xref: /freebsd/contrib/llvm-project/openmp/runtime/src/kmp_wait_release.h (revision a03411e84728e9b267056fd31c7d1d9d1dc1b01e)
1 /*
2  * kmp_wait_release.h -- Wait/Release implementation
3  */
4 
5 //===----------------------------------------------------------------------===//
6 //
7 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
8 // See https://llvm.org/LICENSE.txt for license information.
9 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
10 //
11 //===----------------------------------------------------------------------===//
12 
13 #ifndef KMP_WAIT_RELEASE_H
14 #define KMP_WAIT_RELEASE_H
15 
16 #include "kmp.h"
17 #include "kmp_itt.h"
18 #include "kmp_stats.h"
19 #if OMPT_SUPPORT
20 #include "ompt-specific.h"
21 #endif
22 
23 /*!
24 @defgroup WAIT_RELEASE Wait/Release operations
25 
26 The definitions and functions here implement the lowest level thread
27 synchronizations of suspending a thread and awaking it. They are used to build
28 higher level operations such as barriers and fork/join.
29 */
30 
31 /*!
32 @ingroup WAIT_RELEASE
33 @{
34 */
35 
36 struct flag_properties {
37   unsigned int type : 16;
38   unsigned int reserved : 16;
39 };
40 
41 template <enum flag_type FlagType> struct flag_traits {};
42 
43 template <> struct flag_traits<flag32> {
44   typedef kmp_uint32 flag_t;
45   static const flag_type t = flag32;
46   static inline flag_t tcr(flag_t f) { return TCR_4(f); }
47   static inline flag_t test_then_add4(volatile flag_t *f) {
48     return KMP_TEST_THEN_ADD4_32(RCAST(volatile kmp_int32 *, f));
49   }
50   static inline flag_t test_then_or(volatile flag_t *f, flag_t v) {
51     return KMP_TEST_THEN_OR32(f, v);
52   }
53   static inline flag_t test_then_and(volatile flag_t *f, flag_t v) {
54     return KMP_TEST_THEN_AND32(f, v);
55   }
56 };
57 
58 template <> struct flag_traits<atomic_flag64> {
59   typedef kmp_uint64 flag_t;
60   static const flag_type t = atomic_flag64;
61   static inline flag_t tcr(flag_t f) { return TCR_8(f); }
62   static inline flag_t test_then_add4(volatile flag_t *f) {
63     return KMP_TEST_THEN_ADD4_64(RCAST(volatile kmp_int64 *, f));
64   }
65   static inline flag_t test_then_or(volatile flag_t *f, flag_t v) {
66     return KMP_TEST_THEN_OR64(f, v);
67   }
68   static inline flag_t test_then_and(volatile flag_t *f, flag_t v) {
69     return KMP_TEST_THEN_AND64(f, v);
70   }
71 };
72 
73 template <> struct flag_traits<flag64> {
74   typedef kmp_uint64 flag_t;
75   static const flag_type t = flag64;
76   static inline flag_t tcr(flag_t f) { return TCR_8(f); }
77   static inline flag_t test_then_add4(volatile flag_t *f) {
78     return KMP_TEST_THEN_ADD4_64(RCAST(volatile kmp_int64 *, f));
79   }
80   static inline flag_t test_then_or(volatile flag_t *f, flag_t v) {
81     return KMP_TEST_THEN_OR64(f, v);
82   }
83   static inline flag_t test_then_and(volatile flag_t *f, flag_t v) {
84     return KMP_TEST_THEN_AND64(f, v);
85   }
86 };
87 
88 template <> struct flag_traits<flag_oncore> {
89   typedef kmp_uint64 flag_t;
90   static const flag_type t = flag_oncore;
91   static inline flag_t tcr(flag_t f) { return TCR_8(f); }
92   static inline flag_t test_then_add4(volatile flag_t *f) {
93     return KMP_TEST_THEN_ADD4_64(RCAST(volatile kmp_int64 *, f));
94   }
95   static inline flag_t test_then_or(volatile flag_t *f, flag_t v) {
96     return KMP_TEST_THEN_OR64(f, v);
97   }
98   static inline flag_t test_then_and(volatile flag_t *f, flag_t v) {
99     return KMP_TEST_THEN_AND64(f, v);
100   }
101 };
102 
103 /*! Base class for all flags */
104 template <flag_type FlagType> class kmp_flag {
105 protected:
106   flag_properties t; /**< "Type" of the flag in loc */
107   kmp_info_t *waiting_threads[1]; /**< Threads sleeping on this thread. */
108   kmp_uint32 num_waiting_threads; /**< Num threads sleeping on this thread. */
109   std::atomic<bool> *sleepLoc;
110 
111 public:
112   typedef flag_traits<FlagType> traits_type;
113   kmp_flag() : t({FlagType, 0U}), num_waiting_threads(0), sleepLoc(nullptr) {}
114   kmp_flag(int nwaiters)
115       : t({FlagType, 0U}), num_waiting_threads(nwaiters), sleepLoc(nullptr) {}
116   kmp_flag(std::atomic<bool> *sloc)
117       : t({FlagType, 0U}), num_waiting_threads(0), sleepLoc(sloc) {}
118   /*! @result the flag_type */
119   flag_type get_type() { return (flag_type)(t.type); }
120 
121   /*! param i in   index into waiting_threads
122    *  @result the thread that is waiting at index i */
123   kmp_info_t *get_waiter(kmp_uint32 i) {
124     KMP_DEBUG_ASSERT(i < num_waiting_threads);
125     return waiting_threads[i];
126   }
127   /*! @result num_waiting_threads */
128   kmp_uint32 get_num_waiters() { return num_waiting_threads; }
129   /*! @param thr in   the thread which is now waiting
130    *  Insert a waiting thread at index 0. */
131   void set_waiter(kmp_info_t *thr) {
132     waiting_threads[0] = thr;
133     num_waiting_threads = 1;
134   }
135   enum barrier_type get_bt() { return bs_last_barrier; }
136 };
137 
138 /*! Base class for wait/release volatile flag */
139 template <typename PtrType, flag_type FlagType, bool Sleepable>
140 class kmp_flag_native : public kmp_flag<FlagType> {
141 protected:
142   volatile PtrType *loc;
143   PtrType checker; /**< When flag==checker, it has been released. */
144   typedef flag_traits<FlagType> traits_type;
145 
146 public:
147   typedef PtrType flag_t;
148   kmp_flag_native(volatile PtrType *p) : kmp_flag<FlagType>(), loc(p) {}
149   kmp_flag_native(volatile PtrType *p, kmp_info_t *thr)
150       : kmp_flag<FlagType>(1), loc(p) {
151     this->waiting_threads[0] = thr;
152   }
153   kmp_flag_native(volatile PtrType *p, PtrType c)
154       : kmp_flag<FlagType>(), loc(p), checker(c) {}
155   kmp_flag_native(volatile PtrType *p, PtrType c, std::atomic<bool> *sloc)
156       : kmp_flag<FlagType>(sloc), loc(p), checker(c) {}
157   virtual ~kmp_flag_native() {}
158   void *operator new(size_t size) { return __kmp_allocate(size); }
159   void operator delete(void *p) { __kmp_free(p); }
160   volatile PtrType *get() { return loc; }
161   void *get_void_p() { return RCAST(void *, CCAST(PtrType *, loc)); }
162   void set(volatile PtrType *new_loc) { loc = new_loc; }
163   PtrType load() { return *loc; }
164   void store(PtrType val) { *loc = val; }
165   /*! @result true if the flag object has been released. */
166   virtual bool done_check() {
167     if (Sleepable && !(this->sleepLoc))
168       return (traits_type::tcr(*(this->get())) & ~KMP_BARRIER_SLEEP_STATE) ==
169              checker;
170     else
171       return traits_type::tcr(*(this->get())) == checker;
172   }
173   /*! @param old_loc in   old value of flag
174    *  @result true if the flag's old value indicates it was released. */
175   virtual bool done_check_val(PtrType old_loc) { return old_loc == checker; }
176   /*! @result true if the flag object is not yet released.
177    * Used in __kmp_wait_template like:
178    * @code
179    * while (flag.notdone_check()) { pause(); }
180    * @endcode */
181   virtual bool notdone_check() {
182     return traits_type::tcr(*(this->get())) != checker;
183   }
184   /*! @result Actual flag value before release was applied.
185    * Trigger all waiting threads to run by modifying flag to release state. */
186   void internal_release() {
187     (void)traits_type::test_then_add4((volatile PtrType *)this->get());
188   }
189   /*! @result Actual flag value before sleep bit(s) set.
190    * Notes that there is at least one thread sleeping on the flag by setting
191    * sleep bit(s). */
192   PtrType set_sleeping() {
193     if (this->sleepLoc) {
194       this->sleepLoc->store(true);
195       return *(this->get());
196     }
197     return traits_type::test_then_or((volatile PtrType *)this->get(),
198                                      KMP_BARRIER_SLEEP_STATE);
199   }
200   /*! @result Actual flag value before sleep bit(s) cleared.
201    * Notes that there are no longer threads sleeping on the flag by clearing
202    * sleep bit(s). */
203   void unset_sleeping() {
204     if (this->sleepLoc) {
205       this->sleepLoc->store(false);
206       return;
207     }
208     traits_type::test_then_and((volatile PtrType *)this->get(),
209                                ~KMP_BARRIER_SLEEP_STATE);
210   }
211   /*! @param old_loc in   old value of flag
212    * Test if there are threads sleeping on the flag's old value in old_loc. */
213   bool is_sleeping_val(PtrType old_loc) {
214     if (this->sleepLoc)
215       return this->sleepLoc->load();
216     return old_loc & KMP_BARRIER_SLEEP_STATE;
217   }
218   /*! Test whether there are threads sleeping on the flag. */
219   bool is_sleeping() {
220     if (this->sleepLoc)
221       return this->sleepLoc->load();
222     return is_sleeping_val(*(this->get()));
223   }
224   bool is_any_sleeping() {
225     if (this->sleepLoc)
226       return this->sleepLoc->load();
227     return is_sleeping_val(*(this->get()));
228   }
229   kmp_uint8 *get_stolen() { return NULL; }
230 };
231 
232 /*! Base class for wait/release atomic flag */
233 template <typename PtrType, flag_type FlagType, bool Sleepable>
234 class kmp_flag_atomic : public kmp_flag<FlagType> {
235 protected:
236   std::atomic<PtrType> *loc; /**< Pointer to flag location to wait on */
237   PtrType checker; /**< Flag == checker means it has been released. */
238 public:
239   typedef flag_traits<FlagType> traits_type;
240   typedef PtrType flag_t;
241   kmp_flag_atomic(std::atomic<PtrType> *p) : kmp_flag<FlagType>(), loc(p) {}
242   kmp_flag_atomic(std::atomic<PtrType> *p, kmp_info_t *thr)
243       : kmp_flag<FlagType>(1), loc(p) {
244     this->waiting_threads[0] = thr;
245   }
246   kmp_flag_atomic(std::atomic<PtrType> *p, PtrType c)
247       : kmp_flag<FlagType>(), loc(p), checker(c) {}
248   kmp_flag_atomic(std::atomic<PtrType> *p, PtrType c, std::atomic<bool> *sloc)
249       : kmp_flag<FlagType>(sloc), loc(p), checker(c) {}
250   /*! @result the pointer to the actual flag */
251   std::atomic<PtrType> *get() { return loc; }
252   /*! @result void* pointer to the actual flag */
253   void *get_void_p() { return RCAST(void *, loc); }
254   /*! @param new_loc in   set loc to point at new_loc */
255   void set(std::atomic<PtrType> *new_loc) { loc = new_loc; }
256   /*! @result flag value */
257   PtrType load() { return loc->load(std::memory_order_acquire); }
258   /*! @param val the new flag value to be stored */
259   void store(PtrType val) { loc->store(val, std::memory_order_release); }
260   /*! @result true if the flag object has been released. */
261   bool done_check() {
262     if (Sleepable && !(this->sleepLoc))
263       return (this->load() & ~KMP_BARRIER_SLEEP_STATE) == checker;
264     else
265       return this->load() == checker;
266   }
267   /*! @param old_loc in   old value of flag
268    * @result true if the flag's old value indicates it was released. */
269   bool done_check_val(PtrType old_loc) { return old_loc == checker; }
270   /*! @result true if the flag object is not yet released.
271    * Used in __kmp_wait_template like:
272    * @code
273    * while (flag.notdone_check()) { pause(); }
274    * @endcode */
275   bool notdone_check() { return this->load() != checker; }
276   /*! @result Actual flag value before release was applied.
277    * Trigger all waiting threads to run by modifying flag to release state. */
278   void internal_release() { KMP_ATOMIC_ADD(this->get(), 4); }
279   /*! @result Actual flag value before sleep bit(s) set.
280    * Notes that there is at least one thread sleeping on the flag by setting
281    * sleep bit(s). */
282   PtrType set_sleeping() {
283     if (this->sleepLoc) {
284       this->sleepLoc->store(true);
285       return *(this->get());
286     }
287     return KMP_ATOMIC_OR(this->get(), KMP_BARRIER_SLEEP_STATE);
288   }
289   /*! @result Actual flag value before sleep bit(s) cleared.
290    * Notes that there are no longer threads sleeping on the flag by clearing
291    * sleep bit(s). */
292   void unset_sleeping() {
293     if (this->sleepLoc) {
294       this->sleepLoc->store(false);
295       return;
296     }
297     KMP_ATOMIC_AND(this->get(), ~KMP_BARRIER_SLEEP_STATE);
298   }
299   /*! @param old_loc in   old value of flag
300    * Test whether there are threads sleeping on flag's old value in old_loc. */
301   bool is_sleeping_val(PtrType old_loc) {
302     if (this->sleepLoc)
303       return this->sleepLoc->load();
304     return old_loc & KMP_BARRIER_SLEEP_STATE;
305   }
306   /*! Test whether there are threads sleeping on the flag. */
307   bool is_sleeping() {
308     if (this->sleepLoc)
309       return this->sleepLoc->load();
310     return is_sleeping_val(this->load());
311   }
312   bool is_any_sleeping() {
313     if (this->sleepLoc)
314       return this->sleepLoc->load();
315     return is_sleeping_val(this->load());
316   }
317   kmp_uint8 *get_stolen() { return NULL; }
318 };
319 
320 #if OMPT_SUPPORT
321 OMPT_NOINLINE
322 static void __ompt_implicit_task_end(kmp_info_t *this_thr,
323                                      ompt_state_t ompt_state,
324                                      ompt_data_t *tId) {
325   int ds_tid = this_thr->th.th_info.ds.ds_tid;
326   if (ompt_state == ompt_state_wait_barrier_implicit) {
327     this_thr->th.ompt_thread_info.state = ompt_state_overhead;
328 #if OMPT_OPTIONAL
329     void *codeptr = NULL;
330     if (ompt_enabled.ompt_callback_sync_region_wait) {
331       ompt_callbacks.ompt_callback(ompt_callback_sync_region_wait)(
332           ompt_sync_region_barrier_implicit, ompt_scope_end, NULL, tId,
333           codeptr);
334     }
335     if (ompt_enabled.ompt_callback_sync_region) {
336       ompt_callbacks.ompt_callback(ompt_callback_sync_region)(
337           ompt_sync_region_barrier_implicit, ompt_scope_end, NULL, tId,
338           codeptr);
339     }
340 #endif
341     if (!KMP_MASTER_TID(ds_tid)) {
342       if (ompt_enabled.ompt_callback_implicit_task) {
343         int flags = this_thr->th.ompt_thread_info.parallel_flags;
344         flags = (flags & ompt_parallel_league) ? ompt_task_initial
345                                                : ompt_task_implicit;
346         ompt_callbacks.ompt_callback(ompt_callback_implicit_task)(
347             ompt_scope_end, NULL, tId, 0, ds_tid, flags);
348       }
349       // return to idle state
350       this_thr->th.ompt_thread_info.state = ompt_state_idle;
351     } else {
352       this_thr->th.ompt_thread_info.state = ompt_state_overhead;
353     }
354   }
355 }
356 #endif
357 
358 /* Spin wait loop that first does pause/yield, then sleep. A thread that calls
359    __kmp_wait_*  must make certain that another thread calls __kmp_release
360    to wake it back up to prevent deadlocks!
361 
362    NOTE: We may not belong to a team at this point.  */
363 template <class C, bool final_spin, bool Cancellable = false,
364           bool Sleepable = true>
365 static inline bool
366 __kmp_wait_template(kmp_info_t *this_thr,
367                     C *flag USE_ITT_BUILD_ARG(void *itt_sync_obj)) {
368 #if USE_ITT_BUILD && USE_ITT_NOTIFY
369   volatile void *spin = flag->get();
370 #endif
371   kmp_uint32 spins;
372   int th_gtid;
373   int tasks_completed = FALSE;
374 #if !KMP_USE_MONITOR
375   kmp_uint64 poll_count;
376   kmp_uint64 hibernate_goal;
377 #else
378   kmp_uint32 hibernate;
379 #endif
380   kmp_uint64 time;
381 
382   KMP_FSYNC_SPIN_INIT(spin, NULL);
383   if (flag->done_check()) {
384     KMP_FSYNC_SPIN_ACQUIRED(CCAST(void *, spin));
385     return false;
386   }
387   th_gtid = this_thr->th.th_info.ds.ds_gtid;
388   if (Cancellable) {
389     kmp_team_t *team = this_thr->th.th_team;
390     if (team && team->t.t_cancel_request == cancel_parallel)
391       return true;
392   }
393 #if KMP_OS_UNIX
394   if (final_spin)
395     KMP_ATOMIC_ST_REL(&this_thr->th.th_blocking, true);
396 #endif
397   KA_TRACE(20,
398            ("__kmp_wait_sleep: T#%d waiting for flag(%p)\n", th_gtid, flag));
399 #if KMP_STATS_ENABLED
400   stats_state_e thread_state = KMP_GET_THREAD_STATE();
401 #endif
402 
403 /* OMPT Behavior:
404 THIS function is called from
405   __kmp_barrier (2 times)  (implicit or explicit barrier in parallel regions)
406             these have join / fork behavior
407 
408        In these cases, we don't change the state or trigger events in THIS
409 function.
410        Events are triggered in the calling code (__kmp_barrier):
411 
412                 state := ompt_state_overhead
413             barrier-begin
414             barrier-wait-begin
415                 state := ompt_state_wait_barrier
416           call join-barrier-implementation (finally arrive here)
417           {}
418           call fork-barrier-implementation (finally arrive here)
419           {}
420                 state := ompt_state_overhead
421             barrier-wait-end
422             barrier-end
423                 state := ompt_state_work_parallel
424 
425 
426   __kmp_fork_barrier  (after thread creation, before executing implicit task)
427           call fork-barrier-implementation (finally arrive here)
428           {} // worker arrive here with state = ompt_state_idle
429 
430 
431   __kmp_join_barrier  (implicit barrier at end of parallel region)
432                 state := ompt_state_barrier_implicit
433             barrier-begin
434             barrier-wait-begin
435           call join-barrier-implementation (finally arrive here
436 final_spin=FALSE)
437           {
438           }
439   __kmp_fork_barrier  (implicit barrier at end of parallel region)
440           call fork-barrier-implementation (finally arrive here final_spin=TRUE)
441 
442        Worker after task-team is finished:
443             barrier-wait-end
444             barrier-end
445             implicit-task-end
446             idle-begin
447                 state := ompt_state_idle
448 
449        Before leaving, if state = ompt_state_idle
450             idle-end
451                 state := ompt_state_overhead
452 */
453 #if OMPT_SUPPORT
454   ompt_state_t ompt_entry_state;
455   ompt_data_t *tId;
456   if (ompt_enabled.enabled) {
457     ompt_entry_state = this_thr->th.ompt_thread_info.state;
458     if (!final_spin || ompt_entry_state != ompt_state_wait_barrier_implicit ||
459         KMP_MASTER_TID(this_thr->th.th_info.ds.ds_tid)) {
460       ompt_lw_taskteam_t *team = NULL;
461       if (this_thr->th.th_team)
462         team = this_thr->th.th_team->t.ompt_serialized_team_info;
463       if (team) {
464         tId = &(team->ompt_task_info.task_data);
465       } else {
466         tId = OMPT_CUR_TASK_DATA(this_thr);
467       }
468     } else {
469       tId = &(this_thr->th.ompt_thread_info.task_data);
470     }
471     if (final_spin && (__kmp_tasking_mode == tskm_immediate_exec ||
472                        this_thr->th.th_task_team == NULL)) {
473       // implicit task is done. Either no taskqueue, or task-team finished
474       __ompt_implicit_task_end(this_thr, ompt_entry_state, tId);
475     }
476   }
477 #endif
478 
479   KMP_INIT_YIELD(spins); // Setup for waiting
480   KMP_INIT_BACKOFF(time);
481 
482   if (__kmp_dflt_blocktime != KMP_MAX_BLOCKTIME ||
483       __kmp_pause_status == kmp_soft_paused) {
484 #if KMP_USE_MONITOR
485 // The worker threads cannot rely on the team struct existing at this point.
486 // Use the bt values cached in the thread struct instead.
487 #ifdef KMP_ADJUST_BLOCKTIME
488     if (__kmp_pause_status == kmp_soft_paused ||
489         (__kmp_zero_bt && !this_thr->th.th_team_bt_set))
490       // Force immediate suspend if not set by user and more threads than
491       // available procs
492       hibernate = 0;
493     else
494       hibernate = this_thr->th.th_team_bt_intervals;
495 #else
496     hibernate = this_thr->th.th_team_bt_intervals;
497 #endif /* KMP_ADJUST_BLOCKTIME */
498 
499     /* If the blocktime is nonzero, we want to make sure that we spin wait for
500        the entirety of the specified #intervals, plus up to one interval more.
501        This increment make certain that this thread doesn't go to sleep too
502        soon.  */
503     if (hibernate != 0)
504       hibernate++;
505 
506     // Add in the current time value.
507     hibernate += TCR_4(__kmp_global.g.g_time.dt.t_value);
508     KF_TRACE(20, ("__kmp_wait_sleep: T#%d now=%d, hibernate=%d, intervals=%d\n",
509                   th_gtid, __kmp_global.g.g_time.dt.t_value, hibernate,
510                   hibernate - __kmp_global.g.g_time.dt.t_value));
511 #else
512     if (__kmp_pause_status == kmp_soft_paused) {
513       // Force immediate suspend
514       hibernate_goal = KMP_NOW();
515     } else
516       hibernate_goal = KMP_NOW() + this_thr->th.th_team_bt_intervals;
517     poll_count = 0;
518     (void)poll_count;
519 #endif // KMP_USE_MONITOR
520   }
521 
522   KMP_MB();
523 
524   // Main wait spin loop
525   while (flag->notdone_check()) {
526     kmp_task_team_t *task_team = NULL;
527     if (__kmp_tasking_mode != tskm_immediate_exec) {
528       task_team = this_thr->th.th_task_team;
529       /* If the thread's task team pointer is NULL, it means one of 3 things:
530          1) A newly-created thread is first being released by
531          __kmp_fork_barrier(), and its task team has not been set up yet.
532          2) All tasks have been executed to completion.
533          3) Tasking is off for this region.  This could be because we are in a
534          serialized region (perhaps the outer one), or else tasking was manually
535          disabled (KMP_TASKING=0).  */
536       if (task_team != NULL) {
537         if (TCR_SYNC_4(task_team->tt.tt_active)) {
538           if (KMP_TASKING_ENABLED(task_team)) {
539             flag->execute_tasks(
540                 this_thr, th_gtid, final_spin,
541                 &tasks_completed USE_ITT_BUILD_ARG(itt_sync_obj), 0);
542           } else
543             this_thr->th.th_reap_state = KMP_SAFE_TO_REAP;
544         } else {
545           KMP_DEBUG_ASSERT(!KMP_MASTER_TID(this_thr->th.th_info.ds.ds_tid));
546 #if OMPT_SUPPORT
547           // task-team is done now, other cases should be catched above
548           if (final_spin && ompt_enabled.enabled)
549             __ompt_implicit_task_end(this_thr, ompt_entry_state, tId);
550 #endif
551           this_thr->th.th_task_team = NULL;
552           this_thr->th.th_reap_state = KMP_SAFE_TO_REAP;
553         }
554       } else {
555         this_thr->th.th_reap_state = KMP_SAFE_TO_REAP;
556       } // if
557     } // if
558 
559     KMP_FSYNC_SPIN_PREPARE(CCAST(void *, spin));
560     if (TCR_4(__kmp_global.g.g_done)) {
561       if (__kmp_global.g.g_abort)
562         __kmp_abort_thread();
563       break;
564     }
565 
566     // If we are oversubscribed, or have waited a bit (and
567     // KMP_LIBRARY=throughput), then yield
568     KMP_YIELD_OVERSUB_ELSE_SPIN(spins, time);
569 
570 #if KMP_STATS_ENABLED
571     // Check if thread has been signalled to idle state
572     // This indicates that the logical "join-barrier" has finished
573     if (this_thr->th.th_stats->isIdle() &&
574         KMP_GET_THREAD_STATE() == FORK_JOIN_BARRIER) {
575       KMP_SET_THREAD_STATE(IDLE);
576       KMP_PUSH_PARTITIONED_TIMER(OMP_idle);
577     }
578 #endif
579     // Check if the barrier surrounding this wait loop has been cancelled
580     if (Cancellable) {
581       kmp_team_t *team = this_thr->th.th_team;
582       if (team && team->t.t_cancel_request == cancel_parallel)
583         break;
584     }
585 
586     // For hidden helper thread, if task_team is nullptr, it means the main
587     // thread has not released the barrier. We cannot wait here because once the
588     // main thread releases all children barriers, all hidden helper threads are
589     // still sleeping. This leads to a problem that following configuration,
590     // such as task team sync, will not be performed such that this thread does
591     // not have task team. Usually it is not bad. However, a corner case is,
592     // when the first task encountered is an untied task, the check in
593     // __kmp_task_alloc will crash because it uses the task team pointer without
594     // checking whether it is nullptr. It is probably under some kind of
595     // assumption.
596     if (task_team && KMP_HIDDEN_HELPER_WORKER_THREAD(th_gtid) &&
597         !TCR_4(__kmp_hidden_helper_team_done)) {
598       // If there is still hidden helper tasks to be executed, the hidden helper
599       // thread will not enter a waiting status.
600       if (KMP_ATOMIC_LD_ACQ(&__kmp_unexecuted_hidden_helper_tasks) == 0) {
601         __kmp_hidden_helper_worker_thread_wait();
602       }
603       continue;
604     }
605 
606     // Don't suspend if KMP_BLOCKTIME is set to "infinite"
607     if (__kmp_dflt_blocktime == KMP_MAX_BLOCKTIME &&
608         __kmp_pause_status != kmp_soft_paused)
609       continue;
610 
611     // Don't suspend if there is a likelihood of new tasks being spawned.
612     if (task_team != NULL && TCR_4(task_team->tt.tt_found_tasks) &&
613         !__kmp_wpolicy_passive)
614       continue;
615 
616 #if KMP_USE_MONITOR
617     // If we have waited a bit more, fall asleep
618     if (TCR_4(__kmp_global.g.g_time.dt.t_value) < hibernate)
619       continue;
620 #else
621     if (KMP_BLOCKING(hibernate_goal, poll_count++))
622       continue;
623 #endif
624     // Don't suspend if wait loop designated non-sleepable
625     // in template parameters
626     if (!Sleepable)
627       continue;
628 
629 #if KMP_HAVE_MWAIT || KMP_HAVE_UMWAIT
630     if (__kmp_mwait_enabled || __kmp_umwait_enabled) {
631       KF_TRACE(50, ("__kmp_wait_sleep: T#%d using monitor/mwait\n", th_gtid));
632       flag->mwait(th_gtid);
633     } else {
634 #endif
635       KF_TRACE(50, ("__kmp_wait_sleep: T#%d suspend time reached\n", th_gtid));
636 #if KMP_OS_UNIX
637       if (final_spin)
638         KMP_ATOMIC_ST_REL(&this_thr->th.th_blocking, false);
639 #endif
640       flag->suspend(th_gtid);
641 #if KMP_OS_UNIX
642       if (final_spin)
643         KMP_ATOMIC_ST_REL(&this_thr->th.th_blocking, true);
644 #endif
645 #if KMP_HAVE_MWAIT || KMP_HAVE_UMWAIT
646     }
647 #endif
648 
649     if (TCR_4(__kmp_global.g.g_done)) {
650       if (__kmp_global.g.g_abort)
651         __kmp_abort_thread();
652       break;
653     } else if (__kmp_tasking_mode != tskm_immediate_exec &&
654                this_thr->th.th_reap_state == KMP_SAFE_TO_REAP) {
655       this_thr->th.th_reap_state = KMP_NOT_SAFE_TO_REAP;
656     }
657     // TODO: If thread is done with work and times out, disband/free
658   }
659 
660 #if OMPT_SUPPORT
661   ompt_state_t ompt_exit_state = this_thr->th.ompt_thread_info.state;
662   if (ompt_enabled.enabled && ompt_exit_state != ompt_state_undefined) {
663 #if OMPT_OPTIONAL
664     if (final_spin) {
665       __ompt_implicit_task_end(this_thr, ompt_exit_state, tId);
666       ompt_exit_state = this_thr->th.ompt_thread_info.state;
667     }
668 #endif
669     if (ompt_exit_state == ompt_state_idle) {
670       this_thr->th.ompt_thread_info.state = ompt_state_overhead;
671     }
672   }
673 #endif
674 #if KMP_STATS_ENABLED
675   // If we were put into idle state, pop that off the state stack
676   if (KMP_GET_THREAD_STATE() == IDLE) {
677     KMP_POP_PARTITIONED_TIMER();
678     KMP_SET_THREAD_STATE(thread_state);
679     this_thr->th.th_stats->resetIdleFlag();
680   }
681 #endif
682 
683 #if KMP_OS_UNIX
684   if (final_spin)
685     KMP_ATOMIC_ST_REL(&this_thr->th.th_blocking, false);
686 #endif
687   KMP_FSYNC_SPIN_ACQUIRED(CCAST(void *, spin));
688   if (Cancellable) {
689     kmp_team_t *team = this_thr->th.th_team;
690     if (team && team->t.t_cancel_request == cancel_parallel) {
691       if (tasks_completed) {
692         // undo the previous decrement of unfinished_threads so that the
693         // thread can decrement at the join barrier with no problem
694         kmp_task_team_t *task_team = this_thr->th.th_task_team;
695         std::atomic<kmp_int32> *unfinished_threads =
696             &(task_team->tt.tt_unfinished_threads);
697         KMP_ATOMIC_INC(unfinished_threads);
698       }
699       return true;
700     }
701   }
702   return false;
703 }
704 
705 #if KMP_HAVE_MWAIT || KMP_HAVE_UMWAIT
706 // Set up a monitor on the flag variable causing the calling thread to wait in
707 // a less active state until the flag variable is modified.
708 template <class C>
709 static inline void __kmp_mwait_template(int th_gtid, C *flag) {
710   KMP_TIME_DEVELOPER_PARTITIONED_BLOCK(USER_mwait);
711   kmp_info_t *th = __kmp_threads[th_gtid];
712 
713   KF_TRACE(30, ("__kmp_mwait_template: T#%d enter for flag = %p\n", th_gtid,
714                 flag->get()));
715 
716   // User-level mwait is available
717   KMP_DEBUG_ASSERT(__kmp_mwait_enabled || __kmp_umwait_enabled);
718 
719   __kmp_suspend_initialize_thread(th);
720   __kmp_lock_suspend_mx(th);
721 
722   volatile void *spin = flag->get();
723   void *cacheline = (void *)(kmp_uintptr_t(spin) & ~(CACHE_LINE - 1));
724 
725   if (!flag->done_check()) {
726     // Mark thread as no longer active
727     th->th.th_active = FALSE;
728     if (th->th.th_active_in_pool) {
729       th->th.th_active_in_pool = FALSE;
730       KMP_ATOMIC_DEC(&__kmp_thread_pool_active_nth);
731       KMP_DEBUG_ASSERT(TCR_4(__kmp_thread_pool_active_nth) >= 0);
732     }
733     flag->set_sleeping();
734     KF_TRACE(50, ("__kmp_mwait_template: T#%d calling monitor\n", th_gtid));
735 #if KMP_HAVE_UMWAIT
736     if (__kmp_umwait_enabled) {
737       __kmp_umonitor(cacheline);
738     }
739 #elif KMP_HAVE_MWAIT
740     if (__kmp_mwait_enabled) {
741       __kmp_mm_monitor(cacheline, 0, 0);
742     }
743 #endif
744     // To avoid a race, check flag between 'monitor' and 'mwait'. A write to
745     // the address could happen after the last time we checked and before
746     // monitoring started, in which case monitor can't detect the change.
747     if (flag->done_check())
748       flag->unset_sleeping();
749     else {
750       // if flag changes here, wake-up happens immediately
751       TCW_PTR(th->th.th_sleep_loc, (void *)flag);
752       th->th.th_sleep_loc_type = flag->get_type();
753       __kmp_unlock_suspend_mx(th);
754       KF_TRACE(50, ("__kmp_mwait_template: T#%d calling mwait\n", th_gtid));
755 #if KMP_HAVE_UMWAIT
756       if (__kmp_umwait_enabled) {
757         __kmp_umwait(1, 100); // to do: enable ctrl via hints, backoff counter
758       }
759 #elif KMP_HAVE_MWAIT
760       if (__kmp_mwait_enabled) {
761         __kmp_mm_mwait(0, __kmp_mwait_hints);
762       }
763 #endif
764       KF_TRACE(50, ("__kmp_mwait_template: T#%d mwait done\n", th_gtid));
765       __kmp_lock_suspend_mx(th);
766       // Clean up sleep info; doesn't matter how/why this thread stopped waiting
767       if (flag->is_sleeping())
768         flag->unset_sleeping();
769       TCW_PTR(th->th.th_sleep_loc, NULL);
770       th->th.th_sleep_loc_type = flag_unset;
771     }
772     // Mark thread as active again
773     th->th.th_active = TRUE;
774     if (TCR_4(th->th.th_in_pool)) {
775       KMP_ATOMIC_INC(&__kmp_thread_pool_active_nth);
776       th->th.th_active_in_pool = TRUE;
777     }
778   } // Drop out to main wait loop to check flag, handle tasks, etc.
779   __kmp_unlock_suspend_mx(th);
780   KF_TRACE(30, ("__kmp_mwait_template: T#%d exit\n", th_gtid));
781 }
782 #endif // KMP_HAVE_MWAIT || KMP_HAVE_UMWAIT
783 
784 /* Release any threads specified as waiting on the flag by releasing the flag
785    and resume the waiting thread if indicated by the sleep bit(s). A thread that
786    calls __kmp_wait_template must call this function to wake up the potentially
787    sleeping thread and prevent deadlocks!  */
788 template <class C> static inline void __kmp_release_template(C *flag) {
789 #ifdef KMP_DEBUG
790   int gtid = TCR_4(__kmp_init_gtid) ? __kmp_get_gtid() : -1;
791 #endif
792   KF_TRACE(20, ("__kmp_release: T#%d releasing flag(%x)\n", gtid, flag->get()));
793   KMP_DEBUG_ASSERT(flag->get());
794   KMP_FSYNC_RELEASING(flag->get_void_p());
795 
796   flag->internal_release();
797 
798   KF_TRACE(100, ("__kmp_release: T#%d set new spin=%d\n", gtid, flag->get(),
799                  flag->load()));
800 
801   if (__kmp_dflt_blocktime != KMP_MAX_BLOCKTIME) {
802     // Only need to check sleep stuff if infinite block time not set.
803     // Are *any* threads waiting on flag sleeping?
804     if (flag->is_any_sleeping()) {
805       for (unsigned int i = 0; i < flag->get_num_waiters(); ++i) {
806         // if sleeping waiter exists at i, sets current_waiter to i inside flag
807         kmp_info_t *waiter = flag->get_waiter(i);
808         if (waiter) {
809           int wait_gtid = waiter->th.th_info.ds.ds_gtid;
810           // Wake up thread if needed
811           KF_TRACE(50, ("__kmp_release: T#%d waking up thread T#%d since sleep "
812                         "flag(%p) set\n",
813                         gtid, wait_gtid, flag->get()));
814           flag->resume(wait_gtid); // unsets flag's current_waiter when done
815         }
816       }
817     }
818   }
819 }
820 
821 template <bool Cancellable, bool Sleepable>
822 class kmp_flag_32 : public kmp_flag_atomic<kmp_uint32, flag32, Sleepable> {
823 public:
824   kmp_flag_32(std::atomic<kmp_uint32> *p)
825       : kmp_flag_atomic<kmp_uint32, flag32, Sleepable>(p) {}
826   kmp_flag_32(std::atomic<kmp_uint32> *p, kmp_info_t *thr)
827       : kmp_flag_atomic<kmp_uint32, flag32, Sleepable>(p, thr) {}
828   kmp_flag_32(std::atomic<kmp_uint32> *p, kmp_uint32 c)
829       : kmp_flag_atomic<kmp_uint32, flag32, Sleepable>(p, c) {}
830   void suspend(int th_gtid) { __kmp_suspend_32(th_gtid, this); }
831 #if KMP_HAVE_MWAIT || KMP_HAVE_UMWAIT
832   void mwait(int th_gtid) { __kmp_mwait_32(th_gtid, this); }
833 #endif
834   void resume(int th_gtid) { __kmp_resume_32(th_gtid, this); }
835   int execute_tasks(kmp_info_t *this_thr, kmp_int32 gtid, int final_spin,
836                     int *thread_finished USE_ITT_BUILD_ARG(void *itt_sync_obj),
837                     kmp_int32 is_constrained) {
838     return __kmp_execute_tasks_32(
839         this_thr, gtid, this, final_spin,
840         thread_finished USE_ITT_BUILD_ARG(itt_sync_obj), is_constrained);
841   }
842   bool wait(kmp_info_t *this_thr,
843             int final_spin USE_ITT_BUILD_ARG(void *itt_sync_obj)) {
844     if (final_spin)
845       return __kmp_wait_template<kmp_flag_32, TRUE, Cancellable, Sleepable>(
846           this_thr, this USE_ITT_BUILD_ARG(itt_sync_obj));
847     else
848       return __kmp_wait_template<kmp_flag_32, FALSE, Cancellable, Sleepable>(
849           this_thr, this USE_ITT_BUILD_ARG(itt_sync_obj));
850   }
851   void release() { __kmp_release_template(this); }
852   flag_type get_ptr_type() { return flag32; }
853 };
854 
855 template <bool Cancellable, bool Sleepable>
856 class kmp_flag_64 : public kmp_flag_native<kmp_uint64, flag64, Sleepable> {
857 public:
858   kmp_flag_64(volatile kmp_uint64 *p)
859       : kmp_flag_native<kmp_uint64, flag64, Sleepable>(p) {}
860   kmp_flag_64(volatile kmp_uint64 *p, kmp_info_t *thr)
861       : kmp_flag_native<kmp_uint64, flag64, Sleepable>(p, thr) {}
862   kmp_flag_64(volatile kmp_uint64 *p, kmp_uint64 c)
863       : kmp_flag_native<kmp_uint64, flag64, Sleepable>(p, c) {}
864   kmp_flag_64(volatile kmp_uint64 *p, kmp_uint64 c, std::atomic<bool> *loc)
865       : kmp_flag_native<kmp_uint64, flag64, Sleepable>(p, c, loc) {}
866   void suspend(int th_gtid) { __kmp_suspend_64(th_gtid, this); }
867 #if KMP_HAVE_MWAIT || KMP_HAVE_UMWAIT
868   void mwait(int th_gtid) { __kmp_mwait_64(th_gtid, this); }
869 #endif
870   void resume(int th_gtid) { __kmp_resume_64(th_gtid, this); }
871   int execute_tasks(kmp_info_t *this_thr, kmp_int32 gtid, int final_spin,
872                     int *thread_finished USE_ITT_BUILD_ARG(void *itt_sync_obj),
873                     kmp_int32 is_constrained) {
874     return __kmp_execute_tasks_64(
875         this_thr, gtid, this, final_spin,
876         thread_finished USE_ITT_BUILD_ARG(itt_sync_obj), is_constrained);
877   }
878   bool wait(kmp_info_t *this_thr,
879             int final_spin USE_ITT_BUILD_ARG(void *itt_sync_obj)) {
880     if (final_spin)
881       return __kmp_wait_template<kmp_flag_64, TRUE, Cancellable, Sleepable>(
882           this_thr, this USE_ITT_BUILD_ARG(itt_sync_obj));
883     else
884       return __kmp_wait_template<kmp_flag_64, FALSE, Cancellable, Sleepable>(
885           this_thr, this USE_ITT_BUILD_ARG(itt_sync_obj));
886   }
887   void release() { __kmp_release_template(this); }
888   flag_type get_ptr_type() { return flag64; }
889 };
890 
891 template <bool Cancellable, bool Sleepable>
892 class kmp_atomic_flag_64
893     : public kmp_flag_atomic<kmp_uint64, atomic_flag64, Sleepable> {
894 public:
895   kmp_atomic_flag_64(std::atomic<kmp_uint64> *p)
896       : kmp_flag_atomic<kmp_uint64, atomic_flag64, Sleepable>(p) {}
897   kmp_atomic_flag_64(std::atomic<kmp_uint64> *p, kmp_info_t *thr)
898       : kmp_flag_atomic<kmp_uint64, atomic_flag64, Sleepable>(p, thr) {}
899   kmp_atomic_flag_64(std::atomic<kmp_uint64> *p, kmp_uint64 c)
900       : kmp_flag_atomic<kmp_uint64, atomic_flag64, Sleepable>(p, c) {}
901   kmp_atomic_flag_64(std::atomic<kmp_uint64> *p, kmp_uint64 c,
902                      std::atomic<bool> *loc)
903       : kmp_flag_atomic<kmp_uint64, atomic_flag64, Sleepable>(p, c, loc) {}
904   void suspend(int th_gtid) { __kmp_atomic_suspend_64(th_gtid, this); }
905   void mwait(int th_gtid) { __kmp_atomic_mwait_64(th_gtid, this); }
906   void resume(int th_gtid) { __kmp_atomic_resume_64(th_gtid, this); }
907   int execute_tasks(kmp_info_t *this_thr, kmp_int32 gtid, int final_spin,
908                     int *thread_finished USE_ITT_BUILD_ARG(void *itt_sync_obj),
909                     kmp_int32 is_constrained) {
910     return __kmp_atomic_execute_tasks_64(
911         this_thr, gtid, this, final_spin,
912         thread_finished USE_ITT_BUILD_ARG(itt_sync_obj), is_constrained);
913   }
914   bool wait(kmp_info_t *this_thr,
915             int final_spin USE_ITT_BUILD_ARG(void *itt_sync_obj)) {
916     if (final_spin)
917       return __kmp_wait_template<kmp_atomic_flag_64, TRUE, Cancellable,
918                                  Sleepable>(
919           this_thr, this USE_ITT_BUILD_ARG(itt_sync_obj));
920     else
921       return __kmp_wait_template<kmp_atomic_flag_64, FALSE, Cancellable,
922                                  Sleepable>(
923           this_thr, this USE_ITT_BUILD_ARG(itt_sync_obj));
924   }
925   void release() { __kmp_release_template(this); }
926   flag_type get_ptr_type() { return atomic_flag64; }
927 };
928 
929 // Hierarchical 64-bit on-core barrier instantiation
930 class kmp_flag_oncore : public kmp_flag_native<kmp_uint64, flag_oncore, false> {
931   kmp_uint32 offset; /**< Portion of flag of interest for an operation. */
932   bool flag_switch; /**< Indicates a switch in flag location. */
933   enum barrier_type bt; /**< Barrier type. */
934   kmp_info_t *this_thr; /**< Thread to redirect to different flag location. */
935 #if USE_ITT_BUILD
936   void *itt_sync_obj; /**< ITT object to pass to new flag location. */
937 #endif
938   unsigned char &byteref(volatile kmp_uint64 *loc, size_t offset) {
939     return (RCAST(unsigned char *, CCAST(kmp_uint64 *, loc)))[offset];
940   }
941 
942 public:
943   kmp_flag_oncore(volatile kmp_uint64 *p)
944       : kmp_flag_native<kmp_uint64, flag_oncore, false>(p), flag_switch(false) {
945   }
946   kmp_flag_oncore(volatile kmp_uint64 *p, kmp_uint32 idx)
947       : kmp_flag_native<kmp_uint64, flag_oncore, false>(p), offset(idx),
948         flag_switch(false),
949         bt(bs_last_barrier) USE_ITT_BUILD_ARG(itt_sync_obj(nullptr)) {}
950   kmp_flag_oncore(volatile kmp_uint64 *p, kmp_uint64 c, kmp_uint32 idx,
951                   enum barrier_type bar_t,
952                   kmp_info_t *thr USE_ITT_BUILD_ARG(void *itt))
953       : kmp_flag_native<kmp_uint64, flag_oncore, false>(p, c), offset(idx),
954         flag_switch(false), bt(bar_t),
955         this_thr(thr) USE_ITT_BUILD_ARG(itt_sync_obj(itt)) {}
956   virtual ~kmp_flag_oncore() override {}
957   void *operator new(size_t size) { return __kmp_allocate(size); }
958   void operator delete(void *p) { __kmp_free(p); }
959   bool done_check_val(kmp_uint64 old_loc) override {
960     return byteref(&old_loc, offset) == checker;
961   }
962   bool done_check() override { return done_check_val(*get()); }
963   bool notdone_check() override {
964     // Calculate flag_switch
965     if (this_thr->th.th_bar[bt].bb.wait_flag == KMP_BARRIER_SWITCH_TO_OWN_FLAG)
966       flag_switch = true;
967     if (byteref(get(), offset) != 1 && !flag_switch)
968       return true;
969     else if (flag_switch) {
970       this_thr->th.th_bar[bt].bb.wait_flag = KMP_BARRIER_SWITCHING;
971       kmp_flag_64<> flag(&this_thr->th.th_bar[bt].bb.b_go,
972                          (kmp_uint64)KMP_BARRIER_STATE_BUMP);
973       __kmp_wait_64(this_thr, &flag, TRUE USE_ITT_BUILD_ARG(itt_sync_obj));
974     }
975     return false;
976   }
977   void internal_release() {
978     // Other threads can write their own bytes simultaneously.
979     if (__kmp_dflt_blocktime == KMP_MAX_BLOCKTIME) {
980       byteref(get(), offset) = 1;
981     } else {
982       kmp_uint64 mask = 0;
983       byteref(&mask, offset) = 1;
984       KMP_TEST_THEN_OR64(get(), mask);
985     }
986   }
987   void wait(kmp_info_t *this_thr, int final_spin) {
988     if (final_spin)
989       __kmp_wait_template<kmp_flag_oncore, TRUE>(
990           this_thr, this USE_ITT_BUILD_ARG(itt_sync_obj));
991     else
992       __kmp_wait_template<kmp_flag_oncore, FALSE>(
993           this_thr, this USE_ITT_BUILD_ARG(itt_sync_obj));
994   }
995   void release() { __kmp_release_template(this); }
996   void suspend(int th_gtid) { __kmp_suspend_oncore(th_gtid, this); }
997 #if KMP_HAVE_MWAIT || KMP_HAVE_UMWAIT
998   void mwait(int th_gtid) { __kmp_mwait_oncore(th_gtid, this); }
999 #endif
1000   void resume(int th_gtid) { __kmp_resume_oncore(th_gtid, this); }
1001   int execute_tasks(kmp_info_t *this_thr, kmp_int32 gtid, int final_spin,
1002                     int *thread_finished USE_ITT_BUILD_ARG(void *itt_sync_obj),
1003                     kmp_int32 is_constrained) {
1004 #if OMPD_SUPPORT
1005     int ret = __kmp_execute_tasks_oncore(
1006         this_thr, gtid, this, final_spin,
1007         thread_finished USE_ITT_BUILD_ARG(itt_sync_obj), is_constrained);
1008     if (ompd_state & OMPD_ENABLE_BP)
1009       ompd_bp_task_end();
1010     return ret;
1011 #else
1012     return __kmp_execute_tasks_oncore(
1013         this_thr, gtid, this, final_spin,
1014         thread_finished USE_ITT_BUILD_ARG(itt_sync_obj), is_constrained);
1015 #endif
1016   }
1017   enum barrier_type get_bt() { return bt; }
1018   flag_type get_ptr_type() { return flag_oncore; }
1019 };
1020 
1021 static inline void __kmp_null_resume_wrapper(kmp_info_t *thr) {
1022   int gtid = __kmp_gtid_from_thread(thr);
1023   void *flag = CCAST(void *, thr->th.th_sleep_loc);
1024   flag_type type = thr->th.th_sleep_loc_type;
1025   if (!flag)
1026     return;
1027   // Attempt to wake up a thread: examine its type and call appropriate template
1028   switch (type) {
1029   case flag32:
1030     __kmp_resume_32(gtid, RCAST(kmp_flag_32<> *, flag));
1031     break;
1032   case flag64:
1033     __kmp_resume_64(gtid, RCAST(kmp_flag_64<> *, flag));
1034     break;
1035   case atomic_flag64:
1036     __kmp_atomic_resume_64(gtid, RCAST(kmp_atomic_flag_64<> *, flag));
1037     break;
1038   case flag_oncore:
1039     __kmp_resume_oncore(gtid, RCAST(kmp_flag_oncore *, flag));
1040     break;
1041 #ifdef KMP_DEBUG
1042   case flag_unset:
1043     KF_TRACE(100, ("__kmp_null_resume_wrapper: flag type %d is unset\n", type));
1044     break;
1045   default:
1046     KF_TRACE(100, ("__kmp_null_resume_wrapper: flag type %d does not match any "
1047                    "known flag type\n",
1048                    type));
1049 #endif
1050   }
1051 }
1052 
1053 /*!
1054 @}
1055 */
1056 
1057 #endif // KMP_WAIT_RELEASE_H
1058