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/**
* @file schema_compile.h
* @author Radek Krejci <rkrejci@cesnet.cz>
* @brief Header for schema compilation.
*
* Copyright (c) 2015 - 2020 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_SCHEMA_COMPILE_H_
#define LY_SCHEMA_COMPILE_H_
#include "log.h"
#include "schema_compile_node.h"
#include "set.h"
#include "tree_schema.h"
/**
* @defgroup scflags Schema compile flags
*
* Flags are currently used only internally - the compilation process does not have a public interface and it is
* integrated in the schema parsers. The current options set does not make sense for public used, but it can be a way
* to modify behavior of the compilation process in future.
*
* @{
*/
#define LYS_COMPILE_RPC_INPUT LYS_CONFIG_W /**< Internal option when compiling schema tree of RPC/action input */
#define LYS_COMPILE_RPC_OUTPUT LYS_CONFIG_R /**< Internal option when compiling schema tree of RPC/action output */
#define LYS_COMPILE_RPC_MASK LYS_CONFIG_MASK /**< mask for the internal RPC options */
#define LYS_COMPILE_NOTIFICATION 0x08 /**< Internal option when compiling schema tree of Notification */
#define LYS_COMPILE_GROUPING 0x10 /** Compiling (validation) of a non-instantiated grouping.
In this case not all the restrictions are checked since they can be valid only
in the real placement of the grouping. TODO - what specifically is not done */
/** @} scflags */
/**
* @brief internal context for compilation
*/
struct lysc_ctx {
struct ly_ctx *ctx;
struct lys_module *cur_mod; /**< module currently being compiled, used as the current module for unprefixed nodes */
struct lysp_module *pmod; /**< parsed module being processed, used for searching imports to resolve prefixed nodes */
struct ly_set groupings; /**< stack for groupings circular check */
struct ly_set xpath; /**< when/must to check */
struct ly_set leafrefs; /**< to validate leafref's targets */
struct ly_set dflts; /**< set of incomplete default values */
struct ly_set tpdf_chain;
struct ly_set augs; /**< set of compiled non-applied top-level augments */
struct ly_set devs; /**< set of compiled non-applied deviations */
struct ly_set uses_augs; /**< set of compiled non-applied uses augments */
struct ly_set uses_rfns; /**< set of compiled non-applied uses refines */
uint32_t path_len;
uint32_t options; /**< various @ref scflags. */
#define LYSC_CTX_BUFSIZE 4078
char path[LYSC_CTX_BUFSIZE];
};
/**
* @brief Structure for remembering default values of leaves and leaf-lists. They are resolved at schema compilation
* end when the whole schema tree is available.
*/
struct lysc_unres_dflt {
union {
struct lysc_node_leaf *leaf;
struct lysc_node_leaflist *llist;
};
struct lysp_qname *dflt;
struct lysp_qname *dflts; /**< this is a sized array */
};
/**
* @brief Duplicate string into dictionary
* @param[in] CTX libyang context of the dictionary.
* @param[in] ORIG String to duplicate.
* @param[out] DUP Where to store the result.
*/
#define DUP_STRING(CTX, ORIG, DUP, RET) if (ORIG) {RET = lydict_insert(CTX, ORIG, 0, &DUP);}
#define DUP_STRING_GOTO(CTX, ORIG, DUP, RET, GOTO) if (ORIG) {LY_CHECK_GOTO(RET = lydict_insert(CTX, ORIG, 0, &DUP), GOTO);}
#define DUP_ARRAY(CTX, ORIG_ARRAY, NEW_ARRAY, DUP_FUNC) \
if (ORIG_ARRAY) { \
LY_ARRAY_COUNT_TYPE u; \
LY_ARRAY_CREATE_RET(CTX, NEW_ARRAY, LY_ARRAY_COUNT(ORIG_ARRAY), LY_EMEM); \
LY_ARRAY_FOR(ORIG_ARRAY, u) { \
LY_ARRAY_INCREMENT(NEW_ARRAY); \
LY_CHECK_RET(DUP_FUNC(CTX, &(NEW_ARRAY)[u], &(ORIG_ARRAY)[u])); \
} \
}
#define COMPILE_OP_ARRAY_GOTO(CTX, ARRAY_P, ARRAY_C, PARENT, ITER, FUNC, USES_STATUS, RET, GOTO) \
if (ARRAY_P) { \
LY_ARRAY_CREATE_GOTO((CTX)->ctx, ARRAY_C, LY_ARRAY_COUNT(ARRAY_P), RET, GOTO); \
LY_ARRAY_COUNT_TYPE __array_offset = LY_ARRAY_COUNT(ARRAY_C); \
for (ITER = 0; ITER < LY_ARRAY_COUNT(ARRAY_P); ++ITER) { \
LY_ARRAY_INCREMENT(ARRAY_C); \
RET = FUNC(CTX, &(ARRAY_P)[ITER], PARENT, &(ARRAY_C)[ITER + __array_offset], USES_STATUS); \
if (RET == LY_EDENIED) { \
LY_ARRAY_DECREMENT(ARRAY_C); \
} else if (RET != LY_SUCCESS) { \
goto GOTO; \
} \
} \
}
#define COMPILE_ARRAY_GOTO(CTX, ARRAY_P, ARRAY_C, ITER, FUNC, RET, GOTO) \
if (ARRAY_P) { \
LY_ARRAY_CREATE_GOTO((CTX)->ctx, ARRAY_C, LY_ARRAY_COUNT(ARRAY_P), RET, GOTO); \
LY_ARRAY_COUNT_TYPE __array_offset = LY_ARRAY_COUNT(ARRAY_C); \
for (ITER = 0; ITER < LY_ARRAY_COUNT(ARRAY_P); ++ITER) { \
LY_ARRAY_INCREMENT(ARRAY_C); \
RET = FUNC(CTX, &(ARRAY_P)[ITER], &(ARRAY_C)[ITER + __array_offset]); \
LY_CHECK_GOTO(RET != LY_SUCCESS, GOTO); \
} \
}
#define COMPILE_EXTS_GOTO(CTX, EXTS_P, EXT_C, PARENT, PARENT_TYPE, RET, GOTO) \
if (EXTS_P) { \
LY_ARRAY_CREATE_GOTO((CTX)->ctx, EXT_C, LY_ARRAY_COUNT(EXTS_P), RET, GOTO); \
for (LY_ARRAY_COUNT_TYPE __exts_iter = 0, __array_offset = LY_ARRAY_COUNT(EXT_C); __exts_iter < LY_ARRAY_COUNT(EXTS_P); ++__exts_iter) { \
LY_ARRAY_INCREMENT(EXT_C); \
RET = lys_compile_ext(CTX, &(EXTS_P)[__exts_iter], &(EXT_C)[__exts_iter + __array_offset], PARENT, PARENT_TYPE, NULL); \
LY_CHECK_GOTO(RET != LY_SUCCESS, GOTO); \
} \
}
/**
* @brief Fill in the prepared compiled extension instance structure according to the parsed extension instance.
*
* @param[in] ctx Compilation context.
* @param[in] ext_p Parsed extension instance.
* @param[in,out] ext Prepared compiled extension instance.
* @param[in] parent Extension instance parent.
* @param[in] parent_type Extension instance parent type.
* @param[in] ext_mod Optional module with the extension instance extension definition, set only for internal annotations.
* @return LY_ERR value.
*/
LY_ERR lys_compile_ext(struct lysc_ctx *ctx, struct lysp_ext_instance *ext_p, struct lysc_ext_instance *ext, void *parent,
LYEXT_PARENT parent_type, const struct lys_module *ext_mod);
/**
* @brief Compile information from the if-feature statement
* @param[in] ctx Compile context.
* @param[in] qname The if-feature argument to process. It is pointer-to-qname just to unify the compile functions.
* @param[in,out] iff Prepared (empty) compiled if-feature structure to fill.
* @return LY_ERR value.
*/
LY_ERR lys_compile_iffeature(struct lysc_ctx *ctx, struct lysp_qname *qname, struct lysc_iffeature *iff);
/**
* @brief Compile information from the identity statement
*
* The backlinks to the identities derived from this one are supposed to be filled later via ::lys_compile_identity_bases().
*
* @param[in] ctx_sc Compile context - alternative to the combination of @p ctx and @p parsed_mod.
* @param[in] ctx libyang context.
* @param[in] parsed_mod Module with the identities.
* @param[in] identities_p Array of the parsed identity definitions to precompile.
* @param[in,out] identities Pointer to the storage of the (pre)compiled identities array where the new identities are
* supposed to be added. The storage is supposed to be initiated to NULL when the first parsed identities are going
* to be processed.
* @return LY_ERR value.
*/
LY_ERR lys_identity_precompile(struct lysc_ctx *ctx_sc, struct ly_ctx *ctx, struct lysp_module *parsed_mod,
struct lysp_ident *identities_p, struct lysc_ident **identities);
/**
* @brief Find and process the referenced base identities from another identity or identityref
*
* For bases in identity set backlinks to them from the base identities. For identityref, store
* the array of pointers to the base identities. So one of the ident or bases parameter must be set
* to distinguish these two use cases.
*
* @param[in] ctx Compile context, not only for logging but also to get the current module to resolve prefixes.
* @param[in] base_pmod Module where to resolve @p bases_p prefixes.
* @param[in] bases_p Array of names (including prefix if necessary) of base identities.
* @param[in] ident Referencing identity to work with, NULL for identityref.
* @param[in] bases Array of bases of identityref to fill in.
* @return LY_ERR value.
*/
LY_ERR lys_compile_identity_bases(struct lysc_ctx *ctx, const struct lysp_module *base_pmod, const char **bases_p,
struct lysc_ident *ident, struct lysc_ident ***bases);
/**
* @brief Create pre-compiled features array.
*
* Features are compiled in two steps to allow forward references between them via their if-feature statements.
* In case of not implemented schemas, the precompiled list of features is stored in lys_module structure and
* the compilation is not finished (if-feature and extensions are missing) and all the features are permanently
* disabled without a chance to change it. The list is used as target for any if-feature statement in any
* implemented module to get valid data to evaluate its result. The compilation is finished via
* ::lys_feature_precompile_finish() in implemented modules. In case a not implemented module becomes implemented,
* the precompiled list is reused to finish the compilation to preserve pointers already used in various compiled
* if-feature structures.
*
* @param[in] ctx_sc Compile context - alternative to the combination of @p ctx and @p parsed_mod.
* @param[in] ctx libyang context.
* @param[in] parsed_mod Module with the features.
* @param[in] features_p Array of the parsed features definitions to precompile.
* @param[in,out] features Pointer to the storage of the (pre)compiled features array where the new features are
* supposed to be added. The storage is supposed to be initiated to NULL when the first parsed features are going
* to be processed.
* @return LY_ERR value.
*/
LY_ERR lys_feature_precompile(struct lysc_ctx *ctx_sc, struct ly_ctx *ctx, struct lysp_module *parsed_mod,
struct lysp_feature *features_p, struct lysc_feature **features);
/**
* @brief Revert compiled list of features back to the precompiled state.
*
* Function is needed in case the compilation failed and the schema is expected to revert back to the non-compiled status.
*
* @param[in] ctx Compilation context.
* @param[in] mod The module structure with the features to decompile.
*/
void lys_feature_precompile_revert(struct lysc_ctx *ctx, struct lys_module *mod);
/**
* @brief Check statement's status for invalid combination.
*
* The modX parameters are used just to determine if both flags are in the same module,
* so any of the schema module structure can be used, but both modules must be provided
* in the same type.
*
* @param[in] ctx Compile context for logging.
* @param[in] flags1 Flags of the referencing node.
* @param[in] mod1 Module of the referencing node,
* @param[in] name1 Schema node name of the referencing node.
* @param[in] flags2 Flags of the referenced node.
* @param[in] mod2 Module of the referenced node,
* @param[in] name2 Schema node name of the referenced node.
* @return LY_ERR value
*/
LY_ERR lysc_check_status(struct lysc_ctx *ctx, uint16_t flags1, void *mod1, const char *name1, uint16_t flags2,
void *mod2, const char *name2);
/**
* @brief Check parsed expression for any prefixes of unimplemented modules.
*
* @param[in] ctx libyang context.
* @param[in] expr Parsed expression.
* @param[in] format Prefix format.
* @param[in] prefix_data Format-specific data (see ::ly_resolve_prefix()).
* @param[in] implement Whether all the non-implemented modules should are implemented or the first
* non-implemented module, if any, returned in @p mod_p.
* @param[out] mod_p Module that is not implemented.
* @return LY_SUCCESS on success.
* @return LY_ERR on error.
*/
LY_ERR lys_compile_expr_implement(const struct ly_ctx *ctx, const struct lyxp_expr *expr, LY_PREFIX_FORMAT format,
void *prefix_data, ly_bool implement, const struct lys_module **mod_p);
/**
* @brief Compile printable schema into a validated schema linking all the references.
*
* @param[in] mod Pointer to the schema structure holding pointers to both schema structure types. The ::lys_module#parsed
* member is used as input and ::lys_module#compiled is used to hold the result of the compilation.
* @param[in] options Various options to modify compiler behavior, see [compile flags](@ref scflags).
* @return LY_ERR value - LY_SUCCESS or LY_EVALID.
*/
LY_ERR lys_compile(struct lys_module *mod, uint32_t options);
#endif /* LY_SCHEMA_COMPILE_H_ */