/* * runqueue.c - a simple task queueing/completion tracking helper * * Copyright (C) 2013 Felix Fietkau * * Permission to use, copy, modify, and/or distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include #include #include "runqueue.h" static void __runqueue_empty_cb(struct uloop_timeout *timeout) { struct runqueue *q = container_of(timeout, struct runqueue, timeout); q->empty_cb(q); } void runqueue_init(struct runqueue *q) { INIT_SAFE_LIST(&q->tasks_active); INIT_SAFE_LIST(&q->tasks_inactive); } static void __runqueue_start_next(struct uloop_timeout *timeout) { struct runqueue *q = container_of(timeout, struct runqueue, timeout); struct runqueue_task *t; do { if (q->stopped) break; if (list_empty(&q->tasks_inactive.list)) break; if (q->max_running_tasks && q->running_tasks >= q->max_running_tasks) break; t = list_first_entry(&q->tasks_inactive.list, struct runqueue_task, list.list); safe_list_del(&t->list); safe_list_add(&t->list, &q->tasks_active); t->running = true; q->running_tasks++; if (t->run_timeout) uloop_timeout_set(&t->timeout, t->run_timeout); t->type->run(q, t); } while (1); if (!q->empty && list_empty(&q->tasks_active.list) && list_empty(&q->tasks_inactive.list)) { q->empty = true; if (q->empty_cb) { q->timeout.cb = __runqueue_empty_cb; uloop_timeout_set(&q->timeout, 1); } } } static void runqueue_start_next(struct runqueue *q) { if (q->empty) return; q->timeout.cb = __runqueue_start_next; uloop_timeout_set(&q->timeout, 1); } static int __runqueue_cancel(void *ctx, struct safe_list *list) { struct runqueue_task *t; t = container_of(list, struct runqueue_task, list); runqueue_task_cancel(t, 0); return 0; } void runqueue_cancel_active(struct runqueue *q) { safe_list_for_each(&q->tasks_active, __runqueue_cancel, NULL); } void runqueue_cancel_pending(struct runqueue *q) { safe_list_for_each(&q->tasks_inactive, __runqueue_cancel, NULL); } void runqueue_cancel(struct runqueue *q) { runqueue_cancel_pending(q); runqueue_cancel_active(q); } void runqueue_kill(struct runqueue *q) { struct runqueue_task *t; while (!list_empty(&q->tasks_active.list)) { t = list_first_entry(&q->tasks_active.list, struct runqueue_task, list.list); runqueue_task_kill(t); } runqueue_cancel_pending(q); uloop_timeout_cancel(&q->timeout); } void runqueue_task_cancel(struct runqueue_task *t, int type) { if (!t->queued) return; if (!t->running) { runqueue_task_complete(t); return; } t->cancelled = true; if (t->cancel_timeout) uloop_timeout_set(&t->timeout, t->cancel_timeout); if (t->type->cancel) t->type->cancel(t->q, t, type); } static void __runqueue_task_timeout(struct uloop_timeout *timeout) { struct runqueue_task *t = container_of(timeout, struct runqueue_task, timeout); if (t->cancelled) runqueue_task_kill(t); else runqueue_task_cancel(t, t->cancel_type); } static void _runqueue_task_add(struct runqueue *q, struct runqueue_task *t, bool running, bool first) { struct safe_list *head; if (t->queued) return; if (!t->type->run && !running) { fprintf(stderr, "BUG: inactive task added without run() callback\n"); return; } if (running) { q->running_tasks++; head = &q->tasks_active; } else { head = &q->tasks_inactive; } t->timeout.cb = __runqueue_task_timeout; t->q = q; if (first) safe_list_add_first(&t->list, head); else safe_list_add(&t->list, head); t->cancelled = false; t->queued = true; t->running = running; q->empty = false; runqueue_start_next(q); } void runqueue_task_add(struct runqueue *q, struct runqueue_task *t, bool running) { _runqueue_task_add(q, t, running, 0); } void runqueue_task_add_first(struct runqueue *q, struct runqueue_task *t, bool running) { _runqueue_task_add(q, t, running, 1); } void runqueue_task_kill(struct runqueue_task *t) { struct runqueue *q = t->q; bool running = t->running; if (!t->queued) return; runqueue_task_complete(t); if (running && t->type->kill) t->type->kill(q, t); runqueue_start_next(q); } void runqueue_stop(struct runqueue *q) { q->stopped = true; } void runqueue_resume(struct runqueue *q) { q->stopped = false; runqueue_start_next(q); } void runqueue_task_complete(struct runqueue_task *t) { struct runqueue *q = t->q; if (!t->queued) return; if (t->running) t->q->running_tasks--; safe_list_del(&t->list); t->queued = false; t->running = false; t->cancelled = false; if (t->complete) t->complete(q, t); runqueue_start_next(t->q); } static void __runqueue_proc_cb(struct uloop_process *p, int ret) { struct runqueue_process *t = container_of(p, struct runqueue_process, proc); runqueue_task_complete(&t->task); } void runqueue_process_cancel_cb(struct runqueue *q, struct runqueue_task *t, int type) { struct runqueue_process *p = container_of(t, struct runqueue_process, task); if (!type) type = SIGTERM; kill(p->proc.pid, type); } void runqueue_process_kill_cb(struct runqueue *q, struct runqueue_task *t) { struct runqueue_process *p = container_of(t, struct runqueue_process, task); uloop_process_delete(&p->proc); kill(p->proc.pid, SIGKILL); } static const struct runqueue_task_type runqueue_proc_type = { .name = "process", .cancel = runqueue_process_cancel_cb, .kill = runqueue_process_kill_cb, }; void runqueue_process_add(struct runqueue *q, struct runqueue_process *p, pid_t pid) { if (p->proc.pending) return; p->proc.pid = pid; p->proc.cb = __runqueue_proc_cb; if (!p->task.type) p->task.type = &runqueue_proc_type; uloop_process_add(&p->proc); if (!p->task.running) runqueue_task_add(q, &p->task, true); }