/** * @file schema_compile_amend.c * @author Radek Krejci * @author Michal Vasko * @brief Schema compilation of augments, deviations, and refines. * * Copyright (c) 2015 - 2024 CESNET, z.s.p.o. * * This source code is licensed under BSD 3-Clause License (the "License"). * You may not use this file except in compliance with the License. * You may obtain a copy of the License at * * https://opensource.org/licenses/BSD-3-Clause */ #define _GNU_SOURCE #include "schema_compile_amend.h" #include #include #include #include #include #include "dict.h" #include "log.h" #include "ly_common.h" #include "schema_compile.h" #include "schema_compile_node.h" #include "schema_features.h" #include "set.h" #include "tree.h" #include "tree_data_internal.h" #include "tree_edit.h" #include "tree_schema.h" #include "tree_schema_internal.h" #include "xpath.h" /** * @brief Free a nodeid structure. * * @param[in] ctx Context to use. * @param[in] nodeid Nodeid to free. */ static void lysc_nodeid_free(const struct ly_ctx *ctx, struct lysc_nodeid *nodeid) { uint32_t i; if (!nodeid) { return; } for (i = 0; i < nodeid->count; ++i) { lydict_remove(ctx, nodeid->prefix[i]); lydict_remove(ctx, nodeid->name[i]); } free(nodeid->prefix); free(nodeid->name); free(nodeid); } /** * @brief Compile a schema-node-id into a temporary array of prefixes and node names. * * @param[in] ctx Context to use. * @param[in] str Schema-node-id to compile. * @param[out] nodeid Compiled nodeid. * @return LY_ERR value. */ static LY_ERR lys_precompile_nodeid(const struct ly_ctx *ctx, const char *str, struct lysc_nodeid **nodeid) { LY_ERR rc = LY_SUCCESS; struct lyxp_expr *exp = NULL; void *mem; const char *ptr, *name; size_t len; uint32_t i; *nodeid = NULL; /* parse */ rc = lyxp_expr_parse(ctx, str, strlen(str), 0, &exp); LY_CHECK_GOTO(rc, cleanup); /* alloc */ *nodeid = calloc(1, sizeof **nodeid); LY_CHECK_ERR_GOTO(!*nodeid, LOGMEM(ctx); rc = LY_EMEM, cleanup); /* store the full schema-node-id */ (*nodeid)->str = str; /* absolute vs. relative path */ i = 0; if (exp->tokens[0] == LYXP_TOKEN_NAMETEST) { goto relative_path; } while (i < exp->used) { /* skip '/' */ assert(exp->tokens[i] == LYXP_TOKEN_OPER_PATH); ++i; relative_path: /* new node */ mem = realloc((*nodeid)->prefix, ((*nodeid)->count + 1) * sizeof *(*nodeid)->prefix); LY_CHECK_ERR_GOTO(!mem, LOGMEM(ctx); rc = LY_EMEM, cleanup); (*nodeid)->prefix = mem; (*nodeid)->prefix[(*nodeid)->count] = NULL; mem = realloc((*nodeid)->name, ((*nodeid)->count + 1) * sizeof *(*nodeid)->name); LY_CHECK_ERR_GOTO(!mem, LOGMEM(ctx); rc = LY_EMEM, cleanup); (*nodeid)->name = mem; (*nodeid)->name[(*nodeid)->count] = NULL; ++(*nodeid)->count; /* compile the name test */ assert(exp->tokens[i] == LYXP_TOKEN_NAMETEST); name = str + exp->tok_pos[i]; len = exp->tok_len[i]; ptr = ly_strnchr(name, ':', len); if (ptr) { /* store prefix */ rc = lydict_insert(ctx, name, ptr - name, &(*nodeid)->prefix[(*nodeid)->count - 1]); LY_CHECK_GOTO(rc, cleanup); /* move name */ len -= (ptr - name) + 1; name = ptr + 1; } /* store name */ rc = lydict_insert(ctx, name, len, &(*nodeid)->name[(*nodeid)->count - 1]); LY_CHECK_GOTO(rc, cleanup); ++i; } cleanup: lyxp_expr_free(ctx, exp); if (rc) { lysc_nodeid_free(ctx, *nodeid); *nodeid = NULL; } return rc; } /** * @brief Get module of a single nodeid node name test. * * @param[in] ctx libyang context. * @param[in] prefix_dict Optional prefix of the node test, in the dictionary. * @param[in] pmod Both current and prefix module for resolving prefixes and to return in case of no prefix. * @return Resolved module. */ static const struct lys_module * lys_schema_node_get_module(const struct ly_ctx *ctx, const char *prefix_dict, const struct lysp_module *pmod) { const char *local_prefix; LY_ARRAY_COUNT_TYPE u; if (!prefix_dict) { /* local module */ return pmod->mod; } local_prefix = pmod->is_submod ? ((struct lysp_submodule *)pmod)->prefix : pmod->mod->prefix; if (local_prefix == prefix_dict) { /* local module prefix */ return pmod->mod; } LY_ARRAY_FOR(pmod->imports, u) { if (pmod->imports[u].prefix == prefix_dict) { /* import module prefix */ return pmod->imports[u].module; } } /* prefix module not found */ LOGVAL(ctx, LYVE_REFERENCE, "Invalid absolute-schema-nodeid nametest - prefix \"%s\" not defined in module \"%s\".", prefix_dict, LYSP_MODULE_NAME(pmod)); return NULL; } /** * @brief Check the syntax of a node-id and collect all the referenced modules. * * @param[in] ctx Compile context. * @param[in] str Node-id to check. * @param[in] abs Whether @p str must be absolute or relative. * @param[in,out] mod_set Set to add referenced modules into. * @param[out] nodeid Optional compiled node-id. * @param[out] target_mod Optional target module of the node-id. * @return LY_ERR value. */ static LY_ERR lys_nodeid_mod_check(struct lysc_ctx *ctx, const char *str, ly_bool abs, struct ly_set *mod_set, struct lysc_nodeid **nodeid, struct lys_module **target_mod) { LY_ERR ret = LY_SUCCESS; struct lyxp_expr *e = NULL; struct lysc_nodeid *ni = NULL; struct lys_module *tmod = NULL, *mod; const char *nodeid_type = abs ? "absolute-schema-nodeid" : "descendant-schema-nodeid"; uint32_t i; /* parse */ ret = lyxp_expr_parse(ctx->ctx, str, strlen(str), 0, &e); if (ret) { LOGVAL(ctx->ctx, LYVE_SYNTAX_YANG, "Invalid %s value \"%s\" - invalid syntax.", nodeid_type, str); ret = LY_EVALID; goto cleanup; } if (abs) { /* absolute schema nodeid */ i = 0; } else { /* descendant schema nodeid */ if (e->tokens[0] != LYXP_TOKEN_NAMETEST) { LOGVAL(ctx->ctx, LYVE_REFERENCE, "Invalid %s value \"%s\" - name test expected instead of \"%.*s\".", nodeid_type, str, (int)e->tok_len[0], e->expr + e->tok_pos[0]); ret = LY_EVALID; goto cleanup; } i = 1; } /* check all the tokens */ for ( ; i < e->used; i += 2) { if (e->tokens[i] != LYXP_TOKEN_OPER_PATH) { LOGVAL(ctx->ctx, LYVE_REFERENCE, "Invalid %s value \"%s\" - \"/\" expected instead of \"%.*s\".", nodeid_type, str, (int)e->tok_len[i], e->expr + e->tok_pos[i]); ret = LY_EVALID; goto cleanup; } else if (e->used == i + 1) { LOGVAL(ctx->ctx, LYVE_REFERENCE, "Invalid %s value \"%s\" - unexpected end of expression.", nodeid_type, e->expr); ret = LY_EVALID; goto cleanup; } else if (e->tokens[i + 1] != LYXP_TOKEN_NAMETEST) { LOGVAL(ctx->ctx, LYVE_REFERENCE, "Invalid %s value \"%s\" - name test expected instead of \"%.*s\".", nodeid_type, str, (int)e->tok_len[i + 1], e->expr + e->tok_pos[i + 1]); ret = LY_EVALID; goto cleanup; } } if (abs || nodeid) { /* compile into nodeid, only if needed */ LY_CHECK_GOTO(ret = lys_precompile_nodeid(ctx->ctx, str, &ni), cleanup); } if (abs) { for (i = 0; i < ni->count; ++i) { mod = (struct lys_module *)lys_schema_node_get_module(ctx->ctx, ni->prefix[i], ctx->pmod); LY_CHECK_ERR_GOTO(!mod, ret = LY_EVALID, cleanup); /* only keep the first module */ if (!tmod) { tmod = mod; } /* store the referenced module */ LY_CHECK_GOTO(ret = ly_set_add(mod_set, mod, 0, NULL), cleanup); } } if (nodeid) { *nodeid = ni; ni = NULL; } if (target_mod) { *target_mod = tmod; } cleanup: lyxp_expr_free(ctx->ctx, e); lysc_nodeid_free(ctx->ctx, ni); return ret; } /** * @brief Check whether 2 schema nodeids match. * * @param[in] ctx libyang context. * @param[in] nodeid1 First schema nodeid. * @param[in] nodeid1_pmod Module of @p nodeid1 nodes without any prefix. * @param[in] nodeid2 Second schema nodeid. * @param[in] nodeid2_pmod Module of @p nodeid2 nodes without any prefix. * @return Whether the schema nodeids match or not. */ static ly_bool lys_abs_schema_nodeid_match(const struct ly_ctx *ctx, const struct lysc_nodeid *nodeid1, const struct lysp_module *nodeid1_pmod, const struct lysc_nodeid *nodeid2, const struct lysp_module *nodeid2_pmod) { uint32_t i; const struct lys_module *mod1, *mod2; if (nodeid1->count != nodeid2->count) { return 0; } for (i = 0; i < nodeid1->count; ++i) { /* check modules of all the nodes in the node ID */ mod1 = lys_schema_node_get_module(ctx, nodeid1->prefix[i], nodeid1_pmod); assert(mod1); mod2 = lys_schema_node_get_module(ctx, nodeid2->prefix[i], nodeid2_pmod); assert(mod2); /* compare modules */ if (mod1 != mod2) { return 0; } /* compare names, both in the dictionary */ if (nodeid1->name[i] != nodeid2->name[i]) { return 0; } } return 1; } LY_ERR lys_precompile_uses_augments_refines(struct lysc_ctx *ctx, struct lysp_node_uses *uses_p, const struct lysc_node *ctx_node) { LY_ERR ret = LY_SUCCESS; struct lysc_nodeid *nodeid = NULL; struct lysc_augment *aug; struct lysp_node_augment *aug_p; struct lysc_refine *rfn; struct lysp_refine **new_rfn; LY_ARRAY_COUNT_TYPE u; uint32_t i; struct ly_set mod_set = {0}; LY_LIST_FOR(uses_p->augments, aug_p) { lysc_update_path(ctx, NULL, "{augment}"); lysc_update_path(ctx, NULL, aug_p->nodeid); /* parse the nodeid */ LY_CHECK_GOTO(ret = lys_nodeid_mod_check(ctx, aug_p->nodeid, 0, &mod_set, &nodeid, NULL), cleanup); /* allocate new compiled augment and store it in the set */ aug = calloc(1, sizeof *aug); LY_CHECK_ERR_GOTO(!aug, LOGMEM(ctx->ctx); ret = LY_EMEM, cleanup); LY_CHECK_GOTO(ret = ly_set_add(&ctx->uses_augs, aug, 1, NULL), cleanup); aug->nodeid = nodeid; nodeid = NULL; aug->aug_pmod = ctx->pmod; aug->nodeid_ctx_node = ctx_node; aug->aug_p = aug_p; lysc_update_path(ctx, NULL, NULL); lysc_update_path(ctx, NULL, NULL); } LY_ARRAY_FOR(uses_p->refines, u) { lysc_update_path(ctx, NULL, "{refine}"); lysc_update_path(ctx, NULL, uses_p->refines[u].nodeid); /* parse the nodeid */ LY_CHECK_GOTO(ret = lys_nodeid_mod_check(ctx, uses_p->refines[u].nodeid, 0, &mod_set, &nodeid, NULL), cleanup); /* try to find the node in already compiled refines */ rfn = NULL; for (i = 0; i < ctx->uses_rfns.count; ++i) { if (lys_abs_schema_nodeid_match(ctx->ctx, nodeid, ctx->pmod, ((struct lysc_refine *)ctx->uses_rfns.objs[i])->nodeid, ctx->pmod)) { rfn = ctx->uses_rfns.objs[i]; break; } } if (!rfn) { /* allocate new compiled refine */ rfn = calloc(1, sizeof *rfn); LY_CHECK_ERR_GOTO(!rfn, LOGMEM(ctx->ctx); ret = LY_EMEM, cleanup); LY_CHECK_GOTO(ret = ly_set_add(&ctx->uses_rfns, rfn, 1, NULL), cleanup); rfn->nodeid = nodeid; nodeid = NULL; rfn->nodeid_pmod = ctx->cur_mod->parsed; rfn->nodeid_ctx_node = ctx_node; rfn->uses_p = uses_p; } else { /* just free nodeid */ lysc_nodeid_free(ctx->ctx, nodeid); nodeid = NULL; } /* add new parsed refine structure */ LY_ARRAY_NEW_GOTO(ctx->ctx, rfn->rfns, new_rfn, ret, cleanup); *new_rfn = &uses_p->refines[u]; lysc_update_path(ctx, NULL, NULL); lysc_update_path(ctx, NULL, NULL); } cleanup: if (ret) { lysc_update_path(ctx, NULL, NULL); lysc_update_path(ctx, NULL, NULL); } /* should include only this module, will fail later if not */ ly_set_erase(&mod_set, NULL); lysc_nodeid_free(ctx->ctx, nodeid); return ret; } /** * @brief Duplicate parsed extension children, recursively. * * @param[in] ctx Context. * @param[in] orig_child First original child to duplicate. * @param[in,out] child Duplicated children to add to. * @return LY_ERR value. */ static LY_ERR lysp_ext_children_dup(const struct ly_ctx *ctx, const struct lysp_stmt *orig_child, struct lysp_stmt **child) { struct lysp_stmt *ch = NULL; assert(!*child); LY_LIST_FOR(orig_child, orig_child) { /* new child */ if (!*child) { *child = ch = calloc(1, sizeof *ch); LY_CHECK_ERR_RET(!ch, LOGMEM(ctx), LY_EMEM); } else { ch->next = calloc(1, sizeof *ch); LY_CHECK_ERR_RET(!ch->next, LOGMEM(ctx), LY_EMEM); ch = ch->next; } /* fill */ DUP_STRING_RET(ctx, orig_child->stmt, ch->stmt); ch->flags = orig_child->flags; DUP_STRING_RET(ctx, orig_child->arg, ch->arg); ch->format = orig_child->format; LY_CHECK_RET(ly_dup_prefix_data(ctx, orig_child->format, orig_child->prefix_data, &(ch->prefix_data))); ch->kw = orig_child->kw; /* recursive children */ LY_CHECK_RET(lysp_ext_children_dup(ctx, orig_child->child, &ch->child)); } return LY_SUCCESS; } /** * @brief Duplicate parsed extension instance. * * @param[in] ctx Context. * @param[in] pmod Current parsed module. * @param[in] parent Parent of the duplicated ext instance. * @param[in] parent_stmt Parent statement of the duplicated ext instance (should be @p parent). * @param[out] ext Duplicated ext instance to fill. * @return LY_ERR value. */ static LY_ERR lysp_ext_dup(const struct ly_ctx *ctx, const struct lysp_module *pmod, void *parent, enum ly_stmt parent_stmt, const struct lysp_ext_instance *orig_ext, struct lysp_ext_instance *ext) { LY_ERR ret = LY_SUCCESS; struct ly_set pmods = {0}; struct lysp_ctx pctx = {.parsed_mods = &pmods}; DUP_STRING_GOTO(ctx, orig_ext->name, ext->name, ret, cleanup); DUP_STRING_GOTO(ctx, orig_ext->argument, ext->argument, ret, cleanup); ext->format = orig_ext->format; LY_CHECK_GOTO(ret = ly_dup_prefix_data(ctx, orig_ext->format, orig_ext->prefix_data, &ext->prefix_data), cleanup); ext->def = orig_ext->def; ext->parent = parent; ext->parent_stmt = parent_stmt; ext->parent_stmt_index = orig_ext->parent_stmt_index; ext->flags = orig_ext->flags; ext->record = orig_ext->record; LY_CHECK_GOTO(ret = lysp_ext_children_dup(ctx, orig_ext->child, &ext->child), cleanup); if (ext->record && ext->record->plugin.parse) { /* parse again */ LY_CHECK_GOTO(ret = ly_set_add(&pmods, pmod, 1, NULL), cleanup); LY_CHECK_GOTO(ret = ext->record->plugin.parse(&pctx, ext), cleanup); } cleanup: ly_set_erase(&pmods, NULL); return ret; } static LY_ERR lysp_restr_dup(const struct ly_ctx *ctx, const struct lysp_module *pmod, const struct lysp_restr *orig_restr, struct lysp_restr *restr) { LY_ERR ret = LY_SUCCESS; if (orig_restr) { DUP_STRING(ctx, orig_restr->arg.str, restr->arg.str, ret); restr->arg.mod = orig_restr->arg.mod; DUP_STRING(ctx, orig_restr->emsg, restr->emsg, ret); DUP_STRING(ctx, orig_restr->eapptag, restr->eapptag, ret); DUP_STRING(ctx, orig_restr->dsc, restr->dsc, ret); DUP_STRING(ctx, orig_restr->ref, restr->ref, ret); DUP_EXTS(ctx, pmod, restr, LY_STMT_MUST, orig_restr->exts, restr->exts, lysp_ext_dup); } return ret; } static LY_ERR lysp_string_dup(const struct ly_ctx *ctx, const char **orig_str, const char **str) { LY_ERR ret = LY_SUCCESS; DUP_STRING(ctx, *orig_str, *str, ret); return ret; } LY_ERR lysp_qname_dup(const struct ly_ctx *ctx, const struct lysp_qname *orig_qname, struct lysp_qname *qname) { LY_ERR ret = LY_SUCCESS; if (!orig_qname->str) { return LY_SUCCESS; } DUP_STRING(ctx, orig_qname->str, qname->str, ret); assert(orig_qname->mod); qname->mod = orig_qname->mod; return ret; } static LY_ERR lysp_type_enum_dup(const struct ly_ctx *ctx, const struct lysp_module *pmod, const struct lysp_type_enum *orig_enm, struct lysp_type_enum *enm) { LY_ERR ret = LY_SUCCESS; DUP_STRING(ctx, orig_enm->name, enm->name, ret); DUP_STRING(ctx, orig_enm->dsc, enm->dsc, ret); DUP_STRING(ctx, orig_enm->ref, enm->ref, ret); enm->value = orig_enm->value; DUP_ARRAY(ctx, orig_enm->iffeatures, enm->iffeatures, lysp_qname_dup); DUP_EXTS(ctx, pmod, enm, LY_STMT_ENUM, orig_enm->exts, enm->exts, lysp_ext_dup); enm->flags = orig_enm->flags; return ret; } static LY_ERR lysp_type_dup(const struct ly_ctx *ctx, const struct lysp_module *pmod, const struct lysp_type *orig_type, struct lysp_type *type) { LY_ERR ret = LY_SUCCESS; /* array macros read previous data so we must zero it */ memset(type, 0, sizeof *type); DUP_STRING_GOTO(ctx, orig_type->name, type->name, ret, done); if (orig_type->range) { type->range = calloc(1, sizeof *type->range); LY_CHECK_ERR_RET(!type->range, LOGMEM(ctx), LY_EMEM); LY_CHECK_RET(lysp_restr_dup(ctx, pmod, orig_type->range, type->range)); } if (orig_type->length) { type->length = calloc(1, sizeof *type->length); LY_CHECK_ERR_RET(!type->length, LOGMEM(ctx), LY_EMEM); LY_CHECK_RET(lysp_restr_dup(ctx, pmod, orig_type->length, type->length)); } DUP_ARRAY2(ctx, pmod, orig_type->patterns, type->patterns, lysp_restr_dup); DUP_ARRAY2(ctx, pmod, orig_type->enums, type->enums, lysp_type_enum_dup); DUP_ARRAY2(ctx, pmod, orig_type->bits, type->bits, lysp_type_enum_dup); LY_CHECK_GOTO(ret = lyxp_expr_dup(ctx, orig_type->path, 0, 0, &type->path), done); DUP_ARRAY(ctx, orig_type->bases, type->bases, lysp_string_dup); DUP_ARRAY2(ctx, pmod, orig_type->types, type->types, lysp_type_dup); DUP_EXTS(ctx, pmod, type, LY_STMT_TYPE, orig_type->exts, type->exts, lysp_ext_dup); type->pmod = orig_type->pmod; type->compiled = orig_type->compiled; type->fraction_digits = orig_type->fraction_digits; type->require_instance = orig_type->require_instance; type->flags = orig_type->flags; done: return ret; } static LY_ERR lysp_when_dup(const struct ly_ctx *ctx, const struct lysp_module *pmod, struct lysp_when *when, const struct lysp_when *orig_when) { LY_ERR ret = LY_SUCCESS; DUP_STRING(ctx, orig_when->cond, when->cond, ret); DUP_STRING(ctx, orig_when->dsc, when->dsc, ret); DUP_STRING(ctx, orig_when->ref, when->ref, ret); DUP_EXTS(ctx, pmod, when, LY_STMT_WHEN, orig_when->exts, when->exts, lysp_ext_dup); return ret; } static LY_ERR lysp_node_common_dup(const struct ly_ctx *ctx, const struct lysp_module *pmod, struct lysp_node *node, const struct lysp_node *orig) { LY_ERR ret = LY_SUCCESS; node->parent = NULL; node->nodetype = orig->nodetype; node->flags = orig->flags; node->next = NULL; DUP_STRING(ctx, orig->name, node->name, ret); DUP_STRING(ctx, orig->dsc, node->dsc, ret); DUP_STRING(ctx, orig->ref, node->ref, ret); DUP_ARRAY(ctx, orig->iffeatures, node->iffeatures, lysp_qname_dup); DUP_EXTS(ctx, pmod, node, lyplg_ext_nodetype2stmt(node->nodetype), orig->exts, node->exts, lysp_ext_dup); return ret; } #define DUP_PWHEN(CTX, PMOD, ORIG, NEW) \ if (ORIG) { \ NEW = calloc(1, sizeof *NEW); \ LY_CHECK_ERR_RET(!NEW, LOGMEM(CTX), LY_EMEM); \ LY_CHECK_RET(lysp_when_dup(CTX, PMOD, NEW, ORIG)); \ } static LY_ERR lysp_node_dup(const struct ly_ctx *ctx, const struct lysp_module *pmod, struct lysp_node *node, const struct lysp_node *orig) { LY_ERR ret = LY_SUCCESS; struct lysp_node_container *cont; const struct lysp_node_container *orig_cont; struct lysp_node_leaf *leaf; const struct lysp_node_leaf *orig_leaf; struct lysp_node_leaflist *llist; const struct lysp_node_leaflist *orig_llist; struct lysp_node_list *list; const struct lysp_node_list *orig_list; struct lysp_node_choice *choice; const struct lysp_node_choice *orig_choice; struct lysp_node_case *cas; const struct lysp_node_case *orig_cas; struct lysp_node_anydata *any; const struct lysp_node_anydata *orig_any; struct lysp_node_action *action; const struct lysp_node_action *orig_action; struct lysp_node_action_inout *action_inout; const struct lysp_node_action_inout *orig_action_inout; struct lysp_node_notif *notif; const struct lysp_node_notif *orig_notif; assert(orig->nodetype & (LYS_CONTAINER | LYS_LEAF | LYS_LEAFLIST | LYS_LIST | LYS_CHOICE | LYS_CASE | LYS_ANYDATA | LYS_RPC | LYS_ACTION | LYS_NOTIF)); /* common part */ LY_CHECK_RET(lysp_node_common_dup(ctx, pmod, node, orig)); /* specific part */ switch (node->nodetype) { case LYS_CONTAINER: cont = (struct lysp_node_container *)node; orig_cont = (const struct lysp_node_container *)orig; DUP_PWHEN(ctx, pmod, orig_cont->when, cont->when); DUP_ARRAY2(ctx, pmod, orig_cont->musts, cont->musts, lysp_restr_dup); DUP_STRING(ctx, orig_cont->presence, cont->presence, ret); /* we do not need the rest */ break; case LYS_LEAF: leaf = (struct lysp_node_leaf *)node; orig_leaf = (const struct lysp_node_leaf *)orig; DUP_PWHEN(ctx, pmod, orig_leaf->when, leaf->when); DUP_ARRAY2(ctx, pmod, orig_leaf->musts, leaf->musts, lysp_restr_dup); LY_CHECK_RET(lysp_type_dup(ctx, pmod, &orig_leaf->type, &leaf->type)); DUP_STRING(ctx, orig_leaf->units, leaf->units, ret); LY_CHECK_RET(lysp_qname_dup(ctx, &orig_leaf->dflt, &leaf->dflt)); break; case LYS_LEAFLIST: llist = (struct lysp_node_leaflist *)node; orig_llist = (const struct lysp_node_leaflist *)orig; DUP_PWHEN(ctx, pmod, orig_llist->when, llist->when); DUP_ARRAY2(ctx, pmod, orig_llist->musts, llist->musts, lysp_restr_dup); LY_CHECK_RET(lysp_type_dup(ctx, pmod, &orig_llist->type, &llist->type)); DUP_STRING(ctx, orig_llist->units, llist->units, ret); DUP_ARRAY(ctx, orig_llist->dflts, llist->dflts, lysp_qname_dup); llist->min = orig_llist->min; llist->max = orig_llist->max; break; case LYS_LIST: list = (struct lysp_node_list *)node; orig_list = (const struct lysp_node_list *)orig; DUP_PWHEN(ctx, pmod, orig_list->when, list->when); DUP_ARRAY2(ctx, pmod, orig_list->musts, list->musts, lysp_restr_dup); DUP_STRING(ctx, orig_list->key, list->key, ret); /* we do not need these arrays */ DUP_ARRAY(ctx, orig_list->uniques, list->uniques, lysp_qname_dup); list->min = orig_list->min; list->max = orig_list->max; break; case LYS_CHOICE: choice = (struct lysp_node_choice *)node; orig_choice = (const struct lysp_node_choice *)orig; DUP_PWHEN(ctx, pmod, orig_choice->when, choice->when); /* we do not need children */ LY_CHECK_RET(lysp_qname_dup(ctx, &orig_choice->dflt, &choice->dflt)); break; case LYS_CASE: cas = (struct lysp_node_case *)node; orig_cas = (const struct lysp_node_case *)orig; DUP_PWHEN(ctx, pmod, orig_cas->when, cas->when); /* we do not need children */ break; case LYS_ANYDATA: case LYS_ANYXML: any = (struct lysp_node_anydata *)node; orig_any = (const struct lysp_node_anydata *)orig; DUP_PWHEN(ctx, pmod, orig_any->when, any->when); DUP_ARRAY2(ctx, pmod, orig_any->musts, any->musts, lysp_restr_dup); break; case LYS_RPC: case LYS_ACTION: action = (struct lysp_node_action *)node; orig_action = (const struct lysp_node_action *)orig; action->input.nodetype = orig_action->input.nodetype; action->output.nodetype = orig_action->output.nodetype; /* we do not need the rest */ break; case LYS_INPUT: case LYS_OUTPUT: action_inout = (struct lysp_node_action_inout *)node; orig_action_inout = (const struct lysp_node_action_inout *)orig; DUP_ARRAY2(ctx, pmod, orig_action_inout->musts, action_inout->musts, lysp_restr_dup); /* we do not need the rest */ break; case LYS_NOTIF: notif = (struct lysp_node_notif *)node; orig_notif = (const struct lysp_node_notif *)orig; DUP_ARRAY2(ctx, pmod, orig_notif->musts, notif->musts, lysp_restr_dup); /* we do not need the rest */ break; default: LOGINT_RET(ctx); } return ret; } /** * @brief Duplicate a single parsed node. Only attributes that are used in compilation are copied. * * @param[in] ctx libyang context. * @param[in] pmod Current parsed module. * @param[in] pnode Node to duplicate. * @param[in] with_links Whether to also copy any links (child, parent pointers). * @param[out] dup_p Duplicated parsed node. * @return LY_ERR value. */ static LY_ERR lysp_dup_single(struct lysc_ctx *cctx, const struct lysp_node *pnode, ly_bool with_links, struct lysp_node **dup_p) { LY_ERR ret = LY_SUCCESS; struct lysp_node *dup = NULL; if (!pnode) { *dup_p = NULL; return LY_SUCCESS; } switch (pnode->nodetype) { case LYS_CONTAINER: dup = calloc(1, sizeof(struct lysp_node_container)); break; case LYS_LEAF: dup = calloc(1, sizeof(struct lysp_node_leaf)); break; case LYS_LEAFLIST: dup = calloc(1, sizeof(struct lysp_node_leaflist)); break; case LYS_LIST: dup = calloc(1, sizeof(struct lysp_node_list)); break; case LYS_CHOICE: dup = calloc(1, sizeof(struct lysp_node_choice)); break; case LYS_CASE: dup = calloc(1, sizeof(struct lysp_node_case)); break; case LYS_ANYDATA: case LYS_ANYXML: dup = calloc(1, sizeof(struct lysp_node_anydata)); break; case LYS_INPUT: case LYS_OUTPUT: dup = calloc(1, sizeof(struct lysp_node_action_inout)); break; case LYS_ACTION: case LYS_RPC: dup = calloc(1, sizeof(struct lysp_node_action)); break; case LYS_NOTIF: dup = calloc(1, sizeof(struct lysp_node_notif)); break; default: LOGINT_RET(cctx->ctx); } LY_CHECK_ERR_GOTO(!dup, LOGMEM(cctx->ctx); ret = LY_EMEM, cleanup); LY_CHECK_GOTO(ret = lysp_node_dup(cctx->ctx, cctx->pmod, dup, pnode), cleanup); if (with_links) { /* copy also parent, child, action, and notification pointers */ dup->parent = pnode->parent; switch (pnode->nodetype) { case LYS_CONTAINER: ((struct lysp_node_container *)dup)->child = ((struct lysp_node_container *)pnode)->child; ((struct lysp_node_container *)dup)->actions = ((struct lysp_node_container *)pnode)->actions; ((struct lysp_node_container *)dup)->notifs = ((struct lysp_node_container *)pnode)->notifs; break; case LYS_LIST: ((struct lysp_node_list *)dup)->child = ((struct lysp_node_list *)pnode)->child; ((struct lysp_node_list *)dup)->actions = ((struct lysp_node_list *)pnode)->actions; ((struct lysp_node_list *)dup)->notifs = ((struct lysp_node_list *)pnode)->notifs; break; case LYS_CHOICE: ((struct lysp_node_choice *)dup)->child = ((struct lysp_node_choice *)pnode)->child; break; case LYS_CASE: ((struct lysp_node_case *)dup)->child = ((struct lysp_node_case *)pnode)->child; break; default: break; } } cleanup: if (ret) { lysp_dev_node_free(cctx, dup); } else { *dup_p = dup; } return ret; } #define AMEND_WRONG_NODETYPE(AMEND_STR, OP_STR, PROPERTY) \ LOGVAL(ctx->ctx, LYVE_REFERENCE, "Invalid %s of %s node - it is not possible to %s \"%s\" property.", \ AMEND_STR, lys_nodetype2str(target->nodetype), OP_STR, PROPERTY);\ ret = LY_EVALID; \ goto cleanup; #define AMEND_CHECK_CARDINALITY(ARRAY, MAX, AMEND_STR, PROPERTY) \ if (LY_ARRAY_COUNT(ARRAY) > MAX) { \ LOGVAL(ctx->ctx, LYVE_SEMANTICS, "Invalid %s of %s with too many (%"LY_PRI_ARRAY_COUNT_TYPE") %s properties.", \ AMEND_STR, lys_nodetype2str(target->nodetype), LY_ARRAY_COUNT(ARRAY), PROPERTY); \ ret = LY_EVALID; \ goto cleanup; \ } /** * @brief Apply refine. * * @param[in] ctx Compile context. * @param[in] rfn Refine to apply. * @param[in] rfn_pmod Local module fo the refine. * @param[in,out] target Refine target. * @return LY_ERR value. */ static LY_ERR lys_apply_refine(struct lysc_ctx *ctx, struct lysp_refine *rfn, const struct lysp_module *rfn_pmod, struct lysp_node *target) { LY_ERR ret = LY_SUCCESS; struct lys_module *orig_mod = ctx->cur_mod; struct lysp_module *orig_pmod = ctx->pmod; LY_ARRAY_COUNT_TYPE u; struct lysp_qname *qname; struct lysp_restr **musts, *must; uint32_t *num; /* use module from the refine */ ctx->cur_mod = rfn_pmod->mod; ctx->pmod = (struct lysp_module *)rfn_pmod; /* keep the current path and add to it */ lysc_update_path(ctx, NULL, "{refine}"); lysc_update_path(ctx, NULL, rfn->nodeid); /* default value */ if (rfn->dflts) { switch (target->nodetype) { case LYS_LEAF: AMEND_CHECK_CARDINALITY(rfn->dflts, 1, "refine", "default"); lydict_remove(ctx->ctx, ((struct lysp_node_leaf *)target)->dflt.str); LY_CHECK_GOTO(ret = lysp_qname_dup(ctx->ctx, &rfn->dflts[0], &((struct lysp_node_leaf *)target)->dflt), cleanup); break; case LYS_LEAFLIST: if (rfn->dflts[0].mod->version < LYS_VERSION_1_1) { LOGVAL(ctx->ctx, LYVE_SEMANTICS, "Invalid refine of default in leaf-list - the default statement is allowed only in YANG 1.1 modules."); ret = LY_EVALID; goto cleanup; } FREE_ARRAY(ctx->ctx, ((struct lysp_node_leaflist *)target)->dflts, lysp_qname_free); ((struct lysp_node_leaflist *)target)->dflts = NULL; LY_ARRAY_FOR(rfn->dflts, u) { LY_ARRAY_NEW_GOTO(ctx->ctx, ((struct lysp_node_leaflist *)target)->dflts, qname, ret, cleanup); LY_CHECK_GOTO(ret = lysp_qname_dup(ctx->ctx, &rfn->dflts[u], qname), cleanup); } break; case LYS_CHOICE: AMEND_CHECK_CARDINALITY(rfn->dflts, 1, "refine", "default"); lydict_remove(ctx->ctx, ((struct lysp_node_choice *)target)->dflt.str); LY_CHECK_GOTO(ret = lysp_qname_dup(ctx->ctx, &rfn->dflts[0], &((struct lysp_node_choice *)target)->dflt), cleanup); break; default: AMEND_WRONG_NODETYPE("refine", "replace", "default"); } } /* description */ if (rfn->dsc) { lydict_remove(ctx->ctx, target->dsc); DUP_STRING_GOTO(ctx->ctx, rfn->dsc, target->dsc, ret, cleanup); } /* reference */ if (rfn->ref) { lydict_remove(ctx->ctx, target->ref); DUP_STRING_GOTO(ctx->ctx, rfn->ref, target->ref, ret, cleanup); } /* config */ if (rfn->flags & LYS_CONFIG_MASK) { if (ctx->compile_opts & LYS_COMPILE_NO_CONFIG) { LOGWRN(ctx->ctx, "Refining config inside %s has no effect (%s).", (ctx->compile_opts & (LYS_IS_INPUT | LYS_IS_OUTPUT)) ? "RPC/action" : ctx->compile_opts & LYS_IS_NOTIF ? "notification" : "a subtree ignoring config", ctx->path); } else { target->flags &= ~LYS_CONFIG_MASK; target->flags |= rfn->flags & LYS_CONFIG_MASK; } } /* mandatory */ if (rfn->flags & LYS_MAND_MASK) { switch (target->nodetype) { case LYS_LEAF: case LYS_CHOICE: case LYS_ANYDATA: case LYS_ANYXML: break; default: AMEND_WRONG_NODETYPE("refine", "replace", "mandatory"); } target->flags &= ~LYS_MAND_MASK; target->flags |= rfn->flags & LYS_MAND_MASK; } /* presence */ if (rfn->presence) { if (target->nodetype != LYS_CONTAINER) { AMEND_WRONG_NODETYPE("refine", "replace", "presence"); } lydict_remove(ctx->ctx, ((struct lysp_node_container *)target)->presence); DUP_STRING_GOTO(ctx->ctx, rfn->presence, ((struct lysp_node_container *)target)->presence, ret, cleanup); } /* must */ if (rfn->musts) { switch (target->nodetype) { case LYS_CONTAINER: case LYS_LIST: case LYS_LEAF: case LYS_LEAFLIST: case LYS_ANYDATA: case LYS_ANYXML: musts = &((struct lysp_node_container *)target)->musts; break; default: AMEND_WRONG_NODETYPE("refine", "add", "must"); } LY_ARRAY_FOR(rfn->musts, u) { LY_ARRAY_NEW_GOTO(ctx->ctx, *musts, must, ret, cleanup); LY_CHECK_GOTO(ret = lysp_restr_dup(ctx->ctx, rfn_pmod, &rfn->musts[u], must), cleanup); } } /* min-elements */ if (rfn->flags & LYS_SET_MIN) { switch (target->nodetype) { case LYS_LEAFLIST: num = &((struct lysp_node_leaflist *)target)->min; break; case LYS_LIST: num = &((struct lysp_node_list *)target)->min; break; default: AMEND_WRONG_NODETYPE("refine", "replace", "min-elements"); } *num = rfn->min; } /* max-elements */ if (rfn->flags & LYS_SET_MAX) { switch (target->nodetype) { case LYS_LEAFLIST: num = &((struct lysp_node_leaflist *)target)->max; break; case LYS_LIST: num = &((struct lysp_node_list *)target)->max; break; default: AMEND_WRONG_NODETYPE("refine", "replace", "max-elements"); } *num = rfn->max; } /* if-feature */ if (rfn->iffeatures) { switch (target->nodetype) { case LYS_LEAF: case LYS_LEAFLIST: case LYS_LIST: case LYS_CONTAINER: case LYS_CHOICE: case LYS_CASE: case LYS_ANYDATA: case LYS_ANYXML: break; default: AMEND_WRONG_NODETYPE("refine", "add", "if-feature"); } LY_ARRAY_FOR(rfn->iffeatures, u) { LY_ARRAY_NEW_GOTO(ctx->ctx, target->iffeatures, qname, ret, cleanup); LY_CHECK_GOTO(ret = lysp_qname_dup(ctx->ctx, &rfn->iffeatures[u], qname), cleanup); } } /* extension instances */ DUP_EXTS(ctx->ctx, rfn_pmod, target, lyplg_ext_nodetype2stmt(target->nodetype), rfn->exts, target->exts, lysp_ext_dup); cleanup: ctx->cur_mod = orig_mod; ctx->pmod = orig_pmod; lysc_update_path(ctx, NULL, NULL); lysc_update_path(ctx, NULL, NULL); return ret; } /** * @brief Apply deviate add. * * @param[in] ctx Compile context. * @param[in] d Deviate add to apply. * @param[in,out] target Deviation target. * @return LY_ERR value. */ static LY_ERR lys_apply_deviate_add(struct lysc_ctx *ctx, struct lysp_deviate_add *d, struct lysp_node *target) { LY_ERR ret = LY_SUCCESS; LY_ARRAY_COUNT_TYPE u; struct lysp_qname *qname; uint32_t *num; struct lysp_restr **musts, *must; #define DEV_CHECK_NONPRESENCE(TYPE, MEMBER, PROPERTY, VALUEMEMBER) \ if (((TYPE)target)->MEMBER) { \ LOGVAL(ctx->ctx, LYVE_REFERENCE, "Invalid deviation adding \"%s\" property which already exists (with value \"%s\").", \ PROPERTY, ((TYPE)target)->VALUEMEMBER); \ ret = LY_EVALID; \ goto cleanup; \ } /* [units-stmt] */ if (d->units) { switch (target->nodetype) { case LYS_LEAF: case LYS_LEAFLIST: break; default: AMEND_WRONG_NODETYPE("deviation", "add", "units"); } DEV_CHECK_NONPRESENCE(struct lysp_node_leaf *, units, "units", units); DUP_STRING_GOTO(ctx->ctx, d->units, ((struct lysp_node_leaf *)target)->units, ret, cleanup); } /* *must-stmt */ if (d->musts) { musts = lysp_node_musts_p(target); if (!musts) { AMEND_WRONG_NODETYPE("deviation", "add", "must"); } LY_ARRAY_FOR(d->musts, u) { LY_ARRAY_NEW_GOTO(ctx->ctx, *musts, must, ret, cleanup); LY_CHECK_GOTO(ret = lysp_restr_dup(ctx->ctx, ctx->pmod, &d->musts[u], must), cleanup); } } /* *unique-stmt */ if (d->uniques) { if (target->nodetype != LYS_LIST) { AMEND_WRONG_NODETYPE("deviation", "add", "unique"); } LY_ARRAY_FOR(d->uniques, u) { LY_ARRAY_NEW_GOTO(ctx->ctx, ((struct lysp_node_list *)target)->uniques, qname, ret, cleanup); LY_CHECK_GOTO(ret = lysp_qname_dup(ctx->ctx, &d->uniques[u], qname), cleanup); } } /* *default-stmt */ if (d->dflts) { switch (target->nodetype) { case LYS_LEAF: AMEND_CHECK_CARDINALITY(d->dflts, 1, "deviation", "default"); DEV_CHECK_NONPRESENCE(struct lysp_node_leaf *, dflt.str, "default", dflt.str); LY_CHECK_GOTO(ret = lysp_qname_dup(ctx->ctx, &d->dflts[0], &((struct lysp_node_leaf *)target)->dflt), cleanup); break; case LYS_LEAFLIST: LY_ARRAY_FOR(d->dflts, u) { LY_ARRAY_NEW_GOTO(ctx->ctx, ((struct lysp_node_leaflist *)target)->dflts, qname, ret, cleanup); LY_CHECK_GOTO(ret = lysp_qname_dup(ctx->ctx, &d->dflts[u], qname), cleanup); } break; case LYS_CHOICE: AMEND_CHECK_CARDINALITY(d->dflts, 1, "deviation", "default"); DEV_CHECK_NONPRESENCE(struct lysp_node_choice *, dflt.str, "default", dflt.str); LY_CHECK_GOTO(ret = lysp_qname_dup(ctx->ctx, &d->dflts[0], &((struct lysp_node_choice *)target)->dflt), cleanup); break; default: AMEND_WRONG_NODETYPE("deviation", "add", "default"); } } /* [config-stmt] */ if (d->flags & LYS_CONFIG_MASK) { switch (target->nodetype) { case LYS_CONTAINER: case LYS_LEAF: case LYS_LEAFLIST: case LYS_LIST: case LYS_CHOICE: case LYS_ANYDATA: case LYS_ANYXML: break; default: AMEND_WRONG_NODETYPE("deviation", "add", "config"); } if (target->flags & LYS_CONFIG_MASK) { LOGVAL(ctx->ctx, LYVE_REFERENCE, "Invalid deviation adding \"config\" property which already exists (with value \"config %s\").", target->flags & LYS_CONFIG_W ? "true" : "false"); ret = LY_EVALID; goto cleanup; } target->flags |= d->flags & LYS_CONFIG_MASK; } /* [mandatory-stmt] */ if (d->flags & LYS_MAND_MASK) { switch (target->nodetype) { case LYS_LEAF: case LYS_CHOICE: case LYS_ANYDATA: case LYS_ANYXML: break; default: AMEND_WRONG_NODETYPE("deviation", "add", "mandatory"); } if (target->flags & LYS_MAND_MASK) { LOGVAL(ctx->ctx, LYVE_REFERENCE, "Invalid deviation adding \"mandatory\" property which already exists (with value \"mandatory %s\").", target->flags & LYS_MAND_TRUE ? "true" : "false"); ret = LY_EVALID; goto cleanup; } target->flags |= d->flags & LYS_MAND_MASK; } /* [min-elements-stmt] */ if (d->flags & LYS_SET_MIN) { switch (target->nodetype) { case LYS_LEAFLIST: num = &((struct lysp_node_leaflist *)target)->min; break; case LYS_LIST: num = &((struct lysp_node_list *)target)->min; break; default: AMEND_WRONG_NODETYPE("deviation", "add", "min-elements"); } if (target->flags & LYS_SET_MIN) { LOGVAL(ctx->ctx, LYVE_REFERENCE, "Invalid deviation adding \"min-elements\" property which already exists (with value \"%" PRIu32 "\").", *num); ret = LY_EVALID; goto cleanup; } *num = d->min; } /* [max-elements-stmt] */ if (d->flags & LYS_SET_MAX) { switch (target->nodetype) { case LYS_LEAFLIST: num = &((struct lysp_node_leaflist *)target)->max; break; case LYS_LIST: num = &((struct lysp_node_list *)target)->max; break; default: AMEND_WRONG_NODETYPE("deviation", "add", "max-elements"); } if (target->flags & LYS_SET_MAX) { if (*num) { LOGVAL(ctx->ctx, LYVE_REFERENCE, "Invalid deviation adding \"max-elements\" property which already exists (with value \"%" PRIu32 "\").", *num); } else { LOGVAL(ctx->ctx, LYVE_REFERENCE, "Invalid deviation adding \"max-elements\" property which already exists (with value \"unbounded\")."); } ret = LY_EVALID; goto cleanup; } *num = d->max; } cleanup: return ret; } /** * @brief Apply deviate delete. * * @param[in] ctx Compile context. * @param[in] d Deviate delete to apply. * @param[in,out] target Deviation target. * @return LY_ERR value. */ static LY_ERR lys_apply_deviate_delete(struct lysc_ctx *ctx, struct lysp_deviate_del *d, struct lysp_node *target) { LY_ERR ret = LY_SUCCESS; struct lysp_restr **musts; LY_ARRAY_COUNT_TYPE u, v; struct lysp_qname **uniques, **dflts; #define DEV_DEL_ARRAY(DEV_ARRAY, ORIG_ARRAY, DEV_MEMBER, ORIG_MEMBER, FREE_FUNC, FREE_CTX, PROPERTY) \ LY_ARRAY_FOR(d->DEV_ARRAY, u) { \ int found = 0; \ LY_ARRAY_FOR(ORIG_ARRAY, v) { \ if (!strcmp(d->DEV_ARRAY[u]DEV_MEMBER, (ORIG_ARRAY)[v]ORIG_MEMBER)) { \ found = 1; \ break; \ } \ } \ if (!found) { \ LOGVAL(ctx->ctx, LYVE_REFERENCE, \ "Invalid deviation deleting \"%s\" property \"%s\" which does not match any of the target's property values.", \ PROPERTY, d->DEV_ARRAY[u]DEV_MEMBER); \ ret = LY_EVALID; \ goto cleanup; \ } \ LY_ARRAY_DECREMENT(ORIG_ARRAY); \ FREE_FUNC(FREE_CTX, &(ORIG_ARRAY)[v]); \ if (v < LY_ARRAY_COUNT(ORIG_ARRAY)) { \ memmove(&(ORIG_ARRAY)[v], &(ORIG_ARRAY)[v + 1], (LY_ARRAY_COUNT(ORIG_ARRAY) - v) * sizeof *(ORIG_ARRAY)); \ } \ } \ if (!LY_ARRAY_COUNT(ORIG_ARRAY)) { \ LY_ARRAY_FREE(ORIG_ARRAY); \ ORIG_ARRAY = NULL; \ } #define DEV_CHECK_PRESENCE_VALUE(TYPE, MEMBER, DEVTYPE, PROPERTY, VALUE) \ if (!((TYPE)target)->MEMBER) { \ LOGVAL(ctx->ctx, LY_VCODE_DEV_NOT_PRESENT, DEVTYPE, PROPERTY, VALUE); \ ret = LY_EVALID; \ goto cleanup; \ } else if (strcmp(((TYPE)target)->MEMBER, VALUE)) { \ LOGVAL(ctx->ctx, LYVE_REFERENCE, \ "Invalid deviation deleting \"%s\" property \"%s\" which does not match the target's property value \"%s\".", \ PROPERTY, VALUE, ((TYPE)target)->MEMBER); \ ret = LY_EVALID; \ goto cleanup; \ } /* [units-stmt] */ if (d->units) { switch (target->nodetype) { case LYS_LEAF: case LYS_LEAFLIST: break; default: AMEND_WRONG_NODETYPE("deviation", "delete", "units"); } DEV_CHECK_PRESENCE_VALUE(struct lysp_node_leaf *, units, "deleting", "units", d->units); lydict_remove(ctx->ctx, ((struct lysp_node_leaf *)target)->units); ((struct lysp_node_leaf *)target)->units = NULL; } /* *must-stmt */ if (d->musts) { musts = lysp_node_musts_p(target); if (!musts) { AMEND_WRONG_NODETYPE("deviation", "delete", "must"); } DEV_DEL_ARRAY(musts, *musts, .arg.str, .arg.str, lysp_restr_free, &ctx->free_ctx, "must"); } /* *unique-stmt */ if (d->uniques) { if (target->nodetype != LYS_LIST) { AMEND_WRONG_NODETYPE("deviation", "delete", "unique"); } uniques = &((struct lysp_node_list *)target)->uniques; DEV_DEL_ARRAY(uniques, *uniques, .str, .str, lysp_qname_free, ctx->ctx, "unique"); } /* *default-stmt */ if (d->dflts) { switch (target->nodetype) { case LYS_LEAF: AMEND_CHECK_CARDINALITY(d->dflts, 1, "deviation", "default"); DEV_CHECK_PRESENCE_VALUE(struct lysp_node_leaf *, dflt.str, "deleting", "default", d->dflts[0].str); lydict_remove(ctx->ctx, ((struct lysp_node_leaf *)target)->dflt.str); ((struct lysp_node_leaf *)target)->dflt.str = NULL; break; case LYS_LEAFLIST: dflts = &((struct lysp_node_leaflist *)target)->dflts; DEV_DEL_ARRAY(dflts, *dflts, .str, .str, lysp_qname_free, ctx->ctx, "default"); break; case LYS_CHOICE: AMEND_CHECK_CARDINALITY(d->dflts, 1, "deviation", "default"); DEV_CHECK_PRESENCE_VALUE(struct lysp_node_choice *, dflt.str, "deleting", "default", d->dflts[0].str); lydict_remove(ctx->ctx, ((struct lysp_node_choice *)target)->dflt.str); ((struct lysp_node_choice *)target)->dflt.str = NULL; break; default: AMEND_WRONG_NODETYPE("deviation", "delete", "default"); } } cleanup: return ret; } /** * @brief Apply deviate replace. * * @param[in] ctx Compile context. * @param[in] d Deviate replace to apply. * @param[in,out] target Deviation target. * @return LY_ERR value. */ static LY_ERR lys_apply_deviate_replace(struct lysc_ctx *ctx, struct lysp_deviate_rpl *d, struct lysp_node *target) { LY_ERR ret = LY_SUCCESS; uint32_t *num; #define DEV_CHECK_PRESENCE(TYPE, MEMBER, DEVTYPE, PROPERTY, VALUE) \ if (!((TYPE)target)->MEMBER) { \ LOGVAL(ctx->ctx, LY_VCODE_DEV_NOT_PRESENT, DEVTYPE, PROPERTY, VALUE); \ ret = LY_EVALID; \ goto cleanup; \ } /* [type-stmt] */ if (d->type) { switch (target->nodetype) { case LYS_LEAF: case LYS_LEAFLIST: break; default: AMEND_WRONG_NODETYPE("deviation", "replace", "type"); } lysp_type_free(&ctx->free_ctx, &((struct lysp_node_leaf *)target)->type); lysp_type_dup(ctx->ctx, ctx->pmod, d->type, &((struct lysp_node_leaf *)target)->type); } /* [units-stmt] */ if (d->units) { switch (target->nodetype) { case LYS_LEAF: case LYS_LEAFLIST: break; default: AMEND_WRONG_NODETYPE("deviation", "replace", "units"); } DEV_CHECK_PRESENCE(struct lysp_node_leaf *, units, "replacing", "units", d->units); lydict_remove(ctx->ctx, ((struct lysp_node_leaf *)target)->units); DUP_STRING_GOTO(ctx->ctx, d->units, ((struct lysp_node_leaf *)target)->units, ret, cleanup); } /* [default-stmt] */ if (d->dflt.str) { switch (target->nodetype) { case LYS_LEAF: DEV_CHECK_PRESENCE(struct lysp_node_leaf *, dflt.str, "replacing", "default", d->dflt.str); lydict_remove(ctx->ctx, ((struct lysp_node_leaf *)target)->dflt.str); LY_CHECK_GOTO(ret = lysp_qname_dup(ctx->ctx, &d->dflt, &((struct lysp_node_leaf *)target)->dflt), cleanup); break; case LYS_CHOICE: DEV_CHECK_PRESENCE(struct lysp_node_choice *, dflt.str, "replacing", "default", d->dflt.str); lydict_remove(ctx->ctx, ((struct lysp_node_choice *)target)->dflt.str); LY_CHECK_GOTO(ret = lysp_qname_dup(ctx->ctx, &d->dflt, &((struct lysp_node_choice *)target)->dflt), cleanup); break; default: AMEND_WRONG_NODETYPE("deviation", "replace", "default"); } } /* [config-stmt] */ if (d->flags & LYS_CONFIG_MASK) { switch (target->nodetype) { case LYS_CONTAINER: case LYS_LEAF: case LYS_LEAFLIST: case LYS_LIST: case LYS_CHOICE: case LYS_ANYDATA: case LYS_ANYXML: break; default: AMEND_WRONG_NODETYPE("deviation", "replace", "config"); } target->flags &= ~LYS_CONFIG_MASK; target->flags |= d->flags & LYS_CONFIG_MASK; } /* [mandatory-stmt] */ if (d->flags & LYS_MAND_MASK) { switch (target->nodetype) { case LYS_LEAF: case LYS_CHOICE: case LYS_ANYDATA: case LYS_ANYXML: break; default: AMEND_WRONG_NODETYPE("deviation", "replace", "mandatory"); } target->flags &= ~LYS_MAND_MASK; target->flags |= d->flags & LYS_MAND_MASK; } /* [min-elements-stmt] */ if (d->flags & LYS_SET_MIN) { switch (target->nodetype) { case LYS_LEAFLIST: num = &((struct lysp_node_leaflist *)target)->min; break; case LYS_LIST: num = &((struct lysp_node_list *)target)->min; break; default: AMEND_WRONG_NODETYPE("deviation", "replace", "min-elements"); } *num = d->min; } /* [max-elements-stmt] */ if (d->flags & LYS_SET_MAX) { switch (target->nodetype) { case LYS_LEAFLIST: num = &((struct lysp_node_leaflist *)target)->max; break; case LYS_LIST: num = &((struct lysp_node_list *)target)->max; break; default: AMEND_WRONG_NODETYPE("deviation", "replace", "max-elements"); } *num = d->max; } cleanup: return ret; } /** * @brief Apply deviation with all its deviates. * * @param[in] ctx Compile context. * @param[in] dev Deviation to apply. * @param[in] dev_pmod Local module of the deviation. * @param[in,out] target Deviation target. * @return LY_ERR value. */ static LY_ERR lys_apply_deviation(struct lysc_ctx *ctx, struct lysp_deviation *dev, const struct lysp_module *dev_pmod, struct lysp_node *target) { LY_ERR ret = LY_SUCCESS; struct lys_module *orig_mod = ctx->cur_mod; struct lysp_module *orig_pmod = ctx->pmod; char orig_path[LYSC_CTX_BUFSIZE]; struct lysp_deviate *d; /* clear path and set modules */ strcpy(orig_path, ctx->path); ctx->path_len = 1; ctx->cur_mod = dev_pmod->mod; ctx->pmod = (struct lysp_module *)dev_pmod; /* generate correct path */ lysc_update_path(ctx, NULL, "{deviation}"); lysc_update_path(ctx, NULL, dev->nodeid); LY_LIST_FOR(dev->deviates, d) { switch (d->mod) { case LYS_DEV_ADD: ret = lys_apply_deviate_add(ctx, (struct lysp_deviate_add *)d, target); break; case LYS_DEV_DELETE: ret = lys_apply_deviate_delete(ctx, (struct lysp_deviate_del *)d, target); break; case LYS_DEV_REPLACE: ret = lys_apply_deviate_replace(ctx, (struct lysp_deviate_rpl *)d, target); break; default: LOGINT(ctx->ctx); ret = LY_EINT; } LY_CHECK_GOTO(ret, cleanup); } /* deviation extension instances */ DUP_EXTS(ctx->ctx, dev_pmod, target, lyplg_ext_nodetype2stmt(target->nodetype), dev->exts, target->exts, lysp_ext_dup); cleanup: ctx->cur_mod = orig_mod; ctx->pmod = orig_pmod; strcpy(ctx->path, orig_path); ctx->path_len = strlen(ctx->path); return ret; } /** * @brief Check whether a compiled node matches a single schema nodeid name test. * * @param[in,out] node Compiled node to consider. On a match it is moved to its parent. * @param[in] mod Expected module. * @param[in] name_dict Expected name, in the dictionary. * @return Whether it is a match or not. */ static ly_bool lysp_schema_nodeid_match_node(const struct lysc_node **node, const struct lys_module *mod, const char *name_dict) { /* compare with the module of the node */ if ((*node)->module != mod) { return 0; } /* compare names */ if ((*node)->name != name_dict) { return 0; } /* move to next parent */ *node = (*node)->parent; return 1; } /** * @brief Check whether a compiled ext instance matches a single schema nodeid name test. * * @param[in,out] ext Compiled ext instance to consider. On a match it is zeroed to not match again. * @param[in] mod Expected module. * @param[in] name Expected name, in the dictionary. * @return Whether it is a match or not. */ static ly_bool lysp_schema_nodeid_match_ext(const struct lysc_ext_instance **ext, const struct lys_module *mod, const char *name_dict) { /* compare with the module */ if ((*ext)->module != mod) { return 0; } /* compare names (argument) */ if ((*ext)->argument != name_dict) { return 0; } /* zero */ *ext = NULL; return 1; } /** * @brief Check whether a node matches specific schema nodeid. * * @param[in] nodeid Compiled nodeid to match. * @param[in] nodeid_pmod Module to use for nodes in @p nodeid without a prefix. * @param[in] nodeid_ext Extension instance in which @p nodeid is defined, it means it targets an extension instance. * @param[in] ctx_node Initial context node that should match, only for descendant paths. * @param[in] parent First compiled parent to consider. If @p pnode is NULL, it is condered the node to be matched. * @param[in] pnode Parsed node to be matched. May be NULL if the target node was already compiled. * @param[in] pnode_mod Compiled @p pnode to-be module. * @param[in] pnode_ext Extension instance in which @p pnode is defined. * @return Whether it is a match or not. */ static ly_bool lysp_schema_nodeid_match(const struct lysc_nodeid *nodeid, const struct lysp_module *nodeid_pmod, const struct lysp_ext_instance *nodeid_ext, const struct lysc_node *ctx_node, const struct lysc_node *parent, const struct lysp_node *pnode, const struct lys_module *pnode_mod, const struct lysc_ext_instance *pnode_ext) { uint32_t i; const struct lys_module *mod; if (nodeid_ext && !pnode_ext) { /* extension instance augment and standard node, will never match */ return 0; } else if (!nodeid_ext && pnode_ext) { /* standard augment and extension instance node, will never match */ return 0; } /* compare last node in the node ID */ i = nodeid->count - 1; /* get exp node ID module */ mod = lys_schema_node_get_module(nodeid_pmod->mod->ctx, nodeid->prefix[i], nodeid_pmod); assert(mod); if (pnode) { /* compare on the last parsed-only node */ if ((pnode_mod != mod) || (pnode->name != nodeid->name[i])) { return 0; } } else { /* using parent directly */ if (!lysp_schema_nodeid_match_node(&parent, mod, nodeid->name[i])) { return 0; } } /* now compare all the compiled parents */ while (i) { --i; if (!parent && !pnode_ext) { /* no more parents but path continues */ return 0; } /* get exp node ID module */ mod = lys_schema_node_get_module(nodeid_pmod->mod->ctx, nodeid->prefix[i], nodeid_pmod); assert(mod); if (parent) { /* compare with the parent */ if (!lysp_schema_nodeid_match_node(&parent, mod, nodeid->name[i])) { return 0; } } else { /* compare with the ext instance */ if (!lysp_schema_nodeid_match_ext(&pnode_ext, mod, nodeid->name[i])) { return 0; } } } if (ctx_node && (ctx_node != parent)) { /* descendant path has not finished in the context node */ return 0; } else if (!ctx_node && (parent || pnode_ext)) { /* some parent/extension was not matched */ return 0; } return 1; } void lysc_augment_free(const struct ly_ctx *ctx, struct lysc_augment *aug) { if (!aug) { return; } lysc_nodeid_free(ctx, aug->nodeid); free(aug); } void lysc_deviation_free(const struct ly_ctx *ctx, struct lysc_deviation *dev) { if (!dev) { return; } lysc_nodeid_free(ctx, dev->nodeid); LY_ARRAY_FREE(dev->devs); LY_ARRAY_FREE(dev->dev_pmods); free(dev); } void lysc_refine_free(const struct ly_ctx *ctx, struct lysc_refine *rfn) { if (!rfn) { return; } lysc_nodeid_free(ctx, rfn->nodeid); LY_ARRAY_FREE(rfn->rfns); free(rfn); } void lysp_dev_node_free(struct lysc_ctx *cctx, struct lysp_node *dev_pnode) { if (!dev_pnode) { return; } switch (dev_pnode->nodetype) { case LYS_CONTAINER: ((struct lysp_node_container *)dev_pnode)->child = NULL; ((struct lysp_node_container *)dev_pnode)->actions = NULL; ((struct lysp_node_container *)dev_pnode)->notifs = NULL; break; case LYS_LIST: ((struct lysp_node_list *)dev_pnode)->child = NULL; ((struct lysp_node_list *)dev_pnode)->actions = NULL; ((struct lysp_node_list *)dev_pnode)->notifs = NULL; break; case LYS_CHOICE: ((struct lysp_node_choice *)dev_pnode)->child = NULL; break; case LYS_CASE: ((struct lysp_node_case *)dev_pnode)->child = NULL; break; case LYS_LEAF: case LYS_LEAFLIST: case LYS_ANYXML: case LYS_ANYDATA: /* no children */ break; case LYS_NOTIF: ((struct lysp_node_notif *)dev_pnode)->child = NULL; break; case LYS_RPC: case LYS_ACTION: ((struct lysp_node_action *)dev_pnode)->input.child = NULL; ((struct lysp_node_action *)dev_pnode)->output.child = NULL; break; case LYS_INPUT: case LYS_OUTPUT: ((struct lysp_node_action_inout *)dev_pnode)->child = NULL; lysp_node_free(&cctx->free_ctx, dev_pnode); free(dev_pnode); return; default: LOGINT(cctx->ctx); return; } lysp_node_free(&cctx->free_ctx, dev_pnode); } LY_ERR lys_compile_node_deviations_refines(struct lysc_ctx *ctx, const struct lysp_node *pnode, const struct lysc_node *parent, struct lysp_node **dev_pnode, ly_bool *not_supported) { LY_ERR ret = LY_SUCCESS; uint32_t i; LY_ARRAY_COUNT_TYPE u; struct lysc_refine *rfn; struct lysc_deviation *dev; *dev_pnode = NULL; *not_supported = 0; for (i = 0; i < ctx->uses_rfns.count; ) { rfn = ctx->uses_rfns.objs[i]; if (!lysp_schema_nodeid_match(rfn->nodeid, rfn->nodeid_pmod, NULL, rfn->nodeid_ctx_node, parent, pnode, ctx->cur_mod, ctx->ext)) { /* not our target node */ ++i; continue; } if (!*dev_pnode) { /* first refine on this node, create a copy first */ LY_CHECK_GOTO(ret = lysp_dup_single(ctx, pnode, 1, dev_pnode), cleanup); } /* apply all the refines by changing (the copy of) the parsed node */ LY_ARRAY_FOR(rfn->rfns, u) { LY_CHECK_GOTO(ret = lys_apply_refine(ctx, rfn->rfns[u], rfn->nodeid_pmod, *dev_pnode), cleanup); } /* refine was applied, remove it */ lysc_refine_free(ctx->ctx, rfn); ly_set_rm_index(&ctx->uses_rfns, i, NULL); /* refines use relative paths so more may apply to a single node */ } for (i = 0; i < ctx->devs.count; ++i) { dev = ctx->devs.objs[i]; if (!lysp_schema_nodeid_match(dev->nodeid, dev->dev_pmods[0], NULL, NULL, parent, pnode, ctx->cur_mod, ctx->ext)) { /* not our target node */ continue; } if (dev->not_supported) { /* it is not supported, no more deviations */ *not_supported = 1; goto dev_applied; } if (!*dev_pnode) { /* first deviation on this node, create a copy first */ LY_CHECK_GOTO(ret = lysp_dup_single(ctx, pnode, 1, dev_pnode), cleanup); } /* apply all the deviates by changing (the copy of) the parsed node */ LY_ARRAY_FOR(dev->devs, u) { LY_CHECK_GOTO(ret = lys_apply_deviation(ctx, dev->devs[u], dev->dev_pmods[u], *dev_pnode), cleanup); } dev_applied: /* deviation was applied, remove it */ lysc_deviation_free(ctx->ctx, dev); ly_set_rm_index(&ctx->devs, i, NULL); /* all the deviations for one target node are in one structure, we are done */ break; } cleanup: if (ret) { lysp_dev_node_free(ctx, *dev_pnode); *dev_pnode = NULL; *not_supported = 0; } return ret; } /** * @brief Compile augment children. * * @param[in] ctx Compile context. * @param[in] aug_when Parsed augment when to inherit. * @param[in] aug_flags Parsed augment flags. * @param[in] child First augment child to compile. * @param[in] target Target node of the augment. * @param[in] child_unres_disabled Whether the children are to be put into unres disabled set or not. * @return LY_SUCCESS on success. * @return LY_EVALID on failure. */ static LY_ERR lys_compile_augment_children(struct lysc_ctx *ctx, struct lysp_when *aug_when, uint16_t aug_flags, struct lysp_node *child, struct lysc_node *target, ly_bool child_unres_disabled) { LY_ERR rc = LY_SUCCESS; struct lysp_node *pnode; struct lysc_node *node; struct lysc_when *when_shared = NULL; ly_bool enabled, allow_mand = 0; struct ly_set child_set = {0}; uint32_t i, opt_prev = ctx->compile_opts; /* check for mandatory nodes * - new cases augmenting some choice can have mandatory nodes * - mandatory nodes are allowed only in case the augmentation is made conditional with a when statement */ if (aug_when || (target->nodetype == LYS_CHOICE) || (ctx->cur_mod == target->module)) { allow_mand = 1; } LY_LIST_FOR(child, pnode) { /* check if the subnode can be connected to the found target (e.g. case cannot be inserted into container) */ if (((pnode->nodetype == LYS_CASE) && (target->nodetype != LYS_CHOICE)) || ((pnode->nodetype & (LYS_RPC | LYS_ACTION | LYS_NOTIF)) && !(target->nodetype & (LYS_CONTAINER | LYS_LIST))) || ((pnode->nodetype == LYS_USES) && (target->nodetype == LYS_CHOICE))) { LOGVAL(ctx->ctx, LYVE_REFERENCE, "Invalid augment of %s node which is not allowed to contain %s node \"%s\".", lys_nodetype2str(target->nodetype), lys_nodetype2str(pnode->nodetype), pnode->name); rc = LY_EVALID; goto cleanup; } /* compile the children */ if (target->nodetype == LYS_CHOICE) { LY_CHECK_GOTO(rc = lys_compile_node_choice_child(ctx, pnode, target, &child_set), cleanup); } else if (target->nodetype & (LYS_INPUT | LYS_OUTPUT)) { if (target->nodetype == LYS_INPUT) { ctx->compile_opts |= LYS_COMPILE_RPC_INPUT; } else { ctx->compile_opts |= LYS_COMPILE_RPC_OUTPUT; } LY_CHECK_GOTO(rc = lys_compile_node(ctx, pnode, target, aug_flags, &child_set), cleanup); } else { LY_CHECK_GOTO(rc = lys_compile_node(ctx, pnode, target, aug_flags, &child_set), cleanup); } /* eval if-features again for the rest of this node processing */ LY_CHECK_GOTO(rc = lys_eval_iffeatures(ctx->ctx, pnode->iffeatures, &enabled), cleanup); if (!enabled && !(ctx->compile_opts & (LYS_COMPILE_NO_DISABLED | LYS_COMPILE_DISABLED | LYS_COMPILE_GROUPING))) { ctx->compile_opts |= LYS_COMPILE_DISABLED; } /* since the augment node is not present in the compiled tree, we need to pass some of its * statements to all its children */ for (i = 0; i < child_set.count; ++i) { node = child_set.snodes[i]; if (!allow_mand && (node->flags & LYS_CONFIG_W) && (node->flags & LYS_MAND_TRUE)) { node->flags &= ~LYS_MAND_TRUE; lys_compile_mandatory_parents(target, 0); LOGVAL(ctx->ctx, LYVE_SEMANTICS, "Invalid augment adding mandatory node \"%s\" without making it conditional via when statement.", node->name); rc = LY_EVALID; goto cleanup; } if (aug_when) { /* pass augment's when to all the children */ rc = lys_compile_when(ctx, aug_when, aug_flags, target, lysc_data_node(target), node, &when_shared); LY_CHECK_GOTO(rc, cleanup); } if (child_unres_disabled) { /* child is disabled by the augment if-features */ ly_set_add(&ctx->unres->disabled, node, 1, NULL); } } /* next iter */ ly_set_erase(&child_set, NULL); ctx->compile_opts = opt_prev; } cleanup: ly_set_erase(&child_set, NULL); ctx->compile_opts = opt_prev; return rc; } /** * @brief Compile the parsed augment connecting it into its target. * * It is expected that all the data referenced in path are present - augments are ordered so that augment B * targeting data from augment A is being compiled after augment A. Also the modules referenced in the path * are already implemented and compiled. * * @param[in] ctx Compile context. * @param[in] aug_p Parsed augment to compile. * @param[in] target Target node of the augment. * @return LY_SUCCESS on success. * @return LY_EVALID on failure. */ static LY_ERR lys_compile_augment(struct lysc_ctx *ctx, struct lysp_node_augment *aug_p, struct lysc_node *target) { LY_ERR rc = LY_SUCCESS; ly_bool enabled, child_unres_disabled = 0; uint32_t opt_prev = ctx->compile_opts; assert(target->nodetype & (LYS_CONTAINER | LYS_LIST | LYS_CHOICE | LYS_CASE | LYS_INPUT | LYS_OUTPUT | LYS_NOTIF)); /* nodetype checks */ if (aug_p->actions && !lysc_node_actions_p(target)) { LOGVAL(ctx->ctx, LYVE_REFERENCE, "Invalid augment of %s node which is not allowed to contain RPC/action node \"%s\".", lys_nodetype2str(target->nodetype), aug_p->actions->name); rc = LY_EVALID; goto cleanup; } if (aug_p->notifs && !lysc_node_notifs_p(target)) { LOGVAL(ctx->ctx, LYVE_REFERENCE, "Invalid augment of %s node which is not allowed to contain notification node \"%s\".", lys_nodetype2str(target->nodetype), aug_p->notifs->name); rc = LY_EVALID; goto cleanup; } /* augment if-features */ LY_CHECK_GOTO(rc = lys_eval_iffeatures(ctx->ctx, aug_p->iffeatures, &enabled), cleanup); if (!enabled && !(ctx->compile_opts & (LYS_COMPILE_NO_DISABLED | LYS_COMPILE_DISABLED | LYS_COMPILE_GROUPING))) { ctx->compile_opts |= LYS_COMPILE_DISABLED; child_unres_disabled = 1; } /* augment children */ rc = lys_compile_augment_children(ctx, aug_p->when, aug_p->flags, aug_p->child, target, child_unres_disabled); LY_CHECK_GOTO(rc, cleanup); /* augment actions */ rc = lys_compile_augment_children(ctx, aug_p->when, aug_p->flags, (struct lysp_node *)aug_p->actions, target, child_unres_disabled); LY_CHECK_GOTO(rc, cleanup); /* augment notifications */ rc = lys_compile_augment_children(ctx, aug_p->when, aug_p->flags, (struct lysp_node *)aug_p->notifs, target, child_unres_disabled); LY_CHECK_GOTO(rc, cleanup); /* compile extensions into the target */ COMPILE_EXTS_GOTO(ctx, aug_p->exts, target->exts, target, rc, cleanup); cleanup: ctx->compile_opts = opt_prev; return rc; } LY_ERR lys_compile_node_augments(struct lysc_ctx *ctx, struct lysc_node *node) { LY_ERR ret = LY_SUCCESS; struct lys_module *orig_mod = ctx->cur_mod; struct lysp_module *orig_pmod = ctx->pmod; uint32_t i; char orig_path[LYSC_CTX_BUFSIZE]; struct lysc_augment *aug; /* uses augments */ for (i = 0; i < ctx->uses_augs.count; ) { aug = ctx->uses_augs.objs[i]; if (!lysp_schema_nodeid_match(aug->nodeid, orig_mod->parsed, aug->ext, aug->nodeid_ctx_node, node, NULL, NULL, ctx->ext)) { /* not our target node */ ++i; continue; } /* use the path and modules from the augment */ lysc_update_path(ctx, NULL, "{augment}"); lysc_update_path(ctx, NULL, aug->aug_p->nodeid); ctx->pmod = (struct lysp_module *)aug->aug_pmod; /* apply augment, restore the path */ ret = lys_compile_augment(ctx, aug->aug_p, node); lysc_update_path(ctx, NULL, NULL); lysc_update_path(ctx, NULL, NULL); LY_CHECK_GOTO(ret, cleanup); /* augment was applied, remove it (index and the whole set may have changed because other augments * could have been applied) */ ly_set_rm(&ctx->uses_augs, aug, NULL); lysc_augment_free(ctx->ctx, aug); i = 0; } /* top-level augments */ for (i = 0; i < ctx->augs.count; ) { aug = ctx->augs.objs[i]; if (!lysp_schema_nodeid_match(aug->nodeid, aug->aug_pmod, aug->ext, NULL, node, NULL, NULL, ctx->ext)) { /* not our target node */ ++i; continue; } /* use the path and modules from the augment */ strcpy(orig_path, ctx->path); ctx->path_len = 1; ctx->cur_mod = aug->aug_pmod->mod; ctx->pmod = (struct lysp_module *)aug->aug_pmod; lysc_update_path(ctx, NULL, "{augment}"); lysc_update_path(ctx, NULL, aug->aug_p->nodeid); /* apply augment, restore the path */ ret = lys_compile_augment(ctx, aug->aug_p, node); strcpy(ctx->path, orig_path); ctx->path_len = strlen(ctx->path); LY_CHECK_GOTO(ret, cleanup); /* augment was applied, remove it */ ly_set_rm(&ctx->augs, aug, NULL); lysc_augment_free(ctx->ctx, aug); i = 0; } cleanup: ctx->cur_mod = orig_mod; ctx->pmod = orig_pmod; return ret; } /** * @brief Prepare an absolute-nodeid augment to be applied during data nodes compilation. * * @param[in] ctx Compile context. * @param[in] aug_p Parsed augment to be applied. * @param[in] pmod Both current and prefix module for @p aug_p. * @param[in] ext Extension instance in case @p aug_p is defined in one. * @return LY_ERR value. */ static LY_ERR lys_precompile_own_augment(struct lysc_ctx *ctx, struct lysp_node_augment *aug_p, const struct lysp_module *pmod, const struct lysp_ext_instance *ext) { LY_ERR ret = LY_SUCCESS; struct lysc_nodeid *nodeid = NULL; struct lysc_augment *aug; const struct lys_module *mod; /* compile its target, it was already parsed and fully checked (except for the existence of the nodes) */ ret = lys_precompile_nodeid(ctx->ctx, aug_p->nodeid, &nodeid); LY_CHECK_GOTO(ret, cleanup); mod = lys_schema_node_get_module(ctx->ctx, nodeid->prefix[0], pmod); LY_CHECK_ERR_GOTO(!mod, LOGINT(ctx->ctx); ret = LY_EINT, cleanup); if (mod != ctx->cur_mod) { /* augment for another module, ignore */ goto cleanup; } /* allocate new compiled augment and store it in the set */ aug = calloc(1, sizeof *aug); LY_CHECK_ERR_GOTO(!aug, LOGMEM(ctx->ctx); ret = LY_EMEM, cleanup); LY_CHECK_GOTO(ret = ly_set_add(&ctx->augs, aug, 1, NULL), cleanup); aug->nodeid = nodeid; nodeid = NULL; aug->aug_pmod = pmod; aug->ext = ext; aug->aug_p = aug_p; cleanup: lysc_nodeid_free(ctx->ctx, nodeid); return ret; } /** * @brief Prepare all top-level augments and extension instance augments to be applied during data nodes compilation. * * @param[in] ctx Compile context. * @param[in] pmod Parsed mod to use. * @return LY_ERR value. */ static LY_ERR lys_precompile_own_augments_mod(struct lysc_ctx *ctx, const struct lysp_module *pmod) { LY_ARRAY_COUNT_TYPE u, v; struct lysp_node_augment *aug_p; /* module */ LY_LIST_FOR(pmod->augments, aug_p) { LY_CHECK_RET(lys_precompile_own_augment(ctx, aug_p, pmod, NULL)); } /* parsed extension instances */ LY_ARRAY_FOR(pmod->exts, u) { aug_p = NULL; LY_ARRAY_FOR(pmod->exts[u].substmts, v) { if (pmod->exts[u].substmts[v].stmt == LY_STMT_AUGMENT) { aug_p = *VOIDPTR2_C(pmod->exts[u].substmts[v].storage); break; } } if (!aug_p) { continue; } LY_CHECK_RET(lys_precompile_own_augment(ctx, aug_p, pmod, &pmod->exts[u])); } return LY_SUCCESS; } LY_ERR lys_precompile_own_augments(struct lysc_ctx *ctx) { LY_ARRAY_COUNT_TYPE u, v; const struct lys_module *aug_mod; const struct lysp_module *submod; LY_ARRAY_FOR(ctx->cur_mod->augmented_by, u) { aug_mod = ctx->cur_mod->augmented_by[u]; /* collect all module augments */ LY_CHECK_RET(lys_precompile_own_augments_mod(ctx, aug_mod->parsed)); /* collect all submodules augments */ LY_ARRAY_FOR(aug_mod->parsed->includes, v) { submod = (struct lysp_module *)aug_mod->parsed->includes[v].submodule; LY_CHECK_RET(lys_precompile_own_augments_mod(ctx, submod)); } } return LY_SUCCESS; } /** * @brief Prepare a deviation to be applied during data nodes compilation. * * @param[in] ctx Compile context. * @param[in] dev_p Parsed deviation to be applied. * @param[in] pmod Both current and prefix module for @p dev_p. * @return LY_ERR value. */ static LY_ERR lys_precompile_own_deviation(struct lysc_ctx *ctx, struct lysp_deviation *dev_p, const struct lysp_module *pmod) { LY_ERR ret = LY_SUCCESS; struct lysc_deviation *dev = NULL; struct lysc_nodeid *nodeid = NULL; struct lysp_deviation **new_dev; const struct lys_module *mod; const struct lysp_module **new_dev_pmod; uint32_t i; /* parse its target, it was already parsed and fully checked (except for the existence of the nodes) */ ret = lys_precompile_nodeid(ctx->ctx, dev_p->nodeid, &nodeid); LY_CHECK_GOTO(ret, cleanup); mod = lys_schema_node_get_module(ctx->ctx, nodeid->prefix[0], pmod); LY_CHECK_ERR_GOTO(!mod, LOGINT(ctx->ctx); ret = LY_EINT, cleanup); if (mod != ctx->cur_mod) { /* deviation for another module, ignore */ goto cleanup; } /* try to find the node in already compiled deviations */ for (i = 0; i < ctx->devs.count; ++i) { if (lys_abs_schema_nodeid_match(ctx->ctx, nodeid, pmod, ((struct lysc_deviation *)ctx->devs.objs[i])->nodeid, ((struct lysc_deviation *)ctx->devs.objs[i])->dev_pmods[0])) { dev = ctx->devs.objs[i]; break; } } if (!dev) { /* allocate new compiled deviation */ dev = calloc(1, sizeof *dev); LY_CHECK_ERR_GOTO(!dev, LOGMEM(ctx->ctx); ret = LY_EMEM, cleanup); LY_CHECK_GOTO(ret = ly_set_add(&ctx->devs, dev, 1, NULL), cleanup); dev->nodeid = nodeid; nodeid = NULL; } /* add new parsed deviation structure */ LY_ARRAY_NEW_GOTO(ctx->ctx, dev->devs, new_dev, ret, cleanup); *new_dev = dev_p; LY_ARRAY_NEW_GOTO(ctx->ctx, dev->dev_pmods, new_dev_pmod, ret, cleanup); *new_dev_pmod = pmod; cleanup: lysc_nodeid_free(ctx->ctx, nodeid); return ret; } LY_ERR lys_precompile_own_deviations(struct lysc_ctx *ctx) { LY_ARRAY_COUNT_TYPE u, v, w; struct lys_module *orig_cur_mod; const struct lys_module *dev_mod; struct lysc_deviation *dev; struct lysp_deviate *d; int not_supported; uint32_t i; LY_ARRAY_FOR(ctx->cur_mod->deviated_by, u) { dev_mod = ctx->cur_mod->deviated_by[u]; /* compile all module deviations */ LY_ARRAY_FOR(dev_mod->parsed->deviations, v) { LY_CHECK_RET(lys_precompile_own_deviation(ctx, &dev_mod->parsed->deviations[v], dev_mod->parsed)); } /* compile all submodules deviations */ LY_ARRAY_FOR(dev_mod->parsed->includes, v) { LY_ARRAY_FOR(dev_mod->parsed->includes[v].submodule->deviations, w) { LY_CHECK_RET(lys_precompile_own_deviation(ctx, &dev_mod->parsed->includes[v].submodule->deviations[w], (struct lysp_module *)dev_mod->parsed->includes[v].submodule)); } } } /* set not-supported flags for all the deviations */ for (i = 0; i < ctx->devs.count; ++i) { dev = ctx->devs.objs[i]; not_supported = 0; LY_ARRAY_FOR(dev->devs, u) { LY_LIST_FOR(dev->devs[u]->deviates, d) { if (d->mod == LYS_DEV_NOT_SUPPORTED) { not_supported = 1; break; } } if (not_supported) { break; } } if (not_supported && (LY_ARRAY_COUNT(dev->devs) > 1)) { orig_cur_mod = ctx->cur_mod; ctx->cur_mod = dev->dev_pmods[u]->mod; lysc_update_path(ctx, NULL, "{deviation}"); lysc_update_path(ctx, NULL, dev->nodeid->str); LOGVAL(ctx->ctx, LYVE_SEMANTICS, "Multiple deviations of \"%s\" with one of them being \"not-supported\".", dev->nodeid->str); lysc_update_path(ctx, NULL, NULL); lysc_update_path(ctx, NULL, NULL); ctx->cur_mod = orig_cur_mod; return LY_EVALID; } dev->not_supported = not_supported; } return LY_SUCCESS; } /** * @brief Add a module reference into an array, checks for duplicities. * * @param[in] ctx Compile context. * @param[in] mod Module reference to add. * @param[in,out] mod_array Module sized array to add to. * @return LY_ERR value. */ static LY_ERR lys_array_add_mod_ref(struct lysc_ctx *ctx, struct lys_module *mod, struct lys_module ***mod_array) { LY_ARRAY_COUNT_TYPE u; struct lys_module **new_mod; LY_ARRAY_FOR(*mod_array, u) { if ((*mod_array)[u] == mod) { /* already there */ return LY_EEXIST; } } /* add the new module ref */ LY_ARRAY_NEW_RET(ctx->ctx, *mod_array, new_mod, LY_EMEM); *new_mod = mod; return LY_SUCCESS; } /** * @brief Check whether all modules in a set are implemented. * * @param[in] mod_set Module set to check. * @return Whether all modules are implemented or not. */ static ly_bool lys_precompile_mod_set_is_all_implemented(const struct ly_set *mod_set) { uint32_t i; const struct lys_module *mod; for (i = 0; i < mod_set->count; ++i) { mod = mod_set->objs[i]; if (!mod->implemented) { return 0; } } return 1; } /** * @brief Add references to target modules of top-level augments, deviations, and augments in extension instances * in a module and all its submodules. * * @param[in] pmod Module to process. * @param[in,out] mod_set Module set to add referenced modules into. * @return LY_SUCCESS on success. * @return LY_ERR on error. */ static LY_ERR lys_precompile_mod_augments_deviations(struct lysp_module *pmod, struct ly_set *mod_set) { LY_ERR ret = LY_SUCCESS; LY_ARRAY_COUNT_TYPE u, v; struct lysc_ctx ctx; struct lys_module *m; struct lysp_node_augment *aug; struct ly_set set = {0}; LYSC_CTX_INIT_PMOD(ctx, pmod, NULL); LY_LIST_FOR(pmod->augments, aug) { /* get target module */ lysc_update_path(&ctx, NULL, "{augment}"); lysc_update_path(&ctx, NULL, aug->nodeid); ret = lys_nodeid_mod_check(&ctx, aug->nodeid, 1, &set, NULL, &m); lysc_update_path(&ctx, NULL, NULL); lysc_update_path(&ctx, NULL, NULL); LY_CHECK_GOTO(ret, cleanup); /* add this module into the target module augmented_by, if not there and implemented */ if ((lys_array_add_mod_ref(&ctx, pmod->mod, &m->augmented_by) != LY_EEXIST) || !lys_precompile_mod_set_is_all_implemented(&set)) { LY_CHECK_GOTO(ret = ly_set_merge(mod_set, &set, 0, NULL), cleanup); } ly_set_erase(&set, NULL); } LY_ARRAY_FOR(pmod->deviations, u) { /* get target module */ lysc_update_path(&ctx, NULL, "{deviation}"); lysc_update_path(&ctx, NULL, pmod->deviations[u].nodeid); ret = lys_nodeid_mod_check(&ctx, pmod->deviations[u].nodeid, 1, &set, NULL, &m); lysc_update_path(&ctx, NULL, NULL); lysc_update_path(&ctx, NULL, NULL); LY_CHECK_GOTO(ret, cleanup); /* add this module into the target module deviated_by, if not there and implemented */ if ((lys_array_add_mod_ref(&ctx, pmod->mod, &m->deviated_by) != LY_EEXIST) || !lys_precompile_mod_set_is_all_implemented(&set)) { LY_CHECK_GOTO(ret = ly_set_merge(mod_set, &set, 0, NULL), cleanup); } ly_set_erase(&set, NULL); } LY_ARRAY_FOR(pmod->exts, u) { aug = NULL; LY_ARRAY_FOR(pmod->exts[u].substmts, v) { if (pmod->exts[u].substmts[v].stmt == LY_STMT_AUGMENT) { aug = *VOIDPTR2_C(pmod->exts[u].substmts[v].storage); break; } } if (!aug) { continue; } /* get target module */ lysc_update_path(&ctx, NULL, "{ext-augment}"); lysc_update_path(&ctx, NULL, aug->nodeid); ret = lys_nodeid_mod_check(&ctx, aug->nodeid, 1, &set, NULL, &m); lysc_update_path(&ctx, NULL, NULL); lysc_update_path(&ctx, NULL, NULL); LY_CHECK_GOTO(ret, cleanup); /* add this module into the target module augmented_by, if not there and implemented */ if ((lys_array_add_mod_ref(&ctx, pmod->mod, &m->augmented_by) != LY_EEXIST) || !lys_precompile_mod_set_is_all_implemented(&set)) { LY_CHECK_GOTO(ret = ly_set_merge(mod_set, &set, 0, NULL), cleanup); } ly_set_erase(&set, NULL); } cleanup: ly_set_erase(&set, NULL); return ret; } LY_ERR lys_precompile_augments_deviations(struct lys_module *mod, struct lys_glob_unres *unres) { LY_ERR ret = LY_SUCCESS, r; LY_ARRAY_COUNT_TYPE u; struct lys_module *m; struct lysp_module *submod; const char **imp_f, *all_f[] = {"*", NULL}; uint32_t i; struct ly_set mod_set = {0}; /* module */ LY_CHECK_GOTO(ret = lys_precompile_mod_augments_deviations(mod->parsed, &mod_set), cleanup); /* submodules */ LY_ARRAY_FOR(mod->parsed->includes, u) { submod = (struct lysp_module *)mod->parsed->includes[u].submodule; LY_CHECK_GOTO(ret = lys_precompile_mod_augments_deviations(submod, &mod_set), cleanup); } for (i = 0; i < mod_set.count; ++i) { m = mod_set.objs[i]; if (m == mod) { /* will be applied normally later */ continue; } /* we do not actually need the target modules compiled with out amends, they just need to be implemented * not compiled yet and marked for compilation */ if (!m->implemented) { /* implement the target module */ imp_f = (mod->ctx->flags & LY_CTX_ENABLE_IMP_FEATURES) ? all_f : NULL; r = lys_implement(m, imp_f, unres); if (r == LY_ERECOMPILE) { /* implement all the modules right away to save possible later recompilation */ ret = r; continue; } else if (r) { /* error */ ret = r; goto cleanup; } } else if (m->compiled) { /* target module was already compiled without our amends (augment/deviation), we need to recompile it */ m->to_compile = 1; ret = LY_ERECOMPILE; continue; } } cleanup: ly_set_erase(&mod_set, NULL); return ret; } void lys_precompile_augments_deviations_revert(struct ly_ctx *ctx, const struct lys_module *mod) { uint32_t i; LY_ARRAY_COUNT_TYPE u, count; struct lys_module *m; for (i = 0; i < ctx->list.count; ++i) { m = ctx->list.objs[i]; if (m->augmented_by) { count = LY_ARRAY_COUNT(m->augmented_by); for (u = 0; u < count; ++u) { if (m->augmented_by[u] == mod) { /* keep the order */ if (u < count - 1) { memmove(m->augmented_by + u, m->augmented_by + u + 1, (count - u - 1) * sizeof *m->augmented_by); } LY_ARRAY_DECREMENT(m->augmented_by); break; } } if (!LY_ARRAY_COUNT(m->augmented_by)) { LY_ARRAY_FREE(m->augmented_by); m->augmented_by = NULL; } } if (m->deviated_by) { count = LY_ARRAY_COUNT(m->deviated_by); for (u = 0; u < count; ++u) { if (m->deviated_by[u] == mod) { /* keep the order */ if (u < count - 1) { memmove(m->deviated_by + u, m->deviated_by + u + 1, (count - u - 1) * sizeof *m->deviated_by); } LY_ARRAY_DECREMENT(m->deviated_by); break; } } if (!LY_ARRAY_COUNT(m->deviated_by)) { LY_ARRAY_FREE(m->deviated_by); m->deviated_by = NULL; } } } }