/* * Copyright (c) 2018 Intel Corporation. * * SPDX-License-Identifier: Apache-2.0 */ #include #include #include "../../../lib/os/rb.c" #define _CHECK(n) \ zassert_true(!!(n), "Tree check failed: [ " #n " ] @%d", __LINE__) #define MAX_NODES 256 static struct rbtree tree; static struct rbnode nodes[MAX_NODES]; /* Bit is set if node is in the tree */ static unsigned int node_mask[(MAX_NODES + 31)/32]; /* Array of nodes dumed via rb_walk */ static struct rbnode *walked_nodes[MAX_NODES]; /* Node currently being inserted, for testing lessthan() argument order */ static struct rbnode *current_insertee; void set_node_mask(int node, int val) { unsigned int *p = &node_mask[node / 32]; unsigned int bit = 1u << (node % 32); *p &= ~bit; *p |= val ? bit : 0; } int get_node_mask(int node) { unsigned int *p = &node_mask[node / 32]; unsigned int bit = 1u << (node % 32); return !!(*p & bit); } int node_index(struct rbnode *n) { return (int)(n - &nodes[0]); } /* Our "lessthan" is just the location of the struct */ bool node_lessthan(struct rbnode *a, struct rbnode *b) { if (current_insertee) { _CHECK(a == current_insertee); _CHECK(b != current_insertee); } return a < b; } /* Simple LCRNG (modulus is 2^64!) cribbed from: * https://nuclear.llnl.gov/CNP/rng/rngman/node4.html * * Don't need much in the way of quality, do need repeatability across * platforms. */ static unsigned int next_rand_mod(unsigned int mod) { static unsigned long long state = 123456789; /* seed */ state = state * 2862933555777941757ul + 3037000493ul; return ((unsigned int)(state >> 32)) % mod; } void visit_node(struct rbnode *node, void *cookie) { int *nwalked = cookie; _CHECK(*nwalked < MAX_NODES); walked_nodes[*nwalked] = node; *nwalked += 1; } /* Stores the last-seen black height at a leaf during check_rb(), or * zero if no leaves have been seen yet */ static int last_black_height; void check_rbnode(struct rbnode *node, int blacks_above) { int side, bheight = blacks_above + z_rb_is_black(node); for (side = 0; side < 2; side++) { struct rbnode *ch = z_rb_child(node, side); if (ch) { /* Basic tree requirement */ if (side == 0) { _CHECK(node_lessthan(ch, node)); } else { _CHECK(node_lessthan(node, ch)); } /* Can't have adjacent red nodes */ _CHECK(z_rb_is_black(node) || z_rb_is_black(ch)); /* Recurse */ check_rbnode(ch, bheight); } else { /* All leaf nodes must be at the same black height */ if (last_black_height) { _CHECK(last_black_height == bheight); } last_black_height = bheight; } } } void check_rb(void) { last_black_height = 0; _CHECK(tree.root); _CHECK(z_rb_is_black(tree.root)); check_rbnode(tree.root, 0); } /* First validates the external API behavior via a walk, then checks * interior tree and red/black state via internal APIs. */ void _check_tree(int size, int use_foreach) { int nwalked = 0, i, ni; struct rbnode *n, *last = NULL; (void)memset(walked_nodes, 0, sizeof(walked_nodes)); if (use_foreach) { RB_FOR_EACH(&tree, n) { visit_node(n, &nwalked); } } else { rb_walk(&tree, visit_node, &nwalked); } /* Make sure all found nodes are in-order and marked in the tree */ for (i = 0; i < nwalked; i++) { n = walked_nodes[i]; ni = node_index(n); if (last) { _CHECK(node_lessthan(last, n)); } _CHECK(get_node_mask(ni)); last = n; } /* Make sure all tree bits properly reflect the set of nodes we found */ ni = 0; for (i = 0; i < MAX_NODES; i++) { _CHECK(get_node_mask(i) == rb_contains(&tree, &nodes[i])); if (get_node_mask(i)) { _CHECK(node_index(walked_nodes[ni]) == i); ni++; } } _CHECK(ni == nwalked); if (tree.root) { check_rb(); } } void check_tree(int size) { /* Do it with both enumeration mechanisms */ _check_tree(size, 0); _check_tree(size, 1); } void checked_insert(struct rbtree *tree, struct rbnode *node) { current_insertee = node; rb_insert(tree, node); current_insertee = NULL; } void test_tree(int size) { int i, j; /* Small trees get checked after every op, big trees less often */ int small_tree = size <= 32; (void)memset(&tree, 0, sizeof(tree)); tree.lessthan_fn = node_lessthan; (void)memset(nodes, 0, sizeof(nodes)); (void)memset(node_mask, 0, sizeof(node_mask)); for (j = 0; j < 10; j++) { for (i = 0; i < size; i++) { int node = next_rand_mod(size); if (!get_node_mask(node)) { rb_insert(&tree, &nodes[node]); set_node_mask(node, 1); } else { rb_remove(&tree, &nodes[node]); set_node_mask(node, 0); } if (small_tree) { check_tree(size); } } if (!small_tree) { check_tree(size); } } } void test_rbtree_spam(void) { int size = 1; do { size += next_rand_mod(size) + 1; if (size > MAX_NODES) { size = MAX_NODES; } TC_PRINT("Checking trees built from %d nodes...\n", size); test_tree(size); } while (size < MAX_NODES); } /** * @brief Test removing a node with abnormal color. * * @details Initialize a tree and insert it, * and test APIs rb_get_min(), rb_get_max(). * * @ingroup lib_rbtree_tests * * @see rb_get_min(), rb_get_max() */ void test_rb_get_minmax(void) { struct rbnode temp = {0}; /* Initialize a tree and insert it */ (void)memset(&tree, 0, sizeof(tree)); tree.lessthan_fn = node_lessthan; (void)memset(nodes, 0, sizeof(nodes)); zassert_true(rb_get_min(&tree) == NULL, "the tree is invalid"); for (int i = 0; i < 8; i++) { rb_insert(&tree, &nodes[i]); } rb_remove(&tree, &temp); /* Check if tree's max and min node are expected */ zassert_true(rb_get_min(&tree) == &nodes[0], "the tree is invalid"); zassert_true(rb_get_max(&tree) == &nodes[7], "the tree is invalid"); } void test_main(void) { ztest_test_suite(test_rbtree, ztest_unit_test(test_rbtree_spam), ztest_unit_test(test_rb_get_minmax) ); ztest_run_test_suite(test_rbtree); }