boost_1_45_0/libs/multi_array/test/generative_tests.hpp - nest-learning-thermostat/5.0/boost - Git at Google

 #ifndef GENERATIVE_TESTS_RG072001_HPP
 #define GENERATIVE_TESTS_RG072001_HPP

 // 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.

 //
 // generative-tests.hpp - Framework for running tests on all the types
 //   of multi_array
 //
 //  In order to create a set of tests, you must define the following two
 //  function signatures:
 //   template <typename Array>
 //   void access(Array& A, const mutable_array_tag&);
 //
 //   template <typename Array>
 //   void access(Array& A, const const_array_tag&);
 //
 //  The framework will always pass 2x3x4 arrays into these functions.
 //  The const_array_tag version of access must NOT attempt to modify
 //  the array.  Assume that the passed array has constness in this case.
 //
 //  The mutable_array_tag version of access should pass the array to the
 //  assign() function in order to set its values before running tests.
 //
 //  If you wish to write your own code to assign data to the array
 //  (ie. test the iterators by assigning data with them), you must
 //  #define MULTIARRAY_TEST_ASSIGN before including this file.
 //  assign() will call this function.
 //
 //  If you wish to know how many tests were run, you must increment
 //  the global variable 'tests_run' somewhere in your test code.
 //
 //  Since generative-tests uses the Boost.Test framework, you must
 //  define at least the following:
 //
 //  int test_main(int,char*[]) { return run_generative_tests(); }
 //
 #include "boost/multi_array.hpp"

 #include "boost/test/minimal.hpp"

 #include <boost/config.hpp> /* BOOST_NO_SFINAE */
 #include <algorithm>
 #include <iostream>
 #include <vector>

 namespace {
   unsigned int tests_run = 0;
 } // empty namespace

 struct mutable_array_tag { };
 struct const_array_tag { };

 template <typename Array>
 void assign_if_not_const(Array&, const const_array_tag&) {
   // do nothing
 }

 template <typename Array>
 void assign_if_not_const(Array& A, const mutable_array_tag&);

 #ifndef MULTIARRAY_TEST_ASSIGN
 template <typename Array>
 void assign_if_not_const(Array& A, const mutable_array_tag&) {

   typedef typename Array::index index;

   const index idx0 = A.index_bases()[0];
   const index idx1 = A.index_bases()[1];
   const index idx2 = A.index_bases()[2];


   int num = 0;
   for (index i = idx0; i != idx0 + 2; ++i)
     for (index j = idx1; j != idx1 + 3; ++j)
       for (index k = idx2; k != idx2 + 4; ++k)
         A[i][j][k] = num++;
 }
 #endif // MULTIARRAY_TEST_ASSIGN

 template <typename Array>
 void assign(Array& A) {
   assign_if_not_const(A,mutable_array_tag());
 }

 template <typename Array>
 void access(Array& A, const mutable_array_tag&);

 template <typename Array>
 void access(Array& A, const const_array_tag&);

 template <typename StorageOrder3,typename StorageOrder4,typename Modifier>
 int run_configuration(const StorageOrder3& so3,
                       const StorageOrder4& so4,
                       const Modifier& modifier) {
   // multi_array
   {
     typedef boost::multi_array<int,3> array;
     typename array::extent_gen extents;
     {
       array A(extents[2][3][4],so3);
       modifier.modify(A);
       access(A,mutable_array_tag());
     }
   }
   // multi_array_ref
   {
     typedef boost::multi_array_ref<int,3> array_ref;
     typename array_ref::extent_gen extents;
     {
       int local[24];
       array_ref A(local,extents[2][3][4],so3);
       modifier.modify(A);
       access(A,mutable_array_tag());
     }
   }
   // const_multi_array_ref
   {
     typedef boost::multi_array_ref<int,3> array_ref;
     typedef boost::const_multi_array_ref<int,3> const_array_ref;
     typename array_ref::extent_gen extents;
     {
       int local[24];
       array_ref A(local,extents[2][3][4],so3);
       modifier.modify(A);
       assign(A);

       const_array_ref B = A;
       access(B,const_array_tag());
     }
   }
   // sub_array
   {
     typedef boost::multi_array<int,4> array;
     typename array::extent_gen extents;
     {
       array A(extents[2][2][3][4],so4);
       modifier.modify(A);
       typename array::template subarray<3>::type B = A[1];
       access(B,mutable_array_tag());
     }
   }
   // const_sub_array
   {
     typedef boost::multi_array<int,4> array;
     typename array::extent_gen extents;
     {
       array A(extents[2][2][3][4],so4);
       modifier.modify(A);
       typename array::template subarray<3>::type B = A[1];
       assign(B);

       typename array::template const_subarray<3>::type C = B;
       access(C,const_array_tag());
     }
   }
   // array_view
   {
     typedef boost::multi_array<int,3> array;
     typedef typename array::index_range range;
     typename array::index_gen indices;
     typename array::extent_gen extents;
     {
       typedef typename array::index index;

       array A(extents[4][5][6],so3);
       modifier.modify(A);
       const index idx0 = A.index_bases()[0];
       const index idx1 = A.index_bases()[1];
       const index idx2 = A.index_bases()[2];

       typename array::template array_view<3>::type B =A[
         indices[range(idx0+1,idx0+3)]
                [range(idx1+1,idx1+4)]
                [range(idx2+1,idx2+5)]
       ];
       access(B,mutable_array_tag());
     }
   }
   // const_array_view
   {
     typedef boost::multi_array<int,3> array;
     typedef typename array::index_range range;
     typename array::index_gen indices;
     typename array::extent_gen extents;
     {
       typedef typename array::index index;

       array A(extents[4][5][6],so3);
       modifier.modify(A);
       const index idx0 = A.index_bases()[0];
       const index idx1 = A.index_bases()[1];
       const index idx2 = A.index_bases()[2];

       typename array::template array_view<3>::type B =A[
         indices[range(idx0+1,idx0+3)]
                [range(idx1+1,idx1+4)]
                [range(idx2+1,idx2+5)]
       ];
       assign(B);

       typename array::template const_array_view<3>::type C = B;
       access(C,const_array_tag());
     }
   }
   return boost::exit_success;
 }

 template <typename ArrayModifier>
 int run_storage_tests(const ArrayModifier& modifier) {
   run_configuration(boost::c_storage_order(),
                     boost::c_storage_order(),modifier);
   run_configuration(boost::fortran_storage_order(),
                     boost::fortran_storage_order(),modifier);

   std::size_t ordering[] = {2,0,1,3};
   bool ascending[] = {false,true,true,true};
   run_configuration(boost::general_storage_order<3>(ordering,ascending),
                     boost::general_storage_order<4>(ordering,ascending),
                     modifier);

   return boost::exit_success;
 }

 struct null_modifier {
   template <typename Array>
   void modify(Array&) const { }
 };

 struct set_index_base_modifier {
   template <typename Array>
   void modify(Array& A) const {
 #ifdef BOOST_NO_SFINAE
     typedef boost::multi_array_types::index index;
     A.reindex(index(1));
 #else
     A.reindex(1);
 #endif
   }
 };

 struct reindex_modifier {
   template <typename Array>
   void modify(Array& A) const {
     boost::array<int,4> bases = {{1,2,3,4}};
     A.reindex(bases);
  }
 };

 struct reshape_modifier {
   template <typename Array>
   void modify(Array& A) const {
     typedef typename Array::size_type size_type;
     std::vector<size_type> old_shape(A.num_dimensions());
     std::vector<size_type> new_shape(A.num_dimensions());

     std::copy(A.shape(),A.shape()+A.num_dimensions(),old_shape.begin());
     std::copy(old_shape.rbegin(),old_shape.rend(),new_shape.begin());

     A.reshape(new_shape);
     A.reshape(old_shape);
   }
 };

 int run_generative_tests() {

   run_storage_tests(null_modifier());
   run_storage_tests(set_index_base_modifier());
   run_storage_tests(reindex_modifier());
   run_storage_tests(reshape_modifier());
   std::cout << "Total Tests Run: " << tests_run << '\n';
   return boost::exit_success;
 }

 #endif // GENERATIVE_TESTS_RG072001_HPP
	#ifndef GENERATIVE_TESTS_RG072001_HPP
	#define GENERATIVE_TESTS_RG072001_HPP

	// 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.

	//
	// generative-tests.hpp - Framework for running tests on all the types
	// of multi_array
	//
	// In order to create a set of tests, you must define the following two
	// function signatures:
	// template <typename Array>
	// void access(Array& A, const mutable_array_tag&);
	//
	// template <typename Array>
	// void access(Array& A, const const_array_tag&);
	//
	// The framework will always pass 2x3x4 arrays into these functions.
	// The const_array_tag version of access must NOT attempt to modify
	// the array. Assume that the passed array has constness in this case.
	//
	// The mutable_array_tag version of access should pass the array to the
	// assign() function in order to set its values before running tests.
	//
	// If you wish to write your own code to assign data to the array
	// (ie. test the iterators by assigning data with them), you must
	// #define MULTIARRAY_TEST_ASSIGN before including this file.
	// assign() will call this function.
	//
	// If you wish to know how many tests were run, you must increment
	// the global variable 'tests_run' somewhere in your test code.
	//
	// Since generative-tests uses the Boost.Test framework, you must
	// define at least the following:
	//
	// int test_main(int,char*[]) { return run_generative_tests(); }
	//
	#include "boost/multi_array.hpp"

	#include "boost/test/minimal.hpp"

	#include <boost/config.hpp> /* BOOST_NO_SFINAE */
	#include <algorithm>
	#include <iostream>
	#include <vector>

	namespace {
	unsigned int tests_run = 0;
	} // empty namespace

	struct mutable_array_tag { };
	struct const_array_tag { };

	template <typename Array>
	void assign_if_not_const(Array&, const const_array_tag&) {
	// do nothing
	}

	template <typename Array>
	void assign_if_not_const(Array& A, const mutable_array_tag&);

	#ifndef MULTIARRAY_TEST_ASSIGN
	template <typename Array>
	void assign_if_not_const(Array& A, const mutable_array_tag&) {

	typedef typename Array::index index;

	const index idx0 = A.index_bases()[0];
	const index idx1 = A.index_bases()[1];
	const index idx2 = A.index_bases()[2];


	int num = 0;
	for (index i = idx0; i != idx0 + 2; ++i)
	for (index j = idx1; j != idx1 + 3; ++j)
	for (index k = idx2; k != idx2 + 4; ++k)
	A[i][j][k] = num++;
	}
	#endif // MULTIARRAY_TEST_ASSIGN

	template <typename Array>
	void assign(Array& A) {
	assign_if_not_const(A,mutable_array_tag());
	}

	template <typename Array>
	void access(Array& A, const mutable_array_tag&);

	template <typename Array>
	void access(Array& A, const const_array_tag&);

	template <typename StorageOrder3,typename StorageOrder4,typename Modifier>
	int run_configuration(const StorageOrder3& so3,
	const StorageOrder4& so4,
	const Modifier& modifier) {
	// multi_array
	{
	typedef boost::multi_array<int,3> array;
	typename array::extent_gen extents;
	{
	array A(extents[2][3][4],so3);
	modifier.modify(A);
	access(A,mutable_array_tag());
	}
	}
	// multi_array_ref
	{
	typedef boost::multi_array_ref<int,3> array_ref;
	typename array_ref::extent_gen extents;
	{
	int local[24];
	array_ref A(local,extents[2][3][4],so3);
	modifier.modify(A);
	access(A,mutable_array_tag());
	}
	}
	// const_multi_array_ref
	{
	typedef boost::multi_array_ref<int,3> array_ref;
	typedef boost::const_multi_array_ref<int,3> const_array_ref;
	typename array_ref::extent_gen extents;
	{
	int local[24];
	array_ref A(local,extents[2][3][4],so3);
	modifier.modify(A);
	assign(A);

	const_array_ref B = A;
	access(B,const_array_tag());
	}
	}
	// sub_array
	{
	typedef boost::multi_array<int,4> array;
	typename array::extent_gen extents;
	{
	array A(extents[2][2][3][4],so4);
	modifier.modify(A);
	typename array::template subarray<3>::type B = A[1];
	access(B,mutable_array_tag());
	}
	}
	// const_sub_array
	{
	typedef boost::multi_array<int,4> array;
	typename array::extent_gen extents;
	{
	array A(extents[2][2][3][4],so4);
	modifier.modify(A);
	typename array::template subarray<3>::type B = A[1];
	assign(B);

	typename array::template const_subarray<3>::type C = B;
	access(C,const_array_tag());
	}
	}
	// array_view
	{
	typedef boost::multi_array<int,3> array;
	typedef typename array::index_range range;
	typename array::index_gen indices;
	typename array::extent_gen extents;
	{
	typedef typename array::index index;

	array A(extents[4][5][6],so3);
	modifier.modify(A);
	const index idx0 = A.index_bases()[0];
	const index idx1 = A.index_bases()[1];
	const index idx2 = A.index_bases()[2];

	typename array::template array_view<3>::type B =A[
	indices[range(idx0+1,idx0+3)]
	[range(idx1+1,idx1+4)]
	[range(idx2+1,idx2+5)]
	];
	access(B,mutable_array_tag());
	}
	}
	// const_array_view
	{
	typedef boost::multi_array<int,3> array;
	typedef typename array::index_range range;
	typename array::index_gen indices;
	typename array::extent_gen extents;
	{
	typedef typename array::index index;

	array A(extents[4][5][6],so3);
	modifier.modify(A);
	const index idx0 = A.index_bases()[0];
	const index idx1 = A.index_bases()[1];
	const index idx2 = A.index_bases()[2];

	typename array::template array_view<3>::type B =A[
	indices[range(idx0+1,idx0+3)]
	[range(idx1+1,idx1+4)]
	[range(idx2+1,idx2+5)]
	];
	assign(B);

	typename array::template const_array_view<3>::type C = B;
	access(C,const_array_tag());
	}
	}
	return boost::exit_success;
	}

	template <typename ArrayModifier>
	int run_storage_tests(const ArrayModifier& modifier) {
	run_configuration(boost::c_storage_order(),
	boost::c_storage_order(),modifier);
	run_configuration(boost::fortran_storage_order(),
	boost::fortran_storage_order(),modifier);

	std::size_t ordering[] = {2,0,1,3};
	bool ascending[] = {false,true,true,true};
	run_configuration(boost::general_storage_order<3>(ordering,ascending),
	boost::general_storage_order<4>(ordering,ascending),
	modifier);

	return boost::exit_success;
	}

	struct null_modifier {
	template <typename Array>
	void modify(Array&) const { }
	};

	struct set_index_base_modifier {
	template <typename Array>
	void modify(Array& A) const {
	#ifdef BOOST_NO_SFINAE
	typedef boost::multi_array_types::index index;
	A.reindex(index(1));
	#else
	A.reindex(1);
	#endif
	}
	};

	struct reindex_modifier {
	template <typename Array>
	void modify(Array& A) const {
	boost::array<int,4> bases = {{1,2,3,4}};
	A.reindex(bases);
	}
	};

	struct reshape_modifier {
	template <typename Array>
	void modify(Array& A) const {
	typedef typename Array::size_type size_type;
	std::vector<size_type> old_shape(A.num_dimensions());
	std::vector<size_type> new_shape(A.num_dimensions());

	std::copy(A.shape(),A.shape()+A.num_dimensions(),old_shape.begin());
	std::copy(old_shape.rbegin(),old_shape.rend(),new_shape.begin());

	A.reshape(new_shape);
	A.reshape(old_shape);
	}
	};

	int run_generative_tests() {

	run_storage_tests(null_modifier());
	run_storage_tests(set_index_base_modifier());
	run_storage_tests(reindex_modifier());
	run_storage_tests(reshape_modifier());
	std::cout << "Total Tests Run: " << tests_run << '\n';
	return boost::exit_success;
	}

	#endif // GENERATIVE_TESTS_RG072001_HPP