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2 //
3 // @APPLE_OSREFERENCE_LICENSE_HEADER_START@
4 //
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6 // as defined in and that are subject to the Apple Public Source License
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16 //
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19 // EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
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26
27 #include <kern/assert.h>
28 #include <kern/kalloc.h>
29 #include <pexpert/pexpert.h>
30 #include <sys/kdebug.h>
31 #include <sys/_types/_size_t.h>
32 #if MONOTONIC
33 #include <kern/monotonic.h>
34 #endif // MONOTONIC
35 #include <kern/percpu.h>
36 #include <kern/processor.h>
37 #include <kern/recount.h>
38 #include <kern/startup.h>
39 #include <kern/task.h>
40 #include <kern/thread.h>
41 #include <kern/work_interval.h>
42 #include <mach/mach_time.h>
43 #include <mach/mach_types.h>
44 #include <machine/config.h>
45 #include <machine/machine_routines.h>
46 #include <os/atomic_private.h>
47 #include <stdbool.h>
48 #include <stdint.h>
49
50 // Recount's machine-independent implementation and interfaces for the kernel
51 // at-large.
52
53 #define PRECISE_USER_KERNEL_PMCS PRECISE_USER_KERNEL_TIME
54
55 // On non-release kernels, allow precise PMC (instructions, cycles) updates to
56 // be disabled for performance characterization.
57 #if PRECISE_USER_KERNEL_PMCS && (DEVELOPMENT || DEBUG)
58 #define PRECISE_USER_KERNEL_PMC_TUNABLE 1
59
60 TUNABLE(bool, no_precise_pmcs, "-no-precise-pmcs", false);
61 #endif // PRECISE_USER_KERNEL_PMCS
62
63 #if !PRECISE_USER_KERNEL_TIME
64 #define PRECISE_TIME_FATAL_FUNC OS_NORETURN
65 #define PRECISE_TIME_ONLY_FUNC OS_UNUSED
66 #else // !PRECISE_USER_KERNEL_TIME
67 #define PRECISE_TIME_FATAL_FUNC
68 #define PRECISE_TIME_ONLY_FUNC
69 #endif // PRECISE_USER_KERNEL_TIME
70
71 #if !PRECISE_USER_KERNEL_PMCS
72 #define PRECISE_PMCS_ONLY_FUNC OS_UNUSED
73 #else // !PRECISE_PMCS_ONLY_FUNC
74 #define PRECISE_PMCS_ONLY_FUNC
75 #endif // PRECISE_USER_KERNEL_PMCS
76
77 #if HAS_CPU_DPE_COUNTER
78 // Only certain platforms have DPE counters.
79 #define RECOUNT_ENERGY CONFIG_PERVASIVE_ENERGY
80 #else // HAS_CPU_DPE_COUNTER
81 #define RECOUNT_ENERGY 0
82 #endif // !HAS_CPU_DPE_COUNTER
83
84 // Topography helpers.
85 size_t recount_topo_count(recount_topo_t topo);
86 static bool recount_topo_matches_cpu_kind(recount_topo_t topo,
87 recount_cpu_kind_t kind, size_t idx);
88 static size_t recount_topo_index(recount_topo_t topo, processor_t processor);
89 static size_t recount_convert_topo_index(recount_topo_t from, recount_topo_t to,
90 size_t i);
91
92 // Prevent counter updates before the system is ready.
93 __security_const_late bool recount_started = false;
94
95 // Lookup table that matches CPU numbers (indices) to their track index.
96 __security_const_late uint8_t _topo_cpu_kinds[MAX_CPUS] = { 0 };
97
98 __startup_func
99 static void
recount_startup(void)100 recount_startup(void)
101 {
102 #if __AMP__
103 unsigned int cpu_count = ml_get_cpu_count();
104 const ml_topology_info_t *topo_info = ml_get_topology_info();
105 for (unsigned int i = 0; i < cpu_count; i++) {
106 cluster_type_t type = topo_info->cpus[i].cluster_type;
107 uint8_t cluster_i = (type == CLUSTER_TYPE_P) ? RCT_CPU_PERFORMANCE :
108 RCT_CPU_EFFICIENCY;
109 _topo_cpu_kinds[i] = cluster_i;
110 }
111 #endif // __AMP__
112
113 recount_started = true;
114 }
115
116 STARTUP(PERCPU, STARTUP_RANK_LAST, recount_startup);
117
118 #pragma mark - tracks
119
120 RECOUNT_PLAN_DEFINE(recount_thread_plan, RCT_TOPO_CPU_KIND);
121 RECOUNT_PLAN_DEFINE(recount_work_interval_plan, RCT_TOPO_CPU);
122 RECOUNT_PLAN_DEFINE(recount_task_plan, RCT_TOPO_CPU);
123 RECOUNT_PLAN_DEFINE(recount_task_terminated_plan, RCT_TOPO_CPU_KIND);
124 RECOUNT_PLAN_DEFINE(recount_coalition_plan, RCT_TOPO_CPU_KIND);
125 RECOUNT_PLAN_DEFINE(recount_processor_plan, RCT_TOPO_SYSTEM);
126
127 OS_ALWAYS_INLINE
128 static inline uint64_t
recount_timestamp_speculative(void)129 recount_timestamp_speculative(void)
130 {
131 #if __arm__ || __arm64__
132 return ml_get_speculative_timebase();
133 #else // __arm__ || __arm64__
134 return mach_absolute_time();
135 #endif // !__arm__ && !__arm64__
136 }
137
138 OS_ALWAYS_INLINE
139 void
recount_snapshot_speculative(struct recount_snap * snap)140 recount_snapshot_speculative(struct recount_snap *snap)
141 {
142 snap->rsn_time_mach = recount_timestamp_speculative();
143 #if CONFIG_PERVASIVE_CPI
144 mt_cur_cpu_cycles_instrs_speculative(&snap->rsn_cycles, &snap->rsn_insns);
145 #endif // CONFIG_PERVASIVE_CPI
146 }
147
148 void
recount_snapshot(struct recount_snap * snap)149 recount_snapshot(struct recount_snap *snap)
150 {
151 #if __arm__ || __arm64__
152 __builtin_arm_isb(ISB_SY);
153 #endif // __arm__ || __arm64__
154 recount_snapshot_speculative(snap);
155 }
156
157 static struct recount_snap *
recount_get_snap(processor_t processor)158 recount_get_snap(processor_t processor)
159 {
160 return &processor->pr_recount.rpr_snap;
161 }
162
163 // A simple sequence lock implementation.
164
165 static void
_seqlock_shared_lock_slowpath(const uint32_t * lck,uint32_t gen)166 _seqlock_shared_lock_slowpath(const uint32_t *lck, uint32_t gen)
167 {
168 disable_preemption();
169 do {
170 gen = hw_wait_while_equals32((uint32_t *)(uintptr_t)lck, gen);
171 } while (__improbable((gen & 1) != 0));
172 os_atomic_thread_fence(acquire);
173 enable_preemption();
174 }
175
176 static uintptr_t
_seqlock_shared_lock(const uint32_t * lck)177 _seqlock_shared_lock(const uint32_t *lck)
178 {
179 uint32_t gen = os_atomic_load(lck, acquire);
180 if (__improbable((gen & 1) != 0)) {
181 _seqlock_shared_lock_slowpath(lck, gen);
182 }
183 return gen;
184 }
185
186 static bool
_seqlock_shared_try_unlock(const uint32_t * lck,uintptr_t on_enter)187 _seqlock_shared_try_unlock(const uint32_t *lck, uintptr_t on_enter)
188 {
189 return os_atomic_load(lck, acquire) == on_enter;
190 }
191
192 static void
_seqlock_excl_lock_relaxed(uint32_t * lck)193 _seqlock_excl_lock_relaxed(uint32_t *lck)
194 {
195 __assert_only uintptr_t new = os_atomic_inc(lck, relaxed);
196 assert3u((new & 1), ==, 1);
197 }
198
199 static void
_seqlock_excl_commit(void)200 _seqlock_excl_commit(void)
201 {
202 os_atomic_thread_fence(release);
203 }
204
205 static void
_seqlock_excl_unlock_relaxed(uint32_t * lck)206 _seqlock_excl_unlock_relaxed(uint32_t *lck)
207 {
208 __assert_only uint32_t new = os_atomic_inc(lck, relaxed);
209 assert3u((new & 1), ==, 0);
210 }
211
212 static struct recount_track *
recount_update_start(struct recount_track * tracks,recount_topo_t topo,processor_t processor)213 recount_update_start(struct recount_track *tracks, recount_topo_t topo,
214 processor_t processor)
215 {
216 struct recount_track *track = &tracks[recount_topo_index(topo, processor)];
217 _seqlock_excl_lock_relaxed(&track->rt_sync);
218 return track;
219 }
220
221 #if RECOUNT_ENERGY
222
223 static struct recount_track *
recount_update_single_start(struct recount_track * tracks,recount_topo_t topo,processor_t processor)224 recount_update_single_start(struct recount_track *tracks, recount_topo_t topo,
225 processor_t processor)
226 {
227 return &tracks[recount_topo_index(topo, processor)];
228 }
229
230 #endif // RECOUNT_ENERGY
231
232 static void
recount_update_commit(void)233 recount_update_commit(void)
234 {
235 _seqlock_excl_commit();
236 }
237
238 static void
recount_update_end(struct recount_track * track)239 recount_update_end(struct recount_track *track)
240 {
241 _seqlock_excl_unlock_relaxed(&track->rt_sync);
242 }
243
244 static const struct recount_usage *
recount_read_start(const struct recount_track * track,uintptr_t * on_enter)245 recount_read_start(const struct recount_track *track, uintptr_t *on_enter)
246 {
247 const struct recount_usage *stats = &track->rt_usage;
248 *on_enter = _seqlock_shared_lock(&track->rt_sync);
249 return stats;
250 }
251
252 static bool
recount_try_read_end(const struct recount_track * track,uintptr_t on_enter)253 recount_try_read_end(const struct recount_track *track, uintptr_t on_enter)
254 {
255 return _seqlock_shared_try_unlock(&track->rt_sync, on_enter);
256 }
257
258 static void
recount_read_track(struct recount_usage * stats,const struct recount_track * track)259 recount_read_track(struct recount_usage *stats,
260 const struct recount_track *track)
261 {
262 uintptr_t on_enter = 0;
263 do {
264 const struct recount_usage *vol_stats =
265 recount_read_start(track, &on_enter);
266 *stats = *vol_stats;
267 } while (!recount_try_read_end(track, on_enter));
268 }
269
270 static void
recount_usage_add(struct recount_usage * sum,const struct recount_usage * to_add)271 recount_usage_add(struct recount_usage *sum, const struct recount_usage *to_add)
272 {
273 sum->ru_user_time_mach += to_add->ru_user_time_mach;
274 sum->ru_system_time_mach += to_add->ru_system_time_mach;
275 #if CONFIG_PERVASIVE_CPI
276 sum->ru_cycles += to_add->ru_cycles;
277 sum->ru_instructions += to_add->ru_instructions;
278 #endif // CONFIG_PERVASIVE_CPI
279 #if CONFIG_PERVASIVE_ENERGY
280 sum->ru_energy_nj += to_add->ru_energy_nj;
281 #endif // CONFIG_PERVASIVE_CPI
282 }
283
284 OS_ALWAYS_INLINE
285 static inline void
recount_usage_add_snap(struct recount_usage * usage,uint64_t * add_time,struct recount_snap * snap)286 recount_usage_add_snap(struct recount_usage *usage, uint64_t *add_time,
287 struct recount_snap *snap)
288 {
289 *add_time += snap->rsn_time_mach;
290 #if CONFIG_PERVASIVE_CPI
291 usage->ru_cycles += snap->rsn_cycles;
292 usage->ru_instructions += snap->rsn_insns;
293 #else // CONFIG_PERVASIVE_CPI
294 #pragma unused(usage)
295 #endif // !CONFIG_PERVASIVE_CPI
296 }
297
298 static void
recount_rollup(recount_plan_t plan,const struct recount_track * tracks,recount_topo_t to_topo,struct recount_usage * stats)299 recount_rollup(recount_plan_t plan, const struct recount_track *tracks,
300 recount_topo_t to_topo, struct recount_usage *stats)
301 {
302 recount_topo_t from_topo = plan->rpl_topo;
303 size_t topo_count = recount_topo_count(from_topo);
304 struct recount_usage tmp = { 0 };
305 for (size_t i = 0; i < topo_count; i++) {
306 recount_read_track(&tmp, &tracks[i]);
307 size_t to_i = recount_convert_topo_index(from_topo, to_topo, i);
308 recount_usage_add(&stats[to_i], &tmp);
309 }
310 }
311
312 // This function must be run when counters cannot increment for the track, like from the current thread.
313 static void
recount_rollup_unsafe(recount_plan_t plan,struct recount_track * tracks,recount_topo_t to_topo,struct recount_usage * stats)314 recount_rollup_unsafe(recount_plan_t plan, struct recount_track *tracks,
315 recount_topo_t to_topo, struct recount_usage *stats)
316 {
317 recount_topo_t from_topo = plan->rpl_topo;
318 size_t topo_count = recount_topo_count(from_topo);
319 for (size_t i = 0; i < topo_count; i++) {
320 size_t to_i = recount_convert_topo_index(from_topo, to_topo, i);
321 recount_usage_add(&stats[to_i], &tracks[i].rt_usage);
322 }
323 }
324
325 void
recount_sum(recount_plan_t plan,const struct recount_track * tracks,struct recount_usage * sum)326 recount_sum(recount_plan_t plan, const struct recount_track *tracks,
327 struct recount_usage *sum)
328 {
329 recount_rollup(plan, tracks, RCT_TOPO_SYSTEM, sum);
330 }
331
332 void
recount_sum_unsafe(recount_plan_t plan,const struct recount_track * tracks,struct recount_usage * sum)333 recount_sum_unsafe(recount_plan_t plan, const struct recount_track *tracks,
334 struct recount_usage *sum)
335 {
336 recount_topo_t topo = plan->rpl_topo;
337 size_t topo_count = recount_topo_count(topo);
338 for (size_t i = 0; i < topo_count; i++) {
339 recount_usage_add(sum, &tracks[i].rt_usage);
340 }
341 }
342
343 void
recount_sum_and_isolate_cpu_kind(recount_plan_t plan,struct recount_track * tracks,recount_cpu_kind_t kind,struct recount_usage * sum,struct recount_usage * only_kind)344 recount_sum_and_isolate_cpu_kind(recount_plan_t plan,
345 struct recount_track *tracks, recount_cpu_kind_t kind,
346 struct recount_usage *sum, struct recount_usage *only_kind)
347 {
348 size_t topo_count = recount_topo_count(plan->rpl_topo);
349 struct recount_usage tmp = { 0 };
350 for (size_t i = 0; i < topo_count; i++) {
351 recount_read_track(&tmp, &tracks[i]);
352 recount_usage_add(sum, &tmp);
353 if (recount_topo_matches_cpu_kind(plan->rpl_topo, kind, i)) {
354 recount_usage_add(only_kind, &tmp);
355 }
356 }
357 }
358
359 static void
recount_sum_usage(recount_plan_t plan,const struct recount_usage * usages,struct recount_usage * sum)360 recount_sum_usage(recount_plan_t plan, const struct recount_usage *usages,
361 struct recount_usage *sum)
362 {
363 const size_t topo_count = recount_topo_count(plan->rpl_topo);
364 for (size_t i = 0; i < topo_count; i++) {
365 recount_usage_add(sum, &usages[i]);
366 }
367 }
368
369 void
recount_sum_usage_and_isolate_cpu_kind(recount_plan_t plan,struct recount_usage * usage,recount_cpu_kind_t kind,struct recount_usage * sum,struct recount_usage * only_kind)370 recount_sum_usage_and_isolate_cpu_kind(recount_plan_t plan,
371 struct recount_usage *usage, recount_cpu_kind_t kind,
372 struct recount_usage *sum, struct recount_usage *only_kind)
373 {
374 const size_t topo_count = recount_topo_count(plan->rpl_topo);
375 for (size_t i = 0; i < topo_count; i++) {
376 recount_usage_add(sum, &usage[i]);
377 if (only_kind && recount_topo_matches_cpu_kind(plan->rpl_topo, kind, i)) {
378 recount_usage_add(only_kind, &usage[i]);
379 }
380 }
381 }
382
383 void
recount_sum_perf_levels(recount_plan_t plan,struct recount_track * tracks,struct recount_usage * sums)384 recount_sum_perf_levels(recount_plan_t plan, struct recount_track *tracks,
385 struct recount_usage *sums)
386 {
387 recount_rollup(plan, tracks, RCT_TOPO_CPU_KIND, sums);
388 }
389
390 // Plan-specific helpers.
391
392 void
recount_coalition_rollup_task(struct recount_coalition * co,struct recount_task * tk)393 recount_coalition_rollup_task(struct recount_coalition *co,
394 struct recount_task *tk)
395 {
396 recount_rollup(&recount_task_plan, tk->rtk_lifetime,
397 recount_coalition_plan.rpl_topo, co->rco_exited);
398 }
399
400 void
recount_task_rollup_thread(struct recount_task * tk,const struct recount_thread * th)401 recount_task_rollup_thread(struct recount_task *tk,
402 const struct recount_thread *th)
403 {
404 recount_rollup(&recount_thread_plan, th->rth_lifetime,
405 recount_task_terminated_plan.rpl_topo, tk->rtk_terminated);
406 }
407
408 #pragma mark - scheduler
409
410 // `result = lhs - rhs` for snapshots.
411 OS_ALWAYS_INLINE
412 static void
recount_snap_diff(struct recount_snap * result,const struct recount_snap * lhs,const struct recount_snap * rhs)413 recount_snap_diff(struct recount_snap *result,
414 const struct recount_snap *lhs, const struct recount_snap *rhs)
415 {
416 assert3u(lhs->rsn_time_mach, >=, rhs->rsn_time_mach);
417 result->rsn_time_mach = lhs->rsn_time_mach - rhs->rsn_time_mach;
418 #if CONFIG_PERVASIVE_CPI
419 assert3u(lhs->rsn_insns, >=, rhs->rsn_insns);
420 assert3u(lhs->rsn_cycles, >=, rhs->rsn_cycles);
421 result->rsn_cycles = lhs->rsn_cycles - rhs->rsn_cycles;
422 result->rsn_insns = lhs->rsn_insns - rhs->rsn_insns;
423 #endif // CONFIG_PERVASIVE_CPI
424 }
425
426 void
recount_update_snap(struct recount_snap * cur)427 recount_update_snap(struct recount_snap *cur)
428 {
429 struct recount_snap *this_snap = recount_get_snap(current_processor());
430 this_snap->rsn_time_mach = cur->rsn_time_mach;
431 #if CONFIG_PERVASIVE_CPI
432 this_snap->rsn_cycles = cur->rsn_cycles;
433 this_snap->rsn_insns = cur->rsn_insns;
434 #endif // CONFIG_PERVASIVE_CPI
435 }
436
437 static void
_fix_time_precision(struct recount_usage * usage)438 _fix_time_precision(struct recount_usage *usage)
439 {
440 #if PRECISE_USER_KERNEL_TIME
441 #pragma unused(usage)
442 #else // PRECISE_USER_KERNEL_TIME
443 // Attribute all time to user, as the system is only acting "on behalf
444 // of" user processes -- a bit sketchy.
445 usage->ru_user_time_mach += usage->ru_system_time_mach;
446 usage->ru_system_time_mach = 0;
447 #endif // !PRECISE_USER_KERNEL_TIME
448 }
449
450 void
recount_current_thread_usage(struct recount_usage * usage)451 recount_current_thread_usage(struct recount_usage *usage)
452 {
453 assert(ml_get_interrupts_enabled() == FALSE);
454 thread_t thread = current_thread();
455 struct recount_snap snap = { 0 };
456 recount_snapshot(&snap);
457 recount_sum_unsafe(&recount_thread_plan, thread->th_recount.rth_lifetime,
458 usage);
459 struct recount_snap *last = recount_get_snap(current_processor());
460 struct recount_snap diff = { 0 };
461 recount_snap_diff(&diff, &snap, last);
462 recount_usage_add_snap(usage, &usage->ru_system_time_mach, &diff);
463 _fix_time_precision(usage);
464 }
465
466 void
recount_current_thread_usage_perf_only(struct recount_usage * usage,struct recount_usage * usage_perf_only)467 recount_current_thread_usage_perf_only(struct recount_usage *usage,
468 struct recount_usage *usage_perf_only)
469 {
470 struct recount_usage usage_perf_levels[RCT_CPU_KIND_COUNT] = { 0 };
471 recount_current_thread_perf_level_usage(usage_perf_levels);
472 recount_sum_usage(&recount_thread_plan, usage_perf_levels, usage);
473 *usage_perf_only = usage_perf_levels[RCT_CPU_PERFORMANCE];
474 _fix_time_precision(usage);
475 _fix_time_precision(usage_perf_only);
476 }
477
478 void
recount_thread_perf_level_usage(struct thread * thread,struct recount_usage * usage_levels)479 recount_thread_perf_level_usage(struct thread *thread,
480 struct recount_usage *usage_levels)
481 {
482 recount_rollup(&recount_thread_plan, thread->th_recount.rth_lifetime,
483 RCT_TOPO_CPU_KIND, usage_levels);
484 size_t topo_count = recount_topo_count(RCT_TOPO_CPU_KIND);
485 for (size_t i = 0; i < topo_count; i++) {
486 _fix_time_precision(&usage_levels[i]);
487 }
488 }
489
490 void
recount_current_thread_perf_level_usage(struct recount_usage * usage_levels)491 recount_current_thread_perf_level_usage(struct recount_usage *usage_levels)
492 {
493 assert(ml_get_interrupts_enabled() == FALSE);
494 processor_t processor = current_processor();
495 thread_t thread = current_thread();
496 struct recount_snap snap = { 0 };
497 recount_snapshot(&snap);
498 recount_rollup_unsafe(&recount_thread_plan, thread->th_recount.rth_lifetime,
499 RCT_TOPO_CPU_KIND, usage_levels);
500 struct recount_snap *last = recount_get_snap(processor);
501 struct recount_snap diff = { 0 };
502 recount_snap_diff(&diff, &snap, last);
503 size_t cur_i = recount_topo_index(RCT_TOPO_CPU_KIND, processor);
504 struct recount_usage *cur_usage = &usage_levels[cur_i];
505 recount_usage_add_snap(cur_usage, &cur_usage->ru_system_time_mach, &diff);
506 size_t topo_count = recount_topo_count(RCT_TOPO_CPU_KIND);
507 for (size_t i = 0; i < topo_count; i++) {
508 _fix_time_precision(&usage_levels[i]);
509 }
510 }
511
512 uint64_t
recount_current_thread_energy_nj(void)513 recount_current_thread_energy_nj(void)
514 {
515 #if RECOUNT_ENERGY
516 assert(ml_get_interrupts_enabled() == FALSE);
517 thread_t thread = current_thread();
518 size_t topo_count = recount_topo_count(recount_thread_plan.rpl_topo);
519 uint64_t energy_nj = 0;
520 for (size_t i = 0; i < topo_count; i++) {
521 energy_nj += thread->th_recount.rth_lifetime[i].rt_usage.ru_energy_nj;
522 }
523 return energy_nj;
524 #else // RECOUNT_ENERGY
525 return 0;
526 #endif // !RECOUNT_ENERGY
527 }
528
529 static void
_times_add_usage(struct recount_times_mach * times,struct recount_usage * usage)530 _times_add_usage(struct recount_times_mach *times, struct recount_usage *usage)
531 {
532 times->rtm_user += usage->ru_user_time_mach;
533 #if PRECISE_USER_KERNEL_TIME
534 times->rtm_system += usage->ru_system_time_mach;
535 #else // PRECISE_USER_KERNEL_TIME
536 times->rtm_user += usage->ru_system_time_mach;
537 #endif // !PRECISE_USER_KERNEL_TIME
538 }
539
540 struct recount_times_mach
recount_thread_times(struct thread * thread)541 recount_thread_times(struct thread *thread)
542 {
543 size_t topo_count = recount_topo_count(recount_thread_plan.rpl_topo);
544 struct recount_times_mach times = { 0 };
545 for (size_t i = 0; i < topo_count; i++) {
546 _times_add_usage(×, &thread->th_recount.rth_lifetime[i].rt_usage);
547 }
548 return times;
549 }
550
551 uint64_t
recount_thread_time_mach(struct thread * thread)552 recount_thread_time_mach(struct thread *thread)
553 {
554 struct recount_times_mach times = recount_thread_times(thread);
555 return times.rtm_user + times.rtm_system;
556 }
557
558 static uint64_t
_time_since_last_snapshot(void)559 _time_since_last_snapshot(void)
560 {
561 struct recount_snap *last = recount_get_snap(current_processor());
562 uint64_t cur_time = mach_absolute_time();
563 return cur_time - last->rsn_time_mach;
564 }
565
566 uint64_t
recount_current_thread_time_mach(void)567 recount_current_thread_time_mach(void)
568 {
569 assert(ml_get_interrupts_enabled() == FALSE);
570 uint64_t previous_time = recount_thread_time_mach(current_thread());
571 return previous_time + _time_since_last_snapshot();
572 }
573
574 struct recount_times_mach
recount_current_thread_times(void)575 recount_current_thread_times(void)
576 {
577 assert(ml_get_interrupts_enabled() == FALSE);
578 struct recount_times_mach times = recount_thread_times(
579 current_thread());
580 #if PRECISE_USER_KERNEL_TIME
581 // This code is executing in the kernel, so the time since the last snapshot
582 // (with precise user/kernel time) is since entering the kernel.
583 times.rtm_system += _time_since_last_snapshot();
584 #else // PRECISE_USER_KERNEL_TIME
585 times.rtm_user += _time_since_last_snapshot();
586 #endif // !PRECISE_USER_KERNEL_TIME
587 return times;
588 }
589
590 void
recount_thread_usage(thread_t thread,struct recount_usage * usage)591 recount_thread_usage(thread_t thread, struct recount_usage *usage)
592 {
593 recount_sum(&recount_thread_plan, thread->th_recount.rth_lifetime, usage);
594 _fix_time_precision(usage);
595 }
596
597 void
recount_work_interval_usage(struct work_interval * work_interval,struct recount_usage * usage)598 recount_work_interval_usage(struct work_interval *work_interval, struct recount_usage *usage)
599 {
600 recount_sum(&recount_work_interval_plan, work_interval_get_recount_tracks(work_interval), usage);
601 _fix_time_precision(usage);
602 }
603
604 struct recount_times_mach
recount_work_interval_times(struct work_interval * work_interval)605 recount_work_interval_times(struct work_interval *work_interval)
606 {
607 size_t topo_count = recount_topo_count(recount_work_interval_plan.rpl_topo);
608 struct recount_times_mach times = { 0 };
609 for (size_t i = 0; i < topo_count; i++) {
610 _times_add_usage(×, &work_interval_get_recount_tracks(work_interval)[i].rt_usage);
611 }
612 return times;
613 }
614
615 uint64_t
recount_work_interval_energy_nj(struct work_interval * work_interval)616 recount_work_interval_energy_nj(struct work_interval *work_interval)
617 {
618 #if RECOUNT_ENERGY
619 size_t topo_count = recount_topo_count(recount_work_interval_plan.rpl_topo);
620 uint64_t energy = 0;
621 for (size_t i = 0; i < topo_count; i++) {
622 energy += work_interval_get_recount_tracks(work_interval)[i].rt_usage.ru_energy_nj;
623 }
624 return energy;
625 #else // RECOUNT_ENERGY
626 #pragma unused(work_interval)
627 return 0;
628 #endif // !RECOUNT_ENERGY
629 }
630
631 void
recount_current_task_usage(struct recount_usage * usage)632 recount_current_task_usage(struct recount_usage *usage)
633 {
634 task_t task = current_task();
635 struct recount_track *tracks = task->tk_recount.rtk_lifetime;
636 recount_sum(&recount_task_plan, tracks, usage);
637 _fix_time_precision(usage);
638 }
639
640 void
recount_current_task_usage_perf_only(struct recount_usage * usage,struct recount_usage * usage_perf_only)641 recount_current_task_usage_perf_only(struct recount_usage *usage,
642 struct recount_usage *usage_perf_only)
643 {
644 task_t task = current_task();
645 struct recount_track *tracks = task->tk_recount.rtk_lifetime;
646 recount_sum_and_isolate_cpu_kind(&recount_task_plan,
647 tracks, RCT_CPU_PERFORMANCE, usage, usage_perf_only);
648 _fix_time_precision(usage);
649 _fix_time_precision(usage_perf_only);
650 }
651
652 void
recount_task_times_perf_only(struct task * task,struct recount_times_mach * sum,struct recount_times_mach * sum_perf_only)653 recount_task_times_perf_only(struct task *task,
654 struct recount_times_mach *sum, struct recount_times_mach *sum_perf_only)
655 {
656 const recount_topo_t topo = recount_task_plan.rpl_topo;
657 const size_t topo_count = recount_topo_count(topo);
658 struct recount_track *tracks = task->tk_recount.rtk_lifetime;
659 for (size_t i = 0; i < topo_count; i++) {
660 struct recount_usage *usage = &tracks[i].rt_usage;
661 _times_add_usage(sum, usage);
662 if (recount_topo_matches_cpu_kind(topo, RCT_CPU_PERFORMANCE, i)) {
663 _times_add_usage(sum_perf_only, usage);
664 }
665 }
666 }
667
668 void
recount_task_terminated_usage(task_t task,struct recount_usage * usage)669 recount_task_terminated_usage(task_t task, struct recount_usage *usage)
670 {
671 recount_sum_usage(&recount_task_terminated_plan,
672 task->tk_recount.rtk_terminated, usage);
673 _fix_time_precision(usage);
674 }
675
676 struct recount_times_mach
recount_task_terminated_times(struct task * task)677 recount_task_terminated_times(struct task *task)
678 {
679 size_t topo_count = recount_topo_count(recount_task_terminated_plan.rpl_topo);
680 struct recount_times_mach times = { 0 };
681 for (size_t i = 0; i < topo_count; i++) {
682 _times_add_usage(×, &task->tk_recount.rtk_terminated[i]);
683 }
684 return times;
685 }
686
687 void
recount_task_terminated_usage_perf_only(task_t task,struct recount_usage * usage,struct recount_usage * perf_only)688 recount_task_terminated_usage_perf_only(task_t task,
689 struct recount_usage *usage, struct recount_usage *perf_only)
690 {
691 recount_sum_usage_and_isolate_cpu_kind(&recount_task_terminated_plan,
692 task->tk_recount.rtk_terminated, RCT_CPU_PERFORMANCE, usage, perf_only);
693 _fix_time_precision(usage);
694 _fix_time_precision(perf_only);
695 }
696
697 void
recount_task_usage_perf_only(task_t task,struct recount_usage * sum,struct recount_usage * sum_perf_only)698 recount_task_usage_perf_only(task_t task, struct recount_usage *sum,
699 struct recount_usage *sum_perf_only)
700 {
701 recount_sum_and_isolate_cpu_kind(&recount_task_plan,
702 task->tk_recount.rtk_lifetime, RCT_CPU_PERFORMANCE, sum, sum_perf_only);
703 _fix_time_precision(sum);
704 _fix_time_precision(sum_perf_only);
705 }
706
707 void
recount_task_usage(task_t task,struct recount_usage * usage)708 recount_task_usage(task_t task, struct recount_usage *usage)
709 {
710 recount_sum(&recount_task_plan, task->tk_recount.rtk_lifetime, usage);
711 _fix_time_precision(usage);
712 }
713
714 struct recount_times_mach
recount_task_times(struct task * task)715 recount_task_times(struct task *task)
716 {
717 size_t topo_count = recount_topo_count(recount_task_plan.rpl_topo);
718 struct recount_times_mach times = { 0 };
719 for (size_t i = 0; i < topo_count; i++) {
720 _times_add_usage(×, &task->tk_recount.rtk_lifetime[i].rt_usage);
721 }
722 return times;
723 }
724
725 uint64_t
recount_task_energy_nj(struct task * task)726 recount_task_energy_nj(struct task *task)
727 {
728 #if RECOUNT_ENERGY
729 size_t topo_count = recount_topo_count(recount_task_plan.rpl_topo);
730 uint64_t energy = 0;
731 for (size_t i = 0; i < topo_count; i++) {
732 energy += task->tk_recount.rtk_lifetime[i].rt_usage.ru_energy_nj;
733 }
734 return energy;
735 #else // RECOUNT_ENERGY
736 #pragma unused(task)
737 return 0;
738 #endif // !RECOUNT_ENERGY
739 }
740
741 void
recount_coalition_usage_perf_only(struct recount_coalition * coal,struct recount_usage * sum,struct recount_usage * sum_perf_only)742 recount_coalition_usage_perf_only(struct recount_coalition *coal,
743 struct recount_usage *sum, struct recount_usage *sum_perf_only)
744 {
745 recount_sum_usage_and_isolate_cpu_kind(&recount_coalition_plan,
746 coal->rco_exited, RCT_CPU_PERFORMANCE, sum, sum_perf_only);
747 _fix_time_precision(sum);
748 _fix_time_precision(sum_perf_only);
749 }
750
751 OS_ALWAYS_INLINE
752 static void
recount_absorb_snap(struct recount_snap * to_add,thread_t thread,task_t task,processor_t processor,bool from_user)753 recount_absorb_snap(struct recount_snap *to_add, thread_t thread, task_t task,
754 processor_t processor, bool from_user)
755 {
756 // Idle threads do not attribute their usage back to the task or processor,
757 // as the time is not spent "running."
758 //
759 // The processor-level metrics include idle time, instead, as the idle time
760 // needs to be read as up-to-date from `recount_processor_usage`.
761
762 bool was_idle = (thread->options & TH_OPT_IDLE_THREAD) != 0;
763 struct recount_track *wi_tracks_array = work_interval_get_recount_tracks(thread->th_work_interval);
764 bool collect_work_interval_telemetry = wi_tracks_array != NULL;
765
766 struct recount_track *th_track = recount_update_start(
767 thread->th_recount.rth_lifetime, recount_thread_plan.rpl_topo,
768 processor);
769 struct recount_track *wi_track =
770 (was_idle || !collect_work_interval_telemetry) ? NULL : recount_update_start(
771 wi_tracks_array,
772 recount_work_interval_plan.rpl_topo,
773 processor);
774 struct recount_track *tk_track = was_idle ? NULL : recount_update_start(
775 task->tk_recount.rtk_lifetime, recount_task_plan.rpl_topo,
776 processor);
777 struct recount_track *pr_track = was_idle ? NULL : recount_update_start(
778 &processor->pr_recount.rpr_active, recount_processor_plan.rpl_topo,
779 processor);
780 recount_update_commit();
781
782 uint64_t *th_time = NULL, *wi_time = NULL, *tk_time = NULL, *pr_time = NULL;
783 if (from_user) {
784 th_time = &th_track->rt_usage.ru_user_time_mach;
785 wi_time = &wi_track->rt_usage.ru_user_time_mach;
786 tk_time = &tk_track->rt_usage.ru_user_time_mach;
787 pr_time = &pr_track->rt_usage.ru_user_time_mach;
788 } else {
789 th_time = &th_track->rt_usage.ru_system_time_mach;
790 wi_time = &wi_track->rt_usage.ru_system_time_mach;
791 tk_time = &tk_track->rt_usage.ru_system_time_mach;
792 pr_time = &pr_track->rt_usage.ru_system_time_mach;
793 }
794
795 recount_usage_add_snap(&th_track->rt_usage, th_time, to_add);
796 if (!was_idle) {
797 if (collect_work_interval_telemetry) {
798 recount_usage_add_snap(&wi_track->rt_usage, wi_time, to_add);
799 }
800 recount_usage_add_snap(&tk_track->rt_usage, tk_time, to_add);
801 recount_usage_add_snap(&pr_track->rt_usage, pr_time, to_add);
802 }
803
804 recount_update_commit();
805 recount_update_end(th_track);
806 if (!was_idle) {
807 if (collect_work_interval_telemetry) {
808 recount_update_end(wi_track);
809 }
810 recount_update_end(tk_track);
811 recount_update_end(pr_track);
812 }
813 }
814
815 void
recount_switch_thread(struct recount_snap * cur,struct thread * off_thread,struct task * off_task)816 recount_switch_thread(struct recount_snap *cur, struct thread *off_thread,
817 struct task *off_task)
818 {
819 assert(ml_get_interrupts_enabled() == FALSE);
820
821 if (__improbable(!recount_started)) {
822 return;
823 }
824
825 processor_t processor = current_processor();
826
827 struct recount_snap *last = recount_get_snap(processor);
828 struct recount_snap diff = { 0 };
829 recount_snap_diff(&diff, cur, last);
830 recount_absorb_snap(&diff, off_thread, off_task, processor, false);
831 recount_update_snap(cur);
832 }
833
834 void
recount_add_energy(struct thread * off_thread,struct task * off_task,uint64_t energy_nj)835 recount_add_energy(struct thread *off_thread, struct task *off_task,
836 uint64_t energy_nj)
837 {
838 #if RECOUNT_ENERGY
839 assert(ml_get_interrupts_enabled() == FALSE);
840 if (__improbable(!recount_started)) {
841 return;
842 }
843
844 bool was_idle = (off_thread->options & TH_OPT_IDLE_THREAD) != 0;
845 struct recount_track *wi_tracks_array = work_interval_get_recount_tracks(off_thread->th_work_interval);
846 bool collect_work_interval_telemetry = wi_tracks_array != NULL;
847 processor_t processor = current_processor();
848
849 struct recount_track *th_track = recount_update_single_start(
850 off_thread->th_recount.rth_lifetime, recount_thread_plan.rpl_topo,
851 processor);
852 struct recount_track *wi_track = (was_idle || !collect_work_interval_telemetry) ? NULL :
853 recount_update_single_start(wi_tracks_array,
854 recount_work_interval_plan.rpl_topo, processor);
855 struct recount_track *tk_track = was_idle ? NULL :
856 recount_update_single_start(off_task->tk_recount.rtk_lifetime,
857 recount_task_plan.rpl_topo, processor);
858 struct recount_track *pr_track = was_idle ? NULL :
859 recount_update_single_start(&processor->pr_recount.rpr_active,
860 recount_processor_plan.rpl_topo, processor);
861
862 th_track->rt_usage.ru_energy_nj += energy_nj;
863 if (!was_idle) {
864 if (collect_work_interval_telemetry) {
865 wi_track->rt_usage.ru_energy_nj += energy_nj;
866 }
867 tk_track->rt_usage.ru_energy_nj += energy_nj;
868 pr_track->rt_usage.ru_energy_nj += energy_nj;
869 }
870 #else // RECOUNT_ENERGY
871 #pragma unused(off_thread, off_task, energy_nj)
872 #endif // !RECOUNT_ENERGY
873 }
874
875 #define MT_KDBG_IC_CPU_CSWITCH \
876 KDBG_EVENTID(DBG_MONOTONIC, DBG_MT_INSTRS_CYCLES, 1)
877
878 #define MT_KDBG_IC_CPU_CSWITCH_ON \
879 KDBG_EVENTID(DBG_MONOTONIC, DBG_MT_INSTRS_CYCLES_ON_CPU, 1)
880
881 void
recount_log_switch_thread(const struct recount_snap * snap)882 recount_log_switch_thread(const struct recount_snap *snap)
883 {
884 #if CONFIG_PERVASIVE_CPI
885 if (kdebug_debugid_explicitly_enabled(MT_KDBG_IC_CPU_CSWITCH)) {
886 // In Monotonic's event hierarchy for backwards-compatibility.
887 KDBG_RELEASE(MT_KDBG_IC_CPU_CSWITCH, snap->rsn_insns, snap->rsn_cycles);
888 }
889 #else // CONFIG_PERVASIVE_CPI
890 #pragma unused(snap)
891 #endif // CONFIG_PERVASIVE_CPI
892 }
893
894 void
recount_log_switch_thread_on(const struct recount_snap * snap)895 recount_log_switch_thread_on(const struct recount_snap *snap)
896 {
897 #if CONFIG_PERVASIVE_CPI
898 if (kdebug_debugid_explicitly_enabled(MT_KDBG_IC_CPU_CSWITCH_ON)) {
899 if (!snap) {
900 snap = recount_get_snap(current_processor());
901 }
902 // In Monotonic's event hierarchy for backwards-compatibility.
903 KDBG_RELEASE(MT_KDBG_IC_CPU_CSWITCH_ON, snap->rsn_insns, snap->rsn_cycles);
904 }
905 #else // CONFIG_PERVASIVE_CPI
906 #pragma unused(snap)
907 #endif // CONFIG_PERVASIVE_CPI
908 }
909
910 OS_ALWAYS_INLINE
911 PRECISE_TIME_ONLY_FUNC
912 static void
recount_precise_transition_diff(struct recount_snap * diff,struct recount_snap * last,struct recount_snap * cur)913 recount_precise_transition_diff(struct recount_snap *diff,
914 struct recount_snap *last, struct recount_snap *cur)
915 {
916 #if PRECISE_USER_KERNEL_PMCS
917 #if PRECISE_USER_KERNEL_PMC_TUNABLE
918 // The full `recount_snapshot_speculative` shouldn't get PMCs with a tunable
919 // in this configuration.
920 if (__improbable(no_precise_pmcs)) {
921 cur->rsn_time_mach = recount_timestamp_speculative();
922 diff->rsn_time_mach = cur->rsn_time_mach - last->rsn_time_mach;
923 } else
924 #endif // PRECISE_USER_KERNEL_PMC_TUNABLE
925 {
926 recount_snapshot_speculative(cur);
927 recount_snap_diff(diff, cur, last);
928 }
929 #else // PRECISE_USER_KERNEL_PMCS
930 cur->rsn_time_mach = recount_timestamp_speculative();
931 diff->rsn_time_mach = cur->rsn_time_mach - last->rsn_time_mach;
932 #endif // !PRECISE_USER_KERNEL_PMCS
933 }
934
935 /// Called when entering or exiting the kernel to maintain system vs. user counts, extremely performance sensitive.
936 ///
937 /// Must be called with interrupts disabled.
938 ///
939 /// - Parameter from_user: Whether the kernel is being entered from user space.
940 ///
941 /// - Returns: The value of Mach time that was sampled inside this function.
942 PRECISE_TIME_FATAL_FUNC
943 static uint64_t
recount_kernel_transition(bool from_user)944 recount_kernel_transition(bool from_user)
945 {
946 #if PRECISE_USER_KERNEL_TIME
947 // Omit interrupts-disabled assertion for performance reasons.
948 processor_t processor = current_processor();
949 thread_t thread = processor->active_thread;
950 task_t task = get_thread_ro_unchecked(thread)->tro_task;
951
952 struct recount_snap *last = recount_get_snap(processor);
953 struct recount_snap diff = { 0 };
954 struct recount_snap cur = { 0 };
955 recount_precise_transition_diff(&diff, last, &cur);
956 recount_absorb_snap(&diff, thread, task, processor, from_user);
957 recount_update_snap(&cur);
958
959 return cur.rsn_time_mach;
960 #else // PRECISE_USER_KERNEL_TIME
961 #pragma unused(from_user)
962 panic("recount: kernel transition called with precise time off");
963 #endif // !PRECISE_USER_KERNEL_TIME
964 }
965
966 PRECISE_TIME_FATAL_FUNC
967 void
recount_leave_user(void)968 recount_leave_user(void)
969 {
970 recount_kernel_transition(true);
971 }
972
973 PRECISE_TIME_FATAL_FUNC
974 void
recount_enter_user(void)975 recount_enter_user(void)
976 {
977 recount_kernel_transition(false);
978 }
979
980 #if __x86_64__
981
982 void
recount_enter_intel_interrupt(x86_saved_state_t * state)983 recount_enter_intel_interrupt(x86_saved_state_t *state)
984 {
985 // The low bits of `%cs` being set indicate interrupt was delivered while
986 // executing in user space.
987 bool from_user = (is_saved_state64(state) ? state->ss_64.isf.cs :
988 state->ss_32.cs) & 0x03;
989 uint64_t timestamp = recount_kernel_transition(from_user);
990 current_cpu_datap()->cpu_int_event_time = timestamp;
991 }
992
993 void
recount_leave_intel_interrupt(void)994 recount_leave_intel_interrupt(void)
995 {
996 // XXX This is not actually entering user space, but it does update the
997 // system timer, which is desirable.
998 recount_enter_user();
999 current_cpu_datap()->cpu_int_event_time = 0;
1000 }
1001
1002 #endif // __x86_64__
1003
1004 // Set on rpr_state_last_abs_time when the processor is idle.
1005 #define RCT_PR_IDLING (0x1ULL << 63)
1006
1007 void
recount_processor_idle(struct recount_processor * pr,struct recount_snap * snap)1008 recount_processor_idle(struct recount_processor *pr, struct recount_snap *snap)
1009 {
1010 __assert_only uint64_t state_time = os_atomic_load_wide(
1011 &pr->rpr_state_last_abs_time, relaxed);
1012 assert((state_time & RCT_PR_IDLING) == 0);
1013 assert((snap->rsn_time_mach & RCT_PR_IDLING) == 0);
1014 uint64_t new_state_stamp = RCT_PR_IDLING | snap->rsn_time_mach;
1015 os_atomic_store_wide(&pr->rpr_state_last_abs_time, new_state_stamp,
1016 relaxed);
1017 }
1018
1019 OS_PURE OS_ALWAYS_INLINE
1020 static inline uint64_t
_state_time(uint64_t state_stamp)1021 _state_time(uint64_t state_stamp)
1022 {
1023 return state_stamp & ~(RCT_PR_IDLING);
1024 }
1025
1026 void
recount_processor_init(processor_t processor)1027 recount_processor_init(processor_t processor)
1028 {
1029 #if __AMP__
1030 processor->pr_recount.rpr_cpu_kind_index =
1031 processor->processor_set->pset_cluster_type == PSET_AMP_P ? 1 : 0;
1032 #else // __AMP__
1033 #pragma unused(processor)
1034 #endif // !__AMP__
1035 }
1036
1037 void
recount_processor_run(struct recount_processor * pr,struct recount_snap * snap)1038 recount_processor_run(struct recount_processor *pr, struct recount_snap *snap)
1039 {
1040 uint64_t state = os_atomic_load_wide(&pr->rpr_state_last_abs_time, relaxed);
1041 assert(state == 0 || (state & RCT_PR_IDLING) == RCT_PR_IDLING);
1042 assert((snap->rsn_time_mach & RCT_PR_IDLING) == 0);
1043 uint64_t new_state_stamp = snap->rsn_time_mach;
1044 pr->rpr_idle_time_mach += snap->rsn_time_mach - _state_time(state);
1045 os_atomic_store_wide(&pr->rpr_state_last_abs_time, new_state_stamp,
1046 relaxed);
1047 }
1048
1049 void
recount_processor_usage(struct recount_processor * pr,struct recount_usage * usage,uint64_t * idle_time_out)1050 recount_processor_usage(struct recount_processor *pr,
1051 struct recount_usage *usage, uint64_t *idle_time_out)
1052 {
1053 recount_sum(&recount_processor_plan, &pr->rpr_active, usage);
1054 _fix_time_precision(usage);
1055
1056 uint64_t idle_time = pr->rpr_idle_time_mach;
1057 uint64_t idle_stamp = os_atomic_load_wide(&pr->rpr_state_last_abs_time,
1058 relaxed);
1059 bool idle = (idle_stamp & RCT_PR_IDLING) == RCT_PR_IDLING;
1060 if (idle) {
1061 // Since processors can idle for some time without an update, make sure
1062 // the idle time is up-to-date with respect to the caller.
1063 idle_time += mach_absolute_time() - _state_time(idle_stamp);
1064 }
1065 *idle_time_out = idle_time;
1066 }
1067
1068 bool
recount_task_thread_perf_level_usage(struct task * task,uint64_t tid,struct recount_usage * usage_levels)1069 recount_task_thread_perf_level_usage(struct task *task, uint64_t tid,
1070 struct recount_usage *usage_levels)
1071 {
1072 thread_t thread = task_findtid(task, tid);
1073 if (thread != THREAD_NULL) {
1074 if (thread == current_thread()) {
1075 boolean_t interrupt_state = ml_set_interrupts_enabled(FALSE);
1076 recount_current_thread_perf_level_usage(usage_levels);
1077 ml_set_interrupts_enabled(interrupt_state);
1078 } else {
1079 recount_thread_perf_level_usage(thread, usage_levels);
1080 }
1081 }
1082 return thread != THREAD_NULL;
1083 }
1084
1085 #pragma mark - utilities
1086
1087 // For rolling up counts, convert an index from one topography to another.
1088 static size_t
recount_convert_topo_index(recount_topo_t from,recount_topo_t to,size_t i)1089 recount_convert_topo_index(recount_topo_t from, recount_topo_t to, size_t i)
1090 {
1091 if (from == to) {
1092 return i;
1093 } else if (to == RCT_TOPO_SYSTEM) {
1094 return 0;
1095 } else if (from == RCT_TOPO_CPU) {
1096 assertf(to == RCT_TOPO_CPU_KIND,
1097 "recount: cannot convert from CPU topography to %d", to);
1098 return _topo_cpu_kinds[i];
1099 } else {
1100 panic("recount: unexpected rollup request from %d to %d", from, to);
1101 }
1102 }
1103
1104 // Get the track index of the provided processor and topography.
1105 OS_ALWAYS_INLINE
1106 static size_t
recount_topo_index(recount_topo_t topo,processor_t processor)1107 recount_topo_index(recount_topo_t topo, processor_t processor)
1108 {
1109 switch (topo) {
1110 case RCT_TOPO_SYSTEM:
1111 return 0;
1112 case RCT_TOPO_CPU:
1113 return processor->cpu_id;
1114 case RCT_TOPO_CPU_KIND:
1115 #if __AMP__
1116 return processor->pr_recount.rpr_cpu_kind_index;
1117 #else // __AMP__
1118 return 0;
1119 #endif // !__AMP__
1120 default:
1121 panic("recount: invalid topology %u to index", topo);
1122 }
1123 }
1124
1125 // Return the number of tracks needed for a given topography.
1126 size_t
recount_topo_count(recount_topo_t topo)1127 recount_topo_count(recount_topo_t topo)
1128 {
1129 // Allow the compiler to reason about at least the system and CPU kind
1130 // counts.
1131 switch (topo) {
1132 case RCT_TOPO_SYSTEM:
1133 return 1;
1134
1135 case RCT_TOPO_CPU_KIND:
1136 #if __AMP__
1137 return 2;
1138 #else // __AMP__
1139 return 1;
1140 #endif // !__AMP__
1141
1142 case RCT_TOPO_CPU:
1143 #if __arm__ || __arm64__
1144 return ml_get_cpu_count();
1145 #else // __arm__ || __arm64__
1146 return ml_early_cpu_max_number() + 1;
1147 #endif // !__arm__ && !__arm64__
1148
1149 default:
1150 panic("recount: invalid topography %d", topo);
1151 }
1152 }
1153
1154 static bool
recount_topo_matches_cpu_kind(recount_topo_t topo,recount_cpu_kind_t kind,size_t idx)1155 recount_topo_matches_cpu_kind(recount_topo_t topo, recount_cpu_kind_t kind,
1156 size_t idx)
1157 {
1158 #if !__AMP__
1159 #pragma unused(kind, idx)
1160 #endif // !__AMP__
1161 switch (topo) {
1162 case RCT_TOPO_SYSTEM:
1163 return true;
1164
1165 case RCT_TOPO_CPU_KIND:
1166 #if __AMP__
1167 return kind == idx;
1168 #else // __AMP__
1169 return false;
1170 #endif // !__AMP__
1171
1172 case RCT_TOPO_CPU: {
1173 #if __AMP__
1174 return _topo_cpu_kinds[idx] == kind;
1175 #else // __AMP__
1176 return false;
1177 #endif // !__AMP__
1178 }
1179
1180 default:
1181 panic("recount: unexpected topography %d", topo);
1182 }
1183 }
1184
1185 struct recount_track *
recount_tracks_create(recount_plan_t plan)1186 recount_tracks_create(recount_plan_t plan)
1187 {
1188 return kalloc_type_tag(struct recount_track,
1189 recount_topo_count(plan->rpl_topo), Z_WAITOK | Z_ZERO | Z_NOFAIL,
1190 VM_KERN_MEMORY_RECOUNT);
1191 }
1192
1193 static void
recount_tracks_copy(recount_plan_t plan,struct recount_track * dst,struct recount_track * src)1194 recount_tracks_copy(recount_plan_t plan, struct recount_track *dst,
1195 struct recount_track *src)
1196 {
1197 size_t topo_count = recount_topo_count(plan->rpl_topo);
1198 for (size_t i = 0; i < topo_count; i++) {
1199 recount_read_track(&dst[i].rt_usage, &src[i]);
1200 }
1201 }
1202
1203 void
recount_tracks_destroy(recount_plan_t plan,struct recount_track * tracks)1204 recount_tracks_destroy(recount_plan_t plan, struct recount_track *tracks)
1205 {
1206 kfree_type(struct recount_track, recount_topo_count(plan->rpl_topo),
1207 tracks);
1208 }
1209
1210 void
recount_thread_init(struct recount_thread * th)1211 recount_thread_init(struct recount_thread *th)
1212 {
1213 th->rth_lifetime = recount_tracks_create(&recount_thread_plan);
1214 }
1215
1216 void
recount_thread_copy(struct recount_thread * dst,struct recount_thread * src)1217 recount_thread_copy(struct recount_thread *dst, struct recount_thread *src)
1218 {
1219 recount_tracks_copy(&recount_thread_plan, dst->rth_lifetime,
1220 src->rth_lifetime);
1221 }
1222
1223 void
recount_task_copy(struct recount_task * dst,const struct recount_task * src)1224 recount_task_copy(struct recount_task *dst, const struct recount_task *src)
1225 {
1226 recount_tracks_copy(&recount_task_plan, dst->rtk_lifetime,
1227 src->rtk_lifetime);
1228 }
1229
1230 void
recount_thread_deinit(struct recount_thread * th)1231 recount_thread_deinit(struct recount_thread *th)
1232 {
1233 recount_tracks_destroy(&recount_thread_plan, th->rth_lifetime);
1234 }
1235
1236 void
recount_task_init(struct recount_task * tk)1237 recount_task_init(struct recount_task *tk)
1238 {
1239 tk->rtk_lifetime = recount_tracks_create(&recount_task_plan);
1240 tk->rtk_terminated = recount_usage_alloc(
1241 recount_task_terminated_plan.rpl_topo);
1242 }
1243
1244 void
recount_task_deinit(struct recount_task * tk)1245 recount_task_deinit(struct recount_task *tk)
1246 {
1247 recount_tracks_destroy(&recount_task_plan, tk->rtk_lifetime);
1248 recount_usage_free(recount_task_terminated_plan.rpl_topo,
1249 tk->rtk_terminated);
1250 }
1251
1252 void
recount_coalition_init(struct recount_coalition * co)1253 recount_coalition_init(struct recount_coalition *co)
1254 {
1255 co->rco_exited = recount_usage_alloc(recount_coalition_plan.rpl_topo);
1256 }
1257
1258 void
recount_coalition_deinit(struct recount_coalition * co)1259 recount_coalition_deinit(struct recount_coalition *co)
1260 {
1261 recount_usage_free(recount_coalition_plan.rpl_topo, co->rco_exited);
1262 }
1263
1264 void
recount_work_interval_init(struct recount_work_interval * wi)1265 recount_work_interval_init(struct recount_work_interval *wi)
1266 {
1267 wi->rwi_current_instance = recount_tracks_create(&recount_work_interval_plan);
1268 }
1269
1270 void
recount_work_interval_deinit(struct recount_work_interval * wi)1271 recount_work_interval_deinit(struct recount_work_interval *wi)
1272 {
1273 recount_tracks_destroy(&recount_work_interval_plan, wi->rwi_current_instance);
1274 }
1275
1276 struct recount_usage *
recount_usage_alloc(recount_topo_t topo)1277 recount_usage_alloc(recount_topo_t topo)
1278 {
1279 return kalloc_type_tag(struct recount_usage, recount_topo_count(topo),
1280 Z_WAITOK | Z_ZERO | Z_NOFAIL, VM_KERN_MEMORY_RECOUNT);
1281 }
1282
1283 void
recount_usage_free(recount_topo_t topo,struct recount_usage * usage)1284 recount_usage_free(recount_topo_t topo, struct recount_usage *usage)
1285 {
1286 kfree_type(struct recount_usage, recount_topo_count(topo),
1287 usage);
1288 }
1289