tests/test_list.cpp@d7129285ac32
tests/test_list.cpp
Tue, 21 Mar 2023 17:21:20 +0100
- author
- Mike Becker <universe@uap-core.de>
- date
- Tue, 21 Mar 2023 17:21:20 +0100
- changeset 668
- d7129285ac32
- parent 667
- 2f88a7c13a28
- child 672
- 55d8fdd38ca4
- permissions
- -rw-r--r--
add CX_STORE_POINTERS special item size for maps
/* * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS HEADER. * * Copyright 2021 Mike Becker, Olaf Wintermann All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. */ #include "cx/linked_list.h" #include "cx/array_list.h" #include "cx/utils.h" #include "cx/compare.h" #include "util_allocator.h" #include <gtest/gtest.h> #include <array> #include <vector> #include <unordered_set> #include <algorithm> struct testdatastruct { int x; void *ptr; }; static void free_testdatastruct( void *a, void *s ) { auto al = reinterpret_cast<CxTestingAllocator *>(a); cxFree(al, reinterpret_cast<testdatastruct *>(s)->ptr); } struct node { node *next = nullptr; node *prev = nullptr; int data = 0; }; const ptrdiff_t loc_prev = offsetof(struct node, prev); const ptrdiff_t loc_next = offsetof(struct node, next); const ptrdiff_t loc_data = offsetof(struct node, data); struct node_test_data { node *begin = nullptr; explicit node_test_data(node *begin) : begin(begin) { auto n = begin; while (n != nullptr) { nodes.push_back(n); n = n->next; } } node_test_data(node_test_data &) = delete; node_test_data(node_test_data &&) = default; ~node_test_data() { for (auto &&n: nodes) delete n; } private: std::vector<node *> nodes; }; static node_test_data create_nodes_test_data(size_t len) { if (len == 0) return node_test_data{nullptr}; auto begin = new node; auto prev = begin; for (size_t i = 1; i < len; i++) { auto n = new node; cx_linked_list_link(prev, n, loc_prev, loc_next); prev = n; } return node_test_data{begin}; } template<typename InputIter> static node_test_data create_nodes_test_data( InputIter begin, InputIter end ) { if (begin == end) return node_test_data{nullptr}; node *first = new node; first->data = *begin; node *prev = first; begin++; for (; begin != end; begin++) { auto n = new node; n->data = *begin; cx_linked_list_link(prev, n, loc_prev, loc_next); prev = n; } return node_test_data{first}; } static node_test_data create_nodes_test_data(std::initializer_list<int> data) { return create_nodes_test_data(data.begin(), data.end()); } template<size_t N> struct int_test_data { std::array<int, N> data; int_test_data() { cx_for_n (i, N) data[i] = ::rand(); // NOLINT(cert-msc50-cpp) } }; TEST(LinkedList_LowLevel, link_unlink) { node a, b, c; cx_linked_list_link(&a, &b, loc_prev, loc_next); EXPECT_EQ(a.prev, nullptr); EXPECT_EQ(a.next, &b); EXPECT_EQ(b.prev, &a); EXPECT_EQ(b.next, nullptr); cx_linked_list_unlink(&a, &b, loc_prev, loc_next); EXPECT_EQ(a.prev, nullptr); EXPECT_EQ(a.next, nullptr); EXPECT_EQ(b.prev, nullptr); EXPECT_EQ(b.next, nullptr); cx_linked_list_link(&b, &c, loc_prev, loc_next); cx_linked_list_link(&a, &b, loc_prev, loc_next); cx_linked_list_unlink(&b, &c, loc_prev, loc_next); EXPECT_EQ(a.prev, nullptr); EXPECT_EQ(a.next, &b); EXPECT_EQ(b.prev, &a); EXPECT_EQ(b.next, nullptr); EXPECT_EQ(c.prev, nullptr); EXPECT_EQ(c.next, nullptr); } TEST(LinkedList_LowLevel, cx_linked_list_at) { node a, b, c, d; cx_linked_list_link(&a, &b, loc_prev, loc_next); cx_linked_list_link(&b, &c, loc_prev, loc_next); cx_linked_list_link(&c, &d, loc_prev, loc_next); EXPECT_EQ(cx_linked_list_at(&a, 0, loc_next, 0), &a); EXPECT_EQ(cx_linked_list_at(&a, 0, loc_next, 1), &b); EXPECT_EQ(cx_linked_list_at(&a, 0, loc_next, 2), &c); EXPECT_EQ(cx_linked_list_at(&a, 0, loc_next, 3), &d); EXPECT_EQ(cx_linked_list_at(&a, 0, loc_next, 4), nullptr); EXPECT_EQ(cx_linked_list_at(&b, 1, loc_prev, 0), &a); EXPECT_EQ(cx_linked_list_at(&b, 1, loc_next, 1), &b); EXPECT_EQ(cx_linked_list_at(&b, 1, loc_next, 2), &c); EXPECT_EQ(cx_linked_list_at(&b, 1, loc_next, 3), &d); EXPECT_EQ(cx_linked_list_at(&b, 1, loc_next, 4), nullptr); EXPECT_EQ(cx_linked_list_at(&d, 3, loc_prev, 0), &a); EXPECT_EQ(cx_linked_list_at(&d, 3, loc_prev, 1), &b); } TEST(LinkedList_LowLevel, cx_linked_list_find) { auto testdata = create_nodes_test_data({2, 4, 6, 8}); auto list = testdata.begin; int s; s = 2; EXPECT_EQ(cx_linked_list_find(list, loc_next, loc_data, cx_cmp_int, &s), 0); s = 4; EXPECT_EQ(cx_linked_list_find(list, loc_next, loc_data, cx_cmp_int, &s), 1); s = 6; EXPECT_EQ(cx_linked_list_find(list, loc_next, loc_data, cx_cmp_int, &s), 2); s = 8; EXPECT_EQ(cx_linked_list_find(list, loc_next, loc_data, cx_cmp_int, &s), 3); s = 10; EXPECT_EQ(cx_linked_list_find(list, loc_next, loc_data, cx_cmp_int, &s), 4); s = -2; EXPECT_EQ(cx_linked_list_find(list, loc_next, loc_data, cx_cmp_int, &s), 4); } TEST(LinkedList_LowLevel, cx_linked_list_compare) { auto ta = create_nodes_test_data({2, 4, 6, 8}); auto tb = create_nodes_test_data({2, 4, 6}); auto tc = create_nodes_test_data({2, 4, 6, 9}); auto la = ta.begin, lb = tb.begin, lc = tc.begin; EXPECT_GT(cx_linked_list_compare(la, lb, loc_next, loc_data, cx_cmp_int), 0); EXPECT_LT(cx_linked_list_compare(lb, la, loc_next, loc_data, cx_cmp_int), 0); EXPECT_GT(cx_linked_list_compare(lc, la, loc_next, loc_data, cx_cmp_int), 0); EXPECT_LT(cx_linked_list_compare(la, lc, loc_next, loc_data, cx_cmp_int), 0); EXPECT_EQ(cx_linked_list_compare(la, la, loc_next, loc_data, cx_cmp_int), 0); } TEST(LinkedList_LowLevel, cx_linked_list_add) { // test with begin, end / prev, next { node nodes[4]; void *begin = nullptr, *end = nullptr; cx_linked_list_add(&begin, &end, loc_prev, loc_next, &nodes[0]); EXPECT_EQ(begin, &nodes[0]); EXPECT_EQ(end, &nodes[0]); EXPECT_EQ(nodes[0].prev, nullptr); EXPECT_EQ(nodes[0].next, nullptr); cx_linked_list_add(&begin, &end, loc_prev, loc_next, &nodes[1]); EXPECT_EQ(begin, &nodes[0]); EXPECT_EQ(end, &nodes[1]); EXPECT_EQ(nodes[0].next, &nodes[1]); EXPECT_EQ(nodes[1].prev, &nodes[0]); } // test with begin only / prev, next { node nodes[4]; void *begin = nullptr; cx_linked_list_add(&begin, nullptr, loc_prev, loc_next, &nodes[0]); EXPECT_EQ(begin, &nodes[0]); cx_linked_list_add(&begin, nullptr, loc_prev, loc_next, &nodes[1]); EXPECT_EQ(begin, &nodes[0]); EXPECT_EQ(nodes[0].next, &nodes[1]); EXPECT_EQ(nodes[1].prev, &nodes[0]); cx_linked_list_add(&begin, nullptr, loc_prev, loc_next, &nodes[2]); EXPECT_EQ(nodes[1].next, &nodes[2]); EXPECT_EQ(nodes[2].prev, &nodes[1]); } // test with end only / prev, next { node nodes[4]; void *end = nullptr; cx_linked_list_add(nullptr, &end, loc_prev, loc_next, &nodes[0]); EXPECT_EQ(end, &nodes[0]); cx_linked_list_add(nullptr, &end, loc_prev, loc_next, &nodes[1]); EXPECT_EQ(end, &nodes[1]); EXPECT_EQ(nodes[0].next, &nodes[1]); EXPECT_EQ(nodes[1].prev, &nodes[0]); cx_linked_list_add(nullptr, &end, loc_prev, loc_next, &nodes[2]); EXPECT_EQ(end, &nodes[2]); EXPECT_EQ(nodes[1].next, &nodes[2]); EXPECT_EQ(nodes[2].prev, &nodes[1]); } // test with begin, end / next { node nodes[4]; void *begin = nullptr, *end = nullptr; cx_linked_list_add(&begin, &end, -1, loc_next, &nodes[0]); EXPECT_EQ(begin, &nodes[0]); EXPECT_EQ(end, &nodes[0]); cx_linked_list_add(&begin, &end, -1, loc_next, &nodes[1]); EXPECT_EQ(end, &nodes[1]); EXPECT_EQ(nodes[0].next, &nodes[1]); EXPECT_EQ(nodes[1].prev, nullptr); } } TEST(LinkedList_LowLevel, cx_linked_list_prepend) { // test with begin, end / prev, next { node nodes[4]; void *begin = nullptr, *end = nullptr; cx_linked_list_prepend(&begin, &end, loc_prev, loc_next, &nodes[0]); EXPECT_EQ(begin, &nodes[0]); EXPECT_EQ(end, &nodes[0]); EXPECT_EQ(nodes[0].prev, nullptr); EXPECT_EQ(nodes[0].next, nullptr); cx_linked_list_prepend(&begin, &end, loc_prev, loc_next, &nodes[1]); EXPECT_EQ(begin, &nodes[1]); EXPECT_EQ(end, &nodes[0]); EXPECT_EQ(nodes[1].next, &nodes[0]); EXPECT_EQ(nodes[0].prev, &nodes[1]); } // test with begin only / prev, next { node nodes[4]; void *begin = nullptr; cx_linked_list_prepend(&begin, nullptr, loc_prev, loc_next, &nodes[0]); EXPECT_EQ(begin, &nodes[0]); cx_linked_list_prepend(&begin, nullptr, loc_prev, loc_next, &nodes[1]); EXPECT_EQ(begin, &nodes[1]); EXPECT_EQ(nodes[1].next, &nodes[0]); EXPECT_EQ(nodes[0].prev, &nodes[1]); cx_linked_list_prepend(&begin, nullptr, loc_prev, loc_next, &nodes[2]); EXPECT_EQ(begin, &nodes[2]); EXPECT_EQ(nodes[2].next, &nodes[1]); EXPECT_EQ(nodes[1].prev, &nodes[2]); } // test with end only / prev, next { node nodes[4]; void *end = nullptr; cx_linked_list_prepend(nullptr, &end, loc_prev, loc_next, &nodes[0]); EXPECT_EQ(end, &nodes[0]); cx_linked_list_prepend(nullptr, &end, loc_prev, loc_next, &nodes[1]); EXPECT_EQ(end, &nodes[0]); EXPECT_EQ(nodes[1].next, &nodes[0]); EXPECT_EQ(nodes[0].prev, &nodes[1]); cx_linked_list_prepend(nullptr, &end, loc_prev, loc_next, &nodes[2]); EXPECT_EQ(end, &nodes[0]); EXPECT_EQ(nodes[2].next, &nodes[1]); EXPECT_EQ(nodes[1].prev, &nodes[2]); } // test with begin, end / next { node nodes[4]; void *begin = nullptr, *end = nullptr; cx_linked_list_prepend(&begin, &end, -1, loc_next, &nodes[0]); EXPECT_EQ(begin, &nodes[0]); EXPECT_EQ(end, &nodes[0]); cx_linked_list_prepend(&begin, &end, -1, loc_next, &nodes[1]); cx_linked_list_prepend(&begin, &end, -1, loc_next, &nodes[2]); EXPECT_EQ(begin, &nodes[2]); EXPECT_EQ(end, &nodes[0]); EXPECT_EQ(nodes[1].next, &nodes[0]); EXPECT_EQ(nodes[2].next, &nodes[1]); EXPECT_EQ(nodes[1].prev, nullptr); EXPECT_EQ(nodes[0].prev, nullptr); } } TEST(LinkedList_LowLevel, cx_linked_list_insert) { // insert mid list { node nodes[4]; void *begin = &nodes[0], *end = &nodes[2]; cx_linked_list_link(&nodes[0], &nodes[1], loc_prev, loc_next); cx_linked_list_link(&nodes[1], &nodes[2], loc_prev, loc_next); cx_linked_list_insert(&begin, &end, loc_prev, loc_next, &nodes[1], &nodes[3]); EXPECT_EQ(begin, &nodes[0]); EXPECT_EQ(end, &nodes[2]); EXPECT_EQ(nodes[1].next, &nodes[3]); EXPECT_EQ(nodes[2].prev, &nodes[3]); EXPECT_EQ(nodes[3].prev, &nodes[1]); EXPECT_EQ(nodes[3].next, &nodes[2]); } // insert end { node nodes[4]; void *begin = &nodes[0], *end = &nodes[2]; cx_linked_list_link(&nodes[0], &nodes[1], loc_prev, loc_next); cx_linked_list_link(&nodes[1], &nodes[2], loc_prev, loc_next); cx_linked_list_insert(&begin, &end, loc_prev, loc_next, &nodes[2], &nodes[3]); EXPECT_EQ(begin, &nodes[0]); EXPECT_EQ(end, &nodes[3]); EXPECT_EQ(nodes[2].next, &nodes[3]); EXPECT_EQ(nodes[3].prev, &nodes[2]); EXPECT_EQ(nodes[3].next, nullptr); } // insert begin { node nodes[4]; void *begin = &nodes[0], *end = &nodes[2]; cx_linked_list_link(&nodes[0], &nodes[1], loc_prev, loc_next); cx_linked_list_link(&nodes[1], &nodes[2], loc_prev, loc_next); cx_linked_list_insert(&begin, &end, loc_prev, loc_next, nullptr, &nodes[3]); EXPECT_EQ(begin, &nodes[3]); EXPECT_EQ(end, &nodes[2]); EXPECT_EQ(nodes[0].prev, &nodes[3]); EXPECT_EQ(nodes[3].prev, nullptr); EXPECT_EQ(nodes[3].next, &nodes[0]); } } TEST(LinkedList_LowLevel, cx_linked_list_insert_chain) { // insert mid list { node nodes[5]; void *begin = &nodes[0], *end = &nodes[2]; cx_linked_list_link(&nodes[0], &nodes[1], loc_prev, loc_next); cx_linked_list_link(&nodes[1], &nodes[2], loc_prev, loc_next); cx_linked_list_link(&nodes[3], &nodes[4], loc_prev, loc_next); cx_linked_list_insert_chain(&begin, &end, loc_prev, loc_next, &nodes[1], &nodes[3], nullptr); EXPECT_EQ(begin, &nodes[0]); EXPECT_EQ(end, &nodes[2]); EXPECT_EQ(nodes[1].next, &nodes[3]); EXPECT_EQ(nodes[2].prev, &nodes[4]); EXPECT_EQ(nodes[3].prev, &nodes[1]); EXPECT_EQ(nodes[4].next, &nodes[2]); } // insert end { node nodes[5]; void *begin = &nodes[0], *end = &nodes[2]; cx_linked_list_link(&nodes[0], &nodes[1], loc_prev, loc_next); cx_linked_list_link(&nodes[1], &nodes[2], loc_prev, loc_next); cx_linked_list_link(&nodes[3], &nodes[4], loc_prev, loc_next); cx_linked_list_insert_chain(&begin, &end, loc_prev, loc_next, &nodes[2], &nodes[3], nullptr); EXPECT_EQ(begin, &nodes[0]); EXPECT_EQ(end, &nodes[4]); EXPECT_EQ(nodes[2].next, &nodes[3]); EXPECT_EQ(nodes[3].prev, &nodes[2]); EXPECT_EQ(nodes[4].next, nullptr); } // insert begin { node nodes[5]; void *begin = &nodes[0], *end = &nodes[2]; cx_linked_list_link(&nodes[0], &nodes[1], loc_prev, loc_next); cx_linked_list_link(&nodes[1], &nodes[2], loc_prev, loc_next); cx_linked_list_link(&nodes[3], &nodes[4], loc_prev, loc_next); cx_linked_list_insert_chain(&begin, &end, loc_prev, loc_next, nullptr, &nodes[3], nullptr); EXPECT_EQ(begin, &nodes[3]); EXPECT_EQ(end, &nodes[2]); EXPECT_EQ(nodes[0].prev, &nodes[4]); EXPECT_EQ(nodes[3].prev, nullptr); EXPECT_EQ(nodes[4].next, &nodes[0]); } } TEST(LinkedList_LowLevel, cx_linked_list_first) { auto testdata = create_nodes_test_data(3); auto begin = testdata.begin; EXPECT_EQ(cx_linked_list_first(begin, loc_prev), begin); EXPECT_EQ(cx_linked_list_first(begin->next, loc_prev), begin); EXPECT_EQ(cx_linked_list_first(begin->next->next, loc_prev), begin); } TEST(LinkedList_LowLevel, cx_linked_list_last) { auto testdata = create_nodes_test_data(3); auto begin = testdata.begin; auto end = begin->next->next; EXPECT_EQ(cx_linked_list_last(begin, loc_next), end); EXPECT_EQ(cx_linked_list_last(begin->next, loc_next), end); EXPECT_EQ(cx_linked_list_last(begin->next->next, loc_next), end); } TEST(LinkedList_LowLevel, cx_linked_list_prev) { auto testdata = create_nodes_test_data(3); auto begin = testdata.begin; EXPECT_EQ(cx_linked_list_prev(begin, loc_next, begin), nullptr); EXPECT_EQ(cx_linked_list_prev(begin, loc_next, begin->next), begin); EXPECT_EQ(cx_linked_list_prev(begin, loc_next, begin->next->next), begin->next); } TEST(LinkedList_LowLevel, cx_linked_list_remove) { auto testdata = create_nodes_test_data({2, 4, 6}); auto begin = reinterpret_cast<void *>(testdata.begin); auto first = testdata.begin; auto second = first->next; auto third = second->next; auto end = reinterpret_cast<void *>(third); cx_linked_list_remove(&begin, &end, loc_prev, loc_next, second); EXPECT_EQ(begin, first); EXPECT_EQ(end, third); EXPECT_EQ(first->prev, nullptr); EXPECT_EQ(first->next, third); EXPECT_EQ(third->prev, first); EXPECT_EQ(third->next, nullptr); cx_linked_list_remove(&begin, &end, loc_prev, loc_next, third); EXPECT_EQ(begin, first); EXPECT_EQ(end, first); EXPECT_EQ(first->prev, nullptr); EXPECT_EQ(first->next, nullptr); cx_linked_list_remove(&begin, &end, loc_prev, loc_next, first); EXPECT_EQ(begin, nullptr); EXPECT_EQ(end, nullptr); } TEST(LinkedList_LowLevel, cx_linked_list_size) { EXPECT_EQ(cx_linked_list_size(nullptr, loc_next), 0); { auto testdata = create_nodes_test_data(5); EXPECT_EQ(cx_linked_list_size(testdata.begin, loc_next), 5); } { auto testdata = create_nodes_test_data(13); EXPECT_EQ(cx_linked_list_size(testdata.begin, loc_next), 13); } } TEST(LinkedList_LowLevel, cx_linked_list_sort) { int_test_data<1500> testdata; std::array<int, 1500> sorted{}; std::partial_sort_copy(testdata.data.begin(), testdata.data.end(), sorted.begin(), sorted.end()); auto scrambled = create_nodes_test_data(testdata.data.begin(), testdata.data.end()); void *begin = scrambled.begin; void *end = cx_linked_list_last(begin, loc_next); cx_linked_list_sort(&begin, &end, loc_prev, loc_next, loc_data, cx_cmp_int); node *check = reinterpret_cast<node *>(begin); node *check_last = nullptr; cx_for_n (i, sorted.size()) { EXPECT_EQ(check->data, sorted[i]); EXPECT_EQ(check->prev, check_last); if (i < sorted.size() - 1) { ASSERT_NE(check->next, nullptr); } check_last = check; check = check->next; } EXPECT_EQ(check, nullptr); EXPECT_EQ(end, check_last); } TEST(LinkedList_LowLevel, cx_linked_list_reverse) { auto testdata = create_nodes_test_data({2, 4, 6, 8}); auto expected = create_nodes_test_data({8, 6, 4, 2}); auto begin = reinterpret_cast<void *>(testdata.begin); auto end = cx_linked_list_last(begin, loc_next); auto orig_begin = begin, orig_end = end; cx_linked_list_reverse(&begin, &end, loc_prev, loc_next); EXPECT_EQ(end, orig_begin); EXPECT_EQ(begin, orig_end); EXPECT_EQ(cx_linked_list_compare(begin, expected.begin, loc_next, loc_data, cx_cmp_int), 0); } class HighLevelTest : public ::testing::Test { mutable std::unordered_set<CxList *> lists; protected: CxTestingAllocator testingAllocator; void TearDown() override { for (auto &&l: lists) cxListDestroy(l); EXPECT_TRUE(testingAllocator.verify()); } static constexpr size_t testdata_len = 250; int_test_data<testdata_len> testdata; auto autofree(CxList *list) const -> CxList * { if (list != nullptr) lists.insert(list); return list; } auto linkedListFromTestData() const -> CxList * { auto list = autofree(cxLinkedListCreate(&testingAllocator, cx_cmp_int, sizeof(int))); cxListAddArray(list, testdata.data.data(), testdata_len); return list; } auto pointerLinkedListFromTestData() const -> CxList * { auto list = autofree(cxLinkedListCreate(&testingAllocator, cx_cmp_int, CX_STORE_POINTERS)); // note: cannot use cxListAddArray() because we don't have a list of pointers cx_for_n(i, testdata_len) cxListAdd(list, &testdata.data[i]); return list; } auto arrayListFromTestData() const -> CxList * { auto list = autofree(cxArrayListCreate(&testingAllocator, cx_cmp_int, sizeof(int), testdata_len)); cxListAddArray(list, testdata.data.data(), testdata_len); return list; } void verifyCreate(CxList *list) const { EXPECT_EQ(list->content_destructor_type, CX_DESTRUCTOR_NONE); EXPECT_EQ(list->size, 0); EXPECT_EQ(list->allocator, &testingAllocator); EXPECT_EQ(list->cmpfunc, cx_cmp_int); } void verifyAdd( CxList *list, bool as_pointer ) { auto len = testdata_len; cx_for_n (i, len) EXPECT_EQ(cxListAdd(list, &testdata.data[i]), 0); EXPECT_EQ(list->size, len); EXPECT_GE(list->capacity, list->size); cx_for_n (i, len) EXPECT_EQ(*(int *) cxListAt(list, i), testdata.data[i]); cx_for_n (i, len) ++testdata.data[i]; if (as_pointer) { cx_for_n (i, len) EXPECT_EQ(*(int *) cxListAt(list, i), testdata.data[i]); } else { cx_for_n (i, len) EXPECT_EQ(*(int *) cxListAt(list, i), testdata.data[i] - 1); } } static void verifyInsert(CxList *list) { int a = 5, b = 47, c = 13, d = 42; EXPECT_NE(cxListInsert(list, 1, &a), 0); EXPECT_EQ(list->size, 0); EXPECT_EQ(cxListInsert(list, 0, &a), 0); EXPECT_EQ(list->size, 1); EXPECT_EQ(cxListInsert(list, 0, &b), 0); EXPECT_EQ(list->size, 2); EXPECT_EQ(cxListInsert(list, 1, &c), 0); EXPECT_EQ(list->size, 3); EXPECT_EQ(cxListInsert(list, 3, &d), 0); ASSERT_EQ(list->size, 4); EXPECT_GE(list->capacity, list->size); EXPECT_EQ(*(int *) cxListAt(list, 0), 47); EXPECT_EQ(*(int *) cxListAt(list, 1), 13); EXPECT_EQ(*(int *) cxListAt(list, 2), 5); EXPECT_EQ(*(int *) cxListAt(list, 3), 42); } static void verifyInsertArray( CxList *list, bool pointers = false ) { int a[5] = {5, 47, 11, 13, 42}; int b[5] = {9, 18, 72, 50, 7}; int *aptr[5]; int *bptr[5]; cx_for_n(i, 5) { aptr[i] = &a[i]; bptr[i] = &b[i]; } size_t inserted; if (pointers) { inserted = cxListInsertArray(list, 0, aptr, 5); } else { inserted = cxListInsertArray(list, 0, a, 5); } EXPECT_EQ(inserted, 5); EXPECT_EQ(*(int *) cxListAt(list, 0), 5); EXPECT_EQ(*(int *) cxListAt(list, 1), 47); EXPECT_EQ(*(int *) cxListAt(list, 2), 11); EXPECT_EQ(*(int *) cxListAt(list, 3), 13); EXPECT_EQ(*(int *) cxListAt(list, 4), 42); if (pointers) { inserted = cxListInsertArray(list, 3, bptr, 5); } else { inserted = cxListInsertArray(list, 3, b, 5); } EXPECT_EQ(inserted, 5); EXPECT_EQ(*(int *) cxListAt(list, 0), 5); EXPECT_EQ(*(int *) cxListAt(list, 1), 47); EXPECT_EQ(*(int *) cxListAt(list, 2), 11); EXPECT_EQ(*(int *) cxListAt(list, 3), 9); EXPECT_EQ(*(int *) cxListAt(list, 4), 18); EXPECT_EQ(*(int *) cxListAt(list, 5), 72); EXPECT_EQ(*(int *) cxListAt(list, 6), 50); EXPECT_EQ(*(int *) cxListAt(list, 7), 7); EXPECT_EQ(*(int *) cxListAt(list, 8), 13); EXPECT_EQ(*(int *) cxListAt(list, 9), 42); } void verifyRemove(CxList *list) const { EXPECT_EQ(cxListRemove(list, 2), 0); EXPECT_EQ(cxListRemove(list, 4), 0); EXPECT_EQ(list->size, testdata_len - 2); EXPECT_GE(list->capacity, list->size); EXPECT_EQ(*(int *) cxListAt(list, 0), testdata.data[0]); EXPECT_EQ(*(int *) cxListAt(list, 1), testdata.data[1]); EXPECT_EQ(*(int *) cxListAt(list, 2), testdata.data[3]); EXPECT_EQ(*(int *) cxListAt(list, 3), testdata.data[4]); EXPECT_EQ(*(int *) cxListAt(list, 4), testdata.data[6]); EXPECT_EQ(cxListRemove(list, 0), 0); EXPECT_EQ(list->size, testdata_len - 3); EXPECT_GE(list->capacity, list->size); EXPECT_EQ(*(int *) cxListAt(list, 0), testdata.data[1]); EXPECT_EQ(*(int *) cxListAt(list, 1), testdata.data[3]); EXPECT_NE(cxListRemove(list, testdata_len), 0); } void verifyClear(CxList *list) { // use the testing allocator for testing the destructor function list->content_destructor_type = CX_DESTRUCTOR_ADVANCED; list->advanced_destructor.func = free_testdatastruct; list->advanced_destructor.data = &testingAllocator; testdatastruct s[10]; for (auto &t: s) { t.ptr = cxMalloc(&testingAllocator, 16); cxListAdd(list, &t); } cxListClear(list); } static void verifySwap(CxList *list) { ASSERT_EQ(list->size, 0); int original[16] = {0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15}; int swapped[16] = {8, 4, 14, 3, 1, 5, 9, 12, 0, 6, 11, 10, 7, 15, 2, 13}; // we have to add the items one by one, because it could be a pointer list cx_for_n(i, 16) { cxListAdd(list, &original[i]); } int result; // execute the test two times with different item sizes result = cxListSwap(list, 1, 4); EXPECT_EQ(0, result); result = cxListSwap(list, 2, 14); EXPECT_EQ(0, result); result = cxListSwap(list, 9, 6); EXPECT_EQ(0, result); result = cxListSwap(list, 3, 3); EXPECT_EQ(0, result); result = cxListSwap(list, 10, 11); EXPECT_EQ(0, result); result = cxListSwap(list, 8, 0); EXPECT_EQ(0, result); result = cxListSwap(list, 7, 12); EXPECT_EQ(0, result); result = cxListSwap(list, 13, 15); EXPECT_EQ(0, result); result = cxListSwap(list, 5, 16); EXPECT_NE(0, result); result = cxListSwap(list, 16, 6); EXPECT_NE(0, result); result = cxListSwap(list, 16, 17); EXPECT_NE(0, result); auto iter = cxListIterator(list); cx_foreach(int*, e, iter) { EXPECT_EQ(*e, swapped[iter.index]); } iter = cxListBackwardsIterator(list); cx_foreach(int*, e, iter) { EXPECT_EQ(*e, swapped[iter.index]); } } void verifyAt(CxList *list) const { auto len = testdata_len; EXPECT_EQ(list->size, len); cx_for_n (i, len) { EXPECT_EQ(*(int *) cxListAt(list, i), testdata.data[i]); } EXPECT_EQ(cxListAt(list, list->size), nullptr); } void verifyFind(CxList *list) const { cx_for_n (attempt, 25) { size_t exp = rand() % testdata_len; // NOLINT(cert-msc50-cpp) int val = testdata.data[exp]; // randomly picked number could occur earlier in list - find first position cx_for_n (i, exp) { if (testdata.data[i] == val) { exp = i; break; } } EXPECT_EQ(cxListFind(list, &val), exp); } } void verifySort(CxList *list) const { std::array<int, testdata_len> expected{}; std::partial_sort_copy(testdata.data.begin(), testdata.data.end(), expected.begin(), expected.end()); cxListSort(list); cx_for_n (i, testdata_len) ASSERT_EQ(*(int *) cxListAt(list, i), expected[i]); } void verifyIterator(CxList *list) const { auto iter = cxListIterator(list); size_t i = 0; cx_foreach(int*, x, iter) { ASSERT_EQ(i, iter.index); EXPECT_EQ(*x, testdata.data[iter.index]); i++; } ASSERT_EQ(i, list->size); iter = cxListBackwardsIterator(list); cx_foreach(int*, x, iter) { ASSERT_EQ(i - 1, iter.index); EXPECT_EQ(*x, testdata.data[iter.index]); i--; } ASSERT_EQ(i, 0); auto len = testdata_len; i = len / 2; auto mut_iter = cxListMutIteratorAt(list, i); size_t j = 0; cx_foreach(int*, x, mut_iter) { ASSERT_EQ(mut_iter.index, len / 2 + j / 2); ASSERT_EQ(*x, testdata.data[i]); if (i % 2 == 1) cxIteratorFlagRemoval(mut_iter); i++; j++; } ASSERT_EQ(i, len); i = len / 2; j = 0; mut_iter = cxListMutBackwardsIteratorAt(list, i - 1); cx_foreach(int*, x, mut_iter) { ASSERT_EQ(mut_iter.index, len / 2 - 1 - j); ASSERT_EQ(*x, testdata.data[i - 1]); if (i % 2 == 0) cxIteratorFlagRemoval(mut_iter); i--; j++; } ASSERT_EQ(i, 0); ASSERT_EQ(list->size, len / 2); cx_for_n(j, len / 2) ASSERT_EQ(*(int *) cxListAt(list, j), testdata.data[j * 2]); } static void verifyInsertViaIterator(CxList *list) { int newdata[] = {10, 20, 30, 40, 50}; auto iter = cxListMutIteratorAt(list, 2); EXPECT_TRUE(cxIteratorValid(iter)); EXPECT_EQ(iter.index, 2); EXPECT_EQ(*(int *) cxIteratorCurrent(iter), 2); cxListInsertAfter(&iter, &newdata[0]); EXPECT_TRUE(cxIteratorValid(iter)); EXPECT_EQ(iter.index, 2); EXPECT_EQ(*(int *) cxIteratorCurrent(iter), 2); cxListInsertBefore(&iter, &newdata[1]); EXPECT_TRUE(cxIteratorValid(iter)); EXPECT_EQ(iter.index, 3); EXPECT_EQ(*(int *) cxIteratorCurrent(iter), 2); iter = cxListMutIterator(list); cxListInsertBefore(&iter, &newdata[2]); EXPECT_TRUE(cxIteratorValid(iter)); EXPECT_EQ(iter.index, 1); EXPECT_EQ(*(int *) cxIteratorCurrent(iter), 0); iter = cxListMutIteratorAt(list, list->size); cxListInsertBefore(&iter, &newdata[3]); EXPECT_FALSE(cxIteratorValid(iter)); EXPECT_EQ(iter.index, 9); iter = cxListMutIteratorAt(list, list->size); cxListInsertAfter(&iter, &newdata[4]); EXPECT_FALSE(cxIteratorValid(iter)); EXPECT_EQ(iter.index, 10); int expdata[] = {30, 0, 1, 20, 2, 10, 3, 4, 40, 50}; cx_for_n (j, 10) EXPECT_EQ(*(int *) cxListAt(list, j), expdata[j]); } void verifyReverse(CxList *list) const { cxListReverse(list); cx_for_n(i, testdata_len) { ASSERT_EQ(*(int *) cxListAt(list, i), testdata.data[testdata_len - 1 - i]); } } static void verifyCompare( CxList *left, CxList *right ) { EXPECT_EQ(cxListCompare(left, right), 0); int x = 42; cxListAdd(left, &x); ASSERT_GT(left->size, right->size); EXPECT_GT(cxListCompare(left, right), 0); EXPECT_LT(cxListCompare(right, left), 0); cxListAdd(right, &x); ASSERT_EQ(left->size, right->size); EXPECT_EQ(cxListCompare(left, right), 0); int a = 5, b = 10; cxListInsert(left, 15, &a); cxListInsert(right, 15, &b); ASSERT_EQ(left->size, right->size); EXPECT_LT(cxListCompare(left, right), 0); EXPECT_GT(cxListCompare(right, left), 0); *(int *) cxListAt(left, 15) = 10; EXPECT_EQ(cxListCompare(left, right), 0); } }; class LinkedList : public HighLevelTest { }; class PointerLinkedList : public HighLevelTest { }; class ArrayList : public HighLevelTest { }; TEST_F(PointerLinkedList, cxListStorePointers) { auto list = autofree(cxLinkedListCreate(&testingAllocator, cx_cmp_int, 47)); EXPECT_FALSE(cxListIsStoringPointers(list)); cxListStorePointers(list); EXPECT_EQ(list->itemsize, sizeof(void *)); EXPECT_NE(list->cl, nullptr); EXPECT_NE(list->climpl, nullptr); EXPECT_TRUE(cxListIsStoringPointers(list)); cxListStoreObjects(list); EXPECT_NE(list->cl, nullptr); EXPECT_EQ(list->climpl, nullptr); EXPECT_FALSE(cxListIsStoringPointers(list)); list = autofree(cxLinkedListCreate(&testingAllocator, cx_cmp_int, CX_STORE_POINTERS)); EXPECT_EQ(list->itemsize, sizeof(void *)); EXPECT_NE(list->cl, nullptr); EXPECT_NE(list->climpl, nullptr); EXPECT_TRUE(cxListIsStoringPointers(list)); } TEST_F(LinkedList, cxLinkedListCreate) { CxList *list = autofree(cxLinkedListCreate(&testingAllocator, cx_cmp_int, sizeof(int))); ASSERT_NE(list, nullptr); EXPECT_EQ(list->itemsize, sizeof(int)); EXPECT_EQ(list->capacity, (size_t) -1); verifyCreate(list); } TEST_F(LinkedList, cxLinkedListCreateSimple) { CxList *list = autofree(cxLinkedListCreateSimple(sizeof(int))); ASSERT_NE(list, nullptr); EXPECT_EQ(list->itemsize, sizeof(int)); EXPECT_EQ(list->capacity, (size_t) -1); EXPECT_EQ(list->cmpfunc, nullptr); EXPECT_EQ(list->allocator, cxDefaultAllocator); } TEST_F(ArrayList, cxArrayListCreate) { CxList *list = autofree(cxArrayListCreate(&testingAllocator, cx_cmp_int, sizeof(int), 8)); ASSERT_NE(list, nullptr); EXPECT_EQ(list->itemsize, sizeof(int)); EXPECT_EQ(list->capacity, 8); verifyCreate(list); } TEST_F(ArrayList, cxArrayListCreateSimple) { CxList *list = autofree(cxArrayListCreateSimple(sizeof(int), 8)); ASSERT_NE(list, nullptr); EXPECT_EQ(list->cmpfunc, nullptr); EXPECT_EQ(list->allocator, cxDefaultAllocator); EXPECT_EQ(list->itemsize, sizeof(int)); EXPECT_EQ(list->capacity, 8); } TEST_F(LinkedList, cxListAdd) { auto list = autofree(cxLinkedListCreate(&testingAllocator, cx_cmp_int, sizeof(int))); verifyAdd(list, false); } TEST_F(PointerLinkedList, cxListAdd) { auto list = autofree(cxLinkedListCreate(&testingAllocator, cx_cmp_int, CX_STORE_POINTERS)); verifyAdd(list, true); } TEST_F(ArrayList, cxListAdd) { auto list = autofree(cxArrayListCreate(&testingAllocator, cx_cmp_int, sizeof(int), 8)); verifyAdd(list, false); } TEST_F(LinkedList, cxListInsert) { verifyInsert(autofree(cxLinkedListCreate(&testingAllocator, cx_cmp_int, sizeof(int)))); } TEST_F(PointerLinkedList, cxListInsert) { verifyInsert(autofree(cxLinkedListCreate(&testingAllocator, cx_cmp_int, CX_STORE_POINTERS))); } TEST_F(ArrayList, cxListInsert) { verifyInsert(autofree(cxArrayListCreate(&testingAllocator, cx_cmp_int, sizeof(int), 2))); } TEST_F(LinkedList, cxListInsertArray) { verifyInsertArray(autofree(cxLinkedListCreate(&testingAllocator, cx_cmp_int, sizeof(int)))); } TEST_F(PointerLinkedList, cxListInsertArray) { verifyInsertArray(autofree(cxLinkedListCreate(&testingAllocator, cx_cmp_int, CX_STORE_POINTERS)), true); } TEST_F(ArrayList, cxListInsertArray) { verifyInsertArray(autofree(cxArrayListCreate(&testingAllocator, cx_cmp_int, sizeof(int), 4))); } TEST_F(LinkedList, cxListRemove) { verifyRemove(linkedListFromTestData()); } TEST_F(PointerLinkedList, cxListRemove) { verifyRemove(pointerLinkedListFromTestData()); } TEST_F(ArrayList, cxListRemove) { verifyRemove(arrayListFromTestData()); } TEST_F(LinkedList, cxListClear) { verifyClear(autofree(cxLinkedListCreateSimple(sizeof(testdatastruct)))); } TEST_F(PointerLinkedList, cxListClear) { verifyClear(cxLinkedListCreateSimple(CX_STORE_POINTERS)); } TEST_F(ArrayList, cxListClear) { verifyClear(autofree(cxArrayListCreateSimple(sizeof(testdatastruct), 8))); } TEST_F(LinkedList, cxListSwap) { verifySwap(autofree(cxLinkedListCreate(&testingAllocator, cx_cmp_int, sizeof(int)))); } TEST_F(PointerLinkedList, cxListSwap) { verifySwap(autofree(cxLinkedListCreate(&testingAllocator, cx_cmp_int, CX_STORE_POINTERS))); } TEST_F(ArrayList, cxListSwap) { verifySwap(autofree(cxArrayListCreate(&testingAllocator, cx_cmp_int, sizeof(int), 16))); } TEST_F(LinkedList, cxListSwapNoSBO) { CX_DISABLE_LINKED_LIST_SWAP_SBO = true; verifySwap(autofree(cxLinkedListCreate(&testingAllocator, cx_cmp_int, sizeof(int)))); CX_DISABLE_LINKED_LIST_SWAP_SBO = false; } TEST_F(PointerLinkedList, cxListSwapNoSBO) { CX_DISABLE_LINKED_LIST_SWAP_SBO = true; verifySwap(autofree(cxLinkedListCreate(&testingAllocator, cx_cmp_int, CX_STORE_POINTERS))); CX_DISABLE_LINKED_LIST_SWAP_SBO = false; } TEST_F(ArrayList, cxListSwapNoSBO) { CX_DISABLE_LINKED_LIST_SWAP_SBO = true; verifySwap(autofree(cxArrayListCreate(&testingAllocator, cx_cmp_int, sizeof(int), 16))); CX_DISABLE_LINKED_LIST_SWAP_SBO = false; } TEST_F(LinkedList, cxListAt) { verifyAt(linkedListFromTestData()); } TEST_F(PointerLinkedList, cxListAt) { verifyAt(pointerLinkedListFromTestData()); } TEST_F(ArrayList, cxListAt) { verifyAt(arrayListFromTestData()); } TEST_F(LinkedList, cxListFind) { verifyFind(linkedListFromTestData()); } TEST_F(PointerLinkedList, cxListFind) { verifyFind(pointerLinkedListFromTestData()); } TEST_F(ArrayList, cxListFind) { verifyFind(arrayListFromTestData()); } TEST_F(LinkedList, cxListSort) { verifySort(linkedListFromTestData()); } TEST_F(PointerLinkedList, cxListSort) { verifySort(pointerLinkedListFromTestData()); } TEST_F(ArrayList, cxListSort) { verifySort(arrayListFromTestData()); } TEST_F(LinkedList, Iterator) { verifyIterator(linkedListFromTestData()); } TEST_F(PointerLinkedList, Iterator) { verifyIterator(pointerLinkedListFromTestData()); } TEST_F(ArrayList, Iterator) { verifyIterator(arrayListFromTestData()); } TEST_F(LinkedList, InsertViaIterator) { int fivenums[] = {0, 1, 2, 3, 4, 5}; CxList *list = autofree(cxLinkedListCreate(&testingAllocator, cx_cmp_int, sizeof(int))); cxListAddArray(list, fivenums, 5); verifyInsertViaIterator(list); } TEST_F(PointerLinkedList, InsertViaIterator) { int fivenums[] = {0, 1, 2, 3, 4, 5}; auto list = autofree(cxLinkedListCreate(&testingAllocator, cx_cmp_int, CX_STORE_POINTERS)); // note: cannot use cxListAddArray() because we don't have a list of pointers cx_for_n(i, 5) cxListAdd(list, &fivenums[i]); verifyInsertViaIterator(list); } TEST_F(ArrayList, InsertViaIterator) { int fivenums[] = {0, 1, 2, 3, 4, 5}; auto list = autofree(cxArrayListCreate(&testingAllocator, cx_cmp_int, sizeof(int), 4)); cxListAddArray(list, fivenums, 5); verifyInsertViaIterator(list); } TEST_F(LinkedList, cxListReverse) { verifyReverse(linkedListFromTestData()); } TEST_F(PointerLinkedList, cxListReverse) { verifyReverse(pointerLinkedListFromTestData()); } TEST_F(ArrayList, cxListReverse) { verifyReverse(arrayListFromTestData()); } TEST_F(LinkedList, cxListCompare) { auto left = linkedListFromTestData(); auto right = linkedListFromTestData(); verifyCompare(left, right); } TEST_F(LinkedList, cxListCompareWithPtrList) { auto left = linkedListFromTestData(); auto right = pointerLinkedListFromTestData(); verifyCompare(left, right); } TEST_F(LinkedList, cxListCompareWithArrayList) { auto left = linkedListFromTestData(); auto right = arrayListFromTestData(); verifyCompare(left, right); } TEST_F(PointerLinkedList, cxListCompare) { auto left = pointerLinkedListFromTestData(); auto right = pointerLinkedListFromTestData(); verifyCompare(left, right); } TEST_F(PointerLinkedList, cxListCompareWithNormalList) { auto left = pointerLinkedListFromTestData(); auto right = linkedListFromTestData(); verifyCompare(left, right); } TEST_F(PointerLinkedList, cxListCompareWithArrayList) { auto left = pointerLinkedListFromTestData(); auto right = arrayListFromTestData(); verifyCompare(left, right); } TEST_F(ArrayList, cxListCompare) { auto left = arrayListFromTestData(); auto right = arrayListFromTestData(); verifyCompare(left, right); } TEST_F(ArrayList, cxListCompareWithPtrList) { auto left = arrayListFromTestData(); auto right = pointerLinkedListFromTestData(); verifyCompare(left, right); } TEST_F(ArrayList, cxListCompareWithNormalList) { auto left = arrayListFromTestData(); auto right = linkedListFromTestData(); verifyCompare(left, right); } TEST_F(PointerLinkedList, NoDestructor) { void *item = cxMalloc(&testingAllocator, sizeof(int)); auto list = cxLinkedListCreate(cxDefaultAllocator, cx_cmp_int, CX_STORE_POINTERS); cxListAdd(list, item); ASSERT_FALSE(testingAllocator.verify()); cxListDestroy(list); EXPECT_FALSE(testingAllocator.verify()); cxFree(&testingAllocator, item); EXPECT_TRUE(testingAllocator.verify()); } TEST_F(PointerLinkedList, SimpleDestructor) { int item = 0; auto list = cxLinkedListCreate(cxDefaultAllocator, cx_cmp_int, CX_STORE_POINTERS); list->content_destructor_type = CX_DESTRUCTOR_SIMPLE; list->simple_destructor = [](void *elem) { *(int *) elem = 42; }; cxListAdd(list, &item); cxListDestroy(list); EXPECT_EQ(item, 42); } TEST_F(PointerLinkedList, AdvancedDestructor) { void *item = cxMalloc(&testingAllocator, sizeof(int)); auto list = cxLinkedListCreate(cxDefaultAllocator, cx_cmp_int, CX_STORE_POINTERS); list->content_destructor_type = CX_DESTRUCTOR_ADVANCED; list->advanced_destructor.data = &testingAllocator; list->advanced_destructor.func = (cx_destructor_func2) cxFree; cxListAdd(list, item); ASSERT_FALSE(testingAllocator.verify()); cxListDestroy(list); EXPECT_TRUE(testingAllocator.verify()); }
