/* * kmp_tasking.cpp -- OpenMP 3.0 tasking support. */ //===----------------------------------------------------------------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #include "kmp.h" #include "kmp_i18n.h" #include "kmp_itt.h" #include "kmp_stats.h" #include "kmp_wait_release.h" #include "kmp_taskdeps.h" #if OMPT_SUPPORT #include "ompt-specific.h" #endif #include "tsan_annotations.h" /* forward declaration */ static void __kmp_enable_tasking(kmp_task_team_t *task_team, kmp_info_t *this_thr); static void __kmp_alloc_task_deque(kmp_info_t *thread, kmp_thread_data_t *thread_data); static int __kmp_realloc_task_threads_data(kmp_info_t *thread, kmp_task_team_t *task_team); static void __kmp_bottom_half_finish_proxy(kmp_int32 gtid, kmp_task_t *ptask); #ifdef BUILD_TIED_TASK_STACK // __kmp_trace_task_stack: print the tied tasks from the task stack in order // from top do bottom // // gtid: global thread identifier for thread containing stack // thread_data: thread data for task team thread containing stack // threshold: value above which the trace statement triggers // location: string identifying call site of this function (for trace) static void __kmp_trace_task_stack(kmp_int32 gtid, kmp_thread_data_t *thread_data, int threshold, char *location) { kmp_task_stack_t *task_stack = &thread_data->td.td_susp_tied_tasks; kmp_taskdata_t **stack_top = task_stack->ts_top; kmp_int32 entries = task_stack->ts_entries; kmp_taskdata_t *tied_task; KA_TRACE( threshold, ("__kmp_trace_task_stack(start): location = %s, gtid = %d, entries = %d, " "first_block = %p, stack_top = %p \n", location, gtid, entries, task_stack->ts_first_block, stack_top)); KMP_DEBUG_ASSERT(stack_top != NULL); KMP_DEBUG_ASSERT(entries > 0); while (entries != 0) { KMP_DEBUG_ASSERT(stack_top != &task_stack->ts_first_block.sb_block[0]); // fix up ts_top if we need to pop from previous block if (entries & TASK_STACK_INDEX_MASK == 0) { kmp_stack_block_t *stack_block = (kmp_stack_block_t *)(stack_top); stack_block = stack_block->sb_prev; stack_top = &stack_block->sb_block[TASK_STACK_BLOCK_SIZE]; } // finish bookkeeping stack_top--; entries--; tied_task = *stack_top; KMP_DEBUG_ASSERT(tied_task != NULL); KMP_DEBUG_ASSERT(tied_task->td_flags.tasktype == TASK_TIED); KA_TRACE(threshold, ("__kmp_trace_task_stack(%s): gtid=%d, entry=%d, " "stack_top=%p, tied_task=%p\n", location, gtid, entries, stack_top, tied_task)); } KMP_DEBUG_ASSERT(stack_top == &task_stack->ts_first_block.sb_block[0]); KA_TRACE(threshold, ("__kmp_trace_task_stack(exit): location = %s, gtid = %d\n", location, gtid)); } // __kmp_init_task_stack: initialize the task stack for the first time // after a thread_data structure is created. // It should not be necessary to do this again (assuming the stack works). // // gtid: global thread identifier of calling thread // thread_data: thread data for task team thread containing stack static void __kmp_init_task_stack(kmp_int32 gtid, kmp_thread_data_t *thread_data) { kmp_task_stack_t *task_stack = &thread_data->td.td_susp_tied_tasks; kmp_stack_block_t *first_block; // set up the first block of the stack first_block = &task_stack->ts_first_block; task_stack->ts_top = (kmp_taskdata_t **)first_block; memset((void *)first_block, '\0', TASK_STACK_BLOCK_SIZE * sizeof(kmp_taskdata_t *)); // initialize the stack to be empty task_stack->ts_entries = TASK_STACK_EMPTY; first_block->sb_next = NULL; first_block->sb_prev = NULL; } // __kmp_free_task_stack: free the task stack when thread_data is destroyed. // // gtid: global thread identifier for calling thread // thread_data: thread info for thread containing stack static void __kmp_free_task_stack(kmp_int32 gtid, kmp_thread_data_t *thread_data) { kmp_task_stack_t *task_stack = &thread_data->td.td_susp_tied_tasks; kmp_stack_block_t *stack_block = &task_stack->ts_first_block; KMP_DEBUG_ASSERT(task_stack->ts_entries == TASK_STACK_EMPTY); // free from the second block of the stack while (stack_block != NULL) { kmp_stack_block_t *next_block = (stack_block) ? stack_block->sb_next : NULL; stack_block->sb_next = NULL; stack_block->sb_prev = NULL; if (stack_block != &task_stack->ts_first_block) { __kmp_thread_free(thread, stack_block); // free the block, if not the first } stack_block = next_block; } // initialize the stack to be empty task_stack->ts_entries = 0; task_stack->ts_top = NULL; } // __kmp_push_task_stack: Push the tied task onto the task stack. // Grow the stack if necessary by allocating another block. // // gtid: global thread identifier for calling thread // thread: thread info for thread containing stack // tied_task: the task to push on the stack static void __kmp_push_task_stack(kmp_int32 gtid, kmp_info_t *thread, kmp_taskdata_t *tied_task) { // GEH - need to consider what to do if tt_threads_data not allocated yet kmp_thread_data_t *thread_data = &thread->th.th_task_team->tt.tt_threads_data[__kmp_tid_from_gtid(gtid)]; kmp_task_stack_t *task_stack = &thread_data->td.td_susp_tied_tasks; if (tied_task->td_flags.team_serial || tied_task->td_flags.tasking_ser) { return; // Don't push anything on stack if team or team tasks are serialized } KMP_DEBUG_ASSERT(tied_task->td_flags.tasktype == TASK_TIED); KMP_DEBUG_ASSERT(task_stack->ts_top != NULL); KA_TRACE(20, ("__kmp_push_task_stack(enter): GTID: %d; THREAD: %p; TASK: %p\n", gtid, thread, tied_task)); // Store entry *(task_stack->ts_top) = tied_task; // Do bookkeeping for next push task_stack->ts_top++; task_stack->ts_entries++; if (task_stack->ts_entries & TASK_STACK_INDEX_MASK == 0) { // Find beginning of this task block kmp_stack_block_t *stack_block = (kmp_stack_block_t *)(task_stack->ts_top - TASK_STACK_BLOCK_SIZE); // Check if we already have a block if (stack_block->sb_next != NULL) { // reset ts_top to beginning of next block task_stack->ts_top = &stack_block->sb_next->sb_block[0]; } else { // Alloc new block and link it up kmp_stack_block_t *new_block = (kmp_stack_block_t *)__kmp_thread_calloc( thread, sizeof(kmp_stack_block_t)); task_stack->ts_top = &new_block->sb_block[0]; stack_block->sb_next = new_block; new_block->sb_prev = stack_block; new_block->sb_next = NULL; KA_TRACE( 30, ("__kmp_push_task_stack(): GTID: %d; TASK: %p; Alloc new block: %p\n", gtid, tied_task, new_block)); } } KA_TRACE(20, ("__kmp_push_task_stack(exit): GTID: %d; TASK: %p\n", gtid, tied_task)); } // __kmp_pop_task_stack: Pop the tied task from the task stack. Don't return // the task, just check to make sure it matches the ending task passed in. // // gtid: global thread identifier for the calling thread // thread: thread info structure containing stack // tied_task: the task popped off the stack // ending_task: the task that is ending (should match popped task) static void __kmp_pop_task_stack(kmp_int32 gtid, kmp_info_t *thread, kmp_taskdata_t *ending_task) { // GEH - need to consider what to do if tt_threads_data not allocated yet kmp_thread_data_t *thread_data = &thread->th.th_task_team->tt_threads_data[__kmp_tid_from_gtid(gtid)]; kmp_task_stack_t *task_stack = &thread_data->td.td_susp_tied_tasks; kmp_taskdata_t *tied_task; if (ending_task->td_flags.team_serial || ending_task->td_flags.tasking_ser) { // Don't pop anything from stack if team or team tasks are serialized return; } KMP_DEBUG_ASSERT(task_stack->ts_top != NULL); KMP_DEBUG_ASSERT(task_stack->ts_entries > 0); KA_TRACE(20, ("__kmp_pop_task_stack(enter): GTID: %d; THREAD: %p\n", gtid, thread)); // fix up ts_top if we need to pop from previous block if (task_stack->ts_entries & TASK_STACK_INDEX_MASK == 0) { kmp_stack_block_t *stack_block = (kmp_stack_block_t *)(task_stack->ts_top); stack_block = stack_block->sb_prev; task_stack->ts_top = &stack_block->sb_block[TASK_STACK_BLOCK_SIZE]; } // finish bookkeeping task_stack->ts_top--; task_stack->ts_entries--; tied_task = *(task_stack->ts_top); KMP_DEBUG_ASSERT(tied_task != NULL); KMP_DEBUG_ASSERT(tied_task->td_flags.tasktype == TASK_TIED); KMP_DEBUG_ASSERT(tied_task == ending_task); // If we built the stack correctly KA_TRACE(20, ("__kmp_pop_task_stack(exit): GTID: %d; TASK: %p\n", gtid, tied_task)); return; } #endif /* BUILD_TIED_TASK_STACK */ // returns 1 if new task is allowed to execute, 0 otherwise // checks Task Scheduling constraint (if requested) and // mutexinoutset dependencies if any static bool __kmp_task_is_allowed(int gtid, const kmp_int32 is_constrained, const kmp_taskdata_t *tasknew, const kmp_taskdata_t *taskcurr) { if (is_constrained && (tasknew->td_flags.tiedness == TASK_TIED)) { // Check if the candidate obeys the Task Scheduling Constraints (TSC) // only descendant of all deferred tied tasks can be scheduled, checking // the last one is enough, as it in turn is the descendant of all others kmp_taskdata_t *current = taskcurr->td_last_tied; KMP_DEBUG_ASSERT(current != NULL); // check if the task is not suspended on barrier if (current->td_flags.tasktype == TASK_EXPLICIT || current->td_taskwait_thread > 0) { // <= 0 on barrier kmp_int32 level = current->td_level; kmp_taskdata_t *parent = tasknew->td_parent; while (parent != current && parent->td_level > level) { // check generation up to the level of the current task parent = parent->td_parent; KMP_DEBUG_ASSERT(parent != NULL); } if (parent != current) return false; } } // Check mutexinoutset dependencies, acquire locks kmp_depnode_t *node = tasknew->td_depnode; if (node && (node->dn.mtx_num_locks > 0)) { for (int i = 0; i < node->dn.mtx_num_locks; ++i) { KMP_DEBUG_ASSERT(node->dn.mtx_locks[i] != NULL); if (__kmp_test_lock(node->dn.mtx_locks[i], gtid)) continue; // could not get the lock, release previous locks for (int j = i - 1; j >= 0; --j) __kmp_release_lock(node->dn.mtx_locks[j], gtid); return false; } // negative num_locks means all locks acquired successfully node->dn.mtx_num_locks = -node->dn.mtx_num_locks; } return true; } // __kmp_realloc_task_deque: // Re-allocates a task deque for a particular thread, copies the content from // the old deque and adjusts the necessary data structures relating to the // deque. This operation must be done with the deque_lock being held static void __kmp_realloc_task_deque(kmp_info_t *thread, kmp_thread_data_t *thread_data) { kmp_int32 size = TASK_DEQUE_SIZE(thread_data->td); KMP_DEBUG_ASSERT(TCR_4(thread_data->td.td_deque_ntasks) == size); kmp_int32 new_size = 2 * size; KE_TRACE(10, ("__kmp_realloc_task_deque: T#%d reallocating deque[from %d to " "%d] for thread_data %p\n", __kmp_gtid_from_thread(thread), size, new_size, thread_data)); kmp_taskdata_t **new_deque = (kmp_taskdata_t **)__kmp_allocate(new_size * sizeof(kmp_taskdata_t *)); int i, j; for (i = thread_data->td.td_deque_head, j = 0; j < size; i = (i + 1) & TASK_DEQUE_MASK(thread_data->td), j++) new_deque[j] = thread_data->td.td_deque[i]; __kmp_free(thread_data->td.td_deque); thread_data->td.td_deque_head = 0; thread_data->td.td_deque_tail = size; thread_data->td.td_deque = new_deque; thread_data->td.td_deque_size = new_size; } // __kmp_push_task: Add a task to the thread's deque static kmp_int32 __kmp_push_task(kmp_int32 gtid, kmp_task_t *task) { kmp_info_t *thread = __kmp_threads[gtid]; kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(task); kmp_task_team_t *task_team = thread->th.th_task_team; kmp_int32 tid = __kmp_tid_from_gtid(gtid); kmp_thread_data_t *thread_data; KA_TRACE(20, ("__kmp_push_task: T#%d trying to push task %p.\n", gtid, taskdata)); if (taskdata->td_flags.tiedness == TASK_UNTIED) { // untied task needs to increment counter so that the task structure is not // freed prematurely kmp_int32 counter = 1 + KMP_ATOMIC_INC(&taskdata->td_untied_count); KMP_DEBUG_USE_VAR(counter); KA_TRACE( 20, ("__kmp_push_task: T#%d untied_count (%d) incremented for task %p\n", gtid, counter, taskdata)); } // The first check avoids building task_team thread data if serialized if (taskdata->td_flags.task_serial) { KA_TRACE(20, ("__kmp_push_task: T#%d team serialized; returning " "TASK_NOT_PUSHED for task %p\n", gtid, taskdata)); return TASK_NOT_PUSHED; } // Now that serialized tasks have returned, we can assume that we are not in // immediate exec mode KMP_DEBUG_ASSERT(__kmp_tasking_mode != tskm_immediate_exec); if (!KMP_TASKING_ENABLED(task_team)) { __kmp_enable_tasking(task_team, thread); } KMP_DEBUG_ASSERT(TCR_4(task_team->tt.tt_found_tasks) == TRUE); KMP_DEBUG_ASSERT(TCR_PTR(task_team->tt.tt_threads_data) != NULL); // Find tasking deque specific to encountering thread thread_data = &task_team->tt.tt_threads_data[tid]; // No lock needed since only owner can allocate if (thread_data->td.td_deque == NULL) { __kmp_alloc_task_deque(thread, thread_data); } int locked = 0; // Check if deque is full if (TCR_4(thread_data->td.td_deque_ntasks) >= TASK_DEQUE_SIZE(thread_data->td)) { if (__kmp_enable_task_throttling && __kmp_task_is_allowed(gtid, __kmp_task_stealing_constraint, taskdata, thread->th.th_current_task)) { KA_TRACE(20, ("__kmp_push_task: T#%d deque is full; returning " "TASK_NOT_PUSHED for task %p\n", gtid, taskdata)); return TASK_NOT_PUSHED; } else { __kmp_acquire_bootstrap_lock(&thread_data->td.td_deque_lock); locked = 1; if (TCR_4(thread_data->td.td_deque_ntasks) >= TASK_DEQUE_SIZE(thread_data->td)) { // expand deque to push the task which is not allowed to execute __kmp_realloc_task_deque(thread, thread_data); } } } // Lock the deque for the task push operation if (!locked) { __kmp_acquire_bootstrap_lock(&thread_data->td.td_deque_lock); // Need to recheck as we can get a proxy task from thread outside of OpenMP if (TCR_4(thread_data->td.td_deque_ntasks) >= TASK_DEQUE_SIZE(thread_data->td)) { if (__kmp_enable_task_throttling && __kmp_task_is_allowed(gtid, __kmp_task_stealing_constraint, taskdata, thread->th.th_current_task)) { __kmp_release_bootstrap_lock(&thread_data->td.td_deque_lock); KA_TRACE(20, ("__kmp_push_task: T#%d deque is full on 2nd check; " "returning TASK_NOT_PUSHED for task %p\n", gtid, taskdata)); return TASK_NOT_PUSHED; } else { // expand deque to push the task which is not allowed to execute __kmp_realloc_task_deque(thread, thread_data); } } } // Must have room since no thread can add tasks but calling thread KMP_DEBUG_ASSERT(TCR_4(thread_data->td.td_deque_ntasks) < TASK_DEQUE_SIZE(thread_data->td)); thread_data->td.td_deque[thread_data->td.td_deque_tail] = taskdata; // Push taskdata // Wrap index. thread_data->td.td_deque_tail = (thread_data->td.td_deque_tail + 1) & TASK_DEQUE_MASK(thread_data->td); TCW_4(thread_data->td.td_deque_ntasks, TCR_4(thread_data->td.td_deque_ntasks) + 1); // Adjust task count KA_TRACE(20, ("__kmp_push_task: T#%d returning TASK_SUCCESSFULLY_PUSHED: " "task=%p ntasks=%d head=%u tail=%u\n", gtid, taskdata, thread_data->td.td_deque_ntasks, thread_data->td.td_deque_head, thread_data->td.td_deque_tail)); __kmp_release_bootstrap_lock(&thread_data->td.td_deque_lock); return TASK_SUCCESSFULLY_PUSHED; } // __kmp_pop_current_task_from_thread: set up current task from called thread // when team ends // // this_thr: thread structure to set current_task in. void __kmp_pop_current_task_from_thread(kmp_info_t *this_thr) { KF_TRACE(10, ("__kmp_pop_current_task_from_thread(enter): T#%d " "this_thread=%p, curtask=%p, " "curtask_parent=%p\n", 0, this_thr, this_thr->th.th_current_task, this_thr->th.th_current_task->td_parent)); this_thr->th.th_current_task = this_thr->th.th_current_task->td_parent; KF_TRACE(10, ("__kmp_pop_current_task_from_thread(exit): T#%d " "this_thread=%p, curtask=%p, " "curtask_parent=%p\n", 0, this_thr, this_thr->th.th_current_task, this_thr->th.th_current_task->td_parent)); } // __kmp_push_current_task_to_thread: set up current task in called thread for a // new team // // this_thr: thread structure to set up // team: team for implicit task data // tid: thread within team to set up void __kmp_push_current_task_to_thread(kmp_info_t *this_thr, kmp_team_t *team, int tid) { // current task of the thread is a parent of the new just created implicit // tasks of new team KF_TRACE(10, ("__kmp_push_current_task_to_thread(enter): T#%d this_thread=%p " "curtask=%p " "parent_task=%p\n", tid, this_thr, this_thr->th.th_current_task, team->t.t_implicit_task_taskdata[tid].td_parent)); KMP_DEBUG_ASSERT(this_thr != NULL); if (tid == 0) { if (this_thr->th.th_current_task != &team->t.t_implicit_task_taskdata[0]) { team->t.t_implicit_task_taskdata[0].td_parent = this_thr->th.th_current_task; this_thr->th.th_current_task = &team->t.t_implicit_task_taskdata[0]; } } else { team->t.t_implicit_task_taskdata[tid].td_parent = team->t.t_implicit_task_taskdata[0].td_parent; this_thr->th.th_current_task = &team->t.t_implicit_task_taskdata[tid]; } KF_TRACE(10, ("__kmp_push_current_task_to_thread(exit): T#%d this_thread=%p " "curtask=%p " "parent_task=%p\n", tid, this_thr, this_thr->th.th_current_task, team->t.t_implicit_task_taskdata[tid].td_parent)); } // __kmp_task_start: bookkeeping for a task starting execution // // GTID: global thread id of calling thread // task: task starting execution // current_task: task suspending static void __kmp_task_start(kmp_int32 gtid, kmp_task_t *task, kmp_taskdata_t *current_task) { kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(task); kmp_info_t *thread = __kmp_threads[gtid]; KA_TRACE(10, ("__kmp_task_start(enter): T#%d starting task %p: current_task=%p\n", gtid, taskdata, current_task)); KMP_DEBUG_ASSERT(taskdata->td_flags.tasktype == TASK_EXPLICIT); // mark currently executing task as suspended // TODO: GEH - make sure root team implicit task is initialized properly. // KMP_DEBUG_ASSERT( current_task -> td_flags.executing == 1 ); current_task->td_flags.executing = 0; // Add task to stack if tied #ifdef BUILD_TIED_TASK_STACK if (taskdata->td_flags.tiedness == TASK_TIED) { __kmp_push_task_stack(gtid, thread, taskdata); } #endif /* BUILD_TIED_TASK_STACK */ // mark starting task as executing and as current task thread->th.th_current_task = taskdata; KMP_DEBUG_ASSERT(taskdata->td_flags.started == 0 || taskdata->td_flags.tiedness == TASK_UNTIED); KMP_DEBUG_ASSERT(taskdata->td_flags.executing == 0 || taskdata->td_flags.tiedness == TASK_UNTIED); taskdata->td_flags.started = 1; taskdata->td_flags.executing = 1; KMP_DEBUG_ASSERT(taskdata->td_flags.complete == 0); KMP_DEBUG_ASSERT(taskdata->td_flags.freed == 0); // GEH TODO: shouldn't we pass some sort of location identifier here? // APT: yes, we will pass location here. // need to store current thread state (in a thread or taskdata structure) // before setting work_state, otherwise wrong state is set after end of task KA_TRACE(10, ("__kmp_task_start(exit): T#%d task=%p\n", gtid, taskdata)); return; } #if OMPT_SUPPORT //------------------------------------------------------------------------------ // __ompt_task_init: // Initialize OMPT fields maintained by a task. This will only be called after // ompt_start_tool, so we already know whether ompt is enabled or not. static inline void __ompt_task_init(kmp_taskdata_t *task, int tid) { // The calls to __ompt_task_init already have the ompt_enabled condition. task->ompt_task_info.task_data.value = 0; task->ompt_task_info.frame.exit_frame = ompt_data_none; task->ompt_task_info.frame.enter_frame = ompt_data_none; task->ompt_task_info.frame.exit_frame_flags = ompt_frame_runtime | ompt_frame_framepointer; task->ompt_task_info.frame.enter_frame_flags = ompt_frame_runtime | ompt_frame_framepointer; } // __ompt_task_start: // Build and trigger task-begin event static inline void __ompt_task_start(kmp_task_t *task, kmp_taskdata_t *current_task, kmp_int32 gtid) { kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(task); ompt_task_status_t status = ompt_task_switch; if (__kmp_threads[gtid]->th.ompt_thread_info.ompt_task_yielded) { status = ompt_task_yield; __kmp_threads[gtid]->th.ompt_thread_info.ompt_task_yielded = 0; } /* let OMPT know that we're about to run this task */ if (ompt_enabled.ompt_callback_task_schedule) { ompt_callbacks.ompt_callback(ompt_callback_task_schedule)( &(current_task->ompt_task_info.task_data), status, &(taskdata->ompt_task_info.task_data)); } taskdata->ompt_task_info.scheduling_parent = current_task; } // __ompt_task_finish: // Build and trigger final task-schedule event static inline void __ompt_task_finish(kmp_task_t *task, kmp_taskdata_t *resumed_task, ompt_task_status_t status) { if (ompt_enabled.ompt_callback_task_schedule) { kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(task); if (__kmp_omp_cancellation && taskdata->td_taskgroup && taskdata->td_taskgroup->cancel_request == cancel_taskgroup) { status = ompt_task_cancel; } /* let OMPT know that we're returning to the callee task */ ompt_callbacks.ompt_callback(ompt_callback_task_schedule)( &(taskdata->ompt_task_info.task_data), status, (resumed_task ? &(resumed_task->ompt_task_info.task_data) : NULL)); } } #endif template static void __kmpc_omp_task_begin_if0_template(ident_t *loc_ref, kmp_int32 gtid, kmp_task_t *task, void *frame_address, void *return_address) { kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(task); kmp_taskdata_t *current_task = __kmp_threads[gtid]->th.th_current_task; KA_TRACE(10, ("__kmpc_omp_task_begin_if0(enter): T#%d loc=%p task=%p " "current_task=%p\n", gtid, loc_ref, taskdata, current_task)); if (taskdata->td_flags.tiedness == TASK_UNTIED) { // untied task needs to increment counter so that the task structure is not // freed prematurely kmp_int32 counter = 1 + KMP_ATOMIC_INC(&taskdata->td_untied_count); KMP_DEBUG_USE_VAR(counter); KA_TRACE(20, ("__kmpc_omp_task_begin_if0: T#%d untied_count (%d) " "incremented for task %p\n", gtid, counter, taskdata)); } taskdata->td_flags.task_serial = 1; // Execute this task immediately, not deferred. __kmp_task_start(gtid, task, current_task); #if OMPT_SUPPORT if (ompt) { if (current_task->ompt_task_info.frame.enter_frame.ptr == NULL) { current_task->ompt_task_info.frame.enter_frame.ptr = taskdata->ompt_task_info.frame.exit_frame.ptr = frame_address; current_task->ompt_task_info.frame.enter_frame_flags = taskdata->ompt_task_info.frame.exit_frame_flags = ompt_frame_application | ompt_frame_framepointer; } if (ompt_enabled.ompt_callback_task_create) { ompt_task_info_t *parent_info = &(current_task->ompt_task_info); ompt_callbacks.ompt_callback(ompt_callback_task_create)( &(parent_info->task_data), &(parent_info->frame), &(taskdata->ompt_task_info.task_data), ompt_task_explicit | TASK_TYPE_DETAILS_FORMAT(taskdata), 0, return_address); } __ompt_task_start(task, current_task, gtid); } #endif // OMPT_SUPPORT KA_TRACE(10, ("__kmpc_omp_task_begin_if0(exit): T#%d loc=%p task=%p,\n", gtid, loc_ref, taskdata)); } #if OMPT_SUPPORT OMPT_NOINLINE static void __kmpc_omp_task_begin_if0_ompt(ident_t *loc_ref, kmp_int32 gtid, kmp_task_t *task, void *frame_address, void *return_address) { __kmpc_omp_task_begin_if0_template(loc_ref, gtid, task, frame_address, return_address); } #endif // OMPT_SUPPORT // __kmpc_omp_task_begin_if0: report that a given serialized task has started // execution // // loc_ref: source location information; points to beginning of task block. // gtid: global thread number. // task: task thunk for the started task. void __kmpc_omp_task_begin_if0(ident_t *loc_ref, kmp_int32 gtid, kmp_task_t *task) { #if OMPT_SUPPORT if (UNLIKELY(ompt_enabled.enabled)) { OMPT_STORE_RETURN_ADDRESS(gtid); __kmpc_omp_task_begin_if0_ompt(loc_ref, gtid, task, OMPT_GET_FRAME_ADDRESS(1), OMPT_LOAD_RETURN_ADDRESS(gtid)); return; } #endif __kmpc_omp_task_begin_if0_template(loc_ref, gtid, task, NULL, NULL); } #ifdef TASK_UNUSED // __kmpc_omp_task_begin: report that a given task has started execution // NEVER GENERATED BY COMPILER, DEPRECATED!!! void __kmpc_omp_task_begin(ident_t *loc_ref, kmp_int32 gtid, kmp_task_t *task) { kmp_taskdata_t *current_task = __kmp_threads[gtid]->th.th_current_task; KA_TRACE( 10, ("__kmpc_omp_task_begin(enter): T#%d loc=%p task=%p current_task=%p\n", gtid, loc_ref, KMP_TASK_TO_TASKDATA(task), current_task)); __kmp_task_start(gtid, task, current_task); KA_TRACE(10, ("__kmpc_omp_task_begin(exit): T#%d loc=%p task=%p,\n", gtid, loc_ref, KMP_TASK_TO_TASKDATA(task))); return; } #endif // TASK_UNUSED // __kmp_free_task: free the current task space and the space for shareds // // gtid: Global thread ID of calling thread // taskdata: task to free // thread: thread data structure of caller static void __kmp_free_task(kmp_int32 gtid, kmp_taskdata_t *taskdata, kmp_info_t *thread) { KA_TRACE(30, ("__kmp_free_task: T#%d freeing data from task %p\n", gtid, taskdata)); // Check to make sure all flags and counters have the correct values KMP_DEBUG_ASSERT(taskdata->td_flags.tasktype == TASK_EXPLICIT); KMP_DEBUG_ASSERT(taskdata->td_flags.executing == 0); KMP_DEBUG_ASSERT(taskdata->td_flags.complete == 1); KMP_DEBUG_ASSERT(taskdata->td_flags.freed == 0); KMP_DEBUG_ASSERT(taskdata->td_allocated_child_tasks == 0 || taskdata->td_flags.task_serial == 1); KMP_DEBUG_ASSERT(taskdata->td_incomplete_child_tasks == 0); taskdata->td_flags.freed = 1; ANNOTATE_HAPPENS_BEFORE(taskdata); // deallocate the taskdata and shared variable blocks associated with this task #if USE_FAST_MEMORY __kmp_fast_free(thread, taskdata); #else /* ! USE_FAST_MEMORY */ __kmp_thread_free(thread, taskdata); #endif KA_TRACE(20, ("__kmp_free_task: T#%d freed task %p\n", gtid, taskdata)); } // __kmp_free_task_and_ancestors: free the current task and ancestors without // children // // gtid: Global thread ID of calling thread // taskdata: task to free // thread: thread data structure of caller static void __kmp_free_task_and_ancestors(kmp_int32 gtid, kmp_taskdata_t *taskdata, kmp_info_t *thread) { // Proxy tasks must always be allowed to free their parents // because they can be run in background even in serial mode. kmp_int32 team_serial = (taskdata->td_flags.team_serial || taskdata->td_flags.tasking_ser) && !taskdata->td_flags.proxy; KMP_DEBUG_ASSERT(taskdata->td_flags.tasktype == TASK_EXPLICIT); kmp_int32 children = KMP_ATOMIC_DEC(&taskdata->td_allocated_child_tasks) - 1; KMP_DEBUG_ASSERT(children >= 0); // Now, go up the ancestor tree to see if any ancestors can now be freed. while (children == 0) { kmp_taskdata_t *parent_taskdata = taskdata->td_parent; KA_TRACE(20, ("__kmp_free_task_and_ancestors(enter): T#%d task %p complete " "and freeing itself\n", gtid, taskdata)); // --- Deallocate my ancestor task --- __kmp_free_task(gtid, taskdata, thread); taskdata = parent_taskdata; if (team_serial) return; // Stop checking ancestors at implicit task instead of walking up ancestor // tree to avoid premature deallocation of ancestors. if (taskdata->td_flags.tasktype == TASK_IMPLICIT) { if (taskdata->td_dephash) { // do we need to cleanup dephash? int children = KMP_ATOMIC_LD_ACQ(&taskdata->td_incomplete_child_tasks); kmp_tasking_flags_t flags_old = taskdata->td_flags; if (children == 0 && flags_old.complete == 1) { kmp_tasking_flags_t flags_new = flags_old; flags_new.complete = 0; if (KMP_COMPARE_AND_STORE_ACQ32( RCAST(kmp_int32 *, &taskdata->td_flags), *RCAST(kmp_int32 *, &flags_old), *RCAST(kmp_int32 *, &flags_new))) { KA_TRACE(100, ("__kmp_free_task_and_ancestors: T#%d cleans " "dephash of implicit task %p\n", gtid, taskdata)); // cleanup dephash of finished implicit task __kmp_dephash_free_entries(thread, taskdata->td_dephash); } } } return; } // Predecrement simulated by "- 1" calculation children = KMP_ATOMIC_DEC(&taskdata->td_allocated_child_tasks) - 1; KMP_DEBUG_ASSERT(children >= 0); } KA_TRACE( 20, ("__kmp_free_task_and_ancestors(exit): T#%d task %p has %d children; " "not freeing it yet\n", gtid, taskdata, children)); } // __kmp_task_finish: bookkeeping to do when a task finishes execution // // gtid: global thread ID for calling thread // task: task to be finished // resumed_task: task to be resumed. (may be NULL if task is serialized) // // template: effectively ompt_enabled.enabled!=0 // the version with ompt=false is inlined, allowing to optimize away all ompt // code in this case template static void __kmp_task_finish(kmp_int32 gtid, kmp_task_t *task, kmp_taskdata_t *resumed_task) { kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(task); kmp_info_t *thread = __kmp_threads[gtid]; kmp_task_team_t *task_team = thread->th.th_task_team; // might be NULL for serial teams... kmp_int32 children = 0; KA_TRACE(10, ("__kmp_task_finish(enter): T#%d finishing task %p and resuming " "task %p\n", gtid, taskdata, resumed_task)); KMP_DEBUG_ASSERT(taskdata->td_flags.tasktype == TASK_EXPLICIT); // Pop task from stack if tied #ifdef BUILD_TIED_TASK_STACK if (taskdata->td_flags.tiedness == TASK_TIED) { __kmp_pop_task_stack(gtid, thread, taskdata); } #endif /* BUILD_TIED_TASK_STACK */ if (taskdata->td_flags.tiedness == TASK_UNTIED) { // untied task needs to check the counter so that the task structure is not // freed prematurely kmp_int32 counter = KMP_ATOMIC_DEC(&taskdata->td_untied_count) - 1; KA_TRACE( 20, ("__kmp_task_finish: T#%d untied_count (%d) decremented for task %p\n", gtid, counter, taskdata)); if (counter > 0) { // untied task is not done, to be continued possibly by other thread, do // not free it now if (resumed_task == NULL) { KMP_DEBUG_ASSERT(taskdata->td_flags.task_serial); resumed_task = taskdata->td_parent; // In a serialized task, the resumed // task is the parent } thread->th.th_current_task = resumed_task; // restore current_task resumed_task->td_flags.executing = 1; // resume previous task KA_TRACE(10, ("__kmp_task_finish(exit): T#%d partially done task %p, " "resuming task %p\n", gtid, taskdata, resumed_task)); return; } } // Check mutexinoutset dependencies, release locks kmp_depnode_t *node = taskdata->td_depnode; if (node && (node->dn.mtx_num_locks < 0)) { // negative num_locks means all locks were acquired node->dn.mtx_num_locks = -node->dn.mtx_num_locks; for (int i = node->dn.mtx_num_locks - 1; i >= 0; --i) { KMP_DEBUG_ASSERT(node->dn.mtx_locks[i] != NULL); __kmp_release_lock(node->dn.mtx_locks[i], gtid); } } // bookkeeping for resuming task: // GEH - note tasking_ser => task_serial KMP_DEBUG_ASSERT( (taskdata->td_flags.tasking_ser || taskdata->td_flags.task_serial) == taskdata->td_flags.task_serial); if (taskdata->td_flags.task_serial) { if (resumed_task == NULL) { resumed_task = taskdata->td_parent; // In a serialized task, the resumed // task is the parent } } else { KMP_DEBUG_ASSERT(resumed_task != NULL); // verify that resumed task is passed as argument } /* If the tasks' destructor thunk flag has been set, we need to invoke the destructor thunk that has been generated by the compiler. The code is placed here, since at this point other tasks might have been released hence overlapping the destructor invocations with some other work in the released tasks. The OpenMP spec is not specific on when the destructors are invoked, so we should be free to choose. */ if (taskdata->td_flags.destructors_thunk) { kmp_routine_entry_t destr_thunk = task->data1.destructors; KMP_ASSERT(destr_thunk); destr_thunk(gtid, task); } KMP_DEBUG_ASSERT(taskdata->td_flags.complete == 0); KMP_DEBUG_ASSERT(taskdata->td_flags.started == 1); KMP_DEBUG_ASSERT(taskdata->td_flags.freed == 0); bool detach = false; if (taskdata->td_flags.detachable == TASK_DETACHABLE) { if (taskdata->td_allow_completion_event.type == KMP_EVENT_ALLOW_COMPLETION) { // event hasn't been fulfilled yet. Try to detach task. __kmp_acquire_tas_lock(&taskdata->td_allow_completion_event.lock, gtid); if (taskdata->td_allow_completion_event.type == KMP_EVENT_ALLOW_COMPLETION) { // task finished execution KMP_DEBUG_ASSERT(taskdata->td_flags.executing == 1); taskdata->td_flags.executing = 0; // suspend the finishing task #if OMPT_SUPPORT // For a detached task, which is not completed, we switch back // the omp_fulfill_event signals completion // locking is necessary to avoid a race with ompt_task_late_fulfill if (ompt) __ompt_task_finish(task, resumed_task, ompt_task_detach); #endif // no access to taskdata after this point! // __kmp_fulfill_event might free taskdata at any time from now taskdata->td_flags.proxy = TASK_PROXY; // proxify! detach = true; } __kmp_release_tas_lock(&taskdata->td_allow_completion_event.lock, gtid); } } if (!detach) { taskdata->td_flags.complete = 1; // mark the task as completed #if OMPT_SUPPORT // This is not a detached task, we are done here if (ompt) __ompt_task_finish(task, resumed_task, ompt_task_complete); #endif // Only need to keep track of count if team parallel and tasking not // serialized, or task is detachable and event has already been fulfilled if (!(taskdata->td_flags.team_serial || taskdata->td_flags.tasking_ser) || taskdata->td_flags.detachable == TASK_DETACHABLE) { // Predecrement simulated by "- 1" calculation children = KMP_ATOMIC_DEC(&taskdata->td_parent->td_incomplete_child_tasks) - 1; KMP_DEBUG_ASSERT(children >= 0); if (taskdata->td_taskgroup) KMP_ATOMIC_DEC(&taskdata->td_taskgroup->count); __kmp_release_deps(gtid, taskdata); } else if (task_team && task_team->tt.tt_found_proxy_tasks) { // if we found proxy tasks there could exist a dependency chain // with the proxy task as origin __kmp_release_deps(gtid, taskdata); } // td_flags.executing must be marked as 0 after __kmp_release_deps has been // called. Othertwise, if a task is executed immediately from the // release_deps code, the flag will be reset to 1 again by this same // function KMP_DEBUG_ASSERT(taskdata->td_flags.executing == 1); taskdata->td_flags.executing = 0; // suspend the finishing task } KA_TRACE( 20, ("__kmp_task_finish: T#%d finished task %p, %d incomplete children\n", gtid, taskdata, children)); // Free this task and then ancestor tasks if they have no children. // Restore th_current_task first as suggested by John: // johnmc: if an asynchronous inquiry peers into the runtime system // it doesn't see the freed task as the current task. thread->th.th_current_task = resumed_task; if (!detach) __kmp_free_task_and_ancestors(gtid, taskdata, thread); // TODO: GEH - make sure root team implicit task is initialized properly. // KMP_DEBUG_ASSERT( resumed_task->td_flags.executing == 0 ); resumed_task->td_flags.executing = 1; // resume previous task KA_TRACE( 10, ("__kmp_task_finish(exit): T#%d finished task %p, resuming task %p\n", gtid, taskdata, resumed_task)); return; } template static void __kmpc_omp_task_complete_if0_template(ident_t *loc_ref, kmp_int32 gtid, kmp_task_t *task) { KA_TRACE(10, ("__kmpc_omp_task_complete_if0(enter): T#%d loc=%p task=%p\n", gtid, loc_ref, KMP_TASK_TO_TASKDATA(task))); // this routine will provide task to resume __kmp_task_finish(gtid, task, NULL); KA_TRACE(10, ("__kmpc_omp_task_complete_if0(exit): T#%d loc=%p task=%p\n", gtid, loc_ref, KMP_TASK_TO_TASKDATA(task))); #if OMPT_SUPPORT if (ompt) { ompt_frame_t *ompt_frame; __ompt_get_task_info_internal(0, NULL, NULL, &ompt_frame, NULL, NULL); ompt_frame->enter_frame = ompt_data_none; ompt_frame->enter_frame_flags = ompt_frame_runtime | ompt_frame_framepointer; } #endif return; } #if OMPT_SUPPORT OMPT_NOINLINE void __kmpc_omp_task_complete_if0_ompt(ident_t *loc_ref, kmp_int32 gtid, kmp_task_t *task) { __kmpc_omp_task_complete_if0_template(loc_ref, gtid, task); } #endif // OMPT_SUPPORT // __kmpc_omp_task_complete_if0: report that a task has completed execution // // loc_ref: source location information; points to end of task block. // gtid: global thread number. // task: task thunk for the completed task. void __kmpc_omp_task_complete_if0(ident_t *loc_ref, kmp_int32 gtid, kmp_task_t *task) { #if OMPT_SUPPORT if (UNLIKELY(ompt_enabled.enabled)) { __kmpc_omp_task_complete_if0_ompt(loc_ref, gtid, task); return; } #endif __kmpc_omp_task_complete_if0_template(loc_ref, gtid, task); } #ifdef TASK_UNUSED // __kmpc_omp_task_complete: report that a task has completed execution // NEVER GENERATED BY COMPILER, DEPRECATED!!! void __kmpc_omp_task_complete(ident_t *loc_ref, kmp_int32 gtid, kmp_task_t *task) { KA_TRACE(10, ("__kmpc_omp_task_complete(enter): T#%d loc=%p task=%p\n", gtid, loc_ref, KMP_TASK_TO_TASKDATA(task))); __kmp_task_finish(gtid, task, NULL); // Not sure how to find task to resume KA_TRACE(10, ("__kmpc_omp_task_complete(exit): T#%d loc=%p task=%p\n", gtid, loc_ref, KMP_TASK_TO_TASKDATA(task))); return; } #endif // TASK_UNUSED // __kmp_init_implicit_task: Initialize the appropriate fields in the implicit // task for a given thread // // loc_ref: reference to source location of parallel region // this_thr: thread data structure corresponding to implicit task // team: team for this_thr // tid: thread id of given thread within team // set_curr_task: TRUE if need to push current task to thread // NOTE: Routine does not set up the implicit task ICVS. This is assumed to // have already been done elsewhere. // TODO: Get better loc_ref. Value passed in may be NULL void __kmp_init_implicit_task(ident_t *loc_ref, kmp_info_t *this_thr, kmp_team_t *team, int tid, int set_curr_task) { kmp_taskdata_t *task = &team->t.t_implicit_task_taskdata[tid]; KF_TRACE( 10, ("__kmp_init_implicit_task(enter): T#:%d team=%p task=%p, reinit=%s\n", tid, team, task, set_curr_task ? "TRUE" : "FALSE")); task->td_task_id = KMP_GEN_TASK_ID(); task->td_team = team; // task->td_parent = NULL; // fix for CQ230101 (broken parent task info // in debugger) task->td_ident = loc_ref; task->td_taskwait_ident = NULL; task->td_taskwait_counter = 0; task->td_taskwait_thread = 0; task->td_flags.tiedness = TASK_TIED; task->td_flags.tasktype = TASK_IMPLICIT; task->td_flags.proxy = TASK_FULL; // All implicit tasks are executed immediately, not deferred task->td_flags.task_serial = 1; task->td_flags.tasking_ser = (__kmp_tasking_mode == tskm_immediate_exec); task->td_flags.team_serial = (team->t.t_serialized) ? 1 : 0; task->td_flags.started = 1; task->td_flags.executing = 1; task->td_flags.complete = 0; task->td_flags.freed = 0; task->td_depnode = NULL; task->td_last_tied = task; task->td_allow_completion_event.type = KMP_EVENT_UNINITIALIZED; if (set_curr_task) { // only do this init first time thread is created KMP_ATOMIC_ST_REL(&task->td_incomplete_child_tasks, 0); // Not used: don't need to deallocate implicit task KMP_ATOMIC_ST_REL(&task->td_allocated_child_tasks, 0); task->td_taskgroup = NULL; // An implicit task does not have taskgroup task->td_dephash = NULL; __kmp_push_current_task_to_thread(this_thr, team, tid); } else { KMP_DEBUG_ASSERT(task->td_incomplete_child_tasks == 0); KMP_DEBUG_ASSERT(task->td_allocated_child_tasks == 0); } #if OMPT_SUPPORT if (UNLIKELY(ompt_enabled.enabled)) __ompt_task_init(task, tid); #endif KF_TRACE(10, ("__kmp_init_implicit_task(exit): T#:%d team=%p task=%p\n", tid, team, task)); } // __kmp_finish_implicit_task: Release resources associated to implicit tasks // at the end of parallel regions. Some resources are kept for reuse in the next // parallel region. // // thread: thread data structure corresponding to implicit task void __kmp_finish_implicit_task(kmp_info_t *thread) { kmp_taskdata_t *task = thread->th.th_current_task; if (task->td_dephash) { int children; task->td_flags.complete = 1; children = KMP_ATOMIC_LD_ACQ(&task->td_incomplete_child_tasks); kmp_tasking_flags_t flags_old = task->td_flags; if (children == 0 && flags_old.complete == 1) { kmp_tasking_flags_t flags_new = flags_old; flags_new.complete = 0; if (KMP_COMPARE_AND_STORE_ACQ32(RCAST(kmp_int32 *, &task->td_flags), *RCAST(kmp_int32 *, &flags_old), *RCAST(kmp_int32 *, &flags_new))) { KA_TRACE(100, ("__kmp_finish_implicit_task: T#%d cleans " "dephash of implicit task %p\n", thread->th.th_info.ds.ds_gtid, task)); __kmp_dephash_free_entries(thread, task->td_dephash); } } } } // __kmp_free_implicit_task: Release resources associated to implicit tasks // when these are destroyed regions // // thread: thread data structure corresponding to implicit task void __kmp_free_implicit_task(kmp_info_t *thread) { kmp_taskdata_t *task = thread->th.th_current_task; if (task && task->td_dephash) { __kmp_dephash_free(thread, task->td_dephash); task->td_dephash = NULL; } } // Round up a size to a power of two specified by val: Used to insert padding // between structures co-allocated using a single malloc() call static size_t __kmp_round_up_to_val(size_t size, size_t val) { if (size & (val - 1)) { size &= ~(val - 1); if (size <= KMP_SIZE_T_MAX - val) { size += val; // Round up if there is no overflow. } } return size; } // __kmp_round_up_to_va // __kmp_task_alloc: Allocate the taskdata and task data structures for a task // // loc_ref: source location information // gtid: global thread number. // flags: include tiedness & task type (explicit vs. implicit) of the ''new'' // task encountered. Converted from kmp_int32 to kmp_tasking_flags_t in routine. // sizeof_kmp_task_t: Size in bytes of kmp_task_t data structure including // private vars accessed in task. // sizeof_shareds: Size in bytes of array of pointers to shared vars accessed // in task. // task_entry: Pointer to task code entry point generated by compiler. // returns: a pointer to the allocated kmp_task_t structure (task). kmp_task_t *__kmp_task_alloc(ident_t *loc_ref, kmp_int32 gtid, kmp_tasking_flags_t *flags, size_t sizeof_kmp_task_t, size_t sizeof_shareds, kmp_routine_entry_t task_entry) { kmp_task_t *task; kmp_taskdata_t *taskdata; kmp_info_t *thread = __kmp_threads[gtid]; kmp_team_t *team = thread->th.th_team; kmp_taskdata_t *parent_task = thread->th.th_current_task; size_t shareds_offset; if (!TCR_4(__kmp_init_middle)) __kmp_middle_initialize(); KA_TRACE(10, ("__kmp_task_alloc(enter): T#%d loc=%p, flags=(0x%x) " "sizeof_task=%ld sizeof_shared=%ld entry=%p\n", gtid, loc_ref, *((kmp_int32 *)flags), sizeof_kmp_task_t, sizeof_shareds, task_entry)); if (parent_task->td_flags.final) { if (flags->merged_if0) { } flags->final = 1; } if (flags->tiedness == TASK_UNTIED && !team->t.t_serialized) { // Untied task encountered causes the TSC algorithm to check entire deque of // the victim thread. If no untied task encountered, then checking the head // of the deque should be enough. KMP_CHECK_UPDATE(thread->th.th_task_team->tt.tt_untied_task_encountered, 1); } // Detachable tasks are not proxy tasks yet but could be in the future. Doing // the tasking setup // when that happens is too late. if (flags->proxy == TASK_PROXY || flags->detachable == TASK_DETACHABLE) { if (flags->proxy == TASK_PROXY) { flags->tiedness = TASK_UNTIED; flags->merged_if0 = 1; } /* are we running in a sequential parallel or tskm_immediate_exec... we need tasking support enabled */ if ((thread->th.th_task_team) == NULL) { /* This should only happen if the team is serialized setup a task team and propagate it to the thread */ KMP_DEBUG_ASSERT(team->t.t_serialized); KA_TRACE(30, ("T#%d creating task team in __kmp_task_alloc for proxy task\n", gtid)); __kmp_task_team_setup( thread, team, 1); // 1 indicates setup the current team regardless of nthreads thread->th.th_task_team = team->t.t_task_team[thread->th.th_task_state]; } kmp_task_team_t *task_team = thread->th.th_task_team; /* tasking must be enabled now as the task might not be pushed */ if (!KMP_TASKING_ENABLED(task_team)) { KA_TRACE( 30, ("T#%d enabling tasking in __kmp_task_alloc for proxy task\n", gtid)); __kmp_enable_tasking(task_team, thread); kmp_int32 tid = thread->th.th_info.ds.ds_tid; kmp_thread_data_t *thread_data = &task_team->tt.tt_threads_data[tid]; // No lock needed since only owner can allocate if (thread_data->td.td_deque == NULL) { __kmp_alloc_task_deque(thread, thread_data); } } if (task_team->tt.tt_found_proxy_tasks == FALSE) TCW_4(task_team->tt.tt_found_proxy_tasks, TRUE); } // Calculate shared structure offset including padding after kmp_task_t struct // to align pointers in shared struct shareds_offset = sizeof(kmp_taskdata_t) + sizeof_kmp_task_t; shareds_offset = __kmp_round_up_to_val(shareds_offset, sizeof(void *)); // Allocate a kmp_taskdata_t block and a kmp_task_t block. KA_TRACE(30, ("__kmp_task_alloc: T#%d First malloc size: %ld\n", gtid, shareds_offset)); KA_TRACE(30, ("__kmp_task_alloc: T#%d Second malloc size: %ld\n", gtid, sizeof_shareds)); // Avoid double allocation here by combining shareds with taskdata #if USE_FAST_MEMORY taskdata = (kmp_taskdata_t *)__kmp_fast_allocate(thread, shareds_offset + sizeof_shareds); #else /* ! USE_FAST_MEMORY */ taskdata = (kmp_taskdata_t *)__kmp_thread_malloc(thread, shareds_offset + sizeof_shareds); #endif /* USE_FAST_MEMORY */ ANNOTATE_HAPPENS_AFTER(taskdata); task = KMP_TASKDATA_TO_TASK(taskdata); // Make sure task & taskdata are aligned appropriately #if KMP_ARCH_X86 || KMP_ARCH_PPC64 || !KMP_HAVE_QUAD KMP_DEBUG_ASSERT((((kmp_uintptr_t)taskdata) & (sizeof(double) - 1)) == 0); KMP_DEBUG_ASSERT((((kmp_uintptr_t)task) & (sizeof(double) - 1)) == 0); #else KMP_DEBUG_ASSERT((((kmp_uintptr_t)taskdata) & (sizeof(_Quad) - 1)) == 0); KMP_DEBUG_ASSERT((((kmp_uintptr_t)task) & (sizeof(_Quad) - 1)) == 0); #endif if (sizeof_shareds > 0) { // Avoid double allocation here by combining shareds with taskdata task->shareds = &((char *)taskdata)[shareds_offset]; // Make sure shareds struct is aligned to pointer size KMP_DEBUG_ASSERT((((kmp_uintptr_t)task->shareds) & (sizeof(void *) - 1)) == 0); } else { task->shareds = NULL; } task->routine = task_entry; task->part_id = 0; // AC: Always start with 0 part id taskdata->td_task_id = KMP_GEN_TASK_ID(); taskdata->td_team = team; taskdata->td_alloc_thread = thread; taskdata->td_parent = parent_task; taskdata->td_level = parent_task->td_level + 1; // increment nesting level KMP_ATOMIC_ST_RLX(&taskdata->td_untied_count, 0); taskdata->td_ident = loc_ref; taskdata->td_taskwait_ident = NULL; taskdata->td_taskwait_counter = 0; taskdata->td_taskwait_thread = 0; KMP_DEBUG_ASSERT(taskdata->td_parent != NULL); // avoid copying icvs for proxy tasks if (flags->proxy == TASK_FULL) copy_icvs(&taskdata->td_icvs, &taskdata->td_parent->td_icvs); taskdata->td_flags.tiedness = flags->tiedness; taskdata->td_flags.final = flags->final; taskdata->td_flags.merged_if0 = flags->merged_if0; taskdata->td_flags.destructors_thunk = flags->destructors_thunk; taskdata->td_flags.proxy = flags->proxy; taskdata->td_flags.detachable = flags->detachable; taskdata->td_task_team = thread->th.th_task_team; taskdata->td_size_alloc = shareds_offset + sizeof_shareds; taskdata->td_flags.tasktype = TASK_EXPLICIT; // GEH - TODO: fix this to copy parent task's value of tasking_ser flag taskdata->td_flags.tasking_ser = (__kmp_tasking_mode == tskm_immediate_exec); // GEH - TODO: fix this to copy parent task's value of team_serial flag taskdata->td_flags.team_serial = (team->t.t_serialized) ? 1 : 0; // GEH - Note we serialize the task if the team is serialized to make sure // implicit parallel region tasks are not left until program termination to // execute. Also, it helps locality to execute immediately. taskdata->td_flags.task_serial = (parent_task->td_flags.final || taskdata->td_flags.team_serial || taskdata->td_flags.tasking_ser || flags->merged_if0); taskdata->td_flags.started = 0; taskdata->td_flags.executing = 0; taskdata->td_flags.complete = 0; taskdata->td_flags.freed = 0; taskdata->td_flags.native = flags->native; KMP_ATOMIC_ST_RLX(&taskdata->td_incomplete_child_tasks, 0); // start at one because counts current task and children KMP_ATOMIC_ST_RLX(&taskdata->td_allocated_child_tasks, 1); taskdata->td_taskgroup = parent_task->td_taskgroup; // task inherits taskgroup from the parent task taskdata->td_dephash = NULL; taskdata->td_depnode = NULL; if (flags->tiedness == TASK_UNTIED) taskdata->td_last_tied = NULL; // will be set when the task is scheduled else taskdata->td_last_tied = taskdata; taskdata->td_allow_completion_event.type = KMP_EVENT_UNINITIALIZED; #if OMPT_SUPPORT if (UNLIKELY(ompt_enabled.enabled)) __ompt_task_init(taskdata, gtid); #endif // Only need to keep track of child task counts if team parallel and tasking not // serialized or if it is a proxy or detachable task if (flags->proxy == TASK_PROXY || flags->detachable == TASK_DETACHABLE || !(taskdata->td_flags.team_serial || taskdata->td_flags.tasking_ser)) { KMP_ATOMIC_INC(&parent_task->td_incomplete_child_tasks); if (parent_task->td_taskgroup) KMP_ATOMIC_INC(&parent_task->td_taskgroup->count); // Only need to keep track of allocated child tasks for explicit tasks since // implicit not deallocated if (taskdata->td_parent->td_flags.tasktype == TASK_EXPLICIT) { KMP_ATOMIC_INC(&taskdata->td_parent->td_allocated_child_tasks); } } KA_TRACE(20, ("__kmp_task_alloc(exit): T#%d created task %p parent=%p\n", gtid, taskdata, taskdata->td_parent)); ANNOTATE_HAPPENS_BEFORE(task); return task; } kmp_task_t *__kmpc_omp_task_alloc(ident_t *loc_ref, kmp_int32 gtid, kmp_int32 flags, size_t sizeof_kmp_task_t, size_t sizeof_shareds, kmp_routine_entry_t task_entry) { kmp_task_t *retval; kmp_tasking_flags_t *input_flags = (kmp_tasking_flags_t *)&flags; input_flags->native = FALSE; // __kmp_task_alloc() sets up all other runtime flags KA_TRACE(10, ("__kmpc_omp_task_alloc(enter): T#%d loc=%p, flags=(%s %s %s) " "sizeof_task=%ld sizeof_shared=%ld entry=%p\n", gtid, loc_ref, input_flags->tiedness ? "tied " : "untied", input_flags->proxy ? "proxy" : "", input_flags->detachable ? "detachable" : "", sizeof_kmp_task_t, sizeof_shareds, task_entry)); retval = __kmp_task_alloc(loc_ref, gtid, input_flags, sizeof_kmp_task_t, sizeof_shareds, task_entry); KA_TRACE(20, ("__kmpc_omp_task_alloc(exit): T#%d retval %p\n", gtid, retval)); return retval; } kmp_task_t *__kmpc_omp_target_task_alloc(ident_t *loc_ref, kmp_int32 gtid, kmp_int32 flags, size_t sizeof_kmp_task_t, size_t sizeof_shareds, kmp_routine_entry_t task_entry, kmp_int64 device_id) { return __kmpc_omp_task_alloc(loc_ref, gtid, flags, sizeof_kmp_task_t, sizeof_shareds, task_entry); } /*! @ingroup TASKING @param loc_ref location of the original task directive @param gtid Global Thread ID of encountering thread @param new_task task thunk allocated by __kmpc_omp_task_alloc() for the ''new task'' @param naffins Number of affinity items @param affin_list List of affinity items @return Returns non-zero if registering affinity information was not successful. Returns 0 if registration was successful This entry registers the affinity information attached to a task with the task thunk structure kmp_taskdata_t. */ kmp_int32 __kmpc_omp_reg_task_with_affinity(ident_t *loc_ref, kmp_int32 gtid, kmp_task_t *new_task, kmp_int32 naffins, kmp_task_affinity_info_t *affin_list) { return 0; } // __kmp_invoke_task: invoke the specified task // // gtid: global thread ID of caller // task: the task to invoke // current_task: the task to resume after task invocation static void __kmp_invoke_task(kmp_int32 gtid, kmp_task_t *task, kmp_taskdata_t *current_task) { kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(task); kmp_info_t *thread; int discard = 0 /* false */; KA_TRACE( 30, ("__kmp_invoke_task(enter): T#%d invoking task %p, current_task=%p\n", gtid, taskdata, current_task)); KMP_DEBUG_ASSERT(task); if (taskdata->td_flags.proxy == TASK_PROXY && taskdata->td_flags.complete == 1) { // This is a proxy task that was already completed but it needs to run // its bottom-half finish KA_TRACE( 30, ("__kmp_invoke_task: T#%d running bottom finish for proxy task %p\n", gtid, taskdata)); __kmp_bottom_half_finish_proxy(gtid, task); KA_TRACE(30, ("__kmp_invoke_task(exit): T#%d completed bottom finish for " "proxy task %p, resuming task %p\n", gtid, taskdata, current_task)); return; } #if OMPT_SUPPORT // For untied tasks, the first task executed only calls __kmpc_omp_task and // does not execute code. ompt_thread_info_t oldInfo; if (UNLIKELY(ompt_enabled.enabled)) { // Store the threads states and restore them after the task thread = __kmp_threads[gtid]; oldInfo = thread->th.ompt_thread_info; thread->th.ompt_thread_info.wait_id = 0; thread->th.ompt_thread_info.state = (thread->th.th_team_serialized) ? ompt_state_work_serial : ompt_state_work_parallel; taskdata->ompt_task_info.frame.exit_frame.ptr = OMPT_GET_FRAME_ADDRESS(0); } #endif // Proxy tasks are not handled by the runtime if (taskdata->td_flags.proxy != TASK_PROXY) { ANNOTATE_HAPPENS_AFTER(task); __kmp_task_start(gtid, task, current_task); // OMPT only if not discarded } // TODO: cancel tasks if the parallel region has also been cancelled // TODO: check if this sequence can be hoisted above __kmp_task_start // if cancellation has been enabled for this run ... if (__kmp_omp_cancellation) { thread = __kmp_threads[gtid]; kmp_team_t *this_team = thread->th.th_team; kmp_taskgroup_t *taskgroup = taskdata->td_taskgroup; if ((taskgroup && taskgroup->cancel_request) || (this_team->t.t_cancel_request == cancel_parallel)) { #if OMPT_SUPPORT && OMPT_OPTIONAL ompt_data_t *task_data; if (UNLIKELY(ompt_enabled.ompt_callback_cancel)) { __ompt_get_task_info_internal(0, NULL, &task_data, NULL, NULL, NULL); ompt_callbacks.ompt_callback(ompt_callback_cancel)( task_data, ((taskgroup && taskgroup->cancel_request) ? ompt_cancel_taskgroup : ompt_cancel_parallel) | ompt_cancel_discarded_task, NULL); } #endif KMP_COUNT_BLOCK(TASK_cancelled); // this task belongs to a task group and we need to cancel it discard = 1 /* true */; } } // Invoke the task routine and pass in relevant data. // Thunks generated by gcc take a different argument list. if (!discard) { if (taskdata->td_flags.tiedness == TASK_UNTIED) { taskdata->td_last_tied = current_task->td_last_tied; KMP_DEBUG_ASSERT(taskdata->td_last_tied); } #if KMP_STATS_ENABLED KMP_COUNT_BLOCK(TASK_executed); switch (KMP_GET_THREAD_STATE()) { case FORK_JOIN_BARRIER: KMP_PUSH_PARTITIONED_TIMER(OMP_task_join_bar); break; case PLAIN_BARRIER: KMP_PUSH_PARTITIONED_TIMER(OMP_task_plain_bar); break; case TASKYIELD: KMP_PUSH_PARTITIONED_TIMER(OMP_task_taskyield); break; case TASKWAIT: KMP_PUSH_PARTITIONED_TIMER(OMP_task_taskwait); break; case TASKGROUP: KMP_PUSH_PARTITIONED_TIMER(OMP_task_taskgroup); break; default: KMP_PUSH_PARTITIONED_TIMER(OMP_task_immediate); break; } #endif // KMP_STATS_ENABLED // OMPT task begin #if OMPT_SUPPORT if (UNLIKELY(ompt_enabled.enabled)) __ompt_task_start(task, current_task, gtid); #endif #if USE_ITT_BUILD && USE_ITT_NOTIFY kmp_uint64 cur_time; kmp_int32 kmp_itt_count_task = __kmp_forkjoin_frames_mode == 3 && !taskdata->td_flags.task_serial && current_task->td_flags.tasktype == TASK_IMPLICIT; if (kmp_itt_count_task) { thread = __kmp_threads[gtid]; // Time outer level explicit task on barrier for adjusting imbalance time if (thread->th.th_bar_arrive_time) cur_time = __itt_get_timestamp(); else kmp_itt_count_task = 0; // thread is not on a barrier - skip timing } #endif #ifdef KMP_GOMP_COMPAT if (taskdata->td_flags.native) { ((void (*)(void *))(*(task->routine)))(task->shareds); } else #endif /* KMP_GOMP_COMPAT */ { (*(task->routine))(gtid, task); } KMP_POP_PARTITIONED_TIMER(); #if USE_ITT_BUILD && USE_ITT_NOTIFY if (kmp_itt_count_task) { // Barrier imbalance - adjust arrive time with the task duration thread->th.th_bar_arrive_time += (__itt_get_timestamp() - cur_time); } #endif } // Proxy tasks are not handled by the runtime if (taskdata->td_flags.proxy != TASK_PROXY) { ANNOTATE_HAPPENS_BEFORE(taskdata->td_parent); #if OMPT_SUPPORT if (UNLIKELY(ompt_enabled.enabled)) { thread->th.ompt_thread_info = oldInfo; if (taskdata->td_flags.tiedness == TASK_TIED) { taskdata->ompt_task_info.frame.exit_frame = ompt_data_none; } __kmp_task_finish(gtid, task, current_task); } else #endif __kmp_task_finish(gtid, task, current_task); } KA_TRACE( 30, ("__kmp_invoke_task(exit): T#%d completed task %p, resuming task %p\n", gtid, taskdata, current_task)); return; } // __kmpc_omp_task_parts: Schedule a thread-switchable task for execution // // loc_ref: location of original task pragma (ignored) // gtid: Global Thread ID of encountering thread // new_task: task thunk allocated by __kmp_omp_task_alloc() for the ''new task'' // Returns: // TASK_CURRENT_NOT_QUEUED (0) if did not suspend and queue current task to // be resumed later. // TASK_CURRENT_QUEUED (1) if suspended and queued the current task to be // resumed later. kmp_int32 __kmpc_omp_task_parts(ident_t *loc_ref, kmp_int32 gtid, kmp_task_t *new_task) { kmp_taskdata_t *new_taskdata = KMP_TASK_TO_TASKDATA(new_task); KA_TRACE(10, ("__kmpc_omp_task_parts(enter): T#%d loc=%p task=%p\n", gtid, loc_ref, new_taskdata)); #if OMPT_SUPPORT kmp_taskdata_t *parent; if (UNLIKELY(ompt_enabled.enabled)) { parent = new_taskdata->td_parent; if (ompt_enabled.ompt_callback_task_create) { ompt_data_t task_data = ompt_data_none; ompt_callbacks.ompt_callback(ompt_callback_task_create)( parent ? &(parent->ompt_task_info.task_data) : &task_data, parent ? &(parent->ompt_task_info.frame) : NULL, &(new_taskdata->ompt_task_info.task_data), ompt_task_explicit, 0, OMPT_GET_RETURN_ADDRESS(0)); } } #endif /* Should we execute the new task or queue it? For now, let's just always try to queue it. If the queue fills up, then we'll execute it. */ if (__kmp_push_task(gtid, new_task) == TASK_NOT_PUSHED) // if cannot defer { // Execute this task immediately kmp_taskdata_t *current_task = __kmp_threads[gtid]->th.th_current_task; new_taskdata->td_flags.task_serial = 1; __kmp_invoke_task(gtid, new_task, current_task); } KA_TRACE( 10, ("__kmpc_omp_task_parts(exit): T#%d returning TASK_CURRENT_NOT_QUEUED: " "loc=%p task=%p, return: TASK_CURRENT_NOT_QUEUED\n", gtid, loc_ref, new_taskdata)); ANNOTATE_HAPPENS_BEFORE(new_task); #if OMPT_SUPPORT if (UNLIKELY(ompt_enabled.enabled)) { parent->ompt_task_info.frame.enter_frame = ompt_data_none; } #endif return TASK_CURRENT_NOT_QUEUED; } // __kmp_omp_task: Schedule a non-thread-switchable task for execution // // gtid: Global Thread ID of encountering thread // new_task:non-thread-switchable task thunk allocated by __kmp_omp_task_alloc() // serialize_immediate: if TRUE then if the task is executed immediately its // execution will be serialized // Returns: // TASK_CURRENT_NOT_QUEUED (0) if did not suspend and queue current task to // be resumed later. // TASK_CURRENT_QUEUED (1) if suspended and queued the current task to be // resumed later. kmp_int32 __kmp_omp_task(kmp_int32 gtid, kmp_task_t *new_task, bool serialize_immediate) { kmp_taskdata_t *new_taskdata = KMP_TASK_TO_TASKDATA(new_task); /* Should we execute the new task or queue it? For now, let's just always try to queue it. If the queue fills up, then we'll execute it. */ if (new_taskdata->td_flags.proxy == TASK_PROXY || __kmp_push_task(gtid, new_task) == TASK_NOT_PUSHED) // if cannot defer { // Execute this task immediately kmp_taskdata_t *current_task = __kmp_threads[gtid]->th.th_current_task; if (serialize_immediate) new_taskdata->td_flags.task_serial = 1; __kmp_invoke_task(gtid, new_task, current_task); } ANNOTATE_HAPPENS_BEFORE(new_task); return TASK_CURRENT_NOT_QUEUED; } // __kmpc_omp_task: Wrapper around __kmp_omp_task to schedule a // non-thread-switchable task from the parent thread only! // // loc_ref: location of original task pragma (ignored) // gtid: Global Thread ID of encountering thread // new_task: non-thread-switchable task thunk allocated by // __kmp_omp_task_alloc() // Returns: // TASK_CURRENT_NOT_QUEUED (0) if did not suspend and queue current task to // be resumed later. // TASK_CURRENT_QUEUED (1) if suspended and queued the current task to be // resumed later. kmp_int32 __kmpc_omp_task(ident_t *loc_ref, kmp_int32 gtid, kmp_task_t *new_task) { kmp_int32 res; KMP_SET_THREAD_STATE_BLOCK(EXPLICIT_TASK); #if KMP_DEBUG || OMPT_SUPPORT kmp_taskdata_t *new_taskdata = KMP_TASK_TO_TASKDATA(new_task); #endif KA_TRACE(10, ("__kmpc_omp_task(enter): T#%d loc=%p task=%p\n", gtid, loc_ref, new_taskdata)); #if OMPT_SUPPORT kmp_taskdata_t *parent = NULL; if (UNLIKELY(ompt_enabled.enabled)) { if (!new_taskdata->td_flags.started) { OMPT_STORE_RETURN_ADDRESS(gtid); parent = new_taskdata->td_parent; if (!parent->ompt_task_info.frame.enter_frame.ptr) { parent->ompt_task_info.frame.enter_frame.ptr = OMPT_GET_FRAME_ADDRESS(0); } if (ompt_enabled.ompt_callback_task_create) { ompt_data_t task_data = ompt_data_none; ompt_callbacks.ompt_callback(ompt_callback_task_create)( parent ? &(parent->ompt_task_info.task_data) : &task_data, parent ? &(parent->ompt_task_info.frame) : NULL, &(new_taskdata->ompt_task_info.task_data), ompt_task_explicit | TASK_TYPE_DETAILS_FORMAT(new_taskdata), 0, OMPT_LOAD_RETURN_ADDRESS(gtid)); } } else { // We are scheduling the continuation of an UNTIED task. // Scheduling back to the parent task. __ompt_task_finish(new_task, new_taskdata->ompt_task_info.scheduling_parent, ompt_task_switch); new_taskdata->ompt_task_info.frame.exit_frame = ompt_data_none; } } #endif res = __kmp_omp_task(gtid, new_task, true); KA_TRACE(10, ("__kmpc_omp_task(exit): T#%d returning " "TASK_CURRENT_NOT_QUEUED: loc=%p task=%p\n", gtid, loc_ref, new_taskdata)); #if OMPT_SUPPORT if (UNLIKELY(ompt_enabled.enabled && parent != NULL)) { parent->ompt_task_info.frame.enter_frame = ompt_data_none; } #endif return res; } // __kmp_omp_taskloop_task: Wrapper around __kmp_omp_task to schedule // a taskloop task with the correct OMPT return address // // loc_ref: location of original task pragma (ignored) // gtid: Global Thread ID of encountering thread // new_task: non-thread-switchable task thunk allocated by // __kmp_omp_task_alloc() // codeptr_ra: return address for OMPT callback // Returns: // TASK_CURRENT_NOT_QUEUED (0) if did not suspend and queue current task to // be resumed later. // TASK_CURRENT_QUEUED (1) if suspended and queued the current task to be // resumed later. kmp_int32 __kmp_omp_taskloop_task(ident_t *loc_ref, kmp_int32 gtid, kmp_task_t *new_task, void *codeptr_ra) { kmp_int32 res; KMP_SET_THREAD_STATE_BLOCK(EXPLICIT_TASK); #if KMP_DEBUG || OMPT_SUPPORT kmp_taskdata_t *new_taskdata = KMP_TASK_TO_TASKDATA(new_task); #endif KA_TRACE(10, ("__kmpc_omp_task(enter): T#%d loc=%p task=%p\n", gtid, loc_ref, new_taskdata)); #if OMPT_SUPPORT kmp_taskdata_t *parent = NULL; if (UNLIKELY(ompt_enabled.enabled && !new_taskdata->td_flags.started)) { parent = new_taskdata->td_parent; if (!parent->ompt_task_info.frame.enter_frame.ptr) parent->ompt_task_info.frame.enter_frame.ptr = OMPT_GET_FRAME_ADDRESS(0); if (ompt_enabled.ompt_callback_task_create) { ompt_data_t task_data = ompt_data_none; ompt_callbacks.ompt_callback(ompt_callback_task_create)( parent ? &(parent->ompt_task_info.task_data) : &task_data, parent ? &(parent->ompt_task_info.frame) : NULL, &(new_taskdata->ompt_task_info.task_data), ompt_task_explicit | TASK_TYPE_DETAILS_FORMAT(new_taskdata), 0, codeptr_ra); } } #endif res = __kmp_omp_task(gtid, new_task, true); KA_TRACE(10, ("__kmpc_omp_task(exit): T#%d returning " "TASK_CURRENT_NOT_QUEUED: loc=%p task=%p\n", gtid, loc_ref, new_taskdata)); #if OMPT_SUPPORT if (UNLIKELY(ompt_enabled.enabled && parent != NULL)) { parent->ompt_task_info.frame.enter_frame = ompt_data_none; } #endif return res; } template static kmp_int32 __kmpc_omp_taskwait_template(ident_t *loc_ref, kmp_int32 gtid, void *frame_address, void *return_address) { kmp_taskdata_t *taskdata; kmp_info_t *thread; int thread_finished = FALSE; KMP_SET_THREAD_STATE_BLOCK(TASKWAIT); KA_TRACE(10, ("__kmpc_omp_taskwait(enter): T#%d loc=%p\n", gtid, loc_ref)); if (__kmp_tasking_mode != tskm_immediate_exec) { thread = __kmp_threads[gtid]; taskdata = thread->th.th_current_task; #if OMPT_SUPPORT && OMPT_OPTIONAL ompt_data_t *my_task_data; ompt_data_t *my_parallel_data; if (ompt) { my_task_data = &(taskdata->ompt_task_info.task_data); my_parallel_data = OMPT_CUR_TEAM_DATA(thread); taskdata->ompt_task_info.frame.enter_frame.ptr = frame_address; if (ompt_enabled.ompt_callback_sync_region) { ompt_callbacks.ompt_callback(ompt_callback_sync_region)( ompt_sync_region_taskwait, ompt_scope_begin, my_parallel_data, my_task_data, return_address); } if (ompt_enabled.ompt_callback_sync_region_wait) { ompt_callbacks.ompt_callback(ompt_callback_sync_region_wait)( ompt_sync_region_taskwait, ompt_scope_begin, my_parallel_data, my_task_data, return_address); } } #endif // OMPT_SUPPORT && OMPT_OPTIONAL // Debugger: The taskwait is active. Store location and thread encountered the // taskwait. #if USE_ITT_BUILD // Note: These values are used by ITT events as well. #endif /* USE_ITT_BUILD */ taskdata->td_taskwait_counter += 1; taskdata->td_taskwait_ident = loc_ref; taskdata->td_taskwait_thread = gtid + 1; #if USE_ITT_BUILD void *itt_sync_obj = __kmp_itt_taskwait_object(gtid); if (itt_sync_obj != NULL) __kmp_itt_taskwait_starting(gtid, itt_sync_obj); #endif /* USE_ITT_BUILD */ bool must_wait = !taskdata->td_flags.team_serial && !taskdata->td_flags.final; must_wait = must_wait || (thread->th.th_task_team != NULL && thread->th.th_task_team->tt.tt_found_proxy_tasks); if (must_wait) { kmp_flag_32 flag(RCAST(std::atomic *, &(taskdata->td_incomplete_child_tasks)), 0U); while (KMP_ATOMIC_LD_ACQ(&taskdata->td_incomplete_child_tasks) != 0) { flag.execute_tasks(thread, gtid, FALSE, &thread_finished USE_ITT_BUILD_ARG(itt_sync_obj), __kmp_task_stealing_constraint); } } #if USE_ITT_BUILD if (itt_sync_obj != NULL) __kmp_itt_taskwait_finished(gtid, itt_sync_obj); #endif /* USE_ITT_BUILD */ // Debugger: The taskwait is completed. Location remains, but thread is // negated. taskdata->td_taskwait_thread = -taskdata->td_taskwait_thread; #if OMPT_SUPPORT && OMPT_OPTIONAL if (ompt) { if (ompt_enabled.ompt_callback_sync_region_wait) { ompt_callbacks.ompt_callback(ompt_callback_sync_region_wait)( ompt_sync_region_taskwait, ompt_scope_end, my_parallel_data, my_task_data, return_address); } if (ompt_enabled.ompt_callback_sync_region) { ompt_callbacks.ompt_callback(ompt_callback_sync_region)( ompt_sync_region_taskwait, ompt_scope_end, my_parallel_data, my_task_data, return_address); } taskdata->ompt_task_info.frame.enter_frame = ompt_data_none; } #endif // OMPT_SUPPORT && OMPT_OPTIONAL ANNOTATE_HAPPENS_AFTER(taskdata); } KA_TRACE(10, ("__kmpc_omp_taskwait(exit): T#%d task %p finished waiting, " "returning TASK_CURRENT_NOT_QUEUED\n", gtid, taskdata)); return TASK_CURRENT_NOT_QUEUED; } #if OMPT_SUPPORT && OMPT_OPTIONAL OMPT_NOINLINE static kmp_int32 __kmpc_omp_taskwait_ompt(ident_t *loc_ref, kmp_int32 gtid, void *frame_address, void *return_address) { return __kmpc_omp_taskwait_template(loc_ref, gtid, frame_address, return_address); } #endif // OMPT_SUPPORT && OMPT_OPTIONAL // __kmpc_omp_taskwait: Wait until all tasks generated by the current task are // complete kmp_int32 __kmpc_omp_taskwait(ident_t *loc_ref, kmp_int32 gtid) { #if OMPT_SUPPORT && OMPT_OPTIONAL if (UNLIKELY(ompt_enabled.enabled)) { OMPT_STORE_RETURN_ADDRESS(gtid); return __kmpc_omp_taskwait_ompt(loc_ref, gtid, OMPT_GET_FRAME_ADDRESS(0), OMPT_LOAD_RETURN_ADDRESS(gtid)); } #endif return __kmpc_omp_taskwait_template(loc_ref, gtid, NULL, NULL); } // __kmpc_omp_taskyield: switch to a different task kmp_int32 __kmpc_omp_taskyield(ident_t *loc_ref, kmp_int32 gtid, int end_part) { kmp_taskdata_t *taskdata; kmp_info_t *thread; int thread_finished = FALSE; KMP_COUNT_BLOCK(OMP_TASKYIELD); KMP_SET_THREAD_STATE_BLOCK(TASKYIELD); KA_TRACE(10, ("__kmpc_omp_taskyield(enter): T#%d loc=%p end_part = %d\n", gtid, loc_ref, end_part)); if (__kmp_tasking_mode != tskm_immediate_exec && __kmp_init_parallel) { thread = __kmp_threads[gtid]; taskdata = thread->th.th_current_task; // Should we model this as a task wait or not? // Debugger: The taskwait is active. Store location and thread encountered the // taskwait. #if USE_ITT_BUILD // Note: These values are used by ITT events as well. #endif /* USE_ITT_BUILD */ taskdata->td_taskwait_counter += 1; taskdata->td_taskwait_ident = loc_ref; taskdata->td_taskwait_thread = gtid + 1; #if USE_ITT_BUILD void *itt_sync_obj = __kmp_itt_taskwait_object(gtid); if (itt_sync_obj != NULL) __kmp_itt_taskwait_starting(gtid, itt_sync_obj); #endif /* USE_ITT_BUILD */ if (!taskdata->td_flags.team_serial) { kmp_task_team_t *task_team = thread->th.th_task_team; if (task_team != NULL) { if (KMP_TASKING_ENABLED(task_team)) { #if OMPT_SUPPORT if (UNLIKELY(ompt_enabled.enabled)) thread->th.ompt_thread_info.ompt_task_yielded = 1; #endif __kmp_execute_tasks_32( thread, gtid, NULL, FALSE, &thread_finished USE_ITT_BUILD_ARG(itt_sync_obj), __kmp_task_stealing_constraint); #if OMPT_SUPPORT if (UNLIKELY(ompt_enabled.enabled)) thread->th.ompt_thread_info.ompt_task_yielded = 0; #endif } } } #if USE_ITT_BUILD if (itt_sync_obj != NULL) __kmp_itt_taskwait_finished(gtid, itt_sync_obj); #endif /* USE_ITT_BUILD */ // Debugger: The taskwait is completed. Location remains, but thread is // negated. taskdata->td_taskwait_thread = -taskdata->td_taskwait_thread; } KA_TRACE(10, ("__kmpc_omp_taskyield(exit): T#%d task %p resuming, " "returning TASK_CURRENT_NOT_QUEUED\n", gtid, taskdata)); return TASK_CURRENT_NOT_QUEUED; } // Task Reduction implementation // // Note: initial implementation didn't take into account the possibility // to specify omp_orig for initializer of the UDR (user defined reduction). // Corrected implementation takes into account the omp_orig object. // Compiler is free to use old implementation if omp_orig is not specified. /*! @ingroup BASIC_TYPES @{ */ /*! Flags for special info per task reduction item. */ typedef struct kmp_taskred_flags { /*! 1 - use lazy alloc/init (e.g. big objects, #tasks < #threads) */ unsigned lazy_priv : 1; unsigned reserved31 : 31; } kmp_taskred_flags_t; /*! Internal struct for reduction data item related info set up by compiler. */ typedef struct kmp_task_red_input { void *reduce_shar; /**< shared between tasks item to reduce into */ size_t reduce_size; /**< size of data item in bytes */ // three compiler-generated routines (init, fini are optional): void *reduce_init; /**< data initialization routine (single parameter) */ void *reduce_fini; /**< data finalization routine */ void *reduce_comb; /**< data combiner routine */ kmp_taskred_flags_t flags; /**< flags for additional info from compiler */ } kmp_task_red_input_t; /*! Internal struct for reduction data item related info saved by the library. */ typedef struct kmp_taskred_data { void *reduce_shar; /**< shared between tasks item to reduce into */ size_t reduce_size; /**< size of data item */ kmp_taskred_flags_t flags; /**< flags for additional info from compiler */ void *reduce_priv; /**< array of thread specific items */ void *reduce_pend; /**< end of private data for faster comparison op */ // three compiler-generated routines (init, fini are optional): void *reduce_comb; /**< data combiner routine */ void *reduce_init; /**< data initialization routine (two parameters) */ void *reduce_fini; /**< data finalization routine */ void *reduce_orig; /**< original item (can be used in UDR initializer) */ } kmp_taskred_data_t; /*! Internal struct for reduction data item related info set up by compiler. New interface: added reduce_orig field to provide omp_orig for UDR initializer. */ typedef struct kmp_taskred_input { void *reduce_shar; /**< shared between tasks item to reduce into */ void *reduce_orig; /**< original reduction item used for initialization */ size_t reduce_size; /**< size of data item */ // three compiler-generated routines (init, fini are optional): void *reduce_init; /**< data initialization routine (two parameters) */ void *reduce_fini; /**< data finalization routine */ void *reduce_comb; /**< data combiner routine */ kmp_taskred_flags_t flags; /**< flags for additional info from compiler */ } kmp_taskred_input_t; /*! @} */ template void __kmp_assign_orig(kmp_taskred_data_t &item, T &src); template <> void __kmp_assign_orig(kmp_taskred_data_t &item, kmp_task_red_input_t &src) { item.reduce_orig = NULL; } template <> void __kmp_assign_orig(kmp_taskred_data_t &item, kmp_taskred_input_t &src) { if (src.reduce_orig != NULL) { item.reduce_orig = src.reduce_orig; } else { item.reduce_orig = src.reduce_shar; } // non-NULL reduce_orig means new interface used } template void __kmp_call_init(kmp_taskred_data_t &item, int j); template <> void __kmp_call_init(kmp_taskred_data_t &item, int offset) { ((void (*)(void *))item.reduce_init)((char *)(item.reduce_priv) + offset); } template <> void __kmp_call_init(kmp_taskred_data_t &item, int offset) { ((void (*)(void *, void *))item.reduce_init)( (char *)(item.reduce_priv) + offset, item.reduce_orig); } template void *__kmp_task_reduction_init(int gtid, int num, T *data) { kmp_info_t *thread = __kmp_threads[gtid]; kmp_taskgroup_t *tg = thread->th.th_current_task->td_taskgroup; kmp_int32 nth = thread->th.th_team_nproc; kmp_taskred_data_t *arr; // check input data just in case KMP_ASSERT(tg != NULL); KMP_ASSERT(data != NULL); KMP_ASSERT(num > 0); if (nth == 1) { KA_TRACE(10, ("__kmpc_task_reduction_init: T#%d, tg %p, exiting nth=1\n", gtid, tg)); return (void *)tg; } KA_TRACE(10, ("__kmpc_task_reduction_init: T#%d, taskgroup %p, #items %d\n", gtid, tg, num)); arr = (kmp_taskred_data_t *)__kmp_thread_malloc( thread, num * sizeof(kmp_taskred_data_t)); for (int i = 0; i < num; ++i) { size_t size = data[i].reduce_size - 1; // round the size up to cache line per thread-specific item size += CACHE_LINE - size % CACHE_LINE; KMP_ASSERT(data[i].reduce_comb != NULL); // combiner is mandatory arr[i].reduce_shar = data[i].reduce_shar; arr[i].reduce_size = size; arr[i].flags = data[i].flags; arr[i].reduce_comb = data[i].reduce_comb; arr[i].reduce_init = data[i].reduce_init; arr[i].reduce_fini = data[i].reduce_fini; __kmp_assign_orig(arr[i], data[i]); if (!arr[i].flags.lazy_priv) { // allocate cache-line aligned block and fill it with zeros arr[i].reduce_priv = __kmp_allocate(nth * size); arr[i].reduce_pend = (char *)(arr[i].reduce_priv) + nth * size; if (arr[i].reduce_init != NULL) { // initialize all thread-specific items for (int j = 0; j < nth; ++j) { __kmp_call_init(arr[i], j * size); } } } else { // only allocate space for pointers now, // objects will be lazily allocated/initialized if/when requested // note that __kmp_allocate zeroes the allocated memory arr[i].reduce_priv = __kmp_allocate(nth * sizeof(void *)); } } tg->reduce_data = (void *)arr; tg->reduce_num_data = num; return (void *)tg; } /*! @ingroup TASKING @param gtid Global thread ID @param num Number of data items to reduce @param data Array of data for reduction @return The taskgroup identifier Initialize task reduction for the taskgroup. Note: this entry supposes the optional compiler-generated initializer routine has single parameter - pointer to object to be initialized. That means the reduction either does not use omp_orig object, or the omp_orig is accessible without help of the runtime library. */ void *__kmpc_task_reduction_init(int gtid, int num, void *data) { return __kmp_task_reduction_init(gtid, num, (kmp_task_red_input_t *)data); } /*! @ingroup TASKING @param gtid Global thread ID @param num Number of data items to reduce @param data Array of data for reduction @return The taskgroup identifier Initialize task reduction for the taskgroup. Note: this entry supposes the optional compiler-generated initializer routine has two parameters, pointer to object to be initialized and pointer to omp_orig */ void *__kmpc_taskred_init(int gtid, int num, void *data) { return __kmp_task_reduction_init(gtid, num, (kmp_taskred_input_t *)data); } // Copy task reduction data (except for shared pointers). template void __kmp_task_reduction_init_copy(kmp_info_t *thr, int num, T *data, kmp_taskgroup_t *tg, void *reduce_data) { kmp_taskred_data_t *arr; KA_TRACE(20, ("__kmp_task_reduction_init_copy: Th %p, init taskgroup %p," " from data %p\n", thr, tg, reduce_data)); arr = (kmp_taskred_data_t *)__kmp_thread_malloc( thr, num * sizeof(kmp_taskred_data_t)); // threads will share private copies, thunk routines, sizes, flags, etc.: KMP_MEMCPY(arr, reduce_data, num * sizeof(kmp_taskred_data_t)); for (int i = 0; i < num; ++i) { arr[i].reduce_shar = data[i].reduce_shar; // init unique shared pointers } tg->reduce_data = (void *)arr; tg->reduce_num_data = num; } /*! @ingroup TASKING @param gtid Global thread ID @param tskgrp The taskgroup ID (optional) @param data Shared location of the item @return The pointer to per-thread data Get thread-specific location of data item */ void *__kmpc_task_reduction_get_th_data(int gtid, void *tskgrp, void *data) { kmp_info_t *thread = __kmp_threads[gtid]; kmp_int32 nth = thread->th.th_team_nproc; if (nth == 1) return data; // nothing to do kmp_taskgroup_t *tg = (kmp_taskgroup_t *)tskgrp; if (tg == NULL) tg = thread->th.th_current_task->td_taskgroup; KMP_ASSERT(tg != NULL); kmp_taskred_data_t *arr = (kmp_taskred_data_t *)(tg->reduce_data); kmp_int32 num = tg->reduce_num_data; kmp_int32 tid = thread->th.th_info.ds.ds_tid; KMP_ASSERT(data != NULL); while (tg != NULL) { for (int i = 0; i < num; ++i) { if (!arr[i].flags.lazy_priv) { if (data == arr[i].reduce_shar || (data >= arr[i].reduce_priv && data < arr[i].reduce_pend)) return (char *)(arr[i].reduce_priv) + tid * arr[i].reduce_size; } else { // check shared location first void **p_priv = (void **)(arr[i].reduce_priv); if (data == arr[i].reduce_shar) goto found; // check if we get some thread specific location as parameter for (int j = 0; j < nth; ++j) if (data == p_priv[j]) goto found; continue; // not found, continue search found: if (p_priv[tid] == NULL) { // allocate thread specific object lazily p_priv[tid] = __kmp_allocate(arr[i].reduce_size); if (arr[i].reduce_init != NULL) { if (arr[i].reduce_orig != NULL) { // new interface ((void (*)(void *, void *))arr[i].reduce_init)( p_priv[tid], arr[i].reduce_orig); } else { // old interface (single parameter) ((void (*)(void *))arr[i].reduce_init)(p_priv[tid]); } } } return p_priv[tid]; } } tg = tg->parent; arr = (kmp_taskred_data_t *)(tg->reduce_data); num = tg->reduce_num_data; } KMP_ASSERT2(0, "Unknown task reduction item"); return NULL; // ERROR, this line never executed } // Finalize task reduction. // Called from __kmpc_end_taskgroup() static void __kmp_task_reduction_fini(kmp_info_t *th, kmp_taskgroup_t *tg) { kmp_int32 nth = th->th.th_team_nproc; KMP_DEBUG_ASSERT(nth > 1); // should not be called if nth == 1 kmp_taskred_data_t *arr = (kmp_taskred_data_t *)tg->reduce_data; kmp_int32 num = tg->reduce_num_data; for (int i = 0; i < num; ++i) { void *sh_data = arr[i].reduce_shar; void (*f_fini)(void *) = (void (*)(void *))(arr[i].reduce_fini); void (*f_comb)(void *, void *) = (void (*)(void *, void *))(arr[i].reduce_comb); if (!arr[i].flags.lazy_priv) { void *pr_data = arr[i].reduce_priv; size_t size = arr[i].reduce_size; for (int j = 0; j < nth; ++j) { void *priv_data = (char *)pr_data + j * size; f_comb(sh_data, priv_data); // combine results if (f_fini) f_fini(priv_data); // finalize if needed } } else { void **pr_data = (void **)(arr[i].reduce_priv); for (int j = 0; j < nth; ++j) { if (pr_data[j] != NULL) { f_comb(sh_data, pr_data[j]); // combine results if (f_fini) f_fini(pr_data[j]); // finalize if needed __kmp_free(pr_data[j]); } } } __kmp_free(arr[i].reduce_priv); } __kmp_thread_free(th, arr); tg->reduce_data = NULL; tg->reduce_num_data = 0; } // Cleanup task reduction data for parallel or worksharing, // do not touch task private data other threads still working with. // Called from __kmpc_end_taskgroup() static void __kmp_task_reduction_clean(kmp_info_t *th, kmp_taskgroup_t *tg) { __kmp_thread_free(th, tg->reduce_data); tg->reduce_data = NULL; tg->reduce_num_data = 0; } template void *__kmp_task_reduction_modifier_init(ident_t *loc, int gtid, int is_ws, int num, T *data) { kmp_info_t *thr = __kmp_threads[gtid]; kmp_int32 nth = thr->th.th_team_nproc; __kmpc_taskgroup(loc, gtid); // form new taskgroup first if (nth == 1) { KA_TRACE(10, ("__kmpc_reduction_modifier_init: T#%d, tg %p, exiting nth=1\n", gtid, thr->th.th_current_task->td_taskgroup)); return (void *)thr->th.th_current_task->td_taskgroup; } kmp_team_t *team = thr->th.th_team; void *reduce_data; kmp_taskgroup_t *tg; reduce_data = KMP_ATOMIC_LD_RLX(&team->t.t_tg_reduce_data[is_ws]); if (reduce_data == NULL && __kmp_atomic_compare_store(&team->t.t_tg_reduce_data[is_ws], reduce_data, (void *)1)) { // single thread enters this block to initialize common reduction data KMP_DEBUG_ASSERT(reduce_data == NULL); // first initialize own data, then make a copy other threads can use tg = (kmp_taskgroup_t *)__kmp_task_reduction_init(gtid, num, data); reduce_data = __kmp_thread_malloc(thr, num * sizeof(kmp_taskred_data_t)); KMP_MEMCPY(reduce_data, tg->reduce_data, num * sizeof(kmp_taskred_data_t)); // fini counters should be 0 at this point KMP_DEBUG_ASSERT(KMP_ATOMIC_LD_RLX(&team->t.t_tg_fini_counter[0]) == 0); KMP_DEBUG_ASSERT(KMP_ATOMIC_LD_RLX(&team->t.t_tg_fini_counter[1]) == 0); KMP_ATOMIC_ST_REL(&team->t.t_tg_reduce_data[is_ws], reduce_data); } else { while ( (reduce_data = KMP_ATOMIC_LD_ACQ(&team->t.t_tg_reduce_data[is_ws])) == (void *)1) { // wait for task reduction initialization KMP_CPU_PAUSE(); } KMP_DEBUG_ASSERT(reduce_data > (void *)1); // should be valid pointer here tg = thr->th.th_current_task->td_taskgroup; __kmp_task_reduction_init_copy(thr, num, data, tg, reduce_data); } return tg; } /*! @ingroup TASKING @param loc Source location info @param gtid Global thread ID @param is_ws Is 1 if the reduction is for worksharing, 0 otherwise @param num Number of data items to reduce @param data Array of data for reduction @return The taskgroup identifier Initialize task reduction for a parallel or worksharing. Note: this entry supposes the optional compiler-generated initializer routine has single parameter - pointer to object to be initialized. That means the reduction either does not use omp_orig object, or the omp_orig is accessible without help of the runtime library. */ void *__kmpc_task_reduction_modifier_init(ident_t *loc, int gtid, int is_ws, int num, void *data) { return __kmp_task_reduction_modifier_init(loc, gtid, is_ws, num, (kmp_task_red_input_t *)data); } /*! @ingroup TASKING @param loc Source location info @param gtid Global thread ID @param is_ws Is 1 if the reduction is for worksharing, 0 otherwise @param num Number of data items to reduce @param data Array of data for reduction @return The taskgroup identifier Initialize task reduction for a parallel or worksharing. Note: this entry supposes the optional compiler-generated initializer routine has two parameters, pointer to object to be initialized and pointer to omp_orig */ void *__kmpc_taskred_modifier_init(ident_t *loc, int gtid, int is_ws, int num, void *data) { return __kmp_task_reduction_modifier_init(loc, gtid, is_ws, num, (kmp_taskred_input_t *)data); } /*! @ingroup TASKING @param loc Source location info @param gtid Global thread ID @param is_ws Is 1 if the reduction is for worksharing, 0 otherwise Finalize task reduction for a parallel or worksharing. */ void __kmpc_task_reduction_modifier_fini(ident_t *loc, int gtid, int is_ws) { __kmpc_end_taskgroup(loc, gtid); } // __kmpc_taskgroup: Start a new taskgroup void __kmpc_taskgroup(ident_t *loc, int gtid) { kmp_info_t *thread = __kmp_threads[gtid]; kmp_taskdata_t *taskdata = thread->th.th_current_task; kmp_taskgroup_t *tg_new = (kmp_taskgroup_t *)__kmp_thread_malloc(thread, sizeof(kmp_taskgroup_t)); KA_TRACE(10, ("__kmpc_taskgroup: T#%d loc=%p group=%p\n", gtid, loc, tg_new)); KMP_ATOMIC_ST_RLX(&tg_new->count, 0); KMP_ATOMIC_ST_RLX(&tg_new->cancel_request, cancel_noreq); tg_new->parent = taskdata->td_taskgroup; tg_new->reduce_data = NULL; tg_new->reduce_num_data = 0; taskdata->td_taskgroup = tg_new; #if OMPT_SUPPORT && OMPT_OPTIONAL if (UNLIKELY(ompt_enabled.ompt_callback_sync_region)) { void *codeptr = OMPT_LOAD_RETURN_ADDRESS(gtid); if (!codeptr) codeptr = OMPT_GET_RETURN_ADDRESS(0); kmp_team_t *team = thread->th.th_team; ompt_data_t my_task_data = taskdata->ompt_task_info.task_data; // FIXME: I think this is wrong for lwt! ompt_data_t my_parallel_data = team->t.ompt_team_info.parallel_data; ompt_callbacks.ompt_callback(ompt_callback_sync_region)( ompt_sync_region_taskgroup, ompt_scope_begin, &(my_parallel_data), &(my_task_data), codeptr); } #endif } // __kmpc_end_taskgroup: Wait until all tasks generated by the current task // and its descendants are complete void __kmpc_end_taskgroup(ident_t *loc, int gtid) { kmp_info_t *thread = __kmp_threads[gtid]; kmp_taskdata_t *taskdata = thread->th.th_current_task; kmp_taskgroup_t *taskgroup = taskdata->td_taskgroup; int thread_finished = FALSE; #if OMPT_SUPPORT && OMPT_OPTIONAL kmp_team_t *team; ompt_data_t my_task_data; ompt_data_t my_parallel_data; void *codeptr; if (UNLIKELY(ompt_enabled.enabled)) { team = thread->th.th_team; my_task_data = taskdata->ompt_task_info.task_data; // FIXME: I think this is wrong for lwt! my_parallel_data = team->t.ompt_team_info.parallel_data; codeptr = OMPT_LOAD_RETURN_ADDRESS(gtid); if (!codeptr) codeptr = OMPT_GET_RETURN_ADDRESS(0); } #endif KA_TRACE(10, ("__kmpc_end_taskgroup(enter): T#%d loc=%p\n", gtid, loc)); KMP_DEBUG_ASSERT(taskgroup != NULL); KMP_SET_THREAD_STATE_BLOCK(TASKGROUP); if (__kmp_tasking_mode != tskm_immediate_exec) { // mark task as waiting not on a barrier taskdata->td_taskwait_counter += 1; taskdata->td_taskwait_ident = loc; taskdata->td_taskwait_thread = gtid + 1; #if USE_ITT_BUILD // For ITT the taskgroup wait is similar to taskwait until we need to // distinguish them void *itt_sync_obj = __kmp_itt_taskwait_object(gtid); if (itt_sync_obj != NULL) __kmp_itt_taskwait_starting(gtid, itt_sync_obj); #endif /* USE_ITT_BUILD */ #if OMPT_SUPPORT && OMPT_OPTIONAL if (UNLIKELY(ompt_enabled.ompt_callback_sync_region_wait)) { ompt_callbacks.ompt_callback(ompt_callback_sync_region_wait)( ompt_sync_region_taskgroup, ompt_scope_begin, &(my_parallel_data), &(my_task_data), codeptr); } #endif if (!taskdata->td_flags.team_serial || (thread->th.th_task_team != NULL && thread->th.th_task_team->tt.tt_found_proxy_tasks)) { kmp_flag_32 flag(RCAST(std::atomic *, &(taskgroup->count)), 0U); while (KMP_ATOMIC_LD_ACQ(&taskgroup->count) != 0) { flag.execute_tasks(thread, gtid, FALSE, &thread_finished USE_ITT_BUILD_ARG(itt_sync_obj), __kmp_task_stealing_constraint); } } taskdata->td_taskwait_thread = -taskdata->td_taskwait_thread; // end waiting #if OMPT_SUPPORT && OMPT_OPTIONAL if (UNLIKELY(ompt_enabled.ompt_callback_sync_region_wait)) { ompt_callbacks.ompt_callback(ompt_callback_sync_region_wait)( ompt_sync_region_taskgroup, ompt_scope_end, &(my_parallel_data), &(my_task_data), codeptr); } #endif #if USE_ITT_BUILD if (itt_sync_obj != NULL) __kmp_itt_taskwait_finished(gtid, itt_sync_obj); #endif /* USE_ITT_BUILD */ } KMP_DEBUG_ASSERT(taskgroup->count == 0); if (taskgroup->reduce_data != NULL) { // need to reduce? int cnt; void *reduce_data; kmp_team_t *t = thread->th.th_team; kmp_taskred_data_t *arr = (kmp_taskred_data_t *)taskgroup->reduce_data; // check if data of the first reduction variable shared for the team void *priv0 = arr[0].reduce_priv; if ((reduce_data = KMP_ATOMIC_LD_ACQ(&t->t.t_tg_reduce_data[0])) != NULL && ((kmp_taskred_data_t *)reduce_data)[0].reduce_priv == priv0) { // finishing task reduction on parallel cnt = KMP_ATOMIC_INC(&t->t.t_tg_fini_counter[0]); if (cnt == thread->th.th_team_nproc - 1) { // we are the last thread passing __kmpc_reduction_modifier_fini() // finalize task reduction: __kmp_task_reduction_fini(thread, taskgroup); // cleanup fields in the team structure: // TODO: is relaxed store enough here (whole barrier should follow)? __kmp_thread_free(thread, reduce_data); KMP_ATOMIC_ST_REL(&t->t.t_tg_reduce_data[0], NULL); KMP_ATOMIC_ST_REL(&t->t.t_tg_fini_counter[0], 0); } else { // we are not the last thread passing __kmpc_reduction_modifier_fini(), // so do not finalize reduction, just clean own copy of the data __kmp_task_reduction_clean(thread, taskgroup); } } else if ((reduce_data = KMP_ATOMIC_LD_ACQ(&t->t.t_tg_reduce_data[1])) != NULL && ((kmp_taskred_data_t *)reduce_data)[0].reduce_priv == priv0) { // finishing task reduction on worksharing cnt = KMP_ATOMIC_INC(&t->t.t_tg_fini_counter[1]); if (cnt == thread->th.th_team_nproc - 1) { // we are the last thread passing __kmpc_reduction_modifier_fini() __kmp_task_reduction_fini(thread, taskgroup); // cleanup fields in team structure: // TODO: is relaxed store enough here (whole barrier should follow)? __kmp_thread_free(thread, reduce_data); KMP_ATOMIC_ST_REL(&t->t.t_tg_reduce_data[1], NULL); KMP_ATOMIC_ST_REL(&t->t.t_tg_fini_counter[1], 0); } else { // we are not the last thread passing __kmpc_reduction_modifier_fini(), // so do not finalize reduction, just clean own copy of the data __kmp_task_reduction_clean(thread, taskgroup); } } else { // finishing task reduction on taskgroup __kmp_task_reduction_fini(thread, taskgroup); } } // Restore parent taskgroup for the current task taskdata->td_taskgroup = taskgroup->parent; __kmp_thread_free(thread, taskgroup); KA_TRACE(10, ("__kmpc_end_taskgroup(exit): T#%d task %p finished waiting\n", gtid, taskdata)); ANNOTATE_HAPPENS_AFTER(taskdata); #if OMPT_SUPPORT && OMPT_OPTIONAL if (UNLIKELY(ompt_enabled.ompt_callback_sync_region)) { ompt_callbacks.ompt_callback(ompt_callback_sync_region)( ompt_sync_region_taskgroup, ompt_scope_end, &(my_parallel_data), &(my_task_data), codeptr); } #endif } // __kmp_remove_my_task: remove a task from my own deque static kmp_task_t *__kmp_remove_my_task(kmp_info_t *thread, kmp_int32 gtid, kmp_task_team_t *task_team, kmp_int32 is_constrained) { kmp_task_t *task; kmp_taskdata_t *taskdata; kmp_thread_data_t *thread_data; kmp_uint32 tail; KMP_DEBUG_ASSERT(__kmp_tasking_mode != tskm_immediate_exec); KMP_DEBUG_ASSERT(task_team->tt.tt_threads_data != NULL); // Caller should check this condition thread_data = &task_team->tt.tt_threads_data[__kmp_tid_from_gtid(gtid)]; KA_TRACE(10, ("__kmp_remove_my_task(enter): T#%d ntasks=%d head=%u tail=%u\n", gtid, thread_data->td.td_deque_ntasks, thread_data->td.td_deque_head, thread_data->td.td_deque_tail)); if (TCR_4(thread_data->td.td_deque_ntasks) == 0) { KA_TRACE(10, ("__kmp_remove_my_task(exit #1): T#%d No tasks to remove: " "ntasks=%d head=%u tail=%u\n", gtid, thread_data->td.td_deque_ntasks, thread_data->td.td_deque_head, thread_data->td.td_deque_tail)); return NULL; } __kmp_acquire_bootstrap_lock(&thread_data->td.td_deque_lock); if (TCR_4(thread_data->td.td_deque_ntasks) == 0) { __kmp_release_bootstrap_lock(&thread_data->td.td_deque_lock); KA_TRACE(10, ("__kmp_remove_my_task(exit #2): T#%d No tasks to remove: " "ntasks=%d head=%u tail=%u\n", gtid, thread_data->td.td_deque_ntasks, thread_data->td.td_deque_head, thread_data->td.td_deque_tail)); return NULL; } tail = (thread_data->td.td_deque_tail - 1) & TASK_DEQUE_MASK(thread_data->td); // Wrap index. taskdata = thread_data->td.td_deque[tail]; if (!__kmp_task_is_allowed(gtid, is_constrained, taskdata, thread->th.th_current_task)) { // The TSC does not allow to steal victim task __kmp_release_bootstrap_lock(&thread_data->td.td_deque_lock); KA_TRACE(10, ("__kmp_remove_my_task(exit #3): T#%d TSC blocks tail task: " "ntasks=%d head=%u tail=%u\n", gtid, thread_data->td.td_deque_ntasks, thread_data->td.td_deque_head, thread_data->td.td_deque_tail)); return NULL; } thread_data->td.td_deque_tail = tail; TCW_4(thread_data->td.td_deque_ntasks, thread_data->td.td_deque_ntasks - 1); __kmp_release_bootstrap_lock(&thread_data->td.td_deque_lock); KA_TRACE(10, ("__kmp_remove_my_task(exit #4): T#%d task %p removed: " "ntasks=%d head=%u tail=%u\n", gtid, taskdata, thread_data->td.td_deque_ntasks, thread_data->td.td_deque_head, thread_data->td.td_deque_tail)); task = KMP_TASKDATA_TO_TASK(taskdata); return task; } // __kmp_steal_task: remove a task from another thread's deque // Assume that calling thread has already checked existence of // task_team thread_data before calling this routine. static kmp_task_t *__kmp_steal_task(kmp_info_t *victim_thr, kmp_int32 gtid, kmp_task_team_t *task_team, std::atomic *unfinished_threads, int *thread_finished, kmp_int32 is_constrained) { kmp_task_t *task; kmp_taskdata_t *taskdata; kmp_taskdata_t *current; kmp_thread_data_t *victim_td, *threads_data; kmp_int32 target; kmp_int32 victim_tid; KMP_DEBUG_ASSERT(__kmp_tasking_mode != tskm_immediate_exec); threads_data = task_team->tt.tt_threads_data; KMP_DEBUG_ASSERT(threads_data != NULL); // Caller should check this condition victim_tid = victim_thr->th.th_info.ds.ds_tid; victim_td = &threads_data[victim_tid]; KA_TRACE(10, ("__kmp_steal_task(enter): T#%d try to steal from T#%d: " "task_team=%p ntasks=%d head=%u tail=%u\n", gtid, __kmp_gtid_from_thread(victim_thr), task_team, victim_td->td.td_deque_ntasks, victim_td->td.td_deque_head, victim_td->td.td_deque_tail)); if (TCR_4(victim_td->td.td_deque_ntasks) == 0) { KA_TRACE(10, ("__kmp_steal_task(exit #1): T#%d could not steal from T#%d: " "task_team=%p ntasks=%d head=%u tail=%u\n", gtid, __kmp_gtid_from_thread(victim_thr), task_team, victim_td->td.td_deque_ntasks, victim_td->td.td_deque_head, victim_td->td.td_deque_tail)); return NULL; } __kmp_acquire_bootstrap_lock(&victim_td->td.td_deque_lock); int ntasks = TCR_4(victim_td->td.td_deque_ntasks); // Check again after we acquire the lock if (ntasks == 0) { __kmp_release_bootstrap_lock(&victim_td->td.td_deque_lock); KA_TRACE(10, ("__kmp_steal_task(exit #2): T#%d could not steal from T#%d: " "task_team=%p ntasks=%d head=%u tail=%u\n", gtid, __kmp_gtid_from_thread(victim_thr), task_team, ntasks, victim_td->td.td_deque_head, victim_td->td.td_deque_tail)); return NULL; } KMP_DEBUG_ASSERT(victim_td->td.td_deque != NULL); current = __kmp_threads[gtid]->th.th_current_task; taskdata = victim_td->td.td_deque[victim_td->td.td_deque_head]; if (__kmp_task_is_allowed(gtid, is_constrained, taskdata, current)) { // Bump head pointer and Wrap. victim_td->td.td_deque_head = (victim_td->td.td_deque_head + 1) & TASK_DEQUE_MASK(victim_td->td); } else { if (!task_team->tt.tt_untied_task_encountered) { // The TSC does not allow to steal victim task __kmp_release_bootstrap_lock(&victim_td->td.td_deque_lock); KA_TRACE(10, ("__kmp_steal_task(exit #3): T#%d could not steal from " "T#%d: task_team=%p ntasks=%d head=%u tail=%u\n", gtid, __kmp_gtid_from_thread(victim_thr), task_team, ntasks, victim_td->td.td_deque_head, victim_td->td.td_deque_tail)); return NULL; } int i; // walk through victim's deque trying to steal any task target = victim_td->td.td_deque_head; taskdata = NULL; for (i = 1; i < ntasks; ++i) { target = (target + 1) & TASK_DEQUE_MASK(victim_td->td); taskdata = victim_td->td.td_deque[target]; if (__kmp_task_is_allowed(gtid, is_constrained, taskdata, current)) { break; // found victim task } else { taskdata = NULL; } } if (taskdata == NULL) { // No appropriate candidate to steal found __kmp_release_bootstrap_lock(&victim_td->td.td_deque_lock); KA_TRACE(10, ("__kmp_steal_task(exit #4): T#%d could not steal from " "T#%d: task_team=%p ntasks=%d head=%u tail=%u\n", gtid, __kmp_gtid_from_thread(victim_thr), task_team, ntasks, victim_td->td.td_deque_head, victim_td->td.td_deque_tail)); return NULL; } int prev = target; for (i = i + 1; i < ntasks; ++i) { // shift remaining tasks in the deque left by 1 target = (target + 1) & TASK_DEQUE_MASK(victim_td->td); victim_td->td.td_deque[prev] = victim_td->td.td_deque[target]; prev = target; } KMP_DEBUG_ASSERT( victim_td->td.td_deque_tail == (kmp_uint32)((target + 1) & TASK_DEQUE_MASK(victim_td->td))); victim_td->td.td_deque_tail = target; // tail -= 1 (wrapped)) } if (*thread_finished) { // We need to un-mark this victim as a finished victim. This must be done // before releasing the lock, or else other threads (starting with the // master victim) might be prematurely released from the barrier!!! kmp_int32 count; count = KMP_ATOMIC_INC(unfinished_threads); KA_TRACE( 20, ("__kmp_steal_task: T#%d inc unfinished_threads to %d: task_team=%p\n", gtid, count + 1, task_team)); *thread_finished = FALSE; } TCW_4(victim_td->td.td_deque_ntasks, ntasks - 1); __kmp_release_bootstrap_lock(&victim_td->td.td_deque_lock); KMP_COUNT_BLOCK(TASK_stolen); KA_TRACE(10, ("__kmp_steal_task(exit #5): T#%d stole task %p from T#%d: " "task_team=%p ntasks=%d head=%u tail=%u\n", gtid, taskdata, __kmp_gtid_from_thread(victim_thr), task_team, ntasks, victim_td->td.td_deque_head, victim_td->td.td_deque_tail)); task = KMP_TASKDATA_TO_TASK(taskdata); return task; } // __kmp_execute_tasks_template: Choose and execute tasks until either the // condition is statisfied (return true) or there are none left (return false). // // final_spin is TRUE if this is the spin at the release barrier. // thread_finished indicates whether the thread is finished executing all // the tasks it has on its deque, and is at the release barrier. // spinner is the location on which to spin. // spinner == NULL means only execute a single task and return. // checker is the value to check to terminate the spin. template static inline int __kmp_execute_tasks_template( kmp_info_t *thread, kmp_int32 gtid, C *flag, int final_spin, int *thread_finished USE_ITT_BUILD_ARG(void *itt_sync_obj), kmp_int32 is_constrained) { kmp_task_team_t *task_team = thread->th.th_task_team; kmp_thread_data_t *threads_data; kmp_task_t *task; kmp_info_t *other_thread; kmp_taskdata_t *current_task = thread->th.th_current_task; std::atomic *unfinished_threads; kmp_int32 nthreads, victim_tid = -2, use_own_tasks = 1, new_victim = 0, tid = thread->th.th_info.ds.ds_tid; KMP_DEBUG_ASSERT(__kmp_tasking_mode != tskm_immediate_exec); KMP_DEBUG_ASSERT(thread == __kmp_threads[gtid]); if (task_team == NULL || current_task == NULL) return FALSE; KA_TRACE(15, ("__kmp_execute_tasks_template(enter): T#%d final_spin=%d " "*thread_finished=%d\n", gtid, final_spin, *thread_finished)); thread->th.th_reap_state = KMP_NOT_SAFE_TO_REAP; threads_data = (kmp_thread_data_t *)TCR_PTR(task_team->tt.tt_threads_data); KMP_DEBUG_ASSERT(threads_data != NULL); nthreads = task_team->tt.tt_nproc; unfinished_threads = &(task_team->tt.tt_unfinished_threads); KMP_DEBUG_ASSERT(nthreads > 1 || task_team->tt.tt_found_proxy_tasks); KMP_DEBUG_ASSERT(*unfinished_threads >= 0); while (1) { // Outer loop keeps trying to find tasks in case of single thread // getting tasks from target constructs while (1) { // Inner loop to find a task and execute it task = NULL; if (use_own_tasks) { // check on own queue first task = __kmp_remove_my_task(thread, gtid, task_team, is_constrained); } if ((task == NULL) && (nthreads > 1)) { // Steal a task int asleep = 1; use_own_tasks = 0; // Try to steal from the last place I stole from successfully. if (victim_tid == -2) { // haven't stolen anything yet victim_tid = threads_data[tid].td.td_deque_last_stolen; if (victim_tid != -1) // if we have a last stolen from victim, get the thread other_thread = threads_data[victim_tid].td.td_thr; } if (victim_tid != -1) { // found last victim asleep = 0; } else if (!new_victim) { // no recent steals and we haven't already // used a new victim; select a random thread do { // Find a different thread to steal work from. // Pick a random thread. Initial plan was to cycle through all the // threads, and only return if we tried to steal from every thread, // and failed. Arch says that's not such a great idea. victim_tid = __kmp_get_random(thread) % (nthreads - 1); if (victim_tid >= tid) { ++victim_tid; // Adjusts random distribution to exclude self } // Found a potential victim other_thread = threads_data[victim_tid].td.td_thr; // There is a slight chance that __kmp_enable_tasking() did not wake // up all threads waiting at the barrier. If victim is sleeping, // then wake it up. Since we were going to pay the cache miss // penalty for referencing another thread's kmp_info_t struct // anyway, // the check shouldn't cost too much performance at this point. In // extra barrier mode, tasks do not sleep at the separate tasking // barrier, so this isn't a problem. asleep = 0; if ((__kmp_tasking_mode == tskm_task_teams) && (__kmp_dflt_blocktime != KMP_MAX_BLOCKTIME) && (TCR_PTR(CCAST(void *, other_thread->th.th_sleep_loc)) != NULL)) { asleep = 1; __kmp_null_resume_wrapper(__kmp_gtid_from_thread(other_thread), other_thread->th.th_sleep_loc); // A sleeping thread should not have any tasks on it's queue. // There is a slight possibility that it resumes, steals a task // from another thread, which spawns more tasks, all in the time // that it takes this thread to check => don't write an assertion // that the victim's queue is empty. Try stealing from a // different thread. } } while (asleep); } if (!asleep) { // We have a victim to try to steal from task = __kmp_steal_task(other_thread, gtid, task_team, unfinished_threads, thread_finished, is_constrained); } if (task != NULL) { // set last stolen to victim if (threads_data[tid].td.td_deque_last_stolen != victim_tid) { threads_data[tid].td.td_deque_last_stolen = victim_tid; // The pre-refactored code did not try more than 1 successful new // vicitm, unless the last one generated more local tasks; // new_victim keeps track of this new_victim = 1; } } else { // No tasks found; unset last_stolen KMP_CHECK_UPDATE(threads_data[tid].td.td_deque_last_stolen, -1); victim_tid = -2; // no successful victim found } } if (task == NULL) // break out of tasking loop break; // Found a task; execute it #if USE_ITT_BUILD && USE_ITT_NOTIFY if (__itt_sync_create_ptr || KMP_ITT_DEBUG) { if (itt_sync_obj == NULL) { // we are at fork barrier where we could not // get the object reliably itt_sync_obj = __kmp_itt_barrier_object(gtid, bs_forkjoin_barrier); } __kmp_itt_task_starting(itt_sync_obj); } #endif /* USE_ITT_BUILD && USE_ITT_NOTIFY */ __kmp_invoke_task(gtid, task, current_task); #if USE_ITT_BUILD if (itt_sync_obj != NULL) __kmp_itt_task_finished(itt_sync_obj); #endif /* USE_ITT_BUILD */ // If this thread is only partway through the barrier and the condition is // met, then return now, so that the barrier gather/release pattern can // proceed. If this thread is in the last spin loop in the barrier, // waiting to be released, we know that the termination condition will not // be satisfied, so don't waste any cycles checking it. if (flag == NULL || (!final_spin && flag->done_check())) { KA_TRACE( 15, ("__kmp_execute_tasks_template: T#%d spin condition satisfied\n", gtid)); return TRUE; } if (thread->th.th_task_team == NULL) { break; } KMP_YIELD(__kmp_library == library_throughput); // Yield before next task // If execution of a stolen task results in more tasks being placed on our // run queue, reset use_own_tasks if (!use_own_tasks && TCR_4(threads_data[tid].td.td_deque_ntasks) != 0) { KA_TRACE(20, ("__kmp_execute_tasks_template: T#%d stolen task spawned " "other tasks, restart\n", gtid)); use_own_tasks = 1; new_victim = 0; } } // The task source has been exhausted. If in final spin loop of barrier, // check if termination condition is satisfied. The work queue may be empty // but there might be proxy tasks still executing. if (final_spin && KMP_ATOMIC_LD_ACQ(¤t_task->td_incomplete_child_tasks) == 0) { // First, decrement the #unfinished threads, if that has not already been // done. This decrement might be to the spin location, and result in the // termination condition being satisfied. if (!*thread_finished) { kmp_int32 count; count = KMP_ATOMIC_DEC(unfinished_threads) - 1; KA_TRACE(20, ("__kmp_execute_tasks_template: T#%d dec " "unfinished_threads to %d task_team=%p\n", gtid, count, task_team)); *thread_finished = TRUE; } // It is now unsafe to reference thread->th.th_team !!! // Decrementing task_team->tt.tt_unfinished_threads can allow the master // thread to pass through the barrier, where it might reset each thread's // th.th_team field for the next parallel region. If we can steal more // work, we know that this has not happened yet. if (flag != NULL && flag->done_check()) { KA_TRACE( 15, ("__kmp_execute_tasks_template: T#%d spin condition satisfied\n", gtid)); return TRUE; } } // If this thread's task team is NULL, master has recognized that there are // no more tasks; bail out if (thread->th.th_task_team == NULL) { KA_TRACE(15, ("__kmp_execute_tasks_template: T#%d no more tasks\n", gtid)); return FALSE; } // We could be getting tasks from target constructs; if this is the only // thread, keep trying to execute tasks from own queue if (nthreads == 1) use_own_tasks = 1; else { KA_TRACE(15, ("__kmp_execute_tasks_template: T#%d can't find work\n", gtid)); return FALSE; } } } int __kmp_execute_tasks_32( kmp_info_t *thread, kmp_int32 gtid, kmp_flag_32 *flag, int final_spin, int *thread_finished USE_ITT_BUILD_ARG(void *itt_sync_obj), kmp_int32 is_constrained) { return __kmp_execute_tasks_template( thread, gtid, flag, final_spin, thread_finished USE_ITT_BUILD_ARG(itt_sync_obj), is_constrained); } int __kmp_execute_tasks_64( kmp_info_t *thread, kmp_int32 gtid, kmp_flag_64 *flag, int final_spin, int *thread_finished USE_ITT_BUILD_ARG(void *itt_sync_obj), kmp_int32 is_constrained) { return __kmp_execute_tasks_template( thread, gtid, flag, final_spin, thread_finished USE_ITT_BUILD_ARG(itt_sync_obj), is_constrained); } int __kmp_execute_tasks_oncore( kmp_info_t *thread, kmp_int32 gtid, kmp_flag_oncore *flag, int final_spin, int *thread_finished USE_ITT_BUILD_ARG(void *itt_sync_obj), kmp_int32 is_constrained) { return __kmp_execute_tasks_template( thread, gtid, flag, final_spin, thread_finished USE_ITT_BUILD_ARG(itt_sync_obj), is_constrained); } // __kmp_enable_tasking: Allocate task team and resume threads sleeping at the // next barrier so they can assist in executing enqueued tasks. // First thread in allocates the task team atomically. static void __kmp_enable_tasking(kmp_task_team_t *task_team, kmp_info_t *this_thr) { kmp_thread_data_t *threads_data; int nthreads, i, is_init_thread; KA_TRACE(10, ("__kmp_enable_tasking(enter): T#%d\n", __kmp_gtid_from_thread(this_thr))); KMP_DEBUG_ASSERT(task_team != NULL); KMP_DEBUG_ASSERT(this_thr->th.th_team != NULL); nthreads = task_team->tt.tt_nproc; KMP_DEBUG_ASSERT(nthreads > 0); KMP_DEBUG_ASSERT(nthreads == this_thr->th.th_team->t.t_nproc); // Allocate or increase the size of threads_data if necessary is_init_thread = __kmp_realloc_task_threads_data(this_thr, task_team); if (!is_init_thread) { // Some other thread already set up the array. KA_TRACE( 20, ("__kmp_enable_tasking(exit): T#%d: threads array already set up.\n", __kmp_gtid_from_thread(this_thr))); return; } threads_data = (kmp_thread_data_t *)TCR_PTR(task_team->tt.tt_threads_data); KMP_DEBUG_ASSERT(threads_data != NULL); if (__kmp_tasking_mode == tskm_task_teams && (__kmp_dflt_blocktime != KMP_MAX_BLOCKTIME)) { // Release any threads sleeping at the barrier, so that they can steal // tasks and execute them. In extra barrier mode, tasks do not sleep // at the separate tasking barrier, so this isn't a problem. for (i = 0; i < nthreads; i++) { volatile void *sleep_loc; kmp_info_t *thread = threads_data[i].td.td_thr; if (i == this_thr->th.th_info.ds.ds_tid) { continue; } // Since we haven't locked the thread's suspend mutex lock at this // point, there is a small window where a thread might be putting // itself to sleep, but hasn't set the th_sleep_loc field yet. // To work around this, __kmp_execute_tasks_template() periodically checks // see if other threads are sleeping (using the same random mechanism that // is used for task stealing) and awakens them if they are. if ((sleep_loc = TCR_PTR(CCAST(void *, thread->th.th_sleep_loc))) != NULL) { KF_TRACE(50, ("__kmp_enable_tasking: T#%d waking up thread T#%d\n", __kmp_gtid_from_thread(this_thr), __kmp_gtid_from_thread(thread))); __kmp_null_resume_wrapper(__kmp_gtid_from_thread(thread), sleep_loc); } else { KF_TRACE(50, ("__kmp_enable_tasking: T#%d don't wake up thread T#%d\n", __kmp_gtid_from_thread(this_thr), __kmp_gtid_from_thread(thread))); } } } KA_TRACE(10, ("__kmp_enable_tasking(exit): T#%d\n", __kmp_gtid_from_thread(this_thr))); } /* // TODO: Check the comment consistency * Utility routines for "task teams". A task team (kmp_task_t) is kind of * like a shadow of the kmp_team_t data struct, with a different lifetime. * After a child * thread checks into a barrier and calls __kmp_release() from * the particular variant of __kmp__barrier_gather(), it can no * longer assume that the kmp_team_t structure is intact (at any moment, the * master thread may exit the barrier code and free the team data structure, * and return the threads to the thread pool). * * This does not work with the tasking code, as the thread is still * expected to participate in the execution of any tasks that may have been * spawned my a member of the team, and the thread still needs access to all * to each thread in the team, so that it can steal work from it. * * Enter the existence of the kmp_task_team_t struct. It employs a reference * counting mechanism, and is allocated by the master thread before calling * __kmp__release, and then is release by the last thread to * exit __kmp__release at the next barrier. I.e. the lifetimes * of the kmp_task_team_t structs for consecutive barriers can overlap * (and will, unless the master thread is the last thread to exit the barrier * release phase, which is not typical). The existence of such a struct is * useful outside the context of tasking. * * We currently use the existence of the threads array as an indicator that * tasks were spawned since the last barrier. If the structure is to be * useful outside the context of tasking, then this will have to change, but * not setting the field minimizes the performance impact of tasking on * barriers, when no explicit tasks were spawned (pushed, actually). */ static kmp_task_team_t *__kmp_free_task_teams = NULL; // Free list for task_team data structures // Lock for task team data structures kmp_bootstrap_lock_t __kmp_task_team_lock = KMP_BOOTSTRAP_LOCK_INITIALIZER(__kmp_task_team_lock); // __kmp_alloc_task_deque: // Allocates a task deque for a particular thread, and initialize the necessary // data structures relating to the deque. This only happens once per thread // per task team since task teams are recycled. No lock is needed during // allocation since each thread allocates its own deque. static void __kmp_alloc_task_deque(kmp_info_t *thread, kmp_thread_data_t *thread_data) { __kmp_init_bootstrap_lock(&thread_data->td.td_deque_lock); KMP_DEBUG_ASSERT(thread_data->td.td_deque == NULL); // Initialize last stolen task field to "none" thread_data->td.td_deque_last_stolen = -1; KMP_DEBUG_ASSERT(TCR_4(thread_data->td.td_deque_ntasks) == 0); KMP_DEBUG_ASSERT(thread_data->td.td_deque_head == 0); KMP_DEBUG_ASSERT(thread_data->td.td_deque_tail == 0); KE_TRACE( 10, ("__kmp_alloc_task_deque: T#%d allocating deque[%d] for thread_data %p\n", __kmp_gtid_from_thread(thread), INITIAL_TASK_DEQUE_SIZE, thread_data)); // Allocate space for task deque, and zero the deque // Cannot use __kmp_thread_calloc() because threads not around for // kmp_reap_task_team( ). thread_data->td.td_deque = (kmp_taskdata_t **)__kmp_allocate( INITIAL_TASK_DEQUE_SIZE * sizeof(kmp_taskdata_t *)); thread_data->td.td_deque_size = INITIAL_TASK_DEQUE_SIZE; } // __kmp_free_task_deque: // Deallocates a task deque for a particular thread. Happens at library // deallocation so don't need to reset all thread data fields. static void __kmp_free_task_deque(kmp_thread_data_t *thread_data) { if (thread_data->td.td_deque != NULL) { __kmp_acquire_bootstrap_lock(&thread_data->td.td_deque_lock); TCW_4(thread_data->td.td_deque_ntasks, 0); __kmp_free(thread_data->td.td_deque); thread_data->td.td_deque = NULL; __kmp_release_bootstrap_lock(&thread_data->td.td_deque_lock); } #ifdef BUILD_TIED_TASK_STACK // GEH: Figure out what to do here for td_susp_tied_tasks if (thread_data->td.td_susp_tied_tasks.ts_entries != TASK_STACK_EMPTY) { __kmp_free_task_stack(__kmp_thread_from_gtid(gtid), thread_data); } #endif // BUILD_TIED_TASK_STACK } // __kmp_realloc_task_threads_data: // Allocates a threads_data array for a task team, either by allocating an // initial array or enlarging an existing array. Only the first thread to get // the lock allocs or enlarges the array and re-initializes the array elements. // That thread returns "TRUE", the rest return "FALSE". // Assumes that the new array size is given by task_team -> tt.tt_nproc. // The current size is given by task_team -> tt.tt_max_threads. static int __kmp_realloc_task_threads_data(kmp_info_t *thread, kmp_task_team_t *task_team) { kmp_thread_data_t **threads_data_p; kmp_int32 nthreads, maxthreads; int is_init_thread = FALSE; if (TCR_4(task_team->tt.tt_found_tasks)) { // Already reallocated and initialized. return FALSE; } threads_data_p = &task_team->tt.tt_threads_data; nthreads = task_team->tt.tt_nproc; maxthreads = task_team->tt.tt_max_threads; // All threads must lock when they encounter the first task of the implicit // task region to make sure threads_data fields are (re)initialized before // used. __kmp_acquire_bootstrap_lock(&task_team->tt.tt_threads_lock); if (!TCR_4(task_team->tt.tt_found_tasks)) { // first thread to enable tasking kmp_team_t *team = thread->th.th_team; int i; is_init_thread = TRUE; if (maxthreads < nthreads) { if (*threads_data_p != NULL) { kmp_thread_data_t *old_data = *threads_data_p; kmp_thread_data_t *new_data = NULL; KE_TRACE( 10, ("__kmp_realloc_task_threads_data: T#%d reallocating " "threads data for task_team %p, new_size = %d, old_size = %d\n", __kmp_gtid_from_thread(thread), task_team, nthreads, maxthreads)); // Reallocate threads_data to have more elements than current array // Cannot use __kmp_thread_realloc() because threads not around for // kmp_reap_task_team( ). Note all new array entries are initialized // to zero by __kmp_allocate(). new_data = (kmp_thread_data_t *)__kmp_allocate( nthreads * sizeof(kmp_thread_data_t)); // copy old data to new data KMP_MEMCPY_S((void *)new_data, nthreads * sizeof(kmp_thread_data_t), (void *)old_data, maxthreads * sizeof(kmp_thread_data_t)); #ifdef BUILD_TIED_TASK_STACK // GEH: Figure out if this is the right thing to do for (i = maxthreads; i < nthreads; i++) { kmp_thread_data_t *thread_data = &(*threads_data_p)[i]; __kmp_init_task_stack(__kmp_gtid_from_thread(thread), thread_data); } #endif // BUILD_TIED_TASK_STACK // Install the new data and free the old data (*threads_data_p) = new_data; __kmp_free(old_data); } else { KE_TRACE(10, ("__kmp_realloc_task_threads_data: T#%d allocating " "threads data for task_team %p, size = %d\n", __kmp_gtid_from_thread(thread), task_team, nthreads)); // Make the initial allocate for threads_data array, and zero entries // Cannot use __kmp_thread_calloc() because threads not around for // kmp_reap_task_team( ). ANNOTATE_IGNORE_WRITES_BEGIN(); *threads_data_p = (kmp_thread_data_t *)__kmp_allocate( nthreads * sizeof(kmp_thread_data_t)); ANNOTATE_IGNORE_WRITES_END(); #ifdef BUILD_TIED_TASK_STACK // GEH: Figure out if this is the right thing to do for (i = 0; i < nthreads; i++) { kmp_thread_data_t *thread_data = &(*threads_data_p)[i]; __kmp_init_task_stack(__kmp_gtid_from_thread(thread), thread_data); } #endif // BUILD_TIED_TASK_STACK } task_team->tt.tt_max_threads = nthreads; } else { // If array has (more than) enough elements, go ahead and use it KMP_DEBUG_ASSERT(*threads_data_p != NULL); } // initialize threads_data pointers back to thread_info structures for (i = 0; i < nthreads; i++) { kmp_thread_data_t *thread_data = &(*threads_data_p)[i]; thread_data->td.td_thr = team->t.t_threads[i]; if (thread_data->td.td_deque_last_stolen >= nthreads) { // The last stolen field survives across teams / barrier, and the number // of threads may have changed. It's possible (likely?) that a new // parallel region will exhibit the same behavior as previous region. thread_data->td.td_deque_last_stolen = -1; } } KMP_MB(); TCW_SYNC_4(task_team->tt.tt_found_tasks, TRUE); } __kmp_release_bootstrap_lock(&task_team->tt.tt_threads_lock); return is_init_thread; } // __kmp_free_task_threads_data: // Deallocates a threads_data array for a task team, including any attached // tasking deques. Only occurs at library shutdown. static void __kmp_free_task_threads_data(kmp_task_team_t *task_team) { __kmp_acquire_bootstrap_lock(&task_team->tt.tt_threads_lock); if (task_team->tt.tt_threads_data != NULL) { int i; for (i = 0; i < task_team->tt.tt_max_threads; i++) { __kmp_free_task_deque(&task_team->tt.tt_threads_data[i]); } __kmp_free(task_team->tt.tt_threads_data); task_team->tt.tt_threads_data = NULL; } __kmp_release_bootstrap_lock(&task_team->tt.tt_threads_lock); } // __kmp_allocate_task_team: // Allocates a task team associated with a specific team, taking it from // the global task team free list if possible. Also initializes data // structures. static kmp_task_team_t *__kmp_allocate_task_team(kmp_info_t *thread, kmp_team_t *team) { kmp_task_team_t *task_team = NULL; int nthreads; KA_TRACE(20, ("__kmp_allocate_task_team: T#%d entering; team = %p\n", (thread ? __kmp_gtid_from_thread(thread) : -1), team)); if (TCR_PTR(__kmp_free_task_teams) != NULL) { // Take a task team from the task team pool __kmp_acquire_bootstrap_lock(&__kmp_task_team_lock); if (__kmp_free_task_teams != NULL) { task_team = __kmp_free_task_teams; TCW_PTR(__kmp_free_task_teams, task_team->tt.tt_next); task_team->tt.tt_next = NULL; } __kmp_release_bootstrap_lock(&__kmp_task_team_lock); } if (task_team == NULL) { KE_TRACE(10, ("__kmp_allocate_task_team: T#%d allocating " "task team for team %p\n", __kmp_gtid_from_thread(thread), team)); // Allocate a new task team if one is not available. // Cannot use __kmp_thread_malloc() because threads not around for // kmp_reap_task_team( ). task_team = (kmp_task_team_t *)__kmp_allocate(sizeof(kmp_task_team_t)); __kmp_init_bootstrap_lock(&task_team->tt.tt_threads_lock); // AC: __kmp_allocate zeroes returned memory // task_team -> tt.tt_threads_data = NULL; // task_team -> tt.tt_max_threads = 0; // task_team -> tt.tt_next = NULL; } TCW_4(task_team->tt.tt_found_tasks, FALSE); TCW_4(task_team->tt.tt_found_proxy_tasks, FALSE); task_team->tt.tt_nproc = nthreads = team->t.t_nproc; KMP_ATOMIC_ST_REL(&task_team->tt.tt_unfinished_threads, nthreads); TCW_4(task_team->tt.tt_active, TRUE); KA_TRACE(20, ("__kmp_allocate_task_team: T#%d exiting; task_team = %p " "unfinished_threads init'd to %d\n", (thread ? __kmp_gtid_from_thread(thread) : -1), task_team, KMP_ATOMIC_LD_RLX(&task_team->tt.tt_unfinished_threads))); return task_team; } // __kmp_free_task_team: // Frees the task team associated with a specific thread, and adds it // to the global task team free list. void __kmp_free_task_team(kmp_info_t *thread, kmp_task_team_t *task_team) { KA_TRACE(20, ("__kmp_free_task_team: T#%d task_team = %p\n", thread ? __kmp_gtid_from_thread(thread) : -1, task_team)); // Put task team back on free list __kmp_acquire_bootstrap_lock(&__kmp_task_team_lock); KMP_DEBUG_ASSERT(task_team->tt.tt_next == NULL); task_team->tt.tt_next = __kmp_free_task_teams; TCW_PTR(__kmp_free_task_teams, task_team); __kmp_release_bootstrap_lock(&__kmp_task_team_lock); } // __kmp_reap_task_teams: // Free all the task teams on the task team free list. // Should only be done during library shutdown. // Cannot do anything that needs a thread structure or gtid since they are // already gone. void __kmp_reap_task_teams(void) { kmp_task_team_t *task_team; if (TCR_PTR(__kmp_free_task_teams) != NULL) { // Free all task_teams on the free list __kmp_acquire_bootstrap_lock(&__kmp_task_team_lock); while ((task_team = __kmp_free_task_teams) != NULL) { __kmp_free_task_teams = task_team->tt.tt_next; task_team->tt.tt_next = NULL; // Free threads_data if necessary if (task_team->tt.tt_threads_data != NULL) { __kmp_free_task_threads_data(task_team); } __kmp_free(task_team); } __kmp_release_bootstrap_lock(&__kmp_task_team_lock); } } // __kmp_wait_to_unref_task_teams: // Some threads could still be in the fork barrier release code, possibly // trying to steal tasks. Wait for each thread to unreference its task team. void __kmp_wait_to_unref_task_teams(void) { kmp_info_t *thread; kmp_uint32 spins; int done; KMP_INIT_YIELD(spins); for (;;) { done = TRUE; // TODO: GEH - this may be is wrong because some sync would be necessary // in case threads are added to the pool during the traversal. Need to // verify that lock for thread pool is held when calling this routine. for (thread = CCAST(kmp_info_t *, __kmp_thread_pool); thread != NULL; thread = thread->th.th_next_pool) { #if KMP_OS_WINDOWS DWORD exit_val; #endif if (TCR_PTR(thread->th.th_task_team) == NULL) { KA_TRACE(10, ("__kmp_wait_to_unref_task_team: T#%d task_team == NULL\n", __kmp_gtid_from_thread(thread))); continue; } #if KMP_OS_WINDOWS // TODO: GEH - add this check for Linux* OS / OS X* as well? if (!__kmp_is_thread_alive(thread, &exit_val)) { thread->th.th_task_team = NULL; continue; } #endif done = FALSE; // Because th_task_team pointer is not NULL for this thread KA_TRACE(10, ("__kmp_wait_to_unref_task_team: Waiting for T#%d to " "unreference task_team\n", __kmp_gtid_from_thread(thread))); if (__kmp_dflt_blocktime != KMP_MAX_BLOCKTIME) { volatile void *sleep_loc; // If the thread is sleeping, awaken it. if ((sleep_loc = TCR_PTR(CCAST(void *, thread->th.th_sleep_loc))) != NULL) { KA_TRACE( 10, ("__kmp_wait_to_unref_task_team: T#%d waking up thread T#%d\n", __kmp_gtid_from_thread(thread), __kmp_gtid_from_thread(thread))); __kmp_null_resume_wrapper(__kmp_gtid_from_thread(thread), sleep_loc); } } } if (done) { break; } // If oversubscribed or have waited a bit, yield. KMP_YIELD_OVERSUB_ELSE_SPIN(spins); } } // __kmp_task_team_setup: Create a task_team for the current team, but use // an already created, unused one if it already exists. void __kmp_task_team_setup(kmp_info_t *this_thr, kmp_team_t *team, int always) { KMP_DEBUG_ASSERT(__kmp_tasking_mode != tskm_immediate_exec); // If this task_team hasn't been created yet, allocate it. It will be used in // the region after the next. // If it exists, it is the current task team and shouldn't be touched yet as // it may still be in use. if (team->t.t_task_team[this_thr->th.th_task_state] == NULL && (always || team->t.t_nproc > 1)) { team->t.t_task_team[this_thr->th.th_task_state] = __kmp_allocate_task_team(this_thr, team); KA_TRACE(20, ("__kmp_task_team_setup: Master T#%d created new task_team %p " "for team %d at parity=%d\n", __kmp_gtid_from_thread(this_thr), team->t.t_task_team[this_thr->th.th_task_state], ((team != NULL) ? team->t.t_id : -1), this_thr->th.th_task_state)); } // After threads exit the release, they will call sync, and then point to this // other task_team; make sure it is allocated and properly initialized. As // threads spin in the barrier release phase, they will continue to use the // previous task_team struct(above), until they receive the signal to stop // checking for tasks (they can't safely reference the kmp_team_t struct, // which could be reallocated by the master thread). No task teams are formed // for serialized teams. if (team->t.t_nproc > 1) { int other_team = 1 - this_thr->th.th_task_state; if (team->t.t_task_team[other_team] == NULL) { // setup other team as well team->t.t_task_team[other_team] = __kmp_allocate_task_team(this_thr, team); KA_TRACE(20, ("__kmp_task_team_setup: Master T#%d created second new " "task_team %p for team %d at parity=%d\n", __kmp_gtid_from_thread(this_thr), team->t.t_task_team[other_team], ((team != NULL) ? team->t.t_id : -1), other_team)); } else { // Leave the old task team struct in place for the upcoming region; // adjust as needed kmp_task_team_t *task_team = team->t.t_task_team[other_team]; if (!task_team->tt.tt_active || team->t.t_nproc != task_team->tt.tt_nproc) { TCW_4(task_team->tt.tt_nproc, team->t.t_nproc); TCW_4(task_team->tt.tt_found_tasks, FALSE); TCW_4(task_team->tt.tt_found_proxy_tasks, FALSE); KMP_ATOMIC_ST_REL(&task_team->tt.tt_unfinished_threads, team->t.t_nproc); TCW_4(task_team->tt.tt_active, TRUE); } // if team size has changed, the first thread to enable tasking will // realloc threads_data if necessary KA_TRACE(20, ("__kmp_task_team_setup: Master T#%d reset next task_team " "%p for team %d at parity=%d\n", __kmp_gtid_from_thread(this_thr), team->t.t_task_team[other_team], ((team != NULL) ? team->t.t_id : -1), other_team)); } } } // __kmp_task_team_sync: Propagation of task team data from team to threads // which happens just after the release phase of a team barrier. This may be // called by any thread, but only for teams with # threads > 1. void __kmp_task_team_sync(kmp_info_t *this_thr, kmp_team_t *team) { KMP_DEBUG_ASSERT(__kmp_tasking_mode != tskm_immediate_exec); // Toggle the th_task_state field, to switch which task_team this thread // refers to this_thr->th.th_task_state = 1 - this_thr->th.th_task_state; // It is now safe to propagate the task team pointer from the team struct to // the current thread. TCW_PTR(this_thr->th.th_task_team, team->t.t_task_team[this_thr->th.th_task_state]); KA_TRACE(20, ("__kmp_task_team_sync: Thread T#%d task team switched to task_team " "%p from Team #%d (parity=%d)\n", __kmp_gtid_from_thread(this_thr), this_thr->th.th_task_team, ((team != NULL) ? team->t.t_id : -1), this_thr->th.th_task_state)); } // __kmp_task_team_wait: Master thread waits for outstanding tasks after the // barrier gather phase. Only called by master thread if #threads in team > 1 or // if proxy tasks were created. // // wait is a flag that defaults to 1 (see kmp.h), but waiting can be turned off // by passing in 0 optionally as the last argument. When wait is zero, master // thread does not wait for unfinished_threads to reach 0. void __kmp_task_team_wait( kmp_info_t *this_thr, kmp_team_t *team USE_ITT_BUILD_ARG(void *itt_sync_obj), int wait) { kmp_task_team_t *task_team = team->t.t_task_team[this_thr->th.th_task_state]; KMP_DEBUG_ASSERT(__kmp_tasking_mode != tskm_immediate_exec); KMP_DEBUG_ASSERT(task_team == this_thr->th.th_task_team); if ((task_team != NULL) && KMP_TASKING_ENABLED(task_team)) { if (wait) { KA_TRACE(20, ("__kmp_task_team_wait: Master T#%d waiting for all tasks " "(for unfinished_threads to reach 0) on task_team = %p\n", __kmp_gtid_from_thread(this_thr), task_team)); // Worker threads may have dropped through to release phase, but could // still be executing tasks. Wait here for tasks to complete. To avoid // memory contention, only master thread checks termination condition. kmp_flag_32 flag(RCAST(std::atomic *, &task_team->tt.tt_unfinished_threads), 0U); flag.wait(this_thr, TRUE USE_ITT_BUILD_ARG(itt_sync_obj)); } // Deactivate the old task team, so that the worker threads will stop // referencing it while spinning. KA_TRACE( 20, ("__kmp_task_team_wait: Master T#%d deactivating task_team %p: " "setting active to false, setting local and team's pointer to NULL\n", __kmp_gtid_from_thread(this_thr), task_team)); KMP_DEBUG_ASSERT(task_team->tt.tt_nproc > 1 || task_team->tt.tt_found_proxy_tasks == TRUE); TCW_SYNC_4(task_team->tt.tt_found_proxy_tasks, FALSE); KMP_CHECK_UPDATE(task_team->tt.tt_untied_task_encountered, 0); TCW_SYNC_4(task_team->tt.tt_active, FALSE); KMP_MB(); TCW_PTR(this_thr->th.th_task_team, NULL); } } // __kmp_tasking_barrier: // This routine may only called when __kmp_tasking_mode == tskm_extra_barrier. // Internal function to execute all tasks prior to a regular barrier or a join // barrier. It is a full barrier itself, which unfortunately turns regular // barriers into double barriers and join barriers into 1 1/2 barriers. void __kmp_tasking_barrier(kmp_team_t *team, kmp_info_t *thread, int gtid) { std::atomic *spin = RCAST( std::atomic *, &team->t.t_task_team[thread->th.th_task_state]->tt.tt_unfinished_threads); int flag = FALSE; KMP_DEBUG_ASSERT(__kmp_tasking_mode == tskm_extra_barrier); #if USE_ITT_BUILD KMP_FSYNC_SPIN_INIT(spin, NULL); #endif /* USE_ITT_BUILD */ kmp_flag_32 spin_flag(spin, 0U); while (!spin_flag.execute_tasks(thread, gtid, TRUE, &flag USE_ITT_BUILD_ARG(NULL), 0)) { #if USE_ITT_BUILD // TODO: What about itt_sync_obj?? KMP_FSYNC_SPIN_PREPARE(RCAST(void *, spin)); #endif /* USE_ITT_BUILD */ if (TCR_4(__kmp_global.g.g_done)) { if (__kmp_global.g.g_abort) __kmp_abort_thread(); break; } KMP_YIELD(TRUE); } #if USE_ITT_BUILD KMP_FSYNC_SPIN_ACQUIRED(RCAST(void *, spin)); #endif /* USE_ITT_BUILD */ } // __kmp_give_task puts a task into a given thread queue if: // - the queue for that thread was created // - there's space in that queue // Because of this, __kmp_push_task needs to check if there's space after // getting the lock static bool __kmp_give_task(kmp_info_t *thread, kmp_int32 tid, kmp_task_t *task, kmp_int32 pass) { kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(task); kmp_task_team_t *task_team = taskdata->td_task_team; KA_TRACE(20, ("__kmp_give_task: trying to give task %p to thread %d.\n", taskdata, tid)); // If task_team is NULL something went really bad... KMP_DEBUG_ASSERT(task_team != NULL); bool result = false; kmp_thread_data_t *thread_data = &task_team->tt.tt_threads_data[tid]; if (thread_data->td.td_deque == NULL) { // There's no queue in this thread, go find another one // We're guaranteed that at least one thread has a queue KA_TRACE(30, ("__kmp_give_task: thread %d has no queue while giving task %p.\n", tid, taskdata)); return result; } if (TCR_4(thread_data->td.td_deque_ntasks) >= TASK_DEQUE_SIZE(thread_data->td)) { KA_TRACE( 30, ("__kmp_give_task: queue is full while giving task %p to thread %d.\n", taskdata, tid)); // if this deque is bigger than the pass ratio give a chance to another // thread if (TASK_DEQUE_SIZE(thread_data->td) / INITIAL_TASK_DEQUE_SIZE >= pass) return result; __kmp_acquire_bootstrap_lock(&thread_data->td.td_deque_lock); if (TCR_4(thread_data->td.td_deque_ntasks) >= TASK_DEQUE_SIZE(thread_data->td)) { // expand deque to push the task which is not allowed to execute __kmp_realloc_task_deque(thread, thread_data); } } else { __kmp_acquire_bootstrap_lock(&thread_data->td.td_deque_lock); if (TCR_4(thread_data->td.td_deque_ntasks) >= TASK_DEQUE_SIZE(thread_data->td)) { KA_TRACE(30, ("__kmp_give_task: queue is full while giving task %p to " "thread %d.\n", taskdata, tid)); // if this deque is bigger than the pass ratio give a chance to another // thread if (TASK_DEQUE_SIZE(thread_data->td) / INITIAL_TASK_DEQUE_SIZE >= pass) goto release_and_exit; __kmp_realloc_task_deque(thread, thread_data); } } // lock is held here, and there is space in the deque thread_data->td.td_deque[thread_data->td.td_deque_tail] = taskdata; // Wrap index. thread_data->td.td_deque_tail = (thread_data->td.td_deque_tail + 1) & TASK_DEQUE_MASK(thread_data->td); TCW_4(thread_data->td.td_deque_ntasks, TCR_4(thread_data->td.td_deque_ntasks) + 1); result = true; KA_TRACE(30, ("__kmp_give_task: successfully gave task %p to thread %d.\n", taskdata, tid)); release_and_exit: __kmp_release_bootstrap_lock(&thread_data->td.td_deque_lock); return result; } /* The finish of the proxy tasks is divided in two pieces: - the top half is the one that can be done from a thread outside the team - the bottom half must be run from a thread within the team In order to run the bottom half the task gets queued back into one of the threads of the team. Once the td_incomplete_child_task counter of the parent is decremented the threads can leave the barriers. So, the bottom half needs to be queued before the counter is decremented. The top half is therefore divided in two parts: - things that can be run before queuing the bottom half - things that must be run after queuing the bottom half This creates a second race as the bottom half can free the task before the second top half is executed. To avoid this we use the td_incomplete_child_task of the proxy task to synchronize the top and bottom half. */ static void __kmp_first_top_half_finish_proxy(kmp_taskdata_t *taskdata) { KMP_DEBUG_ASSERT(taskdata->td_flags.tasktype == TASK_EXPLICIT); KMP_DEBUG_ASSERT(taskdata->td_flags.proxy == TASK_PROXY); KMP_DEBUG_ASSERT(taskdata->td_flags.complete == 0); KMP_DEBUG_ASSERT(taskdata->td_flags.freed == 0); taskdata->td_flags.complete = 1; // mark the task as completed if (taskdata->td_taskgroup) KMP_ATOMIC_DEC(&taskdata->td_taskgroup->count); // Create an imaginary children for this task so the bottom half cannot // release the task before we have completed the second top half KMP_ATOMIC_INC(&taskdata->td_incomplete_child_tasks); } static void __kmp_second_top_half_finish_proxy(kmp_taskdata_t *taskdata) { kmp_int32 children = 0; // Predecrement simulated by "- 1" calculation children = KMP_ATOMIC_DEC(&taskdata->td_parent->td_incomplete_child_tasks) - 1; KMP_DEBUG_ASSERT(children >= 0); // Remove the imaginary children KMP_ATOMIC_DEC(&taskdata->td_incomplete_child_tasks); } static void __kmp_bottom_half_finish_proxy(kmp_int32 gtid, kmp_task_t *ptask) { kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(ptask); kmp_info_t *thread = __kmp_threads[gtid]; KMP_DEBUG_ASSERT(taskdata->td_flags.proxy == TASK_PROXY); KMP_DEBUG_ASSERT(taskdata->td_flags.complete == 1); // top half must run before bottom half // We need to wait to make sure the top half is finished // Spinning here should be ok as this should happen quickly while (KMP_ATOMIC_LD_ACQ(&taskdata->td_incomplete_child_tasks) > 0) ; __kmp_release_deps(gtid, taskdata); __kmp_free_task_and_ancestors(gtid, taskdata, thread); } /*! @ingroup TASKING @param gtid Global Thread ID of encountering thread @param ptask Task which execution is completed Execute the completion of a proxy task from a thread of that is part of the team. Run first and bottom halves directly. */ void __kmpc_proxy_task_completed(kmp_int32 gtid, kmp_task_t *ptask) { KMP_DEBUG_ASSERT(ptask != NULL); kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(ptask); KA_TRACE( 10, ("__kmp_proxy_task_completed(enter): T#%d proxy task %p completing\n", gtid, taskdata)); KMP_DEBUG_ASSERT(taskdata->td_flags.proxy == TASK_PROXY); __kmp_first_top_half_finish_proxy(taskdata); __kmp_second_top_half_finish_proxy(taskdata); __kmp_bottom_half_finish_proxy(gtid, ptask); KA_TRACE(10, ("__kmp_proxy_task_completed(exit): T#%d proxy task %p completing\n", gtid, taskdata)); } /*! @ingroup TASKING @param ptask Task which execution is completed Execute the completion of a proxy task from a thread that could not belong to the team. */ void __kmpc_proxy_task_completed_ooo(kmp_task_t *ptask) { KMP_DEBUG_ASSERT(ptask != NULL); kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(ptask); KA_TRACE( 10, ("__kmp_proxy_task_completed_ooo(enter): proxy task completing ooo %p\n", taskdata)); KMP_DEBUG_ASSERT(taskdata->td_flags.proxy == TASK_PROXY); __kmp_first_top_half_finish_proxy(taskdata); // Enqueue task to complete bottom half completion from a thread within the // corresponding team kmp_team_t *team = taskdata->td_team; kmp_int32 nthreads = team->t.t_nproc; kmp_info_t *thread; // This should be similar to start_k = __kmp_get_random( thread ) % nthreads // but we cannot use __kmp_get_random here kmp_int32 start_k = 0; kmp_int32 pass = 1; kmp_int32 k = start_k; do { // For now we're just linearly trying to find a thread thread = team->t.t_threads[k]; k = (k + 1) % nthreads; // we did a full pass through all the threads if (k == start_k) pass = pass << 1; } while (!__kmp_give_task(thread, k, ptask, pass)); __kmp_second_top_half_finish_proxy(taskdata); KA_TRACE( 10, ("__kmp_proxy_task_completed_ooo(exit): proxy task completing ooo %p\n", taskdata)); } kmp_event_t *__kmpc_task_allow_completion_event(ident_t *loc_ref, int gtid, kmp_task_t *task) { kmp_taskdata_t *td = KMP_TASK_TO_TASKDATA(task); if (td->td_allow_completion_event.type == KMP_EVENT_UNINITIALIZED) { td->td_allow_completion_event.type = KMP_EVENT_ALLOW_COMPLETION; td->td_allow_completion_event.ed.task = task; __kmp_init_tas_lock(&td->td_allow_completion_event.lock); } return &td->td_allow_completion_event; } void __kmp_fulfill_event(kmp_event_t *event) { if (event->type == KMP_EVENT_ALLOW_COMPLETION) { kmp_task_t *ptask = event->ed.task; kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(ptask); bool detached = false; int gtid = __kmp_get_gtid(); // The associated task might have completed or could be completing at this // point. // We need to take the lock to avoid races __kmp_acquire_tas_lock(&event->lock, gtid); if (taskdata->td_flags.proxy == TASK_PROXY) { detached = true; } else { #if OMPT_SUPPORT // The OMPT event must occur under mutual exclusion, // otherwise the tool might access ptask after free if (UNLIKELY(ompt_enabled.enabled)) __ompt_task_finish(ptask, NULL, ompt_task_early_fulfill); #endif } event->type = KMP_EVENT_UNINITIALIZED; __kmp_release_tas_lock(&event->lock, gtid); if (detached) { #if OMPT_SUPPORT // We free ptask afterwards and know the task is finished, // so locking is not necessary if (UNLIKELY(ompt_enabled.enabled)) __ompt_task_finish(ptask, NULL, ompt_task_late_fulfill); #endif // If the task detached complete the proxy task if (gtid >= 0) { kmp_team_t *team = taskdata->td_team; kmp_info_t *thread = __kmp_get_thread(); if (thread->th.th_team == team) { __kmpc_proxy_task_completed(gtid, ptask); return; } } // fallback __kmpc_proxy_task_completed_ooo(ptask); } } } // __kmp_task_dup_alloc: Allocate the taskdata and make a copy of source task // for taskloop // // thread: allocating thread // task_src: pointer to source task to be duplicated // returns: a pointer to the allocated kmp_task_t structure (task). kmp_task_t *__kmp_task_dup_alloc(kmp_info_t *thread, kmp_task_t *task_src) { kmp_task_t *task; kmp_taskdata_t *taskdata; kmp_taskdata_t *taskdata_src = KMP_TASK_TO_TASKDATA(task_src); kmp_taskdata_t *parent_task = taskdata_src->td_parent; // same parent task size_t shareds_offset; size_t task_size; KA_TRACE(10, ("__kmp_task_dup_alloc(enter): Th %p, source task %p\n", thread, task_src)); KMP_DEBUG_ASSERT(taskdata_src->td_flags.proxy == TASK_FULL); // it should not be proxy task KMP_DEBUG_ASSERT(taskdata_src->td_flags.tasktype == TASK_EXPLICIT); task_size = taskdata_src->td_size_alloc; // Allocate a kmp_taskdata_t block and a kmp_task_t block. KA_TRACE(30, ("__kmp_task_dup_alloc: Th %p, malloc size %ld\n", thread, task_size)); #if USE_FAST_MEMORY taskdata = (kmp_taskdata_t *)__kmp_fast_allocate(thread, task_size); #else taskdata = (kmp_taskdata_t *)__kmp_thread_malloc(thread, task_size); #endif /* USE_FAST_MEMORY */ KMP_MEMCPY(taskdata, taskdata_src, task_size); task = KMP_TASKDATA_TO_TASK(taskdata); // Initialize new task (only specific fields not affected by memcpy) taskdata->td_task_id = KMP_GEN_TASK_ID(); if (task->shareds != NULL) { // need setup shareds pointer shareds_offset = (char *)task_src->shareds - (char *)taskdata_src; task->shareds = &((char *)taskdata)[shareds_offset]; KMP_DEBUG_ASSERT((((kmp_uintptr_t)task->shareds) & (sizeof(void *) - 1)) == 0); } taskdata->td_alloc_thread = thread; taskdata->td_parent = parent_task; // task inherits the taskgroup from the parent task taskdata->td_taskgroup = parent_task->td_taskgroup; // tied task needs to initialize the td_last_tied at creation, // untied one does this when it is scheduled for execution if (taskdata->td_flags.tiedness == TASK_TIED) taskdata->td_last_tied = taskdata; // Only need to keep track of child task counts if team parallel and tasking // not serialized if (!(taskdata->td_flags.team_serial || taskdata->td_flags.tasking_ser)) { KMP_ATOMIC_INC(&parent_task->td_incomplete_child_tasks); if (parent_task->td_taskgroup) KMP_ATOMIC_INC(&parent_task->td_taskgroup->count); // Only need to keep track of allocated child tasks for explicit tasks since // implicit not deallocated if (taskdata->td_parent->td_flags.tasktype == TASK_EXPLICIT) KMP_ATOMIC_INC(&taskdata->td_parent->td_allocated_child_tasks); } KA_TRACE(20, ("__kmp_task_dup_alloc(exit): Th %p, created task %p, parent=%p\n", thread, taskdata, taskdata->td_parent)); #if OMPT_SUPPORT if (UNLIKELY(ompt_enabled.enabled)) __ompt_task_init(taskdata, thread->th.th_info.ds.ds_gtid); #endif return task; } // Routine optionally generated by the compiler for setting the lastprivate flag // and calling needed constructors for private/firstprivate objects // (used to form taskloop tasks from pattern task) // Parameters: dest task, src task, lastprivate flag. typedef void (*p_task_dup_t)(kmp_task_t *, kmp_task_t *, kmp_int32); KMP_BUILD_ASSERT(sizeof(long) == 4 || sizeof(long) == 8); // class to encapsulate manipulating loop bounds in a taskloop task. // this abstracts away the Intel vs GOMP taskloop interface for setting/getting // the loop bound variables. class kmp_taskloop_bounds_t { kmp_task_t *task; const kmp_taskdata_t *taskdata; size_t lower_offset; size_t upper_offset; public: kmp_taskloop_bounds_t(kmp_task_t *_task, kmp_uint64 *lb, kmp_uint64 *ub) : task(_task), taskdata(KMP_TASK_TO_TASKDATA(task)), lower_offset((char *)lb - (char *)task), upper_offset((char *)ub - (char *)task) { KMP_DEBUG_ASSERT((char *)lb > (char *)_task); KMP_DEBUG_ASSERT((char *)ub > (char *)_task); } kmp_taskloop_bounds_t(kmp_task_t *_task, const kmp_taskloop_bounds_t &bounds) : task(_task), taskdata(KMP_TASK_TO_TASKDATA(_task)), lower_offset(bounds.lower_offset), upper_offset(bounds.upper_offset) {} size_t get_lower_offset() const { return lower_offset; } size_t get_upper_offset() const { return upper_offset; } kmp_uint64 get_lb() const { kmp_int64 retval; #if defined(KMP_GOMP_COMPAT) // Intel task just returns the lower bound normally if (!taskdata->td_flags.native) { retval = *(kmp_int64 *)((char *)task + lower_offset); } else { // GOMP task has to take into account the sizeof(long) if (taskdata->td_size_loop_bounds == 4) { kmp_int32 *lb = RCAST(kmp_int32 *, task->shareds); retval = (kmp_int64)*lb; } else { kmp_int64 *lb = RCAST(kmp_int64 *, task->shareds); retval = (kmp_int64)*lb; } } #else retval = *(kmp_int64 *)((char *)task + lower_offset); #endif // defined(KMP_GOMP_COMPAT) return retval; } kmp_uint64 get_ub() const { kmp_int64 retval; #if defined(KMP_GOMP_COMPAT) // Intel task just returns the upper bound normally if (!taskdata->td_flags.native) { retval = *(kmp_int64 *)((char *)task + upper_offset); } else { // GOMP task has to take into account the sizeof(long) if (taskdata->td_size_loop_bounds == 4) { kmp_int32 *ub = RCAST(kmp_int32 *, task->shareds) + 1; retval = (kmp_int64)*ub; } else { kmp_int64 *ub = RCAST(kmp_int64 *, task->shareds) + 1; retval = (kmp_int64)*ub; } } #else retval = *(kmp_int64 *)((char *)task + upper_offset); #endif // defined(KMP_GOMP_COMPAT) return retval; } void set_lb(kmp_uint64 lb) { #if defined(KMP_GOMP_COMPAT) // Intel task just sets the lower bound normally if (!taskdata->td_flags.native) { *(kmp_uint64 *)((char *)task + lower_offset) = lb; } else { // GOMP task has to take into account the sizeof(long) if (taskdata->td_size_loop_bounds == 4) { kmp_uint32 *lower = RCAST(kmp_uint32 *, task->shareds); *lower = (kmp_uint32)lb; } else { kmp_uint64 *lower = RCAST(kmp_uint64 *, task->shareds); *lower = (kmp_uint64)lb; } } #else *(kmp_uint64 *)((char *)task + lower_offset) = lb; #endif // defined(KMP_GOMP_COMPAT) } void set_ub(kmp_uint64 ub) { #if defined(KMP_GOMP_COMPAT) // Intel task just sets the upper bound normally if (!taskdata->td_flags.native) { *(kmp_uint64 *)((char *)task + upper_offset) = ub; } else { // GOMP task has to take into account the sizeof(long) if (taskdata->td_size_loop_bounds == 4) { kmp_uint32 *upper = RCAST(kmp_uint32 *, task->shareds) + 1; *upper = (kmp_uint32)ub; } else { kmp_uint64 *upper = RCAST(kmp_uint64 *, task->shareds) + 1; *upper = (kmp_uint64)ub; } } #else *(kmp_uint64 *)((char *)task + upper_offset) = ub; #endif // defined(KMP_GOMP_COMPAT) } }; // __kmp_taskloop_linear: Start tasks of the taskloop linearly // // loc Source location information // gtid Global thread ID // task Pattern task, exposes the loop iteration range // lb Pointer to loop lower bound in task structure // ub Pointer to loop upper bound in task structure // st Loop stride // ub_glob Global upper bound (used for lastprivate check) // num_tasks Number of tasks to execute // grainsize Number of loop iterations per task // extras Number of chunks with grainsize+1 iterations // tc Iterations count // task_dup Tasks duplication routine // codeptr_ra Return address for OMPT events void __kmp_taskloop_linear(ident_t *loc, int gtid, kmp_task_t *task, kmp_uint64 *lb, kmp_uint64 *ub, kmp_int64 st, kmp_uint64 ub_glob, kmp_uint64 num_tasks, kmp_uint64 grainsize, kmp_uint64 extras, kmp_uint64 tc, #if OMPT_SUPPORT void *codeptr_ra, #endif void *task_dup) { KMP_COUNT_BLOCK(OMP_TASKLOOP); KMP_TIME_PARTITIONED_BLOCK(OMP_taskloop_scheduling); p_task_dup_t ptask_dup = (p_task_dup_t)task_dup; // compiler provides global bounds here kmp_taskloop_bounds_t task_bounds(task, lb, ub); kmp_uint64 lower = task_bounds.get_lb(); kmp_uint64 upper = task_bounds.get_ub(); kmp_uint64 i; kmp_info_t *thread = __kmp_threads[gtid]; kmp_taskdata_t *current_task = thread->th.th_current_task; kmp_task_t *next_task; kmp_int32 lastpriv = 0; KMP_DEBUG_ASSERT(tc == num_tasks * grainsize + extras); KMP_DEBUG_ASSERT(num_tasks > extras); KMP_DEBUG_ASSERT(num_tasks > 0); KA_TRACE(20, ("__kmp_taskloop_linear: T#%d: %lld tasks, grainsize %lld, " "extras %lld, i=%lld,%lld(%d)%lld, dup %p\n", gtid, num_tasks, grainsize, extras, lower, upper, ub_glob, st, task_dup)); // Launch num_tasks tasks, assign grainsize iterations each task for (i = 0; i < num_tasks; ++i) { kmp_uint64 chunk_minus_1; if (extras == 0) { chunk_minus_1 = grainsize - 1; } else { chunk_minus_1 = grainsize; --extras; // first extras iterations get bigger chunk (grainsize+1) } upper = lower + st * chunk_minus_1; if (i == num_tasks - 1) { // schedule the last task, set lastprivate flag if needed if (st == 1) { // most common case KMP_DEBUG_ASSERT(upper == *ub); if (upper == ub_glob) lastpriv = 1; } else if (st > 0) { // positive loop stride KMP_DEBUG_ASSERT((kmp_uint64)st > *ub - upper); if ((kmp_uint64)st > ub_glob - upper) lastpriv = 1; } else { // negative loop stride KMP_DEBUG_ASSERT(upper + st < *ub); if (upper - ub_glob < (kmp_uint64)(-st)) lastpriv = 1; } } next_task = __kmp_task_dup_alloc(thread, task); // allocate new task kmp_taskdata_t *next_taskdata = KMP_TASK_TO_TASKDATA(next_task); kmp_taskloop_bounds_t next_task_bounds = kmp_taskloop_bounds_t(next_task, task_bounds); // adjust task-specific bounds next_task_bounds.set_lb(lower); if (next_taskdata->td_flags.native) { next_task_bounds.set_ub(upper + (st > 0 ? 1 : -1)); } else { next_task_bounds.set_ub(upper); } if (ptask_dup != NULL) // set lastprivate flag, construct firstprivates, // etc. ptask_dup(next_task, task, lastpriv); KA_TRACE(40, ("__kmp_taskloop_linear: T#%d; task #%llu: task %p: lower %lld, " "upper %lld stride %lld, (offsets %p %p)\n", gtid, i, next_task, lower, upper, st, next_task_bounds.get_lower_offset(), next_task_bounds.get_upper_offset())); #if OMPT_SUPPORT __kmp_omp_taskloop_task(NULL, gtid, next_task, codeptr_ra); // schedule new task #else __kmp_omp_task(gtid, next_task, true); // schedule new task #endif lower = upper + st; // adjust lower bound for the next iteration } // free the pattern task and exit __kmp_task_start(gtid, task, current_task); // make internal bookkeeping // do not execute the pattern task, just do internal bookkeeping __kmp_task_finish(gtid, task, current_task); } // Structure to keep taskloop parameters for auxiliary task // kept in the shareds of the task structure. typedef struct __taskloop_params { kmp_task_t *task; kmp_uint64 *lb; kmp_uint64 *ub; void *task_dup; kmp_int64 st; kmp_uint64 ub_glob; kmp_uint64 num_tasks; kmp_uint64 grainsize; kmp_uint64 extras; kmp_uint64 tc; kmp_uint64 num_t_min; #if OMPT_SUPPORT void *codeptr_ra; #endif } __taskloop_params_t; void __kmp_taskloop_recur(ident_t *, int, kmp_task_t *, kmp_uint64 *, kmp_uint64 *, kmp_int64, kmp_uint64, kmp_uint64, kmp_uint64, kmp_uint64, kmp_uint64, kmp_uint64, #if OMPT_SUPPORT void *, #endif void *); // Execute part of the taskloop submitted as a task. int __kmp_taskloop_task(int gtid, void *ptask) { __taskloop_params_t *p = (__taskloop_params_t *)((kmp_task_t *)ptask)->shareds; kmp_task_t *task = p->task; kmp_uint64 *lb = p->lb; kmp_uint64 *ub = p->ub; void *task_dup = p->task_dup; // p_task_dup_t ptask_dup = (p_task_dup_t)task_dup; kmp_int64 st = p->st; kmp_uint64 ub_glob = p->ub_glob; kmp_uint64 num_tasks = p->num_tasks; kmp_uint64 grainsize = p->grainsize; kmp_uint64 extras = p->extras; kmp_uint64 tc = p->tc; kmp_uint64 num_t_min = p->num_t_min; #if OMPT_SUPPORT void *codeptr_ra = p->codeptr_ra; #endif #if KMP_DEBUG kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(task); KMP_DEBUG_ASSERT(task != NULL); KA_TRACE(20, ("__kmp_taskloop_task: T#%d, task %p: %lld tasks, grainsize" " %lld, extras %lld, i=%lld,%lld(%d), dup %p\n", gtid, taskdata, num_tasks, grainsize, extras, *lb, *ub, st, task_dup)); #endif KMP_DEBUG_ASSERT(num_tasks * 2 + 1 > num_t_min); if (num_tasks > num_t_min) __kmp_taskloop_recur(NULL, gtid, task, lb, ub, st, ub_glob, num_tasks, grainsize, extras, tc, num_t_min, #if OMPT_SUPPORT codeptr_ra, #endif task_dup); else __kmp_taskloop_linear(NULL, gtid, task, lb, ub, st, ub_glob, num_tasks, grainsize, extras, tc, #if OMPT_SUPPORT codeptr_ra, #endif task_dup); KA_TRACE(40, ("__kmp_taskloop_task(exit): T#%d\n", gtid)); return 0; } // Schedule part of the taskloop as a task, // execute the rest of the taskloop. // // loc Source location information // gtid Global thread ID // task Pattern task, exposes the loop iteration range // lb Pointer to loop lower bound in task structure // ub Pointer to loop upper bound in task structure // st Loop stride // ub_glob Global upper bound (used for lastprivate check) // num_tasks Number of tasks to execute // grainsize Number of loop iterations per task // extras Number of chunks with grainsize+1 iterations // tc Iterations count // num_t_min Threshold to launch tasks recursively // task_dup Tasks duplication routine // codeptr_ra Return address for OMPT events void __kmp_taskloop_recur(ident_t *loc, int gtid, kmp_task_t *task, kmp_uint64 *lb, kmp_uint64 *ub, kmp_int64 st, kmp_uint64 ub_glob, kmp_uint64 num_tasks, kmp_uint64 grainsize, kmp_uint64 extras, kmp_uint64 tc, kmp_uint64 num_t_min, #if OMPT_SUPPORT void *codeptr_ra, #endif void *task_dup) { kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(task); KMP_DEBUG_ASSERT(task != NULL); KMP_DEBUG_ASSERT(num_tasks > num_t_min); KA_TRACE(20, ("__kmp_taskloop_recur: T#%d, task %p: %lld tasks, grainsize" " %lld, extras %lld, i=%lld,%lld(%d), dup %p\n", gtid, taskdata, num_tasks, grainsize, extras, *lb, *ub, st, task_dup)); p_task_dup_t ptask_dup = (p_task_dup_t)task_dup; kmp_uint64 lower = *lb; kmp_info_t *thread = __kmp_threads[gtid]; // kmp_taskdata_t *current_task = thread->th.th_current_task; kmp_task_t *next_task; size_t lower_offset = (char *)lb - (char *)task; // remember offset of lb in the task structure size_t upper_offset = (char *)ub - (char *)task; // remember offset of ub in the task structure KMP_DEBUG_ASSERT(tc == num_tasks * grainsize + extras); KMP_DEBUG_ASSERT(num_tasks > extras); KMP_DEBUG_ASSERT(num_tasks > 0); // split the loop in two halves kmp_uint64 lb1, ub0, tc0, tc1, ext0, ext1; kmp_uint64 gr_size0 = grainsize; kmp_uint64 n_tsk0 = num_tasks >> 1; // num_tasks/2 to execute kmp_uint64 n_tsk1 = num_tasks - n_tsk0; // to schedule as a task if (n_tsk0 <= extras) { gr_size0++; // integrate extras into grainsize ext0 = 0; // no extra iters in 1st half ext1 = extras - n_tsk0; // remaining extras tc0 = gr_size0 * n_tsk0; tc1 = tc - tc0; } else { // n_tsk0 > extras ext1 = 0; // no extra iters in 2nd half ext0 = extras; tc1 = grainsize * n_tsk1; tc0 = tc - tc1; } ub0 = lower + st * (tc0 - 1); lb1 = ub0 + st; // create pattern task for 2nd half of the loop next_task = __kmp_task_dup_alloc(thread, task); // duplicate the task // adjust lower bound (upper bound is not changed) for the 2nd half *(kmp_uint64 *)((char *)next_task + lower_offset) = lb1; if (ptask_dup != NULL) // construct firstprivates, etc. ptask_dup(next_task, task, 0); *ub = ub0; // adjust upper bound for the 1st half // create auxiliary task for 2nd half of the loop // make sure new task has same parent task as the pattern task kmp_taskdata_t *current_task = thread->th.th_current_task; thread->th.th_current_task = taskdata->td_parent; kmp_task_t *new_task = __kmpc_omp_task_alloc(loc, gtid, 1, 3 * sizeof(void *), sizeof(__taskloop_params_t), &__kmp_taskloop_task); // restore current task thread->th.th_current_task = current_task; __taskloop_params_t *p = (__taskloop_params_t *)new_task->shareds; p->task = next_task; p->lb = (kmp_uint64 *)((char *)next_task + lower_offset); p->ub = (kmp_uint64 *)((char *)next_task + upper_offset); p->task_dup = task_dup; p->st = st; p->ub_glob = ub_glob; p->num_tasks = n_tsk1; p->grainsize = grainsize; p->extras = ext1; p->tc = tc1; p->num_t_min = num_t_min; #if OMPT_SUPPORT p->codeptr_ra = codeptr_ra; #endif #if OMPT_SUPPORT // schedule new task with correct return address for OMPT events __kmp_omp_taskloop_task(NULL, gtid, new_task, codeptr_ra); #else __kmp_omp_task(gtid, new_task, true); // schedule new task #endif // execute the 1st half of current subrange if (n_tsk0 > num_t_min) __kmp_taskloop_recur(loc, gtid, task, lb, ub, st, ub_glob, n_tsk0, gr_size0, ext0, tc0, num_t_min, #if OMPT_SUPPORT codeptr_ra, #endif task_dup); else __kmp_taskloop_linear(loc, gtid, task, lb, ub, st, ub_glob, n_tsk0, gr_size0, ext0, tc0, #if OMPT_SUPPORT codeptr_ra, #endif task_dup); KA_TRACE(40, ("__kmpc_taskloop_recur(exit): T#%d\n", gtid)); } /*! @ingroup TASKING @param loc Source location information @param gtid Global thread ID @param task Task structure @param if_val Value of the if clause @param lb Pointer to loop lower bound in task structure @param ub Pointer to loop upper bound in task structure @param st Loop stride @param nogroup Flag, 1 if no taskgroup needs to be added, 0 otherwise @param sched Schedule specified 0/1/2 for none/grainsize/num_tasks @param grainsize Schedule value if specified @param task_dup Tasks duplication routine Execute the taskloop construct. */ void __kmpc_taskloop(ident_t *loc, int gtid, kmp_task_t *task, int if_val, kmp_uint64 *lb, kmp_uint64 *ub, kmp_int64 st, int nogroup, int sched, kmp_uint64 grainsize, void *task_dup) { kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(task); KMP_DEBUG_ASSERT(task != NULL); if (nogroup == 0) { #if OMPT_SUPPORT && OMPT_OPTIONAL OMPT_STORE_RETURN_ADDRESS(gtid); #endif __kmpc_taskgroup(loc, gtid); } // ========================================================================= // calculate loop parameters kmp_taskloop_bounds_t task_bounds(task, lb, ub); kmp_uint64 tc; // compiler provides global bounds here kmp_uint64 lower = task_bounds.get_lb(); kmp_uint64 upper = task_bounds.get_ub(); kmp_uint64 ub_glob = upper; // global upper used to calc lastprivate flag kmp_uint64 num_tasks = 0, extras = 0; kmp_uint64 num_tasks_min = __kmp_taskloop_min_tasks; kmp_info_t *thread = __kmp_threads[gtid]; kmp_taskdata_t *current_task = thread->th.th_current_task; KA_TRACE(20, ("__kmpc_taskloop: T#%d, task %p, lb %lld, ub %lld, st %lld, " "grain %llu(%d), dup %p\n", gtid, taskdata, lower, upper, st, grainsize, sched, task_dup)); // compute trip count if (st == 1) { // most common case tc = upper - lower + 1; } else if (st < 0) { tc = (lower - upper) / (-st) + 1; } else { // st > 0 tc = (upper - lower) / st + 1; } if (tc == 0) { KA_TRACE(20, ("__kmpc_taskloop(exit): T#%d zero-trip loop\n", gtid)); // free the pattern task and exit __kmp_task_start(gtid, task, current_task); // do not execute anything for zero-trip loop __kmp_task_finish(gtid, task, current_task); return; } #if OMPT_SUPPORT && OMPT_OPTIONAL ompt_team_info_t *team_info = __ompt_get_teaminfo(0, NULL); ompt_task_info_t *task_info = __ompt_get_task_info_object(0); if (ompt_enabled.ompt_callback_work) { ompt_callbacks.ompt_callback(ompt_callback_work)( ompt_work_taskloop, ompt_scope_begin, &(team_info->parallel_data), &(task_info->task_data), tc, OMPT_GET_RETURN_ADDRESS(0)); } #endif if (num_tasks_min == 0) // TODO: can we choose better default heuristic? num_tasks_min = KMP_MIN(thread->th.th_team_nproc * 10, INITIAL_TASK_DEQUE_SIZE); // compute num_tasks/grainsize based on the input provided switch (sched) { case 0: // no schedule clause specified, we can choose the default // let's try to schedule (team_size*10) tasks grainsize = thread->th.th_team_nproc * 10; KMP_FALLTHROUGH(); case 2: // num_tasks provided if (grainsize > tc) { num_tasks = tc; // too big num_tasks requested, adjust values grainsize = 1; extras = 0; } else { num_tasks = grainsize; grainsize = tc / num_tasks; extras = tc % num_tasks; } break; case 1: // grainsize provided if (grainsize > tc) { num_tasks = 1; // too big grainsize requested, adjust values grainsize = tc; extras = 0; } else { num_tasks = tc / grainsize; // adjust grainsize for balanced distribution of iterations grainsize = tc / num_tasks; extras = tc % num_tasks; } break; default: KMP_ASSERT2(0, "unknown scheduling of taskloop"); } KMP_DEBUG_ASSERT(tc == num_tasks * grainsize + extras); KMP_DEBUG_ASSERT(num_tasks > extras); KMP_DEBUG_ASSERT(num_tasks > 0); // ========================================================================= // check if clause value first // Also require GOMP_taskloop to reduce to linear (taskdata->td_flags.native) if (if_val == 0) { // if(0) specified, mark task as serial taskdata->td_flags.task_serial = 1; taskdata->td_flags.tiedness = TASK_TIED; // AC: serial task cannot be untied // always start serial tasks linearly __kmp_taskloop_linear(loc, gtid, task, lb, ub, st, ub_glob, num_tasks, grainsize, extras, tc, #if OMPT_SUPPORT OMPT_GET_RETURN_ADDRESS(0), #endif task_dup); // !taskdata->td_flags.native => currently force linear spawning of tasks // for GOMP_taskloop } else if (num_tasks > num_tasks_min && !taskdata->td_flags.native) { KA_TRACE(20, ("__kmpc_taskloop: T#%d, go recursive: tc %llu, #tasks %llu" "(%lld), grain %llu, extras %llu\n", gtid, tc, num_tasks, num_tasks_min, grainsize, extras)); __kmp_taskloop_recur(loc, gtid, task, lb, ub, st, ub_glob, num_tasks, grainsize, extras, tc, num_tasks_min, #if OMPT_SUPPORT OMPT_GET_RETURN_ADDRESS(0), #endif task_dup); } else { KA_TRACE(20, ("__kmpc_taskloop: T#%d, go linear: tc %llu, #tasks %llu" "(%lld), grain %llu, extras %llu\n", gtid, tc, num_tasks, num_tasks_min, grainsize, extras)); __kmp_taskloop_linear(loc, gtid, task, lb, ub, st, ub_glob, num_tasks, grainsize, extras, tc, #if OMPT_SUPPORT OMPT_GET_RETURN_ADDRESS(0), #endif task_dup); } #if OMPT_SUPPORT && OMPT_OPTIONAL if (ompt_enabled.ompt_callback_work) { ompt_callbacks.ompt_callback(ompt_callback_work)( ompt_work_taskloop, ompt_scope_end, &(team_info->parallel_data), &(task_info->task_data), tc, OMPT_GET_RETURN_ADDRESS(0)); } #endif if (nogroup == 0) { #if OMPT_SUPPORT && OMPT_OPTIONAL OMPT_STORE_RETURN_ADDRESS(gtid); #endif __kmpc_end_taskgroup(loc, gtid); } KA_TRACE(20, ("__kmpc_taskloop(exit): T#%d\n", gtid)); }