src/tree.h - github/CESNET/libyang - Gitiles

 /**
  * @file tree.h
  * @author Radek Krejci <rkrejci@cesnet.cz>
  * @brief libyang generic macros and functions to work with YANG schema or data trees.
  *
  * Copyright (c) 2019 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_H_
 #define LY_TREE_H_

 #include <inttypes.h>

 #include "tree_data.h"

 #ifdef __cplusplus
 extern "C" {
 #endif

 /**
  * @page howtoXPath XPath Addressing
  *
  * Internally, XPath evaluation is performed on __when__ and __must__ conditions in the schema. For that almost
  * a full [XPath 1.0](http://www.w3.org/TR/1999/REC-xpath-19991116/) evaluator was implemented.
  * In YANG models you can also find paths identifying __augment__ targets, __leafref__ targets, and trivial paths in
  * __choice default__ and __unique__ statements argument. The exact format of all those paths can be found in the
  * relevant RFCs. Further will only be discussed paths that are used directly in libyang API functions.
  *
  * XPath
  * =====
  *
  * Generally, any xpath argument expects an expression similar to _when_ or _must_ as the same evaluator is used. As for
  * the format of any prefixes, the standardized JSON ([RFC 7951](https://tools.ietf.org/html/rfc7951#section-6.11))
  * was used. Summarized, xpath follows these conventions:
  *   - full XPath can be used, but only data nodes (node sets) will always be returned,
  *   - as per the specification, prefixes are actually __module names__,
  *   - also in the specification, for _absolute_ paths, the first (leftmost) node _MUST_ have a prefix,
  *   - for _relative_ paths, you specify the __context node__, which then acts as a parent for the first node in the path,
  *   - nodes always inherit their module (prefix) from their __parent node__ so whenever a node is from a different
  *     module than its parent, it _MUST_ have a prefix,
  *   - nodes from the same module as their __parent__ _MUST NOT_ have a prefix,
  *   - note that non-data nodes/schema-only node (choice, case, uses, input, output) are skipped and _MUST_ not be
  *     included in the path.
  *
  * Functions List
  * --------------
  * - ::lyd_find_xpath()
  * - ::lys_find_xpath()
  *
  * Path
  * ====
  *
  * The term path is used when a simplified (subset of) XPath is expected. Path is always a valid XPath but not
  * the other way around. In short, paths only identify a specific (set of) nodes based on their ancestors in the
  * schema. Predicates are allowed the same as for an [instance-identifier](https://tools.ietf.org/html/rfc7950#section-9.13).
  * Specifically, key values of a list, leaf-list value, or position of lists without keys can be used.
  *
  * Examples
  * --------
  *
  * - get __list__ instance with __key1__ of value __1__ and __key2__ of value __2__ (this can return more __list__ instances if there are more keys than __key1__ and __key2__)
  *
  *       /module-name:container/list[key1='1'][key2='2']
  *
  * - get __leaf-list__ instance with the value __val__
  *
  *       /module-name:container/leaf-list[.='val']
  *
  * - get __3rd list-without-keys__ instance with no keys defined
  *
  *       /module-name:container/list-without-keys[3]
  *
  * - get __aug-list__ with __aug-list-key__, which was added to __module-name__ from an augment module __augment-module__
  *
  *       /module-name:container/container2/augment-module:aug-cont/aug-list[aug-list-key='value']
  *
  * Functions List
  * --------------
  * - ::lyd_new_path()
  * - ::lyd_new_path2()
  * - ::lyd_path()
  * - ::lyd_find_path()
  * - ::lys_find_path()
  *
  */

 /**
  * @defgroup trees Trees
  *
  * Generic macros, functions, etc. to work with both [schema](@ref schematree) and [data](@ref datatree) trees.
  *
  * @{
  */

 /**
  * @brief Type (i.e. size) of the [sized array](@ref sizedarrays)'s size counter.
  *
  * To print the value via a print format, use LY_PRI_ARRAY_COUNT_TYPE specifier.
  */
 #define LY_ARRAY_COUNT_TYPE uint64_t

 /**
  * @brief Printing format specifier macro for LY_ARRAY_SIZE_TYPE values.
  */
 #define LY_PRI_ARRAY_COUNT_TYPE PRIu64

 /**
  * @brief Macro selector for other LY_ARRAY_* macros, do not use directly!
  */
 #define LY_ARRAY_SELECT(_1, _2, NAME, ...) NAME

 /**
  * @brief Helper macro to go through sized-arrays with a pointer iterator.
  *
  * Use with opening curly bracket (`{`).
  *
  * @param[in] ARRAY Array to go through
  * @param[in] TYPE Type of the records in the ARRAY
  * @param[out] ITER Iterating pointer to the item being processed in each loop
  */
 #define LY_ARRAY_FOR_ITER(ARRAY, TYPE, ITER) \
     for (ITER = ARRAY; \
          (ARRAY) && ((void*)ITER - (void*)ARRAY)/(sizeof(TYPE)) < (*((LY_ARRAY_COUNT_TYPE*)(ARRAY) - 1)); \
          ITER = (void*)((TYPE*)ITER + 1))

 /**
  * @brief Helper macro to go through sized-arrays with a numeric iterator.
  *
  * Use with opening curly bracket (`{`).
  *
  * The item on the current INDEX in the ARRAY can be accessed in a standard C way as ARRAY[INDEX].
  *
  * @param[in] ARRAY Array to go through
  * @param[out] INDEX Variable for the iterating index of the item being processed in each loop
  */
 #define LY_ARRAY_FOR_INDEX(ARRAY, INDEX) \
     for (INDEX = 0; \
          INDEX < LY_ARRAY_COUNT(ARRAY); \
          ++INDEX)

 /**
  * @brief Get the number of records in the ARRAY.
  */
 #define LY_ARRAY_COUNT(ARRAY) (ARRAY ? (*((LY_ARRAY_COUNT_TYPE*)(ARRAY) - 1)) : 0)

 /**
  * @brief Sized-array iterator (for-loop).
  *
  * Use with opening curly bracket (`{`).
  *
  * There are 2 variants:
  *
  *     LY_ARRAY_FOR(ARRAY, TYPE, ITER)
  *
  * Where ARRAY is a sized-array to go through, TYPE is the type of the items in the ARRAY and ITER is a pointer variable
  * providing the items of the ARRAY in the loops. This functionality is provided by LY_ARRAY_FOR_ITER macro
  *
  *     LY_ARRAY_FOR(ARRAY, INDEX)
  *
  * The ARRAY is again a sized-array to go through, the INDEX is a variable (LY_ARRAY_COUNT_TYPE) for storing iterating ARRAY's index
  * to access the items of ARRAY in the loops. This functionality is provided by LY_ARRAY_FOR_INDEX macro.
  */
 #define LY_ARRAY_FOR(ARRAY, ...) LY_ARRAY_SELECT(__VA_ARGS__, LY_ARRAY_FOR_ITER, LY_ARRAY_FOR_INDEX)(ARRAY, __VA_ARGS__)

 /**
  * @brief Macro to iterate via all sibling elements without affecting the list itself
  *
  * Works for all types of nodes despite it is data or schema tree, but all the
  * parameters must be pointers to the same type.
  *
  * Use with opening curly bracket (`{`). All parameters must be of the same type.
  *
  * @param START Pointer to the starting element.
  * @param ELEM Iterator.
  */
 #define LY_LIST_FOR(START, ELEM) \
     for ((ELEM) = (START); \
          (ELEM); \
          (ELEM) = (ELEM)->next)

 /**
  * @brief Macro to iterate via all sibling elements allowing to modify the list itself (e.g. removing elements)
  *
  * Use with opening curly bracket (`{`). All parameters must be of the same type.
  *
  * @param START Pointer to the starting element.
  * @param NEXT Temporary storage to allow removing of the current iterator content.
  * @param ELEM Iterator.
  */
 #define LY_LIST_FOR_SAFE(START, NEXT, ELEM) \
     for ((ELEM) = (START); \
          (ELEM) ? (NEXT = (ELEM)->next, 1) : 0; \
          (ELEM) = (NEXT))

 /**
  * @brief Macro to iterate via all schema node data instances in data siblings.
  *
  * @param START Pointer to the starting sibling. Even if it is not first, all the siblings are searched.
  * @param SCHEMA Schema node of the searched instances.
  * @param ELEM Iterator.
  */
 #define LYD_LIST_FOR_INST(START, SCHEMA, ELEM) \
     for (lyd_find_sibling_val(START, SCHEMA, NULL, 0, &(ELEM)); \
          (ELEM) && ((ELEM)->schema == (SCHEMA)); \
          (ELEM) = (ELEM)->next)

 /**
  * @brief Macro to iterate via all schema node data instances in data siblings allowing to modify the list itself.
  *
  * @param START Pointer to the starting sibling. Even if it is not first, all the siblings are searched.
  * @param SCHEMA Schema node of the searched instances.
  * @param NEXT Temporary storage to allow removing of the current iterator content.
  * @param ELEM Iterator.
  */
 #define LYD_LIST_FOR_INST_SAFE(START, SCHEMA, NEXT, ELEM) \
     for (lyd_find_sibling_val(START, SCHEMA, NULL, 0, &(ELEM)); \
          (ELEM) && ((ELEM)->schema == (SCHEMA)) ? ((NEXT) = (ELEM)->next, 1) : 0; \
          (ELEM) = (NEXT))

 /**
  * @brief YANG built-in types
  */
 typedef enum
 {
     LY_TYPE_UNKNOWN = 0, /**< Unknown type */
     LY_TYPE_BINARY, /**< Any binary data ([RFC 6020 sec 9.8](http://tools.ietf.org/html/rfc6020#section-9.8)) */
     LY_TYPE_UINT8, /**< 8-bit unsigned integer ([RFC 6020 sec 9.2](http://tools.ietf.org/html/rfc6020#section-9.2)) */
     LY_TYPE_UINT16, /**< 16-bit unsigned integer ([RFC 6020 sec 9.2](http://tools.ietf.org/html/rfc6020#section-9.2)) */
     LY_TYPE_UINT32, /**< 32-bit unsigned integer ([RFC 6020 sec 9.2](http://tools.ietf.org/html/rfc6020#section-9.2)) */
     LY_TYPE_UINT64, /**< 64-bit unsigned integer ([RFC 6020 sec 9.2](http://tools.ietf.org/html/rfc6020#section-9.2)) */
     LY_TYPE_STRING, /**< Human-readable string ([RFC 6020 sec 9.4](http://tools.ietf.org/html/rfc6020#section-9.4)) */
     LY_TYPE_BITS, /**< A set of bits or flags ([RFC 6020 sec 9.7](http://tools.ietf.org/html/rfc6020#section-9.7)) */
     LY_TYPE_BOOL, /**< "true" or "false" ([RFC 6020 sec 9.5](http://tools.ietf.org/html/rfc6020#section-9.5)) */
     LY_TYPE_DEC64, /**< 64-bit signed decimal number ([RFC 6020 sec 9.3](http://tools.ietf.org/html/rfc6020#section-9.3))*/
     LY_TYPE_EMPTY, /**< A leaf that does not have any value ([RFC 6020 sec 9.11](http://tools.ietf.org/html/rfc6020#section-9.11)) */
     LY_TYPE_ENUM, /**< Enumerated strings ([RFC 6020 sec 9.6](http://tools.ietf.org/html/rfc6020#section-9.6)) */
     LY_TYPE_IDENT, /**< A reference to an abstract identity ([RFC 6020 sec 9.10](http://tools.ietf.org/html/rfc6020#section-9.10)) */
     LY_TYPE_INST, /**< References a data tree node ([RFC 6020 sec 9.13](http://tools.ietf.org/html/rfc6020#section-9.13)) */
     LY_TYPE_LEAFREF, /**< A reference to a leaf instance ([RFC 6020 sec 9.9](http://tools.ietf.org/html/rfc6020#section-9.9))*/
     LY_TYPE_UNION, /**< Choice of member types ([RFC 6020 sec 9.12](http://tools.ietf.org/html/rfc6020#section-9.12)) */
     LY_TYPE_INT8, /**< 8-bit signed integer ([RFC 6020 sec 9.2](http://tools.ietf.org/html/rfc6020#section-9.2)) */
     LY_TYPE_INT16, /**< 16-bit signed integer ([RFC 6020 sec 9.2](http://tools.ietf.org/html/rfc6020#section-9.2)) */
     LY_TYPE_INT32, /**< 32-bit signed integer ([RFC 6020 sec 9.2](http://tools.ietf.org/html/rfc6020#section-9.2)) */
     LY_TYPE_INT64  /**< 64-bit signed integer ([RFC 6020 sec 9.2](http://tools.ietf.org/html/rfc6020#section-9.2)) */
 } LY_DATA_TYPE;
 #define LY_DATA_TYPE_COUNT 20 /**< Number of different types */

 /**
  * @brief Stringified YANG built-in data types
  */
 extern const char *ly_data_type2str[LY_DATA_TYPE_COUNT];

 /** @} trees */

 #ifdef __cplusplus
 }
 #endif

 #endif /* LY_TREE_H_ */
	/**
	* @file tree.h
	* @author Radek Krejci <rkrejci@cesnet.cz>
	* @brief libyang generic macros and functions to work with YANG schema or data trees.
	*
	* Copyright (c) 2019 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_H_
	#define LY_TREE_H_

	#include <inttypes.h>

	#include "tree_data.h"

	#ifdef __cplusplus
	extern "C" {
	#endif

	/**
	* @page howtoXPath XPath Addressing
	*
	* Internally, XPath evaluation is performed on __when__ and __must__ conditions in the schema. For that almost
	* a full [XPath 1.0](http://www.w3.org/TR/1999/REC-xpath-19991116/) evaluator was implemented.
	* In YANG models you can also find paths identifying __augment__ targets, __leafref__ targets, and trivial paths in
	* __choice default__ and __unique__ statements argument. The exact format of all those paths can be found in the
	* relevant RFCs. Further will only be discussed paths that are used directly in libyang API functions.
	*
	* XPath
	* =====
	*
	* Generally, any xpath argument expects an expression similar to _when_ or _must_ as the same evaluator is used. As for
	* the format of any prefixes, the standardized JSON ([RFC 7951](https://tools.ietf.org/html/rfc7951#section-6.11))
	* was used. Summarized, xpath follows these conventions:
	* - full XPath can be used, but only data nodes (node sets) will always be returned,
	* - as per the specification, prefixes are actually __module names__,
	* - also in the specification, for _absolute_ paths, the first (leftmost) node _MUST_ have a prefix,
	* - for _relative_ paths, you specify the __context node__, which then acts as a parent for the first node in the path,
	* - nodes always inherit their module (prefix) from their __parent node__ so whenever a node is from a different
	* module than its parent, it _MUST_ have a prefix,
	* - nodes from the same module as their __parent__ _MUST NOT_ have a prefix,
	* - note that non-data nodes/schema-only node (choice, case, uses, input, output) are skipped and _MUST_ not be
	* included in the path.
	*
	* Functions List
	* --------------
	* - ::lyd_find_xpath()
	* - ::lys_find_xpath()
	*
	* Path
	* ====
	*
	* The term path is used when a simplified (subset of) XPath is expected. Path is always a valid XPath but not
	* the other way around. In short, paths only identify a specific (set of) nodes based on their ancestors in the
	* schema. Predicates are allowed the same as for an [instance-identifier](https://tools.ietf.org/html/rfc7950#section-9.13).
	* Specifically, key values of a list, leaf-list value, or position of lists without keys can be used.
	*
	* Examples
	* --------
	*
	* - get __list__ instance with __key1__ of value __1__ and __key2__ of value __2__ (this can return more __list__ instances if there are more keys than __key1__ and __key2__)
	*
	* /module-name:container/list[key1='1'][key2='2']
	*
	* - get __leaf-list__ instance with the value __val__
	*
	* /module-name:container/leaf-list[.='val']
	*
	* - get __3rd list-without-keys__ instance with no keys defined
	*
	* /module-name:container/list-without-keys[3]
	*
	* - get __aug-list__ with __aug-list-key__, which was added to __module-name__ from an augment module __augment-module__
	*
	* /module-name:container/container2/augment-module:aug-cont/aug-list[aug-list-key='value']
	*
	* Functions List
	* --------------
	* - ::lyd_new_path()
	* - ::lyd_new_path2()
	* - ::lyd_path()
	* - ::lyd_find_path()
	* - ::lys_find_path()
	*
	*/

	/**
	* @defgroup trees Trees
	*
	* Generic macros, functions, etc. to work with both [schema](@ref schematree) and [data](@ref datatree) trees.
	*
	* @{
	*/

	/**
	* @brief Type (i.e. size) of the [sized array](@ref sizedarrays)'s size counter.
	*
	* To print the value via a print format, use LY_PRI_ARRAY_COUNT_TYPE specifier.
	*/
	#define LY_ARRAY_COUNT_TYPE uint64_t

	/**
	* @brief Printing format specifier macro for LY_ARRAY_SIZE_TYPE values.
	*/
	#define LY_PRI_ARRAY_COUNT_TYPE PRIu64

	/**
	* @brief Macro selector for other LY_ARRAY_* macros, do not use directly!
	*/
	#define LY_ARRAY_SELECT(_1, _2, NAME, ...) NAME

	/**
	* @brief Helper macro to go through sized-arrays with a pointer iterator.
	*
	* Use with opening curly bracket (`{`).
	*
	* @param[in] ARRAY Array to go through
	* @param[in] TYPE Type of the records in the ARRAY
	* @param[out] ITER Iterating pointer to the item being processed in each loop
	*/
	#define LY_ARRAY_FOR_ITER(ARRAY, TYPE, ITER) \
	for (ITER = ARRAY; \
	(ARRAY) && ((void)ITER - (void)ARRAY)/(sizeof(TYPE)) < (((LY_ARRAY_COUNT_TYPE)(ARRAY) - 1)); \
	ITER = (void)((TYPE)ITER + 1))

	/**
	* @brief Helper macro to go through sized-arrays with a numeric iterator.
	*
	* Use with opening curly bracket (`{`).
	*
	* The item on the current INDEX in the ARRAY can be accessed in a standard C way as ARRAY[INDEX].
	*
	* @param[in] ARRAY Array to go through
	* @param[out] INDEX Variable for the iterating index of the item being processed in each loop
	*/
	#define LY_ARRAY_FOR_INDEX(ARRAY, INDEX) \
	for (INDEX = 0; \
	INDEX < LY_ARRAY_COUNT(ARRAY); \
	++INDEX)

	/**
	* @brief Get the number of records in the ARRAY.
	*/
	#define LY_ARRAY_COUNT(ARRAY) (ARRAY ? (((LY_ARRAY_COUNT_TYPE)(ARRAY) - 1)) : 0)

	/**
	* @brief Sized-array iterator (for-loop).
	*
	* Use with opening curly bracket (`{`).
	*
	* There are 2 variants:
	*
	* LY_ARRAY_FOR(ARRAY, TYPE, ITER)
	*
	* Where ARRAY is a sized-array to go through, TYPE is the type of the items in the ARRAY and ITER is a pointer variable
	* providing the items of the ARRAY in the loops. This functionality is provided by LY_ARRAY_FOR_ITER macro
	*
	* LY_ARRAY_FOR(ARRAY, INDEX)
	*
	* The ARRAY is again a sized-array to go through, the INDEX is a variable (LY_ARRAY_COUNT_TYPE) for storing iterating ARRAY's index
	* to access the items of ARRAY in the loops. This functionality is provided by LY_ARRAY_FOR_INDEX macro.
	*/
	#define LY_ARRAY_FOR(ARRAY, ...) LY_ARRAY_SELECT(__VA_ARGS__, LY_ARRAY_FOR_ITER, LY_ARRAY_FOR_INDEX)(ARRAY, __VA_ARGS__)

	/**
	* @brief Macro to iterate via all sibling elements without affecting the list itself
	*
	* Works for all types of nodes despite it is data or schema tree, but all the
	* parameters must be pointers to the same type.
	*
	* Use with opening curly bracket (`{`). All parameters must be of the same type.
	*
	* @param START Pointer to the starting element.
	* @param ELEM Iterator.
	*/
	#define LY_LIST_FOR(START, ELEM) \
	for ((ELEM) = (START); \
	(ELEM); \
	(ELEM) = (ELEM)->next)

	/**
	* @brief Macro to iterate via all sibling elements allowing to modify the list itself (e.g. removing elements)
	*
	* Use with opening curly bracket (`{`). All parameters must be of the same type.
	*
	* @param START Pointer to the starting element.
	* @param NEXT Temporary storage to allow removing of the current iterator content.
	* @param ELEM Iterator.
	*/
	#define LY_LIST_FOR_SAFE(START, NEXT, ELEM) \
	for ((ELEM) = (START); \
	(ELEM) ? (NEXT = (ELEM)->next, 1) : 0; \
	(ELEM) = (NEXT))

	/**
	* @brief Macro to iterate via all schema node data instances in data siblings.
	*
	* @param START Pointer to the starting sibling. Even if it is not first, all the siblings are searched.
	* @param SCHEMA Schema node of the searched instances.
	* @param ELEM Iterator.
	*/
	#define LYD_LIST_FOR_INST(START, SCHEMA, ELEM) \
	for (lyd_find_sibling_val(START, SCHEMA, NULL, 0, &(ELEM)); \
	(ELEM) && ((ELEM)->schema == (SCHEMA)); \
	(ELEM) = (ELEM)->next)

	/**
	* @brief Macro to iterate via all schema node data instances in data siblings allowing to modify the list itself.
	*
	* @param START Pointer to the starting sibling. Even if it is not first, all the siblings are searched.
	* @param SCHEMA Schema node of the searched instances.
	* @param NEXT Temporary storage to allow removing of the current iterator content.
	* @param ELEM Iterator.
	*/
	#define LYD_LIST_FOR_INST_SAFE(START, SCHEMA, NEXT, ELEM) \
	for (lyd_find_sibling_val(START, SCHEMA, NULL, 0, &(ELEM)); \
	(ELEM) && ((ELEM)->schema == (SCHEMA)) ? ((NEXT) = (ELEM)->next, 1) : 0; \
	(ELEM) = (NEXT))

	/**
	* @brief YANG built-in types
	*/
	typedef enum
	{
	LY_TYPE_UNKNOWN = 0, /*< Unknown type /
	LY_TYPE_BINARY, /*< Any binary data ([RFC 6020 sec 9.8](http://tools.ietf.org/html/rfc6020#section-9.8)) /
	LY_TYPE_UINT8, /*< 8-bit unsigned integer ([RFC 6020 sec 9.2](http://tools.ietf.org/html/rfc6020#section-9.2)) /
	LY_TYPE_UINT16, /*< 16-bit unsigned integer ([RFC 6020 sec 9.2](http://tools.ietf.org/html/rfc6020#section-9.2)) /
	LY_TYPE_UINT32, /*< 32-bit unsigned integer ([RFC 6020 sec 9.2](http://tools.ietf.org/html/rfc6020#section-9.2)) /
	LY_TYPE_UINT64, /*< 64-bit unsigned integer ([RFC 6020 sec 9.2](http://tools.ietf.org/html/rfc6020#section-9.2)) /
	LY_TYPE_STRING, /*< Human-readable string ([RFC 6020 sec 9.4](http://tools.ietf.org/html/rfc6020#section-9.4)) /
	LY_TYPE_BITS, /*< A set of bits or flags ([RFC 6020 sec 9.7](http://tools.ietf.org/html/rfc6020#section-9.7)) /
	LY_TYPE_BOOL, /*< "true" or "false" ([RFC 6020 sec 9.5](http://tools.ietf.org/html/rfc6020#section-9.5)) /
	LY_TYPE_DEC64, /*< 64-bit signed decimal number ([RFC 6020 sec 9.3](http://tools.ietf.org/html/rfc6020#section-9.3))/
	LY_TYPE_EMPTY, /*< A leaf that does not have any value ([RFC 6020 sec 9.11](http://tools.ietf.org/html/rfc6020#section-9.11)) /
	LY_TYPE_ENUM, /*< Enumerated strings ([RFC 6020 sec 9.6](http://tools.ietf.org/html/rfc6020#section-9.6)) /
	LY_TYPE_IDENT, /*< A reference to an abstract identity ([RFC 6020 sec 9.10](http://tools.ietf.org/html/rfc6020#section-9.10)) /
	LY_TYPE_INST, /*< References a data tree node ([RFC 6020 sec 9.13](http://tools.ietf.org/html/rfc6020#section-9.13)) /
	LY_TYPE_LEAFREF, /*< A reference to a leaf instance ([RFC 6020 sec 9.9](http://tools.ietf.org/html/rfc6020#section-9.9))/
	LY_TYPE_UNION, /*< Choice of member types ([RFC 6020 sec 9.12](http://tools.ietf.org/html/rfc6020#section-9.12)) /
	LY_TYPE_INT8, /*< 8-bit signed integer ([RFC 6020 sec 9.2](http://tools.ietf.org/html/rfc6020#section-9.2)) /
	LY_TYPE_INT16, /*< 16-bit signed integer ([RFC 6020 sec 9.2](http://tools.ietf.org/html/rfc6020#section-9.2)) /
	LY_TYPE_INT32, /*< 32-bit signed integer ([RFC 6020 sec 9.2](http://tools.ietf.org/html/rfc6020#section-9.2)) /
	LY_TYPE_INT64 /*< 64-bit signed integer ([RFC 6020 sec 9.2](http://tools.ietf.org/html/rfc6020#section-9.2)) /
	} LY_DATA_TYPE;
	#define LY_DATA_TYPE_COUNT 20 /*< Number of different types /

	/**
	* @brief Stringified YANG built-in data types
	*/
	extern const char *ly_data_type2str[LY_DATA_TYPE_COUNT];

	/** @} trees */

	#ifdef __cplusplus
	}
	#endif

	#endif /* LY_TREE_H_ */