/* * Copyright (c) 2021, Idan Horowitz * * SPDX-License-Identifier: BSD-2-Clause */ #include #include #include #include #include class IntrusiveTest { public: IntrusiveTest(int value) : m_some_value(value) { } IntrusiveRedBlackTreeNode> m_tree_node; int m_some_value; }; using IntrusiveRBTree = IntrusiveRedBlackTree<&IntrusiveTest::m_tree_node>; TEST_CASE(construct) { IntrusiveRBTree empty; EXPECT(empty.is_empty()); EXPECT(empty.size() == 0); } TEST_CASE(ints) { IntrusiveRBTree test; IntrusiveTest first { 10 }; test.insert(1, first); IntrusiveTest second { 20 }; test.insert(3, second); IntrusiveTest third { 30 }; test.insert(2, third); EXPECT_EQ(test.size(), 3u); EXPECT_EQ(test.find(3)->m_some_value, 20); EXPECT_EQ(test.find(2)->m_some_value, 30); EXPECT_EQ(test.find(1)->m_some_value, 10); EXPECT(!test.remove(4)); EXPECT(test.remove(2)); EXPECT(test.remove(1)); EXPECT(test.remove(3)); EXPECT_EQ(test.size(), 0u); } TEST_CASE(largest_smaller_than) { IntrusiveRBTree test; IntrusiveTest first { 10 }; test.insert(1, first); IntrusiveTest second { 20 }; test.insert(11, second); IntrusiveTest third { 30 }; test.insert(21, third); EXPECT_EQ(test.size(), 3u); EXPECT_EQ(test.find_largest_not_above(3)->m_some_value, 10); EXPECT_EQ(test.find_largest_not_above(17)->m_some_value, 20); EXPECT_EQ(test.find_largest_not_above(22)->m_some_value, 30); EXPECT_EQ(test.find_largest_not_above(-5), nullptr); VERIFY(test.remove(1)); VERIFY(test.remove(11)); VERIFY(test.remove(21)); } TEST_CASE(key_ordered_iteration) { constexpr auto amount = 10000; IntrusiveRBTree test; Vector> m_entries; Array keys {}; // generate random key order for (int i = 0; i < amount; i++) { keys[i] = i; } for (size_t i = 0; i < amount; i++) { swap(keys[i], keys[get_random() % amount]); } // insert random keys for (size_t i = 0; i < amount; i++) { auto entry = make(keys[i]); test.insert(keys[i], *entry); m_entries.append(move(entry)); } // check key-ordered iteration int index = 0; for (auto& value : test) { EXPECT(value.m_some_value == index++); } // ensure we can remove all of them (aka, tree structure is not destroyed somehow) for (size_t i = 0; i < amount; i++) { EXPECT(test.remove(i)); } } TEST_CASE(clear) { IntrusiveRBTree test; Vector> m_entries; for (size_t i = 0; i < 1000; i++) { auto entry = make(i); test.insert(i, *entry); m_entries.append(move(entry)); } test.clear(); EXPECT_EQ(test.size(), 0u); } class IntrusiveRefPtrTest : public RefCounted { public: IntrusiveRefPtrTest() { } IntrusiveRedBlackTreeNode> m_tree_node; }; using IntrusiveRefPtrRBTree = IntrusiveRedBlackTree<&IntrusiveRefPtrTest::m_tree_node>; TEST_CASE(intrusive_ref_ptr_no_ref_leaks) { auto item = adopt_ref(*new IntrusiveRefPtrTest()); EXPECT_EQ(1u, item->ref_count()); IntrusiveRefPtrRBTree ref_tree; ref_tree.insert(0, *item); EXPECT_EQ(2u, item->ref_count()); ref_tree.remove(0); EXPECT_EQ(1u, item->ref_count()); } TEST_CASE(intrusive_ref_ptr_clear) { auto item = adopt_ref(*new IntrusiveRefPtrTest()); EXPECT_EQ(1u, item->ref_count()); IntrusiveRefPtrRBTree ref_tree; ref_tree.insert(0, *item); EXPECT_EQ(2u, item->ref_count()); ref_tree.clear(); EXPECT_EQ(1u, item->ref_count()); } TEST_CASE(intrusive_ref_ptr_destructor) { auto item = adopt_ref(*new IntrusiveRefPtrTest()); EXPECT_EQ(1u, item->ref_count()); { IntrusiveRefPtrRBTree ref_tree; ref_tree.insert(0, *item); EXPECT_EQ(2u, item->ref_count()); } EXPECT_EQ(1u, item->ref_count()); } class IntrusiveNonnullRefPtrTest : public RefCounted { public: IntrusiveNonnullRefPtrTest() { } IntrusiveRedBlackTreeNode> m_tree_node; }; using IntrusiveNonnullRefPtrRBTree = IntrusiveRedBlackTree<&IntrusiveNonnullRefPtrTest::m_tree_node>; TEST_CASE(intrusive_nonnull_ref_ptr_intrusive) { auto item = adopt_ref(*new IntrusiveNonnullRefPtrTest()); EXPECT_EQ(1u, item->ref_count()); IntrusiveNonnullRefPtrRBTree nonnull_ref_tree; nonnull_ref_tree.insert(0, *item); EXPECT_EQ(2u, item->ref_count()); EXPECT(!nonnull_ref_tree.is_empty()); nonnull_ref_tree.remove(0); EXPECT_EQ(1u, item->ref_count()); EXPECT(nonnull_ref_tree.is_empty()); }