/** * @file test_xpath.c * @author: Michal Vasko * @brief unit tests for XPath evaluation * * Copyright (c) 2020 CESNET, z.s.p.o. * * This source code is licensed under BSD 3-Clause License (the "License"). * You may not use this file except in compliance with the License. * You may obtain a copy of the License at * * https://opensource.org/licenses/BSD-3-Clause */ #define _UTEST_MAIN_ #include "utests.h" #include #include "context.h" #include "parser_data.h" #include "set.h" #include "tests_config.h" #include "tree_data.h" #include "tree_schema.h" const char *schema_a = "module a {\n" " namespace urn:tests:a;\n" " prefix a;\n" " yang-version 1.1;\n" "\n" " identity id_a;\n" " identity id_b {\n" " base id_a;\n" " }\n" " identity id_c {\n" " base id_b;\n" " }\n" "\n" " list l1 {\n" " key \"a b\";\n" " leaf a {\n" " type string;\n" " }\n" " leaf b {\n" " type string;\n" " }\n" " leaf c {\n" " type string;\n" " }\n" " }\n" " leaf foo {\n" " type string;\n" " }\n" " leaf foo2 {\n" " type uint8;\n" " }\n" " leaf foo3 {\n" " type identityref {\n" " base id_a;\n" " }\n" " }\n" " leaf foo4 {\n" " type decimal64 {\n" " fraction-digits 5;\n" " }\n" " }\n" " container c {\n" " leaf x {\n" " type string;\n" " }\n" " list ll {\n" " key \"a\";\n" " leaf a {\n" " type string;\n" " }\n" " list ll {\n" " key \"a\";\n" " leaf a {\n" " type string;\n" " }\n" " leaf b {\n" " type string;\n" " }\n" " }\n" " }\n" " leaf-list ll2 {\n" " type string;\n" " }\n" " }\n" "\n" " rpc r {\n" " input {\n" " leaf l {\n" " type string;\n" " }\n" " }\n" " output {\n" " leaf l {\n" " type string;\n" " }\n" " }\n" " }\n" "}"; static int setup(void **state) { UTEST_SETUP; UTEST_ADD_MODULE(schema_a, LYS_IN_YANG, NULL, NULL); lys_parse_path(UTEST_LYCTX, TESTS_DIR_MODULES_YANG "/ietf-interfaces@2014-05-08.yang", LYS_IN_YANG, NULL); return 0; } static void test_predicate(void **state) { const char *data; struct lyd_node *tree; struct ly_set *set; data = "50" "" " a1" " b1" " c1" "" "" " a2" " b2" "" "" " a3" " b3" "" "" " a4" " b4" " c4" "" "" " a5" " b5" " c5" "" "" " key2" " " " key1" " " " key11" " val11" " " " " " key12" " val12" " " " " " key13" " val13" " " " " " " " key2" " " " key21" " val21" " " " " " key22" " val22" " " " " " " " key3" " " " key31" " val31" " " " " " key32" " val32" " " " " ""; assert_int_equal(LY_SUCCESS, lyd_parse_data_mem(UTEST_LYCTX, data, LYD_XML, LYD_PARSE_STRICT, LYD_VALIDATE_PRESENT, &tree)); assert_non_null(tree); /* predicate after number */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/foo2[4[3 = 3]]", &set)); assert_int_equal(0, set->count); ly_set_free(set, NULL); /* reverse axis */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/c/child::ll[2]/preceding::ll[3]", &set)); assert_int_equal(1, set->count); assert_string_equal("key11", lyd_get_value(lyd_child(set->dnodes[0]))); ly_set_free(set, NULL); /* special predicate evaluated using hashes */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/a:l1[a=concat('a', '1')][b=substring('ab1',2)]", &set)); assert_int_equal(1, set->count); ly_set_free(set, NULL); assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/a:c/ll[a=../x]", &set)); assert_int_equal(1, set->count); ly_set_free(set, NULL); /* cannot use hashes */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/a:c/ll[a=substring(ll/a,1,4)]", &set)); assert_int_equal(3, set->count); ly_set_free(set, NULL); /* nested predicate */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/a:c/a:ll[a:a=string(/a:l1[a:a='foo']/a:a)]/a:a", &set)); assert_int_equal(0, set->count); ly_set_free(set, NULL); lyd_free_all(tree); } static void test_union(void **state) { const char *data; struct lyd_node *tree; struct ly_set *set; data = "\n" " a1\n" " b1\n" " c1\n" "\n" "\n" " a2\n" " b2\n" "" "\n" " a3\n" " b3\n" " c3\n" ""; assert_int_equal(LY_SUCCESS, lyd_parse_data_mem(UTEST_LYCTX, data, LYD_XML, LYD_PARSE_STRICT, LYD_VALIDATE_PRESENT, &tree)); assert_non_null(tree); /* Predicate for operand. */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/l1[c[../a = 'a1'] | c]/a", &set)); ly_set_free(set, NULL); lyd_free_all(tree); } static void test_invalid(void **state) { const char *data = "50"; struct lyd_node *tree; struct ly_set *set; assert_int_equal(LY_SUCCESS, lyd_parse_data_mem(UTEST_LYCTX, data, LYD_XML, LYD_PARSE_STRICT, LYD_VALIDATE_PRESENT, &tree)); assert_non_null(tree); assert_int_equal(LY_EVALID, lyd_find_xpath(tree, "/a:foo2[.=]", &set)); assert_null(set); CHECK_LOG_CTX("Unexpected XPath token \"]\" (\"]\").", NULL); assert_int_equal(LY_EVALID, lyd_find_xpath(tree, "/a:", &set)); assert_null(set); CHECK_LOG_CTX("Invalid character 'a'[2] of expression '/a:'.", NULL); lyd_free_all(tree); } static void test_hash(void **state) { const char *data = "\n" " a1\n" " b1\n" " c1\n" "\n" "\n" " a2\n" " b2\n" "\n" "\n" " a3\n" " b3\n" " c3\n" "\n" "foo value\n" "\n" " val\n" " \n" " val_a\n" " \n" " val_a\n" " val\n" " \n" " \n" " val_b\n" " \n" " \n" " \n" " val_b\n" " \n" " val_a\n" " \n" " \n" " val_b\n" " val\n" " \n" " \n" " \n" " val_c\n" " \n" " val_a\n" " \n" " \n" " val_b\n" " \n" " \n" " one\n" " two\n" " three\n" " four\n" ""; struct lyd_node *tree, *node; struct ly_set *set; assert_int_equal(LY_SUCCESS, lyd_parse_data_mem(UTEST_LYCTX, data, LYD_XML, LYD_PARSE_STRICT, LYD_VALIDATE_PRESENT, &tree)); assert_non_null(tree); /* top-level, so hash table is not ultimately used but instances can be compared based on hashes */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/a:l1[a='a3'][b='b3']", &set)); assert_int_equal(1, set->count); node = set->objs[0]; assert_string_equal(node->schema->name, "l1"); node = lyd_child(node); assert_string_equal(node->schema->name, "a"); assert_string_equal(lyd_get_value(node), "a3"); ly_set_free(set, NULL); /* hashes should be used for both searches (well, there are not enough nested ll instances, so technically not true) */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/a:c/ll[a='val_b']/ll[a='val_b']", &set)); assert_int_equal(1, set->count); node = set->objs[0]; assert_string_equal(node->schema->name, "ll"); node = lyd_child(node); assert_string_equal(node->schema->name, "a"); assert_string_equal(lyd_get_value(node), "val_b"); node = node->next; assert_string_equal(node->schema->name, "b"); assert_null(node->next); ly_set_free(set, NULL); /* hashes are not used */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/a:c//ll[a='val_b']", &set)); assert_int_equal(4, set->count); ly_set_free(set, NULL); /* hashes used even for leaf-lists */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/a:c/ll2[. = 'three']", &set)); assert_int_equal(1, set->count); node = set->objs[0]; assert_string_equal(node->schema->name, "ll2"); assert_string_equal(lyd_get_value(node), "three"); ly_set_free(set, NULL); /* not found using hashes */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/a:c/ll[a='val_d']", &set)); assert_int_equal(0, set->count); ly_set_free(set, NULL); /* white-spaces are also ok */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/a:c/ll[ \na = 'val_c' ]", &set)); assert_int_equal(1, set->count); ly_set_free(set, NULL); lyd_free_all(tree); } static void test_rpc(void **state) { const char *data = "\n" " val\n" ""; struct ly_in *in; struct lyd_node *tree; struct ly_set *set; assert_int_equal(LY_SUCCESS, ly_in_new_memory(data, &in)); assert_int_equal(LY_SUCCESS, lyd_parse_op(UTEST_LYCTX, NULL, in, LYD_XML, LYD_TYPE_REPLY_YANG, &tree, NULL)); ly_in_free(in, 0); assert_non_null(tree); /* name collision input/output, hashes are not used */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/a:r/l", &set)); assert_int_equal(1, set->count); ly_set_free(set, NULL); lyd_free_all(tree); } static void test_toplevel(void **state) { const char *schema_b = "module b {\n" " namespace urn:tests:b;\n" " prefix b;\n" " yang-version 1.1;\n" "\n" " list l2 {\n" " key \"a\";\n" " leaf a {\n" " type uint16;\n" " }\n" " leaf b {\n" " type uint16;\n" " }\n" " }\n" "}"; const char *data = "\n" " a1\n" " b1\n" " c1\n" "\n" "\n" " a2\n" " b2\n" "\n" "\n" " a3\n" " b3\n" " c3\n" "\n" "foo value\n" "\n" " 1\n" " 1\n" "\n" "\n" " 2\n" " 1\n" "\n" "\n" " 3\n" " 1\n" ""; struct lyd_node *tree; struct ly_set *set; UTEST_ADD_MODULE(schema_b, LYS_IN_YANG, NULL, NULL); assert_int_equal(LY_SUCCESS, lyd_parse_data_mem(UTEST_LYCTX, data, LYD_XML, LYD_PARSE_STRICT, LYD_VALIDATE_PRESENT, &tree)); assert_non_null(tree); /* all top-level nodes from one module (default container as well) */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/a:*", &set)); assert_int_equal(5, set->count); ly_set_free(set, NULL); /* all top-level nodes from all modules */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/*", &set)); assert_int_equal(8, set->count); ly_set_free(set, NULL); /* all nodes from one module */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "//a:*", &set)); assert_int_equal(13, set->count); ly_set_free(set, NULL); /* all nodes from all modules */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "//*", &set)); assert_int_equal(22, set->count); ly_set_free(set, NULL); /* all nodes from all modules #2 */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "//.", &set)); assert_int_equal(22, set->count); ly_set_free(set, NULL); lyd_free_all(tree); } static void test_atomize(void **state) { struct ly_set *set; const struct lys_module *mod; mod = ly_ctx_get_module_latest(UTEST_LYCTX, "a"); assert_non_null(mod); /* some random paths just making sure the API function works */ assert_int_equal(LY_SUCCESS, lys_find_xpath_atoms(UTEST_LYCTX, NULL, "/a:*", 0, &set)); assert_int_equal(7, set->count); ly_set_free(set, NULL); /* all nodes from all modules (including internal, which can change easily, so check just the test modules) */ assert_int_equal(LY_SUCCESS, lys_find_xpath_atoms(UTEST_LYCTX, NULL, "//.", 0, &set)); assert_in_range(set->count, 17, UINT32_MAX); ly_set_free(set, NULL); assert_int_equal(LY_SUCCESS, lys_find_xpath_atoms(UTEST_LYCTX, NULL, "/a:c/ll[a='val1']/ll[a='val2']/b", 0, &set)); assert_int_equal(6, set->count); ly_set_free(set, NULL); assert_int_equal(LY_SUCCESS, lys_find_xpath_atoms(UTEST_LYCTX, NULL, "/ietf-interfaces:interfaces/*", 0, &set)); assert_int_equal(2, set->count); ly_set_free(set, NULL); assert_int_equal(LY_SUCCESS, lys_find_xpath_atoms(UTEST_LYCTX, NULL, "/*", 0, &set)); assert_int_equal(14, set->count); ly_set_free(set, NULL); /* * axes */ /* ancestor */ assert_int_equal(LY_SUCCESS, lys_find_xpath_atoms(UTEST_LYCTX, NULL, "//ll[a and b]/a/ancestor::node()", 0, &set)); assert_int_equal(6, set->count); ly_set_free(set, NULL); /* ancestor-or-self */ assert_int_equal(LY_SUCCESS, lys_find_xpath_atoms(UTEST_LYCTX, NULL, "//ll[a and b]/ancestor-or-self::ll", 0, &set)); assert_int_equal(5, set->count); ly_set_free(set, NULL); /* attribute */ assert_int_equal(LY_SUCCESS, lys_find_xpath_atoms(UTEST_LYCTX, NULL, "/l1/attribute::key", 0, &set)); assert_int_equal(1, set->count); ly_set_free(set, NULL); /* child */ assert_int_equal(LY_SUCCESS, lys_find_xpath_atoms(UTEST_LYCTX, NULL, "/child::l1/child::a", 0, &set)); assert_int_equal(2, set->count); ly_set_free(set, NULL); /* descendant */ assert_int_equal(LY_SUCCESS, lys_find_xpath_atoms(UTEST_LYCTX, NULL, "/descendant::c/descendant::b", 0, &set)); assert_int_equal(3, set->count); ly_set_free(set, NULL); /* descendant-or-self */ assert_int_equal(LY_SUCCESS, lys_find_xpath_atoms(UTEST_LYCTX, NULL, "/a:*/descendant-or-self::c", 0, &set)); assert_int_equal(8, set->count); ly_set_free(set, NULL); /* following */ assert_int_equal(LY_SUCCESS, lys_find_xpath_atoms(UTEST_LYCTX, NULL, "/c/x/following::a", 0, &set)); assert_int_equal(4, set->count); ly_set_free(set, NULL); /* following-sibling */ assert_int_equal(LY_SUCCESS, lys_find_xpath_atoms(UTEST_LYCTX, NULL, "/c/x/following-sibling::ll", 0, &set)); assert_int_equal(3, set->count); ly_set_free(set, NULL); /* parent */ assert_int_equal(LY_SUCCESS, lys_find_xpath_atoms(UTEST_LYCTX, NULL, "/child::a:*/c/parent::l1", 0, &set)); assert_int_equal(8, set->count); ly_set_free(set, NULL); assert_int_equal(LY_SUCCESS, lys_find_xpath_atoms(UTEST_LYCTX, NULL, "/child::a:c//..", 0, &set)); assert_int_equal(11, set->count); ly_set_free(set, NULL); /* preceding */ assert_int_equal(LY_SUCCESS, lys_find_xpath_atoms(UTEST_LYCTX, NULL, "/c/preceding::a", 0, &set)); assert_int_equal(2, set->count); ly_set_free(set, NULL); /* preceding-sibling */ assert_int_equal(LY_SUCCESS, lys_find_xpath_atoms(UTEST_LYCTX, NULL, "/c/ll/preceding-sibling::node()", 0, &set)); assert_int_equal(3, set->count); ly_set_free(set, NULL); /* self */ assert_int_equal(LY_SUCCESS, lys_find_xpath_atoms(UTEST_LYCTX, NULL, "/c/self::c/ll/ll/b/self::b", 0, &set)); assert_int_equal(4, set->count); ly_set_free(set, NULL); } static void test_canonize(void **state) { const char *data = "50" "a:id_b" "250.5"; struct lyd_node *tree; struct ly_set *set; assert_int_equal(LY_SUCCESS, lyd_parse_data_mem(UTEST_LYCTX, data, LYD_XML, LYD_PARSE_STRICT, LYD_VALIDATE_PRESENT, &tree)); assert_non_null(tree); /* integer */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/a:foo2[.='050']", &set)); assert_int_equal(1, set->count); ly_set_free(set, NULL); /* identityref */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/a:foo3[.='id_b']", &set)); assert_int_equal(1, set->count); ly_set_free(set, NULL); /* decimal64 */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/a:foo4[.='0250.500']", &set)); assert_int_equal(1, set->count); ly_set_free(set, NULL); lyd_free_all(tree); } static void test_derived_from(void **state) { const char *data = "id_c"; struct lyd_node *tree; struct ly_set *set; assert_int_equal(LY_SUCCESS, lyd_parse_data_mem(UTEST_LYCTX, data, LYD_XML, LYD_PARSE_STRICT, LYD_VALIDATE_PRESENT, &tree)); assert_non_null(tree); assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/a:foo3[derived-from(., 'a:id_b')]", &set)); assert_int_equal(1, set->count); ly_set_free(set, NULL); assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/a:foo3[derived-from(., 'a:id_a')]", &set)); assert_int_equal(1, set->count); ly_set_free(set, NULL); lyd_free_all(tree); } static void test_augment(void **state) { const char *schema_b = "module b {\n" " namespace urn:tests:b;\n" " prefix b;\n" " yang-version 1.1;\n" "\n" " import a {\n" " prefix a;\n" " }\n" "\n" " augment /a:c {\n" " leaf a {\n" " type uint16;\n" " }\n" " }\n" "}"; const char *data = "\n" " value\n" " \n" " key\n" " \n" " 25\n" " c1\n" ""; struct lyd_node *tree; struct ly_set *set; UTEST_ADD_MODULE(schema_b, LYS_IN_YANG, NULL, NULL); assert_int_equal(LY_SUCCESS, lyd_parse_data_mem(UTEST_LYCTX, data, LYD_XML, LYD_PARSE_STRICT, LYD_VALIDATE_PRESENT, &tree)); assert_non_null(tree); /* get all children ignoring their module */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/a:c/*", &set)); assert_int_equal(4, set->count); ly_set_free(set, NULL); lyd_free_all(tree); } static void test_variables(void **state) { struct lyd_node *tree, *node; struct ly_set *set; const char *data; struct lyxp_var *vars = NULL; #define LOCAL_SETUP(DATA, TREE) \ assert_int_equal(LY_SUCCESS, lyd_parse_data_mem(UTEST_LYCTX, DATA, LYD_XML, LYD_PARSE_STRICT, LYD_VALIDATE_PRESENT, &TREE)); \ assert_non_null(TREE); #define SET_NODE(NODE, SET, INDEX) \ assert_non_null(SET); \ assert_true(INDEX < SET->count); \ NODE = SET->objs[INDEX]; #define LOCAL_TEARDOWN(SET, TREE, VARS) \ ly_set_free(SET, NULL); \ lyd_free_all(TREE); \ lyxp_vars_free(VARS); \ vars = NULL; /* Eval variable to number. */ data = "\n" " a1\n" " b1\n" " c1\n" "" "\n" " a2\n" " b2\n" " c2\n" ""; LOCAL_SETUP(data, tree); assert_int_equal(LY_SUCCESS, lyxp_vars_set(&vars, "var", "2")); assert_int_equal(LY_SUCCESS, lyd_find_xpath2(tree, "/l1[$var]/a", vars, &set)); SET_NODE(node, set, 0); assert_string_equal(lyd_get_value(node), "a2"); LOCAL_TEARDOWN(set, tree, vars); /* Eval variable to string. */ data = "mstr"; LOCAL_SETUP(data, tree); assert_int_equal(LY_SUCCESS, lyxp_vars_set(&vars, "var", "\"mstr\"")); assert_int_equal(LY_SUCCESS, lyd_find_xpath2(tree, "/foo[text() = $var]", vars, &set)); SET_NODE(node, set, 0); assert_string_equal(lyd_get_value(node), "mstr"); LOCAL_TEARDOWN(set, tree, vars); /* Eval variable to set of nodes. */ data = "\n" " a1\n" " b1\n" "" "\n" " a2\n" " b2\n" " c2\n" ""; LOCAL_SETUP(data, tree); assert_int_equal(LY_SUCCESS, lyxp_vars_set(&vars, "var", "c")); assert_int_equal(LY_SUCCESS, lyd_find_xpath2(tree, "/l1[$var]/a", vars, &set)); SET_NODE(node, set, 0); assert_string_equal(lyd_get_value(node), "a2"); LOCAL_TEARDOWN(set, tree, vars); /* Variable in union expr. */ data = "\n" " a1\n" " b1\n" " c1\n" "" "\n" " a2\n" " b2\n" " c2\n" "" "\n" " a3\n" " b3\n" " c3\n" ""; LOCAL_SETUP(data, tree); assert_int_equal(LY_SUCCESS, lyxp_vars_set(&vars, "var", "c[../a = 'a3']")); assert_int_equal(LY_SUCCESS, lyd_find_xpath2(tree, "/l1[c[../a = 'a1'] | $var]/a", vars, &set)); SET_NODE(node, set, 0); assert_string_equal(lyd_get_value(node), "a1"); SET_NODE(node, set, 1); assert_string_equal(lyd_get_value(node), "a3"); assert_int_equal(set->count, 2); LOCAL_TEARDOWN(set, tree, vars); /* Predicate after variable. */ data = "\n" " a1\n" " b1\n" " c1\n" "" "\n" " a2\n" " b2\n" " c2\n" ""; LOCAL_SETUP(data, tree); assert_int_equal(LY_SUCCESS, lyxp_vars_set(&vars, "var", "c")); assert_int_equal(LY_SUCCESS, lyd_find_xpath2(tree, "/l1[$var[../a = 'a1']]/a", vars, &set)); SET_NODE(node, set, 0); assert_string_equal(lyd_get_value(node), "a1"); LOCAL_TEARDOWN(set, tree, vars); /* Variable in variable. */ data = "mstr"; LOCAL_SETUP(data, tree); assert_int_equal(LY_SUCCESS, lyxp_vars_set(&vars, "var1", "$var2")); assert_int_equal(LY_SUCCESS, lyxp_vars_set(&vars, "var2", "\"mstr\"")); assert_int_equal(LY_SUCCESS, lyd_find_xpath2(tree, "/foo[text() = $var]", vars, &set)); SET_NODE(node, set, 0); assert_string_equal(lyd_get_value(node), "mstr"); LOCAL_TEARDOWN(set, tree, vars); /* Compare two variables. */ data = "mstr"; LOCAL_SETUP(data, tree); assert_int_equal(LY_SUCCESS, lyxp_vars_set(&vars, "var1", "\"str\"")); assert_int_equal(LY_SUCCESS, lyxp_vars_set(&vars, "var2", "\"str\"")); assert_int_equal(LY_SUCCESS, lyd_find_xpath2(tree, "/foo[$var1 = $var2]", vars, &set)); SET_NODE(node, set, 0); assert_string_equal(lyd_get_value(node), "mstr"); LOCAL_TEARDOWN(set, tree, vars); /* Arithmetic operation with variable. */ data = "4"; LOCAL_SETUP(data, tree); assert_int_equal(LY_SUCCESS, lyxp_vars_set(&vars, "var1", "2")); assert_int_equal(LY_SUCCESS, lyd_find_xpath2(tree, "/foo2[.= ($var1 * 2)]", vars, &set)); SET_NODE(node, set, 0); assert_string_equal(lyd_get_value(node), "4"); LOCAL_TEARDOWN(set, tree, vars); /* Variable as function parameter. */ data = "\n" " a1\n" " b1\n" " c1\n" "" "\n" " a2\n" " b2\n" ""; LOCAL_SETUP(data, tree); assert_int_equal(LY_SUCCESS, lyxp_vars_set(&vars, "var", "./c")); assert_int_equal(LY_SUCCESS, lyd_find_xpath2(tree, "/l1[count($var) = 1]/a", vars, &set)); SET_NODE(node, set, 0); assert_string_equal(lyd_get_value(node), "a1"); LOCAL_TEARDOWN(set, tree, vars); /* Variable in path expr. */ /* NOTE: The variable can only be at the beginning of the expression path. */ data = "\n" " a1\n" " b1\n" " c1\n" "" "\n" " a2\n" " b2\n" ""; LOCAL_SETUP(data, tree); assert_int_equal(LY_SUCCESS, lyxp_vars_set(&vars, "var", "/l1")); assert_int_equal(LY_SUCCESS, lyd_find_xpath2(tree, "/l1[$var/a]", vars, &set)); assert_int_equal(set->count, 2); LOCAL_TEARDOWN(set, tree, vars); /* Variable as function. */ data = "\n" " a1\n" " b1\n" " c1\n" "" "\n" " a2\n" " b2\n" ""; LOCAL_SETUP(data, tree); assert_int_equal(LY_SUCCESS, lyxp_vars_set(&vars, "var", "position()")); assert_int_equal(LY_SUCCESS, lyd_find_xpath2(tree, "/l1[$var = 2]/a", vars, &set)); SET_NODE(node, set, 0); assert_string_equal(lyd_get_value(node), "a2"); LOCAL_TEARDOWN(set, tree, vars); /* Dynamic change of value. */ data = "\n" " a1\n" " b1\n" " c1\n" "" "\n" " a2\n" " b2\n" " c2\n" ""; LOCAL_SETUP(data, tree); assert_int_equal(LY_SUCCESS, lyxp_vars_set(&vars, "var", "1")); assert_int_equal(LY_SUCCESS, lyd_find_xpath2(tree, "/l1[$var]/a", vars, &set)); SET_NODE(node, set, 0); assert_string_equal(lyd_get_value(node), "a1"); ly_set_free(set, NULL); assert_int_equal(LY_SUCCESS, lyxp_vars_set(&vars, "var", "2")); assert_int_equal(LY_SUCCESS, lyd_find_xpath2(tree, "/l1[$var]/a", vars, &set)); SET_NODE(node, set, 0); assert_string_equal(lyd_get_value(node), "a2"); LOCAL_TEARDOWN(set, tree, vars); /* Variable not defined. */ data = "mstr"; LOCAL_SETUP(data, tree); assert_int_equal(LY_SUCCESS, lyxp_vars_set(&vars, "var1", "\"mstr\"")); assert_int_equal(LY_ENOTFOUND, lyd_find_xpath2(tree, "/foo[text() = $var55]", vars, &set)); CHECK_LOG_CTX("Variable \"var55\" not defined.", NULL); LOCAL_TEARDOWN(set, tree, vars); /* Syntax error in value. */ data = "mstr"; LOCAL_SETUP(data, tree); assert_int_equal(LY_SUCCESS, lyxp_vars_set(&vars, "var", "\"")); assert_int_equal(LY_EVALID, lyd_find_xpath2(tree, "/foo[$var]", vars, &set)); CHECK_LOG_CTX("Unterminated string delimited with \" (\").", "Data location \"/a:foo\"."); LOCAL_TEARDOWN(set, tree, vars); /* Prefix is not supported. */ data = "mstr"; LOCAL_SETUP(data, tree); assert_int_equal(LY_SUCCESS, lyxp_vars_set(&vars, "var", "\"")); assert_int_equal(LY_EVALID, lyd_find_xpath2(tree, "/foo[$pref:var]", vars, &set)); CHECK_LOG_CTX("Variable with prefix is not supported.", NULL); LOCAL_TEARDOWN(set, tree, vars); #undef LOCAL_SETUP #undef LOCAL_TEARDOWN } static void test_axes(void **state) { const char *data; struct lyd_node *tree; struct ly_set *set; data = "\n" " a1\n" " b1\n" " c1\n" "\n" "\n" " a2\n" " b2\n" "" "\n" " a3\n" " b3\n" " c3\n" "" "" " val" " " " key1" " " " key11" " val11" " " " " " key12" " val12" " " " " " key13" " val13" " " " " " " " key2" " " " key21" " val21" " " " " " key22" " val22" " " " " ""; assert_int_equal(LY_SUCCESS, lyd_parse_data_mem(UTEST_LYCTX, data, LYD_XML, LYD_PARSE_STRICT, LYD_VALIDATE_PRESENT, &tree)); assert_non_null(tree); /* ancestor */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "//ll[a and b]/a/ancestor::node()", &set)); assert_int_equal(8, set->count); ly_set_free(set, NULL); /* ancestor-or-self */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "//ll[a and b]/ancestor-or-self::ll", &set)); assert_int_equal(7, set->count); ly_set_free(set, NULL); /* attribute */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/l1/@operation", &set)); assert_int_equal(0, set->count); ly_set_free(set, NULL); assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/l1/attribute::key", &set)); assert_int_equal(0, set->count); ly_set_free(set, NULL); /* child */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/child::l1/child::a", &set)); assert_int_equal(3, set->count); ly_set_free(set, NULL); /* descendant */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/descendant::c/descendant::b", &set)); assert_int_equal(5, set->count); ly_set_free(set, NULL); /* descendant-or-self */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "//c", &set)); assert_int_equal(3, set->count); ly_set_free(set, NULL); assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/descendant-or-self::node()/c", &set)); assert_int_equal(3, set->count); ly_set_free(set, NULL); /* following */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/c/x/following::a", &set)); assert_int_equal(7, set->count); ly_set_free(set, NULL); /* following-sibling */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/c/x/following-sibling::ll", &set)); assert_int_equal(2, set->count); ly_set_free(set, NULL); /* parent */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/child::*/c/parent::l1", &set)); assert_int_equal(2, set->count); ly_set_free(set, NULL); assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/child::c//..", &set)); assert_int_equal(8, set->count); ly_set_free(set, NULL); /* preceding */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/c/preceding::a", &set)); assert_int_equal(3, set->count); ly_set_free(set, NULL); /* preceding-sibling */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/c/ll/preceding-sibling::node()", &set)); assert_int_equal(2, set->count); ly_set_free(set, NULL); /* self */ assert_int_equal(LY_SUCCESS, lyd_find_xpath(tree, "/c/self::c/ll/ll/b/self::b", &set)); assert_int_equal(5, set->count); ly_set_free(set, NULL); lyd_free_all(tree); } static void test_trim(void **state) { const char *data; char *str1; struct lyd_node *tree; data = "" " a1" " b1" " c1" "" "" " a2" " b2" "" "" " a3" " b3" "" "" " a4" " b4" " c4" "" "" " a5" " b5" " c5" "" "50" "" " key2" " " " key1" " " " key11" " val11" " " " " " key12" " val12" " " " " " key13" " val13" " " " " " " " key2" " " " key21" " val21" " " " " " key22" " val22" " " " " " " " key3" " " " key31" " val31" " " " " " key32" " val32" " " " " ""; /* trim #1 */ assert_int_equal(LY_SUCCESS, lyd_parse_data_mem(UTEST_LYCTX, data, LYD_XML, LYD_PARSE_STRICT, LYD_VALIDATE_PRESENT, &tree)); assert_non_null(tree); assert_int_equal(LY_SUCCESS, lyd_trim_xpath(&tree, "/a:c/ll/ll[a='key11']", NULL)); lyd_print_mem(&str1, tree, LYD_XML, LYD_PRINT_WITHSIBLINGS); assert_string_equal(str1, "\n" " \n" " key1\n" " \n" " key11\n" " val11\n" " \n" " \n" "\n"); free(str1); lyd_free_all(tree); /* trim #2 */ assert_int_equal(LY_SUCCESS, lyd_parse_data_mem(UTEST_LYCTX, data, LYD_XML, LYD_PARSE_STRICT, LYD_VALIDATE_PRESENT, &tree)); assert_non_null(tree); assert_int_equal(LY_SUCCESS, lyd_trim_xpath(&tree, "/a:c/ll/ll[contains(.,'2')]", NULL)); lyd_print_mem(&str1, tree, LYD_XML, LYD_PRINT_WITHSIBLINGS); assert_string_equal(str1, "\n" " \n" " key1\n" " \n" " key12\n" " val12\n" " \n" " \n" " \n" " key2\n" " \n" " key21\n" " val21\n" " \n" " \n" " key22\n" " val22\n" " \n" " \n" " \n" " key3\n" " \n" " key32\n" " val32\n" " \n" " \n" "\n"); free(str1); lyd_free_all(tree); /* trim #3 */ assert_int_equal(LY_SUCCESS, lyd_parse_data_mem(UTEST_LYCTX, data, LYD_XML, LYD_PARSE_STRICT, LYD_VALIDATE_PRESENT, &tree)); assert_non_null(tree); assert_int_equal(LY_SUCCESS, lyd_trim_xpath(&tree, "/l1[4]//.", NULL)); lyd_print_mem(&str1, tree, LYD_XML, LYD_PRINT_WITHSIBLINGS); assert_string_equal(str1, "\n" " a4\n" " b4\n" " c4\n" "\n"); free(str1); lyd_free_all(tree); } int main(void) { const struct CMUnitTest tests[] = { UTEST(test_predicate, setup), UTEST(test_union, setup), UTEST(test_invalid, setup), UTEST(test_hash, setup), UTEST(test_rpc, setup), UTEST(test_toplevel, setup), UTEST(test_atomize, setup), UTEST(test_canonize, setup), UTEST(test_derived_from, setup), UTEST(test_augment, setup), UTEST(test_variables, setup), UTEST(test_axes, setup), UTEST(test_trim, setup), }; return cmocka_run_group_tests(tests, NULL, NULL); }