base/mac/scoped_typeref.h - gn.git - Git at Google

 // Copyright 2014 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_MAC_SCOPED_TYPEREF_H_
 #define BASE_MAC_SCOPED_TYPEREF_H_

 #include "base/compiler_specific.h"
 #include "base/logging.h"
 #include "base/memory/scoped_policy.h"

 namespace base {

 // ScopedTypeRef<> is patterned after std::unique_ptr<>, but maintains ownership
 // of a reference to any type that is maintained by Retain and Release methods.
 //
 // The Traits structure must provide the Retain and Release methods for type T.
 // A default ScopedTypeRefTraits is used but not defined, and should be defined
 // for each type to use this interface. For example, an appropriate definition
 // of ScopedTypeRefTraits for CGLContextObj would be:
 //
 //   template<>
 //   struct ScopedTypeRefTraits<CGLContextObj> {
 //     static CGLContextObj InvalidValue() { return nullptr; }
 //     static CGLContextObj Retain(CGLContextObj object) {
 //       CGLContextRetain(object);
 //       return object;
 //     }
 //     static void Release(CGLContextObj object) { CGLContextRelease(object); }
 //   };
 //
 // For the many types that have pass-by-pointer create functions, the function
 // InitializeInto() is provided to allow direct initialization and assumption
 // of ownership of the object. For example, continuing to use the above
 // CGLContextObj specialization:
 //
 //   base::ScopedTypeRef<CGLContextObj> context;
 //   CGLCreateContext(pixel_format, share_group, context.InitializeInto());
 //
 // For initialization with an existing object, the caller may specify whether
 // the ScopedTypeRef<> being initialized is assuming the caller's existing
 // ownership of the object (and should not call Retain in initialization) or if
 // it should not assume this ownership and must create its own (by calling
 // Retain in initialization). This behavior is based on the |policy| parameter,
 // with |ASSUME| for the former and |RETAIN| for the latter. The default policy
 // is to |ASSUME|.

 template <typename T>
 struct ScopedTypeRefTraits;

 template <typename T, typename Traits = ScopedTypeRefTraits<T>>
 class ScopedTypeRef {
  public:
   typedef T element_type;

   explicit constexpr ScopedTypeRef(
       __unsafe_unretained T object = Traits::InvalidValue(),
       base::scoped_policy::OwnershipPolicy policy = base::scoped_policy::ASSUME)
       : object_(object) {
     if (object_ && policy == base::scoped_policy::RETAIN)
       object_ = Traits::Retain(object_);
   }

   ScopedTypeRef(const ScopedTypeRef<T, Traits>& that) : object_(that.object_) {
     if (object_)
       object_ = Traits::Retain(object_);
   }

   // This allows passing an object to a function that takes its superclass.
   template <typename R, typename RTraits>
   explicit ScopedTypeRef(const ScopedTypeRef<R, RTraits>& that_as_subclass)
       : object_(that_as_subclass.get()) {
     if (object_)
       object_ = Traits::Retain(object_);
   }

   ScopedTypeRef(ScopedTypeRef<T, Traits>&& that) : object_(that.object_) {
     that.object_ = Traits::InvalidValue();
   }

   ~ScopedTypeRef() {
     if (object_)
       Traits::Release(object_);
   }

   ScopedTypeRef& operator=(const ScopedTypeRef<T, Traits>& that) {
     reset(that.get(), base::scoped_policy::RETAIN);
     return *this;
   }

   // This is to be used only to take ownership of objects that are created
   // by pass-by-pointer create functions. To enforce this, require that the
   // object be reset to NULL before this may be used.
   T* InitializeInto() WARN_UNUSED_RESULT {
     DCHECK(!object_);
     return &object_;
   }

   void reset(__unsafe_unretained T object = Traits::InvalidValue(),
              base::scoped_policy::OwnershipPolicy policy =
                  base::scoped_policy::ASSUME) {
     if (object && policy == base::scoped_policy::RETAIN)
       object = Traits::Retain(object);
     if (object_)
       Traits::Release(object_);
     object_ = object;
   }

   bool operator==(__unsafe_unretained T that) const { return object_ == that; }

   bool operator!=(__unsafe_unretained T that) const { return object_ != that; }

   operator T() const __attribute((ns_returns_not_retained)) { return object_; }

   T get() const __attribute((ns_returns_not_retained)) { return object_; }

   void swap(ScopedTypeRef& that) {
     __unsafe_unretained T temp = that.object_;
     that.object_ = object_;
     object_ = temp;
   }

   // ScopedTypeRef<>::release() is like std::unique_ptr<>::release.  It is NOT
   // a wrapper for Release().  To force a ScopedTypeRef<> object to call
   // Release(), use ScopedTypeRef<>::reset().
   T release() __attribute((ns_returns_not_retained)) WARN_UNUSED_RESULT {
     __unsafe_unretained T temp = object_;
     object_ = Traits::InvalidValue();
     return temp;
   }

  private:
   __unsafe_unretained T object_;
 };

 }  // namespace base

 #endif  // BASE_MAC_SCOPED_TYPEREF_H_
	// Copyright 2014 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_MAC_SCOPED_TYPEREF_H_
	#define BASE_MAC_SCOPED_TYPEREF_H_

	#include "base/compiler_specific.h"
	#include "base/logging.h"
	#include "base/memory/scoped_policy.h"

	namespace base {

	// ScopedTypeRef<> is patterned after std::unique_ptr<>, but maintains ownership
	// of a reference to any type that is maintained by Retain and Release methods.
	//
	// The Traits structure must provide the Retain and Release methods for type T.
	// A default ScopedTypeRefTraits is used but not defined, and should be defined
	// for each type to use this interface. For example, an appropriate definition
	// of ScopedTypeRefTraits for CGLContextObj would be:
	//
	// template<>
	// struct ScopedTypeRefTraits<CGLContextObj> {
	// static CGLContextObj InvalidValue() { return nullptr; }
	// static CGLContextObj Retain(CGLContextObj object) {
	// CGLContextRetain(object);
	// return object;
	// }
	// static void Release(CGLContextObj object) { CGLContextRelease(object); }
	// };
	//
	// For the many types that have pass-by-pointer create functions, the function
	// InitializeInto() is provided to allow direct initialization and assumption
	// of ownership of the object. For example, continuing to use the above
	// CGLContextObj specialization:
	//
	// base::ScopedTypeRef<CGLContextObj> context;
	// CGLCreateContext(pixel_format, share_group, context.InitializeInto());
	//
	// For initialization with an existing object, the caller may specify whether
	// the ScopedTypeRef<> being initialized is assuming the caller's existing
	// ownership of the object (and should not call Retain in initialization) or if
	// it should not assume this ownership and must create its own (by calling
	// Retain in initialization). This behavior is based on the \|policy\| parameter,
	// with \|ASSUME\| for the former and \|RETAIN\| for the latter. The default policy
	// is to \|ASSUME\|.

	template <typename T>
	struct ScopedTypeRefTraits;

	template <typename T, typename Traits = ScopedTypeRefTraits<T>>
	class ScopedTypeRef {
	public:
	typedef T element_type;

	explicit constexpr ScopedTypeRef(
	__unsafe_unretained T object = Traits::InvalidValue(),
	base::scoped_policy::OwnershipPolicy policy = base::scoped_policy::ASSUME)
	: object_(object) {
	if (object_ && policy == base::scoped_policy::RETAIN)
	object_ = Traits::Retain(object_);
	}

	ScopedTypeRef(const ScopedTypeRef<T, Traits>& that) : object_(that.object_) {
	if (object_)
	object_ = Traits::Retain(object_);
	}

	// This allows passing an object to a function that takes its superclass.
	template <typename R, typename RTraits>
	explicit ScopedTypeRef(const ScopedTypeRef<R, RTraits>& that_as_subclass)
	: object_(that_as_subclass.get()) {
	if (object_)
	object_ = Traits::Retain(object_);
	}

	ScopedTypeRef(ScopedTypeRef<T, Traits>&& that) : object_(that.object_) {
	that.object_ = Traits::InvalidValue();
	}

	~ScopedTypeRef() {
	if (object_)
	Traits::Release(object_);
	}

	ScopedTypeRef& operator=(const ScopedTypeRef<T, Traits>& that) {
	reset(that.get(), base::scoped_policy::RETAIN);
	return *this;
	}

	// This is to be used only to take ownership of objects that are created
	// by pass-by-pointer create functions. To enforce this, require that the
	// object be reset to NULL before this may be used.
	T* InitializeInto() WARN_UNUSED_RESULT {
	DCHECK(!object_);
	return &object_;
	}

	void reset(__unsafe_unretained T object = Traits::InvalidValue(),
	base::scoped_policy::OwnershipPolicy policy =
	base::scoped_policy::ASSUME) {
	if (object && policy == base::scoped_policy::RETAIN)
	object = Traits::Retain(object);
	if (object_)
	Traits::Release(object_);
	object_ = object;
	}

	bool operator==(__unsafe_unretained T that) const { return object_ == that; }

	bool operator!=(__unsafe_unretained T that) const { return object_ != that; }

	operator T() const __attribute((ns_returns_not_retained)) { return object_; }

	T get() const __attribute((ns_returns_not_retained)) { return object_; }

	void swap(ScopedTypeRef& that) {
	__unsafe_unretained T temp = that.object_;
	that.object_ = object_;
	object_ = temp;
	}

	// ScopedTypeRef<>::release() is like std::unique_ptr<>::release. It is NOT
	// a wrapper for Release(). To force a ScopedTypeRef<> object to call
	// Release(), use ScopedTypeRef<>::reset().
	T release() __attribute((ns_returns_not_retained)) WARN_UNUSED_RESULT {
	__unsafe_unretained T temp = object_;
	object_ = Traits::InvalidValue();
	return temp;
	}

	private:
	__unsafe_unretained T object_;
	};

	} // namespace base

	#endif // BASE_MAC_SCOPED_TYPEREF_H_