base/threading/thread_local_storage_win.cc - chromium/src - Git at Google

 // Copyright (c) 2011 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "base/threading/thread_local_storage.h"

 #include <windows.h>

 #include "base/logging.h"

 namespace base {

 // In order to make TLS destructors work, we need to keep function
 // pointers to the destructor for each TLS that we allocate.
 // We make this work by allocating a single OS-level TLS, which
 // contains an array of slots for the application to use.  In
 // parallel, we also allocate an array of destructors, which we
 // keep track of and call when threads terminate.

 // tls_key_ is the one native TLS that we use.  It stores our
 // table.
 long ThreadLocalStorage::tls_key_ = TLS_OUT_OF_INDEXES;

 // tls_max_ is the high-water-mark of allocated thread local storage.
 // We intentionally skip 0 so that it is not confused with an
 // unallocated TLS slot.
 long ThreadLocalStorage::tls_max_ = 1;

 // An array of destructor function pointers for the slots.  If
 // a slot has a destructor, it will be stored in its corresponding
 // entry in this array.
 ThreadLocalStorage::TLSDestructorFunc
   ThreadLocalStorage::tls_destructors_[kThreadLocalStorageSize];

 void** ThreadLocalStorage::Initialize() {
   if (tls_key_ == TLS_OUT_OF_INDEXES) {
     long value = TlsAlloc();
     DCHECK(value != TLS_OUT_OF_INDEXES);

     // Atomically test-and-set the tls_key.  If the key is TLS_OUT_OF_INDEXES,
     // go ahead and set it.  Otherwise, do nothing, as another
     // thread already did our dirty work.
     if (InterlockedCompareExchange(&tls_key_, value, TLS_OUT_OF_INDEXES) !=
             TLS_OUT_OF_INDEXES) {
       // We've been shortcut. Another thread replaced tls_key_ first so we need
       // to destroy our index and use the one the other thread got first.
       TlsFree(value);
     }
   }
   DCHECK(!TlsGetValue(tls_key_));

   // Create an array to store our data.
   void** tls_data = new void*[kThreadLocalStorageSize];
   memset(tls_data, 0, sizeof(void*[kThreadLocalStorageSize]));
   TlsSetValue(tls_key_, tls_data);
   return tls_data;
 }

 ThreadLocalStorage::Slot::Slot(TLSDestructorFunc destructor)
     : initialized_(false),
       slot_(0) {
   Initialize(destructor);
 }

 bool ThreadLocalStorage::Slot::Initialize(TLSDestructorFunc destructor) {
   if (tls_key_ == TLS_OUT_OF_INDEXES || !TlsGetValue(tls_key_))
     ThreadLocalStorage::Initialize();

   // Grab a new slot.
   slot_ = InterlockedIncrement(&tls_max_) - 1;
   if (slot_ >= kThreadLocalStorageSize) {
     NOTREACHED();
     return false;
   }

   // Setup our destructor.
   tls_destructors_[slot_] = destructor;
   initialized_ = true;
   return true;
 }

 void ThreadLocalStorage::Slot::Free() {
   // At this time, we don't reclaim old indices for TLS slots.
   // So all we need to do is wipe the destructor.
   tls_destructors_[slot_] = NULL;
   initialized_ = false;
 }

 void* ThreadLocalStorage::Slot::Get() const {
   void** tls_data = static_cast<void**>(TlsGetValue(tls_key_));
   if (!tls_data)
     tls_data = ThreadLocalStorage::Initialize();
   DCHECK_GE(slot_, 0);
   DCHECK_LT(slot_, kThreadLocalStorageSize);
   return tls_data[slot_];
 }

 void ThreadLocalStorage::Slot::Set(void* value) {
   void** tls_data = static_cast<void**>(TlsGetValue(tls_key_));
   if (!tls_data)
     tls_data = ThreadLocalStorage::Initialize();
   DCHECK_GE(slot_, 0);
   DCHECK_LT(slot_, kThreadLocalStorageSize);
   tls_data[slot_] = value;
 }

 void ThreadLocalStorage::ThreadExit() {
   if (tls_key_ == TLS_OUT_OF_INDEXES)
     return;

   void** tls_data = static_cast<void**>(TlsGetValue(tls_key_));

   // Maybe we have never initialized TLS for this thread.
   if (!tls_data)
     return;

   for (int slot = 0; slot < tls_max_; slot++) {
     if (tls_destructors_[slot] != NULL) {
       void* value = tls_data[slot];
       tls_destructors_[slot](value);
     }
   }

   delete[] tls_data;

   // In case there are other "onexit" handlers...
   TlsSetValue(tls_key_, NULL);
 }

 }  // namespace base

 // Thread Termination Callbacks.
 // Windows doesn't support a per-thread destructor with its
 // TLS primitives.  So, we build it manually by inserting a
 // function to be called on each thread's exit.
 // This magic is from http://www.codeproject.com/threads/tls.asp
 // and it works for VC++ 7.0 and later.

 // Force a reference to _tls_used to make the linker create the TLS directory
 // if it's not already there.  (e.g. if __declspec(thread) is not used).
 // Force a reference to p_thread_callback_base to prevent whole program
 // optimization from discarding the variable.
 #ifdef _WIN64

 #pragma comment(linker, "/INCLUDE:_tls_used")
 #pragma comment(linker, "/INCLUDE:p_thread_callback_base")

 #else  // _WIN64

 #pragma comment(linker, "/INCLUDE:__tls_used")
 #pragma comment(linker, "/INCLUDE:_p_thread_callback_base")

 #endif  // _WIN64

 // Static callback function to call with each thread termination.
 void NTAPI OnThreadExit(PVOID module, DWORD reason, PVOID reserved) {
   // On XP SP0 & SP1, the DLL_PROCESS_ATTACH is never seen. It is sent on SP2+
   // and on W2K and W2K3. So don't assume it is sent.
   if (DLL_THREAD_DETACH == reason || DLL_PROCESS_DETACH == reason)
     base::ThreadLocalStorage::ThreadExit();
 }

 // .CRT$XLA to .CRT$XLZ is an array of PIMAGE_TLS_CALLBACK pointers that are
 // called automatically by the OS loader code (not the CRT) when the module is
 // loaded and on thread creation. They are NOT called if the module has been
 // loaded by a LoadLibrary() call. It must have implicitly been loaded at
 // process startup.
 // By implicitly loaded, I mean that it is directly referenced by the main EXE
 // or by one of its dependent DLLs. Delay-loaded DLL doesn't count as being
 // implicitly loaded.
 //
 // See VC\crt\src\tlssup.c for reference.

 // extern "C" suppresses C++ name mangling so we know the symbol name for the
 // linker /INCLUDE:symbol pragma above.
 extern "C" {
 // The linker must not discard p_thread_callback_base.  (We force a reference
 // to this variable with a linker /INCLUDE:symbol pragma to ensure that.) If
 // this variable is discarded, the OnThreadExit function will never be called.
 #ifdef _WIN64

 // .CRT section is merged with .rdata on x64 so it must be constant data.
 #pragma const_seg(".CRT$XLB")
 // When defining a const variable, it must have external linkage to be sure the
 // linker doesn't discard it.
 extern const PIMAGE_TLS_CALLBACK p_thread_callback_base;
 const PIMAGE_TLS_CALLBACK p_thread_callback_base = OnThreadExit;

 // Reset the default section.
 #pragma const_seg()

 #else  // _WIN64

 #pragma data_seg(".CRT$XLB")
 PIMAGE_TLS_CALLBACK p_thread_callback_base = OnThreadExit;

 // Reset the default section.
 #pragma data_seg()

 #endif  // _WIN64
 }  // extern "C"
	// Copyright (c) 2011 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "base/threading/thread_local_storage.h"

	#include <windows.h>

	#include "base/logging.h"

	namespace base {

	// In order to make TLS destructors work, we need to keep function
	// pointers to the destructor for each TLS that we allocate.
	// We make this work by allocating a single OS-level TLS, which
	// contains an array of slots for the application to use. In
	// parallel, we also allocate an array of destructors, which we
	// keep track of and call when threads terminate.

	// tls_key_ is the one native TLS that we use. It stores our
	// table.
	long ThreadLocalStorage::tls_key_ = TLS_OUT_OF_INDEXES;

	// tls_max_ is the high-water-mark of allocated thread local storage.
	// We intentionally skip 0 so that it is not confused with an
	// unallocated TLS slot.
	long ThreadLocalStorage::tls_max_ = 1;

	// An array of destructor function pointers for the slots. If
	// a slot has a destructor, it will be stored in its corresponding
	// entry in this array.
	ThreadLocalStorage::TLSDestructorFunc
	ThreadLocalStorage::tls_destructors_[kThreadLocalStorageSize];

	void** ThreadLocalStorage::Initialize() {
	if (tls_key_ == TLS_OUT_OF_INDEXES) {
	long value = TlsAlloc();
	DCHECK(value != TLS_OUT_OF_INDEXES);

	// Atomically test-and-set the tls_key. If the key is TLS_OUT_OF_INDEXES,
	// go ahead and set it. Otherwise, do nothing, as another
	// thread already did our dirty work.
	if (InterlockedCompareExchange(&tls_key_, value, TLS_OUT_OF_INDEXES) !=
	TLS_OUT_OF_INDEXES) {
	// We've been shortcut. Another thread replaced tls_key_ first so we need
	// to destroy our index and use the one the other thread got first.
	TlsFree(value);
	}
	}
	DCHECK(!TlsGetValue(tls_key_));

	// Create an array to store our data.
	void** tls_data = new void*[kThreadLocalStorageSize];
	memset(tls_data, 0, sizeof(void*[kThreadLocalStorageSize]));
	TlsSetValue(tls_key_, tls_data);
	return tls_data;
	}

	ThreadLocalStorage::Slot::Slot(TLSDestructorFunc destructor)
	: initialized_(false),
	slot_(0) {
	Initialize(destructor);
	}

	bool ThreadLocalStorage::Slot::Initialize(TLSDestructorFunc destructor) {
	if (tls_key_ == TLS_OUT_OF_INDEXES \|\| !TlsGetValue(tls_key_))
	ThreadLocalStorage::Initialize();

	// Grab a new slot.
	slot_ = InterlockedIncrement(&tls_max_) - 1;
	if (slot_ >= kThreadLocalStorageSize) {
	NOTREACHED();
	return false;
	}

	// Setup our destructor.
	tls_destructors_[slot_] = destructor;
	initialized_ = true;
	return true;
	}

	void ThreadLocalStorage::Slot::Free() {
	// At this time, we don't reclaim old indices for TLS slots.
	// So all we need to do is wipe the destructor.
	tls_destructors_[slot_] = NULL;
	initialized_ = false;
	}

	void* ThreadLocalStorage::Slot::Get() const {
	void tls_data = static_cast<void>(TlsGetValue(tls_key_));
	if (!tls_data)
	tls_data = ThreadLocalStorage::Initialize();
	DCHECK_GE(slot_, 0);
	DCHECK_LT(slot_, kThreadLocalStorageSize);
	return tls_data[slot_];
	}

	void ThreadLocalStorage::Slot::Set(void* value) {
	void tls_data = static_cast<void>(TlsGetValue(tls_key_));
	if (!tls_data)
	tls_data = ThreadLocalStorage::Initialize();
	DCHECK_GE(slot_, 0);
	DCHECK_LT(slot_, kThreadLocalStorageSize);
	tls_data[slot_] = value;
	}

	void ThreadLocalStorage::ThreadExit() {
	if (tls_key_ == TLS_OUT_OF_INDEXES)
	return;

	void tls_data = static_cast<void>(TlsGetValue(tls_key_));

	// Maybe we have never initialized TLS for this thread.
	if (!tls_data)
	return;

	for (int slot = 0; slot < tls_max_; slot++) {
	if (tls_destructors_[slot] != NULL) {
	void* value = tls_data[slot];
	tls_destructors_[slot](value);
	}
	}

	delete[] tls_data;

	// In case there are other "onexit" handlers...
	TlsSetValue(tls_key_, NULL);
	}

	} // namespace base

	// Thread Termination Callbacks.
	// Windows doesn't support a per-thread destructor with its
	// TLS primitives. So, we build it manually by inserting a
	// function to be called on each thread's exit.
	// This magic is from http://www.codeproject.com/threads/tls.asp
	// and it works for VC++ 7.0 and later.

	// Force a reference to _tls_used to make the linker create the TLS directory
	// if it's not already there. (e.g. if __declspec(thread) is not used).
	// Force a reference to p_thread_callback_base to prevent whole program
	// optimization from discarding the variable.
	#ifdef _WIN64

	#pragma comment(linker, "/INCLUDE:_tls_used")
	#pragma comment(linker, "/INCLUDE:p_thread_callback_base")

	#else // _WIN64

	#pragma comment(linker, "/INCLUDE:__tls_used")
	#pragma comment(linker, "/INCLUDE:_p_thread_callback_base")

	#endif // _WIN64

	// Static callback function to call with each thread termination.
	void NTAPI OnThreadExit(PVOID module, DWORD reason, PVOID reserved) {
	// On XP SP0 & SP1, the DLL_PROCESS_ATTACH is never seen. It is sent on SP2+
	// and on W2K and W2K3. So don't assume it is sent.
	if (DLL_THREAD_DETACH == reason \|\| DLL_PROCESS_DETACH == reason)
	base::ThreadLocalStorage::ThreadExit();
	}

	// .CRT$XLA to .CRT$XLZ is an array of PIMAGE_TLS_CALLBACK pointers that are
	// called automatically by the OS loader code (not the CRT) when the module is
	// loaded and on thread creation. They are NOT called if the module has been
	// loaded by a LoadLibrary() call. It must have implicitly been loaded at
	// process startup.
	// By implicitly loaded, I mean that it is directly referenced by the main EXE
	// or by one of its dependent DLLs. Delay-loaded DLL doesn't count as being
	// implicitly loaded.
	//
	// See VC\crt\src\tlssup.c for reference.

	// extern "C" suppresses C++ name mangling so we know the symbol name for the
	// linker /INCLUDE:symbol pragma above.
	extern "C" {
	// The linker must not discard p_thread_callback_base. (We force a reference
	// to this variable with a linker /INCLUDE:symbol pragma to ensure that.) If
	// this variable is discarded, the OnThreadExit function will never be called.
	#ifdef _WIN64

	// .CRT section is merged with .rdata on x64 so it must be constant data.
	#pragma const_seg(".CRT$XLB")
	// When defining a const variable, it must have external linkage to be sure the
	// linker doesn't discard it.
	extern const PIMAGE_TLS_CALLBACK p_thread_callback_base;
	const PIMAGE_TLS_CALLBACK p_thread_callback_base = OnThreadExit;

	// Reset the default section.
	#pragma const_seg()

	#else // _WIN64

	#pragma data_seg(".CRT$XLB")
	PIMAGE_TLS_CALLBACK p_thread_callback_base = OnThreadExit;

	// Reset the default section.
	#pragma data_seg()

	#endif // _WIN64
	} // extern "C"