base/memory/weak_ptr.h - platform/external/libchrome - Gitiles

 // 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.

 // Weak pointers are pointers to an object that do not affect its lifetime,
 // and which may be invalidated (i.e. reset to NULL) by the object, or its
 // owner, at any time, most commonly when the object is about to be deleted.

 // Weak pointers are useful when an object needs to be accessed safely by one
 // or more objects other than its owner, and those callers can cope with the
 // object vanishing and e.g. tasks posted to it being silently dropped.
 // Reference-counting such an object would complicate the ownership graph and
 // make it harder to reason about the object's lifetime.

 // EXAMPLE:
 //
 //  class Controller {
 //   public:
 //    void SpawnWorker() { Worker::StartNew(weak_factory_.GetWeakPtr()); }
 //    void WorkComplete(const Result& result) { ... }
 //   private:
 //    // Member variables should appear before the WeakPtrFactory, to ensure
 //    // that any WeakPtrs to Controller are invalidated before its members
 //    // variable's destructors are executed, rendering them invalid.
 //    WeakPtrFactory<Controller> weak_factory_;
 //  };
 //
 //  class Worker {
 //   public:
 //    static void StartNew(const WeakPtr<Controller>& controller) {
 //      Worker* worker = new Worker(controller);
 //      // Kick off asynchronous processing...
 //    }
 //   private:
 //    Worker(const WeakPtr<Controller>& controller)
 //        : controller_(controller) {}
 //    void DidCompleteAsynchronousProcessing(const Result& result) {
 //      if (controller_)
 //        controller_->WorkComplete(result);
 //    }
 //    WeakPtr<Controller> controller_;
 //  };
 //
 // With this implementation a caller may use SpawnWorker() to dispatch multiple
 // Workers and subsequently delete the Controller, without waiting for all
 // Workers to have completed.

 // ------------------------- IMPORTANT: Thread-safety -------------------------

 // Weak pointers may be passed safely between threads, but must always be
 // dereferenced and invalidated on the same SequencedTaskRunner otherwise
 // checking the pointer would be racey.
 //
 // To ensure correct use, the first time a WeakPtr issued by a WeakPtrFactory
 // is dereferenced, the factory and its WeakPtrs become bound to the calling
 // thread or current SequencedWorkerPool token, and cannot be dereferenced or
 // invalidated on any other task runner. Bound WeakPtrs can still be handed
 // off to other task runners, e.g. to use to post tasks back to object on the
 // bound sequence.
 //
 // Invalidating the factory's WeakPtrs un-binds it from the sequence, allowing
 // it to be passed for a different sequence to use or delete it.

 #ifndef BASE_MEMORY_WEAK_PTR_H_
 #define BASE_MEMORY_WEAK_PTR_H_

 #include "base/basictypes.h"
 #include "base/base_export.h"
 #include "base/logging.h"
 #include "base/memory/ref_counted.h"
 #include "base/sequence_checker.h"
 #include "base/template_util.h"

 namespace base {

 template <typename T> class SupportsWeakPtr;
 template <typename T> class WeakPtr;

 namespace internal {
 // These classes are part of the WeakPtr implementation.
 // DO NOT USE THESE CLASSES DIRECTLY YOURSELF.

 class BASE_EXPORT WeakReference {
  public:
   // Although Flag is bound to a specific SequencedTaskRunner, it may be
   // deleted from another via base::WeakPtr::~WeakPtr().
   class BASE_EXPORT Flag : public RefCountedThreadSafe<Flag> {
    public:
     Flag();

     void Invalidate();
     bool IsValid() const;

    private:
     friend class base::RefCountedThreadSafe<Flag>;

     ~Flag();

     SequenceChecker sequence_checker_;
     bool is_valid_;
   };

   WeakReference();
   explicit WeakReference(const Flag* flag);
   ~WeakReference();

   bool is_valid() const;

  private:
   scoped_refptr<const Flag> flag_;
 };

 class BASE_EXPORT WeakReferenceOwner {
  public:
   WeakReferenceOwner();
   ~WeakReferenceOwner();

   WeakReference GetRef() const;

   bool HasRefs() const {
     return flag_.get() && !flag_->HasOneRef();
   }

   void Invalidate();

  private:
   mutable scoped_refptr<WeakReference::Flag> flag_;
 };

 // This class simplifies the implementation of WeakPtr's type conversion
 // constructor by avoiding the need for a public accessor for ref_.  A
 // WeakPtr<T> cannot access the private members of WeakPtr<U>, so this
 // base class gives us a way to access ref_ in a protected fashion.
 class BASE_EXPORT WeakPtrBase {
  public:
   WeakPtrBase();
   ~WeakPtrBase();

  protected:
   explicit WeakPtrBase(const WeakReference& ref);

   WeakReference ref_;
 };

 // This class provides a common implementation of common functions that would
 // otherwise get instantiated separately for each distinct instantiation of
 // SupportsWeakPtr<>.
 class SupportsWeakPtrBase {
  public:
   // A safe static downcast of a WeakPtr<Base> to WeakPtr<Derived>. This
   // conversion will only compile if there is exists a Base which inherits
   // from SupportsWeakPtr<Base>. See base::AsWeakPtr() below for a helper
   // function that makes calling this easier.
   template<typename Derived>
   static WeakPtr<Derived> StaticAsWeakPtr(Derived* t) {
     typedef
         is_convertible<Derived, internal::SupportsWeakPtrBase&> convertible;
     COMPILE_ASSERT(convertible::value,
                    AsWeakPtr_argument_inherits_from_SupportsWeakPtr);
     return AsWeakPtrImpl<Derived>(t, *t);
   }

  private:
   // This template function uses type inference to find a Base of Derived
   // which is an instance of SupportsWeakPtr<Base>. We can then safely
   // static_cast the Base* to a Derived*.
   template <typename Derived, typename Base>
   static WeakPtr<Derived> AsWeakPtrImpl(
       Derived* t, const SupportsWeakPtr<Base>&) {
     WeakPtr<Base> ptr = t->Base::AsWeakPtr();
     return WeakPtr<Derived>(ptr.ref_, static_cast<Derived*>(ptr.ptr_));
   }
 };

 }  // namespace internal

 template <typename T> class WeakPtrFactory;

 // The WeakPtr class holds a weak reference to |T*|.
 //
 // This class is designed to be used like a normal pointer.  You should always
 // null-test an object of this class before using it or invoking a method that
 // may result in the underlying object being destroyed.
 //
 // EXAMPLE:
 //
 //   class Foo { ... };
 //   WeakPtr<Foo> foo;
 //   if (foo)
 //     foo->method();
 //
 template <typename T>
 class WeakPtr : public internal::WeakPtrBase {
  public:
   WeakPtr() : ptr_(NULL) {
   }

   // Allow conversion from U to T provided U "is a" T. Note that this
   // is separate from the (implicit) copy constructor.
   template <typename U>
   WeakPtr(const WeakPtr<U>& other) : WeakPtrBase(other), ptr_(other.ptr_) {
   }

   T* get() const { return ref_.is_valid() ? ptr_ : NULL; }

   T& operator*() const {
     DCHECK(get() != NULL);
     return *get();
   }
   T* operator->() const {
     DCHECK(get() != NULL);
     return get();
   }

   // Allow WeakPtr<element_type> to be used in boolean expressions, but not
   // implicitly convertible to a real bool (which is dangerous).
   //
   // Note that this trick is only safe when the == and != operators
   // are declared explicitly, as otherwise "weak_ptr1 == weak_ptr2"
   // will compile but do the wrong thing (i.e., convert to Testable
   // and then do the comparison).
  private:
   typedef T* WeakPtr::*Testable;

  public:
   operator Testable() const { return get() ? &WeakPtr::ptr_ : NULL; }

   void reset() {
     ref_ = internal::WeakReference();
     ptr_ = NULL;
   }

  private:
   // Explicitly declare comparison operators as required by the bool
   // trick, but keep them private.
   template <class U> bool operator==(WeakPtr<U> const&) const;
   template <class U> bool operator!=(WeakPtr<U> const&) const;

   friend class internal::SupportsWeakPtrBase;
   template <typename U> friend class WeakPtr;
   friend class SupportsWeakPtr<T>;
   friend class WeakPtrFactory<T>;

   WeakPtr(const internal::WeakReference& ref, T* ptr)
       : WeakPtrBase(ref),
         ptr_(ptr) {
   }

   // This pointer is only valid when ref_.is_valid() is true.  Otherwise, its
   // value is undefined (as opposed to NULL).
   T* ptr_;
 };

 // A class may be composed of a WeakPtrFactory and thereby
 // control how it exposes weak pointers to itself.  This is helpful if you only
 // need weak pointers within the implementation of a class.  This class is also
 // useful when working with primitive types.  For example, you could have a
 // WeakPtrFactory<bool> that is used to pass around a weak reference to a bool.
 template <class T>
 class WeakPtrFactory {
  public:
   explicit WeakPtrFactory(T* ptr) : ptr_(ptr) {
   }

   ~WeakPtrFactory() {
     ptr_ = NULL;
   }

   WeakPtr<T> GetWeakPtr() {
     DCHECK(ptr_);
     return WeakPtr<T>(weak_reference_owner_.GetRef(), ptr_);
   }

   // Call this method to invalidate all existing weak pointers.
   void InvalidateWeakPtrs() {
     DCHECK(ptr_);
     weak_reference_owner_.Invalidate();
   }

   // Call this method to determine if any weak pointers exist.
   bool HasWeakPtrs() const {
     DCHECK(ptr_);
     return weak_reference_owner_.HasRefs();
   }

  private:
   internal::WeakReferenceOwner weak_reference_owner_;
   T* ptr_;
   DISALLOW_IMPLICIT_CONSTRUCTORS(WeakPtrFactory);
 };

 // A class may extend from SupportsWeakPtr to let others take weak pointers to
 // it. This avoids the class itself implementing boilerplate to dispense weak
 // pointers.  However, since SupportsWeakPtr's destructor won't invalidate
 // weak pointers to the class until after the derived class' members have been
 // destroyed, its use can lead to subtle use-after-destroy issues.
 template <class T>
 class SupportsWeakPtr : public internal::SupportsWeakPtrBase {
  public:
   SupportsWeakPtr() {}

   WeakPtr<T> AsWeakPtr() {
     return WeakPtr<T>(weak_reference_owner_.GetRef(), static_cast<T*>(this));
   }

  protected:
   ~SupportsWeakPtr() {}

  private:
   internal::WeakReferenceOwner weak_reference_owner_;
   DISALLOW_COPY_AND_ASSIGN(SupportsWeakPtr);
 };

 // Helper function that uses type deduction to safely return a WeakPtr<Derived>
 // when Derived doesn't directly extend SupportsWeakPtr<Derived>, instead it
 // extends a Base that extends SupportsWeakPtr<Base>.
 //
 // EXAMPLE:
 //   class Base : public base::SupportsWeakPtr<Producer> {};
 //   class Derived : public Base {};
 //
 //   Derived derived;
 //   base::WeakPtr<Derived> ptr = base::AsWeakPtr(&derived);
 //
 // Note that the following doesn't work (invalid type conversion) since
 // Derived::AsWeakPtr() is WeakPtr<Base> SupportsWeakPtr<Base>::AsWeakPtr(),
 // and there's no way to safely cast WeakPtr<Base> to WeakPtr<Derived> at
 // the caller.
 //
 //   base::WeakPtr<Derived> ptr = derived.AsWeakPtr();  // Fails.

 template <typename Derived>
 WeakPtr<Derived> AsWeakPtr(Derived* t) {
   return internal::SupportsWeakPtrBase::StaticAsWeakPtr<Derived>(t);
 }

 }  // namespace base

 #endif  // BASE_MEMORY_WEAK_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.

	// Weak pointers are pointers to an object that do not affect its lifetime,
	// and which may be invalidated (i.e. reset to NULL) by the object, or its
	// owner, at any time, most commonly when the object is about to be deleted.

	// Weak pointers are useful when an object needs to be accessed safely by one
	// or more objects other than its owner, and those callers can cope with the
	// object vanishing and e.g. tasks posted to it being silently dropped.
	// Reference-counting such an object would complicate the ownership graph and
	// make it harder to reason about the object's lifetime.

	// EXAMPLE:
	//
	// class Controller {
	// public:
	// void SpawnWorker() { Worker::StartNew(weak_factory_.GetWeakPtr()); }
	// void WorkComplete(const Result& result) { ... }
	// private:
	// // Member variables should appear before the WeakPtrFactory, to ensure
	// // that any WeakPtrs to Controller are invalidated before its members
	// // variable's destructors are executed, rendering them invalid.
	// WeakPtrFactory<Controller> weak_factory_;
	// };
	//
	// class Worker {
	// public:
	// static void StartNew(const WeakPtr<Controller>& controller) {
	// Worker* worker = new Worker(controller);
	// // Kick off asynchronous processing...
	// }
	// private:
	// Worker(const WeakPtr<Controller>& controller)
	// : controller_(controller) {}
	// void DidCompleteAsynchronousProcessing(const Result& result) {
	// if (controller_)
	// controller_->WorkComplete(result);
	// }
	// WeakPtr<Controller> controller_;
	// };
	//
	// With this implementation a caller may use SpawnWorker() to dispatch multiple
	// Workers and subsequently delete the Controller, without waiting for all
	// Workers to have completed.

	// ------------------------- IMPORTANT: Thread-safety -------------------------

	// Weak pointers may be passed safely between threads, but must always be
	// dereferenced and invalidated on the same SequencedTaskRunner otherwise
	// checking the pointer would be racey.
	//
	// To ensure correct use, the first time a WeakPtr issued by a WeakPtrFactory
	// is dereferenced, the factory and its WeakPtrs become bound to the calling
	// thread or current SequencedWorkerPool token, and cannot be dereferenced or
	// invalidated on any other task runner. Bound WeakPtrs can still be handed
	// off to other task runners, e.g. to use to post tasks back to object on the
	// bound sequence.
	//
	// Invalidating the factory's WeakPtrs un-binds it from the sequence, allowing
	// it to be passed for a different sequence to use or delete it.

	#ifndef BASE_MEMORY_WEAK_PTR_H_
	#define BASE_MEMORY_WEAK_PTR_H_

	#include "base/basictypes.h"
	#include "base/base_export.h"
	#include "base/logging.h"
	#include "base/memory/ref_counted.h"
	#include "base/sequence_checker.h"
	#include "base/template_util.h"

	namespace base {

	template <typename T> class SupportsWeakPtr;
	template <typename T> class WeakPtr;

	namespace internal {
	// These classes are part of the WeakPtr implementation.
	// DO NOT USE THESE CLASSES DIRECTLY YOURSELF.

	class BASE_EXPORT WeakReference {
	public:
	// Although Flag is bound to a specific SequencedTaskRunner, it may be
	// deleted from another via base::WeakPtr::~WeakPtr().
	class BASE_EXPORT Flag : public RefCountedThreadSafe<Flag> {
	public:
	Flag();

	void Invalidate();
	bool IsValid() const;

	private:
	friend class base::RefCountedThreadSafe<Flag>;

	~Flag();

	SequenceChecker sequence_checker_;
	bool is_valid_;
	};

	WeakReference();
	explicit WeakReference(const Flag* flag);
	~WeakReference();

	bool is_valid() const;

	private:
	scoped_refptr<const Flag> flag_;
	};

	class BASE_EXPORT WeakReferenceOwner {
	public:
	WeakReferenceOwner();
	~WeakReferenceOwner();

	WeakReference GetRef() const;

	bool HasRefs() const {
	return flag_.get() && !flag_->HasOneRef();
	}

	void Invalidate();

	private:
	mutable scoped_refptr<WeakReference::Flag> flag_;
	};

	// This class simplifies the implementation of WeakPtr's type conversion
	// constructor by avoiding the need for a public accessor for ref_. A
	// WeakPtr<T> cannot access the private members of WeakPtr<U>, so this
	// base class gives us a way to access ref_ in a protected fashion.
	class BASE_EXPORT WeakPtrBase {
	public:
	WeakPtrBase();
	~WeakPtrBase();

	protected:
	explicit WeakPtrBase(const WeakReference& ref);

	WeakReference ref_;
	};

	// This class provides a common implementation of common functions that would
	// otherwise get instantiated separately for each distinct instantiation of
	// SupportsWeakPtr<>.
	class SupportsWeakPtrBase {
	public:
	// A safe static downcast of a WeakPtr<Base> to WeakPtr<Derived>. This
	// conversion will only compile if there is exists a Base which inherits
	// from SupportsWeakPtr<Base>. See base::AsWeakPtr() below for a helper
	// function that makes calling this easier.
	template<typename Derived>
	static WeakPtr<Derived> StaticAsWeakPtr(Derived* t) {
	typedef
	is_convertible<Derived, internal::SupportsWeakPtrBase&> convertible;
	COMPILE_ASSERT(convertible::value,
	AsWeakPtr_argument_inherits_from_SupportsWeakPtr);
	return AsWeakPtrImpl<Derived>(t, *t);
	}

	private:
	// This template function uses type inference to find a Base of Derived
	// which is an instance of SupportsWeakPtr<Base>. We can then safely
	// static_cast the Base* to a Derived*.
	template <typename Derived, typename Base>
	static WeakPtr<Derived> AsWeakPtrImpl(
	Derived* t, const SupportsWeakPtr<Base>&) {
	WeakPtr<Base> ptr = t->Base::AsWeakPtr();
	return WeakPtr<Derived>(ptr.ref_, static_cast<Derived*>(ptr.ptr_));
	}
	};

	} // namespace internal

	template <typename T> class WeakPtrFactory;

	// The WeakPtr class holds a weak reference to \|T*\|.
	//
	// This class is designed to be used like a normal pointer. You should always
	// null-test an object of this class before using it or invoking a method that
	// may result in the underlying object being destroyed.
	//
	// EXAMPLE:
	//
	// class Foo { ... };
	// WeakPtr<Foo> foo;
	// if (foo)
	// foo->method();
	//
	template <typename T>
	class WeakPtr : public internal::WeakPtrBase {
	public:
	WeakPtr() : ptr_(NULL) {
	}

	// Allow conversion from U to T provided U "is a" T. Note that this
	// is separate from the (implicit) copy constructor.
	template <typename U>
	WeakPtr(const WeakPtr<U>& other) : WeakPtrBase(other), ptr_(other.ptr_) {
	}

	T* get() const { return ref_.is_valid() ? ptr_ : NULL; }

	T& operator*() const {
	DCHECK(get() != NULL);
	return *get();
	}
	T* operator->() const {
	DCHECK(get() != NULL);
	return get();
	}

	// Allow WeakPtr<element_type> to be used in boolean expressions, but not
	// implicitly convertible to a real bool (which is dangerous).
	//
	// Note that this trick is only safe when the == and != operators
	// are declared explicitly, as otherwise "weak_ptr1 == weak_ptr2"
	// will compile but do the wrong thing (i.e., convert to Testable
	// and then do the comparison).
	private:
	typedef T* WeakPtr::*Testable;

	public:
	operator Testable() const { return get() ? &WeakPtr::ptr_ : NULL; }

	void reset() {
	ref_ = internal::WeakReference();
	ptr_ = NULL;
	}

	private:
	// Explicitly declare comparison operators as required by the bool
	// trick, but keep them private.
	template <class U> bool operator==(WeakPtr<U> const&) const;
	template <class U> bool operator!=(WeakPtr<U> const&) const;

	friend class internal::SupportsWeakPtrBase;
	template <typename U> friend class WeakPtr;
	friend class SupportsWeakPtr<T>;
	friend class WeakPtrFactory<T>;

	WeakPtr(const internal::WeakReference& ref, T* ptr)
	: WeakPtrBase(ref),
	ptr_(ptr) {
	}

	// This pointer is only valid when ref_.is_valid() is true. Otherwise, its
	// value is undefined (as opposed to NULL).
	T* ptr_;
	};

	// A class may be composed of a WeakPtrFactory and thereby
	// control how it exposes weak pointers to itself. This is helpful if you only
	// need weak pointers within the implementation of a class. This class is also
	// useful when working with primitive types. For example, you could have a
	// WeakPtrFactory<bool> that is used to pass around a weak reference to a bool.
	template <class T>
	class WeakPtrFactory {
	public:
	explicit WeakPtrFactory(T* ptr) : ptr_(ptr) {
	}

	~WeakPtrFactory() {
	ptr_ = NULL;
	}

	WeakPtr<T> GetWeakPtr() {
	DCHECK(ptr_);
	return WeakPtr<T>(weak_reference_owner_.GetRef(), ptr_);
	}

	// Call this method to invalidate all existing weak pointers.
	void InvalidateWeakPtrs() {
	DCHECK(ptr_);
	weak_reference_owner_.Invalidate();
	}

	// Call this method to determine if any weak pointers exist.
	bool HasWeakPtrs() const {
	DCHECK(ptr_);
	return weak_reference_owner_.HasRefs();
	}

	private:
	internal::WeakReferenceOwner weak_reference_owner_;
	T* ptr_;
	DISALLOW_IMPLICIT_CONSTRUCTORS(WeakPtrFactory);
	};

	// A class may extend from SupportsWeakPtr to let others take weak pointers to
	// it. This avoids the class itself implementing boilerplate to dispense weak
	// pointers. However, since SupportsWeakPtr's destructor won't invalidate
	// weak pointers to the class until after the derived class' members have been
	// destroyed, its use can lead to subtle use-after-destroy issues.
	template <class T>
	class SupportsWeakPtr : public internal::SupportsWeakPtrBase {
	public:
	SupportsWeakPtr() {}

	WeakPtr<T> AsWeakPtr() {
	return WeakPtr<T>(weak_reference_owner_.GetRef(), static_cast<T*>(this));
	}

	protected:
	~SupportsWeakPtr() {}

	private:
	internal::WeakReferenceOwner weak_reference_owner_;
	DISALLOW_COPY_AND_ASSIGN(SupportsWeakPtr);
	};

	// Helper function that uses type deduction to safely return a WeakPtr<Derived>
	// when Derived doesn't directly extend SupportsWeakPtr<Derived>, instead it
	// extends a Base that extends SupportsWeakPtr<Base>.
	//
	// EXAMPLE:
	// class Base : public base::SupportsWeakPtr<Producer> {};
	// class Derived : public Base {};
	//
	// Derived derived;
	// base::WeakPtr<Derived> ptr = base::AsWeakPtr(&derived);
	//
	// Note that the following doesn't work (invalid type conversion) since
	// Derived::AsWeakPtr() is WeakPtr<Base> SupportsWeakPtr<Base>::AsWeakPtr(),
	// and there's no way to safely cast WeakPtr<Base> to WeakPtr<Derived> at
	// the caller.
	//
	// base::WeakPtr<Derived> ptr = derived.AsWeakPtr(); // Fails.

	template <typename Derived>
	WeakPtr<Derived> AsWeakPtr(Derived* t) {
	return internal::SupportsWeakPtrBase::StaticAsWeakPtr<Derived>(t);
	}

	} // namespace base

	#endif // BASE_MEMORY_WEAK_PTR_H_