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/**
* @file tree_internal.h
* @author Radek Krejci <rkrejci@cesnet.cz>
* @brief libyang internal functions for manipulating with the data model and
* data trees.
*
* 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
*/
#ifndef LY_TREE_INTERNAL_H_
#define LY_TREE_INTERNAL_H_
#include "libyang.h"
#include "tree_schema.h"
#include "tree_data.h"
#include "resolve.h"
/* this is used to distinguish lyxml_elem * from a YANG temporary parsing structure, the first byte is compared */
#define LY_YANG_STRUCTURE_FLAG 0x80
/**
* @brief YANG namespace
*/
#define LY_NSYANG "urn:ietf:params:xml:ns:yang:1"
/**
* @brief YIN namespace
*/
#define LY_NSYIN "urn:ietf:params:xml:ns:yang:yin:1"
/**
* @brief NETCONF namespace
*/
#define LY_NSNC "urn:ietf:params:xml:ns:netconf:base:1.0"
/**
* @brief NACM namespace
*/
#define LY_NSNACM "urn:ietf:params:xml:ns:yang:ietf-netconf-acm"
/**
* @brief internal parser flag for actions and inline notifications
*/
#define LYD_OPT_ACT_NOTIF 0x100
/**
* @brief Internal list of built-in types
*/
extern struct lys_tpdf *ly_types[LY_DATA_TYPE_COUNT];
/**
* @brief Internal structure for data node sorting.
*/
struct lyd_node_pos {
struct lyd_node *node;
uint32_t pos;
};
/**
* Macros to work with ::lyd_node#when_status
* +--- bit 1 - some when-stmt connected with the node (resolve_applies_when() is true)
* |+-- bit 2 - when-stmt's condition is resolved and it is true
* ||+- bit 3 - when-stmt's condition is resolved and it is false
* XXX
*
* bit 1 is set when the node is created
* if none of bits 2 and 3 is set, the when condition is not yet resolved
*/
#define LYD_WHEN 0x04
#define LYD_WHEN_TRUE 0x02
#define LYD_WHEN_FALSE 0x01
#define LYD_WHEN_DONE(status) (!((status) & LYD_WHEN) || ((status) & (LYD_WHEN_TRUE | LYD_WHEN_FALSE)))
/**
* @brief Type flag for an unresolved type in a grouping.
*/
#define LYTYPE_GRP 0x80
#ifdef LY_ENABLED_CACHE
/**
* @brief Minimum number of children for the parent to create a hash table for them.
*/
# define LY_CACHE_HT_MIN_CHILDREN 4
int lyd_hash(struct lyd_node *node);
void lyd_insert_hash(struct lyd_node *node);
void lyd_unlink_hash(struct lyd_node *node, struct lyd_node *orig_parent);
#endif
/**
* @brief Create submodule structure by reading data from memory.
*
* @param[in] module Schema tree where to connect the submodule, belongs-to value must match.
* @param[in] data String containing the submodule specification in the given \p format.
* @param[in] format Format of the data to read.
* @param[in] unres list of unresolved items
* @return Created submodule structure or NULL in case of error.
*/
struct lys_submodule *lys_sub_parse_mem(struct lys_module *module, const char *data, LYS_INFORMAT format,
struct unres_schema *unres);
/**
* @brief Create submodule structure by reading data from file descriptor.
*
* \note Current implementation supports only reading data from standard (disk) file, not from sockets, pipes, etc.
*
* @param[in] module Schema tree where to connect the submodule, belongs-to value must match.
* @param[in] fd File descriptor of a regular file (e.g. sockets are not supported) containing the submodule
* specification in the given \p format.
* @param[in] format Format of the data to read.
* @param[in] unres list of unresolved items
* @return Created submodule structure or NULL in case of error.
*/
struct lys_submodule *lys_sub_parse_fd(struct lys_module *module, int fd, LYS_INFORMAT format, struct unres_schema *unres);
/**
* @brief Free the submodule structure
*
* @param[in] submodule The structure to free. Do not use the pointer after calling this function.
* @param[in] private_destructor Optional destructor function for private objects assigned
* to the nodes via lys_set_private(). If NULL, the private objects are not freed by libyang.
*/
void lys_submodule_free(struct lys_submodule *submodule, void (*private_destructor)(const struct lys_node *node, void *priv));
/**
* @brief Add child schema tree node at the end of the parent's child list.
*
* If the child is connected somewhere (has a parent), it is completely
* unlinked and none of the following conditions applies.
* If the child has prev sibling(s), they are ignored (child is added at the
* end of the child list).
* If the child has next sibling(s), all of them are connected with the parent.
*
* @param[in] parent Parent node where the \p child will be added.
* @param[in] module Module where the \p child will be added if the \p parent
* parameter is NULL (case of top-level elements). The parameter does not change
* the module of the \p child element. If the \p parent parameter is present,
* the \p module parameter is ignored.
* @param[in] child The schema tree node to be added.
* @return 0 on success, nonzero else
*/
int lys_node_addchild(struct lys_node *parent, struct lys_module *module, struct lys_node *child);
/**
* @brief Find a valid grouping definition relative to a node.
*
* Valid definition means a sibling of \p start or a sibling of any of \p start 's parents.
*
* @param[in] name Name of the searched grouping.
* @param[in] start Definition must be valid (visible) for this node.
* @return Matching valid grouping or NULL.
*/
struct lys_node_grp *lys_find_grouping_up(const char *name, struct lys_node *start);
/**
* @brief Check that the \p node being connected into the \p parent has a unique name (identifier).
*
* Function is performed also as part of lys_node_addchild().
*
* @param[in] node The schema tree node to be checked.
* @param[in] parent Parent node where the \p child is supposed to be added.
* @param[in] module Module where the \p child is supposed to be added if the \p parent
* parameter is NULL (case of top-level elements). The parameter does not change
* the module of the \p child element. If the \p parent parameter is present,
* the \p module parameter is ignored.
* @return 0 on success, nonzero else
*/
int lys_check_id(struct lys_node *node, struct lys_node *parent, struct lys_module *module);
/**
* @brief Get know if the node contains must or when with XPath expression
*
* @param[in] node Node to examine.
* @return 1 if contains, 0 otherwise
*/
int lys_has_xpath(const struct lys_node *node);
/**
* @brief Learn if \p type is defined in the local module or from an import.
*
* @param[in] type Type to examine.
* @return non-zero if local, 0 if from an import.
*/
int lys_type_is_local(const struct lys_type *type);
/**
* @brief Create a copy of the specified schema tree \p node
*
* @param[in] module Target module for the duplicated node.
* @param[in] parent Schema tree node where the node is being connected, NULL in case of top level \p node.
* @param[in] node Schema tree node to be duplicated.
* @param[in] unres list of unresolved items
* @param[in] shallow Whether to copy children and connect to parent/module too.
* @return Created copy of the provided schema \p node.
*/
struct lys_node *lys_node_dup(struct lys_module *module, struct lys_node *parent, const struct lys_node *node,
struct unres_schema *unres, int shallow);
/**
* @brief duplicate the list of extension instances.
*
* @param[in] ctx Context to store errors in.
* @param[in] mod Module where we are
* @param[in] orig list of the extension instances to duplicate, the size of the array must correspond with \p size
* @param[in] size number of items in \p old array to duplicate
* @param[in] parent Parent structure of the new extension instances list
* @param[in] parent_type Type of the provide \p parent *
* @param[in,out] new Address where to store the created list of duplicated extension instances
* @param[in] shallow Whether to copy children and connect to parent/module too.
* @param[in] unres list of unresolved items
*
*/
int lys_ext_dup(struct ly_ctx *ctx, struct lys_module *mod, struct lys_ext_instance **orig, uint8_t size, void *parent,
LYEXT_PAR parent_type, struct lys_ext_instance ***new, int shallow, struct unres_schema *unres);
/**
* @brief Iterate over the specified type of the extension instances
*
* @param[in] ext Array of extensions to explore
* @param[in] ext_size Size of the provided \p ext array
* @param[in] start Index in the \p ext array where to start searching (first call with 0, the consequent calls with
* the returned index increased by 1, unless the returned index is -1)
* @param[in] substmt Type of the extension (its belongins to the specific substatement) to iterate, use
* #LYEXT_SUBSTMT_ALL to go through all the extensions in the array
* @result index in the ext, -1 if not present
*/
int lys_ext_iter(struct lys_ext_instance **ext, uint8_t ext_size, uint8_t start, LYEXT_SUBSTMT substmt);
/**
* @brief free the array of the extension instances
*/
void lys_extension_instances_free(struct ly_ctx *ctx, struct lys_ext_instance **e, unsigned int size,
void (*private_destructor)(const struct lys_node *node, void *priv));
/**
* @brief Switch two same schema nodes. \p src must be a shallow copy
* of \p dst.
*
* @param[in] dst Destination node that will be replaced with \p src.
* @param[in] src Source node that will replace \p dst.
*/
void lys_node_switch(struct lys_node *dst, struct lys_node *src);
/**
* @brief Add pointer to \p leafref to \p leafref_target children so that it knows there
* are some leafrefs referring it.
*
* @param[in] leafref_target Leaf that is \p leafref's target.
* @param[in] leafref Leaf or leaflist of type #LY_TYPE_LEAFREF referring \p leafref_target.
* @return 0 on success, -1 on error.
*/
int lys_leaf_add_leafref_target(struct lys_node_leaf *leafref_target, struct lys_node *leafref);
/**
* @brief Free a schema when condition
*
* @param[in] libyang context where the schema of the ondition is used.
* @param[in] w When structure to free.
* @param[in] private_destructor Destructor for priv member in extension instances
*/
void lys_when_free(struct ly_ctx *ctx, struct lys_when *w,
void (*private_destructor)(const struct lys_node *node, void *priv));
/**
* @brief Free the schema tree restriction (must, ...) structure content
*
* @param[in] ctx libyang context where the schema of the restriction is used.
* @param[in] restr The restriction structure to free. The function actually frees only
* the content of the structure, so after using this function, caller is supposed to
* use free(restr). It is done to free the content of structures being allocated as
* part of array, in that case the free() is used on the whole array.
* @param[in] private_destructor Destructor for priv member in extension instances
*/
void lys_restr_free(struct ly_ctx *ctx, struct lys_restr *restr,
void (*private_destructor)(const struct lys_node *node, void *priv));
/**
* @brief Free the schema tree type structure content
*
* @param[in] ctx libyang context where the schema of the type is used.
* @param[in] restr The type structure to free. The function actually frees only
* the content of the structure, so after using this function, caller is supposed to
* use free(type). It is done to free the content of structures being allocated as
* part of array, in that case the free() is used on the whole array.
* @param[in] private_destructor Destructor for priv member in extension instances
*/
void lys_type_free(struct ly_ctx *ctx, struct lys_type *type,
void (*private_destructor)(const struct lys_node *node, void *priv));
/**
* @brief Unlink the schema node from the tree.
*
* @param[in] node Schema tree node to unlink.
*/
void lys_node_unlink(struct lys_node *node);
/**
* @brief Free the schema node structure, includes unlinking it from the tree
*
* @param[in] node Schema tree node to free. Do not use the pointer after calling this function.
* @param[in] private_destructor Optional destructor function for private objects assigned
* to the nodes via lys_set_private(). If NULL, the private objects are not freed by libyang.
* @param[in] shallow Whether to do a shallow free only (on a shallow copy of a node).
*/
void lys_node_free(struct lys_node *node, void (*private_destructor)(const struct lys_node *node, void *priv), int shallow);
/**
* @brief Free (and unlink it from the context) the specified schema.
*
* It is dangerous to call this function on schemas already placed into the context's
* list of modules - there can be many references from other modules and data instances.
*
* @param[in] module Data model to free.
* @param[in] private_destructor Optional destructor function for private objects assigned
* to the nodes via lys_set_private(). If NULL, the private objects are not freed by libyang.
* @param[in] free_subs Whether to free included submodules.
* @param[in] remove_from_ctx Whether to remove this model from context. Always use 1 except
* when removing all the models (in ly_ctx_destroy()).
*/
void lys_free(struct lys_module *module, void (*private_destructor)(const struct lys_node *node, void *priv),
int free_subs, int remove_from_ctx);
/**
* @brief Create a data container knowing it's schema node.
*
* @param[in] parent Data parent of the new node.
* @param[in] schema Schema node of the new node.
* @param[in] dflt Set dflt flag in the created data nodes
* @return New node, NULL on error.
*/
struct lyd_node *_lyd_new(struct lyd_node *parent, const struct lys_node *schema, int dflt);
/**
* @brief Create a dummy node for XPath evaluation. After done using, it should be removed.
*
* The function must be used very carefully:
* - there must not be a list node to create
*
* @param[in] data Any data node of the tree where the dummy node will be created
* @param[in] parent To optimize searching in data tree (and to avoid issues with lists), caller can specify a
* parent node that exists in the data tree.
* @param[in] schema Schema node of the dummy node to create, must be of nodetype that
* appears also in data tree.
* @param[in] value Optional value to be set in the dummy node
* @param[in] dflt Set dflt flag in the created data nodes
*
* @return The first created node needed for the dummy node in the given tree.
*/
struct lyd_node *lyd_new_dummy(struct lyd_node *data, struct lyd_node *parent, const struct lys_node *schema,
const char *value, int dflt);
/**
* @brief Find the parent node of an attribute.
*
* @param[in] root Root element of the data tree with the attribute.
* @param[in] attr Attribute to find.
*
* @return Parent of \p attr, NULL if not found.
*/
const struct lyd_node *lyd_attr_parent(const struct lyd_node *root, struct lyd_attr *attr);
/**
* @brief Internal version of lyd_unlink().
*
* @param[in] node Node to unlink.
* @param[in] permanent 0 - the node will be linked back,
* 1 - the node is premanently unlinked,
* 2 - the node is being freed.
*
* @return EXIT_SUCCESS on success, EXIT_FAILURE on error.
*/
int lyd_unlink_internal(struct lyd_node *node, int permanent);
/**
* @brief Internal version of lyd_insert() and lyd_insert_sibling().
*
* @param[in] invalidate Whether to invalidate any nodes. Set 0 only if linking back some temporarily internally unlinked nodes.
*/
int lyd_insert_common(struct lyd_node *parent, struct lyd_node **sibling, struct lyd_node *node, int invalidate);
/**
* @brief Internal version of lyd_insert_before() and lyd_insert_after().
*
* @param[in] invalidate Whether to invalidate any nodes. Set 0 only if linking back some temporarily internally unlinked nodes.
*/
int lyd_insert_nextto(struct lyd_node *sibling, struct lyd_node *node, int before, int invalidate);
/**
* @brief Find a specific sibling. Does not log.
*
* Since \p mod_name is mandatory, augments are handled.
*
* @param[in] siblings Siblings to consider. They are first adjusted to
* point to the first sibling.
* @param[in] mod_name Module name, mandatory.
* @param[in] mod_name_len Module name length.
* @param[in] name Node name, mandatory.
* @param[in] nam_len Node name length.
* @param[in] type ORed desired type of the node. 0 means any type.
* Does not return groupings, uses, and augments (but can return augment nodes).
* @param[out] ret Pointer to the node of the desired type. Can be NULL.
*
* @return EXIT_SUCCESS on success, EXIT_FAILURE on forward reference.
*/
int lys_get_sibling(const struct lys_node *siblings, const char *mod_name, int mod_name_len, const char *name,
int nam_len, LYS_NODE type, const struct lys_node **ret);
/**
* @brief Find a specific node that can only appear in the data. Does not log.
*
* @param[in] mod Main module with the node. Must be set if \p parent == NULL (top-level node).
* @param[in] parent Parent of the node. Must be set if \p mod == NULL (nested node).
* @param[in] name Node name.
* @param[in] nam_len Node \p name length.
* @param[in] type ORed desired type of the node. 0 means any (data node) type.
* @param[out] ret Pointer to the node of the desired type. Can be NULL.
*
* @return EXIT_SUCCESS on success, EXIT_FAILURE on fail.
*/
int lys_getnext_data(const struct lys_module *mod, const struct lys_node *parent, const char *name, int nam_len,
LYS_NODE type, const struct lys_node **ret);
int lyd_get_unique_default(const char* unique_expr, struct lyd_node *list, const char **dflt);
int lyd_build_relative_data_path(const struct lys_module *module, const struct lyd_node *node, const char *schema_id,
char *buf);
void lyd_free_value(lyd_val value, LY_DATA_TYPE value_type, uint8_t value_flags, struct lys_type *type);
int lyd_list_equal(struct lyd_node *node1, struct lyd_node *node2, int with_defaults);
/**
* @brief Check for (validate) mandatory nodes of a data tree. Checks recursively whole data tree. Requires all when
* statement to be solved.
*
* @param[in] root Data tree to validate.
* @param[in] ctx libyang context (for the case when the data tree is empty - i.e. root == NULL).
* @param[in] options Standard @ref parseroptions.
* @return EXIT_SUCCESS or EXIT_FAILURE.
*/
int lyd_check_mandatory_tree(struct lyd_node *root, struct ly_ctx *ctx, int options);
/**
* @brief Check if the provided node is inside a grouping.
*
* @param[in] node Schema node to check.
* @return 0 as false, 1 as true
*/
int lys_ingrouping(const struct lys_node *node);
/**
* @brief Add default values, \p resolve unres, and finally
* remove any redundant default values based on \p options.
*
* @param[in] root Data tree root. With empty data tree, new default nodes can be created so the root pointer
* will contain/return the newly created data tree.
* @param[in] options Options for the inserting data to the target data tree options, see @ref parseroptions.
* @param[in] ctx Optional parameter. If provided, default nodes from all modules in the context will be added.
* If NULL, only the modules explicitly mentioned in data tree are taken into account.
* @param[in] data_tree Additional data tree to be traversed when evaluating when or must expressions in \p root
* tree.
* @param[in] act_notif Action/notification itself in case \p root is actually an action/notification.
* @param[in] unres Valid unres structure, on function successful exit they are all resolved.
* @return 0 on success, nonzero on failure.
*/
int lyd_defaults_add_unres(struct lyd_node **root, int options, struct ly_ctx *ctx, const struct lyd_node *data_tree,
struct lyd_node *act_notif, struct unres_data *unres);
void lys_enable_deviations(struct lys_module *module);
void lys_disable_deviations(struct lys_module *module);
void lys_sub_module_remove_devs_augs(struct lys_module *module);
void lys_sub_module_apply_devs_augs(struct lys_module *module);
int apply_aug(struct lys_node_augment *augment, struct unres_schema *unres);
void lys_submodule_module_data_free(struct lys_submodule *submodule);
int lys_copy_union_leafrefs(struct lys_module *mod, struct lys_node *parent, struct lys_type *type,
struct lys_type *prev_new, struct unres_schema *unres);
const struct lys_module *lys_parse_fd_(struct ly_ctx *ctx, int fd, LYS_INFORMAT format, const char *revision, int implement);
const struct lys_module *lys_parse_mem_(struct ly_ctx *ctx, const char *data, LYS_INFORMAT format, const char *revision,
int internal, int implement);
/**
* @brief Get next augment from \p mod augmenting \p aug_target
*/
struct lys_node_augment *lys_getnext_target_aug(struct lys_node_augment *last, const struct lys_module *mod,
const struct lys_node *aug_target);
LY_STMT lys_snode2stmt(LYS_NODE nodetype);
struct lys_node ** lys_child(const struct lys_node *node, LYS_NODE nodetype);
#endif /* LY_TREE_INTERNAL_H_ */