//===----------------------------------------------------------------------===// // // The LLVM Compiler Infrastructure // // This file is dual licensed under the MIT and the University of Illinois Open // Source Licenses. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // template , class Pred = equal_to, // class Alloc = allocator>> // class unordered_multimap // void swap(unordered_multimap& __u); #include #include #include #include "../../test_compare.h" #include "../../test_hash.h" #include "../../test_allocator.h" int main() { { typedef test_hash > Hash; typedef test_compare > Compare; typedef test_allocator > Alloc; typedef std::unordered_multimap C; typedef std::pair P; C c1(0, Hash(1), Compare(1), Alloc(1)); C c2(0, Hash(2), Compare(2), Alloc(2)); c2.max_load_factor(2); c1.swap(c2); assert(c1.bucket_count() == 0); assert(c1.size() == 0); assert(c1.hash_function() == Hash(2)); assert(c1.key_eq() == Compare(2)); assert(c1.get_allocator() == Alloc(1)); assert(std::distance(c1.begin(), c1.end()) == c1.size()); assert(std::distance(c1.cbegin(), c1.cend()) == c1.size()); assert(c1.max_load_factor() == 2); assert(c2.bucket_count() == 0); assert(c2.size() == 0); assert(c2.hash_function() == Hash(1)); assert(c2.key_eq() == Compare(1)); assert(c2.get_allocator() == Alloc(2)); assert(std::distance(c2.begin(), c2.end()) == c2.size()); assert(std::distance(c2.cbegin(), c2.cend()) == c2.size()); assert(c2.max_load_factor() == 1); } { typedef test_hash > Hash; typedef test_compare > Compare; typedef test_allocator > Alloc; typedef std::unordered_multimap C; typedef std::pair P; P a2[] = { P(10, "ten"), P(20, "twenty"), P(30, "thirty"), P(40, "fourty"), P(50, "fifty"), P(60, "sixty"), P(70, "seventy"), P(80, "eighty"), }; C c1(0, Hash(1), Compare(1), Alloc(1)); C c2(std::begin(a2), std::end(a2), 0, Hash(2), Compare(2), Alloc(2)); c2.max_load_factor(2); c1.swap(c2); assert(c1.bucket_count() >= 11); assert(c1.size() == 8); assert(c1.find(10)->second == "ten"); assert(c1.find(20)->second == "twenty"); assert(c1.find(30)->second == "thirty"); assert(c1.find(40)->second == "fourty"); assert(c1.find(50)->second == "fifty"); assert(c1.find(60)->second == "sixty"); assert(c1.find(70)->second == "seventy"); assert(c1.find(80)->second == "eighty"); assert(c1.hash_function() == Hash(2)); assert(c1.key_eq() == Compare(2)); assert(c1.get_allocator() == Alloc(1)); assert(std::distance(c1.begin(), c1.end()) == c1.size()); assert(std::distance(c1.cbegin(), c1.cend()) == c1.size()); assert(c1.max_load_factor() == 2); assert(c2.bucket_count() == 0); assert(c2.size() == 0); assert(c2.hash_function() == Hash(1)); assert(c2.key_eq() == Compare(1)); assert(c2.get_allocator() == Alloc(2)); assert(std::distance(c2.begin(), c2.end()) == c2.size()); assert(std::distance(c2.cbegin(), c2.cend()) == c2.size()); assert(c2.max_load_factor() == 1); } { typedef test_hash > Hash; typedef test_compare > Compare; typedef test_allocator > Alloc; typedef std::unordered_multimap C; typedef std::pair P; P a1[] = { P(1, "one"), P(2, "two"), P(3, "three"), P(4, "four"), P(1, "four"), P(2, "four"), }; C c1(std::begin(a1), std::end(a1), 0, Hash(1), Compare(1), Alloc(1)); C c2(0, Hash(2), Compare(2), Alloc(2)); c2.max_load_factor(2); c1.swap(c2); assert(c1.bucket_count() == 0); assert(c1.size() == 0); assert(c1.hash_function() == Hash(2)); assert(c1.key_eq() == Compare(2)); assert(c1.get_allocator() == Alloc(1)); assert(std::distance(c1.begin(), c1.end()) == c1.size()); assert(std::distance(c1.cbegin(), c1.cend()) == c1.size()); assert(c1.max_load_factor() == 2); assert(c2.bucket_count() >= 7); assert(c2.size() == 6); assert(c2.find(1)->second == "one"); assert(next(c2.find(1))->second == "four"); assert(c2.find(2)->second == "two"); assert(next(c2.find(2))->second == "four"); assert(c2.find(3)->second == "three"); assert(c2.find(4)->second == "four"); assert(c2.hash_function() == Hash(1)); assert(c2.key_eq() == Compare(1)); assert(c2.get_allocator() == Alloc(2)); assert(std::distance(c2.begin(), c2.end()) == c2.size()); assert(std::distance(c2.cbegin(), c2.cend()) == c2.size()); assert(c2.max_load_factor() == 1); } { typedef test_hash > Hash; typedef test_compare > Compare; typedef test_allocator > Alloc; typedef std::unordered_multimap C; typedef std::pair P; P a1[] = { P(1, "one"), P(2, "two"), P(3, "three"), P(4, "four"), P(1, "four"), P(2, "four"), }; P a2[] = { P(10, "ten"), P(20, "twenty"), P(30, "thirty"), P(40, "fourty"), P(50, "fifty"), P(60, "sixty"), P(70, "seventy"), P(80, "eighty"), }; C c1(std::begin(a1), std::end(a1), 0, Hash(1), Compare(1), Alloc(1)); C c2(std::begin(a2), std::end(a2), 0, Hash(2), Compare(2), Alloc(2)); c2.max_load_factor(2); c1.swap(c2); assert(c1.bucket_count() >= 11); assert(c1.size() == 8); assert(c1.find(10)->second == "ten"); assert(c1.find(20)->second == "twenty"); assert(c1.find(30)->second == "thirty"); assert(c1.find(40)->second == "fourty"); assert(c1.find(50)->second == "fifty"); assert(c1.find(60)->second == "sixty"); assert(c1.find(70)->second == "seventy"); assert(c1.find(80)->second == "eighty"); assert(c1.hash_function() == Hash(2)); assert(c1.key_eq() == Compare(2)); assert(c1.get_allocator() == Alloc(1)); assert(std::distance(c1.begin(), c1.end()) == c1.size()); assert(std::distance(c1.cbegin(), c1.cend()) == c1.size()); assert(c1.max_load_factor() == 2); assert(c2.bucket_count() >= 7); assert(c2.size() == 6); assert(c2.find(1)->second == "one"); assert(next(c2.find(1))->second == "four"); assert(c2.find(2)->second == "two"); assert(next(c2.find(2))->second == "four"); assert(c2.find(3)->second == "three"); assert(c2.find(4)->second == "four"); assert(c2.hash_function() == Hash(1)); assert(c2.key_eq() == Compare(1)); assert(c2.get_allocator() == Alloc(2)); assert(std::distance(c2.begin(), c2.end()) == c2.size()); assert(std::distance(c2.cbegin(), c2.cend()) == c2.size()); assert(c2.max_load_factor() == 1); } { typedef test_hash > Hash; typedef test_compare > Compare; typedef other_allocator > Alloc; typedef std::unordered_multimap C; typedef std::pair P; C c1(0, Hash(1), Compare(1), Alloc(1)); C c2(0, Hash(2), Compare(2), Alloc(2)); c2.max_load_factor(2); c1.swap(c2); assert(c1.bucket_count() == 0); assert(c1.size() == 0); assert(c1.hash_function() == Hash(2)); assert(c1.key_eq() == Compare(2)); assert(c1.get_allocator() == Alloc(2)); assert(std::distance(c1.begin(), c1.end()) == c1.size()); assert(std::distance(c1.cbegin(), c1.cend()) == c1.size()); assert(c1.max_load_factor() == 2); assert(c2.bucket_count() == 0); assert(c2.size() == 0); assert(c2.hash_function() == Hash(1)); assert(c2.key_eq() == Compare(1)); assert(c2.get_allocator() == Alloc(1)); assert(std::distance(c2.begin(), c2.end()) == c2.size()); assert(std::distance(c2.cbegin(), c2.cend()) == c2.size()); assert(c2.max_load_factor() == 1); } { typedef test_hash > Hash; typedef test_compare > Compare; typedef other_allocator > Alloc; typedef std::unordered_multimap C; typedef std::pair P; P a2[] = { P(10, "ten"), P(20, "twenty"), P(30, "thirty"), P(40, "fourty"), P(50, "fifty"), P(60, "sixty"), P(70, "seventy"), P(80, "eighty"), }; C c1(0, Hash(1), Compare(1), Alloc(1)); C c2(std::begin(a2), std::end(a2), 0, Hash(2), Compare(2), Alloc(2)); c2.max_load_factor(2); c1.swap(c2); assert(c1.bucket_count() >= 11); assert(c1.size() == 8); assert(c1.find(10)->second == "ten"); assert(c1.find(20)->second == "twenty"); assert(c1.find(30)->second == "thirty"); assert(c1.find(40)->second == "fourty"); assert(c1.find(50)->second == "fifty"); assert(c1.find(60)->second == "sixty"); assert(c1.find(70)->second == "seventy"); assert(c1.find(80)->second == "eighty"); assert(c1.hash_function() == Hash(2)); assert(c1.key_eq() == Compare(2)); assert(c1.get_allocator() == Alloc(2)); assert(std::distance(c1.begin(), c1.end()) == c1.size()); assert(std::distance(c1.cbegin(), c1.cend()) == c1.size()); assert(c1.max_load_factor() == 2); assert(c2.bucket_count() == 0); assert(c2.size() == 0); assert(c2.hash_function() == Hash(1)); assert(c2.key_eq() == Compare(1)); assert(c2.get_allocator() == Alloc(1)); assert(std::distance(c2.begin(), c2.end()) == c2.size()); assert(std::distance(c2.cbegin(), c2.cend()) == c2.size()); assert(c2.max_load_factor() == 1); } { typedef test_hash > Hash; typedef test_compare > Compare; typedef other_allocator > Alloc; typedef std::unordered_multimap C; typedef std::pair P; P a1[] = { P(1, "one"), P(2, "two"), P(3, "three"), P(4, "four"), P(1, "four"), P(2, "four"), }; C c1(std::begin(a1), std::end(a1), 0, Hash(1), Compare(1), Alloc(1)); C c2(0, Hash(2), Compare(2), Alloc(2)); c2.max_load_factor(2); c1.swap(c2); assert(c1.bucket_count() == 0); assert(c1.size() == 0); assert(c1.hash_function() == Hash(2)); assert(c1.key_eq() == Compare(2)); assert(c1.get_allocator() == Alloc(2)); assert(std::distance(c1.begin(), c1.end()) == c1.size()); assert(std::distance(c1.cbegin(), c1.cend()) == c1.size()); assert(c1.max_load_factor() == 2); assert(c2.bucket_count() >= 7); assert(c2.size() == 6); assert(c2.find(1)->second == "one"); assert(next(c2.find(1))->second == "four"); assert(c2.find(2)->second == "two"); assert(next(c2.find(2))->second == "four"); assert(c2.find(3)->second == "three"); assert(c2.find(4)->second == "four"); assert(c2.hash_function() == Hash(1)); assert(c2.key_eq() == Compare(1)); assert(c2.get_allocator() == Alloc(1)); assert(std::distance(c2.begin(), c2.end()) == c2.size()); assert(std::distance(c2.cbegin(), c2.cend()) == c2.size()); assert(c2.max_load_factor() == 1); } { typedef test_hash > Hash; typedef test_compare > Compare; typedef other_allocator > Alloc; typedef std::unordered_multimap C; typedef std::pair P; P a1[] = { P(1, "one"), P(2, "two"), P(3, "three"), P(4, "four"), P(1, "four"), P(2, "four"), }; P a2[] = { P(10, "ten"), P(20, "twenty"), P(30, "thirty"), P(40, "fourty"), P(50, "fifty"), P(60, "sixty"), P(70, "seventy"), P(80, "eighty"), }; C c1(std::begin(a1), std::end(a1), 0, Hash(1), Compare(1), Alloc(1)); C c2(std::begin(a2), std::end(a2), 0, Hash(2), Compare(2), Alloc(2)); c2.max_load_factor(2); c1.swap(c2); assert(c1.bucket_count() >= 11); assert(c1.size() == 8); assert(c1.find(10)->second == "ten"); assert(c1.find(20)->second == "twenty"); assert(c1.find(30)->second == "thirty"); assert(c1.find(40)->second == "fourty"); assert(c1.find(50)->second == "fifty"); assert(c1.find(60)->second == "sixty"); assert(c1.find(70)->second == "seventy"); assert(c1.find(80)->second == "eighty"); assert(c1.hash_function() == Hash(2)); assert(c1.key_eq() == Compare(2)); assert(c1.get_allocator() == Alloc(2)); assert(std::distance(c1.begin(), c1.end()) == c1.size()); assert(std::distance(c1.cbegin(), c1.cend()) == c1.size()); assert(c1.max_load_factor() == 2); assert(c2.bucket_count() >= 7); assert(c2.size() == 6); assert(c2.find(1)->second == "one"); assert(next(c2.find(1))->second == "four"); assert(c2.find(2)->second == "two"); assert(next(c2.find(2))->second == "four"); assert(c2.find(3)->second == "three"); assert(c2.find(4)->second == "four"); assert(c2.hash_function() == Hash(1)); assert(c2.key_eq() == Compare(1)); assert(c2.get_allocator() == Alloc(1)); assert(std::distance(c2.begin(), c2.end()) == c2.size()); assert(std::distance(c2.cbegin(), c2.cend()) == c2.size()); assert(c2.max_load_factor() == 1); } }