boost_1_45_0/libs/multi_array/test/dimtest.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 // Copyright 2002 The Trustees of Indiana University.

 // Use, modification and distribution is subject to the Boost Software
 // License, Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at
 // http://www.boost.org/LICENSE_1_0.txt)

 //  Boost.MultiArray Library
 //  Authors: Ronald Garcia
 //           Jeremy Siek
 //           Andrew Lumsdaine
 //  See http://www.boost.org/libs/multi_array for documentation.

 //
 // Trying to diagnose problems under visual

 #include "boost/config.hpp"
 #include "boost/array.hpp"
 #include "boost/limits.hpp"
 #include <algorithm>
 #include <utility>

 typedef int index;
 typedef std::size_t size_type;

   template <typename Index,typename SizeType>
   class index_range {
   public:

     index_range()
     {
       start_ = from_start();
       finish_ = to_end();
       stride_ = 1;
       degenerate_ = false;
     }

     explicit index_range(Index pos)
     {
       start_ = pos;
       finish_ = pos;
       stride_ = 1;
       degenerate_ = true;
     }

     explicit index_range(Index start, Index finish, Index stride=1)
       : start_(start), finish_(finish), stride_(stride),
         degenerate_(start_ == finish_)
     { }


     // These are for chaining assignments to an index_range
     index_range& start(Index s) {
       start_ = s;
       degenerate_ = (start_ == finish_);
       return *this;
     }

     index_range& finish(Index f) {
       finish_ = f;
       degenerate_ = (start_ == finish_);
       return *this;
     }

     index_range& stride(Index s) { stride_ = s; return *this; }

     Index start() const
     {
       return start_;
     }

     Index get_start(Index low_index_range = 0) const
     {
       if (start_ == from_start())
         return low_index_range;
       return start_;
     }

     Index finish() const
     {
       return finish_;
     }

     Index get_finish(Index high_index_range = 0) const
     {
       if (finish_ == to_end())
         return high_index_range;
       return finish_;
     }

     unsigned int size(Index recommended_length = 0) const
     {
       if ((start_ == from_start()) || (finish_ == to_end()))
         return recommended_length;
       else
         return (finish_ - start_) / stride_;
     }

     Index stride() const { return stride_; }

     bool is_ascending_contiguous() const
     {
       return (start_ < finish_) && is_unit_stride();
     }

     void set_index_range(Index start, Index finish, Index stride=1)
     {
       start_ = start;
       finish_ = finish;
       stride_ = stride;
     }

     static index_range all()
     { return index_range(from_start(), to_end(), 1); }

     bool is_unit_stride() const
     { return stride_ == 1; }

     bool is_degenerate() const { return degenerate_; }

     index_range operator-(Index shift) const
     {
       return index_range(start_ - shift, finish_ - shift, stride_);
     }

     index_range operator+(Index shift) const
     {
       return index_range(start_ + shift, finish_ + shift, stride_);
     }

     Index operator[](unsigned i) const
     {
       return start_ + i * stride_;
     }

     Index operator()(unsigned i) const
     {
       return start_ + i * stride_;
     }

     // add conversion to std::slice?

   private:
     static Index from_start()
       { return (std::numeric_limits<Index>::min)(); }

     static Index to_end()
       { return (std::numeric_limits<Index>::max)(); }
   public:
     Index start_, finish_, stride_;
     bool degenerate_;
   };

   // Express open and closed interval end-points using the comparison
   // operators.

   // left closed
   template <typename Index, typename SizeType>
   inline index_range<Index,SizeType>
   operator<=(Index s, const index_range<Index,SizeType>& r)
   {
     return index_range<Index,SizeType>(s, r.finish(), r.stride());
   }

   // left open
   template <typename Index, typename SizeType>
   inline index_range<Index,SizeType>
   operator<(Index s, const index_range<Index,SizeType>& r)
   {
     return index_range<Index,SizeType>(s + 1, r.finish(), r.stride());
   }

   // right open
   template <typename Index, typename SizeType>
   inline index_range<Index,SizeType>
   operator<(const index_range<Index,SizeType>& r, Index f)
   {
     return index_range<Index,SizeType>(r.start(), f, r.stride());
   }

   // right closed
   template <typename Index, typename SizeType>
   inline index_range<Index,SizeType>
   operator<=(const index_range<Index,SizeType>& r, Index f)
   {
     return index_range<Index,SizeType>(r.start(), f + 1, r.stride());
   }

 //
 // range_list.hpp - helper to build boost::arrays for *_set types
 //

 /////////////////////////////////////////////////////////////////////////
 // choose range list begins
 //

 struct choose_range_list_n {
   template <typename T, std::size_t NumRanges>
   struct bind {
     typedef boost::array<T,NumRanges> type;
   };
 };

 struct choose_range_list_zero {
   template <typename T, std::size_t NumRanges>
   struct bind {
     typedef boost::array<T,1> type;
   };
 };


 template <std::size_t NumRanges>
 struct range_list_gen_helper {
   typedef choose_range_list_n choice;
 };

 template <>
 struct range_list_gen_helper<0> {
   typedef choose_range_list_zero choice;
 };

 template <typename T, std::size_t NumRanges>
 struct range_list_generator {
 private:
   typedef typename range_list_gen_helper<NumRanges>::choice Choice;
 public:
   typedef typename Choice::template bind<T,NumRanges>::type type;
 };

 //
 // choose range list ends
 /////////////////////////////////////////////////////////////////////////

 //
 // Index_gen.hpp stuff
 //

 template <int NumRanges, int NumDims>
 struct index_gen {
 private:
   typedef index Index;
   typedef size_type SizeType;
   typedef index_range<Index,SizeType> range;
 public:
   typedef typename range_list_generator<range,NumRanges>::type range_list;
   range_list ranges_;

   index_gen() { }

   template <int ND>
   explicit index_gen(const index_gen<NumRanges-1,ND>& rhs,
             const index_range<Index,SizeType>& range)
   {
     std::copy(rhs.ranges_.begin(),rhs.ranges_.end(),ranges_.begin());
     *ranges_.rbegin() = range;
   }

   index_gen<NumRanges+1,NumDims+1>
   operator[](const index_range<Index,SizeType>& range) const
   {
     index_gen<NumRanges+1,NumDims+1> tmp;
     std::copy(ranges_.begin(),ranges_.end(),tmp.ranges_.begin());
     *tmp.ranges_.rbegin() = range;
     return tmp;
   }

   index_gen<NumRanges+1,NumDims>
   operator[](Index idx) const
   {
     index_gen<NumRanges+1,NumDims> tmp;
     std::copy(ranges_.begin(),ranges_.end(),tmp.ranges_.begin());
     *tmp.ranges_.rbegin() = index_range<Index,SizeType>(idx);
     return tmp;
   }
 };


 template <int NDims, int NRanges>
 void accept_gen(index_gen<NRanges,NDims>& indices) {
   // do nothing
 }

 template <typename X, typename Y, int A, int B>
 class foo { };

 class boo {

   template <int NDims, int NRanges>
   void operator[](index_gen<NRanges,NDims>& indices) {

   }
 };

 template <typename X, typename Y, int A1, int A2>
 void take_foo(foo<X,Y,A1,A2>& f) { }

 int main() {

   index_gen<0,0> indices;
   typedef index_range<index,size_type> range;

   take_foo(foo<int,std::size_t,1,2>());

   indices[range()][range()][range()];
   accept_gen(indices);
   accept_gen(index_gen<0,0>());
   accept_gen(indices[range()][range()][range()]);

   boo b;
   b[indices[range()][range()][range()]];

   return 0;
 }
	// Copyright 2002 The Trustees of Indiana University.

	// Use, modification and distribution is subject to the Boost Software
	// License, Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at
	// http://www.boost.org/LICENSE_1_0.txt)

	// Boost.MultiArray Library
	// Authors: Ronald Garcia
	// Jeremy Siek
	// Andrew Lumsdaine
	// See http://www.boost.org/libs/multi_array for documentation.

	//
	// Trying to diagnose problems under visual

	#include "boost/config.hpp"
	#include "boost/array.hpp"
	#include "boost/limits.hpp"
	#include <algorithm>
	#include <utility>

	typedef int index;
	typedef std::size_t size_type;

	template <typename Index,typename SizeType>
	class index_range {
	public:

	index_range()
	{
	start_ = from_start();
	finish_ = to_end();
	stride_ = 1;
	degenerate_ = false;
	}

	explicit index_range(Index pos)
	{
	start_ = pos;
	finish_ = pos;
	stride_ = 1;
	degenerate_ = true;
	}

	explicit index_range(Index start, Index finish, Index stride=1)
	: start_(start), finish_(finish), stride_(stride),
	degenerate_(start_ == finish_)
	{ }


	// These are for chaining assignments to an index_range
	index_range& start(Index s) {
	start_ = s;
	degenerate_ = (start_ == finish_);
	return *this;
	}

	index_range& finish(Index f) {
	finish_ = f;
	degenerate_ = (start_ == finish_);
	return *this;
	}

	index_range& stride(Index s) { stride_ = s; return *this; }

	Index start() const
	{
	return start_;
	}

	Index get_start(Index low_index_range = 0) const
	{
	if (start_ == from_start())
	return low_index_range;
	return start_;
	}

	Index finish() const
	{
	return finish_;
	}

	Index get_finish(Index high_index_range = 0) const
	{
	if (finish_ == to_end())
	return high_index_range;
	return finish_;
	}

	unsigned int size(Index recommended_length = 0) const
	{
	if ((start_ == from_start()) \|\| (finish_ == to_end()))
	return recommended_length;
	else
	return (finish_ - start_) / stride_;
	}

	Index stride() const { return stride_; }

	bool is_ascending_contiguous() const
	{
	return (start_ < finish_) && is_unit_stride();
	}

	void set_index_range(Index start, Index finish, Index stride=1)
	{
	start_ = start;
	finish_ = finish;
	stride_ = stride;
	}

	static index_range all()
	{ return index_range(from_start(), to_end(), 1); }

	bool is_unit_stride() const
	{ return stride_ == 1; }

	bool is_degenerate() const { return degenerate_; }

	index_range operator-(Index shift) const
	{
	return index_range(start_ - shift, finish_ - shift, stride_);
	}

	index_range operator+(Index shift) const
	{
	return index_range(start_ + shift, finish_ + shift, stride_);
	}

	Index operator[](unsigned i) const
	{
	return start_ + i * stride_;
	}

	Index operator()(unsigned i) const
	{
	return start_ + i * stride_;
	}

	// add conversion to std::slice?

	private:
	static Index from_start()
	{ return (std::numeric_limits<Index>::min)(); }

	static Index to_end()
	{ return (std::numeric_limits<Index>::max)(); }
	public:
	Index start_, finish_, stride_;
	bool degenerate_;
	};

	// Express open and closed interval end-points using the comparison
	// operators.

	// left closed
	template <typename Index, typename SizeType>
	inline index_range<Index,SizeType>
	operator<=(Index s, const index_range<Index,SizeType>& r)
	{
	return index_range<Index,SizeType>(s, r.finish(), r.stride());
	}

	// left open
	template <typename Index, typename SizeType>
	inline index_range<Index,SizeType>
	operator<(Index s, const index_range<Index,SizeType>& r)
	{
	return index_range<Index,SizeType>(s + 1, r.finish(), r.stride());
	}

	// right open
	template <typename Index, typename SizeType>
	inline index_range<Index,SizeType>
	operator<(const index_range<Index,SizeType>& r, Index f)
	{
	return index_range<Index,SizeType>(r.start(), f, r.stride());
	}

	// right closed
	template <typename Index, typename SizeType>
	inline index_range<Index,SizeType>
	operator<=(const index_range<Index,SizeType>& r, Index f)
	{
	return index_range<Index,SizeType>(r.start(), f + 1, r.stride());
	}

	//
	// range_list.hpp - helper to build boost::arrays for *_set types
	//

	/////////////////////////////////////////////////////////////////////////
	// choose range list begins
	//

	struct choose_range_list_n {
	template <typename T, std::size_t NumRanges>
	struct bind {
	typedef boost::array<T,NumRanges> type;
	};
	};

	struct choose_range_list_zero {
	template <typename T, std::size_t NumRanges>
	struct bind {
	typedef boost::array<T,1> type;
	};
	};


	template <std::size_t NumRanges>
	struct range_list_gen_helper {
	typedef choose_range_list_n choice;
	};

	template <>
	struct range_list_gen_helper<0> {
	typedef choose_range_list_zero choice;
	};

	template <typename T, std::size_t NumRanges>
	struct range_list_generator {
	private:
	typedef typename range_list_gen_helper<NumRanges>::choice Choice;
	public:
	typedef typename Choice::template bind<T,NumRanges>::type type;
	};

	//
	// choose range list ends
	/////////////////////////////////////////////////////////////////////////

	//
	// Index_gen.hpp stuff
	//

	template <int NumRanges, int NumDims>
	struct index_gen {
	private:
	typedef index Index;
	typedef size_type SizeType;
	typedef index_range<Index,SizeType> range;
	public:
	typedef typename range_list_generator<range,NumRanges>::type range_list;
	range_list ranges_;

	index_gen() { }

	template <int ND>
	explicit index_gen(const index_gen<NumRanges-1,ND>& rhs,
	const index_range<Index,SizeType>& range)
	{
	std::copy(rhs.ranges_.begin(),rhs.ranges_.end(),ranges_.begin());
	*ranges_.rbegin() = range;
	}

	index_gen<NumRanges+1,NumDims+1>
	operator[](const index_range<Index,SizeType>& range) const
	{
	index_gen<NumRanges+1,NumDims+1> tmp;
	std::copy(ranges_.begin(),ranges_.end(),tmp.ranges_.begin());
	*tmp.ranges_.rbegin() = range;
	return tmp;
	}

	index_gen<NumRanges+1,NumDims>
	operator[](Index idx) const
	{
	index_gen<NumRanges+1,NumDims> tmp;
	std::copy(ranges_.begin(),ranges_.end(),tmp.ranges_.begin());
	*tmp.ranges_.rbegin() = index_range<Index,SizeType>(idx);
	return tmp;
	}
	};


	template <int NDims, int NRanges>
	void accept_gen(index_gen<NRanges,NDims>& indices) {
	// do nothing
	}

	template <typename X, typename Y, int A, int B>
	class foo { };

	class boo {

	template <int NDims, int NRanges>
	void operator[](index_gen<NRanges,NDims>& indices) {

	}
	};

	template <typename X, typename Y, int A1, int A2>
	void take_foo(foo<X,Y,A1,A2>& f) { }

	int main() {

	index_gen<0,0> indices;
	typedef index_range<index,size_type> range;

	take_foo(foo<int,std::size_t,1,2>());

	indices[range()][range()][range()];
	accept_gen(indices);
	accept_gen(index_gen<0,0>());
	accept_gen(indices[range()][range()][range()]);

	boo b;
	b[indices[range()][range()][range()]];

	return 0;
	}