Sun, 18 Feb 2024 13:16:38 +0100
make cx_array_simple_add() automatically take the address of the element
/* * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS HEADER. * * Copyright 2023 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/tree.h" #include "cx/test.h" typedef struct tree_node { struct tree_node *parent; struct tree_node *next; struct tree_node *prev; struct tree_node *children; int data; } tree_node; #define tree_node_layout \ offsetof(tree_node, parent), offsetof(tree_node, children), \ offsetof(tree_node, prev), offsetof(tree_node, next) #define tree_child_list offsetof(tree_node, children),offsetof(tree_node, next) CX_TEST(test_tree_link_new_child) { tree_node parent = {0}; tree_node child = {0}; CX_TEST_DO { cx_tree_link(&parent, &child, tree_node_layout); CX_TEST_ASSERT(parent.next == NULL); CX_TEST_ASSERT(parent.prev == NULL); CX_TEST_ASSERT(parent.parent == NULL); CX_TEST_ASSERT(parent.children == &child); CX_TEST_ASSERT(child.parent == &parent); CX_TEST_ASSERT(child.next == NULL); CX_TEST_ASSERT(child.prev == NULL); CX_TEST_ASSERT(child.children == NULL); } } CX_TEST(test_tree_link_add_child) { tree_node parent = {0}; tree_node child1 = {0}; tree_node child2 = {0}; tree_node child3 = {0}; CX_TEST_DO { cx_tree_link(&parent, &child1, tree_node_layout); cx_tree_link(&parent, &child2, tree_node_layout); cx_tree_link(&parent, &child3, tree_node_layout); CX_TEST_ASSERT(parent.next == NULL); CX_TEST_ASSERT(parent.prev == NULL); CX_TEST_ASSERT(parent.parent == NULL); CX_TEST_ASSERT(parent.children == &child3); CX_TEST_ASSERT(child1.parent == &parent); CX_TEST_ASSERT(child2.parent == &parent); CX_TEST_ASSERT(child3.parent == &parent); CX_TEST_ASSERT(child1.children == NULL); CX_TEST_ASSERT(child2.children == NULL); CX_TEST_ASSERT(child3.children == NULL); CX_TEST_ASSERT(child3.prev == NULL); CX_TEST_ASSERT(child3.next == &child2); CX_TEST_ASSERT(child2.prev == &child3); CX_TEST_ASSERT(child2.next == &child1); CX_TEST_ASSERT(child1.prev == &child2); CX_TEST_ASSERT(child1.next == NULL); } } CX_TEST(test_tree_link_move_to_other_parent) { tree_node parent = {0}; tree_node child1 = {0}; tree_node child2 = {0}; tree_node child3 = {0}; cx_tree_link(&parent, &child1, tree_node_layout); cx_tree_link(&parent, &child2, tree_node_layout); cx_tree_link(&parent, &child3, tree_node_layout); CX_TEST_DO { cx_tree_link(&child3, &child2, tree_node_layout); CX_TEST_ASSERT(parent.next == NULL); CX_TEST_ASSERT(parent.prev == NULL); CX_TEST_ASSERT(parent.parent == NULL); CX_TEST_ASSERT(parent.children == &child3); CX_TEST_ASSERT(child1.parent == &parent); CX_TEST_ASSERT(child2.parent == &child3); CX_TEST_ASSERT(child3.parent == &parent); CX_TEST_ASSERT(child1.children == NULL); CX_TEST_ASSERT(child2.children == NULL); CX_TEST_ASSERT(child3.children == &child2); CX_TEST_ASSERT(child3.prev == NULL); CX_TEST_ASSERT(child3.next == &child1); CX_TEST_ASSERT(child1.prev == &child3); CX_TEST_ASSERT(child1.next == NULL); CX_TEST_ASSERT(child2.prev == NULL); CX_TEST_ASSERT(child2.next == NULL); } } CX_TEST(test_tree_unlink) { tree_node parent = {0}; tree_node child1 = {0}; tree_node child2 = {0}; tree_node child3 = {0}; cx_tree_link(&parent, &child1, tree_node_layout); cx_tree_link(&parent, &child3, tree_node_layout); cx_tree_link(&child3, &child2, tree_node_layout); CX_TEST_DO { cx_tree_unlink(&child3, tree_node_layout); CX_TEST_ASSERT(parent.next == NULL); CX_TEST_ASSERT(parent.prev == NULL); CX_TEST_ASSERT(parent.parent == NULL); CX_TEST_ASSERT(parent.children == &child1); CX_TEST_ASSERT(child1.parent == &parent); CX_TEST_ASSERT(child1.children == NULL); CX_TEST_ASSERT(child1.prev == NULL); CX_TEST_ASSERT(child1.next == NULL); // child 3 is unlinked CX_TEST_ASSERT(child3.parent == NULL); CX_TEST_ASSERT(child3.prev == NULL); CX_TEST_ASSERT(child3.next == NULL); // child 2 is still child of the unlinked child 3 CX_TEST_ASSERT(child3.children == &child2); CX_TEST_ASSERT(child2.parent == &child3); CX_TEST_ASSERT(child2.children == NULL); CX_TEST_ASSERT(child2.prev == NULL); CX_TEST_ASSERT(child2.next == NULL); } } static int test_tree_search_function(void const *n, void const *d) { tree_node const *node = n; int data = *((int const*)d); if (data < node->data) return -1; else if (data == node->data) return 0; else return data - node->data; } CX_TEST(test_tree_search) { tree_node root = {0}; tree_node a = {0}; tree_node b = {0}; tree_node c = {0}; tree_node aa = {0}; tree_node ab = {0}; tree_node ba = {0}; tree_node ca = {0}; tree_node cb = {0}; tree_node cc = {0}; tree_node cba = {0}; int testdata[] = {0, 10, 14, 18, 20, 25, 30, 32, 34, 36, 40}; tree_node* testnodes[] = {&root, &a, &aa, &ab, &b, &ba, &c, &ca, &cb, &cba, &cc}; for (unsigned i = 0 ; i <= 10 ; i++) { testnodes[i]->data = testdata[i]; } cx_tree_link(&root, &a, tree_node_layout); cx_tree_link(&root, &b, tree_node_layout); cx_tree_link(&root, &c, tree_node_layout); cx_tree_link(&a, &aa, tree_node_layout); cx_tree_link(&a, &ab, tree_node_layout); cx_tree_link(&b, &ba, tree_node_layout); cx_tree_link(&c, &ca, tree_node_layout); cx_tree_link(&c, &cb, tree_node_layout); cx_tree_link(&c, &cc, tree_node_layout); cx_tree_link(&cb, &cba, tree_node_layout); int s; int r; tree_node *n; CX_TEST_DO { for (unsigned i = 0 ; i <= 10 ; i++) { s = testdata[i]; r = cx_tree_search(&root, &s, test_tree_search_function, (void **) &n, tree_child_list); CX_TEST_ASSERT(r == 0); CX_TEST_ASSERT(n == testnodes[i]); } s = -5; r = cx_tree_search(&root, &s, test_tree_search_function, (void **) &n, tree_child_list); CX_TEST_ASSERT(r < 0); CX_TEST_ASSERT(n == NULL); s = 26; r = cx_tree_search(&root, &s, test_tree_search_function, (void **) &n, tree_child_list); CX_TEST_ASSERT(r > 0); CX_TEST_ASSERT(n == &ba); s = 35; r = cx_tree_search(&root, &s, test_tree_search_function, (void **) &n, tree_child_list); CX_TEST_ASSERT(r > 0); CX_TEST_ASSERT(n == &cb); s = 38; r = cx_tree_search(&root, &s, test_tree_search_function, (void **) &n, tree_child_list); CX_TEST_ASSERT(r > 0); CX_TEST_ASSERT(n == &cba); s = 42; r = cx_tree_search(&root, &s, test_tree_search_function, (void **) &n, tree_child_list); CX_TEST_ASSERT(r > 0); CX_TEST_ASSERT(n == &cc); } } CxTestSuite *cx_test_suite_tree_low_level(void) { CxTestSuite *suite = cx_test_suite_new("tree (low level)"); cx_test_register(suite, test_tree_link_new_child); cx_test_register(suite, test_tree_link_add_child); cx_test_register(suite, test_tree_link_move_to_other_parent); cx_test_register(suite, test_tree_unlink); cx_test_register(suite, test_tree_search); return suite; }