/* * Copyright (C) 2002-2014 Free Software Foundation, Inc. * * This file is part of LIBTASN1. * * The LIBTASN1 library is free software; you can redistribute it * and/or modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA * 02110-1301, USA */ /*****************************************************/ /* File: structure.c */ /* Description: Functions to create and delete an */ /* ASN1 tree. */ /*****************************************************/ #include #include #include "parser_aux.h" #include extern char _asn1_identifierMissing[]; /******************************************************/ /* Function : _asn1_add_single_node */ /* Description: creates a new NODE_ASN element. */ /* Parameters: */ /* type: type of the new element (see ASN1_ETYPE_ */ /* and CONST_ constants). */ /* Return: pointer to the new element. */ /******************************************************/ asn1_node _asn1_add_single_node (unsigned int type) { asn1_node punt; punt = calloc (1, sizeof (struct asn1_node_st)); if (punt == NULL) return NULL; punt->type = type; return punt; } /******************************************************************/ /* Function : _asn1_find_left */ /* Description: returns the NODE_ASN element with RIGHT field that*/ /* points the element NODE. */ /* Parameters: */ /* node: NODE_ASN element pointer. */ /* Return: NULL if not found. */ /******************************************************************/ asn1_node _asn1_find_left (asn1_node_const node) { if ((node == NULL) || (node->left == NULL) || (node->left->down == node)) return NULL; return node->left; } int _asn1_create_static_structure (asn1_node_const pointer, char *output_file_name, char *vector_name) { FILE *file; asn1_node_const p; unsigned long t; file = fopen (output_file_name, "w"); if (file == NULL) return ASN1_FILE_NOT_FOUND; fprintf (file, "#if HAVE_CONFIG_H\n"); fprintf (file, "# include \"config.h\"\n"); fprintf (file, "#endif\n\n"); fprintf (file, "#include \n\n"); fprintf (file, "const asn1_static_node %s[] = {\n", vector_name); p = pointer; while (p) { fprintf (file, " { "); if (p->name[0] != 0) fprintf (file, "\"%s\", ", p->name); else fprintf (file, "NULL, "); t = p->type; if (p->down) t |= CONST_DOWN; if (p->right) t |= CONST_RIGHT; fprintf (file, "%lu, ", t); if (p->value) fprintf (file, "\"%s\"},\n", p->value); else fprintf (file, "NULL },\n"); if (p->down) { p = p->down; } else if (p->right) { p = p->right; } else { while (1) { p = _asn1_find_up (p); if (p == pointer) { p = NULL; break; } if (p->right) { p = p->right; break; } } } } fprintf (file, " { NULL, 0, NULL }\n};\n"); fclose (file); return ASN1_SUCCESS; } /** * asn1_array2tree: * @array: specify the array that contains ASN.1 declarations * @definitions: return the pointer to the structure created by * *ARRAY ASN.1 declarations * @errorDescription: return the error description. * * Creates the structures needed to manage the ASN.1 definitions. * @array is a vector created by asn1_parser2array(). * * Returns: %ASN1_SUCCESS if structure was created correctly, * %ASN1_ELEMENT_NOT_EMPTY if *@definitions not NULL, * %ASN1_IDENTIFIER_NOT_FOUND if in the file there is an identifier * that is not defined (see @errorDescription for more information), * %ASN1_ARRAY_ERROR if the array pointed by @array is wrong. **/ int asn1_array2tree (const asn1_static_node * array, asn1_node * definitions, char *errorDescription) { asn1_node p, p_last = NULL; unsigned long k; int move; int result; unsigned int type; list_type *e_list = NULL; if (errorDescription) errorDescription[0] = 0; if (*definitions != NULL) return ASN1_ELEMENT_NOT_EMPTY; move = UP; for (k = 0; array[k].value || array[k].type || array[k].name; k++) { type = convert_old_type (array[k].type); p = _asn1_add_static_node (&e_list, type & (~CONST_DOWN)); if (array[k].name) _asn1_set_name (p, array[k].name); if (array[k].value) _asn1_set_value (p, array[k].value, strlen (array[k].value) + 1); if (*definitions == NULL) *definitions = p; if (move == DOWN) { if (p_last && p_last->down) _asn1_delete_structure (e_list, &p_last->down, 0); _asn1_set_down (p_last, p); } else if (move == RIGHT) { if (p_last && p_last->right) _asn1_delete_structure (e_list, &p_last->right, 0); _asn1_set_right (p_last, p); } p_last = p; if (type & CONST_DOWN) move = DOWN; else if (type & CONST_RIGHT) move = RIGHT; else { while (p_last != *definitions) { p_last = _asn1_find_up (p_last); if (p_last == NULL) break; if (p_last->type & CONST_RIGHT) { p_last->type &= ~CONST_RIGHT; move = RIGHT; break; } } /* while */ } } /* while */ if (p_last == *definitions) { result = _asn1_check_identifier (*definitions); if (result == ASN1_SUCCESS) { _asn1_change_integer_value (*definitions); result = _asn1_expand_object_id (&e_list, *definitions); } } else { result = ASN1_ARRAY_ERROR; } if (errorDescription != NULL) { if (result == ASN1_IDENTIFIER_NOT_FOUND) { Estrcpy (errorDescription, ":: identifier '"); Estrcat (errorDescription, _asn1_identifierMissing); Estrcat (errorDescription, "' not found"); } else errorDescription[0] = 0; } if (result != ASN1_SUCCESS) { _asn1_delete_list_and_nodes (e_list); *definitions = NULL; } else _asn1_delete_list (e_list); return result; } /** * asn1_delete_structure: * @structure: pointer to the structure that you want to delete. * * Deletes the structure *@structure. At the end, *@structure is set * to NULL. * * Returns: %ASN1_SUCCESS if successful, %ASN1_ELEMENT_NOT_FOUND if * *@structure was NULL. **/ int asn1_delete_structure (asn1_node * structure) { return _asn1_delete_structure (NULL, structure, 0); } /** * asn1_delete_structure2: * @structure: pointer to the structure that you want to delete. * @flags: additional flags (see %ASN1_DELETE_FLAG) * * Deletes the structure *@structure. At the end, *@structure is set * to NULL. * * Returns: %ASN1_SUCCESS if successful, %ASN1_ELEMENT_NOT_FOUND if * *@structure was NULL. **/ int asn1_delete_structure2 (asn1_node * structure, unsigned int flags) { return _asn1_delete_structure (NULL, structure, flags); } int _asn1_delete_structure (list_type *e_list, asn1_node * structure, unsigned int flags) { asn1_node p, p2, p3; if (*structure == NULL) return ASN1_ELEMENT_NOT_FOUND; p = *structure; while (p) { if (p->down) { p = p->down; } else { /* no down */ p2 = p->right; if (p != *structure) { p3 = _asn1_find_up (p); _asn1_set_down (p3, p2); if (e_list) _asn1_delete_node_from_list (e_list, p); _asn1_remove_node (p, flags); p = p3; } else { /* p==root */ p3 = _asn1_find_left (p); if (!p3) { p3 = _asn1_find_up (p); if (p3) _asn1_set_down (p3, p2); else { if (p->right) p->right->left = NULL; } } else _asn1_set_right (p3, p2); if (e_list) _asn1_delete_node_from_list (e_list, p); _asn1_remove_node (p, flags); p = NULL; } } } *structure = NULL; return ASN1_SUCCESS; } /** * asn1_delete_element: * @structure: pointer to the structure that contains the element you * want to delete. * @element_name: element's name you want to delete. * * Deletes the element named *@element_name inside *@structure. * * Returns: %ASN1_SUCCESS if successful, %ASN1_ELEMENT_NOT_FOUND if * the @element_name was not found. **/ int asn1_delete_element (asn1_node structure, const char *element_name) { asn1_node p2, p3, source_node; source_node = asn1_find_node (structure, element_name); if (source_node == NULL) return ASN1_ELEMENT_NOT_FOUND; p2 = source_node->right; p3 = _asn1_find_left (source_node); if (!p3) { p3 = _asn1_find_up (source_node); if (p3) _asn1_set_down (p3, p2); else if (source_node->right) source_node->right->left = NULL; } else _asn1_set_right (p3, p2); return asn1_delete_structure (&source_node); } #ifndef __clang_analyzer__ asn1_node _asn1_copy_structure3 (asn1_node_const source_node) { asn1_node_const p_s; asn1_node dest_node, p_d, p_d_prev; int move; if (source_node == NULL) return NULL; dest_node = _asn1_add_single_node (source_node->type); p_s = source_node; p_d = dest_node; move = DOWN; do { if (move != UP) { if (p_s->name[0] != 0) _asn1_cpy_name (p_d, p_s); if (p_s->value) _asn1_set_value (p_d, p_s->value, p_s->value_len); if (p_s->down) { p_s = p_s->down; p_d_prev = p_d; p_d = _asn1_add_single_node (p_s->type); _asn1_set_down (p_d_prev, p_d); continue; } p_d->start = p_s->start; p_d->end = p_s->end; } if (p_s == source_node) break; if (p_s->right) { move = RIGHT; p_s = p_s->right; p_d_prev = p_d; p_d = _asn1_add_single_node (p_s->type); _asn1_set_right (p_d_prev, p_d); } else { move = UP; p_s = _asn1_find_up (p_s); p_d = _asn1_find_up (p_d); } } while (p_s != source_node); return dest_node; } #else /* Non-production code */ asn1_node _asn1_copy_structure3 (asn1_node_const source_node) { return NULL; } #endif /* __clang_analyzer__ */ static asn1_node _asn1_copy_structure2 (asn1_node_const root, const char *source_name) { asn1_node source_node; source_node = asn1_find_node (root, source_name); return _asn1_copy_structure3 (source_node); } static int _asn1_type_choice_config (asn1_node node) { asn1_node p, p2, p3, p4; int move, tlen; if (node == NULL) return ASN1_ELEMENT_NOT_FOUND; p = node; move = DOWN; while (!((p == node) && (move == UP))) { if (move != UP) { if ((type_field (p->type) == ASN1_ETYPE_CHOICE) && (p->type & CONST_TAG)) { p2 = p->down; while (p2) { if (type_field (p2->type) != ASN1_ETYPE_TAG) { p2->type |= CONST_TAG; p3 = _asn1_find_left (p2); while (p3) { if (type_field (p3->type) == ASN1_ETYPE_TAG) { p4 = _asn1_add_single_node (p3->type); tlen = _asn1_strlen (p3->value); if (tlen > 0) _asn1_set_value (p4, p3->value, tlen + 1); _asn1_set_right (p4, p2->down); _asn1_set_down (p2, p4); } p3 = _asn1_find_left (p3); } } p2 = p2->right; } p->type &= ~(CONST_TAG); p2 = p->down; while (p2) { p3 = p2->right; if (type_field (p2->type) == ASN1_ETYPE_TAG) asn1_delete_structure (&p2); p2 = p3; } } move = DOWN; } else move = RIGHT; if (move == DOWN) { if (p->down) p = p->down; else move = RIGHT; } if (p == node) { move = UP; continue; } if (move == RIGHT) { if (p->right) p = p->right; else move = UP; } if (move == UP) p = _asn1_find_up (p); } return ASN1_SUCCESS; } static int _asn1_expand_identifier (asn1_node * node, asn1_node_const root) { asn1_node p, p2, p3; char name2[ASN1_MAX_NAME_SIZE + 2]; int move; if (node == NULL) return ASN1_ELEMENT_NOT_FOUND; p = *node; move = DOWN; while (!((p == *node) && (move == UP))) { if (move != UP) { if (type_field (p->type) == ASN1_ETYPE_IDENTIFIER) { snprintf (name2, sizeof (name2), "%s.%s", root->name, p->value); p2 = _asn1_copy_structure2 (root, name2); if (p2 == NULL) { return ASN1_IDENTIFIER_NOT_FOUND; } _asn1_cpy_name (p2, p); p2->right = p->right; p2->left = p->left; if (p->right) p->right->left = p2; p3 = p->down; if (p3) { while (p3->right) p3 = p3->right; _asn1_set_right (p3, p2->down); _asn1_set_down (p2, p->down); } p3 = _asn1_find_left (p); if (p3) _asn1_set_right (p3, p2); else { p3 = _asn1_find_up (p); if (p3) _asn1_set_down (p3, p2); else { p2->left = NULL; } } if (p->type & CONST_SIZE) p2->type |= CONST_SIZE; if (p->type & CONST_TAG) p2->type |= CONST_TAG; if (p->type & CONST_OPTION) p2->type |= CONST_OPTION; if (p->type & CONST_DEFAULT) p2->type |= CONST_DEFAULT; if (p->type & CONST_SET) p2->type |= CONST_SET; if (p->type & CONST_NOT_USED) p2->type |= CONST_NOT_USED; if (p == *node) *node = p2; _asn1_remove_node (p, 0); p = p2; move = DOWN; continue; } move = DOWN; } else move = RIGHT; if (move == DOWN) { if (p->down) p = p->down; else move = RIGHT; } if (p == *node) { move = UP; continue; } if (move == RIGHT) { if (p->right) p = p->right; else move = UP; } if (move == UP) p = _asn1_find_up (p); } return ASN1_SUCCESS; } /** * asn1_create_element: * @definitions: pointer to the structure returned by "parser_asn1" function * @source_name: the name of the type of the new structure (must be * inside p_structure). * @element: pointer to the structure created. * * Creates a structure of type @source_name. Example using * "pkix.asn": * * rc = asn1_create_element(cert_def, "PKIX1.Certificate", certptr); * * Returns: %ASN1_SUCCESS if creation OK, %ASN1_ELEMENT_NOT_FOUND if * @source_name is not known. **/ int asn1_create_element (asn1_node_const definitions, const char *source_name, asn1_node * element) { asn1_node dest_node; int res; dest_node = _asn1_copy_structure2 (definitions, source_name); if (dest_node == NULL) return ASN1_ELEMENT_NOT_FOUND; _asn1_set_name (dest_node, ""); res = _asn1_expand_identifier (&dest_node, definitions); _asn1_type_choice_config (dest_node); *element = dest_node; return res; } /** * asn1_print_structure: * @out: pointer to the output file (e.g. stdout). * @structure: pointer to the structure that you want to visit. * @name: an element of the structure * @mode: specify how much of the structure to print, can be * %ASN1_PRINT_NAME, %ASN1_PRINT_NAME_TYPE, * %ASN1_PRINT_NAME_TYPE_VALUE, or %ASN1_PRINT_ALL. * * Prints on the @out file descriptor the structure's tree starting * from the @name element inside the structure @structure. **/ void asn1_print_structure (FILE * out, asn1_node_const structure, const char *name, int mode) { asn1_node_const p, root; int k, indent = 0, len, len2, len3; if (out == NULL) return; root = asn1_find_node (structure, name); if (root == NULL) return; p = root; while (p) { if (mode == ASN1_PRINT_ALL) { for (k = 0; k < indent; k++) fprintf (out, " "); fprintf (out, "name:"); if (p->name[0] != 0) fprintf (out, "%s ", p->name); else fprintf (out, "NULL "); } else { switch (type_field (p->type)) { case ASN1_ETYPE_CONSTANT: case ASN1_ETYPE_TAG: case ASN1_ETYPE_SIZE: break; default: for (k = 0; k < indent; k++) fprintf (out, " "); fprintf (out, "name:"); if (p->name[0] != 0) fprintf (out, "%s ", p->name); else fprintf (out, "NULL "); } } if (mode != ASN1_PRINT_NAME) { unsigned type = type_field (p->type); switch (type) { case ASN1_ETYPE_CONSTANT: if (mode == ASN1_PRINT_ALL) fprintf (out, "type:CONST"); break; case ASN1_ETYPE_TAG: if (mode == ASN1_PRINT_ALL) fprintf (out, "type:TAG"); break; case ASN1_ETYPE_SIZE: if (mode == ASN1_PRINT_ALL) fprintf (out, "type:SIZE"); break; case ASN1_ETYPE_DEFAULT: fprintf (out, "type:DEFAULT"); break; case ASN1_ETYPE_IDENTIFIER: fprintf (out, "type:IDENTIFIER"); break; case ASN1_ETYPE_ANY: fprintf (out, "type:ANY"); break; case ASN1_ETYPE_CHOICE: fprintf (out, "type:CHOICE"); break; case ASN1_ETYPE_DEFINITIONS: fprintf (out, "type:DEFINITIONS"); break; CASE_HANDLED_ETYPES: fprintf (out, "%s", _asn1_tags[type].desc); break; default: break; } } if ((mode == ASN1_PRINT_NAME_TYPE_VALUE) || (mode == ASN1_PRINT_ALL)) { switch (type_field (p->type)) { case ASN1_ETYPE_CONSTANT: if (mode == ASN1_PRINT_ALL) if (p->value) fprintf (out, " value:%s", p->value); break; case ASN1_ETYPE_TAG: if (mode == ASN1_PRINT_ALL) if (p->value) fprintf (out, " value:%s", p->value); break; case ASN1_ETYPE_SIZE: if (mode == ASN1_PRINT_ALL) if (p->value) fprintf (out, " value:%s", p->value); break; case ASN1_ETYPE_DEFAULT: if (p->value) fprintf (out, " value:%s", p->value); else if (p->type & CONST_TRUE) fprintf (out, " value:TRUE"); else if (p->type & CONST_FALSE) fprintf (out, " value:FALSE"); break; case ASN1_ETYPE_IDENTIFIER: if (p->value) fprintf (out, " value:%s", p->value); break; case ASN1_ETYPE_INTEGER: if (p->value) { len2 = -1; len = asn1_get_length_der (p->value, p->value_len, &len2); fprintf (out, " value:0x"); if (len > 0) for (k = 0; k < len; k++) fprintf (out, "%02x", (unsigned) (p->value)[k + len2]); } break; case ASN1_ETYPE_ENUMERATED: if (p->value) { len2 = -1; len = asn1_get_length_der (p->value, p->value_len, &len2); fprintf (out, " value:0x"); if (len > 0) for (k = 0; k < len; k++) fprintf (out, "%02x", (unsigned) (p->value)[k + len2]); } break; case ASN1_ETYPE_BOOLEAN: if (p->value) { if (p->value[0] == 'T') fprintf (out, " value:TRUE"); else if (p->value[0] == 'F') fprintf (out, " value:FALSE"); } break; case ASN1_ETYPE_BIT_STRING: if (p->value) { len2 = -1; len = asn1_get_length_der (p->value, p->value_len, &len2); if (len > 0) { fprintf (out, " value(%i):", (len - 1) * 8 - (p->value[len2])); for (k = 1; k < len; k++) fprintf (out, "%02x", (unsigned) (p->value)[k + len2]); } } break; case ASN1_ETYPE_GENERALIZED_TIME: case ASN1_ETYPE_UTC_TIME: if (p->value) { fprintf (out, " value:"); for (k = 0; k < p->value_len; k++) fprintf (out, "%c", (p->value)[k]); } break; case ASN1_ETYPE_GENERALSTRING: case ASN1_ETYPE_NUMERIC_STRING: case ASN1_ETYPE_IA5_STRING: case ASN1_ETYPE_TELETEX_STRING: case ASN1_ETYPE_PRINTABLE_STRING: case ASN1_ETYPE_UNIVERSAL_STRING: case ASN1_ETYPE_UTF8_STRING: case ASN1_ETYPE_VISIBLE_STRING: if (p->value) { len2 = -1; len = asn1_get_length_der (p->value, p->value_len, &len2); fprintf (out, " value:"); if (len > 0) for (k = 0; k < len; k++) fprintf (out, "%c", (p->value)[k + len2]); } break; case ASN1_ETYPE_BMP_STRING: case ASN1_ETYPE_OCTET_STRING: if (p->value) { len2 = -1; len = asn1_get_length_der (p->value, p->value_len, &len2); fprintf (out, " value:"); if (len > 0) for (k = 0; k < len; k++) fprintf (out, "%02x", (unsigned) (p->value)[k + len2]); } break; case ASN1_ETYPE_OBJECT_ID: if (p->value) fprintf (out, " value:%s", p->value); break; case ASN1_ETYPE_ANY: if (p->value) { len3 = -1; len2 = asn1_get_length_der (p->value, p->value_len, &len3); fprintf (out, " value:"); if (len2 > 0) for (k = 0; k < len2; k++) fprintf (out, "%02x", (unsigned) (p->value)[k + len3]); } break; case ASN1_ETYPE_SET: case ASN1_ETYPE_SET_OF: case ASN1_ETYPE_CHOICE: case ASN1_ETYPE_DEFINITIONS: case ASN1_ETYPE_SEQUENCE_OF: case ASN1_ETYPE_SEQUENCE: case ASN1_ETYPE_NULL: break; default: break; } } if (mode == ASN1_PRINT_ALL) { if (p->type & 0x1FFFFF00) { fprintf (out, " attr:"); if (p->type & CONST_UNIVERSAL) fprintf (out, "UNIVERSAL,"); if (p->type & CONST_PRIVATE) fprintf (out, "PRIVATE,"); if (p->type & CONST_APPLICATION) fprintf (out, "APPLICATION,"); if (p->type & CONST_EXPLICIT) fprintf (out, "EXPLICIT,"); if (p->type & CONST_IMPLICIT) fprintf (out, "IMPLICIT,"); if (p->type & CONST_TAG) fprintf (out, "TAG,"); if (p->type & CONST_DEFAULT) fprintf (out, "DEFAULT,"); if (p->type & CONST_TRUE) fprintf (out, "TRUE,"); if (p->type & CONST_FALSE) fprintf (out, "FALSE,"); if (p->type & CONST_LIST) fprintf (out, "LIST,"); if (p->type & CONST_MIN_MAX) fprintf (out, "MIN_MAX,"); if (p->type & CONST_OPTION) fprintf (out, "OPTION,"); if (p->type & CONST_1_PARAM) fprintf (out, "1_PARAM,"); if (p->type & CONST_SIZE) fprintf (out, "SIZE,"); if (p->type & CONST_DEFINED_BY) fprintf (out, "DEF_BY,"); if (p->type & CONST_GENERALIZED) fprintf (out, "GENERALIZED,"); if (p->type & CONST_UTC) fprintf (out, "UTC,"); if (p->type & CONST_SET) fprintf (out, "SET,"); if (p->type & CONST_NOT_USED) fprintf (out, "NOT_USED,"); if (p->type & CONST_ASSIGN) fprintf (out, "ASSIGNMENT,"); } } if (mode == ASN1_PRINT_ALL) { fprintf (out, "\n"); } else { switch (type_field (p->type)) { case ASN1_ETYPE_CONSTANT: case ASN1_ETYPE_TAG: case ASN1_ETYPE_SIZE: break; default: fprintf (out, "\n"); } } if (p->down) { p = p->down; indent += 2; } else if (p == root) { p = NULL; break; } else if (p->right) p = p->right; else { while (1) { p = _asn1_find_up (p); if (p == root) { p = NULL; break; } indent -= 2; if (p->right) { p = p->right; break; } } } } } /** * asn1_number_of_elements: * @element: pointer to the root of an ASN1 structure. * @name: the name of a sub-structure of ROOT. * @num: pointer to an integer where the result will be stored * * Counts the number of elements of a sub-structure called NAME with * names equal to "?1","?2", ... * * Returns: %ASN1_SUCCESS if successful, %ASN1_ELEMENT_NOT_FOUND if * @name is not known, %ASN1_GENERIC_ERROR if pointer @num is %NULL. **/ int asn1_number_of_elements (asn1_node_const element, const char *name, int *num) { asn1_node_const node, p; if (num == NULL) return ASN1_GENERIC_ERROR; *num = 0; node = asn1_find_node (element, name); if (node == NULL) return ASN1_ELEMENT_NOT_FOUND; p = node->down; while (p) { if (p->name[0] == '?') (*num)++; p = p->right; } return ASN1_SUCCESS; } /** * asn1_find_structure_from_oid: * @definitions: ASN1 definitions * @oidValue: value of the OID to search (e.g. "1.2.3.4"). * * Search the structure that is defined just after an OID definition. * * Returns: %NULL when @oidValue not found, otherwise the pointer to a * constant string that contains the element name defined just after * the OID. **/ const char * asn1_find_structure_from_oid (asn1_node_const definitions, const char *oidValue) { char name[2 * ASN1_MAX_NAME_SIZE + 2]; char value[ASN1_MAX_NAME_SIZE]; asn1_node p; int len; int result; const char *definitionsName; if ((definitions == NULL) || (oidValue == NULL)) return NULL; /* ASN1_ELEMENT_NOT_FOUND; */ definitionsName = definitions->name; /* search the OBJECT_ID into definitions */ p = definitions->down; while (p) { if ((type_field (p->type) == ASN1_ETYPE_OBJECT_ID) && (p->type & CONST_ASSIGN)) { snprintf(name, sizeof(name), "%s.%s", definitionsName, p->name); len = ASN1_MAX_NAME_SIZE; result = asn1_read_value (definitions, name, value, &len); if ((result == ASN1_SUCCESS) && (!strcmp (oidValue, value))) { p = p->right; if (p == NULL) /* reach the end of ASN1 definitions */ return NULL; /* ASN1_ELEMENT_NOT_FOUND; */ return p->name; } } p = p->right; } return NULL; /* ASN1_ELEMENT_NOT_FOUND; */ } /** * asn1_copy_node: * @dst: Destination asn1 node. * @dst_name: Field name in destination node. * @src: Source asn1 node. * @src_name: Field name in source node. * * Create a deep copy of a asn1_node variable. That * function requires @dst to be expanded using asn1_create_element(). * * Returns: Return %ASN1_SUCCESS on success. **/ int asn1_copy_node (asn1_node dst, const char *dst_name, asn1_node_const src, const char *src_name) { int result; asn1_node dst_node; void *data = NULL; int size = 0; result = asn1_der_coding (src, src_name, NULL, &size, NULL); if (result != ASN1_MEM_ERROR) return result; data = malloc (size); if (data == NULL) return ASN1_MEM_ERROR; result = asn1_der_coding (src, src_name, data, &size, NULL); if (result != ASN1_SUCCESS) { free (data); return result; } dst_node = asn1_find_node (dst, dst_name); if (dst_node == NULL) { free (data); return ASN1_ELEMENT_NOT_FOUND; } result = asn1_der_decoding (&dst_node, data, size, NULL); free (data); return result; } /** * asn1_dup_node: * @src: Source asn1 node. * @src_name: Field name in source node. * * Create a deep copy of a asn1_node variable. This function * will return an exact copy of the provided structure. * * Returns: Return %NULL on failure. **/ asn1_node asn1_dup_node (asn1_node_const src, const char *src_name) { return _asn1_copy_structure2(src, src_name); }