1 /* 2 * kmp_tasking.cpp -- OpenMP 3.0 tasking support. 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 #include "kmp.h" 14 #include "kmp_i18n.h" 15 #include "kmp_itt.h" 16 #include "kmp_stats.h" 17 #include "kmp_wait_release.h" 18 #include "kmp_taskdeps.h" 19 20 #if OMPT_SUPPORT 21 #include "ompt-specific.h" 22 #endif 23 24 /* forward declaration */ 25 static void __kmp_enable_tasking(kmp_task_team_t *task_team, 26 kmp_info_t *this_thr); 27 static void __kmp_alloc_task_deque(kmp_info_t *thread, 28 kmp_thread_data_t *thread_data); 29 static int __kmp_realloc_task_threads_data(kmp_info_t *thread, 30 kmp_task_team_t *task_team); 31 static void __kmp_bottom_half_finish_proxy(kmp_int32 gtid, kmp_task_t *ptask); 32 33 #ifdef BUILD_TIED_TASK_STACK 34 35 // __kmp_trace_task_stack: print the tied tasks from the task stack in order 36 // from top do bottom 37 // 38 // gtid: global thread identifier for thread containing stack 39 // thread_data: thread data for task team thread containing stack 40 // threshold: value above which the trace statement triggers 41 // location: string identifying call site of this function (for trace) 42 static void __kmp_trace_task_stack(kmp_int32 gtid, 43 kmp_thread_data_t *thread_data, 44 int threshold, char *location) { 45 kmp_task_stack_t *task_stack = &thread_data->td.td_susp_tied_tasks; 46 kmp_taskdata_t **stack_top = task_stack->ts_top; 47 kmp_int32 entries = task_stack->ts_entries; 48 kmp_taskdata_t *tied_task; 49 50 KA_TRACE( 51 threshold, 52 ("__kmp_trace_task_stack(start): location = %s, gtid = %d, entries = %d, " 53 "first_block = %p, stack_top = %p \n", 54 location, gtid, entries, task_stack->ts_first_block, stack_top)); 55 56 KMP_DEBUG_ASSERT(stack_top != NULL); 57 KMP_DEBUG_ASSERT(entries > 0); 58 59 while (entries != 0) { 60 KMP_DEBUG_ASSERT(stack_top != &task_stack->ts_first_block.sb_block[0]); 61 // fix up ts_top if we need to pop from previous block 62 if (entries & TASK_STACK_INDEX_MASK == 0) { 63 kmp_stack_block_t *stack_block = (kmp_stack_block_t *)(stack_top); 64 65 stack_block = stack_block->sb_prev; 66 stack_top = &stack_block->sb_block[TASK_STACK_BLOCK_SIZE]; 67 } 68 69 // finish bookkeeping 70 stack_top--; 71 entries--; 72 73 tied_task = *stack_top; 74 75 KMP_DEBUG_ASSERT(tied_task != NULL); 76 KMP_DEBUG_ASSERT(tied_task->td_flags.tasktype == TASK_TIED); 77 78 KA_TRACE(threshold, 79 ("__kmp_trace_task_stack(%s): gtid=%d, entry=%d, " 80 "stack_top=%p, tied_task=%p\n", 81 location, gtid, entries, stack_top, tied_task)); 82 } 83 KMP_DEBUG_ASSERT(stack_top == &task_stack->ts_first_block.sb_block[0]); 84 85 KA_TRACE(threshold, 86 ("__kmp_trace_task_stack(exit): location = %s, gtid = %d\n", 87 location, gtid)); 88 } 89 90 // __kmp_init_task_stack: initialize the task stack for the first time 91 // after a thread_data structure is created. 92 // It should not be necessary to do this again (assuming the stack works). 93 // 94 // gtid: global thread identifier of calling thread 95 // thread_data: thread data for task team thread containing stack 96 static void __kmp_init_task_stack(kmp_int32 gtid, 97 kmp_thread_data_t *thread_data) { 98 kmp_task_stack_t *task_stack = &thread_data->td.td_susp_tied_tasks; 99 kmp_stack_block_t *first_block; 100 101 // set up the first block of the stack 102 first_block = &task_stack->ts_first_block; 103 task_stack->ts_top = (kmp_taskdata_t **)first_block; 104 memset((void *)first_block, '\0', 105 TASK_STACK_BLOCK_SIZE * sizeof(kmp_taskdata_t *)); 106 107 // initialize the stack to be empty 108 task_stack->ts_entries = TASK_STACK_EMPTY; 109 first_block->sb_next = NULL; 110 first_block->sb_prev = NULL; 111 } 112 113 // __kmp_free_task_stack: free the task stack when thread_data is destroyed. 114 // 115 // gtid: global thread identifier for calling thread 116 // thread_data: thread info for thread containing stack 117 static void __kmp_free_task_stack(kmp_int32 gtid, 118 kmp_thread_data_t *thread_data) { 119 kmp_task_stack_t *task_stack = &thread_data->td.td_susp_tied_tasks; 120 kmp_stack_block_t *stack_block = &task_stack->ts_first_block; 121 122 KMP_DEBUG_ASSERT(task_stack->ts_entries == TASK_STACK_EMPTY); 123 // free from the second block of the stack 124 while (stack_block != NULL) { 125 kmp_stack_block_t *next_block = (stack_block) ? stack_block->sb_next : NULL; 126 127 stack_block->sb_next = NULL; 128 stack_block->sb_prev = NULL; 129 if (stack_block != &task_stack->ts_first_block) { 130 __kmp_thread_free(thread, 131 stack_block); // free the block, if not the first 132 } 133 stack_block = next_block; 134 } 135 // initialize the stack to be empty 136 task_stack->ts_entries = 0; 137 task_stack->ts_top = NULL; 138 } 139 140 // __kmp_push_task_stack: Push the tied task onto the task stack. 141 // Grow the stack if necessary by allocating another block. 142 // 143 // gtid: global thread identifier for calling thread 144 // thread: thread info for thread containing stack 145 // tied_task: the task to push on the stack 146 static void __kmp_push_task_stack(kmp_int32 gtid, kmp_info_t *thread, 147 kmp_taskdata_t *tied_task) { 148 // GEH - need to consider what to do if tt_threads_data not allocated yet 149 kmp_thread_data_t *thread_data = 150 &thread->th.th_task_team->tt.tt_threads_data[__kmp_tid_from_gtid(gtid)]; 151 kmp_task_stack_t *task_stack = &thread_data->td.td_susp_tied_tasks; 152 153 if (tied_task->td_flags.team_serial || tied_task->td_flags.tasking_ser) { 154 return; // Don't push anything on stack if team or team tasks are serialized 155 } 156 157 KMP_DEBUG_ASSERT(tied_task->td_flags.tasktype == TASK_TIED); 158 KMP_DEBUG_ASSERT(task_stack->ts_top != NULL); 159 160 KA_TRACE(20, 161 ("__kmp_push_task_stack(enter): GTID: %d; THREAD: %p; TASK: %p\n", 162 gtid, thread, tied_task)); 163 // Store entry 164 *(task_stack->ts_top) = tied_task; 165 166 // Do bookkeeping for next push 167 task_stack->ts_top++; 168 task_stack->ts_entries++; 169 170 if (task_stack->ts_entries & TASK_STACK_INDEX_MASK == 0) { 171 // Find beginning of this task block 172 kmp_stack_block_t *stack_block = 173 (kmp_stack_block_t *)(task_stack->ts_top - TASK_STACK_BLOCK_SIZE); 174 175 // Check if we already have a block 176 if (stack_block->sb_next != 177 NULL) { // reset ts_top to beginning of next block 178 task_stack->ts_top = &stack_block->sb_next->sb_block[0]; 179 } else { // Alloc new block and link it up 180 kmp_stack_block_t *new_block = (kmp_stack_block_t *)__kmp_thread_calloc( 181 thread, sizeof(kmp_stack_block_t)); 182 183 task_stack->ts_top = &new_block->sb_block[0]; 184 stack_block->sb_next = new_block; 185 new_block->sb_prev = stack_block; 186 new_block->sb_next = NULL; 187 188 KA_TRACE( 189 30, 190 ("__kmp_push_task_stack(): GTID: %d; TASK: %p; Alloc new block: %p\n", 191 gtid, tied_task, new_block)); 192 } 193 } 194 KA_TRACE(20, ("__kmp_push_task_stack(exit): GTID: %d; TASK: %p\n", gtid, 195 tied_task)); 196 } 197 198 // __kmp_pop_task_stack: Pop the tied task from the task stack. Don't return 199 // the task, just check to make sure it matches the ending task passed in. 200 // 201 // gtid: global thread identifier for the calling thread 202 // thread: thread info structure containing stack 203 // tied_task: the task popped off the stack 204 // ending_task: the task that is ending (should match popped task) 205 static void __kmp_pop_task_stack(kmp_int32 gtid, kmp_info_t *thread, 206 kmp_taskdata_t *ending_task) { 207 // GEH - need to consider what to do if tt_threads_data not allocated yet 208 kmp_thread_data_t *thread_data = 209 &thread->th.th_task_team->tt_threads_data[__kmp_tid_from_gtid(gtid)]; 210 kmp_task_stack_t *task_stack = &thread_data->td.td_susp_tied_tasks; 211 kmp_taskdata_t *tied_task; 212 213 if (ending_task->td_flags.team_serial || ending_task->td_flags.tasking_ser) { 214 // Don't pop anything from stack if team or team tasks are serialized 215 return; 216 } 217 218 KMP_DEBUG_ASSERT(task_stack->ts_top != NULL); 219 KMP_DEBUG_ASSERT(task_stack->ts_entries > 0); 220 221 KA_TRACE(20, ("__kmp_pop_task_stack(enter): GTID: %d; THREAD: %p\n", gtid, 222 thread)); 223 224 // fix up ts_top if we need to pop from previous block 225 if (task_stack->ts_entries & TASK_STACK_INDEX_MASK == 0) { 226 kmp_stack_block_t *stack_block = (kmp_stack_block_t *)(task_stack->ts_top); 227 228 stack_block = stack_block->sb_prev; 229 task_stack->ts_top = &stack_block->sb_block[TASK_STACK_BLOCK_SIZE]; 230 } 231 232 // finish bookkeeping 233 task_stack->ts_top--; 234 task_stack->ts_entries--; 235 236 tied_task = *(task_stack->ts_top); 237 238 KMP_DEBUG_ASSERT(tied_task != NULL); 239 KMP_DEBUG_ASSERT(tied_task->td_flags.tasktype == TASK_TIED); 240 KMP_DEBUG_ASSERT(tied_task == ending_task); // If we built the stack correctly 241 242 KA_TRACE(20, ("__kmp_pop_task_stack(exit): GTID: %d; TASK: %p\n", gtid, 243 tied_task)); 244 return; 245 } 246 #endif /* BUILD_TIED_TASK_STACK */ 247 248 // returns 1 if new task is allowed to execute, 0 otherwise 249 // checks Task Scheduling constraint (if requested) and 250 // mutexinoutset dependencies if any 251 static bool __kmp_task_is_allowed(int gtid, const kmp_int32 is_constrained, 252 const kmp_taskdata_t *tasknew, 253 const kmp_taskdata_t *taskcurr) { 254 if (is_constrained && (tasknew->td_flags.tiedness == TASK_TIED)) { 255 // Check if the candidate obeys the Task Scheduling Constraints (TSC) 256 // only descendant of all deferred tied tasks can be scheduled, checking 257 // the last one is enough, as it in turn is the descendant of all others 258 kmp_taskdata_t *current = taskcurr->td_last_tied; 259 KMP_DEBUG_ASSERT(current != NULL); 260 // check if the task is not suspended on barrier 261 if (current->td_flags.tasktype == TASK_EXPLICIT || 262 current->td_taskwait_thread > 0) { // <= 0 on barrier 263 kmp_int32 level = current->td_level; 264 kmp_taskdata_t *parent = tasknew->td_parent; 265 while (parent != current && parent->td_level > level) { 266 // check generation up to the level of the current task 267 parent = parent->td_parent; 268 KMP_DEBUG_ASSERT(parent != NULL); 269 } 270 if (parent != current) 271 return false; 272 } 273 } 274 // Check mutexinoutset dependencies, acquire locks 275 kmp_depnode_t *node = tasknew->td_depnode; 276 if (UNLIKELY(node && (node->dn.mtx_num_locks > 0))) { 277 for (int i = 0; i < node->dn.mtx_num_locks; ++i) { 278 KMP_DEBUG_ASSERT(node->dn.mtx_locks[i] != NULL); 279 if (__kmp_test_lock(node->dn.mtx_locks[i], gtid)) 280 continue; 281 // could not get the lock, release previous locks 282 for (int j = i - 1; j >= 0; --j) 283 __kmp_release_lock(node->dn.mtx_locks[j], gtid); 284 return false; 285 } 286 // negative num_locks means all locks acquired successfully 287 node->dn.mtx_num_locks = -node->dn.mtx_num_locks; 288 } 289 return true; 290 } 291 292 // __kmp_realloc_task_deque: 293 // Re-allocates a task deque for a particular thread, copies the content from 294 // the old deque and adjusts the necessary data structures relating to the 295 // deque. This operation must be done with the deque_lock being held 296 static void __kmp_realloc_task_deque(kmp_info_t *thread, 297 kmp_thread_data_t *thread_data) { 298 kmp_int32 size = TASK_DEQUE_SIZE(thread_data->td); 299 KMP_DEBUG_ASSERT(TCR_4(thread_data->td.td_deque_ntasks) == size); 300 kmp_int32 new_size = 2 * size; 301 302 KE_TRACE(10, ("__kmp_realloc_task_deque: T#%d reallocating deque[from %d to " 303 "%d] for thread_data %p\n", 304 __kmp_gtid_from_thread(thread), size, new_size, thread_data)); 305 306 kmp_taskdata_t **new_deque = 307 (kmp_taskdata_t **)__kmp_allocate(new_size * sizeof(kmp_taskdata_t *)); 308 309 int i, j; 310 for (i = thread_data->td.td_deque_head, j = 0; j < size; 311 i = (i + 1) & TASK_DEQUE_MASK(thread_data->td), j++) 312 new_deque[j] = thread_data->td.td_deque[i]; 313 314 __kmp_free(thread_data->td.td_deque); 315 316 thread_data->td.td_deque_head = 0; 317 thread_data->td.td_deque_tail = size; 318 thread_data->td.td_deque = new_deque; 319 thread_data->td.td_deque_size = new_size; 320 } 321 322 // __kmp_push_task: Add a task to the thread's deque 323 static kmp_int32 __kmp_push_task(kmp_int32 gtid, kmp_task_t *task) { 324 kmp_info_t *thread = __kmp_threads[gtid]; 325 kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(task); 326 327 // We don't need to map to shadow gtid if it is already hidden helper thread 328 if (taskdata->td_flags.hidden_helper && !KMP_HIDDEN_HELPER_THREAD(gtid)) { 329 gtid = KMP_GTID_TO_SHADOW_GTID(gtid); 330 thread = __kmp_threads[gtid]; 331 } 332 333 kmp_task_team_t *task_team = thread->th.th_task_team; 334 kmp_int32 tid = __kmp_tid_from_gtid(gtid); 335 kmp_thread_data_t *thread_data; 336 337 KA_TRACE(20, 338 ("__kmp_push_task: T#%d trying to push task %p.\n", gtid, taskdata)); 339 340 if (UNLIKELY(taskdata->td_flags.tiedness == TASK_UNTIED)) { 341 // untied task needs to increment counter so that the task structure is not 342 // freed prematurely 343 kmp_int32 counter = 1 + KMP_ATOMIC_INC(&taskdata->td_untied_count); 344 KMP_DEBUG_USE_VAR(counter); 345 KA_TRACE( 346 20, 347 ("__kmp_push_task: T#%d untied_count (%d) incremented for task %p\n", 348 gtid, counter, taskdata)); 349 } 350 351 // The first check avoids building task_team thread data if serialized 352 if (UNLIKELY(taskdata->td_flags.task_serial)) { 353 KA_TRACE(20, ("__kmp_push_task: T#%d team serialized; returning " 354 "TASK_NOT_PUSHED for task %p\n", 355 gtid, taskdata)); 356 return TASK_NOT_PUSHED; 357 } 358 359 // Now that serialized tasks have returned, we can assume that we are not in 360 // immediate exec mode 361 KMP_DEBUG_ASSERT(__kmp_tasking_mode != tskm_immediate_exec); 362 if (UNLIKELY(!KMP_TASKING_ENABLED(task_team))) { 363 __kmp_enable_tasking(task_team, thread); 364 } 365 KMP_DEBUG_ASSERT(TCR_4(task_team->tt.tt_found_tasks) == TRUE); 366 KMP_DEBUG_ASSERT(TCR_PTR(task_team->tt.tt_threads_data) != NULL); 367 368 // Find tasking deque specific to encountering thread 369 thread_data = &task_team->tt.tt_threads_data[tid]; 370 371 // No lock needed since only owner can allocate. If the task is hidden_helper, 372 // we don't need it either because we have initialized the dequeue for hidden 373 // helper thread data. 374 if (UNLIKELY(thread_data->td.td_deque == NULL)) { 375 __kmp_alloc_task_deque(thread, thread_data); 376 } 377 378 int locked = 0; 379 // Check if deque is full 380 if (TCR_4(thread_data->td.td_deque_ntasks) >= 381 TASK_DEQUE_SIZE(thread_data->td)) { 382 if (__kmp_enable_task_throttling && 383 __kmp_task_is_allowed(gtid, __kmp_task_stealing_constraint, taskdata, 384 thread->th.th_current_task)) { 385 KA_TRACE(20, ("__kmp_push_task: T#%d deque is full; returning " 386 "TASK_NOT_PUSHED for task %p\n", 387 gtid, taskdata)); 388 return TASK_NOT_PUSHED; 389 } else { 390 __kmp_acquire_bootstrap_lock(&thread_data->td.td_deque_lock); 391 locked = 1; 392 if (TCR_4(thread_data->td.td_deque_ntasks) >= 393 TASK_DEQUE_SIZE(thread_data->td)) { 394 // expand deque to push the task which is not allowed to execute 395 __kmp_realloc_task_deque(thread, thread_data); 396 } 397 } 398 } 399 // Lock the deque for the task push operation 400 if (!locked) { 401 __kmp_acquire_bootstrap_lock(&thread_data->td.td_deque_lock); 402 // Need to recheck as we can get a proxy task from thread outside of OpenMP 403 if (TCR_4(thread_data->td.td_deque_ntasks) >= 404 TASK_DEQUE_SIZE(thread_data->td)) { 405 if (__kmp_enable_task_throttling && 406 __kmp_task_is_allowed(gtid, __kmp_task_stealing_constraint, taskdata, 407 thread->th.th_current_task)) { 408 __kmp_release_bootstrap_lock(&thread_data->td.td_deque_lock); 409 KA_TRACE(20, ("__kmp_push_task: T#%d deque is full on 2nd check; " 410 "returning TASK_NOT_PUSHED for task %p\n", 411 gtid, taskdata)); 412 return TASK_NOT_PUSHED; 413 } else { 414 // expand deque to push the task which is not allowed to execute 415 __kmp_realloc_task_deque(thread, thread_data); 416 } 417 } 418 } 419 // Must have room since no thread can add tasks but calling thread 420 KMP_DEBUG_ASSERT(TCR_4(thread_data->td.td_deque_ntasks) < 421 TASK_DEQUE_SIZE(thread_data->td)); 422 423 thread_data->td.td_deque[thread_data->td.td_deque_tail] = 424 taskdata; // Push taskdata 425 // Wrap index. 426 thread_data->td.td_deque_tail = 427 (thread_data->td.td_deque_tail + 1) & TASK_DEQUE_MASK(thread_data->td); 428 TCW_4(thread_data->td.td_deque_ntasks, 429 TCR_4(thread_data->td.td_deque_ntasks) + 1); // Adjust task count 430 KMP_FSYNC_RELEASING(thread->th.th_current_task); // releasing self 431 KMP_FSYNC_RELEASING(taskdata); // releasing child 432 KA_TRACE(20, ("__kmp_push_task: T#%d returning TASK_SUCCESSFULLY_PUSHED: " 433 "task=%p ntasks=%d head=%u tail=%u\n", 434 gtid, taskdata, thread_data->td.td_deque_ntasks, 435 thread_data->td.td_deque_head, thread_data->td.td_deque_tail)); 436 437 auto hidden_helper = taskdata->td_flags.hidden_helper; 438 439 __kmp_release_bootstrap_lock(&thread_data->td.td_deque_lock); 440 441 // Signal one worker thread to execute the task 442 if (UNLIKELY(hidden_helper)) { 443 // Wake hidden helper threads up if they're sleeping 444 __kmp_hidden_helper_worker_thread_signal(); 445 } 446 447 return TASK_SUCCESSFULLY_PUSHED; 448 } 449 450 // __kmp_pop_current_task_from_thread: set up current task from called thread 451 // when team ends 452 // 453 // this_thr: thread structure to set current_task in. 454 void __kmp_pop_current_task_from_thread(kmp_info_t *this_thr) { 455 KF_TRACE(10, ("__kmp_pop_current_task_from_thread(enter): T#%d " 456 "this_thread=%p, curtask=%p, " 457 "curtask_parent=%p\n", 458 0, this_thr, this_thr->th.th_current_task, 459 this_thr->th.th_current_task->td_parent)); 460 461 this_thr->th.th_current_task = this_thr->th.th_current_task->td_parent; 462 463 KF_TRACE(10, ("__kmp_pop_current_task_from_thread(exit): T#%d " 464 "this_thread=%p, curtask=%p, " 465 "curtask_parent=%p\n", 466 0, this_thr, this_thr->th.th_current_task, 467 this_thr->th.th_current_task->td_parent)); 468 } 469 470 // __kmp_push_current_task_to_thread: set up current task in called thread for a 471 // new team 472 // 473 // this_thr: thread structure to set up 474 // team: team for implicit task data 475 // tid: thread within team to set up 476 void __kmp_push_current_task_to_thread(kmp_info_t *this_thr, kmp_team_t *team, 477 int tid) { 478 // current task of the thread is a parent of the new just created implicit 479 // tasks of new team 480 KF_TRACE(10, ("__kmp_push_current_task_to_thread(enter): T#%d this_thread=%p " 481 "curtask=%p " 482 "parent_task=%p\n", 483 tid, this_thr, this_thr->th.th_current_task, 484 team->t.t_implicit_task_taskdata[tid].td_parent)); 485 486 KMP_DEBUG_ASSERT(this_thr != NULL); 487 488 if (tid == 0) { 489 if (this_thr->th.th_current_task != &team->t.t_implicit_task_taskdata[0]) { 490 team->t.t_implicit_task_taskdata[0].td_parent = 491 this_thr->th.th_current_task; 492 this_thr->th.th_current_task = &team->t.t_implicit_task_taskdata[0]; 493 } 494 } else { 495 team->t.t_implicit_task_taskdata[tid].td_parent = 496 team->t.t_implicit_task_taskdata[0].td_parent; 497 this_thr->th.th_current_task = &team->t.t_implicit_task_taskdata[tid]; 498 } 499 500 KF_TRACE(10, ("__kmp_push_current_task_to_thread(exit): T#%d this_thread=%p " 501 "curtask=%p " 502 "parent_task=%p\n", 503 tid, this_thr, this_thr->th.th_current_task, 504 team->t.t_implicit_task_taskdata[tid].td_parent)); 505 } 506 507 // __kmp_task_start: bookkeeping for a task starting execution 508 // 509 // GTID: global thread id of calling thread 510 // task: task starting execution 511 // current_task: task suspending 512 static void __kmp_task_start(kmp_int32 gtid, kmp_task_t *task, 513 kmp_taskdata_t *current_task) { 514 kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(task); 515 kmp_info_t *thread = __kmp_threads[gtid]; 516 517 KA_TRACE(10, 518 ("__kmp_task_start(enter): T#%d starting task %p: current_task=%p\n", 519 gtid, taskdata, current_task)); 520 521 KMP_DEBUG_ASSERT(taskdata->td_flags.tasktype == TASK_EXPLICIT); 522 523 // mark currently executing task as suspended 524 // TODO: GEH - make sure root team implicit task is initialized properly. 525 // KMP_DEBUG_ASSERT( current_task -> td_flags.executing == 1 ); 526 current_task->td_flags.executing = 0; 527 528 // Add task to stack if tied 529 #ifdef BUILD_TIED_TASK_STACK 530 if (taskdata->td_flags.tiedness == TASK_TIED) { 531 __kmp_push_task_stack(gtid, thread, taskdata); 532 } 533 #endif /* BUILD_TIED_TASK_STACK */ 534 535 // mark starting task as executing and as current task 536 thread->th.th_current_task = taskdata; 537 538 KMP_DEBUG_ASSERT(taskdata->td_flags.started == 0 || 539 taskdata->td_flags.tiedness == TASK_UNTIED); 540 KMP_DEBUG_ASSERT(taskdata->td_flags.executing == 0 || 541 taskdata->td_flags.tiedness == TASK_UNTIED); 542 taskdata->td_flags.started = 1; 543 taskdata->td_flags.executing = 1; 544 KMP_DEBUG_ASSERT(taskdata->td_flags.complete == 0); 545 KMP_DEBUG_ASSERT(taskdata->td_flags.freed == 0); 546 547 // GEH TODO: shouldn't we pass some sort of location identifier here? 548 // APT: yes, we will pass location here. 549 // need to store current thread state (in a thread or taskdata structure) 550 // before setting work_state, otherwise wrong state is set after end of task 551 552 KA_TRACE(10, ("__kmp_task_start(exit): T#%d task=%p\n", gtid, taskdata)); 553 554 return; 555 } 556 557 #if OMPT_SUPPORT 558 //------------------------------------------------------------------------------ 559 // __ompt_task_init: 560 // Initialize OMPT fields maintained by a task. This will only be called after 561 // ompt_start_tool, so we already know whether ompt is enabled or not. 562 563 static inline void __ompt_task_init(kmp_taskdata_t *task, int tid) { 564 // The calls to __ompt_task_init already have the ompt_enabled condition. 565 task->ompt_task_info.task_data.value = 0; 566 task->ompt_task_info.frame.exit_frame = ompt_data_none; 567 task->ompt_task_info.frame.enter_frame = ompt_data_none; 568 task->ompt_task_info.frame.exit_frame_flags = 569 ompt_frame_runtime | ompt_frame_framepointer; 570 task->ompt_task_info.frame.enter_frame_flags = 571 ompt_frame_runtime | ompt_frame_framepointer; 572 } 573 574 // __ompt_task_start: 575 // Build and trigger task-begin event 576 static inline void __ompt_task_start(kmp_task_t *task, 577 kmp_taskdata_t *current_task, 578 kmp_int32 gtid) { 579 kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(task); 580 ompt_task_status_t status = ompt_task_switch; 581 if (__kmp_threads[gtid]->th.ompt_thread_info.ompt_task_yielded) { 582 status = ompt_task_yield; 583 __kmp_threads[gtid]->th.ompt_thread_info.ompt_task_yielded = 0; 584 } 585 /* let OMPT know that we're about to run this task */ 586 if (ompt_enabled.ompt_callback_task_schedule) { 587 ompt_callbacks.ompt_callback(ompt_callback_task_schedule)( 588 &(current_task->ompt_task_info.task_data), status, 589 &(taskdata->ompt_task_info.task_data)); 590 } 591 taskdata->ompt_task_info.scheduling_parent = current_task; 592 } 593 594 // __ompt_task_finish: 595 // Build and trigger final task-schedule event 596 static inline void __ompt_task_finish(kmp_task_t *task, 597 kmp_taskdata_t *resumed_task, 598 ompt_task_status_t status) { 599 if (ompt_enabled.ompt_callback_task_schedule) { 600 kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(task); 601 if (__kmp_omp_cancellation && taskdata->td_taskgroup && 602 taskdata->td_taskgroup->cancel_request == cancel_taskgroup) { 603 status = ompt_task_cancel; 604 } 605 606 /* let OMPT know that we're returning to the callee task */ 607 ompt_callbacks.ompt_callback(ompt_callback_task_schedule)( 608 &(taskdata->ompt_task_info.task_data), status, 609 (resumed_task ? &(resumed_task->ompt_task_info.task_data) : NULL)); 610 } 611 } 612 #endif 613 614 template <bool ompt> 615 static void __kmpc_omp_task_begin_if0_template(ident_t *loc_ref, kmp_int32 gtid, 616 kmp_task_t *task, 617 void *frame_address, 618 void *return_address) { 619 kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(task); 620 kmp_taskdata_t *current_task = __kmp_threads[gtid]->th.th_current_task; 621 622 KA_TRACE(10, ("__kmpc_omp_task_begin_if0(enter): T#%d loc=%p task=%p " 623 "current_task=%p\n", 624 gtid, loc_ref, taskdata, current_task)); 625 626 if (UNLIKELY(taskdata->td_flags.tiedness == TASK_UNTIED)) { 627 // untied task needs to increment counter so that the task structure is not 628 // freed prematurely 629 kmp_int32 counter = 1 + KMP_ATOMIC_INC(&taskdata->td_untied_count); 630 KMP_DEBUG_USE_VAR(counter); 631 KA_TRACE(20, ("__kmpc_omp_task_begin_if0: T#%d untied_count (%d) " 632 "incremented for task %p\n", 633 gtid, counter, taskdata)); 634 } 635 636 taskdata->td_flags.task_serial = 637 1; // Execute this task immediately, not deferred. 638 __kmp_task_start(gtid, task, current_task); 639 640 #if OMPT_SUPPORT 641 if (ompt) { 642 if (current_task->ompt_task_info.frame.enter_frame.ptr == NULL) { 643 current_task->ompt_task_info.frame.enter_frame.ptr = 644 taskdata->ompt_task_info.frame.exit_frame.ptr = frame_address; 645 current_task->ompt_task_info.frame.enter_frame_flags = 646 taskdata->ompt_task_info.frame.exit_frame_flags = 647 ompt_frame_application | ompt_frame_framepointer; 648 } 649 if (ompt_enabled.ompt_callback_task_create) { 650 ompt_task_info_t *parent_info = &(current_task->ompt_task_info); 651 ompt_callbacks.ompt_callback(ompt_callback_task_create)( 652 &(parent_info->task_data), &(parent_info->frame), 653 &(taskdata->ompt_task_info.task_data), 654 ompt_task_explicit | TASK_TYPE_DETAILS_FORMAT(taskdata), 0, 655 return_address); 656 } 657 __ompt_task_start(task, current_task, gtid); 658 } 659 #endif // OMPT_SUPPORT 660 661 KA_TRACE(10, ("__kmpc_omp_task_begin_if0(exit): T#%d loc=%p task=%p,\n", gtid, 662 loc_ref, taskdata)); 663 } 664 665 #if OMPT_SUPPORT 666 OMPT_NOINLINE 667 static void __kmpc_omp_task_begin_if0_ompt(ident_t *loc_ref, kmp_int32 gtid, 668 kmp_task_t *task, 669 void *frame_address, 670 void *return_address) { 671 __kmpc_omp_task_begin_if0_template<true>(loc_ref, gtid, task, frame_address, 672 return_address); 673 } 674 #endif // OMPT_SUPPORT 675 676 // __kmpc_omp_task_begin_if0: report that a given serialized task has started 677 // execution 678 // 679 // loc_ref: source location information; points to beginning of task block. 680 // gtid: global thread number. 681 // task: task thunk for the started task. 682 void __kmpc_omp_task_begin_if0(ident_t *loc_ref, kmp_int32 gtid, 683 kmp_task_t *task) { 684 #if OMPT_SUPPORT 685 if (UNLIKELY(ompt_enabled.enabled)) { 686 OMPT_STORE_RETURN_ADDRESS(gtid); 687 __kmpc_omp_task_begin_if0_ompt(loc_ref, gtid, task, 688 OMPT_GET_FRAME_ADDRESS(1), 689 OMPT_LOAD_RETURN_ADDRESS(gtid)); 690 return; 691 } 692 #endif 693 __kmpc_omp_task_begin_if0_template<false>(loc_ref, gtid, task, NULL, NULL); 694 } 695 696 #ifdef TASK_UNUSED 697 // __kmpc_omp_task_begin: report that a given task has started execution 698 // NEVER GENERATED BY COMPILER, DEPRECATED!!! 699 void __kmpc_omp_task_begin(ident_t *loc_ref, kmp_int32 gtid, kmp_task_t *task) { 700 kmp_taskdata_t *current_task = __kmp_threads[gtid]->th.th_current_task; 701 702 KA_TRACE( 703 10, 704 ("__kmpc_omp_task_begin(enter): T#%d loc=%p task=%p current_task=%p\n", 705 gtid, loc_ref, KMP_TASK_TO_TASKDATA(task), current_task)); 706 707 __kmp_task_start(gtid, task, current_task); 708 709 KA_TRACE(10, ("__kmpc_omp_task_begin(exit): T#%d loc=%p task=%p,\n", gtid, 710 loc_ref, KMP_TASK_TO_TASKDATA(task))); 711 return; 712 } 713 #endif // TASK_UNUSED 714 715 // __kmp_free_task: free the current task space and the space for shareds 716 // 717 // gtid: Global thread ID of calling thread 718 // taskdata: task to free 719 // thread: thread data structure of caller 720 static void __kmp_free_task(kmp_int32 gtid, kmp_taskdata_t *taskdata, 721 kmp_info_t *thread) { 722 KA_TRACE(30, ("__kmp_free_task: T#%d freeing data from task %p\n", gtid, 723 taskdata)); 724 725 // Check to make sure all flags and counters have the correct values 726 KMP_DEBUG_ASSERT(taskdata->td_flags.tasktype == TASK_EXPLICIT); 727 KMP_DEBUG_ASSERT(taskdata->td_flags.executing == 0); 728 KMP_DEBUG_ASSERT(taskdata->td_flags.complete == 1); 729 KMP_DEBUG_ASSERT(taskdata->td_flags.freed == 0); 730 KMP_DEBUG_ASSERT(taskdata->td_allocated_child_tasks == 0 || 731 taskdata->td_flags.task_serial == 1); 732 KMP_DEBUG_ASSERT(taskdata->td_incomplete_child_tasks == 0); 733 734 taskdata->td_flags.freed = 1; 735 // deallocate the taskdata and shared variable blocks associated with this task 736 #if USE_FAST_MEMORY 737 __kmp_fast_free(thread, taskdata); 738 #else /* ! USE_FAST_MEMORY */ 739 __kmp_thread_free(thread, taskdata); 740 #endif 741 KA_TRACE(20, ("__kmp_free_task: T#%d freed task %p\n", gtid, taskdata)); 742 } 743 744 // __kmp_free_task_and_ancestors: free the current task and ancestors without 745 // children 746 // 747 // gtid: Global thread ID of calling thread 748 // taskdata: task to free 749 // thread: thread data structure of caller 750 static void __kmp_free_task_and_ancestors(kmp_int32 gtid, 751 kmp_taskdata_t *taskdata, 752 kmp_info_t *thread) { 753 // Proxy tasks must always be allowed to free their parents 754 // because they can be run in background even in serial mode. 755 kmp_int32 team_serial = 756 (taskdata->td_flags.team_serial || taskdata->td_flags.tasking_ser) && 757 !taskdata->td_flags.proxy; 758 KMP_DEBUG_ASSERT(taskdata->td_flags.tasktype == TASK_EXPLICIT); 759 760 kmp_int32 children = KMP_ATOMIC_DEC(&taskdata->td_allocated_child_tasks) - 1; 761 KMP_DEBUG_ASSERT(children >= 0); 762 763 // Now, go up the ancestor tree to see if any ancestors can now be freed. 764 while (children == 0) { 765 kmp_taskdata_t *parent_taskdata = taskdata->td_parent; 766 767 KA_TRACE(20, ("__kmp_free_task_and_ancestors(enter): T#%d task %p complete " 768 "and freeing itself\n", 769 gtid, taskdata)); 770 771 // --- Deallocate my ancestor task --- 772 __kmp_free_task(gtid, taskdata, thread); 773 774 taskdata = parent_taskdata; 775 776 if (team_serial) 777 return; 778 // Stop checking ancestors at implicit task instead of walking up ancestor 779 // tree to avoid premature deallocation of ancestors. 780 if (taskdata->td_flags.tasktype == TASK_IMPLICIT) { 781 if (taskdata->td_dephash) { // do we need to cleanup dephash? 782 int children = KMP_ATOMIC_LD_ACQ(&taskdata->td_incomplete_child_tasks); 783 kmp_tasking_flags_t flags_old = taskdata->td_flags; 784 if (children == 0 && flags_old.complete == 1) { 785 kmp_tasking_flags_t flags_new = flags_old; 786 flags_new.complete = 0; 787 if (KMP_COMPARE_AND_STORE_ACQ32( 788 RCAST(kmp_int32 *, &taskdata->td_flags), 789 *RCAST(kmp_int32 *, &flags_old), 790 *RCAST(kmp_int32 *, &flags_new))) { 791 KA_TRACE(100, ("__kmp_free_task_and_ancestors: T#%d cleans " 792 "dephash of implicit task %p\n", 793 gtid, taskdata)); 794 // cleanup dephash of finished implicit task 795 __kmp_dephash_free_entries(thread, taskdata->td_dephash); 796 } 797 } 798 } 799 return; 800 } 801 // Predecrement simulated by "- 1" calculation 802 children = KMP_ATOMIC_DEC(&taskdata->td_allocated_child_tasks) - 1; 803 KMP_DEBUG_ASSERT(children >= 0); 804 } 805 806 KA_TRACE( 807 20, ("__kmp_free_task_and_ancestors(exit): T#%d task %p has %d children; " 808 "not freeing it yet\n", 809 gtid, taskdata, children)); 810 } 811 812 // __kmp_task_finish: bookkeeping to do when a task finishes execution 813 // 814 // gtid: global thread ID for calling thread 815 // task: task to be finished 816 // resumed_task: task to be resumed. (may be NULL if task is serialized) 817 // 818 // template<ompt>: effectively ompt_enabled.enabled!=0 819 // the version with ompt=false is inlined, allowing to optimize away all ompt 820 // code in this case 821 template <bool ompt> 822 static void __kmp_task_finish(kmp_int32 gtid, kmp_task_t *task, 823 kmp_taskdata_t *resumed_task) { 824 kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(task); 825 kmp_info_t *thread = __kmp_threads[gtid]; 826 kmp_task_team_t *task_team = 827 thread->th.th_task_team; // might be NULL for serial teams... 828 kmp_int32 children = 0; 829 830 KA_TRACE(10, ("__kmp_task_finish(enter): T#%d finishing task %p and resuming " 831 "task %p\n", 832 gtid, taskdata, resumed_task)); 833 834 KMP_DEBUG_ASSERT(taskdata->td_flags.tasktype == TASK_EXPLICIT); 835 836 // Pop task from stack if tied 837 #ifdef BUILD_TIED_TASK_STACK 838 if (taskdata->td_flags.tiedness == TASK_TIED) { 839 __kmp_pop_task_stack(gtid, thread, taskdata); 840 } 841 #endif /* BUILD_TIED_TASK_STACK */ 842 843 if (UNLIKELY(taskdata->td_flags.tiedness == TASK_UNTIED)) { 844 // untied task needs to check the counter so that the task structure is not 845 // freed prematurely 846 kmp_int32 counter = KMP_ATOMIC_DEC(&taskdata->td_untied_count) - 1; 847 KA_TRACE( 848 20, 849 ("__kmp_task_finish: T#%d untied_count (%d) decremented for task %p\n", 850 gtid, counter, taskdata)); 851 if (counter > 0) { 852 // untied task is not done, to be continued possibly by other thread, do 853 // not free it now 854 if (resumed_task == NULL) { 855 KMP_DEBUG_ASSERT(taskdata->td_flags.task_serial); 856 resumed_task = taskdata->td_parent; // In a serialized task, the resumed 857 // task is the parent 858 } 859 thread->th.th_current_task = resumed_task; // restore current_task 860 resumed_task->td_flags.executing = 1; // resume previous task 861 KA_TRACE(10, ("__kmp_task_finish(exit): T#%d partially done task %p, " 862 "resuming task %p\n", 863 gtid, taskdata, resumed_task)); 864 return; 865 } 866 } 867 868 // bookkeeping for resuming task: 869 // GEH - note tasking_ser => task_serial 870 KMP_DEBUG_ASSERT( 871 (taskdata->td_flags.tasking_ser || taskdata->td_flags.task_serial) == 872 taskdata->td_flags.task_serial); 873 if (taskdata->td_flags.task_serial) { 874 if (resumed_task == NULL) { 875 resumed_task = taskdata->td_parent; // In a serialized task, the resumed 876 // task is the parent 877 } 878 } else { 879 KMP_DEBUG_ASSERT(resumed_task != 880 NULL); // verify that resumed task is passed as argument 881 } 882 883 /* If the tasks' destructor thunk flag has been set, we need to invoke the 884 destructor thunk that has been generated by the compiler. The code is 885 placed here, since at this point other tasks might have been released 886 hence overlapping the destructor invocations with some other work in the 887 released tasks. The OpenMP spec is not specific on when the destructors 888 are invoked, so we should be free to choose. */ 889 if (UNLIKELY(taskdata->td_flags.destructors_thunk)) { 890 kmp_routine_entry_t destr_thunk = task->data1.destructors; 891 KMP_ASSERT(destr_thunk); 892 destr_thunk(gtid, task); 893 } 894 895 KMP_DEBUG_ASSERT(taskdata->td_flags.complete == 0); 896 KMP_DEBUG_ASSERT(taskdata->td_flags.started == 1); 897 KMP_DEBUG_ASSERT(taskdata->td_flags.freed == 0); 898 899 bool detach = false; 900 if (UNLIKELY(taskdata->td_flags.detachable == TASK_DETACHABLE)) { 901 if (taskdata->td_allow_completion_event.type == 902 KMP_EVENT_ALLOW_COMPLETION) { 903 // event hasn't been fulfilled yet. Try to detach task. 904 __kmp_acquire_tas_lock(&taskdata->td_allow_completion_event.lock, gtid); 905 if (taskdata->td_allow_completion_event.type == 906 KMP_EVENT_ALLOW_COMPLETION) { 907 // task finished execution 908 KMP_DEBUG_ASSERT(taskdata->td_flags.executing == 1); 909 taskdata->td_flags.executing = 0; // suspend the finishing task 910 911 #if OMPT_SUPPORT 912 // For a detached task, which is not completed, we switch back 913 // the omp_fulfill_event signals completion 914 // locking is necessary to avoid a race with ompt_task_late_fulfill 915 if (ompt) 916 __ompt_task_finish(task, resumed_task, ompt_task_detach); 917 #endif 918 919 // no access to taskdata after this point! 920 // __kmp_fulfill_event might free taskdata at any time from now 921 922 taskdata->td_flags.proxy = TASK_PROXY; // proxify! 923 detach = true; 924 } 925 __kmp_release_tas_lock(&taskdata->td_allow_completion_event.lock, gtid); 926 } 927 } 928 929 if (!detach) { 930 taskdata->td_flags.complete = 1; // mark the task as completed 931 932 #if OMPT_SUPPORT 933 // This is not a detached task, we are done here 934 if (ompt) 935 __ompt_task_finish(task, resumed_task, ompt_task_complete); 936 #endif 937 938 // Only need to keep track of count if team parallel and tasking not 939 // serialized, or task is detachable and event has already been fulfilled 940 if (!(taskdata->td_flags.team_serial || taskdata->td_flags.tasking_ser) || 941 taskdata->td_flags.detachable == TASK_DETACHABLE || 942 taskdata->td_flags.hidden_helper) { 943 __kmp_release_deps(gtid, taskdata); 944 // Predecrement simulated by "- 1" calculation 945 children = 946 KMP_ATOMIC_DEC(&taskdata->td_parent->td_incomplete_child_tasks) - 1; 947 KMP_DEBUG_ASSERT(children >= 0); 948 if (taskdata->td_taskgroup) 949 KMP_ATOMIC_DEC(&taskdata->td_taskgroup->count); 950 } else if (task_team && (task_team->tt.tt_found_proxy_tasks || 951 task_team->tt.tt_hidden_helper_task_encountered)) { 952 // if we found proxy or hidden helper tasks there could exist a dependency 953 // chain with the proxy task as origin 954 __kmp_release_deps(gtid, taskdata); 955 } 956 // td_flags.executing must be marked as 0 after __kmp_release_deps has been 957 // called. Othertwise, if a task is executed immediately from the 958 // release_deps code, the flag will be reset to 1 again by this same 959 // function 960 KMP_DEBUG_ASSERT(taskdata->td_flags.executing == 1); 961 taskdata->td_flags.executing = 0; // suspend the finishing task 962 } 963 964 KA_TRACE( 965 20, ("__kmp_task_finish: T#%d finished task %p, %d incomplete children\n", 966 gtid, taskdata, children)); 967 968 // Free this task and then ancestor tasks if they have no children. 969 // Restore th_current_task first as suggested by John: 970 // johnmc: if an asynchronous inquiry peers into the runtime system 971 // it doesn't see the freed task as the current task. 972 thread->th.th_current_task = resumed_task; 973 if (!detach) 974 __kmp_free_task_and_ancestors(gtid, taskdata, thread); 975 976 // TODO: GEH - make sure root team implicit task is initialized properly. 977 // KMP_DEBUG_ASSERT( resumed_task->td_flags.executing == 0 ); 978 resumed_task->td_flags.executing = 1; // resume previous task 979 980 KA_TRACE( 981 10, ("__kmp_task_finish(exit): T#%d finished task %p, resuming task %p\n", 982 gtid, taskdata, resumed_task)); 983 984 return; 985 } 986 987 template <bool ompt> 988 static void __kmpc_omp_task_complete_if0_template(ident_t *loc_ref, 989 kmp_int32 gtid, 990 kmp_task_t *task) { 991 KA_TRACE(10, ("__kmpc_omp_task_complete_if0(enter): T#%d loc=%p task=%p\n", 992 gtid, loc_ref, KMP_TASK_TO_TASKDATA(task))); 993 KMP_DEBUG_ASSERT(gtid >= 0); 994 // this routine will provide task to resume 995 __kmp_task_finish<ompt>(gtid, task, NULL); 996 997 KA_TRACE(10, ("__kmpc_omp_task_complete_if0(exit): T#%d loc=%p task=%p\n", 998 gtid, loc_ref, KMP_TASK_TO_TASKDATA(task))); 999 1000 #if OMPT_SUPPORT 1001 if (ompt) { 1002 ompt_frame_t *ompt_frame; 1003 __ompt_get_task_info_internal(0, NULL, NULL, &ompt_frame, NULL, NULL); 1004 ompt_frame->enter_frame = ompt_data_none; 1005 ompt_frame->enter_frame_flags = 1006 ompt_frame_runtime | ompt_frame_framepointer; 1007 } 1008 #endif 1009 1010 return; 1011 } 1012 1013 #if OMPT_SUPPORT 1014 OMPT_NOINLINE 1015 void __kmpc_omp_task_complete_if0_ompt(ident_t *loc_ref, kmp_int32 gtid, 1016 kmp_task_t *task) { 1017 __kmpc_omp_task_complete_if0_template<true>(loc_ref, gtid, task); 1018 } 1019 #endif // OMPT_SUPPORT 1020 1021 // __kmpc_omp_task_complete_if0: report that a task has completed execution 1022 // 1023 // loc_ref: source location information; points to end of task block. 1024 // gtid: global thread number. 1025 // task: task thunk for the completed task. 1026 void __kmpc_omp_task_complete_if0(ident_t *loc_ref, kmp_int32 gtid, 1027 kmp_task_t *task) { 1028 #if OMPT_SUPPORT 1029 if (UNLIKELY(ompt_enabled.enabled)) { 1030 __kmpc_omp_task_complete_if0_ompt(loc_ref, gtid, task); 1031 return; 1032 } 1033 #endif 1034 __kmpc_omp_task_complete_if0_template<false>(loc_ref, gtid, task); 1035 } 1036 1037 #ifdef TASK_UNUSED 1038 // __kmpc_omp_task_complete: report that a task has completed execution 1039 // NEVER GENERATED BY COMPILER, DEPRECATED!!! 1040 void __kmpc_omp_task_complete(ident_t *loc_ref, kmp_int32 gtid, 1041 kmp_task_t *task) { 1042 KA_TRACE(10, ("__kmpc_omp_task_complete(enter): T#%d loc=%p task=%p\n", gtid, 1043 loc_ref, KMP_TASK_TO_TASKDATA(task))); 1044 1045 __kmp_task_finish<false>(gtid, task, 1046 NULL); // Not sure how to find task to resume 1047 1048 KA_TRACE(10, ("__kmpc_omp_task_complete(exit): T#%d loc=%p task=%p\n", gtid, 1049 loc_ref, KMP_TASK_TO_TASKDATA(task))); 1050 return; 1051 } 1052 #endif // TASK_UNUSED 1053 1054 // __kmp_init_implicit_task: Initialize the appropriate fields in the implicit 1055 // task for a given thread 1056 // 1057 // loc_ref: reference to source location of parallel region 1058 // this_thr: thread data structure corresponding to implicit task 1059 // team: team for this_thr 1060 // tid: thread id of given thread within team 1061 // set_curr_task: TRUE if need to push current task to thread 1062 // NOTE: Routine does not set up the implicit task ICVS. This is assumed to 1063 // have already been done elsewhere. 1064 // TODO: Get better loc_ref. Value passed in may be NULL 1065 void __kmp_init_implicit_task(ident_t *loc_ref, kmp_info_t *this_thr, 1066 kmp_team_t *team, int tid, int set_curr_task) { 1067 kmp_taskdata_t *task = &team->t.t_implicit_task_taskdata[tid]; 1068 1069 KF_TRACE( 1070 10, 1071 ("__kmp_init_implicit_task(enter): T#:%d team=%p task=%p, reinit=%s\n", 1072 tid, team, task, set_curr_task ? "TRUE" : "FALSE")); 1073 1074 task->td_task_id = KMP_GEN_TASK_ID(); 1075 task->td_team = team; 1076 // task->td_parent = NULL; // fix for CQ230101 (broken parent task info 1077 // in debugger) 1078 task->td_ident = loc_ref; 1079 task->td_taskwait_ident = NULL; 1080 task->td_taskwait_counter = 0; 1081 task->td_taskwait_thread = 0; 1082 1083 task->td_flags.tiedness = TASK_TIED; 1084 task->td_flags.tasktype = TASK_IMPLICIT; 1085 task->td_flags.proxy = TASK_FULL; 1086 1087 // All implicit tasks are executed immediately, not deferred 1088 task->td_flags.task_serial = 1; 1089 task->td_flags.tasking_ser = (__kmp_tasking_mode == tskm_immediate_exec); 1090 task->td_flags.team_serial = (team->t.t_serialized) ? 1 : 0; 1091 1092 task->td_flags.started = 1; 1093 task->td_flags.executing = 1; 1094 task->td_flags.complete = 0; 1095 task->td_flags.freed = 0; 1096 1097 task->td_depnode = NULL; 1098 task->td_last_tied = task; 1099 task->td_allow_completion_event.type = KMP_EVENT_UNINITIALIZED; 1100 1101 if (set_curr_task) { // only do this init first time thread is created 1102 KMP_ATOMIC_ST_REL(&task->td_incomplete_child_tasks, 0); 1103 // Not used: don't need to deallocate implicit task 1104 KMP_ATOMIC_ST_REL(&task->td_allocated_child_tasks, 0); 1105 task->td_taskgroup = NULL; // An implicit task does not have taskgroup 1106 task->td_dephash = NULL; 1107 __kmp_push_current_task_to_thread(this_thr, team, tid); 1108 } else { 1109 KMP_DEBUG_ASSERT(task->td_incomplete_child_tasks == 0); 1110 KMP_DEBUG_ASSERT(task->td_allocated_child_tasks == 0); 1111 } 1112 1113 #if OMPT_SUPPORT 1114 if (UNLIKELY(ompt_enabled.enabled)) 1115 __ompt_task_init(task, tid); 1116 #endif 1117 1118 KF_TRACE(10, ("__kmp_init_implicit_task(exit): T#:%d team=%p task=%p\n", tid, 1119 team, task)); 1120 } 1121 1122 // __kmp_finish_implicit_task: Release resources associated to implicit tasks 1123 // at the end of parallel regions. Some resources are kept for reuse in the next 1124 // parallel region. 1125 // 1126 // thread: thread data structure corresponding to implicit task 1127 void __kmp_finish_implicit_task(kmp_info_t *thread) { 1128 kmp_taskdata_t *task = thread->th.th_current_task; 1129 if (task->td_dephash) { 1130 int children; 1131 task->td_flags.complete = 1; 1132 children = KMP_ATOMIC_LD_ACQ(&task->td_incomplete_child_tasks); 1133 kmp_tasking_flags_t flags_old = task->td_flags; 1134 if (children == 0 && flags_old.complete == 1) { 1135 kmp_tasking_flags_t flags_new = flags_old; 1136 flags_new.complete = 0; 1137 if (KMP_COMPARE_AND_STORE_ACQ32(RCAST(kmp_int32 *, &task->td_flags), 1138 *RCAST(kmp_int32 *, &flags_old), 1139 *RCAST(kmp_int32 *, &flags_new))) { 1140 KA_TRACE(100, ("__kmp_finish_implicit_task: T#%d cleans " 1141 "dephash of implicit task %p\n", 1142 thread->th.th_info.ds.ds_gtid, task)); 1143 __kmp_dephash_free_entries(thread, task->td_dephash); 1144 } 1145 } 1146 } 1147 } 1148 1149 // __kmp_free_implicit_task: Release resources associated to implicit tasks 1150 // when these are destroyed regions 1151 // 1152 // thread: thread data structure corresponding to implicit task 1153 void __kmp_free_implicit_task(kmp_info_t *thread) { 1154 kmp_taskdata_t *task = thread->th.th_current_task; 1155 if (task && task->td_dephash) { 1156 __kmp_dephash_free(thread, task->td_dephash); 1157 task->td_dephash = NULL; 1158 } 1159 } 1160 1161 // Round up a size to a power of two specified by val: Used to insert padding 1162 // between structures co-allocated using a single malloc() call 1163 static size_t __kmp_round_up_to_val(size_t size, size_t val) { 1164 if (size & (val - 1)) { 1165 size &= ~(val - 1); 1166 if (size <= KMP_SIZE_T_MAX - val) { 1167 size += val; // Round up if there is no overflow. 1168 } 1169 } 1170 return size; 1171 } // __kmp_round_up_to_va 1172 1173 // __kmp_task_alloc: Allocate the taskdata and task data structures for a task 1174 // 1175 // loc_ref: source location information 1176 // gtid: global thread number. 1177 // flags: include tiedness & task type (explicit vs. implicit) of the ''new'' 1178 // task encountered. Converted from kmp_int32 to kmp_tasking_flags_t in routine. 1179 // sizeof_kmp_task_t: Size in bytes of kmp_task_t data structure including 1180 // private vars accessed in task. 1181 // sizeof_shareds: Size in bytes of array of pointers to shared vars accessed 1182 // in task. 1183 // task_entry: Pointer to task code entry point generated by compiler. 1184 // returns: a pointer to the allocated kmp_task_t structure (task). 1185 kmp_task_t *__kmp_task_alloc(ident_t *loc_ref, kmp_int32 gtid, 1186 kmp_tasking_flags_t *flags, 1187 size_t sizeof_kmp_task_t, size_t sizeof_shareds, 1188 kmp_routine_entry_t task_entry) { 1189 kmp_task_t *task; 1190 kmp_taskdata_t *taskdata; 1191 kmp_info_t *thread = __kmp_threads[gtid]; 1192 kmp_info_t *encountering_thread = thread; 1193 kmp_team_t *team = thread->th.th_team; 1194 kmp_taskdata_t *parent_task = thread->th.th_current_task; 1195 size_t shareds_offset; 1196 1197 if (UNLIKELY(!TCR_4(__kmp_init_middle))) 1198 __kmp_middle_initialize(); 1199 1200 if (flags->hidden_helper) { 1201 if (__kmp_enable_hidden_helper) { 1202 if (!TCR_4(__kmp_init_hidden_helper)) 1203 __kmp_hidden_helper_initialize(); 1204 1205 // For a hidden helper task encountered by a regular thread, we will push 1206 // the task to the (gtid%__kmp_hidden_helper_threads_num)-th hidden helper 1207 // thread. 1208 if (!KMP_HIDDEN_HELPER_THREAD(gtid)) { 1209 thread = __kmp_threads[KMP_GTID_TO_SHADOW_GTID(gtid)]; 1210 // We don't change the parent-child relation for hidden helper task as 1211 // we need that to do per-task-region synchronization. 1212 } 1213 } else { 1214 // If the hidden helper task is not enabled, reset the flag to FALSE. 1215 flags->hidden_helper = FALSE; 1216 } 1217 } 1218 1219 KA_TRACE(10, ("__kmp_task_alloc(enter): T#%d loc=%p, flags=(0x%x) " 1220 "sizeof_task=%ld sizeof_shared=%ld entry=%p\n", 1221 gtid, loc_ref, *((kmp_int32 *)flags), sizeof_kmp_task_t, 1222 sizeof_shareds, task_entry)); 1223 1224 KMP_DEBUG_ASSERT(parent_task); 1225 if (parent_task->td_flags.final) { 1226 if (flags->merged_if0) { 1227 } 1228 flags->final = 1; 1229 } 1230 1231 if (flags->tiedness == TASK_UNTIED && !team->t.t_serialized) { 1232 // Untied task encountered causes the TSC algorithm to check entire deque of 1233 // the victim thread. If no untied task encountered, then checking the head 1234 // of the deque should be enough. 1235 KMP_CHECK_UPDATE( 1236 encountering_thread->th.th_task_team->tt.tt_untied_task_encountered, 1); 1237 } 1238 1239 // Detachable tasks are not proxy tasks yet but could be in the future. Doing 1240 // the tasking setup 1241 // when that happens is too late. 1242 if (UNLIKELY(flags->proxy == TASK_PROXY || 1243 flags->detachable == TASK_DETACHABLE || flags->hidden_helper)) { 1244 if (flags->proxy == TASK_PROXY) { 1245 flags->tiedness = TASK_UNTIED; 1246 flags->merged_if0 = 1; 1247 } 1248 /* are we running in a sequential parallel or tskm_immediate_exec... we need 1249 tasking support enabled */ 1250 if ((encountering_thread->th.th_task_team) == NULL) { 1251 /* This should only happen if the team is serialized 1252 setup a task team and propagate it to the thread */ 1253 KMP_DEBUG_ASSERT(team->t.t_serialized); 1254 KA_TRACE(30, 1255 ("T#%d creating task team in __kmp_task_alloc for proxy task\n", 1256 gtid)); 1257 __kmp_task_team_setup( 1258 encountering_thread, team, 1259 1); // 1 indicates setup the current team regardless of nthreads 1260 encountering_thread->th.th_task_team = 1261 team->t.t_task_team[encountering_thread->th.th_task_state]; 1262 } 1263 kmp_task_team_t *task_team = encountering_thread->th.th_task_team; 1264 1265 /* tasking must be enabled now as the task might not be pushed */ 1266 if (!KMP_TASKING_ENABLED(task_team)) { 1267 KA_TRACE( 1268 30, 1269 ("T#%d enabling tasking in __kmp_task_alloc for proxy task\n", gtid)); 1270 __kmp_enable_tasking(task_team, encountering_thread); 1271 kmp_int32 tid = encountering_thread->th.th_info.ds.ds_tid; 1272 kmp_thread_data_t *thread_data = &task_team->tt.tt_threads_data[tid]; 1273 // No lock needed since only owner can allocate 1274 if (thread_data->td.td_deque == NULL) { 1275 __kmp_alloc_task_deque(encountering_thread, thread_data); 1276 } 1277 } 1278 1279 if ((flags->proxy == TASK_PROXY || flags->detachable == TASK_DETACHABLE) && 1280 task_team->tt.tt_found_proxy_tasks == FALSE) 1281 TCW_4(task_team->tt.tt_found_proxy_tasks, TRUE); 1282 if (flags->hidden_helper && 1283 task_team->tt.tt_hidden_helper_task_encountered == FALSE) 1284 TCW_4(task_team->tt.tt_hidden_helper_task_encountered, TRUE); 1285 } 1286 1287 // Calculate shared structure offset including padding after kmp_task_t struct 1288 // to align pointers in shared struct 1289 shareds_offset = sizeof(kmp_taskdata_t) + sizeof_kmp_task_t; 1290 shareds_offset = __kmp_round_up_to_val(shareds_offset, sizeof(void *)); 1291 1292 // Allocate a kmp_taskdata_t block and a kmp_task_t block. 1293 KA_TRACE(30, ("__kmp_task_alloc: T#%d First malloc size: %ld\n", gtid, 1294 shareds_offset)); 1295 KA_TRACE(30, ("__kmp_task_alloc: T#%d Second malloc size: %ld\n", gtid, 1296 sizeof_shareds)); 1297 1298 // Avoid double allocation here by combining shareds with taskdata 1299 #if USE_FAST_MEMORY 1300 taskdata = (kmp_taskdata_t *)__kmp_fast_allocate( 1301 encountering_thread, shareds_offset + sizeof_shareds); 1302 #else /* ! USE_FAST_MEMORY */ 1303 taskdata = (kmp_taskdata_t *)__kmp_thread_malloc( 1304 encountering_thread, shareds_offset + sizeof_shareds); 1305 #endif /* USE_FAST_MEMORY */ 1306 1307 task = KMP_TASKDATA_TO_TASK(taskdata); 1308 1309 // Make sure task & taskdata are aligned appropriately 1310 #if KMP_ARCH_X86 || KMP_ARCH_PPC64 || !KMP_HAVE_QUAD 1311 KMP_DEBUG_ASSERT((((kmp_uintptr_t)taskdata) & (sizeof(double) - 1)) == 0); 1312 KMP_DEBUG_ASSERT((((kmp_uintptr_t)task) & (sizeof(double) - 1)) == 0); 1313 #else 1314 KMP_DEBUG_ASSERT((((kmp_uintptr_t)taskdata) & (sizeof(_Quad) - 1)) == 0); 1315 KMP_DEBUG_ASSERT((((kmp_uintptr_t)task) & (sizeof(_Quad) - 1)) == 0); 1316 #endif 1317 if (sizeof_shareds > 0) { 1318 // Avoid double allocation here by combining shareds with taskdata 1319 task->shareds = &((char *)taskdata)[shareds_offset]; 1320 // Make sure shareds struct is aligned to pointer size 1321 KMP_DEBUG_ASSERT((((kmp_uintptr_t)task->shareds) & (sizeof(void *) - 1)) == 1322 0); 1323 } else { 1324 task->shareds = NULL; 1325 } 1326 task->routine = task_entry; 1327 task->part_id = 0; // AC: Always start with 0 part id 1328 1329 taskdata->td_task_id = KMP_GEN_TASK_ID(); 1330 taskdata->td_team = thread->th.th_team; 1331 taskdata->td_alloc_thread = encountering_thread; 1332 taskdata->td_parent = parent_task; 1333 taskdata->td_level = parent_task->td_level + 1; // increment nesting level 1334 KMP_ATOMIC_ST_RLX(&taskdata->td_untied_count, 0); 1335 taskdata->td_ident = loc_ref; 1336 taskdata->td_taskwait_ident = NULL; 1337 taskdata->td_taskwait_counter = 0; 1338 taskdata->td_taskwait_thread = 0; 1339 KMP_DEBUG_ASSERT(taskdata->td_parent != NULL); 1340 // avoid copying icvs for proxy tasks 1341 if (flags->proxy == TASK_FULL) 1342 copy_icvs(&taskdata->td_icvs, &taskdata->td_parent->td_icvs); 1343 1344 taskdata->td_flags = *flags; 1345 taskdata->encountering_gtid = gtid; 1346 taskdata->td_task_team = thread->th.th_task_team; 1347 taskdata->td_size_alloc = shareds_offset + sizeof_shareds; 1348 taskdata->td_flags.tasktype = TASK_EXPLICIT; 1349 1350 // GEH - TODO: fix this to copy parent task's value of tasking_ser flag 1351 taskdata->td_flags.tasking_ser = (__kmp_tasking_mode == tskm_immediate_exec); 1352 1353 // GEH - TODO: fix this to copy parent task's value of team_serial flag 1354 taskdata->td_flags.team_serial = (team->t.t_serialized) ? 1 : 0; 1355 1356 // GEH - Note we serialize the task if the team is serialized to make sure 1357 // implicit parallel region tasks are not left until program termination to 1358 // execute. Also, it helps locality to execute immediately. 1359 1360 taskdata->td_flags.task_serial = 1361 (parent_task->td_flags.final || taskdata->td_flags.team_serial || 1362 taskdata->td_flags.tasking_ser || flags->merged_if0); 1363 1364 taskdata->td_flags.started = 0; 1365 taskdata->td_flags.executing = 0; 1366 taskdata->td_flags.complete = 0; 1367 taskdata->td_flags.freed = 0; 1368 1369 KMP_ATOMIC_ST_RLX(&taskdata->td_incomplete_child_tasks, 0); 1370 // start at one because counts current task and children 1371 KMP_ATOMIC_ST_RLX(&taskdata->td_allocated_child_tasks, 1); 1372 taskdata->td_taskgroup = 1373 parent_task->td_taskgroup; // task inherits taskgroup from the parent task 1374 taskdata->td_dephash = NULL; 1375 taskdata->td_depnode = NULL; 1376 if (flags->tiedness == TASK_UNTIED) 1377 taskdata->td_last_tied = NULL; // will be set when the task is scheduled 1378 else 1379 taskdata->td_last_tied = taskdata; 1380 taskdata->td_allow_completion_event.type = KMP_EVENT_UNINITIALIZED; 1381 #if OMPT_SUPPORT 1382 if (UNLIKELY(ompt_enabled.enabled)) 1383 __ompt_task_init(taskdata, gtid); 1384 #endif 1385 // Only need to keep track of child task counts if team parallel and tasking 1386 // not serialized or if it is a proxy or detachable or hidden helper task 1387 if (flags->proxy == TASK_PROXY || flags->detachable == TASK_DETACHABLE || 1388 flags->hidden_helper || 1389 !(taskdata->td_flags.team_serial || taskdata->td_flags.tasking_ser)) { 1390 KMP_ATOMIC_INC(&parent_task->td_incomplete_child_tasks); 1391 if (parent_task->td_taskgroup) 1392 KMP_ATOMIC_INC(&parent_task->td_taskgroup->count); 1393 // Only need to keep track of allocated child tasks for explicit tasks since 1394 // implicit not deallocated 1395 if (taskdata->td_parent->td_flags.tasktype == TASK_EXPLICIT) { 1396 KMP_ATOMIC_INC(&taskdata->td_parent->td_allocated_child_tasks); 1397 } 1398 if (flags->hidden_helper) { 1399 taskdata->td_flags.task_serial = FALSE; 1400 // Increment the number of hidden helper tasks to be executed 1401 KMP_ATOMIC_INC(&__kmp_unexecuted_hidden_helper_tasks); 1402 } 1403 } 1404 1405 KA_TRACE(20, ("__kmp_task_alloc(exit): T#%d created task %p parent=%p\n", 1406 gtid, taskdata, taskdata->td_parent)); 1407 1408 return task; 1409 } 1410 1411 kmp_task_t *__kmpc_omp_task_alloc(ident_t *loc_ref, kmp_int32 gtid, 1412 kmp_int32 flags, size_t sizeof_kmp_task_t, 1413 size_t sizeof_shareds, 1414 kmp_routine_entry_t task_entry) { 1415 kmp_task_t *retval; 1416 kmp_tasking_flags_t *input_flags = (kmp_tasking_flags_t *)&flags; 1417 __kmp_assert_valid_gtid(gtid); 1418 input_flags->native = FALSE; 1419 // __kmp_task_alloc() sets up all other runtime flags 1420 KA_TRACE(10, ("__kmpc_omp_task_alloc(enter): T#%d loc=%p, flags=(%s %s %s) " 1421 "sizeof_task=%ld sizeof_shared=%ld entry=%p\n", 1422 gtid, loc_ref, input_flags->tiedness ? "tied " : "untied", 1423 input_flags->proxy ? "proxy" : "", 1424 input_flags->detachable ? "detachable" : "", sizeof_kmp_task_t, 1425 sizeof_shareds, task_entry)); 1426 1427 retval = __kmp_task_alloc(loc_ref, gtid, input_flags, sizeof_kmp_task_t, 1428 sizeof_shareds, task_entry); 1429 1430 KA_TRACE(20, ("__kmpc_omp_task_alloc(exit): T#%d retval %p\n", gtid, retval)); 1431 1432 return retval; 1433 } 1434 1435 kmp_task_t *__kmpc_omp_target_task_alloc(ident_t *loc_ref, kmp_int32 gtid, 1436 kmp_int32 flags, 1437 size_t sizeof_kmp_task_t, 1438 size_t sizeof_shareds, 1439 kmp_routine_entry_t task_entry, 1440 kmp_int64 device_id) { 1441 if (__kmp_enable_hidden_helper) { 1442 auto &input_flags = reinterpret_cast<kmp_tasking_flags_t &>(flags); 1443 input_flags.hidden_helper = TRUE; 1444 } 1445 1446 return __kmpc_omp_task_alloc(loc_ref, gtid, flags, sizeof_kmp_task_t, 1447 sizeof_shareds, task_entry); 1448 } 1449 1450 /*! 1451 @ingroup TASKING 1452 @param loc_ref location of the original task directive 1453 @param gtid Global Thread ID of encountering thread 1454 @param new_task task thunk allocated by __kmpc_omp_task_alloc() for the ''new 1455 task'' 1456 @param naffins Number of affinity items 1457 @param affin_list List of affinity items 1458 @return Returns non-zero if registering affinity information was not successful. 1459 Returns 0 if registration was successful 1460 This entry registers the affinity information attached to a task with the task 1461 thunk structure kmp_taskdata_t. 1462 */ 1463 kmp_int32 1464 __kmpc_omp_reg_task_with_affinity(ident_t *loc_ref, kmp_int32 gtid, 1465 kmp_task_t *new_task, kmp_int32 naffins, 1466 kmp_task_affinity_info_t *affin_list) { 1467 return 0; 1468 } 1469 1470 // __kmp_invoke_task: invoke the specified task 1471 // 1472 // gtid: global thread ID of caller 1473 // task: the task to invoke 1474 // current_task: the task to resume after task invocation 1475 static void __kmp_invoke_task(kmp_int32 gtid, kmp_task_t *task, 1476 kmp_taskdata_t *current_task) { 1477 kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(task); 1478 kmp_info_t *thread; 1479 int discard = 0 /* false */; 1480 KA_TRACE( 1481 30, ("__kmp_invoke_task(enter): T#%d invoking task %p, current_task=%p\n", 1482 gtid, taskdata, current_task)); 1483 KMP_DEBUG_ASSERT(task); 1484 if (UNLIKELY(taskdata->td_flags.proxy == TASK_PROXY && 1485 taskdata->td_flags.complete == 1)) { 1486 // This is a proxy task that was already completed but it needs to run 1487 // its bottom-half finish 1488 KA_TRACE( 1489 30, 1490 ("__kmp_invoke_task: T#%d running bottom finish for proxy task %p\n", 1491 gtid, taskdata)); 1492 1493 __kmp_bottom_half_finish_proxy(gtid, task); 1494 1495 KA_TRACE(30, ("__kmp_invoke_task(exit): T#%d completed bottom finish for " 1496 "proxy task %p, resuming task %p\n", 1497 gtid, taskdata, current_task)); 1498 1499 return; 1500 } 1501 1502 #if OMPT_SUPPORT 1503 // For untied tasks, the first task executed only calls __kmpc_omp_task and 1504 // does not execute code. 1505 ompt_thread_info_t oldInfo; 1506 if (UNLIKELY(ompt_enabled.enabled)) { 1507 // Store the threads states and restore them after the task 1508 thread = __kmp_threads[gtid]; 1509 oldInfo = thread->th.ompt_thread_info; 1510 thread->th.ompt_thread_info.wait_id = 0; 1511 thread->th.ompt_thread_info.state = (thread->th.th_team_serialized) 1512 ? ompt_state_work_serial 1513 : ompt_state_work_parallel; 1514 taskdata->ompt_task_info.frame.exit_frame.ptr = OMPT_GET_FRAME_ADDRESS(0); 1515 } 1516 #endif 1517 1518 // Decreament the counter of hidden helper tasks to be executed 1519 if (taskdata->td_flags.hidden_helper) { 1520 // Hidden helper tasks can only be executed by hidden helper threads 1521 KMP_ASSERT(KMP_HIDDEN_HELPER_THREAD(gtid)); 1522 KMP_ATOMIC_DEC(&__kmp_unexecuted_hidden_helper_tasks); 1523 } 1524 1525 // Proxy tasks are not handled by the runtime 1526 if (taskdata->td_flags.proxy != TASK_PROXY) { 1527 __kmp_task_start(gtid, task, current_task); // OMPT only if not discarded 1528 } 1529 1530 // TODO: cancel tasks if the parallel region has also been cancelled 1531 // TODO: check if this sequence can be hoisted above __kmp_task_start 1532 // if cancellation has been enabled for this run ... 1533 if (UNLIKELY(__kmp_omp_cancellation)) { 1534 thread = __kmp_threads[gtid]; 1535 kmp_team_t *this_team = thread->th.th_team; 1536 kmp_taskgroup_t *taskgroup = taskdata->td_taskgroup; 1537 if ((taskgroup && taskgroup->cancel_request) || 1538 (this_team->t.t_cancel_request == cancel_parallel)) { 1539 #if OMPT_SUPPORT && OMPT_OPTIONAL 1540 ompt_data_t *task_data; 1541 if (UNLIKELY(ompt_enabled.ompt_callback_cancel)) { 1542 __ompt_get_task_info_internal(0, NULL, &task_data, NULL, NULL, NULL); 1543 ompt_callbacks.ompt_callback(ompt_callback_cancel)( 1544 task_data, 1545 ((taskgroup && taskgroup->cancel_request) ? ompt_cancel_taskgroup 1546 : ompt_cancel_parallel) | 1547 ompt_cancel_discarded_task, 1548 NULL); 1549 } 1550 #endif 1551 KMP_COUNT_BLOCK(TASK_cancelled); 1552 // this task belongs to a task group and we need to cancel it 1553 discard = 1 /* true */; 1554 } 1555 } 1556 1557 // Invoke the task routine and pass in relevant data. 1558 // Thunks generated by gcc take a different argument list. 1559 if (!discard) { 1560 if (taskdata->td_flags.tiedness == TASK_UNTIED) { 1561 taskdata->td_last_tied = current_task->td_last_tied; 1562 KMP_DEBUG_ASSERT(taskdata->td_last_tied); 1563 } 1564 #if KMP_STATS_ENABLED 1565 KMP_COUNT_BLOCK(TASK_executed); 1566 switch (KMP_GET_THREAD_STATE()) { 1567 case FORK_JOIN_BARRIER: 1568 KMP_PUSH_PARTITIONED_TIMER(OMP_task_join_bar); 1569 break; 1570 case PLAIN_BARRIER: 1571 KMP_PUSH_PARTITIONED_TIMER(OMP_task_plain_bar); 1572 break; 1573 case TASKYIELD: 1574 KMP_PUSH_PARTITIONED_TIMER(OMP_task_taskyield); 1575 break; 1576 case TASKWAIT: 1577 KMP_PUSH_PARTITIONED_TIMER(OMP_task_taskwait); 1578 break; 1579 case TASKGROUP: 1580 KMP_PUSH_PARTITIONED_TIMER(OMP_task_taskgroup); 1581 break; 1582 default: 1583 KMP_PUSH_PARTITIONED_TIMER(OMP_task_immediate); 1584 break; 1585 } 1586 #endif // KMP_STATS_ENABLED 1587 1588 // OMPT task begin 1589 #if OMPT_SUPPORT 1590 if (UNLIKELY(ompt_enabled.enabled)) 1591 __ompt_task_start(task, current_task, gtid); 1592 #endif 1593 1594 #if OMPD_SUPPORT 1595 if (ompd_state & OMPD_ENABLE_BP) 1596 ompd_bp_task_begin(); 1597 #endif 1598 1599 #if USE_ITT_BUILD && USE_ITT_NOTIFY 1600 kmp_uint64 cur_time; 1601 kmp_int32 kmp_itt_count_task = 1602 __kmp_forkjoin_frames_mode == 3 && !taskdata->td_flags.task_serial && 1603 current_task->td_flags.tasktype == TASK_IMPLICIT; 1604 if (kmp_itt_count_task) { 1605 thread = __kmp_threads[gtid]; 1606 // Time outer level explicit task on barrier for adjusting imbalance time 1607 if (thread->th.th_bar_arrive_time) 1608 cur_time = __itt_get_timestamp(); 1609 else 1610 kmp_itt_count_task = 0; // thread is not on a barrier - skip timing 1611 } 1612 KMP_FSYNC_ACQUIRED(taskdata); // acquired self (new task) 1613 #endif 1614 1615 #ifdef KMP_GOMP_COMPAT 1616 if (taskdata->td_flags.native) { 1617 ((void (*)(void *))(*(task->routine)))(task->shareds); 1618 } else 1619 #endif /* KMP_GOMP_COMPAT */ 1620 { 1621 (*(task->routine))(gtid, task); 1622 } 1623 KMP_POP_PARTITIONED_TIMER(); 1624 1625 #if USE_ITT_BUILD && USE_ITT_NOTIFY 1626 if (kmp_itt_count_task) { 1627 // Barrier imbalance - adjust arrive time with the task duration 1628 thread->th.th_bar_arrive_time += (__itt_get_timestamp() - cur_time); 1629 } 1630 KMP_FSYNC_CANCEL(taskdata); // destroy self (just executed) 1631 KMP_FSYNC_RELEASING(taskdata->td_parent); // releasing parent 1632 #endif 1633 } 1634 1635 #if OMPD_SUPPORT 1636 if (ompd_state & OMPD_ENABLE_BP) 1637 ompd_bp_task_end(); 1638 #endif 1639 1640 // Proxy tasks are not handled by the runtime 1641 if (taskdata->td_flags.proxy != TASK_PROXY) { 1642 #if OMPT_SUPPORT 1643 if (UNLIKELY(ompt_enabled.enabled)) { 1644 thread->th.ompt_thread_info = oldInfo; 1645 if (taskdata->td_flags.tiedness == TASK_TIED) { 1646 taskdata->ompt_task_info.frame.exit_frame = ompt_data_none; 1647 } 1648 __kmp_task_finish<true>(gtid, task, current_task); 1649 } else 1650 #endif 1651 __kmp_task_finish<false>(gtid, task, current_task); 1652 } 1653 1654 KA_TRACE( 1655 30, 1656 ("__kmp_invoke_task(exit): T#%d completed task %p, resuming task %p\n", 1657 gtid, taskdata, current_task)); 1658 return; 1659 } 1660 1661 // __kmpc_omp_task_parts: Schedule a thread-switchable task for execution 1662 // 1663 // loc_ref: location of original task pragma (ignored) 1664 // gtid: Global Thread ID of encountering thread 1665 // new_task: task thunk allocated by __kmp_omp_task_alloc() for the ''new task'' 1666 // Returns: 1667 // TASK_CURRENT_NOT_QUEUED (0) if did not suspend and queue current task to 1668 // be resumed later. 1669 // TASK_CURRENT_QUEUED (1) if suspended and queued the current task to be 1670 // resumed later. 1671 kmp_int32 __kmpc_omp_task_parts(ident_t *loc_ref, kmp_int32 gtid, 1672 kmp_task_t *new_task) { 1673 kmp_taskdata_t *new_taskdata = KMP_TASK_TO_TASKDATA(new_task); 1674 1675 KA_TRACE(10, ("__kmpc_omp_task_parts(enter): T#%d loc=%p task=%p\n", gtid, 1676 loc_ref, new_taskdata)); 1677 1678 #if OMPT_SUPPORT 1679 kmp_taskdata_t *parent; 1680 if (UNLIKELY(ompt_enabled.enabled)) { 1681 parent = new_taskdata->td_parent; 1682 if (ompt_enabled.ompt_callback_task_create) { 1683 ompt_callbacks.ompt_callback(ompt_callback_task_create)( 1684 &(parent->ompt_task_info.task_data), &(parent->ompt_task_info.frame), 1685 &(new_taskdata->ompt_task_info.task_data), ompt_task_explicit, 0, 1686 OMPT_GET_RETURN_ADDRESS(0)); 1687 } 1688 } 1689 #endif 1690 1691 /* Should we execute the new task or queue it? For now, let's just always try 1692 to queue it. If the queue fills up, then we'll execute it. */ 1693 1694 if (__kmp_push_task(gtid, new_task) == TASK_NOT_PUSHED) // if cannot defer 1695 { // Execute this task immediately 1696 kmp_taskdata_t *current_task = __kmp_threads[gtid]->th.th_current_task; 1697 new_taskdata->td_flags.task_serial = 1; 1698 __kmp_invoke_task(gtid, new_task, current_task); 1699 } 1700 1701 KA_TRACE( 1702 10, 1703 ("__kmpc_omp_task_parts(exit): T#%d returning TASK_CURRENT_NOT_QUEUED: " 1704 "loc=%p task=%p, return: TASK_CURRENT_NOT_QUEUED\n", 1705 gtid, loc_ref, new_taskdata)); 1706 1707 #if OMPT_SUPPORT 1708 if (UNLIKELY(ompt_enabled.enabled)) { 1709 parent->ompt_task_info.frame.enter_frame = ompt_data_none; 1710 } 1711 #endif 1712 return TASK_CURRENT_NOT_QUEUED; 1713 } 1714 1715 // __kmp_omp_task: Schedule a non-thread-switchable task for execution 1716 // 1717 // gtid: Global Thread ID of encountering thread 1718 // new_task:non-thread-switchable task thunk allocated by __kmp_omp_task_alloc() 1719 // serialize_immediate: if TRUE then if the task is executed immediately its 1720 // execution will be serialized 1721 // Returns: 1722 // TASK_CURRENT_NOT_QUEUED (0) if did not suspend and queue current task to 1723 // be resumed later. 1724 // TASK_CURRENT_QUEUED (1) if suspended and queued the current task to be 1725 // resumed later. 1726 kmp_int32 __kmp_omp_task(kmp_int32 gtid, kmp_task_t *new_task, 1727 bool serialize_immediate) { 1728 kmp_taskdata_t *new_taskdata = KMP_TASK_TO_TASKDATA(new_task); 1729 1730 /* Should we execute the new task or queue it? For now, let's just always try 1731 to queue it. If the queue fills up, then we'll execute it. */ 1732 if (new_taskdata->td_flags.proxy == TASK_PROXY || 1733 __kmp_push_task(gtid, new_task) == TASK_NOT_PUSHED) // if cannot defer 1734 { // Execute this task immediately 1735 kmp_taskdata_t *current_task = __kmp_threads[gtid]->th.th_current_task; 1736 if (serialize_immediate) 1737 new_taskdata->td_flags.task_serial = 1; 1738 __kmp_invoke_task(gtid, new_task, current_task); 1739 } 1740 1741 return TASK_CURRENT_NOT_QUEUED; 1742 } 1743 1744 // __kmpc_omp_task: Wrapper around __kmp_omp_task to schedule a 1745 // non-thread-switchable task from the parent thread only! 1746 // 1747 // loc_ref: location of original task pragma (ignored) 1748 // gtid: Global Thread ID of encountering thread 1749 // new_task: non-thread-switchable task thunk allocated by 1750 // __kmp_omp_task_alloc() 1751 // Returns: 1752 // TASK_CURRENT_NOT_QUEUED (0) if did not suspend and queue current task to 1753 // be resumed later. 1754 // TASK_CURRENT_QUEUED (1) if suspended and queued the current task to be 1755 // resumed later. 1756 kmp_int32 __kmpc_omp_task(ident_t *loc_ref, kmp_int32 gtid, 1757 kmp_task_t *new_task) { 1758 kmp_int32 res; 1759 KMP_SET_THREAD_STATE_BLOCK(EXPLICIT_TASK); 1760 1761 #if KMP_DEBUG || OMPT_SUPPORT 1762 kmp_taskdata_t *new_taskdata = KMP_TASK_TO_TASKDATA(new_task); 1763 #endif 1764 KA_TRACE(10, ("__kmpc_omp_task(enter): T#%d loc=%p task=%p\n", gtid, loc_ref, 1765 new_taskdata)); 1766 __kmp_assert_valid_gtid(gtid); 1767 1768 #if OMPT_SUPPORT 1769 kmp_taskdata_t *parent = NULL; 1770 if (UNLIKELY(ompt_enabled.enabled)) { 1771 if (!new_taskdata->td_flags.started) { 1772 OMPT_STORE_RETURN_ADDRESS(gtid); 1773 parent = new_taskdata->td_parent; 1774 if (!parent->ompt_task_info.frame.enter_frame.ptr) { 1775 parent->ompt_task_info.frame.enter_frame.ptr = 1776 OMPT_GET_FRAME_ADDRESS(0); 1777 } 1778 if (ompt_enabled.ompt_callback_task_create) { 1779 ompt_callbacks.ompt_callback(ompt_callback_task_create)( 1780 &(parent->ompt_task_info.task_data), 1781 &(parent->ompt_task_info.frame), 1782 &(new_taskdata->ompt_task_info.task_data), 1783 ompt_task_explicit | TASK_TYPE_DETAILS_FORMAT(new_taskdata), 0, 1784 OMPT_LOAD_RETURN_ADDRESS(gtid)); 1785 } 1786 } else { 1787 // We are scheduling the continuation of an UNTIED task. 1788 // Scheduling back to the parent task. 1789 __ompt_task_finish(new_task, 1790 new_taskdata->ompt_task_info.scheduling_parent, 1791 ompt_task_switch); 1792 new_taskdata->ompt_task_info.frame.exit_frame = ompt_data_none; 1793 } 1794 } 1795 #endif 1796 1797 res = __kmp_omp_task(gtid, new_task, true); 1798 1799 KA_TRACE(10, ("__kmpc_omp_task(exit): T#%d returning " 1800 "TASK_CURRENT_NOT_QUEUED: loc=%p task=%p\n", 1801 gtid, loc_ref, new_taskdata)); 1802 #if OMPT_SUPPORT 1803 if (UNLIKELY(ompt_enabled.enabled && parent != NULL)) { 1804 parent->ompt_task_info.frame.enter_frame = ompt_data_none; 1805 } 1806 #endif 1807 return res; 1808 } 1809 1810 // __kmp_omp_taskloop_task: Wrapper around __kmp_omp_task to schedule 1811 // a taskloop task with the correct OMPT return address 1812 // 1813 // loc_ref: location of original task pragma (ignored) 1814 // gtid: Global Thread ID of encountering thread 1815 // new_task: non-thread-switchable task thunk allocated by 1816 // __kmp_omp_task_alloc() 1817 // codeptr_ra: return address for OMPT callback 1818 // Returns: 1819 // TASK_CURRENT_NOT_QUEUED (0) if did not suspend and queue current task to 1820 // be resumed later. 1821 // TASK_CURRENT_QUEUED (1) if suspended and queued the current task to be 1822 // resumed later. 1823 kmp_int32 __kmp_omp_taskloop_task(ident_t *loc_ref, kmp_int32 gtid, 1824 kmp_task_t *new_task, void *codeptr_ra) { 1825 kmp_int32 res; 1826 KMP_SET_THREAD_STATE_BLOCK(EXPLICIT_TASK); 1827 1828 #if KMP_DEBUG || OMPT_SUPPORT 1829 kmp_taskdata_t *new_taskdata = KMP_TASK_TO_TASKDATA(new_task); 1830 #endif 1831 KA_TRACE(10, ("__kmpc_omp_task(enter): T#%d loc=%p task=%p\n", gtid, loc_ref, 1832 new_taskdata)); 1833 1834 #if OMPT_SUPPORT 1835 kmp_taskdata_t *parent = NULL; 1836 if (UNLIKELY(ompt_enabled.enabled && !new_taskdata->td_flags.started)) { 1837 parent = new_taskdata->td_parent; 1838 if (!parent->ompt_task_info.frame.enter_frame.ptr) 1839 parent->ompt_task_info.frame.enter_frame.ptr = OMPT_GET_FRAME_ADDRESS(0); 1840 if (ompt_enabled.ompt_callback_task_create) { 1841 ompt_callbacks.ompt_callback(ompt_callback_task_create)( 1842 &(parent->ompt_task_info.task_data), &(parent->ompt_task_info.frame), 1843 &(new_taskdata->ompt_task_info.task_data), 1844 ompt_task_explicit | TASK_TYPE_DETAILS_FORMAT(new_taskdata), 0, 1845 codeptr_ra); 1846 } 1847 } 1848 #endif 1849 1850 res = __kmp_omp_task(gtid, new_task, true); 1851 1852 KA_TRACE(10, ("__kmpc_omp_task(exit): T#%d returning " 1853 "TASK_CURRENT_NOT_QUEUED: loc=%p task=%p\n", 1854 gtid, loc_ref, new_taskdata)); 1855 #if OMPT_SUPPORT 1856 if (UNLIKELY(ompt_enabled.enabled && parent != NULL)) { 1857 parent->ompt_task_info.frame.enter_frame = ompt_data_none; 1858 } 1859 #endif 1860 return res; 1861 } 1862 1863 template <bool ompt> 1864 static kmp_int32 __kmpc_omp_taskwait_template(ident_t *loc_ref, kmp_int32 gtid, 1865 void *frame_address, 1866 void *return_address) { 1867 kmp_taskdata_t *taskdata = nullptr; 1868 kmp_info_t *thread; 1869 int thread_finished = FALSE; 1870 KMP_SET_THREAD_STATE_BLOCK(TASKWAIT); 1871 1872 KA_TRACE(10, ("__kmpc_omp_taskwait(enter): T#%d loc=%p\n", gtid, loc_ref)); 1873 KMP_DEBUG_ASSERT(gtid >= 0); 1874 1875 if (__kmp_tasking_mode != tskm_immediate_exec) { 1876 thread = __kmp_threads[gtid]; 1877 taskdata = thread->th.th_current_task; 1878 1879 #if OMPT_SUPPORT && OMPT_OPTIONAL 1880 ompt_data_t *my_task_data; 1881 ompt_data_t *my_parallel_data; 1882 1883 if (ompt) { 1884 my_task_data = &(taskdata->ompt_task_info.task_data); 1885 my_parallel_data = OMPT_CUR_TEAM_DATA(thread); 1886 1887 taskdata->ompt_task_info.frame.enter_frame.ptr = frame_address; 1888 1889 if (ompt_enabled.ompt_callback_sync_region) { 1890 ompt_callbacks.ompt_callback(ompt_callback_sync_region)( 1891 ompt_sync_region_taskwait, ompt_scope_begin, my_parallel_data, 1892 my_task_data, return_address); 1893 } 1894 1895 if (ompt_enabled.ompt_callback_sync_region_wait) { 1896 ompt_callbacks.ompt_callback(ompt_callback_sync_region_wait)( 1897 ompt_sync_region_taskwait, ompt_scope_begin, my_parallel_data, 1898 my_task_data, return_address); 1899 } 1900 } 1901 #endif // OMPT_SUPPORT && OMPT_OPTIONAL 1902 1903 // Debugger: The taskwait is active. Store location and thread encountered the 1904 // taskwait. 1905 #if USE_ITT_BUILD 1906 // Note: These values are used by ITT events as well. 1907 #endif /* USE_ITT_BUILD */ 1908 taskdata->td_taskwait_counter += 1; 1909 taskdata->td_taskwait_ident = loc_ref; 1910 taskdata->td_taskwait_thread = gtid + 1; 1911 1912 #if USE_ITT_BUILD 1913 void *itt_sync_obj = NULL; 1914 #if USE_ITT_NOTIFY 1915 KMP_ITT_TASKWAIT_STARTING(itt_sync_obj); 1916 #endif /* USE_ITT_NOTIFY */ 1917 #endif /* USE_ITT_BUILD */ 1918 1919 bool must_wait = 1920 !taskdata->td_flags.team_serial && !taskdata->td_flags.final; 1921 1922 must_wait = must_wait || (thread->th.th_task_team != NULL && 1923 thread->th.th_task_team->tt.tt_found_proxy_tasks); 1924 // If hidden helper thread is encountered, we must enable wait here. 1925 must_wait = 1926 must_wait || 1927 (__kmp_enable_hidden_helper && thread->th.th_task_team != NULL && 1928 thread->th.th_task_team->tt.tt_hidden_helper_task_encountered); 1929 1930 if (must_wait) { 1931 kmp_flag_32<false, false> flag( 1932 RCAST(std::atomic<kmp_uint32> *, 1933 &(taskdata->td_incomplete_child_tasks)), 1934 0U); 1935 while (KMP_ATOMIC_LD_ACQ(&taskdata->td_incomplete_child_tasks) != 0) { 1936 flag.execute_tasks(thread, gtid, FALSE, 1937 &thread_finished USE_ITT_BUILD_ARG(itt_sync_obj), 1938 __kmp_task_stealing_constraint); 1939 } 1940 } 1941 #if USE_ITT_BUILD 1942 KMP_ITT_TASKWAIT_FINISHED(itt_sync_obj); 1943 KMP_FSYNC_ACQUIRED(taskdata); // acquire self - sync with children 1944 #endif /* USE_ITT_BUILD */ 1945 1946 // Debugger: The taskwait is completed. Location remains, but thread is 1947 // negated. 1948 taskdata->td_taskwait_thread = -taskdata->td_taskwait_thread; 1949 1950 #if OMPT_SUPPORT && OMPT_OPTIONAL 1951 if (ompt) { 1952 if (ompt_enabled.ompt_callback_sync_region_wait) { 1953 ompt_callbacks.ompt_callback(ompt_callback_sync_region_wait)( 1954 ompt_sync_region_taskwait, ompt_scope_end, my_parallel_data, 1955 my_task_data, return_address); 1956 } 1957 if (ompt_enabled.ompt_callback_sync_region) { 1958 ompt_callbacks.ompt_callback(ompt_callback_sync_region)( 1959 ompt_sync_region_taskwait, ompt_scope_end, my_parallel_data, 1960 my_task_data, return_address); 1961 } 1962 taskdata->ompt_task_info.frame.enter_frame = ompt_data_none; 1963 } 1964 #endif // OMPT_SUPPORT && OMPT_OPTIONAL 1965 1966 } 1967 1968 KA_TRACE(10, ("__kmpc_omp_taskwait(exit): T#%d task %p finished waiting, " 1969 "returning TASK_CURRENT_NOT_QUEUED\n", 1970 gtid, taskdata)); 1971 1972 return TASK_CURRENT_NOT_QUEUED; 1973 } 1974 1975 #if OMPT_SUPPORT && OMPT_OPTIONAL 1976 OMPT_NOINLINE 1977 static kmp_int32 __kmpc_omp_taskwait_ompt(ident_t *loc_ref, kmp_int32 gtid, 1978 void *frame_address, 1979 void *return_address) { 1980 return __kmpc_omp_taskwait_template<true>(loc_ref, gtid, frame_address, 1981 return_address); 1982 } 1983 #endif // OMPT_SUPPORT && OMPT_OPTIONAL 1984 1985 // __kmpc_omp_taskwait: Wait until all tasks generated by the current task are 1986 // complete 1987 kmp_int32 __kmpc_omp_taskwait(ident_t *loc_ref, kmp_int32 gtid) { 1988 #if OMPT_SUPPORT && OMPT_OPTIONAL 1989 if (UNLIKELY(ompt_enabled.enabled)) { 1990 OMPT_STORE_RETURN_ADDRESS(gtid); 1991 return __kmpc_omp_taskwait_ompt(loc_ref, gtid, OMPT_GET_FRAME_ADDRESS(0), 1992 OMPT_LOAD_RETURN_ADDRESS(gtid)); 1993 } 1994 #endif 1995 return __kmpc_omp_taskwait_template<false>(loc_ref, gtid, NULL, NULL); 1996 } 1997 1998 // __kmpc_omp_taskyield: switch to a different task 1999 kmp_int32 __kmpc_omp_taskyield(ident_t *loc_ref, kmp_int32 gtid, int end_part) { 2000 kmp_taskdata_t *taskdata = NULL; 2001 kmp_info_t *thread; 2002 int thread_finished = FALSE; 2003 2004 KMP_COUNT_BLOCK(OMP_TASKYIELD); 2005 KMP_SET_THREAD_STATE_BLOCK(TASKYIELD); 2006 2007 KA_TRACE(10, ("__kmpc_omp_taskyield(enter): T#%d loc=%p end_part = %d\n", 2008 gtid, loc_ref, end_part)); 2009 __kmp_assert_valid_gtid(gtid); 2010 2011 if (__kmp_tasking_mode != tskm_immediate_exec && __kmp_init_parallel) { 2012 thread = __kmp_threads[gtid]; 2013 taskdata = thread->th.th_current_task; 2014 // Should we model this as a task wait or not? 2015 // Debugger: The taskwait is active. Store location and thread encountered the 2016 // taskwait. 2017 #if USE_ITT_BUILD 2018 // Note: These values are used by ITT events as well. 2019 #endif /* USE_ITT_BUILD */ 2020 taskdata->td_taskwait_counter += 1; 2021 taskdata->td_taskwait_ident = loc_ref; 2022 taskdata->td_taskwait_thread = gtid + 1; 2023 2024 #if USE_ITT_BUILD 2025 void *itt_sync_obj = NULL; 2026 #if USE_ITT_NOTIFY 2027 KMP_ITT_TASKWAIT_STARTING(itt_sync_obj); 2028 #endif /* USE_ITT_NOTIFY */ 2029 #endif /* USE_ITT_BUILD */ 2030 if (!taskdata->td_flags.team_serial) { 2031 kmp_task_team_t *task_team = thread->th.th_task_team; 2032 if (task_team != NULL) { 2033 if (KMP_TASKING_ENABLED(task_team)) { 2034 #if OMPT_SUPPORT 2035 if (UNLIKELY(ompt_enabled.enabled)) 2036 thread->th.ompt_thread_info.ompt_task_yielded = 1; 2037 #endif 2038 __kmp_execute_tasks_32( 2039 thread, gtid, (kmp_flag_32<> *)NULL, FALSE, 2040 &thread_finished USE_ITT_BUILD_ARG(itt_sync_obj), 2041 __kmp_task_stealing_constraint); 2042 #if OMPT_SUPPORT 2043 if (UNLIKELY(ompt_enabled.enabled)) 2044 thread->th.ompt_thread_info.ompt_task_yielded = 0; 2045 #endif 2046 } 2047 } 2048 } 2049 #if USE_ITT_BUILD 2050 KMP_ITT_TASKWAIT_FINISHED(itt_sync_obj); 2051 #endif /* USE_ITT_BUILD */ 2052 2053 // Debugger: The taskwait is completed. Location remains, but thread is 2054 // negated. 2055 taskdata->td_taskwait_thread = -taskdata->td_taskwait_thread; 2056 } 2057 2058 KA_TRACE(10, ("__kmpc_omp_taskyield(exit): T#%d task %p resuming, " 2059 "returning TASK_CURRENT_NOT_QUEUED\n", 2060 gtid, taskdata)); 2061 2062 return TASK_CURRENT_NOT_QUEUED; 2063 } 2064 2065 // Task Reduction implementation 2066 // 2067 // Note: initial implementation didn't take into account the possibility 2068 // to specify omp_orig for initializer of the UDR (user defined reduction). 2069 // Corrected implementation takes into account the omp_orig object. 2070 // Compiler is free to use old implementation if omp_orig is not specified. 2071 2072 /*! 2073 @ingroup BASIC_TYPES 2074 @{ 2075 */ 2076 2077 /*! 2078 Flags for special info per task reduction item. 2079 */ 2080 typedef struct kmp_taskred_flags { 2081 /*! 1 - use lazy alloc/init (e.g. big objects, #tasks < #threads) */ 2082 unsigned lazy_priv : 1; 2083 unsigned reserved31 : 31; 2084 } kmp_taskred_flags_t; 2085 2086 /*! 2087 Internal struct for reduction data item related info set up by compiler. 2088 */ 2089 typedef struct kmp_task_red_input { 2090 void *reduce_shar; /**< shared between tasks item to reduce into */ 2091 size_t reduce_size; /**< size of data item in bytes */ 2092 // three compiler-generated routines (init, fini are optional): 2093 void *reduce_init; /**< data initialization routine (single parameter) */ 2094 void *reduce_fini; /**< data finalization routine */ 2095 void *reduce_comb; /**< data combiner routine */ 2096 kmp_taskred_flags_t flags; /**< flags for additional info from compiler */ 2097 } kmp_task_red_input_t; 2098 2099 /*! 2100 Internal struct for reduction data item related info saved by the library. 2101 */ 2102 typedef struct kmp_taskred_data { 2103 void *reduce_shar; /**< shared between tasks item to reduce into */ 2104 size_t reduce_size; /**< size of data item */ 2105 kmp_taskred_flags_t flags; /**< flags for additional info from compiler */ 2106 void *reduce_priv; /**< array of thread specific items */ 2107 void *reduce_pend; /**< end of private data for faster comparison op */ 2108 // three compiler-generated routines (init, fini are optional): 2109 void *reduce_comb; /**< data combiner routine */ 2110 void *reduce_init; /**< data initialization routine (two parameters) */ 2111 void *reduce_fini; /**< data finalization routine */ 2112 void *reduce_orig; /**< original item (can be used in UDR initializer) */ 2113 } kmp_taskred_data_t; 2114 2115 /*! 2116 Internal struct for reduction data item related info set up by compiler. 2117 2118 New interface: added reduce_orig field to provide omp_orig for UDR initializer. 2119 */ 2120 typedef struct kmp_taskred_input { 2121 void *reduce_shar; /**< shared between tasks item to reduce into */ 2122 void *reduce_orig; /**< original reduction item used for initialization */ 2123 size_t reduce_size; /**< size of data item */ 2124 // three compiler-generated routines (init, fini are optional): 2125 void *reduce_init; /**< data initialization routine (two parameters) */ 2126 void *reduce_fini; /**< data finalization routine */ 2127 void *reduce_comb; /**< data combiner routine */ 2128 kmp_taskred_flags_t flags; /**< flags for additional info from compiler */ 2129 } kmp_taskred_input_t; 2130 /*! 2131 @} 2132 */ 2133 2134 template <typename T> void __kmp_assign_orig(kmp_taskred_data_t &item, T &src); 2135 template <> 2136 void __kmp_assign_orig<kmp_task_red_input_t>(kmp_taskred_data_t &item, 2137 kmp_task_red_input_t &src) { 2138 item.reduce_orig = NULL; 2139 } 2140 template <> 2141 void __kmp_assign_orig<kmp_taskred_input_t>(kmp_taskred_data_t &item, 2142 kmp_taskred_input_t &src) { 2143 if (src.reduce_orig != NULL) { 2144 item.reduce_orig = src.reduce_orig; 2145 } else { 2146 item.reduce_orig = src.reduce_shar; 2147 } // non-NULL reduce_orig means new interface used 2148 } 2149 2150 template <typename T> void __kmp_call_init(kmp_taskred_data_t &item, size_t j); 2151 template <> 2152 void __kmp_call_init<kmp_task_red_input_t>(kmp_taskred_data_t &item, 2153 size_t offset) { 2154 ((void (*)(void *))item.reduce_init)((char *)(item.reduce_priv) + offset); 2155 } 2156 template <> 2157 void __kmp_call_init<kmp_taskred_input_t>(kmp_taskred_data_t &item, 2158 size_t offset) { 2159 ((void (*)(void *, void *))item.reduce_init)( 2160 (char *)(item.reduce_priv) + offset, item.reduce_orig); 2161 } 2162 2163 template <typename T> 2164 void *__kmp_task_reduction_init(int gtid, int num, T *data) { 2165 __kmp_assert_valid_gtid(gtid); 2166 kmp_info_t *thread = __kmp_threads[gtid]; 2167 kmp_taskgroup_t *tg = thread->th.th_current_task->td_taskgroup; 2168 kmp_uint32 nth = thread->th.th_team_nproc; 2169 kmp_taskred_data_t *arr; 2170 2171 // check input data just in case 2172 KMP_ASSERT(tg != NULL); 2173 KMP_ASSERT(data != NULL); 2174 KMP_ASSERT(num > 0); 2175 if (nth == 1) { 2176 KA_TRACE(10, ("__kmpc_task_reduction_init: T#%d, tg %p, exiting nth=1\n", 2177 gtid, tg)); 2178 return (void *)tg; 2179 } 2180 KA_TRACE(10, ("__kmpc_task_reduction_init: T#%d, taskgroup %p, #items %d\n", 2181 gtid, tg, num)); 2182 arr = (kmp_taskred_data_t *)__kmp_thread_malloc( 2183 thread, num * sizeof(kmp_taskred_data_t)); 2184 for (int i = 0; i < num; ++i) { 2185 size_t size = data[i].reduce_size - 1; 2186 // round the size up to cache line per thread-specific item 2187 size += CACHE_LINE - size % CACHE_LINE; 2188 KMP_ASSERT(data[i].reduce_comb != NULL); // combiner is mandatory 2189 arr[i].reduce_shar = data[i].reduce_shar; 2190 arr[i].reduce_size = size; 2191 arr[i].flags = data[i].flags; 2192 arr[i].reduce_comb = data[i].reduce_comb; 2193 arr[i].reduce_init = data[i].reduce_init; 2194 arr[i].reduce_fini = data[i].reduce_fini; 2195 __kmp_assign_orig<T>(arr[i], data[i]); 2196 if (!arr[i].flags.lazy_priv) { 2197 // allocate cache-line aligned block and fill it with zeros 2198 arr[i].reduce_priv = __kmp_allocate(nth * size); 2199 arr[i].reduce_pend = (char *)(arr[i].reduce_priv) + nth * size; 2200 if (arr[i].reduce_init != NULL) { 2201 // initialize all thread-specific items 2202 for (size_t j = 0; j < nth; ++j) { 2203 __kmp_call_init<T>(arr[i], j * size); 2204 } 2205 } 2206 } else { 2207 // only allocate space for pointers now, 2208 // objects will be lazily allocated/initialized if/when requested 2209 // note that __kmp_allocate zeroes the allocated memory 2210 arr[i].reduce_priv = __kmp_allocate(nth * sizeof(void *)); 2211 } 2212 } 2213 tg->reduce_data = (void *)arr; 2214 tg->reduce_num_data = num; 2215 return (void *)tg; 2216 } 2217 2218 /*! 2219 @ingroup TASKING 2220 @param gtid Global thread ID 2221 @param num Number of data items to reduce 2222 @param data Array of data for reduction 2223 @return The taskgroup identifier 2224 2225 Initialize task reduction for the taskgroup. 2226 2227 Note: this entry supposes the optional compiler-generated initializer routine 2228 has single parameter - pointer to object to be initialized. That means 2229 the reduction either does not use omp_orig object, or the omp_orig is accessible 2230 without help of the runtime library. 2231 */ 2232 void *__kmpc_task_reduction_init(int gtid, int num, void *data) { 2233 return __kmp_task_reduction_init(gtid, num, (kmp_task_red_input_t *)data); 2234 } 2235 2236 /*! 2237 @ingroup TASKING 2238 @param gtid Global thread ID 2239 @param num Number of data items to reduce 2240 @param data Array of data for reduction 2241 @return The taskgroup identifier 2242 2243 Initialize task reduction for the taskgroup. 2244 2245 Note: this entry supposes the optional compiler-generated initializer routine 2246 has two parameters, pointer to object to be initialized and pointer to omp_orig 2247 */ 2248 void *__kmpc_taskred_init(int gtid, int num, void *data) { 2249 return __kmp_task_reduction_init(gtid, num, (kmp_taskred_input_t *)data); 2250 } 2251 2252 // Copy task reduction data (except for shared pointers). 2253 template <typename T> 2254 void __kmp_task_reduction_init_copy(kmp_info_t *thr, int num, T *data, 2255 kmp_taskgroup_t *tg, void *reduce_data) { 2256 kmp_taskred_data_t *arr; 2257 KA_TRACE(20, ("__kmp_task_reduction_init_copy: Th %p, init taskgroup %p," 2258 " from data %p\n", 2259 thr, tg, reduce_data)); 2260 arr = (kmp_taskred_data_t *)__kmp_thread_malloc( 2261 thr, num * sizeof(kmp_taskred_data_t)); 2262 // threads will share private copies, thunk routines, sizes, flags, etc.: 2263 KMP_MEMCPY(arr, reduce_data, num * sizeof(kmp_taskred_data_t)); 2264 for (int i = 0; i < num; ++i) { 2265 arr[i].reduce_shar = data[i].reduce_shar; // init unique shared pointers 2266 } 2267 tg->reduce_data = (void *)arr; 2268 tg->reduce_num_data = num; 2269 } 2270 2271 /*! 2272 @ingroup TASKING 2273 @param gtid Global thread ID 2274 @param tskgrp The taskgroup ID (optional) 2275 @param data Shared location of the item 2276 @return The pointer to per-thread data 2277 2278 Get thread-specific location of data item 2279 */ 2280 void *__kmpc_task_reduction_get_th_data(int gtid, void *tskgrp, void *data) { 2281 __kmp_assert_valid_gtid(gtid); 2282 kmp_info_t *thread = __kmp_threads[gtid]; 2283 kmp_int32 nth = thread->th.th_team_nproc; 2284 if (nth == 1) 2285 return data; // nothing to do 2286 2287 kmp_taskgroup_t *tg = (kmp_taskgroup_t *)tskgrp; 2288 if (tg == NULL) 2289 tg = thread->th.th_current_task->td_taskgroup; 2290 KMP_ASSERT(tg != NULL); 2291 kmp_taskred_data_t *arr = (kmp_taskred_data_t *)(tg->reduce_data); 2292 kmp_int32 num = tg->reduce_num_data; 2293 kmp_int32 tid = thread->th.th_info.ds.ds_tid; 2294 2295 KMP_ASSERT(data != NULL); 2296 while (tg != NULL) { 2297 for (int i = 0; i < num; ++i) { 2298 if (!arr[i].flags.lazy_priv) { 2299 if (data == arr[i].reduce_shar || 2300 (data >= arr[i].reduce_priv && data < arr[i].reduce_pend)) 2301 return (char *)(arr[i].reduce_priv) + tid * arr[i].reduce_size; 2302 } else { 2303 // check shared location first 2304 void **p_priv = (void **)(arr[i].reduce_priv); 2305 if (data == arr[i].reduce_shar) 2306 goto found; 2307 // check if we get some thread specific location as parameter 2308 for (int j = 0; j < nth; ++j) 2309 if (data == p_priv[j]) 2310 goto found; 2311 continue; // not found, continue search 2312 found: 2313 if (p_priv[tid] == NULL) { 2314 // allocate thread specific object lazily 2315 p_priv[tid] = __kmp_allocate(arr[i].reduce_size); 2316 if (arr[i].reduce_init != NULL) { 2317 if (arr[i].reduce_orig != NULL) { // new interface 2318 ((void (*)(void *, void *))arr[i].reduce_init)( 2319 p_priv[tid], arr[i].reduce_orig); 2320 } else { // old interface (single parameter) 2321 ((void (*)(void *))arr[i].reduce_init)(p_priv[tid]); 2322 } 2323 } 2324 } 2325 return p_priv[tid]; 2326 } 2327 } 2328 tg = tg->parent; 2329 arr = (kmp_taskred_data_t *)(tg->reduce_data); 2330 num = tg->reduce_num_data; 2331 } 2332 KMP_ASSERT2(0, "Unknown task reduction item"); 2333 return NULL; // ERROR, this line never executed 2334 } 2335 2336 // Finalize task reduction. 2337 // Called from __kmpc_end_taskgroup() 2338 static void __kmp_task_reduction_fini(kmp_info_t *th, kmp_taskgroup_t *tg) { 2339 kmp_int32 nth = th->th.th_team_nproc; 2340 KMP_DEBUG_ASSERT(nth > 1); // should not be called if nth == 1 2341 kmp_taskred_data_t *arr = (kmp_taskred_data_t *)tg->reduce_data; 2342 kmp_int32 num = tg->reduce_num_data; 2343 for (int i = 0; i < num; ++i) { 2344 void *sh_data = arr[i].reduce_shar; 2345 void (*f_fini)(void *) = (void (*)(void *))(arr[i].reduce_fini); 2346 void (*f_comb)(void *, void *) = 2347 (void (*)(void *, void *))(arr[i].reduce_comb); 2348 if (!arr[i].flags.lazy_priv) { 2349 void *pr_data = arr[i].reduce_priv; 2350 size_t size = arr[i].reduce_size; 2351 for (int j = 0; j < nth; ++j) { 2352 void *priv_data = (char *)pr_data + j * size; 2353 f_comb(sh_data, priv_data); // combine results 2354 if (f_fini) 2355 f_fini(priv_data); // finalize if needed 2356 } 2357 } else { 2358 void **pr_data = (void **)(arr[i].reduce_priv); 2359 for (int j = 0; j < nth; ++j) { 2360 if (pr_data[j] != NULL) { 2361 f_comb(sh_data, pr_data[j]); // combine results 2362 if (f_fini) 2363 f_fini(pr_data[j]); // finalize if needed 2364 __kmp_free(pr_data[j]); 2365 } 2366 } 2367 } 2368 __kmp_free(arr[i].reduce_priv); 2369 } 2370 __kmp_thread_free(th, arr); 2371 tg->reduce_data = NULL; 2372 tg->reduce_num_data = 0; 2373 } 2374 2375 // Cleanup task reduction data for parallel or worksharing, 2376 // do not touch task private data other threads still working with. 2377 // Called from __kmpc_end_taskgroup() 2378 static void __kmp_task_reduction_clean(kmp_info_t *th, kmp_taskgroup_t *tg) { 2379 __kmp_thread_free(th, tg->reduce_data); 2380 tg->reduce_data = NULL; 2381 tg->reduce_num_data = 0; 2382 } 2383 2384 template <typename T> 2385 void *__kmp_task_reduction_modifier_init(ident_t *loc, int gtid, int is_ws, 2386 int num, T *data) { 2387 __kmp_assert_valid_gtid(gtid); 2388 kmp_info_t *thr = __kmp_threads[gtid]; 2389 kmp_int32 nth = thr->th.th_team_nproc; 2390 __kmpc_taskgroup(loc, gtid); // form new taskgroup first 2391 if (nth == 1) { 2392 KA_TRACE(10, 2393 ("__kmpc_reduction_modifier_init: T#%d, tg %p, exiting nth=1\n", 2394 gtid, thr->th.th_current_task->td_taskgroup)); 2395 return (void *)thr->th.th_current_task->td_taskgroup; 2396 } 2397 kmp_team_t *team = thr->th.th_team; 2398 void *reduce_data; 2399 kmp_taskgroup_t *tg; 2400 reduce_data = KMP_ATOMIC_LD_RLX(&team->t.t_tg_reduce_data[is_ws]); 2401 if (reduce_data == NULL && 2402 __kmp_atomic_compare_store(&team->t.t_tg_reduce_data[is_ws], reduce_data, 2403 (void *)1)) { 2404 // single thread enters this block to initialize common reduction data 2405 KMP_DEBUG_ASSERT(reduce_data == NULL); 2406 // first initialize own data, then make a copy other threads can use 2407 tg = (kmp_taskgroup_t *)__kmp_task_reduction_init<T>(gtid, num, data); 2408 reduce_data = __kmp_thread_malloc(thr, num * sizeof(kmp_taskred_data_t)); 2409 KMP_MEMCPY(reduce_data, tg->reduce_data, num * sizeof(kmp_taskred_data_t)); 2410 // fini counters should be 0 at this point 2411 KMP_DEBUG_ASSERT(KMP_ATOMIC_LD_RLX(&team->t.t_tg_fini_counter[0]) == 0); 2412 KMP_DEBUG_ASSERT(KMP_ATOMIC_LD_RLX(&team->t.t_tg_fini_counter[1]) == 0); 2413 KMP_ATOMIC_ST_REL(&team->t.t_tg_reduce_data[is_ws], reduce_data); 2414 } else { 2415 while ( 2416 (reduce_data = KMP_ATOMIC_LD_ACQ(&team->t.t_tg_reduce_data[is_ws])) == 2417 (void *)1) { // wait for task reduction initialization 2418 KMP_CPU_PAUSE(); 2419 } 2420 KMP_DEBUG_ASSERT(reduce_data > (void *)1); // should be valid pointer here 2421 tg = thr->th.th_current_task->td_taskgroup; 2422 __kmp_task_reduction_init_copy<T>(thr, num, data, tg, reduce_data); 2423 } 2424 return tg; 2425 } 2426 2427 /*! 2428 @ingroup TASKING 2429 @param loc Source location info 2430 @param gtid Global thread ID 2431 @param is_ws Is 1 if the reduction is for worksharing, 0 otherwise 2432 @param num Number of data items to reduce 2433 @param data Array of data for reduction 2434 @return The taskgroup identifier 2435 2436 Initialize task reduction for a parallel or worksharing. 2437 2438 Note: this entry supposes the optional compiler-generated initializer routine 2439 has single parameter - pointer to object to be initialized. That means 2440 the reduction either does not use omp_orig object, or the omp_orig is accessible 2441 without help of the runtime library. 2442 */ 2443 void *__kmpc_task_reduction_modifier_init(ident_t *loc, int gtid, int is_ws, 2444 int num, void *data) { 2445 return __kmp_task_reduction_modifier_init(loc, gtid, is_ws, num, 2446 (kmp_task_red_input_t *)data); 2447 } 2448 2449 /*! 2450 @ingroup TASKING 2451 @param loc Source location info 2452 @param gtid Global thread ID 2453 @param is_ws Is 1 if the reduction is for worksharing, 0 otherwise 2454 @param num Number of data items to reduce 2455 @param data Array of data for reduction 2456 @return The taskgroup identifier 2457 2458 Initialize task reduction for a parallel or worksharing. 2459 2460 Note: this entry supposes the optional compiler-generated initializer routine 2461 has two parameters, pointer to object to be initialized and pointer to omp_orig 2462 */ 2463 void *__kmpc_taskred_modifier_init(ident_t *loc, int gtid, int is_ws, int num, 2464 void *data) { 2465 return __kmp_task_reduction_modifier_init(loc, gtid, is_ws, num, 2466 (kmp_taskred_input_t *)data); 2467 } 2468 2469 /*! 2470 @ingroup TASKING 2471 @param loc Source location info 2472 @param gtid Global thread ID 2473 @param is_ws Is 1 if the reduction is for worksharing, 0 otherwise 2474 2475 Finalize task reduction for a parallel or worksharing. 2476 */ 2477 void __kmpc_task_reduction_modifier_fini(ident_t *loc, int gtid, int is_ws) { 2478 __kmpc_end_taskgroup(loc, gtid); 2479 } 2480 2481 // __kmpc_taskgroup: Start a new taskgroup 2482 void __kmpc_taskgroup(ident_t *loc, int gtid) { 2483 __kmp_assert_valid_gtid(gtid); 2484 kmp_info_t *thread = __kmp_threads[gtid]; 2485 kmp_taskdata_t *taskdata = thread->th.th_current_task; 2486 kmp_taskgroup_t *tg_new = 2487 (kmp_taskgroup_t *)__kmp_thread_malloc(thread, sizeof(kmp_taskgroup_t)); 2488 KA_TRACE(10, ("__kmpc_taskgroup: T#%d loc=%p group=%p\n", gtid, loc, tg_new)); 2489 KMP_ATOMIC_ST_RLX(&tg_new->count, 0); 2490 KMP_ATOMIC_ST_RLX(&tg_new->cancel_request, cancel_noreq); 2491 tg_new->parent = taskdata->td_taskgroup; 2492 tg_new->reduce_data = NULL; 2493 tg_new->reduce_num_data = 0; 2494 tg_new->gomp_data = NULL; 2495 taskdata->td_taskgroup = tg_new; 2496 2497 #if OMPT_SUPPORT && OMPT_OPTIONAL 2498 if (UNLIKELY(ompt_enabled.ompt_callback_sync_region)) { 2499 void *codeptr = OMPT_LOAD_RETURN_ADDRESS(gtid); 2500 if (!codeptr) 2501 codeptr = OMPT_GET_RETURN_ADDRESS(0); 2502 kmp_team_t *team = thread->th.th_team; 2503 ompt_data_t my_task_data = taskdata->ompt_task_info.task_data; 2504 // FIXME: I think this is wrong for lwt! 2505 ompt_data_t my_parallel_data = team->t.ompt_team_info.parallel_data; 2506 2507 ompt_callbacks.ompt_callback(ompt_callback_sync_region)( 2508 ompt_sync_region_taskgroup, ompt_scope_begin, &(my_parallel_data), 2509 &(my_task_data), codeptr); 2510 } 2511 #endif 2512 } 2513 2514 // __kmpc_end_taskgroup: Wait until all tasks generated by the current task 2515 // and its descendants are complete 2516 void __kmpc_end_taskgroup(ident_t *loc, int gtid) { 2517 __kmp_assert_valid_gtid(gtid); 2518 kmp_info_t *thread = __kmp_threads[gtid]; 2519 kmp_taskdata_t *taskdata = thread->th.th_current_task; 2520 kmp_taskgroup_t *taskgroup = taskdata->td_taskgroup; 2521 int thread_finished = FALSE; 2522 2523 #if OMPT_SUPPORT && OMPT_OPTIONAL 2524 kmp_team_t *team; 2525 ompt_data_t my_task_data; 2526 ompt_data_t my_parallel_data; 2527 void *codeptr = nullptr; 2528 if (UNLIKELY(ompt_enabled.enabled)) { 2529 team = thread->th.th_team; 2530 my_task_data = taskdata->ompt_task_info.task_data; 2531 // FIXME: I think this is wrong for lwt! 2532 my_parallel_data = team->t.ompt_team_info.parallel_data; 2533 codeptr = OMPT_LOAD_RETURN_ADDRESS(gtid); 2534 if (!codeptr) 2535 codeptr = OMPT_GET_RETURN_ADDRESS(0); 2536 } 2537 #endif 2538 2539 KA_TRACE(10, ("__kmpc_end_taskgroup(enter): T#%d loc=%p\n", gtid, loc)); 2540 KMP_DEBUG_ASSERT(taskgroup != NULL); 2541 KMP_SET_THREAD_STATE_BLOCK(TASKGROUP); 2542 2543 if (__kmp_tasking_mode != tskm_immediate_exec) { 2544 // mark task as waiting not on a barrier 2545 taskdata->td_taskwait_counter += 1; 2546 taskdata->td_taskwait_ident = loc; 2547 taskdata->td_taskwait_thread = gtid + 1; 2548 #if USE_ITT_BUILD 2549 // For ITT the taskgroup wait is similar to taskwait until we need to 2550 // distinguish them 2551 void *itt_sync_obj = NULL; 2552 #if USE_ITT_NOTIFY 2553 KMP_ITT_TASKWAIT_STARTING(itt_sync_obj); 2554 #endif /* USE_ITT_NOTIFY */ 2555 #endif /* USE_ITT_BUILD */ 2556 2557 #if OMPT_SUPPORT && OMPT_OPTIONAL 2558 if (UNLIKELY(ompt_enabled.ompt_callback_sync_region_wait)) { 2559 ompt_callbacks.ompt_callback(ompt_callback_sync_region_wait)( 2560 ompt_sync_region_taskgroup, ompt_scope_begin, &(my_parallel_data), 2561 &(my_task_data), codeptr); 2562 } 2563 #endif 2564 2565 if (!taskdata->td_flags.team_serial || 2566 (thread->th.th_task_team != NULL && 2567 (thread->th.th_task_team->tt.tt_found_proxy_tasks || 2568 thread->th.th_task_team->tt.tt_hidden_helper_task_encountered))) { 2569 kmp_flag_32<false, false> flag( 2570 RCAST(std::atomic<kmp_uint32> *, &(taskgroup->count)), 0U); 2571 while (KMP_ATOMIC_LD_ACQ(&taskgroup->count) != 0) { 2572 flag.execute_tasks(thread, gtid, FALSE, 2573 &thread_finished USE_ITT_BUILD_ARG(itt_sync_obj), 2574 __kmp_task_stealing_constraint); 2575 } 2576 } 2577 taskdata->td_taskwait_thread = -taskdata->td_taskwait_thread; // end waiting 2578 2579 #if OMPT_SUPPORT && OMPT_OPTIONAL 2580 if (UNLIKELY(ompt_enabled.ompt_callback_sync_region_wait)) { 2581 ompt_callbacks.ompt_callback(ompt_callback_sync_region_wait)( 2582 ompt_sync_region_taskgroup, ompt_scope_end, &(my_parallel_data), 2583 &(my_task_data), codeptr); 2584 } 2585 #endif 2586 2587 #if USE_ITT_BUILD 2588 KMP_ITT_TASKWAIT_FINISHED(itt_sync_obj); 2589 KMP_FSYNC_ACQUIRED(taskdata); // acquire self - sync with descendants 2590 #endif /* USE_ITT_BUILD */ 2591 } 2592 KMP_DEBUG_ASSERT(taskgroup->count == 0); 2593 2594 if (taskgroup->reduce_data != NULL && 2595 !taskgroup->gomp_data) { // need to reduce? 2596 int cnt; 2597 void *reduce_data; 2598 kmp_team_t *t = thread->th.th_team; 2599 kmp_taskred_data_t *arr = (kmp_taskred_data_t *)taskgroup->reduce_data; 2600 // check if <priv> data of the first reduction variable shared for the team 2601 void *priv0 = arr[0].reduce_priv; 2602 if ((reduce_data = KMP_ATOMIC_LD_ACQ(&t->t.t_tg_reduce_data[0])) != NULL && 2603 ((kmp_taskred_data_t *)reduce_data)[0].reduce_priv == priv0) { 2604 // finishing task reduction on parallel 2605 cnt = KMP_ATOMIC_INC(&t->t.t_tg_fini_counter[0]); 2606 if (cnt == thread->th.th_team_nproc - 1) { 2607 // we are the last thread passing __kmpc_reduction_modifier_fini() 2608 // finalize task reduction: 2609 __kmp_task_reduction_fini(thread, taskgroup); 2610 // cleanup fields in the team structure: 2611 // TODO: is relaxed store enough here (whole barrier should follow)? 2612 __kmp_thread_free(thread, reduce_data); 2613 KMP_ATOMIC_ST_REL(&t->t.t_tg_reduce_data[0], NULL); 2614 KMP_ATOMIC_ST_REL(&t->t.t_tg_fini_counter[0], 0); 2615 } else { 2616 // we are not the last thread passing __kmpc_reduction_modifier_fini(), 2617 // so do not finalize reduction, just clean own copy of the data 2618 __kmp_task_reduction_clean(thread, taskgroup); 2619 } 2620 } else if ((reduce_data = KMP_ATOMIC_LD_ACQ(&t->t.t_tg_reduce_data[1])) != 2621 NULL && 2622 ((kmp_taskred_data_t *)reduce_data)[0].reduce_priv == priv0) { 2623 // finishing task reduction on worksharing 2624 cnt = KMP_ATOMIC_INC(&t->t.t_tg_fini_counter[1]); 2625 if (cnt == thread->th.th_team_nproc - 1) { 2626 // we are the last thread passing __kmpc_reduction_modifier_fini() 2627 __kmp_task_reduction_fini(thread, taskgroup); 2628 // cleanup fields in team structure: 2629 // TODO: is relaxed store enough here (whole barrier should follow)? 2630 __kmp_thread_free(thread, reduce_data); 2631 KMP_ATOMIC_ST_REL(&t->t.t_tg_reduce_data[1], NULL); 2632 KMP_ATOMIC_ST_REL(&t->t.t_tg_fini_counter[1], 0); 2633 } else { 2634 // we are not the last thread passing __kmpc_reduction_modifier_fini(), 2635 // so do not finalize reduction, just clean own copy of the data 2636 __kmp_task_reduction_clean(thread, taskgroup); 2637 } 2638 } else { 2639 // finishing task reduction on taskgroup 2640 __kmp_task_reduction_fini(thread, taskgroup); 2641 } 2642 } 2643 // Restore parent taskgroup for the current task 2644 taskdata->td_taskgroup = taskgroup->parent; 2645 __kmp_thread_free(thread, taskgroup); 2646 2647 KA_TRACE(10, ("__kmpc_end_taskgroup(exit): T#%d task %p finished waiting\n", 2648 gtid, taskdata)); 2649 2650 #if OMPT_SUPPORT && OMPT_OPTIONAL 2651 if (UNLIKELY(ompt_enabled.ompt_callback_sync_region)) { 2652 ompt_callbacks.ompt_callback(ompt_callback_sync_region)( 2653 ompt_sync_region_taskgroup, ompt_scope_end, &(my_parallel_data), 2654 &(my_task_data), codeptr); 2655 } 2656 #endif 2657 } 2658 2659 // __kmp_remove_my_task: remove a task from my own deque 2660 static kmp_task_t *__kmp_remove_my_task(kmp_info_t *thread, kmp_int32 gtid, 2661 kmp_task_team_t *task_team, 2662 kmp_int32 is_constrained) { 2663 kmp_task_t *task; 2664 kmp_taskdata_t *taskdata; 2665 kmp_thread_data_t *thread_data; 2666 kmp_uint32 tail; 2667 2668 KMP_DEBUG_ASSERT(__kmp_tasking_mode != tskm_immediate_exec); 2669 KMP_DEBUG_ASSERT(task_team->tt.tt_threads_data != 2670 NULL); // Caller should check this condition 2671 2672 thread_data = &task_team->tt.tt_threads_data[__kmp_tid_from_gtid(gtid)]; 2673 2674 KA_TRACE(10, ("__kmp_remove_my_task(enter): T#%d ntasks=%d head=%u tail=%u\n", 2675 gtid, thread_data->td.td_deque_ntasks, 2676 thread_data->td.td_deque_head, thread_data->td.td_deque_tail)); 2677 2678 if (TCR_4(thread_data->td.td_deque_ntasks) == 0) { 2679 KA_TRACE(10, 2680 ("__kmp_remove_my_task(exit #1): T#%d No tasks to remove: " 2681 "ntasks=%d head=%u tail=%u\n", 2682 gtid, thread_data->td.td_deque_ntasks, 2683 thread_data->td.td_deque_head, thread_data->td.td_deque_tail)); 2684 return NULL; 2685 } 2686 2687 __kmp_acquire_bootstrap_lock(&thread_data->td.td_deque_lock); 2688 2689 if (TCR_4(thread_data->td.td_deque_ntasks) == 0) { 2690 __kmp_release_bootstrap_lock(&thread_data->td.td_deque_lock); 2691 KA_TRACE(10, 2692 ("__kmp_remove_my_task(exit #2): T#%d No tasks to remove: " 2693 "ntasks=%d head=%u tail=%u\n", 2694 gtid, thread_data->td.td_deque_ntasks, 2695 thread_data->td.td_deque_head, thread_data->td.td_deque_tail)); 2696 return NULL; 2697 } 2698 2699 tail = (thread_data->td.td_deque_tail - 1) & 2700 TASK_DEQUE_MASK(thread_data->td); // Wrap index. 2701 taskdata = thread_data->td.td_deque[tail]; 2702 2703 if (!__kmp_task_is_allowed(gtid, is_constrained, taskdata, 2704 thread->th.th_current_task)) { 2705 // The TSC does not allow to steal victim task 2706 __kmp_release_bootstrap_lock(&thread_data->td.td_deque_lock); 2707 KA_TRACE(10, 2708 ("__kmp_remove_my_task(exit #3): T#%d TSC blocks tail task: " 2709 "ntasks=%d head=%u tail=%u\n", 2710 gtid, thread_data->td.td_deque_ntasks, 2711 thread_data->td.td_deque_head, thread_data->td.td_deque_tail)); 2712 return NULL; 2713 } 2714 2715 thread_data->td.td_deque_tail = tail; 2716 TCW_4(thread_data->td.td_deque_ntasks, thread_data->td.td_deque_ntasks - 1); 2717 2718 __kmp_release_bootstrap_lock(&thread_data->td.td_deque_lock); 2719 2720 KA_TRACE(10, ("__kmp_remove_my_task(exit #4): T#%d task %p removed: " 2721 "ntasks=%d head=%u tail=%u\n", 2722 gtid, taskdata, thread_data->td.td_deque_ntasks, 2723 thread_data->td.td_deque_head, thread_data->td.td_deque_tail)); 2724 2725 task = KMP_TASKDATA_TO_TASK(taskdata); 2726 return task; 2727 } 2728 2729 // __kmp_steal_task: remove a task from another thread's deque 2730 // Assume that calling thread has already checked existence of 2731 // task_team thread_data before calling this routine. 2732 static kmp_task_t *__kmp_steal_task(kmp_info_t *victim_thr, kmp_int32 gtid, 2733 kmp_task_team_t *task_team, 2734 std::atomic<kmp_int32> *unfinished_threads, 2735 int *thread_finished, 2736 kmp_int32 is_constrained) { 2737 kmp_task_t *task; 2738 kmp_taskdata_t *taskdata; 2739 kmp_taskdata_t *current; 2740 kmp_thread_data_t *victim_td, *threads_data; 2741 kmp_int32 target; 2742 kmp_int32 victim_tid; 2743 2744 KMP_DEBUG_ASSERT(__kmp_tasking_mode != tskm_immediate_exec); 2745 2746 threads_data = task_team->tt.tt_threads_data; 2747 KMP_DEBUG_ASSERT(threads_data != NULL); // Caller should check this condition 2748 2749 victim_tid = victim_thr->th.th_info.ds.ds_tid; 2750 victim_td = &threads_data[victim_tid]; 2751 2752 KA_TRACE(10, ("__kmp_steal_task(enter): T#%d try to steal from T#%d: " 2753 "task_team=%p ntasks=%d head=%u tail=%u\n", 2754 gtid, __kmp_gtid_from_thread(victim_thr), task_team, 2755 victim_td->td.td_deque_ntasks, victim_td->td.td_deque_head, 2756 victim_td->td.td_deque_tail)); 2757 2758 if (TCR_4(victim_td->td.td_deque_ntasks) == 0) { 2759 KA_TRACE(10, ("__kmp_steal_task(exit #1): T#%d could not steal from T#%d: " 2760 "task_team=%p ntasks=%d head=%u tail=%u\n", 2761 gtid, __kmp_gtid_from_thread(victim_thr), task_team, 2762 victim_td->td.td_deque_ntasks, victim_td->td.td_deque_head, 2763 victim_td->td.td_deque_tail)); 2764 return NULL; 2765 } 2766 2767 __kmp_acquire_bootstrap_lock(&victim_td->td.td_deque_lock); 2768 2769 int ntasks = TCR_4(victim_td->td.td_deque_ntasks); 2770 // Check again after we acquire the lock 2771 if (ntasks == 0) { 2772 __kmp_release_bootstrap_lock(&victim_td->td.td_deque_lock); 2773 KA_TRACE(10, ("__kmp_steal_task(exit #2): T#%d could not steal from T#%d: " 2774 "task_team=%p ntasks=%d head=%u tail=%u\n", 2775 gtid, __kmp_gtid_from_thread(victim_thr), task_team, ntasks, 2776 victim_td->td.td_deque_head, victim_td->td.td_deque_tail)); 2777 return NULL; 2778 } 2779 2780 KMP_DEBUG_ASSERT(victim_td->td.td_deque != NULL); 2781 current = __kmp_threads[gtid]->th.th_current_task; 2782 taskdata = victim_td->td.td_deque[victim_td->td.td_deque_head]; 2783 if (__kmp_task_is_allowed(gtid, is_constrained, taskdata, current)) { 2784 // Bump head pointer and Wrap. 2785 victim_td->td.td_deque_head = 2786 (victim_td->td.td_deque_head + 1) & TASK_DEQUE_MASK(victim_td->td); 2787 } else { 2788 if (!task_team->tt.tt_untied_task_encountered) { 2789 // The TSC does not allow to steal victim task 2790 __kmp_release_bootstrap_lock(&victim_td->td.td_deque_lock); 2791 KA_TRACE(10, ("__kmp_steal_task(exit #3): T#%d could not steal from " 2792 "T#%d: task_team=%p ntasks=%d head=%u tail=%u\n", 2793 gtid, __kmp_gtid_from_thread(victim_thr), task_team, ntasks, 2794 victim_td->td.td_deque_head, victim_td->td.td_deque_tail)); 2795 return NULL; 2796 } 2797 int i; 2798 // walk through victim's deque trying to steal any task 2799 target = victim_td->td.td_deque_head; 2800 taskdata = NULL; 2801 for (i = 1; i < ntasks; ++i) { 2802 target = (target + 1) & TASK_DEQUE_MASK(victim_td->td); 2803 taskdata = victim_td->td.td_deque[target]; 2804 if (__kmp_task_is_allowed(gtid, is_constrained, taskdata, current)) { 2805 break; // found victim task 2806 } else { 2807 taskdata = NULL; 2808 } 2809 } 2810 if (taskdata == NULL) { 2811 // No appropriate candidate to steal found 2812 __kmp_release_bootstrap_lock(&victim_td->td.td_deque_lock); 2813 KA_TRACE(10, ("__kmp_steal_task(exit #4): T#%d could not steal from " 2814 "T#%d: task_team=%p ntasks=%d head=%u tail=%u\n", 2815 gtid, __kmp_gtid_from_thread(victim_thr), task_team, ntasks, 2816 victim_td->td.td_deque_head, victim_td->td.td_deque_tail)); 2817 return NULL; 2818 } 2819 int prev = target; 2820 for (i = i + 1; i < ntasks; ++i) { 2821 // shift remaining tasks in the deque left by 1 2822 target = (target + 1) & TASK_DEQUE_MASK(victim_td->td); 2823 victim_td->td.td_deque[prev] = victim_td->td.td_deque[target]; 2824 prev = target; 2825 } 2826 KMP_DEBUG_ASSERT( 2827 victim_td->td.td_deque_tail == 2828 (kmp_uint32)((target + 1) & TASK_DEQUE_MASK(victim_td->td))); 2829 victim_td->td.td_deque_tail = target; // tail -= 1 (wrapped)) 2830 } 2831 if (*thread_finished) { 2832 // We need to un-mark this victim as a finished victim. This must be done 2833 // before releasing the lock, or else other threads (starting with the 2834 // primary thread victim) might be prematurely released from the barrier!!! 2835 kmp_int32 count; 2836 2837 count = KMP_ATOMIC_INC(unfinished_threads); 2838 2839 KA_TRACE( 2840 20, 2841 ("__kmp_steal_task: T#%d inc unfinished_threads to %d: task_team=%p\n", 2842 gtid, count + 1, task_team)); 2843 2844 *thread_finished = FALSE; 2845 } 2846 TCW_4(victim_td->td.td_deque_ntasks, ntasks - 1); 2847 2848 __kmp_release_bootstrap_lock(&victim_td->td.td_deque_lock); 2849 2850 KMP_COUNT_BLOCK(TASK_stolen); 2851 KA_TRACE(10, 2852 ("__kmp_steal_task(exit #5): T#%d stole task %p from T#%d: " 2853 "task_team=%p ntasks=%d head=%u tail=%u\n", 2854 gtid, taskdata, __kmp_gtid_from_thread(victim_thr), task_team, 2855 ntasks, victim_td->td.td_deque_head, victim_td->td.td_deque_tail)); 2856 2857 task = KMP_TASKDATA_TO_TASK(taskdata); 2858 return task; 2859 } 2860 2861 // __kmp_execute_tasks_template: Choose and execute tasks until either the 2862 // condition is statisfied (return true) or there are none left (return false). 2863 // 2864 // final_spin is TRUE if this is the spin at the release barrier. 2865 // thread_finished indicates whether the thread is finished executing all 2866 // the tasks it has on its deque, and is at the release barrier. 2867 // spinner is the location on which to spin. 2868 // spinner == NULL means only execute a single task and return. 2869 // checker is the value to check to terminate the spin. 2870 template <class C> 2871 static inline int __kmp_execute_tasks_template( 2872 kmp_info_t *thread, kmp_int32 gtid, C *flag, int final_spin, 2873 int *thread_finished USE_ITT_BUILD_ARG(void *itt_sync_obj), 2874 kmp_int32 is_constrained) { 2875 kmp_task_team_t *task_team = thread->th.th_task_team; 2876 kmp_thread_data_t *threads_data; 2877 kmp_task_t *task; 2878 kmp_info_t *other_thread; 2879 kmp_taskdata_t *current_task = thread->th.th_current_task; 2880 std::atomic<kmp_int32> *unfinished_threads; 2881 kmp_int32 nthreads, victim_tid = -2, use_own_tasks = 1, new_victim = 0, 2882 tid = thread->th.th_info.ds.ds_tid; 2883 2884 KMP_DEBUG_ASSERT(__kmp_tasking_mode != tskm_immediate_exec); 2885 KMP_DEBUG_ASSERT(thread == __kmp_threads[gtid]); 2886 2887 if (task_team == NULL || current_task == NULL) 2888 return FALSE; 2889 2890 KA_TRACE(15, ("__kmp_execute_tasks_template(enter): T#%d final_spin=%d " 2891 "*thread_finished=%d\n", 2892 gtid, final_spin, *thread_finished)); 2893 2894 thread->th.th_reap_state = KMP_NOT_SAFE_TO_REAP; 2895 threads_data = (kmp_thread_data_t *)TCR_PTR(task_team->tt.tt_threads_data); 2896 2897 KMP_DEBUG_ASSERT(threads_data != NULL); 2898 2899 nthreads = task_team->tt.tt_nproc; 2900 unfinished_threads = &(task_team->tt.tt_unfinished_threads); 2901 KMP_DEBUG_ASSERT(nthreads > 1 || task_team->tt.tt_found_proxy_tasks || 2902 task_team->tt.tt_hidden_helper_task_encountered); 2903 KMP_DEBUG_ASSERT(*unfinished_threads >= 0); 2904 2905 while (1) { // Outer loop keeps trying to find tasks in case of single thread 2906 // getting tasks from target constructs 2907 while (1) { // Inner loop to find a task and execute it 2908 task = NULL; 2909 if (use_own_tasks) { // check on own queue first 2910 task = __kmp_remove_my_task(thread, gtid, task_team, is_constrained); 2911 } 2912 if ((task == NULL) && (nthreads > 1)) { // Steal a task 2913 int asleep = 1; 2914 use_own_tasks = 0; 2915 // Try to steal from the last place I stole from successfully. 2916 if (victim_tid == -2) { // haven't stolen anything yet 2917 victim_tid = threads_data[tid].td.td_deque_last_stolen; 2918 if (victim_tid != 2919 -1) // if we have a last stolen from victim, get the thread 2920 other_thread = threads_data[victim_tid].td.td_thr; 2921 } 2922 if (victim_tid != -1) { // found last victim 2923 asleep = 0; 2924 } else if (!new_victim) { // no recent steals and we haven't already 2925 // used a new victim; select a random thread 2926 do { // Find a different thread to steal work from. 2927 // Pick a random thread. Initial plan was to cycle through all the 2928 // threads, and only return if we tried to steal from every thread, 2929 // and failed. Arch says that's not such a great idea. 2930 victim_tid = __kmp_get_random(thread) % (nthreads - 1); 2931 if (victim_tid >= tid) { 2932 ++victim_tid; // Adjusts random distribution to exclude self 2933 } 2934 // Found a potential victim 2935 other_thread = threads_data[victim_tid].td.td_thr; 2936 // There is a slight chance that __kmp_enable_tasking() did not wake 2937 // up all threads waiting at the barrier. If victim is sleeping, 2938 // then wake it up. Since we were going to pay the cache miss 2939 // penalty for referencing another thread's kmp_info_t struct 2940 // anyway, 2941 // the check shouldn't cost too much performance at this point. In 2942 // extra barrier mode, tasks do not sleep at the separate tasking 2943 // barrier, so this isn't a problem. 2944 asleep = 0; 2945 if ((__kmp_tasking_mode == tskm_task_teams) && 2946 (__kmp_dflt_blocktime != KMP_MAX_BLOCKTIME) && 2947 (TCR_PTR(CCAST(void *, other_thread->th.th_sleep_loc)) != 2948 NULL)) { 2949 asleep = 1; 2950 __kmp_null_resume_wrapper(other_thread); 2951 // A sleeping thread should not have any tasks on it's queue. 2952 // There is a slight possibility that it resumes, steals a task 2953 // from another thread, which spawns more tasks, all in the time 2954 // that it takes this thread to check => don't write an assertion 2955 // that the victim's queue is empty. Try stealing from a 2956 // different thread. 2957 } 2958 } while (asleep); 2959 } 2960 2961 if (!asleep) { 2962 // We have a victim to try to steal from 2963 task = __kmp_steal_task(other_thread, gtid, task_team, 2964 unfinished_threads, thread_finished, 2965 is_constrained); 2966 } 2967 if (task != NULL) { // set last stolen to victim 2968 if (threads_data[tid].td.td_deque_last_stolen != victim_tid) { 2969 threads_data[tid].td.td_deque_last_stolen = victim_tid; 2970 // The pre-refactored code did not try more than 1 successful new 2971 // vicitm, unless the last one generated more local tasks; 2972 // new_victim keeps track of this 2973 new_victim = 1; 2974 } 2975 } else { // No tasks found; unset last_stolen 2976 KMP_CHECK_UPDATE(threads_data[tid].td.td_deque_last_stolen, -1); 2977 victim_tid = -2; // no successful victim found 2978 } 2979 } 2980 2981 if (task == NULL) 2982 break; // break out of tasking loop 2983 2984 // Found a task; execute it 2985 #if USE_ITT_BUILD && USE_ITT_NOTIFY 2986 if (__itt_sync_create_ptr || KMP_ITT_DEBUG) { 2987 if (itt_sync_obj == NULL) { // we are at fork barrier where we could not 2988 // get the object reliably 2989 itt_sync_obj = __kmp_itt_barrier_object(gtid, bs_forkjoin_barrier); 2990 } 2991 __kmp_itt_task_starting(itt_sync_obj); 2992 } 2993 #endif /* USE_ITT_BUILD && USE_ITT_NOTIFY */ 2994 __kmp_invoke_task(gtid, task, current_task); 2995 #if USE_ITT_BUILD 2996 if (itt_sync_obj != NULL) 2997 __kmp_itt_task_finished(itt_sync_obj); 2998 #endif /* USE_ITT_BUILD */ 2999 // If this thread is only partway through the barrier and the condition is 3000 // met, then return now, so that the barrier gather/release pattern can 3001 // proceed. If this thread is in the last spin loop in the barrier, 3002 // waiting to be released, we know that the termination condition will not 3003 // be satisfied, so don't waste any cycles checking it. 3004 if (flag == NULL || (!final_spin && flag->done_check())) { 3005 KA_TRACE( 3006 15, 3007 ("__kmp_execute_tasks_template: T#%d spin condition satisfied\n", 3008 gtid)); 3009 return TRUE; 3010 } 3011 if (thread->th.th_task_team == NULL) { 3012 break; 3013 } 3014 KMP_YIELD(__kmp_library == library_throughput); // Yield before next task 3015 // If execution of a stolen task results in more tasks being placed on our 3016 // run queue, reset use_own_tasks 3017 if (!use_own_tasks && TCR_4(threads_data[tid].td.td_deque_ntasks) != 0) { 3018 KA_TRACE(20, ("__kmp_execute_tasks_template: T#%d stolen task spawned " 3019 "other tasks, restart\n", 3020 gtid)); 3021 use_own_tasks = 1; 3022 new_victim = 0; 3023 } 3024 } 3025 3026 // The task source has been exhausted. If in final spin loop of barrier, 3027 // check if termination condition is satisfied. The work queue may be empty 3028 // but there might be proxy tasks still executing. 3029 if (final_spin && 3030 KMP_ATOMIC_LD_ACQ(¤t_task->td_incomplete_child_tasks) == 0) { 3031 // First, decrement the #unfinished threads, if that has not already been 3032 // done. This decrement might be to the spin location, and result in the 3033 // termination condition being satisfied. 3034 if (!*thread_finished) { 3035 kmp_int32 count; 3036 3037 count = KMP_ATOMIC_DEC(unfinished_threads) - 1; 3038 KA_TRACE(20, ("__kmp_execute_tasks_template: T#%d dec " 3039 "unfinished_threads to %d task_team=%p\n", 3040 gtid, count, task_team)); 3041 *thread_finished = TRUE; 3042 } 3043 3044 // It is now unsafe to reference thread->th.th_team !!! 3045 // Decrementing task_team->tt.tt_unfinished_threads can allow the primary 3046 // thread to pass through the barrier, where it might reset each thread's 3047 // th.th_team field for the next parallel region. If we can steal more 3048 // work, we know that this has not happened yet. 3049 if (flag != NULL && flag->done_check()) { 3050 KA_TRACE( 3051 15, 3052 ("__kmp_execute_tasks_template: T#%d spin condition satisfied\n", 3053 gtid)); 3054 return TRUE; 3055 } 3056 } 3057 3058 // If this thread's task team is NULL, primary thread has recognized that 3059 // there are no more tasks; bail out 3060 if (thread->th.th_task_team == NULL) { 3061 KA_TRACE(15, 3062 ("__kmp_execute_tasks_template: T#%d no more tasks\n", gtid)); 3063 return FALSE; 3064 } 3065 3066 // We could be getting tasks from target constructs; if this is the only 3067 // thread, keep trying to execute tasks from own queue 3068 if (nthreads == 1 && 3069 KMP_ATOMIC_LD_ACQ(¤t_task->td_incomplete_child_tasks)) 3070 use_own_tasks = 1; 3071 else { 3072 KA_TRACE(15, 3073 ("__kmp_execute_tasks_template: T#%d can't find work\n", gtid)); 3074 return FALSE; 3075 } 3076 } 3077 } 3078 3079 template <bool C, bool S> 3080 int __kmp_execute_tasks_32( 3081 kmp_info_t *thread, kmp_int32 gtid, kmp_flag_32<C, S> *flag, int final_spin, 3082 int *thread_finished USE_ITT_BUILD_ARG(void *itt_sync_obj), 3083 kmp_int32 is_constrained) { 3084 return __kmp_execute_tasks_template( 3085 thread, gtid, flag, final_spin, 3086 thread_finished USE_ITT_BUILD_ARG(itt_sync_obj), is_constrained); 3087 } 3088 3089 template <bool C, bool S> 3090 int __kmp_execute_tasks_64( 3091 kmp_info_t *thread, kmp_int32 gtid, kmp_flag_64<C, S> *flag, int final_spin, 3092 int *thread_finished USE_ITT_BUILD_ARG(void *itt_sync_obj), 3093 kmp_int32 is_constrained) { 3094 return __kmp_execute_tasks_template( 3095 thread, gtid, flag, final_spin, 3096 thread_finished USE_ITT_BUILD_ARG(itt_sync_obj), is_constrained); 3097 } 3098 3099 template <bool C, bool S> 3100 int __kmp_atomic_execute_tasks_64( 3101 kmp_info_t *thread, kmp_int32 gtid, kmp_atomic_flag_64<C, S> *flag, 3102 int final_spin, int *thread_finished USE_ITT_BUILD_ARG(void *itt_sync_obj), 3103 kmp_int32 is_constrained) { 3104 return __kmp_execute_tasks_template( 3105 thread, gtid, flag, final_spin, 3106 thread_finished USE_ITT_BUILD_ARG(itt_sync_obj), is_constrained); 3107 } 3108 3109 int __kmp_execute_tasks_oncore( 3110 kmp_info_t *thread, kmp_int32 gtid, kmp_flag_oncore *flag, int final_spin, 3111 int *thread_finished USE_ITT_BUILD_ARG(void *itt_sync_obj), 3112 kmp_int32 is_constrained) { 3113 return __kmp_execute_tasks_template( 3114 thread, gtid, flag, final_spin, 3115 thread_finished USE_ITT_BUILD_ARG(itt_sync_obj), is_constrained); 3116 } 3117 3118 template int 3119 __kmp_execute_tasks_32<false, false>(kmp_info_t *, kmp_int32, 3120 kmp_flag_32<false, false> *, int, 3121 int *USE_ITT_BUILD_ARG(void *), kmp_int32); 3122 3123 template int __kmp_execute_tasks_64<false, true>(kmp_info_t *, kmp_int32, 3124 kmp_flag_64<false, true> *, 3125 int, 3126 int *USE_ITT_BUILD_ARG(void *), 3127 kmp_int32); 3128 3129 template int __kmp_execute_tasks_64<true, false>(kmp_info_t *, kmp_int32, 3130 kmp_flag_64<true, false> *, 3131 int, 3132 int *USE_ITT_BUILD_ARG(void *), 3133 kmp_int32); 3134 3135 template int __kmp_atomic_execute_tasks_64<false, true>( 3136 kmp_info_t *, kmp_int32, kmp_atomic_flag_64<false, true> *, int, 3137 int *USE_ITT_BUILD_ARG(void *), kmp_int32); 3138 3139 template int __kmp_atomic_execute_tasks_64<true, false>( 3140 kmp_info_t *, kmp_int32, kmp_atomic_flag_64<true, false> *, int, 3141 int *USE_ITT_BUILD_ARG(void *), kmp_int32); 3142 3143 // __kmp_enable_tasking: Allocate task team and resume threads sleeping at the 3144 // next barrier so they can assist in executing enqueued tasks. 3145 // First thread in allocates the task team atomically. 3146 static void __kmp_enable_tasking(kmp_task_team_t *task_team, 3147 kmp_info_t *this_thr) { 3148 kmp_thread_data_t *threads_data; 3149 int nthreads, i, is_init_thread; 3150 3151 KA_TRACE(10, ("__kmp_enable_tasking(enter): T#%d\n", 3152 __kmp_gtid_from_thread(this_thr))); 3153 3154 KMP_DEBUG_ASSERT(task_team != NULL); 3155 KMP_DEBUG_ASSERT(this_thr->th.th_team != NULL); 3156 3157 nthreads = task_team->tt.tt_nproc; 3158 KMP_DEBUG_ASSERT(nthreads > 0); 3159 KMP_DEBUG_ASSERT(nthreads == this_thr->th.th_team->t.t_nproc); 3160 3161 // Allocate or increase the size of threads_data if necessary 3162 is_init_thread = __kmp_realloc_task_threads_data(this_thr, task_team); 3163 3164 if (!is_init_thread) { 3165 // Some other thread already set up the array. 3166 KA_TRACE( 3167 20, 3168 ("__kmp_enable_tasking(exit): T#%d: threads array already set up.\n", 3169 __kmp_gtid_from_thread(this_thr))); 3170 return; 3171 } 3172 threads_data = (kmp_thread_data_t *)TCR_PTR(task_team->tt.tt_threads_data); 3173 KMP_DEBUG_ASSERT(threads_data != NULL); 3174 3175 if (__kmp_tasking_mode == tskm_task_teams && 3176 (__kmp_dflt_blocktime != KMP_MAX_BLOCKTIME)) { 3177 // Release any threads sleeping at the barrier, so that they can steal 3178 // tasks and execute them. In extra barrier mode, tasks do not sleep 3179 // at the separate tasking barrier, so this isn't a problem. 3180 for (i = 0; i < nthreads; i++) { 3181 void *sleep_loc; 3182 kmp_info_t *thread = threads_data[i].td.td_thr; 3183 3184 if (i == this_thr->th.th_info.ds.ds_tid) { 3185 continue; 3186 } 3187 // Since we haven't locked the thread's suspend mutex lock at this 3188 // point, there is a small window where a thread might be putting 3189 // itself to sleep, but hasn't set the th_sleep_loc field yet. 3190 // To work around this, __kmp_execute_tasks_template() periodically checks 3191 // see if other threads are sleeping (using the same random mechanism that 3192 // is used for task stealing) and awakens them if they are. 3193 if ((sleep_loc = TCR_PTR(CCAST(void *, thread->th.th_sleep_loc))) != 3194 NULL) { 3195 KF_TRACE(50, ("__kmp_enable_tasking: T#%d waking up thread T#%d\n", 3196 __kmp_gtid_from_thread(this_thr), 3197 __kmp_gtid_from_thread(thread))); 3198 __kmp_null_resume_wrapper(thread); 3199 } else { 3200 KF_TRACE(50, ("__kmp_enable_tasking: T#%d don't wake up thread T#%d\n", 3201 __kmp_gtid_from_thread(this_thr), 3202 __kmp_gtid_from_thread(thread))); 3203 } 3204 } 3205 } 3206 3207 KA_TRACE(10, ("__kmp_enable_tasking(exit): T#%d\n", 3208 __kmp_gtid_from_thread(this_thr))); 3209 } 3210 3211 /* // TODO: Check the comment consistency 3212 * Utility routines for "task teams". A task team (kmp_task_t) is kind of 3213 * like a shadow of the kmp_team_t data struct, with a different lifetime. 3214 * After a child * thread checks into a barrier and calls __kmp_release() from 3215 * the particular variant of __kmp_<barrier_kind>_barrier_gather(), it can no 3216 * longer assume that the kmp_team_t structure is intact (at any moment, the 3217 * primary thread may exit the barrier code and free the team data structure, 3218 * and return the threads to the thread pool). 3219 * 3220 * This does not work with the tasking code, as the thread is still 3221 * expected to participate in the execution of any tasks that may have been 3222 * spawned my a member of the team, and the thread still needs access to all 3223 * to each thread in the team, so that it can steal work from it. 3224 * 3225 * Enter the existence of the kmp_task_team_t struct. It employs a reference 3226 * counting mechanism, and is allocated by the primary thread before calling 3227 * __kmp_<barrier_kind>_release, and then is release by the last thread to 3228 * exit __kmp_<barrier_kind>_release at the next barrier. I.e. the lifetimes 3229 * of the kmp_task_team_t structs for consecutive barriers can overlap 3230 * (and will, unless the primary thread is the last thread to exit the barrier 3231 * release phase, which is not typical). The existence of such a struct is 3232 * useful outside the context of tasking. 3233 * 3234 * We currently use the existence of the threads array as an indicator that 3235 * tasks were spawned since the last barrier. If the structure is to be 3236 * useful outside the context of tasking, then this will have to change, but 3237 * not setting the field minimizes the performance impact of tasking on 3238 * barriers, when no explicit tasks were spawned (pushed, actually). 3239 */ 3240 3241 static kmp_task_team_t *__kmp_free_task_teams = 3242 NULL; // Free list for task_team data structures 3243 // Lock for task team data structures 3244 kmp_bootstrap_lock_t __kmp_task_team_lock = 3245 KMP_BOOTSTRAP_LOCK_INITIALIZER(__kmp_task_team_lock); 3246 3247 // __kmp_alloc_task_deque: 3248 // Allocates a task deque for a particular thread, and initialize the necessary 3249 // data structures relating to the deque. This only happens once per thread 3250 // per task team since task teams are recycled. No lock is needed during 3251 // allocation since each thread allocates its own deque. 3252 static void __kmp_alloc_task_deque(kmp_info_t *thread, 3253 kmp_thread_data_t *thread_data) { 3254 __kmp_init_bootstrap_lock(&thread_data->td.td_deque_lock); 3255 KMP_DEBUG_ASSERT(thread_data->td.td_deque == NULL); 3256 3257 // Initialize last stolen task field to "none" 3258 thread_data->td.td_deque_last_stolen = -1; 3259 3260 KMP_DEBUG_ASSERT(TCR_4(thread_data->td.td_deque_ntasks) == 0); 3261 KMP_DEBUG_ASSERT(thread_data->td.td_deque_head == 0); 3262 KMP_DEBUG_ASSERT(thread_data->td.td_deque_tail == 0); 3263 3264 KE_TRACE( 3265 10, 3266 ("__kmp_alloc_task_deque: T#%d allocating deque[%d] for thread_data %p\n", 3267 __kmp_gtid_from_thread(thread), INITIAL_TASK_DEQUE_SIZE, thread_data)); 3268 // Allocate space for task deque, and zero the deque 3269 // Cannot use __kmp_thread_calloc() because threads not around for 3270 // kmp_reap_task_team( ). 3271 thread_data->td.td_deque = (kmp_taskdata_t **)__kmp_allocate( 3272 INITIAL_TASK_DEQUE_SIZE * sizeof(kmp_taskdata_t *)); 3273 thread_data->td.td_deque_size = INITIAL_TASK_DEQUE_SIZE; 3274 } 3275 3276 // __kmp_free_task_deque: 3277 // Deallocates a task deque for a particular thread. Happens at library 3278 // deallocation so don't need to reset all thread data fields. 3279 static void __kmp_free_task_deque(kmp_thread_data_t *thread_data) { 3280 if (thread_data->td.td_deque != NULL) { 3281 __kmp_acquire_bootstrap_lock(&thread_data->td.td_deque_lock); 3282 TCW_4(thread_data->td.td_deque_ntasks, 0); 3283 __kmp_free(thread_data->td.td_deque); 3284 thread_data->td.td_deque = NULL; 3285 __kmp_release_bootstrap_lock(&thread_data->td.td_deque_lock); 3286 } 3287 3288 #ifdef BUILD_TIED_TASK_STACK 3289 // GEH: Figure out what to do here for td_susp_tied_tasks 3290 if (thread_data->td.td_susp_tied_tasks.ts_entries != TASK_STACK_EMPTY) { 3291 __kmp_free_task_stack(__kmp_thread_from_gtid(gtid), thread_data); 3292 } 3293 #endif // BUILD_TIED_TASK_STACK 3294 } 3295 3296 // __kmp_realloc_task_threads_data: 3297 // Allocates a threads_data array for a task team, either by allocating an 3298 // initial array or enlarging an existing array. Only the first thread to get 3299 // the lock allocs or enlarges the array and re-initializes the array elements. 3300 // That thread returns "TRUE", the rest return "FALSE". 3301 // Assumes that the new array size is given by task_team -> tt.tt_nproc. 3302 // The current size is given by task_team -> tt.tt_max_threads. 3303 static int __kmp_realloc_task_threads_data(kmp_info_t *thread, 3304 kmp_task_team_t *task_team) { 3305 kmp_thread_data_t **threads_data_p; 3306 kmp_int32 nthreads, maxthreads; 3307 int is_init_thread = FALSE; 3308 3309 if (TCR_4(task_team->tt.tt_found_tasks)) { 3310 // Already reallocated and initialized. 3311 return FALSE; 3312 } 3313 3314 threads_data_p = &task_team->tt.tt_threads_data; 3315 nthreads = task_team->tt.tt_nproc; 3316 maxthreads = task_team->tt.tt_max_threads; 3317 3318 // All threads must lock when they encounter the first task of the implicit 3319 // task region to make sure threads_data fields are (re)initialized before 3320 // used. 3321 __kmp_acquire_bootstrap_lock(&task_team->tt.tt_threads_lock); 3322 3323 if (!TCR_4(task_team->tt.tt_found_tasks)) { 3324 // first thread to enable tasking 3325 kmp_team_t *team = thread->th.th_team; 3326 int i; 3327 3328 is_init_thread = TRUE; 3329 if (maxthreads < nthreads) { 3330 3331 if (*threads_data_p != NULL) { 3332 kmp_thread_data_t *old_data = *threads_data_p; 3333 kmp_thread_data_t *new_data = NULL; 3334 3335 KE_TRACE( 3336 10, 3337 ("__kmp_realloc_task_threads_data: T#%d reallocating " 3338 "threads data for task_team %p, new_size = %d, old_size = %d\n", 3339 __kmp_gtid_from_thread(thread), task_team, nthreads, maxthreads)); 3340 // Reallocate threads_data to have more elements than current array 3341 // Cannot use __kmp_thread_realloc() because threads not around for 3342 // kmp_reap_task_team( ). Note all new array entries are initialized 3343 // to zero by __kmp_allocate(). 3344 new_data = (kmp_thread_data_t *)__kmp_allocate( 3345 nthreads * sizeof(kmp_thread_data_t)); 3346 // copy old data to new data 3347 KMP_MEMCPY_S((void *)new_data, nthreads * sizeof(kmp_thread_data_t), 3348 (void *)old_data, maxthreads * sizeof(kmp_thread_data_t)); 3349 3350 #ifdef BUILD_TIED_TASK_STACK 3351 // GEH: Figure out if this is the right thing to do 3352 for (i = maxthreads; i < nthreads; i++) { 3353 kmp_thread_data_t *thread_data = &(*threads_data_p)[i]; 3354 __kmp_init_task_stack(__kmp_gtid_from_thread(thread), thread_data); 3355 } 3356 #endif // BUILD_TIED_TASK_STACK 3357 // Install the new data and free the old data 3358 (*threads_data_p) = new_data; 3359 __kmp_free(old_data); 3360 } else { 3361 KE_TRACE(10, ("__kmp_realloc_task_threads_data: T#%d allocating " 3362 "threads data for task_team %p, size = %d\n", 3363 __kmp_gtid_from_thread(thread), task_team, nthreads)); 3364 // Make the initial allocate for threads_data array, and zero entries 3365 // Cannot use __kmp_thread_calloc() because threads not around for 3366 // kmp_reap_task_team( ). 3367 *threads_data_p = (kmp_thread_data_t *)__kmp_allocate( 3368 nthreads * sizeof(kmp_thread_data_t)); 3369 #ifdef BUILD_TIED_TASK_STACK 3370 // GEH: Figure out if this is the right thing to do 3371 for (i = 0; i < nthreads; i++) { 3372 kmp_thread_data_t *thread_data = &(*threads_data_p)[i]; 3373 __kmp_init_task_stack(__kmp_gtid_from_thread(thread), thread_data); 3374 } 3375 #endif // BUILD_TIED_TASK_STACK 3376 } 3377 task_team->tt.tt_max_threads = nthreads; 3378 } else { 3379 // If array has (more than) enough elements, go ahead and use it 3380 KMP_DEBUG_ASSERT(*threads_data_p != NULL); 3381 } 3382 3383 // initialize threads_data pointers back to thread_info structures 3384 for (i = 0; i < nthreads; i++) { 3385 kmp_thread_data_t *thread_data = &(*threads_data_p)[i]; 3386 thread_data->td.td_thr = team->t.t_threads[i]; 3387 3388 if (thread_data->td.td_deque_last_stolen >= nthreads) { 3389 // The last stolen field survives across teams / barrier, and the number 3390 // of threads may have changed. It's possible (likely?) that a new 3391 // parallel region will exhibit the same behavior as previous region. 3392 thread_data->td.td_deque_last_stolen = -1; 3393 } 3394 } 3395 3396 KMP_MB(); 3397 TCW_SYNC_4(task_team->tt.tt_found_tasks, TRUE); 3398 } 3399 3400 __kmp_release_bootstrap_lock(&task_team->tt.tt_threads_lock); 3401 return is_init_thread; 3402 } 3403 3404 // __kmp_free_task_threads_data: 3405 // Deallocates a threads_data array for a task team, including any attached 3406 // tasking deques. Only occurs at library shutdown. 3407 static void __kmp_free_task_threads_data(kmp_task_team_t *task_team) { 3408 __kmp_acquire_bootstrap_lock(&task_team->tt.tt_threads_lock); 3409 if (task_team->tt.tt_threads_data != NULL) { 3410 int i; 3411 for (i = 0; i < task_team->tt.tt_max_threads; i++) { 3412 __kmp_free_task_deque(&task_team->tt.tt_threads_data[i]); 3413 } 3414 __kmp_free(task_team->tt.tt_threads_data); 3415 task_team->tt.tt_threads_data = NULL; 3416 } 3417 __kmp_release_bootstrap_lock(&task_team->tt.tt_threads_lock); 3418 } 3419 3420 // __kmp_allocate_task_team: 3421 // Allocates a task team associated with a specific team, taking it from 3422 // the global task team free list if possible. Also initializes data 3423 // structures. 3424 static kmp_task_team_t *__kmp_allocate_task_team(kmp_info_t *thread, 3425 kmp_team_t *team) { 3426 kmp_task_team_t *task_team = NULL; 3427 int nthreads; 3428 3429 KA_TRACE(20, ("__kmp_allocate_task_team: T#%d entering; team = %p\n", 3430 (thread ? __kmp_gtid_from_thread(thread) : -1), team)); 3431 3432 if (TCR_PTR(__kmp_free_task_teams) != NULL) { 3433 // Take a task team from the task team pool 3434 __kmp_acquire_bootstrap_lock(&__kmp_task_team_lock); 3435 if (__kmp_free_task_teams != NULL) { 3436 task_team = __kmp_free_task_teams; 3437 TCW_PTR(__kmp_free_task_teams, task_team->tt.tt_next); 3438 task_team->tt.tt_next = NULL; 3439 } 3440 __kmp_release_bootstrap_lock(&__kmp_task_team_lock); 3441 } 3442 3443 if (task_team == NULL) { 3444 KE_TRACE(10, ("__kmp_allocate_task_team: T#%d allocating " 3445 "task team for team %p\n", 3446 __kmp_gtid_from_thread(thread), team)); 3447 // Allocate a new task team if one is not available. Cannot use 3448 // __kmp_thread_malloc because threads not around for kmp_reap_task_team. 3449 task_team = (kmp_task_team_t *)__kmp_allocate(sizeof(kmp_task_team_t)); 3450 __kmp_init_bootstrap_lock(&task_team->tt.tt_threads_lock); 3451 #if USE_ITT_BUILD && USE_ITT_NOTIFY && KMP_DEBUG 3452 // suppress race conditions detection on synchronization flags in debug mode 3453 // this helps to analyze library internals eliminating false positives 3454 __itt_suppress_mark_range( 3455 __itt_suppress_range, __itt_suppress_threading_errors, 3456 &task_team->tt.tt_found_tasks, sizeof(task_team->tt.tt_found_tasks)); 3457 __itt_suppress_mark_range(__itt_suppress_range, 3458 __itt_suppress_threading_errors, 3459 CCAST(kmp_uint32 *, &task_team->tt.tt_active), 3460 sizeof(task_team->tt.tt_active)); 3461 #endif /* USE_ITT_BUILD && USE_ITT_NOTIFY && KMP_DEBUG */ 3462 // Note: __kmp_allocate zeroes returned memory, othewise we would need: 3463 // task_team->tt.tt_threads_data = NULL; 3464 // task_team->tt.tt_max_threads = 0; 3465 // task_team->tt.tt_next = NULL; 3466 } 3467 3468 TCW_4(task_team->tt.tt_found_tasks, FALSE); 3469 TCW_4(task_team->tt.tt_found_proxy_tasks, FALSE); 3470 task_team->tt.tt_nproc = nthreads = team->t.t_nproc; 3471 3472 KMP_ATOMIC_ST_REL(&task_team->tt.tt_unfinished_threads, nthreads); 3473 TCW_4(task_team->tt.tt_hidden_helper_task_encountered, FALSE); 3474 TCW_4(task_team->tt.tt_active, TRUE); 3475 3476 KA_TRACE(20, ("__kmp_allocate_task_team: T#%d exiting; task_team = %p " 3477 "unfinished_threads init'd to %d\n", 3478 (thread ? __kmp_gtid_from_thread(thread) : -1), task_team, 3479 KMP_ATOMIC_LD_RLX(&task_team->tt.tt_unfinished_threads))); 3480 return task_team; 3481 } 3482 3483 // __kmp_free_task_team: 3484 // Frees the task team associated with a specific thread, and adds it 3485 // to the global task team free list. 3486 void __kmp_free_task_team(kmp_info_t *thread, kmp_task_team_t *task_team) { 3487 KA_TRACE(20, ("__kmp_free_task_team: T#%d task_team = %p\n", 3488 thread ? __kmp_gtid_from_thread(thread) : -1, task_team)); 3489 3490 // Put task team back on free list 3491 __kmp_acquire_bootstrap_lock(&__kmp_task_team_lock); 3492 3493 KMP_DEBUG_ASSERT(task_team->tt.tt_next == NULL); 3494 task_team->tt.tt_next = __kmp_free_task_teams; 3495 TCW_PTR(__kmp_free_task_teams, task_team); 3496 3497 __kmp_release_bootstrap_lock(&__kmp_task_team_lock); 3498 } 3499 3500 // __kmp_reap_task_teams: 3501 // Free all the task teams on the task team free list. 3502 // Should only be done during library shutdown. 3503 // Cannot do anything that needs a thread structure or gtid since they are 3504 // already gone. 3505 void __kmp_reap_task_teams(void) { 3506 kmp_task_team_t *task_team; 3507 3508 if (TCR_PTR(__kmp_free_task_teams) != NULL) { 3509 // Free all task_teams on the free list 3510 __kmp_acquire_bootstrap_lock(&__kmp_task_team_lock); 3511 while ((task_team = __kmp_free_task_teams) != NULL) { 3512 __kmp_free_task_teams = task_team->tt.tt_next; 3513 task_team->tt.tt_next = NULL; 3514 3515 // Free threads_data if necessary 3516 if (task_team->tt.tt_threads_data != NULL) { 3517 __kmp_free_task_threads_data(task_team); 3518 } 3519 __kmp_free(task_team); 3520 } 3521 __kmp_release_bootstrap_lock(&__kmp_task_team_lock); 3522 } 3523 } 3524 3525 // __kmp_wait_to_unref_task_teams: 3526 // Some threads could still be in the fork barrier release code, possibly 3527 // trying to steal tasks. Wait for each thread to unreference its task team. 3528 void __kmp_wait_to_unref_task_teams(void) { 3529 kmp_info_t *thread; 3530 kmp_uint32 spins; 3531 int done; 3532 3533 KMP_INIT_YIELD(spins); 3534 3535 for (;;) { 3536 done = TRUE; 3537 3538 // TODO: GEH - this may be is wrong because some sync would be necessary 3539 // in case threads are added to the pool during the traversal. Need to 3540 // verify that lock for thread pool is held when calling this routine. 3541 for (thread = CCAST(kmp_info_t *, __kmp_thread_pool); thread != NULL; 3542 thread = thread->th.th_next_pool) { 3543 #if KMP_OS_WINDOWS 3544 DWORD exit_val; 3545 #endif 3546 if (TCR_PTR(thread->th.th_task_team) == NULL) { 3547 KA_TRACE(10, ("__kmp_wait_to_unref_task_team: T#%d task_team == NULL\n", 3548 __kmp_gtid_from_thread(thread))); 3549 continue; 3550 } 3551 #if KMP_OS_WINDOWS 3552 // TODO: GEH - add this check for Linux* OS / OS X* as well? 3553 if (!__kmp_is_thread_alive(thread, &exit_val)) { 3554 thread->th.th_task_team = NULL; 3555 continue; 3556 } 3557 #endif 3558 3559 done = FALSE; // Because th_task_team pointer is not NULL for this thread 3560 3561 KA_TRACE(10, ("__kmp_wait_to_unref_task_team: Waiting for T#%d to " 3562 "unreference task_team\n", 3563 __kmp_gtid_from_thread(thread))); 3564 3565 if (__kmp_dflt_blocktime != KMP_MAX_BLOCKTIME) { 3566 void *sleep_loc; 3567 // If the thread is sleeping, awaken it. 3568 if ((sleep_loc = TCR_PTR(CCAST(void *, thread->th.th_sleep_loc))) != 3569 NULL) { 3570 KA_TRACE( 3571 10, 3572 ("__kmp_wait_to_unref_task_team: T#%d waking up thread T#%d\n", 3573 __kmp_gtid_from_thread(thread), __kmp_gtid_from_thread(thread))); 3574 __kmp_null_resume_wrapper(thread); 3575 } 3576 } 3577 } 3578 if (done) { 3579 break; 3580 } 3581 3582 // If oversubscribed or have waited a bit, yield. 3583 KMP_YIELD_OVERSUB_ELSE_SPIN(spins); 3584 } 3585 } 3586 3587 // __kmp_task_team_setup: Create a task_team for the current team, but use 3588 // an already created, unused one if it already exists. 3589 void __kmp_task_team_setup(kmp_info_t *this_thr, kmp_team_t *team, int always) { 3590 KMP_DEBUG_ASSERT(__kmp_tasking_mode != tskm_immediate_exec); 3591 3592 // If this task_team hasn't been created yet, allocate it. It will be used in 3593 // the region after the next. 3594 // If it exists, it is the current task team and shouldn't be touched yet as 3595 // it may still be in use. 3596 if (team->t.t_task_team[this_thr->th.th_task_state] == NULL && 3597 (always || team->t.t_nproc > 1)) { 3598 team->t.t_task_team[this_thr->th.th_task_state] = 3599 __kmp_allocate_task_team(this_thr, team); 3600 KA_TRACE(20, ("__kmp_task_team_setup: Primary T#%d created new task_team %p" 3601 " for team %d at parity=%d\n", 3602 __kmp_gtid_from_thread(this_thr), 3603 team->t.t_task_team[this_thr->th.th_task_state], team->t.t_id, 3604 this_thr->th.th_task_state)); 3605 } 3606 3607 // After threads exit the release, they will call sync, and then point to this 3608 // other task_team; make sure it is allocated and properly initialized. As 3609 // threads spin in the barrier release phase, they will continue to use the 3610 // previous task_team struct(above), until they receive the signal to stop 3611 // checking for tasks (they can't safely reference the kmp_team_t struct, 3612 // which could be reallocated by the primary thread). No task teams are formed 3613 // for serialized teams. 3614 if (team->t.t_nproc > 1) { 3615 int other_team = 1 - this_thr->th.th_task_state; 3616 KMP_DEBUG_ASSERT(other_team >= 0 && other_team < 2); 3617 if (team->t.t_task_team[other_team] == NULL) { // setup other team as well 3618 team->t.t_task_team[other_team] = 3619 __kmp_allocate_task_team(this_thr, team); 3620 KA_TRACE(20, ("__kmp_task_team_setup: Primary T#%d created second new " 3621 "task_team %p for team %d at parity=%d\n", 3622 __kmp_gtid_from_thread(this_thr), 3623 team->t.t_task_team[other_team], team->t.t_id, other_team)); 3624 } else { // Leave the old task team struct in place for the upcoming region; 3625 // adjust as needed 3626 kmp_task_team_t *task_team = team->t.t_task_team[other_team]; 3627 if (!task_team->tt.tt_active || 3628 team->t.t_nproc != task_team->tt.tt_nproc) { 3629 TCW_4(task_team->tt.tt_nproc, team->t.t_nproc); 3630 TCW_4(task_team->tt.tt_found_tasks, FALSE); 3631 TCW_4(task_team->tt.tt_found_proxy_tasks, FALSE); 3632 KMP_ATOMIC_ST_REL(&task_team->tt.tt_unfinished_threads, 3633 team->t.t_nproc); 3634 TCW_4(task_team->tt.tt_active, TRUE); 3635 } 3636 // if team size has changed, the first thread to enable tasking will 3637 // realloc threads_data if necessary 3638 KA_TRACE(20, ("__kmp_task_team_setup: Primary T#%d reset next task_team " 3639 "%p for team %d at parity=%d\n", 3640 __kmp_gtid_from_thread(this_thr), 3641 team->t.t_task_team[other_team], team->t.t_id, other_team)); 3642 } 3643 } 3644 3645 // For regular thread, task enabling should be called when the task is going 3646 // to be pushed to a dequeue. However, for the hidden helper thread, we need 3647 // it ahead of time so that some operations can be performed without race 3648 // condition. 3649 if (this_thr == __kmp_hidden_helper_main_thread) { 3650 for (int i = 0; i < 2; ++i) { 3651 kmp_task_team_t *task_team = team->t.t_task_team[i]; 3652 if (KMP_TASKING_ENABLED(task_team)) { 3653 continue; 3654 } 3655 __kmp_enable_tasking(task_team, this_thr); 3656 for (int j = 0; j < task_team->tt.tt_nproc; ++j) { 3657 kmp_thread_data_t *thread_data = &task_team->tt.tt_threads_data[j]; 3658 if (thread_data->td.td_deque == NULL) { 3659 __kmp_alloc_task_deque(__kmp_hidden_helper_threads[j], thread_data); 3660 } 3661 } 3662 } 3663 } 3664 } 3665 3666 // __kmp_task_team_sync: Propagation of task team data from team to threads 3667 // which happens just after the release phase of a team barrier. This may be 3668 // called by any thread, but only for teams with # threads > 1. 3669 void __kmp_task_team_sync(kmp_info_t *this_thr, kmp_team_t *team) { 3670 KMP_DEBUG_ASSERT(__kmp_tasking_mode != tskm_immediate_exec); 3671 3672 // Toggle the th_task_state field, to switch which task_team this thread 3673 // refers to 3674 this_thr->th.th_task_state = (kmp_uint8)(1 - this_thr->th.th_task_state); 3675 3676 // It is now safe to propagate the task team pointer from the team struct to 3677 // the current thread. 3678 TCW_PTR(this_thr->th.th_task_team, 3679 team->t.t_task_team[this_thr->th.th_task_state]); 3680 KA_TRACE(20, 3681 ("__kmp_task_team_sync: Thread T#%d task team switched to task_team " 3682 "%p from Team #%d (parity=%d)\n", 3683 __kmp_gtid_from_thread(this_thr), this_thr->th.th_task_team, 3684 team->t.t_id, this_thr->th.th_task_state)); 3685 } 3686 3687 // __kmp_task_team_wait: Primary thread waits for outstanding tasks after the 3688 // barrier gather phase. Only called by primary thread if #threads in team > 1 3689 // or if proxy tasks were created. 3690 // 3691 // wait is a flag that defaults to 1 (see kmp.h), but waiting can be turned off 3692 // by passing in 0 optionally as the last argument. When wait is zero, primary 3693 // thread does not wait for unfinished_threads to reach 0. 3694 void __kmp_task_team_wait( 3695 kmp_info_t *this_thr, 3696 kmp_team_t *team USE_ITT_BUILD_ARG(void *itt_sync_obj), int wait) { 3697 kmp_task_team_t *task_team = team->t.t_task_team[this_thr->th.th_task_state]; 3698 3699 KMP_DEBUG_ASSERT(__kmp_tasking_mode != tskm_immediate_exec); 3700 KMP_DEBUG_ASSERT(task_team == this_thr->th.th_task_team); 3701 3702 if ((task_team != NULL) && KMP_TASKING_ENABLED(task_team)) { 3703 if (wait) { 3704 KA_TRACE(20, ("__kmp_task_team_wait: Primary T#%d waiting for all tasks " 3705 "(for unfinished_threads to reach 0) on task_team = %p\n", 3706 __kmp_gtid_from_thread(this_thr), task_team)); 3707 // Worker threads may have dropped through to release phase, but could 3708 // still be executing tasks. Wait here for tasks to complete. To avoid 3709 // memory contention, only primary thread checks termination condition. 3710 kmp_flag_32<false, false> flag( 3711 RCAST(std::atomic<kmp_uint32> *, 3712 &task_team->tt.tt_unfinished_threads), 3713 0U); 3714 flag.wait(this_thr, TRUE USE_ITT_BUILD_ARG(itt_sync_obj)); 3715 } 3716 // Deactivate the old task team, so that the worker threads will stop 3717 // referencing it while spinning. 3718 KA_TRACE( 3719 20, 3720 ("__kmp_task_team_wait: Primary T#%d deactivating task_team %p: " 3721 "setting active to false, setting local and team's pointer to NULL\n", 3722 __kmp_gtid_from_thread(this_thr), task_team)); 3723 KMP_DEBUG_ASSERT(task_team->tt.tt_nproc > 1 || 3724 task_team->tt.tt_found_proxy_tasks == TRUE); 3725 TCW_SYNC_4(task_team->tt.tt_found_proxy_tasks, FALSE); 3726 KMP_CHECK_UPDATE(task_team->tt.tt_untied_task_encountered, 0); 3727 TCW_SYNC_4(task_team->tt.tt_active, FALSE); 3728 KMP_MB(); 3729 3730 TCW_PTR(this_thr->th.th_task_team, NULL); 3731 } 3732 } 3733 3734 // __kmp_tasking_barrier: 3735 // This routine is called only when __kmp_tasking_mode == tskm_extra_barrier. 3736 // Internal function to execute all tasks prior to a regular barrier or a join 3737 // barrier. It is a full barrier itself, which unfortunately turns regular 3738 // barriers into double barriers and join barriers into 1 1/2 barriers. 3739 void __kmp_tasking_barrier(kmp_team_t *team, kmp_info_t *thread, int gtid) { 3740 std::atomic<kmp_uint32> *spin = RCAST( 3741 std::atomic<kmp_uint32> *, 3742 &team->t.t_task_team[thread->th.th_task_state]->tt.tt_unfinished_threads); 3743 int flag = FALSE; 3744 KMP_DEBUG_ASSERT(__kmp_tasking_mode == tskm_extra_barrier); 3745 3746 #if USE_ITT_BUILD 3747 KMP_FSYNC_SPIN_INIT(spin, NULL); 3748 #endif /* USE_ITT_BUILD */ 3749 kmp_flag_32<false, false> spin_flag(spin, 0U); 3750 while (!spin_flag.execute_tasks(thread, gtid, TRUE, 3751 &flag USE_ITT_BUILD_ARG(NULL), 0)) { 3752 #if USE_ITT_BUILD 3753 // TODO: What about itt_sync_obj?? 3754 KMP_FSYNC_SPIN_PREPARE(RCAST(void *, spin)); 3755 #endif /* USE_ITT_BUILD */ 3756 3757 if (TCR_4(__kmp_global.g.g_done)) { 3758 if (__kmp_global.g.g_abort) 3759 __kmp_abort_thread(); 3760 break; 3761 } 3762 KMP_YIELD(TRUE); 3763 } 3764 #if USE_ITT_BUILD 3765 KMP_FSYNC_SPIN_ACQUIRED(RCAST(void *, spin)); 3766 #endif /* USE_ITT_BUILD */ 3767 } 3768 3769 // __kmp_give_task puts a task into a given thread queue if: 3770 // - the queue for that thread was created 3771 // - there's space in that queue 3772 // Because of this, __kmp_push_task needs to check if there's space after 3773 // getting the lock 3774 static bool __kmp_give_task(kmp_info_t *thread, kmp_int32 tid, kmp_task_t *task, 3775 kmp_int32 pass) { 3776 kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(task); 3777 kmp_task_team_t *task_team = taskdata->td_task_team; 3778 3779 KA_TRACE(20, ("__kmp_give_task: trying to give task %p to thread %d.\n", 3780 taskdata, tid)); 3781 3782 // If task_team is NULL something went really bad... 3783 KMP_DEBUG_ASSERT(task_team != NULL); 3784 3785 bool result = false; 3786 kmp_thread_data_t *thread_data = &task_team->tt.tt_threads_data[tid]; 3787 3788 if (thread_data->td.td_deque == NULL) { 3789 // There's no queue in this thread, go find another one 3790 // We're guaranteed that at least one thread has a queue 3791 KA_TRACE(30, 3792 ("__kmp_give_task: thread %d has no queue while giving task %p.\n", 3793 tid, taskdata)); 3794 return result; 3795 } 3796 3797 if (TCR_4(thread_data->td.td_deque_ntasks) >= 3798 TASK_DEQUE_SIZE(thread_data->td)) { 3799 KA_TRACE( 3800 30, 3801 ("__kmp_give_task: queue is full while giving task %p to thread %d.\n", 3802 taskdata, tid)); 3803 3804 // if this deque is bigger than the pass ratio give a chance to another 3805 // thread 3806 if (TASK_DEQUE_SIZE(thread_data->td) / INITIAL_TASK_DEQUE_SIZE >= pass) 3807 return result; 3808 3809 __kmp_acquire_bootstrap_lock(&thread_data->td.td_deque_lock); 3810 if (TCR_4(thread_data->td.td_deque_ntasks) >= 3811 TASK_DEQUE_SIZE(thread_data->td)) { 3812 // expand deque to push the task which is not allowed to execute 3813 __kmp_realloc_task_deque(thread, thread_data); 3814 } 3815 3816 } else { 3817 3818 __kmp_acquire_bootstrap_lock(&thread_data->td.td_deque_lock); 3819 3820 if (TCR_4(thread_data->td.td_deque_ntasks) >= 3821 TASK_DEQUE_SIZE(thread_data->td)) { 3822 KA_TRACE(30, ("__kmp_give_task: queue is full while giving task %p to " 3823 "thread %d.\n", 3824 taskdata, tid)); 3825 3826 // if this deque is bigger than the pass ratio give a chance to another 3827 // thread 3828 if (TASK_DEQUE_SIZE(thread_data->td) / INITIAL_TASK_DEQUE_SIZE >= pass) 3829 goto release_and_exit; 3830 3831 __kmp_realloc_task_deque(thread, thread_data); 3832 } 3833 } 3834 3835 // lock is held here, and there is space in the deque 3836 3837 thread_data->td.td_deque[thread_data->td.td_deque_tail] = taskdata; 3838 // Wrap index. 3839 thread_data->td.td_deque_tail = 3840 (thread_data->td.td_deque_tail + 1) & TASK_DEQUE_MASK(thread_data->td); 3841 TCW_4(thread_data->td.td_deque_ntasks, 3842 TCR_4(thread_data->td.td_deque_ntasks) + 1); 3843 3844 result = true; 3845 KA_TRACE(30, ("__kmp_give_task: successfully gave task %p to thread %d.\n", 3846 taskdata, tid)); 3847 3848 release_and_exit: 3849 __kmp_release_bootstrap_lock(&thread_data->td.td_deque_lock); 3850 3851 return result; 3852 } 3853 3854 #define PROXY_TASK_FLAG 0x40000000 3855 /* The finish of the proxy tasks is divided in two pieces: 3856 - the top half is the one that can be done from a thread outside the team 3857 - the bottom half must be run from a thread within the team 3858 3859 In order to run the bottom half the task gets queued back into one of the 3860 threads of the team. Once the td_incomplete_child_task counter of the parent 3861 is decremented the threads can leave the barriers. So, the bottom half needs 3862 to be queued before the counter is decremented. The top half is therefore 3863 divided in two parts: 3864 - things that can be run before queuing the bottom half 3865 - things that must be run after queuing the bottom half 3866 3867 This creates a second race as the bottom half can free the task before the 3868 second top half is executed. To avoid this we use the 3869 td_incomplete_child_task of the proxy task to synchronize the top and bottom 3870 half. */ 3871 static void __kmp_first_top_half_finish_proxy(kmp_taskdata_t *taskdata) { 3872 KMP_DEBUG_ASSERT(taskdata->td_flags.tasktype == TASK_EXPLICIT); 3873 KMP_DEBUG_ASSERT(taskdata->td_flags.proxy == TASK_PROXY); 3874 KMP_DEBUG_ASSERT(taskdata->td_flags.complete == 0); 3875 KMP_DEBUG_ASSERT(taskdata->td_flags.freed == 0); 3876 3877 taskdata->td_flags.complete = 1; // mark the task as completed 3878 3879 if (taskdata->td_taskgroup) 3880 KMP_ATOMIC_DEC(&taskdata->td_taskgroup->count); 3881 3882 // Create an imaginary children for this task so the bottom half cannot 3883 // release the task before we have completed the second top half 3884 KMP_ATOMIC_OR(&taskdata->td_incomplete_child_tasks, PROXY_TASK_FLAG); 3885 } 3886 3887 static void __kmp_second_top_half_finish_proxy(kmp_taskdata_t *taskdata) { 3888 kmp_int32 children = 0; 3889 3890 // Predecrement simulated by "- 1" calculation 3891 children = 3892 KMP_ATOMIC_DEC(&taskdata->td_parent->td_incomplete_child_tasks) - 1; 3893 KMP_DEBUG_ASSERT(children >= 0); 3894 3895 // Remove the imaginary children 3896 KMP_ATOMIC_AND(&taskdata->td_incomplete_child_tasks, ~PROXY_TASK_FLAG); 3897 } 3898 3899 static void __kmp_bottom_half_finish_proxy(kmp_int32 gtid, kmp_task_t *ptask) { 3900 kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(ptask); 3901 kmp_info_t *thread = __kmp_threads[gtid]; 3902 3903 KMP_DEBUG_ASSERT(taskdata->td_flags.proxy == TASK_PROXY); 3904 KMP_DEBUG_ASSERT(taskdata->td_flags.complete == 3905 1); // top half must run before bottom half 3906 3907 // We need to wait to make sure the top half is finished 3908 // Spinning here should be ok as this should happen quickly 3909 while ((KMP_ATOMIC_LD_ACQ(&taskdata->td_incomplete_child_tasks) & 3910 PROXY_TASK_FLAG) > 0) 3911 ; 3912 3913 __kmp_release_deps(gtid, taskdata); 3914 __kmp_free_task_and_ancestors(gtid, taskdata, thread); 3915 } 3916 3917 /*! 3918 @ingroup TASKING 3919 @param gtid Global Thread ID of encountering thread 3920 @param ptask Task which execution is completed 3921 3922 Execute the completion of a proxy task from a thread of that is part of the 3923 team. Run first and bottom halves directly. 3924 */ 3925 void __kmpc_proxy_task_completed(kmp_int32 gtid, kmp_task_t *ptask) { 3926 KMP_DEBUG_ASSERT(ptask != NULL); 3927 kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(ptask); 3928 KA_TRACE( 3929 10, ("__kmp_proxy_task_completed(enter): T#%d proxy task %p completing\n", 3930 gtid, taskdata)); 3931 __kmp_assert_valid_gtid(gtid); 3932 KMP_DEBUG_ASSERT(taskdata->td_flags.proxy == TASK_PROXY); 3933 3934 __kmp_first_top_half_finish_proxy(taskdata); 3935 __kmp_second_top_half_finish_proxy(taskdata); 3936 __kmp_bottom_half_finish_proxy(gtid, ptask); 3937 3938 KA_TRACE(10, 3939 ("__kmp_proxy_task_completed(exit): T#%d proxy task %p completing\n", 3940 gtid, taskdata)); 3941 } 3942 3943 void __kmpc_give_task(kmp_task_t *ptask, kmp_int32 start = 0) { 3944 KMP_DEBUG_ASSERT(ptask != NULL); 3945 kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(ptask); 3946 3947 // Enqueue task to complete bottom half completion from a thread within the 3948 // corresponding team 3949 kmp_team_t *team = taskdata->td_team; 3950 kmp_int32 nthreads = team->t.t_nproc; 3951 kmp_info_t *thread; 3952 3953 // This should be similar to start_k = __kmp_get_random( thread ) % nthreads 3954 // but we cannot use __kmp_get_random here 3955 kmp_int32 start_k = start; 3956 kmp_int32 pass = 1; 3957 kmp_int32 k = start_k; 3958 3959 do { 3960 // For now we're just linearly trying to find a thread 3961 thread = team->t.t_threads[k]; 3962 k = (k + 1) % nthreads; 3963 3964 // we did a full pass through all the threads 3965 if (k == start_k) 3966 pass = pass << 1; 3967 3968 } while (!__kmp_give_task(thread, k, ptask, pass)); 3969 } 3970 3971 /*! 3972 @ingroup TASKING 3973 @param ptask Task which execution is completed 3974 3975 Execute the completion of a proxy task from a thread that could not belong to 3976 the team. 3977 */ 3978 void __kmpc_proxy_task_completed_ooo(kmp_task_t *ptask) { 3979 KMP_DEBUG_ASSERT(ptask != NULL); 3980 kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(ptask); 3981 3982 KA_TRACE( 3983 10, 3984 ("__kmp_proxy_task_completed_ooo(enter): proxy task completing ooo %p\n", 3985 taskdata)); 3986 3987 KMP_DEBUG_ASSERT(taskdata->td_flags.proxy == TASK_PROXY); 3988 3989 __kmp_first_top_half_finish_proxy(taskdata); 3990 3991 __kmpc_give_task(ptask); 3992 3993 __kmp_second_top_half_finish_proxy(taskdata); 3994 3995 KA_TRACE( 3996 10, 3997 ("__kmp_proxy_task_completed_ooo(exit): proxy task completing ooo %p\n", 3998 taskdata)); 3999 } 4000 4001 kmp_event_t *__kmpc_task_allow_completion_event(ident_t *loc_ref, int gtid, 4002 kmp_task_t *task) { 4003 kmp_taskdata_t *td = KMP_TASK_TO_TASKDATA(task); 4004 if (td->td_allow_completion_event.type == KMP_EVENT_UNINITIALIZED) { 4005 td->td_allow_completion_event.type = KMP_EVENT_ALLOW_COMPLETION; 4006 td->td_allow_completion_event.ed.task = task; 4007 __kmp_init_tas_lock(&td->td_allow_completion_event.lock); 4008 } 4009 return &td->td_allow_completion_event; 4010 } 4011 4012 void __kmp_fulfill_event(kmp_event_t *event) { 4013 if (event->type == KMP_EVENT_ALLOW_COMPLETION) { 4014 kmp_task_t *ptask = event->ed.task; 4015 kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(ptask); 4016 bool detached = false; 4017 int gtid = __kmp_get_gtid(); 4018 4019 // The associated task might have completed or could be completing at this 4020 // point. 4021 // We need to take the lock to avoid races 4022 __kmp_acquire_tas_lock(&event->lock, gtid); 4023 if (taskdata->td_flags.proxy == TASK_PROXY) { 4024 detached = true; 4025 } else { 4026 #if OMPT_SUPPORT 4027 // The OMPT event must occur under mutual exclusion, 4028 // otherwise the tool might access ptask after free 4029 if (UNLIKELY(ompt_enabled.enabled)) 4030 __ompt_task_finish(ptask, NULL, ompt_task_early_fulfill); 4031 #endif 4032 } 4033 event->type = KMP_EVENT_UNINITIALIZED; 4034 __kmp_release_tas_lock(&event->lock, gtid); 4035 4036 if (detached) { 4037 #if OMPT_SUPPORT 4038 // We free ptask afterwards and know the task is finished, 4039 // so locking is not necessary 4040 if (UNLIKELY(ompt_enabled.enabled)) 4041 __ompt_task_finish(ptask, NULL, ompt_task_late_fulfill); 4042 #endif 4043 // If the task detached complete the proxy task 4044 if (gtid >= 0) { 4045 kmp_team_t *team = taskdata->td_team; 4046 kmp_info_t *thread = __kmp_get_thread(); 4047 if (thread->th.th_team == team) { 4048 __kmpc_proxy_task_completed(gtid, ptask); 4049 return; 4050 } 4051 } 4052 4053 // fallback 4054 __kmpc_proxy_task_completed_ooo(ptask); 4055 } 4056 } 4057 } 4058 4059 // __kmp_task_dup_alloc: Allocate the taskdata and make a copy of source task 4060 // for taskloop 4061 // 4062 // thread: allocating thread 4063 // task_src: pointer to source task to be duplicated 4064 // returns: a pointer to the allocated kmp_task_t structure (task). 4065 kmp_task_t *__kmp_task_dup_alloc(kmp_info_t *thread, kmp_task_t *task_src) { 4066 kmp_task_t *task; 4067 kmp_taskdata_t *taskdata; 4068 kmp_taskdata_t *taskdata_src = KMP_TASK_TO_TASKDATA(task_src); 4069 kmp_taskdata_t *parent_task = taskdata_src->td_parent; // same parent task 4070 size_t shareds_offset; 4071 size_t task_size; 4072 4073 KA_TRACE(10, ("__kmp_task_dup_alloc(enter): Th %p, source task %p\n", thread, 4074 task_src)); 4075 KMP_DEBUG_ASSERT(taskdata_src->td_flags.proxy == 4076 TASK_FULL); // it should not be proxy task 4077 KMP_DEBUG_ASSERT(taskdata_src->td_flags.tasktype == TASK_EXPLICIT); 4078 task_size = taskdata_src->td_size_alloc; 4079 4080 // Allocate a kmp_taskdata_t block and a kmp_task_t block. 4081 KA_TRACE(30, ("__kmp_task_dup_alloc: Th %p, malloc size %ld\n", thread, 4082 task_size)); 4083 #if USE_FAST_MEMORY 4084 taskdata = (kmp_taskdata_t *)__kmp_fast_allocate(thread, task_size); 4085 #else 4086 taskdata = (kmp_taskdata_t *)__kmp_thread_malloc(thread, task_size); 4087 #endif /* USE_FAST_MEMORY */ 4088 KMP_MEMCPY(taskdata, taskdata_src, task_size); 4089 4090 task = KMP_TASKDATA_TO_TASK(taskdata); 4091 4092 // Initialize new task (only specific fields not affected by memcpy) 4093 taskdata->td_task_id = KMP_GEN_TASK_ID(); 4094 if (task->shareds != NULL) { // need setup shareds pointer 4095 shareds_offset = (char *)task_src->shareds - (char *)taskdata_src; 4096 task->shareds = &((char *)taskdata)[shareds_offset]; 4097 KMP_DEBUG_ASSERT((((kmp_uintptr_t)task->shareds) & (sizeof(void *) - 1)) == 4098 0); 4099 } 4100 taskdata->td_alloc_thread = thread; 4101 taskdata->td_parent = parent_task; 4102 // task inherits the taskgroup from the parent task 4103 taskdata->td_taskgroup = parent_task->td_taskgroup; 4104 // tied task needs to initialize the td_last_tied at creation, 4105 // untied one does this when it is scheduled for execution 4106 if (taskdata->td_flags.tiedness == TASK_TIED) 4107 taskdata->td_last_tied = taskdata; 4108 4109 // Only need to keep track of child task counts if team parallel and tasking 4110 // not serialized 4111 if (!(taskdata->td_flags.team_serial || taskdata->td_flags.tasking_ser)) { 4112 KMP_ATOMIC_INC(&parent_task->td_incomplete_child_tasks); 4113 if (parent_task->td_taskgroup) 4114 KMP_ATOMIC_INC(&parent_task->td_taskgroup->count); 4115 // Only need to keep track of allocated child tasks for explicit tasks since 4116 // implicit not deallocated 4117 if (taskdata->td_parent->td_flags.tasktype == TASK_EXPLICIT) 4118 KMP_ATOMIC_INC(&taskdata->td_parent->td_allocated_child_tasks); 4119 } 4120 4121 KA_TRACE(20, 4122 ("__kmp_task_dup_alloc(exit): Th %p, created task %p, parent=%p\n", 4123 thread, taskdata, taskdata->td_parent)); 4124 #if OMPT_SUPPORT 4125 if (UNLIKELY(ompt_enabled.enabled)) 4126 __ompt_task_init(taskdata, thread->th.th_info.ds.ds_gtid); 4127 #endif 4128 return task; 4129 } 4130 4131 // Routine optionally generated by the compiler for setting the lastprivate flag 4132 // and calling needed constructors for private/firstprivate objects 4133 // (used to form taskloop tasks from pattern task) 4134 // Parameters: dest task, src task, lastprivate flag. 4135 typedef void (*p_task_dup_t)(kmp_task_t *, kmp_task_t *, kmp_int32); 4136 4137 KMP_BUILD_ASSERT(sizeof(long) == 4 || sizeof(long) == 8); 4138 4139 // class to encapsulate manipulating loop bounds in a taskloop task. 4140 // this abstracts away the Intel vs GOMP taskloop interface for setting/getting 4141 // the loop bound variables. 4142 class kmp_taskloop_bounds_t { 4143 kmp_task_t *task; 4144 const kmp_taskdata_t *taskdata; 4145 size_t lower_offset; 4146 size_t upper_offset; 4147 4148 public: 4149 kmp_taskloop_bounds_t(kmp_task_t *_task, kmp_uint64 *lb, kmp_uint64 *ub) 4150 : task(_task), taskdata(KMP_TASK_TO_TASKDATA(task)), 4151 lower_offset((char *)lb - (char *)task), 4152 upper_offset((char *)ub - (char *)task) { 4153 KMP_DEBUG_ASSERT((char *)lb > (char *)_task); 4154 KMP_DEBUG_ASSERT((char *)ub > (char *)_task); 4155 } 4156 kmp_taskloop_bounds_t(kmp_task_t *_task, const kmp_taskloop_bounds_t &bounds) 4157 : task(_task), taskdata(KMP_TASK_TO_TASKDATA(_task)), 4158 lower_offset(bounds.lower_offset), upper_offset(bounds.upper_offset) {} 4159 size_t get_lower_offset() const { return lower_offset; } 4160 size_t get_upper_offset() const { return upper_offset; } 4161 kmp_uint64 get_lb() const { 4162 kmp_int64 retval; 4163 #if defined(KMP_GOMP_COMPAT) 4164 // Intel task just returns the lower bound normally 4165 if (!taskdata->td_flags.native) { 4166 retval = *(kmp_int64 *)((char *)task + lower_offset); 4167 } else { 4168 // GOMP task has to take into account the sizeof(long) 4169 if (taskdata->td_size_loop_bounds == 4) { 4170 kmp_int32 *lb = RCAST(kmp_int32 *, task->shareds); 4171 retval = (kmp_int64)*lb; 4172 } else { 4173 kmp_int64 *lb = RCAST(kmp_int64 *, task->shareds); 4174 retval = (kmp_int64)*lb; 4175 } 4176 } 4177 #else 4178 (void)taskdata; 4179 retval = *(kmp_int64 *)((char *)task + lower_offset); 4180 #endif // defined(KMP_GOMP_COMPAT) 4181 return retval; 4182 } 4183 kmp_uint64 get_ub() const { 4184 kmp_int64 retval; 4185 #if defined(KMP_GOMP_COMPAT) 4186 // Intel task just returns the upper bound normally 4187 if (!taskdata->td_flags.native) { 4188 retval = *(kmp_int64 *)((char *)task + upper_offset); 4189 } else { 4190 // GOMP task has to take into account the sizeof(long) 4191 if (taskdata->td_size_loop_bounds == 4) { 4192 kmp_int32 *ub = RCAST(kmp_int32 *, task->shareds) + 1; 4193 retval = (kmp_int64)*ub; 4194 } else { 4195 kmp_int64 *ub = RCAST(kmp_int64 *, task->shareds) + 1; 4196 retval = (kmp_int64)*ub; 4197 } 4198 } 4199 #else 4200 retval = *(kmp_int64 *)((char *)task + upper_offset); 4201 #endif // defined(KMP_GOMP_COMPAT) 4202 return retval; 4203 } 4204 void set_lb(kmp_uint64 lb) { 4205 #if defined(KMP_GOMP_COMPAT) 4206 // Intel task just sets the lower bound normally 4207 if (!taskdata->td_flags.native) { 4208 *(kmp_uint64 *)((char *)task + lower_offset) = lb; 4209 } else { 4210 // GOMP task has to take into account the sizeof(long) 4211 if (taskdata->td_size_loop_bounds == 4) { 4212 kmp_uint32 *lower = RCAST(kmp_uint32 *, task->shareds); 4213 *lower = (kmp_uint32)lb; 4214 } else { 4215 kmp_uint64 *lower = RCAST(kmp_uint64 *, task->shareds); 4216 *lower = (kmp_uint64)lb; 4217 } 4218 } 4219 #else 4220 *(kmp_uint64 *)((char *)task + lower_offset) = lb; 4221 #endif // defined(KMP_GOMP_COMPAT) 4222 } 4223 void set_ub(kmp_uint64 ub) { 4224 #if defined(KMP_GOMP_COMPAT) 4225 // Intel task just sets the upper bound normally 4226 if (!taskdata->td_flags.native) { 4227 *(kmp_uint64 *)((char *)task + upper_offset) = ub; 4228 } else { 4229 // GOMP task has to take into account the sizeof(long) 4230 if (taskdata->td_size_loop_bounds == 4) { 4231 kmp_uint32 *upper = RCAST(kmp_uint32 *, task->shareds) + 1; 4232 *upper = (kmp_uint32)ub; 4233 } else { 4234 kmp_uint64 *upper = RCAST(kmp_uint64 *, task->shareds) + 1; 4235 *upper = (kmp_uint64)ub; 4236 } 4237 } 4238 #else 4239 *(kmp_uint64 *)((char *)task + upper_offset) = ub; 4240 #endif // defined(KMP_GOMP_COMPAT) 4241 } 4242 }; 4243 4244 // __kmp_taskloop_linear: Start tasks of the taskloop linearly 4245 // 4246 // loc Source location information 4247 // gtid Global thread ID 4248 // task Pattern task, exposes the loop iteration range 4249 // lb Pointer to loop lower bound in task structure 4250 // ub Pointer to loop upper bound in task structure 4251 // st Loop stride 4252 // ub_glob Global upper bound (used for lastprivate check) 4253 // num_tasks Number of tasks to execute 4254 // grainsize Number of loop iterations per task 4255 // extras Number of chunks with grainsize+1 iterations 4256 // last_chunk Reduction of grainsize for last task 4257 // tc Iterations count 4258 // task_dup Tasks duplication routine 4259 // codeptr_ra Return address for OMPT events 4260 void __kmp_taskloop_linear(ident_t *loc, int gtid, kmp_task_t *task, 4261 kmp_uint64 *lb, kmp_uint64 *ub, kmp_int64 st, 4262 kmp_uint64 ub_glob, kmp_uint64 num_tasks, 4263 kmp_uint64 grainsize, kmp_uint64 extras, 4264 kmp_int64 last_chunk, kmp_uint64 tc, 4265 #if OMPT_SUPPORT 4266 void *codeptr_ra, 4267 #endif 4268 void *task_dup) { 4269 KMP_COUNT_BLOCK(OMP_TASKLOOP); 4270 KMP_TIME_PARTITIONED_BLOCK(OMP_taskloop_scheduling); 4271 p_task_dup_t ptask_dup = (p_task_dup_t)task_dup; 4272 // compiler provides global bounds here 4273 kmp_taskloop_bounds_t task_bounds(task, lb, ub); 4274 kmp_uint64 lower = task_bounds.get_lb(); 4275 kmp_uint64 upper = task_bounds.get_ub(); 4276 kmp_uint64 i; 4277 kmp_info_t *thread = __kmp_threads[gtid]; 4278 kmp_taskdata_t *current_task = thread->th.th_current_task; 4279 kmp_task_t *next_task; 4280 kmp_int32 lastpriv = 0; 4281 4282 KMP_DEBUG_ASSERT(tc == num_tasks * grainsize + 4283 (last_chunk < 0 ? last_chunk : extras)); 4284 KMP_DEBUG_ASSERT(num_tasks > extras); 4285 KMP_DEBUG_ASSERT(num_tasks > 0); 4286 KA_TRACE(20, ("__kmp_taskloop_linear: T#%d: %lld tasks, grainsize %lld, " 4287 "extras %lld, last_chunk %lld, i=%lld,%lld(%d)%lld, dup %p\n", 4288 gtid, num_tasks, grainsize, extras, last_chunk, lower, upper, 4289 ub_glob, st, task_dup)); 4290 4291 // Launch num_tasks tasks, assign grainsize iterations each task 4292 for (i = 0; i < num_tasks; ++i) { 4293 kmp_uint64 chunk_minus_1; 4294 if (extras == 0) { 4295 chunk_minus_1 = grainsize - 1; 4296 } else { 4297 chunk_minus_1 = grainsize; 4298 --extras; // first extras iterations get bigger chunk (grainsize+1) 4299 } 4300 upper = lower + st * chunk_minus_1; 4301 if (upper > *ub) { 4302 upper = *ub; 4303 } 4304 if (i == num_tasks - 1) { 4305 // schedule the last task, set lastprivate flag if needed 4306 if (st == 1) { // most common case 4307 KMP_DEBUG_ASSERT(upper == *ub); 4308 if (upper == ub_glob) 4309 lastpriv = 1; 4310 } else if (st > 0) { // positive loop stride 4311 KMP_DEBUG_ASSERT((kmp_uint64)st > *ub - upper); 4312 if ((kmp_uint64)st > ub_glob - upper) 4313 lastpriv = 1; 4314 } else { // negative loop stride 4315 KMP_DEBUG_ASSERT(upper + st < *ub); 4316 if (upper - ub_glob < (kmp_uint64)(-st)) 4317 lastpriv = 1; 4318 } 4319 } 4320 next_task = __kmp_task_dup_alloc(thread, task); // allocate new task 4321 kmp_taskdata_t *next_taskdata = KMP_TASK_TO_TASKDATA(next_task); 4322 kmp_taskloop_bounds_t next_task_bounds = 4323 kmp_taskloop_bounds_t(next_task, task_bounds); 4324 4325 // adjust task-specific bounds 4326 next_task_bounds.set_lb(lower); 4327 if (next_taskdata->td_flags.native) { 4328 next_task_bounds.set_ub(upper + (st > 0 ? 1 : -1)); 4329 } else { 4330 next_task_bounds.set_ub(upper); 4331 } 4332 if (ptask_dup != NULL) // set lastprivate flag, construct firstprivates, 4333 // etc. 4334 ptask_dup(next_task, task, lastpriv); 4335 KA_TRACE(40, 4336 ("__kmp_taskloop_linear: T#%d; task #%llu: task %p: lower %lld, " 4337 "upper %lld stride %lld, (offsets %p %p)\n", 4338 gtid, i, next_task, lower, upper, st, 4339 next_task_bounds.get_lower_offset(), 4340 next_task_bounds.get_upper_offset())); 4341 #if OMPT_SUPPORT 4342 __kmp_omp_taskloop_task(NULL, gtid, next_task, 4343 codeptr_ra); // schedule new task 4344 #else 4345 __kmp_omp_task(gtid, next_task, true); // schedule new task 4346 #endif 4347 lower = upper + st; // adjust lower bound for the next iteration 4348 } 4349 // free the pattern task and exit 4350 __kmp_task_start(gtid, task, current_task); // make internal bookkeeping 4351 // do not execute the pattern task, just do internal bookkeeping 4352 __kmp_task_finish<false>(gtid, task, current_task); 4353 } 4354 4355 // Structure to keep taskloop parameters for auxiliary task 4356 // kept in the shareds of the task structure. 4357 typedef struct __taskloop_params { 4358 kmp_task_t *task; 4359 kmp_uint64 *lb; 4360 kmp_uint64 *ub; 4361 void *task_dup; 4362 kmp_int64 st; 4363 kmp_uint64 ub_glob; 4364 kmp_uint64 num_tasks; 4365 kmp_uint64 grainsize; 4366 kmp_uint64 extras; 4367 kmp_int64 last_chunk; 4368 kmp_uint64 tc; 4369 kmp_uint64 num_t_min; 4370 #if OMPT_SUPPORT 4371 void *codeptr_ra; 4372 #endif 4373 } __taskloop_params_t; 4374 4375 void __kmp_taskloop_recur(ident_t *, int, kmp_task_t *, kmp_uint64 *, 4376 kmp_uint64 *, kmp_int64, kmp_uint64, kmp_uint64, 4377 kmp_uint64, kmp_uint64, kmp_int64, kmp_uint64, 4378 kmp_uint64, 4379 #if OMPT_SUPPORT 4380 void *, 4381 #endif 4382 void *); 4383 4384 // Execute part of the taskloop submitted as a task. 4385 int __kmp_taskloop_task(int gtid, void *ptask) { 4386 __taskloop_params_t *p = 4387 (__taskloop_params_t *)((kmp_task_t *)ptask)->shareds; 4388 kmp_task_t *task = p->task; 4389 kmp_uint64 *lb = p->lb; 4390 kmp_uint64 *ub = p->ub; 4391 void *task_dup = p->task_dup; 4392 // p_task_dup_t ptask_dup = (p_task_dup_t)task_dup; 4393 kmp_int64 st = p->st; 4394 kmp_uint64 ub_glob = p->ub_glob; 4395 kmp_uint64 num_tasks = p->num_tasks; 4396 kmp_uint64 grainsize = p->grainsize; 4397 kmp_uint64 extras = p->extras; 4398 kmp_int64 last_chunk = p->last_chunk; 4399 kmp_uint64 tc = p->tc; 4400 kmp_uint64 num_t_min = p->num_t_min; 4401 #if OMPT_SUPPORT 4402 void *codeptr_ra = p->codeptr_ra; 4403 #endif 4404 #if KMP_DEBUG 4405 kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(task); 4406 KMP_DEBUG_ASSERT(task != NULL); 4407 KA_TRACE(20, 4408 ("__kmp_taskloop_task: T#%d, task %p: %lld tasks, grainsize" 4409 " %lld, extras %lld, last_chunk %lld, i=%lld,%lld(%d), dup %p\n", 4410 gtid, taskdata, num_tasks, grainsize, extras, last_chunk, *lb, *ub, 4411 st, task_dup)); 4412 #endif 4413 KMP_DEBUG_ASSERT(num_tasks * 2 + 1 > num_t_min); 4414 if (num_tasks > num_t_min) 4415 __kmp_taskloop_recur(NULL, gtid, task, lb, ub, st, ub_glob, num_tasks, 4416 grainsize, extras, last_chunk, tc, num_t_min, 4417 #if OMPT_SUPPORT 4418 codeptr_ra, 4419 #endif 4420 task_dup); 4421 else 4422 __kmp_taskloop_linear(NULL, gtid, task, lb, ub, st, ub_glob, num_tasks, 4423 grainsize, extras, last_chunk, tc, 4424 #if OMPT_SUPPORT 4425 codeptr_ra, 4426 #endif 4427 task_dup); 4428 4429 KA_TRACE(40, ("__kmp_taskloop_task(exit): T#%d\n", gtid)); 4430 return 0; 4431 } 4432 4433 // Schedule part of the taskloop as a task, 4434 // execute the rest of the taskloop. 4435 // 4436 // loc Source location information 4437 // gtid Global thread ID 4438 // task Pattern task, exposes the loop iteration range 4439 // lb Pointer to loop lower bound in task structure 4440 // ub Pointer to loop upper bound in task structure 4441 // st Loop stride 4442 // ub_glob Global upper bound (used for lastprivate check) 4443 // num_tasks Number of tasks to execute 4444 // grainsize Number of loop iterations per task 4445 // extras Number of chunks with grainsize+1 iterations 4446 // last_chunk Reduction of grainsize for last task 4447 // tc Iterations count 4448 // num_t_min Threshold to launch tasks recursively 4449 // task_dup Tasks duplication routine 4450 // codeptr_ra Return address for OMPT events 4451 void __kmp_taskloop_recur(ident_t *loc, int gtid, kmp_task_t *task, 4452 kmp_uint64 *lb, kmp_uint64 *ub, kmp_int64 st, 4453 kmp_uint64 ub_glob, kmp_uint64 num_tasks, 4454 kmp_uint64 grainsize, kmp_uint64 extras, 4455 kmp_int64 last_chunk, kmp_uint64 tc, 4456 kmp_uint64 num_t_min, 4457 #if OMPT_SUPPORT 4458 void *codeptr_ra, 4459 #endif 4460 void *task_dup) { 4461 kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(task); 4462 KMP_DEBUG_ASSERT(task != NULL); 4463 KMP_DEBUG_ASSERT(num_tasks > num_t_min); 4464 KA_TRACE(20, 4465 ("__kmp_taskloop_recur: T#%d, task %p: %lld tasks, grainsize" 4466 " %lld, extras %lld, last_chunk %lld, i=%lld,%lld(%d), dup %p\n", 4467 gtid, taskdata, num_tasks, grainsize, extras, last_chunk, *lb, *ub, 4468 st, task_dup)); 4469 p_task_dup_t ptask_dup = (p_task_dup_t)task_dup; 4470 kmp_uint64 lower = *lb; 4471 kmp_info_t *thread = __kmp_threads[gtid]; 4472 // kmp_taskdata_t *current_task = thread->th.th_current_task; 4473 kmp_task_t *next_task; 4474 size_t lower_offset = 4475 (char *)lb - (char *)task; // remember offset of lb in the task structure 4476 size_t upper_offset = 4477 (char *)ub - (char *)task; // remember offset of ub in the task structure 4478 4479 KMP_DEBUG_ASSERT(tc == num_tasks * grainsize + 4480 (last_chunk < 0 ? last_chunk : extras)); 4481 KMP_DEBUG_ASSERT(num_tasks > extras); 4482 KMP_DEBUG_ASSERT(num_tasks > 0); 4483 4484 // split the loop in two halves 4485 kmp_uint64 lb1, ub0, tc0, tc1, ext0, ext1; 4486 kmp_int64 last_chunk0 = 0, last_chunk1 = 0; 4487 kmp_uint64 gr_size0 = grainsize; 4488 kmp_uint64 n_tsk0 = num_tasks >> 1; // num_tasks/2 to execute 4489 kmp_uint64 n_tsk1 = num_tasks - n_tsk0; // to schedule as a task 4490 if (last_chunk < 0) { 4491 ext0 = ext1 = 0; 4492 last_chunk1 = last_chunk; 4493 tc0 = grainsize * n_tsk0; 4494 tc1 = tc - tc0; 4495 } else if (n_tsk0 <= extras) { 4496 gr_size0++; // integrate extras into grainsize 4497 ext0 = 0; // no extra iters in 1st half 4498 ext1 = extras - n_tsk0; // remaining extras 4499 tc0 = gr_size0 * n_tsk0; 4500 tc1 = tc - tc0; 4501 } else { // n_tsk0 > extras 4502 ext1 = 0; // no extra iters in 2nd half 4503 ext0 = extras; 4504 tc1 = grainsize * n_tsk1; 4505 tc0 = tc - tc1; 4506 } 4507 ub0 = lower + st * (tc0 - 1); 4508 lb1 = ub0 + st; 4509 4510 // create pattern task for 2nd half of the loop 4511 next_task = __kmp_task_dup_alloc(thread, task); // duplicate the task 4512 // adjust lower bound (upper bound is not changed) for the 2nd half 4513 *(kmp_uint64 *)((char *)next_task + lower_offset) = lb1; 4514 if (ptask_dup != NULL) // construct firstprivates, etc. 4515 ptask_dup(next_task, task, 0); 4516 *ub = ub0; // adjust upper bound for the 1st half 4517 4518 // create auxiliary task for 2nd half of the loop 4519 // make sure new task has same parent task as the pattern task 4520 kmp_taskdata_t *current_task = thread->th.th_current_task; 4521 thread->th.th_current_task = taskdata->td_parent; 4522 kmp_task_t *new_task = 4523 __kmpc_omp_task_alloc(loc, gtid, 1, 3 * sizeof(void *), 4524 sizeof(__taskloop_params_t), &__kmp_taskloop_task); 4525 // restore current task 4526 thread->th.th_current_task = current_task; 4527 __taskloop_params_t *p = (__taskloop_params_t *)new_task->shareds; 4528 p->task = next_task; 4529 p->lb = (kmp_uint64 *)((char *)next_task + lower_offset); 4530 p->ub = (kmp_uint64 *)((char *)next_task + upper_offset); 4531 p->task_dup = task_dup; 4532 p->st = st; 4533 p->ub_glob = ub_glob; 4534 p->num_tasks = n_tsk1; 4535 p->grainsize = grainsize; 4536 p->extras = ext1; 4537 p->last_chunk = last_chunk1; 4538 p->tc = tc1; 4539 p->num_t_min = num_t_min; 4540 #if OMPT_SUPPORT 4541 p->codeptr_ra = codeptr_ra; 4542 #endif 4543 4544 #if OMPT_SUPPORT 4545 // schedule new task with correct return address for OMPT events 4546 __kmp_omp_taskloop_task(NULL, gtid, new_task, codeptr_ra); 4547 #else 4548 __kmp_omp_task(gtid, new_task, true); // schedule new task 4549 #endif 4550 4551 // execute the 1st half of current subrange 4552 if (n_tsk0 > num_t_min) 4553 __kmp_taskloop_recur(loc, gtid, task, lb, ub, st, ub_glob, n_tsk0, gr_size0, 4554 ext0, last_chunk0, tc0, num_t_min, 4555 #if OMPT_SUPPORT 4556 codeptr_ra, 4557 #endif 4558 task_dup); 4559 else 4560 __kmp_taskloop_linear(loc, gtid, task, lb, ub, st, ub_glob, n_tsk0, 4561 gr_size0, ext0, last_chunk0, tc0, 4562 #if OMPT_SUPPORT 4563 codeptr_ra, 4564 #endif 4565 task_dup); 4566 4567 KA_TRACE(40, ("__kmp_taskloop_recur(exit): T#%d\n", gtid)); 4568 } 4569 4570 static void __kmp_taskloop(ident_t *loc, int gtid, kmp_task_t *task, int if_val, 4571 kmp_uint64 *lb, kmp_uint64 *ub, kmp_int64 st, 4572 int nogroup, int sched, kmp_uint64 grainsize, 4573 int modifier, void *task_dup) { 4574 kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(task); 4575 KMP_DEBUG_ASSERT(task != NULL); 4576 if (nogroup == 0) { 4577 #if OMPT_SUPPORT && OMPT_OPTIONAL 4578 OMPT_STORE_RETURN_ADDRESS(gtid); 4579 #endif 4580 __kmpc_taskgroup(loc, gtid); 4581 } 4582 4583 // ========================================================================= 4584 // calculate loop parameters 4585 kmp_taskloop_bounds_t task_bounds(task, lb, ub); 4586 kmp_uint64 tc; 4587 // compiler provides global bounds here 4588 kmp_uint64 lower = task_bounds.get_lb(); 4589 kmp_uint64 upper = task_bounds.get_ub(); 4590 kmp_uint64 ub_glob = upper; // global upper used to calc lastprivate flag 4591 kmp_uint64 num_tasks = 0, extras = 0; 4592 kmp_int64 last_chunk = 4593 0; // reduce grainsize of last task by last_chunk in strict mode 4594 kmp_uint64 num_tasks_min = __kmp_taskloop_min_tasks; 4595 kmp_info_t *thread = __kmp_threads[gtid]; 4596 kmp_taskdata_t *current_task = thread->th.th_current_task; 4597 4598 KA_TRACE(20, ("__kmp_taskloop: T#%d, task %p, lb %lld, ub %lld, st %lld, " 4599 "grain %llu(%d, %d), dup %p\n", 4600 gtid, taskdata, lower, upper, st, grainsize, sched, modifier, 4601 task_dup)); 4602 4603 // compute trip count 4604 if (st == 1) { // most common case 4605 tc = upper - lower + 1; 4606 } else if (st < 0) { 4607 tc = (lower - upper) / (-st) + 1; 4608 } else { // st > 0 4609 tc = (upper - lower) / st + 1; 4610 } 4611 if (tc == 0) { 4612 KA_TRACE(20, ("__kmp_taskloop(exit): T#%d zero-trip loop\n", gtid)); 4613 // free the pattern task and exit 4614 __kmp_task_start(gtid, task, current_task); 4615 // do not execute anything for zero-trip loop 4616 __kmp_task_finish<false>(gtid, task, current_task); 4617 return; 4618 } 4619 4620 #if OMPT_SUPPORT && OMPT_OPTIONAL 4621 ompt_team_info_t *team_info = __ompt_get_teaminfo(0, NULL); 4622 ompt_task_info_t *task_info = __ompt_get_task_info_object(0); 4623 if (ompt_enabled.ompt_callback_work) { 4624 ompt_callbacks.ompt_callback(ompt_callback_work)( 4625 ompt_work_taskloop, ompt_scope_begin, &(team_info->parallel_data), 4626 &(task_info->task_data), tc, OMPT_GET_RETURN_ADDRESS(0)); 4627 } 4628 #endif 4629 4630 if (num_tasks_min == 0) 4631 // TODO: can we choose better default heuristic? 4632 num_tasks_min = 4633 KMP_MIN(thread->th.th_team_nproc * 10, INITIAL_TASK_DEQUE_SIZE); 4634 4635 // compute num_tasks/grainsize based on the input provided 4636 switch (sched) { 4637 case 0: // no schedule clause specified, we can choose the default 4638 // let's try to schedule (team_size*10) tasks 4639 grainsize = thread->th.th_team_nproc * 10; 4640 KMP_FALLTHROUGH(); 4641 case 2: // num_tasks provided 4642 if (grainsize > tc) { 4643 num_tasks = tc; // too big num_tasks requested, adjust values 4644 grainsize = 1; 4645 extras = 0; 4646 } else { 4647 num_tasks = grainsize; 4648 grainsize = tc / num_tasks; 4649 extras = tc % num_tasks; 4650 } 4651 break; 4652 case 1: // grainsize provided 4653 if (grainsize > tc) { 4654 num_tasks = 1; 4655 grainsize = tc; // too big grainsize requested, adjust values 4656 extras = 0; 4657 } else { 4658 if (modifier) { 4659 num_tasks = (tc + grainsize - 1) / grainsize; 4660 last_chunk = tc - (num_tasks * grainsize); 4661 extras = 0; 4662 } else { 4663 num_tasks = tc / grainsize; 4664 // adjust grainsize for balanced distribution of iterations 4665 grainsize = tc / num_tasks; 4666 extras = tc % num_tasks; 4667 } 4668 } 4669 break; 4670 default: 4671 KMP_ASSERT2(0, "unknown scheduling of taskloop"); 4672 } 4673 4674 KMP_DEBUG_ASSERT(tc == num_tasks * grainsize + 4675 (last_chunk < 0 ? last_chunk : extras)); 4676 KMP_DEBUG_ASSERT(num_tasks > extras); 4677 KMP_DEBUG_ASSERT(num_tasks > 0); 4678 // ========================================================================= 4679 4680 // check if clause value first 4681 // Also require GOMP_taskloop to reduce to linear (taskdata->td_flags.native) 4682 if (if_val == 0) { // if(0) specified, mark task as serial 4683 taskdata->td_flags.task_serial = 1; 4684 taskdata->td_flags.tiedness = TASK_TIED; // AC: serial task cannot be untied 4685 // always start serial tasks linearly 4686 __kmp_taskloop_linear(loc, gtid, task, lb, ub, st, ub_glob, num_tasks, 4687 grainsize, extras, last_chunk, tc, 4688 #if OMPT_SUPPORT 4689 OMPT_GET_RETURN_ADDRESS(0), 4690 #endif 4691 task_dup); 4692 // !taskdata->td_flags.native => currently force linear spawning of tasks 4693 // for GOMP_taskloop 4694 } else if (num_tasks > num_tasks_min && !taskdata->td_flags.native) { 4695 KA_TRACE(20, ("__kmp_taskloop: T#%d, go recursive: tc %llu, #tasks %llu" 4696 "(%lld), grain %llu, extras %llu, last_chunk %lld\n", 4697 gtid, tc, num_tasks, num_tasks_min, grainsize, extras, 4698 last_chunk)); 4699 __kmp_taskloop_recur(loc, gtid, task, lb, ub, st, ub_glob, num_tasks, 4700 grainsize, extras, last_chunk, tc, num_tasks_min, 4701 #if OMPT_SUPPORT 4702 OMPT_GET_RETURN_ADDRESS(0), 4703 #endif 4704 task_dup); 4705 } else { 4706 KA_TRACE(20, ("__kmp_taskloop: T#%d, go linear: tc %llu, #tasks %llu" 4707 "(%lld), grain %llu, extras %llu, last_chunk %lld\n", 4708 gtid, tc, num_tasks, num_tasks_min, grainsize, extras, 4709 last_chunk)); 4710 __kmp_taskloop_linear(loc, gtid, task, lb, ub, st, ub_glob, num_tasks, 4711 grainsize, extras, last_chunk, tc, 4712 #if OMPT_SUPPORT 4713 OMPT_GET_RETURN_ADDRESS(0), 4714 #endif 4715 task_dup); 4716 } 4717 4718 #if OMPT_SUPPORT && OMPT_OPTIONAL 4719 if (ompt_enabled.ompt_callback_work) { 4720 ompt_callbacks.ompt_callback(ompt_callback_work)( 4721 ompt_work_taskloop, ompt_scope_end, &(team_info->parallel_data), 4722 &(task_info->task_data), tc, OMPT_GET_RETURN_ADDRESS(0)); 4723 } 4724 #endif 4725 4726 if (nogroup == 0) { 4727 #if OMPT_SUPPORT && OMPT_OPTIONAL 4728 OMPT_STORE_RETURN_ADDRESS(gtid); 4729 #endif 4730 __kmpc_end_taskgroup(loc, gtid); 4731 } 4732 KA_TRACE(20, ("__kmp_taskloop(exit): T#%d\n", gtid)); 4733 } 4734 4735 /*! 4736 @ingroup TASKING 4737 @param loc Source location information 4738 @param gtid Global thread ID 4739 @param task Task structure 4740 @param if_val Value of the if clause 4741 @param lb Pointer to loop lower bound in task structure 4742 @param ub Pointer to loop upper bound in task structure 4743 @param st Loop stride 4744 @param nogroup Flag, 1 if nogroup clause specified, 0 otherwise 4745 @param sched Schedule specified 0/1/2 for none/grainsize/num_tasks 4746 @param grainsize Schedule value if specified 4747 @param task_dup Tasks duplication routine 4748 4749 Execute the taskloop construct. 4750 */ 4751 void __kmpc_taskloop(ident_t *loc, int gtid, kmp_task_t *task, int if_val, 4752 kmp_uint64 *lb, kmp_uint64 *ub, kmp_int64 st, int nogroup, 4753 int sched, kmp_uint64 grainsize, void *task_dup) { 4754 __kmp_assert_valid_gtid(gtid); 4755 KA_TRACE(20, ("__kmpc_taskloop(enter): T#%d\n", gtid)); 4756 __kmp_taskloop(loc, gtid, task, if_val, lb, ub, st, nogroup, sched, grainsize, 4757 0, task_dup); 4758 KA_TRACE(20, ("__kmpc_taskloop(exit): T#%d\n", gtid)); 4759 } 4760 4761 /*! 4762 @ingroup TASKING 4763 @param loc Source location information 4764 @param gtid Global thread ID 4765 @param task Task structure 4766 @param if_val Value of the if clause 4767 @param lb Pointer to loop lower bound in task structure 4768 @param ub Pointer to loop upper bound in task structure 4769 @param st Loop stride 4770 @param nogroup Flag, 1 if nogroup clause specified, 0 otherwise 4771 @param sched Schedule specified 0/1/2 for none/grainsize/num_tasks 4772 @param grainsize Schedule value if specified 4773 @param modifer Modifier 'strict' for sched, 1 if present, 0 otherwise 4774 @param task_dup Tasks duplication routine 4775 4776 Execute the taskloop construct. 4777 */ 4778 void __kmpc_taskloop_5(ident_t *loc, int gtid, kmp_task_t *task, int if_val, 4779 kmp_uint64 *lb, kmp_uint64 *ub, kmp_int64 st, 4780 int nogroup, int sched, kmp_uint64 grainsize, 4781 int modifier, void *task_dup) { 4782 __kmp_assert_valid_gtid(gtid); 4783 KA_TRACE(20, ("__kmpc_taskloop_5(enter): T#%d\n", gtid)); 4784 __kmp_taskloop(loc, gtid, task, if_val, lb, ub, st, nogroup, sched, grainsize, 4785 modifier, task_dup); 4786 KA_TRACE(20, ("__kmpc_taskloop_5(exit): T#%d\n", gtid)); 4787 } 4788