Implement chromium's TLS.

base/threading/thread_local_storage_win.cc

 // Copyright (c) 2012 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 {
 
-namespace {
-// 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.
+namespace internal {
 
-// g_native_tls_key is the one native TLS that we use.  It stores our table.
-long g_native_tls_key = TLS_OUT_OF_INDEXES;
-
-// g_last_used_tls_key is the high-water-mark of allocated thread local storage.
-// Each allocation is an index into our g_tls_destructors[].  Each such index is
-// assigned to the instance variable slot_ in a ThreadLocalStorage::Slot
-// instance.  We reserve the value slot_ == 0 to indicate that the corresponding
-// instance of ThreadLocalStorage::Slot has been freed (i.e., destructor called,
-// etc.).  This reserved use of 0 is then stated as the initial value of
-// g_last_used_tls_key, so that the first issued index will be 1.
-long g_last_used_tls_key = 0;
-
-// The maximum number of 'slots' in our thread local storage stack.
-const int kThreadLocalStorageSize = 64;
-
-// The maximum number of times to try to clear slots by calling destructors.
-// Use pthread naming convention for clarity.
-const int kMaxDestructorIterations = kThreadLocalStorageSize;
-
-// 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.
-// The elements are volatile to ensure that when the compiler reads the value
-// to potentially call the destructor, it does so once, and that value is tested
-// for null-ness and then used. Yes, that would be a weird de-optimization,
-// but I can imagine some register machines where it was just as easy to
-// re-fetch an array element, and I want to be sure a call to free the key
-// (i.e., null out the destructor entry) that happens on a separate thread can't
-// hurt the racy calls to the destructors on another thread.
-volatile base::ThreadLocalStorage::TLSDestructorFunc
-    g_tls_destructors[kThreadLocalStorageSize];
-
-void** ConstructTlsVector() {
-  if (g_native_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 (TLS_OUT_OF_INDEXES != InterlockedCompareExchange(
-            &g_native_tls_key, value, TLS_OUT_OF_INDEXES)) {
-      // We've been shortcut. Another thread replaced g_native_tls_key first so
-      // we need to destroy our index and use the one the other thread got
-      // first.
-      TlsFree(value);
-    }
+bool PlatformThreadLocalStorage::AllocTLS(TLSKey* key) {
+  TLSKey value = TlsAlloc();
+  if (value != TLS_OUT_OF_INDEXES) {
+    *key = value;
+    return true;
   }
-  DCHECK(!TlsGetValue(g_native_tls_key));
-
-  // Some allocators, such as TCMalloc, make use of thread local storage.
-  // As a result, any attempt to call new (or malloc) will lazily cause such a
-  // system to initialize, which will include registering for a TLS key.  If we
-  // are not careful here, then that request to create a key will call new back,
-  // and we'll have an infinite loop.  We avoid that as follows:
-  // Use a stack allocated vector, so that we don't have dependence on our
-  // allocator until our service is in place.  (i.e., don't even call new until
-  // after we're setup)
-  void* stack_allocated_tls_data[kThreadLocalStorageSize];
-  memset(stack_allocated_tls_data, 0, sizeof(stack_allocated_tls_data));
-  // Ensure that any rentrant calls change the temp version.
-  TlsSetValue(g_native_tls_key, stack_allocated_tls_data);
-
-  // Allocate an array to store our data.
-  void** tls_data = new void*[kThreadLocalStorageSize];
-  memcpy(tls_data, stack_allocated_tls_data, sizeof(stack_allocated_tls_data));
-  TlsSetValue(g_native_tls_key, tls_data);
-  return tls_data;
+  return false;
 }
 
-// Called when we terminate a thread, this function calls any TLS destructors
-// that are pending for this thread.
-void WinThreadExit() {
-  if (g_native_tls_key == TLS_OUT_OF_INDEXES)
-    return;
-
-  void** tls_data = static_cast<void**>(TlsGetValue(g_native_tls_key));
-  // Maybe we have never initialized TLS for this thread.
-  if (!tls_data)
-    return;
-
-  // Some allocators, such as TCMalloc, use TLS.  As a result, when a thread
-  // terminates, one of the destructor calls we make may be to shut down an
-  // allocator.  We have to be careful that after we've shutdown all of the
-  // known destructors (perchance including an allocator), that we don't call
-  // the allocator and cause it to resurrect itself (with no possibly destructor
-  // call to follow).  We handle this problem as follows:
-  // Switch to using a stack allocated vector, so that we don't have dependence
-  // on our allocator after we have called all g_tls_destructors.  (i.e., don't
-  // even call delete[] after we're done with destructors.)
-  void* stack_allocated_tls_data[kThreadLocalStorageSize];
-  memcpy(stack_allocated_tls_data, tls_data, sizeof(stack_allocated_tls_data));
-  // Ensure that any re-entrant calls change the temp version.
-  TlsSetValue(g_native_tls_key, stack_allocated_tls_data);
-  delete[] tls_data;  // Our last dependence on an allocator.
-
-  int remaining_attempts = kMaxDestructorIterations;
-  bool need_to_scan_destructors = true;
-  while (need_to_scan_destructors) {
-    need_to_scan_destructors = false;
-    // Try to destroy the first-created-slot (which is slot 1) in our last
-    // destructor call.  That user was able to function, and define a slot with
-    // no other services running, so perhaps it is a basic service (like an
-    // allocator) and should also be destroyed last.  If we get the order wrong,
-    // then we'll itterate several more times, so it is really not that
-    // critical (but it might help).
-    for (int slot = g_last_used_tls_key; slot > 0; --slot) {
-      void* value = stack_allocated_tls_data[slot];
-      if (value == NULL)
-        continue;
-      base::ThreadLocalStorage::TLSDestructorFunc destructor =
-          g_tls_destructors[slot];
-      if (destructor == NULL)
-        continue;
-      stack_allocated_tls_data[slot] = NULL;  // pre-clear the slot.
-      destructor(value);
-      // Any destructor might have called a different service, which then set
-      // a different slot to a non-NULL value.  Hence we need to check
-      // the whole vector again.  This is a pthread standard.
-      need_to_scan_destructors = true;
-    }
-    if (--remaining_attempts <= 0) {
-      NOTREACHED();  // Destructors might not have been called.
-      break;
-    }
-  }
-
-  // Remove our stack allocated vector.
-  TlsSetValue(g_native_tls_key, NULL);
+void PlatformThreadLocalStorage::FreeTLS(TLSKey key) {
+  BOOL ret = TlsFree(key);
+  DCHECK(ret);
 }
 
-}  // namespace
-
-namespace base {
-
-ThreadLocalStorage::Slot::Slot(TLSDestructorFunc destructor) {
-  initialized_ = false;
-  slot_ = 0;
-  Initialize(destructor);
+void* PlatformThreadLocalStorage::GetTLSValue(TLSKey key) {
+  return TlsGetValue(key);
 }
 
-bool ThreadLocalStorage::StaticSlot::Initialize(TLSDestructorFunc destructor) {
-  if (g_native_tls_key == TLS_OUT_OF_INDEXES || !TlsGetValue(g_native_tls_key))
-    ConstructTlsVector();
-
-  // Grab a new slot.
-  slot_ = InterlockedIncrement(&g_last_used_tls_key);
-  DCHECK_GT(slot_, 0);
-  if (slot_ >= kThreadLocalStorageSize) {
-    NOTREACHED();
-    return false;
-  }
-
-  // Setup our destructor.
-  g_tls_destructors[slot_] = destructor;
-  initialized_ = true;
-  return true;
+void PlatformThreadLocalStorage::SetTLSValue(TLSKey key, void* value) {
+  BOOL ret = TlsSetValue(key, value);
+  DCHECK(ret);
 }
 
-void ThreadLocalStorage::StaticSlot::Free() {
-  // At this time, we don't reclaim old indices for TLS slots.
-  // So all we need to do is wipe the destructor.
-  DCHECK_GT(slot_, 0);
-  DCHECK_LT(slot_, kThreadLocalStorageSize);
-  g_tls_destructors[slot_] = NULL;
-  slot_ = 0;
-  initialized_ = false;
-}
-
-void* ThreadLocalStorage::StaticSlot::Get() const {
-  void** tls_data = static_cast<void**>(TlsGetValue(g_native_tls_key));
-  if (!tls_data)
-    tls_data = ConstructTlsVector();
-  DCHECK_GT(slot_, 0);
-  DCHECK_LT(slot_, kThreadLocalStorageSize);
-  return tls_data[slot_];
-}
-
-void ThreadLocalStorage::StaticSlot::Set(void* value) {
-  void** tls_data = static_cast<void**>(TlsGetValue(g_native_tls_key));
-  if (!tls_data)
-    tls_data = ConstructTlsVector();
-  DCHECK_GT(slot_, 0);
-  DCHECK_LT(slot_, kThreadLocalStorageSize);
-  tls_data[slot_] = value;
-}
+}  // namespace internal
 
 }  // 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.
 
@@ skipping 11 matching lines @@
 #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)
-    WinThreadExit();
+    base::internal::PlatformThreadLocalStorage::OnThreadExit();
 }
 
 // .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.
@@ skipping 21 matching lines @@
 #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"