src/base/callback_internal.h - cobalt - Git at Google

 // 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.

 // This file contains utility functions and classes that help the
 // implementation, and management of the Callback objects.

 #ifndef BASE_CALLBACK_INTERNAL_H_
 #define BASE_CALLBACK_INTERNAL_H_

 #include <stddef.h>

 #include "base/base_export.h"
 #include "base/memory/ref_counted.h"
 #include "base/memory/scoped_ptr.h"

 template <typename T>
 class ScopedVector;

 namespace base {
 namespace internal {

 // BindStateBase is used to provide an opaque handle that the Callback
 // class can use to represent a function object with bound arguments.  It
 // behaves as an existential type that is used by a corresponding
 // DoInvoke function to perform the function execution.  This allows
 // us to shield the Callback class from the types of the bound argument via
 // "type erasure."
 class BindStateBase : public RefCountedThreadSafe<BindStateBase> {
  protected:
   friend class RefCountedThreadSafe<BindStateBase>;
   virtual ~BindStateBase() {}
 };

 // Holds the Callback methods that don't require specialization to reduce
 // template bloat.
 class BASE_EXPORT CallbackBase {
  public:
   // Returns true if Callback is null (doesn't refer to anything).
   bool is_null() const;

   // Returns the Callback into an uninitialized state.
   void Reset();

  protected:
   // In C++, it is safe to cast function pointers to function pointers of
   // another type. It is not okay to use void*. We create a InvokeFuncStorage
   // that that can store our function pointer, and then cast it back to
   // the original type on usage.
   typedef void(*InvokeFuncStorage)(void);

   // Returns true if this callback equals |other|. |other| may be null.
   bool Equals(const CallbackBase& other) const;

   // Allow initializing of |bind_state_| via the constructor to avoid default
   // initialization of the scoped_refptr.  We do not also initialize
   // |polymorphic_invoke_| here because doing a normal assignment in the
   // derived Callback templates makes for much nicer compiler errors.
   explicit CallbackBase(BindStateBase* bind_state);

   // Force the destructor to be instantiated inside this translation unit so
   // that our subclasses will not get inlined versions.  Avoids more template
   // bloat.
   ~CallbackBase();

   scoped_refptr<BindStateBase> bind_state_;
   InvokeFuncStorage polymorphic_invoke_;
 };

 // This is a typetraits object that's used to take an argument type, and
 // extract a suitable type for storing and forwarding arguments.
 //
 // In particular, it strips off references, and converts arrays to
 // pointers for storage; and it avoids accidentally trying to create a
 // "reference of a reference" if the argument is a reference type.
 //
 // This array type becomes an issue for storage because we are passing bound
 // parameters by const reference. In this case, we end up passing an actual
 // array type in the initializer list which C++ does not allow.  This will
 // break passing of C-string literals.
 template <typename T>
 struct CallbackParamTraits {
   typedef const T& ForwardType;
   typedef T StorageType;
 };

 // The Storage should almost be impossible to trigger unless someone manually
 // specifies type of the bind parameters.  However, in case they do,
 // this will guard against us accidentally storing a reference parameter.
 //
 // The ForwardType should only be used for unbound arguments.
 template <typename T>
 struct CallbackParamTraits<T&> {
   typedef T& ForwardType;
   typedef T StorageType;
 };

 // Note that for array types, we implicitly add a const in the conversion. This
 // means that it is not possible to bind array arguments to functions that take
 // a non-const pointer. Trying to specialize the template based on a "const
 // T[n]" does not seem to match correctly, so we are stuck with this
 // restriction.
 template <typename T, size_t n>
 struct CallbackParamTraits<T[n]> {
   typedef const T* ForwardType;
   typedef const T* StorageType;
 };

 // See comment for CallbackParamTraits<T[n]>.
 template <typename T>
 struct CallbackParamTraits<T[]> {
   typedef const T* ForwardType;
   typedef const T* StorageType;
 };

 // Parameter traits for movable-but-not-copyable scopers.
 //
 // Callback<>/Bind() understands movable-but-not-copyable semantics where
 // the type cannot be copied but can still have its state destructively
 // transferred (aka. moved) to another instance of the same type by calling a
 // helper function.  When used with Bind(), this signifies transferal of the
 // object's state to the target function.
 //
 // For these types, the ForwardType must not be a const reference, or a
 // reference.  A const reference is inappropriate, and would break const
 // correctness, because we are implementing a destructive move.  A non-const
 // reference cannot be used with temporaries which means the result of a
 // function or a cast would not be usable with Callback<> or Bind().
 //
 // TODO(ajwong): We might be able to use SFINAE to search for the existence of
 // a Pass() function in the type and avoid the whitelist in CallbackParamTraits
 // and CallbackForward.
 template <typename T>
 struct CallbackParamTraits<scoped_ptr<T> > {
   typedef scoped_ptr<T> ForwardType;
   typedef scoped_ptr<T> StorageType;
 };

 template <typename T>
 struct CallbackParamTraits<scoped_array<T> > {
   typedef scoped_array<T> ForwardType;
   typedef scoped_array<T> StorageType;
 };

 template <typename T, typename R>
 struct CallbackParamTraits<scoped_ptr_malloc<T, R> > {
   typedef scoped_ptr_malloc<T, R> ForwardType;
   typedef scoped_ptr_malloc<T, R> StorageType;
 };

 template <typename T>
 struct CallbackParamTraits<ScopedVector<T> > {
   typedef ScopedVector<T> ForwardType;
   typedef ScopedVector<T> StorageType;
 };

 // CallbackForward() is a very limited simulation of C++11's std::forward()
 // used by the Callback/Bind system for a set of movable-but-not-copyable
 // types.  It is needed because forwarding a movable-but-not-copyable
 // argument to another function requires us to invoke the proper move
 // operator to create a rvalue version of the type.  The supported types are
 // whitelisted below as overloads of the CallbackForward() function. The
 // default template compiles out to be a no-op.
 //
 // In C++11, std::forward would replace all uses of this function.  However, it
 // is impossible to implement a general std::forward with C++11 due to a lack
 // of rvalue references.
 //
 // In addition to Callback/Bind, this is used by PostTaskAndReplyWithResult to
 // simulate std::forward() and forward the result of one Callback as a
 // parameter to another callback. This is to support Callbacks that return
 // the movable-but-not-copyable types whitelisted above.
 template <typename T>
 T& CallbackForward(T& t) { return t; }

 template <typename T>
 scoped_ptr<T> CallbackForward(scoped_ptr<T>& p) { return p.Pass(); }

 template <typename T>
 scoped_array<T> CallbackForward(scoped_array<T>& p) { return p.Pass(); }

 template <typename T, typename R>
 scoped_ptr_malloc<T, R> CallbackForward(scoped_ptr_malloc<T, R>& p) {
   return p.Pass();
 }

 template <typename T>
 ScopedVector<T> CallbackForward(ScopedVector<T>& p) { return p.Pass(); }

 }  // namespace internal
 }  // namespace base

 #endif  // BASE_CALLBACK_INTERNAL_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.

	// This file contains utility functions and classes that help the
	// implementation, and management of the Callback objects.

	#ifndef BASE_CALLBACK_INTERNAL_H_
	#define BASE_CALLBACK_INTERNAL_H_

	#include <stddef.h>

	#include "base/base_export.h"
	#include "base/memory/ref_counted.h"
	#include "base/memory/scoped_ptr.h"

	template <typename T>
	class ScopedVector;

	namespace base {
	namespace internal {

	// BindStateBase is used to provide an opaque handle that the Callback
	// class can use to represent a function object with bound arguments. It
	// behaves as an existential type that is used by a corresponding
	// DoInvoke function to perform the function execution. This allows
	// us to shield the Callback class from the types of the bound argument via
	// "type erasure."
	class BindStateBase : public RefCountedThreadSafe<BindStateBase> {
	protected:
	friend class RefCountedThreadSafe<BindStateBase>;
	virtual ~BindStateBase() {}
	};

	// Holds the Callback methods that don't require specialization to reduce
	// template bloat.
	class BASE_EXPORT CallbackBase {
	public:
	// Returns true if Callback is null (doesn't refer to anything).
	bool is_null() const;

	// Returns the Callback into an uninitialized state.
	void Reset();

	protected:
	// In C++, it is safe to cast function pointers to function pointers of
	// another type. It is not okay to use void*. We create a InvokeFuncStorage
	// that that can store our function pointer, and then cast it back to
	// the original type on usage.
	typedef void(*InvokeFuncStorage)(void);

	// Returns true if this callback equals \|other\|. \|other\| may be null.
	bool Equals(const CallbackBase& other) const;

	// Allow initializing of \|bind_state_\| via the constructor to avoid default
	// initialization of the scoped_refptr. We do not also initialize
	// \|polymorphic_invoke_\| here because doing a normal assignment in the
	// derived Callback templates makes for much nicer compiler errors.
	explicit CallbackBase(BindStateBase* bind_state);

	// Force the destructor to be instantiated inside this translation unit so
	// that our subclasses will not get inlined versions. Avoids more template
	// bloat.
	~CallbackBase();

	scoped_refptr<BindStateBase> bind_state_;
	InvokeFuncStorage polymorphic_invoke_;
	};

	// This is a typetraits object that's used to take an argument type, and
	// extract a suitable type for storing and forwarding arguments.
	//
	// In particular, it strips off references, and converts arrays to
	// pointers for storage; and it avoids accidentally trying to create a
	// "reference of a reference" if the argument is a reference type.
	//
	// This array type becomes an issue for storage because we are passing bound
	// parameters by const reference. In this case, we end up passing an actual
	// array type in the initializer list which C++ does not allow. This will
	// break passing of C-string literals.
	template <typename T>
	struct CallbackParamTraits {
	typedef const T& ForwardType;
	typedef T StorageType;
	};

	// The Storage should almost be impossible to trigger unless someone manually
	// specifies type of the bind parameters. However, in case they do,
	// this will guard against us accidentally storing a reference parameter.
	//
	// The ForwardType should only be used for unbound arguments.
	template <typename T>
	struct CallbackParamTraits<T&> {
	typedef T& ForwardType;
	typedef T StorageType;
	};

	// Note that for array types, we implicitly add a const in the conversion. This
	// means that it is not possible to bind array arguments to functions that take
	// a non-const pointer. Trying to specialize the template based on a "const
	// T[n]" does not seem to match correctly, so we are stuck with this
	// restriction.
	template <typename T, size_t n>
	struct CallbackParamTraits<T[n]> {
	typedef const T* ForwardType;
	typedef const T* StorageType;
	};

	// See comment for CallbackParamTraits<T[n]>.
	template <typename T>
	struct CallbackParamTraits<T[]> {
	typedef const T* ForwardType;
	typedef const T* StorageType;
	};

	// Parameter traits for movable-but-not-copyable scopers.
	//
	// Callback<>/Bind() understands movable-but-not-copyable semantics where
	// the type cannot be copied but can still have its state destructively
	// transferred (aka. moved) to another instance of the same type by calling a
	// helper function. When used with Bind(), this signifies transferal of the
	// object's state to the target function.
	//
	// For these types, the ForwardType must not be a const reference, or a
	// reference. A const reference is inappropriate, and would break const
	// correctness, because we are implementing a destructive move. A non-const
	// reference cannot be used with temporaries which means the result of a
	// function or a cast would not be usable with Callback<> or Bind().
	//
	// TODO(ajwong): We might be able to use SFINAE to search for the existence of
	// a Pass() function in the type and avoid the whitelist in CallbackParamTraits
	// and CallbackForward.
	template <typename T>
	struct CallbackParamTraits<scoped_ptr<T> > {
	typedef scoped_ptr<T> ForwardType;
	typedef scoped_ptr<T> StorageType;
	};

	template <typename T>
	struct CallbackParamTraits<scoped_array<T> > {
	typedef scoped_array<T> ForwardType;
	typedef scoped_array<T> StorageType;
	};

	template <typename T, typename R>
	struct CallbackParamTraits<scoped_ptr_malloc<T, R> > {
	typedef scoped_ptr_malloc<T, R> ForwardType;
	typedef scoped_ptr_malloc<T, R> StorageType;
	};

	template <typename T>
	struct CallbackParamTraits<ScopedVector<T> > {
	typedef ScopedVector<T> ForwardType;
	typedef ScopedVector<T> StorageType;
	};

	// CallbackForward() is a very limited simulation of C++11's std::forward()
	// used by the Callback/Bind system for a set of movable-but-not-copyable
	// types. It is needed because forwarding a movable-but-not-copyable
	// argument to another function requires us to invoke the proper move
	// operator to create a rvalue version of the type. The supported types are
	// whitelisted below as overloads of the CallbackForward() function. The
	// default template compiles out to be a no-op.
	//
	// In C++11, std::forward would replace all uses of this function. However, it
	// is impossible to implement a general std::forward with C++11 due to a lack
	// of rvalue references.
	//
	// In addition to Callback/Bind, this is used by PostTaskAndReplyWithResult to
	// simulate std::forward() and forward the result of one Callback as a
	// parameter to another callback. This is to support Callbacks that return
	// the movable-but-not-copyable types whitelisted above.
	template <typename T>
	T& CallbackForward(T& t) { return t; }

	template <typename T>
	scoped_ptr<T> CallbackForward(scoped_ptr<T>& p) { return p.Pass(); }

	template <typename T>
	scoped_array<T> CallbackForward(scoped_array<T>& p) { return p.Pass(); }

	template <typename T, typename R>
	scoped_ptr_malloc<T, R> CallbackForward(scoped_ptr_malloc<T, R>& p) {
	return p.Pass();
	}

	template <typename T>
	ScopedVector<T> CallbackForward(ScopedVector<T>& p) { return p.Pass(); }

	} // namespace internal
	} // namespace base

	#endif // BASE_CALLBACK_INTERNAL_H_