third_party/grpc/include/grpc/support/sync.h - bazel - Git at Google

 /*
  *
  * Copyright 2015 gRPC authors.
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *     http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  *
  */

 #ifndef GRPC_SUPPORT_SYNC_H
 #define GRPC_SUPPORT_SYNC_H

 #include <grpc/support/port_platform.h>

 #include <grpc/impl/codegen/gpr_types.h> /* for gpr_timespec */
 #include <grpc/impl/codegen/sync.h>

 #ifdef __cplusplus
 extern "C" {
 #endif

 /** --- Mutex interface ---

    At most one thread may hold an exclusive lock on a mutex at any given time.
    Actions taken by a thread that holds a mutex exclusively happen after
    actions taken by all previous holders of the mutex.  Variables of type
    gpr_mu are uninitialized when first declared.  */

 /** Initialize *mu.  Requires:  *mu uninitialized.  */
 GPRAPI void gpr_mu_init(gpr_mu* mu);

 /** Cause *mu no longer to be initialized, freeing any memory in use.  Requires:
  *mu initialized; no other concurrent operation on *mu.  */
 GPRAPI void gpr_mu_destroy(gpr_mu* mu);

 /** Wait until no thread has a lock on *mu, cause the calling thread to own an
    exclusive lock on *mu, then return.  May block indefinitely or crash if the
    calling thread has a lock on *mu.  Requires:  *mu initialized.  */
 GPRAPI void gpr_mu_lock(gpr_mu* mu);

 /** Release an exclusive lock on *mu held by the calling thread.  Requires:  *mu
    initialized; the calling thread holds an exclusive lock on *mu.  */
 GPRAPI void gpr_mu_unlock(gpr_mu* mu);

 /** Without blocking, attempt to acquire an exclusive lock on *mu for the
    calling thread, then return non-zero iff success.  Fail, if any thread holds
    the lock; succeeds with high probability if no thread holds the lock.
    Requires:  *mu initialized.  */
 GPRAPI int gpr_mu_trylock(gpr_mu* mu);

 /** --- Condition variable interface ---

    A while-loop should be used with gpr_cv_wait() when waiting for conditions
    to become true.  See the example below.  Variables of type gpr_cv are
    uninitialized when first declared.  */

 /** Initialize *cv.  Requires:  *cv uninitialized.  */
 GPRAPI void gpr_cv_init(gpr_cv* cv);

 /** Cause *cv no longer to be initialized, freeing any memory in use.  Requires:
  *cv initialized; no other concurrent operation on *cv.*/
 GPRAPI void gpr_cv_destroy(gpr_cv* cv);

 /** Atomically release *mu and wait on *cv.  When the calling thread is woken
    from *cv or the deadline abs_deadline is exceeded, execute gpr_mu_lock(mu)
    and return whether the deadline was exceeded.  Use
    abs_deadline==gpr_inf_future for no deadline.  abs_deadline can be either
    an absolute deadline, or a GPR_TIMESPAN.  May return even when not
    woken explicitly.  Requires:  *mu and *cv initialized; the calling thread
    holds an exclusive lock on *mu.  */
 GPRAPI int gpr_cv_wait(gpr_cv* cv, gpr_mu* mu, gpr_timespec abs_deadline);

 /** If any threads are waiting on *cv, wake at least one.
    Clients may treat this as an optimization of gpr_cv_broadcast()
    for use in the case where waking more than one waiter is not useful.
    Requires:  *cv initialized.  */
 GPRAPI void gpr_cv_signal(gpr_cv* cv);

 /** Wake all threads waiting on *cv.  Requires:  *cv initialized.  */
 GPRAPI void gpr_cv_broadcast(gpr_cv* cv);

 /** --- One-time initialization ---

    gpr_once must be declared with static storage class, and initialized with
    GPR_ONCE_INIT.  e.g.,
      static gpr_once once_var = GPR_ONCE_INIT;     */

 /** Ensure that (*init_routine)() has been called exactly once (for the
    specified gpr_once instance) and then return.
    If multiple threads call gpr_once() on the same gpr_once instance, one of
    them will call (*init_routine)(), and the others will block until that call
    finishes.*/
 GPRAPI void gpr_once_init(gpr_once* once, void (*init_routine)(void));

 /** --- One-time event notification ---

   These operations act on a gpr_event, which should be initialized with
   gpr_ev_init(), or with GPR_EVENT_INIT if static, e.g.,
        static gpr_event event_var = GPR_EVENT_INIT;
   It requires no destruction.  */

 /** Initialize *ev. */
 GPRAPI void gpr_event_init(gpr_event* ev);

 /** Set *ev so that gpr_event_get() and gpr_event_wait() will return value.
    Requires:  *ev initialized; value != NULL; no prior or concurrent calls to
    gpr_event_set(ev, ...) since initialization.  */
 GPRAPI void gpr_event_set(gpr_event* ev, void* value);

 /** Return the value set by gpr_event_set(ev, ...), or NULL if no such call has
    completed.  If the result is non-NULL, all operations that occurred prior to
    the gpr_event_set(ev, ...) set will be visible after this call returns.
    Requires:  *ev initialized.  This operation is faster than acquiring a mutex
    on most platforms.  */
 GPRAPI void* gpr_event_get(gpr_event* ev);

 /** Wait until *ev is set by gpr_event_set(ev, ...), or abs_deadline is
    exceeded, then return gpr_event_get(ev).  Requires:  *ev initialized.  Use
    abs_deadline==gpr_inf_future for no deadline.  When the event has been
    signalled before the call, this operation is faster than acquiring a mutex
    on most platforms.  */
 GPRAPI void* gpr_event_wait(gpr_event* ev, gpr_timespec abs_deadline);

 /** --- Reference counting ---

    These calls act on the type gpr_refcount.  It requires no destruction.  */

 /** Initialize *r to value n.  */
 GPRAPI void gpr_ref_init(gpr_refcount* r, int n);

 /** Increment the reference count *r.  Requires *r initialized. */
 GPRAPI void gpr_ref(gpr_refcount* r);

 /** Increment the reference count *r.  Requires *r initialized.
    Crashes if refcount is zero */
 GPRAPI void gpr_ref_non_zero(gpr_refcount* r);

 /** Increment the reference count *r by n.  Requires *r initialized, n > 0. */
 GPRAPI void gpr_refn(gpr_refcount* r, int n);

 /** Decrement the reference count *r and return non-zero iff it has reached
    zero. .  Requires *r initialized. */
 GPRAPI int gpr_unref(gpr_refcount* r);

 /** Return non-zero iff the reference count of *r is one, and thus is owned
    by exactly one object. */
 GPRAPI int gpr_ref_is_unique(gpr_refcount* r);

 /** --- Stats counters ---

    These calls act on the integral type gpr_stats_counter.  It requires no
    destruction.  Static instances may be initialized with
        gpr_stats_counter c = GPR_STATS_INIT;
    Beware:  These operations do not imply memory barriers.  Do not use them to
    synchronize other events.  */

 /** Initialize *c to the value n. */
 GPRAPI void gpr_stats_init(gpr_stats_counter* c, intptr_t n);

 /** *c += inc.  Requires: *c initialized. */
 GPRAPI void gpr_stats_inc(gpr_stats_counter* c, intptr_t inc);

 /** Return *c.  Requires: *c initialized. */
 GPRAPI intptr_t gpr_stats_read(const gpr_stats_counter* c);

 /** ==================Example use of interface===================
    A producer-consumer queue of up to N integers,
    illustrating the use of the calls in this interface. */
 #if 0

 #define N 4

    typedef struct queue {
      gpr_cv non_empty;  /* Signalled when length becomes non-zero. */
      gpr_cv non_full;   /* Signalled when length becomes non-N. */
      gpr_mu mu;         /* Protects all fields below.
                             (That is, except during initialization or
                             destruction, the fields below should be accessed
                             only by a thread that holds mu.) */
      int head;           /* Index of head of queue 0..N-1. */
      int length;         /* Number of valid elements in queue 0..N. */
      int elem[N];        /* elem[head .. head+length-1] are queue elements. */
    } queue;

    /* Initialize *q. */
    void queue_init(queue *q) {
      gpr_mu_init(&q->mu);
      gpr_cv_init(&q->non_empty);
      gpr_cv_init(&q->non_full);
      q->head = 0;
      q->length = 0;
    }

    /* Free storage associated with *q. */
    void queue_destroy(queue *q) {
      gpr_mu_destroy(&q->mu);
      gpr_cv_destroy(&q->non_empty);
      gpr_cv_destroy(&q->non_full);
    }

    /* Wait until there is room in *q, then append x to *q. */
    void queue_append(queue *q, int x) {
      gpr_mu_lock(&q->mu);
      /* To wait for a predicate without a deadline, loop on the negation of the
         predicate, and use gpr_cv_wait(..., gpr_inf_future) inside the loop
         to release the lock, wait, and reacquire on each iteration.  Code that
         makes the condition true should use gpr_cv_broadcast() on the
         corresponding condition variable.  The predicate must be on state
         protected by the lock.  */
      while (q->length == N) {
        gpr_cv_wait(&q->non_full, &q->mu, gpr_inf_future);
      }
      if (q->length == 0) {  /* Wake threads blocked in queue_remove(). */
        /* It's normal to use gpr_cv_broadcast() or gpr_signal() while
           holding the lock. */
        gpr_cv_broadcast(&q->non_empty);
      }
      q->elem[(q->head + q->length) % N] = x;
      q->length++;
      gpr_mu_unlock(&q->mu);
    }

    /* If it can be done without blocking, append x to *q and return non-zero.
       Otherwise return 0. */
    int queue_try_append(queue *q, int x) {
      int result = 0;
      if (gpr_mu_trylock(&q->mu)) {
        if (q->length != N) {
          if (q->length == 0) {  /* Wake threads blocked in queue_remove(). */
            gpr_cv_broadcast(&q->non_empty);
          }
          q->elem[(q->head + q->length) % N] = x;
          q->length++;
          result = 1;
        }
        gpr_mu_unlock(&q->mu);
      }
      return result;
    }

    /* Wait until the *q is non-empty or deadline abs_deadline passes.  If the
       queue is non-empty, remove its head entry, place it in *head, and return
       non-zero.  Otherwise return 0.  */
    int queue_remove(queue *q, int *head, gpr_timespec abs_deadline) {
      int result = 0;
      gpr_mu_lock(&q->mu);
      /* To wait for a predicate with a deadline, loop on the negation of the
         predicate or until gpr_cv_wait() returns true.  Code that makes
         the condition true should use gpr_cv_broadcast() on the corresponding
         condition variable.  The predicate must be on state protected by the
         lock. */
      while (q->length == 0 &&
             !gpr_cv_wait(&q->non_empty, &q->mu, abs_deadline)) {
      }
      if (q->length != 0) {    /* Queue is non-empty. */
        result = 1;
        if (q->length == N) {  /* Wake threads blocked in queue_append(). */
          gpr_cv_broadcast(&q->non_full);
        }
        *head = q->elem[q->head];
        q->head = (q->head + 1) % N;
        q->length--;
      } /* else deadline exceeded */
      gpr_mu_unlock(&q->mu);
      return result;
    }
 #endif /* 0 */

 #ifdef __cplusplus
 }  // extern "C"
 #endif

 #endif /* GRPC_SUPPORT_SYNC_H */
	/*
	*
	* Copyright 2015 gRPC authors.
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*
	*/

	#ifndef GRPC_SUPPORT_SYNC_H
	#define GRPC_SUPPORT_SYNC_H

	#include <grpc/support/port_platform.h>

	#include <grpc/impl/codegen/gpr_types.h> /* for gpr_timespec */
	#include <grpc/impl/codegen/sync.h>

	#ifdef __cplusplus
	extern "C" {
	#endif

	/** --- Mutex interface ---

	At most one thread may hold an exclusive lock on a mutex at any given time.
	Actions taken by a thread that holds a mutex exclusively happen after
	actions taken by all previous holders of the mutex. Variables of type
	gpr_mu are uninitialized when first declared. */

	/** Initialize mu. Requires: mu uninitialized. */
	GPRAPI void gpr_mu_init(gpr_mu* mu);

	/** Cause *mu no longer to be initialized, freeing any memory in use. Requires:
	mu initialized; no other concurrent operation on mu. */
	GPRAPI void gpr_mu_destroy(gpr_mu* mu);

	/** Wait until no thread has a lock on *mu, cause the calling thread to own an
	exclusive lock on *mu, then return. May block indefinitely or crash if the
	calling thread has a lock on mu. Requires: mu initialized. */
	GPRAPI void gpr_mu_lock(gpr_mu* mu);

	/** Release an exclusive lock on mu held by the calling thread. Requires: mu
	initialized; the calling thread holds an exclusive lock on mu. /
	GPRAPI void gpr_mu_unlock(gpr_mu* mu);

	/** Without blocking, attempt to acquire an exclusive lock on *mu for the
	calling thread, then return non-zero iff success. Fail, if any thread holds
	the lock; succeeds with high probability if no thread holds the lock.
	Requires: mu initialized. /
	GPRAPI int gpr_mu_trylock(gpr_mu* mu);

	/** --- Condition variable interface ---

	A while-loop should be used with gpr_cv_wait() when waiting for conditions
	to become true. See the example below. Variables of type gpr_cv are
	uninitialized when first declared. */

	/** Initialize cv. Requires: cv uninitialized. */
	GPRAPI void gpr_cv_init(gpr_cv* cv);

	/** Cause *cv no longer to be initialized, freeing any memory in use. Requires:
	cv initialized; no other concurrent operation on cv.*/
	GPRAPI void gpr_cv_destroy(gpr_cv* cv);

	/** Atomically release mu and wait on cv. When the calling thread is woken
	from *cv or the deadline abs_deadline is exceeded, execute gpr_mu_lock(mu)
	and return whether the deadline was exceeded. Use
	abs_deadline==gpr_inf_future for no deadline. abs_deadline can be either
	an absolute deadline, or a GPR_TIMESPAN. May return even when not
	woken explicitly. Requires: mu and cv initialized; the calling thread
	holds an exclusive lock on mu. /
	GPRAPI int gpr_cv_wait(gpr_cv* cv, gpr_mu* mu, gpr_timespec abs_deadline);

	/** If any threads are waiting on *cv, wake at least one.
	Clients may treat this as an optimization of gpr_cv_broadcast()
	for use in the case where waking more than one waiter is not useful.
	Requires: cv initialized. /
	GPRAPI void gpr_cv_signal(gpr_cv* cv);

	/** Wake all threads waiting on cv. Requires: cv initialized. */
	GPRAPI void gpr_cv_broadcast(gpr_cv* cv);

	/** --- One-time initialization ---

	gpr_once must be declared with static storage class, and initialized with
	GPR_ONCE_INIT. e.g.,
	static gpr_once once_var = GPR_ONCE_INIT; */

	/** Ensure that (*init_routine)() has been called exactly once (for the
	specified gpr_once instance) and then return.
	If multiple threads call gpr_once() on the same gpr_once instance, one of
	them will call (*init_routine)(), and the others will block until that call
	finishes.*/
	GPRAPI void gpr_once_init(gpr_once* once, void (*init_routine)(void));

	/** --- One-time event notification ---

	These operations act on a gpr_event, which should be initialized with
	gpr_ev_init(), or with GPR_EVENT_INIT if static, e.g.,
	static gpr_event event_var = GPR_EVENT_INIT;
	It requires no destruction. */

	/** Initialize ev. /
	GPRAPI void gpr_event_init(gpr_event* ev);

	/** Set *ev so that gpr_event_get() and gpr_event_wait() will return value.
	Requires: *ev initialized; value != NULL; no prior or concurrent calls to
	gpr_event_set(ev, ...) since initialization. */
	GPRAPI void gpr_event_set(gpr_event* ev, void* value);

	/** Return the value set by gpr_event_set(ev, ...), or NULL if no such call has
	completed. If the result is non-NULL, all operations that occurred prior to
	the gpr_event_set(ev, ...) set will be visible after this call returns.
	Requires: *ev initialized. This operation is faster than acquiring a mutex
	on most platforms. */
	GPRAPI void* gpr_event_get(gpr_event* ev);

	/** Wait until *ev is set by gpr_event_set(ev, ...), or abs_deadline is
	exceeded, then return gpr_event_get(ev). Requires: *ev initialized. Use
	abs_deadline==gpr_inf_future for no deadline. When the event has been
	signalled before the call, this operation is faster than acquiring a mutex
	on most platforms. */
	GPRAPI void* gpr_event_wait(gpr_event* ev, gpr_timespec abs_deadline);

	/** --- Reference counting ---

	These calls act on the type gpr_refcount. It requires no destruction. */

	/** Initialize r to value n. /
	GPRAPI void gpr_ref_init(gpr_refcount* r, int n);

	/** Increment the reference count r. Requires r initialized. */
	GPRAPI void gpr_ref(gpr_refcount* r);

	/** Increment the reference count r. Requires r initialized.
	Crashes if refcount is zero */
	GPRAPI void gpr_ref_non_zero(gpr_refcount* r);

	/** Increment the reference count r by n. Requires r initialized, n > 0. */
	GPRAPI void gpr_refn(gpr_refcount* r, int n);

	/** Decrement the reference count *r and return non-zero iff it has reached
	zero. . Requires r initialized. /
	GPRAPI int gpr_unref(gpr_refcount* r);

	/** Return non-zero iff the reference count of *r is one, and thus is owned
	by exactly one object. */
	GPRAPI int gpr_ref_is_unique(gpr_refcount* r);

	/** --- Stats counters ---

	These calls act on the integral type gpr_stats_counter. It requires no
	destruction. Static instances may be initialized with
	gpr_stats_counter c = GPR_STATS_INIT;
	Beware: These operations do not imply memory barriers. Do not use them to
	synchronize other events. */

	/** Initialize c to the value n. /
	GPRAPI void gpr_stats_init(gpr_stats_counter* c, intptr_t n);

	/** c += inc. Requires: c initialized. */
	GPRAPI void gpr_stats_inc(gpr_stats_counter* c, intptr_t inc);

	/** Return c. Requires: c initialized. */
	GPRAPI intptr_t gpr_stats_read(const gpr_stats_counter* c);

	/** ==================Example use of interface===================
	A producer-consumer queue of up to N integers,
	illustrating the use of the calls in this interface. */
	#if 0

	#define N 4

	typedef struct queue {
	gpr_cv non_empty; /* Signalled when length becomes non-zero. */
	gpr_cv non_full; /* Signalled when length becomes non-N. */
	gpr_mu mu; /* Protects all fields below.
	(That is, except during initialization or
	destruction, the fields below should be accessed
	only by a thread that holds mu.) */
	int head; /* Index of head of queue 0..N-1. */
	int length; /* Number of valid elements in queue 0..N. */
	int elem[N]; /* elem[head .. head+length-1] are queue elements. */
	} queue;

	/* Initialize q. /
	void queue_init(queue *q) {
	gpr_mu_init(&q->mu);
	gpr_cv_init(&q->non_empty);
	gpr_cv_init(&q->non_full);
	q->head = 0;
	q->length = 0;
	}

	/* Free storage associated with q. /
	void queue_destroy(queue *q) {
	gpr_mu_destroy(&q->mu);
	gpr_cv_destroy(&q->non_empty);
	gpr_cv_destroy(&q->non_full);
	}

	/* Wait until there is room in q, then append x to q. */
	void queue_append(queue *q, int x) {
	gpr_mu_lock(&q->mu);
	/* To wait for a predicate without a deadline, loop on the negation of the
	predicate, and use gpr_cv_wait(..., gpr_inf_future) inside the loop
	to release the lock, wait, and reacquire on each iteration. Code that
	makes the condition true should use gpr_cv_broadcast() on the
	corresponding condition variable. The predicate must be on state
	protected by the lock. */
	while (q->length == N) {
	gpr_cv_wait(&q->non_full, &q->mu, gpr_inf_future);
	}
	if (q->length == 0) { /* Wake threads blocked in queue_remove(). */
	/* It's normal to use gpr_cv_broadcast() or gpr_signal() while
	holding the lock. */
	gpr_cv_broadcast(&q->non_empty);
	}
	q->elem[(q->head + q->length) % N] = x;
	q->length++;
	gpr_mu_unlock(&q->mu);
	}

	/* If it can be done without blocking, append x to *q and return non-zero.
	Otherwise return 0. */
	int queue_try_append(queue *q, int x) {
	int result = 0;
	if (gpr_mu_trylock(&q->mu)) {
	if (q->length != N) {
	if (q->length == 0) { /* Wake threads blocked in queue_remove(). */
	gpr_cv_broadcast(&q->non_empty);
	}
	q->elem[(q->head + q->length) % N] = x;
	q->length++;
	result = 1;
	}
	gpr_mu_unlock(&q->mu);
	}
	return result;
	}

	/* Wait until the *q is non-empty or deadline abs_deadline passes. If the
	queue is non-empty, remove its head entry, place it in *head, and return
	non-zero. Otherwise return 0. */
	int queue_remove(queue q, int head, gpr_timespec abs_deadline) {
	int result = 0;
	gpr_mu_lock(&q->mu);
	/* To wait for a predicate with a deadline, loop on the negation of the
	predicate or until gpr_cv_wait() returns true. Code that makes
	the condition true should use gpr_cv_broadcast() on the corresponding
	condition variable. The predicate must be on state protected by the
	lock. */
	while (q->length == 0 &&
	!gpr_cv_wait(&q->non_empty, &q->mu, abs_deadline)) {
	}
	if (q->length != 0) { /* Queue is non-empty. */
	result = 1;
	if (q->length == N) { /* Wake threads blocked in queue_append(). */
	gpr_cv_broadcast(&q->non_full);
	}
	*head = q->elem[q->head];
	q->head = (q->head + 1) % N;
	q->length--;
	} /* else deadline exceeded */
	gpr_mu_unlock(&q->mu);
	return result;
	}
	#endif /* 0 */

	#ifdef __cplusplus
	} // extern "C"
	#endif

	#endif /* GRPC_SUPPORT_SYNC_H */