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gerrit.cesnet.cz / github / CESNET / libyang / 45c4b1a19f4ab9d97d2522648dbb48b583ca4c33 / . / src / tree_data_helpers.c
blob: f26749baf0e6ec2f66a3dc5d55946e5192a0ef19 [file] [log] [blame]
/**
* @file tree_data_helpers.c
* @author Radek Krejci <rkrejci@cesnet.cz>
* @brief Parsing and validation helper functions for data trees
*
* Copyright (c) 2015 - 2018 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 /* asprintf, strdup */
#include <sys/cdefs.h>
#include <assert.h>
#include <ctype.h>
#include <stdint.h>
#include <stdlib.h>
#include <string.h>
#include <time.h>
#include "common.h"
#include "compat.h"
#include "context.h"
#include "dict.h"
#include "hash_table.h"
#include "log.h"
#include "lyb.h"
#include "parser_data.h"
#include "printer_data.h"
#include "set.h"
#include "tree.h"
#include "tree_data.h"
#include "tree_data_internal.h"
#include "tree_edit.h"
#include "tree_schema.h"
#include "tree_schema_internal.h"
#include "validation.h"
#include "xml.h"
/**
* @brief Find an entry in duplicate instance cache for an instance. Create it if it does not exist.
*
* @param[in] first_inst Instance of the cache entry.
* @param[in,out] dup_inst_cache Duplicate instance cache.
* @return Instance cache entry.
*/
static struct lyd_dup_inst *
lyd_dup_inst_get(const struct lyd_node *first_inst, struct lyd_dup_inst **dup_inst_cache)
{
struct lyd_dup_inst *item;
LY_ARRAY_COUNT_TYPE u;
LY_ARRAY_FOR(*dup_inst_cache, u) {
if ((*dup_inst_cache)[u].inst_set->dnodes[0] == first_inst) {
return &(*dup_inst_cache)[u];
}
}
/* it was not added yet, add it now */
LY_ARRAY_NEW_RET(LYD_CTX(first_inst), *dup_inst_cache, item, NULL);
return item;
}
LY_ERR
lyd_dup_inst_next(struct lyd_node **inst, const struct lyd_node *siblings, struct lyd_dup_inst **dup_inst_cache)
{
struct lyd_dup_inst *dup_inst;
if (!*inst || !lysc_is_dup_inst_list((*inst)->schema)) {
/* no match or not dup-inst list, inst is unchanged */
return LY_SUCCESS;
}
/* there can be more exact same instances and we must make sure we do not match a single node more times */
dup_inst = lyd_dup_inst_get(*inst, dup_inst_cache);
LY_CHECK_ERR_RET(!dup_inst, LOGMEM(LYD_CTX(siblings)), LY_EMEM);
if (!dup_inst->used) {
/* we did not cache these instances yet, do so */
lyd_find_sibling_dup_inst_set(siblings, *inst, &dup_inst->inst_set);
assert(dup_inst->inst_set->count && (dup_inst->inst_set->dnodes[0] == *inst));
}
if (dup_inst->used == dup_inst->inst_set->count) {
/* we have used all the instances */
*inst = NULL;
} else {
assert(dup_inst->used < dup_inst->inst_set->count);
/* use another instance */
*inst = dup_inst->inst_set->dnodes[dup_inst->used];
++dup_inst->used;
}
return LY_SUCCESS;
}
void
lyd_dup_inst_free(struct lyd_dup_inst *dup_inst)
{
LY_ARRAY_COUNT_TYPE u;
LY_ARRAY_FOR(dup_inst, u) {
ly_set_free(dup_inst[u].inst_set, NULL);
}
LY_ARRAY_FREE(dup_inst);
}
struct lyd_node *
lys_getnext_data(const struct lyd_node *last, const struct lyd_node *sibling, const struct lysc_node **slast,
const struct lysc_node *parent, const struct lysc_module *module)
{
const struct lysc_node *siter = NULL;
struct lyd_node *match = NULL;
assert(parent || module);
assert(!last || (slast && *slast));
if (slast) {
siter = *slast;
}
if (last && last->next && (last->next->schema == siter)) {
/* return next data instance */
return last->next;
}
/* find next schema node data instance */
while ((siter = lys_getnext(siter, parent, module, 0))) {
if (!lyd_find_sibling_val(sibling, siter, NULL, 0, &match)) {
break;
}
}
if (slast) {
*slast = siter;
}
return match;
}
struct lyd_node **
lyd_node_child_p(struct lyd_node *node)
{
assert(node);
if (!node->schema) {
return &((struct lyd_node_opaq *)node)->child;
} else {
switch (node->schema->nodetype) {
case LYS_CONTAINER:
case LYS_LIST:
case LYS_RPC:
case LYS_ACTION:
case LYS_NOTIF:
return &((struct lyd_node_inner *)node)->child;
default:
return NULL;
}
}
}
API struct lyd_node *
lyd_child_no_keys(const struct lyd_node *node)
{
struct lyd_node **children;
if (!node) {
return NULL;
}
if (!node->schema) {
/* opaq node */
return ((struct lyd_node_opaq *)node)->child;
}
children = lyd_node_child_p((struct lyd_node *)node);
if (children) {
struct lyd_node *child = *children;
while (child && child->schema && (child->schema->flags & LYS_KEY)) {
child = child->next;
}
return child;
} else {
return NULL;
}
}
API const struct lys_module *
lyd_owner_module(const struct lyd_node *node)
{
const struct lysc_node *schema;
const struct lyd_node_opaq *opaq;
if (!node) {
return NULL;
}
if (!node->schema) {
opaq = (struct lyd_node_opaq *)node;
switch (opaq->format) {
case LY_VALUE_XML:
return ly_ctx_get_module_implemented_ns(LYD_CTX(node), opaq->name.module_ns);
case LY_VALUE_JSON:
return ly_ctx_get_module_implemented(LYD_CTX(node), opaq->name.module_name);
default:
return NULL;
}
}
for (schema = node->schema; schema->parent; schema = schema->parent) {}
return schema->module;
}
const struct lys_module *
lyd_mod_next_module(struct lyd_node *tree, const struct lys_module *module, const struct ly_ctx *ctx, uint32_t *i,
struct lyd_node **first)
{
struct lyd_node *iter;
const struct lys_module *mod;
/* get the next module */
if (module) {
if (*i) {
mod = NULL;
} else {
mod = module;
++(*i);
}
} else {
do {
mod = ly_ctx_get_module_iter(ctx, i);
} while (mod && !mod->implemented);
}
/* find its data */
*first = NULL;
if (mod) {
LY_LIST_FOR(tree, iter) {
if (lyd_owner_module(iter) == mod) {
*first = iter;
break;
}
}
}
return mod;
}
const struct lys_module *
lyd_data_next_module(struct lyd_node **next, struct lyd_node **first)
{
const struct lys_module *mod;
if (!*next) {
/* all data traversed */
*first = NULL;
return NULL;
}
*first = *next;
/* prepare next */
mod = lyd_owner_module(*next);
LY_LIST_FOR(*next, *next) {
if (lyd_owner_module(*next) != mod) {
break;
}
}
return mod;
}
LY_ERR
lyd_parse_check_keys(struct lyd_node *node)
{
const struct lysc_node *skey = NULL;
const struct lyd_node *key;
assert(node->schema->nodetype == LYS_LIST);
key = lyd_child(node);
while ((skey = lys_getnext(skey, node->schema, NULL, 0)) && (skey->flags & LYS_KEY)) {
if (!key || (key->schema != skey)) {
LOGVAL(LYD_CTX(node), LY_VCODE_NOKEY, skey->name);
return LY_EVALID;
}
key = key->next;
}
return LY_SUCCESS;
}
void
lyd_parse_set_data_flags(struct lyd_node *node, struct ly_set *when_check, struct ly_set *exts_check, struct lyd_meta **meta,
uint32_t options)
{
struct lyd_meta *meta2, *prev_meta = NULL;
if (lysc_has_when(node->schema)) {
if (!(options & LYD_PARSE_ONLY)) {
/* remember we need to evaluate this node's when */
LY_CHECK_RET(ly_set_add(when_check, node, 1, NULL), );
}
}
LY_CHECK_RET(lysc_node_ext_tovalidate(exts_check, node), );
LY_LIST_FOR(*meta, meta2) {
if (!strcmp(meta2->name, "default") && !strcmp(meta2->annotation->module->name, "ietf-netconf-with-defaults") &&
meta2->value.boolean) {
/* node is default according to the metadata */
node->flags |= LYD_DEFAULT;
/* delete the metadata */
if (prev_meta) {
prev_meta->next = meta2->next;
} else {
*meta = (*meta)->next;
}
lyd_free_meta_single(meta2);
break;
}
prev_meta = meta2;
}
}
API const char *
lyd_value_get_canonical(const struct ly_ctx *ctx, const struct lyd_value *value)
{
LY_CHECK_ARG_RET(ctx, ctx, value, NULL);
return value->_canonical ? value->_canonical :
(const char *)value->realtype->plugin->print(ctx, value, LY_VALUE_CANON, NULL, NULL, NULL);
}
API LY_ERR
lyd_any_value_str(const struct lyd_node *any, char **value_str)
{
const struct lyd_node_any *a;
struct lyd_node *tree = NULL;
const char *str = NULL;
ly_bool dynamic = 0;
LY_ERR ret = LY_SUCCESS;
LY_CHECK_ARG_RET(NULL, any, value_str, LY_EINVAL);
LY_CHECK_ARG_RET(NULL, any->schema, any->schema->nodetype & LYS_ANYDATA, LY_EINVAL);
a = (struct lyd_node_any *)any;
*value_str = NULL;
if (!a->value.str) {
/* there is no value in the union */
return LY_SUCCESS;
}
switch (a->value_type) {
case LYD_ANYDATA_LYB:
/* parse into a data tree */
ret = lyd_parse_data_mem(LYD_CTX(any), a->value.mem, LYD_LYB, LYD_PARSE_ONLY, 0, &tree);
LY_CHECK_GOTO(ret, cleanup);
dynamic = 1;
break;
case LYD_ANYDATA_DATATREE:
tree = a->value.tree;
break;
case LYD_ANYDATA_STRING:
case LYD_ANYDATA_XML:
case LYD_ANYDATA_JSON:
/* simply use the string */
str = a->value.str;
break;
}
if (tree) {
/* print into a string */
ret = lyd_print_mem(value_str, tree, LYD_XML, LYD_PRINT_WITHSIBLINGS);
LY_CHECK_GOTO(ret, cleanup);
} else {
assert(str);
*value_str = strdup(str);
LY_CHECK_ERR_GOTO(!*value_str, LOGMEM(LYD_CTX(any)), cleanup);
}
/* success */
cleanup:
if (dynamic) {
lyd_free_all(tree);
}
return ret;
}
API LY_ERR
lyd_any_copy_value(struct lyd_node *trg, const union lyd_any_value *value, LYD_ANYDATA_VALUETYPE value_type)
{
struct lyd_node_any *t;
LY_CHECK_ARG_RET(NULL, trg, LY_EINVAL);
LY_CHECK_ARG_RET(NULL, trg->schema, trg->schema->nodetype & LYS_ANYDATA, LY_EINVAL);
t = (struct lyd_node_any *)trg;
/* free trg */
switch (t->value_type) {
case LYD_ANYDATA_DATATREE:
lyd_free_all(t->value.tree);
break;
case LYD_ANYDATA_STRING:
case LYD_ANYDATA_XML:
case LYD_ANYDATA_JSON:
lydict_remove(LYD_CTX(trg), t->value.str);
break;
case LYD_ANYDATA_LYB:
free(t->value.mem);
break;
}
t->value.str = NULL;
if (!value) {
/* only free value in this case */
return LY_SUCCESS;
}
/* copy src */
t->value_type = value_type;
switch (value_type) {
case LYD_ANYDATA_DATATREE:
if (value->tree) {
LY_CHECK_RET(lyd_dup_siblings(value->tree, NULL, LYD_DUP_RECURSIVE, &t->value.tree));
}
break;
case LYD_ANYDATA_STRING:
case LYD_ANYDATA_XML:
case LYD_ANYDATA_JSON:
if (value->str) {
LY_CHECK_RET(lydict_insert(LYD_CTX(trg), value->str, 0, &t->value.str));
}
break;
case LYD_ANYDATA_LYB:
if (value->mem) {
int len = lyd_lyb_data_length(value->mem);
LY_CHECK_RET(len == -1, LY_EINVAL);
t->value.mem = malloc(len);
LY_CHECK_ERR_RET(!t->value.mem, LOGMEM(LYD_CTX(trg)), LY_EMEM);
memcpy(t->value.mem, value->mem, len);
}
break;
}
return LY_SUCCESS;
}
void
lyd_del_move_root(struct lyd_node **root, const struct lyd_node *to_del, const struct lys_module *mod)
{
if (*root && (lyd_owner_module(*root) != mod)) {
/* there are no data of mod so this is simply the first top-level sibling */
mod = NULL;
}
if ((*root != to_del) || (*root)->parent) {
return;
}
*root = (*root)->next;
if (mod && *root && (lyd_owner_module(to_del) != lyd_owner_module(*root))) {
/* there are no more nodes from mod */
*root = lyd_first_sibling(*root);
}
}
void
ly_free_prefix_data(LY_VALUE_FORMAT format, void *prefix_data)
{
struct ly_set *ns_list;
struct lysc_prefix *prefixes;
uint32_t i;
LY_ARRAY_COUNT_TYPE u;
if (!prefix_data) {
return;
}
switch (format) {
case LY_VALUE_XML:
ns_list = prefix_data;
for (i = 0; i < ns_list->count; ++i) {
free(((struct lyxml_ns *)ns_list->objs[i])->prefix);
free(((struct lyxml_ns *)ns_list->objs[i])->uri);
}
ly_set_free(ns_list, free);
break;
case LY_VALUE_SCHEMA_RESOLVED:
prefixes = prefix_data;
LY_ARRAY_FOR(prefixes, u) {
free(prefixes[u].prefix);
}
LY_ARRAY_FREE(prefixes);
break;
case LY_VALUE_CANON:
case LY_VALUE_SCHEMA:
case LY_VALUE_JSON:
case LY_VALUE_LYB:
break;
}
}
LY_ERR
ly_dup_prefix_data(const struct ly_ctx *ctx, LY_VALUE_FORMAT format, const void *prefix_data,
void **prefix_data_p)
{
LY_ERR ret = LY_SUCCESS;
struct lyxml_ns *ns;
struct lysc_prefix *prefixes = NULL, *orig_pref;
struct ly_set *ns_list, *orig_ns;
uint32_t i;
LY_ARRAY_COUNT_TYPE u;
assert(!*prefix_data_p);
switch (format) {
case LY_VALUE_SCHEMA:
*prefix_data_p = (void *)prefix_data;
break;
case LY_VALUE_SCHEMA_RESOLVED:
/* copy all the value prefixes */
orig_pref = (struct lysc_prefix *)prefix_data;
LY_ARRAY_CREATE_GOTO(ctx, prefixes, LY_ARRAY_COUNT(orig_pref), ret, cleanup);
*prefix_data_p = prefixes;
LY_ARRAY_FOR(orig_pref, u) {
if (orig_pref[u].prefix) {
prefixes[u].prefix = strdup(orig_pref[u].prefix);
LY_CHECK_ERR_GOTO(!prefixes[u].prefix, LOGMEM(ctx); ret = LY_EMEM, cleanup);
}
prefixes[u].mod = orig_pref[u].mod;
LY_ARRAY_INCREMENT(prefixes);
}
break;
case LY_VALUE_XML:
/* copy all the namespaces */
LY_CHECK_GOTO(ret = ly_set_new(&ns_list), cleanup);
*prefix_data_p = ns_list;
orig_ns = (struct ly_set *)prefix_data;
for (i = 0; i < orig_ns->count; ++i) {
ns = calloc(1, sizeof *ns);
LY_CHECK_ERR_GOTO(!ns, LOGMEM(ctx); ret = LY_EMEM, cleanup);
LY_CHECK_GOTO(ret = ly_set_add(ns_list, ns, 1, NULL), cleanup);
if (((struct lyxml_ns *)orig_ns->objs[i])->prefix) {
ns->prefix = strdup(((struct lyxml_ns *)orig_ns->objs[i])->prefix);
LY_CHECK_ERR_GOTO(!ns->prefix, LOGMEM(ctx); ret = LY_EMEM, cleanup);
}
ns->uri = strdup(((struct lyxml_ns *)orig_ns->objs[i])->uri);
LY_CHECK_ERR_GOTO(!ns->uri, LOGMEM(ctx); ret = LY_EMEM, cleanup);
}
break;
case LY_VALUE_CANON:
case LY_VALUE_JSON:
case LY_VALUE_LYB:
assert(!prefix_data);
*prefix_data_p = NULL;
break;
}
cleanup:
if (ret) {
ly_free_prefix_data(format, *prefix_data_p);
*prefix_data_p = NULL;
}
return ret;
}
LY_ERR
ly_store_prefix_data(const struct ly_ctx *ctx, const void *value, size_t value_len, LY_VALUE_FORMAT format,
const void *prefix_data, LY_VALUE_FORMAT *format_p, void **prefix_data_p)
{
LY_ERR ret = LY_SUCCESS;
const struct lys_module *mod;
const struct lyxml_ns *ns;
struct lyxml_ns *new_ns;
struct ly_set *ns_list;
struct lysc_prefix *prefixes = NULL, *val_pref;
const char *value_iter, *value_next, *value_end;
uint32_t substr_len;
ly_bool is_prefix;
switch (format) {
case LY_VALUE_SCHEMA:
/* copy all referenced modules as prefix - module pairs */
if (!*prefix_data_p) {
/* new prefix data */
LY_ARRAY_CREATE_GOTO(ctx, prefixes, 0, ret, cleanup);
*format_p = LY_VALUE_SCHEMA_RESOLVED;
*prefix_data_p = prefixes;
} else {
/* reuse prefix data */
assert(*format_p == LY_VALUE_SCHEMA_RESOLVED);
prefixes = *prefix_data_p;
}
/* add all used prefixes */
value_end = value + value_len;
for (value_iter = value; value_iter; value_iter = value_next) {
LY_CHECK_GOTO(ret = ly_value_prefix_next(value_iter, value_end, &substr_len, &is_prefix, &value_next), cleanup);
if (is_prefix) {
/* we have a possible prefix. Do we already have the prefix? */
mod = ly_resolve_prefix(ctx, value_iter, substr_len, *format_p, *prefix_data_p);
if (!mod) {
mod = ly_resolve_prefix(ctx, value_iter, substr_len, format, prefix_data);
if (mod) {
assert(*format_p == LY_VALUE_SCHEMA_RESOLVED);
/* store a new prefix - module pair */
LY_ARRAY_NEW_GOTO(ctx, prefixes, val_pref, ret, cleanup);
*prefix_data_p = prefixes;
val_pref->prefix = strndup(value_iter, substr_len);
LY_CHECK_ERR_GOTO(!val_pref->prefix, LOGMEM(ctx); ret = LY_EMEM, cleanup);
val_pref->mod = mod;
} /* else it is not even defined */
} /* else the prefix is already present */
}
}
break;
case LY_VALUE_XML:
/* copy all referenced namespaces as prefix - namespace pairs */
if (!*prefix_data_p) {
/* new prefix data */
LY_CHECK_GOTO(ret = ly_set_new(&ns_list), cleanup);
*format_p = LY_VALUE_XML;
*prefix_data_p = ns_list;
} else {
/* reuse prefix data */
assert(*format_p == LY_VALUE_XML);
ns_list = *prefix_data_p;
}
/* add all used prefixes */
value_end = value + value_len;
for (value_iter = value; value_iter; value_iter = value_next) {
LY_CHECK_GOTO(ret = ly_value_prefix_next(value_iter, value_end, &substr_len, &is_prefix, &value_next), cleanup);
if (is_prefix) {
/* we have a possible prefix. Do we already have the prefix? */
ns = lyxml_ns_get(ns_list, value_iter, substr_len);
if (!ns) {
ns = lyxml_ns_get(prefix_data, value_iter, substr_len);
if (ns) {
/* store a new prefix - namespace pair */
new_ns = calloc(1, sizeof *new_ns);
LY_CHECK_ERR_GOTO(!new_ns, LOGMEM(ctx); ret = LY_EMEM, cleanup);
LY_CHECK_GOTO(ret = ly_set_add(ns_list, new_ns, 1, NULL), cleanup);
new_ns->prefix = strndup(value_iter, substr_len);
LY_CHECK_ERR_GOTO(!new_ns->prefix, LOGMEM(ctx); ret = LY_EMEM, cleanup);
new_ns->uri = strdup(ns->uri);
LY_CHECK_ERR_GOTO(!new_ns->uri, LOGMEM(ctx); ret = LY_EMEM, cleanup);
} /* else it is not even defined */
} /* else the prefix is already present */
}
}
break;
case LY_VALUE_CANON:
case LY_VALUE_SCHEMA_RESOLVED:
case LY_VALUE_JSON:
case LY_VALUE_LYB:
if (!*prefix_data_p) {
/* new prefix data - simply copy all the prefix data */
*format_p = format;
LY_CHECK_GOTO(ret = ly_dup_prefix_data(ctx, format, prefix_data, prefix_data_p), cleanup);
} /* else reuse prefix data - the prefix data are always the same, nothing to do */
break;
}
cleanup:
if (ret) {
ly_free_prefix_data(*format_p, *prefix_data_p);
*prefix_data_p = NULL;
}
return ret;
}
const char *
ly_format2str(LY_VALUE_FORMAT format)
{
switch (format) {
case LY_VALUE_CANON:
return "canonical";
case LY_VALUE_SCHEMA:
return "schema imports";
case LY_VALUE_SCHEMA_RESOLVED:
return "schema stored mapping";
case LY_VALUE_XML:
return "XML prefixes";
case LY_VALUE_JSON:
return "JSON module names";
case LY_VALUE_LYB:
return "LYB prefixes";
default:
break;
}
return NULL;
}
API LY_ERR
ly_time_str2time(const char *value, time_t *time, char **fractions_s)
{
struct tm tm = {0};
uint32_t i, frac_len;
const char *frac;
int64_t shift, shift_m;
time_t t;
LY_CHECK_ARG_RET(NULL, value, time, LY_EINVAL);
tm.tm_year = atoi(&value[0]) - 1900;
tm.tm_mon = atoi(&value[5]) - 1;
tm.tm_mday = atoi(&value[8]);
tm.tm_hour = atoi(&value[11]);
tm.tm_min = atoi(&value[14]);
tm.tm_sec = atoi(&value[17]);
t = timegm(&tm);
i = 19;
/* fractions of a second */
if (value[i] == '.') {
++i;
frac = &value[i];
for (frac_len = 0; isdigit(frac[frac_len]); ++frac_len) {}
i += frac_len;
/* skip trailing zeros */
for ( ; frac_len && (frac[frac_len - 1] == '0'); --frac_len) {}
if (!frac_len) {
/* only zeros, ignore */
frac = NULL;
}
} else {
frac = NULL;
}
/* apply offset */
if ((value[i] == 'Z') || (value[i] == 'z')) {
/* zero shift */
shift = 0;
} else {
shift = strtol(&value[i], NULL, 10);
shift = shift * 60 * 60; /* convert from hours to seconds */
shift_m = strtol(&value[i + 4], NULL, 10) * 60; /* includes conversion from minutes to seconds */
/* correct sign */
if (shift < 0) {
shift_m *= -1;
}
/* connect hours and minutes of the shift */
shift = shift + shift_m;
}
/* we have to shift to the opposite way to correct the time */
t -= shift;
*time = t;
if (fractions_s) {
if (frac) {
*fractions_s = strndup(frac, frac_len);
LY_CHECK_RET(!*fractions_s, LY_EMEM);
} else {
*fractions_s = NULL;
}
}
return LY_SUCCESS;
}
API LY_ERR
ly_time_time2str(time_t time, const char *fractions_s, char **str)
{
struct tm tm;
char zoneshift[7];
int32_t zonediff_h, zonediff_m;
LY_CHECK_ARG_RET(NULL, str, LY_EINVAL);
/* initialize the local timezone */
tzset();
/* convert */
if (!localtime_r(&time, &tm)) {
return LY_ESYS;
}
/* get timezone offset */
if (tm.tm_gmtoff == 0) {
/* time is Zulu (UTC) */
zonediff_h = 0;
zonediff_m = 0;
} else {
/* timezone offset */
zonediff_h = tm.tm_gmtoff / 60 / 60;
zonediff_m = tm.tm_gmtoff / 60 % 60;
}
sprintf(zoneshift, "%+03d:%02d", zonediff_h, zonediff_m);
/* print */
if (asprintf(str, "%04d-%02d-%02dT%02d:%02d:%02d%s%s%s",
tm.tm_year + 1900, tm.tm_mon + 1, tm.tm_mday, tm.tm_hour, tm.tm_min, tm.tm_sec,
fractions_s ? "." : "", fractions_s ? fractions_s : "", zoneshift) == -1) {
return LY_EMEM;
}
return LY_SUCCESS;
}
API LY_ERR
ly_time_str2ts(const char *value, struct timespec *ts)
{
LY_ERR rc;
char *fractions_s, frac_buf[10] = {'0'};
int frac_len;
LY_CHECK_ARG_RET(NULL, value, ts, LY_EINVAL);
rc = ly_time_str2time(value, &ts->tv_sec, &fractions_s);
LY_CHECK_RET(rc);
/* convert fractions of a second to nanoseconds */
if (fractions_s) {
frac_len = strlen(fractions_s);
memcpy(frac_buf, fractions_s, frac_len > 9 ? 9 : frac_len);
ts->tv_nsec = atol(frac_buf);
free(fractions_s);
} else {
ts->tv_nsec = 0;
}
return LY_SUCCESS;
}
API LY_ERR
ly_time_ts2str(const struct timespec *ts, char **str)
{
char frac_buf[10];
LY_CHECK_ARG_RET(NULL, ts, str, LY_EINVAL);
/* convert nanoseconds to fractions of a second */
if (ts->tv_nsec) {
sprintf(frac_buf, "%09ld", ts->tv_nsec);
}
return ly_time_time2str(ts->tv_sec, ts->tv_nsec ? frac_buf : NULL, str);
}