src/starboard/common/scoped_ptr.h - cobalt - Git at Google

 // 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.

 // Scopers help you manage ownership of a pointer, helping you easily manage the
 // a pointer within a scope, and automatically destroying the pointer at the
 // end of a scope.  There are two main classes you will use, which correspond
 // to the operators new/delete and new[]/delete[].
 //
 // Example usage (scoped_ptr):
 //   {
 //     scoped_ptr<Foo> foo(new Foo("wee"));
 //   }  // foo goes out of scope, releasing the pointer with it.
 //
 //   {
 //     scoped_ptr<Foo> foo;          // No pointer managed.
 //     foo.reset(new Foo("wee"));    // Now a pointer is managed.
 //     foo.reset(new Foo("wee2"));   // Foo("wee") was destroyed.
 //     foo.reset(new Foo("wee3"));   // Foo("wee2") was destroyed.
 //     foo->Method();                // Foo::Method() called.
 //     foo.get()->Method();          // Foo::Method() called.
 //     SomeFunc(foo.release());      // SomeFunc takes ownership, foo no longer
 //                                   // manages a pointer.
 //     foo.reset(new Foo("wee4"));   // foo manages a pointer again.
 //     foo.reset();                  // Foo("wee4") destroyed, foo no longer
 //                                   // manages a pointer.
 //   }  // foo wasn't managing a pointer, so nothing was destroyed.
 //
 // Example usage (scoped_array):
 //   {
 //     scoped_array<Foo> foo(new Foo[100]);
 //     foo.get()->Method();  // Foo::Method on the 0th element.
 //     foo[10].Method();     // Foo::Method on the 10th element.
 //   }
 //
 // These scopers also implement part of the functionality of C++11 unique_ptr
 // in that they are "movable but not copyable."  You can use the scopers in
 // the parameter and return types of functions to signify ownership transfer
 // in to and out of a function.  When calling a function that has a scoper
 // as the argument type, it must be called with the result of an analogous
 // scoper's Pass() function or another function that generates a temporary;
 // passing by copy will NOT work.  Here is an example using scoped_ptr:
 //
 //   void TakesOwnership(scoped_ptr<Foo> arg) {
 //     // Do something with arg
 //   }
 //   scoped_ptr<Foo> CreateFoo() {
 //     // No need for calling Pass() because we are constructing a temporary
 //     // for the return value.
 //     return scoped_ptr<Foo>(new Foo("new"));
 //   }
 //   scoped_ptr<Foo> PassThru(scoped_ptr<Foo> arg) {
 //     return arg.Pass();
 //   }
 //
 //   {
 //     scoped_ptr<Foo> ptr(new Foo("yay"));  // ptr manages Foo("yay").
 //     TakesOwnership(ptr.Pass());           // ptr no longer owns Foo("yay").
 //     scoped_ptr<Foo> ptr2 = CreateFoo();   // ptr2 owns the return Foo.
 //     scoped_ptr<Foo> ptr3 =                // ptr3 now owns what was in ptr2.
 //         PassThru(ptr2.Pass());            // ptr2 is correspondingly NULL.
 //   }
 //
 // Notice that if you do not call Pass() when returning from PassThru(), or
 // when invoking TakesOwnership(), the code will not compile because scopers
 // are not copyable; they only implement move semantics which require calling
 // the Pass() function to signify a destructive transfer of state. CreateFoo()
 // is different though because we are constructing a temporary on the return
 // line and thus can avoid needing to call Pass().
 //
 // Pass() properly handles upcast in assignment, i.e. you can assign
 // scoped_ptr<Child> to scoped_ptr<Parent>:
 //
 //   scoped_ptr<Foo> foo(new Foo());
 //   scoped_ptr<FooParent> parent = foo.Pass();
 //
 // PassAs<>() should be used to upcast return value in return statement:
 //
 //   scoped_ptr<Foo> CreateFoo() {
 //     scoped_ptr<FooChild> result(new FooChild());
 //     return result.PassAs<Foo>();
 //   }
 //
 // Note that PassAs<>() is implemented only for scoped_ptr, but not for
 // scoped_array. This is because casting array pointers may not be safe.

 #ifndef STARBOARD_COMMON_SCOPED_PTR_H_
 #define STARBOARD_COMMON_SCOPED_PTR_H_

 // This is an implementation designed to match the anticipated future TR2
 // implementation of the scoped_ptr class, and its closely-related brethren,
 // scoped_array, scoped_ptr_malloc.

 #include <algorithm>

 #include "starboard/common/log.h"
 #include "starboard/common/move.h"
 #include "starboard/memory.h"
 #include "starboard/types.h"

 namespace starboard {

 // A scoped_ptr<T> is like a T*, except that the destructor of scoped_ptr<T>
 // automatically deletes the pointer it holds (if any).
 // That is, scoped_ptr<T> owns the T object that it points to.
 // Like a T*, a scoped_ptr<T> may hold either NULL or a pointer to a T object.
 // Also like T*, scoped_ptr<T> is thread-compatible, and once you
 // dereference it, you get the thread safety guarantees of T.
 //
 // The size of a scoped_ptr is small:
 // sizeof(scoped_ptr<C>) == sizeof(C*)
 template <class C>
 class scoped_ptr {
   MOVE_ONLY_TYPE_FOR_CPP_03(scoped_ptr, RValue)

  public:
   // The element type
   typedef C element_type;

   // Constructor.  Defaults to initializing with NULL.
   // There is no way to create an uninitialized scoped_ptr.
   // The input parameter must be allocated with new.
   explicit scoped_ptr(C* p = NULL) : ptr_(p) {}

 // The GHS compiler always chooses this copy constructor over the next one,
 // so disable this to promote the more important and frequently used constr.
 #if !defined(COMPILER_GHS)
   // Constructor.  Allows construction from a scoped_ptr rvalue for a
   // convertible type.
   template <typename U>
   scoped_ptr(scoped_ptr<U> other)
       : ptr_(other.release()) {}
 #endif

   // Constructor.  Move constructor for C++03 move emulation of this type.
   scoped_ptr(RValue rvalue) : ptr_(rvalue.object->release()) {}

   // Destructor.  If there is a C object, delete it.
   // We don't need to test ptr_ == NULL because C++ does that for us.
   ~scoped_ptr() {
     enum { type_must_be_complete = sizeof(C) };
     delete ptr_;
   }

   // operator=.  Allows assignment from a scoped_ptr rvalue for a convertible
   // type.
   template <typename U>
   scoped_ptr& operator=(scoped_ptr<U> rhs) {
     reset(rhs.release());
     return *this;
   }

   // operator=.  Move operator= for C++03 move emulation of this type.
   scoped_ptr& operator=(RValue rhs) {
     swap(*rhs->object);
     return *this;
   }

   // Reset.  Deletes the current owned object, if any.
   // Then takes ownership of a new object, if given.
   // this->reset(this->get()) works.
   void reset(C* p = NULL) {
     if (p != ptr_) {
       enum { type_must_be_complete = sizeof(C) };
       delete ptr_;
       ptr_ = p;
     }
   }

   // Accessors to get the owned object.
   // operator* and operator-> will SB_DCHECK() if there is no current object.
   C& operator*() const {
     SB_DCHECK(ptr_ != NULL);
     return *ptr_;
   }
   C* operator->() const {
     SB_DCHECK(ptr_ != NULL);
     return ptr_;
   }
   C* get() const { return ptr_; }

   // Allow scoped_ptr<C> to be used in boolean expressions, but not
   // implicitly convertible to a real bool (which is dangerous).
   typedef C* scoped_ptr::*Testable;
   operator Testable() const { return ptr_ ? &scoped_ptr::ptr_ : NULL; }

   // Comparison operators.
   // These return whether two scoped_ptr refer to the same object, not just to
   // two different but equal objects.
   bool operator==(C* p) const { return ptr_ == p; }
   bool operator!=(C* p) const { return ptr_ != p; }

   // Swap two scoped pointers.
   void swap(scoped_ptr& p2) {
     C* tmp = ptr_;
     ptr_ = p2.ptr_;
     p2.ptr_ = tmp;
   }

   // Release a pointer.
   // The return value is the current pointer held by this object.
   // If this object holds a NULL pointer, the return value is NULL.
   // After this operation, this object will hold a NULL pointer,
   // and will not own the object any more.
   C* release() {
     C* retVal = ptr_;
     ptr_ = NULL;
     return retVal;
   }

   template <typename PassAsType>
   scoped_ptr<PassAsType> PassAs() {
     return scoped_ptr<PassAsType>(release());
   }

  private:
   C* ptr_;

   // Forbid comparison of scoped_ptr types.  If C2 != C, it totally doesn't
   // make sense, and if C2 == C, it still doesn't make sense because you should
   // never have the same object owned by two different scoped_ptrs.
   template <class C2>
   bool operator==(scoped_ptr<C2> const& p2) const;
   template <class C2>
   bool operator!=(scoped_ptr<C2> const& p2) const;
 };

 // Free functions
 template <class C>
 void swap(scoped_ptr<C>& p1, scoped_ptr<C>& p2) {
   p1.swap(p2);
 }

 template <class C>
 bool operator==(C* p1, const scoped_ptr<C>& p2) {
   return p1 == p2.get();
 }

 template <class C>
 bool operator!=(C* p1, const scoped_ptr<C>& p2) {
   return p1 != p2.get();
 }

 // scoped_array<C> is like scoped_ptr<C>, except that the caller must allocate
 // with new [] and the destructor deletes objects with delete [].
 //
 // As with scoped_ptr<C>, a scoped_array<C> either points to an object
 // or is NULL.  A scoped_array<C> owns the object that it points to.
 // scoped_array<T> is thread-compatible, and once you index into it,
 // the returned objects have only the thread safety guarantees of T.
 //
 // Size: sizeof(scoped_array<C>) == sizeof(C*)
 template <class C>
 class scoped_array {
   MOVE_ONLY_TYPE_FOR_CPP_03(scoped_array, RValue)

  public:
   // The element type
   typedef C element_type;

   // Constructor.  Defaults to initializing with NULL.
   // There is no way to create an uninitialized scoped_array.
   // The input parameter must be allocated with new [].
   explicit scoped_array(C* p = NULL) : array_(p) {}

   // Constructor.  Move constructor for C++03 move emulation of this type.
   scoped_array(RValue rvalue) : array_(rvalue.object->release()) {}

   // Destructor.  If there is a C object, delete it.
   // We don't need to test ptr_ == NULL because C++ does that for us.
   ~scoped_array() {
     enum { type_must_be_complete = sizeof(C) };
     delete[] array_;
   }

   // operator=.  Move operator= for C++03 move emulation of this type.
   scoped_array& operator=(RValue rhs) {
     swap(*rhs.object);
     return *this;
   }

   // Reset.  Deletes the current owned object, if any.
   // Then takes ownership of a new object, if given.
   // this->reset(this->get()) works.
   void reset(C* p = NULL) {
     if (p != array_) {
       enum { type_must_be_complete = sizeof(C) };
       delete[] array_;
       array_ = p;
     }
   }

   // Get one element of the current object.
   // Will SB_DCHECK() if there is no current object, or index i is negative.
   C& operator[](ptrdiff_t i) const {
     SB_DCHECK(i >= 0);
     SB_DCHECK(array_ != NULL);
     return array_[i];
   }

   // Get a pointer to the zeroth element of the current object.
   // If there is no current object, return NULL.
   C* get() const { return array_; }

   // Allow scoped_array<C> to be used in boolean expressions, but not
   // implicitly convertible to a real bool (which is dangerous).
   typedef C* scoped_array::*Testable;
   operator Testable() const { return array_ ? &scoped_array::array_ : NULL; }

   // Comparison operators.
   // These return whether two scoped_array refer to the same object, not just to
   // two different but equal objects.
   bool operator==(C* p) const { return array_ == p; }
   bool operator!=(C* p) const { return array_ != p; }

   // Swap two scoped arrays.
   void swap(scoped_array& p2) {
     C* tmp = array_;
     array_ = p2.array_;
     p2.array_ = tmp;
   }

   // Release an array.
   // The return value is the current pointer held by this object.
   // If this object holds a NULL pointer, the return value is NULL.
   // After this operation, this object will hold a NULL pointer,
   // and will not own the object any more.
   C* release() {
     C* retVal = array_;
     array_ = NULL;
     return retVal;
   }

  private:
   C* array_;

   // Forbid comparison of different scoped_array types.
   template <class C2>
   bool operator==(scoped_array<C2> const& p2) const;
   template <class C2>
   bool operator!=(scoped_array<C2> const& p2) const;
 };

 // Free functions
 template <class C>
 void swap(scoped_array<C>& p1, scoped_array<C>& p2) {
   p1.swap(p2);
 }

 template <class C>
 bool operator==(C* p1, const scoped_array<C>& p2) {
   return p1 == p2.get();
 }

 template <class C>
 bool operator!=(C* p1, const scoped_array<C>& p2) {
   return p1 != p2.get();
 }

 // This class wraps the SbMemoryDeallocate() function in a class that can be
 // passed as a template argument to scoped_ptr_malloc below.
 class ScopedPtrMallocFree {
  public:
   inline void operator()(void* x) const { SbMemoryDeallocate(x); }
 };

 // This class wraps the SbMemoryDeallocateAligned() function in a class that
 // can be passed as a template argument to scoped_ptr_malloc below.
 class ScopedPtrMallocFreeAligned {
  public:
   inline void operator()(void* x) const { SbMemoryDeallocateAligned(x); }
 };

 // scoped_ptr_malloc<> is similar to scoped_ptr<>, but it accepts a
 // second template argument, the functor used to free the object.

 template <class C, class FreeProc = ScopedPtrMallocFree>
 class scoped_ptr_malloc {
   MOVE_ONLY_TYPE_FOR_CPP_03(scoped_ptr_malloc, RValue)

  public:
   // The element type
   typedef C element_type;

   // Constructor.  Defaults to initializing with NULL.
   // There is no way to create an uninitialized scoped_ptr.
   // The input parameter must be allocated with an allocator that matches the
   // Free functor.  For the default Free functor, this is malloc, calloc, or
   // realloc.
   explicit scoped_ptr_malloc(C* p = NULL) : ptr_(p) {}

   // Constructor.  Move constructor for C++03 move emulation of this type.
   scoped_ptr_malloc(RValue rvalue) : ptr_(rvalue.object->release()) {}

   // Destructor.  If there is a C object, call the Free functor.
   ~scoped_ptr_malloc() { reset(); }

   // operator=.  Move operator= for C++03 move emulation of this type.
   scoped_ptr_malloc& operator=(RValue rhs) {
     swap(*rhs.object);
     return *this;
   }

   // Reset.  Calls the Free functor on the current owned object, if any.
   // Then takes ownership of a new object, if given.
   // this->reset(this->get()) works.
   void reset(C* p = NULL) {
     if (ptr_ != p) {
       FreeProc free_proc;
       free_proc(ptr_);
       ptr_ = p;
     }
   }

   // Get the current object.
   // operator* and operator-> will cause an SB_DCHECK() failure if there is
   // no current object.
   C& operator*() const {
     SB_DCHECK(ptr_ != NULL);
     return *ptr_;
   }

   C* operator->() const {
     SB_DCHECK(ptr_ != NULL);
     return ptr_;
   }

   C* get() const { return ptr_; }

   // Allow scoped_ptr_malloc<C> to be used in boolean expressions, but not
   // implicitly convertible to a real bool (which is dangerous).
   typedef C* scoped_ptr_malloc::*Testable;
   operator Testable() const { return ptr_ ? &scoped_ptr_malloc::ptr_ : NULL; }

   // Comparison operators.
   // These return whether a scoped_ptr_malloc and a plain pointer refer
   // to the same object, not just to two different but equal objects.
   // For compatibility with the boost-derived implementation, these
   // take non-const arguments.
   bool operator==(C* p) const { return ptr_ == p; }

   bool operator!=(C* p) const { return ptr_ != p; }

   // Swap two scoped pointers.
   void swap(scoped_ptr_malloc& b) {
     C* tmp = b.ptr_;
     b.ptr_ = ptr_;
     ptr_ = tmp;
   }

   // Release a pointer.
   // The return value is the current pointer held by this object.
   // If this object holds a NULL pointer, the return value is NULL.
   // After this operation, this object will hold a NULL pointer,
   // and will not own the object any more.
   C* release() {
     C* tmp = ptr_;
     ptr_ = NULL;
     return tmp;
   }

  private:
   C* ptr_;

   // no reason to use these: each scoped_ptr_malloc should have its own object
   template <class C2, class GP>
   bool operator==(scoped_ptr_malloc<C2, GP> const& p) const;
   template <class C2, class GP>
   bool operator!=(scoped_ptr_malloc<C2, GP> const& p) const;
 };

 template <class C, class FP>
 inline void swap(scoped_ptr_malloc<C, FP>& a, scoped_ptr_malloc<C, FP>& b) {
   a.swap(b);
 }

 template <class C, class FP>
 inline bool operator==(C* p, const scoped_ptr_malloc<C, FP>& b) {
   return p == b.get();
 }

 template <class C, class FP>
 inline bool operator!=(C* p, const scoped_ptr_malloc<C, FP>& b) {
   return p != b.get();
 }

 // A function to convert T* into scoped_ptr<T>
 // Doing e.g. make_scoped_ptr(new FooBarBaz<type>(arg)) is a shorter notation
 // for scoped_ptr<FooBarBaz<type> >(new FooBarBaz<type>(arg))
 template <typename T>
 scoped_ptr<T> make_scoped_ptr(T* ptr) {
   return scoped_ptr<T>(ptr);
 }

 }  // namespace starboard

 #endif  // STARBOARD_COMMON_SCOPED_PTR_H_
	// 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.

	// Scopers help you manage ownership of a pointer, helping you easily manage the
	// a pointer within a scope, and automatically destroying the pointer at the
	// end of a scope. There are two main classes you will use, which correspond
	// to the operators new/delete and new[]/delete[].
	//
	// Example usage (scoped_ptr):
	// {
	// scoped_ptr<Foo> foo(new Foo("wee"));
	// } // foo goes out of scope, releasing the pointer with it.
	//
	// {
	// scoped_ptr<Foo> foo; // No pointer managed.
	// foo.reset(new Foo("wee")); // Now a pointer is managed.
	// foo.reset(new Foo("wee2")); // Foo("wee") was destroyed.
	// foo.reset(new Foo("wee3")); // Foo("wee2") was destroyed.
	// foo->Method(); // Foo::Method() called.
	// foo.get()->Method(); // Foo::Method() called.
	// SomeFunc(foo.release()); // SomeFunc takes ownership, foo no longer
	// // manages a pointer.
	// foo.reset(new Foo("wee4")); // foo manages a pointer again.
	// foo.reset(); // Foo("wee4") destroyed, foo no longer
	// // manages a pointer.
	// } // foo wasn't managing a pointer, so nothing was destroyed.
	//
	// Example usage (scoped_array):
	// {
	// scoped_array<Foo> foo(new Foo[100]);
	// foo.get()->Method(); // Foo::Method on the 0th element.
	// foo[10].Method(); // Foo::Method on the 10th element.
	// }
	//
	// These scopers also implement part of the functionality of C++11 unique_ptr
	// in that they are "movable but not copyable." You can use the scopers in
	// the parameter and return types of functions to signify ownership transfer
	// in to and out of a function. When calling a function that has a scoper
	// as the argument type, it must be called with the result of an analogous
	// scoper's Pass() function or another function that generates a temporary;
	// passing by copy will NOT work. Here is an example using scoped_ptr:
	//
	// void TakesOwnership(scoped_ptr<Foo> arg) {
	// // Do something with arg
	// }
	// scoped_ptr<Foo> CreateFoo() {
	// // No need for calling Pass() because we are constructing a temporary
	// // for the return value.
	// return scoped_ptr<Foo>(new Foo("new"));
	// }
	// scoped_ptr<Foo> PassThru(scoped_ptr<Foo> arg) {
	// return arg.Pass();
	// }
	//
	// {
	// scoped_ptr<Foo> ptr(new Foo("yay")); // ptr manages Foo("yay").
	// TakesOwnership(ptr.Pass()); // ptr no longer owns Foo("yay").
	// scoped_ptr<Foo> ptr2 = CreateFoo(); // ptr2 owns the return Foo.
	// scoped_ptr<Foo> ptr3 = // ptr3 now owns what was in ptr2.
	// PassThru(ptr2.Pass()); // ptr2 is correspondingly NULL.
	// }
	//
	// Notice that if you do not call Pass() when returning from PassThru(), or
	// when invoking TakesOwnership(), the code will not compile because scopers
	// are not copyable; they only implement move semantics which require calling
	// the Pass() function to signify a destructive transfer of state. CreateFoo()
	// is different though because we are constructing a temporary on the return
	// line and thus can avoid needing to call Pass().
	//
	// Pass() properly handles upcast in assignment, i.e. you can assign
	// scoped_ptr<Child> to scoped_ptr<Parent>:
	//
	// scoped_ptr<Foo> foo(new Foo());
	// scoped_ptr<FooParent> parent = foo.Pass();
	//
	// PassAs<>() should be used to upcast return value in return statement:
	//
	// scoped_ptr<Foo> CreateFoo() {
	// scoped_ptr<FooChild> result(new FooChild());
	// return result.PassAs<Foo>();
	// }
	//
	// Note that PassAs<>() is implemented only for scoped_ptr, but not for
	// scoped_array. This is because casting array pointers may not be safe.

	#ifndef STARBOARD_COMMON_SCOPED_PTR_H_
	#define STARBOARD_COMMON_SCOPED_PTR_H_

	// This is an implementation designed to match the anticipated future TR2
	// implementation of the scoped_ptr class, and its closely-related brethren,
	// scoped_array, scoped_ptr_malloc.

	#include <algorithm>

	#include "starboard/common/log.h"
	#include "starboard/common/move.h"
	#include "starboard/memory.h"
	#include "starboard/types.h"

	namespace starboard {

	// A scoped_ptr<T> is like a T*, except that the destructor of scoped_ptr<T>
	// automatically deletes the pointer it holds (if any).
	// That is, scoped_ptr<T> owns the T object that it points to.
	// Like a T*, a scoped_ptr<T> may hold either NULL or a pointer to a T object.
	// Also like T*, scoped_ptr<T> is thread-compatible, and once you
	// dereference it, you get the thread safety guarantees of T.
	//
	// The size of a scoped_ptr is small:
	// sizeof(scoped_ptr<C>) == sizeof(C*)
	template <class C>
	class scoped_ptr {
	MOVE_ONLY_TYPE_FOR_CPP_03(scoped_ptr, RValue)

	public:
	// The element type
	typedef C element_type;

	// Constructor. Defaults to initializing with NULL.
	// There is no way to create an uninitialized scoped_ptr.
	// The input parameter must be allocated with new.
	explicit scoped_ptr(C* p = NULL) : ptr_(p) {}

	// The GHS compiler always chooses this copy constructor over the next one,
	// so disable this to promote the more important and frequently used constr.
	#if !defined(COMPILER_GHS)
	// Constructor. Allows construction from a scoped_ptr rvalue for a
	// convertible type.
	template <typename U>
	scoped_ptr(scoped_ptr<U> other)
	: ptr_(other.release()) {}
	#endif

	// Constructor. Move constructor for C++03 move emulation of this type.
	scoped_ptr(RValue rvalue) : ptr_(rvalue.object->release()) {}

	// Destructor. If there is a C object, delete it.
	// We don't need to test ptr_ == NULL because C++ does that for us.
	~scoped_ptr() {
	enum { type_must_be_complete = sizeof(C) };
	delete ptr_;
	}

	// operator=. Allows assignment from a scoped_ptr rvalue for a convertible
	// type.
	template <typename U>
	scoped_ptr& operator=(scoped_ptr<U> rhs) {
	reset(rhs.release());
	return *this;
	}

	// operator=. Move operator= for C++03 move emulation of this type.
	scoped_ptr& operator=(RValue rhs) {
	swap(*rhs->object);
	return *this;
	}

	// Reset. Deletes the current owned object, if any.
	// Then takes ownership of a new object, if given.
	// this->reset(this->get()) works.
	void reset(C* p = NULL) {
	if (p != ptr_) {
	enum { type_must_be_complete = sizeof(C) };
	delete ptr_;
	ptr_ = p;
	}
	}

	// Accessors to get the owned object.
	// operator* and operator-> will SB_DCHECK() if there is no current object.
	C& operator*() const {
	SB_DCHECK(ptr_ != NULL);
	return *ptr_;
	}
	C* operator->() const {
	SB_DCHECK(ptr_ != NULL);
	return ptr_;
	}
	C* get() const { return ptr_; }

	// Allow scoped_ptr<C> to be used in boolean expressions, but not
	// implicitly convertible to a real bool (which is dangerous).
	typedef C* scoped_ptr::*Testable;
	operator Testable() const { return ptr_ ? &scoped_ptr::ptr_ : NULL; }

	// Comparison operators.
	// These return whether two scoped_ptr refer to the same object, not just to
	// two different but equal objects.
	bool operator==(C* p) const { return ptr_ == p; }
	bool operator!=(C* p) const { return ptr_ != p; }

	// Swap two scoped pointers.
	void swap(scoped_ptr& p2) {
	C* tmp = ptr_;
	ptr_ = p2.ptr_;
	p2.ptr_ = tmp;
	}

	// Release a pointer.
	// The return value is the current pointer held by this object.
	// If this object holds a NULL pointer, the return value is NULL.
	// After this operation, this object will hold a NULL pointer,
	// and will not own the object any more.
	C* release() {
	C* retVal = ptr_;
	ptr_ = NULL;
	return retVal;
	}

	template <typename PassAsType>
	scoped_ptr<PassAsType> PassAs() {
	return scoped_ptr<PassAsType>(release());
	}

	private:
	C* ptr_;

	// Forbid comparison of scoped_ptr types. If C2 != C, it totally doesn't
	// make sense, and if C2 == C, it still doesn't make sense because you should
	// never have the same object owned by two different scoped_ptrs.
	template <class C2>
	bool operator==(scoped_ptr<C2> const& p2) const;
	template <class C2>
	bool operator!=(scoped_ptr<C2> const& p2) const;
	};

	// Free functions
	template <class C>
	void swap(scoped_ptr<C>& p1, scoped_ptr<C>& p2) {
	p1.swap(p2);
	}

	template <class C>
	bool operator==(C* p1, const scoped_ptr<C>& p2) {
	return p1 == p2.get();
	}

	template <class C>
	bool operator!=(C* p1, const scoped_ptr<C>& p2) {
	return p1 != p2.get();
	}

	// scoped_array<C> is like scoped_ptr<C>, except that the caller must allocate
	// with new [] and the destructor deletes objects with delete [].
	//
	// As with scoped_ptr<C>, a scoped_array<C> either points to an object
	// or is NULL. A scoped_array<C> owns the object that it points to.
	// scoped_array<T> is thread-compatible, and once you index into it,
	// the returned objects have only the thread safety guarantees of T.
	//
	// Size: sizeof(scoped_array<C>) == sizeof(C*)
	template <class C>
	class scoped_array {
	MOVE_ONLY_TYPE_FOR_CPP_03(scoped_array, RValue)

	public:
	// The element type
	typedef C element_type;

	// Constructor. Defaults to initializing with NULL.
	// There is no way to create an uninitialized scoped_array.
	// The input parameter must be allocated with new [].
	explicit scoped_array(C* p = NULL) : array_(p) {}

	// Constructor. Move constructor for C++03 move emulation of this type.
	scoped_array(RValue rvalue) : array_(rvalue.object->release()) {}

	// Destructor. If there is a C object, delete it.
	// We don't need to test ptr_ == NULL because C++ does that for us.
	~scoped_array() {
	enum { type_must_be_complete = sizeof(C) };
	delete[] array_;
	}

	// operator=. Move operator= for C++03 move emulation of this type.
	scoped_array& operator=(RValue rhs) {
	swap(*rhs.object);
	return *this;
	}

	// Reset. Deletes the current owned object, if any.
	// Then takes ownership of a new object, if given.
	// this->reset(this->get()) works.
	void reset(C* p = NULL) {
	if (p != array_) {
	enum { type_must_be_complete = sizeof(C) };
	delete[] array_;
	array_ = p;
	}
	}

	// Get one element of the current object.
	// Will SB_DCHECK() if there is no current object, or index i is negative.
	C& operator[](ptrdiff_t i) const {
	SB_DCHECK(i >= 0);
	SB_DCHECK(array_ != NULL);
	return array_[i];
	}

	// Get a pointer to the zeroth element of the current object.
	// If there is no current object, return NULL.
	C* get() const { return array_; }

	// Allow scoped_array<C> to be used in boolean expressions, but not
	// implicitly convertible to a real bool (which is dangerous).
	typedef C* scoped_array::*Testable;
	operator Testable() const { return array_ ? &scoped_array::array_ : NULL; }

	// Comparison operators.
	// These return whether two scoped_array refer to the same object, not just to
	// two different but equal objects.
	bool operator==(C* p) const { return array_ == p; }
	bool operator!=(C* p) const { return array_ != p; }

	// Swap two scoped arrays.
	void swap(scoped_array& p2) {
	C* tmp = array_;
	array_ = p2.array_;
	p2.array_ = tmp;
	}

	// Release an array.
	// The return value is the current pointer held by this object.
	// If this object holds a NULL pointer, the return value is NULL.
	// After this operation, this object will hold a NULL pointer,
	// and will not own the object any more.
	C* release() {
	C* retVal = array_;
	array_ = NULL;
	return retVal;
	}

	private:
	C* array_;

	// Forbid comparison of different scoped_array types.
	template <class C2>
	bool operator==(scoped_array<C2> const& p2) const;
	template <class C2>
	bool operator!=(scoped_array<C2> const& p2) const;
	};

	// Free functions
	template <class C>
	void swap(scoped_array<C>& p1, scoped_array<C>& p2) {
	p1.swap(p2);
	}

	template <class C>
	bool operator==(C* p1, const scoped_array<C>& p2) {
	return p1 == p2.get();
	}

	template <class C>
	bool operator!=(C* p1, const scoped_array<C>& p2) {
	return p1 != p2.get();
	}

	// This class wraps the SbMemoryDeallocate() function in a class that can be
	// passed as a template argument to scoped_ptr_malloc below.
	class ScopedPtrMallocFree {
	public:
	inline void operator()(void* x) const { SbMemoryDeallocate(x); }
	};

	// This class wraps the SbMemoryDeallocateAligned() function in a class that
	// can be passed as a template argument to scoped_ptr_malloc below.
	class ScopedPtrMallocFreeAligned {
	public:
	inline void operator()(void* x) const { SbMemoryDeallocateAligned(x); }
	};

	// scoped_ptr_malloc<> is similar to scoped_ptr<>, but it accepts a
	// second template argument, the functor used to free the object.

	template <class C, class FreeProc = ScopedPtrMallocFree>
	class scoped_ptr_malloc {
	MOVE_ONLY_TYPE_FOR_CPP_03(scoped_ptr_malloc, RValue)

	public:
	// The element type
	typedef C element_type;

	// Constructor. Defaults to initializing with NULL.
	// There is no way to create an uninitialized scoped_ptr.
	// The input parameter must be allocated with an allocator that matches the
	// Free functor. For the default Free functor, this is malloc, calloc, or
	// realloc.
	explicit scoped_ptr_malloc(C* p = NULL) : ptr_(p) {}

	// Constructor. Move constructor for C++03 move emulation of this type.
	scoped_ptr_malloc(RValue rvalue) : ptr_(rvalue.object->release()) {}

	// Destructor. If there is a C object, call the Free functor.
	~scoped_ptr_malloc() { reset(); }

	// operator=. Move operator= for C++03 move emulation of this type.
	scoped_ptr_malloc& operator=(RValue rhs) {
	swap(*rhs.object);
	return *this;
	}

	// Reset. Calls the Free functor on the current owned object, if any.
	// Then takes ownership of a new object, if given.
	// this->reset(this->get()) works.
	void reset(C* p = NULL) {
	if (ptr_ != p) {
	FreeProc free_proc;
	free_proc(ptr_);
	ptr_ = p;
	}
	}

	// Get the current object.
	// operator* and operator-> will cause an SB_DCHECK() failure if there is
	// no current object.
	C& operator*() const {
	SB_DCHECK(ptr_ != NULL);
	return *ptr_;
	}

	C* operator->() const {
	SB_DCHECK(ptr_ != NULL);
	return ptr_;
	}

	C* get() const { return ptr_; }

	// Allow scoped_ptr_malloc<C> to be used in boolean expressions, but not
	// implicitly convertible to a real bool (which is dangerous).
	typedef C* scoped_ptr_malloc::*Testable;
	operator Testable() const { return ptr_ ? &scoped_ptr_malloc::ptr_ : NULL; }

	// Comparison operators.
	// These return whether a scoped_ptr_malloc and a plain pointer refer
	// to the same object, not just to two different but equal objects.
	// For compatibility with the boost-derived implementation, these
	// take non-const arguments.
	bool operator==(C* p) const { return ptr_ == p; }

	bool operator!=(C* p) const { return ptr_ != p; }

	// Swap two scoped pointers.
	void swap(scoped_ptr_malloc& b) {
	C* tmp = b.ptr_;
	b.ptr_ = ptr_;
	ptr_ = tmp;
	}

	// Release a pointer.
	// The return value is the current pointer held by this object.
	// If this object holds a NULL pointer, the return value is NULL.
	// After this operation, this object will hold a NULL pointer,
	// and will not own the object any more.
	C* release() {
	C* tmp = ptr_;
	ptr_ = NULL;
	return tmp;
	}

	private:
	C* ptr_;

	// no reason to use these: each scoped_ptr_malloc should have its own object
	template <class C2, class GP>
	bool operator==(scoped_ptr_malloc<C2, GP> const& p) const;
	template <class C2, class GP>
	bool operator!=(scoped_ptr_malloc<C2, GP> const& p) const;
	};

	template <class C, class FP>
	inline void swap(scoped_ptr_malloc<C, FP>& a, scoped_ptr_malloc<C, FP>& b) {
	a.swap(b);
	}

	template <class C, class FP>
	inline bool operator==(C* p, const scoped_ptr_malloc<C, FP>& b) {
	return p == b.get();
	}

	template <class C, class FP>
	inline bool operator!=(C* p, const scoped_ptr_malloc<C, FP>& b) {
	return p != b.get();
	}

	// A function to convert T* into scoped_ptr<T>
	// Doing e.g. make_scoped_ptr(new FooBarBaz<type>(arg)) is a shorter notation
	// for scoped_ptr<FooBarBaz<type> >(new FooBarBaz<type>(arg))
	template <typename T>
	scoped_ptr<T> make_scoped_ptr(T* ptr) {
	return scoped_ptr<T>(ptr);
	}

	} // namespace starboard

	#endif // STARBOARD_COMMON_SCOPED_PTR_H_