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491 lines
16 KiB
C
491 lines
16 KiB
C
/* Copyright (C) 2015-2023 Free Software Foundation, Inc.
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Contributed by Aldy Hernandez <aldyh@redhat.com>.
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This file is part of the GNU Offloading and Multi Processing Library
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(libgomp).
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Libgomp is free software; you can redistribute it and/or modify it
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under the terms of the GNU General Public License as published by
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the Free Software Foundation; either version 3, or (at your option)
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any later version.
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Libgomp is distributed in the hope that it will be useful, but WITHOUT ANY
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WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
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FOR A PARTICULAR PURPOSE. See the GNU General Public License for
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more details.
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Under Section 7 of GPL version 3, you are granted additional
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permissions described in the GCC Runtime Library Exception, version
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3.1, as published by the Free Software Foundation.
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You should have received a copy of the GNU General Public License and
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a copy of the GCC Runtime Library Exception along with this program;
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see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
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<http://www.gnu.org/licenses/>. */
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/* Header file for a priority queue of GOMP tasks. */
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/* ?? Perhaps all the priority_tree_* functions are complex and rare
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enough to go out-of-line and be moved to priority_queue.c. ?? */
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#ifndef _PRIORITY_QUEUE_H_
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#define _PRIORITY_QUEUE_H_
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/* One task. */
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struct priority_node
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{
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/* Next and previous chains in a circular doubly linked list for
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tasks within this task's priority. */
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struct priority_node *next, *prev;
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};
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/* All tasks within the same priority. */
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struct priority_list
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{
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/* Priority of the tasks in this set. */
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int priority;
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/* Tasks. */
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struct priority_node *tasks;
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/* This points to the last of the higher priority WAITING tasks.
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Remember that for the children queue, we have:
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parent_depends_on WAITING tasks.
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!parent_depends_on WAITING tasks.
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TIED tasks.
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This is a pointer to the last of the parent_depends_on WAITING
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tasks which are essentially, higher priority items within their
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priority. */
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struct priority_node *last_parent_depends_on;
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};
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/* Another splay tree instantiation, for priority_list's. */
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typedef struct prio_splay_tree_node_s *prio_splay_tree_node;
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typedef struct prio_splay_tree_s *prio_splay_tree;
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typedef struct prio_splay_tree_key_s *prio_splay_tree_key;
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struct prio_splay_tree_key_s {
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/* This structure must only containing a priority_list, as we cast
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prio_splay_tree_key to priority_list throughout. */
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struct priority_list l;
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};
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#define splay_tree_prefix prio
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#include "splay-tree.h"
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/* The entry point into a priority queue of tasks.
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There are two alternate implementations with which to store tasks:
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as a balanced tree of sorts, or as a simple list of tasks. If
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there are only priority-0 items (ROOT is NULL), we use the simple
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list, otherwise (ROOT is non-NULL) we use the tree. */
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struct priority_queue
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{
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/* If t.root != NULL, this is a splay tree of priority_lists to hold
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all tasks. This is only used if multiple priorities are in play,
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otherwise we use the priority_list `l' below to hold all
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(priority-0) tasks. */
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struct prio_splay_tree_s t;
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/* If T above is NULL, only priority-0 items exist, so keep them
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in a simple list. */
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struct priority_list l;
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};
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enum priority_insert_type {
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/* Insert at the beginning of a priority list. */
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PRIORITY_INSERT_BEGIN,
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/* Insert at the end of a priority list. */
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PRIORITY_INSERT_END
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};
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/* Used to determine in which queue a given priority node belongs in.
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See pnode field of gomp_task. */
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enum priority_queue_type
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{
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PQ_TEAM, /* Node belongs in gomp_team's task_queue. */
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PQ_CHILDREN, /* Node belongs in parent's children_queue. */
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PQ_TASKGROUP, /* Node belongs in taskgroup->taskgroup_queue. */
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PQ_IGNORED = 999
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};
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typedef bool (*priority_queue_predicate) (struct gomp_task *);
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/* Priority queue implementation prototypes. */
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extern bool priority_queue_task_in_queue_p (enum priority_queue_type,
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struct priority_queue *,
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struct gomp_task *);
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extern void priority_queue_dump (enum priority_queue_type,
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struct priority_queue *);
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extern void priority_queue_verify (enum priority_queue_type,
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struct priority_queue *, bool);
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extern struct gomp_task *priority_queue_find (enum priority_queue_type,
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struct priority_queue *,
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priority_queue_predicate);
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extern void priority_tree_remove (enum priority_queue_type,
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struct priority_queue *,
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struct priority_node *);
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extern struct gomp_task *priority_tree_next_task (enum priority_queue_type,
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struct priority_queue *,
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enum priority_queue_type,
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struct priority_queue *,
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bool *);
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/* Return TRUE if there is more than one priority in HEAD. This is
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used throughout to to choose between the fast path (priority 0 only
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items) and a world with multiple priorities. */
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static inline bool
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priority_queue_multi_p (struct priority_queue *head)
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{
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return __builtin_expect (head->t.root != NULL, 0);
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}
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/* Initialize a priority queue. */
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static inline void
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priority_queue_init (struct priority_queue *head)
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{
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head->t.root = NULL;
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/* To save a few microseconds, we don't initialize head->l.priority
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to 0 here. It is implied that priority will be 0 if head->t.root
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== NULL.
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priority_tree_insert() will fix this when we encounter multiple
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priorities. */
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head->l.tasks = NULL;
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head->l.last_parent_depends_on = NULL;
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}
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static inline void
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priority_queue_free (struct priority_queue *head)
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{
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/* There's nothing to do, as tasks were freed as they were removed
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in priority_queue_remove. */
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}
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/* Forward declarations. */
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static inline size_t priority_queue_offset (enum priority_queue_type);
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static inline struct gomp_task *priority_node_to_task
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(enum priority_queue_type,
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struct priority_node *);
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static inline struct priority_node *task_to_priority_node
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(enum priority_queue_type,
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struct gomp_task *);
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/* Return TRUE if priority queue HEAD is empty.
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MODEL IS MEMMODEL_ACQUIRE if we should use an acquire atomic to
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read from the root of the queue, otherwise MEMMODEL_RELAXED if we
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should use a plain load. */
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static inline _Bool
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priority_queue_empty_p (struct priority_queue *head, enum memmodel model)
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{
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/* Note: The acquire barriers on the loads here synchronize with
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the write of a NULL in gomp_task_run_post_remove_parent. It is
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not necessary that we synchronize with other non-NULL writes at
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this point, but we must ensure that all writes to memory by a
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child thread task work function are seen before we exit from
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GOMP_taskwait. */
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if (priority_queue_multi_p (head))
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{
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if (model == MEMMODEL_ACQUIRE)
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return __atomic_load_n (&head->t.root, MEMMODEL_ACQUIRE) == NULL;
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return head->t.root == NULL;
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}
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if (model == MEMMODEL_ACQUIRE)
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return __atomic_load_n (&head->l.tasks, MEMMODEL_ACQUIRE) == NULL;
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return head->l.tasks == NULL;
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}
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/* Look for a given PRIORITY in HEAD. Return it if found, otherwise
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return NULL. This only applies to the tree variant in HEAD. There
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is no point in searching for priorities in HEAD->L. */
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static inline struct priority_list *
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priority_queue_lookup_priority (struct priority_queue *head, int priority)
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{
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if (head->t.root == NULL)
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return NULL;
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struct prio_splay_tree_key_s k;
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k.l.priority = priority;
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return (struct priority_list *)
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prio_splay_tree_lookup (&head->t, &k);
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}
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/* Insert task in DATA, with PRIORITY, in the priority list in LIST.
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LIST contains items of type TYPE.
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If POS is PRIORITY_INSERT_BEGIN, the new task is inserted at the
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top of its respective priority. If POS is PRIORITY_INSERT_END, the
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task is inserted at the end of its priority.
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If ADJUST_PARENT_DEPENDS_ON is TRUE, LIST is a children queue, and
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we must keep track of higher and lower priority WAITING tasks by
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keeping the queue's last_parent_depends_on field accurate. This
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only applies to the children queue, and the caller must ensure LIST
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is a children queue in this case.
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If ADJUST_PARENT_DEPENDS_ON is TRUE, TASK_IS_PARENT_DEPENDS_ON is
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set to the task's parent_depends_on field. If
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ADJUST_PARENT_DEPENDS_ON is FALSE, this field is irrelevant.
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Return the new priority_node. */
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static inline void
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priority_list_insert (enum priority_queue_type type,
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struct priority_list *list,
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struct gomp_task *task,
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int priority,
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enum priority_insert_type pos,
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bool adjust_parent_depends_on,
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bool task_is_parent_depends_on)
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{
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struct priority_node *node = task_to_priority_node (type, task);
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if (list->tasks)
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{
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/* If we are keeping track of higher/lower priority items,
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but this is a lower priority WAITING task
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(parent_depends_on != NULL), put it after all ready to
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run tasks. See the comment in
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priority_queue_upgrade_task for a visual on how tasks
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should be organized. */
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if (adjust_parent_depends_on
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&& pos == PRIORITY_INSERT_BEGIN
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&& list->last_parent_depends_on
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&& !task_is_parent_depends_on)
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{
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struct priority_node *last_parent_depends_on
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= list->last_parent_depends_on;
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node->next = last_parent_depends_on->next;
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node->prev = last_parent_depends_on;
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}
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/* Otherwise, put it at the top/bottom of the queue. */
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else
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{
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node->next = list->tasks;
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node->prev = list->tasks->prev;
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if (pos == PRIORITY_INSERT_BEGIN)
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list->tasks = node;
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}
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node->next->prev = node;
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node->prev->next = node;
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}
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else
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{
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node->next = node;
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node->prev = node;
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list->tasks = node;
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}
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if (adjust_parent_depends_on
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&& list->last_parent_depends_on == NULL
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&& task_is_parent_depends_on)
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list->last_parent_depends_on = node;
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}
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/* Tree version of priority_list_insert. */
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static inline void
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priority_tree_insert (enum priority_queue_type type,
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struct priority_queue *head,
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struct gomp_task *task,
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int priority,
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enum priority_insert_type pos,
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bool adjust_parent_depends_on,
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bool task_is_parent_depends_on)
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{
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if (__builtin_expect (head->t.root == NULL, 0))
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{
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/* The first time around, transfer any priority 0 items to the
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tree. */
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if (head->l.tasks != NULL)
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{
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prio_splay_tree_node k = gomp_malloc (sizeof (*k));
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k->left = NULL;
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k->right = NULL;
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k->key.l.priority = 0;
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k->key.l.tasks = head->l.tasks;
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k->key.l.last_parent_depends_on = head->l.last_parent_depends_on;
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prio_splay_tree_insert (&head->t, k);
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head->l.tasks = NULL;
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}
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}
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struct priority_list *list
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= priority_queue_lookup_priority (head, priority);
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if (!list)
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{
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prio_splay_tree_node k = gomp_malloc (sizeof (*k));
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k->left = NULL;
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k->right = NULL;
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k->key.l.priority = priority;
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k->key.l.tasks = NULL;
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k->key.l.last_parent_depends_on = NULL;
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prio_splay_tree_insert (&head->t, k);
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list = &k->key.l;
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}
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priority_list_insert (type, list, task, priority, pos,
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adjust_parent_depends_on,
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task_is_parent_depends_on);
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}
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/* Generic version of priority_*_insert. */
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static inline void
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priority_queue_insert (enum priority_queue_type type,
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struct priority_queue *head,
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struct gomp_task *task,
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int priority,
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enum priority_insert_type pos,
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bool adjust_parent_depends_on,
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bool task_is_parent_depends_on)
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{
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#if _LIBGOMP_CHECKING_
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if (priority_queue_task_in_queue_p (type, head, task))
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gomp_fatal ("Attempt to insert existing task %p", task);
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#endif
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if (priority_queue_multi_p (head) || __builtin_expect (priority > 0, 0))
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priority_tree_insert (type, head, task, priority, pos,
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adjust_parent_depends_on,
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task_is_parent_depends_on);
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else
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priority_list_insert (type, &head->l, task, priority, pos,
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adjust_parent_depends_on,
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task_is_parent_depends_on);
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}
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/* If multiple priorities are in play, return the highest priority
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task from within Q1 and Q2, while giving preference to tasks from
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Q1. If the returned task is chosen from Q1, *Q1_CHOSEN_P is set to
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TRUE, otherwise it is set to FALSE.
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If multiple priorities are not in play (only 0 priorities are
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available), the next task is chosen exclusively from Q1.
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As a special case, Q2 can be NULL, in which case, we just choose
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the highest priority WAITING task in Q1. This is an optimization
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to speed up looking through only one queue.
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We assume Q1 has at least one item. */
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static inline struct gomp_task *
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priority_queue_next_task (enum priority_queue_type t1,
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struct priority_queue *q1,
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enum priority_queue_type t2,
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struct priority_queue *q2,
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bool *q1_chosen_p)
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{
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#if _LIBGOMP_CHECKING_
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if (priority_queue_empty_p (q1, MEMMODEL_RELAXED))
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gomp_fatal ("priority_queue_next_task: Q1 is empty");
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#endif
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if (priority_queue_multi_p (q1))
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{
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struct gomp_task *t
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= priority_tree_next_task (t1, q1, t2, q2, q1_chosen_p);
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/* If T is NULL, there are no WAITING tasks in Q1. In which
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case, return any old (non-waiting) task which will cause the
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caller to do the right thing when checking T->KIND ==
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GOMP_TASK_WAITING. */
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if (!t)
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{
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#if _LIBGOMP_CHECKING_
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if (*q1_chosen_p == false)
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gomp_fatal ("priority_queue_next_task inconsistency");
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#endif
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return priority_node_to_task (t1, q1->t.root->key.l.tasks);
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}
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return t;
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}
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else
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{
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*q1_chosen_p = true;
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return priority_node_to_task (t1, q1->l.tasks);
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}
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}
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/* Remove NODE from LIST.
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If we are removing the one and only item in the list, and MODEL is
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MEMMODEL_RELEASE, use an atomic release to clear the list.
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If the list becomes empty after the remove, return TRUE. */
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static inline bool
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priority_list_remove (struct priority_list *list,
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struct priority_node *node,
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enum memmodel model)
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{
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bool empty = false;
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node->prev->next = node->next;
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node->next->prev = node->prev;
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if (list->tasks == node)
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{
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if (node->next != node)
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list->tasks = node->next;
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else
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{
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/* We access task->children in GOMP_taskwait outside of
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the task lock mutex region, so need a release barrier
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here to ensure memory written by child_task->fn above
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is flushed before the NULL is written. */
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if (model == MEMMODEL_RELEASE)
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__atomic_store_n (&list->tasks, NULL, MEMMODEL_RELEASE);
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else
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list->tasks = NULL;
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empty = true;
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goto remove_out;
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}
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}
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remove_out:
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#if _LIBGOMP_CHECKING_
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memset (node, 0xaf, sizeof (*node));
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#endif
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return empty;
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}
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/* This is the generic version of priority_list_remove.
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Remove NODE from priority queue HEAD. HEAD contains tasks of type TYPE.
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If we are removing the one and only item in the priority queue and
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MODEL is MEMMODEL_RELEASE, use an atomic release to clear the queue.
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If the queue becomes empty after the remove, return TRUE. */
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static inline bool
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priority_queue_remove (enum priority_queue_type type,
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struct priority_queue *head,
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struct gomp_task *task,
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enum memmodel model)
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{
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#if _LIBGOMP_CHECKING_
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if (!priority_queue_task_in_queue_p (type, head, task))
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gomp_fatal ("Attempt to remove missing task %p", task);
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#endif
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if (priority_queue_multi_p (head))
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{
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priority_tree_remove (type, head, task_to_priority_node (type, task));
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if (head->t.root == NULL)
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{
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if (model == MEMMODEL_RELEASE)
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/* Errr, we store NULL twice, the alternative would be to
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use an atomic release directly in the splay tree
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routines. Worth it? */
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__atomic_store_n (&head->t.root, NULL, MEMMODEL_RELEASE);
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return true;
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}
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return false;
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}
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else
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return priority_list_remove (&head->l,
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task_to_priority_node (type, task), model);
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}
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#endif /* _PRIORITY_QUEUE_H_ */
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