rtc_base/ref_counted_object.h - src - Git at Google

 /*
  *  Copyright 2016 The WebRTC Project Authors. All rights reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */
 #ifndef RTC_BASE_REF_COUNTED_OBJECT_H_
 #define RTC_BASE_REF_COUNTED_OBJECT_H_

 #include <type_traits>
 #include <utility>

 #include "api/scoped_refptr.h"
 #include "rtc_base/ref_count.h"
 #include "rtc_base/ref_counter.h"

 namespace rtc {

 namespace webrtc_make_ref_counted_internal {
 // Determines if the given class has AddRef and Release methods.
 template <typename T>
 class HasAddRefAndRelease {
  private:
   template <typename C,
             decltype(std::declval<C>().AddRef())* = nullptr,
             decltype(std::declval<C>().Release())* = nullptr>
   static int Test(int);
   template <typename>
   static char Test(...);

  public:
   static constexpr bool value = std::is_same_v<decltype(Test<T>(0)), int>;
 };
 }  // namespace webrtc_make_ref_counted_internal

 template <class T>
 class RefCountedObject : public T {
  public:
   RefCountedObject() {}

   RefCountedObject(const RefCountedObject&) = delete;
   RefCountedObject& operator=(const RefCountedObject&) = delete;

   template <class P0>
   explicit RefCountedObject(P0&& p0) : T(std::forward<P0>(p0)) {}

   template <class P0, class P1, class... Args>
   RefCountedObject(P0&& p0, P1&& p1, Args&&... args)
       : T(std::forward<P0>(p0),
           std::forward<P1>(p1),
           std::forward<Args>(args)...) {}

   void AddRef() const override { ref_count_.IncRef(); }

   RefCountReleaseStatus Release() const override {
     const auto status = ref_count_.DecRef();
     if (status == RefCountReleaseStatus::kDroppedLastRef) {
       delete this;
     }
     return status;
   }

   // Return whether the reference count is one. If the reference count is used
   // in the conventional way, a reference count of 1 implies that the current
   // thread owns the reference and no other thread shares it. This call
   // performs the test for a reference count of one, and performs the memory
   // barrier needed for the owning thread to act on the object, knowing that it
   // has exclusive access to the object.
   virtual bool HasOneRef() const { return ref_count_.HasOneRef(); }

  protected:
   ~RefCountedObject() override {}

   mutable webrtc::webrtc_impl::RefCounter ref_count_{0};
 };

 template <class T>
 class FinalRefCountedObject final : public T {
  public:
   using T::T;
   // Above using declaration propagates a default move constructor
   // FinalRefCountedObject(FinalRefCountedObject&& other), but we also need
   // move construction from T.
   explicit FinalRefCountedObject(T&& other) : T(std::move(other)) {}
   FinalRefCountedObject(const FinalRefCountedObject&) = delete;
   FinalRefCountedObject& operator=(const FinalRefCountedObject&) = delete;

   void AddRef() const { ref_count_.IncRef(); }
   RefCountReleaseStatus Release() const {
     const auto status = ref_count_.DecRef();
     if (status == RefCountReleaseStatus::kDroppedLastRef) {
       delete this;
     }
     return status;
   }
   bool HasOneRef() const { return ref_count_.HasOneRef(); }

  private:
   ~FinalRefCountedObject() = default;

   mutable webrtc::webrtc_impl::RefCounter ref_count_{0};
 };

 // General utilities for constructing a reference counted class and the
 // appropriate reference count implementation for that class.
 //
 // These utilities select either the `RefCountedObject` implementation or
 // `FinalRefCountedObject` depending on whether the to-be-shared class is
 // derived from the RefCountInterface interface or not (respectively).

 // `make_ref_counted`:
 //
 // Use this when you want to construct a reference counted object of type T and
 // get a `scoped_refptr<>` back. Example:
 //
 //   auto p = make_ref_counted<Foo>("bar", 123);
 //
 // For a class that inherits from RefCountInterface, this is equivalent to:
 //
 //   auto p = scoped_refptr<Foo>(new RefCountedObject<Foo>("bar", 123));
 //
 // If the class does not inherit from RefCountInterface, but does have
 // AddRef/Release methods (so a T* is convertible to rtc::scoped_refptr), this
 // is equivalent to just
 //
 //   auto p = scoped_refptr<Foo>(new Foo("bar", 123));
 //
 // Otherwise, the example is equivalent to:
 //
 //   auto p = scoped_refptr<FinalRefCountedObject<Foo>>(
 //       new FinalRefCountedObject<Foo>("bar", 123));
 //
 // In these cases, `make_ref_counted` reduces the amount of boilerplate code but
 // also helps with the most commonly intended usage of RefCountedObject whereby
 // methods for reference counting, are virtual and designed to satisfy the need
 // of an interface. When such a need does not exist, it is more efficient to use
 // the `FinalRefCountedObject` template, which does not add the vtable overhead.
 //
 // Note that in some cases, using RefCountedObject directly may still be what's
 // needed.

 // `make_ref_counted` for classes that are convertible to RefCountInterface.
 template <typename T,
           typename... Args,
           typename std::enable_if<std::is_convertible_v<T*, RefCountInterface*>,
                                   T>::type* = nullptr>
 scoped_refptr<T> make_ref_counted(Args&&... args) {
   return scoped_refptr<T>(new RefCountedObject<T>(std::forward<Args>(args)...));
 }

 // `make_ref_counted` for complete classes that are not convertible to
 // RefCountInterface and already carry a ref count.
 template <
     typename T,
     typename... Args,
     typename std::enable_if<
         !std::is_convertible_v<T*, RefCountInterface*> &&
             webrtc_make_ref_counted_internal::HasAddRefAndRelease<T>::value,
         T>::type* = nullptr>
 scoped_refptr<T> make_ref_counted(Args&&... args) {
   return scoped_refptr<T>(new T(std::forward<Args>(args)...));
 }

 // `make_ref_counted` for complete classes that are not convertible to
 // RefCountInterface and have no ref count of their own.
 template <
     typename T,
     typename... Args,
     typename std::enable_if<
         !std::is_convertible_v<T*, RefCountInterface*> &&
             !webrtc_make_ref_counted_internal::HasAddRefAndRelease<T>::value,

         T>::type* = nullptr>
 scoped_refptr<FinalRefCountedObject<T>> make_ref_counted(Args&&... args) {
   return scoped_refptr<FinalRefCountedObject<T>>(
       new FinalRefCountedObject<T>(std::forward<Args>(args)...));
 }

 // `Ref<>`, `Ref<>::Type` and `Ref<>::Ptr`:
 //
 // `Ref` is a type declaring utility that is compatible with `make_ref_counted`
 // and can be used in classes and methods where it's more convenient (or
 // readable) to have the compiler figure out the fully fleshed out type for a
 // class rather than spell it out verbatim in all places the type occurs (which
 // can mean maintenance work if the class layout changes).
 //
 // Usage examples:
 //
 // If you want to declare the parameter type that's always compatible with
 // this code:
 //
 //   Bar(make_ref_counted<Foo>());
 //
 // You can use `Ref<>::Ptr` to declare a compatible scoped_refptr type:
 //
 //   void Bar(Ref<Foo>::Ptr p);
 //
 // This might be more practically useful in templates though.
 //
 // In rare cases you might need to be able to declare a parameter that's fully
 // compatible with the reference counted T type - and just using T* is not
 // enough. To give a code example, we can declare a function, `Foo` that is
 // compatible with this code:
 //   auto p = make_ref_counted<Foo>();
 //   Foo(p.get());
 //
 //   void Foo(Ref<Foo>::Type* foo_ptr);
 //
 // Alternatively this would be:
 //   void Foo(Foo* foo_ptr);
 // or
 //   void Foo(FinalRefCountedObject<Foo>* foo_ptr);

 // Declares the approprate reference counted type for T depending on whether
 // T is convertible to RefCountInterface or not.
 // For classes that are convertible, the type will simply be T.
 // For classes that cannot be converted to RefCountInterface, the type will be
 // FinalRefCountedObject<T>.
 // This is most useful for declaring a scoped_refptr<T> instance for a class
 // that may or may not implement a virtual reference counted interface:
 // * scoped_refptr<Ref<Foo>::Type> my_ptr;
 template <typename T>
 struct Ref {
   typedef typename std::conditional<
       webrtc_make_ref_counted_internal::HasAddRefAndRelease<T>::value,
       T,
       FinalRefCountedObject<T>>::type Type;

   typedef scoped_refptr<Type> Ptr;
 };

 }  // namespace rtc

 #endif  // RTC_BASE_REF_COUNTED_OBJECT_H_
	/*
	* Copyright 2016 The WebRTC Project Authors. All rights reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/
	#ifndef RTC_BASE_REF_COUNTED_OBJECT_H_
	#define RTC_BASE_REF_COUNTED_OBJECT_H_

	#include <type_traits>
	#include <utility>

	#include "api/scoped_refptr.h"
	#include "rtc_base/ref_count.h"
	#include "rtc_base/ref_counter.h"

	namespace rtc {

	namespace webrtc_make_ref_counted_internal {
	// Determines if the given class has AddRef and Release methods.
	template <typename T>
	class HasAddRefAndRelease {
	private:
	template <typename C,
	decltype(std::declval<C>().AddRef())* = nullptr,
	decltype(std::declval<C>().Release())* = nullptr>
	static int Test(int);
	template <typename>
	static char Test(...);

	public:
	static constexpr bool value = std::is_same_v<decltype(Test<T>(0)), int>;
	};
	} // namespace webrtc_make_ref_counted_internal

	template <class T>
	class RefCountedObject : public T {
	public:
	RefCountedObject() {}

	RefCountedObject(const RefCountedObject&) = delete;
	RefCountedObject& operator=(const RefCountedObject&) = delete;

	template <class P0>
	explicit RefCountedObject(P0&& p0) : T(std::forward<P0>(p0)) {}

	template <class P0, class P1, class... Args>
	RefCountedObject(P0&& p0, P1&& p1, Args&&... args)
	: T(std::forward<P0>(p0),
	std::forward<P1>(p1),
	std::forward<Args>(args)...) {}

	void AddRef() const override { ref_count_.IncRef(); }

	RefCountReleaseStatus Release() const override {
	const auto status = ref_count_.DecRef();
	if (status == RefCountReleaseStatus::kDroppedLastRef) {
	delete this;
	}
	return status;
	}

	// Return whether the reference count is one. If the reference count is used
	// in the conventional way, a reference count of 1 implies that the current
	// thread owns the reference and no other thread shares it. This call
	// performs the test for a reference count of one, and performs the memory
	// barrier needed for the owning thread to act on the object, knowing that it
	// has exclusive access to the object.
	virtual bool HasOneRef() const { return ref_count_.HasOneRef(); }

	protected:
	~RefCountedObject() override {}

	mutable webrtc::webrtc_impl::RefCounter ref_count_{0};
	};

	template <class T>
	class FinalRefCountedObject final : public T {
	public:
	using T::T;
	// Above using declaration propagates a default move constructor
	// FinalRefCountedObject(FinalRefCountedObject&& other), but we also need
	// move construction from T.
	explicit FinalRefCountedObject(T&& other) : T(std::move(other)) {}
	FinalRefCountedObject(const FinalRefCountedObject&) = delete;
	FinalRefCountedObject& operator=(const FinalRefCountedObject&) = delete;

	void AddRef() const { ref_count_.IncRef(); }
	RefCountReleaseStatus Release() const {
	const auto status = ref_count_.DecRef();
	if (status == RefCountReleaseStatus::kDroppedLastRef) {
	delete this;
	}
	return status;
	}
	bool HasOneRef() const { return ref_count_.HasOneRef(); }

	private:
	~FinalRefCountedObject() = default;

	mutable webrtc::webrtc_impl::RefCounter ref_count_{0};
	};

	// General utilities for constructing a reference counted class and the
	// appropriate reference count implementation for that class.
	//
	// These utilities select either the `RefCountedObject` implementation or
	// `FinalRefCountedObject` depending on whether the to-be-shared class is
	// derived from the RefCountInterface interface or not (respectively).

	// `make_ref_counted`:
	//
	// Use this when you want to construct a reference counted object of type T and
	// get a `scoped_refptr<>` back. Example:
	//
	// auto p = make_ref_counted<Foo>("bar", 123);
	//
	// For a class that inherits from RefCountInterface, this is equivalent to:
	//
	// auto p = scoped_refptr<Foo>(new RefCountedObject<Foo>("bar", 123));
	//
	// If the class does not inherit from RefCountInterface, but does have
	// AddRef/Release methods (so a T* is convertible to rtc::scoped_refptr), this
	// is equivalent to just
	//
	// auto p = scoped_refptr<Foo>(new Foo("bar", 123));
	//
	// Otherwise, the example is equivalent to:
	//
	// auto p = scoped_refptr<FinalRefCountedObject<Foo>>(
	// new FinalRefCountedObject<Foo>("bar", 123));
	//
	// In these cases, `make_ref_counted` reduces the amount of boilerplate code but
	// also helps with the most commonly intended usage of RefCountedObject whereby
	// methods for reference counting, are virtual and designed to satisfy the need
	// of an interface. When such a need does not exist, it is more efficient to use
	// the `FinalRefCountedObject` template, which does not add the vtable overhead.
	//
	// Note that in some cases, using RefCountedObject directly may still be what's
	// needed.

	// `make_ref_counted` for classes that are convertible to RefCountInterface.
	template <typename T,
	typename... Args,
	typename std::enable_if<std::is_convertible_v<T, RefCountInterface>,
	T>::type* = nullptr>
	scoped_refptr<T> make_ref_counted(Args&&... args) {
	return scoped_refptr<T>(new RefCountedObject<T>(std::forward<Args>(args)...));
	}

	// `make_ref_counted` for complete classes that are not convertible to
	// RefCountInterface and already carry a ref count.
	template <
	typename T,
	typename... Args,
	typename std::enable_if<
	!std::is_convertible_v<T, RefCountInterface> &&
	webrtc_make_ref_counted_internal::HasAddRefAndRelease<T>::value,
	T>::type* = nullptr>
	scoped_refptr<T> make_ref_counted(Args&&... args) {
	return scoped_refptr<T>(new T(std::forward<Args>(args)...));
	}

	// `make_ref_counted` for complete classes that are not convertible to
	// RefCountInterface and have no ref count of their own.
	template <
	typename T,
	typename... Args,
	typename std::enable_if<
	!std::is_convertible_v<T, RefCountInterface> &&
	!webrtc_make_ref_counted_internal::HasAddRefAndRelease<T>::value,

	T>::type* = nullptr>
	scoped_refptr<FinalRefCountedObject<T>> make_ref_counted(Args&&... args) {
	return scoped_refptr<FinalRefCountedObject<T>>(
	new FinalRefCountedObject<T>(std::forward<Args>(args)...));
	}

	// `Ref<>`, `Ref<>::Type` and `Ref<>::Ptr`:
	//
	// `Ref` is a type declaring utility that is compatible with `make_ref_counted`
	// and can be used in classes and methods where it's more convenient (or
	// readable) to have the compiler figure out the fully fleshed out type for a
	// class rather than spell it out verbatim in all places the type occurs (which
	// can mean maintenance work if the class layout changes).
	//
	// Usage examples:
	//
	// If you want to declare the parameter type that's always compatible with
	// this code:
	//
	// Bar(make_ref_counted<Foo>());
	//
	// You can use `Ref<>::Ptr` to declare a compatible scoped_refptr type:
	//
	// void Bar(Ref<Foo>::Ptr p);
	//
	// This might be more practically useful in templates though.
	//
	// In rare cases you might need to be able to declare a parameter that's fully
	// compatible with the reference counted T type - and just using T* is not
	// enough. To give a code example, we can declare a function, `Foo` that is
	// compatible with this code:
	// auto p = make_ref_counted<Foo>();
	// Foo(p.get());
	//
	// void Foo(Ref<Foo>::Type* foo_ptr);
	//
	// Alternatively this would be:
	// void Foo(Foo* foo_ptr);
	// or
	// void Foo(FinalRefCountedObject<Foo>* foo_ptr);

	// Declares the approprate reference counted type for T depending on whether
	// T is convertible to RefCountInterface or not.
	// For classes that are convertible, the type will simply be T.
	// For classes that cannot be converted to RefCountInterface, the type will be
	// FinalRefCountedObject<T>.
	// This is most useful for declaring a scoped_refptr<T> instance for a class
	// that may or may not implement a virtual reference counted interface:
	// * scoped_refptr<Ref<Foo>::Type> my_ptr;
	template <typename T>
	struct Ref {
	typedef typename std::conditional<
	webrtc_make_ref_counted_internal::HasAddRefAndRelease<T>::value,
	T,
	FinalRefCountedObject<T>>::type Type;

	typedef scoped_refptr<Type> Ptr;
	};

	} // namespace rtc

	#endif // RTC_BASE_REF_COUNTED_OBJECT_H_