/* Authors: Karl MacMillan <kmacmillan@mentalrootkit.com> * Joshua Brindle <jbrindle@tresys.com> * Jason Tang <jtang@tresys.com> * * Copyright (C) 2004-2005 Tresys Technology, LLC * Copyright (C) 2007 Red Hat, Inc. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA */ #include <sepol/policydb/policydb.h> #include <sepol/policydb/conditional.h> #include <sepol/policydb/hashtab.h> #include <sepol/policydb/avrule_block.h> #include <sepol/policydb/link.h> #include <sepol/policydb/util.h> #include <stdlib.h> #include <stdarg.h> #include <stdio.h> #include <string.h> #include <assert.h> #include "debug.h" #undef min #define min(a,b) (((a) < (b)) ? (a) : (b)) typedef struct policy_module { policydb_t *policy; uint32_t num_decls; uint32_t *map[SYM_NUM]; uint32_t *avdecl_map; uint32_t **perm_map; uint32_t *perm_map_len; /* a pointer to within the base module's avrule_block chain to * where this module's global now resides */ avrule_block_t *base_global; } policy_module_t; typedef struct link_state { int verbose; policydb_t *base; avrule_block_t *last_avrule_block, *last_base_avrule_block; uint32_t next_decl_id, current_decl_id; /* temporary variables, used during hashtab_map() calls */ policy_module_t *cur; char *cur_mod_name; avrule_decl_t *dest_decl; class_datum_t *src_class, *dest_class; char *dest_class_name; char dest_class_req; /* flag indicating the class was not declared */ uint32_t symbol_num; /* used to report the name of the module if dependancy error occurs */ policydb_t **decl_to_mod; /* error reporting fields */ sepol_handle_t *handle; } link_state_t; typedef struct missing_requirement { uint32_t symbol_type; uint32_t symbol_value; uint32_t perm_value; } missing_requirement_t; static const char *symtab_names[SYM_NUM] = { "common", "class", "role", "type/attribute", "user", "bool", "level", "category" }; /* Deallocates all elements within a module, but NOT the policydb_t * structure within, as well as the pointer itself. */ static void policy_module_destroy(policy_module_t * mod) { unsigned int i; if (mod == NULL) { return; } for (i = 0; i < SYM_NUM; i++) { free(mod->map[i]); } for (i = 0; mod->perm_map != NULL && i < mod->policy->p_classes.nprim; i++) { free(mod->perm_map[i]); } free(mod->perm_map); free(mod->perm_map_len); free(mod->avdecl_map); free(mod); } /***** functions that copy identifiers from a module to base *****/ /* Note: there is currently no scoping for permissions, which causes some * strange side-effects. The current approach is this: * * a) perm is required and the class _and_ perm are declared in base: only add a mapping. * b) perm is required and the class and perm are _not_ declared in base: simply add the permissions * to the object class. This means that the requirements for the decl are the union of the permissions * required for all decls, but who cares. * c) perm is required, the class is declared in base, but the perm is not present. Nothing we can do * here because we can't mark a single permission as required, so we bail with a requirement error * _even_ if we are in an optional. * * A is correct behavior, b is wrong but not too bad, c is totall wrong for optionals. Fixing this requires * a format change. */ static int permission_copy_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { char *perm_id = key, *new_id = NULL; perm_datum_t *perm, *new_perm = NULL, *dest_perm; link_state_t *state = (link_state_t *) data; class_datum_t *src_class = state->src_class; class_datum_t *dest_class = state->dest_class; policy_module_t *mod = state->cur; uint32_t sclassi = src_class->s.value - 1; int ret; perm = (perm_datum_t *) datum; dest_perm = hashtab_search(dest_class->permissions.table, perm_id); if (dest_perm == NULL && dest_class->comdatum != NULL) { dest_perm = hashtab_search(dest_class->comdatum->permissions.table, perm_id); } if (dest_perm == NULL) { /* If the object class was not declared in the base, add the perm * to the object class. */ if (state->dest_class_req) { /* If the class was required (not declared), insert the new permission */ new_id = strdup(perm_id); if (new_id == NULL) { ERR(state->handle, "Memory error"); ret = SEPOL_ERR; goto err; } new_perm = (perm_datum_t *) calloc(1, sizeof(perm_datum_t)); if (new_perm == NULL) { ERR(state->handle, "Memory error"); ret = SEPOL_ERR; goto err; } ret = hashtab_insert(dest_class->permissions.table, (hashtab_key_t) new_id, (hashtab_datum_t) new_perm); if (ret) { ERR(state->handle, "could not insert permission into class\n"); goto err; } new_perm->s.value = dest_class->permissions.nprim + 1; dest_perm = new_perm; } else { /* this is case c from above */ ERR(state->handle, "Module %s depends on permission %s in class %s, not satisfied", state->cur_mod_name, perm_id, state->dest_class_name); return SEPOL_EREQ; } } /* build the mapping for permissions encompassing this class. * unlike symbols, the permission map translates between * module permission bit to target permission bit. that bit * may have originated from the class -or- it could be from * the class's common parent.*/ if (perm->s.value > mod->perm_map_len[sclassi]) { uint32_t *newmap = calloc(perm->s.value, sizeof(*newmap)); if (newmap == NULL) { ERR(state->handle, "Out of memory!"); return -1; } memcpy(newmap, mod->perm_map[sclassi], mod->perm_map_len[sclassi] * sizeof(*newmap)); free(mod->perm_map[sclassi]); mod->perm_map[sclassi] = newmap; mod->perm_map_len[sclassi] = perm->s.value; } mod->perm_map[sclassi][perm->s.value - 1] = dest_perm->s.value; return 0; err: free(new_id); free(new_perm); return ret; } static int class_copy_default_new_object(link_state_t *state, class_datum_t *olddatum, class_datum_t *newdatum) { if (olddatum->default_user) { if (newdatum->default_user && olddatum->default_user != newdatum->default_user) { ERR(state->handle, "Found conflicting default user definitions"); return SEPOL_ENOTSUP; } newdatum->default_user = olddatum->default_user; } if (olddatum->default_role) { if (newdatum->default_role && olddatum->default_role != newdatum->default_role) { ERR(state->handle, "Found conflicting default role definitions"); return SEPOL_ENOTSUP; } newdatum->default_role = olddatum->default_role; } if (olddatum->default_type) { if (newdatum->default_type && olddatum->default_type != newdatum->default_type) { ERR(state->handle, "Found conflicting default type definitions"); return SEPOL_ENOTSUP; } newdatum->default_type = olddatum->default_type; } if (olddatum->default_range) { if (newdatum->default_range && olddatum->default_range != newdatum->default_range) { ERR(state->handle, "Found conflicting default range definitions"); return SEPOL_ENOTSUP; } newdatum->default_range = olddatum->default_range; } return 0; } static int class_copy_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { char *id = key, *new_id = NULL; class_datum_t *cladatum, *new_class = NULL; link_state_t *state = (link_state_t *) data; scope_datum_t *scope = NULL; int ret; cladatum = (class_datum_t *) datum; state->dest_class_req = 0; new_class = hashtab_search(state->base->p_classes.table, id); /* If there is not an object class already in the base symtab that means * that either a) a module is trying to declare a new object class (which * the compiler should prevent) or b) an object class was required that is * not in the base. */ if (new_class == NULL) { scope = hashtab_search(state->cur->policy->p_classes_scope.table, id); if (scope == NULL) { ret = SEPOL_ERR; goto err; } if (scope->scope == SCOPE_DECL) { /* disallow declarations in modules */ ERR(state->handle, "%s: Modules may not yet declare new classes.", state->cur_mod_name); ret = SEPOL_ENOTSUP; goto err; } else { /* It would be nice to error early here because the requirement is * not met, but we cannot because the decl might be optional (in which * case we should record the requirement so that it is just turned * off). Note: this will break horribly if modules can declare object * classes because the class numbers will be all wrong (i.e., they * might be assigned in the order they were required rather than the * current scheme which ensures correct numbering by ordering the * declarations properly). This can't be fixed until some infrastructure * for querying the object class numbers is in place. */ state->dest_class_req = 1; new_class = (class_datum_t *) calloc(1, sizeof(class_datum_t)); if (new_class == NULL) { ERR(state->handle, "Memory error\n"); ret = SEPOL_ERR; goto err; } if (symtab_init (&new_class->permissions, PERM_SYMTAB_SIZE)) { ret = SEPOL_ERR; goto err; } new_id = strdup(id); if (new_id == NULL) { ERR(state->handle, "Memory error\n"); symtab_destroy(&new_class->permissions); ret = SEPOL_ERR; goto err; } ret = hashtab_insert(state->base->p_classes.table, (hashtab_key_t) new_id, (hashtab_datum_t) new_class); if (ret) { ERR(state->handle, "could not insert new class into symtab"); symtab_destroy(&new_class->permissions); goto err; } new_class->s.value = ++(state->base->p_classes.nprim); } } state->cur->map[SYM_CLASSES][cladatum->s.value - 1] = new_class->s.value; /* copy permissions */ state->src_class = cladatum; state->dest_class = new_class; state->dest_class_name = (char *)key; /* copy default new object rules */ ret = class_copy_default_new_object(state, cladatum, new_class); if (ret) return ret; ret = hashtab_map(cladatum->permissions.table, permission_copy_callback, state); if (ret != 0) { return ret; } return 0; err: free(new_class); free(new_id); return ret; } static int role_copy_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { int ret; char *id = key, *new_id = NULL; role_datum_t *role, *base_role, *new_role = NULL; link_state_t *state = (link_state_t *) data; role = (role_datum_t *) datum; base_role = hashtab_search(state->base->p_roles.table, id); if (base_role != NULL) { /* role already exists. check that it is what this * module expected. duplicate declarations (e.g., two * modules both declare role foo_r) is checked during * scope_copy_callback(). */ if (role->flavor == ROLE_ATTRIB && base_role->flavor != ROLE_ATTRIB) { ERR(state->handle, "%s: Expected %s to be a role attribute, but it was already declared as a regular role.", state->cur_mod_name, id); return -1; } else if (role->flavor != ROLE_ATTRIB && base_role->flavor == ROLE_ATTRIB) { ERR(state->handle, "%s: Expected %s to be a regular role, but it was already declared as a role attribute.", state->cur_mod_name, id); return -1; } } else { if (state->verbose) INFO(state->handle, "copying role %s", id); if ((new_id = strdup(id)) == NULL) { goto cleanup; } if ((new_role = (role_datum_t *) malloc(sizeof(*new_role))) == NULL) { goto cleanup; } role_datum_init(new_role); /* new_role's dominates, types and roles field will be copied * during role_fix_callback() */ new_role->flavor = role->flavor; new_role->s.value = state->base->p_roles.nprim + 1; ret = hashtab_insert(state->base->p_roles.table, (hashtab_key_t) new_id, (hashtab_datum_t) new_role); if (ret) { goto cleanup; } state->base->p_roles.nprim++; base_role = new_role; } if (state->dest_decl) { new_id = NULL; if ((new_role = malloc(sizeof(*new_role))) == NULL) { goto cleanup; } role_datum_init(new_role); new_role->flavor = base_role->flavor; new_role->s.value = base_role->s.value; if ((new_id = strdup(id)) == NULL) { goto cleanup; } if (hashtab_insert (state->dest_decl->p_roles.table, new_id, new_role)) { goto cleanup; } state->dest_decl->p_roles.nprim++; } state->cur->map[SYM_ROLES][role->s.value - 1] = base_role->s.value; return 0; cleanup: ERR(state->handle, "Out of memory!"); role_datum_destroy(new_role); free(new_id); free(new_role); return -1; } /* Copy types and attributes from a module into the base module. The * attributes are copied, but the types that make up this attribute * are delayed type_fix_callback(). */ static int type_copy_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { int ret; char *id = key, *new_id = NULL; type_datum_t *type, *base_type, *new_type = NULL; link_state_t *state = (link_state_t *) data; type = (type_datum_t *) datum; if ((type->flavor == TYPE_TYPE && !type->primary) || type->flavor == TYPE_ALIAS) { /* aliases are handled later, in alias_copy_callback() */ return 0; } base_type = hashtab_search(state->base->p_types.table, id); if (base_type != NULL) { /* type already exists. check that it is what this * module expected. duplicate declarations (e.g., two * modules both declare type foo_t) is checked during * scope_copy_callback(). */ if (type->flavor == TYPE_ATTRIB && base_type->flavor != TYPE_ATTRIB) { ERR(state->handle, "%s: Expected %s to be an attribute, but it was already declared as a type.", state->cur_mod_name, id); return -1; } else if (type->flavor != TYPE_ATTRIB && base_type->flavor == TYPE_ATTRIB) { ERR(state->handle, "%s: Expected %s to be a type, but it was already declared as an attribute.", state->cur_mod_name, id); return -1; } /* permissive should pass to the base type */ base_type->flags |= (type->flags & TYPE_FLAGS_PERMISSIVE); } else { if (state->verbose) INFO(state->handle, "copying type %s", id); if ((new_id = strdup(id)) == NULL) { goto cleanup; } if ((new_type = (type_datum_t *) calloc(1, sizeof(*new_type))) == NULL) { goto cleanup; } new_type->primary = type->primary; new_type->flags = type->flags; new_type->flavor = type->flavor; /* for attributes, the writing of new_type->types is done in type_fix_callback() */ new_type->s.value = state->base->p_types.nprim + 1; ret = hashtab_insert(state->base->p_types.table, (hashtab_key_t) new_id, (hashtab_datum_t) new_type); if (ret) { goto cleanup; } state->base->p_types.nprim++; base_type = new_type; } if (state->dest_decl) { new_id = NULL; if ((new_type = calloc(1, sizeof(*new_type))) == NULL) { goto cleanup; } new_type->primary = type->primary; new_type->flavor = type->flavor; new_type->flags = type->flags; new_type->s.value = base_type->s.value; if ((new_id = strdup(id)) == NULL) { goto cleanup; } if (hashtab_insert (state->dest_decl->p_types.table, new_id, new_type)) { goto cleanup; } state->dest_decl->p_types.nprim++; } state->cur->map[SYM_TYPES][type->s.value - 1] = base_type->s.value; return 0; cleanup: ERR(state->handle, "Out of memory!"); free(new_id); free(new_type); return -1; } static int user_copy_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { int ret; char *id = key, *new_id = NULL; user_datum_t *user, *base_user, *new_user = NULL; link_state_t *state = (link_state_t *) data; user = (user_datum_t *) datum; base_user = hashtab_search(state->base->p_users.table, id); if (base_user == NULL) { if (state->verbose) INFO(state->handle, "copying user %s", id); if ((new_id = strdup(id)) == NULL) { goto cleanup; } if ((new_user = (user_datum_t *) malloc(sizeof(*new_user))) == NULL) { goto cleanup; } user_datum_init(new_user); /* new_users's roles and MLS fields will be copied during user_fix_callback(). */ new_user->s.value = state->base->p_users.nprim + 1; ret = hashtab_insert(state->base->p_users.table, (hashtab_key_t) new_id, (hashtab_datum_t) new_user); if (ret) { goto cleanup; } state->base->p_users.nprim++; base_user = new_user; } if (state->dest_decl) { new_id = NULL; if ((new_user = malloc(sizeof(*new_user))) == NULL) { goto cleanup; } user_datum_init(new_user); new_user->s.value = base_user->s.value; if ((new_id = strdup(id)) == NULL) { goto cleanup; } if (hashtab_insert (state->dest_decl->p_users.table, new_id, new_user)) { goto cleanup; } state->dest_decl->p_users.nprim++; } state->cur->map[SYM_USERS][user->s.value - 1] = base_user->s.value; return 0; cleanup: ERR(state->handle, "Out of memory!"); user_datum_destroy(new_user); free(new_id); free(new_user); return -1; } static int bool_copy_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { int ret; char *id = key, *new_id = NULL; cond_bool_datum_t *booldatum, *base_bool, *new_bool = NULL; link_state_t *state = (link_state_t *) data; scope_datum_t *scope; booldatum = (cond_bool_datum_t *) datum; base_bool = hashtab_search(state->base->p_bools.table, id); if (base_bool == NULL) { if (state->verbose) INFO(state->handle, "copying boolean %s", id); if ((new_id = strdup(id)) == NULL) { goto cleanup; } if ((new_bool = (cond_bool_datum_t *) malloc(sizeof(*new_bool))) == NULL) { goto cleanup; } new_bool->s.value = state->base->p_bools.nprim + 1; ret = hashtab_insert(state->base->p_bools.table, (hashtab_key_t) new_id, (hashtab_datum_t) new_bool); if (ret) { goto cleanup; } state->base->p_bools.nprim++; base_bool = new_bool; base_bool->flags = booldatum->flags; } else if ((booldatum->flags & COND_BOOL_FLAGS_TUNABLE) != (base_bool->flags & COND_BOOL_FLAGS_TUNABLE)) { /* A mismatch between boolean/tunable declaration * and usage(for example a boolean used in the * tunable_policy() or vice versa). * * This is not allowed and bail out with errors */ ERR(state->handle, "%s: Mismatch between boolean/tunable definition " "and usage for %s", state->cur_mod_name, id); return -1; } /* Get the scope info for this boolean to see if this is the declaration, * if so set the state */ scope = hashtab_search(state->cur->policy->p_bools_scope.table, id); if (!scope) return SEPOL_ERR; if (scope->scope == SCOPE_DECL) { base_bool->state = booldatum->state; /* Only the declaration rather than requirement * decides if it is a boolean or tunable. */ base_bool->flags = booldatum->flags; } state->cur->map[SYM_BOOLS][booldatum->s.value - 1] = base_bool->s.value; return 0; cleanup: ERR(state->handle, "Out of memory!"); cond_destroy_bool(new_id, new_bool, NULL); return -1; } static int sens_copy_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { char *id = key; level_datum_t *level, *base_level; link_state_t *state = (link_state_t *) data; scope_datum_t *scope; level = (level_datum_t *) datum; base_level = hashtab_search(state->base->p_levels.table, id); if (!base_level) { scope = hashtab_search(state->cur->policy->p_sens_scope.table, id); if (!scope) return SEPOL_ERR; if (scope->scope == SCOPE_DECL) { /* disallow declarations in modules */ ERR(state->handle, "%s: Modules may not declare new sensitivities.", state->cur_mod_name); return SEPOL_ENOTSUP; } else if (scope->scope == SCOPE_REQ) { /* unmet requirement */ ERR(state->handle, "%s: Sensitivity %s not declared by base.", state->cur_mod_name, id); return SEPOL_ENOTSUP; } else { ERR(state->handle, "%s: has an unknown scope: %d\n", state->cur_mod_name, scope->scope); return SEPOL_ENOTSUP; } } state->cur->map[SYM_LEVELS][level->level->sens - 1] = base_level->level->sens; return 0; } static int cat_copy_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { char *id = key; cat_datum_t *cat, *base_cat; link_state_t *state = (link_state_t *) data; scope_datum_t *scope; cat = (cat_datum_t *) datum; base_cat = hashtab_search(state->base->p_cats.table, id); if (!base_cat) { scope = hashtab_search(state->cur->policy->p_cat_scope.table, id); if (!scope) return SEPOL_ERR; if (scope->scope == SCOPE_DECL) { /* disallow declarations in modules */ ERR(state->handle, "%s: Modules may not declare new categories.", state->cur_mod_name); return SEPOL_ENOTSUP; } else if (scope->scope == SCOPE_REQ) { /* unmet requirement */ ERR(state->handle, "%s: Category %s not declared by base.", state->cur_mod_name, id); return SEPOL_ENOTSUP; } else { /* unknown scope? malformed policy? */ ERR(state->handle, "%s: has an unknown scope: %d\n", state->cur_mod_name, scope->scope); return SEPOL_ENOTSUP; } } state->cur->map[SYM_CATS][cat->s.value - 1] = base_cat->s.value; return 0; } static int (*copy_callback_f[SYM_NUM]) (hashtab_key_t key, hashtab_datum_t datum, void *datap) = { NULL, class_copy_callback, role_copy_callback, type_copy_callback, user_copy_callback, bool_copy_callback, sens_copy_callback, cat_copy_callback}; /* * The boundaries have to be copied after the types/roles/users are copied, * because it refers hashtab to lookup destinated objects. */ static int type_bounds_copy_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { link_state_t *state = (link_state_t *) data; type_datum_t *type = (type_datum_t *) datum; type_datum_t *dest; uint32_t bounds_val; if (!type->bounds) return 0; bounds_val = state->cur->map[SYM_TYPES][type->bounds - 1]; dest = hashtab_search(state->base->p_types.table, key); if (!dest) { ERR(state->handle, "Type lookup failed for %s", (char *)key); return -1; } if (dest->bounds != 0 && dest->bounds != bounds_val) { ERR(state->handle, "Inconsistent boundary for %s", (char *)key); return -1; } dest->bounds = bounds_val; return 0; } static int role_bounds_copy_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { link_state_t *state = (link_state_t *) data; role_datum_t *role = (role_datum_t *) datum; role_datum_t *dest; uint32_t bounds_val; if (!role->bounds) return 0; bounds_val = state->cur->map[SYM_ROLES][role->bounds - 1]; dest = hashtab_search(state->base->p_roles.table, key); if (!dest) { ERR(state->handle, "Role lookup failed for %s", (char *)key); return -1; } if (dest->bounds != 0 && dest->bounds != bounds_val) { ERR(state->handle, "Inconsistent boundary for %s", (char *)key); return -1; } dest->bounds = bounds_val; return 0; } static int user_bounds_copy_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { link_state_t *state = (link_state_t *) data; user_datum_t *user = (user_datum_t *) datum; user_datum_t *dest; uint32_t bounds_val; if (!user->bounds) return 0; bounds_val = state->cur->map[SYM_USERS][user->bounds - 1]; dest = hashtab_search(state->base->p_users.table, key); if (!dest) { ERR(state->handle, "User lookup failed for %s", (char *)key); return -1; } if (dest->bounds != 0 && dest->bounds != bounds_val) { ERR(state->handle, "Inconsistent boundary for %s", (char *)key); return -1; } dest->bounds = bounds_val; return 0; } /* The aliases have to be copied after the types and attributes to be * certain that the base symbol table will have the type that the * alias refers. Otherwise, we won't be able to find the type value * for the alias. We can't depend on the declaration ordering because * of the hash table. */ static int alias_copy_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { char *id = key, *new_id = NULL, *target_id; type_datum_t *type, *base_type, *new_type = NULL, *target_type; link_state_t *state = (link_state_t *) data; policy_module_t *mod = state->cur; int primval; type = (type_datum_t *) datum; /* there are 2 kinds of aliases. Ones with their own value (TYPE_ALIAS) * and ones with the value of their primary (TYPE_TYPE && type->primary = 0) */ if (! (type->flavor == TYPE_ALIAS || (type->flavor == TYPE_TYPE && !type->primary))) { /* ignore types and attributes -- they were handled in * type_copy_callback() */ return 0; } if (type->flavor == TYPE_ALIAS) primval = type->primary; else primval = type->s.value; target_id = mod->policy->p_type_val_to_name[primval - 1]; target_type = hashtab_search(state->base->p_types.table, target_id); if (target_type == NULL) { ERR(state->handle, "%s: Could not find type %s for alias %s.", state->cur_mod_name, target_id, id); return -1; } if (!strcmp(id, target_id)) { ERR(state->handle, "%s: Self aliasing of %s.", state->cur_mod_name, id); return -1; } target_type->flags |= (type->flags & TYPE_FLAGS_PERMISSIVE); base_type = hashtab_search(state->base->p_types.table, id); if (base_type == NULL) { if (state->verbose) INFO(state->handle, "copying alias %s", id); if ((new_type = (type_datum_t *) calloc(1, sizeof(*new_type))) == NULL) { goto cleanup; } /* the linked copy always has TYPE_ALIAS style aliases */ new_type->primary = target_type->s.value; new_type->flags = target_type->flags; new_type->flavor = TYPE_ALIAS; new_type->s.value = state->base->p_types.nprim + 1; if ((new_id = strdup(id)) == NULL) { goto cleanup; } if (hashtab_insert (state->base->p_types.table, new_id, new_type)) { goto cleanup; } state->base->p_types.nprim++; base_type = new_type; } else { /* if this already exists and isn't an alias it was required by another module (or base) * and inserted into the hashtable as a type, fix it up now */ if (base_type->flavor == TYPE_ALIAS) { /* error checking */ assert(base_type->primary == target_type->s.value); assert(base_type->primary == mod->map[SYM_TYPES][primval - 1]); assert(mod->map[SYM_TYPES][type->s.value - 1] == base_type->primary); return 0; } if (base_type->flavor == TYPE_ATTRIB) { ERR(state->handle, "%s is an alias of an attribute, not allowed", id); return -1; } base_type->flavor = TYPE_ALIAS; base_type->primary = target_type->s.value; base_type->flags |= (target_type->flags & TYPE_FLAGS_PERMISSIVE); } /* the aliases map points from its value to its primary so when this module * references this type the value it gets back from the map is the primary */ mod->map[SYM_TYPES][type->s.value - 1] = base_type->primary; return 0; cleanup: ERR(state->handle, "Out of memory!"); free(new_id); free(new_type); return -1; } /*********** callbacks that fix bitmaps ***********/ static int type_set_convert(type_set_t * types, type_set_t * dst, policy_module_t * mod, link_state_t * state __attribute__ ((unused))) { unsigned int i; ebitmap_node_t *tnode; ebitmap_for_each_bit(&types->types, tnode, i) { if (ebitmap_node_get_bit(tnode, i)) { assert(mod->map[SYM_TYPES][i]); if (ebitmap_set_bit (&dst->types, mod->map[SYM_TYPES][i] - 1, 1)) { goto cleanup; } } } ebitmap_for_each_bit(&types->negset, tnode, i) { if (ebitmap_node_get_bit(tnode, i)) { assert(mod->map[SYM_TYPES][i]); if (ebitmap_set_bit (&dst->negset, mod->map[SYM_TYPES][i] - 1, 1)) { goto cleanup; } } } dst->flags = types->flags; return 0; cleanup: return -1; } /* OR 2 typemaps together and at the same time map the src types to * the correct values in the dst typeset. */ static int type_set_or_convert(type_set_t * types, type_set_t * dst, policy_module_t * mod, link_state_t * state) { type_set_t ts_tmp; type_set_init(&ts_tmp); if (type_set_convert(types, &ts_tmp, mod, state) == -1) { goto cleanup; } if (type_set_or_eq(dst, &ts_tmp)) { goto cleanup; } type_set_destroy(&ts_tmp); return 0; cleanup: ERR(state->handle, "Out of memory!"); type_set_destroy(&ts_tmp); return -1; } static int role_set_or_convert(role_set_t * roles, role_set_t * dst, policy_module_t * mod, link_state_t * state) { unsigned int i; ebitmap_t tmp; ebitmap_node_t *rnode; ebitmap_init(&tmp); ebitmap_for_each_bit(&roles->roles, rnode, i) { if (ebitmap_node_get_bit(rnode, i)) { assert(mod->map[SYM_ROLES][i]); if (ebitmap_set_bit (&tmp, mod->map[SYM_ROLES][i] - 1, 1)) { goto cleanup; } } } if (ebitmap_union(&dst->roles, &tmp)) { goto cleanup; } dst->flags |= roles->flags; ebitmap_destroy(&tmp); return 0; cleanup: ERR(state->handle, "Out of memory!"); ebitmap_destroy(&tmp); return -1; } static int mls_level_convert(mls_semantic_level_t * src, mls_semantic_level_t * dst, policy_module_t * mod, link_state_t * state) { mls_semantic_cat_t *src_cat, *new_cat; if (!mod->policy->mls) return 0; /* Required not declared. */ if (!src->sens) return 0; assert(mod->map[SYM_LEVELS][src->sens - 1]); dst->sens = mod->map[SYM_LEVELS][src->sens - 1]; for (src_cat = src->cat; src_cat; src_cat = src_cat->next) { new_cat = (mls_semantic_cat_t *) malloc(sizeof(mls_semantic_cat_t)); if (!new_cat) { ERR(state->handle, "Out of memory"); return -1; } mls_semantic_cat_init(new_cat); new_cat->next = dst->cat; dst->cat = new_cat; assert(mod->map[SYM_CATS][src_cat->low - 1]); dst->cat->low = mod->map[SYM_CATS][src_cat->low - 1]; assert(mod->map[SYM_CATS][src_cat->high - 1]); dst->cat->high = mod->map[SYM_CATS][src_cat->high - 1]; } return 0; } static int mls_range_convert(mls_semantic_range_t * src, mls_semantic_range_t * dst, policy_module_t * mod, link_state_t * state) { int ret; ret = mls_level_convert(&src->level[0], &dst->level[0], mod, state); if (ret) return ret; ret = mls_level_convert(&src->level[1], &dst->level[1], mod, state); if (ret) return ret; return 0; } static int role_fix_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { unsigned int i; char *id = key; role_datum_t *role, *dest_role = NULL; link_state_t *state = (link_state_t *) data; ebitmap_t e_tmp; policy_module_t *mod = state->cur; ebitmap_node_t *rnode; hashtab_t role_tab; role = (role_datum_t *) datum; if (state->dest_decl == NULL) role_tab = state->base->p_roles.table; else role_tab = state->dest_decl->p_roles.table; dest_role = hashtab_search(role_tab, id); assert(dest_role != NULL); if (state->verbose) { INFO(state->handle, "fixing role %s", id); } ebitmap_init(&e_tmp); ebitmap_for_each_bit(&role->dominates, rnode, i) { if (ebitmap_node_get_bit(rnode, i)) { assert(mod->map[SYM_ROLES][i]); if (ebitmap_set_bit (&e_tmp, mod->map[SYM_ROLES][i] - 1, 1)) { goto cleanup; } } } if (ebitmap_union(&dest_role->dominates, &e_tmp)) { goto cleanup; } if (type_set_or_convert(&role->types, &dest_role->types, mod, state)) { goto cleanup; } ebitmap_destroy(&e_tmp); if (role->flavor == ROLE_ATTRIB) { ebitmap_init(&e_tmp); ebitmap_for_each_bit(&role->roles, rnode, i) { if (ebitmap_node_get_bit(rnode, i)) { assert(mod->map[SYM_ROLES][i]); if (ebitmap_set_bit (&e_tmp, mod->map[SYM_ROLES][i] - 1, 1)) { goto cleanup; } } } if (ebitmap_union(&dest_role->roles, &e_tmp)) { goto cleanup; } ebitmap_destroy(&e_tmp); } return 0; cleanup: ERR(state->handle, "Out of memory!"); ebitmap_destroy(&e_tmp); return -1; } static int type_fix_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { unsigned int i; char *id = key; type_datum_t *type, *new_type = NULL; link_state_t *state = (link_state_t *) data; ebitmap_t e_tmp; policy_module_t *mod = state->cur; ebitmap_node_t *tnode; symtab_t *typetab; type = (type_datum_t *) datum; if (state->dest_decl == NULL) typetab = &state->base->p_types; else typetab = &state->dest_decl->p_types; /* only fix attributes */ if (type->flavor != TYPE_ATTRIB) { return 0; } new_type = hashtab_search(typetab->table, id); assert(new_type != NULL && new_type->flavor == TYPE_ATTRIB); if (state->verbose) { INFO(state->handle, "fixing attribute %s", id); } ebitmap_init(&e_tmp); ebitmap_for_each_bit(&type->types, tnode, i) { if (ebitmap_node_get_bit(tnode, i)) { assert(mod->map[SYM_TYPES][i]); if (ebitmap_set_bit (&e_tmp, mod->map[SYM_TYPES][i] - 1, 1)) { goto cleanup; } } } if (ebitmap_union(&new_type->types, &e_tmp)) { goto cleanup; } ebitmap_destroy(&e_tmp); return 0; cleanup: ERR(state->handle, "Out of memory!"); ebitmap_destroy(&e_tmp); return -1; } static int user_fix_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { char *id = key; user_datum_t *user, *new_user = NULL; link_state_t *state = (link_state_t *) data; policy_module_t *mod = state->cur; symtab_t *usertab; user = (user_datum_t *) datum; if (state->dest_decl == NULL) usertab = &state->base->p_users; else usertab = &state->dest_decl->p_users; new_user = hashtab_search(usertab->table, id); assert(new_user != NULL); if (state->verbose) { INFO(state->handle, "fixing user %s", id); } if (role_set_or_convert(&user->roles, &new_user->roles, mod, state)) { goto cleanup; } if (mls_range_convert(&user->range, &new_user->range, mod, state)) goto cleanup; if (mls_level_convert(&user->dfltlevel, &new_user->dfltlevel, mod, state)) goto cleanup; return 0; cleanup: ERR(state->handle, "Out of memory!"); return -1; } static int (*fix_callback_f[SYM_NUM]) (hashtab_key_t key, hashtab_datum_t datum, void *datap) = { NULL, NULL, role_fix_callback, type_fix_callback, user_fix_callback, NULL, NULL, NULL}; /*********** functions that copy AV rules ***********/ static int copy_avrule_list(avrule_t * list, avrule_t ** dst, policy_module_t * module, link_state_t * state) { unsigned int i; avrule_t *cur, *new_rule = NULL, *tail; class_perm_node_t *cur_perm, *new_perm, *tail_perm = NULL; tail = *dst; while (tail && tail->next) { tail = tail->next; } cur = list; while (cur) { if ((new_rule = (avrule_t *) malloc(sizeof(avrule_t))) == NULL) { goto cleanup; } avrule_init(new_rule); new_rule->specified = cur->specified; new_rule->flags = cur->flags; if (type_set_convert (&cur->stypes, &new_rule->stypes, module, state) == -1 || type_set_convert(&cur->ttypes, &new_rule->ttypes, module, state) == -1) { goto cleanup; } cur_perm = cur->perms; tail_perm = NULL; while (cur_perm) { if ((new_perm = (class_perm_node_t *) malloc(sizeof(class_perm_node_t))) == NULL) { goto cleanup; } class_perm_node_init(new_perm); new_perm->class = module->map[SYM_CLASSES][cur_perm->class - 1]; assert(new_perm->class); if (new_rule->specified & AVRULE_AV) { for (i = 0; i < module->perm_map_len[cur_perm->class - 1]; i++) { if (!(cur_perm->data & (1U << i))) continue; new_perm->data |= (1U << (module-> perm_map[cur_perm->class - 1][i] - 1)); } } else { new_perm->data = module->map[SYM_TYPES][cur_perm->data - 1]; } if (new_rule->perms == NULL) { new_rule->perms = new_perm; } else { assert(tail_perm); tail_perm->next = new_perm; } tail_perm = new_perm; cur_perm = cur_perm->next; } new_rule->line = cur->line; cur = cur->next; if (*dst == NULL) { *dst = new_rule; } else { tail->next = new_rule; } tail = new_rule; } return 0; cleanup: ERR(state->handle, "Out of memory!"); avrule_destroy(new_rule); free(new_rule); return -1; } static int copy_role_trans_list(role_trans_rule_t * list, role_trans_rule_t ** dst, policy_module_t * module, link_state_t * state) { role_trans_rule_t *cur, *new_rule = NULL, *tail; unsigned int i; ebitmap_node_t *cnode; cur = list; tail = *dst; while (tail && tail->next) { tail = tail->next; } while (cur) { if ((new_rule = (role_trans_rule_t *) malloc(sizeof(role_trans_rule_t))) == NULL) { goto cleanup; } role_trans_rule_init(new_rule); if (role_set_or_convert (&cur->roles, &new_rule->roles, module, state) || type_set_or_convert(&cur->types, &new_rule->types, module, state)) { goto cleanup; } ebitmap_for_each_bit(&cur->classes, cnode, i) { if (ebitmap_node_get_bit(cnode, i)) { assert(module->map[SYM_CLASSES][i]); if (ebitmap_set_bit(&new_rule->classes, module-> map[SYM_CLASSES][i] - 1, 1)) { goto cleanup; } } } new_rule->new_role = module->map[SYM_ROLES][cur->new_role - 1]; if (*dst == NULL) { *dst = new_rule; } else { tail->next = new_rule; } tail = new_rule; cur = cur->next; } return 0; cleanup: ERR(state->handle, "Out of memory!"); role_trans_rule_list_destroy(new_rule); return -1; } static int copy_role_allow_list(role_allow_rule_t * list, role_allow_rule_t ** dst, policy_module_t * module, link_state_t * state) { role_allow_rule_t *cur, *new_rule = NULL, *tail; cur = list; tail = *dst; while (tail && tail->next) { tail = tail->next; } while (cur) { if ((new_rule = (role_allow_rule_t *) malloc(sizeof(role_allow_rule_t))) == NULL) { goto cleanup; } role_allow_rule_init(new_rule); if (role_set_or_convert (&cur->roles, &new_rule->roles, module, state) || role_set_or_convert(&cur->new_roles, &new_rule->new_roles, module, state)) { goto cleanup; } if (*dst == NULL) { *dst = new_rule; } else { tail->next = new_rule; } tail = new_rule; cur = cur->next; } return 0; cleanup: ERR(state->handle, "Out of memory!"); role_allow_rule_list_destroy(new_rule); return -1; } static int copy_filename_trans_list(filename_trans_rule_t * list, filename_trans_rule_t ** dst, policy_module_t * module, link_state_t * state) { filename_trans_rule_t *cur, *new_rule, *tail; cur = list; tail = *dst; while (tail && tail->next) tail = tail->next; while (cur) { new_rule = malloc(sizeof(*new_rule)); if (!new_rule) goto err; filename_trans_rule_init(new_rule); if (*dst == NULL) *dst = new_rule; else tail->next = new_rule; tail = new_rule; new_rule->name = strdup(cur->name); if (!new_rule->name) goto err; if (type_set_or_convert(&cur->stypes, &new_rule->stypes, module, state) || type_set_or_convert(&cur->ttypes, &new_rule->ttypes, module, state)) goto err; new_rule->tclass = module->map[SYM_CLASSES][cur->tclass - 1]; new_rule->otype = module->map[SYM_TYPES][cur->otype - 1]; cur = cur->next; } return 0; err: ERR(state->handle, "Out of memory!"); return -1; } static int copy_range_trans_list(range_trans_rule_t * rules, range_trans_rule_t ** dst, policy_module_t * mod, link_state_t * state) { range_trans_rule_t *rule, *new_rule = NULL; unsigned int i; ebitmap_node_t *cnode; for (rule = rules; rule; rule = rule->next) { new_rule = (range_trans_rule_t *) malloc(sizeof(range_trans_rule_t)); if (!new_rule) goto cleanup; range_trans_rule_init(new_rule); new_rule->next = *dst; *dst = new_rule; if (type_set_convert(&rule->stypes, &new_rule->stypes, mod, state)) goto cleanup; if (type_set_convert(&rule->ttypes, &new_rule->ttypes, mod, state)) goto cleanup; ebitmap_for_each_bit(&rule->tclasses, cnode, i) { if (ebitmap_node_get_bit(cnode, i)) { assert(mod->map[SYM_CLASSES][i]); if (ebitmap_set_bit (&new_rule->tclasses, mod->map[SYM_CLASSES][i] - 1, 1)) { goto cleanup; } } } if (mls_range_convert(&rule->trange, &new_rule->trange, mod, state)) goto cleanup; } return 0; cleanup: ERR(state->handle, "Out of memory!"); range_trans_rule_list_destroy(new_rule); return -1; } static int copy_cond_list(cond_node_t * list, cond_node_t ** dst, policy_module_t * module, link_state_t * state) { unsigned i; cond_node_t *cur, *new_node = NULL, *tail; cond_expr_t *cur_expr; tail = *dst; while (tail && tail->next) tail = tail->next; cur = list; while (cur) { new_node = (cond_node_t *) malloc(sizeof(cond_node_t)); if (!new_node) { goto cleanup; } memset(new_node, 0, sizeof(cond_node_t)); new_node->cur_state = cur->cur_state; new_node->expr = cond_copy_expr(cur->expr); if (!new_node->expr) goto cleanup; /* go back through and remap the expression */ for (cur_expr = new_node->expr; cur_expr != NULL; cur_expr = cur_expr->next) { /* expression nodes don't have a bool value of 0 - don't map them */ if (cur_expr->expr_type != COND_BOOL) continue; assert(module->map[SYM_BOOLS][cur_expr->bool - 1] != 0); cur_expr->bool = module->map[SYM_BOOLS][cur_expr->bool - 1]; } new_node->nbools = cur->nbools; /* FIXME should COND_MAX_BOOLS be used here? */ for (i = 0; i < min(cur->nbools, COND_MAX_BOOLS); i++) { uint32_t remapped_id = module->map[SYM_BOOLS][cur->bool_ids[i] - 1]; assert(remapped_id != 0); new_node->bool_ids[i] = remapped_id; } new_node->expr_pre_comp = cur->expr_pre_comp; if (copy_avrule_list (cur->avtrue_list, &new_node->avtrue_list, module, state) || copy_avrule_list(cur->avfalse_list, &new_node->avfalse_list, module, state)) { goto cleanup; } if (*dst == NULL) { *dst = new_node; } else { tail->next = new_node; } tail = new_node; cur = cur->next; } return 0; cleanup: ERR(state->handle, "Out of memory!"); cond_node_destroy(new_node); free(new_node); return -1; } /*********** functions that copy avrule_decls from module to base ***********/ static int copy_identifiers(link_state_t * state, symtab_t * src_symtab, avrule_decl_t * dest_decl) { int i, ret; state->dest_decl = dest_decl; for (i = 0; i < SYM_NUM; i++) { if (copy_callback_f[i] != NULL) { ret = hashtab_map(src_symtab[i].table, copy_callback_f[i], state); if (ret) { return ret; } } } if (hashtab_map(src_symtab[SYM_TYPES].table, type_bounds_copy_callback, state)) return -1; if (hashtab_map(src_symtab[SYM_TYPES].table, alias_copy_callback, state)) return -1; if (hashtab_map(src_symtab[SYM_ROLES].table, role_bounds_copy_callback, state)) return -1; if (hashtab_map(src_symtab[SYM_USERS].table, user_bounds_copy_callback, state)) return -1; /* then fix bitmaps associated with those newly copied identifiers */ for (i = 0; i < SYM_NUM; i++) { if (fix_callback_f[i] != NULL && hashtab_map(src_symtab[i].table, fix_callback_f[i], state)) { return -1; } } return 0; } static int copy_scope_index(scope_index_t * src, scope_index_t * dest, policy_module_t * module, link_state_t * state) { unsigned int i, j; uint32_t largest_mapped_class_value = 0; ebitmap_node_t *node; /* copy the scoping information for this avrule decl block */ for (i = 0; i < SYM_NUM; i++) { ebitmap_t *srcmap = src->scope + i; ebitmap_t *destmap = dest->scope + i; if (copy_callback_f[i] == NULL) { continue; } ebitmap_for_each_bit(srcmap, node, j) { if (ebitmap_node_get_bit(node, j)) { assert(module->map[i][j] != 0); if (ebitmap_set_bit (destmap, module->map[i][j] - 1, 1) != 0) { goto cleanup; } if (i == SYM_CLASSES && largest_mapped_class_value < module->map[SYM_CLASSES][j]) { largest_mapped_class_value = module->map[SYM_CLASSES][j]; } } } } /* next copy the enabled permissions data */ if ((dest->class_perms_map = malloc(largest_mapped_class_value * sizeof(*dest->class_perms_map))) == NULL) { goto cleanup; } for (i = 0; i < largest_mapped_class_value; i++) { ebitmap_init(dest->class_perms_map + i); } dest->class_perms_len = largest_mapped_class_value; for (i = 0; i < src->class_perms_len; i++) { ebitmap_t *srcmap = src->class_perms_map + i; ebitmap_t *destmap = dest->class_perms_map + module->map[SYM_CLASSES][i] - 1; ebitmap_for_each_bit(srcmap, node, j) { if (ebitmap_node_get_bit(node, j) && ebitmap_set_bit(destmap, module->perm_map[i][j] - 1, 1)) { goto cleanup; } } } return 0; cleanup: ERR(state->handle, "Out of memory!"); return -1; } static int copy_avrule_decl(link_state_t * state, policy_module_t * module, avrule_decl_t * src_decl, avrule_decl_t * dest_decl) { int ret; /* copy all of the RBAC and TE rules */ if (copy_avrule_list (src_decl->avrules, &dest_decl->avrules, module, state) == -1 || copy_role_trans_list(src_decl->role_tr_rules, &dest_decl->role_tr_rules, module, state) == -1 || copy_role_allow_list(src_decl->role_allow_rules, &dest_decl->role_allow_rules, module, state) == -1 || copy_cond_list(src_decl->cond_list, &dest_decl->cond_list, module, state) == -1) { return -1; } if (copy_filename_trans_list(src_decl->filename_trans_rules, &dest_decl->filename_trans_rules, module, state)) return -1; if (copy_range_trans_list(src_decl->range_tr_rules, &dest_decl->range_tr_rules, module, state)) return -1; /* finally copy any identifiers local to this declaration */ ret = copy_identifiers(state, src_decl->symtab, dest_decl); if (ret < 0) { return ret; } /* then copy required and declared scope indices here */ if (copy_scope_index(&src_decl->required, &dest_decl->required, module, state) == -1 || copy_scope_index(&src_decl->declared, &dest_decl->declared, module, state) == -1) { return -1; } return 0; } static int copy_avrule_block(link_state_t * state, policy_module_t * module, avrule_block_t * block) { avrule_block_t *new_block = avrule_block_create(); avrule_decl_t *decl, *last_decl = NULL; int ret; if (new_block == NULL) { ERR(state->handle, "Out of memory!"); ret = -1; goto cleanup; } new_block->flags = block->flags; for (decl = block->branch_list; decl != NULL; decl = decl->next) { avrule_decl_t *new_decl = avrule_decl_create(state->next_decl_id); if (new_decl == NULL) { ERR(state->handle, "Out of memory!"); ret = -1; goto cleanup; } if (module->policy->name != NULL) { new_decl->module_name = strdup(module->policy->name); if (new_decl->module_name == NULL) { ERR(state->handle, "Out of memory\n"); avrule_decl_destroy(new_decl); ret = -1; goto cleanup; } } if (last_decl == NULL) { new_block->branch_list = new_decl; } else { last_decl->next = new_decl; } last_decl = new_decl; state->base->decl_val_to_struct[state->next_decl_id - 1] = new_decl; state->decl_to_mod[state->next_decl_id] = module->policy; module->avdecl_map[decl->decl_id] = new_decl->decl_id; ret = copy_avrule_decl(state, module, decl, new_decl); if (ret) { avrule_decl_destroy(new_decl); goto cleanup; } state->next_decl_id++; } state->last_avrule_block->next = new_block; state->last_avrule_block = new_block; return 0; cleanup: avrule_block_list_destroy(new_block); return ret; } static int scope_copy_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { unsigned int i; int ret; char *id = key, *new_id = NULL; scope_datum_t *scope, *base_scope; link_state_t *state = (link_state_t *) data; uint32_t symbol_num = state->symbol_num; uint32_t *avdecl_map = state->cur->avdecl_map; scope = (scope_datum_t *) datum; /* check if the base already has a scope entry */ base_scope = hashtab_search(state->base->scope[symbol_num].table, id); if (base_scope == NULL) { scope_datum_t *new_scope; if ((new_id = strdup(id)) == NULL) { goto cleanup; } if ((new_scope = (scope_datum_t *) calloc(1, sizeof(*new_scope))) == NULL) { free(new_id); goto cleanup; } ret = hashtab_insert(state->base->scope[symbol_num].table, (hashtab_key_t) new_id, (hashtab_datum_t) new_scope); if (ret) { free(new_id); free(new_scope); goto cleanup; } new_scope->scope = SCOPE_REQ; /* this is reset further down */ base_scope = new_scope; } if (base_scope->scope == SCOPE_REQ && scope->scope == SCOPE_DECL) { /* this module declared symbol, so overwrite the old * list with the new decl ids */ base_scope->scope = SCOPE_DECL; free(base_scope->decl_ids); base_scope->decl_ids = NULL; base_scope->decl_ids_len = 0; for (i = 0; i < scope->decl_ids_len; i++) { if (add_i_to_a(avdecl_map[scope->decl_ids[i]], &base_scope->decl_ids_len, &base_scope->decl_ids) == -1) { goto cleanup; } } } else if (base_scope->scope == SCOPE_DECL && scope->scope == SCOPE_REQ) { /* this module depended on a symbol that now exists, * so don't do anything */ } else if (base_scope->scope == SCOPE_REQ && scope->scope == SCOPE_REQ) { /* symbol is still required, so add to the list */ for (i = 0; i < scope->decl_ids_len; i++) { if (add_i_to_a(avdecl_map[scope->decl_ids[i]], &base_scope->decl_ids_len, &base_scope->decl_ids) == -1) { goto cleanup; } } } else { /* this module declared a symbol, and it was already * declared. only roles and users may be multiply * declared; for all others this is an error. */ if (symbol_num != SYM_ROLES && symbol_num != SYM_USERS) { ERR(state->handle, "%s: Duplicate declaration in module: %s %s", state->cur_mod_name, symtab_names[state->symbol_num], id); return -1; } for (i = 0; i < scope->decl_ids_len; i++) { if (add_i_to_a(avdecl_map[scope->decl_ids[i]], &base_scope->decl_ids_len, &base_scope->decl_ids) == -1) { goto cleanup; } } } return 0; cleanup: ERR(state->handle, "Out of memory!"); return -1; } /* Copy a module over to a base, remapping all values within. After * all identifiers and rules are done, copy the scoping information. * This is when it checks for duplicate declarations. */ static int copy_module(link_state_t * state, policy_module_t * module) { int i, ret; avrule_block_t *cur; state->cur = module; state->cur_mod_name = module->policy->name; /* first copy all of the identifiers */ ret = copy_identifiers(state, module->policy->symtab, NULL); if (ret) { return ret; } /* next copy all of the avrule blocks */ for (cur = module->policy->global; cur != NULL; cur = cur->next) { ret = copy_avrule_block(state, module, cur); if (ret) { return ret; } } /* then copy the scoping tables */ for (i = 0; i < SYM_NUM; i++) { state->symbol_num = i; if (hashtab_map (module->policy->scope[i].table, scope_copy_callback, state)) { return -1; } } return 0; } /***** functions that check requirements and enable blocks in a module ******/ /* borrowed from checkpolicy.c */ struct find_perm_arg { unsigned int valuep; hashtab_key_t key; }; static int find_perm(hashtab_key_t key, hashtab_datum_t datum, void *varg) { struct find_perm_arg *arg = varg; perm_datum_t *perdatum = (perm_datum_t *) datum; if (arg->valuep == perdatum->s.value) { arg->key = key; return 1; } return 0; } /* Check if the requirements are met for a single declaration. If all * are met return 1. For the first requirement found to be missing, * if 'missing_sym_num' and 'missing_value' are both not NULL then * write to them the symbol number and value for the missing * declaration. Then return 0 to indicate a missing declaration. * Note that if a declaration had no requirement at all (e.g., an ELSE * block) this returns 1. */ static int is_decl_requires_met(link_state_t * state, avrule_decl_t * decl, struct missing_requirement *req) { /* (This algorithm is very unoptimized. It performs many * redundant checks. A very obvious improvement is to cache * which symbols have been verified, so that they do not need * to be re-checked.) */ unsigned int i, j; ebitmap_t *bitmap; char *id, *perm_id; policydb_t *pol = state->base; ebitmap_node_t *node; /* check that all symbols have been satisfied */ for (i = 0; i < SYM_NUM; i++) { if (i == SYM_CLASSES) { /* classes will be checked during permissions * checking phase below */ continue; } bitmap = &decl->required.scope[i]; ebitmap_for_each_bit(bitmap, node, j) { if (!ebitmap_node_get_bit(node, j)) { continue; } /* check base's scope table */ id = pol->sym_val_to_name[i][j]; if (!is_id_enabled(id, state->base, i)) { /* this symbol was not found */ if (req != NULL) { req->symbol_type = i; req->symbol_value = j + 1; } return 0; } } } /* check that all classes and permissions have been satisfied */ for (i = 0; i < decl->required.class_perms_len; i++) { bitmap = decl->required.class_perms_map + i; ebitmap_for_each_bit(bitmap, node, j) { struct find_perm_arg fparg; class_datum_t *cladatum; uint32_t perm_value = j + 1; int rc; scope_datum_t *scope; if (!ebitmap_node_get_bit(node, j)) { continue; } id = pol->p_class_val_to_name[i]; cladatum = pol->class_val_to_struct[i]; scope = hashtab_search(state->base->p_classes_scope.table, id); if (scope == NULL) { ERR(state->handle, "Could not find scope information for class %s", id); return -1; } fparg.valuep = perm_value; fparg.key = NULL; (void)hashtab_map(cladatum->permissions.table, find_perm, &fparg); if (fparg.key == NULL && cladatum->comdatum != NULL) { rc = hashtab_map(cladatum->comdatum->permissions.table, find_perm, &fparg); assert(rc == 1); } perm_id = fparg.key; assert(perm_id != NULL); if (!is_perm_enabled(id, perm_id, state->base)) { if (req != NULL) { req->symbol_type = SYM_CLASSES; req->symbol_value = i + 1; req->perm_value = perm_value; } return 0; } } } /* all requirements have been met */ return 1; } static int debug_requirements(link_state_t * state, policydb_t * p) { int ret; avrule_block_t *cur; missing_requirement_t req; memset(&req, 0, sizeof(req)); for (cur = p->global; cur != NULL; cur = cur->next) { if (cur->enabled != NULL) continue; ret = is_decl_requires_met(state, cur->branch_list, &req); if (ret < 0) { return ret; } else if (ret == 0) { char *mod_name = cur->branch_list->module_name ? cur->branch_list->module_name : "BASE"; if (req.symbol_type == SYM_CLASSES) { struct find_perm_arg fparg; class_datum_t *cladatum; cladatum = p->class_val_to_struct[req.symbol_value - 1]; fparg.valuep = req.perm_value; fparg.key = NULL; (void)hashtab_map(cladatum->permissions.table, find_perm, &fparg); if (cur->flags & AVRULE_OPTIONAL) { ERR(state->handle, "%s[%d]'s optional requirements were not met: class %s, permission %s", mod_name, cur->branch_list->decl_id, p->p_class_val_to_name[req.symbol_value - 1], fparg.key); } else { ERR(state->handle, "%s[%d]'s global requirements were not met: class %s, permission %s", mod_name, cur->branch_list->decl_id, p->p_class_val_to_name[req.symbol_value - 1], fparg.key); } } else { if (cur->flags & AVRULE_OPTIONAL) { ERR(state->handle, "%s[%d]'s optional requirements were not met: %s %s", mod_name, cur->branch_list->decl_id, symtab_names[req.symbol_type], p->sym_val_to_name[req. symbol_type][req. symbol_value - 1]); } else { ERR(state->handle, "%s[%d]'s global requirements were not met: %s %s", mod_name, cur->branch_list->decl_id, symtab_names[req.symbol_type], p->sym_val_to_name[req. symbol_type][req. symbol_value - 1]); } } } } return 0; } static void print_missing_requirements(link_state_t * state, avrule_block_t * cur, missing_requirement_t * req) { policydb_t *p = state->base; char *mod_name = cur->branch_list->module_name ? cur->branch_list->module_name : "BASE"; if (req->symbol_type == SYM_CLASSES) { struct find_perm_arg fparg; class_datum_t *cladatum; cladatum = p->class_val_to_struct[req->symbol_value - 1]; fparg.valuep = req->perm_value; fparg.key = NULL; (void)hashtab_map(cladatum->permissions.table, find_perm, &fparg); ERR(state->handle, "%s's global requirements were not met: class %s, permission %s", mod_name, p->p_class_val_to_name[req->symbol_value - 1], fparg.key); } else { ERR(state->handle, "%s's global requirements were not met: %s %s", mod_name, symtab_names[req->symbol_type], p->sym_val_to_name[req->symbol_type][req->symbol_value - 1]); } } /* Enable all of the avrule_decl blocks for the policy. This simple * algorithm is the following: * * 1) Enable all of the non-else avrule_decls for all blocks. * 2) Iterate through the non-else decls looking for decls whose requirements * are not met. * 2a) If the decl is non-optional, return immediately with an error. * 2b) If the decl is optional, disable the block and mark changed = 1 * 3) If changed == 1 goto 2. * 4) Iterate through all blocks looking for those that have no enabled * decl. If the block has an else decl, enable. * * This will correctly handle all dependencies, including mutual and * cicular. The only downside is that it is slow. */ static int enable_avrules(link_state_t * state, policydb_t * pol) { int changed = 1; avrule_block_t *block; avrule_decl_t *decl; missing_requirement_t req; int ret = 0, rc; if (state->verbose) { INFO(state->handle, "Determining which avrules to enable."); } /* 1) enable all of the non-else blocks */ for (block = pol->global; block != NULL; block = block->next) { block->enabled = block->branch_list; block->enabled->enabled = 1; for (decl = block->branch_list->next; decl != NULL; decl = decl->next) decl->enabled = 0; } /* 2) Iterate */ while (changed) { changed = 0; for (block = pol->global; block != NULL; block = block->next) { if (block->enabled == NULL) { continue; } decl = block->branch_list; if (state->verbose) { char *mod_name = decl->module_name ? decl->module_name : "BASE"; INFO(state->handle, "check module %s decl %d\n", mod_name, decl->decl_id); } rc = is_decl_requires_met(state, decl, &req); if (rc < 0) { ret = SEPOL_ERR; goto out; } else if (rc == 0) { decl->enabled = 0; block->enabled = NULL; changed = 1; if (!(block->flags & AVRULE_OPTIONAL)) { print_missing_requirements(state, block, &req); ret = SEPOL_EREQ; goto out; } } } } /* 4) else handling * * Iterate through all of the blocks skipping the first (which is the * global block, is required to be present, and cannot have an else). * If the block is disabled and has an else decl, enable that. * * This code assumes that the second block in the branch list is the else * block. This is currently supported by the compiler. */ for (block = pol->global->next; block != NULL; block = block->next) { if (block->enabled == NULL) { if (block->branch_list->next != NULL) { block->enabled = block->branch_list->next; block->branch_list->next->enabled = 1; } } } out: if (state->verbose) debug_requirements(state, pol); return ret; } /*********** the main linking functions ***********/ /* Given a module's policy, normalize all conditional expressions * within. Return 0 on success, -1 on error. */ static int cond_normalize(policydb_t * p) { avrule_block_t *block; for (block = p->global; block != NULL; block = block->next) { avrule_decl_t *decl; for (decl = block->branch_list; decl != NULL; decl = decl->next) { cond_list_t *cond = decl->cond_list; while (cond) { if (cond_normalize_expr(p, cond) < 0) return -1; cond = cond->next; } } } return 0; } /* Allocate space for the various remapping arrays. */ static int prepare_module(link_state_t * state, policy_module_t * module) { int i; uint32_t items, num_decls = 0; avrule_block_t *cur; /* allocate the maps */ for (i = 0; i < SYM_NUM; i++) { items = module->policy->symtab[i].nprim; if ((module->map[i] = (uint32_t *) calloc(items, sizeof(*module->map[i]))) == NULL) { ERR(state->handle, "Out of memory!"); return -1; } } /* allocate the permissions remap here */ items = module->policy->p_classes.nprim; if ((module->perm_map_len = calloc(items, sizeof(*module->perm_map_len))) == NULL) { ERR(state->handle, "Out of memory!"); return -1; } if ((module->perm_map = calloc(items, sizeof(*module->perm_map))) == NULL) { ERR(state->handle, "Out of memory!"); return -1; } /* allocate a map for avrule_decls */ for (cur = module->policy->global; cur != NULL; cur = cur->next) { avrule_decl_t *decl; for (decl = cur->branch_list; decl != NULL; decl = decl->next) { if (decl->decl_id > num_decls) { num_decls = decl->decl_id; } } } num_decls++; if ((module->avdecl_map = calloc(num_decls, sizeof(uint32_t))) == NULL) { ERR(state->handle, "Out of memory!"); return -1; } module->num_decls = num_decls; /* normalize conditionals within */ if (cond_normalize(module->policy) < 0) { ERR(state->handle, "Error while normalizing conditionals within the module %s.", module->policy->name); return -1; } return 0; } static int prepare_base(link_state_t * state, uint32_t num_mod_decls) { avrule_block_t *cur = state->base->global; assert(cur != NULL); state->next_decl_id = 0; /* iterate through all of the declarations in the base, to determine what the next decl_id should be */ while (cur != NULL) { avrule_decl_t *decl; for (decl = cur->branch_list; decl != NULL; decl = decl->next) { if (decl->decl_id > state->next_decl_id) { state->next_decl_id = decl->decl_id; } } state->last_avrule_block = cur; cur = cur->next; } state->last_base_avrule_block = state->last_avrule_block; state->next_decl_id++; /* allocate the table mapping from base's decl_id to its * avrule_decls and set the initial mappings */ free(state->base->decl_val_to_struct); if ((state->base->decl_val_to_struct = calloc(state->next_decl_id + num_mod_decls, sizeof(*(state->base->decl_val_to_struct)))) == NULL) { ERR(state->handle, "Out of memory!"); return -1; } /* This allocates the decl block to module mapping used for error reporting */ if ((state->decl_to_mod = calloc(state->next_decl_id + num_mod_decls, sizeof(*(state->decl_to_mod)))) == NULL) { ERR(state->handle, "Out of memory!"); return -1; } cur = state->base->global; while (cur != NULL) { avrule_decl_t *decl = cur->branch_list; while (decl != NULL) { state->base->decl_val_to_struct[decl->decl_id - 1] = decl; state->decl_to_mod[decl->decl_id] = state->base; decl = decl->next; } cur = cur->next; } /* normalize conditionals within */ if (cond_normalize(state->base) < 0) { ERR(state->handle, "Error while normalizing conditionals within the base module."); return -1; } return 0; } static int expand_role_attributes(hashtab_key_t key, hashtab_datum_t datum, void * data) { char *id; role_datum_t *role, *sub_attr; link_state_t *state; unsigned int i; ebitmap_node_t *rnode; id = key; role = (role_datum_t *)datum; state = (link_state_t *)data; if (strcmp(id, OBJECT_R) == 0){ /* object_r is never a role attribute by far */ return 0; } if (role->flavor != ROLE_ATTRIB) return 0; if (state->verbose) INFO(state->handle, "expanding role attribute %s", id); restart: ebitmap_for_each_bit(&role->roles, rnode, i) { if (ebitmap_node_get_bit(rnode, i)) { sub_attr = state->base->role_val_to_struct[i]; if (sub_attr->flavor != ROLE_ATTRIB) continue; /* remove the sub role attribute from the parent * role attribute's roles ebitmap */ if (ebitmap_set_bit(&role->roles, i, 0)) return -1; /* loop dependency of role attributes */ if (sub_attr->s.value == role->s.value) continue; /* now go on to expand a sub role attribute * by escalating its roles ebitmap */ if (ebitmap_union(&role->roles, &sub_attr->roles)) { ERR(state->handle, "Out of memory!"); return -1; } /* sub_attr->roles may contain other role attributes, * re-scan the parent role attribute's roles ebitmap */ goto restart; } } return 0; } /* For any role attribute in a declaration's local symtab[SYM_ROLES] table, * copy its roles ebitmap into its duplicate's in the base->p_roles.table. */ static int populate_decl_roleattributes(hashtab_key_t key, hashtab_datum_t datum, void *data) { char *id = key; role_datum_t *decl_role, *base_role; link_state_t *state = (link_state_t *)data; decl_role = (role_datum_t *)datum; if (strcmp(id, OBJECT_R) == 0) { /* object_r is never a role attribute by far */ return 0; } if (decl_role->flavor != ROLE_ATTRIB) return 0; base_role = (role_datum_t *)hashtab_search(state->base->p_roles.table, id); assert(base_role != NULL && base_role->flavor == ROLE_ATTRIB); if (ebitmap_union(&base_role->roles, &decl_role->roles)) { ERR(state->handle, "Out of memory!"); return -1; } return 0; } static int populate_roleattributes(link_state_t *state, policydb_t *pol) { avrule_block_t *block; avrule_decl_t *decl; if (state->verbose) INFO(state->handle, "Populating role-attribute relationship " "from enabled declarations' local symtab."); /* Iterate through all of the blocks skipping the first(which is the * global block, is required to be present and can't have an else). * If the block is disabled or not having an enabled decl, skip it. */ for (block = pol->global->next; block != NULL; block = block->next) { decl = block->enabled; if (decl == NULL || decl->enabled == 0) continue; if (hashtab_map(decl->symtab[SYM_ROLES].table, populate_decl_roleattributes, state)) return -1; } return 0; } /* Link a set of modules into a base module. This process is somewhat * similar to an actual compiler: it requires a set of order dependent * steps. The base and every module must have been indexed prior to * calling this function. */ int link_modules(sepol_handle_t * handle, policydb_t * b, policydb_t ** mods, int len, int verbose) { int i, ret, retval = -1; policy_module_t **modules = NULL; link_state_t state; uint32_t num_mod_decls = 0; memset(&state, 0, sizeof(state)); state.base = b; state.verbose = verbose; state.handle = handle; if (b->policy_type != POLICY_BASE) { ERR(state.handle, "Target of link was not a base policy."); return -1; } /* first allocate some space to hold the maps from module * symbol's value to the destination symbol value; then do * other preparation work */ if ((modules = (policy_module_t **) calloc(len, sizeof(*modules))) == NULL) { ERR(state.handle, "Out of memory!"); return -1; } for (i = 0; i < len; i++) { if (mods[i]->policy_type != POLICY_MOD) { ERR(state.handle, "Tried to link in a policy that was not a module."); goto cleanup; } if (mods[i]->mls != b->mls) { if (b->mls) ERR(state.handle, "Tried to link in a non-MLS module with an MLS base."); else ERR(state.handle, "Tried to link in an MLS module with a non-MLS base."); goto cleanup; } if ((modules[i] = (policy_module_t *) calloc(1, sizeof(policy_module_t))) == NULL) { ERR(state.handle, "Out of memory!"); goto cleanup; } modules[i]->policy = mods[i]; if (prepare_module(&state, modules[i]) == -1) { goto cleanup; } num_mod_decls += modules[i]->num_decls; } if (prepare_base(&state, num_mod_decls) == -1) { goto cleanup; } /* copy all types, declared and required */ for (i = 0; i < len; i++) { state.cur = modules[i]; state.cur_mod_name = modules[i]->policy->name; ret = hashtab_map(modules[i]->policy->p_types.table, type_copy_callback, &state); if (ret) { retval = ret; goto cleanup; } } /* then copy everything else, including aliases, and fixup attributes */ for (i = 0; i < len; i++) { state.cur = modules[i]; state.cur_mod_name = modules[i]->policy->name; ret = copy_identifiers(&state, modules[i]->policy->symtab, NULL); if (ret) { retval = ret; goto cleanup; } } if (policydb_index_others(state.handle, state.base, 0)) { ERR(state.handle, "Error while indexing others"); goto cleanup; } /* copy and remap the module's data over to base */ for (i = 0; i < len; i++) { state.cur = modules[i]; ret = copy_module(&state, modules[i]); if (ret) { retval = ret; goto cleanup; } } /* re-index base, for symbols were added to symbol tables */ if (policydb_index_classes(state.base)) { ERR(state.handle, "Error while indexing classes"); goto cleanup; } if (policydb_index_others(state.handle, state.base, 0)) { ERR(state.handle, "Error while indexing others"); goto cleanup; } if (enable_avrules(&state, state.base)) { retval = SEPOL_EREQ; goto cleanup; } /* Now that all role attribute's roles ebitmap have been settled, * escalate sub role attribute's roles ebitmap into that of parent. * * First, since some role-attribute relationships could be recorded * in some decl's local symtab(see get_local_role()), we need to * populate them up to the base.p_roles table. */ if (populate_roleattributes(&state, state.base)) { retval = SEPOL_EREQ; goto cleanup; } /* Now do the escalation. */ if (hashtab_map(state.base->p_roles.table, expand_role_attributes, &state)) goto cleanup; retval = 0; cleanup: for (i = 0; modules != NULL && i < len; i++) { policy_module_destroy(modules[i]); } free(modules); free(state.decl_to_mod); return retval; }