btrfs: Attempt to fix GCC2 build.
[haiku.git] / src / system / kernel / scheduler / scheduler.cpp
blob27022e371c99140b1c6622c1a1d74f33c4490344
1 /*
2 * Copyright 2013-2014, Paweł Dziepak, pdziepak@quarnos.org.
3 * Copyright 2009, Rene Gollent, rene@gollent.com.
4 * Copyright 2008-2011, Ingo Weinhold, ingo_weinhold@gmx.de.
5 * Copyright 2002-2010, Axel Dörfler, axeld@pinc-software.de.
6 * Copyright 2002, Angelo Mottola, a.mottola@libero.it.
7 * Distributed under the terms of the MIT License.
9 * Copyright 2001-2002, Travis Geiselbrecht. All rights reserved.
10 * Distributed under the terms of the NewOS License.
14 /*! The thread scheduler */
17 #include <OS.h>
19 #include <AutoDeleter.h>
20 #include <cpu.h>
21 #include <debug.h>
22 #include <int.h>
23 #include <kernel.h>
24 #include <kscheduler.h>
25 #include <listeners.h>
26 #include <load_tracking.h>
27 #include <scheduler_defs.h>
28 #include <smp.h>
29 #include <timer.h>
30 #include <util/Random.h>
32 #include "scheduler_common.h"
33 #include "scheduler_cpu.h"
34 #include "scheduler_locking.h"
35 #include "scheduler_modes.h"
36 #include "scheduler_profiler.h"
37 #include "scheduler_thread.h"
38 #include "scheduler_tracing.h"
41 namespace Scheduler {
44 class ThreadEnqueuer : public ThreadProcessing {
45 public:
46 void operator()(ThreadData* thread);
49 scheduler_mode gCurrentModeID;
50 scheduler_mode_operations* gCurrentMode;
52 bool gSingleCore;
53 bool gTrackCoreLoad;
54 bool gTrackCPULoad;
56 } // namespace Scheduler
58 using namespace Scheduler;
61 static bool sSchedulerEnabled;
63 SchedulerListenerList gSchedulerListeners;
64 spinlock gSchedulerListenersLock = B_SPINLOCK_INITIALIZER;
66 static scheduler_mode_operations* sSchedulerModes[] = {
67 &gSchedulerLowLatencyMode,
68 &gSchedulerPowerSavingMode,
71 // Since CPU IDs used internally by the kernel bear no relation to the actual
72 // CPU topology the following arrays are used to efficiently get the core
73 // and the package that CPU in question belongs to.
74 static int32* sCPUToCore;
75 static int32* sCPUToPackage;
78 static void enqueue(Thread* thread, bool newOne);
81 void
82 ThreadEnqueuer::operator()(ThreadData* thread)
84 enqueue(thread->GetThread(), false);
88 void
89 scheduler_dump_thread_data(Thread* thread)
91 thread->scheduler_data->Dump();
95 static void
96 enqueue(Thread* thread, bool newOne)
98 SCHEDULER_ENTER_FUNCTION();
100 ThreadData* threadData = thread->scheduler_data;
102 int32 threadPriority = threadData->GetEffectivePriority();
103 T(EnqueueThread(thread, threadPriority));
105 CPUEntry* targetCPU = NULL;
106 CoreEntry* targetCore = NULL;
107 if (thread->pinned_to_cpu > 0) {
108 ASSERT(thread->previous_cpu != NULL);
109 ASSERT(threadData->Core() != NULL);
110 targetCPU = &gCPUEntries[thread->previous_cpu->cpu_num];
111 } else if (gSingleCore)
112 targetCore = &gCoreEntries[0];
113 else if (threadData->Core() != NULL
114 && (!newOne || !threadData->HasCacheExpired())) {
115 targetCore = threadData->Rebalance();
118 bool rescheduleNeeded = threadData->ChooseCoreAndCPU(targetCore, targetCPU);
120 TRACE("enqueueing thread %ld with priority %ld on CPU %ld (core %ld)\n",
121 thread->id, threadPriority, targetCPU->fCPUNumber, targetCore->fCoreID);
123 threadData->Enqueue();
125 // notify listeners
126 NotifySchedulerListeners(&SchedulerListener::ThreadEnqueuedInRunQueue,
127 thread);
129 int32 heapPriority = CPUPriorityHeap::GetKey(targetCPU);
130 if (threadPriority > heapPriority
131 || (threadPriority == heapPriority && rescheduleNeeded)) {
133 if (targetCPU->ID() == smp_get_current_cpu())
134 gCPU[targetCPU->ID()].invoke_scheduler = true;
135 else {
136 smp_send_ici(targetCPU->ID(), SMP_MSG_RESCHEDULE, 0, 0, 0,
137 NULL, SMP_MSG_FLAG_ASYNC);
143 /*! Enqueues the thread into the run queue.
144 Note: thread lock must be held when entering this function
146 void
147 scheduler_enqueue_in_run_queue(Thread *thread)
149 ASSERT(!are_interrupts_enabled());
150 SCHEDULER_ENTER_FUNCTION();
152 SchedulerModeLocker _;
154 TRACE("enqueueing new thread %ld with static priority %ld\n", thread->id,
155 thread->priority);
157 ThreadData* threadData = thread->scheduler_data;
159 if (threadData->ShouldCancelPenalty())
160 threadData->CancelPenalty();
162 enqueue(thread, true);
166 /*! Sets the priority of a thread.
168 int32
169 scheduler_set_thread_priority(Thread *thread, int32 priority)
171 ASSERT(are_interrupts_enabled());
173 InterruptsSpinLocker _(thread->scheduler_lock);
174 SchedulerModeLocker modeLocker;
176 SCHEDULER_ENTER_FUNCTION();
178 ThreadData* threadData = thread->scheduler_data;
179 int32 oldPriority = thread->priority;
181 TRACE("changing thread %ld priority to %ld (old: %ld, effective: %ld)\n",
182 thread->id, priority, oldPriority, threadData->GetEffectivePriority());
184 thread->priority = priority;
185 threadData->CancelPenalty();
187 if (priority == thread->priority)
188 return thread->priority;
190 if (thread->state != B_THREAD_READY) {
191 if (thread->state == B_THREAD_RUNNING) {
192 ASSERT(threadData->Core() != NULL);
194 ASSERT(thread->cpu != NULL);
195 CPUEntry* cpu = &gCPUEntries[thread->cpu->cpu_num];
197 CoreCPUHeapLocker _(threadData->Core());
198 cpu->UpdatePriority(priority);
201 return oldPriority;
204 // The thread is in the run queue. We need to remove it and re-insert it at
205 // a new position.
207 T(RemoveThread(thread));
209 // notify listeners
210 NotifySchedulerListeners(&SchedulerListener::ThreadRemovedFromRunQueue,
211 thread);
213 if (threadData->Dequeue())
214 enqueue(thread, true);
216 return oldPriority;
220 void
221 scheduler_reschedule_ici()
223 // This function is called as a result of an incoming ICI.
224 // Make sure the reschedule() is invoked.
225 get_cpu_struct()->invoke_scheduler = true;
229 static inline void
230 stop_cpu_timers(Thread* fromThread, Thread* toThread)
232 SpinLocker teamLocker(&fromThread->team->time_lock);
233 SpinLocker threadLocker(&fromThread->time_lock);
235 if (fromThread->HasActiveCPUTimeUserTimers()
236 || fromThread->team->HasActiveCPUTimeUserTimers()) {
237 user_timer_stop_cpu_timers(fromThread, toThread);
242 static inline void
243 continue_cpu_timers(Thread* thread, cpu_ent* cpu)
245 SpinLocker teamLocker(&thread->team->time_lock);
246 SpinLocker threadLocker(&thread->time_lock);
248 if (thread->HasActiveCPUTimeUserTimers()
249 || thread->team->HasActiveCPUTimeUserTimers()) {
250 user_timer_continue_cpu_timers(thread, cpu->previous_thread);
255 static void
256 thread_resumes(Thread* thread)
258 cpu_ent* cpu = thread->cpu;
260 release_spinlock(&cpu->previous_thread->scheduler_lock);
262 // continue CPU time based user timers
263 continue_cpu_timers(thread, cpu);
265 // notify the user debugger code
266 if ((thread->flags & THREAD_FLAGS_DEBUGGER_INSTALLED) != 0)
267 user_debug_thread_scheduled(thread);
271 void
272 scheduler_new_thread_entry(Thread* thread)
274 thread_resumes(thread);
276 SpinLocker locker(thread->time_lock);
277 thread->last_time = system_time();
281 /*! Switches the currently running thread.
282 This is a service function for scheduler implementations.
284 \param fromThread The currently running thread.
285 \param toThread The thread to switch to. Must be different from
286 \a fromThread.
288 static inline void
289 switch_thread(Thread* fromThread, Thread* toThread)
291 // notify the user debugger code
292 if ((fromThread->flags & THREAD_FLAGS_DEBUGGER_INSTALLED) != 0)
293 user_debug_thread_unscheduled(fromThread);
295 // stop CPU time based user timers
296 stop_cpu_timers(fromThread, toThread);
298 // update CPU and Thread structures and perform the context switch
299 cpu_ent* cpu = fromThread->cpu;
300 toThread->previous_cpu = toThread->cpu = cpu;
301 fromThread->cpu = NULL;
302 cpu->running_thread = toThread;
303 cpu->previous_thread = fromThread;
305 arch_thread_set_current_thread(toThread);
306 arch_thread_context_switch(fromThread, toThread);
308 // The use of fromThread below looks weird, but is correct. fromThread had
309 // been unscheduled earlier, but is back now. For a thread scheduled the
310 // first time the same is done in thread.cpp:common_thread_entry().
311 thread_resumes(fromThread);
315 static void
316 reschedule(int32 nextState)
318 ASSERT(!are_interrupts_enabled());
319 SCHEDULER_ENTER_FUNCTION();
321 int32 thisCPU = smp_get_current_cpu();
323 CPUEntry* cpu = CPUEntry::GetCPU(thisCPU);
324 CoreEntry* core = CoreEntry::GetCore(thisCPU);
326 Thread* oldThread = thread_get_current_thread();
327 ThreadData* oldThreadData = oldThread->scheduler_data;
329 oldThreadData->StopCPUTime();
331 SchedulerModeLocker modeLocker;
333 TRACE("reschedule(): cpu %ld, current thread = %ld\n", thisCPU,
334 oldThread->id);
336 oldThread->state = nextState;
338 // return time spent in interrupts
339 oldThreadData->SetStolenInterruptTime(gCPU[thisCPU].interrupt_time);
341 bool enqueueOldThread = false;
342 bool putOldThreadAtBack = false;
343 switch (nextState) {
344 case B_THREAD_RUNNING:
345 case B_THREAD_READY:
346 enqueueOldThread = true;
348 if (!oldThreadData->IsIdle()) {
349 oldThreadData->Continues();
350 if (oldThreadData->HasQuantumEnded(oldThread->cpu->preempted,
351 oldThread->has_yielded)) {
352 TRACE("enqueueing thread %ld into run queue priority ="
353 " %ld\n", oldThread->id,
354 oldThreadData->GetEffectivePriority());
355 putOldThreadAtBack = true;
356 } else {
357 TRACE("putting thread %ld back in run queue priority ="
358 " %ld\n", oldThread->id,
359 oldThreadData->GetEffectivePriority());
360 putOldThreadAtBack = false;
364 break;
365 case THREAD_STATE_FREE_ON_RESCHED:
366 oldThreadData->Dies();
367 break;
368 default:
369 oldThreadData->GoesAway();
370 TRACE("not enqueueing thread %ld into run queue next_state = %ld\n",
371 oldThread->id, nextState);
372 break;
375 oldThread->has_yielded = false;
377 // select thread with the biggest priority and enqueue back the old thread
378 ThreadData* nextThreadData;
379 if (gCPU[thisCPU].disabled) {
380 if (!oldThreadData->IsIdle()) {
381 putOldThreadAtBack = oldThread->pinned_to_cpu == 0;
382 oldThreadData->UnassignCore(true);
384 CPURunQueueLocker cpuLocker(cpu);
385 nextThreadData = cpu->PeekIdleThread();
386 cpu->Remove(nextThreadData);
387 } else
388 nextThreadData = oldThreadData;
389 } else {
390 nextThreadData
391 = cpu->ChooseNextThread(enqueueOldThread ? oldThreadData : NULL,
392 putOldThreadAtBack);
394 // update CPU heap
395 CoreCPUHeapLocker cpuLocker(core);
396 cpu->UpdatePriority(nextThreadData->GetEffectivePriority());
399 Thread* nextThread = nextThreadData->GetThread();
400 ASSERT(!gCPU[thisCPU].disabled || nextThreadData->IsIdle());
402 if (nextThread != oldThread) {
403 if (enqueueOldThread) {
404 if (putOldThreadAtBack)
405 enqueue(oldThread, false);
406 else
407 oldThreadData->PutBack();
410 acquire_spinlock(&nextThread->scheduler_lock);
413 TRACE("reschedule(): cpu %ld, next thread = %ld\n", thisCPU,
414 nextThread->id);
416 T(ScheduleThread(nextThread, oldThread));
418 // notify listeners
419 NotifySchedulerListeners(&SchedulerListener::ThreadScheduled,
420 oldThread, nextThread);
422 ASSERT(nextThreadData->Core() == core);
423 nextThread->state = B_THREAD_RUNNING;
424 nextThreadData->StartCPUTime();
426 // track CPU activity
427 cpu->TrackActivity(oldThreadData, nextThreadData);
429 if (nextThread != oldThread || oldThread->cpu->preempted) {
430 cpu->StartQuantumTimer(nextThreadData, oldThread->cpu->preempted);
432 oldThread->cpu->preempted = false;
433 if (!nextThreadData->IsIdle())
434 nextThreadData->Continues();
435 else
436 gCurrentMode->rebalance_irqs(true);
437 nextThreadData->StartQuantum();
439 modeLocker.Unlock();
441 SCHEDULER_EXIT_FUNCTION();
443 if (nextThread != oldThread)
444 switch_thread(oldThread, nextThread);
449 /*! Runs the scheduler.
450 Note: expects thread spinlock to be held
452 void
453 scheduler_reschedule(int32 nextState)
455 ASSERT(!are_interrupts_enabled());
456 SCHEDULER_ENTER_FUNCTION();
458 if (!sSchedulerEnabled) {
459 Thread* thread = thread_get_current_thread();
460 if (thread != NULL && nextState != B_THREAD_READY)
461 panic("scheduler_reschedule_no_op() called in non-ready thread");
462 return;
465 reschedule(nextState);
469 status_t
470 scheduler_on_thread_create(Thread* thread, bool idleThread)
472 thread->scheduler_data = new(std::nothrow) ThreadData(thread);
473 if (thread->scheduler_data == NULL)
474 return B_NO_MEMORY;
475 return B_OK;
479 void
480 scheduler_on_thread_init(Thread* thread)
482 ASSERT(thread->scheduler_data != NULL);
484 if (thread_is_idle_thread(thread)) {
485 static int32 sIdleThreadsID;
486 int32 cpuID = atomic_add(&sIdleThreadsID, 1);
488 thread->previous_cpu = &gCPU[cpuID];
489 thread->pinned_to_cpu = 1;
491 thread->scheduler_data->Init(CoreEntry::GetCore(cpuID));
492 } else
493 thread->scheduler_data->Init();
497 void
498 scheduler_on_thread_destroy(Thread* thread)
500 delete thread->scheduler_data;
504 /*! This starts the scheduler. Must be run in the context of the initial idle
505 thread. Interrupts must be disabled and will be disabled when returning.
507 void
508 scheduler_start()
510 InterruptsSpinLocker _(thread_get_current_thread()->scheduler_lock);
511 SCHEDULER_ENTER_FUNCTION();
513 reschedule(B_THREAD_READY);
517 status_t
518 scheduler_set_operation_mode(scheduler_mode mode)
520 if (mode != SCHEDULER_MODE_LOW_LATENCY
521 && mode != SCHEDULER_MODE_POWER_SAVING) {
522 return B_BAD_VALUE;
525 dprintf("scheduler: switching to %s mode\n", sSchedulerModes[mode]->name);
527 InterruptsBigSchedulerLocker _;
529 gCurrentModeID = mode;
530 gCurrentMode = sSchedulerModes[mode];
531 gCurrentMode->switch_to_mode();
533 ThreadData::ComputeQuantumLengths();
535 return B_OK;
539 void
540 scheduler_set_cpu_enabled(int32 cpuID, bool enabled)
542 #if KDEBUG
543 if (are_interrupts_enabled())
544 panic("scheduler_set_cpu_enabled: called with interrupts enabled");
545 #endif
547 dprintf("scheduler: %s CPU %" B_PRId32 "\n",
548 enabled ? "enabling" : "disabling", cpuID);
550 InterruptsBigSchedulerLocker _;
552 gCurrentMode->set_cpu_enabled(cpuID, enabled);
554 CPUEntry* cpu = &gCPUEntries[cpuID];
555 CoreEntry* core = cpu->Core();
557 ASSERT(core->CPUCount() >= 0);
558 if (enabled)
559 cpu->Start();
560 else {
561 cpu->UpdatePriority(B_IDLE_PRIORITY);
563 ThreadEnqueuer enqueuer;
564 core->RemoveCPU(cpu, enqueuer);
567 gCPU[cpuID].disabled = !enabled;
569 if (!enabled) {
570 cpu->Stop();
572 // don't wait until the thread quantum ends
573 if (smp_get_current_cpu() != cpuID) {
574 smp_send_ici(cpuID, SMP_MSG_RESCHEDULE, 0, 0, 0, NULL,
575 SMP_MSG_FLAG_ASYNC);
581 static void
582 traverse_topology_tree(const cpu_topology_node* node, int packageID, int coreID)
584 switch (node->level) {
585 case CPU_TOPOLOGY_SMT:
586 sCPUToCore[node->id] = coreID;
587 sCPUToPackage[node->id] = packageID;
588 return;
590 case CPU_TOPOLOGY_CORE:
591 coreID = node->id;
592 break;
594 case CPU_TOPOLOGY_PACKAGE:
595 packageID = node->id;
596 break;
598 default:
599 break;
602 for (int32 i = 0; i < node->children_count; i++)
603 traverse_topology_tree(node->children[i], packageID, coreID);
607 static status_t
608 build_topology_mappings(int32& cpuCount, int32& coreCount, int32& packageCount)
610 cpuCount = smp_get_num_cpus();
612 sCPUToCore = new(std::nothrow) int32[cpuCount];
613 if (sCPUToCore == NULL)
614 return B_NO_MEMORY;
615 ArrayDeleter<int32> cpuToCoreDeleter(sCPUToCore);
617 sCPUToPackage = new(std::nothrow) int32[cpuCount];
618 if (sCPUToPackage == NULL)
619 return B_NO_MEMORY;
620 ArrayDeleter<int32> cpuToPackageDeleter(sCPUToPackage);
622 coreCount = 0;
623 for (int32 i = 0; i < cpuCount; i++) {
624 if (gCPU[i].topology_id[CPU_TOPOLOGY_SMT] == 0)
625 coreCount++;
628 packageCount = 0;
629 for (int32 i = 0; i < cpuCount; i++) {
630 if (gCPU[i].topology_id[CPU_TOPOLOGY_SMT] == 0
631 && gCPU[i].topology_id[CPU_TOPOLOGY_CORE] == 0) {
632 packageCount++;
636 const cpu_topology_node* root = get_cpu_topology();
637 traverse_topology_tree(root, 0, 0);
639 cpuToCoreDeleter.Detach();
640 cpuToPackageDeleter.Detach();
641 return B_OK;
645 static status_t
646 init()
648 // create logical processor to core and package mappings
649 int32 cpuCount, coreCount, packageCount;
650 status_t result = build_topology_mappings(cpuCount, coreCount,
651 packageCount);
652 if (result != B_OK)
653 return result;
655 // disable parts of the scheduler logic that are not needed
656 gSingleCore = coreCount == 1;
657 gTrackCPULoad = increase_cpu_performance(0) == B_OK;
658 gTrackCoreLoad = !gSingleCore || gTrackCPULoad;
659 dprintf("scheduler switches: single core: %s, cpu load tracking: %s,"
660 " core load tracking: %s\n", gSingleCore ? "true" : "false",
661 gTrackCPULoad ? "true" : "false",
662 gTrackCoreLoad ? "true" : "false");
664 gCoreCount = coreCount;
665 gPackageCount = packageCount;
667 gCPUEntries = new(std::nothrow) CPUEntry[cpuCount];
668 if (gCPUEntries == NULL)
669 return B_NO_MEMORY;
670 ArrayDeleter<CPUEntry> cpuEntriesDeleter(gCPUEntries);
672 gCoreEntries = new(std::nothrow) CoreEntry[coreCount];
673 if (gCoreEntries == NULL)
674 return B_NO_MEMORY;
675 ArrayDeleter<CoreEntry> coreEntriesDeleter(gCoreEntries);
677 gPackageEntries = new(std::nothrow) PackageEntry[packageCount];
678 if (gPackageEntries == NULL)
679 return B_NO_MEMORY;
680 ArrayDeleter<PackageEntry> packageEntriesDeleter(gPackageEntries);
682 new(&gCoreLoadHeap) CoreLoadHeap(coreCount);
683 new(&gCoreHighLoadHeap) CoreLoadHeap(coreCount);
685 new(&gIdlePackageList) IdlePackageList;
687 for (int32 i = 0; i < cpuCount; i++) {
688 CoreEntry* core = &gCoreEntries[sCPUToCore[i]];
689 PackageEntry* package = &gPackageEntries[sCPUToPackage[i]];
691 package->Init(sCPUToPackage[i]);
692 core->Init(sCPUToCore[i], package);
693 gCPUEntries[i].Init(i, core);
695 core->AddCPU(&gCPUEntries[i]);
698 packageEntriesDeleter.Detach();
699 coreEntriesDeleter.Detach();
700 cpuEntriesDeleter.Detach();
702 return B_OK;
706 void
707 scheduler_init()
709 int32 cpuCount = smp_get_num_cpus();
710 dprintf("scheduler_init: found %" B_PRId32 " logical cpu%s and %" B_PRId32
711 " cache level%s\n", cpuCount, cpuCount != 1 ? "s" : "",
712 gCPUCacheLevelCount, gCPUCacheLevelCount != 1 ? "s" : "");
714 #ifdef SCHEDULER_PROFILING
715 Profiling::Profiler::Initialize();
716 #endif
718 status_t result = init();
719 if (result != B_OK)
720 panic("scheduler_init: failed to initialize scheduler\n");
722 scheduler_set_operation_mode(SCHEDULER_MODE_LOW_LATENCY);
724 init_debug_commands();
726 #if SCHEDULER_TRACING
727 add_debugger_command_etc("scheduler", &cmd_scheduler,
728 "Analyze scheduler tracing information",
729 "<thread>\n"
730 "Analyzes scheduler tracing information for a given thread.\n"
731 " <thread> - ID of the thread.\n", 0);
732 #endif
736 void
737 scheduler_enable_scheduling()
739 sSchedulerEnabled = true;
743 // #pragma mark - SchedulerListener
746 SchedulerListener::~SchedulerListener()
751 // #pragma mark - kernel private
754 /*! Add the given scheduler listener. Thread lock must be held.
756 void
757 scheduler_add_listener(struct SchedulerListener* listener)
759 InterruptsSpinLocker _(gSchedulerListenersLock);
760 gSchedulerListeners.Add(listener);
764 /*! Remove the given scheduler listener. Thread lock must be held.
766 void
767 scheduler_remove_listener(struct SchedulerListener* listener)
769 InterruptsSpinLocker _(gSchedulerListenersLock);
770 gSchedulerListeners.Remove(listener);
774 // #pragma mark - Syscalls
777 bigtime_t
778 _user_estimate_max_scheduling_latency(thread_id id)
780 syscall_64_bit_return_value();
782 // get the thread
783 Thread* thread;
784 if (id < 0) {
785 thread = thread_get_current_thread();
786 thread->AcquireReference();
787 } else {
788 thread = Thread::Get(id);
789 if (thread == NULL)
790 return 0;
792 BReference<Thread> threadReference(thread, true);
794 #ifdef SCHEDULER_PROFILING
795 InterruptsLocker _;
796 #endif
798 ThreadData* threadData = thread->scheduler_data;
799 CoreEntry* core = threadData->Core();
800 if (core == NULL)
801 core = &gCoreEntries[get_random<int32>() % gCoreCount];
803 int32 threadCount = core->ThreadCount();
804 if (core->CPUCount() > 0)
805 threadCount /= core->CPUCount();
807 if (threadData->GetEffectivePriority() > 0) {
808 threadCount -= threadCount * THREAD_MAX_SET_PRIORITY
809 / threadData->GetEffectivePriority();
812 return std::min(std::max(threadCount * gCurrentMode->base_quantum,
813 gCurrentMode->minimal_quantum),
814 gCurrentMode->maximum_latency);
818 status_t
819 _user_set_scheduler_mode(int32 mode)
821 scheduler_mode schedulerMode = static_cast<scheduler_mode>(mode);
822 status_t error = scheduler_set_operation_mode(schedulerMode);
823 if (error == B_OK)
824 cpu_set_scheduler_mode(schedulerMode);
825 return error;
829 int32
830 _user_get_scheduler_mode()
832 return gCurrentModeID;