windows_msvc-x86_64/include/google/protobuf/stubs/shared_ptr.h - platform/prebuilts/android-emulator-build/protobuf - Git at Google

 // Protocol Buffers - Google's data interchange format
 // Copyright 2014 Google Inc.  All rights reserved.
 // https://developers.google.com/protocol-buffers/
 //
 // 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.
 //     * Neither the name of Google Inc. nor the names of its
 // contributors may be used to endorse or promote products derived from
 // this software without specific prior written permission.
 //
 // 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.

 // from google3/util/gtl/shared_ptr.h

 #ifndef GOOGLE_PROTOBUF_STUBS_SHARED_PTR_H__
 #define GOOGLE_PROTOBUF_STUBS_SHARED_PTR_H__

 #include <google/protobuf/stubs/atomicops.h>

 #include <algorithm>  // for swap
 #include <stddef.h>
 #include <memory>

 namespace google {
 namespace protobuf {
 namespace internal {

 // Alias to std::shared_ptr for any C++11 platform,
 // and for any supported MSVC compiler.
 #if !defined(UTIL_GTL_USE_STD_SHARED_PTR) && \
     (defined(COMPILER_MSVC) || defined(LANG_CXX11))
 #define UTIL_GTL_USE_STD_SHARED_PTR 1
 #endif

 #if defined(UTIL_GTL_USE_STD_SHARED_PTR) && UTIL_GTL_USE_STD_SHARED_PTR

 // These are transitional.  They will be going away soon.
 // Please just #include <memory> and just type std::shared_ptr yourself, instead
 // of relying on this file.
 //
 // Migration doc: http://go/std-shared-ptr-lsc
 using std::enable_shared_from_this;
 using std::shared_ptr;
 using std::static_pointer_cast;
 using std::weak_ptr;

 #else  // below, UTIL_GTL_USE_STD_SHARED_PTR not set or set to 0.

 // For everything else there is the google3 implementation.
 inline bool RefCountDec(volatile Atomic32 *ptr) {
   return Barrier_AtomicIncrement(ptr, -1) != 0;
 }

 inline void RefCountInc(volatile Atomic32 *ptr) {
   NoBarrier_AtomicIncrement(ptr, 1);
 }

 template <typename T> class shared_ptr;
 template <typename T> class weak_ptr;

 // This class is an internal implementation detail for shared_ptr. If two
 // shared_ptrs point to the same object, they also share a control block.
 // An "empty" shared_pointer refers to NULL and also has a NULL control block.
 // It contains all of the state that's needed for reference counting or any
 // other kind of resource management. In this implementation the control block
 // happens to consist of two atomic words, the reference count (the number
 // of shared_ptrs that share ownership of the object) and the weak count
 // (the number of weak_ptrs that observe the object, plus 1 if the
 // refcount is nonzero).
 //
 // The "plus 1" is to prevent a race condition in the shared_ptr and
 // weak_ptr destructors. We need to make sure the control block is
 // only deleted once, so we need to make sure that at most one
 // object sees the weak count decremented from 1 to 0.
 class SharedPtrControlBlock {
   template <typename T> friend class shared_ptr;
   template <typename T> friend class weak_ptr;
  private:
   SharedPtrControlBlock() : refcount_(1), weak_count_(1) { }
   Atomic32 refcount_;
   Atomic32 weak_count_;
 };

 // Forward declaration. The class is defined below.
 template <typename T> class enable_shared_from_this;

 template <typename T>
 class shared_ptr {
   template <typename U> friend class weak_ptr;
  public:
   typedef T element_type;

   shared_ptr() : ptr_(NULL), control_block_(NULL) {}

   explicit shared_ptr(T* ptr)
       : ptr_(ptr),
         control_block_(ptr != NULL ? new SharedPtrControlBlock : NULL) {
     // If p is non-null and T inherits from enable_shared_from_this, we
     // set up the data that shared_from_this needs.
     MaybeSetupWeakThis(ptr);
   }

   // Copy constructor: makes this object a copy of ptr, and increments
   // the reference count.
   template <typename U>
   shared_ptr(const shared_ptr<U>& ptr)
       : ptr_(NULL),
         control_block_(NULL) {
     Initialize(ptr);
   }
   // Need non-templated version to prevent the compiler-generated default
   shared_ptr(const shared_ptr<T>& ptr)
       : ptr_(NULL),
         control_block_(NULL) {
     Initialize(ptr);
   }

   // Assignment operator. Replaces the existing shared_ptr with ptr.
   // Increment ptr's reference count and decrement the one being replaced.
   template <typename U>
   shared_ptr<T>& operator=(const shared_ptr<U>& ptr) {
     if (ptr_ != ptr.ptr_) {
       shared_ptr<T> me(ptr);   // will hold our previous state to be destroyed.
       swap(me);
     }
     return *this;
   }

   // Need non-templated version to prevent the compiler-generated default
   shared_ptr<T>& operator=(const shared_ptr<T>& ptr) {
     if (ptr_ != ptr.ptr_) {
       shared_ptr<T> me(ptr);   // will hold our previous state to be destroyed.
       swap(me);
     }
     return *this;
   }

   // TODO(austern): Consider providing this constructor. The draft C++ standard
   // (20.8.10.2.1) includes it. However, it says that this constructor throws
   // a bad_weak_ptr exception when ptr is expired. Is it better to provide this
   // constructor and make it do something else, like fail with a CHECK, or to
   // leave this constructor out entirely?
   //
   // template <typename U>
   // shared_ptr(const weak_ptr<U>& ptr);

   ~shared_ptr() {
     if (ptr_ != NULL) {
       if (!RefCountDec(&control_block_->refcount_)) {
         delete ptr_;

         // weak_count_ is defined as the number of weak_ptrs that observe
         // ptr_, plus 1 if refcount_ is nonzero.
         if (!RefCountDec(&control_block_->weak_count_)) {
           delete control_block_;
         }
       }
     }
   }

   // Replaces underlying raw pointer with the one passed in.  The reference
   // count is set to one (or zero if the pointer is NULL) for the pointer
   // being passed in and decremented for the one being replaced.
   //
   // If you have a compilation error with this code, make sure you aren't
   // passing NULL, nullptr, or 0 to this function.  Call reset without an
   // argument to reset to a null ptr.
   template <typename Y>
   void reset(Y* p) {
     if (p != ptr_) {
       shared_ptr<T> tmp(p);
       tmp.swap(*this);
     }
   }

   void reset() {
     reset(static_cast<T*>(NULL));
   }

   // Exchanges the contents of this with the contents of r.  This function
   // supports more efficient swapping since it eliminates the need for a
   // temporary shared_ptr object.
   void swap(shared_ptr<T>& r) {
     using std::swap;  // http://go/using-std-swap
     swap(ptr_, r.ptr_);
     swap(control_block_, r.control_block_);
   }

   // The following function is useful for gaining access to the underlying
   // pointer when a shared_ptr remains in scope so the reference-count is
   // known to be > 0 (e.g. for parameter passing).
   T* get() const {
     return ptr_;
   }

   T& operator*() const {
     return *ptr_;
   }

   T* operator->() const {
     return ptr_;
   }

   long use_count() const {
     return control_block_ ? control_block_->refcount_ : 1;
   }

   bool unique() const {
     return use_count() == 1;
   }

  private:
   // If r is non-empty, initialize *this to share ownership with r,
   // increasing the underlying reference count.
   // If r is empty, *this remains empty.
   // Requires: this is empty, namely this->ptr_ == NULL.
   template <typename U>
   void Initialize(const shared_ptr<U>& r) {
     // This performs a static_cast on r.ptr_ to U*, which is a no-op since it
     // is already a U*. So initialization here requires that r.ptr_ is
     // implicitly convertible to T*.
     InitializeWithStaticCast<U>(r);
   }

   // Initializes *this as described in Initialize, but additionally performs a
   // static_cast from r.ptr_ (V*) to U*.
   // NOTE(gfc): We'd need a more general form to support const_pointer_cast and
   // dynamic_pointer_cast, but those operations are sufficiently discouraged
   // that supporting static_pointer_cast is sufficient.
   template <typename U, typename V>
   void InitializeWithStaticCast(const shared_ptr<V>& r) {
     if (r.control_block_ != NULL) {
       RefCountInc(&r.control_block_->refcount_);

       ptr_ = static_cast<U*>(r.ptr_);
       control_block_ = r.control_block_;
     }
   }

   // Helper function for the constructor that takes a raw pointer. If T
   // doesn't inherit from enable_shared_from_this<T> then we have nothing to
   // do, so this function is trivial and inline. The other version is declared
   // out of line, after the class definition of enable_shared_from_this.
   void MaybeSetupWeakThis(enable_shared_from_this<T>* ptr);
   void MaybeSetupWeakThis(...) { }

   T* ptr_;
   SharedPtrControlBlock* control_block_;

 #ifndef SWIG
   template <typename U>
   friend class shared_ptr;

   template <typename U, typename V>
   friend shared_ptr<U> static_pointer_cast(const shared_ptr<V>& rhs);
 #endif
 };

 // Matches the interface of std::swap as an aid to generic programming.
 template <typename T> void swap(shared_ptr<T>& r, shared_ptr<T>& s) {
   r.swap(s);
 }

 template <typename T, typename U>
 shared_ptr<T> static_pointer_cast(const shared_ptr<U>& rhs) {
   shared_ptr<T> lhs;
   lhs.template InitializeWithStaticCast<T>(rhs);
   return lhs;
 }

 // See comments at the top of the file for a description of why this
 // class exists, and the draft C++ standard (as of July 2009 the
 // latest draft is N2914) for the detailed specification.
 template <typename T>
 class weak_ptr {
   template <typename U> friend class weak_ptr;
  public:
   typedef T element_type;

   // Create an empty (i.e. already expired) weak_ptr.
   weak_ptr() : ptr_(NULL), control_block_(NULL) { }

   // Create a weak_ptr that observes the same object that ptr points
   // to.  Note that there is no race condition here: we know that the
   // control block can't disappear while we're looking at it because
   // it is owned by at least one shared_ptr, ptr.
   template <typename U> weak_ptr(const shared_ptr<U>& ptr) {
     CopyFrom(ptr.ptr_, ptr.control_block_);
   }

   // Copy a weak_ptr. The object it points to might disappear, but we
   // don't care: we're only working with the control block, and it can't
   // disappear while we're looking at because it's owned by at least one
   // weak_ptr, ptr.
   template <typename U> weak_ptr(const weak_ptr<U>& ptr) {
     CopyFrom(ptr.ptr_, ptr.control_block_);
   }

   // Need non-templated version to prevent default copy constructor
   weak_ptr(const weak_ptr& ptr) {
     CopyFrom(ptr.ptr_, ptr.control_block_);
   }

   // Destroy the weak_ptr. If no shared_ptr owns the control block, and if
   // we are the last weak_ptr to own it, then it can be deleted. Note that
   // weak_count_ is defined as the number of weak_ptrs sharing this control
   // block, plus 1 if there are any shared_ptrs. We therefore know that it's
   // safe to delete the control block when weak_count_ reaches 0, without
   // having to perform any additional tests.
   ~weak_ptr() {
     if (control_block_ != NULL &&
         !RefCountDec(&control_block_->weak_count_)) {
       delete control_block_;
     }
   }

   weak_ptr& operator=(const weak_ptr& ptr) {
     if (&ptr != this) {
       weak_ptr tmp(ptr);
       tmp.swap(*this);
     }
     return *this;
   }
   template <typename U> weak_ptr& operator=(const weak_ptr<U>& ptr) {
     weak_ptr tmp(ptr);
     tmp.swap(*this);
     return *this;
   }
   template <typename U> weak_ptr& operator=(const shared_ptr<U>& ptr) {
     weak_ptr tmp(ptr);
     tmp.swap(*this);
     return *this;
   }

   void swap(weak_ptr& ptr) {
     using std::swap;  // http://go/using-std-swap
     swap(ptr_, ptr.ptr_);
     swap(control_block_, ptr.control_block_);
   }

   void reset() {
     weak_ptr tmp;
     tmp.swap(*this);
   }

   // Return the number of shared_ptrs that own the object we are observing.
   // Note that this number can be 0 (if this pointer has expired).
   long use_count() const {
     return control_block_ != NULL ? control_block_->refcount_ : 0;
   }

   bool expired() const { return use_count() == 0; }

   // Return a shared_ptr that owns the object we are observing. If we
   // have expired, the shared_ptr will be empty. We have to be careful
   // about concurrency, though, since some other thread might be
   // destroying the last owning shared_ptr while we're in this
   // function.  We want to increment the refcount only if it's nonzero
   // and get the new value, and we want that whole operation to be
   // atomic.
   shared_ptr<T> lock() const {
     shared_ptr<T> result;
     if (control_block_ != NULL) {
       Atomic32 old_refcount;
       do {
         old_refcount = control_block_->refcount_;
         if (old_refcount == 0)
           break;
       } while (old_refcount !=
                NoBarrier_CompareAndSwap(
                    &control_block_->refcount_, old_refcount,
                    old_refcount + 1));
       if (old_refcount > 0) {
         result.ptr_ = ptr_;
         result.control_block_ = control_block_;
       }
     }

     return result;
   }

  private:
   void CopyFrom(T* ptr, SharedPtrControlBlock* control_block) {
     ptr_ = ptr;
     control_block_ = control_block;
     if (control_block_ != NULL)
       RefCountInc(&control_block_->weak_count_);
   }

  private:
   element_type* ptr_;
   SharedPtrControlBlock* control_block_;
 };

 template <typename T> void swap(weak_ptr<T>& r, weak_ptr<T>& s) {
   r.swap(s);
 }

 // See comments at the top of the file for a description of why this class
 // exists, and section 20.8.10.5 of the draft C++ standard (as of July 2009
 // the latest draft is N2914) for the detailed specification.
 template <typename T>
 class enable_shared_from_this {
   friend class shared_ptr<T>;
  public:
   // Precondition: there must be a shared_ptr that owns *this and that was
   // created, directly or indirectly, from a raw pointer of type T*. (The
   // latter part of the condition is technical but not quite redundant; it
   // rules out some complicated uses involving inheritance hierarchies.)
   shared_ptr<T> shared_from_this() {
     // Behavior is undefined if the precondition isn't satisfied; we choose
     // to die with a CHECK failure.
     CHECK(!weak_this_.expired()) << "No shared_ptr owns this object";
     return weak_this_.lock();
   }
   shared_ptr<const T> shared_from_this() const {
     CHECK(!weak_this_.expired()) << "No shared_ptr owns this object";
     return weak_this_.lock();
   }

  protected:
   enable_shared_from_this() { }
   enable_shared_from_this(const enable_shared_from_this& other) { }
   enable_shared_from_this& operator=(const enable_shared_from_this& other) {
     return *this;
   }
   ~enable_shared_from_this() { }

  private:
   weak_ptr<T> weak_this_;
 };

 // This is a helper function called by shared_ptr's constructor from a raw
 // pointer. If T inherits from enable_shared_from_this<T>, it sets up
 // weak_this_ so that shared_from_this works correctly. If T does not inherit
 // from weak_this we get a different overload, defined inline, which does
 // nothing.
 template<typename T>
 void shared_ptr<T>::MaybeSetupWeakThis(enable_shared_from_this<T>* ptr) {
   if (ptr) {
     CHECK(ptr->weak_this_.expired()) << "Object already owned by a shared_ptr";
     ptr->weak_this_ = *this;
   }
 }

 #endif  // UTIL_GTL_USE_STD_SHARED_PTR

 }  // internal
 }  // namespace protobuf
 }  // namespace google

 #endif  // GOOGLE_PROTOBUF_STUBS_SHARED_PTR_H__
	// Protocol Buffers - Google's data interchange format
	// Copyright 2014 Google Inc. All rights reserved.
	// https://developers.google.com/protocol-buffers/
	//
	// 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.
	// * Neither the name of Google Inc. nor the names of its
	// contributors may be used to endorse or promote products derived from
	// this software without specific prior written permission.
	//
	// 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.

	// from google3/util/gtl/shared_ptr.h

	#ifndef GOOGLE_PROTOBUF_STUBS_SHARED_PTR_H__
	#define GOOGLE_PROTOBUF_STUBS_SHARED_PTR_H__

	#include <google/protobuf/stubs/atomicops.h>

	#include <algorithm> // for swap
	#include <stddef.h>
	#include <memory>

	namespace google {
	namespace protobuf {
	namespace internal {

	// Alias to std::shared_ptr for any C++11 platform,
	// and for any supported MSVC compiler.
	#if !defined(UTIL_GTL_USE_STD_SHARED_PTR) && \
	(defined(COMPILER_MSVC) \|\| defined(LANG_CXX11))
	#define UTIL_GTL_USE_STD_SHARED_PTR 1
	#endif

	#if defined(UTIL_GTL_USE_STD_SHARED_PTR) && UTIL_GTL_USE_STD_SHARED_PTR

	// These are transitional. They will be going away soon.
	// Please just #include <memory> and just type std::shared_ptr yourself, instead
	// of relying on this file.
	//
	// Migration doc: http://go/std-shared-ptr-lsc
	using std::enable_shared_from_this;
	using std::shared_ptr;
	using std::static_pointer_cast;
	using std::weak_ptr;

	#else // below, UTIL_GTL_USE_STD_SHARED_PTR not set or set to 0.

	// For everything else there is the google3 implementation.
	inline bool RefCountDec(volatile Atomic32 *ptr) {
	return Barrier_AtomicIncrement(ptr, -1) != 0;
	}

	inline void RefCountInc(volatile Atomic32 *ptr) {
	NoBarrier_AtomicIncrement(ptr, 1);
	}

	template <typename T> class shared_ptr;
	template <typename T> class weak_ptr;

	// This class is an internal implementation detail for shared_ptr. If two
	// shared_ptrs point to the same object, they also share a control block.
	// An "empty" shared_pointer refers to NULL and also has a NULL control block.
	// It contains all of the state that's needed for reference counting or any
	// other kind of resource management. In this implementation the control block
	// happens to consist of two atomic words, the reference count (the number
	// of shared_ptrs that share ownership of the object) and the weak count
	// (the number of weak_ptrs that observe the object, plus 1 if the
	// refcount is nonzero).
	//
	// The "plus 1" is to prevent a race condition in the shared_ptr and
	// weak_ptr destructors. We need to make sure the control block is
	// only deleted once, so we need to make sure that at most one
	// object sees the weak count decremented from 1 to 0.
	class SharedPtrControlBlock {
	template <typename T> friend class shared_ptr;
	template <typename T> friend class weak_ptr;
	private:
	SharedPtrControlBlock() : refcount_(1), weak_count_(1) { }
	Atomic32 refcount_;
	Atomic32 weak_count_;
	};

	// Forward declaration. The class is defined below.
	template <typename T> class enable_shared_from_this;

	template <typename T>
	class shared_ptr {
	template <typename U> friend class weak_ptr;
	public:
	typedef T element_type;

	shared_ptr() : ptr_(NULL), control_block_(NULL) {}

	explicit shared_ptr(T* ptr)
	: ptr_(ptr),
	control_block_(ptr != NULL ? new SharedPtrControlBlock : NULL) {
	// If p is non-null and T inherits from enable_shared_from_this, we
	// set up the data that shared_from_this needs.
	MaybeSetupWeakThis(ptr);
	}

	// Copy constructor: makes this object a copy of ptr, and increments
	// the reference count.
	template <typename U>
	shared_ptr(const shared_ptr<U>& ptr)
	: ptr_(NULL),
	control_block_(NULL) {
	Initialize(ptr);
	}
	// Need non-templated version to prevent the compiler-generated default
	shared_ptr(const shared_ptr<T>& ptr)
	: ptr_(NULL),
	control_block_(NULL) {
	Initialize(ptr);
	}

	// Assignment operator. Replaces the existing shared_ptr with ptr.
	// Increment ptr's reference count and decrement the one being replaced.
	template <typename U>
	shared_ptr<T>& operator=(const shared_ptr<U>& ptr) {
	if (ptr_ != ptr.ptr_) {
	shared_ptr<T> me(ptr); // will hold our previous state to be destroyed.
	swap(me);
	}
	return *this;
	}

	// Need non-templated version to prevent the compiler-generated default
	shared_ptr<T>& operator=(const shared_ptr<T>& ptr) {
	if (ptr_ != ptr.ptr_) {
	shared_ptr<T> me(ptr); // will hold our previous state to be destroyed.
	swap(me);
	}
	return *this;
	}

	// TODO(austern): Consider providing this constructor. The draft C++ standard
	// (20.8.10.2.1) includes it. However, it says that this constructor throws
	// a bad_weak_ptr exception when ptr is expired. Is it better to provide this
	// constructor and make it do something else, like fail with a CHECK, or to
	// leave this constructor out entirely?
	//
	// template <typename U>
	// shared_ptr(const weak_ptr<U>& ptr);

	~shared_ptr() {
	if (ptr_ != NULL) {
	if (!RefCountDec(&control_block_->refcount_)) {
	delete ptr_;

	// weak_count_ is defined as the number of weak_ptrs that observe
	// ptr_, plus 1 if refcount_ is nonzero.
	if (!RefCountDec(&control_block_->weak_count_)) {
	delete control_block_;
	}
	}
	}
	}

	// Replaces underlying raw pointer with the one passed in. The reference
	// count is set to one (or zero if the pointer is NULL) for the pointer
	// being passed in and decremented for the one being replaced.
	//
	// If you have a compilation error with this code, make sure you aren't
	// passing NULL, nullptr, or 0 to this function. Call reset without an
	// argument to reset to a null ptr.
	template <typename Y>
	void reset(Y* p) {
	if (p != ptr_) {
	shared_ptr<T> tmp(p);
	tmp.swap(*this);
	}
	}

	void reset() {
	reset(static_cast<T*>(NULL));
	}

	// Exchanges the contents of this with the contents of r. This function
	// supports more efficient swapping since it eliminates the need for a
	// temporary shared_ptr object.
	void swap(shared_ptr<T>& r) {
	using std::swap; // http://go/using-std-swap
	swap(ptr_, r.ptr_);
	swap(control_block_, r.control_block_);
	}

	// The following function is useful for gaining access to the underlying
	// pointer when a shared_ptr remains in scope so the reference-count is
	// known to be > 0 (e.g. for parameter passing).
	T* get() const {
	return ptr_;
	}

	T& operator*() const {
	return *ptr_;
	}

	T* operator->() const {
	return ptr_;
	}

	long use_count() const {
	return control_block_ ? control_block_->refcount_ : 1;
	}

	bool unique() const {
	return use_count() == 1;
	}

	private:
	// If r is non-empty, initialize *this to share ownership with r,
	// increasing the underlying reference count.
	// If r is empty, *this remains empty.
	// Requires: this is empty, namely this->ptr_ == NULL.
	template <typename U>
	void Initialize(const shared_ptr<U>& r) {
	// This performs a static_cast on r.ptr_ to U*, which is a no-op since it
	// is already a U*. So initialization here requires that r.ptr_ is
	// implicitly convertible to T*.
	InitializeWithStaticCast<U>(r);
	}

	// Initializes *this as described in Initialize, but additionally performs a
	// static_cast from r.ptr_ (V) to U.
	// NOTE(gfc): We'd need a more general form to support const_pointer_cast and
	// dynamic_pointer_cast, but those operations are sufficiently discouraged
	// that supporting static_pointer_cast is sufficient.
	template <typename U, typename V>
	void InitializeWithStaticCast(const shared_ptr<V>& r) {
	if (r.control_block_ != NULL) {
	RefCountInc(&r.control_block_->refcount_);

	ptr_ = static_cast<U*>(r.ptr_);
	control_block_ = r.control_block_;
	}
	}

	// Helper function for the constructor that takes a raw pointer. If T
	// doesn't inherit from enable_shared_from_this<T> then we have nothing to
	// do, so this function is trivial and inline. The other version is declared
	// out of line, after the class definition of enable_shared_from_this.
	void MaybeSetupWeakThis(enable_shared_from_this<T>* ptr);
	void MaybeSetupWeakThis(...) { }

	T* ptr_;
	SharedPtrControlBlock* control_block_;

	#ifndef SWIG
	template <typename U>
	friend class shared_ptr;

	template <typename U, typename V>
	friend shared_ptr<U> static_pointer_cast(const shared_ptr<V>& rhs);
	#endif
	};

	// Matches the interface of std::swap as an aid to generic programming.
	template <typename T> void swap(shared_ptr<T>& r, shared_ptr<T>& s) {
	r.swap(s);
	}

	template <typename T, typename U>
	shared_ptr<T> static_pointer_cast(const shared_ptr<U>& rhs) {
	shared_ptr<T> lhs;
	lhs.template InitializeWithStaticCast<T>(rhs);
	return lhs;
	}

	// See comments at the top of the file for a description of why this
	// class exists, and the draft C++ standard (as of July 2009 the
	// latest draft is N2914) for the detailed specification.
	template <typename T>
	class weak_ptr {
	template <typename U> friend class weak_ptr;
	public:
	typedef T element_type;

	// Create an empty (i.e. already expired) weak_ptr.
	weak_ptr() : ptr_(NULL), control_block_(NULL) { }

	// Create a weak_ptr that observes the same object that ptr points
	// to. Note that there is no race condition here: we know that the
	// control block can't disappear while we're looking at it because
	// it is owned by at least one shared_ptr, ptr.
	template <typename U> weak_ptr(const shared_ptr<U>& ptr) {
	CopyFrom(ptr.ptr_, ptr.control_block_);
	}

	// Copy a weak_ptr. The object it points to might disappear, but we
	// don't care: we're only working with the control block, and it can't
	// disappear while we're looking at because it's owned by at least one
	// weak_ptr, ptr.
	template <typename U> weak_ptr(const weak_ptr<U>& ptr) {
	CopyFrom(ptr.ptr_, ptr.control_block_);
	}

	// Need non-templated version to prevent default copy constructor
	weak_ptr(const weak_ptr& ptr) {
	CopyFrom(ptr.ptr_, ptr.control_block_);
	}

	// Destroy the weak_ptr. If no shared_ptr owns the control block, and if
	// we are the last weak_ptr to own it, then it can be deleted. Note that
	// weak_count_ is defined as the number of weak_ptrs sharing this control
	// block, plus 1 if there are any shared_ptrs. We therefore know that it's
	// safe to delete the control block when weak_count_ reaches 0, without
	// having to perform any additional tests.
	~weak_ptr() {
	if (control_block_ != NULL &&
	!RefCountDec(&control_block_->weak_count_)) {
	delete control_block_;
	}
	}

	weak_ptr& operator=(const weak_ptr& ptr) {
	if (&ptr != this) {
	weak_ptr tmp(ptr);
	tmp.swap(*this);
	}
	return *this;
	}
	template <typename U> weak_ptr& operator=(const weak_ptr<U>& ptr) {
	weak_ptr tmp(ptr);
	tmp.swap(*this);
	return *this;
	}
	template <typename U> weak_ptr& operator=(const shared_ptr<U>& ptr) {
	weak_ptr tmp(ptr);
	tmp.swap(*this);
	return *this;
	}

	void swap(weak_ptr& ptr) {
	using std::swap; // http://go/using-std-swap
	swap(ptr_, ptr.ptr_);
	swap(control_block_, ptr.control_block_);
	}

	void reset() {
	weak_ptr tmp;
	tmp.swap(*this);
	}

	// Return the number of shared_ptrs that own the object we are observing.
	// Note that this number can be 0 (if this pointer has expired).
	long use_count() const {
	return control_block_ != NULL ? control_block_->refcount_ : 0;
	}

	bool expired() const { return use_count() == 0; }

	// Return a shared_ptr that owns the object we are observing. If we
	// have expired, the shared_ptr will be empty. We have to be careful
	// about concurrency, though, since some other thread might be
	// destroying the last owning shared_ptr while we're in this
	// function. We want to increment the refcount only if it's nonzero
	// and get the new value, and we want that whole operation to be
	// atomic.
	shared_ptr<T> lock() const {
	shared_ptr<T> result;
	if (control_block_ != NULL) {
	Atomic32 old_refcount;
	do {
	old_refcount = control_block_->refcount_;
	if (old_refcount == 0)
	break;
	} while (old_refcount !=
	NoBarrier_CompareAndSwap(
	&control_block_->refcount_, old_refcount,
	old_refcount + 1));
	if (old_refcount > 0) {
	result.ptr_ = ptr_;
	result.control_block_ = control_block_;
	}
	}

	return result;
	}

	private:
	void CopyFrom(T* ptr, SharedPtrControlBlock* control_block) {
	ptr_ = ptr;
	control_block_ = control_block;
	if (control_block_ != NULL)
	RefCountInc(&control_block_->weak_count_);
	}

	private:
	element_type* ptr_;
	SharedPtrControlBlock* control_block_;
	};

	template <typename T> void swap(weak_ptr<T>& r, weak_ptr<T>& s) {
	r.swap(s);
	}

	// See comments at the top of the file for a description of why this class
	// exists, and section 20.8.10.5 of the draft C++ standard (as of July 2009
	// the latest draft is N2914) for the detailed specification.
	template <typename T>
	class enable_shared_from_this {
	friend class shared_ptr<T>;
	public:
	// Precondition: there must be a shared_ptr that owns *this and that was
	// created, directly or indirectly, from a raw pointer of type T*. (The
	// latter part of the condition is technical but not quite redundant; it
	// rules out some complicated uses involving inheritance hierarchies.)
	shared_ptr<T> shared_from_this() {
	// Behavior is undefined if the precondition isn't satisfied; we choose
	// to die with a CHECK failure.
	CHECK(!weak_this_.expired()) << "No shared_ptr owns this object";
	return weak_this_.lock();
	}
	shared_ptr<const T> shared_from_this() const {
	CHECK(!weak_this_.expired()) << "No shared_ptr owns this object";
	return weak_this_.lock();
	}

	protected:
	enable_shared_from_this() { }
	enable_shared_from_this(const enable_shared_from_this& other) { }
	enable_shared_from_this& operator=(const enable_shared_from_this& other) {
	return *this;
	}
	~enable_shared_from_this() { }

	private:
	weak_ptr<T> weak_this_;
	};

	// This is a helper function called by shared_ptr's constructor from a raw
	// pointer. If T inherits from enable_shared_from_this<T>, it sets up
	// weak_this_ so that shared_from_this works correctly. If T does not inherit
	// from weak_this we get a different overload, defined inline, which does
	// nothing.
	template<typename T>
	void shared_ptr<T>::MaybeSetupWeakThis(enable_shared_from_this<T>* ptr) {
	if (ptr) {
	CHECK(ptr->weak_this_.expired()) << "Object already owned by a shared_ptr";
	ptr->weak_this_ = *this;
	}
	}

	#endif // UTIL_GTL_USE_STD_SHARED_PTR

	} // internal
	} // namespace protobuf
	} // namespace google

	#endif // GOOGLE_PROTOBUF_STUBS_SHARED_PTR_H__