/* Authors: Karl MacMillan * Jason Tang * Joshua Brindle * * Copyright (C) 2004-2005 Tresys Technology, LLC * Copyright (C) 2007 Red Hat, Inc. * Copyright (C) 2017 Mellanox Technologies, 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 "context.h" #include #include #include #include #include #include #include #include #include #include #include #include #include "debug.h" #include "private.h" typedef struct expand_state { int verbose; uint32_t *typemap; uint32_t *boolmap; uint32_t *rolemap; uint32_t *usermap; policydb_t *base; policydb_t *out; sepol_handle_t *handle; int expand_neverallow; } expand_state_t; static void expand_state_init(expand_state_t * state) { memset(state, 0, sizeof(expand_state_t)); } static int map_ebitmap(ebitmap_t * src, ebitmap_t * dst, uint32_t * map) { unsigned int i; ebitmap_node_t *tnode; ebitmap_init(dst); ebitmap_for_each_bit(src, tnode, i) { if (!ebitmap_node_get_bit(tnode, i)) continue; if (!map[i]) continue; if (ebitmap_set_bit(dst, map[i] - 1, 1)) return -1; } return 0; } static int type_copy_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { int ret; char *id, *new_id; type_datum_t *type, *new_type; expand_state_t *state; id = (char *)key; type = (type_datum_t *) datum; state = (expand_state_t *) data; if ((type->flavor == TYPE_TYPE && !type->primary) || type->flavor == TYPE_ALIAS) { /* aliases are handled later */ return 0; } if (!is_id_enabled(id, state->base, SYM_TYPES)) { /* identifier's scope is not enabled */ return 0; } if (state->verbose) INFO(state->handle, "copying type or attribute %s", id); new_id = strdup(id); if (new_id == NULL) { ERR(state->handle, "Out of memory!"); return -1; } new_type = (type_datum_t *) malloc(sizeof(type_datum_t)); if (!new_type) { ERR(state->handle, "Out of memory!"); free(new_id); return SEPOL_ENOMEM; } memset(new_type, 0, sizeof(type_datum_t)); new_type->flavor = type->flavor; new_type->flags = type->flags; new_type->s.value = ++state->out->p_types.nprim; if (new_type->s.value > UINT16_MAX) { free(new_id); free(new_type); ERR(state->handle, "type space overflow"); return -1; } new_type->primary = 1; state->typemap[type->s.value - 1] = new_type->s.value; ret = hashtab_insert(state->out->p_types.table, (hashtab_key_t) new_id, (hashtab_datum_t) new_type); if (ret) { free(new_id); free(new_type); ERR(state->handle, "hashtab overflow"); return -1; } if (new_type->flags & TYPE_FLAGS_PERMISSIVE) if (ebitmap_set_bit(&state->out->permissive_map, new_type->s.value, 1)) { ERR(state->handle, "Out of memory!\n"); return -1; } return 0; } static int attr_convert_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { char *id; type_datum_t *type, *new_type; expand_state_t *state; ebitmap_t tmp_union; id = (char *)key; type = (type_datum_t *) datum; state = (expand_state_t *) data; if (type->flavor != TYPE_ATTRIB) return 0; if (!is_id_enabled(id, state->base, SYM_TYPES)) { /* identifier's scope is not enabled */ return 0; } if (state->verbose) INFO(state->handle, "converting attribute %s", id); new_type = hashtab_search(state->out->p_types.table, id); if (!new_type) { ERR(state->handle, "attribute %s vanished!", id); return -1; } if (map_ebitmap(&type->types, &tmp_union, state->typemap)) { ERR(state->handle, "out of memory"); return -1; } /* then union tmp_union onto &new_type->types */ if (ebitmap_union(&new_type->types, &tmp_union)) { ERR(state->handle, "Out of memory!"); return -1; } ebitmap_destroy(&tmp_union); return 0; } static int perm_copy_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { int ret; char *id, *new_id; symtab_t *s; perm_datum_t *perm, *new_perm; id = key; perm = (perm_datum_t *) datum; s = (symtab_t *) data; new_perm = (perm_datum_t *) malloc(sizeof(perm_datum_t)); if (!new_perm) { return -1; } memset(new_perm, 0, sizeof(perm_datum_t)); new_id = strdup(id); if (!new_id) { free(new_perm); return -1; } new_perm->s.value = perm->s.value; s->nprim++; ret = hashtab_insert(s->table, new_id, (hashtab_datum_t *) new_perm); if (ret) { free(new_id); free(new_perm); return -1; } return 0; } static int common_copy_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { int ret; char *id, *new_id; common_datum_t *common, *new_common; expand_state_t *state; id = (char *)key; common = (common_datum_t *) datum; state = (expand_state_t *) data; if (state->verbose) INFO(state->handle, "copying common %s", id); new_common = (common_datum_t *) malloc(sizeof(common_datum_t)); if (!new_common) { ERR(state->handle, "Out of memory!"); return -1; } memset(new_common, 0, sizeof(common_datum_t)); if (symtab_init(&new_common->permissions, PERM_SYMTAB_SIZE)) { ERR(state->handle, "Out of memory!"); free(new_common); return -1; } new_id = strdup(id); if (!new_id) { ERR(state->handle, "Out of memory!"); /* free memory created by symtab_init first, then free new_common */ symtab_destroy(&new_common->permissions); free(new_common); return -1; } new_common->s.value = common->s.value; state->out->p_commons.nprim++; ret = hashtab_insert(state->out->p_commons.table, new_id, (hashtab_datum_t *) new_common); if (ret) { ERR(state->handle, "hashtab overflow"); free(new_common); free(new_id); return -1; } if (hashtab_map (common->permissions.table, perm_copy_callback, &new_common->permissions)) { ERR(state->handle, "Out of memory!"); return -1; } return 0; } static int constraint_node_clone(constraint_node_t ** dst, constraint_node_t * src, expand_state_t * state) { constraint_node_t *new_con = NULL, *last_new_con = NULL; constraint_expr_t *new_expr = NULL; *dst = NULL; while (src != NULL) { constraint_expr_t *expr, *expr_l = NULL; new_con = (constraint_node_t *) malloc(sizeof(constraint_node_t)); if (!new_con) { goto out_of_mem; } memset(new_con, 0, sizeof(constraint_node_t)); new_con->permissions = src->permissions; for (expr = src->expr; expr; expr = expr->next) { if ((new_expr = calloc(1, sizeof(*new_expr))) == NULL) { goto out_of_mem; } if (constraint_expr_init(new_expr) == -1) { goto out_of_mem; } new_expr->expr_type = expr->expr_type; new_expr->attr = expr->attr; new_expr->op = expr->op; if (new_expr->expr_type == CEXPR_NAMES) { if (new_expr->attr & CEXPR_TYPE) { /* * Copy over constraint policy source types and/or * attributes for sepol_compute_av_reason_buffer(3) * so that utilities can analyse constraint errors. */ if (map_ebitmap(&expr->type_names->types, &new_expr->type_names->types, state->typemap)) { ERR(NULL, "Failed to map type_names->types"); goto out_of_mem; } /* Type sets require expansion and conversion. */ if (expand_convert_type_set(state->out, state-> typemap, expr-> type_names, &new_expr-> names, 1)) { goto out_of_mem; } } else if (new_expr->attr & CEXPR_ROLE) { if (map_ebitmap(&expr->names, &new_expr->names, state->rolemap)) { goto out_of_mem; } } else if (new_expr->attr & CEXPR_USER) { if (map_ebitmap(&expr->names, &new_expr->names, state->usermap)) { goto out_of_mem; } } else { /* Other kinds of sets do not. */ if (ebitmap_cpy(&new_expr->names, &expr->names)) { goto out_of_mem; } } } if (expr_l) { expr_l->next = new_expr; } else { new_con->expr = new_expr; } expr_l = new_expr; new_expr = NULL; } if (last_new_con == NULL) { *dst = new_con; } else { last_new_con->next = new_con; } last_new_con = new_con; src = src->next; } return 0; out_of_mem: ERR(state->handle, "Out of memory!"); if (new_con) free(new_con); constraint_expr_destroy(new_expr); return -1; } static int class_copy_default_new_object(expand_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) { int ret; char *id, *new_id; class_datum_t *class, *new_class; expand_state_t *state; id = (char *)key; class = (class_datum_t *) datum; state = (expand_state_t *) data; if (!is_id_enabled(id, state->base, SYM_CLASSES)) { /* identifier's scope is not enabled */ return 0; } if (state->verbose) INFO(state->handle, "copying class %s", id); new_class = (class_datum_t *) malloc(sizeof(class_datum_t)); if (!new_class) { ERR(state->handle, "Out of memory!"); return -1; } memset(new_class, 0, sizeof(class_datum_t)); if (symtab_init(&new_class->permissions, PERM_SYMTAB_SIZE)) { ERR(state->handle, "Out of memory!"); free(new_class); return -1; } new_class->s.value = class->s.value; state->out->p_classes.nprim++; ret = class_copy_default_new_object(state, class, new_class); if (ret) { free(new_class); return ret; } new_id = strdup(id); if (!new_id) { ERR(state->handle, "Out of memory!"); free(new_class); return -1; } ret = hashtab_insert(state->out->p_classes.table, new_id, (hashtab_datum_t *) new_class); if (ret) { ERR(state->handle, "hashtab overflow"); free(new_class); free(new_id); return -1; } if (hashtab_map (class->permissions.table, perm_copy_callback, &new_class->permissions)) { ERR(state->handle, "hashtab overflow"); return -1; } if (class->comkey) { new_class->comkey = strdup(class->comkey); if (!new_class->comkey) { ERR(state->handle, "Out of memory!"); return -1; } new_class->comdatum = hashtab_search(state->out->p_commons.table, new_class->comkey); if (!new_class->comdatum) { ERR(state->handle, "could not find common datum %s", new_class->comkey); return -1; } new_class->permissions.nprim += new_class->comdatum->permissions.nprim; } return 0; } static int constraint_copy_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { char *id; class_datum_t *class, *new_class; expand_state_t *state; id = (char *)key; class = (class_datum_t *) datum; state = (expand_state_t *) data; new_class = hashtab_search(state->out->p_classes.table, id); if (!new_class) { ERR(state->handle, "class %s vanished", id); return -1; } /* constraints */ if (constraint_node_clone (&new_class->constraints, class->constraints, state) == -1 || constraint_node_clone(&new_class->validatetrans, class->validatetrans, state) == -1) { return -1; } return 0; } /* * 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) { expand_state_t *state = (expand_state_t *) data; type_datum_t *type = (type_datum_t *) datum; type_datum_t *dest; uint32_t bounds_val; if (!type->bounds) return 0; if (!is_id_enabled((char *)key, state->base, SYM_TYPES)) return 0; bounds_val = state->typemap[type->bounds - 1]; dest = hashtab_search(state->out->p_types.table, (char *)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) { expand_state_t *state = (expand_state_t *) data; role_datum_t *role = (role_datum_t *) datum; role_datum_t *dest; uint32_t bounds_val; if (!role->bounds) return 0; if (!is_id_enabled((char *)key, state->base, SYM_ROLES)) return 0; bounds_val = state->rolemap[role->bounds - 1]; dest = hashtab_search(state->out->p_roles.table, (char *)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) { expand_state_t *state = (expand_state_t *) data; user_datum_t *user = (user_datum_t *) datum; user_datum_t *dest; uint32_t bounds_val; if (!user->bounds) return 0; if (!is_id_enabled((char *)key, state->base, SYM_USERS)) return 0; bounds_val = state->usermap[user->bounds - 1]; dest = hashtab_search(state->out->p_users.table, (char *)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 out 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) { int ret; char *id, *new_id; type_datum_t *alias, *new_alias; expand_state_t *state; uint32_t prival; id = (char *)key; alias = (type_datum_t *) datum; state = (expand_state_t *) data; /* ignore regular types */ if (alias->flavor == TYPE_TYPE && alias->primary) return 0; /* ignore attributes */ if (alias->flavor == TYPE_ATTRIB) return 0; if (alias->flavor == TYPE_ALIAS) prival = alias->primary; else prival = alias->s.value; if (!is_id_enabled(state->base->p_type_val_to_name[prival - 1], state->base, SYM_TYPES)) { /* The primary type for this alias is not enabled, the alias * shouldn't be either */ return 0; } if (state->verbose) INFO(state->handle, "copying alias %s", id); new_id = strdup(id); if (!new_id) { ERR(state->handle, "Out of memory!"); return -1; } new_alias = (type_datum_t *) malloc(sizeof(type_datum_t)); if (!new_alias) { ERR(state->handle, "Out of memory!"); free(new_id); return SEPOL_ENOMEM; } memset(new_alias, 0, sizeof(type_datum_t)); if (alias->flavor == TYPE_TYPE) new_alias->s.value = state->typemap[alias->s.value - 1]; else if (alias->flavor == TYPE_ALIAS) new_alias->s.value = state->typemap[alias->primary - 1]; else assert(0); /* unreachable */ new_alias->flags = alias->flags; ret = hashtab_insert(state->out->p_types.table, (hashtab_key_t) new_id, (hashtab_datum_t) new_alias); if (ret) { ERR(state->handle, "hashtab overflow"); free(new_alias); free(new_id); return -1; } state->typemap[alias->s.value - 1] = new_alias->s.value; if (new_alias->flags & TYPE_FLAGS_PERMISSIVE) if (ebitmap_set_bit(&state->out->permissive_map, new_alias->s.value, 1)) { ERR(state->handle, "Out of memory!"); return -1; } return 0; } static int role_remap_dominates(hashtab_key_t key __attribute__ ((unused)), hashtab_datum_t datum, void *data) { ebitmap_t mapped_roles; role_datum_t *role = (role_datum_t *) datum; expand_state_t *state = (expand_state_t *) data; if (map_ebitmap(&role->dominates, &mapped_roles, state->rolemap)) return -1; ebitmap_destroy(&role->dominates); if (ebitmap_cpy(&role->dominates, &mapped_roles)) return -1; ebitmap_destroy(&mapped_roles); return 0; } /* For the role attribute in the base module, escalate its counterpart's * types.types ebitmap in the out module to the counterparts of all the * regular role that belongs to the current role attribute. Note, must be * invoked after role_copy_callback so that state->rolemap is available. */ static int role_fix_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { char *id, *base_reg_role_id; role_datum_t *role, *new_role, *regular_role; expand_state_t *state; ebitmap_node_t *rnode; unsigned int i; ebitmap_t mapped_roles; id = key; role = (role_datum_t *)datum; state = (expand_state_t *)data; if (strcmp(id, OBJECT_R) == 0) { /* object_r is never a role attribute by far */ return 0; } if (!is_id_enabled(id, state->base, SYM_ROLES)) { /* identifier's scope is not enabled */ return 0; } if (role->flavor != ROLE_ATTRIB) return 0; if (state->verbose) INFO(state->handle, "fixing role attribute %s", id); new_role = (role_datum_t *)hashtab_search(state->out->p_roles.table, id); assert(new_role != NULL && new_role->flavor == ROLE_ATTRIB); ebitmap_init(&mapped_roles); if (map_ebitmap(&role->roles, &mapped_roles, state->rolemap)) return -1; if (ebitmap_union(&new_role->roles, &mapped_roles)) { ERR(state->handle, "Out of memory!"); ebitmap_destroy(&mapped_roles); return -1; } ebitmap_destroy(&mapped_roles); ebitmap_for_each_bit(&role->roles, rnode, i) { if (ebitmap_node_get_bit(rnode, i)) { /* take advantage of sym_val_to_name[] * of the base module */ base_reg_role_id = state->base->p_role_val_to_name[i]; regular_role = (role_datum_t *)hashtab_search( state->out->p_roles.table, base_reg_role_id); assert(regular_role != NULL && regular_role->flavor == ROLE_ROLE); if (ebitmap_union(®ular_role->types.types, &new_role->types.types)) { ERR(state->handle, "Out of memory!"); return -1; } } } return 0; } static int role_copy_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { int ret; char *id, *new_id; role_datum_t *role; role_datum_t *new_role; expand_state_t *state; ebitmap_t tmp_union_types; id = key; role = (role_datum_t *) datum; state = (expand_state_t *) data; if (strcmp(id, OBJECT_R) == 0) { /* object_r is always value 1 */ state->rolemap[role->s.value - 1] = 1; return 0; } if (!is_id_enabled(id, state->base, SYM_ROLES)) { /* identifier's scope is not enabled */ return 0; } if (state->verbose) INFO(state->handle, "copying role %s", id); new_role = (role_datum_t *) hashtab_search(state->out->p_roles.table, id); if (!new_role) { new_role = (role_datum_t *) malloc(sizeof(role_datum_t)); if (!new_role) { ERR(state->handle, "Out of memory!"); return -1; } memset(new_role, 0, sizeof(role_datum_t)); new_id = strdup(id); if (!new_id) { ERR(state->handle, "Out of memory!"); free(new_role); return -1; } state->out->p_roles.nprim++; new_role->flavor = role->flavor; new_role->s.value = state->out->p_roles.nprim; state->rolemap[role->s.value - 1] = new_role->s.value; ret = hashtab_insert(state->out->p_roles.table, (hashtab_key_t) new_id, (hashtab_datum_t) new_role); if (ret) { ERR(state->handle, "hashtab overflow"); free(new_role); free(new_id); return -1; } } /* The dominates bitmap is going to be wrong for the moment, * we'll come back later and remap them, after we are sure all * the roles have been added */ if (ebitmap_union(&new_role->dominates, &role->dominates)) { ERR(state->handle, "Out of memory!"); return -1; } ebitmap_init(&tmp_union_types); /* convert types in the role datum in the global symtab */ if (expand_convert_type_set (state->out, state->typemap, &role->types, &tmp_union_types, 1)) { ebitmap_destroy(&tmp_union_types); ERR(state->handle, "Out of memory!"); return -1; } if (ebitmap_union(&new_role->types.types, &tmp_union_types)) { ERR(state->handle, "Out of memory!"); ebitmap_destroy(&tmp_union_types); return -1; } ebitmap_destroy(&tmp_union_types); return 0; } int mls_semantic_level_expand(mls_semantic_level_t * sl, mls_level_t * l, policydb_t * p, sepol_handle_t * h) { mls_semantic_cat_t *cat; level_datum_t *levdatum; unsigned int i; mls_level_init(l); if (!p->mls) return 0; /* Required not declared. */ if (!sl->sens) return 0; l->sens = sl->sens; levdatum = (level_datum_t *) hashtab_search(p->p_levels.table, p->p_sens_val_to_name[l->sens - 1]); if (!levdatum) { ERR(h, "%s: Impossible situation found, nothing in p_levels.table.\n", __func__); errno = ENOENT; return -1; } for (cat = sl->cat; cat; cat = cat->next) { if (cat->low > cat->high) { ERR(h, "Category range is not valid %s.%s", p->p_cat_val_to_name[cat->low - 1], p->p_cat_val_to_name[cat->high - 1]); return -1; } for (i = cat->low - 1; i < cat->high; i++) { if (!ebitmap_get_bit(&levdatum->level->cat, i)) { ERR(h, "Category %s can not be associated with " "level %s", p->p_cat_val_to_name[i], p->p_sens_val_to_name[l->sens - 1]); return -1; } if (ebitmap_set_bit(&l->cat, i, 1)) { ERR(h, "Out of memory!"); return -1; } } } return 0; } int mls_semantic_range_expand(mls_semantic_range_t * sr, mls_range_t * r, policydb_t * p, sepol_handle_t * h) { if (mls_semantic_level_expand(&sr->level[0], &r->level[0], p, h) < 0) return -1; if (mls_semantic_level_expand(&sr->level[1], &r->level[1], p, h) < 0) { mls_level_destroy(&r->level[0]); return -1; } if (!mls_level_dom(&r->level[1], &r->level[0])) { mls_range_destroy(r); ERR(h, "MLS range high level does not dominate low level"); return -1; } return 0; } static int user_copy_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { int ret; expand_state_t *state; user_datum_t *user; user_datum_t *new_user; char *id, *new_id; ebitmap_t tmp_union; id = key; user = (user_datum_t *) datum; state = (expand_state_t *) data; if (!is_id_enabled(id, state->base, SYM_USERS)) { /* identifier's scope is not enabled */ return 0; } if (state->verbose) INFO(state->handle, "copying user %s", id); new_user = (user_datum_t *) hashtab_search(state->out->p_users.table, id); if (!new_user) { new_user = (user_datum_t *) malloc(sizeof(user_datum_t)); if (!new_user) { ERR(state->handle, "Out of memory!"); return -1; } memset(new_user, 0, sizeof(user_datum_t)); state->out->p_users.nprim++; new_user->s.value = state->out->p_users.nprim; state->usermap[user->s.value - 1] = new_user->s.value; new_id = strdup(id); if (!new_id) { ERR(state->handle, "Out of memory!"); free(new_user); return -1; } ret = hashtab_insert(state->out->p_users.table, (hashtab_key_t) new_id, (hashtab_datum_t) new_user); if (ret) { ERR(state->handle, "hashtab overflow"); user_datum_destroy(new_user); free(new_user); free(new_id); return -1; } /* expand the semantic MLS info */ if (mls_semantic_range_expand(&user->range, &new_user->exp_range, state->out, state->handle)) { return -1; } if (mls_semantic_level_expand(&user->dfltlevel, &new_user->exp_dfltlevel, state->out, state->handle)) { return -1; } if (!mls_level_between(&new_user->exp_dfltlevel, &new_user->exp_range.level[0], &new_user->exp_range.level[1])) { ERR(state->handle, "default level not within user " "range"); return -1; } } else { /* require that the MLS info match */ mls_range_t tmp_range; mls_level_t tmp_level; if (mls_semantic_range_expand(&user->range, &tmp_range, state->out, state->handle)) { return -1; } if (mls_semantic_level_expand(&user->dfltlevel, &tmp_level, state->out, state->handle)) { mls_range_destroy(&tmp_range); return -1; } if (!mls_range_eq(&new_user->exp_range, &tmp_range) || !mls_level_eq(&new_user->exp_dfltlevel, &tmp_level)) { mls_range_destroy(&tmp_range); mls_level_destroy(&tmp_level); return -1; } mls_range_destroy(&tmp_range); mls_level_destroy(&tmp_level); } ebitmap_init(&tmp_union); /* get global roles for this user */ if (role_set_expand(&user->roles, &tmp_union, state->out, state->base, state->rolemap)) { ERR(state->handle, "Out of memory!"); ebitmap_destroy(&tmp_union); return -1; } if (ebitmap_union(&new_user->roles.roles, &tmp_union)) { ERR(state->handle, "Out of memory!"); ebitmap_destroy(&tmp_union); return -1; } ebitmap_destroy(&tmp_union); return 0; } static int bool_copy_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { int ret; expand_state_t *state; cond_bool_datum_t *bool, *new_bool; char *id, *new_id; id = key; bool = (cond_bool_datum_t *) datum; state = (expand_state_t *) data; if (!is_id_enabled(id, state->base, SYM_BOOLS)) { /* identifier's scope is not enabled */ return 0; } if (bool->flags & COND_BOOL_FLAGS_TUNABLE) { /* Skip tunables */ return 0; } if (state->verbose) INFO(state->handle, "copying boolean %s", id); new_bool = (cond_bool_datum_t *) malloc(sizeof(cond_bool_datum_t)); if (!new_bool) { ERR(state->handle, "Out of memory!"); return -1; } new_id = strdup(id); if (!new_id) { ERR(state->handle, "Out of memory!"); free(new_bool); return -1; } state->out->p_bools.nprim++; new_bool->s.value = state->out->p_bools.nprim; ret = hashtab_insert(state->out->p_bools.table, (hashtab_key_t) new_id, (hashtab_datum_t) new_bool); if (ret) { ERR(state->handle, "hashtab overflow"); free(new_bool); free(new_id); return -1; } state->boolmap[bool->s.value - 1] = new_bool->s.value; new_bool->state = bool->state; new_bool->flags = bool->flags; return 0; } static int sens_copy_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { expand_state_t *state = (expand_state_t *) data; level_datum_t *level = (level_datum_t *) datum, *new_level = NULL; char *id = (char *)key, *new_id = NULL; if (!is_id_enabled(id, state->base, SYM_LEVELS)) { /* identifier's scope is not enabled */ return 0; } if (state->verbose) INFO(state->handle, "copying sensitivity level %s", id); new_level = (level_datum_t *) malloc(sizeof(level_datum_t)); if (!new_level) goto out_of_mem; level_datum_init(new_level); new_level->level = (mls_level_t *) malloc(sizeof(mls_level_t)); if (!new_level->level) goto out_of_mem; mls_level_init(new_level->level); new_id = strdup(id); if (!new_id) goto out_of_mem; if (mls_level_cpy(new_level->level, level->level)) { goto out_of_mem; } new_level->isalias = level->isalias; state->out->p_levels.nprim++; if (hashtab_insert(state->out->p_levels.table, (hashtab_key_t) new_id, (hashtab_datum_t) new_level)) { goto out_of_mem; } return 0; out_of_mem: ERR(state->handle, "Out of memory!"); if (new_level != NULL && new_level->level != NULL) { mls_level_destroy(new_level->level); free(new_level->level); } level_datum_destroy(new_level); free(new_level); free(new_id); return -1; } static int cats_copy_callback(hashtab_key_t key, hashtab_datum_t datum, void *data) { expand_state_t *state = (expand_state_t *) data; cat_datum_t *cat = (cat_datum_t *) datum, *new_cat = NULL; char *id = (char *)key, *new_id = NULL; if (!is_id_enabled(id, state->base, SYM_CATS)) { /* identifier's scope is not enabled */ return 0; } if (state->verbose) INFO(state->handle, "copying category attribute %s", id); new_cat = (cat_datum_t *) malloc(sizeof(cat_datum_t)); if (!new_cat) goto out_of_mem; cat_datum_init(new_cat); new_id = strdup(id); if (!new_id) goto out_of_mem; new_cat->s.value = cat->s.value; new_cat->isalias = cat->isalias; state->out->p_cats.nprim++; if (hashtab_insert(state->out->p_cats.table, (hashtab_key_t) new_id, (hashtab_datum_t) new_cat)) { goto out_of_mem; } return 0; out_of_mem: ERR(state->handle, "Out of memory!"); cat_datum_destroy(new_cat); free(new_cat); free(new_id); return -1; } static int copy_role_allows(expand_state_t * state, role_allow_rule_t * rules) { unsigned int i, j; role_allow_t *cur_allow, *n, *l; role_allow_rule_t *cur; ebitmap_t roles, new_roles; ebitmap_node_t *snode, *tnode; /* start at the end of the list */ for (l = state->out->role_allow; l && l->next; l = l->next) ; cur = rules; while (cur) { ebitmap_init(&roles); ebitmap_init(&new_roles); if (role_set_expand(&cur->roles, &roles, state->out, state->base, state->rolemap)) { ERR(state->handle, "Out of memory!"); return -1; } if (role_set_expand(&cur->new_roles, &new_roles, state->out, state->base, state->rolemap)) { ERR(state->handle, "Out of memory!"); return -1; } ebitmap_for_each_bit(&roles, snode, i) { if (!ebitmap_node_get_bit(snode, i)) continue; ebitmap_for_each_bit(&new_roles, tnode, j) { if (!ebitmap_node_get_bit(tnode, j)) continue; /* check for duplicates */ cur_allow = state->out->role_allow; while (cur_allow) { if ((cur_allow->role == i + 1) && (cur_allow->new_role == j + 1)) break; cur_allow = cur_allow->next; } if (cur_allow) continue; n = (role_allow_t *) malloc(sizeof(role_allow_t)); if (!n) { ERR(state->handle, "Out of memory!"); return -1; } memset(n, 0, sizeof(role_allow_t)); n->role = i + 1; n->new_role = j + 1; if (l) { l->next = n; } else { state->out->role_allow = n; } l = n; } } ebitmap_destroy(&roles); ebitmap_destroy(&new_roles); cur = cur->next; } return 0; } static int copy_role_trans(expand_state_t * state, role_trans_rule_t * rules) { unsigned int i, j, k; role_trans_t *n, *l, *cur_trans; role_trans_rule_t *cur; ebitmap_t roles, types; ebitmap_node_t *rnode, *tnode, *cnode; /* start at the end of the list */ for (l = state->out->role_tr; l && l->next; l = l->next) ; cur = rules; while (cur) { ebitmap_init(&roles); ebitmap_init(&types); if (role_set_expand(&cur->roles, &roles, state->out, state->base, state->rolemap)) { ERR(state->handle, "Out of memory!"); return -1; } if (expand_convert_type_set (state->out, state->typemap, &cur->types, &types, 1)) { ERR(state->handle, "Out of memory!"); return -1; } ebitmap_for_each_bit(&roles, rnode, i) { if (!ebitmap_node_get_bit(rnode, i)) continue; ebitmap_for_each_bit(&types, tnode, j) { if (!ebitmap_node_get_bit(tnode, j)) continue; ebitmap_for_each_bit(&cur->classes, cnode, k) { if (!ebitmap_node_get_bit(cnode, k)) continue; cur_trans = state->out->role_tr; while (cur_trans) { unsigned int mapped_role; mapped_role = state->rolemap[cur->new_role - 1]; if ((cur_trans->role == i + 1) && (cur_trans->type == j + 1) && (cur_trans->tclass == k + 1)) { if (cur_trans->new_role == mapped_role) { break; } else { ERR(state->handle, "Conflicting role trans rule %s %s : %s { %s vs %s }", state->out->p_role_val_to_name[i], state->out->p_type_val_to_name[j], state->out->p_class_val_to_name[k], state->out->p_role_val_to_name[mapped_role - 1], state->out->p_role_val_to_name[cur_trans->new_role - 1]); return -1; } } cur_trans = cur_trans->next; } if (cur_trans) continue; n = (role_trans_t *) malloc(sizeof(role_trans_t)); if (!n) { ERR(state->handle, "Out of memory!"); return -1; } memset(n, 0, sizeof(role_trans_t)); n->role = i + 1; n->type = j + 1; n->tclass = k + 1; n->new_role = state->rolemap [cur->new_role - 1]; if (l) l->next = n; else state->out->role_tr = n; l = n; } } } ebitmap_destroy(&roles); ebitmap_destroy(&types); cur = cur->next; } return 0; } static int expand_filename_trans(expand_state_t *state, filename_trans_rule_t *rules) { unsigned int i, j; filename_trans_t key, *new_trans; filename_trans_datum_t *otype; filename_trans_rule_t *cur_rule; ebitmap_t stypes, ttypes; ebitmap_node_t *snode, *tnode; int rc; cur_rule = rules; while (cur_rule) { uint32_t mapped_otype; ebitmap_init(&stypes); ebitmap_init(&ttypes); if (expand_convert_type_set(state->out, state->typemap, &cur_rule->stypes, &stypes, 1)) { ERR(state->handle, "Out of memory!"); return -1; } if (expand_convert_type_set(state->out, state->typemap, &cur_rule->ttypes, &ttypes, 1)) { ERR(state->handle, "Out of memory!"); return -1; } mapped_otype = state->typemap[cur_rule->otype - 1]; ebitmap_for_each_bit(&stypes, snode, i) { if (!ebitmap_node_get_bit(snode, i)) continue; ebitmap_for_each_bit(&ttypes, tnode, j) { if (!ebitmap_node_get_bit(tnode, j)) continue; key.stype = i + 1; key.ttype = j + 1; key.tclass = cur_rule->tclass; key.name = cur_rule->name; otype = hashtab_search(state->out->filename_trans, (hashtab_key_t) &key); if (otype) { /* duplicate rule, ignore */ if (otype->otype == mapped_otype) continue; ERR(state->handle, "Conflicting name-based type_transition %s %s:%s \"%s\": %s vs %s", state->out->p_type_val_to_name[i], state->out->p_type_val_to_name[j], state->out->p_class_val_to_name[cur_rule->tclass - 1], cur_rule->name, state->out->p_type_val_to_name[otype->otype - 1], state->out->p_type_val_to_name[mapped_otype - 1]); return -1; } new_trans = calloc(1, sizeof(*new_trans)); if (!new_trans) { ERR(state->handle, "Out of memory!"); return -1; } new_trans->name = strdup(cur_rule->name); if (!new_trans->name) { ERR(state->handle, "Out of memory!"); return -1; } new_trans->stype = i + 1; new_trans->ttype = j + 1; new_trans->tclass = cur_rule->tclass; otype = calloc(1, sizeof(*otype)); if (!otype) { ERR(state->handle, "Out of memory!"); return -1; } otype->otype = mapped_otype; rc = hashtab_insert(state->out->filename_trans, (hashtab_key_t)new_trans, otype); if (rc) { ERR(state->handle, "Out of memory!"); return -1; } } } ebitmap_destroy(&stypes); ebitmap_destroy(&ttypes); cur_rule = cur_rule->next; } return 0; } static int exp_rangetr_helper(uint32_t stype, uint32_t ttype, uint32_t tclass, mls_semantic_range_t * trange, expand_state_t * state) { range_trans_t *rt = NULL, key; mls_range_t *r, *exp_range = NULL; int rc = -1; exp_range = calloc(1, sizeof(*exp_range)); if (!exp_range) { ERR(state->handle, "Out of memory!"); return -1; } if (mls_semantic_range_expand(trange, exp_range, state->out, state->handle)) goto err; /* check for duplicates/conflicts */ key.source_type = stype; key.target_type = ttype; key.target_class = tclass; r = hashtab_search(state->out->range_tr, (hashtab_key_t) &key); if (r) { if (mls_range_eq(r, exp_range)) { /* duplicate, ignore */ mls_range_destroy(exp_range); free(exp_range); return 0; } /* conflict */ ERR(state->handle, "Conflicting range trans rule %s %s : %s", state->out->p_type_val_to_name[stype - 1], state->out->p_type_val_to_name[ttype - 1], state->out->p_class_val_to_name[tclass - 1]); goto err; } rt = calloc(1, sizeof(*rt)); if (!rt) { ERR(state->handle, "Out of memory!"); goto err; } rt->source_type = stype; rt->target_type = ttype; rt->target_class = tclass; rc = hashtab_insert(state->out->range_tr, (hashtab_key_t) rt, exp_range); if (rc) { ERR(state->handle, "Out of memory!"); goto err; } return 0; err: free(rt); if (exp_range) { mls_range_destroy(exp_range); free(exp_range); } return -1; } static int expand_range_trans(expand_state_t * state, range_trans_rule_t * rules) { unsigned int i, j, k; range_trans_rule_t *rule; ebitmap_t stypes, ttypes; ebitmap_node_t *snode, *tnode, *cnode; if (state->verbose) INFO(state->handle, "expanding range transitions"); for (rule = rules; rule; rule = rule->next) { ebitmap_init(&stypes); ebitmap_init(&ttypes); /* expand the type sets */ if (expand_convert_type_set(state->out, state->typemap, &rule->stypes, &stypes, 1)) { ERR(state->handle, "Out of memory!"); return -1; } if (expand_convert_type_set(state->out, state->typemap, &rule->ttypes, &ttypes, 1)) { ebitmap_destroy(&stypes); ERR(state->handle, "Out of memory!"); return -1; } /* loop on source type */ ebitmap_for_each_bit(&stypes, snode, i) { if (!ebitmap_node_get_bit(snode, i)) continue; /* loop on target type */ ebitmap_for_each_bit(&ttypes, tnode, j) { if (!ebitmap_node_get_bit(tnode, j)) continue; /* loop on target class */ ebitmap_for_each_bit(&rule->tclasses, cnode, k) { if (!ebitmap_node_get_bit(cnode, k)) continue; if (exp_rangetr_helper(i + 1, j + 1, k + 1, &rule->trange, state)) { ebitmap_destroy(&stypes); ebitmap_destroy(&ttypes); return -1; } } } } ebitmap_destroy(&stypes); ebitmap_destroy(&ttypes); } return 0; } /* Search for an AV tab node within a hash table with the given key. * If the node does not exist, create it and return it; otherwise * return the pre-existing one. */ static avtab_ptr_t find_avtab_node(sepol_handle_t * handle, avtab_t * avtab, avtab_key_t * key, cond_av_list_t ** cond, av_extended_perms_t *xperms) { avtab_ptr_t node; avtab_datum_t avdatum; cond_av_list_t *nl; int match = 0; /* AVTAB_XPERMS entries are not necessarily unique */ if (key->specified & AVTAB_XPERMS) { node = avtab_search_node(avtab, key); while (node) { if ((node->datum.xperms->specified == xperms->specified) && (node->datum.xperms->driver == xperms->driver)) { match = 1; break; } node = avtab_search_node_next(node, key->specified); } if (!match) node = NULL; } else { node = avtab_search_node(avtab, key); } /* If this is for conditional policies, keep searching in case the node is part of my conditional avtab. */ if (cond) { while (node) { if (node->parse_context == cond) break; node = avtab_search_node_next(node, key->specified); } } if (!node) { memset(&avdatum, 0, sizeof avdatum); /* * AUDITDENY, aka DONTAUDIT, are &= assigned, versus |= for * others. Initialize the data accordingly. */ avdatum.data = key->specified == AVTAB_AUDITDENY ? ~0 : 0; /* this is used to get the node - insertion is actually unique */ node = avtab_insert_nonunique(avtab, key, &avdatum); if (!node) { ERR(handle, "hash table overflow"); return NULL; } if (cond) { node->parse_context = cond; nl = (cond_av_list_t *) malloc(sizeof(cond_av_list_t)); if (!nl) { ERR(handle, "Memory error"); return NULL; } memset(nl, 0, sizeof(cond_av_list_t)); nl->node = node; nl->next = *cond; *cond = nl; } } return node; } static uint32_t avrule_to_avtab_spec(uint32_t specification) { return (specification == AVRULE_DONTAUDIT) ? AVTAB_AUDITDENY : specification; } #define EXPAND_RULE_SUCCESS 1 #define EXPAND_RULE_CONFLICT 0 #define EXPAND_RULE_ERROR -1 static int expand_terule_helper(sepol_handle_t * handle, policydb_t * p, uint32_t * typemap, uint32_t specified, cond_av_list_t ** cond, cond_av_list_t ** other, uint32_t stype, uint32_t ttype, class_perm_node_t * perms, avtab_t * avtab, int enabled) { avtab_key_t avkey; avtab_datum_t *avdatump; avtab_ptr_t node; class_perm_node_t *cur; int conflict; uint32_t oldtype = 0; if (!(specified & (AVRULE_TRANSITION|AVRULE_MEMBER|AVRULE_CHANGE))) { ERR(handle, "Invalid specification: %"PRIu32"\n", specified); return EXPAND_RULE_ERROR; } avkey.specified = avrule_to_avtab_spec(specified); avkey.source_type = stype + 1; avkey.target_type = ttype + 1; cur = perms; while (cur) { uint32_t remapped_data = typemap ? typemap[cur->data - 1] : cur->data; avkey.target_class = cur->tclass; conflict = 0; /* check to see if the expanded TE already exists -- * either in the global scope or in another * conditional AV tab */ node = avtab_search_node(&p->te_avtab, &avkey); if (node) { conflict = 1; } else { node = avtab_search_node(&p->te_cond_avtab, &avkey); if (node && node->parse_context != other) { conflict = 2; } } if (conflict) { avdatump = &node->datum; if (specified & AVRULE_TRANSITION) { oldtype = avdatump->data; } else if (specified & AVRULE_MEMBER) { oldtype = avdatump->data; } else if (specified & AVRULE_CHANGE) { oldtype = avdatump->data; } if (oldtype == remapped_data) { /* if the duplicate is inside the same scope (eg., unconditional * or in same conditional then ignore it */ if ((conflict == 1 && cond == NULL) || node->parse_context == cond) return EXPAND_RULE_SUCCESS; ERR(handle, "duplicate TE rule for %s %s:%s %s", p->p_type_val_to_name[avkey.source_type - 1], p->p_type_val_to_name[avkey.target_type - 1], p->p_class_val_to_name[avkey.target_class - 1], p->p_type_val_to_name[oldtype - 1]); return EXPAND_RULE_CONFLICT; } ERR(handle, "conflicting TE rule for (%s, %s:%s): old was %s, new is %s", p->p_type_val_to_name[avkey.source_type - 1], p->p_type_val_to_name[avkey.target_type - 1], p->p_class_val_to_name[avkey.target_class - 1], p->p_type_val_to_name[oldtype - 1], p->p_type_val_to_name[remapped_data - 1]); return EXPAND_RULE_CONFLICT; } node = find_avtab_node(handle, avtab, &avkey, cond, NULL); if (!node) return -1; if (enabled) { node->key.specified |= AVTAB_ENABLED; } else { node->key.specified &= ~AVTAB_ENABLED; } avdatump = &node->datum; avdatump->data = remapped_data; cur = cur->next; } return EXPAND_RULE_SUCCESS; } /* 0 for success -1 indicates failure */ static int allocate_xperms(sepol_handle_t * handle, avtab_datum_t * avdatump, av_extended_perms_t * extended_perms) { unsigned int i; avtab_extended_perms_t *xperms = avdatump->xperms; if (!xperms) { xperms = (avtab_extended_perms_t *) calloc(1, sizeof(avtab_extended_perms_t)); if (!xperms) { ERR(handle, "Out of memory!"); return -1; } avdatump->xperms = xperms; } switch (extended_perms->specified) { case AVRULE_XPERMS_IOCTLFUNCTION: xperms->specified = AVTAB_XPERMS_IOCTLFUNCTION; break; case AVRULE_XPERMS_IOCTLDRIVER: xperms->specified = AVTAB_XPERMS_IOCTLDRIVER; break; default: return -1; } xperms->driver = extended_perms->driver; for (i = 0; i < ARRAY_SIZE(xperms->perms); i++) xperms->perms[i] |= extended_perms->perms[i]; return 0; } static int expand_avrule_helper(sepol_handle_t * handle, uint32_t specified, cond_av_list_t ** cond, uint32_t stype, uint32_t ttype, class_perm_node_t * perms, avtab_t * avtab, int enabled, av_extended_perms_t *extended_perms) { avtab_key_t avkey; avtab_datum_t *avdatump; avtab_ptr_t node; class_perm_node_t *cur; /* bail early if dontaudit's are disabled and it's a dontaudit rule */ if ((specified & (AVRULE_DONTAUDIT|AVRULE_XPERMS_DONTAUDIT)) && handle && handle->disable_dontaudit) return EXPAND_RULE_SUCCESS; avkey.source_type = stype + 1; avkey.target_type = ttype + 1; avkey.specified = avrule_to_avtab_spec(specified); cur = perms; while (cur) { avkey.target_class = cur->tclass; node = find_avtab_node(handle, avtab, &avkey, cond, extended_perms); if (!node) return EXPAND_RULE_ERROR; if (enabled) { node->key.specified |= AVTAB_ENABLED; } else { node->key.specified &= ~AVTAB_ENABLED; } avdatump = &node->datum; switch (specified) { case AVRULE_ALLOWED: case AVRULE_AUDITALLOW: case AVRULE_NEVERALLOW: avdatump->data |= cur->data; break; case AVRULE_DONTAUDIT: avdatump->data &= ~cur->data; break; case AVRULE_AUDITDENY: /* Since a '0' in an auditdeny mask represents * a permission we do NOT want to audit * (dontaudit), we use the '&' operand to * ensure that all '0's in the mask are * retained (much unlike the allow and * auditallow cases). */ avdatump->data &= cur->data; break; case AVRULE_XPERMS_ALLOWED: case AVRULE_XPERMS_AUDITALLOW: case AVRULE_XPERMS_DONTAUDIT: case AVRULE_XPERMS_NEVERALLOW: if (allocate_xperms(handle, avdatump, extended_perms)) return EXPAND_RULE_ERROR; break; default: ERR(handle, "Unknown specification: %"PRIu32"\n", specified); return EXPAND_RULE_ERROR; } cur = cur->next; } return EXPAND_RULE_SUCCESS; } static int expand_rule_helper(sepol_handle_t * handle, policydb_t * p, uint32_t * typemap, avrule_t * source_rule, avtab_t * dest_avtab, cond_av_list_t ** cond, cond_av_list_t ** other, int enabled, ebitmap_t * stypes, ebitmap_t * ttypes) { unsigned int i, j; int retval; ebitmap_node_t *snode, *tnode; ebitmap_for_each_bit(stypes, snode, i) { if (!ebitmap_node_get_bit(snode, i)) continue; if (source_rule->flags & RULE_SELF) { if (source_rule->specified & (AVRULE_AV | AVRULE_XPERMS)) { retval = expand_avrule_helper(handle, source_rule->specified, cond, i, i, source_rule->perms, dest_avtab, enabled, source_rule->xperms); if (retval != EXPAND_RULE_SUCCESS) return retval; } else { retval = expand_terule_helper(handle, p, typemap, source_rule->specified, cond, other, i, i, source_rule->perms, dest_avtab, enabled); if (retval != EXPAND_RULE_SUCCESS) return retval; } } ebitmap_for_each_bit(ttypes, tnode, j) { if (!ebitmap_node_get_bit(tnode, j)) continue; if (source_rule->specified & (AVRULE_AV | AVRULE_XPERMS)) { retval = expand_avrule_helper(handle, source_rule->specified, cond, i, j, source_rule->perms, dest_avtab, enabled, source_rule->xperms); if (retval != EXPAND_RULE_SUCCESS) return retval; } else { retval = expand_terule_helper(handle, p, typemap, source_rule->specified, cond, other, i, j, source_rule->perms, dest_avtab, enabled); if (retval != EXPAND_RULE_SUCCESS) return retval; } } } return EXPAND_RULE_SUCCESS; } /* * Expand a rule into a given avtab - checking for conflicting type * rules in the destination policy. Return EXPAND_RULE_SUCCESS on * success, EXPAND_RULE_CONFLICT if the rule conflicts with something * (and hence was not added), or EXPAND_RULE_ERROR on error. */ static int convert_and_expand_rule(sepol_handle_t * handle, policydb_t * dest_pol, uint32_t * typemap, avrule_t * source_rule, avtab_t * dest_avtab, cond_av_list_t ** cond, cond_av_list_t ** other, int enabled, int do_neverallow) { int retval; ebitmap_t stypes, ttypes; unsigned char alwaysexpand; if (!do_neverallow && source_rule->specified & AVRULE_NEVERALLOW) return EXPAND_RULE_SUCCESS; if (!do_neverallow && source_rule->specified & AVRULE_XPERMS_NEVERALLOW) return EXPAND_RULE_SUCCESS; ebitmap_init(&stypes); ebitmap_init(&ttypes); /* Force expansion for type rules and for self rules. */ alwaysexpand = ((source_rule->specified & AVRULE_TYPE) || (source_rule->flags & RULE_SELF)); if (expand_convert_type_set (dest_pol, typemap, &source_rule->stypes, &stypes, alwaysexpand)) return EXPAND_RULE_ERROR; if (expand_convert_type_set (dest_pol, typemap, &source_rule->ttypes, &ttypes, alwaysexpand)) return EXPAND_RULE_ERROR; retval = expand_rule_helper(handle, dest_pol, typemap, source_rule, dest_avtab, cond, other, enabled, &stypes, &ttypes); ebitmap_destroy(&stypes); ebitmap_destroy(&ttypes); return retval; } static int cond_avrule_list_copy(policydb_t * dest_pol, avrule_t * source_rules, avtab_t * dest_avtab, cond_av_list_t ** list, cond_av_list_t ** other, uint32_t * typemap, int enabled, expand_state_t * state) { avrule_t *cur; cur = source_rules; while (cur) { if (convert_and_expand_rule(state->handle, dest_pol, typemap, cur, dest_avtab, list, other, enabled, 0) != EXPAND_RULE_SUCCESS) { return -1; } cur = cur->next; } return 0; } static int cond_node_map_bools(expand_state_t * state, cond_node_t * cn) { cond_expr_t *cur; unsigned int i; cur = cn->expr; while (cur) { if (cur->bool) cur->bool = state->boolmap[cur->bool - 1]; cur = cur->next; } for (i = 0; i < min(cn->nbools, COND_MAX_BOOLS); i++) cn->bool_ids[i] = state->boolmap[cn->bool_ids[i] - 1]; if (cond_normalize_expr(state->out, cn)) { ERR(state->handle, "Error while normalizing conditional"); return -1; } return 0; } /* copy the nodes in *reverse* order -- the result is that the last * given conditional appears first in the policy, so as to match the * behavior of the upstream compiler */ static int cond_node_copy(expand_state_t * state, cond_node_t * cn) { cond_node_t *new_cond, *tmp; if (cn == NULL) { return 0; } if (cond_node_copy(state, cn->next)) { return -1; } /* If current cond_node_t is of tunable, its effective branch * has been appended to its home decl->avrules list during link * and now we should just skip it. */ if (cn->flags & COND_NODE_FLAGS_TUNABLE) return 0; if (cond_normalize_expr(state->base, cn)) { ERR(state->handle, "Error while normalizing conditional"); return -1; } /* create a new temporary conditional node with the booleans * mapped */ tmp = cond_node_create(state->base, cn); if (!tmp) { ERR(state->handle, "Out of memory"); return -1; } if (cond_node_map_bools(state, tmp)) { cond_node_destroy(tmp); free(tmp); ERR(state->handle, "Error mapping booleans"); return -1; } new_cond = cond_node_search(state->out, state->out->cond_list, tmp); if (!new_cond) { cond_node_destroy(tmp); free(tmp); ERR(state->handle, "Out of memory!"); return -1; } cond_node_destroy(tmp); free(tmp); if (cond_avrule_list_copy (state->out, cn->avtrue_list, &state->out->te_cond_avtab, &new_cond->true_list, &new_cond->false_list, state->typemap, new_cond->cur_state, state)) return -1; if (cond_avrule_list_copy (state->out, cn->avfalse_list, &state->out->te_cond_avtab, &new_cond->false_list, &new_cond->true_list, state->typemap, !new_cond->cur_state, state)) return -1; return 0; } static int context_copy(context_struct_t * dst, context_struct_t * src, expand_state_t * state) { dst->user = state->usermap[src->user - 1]; dst->role = state->rolemap[src->role - 1]; dst->type = state->typemap[src->type - 1]; return mls_context_cpy(dst, src); } static int ocontext_copy_xen(expand_state_t *state) { unsigned int i; ocontext_t *c, *n, *l; for (i = 0; i < OCON_NUM; i++) { l = NULL; for (c = state->base->ocontexts[i]; c; c = c->next) { n = malloc(sizeof(ocontext_t)); if (!n) { ERR(state->handle, "Out of memory!"); return -1; } memset(n, 0, sizeof(ocontext_t)); if (l) l->next = n; else state->out->ocontexts[i] = n; l = n; switch (i) { case OCON_XEN_ISID: if (c->context[0].user == 0) { ERR(state->handle, "Missing context for %s initial sid", c->u.name); return -1; } n->sid[0] = c->sid[0]; break; case OCON_XEN_PIRQ: n->u.pirq = c->u.pirq; break; case OCON_XEN_IOPORT: n->u.ioport.low_ioport = c->u.ioport.low_ioport; n->u.ioport.high_ioport = c->u.ioport.high_ioport; break; case OCON_XEN_IOMEM: n->u.iomem.low_iomem = c->u.iomem.low_iomem; n->u.iomem.high_iomem = c->u.iomem.high_iomem; break; case OCON_XEN_PCIDEVICE: n->u.device = c->u.device; break; case OCON_XEN_DEVICETREE: n->u.name = strdup(c->u.name); if (!n->u.name) { ERR(state->handle, "Out of memory!"); return -1; } break; default: /* shouldn't get here */ ERR(state->handle, "Unknown ocontext"); return -1; } if (context_copy(&n->context[0], &c->context[0], state)) { ERR(state->handle, "Out of memory!"); return -1; } } } return 0; } static int ocontext_copy_selinux(expand_state_t *state) { unsigned int i, j; ocontext_t *c, *n, *l; for (i = 0; i < OCON_NUM; i++) { l = NULL; for (c = state->base->ocontexts[i]; c; c = c->next) { n = malloc(sizeof(ocontext_t)); if (!n) { ERR(state->handle, "Out of memory!"); return -1; } memset(n, 0, sizeof(ocontext_t)); if (l) l->next = n; else state->out->ocontexts[i] = n; l = n; switch (i) { case OCON_ISID: if (c->context[0].user == 0) { ERR(state->handle, "Missing context for %s initial sid", c->u.name); return -1; } n->sid[0] = c->sid[0]; break; case OCON_FS: /* FALLTHROUGH */ case OCON_NETIF: n->u.name = strdup(c->u.name); if (!n->u.name) { ERR(state->handle, "Out of memory!"); return -1; } if (context_copy (&n->context[1], &c->context[1], state)) { ERR(state->handle, "Out of memory!"); return -1; } break; case OCON_IBPKEY: n->u.ibpkey.subnet_prefix = c->u.ibpkey.subnet_prefix; n->u.ibpkey.low_pkey = c->u.ibpkey.low_pkey; n->u.ibpkey.high_pkey = c->u.ibpkey.high_pkey; break; case OCON_IBENDPORT: n->u.ibendport.dev_name = strdup(c->u.ibendport.dev_name); if (!n->u.ibendport.dev_name) { ERR(state->handle, "Out of memory!"); return -1; } n->u.ibendport.port = c->u.ibendport.port; break; case OCON_PORT: n->u.port.protocol = c->u.port.protocol; n->u.port.low_port = c->u.port.low_port; n->u.port.high_port = c->u.port.high_port; break; case OCON_NODE: n->u.node.addr = c->u.node.addr; n->u.node.mask = c->u.node.mask; break; case OCON_FSUSE: n->v.behavior = c->v.behavior; n->u.name = strdup(c->u.name); if (!n->u.name) { ERR(state->handle, "Out of memory!"); return -1; } break; case OCON_NODE6: for (j = 0; j < 4; j++) n->u.node6.addr[j] = c->u.node6.addr[j]; for (j = 0; j < 4; j++) n->u.node6.mask[j] = c->u.node6.mask[j]; break; default: /* shouldn't get here */ ERR(state->handle, "Unknown ocontext"); return -1; } if (context_copy(&n->context[0], &c->context[0], state)) { ERR(state->handle, "Out of memory!"); return -1; } } } return 0; } static int ocontext_copy(expand_state_t *state, uint32_t target) { int rc = -1; switch (target) { case SEPOL_TARGET_SELINUX: rc = ocontext_copy_selinux(state); break; case SEPOL_TARGET_XEN: rc = ocontext_copy_xen(state); break; default: ERR(state->handle, "Unknown target"); return -1; } return rc; } static int genfs_copy(expand_state_t * state) { ocontext_t *c, *newc, *l; genfs_t *genfs, *newgenfs, *end; end = NULL; for (genfs = state->base->genfs; genfs; genfs = genfs->next) { newgenfs = malloc(sizeof(genfs_t)); if (!newgenfs) { ERR(state->handle, "Out of memory!"); return -1; } memset(newgenfs, 0, sizeof(genfs_t)); newgenfs->fstype = strdup(genfs->fstype); if (!newgenfs->fstype) { free(newgenfs); ERR(state->handle, "Out of memory!"); return -1; } if (!end) state->out->genfs = newgenfs; else end->next = newgenfs; end = newgenfs; l = NULL; for (c = genfs->head; c; c = c->next) { newc = malloc(sizeof(ocontext_t)); if (!newc) { ERR(state->handle, "Out of memory!"); return -1; } memset(newc, 0, sizeof(ocontext_t)); newc->u.name = strdup(c->u.name); if (!newc->u.name) { ERR(state->handle, "Out of memory!"); free(newc); return -1; } newc->v.sclass = c->v.sclass; context_copy(&newc->context[0], &c->context[0], state); if (l) l->next = newc; else newgenfs->head = newc; l = newc; } } return 0; } static int type_attr_map(hashtab_key_t key __attribute__ ((unused)), hashtab_datum_t datum, void *ptr) { type_datum_t *type; expand_state_t *state = ptr; policydb_t *p = state->out; unsigned int i; ebitmap_node_t *tnode; int value; type = (type_datum_t *) datum; value = type->s.value; if (type->flavor == TYPE_ATTRIB) { if (!(type->flags & TYPE_FLAGS_EXPAND_ATTR_TRUE)) { if (ebitmap_cpy(&p->attr_type_map[value - 1], &type->types)) { goto oom; } ebitmap_for_each_bit(&type->types, tnode, i) { if (!ebitmap_node_get_bit(tnode, i)) continue; if (ebitmap_set_bit(&p->type_attr_map[i], value - 1, 1)) { goto oom; } } } else { /* Attribute is being expanded, so remove */ if (ebitmap_set_bit(&p->type_attr_map[value - 1], value - 1, 0)) { goto oom; } } } else { if (ebitmap_set_bit(&p->attr_type_map[value - 1], value - 1, 1)) { goto oom; } } return 0; oom: ERR(state->handle, "Out of memory!"); return -1; } /* converts typeset using typemap and expands into ebitmap_t types using the attributes in the passed in policy. * this should not be called until after all the blocks have been processed and the attributes in target policy * are complete. */ int expand_convert_type_set(policydb_t * p, uint32_t * typemap, type_set_t * set, ebitmap_t * types, unsigned char alwaysexpand) { type_set_t tmpset; type_set_init(&tmpset); if (map_ebitmap(&set->types, &tmpset.types, typemap)) return -1; if (map_ebitmap(&set->negset, &tmpset.negset, typemap)) return -1; tmpset.flags = set->flags; if (type_set_expand(&tmpset, types, p, alwaysexpand)) return -1; type_set_destroy(&tmpset); return 0; } /* Expand a rule into a given avtab - checking for conflicting type * rules. Return 1 on success, 0 if the rule conflicts with something * (and hence was not added), or -1 on error. */ int expand_rule(sepol_handle_t * handle, policydb_t * source_pol, avrule_t * source_rule, avtab_t * dest_avtab, cond_av_list_t ** cond, cond_av_list_t ** other, int enabled) { int retval; ebitmap_t stypes, ttypes; if ((source_rule->specified & AVRULE_NEVERALLOW) || (source_rule->specified & AVRULE_XPERMS_NEVERALLOW)) return 1; ebitmap_init(&stypes); ebitmap_init(&ttypes); if (type_set_expand(&source_rule->stypes, &stypes, source_pol, 1)) return -1; if (type_set_expand(&source_rule->ttypes, &ttypes, source_pol, 1)) return -1; retval = expand_rule_helper(handle, source_pol, NULL, source_rule, dest_avtab, cond, other, enabled, &stypes, &ttypes); ebitmap_destroy(&stypes); ebitmap_destroy(&ttypes); return retval; } /* Expand a role set into an ebitmap containing the roles. * This handles the attribute and flags. * Attribute expansion depends on if the rolemap is available. * During module compile the rolemap is not available, the * possible duplicates of a regular role and the role attribute * the regular role belongs to could be properly handled by * copy_role_trans and copy_role_allow. */ int role_set_expand(role_set_t * x, ebitmap_t * r, policydb_t * out, policydb_t * base, uint32_t * rolemap) { unsigned int i; ebitmap_node_t *rnode; ebitmap_t mapped_roles, roles; policydb_t *p = out; role_datum_t *role; ebitmap_init(r); if (x->flags & ROLE_STAR) { for (i = 0; i < p->p_roles.nprim; i++) if (ebitmap_set_bit(r, i, 1)) return -1; return 0; } ebitmap_init(&mapped_roles); ebitmap_init(&roles); if (rolemap) { assert(base != NULL); ebitmap_for_each_bit(&x->roles, rnode, i) { if (ebitmap_node_get_bit(rnode, i)) { /* take advantage of p_role_val_to_struct[] * of the base module */ role = base->role_val_to_struct[i]; assert(role != NULL); if (role->flavor == ROLE_ATTRIB) { if (ebitmap_union(&roles, &role->roles)) goto bad; } else { if (ebitmap_set_bit(&roles, i, 1)) goto bad; } } } if (map_ebitmap(&roles, &mapped_roles, rolemap)) goto bad; } else { if (ebitmap_cpy(&mapped_roles, &x->roles)) goto bad; } ebitmap_for_each_bit(&mapped_roles, rnode, i) { if (ebitmap_node_get_bit(rnode, i)) { if (ebitmap_set_bit(r, i, 1)) goto bad; } } ebitmap_destroy(&mapped_roles); ebitmap_destroy(&roles); /* if role is to be complimented, invert the entire bitmap here */ if (x->flags & ROLE_COMP) { for (i = 0; i < ebitmap_length(r); i++) { if (ebitmap_get_bit(r, i)) { if (ebitmap_set_bit(r, i, 0)) return -1; } else { if (ebitmap_set_bit(r, i, 1)) return -1; } } } return 0; bad: ebitmap_destroy(&mapped_roles); ebitmap_destroy(&roles); return -1; } /* Expand a type set into an ebitmap containing the types. This * handles the negset, attributes, and flags. * Attribute expansion depends on several factors: * - if alwaysexpand is 1, then they will be expanded, * - if the type set has a negset or flags, then they will be expanded, * - otherwise, they will not be expanded. */ int type_set_expand(type_set_t * set, ebitmap_t * t, policydb_t * p, unsigned char alwaysexpand) { unsigned int i; ebitmap_t types, neg_types; ebitmap_node_t *tnode; unsigned char expand = alwaysexpand || ebitmap_length(&set->negset) || set->flags; type_datum_t *type; int rc =-1; ebitmap_init(&types); ebitmap_init(t); /* First go through the types and OR all the attributes to types */ ebitmap_for_each_bit(&set->types, tnode, i) { if (!ebitmap_node_get_bit(tnode, i)) continue; /* * invalid policies might have more types set in the ebitmap than * what's available in the type_val_to_struct mapping */ if (i >= p->p_types.nprim) goto err_types; type = p->type_val_to_struct[i]; if (!type) { goto err_types; } if (type->flavor == TYPE_ATTRIB && (expand || (type->flags & TYPE_FLAGS_EXPAND_ATTR_TRUE))) { if (ebitmap_union(&types, &type->types)) { goto err_types; } } else { if (ebitmap_set_bit(&types, i, 1)) { goto err_types; } } } /* Now do the same thing for negset */ ebitmap_init(&neg_types); ebitmap_for_each_bit(&set->negset, tnode, i) { if (ebitmap_node_get_bit(tnode, i)) { if (p->type_val_to_struct[i] && p->type_val_to_struct[i]->flavor == TYPE_ATTRIB) { if (ebitmap_union (&neg_types, &p->type_val_to_struct[i]->types)) { goto err_neg; } } else { if (ebitmap_set_bit(&neg_types, i, 1)) { goto err_neg; } } } } if (set->flags & TYPE_STAR) { /* set all types not in neg_types */ for (i = 0; i < p->p_types.nprim; i++) { if (ebitmap_get_bit(&neg_types, i)) continue; if (p->type_val_to_struct[i] && p->type_val_to_struct[i]->flavor == TYPE_ATTRIB) continue; if (ebitmap_set_bit(t, i, 1)) goto err_neg; } goto out; } ebitmap_for_each_bit(&types, tnode, i) { if (ebitmap_node_get_bit(tnode, i) && (!ebitmap_get_bit(&neg_types, i))) if (ebitmap_set_bit(t, i, 1)) goto err_neg; } if (set->flags & TYPE_COMP) { for (i = 0; i < p->p_types.nprim; i++) { if (p->type_val_to_struct[i] && p->type_val_to_struct[i]->flavor == TYPE_ATTRIB) { assert(!ebitmap_get_bit(t, i)); continue; } if (ebitmap_get_bit(t, i)) { if (ebitmap_set_bit(t, i, 0)) goto err_neg; } else { if (ebitmap_set_bit(t, i, 1)) goto err_neg; } } } out: rc = 0; err_neg: ebitmap_destroy(&neg_types); err_types: ebitmap_destroy(&types); return rc; } static int copy_neverallow(policydb_t * dest_pol, uint32_t * typemap, avrule_t * source_rule) { ebitmap_t stypes, ttypes; avrule_t *avrule; class_perm_node_t *cur_perm, *new_perm, *tail_perm; av_extended_perms_t *xperms = NULL; ebitmap_init(&stypes); ebitmap_init(&ttypes); if (expand_convert_type_set (dest_pol, typemap, &source_rule->stypes, &stypes, 1)) return -1; if (expand_convert_type_set (dest_pol, typemap, &source_rule->ttypes, &ttypes, 1)) return -1; avrule = (avrule_t *) malloc(sizeof(avrule_t)); if (!avrule) return -1; avrule_init(avrule); avrule->specified = source_rule->specified; avrule->line = source_rule->line; avrule->flags = source_rule->flags; avrule->source_line = source_rule->source_line; if (source_rule->source_filename) { avrule->source_filename = strdup(source_rule->source_filename); if (!avrule->source_filename) goto err; } if (ebitmap_cpy(&avrule->stypes.types, &stypes)) goto err; if (ebitmap_cpy(&avrule->ttypes.types, &ttypes)) goto err; cur_perm = source_rule->perms; tail_perm = NULL; while (cur_perm) { new_perm = (class_perm_node_t *) malloc(sizeof(class_perm_node_t)); if (!new_perm) goto err; class_perm_node_init(new_perm); new_perm->tclass = cur_perm->tclass; assert(new_perm->tclass); /* once we have modules with permissions we'll need to map the permissions (and classes) */ new_perm->data = cur_perm->data; if (!avrule->perms) avrule->perms = new_perm; if (tail_perm) tail_perm->next = new_perm; tail_perm = new_perm; cur_perm = cur_perm->next; } /* copy over extended permissions */ if (source_rule->xperms) { xperms = calloc(1, sizeof(av_extended_perms_t)); if (!xperms) goto err; memcpy(xperms, source_rule->xperms, sizeof(av_extended_perms_t)); avrule->xperms = xperms; } /* just prepend the avrule to the first branch; it'll never be written to disk */ if (!dest_pol->global->branch_list->avrules) dest_pol->global->branch_list->avrules = avrule; else { avrule->next = dest_pol->global->branch_list->avrules; dest_pol->global->branch_list->avrules = avrule; } ebitmap_destroy(&stypes); ebitmap_destroy(&ttypes); return 0; err: ebitmap_destroy(&stypes); ebitmap_destroy(&ttypes); ebitmap_destroy(&avrule->stypes.types); ebitmap_destroy(&avrule->ttypes.types); cur_perm = avrule->perms; while (cur_perm) { tail_perm = cur_perm->next; free(cur_perm); cur_perm = tail_perm; } free(xperms); free(avrule); return -1; } /* * Expands the avrule blocks for a policy. RBAC rules are copied. Neverallow * rules are copied or expanded as per the settings in the state object; all * other AV rules are expanded. If neverallow rules are expanded, they are not * copied, otherwise they are copied for later use by the assertion checker. */ static int copy_and_expand_avrule_block(expand_state_t * state) { avrule_block_t *curblock = state->base->global; avrule_block_t *prevblock; int retval = -1; if (avtab_alloc(&state->out->te_avtab, MAX_AVTAB_SIZE)) { ERR(state->handle, "Out of Memory!"); return -1; } if (avtab_alloc(&state->out->te_cond_avtab, MAX_AVTAB_SIZE)) { ERR(state->handle, "Out of Memory!"); return -1; } while (curblock) { avrule_decl_t *decl = curblock->enabled; avrule_t *cur_avrule; if (decl == NULL) { /* nothing was enabled within this block */ goto cont; } /* copy role allows and role trans */ if (copy_role_allows(state, decl->role_allow_rules) != 0 || copy_role_trans(state, decl->role_tr_rules) != 0) { goto cleanup; } if (expand_filename_trans(state, decl->filename_trans_rules)) goto cleanup; /* expand the range transition rules */ if (expand_range_trans(state, decl->range_tr_rules)) goto cleanup; /* copy rules */ cur_avrule = decl->avrules; while (cur_avrule != NULL) { if (!(state->expand_neverallow) && cur_avrule->specified & (AVRULE_NEVERALLOW | AVRULE_XPERMS_NEVERALLOW)) { /* copy this over directly so that assertions are checked later */ if (copy_neverallow (state->out, state->typemap, cur_avrule)) ERR(state->handle, "Error while copying neverallow."); } else { if (cur_avrule->specified & (AVRULE_NEVERALLOW | AVRULE_XPERMS_NEVERALLOW)) state->out->unsupported_format = 1; if (convert_and_expand_rule (state->handle, state->out, state->typemap, cur_avrule, &state->out->te_avtab, NULL, NULL, 0, state->expand_neverallow) != EXPAND_RULE_SUCCESS) { goto cleanup; } } cur_avrule = cur_avrule->next; } /* copy conditional rules */ if (cond_node_copy(state, decl->cond_list)) goto cleanup; cont: prevblock = curblock; curblock = curblock->next; if (state->handle && state->handle->expand_consume_base) { /* set base top avrule block in case there * is an error condition and the policy needs * to be destroyed */ state->base->global = curblock; avrule_block_destroy(prevblock); } } retval = 0; cleanup: return retval; } /* * This function allows external users of the library (such as setools) to * expand only the avrules and optionally perform expansion of neverallow rules * or expand into the same policy for analysis purposes. */ int expand_module_avrules(sepol_handle_t * handle, policydb_t * base, policydb_t * out, uint32_t * typemap, uint32_t * boolmap, uint32_t * rolemap, uint32_t * usermap, int verbose, int expand_neverallow) { expand_state_t state; expand_state_init(&state); state.base = base; state.out = out; state.typemap = typemap; state.boolmap = boolmap; state.rolemap = rolemap; state.usermap = usermap; state.handle = handle; state.verbose = verbose; state.expand_neverallow = expand_neverallow; return copy_and_expand_avrule_block(&state); } static void discard_tunables(sepol_handle_t *sh, policydb_t *pol) { avrule_block_t *block; avrule_decl_t *decl; cond_node_t *cur_node; cond_expr_t *cur_expr; int cur_state, preserve_tunables = 0; avrule_t *tail, *to_be_appended; if (sh && sh->preserve_tunables) preserve_tunables = 1; /* Iterate through all cond_node of all enabled decls, if a cond_node * is about tunable, calculate its state value and concatenate one of * its avrule list to the current decl->avrules list. On the other * hand, the disabled unused branch of a tunable would be discarded. * * Note, such tunable cond_node would be skipped over in expansion, * so we won't have to worry about removing it from decl->cond_list * here :-) * * If tunables are requested to be preserved then they would be * "transformed" as booleans by having their TUNABLE flag cleared. */ for (block = pol->global; block != NULL; block = block->next) { decl = block->enabled; if (decl == NULL || decl->enabled == 0) continue; tail = decl->avrules; while (tail && tail->next) tail = tail->next; for (cur_node = decl->cond_list; cur_node != NULL; cur_node = cur_node->next) { int booleans, tunables, i; cond_bool_datum_t *booldatum; cond_bool_datum_t *tmp[COND_EXPR_MAXDEPTH]; booleans = tunables = 0; memset(tmp, 0, sizeof(cond_bool_datum_t *) * COND_EXPR_MAXDEPTH); for (cur_expr = cur_node->expr; cur_expr != NULL; cur_expr = cur_expr->next) { if (cur_expr->expr_type != COND_BOOL) continue; booldatum = pol->bool_val_to_struct[cur_expr->bool - 1]; if (booldatum->flags & COND_BOOL_FLAGS_TUNABLE) tmp[tunables++] = booldatum; else booleans++; } /* bool_copy_callback() at link phase has ensured * that no mixture of tunables and booleans in one * expression. However, this would be broken by the * request to preserve tunables */ if (!preserve_tunables) assert(!(booleans && tunables)); if (booleans || preserve_tunables) { cur_node->flags &= ~COND_NODE_FLAGS_TUNABLE; if (tunables) { for (i = 0; i < tunables; i++) tmp[i]->flags &= ~COND_BOOL_FLAGS_TUNABLE; } } else { cur_node->flags |= COND_NODE_FLAGS_TUNABLE; cur_state = cond_evaluate_expr(pol, cur_node->expr); if (cur_state == -1) { printf("Expression result was " "undefined, skipping all" "rules\n"); continue; } to_be_appended = (cur_state == 1) ? cur_node->avtrue_list : cur_node->avfalse_list; if (tail) tail->next = to_be_appended; else tail = decl->avrules = to_be_appended; /* Now that the effective branch has been * appended, neutralize its original pointer */ if (cur_state == 1) cur_node->avtrue_list = NULL; else cur_node->avfalse_list = NULL; /* Update the tail of decl->avrules for * further concatenation */ while (tail && tail->next) tail = tail->next; } } } } /* Linking should always be done before calling expand, even if * there is only a base since all optionals are dealt with at link time * the base passed in should be indexed and avrule blocks should be * enabled. */ int expand_module(sepol_handle_t * handle, policydb_t * base, policydb_t * out, int verbose, int check) { int retval = -1; unsigned int i; expand_state_t state; avrule_block_t *curblock; /* Append tunable's avtrue_list or avfalse_list to the avrules list * of its home decl depending on its state value, so that the effect * rules of a tunable would be added to te_avtab permanently. Whereas * the disabled unused branch would be discarded. * * Originally this function is called at the very end of link phase, * however, we need to keep the linked policy intact for analysis * purpose. */ discard_tunables(handle, base); expand_state_init(&state); state.verbose = verbose; state.typemap = NULL; state.base = base; state.out = out; state.handle = handle; if (base->policy_type != POLICY_BASE) { ERR(handle, "Target of expand was not a base policy."); return -1; } state.out->policy_type = POLICY_KERN; state.out->policyvers = POLICYDB_VERSION_MAX; /* Copy mls state from base to out */ out->mls = base->mls; out->handle_unknown = base->handle_unknown; /* Copy target from base to out */ out->target_platform = base->target_platform; /* Copy policy capabilities */ if (ebitmap_cpy(&out->policycaps, &base->policycaps)) { ERR(handle, "Out of memory!"); goto cleanup; } if ((state.typemap = (uint32_t *) calloc(state.base->p_types.nprim, sizeof(uint32_t))) == NULL) { ERR(handle, "Out of memory!"); goto cleanup; } state.boolmap = (uint32_t *)calloc(state.base->p_bools.nprim, sizeof(uint32_t)); if (!state.boolmap) { ERR(handle, "Out of memory!"); goto cleanup; } state.rolemap = (uint32_t *)calloc(state.base->p_roles.nprim, sizeof(uint32_t)); if (!state.rolemap) { ERR(handle, "Out of memory!"); goto cleanup; } state.usermap = (uint32_t *)calloc(state.base->p_users.nprim, sizeof(uint32_t)); if (!state.usermap) { ERR(handle, "Out of memory!"); goto cleanup; } /* order is important - types must be first */ /* copy types */ if (hashtab_map(state.base->p_types.table, type_copy_callback, &state)) { goto cleanup; } /* convert attribute type sets */ if (hashtab_map (state.base->p_types.table, attr_convert_callback, &state)) { goto cleanup; } /* copy commons */ if (hashtab_map (state.base->p_commons.table, common_copy_callback, &state)) { goto cleanup; } /* copy classes, note, this does not copy constraints, constraints can't be * copied until after all the blocks have been processed and attributes are complete */ if (hashtab_map (state.base->p_classes.table, class_copy_callback, &state)) { goto cleanup; } /* copy type bounds */ if (hashtab_map(state.base->p_types.table, type_bounds_copy_callback, &state)) goto cleanup; /* copy aliases */ if (hashtab_map(state.base->p_types.table, alias_copy_callback, &state)) goto cleanup; /* index here so that type indexes are available for role_copy_callback */ if (policydb_index_others(handle, out, verbose)) { ERR(handle, "Error while indexing out symbols"); goto cleanup; } /* copy roles */ if (hashtab_map(state.base->p_roles.table, role_copy_callback, &state)) goto cleanup; if (hashtab_map(state.base->p_roles.table, role_bounds_copy_callback, &state)) goto cleanup; /* escalate the type_set_t in a role attribute to all regular roles * that belongs to it. */ if (hashtab_map(state.base->p_roles.table, role_fix_callback, &state)) goto cleanup; /* copy MLS's sensitivity level and categories - this needs to be done * before expanding users (they need to be indexed too) */ if (hashtab_map(state.base->p_levels.table, sens_copy_callback, &state)) goto cleanup; if (hashtab_map(state.base->p_cats.table, cats_copy_callback, &state)) goto cleanup; if (policydb_index_others(handle, out, verbose)) { ERR(handle, "Error while indexing out symbols"); goto cleanup; } /* copy users */ if (hashtab_map(state.base->p_users.table, user_copy_callback, &state)) goto cleanup; if (hashtab_map(state.base->p_users.table, user_bounds_copy_callback, &state)) goto cleanup; /* copy bools */ if (hashtab_map(state.base->p_bools.table, bool_copy_callback, &state)) goto cleanup; if (policydb_index_classes(out)) { ERR(handle, "Error while indexing out classes"); goto cleanup; } if (policydb_index_others(handle, out, verbose)) { ERR(handle, "Error while indexing out symbols"); goto cleanup; } /* loop through all decls and union attributes, roles, users */ for (curblock = state.base->global; curblock != NULL; curblock = curblock->next) { avrule_decl_t *decl = curblock->enabled; if (decl == NULL) { /* nothing was enabled within this block */ continue; } /* convert attribute type sets */ if (hashtab_map (decl->p_types.table, attr_convert_callback, &state)) { goto cleanup; } /* copy roles */ if (hashtab_map (decl->p_roles.table, role_copy_callback, &state)) goto cleanup; /* copy users */ if (hashtab_map (decl->p_users.table, user_copy_callback, &state)) goto cleanup; } /* remap role dominates bitmaps */ if (hashtab_map(state.out->p_roles.table, role_remap_dominates, &state)) { goto cleanup; } if (copy_and_expand_avrule_block(&state) < 0) { ERR(handle, "Error during expand"); goto cleanup; } /* copy constraints */ if (hashtab_map (state.base->p_classes.table, constraint_copy_callback, &state)) { goto cleanup; } cond_optimize_lists(state.out->cond_list); if (evaluate_conds(state.out)) goto cleanup; /* copy ocontexts */ if (ocontext_copy(&state, out->target_platform)) goto cleanup; /* copy genfs */ if (genfs_copy(&state)) goto cleanup; /* Build the type<->attribute maps and remove attributes. */ state.out->attr_type_map = malloc(state.out->p_types.nprim * sizeof(ebitmap_t)); state.out->type_attr_map = malloc(state.out->p_types.nprim * sizeof(ebitmap_t)); if (!state.out->attr_type_map || !state.out->type_attr_map) { ERR(handle, "Out of memory!"); goto cleanup; } for (i = 0; i < state.out->p_types.nprim; i++) { ebitmap_init(&state.out->type_attr_map[i]); ebitmap_init(&state.out->attr_type_map[i]); /* add the type itself as the degenerate case */ if (ebitmap_set_bit(&state.out->type_attr_map[i], i, 1)) { ERR(handle, "Out of memory!"); goto cleanup; } } if (hashtab_map(state.out->p_types.table, type_attr_map, &state)) goto cleanup; if (check) { if (hierarchy_check_constraints(handle, state.out)) goto cleanup; if (check_assertions (handle, state.out, state.out->global->branch_list->avrules)) goto cleanup; } retval = 0; cleanup: free(state.typemap); free(state.boolmap); free(state.rolemap); free(state.usermap); return retval; } static int expand_avtab_insert(avtab_t * a, avtab_key_t * k, avtab_datum_t * d) { avtab_ptr_t node; avtab_datum_t *avd; avtab_extended_perms_t *xperms; unsigned int i; unsigned int match = 0; if (k->specified & AVTAB_XPERMS) { /* * AVTAB_XPERMS entries are not necessarily unique. * find node with matching xperms */ node = avtab_search_node(a, k); while (node) { if ((node->datum.xperms->specified == d->xperms->specified) && (node->datum.xperms->driver == d->xperms->driver)) { match = 1; break; } node = avtab_search_node_next(node, k->specified); } if (!match) node = NULL; } else { node = avtab_search_node(a, k); } if (!node || ((k->specified & AVTAB_ENABLED) != (node->key.specified & AVTAB_ENABLED))) { node = avtab_insert_nonunique(a, k, d); if (!node) { ERR(NULL, "Out of memory!"); return -1; } return 0; } avd = &node->datum; xperms = node->datum.xperms; switch (k->specified & ~AVTAB_ENABLED) { case AVTAB_ALLOWED: case AVTAB_AUDITALLOW: avd->data |= d->data; break; case AVTAB_AUDITDENY: avd->data &= d->data; break; case AVTAB_XPERMS_ALLOWED: case AVTAB_XPERMS_AUDITALLOW: case AVTAB_XPERMS_DONTAUDIT: for (i = 0; i < ARRAY_SIZE(xperms->perms); i++) xperms->perms[i] |= d->xperms->perms[i]; break; default: ERR(NULL, "Type conflict!"); return -1; } return 0; } struct expand_avtab_data { avtab_t *expa; policydb_t *p; }; static int expand_avtab_node(avtab_key_t * k, avtab_datum_t * d, void *args) { struct expand_avtab_data *ptr = args; avtab_t *expa = ptr->expa; policydb_t *p = ptr->p; type_datum_t *stype = p->type_val_to_struct[k->source_type - 1]; type_datum_t *ttype = p->type_val_to_struct[k->target_type - 1]; ebitmap_t *sattr = &p->attr_type_map[k->source_type - 1]; ebitmap_t *tattr = &p->attr_type_map[k->target_type - 1]; ebitmap_node_t *snode, *tnode; unsigned int i, j; avtab_key_t newkey; int rc; newkey.target_class = k->target_class; newkey.specified = k->specified; if (stype && ttype && stype->flavor != TYPE_ATTRIB && ttype->flavor != TYPE_ATTRIB) { /* Both are individual types, no expansion required. */ return expand_avtab_insert(expa, k, d); } if (stype && stype->flavor != TYPE_ATTRIB) { /* Source is an individual type, target is an attribute. */ newkey.source_type = k->source_type; ebitmap_for_each_bit(tattr, tnode, j) { if (!ebitmap_node_get_bit(tnode, j)) continue; newkey.target_type = j + 1; rc = expand_avtab_insert(expa, &newkey, d); if (rc) return -1; } return 0; } if (ttype && ttype->flavor != TYPE_ATTRIB) { /* Target is an individual type, source is an attribute. */ newkey.target_type = k->target_type; ebitmap_for_each_bit(sattr, snode, i) { if (!ebitmap_node_get_bit(snode, i)) continue; newkey.source_type = i + 1; rc = expand_avtab_insert(expa, &newkey, d); if (rc) return -1; } return 0; } /* Both source and target type are attributes. */ ebitmap_for_each_bit(sattr, snode, i) { if (!ebitmap_node_get_bit(snode, i)) continue; ebitmap_for_each_bit(tattr, tnode, j) { if (!ebitmap_node_get_bit(tnode, j)) continue; newkey.source_type = i + 1; newkey.target_type = j + 1; rc = expand_avtab_insert(expa, &newkey, d); if (rc) return -1; } } return 0; } int expand_avtab(policydb_t * p, avtab_t * a, avtab_t * expa) { struct expand_avtab_data data; if (avtab_alloc(expa, MAX_AVTAB_SIZE)) { ERR(NULL, "Out of memory!"); return -1; } data.expa = expa; data.p = p; return avtab_map(a, expand_avtab_node, &data); } static int expand_cond_insert(cond_av_list_t ** l, avtab_t * expa, avtab_key_t * k, avtab_datum_t * d) { avtab_ptr_t node; avtab_datum_t *avd; cond_av_list_t *nl; node = avtab_search_node(expa, k); if (!node || (k->specified & AVTAB_ENABLED) != (node->key.specified & AVTAB_ENABLED)) { node = avtab_insert_nonunique(expa, k, d); if (!node) { ERR(NULL, "Out of memory!"); return -1; } node->parse_context = (void *)1; nl = (cond_av_list_t *) malloc(sizeof(*nl)); if (!nl) { ERR(NULL, "Out of memory!"); return -1; } memset(nl, 0, sizeof(*nl)); nl->node = node; nl->next = *l; *l = nl; return 0; } avd = &node->datum; switch (k->specified & ~AVTAB_ENABLED) { case AVTAB_ALLOWED: case AVTAB_AUDITALLOW: avd->data |= d->data; break; case AVTAB_AUDITDENY: avd->data &= d->data; break; default: ERR(NULL, "Type conflict!"); return -1; } return 0; } int expand_cond_av_node(policydb_t * p, avtab_ptr_t node, cond_av_list_t ** newl, avtab_t * expa) { avtab_key_t *k = &node->key; avtab_datum_t *d = &node->datum; type_datum_t *stype = p->type_val_to_struct[k->source_type - 1]; type_datum_t *ttype = p->type_val_to_struct[k->target_type - 1]; ebitmap_t *sattr = &p->attr_type_map[k->source_type - 1]; ebitmap_t *tattr = &p->attr_type_map[k->target_type - 1]; ebitmap_node_t *snode, *tnode; unsigned int i, j; avtab_key_t newkey; int rc; newkey.target_class = k->target_class; newkey.specified = k->specified; if (stype && ttype && stype->flavor != TYPE_ATTRIB && ttype->flavor != TYPE_ATTRIB) { /* Both are individual types, no expansion required. */ return expand_cond_insert(newl, expa, k, d); } if (stype && stype->flavor != TYPE_ATTRIB) { /* Source is an individual type, target is an attribute. */ newkey.source_type = k->source_type; ebitmap_for_each_bit(tattr, tnode, j) { if (!ebitmap_node_get_bit(tnode, j)) continue; newkey.target_type = j + 1; rc = expand_cond_insert(newl, expa, &newkey, d); if (rc) return -1; } return 0; } if (ttype && ttype->flavor != TYPE_ATTRIB) { /* Target is an individual type, source is an attribute. */ newkey.target_type = k->target_type; ebitmap_for_each_bit(sattr, snode, i) { if (!ebitmap_node_get_bit(snode, i)) continue; newkey.source_type = i + 1; rc = expand_cond_insert(newl, expa, &newkey, d); if (rc) return -1; } return 0; } /* Both source and target type are attributes. */ ebitmap_for_each_bit(sattr, snode, i) { if (!ebitmap_node_get_bit(snode, i)) continue; ebitmap_for_each_bit(tattr, tnode, j) { if (!ebitmap_node_get_bit(tnode, j)) continue; newkey.source_type = i + 1; newkey.target_type = j + 1; rc = expand_cond_insert(newl, expa, &newkey, d); if (rc) return -1; } } return 0; } int expand_cond_av_list(policydb_t * p, cond_av_list_t * l, cond_av_list_t ** newl, avtab_t * expa) { cond_av_list_t *cur; avtab_ptr_t node; int rc; if (avtab_alloc(expa, MAX_AVTAB_SIZE)) { ERR(NULL, "Out of memory!"); return -1; } *newl = NULL; for (cur = l; cur; cur = cur->next) { node = cur->node; rc = expand_cond_av_node(p, node, newl, expa); if (rc) return rc; } return 0; }