ob_compressed_pair.hpp

来自「support vector clustering for vc++」· HPP 代码 · 共 511 行 · 第 1/2 页

HPP
511
字号
12

            compressed_pair_3() : T1(), T2() {}
            compressed_pair_3(first_param_type x, second_param_type y) : T1(x), T2(y) {}
   template <class A>
   explicit compressed_pair_3(const A& val)
   {
      init_one<best_conversion_traits<A, T1, T2>::value>::init(val, static_cast<T1*>(this), static_cast<T2*>(this));
   }
   compressed_pair_3(const ::boost::compressed_pair<T1,T2>& x)
      : T1(x.first()), T2(x.second()) {}

   first_reference       first()       { return *this; }
   first_const_reference first() const { return *this; }

   second_reference       second()       { return *this; }
   second_const_reference second() const { return *this; }

   void swap(compressed_pair_3& y)
   {
      // no need to swap empty base classes:
   }
};

// T1 == T2, and empty
template <class T1, class T2>
class compressed_pair_4 : T1
{
public:
   typedef T1                                                 first_type;
   typedef T2                                                 second_type;
   typedef typename call_traits<first_type>::param_type       first_param_type;
   typedef typename call_traits<second_type>::param_type      second_param_type;
   typedef typename call_traits<first_type>::reference        first_reference;
   typedef typename call_traits<second_type>::reference       second_reference;
   typedef typename call_traits<first_type>::const_reference  first_const_reference;
   typedef typename call_traits<second_type>::const_reference second_const_reference;

            compressed_pair_4() : T1() {}
            compressed_pair_4(first_param_type x, second_param_type y) : T1(x), m_second(y) {}
   // only one single argument constructor since T1 == T2
   explicit compressed_pair_4(first_param_type x) : T1(x), m_second(x) {}
   compressed_pair_4(const ::boost::compressed_pair<T1,T2>& x)
      : T1(x.first()), m_second(x.second()) {}

   first_reference       first()       { return *this; }
   first_const_reference first() const { return *this; }

   second_reference       second()       { return m_second; }
   second_const_reference second() const { return m_second; }

   void swap(compressed_pair_4& y)
   {
      // no need to swap empty base classes:
   }
private:
   T2 m_second;
};

// T1 == T2, not empty
template <class T1, class T2>
class compressed_pair_5
{
private:
   T1 _first;
   T2 _second;
public:
   typedef T1                                                 first_type;
   typedef T2                                                 second_type;
   typedef typename call_traits<first_type>::param_type       first_param_type;
   typedef typename call_traits<second_type>::param_type      second_param_type;
   typedef typename call_traits<first_type>::reference        first_reference;
   typedef typename call_traits<second_type>::reference       second_reference;
   typedef typename call_traits<first_type>::const_reference  first_const_reference;
   typedef typename call_traits<second_type>::const_reference second_const_reference;

            compressed_pair_5() : _first(), _second() {}
            compressed_pair_5(first_param_type x, second_param_type y) : _first(x), _second(y) {}
   // only one single argument constructor since T1 == T2
   explicit compressed_pair_5(first_param_type x) : _first(x), _second(x) {}
   compressed_pair_5(const ::boost::compressed_pair<T1,T2>& c) 
      : _first(c.first()), _second(c.second()) {}

   first_reference       first()       { return _first; }
   first_const_reference first() const { return _first; }

   second_reference       second()       { return _second; }
   second_const_reference second() const { return _second; }

   void swap(compressed_pair_5& y)
   {
      using std::swap;
      swap(_first, y._first);
      swap(_second, y._second);
   }
};

template <bool e1, bool e2, bool same>
struct compressed_pair_chooser
{
   template <class T1, class T2>
   struct rebind
   {
      typedef compressed_pair_0<T1, T2> type;
   };
};

template <>
struct compressed_pair_chooser<false, true, false>
{
   template <class T1, class T2>
   struct rebind
   {
      typedef compressed_pair_1<T1, T2> type;
   };
};

template <>
struct compressed_pair_chooser<true, false, false>
{
   template <class T1, class T2>
   struct rebind
   {
      typedef compressed_pair_2<T1, T2> type;
   };
};

template <>
struct compressed_pair_chooser<true, true, false>
{
   template <class T1, class T2>
   struct rebind
   {
      typedef compressed_pair_3<T1, T2> type;
   };
};

template <>
struct compressed_pair_chooser<true, true, true>
{
   template <class T1, class T2>
   struct rebind
   {
      typedef compressed_pair_4<T1, T2> type;
   };
};

template <>
struct compressed_pair_chooser<false, false, true>
{
   template <class T1, class T2>
   struct rebind
   {
      typedef compressed_pair_5<T1, T2> type;
   };
};

template <class T1, class T2>
struct compressed_pair_traits
{
private:
   typedef compressed_pair_chooser<is_empty<T1>::value, is_empty<T2>::value, is_same<T1,T2>::value> chooser;
   typedef typename chooser::template rebind<T1, T2> bound_type;
public:
   typedef typename bound_type::type type;
};

} // namespace detail

template <class T1, class T2>
class compressed_pair : public detail::compressed_pair_traits<T1, T2>::type
{
private:
   typedef typename detail::compressed_pair_traits<T1, T2>::type base_type;
public:
   typedef T1                                                 first_type;
   typedef T2                                                 second_type;
   typedef typename call_traits<first_type>::param_type       first_param_type;
   typedef typename call_traits<second_type>::param_type      second_param_type;
   typedef typename call_traits<first_type>::reference        first_reference;
   typedef typename call_traits<second_type>::reference       second_reference;
   typedef typename call_traits<first_type>::const_reference  first_const_reference;
   typedef typename call_traits<second_type>::const_reference second_const_reference;

            compressed_pair() : base_type() {}
            compressed_pair(first_param_type x, second_param_type y) : base_type(x, y) {}
   template <class A>
   explicit compressed_pair(const A& x) : base_type(x){}

   first_reference       first()       { return base_type::first(); }
   first_const_reference first() const { return base_type::first(); }

   second_reference       second()       { return base_type::second(); }
   second_const_reference second() const { return base_type::second(); }
};

template <class T1, class T2>
inline void swap(compressed_pair<T1, T2>& x, compressed_pair<T1, T2>& y)
{
   x.swap(y);
}

#else
// no partial specialisation, no member templates:

template <class T1, class T2>
class compressed_pair
{
private:
   T1 _first;
   T2 _second;
public:
   typedef T1                                                 first_type;
   typedef T2                                                 second_type;
   typedef typename call_traits<first_type>::param_type       first_param_type;
   typedef typename call_traits<second_type>::param_type      second_param_type;
   typedef typename call_traits<first_type>::reference        first_reference;
   typedef typename call_traits<second_type>::reference       second_reference;
   typedef typename call_traits<first_type>::const_reference  first_const_reference;
   typedef typename call_traits<second_type>::const_reference second_const_reference;

            compressed_pair() : _first(), _second() {}
            compressed_pair(first_param_type x, second_param_type y) : _first(x), _second(y) {}
   explicit compressed_pair(first_param_type x) : _first(x), _second() {}
   // can't define this in case T1 == T2:
   // explicit compressed_pair(second_param_type y) : _first(), _second(y) {}

   first_reference       first()       { return _first; }
   first_const_reference first() const { return _first; }

   second_reference       second()       { return _second; }
   second_const_reference second() const { return _second; }

   void swap(compressed_pair& y)
   {
      using std::swap;
      swap(_first, y._first);
      swap(_second, y._second);
   }
};

template <class T1, class T2>
inline void swap(compressed_pair<T1, T2>& x, compressed_pair<T1, T2>& y)
{
   x.swap(y);
}

#endif

} // boost

#endif // BOOST_OB_COMPRESSED_PAIR_HPP
12

ob_compressed_pair.hpp - 源码说明

本页面展示了「support vector clustering for vc++」中的 ob_compressed_pair.hpp 源码文件,采用 HPP 编程语言编写,共 511 行代码。您可以在线阅读完整代码内容,也可以返回资源详情页下载完整源码包进行本地学习和开发。

虫虫下载站收录了大量与clustering相关的技术资源,包括源代码、技术文档、电路图等,是电子工程师和嵌入式开发者的专业学习平台。

⌨️ 快捷键说明

复制代码Ctrl + C
搜索代码Ctrl + F
全屏模式F11
增大字号Ctrl + =
减小字号Ctrl + -
显示快捷键?