blob: 46d54e48fdb3763bdfa4863bc1188841a2e8a017 [file] [log] [blame]
/**
* @file context.c
* @author Radek Krejci <rkrejci@cesnet.cz>
* @brief context implementation for libyang
*
* Copyright (c) 2015 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 <pthread.h>
#include <stddef.h>
#include <stdlib.h>
#include <string.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <unistd.h>
#include <errno.h>
#include <fcntl.h>
#include "common.h"
#include "context.h"
#include "dict_private.h"
#include "parser.h"
#include "tree_internal.h"
#include "resolve.h"
/*
* counter for references to the extensions plugins (for the number of contexts)
* located in extensions.c
*/
extern unsigned int ext_plugins_ref;
#define IETF_YANG_METADATA_PATH "../models/ietf-yang-metadata@2016-08-05.h"
#define YANG_PATH "../models/yang@2017-02-20.h"
#define IETF_INET_TYPES_PATH "../models/ietf-inet-types@2013-07-15.h"
#define IETF_YANG_TYPES_PATH "../models/ietf-yang-types@2013-07-15.h"
#define IETF_DATASTORES "../models/ietf-datastores@2017-08-17.h"
#define IETF_YANG_LIB_PATH "../models/ietf-yang-library@2018-01-17.h"
#define IETF_YANG_LIB_REV "2018-01-17"
#include IETF_YANG_METADATA_PATH
#include YANG_PATH
#include IETF_INET_TYPES_PATH
#include IETF_YANG_TYPES_PATH
#include IETF_DATASTORES
#include IETF_YANG_LIB_PATH
#define LY_INTERNAL_MODULE_COUNT 6
static struct internal_modules_s {
const char *name;
const char *revision;
const char *data;
uint8_t implemented;
LYS_INFORMAT format;
} internal_modules[LY_INTERNAL_MODULE_COUNT] = {
{"ietf-yang-metadata", "2016-08-05", (const char*)ietf_yang_metadata_2016_08_05_yin, 0, LYS_IN_YIN},
{"yang", "2017-02-20", (const char*)yang_2017_02_20_yin, 1, LYS_IN_YIN},
{"ietf-inet-types", "2013-07-15", (const char*)ietf_inet_types_2013_07_15_yin, 0, LYS_IN_YIN},
{"ietf-yang-types", "2013-07-15", (const char*)ietf_yang_types_2013_07_15_yin, 0, LYS_IN_YIN},
/* ietf-datastores and ietf-yang-library must be right here at the end of the list! */
{"ietf-datastores", "2017-08-17", (const char*)ietf_datastores_2017_08_17_yin, 0, LYS_IN_YIN},
{"ietf-yang-library", IETF_YANG_LIB_REV, (const char*)ietf_yang_library_2018_01_17_yin, 1, LYS_IN_YIN}
};
API unsigned int
ly_ctx_internal_modules_count(struct ly_ctx *ctx)
{
if (!ctx) {
return 0;
}
return ctx->internal_module_count;
}
API struct ly_ctx *
ly_ctx_new(const char *search_dir, int options)
{
struct ly_ctx *ctx = NULL;
struct lys_module *module;
char *cwd = NULL;
char *search_dir_list;
char *sep, *dir;
int rc = EXIT_SUCCESS;
int i;
ctx = calloc(1, sizeof *ctx);
LY_CHECK_ERR_RETURN(!ctx, LOGMEM, NULL);
/* dictionary */
lydict_init(&ctx->dict);
/* plugins */
lyext_load_plugins();
/* initialize thread-specific key */
while ((i = pthread_key_create(&ctx->errlist_key, ly_err_free)) == EAGAIN);
/* models list */
ctx->models.list = calloc(16, sizeof *ctx->models.list);
LY_CHECK_ERR_RETURN(!ctx->models.list, LOGMEM; free(ctx), NULL);
ext_plugins_ref++;
ctx->models.flags = options;
ctx->models.used = 0;
ctx->models.size = 16;
if (search_dir) {
search_dir_list = strdup(search_dir);
LY_CHECK_ERR_GOTO(!search_dir_list, LOGMEM, error);
for (dir = search_dir_list; (sep = strchr(dir, ':')) != NULL && rc == EXIT_SUCCESS; dir = sep + 1) {
*sep = 0;
rc = ly_ctx_set_searchdir(ctx, dir);
}
if (*dir && rc == EXIT_SUCCESS) {
rc = ly_ctx_set_searchdir(ctx, dir);
}
free(search_dir_list);
/* If ly_ctx_set_searchdir() failed, the error is already logged. Just exit */
if (rc != EXIT_SUCCESS) {
goto error;
}
}
ctx->models.module_set_id = 1;
/* load internal modules */
if (options & LY_CTX_NOYANGLIBRARY) {
ctx->internal_module_count = LY_INTERNAL_MODULE_COUNT - 2;
} else {
ctx->internal_module_count = LY_INTERNAL_MODULE_COUNT;
}
for (i = 0; i < ctx->internal_module_count; i++) {
module = (struct lys_module *)lys_parse_mem(ctx, internal_modules[i].data, internal_modules[i].format);
if (!module) {
goto error;
}
module->implemented = internal_modules[i].implemented;
}
/* cleanup */
free(cwd);
return ctx;
error:
free(cwd);
ly_ctx_destroy(ctx, NULL);
return NULL;
}
static int
ly_ctx_new_yl_legacy(struct ly_ctx *ctx, struct lyd_node *yltree)
{
unsigned int i, u;
struct lyd_node *module, *node;
struct ly_set *set;
const char *name, *revision;
struct ly_set features = {0, 0, {NULL}};
const struct lys_module *mod;
set = lyd_find_path(yltree, "/ietf-yang-library:yang-library/modules-state/module");
if (!set) {
return 1;
}
/* process the data tree */
for (i = 0; i < set->number; ++i) {
module = set->set.d[i];
/* initiate */
name = NULL;
revision = NULL;
ly_set_clean(&features);
LY_TREE_FOR(module->child, node) {
if (!strcmp(node->schema->name, "name")) {
name = ((struct lyd_node_leaf_list*)node)->value_str;
} else if (!strcmp(node->schema->name, "revision")) {
revision = ((struct lyd_node_leaf_list*)node)->value_str;
} else if (!strcmp(node->schema->name, "feature")) {
ly_set_add(&features, node, LY_SET_OPT_USEASLIST);
} else if (!strcmp(node->schema->name, "conformance-type") &&
((struct lyd_node_leaf_list*)node)->value.enm->value) {
/* imported module - skip it, it will be loaded as a side effect
* of loading another module */
continue;
}
}
/* use the gathered data to load the module */
mod = ly_ctx_load_module(ctx, name, revision);
if (!mod) {
LOGERR(LY_EINVAL, "Unable to load module specified by yang library data.");
ly_set_free(set);
return 1;
}
/* set features */
for (u = 0; u < features.number; u++) {
lys_features_enable(mod, ((struct lyd_node_leaf_list*)features.set.d[u])->value_str);
}
}
ly_set_free(set);
return 0;
}
static struct ly_ctx *
ly_ctx_new_yl_common(const char *search_dir, const char *input, LYD_FORMAT format, int options,
struct lyd_node* (*parser_func)(struct ly_ctx*, const char*, LYD_FORMAT, int,...))
{
unsigned int i, u;
struct lyd_node *module, *node;
const char *name, *revision;
struct ly_set features = {0, 0, {NULL}};
const struct lys_module *mod;
struct lyd_node *yltree = NULL;
struct ly_ctx *ctx = NULL;
struct ly_set *set = NULL;
/* create empty (with internal modules including ietf-yang-library) context */
ctx = ly_ctx_new(search_dir, options);
if (!ctx) {
goto error;
}
/* parse yang library data tree */
yltree = parser_func(ctx, input, format, LYD_OPT_DATA, NULL);
if (!yltree) {
goto error;
}
set = lyd_find_path(yltree, "/ietf-yang-library:yang-library/module-set[1]/module");
if (!set) {
goto error;
}
if (set->number == 0) {
/* perhaps a legacy data tree? */
if (ly_ctx_new_yl_legacy(ctx, yltree)) {
goto error;
}
} else {
/* process the data tree */
for (i = 0; i < set->number; ++i) {
module = set->set.d[i];
/* initiate */
name = NULL;
revision = NULL;
ly_set_clean(&features);
LY_TREE_FOR(module->child, node) {
if (!strcmp(node->schema->name, "name")) {
name = ((struct lyd_node_leaf_list*)node)->value_str;
} else if (!strcmp(node->schema->name, "revision")) {
revision = ((struct lyd_node_leaf_list*)node)->value_str;
} else if (!strcmp(node->schema->name, "feature")) {
ly_set_add(&features, node->child, LY_SET_OPT_USEASLIST);
}
}
/* use the gathered data to load the module */
mod = ly_ctx_load_module(ctx, name, revision);
if (!mod) {
LOGERR(LY_EINVAL, "Unable to load module specified by yang library data.");
goto error;
}
/* set features */
for (u = 0; u < features.number; u++) {
lys_features_enable(mod, ((struct lyd_node_leaf_list*)features.set.d[u])->value_str);
}
}
}
if (0) {
/* skip context destroy in case of success */
error:
ly_ctx_destroy(ctx, NULL);
ctx = NULL;
}
/* cleanup */
if (yltree) {
/* yang library data tree */
lyd_free_withsiblings(yltree);
}
if (set) {
ly_set_free(set);
}
return ctx;
}
API struct ly_ctx *
ly_ctx_new_ylpath(const char *search_dir, const char *path, LYD_FORMAT format, int options)
{
return ly_ctx_new_yl_common(search_dir, path, format, options, lyd_parse_path);
}
API struct ly_ctx *
ly_ctx_new_ylmem(const char *search_dir, const char *data, LYD_FORMAT format, int options)
{
return ly_ctx_new_yl_common(search_dir, data, format, options, lyd_parse_mem);
}
static void
ly_ctx_set_option(struct ly_ctx *ctx, int options)
{
if (!ctx) {
return;
}
ctx->models.flags |= options;
}
static void
ly_ctx_unset_option(struct ly_ctx *ctx, int options)
{
if (!ctx) {
return;
}
ctx->models.flags &= ~options;
}
API void
ly_ctx_set_allimplemented(struct ly_ctx *ctx)
{
ly_ctx_set_option(ctx, LY_CTX_ALLIMPLEMENTED);
}
API void
ly_ctx_unset_allimplemented(struct ly_ctx *ctx)
{
ly_ctx_unset_option(ctx, LY_CTX_ALLIMPLEMENTED);
}
API void
ly_ctx_set_trusted(struct ly_ctx *ctx)
{
ly_ctx_set_option(ctx, LY_CTX_TRUSTED);
}
API void
ly_ctx_unset_trusted(struct ly_ctx *ctx)
{
ly_ctx_unset_option(ctx, LY_CTX_TRUSTED);
}
API int
ly_ctx_set_searchdir(struct ly_ctx *ctx, const char *search_dir)
{
char *cwd = NULL, *new = NULL;
int index = 0;
void *r;
int rc = EXIT_FAILURE;
if (!ctx) {
LOGERR(LY_EINVAL, "%s: Invalid ctx parameter", __func__);
return EXIT_FAILURE;
}
if (search_dir) {
cwd = get_current_dir_name();
if (chdir(search_dir)) {
LOGERR(LY_ESYS, "Unable to use search directory \"%s\" (%s)",
search_dir, strerror(errno));
goto cleanup;
}
new = get_current_dir_name();
if (!ctx->models.search_paths) {
ctx->models.search_paths = malloc(2 * sizeof *ctx->models.search_paths);
LY_CHECK_ERR_GOTO(!ctx->models.search_paths, LOGMEM, cleanup);
index = 0;
} else {
for (index = 0; ctx->models.search_paths[index]; index++) {
/* check for duplicities */
if (!strcmp(new, ctx->models.search_paths[index])) {
/* path is already present */
goto success;
}
}
r = realloc(ctx->models.search_paths, (index + 2) * sizeof *ctx->models.search_paths);
LY_CHECK_ERR_GOTO(!r, LOGMEM, cleanup);
ctx->models.search_paths = r;
}
ctx->models.search_paths[index] = new;
new = NULL;
ctx->models.search_paths[index + 1] = NULL;
success:
if (chdir(cwd)) {
LOGWRN("Unable to return back to working directory \"%s\" (%s)",
cwd, strerror(errno));
}
rc = EXIT_SUCCESS;
} else {
/* consider that no change is not actually an error */
return EXIT_SUCCESS;
}
cleanup:
free(cwd);
free(new);
return rc;
}
API const char * const *
ly_ctx_get_searchdirs(const struct ly_ctx *ctx)
{
if (!ctx) {
LOGERR(LY_EINVAL, "%s: Invalid ctx parameter", __func__);
return NULL;
}
return (const char * const *)ctx->models.search_paths;
}
API void
ly_ctx_unset_searchdirs(struct ly_ctx *ctx, int index)
{
int i;
if (!ctx->models.search_paths) {
return;
}
for (i = 0; ctx->models.search_paths[i]; i++) {
if (index < 0 || index == i) {
free(ctx->models.search_paths[i]);
ctx->models.search_paths[i] = NULL;
} else if (i > index) {
ctx->models.search_paths[i - 1] = ctx->models.search_paths[i];
ctx->models.search_paths[i] = NULL;
}
}
if (index < 0 || !ctx->models.search_paths[0]) {
free(ctx->models.search_paths);
ctx->models.search_paths = NULL;
}
}
API void
ly_ctx_destroy(struct ly_ctx *ctx, void (*private_destructor)(const struct lys_node *node, void *priv))
{
int i;
if (!ctx) {
return;
}
/* models list */
for (; ctx->models.used > 0; ctx->models.used--) {
/* remove the applied deviations and augments */
lys_sub_module_remove_devs_augs(ctx->models.list[ctx->models.used - 1]);
/* remove the module */
lys_free(ctx->models.list[ctx->models.used - 1], private_destructor, 1, 0);
}
if (ctx->models.search_paths) {
for(i = 0; ctx->models.search_paths[i]; i++) {
free(ctx->models.search_paths[i]);
}
free(ctx->models.search_paths);
}
free(ctx->models.list);
/* clean the error list */
ly_err_clean(ctx, 0);
pthread_key_delete(ctx->errlist_key);
/* dictionary */
lydict_clean(&ctx->dict);
/* plugins - will be removed only if this is the last context */
ext_plugins_ref--;
lyext_clean_plugins();
free(ctx);
}
API const struct lys_submodule *
ly_ctx_get_submodule2(const struct lys_module *main_module, const char *submodule)
{
const struct lys_submodule *result;
int i;
if (!main_module || !submodule) {
ly_errno = LY_EINVAL;
return NULL;
}
/* search in submodules list */
for (i = 0; i < main_module->inc_size; i++) {
result = main_module->inc[i].submodule;
if (ly_strequal(submodule, result->name, 0)) {
return result;
}
/* in YANG 1.1 all the submodules must be included in the main module, so we are done.
* YANG 1.0 allows (is unclear about denying it) to include a submodule only in another submodule
* but when libyang parses such a module it adds the include into the main module so we are also done.
*/
}
return NULL;
}
API const struct lys_submodule *
ly_ctx_get_submodule(const struct ly_ctx *ctx, const char *module, const char *revision, const char *submodule,
const char *sub_revision)
{
const struct lys_module *mainmod;
const struct lys_submodule *ret = NULL, *submod;
uint32_t idx = 0;
if (!ctx || !submodule || (revision && !module)) {
ly_errno = LY_EINVAL;
return NULL;
}
while ((mainmod = ly_ctx_get_module_iter(ctx, &idx))) {
if (module && strcmp(mainmod->name, module)) {
/* main module name does not match */
continue;
}
if (revision && (!mainmod->rev || strcmp(revision, mainmod->rev[0].date))) {
/* main module revision does not match */
continue;
}
submod = ly_ctx_get_submodule2(mainmod, submodule);
if (!submod) {
continue;
}
if (!sub_revision) {
/* store only if newer */
if (ret) {
if (submod->rev && (!ret->rev || (strcmp(submod->rev[0].date, ret->rev[0].date) > 0))) {
ret = submod;
}
} else {
ret = submod;
}
} else {
/* store only if revision matches, we are done if it does */
if (!submod->rev) {
continue;
} else if (!strcmp(sub_revision, submod->rev[0].date)) {
ret = submod;
break;
}
}
}
return ret;
}
static const struct lys_module *
ly_ctx_get_module_by(const struct ly_ctx *ctx, const char *key, int offset, const char *revision, int with_disabled, int implemented)
{
int i;
struct lys_module *result = NULL;
if (!ctx || !key) {
ly_errno = LY_EINVAL;
return NULL;
}
for (i = 0; i < ctx->models.used; i++) {
if (!with_disabled && ctx->models.list[i]->disabled) {
/* skip the disabled modules */
continue;
}
/* use offset to get address of the pointer to string (char**), remember that offset is in
* bytes, so we have to cast the pointer to the module to (char*), finally, we want to have
* string not the pointer to string
*/
if (!ctx->models.list[i] || strcmp(key, *(char**)(((char*)ctx->models.list[i]) + offset))) {
continue;
}
if (!revision) {
/* compare revisons and remember the newest one */
if (result) {
if (!ctx->models.list[i]->rev_size) {
/* the current have no revision, keep the previous with some revision */
continue;
}
if (result->rev_size && strcmp(ctx->models.list[i]->rev[0].date, result->rev[0].date) < 0) {
/* the previous found matching module has a newer revision */
continue;
}
}
if (implemented) {
if (ctx->models.list[i]->implemented) {
/* we have the implemented revision */
result = ctx->models.list[i];
break;
} else {
/* do not remember the result, we are supposed to return the implemented revision
* not the newest one */
continue;
}
}
/* remember the current match and search for newer version */
result = ctx->models.list[i];
} else {
if (ctx->models.list[i]->rev_size && !strcmp(revision, ctx->models.list[i]->rev[0].date)) {
/* matching revision */
result = ctx->models.list[i];
break;
}
}
}
return result;
}
API const struct lys_module *
ly_ctx_get_module_by_ns(const struct ly_ctx *ctx, const char *ns, const char *revision, int implemented)
{
return ly_ctx_get_module_by(ctx, ns, offsetof(struct lys_module, ns), revision, 0, implemented);
}
API const struct lys_module *
ly_ctx_get_module(const struct ly_ctx *ctx, const char *name, const char *revision, int implemented)
{
return ly_ctx_get_module_by(ctx, name, offsetof(struct lys_module, name), revision, 0, implemented);
}
API const struct lys_module *
ly_ctx_get_module_older(const struct ly_ctx *ctx, const struct lys_module *module)
{
int i;
const struct lys_module *result = NULL, *iter;
if (!ctx || !module || !module->rev_size) {
ly_errno = LY_EINVAL;
return NULL;
}
for (i = 0; i < ctx->models.used; i++) {
iter = ctx->models.list[i];
if (iter->disabled) {
/* skip the disabled modules */
continue;
}
if (iter == module || !iter->rev_size) {
/* iter is the module itself or iter has no revision */
continue;
}
if (!ly_strequal(module->name, iter->name, 0)) {
/* different module */
continue;
}
if (strcmp(iter->rev[0].date, module->rev[0].date) < 0) {
/* iter is older than module */
if (result) {
if (strcmp(iter->rev[0].date, result->rev[0].date) > 0) {
/* iter is newer than current result */
result = iter;
}
} else {
result = iter;
}
}
}
return result;
}
API void
ly_ctx_set_module_imp_clb(struct ly_ctx *ctx, ly_module_imp_clb clb, void *user_data)
{
if (!ctx) {
ly_errno = LY_EINVAL;
return;
}
ctx->imp_clb = clb;
ctx->imp_clb_data = user_data;
}
API ly_module_imp_clb
ly_ctx_get_module_imp_clb(const struct ly_ctx *ctx, void **user_data)
{
if (!ctx) {
ly_errno = LY_EINVAL;
return NULL;
}
if (user_data) {
*user_data = ctx->imp_clb_data;
}
return ctx->imp_clb;
}
API void
ly_ctx_set_module_data_clb(struct ly_ctx *ctx, ly_module_data_clb clb, void *user_data)
{
if (!ctx) {
ly_errno = LY_EINVAL;
return;
}
ctx->data_clb = clb;
ctx->data_clb_data = user_data;
}
API ly_module_data_clb
ly_ctx_get_module_data_clb(const struct ly_ctx *ctx, void **user_data)
{
if (!ctx) {
ly_errno = LY_EINVAL;
return NULL;
}
if (user_data) {
*user_data = ctx->data_clb_data;
}
return ctx->data_clb;
}
const struct lys_module *
ly_ctx_load_sub_module(struct ly_ctx *ctx, struct lys_module *module, const char *name, const char *revision,
int implement, struct unres_schema *unres)
{
struct lys_module *mod;
char *module_data = NULL;
int i;
void (*module_data_free)(void *module_data) = NULL;
LYS_INFORMAT format = LYS_IN_UNKNOWN;
if (!module) {
/* exception for internal modules */
for (i = 0; i < ctx->internal_module_count; i++) {
if (ly_strequal(name, internal_modules[i].name, 0)) {
if (!revision || ly_strequal(revision, internal_modules[i].revision, 0)) {
/* return internal module */
return (struct lys_module *)ly_ctx_get_module(ctx, name, revision, 0);
}
}
}
/* try to get the schema from the context (with or without revision),
* include the disabled modules in the search to avoid their duplication,
* they are enabled by the subsequent call to lys_set_implemented() */
for (i = ctx->internal_module_count, mod = NULL; i < ctx->models.used; i++) {
mod = ctx->models.list[i]; /* shortcut */
if (ly_strequal(name, mod->name, 0)) {
if (revision && mod->rev_size && !strcmp(revision, mod->rev[0].date)) {
/* the specific revision was already loaded */
break;
} else if (!revision && mod->latest_revision) {
/* the latest revision of this module was already loaded */
break;
} else if (implement && mod->implemented && !revision) {
/* we are not able to implement another module, so consider this module as the latest one */
break;
}
}
mod = NULL;
}
if (mod) {
/* module must be enabled */
if (mod->disabled) {
lys_set_enabled(mod);
}
/* module is supposed to be implemented */
if (implement && lys_set_implemented(mod)) {
/* the schema cannot be implemented */
mod = NULL;
}
return mod;
}
}
/* module is not yet in context, use the user callback or try to find the schema on our own */
if (ctx->imp_clb) {
ly_errno = LY_SUCCESS;
if (module) {
mod = lys_main_module(module);
module_data = ctx->imp_clb(mod->name, (mod->rev_size ? mod->rev[0].date : NULL), name, revision, ctx->imp_clb_data, &format, &module_data_free);
} else {
module_data = ctx->imp_clb(name, revision, NULL, NULL, ctx->imp_clb_data, &format, &module_data_free);
}
if (!module_data && (ly_errno != LY_SUCCESS)) {
/* callback encountered an error, do not change it */
LOGERR(LY_SUCCESS, "User module retrieval callback failed!");
return NULL;
}
}
if (module_data) {
/* we got the module from the callback */
if (module) {
mod = (struct lys_module *)lys_sub_parse_mem(module, module_data, format, unres);
} else {
mod = (struct lys_module *)lys_parse_mem_(ctx, module_data, format, NULL, 0, implement);
}
if (module_data_free) {
module_data_free(module_data);
}
} else {
/* module was not received from the callback or there is no callback set */
mod = lyp_search_file(ctx, module, name, revision, implement, unres);
}
#ifdef LY_ENABLED_LATEST_REVISIONS
if (!revision && mod) {
/* module is the latest revision found */
mod->latest_revision = 1;
}
#endif
return mod;
}
API const struct lys_module *
ly_ctx_load_module(struct ly_ctx *ctx, const char *name, const char *revision)
{
const struct lys_module *mod;
struct ly_ctx *ctx_prev = ly_parser_data.ctx;
if (!ctx || !name) {
ly_errno = LY_EINVAL;
return NULL;
}
ly_parser_data.ctx = ctx;
mod = ly_ctx_load_sub_module(ctx, NULL, name, revision && revision[0] ? revision : NULL, 1, NULL);
ly_parser_data.ctx = ctx_prev;
return mod;
}
/*
* mods - set of removed modules, if NULL all modules are supposed to be removed so any backlink is invalid
*/
static void
ctx_modules_undo_backlinks(struct ly_ctx *ctx, struct ly_set *mods)
{
int o;
uint8_t j;
unsigned int u, v;
struct lys_module *mod;
struct lys_node *elem, *next;
struct lys_node_leaf *leaf;
/* maintain backlinks (start with internal ietf-yang-library which have leafs as possible targets of leafrefs */
for (o = ctx->internal_module_count - 1; o < ctx->models.used; o++) {
mod = ctx->models.list[o]; /* shortcut */
/* 1) features */
for (j = 0; j < mod->features_size; j++) {
if (!mod->features[j].depfeatures) {
continue;
}
for (v = 0; v < mod->features[j].depfeatures->number; v++) {
if (!mods || ly_set_contains(mods, ((struct lys_feature *)mod->features[j].depfeatures->set.g[v])->module) != -1) {
/* depending feature is in module to remove */
ly_set_rm_index(mod->features[j].depfeatures, v);
v--;
}
}
if (!mod->features[j].depfeatures->number) {
/* all backlinks removed */
ly_set_free(mod->features[j].depfeatures);
mod->features[j].depfeatures = NULL;
}
}
/* 2) identities */
for (u = 0; u < mod->ident_size; u++) {
if (!mod->ident[u].der) {
continue;
}
for (v = 0; v < mod->ident[u].der->number; v++) {
if (!mods || ly_set_contains(mods, ((struct lys_ident *)mod->ident[u].der->set.g[v])->module) != -1) {
/* derived identity is in module to remove */
ly_set_rm_index(mod->ident[u].der, v);
v--;
}
}
if (!mod->ident[u].der->number) {
/* all backlinks removed */
ly_set_free(mod->ident[u].der);
mod->ident[u].der = NULL;
}
}
/* 3) leafrefs */
for (elem = next = mod->data; elem; elem = next) {
if (elem->nodetype & (LYS_LEAF | LYS_LEAFLIST)) {
leaf = (struct lys_node_leaf *)elem; /* shortcut */
if (leaf->backlinks) {
if (!mods) {
/* remove all backlinks */
ly_set_free(leaf->backlinks);
leaf->backlinks = NULL;
} else {
for (v = 0; v < leaf->backlinks->number; v++) {
if (ly_set_contains(mods, leaf->backlinks->set.s[v]->module) != -1) {
/* derived identity is in module to remove */
ly_set_rm_index(leaf->backlinks, v);
v--;
}
}
if (!leaf->backlinks->number) {
/* all backlinks removed */
ly_set_free(leaf->backlinks);
leaf->backlinks = NULL;
}
}
}
}
/* select next element to process */
next = elem->child;
/* child exception for leafs, leaflists, anyxml and groupings */
if (elem->nodetype & (LYS_LEAF | LYS_LEAFLIST | LYS_ANYDATA | LYS_GROUPING)) {
next = NULL;
}
if (!next) {
/* no children, try siblings */
next = elem->next;
}
while (!next) {
/* parent is already processed, go to its sibling */
elem = lys_parent(elem);
if (!elem) {
/* we are done, no next element to process */
break;
}
/* no siblings, go back through parents */
next = elem->next;
}
}
}
}
static int
ctx_modules_redo_backlinks(struct ly_set *mods)
{
unsigned int i, j, k, s;
struct lys_module *mod;
struct lys_node *next, *elem;
struct lys_type *type;
struct lys_feature *feat;
for (i = 0; i < mods->number; ++i) {
mod = (struct lys_module *)mods->set.g[i]; /* shortcut */
/* identities */
if (mod->implemented) {
for (j = 0; j < mod->ident_size; j++) {
for (k = 0; k < mod->ident[j].base_size; k++) {
resolve_identity_backlink_update(&mod->ident[j], mod->ident[j].base[k]);
}
}
}
/* features */
for (j = 0; j < mod->features_size; j++) {
for (k = 0; k < mod->features[j].iffeature_size; k++) {
resolve_iffeature_getsizes(&mod->features[j].iffeature[k], NULL, &s);
while (s--) {
feat = mod->features[j].iffeature[k].features[s]; /* shortcut */
if (!feat->depfeatures) {
feat->depfeatures = ly_set_new();
}
ly_set_add(feat->depfeatures, &mod->features[j], LY_SET_OPT_USEASLIST);
}
}
}
/* leafrefs */
LY_TREE_DFS_BEGIN(mod->data, next, elem) {
if (elem->nodetype == LYS_GROUPING) {
goto next_sibling;
}
if (elem->nodetype & (LYS_LEAF | LYS_LEAFLIST)) {
type = &((struct lys_node_leaf *)elem)->type; /* shortcut */
if (type->base == LY_TYPE_LEAFREF) {
lys_leaf_add_leafref_target(type->info.lref.target, elem);
}
}
/* select element for the next run - children first */
next = elem->child;
/* child exception for leafs, leaflists and anyxml without children */
if (elem->nodetype & (LYS_LEAF | LYS_LEAFLIST | LYS_ANYDATA)) {
next = NULL;
}
if (!next) {
next_sibling:
/* no children */
if (elem == mod->data) {
/* we are done, (START) has no children */
break;
}
/* try siblings */
next = elem->next;
}
while (!next) {
/* parent is already processed, go to its sibling */
elem = lys_parent(elem);
/* no siblings, go back through parents */
if (lys_parent(elem) == lys_parent(mod->data)) {
/* we are done, no next element to process */
break;
}
next = elem->next;
}
}
}
return 0;
}
API int
lys_set_disabled(const struct lys_module *module)
{
struct ly_ctx *ctx; /* shortcut */
struct lys_module *mod;
struct ly_set *mods;
uint8_t j, imported;
int i, o;
unsigned int u, v;
if (!module) {
ly_errno = LY_EINVAL;
return EXIT_FAILURE;
} else if (module->disabled) {
/* already disabled module */
return EXIT_SUCCESS;
}
mod = (struct lys_module *)module;
ctx = mod->ctx;
/* avoid disabling internal modules */
for (i = 0; i < ctx->internal_module_count; i++) {
if (mod == ctx->models.list[i]) {
LOGERR(LY_EINVAL, "Internal module \"%s\" cannot be disabled.", mod->name);
return EXIT_FAILURE;
}
}
/* disable the module */
mod->disabled = 1;
/* get the complete list of modules to disable because of dependencies,
* we are going also to disable all the imported (not implemented) modules
* that are not used in any other module */
mods = ly_set_new();
ly_set_add(mods, mod, 0);
checkdependency:
for (i = ctx->internal_module_count; i < ctx->models.used; i++) {
mod = ctx->models.list[i]; /* shortcut */
if (mod->disabled) {
/* skip the already disabled modules */
continue;
}
/* check depndency of imported modules */
for (j = 0; j < mod->imp_size; j++) {
for (u = 0; u < mods->number; u++) {
if (mod->imp[j].module == mods->set.g[u]) {
/* module is importing some module to disable, so it must be also disabled */
mod->disabled = 1;
ly_set_add(mods, mod, 0);
/* we have to start again because some of the already checked modules can
* depend on the one we have just decided to disable */
goto checkdependency;
}
}
}
/* check if the imported module is used in any module supposed to be kept */
if (!mod->implemented) {
imported = 0;
for (o = ctx->internal_module_count; o < ctx->models.used; o++) {
if (ctx->models.list[o]->disabled) {
/* skip modules already disabled */
continue;
}
for (j = 0; j < ctx->models.list[o]->imp_size; j++) {
if (ctx->models.list[o]->imp[j].module == mod) {
/* the module is used in some other module not yet selected to be disabled */
imported = 1;
goto imported;
}
}
}
imported:
if (!imported) {
/* module is not implemented and neither imported by any other module in context
* which is supposed to be kept enabled after this operation, so we are going to disable also
* this module */
mod->disabled = 1;
ly_set_add(mods, mod, 0);
/* we have to start again, this time not because other module can depend on this one
* (we know that there is no such module), but because the module can import module
* that could became useless. If there are no imports, we can continue */
if (mod->imp_size) {
goto checkdependency;
}
}
}
}
/* before removing applied deviations, augments and updating leafrefs, we have to enable the modules
* to disable to allow all that operations */
for (u = 0; u < mods->number; u++) {
((struct lys_module *)mods->set.g[u])->disabled = 0;
}
/* maintain backlinks (start with internal ietf-yang-library which have leafs as possible targets of leafrefs */
ctx_modules_undo_backlinks(ctx, mods);
/* remove the applied deviations and augments */
for (u = 0; u < mods->number; u++) {
lys_sub_module_remove_devs_augs((struct lys_module *)mods->set.g[u]);
}
/* now again disable the modules to disable and disable also all its submodules */
for (u = 0; u < mods->number; u++) {
mod = (struct lys_module *)mods->set.g[u];
mod->disabled = 1;
for (v = 0; v < mod->inc_size; v++) {
mod->inc[v].submodule->disabled = 1;
}
}
/* free the set */
ly_set_free(mods);
/* update the module-set-id */
ctx->models.module_set_id++;
return EXIT_SUCCESS;
}
static void
lys_set_enabled_(struct ly_set *mods, struct lys_module *mod)
{
unsigned int i;
ly_set_add(mods, mod, 0);
mod->disabled = 0;
for (i = 0; i < mod->inc_size; i++) {
mod->inc[i].submodule->disabled = 0;
}
/* go recursively */
for (i = 0; i < mod->imp_size; i++) {
if (!mod->imp[i].module->disabled) {
continue;
}
lys_set_enabled_(mods, mod->imp[i].module);
}
}
API int
lys_set_enabled(const struct lys_module *module)
{
struct ly_ctx *ctx; /* shortcut */
struct lys_module *mod;
struct ly_set *mods, *disabled;
int i;
unsigned int u, v, w;
if (!module) {
ly_errno = LY_EINVAL;
return EXIT_FAILURE;
} else if (!module->disabled) {
/* already enabled module */
return EXIT_SUCCESS;
}
mod = (struct lys_module *)module;
ctx = mod->ctx;
/* avoid disabling internal modules */
for (i = 0; i < ctx->internal_module_count; i++) {
if (mod == ctx->models.list[i]) {
LOGERR(LY_EINVAL, "Internal module \"%s\" cannot be removed.", mod->name);
return EXIT_FAILURE;
}
}
mods = ly_set_new();
disabled = ly_set_new();
/* enable the module, including its dependencies */
lys_set_enabled_(mods, mod);
/* we will go through the all disabled modules in the context, if the module has no dependency (import)
* that is still disabled AND at least one of its imported module is from the set we are enabling now,
* it is going to be also enabled. This way we try to revert everething that was possibly done by
* lys_set_disabled(). */
checkdependency:
for (i = ctx->internal_module_count; i < ctx->models.used; i++) {
mod = ctx->models.list[i]; /* shortcut */
if (!mod->disabled || ly_set_contains(disabled, mod) != -1) {
/* skip the enabled modules */
continue;
}
/* check imported modules */
for (u = 0; u < mod->imp_size; u++) {
if (mod->imp[u].module->disabled) {
/* it has disabled dependency so it must stay disabled */
break;
}
}
if (u < mod->imp_size) {
/* it has disabled dependency, continue with the next module in the context */
continue;
}
/* get know if at least one of the imported modules is being enabled this time */
for (u = 0; u < mod->imp_size; u++) {
for (v = 0; v < mods->number; v++) {
if (mod->imp[u].module == mods->set.g[v]) {
/* yes, it is, so they are connected and we are going to enable it as well,
* it is not necessary to call recursive lys_set_enable_() because we already
* know that there is no disabled import to enable */
mod->disabled = 0;
ly_set_add(mods, mod, 0);
for (w = 0; w < mod->inc_size; w++) {
mod->inc[w].submodule->disabled = 0;
}
/* we have to start again because some of the already checked modules can
* depend on the one we have just decided to enable */
goto checkdependency;
}
}
}
/* this module is disabled, but it does not depend on any other disabled module and none
* of its imports was not enabled in this call. No future enabling of the disabled module
* will change this so we can remember the module and skip it next time we will have to go
* through the all context because of the checkdependency goto.
*/
ly_set_add(disabled, mod, 0);
}
/* maintain backlinks (start with internal ietf-yang-library which have leafs as possible targets of leafrefs */
ctx_modules_redo_backlinks(mods);
/* re-apply the deviations and augments */
for (v = 0; v < mods->number; v++) {
lys_sub_module_apply_devs_augs((struct lys_module *)mods->set.g[v]);
}
/* free the sets */
ly_set_free(mods);
ly_set_free(disabled);
/* update the module-set-id */
ctx->models.module_set_id++;
return EXIT_SUCCESS;
}
API int
ly_ctx_remove_module(const struct lys_module *module,
void (*private_destructor)(const struct lys_node *node, void *priv))
{
struct ly_ctx *ctx; /* shortcut */
struct lys_module *mod = NULL;
struct ly_set *mods;
uint8_t j, imported;
int i, o;
unsigned int u;
if (!module) {
ly_errno = LY_EINVAL;
return EXIT_FAILURE;
}
mod = (struct lys_module *)module;
ctx = mod->ctx;
/* avoid removing internal modules ... */
for (i = 0; i < ctx->internal_module_count; i++) {
if (mod == ctx->models.list[i]) {
LOGERR(LY_EINVAL, "Internal module \"%s\" cannot be removed.", mod->name);
return EXIT_FAILURE;
}
}
/* ... and hide the module from the further processing of the context modules list */
for (i = ctx->internal_module_count; i < ctx->models.used; i++) {
if (mod == ctx->models.list[i]) {
ctx->models.list[i] = NULL;
break;
}
}
/* get the complete list of modules to remove because of dependencies,
* we are going also to remove all the imported (not implemented) modules
* that are not used in any other module */
mods = ly_set_new();
ly_set_add(mods, mod, 0);
checkdependency:
for (i = ctx->internal_module_count; i < ctx->models.used; i++) {
mod = ctx->models.list[i]; /* shortcut */
if (!mod) {
/* skip modules already selected for removing */
continue;
}
/* check depndency of imported modules */
for (j = 0; j < mod->imp_size; j++) {
for (u = 0; u < mods->number; u++) {
if (mod->imp[j].module == mods->set.g[u]) {
/* module is importing some module to remove, so it must be also removed */
ly_set_add(mods, mod, 0);
ctx->models.list[i] = NULL;
/* we have to start again because some of the already checked modules can
* depend on the one we have just decided to remove */
goto checkdependency;
}
}
}
/* check if the imported module is used in any module supposed to be kept */
if (!mod->implemented) {
imported = 0;
for (o = ctx->internal_module_count; o < ctx->models.used; o++) {
if (!ctx->models.list[o]) {
/* skip modules already selected for removing */
continue;
}
for (j = 0; j < ctx->models.list[o]->imp_size; j++) {
if (ctx->models.list[o]->imp[j].module == mod) {
/* the module is used in some other module not yet selected to be deleted */
imported = 1;
goto imported;
}
}
}
imported:
if (!imported) {
/* module is not implemented and neither imported by any other module in context
* which is supposed to be kept after this operation, so we are going to remove also
* this useless module */
ly_set_add(mods, mod, 0);
ctx->models.list[i] = NULL;
/* we have to start again, this time not because other module can depend on this one
* (we know that there is no such module), but because the module can import module
* that could became useless. If there are no imports, we can continue */
if (mod->imp_size) {
goto checkdependency;
}
}
}
}
/* consolidate the modules list */
for (i = o = ctx->internal_module_count; i < ctx->models.used; i++) {
if (ctx->models.list[o]) {
/* used cell */
o++;
} else {
/* the current output cell is empty, move here an input cell */
ctx->models.list[o] = ctx->models.list[i];
ctx->models.list[i] = NULL;
}
}
/* get the last used cell to get know the number of used */
while (!ctx->models.list[o]) {
o--;
}
ctx->models.used = o + 1;
ctx->models.module_set_id++;
/* maintain backlinks (start with internal ietf-yang-library which have leafs as possible targets of leafrefs */
ctx_modules_undo_backlinks(ctx, mods);
/* free the modules */
for (u = 0; u < mods->number; u++) {
/* remove the applied deviations and augments */
lys_sub_module_remove_devs_augs((struct lys_module *)mods->set.g[u]);
/* remove the module */
lys_free((struct lys_module *)mods->set.g[u], private_destructor, 1, 0);
}
ly_set_free(mods);
return EXIT_SUCCESS;
}
API void
ly_ctx_clean(struct ly_ctx *ctx, void (*private_destructor)(const struct lys_node *node, void *priv))
{
if (!ctx) {
return;
}
/* models list */
for (; ctx->models.used > ctx->internal_module_count; ctx->models.used--) {
/* remove the applied deviations and augments */
lys_sub_module_remove_devs_augs(ctx->models.list[ctx->models.used - 1]);
/* remove the module */
lys_free(ctx->models.list[ctx->models.used - 1], private_destructor, 1, 0);
/* clean it for safer future use */
ctx->models.list[ctx->models.used - 1] = NULL;
}
ctx->models.module_set_id++;
/* maintain backlinks (actually done only with ietf-yang-library since its leafs can be target of leafref) */
ctx_modules_undo_backlinks(ctx, NULL);
}
API const struct lys_module *
ly_ctx_get_module_iter(const struct ly_ctx *ctx, uint32_t *idx)
{
if (!ctx || !idx) {
ly_errno = LY_EINVAL;
return NULL;
}
for ( ; *idx < (unsigned)ctx->models.used; (*idx)++) {
if (!ctx->models.list[(*idx)]->disabled) {
return ctx->models.list[(*idx)++];
}
}
return NULL;
}
API const struct lys_module *
ly_ctx_get_disabled_module_iter(const struct ly_ctx *ctx, uint32_t *idx)
{
if (!ctx || !idx) {
ly_errno = LY_EINVAL;
return NULL;
}
for ( ; *idx < (unsigned)ctx->models.used; (*idx)++) {
if (ctx->models.list[(*idx)]->disabled) {
return ctx->models.list[(*idx)++];
}
}
return NULL;
}
static int
ylib_feature(struct lyd_node *parent, struct lys_module *cur_mod, int bis)
{
int i, j;
struct lyd_node *list;
/* module features */
for (i = 0; i < cur_mod->features_size; ++i) {
if (!(cur_mod->features[i].flags & LYS_FENABLED)) {
continue;
}
if (bis) {
if (!(list = lyd_new(parent, NULL, "feature")) || !lyd_new_leaf(list, NULL, "name", cur_mod->features[i].name)) {
return EXIT_FAILURE;
}
} else if (!lyd_new_leaf(parent, NULL, "feature", cur_mod->features[i].name)) {
return EXIT_FAILURE;
}
}
/* submodule features */
for (i = 0; i < cur_mod->inc_size && cur_mod->inc[i].submodule; ++i) {
for (j = 0; j < cur_mod->inc[i].submodule->features_size; ++j) {
if (!(cur_mod->inc[i].submodule->features[j].flags & LYS_FENABLED)) {
continue;
}
if (bis) {
if (!(list = lyd_new(parent, NULL, "feature"))
|| !lyd_new_leaf(list, NULL, "name", cur_mod->inc[i].submodule->features[j].name)) {
return EXIT_FAILURE;
}
} else if (!lyd_new_leaf(parent, NULL, "feature", cur_mod->inc[i].submodule->features[j].name)) {
return EXIT_FAILURE;
}
}
}
return EXIT_SUCCESS;
}
static int
ylib_deviation(struct lyd_node *parent, struct lys_module *cur_mod, int bis)
{
uint32_t i = 0, j;
const struct lys_module *mod;
struct lyd_node *cont;
const char *ptr;
if (cur_mod->deviated) {
while ((mod = ly_ctx_get_module_iter(cur_mod->ctx, &i))) {
if (mod == cur_mod) {
continue;
}
for (j = 0; j < mod->deviation_size; ++j) {
ptr = strstr(mod->deviation[j].target_name, cur_mod->name);
if (ptr && ptr[strlen(cur_mod->name)] == ':') {
cont = lyd_new(parent, NULL, "deviation");
if (!cont) {
return EXIT_FAILURE;
}
if (bis) {
if (!lyd_new_leaf(cont, NULL, "module", mod->name)) {
return EXIT_FAILURE;
}
} else {
if (!lyd_new_leaf(cont, NULL, "name", mod->name)) {
return EXIT_FAILURE;
}
if (!lyd_new_leaf(cont, NULL, "revision", (mod->rev_size ? mod->rev[0].date : ""))) {
return EXIT_FAILURE;
}
}
break;
}
}
}
}
return EXIT_SUCCESS;
}
static int
ylib_submodules(struct lyd_node *parent, struct lys_module *cur_mod, int bis)
{
int i;
char *str;
struct lyd_node *item;
for (i = 0; i < cur_mod->inc_size && cur_mod->inc[i].submodule; ++i) {
item = lyd_new(parent, NULL, "submodule");
if (!item) {
return EXIT_FAILURE;
}
if (!lyd_new_leaf(item, NULL, "name", cur_mod->inc[i].submodule->name)) {
return EXIT_FAILURE;
}
if ((!bis || cur_mod->inc[i].submodule->rev_size)
&& !lyd_new_leaf(item, NULL, "revision",
(cur_mod->inc[i].submodule->rev_size ? cur_mod->inc[i].submodule->rev[0].date : ""))) {
return EXIT_FAILURE;
}
if (cur_mod->inc[i].submodule->filepath) {
if (asprintf(&str, "file://%s", cur_mod->inc[i].submodule->filepath) == -1) {
LOGMEM;
return EXIT_FAILURE;
} else if (!lyd_new_leaf(item, NULL, bis ? "location" : "schema", str)) {
free(str);
return EXIT_FAILURE;
}
free(str);
}
}
return EXIT_SUCCESS;
}
API struct lyd_node *
ly_ctx_info(struct ly_ctx *ctx)
{
int i, bis = 0;
char id[8];
char *str;
const struct lys_module *mod;
struct lyd_node *root, *root_bis = NULL, *cont = NULL, *set_bis = NULL;
if (!ctx) {
ly_errno = LY_EINVAL;
return NULL;
}
mod = ly_ctx_get_module(ctx, "ietf-yang-library", NULL, 1);
if (!mod || !mod->data) {
LOGERR(LY_EINVAL, "ietf-yang-library is not implemented.");
return NULL;
}
if (mod->rev && !strcmp(mod->rev[0].date, "2016-04-09")) {
bis = 0;
} else if (mod->rev && !strcmp(mod->rev[0].date, IETF_YANG_LIB_REV)) {
bis = 1;
} else {
LOGERR(LY_EINVAL, "Incompatible ietf-yang-library version in context.");
return NULL;
}
root = lyd_new(NULL, mod, "modules-state");
if (!root) {
return NULL;
}
if (bis) {
if (!(root_bis = lyd_new(NULL, mod, "yang-library")) || !(set_bis = lyd_new(root_bis, NULL, "module-set"))) {
goto error;
}
if (!lyd_new_leaf(set_bis, NULL, "name", "complete")) {
goto error;
}
sprintf(id, "%u", ctx->models.module_set_id);
if (!lyd_new_leaf(set_bis, NULL, "checksum", id)) {
goto error;
}
}
for (i = 0; i < ctx->models.used; ++i) {
if (ctx->models.list[i]->disabled) {
/* skip the disabled modules */
continue;
}
/*
* deprecated legacy
*/
cont = lyd_new(root, NULL, "module");
if (!cont) {
goto error;
}
/* name */
if (!lyd_new_leaf(cont, NULL, "name", ctx->models.list[i]->name)) {
goto error;
}
/* revision */
if (!lyd_new_leaf(cont, NULL, "revision", (ctx->models.list[i]->rev_size ? ctx->models.list[i]->rev[0].date : ""))) {
goto error;
}
/* schema */
if (ctx->models.list[i]->filepath) {
if (asprintf(&str, "file://%s", ctx->models.list[i]->filepath) == -1) {
LOGMEM;
goto error;
}
if (!lyd_new_leaf(cont, NULL, "schema", str)) {
free(str);
goto error;
}
free(str);
}
/* namespace */
if (!lyd_new_leaf(cont, NULL, "namespace", ctx->models.list[i]->ns)) {
goto error;
}
/* feature leaf-list */
if (ylib_feature(cont, ctx->models.list[i], 0)) {
goto error;
}
/* deviation list */
if (ylib_deviation(cont, ctx->models.list[i], 0)) {
goto error;
}
/* conformance-type */
if (!lyd_new_leaf(cont, NULL, "conformance-type", ctx->models.list[i]->implemented ? "implement" : "import")) {
goto error;
}
/* submodule list */
if (ylib_submodules(cont, ctx->models.list[i], 0)) {
goto error;
}
/*
* current revision
*/
if (bis) {
if (ctx->models.list[i]->implemented) {
if (!(cont = lyd_new(set_bis, NULL, "module"))) {
goto error;
}
} else {
if (!(cont = lyd_new(set_bis, NULL, "import-only-module"))) {
goto error;
}
}
/* name */
if (!lyd_new_leaf(cont, NULL, "name", ctx->models.list[i]->name)) {
goto error;
}
/* revision */
if ((!ctx->models.list[i]->implemented || ctx->models.list[i]->rev_size)
&& !lyd_new_leaf(cont, NULL, "revision", ctx->models.list[i]->rev[0].date)) {
goto error;
}
/* namespace */
if (!lyd_new_leaf(cont, NULL, "namespace", ctx->models.list[i]->ns)) {
goto error;
}
/* location */
if (ctx->models.list[i]->filepath) {
if (asprintf(&str, "file://%s", ctx->models.list[i]->filepath) == -1) {
LOGMEM;
goto error;
}
if (!lyd_new_leaf(cont, NULL, "location", str)) {
free(str);
goto error;
}
free(str);
}
/* submodule list */
if (ylib_submodules(cont, ctx->models.list[i], 1)) {
goto error;
}
if (ctx->models.list[i]->implemented) {
/* feature list */
if (ylib_feature(cont, ctx->models.list[i], 1)) {
goto error;
}
/* deviation */
if (ylib_deviation(cont, ctx->models.list[i], 1)) {
goto error;
}
}
}
}
sprintf(id, "%u", ctx->models.module_set_id);
if (!lyd_new_leaf(root, NULL, "module-set-id", id)) {
goto error;
}
if (bis && !lyd_new_leaf(root_bis, NULL, "checksum", id)) {
goto error;
}
if (root_bis) {
if (lyd_insert_sibling(&root_bis, root)) {
goto error;
}
root = root_bis;
root_bis = 0;
}
if (lyd_validate(&root, LYD_OPT_NOSIBLINGS, NULL)) {
goto error;
}
return root;
error:
lyd_free_withsiblings(root);
lyd_free_withsiblings(root_bis);
return NULL;
}
API const struct lys_node *
ly_ctx_get_node(struct ly_ctx *ctx, const struct lys_node *start, const char *nodeid, int output)
{
const struct lys_node *node;
if ((!ctx && !start) || !nodeid || ((nodeid[0] != '/') && !start)) {
ly_errno = LY_EINVAL;
return NULL;
}
if (!ctx) {
ctx = start->module->ctx;
}
/* sets error and everything */
node = resolve_json_nodeid(nodeid, ctx, start, output);
return node;
}