/* * Copyright (c) 2021, Jan de Visser * * SPDX-License-Identifier: BSD-2-Clause */ #include #include #include #include #include #include #include constexpr static int keys[] = { 39, 87, 77, 42, 98, 40, 53, 8, 37, 12, 90, 72, 73, 11, 88, 22, 10, 82, 25, 61, 97, 18, 60, 68, 21, 3, 58, 29, 13, 17, 89, 81, 16, 64, 5, 41, 36, 91, 38, 24, 32, 50, 34, 94, 49, 47, 1, 6, 44, 76, }; constexpr static u32 pointers[] = { 92, 4, 50, 47, 68, 73, 24, 28, 50, 93, 60, 36, 92, 72, 53, 26, 91, 84, 25, 43, 88, 12, 62, 35, 96, 27, 96, 27, 99, 30, 21, 89, 54, 60, 37, 68, 35, 55, 80, 2, 33, 26, 93, 70, 45, 44, 3, 66, 75, 4, }; NonnullRefPtr setup_hash_index(SQL::Serializer&); void insert_and_get_to_and_from_hash_index(int); void insert_into_and_scan_hash_index(int); NonnullRefPtr setup_hash_index(SQL::Serializer& serializer) { NonnullRefPtr tuple_descriptor = adopt_ref(*new SQL::TupleDescriptor); tuple_descriptor->append({ "key_value", SQL::SQLType::Integer, SQL::Order::Ascending }); tuple_descriptor->append({ "text_value", SQL::SQLType::Text, SQL::Order::Ascending }); auto directory_pointer = serializer.heap().user_value(0); if (!directory_pointer) { directory_pointer = serializer.heap().new_record_pointer(); serializer.heap().set_user_value(0, directory_pointer); } auto hash_index = SQL::HashIndex::construct(serializer, tuple_descriptor, directory_pointer); return hash_index; } void insert_and_get_to_and_from_hash_index(int num_keys) { ScopeGuard guard([]() { unlink("/tmp/test.db"); }); { auto heap = SQL::Heap::construct("/tmp/test.db"); SQL::Serializer serializer(heap); auto hash_index = setup_hash_index(serializer); for (auto ix = 0; ix < num_keys; ix++) { SQL::Key k(hash_index->descriptor()); k[0] = keys[ix]; k[1] = String::formatted("The key value is {} and the pointer is {}", keys[ix], pointers[ix]); k.set_pointer(pointers[ix]); hash_index->insert(k); } #ifdef LIST_HASH_INDEX hash_index->list_hash(); #endif } { auto heap = SQL::Heap::construct("/tmp/test.db"); SQL::Serializer serializer(heap); auto hash_index = setup_hash_index(serializer); for (auto ix = 0; ix < num_keys; ix++) { SQL::Key k(hash_index->descriptor()); k[0] = keys[ix]; k[1] = String::formatted("The key value is {} and the pointer is {}", keys[ix], pointers[ix]); auto pointer_opt = hash_index->get(k); VERIFY(pointer_opt.has_value()); EXPECT_EQ(pointer_opt.value(), pointers[ix]); } } } TEST_CASE(hash_index_one_key) { insert_and_get_to_and_from_hash_index(1); } TEST_CASE(hash_index_four_keys) { insert_and_get_to_and_from_hash_index(4); } TEST_CASE(hash_index_five_keys) { insert_and_get_to_and_from_hash_index(5); } TEST_CASE(hash_index_10_keys) { insert_and_get_to_and_from_hash_index(10); } TEST_CASE(hash_index_13_keys) { insert_and_get_to_and_from_hash_index(13); } TEST_CASE(hash_index_20_keys) { insert_and_get_to_and_from_hash_index(20); } TEST_CASE(hash_index_25_keys) { insert_and_get_to_and_from_hash_index(25); } TEST_CASE(hash_index_30_keys) { insert_and_get_to_and_from_hash_index(30); } TEST_CASE(hash_index_35_keys) { insert_and_get_to_and_from_hash_index(35); } TEST_CASE(hash_index_40_keys) { insert_and_get_to_and_from_hash_index(40); } TEST_CASE(hash_index_45_keys) { insert_and_get_to_and_from_hash_index(45); } TEST_CASE(hash_index_50_keys) { insert_and_get_to_and_from_hash_index(50); } void insert_into_and_scan_hash_index(int num_keys) { ScopeGuard guard([]() { unlink("/tmp/test.db"); }); { auto heap = SQL::Heap::construct("/tmp/test.db"); SQL::Serializer serializer(heap); auto hash_index = setup_hash_index(serializer); for (auto ix = 0; ix < num_keys; ix++) { SQL::Key k(hash_index->descriptor()); k[0] = keys[ix]; k[1] = String::formatted("The key value is {} and the pointer is {}", keys[ix], pointers[ix]); k.set_pointer(pointers[ix]); hash_index->insert(k); } #ifdef LIST_HASH_INDEX hash_index->list_hash(); #endif } { auto heap = SQL::Heap::construct("/tmp/test.db"); SQL::Serializer serializer(heap); auto hash_index = setup_hash_index(serializer); Vector found; for (auto ix = 0; ix < num_keys; ix++) { found.append(false); } int count = 0; for (auto iter = hash_index->begin(); !iter.is_end(); iter++, count++) { auto key = (*iter); auto key_value = (int)key[0]; for (auto ix = 0; ix < num_keys; ix++) { if (keys[ix] == key_value) { EXPECT_EQ(key.pointer(), pointers[ix]); if (found[ix]) FAIL(String::formatted("Key {}, index {} already found previously", key_value, ix)); found[ix] = true; break; } } } #ifdef LIST_HASH_INDEX hash_index->list_hash(); #endif EXPECT_EQ(count, num_keys); for (auto ix = 0; ix < num_keys; ix++) { if (!found[ix]) FAIL(String::formatted("Key {}, index {} not found", keys[ix], ix)); } } } TEST_CASE(hash_index_scan_one_key) { insert_into_and_scan_hash_index(1); } TEST_CASE(hash_index_scan_four_keys) { insert_into_and_scan_hash_index(4); } TEST_CASE(hash_index_scan_five_keys) { insert_into_and_scan_hash_index(5); } TEST_CASE(hash_index_scan_10_keys) { insert_into_and_scan_hash_index(10); } TEST_CASE(hash_index_scan_15_keys) { insert_into_and_scan_hash_index(15); } TEST_CASE(hash_index_scan_20_keys) { insert_into_and_scan_hash_index(20); } TEST_CASE(hash_index_scan_30_keys) { insert_into_and_scan_hash_index(30); } TEST_CASE(hash_index_scan_40_keys) { insert_into_and_scan_hash_index(40); } TEST_CASE(hash_index_scan_50_keys) { insert_into_and_scan_hash_index(50); }