blob: 19ece23db30089476b3c726d87a8fb6355630e3d [file] [log] [blame]
/**
* @file common.h
* @author Radek Krejci <rkrejci@cesnet.cz>
* @brief common internal definitions for libyang
*
* 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
*/
#ifndef LY_COMMON_H_
#define LY_COMMON_H_
#include <pthread.h>
#include <stddef.h>
#include <stdint.h>
#include "context.h"
#include "dict.h"
#include "hash_table.h"
#include "log.h"
#include "set.h"
#include "tree.h"
#include "tree_data.h"
struct ly_ctx;
struct lys_module;
#if __STDC_VERSION__ >= 201112 && !defined __STDC_NO_THREADS__
# define THREAD_LOCAL _Thread_local
#elif defined __GNUC__ || \
defined __SUNPRO_C || \
defined __xlC__
# define THREAD_LOCAL __thread
#else
# error "Cannot define THREAD_LOCAL"
#endif
#define GETMACRO1(_1, NAME, ...) NAME
#define GETMACRO2(_1, _2, NAME, ...) NAME
#define GETMACRO3(_1, _2, _3, NAME, ...) NAME
#define GETMACRO4(_1, _2, _3, _4, NAME, ...) NAME
#define GETMACRO5(_1, _2, _3, _4, _5, NAME, ...) NAME
/*
* If the compiler supports attribute to mark objects as hidden, mark all
* objects as hidden and export only objects explicitly marked to be part of
* the public API.
*/
#define API __attribute__((visibility("default")))
/******************************************************************************
* Logger
*****************************************************************************/
enum LY_VLOG_ELEM {
LY_VLOG_NONE = 0,
LY_VLOG_LINE, /* line number (uint64_t*) */
LY_VLOG_LYSC, /* struct lysc_node* */
LY_VLOG_LYD, /* struct lyd_node* */
LY_VLOG_STR, /* const char* */
LY_VLOG_PREV /* use exact same previous path */
};
extern THREAD_LOCAL enum int_log_opts log_opt;
extern volatile LY_LOG_LEVEL ly_ll;
extern volatile uint32_t ly_log_opts;
/**
* @brief Print a log message and store it into the context (if provided).
*
* @param[in] ctx libyang context to store the error record. If not provided, the error is just printed.
* @param[in] level Log message level (error, warning, etc.)
* @param[in] no Error type code.
* @param[in] format Format string to print.
*/
void ly_log(const struct ly_ctx *ctx, LY_LOG_LEVEL level, LY_ERR no, const char *format, ...);
/**
* @brief Print Validation error and store it into the context (if provided).
*
* @param[in] ctx libyang context to store the error record. If not provided, the error is just printed.
* @param[in] elem_type Type of the data in @p elem variable.
* @param[in] elem Object to provide more information about the place where the error appeared.
* @param[in] code Validation error code.
* @param[in] format Format string to print.
*/
void ly_vlog(const struct ly_ctx *ctx, enum LY_VLOG_ELEM elem_type, const void *elem, LY_VECODE code, const char *format, ...);
#define LOGERR(ctx, errno, str, ...) ly_log(ctx, LY_LLERR, errno, str, ##__VA_ARGS__)
#define LOGWRN(ctx, str, ...) ly_log(ctx, LY_LLWRN, 0, str, ##__VA_ARGS__)
#define LOGVRB(str, ...) ly_log(NULL, LY_LLVRB, 0, str, ##__VA_ARGS__)
#ifdef NDEBUG
# define LOGDBG(dbg_group, str, ...)
#else
void ly_log_dbg(uint32_t group, const char *format, ...);
# define LOGDBG(dbg_group, str, ...) ly_log_dbg(dbg_group, str, ##__VA_ARGS__);
#endif
/**
* Simple EMEM message, it can be safely stored in ::ly_err_item structures without problems when freeing.
*/
#define LY_EMEM_MSG "Memory allocation failed."
#define LOGMEM(CTX) LOGERR(CTX, LY_EMEM, "Memory allocation failed (%s()).", __func__)
#define LOGINT(CTX) LOGERR(CTX, LY_EINT, "Internal error (%s:%d).", __FILE__, __LINE__)
#define LOGARG(CTX, ARG) LOGERR(CTX, LY_EINVAL, "Invalid argument %s (%s()).", #ARG, __func__)
#define LOGVAL(CTX, ELEM_TYPE, ELEM, CODE, ...) ly_vlog(CTX, ELEM_TYPE, ELEM, CODE, ##__VA_ARGS__)
#define LOGMEM_RET(CTX) LOGMEM(CTX); return LY_EMEM
#define LOGINT_RET(CTX) LOGINT(CTX); return LY_EINT
#define LOGARG_RET(CTX) LOGARG(CTX); return LY_EINVAL
/*
* Common code to check return value and perform appropriate action.
*/
#define LY_CHECK_GOTO(COND, GOTO) if ((COND)) {goto GOTO;}
#define LY_CHECK_ERR_GOTO(COND, ERR, GOTO) if ((COND)) {ERR; goto GOTO;}
#define LY_CHECK_RET1(RETVAL) {LY_ERR ret__ = RETVAL;if (ret__ != LY_SUCCESS) {return ret__;}}
#define LY_CHECK_RET2(COND, RETVAL) if ((COND)) {return RETVAL;}
#define LY_CHECK_RET(...) GETMACRO2(__VA_ARGS__, LY_CHECK_RET2, LY_CHECK_RET1)(__VA_ARGS__)
#define LY_CHECK_ERR_RET(COND, ERR, RETVAL) if ((COND)) {ERR; return RETVAL;}
#define LY_CHECK_ARG_GOTO1(CTX, ARG, GOTO) if (!(ARG)) {LOGARG(CTX, ARG);goto GOTO;}
#define LY_CHECK_ARG_GOTO2(CTX, ARG1, ARG2, GOTO) LY_CHECK_ARG_GOTO1(CTX, ARG1, GOTO);LY_CHECK_ARG_GOTO1(CTX, ARG2, GOTO)
#define LY_CHECK_ARG_GOTO3(CTX, ARG1, ARG2, ARG3, GOTO) LY_CHECK_ARG_GOTO2(CTX, ARG1, ARG2, GOTO);LY_CHECK_ARG_GOTO1(CTX, ARG3, GOTO)
#define LY_CHECK_ARG_GOTO4(CTX, ARG1, ARG2, ARG3, ARG4, GOTO) LY_CHECK_ARG_GOTO3(CTX, ARG1, ARG2, ARG3, GOTO);\
LY_CHECK_ARG_GOTO1(CTX, ARG4, GOTO)
#define LY_CHECK_ARG_GOTO(CTX, ...) GETMACRO5(__VA_ARGS__, LY_CHECK_ARG_GOTO4, LY_CHECK_ARG_GOTO3, LY_CHECK_ARG_GOTO2, \
LY_CHECK_ARG_GOTO1)(CTX, __VA_ARGS__)
#define LY_CHECK_ARG_RET1(CTX, ARG, RETVAL) if (!(ARG)) {LOGARG(CTX, ARG);return RETVAL;}
#define LY_CHECK_ARG_RET2(CTX, ARG1, ARG2, RETVAL) LY_CHECK_ARG_RET1(CTX, ARG1, RETVAL);LY_CHECK_ARG_RET1(CTX, ARG2, RETVAL)
#define LY_CHECK_ARG_RET3(CTX, ARG1, ARG2, ARG3, RETVAL) LY_CHECK_ARG_RET2(CTX, ARG1, ARG2, RETVAL);LY_CHECK_ARG_RET1(CTX, ARG3, RETVAL)
#define LY_CHECK_ARG_RET4(CTX, ARG1, ARG2, ARG3, ARG4, RETVAL) LY_CHECK_ARG_RET3(CTX, ARG1, ARG2, ARG3, RETVAL);\
LY_CHECK_ARG_RET1(CTX, ARG4, RETVAL)
#define LY_CHECK_ARG_RET(CTX, ...) GETMACRO5(__VA_ARGS__, LY_CHECK_ARG_RET4, LY_CHECK_ARG_RET3, LY_CHECK_ARG_RET2, LY_CHECK_ARG_RET1)\
(CTX, __VA_ARGS__)
/* count sequence size for LY_VCODE_INCHILDSTMT validation error code */
size_t LY_VCODE_INSTREXP_len(const char *str);
/* default maximum characters to print in LY_VCODE_INCHILDSTMT */
#define LY_VCODE_INSTREXP_MAXLEN 20
#define LY_VCODE_INCHAR LYVE_SYNTAX, "Invalid character 0x%x."
#define LY_VCODE_INSTREXP LYVE_SYNTAX, "Invalid character sequence \"%.*s\", expected %s."
#define LY_VCODE_EOF LYVE_SYNTAX, "Unexpected end-of-input."
#define LY_VCODE_NTERM LYVE_SYNTAX, "%s not terminated."
#define LY_VCODE_NSUPP LYVE_SYNTAX, "%s not supported."
#define LY_VCODE_MOD_SUBOMD LYVE_SYNTAX, "Invalid keyword \"%s\", expected \"module\" or \"submodule\"."
#define LY_VCODE_TRAILING_MOD LYVE_SYNTAX, "Trailing garbage \"%.*s%s\" after module, expected end-of-input."
#define LY_VCODE_TRAILING_SUBMOD LYVE_SYNTAX, "Trailing garbage \"%.*s%s\" after submodule, expected end-of-input."
#define LY_VCODE_INVAL_MINMAX LYVE_SEMANTICS, "Invalid combination of min-elements and max-elements: min value %u is bigger than the max value %u."
#define LY_VCODE_CIRC_WHEN LYVE_SEMANTICS, "When condition of \"%s\" includes a self-reference (referenced by when of \"%s\")."
#define LY_VCODE_DUMMY_WHEN LYVE_SEMANTICS, "When condition of \"%s\" is accessing its own conditional node."
#define LY_VCODE_INSTMT LYVE_SYNTAX_YANG, "Invalid keyword \"%s\"."
#define LY_VCODE_INCHILDSTMT LYVE_SYNTAX_YANG, "Invalid keyword \"%s\" as a child of \"%s\"."
#define LY_VCODE_INCHILDSTMT2 LYVE_SYNTAX_YANG, "Invalid keyword \"%s\" as a child of \"%s\" - the statement is allowed only in YANG 1.1 modules."
#define LY_VCODE_INCHILDSTMSCOMB LYVE_SYNTAX_YANG, "Invalid combination of keywords \"%s\" and \"%s\" as substatements of \"%s\"."
#define LY_VCODE_DUPSTMT LYVE_SYNTAX_YANG, "Duplicate keyword \"%s\"."
#define LY_VCODE_DUPIDENT LYVE_SYNTAX_YANG, "Duplicate identifier \"%s\" of %s statement."
#define LY_VCODE_INVAL LYVE_SYNTAX_YANG, "Invalid value \"%.*s\" of \"%s\"."
#define LY_VCODE_MISSTMT LYVE_SYNTAX_YANG, "Missing mandatory keyword \"%s\" as a child of \"%s\"."
#define LY_VCODE_MISSCHILDSTMT LYVE_SYNTAX_YANG, "Missing %s substatement for %s%s."
#define LY_VCODE_INORD LYVE_SYNTAX_YANG, "Invalid keyword \"%s\", it cannot appear after \"%s\"."
#define LY_VCODE_OOB LYVE_SYNTAX_YANG, "Value \"%.*s\" is out of \"%s\" bounds."
#define LY_VCODE_INDEV LYVE_SYNTAX_YANG, "Deviate \"%s\" does not support keyword \"%s\"."
#define LY_VCODE_INREGEXP LYVE_SYNTAX_YANG, "Regular expression \"%s\" is not valid (\"%s\": %s)."
#define LY_VCODE_INSUBELEM2 LYVE_SYNTAX_YIN, "Invalid sub-elemnt \"%s\" of \"%s\" element - this sub-element is allowed only in modules with version 1.1 or newer."
#define LY_VCODE_INVAL_YIN LYVE_SYNTAX_YIN, "Invalid value \"%s\" of \"%s\" attribute in \"%s\" element."
#define LY_VCODE_UNEXP_SUBELEM LYVE_SYNTAX_YIN, "Unexpected sub-element \"%.*s\" of \"%s\" element."
#define LY_VCODE_INDEV_YIN LYVE_SYNTAX_YIN, "Deviate of this type doesn't allow \"%s\" as it's sub-element."
#define LY_VCODE_INORDER_YIN LYVE_SYNTAX_YIN, "Invalid order of %s\'s sub-elements \"%s\" can't appear after \"%s\"."
#define LY_VCODE_OOB_YIN LYVE_SYNTAX_YIN, "Value \"%s\" of \"%s\" attribute in \"%s\" element is out of bounds."
#define LY_VCODE_INCHILDSTMSCOMB_YIN LYVE_SYNTAX_YIN, "Invalid combination of sub-elemnts \"%s\" and \"%s\" in \"%s\" element."
#define LY_VCODE_DUP_ATTR LYVE_SYNTAX_YIN, "Duplicit definition of \"%s\" attribute in \"%s\" element."
#define LY_VCODE_UNEXP_ATTR LYVE_SYNTAX_YIN, "Unexpected attribute \"%.*s\" of \"%s\" element."
#define LY_VCODE_MAND_SUBELEM LYVE_SYNTAX_YIN, "Missing mandatory sub-element \"%s\" of \"%s\" element."
#define LY_VCODE_FIRT_SUBELEM LYVE_SYNTAX_YIN, "Sub-element \"%s\" of \"%s\" element must be defined as it's first sub-element."
#define LY_VCODE_NAME_COL LYVE_SYNTAX_YIN, "Name collision between module and submodule of name \"%s\"."
#define LY_VCODE_SUBELEM_REDEF LYVE_SYNTAX_YIN, "Redefinition of \"%s\" sub-element in \"%s\" element."
#define LY_VCODE_XP_EOE LYVE_XPATH, "Unterminated string delimited with %c (%.15s)."
#define LY_VCODE_XP_INEXPR LYVE_XPATH, "Invalid character number %u of expression \'%s\'."
#define LY_VCODE_XP_EOF LYVE_XPATH, "Unexpected XPath expression end."
#define LY_VCODE_XP_INTOK LYVE_XPATH, "Unexpected XPath token \"%s\" (\"%.15s\")."
#define LY_VCODE_XP_INTOK2 LYVE_XPATH, "Unexpected XPath token \"%s\" (\"%.15s\"), expected \"%s\"."
#define LY_VCODE_XP_INFUNC LYVE_XPATH, "Unknown XPath function \"%.*s\"."
#define LY_VCODE_XP_INARGCOUNT LYVE_XPATH, "Invalid number of arguments (%d) for the XPath function %.*s."
#define LY_VCODE_XP_INARGTYPE LYVE_XPATH, "Wrong type of argument #%d (%s) for the XPath function %s."
#define LY_VCODE_XP_INCTX LYVE_XPATH, "Invalid context type %s in %s."
#define LY_VCODE_XP_INOP_1 LYVE_XPATH, "Cannot apply XPath operation %s on %s."
#define LY_VCODE_XP_INOP_2 LYVE_XPATH, "Cannot apply XPath operation %s on %s and %s."
#define LY_VCODE_XP_INMOD LYVE_XPATH, "Unknown/non-implemented module \"%.*s\"."
#define LY_VCODE_DEV_NOT_PRESENT LYVE_REFERENCE, "Invalid deviation %s \"%s\" property \"%s\" which is not present."
#define LY_VCODE_NOWHEN LYVE_DATA, "When condition \"%s\" not satisfied."
#define LY_VCODE_NOMUST LYVE_DATA, "Must condition \"%s\" not satisfied."
#define LY_VCODE_NOMAND LYVE_DATA, "Mandatory node \"%s\" instance does not exist."
#define LY_VCODE_NOMIN LYVE_DATA, "Too few \"%s\" instances."
#define LY_VCODE_NOMAX LYVE_DATA, "Too many \"%s\" instances."
#define LY_VCODE_NOUNIQ LYVE_DATA, "Unique data leaf(s) \"%s\" not satisfied in \"%s\" and \"%s\"."
#define LY_VCODE_DUP LYVE_DATA, "Duplicate instance of \"%s\"."
#define LY_VCODE_DUPCASE LYVE_DATA, "Data for both cases \"%s\" and \"%s\" exist."
#define LY_VCODE_INNODE LYVE_DATA, "Invalid %s data node \"%s\" found."
#define LY_VCODE_NOKEY LYVE_DATA, "List instance is missing its key \"%s\"."
/******************************************************************************
* Context
*****************************************************************************/
/**
* @brief Context of the YANG schemas
*/
struct ly_ctx {
struct dict_table dict; /**< dictionary to effectively store strings used in the context related structures */
struct ly_set search_paths; /**< set of directories where to search for schema's imports/includes */
struct ly_set list; /**< set of loaded YANG schemas */
ly_module_imp_clb imp_clb; /**< Optional callback for retrieving missing included or imported models in a custom way. */
void *imp_clb_data; /**< Optional private data for ::ly_ctx.imp_clb */
uint16_t module_set_id; /**< ID of the current set of schemas */
uint16_t flags; /**< context settings, see @ref contextoptions. */
pthread_key_t errlist_key; /**< key for the thread-specific list of errors related to the context */
};
/**
* @brief Try to find submodule in the context. Submodules are present only in the parsed (lysp_) schema trees, if only
* the compiled versions of the schemas are present, the submodule cannot be returned even if it was used to compile
* some of the currently present schemas.
*
* @param[in] ctx Context where to search in case @p module is NULL.
* @param[in] module Submodule parent (belongs-to) module in case @p ctx is NULL.
* @param[in] submodule Name of the submodule to find.
* @param[in] revision Optional revision of the submodule to find. If not specified, the latest revision is returned.
* @return Pointer to the specified submodule if it is present in the context.
*/
struct lysp_submodule *ly_ctx_get_submodule(const struct ly_ctx *ctx, const struct lys_module *module,
const char *submodule, const char *revision);
/**
* @brief Get the (only) implemented YANG module specified by its name.
*
* @param[in] ctx Context where to search.
* @param[in] name Name of the YANG module to get.
* @param[in] name_len Optional length of the @p name. If zero, NULL-terminated name is expected.
* @return The only implemented YANG module revision of the given name in the given context. NULL if there is no
* implemented module of the given name.
*/
struct lys_module *ly_ctx_get_module_implemented2(const struct ly_ctx *ctx, const char *name, size_t name_len);
/******************************************************************************
* Parsers
*****************************************************************************/
/* list of the YANG statements strings */
extern const char * const ly_stmt_list[];
#define ly_stmt2str(STMT) ly_stmt_list[STMT]
/* list of the extensions' substatements strings */
extern const char * const lyext_substmt_list[];
#define lyext_substmt2str(STMT) lyext_substmt_list[STMT]
/* list of the deviate modifications strings */
extern const char * const ly_devmod_list[];
#define ly_devmod2str(TYPE) ly_devmod_list[TYPE]
/******************************************************************************
* Generic useful functions.
*****************************************************************************/
/**
* @brief Insert string into dictionary.
*
* @param[in] CTX libyang context.
* @param[in] STRING string to store.
* @param[in] LEN length of the string in WORD to store.
* @param[in,out] DYNAMIC Set to 1 if STR is dynamically allocated, 0 otherwise. If set to 1, zerocopy version of lydict_insert is used.
*/
#define INSERT_STRING_RET(CTX, STRING, LEN, DYNAMIC, TARGET) \
if (DYNAMIC) { \
LY_CHECK_RET(lydict_insert_zc(CTX, (char *)(STRING), &(TARGET))); \
} else { \
LY_CHECK_RET(lydict_insert(CTX, LEN ? (STRING) : "", LEN, &(TARGET))); \
} \
DYNAMIC = 0
#define FREE_STRING(CTX, STRING) if (STRING) {lydict_remove(CTX, STRING);}
/**
* @brief Wrapper for realloc() call. The only difference is that if it fails to
* allocate the requested memory, the original memory is freed as well.
*
* @param[in] ptr Memory to reallocate.
* @param[in] size New size of the memory block.
*
* @return Pointer to the new memory, NULL on error.
*/
void *ly_realloc(void *ptr, size_t size);
/**
* @brief Just like strchr() function except limit the number of examined characters.
*
* @param[in] s String to search in.
* @param[in] c Character to search for.
* @param[in] len Limit the search to this number of characters in @p s.
* @return Pointer to first @p c occurence in @p s, NULL if not found in first @p len characters.
*/
char *ly_strnchr(const char *s, int c, size_t len);
/**
* @brief Compare NULL-terminated @p refstr with @str_len bytes from @p str.
*
* @param[in] refstr NULL-terminated string which must match @str_len bytes from @str followed by NULL-byte.
* @param[in] str String to compare
* @param[in] str_len Number of bytes to take into comparison from @p str.
* @return An integer less than, equal to, or greater than zero if @p refstr matches,
* respectively, to be less than, to match, or be greater than @p str.
*/
int ly_strncmp(const char *refstr, const char *str, size_t str_len);
/**
* @brief Wrapper around strlen() to handle NULL strings.
*/
#define ly_strlen(STR) (STR ? strlen(STR) : 0)
/**
* @brief Compile-time strlen() for string contants.
*
* Use to avoid magic numbers usage
*/
#define ly_strlen_const(STR) (sizeof STR - 1)
#define ly_sizeofarray(ARRAY) (sizeof ARRAY / sizeof *ARRAY)
/*
* Numerical bases for use in functions like strtoll() instead of magic numbers
*/
#define LY_BASE_DEC 10 /**< Decimal numeral base */
#define LY_BASE_OCT 8 /**< Octal numeral base */
#define LY_BASE_HEX 16 /**< Hexadecimal numeral base */
/**
* Maximal length of (needed storage for) a number encoded as a string.
*
* Applies not only for standard numbers, but also for YANG's decimal64.
*/
#define LY_NUMBER_MAXLEN 22
/**
* @brief Get UTF8 code point of the next character in the input string.
*
* @param[in,out] input Input string to process, updated according to the processed/read data.
* @param[out] utf8_char UTF8 code point of the next character.
* @param[out] bytes_read Number of bytes used to encode the read utf8_char.
* @return LY_ERR value
*/
LY_ERR ly_getutf8(const char **input, uint32_t *utf8_char, size_t *bytes_read);
/**
* Store UTF-8 character specified as 4byte integer into the dst buffer.
*
* UTF-8 mapping:
* 00000000 -- 0000007F: 0xxxxxxx
* 00000080 -- 000007FF: 110xxxxx 10xxxxxx
* 00000800 -- 0000FFFF: 1110xxxx 10xxxxxx 10xxxxxx
* 00010000 -- 001FFFFF: 11110xxx 10xxxxxx 10xxxxxx 10xxxxxx
*
* Includes checking for valid characters (following RFC 7950, sec 9.4)
*
* @param[in, out] dst Destination buffer to store the UTF-8 character, must provide enough space (up to 4 bytes) for storing the UTF-8 character.
* @param[in] value 32b value of the UTF-8 character to store.
* @param[out] bytes_written Number of bytes written into @p dst (size of the written UTF-8 character).
* @return LY_SUCCESS on success
* @return LY_EINVAL in case of invalid UTF-8 @p value to store.
*/
LY_ERR ly_pututf8(char *dst, uint32_t value, size_t *bytes_written);
/**
* @brief Get number of characters in the @p str, taking multibyte characters into account.
* @param[in] str String to examine.
* @param[in] bytes Number of valid bytes that are supposed to be taken into account in @p str.
* This parameter is useful mainly for non NULL-terminated strings. In case of NULL-terminated
* string, strlen() can be used.
* @return Number of characters in (possibly) multibyte characters string.
*/
size_t ly_utf8len(const char *str, size_t bytes);
/**
* @brief Parse signed integer with possible limitation.
* @param[in] val_str String value containing signed integer, note that
* nothing else than whitespaces are expected after the value itself.
* @param[in] val_len Length of the @p val_str string.
* @param[in] min Limitation for the value which must not be lower than min.
* @param[in] max Limitation for the value which must not be higher than max.
* @param[in] base Numeric base for parsing:
* 0 - to accept decimal, octal, hexadecimal (e.g. in default value)
* 10 - to accept only decimal (e.g. data instance value)
* @param[out] ret Resulting value.
* @return LY_ERR value:
* LY_EDENIED - the value breaks the limits,
* LY_EVALID - string contains invalid value,
* LY_SUCCESS - successful parsing.
*/
LY_ERR ly_parse_int(const char *val_str, size_t val_len, int64_t min, int64_t max, int base, int64_t *ret);
/**
* @brief Parse unsigned integer with possible limitation.
* @param[in] val_str String value containing unsigned integer, note that
* nothing else than whitespaces are expected after the value itself.
* @param[in] val_len Length of the @p val_str string.
* @param[in] max Limitation for the value which must not be higher than max.
* @param[in] base Numeric base for parsing:
* 0 - to accept decimal, octal, hexadecimal (e.g. in default value)
* 10 - to accept only decimal (e.g. data instance value)
* @param[out] ret Resulting value.
* @return LY_ERR value:
* LY_EDENIED - the value breaks the limits,
* LY_EVALID - string contains invalid value,
* LY_SUCCESS - successful parsing.
*/
LY_ERR ly_parse_uint(const char *val_str, size_t val_len, uint64_t max, int base, uint64_t *ret);
/**
* @brief Parse a node-identifier.
*
* node-identifier = [prefix ":"] identifier
*
* @param[in, out] id Identifier to parse. When returned, it points to the first character which is not part of the identifier.
* @param[out] prefix Node's prefix, NULL if there is not any.
* @param[out] prefix_len Length of the node's prefix, 0 if there is not any.
* @param[out] name Node's name.
* @param[out] nam_len Length of the node's name.
* @return LY_ERR value: LY_SUCCESS or LY_EINVAL in case of invalid character in the id.
*/
LY_ERR ly_parse_nodeid(const char **id, const char **prefix, size_t *prefix_len, const char **name, size_t *name_len);
/**
* @brief parse instance-identifier's predicate, supports key-predicate, leaf-list-predicate and pos rules from YANG ABNF Grammar.
*
* @param[in, out] pred Predicate string (including the leading '[') to parse. The string is updated according to what was parsed
* (even for error case, so it can be used to determine which substring caused failure).
* @param[in] limit Limiting length of the @p pred. Function expects NULL terminated string which is not overread.
* The limit value is not checked with each character, so it can be overread and the failure is detected later.
* @param[in] format Input format of the data containing the @p pred.
* @param[out] prefix Start of the node-identifier's prefix if any, NULL in case of pos or leaf-list-predicate rules.
* @param[out] prefix_len Length of the parsed @p prefix.
* @param[out] id Start of the node-identifier's identifier string, NULL in case of pos rule, "." in case of leaf-list-predicate rule.
* @param[out] id_len Length of the parsed @p id.
* @param[out] value Start of the quoted-string (without quotation marks), not NULL in case of success.
* @param[out] value_len Length of the parsed @p value.
* @param[out] errmsg Error message string in case of error.
* @return LY_SUCCESS in case a complete predicate was parsed.
* @return LY_EVALID in case of invalid predicate form.
* @return LY_EINVAL in case of reaching @p limit when parsing @p pred.
*/
LY_ERR ly_parse_instance_predicate(const char **pred, size_t limit, LYD_FORMAT format,
const char **prefix, size_t *prefix_len, const char **id, size_t *id_len,
const char **value, size_t *value_len, const char **errmsg);
/**
* @brief mmap(2) wrapper to map input files into memory to unify parsing.
*
* The address space is allocate only for reading.
*
* @param[in] ctx libyang context for logging
* @param[in] fd Open file descriptor of a file to map.
* @param[out] length Allocated size.
* @param[out] addr Address where the file is mapped.
* @return LY_ERR value.
*/
LY_ERR ly_mmap(struct ly_ctx *ctx, int fd, size_t *length, void **addr);
/**
* @brief munmap(2) wrapper to free the memory mapped by ::ly_mmap()
*
* @param[in] addr Address where the input file is mapped.
* @param[in] length Allocated size of the address space.
* @return LY_ERR value.
*/
LY_ERR ly_munmap(void *addr, size_t length);
/**
* @brief Concatenate formating string to the @p dest.
*
* @param[in, out] dest String to be concatenated by @p format.
* Note that the input string can be reallocated during concatenation.
* @param[in] format Formating string (as for printf) which is supposed to be added after @p dest.
* @return LY_SUCCESS or LY_EMEM.
*/
LY_ERR ly_strcat(char **dest, const char *format, ...);
/**
* @brief (Re-)Allocation of a ([sized array](@ref sizedarrays)).
*
* Increases the size information.
*
* @param[in] CTX libyang context for logging.
* @param[in,out] ARRAY Pointer to the array to allocate/resize. The size of the allocated
* space is counted from the type of the ARRAY, so do not provide placeholder void pointers.
* @param[out] NEW_ITEM Returning pointer to the newly allocated record in the ARRAY.
* @param[in] RETVAL Return value for the case of error (memory allocation failure).
*/
#define LY_ARRAY_NEW_RET(CTX, ARRAY, NEW_ITEM, RETVAL) \
if (!(ARRAY)) { \
ARRAY = malloc(sizeof(LY_ARRAY_COUNT_TYPE) + sizeof *(ARRAY)); \
*((LY_ARRAY_COUNT_TYPE*)(ARRAY)) = 1; \
} else { \
++(*((LY_ARRAY_COUNT_TYPE*)(ARRAY) - 1)); \
ARRAY = ly_realloc(((LY_ARRAY_COUNT_TYPE*)(ARRAY) - 1), sizeof(LY_ARRAY_COUNT_TYPE) + (*((LY_ARRAY_COUNT_TYPE*)(ARRAY) - 1) * sizeof *(ARRAY))); \
LY_CHECK_ERR_RET(!(ARRAY), LOGMEM(CTX), RETVAL); \
} \
ARRAY = (void*)((LY_ARRAY_COUNT_TYPE*)(ARRAY) + 1); \
(NEW_ITEM) = &(ARRAY)[*((LY_ARRAY_COUNT_TYPE*)(ARRAY) - 1) - 1]; \
memset(NEW_ITEM, 0, sizeof *(NEW_ITEM))
/**
* @brief (Re-)Allocation of a ([sized array](@ref sizedarrays)).
*
* Increases the size information.
*
* @param[in] CTX libyang context for logging.
* @param[in,out] ARRAY Pointer to the array to allocate/resize. The size of the allocated
* space is counted from the type of the ARRAY, so do not provide placeholder void pointers.
* @param[out] NEW_ITEM Returning pointer to the newly allocated record in the ARRAY.
* @param[out] RET Variable to store error code.
* @param[in] GOTO Label to go in case of error (memory allocation failure).
*/
#define LY_ARRAY_NEW_GOTO(CTX, ARRAY, NEW_ITEM, RET, GOTO) \
if (!(ARRAY)) { \
ARRAY = malloc(sizeof(LY_ARRAY_COUNT_TYPE) + sizeof *(ARRAY)); \
*((LY_ARRAY_COUNT_TYPE*)(ARRAY)) = 1; \
} else { \
++(*((LY_ARRAY_COUNT_TYPE*)(ARRAY) - 1)); \
ARRAY = ly_realloc(((LY_ARRAY_COUNT_TYPE*)(ARRAY) - 1), sizeof(LY_ARRAY_COUNT_TYPE) + (*((LY_ARRAY_COUNT_TYPE*)(ARRAY) - 1) * sizeof *(ARRAY))); \
LY_CHECK_ERR_GOTO(!(ARRAY), LOGMEM(CTX); RET = LY_EMEM, GOTO); \
} \
ARRAY = (void*)((LY_ARRAY_COUNT_TYPE*)(ARRAY) + 1); \
(NEW_ITEM) = &(ARRAY)[*((LY_ARRAY_COUNT_TYPE*)(ARRAY) - 1) - 1]; \
memset(NEW_ITEM, 0, sizeof *(NEW_ITEM))
/**
* @brief Allocate a ([sized array](@ref sizedarrays)) for the specified number of items.
* If the ARRAY already exists, it is resized (space for SIZE items is added and zeroed).
*
* Does not set the size information, it is supposed to be incremented via ::LY_ARRAY_INCREMENT
* when the items are filled.
*
* @param[in] CTX libyang context for logging.
* @param[in,out] ARRAY Pointer to the array to create.
* @param[in] SIZE Number of the new items the array is supposed to hold. The size of the allocated
* space is then counted from the type of the ARRAY, so do not provide placeholder void pointers.
* @param[in] RETVAL Return value for the case of error (memory allocation failure).
*/
#define LY_ARRAY_CREATE_RET(CTX, ARRAY, SIZE, RETVAL) \
if (ARRAY) { \
ARRAY = ly_realloc(((LY_ARRAY_COUNT_TYPE*)(ARRAY) - 1), sizeof(LY_ARRAY_COUNT_TYPE) + ((*((LY_ARRAY_COUNT_TYPE*)(ARRAY) - 1) + (SIZE)) * sizeof *(ARRAY))); \
LY_CHECK_ERR_RET(!(ARRAY), LOGMEM(CTX), RETVAL); \
ARRAY = (void*)((LY_ARRAY_COUNT_TYPE*)(ARRAY) + 1); \
memset(&(ARRAY)[*((LY_ARRAY_COUNT_TYPE*)(ARRAY) - 1)], 0, (SIZE) * sizeof *(ARRAY)); \
} else { \
ARRAY = calloc(1, sizeof(LY_ARRAY_COUNT_TYPE) + (SIZE) * sizeof *(ARRAY)); \
LY_CHECK_ERR_RET(!(ARRAY), LOGMEM(CTX), RETVAL); \
ARRAY = (void*)((LY_ARRAY_COUNT_TYPE*)(ARRAY) + 1); \
}
/**
* @brief Allocate a ([sized array](@ref sizedarrays)) for the specified number of items.
* If the ARRAY already exists, it is resized (space for SIZE items is added).
*
* Does not set the count information, it is supposed to be incremented via ::LY_ARRAY_INCREMENT
* when the items are filled.
*
* @param[in] CTX libyang context for logging.
* @param[in,out] ARRAY Pointer to the array to create.
* @param[in] SIZE Number of the new items the array is supposed to hold. The size of the allocated
* space is then counted from the type of the ARRAY, so do not provide placeholder void pointers.
* @param[out] RET Variable to store error code.
* @param[in] GOTO Label to go in case of error (memory allocation failure).
*/
#define LY_ARRAY_CREATE_GOTO(CTX, ARRAY, SIZE, RET, GOTO) \
if (ARRAY) { \
ARRAY = ly_realloc(((LY_ARRAY_COUNT_TYPE*)(ARRAY) - 1), sizeof(LY_ARRAY_COUNT_TYPE) + ((LY_ARRAY_COUNT(ARRAY) + (SIZE)) * sizeof *(ARRAY))); \
LY_CHECK_ERR_GOTO(!(ARRAY), LOGMEM(CTX); RET = LY_EMEM, GOTO); \
ARRAY = (void*)((LY_ARRAY_COUNT_TYPE*)(ARRAY) + 1); \
memset(&(ARRAY)[*((LY_ARRAY_COUNT_TYPE*)(ARRAY) - 1)], 0, (SIZE) * sizeof *(ARRAY)); \
} else { \
ARRAY = calloc(1, sizeof(LY_ARRAY_COUNT_TYPE) + (SIZE) * sizeof *(ARRAY)); \
LY_CHECK_ERR_GOTO(!(ARRAY), LOGMEM(CTX); RET = LY_EMEM, GOTO); \
ARRAY = (void*)((LY_ARRAY_COUNT_TYPE*)(ARRAY) + 1); \
}
/**
* @brief Increment the items counter in a ([sized array](@ref sizedarrays)).
*
* Does not change the allocated memory used by the ARRAY. To do so, use LY_ARRAY_CREATE_RET,
* LY_ARRAY_CREATE_GOTO or LY_ARRAY_RESIZE_ERR_RET.
*
* @param[in] ARRAY Pointer to the array to affect.
*/
#define LY_ARRAY_INCREMENT(ARRAY) \
++(*((LY_ARRAY_COUNT_TYPE*)(ARRAY) - 1))
/**
* @brief Decrement the items counter in a ([sized array](@ref sizedarrays)).
*
* Does not change the allocated memory used by the ARRAY. To do so, use LY_ARRAY_CREATE_RET,
* LY_ARRAY_CREATE_GOTO or LY_ARRAY_RESIZE_ERR_RET.
*
* @param[in] ARRAY Pointer to the array to affect.
*/
#define LY_ARRAY_DECREMENT(ARRAY) \
--(*((LY_ARRAY_COUNT_TYPE*)(ARRAY) - 1))
/**
* @brief Decrement the items counter in a ([sized array](@ref sizedarrays)) and free the whole array
* in case it was decremented to 0.
*
* @param[in] ARRAY Pointer to the array to affect.
*/
#define LY_ARRAY_DECREMENT_FREE(ARRAY) \
--(*((LY_ARRAY_COUNT_TYPE*)(ARRAY) - 1)); \
if (!LY_ARRAY_COUNT(ARRAY)) { \
LY_ARRAY_FREE(ARRAY); \
(ARRAY) = NULL; \
}
/**
* @brief Free the space allocated for the ([sized array](@ref sizedarrays)).
*
* The items inside the array are not freed.
*
* @param[in] ARRAY A ([sized array](@ref sizedarrays)) to be freed.
*/
#define LY_ARRAY_FREE(ARRAY) \
if (ARRAY){free((LY_ARRAY_COUNT_TYPE*)(ARRAY) - 1);}
/**
* @brief Insert item into linked list.
*
* @param[in,out] LIST Linked list to add to.
* @param[in] NEW_ITEM New item, that will be appended to the list, must be already allocated.
* @param[in] LINKER name of structuin member that is used to connect items together.
*/
#define LY_LIST_INSERT(LIST, NEW_ITEM, LINKER)\
if (!(*LIST)) { \
*LIST = (__typeof__(*(LIST)))NEW_ITEM; \
} else { \
do { \
__typeof__(*(LIST)) iterator; \
for (iterator = *(LIST); iterator->LINKER; iterator = iterator->LINKER) {} \
iterator->LINKER = (__typeof__(*(LIST)))NEW_ITEM; \
} while (0); \
}
/**
* @brief Allocate and insert new item into linked list, return in case of error.
*
* @param[in] CTX used for logging.
* @param[in,out] LIST Linked list to add to.
* @param[out] NEW_ITEM New item that is appended to the list.
* @param[in] LINKER name of structure member that is used to connect items together.
* @param[in] RETVAL Return value for the case of error (memory allocation failure).
*/
#define LY_LIST_NEW_RET(CTX, LIST, NEW_ITEM, LINKER, RETVAL) \
NEW_ITEM = calloc(1, sizeof *NEW_ITEM); \
LY_CHECK_ERR_RET(!(NEW_ITEM), LOGMEM(CTX), RETVAL); \
LY_LIST_INSERT(LIST, NEW_ITEM, LINKER)
/**
* @brief Allocate and insert new item into linked list, goto specified label in case of error.
*
* @param[in] CTX used for logging.
* @param[in,out] LIST Linked list to add to.
* @param[out] NEW_ITEM New item that is appended to the list.
* @param[in] LINKER name of structure member that is used to connect items together.
* @param[in] RET variable to store returned error type.
* @param[in] LABEL label to goto in case of error.
*/
#define LY_LIST_NEW_GOTO(CTX, LIST, NEW_ITEM, LINKER, RET, LABEL) \
NEW_ITEM = calloc(1, sizeof *NEW_ITEM); \
LY_CHECK_ERR_GOTO(!(NEW_ITEM), RET = LY_EMEM; LOGMEM(CTX), LABEL); \
LY_LIST_INSERT(LIST, NEW_ITEM, LINKER)
#endif /* LY_COMMON_H_ */