llvm-gcc-4.2/boehm-gc/specific.c - llvm-archive - Git at Google

 /*
  * Copyright (c) 2000 by Hewlett-Packard Company.  All rights reserved.
  *
  * THIS MATERIAL IS PROVIDED AS IS, WITH ABSOLUTELY NO WARRANTY EXPRESSED
  * OR IMPLIED.  ANY USE IS AT YOUR OWN RISK.
  *
  * Permission is hereby granted to use or copy this program
  * for any purpose,  provided the above notices are retained on all copies.
  * Permission to modify the code and to distribute modified code is granted,
  * provided the above notices are retained, and a notice that the code was
  * modified is included with the above copyright notice.
  */

 #include "private/gc_priv.h" /* For GC_compare_and_exchange, GC_memory_barrier */

 #if defined(GC_LINUX_THREADS)

 #include "private/specific.h"

 static tse invalid_tse = {INVALID_QTID, 0, 0, INVALID_THREADID};
 			/* A thread-specific data entry which will never	*/
 			/* appear valid to a reader.  Used to fill in empty	*/
 			/* cache entries to avoid a check for 0.		*/

 int PREFIXED(key_create) (tsd ** key_ptr, void (* destructor)(void *)) {
     int i;
     tsd * result = (tsd *)MALLOC_CLEAR(sizeof (tsd));

     /* A quick alignment check, since we need atomic stores */
       GC_ASSERT((unsigned long)(&invalid_tse.next) % sizeof(tse *) == 0);
     if (0 == result) return ENOMEM;
     pthread_mutex_init(&(result -> lock), NULL);
     for (i = 0; i < TS_CACHE_SIZE; ++i) {
 	result -> cache[i] = &invalid_tse;
     }
 #   ifdef GC_ASSERTIONS
       for (i = 0; i < TS_HASH_SIZE; ++i) {
 	GC_ASSERT(result -> hash[i] == 0);
       }
 #   endif
     *key_ptr = result;
     return 0;
 }

 int PREFIXED(setspecific) (tsd * key, void * value) {
     pthread_t self = pthread_self();
     int hash_val = HASH(self);
     volatile tse * entry = (volatile tse *)MALLOC_CLEAR(sizeof (tse));

     GC_ASSERT(self != INVALID_THREADID);
     if (0 == entry) return ENOMEM;
     pthread_mutex_lock(&(key -> lock));
     /* Could easily check for an existing entry here.	*/
     entry -> next = key -> hash[hash_val];
     entry -> thread = self;
     entry -> value = value;
     GC_ASSERT(entry -> qtid == INVALID_QTID);
     /* There can only be one writer at a time, but this needs to be	*/
     /* atomic with respect to concurrent readers.			*/
     *(volatile tse **)(key -> hash + hash_val) = entry;
     pthread_mutex_unlock(&(key -> lock));
     return 0;
 }

 /* Remove thread-specific data for this thread.  Should be called on	*/
 /* thread exit.								*/
 void PREFIXED(remove_specific) (tsd * key) {
     pthread_t self = pthread_self();
     unsigned hash_val = HASH(self);
     tse *entry;
     tse **link = key -> hash + hash_val;

     pthread_mutex_lock(&(key -> lock));
     entry = *link;
     while (entry != NULL && entry -> thread != self) {
 	link = &(entry -> next);
         entry = *link;
     }
     /* Invalidate qtid field, since qtids may be reused, and a later 	*/
     /* cache lookup could otherwise find this entry.			*/
         entry -> qtid = INVALID_QTID;
     if (entry != NULL) {
 	*link = entry -> next;
 	/* Atomic! concurrent accesses still work.	*/
 	/* They must, since readers don't lock.		*/
 	/* We shouldn't need a volatile access here,	*/
 	/* since both this and the preceding write 	*/
 	/* should become visible no later than		*/
 	/* the pthread_mutex_unlock() call.		*/
     }
     /* If we wanted to deallocate the entry, we'd first have to clear 	*/
     /* any cache entries pointing to it.  That probably requires	*/
     /* additional synchronization, since we can't prevent a concurrent 	*/
     /* cache lookup, which should still be examining deallocated memory.*/
     /* This can only happen if the concurrent access is from another	*/
     /* thread, and hence has missed the cache, but still...		*/

     /* With GC, we're done, since the pointers from the cache will 	*/
     /* be overwritten, all local pointers to the entries will be	*/
     /* dropped, and the entry will then be reclaimed.			*/
     pthread_mutex_unlock(&(key -> lock));
 }

 /* Note that even the slow path doesn't lock.	*/
 void *  PREFIXED(slow_getspecific) (tsd * key, unsigned long qtid,
 				    tse * volatile * cache_ptr) {
     pthread_t self = pthread_self();
     unsigned hash_val = HASH(self);
     tse *entry = key -> hash[hash_val];

     GC_ASSERT(qtid != INVALID_QTID);
     while (entry != NULL && entry -> thread != self) {
 	entry = entry -> next;
     }
     if (entry == NULL) return NULL;
     /* Set cache_entry.		*/
         entry -> qtid = qtid;
 		/* It's safe to do this asynchronously.  Either value 	*/
 		/* is safe, though may produce spurious misses.		*/
 		/* We're replacing one qtid with another one for the	*/
 		/* same thread.						*/
 	*cache_ptr = entry;
 		/* Again this is safe since pointer assignments are 	*/
 		/* presumed atomic, and either pointer is valid.	*/
     return entry -> value;
 }

 #endif /* GC_LINUX_THREADS */
	/*
	* Copyright (c) 2000 by Hewlett-Packard Company. All rights reserved.
	*
	* THIS MATERIAL IS PROVIDED AS IS, WITH ABSOLUTELY NO WARRANTY EXPRESSED
	* OR IMPLIED. ANY USE IS AT YOUR OWN RISK.
	*
	* Permission is hereby granted to use or copy this program
	* for any purpose, provided the above notices are retained on all copies.
	* Permission to modify the code and to distribute modified code is granted,
	* provided the above notices are retained, and a notice that the code was
	* modified is included with the above copyright notice.
	*/

	#include "private/gc_priv.h" /* For GC_compare_and_exchange, GC_memory_barrier */

	#if defined(GC_LINUX_THREADS)

	#include "private/specific.h"

	static tse invalid_tse = {INVALID_QTID, 0, 0, INVALID_THREADID};
	/* A thread-specific data entry which will never */
	/* appear valid to a reader. Used to fill in empty */
	/* cache entries to avoid a check for 0. */

	int PREFIXED(key_create) (tsd ** key_ptr, void (* destructor)(void *)) {
	int i;
	tsd * result = (tsd *)MALLOC_CLEAR(sizeof (tsd));

	/* A quick alignment check, since we need atomic stores */
	GC_ASSERT((unsigned long)(&invalid_tse.next) % sizeof(tse *) == 0);
	if (0 == result) return ENOMEM;
	pthread_mutex_init(&(result -> lock), NULL);
	for (i = 0; i < TS_CACHE_SIZE; ++i) {
	result -> cache[i] = &invalid_tse;
	}
	# ifdef GC_ASSERTIONS
	for (i = 0; i < TS_HASH_SIZE; ++i) {
	GC_ASSERT(result -> hash[i] == 0);
	}
	# endif
	*key_ptr = result;
	return 0;
	}

	int PREFIXED(setspecific) (tsd * key, void * value) {
	pthread_t self = pthread_self();
	int hash_val = HASH(self);
	volatile tse * entry = (volatile tse *)MALLOC_CLEAR(sizeof (tse));

	GC_ASSERT(self != INVALID_THREADID);
	if (0 == entry) return ENOMEM;
	pthread_mutex_lock(&(key -> lock));
	/* Could easily check for an existing entry here. */
	entry -> next = key -> hash[hash_val];
	entry -> thread = self;
	entry -> value = value;
	GC_ASSERT(entry -> qtid == INVALID_QTID);
	/* There can only be one writer at a time, but this needs to be */
	/* atomic with respect to concurrent readers. */
	(volatile tse *)(key -> hash + hash_val) = entry;
	pthread_mutex_unlock(&(key -> lock));
	return 0;
	}

	/* Remove thread-specific data for this thread. Should be called on */
	/* thread exit. */
	void PREFIXED(remove_specific) (tsd * key) {
	pthread_t self = pthread_self();
	unsigned hash_val = HASH(self);
	tse *entry;
	tse **link = key -> hash + hash_val;

	pthread_mutex_lock(&(key -> lock));
	entry = *link;
	while (entry != NULL && entry -> thread != self) {
	link = &(entry -> next);
	entry = *link;
	}
	/* Invalidate qtid field, since qtids may be reused, and a later */
	/* cache lookup could otherwise find this entry. */
	entry -> qtid = INVALID_QTID;
	if (entry != NULL) {
	*link = entry -> next;
	/* Atomic! concurrent accesses still work. */
	/* They must, since readers don't lock. */
	/* We shouldn't need a volatile access here, */
	/* since both this and the preceding write */
	/* should become visible no later than */
	/* the pthread_mutex_unlock() call. */
	}
	/* If we wanted to deallocate the entry, we'd first have to clear */
	/* any cache entries pointing to it. That probably requires */
	/* additional synchronization, since we can't prevent a concurrent */
	/* cache lookup, which should still be examining deallocated memory.*/
	/* This can only happen if the concurrent access is from another */
	/* thread, and hence has missed the cache, but still... */

	/* With GC, we're done, since the pointers from the cache will */
	/* be overwritten, all local pointers to the entries will be */
	/* dropped, and the entry will then be reclaimed. */
	pthread_mutex_unlock(&(key -> lock));
	}

	/* Note that even the slow path doesn't lock. */
	void * PREFIXED(slow_getspecific) (tsd * key, unsigned long qtid,
	tse * volatile * cache_ptr) {
	pthread_t self = pthread_self();
	unsigned hash_val = HASH(self);
	tse *entry = key -> hash[hash_val];

	GC_ASSERT(qtid != INVALID_QTID);
	while (entry != NULL && entry -> thread != self) {
	entry = entry -> next;
	}
	if (entry == NULL) return NULL;
	/* Set cache_entry. */
	entry -> qtid = qtid;
	/* It's safe to do this asynchronously. Either value */
	/* is safe, though may produce spurious misses. */
	/* We're replacing one qtid with another one for the */
	/* same thread. */
	*cache_ptr = entry;
	/* Again this is safe since pointer assignments are */
	/* presumed atomic, and either pointer is valid. */
	return entry -> value;
	}

	#endif /* GC_LINUX_THREADS */