///////////////////////////////////////////////////////////////////////////// // // (C) Copyright Olaf Krzikalla 2004-2006. // (C) Copyright Ion Gaztanaga 2006-2013. // // 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/intrusive for documentation. // ///////////////////////////////////////////////////////////////////////////// #include #include #include "itestvalue.hpp" #include "bptr_value.hpp" #include "smart_ptr.hpp" #include "common_functors.hpp" #include #include #include "test_macros.hpp" #include "test_container.hpp" #include using namespace boost::intrusive; template struct hooks { typedef list_base_hook > base_hook_type; typedef list_base_hook< link_mode , void_pointer, tag > auto_base_hook_type; typedef list_member_hook, tag > member_hook_type; typedef list_member_hook< link_mode , void_pointer > auto_member_hook_type; typedef nonhook_node_member< list_node_traits< VoidPointer >, circular_list_algorithms > nonhook_node_member_type; }; template < typename ListType, typename ValueContainer > struct test_list { typedef ListType list_type; typedef typename list_type::value_traits value_traits; typedef typename value_traits::value_type value_type; typedef typename list_type::node_algorithms node_algorithms; static void test_all(ValueContainer&); static void test_front_back(ValueContainer&); static void test_sort(ValueContainer&); static void test_merge(ValueContainer&); static void test_remove_unique(ValueContainer&); static void test_insert(ValueContainer&); static void test_shift(ValueContainer&); static void test_swap(ValueContainer&); static void test_clone(ValueContainer&); static void test_container_from_end(ValueContainer&, detail::true_type); static void test_container_from_end(ValueContainer&, detail::false_type) {} }; template < typename ListType, typename ValueContainer > void test_list< ListType, ValueContainer >::test_all(ValueContainer& values) { { list_type list(values.begin(), values.end()); test::test_container(list); list.clear(); list.insert(list.end(), values.begin(), values.end()); test::test_sequence_container(list, values); } { list_type list(values.begin(), values.end()); test::test_iterator_bidirectional(list); } test_front_back(values); test_sort(values); test_merge(values); test_remove_unique(values); test_insert(values); test_shift(values); test_swap(values); test_clone(values); test_container_from_end(values, detail::bool_< ListType::has_container_from_iterator >()); } //test: push_front, pop_front, push_back, pop_back, front, back, size, empty: template < class ListType, typename ValueContainer > void test_list< ListType, ValueContainer > ::test_front_back(ValueContainer& values) { list_type testlist; BOOST_TEST (testlist.empty()); testlist.push_back (values[0]); BOOST_TEST (testlist.size() == 1); BOOST_TEST (&testlist.front() == &values[0]); BOOST_TEST (&testlist.back() == &values[0]); testlist.push_front (values[1]); BOOST_TEST (testlist.size() == 2); BOOST_TEST (&testlist.front() == &values[1]); BOOST_TEST (&testlist.back() == &values[0]); testlist.pop_back(); BOOST_TEST (testlist.size() == 1); const list_type &const_testlist = testlist; BOOST_TEST (&const_testlist.front() == &values[1]); BOOST_TEST (&const_testlist.back() == &values[1]); testlist.pop_front(); BOOST_TEST (testlist.empty()); } //test: constructor, iterator, reverse_iterator, sort, reverse: template < class ListType, typename ValueContainer > void test_list< ListType, ValueContainer > ::test_sort(ValueContainer& values) { list_type testlist(values.begin(), values.end()); { int init_values [] = { 1, 2, 3, 4, 5 }; TEST_INTRUSIVE_SEQUENCE( init_values, testlist.begin() ); } testlist.sort (even_odd()); { int init_values [] = { 5, 3, 1, 4, 2 }; TEST_INTRUSIVE_SEQUENCE( init_values, testlist.rbegin() ); } testlist.reverse(); { int init_values [] = { 5, 3, 1, 4, 2 }; TEST_INTRUSIVE_SEQUENCE( init_values, testlist.begin() ); } } //test: merge due to error in merge implementation: template < class ListType, typename ValueContainer > void test_list< ListType, ValueContainer > ::test_remove_unique (ValueContainer& values) { { list_type list(values.begin(), values.end()); list.remove_if(is_even()); int init_values [] = { 1, 3, 5 }; TEST_INTRUSIVE_SEQUENCE( init_values, list.begin() ); } { list_type list(values.begin(), values.end()); list.remove_if(is_odd()); int init_values [] = { 2, 4 }; TEST_INTRUSIVE_SEQUENCE( init_values, list.begin() ); } { list_type list(values.begin(), values.end()); list.remove_and_dispose_if(is_even(), test::empty_disposer()); int init_values [] = { 1, 3, 5 }; TEST_INTRUSIVE_SEQUENCE( init_values, list.begin() ); } { list_type list(values.begin(), values.end()); list.remove_and_dispose_if(is_odd(), test::empty_disposer()); int init_values [] = { 2, 4 }; TEST_INTRUSIVE_SEQUENCE( init_values, list.begin() ); } { ValueContainer values2(values); list_type list(values.begin(), values.end()); list.insert(list.end(), values2.begin(), values2.end()); list.sort(); int init_values [] = { 1, 1, 2, 2, 3, 3, 4, 4, 5, 5 }; TEST_INTRUSIVE_SEQUENCE( init_values, list.begin() ); list.unique(); int init_values2 [] = { 1, 2, 3, 4, 5 }; TEST_INTRUSIVE_SEQUENCE( init_values2, list.begin() ); } } //test: merge due to error in merge implementation: template < class ListType, typename ValueContainer > void test_list< ListType, ValueContainer > ::test_merge (ValueContainer& values) { list_type testlist1, testlist2; testlist1.push_front (values[0]); testlist2.push_front (values[4]); testlist2.push_front (values[3]); testlist2.push_front (values[2]); testlist1.merge (testlist2); int init_values [] = { 1, 3, 4, 5 }; TEST_INTRUSIVE_SEQUENCE( init_values, testlist1.begin() ); } //test: assign, insert, const_iterator, const_reverse_iterator, erase, s_iterator_to: template < class ListType, typename ValueContainer > void test_list< ListType, ValueContainer > ::test_insert(ValueContainer& values) { list_type testlist; testlist.assign (values.begin() + 2, values.begin() + 5); const list_type& const_testlist = testlist; { int init_values [] = { 3, 4, 5 }; TEST_INTRUSIVE_SEQUENCE( init_values, const_testlist.begin() ); } typename list_type::iterator i = ++testlist.begin(); BOOST_TEST (i->value_ == 4); { typename list_type::const_iterator ci = typename list_type::iterator(); (void)ci; } testlist.insert (i, values[0]); { int init_values [] = { 5, 4, 1, 3 }; TEST_INTRUSIVE_SEQUENCE( init_values, const_testlist.rbegin() ); } i = testlist.iterator_to (values[4]); BOOST_TEST (&*i == &values[4]); i = list_type::s_iterator_to (values[4]); BOOST_TEST (&*i == &values[4]); typename list_type::const_iterator ic; ic = testlist.iterator_to (static_cast< typename list_type::const_reference >(values[4])); BOOST_TEST (&*ic == &values[4]); ic = list_type::s_iterator_to (static_cast< typename list_type::const_reference >(values[4])); BOOST_TEST (&*ic == &values[4]); i = testlist.erase (i); BOOST_TEST (i == testlist.end()); { int init_values [] = { 3, 1, 4 }; TEST_INTRUSIVE_SEQUENCE( init_values, const_testlist.begin() ); } } template < class ListType, typename ValueContainer > void test_list< ListType, ValueContainer > ::test_shift(ValueContainer& values) { list_type testlist; const int num_values = (int)values.size(); std::vector expected_values(num_values); for(int s = 1; s <= num_values; ++s){ expected_values.resize(s); //Shift forward all possible positions 3 times for(int i = 0; i < s*3; ++i){ testlist.insert(testlist.begin(), values.begin(), values.begin() + s); testlist.shift_forward(i); for(int j = 0; j < s; ++j){ expected_values[(j + s - i%s) % s] = (j + 1); } TEST_INTRUSIVE_SEQUENCE_EXPECTED(expected_values, testlist.begin()); testlist.clear(); } //Shift backwards all possible positions for(int i = 0; i < s*3; ++i){ testlist.insert(testlist.begin(), values.begin(), values.begin() + s); testlist.shift_backwards(i); for(int j = 0; j < s; ++j){ expected_values[(j + i) % s] = (j + 1); } TEST_INTRUSIVE_SEQUENCE_EXPECTED(expected_values, testlist.begin()); testlist.clear(); } } } //test: insert (seq-version), swap, splice, erase (seq-version): template < class ListType, typename ValueContainer > void test_list< ListType, ValueContainer > ::test_swap(ValueContainer& values) { { list_type testlist1 (values.begin(), values.begin() + 2); list_type testlist2; testlist2.insert (testlist2.end(), values.begin() + 2, values.begin() + 5); testlist1.swap (testlist2); { int init_values [] = { 3, 4, 5 }; TEST_INTRUSIVE_SEQUENCE( init_values, testlist1.begin() ); } { int init_values [] = { 1, 2 }; TEST_INTRUSIVE_SEQUENCE( init_values, testlist2.begin() ); } testlist2.splice (++testlist2.begin(), testlist1); { int init_values [] = { 1, 3, 4, 5, 2 }; TEST_INTRUSIVE_SEQUENCE( init_values, testlist2.begin() ); } BOOST_TEST (testlist1.empty()); testlist1.splice (testlist1.end(), testlist2, ++(++testlist2.begin())); { int init_values [] = { 4 }; TEST_INTRUSIVE_SEQUENCE( init_values, testlist1.begin() ); } { int init_values [] = { 1, 3, 5, 2 }; TEST_INTRUSIVE_SEQUENCE( init_values, testlist2.begin() ); } testlist1.splice (testlist1.end(), testlist2, testlist2.begin(), ----testlist2.end()); { int init_values [] = { 4, 1, 3 }; TEST_INTRUSIVE_SEQUENCE( init_values, testlist1.begin() ); } { int init_values [] = { 5, 2 }; TEST_INTRUSIVE_SEQUENCE( init_values, testlist2.begin() ); } testlist1.erase (testlist1.iterator_to(values[0]), testlist1.end()); BOOST_TEST (testlist1.size() == 1); BOOST_TEST (&testlist1.front() == &values[3]); } { list_type testlist1 (values.begin(), values.begin() + 2); list_type testlist2 (values.begin() + 3, values.begin() + 5); swap_nodes< node_algorithms >(values[0], values[2]); { int init_values [] = { 3, 2 }; TEST_INTRUSIVE_SEQUENCE( init_values, testlist1.begin() ); } swap_nodes< node_algorithms >(values[2], values[4]); { int init_values [] = { 5, 2 }; TEST_INTRUSIVE_SEQUENCE( init_values, testlist1.begin() ); } { int init_values [] = { 4, 3 }; TEST_INTRUSIVE_SEQUENCE( init_values, testlist2.begin() ); } } { list_type testlist1 (values.begin(), values.begin() + 1); { int init_values [] = { 1 }; TEST_INTRUSIVE_SEQUENCE( init_values, testlist1.begin() ); } swap_nodes< node_algorithms >(values[1], values[2]); { int init_values [] = { 1 }; TEST_INTRUSIVE_SEQUENCE( init_values, testlist1.begin() ); } swap_nodes< node_algorithms >(values[0], values[2]); { int init_values [] = { 3 }; TEST_INTRUSIVE_SEQUENCE( init_values, testlist1.begin() ); } swap_nodes< node_algorithms >(values[0], values[2]); { int init_values [] = { 1 }; TEST_INTRUSIVE_SEQUENCE( init_values, testlist1.begin() ); } } } template < class ListType, typename ValueContainer > void test_list< ListType, ValueContainer > ::test_container_from_end(ValueContainer& values, detail::true_type) { list_type testlist1 (values.begin(), values.begin() + values.size()); BOOST_TEST (testlist1 == list_type::container_from_end_iterator(testlist1.end())); BOOST_TEST (testlist1 == list_type::container_from_end_iterator(testlist1.cend())); } template < class ListType, typename ValueContainer > void test_list< ListType, ValueContainer > ::test_clone(ValueContainer& values) { list_type testlist1 (values.begin(), values.begin() + values.size()); list_type testlist2; testlist2.clone_from(testlist1, test::new_cloner(), test::delete_disposer()); BOOST_TEST (testlist2 == testlist1); testlist2.clear_and_dispose(test::delete_disposer()); BOOST_TEST (testlist2.empty()); } template < typename ValueTraits, bool ConstantTimeSize, bool Default_Holder, typename ValueContainer > struct make_and_test_list : test_list< list< typename ValueTraits::value_type, value_traits< ValueTraits >, size_type< std::size_t >, constant_time_size< ConstantTimeSize > >, ValueContainer > {}; template < typename ValueTraits, bool ConstantTimeSize, typename ValueContainer > struct make_and_test_list< ValueTraits, ConstantTimeSize, false, ValueContainer > : test_list< list< typename ValueTraits::value_type, value_traits< ValueTraits >, size_type< std::size_t >, constant_time_size< ConstantTimeSize >, header_holder_type< heap_node_holder< typename ValueTraits::pointer > > >, ValueContainer > {}; template < class VoidPointer, bool ConstantTimeSize, bool Default_Holder > class test_main_template { public: int operator()() { typedef testvalue< hooks > value_type; std::vector data (5); for (int i = 0; i < 5; ++i) data[i].value_ = i + 1; make_and_test_list < typename detail::get_base_value_traits < value_type, typename hooks::base_hook_type >::type, ConstantTimeSize, Default_Holder, std::vector< value_type > >::test_all(data); make_and_test_list < typename detail::get_member_value_traits < member_hook< value_type, typename hooks::member_hook_type, &value_type::node_> >::type, ConstantTimeSize, Default_Holder, std::vector< value_type > >::test_all(data); make_and_test_list< nonhook_node_member_value_traits < value_type, typename hooks::nonhook_node_member_type, &value_type::nhn_member_, safe_link >, ConstantTimeSize, Default_Holder, std::vector< value_type > >::test_all(data); return 0; } }; template < class VoidPointer, bool Default_Holder > class test_main_template< VoidPointer, false, Default_Holder > { public: int operator()() { typedef testvalue< hooks > value_type; std::vector data (5); for (int i = 0; i < 5; ++i) data[i].value_ = i + 1; make_and_test_list < typename detail::get_base_value_traits < value_type, typename hooks::auto_base_hook_type >::type, false, Default_Holder, std::vector< value_type > >::test_all(data); make_and_test_list < typename detail::get_member_value_traits < member_hook< value_type, typename hooks::auto_member_hook_type, &value_type::auto_node_> >::type, false, Default_Holder, std::vector< value_type > >::test_all(data); return 0; } }; template < bool ConstantTimeSize > struct test_main_template_bptr { int operator()() { typedef BPtr_Value value_type; typedef BPtr_Value_Traits< List_BPtr_Node_Traits > list_value_traits; typedef typename list_value_traits::node_ptr node_ptr; typedef bounded_allocator< value_type > allocator_type; bounded_allocator_scope bounded_scope; (void)bounded_scope; allocator_type allocator; { bounded_reference_cont< value_type > ref_cont; for (int i = 0; i < 5; ++i) { node_ptr tmp = allocator.allocate(1); new (tmp.raw()) value_type(i + 1); ref_cont.push_back(*tmp); } test_list < list < value_type, value_traits< list_value_traits >, size_type< std::size_t >, constant_time_size< ConstantTimeSize >, header_holder_type< bounded_pointer_holder< value_type > > >, bounded_reference_cont< value_type > >::test_all(ref_cont); } return 0; } }; int main() { // test (plain/smart pointers) x (nonconst/const size) x (void node allocator) test_main_template()(); test_main_template, false, true>()(); test_main_template()(); test_main_template, true, true>()(); // test (bounded pointers) x ((nonconst/const size) x (special node allocator) test_main_template_bptr< true >()(); test_main_template_bptr< false >()(); return boost::report_errors(); }