libc/bionic/pthread_key.cpp - platform/bionic - Git at Google

 /*
  * Copyright (C) 2008 The Android Open Source Project
  * All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions
  * are met:
  *  * Redistributions of source code must retain the above copyright
  *    notice, this list of conditions and the following disclaimer.
  *  * Redistributions in binary form must reproduce the above copyright
  *    notice, this list of conditions and the following disclaimer in
  *    the documentation and/or other materials provided with the
  *    distribution.
  *
  * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
  * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
  * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
  * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
  * COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
  * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
  * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
  * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
  * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
  * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
  * SUCH DAMAGE.
  */

 #include <pthread.h>

 #include "bionic_tls.h"
 #include "pthread_internal.h"

 /* A technical note regarding our thread-local-storage (TLS) implementation:
  *
  * There can be up to BIONIC_TLS_SLOTS independent TLS keys in a given process,
  * The keys below TLS_SLOT_FIRST_USER_SLOT are reserved for Bionic to hold
  * special thread-specific variables like errno or a pointer to
  * the current thread's descriptor. These entries cannot be accessed through
  * pthread_getspecific() / pthread_setspecific() or pthread_key_delete()
  *
  * The 'tls_map_t' type defined below implements a shared global map of
  * currently created/allocated TLS keys and the destructors associated
  * with them.
  *
  * The global TLS map simply contains a bitmap of allocated keys, and
  * an array of destructors.
  *
  * Each thread has a TLS area that is a simple array of BIONIC_TLS_SLOTS void*
  * pointers. the TLS area of the main thread is stack-allocated in
  * __libc_init_common, while the TLS area of other threads is placed at
  * the top of their stack in pthread_create.
  *
  * When pthread_key_delete() is called it will erase the key's bitmap bit
  * and its destructor, and will also clear the key data in the TLS area of
  * all created threads. As mandated by Posix, it is the responsibility of
  * the caller of pthread_key_delete() to properly reclaim the objects that
  * were pointed to by these data fields (either before or after the call).
  */

 #define TLSMAP_BITS       32
 #define TLSMAP_WORDS      ((BIONIC_TLS_SLOTS+TLSMAP_BITS-1)/TLSMAP_BITS)
 #define TLSMAP_WORD(m,k)  (m).map[(k)/TLSMAP_BITS]
 #define TLSMAP_MASK(k)    (1U << ((k)&(TLSMAP_BITS-1)))

 static inline bool IsValidUserKey(pthread_key_t key) {
   return (key >= TLS_SLOT_FIRST_USER_SLOT && key < BIONIC_TLS_SLOTS);
 }

 typedef void (*key_destructor_t)(void*);

 struct tls_map_t {
   bool is_initialized;

   /* bitmap of allocated keys */
   uint32_t map[TLSMAP_WORDS];

   key_destructor_t key_destructors[BIONIC_TLS_SLOTS];
 };

 class ScopedTlsMapAccess {
  public:
   ScopedTlsMapAccess() {
     Lock();

     // If this is the first time the TLS map has been accessed,
     // mark the slots belonging to well-known keys as being in use.
     // This isn't currently necessary because the well-known keys
     // can only be accessed directly by bionic itself, do not have
     // destructors, and all the functions that touch the TLS map
     // start after the maximum well-known slot.
     if (!s_tls_map_.is_initialized) {
       for (pthread_key_t key = 0; key < TLS_SLOT_FIRST_USER_SLOT; ++key) {
         SetInUse(key, NULL);
       }
       s_tls_map_.is_initialized = true;
     }
   }

   ~ScopedTlsMapAccess() {
     Unlock();
   }

   int CreateKey(pthread_key_t* result, void (*key_destructor)(void*)) {
     // Take the first unallocated key.
     for (int key = 0; key < BIONIC_TLS_SLOTS; ++key) {
       if (!IsInUse(key)) {
         SetInUse(key, key_destructor);
         *result = key;
         return 0;
       }
     }

     // We hit PTHREAD_KEYS_MAX. POSIX says EAGAIN for this case.
     return EAGAIN;
   }

   void DeleteKey(pthread_key_t key) {
     TLSMAP_WORD(s_tls_map_, key) &= ~TLSMAP_MASK(key);
     s_tls_map_.key_destructors[key] = NULL;
   }

   bool IsInUse(pthread_key_t key) {
     return (TLSMAP_WORD(s_tls_map_, key) & TLSMAP_MASK(key)) != 0;
   }

   void SetInUse(pthread_key_t key, void (*key_destructor)(void*)) {
     TLSMAP_WORD(s_tls_map_, key) |= TLSMAP_MASK(key);
     s_tls_map_.key_destructors[key] = key_destructor;
   }

   // Called from pthread_exit() to remove all TLS key data
   // from this thread's TLS area. This must call the destructor of all keys
   // that have a non-NULL data value and a non-NULL destructor.
   void CleanAll() {
     void** tls = (void**)__get_tls();

     // Because destructors can do funky things like deleting/creating other
     // keys, we need to implement this in a loop.
     for (int rounds = PTHREAD_DESTRUCTOR_ITERATIONS; rounds > 0; --rounds) {
       size_t called_destructor_count = 0;
       for (int key = 0; key < BIONIC_TLS_SLOTS; ++key) {
         if (IsInUse(key)) {
           void* data = tls[key];
           void (*key_destructor)(void*) = s_tls_map_.key_destructors[key];

           if (data != NULL && key_destructor != NULL) {
             // we need to clear the key data now, this will prevent the
             // destructor (or a later one) from seeing the old value if
             // it calls pthread_getspecific() for some odd reason

             // we do not do this if 'key_destructor == NULL' just in case another
             // destructor function might be responsible for manually
             // releasing the corresponding data.
             tls[key] = NULL;

             // because the destructor is free to call pthread_key_create
             // and/or pthread_key_delete, we need to temporarily unlock
             // the TLS map
             Unlock();
             (*key_destructor)(data);
             Lock();
             ++called_destructor_count;
           }
         }
       }

       // If we didn't call any destructors, there is no need to check the TLS data again.
       if (called_destructor_count == 0) {
         break;
       }
     }
   }

  private:
   static tls_map_t s_tls_map_;
   static pthread_mutex_t s_tls_map_lock_;

   void Lock() {
     pthread_mutex_lock(&s_tls_map_lock_);
   }

   void Unlock() {
     pthread_mutex_unlock(&s_tls_map_lock_);
   }
 };

 __LIBC_HIDDEN__ tls_map_t ScopedTlsMapAccess::s_tls_map_;
 __LIBC_HIDDEN__ pthread_mutex_t ScopedTlsMapAccess::s_tls_map_lock_;

 __LIBC_HIDDEN__ void pthread_key_clean_all() {
   ScopedTlsMapAccess tls_map;
   tls_map.CleanAll();
 }

 int pthread_key_create(pthread_key_t* key, void (*key_destructor)(void*)) {
   ScopedTlsMapAccess tls_map;
   return tls_map.CreateKey(key, key_destructor);
 }

 // Deletes a pthread_key_t. note that the standard mandates that this does
 // not call the destructors for non-NULL key values. Instead, it is the
 // responsibility of the caller to properly dispose of the corresponding data
 // and resources, using any means it finds suitable.
 int pthread_key_delete(pthread_key_t key) {
   ScopedTlsMapAccess tls_map;

   if (!IsValidUserKey(key) || !tls_map.IsInUse(key)) {
     return EINVAL;
   }

   // Clear value in all threads.
   pthread_mutex_lock(&gThreadListLock);
   for (pthread_internal_t*  t = gThreadList; t != NULL; t = t->next) {
     // Skip zombie threads. They don't have a valid TLS area any more.
     // Similarly, it is possible to have t->tls == NULL for threads that
     // were just recently created through pthread_create() but whose
     // startup trampoline (__thread_entry) hasn't been run yet by the
     // scheduler. t->tls will also be NULL after a thread's stack has been
     // unmapped but before the ongoing pthread_join() is finished.
     if ((t->attr.flags & PTHREAD_ATTR_FLAG_ZOMBIE) || t->tls == NULL) {
       continue;
     }

     t->tls[key] = NULL;
   }
   tls_map.DeleteKey(key);

   pthread_mutex_unlock(&gThreadListLock);
   return 0;
 }

 void* pthread_getspecific(pthread_key_t key) {
   if (!IsValidUserKey(key)) {
     return NULL;
   }

   // For performance reasons, we do not lock/unlock the global TLS map
   // to check that the key is properly allocated. If the key was not
   // allocated, the value read from the TLS should always be NULL
   // due to pthread_key_delete() clearing the values for all threads.
   return (void *)(((unsigned *)__get_tls())[key]);
 }

 int pthread_setspecific(pthread_key_t key, const void* ptr) {
   ScopedTlsMapAccess tls_map;

   if (!IsValidUserKey(key) || !tls_map.IsInUse(key)) {
     return EINVAL;
   }

   ((uint32_t *)__get_tls())[key] = (uint32_t)ptr;
   return 0;
 }
	/*
	* Copyright (C) 2008 The Android Open Source Project
	* All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions
	* are met:
	* * Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	* * Redistributions in binary form must reproduce the above copyright
	* notice, this list of conditions and the following disclaimer in
	* the documentation and/or other materials provided with the
	* distribution.
	*
	* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
	* FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
	* COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
	* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
	* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
	* OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
	* AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
	* OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
	* OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
	* SUCH DAMAGE.
	*/

	#include <pthread.h>

	#include "bionic_tls.h"
	#include "pthread_internal.h"

	/* A technical note regarding our thread-local-storage (TLS) implementation:
	*
	* There can be up to BIONIC_TLS_SLOTS independent TLS keys in a given process,
	* The keys below TLS_SLOT_FIRST_USER_SLOT are reserved for Bionic to hold
	* special thread-specific variables like errno or a pointer to
	* the current thread's descriptor. These entries cannot be accessed through
	* pthread_getspecific() / pthread_setspecific() or pthread_key_delete()
	*
	* The 'tls_map_t' type defined below implements a shared global map of
	* currently created/allocated TLS keys and the destructors associated
	* with them.
	*
	* The global TLS map simply contains a bitmap of allocated keys, and
	* an array of destructors.
	*
	* Each thread has a TLS area that is a simple array of BIONIC_TLS_SLOTS void*
	* pointers. the TLS area of the main thread is stack-allocated in
	* __libc_init_common, while the TLS area of other threads is placed at
	* the top of their stack in pthread_create.
	*
	* When pthread_key_delete() is called it will erase the key's bitmap bit
	* and its destructor, and will also clear the key data in the TLS area of
	* all created threads. As mandated by Posix, it is the responsibility of
	* the caller of pthread_key_delete() to properly reclaim the objects that
	* were pointed to by these data fields (either before or after the call).
	*/

	#define TLSMAP_BITS 32
	#define TLSMAP_WORDS ((BIONIC_TLS_SLOTS+TLSMAP_BITS-1)/TLSMAP_BITS)
	#define TLSMAP_WORD(m,k) (m).map[(k)/TLSMAP_BITS]
	#define TLSMAP_MASK(k) (1U << ((k)&(TLSMAP_BITS-1)))

	static inline bool IsValidUserKey(pthread_key_t key) {
	return (key >= TLS_SLOT_FIRST_USER_SLOT && key < BIONIC_TLS_SLOTS);
	}

	typedef void (key_destructor_t)(void);

	struct tls_map_t {
	bool is_initialized;

	/* bitmap of allocated keys */
	uint32_t map[TLSMAP_WORDS];

	key_destructor_t key_destructors[BIONIC_TLS_SLOTS];
	};

	class ScopedTlsMapAccess {
	public:
	ScopedTlsMapAccess() {
	Lock();

	// If this is the first time the TLS map has been accessed,
	// mark the slots belonging to well-known keys as being in use.
	// This isn't currently necessary because the well-known keys
	// can only be accessed directly by bionic itself, do not have
	// destructors, and all the functions that touch the TLS map
	// start after the maximum well-known slot.
	if (!s_tls_map_.is_initialized) {
	for (pthread_key_t key = 0; key < TLS_SLOT_FIRST_USER_SLOT; ++key) {
	SetInUse(key, NULL);
	}
	s_tls_map_.is_initialized = true;
	}
	}

	~ScopedTlsMapAccess() {
	Unlock();
	}

	int CreateKey(pthread_key_t* result, void (key_destructor)(void)) {
	// Take the first unallocated key.
	for (int key = 0; key < BIONIC_TLS_SLOTS; ++key) {
	if (!IsInUse(key)) {
	SetInUse(key, key_destructor);
	*result = key;
	return 0;
	}
	}

	// We hit PTHREAD_KEYS_MAX. POSIX says EAGAIN for this case.
	return EAGAIN;
	}

	void DeleteKey(pthread_key_t key) {
	TLSMAP_WORD(s_tls_map_, key) &= ~TLSMAP_MASK(key);
	s_tls_map_.key_destructors[key] = NULL;
	}

	bool IsInUse(pthread_key_t key) {
	return (TLSMAP_WORD(s_tls_map_, key) & TLSMAP_MASK(key)) != 0;
	}

	void SetInUse(pthread_key_t key, void (key_destructor)(void)) {
	TLSMAP_WORD(s_tls_map_, key) \|= TLSMAP_MASK(key);
	s_tls_map_.key_destructors[key] = key_destructor;
	}

	// Called from pthread_exit() to remove all TLS key data
	// from this thread's TLS area. This must call the destructor of all keys
	// that have a non-NULL data value and a non-NULL destructor.
	void CleanAll() {
	void tls = (void)__get_tls();

	// Because destructors can do funky things like deleting/creating other
	// keys, we need to implement this in a loop.
	for (int rounds = PTHREAD_DESTRUCTOR_ITERATIONS; rounds > 0; --rounds) {
	size_t called_destructor_count = 0;
	for (int key = 0; key < BIONIC_TLS_SLOTS; ++key) {
	if (IsInUse(key)) {
	void* data = tls[key];
	void (key_destructor)(void) = s_tls_map_.key_destructors[key];

	if (data != NULL && key_destructor != NULL) {
	// we need to clear the key data now, this will prevent the
	// destructor (or a later one) from seeing the old value if
	// it calls pthread_getspecific() for some odd reason

	// we do not do this if 'key_destructor == NULL' just in case another
	// destructor function might be responsible for manually
	// releasing the corresponding data.
	tls[key] = NULL;

	// because the destructor is free to call pthread_key_create
	// and/or pthread_key_delete, we need to temporarily unlock
	// the TLS map
	Unlock();
	(*key_destructor)(data);
	Lock();
	++called_destructor_count;
	}
	}
	}

	// If we didn't call any destructors, there is no need to check the TLS data again.
	if (called_destructor_count == 0) {
	break;
	}
	}
	}

	private:
	static tls_map_t s_tls_map_;
	static pthread_mutex_t s_tls_map_lock_;

	void Lock() {
	pthread_mutex_lock(&s_tls_map_lock_);
	}

	void Unlock() {
	pthread_mutex_unlock(&s_tls_map_lock_);
	}
	};

	__LIBC_HIDDEN__ tls_map_t ScopedTlsMapAccess::s_tls_map_;
	__LIBC_HIDDEN__ pthread_mutex_t ScopedTlsMapAccess::s_tls_map_lock_;

	__LIBC_HIDDEN__ void pthread_key_clean_all() {
	ScopedTlsMapAccess tls_map;
	tls_map.CleanAll();
	}

	int pthread_key_create(pthread_key_t* key, void (key_destructor)(void)) {
	ScopedTlsMapAccess tls_map;
	return tls_map.CreateKey(key, key_destructor);
	}

	// Deletes a pthread_key_t. note that the standard mandates that this does
	// not call the destructors for non-NULL key values. Instead, it is the
	// responsibility of the caller to properly dispose of the corresponding data
	// and resources, using any means it finds suitable.
	int pthread_key_delete(pthread_key_t key) {
	ScopedTlsMapAccess tls_map;

	if (!IsValidUserKey(key) \|\| !tls_map.IsInUse(key)) {
	return EINVAL;
	}

	// Clear value in all threads.
	pthread_mutex_lock(&gThreadListLock);
	for (pthread_internal_t* t = gThreadList; t != NULL; t = t->next) {
	// Skip zombie threads. They don't have a valid TLS area any more.
	// Similarly, it is possible to have t->tls == NULL for threads that
	// were just recently created through pthread_create() but whose
	// startup trampoline (__thread_entry) hasn't been run yet by the
	// scheduler. t->tls will also be NULL after a thread's stack has been
	// unmapped but before the ongoing pthread_join() is finished.
	if ((t->attr.flags & PTHREAD_ATTR_FLAG_ZOMBIE) \|\| t->tls == NULL) {
	continue;
	}

	t->tls[key] = NULL;
	}
	tls_map.DeleteKey(key);

	pthread_mutex_unlock(&gThreadListLock);
	return 0;
	}

	void* pthread_getspecific(pthread_key_t key) {
	if (!IsValidUserKey(key)) {
	return NULL;
	}

	// For performance reasons, we do not lock/unlock the global TLS map
	// to check that the key is properly allocated. If the key was not
	// allocated, the value read from the TLS should always be NULL
	// due to pthread_key_delete() clearing the values for all threads.
	return (void )(((unsigned )__get_tls())[key]);
	}

	int pthread_setspecific(pthread_key_t key, const void* ptr) {
	ScopedTlsMapAccess tls_map;

	if (!IsValidUserKey(key) \|\| !tls_map.IsInUse(key)) {
	return EINVAL;
	}

	((uint32_t *)__get_tls())[key] = (uint32_t)ptr;
	return 0;
	}