = nset;
366 pset_lock(pset);
367 }
368
369 /* "processor" and its pset are locked */
370 if (processor->state == PROCESSOR_RUNNING) {
371 if (AST_NONE != sfi_processor_needs_ast(processor)) {
372 needs_cause_ast_mask |= (1U << processor->cpu_id);
373 }
374 }
375 } while ((processor = processor->processor_list) != NULL);
376
377 pset_unlock(pset);
378
379 processor = processor_list;
380 do {
381 if (needs_cause_ast_mask & (1U << processor->cpu_id)) {
382 if (processor == current_processor())
383 ast_on(AST_SFI);
384 else
385 cause_ast_check(processor);
386 }
387 } while ((processor = processor->processor_list) != NULL);
388
389 /* Re-arm timer if still enabled */
390 simple_lock(&sfi_lock);
391 if (sfi_is_enabled) {
392 clock_deadline_for_periodic_event(sfi_window_interval,
393 now,
394 &sfi_next_off_deadline);
395 timer_call_enter1(&sfi_timer_call_entry,
396 NULL,
397 sfi_next_off_deadline,
398 TIMER_CALL_SYS_CRITICAL);
399 }
400
401 KERNEL_DEBUG_CONSTANT(MACHDBG_CODE(DBG_MACH_SFI, SFI_OFF_TIMER) | DBG_FUNC_END, 0, 0, 0, 0, 0);
402
403 simple_unlock(&sfi_lock);
404
405 splx(s);
406 }
407
408 static void sfi_timer_per_class_on(
409 timer_call_param_t param0,
410 timer_call_param_t param1 __unused)
411 {
412 sfi_class_id_t sfi_class_id = (sfi_class_id_t)(uintptr_t)param0;
413 struct sfi_class_state *sfi_class = &sfi_classes[sfi_class_id];
414 kern_return_t kret;
415 spl_t s;
416
417 s = splsched();
418
419 simple_lock(&sfi_lock);
420
421 KERNEL_DEBUG_CONSTANT(MACHDBG_CODE(DBG_MACH_SFI, SFI_ON_TIMER) | DBG_FUNC_START, sfi_class_id, 0, 0, 0, 0);
422
423 /*
424 * Any threads that may have accumulated in the ready queue for this class should get re-enqueued.
425 * Since we have the sfi_lock held and have changed "class_in_on_phase", we expect
426 * no new threads to be put on this wait queue until the global "off timer" has fired.
427 */
428
429 sfi_class->class_in_on_phase = TRUE;
430 sfi_class->on_timer_programmed = FALSE;
431
432 kret = waitq_wakeup64_all(&sfi_class->waitq,
433 CAST_EVENT64_T(sfi_class_id),
434 THREAD_AWAKENED, WAITQ_ALL_PRIORITIES);
435 assert(kret == KERN_SUCCESS || kret == KERN_NOT_WAITING);
436
437 KERNEL_DEBUG_CONSTANT(MACHDBG_CODE(DBG_MACH_SFI, SFI_ON_TIMER) | DBG_FUNC_END, 0, 0, 0, 0, 0);
438
439 simple_unlock(&sfi_lock);
440
441 splx(s);
442 }
443
444
445 kern_return_t sfi_set_window(uint64_t window_usecs)
446 {
447 uint64_t interval, deadline;
448 uint64_t now = mach_absolute_time();
449 sfi_class_id_t i;
450 spl_t s;
451 uint64_t largest_class_off_interval = 0;
452
453 if (window_usecs < MIN_SFI_WINDOW_USEC)
454 window_usecs = MIN_SFI_WINDOW_USEC;
455
456 if (window_usecs > UINT32_MAX)
457 return (KERN_INVALID_ARGUMENT);
458
459 KERNEL_DEBUG_CONSTANT(MACHDBG_CODE(DBG_MACH_SFI, SFI_SET_WINDOW), window_usecs, 0, 0, 0, 0);
460
461 clock_interval_to_absolutetime_interval((uint32_t)window_usecs, NSEC_PER_USEC, &interval);
462 deadline = now + interval;
463
464 s = splsched();
465
466 simple_lock(&sfi_lock);
467
468 /* Check that we are not bringing in the SFI window smaller than any class */
469 for (i = 0; i < MAX_SFI_CLASS_ID; i++) {
470 if (sfi_classes[i].class_sfi_is_enabled) {
471 largest_class_off_interval = MAX(largest_class_off_interval, sfi_classes[i].off_time_interval);
472 }
473 }
474
475 /*
476 * Off window must be strictly greater than all enabled classes,
477 * otherwise threads would build up on ready queue and never be able to run.
478 */
479 if (interval <= largest_class_off_interval) {
480 simple_unlock(&sfi_lock);
481 splx(s);
482 return (KERN_INVALID_ARGUMENT);
483 }
484
485 /*
486 * If the new "off" deadline is further out than the current programmed timer,
487 * just let the current one expire (and the new cadence will be established thereafter).
488 * If the new "off" deadline is nearer than the current one, bring it in, so we
489 * can start the new behavior sooner. Note that this may cause the "off" timer to
490 * fire before some of the class "on" timers have fired.
491 */
492 sfi_window_usecs = window_usecs;
493 sfi_window_interval = interval;
494 sfi_window_is_set = TRUE;
495
496 if (sfi_enabled_class_count == 0) {
497 /* Can't program timer yet */
498 } else if (!sfi_is_enabled) {
499 sfi_is_enabled = TRUE;
500 sfi_next_off_deadline = deadline;
501 timer_call_enter1(&sfi_timer_call_entry,
502 NULL,
503 sfi_next_off_deadline,
504 TIMER_CALL_SYS_CRITICAL);
505 } else if (deadline >= sfi_next_off_deadline) {
506 sfi_next_off_deadline = deadline;
507 } else {
508 sfi_next_off_deadline = deadline;
509 timer_call_enter1(&sfi_timer_call_entry,
510 NULL,
511 sfi_next_off_deadline,
512 TIMER_CALL_SYS_CRITICAL);
513 }
514
515 simple_unlock(&sfi_lock);
516 splx(s);
517
518 return (KERN_SUCCESS);
519 }
520
521 kern_return_t sfi_window_cancel(void)
522 {
523 spl_t s;
524
525 s = splsched();
526
527 KERNEL_DEBUG_CONSTANT(MACHDBG_CODE(DBG_MACH_SFI, SFI_CANCEL_WINDOW), 0, 0, 0, 0, 0);
528
529 /* Disable globals so that global "off-timer" is not re-armed */
530 simple_lock(&sfi_lock);
531 sfi_window_is_set = FALSE;
532 sfi_window_usecs = 0;
533 sfi_window_interval = 0;
534 sfi_next_off_deadline = 0;
535 sfi_is_enabled = FALSE;
536 simple_unlock(&sfi_lock);
537
538 splx(s);
539
540 return (KERN_SUCCESS);
541 }
542
543 /* Defers SFI off and per-class on timers (if live) by the specified interval
544 * in Mach Absolute Time Units. Currently invoked to align with the global
545 * forced idle mechanism. Making some simplifying assumptions, the iterative GFI
546 * induced SFI on+off deferrals form a geometric series that converges to yield
547 * an effective SFI duty cycle that is scaled by the GFI duty cycle. Initial phase
548 * alignment and congruency of the SFI/GFI periods can distort this to some extent.
549 */
550
551 kern_return_t sfi_defer(uint64_t sfi_defer_matus)
552 {
553 spl_t s;
554 kern_return_t kr = KERN_FAILURE;
555 s = splsched();
556
557 KERNEL_DEBUG_CONSTANT(MACHDBG_CODE(DBG_MACH_SFI, SFI_GLOBAL_DEFER), sfi_defer_matus, 0, 0, 0, 0);
558
559 simple_lock(&sfi_lock);
560 if (!sfi_is_enabled) {
561 goto sfi_defer_done;
562 }
563
564 assert(sfi_next_off_deadline != 0);
565
566 sfi_next_off_deadline += sfi_defer_matus;
567 timer_call_enter1(&sfi_timer_call_entry, NULL, sfi_next_off_deadline, TIMER_CALL_SYS_CRITICAL);
568
569 int i;
570 for (i = 0; i < MAX_SFI_CLASS_ID; i++) {
571 if (sfi_classes[i].class_sfi_is_enabled) {
572 if (sfi_classes[i].on_timer_programmed) {
573 uint64_t new_on_deadline = sfi_classes[i].on_timer_deadline + sfi_defer_matus;
574 sfi_classes[i].on_timer_deadline = new_on_deadline;
575 timer_call_enter1(&sfi_classes[i].on_timer, NULL, new_on_deadline, TIMER_CALL_SYS_CRITICAL);
576 }
577 }
578 }
579
580 kr = KERN_SUCCESS;
581 sfi_defer_done:
582 simple_unlock(&sfi_lock);
583
584 splx(s);
585
586 return (kr);
587 }
588
589
590 kern_return_t sfi_get_window(uint64_t *window_usecs)
591 {
592 spl_t s;
593 uint64_t off_window_us;
594
595 s = splsched();
596 simple_lock(&sfi_lock);
597
598 off_window_us = sfi_window_usecs;
599
600 simple_unlock(&sfi_lock);
601 splx(s);
602
603 *window_usecs = off_window_us;
604
605 return (KERN_SUCCESS);
606 }
607
608
609 kern_return_t sfi_set_class_offtime(sfi_class_id_t class_id, uint64_t offtime_usecs)
610 {
611 uint64_t interval;
612 spl_t s;
613 uint64_t off_window_interval;
614
615 if (offtime_usecs < MIN_SFI_WINDOW_USEC)
616 offtime_usecs = MIN_SFI_WINDOW_USEC;
617
618 if (class_id == SFI_CLASS_UNSPECIFIED || class_id >= MAX_SFI_CLASS_ID)
619 return (KERN_INVALID_ARGUMENT);
620
621 if (offtime_usecs > UINT32_MAX)
622 return (KERN_INVALID_ARGUMENT);
623
624 KERNEL_DEBUG_CONSTANT(MACHDBG_CODE(DBG_MACH_SFI, SFI_SET_CLASS_OFFTIME), offtime_usecs, class_id, 0, 0, 0);
625
626 clock_interval_to_absolutetime_interval((uint32_t)offtime_usecs, NSEC_PER_USEC, &interval);
627
628 s = splsched();
629
630 simple_lock(&sfi_lock);
631 off_window_interval = sfi_window_interval;
632
633 /* Check that we are not bringing in class off-time larger than the SFI window */
634 if (off_window_interval && (interval >= off_window_interval)) {
635 simple_unlock(&sfi_lock);
636 splx(s);
637 return (KERN_INVALID_ARGUMENT);
638 }
639
640 /* We never re-program the per-class on-timer, but rather just let it expire naturally */
641 if (!sfi_classes[class_id].class_sfi_is_enabled) {
642 sfi_enabled_class_count++;
643 }
644 sfi_classes[class_id].off_time_usecs = offtime_usecs;
645 sfi_classes[class_id].off_time_interval = interval;
646 sfi_classes[class_id].class_sfi_is_enabled = TRUE;
647
648 if (sfi_window_is_set && !sfi_is_enabled) {
649 /* start global off timer */
650 sfi_is_enabled = TRUE;
651 sfi_next_off_deadline = mach_absolute_time() + sfi_window_interval;
652 timer_call_enter1(&sfi_timer_call_entry,
653 NULL,
654 sfi_next_off_deadline,
655 TIMER_CALL_SYS_CRITICAL);
656 }
657
658 simple_unlock(&sfi_lock);
659
660 splx(s);
661
662 return (KERN_SUCCESS);
663 }
664
665 kern_return_t sfi_class_offtime_cancel(sfi_class_id_t class_id)
666 {
667 spl_t s;
668
669 if (class_id == SFI_CLASS_UNSPECIFIED || class_id >= MAX_SFI_CLASS_ID)
670 return (KERN_INVALID_ARGUMENT);
671
672 s = splsched();
673
674 KERNEL_DEBUG_CONSTANT(MACHDBG_CODE(DBG_MACH_SFI, SFI_CANCEL_CLASS_OFFTIME), class_id, 0, 0, 0, 0);
675
676 simple_lock(&sfi_lock);
677
678 /* We never re-program the per-class on-timer, but rather just let it expire naturally */
679 if (sfi_classes[class_id].class_sfi_is_enabled) {
680 sfi_enabled_class_count--;
681 }
682 sfi_classes[class_id].off_time_usecs = 0;
683 sfi_classes[class_id].off_time_interval = 0;
684 sfi_classes[class_id].class_sfi_is_enabled = FALSE;
685
686 if (sfi_enabled_class_count == 0) {
687 sfi_is_enabled = FALSE;
688 }
689
690 simple_unlock(&sfi_lock);
691
692 splx(s);
693
694 return (KERN_SUCCESS);
695 }
696
697 kern_return_t sfi_get_class_offtime(sfi_class_id_t class_id, uint64_t *offtime_usecs)
698 {
699 uint64_t off_time_us;
700 spl_t s;
701
702 if (class_id == SFI_CLASS_UNSPECIFIED || class_id >= MAX_SFI_CLASS_ID)
703 return (0);
704
705 s = splsched();
706
707 simple_lock(&sfi_lock);
708 off_time_us = sfi_classes[class_id].off_time_usecs;
709 simple_unlock(&sfi_lock);
710
711 splx(s);
712
713 *offtime_usecs = off_time_us;
714
715 return (KERN_SUCCESS);
716 }
717
718 /*
719 * sfi_thread_classify and sfi_processor_active_thread_classify perform the critical
720 * role of quickly categorizing a thread into its SFI class so that an AST_SFI can be
721 * set. As the thread is unwinding to userspace, sfi_ast() performs full locking
722 * and determines whether the thread should enter an SFI wait state. Because of
723 * the inherent races between the time the AST is set and when it is evaluated,
724 * thread classification can be inaccurate (but should always be safe). This is
725 * especially the case for sfi_processor_active_thread_classify, which must
726 * classify the active thread on a remote processor without taking the thread lock.
727 * When in doubt, classification should err on the side of *not* classifying a
728 * thread at all, and wait for the thread itself to either hit a quantum expiration
729 * or block inside the kernel.
730 */
731
732 /*
733 * Thread must be locked. Ultimately, the real decision to enter
734 * SFI wait happens at the AST boundary.
735 */
736 sfi_class_id_t sfi_thread_classify(thread_t thread)
737 {
738 task_t task = thread->task;
739 boolean_t is_kernel_thread = (task == kernel_task);
740 sched_mode_t thmode = thread->sched_mode;
741 int latency_qos = proc_get_effective_task_policy(task, TASK_POLICY_LATENCY_QOS);
742 int task_role = proc_get_effective_task_policy(task, TASK_POLICY_ROLE);
743 int thread_bg = proc_get_effective_thread_policy(thread, TASK_POLICY_DARWIN_BG);
744 int managed_task = proc_get_effective_task_policy(task, TASK_POLICY_SFI_MANAGED);
745 int thread_qos = proc_get_effective_thread_policy(thread, TASK_POLICY_QOS);
746 boolean_t focal = FALSE;
747
748 /* kernel threads never reach the user AST boundary, and are in a separate world for SFI */
749 if (is_kernel_thread) {
750 return SFI_CLASS_KERNEL;
751 }
752
753 if (thread_qos == THREAD_QOS_MAINTENANCE)
754 return SFI_CLASS_MAINTENANCE;
755
756 if (thread_bg || thread_qos == THREAD_QOS_BACKGROUND) {
757 return SFI_CLASS_DARWIN_BG;
758 }
759
760 if (latency_qos != 0) {
761 int latency_qos_wtf = latency_qos - 1;
762
763 if ((latency_qos_wtf >= 4) && (latency_qos_wtf <= 5)) {
764 return SFI_CLASS_APP_NAP;
765 }
766 }
767
768 /*
769 * Realtime and fixed priority threads express their duty cycle constraints
770 * via other mechanisms, and are opted out of (most) forms of SFI
771 */
772 if (thmode == TH_MODE_REALTIME || thmode == TH_MODE_FIXED || task_role == TASK_GRAPHICS_SERVER) {
773 return SFI_CLASS_OPTED_OUT;
774 }
775
776 /*
777 * Threads with unspecified, legacy, or user-initiated QOS class can be individually managed.
778 */
779 switch (task_role) {
780 case TASK_CONTROL_APPLICATION:
781 case TASK_FOREGROUND_APPLICATION:
782 focal = TRUE;
783 break;
784 case TASK_BACKGROUND_APPLICATION:
785 case TASK_DEFAULT_APPLICATION:
786 case TASK_THROTTLE_APPLICATION:
787 case TASK_UNSPECIFIED:
788 /* Focal if the task is in a coalition with a FG/focal app */
789 if (task_coalition_focal_count(thread->task) > 0)
790 focal = TRUE;
791 break;
792 default:
793 break;
794 }
795
796 if (managed_task) {
797 switch (thread_qos) {
798 case THREAD_QOS_UNSPECIFIED:
799 case THREAD_QOS_LEGACY:
800 case THREAD_QOS_USER_INITIATED:
801 if (focal)
802 return SFI_CLASS_MANAGED_FOCAL;
803 else
804 return SFI_CLASS_MANAGED_NONFOCAL;
805 default:
806 break;
807 }
808 }
809
810 if (thread_qos == THREAD_QOS_UTILITY)
811 return SFI_CLASS_UTILITY;
812
813 /*
814 * Classify threads in non-managed tasks
815 */
816 if (focal) {
817 switch (thread_qos) {
818 case THREAD_QOS_USER_INTERACTIVE:
819 return SFI_CLASS_USER_INTERACTIVE_FOCAL;
820 case THREAD_QOS_USER_INITIATED:
821 return SFI_CLASS_USER_INITIATED_FOCAL;
822 case THREAD_QOS_LEGACY:
823 return SFI_CLASS_LEGACY_FOCAL;
824 default:
825 return SFI_CLASS_DEFAULT_FOCAL;
826 }
827 } else {
828 switch (thread_qos) {
829 case THREAD_QOS_USER_INTERACTIVE:
830 return SFI_CLASS_USER_INTERACTIVE_NONFOCAL;
831 case THREAD_QOS_USER_INITIATED:
832 return SFI_CLASS_USER_INITIATED_NONFOCAL;
833 case THREAD_QOS_LEGACY:
834 return SFI_CLASS_LEGACY_NONFOCAL;
835 default:
836 return SFI_CLASS_DEFAULT_NONFOCAL;
837 }
838 }
839 }
840
841 /*
842 * pset must be locked.
843 */
844 sfi_class_id_t sfi_processor_active_thread_classify(processor_t processor)
845 {
846 return processor->current_sfi_class;
847 }
848
849 /*
850 * thread must be locked. This is inherently racy, with the intent that
851 * at the AST boundary, it will be fully evaluated whether we need to
852 * perform an AST wait
853 */
854 ast_t sfi_thread_needs_ast(thread_t thread, sfi_class_id_t *out_class)
855 {
856 sfi_class_id_t class_id;
857
858 class_id = sfi_thread_classify(thread);
859
860 if (out_class)
861 *out_class = class_id;
862
863 /* No lock taken, so a stale value may be used. */
864 if (!sfi_classes[class_id].class_in_on_phase)
865 return AST_SFI;
866 else
867 return AST_NONE;
868 }
869
870 /*
871 * pset must be locked. We take the SFI class for
872 * the currently running thread which is cached on
873 * the processor_t, and assume it is accurate. In the
874 * worst case, the processor will get an IPI and be asked
875 * to evaluate if the current running thread at that
876 * later point in time should be in an SFI wait.
877 */
878 ast_t sfi_processor_needs_ast(processor_t processor)
879 {
880 sfi_class_id_t class_id;
881
882 class_id = sfi_processor_active_thread_classify(processor);
883
884 /* No lock taken, so a stale value may be used. */
885 if (!sfi_classes[class_id].class_in_on_phase)
886 return AST_SFI;
887 else
888 return AST_NONE;
889
890 }
891
892 static inline void _sfi_wait_cleanup(sched_call_t callback) {
893 thread_t self = current_thread();
894 sfi_class_id_t current_sfi_wait_class = SFI_CLASS_UNSPECIFIED;
895 int64_t sfi_wait_time, sfi_wait_begin = 0;
896
897 spl_t s = splsched();
898 thread_lock(self);
899 if (callback) {
900 thread_sched_call(self, callback);
901 }
902 sfi_wait_begin = self->wait_sfi_begin_time;
903 thread_unlock(self);
904
905 simple_lock(&sfi_lock);
906 sfi_wait_time = mach_absolute_time() - sfi_wait_begin;
907 current_sfi_wait_class = self->sfi_wait_class;
908 self->sfi_wait_class = SFI_CLASS_UNSPECIFIED;
909 simple_unlock(&sfi_lock);
910 splx(s);
911 assert((SFI_CLASS_UNSPECIFIED < current_sfi_wait_class) && (current_sfi_wait_class < MAX_SFI_CLASS_ID));
912 ledger_credit(self->task->ledger, task_ledgers.sfi_wait_times[current_sfi_wait_class], sfi_wait_time);
913 }
914
915 /*
916 * Called at AST context to fully evaluate if the current thread
917 * (which is obviously running) should instead block in an SFI wait.
918 * We must take the sfi_lock to check whether we are in the "off" period
919 * for the class, and if so, block.
920 */
921 void sfi_ast(thread_t thread)
922 {
923 sfi_class_id_t class_id;
924 spl_t s;
925 struct sfi_class_state *sfi_class;
926 wait_result_t waitret;
927 boolean_t did_wait = FALSE;
928 uint64_t tid;
929 thread_continue_t continuation;
930 sched_call_t workq_callback = workqueue_get_sched_callback();
931 boolean_t did_clear_wq = FALSE;
932
933 s = splsched();
934
935 simple_lock(&sfi_lock);
936
937 if (!sfi_is_enabled) {
938 /*
939 * SFI is not enabled, or has recently been disabled.
940 * There is no point putting this thread on a deferred ready
941 * queue, even if it were classified as needing it, since
942 * SFI will truly be off at the next global off timer
943 */
944 simple_unlock(&sfi_lock);
945 splx(s);
946
947 return;
948 }
949
950 thread_lock(thread);
951 thread->sfi_class = class_id = sfi_thread_classify(thread);
952 tid = thread_tid(thread);
953
954 /*
955 * Once the sfi_lock is taken and the thread's ->sfi_class field is updated, we
956 * are committed to transitioning to whatever state is indicated by "->class_in_on_phase".
957 * If another thread tries to call sfi_reevaluate() after this point, it will take the
958 * sfi_lock and see the thread in this wait state. If another thread calls
959 * sfi_reevaluate() before this point, it would see a runnable thread and at most
960 * attempt to send an AST to this processor, but we would have the most accurate
961 * classification.
962 */
963
964 /* Optimistically clear workq callback while thread is already locked */
965 if (workq_callback && (thread->sched_call == workq_callback)) {
966 thread_sched_call(thread, NULL);
967 did_clear_wq = TRUE;
968 }
969 thread_unlock(thread);
970
971 sfi_class = &sfi_classes[class_id];
972 if (!sfi_class->class_in_on_phase) {
973 /* Need to block thread in wait queue */
974 KERNEL_DEBUG_CONSTANT(MACHDBG_CODE(DBG_MACH_SFI, SFI_THREAD_DEFER), tid, class_id, 0, 0, 0);
975
976 waitret = waitq_assert_wait64(&sfi_class->waitq,
977 CAST_EVENT64_T(class_id),
978 THREAD_INTERRUPTIBLE,
979 0);
980 if (waitret == THREAD_WAITING) {
981 thread->sfi_wait_class = class_id;
982 did_wait = TRUE;
983 continuation = sfi_class->continuation;
984 } else {
985 /* thread may be exiting already, all other errors are unexpected */
986 assert(waitret == THREAD_INTERRUPTED);
987 }
988 }
989 simple_unlock(&sfi_lock);
990
991 splx(s);
992
993 if (did_wait) {
994 thread_block_reason(continuation, did_clear_wq ? workq_callback : NULL, AST_SFI);
995 } else {
996 if (did_clear_wq) {
997 s = splsched();
998 thread_lock(thread);
999 thread_sched_call(thread, workq_callback);
1000 thread_unlock(thread);
1001 splx(s);
1002 }
1003 }
1004 }
1005
1006 /* Thread must be unlocked */
1007 void sfi_reevaluate(thread_t thread)
1008 {
1009 kern_return_t kret;
1010 spl_t s;
1011 sfi_class_id_t class_id, current_class_id;
1012 ast_t sfi_ast;
1013
1014 s = splsched();
1015
1016 simple_lock(&sfi_lock);
1017
1018 thread_lock(thread);
1019 sfi_ast = sfi_thread_needs_ast(thread, &class_id);
1020 thread->sfi_class = class_id;
1021
1022 /*
1023 * This routine chiefly exists to boost threads out of an SFI wait
1024 * if their classification changes before the "on" timer fires.
1025 *
1026 * If we calculate that a thread is in a different ->sfi_wait_class
1027 * than we think it should be (including no-SFI-wait), we need to
1028 * correct that:
1029 *
1030 * If the thread is in SFI wait and should not be (or should be waiting
1031 * on a different class' "on" timer), we wake it up. If needed, the
1032 * thread may immediately block again in the different SFI wait state.
1033 *
1034 * If the thread is not in an SFI wait state and it should be, we need
1035 * to get that thread's attention, possibly by sending an AST to another
1036 * processor.
1037 */
1038
1039 if ((current_class_id = thread->sfi_wait_class) != SFI_CLASS_UNSPECIFIED) {
1040
1041 thread_unlock(thread); /* not needed anymore */
1042
1043 assert(current_class_id < MAX_SFI_CLASS_ID);
1044
1045 if ((sfi_ast == AST_NONE) || (class_id != current_class_id)) {
1046 struct sfi_class_state *sfi_class = &sfi_classes[current_class_id];
1047
1048 KERNEL_DEBUG_CONSTANT(MACHDBG_CODE(DBG_MACH_SFI, SFI_WAIT_CANCELED), thread_tid(thread), current_class_id, class_id, 0, 0);
1049
1050 kret = waitq_wakeup64_thread(&sfi_class->waitq,
1051 CAST_EVENT64_T(current_class_id),
1052 thread,
1053 THREAD_AWAKENED);
1054 assert(kret == KERN_SUCCESS || kret == KERN_NOT_WAITING);
1055 }
1056 } else {
1057 /*
1058 * Thread's current SFI wait class is not set, and because we
1059 * have the sfi_lock, it won't get set.
1060 */
1061
1062 if ((thread->state & (TH_RUN | TH_IDLE)) == TH_RUN) {
1063 if (sfi_ast != AST_NONE) {
1064 if (thread == current_thread())
1065 ast_on(sfi_ast);
1066 else {
1067 processor_t processor = thread->last_processor;
1068
1069 if (processor != PROCESSOR_NULL &&
1070 processor->state == PROCESSOR_RUNNING &&
1071 processor->active_thread == thread) {
1072 cause_ast_check(processor);
1073 } else {
1074 /*
1075 * Runnable thread that's not on a CPU currently. When a processor
1076 * does context switch to it, the AST will get set based on whether
1077 * the thread is in its "off time".
1078 */
1079 }
1080 }
1081 }
1082 }
1083
1084 thread_unlock(thread);
1085 }
1086
1087 simple_unlock(&sfi_lock);
1088 splx(s);
1089 }
1090
1091 #else /* !CONFIG_SCHED_SFI */
1092
1093 kern_return_t sfi_set_window(uint64_t window_usecs __unused)
1094 {
1095 return (KERN_NOT_SUPPORTED);
1096 }
1097
1098 kern_return_t sfi_window_cancel(void)
1099 {
1100 return (KERN_NOT_SUPPORTED);
1101 }
1102
1103
1104 kern_return_t sfi_get_window(uint64_t *window_usecs __unused)
1105 {
1106 return (KERN_NOT_SUPPORTED);
1107 }
1108
1109
1110 kern_return_t sfi_set_class_offtime(sfi_class_id_t class_id __unused, uint64_t offtime_usecs __unused)
1111 {
1112 return (KERN_NOT_SUPPORTED);
1113 }
1114
1115 kern_return_t sfi_class_offtime_cancel(sfi_class_id_t class_id __unused)
1116 {
1117 return (KERN_NOT_SUPPORTED);
1118 }
1119
1120 kern_return_t sfi_get_class_offtime(sfi_class_id_t class_id __unused, uint64_t *offtime_usecs __unused)
1121 {
1122 return (KERN_NOT_SUPPORTED);
1123 }
1124
1125 void sfi_reevaluate(thread_t thread __unused)
1126 {
1127 return;
1128 }
1129
1130 sfi_class_id_t sfi_thread_classify(thread_t thread)
1131 {
1132 task_t task = thread->task;
1133 boolean_t is_kernel_thread = (task == kernel_task);
1134
1135 if (is_kernel_thread) {
1136 return SFI_CLASS_KERNEL;
1137 }
1138
1139 return SFI_CLASS_OPTED_OUT;
1140 }
1141
1142 #endif /* !CONFIG_SCHED_SFI */
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