boost_1_45_0/libs/algorithm/minmax/test/minmax_element_test.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 //  (C) Copyright Herve Bronnimann 2004.
 //  Use, modification and distribution are 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)

 #include <utility>
 #include <functional>
 #include <algorithm>
 #include <numeric>
 #include <iterator>
 #include <vector>
 #include <list>
 #include <set>
 #include <cstdlib>

 #include <boost/config.hpp> /* prevents some nasty warns in MSVC */
 #include <boost/algorithm/minmax_element.hpp>
 #include <boost/test/included/test_exec_monitor.hpp>
 #include <boost/iterator/reverse_iterator.hpp>

 class custom {
   int m_x;
   friend bool operator<(custom const& x, custom const& y);
 public:
   explicit custom(int x = 0) : m_x(x) {}
   custom(custom const& y) : m_x(y.m_x) {}
   custom operator+(custom const& y) const { return custom(m_x+y.m_x); }
   custom& operator+=(custom const& y) { m_x += y.m_x; return *this; }
 };

 bool operator< (custom const& x, custom const& y)
 {
   return x.m_x < y.m_x;
 }

 BOOST_BROKEN_COMPILER_TYPE_TRAITS_SPECIALIZATION(custom)

 namespace std {

 template <>
 struct iterator_traits<int*> {
   typedef random_access_iterator_tag  iterator_category;
   typedef int                          value_type;
   typedef ptrdiff_t                    difference_type;
   typedef value_type*                  pointer;
   typedef value_type&                  reference;
 };

 template <>
 struct iterator_traits<custom*> {
   typedef random_access_iterator_tag  iterator_category;
   typedef custom                       value_type;
   typedef ptrdiff_t                    difference_type;
   typedef value_type*                  pointer;
   typedef value_type&                  reference;
 };

 }

 template <class T1, class T2, class T3, class T4>
 void tie(std::pair<T1, T2> p, T3& first, T4& second)
 {
   first = T3(p.first); second = T4(p.second);
 }

 template <class Value>
 struct less_count : std::less<Value> {
     typedef std::less<Value> Base;
   less_count(less_count<Value> const& lc) : m_counter(lc.m_counter) {}
   less_count(int& counter) : m_counter(counter) {}
   bool operator()(Value const& a, Value const& b) const {
     ++m_counter;
     return Base::operator()(a,b);
   }
   void reset() {
     m_counter = 0;
   }
 private:
   int& m_counter;
 };

 inline int opt_min_count(int n) {
   return (n==0) ? 0 : n-1;
 }
 inline int opt_minmax_count(int n) {
   if (n < 2) return 0;
   if (n == 2) return 2;
   return (n%2 == 0) ? 3*(n/2)-1 : 3*(n/2)+1;
 }
 inline int opt_boost_minmax_count(int n) {
   if (n < 2) return 0;
   if (n == 2) return 1;
   return (n%2 == 0) ? 3*(n/2)-2 : 3*(n/2);
 }

 #define CHECK_EQUAL_ITERATORS( left, right, first ) \
 BOOST_CHECK_EQUAL( std::distance( first, left ), std::distance( first, right ) )

 template <class CIterator>
 void test_minmax(CIterator first, CIterator last, int n)
 {
   using namespace boost;

   typedef typename std::iterator_traits<CIterator>::value_type Value;
   typedef boost::reverse_iterator<CIterator> RCIterator;
   // assume that CIterator is BidirectionalIter
   CIterator min, max;
   RCIterator rfirst(last), rlast(first), rmin, rmax;
   int counter = 0;
   less_count<Value> lc(counter);

   // standard extensions
   // first version, operator<
   tie( boost::minmax_element(first, last), min, max );

   CHECK_EQUAL_ITERATORS( min, std::min_element(first, last), first );
   CHECK_EQUAL_ITERATORS( max, std::max_element(first, last), first );

   // second version, comp function object (keeps a counter!)
   lc.reset();
   tie( boost::minmax_element(first, last, lc), min, max );
   BOOST_CHECK( counter <= opt_minmax_count(n) );
   CHECK_EQUAL_ITERATORS( min, std::min_element(first, last, lc), first );
   CHECK_EQUAL_ITERATORS( max, std::max_element(first, last, lc), first );

   // boost extensions
   // first version, operator<
   CHECK_EQUAL_ITERATORS( boost::first_min_element(first, last), std::min_element(first, last), first );
   rmin = RCIterator(boost::last_min_element(first, last));
   rmin = (rmin == rfirst) ? rlast : --rmin;
   CHECK_EQUAL_ITERATORS( rmin, std::min_element(rfirst, rlast), rfirst );
   CHECK_EQUAL_ITERATORS( boost::first_max_element(first, last), std::max_element(first, last), first );
   rmax = RCIterator(boost::last_max_element(first, last));
   rmax = (rmax == rfirst) ? rlast : --rmax;
   CHECK_EQUAL_ITERATORS( rmax, std::max_element(rfirst, rlast), rfirst );
   tie( boost::first_min_last_max_element(first, last), min, max );
   CHECK_EQUAL_ITERATORS( min, boost::first_min_element(first, last), first );
   CHECK_EQUAL_ITERATORS( max, boost::last_max_element(first, last), first );
   tie( boost::last_min_first_max_element(first, last), min, max );
   CHECK_EQUAL_ITERATORS( min, boost::last_min_element(first, last), first );
   CHECK_EQUAL_ITERATORS( max, boost::first_max_element(first, last), first );
   tie( boost::last_min_last_max_element(first, last), min, max );
   CHECK_EQUAL_ITERATORS( min, boost::last_min_element(first, last), first );
   CHECK_EQUAL_ITERATORS( max, boost::last_max_element(first, last), first );

   // second version, comp function object (keeps a counter!)
   lc.reset();
   min = boost::first_min_element(first, last, lc);
   BOOST_CHECK( counter <= opt_min_count(n) );
   CHECK_EQUAL_ITERATORS( min, std::min_element(first, last, lc), first );
   lc.reset();
   rmin = RCIterator(boost::last_min_element(first, last, lc));
   rmin = (rmin == rfirst) ? rlast : --rmin;
   BOOST_CHECK( counter <= opt_min_count(n) );
   CHECK_EQUAL_ITERATORS( rmin, std::min_element(rfirst, rlast, lc), rfirst );
   lc.reset();
   max =  boost::first_max_element(first, last, lc);
   BOOST_CHECK( counter <= opt_min_count(n) );
   CHECK_EQUAL_ITERATORS( max, std::max_element(first, last, lc), first );
   lc.reset();
   rmax = RCIterator(boost::last_max_element(first, last, lc));
   rmax = (rmax == rfirst) ? rlast : --rmax;
   BOOST_CHECK( counter <= opt_min_count(n) );
   CHECK_EQUAL_ITERATORS( rmax, std::max_element(rfirst, rlast, lc), rfirst );
   lc.reset();
   tie( boost::first_min_last_max_element(first, last, lc), min, max );
   BOOST_CHECK( counter <= opt_boost_minmax_count(n) );
   CHECK_EQUAL_ITERATORS( min, boost::first_min_element(first, last, lc), first );
   CHECK_EQUAL_ITERATORS( max, boost::last_max_element(first, last, lc), first );
   lc.reset();
   tie( boost::last_min_first_max_element(first, last, lc), min, max );
   BOOST_CHECK( counter <= opt_boost_minmax_count(n) );
   BOOST_CHECK( min == boost::last_min_element(first, last, lc) );
   CHECK_EQUAL_ITERATORS( max, boost::first_max_element(first, last, lc), first );
   lc.reset();
   tie( boost::last_min_last_max_element(first, last, lc), min, max );
   BOOST_CHECK( counter <= opt_minmax_count(n) );
   CHECK_EQUAL_ITERATORS( min, boost::last_min_element(first, last, lc), first );
   CHECK_EQUAL_ITERATORS( max, boost::last_max_element(first, last, lc), first );
 }

 template <class Container, class Iterator, class Value>
 void test_container(Iterator first, Iterator last, int n,
                     Container* dummy = 0
                     BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(Value) )
 {
   Container c(first, last);
   test_minmax(c.begin(), c.end(), n);
 }

 template <class Iterator>
 void test_range(Iterator first, Iterator last, int n)
 {
   typedef typename std::iterator_traits<Iterator>::value_type Value;
   // Test various containers with these values
   test_container< std::vector<Value>, Iterator, Value >(first, last, n);
   test_container< std::list<Value>,   Iterator, Value >(first, last, n);
   test_container< std::set<Value>,    Iterator, Value >(first, last, n);
 }

 template <class Value>
 void test(int n BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(Value))
 {
   // Populate test vector with identical values
   std::vector<Value> test_vector(n, Value(1));
   typename std::vector<Value>::iterator first( test_vector.begin() );
   typename std::vector<Value>::iterator last( test_vector.end() );
   test_range(first, last, n);

   // Populate test vector with two values
   typename std::vector<Value>::iterator middle( first + n/2 );
   std::fill(middle, last, Value(2));
   test_range(first, last, n);

   // Populate test vector with increasing values
   std::accumulate(first, last, Value(0));
   test_range(first, last, n);

   // Populate test vector with decreasing values
   std::reverse(first, last);
   test_range(first, last, n);

   // Populate test vector with random values
   std::random_shuffle(first, last);
   test_range(first, last, n);
 }

 int test_main( int argc, char* argv[] )
 {
 #ifndef BOOST_NO_STDC_NAMESPACE
   using std::atoi;
 #endif

   int n = 100;
   if (argc > 1) n = atoi(argv[1]);

   test<int>(n);
   test<custom>(n);

   return 0;
 }
	// (C) Copyright Herve Bronnimann 2004.
	// Use, modification and distribution are 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)

	#include <utility>
	#include <functional>
	#include <algorithm>
	#include <numeric>
	#include <iterator>
	#include <vector>
	#include <list>
	#include <set>
	#include <cstdlib>

	#include <boost/config.hpp> /* prevents some nasty warns in MSVC */
	#include <boost/algorithm/minmax_element.hpp>
	#include <boost/test/included/test_exec_monitor.hpp>
	#include <boost/iterator/reverse_iterator.hpp>

	class custom {
	int m_x;
	friend bool operator<(custom const& x, custom const& y);
	public:
	explicit custom(int x = 0) : m_x(x) {}
	custom(custom const& y) : m_x(y.m_x) {}
	custom operator+(custom const& y) const { return custom(m_x+y.m_x); }
	custom& operator+=(custom const& y) { m_x += y.m_x; return *this; }
	};

	bool operator< (custom const& x, custom const& y)
	{
	return x.m_x < y.m_x;
	}

	BOOST_BROKEN_COMPILER_TYPE_TRAITS_SPECIALIZATION(custom)

	namespace std {

	template <>
	struct iterator_traits<int*> {
	typedef random_access_iterator_tag iterator_category;
	typedef int value_type;
	typedef ptrdiff_t difference_type;
	typedef value_type* pointer;
	typedef value_type& reference;
	};

	template <>
	struct iterator_traits<custom*> {
	typedef random_access_iterator_tag iterator_category;
	typedef custom value_type;
	typedef ptrdiff_t difference_type;
	typedef value_type* pointer;
	typedef value_type& reference;
	};

	}

	template <class T1, class T2, class T3, class T4>
	void tie(std::pair<T1, T2> p, T3& first, T4& second)
	{
	first = T3(p.first); second = T4(p.second);
	}

	template <class Value>
	struct less_count : std::less<Value> {
	typedef std::less<Value> Base;
	less_count(less_count<Value> const& lc) : m_counter(lc.m_counter) {}
	less_count(int& counter) : m_counter(counter) {}
	bool operator()(Value const& a, Value const& b) const {
	++m_counter;
	return Base::operator()(a,b);
	}
	void reset() {
	m_counter = 0;
	}
	private:
	int& m_counter;
	};

	inline int opt_min_count(int n) {
	return (n==0) ? 0 : n-1;
	}
	inline int opt_minmax_count(int n) {
	if (n < 2) return 0;
	if (n == 2) return 2;
	return (n%2 == 0) ? 3(n/2)-1 : 3(n/2)+1;
	}
	inline int opt_boost_minmax_count(int n) {
	if (n < 2) return 0;
	if (n == 2) return 1;
	return (n%2 == 0) ? 3(n/2)-2 : 3(n/2);
	}

	#define CHECK_EQUAL_ITERATORS( left, right, first ) \
	BOOST_CHECK_EQUAL( std::distance( first, left ), std::distance( first, right ) )

	template <class CIterator>
	void test_minmax(CIterator first, CIterator last, int n)
	{
	using namespace boost;

	typedef typename std::iterator_traits<CIterator>::value_type Value;
	typedef boost::reverse_iterator<CIterator> RCIterator;
	// assume that CIterator is BidirectionalIter
	CIterator min, max;
	RCIterator rfirst(last), rlast(first), rmin, rmax;
	int counter = 0;
	less_count<Value> lc(counter);

	// standard extensions
	// first version, operator<
	tie( boost::minmax_element(first, last), min, max );

	CHECK_EQUAL_ITERATORS( min, std::min_element(first, last), first );
	CHECK_EQUAL_ITERATORS( max, std::max_element(first, last), first );

	// second version, comp function object (keeps a counter!)
	lc.reset();
	tie( boost::minmax_element(first, last, lc), min, max );
	BOOST_CHECK( counter <= opt_minmax_count(n) );
	CHECK_EQUAL_ITERATORS( min, std::min_element(first, last, lc), first );
	CHECK_EQUAL_ITERATORS( max, std::max_element(first, last, lc), first );

	// boost extensions
	// first version, operator<
	CHECK_EQUAL_ITERATORS( boost::first_min_element(first, last), std::min_element(first, last), first );
	rmin = RCIterator(boost::last_min_element(first, last));
	rmin = (rmin == rfirst) ? rlast : --rmin;
	CHECK_EQUAL_ITERATORS( rmin, std::min_element(rfirst, rlast), rfirst );
	CHECK_EQUAL_ITERATORS( boost::first_max_element(first, last), std::max_element(first, last), first );
	rmax = RCIterator(boost::last_max_element(first, last));
	rmax = (rmax == rfirst) ? rlast : --rmax;
	CHECK_EQUAL_ITERATORS( rmax, std::max_element(rfirst, rlast), rfirst );
	tie( boost::first_min_last_max_element(first, last), min, max );
	CHECK_EQUAL_ITERATORS( min, boost::first_min_element(first, last), first );
	CHECK_EQUAL_ITERATORS( max, boost::last_max_element(first, last), first );
	tie( boost::last_min_first_max_element(first, last), min, max );
	CHECK_EQUAL_ITERATORS( min, boost::last_min_element(first, last), first );
	CHECK_EQUAL_ITERATORS( max, boost::first_max_element(first, last), first );
	tie( boost::last_min_last_max_element(first, last), min, max );
	CHECK_EQUAL_ITERATORS( min, boost::last_min_element(first, last), first );
	CHECK_EQUAL_ITERATORS( max, boost::last_max_element(first, last), first );

	// second version, comp function object (keeps a counter!)
	lc.reset();
	min = boost::first_min_element(first, last, lc);
	BOOST_CHECK( counter <= opt_min_count(n) );
	CHECK_EQUAL_ITERATORS( min, std::min_element(first, last, lc), first );
	lc.reset();
	rmin = RCIterator(boost::last_min_element(first, last, lc));
	rmin = (rmin == rfirst) ? rlast : --rmin;
	BOOST_CHECK( counter <= opt_min_count(n) );
	CHECK_EQUAL_ITERATORS( rmin, std::min_element(rfirst, rlast, lc), rfirst );
	lc.reset();
	max = boost::first_max_element(first, last, lc);
	BOOST_CHECK( counter <= opt_min_count(n) );
	CHECK_EQUAL_ITERATORS( max, std::max_element(first, last, lc), first );
	lc.reset();
	rmax = RCIterator(boost::last_max_element(first, last, lc));
	rmax = (rmax == rfirst) ? rlast : --rmax;
	BOOST_CHECK( counter <= opt_min_count(n) );
	CHECK_EQUAL_ITERATORS( rmax, std::max_element(rfirst, rlast, lc), rfirst );
	lc.reset();
	tie( boost::first_min_last_max_element(first, last, lc), min, max );
	BOOST_CHECK( counter <= opt_boost_minmax_count(n) );
	CHECK_EQUAL_ITERATORS( min, boost::first_min_element(first, last, lc), first );
	CHECK_EQUAL_ITERATORS( max, boost::last_max_element(first, last, lc), first );
	lc.reset();
	tie( boost::last_min_first_max_element(first, last, lc), min, max );
	BOOST_CHECK( counter <= opt_boost_minmax_count(n) );
	BOOST_CHECK( min == boost::last_min_element(first, last, lc) );
	CHECK_EQUAL_ITERATORS( max, boost::first_max_element(first, last, lc), first );
	lc.reset();
	tie( boost::last_min_last_max_element(first, last, lc), min, max );
	BOOST_CHECK( counter <= opt_minmax_count(n) );
	CHECK_EQUAL_ITERATORS( min, boost::last_min_element(first, last, lc), first );
	CHECK_EQUAL_ITERATORS( max, boost::last_max_element(first, last, lc), first );
	}

	template <class Container, class Iterator, class Value>
	void test_container(Iterator first, Iterator last, int n,
	Container* dummy = 0
	BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(Value) )
	{
	Container c(first, last);
	test_minmax(c.begin(), c.end(), n);
	}

	template <class Iterator>
	void test_range(Iterator first, Iterator last, int n)
	{
	typedef typename std::iterator_traits<Iterator>::value_type Value;
	// Test various containers with these values
	test_container< std::vector<Value>, Iterator, Value >(first, last, n);
	test_container< std::list<Value>, Iterator, Value >(first, last, n);
	test_container< std::set<Value>, Iterator, Value >(first, last, n);
	}

	template <class Value>
	void test(int n BOOST_APPEND_EXPLICIT_TEMPLATE_TYPE(Value))
	{
	// Populate test vector with identical values
	std::vector<Value> test_vector(n, Value(1));
	typename std::vector<Value>::iterator first( test_vector.begin() );
	typename std::vector<Value>::iterator last( test_vector.end() );
	test_range(first, last, n);

	// Populate test vector with two values
	typename std::vector<Value>::iterator middle( first + n/2 );
	std::fill(middle, last, Value(2));
	test_range(first, last, n);

	// Populate test vector with increasing values
	std::accumulate(first, last, Value(0));
	test_range(first, last, n);

	// Populate test vector with decreasing values
	std::reverse(first, last);
	test_range(first, last, n);

	// Populate test vector with random values
	std::random_shuffle(first, last);
	test_range(first, last, n);
	}

	int test_main( int argc, char* argv[] )
	{
	#ifndef BOOST_NO_STDC_NAMESPACE
	using std::atoi;
	#endif

	int n = 100;
	if (argc > 1) n = atoi(argv[1]);

	test<int>(n);
	test<custom>(n);

	return 0;
	}