boost_1_45_0/libs/unordered/test/unordered/unnecessary_copy_tests.cpp - nest-learning-thermostat/5.0/boost - Git at Google


 // Copyright 2006-2009 Daniel James.
 // 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)

 #include "../helpers/prefix.hpp"

 #include <boost/unordered_set.hpp>
 #include <boost/unordered_map.hpp>
 #include "../helpers/test.hpp"

 namespace unnecessary_copy_tests
 {
     struct count_copies
     {
         static int copies;
         static int moves;
         count_copies() : tag_(0) { ++copies; }
         explicit count_copies(int tag) : tag_(tag) { ++copies; }

         // This bizarre constructor is an attempt to confuse emplace.
         //
         // unordered_map<count_copies, count_copies> x:
         // x.emplace(count_copies(1), count_copies(2));
         // x.emplace(count_copies(1), count_copies(2), count_copies(3));
         //
         // The first emplace should use the single argument constructor twice.
         // The second emplace should use the single argument contructor for
         // the key, and this constructor for the value.
         count_copies(count_copies const&, count_copies const& x)
             : tag_(x.tag_) { ++copies; }

         count_copies(count_copies const& x) : tag_(x.tag_) { ++copies; }
 #if !defined(BOOST_NO_RVALUE_REFERENCES)
         count_copies(count_copies&& x) : tag_(x.tag_) {
             x.tag_ = -1; ++moves;
         }
 #endif
        int tag_;
     private:
        count_copies& operator=(count_copies const&);
     };

     bool operator==(count_copies const& x, count_copies const& y) {
         return x.tag_ == y.tag_;
     }

     template <class T>
     T source() {
         return T();
     }

     void reset() {
         count_copies::copies = 0;
         count_copies::moves = 0;
     }
 }

 #if defined(BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP)
 namespace boost
 #else
 namespace unnecessary_copy_tests
 #endif
 {
     std::size_t hash_value(unnecessary_copy_tests::count_copies const& x) {
         return x.tag_;
     }
 }

 #define COPY_COUNT(n)                                                       \
     if(count_copies::copies != n) {                                         \
         BOOST_ERROR("Wrong number of copies.");                             \
         std::cerr                                                           \
             << "Number of copies: " << count_copies::copies                 \
             << " expecting: " << n << std::endl;                            \
     }
 #define MOVE_COUNT(n)                                                       \
     if(count_copies::moves != n) {                                          \
         BOOST_ERROR("Wrong number of moves.");                              \
         std::cerr                                                           \
             << "Number of moves: " << count_copies::moves                   \
             << " expecting: " <<n << std::endl;                             \
     }
 #define COPY_COUNT_RANGE(a, b)                                              \
     if(count_copies::copies < a || count_copies::copies > b) {              \
         BOOST_ERROR("Wrong number of copies.");                             \
         std::cerr                                                           \
             << "Number of copies: " << count_copies::copies                 \
             << " expecting: [" << a << ", " << b << "]" << std::endl;       \
     }
 #define MOVE_COUNT_RANGE(a, b)                                              \
     if(count_copies::moves < a || count_copies::moves > b) {                \
         BOOST_ERROR("Wrong number of moves.");                              \
         std::cerr                                                           \
             << "Number of moves: " << count_copies::copies                  \
             << " expecting: [" << a << ", " << b << "]" << std::endl;       \
     }

 namespace unnecessary_copy_tests
 {
     int count_copies::copies;
     int count_copies::moves;

     template <class T>
     void unnecessary_copy_insert_test(T*)
     {
         T x;
         BOOST_DEDUCED_TYPENAME T::value_type a;
         reset();
         x.insert(a);
         COPY_COUNT(1);
     }

     boost::unordered_set<count_copies>* set;
     boost::unordered_multiset<count_copies>* multiset;
     boost::unordered_map<int, count_copies>* map;
     boost::unordered_multimap<int, count_copies>* multimap;

     UNORDERED_TEST(unnecessary_copy_insert_test,
             ((set)(multiset)(map)(multimap)))

     template <class T>
     void unnecessary_copy_emplace_test(T*)
     {
         reset();
         T x;
         BOOST_DEDUCED_TYPENAME T::value_type a;
         COPY_COUNT(1);
         x.emplace(a);
         COPY_COUNT(2);
     }

     template <class T>
     void unnecessary_copy_emplace_rvalue_test(T*)
     {
         reset();
         T x;
         x.emplace(source<BOOST_DEDUCED_TYPENAME T::value_type>());
 #if !defined(BOOST_NO_RVALUE_REFERENCES) && !defined(BOOST_NO_VARIADIC_TEMPLATES)
         COPY_COUNT(1);
 #else
         COPY_COUNT(2);
 #endif
     }

     UNORDERED_TEST(unnecessary_copy_emplace_test,
             ((set)(multiset)(map)(multimap)))
     UNORDERED_TEST(unnecessary_copy_emplace_rvalue_test,
             ((set)(multiset)(map)(multimap)))

 #if !defined(BOOST_NO_RVALUE_REFERENCES) && !defined(BOOST_NO_VARIADIC_TEMPLATES)
     template <class T>
     void unnecessary_copy_emplace_move_test(T*)
     {
         reset();
         T x;
         BOOST_DEDUCED_TYPENAME T::value_type a;
         COPY_COUNT(1); MOVE_COUNT(0);
         x.emplace(std::move(a));
         COPY_COUNT(1); MOVE_COUNT(1);
     }

     UNORDERED_TEST(unnecessary_copy_emplace_move_test,
             ((set)(multiset)(map)(multimap)))

 #endif

     UNORDERED_AUTO_TEST(unnecessary_copy_emplace_set_test)
     {
         reset();
         boost::unordered_set<count_copies> x;
         count_copies a;
         x.insert(a);
         COPY_COUNT(2); MOVE_COUNT(0);

         //
         // 0 arguments
         //

         // The container will have to create a copy in order to compare with
         // the existing element.
         reset();
         x.emplace();
         COPY_COUNT(1); MOVE_COUNT(0);

         //
         // 1 argument
         //

         // Emplace should be able to tell that there already is an element
         // without creating a new one.
         reset();
         x.emplace(a);
         COPY_COUNT(0); MOVE_COUNT(0);

         // A new object is created by source, but it shouldn't be moved or
         // copied.
         reset();
         x.emplace(source<count_copies>());
         COPY_COUNT(1); MOVE_COUNT(0);

 #if !defined(BOOST_NO_RVALUE_REFERENCES)
         // No move should take place.
         reset();
         x.emplace(std::move(a));
         COPY_COUNT(0); MOVE_COUNT(0);
 #endif

         // Just in case a did get moved...
         count_copies b;

         // The container will have to create a copy in order to compare with
         // the existing element.
         reset();
         x.emplace(b.tag_);
         COPY_COUNT(1); MOVE_COUNT(0);

         //
         // 2 arguments
         //

         // The container will have to create b copy in order to compare with
         // the existing element.
         //
         // Note to self: If copy_count == 0 it's an error not an optimization.
         // TODO: Devise a better test.

         reset();

         x.emplace(b, b);
         COPY_COUNT(1); MOVE_COUNT(0);
     }

     UNORDERED_AUTO_TEST(unnecessary_copy_emplace_map_test)
     {
         reset();
         boost::unordered_map<count_copies, count_copies> x;
         // TODO: Run tests for pairs without const etc.
         std::pair<count_copies const, count_copies> a;
         x.emplace(a);
         COPY_COUNT(4); MOVE_COUNT(0);

         //
         // 0 arguments
         //

         // COPY_COUNT(1) would be okay here.
         reset();
         x.emplace();
         COPY_COUNT(2); MOVE_COUNT(0);

         //
         // 1 argument
         //

         reset();
         x.emplace(a);
         COPY_COUNT(0); MOVE_COUNT(0);

         // A new object is created by source, but it shouldn't be moved or
         // copied.
         reset();
         x.emplace(source<std::pair<count_copies, count_copies> >());
         COPY_COUNT(2); MOVE_COUNT(0);

         // TODO: This doesn't work on older versions of gcc.
         //count_copies part;
         std::pair<count_copies const, count_copies> b;
         //reset();
         //std::pair<count_copies const&, count_copies const&> a_ref(part, part);
         //x.emplace(a_ref);
         //COPY_COUNT(0); MOVE_COUNT(0);

 #if !defined(BOOST_NO_RVALUE_REFERENCES)
         // No move should take place.
         // (since a is already in the container)
         reset();
         x.emplace(std::move(a));
         COPY_COUNT(0); MOVE_COUNT(0);
 #endif


         //
         // 2 arguments
         //

         reset();
         x.emplace(b.first, b.second);
         COPY_COUNT(0); MOVE_COUNT(0);

         reset();
         x.emplace(source<count_copies>(), source<count_copies>());
         COPY_COUNT(2); MOVE_COUNT(0);

         // source<count_copies> creates a single copy.
         reset();
         x.emplace(b.first, source<count_copies>());
         COPY_COUNT(1); MOVE_COUNT(0);

         reset();
         x.emplace(count_copies(b.first.tag_), count_copies(b.second.tag_));
         COPY_COUNT(2); MOVE_COUNT(0);
     }
 }

 RUN_TESTS()

	// Copyright 2006-2009 Daniel James.
	// 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)

	#include "../helpers/prefix.hpp"

	#include <boost/unordered_set.hpp>
	#include <boost/unordered_map.hpp>
	#include "../helpers/test.hpp"

	namespace unnecessary_copy_tests
	{
	struct count_copies
	{
	static int copies;
	static int moves;
	count_copies() : tag_(0) { ++copies; }
	explicit count_copies(int tag) : tag_(tag) { ++copies; }

	// This bizarre constructor is an attempt to confuse emplace.
	//
	// unordered_map<count_copies, count_copies> x:
	// x.emplace(count_copies(1), count_copies(2));
	// x.emplace(count_copies(1), count_copies(2), count_copies(3));
	//
	// The first emplace should use the single argument constructor twice.
	// The second emplace should use the single argument contructor for
	// the key, and this constructor for the value.
	count_copies(count_copies const&, count_copies const& x)
	: tag_(x.tag_) { ++copies; }

	count_copies(count_copies const& x) : tag_(x.tag_) { ++copies; }
	#if !defined(BOOST_NO_RVALUE_REFERENCES)
	count_copies(count_copies&& x) : tag_(x.tag_) {
	x.tag_ = -1; ++moves;
	}
	#endif
	int tag_;
	private:
	count_copies& operator=(count_copies const&);
	};

	bool operator==(count_copies const& x, count_copies const& y) {
	return x.tag_ == y.tag_;
	}

	template <class T>
	T source() {
	return T();
	}

	void reset() {
	count_copies::copies = 0;
	count_copies::moves = 0;
	}
	}

	#if defined(BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP)
	namespace boost
	#else
	namespace unnecessary_copy_tests
	#endif
	{
	std::size_t hash_value(unnecessary_copy_tests::count_copies const& x) {
	return x.tag_;
	}
	}

	#define COPY_COUNT(n) \
	if(count_copies::copies != n) { \
	BOOST_ERROR("Wrong number of copies."); \
	std::cerr \
	<< "Number of copies: " << count_copies::copies \
	<< " expecting: " << n << std::endl; \
	}
	#define MOVE_COUNT(n) \
	if(count_copies::moves != n) { \
	BOOST_ERROR("Wrong number of moves."); \
	std::cerr \
	<< "Number of moves: " << count_copies::moves \
	<< " expecting: " <<n << std::endl; \
	}
	#define COPY_COUNT_RANGE(a, b) \
	if(count_copies::copies < a \|\| count_copies::copies > b) { \
	BOOST_ERROR("Wrong number of copies."); \
	std::cerr \
	<< "Number of copies: " << count_copies::copies \
	<< " expecting: [" << a << ", " << b << "]" << std::endl; \
	}
	#define MOVE_COUNT_RANGE(a, b) \
	if(count_copies::moves < a \|\| count_copies::moves > b) { \
	BOOST_ERROR("Wrong number of moves."); \
	std::cerr \
	<< "Number of moves: " << count_copies::copies \
	<< " expecting: [" << a << ", " << b << "]" << std::endl; \
	}

	namespace unnecessary_copy_tests
	{
	int count_copies::copies;
	int count_copies::moves;

	template <class T>
	void unnecessary_copy_insert_test(T*)
	{
	T x;
	BOOST_DEDUCED_TYPENAME T::value_type a;
	reset();
	x.insert(a);
	COPY_COUNT(1);
	}

	boost::unordered_set<count_copies>* set;
	boost::unordered_multiset<count_copies>* multiset;
	boost::unordered_map<int, count_copies>* map;
	boost::unordered_multimap<int, count_copies>* multimap;

	UNORDERED_TEST(unnecessary_copy_insert_test,
	((set)(multiset)(map)(multimap)))

	template <class T>
	void unnecessary_copy_emplace_test(T*)
	{
	reset();
	T x;
	BOOST_DEDUCED_TYPENAME T::value_type a;
	COPY_COUNT(1);
	x.emplace(a);
	COPY_COUNT(2);
	}

	template <class T>
	void unnecessary_copy_emplace_rvalue_test(T*)
	{
	reset();
	T x;
	x.emplace(source<BOOST_DEDUCED_TYPENAME T::value_type>());
	#if !defined(BOOST_NO_RVALUE_REFERENCES) && !defined(BOOST_NO_VARIADIC_TEMPLATES)
	COPY_COUNT(1);
	#else
	COPY_COUNT(2);
	#endif
	}

	UNORDERED_TEST(unnecessary_copy_emplace_test,
	((set)(multiset)(map)(multimap)))
	UNORDERED_TEST(unnecessary_copy_emplace_rvalue_test,
	((set)(multiset)(map)(multimap)))

	#if !defined(BOOST_NO_RVALUE_REFERENCES) && !defined(BOOST_NO_VARIADIC_TEMPLATES)
	template <class T>
	void unnecessary_copy_emplace_move_test(T*)
	{
	reset();
	T x;
	BOOST_DEDUCED_TYPENAME T::value_type a;
	COPY_COUNT(1); MOVE_COUNT(0);
	x.emplace(std::move(a));
	COPY_COUNT(1); MOVE_COUNT(1);
	}

	UNORDERED_TEST(unnecessary_copy_emplace_move_test,
	((set)(multiset)(map)(multimap)))

	#endif

	UNORDERED_AUTO_TEST(unnecessary_copy_emplace_set_test)
	{
	reset();
	boost::unordered_set<count_copies> x;
	count_copies a;
	x.insert(a);
	COPY_COUNT(2); MOVE_COUNT(0);

	//
	// 0 arguments
	//

	// The container will have to create a copy in order to compare with
	// the existing element.
	reset();
	x.emplace();
	COPY_COUNT(1); MOVE_COUNT(0);

	//
	// 1 argument
	//

	// Emplace should be able to tell that there already is an element
	// without creating a new one.
	reset();
	x.emplace(a);
	COPY_COUNT(0); MOVE_COUNT(0);

	// A new object is created by source, but it shouldn't be moved or
	// copied.
	reset();
	x.emplace(source<count_copies>());
	COPY_COUNT(1); MOVE_COUNT(0);

	#if !defined(BOOST_NO_RVALUE_REFERENCES)
	// No move should take place.
	reset();
	x.emplace(std::move(a));
	COPY_COUNT(0); MOVE_COUNT(0);
	#endif

	// Just in case a did get moved...
	count_copies b;

	// The container will have to create a copy in order to compare with
	// the existing element.
	reset();
	x.emplace(b.tag_);
	COPY_COUNT(1); MOVE_COUNT(0);

	//
	// 2 arguments
	//

	// The container will have to create b copy in order to compare with
	// the existing element.
	//
	// Note to self: If copy_count == 0 it's an error not an optimization.
	// TODO: Devise a better test.

	reset();

	x.emplace(b, b);
	COPY_COUNT(1); MOVE_COUNT(0);
	}

	UNORDERED_AUTO_TEST(unnecessary_copy_emplace_map_test)
	{
	reset();
	boost::unordered_map<count_copies, count_copies> x;
	// TODO: Run tests for pairs without const etc.
	std::pair<count_copies const, count_copies> a;
	x.emplace(a);
	COPY_COUNT(4); MOVE_COUNT(0);

	//
	// 0 arguments
	//

	// COPY_COUNT(1) would be okay here.
	reset();
	x.emplace();
	COPY_COUNT(2); MOVE_COUNT(0);

	//
	// 1 argument
	//

	reset();
	x.emplace(a);
	COPY_COUNT(0); MOVE_COUNT(0);

	// A new object is created by source, but it shouldn't be moved or
	// copied.
	reset();
	x.emplace(source<std::pair<count_copies, count_copies> >());
	COPY_COUNT(2); MOVE_COUNT(0);

	// TODO: This doesn't work on older versions of gcc.
	//count_copies part;
	std::pair<count_copies const, count_copies> b;
	//reset();
	//std::pair<count_copies const&, count_copies const&> a_ref(part, part);
	//x.emplace(a_ref);
	//COPY_COUNT(0); MOVE_COUNT(0);

	#if !defined(BOOST_NO_RVALUE_REFERENCES)
	// No move should take place.
	// (since a is already in the container)
	reset();
	x.emplace(std::move(a));
	COPY_COUNT(0); MOVE_COUNT(0);
	#endif


	//
	// 2 arguments
	//

	reset();
	x.emplace(b.first, b.second);
	COPY_COUNT(0); MOVE_COUNT(0);

	reset();
	x.emplace(source<count_copies>(), source<count_copies>());
	COPY_COUNT(2); MOVE_COUNT(0);

	// source<count_copies> creates a single copy.
	reset();
	x.emplace(b.first, source<count_copies>());
	COPY_COUNT(1); MOVE_COUNT(0);

	reset();
	x.emplace(count_copies(b.first.tag_), count_copies(b.second.tag_));
	COPY_COUNT(2); MOVE_COUNT(0);
	}
	}

	RUN_TESTS()