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 // 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.

 #ifndef BASE_MOVE_H_
 #define BASE_MOVE_H_

 #include "base/compiler_specific.h"

 // Macro with the boilerplate that makes a type move-only in C++03.
 //
 // USAGE
 //
 // This macro should be used instead of DISALLOW_COPY_AND_ASSIGN to create
 // a "move-only" type.  Unlike DISALLOW_COPY_AND_ASSIGN, this macro should be
 // the first line in a class declaration.
 //
 // A class using this macro must call .Pass() (or somehow be an r-value already)
 // before it can be:
 //
 //   * Passed as a function argument
 //   * Used as the right-hand side of an assignment
 //   * Returned from a function
 //
 // Each class will still need to define their own "move constructor" and "move
 // operator=" to make this useful.  Here's an example of the macro, the move
 // constructor, and the move operator= from the scoped_ptr class:
 //
 //  template <typename T>
 //  class scoped_ptr {
 //     MOVE_ONLY_TYPE_FOR_CPP_03(scoped_ptr, RValue)
 //   public:
 //    scoped_ptr(RValue& other) : ptr_(other.release()) { }
 //    scoped_ptr& operator=(RValue& other) {
 //      swap(other);
 //      return *this;
 //    }
 //  };
 //
 // Note that the constructor must NOT be marked explicit.
 //
 // For consistency, the second parameter to the macro should always be RValue
 // unless you have a strong reason to do otherwise.  It is only exposed as a
 // macro parameter so that the move constructor and move operator= don't look
 // like they're using a phantom type.
 //
 //
 // HOW THIS WORKS
 //
 // For a thorough explanation of this technique, see:
 //
 //   http://en.wikibooks.org/wiki/More_C%2B%2B_Idioms/Move_Constructor
 //
 // The summary is that we take advantage of 2 properties:
 //
 //   1) non-const references will not bind to r-values.
 //   2) C++ can apply one user-defined conversion when initializing a
 //      variable.
 //
 // The first lets us disable the copy constructor and assignment operator
 // by declaring private version of them with a non-const reference parameter.
 //
 // For l-values, direct initialization still fails like in
 // DISALLOW_COPY_AND_ASSIGN because the copy constructor and assignment
 // operators are private.
 //
 // For r-values, the situation is different. The copy constructor and
 // assignment operator are not viable due to (1), so we are trying to call
 // a non-existent constructor and non-existing operator= rather than a private
 // one.  Since we have not committed an error quite yet, we can provide an
 // alternate conversion sequence and a constructor.  We add
 //
 //   * a private struct named "RValue"
 //   * a user-defined conversion "operator RValue()"
 //   * a "move constructor" and "move operator=" that take the RValue& as
 //     their sole parameter.
 //
 // Only r-values will trigger this sequence and execute our "move constructor"
 // or "move operator=."  L-values will match the private copy constructor and
 // operator= first giving a "private in this context" error.  This combination
 // gives us a move-only type.
 //
 // For signaling a destructive transfer of data from an l-value, we provide a
 // method named Pass() which creates an r-value for the current instance
 // triggering the move constructor or move operator=.
 //
 // Other ways to get r-values is to use the result of an expression like a
 // function call.
 //
 // Here's an example with comments explaining what gets triggered where:
 //
 //    class Foo {
 //      MOVE_ONLY_TYPE_FOR_CPP_03(Foo, RValue);
 //
 //     public:
 //       ... API ...
 //       Foo(RValue other);           // Move constructor.
 //       Foo& operator=(RValue rhs);  // Move operator=
 //    };
 //
 //    Foo MakeFoo();  // Function that returns a Foo.
 //
 //    Foo f;
 //    Foo f_copy(f);  // ERROR: Foo(Foo&) is private in this context.
 //    Foo f_assign;
 //    f_assign = f;   // ERROR: operator=(Foo&) is private in this context.
 //
 //
 //    Foo f(MakeFoo());      // R-value so alternate conversion executed.
 //    Foo f_copy(f.Pass());  // R-value so alternate conversion executed.
 //    f = f_copy.Pass();     // R-value so alternate conversion executed.
 //
 //
 // IMPLEMENTATION SUBTLETIES WITH RValue
 //
 // The RValue struct is just a container for a pointer back to the original
 // object. It should only ever be created as a temporary, and no external
 // class should ever declare it or use it in a parameter.
 //
 // It is tempting to want to use the RValue type in function parameters, but
 // excluding the limited usage here for the move constructor and move
 // operator=, doing so would mean that the function could take both r-values
 // and l-values equially which is unexpected.  See COMPARED To Boost.Move for
 // more details.
 //
 // An alternate, and incorrect, implementation of the RValue class used by
 // Boost.Move makes RValue a fieldless child of the move-only type. RValue&
 // is then used in place of RValue in the various operators.  The RValue& is
 // "created" by doing *reinterpret_cast<RValue*>(this).  This has the appeal
 // of never creating a temporary RValue struct even with optimizations
 // disabled.  Also, by virtue of inheritance you can treat the RValue
 // reference as if it were the move-only type itself.  Unfortunately,
 // using the result of this reinterpret_cast<> is actually undefined behavior
 // due to C++98 5.2.10.7. In certain compilers (e.g., NaCl) the optimizer
 // will generate non-working code.
 //
 // In optimized builds, both implementations generate the same assembly so we
 // choose the one that adheres to the standard.
 //
 //
 // WHY HAVE typedef void MoveOnlyTypeForCPP03
 //
 // Callback<>/Bind() needs to understand movable-but-not-copyable semantics
 // to call .Pass() appropriately when it is expected to transfer the value.
 // The cryptic typedef MoveOnlyTypeForCPP03 is added to make this check
 // easy and automatic in helper templates for Callback<>/Bind().
 // See IsMoveOnlyType template and its usage in base/callback_internal.h
 // for more details.
 //
 //
 // COMPARED TO C++11
 //
 // In C++11, you would implement this functionality using an r-value reference
 // and our .Pass() method would be replaced with a call to std::move().
 //
 // This emulation also has a deficiency where it uses up the single
 // user-defined conversion allowed by C++ during initialization.  This can
 // cause problems in some API edge cases.  For instance, in scoped_ptr, it is
 // impossible to make a function "void Foo(scoped_ptr<Parent> p)" accept a
 // value of type scoped_ptr<Child> even if you add a constructor to
 // scoped_ptr<> that would make it look like it should work.  C++11 does not
 // have this deficiency.
 //
 //
 // COMPARED TO Boost.Move
 //
 // Our implementation similar to Boost.Move, but we keep the RValue struct
 // private to the move-only type, and we don't use the reinterpret_cast<> hack.
 //
 // In Boost.Move, RValue is the boost::rv<> template.  This type can be used
 // when writing APIs like:
 //
 //   void MyFunc(boost::rv<Foo>& f)
 //
 // that can take advantage of rv<> to avoid extra copies of a type.  However you
 // would still be able to call this version of MyFunc with an l-value:
 //
 //   Foo f;
 //   MyFunc(f);  // Uh oh, we probably just destroyed |f| w/o calling Pass().
 //
 // unless someone is very careful to also declare a parallel override like:
 //
 //   void MyFunc(const Foo& f)
 //
 // that would catch the l-values first.  This was declared unsafe in C++11 and
 // a C++11 compiler will explicitly fail MyFunc(f).  Unfortunately, we cannot
 // ensure this in C++03.
 //
 // Since we have no need for writing such APIs yet, our implementation keeps
 // RValue private and uses a .Pass() method to do the conversion instead of
 // trying to write a version of "std::move()." Writing an API like std::move()
 // would require the RValue struct to be public.
 //
 //
 // CAVEATS
 //
 // If you include a move-only type as a field inside a class that does not
 // explicitly declare a copy constructor, the containing class's implicit
 // copy constructor will change from Containing(const Containing&) to
 // Containing(Containing&).  This can cause some unexpected errors.
 //
 //   http://llvm.org/bugs/show_bug.cgi?id=11528
 //
 // The workaround is to explicitly declare your copy constructor.
 //
 #define MOVE_ONLY_TYPE_FOR_CPP_03(type, rvalue_type) \
  private: \
   struct rvalue_type { \
     explicit rvalue_type(type* object) : object(object) {} \
     type* object; \
   }; \
   type(type&); \
   void operator=(type&); \
  public: \
   operator rvalue_type() { return rvalue_type(this); } \
   type Pass() WARN_UNUSED_RESULT { return type(rvalue_type(this)); } \
   typedef void MoveOnlyTypeForCPP03; \
  private:

 #define MOVE_ONLY_TYPE_WITH_MOVE_CONSTRUCTOR_FOR_CPP_03(type) \
  private: \
   type(const type&); \
   void operator=(const type&); \
  public: \
   type&& Pass() WARN_UNUSED_RESULT { return static_cast<type&&>(*this); } \
   typedef void MoveOnlyTypeForCPP03; \
  private:

 #define TYPE_WITH_MOVE_CONSTRUCTOR_FOR_CPP_03(type) \
  public: \
   type&& Pass() WARN_UNUSED_RESULT { return static_cast<type&&>(*this); } \
  private:

 #endif  // BASE_MOVE_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.

	#ifndef BASE_MOVE_H_
	#define BASE_MOVE_H_

	#include "base/compiler_specific.h"

	// Macro with the boilerplate that makes a type move-only in C++03.
	//
	// USAGE
	//
	// This macro should be used instead of DISALLOW_COPY_AND_ASSIGN to create
	// a "move-only" type. Unlike DISALLOW_COPY_AND_ASSIGN, this macro should be
	// the first line in a class declaration.
	//
	// A class using this macro must call .Pass() (or somehow be an r-value already)
	// before it can be:
	//
	// * Passed as a function argument
	// * Used as the right-hand side of an assignment
	// * Returned from a function
	//
	// Each class will still need to define their own "move constructor" and "move
	// operator=" to make this useful. Here's an example of the macro, the move
	// constructor, and the move operator= from the scoped_ptr class:
	//
	// template <typename T>
	// class scoped_ptr {
	// MOVE_ONLY_TYPE_FOR_CPP_03(scoped_ptr, RValue)
	// public:
	// scoped_ptr(RValue& other) : ptr_(other.release()) { }
	// scoped_ptr& operator=(RValue& other) {
	// swap(other);
	// return *this;
	// }
	// };
	//
	// Note that the constructor must NOT be marked explicit.
	//
	// For consistency, the second parameter to the macro should always be RValue
	// unless you have a strong reason to do otherwise. It is only exposed as a
	// macro parameter so that the move constructor and move operator= don't look
	// like they're using a phantom type.
	//
	//
	// HOW THIS WORKS
	//
	// For a thorough explanation of this technique, see:
	//
	// http://en.wikibooks.org/wiki/More_C%2B%2B_Idioms/Move_Constructor
	//
	// The summary is that we take advantage of 2 properties:
	//
	// 1) non-const references will not bind to r-values.
	// 2) C++ can apply one user-defined conversion when initializing a
	// variable.
	//
	// The first lets us disable the copy constructor and assignment operator
	// by declaring private version of them with a non-const reference parameter.
	//
	// For l-values, direct initialization still fails like in
	// DISALLOW_COPY_AND_ASSIGN because the copy constructor and assignment
	// operators are private.
	//
	// For r-values, the situation is different. The copy constructor and
	// assignment operator are not viable due to (1), so we are trying to call
	// a non-existent constructor and non-existing operator= rather than a private
	// one. Since we have not committed an error quite yet, we can provide an
	// alternate conversion sequence and a constructor. We add
	//
	// * a private struct named "RValue"
	// * a user-defined conversion "operator RValue()"
	// * a "move constructor" and "move operator=" that take the RValue& as
	// their sole parameter.
	//
	// Only r-values will trigger this sequence and execute our "move constructor"
	// or "move operator=." L-values will match the private copy constructor and
	// operator= first giving a "private in this context" error. This combination
	// gives us a move-only type.
	//
	// For signaling a destructive transfer of data from an l-value, we provide a
	// method named Pass() which creates an r-value for the current instance
	// triggering the move constructor or move operator=.
	//
	// Other ways to get r-values is to use the result of an expression like a
	// function call.
	//
	// Here's an example with comments explaining what gets triggered where:
	//
	// class Foo {
	// MOVE_ONLY_TYPE_FOR_CPP_03(Foo, RValue);
	//
	// public:
	// ... API ...
	// Foo(RValue other); // Move constructor.
	// Foo& operator=(RValue rhs); // Move operator=
	// };
	//
	// Foo MakeFoo(); // Function that returns a Foo.
	//
	// Foo f;
	// Foo f_copy(f); // ERROR: Foo(Foo&) is private in this context.
	// Foo f_assign;
	// f_assign = f; // ERROR: operator=(Foo&) is private in this context.
	//
	//
	// Foo f(MakeFoo()); // R-value so alternate conversion executed.
	// Foo f_copy(f.Pass()); // R-value so alternate conversion executed.
	// f = f_copy.Pass(); // R-value so alternate conversion executed.
	//
	//
	// IMPLEMENTATION SUBTLETIES WITH RValue
	//
	// The RValue struct is just a container for a pointer back to the original
	// object. It should only ever be created as a temporary, and no external
	// class should ever declare it or use it in a parameter.
	//
	// It is tempting to want to use the RValue type in function parameters, but
	// excluding the limited usage here for the move constructor and move
	// operator=, doing so would mean that the function could take both r-values
	// and l-values equially which is unexpected. See COMPARED To Boost.Move for
	// more details.
	//
	// An alternate, and incorrect, implementation of the RValue class used by
	// Boost.Move makes RValue a fieldless child of the move-only type. RValue&
	// is then used in place of RValue in the various operators. The RValue& is
	// "created" by doing reinterpret_cast<RValue>(this). This has the appeal
	// of never creating a temporary RValue struct even with optimizations
	// disabled. Also, by virtue of inheritance you can treat the RValue
	// reference as if it were the move-only type itself. Unfortunately,
	// using the result of this reinterpret_cast<> is actually undefined behavior
	// due to C++98 5.2.10.7. In certain compilers (e.g., NaCl) the optimizer
	// will generate non-working code.
	//
	// In optimized builds, both implementations generate the same assembly so we
	// choose the one that adheres to the standard.
	//
	//
	// WHY HAVE typedef void MoveOnlyTypeForCPP03
	//
	// Callback<>/Bind() needs to understand movable-but-not-copyable semantics
	// to call .Pass() appropriately when it is expected to transfer the value.
	// The cryptic typedef MoveOnlyTypeForCPP03 is added to make this check
	// easy and automatic in helper templates for Callback<>/Bind().
	// See IsMoveOnlyType template and its usage in base/callback_internal.h
	// for more details.
	//
	//
	// COMPARED TO C++11
	//
	// In C++11, you would implement this functionality using an r-value reference
	// and our .Pass() method would be replaced with a call to std::move().
	//
	// This emulation also has a deficiency where it uses up the single
	// user-defined conversion allowed by C++ during initialization. This can
	// cause problems in some API edge cases. For instance, in scoped_ptr, it is
	// impossible to make a function "void Foo(scoped_ptr<Parent> p)" accept a
	// value of type scoped_ptr<Child> even if you add a constructor to
	// scoped_ptr<> that would make it look like it should work. C++11 does not
	// have this deficiency.
	//
	//
	// COMPARED TO Boost.Move
	//
	// Our implementation similar to Boost.Move, but we keep the RValue struct
	// private to the move-only type, and we don't use the reinterpret_cast<> hack.
	//
	// In Boost.Move, RValue is the boost::rv<> template. This type can be used
	// when writing APIs like:
	//
	// void MyFunc(boost::rv<Foo>& f)
	//
	// that can take advantage of rv<> to avoid extra copies of a type. However you
	// would still be able to call this version of MyFunc with an l-value:
	//
	// Foo f;
	// MyFunc(f); // Uh oh, we probably just destroyed \|f\| w/o calling Pass().
	//
	// unless someone is very careful to also declare a parallel override like:
	//
	// void MyFunc(const Foo& f)
	//
	// that would catch the l-values first. This was declared unsafe in C++11 and
	// a C++11 compiler will explicitly fail MyFunc(f). Unfortunately, we cannot
	// ensure this in C++03.
	//
	// Since we have no need for writing such APIs yet, our implementation keeps
	// RValue private and uses a .Pass() method to do the conversion instead of
	// trying to write a version of "std::move()." Writing an API like std::move()
	// would require the RValue struct to be public.
	//
	//
	// CAVEATS
	//
	// If you include a move-only type as a field inside a class that does not
	// explicitly declare a copy constructor, the containing class's implicit
	// copy constructor will change from Containing(const Containing&) to
	// Containing(Containing&). This can cause some unexpected errors.
	//
	// http://llvm.org/bugs/show_bug.cgi?id=11528
	//
	// The workaround is to explicitly declare your copy constructor.
	//
	#define MOVE_ONLY_TYPE_FOR_CPP_03(type, rvalue_type) \
	private: \
	struct rvalue_type { \
	explicit rvalue_type(type* object) : object(object) {} \
	type* object; \
	}; \
	type(type&); \
	void operator=(type&); \
	public: \
	operator rvalue_type() { return rvalue_type(this); } \
	type Pass() WARN_UNUSED_RESULT { return type(rvalue_type(this)); } \
	typedef void MoveOnlyTypeForCPP03; \
	private:

	#define MOVE_ONLY_TYPE_WITH_MOVE_CONSTRUCTOR_FOR_CPP_03(type) \
	private: \
	type(const type&); \
	void operator=(const type&); \
	public: \
	type&& Pass() WARN_UNUSED_RESULT { return static_cast<type&&>(*this); } \
	typedef void MoveOnlyTypeForCPP03; \
	private:

	#define TYPE_WITH_MOVE_CONSTRUCTOR_FOR_CPP_03(type) \
	public: \
	type&& Pass() WARN_UNUSED_RESULT { return static_cast<type&&>(*this); } \
	private:

	#endif // BASE_MOVE_H_