/* * Author : Stephen Smalley, */ /* * Updated: Trusted Computer Solutions, Inc. * * Support for enhanced MLS infrastructure. * * Updated: David Caplan, * * Added conditional policy language extensions * * Updated: Joshua Brindle * Karl MacMillan * Jason Tang * * Added support for binary policy modules * * Copyright (C) 2004-2005 Trusted Computer Solutions, Inc. * Copyright (C) 2003 - 2008 Tresys Technology, LLC * Copyright (C) 2007 Red Hat Inc. * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, version 2. */ /* FLASK */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "queue.h" #include "checkpolicy.h" #include "module_compiler.h" #include "policy_define.h" policydb_t *policydbp; queue_t id_queue = 0; unsigned int pass; char *curfile = 0; int mlspol = 0; extern unsigned long policydb_lineno; extern unsigned long source_lineno; extern unsigned int policydb_errors; extern char source_file[PATH_MAX]; extern int yywarn(const char *msg); extern int yyerror(const char *msg); #define ERRORMSG_LEN 255 static char errormsg[ERRORMSG_LEN + 1] = {0}; static int id_has_dot(char *id); static int parse_security_context(context_struct_t *c); /* initialize all of the state variables for the scanner/parser */ void init_parser(int pass_number) { policydb_lineno = 1; source_lineno = 1; policydb_errors = 0; pass = pass_number; } __attribute__ ((format(printf, 1, 2))) void yyerror2(const char *fmt, ...) { va_list ap; va_start(ap, fmt); vsnprintf(errormsg, ERRORMSG_LEN, fmt, ap); yyerror(errormsg); va_end(ap); } int insert_separator(int push) { int error; if (push) error = queue_push(id_queue, 0); else error = queue_insert(id_queue, 0); if (error) { yyerror("queue overflow"); return -1; } return 0; } int insert_id(const char *id, int push) { char *newid = 0; int error; newid = (char *)malloc(strlen(id) + 1); if (!newid) { yyerror("out of memory"); return -1; } strcpy(newid, id); if (push) error = queue_push(id_queue, (queue_element_t) newid); else error = queue_insert(id_queue, (queue_element_t) newid); if (error) { yyerror("queue overflow"); free(newid); return -1; } return 0; } /* If the identifier has a dot within it and that its first character is not a dot then return 1, else return 0. */ static int id_has_dot(char *id) { if (strchr(id, '.') >= id + 1) { return 1; } return 0; } int define_class(void) { char *id = 0; class_datum_t *datum = 0; int ret; uint32_t value; if (pass == 2) { id = queue_remove(id_queue); free(id); return 0; } id = (char *)queue_remove(id_queue); if (!id) { yyerror("no class name for class definition?"); return -1; } datum = (class_datum_t *) malloc(sizeof(class_datum_t)); if (!datum) { yyerror("out of memory"); goto bad; } memset(datum, 0, sizeof(class_datum_t)); ret = declare_symbol(SYM_CLASSES, id, datum, &value, &value); switch (ret) { case -3:{ yyerror("Out of memory!"); goto bad; } case -2:{ yyerror2("duplicate declaration of class %s", id); goto bad; } case -1:{ yyerror("could not declare class here"); goto bad; } case 0: case 1:{ break; } default:{ assert(0); /* should never get here */ } } datum->s.value = value; return 0; bad: if (id) free(id); if (datum) free(datum); return -1; } int define_permissive(void) { char *type = NULL; struct type_datum *t; int rc = 0; type = queue_remove(id_queue); if (!type) { yyerror2("forgot to include type in permissive definition?"); rc = -1; goto out; } if (pass == 1) goto out; if (!is_id_in_scope(SYM_TYPES, type)) { yyerror2("type %s is not within scope", type); rc = -1; goto out; } t = hashtab_search(policydbp->p_types.table, type); if (!t) { yyerror2("type is not defined: %s", type); rc = -1; goto out; } if (t->flavor == TYPE_ATTRIB) { yyerror2("attributes may not be permissive: %s\n", type); rc = -1; goto out; } t->flags |= TYPE_FLAGS_PERMISSIVE; out: free(type); return rc; } int define_polcap(void) { char *id = 0; int capnum; if (pass == 2) { id = queue_remove(id_queue); free(id); return 0; } id = (char *)queue_remove(id_queue); if (!id) { yyerror("no capability name for policycap definition?"); goto bad; } /* Check for valid cap name -> number mapping */ capnum = sepol_polcap_getnum(id); if (capnum < 0) { yyerror2("invalid policy capability name %s", id); goto bad; } /* Store it */ if (ebitmap_set_bit(&policydbp->policycaps, capnum, TRUE)) { yyerror("out of memory"); goto bad; } free(id); return 0; bad: free(id); return -1; } int define_initial_sid(void) { char *id = 0; ocontext_t *newc = 0, *c, *head; if (pass == 2) { id = queue_remove(id_queue); free(id); return 0; } id = (char *)queue_remove(id_queue); if (!id) { yyerror("no sid name for SID definition?"); return -1; } newc = (ocontext_t *) malloc(sizeof(ocontext_t)); if (!newc) { yyerror("out of memory"); goto bad; } memset(newc, 0, sizeof(ocontext_t)); newc->u.name = id; context_init(&newc->context[0]); head = policydbp->ocontexts[OCON_ISID]; for (c = head; c; c = c->next) { if (!strcmp(newc->u.name, c->u.name)) { yyerror2("duplicate initial SID %s", id); goto bad; } } if (head) { newc->sid[0] = head->sid[0] + 1; } else { newc->sid[0] = 1; } newc->next = head; policydbp->ocontexts[OCON_ISID] = newc; return 0; bad: if (id) free(id); if (newc) free(newc); return -1; } static int read_classes(ebitmap_t *e_classes) { char *id; class_datum_t *cladatum; while ((id = queue_remove(id_queue))) { if (!is_id_in_scope(SYM_CLASSES, id)) { yyerror2("class %s is not within scope", id); return -1; } cladatum = hashtab_search(policydbp->p_classes.table, id); if (!cladatum) { yyerror2("unknown class %s", id); return -1; } if (ebitmap_set_bit(e_classes, cladatum->s.value - 1, TRUE)) { yyerror("Out of memory"); return -1; } free(id); } return 0; } int define_default_user(int which) { char *id; class_datum_t *cladatum; if (pass == 1) { while ((id = queue_remove(id_queue))) free(id); return 0; } while ((id = queue_remove(id_queue))) { if (!is_id_in_scope(SYM_CLASSES, id)) { yyerror2("class %s is not within scope", id); return -1; } cladatum = hashtab_search(policydbp->p_classes.table, id); if (!cladatum) { yyerror2("unknown class %s", id); return -1; } if (cladatum->default_user && cladatum->default_user != which) { yyerror2("conflicting default user information for class %s", id); return -1; } cladatum->default_user = which; free(id); } return 0; } int define_default_role(int which) { char *id; class_datum_t *cladatum; if (pass == 1) { while ((id = queue_remove(id_queue))) free(id); return 0; } while ((id = queue_remove(id_queue))) { if (!is_id_in_scope(SYM_CLASSES, id)) { yyerror2("class %s is not within scope", id); return -1; } cladatum = hashtab_search(policydbp->p_classes.table, id); if (!cladatum) { yyerror2("unknown class %s", id); return -1; } if (cladatum->default_role && cladatum->default_role != which) { yyerror2("conflicting default role information for class %s", id); return -1; } cladatum->default_role = which; free(id); } return 0; } int define_default_type(int which) { char *id; class_datum_t *cladatum; if (pass == 1) { while ((id = queue_remove(id_queue))) free(id); return 0; } while ((id = queue_remove(id_queue))) { if (!is_id_in_scope(SYM_CLASSES, id)) { yyerror2("class %s is not within scope", id); return -1; } cladatum = hashtab_search(policydbp->p_classes.table, id); if (!cladatum) { yyerror2("unknown class %s", id); return -1; } if (cladatum->default_type && cladatum->default_type != which) { yyerror2("conflicting default type information for class %s", id); return -1; } cladatum->default_type = which; free(id); } return 0; } int define_default_range(int which) { char *id; class_datum_t *cladatum; if (pass == 1) { while ((id = queue_remove(id_queue))) free(id); return 0; } while ((id = queue_remove(id_queue))) { if (!is_id_in_scope(SYM_CLASSES, id)) { yyerror2("class %s is not within scope", id); return -1; } cladatum = hashtab_search(policydbp->p_classes.table, id); if (!cladatum) { yyerror2("unknown class %s", id); return -1; } if (cladatum->default_range && cladatum->default_range != which) { yyerror2("conflicting default range information for class %s", id); return -1; } cladatum->default_range = which; free(id); } return 0; } int define_common_perms(void) { char *id = 0, *perm = 0; common_datum_t *comdatum = 0; perm_datum_t *perdatum = 0; int ret; if (pass == 2) { while ((id = queue_remove(id_queue))) free(id); return 0; } id = (char *)queue_remove(id_queue); if (!id) { yyerror("no common name for common perm definition?"); return -1; } comdatum = hashtab_search(policydbp->p_commons.table, id); if (comdatum) { yyerror2("duplicate declaration for common %s\n", id); return -1; } comdatum = (common_datum_t *) malloc(sizeof(common_datum_t)); if (!comdatum) { yyerror("out of memory"); goto bad; } memset(comdatum, 0, sizeof(common_datum_t)); ret = hashtab_insert(policydbp->p_commons.table, (hashtab_key_t) id, (hashtab_datum_t) comdatum); if (ret == SEPOL_EEXIST) { yyerror("duplicate common definition"); goto bad; } if (ret == SEPOL_ENOMEM) { yyerror("hash table overflow"); goto bad; } comdatum->s.value = policydbp->p_commons.nprim + 1; if (symtab_init(&comdatum->permissions, PERM_SYMTAB_SIZE)) { yyerror("out of memory"); goto bad; } policydbp->p_commons.nprim++; while ((perm = queue_remove(id_queue))) { perdatum = (perm_datum_t *) malloc(sizeof(perm_datum_t)); if (!perdatum) { yyerror("out of memory"); goto bad_perm; } memset(perdatum, 0, sizeof(perm_datum_t)); perdatum->s.value = comdatum->permissions.nprim + 1; if (perdatum->s.value > (sizeof(sepol_access_vector_t) * 8)) { yyerror ("too many permissions to fit in an access vector"); goto bad_perm; } ret = hashtab_insert(comdatum->permissions.table, (hashtab_key_t) perm, (hashtab_datum_t) perdatum); if (ret == SEPOL_EEXIST) { yyerror2("duplicate permission %s in common %s", perm, id); goto bad_perm; } if (ret == SEPOL_ENOMEM) { yyerror("hash table overflow"); goto bad_perm; } comdatum->permissions.nprim++; } return 0; bad: if (id) free(id); if (comdatum) free(comdatum); return -1; bad_perm: if (perm) free(perm); if (perdatum) free(perdatum); return -1; } int define_av_perms(int inherits) { char *id; class_datum_t *cladatum; common_datum_t *comdatum; perm_datum_t *perdatum = 0, *perdatum2 = 0; int ret; if (pass == 2) { while ((id = queue_remove(id_queue))) free(id); return 0; } id = (char *)queue_remove(id_queue); if (!id) { yyerror("no tclass name for av perm definition?"); return -1; } cladatum = (class_datum_t *) hashtab_search(policydbp->p_classes.table, (hashtab_key_t) id); if (!cladatum) { yyerror2("class %s is not defined", id); goto bad; } free(id); if (cladatum->comdatum || cladatum->permissions.nprim) { yyerror("duplicate access vector definition"); return -1; } if (symtab_init(&cladatum->permissions, PERM_SYMTAB_SIZE)) { yyerror("out of memory"); return -1; } if (inherits) { id = (char *)queue_remove(id_queue); if (!id) { yyerror ("no inherits name for access vector definition?"); return -1; } comdatum = (common_datum_t *) hashtab_search(policydbp->p_commons. table, (hashtab_key_t) id); if (!comdatum) { yyerror2("common %s is not defined", id); goto bad; } cladatum->comkey = id; cladatum->comdatum = comdatum; /* * Class-specific permissions start with values * after the last common permission. */ cladatum->permissions.nprim += comdatum->permissions.nprim; } while ((id = queue_remove(id_queue))) { perdatum = (perm_datum_t *) malloc(sizeof(perm_datum_t)); if (!perdatum) { yyerror("out of memory"); goto bad; } memset(perdatum, 0, sizeof(perm_datum_t)); perdatum->s.value = ++cladatum->permissions.nprim; if (perdatum->s.value > (sizeof(sepol_access_vector_t) * 8)) { yyerror ("too many permissions to fit in an access vector"); goto bad; } if (inherits) { /* * Class-specific permissions and * common permissions exist in the same * name space. */ perdatum2 = (perm_datum_t *) hashtab_search(cladatum->comdatum-> permissions.table, (hashtab_key_t) id); if (perdatum2) { yyerror2("permission %s conflicts with an " "inherited permission", id); goto bad; } } ret = hashtab_insert(cladatum->permissions.table, (hashtab_key_t) id, (hashtab_datum_t) perdatum); if (ret == SEPOL_EEXIST) { yyerror2("duplicate permission %s", id); goto bad; } if (ret == SEPOL_ENOMEM) { yyerror("hash table overflow"); goto bad; } if (add_perm_to_class(perdatum->s.value, cladatum->s.value)) { yyerror("out of memory"); goto bad; } } return 0; bad: if (id) free(id); if (perdatum) free(perdatum); return -1; } int define_sens(void) { char *id; mls_level_t *level = 0; level_datum_t *datum = 0, *aliasdatum = 0; int ret; uint32_t value; /* dummy variable -- its value is never used */ if (!mlspol) { yyerror("sensitivity definition in non-MLS configuration"); return -1; } if (pass == 2) { while ((id = queue_remove(id_queue))) free(id); return 0; } id = (char *)queue_remove(id_queue); if (!id) { yyerror("no sensitivity name for sensitivity definition?"); return -1; } if (id_has_dot(id)) { yyerror("sensitivity identifiers may not contain periods"); goto bad; } level = (mls_level_t *) malloc(sizeof(mls_level_t)); if (!level) { yyerror("out of memory"); goto bad; } mls_level_init(level); level->sens = 0; /* actual value set in define_dominance */ ebitmap_init(&level->cat); /* actual value set in define_level */ datum = (level_datum_t *) malloc(sizeof(level_datum_t)); if (!datum) { yyerror("out of memory"); goto bad; } level_datum_init(datum); datum->isalias = FALSE; datum->level = level; ret = declare_symbol(SYM_LEVELS, id, datum, &value, &value); switch (ret) { case -3:{ yyerror("Out of memory!"); goto bad; } case -2:{ yyerror("duplicate declaration of sensitivity level"); goto bad; } case -1:{ yyerror("could not declare sensitivity level here"); goto bad; } case 0: case 1:{ break; } default:{ assert(0); /* should never get here */ } } while ((id = queue_remove(id_queue))) { if (id_has_dot(id)) { yyerror("sensitivity aliases may not contain periods"); goto bad_alias; } aliasdatum = (level_datum_t *) malloc(sizeof(level_datum_t)); if (!aliasdatum) { yyerror("out of memory"); goto bad_alias; } level_datum_init(aliasdatum); aliasdatum->isalias = TRUE; aliasdatum->level = level; ret = declare_symbol(SYM_LEVELS, id, aliasdatum, NULL, &value); switch (ret) { case -3:{ yyerror("Out of memory!"); goto bad_alias; } case -2:{ yyerror ("duplicate declaration of sensitivity alias"); goto bad_alias; } case -1:{ yyerror ("could not declare sensitivity alias here"); goto bad_alias; } case 0: case 1:{ break; } default:{ assert(0); /* should never get here */ } } } return 0; bad: if (id) free(id); if (level) free(level); if (datum) { level_datum_destroy(datum); free(datum); } return -1; bad_alias: if (id) free(id); if (aliasdatum) { level_datum_destroy(aliasdatum); free(aliasdatum); } return -1; } int define_dominance(void) { level_datum_t *datum; uint32_t order; char *id; if (!mlspol) { yyerror("dominance definition in non-MLS configuration"); return -1; } if (pass == 2) { while ((id = queue_remove(id_queue))) free(id); return 0; } order = 0; while ((id = (char *)queue_remove(id_queue))) { datum = (level_datum_t *) hashtab_search(policydbp->p_levels.table, (hashtab_key_t) id); if (!datum) { yyerror2("unknown sensitivity %s used in dominance " "definition", id); free(id); return -1; } if (datum->level->sens != 0) { yyerror2("sensitivity %s occurs multiply in dominance " "definition", id); free(id); return -1; } datum->level->sens = ++order; /* no need to keep sensitivity name */ free(id); } if (order != policydbp->p_levels.nprim) { yyerror ("all sensitivities must be specified in dominance definition"); return -1; } return 0; } int define_category(void) { char *id; cat_datum_t *datum = 0, *aliasdatum = 0; int ret; uint32_t value; if (!mlspol) { yyerror("category definition in non-MLS configuration"); return -1; } if (pass == 2) { while ((id = queue_remove(id_queue))) free(id); return 0; } id = (char *)queue_remove(id_queue); if (!id) { yyerror("no category name for category definition?"); return -1; } if (id_has_dot(id)) { yyerror("category identifiers may not contain periods"); goto bad; } datum = (cat_datum_t *) malloc(sizeof(cat_datum_t)); if (!datum) { yyerror("out of memory"); goto bad; } cat_datum_init(datum); datum->isalias = FALSE; ret = declare_symbol(SYM_CATS, id, datum, &value, &value); switch (ret) { case -3:{ yyerror("Out of memory!"); goto bad; } case -2:{ yyerror("duplicate declaration of category"); goto bad; } case -1:{ yyerror("could not declare category here"); goto bad; } case 0: case 1:{ break; } default:{ assert(0); /* should never get here */ } } datum->s.value = value; while ((id = queue_remove(id_queue))) { if (id_has_dot(id)) { yyerror("category aliases may not contain periods"); goto bad_alias; } aliasdatum = (cat_datum_t *) malloc(sizeof(cat_datum_t)); if (!aliasdatum) { yyerror("out of memory"); goto bad_alias; } cat_datum_init(aliasdatum); aliasdatum->isalias = TRUE; aliasdatum->s.value = datum->s.value; ret = declare_symbol(SYM_CATS, id, aliasdatum, NULL, &datum->s.value); switch (ret) { case -3:{ yyerror("Out of memory!"); goto bad_alias; } case -2:{ yyerror ("duplicate declaration of category aliases"); goto bad_alias; } case -1:{ yyerror ("could not declare category aliases here"); goto bad_alias; } case 0: case 1:{ break; } default:{ assert(0); /* should never get here */ } } } return 0; bad: if (id) free(id); if (datum) { cat_datum_destroy(datum); free(datum); } return -1; bad_alias: if (id) free(id); if (aliasdatum) { cat_datum_destroy(aliasdatum); free(aliasdatum); } return -1; } static int clone_level(hashtab_key_t key __attribute__ ((unused)), hashtab_datum_t datum, void *arg) { level_datum_t *levdatum = (level_datum_t *) datum; mls_level_t *level = (mls_level_t *) arg, *newlevel; if (levdatum->level == level) { levdatum->defined = 1; if (!levdatum->isalias) return 0; newlevel = (mls_level_t *) malloc(sizeof(mls_level_t)); if (!newlevel) return -1; if (mls_level_cpy(newlevel, level)) { free(newlevel); return -1; } levdatum->level = newlevel; } return 0; } int define_level(void) { char *id; level_datum_t *levdatum; if (!mlspol) { yyerror("level definition in non-MLS configuration"); return -1; } if (pass == 2) { while ((id = queue_remove(id_queue))) free(id); return 0; } id = (char *)queue_remove(id_queue); if (!id) { yyerror("no level name for level definition?"); return -1; } levdatum = (level_datum_t *) hashtab_search(policydbp->p_levels.table, (hashtab_key_t) id); if (!levdatum) { yyerror2("unknown sensitivity %s used in level definition", id); free(id); return -1; } if (ebitmap_length(&levdatum->level->cat)) { yyerror2("sensitivity %s used in multiple level definitions", id); free(id); return -1; } free(id); levdatum->defined = 1; while ((id = queue_remove(id_queue))) { cat_datum_t *cdatum; int range_start, range_end, i; if (id_has_dot(id)) { char *id_start = id; char *id_end = strchr(id, '.'); *(id_end++) = '\0'; cdatum = (cat_datum_t *) hashtab_search(policydbp->p_cats. table, (hashtab_key_t) id_start); if (!cdatum) { yyerror2("unknown category %s", id_start); free(id); return -1; } range_start = cdatum->s.value - 1; cdatum = (cat_datum_t *) hashtab_search(policydbp->p_cats. table, (hashtab_key_t) id_end); if (!cdatum) { yyerror2("unknown category %s", id_end); free(id); return -1; } range_end = cdatum->s.value - 1; if (range_end < range_start) { yyerror2("category range is invalid"); free(id); return -1; } } else { cdatum = (cat_datum_t *) hashtab_search(policydbp->p_cats. table, (hashtab_key_t) id); range_start = range_end = cdatum->s.value - 1; } for (i = range_start; i <= range_end; i++) { if (ebitmap_set_bit(&levdatum->level->cat, i, TRUE)) { yyerror("out of memory"); free(id); return -1; } } free(id); } if (hashtab_map (policydbp->p_levels.table, clone_level, levdatum->level)) { yyerror("out of memory"); return -1; } return 0; } int define_attrib(void) { if (pass == 2) { free(queue_remove(id_queue)); return 0; } if (declare_type(TRUE, TRUE) == NULL) { return -1; } return 0; } static int add_aliases_to_type(type_datum_t * type) { char *id; type_datum_t *aliasdatum = NULL; int ret; while ((id = queue_remove(id_queue))) { if (id_has_dot(id)) { free(id); yyerror ("type alias identifiers may not contain periods"); return -1; } aliasdatum = (type_datum_t *) malloc(sizeof(type_datum_t)); if (!aliasdatum) { free(id); yyerror("Out of memory!"); return -1; } memset(aliasdatum, 0, sizeof(type_datum_t)); aliasdatum->s.value = type->s.value; ret = declare_symbol(SYM_TYPES, id, aliasdatum, NULL, &aliasdatum->s.value); switch (ret) { case -3:{ yyerror("Out of memory!"); goto cleanup; } case -2:{ yyerror2("duplicate declaration of alias %s", id); goto cleanup; } case -1:{ yyerror("could not declare alias here"); goto cleanup; } case 0: break; case 1:{ /* ret == 1 means the alias was required and therefore already * has a value. Set it up as an alias with a different primary. */ type_datum_destroy(aliasdatum); free(aliasdatum); aliasdatum = hashtab_search(policydbp->symtab[SYM_TYPES].table, id); assert(aliasdatum); aliasdatum->primary = type->s.value; aliasdatum->flavor = TYPE_ALIAS; break; } default:{ assert(0); /* should never get here */ } } } return 0; cleanup: free(id); type_datum_destroy(aliasdatum); free(aliasdatum); return -1; } int define_typealias(void) { char *id; type_datum_t *t; if (pass == 2) { while ((id = queue_remove(id_queue))) free(id); return 0; } id = (char *)queue_remove(id_queue); if (!id) { yyerror("no type name for typealias definition?"); return -1; } if (!is_id_in_scope(SYM_TYPES, id)) { yyerror2("type %s is not within scope", id); free(id); return -1; } t = hashtab_search(policydbp->p_types.table, id); if (!t || t->flavor == TYPE_ATTRIB) { yyerror2("unknown type %s, or it was already declared as an " "attribute", id); free(id); return -1; } return add_aliases_to_type(t); } int define_typeattribute(void) { char *id; type_datum_t *t, *attr; if (pass == 2) { while ((id = queue_remove(id_queue))) free(id); return 0; } id = (char *)queue_remove(id_queue); if (!id) { yyerror("no type name for typeattribute definition?"); return -1; } if (!is_id_in_scope(SYM_TYPES, id)) { yyerror2("type %s is not within scope", id); free(id); return -1; } t = hashtab_search(policydbp->p_types.table, id); if (!t || t->flavor == TYPE_ATTRIB) { yyerror2("unknown type %s", id); free(id); return -1; } while ((id = queue_remove(id_queue))) { if (!is_id_in_scope(SYM_TYPES, id)) { yyerror2("attribute %s is not within scope", id); free(id); return -1; } attr = hashtab_search(policydbp->p_types.table, id); if (!attr) { /* treat it as a fatal error */ yyerror2("attribute %s is not declared", id); free(id); return -1; } if (attr->flavor != TYPE_ATTRIB) { yyerror2("%s is a type, not an attribute", id); free(id); return -1; } if ((attr = get_local_type(id, attr->s.value, 1)) == NULL) { yyerror("Out of memory!"); return -1; } if (ebitmap_set_bit(&attr->types, (t->s.value - 1), TRUE)) { yyerror("out of memory"); return -1; } } return 0; } static int define_typebounds_helper(char *bounds_id, char *type_id) { type_datum_t *bounds, *type; if (!is_id_in_scope(SYM_TYPES, bounds_id)) { yyerror2("type %s is not within scope", bounds_id); return -1; } bounds = hashtab_search(policydbp->p_types.table, bounds_id); if (!bounds || bounds->flavor == TYPE_ATTRIB) { yyerror2("hoge unknown type %s", bounds_id); return -1; } if (!is_id_in_scope(SYM_TYPES, type_id)) { yyerror2("type %s is not within scope", type_id); return -1; } type = hashtab_search(policydbp->p_types.table, type_id); if (!type || type->flavor == TYPE_ATTRIB) { yyerror2("type %s is not declared", type_id); return -1; } if (type->flavor == TYPE_TYPE && !type->primary) { type = policydbp->type_val_to_struct[type->s.value - 1]; } else if (type->flavor == TYPE_ALIAS) { type = policydbp->type_val_to_struct[type->primary - 1]; } if (!type->bounds) type->bounds = bounds->s.value; else if (type->bounds != bounds->s.value) { yyerror2("type %s has inconsistent master {%s,%s}", type_id, policydbp->p_type_val_to_name[type->bounds - 1], policydbp->p_type_val_to_name[bounds->s.value - 1]); return -1; } return 0; } int define_typebounds(void) { char *bounds, *id; if (pass == 1) { while ((id = queue_remove(id_queue))) free(id); return 0; } bounds = (char *) queue_remove(id_queue); if (!bounds) { yyerror("no type name for typebounds definition?"); return -1; } while ((id = queue_remove(id_queue))) { if (define_typebounds_helper(bounds, id)) return -1; free(id); } free(bounds); return 0; } int define_type(int alias) { char *id; type_datum_t *datum, *attr; if (pass == 2) { /* * If type name contains ".", we have to define boundary * relationship implicitly to keep compatibility with * old name based hierarchy. */ if ((id = queue_remove(id_queue))) { char *bounds, *delim; if ((delim = strrchr(id, '.')) && (bounds = strdup(id))) { bounds[(size_t)(delim - id)] = '\0'; if (define_typebounds_helper(bounds, id)) return -1; free(bounds); } free(id); } if (alias) { while ((id = queue_remove(id_queue))) free(id); } while ((id = queue_remove(id_queue))) free(id); return 0; } if ((datum = declare_type(TRUE, FALSE)) == NULL) { return -1; } if (alias) { if (add_aliases_to_type(datum) == -1) { return -1; } } while ((id = queue_remove(id_queue))) { if (!is_id_in_scope(SYM_TYPES, id)) { yyerror2("attribute %s is not within scope", id); free(id); return -1; } attr = hashtab_search(policydbp->p_types.table, id); if (!attr) { /* treat it as a fatal error */ yyerror2("attribute %s is not declared", id); return -1; } if (attr->flavor != TYPE_ATTRIB) { yyerror2("%s is a type, not an attribute", id); return -1; } if ((attr = get_local_type(id, attr->s.value, 1)) == NULL) { yyerror("Out of memory!"); return -1; } if (ebitmap_set_bit(&attr->types, datum->s.value - 1, TRUE)) { yyerror("Out of memory"); return -1; } } return 0; } struct val_to_name { unsigned int val; char *name; }; /* Adds a type, given by its textual name, to a typeset. If *add is 0, then add the type to the negative set; otherwise if *add is 1 then add it to the positive side. */ static int set_types(type_set_t * set, char *id, int *add, char starallowed) { type_datum_t *t; if (strcmp(id, "*") == 0) { if (!starallowed) { yyerror("* not allowed in this type of rule"); return -1; } /* set TYPE_STAR flag */ set->flags = TYPE_STAR; free(id); *add = 1; return 0; } if (strcmp(id, "~") == 0) { if (!starallowed) { yyerror("~ not allowed in this type of rule"); return -1; } /* complement the set */ set->flags = TYPE_COMP; free(id); *add = 1; return 0; } if (strcmp(id, "-") == 0) { *add = 0; free(id); return 0; } if (!is_id_in_scope(SYM_TYPES, id)) { yyerror2("type %s is not within scope", id); free(id); return -1; } t = hashtab_search(policydbp->p_types.table, id); if (!t) { yyerror2("unknown type %s", id); free(id); return -1; } if (*add == 0) { if (ebitmap_set_bit(&set->negset, t->s.value - 1, TRUE)) goto oom; } else { if (ebitmap_set_bit(&set->types, t->s.value - 1, TRUE)) goto oom; } free(id); *add = 1; return 0; oom: yyerror("Out of memory"); free(id); return -1; } int define_compute_type_helper(int which, avrule_t ** rule) { char *id; type_datum_t *datum; ebitmap_t tclasses; ebitmap_node_t *node; avrule_t *avrule; class_perm_node_t *perm; uint32_t i; int add = 1; avrule = malloc(sizeof(avrule_t)); if (!avrule) { yyerror("out of memory"); return -1; } avrule_init(avrule); avrule->specified = which; avrule->line = policydb_lineno; avrule->source_line = source_lineno; avrule->source_filename = strdup(source_file); if (!avrule->source_filename) { yyerror("out of memory"); return -1; } while ((id = queue_remove(id_queue))) { if (set_types(&avrule->stypes, id, &add, 0)) goto bad; } add = 1; while ((id = queue_remove(id_queue))) { if (set_types(&avrule->ttypes, id, &add, 0)) goto bad; } ebitmap_init(&tclasses); if (read_classes(&tclasses)) goto bad; id = (char *)queue_remove(id_queue); if (!id) { yyerror("no newtype?"); goto bad; } if (!is_id_in_scope(SYM_TYPES, id)) { yyerror2("type %s is not within scope", id); free(id); goto bad; } datum = (type_datum_t *) hashtab_search(policydbp->p_types.table, (hashtab_key_t) id); if (!datum || datum->flavor == TYPE_ATTRIB) { yyerror2("unknown type %s", id); goto bad; } ebitmap_for_each_bit(&tclasses, node, i) { if (ebitmap_node_get_bit(node, i)) { perm = malloc(sizeof(class_perm_node_t)); if (!perm) { yyerror("out of memory"); goto bad; } class_perm_node_init(perm); perm->tclass = i + 1; perm->data = datum->s.value; perm->next = avrule->perms; avrule->perms = perm; } } ebitmap_destroy(&tclasses); *rule = avrule; return 0; bad: avrule_destroy(avrule); free(avrule); return -1; } int define_compute_type(int which) { char *id; avrule_t *avrule; if (pass == 1) { while ((id = queue_remove(id_queue))) free(id); while ((id = queue_remove(id_queue))) free(id); while ((id = queue_remove(id_queue))) free(id); id = queue_remove(id_queue); free(id); return 0; } if (define_compute_type_helper(which, &avrule)) return -1; append_avrule(avrule); return 0; } avrule_t *define_cond_compute_type(int which) { char *id; avrule_t *avrule; if (pass == 1) { while ((id = queue_remove(id_queue))) free(id); while ((id = queue_remove(id_queue))) free(id); while ((id = queue_remove(id_queue))) free(id); id = queue_remove(id_queue); free(id); return (avrule_t *) 1; } if (define_compute_type_helper(which, &avrule)) return COND_ERR; return avrule; } int define_bool_tunable(int is_tunable) { char *id, *bool_value; cond_bool_datum_t *datum; int ret; uint32_t value; if (pass == 2) { while ((id = queue_remove(id_queue))) free(id); return 0; } id = (char *)queue_remove(id_queue); if (!id) { yyerror("no identifier for bool definition?"); return -1; } if (id_has_dot(id)) { free(id); yyerror("boolean identifiers may not contain periods"); return -1; } datum = (cond_bool_datum_t *) malloc(sizeof(cond_bool_datum_t)); if (!datum) { yyerror("out of memory"); free(id); return -1; } memset(datum, 0, sizeof(cond_bool_datum_t)); if (is_tunable) datum->flags |= COND_BOOL_FLAGS_TUNABLE; ret = declare_symbol(SYM_BOOLS, id, datum, &value, &value); switch (ret) { case -3:{ yyerror("Out of memory!"); goto cleanup; } case -2:{ yyerror2("duplicate declaration of boolean %s", id); goto cleanup; } case -1:{ yyerror("could not declare boolean here"); goto cleanup; } case 0: case 1:{ break; } default:{ assert(0); /* should never get here */ } } datum->s.value = value; bool_value = (char *)queue_remove(id_queue); if (!bool_value) { yyerror("no default value for bool definition?"); free(id); return -1; } datum->state = (int)(bool_value[0] == 'T') ? 1 : 0; return 0; cleanup: cond_destroy_bool(id, datum, NULL); return -1; } avrule_t *define_cond_pol_list(avrule_t * avlist, avrule_t * sl) { if (pass == 1) { /* return something so we get through pass 1 */ return (avrule_t *) 1; } if (sl == NULL) { /* This is a require block, return previous list */ return avlist; } /* prepend the new avlist to the pre-existing one */ sl->next = avlist; return sl; } #define xperm_test(x, p) (1 & (p[x >> 5] >> (x & 0x1f))) #define xperm_set(x, p) (p[x >> 5] |= (1 << (x & 0x1f))) #define xperm_clear(x, p) (p[x >> 5] &= ~(1 << (x & 0x1f))) typedef struct av_ioctl_range { uint16_t low; uint16_t high; } av_ioctl_range_t; struct av_ioctl_range_list { uint8_t omit; av_ioctl_range_t range; struct av_ioctl_range_list *next; }; int avrule_sort_ioctls(struct av_ioctl_range_list **rangehead) { struct av_ioctl_range_list *r, *r2, *sorted, *sortedhead = NULL; /* order list by range.low */ for (r = *rangehead; r != NULL; r = r->next) { sorted = malloc(sizeof(struct av_ioctl_range_list)); if (sorted == NULL) goto error; memcpy(sorted, r, sizeof(struct av_ioctl_range_list)); sorted->next = NULL; if (sortedhead == NULL) { sortedhead = sorted; continue; } for (r2 = sortedhead; r2 != NULL; r2 = r2->next) { if (sorted->range.low < r2->range.low) { /* range is the new head */ sorted->next = r2; sortedhead = sorted; break; } else if ((r2 ->next != NULL) && (r->range.low < r2->next->range.low)) { /* insert range between elements */ sorted->next = r2->next; r2->next = sorted; break; } else if (r2->next == NULL) { /* range is the new tail*/ r2->next = sorted; break; } } } r = *rangehead; while (r != NULL) { r2 = r; r = r->next; free(r2); } *rangehead = sortedhead; return 0; error: yyerror("out of memory"); return -1; } int avrule_merge_ioctls(struct av_ioctl_range_list **rangehead) { struct av_ioctl_range_list *r, *tmp; r = *rangehead; while (r != NULL && r->next != NULL) { /* merge */ if ((r->range.high + 1) >= r->next->range.low) { /* keep the higher of the two */ if (r->range.high < r->next->range.high) r->range.high = r->next->range.high; tmp = r->next; r->next = r->next->next; free(tmp); continue; } r = r->next; } return 0; } int avrule_read_ioctls(struct av_ioctl_range_list **rangehead) { char *id; struct av_ioctl_range_list *rnew, *r = NULL; *rangehead = NULL; uint8_t omit = 0; /* read in all the ioctl commands */ while ((id = queue_remove(id_queue))) { if (strcmp(id,"~") == 0) { /* these are values to be omitted */ free(id); omit = 1; } else if (strcmp(id,"-") == 0) { /* high value of range */ free(id); id = queue_remove(id_queue); r->range.high = (uint16_t) strtoul(id,NULL,0); if (r->range.high < r->range.low) { yyerror("Ioctl ranges must be in ascending order."); return -1; } free(id); } else { /* read in new low value */ rnew = malloc(sizeof(struct av_ioctl_range_list)); if (rnew == NULL) goto error; rnew->next = NULL; if (*rangehead == NULL) { *rangehead = rnew; r = *rangehead; } else { r->next = rnew; r = r->next; } rnew->range.low = (uint16_t) strtoul(id,NULL,0); rnew->range.high = rnew->range.low; free(id); } } r = *rangehead; r->omit = omit; return 0; error: yyerror("out of memory"); return -1; } /* flip to included ranges */ int avrule_omit_ioctls(struct av_ioctl_range_list **rangehead) { struct av_ioctl_range_list *rnew, *r, *newhead, *r2; rnew = calloc(1, sizeof(struct av_ioctl_range_list)); if (!rnew) goto error; newhead = rnew; r = *rangehead; r2 = newhead; if (r->range.low == 0) { r2->range.low = r->range.high + 1; r = r->next; } else { r2->range.low = 0; } while (r) { r2->range.high = r->range.low - 1; rnew = calloc(1, sizeof(struct av_ioctl_range_list)); if (!rnew) goto error; r2->next = rnew; r2 = r2->next; r2->range.low = r->range.high + 1; if (!r->next) r2->range.high = 0xffff; r = r->next; } r = *rangehead; while (r != NULL) { r2 = r; r = r->next; free(r2); } *rangehead = newhead; return 0; error: yyerror("out of memory"); return -1; } int avrule_ioctl_ranges(struct av_ioctl_range_list **rangelist) { struct av_ioctl_range_list *rangehead; uint8_t omit; /* read in ranges to include and omit */ if (avrule_read_ioctls(&rangehead)) return -1; omit = rangehead->omit; if (rangehead == NULL) { yyerror("error processing ioctl commands"); return -1; } /* sort and merge the input ioctls */ if (avrule_sort_ioctls(&rangehead)) return -1; if (avrule_merge_ioctls(&rangehead)) return -1; /* flip ranges if these are ommited*/ if (omit) { if (avrule_omit_ioctls(&rangehead)) return -1; } *rangelist = rangehead; return 0; } int define_te_avtab_xperms_helper(int which, avrule_t ** rule) { char *id; class_perm_node_t *perms, *tail = NULL, *cur_perms = NULL; ebitmap_t tclasses; ebitmap_node_t *node; avrule_t *avrule; unsigned int i; int add = 1, ret = 0; avrule = (avrule_t *) malloc(sizeof(avrule_t)); if (!avrule) { yyerror("out of memory"); ret = -1; goto out; } avrule_init(avrule); avrule->specified = which; avrule->line = policydb_lineno; avrule->source_line = source_lineno; avrule->source_filename = strdup(source_file); avrule->xperms = NULL; if (!avrule->source_filename) { yyerror("out of memory"); return -1; } while ((id = queue_remove(id_queue))) { if (set_types (&avrule->stypes, id, &add, which == AVRULE_NEVERALLOW ? 1 : 0)) { ret = -1; goto out; } } add = 1; while ((id = queue_remove(id_queue))) { if (strcmp(id, "self") == 0) { free(id); avrule->flags |= RULE_SELF; continue; } if (set_types (&avrule->ttypes, id, &add, which == AVRULE_NEVERALLOW ? 1 : 0)) { ret = -1; goto out; } } ebitmap_init(&tclasses); ret = read_classes(&tclasses); if (ret) goto out; perms = NULL; ebitmap_for_each_bit(&tclasses, node, i) { if (!ebitmap_node_get_bit(node, i)) continue; cur_perms = (class_perm_node_t *) malloc(sizeof(class_perm_node_t)); if (!cur_perms) { yyerror("out of memory"); ret = -1; goto out; } class_perm_node_init(cur_perms); cur_perms->tclass = i + 1; if (!perms) perms = cur_perms; if (tail) tail->next = cur_perms; tail = cur_perms; } ebitmap_destroy(&tclasses); avrule->perms = perms; *rule = avrule; out: return ret; } /* index of the u32 containing the permission */ #define XPERM_IDX(x) (x >> 5) /* set bits 0 through x-1 within the u32 */ #define XPERM_SETBITS(x) ((1 << (x & 0x1f)) - 1) /* low value for this u32 */ #define XPERM_LOW(x) (x << 5) /* high value for this u32 */ #define XPERM_HIGH(x) (((x + 1) << 5) - 1) void avrule_xperm_setrangebits(uint16_t low, uint16_t high, av_extended_perms_t *xperms) { unsigned int i; uint16_t h = high + 1; /* for each u32 that this low-high range touches, set driver permissions */ for (i = XPERM_IDX(low); i <= XPERM_IDX(high); i++) { /* set all bits in u32 */ if ((low <= XPERM_LOW(i)) && (high >= XPERM_HIGH(i))) xperms->perms[i] |= ~0U; /* set low bits */ else if ((low <= XPERM_LOW(i)) && (high < XPERM_HIGH(i))) xperms->perms[i] |= XPERM_SETBITS(h); /* set high bits */ else if ((low > XPERM_LOW(i)) && (high >= XPERM_HIGH(i))) xperms->perms[i] |= ~0U - XPERM_SETBITS(low); /* set middle bits */ else if ((low > XPERM_LOW(i)) && (high <= XPERM_HIGH(i))) xperms->perms[i] |= XPERM_SETBITS(h) - XPERM_SETBITS(low); } } int avrule_xperms_used(av_extended_perms_t *xperms) { unsigned int i; for (i = 0; i < sizeof(xperms->perms)/sizeof(xperms->perms[0]); i++) { if (xperms->perms[i]) return 1; } return 0; } /* * using definitions found in kernel document ioctl-number.txt * The kernel components of an ioctl command are: * dir, size, driver, and fucntion. Only the driver and function fields * are considered here */ #define IOC_DRIV(x) (x >> 8) #define IOC_FUNC(x) (x & 0xff) #define IOC_CMD(driver, func) ((driver << 8) + func) int avrule_ioctl_partialdriver(struct av_ioctl_range_list *rangelist, av_extended_perms_t *complete_driver, av_extended_perms_t **extended_perms) { struct av_ioctl_range_list *r; av_extended_perms_t *xperms; uint8_t low, high; xperms = calloc(1, sizeof(av_extended_perms_t)); if (!xperms) { yyerror("out of memory"); return - 1; } r = rangelist; while(r) { low = IOC_DRIV(r->range.low); high = IOC_DRIV(r->range.high); if (complete_driver) { if (!xperm_test(low, complete_driver->perms)) xperm_set(low, xperms->perms); if (!xperm_test(high, complete_driver->perms)) xperm_set(high, xperms->perms); } else { xperm_set(low, xperms->perms); xperm_set(high, xperms->perms); } r = r->next; } if (avrule_xperms_used(xperms)) { *extended_perms = xperms; } else { free(xperms); *extended_perms = NULL; } return 0; } int avrule_ioctl_completedriver(struct av_ioctl_range_list *rangelist, av_extended_perms_t **extended_perms) { struct av_ioctl_range_list *r; av_extended_perms_t *xperms; uint16_t low, high; xperms = calloc(1, sizeof(av_extended_perms_t)); if (!xperms) { yyerror("out of memory"); return - 1; } r = rangelist; while(r) { /* * Any driver code that has sequence 0x00 - 0xff is a complete code, * * if command number = 0xff, then round high up to next code, * else 0x00 - 0xfe keep current code * of this range. temporarily u32 for the + 1 * to account for possible rollover before right shift */ high = IOC_DRIV((uint32_t) (r->range.high + 1)); /* if 0x00 keep current driver code else 0x01 - 0xff round up to next code*/ low = IOC_DRIV(r->range.low); if (IOC_FUNC(r->range.low)) low++; if (high > low) avrule_xperm_setrangebits(low, high - 1, xperms); r = r->next; } if (avrule_xperms_used(xperms)) { xperms->driver = 0x00; xperms->specified = AVRULE_XPERMS_IOCTLDRIVER; *extended_perms = xperms; } else { free(xperms); *extended_perms = NULL; } return 0; } int avrule_ioctl_func(struct av_ioctl_range_list *rangelist, av_extended_perms_t **extended_perms, unsigned int driver) { struct av_ioctl_range_list *r; av_extended_perms_t *xperms; uint16_t low, high; *extended_perms = NULL; xperms = calloc(1, sizeof(av_extended_perms_t)); if (!xperms) { yyerror("out of memory"); return - 1; } r = rangelist; /* for the passed in driver code, find the ranges that apply */ while (r) { low = r->range.low; high = r->range.high; if ((driver != IOC_DRIV(low)) && (driver != IOC_DRIV(high))) { r = r->next; continue; } if (driver == IOC_DRIV(low)) { if (high > IOC_CMD(driver, 0xff)) high = IOC_CMD(driver, 0xff); } else { if (low < IOC_CMD(driver, 0)) low = IOC_CMD(driver, 0); } low = IOC_FUNC(low); high = IOC_FUNC(high); avrule_xperm_setrangebits(low, high, xperms); xperms->driver = driver; xperms->specified = AVRULE_XPERMS_IOCTLFUNCTION; r = r->next; } if (avrule_xperms_used(xperms)) { *extended_perms = xperms; } else { free(xperms); *extended_perms = NULL; } return 0; } void avrule_ioctl_freeranges(struct av_ioctl_range_list *rangelist) { struct av_ioctl_range_list *r, *tmp; r = rangelist; while (r) { tmp = r; r = r->next; free(tmp); } } unsigned int xperms_for_each_bit(unsigned int *bit, av_extended_perms_t *xperms) { unsigned int i; for (i = *bit; i < sizeof(xperms->perms)*8; i++) { if (xperm_test(i,xperms->perms)) { xperm_clear(i, xperms->perms); *bit = i; return 1; } } return 0; } int avrule_cpy(avrule_t *dest, avrule_t *src) { class_perm_node_t *src_perms; class_perm_node_t *dest_perms, *dest_tail; dest_tail = NULL; avrule_init(dest); dest->specified = src->specified; dest->flags = src->flags; if (type_set_cpy(&dest->stypes, &src->stypes)) { yyerror("out of memory"); return - 1; } if (type_set_cpy(&dest->ttypes, &src->ttypes)) { yyerror("out of memory"); return - 1; } dest->line = src->line; dest->source_filename = strdup(source_file); dest->source_line = src->source_line; /* increment through the class perms and copy over */ src_perms = src->perms; while (src_perms) { dest_perms = (class_perm_node_t *) calloc(1, sizeof(class_perm_node_t)); class_perm_node_init(dest_perms); if (!dest_perms) { yyerror("out of memory"); return -1; } if (!dest->perms) dest->perms = dest_perms; else dest_tail->next = dest_perms; dest_perms->tclass = src_perms->tclass; dest_perms->data = src_perms->data; dest_perms->next = NULL; dest_tail = dest_perms; src_perms = src_perms->next; } return 0; } int define_te_avtab_ioctl(avrule_t *avrule_template) { avrule_t *avrule; struct av_ioctl_range_list *rangelist; av_extended_perms_t *complete_driver, *partial_driver, *xperms; unsigned int i; /* organize ioctl ranges */ if (avrule_ioctl_ranges(&rangelist)) return -1; /* create rule for ioctl driver types that are entirely enabled */ if (avrule_ioctl_completedriver(rangelist, &complete_driver)) return -1; if (complete_driver) { avrule = (avrule_t *) calloc(1, sizeof(avrule_t)); if (!avrule) { yyerror("out of memory"); return -1; } if (avrule_cpy(avrule, avrule_template)) return -1; avrule->xperms = complete_driver; append_avrule(avrule); } /* flag ioctl driver codes that are partially enabled */ if (avrule_ioctl_partialdriver(rangelist, complete_driver, &partial_driver)) return -1; if (!partial_driver || !avrule_xperms_used(partial_driver)) goto done; /* * create rule for each partially used driver codes * "partially used" meaning that the code number e.g. socket 0x89 * has some permission bits set and others not set. */ i = 0; while (xperms_for_each_bit(&i, partial_driver)) { if (avrule_ioctl_func(rangelist, &xperms, i)) return -1; if (xperms) { avrule = (avrule_t *) calloc(1, sizeof(avrule_t)); if (!avrule) { yyerror("out of memory"); return -1; } if (avrule_cpy(avrule, avrule_template)) return -1; avrule->xperms = xperms; append_avrule(avrule); } } done: if (partial_driver) free(partial_driver); return 0; } int define_te_avtab_extended_perms(int which) { char *id; unsigned int i; avrule_t *avrule_template; if (pass == 1) { for (i = 0; i < 4; i++) { while ((id = queue_remove(id_queue))) free(id); } return 0; } /* populate avrule template with source/target/tclass */ if (define_te_avtab_xperms_helper(which, &avrule_template)) return -1; id = queue_remove(id_queue); if (strcmp(id,"ioctl") == 0) { if (define_te_avtab_ioctl(avrule_template)) return -1; free(id); } else { yyerror("only ioctl extended permissions are supported"); return -1; } return 0; } int define_te_avtab_helper(int which, avrule_t ** rule) { char *id; class_datum_t *cladatum; perm_datum_t *perdatum = NULL; class_perm_node_t *perms, *tail = NULL, *cur_perms = NULL; ebitmap_t tclasses; ebitmap_node_t *node; avrule_t *avrule; unsigned int i; int add = 1, ret = 0; int suppress = 0; avrule = (avrule_t *) malloc(sizeof(avrule_t)); if (!avrule) { yyerror("memory error"); ret = -1; goto out; } avrule_init(avrule); avrule->specified = which; avrule->line = policydb_lineno; avrule->source_line = source_lineno; avrule->source_filename = strdup(source_file); avrule->xperms = NULL; if (!avrule->source_filename) { yyerror("out of memory"); return -1; } while ((id = queue_remove(id_queue))) { if (set_types (&avrule->stypes, id, &add, which == AVRULE_NEVERALLOW ? 1 : 0)) { ret = -1; goto out; } } add = 1; while ((id = queue_remove(id_queue))) { if (strcmp(id, "self") == 0) { free(id); avrule->flags |= RULE_SELF; continue; } if (set_types (&avrule->ttypes, id, &add, which == AVRULE_NEVERALLOW ? 1 : 0)) { ret = -1; goto out; } } ebitmap_init(&tclasses); ret = read_classes(&tclasses); if (ret) goto out; perms = NULL; ebitmap_for_each_bit(&tclasses, node, i) { if (!ebitmap_node_get_bit(node, i)) continue; cur_perms = (class_perm_node_t *) malloc(sizeof(class_perm_node_t)); if (!cur_perms) { yyerror("out of memory"); ret = -1; goto out; } class_perm_node_init(cur_perms); cur_perms->tclass = i + 1; if (!perms) perms = cur_perms; if (tail) tail->next = cur_perms; tail = cur_perms; } while ((id = queue_remove(id_queue))) { cur_perms = perms; ebitmap_for_each_bit(&tclasses, node, i) { if (!ebitmap_node_get_bit(node, i)) continue; cladatum = policydbp->class_val_to_struct[i]; if (strcmp(id, "*") == 0) { /* set all permissions in the class */ cur_perms->data = ~0U; goto next; } if (strcmp(id, "~") == 0) { /* complement the set */ if (which == AVRULE_DONTAUDIT) yywarn("dontaudit rule with a ~?"); cur_perms->data = ~cur_perms->data; goto next; } perdatum = hashtab_search(cladatum->permissions.table, id); if (!perdatum) { if (cladatum->comdatum) { perdatum = hashtab_search(cladatum->comdatum-> permissions.table, id); } } if (!perdatum) { if (!suppress) yyerror2("permission %s is not defined" " for class %s", id, policydbp->p_class_val_to_name[i]); continue; } else if (!is_perm_in_scope (id, policydbp->p_class_val_to_name[i])) { if (!suppress) { yyerror2("permission %s of class %s is" " not within scope", id, policydbp->p_class_val_to_name[i]); } continue; } else { cur_perms->data |= 1U << (perdatum->s.value - 1); } next: cur_perms = cur_perms->next; } free(id); } ebitmap_destroy(&tclasses); avrule->perms = perms; *rule = avrule; out: return ret; } avrule_t *define_cond_te_avtab(int which) { char *id; avrule_t *avrule; int i; if (pass == 1) { for (i = 0; i < 4; i++) { while ((id = queue_remove(id_queue))) free(id); } return (avrule_t *) 1; /* any non-NULL value */ } if (define_te_avtab_helper(which, &avrule)) return COND_ERR; return avrule; } int define_te_avtab(int which) { char *id; avrule_t *avrule; int i; if (pass == 1) { for (i = 0; i < 4; i++) { while ((id = queue_remove(id_queue))) free(id); } return 0; } if (define_te_avtab_helper(which, &avrule)) return -1; /* append this avrule to the end of the current rules list */ append_avrule(avrule); return 0; } /* The role-types rule is no longer used to declare regular role or * role attribute, but solely aimed for declaring role-types associations. */ int define_role_types(void) { role_datum_t *role; char *id; int add = 1; if (pass == 1) { while ((id = queue_remove(id_queue))) free(id); return 0; } id = (char *)queue_remove(id_queue); if (!id) { yyerror("no role name for role-types rule?"); return -1; } if (!is_id_in_scope(SYM_ROLES, id)) { yyerror2("role %s is not within scope", id); free(id); return -1; } role = hashtab_search(policydbp->p_roles.table, id); if (!role) { yyerror2("unknown role %s", id); free(id); return -1; } while ((id = queue_remove(id_queue))) { if (set_types(&role->types, id, &add, 0)) return -1; } return 0; } int define_attrib_role(void) { if (pass == 2) { free(queue_remove(id_queue)); return 0; } /* Declare a role attribute */ if (declare_role(TRUE) == NULL) return -1; return 0; } int define_role_attr(void) { char *id; role_datum_t *r, *attr; if (pass == 2) { while ((id = queue_remove(id_queue))) free(id); return 0; } /* Declare a regular role */ if ((r = declare_role(FALSE)) == NULL) return -1; while ((id = queue_remove(id_queue))) { if (!is_id_in_scope(SYM_ROLES, id)) { yyerror2("attribute %s is not within scope", id); free(id); return -1; } attr = hashtab_search(policydbp->p_roles.table, id); if (!attr) { /* treat it as a fatal error */ yyerror2("role attribute %s is not declared", id); free(id); return -1; } if (attr->flavor != ROLE_ATTRIB) { yyerror2("%s is a regular role, not an attribute", id); free(id); return -1; } if ((attr = get_local_role(id, attr->s.value, 1)) == NULL) { yyerror("Out of memory!"); return -1; } if (ebitmap_set_bit(&attr->roles, (r->s.value - 1), TRUE)) { yyerror("out of memory"); return -1; } } return 0; } int define_roleattribute(void) { char *id; role_datum_t *r, *attr; if (pass == 2) { while ((id = queue_remove(id_queue))) free(id); return 0; } id = (char *)queue_remove(id_queue); if (!id) { yyerror("no role name for roleattribute definition?"); return -1; } if (!is_id_in_scope(SYM_ROLES, id)) { yyerror2("role %s is not within scope", id); free(id); return -1; } r = hashtab_search(policydbp->p_roles.table, id); /* We support adding one role attribute into another */ if (!r) { yyerror2("unknown role %s", id); free(id); return -1; } while ((id = queue_remove(id_queue))) { if (!is_id_in_scope(SYM_ROLES, id)) { yyerror2("attribute %s is not within scope", id); free(id); return -1; } attr = hashtab_search(policydbp->p_roles.table, id); if (!attr) { /* treat it as a fatal error */ yyerror2("role attribute %s is not declared", id); free(id); return -1; } if (attr->flavor != ROLE_ATTRIB) { yyerror2("%s is a regular role, not an attribute", id); free(id); return -1; } if ((attr = get_local_role(id, attr->s.value, 1)) == NULL) { yyerror("Out of memory!"); return -1; } if (ebitmap_set_bit(&attr->roles, (r->s.value - 1), TRUE)) { yyerror("out of memory"); return -1; } } return 0; } role_datum_t *merge_roles_dom(role_datum_t * r1, role_datum_t * r2) { role_datum_t *new; if (pass == 1) { return (role_datum_t *) 1; /* any non-NULL value */ } new = malloc(sizeof(role_datum_t)); if (!new) { yyerror("out of memory"); return NULL; } memset(new, 0, sizeof(role_datum_t)); new->s.value = 0; /* temporary role */ if (ebitmap_or(&new->dominates, &r1->dominates, &r2->dominates)) { yyerror("out of memory"); free(new); return NULL; } if (ebitmap_or(&new->types.types, &r1->types.types, &r2->types.types)) { yyerror("out of memory"); free(new); return NULL; } if (!r1->s.value) { /* free intermediate result */ type_set_destroy(&r1->types); ebitmap_destroy(&r1->dominates); free(r1); } if (!r2->s.value) { /* free intermediate result */ yyerror("right hand role is temporary?"); type_set_destroy(&r2->types); ebitmap_destroy(&r2->dominates); free(r2); } return new; } /* This function eliminates the ordering dependency of role dominance rule */ static int dominate_role_recheck(hashtab_key_t key __attribute__ ((unused)), hashtab_datum_t datum, void *arg) { role_datum_t *rdp = (role_datum_t *) arg; role_datum_t *rdatum = (role_datum_t *) datum; ebitmap_node_t *node; uint32_t i; /* Don't bother to process against self role */ if (rdatum->s.value == rdp->s.value) return 0; /* If a dominating role found */ if (ebitmap_get_bit(&(rdatum->dominates), rdp->s.value - 1)) { ebitmap_t types; ebitmap_init(&types); if (type_set_expand(&rdp->types, &types, policydbp, 1)) { ebitmap_destroy(&types); return -1; } /* raise types and dominates from dominated role */ ebitmap_for_each_bit(&rdp->dominates, node, i) { if (ebitmap_node_get_bit(node, i)) if (ebitmap_set_bit (&rdatum->dominates, i, TRUE)) goto oom; } ebitmap_for_each_bit(&types, node, i) { if (ebitmap_node_get_bit(node, i)) if (ebitmap_set_bit (&rdatum->types.types, i, TRUE)) goto oom; } ebitmap_destroy(&types); } /* go through all the roles */ return 0; oom: yyerror("Out of memory"); return -1; } role_datum_t *define_role_dom(role_datum_t * r) { role_datum_t *role; char *role_id; ebitmap_node_t *node; unsigned int i; int ret; if (pass == 1) { role_id = queue_remove(id_queue); free(role_id); return (role_datum_t *) 1; /* any non-NULL value */ } yywarn("Role dominance has been deprecated"); role_id = queue_remove(id_queue); if (!is_id_in_scope(SYM_ROLES, role_id)) { yyerror2("role %s is not within scope", role_id); free(role_id); return NULL; } role = (role_datum_t *) hashtab_search(policydbp->p_roles.table, role_id); if (!role) { role = (role_datum_t *) malloc(sizeof(role_datum_t)); if (!role) { yyerror("out of memory"); free(role_id); return NULL; } memset(role, 0, sizeof(role_datum_t)); ret = declare_symbol(SYM_ROLES, (hashtab_key_t) role_id, (hashtab_datum_t) role, &role->s.value, &role->s.value); switch (ret) { case -3:{ yyerror("Out of memory!"); goto cleanup; } case -2:{ yyerror2("duplicate declaration of role %s", role_id); goto cleanup; } case -1:{ yyerror("could not declare role here"); goto cleanup; } case 0: case 1:{ break; } default:{ assert(0); /* should never get here */ } } if (ebitmap_set_bit(&role->dominates, role->s.value - 1, TRUE)) { yyerror("Out of memory!"); goto cleanup; } } if (r) { ebitmap_t types; ebitmap_init(&types); ebitmap_for_each_bit(&r->dominates, node, i) { if (ebitmap_node_get_bit(node, i)) if (ebitmap_set_bit(&role->dominates, i, TRUE)) goto oom; } if (type_set_expand(&r->types, &types, policydbp, 1)) { ebitmap_destroy(&types); return NULL; } ebitmap_for_each_bit(&types, node, i) { if (ebitmap_node_get_bit(node, i)) if (ebitmap_set_bit (&role->types.types, i, TRUE)) goto oom; } ebitmap_destroy(&types); if (!r->s.value) { /* free intermediate result */ type_set_destroy(&r->types); ebitmap_destroy(&r->dominates); free(r); } /* * Now go through all the roles and escalate this role's * dominates and types if a role dominates this role. */ hashtab_map(policydbp->p_roles.table, dominate_role_recheck, role); } return role; cleanup: free(role_id); role_datum_destroy(role); free(role); return NULL; oom: yyerror("Out of memory"); goto cleanup; } static int role_val_to_name_helper(hashtab_key_t key, hashtab_datum_t datum, void *p) { struct val_to_name *v = p; role_datum_t *roldatum; roldatum = (role_datum_t *) datum; if (v->val == roldatum->s.value) { v->name = key; return 1; } return 0; } static char *role_val_to_name(unsigned int val) { struct val_to_name v; int rc; v.val = val; rc = hashtab_map(policydbp->p_roles.table, role_val_to_name_helper, &v); if (rc) return v.name; return NULL; } static int set_roles(role_set_t * set, char *id) { role_datum_t *r; if (strcmp(id, "*") == 0) { free(id); yyerror("* is not allowed for role sets"); return -1; } if (strcmp(id, "~") == 0) { free(id); yyerror("~ is not allowed for role sets"); return -1; } if (!is_id_in_scope(SYM_ROLES, id)) { yyerror2("role %s is not within scope", id); free(id); return -1; } r = hashtab_search(policydbp->p_roles.table, id); if (!r) { yyerror2("unknown role %s", id); free(id); return -1; } if (ebitmap_set_bit(&set->roles, r->s.value - 1, TRUE)) { yyerror("out of memory"); free(id); return -1; } free(id); return 0; } int define_role_trans(int class_specified) { char *id; role_datum_t *role; role_set_t roles; type_set_t types; class_datum_t *cladatum; ebitmap_t e_types, e_roles, e_classes; ebitmap_node_t *tnode, *rnode, *cnode; struct role_trans *tr = NULL; struct role_trans_rule *rule = NULL; unsigned int i, j, k; int add = 1; if (pass == 1) { while ((id = queue_remove(id_queue))) free(id); while ((id = queue_remove(id_queue))) free(id); if (class_specified) while ((id = queue_remove(id_queue))) free(id); id = queue_remove(id_queue); free(id); return 0; } role_set_init(&roles); ebitmap_init(&e_roles); type_set_init(&types); ebitmap_init(&e_types); ebitmap_init(&e_classes); while ((id = queue_remove(id_queue))) { if (set_roles(&roles, id)) return -1; } add = 1; while ((id = queue_remove(id_queue))) { if (set_types(&types, id, &add, 0)) return -1; } if (class_specified) { if (read_classes(&e_classes)) return -1; } else { cladatum = hashtab_search(policydbp->p_classes.table, "process"); if (!cladatum) { yyerror2("could not find process class for " "legacy role_transition statement"); return -1; } if (ebitmap_set_bit(&e_classes, cladatum->s.value - 1, TRUE)) { yyerror("out of memory"); return -1; } } id = (char *)queue_remove(id_queue); if (!id) { yyerror("no new role in transition definition?"); goto bad; } if (!is_id_in_scope(SYM_ROLES, id)) { yyerror2("role %s is not within scope", id); free(id); goto bad; } role = hashtab_search(policydbp->p_roles.table, id); if (!role) { yyerror2("unknown role %s used in transition definition", id); goto bad; } if (role->flavor != ROLE_ROLE) { yyerror2("the new role %s must be a regular role", id); goto bad; } /* This ebitmap business is just to ensure that there are not conflicting role_trans rules */ if (role_set_expand(&roles, &e_roles, policydbp, NULL, NULL)) goto bad; if (type_set_expand(&types, &e_types, policydbp, 1)) goto bad; ebitmap_for_each_bit(&e_roles, rnode, i) { if (!ebitmap_node_get_bit(rnode, i)) continue; ebitmap_for_each_bit(&e_types, tnode, j) { if (!ebitmap_node_get_bit(tnode, j)) continue; ebitmap_for_each_bit(&e_classes, cnode, k) { if (!ebitmap_node_get_bit(cnode, k)) continue; for (tr = policydbp->role_tr; tr; tr = tr->next) { if (tr->role == (i + 1) && tr->type == (j + 1) && tr->tclass == (k + 1)) { yyerror2("duplicate role " "transition for " "(%s,%s,%s)", role_val_to_name(i+1), policydbp->p_type_val_to_name[j], policydbp->p_class_val_to_name[k]); goto bad; } } tr = malloc(sizeof(struct role_trans)); if (!tr) { yyerror("out of memory"); return -1; } memset(tr, 0, sizeof(struct role_trans)); tr->role = i + 1; tr->type = j + 1; tr->tclass = k + 1; tr->new_role = role->s.value; tr->next = policydbp->role_tr; policydbp->role_tr = tr; } } } /* Now add the real rule */ rule = malloc(sizeof(struct role_trans_rule)); if (!rule) { yyerror("out of memory"); return -1; } memset(rule, 0, sizeof(struct role_trans_rule)); rule->roles = roles; rule->types = types; rule->classes = e_classes; rule->new_role = role->s.value; append_role_trans(rule); ebitmap_destroy(&e_roles); ebitmap_destroy(&e_types); return 0; bad: return -1; } int define_role_allow(void) { char *id; struct role_allow_rule *ra = 0; if (pass == 1) { while ((id = queue_remove(id_queue))) free(id); while ((id = queue_remove(id_queue))) free(id); return 0; } ra = malloc(sizeof(role_allow_rule_t)); if (!ra) { yyerror("out of memory"); return -1; } role_allow_rule_init(ra); while ((id = queue_remove(id_queue))) { if (set_roles(&ra->roles, id)) { free(ra); return -1; } } while ((id = queue_remove(id_queue))) { if (set_roles(&ra->new_roles, id)) { free(ra); return -1; } } append_role_allow(ra); return 0; } avrule_t *define_cond_filename_trans(void) { yyerror("type transitions with a filename not allowed inside " "conditionals\n"); return COND_ERR; } int define_filename_trans(void) { char *id, *name = NULL; type_set_t stypes, ttypes; ebitmap_t e_stypes, e_ttypes; ebitmap_t e_tclasses; ebitmap_node_t *snode, *tnode, *cnode; filename_trans_t *ft; filename_trans_rule_t *ftr; type_datum_t *typdatum; uint32_t otype; unsigned int c, s, t; int add; if (pass == 1) { /* stype */ while ((id = queue_remove(id_queue))) free(id); /* ttype */ while ((id = queue_remove(id_queue))) free(id); /* tclass */ while ((id = queue_remove(id_queue))) free(id); /* otype */ id = queue_remove(id_queue); free(id); /* name */ id = queue_remove(id_queue); free(id); return 0; } add = 1; type_set_init(&stypes); while ((id = queue_remove(id_queue))) { if (set_types(&stypes, id, &add, 0)) goto bad; } add =1; type_set_init(&ttypes); while ((id = queue_remove(id_queue))) { if (set_types(&ttypes, id, &add, 0)) goto bad; } ebitmap_init(&e_tclasses); if (read_classes(&e_tclasses)) goto bad; id = (char *)queue_remove(id_queue); if (!id) { yyerror("no otype in transition definition?"); goto bad; } if (!is_id_in_scope(SYM_TYPES, id)) { yyerror2("type %s is not within scope", id); free(id); goto bad; } typdatum = hashtab_search(policydbp->p_types.table, id); if (!typdatum) { yyerror2("unknown type %s used in transition definition", id); goto bad; } free(id); otype = typdatum->s.value; name = queue_remove(id_queue); if (!name) { yyerror("no pathname specified in filename_trans definition?"); goto bad; } /* We expand the class set into seperate rules. We expand the types * just to make sure there are not duplicates. They will get turned * into seperate rules later */ ebitmap_init(&e_stypes); if (type_set_expand(&stypes, &e_stypes, policydbp, 1)) goto bad; ebitmap_init(&e_ttypes); if (type_set_expand(&ttypes, &e_ttypes, policydbp, 1)) goto bad; ebitmap_for_each_bit(&e_tclasses, cnode, c) { if (!ebitmap_node_get_bit(cnode, c)) continue; ebitmap_for_each_bit(&e_stypes, snode, s) { if (!ebitmap_node_get_bit(snode, s)) continue; ebitmap_for_each_bit(&e_ttypes, tnode, t) { if (!ebitmap_node_get_bit(tnode, t)) continue; for (ft = policydbp->filename_trans; ft; ft = ft->next) { if (ft->stype == (s + 1) && ft->ttype == (t + 1) && ft->tclass == (c + 1) && !strcmp(ft->name, name)) { yyerror2("duplicate filename transition for: filename_trans %s %s %s:%s", name, policydbp->p_type_val_to_name[s], policydbp->p_type_val_to_name[t], policydbp->p_class_val_to_name[c]); goto bad; } } ft = malloc(sizeof(*ft)); if (!ft) { yyerror("out of memory"); goto bad; } memset(ft, 0, sizeof(*ft)); ft->next = policydbp->filename_trans; policydbp->filename_trans = ft; ft->name = strdup(name); if (!ft->name) { yyerror("out of memory"); goto bad; } ft->stype = s + 1; ft->ttype = t + 1; ft->tclass = c + 1; ft->otype = otype; } } /* Now add the real rule since we didn't find any duplicates */ ftr = malloc(sizeof(*ftr)); if (!ftr) { yyerror("out of memory"); goto bad; } filename_trans_rule_init(ftr); append_filename_trans(ftr); ftr->name = strdup(name); ftr->stypes = stypes; ftr->ttypes = ttypes; ftr->tclass = c + 1; ftr->otype = otype; } free(name); ebitmap_destroy(&e_stypes); ebitmap_destroy(&e_ttypes); ebitmap_destroy(&e_tclasses); return 0; bad: free(name); return -1; } static constraint_expr_t *constraint_expr_clone(constraint_expr_t * expr) { constraint_expr_t *h = NULL, *l = NULL, *e, *newe; for (e = expr; e; e = e->next) { newe = malloc(sizeof(*newe)); if (!newe) goto oom; if (constraint_expr_init(newe) == -1) { free(newe); goto oom; } if (l) l->next = newe; else h = newe; l = newe; newe->expr_type = e->expr_type; newe->attr = e->attr; newe->op = e->op; if (newe->expr_type == CEXPR_NAMES) { if (newe->attr & CEXPR_TYPE) { if (type_set_cpy (newe->type_names, e->type_names)) goto oom; } else { if (ebitmap_cpy(&newe->names, &e->names)) goto oom; } } } return h; oom: e = h; while (e) { l = e; e = e->next; constraint_expr_destroy(l); } return NULL; } int define_constraint(constraint_expr_t * expr) { struct constraint_node *node; char *id; class_datum_t *cladatum; perm_datum_t *perdatum; ebitmap_t classmap; ebitmap_node_t *enode; constraint_expr_t *e; unsigned int i; int depth; unsigned char useexpr = 1; if (pass == 1) { while ((id = queue_remove(id_queue))) free(id); while ((id = queue_remove(id_queue))) free(id); return 0; } depth = -1; for (e = expr; e; e = e->next) { switch (e->expr_type) { case CEXPR_NOT: if (depth < 0) { yyerror("illegal constraint expression"); return -1; } break; case CEXPR_AND: case CEXPR_OR: if (depth < 1) { yyerror("illegal constraint expression"); return -1; } depth--; break; case CEXPR_ATTR: case CEXPR_NAMES: if (e->attr & CEXPR_XTARGET) { yyerror("illegal constraint expression"); return -1; /* only for validatetrans rules */ } if (depth == (CEXPR_MAXDEPTH - 1)) { yyerror("constraint expression is too deep"); return -1; } depth++; break; default: yyerror("illegal constraint expression"); return -1; } } if (depth != 0) { yyerror("illegal constraint expression"); return -1; } ebitmap_init(&classmap); while ((id = queue_remove(id_queue))) { if (!is_id_in_scope(SYM_CLASSES, id)) { yyerror2("class %s is not within scope", id); free(id); return -1; } cladatum = (class_datum_t *) hashtab_search(policydbp->p_classes.table, (hashtab_key_t) id); if (!cladatum) { yyerror2("class %s is not defined", id); ebitmap_destroy(&classmap); free(id); return -1; } if (ebitmap_set_bit(&classmap, cladatum->s.value - 1, TRUE)) { yyerror("out of memory"); ebitmap_destroy(&classmap); free(id); return -1; } node = malloc(sizeof(struct constraint_node)); if (!node) { yyerror("out of memory"); free(node); return -1; } memset(node, 0, sizeof(constraint_node_t)); if (useexpr) { node->expr = expr; useexpr = 0; } else { node->expr = constraint_expr_clone(expr); } if (!node->expr) { yyerror("out of memory"); free(node); return -1; } node->permissions = 0; node->next = cladatum->constraints; cladatum->constraints = node; free(id); } while ((id = queue_remove(id_queue))) { ebitmap_for_each_bit(&classmap, enode, i) { if (ebitmap_node_get_bit(enode, i)) { cladatum = policydbp->class_val_to_struct[i]; node = cladatum->constraints; perdatum = (perm_datum_t *) hashtab_search(cladatum-> permissions. table, (hashtab_key_t) id); if (!perdatum) { if (cladatum->comdatum) { perdatum = (perm_datum_t *) hashtab_search(cladatum-> comdatum-> permissions. table, (hashtab_key_t) id); } if (!perdatum) { yyerror2("permission %s is not" " defined", id); free(id); ebitmap_destroy(&classmap); return -1; } } node->permissions |= (1 << (perdatum->s.value - 1)); } } free(id); } ebitmap_destroy(&classmap); return 0; } int define_validatetrans(constraint_expr_t * expr) { struct constraint_node *node; char *id; class_datum_t *cladatum; ebitmap_t classmap; constraint_expr_t *e; int depth; unsigned char useexpr = 1; if (pass == 1) { while ((id = queue_remove(id_queue))) free(id); return 0; } depth = -1; for (e = expr; e; e = e->next) { switch (e->expr_type) { case CEXPR_NOT: if (depth < 0) { yyerror("illegal validatetrans expression"); return -1; } break; case CEXPR_AND: case CEXPR_OR: if (depth < 1) { yyerror("illegal validatetrans expression"); return -1; } depth--; break; case CEXPR_ATTR: case CEXPR_NAMES: if (depth == (CEXPR_MAXDEPTH - 1)) { yyerror("validatetrans expression is too deep"); return -1; } depth++; break; default: yyerror("illegal validatetrans expression"); return -1; } } if (depth != 0) { yyerror("illegal validatetrans expression"); return -1; } ebitmap_init(&classmap); while ((id = queue_remove(id_queue))) { if (!is_id_in_scope(SYM_CLASSES, id)) { yyerror2("class %s is not within scope", id); free(id); return -1; } cladatum = (class_datum_t *) hashtab_search(policydbp->p_classes.table, (hashtab_key_t) id); if (!cladatum) { yyerror2("class %s is not defined", id); ebitmap_destroy(&classmap); free(id); return -1; } if (ebitmap_set_bit(&classmap, (cladatum->s.value - 1), TRUE)) { yyerror("out of memory"); ebitmap_destroy(&classmap); free(id); return -1; } node = malloc(sizeof(struct constraint_node)); if (!node) { yyerror("out of memory"); return -1; } memset(node, 0, sizeof(constraint_node_t)); if (useexpr) { node->expr = expr; useexpr = 0; } else { node->expr = constraint_expr_clone(expr); } node->permissions = 0; node->next = cladatum->validatetrans; cladatum->validatetrans = node; free(id); } ebitmap_destroy(&classmap); return 0; } uintptr_t define_cexpr(uint32_t expr_type, uintptr_t arg1, uintptr_t arg2) { struct constraint_expr *expr, *e1 = NULL, *e2; user_datum_t *user; role_datum_t *role; ebitmap_t negset; char *id; uint32_t val; int add = 1; if (pass == 1) { if (expr_type == CEXPR_NAMES) { while ((id = queue_remove(id_queue))) free(id); } return 1; /* any non-NULL value */ } if ((expr = malloc(sizeof(*expr))) == NULL || constraint_expr_init(expr) == -1) { yyerror("out of memory"); free(expr); return 0; } expr->expr_type = expr_type; switch (expr_type) { case CEXPR_NOT: e1 = NULL; e2 = (struct constraint_expr *)arg1; while (e2) { e1 = e2; e2 = e2->next; } if (!e1 || e1->next) { yyerror("illegal constraint expression"); constraint_expr_destroy(expr); return 0; } e1->next = expr; return arg1; case CEXPR_AND: case CEXPR_OR: e1 = NULL; e2 = (struct constraint_expr *)arg1; while (e2) { e1 = e2; e2 = e2->next; } if (!e1 || e1->next) { yyerror("illegal constraint expression"); constraint_expr_destroy(expr); return 0; } e1->next = (struct constraint_expr *)arg2; e1 = NULL; e2 = (struct constraint_expr *)arg2; while (e2) { e1 = e2; e2 = e2->next; } if (!e1 || e1->next) { yyerror("illegal constraint expression"); constraint_expr_destroy(expr); return 0; } e1->next = expr; return arg1; case CEXPR_ATTR: expr->attr = arg1; expr->op = arg2; return (uintptr_t) expr; case CEXPR_NAMES: add = 1; expr->attr = arg1; expr->op = arg2; ebitmap_init(&negset); while ((id = (char *)queue_remove(id_queue))) { if (expr->attr & CEXPR_USER) { if (!is_id_in_scope(SYM_USERS, id)) { yyerror2("user %s is not within scope", id); constraint_expr_destroy(expr); return 0; } user = (user_datum_t *) hashtab_search(policydbp-> p_users. table, (hashtab_key_t) id); if (!user) { yyerror2("unknown user %s", id); constraint_expr_destroy(expr); return 0; } val = user->s.value; } else if (expr->attr & CEXPR_ROLE) { if (!is_id_in_scope(SYM_ROLES, id)) { yyerror2("role %s is not within scope", id); constraint_expr_destroy(expr); return 0; } role = (role_datum_t *) hashtab_search(policydbp-> p_roles. table, (hashtab_key_t) id); if (!role) { yyerror2("unknown role %s", id); constraint_expr_destroy(expr); return 0; } val = role->s.value; } else if (expr->attr & CEXPR_TYPE) { if (set_types(expr->type_names, id, &add, 0)) { constraint_expr_destroy(expr); return 0; } continue; } else { yyerror("invalid constraint expression"); constraint_expr_destroy(expr); return 0; } if (ebitmap_set_bit(&expr->names, val - 1, TRUE)) { yyerror("out of memory"); ebitmap_destroy(&expr->names); constraint_expr_destroy(expr); return 0; } free(id); } ebitmap_destroy(&negset); return (uintptr_t) expr; default: break; } yyerror("invalid constraint expression"); constraint_expr_destroy(expr); return 0; } int define_conditional(cond_expr_t * expr, avrule_t * t, avrule_t * f) { cond_expr_t *e; int depth; cond_node_t cn, *cn_old; /* expression cannot be NULL */ if (!expr) { yyerror("illegal conditional expression"); return -1; } if (!t) { if (!f) { /* empty is fine, destroy expression and return */ cond_expr_destroy(expr); return 0; } /* Invert */ t = f; f = 0; expr = define_cond_expr(COND_NOT, expr, 0); if (!expr) { yyerror("unable to invert"); return -1; } } /* verify expression */ depth = -1; for (e = expr; e; e = e->next) { switch (e->expr_type) { case COND_NOT: if (depth < 0) { yyerror ("illegal conditional expression; Bad NOT"); return -1; } break; case COND_AND: case COND_OR: case COND_XOR: case COND_EQ: case COND_NEQ: if (depth < 1) { yyerror ("illegal conditional expression; Bad binary op"); return -1; } depth--; break; case COND_BOOL: if (depth == (COND_EXPR_MAXDEPTH - 1)) { yyerror ("conditional expression is like totally too deep"); return -1; } depth++; break; default: yyerror("illegal conditional expression"); return -1; } } if (depth != 0) { yyerror("illegal conditional expression"); return -1; } /* use tmp conditional node to partially build new node */ memset(&cn, 0, sizeof(cn)); cn.expr = expr; cn.avtrue_list = t; cn.avfalse_list = f; /* normalize/precompute expression */ if (cond_normalize_expr(policydbp, &cn) < 0) { yyerror("problem normalizing conditional expression"); return -1; } /* get the existing conditional node, or create a new one */ cn_old = get_current_cond_list(&cn); if (!cn_old) { return -1; } append_cond_list(&cn); /* note that there is no check here for duplicate rules, nor * check that rule already exists in base -- that will be * handled during conditional expansion, in expand.c */ cn.avtrue_list = NULL; cn.avfalse_list = NULL; cond_node_destroy(&cn); return 0; } cond_expr_t *define_cond_expr(uint32_t expr_type, void *arg1, void *arg2) { struct cond_expr *expr, *e1 = NULL, *e2; cond_bool_datum_t *bool_var; char *id; /* expressions are handled in the second pass */ if (pass == 1) { if (expr_type == COND_BOOL) { while ((id = queue_remove(id_queue))) { free(id); } } return (cond_expr_t *) 1; /* any non-NULL value */ } /* create a new expression struct */ expr = malloc(sizeof(struct cond_expr)); if (!expr) { yyerror("out of memory"); return NULL; } memset(expr, 0, sizeof(cond_expr_t)); expr->expr_type = expr_type; /* create the type asked for */ switch (expr_type) { case COND_NOT: e1 = NULL; e2 = (struct cond_expr *)arg1; while (e2) { e1 = e2; e2 = e2->next; } if (!e1 || e1->next) { yyerror("illegal conditional NOT expression"); free(expr); return NULL; } e1->next = expr; return (struct cond_expr *)arg1; case COND_AND: case COND_OR: case COND_XOR: case COND_EQ: case COND_NEQ: e1 = NULL; e2 = (struct cond_expr *)arg1; while (e2) { e1 = e2; e2 = e2->next; } if (!e1 || e1->next) { yyerror ("illegal left side of conditional binary op expression"); free(expr); return NULL; } e1->next = (struct cond_expr *)arg2; e1 = NULL; e2 = (struct cond_expr *)arg2; while (e2) { e1 = e2; e2 = e2->next; } if (!e1 || e1->next) { yyerror ("illegal right side of conditional binary op expression"); free(expr); return NULL; } e1->next = expr; return (struct cond_expr *)arg1; case COND_BOOL: id = (char *)queue_remove(id_queue); if (!id) { yyerror("bad conditional; expected boolean id"); free(id); free(expr); return NULL; } if (!is_id_in_scope(SYM_BOOLS, id)) { yyerror2("boolean %s is not within scope", id); free(id); free(expr); return NULL; } bool_var = (cond_bool_datum_t *) hashtab_search(policydbp->p_bools. table, (hashtab_key_t) id); if (!bool_var) { yyerror2("unknown boolean %s in conditional expression", id); free(expr); free(id); return NULL; } expr->bool = bool_var->s.value; free(id); return expr; default: yyerror("illegal conditional expression"); free(expr); return NULL; } } static int set_user_roles(role_set_t * set, char *id) { role_datum_t *r; unsigned int i; ebitmap_node_t *node; if (strcmp(id, "*") == 0) { free(id); yyerror("* is not allowed in user declarations"); return -1; } if (strcmp(id, "~") == 0) { free(id); yyerror("~ is not allowed in user declarations"); return -1; } if (!is_id_in_scope(SYM_ROLES, id)) { yyerror2("role %s is not within scope", id); free(id); return -1; } r = hashtab_search(policydbp->p_roles.table, id); if (!r) { yyerror2("unknown role %s", id); free(id); return -1; } /* set the role and every role it dominates */ ebitmap_for_each_bit(&r->dominates, node, i) { if (ebitmap_node_get_bit(node, i)) if (ebitmap_set_bit(&set->roles, i, TRUE)) goto oom; } free(id); return 0; oom: yyerror("out of memory"); return -1; } static int parse_categories(char *id, level_datum_t * levdatum, ebitmap_t * cats) { cat_datum_t *cdatum; int range_start, range_end, i; if (id_has_dot(id)) { char *id_start = id; char *id_end = strchr(id, '.'); *(id_end++) = '\0'; cdatum = (cat_datum_t *) hashtab_search(policydbp->p_cats.table, (hashtab_key_t) id_start); if (!cdatum) { yyerror2("unknown category %s", id_start); return -1; } range_start = cdatum->s.value - 1; cdatum = (cat_datum_t *) hashtab_search(policydbp->p_cats.table, (hashtab_key_t) id_end); if (!cdatum) { yyerror2("unknown category %s", id_end); return -1; } range_end = cdatum->s.value - 1; if (range_end < range_start) { yyerror2("category range is invalid"); return -1; } } else { cdatum = (cat_datum_t *) hashtab_search(policydbp->p_cats.table, (hashtab_key_t) id); if (!cdatum) { yyerror2("unknown category %s", id); return -1; } range_start = range_end = cdatum->s.value - 1; } for (i = range_start; i <= range_end; i++) { if (!ebitmap_get_bit(&levdatum->level->cat, i)) { uint32_t level_value = levdatum->level->sens - 1; policydb_index_others(NULL, policydbp, 0); yyerror2("category %s can not be associated " "with level %s", policydbp->p_cat_val_to_name[i], policydbp->p_sens_val_to_name[level_value]); return -1; } if (ebitmap_set_bit(cats, i, TRUE)) { yyerror("out of memory"); return -1; } } return 0; } static int parse_semantic_categories(char *id, level_datum_t * levdatum __attribute__ ((unused)), mls_semantic_cat_t ** cats) { cat_datum_t *cdatum; mls_semantic_cat_t *newcat; unsigned int range_start, range_end; if (id_has_dot(id)) { char *id_start = id; char *id_end = strchr(id, '.'); *(id_end++) = '\0'; cdatum = (cat_datum_t *) hashtab_search(policydbp->p_cats.table, (hashtab_key_t) id_start); if (!cdatum) { yyerror2("unknown category %s", id_start); return -1; } range_start = cdatum->s.value; cdatum = (cat_datum_t *) hashtab_search(policydbp->p_cats.table, (hashtab_key_t) id_end); if (!cdatum) { yyerror2("unknown category %s", id_end); return -1; } range_end = cdatum->s.value; } else { cdatum = (cat_datum_t *) hashtab_search(policydbp->p_cats.table, (hashtab_key_t) id); if (!cdatum) { yyerror2("unknown category %s", id); return -1; } range_start = range_end = cdatum->s.value; } newcat = (mls_semantic_cat_t *) malloc(sizeof(mls_semantic_cat_t)); if (!newcat) { yyerror("out of memory"); return -1; } mls_semantic_cat_init(newcat); newcat->next = *cats; newcat->low = range_start; newcat->high = range_end; *cats = newcat; return 0; } int define_user(void) { char *id; user_datum_t *usrdatum; level_datum_t *levdatum; int l; if (pass == 1) { while ((id = queue_remove(id_queue))) free(id); if (mlspol) { while ((id = queue_remove(id_queue))) free(id); id = queue_remove(id_queue); free(id); for (l = 0; l < 2; l++) { while ((id = queue_remove(id_queue))) { free(id); } id = queue_remove(id_queue); if (!id) break; free(id); } } return 0; } if ((usrdatum = declare_user()) == NULL) { return -1; } while ((id = queue_remove(id_queue))) { if (set_user_roles(&usrdatum->roles, id)) continue; } if (mlspol) { id = queue_remove(id_queue); if (!id) { yyerror("no default level specified for user"); return -1; } levdatum = (level_datum_t *) hashtab_search(policydbp->p_levels.table, (hashtab_key_t) id); if (!levdatum) { yyerror2("unknown sensitivity %s used in user" " level definition", id); free(id); return -1; } free(id); usrdatum->dfltlevel.sens = levdatum->level->sens; while ((id = queue_remove(id_queue))) { if (parse_semantic_categories(id, levdatum, &usrdatum->dfltlevel.cat)) { free(id); return -1; } free(id); } id = queue_remove(id_queue); for (l = 0; l < 2; l++) { levdatum = (level_datum_t *) hashtab_search(policydbp->p_levels.table, (hashtab_key_t) id); if (!levdatum) { yyerror2("unknown sensitivity %s used in user" " range definition", id); free(id); return -1; } free(id); usrdatum->range.level[l].sens = levdatum->level->sens; while ((id = queue_remove(id_queue))) { if (parse_semantic_categories(id, levdatum, &usrdatum->range.level[l].cat)) { free(id); return -1; } free(id); } id = queue_remove(id_queue); if (!id) break; } if (l == 0) { if (mls_semantic_level_cpy(&usrdatum->range.level[1], &usrdatum->range.level[0])) { yyerror("out of memory"); return -1; } } } return 0; } static int parse_security_context(context_struct_t * c) { char *id; role_datum_t *role; type_datum_t *typdatum; user_datum_t *usrdatum; level_datum_t *levdatum; int l; if (pass == 1) { id = queue_remove(id_queue); free(id); /* user */ id = queue_remove(id_queue); free(id); /* role */ id = queue_remove(id_queue); free(id); /* type */ if (mlspol) { id = queue_remove(id_queue); free(id); for (l = 0; l < 2; l++) { while ((id = queue_remove(id_queue))) { free(id); } id = queue_remove(id_queue); if (!id) break; free(id); } } return 0; } /* check context c to make sure ok to dereference c later */ if (c == NULL) { yyerror("null context pointer!"); return -1; } context_init(c); /* extract the user */ id = queue_remove(id_queue); if (!id) { yyerror("no effective user?"); goto bad; } if (!is_id_in_scope(SYM_USERS, id)) { yyerror2("user %s is not within scope", id); free(id); goto bad; } usrdatum = (user_datum_t *) hashtab_search(policydbp->p_users.table, (hashtab_key_t) id); if (!usrdatum) { yyerror2("user %s is not defined", id); free(id); goto bad; } c->user = usrdatum->s.value; /* no need to keep the user name */ free(id); /* extract the role */ id = (char *)queue_remove(id_queue); if (!id) { yyerror("no role name for sid context definition?"); return -1; } if (!is_id_in_scope(SYM_ROLES, id)) { yyerror2("role %s is not within scope", id); free(id); return -1; } role = (role_datum_t *) hashtab_search(policydbp->p_roles.table, (hashtab_key_t) id); if (!role) { yyerror2("role %s is not defined", id); free(id); return -1; } c->role = role->s.value; /* no need to keep the role name */ free(id); /* extract the type */ id = (char *)queue_remove(id_queue); if (!id) { yyerror("no type name for sid context definition?"); return -1; } if (!is_id_in_scope(SYM_TYPES, id)) { yyerror2("type %s is not within scope", id); free(id); return -1; } typdatum = (type_datum_t *) hashtab_search(policydbp->p_types.table, (hashtab_key_t) id); if (!typdatum || typdatum->flavor == TYPE_ATTRIB) { yyerror2("type %s is not defined or is an attribute", id); free(id); return -1; } c->type = typdatum->s.value; /* no need to keep the type name */ free(id); if (mlspol) { /* extract the low sensitivity */ id = (char *)queue_head(id_queue); if (!id) { yyerror("no sensitivity name for sid context" " definition?"); return -1; } id = (char *)queue_remove(id_queue); for (l = 0; l < 2; l++) { levdatum = (level_datum_t *) hashtab_search(policydbp->p_levels.table, (hashtab_key_t) id); if (!levdatum) { yyerror2("Sensitivity %s is not defined", id); free(id); return -1; } free(id); c->range.level[l].sens = levdatum->level->sens; /* extract low category set */ while ((id = queue_remove(id_queue))) { if (parse_categories(id, levdatum, &c->range.level[l].cat)) { free(id); return -1; } free(id); } /* extract high sensitivity */ id = (char *)queue_remove(id_queue); if (!id) break; } if (l == 0) { c->range.level[1].sens = c->range.level[0].sens; if (ebitmap_cpy(&c->range.level[1].cat, &c->range.level[0].cat)) { yyerror("out of memory"); goto bad; } } } if (!policydb_context_isvalid(policydbp, c)) { yyerror("invalid security context"); goto bad; } return 0; bad: context_destroy(c); return -1; } int define_initial_sid_context(void) { char *id; ocontext_t *c, *head; if (pass == 1) { id = (char *)queue_remove(id_queue); free(id); parse_security_context(NULL); return 0; } id = (char *)queue_remove(id_queue); if (!id) { yyerror("no sid name for SID context definition?"); return -1; } head = policydbp->ocontexts[OCON_ISID]; for (c = head; c; c = c->next) { if (!strcmp(id, c->u.name)) break; } if (!c) { yyerror2("SID %s is not defined", id); free(id); return -1; } if (c->context[0].user) { yyerror2("The context for SID %s is multiply defined", id); free(id); return -1; } /* no need to keep the sid name */ free(id); if (parse_security_context(&c->context[0])) return -1; return 0; } int define_fs_context(unsigned int major, unsigned int minor) { ocontext_t *newc, *c, *head; if (policydbp->target_platform != SEPOL_TARGET_SELINUX) { yyerror("fscon not supported for target"); return -1; } if (pass == 1) { parse_security_context(NULL); parse_security_context(NULL); return 0; } newc = (ocontext_t *) malloc(sizeof(ocontext_t)); if (!newc) { yyerror("out of memory"); return -1; } memset(newc, 0, sizeof(ocontext_t)); newc->u.name = (char *)malloc(6); if (!newc->u.name) { yyerror("out of memory"); free(newc); return -1; } sprintf(newc->u.name, "%02x:%02x", major, minor); if (parse_security_context(&newc->context[0])) { free(newc->u.name); free(newc); return -1; } if (parse_security_context(&newc->context[1])) { context_destroy(&newc->context[0]); free(newc->u.name); free(newc); return -1; } head = policydbp->ocontexts[OCON_FS]; for (c = head; c; c = c->next) { if (!strcmp(newc->u.name, c->u.name)) { yyerror2("duplicate entry for file system %s", newc->u.name); context_destroy(&newc->context[0]); context_destroy(&newc->context[1]); free(newc->u.name); free(newc); return -1; } } newc->next = head; policydbp->ocontexts[OCON_FS] = newc; return 0; } int define_pirq_context(unsigned int pirq) { ocontext_t *newc, *c, *l, *head; char *id; if (policydbp->target_platform != SEPOL_TARGET_XEN) { yyerror("pirqcon not supported for target"); return -1; } if (pass == 1) { id = (char *) queue_remove(id_queue); free(id); parse_security_context(NULL); return 0; } newc = malloc(sizeof(ocontext_t)); if (!newc) { yyerror("out of memory"); return -1; } memset(newc, 0, sizeof(ocontext_t)); newc->u.pirq = pirq; if (parse_security_context(&newc->context[0])) { free(newc); return -1; } head = policydbp->ocontexts[OCON_XEN_PIRQ]; for (l = NULL, c = head; c; l = c, c = c->next) { unsigned int pirq2; pirq2 = c->u.pirq; if (pirq == pirq2) { yyerror2("duplicate pirqcon entry for %d ", pirq); goto bad; } } if (l) l->next = newc; else policydbp->ocontexts[OCON_XEN_PIRQ] = newc; return 0; bad: free(newc); return -1; } int define_iomem_context(uint64_t low, uint64_t high) { ocontext_t *newc, *c, *l, *head; char *id; if (policydbp->target_platform != SEPOL_TARGET_XEN) { yyerror("iomemcon not supported for target"); return -1; } if (pass == 1) { id = (char *)queue_remove(id_queue); free(id); parse_security_context(NULL); return 0; } newc = malloc(sizeof(ocontext_t)); if (!newc) { yyerror("out of memory"); return -1; } memset(newc, 0, sizeof(ocontext_t)); newc->u.iomem.low_iomem = low; newc->u.iomem.high_iomem = high; if (low > high) { yyerror2("low memory 0x%"PRIx64" exceeds high memory 0x%"PRIx64"", low, high); free(newc); return -1; } if (parse_security_context(&newc->context[0])) { free(newc); return -1; } head = policydbp->ocontexts[OCON_XEN_IOMEM]; for (l = NULL, c = head; c; l = c, c = c->next) { uint64_t low2, high2; low2 = c->u.iomem.low_iomem; high2 = c->u.iomem.high_iomem; if (low <= high2 && low2 <= high) { yyerror2("iomemcon entry for 0x%"PRIx64"-0x%"PRIx64" overlaps with " "earlier entry 0x%"PRIx64"-0x%"PRIx64"", low, high, low2, high2); goto bad; } } if (l) l->next = newc; else policydbp->ocontexts[OCON_XEN_IOMEM] = newc; return 0; bad: free(newc); return -1; } int define_ioport_context(unsigned long low, unsigned long high) { ocontext_t *newc, *c, *l, *head; char *id; if (policydbp->target_platform != SEPOL_TARGET_XEN) { yyerror("ioportcon not supported for target"); return -1; } if (pass == 1) { id = (char *)queue_remove(id_queue); free(id); parse_security_context(NULL); return 0; } newc = malloc(sizeof(ocontext_t)); if (!newc) { yyerror("out of memory"); return -1; } memset(newc, 0, sizeof(ocontext_t)); newc->u.ioport.low_ioport = low; newc->u.ioport.high_ioport = high; if (low > high) { yyerror2("low ioport 0x%lx exceeds high ioport 0x%lx", low, high); free(newc); return -1; } if (parse_security_context(&newc->context[0])) { free(newc); return -1; } head = policydbp->ocontexts[OCON_XEN_IOPORT]; for (l = NULL, c = head; c; l = c, c = c->next) { uint32_t low2, high2; low2 = c->u.ioport.low_ioport; high2 = c->u.ioport.high_ioport; if (low <= high2 && low2 <= high) { yyerror2("ioportcon entry for 0x%lx-0x%lx overlaps with" "earlier entry 0x%x-0x%x", low, high, low2, high2); goto bad; } } if (l) l->next = newc; else policydbp->ocontexts[OCON_XEN_IOPORT] = newc; return 0; bad: free(newc); return -1; } int define_pcidevice_context(unsigned long device) { ocontext_t *newc, *c, *l, *head; char *id; if (policydbp->target_platform != SEPOL_TARGET_XEN) { yyerror("pcidevicecon not supported for target"); return -1; } if (pass == 1) { id = (char *) queue_remove(id_queue); free(id); parse_security_context(NULL); return 0; } newc = malloc(sizeof(ocontext_t)); if (!newc) { yyerror("out of memory"); return -1; } memset(newc, 0, sizeof(ocontext_t)); newc->u.device = device; if (parse_security_context(&newc->context[0])) { free(newc); return -1; } head = policydbp->ocontexts[OCON_XEN_PCIDEVICE]; for (l = NULL, c = head; c; l = c, c = c->next) { unsigned int device2; device2 = c->u.device; if (device == device2) { yyerror2("duplicate pcidevicecon entry for 0x%lx", device); goto bad; } } if (l) l->next = newc; else policydbp->ocontexts[OCON_XEN_PCIDEVICE] = newc; return 0; bad: free(newc); return -1; } int define_devicetree_context() { ocontext_t *newc, *c, *l, *head; if (policydbp->target_platform != SEPOL_TARGET_XEN) { yyerror("devicetreecon not supported for target"); return -1; } if (pass == 1) { free(queue_remove(id_queue)); parse_security_context(NULL); return 0; } newc = malloc(sizeof(ocontext_t)); if (!newc) { yyerror("out of memory"); return -1; } memset(newc, 0, sizeof(ocontext_t)); newc->u.name = (char *)queue_remove(id_queue); if (!newc->u.name) { free(newc); return -1; } if (parse_security_context(&newc->context[0])) { free(newc->u.name); free(newc); return -1; } head = policydbp->ocontexts[OCON_XEN_DEVICETREE]; for (l = NULL, c = head; c; l = c, c = c->next) { if (strcmp(newc->u.name, c->u.name) == 0) { yyerror2("duplicate devicetree entry for '%s'", newc->u.name); goto bad; } } if (l) l->next = newc; else policydbp->ocontexts[OCON_XEN_DEVICETREE] = newc; return 0; bad: free(newc->u.name); free(newc); return -1; } int define_port_context(unsigned int low, unsigned int high) { ocontext_t *newc, *c, *l, *head; unsigned int protocol; char *id; if (policydbp->target_platform != SEPOL_TARGET_SELINUX) { yyerror("portcon not supported for target"); return -1; } if (pass == 1) { id = (char *)queue_remove(id_queue); free(id); parse_security_context(NULL); return 0; } newc = malloc(sizeof(ocontext_t)); if (!newc) { yyerror("out of memory"); return -1; } memset(newc, 0, sizeof(ocontext_t)); id = (char *)queue_remove(id_queue); if (!id) { free(newc); return -1; } if ((strcmp(id, "tcp") == 0) || (strcmp(id, "TCP") == 0)) { protocol = IPPROTO_TCP; } else if ((strcmp(id, "udp") == 0) || (strcmp(id, "UDP") == 0)) { protocol = IPPROTO_UDP; } else { yyerror2("unrecognized protocol %s", id); free(newc); return -1; } newc->u.port.protocol = protocol; newc->u.port.low_port = low; newc->u.port.high_port = high; if (low > high) { yyerror2("low port %d exceeds high port %d", low, high); free(newc); return -1; } if (parse_security_context(&newc->context[0])) { free(newc); return -1; } /* Preserve the matching order specified in the configuration. */ head = policydbp->ocontexts[OCON_PORT]; for (l = NULL, c = head; c; l = c, c = c->next) { unsigned int prot2, low2, high2; prot2 = c->u.port.protocol; low2 = c->u.port.low_port; high2 = c->u.port.high_port; if (protocol != prot2) continue; if (low == low2 && high == high2) { yyerror2("duplicate portcon entry for %s %d-%d ", id, low, high); goto bad; } if (low2 <= low && high2 >= high) { yyerror2("portcon entry for %s %d-%d hidden by earlier " "entry for %d-%d", id, low, high, low2, high2); goto bad; } } if (l) l->next = newc; else policydbp->ocontexts[OCON_PORT] = newc; return 0; bad: free(newc); return -1; } int define_netif_context(void) { ocontext_t *newc, *c, *head; if (policydbp->target_platform != SEPOL_TARGET_SELINUX) { yyerror("netifcon not supported for target"); return -1; } if (pass == 1) { free(queue_remove(id_queue)); parse_security_context(NULL); parse_security_context(NULL); return 0; } newc = (ocontext_t *) malloc(sizeof(ocontext_t)); if (!newc) { yyerror("out of memory"); return -1; } memset(newc, 0, sizeof(ocontext_t)); newc->u.name = (char *)queue_remove(id_queue); if (!newc->u.name) { free(newc); return -1; } if (parse_security_context(&newc->context[0])) { free(newc->u.name); free(newc); return -1; } if (parse_security_context(&newc->context[1])) { context_destroy(&newc->context[0]); free(newc->u.name); free(newc); return -1; } head = policydbp->ocontexts[OCON_NETIF]; for (c = head; c; c = c->next) { if (!strcmp(newc->u.name, c->u.name)) { yyerror2("duplicate entry for network interface %s", newc->u.name); context_destroy(&newc->context[0]); context_destroy(&newc->context[1]); free(newc->u.name); free(newc); return -1; } } newc->next = head; policydbp->ocontexts[OCON_NETIF] = newc; return 0; } int define_ipv4_node_context() { char *id; int rc = 0; struct in_addr addr, mask; ocontext_t *newc, *c, *l, *head; if (policydbp->target_platform != SEPOL_TARGET_SELINUX) { yyerror("nodecon not supported for target"); return -1; } if (pass == 1) { free(queue_remove(id_queue)); free(queue_remove(id_queue)); parse_security_context(NULL); goto out; } id = queue_remove(id_queue); if (!id) { yyerror("failed to read ipv4 address"); rc = -1; goto out; } rc = inet_pton(AF_INET, id, &addr); free(id); if (rc < 1) { yyerror("failed to parse ipv4 address"); if (rc == 0) rc = -1; goto out; } id = queue_remove(id_queue); if (!id) { yyerror("failed to read ipv4 address"); rc = -1; goto out; } rc = inet_pton(AF_INET, id, &mask); free(id); if (rc < 1) { yyerror("failed to parse ipv4 mask"); if (rc == 0) rc = -1; goto out; } newc = malloc(sizeof(ocontext_t)); if (!newc) { yyerror("out of memory"); rc = -1; goto out; } memset(newc, 0, sizeof(ocontext_t)); newc->u.node.addr = addr.s_addr; newc->u.node.mask = mask.s_addr; if (parse_security_context(&newc->context[0])) { free(newc); return -1; } /* Create order of most specific to least retaining the order specified in the configuration. */ head = policydbp->ocontexts[OCON_NODE]; for (l = NULL, c = head; c; l = c, c = c->next) { if (newc->u.node.mask > c->u.node.mask) break; } newc->next = c; if (l) l->next = newc; else policydbp->ocontexts[OCON_NODE] = newc; rc = 0; out: return rc; } int define_ipv6_node_context(void) { char *id; int rc = 0; struct in6_addr addr, mask; ocontext_t *newc, *c, *l, *head; if (policydbp->target_platform != SEPOL_TARGET_SELINUX) { yyerror("nodecon not supported for target"); return -1; } if (pass == 1) { free(queue_remove(id_queue)); free(queue_remove(id_queue)); parse_security_context(NULL); goto out; } id = queue_remove(id_queue); if (!id) { yyerror("failed to read ipv6 address"); rc = -1; goto out; } rc = inet_pton(AF_INET6, id, &addr); free(id); if (rc < 1) { yyerror("failed to parse ipv6 address"); if (rc == 0) rc = -1; goto out; } id = queue_remove(id_queue); if (!id) { yyerror("failed to read ipv6 address"); rc = -1; goto out; } rc = inet_pton(AF_INET6, id, &mask); free(id); if (rc < 1) { yyerror("failed to parse ipv6 mask"); if (rc == 0) rc = -1; goto out; } newc = malloc(sizeof(ocontext_t)); if (!newc) { yyerror("out of memory"); rc = -1; goto out; } memset(newc, 0, sizeof(ocontext_t)); #ifdef DARWIN memcpy(&newc->u.node6.addr[0], &addr.s6_addr[0], 16); memcpy(&newc->u.node6.mask[0], &mask.s6_addr[0], 16); #else memcpy(&newc->u.node6.addr[0], &addr.s6_addr32[0], 16); memcpy(&newc->u.node6.mask[0], &mask.s6_addr32[0], 16); #endif if (parse_security_context(&newc->context[0])) { free(newc); rc = -1; goto out; } /* Create order of most specific to least retaining the order specified in the configuration. */ head = policydbp->ocontexts[OCON_NODE6]; for (l = NULL, c = head; c; l = c, c = c->next) { if (memcmp(&newc->u.node6.mask, &c->u.node6.mask, 16) > 0) break; } newc->next = c; if (l) l->next = newc; else policydbp->ocontexts[OCON_NODE6] = newc; rc = 0; out: return rc; } int define_fs_use(int behavior) { ocontext_t *newc, *c, *head; if (policydbp->target_platform != SEPOL_TARGET_SELINUX) { yyerror("fsuse not supported for target"); return -1; } if (pass == 1) { free(queue_remove(id_queue)); parse_security_context(NULL); return 0; } newc = (ocontext_t *) malloc(sizeof(ocontext_t)); if (!newc) { yyerror("out of memory"); return -1; } memset(newc, 0, sizeof(ocontext_t)); newc->u.name = (char *)queue_remove(id_queue); if (!newc->u.name) { free(newc); return -1; } newc->v.behavior = behavior; if (parse_security_context(&newc->context[0])) { free(newc->u.name); free(newc); return -1; } head = policydbp->ocontexts[OCON_FSUSE]; for (c = head; c; c = c->next) { if (!strcmp(newc->u.name, c->u.name)) { yyerror2("duplicate fs_use entry for filesystem type %s", newc->u.name); context_destroy(&newc->context[0]); free(newc->u.name); free(newc); return -1; } } newc->next = head; policydbp->ocontexts[OCON_FSUSE] = newc; return 0; } int define_genfs_context_helper(char *fstype, int has_type) { struct genfs *genfs_p, *genfs, *newgenfs; ocontext_t *newc, *c, *head, *p; char *type = NULL; int len, len2; if (policydbp->target_platform != SEPOL_TARGET_SELINUX) { yyerror("genfs not supported for target"); return -1; } if (pass == 1) { free(fstype); free(queue_remove(id_queue)); if (has_type) free(queue_remove(id_queue)); parse_security_context(NULL); return 0; } for (genfs_p = NULL, genfs = policydbp->genfs; genfs; genfs_p = genfs, genfs = genfs->next) { if (strcmp(fstype, genfs->fstype) <= 0) break; } if (!genfs || strcmp(fstype, genfs->fstype)) { newgenfs = malloc(sizeof(struct genfs)); if (!newgenfs) { yyerror("out of memory"); return -1; } memset(newgenfs, 0, sizeof(struct genfs)); newgenfs->fstype = fstype; newgenfs->next = genfs; if (genfs_p) genfs_p->next = newgenfs; else policydbp->genfs = newgenfs; genfs = newgenfs; } newc = (ocontext_t *) malloc(sizeof(ocontext_t)); if (!newc) { yyerror("out of memory"); return -1; } memset(newc, 0, sizeof(ocontext_t)); newc->u.name = (char *)queue_remove(id_queue); if (!newc->u.name) goto fail; if (has_type) { type = (char *)queue_remove(id_queue); if (!type) goto fail; if (type[1] != 0) { yyerror2("invalid type %s", type); goto fail; } switch (type[0]) { case 'b': newc->v.sclass = SECCLASS_BLK_FILE; break; case 'c': newc->v.sclass = SECCLASS_CHR_FILE; break; case 'd': newc->v.sclass = SECCLASS_DIR; break; case 'p': newc->v.sclass = SECCLASS_FIFO_FILE; break; case 'l': newc->v.sclass = SECCLASS_LNK_FILE; break; case 's': newc->v.sclass = SECCLASS_SOCK_FILE; break; case '-': newc->v.sclass = SECCLASS_FILE; break; default: yyerror2("invalid type %s", type); goto fail; } } if (parse_security_context(&newc->context[0])) goto fail; head = genfs->head; for (p = NULL, c = head; c; p = c, c = c->next) { if (!strcmp(newc->u.name, c->u.name) && (!newc->v.sclass || !c->v.sclass || newc->v.sclass == c->v.sclass)) { yyerror2("duplicate entry for genfs entry (%s, %s)", fstype, newc->u.name); goto fail; } len = strlen(newc->u.name); len2 = strlen(c->u.name); if (len > len2) break; } newc->next = c; if (p) p->next = newc; else genfs->head = newc; return 0; fail: if (type) free(type); context_destroy(&newc->context[0]); if (fstype) free(fstype); if (newc->u.name) free(newc->u.name); free(newc); return -1; } int define_genfs_context(int has_type) { return define_genfs_context_helper(queue_remove(id_queue), has_type); } int define_range_trans(int class_specified) { char *id; level_datum_t *levdatum = 0; class_datum_t *cladatum; range_trans_rule_t *rule; int l, add = 1; if (!mlspol) { yyerror("range_transition rule in non-MLS configuration"); return -1; } if (pass == 1) { while ((id = queue_remove(id_queue))) free(id); while ((id = queue_remove(id_queue))) free(id); if (class_specified) while ((id = queue_remove(id_queue))) free(id); id = queue_remove(id_queue); free(id); for (l = 0; l < 2; l++) { while ((id = queue_remove(id_queue))) { free(id); } id = queue_remove(id_queue); if (!id) break; free(id); } return 0; } rule = malloc(sizeof(struct range_trans_rule)); if (!rule) { yyerror("out of memory"); return -1; } range_trans_rule_init(rule); while ((id = queue_remove(id_queue))) { if (set_types(&rule->stypes, id, &add, 0)) goto out; } add = 1; while ((id = queue_remove(id_queue))) { if (set_types(&rule->ttypes, id, &add, 0)) goto out; } if (class_specified) { if (read_classes(&rule->tclasses)) goto out; } else { cladatum = hashtab_search(policydbp->p_classes.table, "process"); if (!cladatum) { yyerror2("could not find process class for " "legacy range_transition statement"); goto out; } if (ebitmap_set_bit(&rule->tclasses, cladatum->s.value - 1, TRUE)) { yyerror("out of memory"); goto out; } } id = (char *)queue_remove(id_queue); if (!id) { yyerror("no range in range_transition definition?"); goto out; } for (l = 0; l < 2; l++) { levdatum = hashtab_search(policydbp->p_levels.table, id); if (!levdatum) { yyerror2("unknown level %s used in range_transition " "definition", id); free(id); goto out; } free(id); rule->trange.level[l].sens = levdatum->level->sens; while ((id = queue_remove(id_queue))) { if (parse_semantic_categories(id, levdatum, &rule->trange.level[l].cat)) { free(id); goto out; } free(id); } id = (char *)queue_remove(id_queue); if (!id) break; } if (l == 0) { if (mls_semantic_level_cpy(&rule->trange.level[1], &rule->trange.level[0])) { yyerror("out of memory"); goto out; } } append_range_trans(rule); return 0; out: range_trans_rule_destroy(rule); free(rule); return -1; } /* FLASK */