base/scoped_generic.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_SCOPED_GENERIC_H_
 #define BASE_SCOPED_GENERIC_H_

 #include <stdlib.h>

 #include <algorithm>

 #include "base/compiler_specific.h"
 #include "base/macros.h"

 namespace base {

 // This class acts like unique_ptr with a custom deleter (although is slightly
 // less fancy in some of the more escoteric respects) except that it keeps a
 // copy of the object rather than a pointer, and we require that the contained
 // object has some kind of "invalid" value.
 //
 // Defining a scoper based on this class allows you to get a scoper for
 // non-pointer types without having to write custom code for set, reset, and
 // move, etc. and get almost identical semantics that people are used to from
 // unique_ptr.
 //
 // It is intended that you will typedef this class with an appropriate deleter
 // to implement clean up tasks for objects that act like pointers from a
 // resource management standpoint but aren't, such as file descriptors and
 // various types of operating system handles. Using unique_ptr for these
 // things requires that you keep a pointer to the handle valid for the lifetime
 // of the scoper (which is easy to mess up).
 //
 // For an object to be able to be put into a ScopedGeneric, it must support
 // standard copyable semantics and have a specific "invalid" value. The traits
 // must define a free function and also the invalid value to assign for
 // default-constructed and released objects.
 //
 //   struct FooScopedTraits {
 //     // It's assumed that this is a fast inline function with little-to-no
 //     // penalty for duplicate calls. This must be a static function even
 //     // for stateful traits.
 //     static int InvalidValue() {
 //       return 0;
 //     }
 //
 //     // This free function will not be called if f == InvalidValue()!
 //     static void Free(int f) {
 //       ::FreeFoo(f);
 //     }
 //   };
 //
 //   typedef ScopedGeneric<int, FooScopedTraits> ScopedFoo;
 template <typename T, typename Traits>
 class ScopedGeneric {
  private:
   // This must be first since it's used inline below.
   //
   // Use the empty base class optimization to allow us to have a D
   // member, while avoiding any space overhead for it when D is an
   // empty class.  See e.g. http://www.cantrip.org/emptyopt.html for a good
   // discussion of this technique.
   struct Data : public Traits {
     explicit Data(const T& in) : generic(in) {}
     Data(const T& in, const Traits& other) : Traits(other), generic(in) {}
     T generic;
   };

  public:
   typedef T element_type;
   typedef Traits traits_type;

   ScopedGeneric() : data_(traits_type::InvalidValue()) {}

   // Constructor. Takes responsibility for freeing the resource associated with
   // the object T.
   explicit ScopedGeneric(const element_type& value) : data_(value) {}

   // Constructor. Allows initialization of a stateful traits object.
   ScopedGeneric(const element_type& value, const traits_type& traits)
       : data_(value, traits) {}

   // Move constructor. Allows initialization from a ScopedGeneric rvalue.
   ScopedGeneric(ScopedGeneric<T, Traits>&& rvalue)
       : data_(rvalue.release(), rvalue.get_traits()) {}

   ~ScopedGeneric() { FreeIfNecessary(); }

   // operator=. Allows assignment from a ScopedGeneric rvalue.
   ScopedGeneric& operator=(ScopedGeneric<T, Traits>&& rvalue) {
     reset(rvalue.release());
     return *this;
   }

   // Frees the currently owned object, if any. Then takes ownership of a new
   // object, if given. Self-resets are not allowd as on unique_ptr. See
   // http://crbug.com/162971
   void reset(const element_type& value = traits_type::InvalidValue()) {
     if (data_.generic != traits_type::InvalidValue() && data_.generic == value)
       abort();
     FreeIfNecessary();
     data_.generic = value;
   }

   void swap(ScopedGeneric& other) {
     // Standard swap idiom: 'using std::swap' ensures that std::swap is
     // present in the overload set, but we call swap unqualified so that
     // any more-specific overloads can be used, if available.
     using std::swap;
     swap(static_cast<Traits&>(data_), static_cast<Traits&>(other.data_));
     swap(data_.generic, other.data_.generic);
   }

   // Release the object. The return value is the current object held by this
   // object. After this operation, this object will hold a null value, and
   // will not own the object any more.
   element_type release() WARN_UNUSED_RESULT {
     element_type old_generic = data_.generic;
     data_.generic = traits_type::InvalidValue();
     return old_generic;
   }

   // Returns a raw pointer to the object storage, to allow the scoper to be used
   // to receive and manage out-parameter values. Implies reset().
   element_type* receive() WARN_UNUSED_RESULT {
     reset();
     return &data_.generic;
   }

   const element_type& get() const { return data_.generic; }

   // Returns true if this object doesn't hold the special null value for the
   // associated data type.
   bool is_valid() const { return data_.generic != traits_type::InvalidValue(); }

   bool operator==(const element_type& value) const {
     return data_.generic == value;
   }
   bool operator!=(const element_type& value) const {
     return data_.generic != value;
   }

   Traits& get_traits() { return data_; }
   const Traits& get_traits() const { return data_; }

  private:
   void FreeIfNecessary() {
     if (data_.generic != traits_type::InvalidValue()) {
       data_.Free(data_.generic);
       data_.generic = traits_type::InvalidValue();
     }
   }

   // Forbid comparison. If U != T, it totally doesn't make sense, and if U ==
   // T, it still doesn't make sense because you should never have the same
   // object owned by two different ScopedGenerics.
   template <typename T2, typename Traits2>
   bool operator==(const ScopedGeneric<T2, Traits2>& p2) const;
   template <typename T2, typename Traits2>
   bool operator!=(const ScopedGeneric<T2, Traits2>& p2) const;

   Data data_;

   DISALLOW_COPY_AND_ASSIGN(ScopedGeneric);
 };

 template <class T, class Traits>
 void swap(const ScopedGeneric<T, Traits>& a,
           const ScopedGeneric<T, Traits>& b) {
   a.swap(b);
 }

 template <class T, class Traits>
 bool operator==(const T& value, const ScopedGeneric<T, Traits>& scoped) {
   return value == scoped.get();
 }

 template <class T, class Traits>
 bool operator!=(const T& value, const ScopedGeneric<T, Traits>& scoped) {
   return value != scoped.get();
 }

 }  // namespace base

 #endif  // BASE_SCOPED_GENERIC_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_SCOPED_GENERIC_H_
	#define BASE_SCOPED_GENERIC_H_

	#include <stdlib.h>

	#include <algorithm>

	#include "base/compiler_specific.h"
	#include "base/macros.h"

	namespace base {

	// This class acts like unique_ptr with a custom deleter (although is slightly
	// less fancy in some of the more escoteric respects) except that it keeps a
	// copy of the object rather than a pointer, and we require that the contained
	// object has some kind of "invalid" value.
	//
	// Defining a scoper based on this class allows you to get a scoper for
	// non-pointer types without having to write custom code for set, reset, and
	// move, etc. and get almost identical semantics that people are used to from
	// unique_ptr.
	//
	// It is intended that you will typedef this class with an appropriate deleter
	// to implement clean up tasks for objects that act like pointers from a
	// resource management standpoint but aren't, such as file descriptors and
	// various types of operating system handles. Using unique_ptr for these
	// things requires that you keep a pointer to the handle valid for the lifetime
	// of the scoper (which is easy to mess up).
	//
	// For an object to be able to be put into a ScopedGeneric, it must support
	// standard copyable semantics and have a specific "invalid" value. The traits
	// must define a free function and also the invalid value to assign for
	// default-constructed and released objects.
	//
	// struct FooScopedTraits {
	// // It's assumed that this is a fast inline function with little-to-no
	// // penalty for duplicate calls. This must be a static function even
	// // for stateful traits.
	// static int InvalidValue() {
	// return 0;
	// }
	//
	// // This free function will not be called if f == InvalidValue()!
	// static void Free(int f) {
	// ::FreeFoo(f);
	// }
	// };
	//
	// typedef ScopedGeneric<int, FooScopedTraits> ScopedFoo;
	template <typename T, typename Traits>
	class ScopedGeneric {
	private:
	// This must be first since it's used inline below.
	//
	// Use the empty base class optimization to allow us to have a D
	// member, while avoiding any space overhead for it when D is an
	// empty class. See e.g. http://www.cantrip.org/emptyopt.html for a good
	// discussion of this technique.
	struct Data : public Traits {
	explicit Data(const T& in) : generic(in) {}
	Data(const T& in, const Traits& other) : Traits(other), generic(in) {}
	T generic;
	};

	public:
	typedef T element_type;
	typedef Traits traits_type;

	ScopedGeneric() : data_(traits_type::InvalidValue()) {}

	// Constructor. Takes responsibility for freeing the resource associated with
	// the object T.
	explicit ScopedGeneric(const element_type& value) : data_(value) {}

	// Constructor. Allows initialization of a stateful traits object.
	ScopedGeneric(const element_type& value, const traits_type& traits)
	: data_(value, traits) {}

	// Move constructor. Allows initialization from a ScopedGeneric rvalue.
	ScopedGeneric(ScopedGeneric<T, Traits>&& rvalue)
	: data_(rvalue.release(), rvalue.get_traits()) {}

	~ScopedGeneric() { FreeIfNecessary(); }

	// operator=. Allows assignment from a ScopedGeneric rvalue.
	ScopedGeneric& operator=(ScopedGeneric<T, Traits>&& rvalue) {
	reset(rvalue.release());
	return *this;
	}

	// Frees the currently owned object, if any. Then takes ownership of a new
	// object, if given. Self-resets are not allowd as on unique_ptr. See
	// http://crbug.com/162971
	void reset(const element_type& value = traits_type::InvalidValue()) {
	if (data_.generic != traits_type::InvalidValue() && data_.generic == value)
	abort();
	FreeIfNecessary();
	data_.generic = value;
	}

	void swap(ScopedGeneric& other) {
	// Standard swap idiom: 'using std::swap' ensures that std::swap is
	// present in the overload set, but we call swap unqualified so that
	// any more-specific overloads can be used, if available.
	using std::swap;
	swap(static_cast<Traits&>(data_), static_cast<Traits&>(other.data_));
	swap(data_.generic, other.data_.generic);
	}

	// Release the object. The return value is the current object held by this
	// object. After this operation, this object will hold a null value, and
	// will not own the object any more.
	element_type release() WARN_UNUSED_RESULT {
	element_type old_generic = data_.generic;
	data_.generic = traits_type::InvalidValue();
	return old_generic;
	}

	// Returns a raw pointer to the object storage, to allow the scoper to be used
	// to receive and manage out-parameter values. Implies reset().
	element_type* receive() WARN_UNUSED_RESULT {
	reset();
	return &data_.generic;
	}

	const element_type& get() const { return data_.generic; }

	// Returns true if this object doesn't hold the special null value for the
	// associated data type.
	bool is_valid() const { return data_.generic != traits_type::InvalidValue(); }

	bool operator==(const element_type& value) const {
	return data_.generic == value;
	}
	bool operator!=(const element_type& value) const {
	return data_.generic != value;
	}

	Traits& get_traits() { return data_; }
	const Traits& get_traits() const { return data_; }

	private:
	void FreeIfNecessary() {
	if (data_.generic != traits_type::InvalidValue()) {
	data_.Free(data_.generic);
	data_.generic = traits_type::InvalidValue();
	}
	}

	// Forbid comparison. If U != T, it totally doesn't make sense, and if U ==
	// T, it still doesn't make sense because you should never have the same
	// object owned by two different ScopedGenerics.
	template <typename T2, typename Traits2>
	bool operator==(const ScopedGeneric<T2, Traits2>& p2) const;
	template <typename T2, typename Traits2>
	bool operator!=(const ScopedGeneric<T2, Traits2>& p2) const;

	Data data_;

	DISALLOW_COPY_AND_ASSIGN(ScopedGeneric);
	};

	template <class T, class Traits>
	void swap(const ScopedGeneric<T, Traits>& a,
	const ScopedGeneric<T, Traits>& b) {
	a.swap(b);
	}

	template <class T, class Traits>
	bool operator==(const T& value, const ScopedGeneric<T, Traits>& scoped) {
	return value == scoped.get();
	}

	template <class T, class Traits>
	bool operator!=(const T& value, const ScopedGeneric<T, Traits>& scoped) {
	return value != scoped.get();
	}

	} // namespace base

	#endif // BASE_SCOPED_GENERIC_H_