boost_1_45_0/libs/unordered/test/unordered/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"
 #include "../objects/test.hpp"
 #include "../helpers/random_values.hpp"
 #include "../helpers/tracker.hpp"
 #include "../helpers/equivalent.hpp"
 #include "../helpers/invariants.hpp"

 test::seed_t seed(9063);

 namespace copy_tests
 {

 template <class T>
 void copy_construct_tests1(T*,
     test::random_generator const& generator = test::default_generator)
 {
     BOOST_DEDUCED_TYPENAME T::hasher hf;
     BOOST_DEDUCED_TYPENAME T::key_equal eq;
     BOOST_DEDUCED_TYPENAME T::allocator_type al;

     {
         T x;
         T y(x);
         BOOST_TEST(y.empty());
         BOOST_TEST(test::equivalent(y.hash_function(), hf));
         BOOST_TEST(test::equivalent(y.key_eq(), eq));
         BOOST_TEST(test::equivalent(y.get_allocator(), al));
         BOOST_TEST(x.max_load_factor() == y.max_load_factor());
         test::check_equivalent_keys(y);
     }

     {
         test::random_values<T> v(1000, generator);

         T x(v.begin(), v.end());
         T y(x);
         test::unordered_equivalence_tester<T> equivalent(x);
         BOOST_TEST(equivalent(y));
         test::check_equivalent_keys(y);
     }

     {
         // In this test I drop the original containers max load factor, so it
         // is much lower than the load factor. The hash table is not allowed
         // to rehash, but the destination container should probably allocate
         // enough buckets to decrease the load factor appropriately.
         test::random_values<T> v(1000, generator);
         T x(v.begin(), v.end());
         x.max_load_factor(x.load_factor() / 4);
         T y(x);
         test::unordered_equivalence_tester<T> equivalent(x);
         BOOST_TEST(equivalent(y));
         // This isn't guaranteed:
         BOOST_TEST(y.load_factor() < y.max_load_factor());
         test::check_equivalent_keys(y);
     }
 }

 template <class T>
 void copy_construct_tests2(T* ptr,
     test::random_generator const& generator = test::default_generator)
 {
     copy_construct_tests1(ptr);

     BOOST_DEDUCED_TYPENAME T::hasher hf(1);
     BOOST_DEDUCED_TYPENAME T::key_equal eq(1);
     BOOST_DEDUCED_TYPENAME T::allocator_type al(1);
     BOOST_DEDUCED_TYPENAME T::allocator_type al2(2);

     {
         T x(10000, hf, eq, al);
         T y(x);
         BOOST_TEST(y.empty());
         BOOST_TEST(test::equivalent(y.hash_function(), hf));
         BOOST_TEST(test::equivalent(y.key_eq(), eq));
         BOOST_TEST(test::equivalent(y.get_allocator(), al));
         BOOST_TEST(x.max_load_factor() == y.max_load_factor());
         test::check_equivalent_keys(y);
     }

     {
         T x(1000, hf, eq, al);
         T y(x, al2);
         BOOST_TEST(y.empty());
         BOOST_TEST(test::equivalent(y.hash_function(), hf));
         BOOST_TEST(test::equivalent(y.key_eq(), eq));
         BOOST_TEST(test::equivalent(y.get_allocator(), al2));
         BOOST_TEST(x.max_load_factor() == y.max_load_factor());
         test::check_equivalent_keys(y);
     }

     {
         test::random_values<T> v(1000, generator);

         T x(v.begin(), v.end(), 0, hf, eq, al);
         T y(x);
         test::unordered_equivalence_tester<T> equivalent(x);
         BOOST_TEST(equivalent(y));
         test::check_equivalent_keys(y);
         BOOST_TEST(test::equivalent(y.get_allocator(), al));
     }

     {
         test::random_values<T> v(500, generator);

         T x(v.begin(), v.end(), 0, hf, eq, al);
         T y(x, al2);
         test::unordered_equivalence_tester<T> equivalent(x);
         BOOST_TEST(equivalent(y));
         test::check_equivalent_keys(y);
         BOOST_TEST(test::equivalent(y.get_allocator(), al2));
     }
 }

 boost::unordered_set<test::object,
     test::hash, test::equal_to,
     test::allocator<test::object> >* test_set;
 boost::unordered_multiset<test::object,
     test::hash, test::equal_to,
     test::allocator<test::object> >* test_multiset;
 boost::unordered_map<test::object, test::object,
     test::hash, test::equal_to,
     test::allocator<test::object> >* test_map;
 boost::unordered_multimap<test::object, test::object,
     test::hash, test::equal_to,
     test::allocator<test::object> >* test_multimap;

 using test::default_generator;
 using test::generate_collisions;

 UNORDERED_TEST(copy_construct_tests1,
     ((test_set)(test_multiset)(test_map)(test_multimap))
 )

 UNORDERED_TEST(copy_construct_tests2,
     ((test_set)(test_multiset)(test_map)(test_multimap))
     ((default_generator)(generate_collisions))
 )

 }

 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"
	#include "../objects/test.hpp"
	#include "../helpers/random_values.hpp"
	#include "../helpers/tracker.hpp"
	#include "../helpers/equivalent.hpp"
	#include "../helpers/invariants.hpp"

	test::seed_t seed(9063);

	namespace copy_tests
	{

	template <class T>
	void copy_construct_tests1(T*,
	test::random_generator const& generator = test::default_generator)
	{
	BOOST_DEDUCED_TYPENAME T::hasher hf;
	BOOST_DEDUCED_TYPENAME T::key_equal eq;
	BOOST_DEDUCED_TYPENAME T::allocator_type al;

	{
	T x;
	T y(x);
	BOOST_TEST(y.empty());
	BOOST_TEST(test::equivalent(y.hash_function(), hf));
	BOOST_TEST(test::equivalent(y.key_eq(), eq));
	BOOST_TEST(test::equivalent(y.get_allocator(), al));
	BOOST_TEST(x.max_load_factor() == y.max_load_factor());
	test::check_equivalent_keys(y);
	}

	{
	test::random_values<T> v(1000, generator);

	T x(v.begin(), v.end());
	T y(x);
	test::unordered_equivalence_tester<T> equivalent(x);
	BOOST_TEST(equivalent(y));
	test::check_equivalent_keys(y);
	}

	{
	// In this test I drop the original containers max load factor, so it
	// is much lower than the load factor. The hash table is not allowed
	// to rehash, but the destination container should probably allocate
	// enough buckets to decrease the load factor appropriately.
	test::random_values<T> v(1000, generator);
	T x(v.begin(), v.end());
	x.max_load_factor(x.load_factor() / 4);
	T y(x);
	test::unordered_equivalence_tester<T> equivalent(x);
	BOOST_TEST(equivalent(y));
	// This isn't guaranteed:
	BOOST_TEST(y.load_factor() < y.max_load_factor());
	test::check_equivalent_keys(y);
	}
	}

	template <class T>
	void copy_construct_tests2(T* ptr,
	test::random_generator const& generator = test::default_generator)
	{
	copy_construct_tests1(ptr);

	BOOST_DEDUCED_TYPENAME T::hasher hf(1);
	BOOST_DEDUCED_TYPENAME T::key_equal eq(1);
	BOOST_DEDUCED_TYPENAME T::allocator_type al(1);
	BOOST_DEDUCED_TYPENAME T::allocator_type al2(2);

	{
	T x(10000, hf, eq, al);
	T y(x);
	BOOST_TEST(y.empty());
	BOOST_TEST(test::equivalent(y.hash_function(), hf));
	BOOST_TEST(test::equivalent(y.key_eq(), eq));
	BOOST_TEST(test::equivalent(y.get_allocator(), al));
	BOOST_TEST(x.max_load_factor() == y.max_load_factor());
	test::check_equivalent_keys(y);
	}

	{
	T x(1000, hf, eq, al);
	T y(x, al2);
	BOOST_TEST(y.empty());
	BOOST_TEST(test::equivalent(y.hash_function(), hf));
	BOOST_TEST(test::equivalent(y.key_eq(), eq));
	BOOST_TEST(test::equivalent(y.get_allocator(), al2));
	BOOST_TEST(x.max_load_factor() == y.max_load_factor());
	test::check_equivalent_keys(y);
	}

	{
	test::random_values<T> v(1000, generator);

	T x(v.begin(), v.end(), 0, hf, eq, al);
	T y(x);
	test::unordered_equivalence_tester<T> equivalent(x);
	BOOST_TEST(equivalent(y));
	test::check_equivalent_keys(y);
	BOOST_TEST(test::equivalent(y.get_allocator(), al));
	}

	{
	test::random_values<T> v(500, generator);

	T x(v.begin(), v.end(), 0, hf, eq, al);
	T y(x, al2);
	test::unordered_equivalence_tester<T> equivalent(x);
	BOOST_TEST(equivalent(y));
	test::check_equivalent_keys(y);
	BOOST_TEST(test::equivalent(y.get_allocator(), al2));
	}
	}

	boost::unordered_set<test::object,
	test::hash, test::equal_to,
	test::allocator<test::object> >* test_set;
	boost::unordered_multiset<test::object,
	test::hash, test::equal_to,
	test::allocator<test::object> >* test_multiset;
	boost::unordered_map<test::object, test::object,
	test::hash, test::equal_to,
	test::allocator<test::object> >* test_map;
	boost::unordered_multimap<test::object, test::object,
	test::hash, test::equal_to,
	test::allocator<test::object> >* test_multimap;

	using test::default_generator;
	using test::generate_collisions;

	UNORDERED_TEST(copy_construct_tests1,
	((test_set)(test_multiset)(test_map)(test_multimap))
	)

	UNORDERED_TEST(copy_construct_tests2,
	((test_set)(test_multiset)(test_map)(test_multimap))
	((default_generator)(generate_collisions))
	)

	}

	RUN_TESTS()