/* * Copyright (C) Internet Systems Consortium, Inc. ("ISC") * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, you can obtain one at https://mozilla.org/MPL/2.0/. * * See the COPYRIGHT file distributed with this work for additional * information regarding copyright ownership. */ #if HAVE_CMOCKA #include #include #include #include /* IWYU pragma: keep */ #include #include #include #include #include #include #include #include #define UNIT_TESTING #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "dnstest.h" typedef struct { dns_rbt_t *rbt; dns_rbt_t *rbt_distances; } test_context_t; /* The initial structure of domain tree will be as follows: * * . * | * b * / \ * a d.e.f * / | \ * c | g.h * | | * w.y i * / | \ \ * x | z k * | | * p j * / \ * o q */ /* The full absolute names of the nodes in the tree (the tree also * contains "." which is not included in this list). */ static const char *const domain_names[] = { "c", "b", "a", "x.d.e.f", "z.d.e.f", "g.h", "i.g.h", "o.w.y.d.e.f", "j.z.d.e.f", "p.w.y.d.e.f", "q.w.y.d.e.f", "k.g.h" }; static const size_t domain_names_count = (sizeof(domain_names) / sizeof(domain_names[0])); /* These are set as the node data for the tree used in distances check * (for the names in domain_names[] above). */ static const int node_distances[] = { 3, 1, 2, 2, 2, 3, 1, 2, 1, 1, 2, 2 }; /* * The domain order should be: * ., a, b, c, d.e.f, x.d.e.f, w.y.d.e.f, o.w.y.d.e.f, p.w.y.d.e.f, * q.w.y.d.e.f, z.d.e.f, j.z.d.e.f, g.h, i.g.h, k.g.h * . (no data, can't be found) * | * b * / \ * a d.e.f * / | \ * c | g.h * | | * w.y i * / | \ \ * x | z k * | | * p j * / \ * o q */ static const char *const ordered_names[] = { "a", "b", "c", "d.e.f", "x.d.e.f", "w.y.d.e.f", "o.w.y.d.e.f", "p.w.y.d.e.f", "q.w.y.d.e.f", "z.d.e.f", "j.z.d.e.f", "g.h", "i.g.h", "k.g.h" }; static const size_t ordered_names_count = (sizeof(ordered_names) / sizeof(*ordered_names)); static int _setup(void **state) { isc_result_t result; UNUSED(state); result = dns_test_begin(NULL, false); assert_int_equal(result, ISC_R_SUCCESS); return (0); } static int _teardown(void **state) { UNUSED(state); dns_test_end(); return (0); } static void delete_data(void *data, void *arg) { UNUSED(arg); isc_mem_put(dt_mctx, data, sizeof(size_t)); } static test_context_t * test_context_setup(void) { test_context_t *ctx; isc_result_t result; size_t i; ctx = isc_mem_get(dt_mctx, sizeof(*ctx)); assert_non_null(ctx); ctx->rbt = NULL; result = dns_rbt_create(dt_mctx, delete_data, NULL, &ctx->rbt); assert_int_equal(result, ISC_R_SUCCESS); ctx->rbt_distances = NULL; result = dns_rbt_create(dt_mctx, delete_data, NULL, &ctx->rbt_distances); assert_int_equal(result, ISC_R_SUCCESS); for (i = 0; i < domain_names_count; i++) { size_t *n; dns_fixedname_t fname; dns_name_t *name; dns_test_namefromstring(domain_names[i], &fname); name = dns_fixedname_name(&fname); n = isc_mem_get(dt_mctx, sizeof(size_t)); assert_non_null(n); *n = i + 1; result = dns_rbt_addname(ctx->rbt, name, n); assert_int_equal(result, ISC_R_SUCCESS); n = isc_mem_get(dt_mctx, sizeof(size_t)); assert_non_null(n); *n = node_distances[i]; result = dns_rbt_addname(ctx->rbt_distances, name, n); assert_int_equal(result, ISC_R_SUCCESS); } return (ctx); } static void test_context_teardown(test_context_t *ctx) { dns_rbt_destroy(&ctx->rbt); dns_rbt_destroy(&ctx->rbt_distances); isc_mem_put(dt_mctx, ctx, sizeof(*ctx)); } /* * Walk the tree and ensure that all the test nodes are present. */ static void check_test_data(dns_rbt_t *rbt) { dns_fixedname_t fixed; isc_result_t result; dns_name_t *foundname; size_t i; foundname = dns_fixedname_initname(&fixed); for (i = 0; i < domain_names_count; i++) { dns_fixedname_t fname; dns_name_t *name; size_t *n; dns_test_namefromstring(domain_names[i], &fname); name = dns_fixedname_name(&fname); n = NULL; result = dns_rbt_findname(rbt, name, 0, foundname, (void *)&n); assert_int_equal(result, ISC_R_SUCCESS); assert_int_equal(*n, i + 1); } } /* Test the creation of an rbt */ static void rbt_create(void **state) { test_context_t *ctx; bool tree_ok; UNUSED(state); isc_mem_debugging = ISC_MEM_DEBUGRECORD; ctx = test_context_setup(); check_test_data(ctx->rbt); tree_ok = dns__rbt_checkproperties(ctx->rbt); assert_true(tree_ok); test_context_teardown(ctx); } /* Test dns_rbt_nodecount() on a tree */ static void rbt_nodecount(void **state) { test_context_t *ctx; UNUSED(state); isc_mem_debugging = ISC_MEM_DEBUGRECORD; ctx = test_context_setup(); assert_int_equal(15, dns_rbt_nodecount(ctx->rbt)); test_context_teardown(ctx); } /* Test dns_rbtnode_get_distance() on a tree */ static void rbtnode_get_distance(void **state) { isc_result_t result; test_context_t *ctx; const char *name_str = "a"; dns_fixedname_t fname; dns_name_t *name; dns_rbtnode_t *node = NULL; dns_rbtnodechain_t chain; UNUSED(state); isc_mem_debugging = ISC_MEM_DEBUGRECORD; ctx = test_context_setup(); dns_test_namefromstring(name_str, &fname); name = dns_fixedname_name(&fname); dns_rbtnodechain_init(&chain); result = dns_rbt_findnode(ctx->rbt_distances, name, NULL, &node, &chain, 0, NULL, NULL); assert_int_equal(result, ISC_R_SUCCESS); while (node != NULL) { const size_t *distance = (const size_t *)node->data; if (distance != NULL) { assert_int_equal(*distance, dns__rbtnode_getdistance(node)); } result = dns_rbtnodechain_next(&chain, NULL, NULL); if (result == ISC_R_NOMORE) { break; } dns_rbtnodechain_current(&chain, NULL, NULL, &node); } assert_int_equal(result, ISC_R_NOMORE); dns_rbtnodechain_invalidate(&chain); test_context_teardown(ctx); } /* * Test tree balance, inserting names in random order. * * This test checks an important performance-related property of * the red-black tree, which is important for us: the longest * path from a sub-tree's root to a node is no more than * 2log(n). This check verifies that the tree is balanced. */ static void rbt_check_distance_random(void **state) { dns_rbt_t *mytree = NULL; const unsigned int log_num_nodes = 16; isc_result_t result; bool tree_ok; int i; UNUSED(state); isc_mem_debugging = ISC_MEM_DEBUGRECORD; result = dns_rbt_create(dt_mctx, delete_data, NULL, &mytree); assert_int_equal(result, ISC_R_SUCCESS); /* Names are inserted in random order. */ /* Make a large 65536 node top-level domain tree, i.e., the * following code inserts names such as: * * savoucnsrkrqzpkqypbygwoiliawpbmz. * wkadamcbbpjtundbxcmuayuycposvngx. * wzbpznemtooxdpjecdxynsfztvnuyfao. * yueojmhyffslpvfmgyfwioxegfhepnqq. */ for (i = 0; i < (1 << log_num_nodes); i++) { size_t *n; char namebuf[34]; n = isc_mem_get(dt_mctx, sizeof(size_t)); assert_non_null(n); *n = i + 1; while (1) { int j; dns_fixedname_t fname; dns_name_t *name; for (j = 0; j < 32; j++) { uint32_t v = isc_random_uniform(26); namebuf[j] = 'a' + v; } namebuf[32] = '.'; namebuf[33] = 0; dns_test_namefromstring(namebuf, &fname); name = dns_fixedname_name(&fname); result = dns_rbt_addname(mytree, name, n); if (result == ISC_R_SUCCESS) { break; } } } /* 1 (root . node) + (1 << log_num_nodes) */ assert_int_equal(1U + (1U << log_num_nodes), dns_rbt_nodecount(mytree)); /* The distance from each node to its sub-tree root must be less * than 2 * log(n). */ assert_true((2U * log_num_nodes) >= dns__rbt_getheight(mytree)); /* Also check RB tree properties */ tree_ok = dns__rbt_checkproperties(mytree); assert_true(tree_ok); dns_rbt_destroy(&mytree); } /* * Test tree balance, inserting names in sorted order. * * This test checks an important performance-related property of * the red-black tree, which is important for us: the longest * path from a sub-tree's root to a node is no more than * 2log(n). This check verifies that the tree is balanced. */ static void rbt_check_distance_ordered(void **state) { dns_rbt_t *mytree = NULL; const unsigned int log_num_nodes = 16; isc_result_t result; bool tree_ok; int i; UNUSED(state); isc_mem_debugging = ISC_MEM_DEBUGRECORD; result = dns_rbt_create(dt_mctx, delete_data, NULL, &mytree); assert_int_equal(result, ISC_R_SUCCESS); /* Names are inserted in sorted order. */ /* Make a large 65536 node top-level domain tree, i.e., the * following code inserts names such as: * * name00000000. * name00000001. * name00000002. * name00000003. */ for (i = 0; i < (1 << log_num_nodes); i++) { size_t *n; char namebuf[14]; dns_fixedname_t fname; dns_name_t *name; n = isc_mem_get(dt_mctx, sizeof(size_t)); assert_non_null(n); *n = i + 1; snprintf(namebuf, sizeof(namebuf), "name%08x.", i); dns_test_namefromstring(namebuf, &fname); name = dns_fixedname_name(&fname); result = dns_rbt_addname(mytree, name, n); assert_int_equal(result, ISC_R_SUCCESS); } /* 1 (root . node) + (1 << log_num_nodes) */ assert_int_equal(1U + (1U << log_num_nodes), dns_rbt_nodecount(mytree)); /* The distance from each node to its sub-tree root must be less * than 2 * log(n). */ assert_true((2U * log_num_nodes) >= dns__rbt_getheight(mytree)); /* Also check RB tree properties */ tree_ok = dns__rbt_checkproperties(mytree); assert_true(tree_ok); dns_rbt_destroy(&mytree); } static isc_result_t insert_helper(dns_rbt_t *rbt, const char *namestr, dns_rbtnode_t **node) { dns_fixedname_t fname; dns_name_t *name; dns_test_namefromstring(namestr, &fname); name = dns_fixedname_name(&fname); return (dns_rbt_addnode(rbt, name, node)); } static bool compare_labelsequences(dns_rbtnode_t *node, const char *labelstr) { dns_name_t name; isc_result_t result; char *nodestr = NULL; bool is_equal; dns_name_init(&name, NULL); dns_rbt_namefromnode(node, &name); result = dns_name_tostring(&name, &nodestr, dt_mctx); assert_int_equal(result, ISC_R_SUCCESS); is_equal = strcmp(labelstr, nodestr) == 0 ? true : false; isc_mem_free(dt_mctx, nodestr); return (is_equal); } /* Test insertion into a tree */ static void rbt_insert(void **state) { isc_result_t result; test_context_t *ctx; dns_rbtnode_t *node; UNUSED(state); isc_mem_debugging = ISC_MEM_DEBUGRECORD; ctx = test_context_setup(); /* Check node count before beginning. */ assert_int_equal(15, dns_rbt_nodecount(ctx->rbt)); /* Try to insert a node that already exists. */ node = NULL; result = insert_helper(ctx->rbt, "d.e.f", &node); assert_int_equal(result, ISC_R_EXISTS); /* Node count must not have changed. */ assert_int_equal(15, dns_rbt_nodecount(ctx->rbt)); /* Try to insert a node that doesn't exist. */ node = NULL; result = insert_helper(ctx->rbt, "0", &node); assert_int_equal(result, ISC_R_SUCCESS); assert_true(compare_labelsequences(node, "0")); /* Node count must have increased. */ assert_int_equal(16, dns_rbt_nodecount(ctx->rbt)); /* Another. */ node = NULL; result = insert_helper(ctx->rbt, "example.com", &node); assert_int_equal(result, ISC_R_SUCCESS); assert_non_null(node); assert_null(node->data); /* Node count must have increased. */ assert_int_equal(17, dns_rbt_nodecount(ctx->rbt)); /* Re-adding it should return EXISTS */ node = NULL; result = insert_helper(ctx->rbt, "example.com", &node); assert_int_equal(result, ISC_R_EXISTS); /* Node count must not have changed. */ assert_int_equal(17, dns_rbt_nodecount(ctx->rbt)); /* Fission the node d.e.f */ node = NULL; result = insert_helper(ctx->rbt, "k.e.f", &node); assert_int_equal(result, ISC_R_SUCCESS); assert_true(compare_labelsequences(node, "k")); /* Node count must have incremented twice ("d.e.f" fissioned to * "d" and "e.f", and the newly added "k"). */ assert_int_equal(19, dns_rbt_nodecount(ctx->rbt)); /* Fission the node "g.h" */ node = NULL; result = insert_helper(ctx->rbt, "h", &node); assert_int_equal(result, ISC_R_SUCCESS); assert_true(compare_labelsequences(node, "h")); /* Node count must have incremented ("g.h" fissioned to "g" and * "h"). */ assert_int_equal(20, dns_rbt_nodecount(ctx->rbt)); /* Add child domains */ node = NULL; result = insert_helper(ctx->rbt, "m.p.w.y.d.e.f", &node); assert_int_equal(result, ISC_R_SUCCESS); assert_true(compare_labelsequences(node, "m")); assert_int_equal(21, dns_rbt_nodecount(ctx->rbt)); node = NULL; result = insert_helper(ctx->rbt, "n.p.w.y.d.e.f", &node); assert_int_equal(result, ISC_R_SUCCESS); assert_true(compare_labelsequences(node, "n")); assert_int_equal(22, dns_rbt_nodecount(ctx->rbt)); node = NULL; result = insert_helper(ctx->rbt, "l.a", &node); assert_int_equal(result, ISC_R_SUCCESS); assert_true(compare_labelsequences(node, "l")); assert_int_equal(23, dns_rbt_nodecount(ctx->rbt)); node = NULL; result = insert_helper(ctx->rbt, "r.d.e.f", &node); assert_int_equal(result, ISC_R_SUCCESS); node = NULL; result = insert_helper(ctx->rbt, "s.d.e.f", &node); assert_int_equal(result, ISC_R_SUCCESS); assert_int_equal(25, dns_rbt_nodecount(ctx->rbt)); node = NULL; result = insert_helper(ctx->rbt, "h.w.y.d.e.f", &node); assert_int_equal(result, ISC_R_SUCCESS); /* Add more nodes one by one to cover left and right rotation * functions. */ node = NULL; result = insert_helper(ctx->rbt, "f", &node); assert_int_equal(result, ISC_R_SUCCESS); node = NULL; result = insert_helper(ctx->rbt, "m", &node); assert_int_equal(result, ISC_R_SUCCESS); node = NULL; result = insert_helper(ctx->rbt, "nm", &node); assert_int_equal(result, ISC_R_SUCCESS); node = NULL; result = insert_helper(ctx->rbt, "om", &node); assert_int_equal(result, ISC_R_SUCCESS); node = NULL; result = insert_helper(ctx->rbt, "k", &node); assert_int_equal(result, ISC_R_SUCCESS); node = NULL; result = insert_helper(ctx->rbt, "l", &node); assert_int_equal(result, ISC_R_SUCCESS); node = NULL; result = insert_helper(ctx->rbt, "fe", &node); assert_int_equal(result, ISC_R_SUCCESS); node = NULL; result = insert_helper(ctx->rbt, "ge", &node); assert_int_equal(result, ISC_R_SUCCESS); node = NULL; result = insert_helper(ctx->rbt, "i", &node); assert_int_equal(result, ISC_R_SUCCESS); node = NULL; result = insert_helper(ctx->rbt, "ae", &node); assert_int_equal(result, ISC_R_SUCCESS); node = NULL; result = insert_helper(ctx->rbt, "n", &node); assert_int_equal(result, ISC_R_SUCCESS); test_context_teardown(ctx); } /* * Test removal from a tree * * This testcase checks that after node removal, the binary-search tree is * valid and all nodes that are supposed to exist are present in the * correct order. It mainly tests DomainTree as a BST, and not particularly * as a red-black tree. This test checks node deletion when upper nodes * have data. */ static void rbt_remove(void **state) { isc_result_t result; size_t j; UNUSED(state); isc_mem_debugging = ISC_MEM_DEBUGRECORD; /* * Delete single nodes and check if the rest of the nodes exist. */ for (j = 0; j < ordered_names_count; j++) { dns_rbt_t *mytree = NULL; dns_rbtnode_t *node; size_t i; size_t *n; bool tree_ok; dns_rbtnodechain_t chain; size_t start_node; /* Create a tree. */ result = dns_rbt_create(dt_mctx, delete_data, NULL, &mytree); assert_int_equal(result, ISC_R_SUCCESS); /* Insert test data into the tree. */ for (i = 0; i < domain_names_count; i++) { node = NULL; result = insert_helper(mytree, domain_names[i], &node); assert_int_equal(result, ISC_R_SUCCESS); } /* Check that all names exist in order. */ for (i = 0; i < ordered_names_count; i++) { dns_fixedname_t fname; dns_name_t *name; dns_test_namefromstring(ordered_names[i], &fname); name = dns_fixedname_name(&fname); node = NULL; result = dns_rbt_findnode(mytree, name, NULL, &node, NULL, DNS_RBTFIND_EMPTYDATA, NULL, NULL); assert_int_equal(result, ISC_R_SUCCESS); /* Add node data */ assert_non_null(node); assert_null(node->data); n = isc_mem_get(dt_mctx, sizeof(size_t)); assert_non_null(n); *n = i; node->data = n; } /* Now, delete the j'th node from the tree. */ { dns_fixedname_t fname; dns_name_t *name; dns_test_namefromstring(ordered_names[j], &fname); name = dns_fixedname_name(&fname); result = dns_rbt_deletename(mytree, name, false); assert_int_equal(result, ISC_R_SUCCESS); } /* Check RB tree properties. */ tree_ok = dns__rbt_checkproperties(mytree); assert_true(tree_ok); dns_rbtnodechain_init(&chain); /* Now, walk through nodes in order. */ if (j == 0) { /* * Node for ordered_names[0] was already deleted * above. We start from node 1. */ dns_fixedname_t fname; dns_name_t *name; dns_test_namefromstring(ordered_names[0], &fname); name = dns_fixedname_name(&fname); node = NULL; result = dns_rbt_findnode(mytree, name, NULL, &node, NULL, 0, NULL, NULL); assert_int_equal(result, ISC_R_NOTFOUND); dns_test_namefromstring(ordered_names[1], &fname); name = dns_fixedname_name(&fname); node = NULL; result = dns_rbt_findnode(mytree, name, NULL, &node, &chain, 0, NULL, NULL); assert_int_equal(result, ISC_R_SUCCESS); start_node = 1; } else { /* Start from node 0. */ dns_fixedname_t fname; dns_name_t *name; dns_test_namefromstring(ordered_names[0], &fname); name = dns_fixedname_name(&fname); node = NULL; result = dns_rbt_findnode(mytree, name, NULL, &node, &chain, 0, NULL, NULL); assert_int_equal(result, ISC_R_SUCCESS); start_node = 0; } /* * node and chain have been set by the code above at * this point. */ for (i = start_node; i < ordered_names_count; i++) { dns_fixedname_t fname_j, fname_i; dns_name_t *name_j, *name_i; dns_test_namefromstring(ordered_names[j], &fname_j); name_j = dns_fixedname_name(&fname_j); dns_test_namefromstring(ordered_names[i], &fname_i); name_i = dns_fixedname_name(&fname_i); if (dns_name_equal(name_i, name_j)) { /* * This may be true for the last node if * we seek ahead in the loop using * dns_rbtnodechain_next() below. */ if (node == NULL) { break; } /* All ordered nodes have data * initially. If any node is empty, it * means it was removed, but an empty * node exists because it is a * super-domain. Just skip it. */ if (node->data == NULL) { result = dns_rbtnodechain_next( &chain, NULL, NULL); if (result == ISC_R_NOMORE) { node = NULL; } else { dns_rbtnodechain_current( &chain, NULL, NULL, &node); } } continue; } assert_non_null(node); n = (size_t *)node->data; if (n != NULL) { /* printf("n=%zu, i=%zu\n", *n, i); */ assert_int_equal(*n, i); } result = dns_rbtnodechain_next(&chain, NULL, NULL); if (result == ISC_R_NOMORE) { node = NULL; } else { dns_rbtnodechain_current(&chain, NULL, NULL, &node); } } /* We should have reached the end of the tree. */ assert_null(node); dns_rbt_destroy(&mytree); } } static void insert_nodes(dns_rbt_t *mytree, char **names, size_t *names_count, uint32_t num_names) { uint32_t i; dns_rbtnode_t *node; for (i = 0; i < num_names; i++) { size_t *n; char namebuf[34]; n = isc_mem_get(dt_mctx, sizeof(size_t)); assert_non_null(n); *n = i; /* Unused value */ while (1) { int j; dns_fixedname_t fname; dns_name_t *name; isc_result_t result; for (j = 0; j < 32; j++) { uint32_t v = isc_random_uniform(26); namebuf[j] = 'a' + v; } namebuf[32] = '.'; namebuf[33] = 0; dns_test_namefromstring(namebuf, &fname); name = dns_fixedname_name(&fname); node = NULL; result = dns_rbt_addnode(mytree, name, &node); if (result == ISC_R_SUCCESS) { node->data = n; names[*names_count] = isc_mem_strdup(dt_mctx, namebuf); assert_non_null(names[*names_count]); *names_count += 1; break; } } } } static void remove_nodes(dns_rbt_t *mytree, char **names, size_t *names_count, uint32_t num_names) { uint32_t i; UNUSED(mytree); for (i = 0; i < num_names; i++) { uint32_t node; dns_fixedname_t fname; dns_name_t *name; isc_result_t result; node = isc_random_uniform(*names_count); dns_test_namefromstring(names[node], &fname); name = dns_fixedname_name(&fname); result = dns_rbt_deletename(mytree, name, false); assert_int_equal(result, ISC_R_SUCCESS); isc_mem_free(dt_mctx, names[node]); if (*names_count > 0) { names[node] = names[*names_count - 1]; names[*names_count - 1] = NULL; *names_count -= 1; } } } static void check_tree(dns_rbt_t *mytree, char **names, size_t names_count) { bool tree_ok; UNUSED(names); assert_int_equal(names_count + 1, dns_rbt_nodecount(mytree)); /* * The distance from each node to its sub-tree root must be less * than 2 * log_2(1024). */ assert_true((2 * 10) >= dns__rbt_getheight(mytree)); /* Also check RB tree properties */ tree_ok = dns__rbt_checkproperties(mytree); assert_true(tree_ok); } /* * Test insert and remove in a loop. * * What is the best way to test our red-black tree code? It is * not a good method to test every case handled in the actual * code itself. This is because our approach itself may be * incorrect. * * We test our code at the interface level here by exercising the * tree randomly multiple times, checking that red-black tree * properties are valid, and all the nodes that are supposed to be * in the tree exist and are in order. * * NOTE: These tests are run within a single tree level in the * forest. The number of nodes in the tree level doesn't grow * over 1024. */ static void rbt_insert_and_remove(void **state) { isc_result_t result; dns_rbt_t *mytree = NULL; size_t *n; char *names[1024]; size_t names_count; int i; UNUSED(state); isc_mem_debugging = ISC_MEM_DEBUGRECORD; result = dns_rbt_create(dt_mctx, delete_data, NULL, &mytree); assert_int_equal(result, ISC_R_SUCCESS); n = isc_mem_get(dt_mctx, sizeof(size_t)); assert_non_null(n); result = dns_rbt_addname(mytree, dns_rootname, n); assert_int_equal(result, ISC_R_SUCCESS); memset(names, 0, sizeof(names)); names_count = 0; /* Repeat the insert/remove test some 4096 times */ for (i = 0; i < 4096; i++) { uint32_t num_names; if (names_count < 1024) { num_names = isc_random_uniform(1024 - names_count); num_names++; } else { num_names = 0; } insert_nodes(mytree, names, &names_count, num_names); check_tree(mytree, names, names_count); if (names_count > 0) { num_names = isc_random_uniform(names_count); num_names++; } else { num_names = 0; } remove_nodes(mytree, names, &names_count, num_names); check_tree(mytree, names, names_count); } /* Remove the rest of the nodes */ remove_nodes(mytree, names, &names_count, names_count); check_tree(mytree, names, names_count); for (i = 0; i < 1024; i++) { if (names[i] != NULL) { isc_mem_free(dt_mctx, names[i]); } } result = dns_rbt_deletename(mytree, dns_rootname, false); assert_int_equal(result, ISC_R_SUCCESS); assert_int_equal(dns_rbt_nodecount(mytree), 0); dns_rbt_destroy(&mytree); } /* Test findname return values */ static void rbt_findname(void **state) { isc_result_t result; test_context_t *ctx = NULL; dns_fixedname_t fname, found; dns_name_t *name = NULL, *foundname = NULL; size_t *n = NULL; UNUSED(state); isc_mem_debugging = ISC_MEM_DEBUGRECORD; ctx = test_context_setup(); /* Try to find a name that exists. */ dns_test_namefromstring("d.e.f", &fname); name = dns_fixedname_name(&fname); foundname = dns_fixedname_initname(&found); result = dns_rbt_findname(ctx->rbt, name, DNS_RBTFIND_EMPTYDATA, foundname, (void *)&n); assert_true(dns_name_equal(foundname, name)); assert_int_equal(result, ISC_R_SUCCESS); /* Now without EMPTYDATA */ result = dns_rbt_findname(ctx->rbt, name, 0, foundname, (void *)&n); assert_int_equal(result, ISC_R_NOTFOUND); /* Now one that partially matches */ dns_test_namefromstring("d.e.f.g.h.i.j", &fname); name = dns_fixedname_name(&fname); result = dns_rbt_findname(ctx->rbt, name, DNS_RBTFIND_EMPTYDATA, foundname, (void *)&n); assert_int_equal(result, DNS_R_PARTIALMATCH); /* Now one that doesn't match */ dns_test_namefromstring("1.2", &fname); name = dns_fixedname_name(&fname); result = dns_rbt_findname(ctx->rbt, name, DNS_RBTFIND_EMPTYDATA, foundname, (void *)&n); assert_int_equal(result, DNS_R_PARTIALMATCH); assert_true(dns_name_equal(foundname, dns_rootname)); test_context_teardown(ctx); } /* Test addname return values */ static void rbt_addname(void **state) { isc_result_t result; test_context_t *ctx = NULL; dns_fixedname_t fname; dns_name_t *name = NULL; size_t *n; UNUSED(state); isc_mem_debugging = ISC_MEM_DEBUGRECORD; ctx = test_context_setup(); n = isc_mem_get(dt_mctx, sizeof(size_t)); assert_non_null(n); *n = 1; dns_test_namefromstring("d.e.f.g.h.i.j.k", &fname); name = dns_fixedname_name(&fname); /* Add a name that doesn't exist */ result = dns_rbt_addname(ctx->rbt, name, n); assert_int_equal(result, ISC_R_SUCCESS); /* Now add again, should get ISC_R_EXISTS */ n = isc_mem_get(dt_mctx, sizeof(size_t)); assert_non_null(n); *n = 2; result = dns_rbt_addname(ctx->rbt, name, n); assert_int_equal(result, ISC_R_EXISTS); isc_mem_put(dt_mctx, n, sizeof(size_t)); test_context_teardown(ctx); } /* Test deletename return values */ static void rbt_deletename(void **state) { isc_result_t result; test_context_t *ctx = NULL; dns_fixedname_t fname; dns_name_t *name = NULL; UNUSED(state); isc_mem_debugging = ISC_MEM_DEBUGRECORD; ctx = test_context_setup(); /* Delete a name that doesn't exist */ dns_test_namefromstring("z.x.y.w", &fname); name = dns_fixedname_name(&fname); result = dns_rbt_deletename(ctx->rbt, name, false); assert_int_equal(result, ISC_R_NOTFOUND); /* Now one that does */ dns_test_namefromstring("d.e.f", &fname); name = dns_fixedname_name(&fname); result = dns_rbt_deletename(ctx->rbt, name, false); assert_int_equal(result, ISC_R_NOTFOUND); test_context_teardown(ctx); } /* Test nodechain */ static void rbt_nodechain(void **state) { isc_result_t result; test_context_t *ctx; dns_fixedname_t fname, found, expect; dns_name_t *name, *foundname, *expected; dns_rbtnode_t *node = NULL; dns_rbtnodechain_t chain; UNUSED(state); isc_mem_debugging = ISC_MEM_DEBUGRECORD; ctx = test_context_setup(); dns_rbtnodechain_init(&chain); dns_test_namefromstring("a", &fname); name = dns_fixedname_name(&fname); result = dns_rbt_findnode(ctx->rbt, name, NULL, &node, &chain, 0, NULL, NULL); assert_int_equal(result, ISC_R_SUCCESS); foundname = dns_fixedname_initname(&found); dns_test_namefromstring("a", &expect); expected = dns_fixedname_name(&expect); UNUSED(expected); result = dns_rbtnodechain_first(&chain, ctx->rbt, foundname, NULL); assert_int_equal(result, DNS_R_NEWORIGIN); assert_int_equal(dns_name_countlabels(foundname), 0); result = dns_rbtnodechain_prev(&chain, NULL, NULL); assert_int_equal(result, ISC_R_NOMORE); result = dns_rbtnodechain_next(&chain, NULL, NULL); assert_int_equal(result, ISC_R_SUCCESS); result = dns_rbtnodechain_next(&chain, NULL, NULL); assert_int_equal(result, ISC_R_SUCCESS); result = dns_rbtnodechain_last(&chain, ctx->rbt, NULL, NULL); assert_int_equal(result, DNS_R_NEWORIGIN); result = dns_rbtnodechain_next(&chain, NULL, NULL); assert_int_equal(result, ISC_R_NOMORE); result = dns_rbtnodechain_last(&chain, ctx->rbt, NULL, NULL); assert_int_equal(result, DNS_R_NEWORIGIN); result = dns_rbtnodechain_prev(&chain, NULL, NULL); assert_int_equal(result, ISC_R_SUCCESS); dns_rbtnodechain_invalidate(&chain); test_context_teardown(ctx); } /* Test addname return values */ static void rbtnode_namelen(void **state) { isc_result_t result; test_context_t *ctx = NULL; dns_rbtnode_t *node; unsigned int len; UNUSED(state); isc_mem_debugging = ISC_MEM_DEBUGRECORD; ctx = test_context_setup(); node = NULL; result = insert_helper(ctx->rbt, ".", &node); len = dns__rbtnode_namelen(node); assert_int_equal(result, ISC_R_EXISTS); assert_int_equal(len, 1); node = NULL; result = insert_helper(ctx->rbt, "a.b.c.d.e.f.g.h.i.j.k.l.m", &node); len = dns__rbtnode_namelen(node); assert_int_equal(result, ISC_R_SUCCESS); assert_int_equal(len, 27); node = NULL; result = insert_helper(ctx->rbt, "isc.org", &node); len = dns__rbtnode_namelen(node); assert_int_equal(result, ISC_R_SUCCESS); assert_int_equal(len, 9); node = NULL; result = insert_helper(ctx->rbt, "example.com", &node); len = dns__rbtnode_namelen(node); assert_int_equal(result, ISC_R_SUCCESS); assert_int_equal(len, 13); test_context_teardown(ctx); } #if defined(DNS_BENCHMARK_TESTS) && !defined(__SANITIZE_THREAD__) /* * XXXMUKS: Don't delete this code. It is useful in benchmarking the * RBT, but we don't require it as part of the unit test runs. */ static dns_fixedname_t *fnames; static dns_name_t **names; static int *values; static void * find_thread(void *arg) { dns_rbt_t *mytree; isc_result_t result; dns_rbtnode_t *node; unsigned int j, i; unsigned int start = 0; mytree = (dns_rbt_t *)arg; while (start == 0) { start = random() % 4000000; } /* Query 32 million random names from it in each thread */ for (j = 0; j < 8; j++) { for (i = start; i != start - 1; i = (i + 1) % 4000000) { node = NULL; result = dns_rbt_findnode(mytree, names[i], NULL, &node, NULL, DNS_RBTFIND_EMPTYDATA, NULL, NULL); assert_int_equal(result, ISC_R_SUCCESS); assert_non_null(node); assert_int_equal(values[i], (intptr_t)node->data); } } return (NULL); } /* Benchmark RBT implementation */ static void benchmark(void **state) { isc_result_t result; char namestr[sizeof("name18446744073709551616.example.org.")]; unsigned int r; dns_rbt_t *mytree; dns_rbtnode_t *node; unsigned int i; unsigned int maxvalue = 1000000; isc_time_t ts1, ts2; double t; unsigned int nthreads; isc_thread_t threads[32]; UNUSED(state); srandom(time(NULL)); debug_mem_record = false; fnames = (dns_fixedname_t *)malloc(4000000 * sizeof(dns_fixedname_t)); names = (dns_name_t **)malloc(4000000 * sizeof(dns_name_t *)); values = (int *)malloc(4000000 * sizeof(int)); for (i = 0; i < 4000000; i++) { r = ((unsigned long)random()) % maxvalue; snprintf(namestr, sizeof(namestr), "name%u.example.org.", r); dns_test_namefromstring(namestr, &fnames[i]); names[i] = dns_fixedname_name(&fnames[i]); values[i] = r; } /* Create a tree. */ mytree = NULL; result = dns_rbt_create(dt_mctx, NULL, NULL, &mytree); assert_int_equal(result, ISC_R_SUCCESS); /* Insert test data into the tree. */ for (i = 0; i < maxvalue; i++) { snprintf(namestr, sizeof(namestr), "name%u.example.org.", i); node = NULL; result = insert_helper(mytree, namestr, &node); assert_int_equal(result, ISC_R_SUCCESS); node->data = (void *)(intptr_t)i; } result = isc_time_now(&ts1); assert_int_equal(result, ISC_R_SUCCESS); nthreads = ISC_MIN(isc_os_ncpus(), 32); nthreads = ISC_MAX(nthreads, 1); for (i = 0; i < nthreads; i++) { isc_thread_create(find_thread, mytree, &threads[i]); } for (i = 0; i < nthreads; i++) { isc_thread_join(threads[i], NULL); } result = isc_time_now(&ts2); assert_int_equal(result, ISC_R_SUCCESS); t = isc_time_microdiff(&ts2, &ts1); printf("%u findnode calls, %f seconds, %f calls/second\n", nthreads * 8 * 4000000, t / 1000000.0, (nthreads * 8 * 4000000) / (t / 1000000.0)); free(values); free(names); free(fnames); dns_rbt_destroy(&mytree); } #endif /* defined(DNS_BENCHMARK_TESTS) && !defined(__SANITIZE_THREAD__) */ int main(void) { const struct CMUnitTest tests[] = { cmocka_unit_test_setup_teardown(rbt_create, _setup, _teardown), cmocka_unit_test_setup_teardown(rbt_nodecount, _setup, _teardown), cmocka_unit_test_setup_teardown(rbtnode_get_distance, _setup, _teardown), cmocka_unit_test_setup_teardown(rbt_check_distance_random, _setup, _teardown), cmocka_unit_test_setup_teardown(rbt_check_distance_ordered, _setup, _teardown), cmocka_unit_test_setup_teardown(rbt_insert, _setup, _teardown), cmocka_unit_test_setup_teardown(rbt_remove, _setup, _teardown), cmocka_unit_test_setup_teardown(rbt_insert_and_remove, _setup, _teardown), cmocka_unit_test_setup_teardown(rbt_findname, _setup, _teardown), cmocka_unit_test_setup_teardown(rbt_addname, _setup, _teardown), cmocka_unit_test_setup_teardown(rbt_deletename, _setup, _teardown), cmocka_unit_test_setup_teardown(rbt_nodechain, _setup, _teardown), cmocka_unit_test_setup_teardown(rbtnode_namelen, _setup, _teardown), #if defined(DNS_BENCHMARK_TESTS) && !defined(__SANITIZE_THREAD__) cmocka_unit_test_setup_teardown(benchmark, _setup, _teardown), #endif /* defined(DNS_BENCHMARK_TESTS) && !defined(__SANITIZE_THREAD__) */ }; return (cmocka_run_group_tests(tests, NULL, NULL)); } #else /* HAVE_CMOCKA */ #include int main(void) { printf("1..0 # Skipped: cmocka not available\n"); return (SKIPPED_TEST_EXIT_CODE); } #endif /* if HAVE_CMOCKA */