boost_1_45_0/libs/multi_index/perf/test_perf.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 /* Boost.MultiIndex performance test.
  *
  * Copyright 2003-2008 Joaquin M Lopez Munoz.
  * Distributed under 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)
  *
  * See http://www.boost.org/libs/multi_index for library home page.
  */

 #include <boost/config.hpp> /* keep it first to prevent nasty warns in MSVC */

 #include <algorithm>
 #include <assert.h>
 #include <boost/multi_index_container.hpp>
 #include <boost/multi_index/identity.hpp>
 #include <boost/multi_index/ordered_index.hpp>
 #include <boost/multi_index/sequenced_index.hpp>
 #include <boost/next_prior.hpp>
 #include <climits>
 #include <ctime>
 #include <iomanip>
 #include <iostream>
 #include <list>
 #include <set>
 #include <string>
 #include <vector>

 using namespace std;
 using namespace boost::multi_index;

 /* Measurement harness by Andrew Koenig, extracted from companion code to
  *   Stroustrup, B.: "Wrapping C++ Member Function Calls", The C++ Report,
  *     June 2000, Vol 12/No 6.
  * Original code retrievable at: http://www.research.att.com/~bs/wrap_code.cpp
  */

 // How many clock units does it take to interrogate the clock?
 static double clock_overhead()
 {
     clock_t k = clock(), start, limit;

     // Wait for the clock to tick
     do start = clock();
     while (start == k);

     // interrogate the clock until it has advanced at least a second
     // (for reasonable accuracy)
     limit = start + CLOCKS_PER_SEC;

     unsigned long r = 0;
     while ((k = clock()) < limit)
         ++r;

     return double(k - start) / r;
 }

 // We'd like the odds to be factor:1 that the result is
 // within percent% of the median
 const int factor = 10;
 const int percent = 20;

 // Measure a function (object) factor*2 times,
 // appending the measurements to the second argument
 template<class F>
 void measure_aux(F f, vector<double>& mv)
 {
     static double ovhd = clock_overhead();

     // Ensure we don't reallocate in mid-measurement
     mv.reserve(mv.size() + factor*2);

     // Wait for the clock to tick
     clock_t k = clock();
     clock_t start;

     do start = clock();
     while (start == k);

     // Do 2*factor measurements
     for (int i = 2*factor; i; --i) {
         unsigned long count = 0, limit = 1, tcount = 0;

         // Original code used CLOCKS_PER_SEC/100
         const clock_t clocklimit = start + CLOCKS_PER_SEC/10;
         clock_t t;

         do {
             while (count < limit) {
                 f();
                 ++count;
             }
             limit *= 2;
             ++tcount;
         } while ((t = clock()) < clocklimit);

         // Wait for the clock to tick again;
         clock_t t2;
         do ++tcount;
         while ((t2 = clock()) == t);

         // Append the measurement to the vector
         mv.push_back(((t2 - start) - (tcount * ovhd)) / count);

         // Establish a new starting point
         start = t2;
     }
 }

 // Returns the number of clock units per iteration
 // With odds of factor:1, the measurement is within percent% of
 // the value returned, which is also the median of all measurements.
 template<class F>
 double measure(F f)
 {
     vector<double> mv;

     int n = 0;                        // iteration counter
     do {
         ++n;

         // Try 2*factor measurements
         measure_aux(f, mv);
         assert(mv.size() == 2*n*factor);

         // Compute the median.  We know the size is even, so we cheat.
         sort(mv.begin(), mv.end());
         double median = (mv[n*factor] + mv[n*factor-1])/2;

         // If the extrema are within threshold of the median, we're done
         if (mv[n] > (median * (100-percent))/100 &&
             mv[mv.size() - n - 1] < (median * (100+percent))/100)
             return median;

     } while (mv.size() < factor * 200);

     // Give up!
     clog << "Help!\n\n";
     exit(1);
 }

 /* dereferencing compare predicate */

 template <typename Iterator,typename Compare>
 struct it_compare
 {
   bool operator()(const Iterator& x,const Iterator& y)const{return comp(*x,*y);}

 private:
   Compare comp;
 };

 /* list_wrapper and multiset_wrapper adapt std::lists and std::multisets
  * to make them conform to a set-like insert interface which test
  * routines do assume.
  */

 template <typename List>
 struct list_wrapper:List
 {
   typedef typename List::value_type value_type;
   typedef typename List::iterator   iterator;

   pair<iterator,bool> insert(const value_type& v)
   {
     List::push_back(v);
     return pair<iterator,bool>(boost::prior(List::end()),true);
   }
 };

 template <typename Multiset>
 struct multiset_wrapper:Multiset
 {
   typedef typename Multiset::value_type value_type;
   typedef typename Multiset::iterator   iterator;

   pair<iterator,bool> insert(const value_type& v)
   {
     return pair<iterator,bool>(Multiset::insert(v),true);
   }
 };

 /* space comsumption of manual simulations is determined by checking
  * the node sizes of the containers involved. This cannot be done in a
  * portable manner, so node_size has to be written on a per stdlibrary
  * basis. Add your own versions if necessary.
  */

 #if defined(BOOST_DINKUMWARE_STDLIB)

 template<typename Container>
 size_t node_size(const Container&)
 {
   return sizeof(*Container().begin()._Mynode());
 }

 #elif defined(__GLIBCPP__) || defined(__GLIBCXX__)

 template<typename Container>
 size_t node_size(const Container&)
 {
   typedef typename Container::iterator::_Link_type node_ptr;
   node_ptr p=0;
   return sizeof(*p);
 }

 template<typename Value,typename Allocator>
 size_t node_size(const list<Value,Allocator>&)
 {
   return sizeof(typename list<Value,Allocator>::iterator::_Node);
 }

 template<typename List>
 size_t node_size(const list_wrapper<List>&)
 {
   return sizeof(typename List::iterator::_Node);
 }

 #else

 /* default version returns 0 by convention */

 template<typename Container>
 size_t node_size(const Container&)
 {
   return 0;
 }

 #endif

 /* mono_container runs the tested routine on multi_index and manual
  * simulations comprised of one standard container.
  * bi_container and tri_container run the equivalent routine for manual
  * compositions of two and three standard containers, respectively.
  */

 template <typename Container>
 struct mono_container
 {
   mono_container(int n_):n(n_){}

   void operator()()
   {
     typedef typename Container::iterator iterator;

     Container c;

     for(int i=0;i<n;++i)c.insert(i);
     for(iterator it=c.begin();it!=c.end();)c.erase(it++);
   }

   static size_t multi_index_node_size()
   {
     return sizeof(*Container().begin().get_node());
   }

   static size_t node_size()
   {
     return ::node_size(Container());
   }

 private:
   int n;
 };

 template <typename Container1,typename Container2>
 struct bi_container
 {
   bi_container(int n_):n(n_){}

   void operator()()
   {
     typedef typename Container1::iterator iterator1;
     typedef typename Container2::iterator iterator2;

     Container1 c1;
     Container2 c2;

     for(int i=0;i<n;++i){
       iterator1 it1=c1.insert(i).first;
       c2.insert(it1);
     }
     for(iterator2 it2=c2.begin();it2!=c2.end();)
     {
       c1.erase(*it2);
       c2.erase(it2++);
     }
   }

   static size_t node_size()
   {
     return ::node_size(Container1())+::node_size(Container2());
   }

 private:
   int n;
 };

 template <typename Container1,typename Container2,typename Container3>
 struct tri_container
 {
   tri_container(int n_):n(n_){}

   void operator()()
   {
     typedef typename Container1::iterator iterator1;
     typedef typename Container2::iterator iterator2;
     typedef typename Container3::iterator iterator3;

     Container1 c1;
     Container2 c2;
     Container3 c3;

     for(int i=0;i<n;++i){
       iterator1 it1=c1.insert(i).first;
       iterator2 it2=c2.insert(it1).first;
       c3.insert(it2);
     }
     for(iterator3 it3=c3.begin();it3!=c3.end();)
     {
       c1.erase(**it3);
       c2.erase(*it3);
       c3.erase(it3++);
     }
   }

   static size_t node_size()
   {
     return ::node_size(Container1())+
            ::node_size(Container2())+::node_size(Container3());
   }

 private:
   int n;
 };

 /* measure and compare two routines for several numbers of elements
  * and also estimates relative memory consumption.
  */

 template <typename IndexedTest,typename ManualTest>
 void run_tests(
   const char* title
   BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(IndexedTest)
   BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(ManualTest))
 {
   cout<<fixed<<setprecision(2);
   cout<<title<<endl;
   int n=1000;
   for(int i=0;i<3;++i){
     double indexed_t=measure(IndexedTest(n));
     double manual_t=measure(ManualTest(n));
     cout<<"  10^"<<i+3<<" elmts: "
         <<setw(6)<<100.0*indexed_t/manual_t<<"% "
         <<"("
           <<setw(6)<<1000.0*indexed_t/CLOCKS_PER_SEC<<" ms / "
           <<setw(6)<<1000.0*manual_t/CLOCKS_PER_SEC<<" ms)"
         <<endl;
     n*=10;
   }

   size_t indexed_t_node_size=IndexedTest::multi_index_node_size();
   size_t manual_t_node_size=ManualTest::node_size();

   if(manual_t_node_size){
     cout<<"  space gain: "
         <<setw(6)<<100.0*indexed_t_node_size/manual_t_node_size<<"%"<<endl;
   }
 }

 /* compare_structures accept a multi_index_container instantiation and
  * several standard containers, builds a manual simulation out of the
  * latter and run the tests.
  */

 template <typename IndexedType,typename ManualType>
 void compare_structures(
   const char* title
   BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(IndexedType)
   BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(ManualType))
 {
   run_tests<
     mono_container<IndexedType>,
     mono_container<ManualType>
   >(title);
 }

 template <typename IndexedType,typename ManualType1,typename ManualType2>
 void compare_structures2(
   const char* title
   BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(IndexedType)
   BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(ManualType1)
   BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(ManualType2))
 {
   run_tests<
     mono_container<IndexedType>,
     bi_container<ManualType1,ManualType2>
   >(title);
 }

 template <
   typename IndexedType,
   typename ManualType1,typename ManualType2,typename ManualType3
 >
 void compare_structures3(
   const char* title
   BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(IndexedType)
   BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(ManualType1)
   BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(ManualType2)
   BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(ManualType3))
 {
   run_tests<
     mono_container<IndexedType>,
     tri_container<ManualType1,ManualType2,ManualType3>
   >(title);
 }

 int main()
 {
   {
     /* 1 ordered index */

     typedef multi_index_container<int> indexed_t;
     typedef set<int>                   manual_t;
     indexed_t dummy; /* MSVC++ 6.0 chokes if indexed_t is not instantiated */

     compare_structures<indexed_t,manual_t>(
       "1 ordered index");
   }
   {
     /* 1 sequenced index */

     typedef list_wrapper<
       multi_index_container<
         int,
         indexed_by<sequenced<> >
       >
     >                                  indexed_t;
     typedef list_wrapper<list<int> >   manual_t;
     indexed_t dummy; /* MSVC++ 6.0 chokes if indexed_t is not instantiated */

     compare_structures<indexed_t,manual_t>(
       "1 sequenced index");
   }
   {
     /* 2 ordered indices */

     typedef multi_index_container<
       int,
       indexed_by<
         ordered_unique<identity<int> >,
         ordered_non_unique<identity<int> >
       >
     >                                  indexed_t;
     typedef set<int>                   manual_t1;
     typedef multiset<
       manual_t1::iterator,
       it_compare<
         manual_t1::iterator,
         manual_t1::key_compare
       >
     >                                  manual_t2;
     indexed_t dummy; /* MSVC++ 6.0 chokes if indexed_t is not instantiated */

     compare_structures2<indexed_t,manual_t1,manual_t2>(
       "2 ordered indices");
   }
   {
     /* 1 ordered index + 1 sequenced index */

     typedef multi_index_container<
       int,
       indexed_by<
         boost::multi_index::ordered_unique<identity<int> >,
         sequenced<>
       >
     >                                  indexed_t;
     typedef list_wrapper<
       list<int>
     >                                  manual_t1;
     typedef multiset<
       manual_t1::iterator,
       it_compare<
         manual_t1::iterator,
         std::less<int>
       >
     >                                  manual_t2;
     indexed_t dummy; /* MSVC++ 6.0 chokes if indexed_t is not instantiated */

     compare_structures2<indexed_t,manual_t1,manual_t2>(
       "1 ordered index + 1 sequenced index");
   }
   {
     /* 3 ordered indices */

     typedef multi_index_container<
       int,
       indexed_by<
         ordered_unique<identity<int> >,
         ordered_non_unique<identity<int> >,
         ordered_non_unique<identity<int> >
       >
     >                                  indexed_t;
     typedef set<int>                   manual_t1;
     typedef multiset_wrapper<
       multiset<
         manual_t1::iterator,
         it_compare<
           manual_t1::iterator,
           manual_t1::key_compare
         >
       >
     >                                  manual_t2;
     typedef multiset<
       manual_t2::iterator,
       it_compare<
         manual_t2::iterator,
         manual_t2::key_compare
       >
     >                                  manual_t3;
     indexed_t dummy; /* MSVC++ 6.0 chokes if indexed_t is not instantiated */

     compare_structures3<indexed_t,manual_t1,manual_t2,manual_t3>(
       "3 ordered indices");
   }
   {
     /* 2 ordered indices + 1 sequenced index */

     typedef multi_index_container<
       int,
       indexed_by<
         ordered_unique<identity<int> >,
         ordered_non_unique<identity<int> >,
         sequenced<>
       >
     >                                  indexed_t;
     typedef list_wrapper<
       list<int>
     >                                  manual_t1;
     typedef multiset_wrapper<
       multiset<
         manual_t1::iterator,
         it_compare<
           manual_t1::iterator,
           std::less<int>
         >
       >
     >                                  manual_t2;
     typedef multiset<
       manual_t2::iterator,
       it_compare<
         manual_t2::iterator,
         manual_t2::key_compare
       >
     >                                  manual_t3;
     indexed_t dummy; /* MSVC++ 6.0 chokes if indexed_t is not instantiated */

     compare_structures3<indexed_t,manual_t1,manual_t2,manual_t3>(
       "2 ordered indices + 1 sequenced index");
   }

   return 0;
 }
	/* Boost.MultiIndex performance test.
	*
	* Copyright 2003-2008 Joaquin M Lopez Munoz.
	* Distributed under 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)
	*
	* See http://www.boost.org/libs/multi_index for library home page.
	*/

	#include <boost/config.hpp> /* keep it first to prevent nasty warns in MSVC */

	#include <algorithm>
	#include <assert.h>
	#include <boost/multi_index_container.hpp>
	#include <boost/multi_index/identity.hpp>
	#include <boost/multi_index/ordered_index.hpp>
	#include <boost/multi_index/sequenced_index.hpp>
	#include <boost/next_prior.hpp>
	#include <climits>
	#include <ctime>
	#include <iomanip>
	#include <iostream>
	#include <list>
	#include <set>
	#include <string>
	#include <vector>

	using namespace std;
	using namespace boost::multi_index;

	/* Measurement harness by Andrew Koenig, extracted from companion code to
	* Stroustrup, B.: "Wrapping C++ Member Function Calls", The C++ Report,
	* June 2000, Vol 12/No 6.
	* Original code retrievable at: http://www.research.att.com/~bs/wrap_code.cpp
	*/

	// How many clock units does it take to interrogate the clock?
	static double clock_overhead()
	{
	clock_t k = clock(), start, limit;

	// Wait for the clock to tick
	do start = clock();
	while (start == k);

	// interrogate the clock until it has advanced at least a second
	// (for reasonable accuracy)
	limit = start + CLOCKS_PER_SEC;

	unsigned long r = 0;
	while ((k = clock()) < limit)
	++r;

	return double(k - start) / r;
	}

	// We'd like the odds to be factor:1 that the result is
	// within percent% of the median
	const int factor = 10;
	const int percent = 20;

	// Measure a function (object) factor*2 times,
	// appending the measurements to the second argument
	template<class F>
	void measure_aux(F f, vector<double>& mv)
	{
	static double ovhd = clock_overhead();

	// Ensure we don't reallocate in mid-measurement
	mv.reserve(mv.size() + factor*2);

	// Wait for the clock to tick
	clock_t k = clock();
	clock_t start;

	do start = clock();
	while (start == k);

	// Do 2*factor measurements
	for (int i = 2*factor; i; --i) {
	unsigned long count = 0, limit = 1, tcount = 0;

	// Original code used CLOCKS_PER_SEC/100
	const clock_t clocklimit = start + CLOCKS_PER_SEC/10;
	clock_t t;

	do {
	while (count < limit) {
	f();
	++count;
	}
	limit *= 2;
	++tcount;
	} while ((t = clock()) < clocklimit);

	// Wait for the clock to tick again;
	clock_t t2;
	do ++tcount;
	while ((t2 = clock()) == t);

	// Append the measurement to the vector
	mv.push_back(((t2 - start) - (tcount * ovhd)) / count);

	// Establish a new starting point
	start = t2;
	}
	}

	// Returns the number of clock units per iteration
	// With odds of factor:1, the measurement is within percent% of
	// the value returned, which is also the median of all measurements.
	template<class F>
	double measure(F f)
	{
	vector<double> mv;

	int n = 0; // iteration counter
	do {
	++n;

	// Try 2*factor measurements
	measure_aux(f, mv);
	assert(mv.size() == 2nfactor);

	// Compute the median. We know the size is even, so we cheat.
	sort(mv.begin(), mv.end());
	double median = (mv[nfactor] + mv[nfactor-1])/2;

	// If the extrema are within threshold of the median, we're done
	if (mv[n] > (median * (100-percent))/100 &&
	mv[mv.size() - n - 1] < (median * (100+percent))/100)
	return median;

	} while (mv.size() < factor * 200);

	// Give up!
	clog << "Help!\n\n";
	exit(1);
	}

	/* dereferencing compare predicate */

	template <typename Iterator,typename Compare>
	struct it_compare
	{
	bool operator()(const Iterator& x,const Iterator& y)const{return comp(x,y);}

	private:
	Compare comp;
	};

	/* list_wrapper and multiset_wrapper adapt std::lists and std::multisets
	* to make them conform to a set-like insert interface which test
	* routines do assume.
	*/

	template <typename List>
	struct list_wrapper:List
	{
	typedef typename List::value_type value_type;
	typedef typename List::iterator iterator;

	pair<iterator,bool> insert(const value_type& v)
	{
	List::push_back(v);
	return pair<iterator,bool>(boost::prior(List::end()),true);
	}
	};

	template <typename Multiset>
	struct multiset_wrapper:Multiset
	{
	typedef typename Multiset::value_type value_type;
	typedef typename Multiset::iterator iterator;

	pair<iterator,bool> insert(const value_type& v)
	{
	return pair<iterator,bool>(Multiset::insert(v),true);
	}
	};

	/* space comsumption of manual simulations is determined by checking
	* the node sizes of the containers involved. This cannot be done in a
	* portable manner, so node_size has to be written on a per stdlibrary
	* basis. Add your own versions if necessary.
	*/

	#if defined(BOOST_DINKUMWARE_STDLIB)

	template<typename Container>
	size_t node_size(const Container&)
	{
	return sizeof(*Container().begin()._Mynode());
	}

	#elif defined(__GLIBCPP__) \|\| defined(__GLIBCXX__)

	template<typename Container>
	size_t node_size(const Container&)
	{
	typedef typename Container::iterator::_Link_type node_ptr;
	node_ptr p=0;
	return sizeof(*p);
	}

	template<typename Value,typename Allocator>
	size_t node_size(const list<Value,Allocator>&)
	{
	return sizeof(typename list<Value,Allocator>::iterator::_Node);
	}

	template<typename List>
	size_t node_size(const list_wrapper<List>&)
	{
	return sizeof(typename List::iterator::_Node);
	}

	#else

	/* default version returns 0 by convention */

	template<typename Container>
	size_t node_size(const Container&)
	{
	return 0;
	}

	#endif

	/* mono_container runs the tested routine on multi_index and manual
	* simulations comprised of one standard container.
	* bi_container and tri_container run the equivalent routine for manual
	* compositions of two and three standard containers, respectively.
	*/

	template <typename Container>
	struct mono_container
	{
	mono_container(int n_):n(n_){}

	void operator()()
	{
	typedef typename Container::iterator iterator;

	Container c;

	for(int i=0;i<n;++i)c.insert(i);
	for(iterator it=c.begin();it!=c.end();)c.erase(it++);
	}

	static size_t multi_index_node_size()
	{
	return sizeof(*Container().begin().get_node());
	}

	static size_t node_size()
	{
	return ::node_size(Container());
	}

	private:
	int n;
	};

	template <typename Container1,typename Container2>
	struct bi_container
	{
	bi_container(int n_):n(n_){}

	void operator()()
	{
	typedef typename Container1::iterator iterator1;
	typedef typename Container2::iterator iterator2;

	Container1 c1;
	Container2 c2;

	for(int i=0;i<n;++i){
	iterator1 it1=c1.insert(i).first;
	c2.insert(it1);
	}
	for(iterator2 it2=c2.begin();it2!=c2.end();)
	{
	c1.erase(*it2);
	c2.erase(it2++);
	}
	}

	static size_t node_size()
	{
	return ::node_size(Container1())+::node_size(Container2());
	}

	private:
	int n;
	};

	template <typename Container1,typename Container2,typename Container3>
	struct tri_container
	{
	tri_container(int n_):n(n_){}

	void operator()()
	{
	typedef typename Container1::iterator iterator1;
	typedef typename Container2::iterator iterator2;
	typedef typename Container3::iterator iterator3;

	Container1 c1;
	Container2 c2;
	Container3 c3;

	for(int i=0;i<n;++i){
	iterator1 it1=c1.insert(i).first;
	iterator2 it2=c2.insert(it1).first;
	c3.insert(it2);
	}
	for(iterator3 it3=c3.begin();it3!=c3.end();)
	{
	c1.erase(**it3);
	c2.erase(*it3);
	c3.erase(it3++);
	}
	}

	static size_t node_size()
	{
	return ::node_size(Container1())+
	::node_size(Container2())+::node_size(Container3());
	}

	private:
	int n;
	};

	/* measure and compare two routines for several numbers of elements
	* and also estimates relative memory consumption.
	*/

	template <typename IndexedTest,typename ManualTest>
	void run_tests(
	const char* title
	BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(IndexedTest)
	BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(ManualTest))
	{
	cout<<fixed<<setprecision(2);
	cout<<title<<endl;
	int n=1000;
	for(int i=0;i<3;++i){
	double indexed_t=measure(IndexedTest(n));
	double manual_t=measure(ManualTest(n));
	cout<<" 10^"<<i+3<<" elmts: "
	<<setw(6)<<100.0*indexed_t/manual_t<<"% "
	<<"("
	<<setw(6)<<1000.0*indexed_t/CLOCKS_PER_SEC<<" ms / "
	<<setw(6)<<1000.0*manual_t/CLOCKS_PER_SEC<<" ms)"
	<<endl;
	n*=10;
	}

	size_t indexed_t_node_size=IndexedTest::multi_index_node_size();
	size_t manual_t_node_size=ManualTest::node_size();

	if(manual_t_node_size){
	cout<<" space gain: "
	<<setw(6)<<100.0*indexed_t_node_size/manual_t_node_size<<"%"<<endl;
	}
	}

	/* compare_structures accept a multi_index_container instantiation and
	* several standard containers, builds a manual simulation out of the
	* latter and run the tests.
	*/

	template <typename IndexedType,typename ManualType>
	void compare_structures(
	const char* title
	BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(IndexedType)
	BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(ManualType))
	{
	run_tests<
	mono_container<IndexedType>,
	mono_container<ManualType>
	>(title);
	}

	template <typename IndexedType,typename ManualType1,typename ManualType2>
	void compare_structures2(
	const char* title
	BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(IndexedType)
	BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(ManualType1)
	BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(ManualType2))
	{
	run_tests<
	mono_container<IndexedType>,
	bi_container<ManualType1,ManualType2>
	>(title);
	}

	template <
	typename IndexedType,
	typename ManualType1,typename ManualType2,typename ManualType3
	>
	void compare_structures3(
	const char* title
	BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(IndexedType)
	BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(ManualType1)
	BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(ManualType2)
	BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(ManualType3))
	{
	run_tests<
	mono_container<IndexedType>,
	tri_container<ManualType1,ManualType2,ManualType3>
	>(title);
	}

	int main()
	{
	{
	/* 1 ordered index */

	typedef multi_index_container<int> indexed_t;
	typedef set<int> manual_t;
	indexed_t dummy; /* MSVC++ 6.0 chokes if indexed_t is not instantiated */

	compare_structures<indexed_t,manual_t>(
	"1 ordered index");
	}
	{
	/* 1 sequenced index */

	typedef list_wrapper<
	multi_index_container<
	int,
	indexed_by<sequenced<> >
	>
	> indexed_t;
	typedef list_wrapper<list<int> > manual_t;
	indexed_t dummy; /* MSVC++ 6.0 chokes if indexed_t is not instantiated */

	compare_structures<indexed_t,manual_t>(
	"1 sequenced index");
	}
	{
	/* 2 ordered indices */

	typedef multi_index_container<
	int,
	indexed_by<
	ordered_unique<identity<int> >,
	ordered_non_unique<identity<int> >
	>
	> indexed_t;
	typedef set<int> manual_t1;
	typedef multiset<
	manual_t1::iterator,
	it_compare<
	manual_t1::iterator,
	manual_t1::key_compare
	>
	> manual_t2;
	indexed_t dummy; /* MSVC++ 6.0 chokes if indexed_t is not instantiated */

	compare_structures2<indexed_t,manual_t1,manual_t2>(
	"2 ordered indices");
	}
	{
	/* 1 ordered index + 1 sequenced index */

	typedef multi_index_container<
	int,
	indexed_by<
	boost::multi_index::ordered_unique<identity<int> >,
	sequenced<>
	>
	> indexed_t;
	typedef list_wrapper<
	list<int>
	> manual_t1;
	typedef multiset<
	manual_t1::iterator,
	it_compare<
	manual_t1::iterator,
	std::less<int>
	>
	> manual_t2;
	indexed_t dummy; /* MSVC++ 6.0 chokes if indexed_t is not instantiated */

	compare_structures2<indexed_t,manual_t1,manual_t2>(
	"1 ordered index + 1 sequenced index");
	}
	{
	/* 3 ordered indices */

	typedef multi_index_container<
	int,
	indexed_by<
	ordered_unique<identity<int> >,
	ordered_non_unique<identity<int> >,
	ordered_non_unique<identity<int> >
	>
	> indexed_t;
	typedef set<int> manual_t1;
	typedef multiset_wrapper<
	multiset<
	manual_t1::iterator,
	it_compare<
	manual_t1::iterator,
	manual_t1::key_compare
	>
	>
	> manual_t2;
	typedef multiset<
	manual_t2::iterator,
	it_compare<
	manual_t2::iterator,
	manual_t2::key_compare
	>
	> manual_t3;
	indexed_t dummy; /* MSVC++ 6.0 chokes if indexed_t is not instantiated */

	compare_structures3<indexed_t,manual_t1,manual_t2,manual_t3>(
	"3 ordered indices");
	}
	{
	/* 2 ordered indices + 1 sequenced index */

	typedef multi_index_container<
	int,
	indexed_by<
	ordered_unique<identity<int> >,
	ordered_non_unique<identity<int> >,
	sequenced<>
	>
	> indexed_t;
	typedef list_wrapper<
	list<int>
	> manual_t1;
	typedef multiset_wrapper<
	multiset<
	manual_t1::iterator,
	it_compare<
	manual_t1::iterator,
	std::less<int>
	>
	>
	> manual_t2;
	typedef multiset<
	manual_t2::iterator,
	it_compare<
	manual_t2::iterator,
	manual_t2::key_compare
	>
	> manual_t3;
	indexed_t dummy; /* MSVC++ 6.0 chokes if indexed_t is not instantiated */

	compare_structures3<indexed_t,manual_t1,manual_t2,manual_t3>(
	"2 ordered indices + 1 sequenced index");
	}

	return 0;
	}