runtime/bin/reference_counting.h - sdk.git - Git at Google

 // Copyright (c) 2016, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.

 #ifndef RUNTIME_BIN_REFERENCE_COUNTING_H_
 #define RUNTIME_BIN_REFERENCE_COUNTING_H_

 #include <atomic>

 namespace dart {
 namespace bin {

 // Forward declaration.
 template <class Target>
 class RefCntReleaseScope;

 // Inherit from this class where instances of the derived class should be
 // reference counted. Reference counts on instances are incremented and
 // decremented explicitly with calls to Retain() and Release(). E.g.:
 //
 // class Foo : public ReferenceCounted<Foo> {
 //  public:
 //   Foo() : ReferenceCounted() {}
 //   ...
 // };
 //
 // void DoStuffWithAFoo() {
 //   Foo* foo = new Foo();  // Reference count starts at 1, so no explicit
 //                          // call to Retain is needed after allocation.
 //   ...
 //   foo->Release();
 // }
 template <class Derived>
 class ReferenceCounted {
  public:
   ReferenceCounted() : ref_count_(1) {
 #if defined(DEBUG)
     instances_.fetch_add(1u, std::memory_order_relaxed);
 #endif  // defined(DEBUG)
   }

   virtual ~ReferenceCounted() {
     ASSERT(ref_count_ == 0);
 #if defined(DEBUG)
     instances_.fetch_sub(1u, std::memory_order_relaxed);
 #endif  // defined(DEBUG)
   }

   void Retain() {
     intptr_t old = ref_count_.fetch_add(1u, std::memory_order_relaxed);
     ASSERT(old > 0);
   }

   void Release() {
     intptr_t old = ref_count_.fetch_sub(1u, std::memory_order_acq_rel);
     ASSERT(old > 0);
     if (old == 1) {
       delete static_cast<Derived*>(this);
     }
   }

 #if defined(DEBUG)
   static intptr_t instances() {
     return instances_.load(std::memory_order_relaxed);
   }
 #endif  // defined(DEBUG)

  private:
 #if defined(DEBUG)
   static std::atomic<intptr_t> instances_;
 #endif  // defined(DEBUG)

   std::atomic<intptr_t> ref_count_;

   // These are used only in the ASSERT below in RefCntReleaseScope.
   intptr_t ref_count() const {
     return ref_count_.load(std::memory_order_relaxed);
   }
   friend class RefCntReleaseScope<Derived>;
   DISALLOW_COPY_AND_ASSIGN(ReferenceCounted);
 };

 #if defined(DEBUG)
 template <class Derived>
 std::atomic<intptr_t> ReferenceCounted<Derived>::instances_ = {0};
 #endif

 // Creates a scope at the end of which a reference counted object is
 // Released. This is useful for reference counted objects received by the IO
 // Service, which have already been Retained E.g.:
 //
 // CObject* Foo::FooRequest(const CObjectArray& request) {
 //   Foo* foo = CObjectToFoo(request[0]);
 //   RefCntReleaseScope<Foo> rs(foo);
 //   ...
 // }
 template <class Target>
 class RefCntReleaseScope {
  public:
   explicit RefCntReleaseScope(ReferenceCounted<Target>* t) : target_(t) {
     ASSERT(target_ != NULL);
     ASSERT(target_->ref_count() > 0);
   }
   ~RefCntReleaseScope() { target_->Release(); }

  private:
   ReferenceCounted<Target>* target_;

   DISALLOW_ALLOCATION();
   DISALLOW_COPY_AND_ASSIGN(RefCntReleaseScope);
 };

 // Instances of RetainedPointer manage Retaining and Releasing reference counted
 // objects. There are two ways to use it. First, it can be used as a field in
 // a class, e.g.:
 //
 // class Foo {
 //  private:
 //   RetainedPointer<Bar> bar_;
 //  public:
 //   explicit Foo(Bar* b) : bar_(b) {}
 // }
 //
 // In this case, b will be Retained in Foo's constructor, and Released
 // automatically during Foo's destructor.
 //
 // RetainedPointer can also be used as a scope, as with RefCntReleaseScope,
 // with the difference that entering the scope also Retains the pointer, e.g.:
 //
 // void RetainAndDoStuffWithFoo(Foo* foo) {
 //   RetainedPointer<Foo> retained(foo);
 //   ..
 // }
 //
 // This Retains foo on entry and Releases foo at every exit from the scope.
 //
 // The underlying pointer can be accessed with the get() and set() methods.
 // Overwriting a non-NULL pointer with set causes that pointer to be Released.
 template <class Target>
 class RetainedPointer {
  public:
   RetainedPointer() : target_(NULL) {}

   explicit RetainedPointer(ReferenceCounted<Target>* t) : target_(t) {
     if (target_ != NULL) {
       target_->Retain();
     }
   }

   ~RetainedPointer() {
     if (target_ != NULL) {
       target_->Release();
     }
   }

   void set(ReferenceCounted<Target>* t) {
     if (target_ != NULL) {
       target_->Release();
     }
     target_ = t;
     if (target_ != NULL) {
       target_->Retain();
     }
   }

   Target* get() const { return static_cast<Target*>(target_); }

  private:
   ReferenceCounted<Target>* target_;

   DISALLOW_ALLOCATION();
   DISALLOW_COPY_AND_ASSIGN(RetainedPointer);
 };

 }  // namespace bin
 }  // namespace dart

 #endif  // RUNTIME_BIN_REFERENCE_COUNTING_H_
	// Copyright (c) 2016, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.

	#ifndef RUNTIME_BIN_REFERENCE_COUNTING_H_
	#define RUNTIME_BIN_REFERENCE_COUNTING_H_

	#include <atomic>

	namespace dart {
	namespace bin {

	// Forward declaration.
	template <class Target>
	class RefCntReleaseScope;

	// Inherit from this class where instances of the derived class should be
	// reference counted. Reference counts on instances are incremented and
	// decremented explicitly with calls to Retain() and Release(). E.g.:
	//
	// class Foo : public ReferenceCounted<Foo> {
	// public:
	// Foo() : ReferenceCounted() {}
	// ...
	// };
	//
	// void DoStuffWithAFoo() {
	// Foo* foo = new Foo(); // Reference count starts at 1, so no explicit
	// // call to Retain is needed after allocation.
	// ...
	// foo->Release();
	// }
	template <class Derived>
	class ReferenceCounted {
	public:
	ReferenceCounted() : ref_count_(1) {
	#if defined(DEBUG)
	instances_.fetch_add(1u, std::memory_order_relaxed);
	#endif // defined(DEBUG)
	}

	virtual ~ReferenceCounted() {
	ASSERT(ref_count_ == 0);
	#if defined(DEBUG)
	instances_.fetch_sub(1u, std::memory_order_relaxed);
	#endif // defined(DEBUG)
	}

	void Retain() {
	intptr_t old = ref_count_.fetch_add(1u, std::memory_order_relaxed);
	ASSERT(old > 0);
	}

	void Release() {
	intptr_t old = ref_count_.fetch_sub(1u, std::memory_order_acq_rel);
	ASSERT(old > 0);
	if (old == 1) {
	delete static_cast<Derived*>(this);
	}
	}

	#if defined(DEBUG)
	static intptr_t instances() {
	return instances_.load(std::memory_order_relaxed);
	}
	#endif // defined(DEBUG)

	private:
	#if defined(DEBUG)
	static std::atomic<intptr_t> instances_;
	#endif // defined(DEBUG)

	std::atomic<intptr_t> ref_count_;

	// These are used only in the ASSERT below in RefCntReleaseScope.
	intptr_t ref_count() const {
	return ref_count_.load(std::memory_order_relaxed);
	}
	friend class RefCntReleaseScope<Derived>;
	DISALLOW_COPY_AND_ASSIGN(ReferenceCounted);
	};

	#if defined(DEBUG)
	template <class Derived>
	std::atomic<intptr_t> ReferenceCounted<Derived>::instances_ = {0};
	#endif

	// Creates a scope at the end of which a reference counted object is
	// Released. This is useful for reference counted objects received by the IO
	// Service, which have already been Retained E.g.:
	//
	// CObject* Foo::FooRequest(const CObjectArray& request) {
	// Foo* foo = CObjectToFoo(request[0]);
	// RefCntReleaseScope<Foo> rs(foo);
	// ...
	// }
	template <class Target>
	class RefCntReleaseScope {
	public:
	explicit RefCntReleaseScope(ReferenceCounted<Target>* t) : target_(t) {
	ASSERT(target_ != NULL);
	ASSERT(target_->ref_count() > 0);
	}
	~RefCntReleaseScope() { target_->Release(); }

	private:
	ReferenceCounted<Target>* target_;

	DISALLOW_ALLOCATION();
	DISALLOW_COPY_AND_ASSIGN(RefCntReleaseScope);
	};

	// Instances of RetainedPointer manage Retaining and Releasing reference counted
	// objects. There are two ways to use it. First, it can be used as a field in
	// a class, e.g.:
	//
	// class Foo {
	// private:
	// RetainedPointer<Bar> bar_;
	// public:
	// explicit Foo(Bar* b) : bar_(b) {}
	// }
	//
	// In this case, b will be Retained in Foo's constructor, and Released
	// automatically during Foo's destructor.
	//
	// RetainedPointer can also be used as a scope, as with RefCntReleaseScope,
	// with the difference that entering the scope also Retains the pointer, e.g.:
	//
	// void RetainAndDoStuffWithFoo(Foo* foo) {
	// RetainedPointer<Foo> retained(foo);
	// ..
	// }
	//
	// This Retains foo on entry and Releases foo at every exit from the scope.
	//
	// The underlying pointer can be accessed with the get() and set() methods.
	// Overwriting a non-NULL pointer with set causes that pointer to be Released.
	template <class Target>
	class RetainedPointer {
	public:
	RetainedPointer() : target_(NULL) {}

	explicit RetainedPointer(ReferenceCounted<Target>* t) : target_(t) {
	if (target_ != NULL) {
	target_->Retain();
	}
	}

	~RetainedPointer() {
	if (target_ != NULL) {
	target_->Release();
	}
	}

	void set(ReferenceCounted<Target>* t) {
	if (target_ != NULL) {
	target_->Release();
	}
	target_ = t;
	if (target_ != NULL) {
	target_->Retain();
	}
	}

	Target* get() const { return static_cast<Target*>(target_); }

	private:
	ReferenceCounted<Target>* target_;

	DISALLOW_ALLOCATION();
	DISALLOW_COPY_AND_ASSIGN(RetainedPointer);
	};

	} // namespace bin
	} // namespace dart

	#endif // RUNTIME_BIN_REFERENCE_COUNTING_H_