Utilities/cmlibuv/src/threadpool.c - third_party/cmake - Git at Google

 /* Copyright Joyent, Inc. and other Node contributors. All rights reserved.
  *
  * Permission is hereby granted, free of charge, to any person obtaining a copy
  * of this software and associated documentation files (the "Software"), to
  * deal in the Software without restriction, including without limitation the
  * rights to use, copy, modify, merge, publish, distribute, sublicense, and/or
  * sell copies of the Software, and to permit persons to whom the Software is
  * furnished to do so, subject to the following conditions:
  *
  * The above copyright notice and this permission notice shall be included in
  * all copies or substantial portions of the Software.
  *
  * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
  * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
  * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
  * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
  * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
  * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
  * IN THE SOFTWARE.
  */

 #include "uv-common.h"

 #if !defined(_WIN32)
 # include "unix/internal.h"
 #endif

 #include <stdlib.h>

 #define MAX_THREADPOOL_SIZE 128

 static uv_once_t once = UV_ONCE_INIT;
 static uv_cond_t cond;
 static uv_mutex_t mutex;
 static unsigned int idle_threads;
 static unsigned int slow_io_work_running;
 static unsigned int nthreads;
 static uv_thread_t* threads;
 static uv_thread_t default_threads[4];
 static QUEUE exit_message;
 static QUEUE wq;
 static QUEUE run_slow_work_message;
 static QUEUE slow_io_pending_wq;

 static unsigned int slow_work_thread_threshold(void) {
   return (nthreads + 1) / 2;
 }

 static void uv__cancelled(struct uv__work* w) {
   abort();
 }


 /* To avoid deadlock with uv_cancel() it's crucial that the worker
  * never holds the global mutex and the loop-local mutex at the same time.
  */
 static void worker(void* arg) {
   struct uv__work* w;
   QUEUE* q;
   int is_slow_work;

   uv_sem_post((uv_sem_t*) arg);
   arg = NULL;

   uv_mutex_lock(&mutex);
   for (;;) {
     /* `mutex` should always be locked at this point. */

     /* Keep waiting while either no work is present or only slow I/O
        and we're at the threshold for that. */
     while (QUEUE_EMPTY(&wq) ||
            (QUEUE_HEAD(&wq) == &run_slow_work_message &&
             QUEUE_NEXT(&run_slow_work_message) == &wq &&
             slow_io_work_running >= slow_work_thread_threshold())) {
       idle_threads += 1;
       uv_cond_wait(&cond, &mutex);
       idle_threads -= 1;
     }

     q = QUEUE_HEAD(&wq);
     if (q == &exit_message) {
       uv_cond_signal(&cond);
       uv_mutex_unlock(&mutex);
       break;
     }

     QUEUE_REMOVE(q);
     QUEUE_INIT(q);  /* Signal uv_cancel() that the work req is executing. */

     is_slow_work = 0;
     if (q == &run_slow_work_message) {
       /* If we're at the slow I/O threshold, re-schedule until after all
          other work in the queue is done. */
       if (slow_io_work_running >= slow_work_thread_threshold()) {
         QUEUE_INSERT_TAIL(&wq, q);
         continue;
       }

       /* If we encountered a request to run slow I/O work but there is none
          to run, that means it's cancelled => Start over. */
       if (QUEUE_EMPTY(&slow_io_pending_wq))
         continue;

       is_slow_work = 1;
       slow_io_work_running++;

       q = QUEUE_HEAD(&slow_io_pending_wq);
       QUEUE_REMOVE(q);
       QUEUE_INIT(q);

       /* If there is more slow I/O work, schedule it to be run as well. */
       if (!QUEUE_EMPTY(&slow_io_pending_wq)) {
         QUEUE_INSERT_TAIL(&wq, &run_slow_work_message);
         if (idle_threads > 0)
           uv_cond_signal(&cond);
       }
     }

     uv_mutex_unlock(&mutex);

     w = QUEUE_DATA(q, struct uv__work, wq);
     w->work(w);

     uv_mutex_lock(&w->loop->wq_mutex);
     w->work = NULL;  /* Signal uv_cancel() that the work req is done
                         executing. */
     QUEUE_INSERT_TAIL(&w->loop->wq, &w->wq);
     uv_async_send(&w->loop->wq_async);
     uv_mutex_unlock(&w->loop->wq_mutex);

     /* Lock `mutex` since that is expected at the start of the next
      * iteration. */
     uv_mutex_lock(&mutex);
     if (is_slow_work) {
       /* `slow_io_work_running` is protected by `mutex`. */
       slow_io_work_running--;
     }
   }
 }


 static void post(QUEUE* q, enum uv__work_kind kind) {
   uv_mutex_lock(&mutex);
   if (kind == UV__WORK_SLOW_IO) {
     /* Insert into a separate queue. */
     QUEUE_INSERT_TAIL(&slow_io_pending_wq, q);
     if (!QUEUE_EMPTY(&run_slow_work_message)) {
       /* Running slow I/O tasks is already scheduled => Nothing to do here.
          The worker that runs said other task will schedule this one as well. */
       uv_mutex_unlock(&mutex);
       return;
     }
     q = &run_slow_work_message;
   }

   QUEUE_INSERT_TAIL(&wq, q);
   if (idle_threads > 0)
     uv_cond_signal(&cond);
   uv_mutex_unlock(&mutex);
 }


 #ifndef _WIN32
 UV_DESTRUCTOR(static void cleanup(void)) {
   unsigned int i;

   if (nthreads == 0)
     return;

   post(&exit_message, UV__WORK_CPU);

   for (i = 0; i < nthreads; i++)
     if (uv_thread_join(threads + i))
       abort();

   if (threads != default_threads)
     uv__free(threads);

   uv_mutex_destroy(&mutex);
   uv_cond_destroy(&cond);

   threads = NULL;
   nthreads = 0;
 }
 #endif


 static void init_threads(void) {
   unsigned int i;
   const char* val;
   uv_sem_t sem;

   nthreads = ARRAY_SIZE(default_threads);
   val = getenv("UV_THREADPOOL_SIZE");
   if (val != NULL)
     nthreads = atoi(val);
   if (nthreads == 0)
     nthreads = 1;
   if (nthreads > MAX_THREADPOOL_SIZE)
     nthreads = MAX_THREADPOOL_SIZE;

   threads = default_threads;
   if (nthreads > ARRAY_SIZE(default_threads)) {
     threads = uv__malloc(nthreads * sizeof(threads[0]));
     if (threads == NULL) {
       nthreads = ARRAY_SIZE(default_threads);
       threads = default_threads;
     }
   }

   if (uv_cond_init(&cond))
     abort();

   if (uv_mutex_init(&mutex))
     abort();

   QUEUE_INIT(&wq);
   QUEUE_INIT(&slow_io_pending_wq);
   QUEUE_INIT(&run_slow_work_message);

   if (uv_sem_init(&sem, 0))
     abort();

   for (i = 0; i < nthreads; i++)
     if (uv_thread_create(threads + i, worker, &sem))
       abort();

   for (i = 0; i < nthreads; i++)
     uv_sem_wait(&sem);

   uv_sem_destroy(&sem);
 }


 #ifndef _WIN32
 static void reset_once(void) {
   uv_once_t child_once = UV_ONCE_INIT;
   memcpy(&once, &child_once, sizeof(child_once));
 }
 #endif


 static void init_once(void) {
 #ifndef _WIN32
   /* Re-initialize the threadpool after fork.
    * Note that this discards the global mutex and condition as well
    * as the work queue.
    */
   if (pthread_atfork(NULL, NULL, &reset_once))
     abort();
 #endif
   init_threads();
 }


 void uv__work_submit(uv_loop_t* loop,
                      struct uv__work* w,
                      enum uv__work_kind kind,
                      void (*work)(struct uv__work* w),
                      void (*done)(struct uv__work* w, int status)) {
   uv_once(&once, init_once);
   w->loop = loop;
   w->work = work;
   w->done = done;
   post(&w->wq, kind);
 }


 static int uv__work_cancel(uv_loop_t* loop, uv_req_t* req, struct uv__work* w) {
   int cancelled;

   uv_mutex_lock(&mutex);
   uv_mutex_lock(&w->loop->wq_mutex);

   cancelled = !QUEUE_EMPTY(&w->wq) && w->work != NULL;
   if (cancelled)
     QUEUE_REMOVE(&w->wq);

   uv_mutex_unlock(&w->loop->wq_mutex);
   uv_mutex_unlock(&mutex);

   if (!cancelled)
     return UV_EBUSY;

   w->work = uv__cancelled;
   uv_mutex_lock(&loop->wq_mutex);
   QUEUE_INSERT_TAIL(&loop->wq, &w->wq);
   uv_async_send(&loop->wq_async);
   uv_mutex_unlock(&loop->wq_mutex);

   return 0;
 }


 void uv__work_done(uv_async_t* handle) {
   struct uv__work* w;
   uv_loop_t* loop;
   QUEUE* q;
   QUEUE wq;
   int err;

   loop = container_of(handle, uv_loop_t, wq_async);
   uv_mutex_lock(&loop->wq_mutex);
   QUEUE_MOVE(&loop->wq, &wq);
   uv_mutex_unlock(&loop->wq_mutex);

   while (!QUEUE_EMPTY(&wq)) {
     q = QUEUE_HEAD(&wq);
     QUEUE_REMOVE(q);

     w = container_of(q, struct uv__work, wq);
     err = (w->work == uv__cancelled) ? UV_ECANCELED : 0;
     w->done(w, err);
   }
 }


 static void uv__queue_work(struct uv__work* w) {
   uv_work_t* req = container_of(w, uv_work_t, work_req);

   req->work_cb(req);
 }


 static void uv__queue_done(struct uv__work* w, int err) {
   uv_work_t* req;

   req = container_of(w, uv_work_t, work_req);
   uv__req_unregister(req->loop, req);

   if (req->after_work_cb == NULL)
     return;

   req->after_work_cb(req, err);
 }


 int uv_queue_work(uv_loop_t* loop,
                   uv_work_t* req,
                   uv_work_cb work_cb,
                   uv_after_work_cb after_work_cb) {
   if (work_cb == NULL)
     return UV_EINVAL;

   uv__req_init(loop, req, UV_WORK);
   req->loop = loop;
   req->work_cb = work_cb;
   req->after_work_cb = after_work_cb;
   uv__work_submit(loop,
                   &req->work_req,
                   UV__WORK_CPU,
                   uv__queue_work,
                   uv__queue_done);
   return 0;
 }


 int uv_cancel(uv_req_t* req) {
   struct uv__work* wreq;
   uv_loop_t* loop;

   switch (req->type) {
   case UV_FS:
     loop =  ((uv_fs_t*) req)->loop;
     wreq = &((uv_fs_t*) req)->work_req;
     break;
   case UV_GETADDRINFO:
     loop =  ((uv_getaddrinfo_t*) req)->loop;
     wreq = &((uv_getaddrinfo_t*) req)->work_req;
     break;
   case UV_GETNAMEINFO:
     loop = ((uv_getnameinfo_t*) req)->loop;
     wreq = &((uv_getnameinfo_t*) req)->work_req;
     break;
   case UV_WORK:
     loop =  ((uv_work_t*) req)->loop;
     wreq = &((uv_work_t*) req)->work_req;
     break;
   default:
     return UV_EINVAL;
   }

   return uv__work_cancel(loop, req, wreq);
 }
	/* Copyright Joyent, Inc. and other Node contributors. All rights reserved.
	*
	* Permission is hereby granted, free of charge, to any person obtaining a copy
	* of this software and associated documentation files (the "Software"), to
	* deal in the Software without restriction, including without limitation the
	* rights to use, copy, modify, merge, publish, distribute, sublicense, and/or
	* sell copies of the Software, and to permit persons to whom the Software is
	* furnished to do so, subject to the following conditions:
	*
	* The above copyright notice and this permission notice shall be included in
	* all copies or substantial portions of the Software.
	*
	* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
	* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
	* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
	* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
	* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
	* FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
	* IN THE SOFTWARE.
	*/

	#include "uv-common.h"

	#if !defined(_WIN32)
	# include "unix/internal.h"
	#endif

	#include <stdlib.h>

	#define MAX_THREADPOOL_SIZE 128

	static uv_once_t once = UV_ONCE_INIT;
	static uv_cond_t cond;
	static uv_mutex_t mutex;
	static unsigned int idle_threads;
	static unsigned int slow_io_work_running;
	static unsigned int nthreads;
	static uv_thread_t* threads;
	static uv_thread_t default_threads[4];
	static QUEUE exit_message;
	static QUEUE wq;
	static QUEUE run_slow_work_message;
	static QUEUE slow_io_pending_wq;

	static unsigned int slow_work_thread_threshold(void) {
	return (nthreads + 1) / 2;
	}

	static void uv__cancelled(struct uv__work* w) {
	abort();
	}


	/* To avoid deadlock with uv_cancel() it's crucial that the worker
	* never holds the global mutex and the loop-local mutex at the same time.
	*/
	static void worker(void* arg) {
	struct uv__work* w;
	QUEUE* q;
	int is_slow_work;

	uv_sem_post((uv_sem_t*) arg);
	arg = NULL;

	uv_mutex_lock(&mutex);
	for (;;) {
	/* `mutex` should always be locked at this point. */

	/* Keep waiting while either no work is present or only slow I/O
	and we're at the threshold for that. */
	while (QUEUE_EMPTY(&wq) \|\|
	(QUEUE_HEAD(&wq) == &run_slow_work_message &&
	QUEUE_NEXT(&run_slow_work_message) == &wq &&
	slow_io_work_running >= slow_work_thread_threshold())) {
	idle_threads += 1;
	uv_cond_wait(&cond, &mutex);
	idle_threads -= 1;
	}

	q = QUEUE_HEAD(&wq);
	if (q == &exit_message) {
	uv_cond_signal(&cond);
	uv_mutex_unlock(&mutex);
	break;
	}

	QUEUE_REMOVE(q);
	QUEUE_INIT(q); /* Signal uv_cancel() that the work req is executing. */

	is_slow_work = 0;
	if (q == &run_slow_work_message) {
	/* If we're at the slow I/O threshold, re-schedule until after all
	other work in the queue is done. */
	if (slow_io_work_running >= slow_work_thread_threshold()) {
	QUEUE_INSERT_TAIL(&wq, q);
	continue;
	}

	/* If we encountered a request to run slow I/O work but there is none
	to run, that means it's cancelled => Start over. */
	if (QUEUE_EMPTY(&slow_io_pending_wq))
	continue;

	is_slow_work = 1;
	slow_io_work_running++;

	q = QUEUE_HEAD(&slow_io_pending_wq);
	QUEUE_REMOVE(q);
	QUEUE_INIT(q);

	/* If there is more slow I/O work, schedule it to be run as well. */
	if (!QUEUE_EMPTY(&slow_io_pending_wq)) {
	QUEUE_INSERT_TAIL(&wq, &run_slow_work_message);
	if (idle_threads > 0)
	uv_cond_signal(&cond);
	}
	}

	uv_mutex_unlock(&mutex);

	w = QUEUE_DATA(q, struct uv__work, wq);
	w->work(w);

	uv_mutex_lock(&w->loop->wq_mutex);
	w->work = NULL; /* Signal uv_cancel() that the work req is done
	executing. */
	QUEUE_INSERT_TAIL(&w->loop->wq, &w->wq);
	uv_async_send(&w->loop->wq_async);
	uv_mutex_unlock(&w->loop->wq_mutex);

	/* Lock `mutex` since that is expected at the start of the next
	* iteration. */
	uv_mutex_lock(&mutex);
	if (is_slow_work) {
	/* `slow_io_work_running` is protected by `mutex`. */
	slow_io_work_running--;
	}
	}
	}


	static void post(QUEUE* q, enum uv__work_kind kind) {
	uv_mutex_lock(&mutex);
	if (kind == UV__WORK_SLOW_IO) {
	/* Insert into a separate queue. */
	QUEUE_INSERT_TAIL(&slow_io_pending_wq, q);
	if (!QUEUE_EMPTY(&run_slow_work_message)) {
	/* Running slow I/O tasks is already scheduled => Nothing to do here.
	The worker that runs said other task will schedule this one as well. */
	uv_mutex_unlock(&mutex);
	return;
	}
	q = &run_slow_work_message;
	}

	QUEUE_INSERT_TAIL(&wq, q);
	if (idle_threads > 0)
	uv_cond_signal(&cond);
	uv_mutex_unlock(&mutex);
	}


	#ifndef _WIN32
	UV_DESTRUCTOR(static void cleanup(void)) {
	unsigned int i;

	if (nthreads == 0)
	return;

	post(&exit_message, UV__WORK_CPU);

	for (i = 0; i < nthreads; i++)
	if (uv_thread_join(threads + i))
	abort();

	if (threads != default_threads)
	uv__free(threads);

	uv_mutex_destroy(&mutex);
	uv_cond_destroy(&cond);

	threads = NULL;
	nthreads = 0;
	}
	#endif


	static void init_threads(void) {
	unsigned int i;
	const char* val;
	uv_sem_t sem;

	nthreads = ARRAY_SIZE(default_threads);
	val = getenv("UV_THREADPOOL_SIZE");
	if (val != NULL)
	nthreads = atoi(val);
	if (nthreads == 0)
	nthreads = 1;
	if (nthreads > MAX_THREADPOOL_SIZE)
	nthreads = MAX_THREADPOOL_SIZE;

	threads = default_threads;
	if (nthreads > ARRAY_SIZE(default_threads)) {
	threads = uv__malloc(nthreads * sizeof(threads[0]));
	if (threads == NULL) {
	nthreads = ARRAY_SIZE(default_threads);
	threads = default_threads;
	}
	}

	if (uv_cond_init(&cond))
	abort();

	if (uv_mutex_init(&mutex))
	abort();

	QUEUE_INIT(&wq);
	QUEUE_INIT(&slow_io_pending_wq);
	QUEUE_INIT(&run_slow_work_message);

	if (uv_sem_init(&sem, 0))
	abort();

	for (i = 0; i < nthreads; i++)
	if (uv_thread_create(threads + i, worker, &sem))
	abort();

	for (i = 0; i < nthreads; i++)
	uv_sem_wait(&sem);

	uv_sem_destroy(&sem);
	}


	#ifndef _WIN32
	static void reset_once(void) {
	uv_once_t child_once = UV_ONCE_INIT;
	memcpy(&once, &child_once, sizeof(child_once));
	}
	#endif


	static void init_once(void) {
	#ifndef _WIN32
	/* Re-initialize the threadpool after fork.
	* Note that this discards the global mutex and condition as well
	* as the work queue.
	*/
	if (pthread_atfork(NULL, NULL, &reset_once))
	abort();
	#endif
	init_threads();
	}


	void uv__work_submit(uv_loop_t* loop,
	struct uv__work* w,
	enum uv__work_kind kind,
	void (work)(struct uv__work w),
	void (done)(struct uv__work w, int status)) {
	uv_once(&once, init_once);
	w->loop = loop;
	w->work = work;
	w->done = done;
	post(&w->wq, kind);
	}


	static int uv__work_cancel(uv_loop_t* loop, uv_req_t* req, struct uv__work* w) {
	int cancelled;

	uv_mutex_lock(&mutex);
	uv_mutex_lock(&w->loop->wq_mutex);

	cancelled = !QUEUE_EMPTY(&w->wq) && w->work != NULL;
	if (cancelled)
	QUEUE_REMOVE(&w->wq);

	uv_mutex_unlock(&w->loop->wq_mutex);
	uv_mutex_unlock(&mutex);

	if (!cancelled)
	return UV_EBUSY;

	w->work = uv__cancelled;
	uv_mutex_lock(&loop->wq_mutex);
	QUEUE_INSERT_TAIL(&loop->wq, &w->wq);
	uv_async_send(&loop->wq_async);
	uv_mutex_unlock(&loop->wq_mutex);

	return 0;
	}


	void uv__work_done(uv_async_t* handle) {
	struct uv__work* w;
	uv_loop_t* loop;
	QUEUE* q;
	QUEUE wq;
	int err;

	loop = container_of(handle, uv_loop_t, wq_async);
	uv_mutex_lock(&loop->wq_mutex);
	QUEUE_MOVE(&loop->wq, &wq);
	uv_mutex_unlock(&loop->wq_mutex);

	while (!QUEUE_EMPTY(&wq)) {
	q = QUEUE_HEAD(&wq);
	QUEUE_REMOVE(q);

	w = container_of(q, struct uv__work, wq);
	err = (w->work == uv__cancelled) ? UV_ECANCELED : 0;
	w->done(w, err);
	}
	}


	static void uv__queue_work(struct uv__work* w) {
	uv_work_t* req = container_of(w, uv_work_t, work_req);

	req->work_cb(req);
	}


	static void uv__queue_done(struct uv__work* w, int err) {
	uv_work_t* req;

	req = container_of(w, uv_work_t, work_req);
	uv__req_unregister(req->loop, req);

	if (req->after_work_cb == NULL)
	return;

	req->after_work_cb(req, err);
	}


	int uv_queue_work(uv_loop_t* loop,
	uv_work_t* req,
	uv_work_cb work_cb,
	uv_after_work_cb after_work_cb) {
	if (work_cb == NULL)
	return UV_EINVAL;

	uv__req_init(loop, req, UV_WORK);
	req->loop = loop;
	req->work_cb = work_cb;
	req->after_work_cb = after_work_cb;
	uv__work_submit(loop,
	&req->work_req,
	UV__WORK_CPU,
	uv__queue_work,
	uv__queue_done);
	return 0;
	}


	int uv_cancel(uv_req_t* req) {
	struct uv__work* wreq;
	uv_loop_t* loop;

	switch (req->type) {
	case UV_FS:
	loop = ((uv_fs_t*) req)->loop;
	wreq = &((uv_fs_t*) req)->work_req;
	break;
	case UV_GETADDRINFO:
	loop = ((uv_getaddrinfo_t*) req)->loop;
	wreq = &((uv_getaddrinfo_t*) req)->work_req;
	break;
	case UV_GETNAMEINFO:
	loop = ((uv_getnameinfo_t*) req)->loop;
	wreq = &((uv_getnameinfo_t*) req)->work_req;
	break;
	case UV_WORK:
	loop = ((uv_work_t*) req)->loop;
	wreq = &((uv_work_t*) req)->work_req;
	break;
	default:
	return UV_EINVAL;
	}

	return uv__work_cancel(loop, req, wreq);
	}